%------------------------------------------------------------------------------
% File     : CSE_E---1.5
% Problem  : BIO003+1 : TPTP v8.1.2. Bugfixed v6.4.1.
% Transfm  : none
% Format   : tptp:raw
% Command  : java -jar /export/starexec/sandbox2/solver/bin/mcs_scs.jar %d %s

% Computer : n023.cluster.edu
% Model    : x86_64 x86_64
% CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 2.10GHz
% Memory   : 8042.1875MB
% OS       : Linux 3.10.0-693.el7.x86_64
% CPULimit : 300s
% WCLimit  : 300s
% DateTime : Wed Aug 30 17:59:31 EDT 2023

% Result   : Theorem 28.74s 28.87s
% Output   : CNFRefutation 29.32s
% Verified : 
% SZS Type : -

% Comments : 
%------------------------------------------------------------------------------
%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.12/0.13  % Problem    : BIO003+1 : TPTP v8.1.2. Bugfixed v6.4.1.
% 0.12/0.14  % Command    : java -jar /export/starexec/sandbox2/solver/bin/mcs_scs.jar %d %s
% 0.13/0.35  % Computer : n023.cluster.edu
% 0.13/0.35  % Model    : x86_64 x86_64
% 0.13/0.35  % CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.13/0.35  % Memory   : 8042.1875MB
% 0.13/0.35  % OS       : Linux 3.10.0-693.el7.x86_64
% 0.13/0.35  % CPULimit   : 300
% 0.13/0.35  % WCLimit    : 300
% 0.13/0.35  % DateTime   : Tue Aug 29 12:56:25 EDT 2023
% 0.13/0.35  % CPUTime  : 
% 0.21/0.57  start to proof: theBenchmark
% 28.74/28.87  % Version  : CSE_E---1.5
% 28.74/28.87  % Problem  : theBenchmark.p
% 28.74/28.87  % Proof found
% 28.74/28.87  % SZS status Theorem for theBenchmark.p
% 28.74/28.87  % SZS output start Proof
% 28.74/28.87  tff(decl_22, type, rejected_0: $i).
% 28.74/28.87  tff(decl_23, type, acceptance_constant_1: $i > $o).
% 28.74/28.87  tff(decl_24, type, accepted_0: $i).
% 28.74/28.87  tff(decl_25, type, inactive_0: $i).
% 28.74/28.87  tff(decl_26, type, activation_constant_1: $i > $o).
% 28.74/28.87  tff(decl_27, type, active_0: $i).
% 28.74/28.87  tff(decl_28, type, elderly_0: $i).
% 28.74/28.87  tff(decl_29, type, age_constant_1: $i > $o).
% 28.74/28.87  tff(decl_30, type, middle_aged_0: $i).
% 28.74/28.87  tff(decl_31, type, adolescent_0: $i).
% 28.74/28.87  tff(decl_32, type, teenage_0: $i).
% 28.74/28.87  tff(decl_33, type, juvenile_0: $i).
% 28.74/28.87  tff(decl_34, type, young_0: $i).
% 28.74/28.87  tff(decl_35, type, not_animate_0: $i).
% 28.74/28.87  tff(decl_36, type, animacy_constant_1: $i > $o).
% 28.74/28.87  tff(decl_37, type, animate_0: $i).
% 28.74/28.87  tff(decl_38, type, unbreakable_0: $i).
% 28.74/28.87  tff(decl_39, type, breakability_constant_1: $i > $o).
% 28.74/28.87  tff(decl_40, type, delicate_0: $i).
% 28.74/28.87  tff(decl_41, type, brittle_0: $i).
% 28.74/28.87  tff(decl_42, type, fragile_0: $i).
% 28.74/28.87  tff(decl_43, type, breakable_0: $i).
% 28.74/28.87  tff(decl_44, type, dark_0: $i).
% 28.74/28.87  tff(decl_45, type, brightness_constant_1: $i > $o).
% 28.74/28.87  tff(decl_46, type, dim_0: $i).
% 28.74/28.87  tff(decl_47, type, bright_0: $i).
% 28.74/28.87  tff(decl_48, type, blinding_0: $i).
% 28.74/28.87  tff(decl_49, type, capacious_0: $i).
% 28.74/28.87  tff(decl_50, type, capacity_constant_1: $i > $o).
% 28.74/28.87  tff(decl_51, type, roomy_0: $i).
% 28.74/28.87  tff(decl_52, type, unlimited_0: $i).
% 28.74/28.87  tff(decl_53, type, none_0: $i).
% 28.74/28.87  tff(decl_54, type, bluegreen_0: $i).
% 28.74/28.87  tff(decl_55, type, color_constant_1: $i > $o).
% 28.74/28.87  tff(decl_56, type, olivegreen_0: $i).
% 28.74/28.87  tff(decl_57, type, yellowgreen_0: $i).
% 28.74/28.87  tff(decl_58, type, whitesmoke_0: $i).
% 28.74/28.87  tff(decl_59, type, wheat_0: $i).
% 28.74/28.87  tff(decl_60, type, violetred_0: $i).
% 28.74/28.87  tff(decl_61, type, violet_0: $i).
% 28.74/28.87  tff(decl_62, type, turquoise_0: $i).
% 28.74/28.87  tff(decl_63, type, tomato_0: $i).
% 28.74/28.87  tff(decl_64, type, thistle_0: $i).
% 28.74/28.87  tff(decl_65, type, tan_0: $i).
% 28.74/28.87  tff(decl_66, type, steelblue_0: $i).
% 28.74/28.87  tff(decl_67, type, springgreen_0: $i).
% 28.74/28.87  tff(decl_68, type, snow_0: $i).
% 28.74/28.87  tff(decl_69, type, slategray_0: $i).
% 28.74/28.87  tff(decl_70, type, slateblue_0: $i).
% 28.74/28.87  tff(decl_71, type, skyblue_0: $i).
% 28.74/28.87  tff(decl_72, type, sienna_0: $i).
% 28.74/28.87  tff(decl_73, type, seashell_0: $i).
% 28.74/28.87  tff(decl_74, type, seagreen_0: $i).
% 28.74/28.87  tff(decl_75, type, sandybrown_0: $i).
% 28.74/28.87  tff(decl_76, type, salmon_0: $i).
% 28.74/28.87  tff(decl_77, type, saddlebrown_0: $i).
% 28.74/28.87  tff(decl_78, type, royalblue_0: $i).
% 28.74/28.87  tff(decl_79, type, rosybrown_0: $i).
% 28.74/28.87  tff(decl_80, type, powderblue_0: $i).
% 28.74/28.87  tff(decl_81, type, plum_0: $i).
% 28.74/28.87  tff(decl_82, type, peru_0: $i).
% 28.74/28.87  tff(decl_83, type, peachpuff_0: $i).
% 28.74/28.87  tff(decl_84, type, papayawhip_0: $i).
% 28.74/28.87  tff(decl_85, type, palevioletred_0: $i).
% 28.74/28.87  tff(decl_86, type, paleturquoise_0: $i).
% 28.74/28.87  tff(decl_87, type, palegreen_0: $i).
% 28.74/28.87  tff(decl_88, type, palegoldenrod_0: $i).
% 28.74/28.87  tff(decl_89, type, orchid_0: $i).
% 28.74/28.87  tff(decl_90, type, orangered_0: $i).
% 28.74/28.87  tff(decl_91, type, olivedrab_0: $i).
% 28.74/28.87  tff(decl_92, type, oldlace_0: $i).
% 28.74/28.87  tff(decl_93, type, mavajowhite_0: $i).
% 28.74/28.87  tff(decl_94, type, moccasin_0: $i).
% 28.74/28.87  tff(decl_95, type, mistyrose_0: $i).
% 28.74/28.87  tff(decl_96, type, mintcream_0: $i).
% 28.74/28.87  tff(decl_97, type, midnightblue_0: $i).
% 28.74/28.87  tff(decl_98, type, mediumvioletred_0: $i).
% 28.74/28.87  tff(decl_99, type, mediumturquoise_0: $i).
% 28.74/28.87  tff(decl_100, type, mediumspringgreen_0: $i).
% 28.74/28.87  tff(decl_101, type, mediumslateblue_0: $i).
% 28.74/28.87  tff(decl_102, type, mediumseagreen_0: $i).
% 28.74/28.87  tff(decl_103, type, mediumpurple_0: $i).
% 28.74/28.87  tff(decl_104, type, mediumorchid_0: $i).
% 28.74/28.87  tff(decl_105, type, mediumblue_0: $i).
% 28.74/28.87  tff(decl_106, type, mediumaquamarine_0: $i).
% 28.74/28.87  tff(decl_107, type, magenta_0: $i).
% 28.74/28.87  tff(decl_108, type, linen_0: $i).
% 28.74/28.87  tff(decl_109, type, limegreen_0: $i).
% 28.74/28.87  tff(decl_110, type, lightyellow_0: $i).
% 28.74/28.87  tff(decl_111, type, lightsteelblue_0: $i).
% 28.74/28.87  tff(decl_112, type, lightslategray_0: $i).
% 28.74/28.87  tff(decl_113, type, lightslateblue_0: $i).
% 28.74/28.87  tff(decl_114, type, lightskyblue_0: $i).
% 28.74/28.87  tff(decl_115, type, lightseagreen_0: $i).
% 28.74/28.87  tff(decl_116, type, lightsalmon_0: $i).
% 28.74/28.87  tff(decl_117, type, lightpink_0: $i).
% 28.74/28.87  tff(decl_118, type, lightgreen_0: $i).
% 28.74/28.87  tff(decl_119, type, lightgrey_0: $i).
% 28.74/28.87  tff(decl_120, type, lightgoldenrodyellow_0: $i).
% 28.74/28.87  tff(decl_121, type, lightcyan_0: $i).
% 28.74/28.87  tff(decl_122, type, lightcoral_0: $i).
% 28.74/28.87  tff(decl_123, type, lightblue_0: $i).
% 28.74/28.87  tff(decl_124, type, lemonchiffon_0: $i).
% 28.74/28.87  tff(decl_125, type, lawngreen_0: $i).
% 28.74/28.87  tff(decl_126, type, lavenderblush_0: $i).
% 28.74/28.87  tff(decl_127, type, lavender_0: $i).
% 28.74/28.87  tff(decl_128, type, khaki_0: $i).
% 28.74/28.87  tff(decl_129, type, ivory_0: $i).
% 28.74/28.87  tff(decl_130, type, indigo_0: $i).
% 28.74/28.87  tff(decl_131, type, indianred_0: $i).
% 28.74/28.87  tff(decl_132, type, hotpink_0: $i).
% 28.74/28.87  tff(decl_133, type, honeydew_0: $i).
% 28.74/28.87  tff(decl_134, type, greenyellow_0: $i).
% 28.74/28.87  tff(decl_135, type, goldenrod_0: $i).
% 28.74/28.87  tff(decl_136, type, gold_0: $i).
% 28.74/28.87  tff(decl_137, type, ghostwhite_0: $i).
% 28.74/28.87  tff(decl_138, type, gainsboro_0: $i).
% 28.74/28.87  tff(decl_139, type, forestgreen_0: $i).
% 28.74/28.87  tff(decl_140, type, floralwhite_0: $i).
% 28.74/28.87  tff(decl_141, type, firebrick_0: $i).
% 28.74/28.87  tff(decl_142, type, feldspar_0: $i).
% 28.74/28.87  tff(decl_143, type, dodgerblue_0: $i).
% 28.74/28.87  tff(decl_144, type, dimgray_0: $i).
% 28.74/28.87  tff(decl_145, type, deepskyblue_0: $i).
% 28.74/28.87  tff(decl_146, type, deeppink_0: $i).
% 28.74/28.87  tff(decl_147, type, darkviolet_0: $i).
% 28.74/28.87  tff(decl_148, type, darkturquoise_0: $i).
% 28.74/28.87  tff(decl_149, type, darkslategray_0: $i).
% 28.74/28.87  tff(decl_150, type, darkslateblue_0: $i).
% 28.74/28.87  tff(decl_151, type, darkseagreen_0: $i).
% 28.74/28.87  tff(decl_152, type, darksalmon_0: $i).
% 28.74/28.87  tff(decl_153, type, darkred_0: $i).
% 28.74/28.87  tff(decl_154, type, darkorchid_0: $i).
% 28.74/28.87  tff(decl_155, type, darkorange_0: $i).
% 28.74/28.87  tff(decl_156, type, darkolivegreen_0: $i).
% 28.74/28.87  tff(decl_157, type, darkmagenta_0: $i).
% 28.74/28.87  tff(decl_158, type, darkkhaki_0: $i).
% 28.74/28.87  tff(decl_159, type, darkgreen_0: $i).
% 28.74/28.87  tff(decl_160, type, darkgray_0: $i).
% 28.74/28.87  tff(decl_161, type, darkgoldenrod_0: $i).
% 28.74/28.87  tff(decl_162, type, darkcyan_0: $i).
% 28.74/28.87  tff(decl_163, type, darkblue_0: $i).
% 28.74/28.87  tff(decl_164, type, cyan_0: $i).
% 28.74/28.87  tff(decl_165, type, crimson_0: $i).
% 28.74/28.87  tff(decl_166, type, cornsilk_0: $i).
% 28.74/28.87  tff(decl_167, type, cornflowerblue_0: $i).
% 28.74/28.87  tff(decl_168, type, coral_0: $i).
% 28.74/28.87  tff(decl_169, type, chocolate_0: $i).
% 28.74/28.87  tff(decl_170, type, chartreuse_0: $i).
% 28.74/28.87  tff(decl_171, type, cadetblue_0: $i).
% 28.74/28.87  tff(decl_172, type, burlywood_0: $i).
% 28.74/28.87  tff(decl_173, type, blueviolet_0: $i).
% 28.74/28.87  tff(decl_174, type, blanchedalmond_0: $i).
% 28.74/28.87  tff(decl_175, type, bisque_0: $i).
% 28.74/28.87  tff(decl_176, type, beige_0: $i).
% 28.74/28.87  tff(decl_177, type, azure_0: $i).
% 28.74/28.87  tff(decl_178, type, aquamarine_0: $i).
% 28.74/28.87  tff(decl_179, type, antiquewhite_0: $i).
% 28.74/28.87  tff(decl_180, type, aliceblue_0: $i).
% 28.74/28.87  tff(decl_181, type, teal_0: $i).
% 28.74/28.87  tff(decl_182, type, olive_0: $i).
% 28.74/28.87  tff(decl_183, type, navy_0: $i).
% 28.74/28.87  tff(decl_184, type, maroon_0: $i).
% 28.74/28.87  tff(decl_185, type, lime_0: $i).
% 28.74/28.87  tff(decl_186, type, fuchsia_0: $i).
% 28.74/28.87  tff(decl_187, type, aqua_0: $i).
% 28.74/28.87  tff(decl_188, type, hazel_0: $i).
% 28.74/28.87  tff(decl_189, type, silver_0: $i).
% 28.74/28.87  tff(decl_190, type, redhead_0: $i).
% 28.74/28.87  tff(decl_191, type, brunette_0: $i).
% 28.74/28.87  tff(decl_192, type, blonde_0: $i).
% 28.74/28.87  tff(decl_193, type, blond_0: $i).
% 28.74/28.87  tff(decl_194, type, auburn_0: $i).
% 28.74/28.87  tff(decl_195, type, colorless_0: $i).
% 28.74/28.87  tff(decl_196, type, gray_0: $i).
% 28.74/28.87  tff(decl_197, type, white_0: $i).
% 28.74/28.87  tff(decl_198, type, black_0: $i).
% 28.74/28.87  tff(decl_199, type, brown_0: $i).
% 28.74/28.87  tff(decl_200, type, pink_0: $i).
% 28.74/28.87  tff(decl_201, type, purple_0: $i).
% 28.74/28.87  tff(decl_202, type, orange_0: $i).
% 28.74/28.87  tff(decl_203, type, green_0: $i).
% 28.74/28.87  tff(decl_204, type, yellow_0: $i).
% 28.74/28.87  tff(decl_205, type, blue_0: $i).
% 28.74/28.87  tff(decl_206, type, red_0: $i).
% 28.74/28.87  tff(decl_207, type, fleshy_0: $i).
% 28.74/28.87  tff(decl_208, type, consistency_constant_1: $i > $o).
% 28.74/28.87  tff(decl_209, type, elastic_0: $i).
% 28.74/28.87  tff(decl_210, type, soft_0: $i).
% 28.74/28.87  tff(decl_211, type, hard_0: $i).
% 28.74/28.87  tff(decl_212, type, boney_0: $i).
% 28.74/28.87  tff(decl_213, type, stony_0: $i).
% 28.74/28.87  tff(decl_214, type, rocky_0: $i).
% 28.74/28.87  tff(decl_215, type, granitic_0: $i).
% 28.74/28.87  tff(decl_216, type, crystalline_0: $i).
% 28.74/28.87  tff(decl_217, type, glassy_0: $i).
% 28.74/28.87  tff(decl_218, type, grainy_0: $i).
% 28.74/28.87  tff(decl_219, type, gritty_0: $i).
% 28.74/28.87  tff(decl_220, type, saturday_0: $i).
% 28.74/28.87  tff(decl_221, type, day_constant_1: $i > $o).
% 28.74/28.87  tff(decl_222, type, friday_0: $i).
% 28.74/28.87  tff(decl_223, type, thursday_0: $i).
% 28.74/28.87  tff(decl_224, type, wednesday_0: $i).
% 28.74/28.87  tff(decl_225, type, tuesday_0: $i).
% 28.74/28.87  tff(decl_226, type, monday_0: $i).
% 28.74/28.87  tff(decl_227, type, sunday_0: $i).
% 28.74/28.87  tff(decl_228, type, loose_0: $i).
% 28.74/28.87  tff(decl_229, type, density_constant_1: $i > $o).
% 28.74/28.87  tff(decl_230, type, rare_0: $i).
% 28.74/28.87  tff(decl_231, type, dense_0: $i).
% 28.74/28.87  tff(decl_232, type, shallow_0: $i).
% 28.74/28.87  tff(decl_233, type, depth_constant_1: $i > $o).
% 28.74/28.87  tff(decl_234, type, three_dimensional_0: $i).
% 28.74/28.87  tff(decl_235, type, dimension_constant_1: $i > $o).
% 28.74/28.87  tff(decl_236, type, two_dimensional_0: $i).
% 28.74/28.87  tff(decl_237, type, one_dimensional_0: $i).
% 28.74/28.87  tff(decl_238, type, forward_0: $i).
% 28.74/28.87  tff(decl_239, type, direction_constant_1: $i > $o).
% 28.74/28.87  tff(decl_240, type, straight_0: $i).
% 28.74/28.87  tff(decl_241, type, angle_constant_1: $i > $o).
% 28.74/28.87  tff(decl_242, type, reflex_0: $i).
% 28.74/28.87  tff(decl_243, type, obtuse_0: $i).
% 28.74/28.87  tff(decl_244, type, acute_0: $i).
% 28.74/28.87  tff(decl_245, type, outward_0: $i).
% 28.74/28.87  tff(decl_246, type, inward_0: $i).
% 28.74/28.87  tff(decl_247, type, backward_0: $i).
% 28.74/28.87  tff(decl_248, type, transversal_0: $i).
% 28.74/28.87  tff(decl_249, type, lateral_0: $i).
% 28.74/28.87  tff(decl_250, type, northnorthwest_0: $i).
% 28.74/28.87  tff(decl_251, type, northnortheast_0: $i).
% 28.74/28.87  tff(decl_252, type, northeast_0: $i).
% 28.74/28.87  tff(decl_253, type, eastnortheast_0: $i).
% 28.74/28.87  tff(decl_254, type, eastsoutheast_0: $i).
% 28.74/28.87  tff(decl_255, type, southeast_0: $i).
% 28.74/28.87  tff(decl_256, type, southsoutheast_0: $i).
% 28.74/28.87  tff(decl_257, type, southsouthwest_0: $i).
% 28.74/28.87  tff(decl_258, type, southwest_0: $i).
% 28.74/28.87  tff(decl_259, type, westsouthwest_0: $i).
% 28.74/28.87  tff(decl_260, type, westnorthwest_0: $i).
% 28.74/28.87  tff(decl_261, type, northwest_0: $i).
% 28.74/28.87  tff(decl_262, type, down_0: $i).
% 28.74/28.87  tff(decl_263, type, up_0: $i).
% 28.74/28.87  tff(decl_264, type, east_0: $i).
% 28.74/28.87  tff(decl_265, type, west_0: $i).
% 28.74/28.87  tff(decl_266, type, south_0: $i).
% 28.74/28.87  tff(decl_267, type, north_0: $i).
% 28.74/28.87  tff(decl_268, type, far_0: $i).
% 28.74/28.87  tff(decl_269, type, distance_constant_1: $i > $o).
% 28.74/28.87  tff(decl_270, type, near_0: $i).
% 28.74/28.87  tff(decl_271, type, brief_0: $i).
% 28.74/28.87  tff(decl_272, type, duration_constant_1: $i > $o).
% 28.74/28.87  tff(decl_273, type, forever_0: $i).
% 28.74/28.87  tff(decl_274, type, negative_energy_0: $i).
% 28.74/28.87  tff(decl_275, type, energy_constant_1: $i > $o).
% 28.74/28.87  tff(decl_276, type, positive_energy_0: $i).
% 28.74/28.87  tff(decl_277, type, sterile_0: $i).
% 28.74/28.87  tff(decl_278, type, fertility_constant_1: $i > $o).
% 28.74/28.87  tff(decl_279, type, fertile_0: $i).
% 28.74/28.87  tff(decl_280, type, semi_rigid_0: $i).
% 28.74/28.87  tff(decl_281, type, flexibility_constant_1: $i > $o).
% 28.74/28.87  tff(decl_282, type, rigid_0: $i).
% 28.74/28.87  tff(decl_283, type, flexible_0: $i).
% 28.74/28.87  tff(decl_284, type, never_0: $i).
% 28.74/28.87  tff(decl_285, type, frequency_constant_1: $i > $o).
% 28.74/28.87  tff(decl_286, type, rarely_0: $i).
% 28.74/28.87  tff(decl_287, type, often_0: $i).
% 28.74/28.87  tff(decl_288, type, average_0: $i).
% 28.74/28.87  tff(decl_289, type, height_constant_1: $i > $o).
% 28.74/28.87  tff(decl_290, type, important_0: $i).
% 28.74/28.87  tff(decl_291, type, importance_constant_1: $i > $o).
% 28.74/28.87  tff(decl_292, type, moderately_important_0: $i).
% 28.74/28.87  tff(decl_293, type, unimportant_0: $i).
% 28.74/28.87  tff(decl_294, type, permeable_0: $i).
% 28.74/28.87  tff(decl_295, type, integrity_constant_1: $i > $o).
% 28.74/28.87  tff(decl_296, type, semi_permeable_0: $i).
% 28.74/28.87  tff(decl_297, type, impermeable_0: $i).
% 28.74/28.87  tff(decl_298, type, negligible_0: $i).
% 28.74/28.87  tff(decl_299, type, intensity_constant_1: $i > $o).
% 28.74/28.87  tff(decl_300, type, short_0: $i).
% 28.74/28.87  tff(decl_301, type, length_constant_1: $i > $o).
% 28.74/28.87  tff(decl_302, type, politely_0: $i).
% 28.74/28.87  tff(decl_303, type, manner_constant_1: $i > $o).
% 28.74/28.87  tff(decl_304, type, happily_0: $i).
% 28.74/28.87  tff(decl_305, type, dejectedly_0: $i).
% 28.74/28.87  tff(decl_306, type, hefty_0: $i).
% 28.74/28.87  tff(decl_307, type, mass_constant_1: $i > $o).
% 28.74/28.88  tff(decl_308, type, light_0: $i).
% 28.74/28.88  tff(decl_309, type, upright_0: $i).
% 28.74/28.88  tff(decl_310, type, orientation_constant_1: $i > $o).
% 28.74/28.88  tff(decl_311, type, reduced_0: $i).
% 28.74/28.88  tff(decl_312, type, oxidation_state_constant_1: $i > $o).
% 28.74/28.88  tff(decl_313, type, oxidized_0: $i).
% 28.74/28.88  tff(decl_314, type, negative_0: $i).
% 28.74/28.88  tff(decl_315, type, polarity_constant_1: $i > $o).
% 28.74/28.88  tff(decl_316, type, positive_0: $i).
% 28.74/28.88  tff(decl_317, type, tall_0: $i).
% 28.74/28.88  tff(decl_318, type, primary_constant_1: $i > $o).
% 28.74/28.88  tff(decl_319, type, long_0: $i).
% 28.74/28.88  tff(decl_320, type, deep_0: $i).
% 28.74/28.88  tff(decl_321, type, old_0: $i).
% 28.74/28.88  tff(decl_322, type, urgent_0: $i).
% 28.74/28.88  tff(decl_323, type, priority_constant_1: $i > $o).
% 28.74/28.88  tff(decl_324, type, medium_0: $i).
% 28.74/28.88  tff(decl_325, type, highest_0: $i).
% 28.74/28.88  tff(decl_326, type, quantity_constant_1: $i > $o).
% 28.74/28.88  tff(decl_327, type, lowest_0: $i).
% 28.74/28.88  tff(decl_328, type, numerous_0: $i).
% 28.74/28.88  tff(decl_329, type, many_0: $i).
% 28.74/28.88  tff(decl_330, type, few_0: $i).
% 28.74/28.88  tff(decl_331, type, not_sentient_0: $i).
% 28.74/28.88  tff(decl_332, type, sentience_constant_1: $i > $o).
% 28.74/28.88  tff(decl_333, type, sentient_0: $i).
% 28.74/28.88  tff(decl_334, type, male_0: $i).
% 28.74/28.88  tff(decl_335, type, sex_constant_1: $i > $o).
% 28.74/28.88  tff(decl_336, type, female_0: $i).
% 28.74/28.88  tff(decl_337, type, tapered_0: $i).
% 28.74/28.88  tff(decl_338, type, shape_constant_1: $i > $o).
% 28.74/28.88  tff(decl_339, type, zig_zag_0: $i).
% 28.74/28.88  tff(decl_340, type, globular_0: $i).
% 28.74/28.88  tff(decl_341, type, flat_0: $i).
% 28.74/28.88  tff(decl_342, type, branched_0: $i).
% 28.74/28.88  tff(decl_343, type, kink_0: $i).
% 28.74/28.88  tff(decl_344, type, ring_shaped_0: $i).
% 28.74/28.88  tff(decl_345, type, irregularly_shaped_0: $i).
% 28.74/28.88  tff(decl_346, type, polyhedron_0: $i).
% 28.74/28.88  tff(decl_347, type, cylinder_0: $i).
% 28.74/28.88  tff(decl_348, type, tetrahedron_0: $i).
% 28.74/28.88  tff(decl_349, type, helix_0: $i).
% 28.74/28.88  tff(decl_350, type, bell_0: $i).
% 28.74/28.88  tff(decl_351, type, cone_0: $i).
% 28.74/28.88  tff(decl_352, type, tube_0: $i).
% 28.74/28.88  tff(decl_353, type, sphere_0: $i).
% 28.74/28.88  tff(decl_354, type, line_0: $i).
% 28.74/28.88  tff(decl_355, type, net_like_0: $i).
% 28.74/28.88  tff(decl_356, type, trash_can_like_0: $i).
% 28.74/28.88  tff(decl_357, type, wedge_like_0: $i).
% 28.74/28.88  tff(decl_358, type, spindle_like_0: $i).
% 28.74/28.88  tff(decl_359, type, rose_like_0: $i).
% 28.74/28.88  tff(decl_360, type, scale_like_0: $i).
% 28.74/28.88  tff(decl_361, type, needle_like_0: $i).
% 28.74/28.88  tff(decl_362, type, lens_like_0: $i).
% 28.74/28.88  tff(decl_363, type, kidney_like_0: $i).
% 28.74/28.88  tff(decl_364, type, heart_like_0: $i).
% 28.74/28.88  tff(decl_365, type, hatchet_like_0: $i).
% 28.74/28.88  tff(decl_366, type, dumbbell_like_0: $i).
% 28.74/28.88  tff(decl_367, type, dome_like_0: $i).
% 28.74/28.88  tff(decl_368, type, donut_like_0: $i).
% 28.74/28.88  tff(decl_369, type, disc_like_0: $i).
% 28.74/28.88  tff(decl_370, type, cup_like_0: $i).
% 28.74/28.88  tff(decl_371, type, corkscrew_like_0: $i).
% 28.74/28.88  tff(decl_372, type, club_like_0: $i).
% 28.74/28.88  tff(decl_373, type, chevron_like_0: $i).
% 28.74/28.88  tff(decl_374, type, y_like_0: $i).
% 28.74/28.88  tff(decl_375, type, x_like_0: $i).
% 28.74/28.88  tff(decl_376, type, v_like_0: $i).
% 28.74/28.88  tff(decl_377, type, u_like_0: $i).
% 28.74/28.88  tff(decl_378, type, t_like_0: $i).
% 28.74/28.88  tff(decl_379, type, s_like_0: $i).
% 28.74/28.88  tff(decl_380, type, l_like_0: $i).
% 28.74/28.88  tff(decl_381, type, j_like_0: $i).
% 28.74/28.88  tff(decl_382, type, crescent_0: $i).
% 28.74/28.88  tff(decl_383, type, hollow_volume_0: $i).
% 28.74/28.88  tff(decl_384, type, parallelogram_0: $i).
% 28.74/28.88  tff(decl_385, type, polygon_0: $i).
% 28.74/28.88  tff(decl_386, type, oval_0: $i).
% 28.74/28.88  tff(decl_387, type, rectangle_0: $i).
% 28.74/28.88  tff(decl_388, type, triangle_0: $i).
% 28.74/28.88  tff(decl_389, type, square_0: $i).
% 28.74/28.88  tff(decl_390, type, circle_0: $i).
% 28.74/28.88  tff(decl_391, type, oversized_0: $i).
% 28.74/28.88  tff(decl_392, type, size_constant_1: $i > $o).
% 28.74/28.88  tff(decl_393, type, huge_0: $i).
% 28.74/28.88  tff(decl_394, type, area_constant_1: $i > $o).
% 28.74/28.88  tff(decl_395, type, undersized_0: $i).
% 28.74/28.88  tff(decl_396, type, gigantic_0: $i).
% 28.74/28.88  tff(decl_397, type, little_0: $i).
% 28.74/28.88  tff(decl_398, type, big_0: $i).
% 28.74/28.88  tff(decl_399, type, tiny_0: $i).
% 28.74/28.88  tff(decl_400, type, microscopic_0: $i).
% 28.74/28.88  tff(decl_401, type, horizontal_0: $i).
% 28.74/28.88  tff(decl_402, type, slope_constant_1: $i > $o).
% 28.74/28.88  tff(decl_403, type, gradual_0: $i).
% 28.74/28.88  tff(decl_404, type, steep_0: $i).
% 28.74/28.88  tff(decl_405, type, vertical_0: $i).
% 28.74/28.88  tff(decl_406, type, stinky_0: $i).
% 28.74/28.88  tff(decl_407, type, smell_constant_1: $i > $o).
% 28.74/28.88  tff(decl_408, type, fresh_0: $i).
% 28.74/28.88  tff(decl_409, type, foul_0: $i).
% 28.74/28.88  tff(decl_410, type, spicy_0: $i).
% 28.74/28.88  tff(decl_411, type, musky_0: $i).
% 28.74/28.88  tff(decl_412, type, fruity_0: $i).
% 28.74/28.88  tff(decl_413, type, odorless_0: $i).
% 28.74/28.88  tff(decl_414, type, rancid_0: $i).
% 28.74/28.88  tff(decl_415, type, flowery_0: $i).
% 28.74/28.88  tff(decl_416, type, smokey_0: $i).
% 28.74/28.88  tff(decl_417, type, moderate_0: $i).
% 28.74/28.88  tff(decl_418, type, speed_constant_1: $i > $o).
% 28.74/28.88  tff(decl_419, type, solid_0: $i).
% 28.74/28.88  tff(decl_420, type, state_constant_1: $i > $o).
% 28.74/28.88  tff(decl_421, type, liquid_0: $i).
% 28.74/28.88  tff(decl_422, type, aqueous_0: $i).
% 28.74/28.88  tff(decl_423, type, gas_0: $i).
% 28.74/28.88  tff(decl_424, type, juicy_0: $i).
% 28.74/28.88  tff(decl_425, type, taste_constant_1: $i > $o).
% 28.74/28.88  tff(decl_426, type, watery_0: $i).
% 28.74/28.88  tff(decl_427, type, tasteless_0: $i).
% 28.74/28.88  tff(decl_428, type, bitter_0: $i).
% 28.74/28.88  tff(decl_429, type, sweet_0: $i).
% 28.74/28.88  tff(decl_430, type, sour_0: $i).
% 28.74/28.88  tff(decl_431, type, creamy_0: $i).
% 28.74/28.88  tff(decl_432, type, buttery_0: $i).
% 28.74/28.88  tff(decl_433, type, freezing_0: $i).
% 28.74/28.88  tff(decl_434, type, temperature_categorical_constant_1: $i > $o).
% 28.74/28.88  tff(decl_435, type, boiling_0: $i).
% 28.74/28.88  tff(decl_436, type, abnormal_0: $i).
% 28.74/28.88  tff(decl_437, type, temperature_constant_1: $i > $o).
% 28.74/28.88  tff(decl_438, type, normal_0: $i).
% 28.74/28.88  tff(decl_439, type, hot_0: $i).
% 28.74/28.88  tff(decl_440, type, warm_0: $i).
% 28.74/28.88  tff(decl_441, type, mild_0: $i).
% 28.74/28.88  tff(decl_442, type, cool_0: $i).
% 28.74/28.88  tff(decl_443, type, cold_0: $i).
% 28.74/28.88  tff(decl_444, type, rough_0: $i).
% 28.74/28.88  tff(decl_445, type, texture_constant_1: $i > $o).
% 28.74/28.88  tff(decl_446, type, smooth_0: $i).
% 28.74/28.88  tff(decl_447, type, thick_0: $i).
% 28.74/28.88  tff(decl_448, type, thickness_constant_1: $i > $o).
% 28.74/28.88  tff(decl_449, type, thin_0: $i).
% 28.74/28.88  tff(decl_450, type, nzdt_0: $i).
% 28.74/28.88  tff(decl_451, type, time_zone_constant_1: $i > $o).
% 28.74/28.88  tff(decl_452, type, nzst_0: $i).
% 28.74/28.88  tff(decl_453, type, idle_0: $i).
% 28.74/28.88  tff(decl_454, type, aedt_0: $i).
% 28.74/28.88  tff(decl_455, type, aest_0: $i).
% 28.74/28.88  tff(decl_456, type, acdt_0: $i).
% 28.74/28.88  tff(decl_457, type, acst_0: $i).
% 28.74/28.88  tff(decl_458, type, kdt_0: $i).
% 28.74/28.88  tff(decl_459, type, kst_0: $i).
% 28.74/28.88  tff(decl_460, type, jst_0: $i).
% 28.74/28.88  tff(decl_461, type, awst_0: $i).
% 28.74/28.88  tff(decl_462, type, cxt_0: $i).
% 28.74/28.88  tff(decl_463, type, kgst_0: $i).
% 28.74/28.88  tff(decl_464, type, kgt_0: $i).
% 28.74/28.88  tff(decl_465, type, gest_0: $i).
% 28.74/28.88  tff(decl_466, type, get_0: $i).
% 28.74/28.88  tff(decl_467, type, msd_0: $i).
% 28.74/28.88  tff(decl_468, type, msk_0: $i).
% 28.74/28.88  tff(decl_469, type, eest_0: $i).
% 28.74/28.88  tff(decl_470, type, eet_0: $i).
% 28.74/28.88  tff(decl_471, type, cest_0: $i).
% 28.74/28.88  tff(decl_472, type, cet_0: $i).
% 28.74/28.88  tff(decl_473, type, ist_0: $i).
% 28.74/28.88  tff(decl_474, type, wet_0: $i).
% 28.74/28.88  tff(decl_475, type, gmt_0: $i).
% 28.74/28.88  tff(decl_476, type, utc_0: $i).
% 28.74/28.88  tff(decl_477, type, ndt_0: $i).
% 28.74/28.88  tff(decl_478, type, nst_0: $i).
% 28.74/28.88  tff(decl_479, type, adt_0: $i).
% 28.74/28.88  tff(decl_480, type, ast_0: $i).
% 28.74/28.88  tff(decl_481, type, edt_0: $i).
% 28.74/28.88  tff(decl_482, type, est_0: $i).
% 28.74/28.88  tff(decl_483, type, cdt_0: $i).
% 28.74/28.88  tff(decl_484, type, cst_0: $i).
% 28.74/28.88  tff(decl_485, type, mdt_0: $i).
% 28.74/28.88  tff(decl_486, type, mst_0: $i).
% 28.74/28.88  tff(decl_487, type, pdt_0: $i).
% 28.74/28.88  tff(decl_488, type, pst_0: $i).
% 28.74/28.88  tff(decl_489, type, akdt_0: $i).
% 28.74/28.88  tff(decl_490, type, akst_0: $i).
% 28.74/28.88  tff(decl_491, type, hst_0: $i).
% 28.74/28.88  tff(decl_492, type, idlw_0: $i).
% 28.74/28.88  tff(decl_493, type, vulnerable_0: $i).
% 28.74/28.88  tff(decl_494, type, trait_constant_1: $i > $o).
% 28.74/28.88  tff(decl_495, type, tireless_0: $i).
% 28.74/28.88  tff(decl_496, type, lazy_0: $i).
% 28.74/28.88  tff(decl_497, type, honest_0: $i).
% 28.74/28.88  tff(decl_498, type, dishonest_0: $i).
% 28.74/28.88  tff(decl_499, type, aggressive_0: $i).
% 28.74/28.88  tff(decl_500, type, submissive_0: $i).
% 28.74/28.88  tff(decl_501, type, false_0: $i).
% 28.74/28.88  tff(decl_502, type, truth_constant_1: $i > $o).
% 28.74/28.88  tff(decl_503, type, true_0: $i).
% 28.74/28.88  tff(decl_504, type, very_slow_0: $i).
% 28.74/28.88  tff(decl_505, type, velocity_constant_1: $i > $o).
% 28.74/28.88  tff(decl_506, type, slow_0: $i).
% 28.74/28.88  tff(decl_507, type, rate_constant_1: $i > $o).
% 28.74/28.88  tff(decl_508, type, fast_0: $i).
% 28.74/28.88  tff(decl_509, type, constant_0: $i).
% 28.74/28.88  tff(decl_510, type, high_contrast_0: $i).
% 28.74/28.88  tff(decl_511, type, visibility_constant_1: $i > $o).
% 28.74/28.88  tff(decl_512, type, low_contrast_0: $i).
% 28.74/28.88  tff(decl_513, type, clear_0: $i).
% 28.74/28.88  tff(decl_514, type, unclear_0: $i).
% 28.74/28.88  tff(decl_515, type, invisible_0: $i).
% 28.74/28.88  tff(decl_516, type, visible_0: $i).
% 28.74/28.88  tff(decl_517, type, large_0: $i).
% 28.74/28.88  tff(decl_518, type, volume_constant_1: $i > $o).
% 28.74/28.88  tff(decl_519, type, surface_area_categorical_constant_1: $i > $o).
% 28.74/28.88  tff(decl_520, type, small_0: $i).
% 28.74/28.88  tff(decl_521, type, arid_0: $i).
% 28.74/28.88  tff(decl_522, type, wetness_constant_1: $i > $o).
% 28.74/28.88  tff(decl_523, type, dry_0: $i).
% 28.74/28.88  tff(decl_524, type, moist_0: $i).
% 28.74/28.88  tff(decl_525, type, damp_0: $i).
% 28.74/28.88  tff(decl_526, type, wide_0: $i).
% 28.74/28.88  tff(decl_527, type, width_constant_1: $i > $o).
% 28.74/28.88  tff(decl_528, type, narrow_0: $i).
% 28.74/28.88  tff(decl_529, type, expensive_0: $i).
% 28.74/28.88  tff(decl_530, type, worth_constant_1: $i > $o).
% 28.74/28.88  tff(decl_531, type, inexpensive_0: $i).
% 28.74/28.88  tff(decl_532, type, cheap_0: $i).
% 28.74/28.88  tff(decl_533, type, neutral_0: $i).
% 28.74/28.88  tff(decl_534, type, ph_constant_1: $i > $o).
% 28.74/28.88  tff(decl_535, type, acidic_0: $i).
% 28.74/28.88  tff(decl_536, type, basic_0: $i).
% 28.74/28.88  tff(decl_537, type, very_complex_0: $i).
% 28.74/28.88  tff(decl_538, type, structural_complexity_constant_1: $i > $o).
% 28.74/28.88  tff(decl_539, type, complex_0: $i).
% 28.74/28.88  tff(decl_540, type, simple_0: $i).
% 28.74/28.88  tff(decl_541, type, partial_negative_0: $i).
% 28.74/28.88  tff(decl_542, type, charge_categorical_constant_1: $i > $o).
% 28.74/28.88  tff(decl_543, type, partial_positive_0: $i).
% 28.74/28.88  tff(decl_544, type, nonpolar_0: $i).
% 28.74/28.88  tff(decl_545, type, chemical_polarity_constant_1: $i > $o).
% 28.74/28.88  tff(decl_546, type, polar_0: $i).
% 28.74/28.88  tff(decl_547, type, unstable_0: $i).
% 28.74/28.88  tff(decl_548, type, chemical_stability_constant_1: $i > $o).
% 28.74/28.88  tff(decl_549, type, stable_0: $i).
% 28.74/28.88  tff(decl_550, type, low_0: $i).
% 28.74/28.88  tff(decl_551, type, pressure_constant_1: $i > $o).
% 28.74/28.88  tff(decl_552, type, specific_surface_area_constant_1: $i > $o).
% 28.74/28.88  tff(decl_553, type, heat_of_vaporization_constant_1: $i > $o).
% 28.74/28.88  tff(decl_554, type, surface_tension_constant_1: $i > $o).
% 28.74/28.88  tff(decl_555, type, specific_heat_constant_1: $i > $o).
% 28.74/28.88  tff(decl_556, type, humidity_constant_1: $i > $o).
% 28.74/28.88  tff(decl_557, type, fluidity_constant_1: $i > $o).
% 28.74/28.88  tff(decl_558, type, visibility_scalar_constant_1: $i > $o).
% 28.74/28.88  tff(decl_559, type, fertility_scalar_constant_1: $i > $o).
% 28.74/28.88  tff(decl_560, type, transmittance_scalar_constant_1: $i > $o).
% 28.74/28.88  tff(decl_561, type, absorbance_scalar_constant_1: $i > $o).
% 28.74/28.88  tff(decl_562, type, electronegativity_constant_1: $i > $o).
% 28.74/28.88  tff(decl_563, type, surface_area_scalar_constant_1: $i > $o).
% 28.74/28.88  tff(decl_564, type, concentration_constant_1: $i > $o).
% 28.74/28.88  tff(decl_565, type, high_0: $i).
% 28.74/28.88  tff(decl_566, type, concentrated_0: $i).
% 28.74/28.88  tff(decl_567, type, dilute_0: $i).
% 28.74/28.88  tff(decl_568, type, high_conductivity_0: $i).
% 28.74/28.88  tff(decl_569, type, conductivity_constant_1: $i > $o).
% 28.74/28.88  tff(decl_570, type, low_conductivity_0: $i).
% 28.74/28.88  tff(decl_571, type, no_conductivity_0: $i).
% 28.74/28.88  tff(decl_572, type, non_0: $i).
% 28.74/28.88  tff(decl_573, type, electrolyte_status_constant_1: $i > $o).
% 28.74/28.88  tff(decl_574, type, weak_0: $i).
% 28.74/28.88  tff(decl_575, type, strong_0: $i).
% 28.74/28.88  tff(decl_576, type, right_0: $i).
% 28.74/28.88  tff(decl_577, type, reaction_direction_constant_1: $i > $o).
% 28.74/28.88  tff(decl_578, type, left_0: $i).
% 28.74/28.88  tff(decl_579, type, salt_0: $i).
% 28.74/28.88  tff(decl_580, type, salt_status_constant_1: $i > $o).
% 28.74/28.88  tff(decl_581, type, insoluble_0: $i).
% 28.74/28.88  tff(decl_582, type, solubility_constant_1: $i > $o).
% 28.74/28.88  tff(decl_583, type, soluble_0: $i).
% 28.74/28.88  tff(decl_584, type, g_0: $i).
% 28.74/28.88  tff(decl_585, type, uom_acceleration_magnitude_1: $i > $o).
% 28.74/28.88  tff(decl_586, type, kilometer_per_hour_minute_0: $i).
% 28.74/28.88  tff(decl_587, type, mile_per_second_squared_0: $i).
% 28.74/28.88  tff(decl_588, type, kilometer_per_second_squared_0: $i).
% 28.74/28.88  tff(decl_589, type, meter_per_second_squared_0: $i).
% 28.74/28.88  tff(decl_590, type, foot_per_second_squared_0: $i).
% 28.74/28.88  tff(decl_591, type, centimeter_per_second_squared_0: $i).
% 28.74/28.88  tff(decl_592, type, grad_0: $i).
% 28.74/28.88  tff(decl_593, type, uom_angle_1: $i > $o).
% 28.74/28.88  tff(decl_594, type, radian_0: $i).
% 28.74/28.88  tff(decl_595, type, square_foot_0: $i).
% 28.74/28.88  tff(decl_596, type, uom_area_1: $i > $o).
% 28.74/28.88  tff(decl_597, type, arcsecond_0: $i).
% 28.74/28.88  tff(decl_598, type, uom_coordinate_1: $i > $o).
% 28.74/28.88  tff(decl_599, type, arcminute_0: $i).
% 28.74/28.88  tff(decl_600, type, degree_0: $i).
% 28.74/28.88  tff(decl_601, type, gram_liter_0: $i).
% 28.74/28.88  tff(decl_602, type, uom_density_1: $i > $o).
% 28.74/28.88  tff(decl_603, type, microsecond_0: $i).
% 28.74/28.88  tff(decl_604, type, uom_duration_1: $i > $o).
% 28.74/28.88  tff(decl_605, type, nanosecond_0: $i).
% 28.74/28.88  tff(decl_606, type, millisecond_0: $i).
% 28.74/28.88  tff(decl_607, type, week_0: $i).
% 28.74/28.88  tff(decl_608, type, kilo_cal_per_mole_0: $i).
% 28.74/28.88  tff(decl_609, type, uom_energy_1: $i > $o).
% 28.74/28.88  tff(decl_610, type, yearly_0: $i).
% 28.74/28.88  tff(decl_611, type, uom_frequency_1: $i > $o).
% 28.74/28.88  tff(decl_612, type, monthly_0: $i).
% 28.74/28.88  tff(decl_613, type, weekly_0: $i).
% 28.74/28.88  tff(decl_614, type, daily_0: $i).
% 28.74/28.88  tff(decl_615, type, hourly_0: $i).
% 28.74/28.88  tff(decl_616, type, per_year_0: $i).
% 28.74/28.88  tff(decl_617, type, per_month_0: $i).
% 28.74/28.88  tff(decl_618, type, per_week_0: $i).
% 28.74/28.88  tff(decl_619, type, per_day_0: $i).
% 28.74/28.88  tff(decl_620, type, gigahertz_0: $i).
% 28.74/28.88  tff(decl_621, type, megahertz_0: $i).
% 28.74/28.88  tff(decl_622, type, kilohertz_0: $i).
% 28.74/28.88  tff(decl_623, type, hertz_0: $i).
% 28.74/28.88  tff(decl_624, type, per_second_0: $i).
% 28.74/28.88  tff(decl_625, type, per_minute_0: $i).
% 28.74/28.88  tff(decl_626, type, per_hour_0: $i).
% 28.74/28.88  tff(decl_627, type, joule_per_gram_0: $i).
% 28.74/28.88  tff(decl_628, type, uom_heat_of_vaporization_1: $i > $o).
% 28.74/28.88  tff(decl_629, type, calorie_per_gram_0: $i).
% 28.74/28.88  tff(decl_630, type, nanometer_0: $i).
% 28.74/28.88  tff(decl_631, type, uom_length_1: $i > $o).
% 28.74/28.88  tff(decl_632, type, micrometer_0: $i).
% 28.74/28.88  tff(decl_633, type, millimeter_0: $i).
% 28.74/28.88  tff(decl_634, type, centimeter_0: $i).
% 28.74/28.88  tff(decl_635, type, meter_0: $i).
% 28.74/28.88  tff(decl_636, type, yard_0: $i).
% 28.74/28.88  tff(decl_637, type, mile_0: $i).
% 28.74/28.88  tff(decl_638, type, foot_0: $i).
% 28.74/28.88  tff(decl_639, type, inch_0: $i).
% 28.74/28.88  tff(decl_640, type, kilometer_0: $i).
% 28.74/28.88  tff(decl_641, type, candela_per_centimeter_squared_0: $i).
% 28.74/28.88  tff(decl_642, type, uom_luminance_1: $i > $o).
% 28.74/28.88  tff(decl_643, type, candela_per_foot_squared_0: $i).
% 28.74/28.88  tff(decl_644, type, candela_per_meter_squared_0: $i).
% 28.74/28.88  tff(decl_645, type, stilb_0: $i).
% 28.74/28.88  tff(decl_646, type, millilambert_0: $i).
% 28.74/28.88  tff(decl_647, type, footlambert_0: $i).
% 28.74/28.88  tff(decl_648, type, lambert_0: $i).
% 28.74/28.88  tff(decl_649, type, nit_0: $i).
% 28.74/28.88  tff(decl_650, type, lumen_0: $i).
% 28.74/28.88  tff(decl_651, type, uom_luminous_flux_1: $i > $o).
% 28.74/28.88  tff(decl_652, type, candela_0: $i).
% 28.74/28.88  tff(decl_653, type, uom_luminous_intensity_1: $i > $o).
% 28.74/28.88  tff(decl_654, type, uom_brightness_1: $i > $o).
% 28.74/28.88  tff(decl_655, type, slug_0: $i).
% 28.74/28.88  tff(decl_656, type, uom_mass_1: $i > $o).
% 28.74/28.88  tff(decl_657, type, dalton_0: $i).
% 28.74/28.88  tff(decl_658, type, kilogram_0: $i).
% 28.74/28.88  tff(decl_659, type, gram_0: $i).
% 28.74/28.88  tff(decl_660, type, kilogram_meter_squared_0: $i).
% 28.74/28.88  tff(decl_661, type, uom_moment_of_inertia_1: $i > $o).
% 28.74/28.88  tff(decl_662, type, kilogram_meter_per_second_0: $i).
% 28.74/28.88  tff(decl_663, type, uom_momentum_1: $i > $o).
% 28.74/28.88  tff(decl_664, type, horsepower_0: $i).
% 28.74/28.88  tff(decl_665, type, uom_power_1: $i > $o).
% 28.74/28.88  tff(decl_666, type, megawatt_0: $i).
% 28.74/28.88  tff(decl_667, type, kilowatt_0: $i).
% 28.74/28.88  tff(decl_668, type, milliwatt_0: $i).
% 28.74/28.88  tff(decl_669, type, watt_0: $i).
% 28.74/28.88  tff(decl_670, type, millibar_0: $i).
% 28.74/28.88  tff(decl_671, type, uom_pressure_1: $i > $o).
% 28.74/28.88  tff(decl_672, type, bar_0: $i).
% 28.74/28.88  tff(decl_673, type, pounds_per_square_inch_0: $i).
% 28.74/28.88  tff(decl_674, type, pascal_0: $i).
% 28.74/28.88  tff(decl_675, type, uom_potential_quantity_1: $i > $o).
% 28.74/28.88  tff(decl_676, type, kilopascal_0: $i).
% 28.74/28.88  tff(decl_677, type, megapascal_0: $i).
% 28.74/28.88  tff(decl_678, type, joule_0: $i).
% 28.74/28.88  tff(decl_679, type, uom_quantity_1: $i > $o).
% 28.74/28.88  tff(decl_680, type, kilocalorie_0: $i).
% 28.74/28.88  tff(decl_681, type, calorie_0: $i).
% 28.74/28.88  tff(decl_682, type, gross_0: $i).
% 28.74/28.88  tff(decl_683, type, score_0: $i).
% 28.74/28.88  tff(decl_684, type, dozen_0: $i).
% 28.74/28.88  tff(decl_685, type, pair_0: $i).
% 28.74/28.88  tff(decl_686, type, mole_0: $i).
% 28.74/28.88  tff(decl_687, type, nucleotide_per_second_0: $i).
% 28.74/28.88  tff(decl_688, type, uom_rate_1: $i > $o).
% 28.74/28.88  tff(decl_689, type, beat_per_minute_0: $i).
% 28.74/28.88  tff(decl_690, type, revolution_per_minute_0: $i).
% 28.74/28.88  tff(decl_691, type, uom_rotational_rate_1: $i > $o).
% 28.74/28.88  tff(decl_692, type, calorie_per_gram_per_degree_celsius_0: $i).
% 28.74/28.88  tff(decl_693, type, uom_specific_heat_1: $i > $o).
% 28.74/28.88  tff(decl_694, type, square_inch_per_gallon_0: $i).
% 28.74/28.88  tff(decl_695, type, uom_specific_surface_area_1: $i > $o).
% 28.74/28.88  tff(decl_696, type, square_foot_per_gallon_0: $i).
% 28.74/28.88  tff(decl_697, type, square_meter_per_gallon_0: $i).
% 28.74/28.88  tff(decl_698, type, square_foot_per_milliliter_0: $i).
% 28.74/28.88  tff(decl_699, type, square_inch_per_milliliter_0: $i).
% 28.74/28.88  tff(decl_700, type, square_meter_per_milliliter_0: $i).
% 28.74/28.88  tff(decl_701, type, square_inch_per_liter_0: $i).
% 28.74/28.88  tff(decl_702, type, square_foot_per_liter_0: $i).
% 28.74/28.88  tff(decl_703, type, square_meter_per_liter_0: $i).
% 28.74/28.88  tff(decl_704, type, square_inch_per_cubic_meter_0: $i).
% 28.74/28.88  tff(decl_705, type, square_foot_per_cubic_meter_0: $i).
% 28.74/28.88  tff(decl_706, type, square_meter_per_cubic_meter_0: $i).
% 28.74/28.88  tff(decl_707, type, square_inch_per_slug_0: $i).
% 28.74/28.88  tff(decl_708, type, square_inch_per_dalton_0: $i).
% 28.74/28.88  tff(decl_709, type, square_inch_per_kilogram_0: $i).
% 28.74/28.88  tff(decl_710, type, square_inch_per_gram_0: $i).
% 28.74/28.88  tff(decl_711, type, square_foot_per_slug_0: $i).
% 28.74/28.88  tff(decl_712, type, square_foot_per_dalton_0: $i).
% 28.74/28.88  tff(decl_713, type, square_foot_per_kilogram_0: $i).
% 28.74/28.88  tff(decl_714, type, square_foot_per_gram_0: $i).
% 28.74/28.88  tff(decl_715, type, square_meter_per_slug_0: $i).
% 28.74/28.88  tff(decl_716, type, square_meter_per_dalton_0: $i).
% 28.74/28.88  tff(decl_717, type, square_meter_per_kilogram_0: $i).
% 28.74/28.88  tff(decl_718, type, square_meter_per_gram_0: $i).
% 28.74/28.88  tff(decl_719, type, mile_per_hour_0: $i).
% 28.74/28.88  tff(decl_720, type, uom_speed_1: $i > $o).
% 28.74/28.88  tff(decl_721, type, kilometer_per_second_0: $i).
% 28.74/28.88  tff(decl_722, type, kilometer_per_hour_0: $i).
% 28.74/28.88  tff(decl_723, type, mile_per_second_0: $i).
% 28.74/28.88  tff(decl_724, type, meter_per_second_0: $i).
% 28.74/28.88  tff(decl_725, type, foot_per_second_0: $i).
% 28.74/28.88  tff(decl_726, type, centimeter_per_second_0: $i).
% 28.74/28.88  tff(decl_727, type, square_inch_0: $i).
% 28.74/28.88  tff(decl_728, type, uom_surface_area_1: $i > $o).
% 28.74/28.88  tff(decl_729, type, square_millimeter_0: $i).
% 28.74/28.88  tff(decl_730, type, square_micrometer_0: $i).
% 28.74/28.88  tff(decl_731, type, square_centimeter_0: $i).
% 28.74/28.88  tff(decl_732, type, square_meter_0: $i).
% 28.74/28.88  tff(decl_733, type, kelvin_0: $i).
% 28.74/28.88  tff(decl_734, type, uom_temperature_1: $i > $o).
% 28.74/28.88  tff(decl_735, type, celsius_0: $i).
% 28.74/28.88  tff(decl_736, type, fahrenheit_0: $i).
% 28.74/28.88  tff(decl_737, type, year_0: $i).
% 28.74/28.88  tff(decl_738, type, uom_time_1: $i > $o).
% 28.74/28.88  tff(decl_739, type, month_0: $i).
% 28.74/28.88  tff(decl_740, type, day_0: $i).
% 28.74/28.88  tff(decl_741, type, second_0: $i).
% 28.74/28.88  tff(decl_742, type, minute_0: $i).
% 28.74/28.88  tff(decl_743, type, hour_0: $i).
% 28.74/28.88  tff(decl_744, type, unity_0: $i).
% 28.74/28.89  tff(decl_745, type, uom_unitless_1: $i > $o).
% 28.74/28.89  tff(decl_746, type, volt_0: $i).
% 28.74/28.89  tff(decl_747, type, uom_voltage_1: $i > $o).
% 28.74/28.89  tff(decl_748, type, cubic_meter_0: $i).
% 28.74/28.89  tff(decl_749, type, uom_volume_1: $i > $o).
% 28.74/28.89  tff(decl_750, type, gallon_0: $i).
% 28.74/28.89  tff(decl_751, type, liter_0: $i).
% 28.74/28.89  tff(decl_752, type, milliliter_0: $i).
% 28.74/28.89  tff(decl_753, type, yen_0: $i).
% 28.74/28.89  tff(decl_754, type, uom_worth_1: $i > $o).
% 28.74/28.89  tff(decl_755, type, euro_0: $i).
% 28.74/28.89  tff(decl_756, type, britishpound_0: $i).
% 28.74/28.89  tff(decl_757, type, canadiandollar_0: $i).
% 28.74/28.89  tff(decl_758, type, usdollar_0: $i).
% 28.74/28.89  tff(decl_759, type, ringgit_0: $i).
% 28.74/28.89  tff(decl_760, type, sgdollar_0: $i).
% 28.74/28.89  tff(decl_761, type, rmb_0: $i).
% 28.74/28.89  tff(decl_762, type, ntdollar_0: $i).
% 28.74/28.89  tff(decl_763, type, rol_0: $i).
% 28.74/28.89  tff(decl_764, type, osmolarity_per_liter_0: $i).
% 28.74/28.89  tff(decl_765, type, uom_concentration_1: $i > $o).
% 28.74/28.89  tff(decl_766, type, milligrams_per_milliliter_0: $i).
% 28.74/28.89  tff(decl_767, type, parts_per_million_0: $i).
% 28.74/28.89  tff(decl_768, type, percentage_0: $i).
% 28.74/28.89  tff(decl_769, type, molar_0: $i).
% 28.74/28.89  tff(decl_770, type, mili_siemens_per_centimeter_0: $i).
% 28.74/28.89  tff(decl_771, type, uom_conductivity_1: $i > $o).
% 28.74/28.89  tff(decl_772, type, has_reduced_form_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_773, type, chemical_entity_1: $i > $o).
% 28.74/28.89  tff(decl_774, type, 'N-to-N': $i).
% 28.74/28.89  tff(decl_775, type, cardinality: ($i * $i) > $o).
% 28.74/28.89  tff(decl_776, type, is_hypotonic_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_777, type, solution_1: $i > $o).
% 28.74/28.89  tff(decl_778, type, not_equal_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_779, type, thing_1: $i > $o).
% 28.74/28.89  tff(decl_780, type, value_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_781, type, property_group_1: $i > $o).
% 28.74/28.89  tff(decl_782, type, value_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_783, type, used_in_equation_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_784, type, equation_set_1: $i > $o).
% 28.74/28.89  tff(decl_785, type, equation_uses_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_786, type, equation_expression_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_787, type, '1-to-1': $i).
% 28.74/28.89  tff(decl_788, type, equation_symbol_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_789, type, equation_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_790, type, system_1: $i > $o).
% 28.74/28.89  tff(decl_791, type, component_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_792, type, 'N-to-1': $i).
% 28.74/28.89  tff(decl_793, type, facilitates_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_794, type, entity_1: $i > $o).
% 28.74/28.89  tff(decl_795, type, event_1: $i > $o).
% 28.74/28.89  tff(decl_796, type, facilitates_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_797, type, is_isomer_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_798, type, has_isomer_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_799, type, '1-to-N': $i).
% 28.74/28.89  tff(decl_800, type, has_oxidized_form_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_801, type, has_state_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_802, type, spatial_entity_1: $i > $o).
% 28.74/28.89  tff(decl_803, type, is_hypertonic_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_804, type, is_impermeable_to_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_805, type, tangible_entity_1: $i > $o).
% 28.74/28.89  tff(decl_806, type, is_impermeable_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_807, type, is_tonic_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_808, type, is_isotonic_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_809, type, is_permeable_to_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_810, type, is_permeable_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_811, type, is_saturated_with_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_812, type, is_saturated_with_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_813, type, is_specific_to_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_814, type, is_specific_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_815, type, is_unsaturated_with_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_816, type, is_unsaturated_with_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_817, type, plays_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_818, type, role_1: $i > $o).
% 28.74/28.89  tff(decl_819, type, is_ion_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_820, type, ion_1: $i > $o).
% 28.74/28.89  tff(decl_821, type, has_ion_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_822, type, is_habitat_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_823, type, organism_1: $i > $o).
% 28.74/28.89  tff(decl_824, type, has_habitat_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_825, type, is_state_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_826, type, is_isotope_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_827, type, atom_1: $i > $o).
% 28.74/28.89  tff(decl_828, type, has_isotope_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_829, type, is_identical_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_830, type, chemical_1: $i > $o).
% 28.74/28.89  tff(decl_831, type, during_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_832, type, time_at_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_833, type, time_instant_1: $i > $o).
% 28.74/28.89  tff(decl_834, type, time_before_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_835, type, temporal_entity_1: $i > $o).
% 28.74/28.89  tff(decl_836, type, time_is_beginning_or_inside_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_837, type, time_interval_1: $i > $o).
% 28.74/28.89  tff(decl_838, type, time_begins_or_in_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_839, type, time_beginning_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_840, type, time_begins_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_841, type, time_between_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_842, type, time_contains_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_843, type, situation_1: $i > $o).
% 28.74/28.89  tff(decl_844, type, time_during_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_845, type, time_end_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_846, type, time_ends_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_847, type, time_is_inside_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_848, type, time_inside_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_849, type, time_int_after_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_850, type, time_int_before_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_851, type, time_int_during_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_852, type, time_int_equals_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_853, type, time_int_finishes_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_854, type, time_int_met_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_855, type, time_int_meets_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_856, type, time_int_overlaps_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_857, type, time_int_starts_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_858, type, time_of_existence_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_859, type, time_of_existence_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_860, type, abuts_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_861, type, away_from_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_862, type, destination_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_863, type, is_above_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_864, type, is_across_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_865, type, is_across_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_866, type, is_along_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_867, type, is_at_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_868, type, is_behind_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_869, type, is_beside_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_870, type, is_between_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_871, type, is_between_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_872, type, is_faced_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_873, type, is_facing_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_874, type, is_inside_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_875, type, is_near_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_876, type, is_on_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_877, type, is_opposite_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_878, type, is_oriented_toward_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_879, type, is_oriented_toward_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_880, type, is_outside_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_881, type, is_over_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_882, type, is_parallel_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_883, type, is_perpendicular_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_884, type, origin_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_885, type, path_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_886, type, site_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_887, type, toward_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_888, type, agent_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_889, type, base_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_890, type, dissolve_1: $i > $o).
% 28.74/28.89  tff(decl_891, type, beneficiary_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_892, type, living_entity_1: $i > $o).
% 28.74/28.89  tff(decl_893, type, donor_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_894, type, experiencer_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_895, type, is_function_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_896, type, has_function_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_897, type, in_event_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_898, type, instrument_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_899, type, object_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_900, type, raw_material_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_901, type, recipient_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_902, type, result_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_903, type, complement_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_904, type, element_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_905, type, first_element_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_906, type, aggregate_1: $i > $o).
% 28.74/28.89  tff(decl_907, type, sequence_1: $i > $o).
% 28.74/28.89  tff(decl_908, type, first_subevent_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_909, type, first_subevent_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_910, type, has_part_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_911, type, has_region_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_912, type, region_1: $i > $o).
% 28.74/28.89  tff(decl_913, type, in_organization_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_914, type, organization_1: $i > $o).
% 28.74/28.89  tff(decl_915, type, in_organization_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_916, type, information_content_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_917, type, conceptual_entity_1: $i > $o).
% 28.74/28.89  tff(decl_918, type, material_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_919, type, previous_element_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_920, type, next_element_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_921, type, next_event_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_922, type, possesses_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_923, type, chemical_bond_1: $i > $o).
% 28.74/28.89  tff(decl_924, type, energy_1: $i > $o).
% 28.74/28.89  tff(decl_925, type, force_1: $i > $o).
% 28.74/28.89  tff(decl_926, type, gradient_1: $i > $o).
% 28.74/28.89  tff(decl_927, type, subevent_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_928, type, substrate_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_929, type, substrate_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_930, type, is_atom_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_931, type, has_atom_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_932, type, has_solute_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_933, type, substance_1: $i > $o).
% 28.74/28.89  tff(decl_934, type, is_solvent_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_935, type, has_solvent_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_936, type, solute_species_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_937, type, solute_species_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_938, type, by_means_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_939, type, causes_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_940, type, enables_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_941, type, is_goal_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_942, type, has_goal_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_943, type, inhibits_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_944, type, objective_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_945, type, objective_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_946, type, prevents_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_947, type, purpose_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_948, type, purpose_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_949, type, supported_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_950, type, supports_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_951, type, absorbance_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_952, type, absorbance_value_1: $i > $o).
% 28.74/28.89  tff(decl_953, type, absorbance_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_954, type, acceptance_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_955, type, information_1: $i > $o).
% 28.74/28.89  tff(decl_956, type, acceptance_value_1: $i > $o).
% 28.74/28.89  tff(decl_957, type, acceptance_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_958, type, activation_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_959, type, activation_value_1: $i > $o).
% 28.74/28.89  tff(decl_960, type, activation_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_961, type, flexibility_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_962, type, flexibility_value_1: $i > $o).
% 28.74/28.89  tff(decl_963, type, flexibility_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_964, type, fluidity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_965, type, fluidity_value_1: $i > $o).
% 28.74/28.89  tff(decl_966, type, fluidity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_967, type, free_energy_change_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_968, type, free_energy_change_value_1: $i > $o).
% 28.74/28.89  tff(decl_969, type, free_energy_change_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_970, type, heat_of_vaporization_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_971, type, liquid_substance_1: $i > $o).
% 28.74/28.89  tff(decl_972, type, heat_of_vaporization_value_1: $i > $o).
% 28.74/28.89  tff(decl_973, type, heat_of_vaporization_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_974, type, humidity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_975, type, air_1: $i > $o).
% 28.74/28.89  tff(decl_976, type, humidity_value_1: $i > $o).
% 28.74/28.89  tff(decl_977, type, humidity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_978, type, pressure_potential_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_979, type, potential_value_1: $i > $o).
% 28.74/28.89  tff(decl_980, type, pressure_potential_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_981, type, solute_potential_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_982, type, solute_potential_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_983, type, specific_heat_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_984, type, specific_heat_value_1: $i > $o).
% 28.74/28.89  tff(decl_985, type, specific_heat_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_986, type, surface_tension_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_987, type, surface_tension_value_1: $i > $o).
% 28.74/28.89  tff(decl_988, type, surface_tension_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_989, type, transmittance_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_990, type, transmittance_value_1: $i > $o).
% 28.74/28.89  tff(decl_991, type, transmittance_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_992, type, valence_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_993, type, valence_value_1: $i > $o).
% 28.74/28.89  tff(decl_994, type, valence_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_995, type, visibility_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_996, type, visibility_value_1: $i > $o).
% 28.74/28.89  tff(decl_997, type, visibility_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_998, type, water_potential_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_999, type, aqueous_solution_1: $i > $o).
% 28.74/28.89  tff(decl_1000, type, water_potential_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1001, type, atomic_weight_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1002, type, atomic_weight_value_1: $i > $o).
% 28.74/28.89  tff(decl_1003, type, atomic_weight_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1004, type, charge_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1005, type, charge_value_1: $i > $o).
% 28.74/28.89  tff(decl_1006, type, charge_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1007, type, electronegativity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1008, type, electronegativity_value_1: $i > $o).
% 28.74/28.89  tff(decl_1009, type, electronegativity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1010, type, ph_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1011, type, ph_value_1: $i > $o).
% 28.74/28.89  tff(decl_1012, type, ph_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1013, type, chemical_polarity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1014, type, chemical_polarity_value_1: $i > $o).
% 28.74/28.89  tff(decl_1015, type, chemical_polarity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1016, type, chemical_stability_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1017, type, chemical_stability_value_1: $i > $o).
% 28.74/28.89  tff(decl_1018, type, chemical_stability_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1019, type, coefficient_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1020, type, coefficient_value_1: $i > $o).
% 28.74/28.89  tff(decl_1021, type, coefficient_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1022, type, concentration_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1023, type, concentration_value_1: $i > $o).
% 28.74/28.89  tff(decl_1024, type, concentration_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1025, type, conductivity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1026, type, conductivity_value_1: $i > $o).
% 28.74/28.89  tff(decl_1027, type, conductivity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1028, type, default_ka_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1029, type, acid_role_1: $i > $o).
% 28.74/28.89  tff(decl_1030, type, equilibrium_constant_value_1: $i > $o).
% 28.74/28.89  tff(decl_1031, type, default_ka_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1032, type, default_kb_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1033, type, base_role_1: $i > $o).
% 28.74/28.89  tff(decl_1034, type, default_kb_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1035, type, electrolyte_status_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1036, type, electrolyte_status_value_1: $i > $o).
% 28.74/28.89  tff(decl_1037, type, electrolyte_status_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1038, type, equilibrium_concentration_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1039, type, equilibrium_concentration_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1040, type, ka_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1041, type, acid_dissociation_reaction_1: $i > $o).
% 28.74/28.89  tff(decl_1042, type, hydrolysis_1: $i > $o).
% 28.74/28.89  tff(decl_1043, type, ka_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1044, type, kb_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1045, type, kb_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1046, type, keq_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1047, type, chemical_equilibrium_reaction_1: $i > $o).
% 28.74/28.89  tff(decl_1048, type, keq_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1049, type, ki_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1050, type, chemical_reaction_1: $i > $o).
% 28.74/28.89  tff(decl_1051, type, ki_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1052, type, pka_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1053, type, pka_value_1: $i > $o).
% 28.74/28.89  tff(decl_1054, type, pka_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1055, type, pkb_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1056, type, pkb_value_1: $i > $o).
% 28.74/28.89  tff(decl_1057, type, pkb_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1058, type, salt_status_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1059, type, salt_status_value_1: $i > $o).
% 28.74/28.89  tff(decl_1060, type, salt_status_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1061, type, solubility_in_lipid_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1062, type, solubility_value_1: $i > $o).
% 28.74/28.89  tff(decl_1063, type, solubility_in_lipid_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1064, type, solubility_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1065, type, solubility_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1066, type, solubility_in_water_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1067, type, solubility_in_water_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1068, type, subscript_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1069, type, property_value_1: $i > $o).
% 28.74/28.89  tff(decl_1070, type, subscript_value_1: $i > $o).
% 28.74/28.89  tff(decl_1071, type, subscript_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1072, type, acceleration_magnitude_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1073, type, acceleration_magnitude_value_1: $i > $o).
% 28.74/28.89  tff(decl_1074, type, acceleration_magnitude_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1075, type, acceleration_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1076, type, acceleration_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1077, type, direction_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1078, type, angle_value_1: $i > $o).
% 28.74/28.89  tff(decl_1079, type, direction_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1080, type, distance_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1081, type, length_value_1: $i > $o).
% 28.74/28.89  tff(decl_1082, type, distance_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1083, type, duration_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1084, type, duration_value_1: $i > $o).
% 28.74/28.89  tff(decl_1085, type, duration_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1086, type, frequency_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1087, type, frequency_value_1: $i > $o).
% 28.74/28.89  tff(decl_1088, type, frequency_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1089, type, importance_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1090, type, unitless_value_1: $i > $o).
% 28.74/28.89  tff(decl_1091, type, importance_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1092, type, intensity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1093, type, intensity_value_1: $i > $o).
% 28.74/28.89  tff(decl_1094, type, intensity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1095, type, manner_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1096, type, manner_value_1: $i > $o).
% 28.74/28.89  tff(decl_1097, type, manner_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1098, type, momentum_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1099, type, momentum_value_1: $i > $o).
% 28.74/28.89  tff(decl_1100, type, momentum_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1101, type, priority_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1102, type, priority_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1103, type, rate_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1104, type, rate_value_1: $i > $o).
% 28.74/28.89  tff(decl_1105, type, rate_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1106, type, rotational_rate_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1107, type, rotational_rate_value_1: $i > $o).
% 28.74/28.89  tff(decl_1108, type, rotational_rate_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1109, type, speed_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1110, type, speed_value_1: $i > $o).
% 28.74/28.89  tff(decl_1111, type, speed_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1112, type, reaction_direction_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1113, type, reaction_direction_value_1: $i > $o).
% 28.74/28.89  tff(decl_1114, type, reaction_direction_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1115, type, age_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1116, type, age_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1117, type, angle_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1118, type, angle_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1119, type, animacy_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1120, type, animacy_value_1: $i > $o).
% 28.74/28.89  tff(decl_1121, type, animacy_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1122, type, area_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1123, type, area_value_1: $i > $o).
% 28.74/28.89  tff(decl_1124, type, area_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1125, type, breakability_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1126, type, breakability_value_1: $i > $o).
% 28.74/28.89  tff(decl_1127, type, breakability_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1128, type, brightness_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1129, type, brightness_value_1: $i > $o).
% 28.74/28.89  tff(decl_1130, type, brightness_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1131, type, capacity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1132, type, capacity_value_1: $i > $o).
% 28.74/28.89  tff(decl_1133, type, capacity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1134, type, circumference_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1135, type, circumference_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1136, type, color_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1137, type, color_value_1: $i > $o).
% 28.74/28.89  tff(decl_1138, type, color_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1139, type, consistency_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1140, type, consistency_value_1: $i > $o).
% 28.74/28.89  tff(decl_1141, type, consistency_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1142, type, density_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1143, type, density_value_1: $i > $o).
% 28.74/28.89  tff(decl_1144, type, density_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1145, type, depth_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1146, type, depth_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1147, type, diameter_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1148, type, diameter_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1149, type, dimension_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1150, type, dimension_value_1: $i > $o).
% 28.74/28.89  tff(decl_1151, type, dimension_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1152, type, fertility_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1153, type, fertility_value_1: $i > $o).
% 28.74/28.89  tff(decl_1154, type, fertility_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1155, type, height_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1156, type, integrity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1157, type, integrity_value_1: $i > $o).
% 28.74/28.89  tff(decl_1158, type, integrity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1159, type, latitude_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1160, type, latitude_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1161, type, length_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1162, type, length_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1163, type, longitude_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1164, type, longitude_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1165, type, luminance_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1166, type, luminance_value_1: $i > $o).
% 28.74/28.89  tff(decl_1167, type, luminance_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1168, type, luminous_flux_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1169, type, luminous_flux_value_1: $i > $o).
% 28.74/28.89  tff(decl_1170, type, luminous_flux_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1171, type, luminous_intensity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1172, type, luminous_intensity_value_1: $i > $o).
% 28.74/28.89  tff(decl_1173, type, luminous_intensity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1174, type, mass_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1175, type, mass_value_1: $i > $o).
% 28.74/28.89  tff(decl_1176, type, mass_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1177, type, moment_of_inertia_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1178, type, physical_object_1: $i > $o).
% 28.74/28.89  tff(decl_1179, type, moment_of_inertia_value_1: $i > $o).
% 28.74/28.89  tff(decl_1180, type, moment_of_inertia_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1181, type, orientation_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1182, type, orientation_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1183, type, oxidation_state_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1184, type, oxidation_state_value_1: $i > $o).
% 28.74/28.89  tff(decl_1185, type, oxidation_state_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1186, type, perimeter_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1187, type, perimeter_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1188, type, physical_state_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1189, type, state_value_1: $i > $o).
% 28.74/28.89  tff(decl_1190, type, physical_state_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1191, type, polarity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1192, type, polarity_value_1: $i > $o).
% 28.74/28.89  tff(decl_1193, type, polarity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1194, type, power_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1195, type, power_value_1: $i > $o).
% 28.74/28.89  tff(decl_1196, type, power_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1197, type, pressure_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1198, type, pressure_value_1: $i > $o).
% 28.74/28.89  tff(decl_1199, type, pressure_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1200, type, quantity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1201, type, quantity_value_1: $i > $o).
% 28.74/28.89  tff(decl_1202, type, quantity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1203, type, radius_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1204, type, radius_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1205, type, sentience_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1206, type, sentience_value_1: $i > $o).
% 28.74/28.89  tff(decl_1207, type, sentience_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1208, type, sex_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1209, type, sex_value_1: $i > $o).
% 28.74/28.89  tff(decl_1210, type, sex_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1211, type, shape_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1212, type, shape_value_1: $i > $o).
% 28.74/28.89  tff(decl_1213, type, shape_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1214, type, size_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1215, type, size_value_1: $i > $o).
% 28.74/28.89  tff(decl_1216, type, size_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1217, type, slope_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1218, type, slope_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1219, type, smell_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1220, type, smell_value_1: $i > $o).
% 28.74/28.89  tff(decl_1221, type, smell_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1222, type, specific_surface_area_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1223, type, specific_surface_area_value_1: $i > $o).
% 28.74/28.89  tff(decl_1224, type, specific_surface_area_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1225, type, surface_area_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1226, type, surface_area_value_1: $i > $o).
% 28.74/28.89  tff(decl_1227, type, surface_area_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1228, type, taste_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1229, type, taste_value_1: $i > $o).
% 28.74/28.89  tff(decl_1230, type, taste_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1231, type, temperature_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1232, type, temperature_value_1: $i > $o).
% 28.74/28.89  tff(decl_1233, type, temperature_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1234, type, texture_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1235, type, texture_value_1: $i > $o).
% 28.74/28.89  tff(decl_1236, type, texture_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1237, type, thickness_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1238, type, thickness_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1239, type, trait_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1240, type, trait_value_1: $i > $o).
% 28.74/28.89  tff(decl_1241, type, trait_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1242, type, truth_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1243, type, truth_value_1: $i > $o).
% 28.74/28.89  tff(decl_1244, type, truth_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1245, type, voltage_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1246, type, voltage_value_1: $i > $o).
% 28.74/28.89  tff(decl_1247, type, voltage_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1248, type, volume_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1249, type, volume_value_1: $i > $o).
% 28.74/28.89  tff(decl_1250, type, volume_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1251, type, wetness_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1252, type, wetness_value_1: $i > $o).
% 28.74/28.89  tff(decl_1253, type, wetness_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1254, type, width_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1255, type, width_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1256, type, worth_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1257, type, worth_value_1: $i > $o).
% 28.74/28.89  tff(decl_1258, type, worth_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1259, type, atomic_mass_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1260, type, isotope_1: $i > $o).
% 28.74/28.89  tff(decl_1261, type, atomic_mass_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1262, type, atomic_number_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1263, type, atomic_number_value_1: $i > $o).
% 28.74/28.89  tff(decl_1264, type, atomic_number_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1265, type, atomic_symbol_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1266, type, string_1: $i > $o).
% 28.74/28.89  tff(decl_1267, type, class_1: $i > $o).
% 28.74/28.89  tff(decl_1268, type, atomic_symbol_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1269, type, magnification_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1270, type, magnification_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1271, type, optical_resolution_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1272, type, optical_resolution_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1273, type, structural_complexity_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1274, type, structural_complexity_value_1: $i > $o).
% 28.74/28.89  tff(decl_1275, type, structural_complexity_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1276, type, mass_number_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1277, type, atomic_mass_value_1: $i > $o).
% 28.74/28.89  tff(decl_1278, type, mass_number_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1279, type, wavelength_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1280, type, wavelength_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1281, type, correspondence_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1282, type, different_type_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1283, type, directly_proportional_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1284, type, from_value_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1285, type, decrease_1: $i > $o).
% 28.74/28.89  tff(decl_1286, type, increase_1: $i > $o).
% 28.74/28.89  tff(decl_1287, type, from_value_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1288, type, less_than_or_equal_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1289, type, greater_than_or_equal_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1290, type, less_than_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1291, type, greater_than_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1292, type, inversely_proportional_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1293, type, negative_influence_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1294, type, positive_influence_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1295, type, same_as_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1296, type, same_type_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1297, type, to_value_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1298, type, to_value_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1299, type, encloses_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1300, type, instrument_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1301, type, object_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1302, type, agent_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1303, type, raw_material_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1304, type, is_solute_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1305, type, is_basic_structural_unit_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1306, type, is_part_or_unit_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1307, type, base_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1308, type, played_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1309, type, path_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1310, type, content_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1311, type, container_1: $i > $o).
% 28.74/28.89  tff(decl_1312, type, has_part_or_unit_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1313, type, has_basic_structural_unit_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1314, type, away_from_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1315, type, element_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1316, type, beneficiary_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1317, type, content_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1318, type, first_element_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1319, type, is_part_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1320, type, is_possessed_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1321, type, result_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1322, type, information_content_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1323, type, origin_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1324, type, subevent_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1325, type, site_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1326, type, toward_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1327, type, time_int_finished_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1328, type, time_int_overlapped_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1329, type, time_int_started_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1330, type, is_region_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1331, type, time_after_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1332, type, old_has_function_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1333, type, old_is_function_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1334, type, caused_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1335, type, resulting_state_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1336, type, state_1: $i > $o).
% 28.74/28.89  tff(decl_1337, type, resulting_state_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1338, type, defeats_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1339, type, action_1: $i > $o).
% 28.74/28.89  tff(decl_1340, type, time_int_contains_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1341, type, enabled_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1342, type, in_event_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1343, type, inhibited_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1344, type, means_by_which_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1345, type, prevented_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1346, type, experiencer_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1347, type, height_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1348, type, recipient_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1349, type, equal_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1350, type, destination_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1351, type, donor_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1352, type, does_not_enclose_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1353, type, is_at_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1354, type, is_in_front_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1355, type, has_on_it_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1356, type, is_below_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1357, type, is_under_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1358, type, defeated_by_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1359, type, material_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1360, type, related_to_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1361, type, time_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1362, type, prev_event_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1363, type, has_structure_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1364, type, is_structure_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1365, type, is_structure_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1366, type, has_structure_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1367, type, prev_event_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1368, type, next_event_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1369, type, result_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1370, type, time_int_started_by_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1371, type, time_int_starts_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1372, type, time_int_meets_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1373, type, time_int_contains_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1374, type, time_int_during_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1375, type, time_after_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1376, type, time_before_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1377, type, time_int_overlapped_by_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1378, type, time_int_overlaps_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1379, type, time_int_finished_by_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1380, type, time_int_finishes_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1381, type, related_to_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1382, type, is_possessed_by_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1383, type, element_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1384, type, site_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1385, type, result_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1386, type, raw_material_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1387, type, plays_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1388, type, path_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1389, type, origin_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1390, type, object_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1391, type, material_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1392, type, material_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1393, type, is_part_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1394, type, animal_1: $i > $o).
% 28.74/28.89  tff(decl_1395, type, participant_1: $i > $o).
% 28.74/28.89  tff(decl_1396, type, has_region_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1397, type, has_part_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1398, type, destination_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1399, type, content_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1400, type, content_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1401, type, beneficiary_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1402, type, base_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1403, type, inhibited_by_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1404, type, person_1: $i > $o).
% 28.74/28.89  tff(decl_1405, type, experiencer_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1406, type, enabled_by_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1407, type, defeated_by_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1408, type, caused_by_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1409, type, toward_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1410, type, is_under_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1411, type, is_region_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1412, type, is_over_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1413, type, is_outside_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1414, type, is_opposite_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1415, type, is_on_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1416, type, is_near_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1417, type, is_inside_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1418, type, is_in_front_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1419, type, is_beside_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1420, type, is_below_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1421, type, is_behind_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1422, type, is_at_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1423, type, is_at_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1424, type, is_along_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1425, type, is_above_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1426, type, height_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1427, type, has_on_it_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1428, type, encloses_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1429, type, away_from_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1430, type, does_not_enclose_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1431, type, slide_1: $i > $o).
% 28.74/28.89  tff(decl_1432, type, recipient_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1433, type, played_by_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1434, type, move_1: $i > $o).
% 28.74/28.89  tff(decl_1435, type, instrument_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1436, type, in_event_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1437, type, experiencer_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1438, type, donor_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1439, type, agent_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1440, type, reaction_1: $i > $o).
% 28.74/28.89  tff(decl_1441, type, raw_material_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1442, type, possesses_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1443, type, element_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1444, type, conduit_1: $i > $o).
% 28.74/28.89  tff(decl_1445, type, path_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1446, type, origin_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1447, type, destination_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1448, type, mix_1: $i > $o).
% 28.74/28.89  tff(decl_1449, type, message_1: $i > $o).
% 28.74/28.89  tff(decl_1450, type, height_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1451, type, inanimate_object_1: $i > $o).
% 28.74/28.89  tff(decl_1452, type, fall_1: $i > $o).
% 28.74/28.89  tff(decl_1453, type, toward_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1454, type, subevent_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1455, type, subevent_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1456, type, site_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1457, type, recipient_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1458, type, prevents_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1459, type, prevented_by_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1460, type, object_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1461, type, means_by_which_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1462, type, instrument_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1463, type, inhibits_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1464, type, in_event_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1465, type, enables_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1466, type, donor_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1467, type, defeats_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1468, type, causes_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1469, type, by_means_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1470, type, beneficiary_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1471, type, base_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1472, type, away_from_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1473, type, agent_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1474, type, community_1: $i > $o).
% 28.74/28.89  tff(decl_1475, type, is_part_or_unit_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1476, type, has_part_or_unit_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1477, type, first_element_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1478, type, create_1: $i > $o).
% 28.74/28.89  tff(decl_1479, type, is_solute_of_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1480, type, be_touching_1: $i > $o).
% 28.74/28.89  tff(decl_1481, type, be_contained_1: $i > $o).
% 28.74/28.89  tff(decl_1482, type, first_element_star_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1483, type, cardinal_value_1: $i > $o).
% 28.74/28.89  tff(decl_1484, type, categorical_value_1: $i > $o).
% 28.74/28.89  tff(decl_1485, type, scalar_constant_class_1: $i > $o).
% 28.74/28.89  tff(decl_1486, type, scalar_value_1: $i > $o).
% 28.74/28.89  tff(decl_1487, type, unit_of_measurement_1: $i > $o).
% 28.74/28.89  tff(decl_1488, type, categorical_constant_1: $i > $o).
% 28.74/28.89  tff(decl_1489, type, the_scalar_value_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1490, type, scalar_magnitude_of_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1491, type, cardinal_unit_class_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1492, type, cardinal_property_value_1: $i > $o).
% 28.74/28.89  tff(decl_1493, type, the_cardinal_value_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1494, type, float_1: $i > $o).
% 28.74/28.89  tff(decl_1495, type, the_categorical_value_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1496, type, number_1_comma_3_bisphosphoglycerate_1: $i > $o).
% 28.74/28.89  tff(decl_1497, type, '1,3-Bisphosphoglycerate': $i).
% 28.74/28.89  tff(decl_1498, type, original_name_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1499, type, 'Three carbon organic molecule which serves as a metabolic intermediate in cellular respiration and photosynthesis.': $i).
% 28.74/28.89  tff(decl_1500, type, user_description_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1501, type, '1,3 bisphosphoglycerate': $i).
% 28.74/28.89  tff(decl_1502, type, concept2words_2: ($i * $i) > $o).
% 28.74/28.89  tff(decl_1503, type, '1,3-bisphosphoglycerate': $i).
% 28.74/28.89  tff(decl_1504, type, '1 3 bisphosphoglyceric acid': $i).
% 28.74/28.89  tff(decl_1505, type, '1-3-bisphosphoglyceric-acid': $i).
% 28.74/28.89  tff(decl_1506, type, '1 3 bisphosphoglycerate': $i).
% 28.74/28.89  tff(decl_1507, type, '1-3-bisphosphoglycerate': $i).
% 28.74/28.89  tff(decl_1508, type, '1 3bpg': $i).
% 28.74/28.89  tff(decl_1509, type, '1-3bpg': $i).
% 28.74/28.89  tff(decl_1510, type, '1,3 diphosphoglycerate': $i).
% 28.74/28.89  tff(decl_1511, type, '1,3-diphosphoglycerate': $i).
% 28.74/28.89  tff(decl_1512, type, '1,3bpg': $i).
% 28.74/28.89  tff(decl_1513, type, pgap: $i).
% 28.74/28.89  tff(decl_1514, type, phosphorylated_intermediate_1: $i > $o).
% 28.74/28.89  tff(decl_1515, type, fn_1_comma_3_bisphosphoglycerate_1: $i > $i).
% 28.74/28.89  tff(decl_1516, type, phosphorylation_1: $i > $o).
% 28.74/28.89  tff(decl_1517, type, fn_1_comma_3_bisphosphoglycerate_2: $i > $i).
% 28.74/28.89  tff(decl_1518, type, molecule_1: $i > $o).
% 28.74/28.89  tff(decl_1519, type, fn_1_comma_3_bisphosphoglycerate_3: $i > $i).
% 28.74/28.89  tff(decl_1520, type, kinetic_energy_1: $i > $o).
% 28.74/28.89  tff(decl_1521, type, fn_1_comma_3_bisphosphoglycerate_4: $i > $i).
% 28.74/28.89  tff(decl_1522, type, constant_motion_1: $i > $o).
% 28.74/28.89  tff(decl_1523, type, fn_1_comma_3_bisphosphoglycerate_5: $i > $i).
% 28.74/28.89  tff(decl_1524, type, organic_molecule_1: $i > $o).
% 28.74/28.89  tff(decl_1525, type, fn_1_comma_3_bisphosphoglycerate_6: $i > $i).
% 28.74/28.89  tff(decl_1526, type, fn_1_comma_3_bisphosphoglycerate_7: $i > $i).
% 28.74/28.89  tff(decl_1527, type, fn_1_comma_3_bisphosphoglycerate_8: $i > $i).
% 28.74/28.89  tff(decl_1528, type, carbon_1: $i > $o).
% 28.74/28.89  tff(decl_1529, type, fn_1_comma_3_bisphosphoglycerate_9: $i > $i).
% 28.74/28.89  tff(decl_1530, type, oxygen_1: $i > $o).
% 28.74/28.89  tff(decl_1531, type, fn_1_comma_3_bisphosphoglycerate_10: $i > $i).
% 28.74/28.89  tff(decl_1532, type, carbon_skeleton_1: $i > $o).
% 28.74/28.89  tff(decl_1533, type, fn_1_comma_3_bisphosphoglycerate_11: $i > $i).
% 28.74/28.89  tff(decl_1534, type, carboxyl_group_1: $i > $o).
% 28.74/28.89  tff(decl_1535, type, fn_1_comma_3_bisphosphoglycerate_12: $i > $i).
% 28.74/28.89  tff(decl_1536, type, double_bond_1: $i > $o).
% 28.74/28.89  tff(decl_1537, type, fn_1_comma_3_bisphosphoglycerate_13: $i > $i).
% 28.74/28.89  tff(decl_1538, type, covalent_bond_1: $i > $o).
% 28.74/28.89  tff(decl_1539, type, single_bond_1: $i > $o).
% 28.74/28.89  tff(decl_1540, type, fn_1_comma_3_bisphosphoglycerate_14: $i > $i).
% 28.74/28.89  tff(decl_1541, type, fn_1_comma_3_bisphosphoglycerate_15: $i > $i).
% 28.74/28.89  tff(decl_1542, type, functional_group_1: $i > $o).
% 28.74/28.89  tff(decl_1543, type, phosphate_group_1: $i > $o).
% 28.74/28.89  tff(decl_1544, type, fn_1_comma_3_bisphosphoglycerate_16: $i > $i).
% 28.74/28.89  tff(decl_1545, type, hydrogen_1: $i > $o).
% 28.74/28.89  tff(decl_1546, type, fn_1_comma_3_bisphosphoglycerate_17: $i > $i).
% 28.74/28.89  tff(decl_1547, type, fn_1_comma_3_bisphosphoglycerate_18: $i > $i).
% 28.74/28.89  tff(decl_1548, type, phosphorus_1: $i > $o).
% 28.74/28.89  tff(decl_1549, type, fn_functional_group_1: $i > $i).
% 28.74/28.89  tff(decl_1550, type, fn_carboxyl_group_69: $i > $i).
% 28.74/28.89  tff(decl_1551, type, fn_carboxyl_group_25: $i > $i).
% 28.74/28.89  tff(decl_1552, type, fn_carboxyl_group_70: $i > $i).
% 28.74/28.89  tff(decl_1553, type, fn_covalent_bond_19: $i > $i).
% 28.74/28.89  tff(decl_1554, type, fn_carboxyl_group_23: $i > $i).
% 28.74/28.89  tff(decl_1555, type, fn_covalent_bond_20: $i > $i).
% 28.74/28.89  tff(decl_1556, type, fn_carboxyl_group_24: $i > $i).
% 28.74/28.89  tff(decl_1557, type, fn_carboxyl_group_19: $i > $i).
% 28.74/28.89  tff(decl_1558, type, has_region_0: $i).
% 28.74/28.89  tff(decl_1559, type, "2": $i).
% 28.74/28.89  tff(decl_1560, type, phosphate_group_0: $i).
% 28.74/28.89  tff(decl_1561, type, exactCardinality: ($i * $i * $i * $i) > $o).
% 28.74/28.89  tff(decl_1562, type, fn_molecule_11: $i > $i).
% 28.74/28.89  tff(decl_1563, type, fn_molecule_10: $i > $i).
% 28.74/28.89  tff(decl_1564, type, fn_phosphorylated_intermediate_1: $i > $i).
% 28.74/28.89  tff(decl_1565, type, fn_1_comma_3_bisphosphoglycerate_19: $i > $i).
% 28.74/28.89  tff(decl_1566, type, fn_phosphorylated_intermediate_14: $i > $i).
% 28.74/28.89  tff(decl_1567, type, fn_1_comma_3_bisphosphoglycerate_20: $i > $i).
% 28.74/28.89  tff(decl_1568, type, fn_phosphorylated_intermediate_15: $i > $i).
% 28.74/28.89  tff(decl_1569, type, fn_phosphorylated_intermediate_9: $i > $i).
% 28.74/28.89  tff(decl_1570, type, fn_phosphorylated_intermediate_12: $i > $i).
% 28.74/28.89  tff(decl_1571, type, fn_phosphorylated_intermediate_13: $i > $i).
% 28.74/28.89  tff(decl_1572, type, fn_phosphorylated_intermediate_4: $i > $i).
% 28.74/28.89  tff(decl_1573, type, fn_phosphorylated_intermediate_3: $i > $i).
% 28.74/28.89  tff(decl_1574, type, fn_phosphorylated_intermediate_2: $i > $i).
% 28.74/28.89  tff(decl_1575, type, fn_phosphorylated_intermediate_11: $i > $i).
% 28.74/28.89  tff(decl_1576, type, fn_phosphorylated_intermediate_5: $i > $i).
% 28.74/28.89  tff(decl_1577, type, fn_phosphorylated_intermediate_6: $i > $i).
% 28.74/28.89  tff(decl_1578, type, fn_phosphorylated_intermediate_10: $i > $i).
% 28.74/28.89  tff(decl_1579, type, fn_phosphorylated_intermediate_7: $i > $i).
% 28.74/28.89  tff(decl_1580, type, fn_phosphorylated_intermediate_8: $i > $i).
% 28.74/28.89  tff(decl_1581, type, number_3_prime_carbon_1: $i > $o).
% 28.74/28.89  tff(decl_1582, type, '3-Prime-Carbon': $i).
% 28.74/28.89  tff(decl_1583, type, 'The carbon present at 3-prime region.': $i).
% 28.74/28.89  tff(decl_1584, type, '3 prime carbon': $i).
% 28.74/28.89  tff(decl_1585, type, '3-prime-carbon': $i).
% 28.74/28.89  tff(decl_1586, type, fn_3_prime_carbon_1: $i > $i).
% 28.74/28.89  tff(decl_1587, type, number_3_prime_region_1: $i > $o).
% 28.74/28.89  tff(decl_1588, type, number_3_prime_end_1: $i > $o).
% 28.74/28.89  tff(decl_1589, type, '3-Prime-End': $i).
% 28.74/28.89  tff(decl_1590, type, 'The has-region of a nucleotide sequence acid which includes the terminal nucleotide with a free 3\\ hydroxyl group.': $i).
% 28.74/28.89  tff(decl_1591, type, description_2: ($i * $i) > $o).
% 28.89/28.90  tff(decl_1592, type, 'The 3\\- end of a strand is so named due to it terminating at the hydroxyl group of the third carbon in the sugar-ring, and is known as the tail end.': $i).
% 28.89/28.90  tff(decl_1593, type, '3\\ end': $i).
% 28.89/28.90  tff(decl_1594, type, '3\\-end': $i).
% 28.89/28.90  tff(decl_1595, type, '3 prime end': $i).
% 28.89/28.90  tff(decl_1596, type, '3-prime-end': $i).
% 28.89/28.90  tff(decl_1597, type, nucleic_acid_region_1: $i > $o).
% 28.89/28.90  tff(decl_1598, type, number_5_prime_end_1: $i > $o).
% 28.89/28.90  tff(decl_1599, type, a_site_1: $i > $o).
% 28.89/28.90  tff(decl_1600, type, e_site_1: $i > $o).
% 28.89/28.90  tff(decl_1601, type, p_site_1: $i > $o).
% 28.89/28.90  tff(decl_1602, type, active_site_1: $i > $o).
% 28.89/28.90  tff(decl_1603, type, amino_end_1: $i > $o).
% 28.89/28.90  tff(decl_1604, type, carboxyl_end_1: $i > $o).
% 28.89/28.90  tff(decl_1605, type, cell_equator_1: $i > $o).
% 28.89/28.90  tff(decl_1606, type, cell_opposite_pole_1: $i > $o).
% 28.89/28.90  tff(decl_1607, type, cell_pole_1: $i > $o).
% 28.89/28.90  tff(decl_1608, type, centromere_1: $i > $o).
% 28.89/28.90  tff(decl_1609, type, cis_face_1: $i > $o).
% 28.89/28.90  tff(decl_1610, type, cisternal_space_1: $i > $o).
% 28.89/28.90  tff(decl_1611, type, cleavage_furrow_1: $i > $o).
% 28.89/28.90  tff(decl_1612, type, cytoplasmic_side_1: $i > $o).
% 28.89/28.90  tff(decl_1613, type, inside_face_1: $i > $o).
% 28.89/28.90  tff(decl_1614, type, intermembrane_space_1: $i > $o).
% 28.89/28.90  tff(decl_1615, type, metaphase_plate_1: $i > $o).
% 28.89/28.90  tff(decl_1616, type, mitochondrial_matrix_1: $i > $o).
% 28.89/28.90  tff(decl_1617, type, origin_of_replication_1: $i > $o).
% 28.89/28.90  tff(decl_1618, type, plasmodesmata_1: $i > $o).
% 28.89/28.90  tff(decl_1619, type, poly_a__tail_1: $i > $o).
% 28.89/28.90  tff(decl_1620, type, splice_site_1: $i > $o).
% 28.89/28.90  tff(decl_1621, type, target_destination_1: $i > $o).
% 28.89/28.90  tff(decl_1622, type, thylakoid_space_1: $i > $o).
% 28.89/28.90  tff(decl_1623, type, trans_face_1: $i > $o).
% 28.89/28.90  tff(decl_1624, type, '3-Prime-Region': $i).
% 28.89/28.90  tff(decl_1625, type, 'Region of nucleic acids which is associated with the 3\\ carbon on the sugar component of the molecule.': $i).
% 28.89/28.90  tff(decl_1626, type, '3 prime region': $i).
% 28.89/28.90  tff(decl_1627, type, '3-prime-region': $i).
% 28.89/28.90  tff(decl_1628, type, number_5_prime_carbon_1: $i > $o).
% 28.89/28.90  tff(decl_1629, type, '5-Prime-Carbon': $i).
% 28.89/28.90  tff(decl_1630, type, 'The carbon present at 5-prime region.': $i).
% 28.89/28.90  tff(decl_1631, type, '5 prime carbon': $i).
% 28.89/28.90  tff(decl_1632, type, '5-prime-carbon': $i).
% 28.89/28.90  tff(decl_1633, type, fn_5_prime_carbon_1: $i > $i).
% 28.89/28.90  tff(decl_1634, type, number_5_prime_region_1: $i > $o).
% 28.89/28.90  tff(decl_1635, type, '5-Prime-End': $i).
% 28.89/28.90  tff(decl_1636, type, 'The Region of a Nucleotide-Sequence which includes the terminal Nucleotide with a free 5\\ Triphosphate group.': $i).
% 28.89/28.90  tff(decl_1637, type, 'The 5\\-end designates the end of the DNA or RNA strand that has the fifth carbon in the sugar-ring of the deoxyribose or ribose at its terminus. A phosphate group attached to the 5\\-end permits ligation of two nucleotides.': $i).
% 28.89/28.90  tff(decl_1638, type, 'five prime end': $i).
% 28.89/28.90  tff(decl_1639, type, 'five-prime-end': $i).
% 28.89/28.90  tff(decl_1640, type, '5\\ end': $i).
% 28.89/28.90  tff(decl_1641, type, '5\\-end': $i).
% 28.89/28.90  tff(decl_1642, type, '5 prime end': $i).
% 28.89/28.90  tff(decl_1643, type, '5-prime-end': $i).
% 28.89/28.90  tff(decl_1644, type, number_5_prime_nucleotide_1: $i > $o).
% 28.89/28.90  tff(decl_1645, type, '5-Prime-Nucleotide': $i).
% 28.89/28.90  tff(decl_1646, type, 'Nucleotide at the end of a sequence whose 5\\ end either                 bears a free triphosphate (free sequences like DNA strands                 or DNA strand fragments) or whose 5\\ end                 is attached to a neighboring sequence (internal sequences                 like introns or regulatory sequences).': $i).
% 28.89/28.90  tff(decl_1647, type, 'Nucleotide at the 5\\ end of a sequence.': $i).
% 28.89/28.90  tff(decl_1648, type, '5\\ nucleotide': $i).
% 28.89/28.90  tff(decl_1649, type, '5\\-nucleotide': $i).
% 28.89/28.90  tff(decl_1650, type, '5\\ base': $i).
% 28.89/28.90  tff(decl_1651, type, 'five prime base': $i).
% 28.89/28.90  tff(decl_1652, type, '5 prime nucleotide': $i).
% 28.89/28.90  tff(decl_1653, type, '5-prime-nucleotide': $i).
% 28.89/28.90  tff(decl_1654, type, nucleotide_1: $i > $o).
% 28.89/28.90  tff(decl_1655, type, fn_5_prime_nucleotide_1: $i > $i).
% 28.89/28.90  tff(decl_1656, type, '5-Prime-Region': $i).
% 28.89/28.90  tff(decl_1657, type, 'Region of nucleic acids which is associated with the 5\\ carbon on the sugar component of the molecule.': $i).
% 28.89/28.90  tff(decl_1658, type, '5 prime region': $i).
% 28.89/28.90  tff(decl_1659, type, '5-prime-region': $i).
% 28.89/28.90  tff(decl_1660, type, a_antigen_1: $i > $o).
% 28.89/28.90  tff(decl_1661, type, 'A-Antigen': $i).
% 28.89/28.90  tff(decl_1662, type, 'An antigen is a molecule recognized by the immune system. Type A blood has one kind of antigen and type B another. A person with type AB blood has both the A and B antigen.': $i).
% 28.89/28.90  tff(decl_1663, type, 'carbohydrate a': $i).
% 28.89/28.90  tff(decl_1664, type, 'carbohydrate-a': $i).
% 28.89/28.90  tff(decl_1665, type, 'antigen of a': $i).
% 28.89/28.90  tff(decl_1666, type, 'a antigen': $i).
% 28.89/28.90  tff(decl_1667, type, 'a-antigen': $i).
% 28.89/28.90  tff(decl_1668, type, blood_carbohydrate_1: $i > $o).
% 28.89/28.90  tff(decl_1669, type, b_antigen_1: $i > $o).
% 28.89/28.90  tff(decl_1670, type, a_band_1: $i > $o).
% 28.89/28.90  tff(decl_1671, type, 'A-Band': $i).
% 28.89/28.90  tff(decl_1672, type, 'A broad region that corresponds to the length of the thick filaments in a sarcomere': $i).
% 28.89/28.90  tff(decl_1673, type, 'band of a': $i).
% 28.89/28.90  tff(decl_1674, type, 'a band': $i).
% 28.89/28.90  tff(decl_1675, type, 'a-band': $i).
% 28.89/28.90  tff(decl_1676, type, biological_region_1: $i > $o).
% 28.89/28.90  tff(decl_1677, type, 'A-Site': $i).
% 28.89/28.90  tff(decl_1678, type, 'The site on the ribosome where the incoming amino-acyl tRNA binds.': $i).
% 28.89/28.90  tff(decl_1679, type, 'One of a ribosome\\s three binding sites for tRNA during translation.  The A site holds the tRNA carrying the next amino acid to be added to the polypeptide chain.': $i).
% 28.89/28.90  tff(decl_1680, type, 'a-site': $i).
% 28.89/28.90  tff(decl_1681, type, ribosome_region_1: $i > $o).
% 28.89/28.90  tff(decl_1682, type, fn_a_site_1: $i > $i).
% 28.89/28.90  tff(decl_1683, type, three_prime_end_of_mrna_1: $i > $o).
% 28.89/28.90  tff(decl_1684, type, fn_a_site_2: $i > $i).
% 28.89/28.90  tff(decl_1685, type, large_ribosomal_subunit_1: $i > $o).
% 28.89/28.90  tff(decl_1686, type, fn_a_site_3: $i > $i).
% 28.89/28.90  tff(decl_1687, type, ribosome_1: $i > $o).
% 28.89/28.90  tff(decl_1688, type, fn_a_site_4: $i > $i).
% 28.89/28.90  tff(decl_1689, type, aminoacyl_trna_1: $i > $o).
% 28.89/28.90  tff(decl_1690, type, fn_a_site_5: $i > $i).
% 28.89/28.90  tff(decl_1691, type, attach_1: $i > $o).
% 28.89/28.90  tff(decl_1692, type, fn_a_site_6: $i > $i).
% 28.89/28.90  tff(decl_1693, type, fn_a_site_7: $i > $i).
% 28.89/28.90  tff(decl_1694, type, codon_recognition_1: $i > $o).
% 28.89/28.90  tff(decl_1695, type, fn_a_site_8: $i > $i).
% 28.89/28.90  tff(decl_1696, type, move_into_1: $i > $o).
% 28.89/28.90  tff(decl_1697, type, fn_codon_recognition_9: $i > $i).
% 28.89/28.90  tff(decl_1698, type, fn_codon_recognition_8: $i > $i).
% 28.89/28.90  tff(decl_1699, type, fn_move_into_1: $i > $i).
% 28.89/28.90  tff(decl_1700, type, fn_attach_2: $i > $i).
% 28.89/28.90  tff(decl_1701, type, fn_codon_recognition_3: $i > $i).
% 28.89/28.90  tff(decl_1702, type, fn_move_1: $i > $i).
% 28.89/28.90  tff(decl_1703, type, fn_attach_1: $i > $i).
% 28.89/28.90  tff(decl_1704, type, fn_codon_recognition_11: $i > $i).
% 28.89/28.90  tff(decl_1705, type, abdomen_1: $i > $o).
% 28.89/28.90  tff(decl_1706, type, 'Abdomen': $i).
% 28.89/28.90  tff(decl_1707, type, 'In vertebrates such as mammals the abdomen (belly) constitutes the part of the body between the thorax (chest) and pelvis.': $i).
% 28.89/28.90  tff(decl_1708, type, abdomen: $i).
% 28.89/28.90  tff(decl_1709, type, body_segment_1: $i > $o).
% 28.89/28.90  tff(decl_1710, type, thorax_1: $i > $o).
% 28.89/28.90  tff(decl_1711, type, head_1: $i > $o).
% 28.89/28.90  tff(decl_1712, type, abdominal_cavity_1: $i > $o).
% 28.89/28.90  tff(decl_1713, type, 'Abdominal-Cavity': $i).
% 28.89/28.90  tff(decl_1714, type, 'In vertebrate animals, the cavity that encloses the major visceral organs; separated from the thoracic cavity by the diaphragm.': $i).
% 28.89/28.90  tff(decl_1715, type, 'cavity of abdominal': $i).
% 28.89/28.90  tff(decl_1716, type, 'abdominal cavity': $i).
% 28.89/28.90  tff(decl_1717, type, 'abdominal-cavity': $i).
% 28.89/28.90  tff(decl_1718, type, animal_space_1: $i > $o).
% 28.89/28.90  tff(decl_1719, type, antheridium_1: $i > $o).
% 28.89/28.90  tff(decl_1720, type, archegonium_1: $i > $o).
% 28.89/28.90  tff(decl_1721, type, atrium_1: $i > $o).
% 28.89/28.90  tff(decl_1722, type, blastocoel_1: $i > $o).
% 28.89/28.90  tff(decl_1723, type, blastopore_1: $i > $o).
% 28.89/28.90  tff(decl_1724, type, body_cavity_1: $i > $o).
% 28.89/28.90  tff(decl_1725, type, central_canal_1: $i > $o).
% 28.89/28.90  tff(decl_1726, type, cloaca_1: $i > $o).
% 28.89/28.90  tff(decl_1727, type, duodenum_1: $i > $o).
% 28.89/28.90  tff(decl_1728, type, gastrovascular_cavity_1: $i > $o).
% 28.89/28.90  tff(decl_1729, type, micropyle_1: $i > $o).
% 28.89/28.90  tff(decl_1730, type, middle_ear_1: $i > $o).
% 28.89/28.90  tff(decl_1731, type, optic_chiasm_1: $i > $o).
% 28.89/28.90  tff(decl_1732, type, oral_cavity_1: $i > $o).
% 28.89/28.90  tff(decl_1733, type, osculum_1: $i > $o).
% 28.89/28.90  tff(decl_1734, type, outer_ear_1: $i > $o).
% 28.89/28.90  tff(decl_1735, type, oval_window_1: $i > $o).
% 28.89/28.90  tff(decl_1736, type, pharyngeal_cleft_1: $i > $o).
% 28.89/28.90  tff(decl_1737, type, pharyngeal_slit_1: $i > $o).
% 28.89/28.90  tff(decl_1738, type, pupil_of_an_eye_1: $i > $o).
% 28.89/28.90  tff(decl_1739, type, renal_medulla_1: $i > $o).
% 28.89/28.90  tff(decl_1740, type, renal_pelvis_1: $i > $o).
% 28.89/28.90  tff(decl_1741, type, round_window_1: $i > $o).
% 28.89/28.90  tff(decl_1742, type, saccule_1: $i > $o).
% 28.89/28.90  tff(decl_1743, type, semicircular_canal_1: $i > $o).
% 28.89/28.90  tff(decl_1744, type, spongocoel_1: $i > $o).
% 28.89/28.90  tff(decl_1745, type, stoma_1: $i > $o).
% 28.89/28.90  tff(decl_1746, type, synapse_1: $i > $o).
% 28.89/28.90  tff(decl_1747, type, synaptic_cleft_1: $i > $o).
% 28.89/28.90  tff(decl_1748, type, utricle_1: $i > $o).
% 28.89/28.90  tff(decl_1749, type, ventricle_1: $i > $o).
% 28.89/28.90  tff(decl_1750, type, vestibule_of_the_ear_1: $i > $o).
% 28.89/28.90  tff(decl_1751, type, abiotic_factor_1: $i > $o).
% 28.89/28.90  tff(decl_1752, type, 'Abiotic-Factor': $i).
% 28.89/28.90  tff(decl_1753, type, 'A nonliving physical or chemical component of an ecosystem, with which organisms interact.': $i).
% 28.89/28.90  tff(decl_1754, type, 'abiotic factor': $i).
% 28.89/28.90  tff(decl_1755, type, 'abiotic-factor': $i).
% 28.89/28.90  tff(decl_1756, type, ecological_role_1: $i > $o).
% 28.89/28.90  tff(decl_1757, type, abnormal_1: $i > $o).
% 28.89/28.90  tff(decl_1758, type, 'Abnormal': $i).
% 28.89/28.90  tff(decl_1759, type, 'Not normal or as expected': $i).
% 28.89/28.90  tff(decl_1760, type, abnormal: $i).
% 28.89/28.90  tff(decl_1761, type, abnormal_cloned_embryo_1: $i > $o).
% 28.89/28.90  tff(decl_1762, type, 'Abnormal-Cloned-Embryo': $i).
% 28.89/28.90  tff(decl_1763, type, 'A cloned embryo that is not normal.': $i).
% 28.89/28.90  tff(decl_1764, type, 'abnormal cloned embryo': $i).
% 28.89/28.90  tff(decl_1765, type, 'abnormal-cloned-embryo': $i).
% 28.89/28.90  tff(decl_1766, type, embryo_1: $i > $o).
% 28.89/28.90  tff(decl_1767, type, clone_1: $i > $o).
% 28.89/28.90  tff(decl_1768, type, cloned_embryo_1: $i > $o).
% 28.89/28.90  tff(decl_1769, type, animal_embryo_1: $i > $o).
% 28.89/28.90  tff(decl_1770, type, early_embryo_1: $i > $o).
% 28.89/28.90  tff(decl_1771, type, eight_cell_embryo_1: $i > $o).
% 28.89/28.90  tff(decl_1772, type, embryoid_1: $i > $o).
% 28.89/28.90  tff(decl_1773, type, plant_embryo_1: $i > $o).
% 28.89/28.90  tff(decl_1774, type, segmented_embryo_1: $i > $o).
% 28.89/28.90  tff(decl_1775, type, two_cell_embryo_1: $i > $o).
% 28.89/28.90  tff(decl_1776, type, fn_abnormal_cloned_embryo_1: $i > $i).
% 28.89/28.90  tff(decl_1777, type, fn_abnormal_cloned_embryo_2: $i > $i).
% 28.89/28.90  tff(decl_1778, type, dna_1: $i > $o).
% 28.89/28.90  tff(decl_1779, type, fn_abnormal_cloned_embryo_3: $i > $i).
% 28.89/28.90  tff(decl_1780, type, dna_hypermethylation_1: $i > $o).
% 28.89/28.90  tff(decl_1781, type, fn_abnormal_cloned_embryo_4: $i > $i).
% 28.89/28.90  tff(decl_1782, type, embryogenesis_1: $i > $o).
% 28.89/28.90  tff(decl_1783, type, fn_abnormal_cloned_embryo_5: $i > $i).
% 28.89/28.90  tff(decl_1784, type, fn_embryogenesis_8: $i > $i).
% 28.89/28.90  tff(decl_1785, type, fn_create_1: $i > $i).
% 28.89/28.90  tff(decl_1786, type, fn_embryogenesis_30: $i > $i).
% 28.89/28.90  tff(decl_1787, type, fn_embryogenesis_51: $i > $i).
% 28.89/28.90  tff(decl_1788, type, abo_blood_group_1: $i > $o).
% 28.89/28.90  tff(decl_1789, type, 'ABO-Blood-Group': $i).
% 28.89/28.90  tff(decl_1790, type, 'The ABO blood group phenotypes, also called blood types, are A, B, AB, and O.': $i).
% 28.89/28.90  tff(decl_1791, type, 'abo blood group': $i).
% 28.89/28.90  tff(decl_1792, type, 'abo-blood-group': $i).
% 28.89/28.90  tff(decl_1793, type, gene_with_multiple_alleles_1: $i > $o).
% 28.89/28.90  tff(decl_1794, type, fn_abo_blood_group_1: $i > $i).
% 28.89/28.90  tff(decl_1795, type, codominance_1: $i > $o).
% 28.89/28.90  tff(decl_1796, type, fn_abo_blood_group_2: $i > $i).
% 28.89/28.90  tff(decl_1797, type, blood_type_genotype_1: $i > $o).
% 28.89/28.90  tff(decl_1798, type, fn_abo_blood_group_3: $i > $i).
% 28.89/28.90  tff(decl_1799, type, inheritance_1: $i > $o).
% 28.89/28.90  tff(decl_1800, type, fn_transfer_1: $i > $i).
% 28.89/28.90  tff(decl_1801, type, abomasum_1: $i > $o).
% 28.89/28.90  tff(decl_1802, type, 'Abomasum': $i).
% 28.89/28.90  tff(decl_1803, type, 'The fourth chamber in a ruminant\\s digestive system in which cud is digested by the ruminant\\s own enzymes. The abomasum corresponds to the stomach in other mammals.': $i).
% 28.89/28.90  tff(decl_1804, type, abomasum: $i).
% 28.89/28.90  tff(decl_1805, type, digestive_organ_1: $i > $o).
% 28.89/28.90  tff(decl_1806, type, abortion_1: $i > $o).
% 28.89/28.90  tff(decl_1807, type, 'Abortion': $i).
% 28.89/28.90  tff(decl_1808, type, 'An embryo or fetus removed or expelled from the uterus before it reaches a viable age.': $i).
% 28.89/28.90  tff(decl_1809, type, abort: $i).
% 28.89/28.90  tff(decl_1810, type, abortion: $i).
% 28.89/28.90  tff(decl_1811, type, medical_procedure_1: $i > $o).
% 28.89/28.90  tff(decl_1812, type, morning_after_pill_1: $i > $o).
% 28.89/28.90  tff(decl_1813, type, assisted_reproductive_technology_1: $i > $o).
% 28.89/28.90  tff(decl_1814, type, electrocardiogram_1: $i > $o).
% 28.89/28.90  tff(decl_1815, type, genetic_testing_1: $i > $o).
% 28.89/28.90  tff(decl_1816, type, immunization_1: $i > $o).
% 28.89/28.90  tff(decl_1817, type, newborn_screening_1: $i > $o).
% 28.89/28.90  tff(decl_1818, type, paternity_testing_1: $i > $o).
% 28.89/28.90  tff(decl_1819, type, tubal_ligation_1: $i > $o).
% 28.89/28.90  tff(decl_1820, type, ultrasound_imaging_1: $i > $o).
% 28.89/28.90  tff(decl_1821, type, vasectomy_1: $i > $o).
% 28.89/28.90  tff(decl_1822, type, abrade_1: $i > $o).
% 28.89/28.90  tff(decl_1823, type, 'Abrade': $i).
% 28.89/28.90  tff(decl_1824, type, 'To wear away or damage by friction.': $i).
% 28.89/28.90  tff(decl_1825, type, abrade: $i).
% 28.89/28.90  tff(decl_1826, type, make_contact_1: $i > $o).
% 28.89/28.90  tff(decl_1827, type, abscisic_acid_1: $i > $o).
% 28.89/28.90  tff(decl_1828, type, 'Abscisic-Acid': $i).
% 28.89/28.90  tff(decl_1829, type, 'A plant hormone involved in developmental processes, including seed and bud dormancy and facilitating drought tolerance.': $i).
% 28.89/28.90  tff(decl_1830, type, aba: $i).
% 28.89/28.90  tff(decl_1831, type, 'abscisic acid': $i).
% 28.89/28.90  tff(decl_1832, type, 'abscisic-acid': $i).
% 28.89/28.90  tff(decl_1833, type, plant_hormone_1: $i > $o).
% 28.89/28.90  tff(decl_1834, type, absolute_dating_1: $i > $o).
% 28.89/28.90  tff(decl_1835, type, 'Absolute-Dating': $i).
% 28.89/28.90  tff(decl_1836, type, 'A collection of methods for dating materials which provide quantitative estimates of age. The most common form of absolute dating is radiometric dating which i based on the decay of radioactive isotopes.': $i).
% 28.89/28.90  tff(decl_1837, type, 'chronometric dating': $i).
% 28.89/28.90  tff(decl_1838, type, 'calendar dating': $i).
% 28.89/28.90  tff(decl_1839, type, 'dating of absolute': $i).
% 28.89/28.90  tff(decl_1840, type, 'absolute dating': $i).
% 28.89/28.90  tff(decl_1841, type, 'absolute-dating': $i).
% 28.89/28.90  tff(decl_1842, type, radiometric_dating_1: $i > $o).
% 28.89/28.90  tff(decl_1843, type, atomic_tracking_1: $i > $o).
% 28.89/28.90  tff(decl_1844, type, autoradiography_1: $i > $o).
% 28.89/28.90  tff(decl_1845, type, cloning_1: $i > $o).
% 28.89/28.90  tff(decl_1846, type, dna_mapping_1: $i > $o).
% 28.89/28.90  tff(decl_1847, type, dna_microarray_1: $i > $o).
% 28.89/28.90  tff(decl_1848, type, fetoscopy_1: $i > $o).
% 28.89/28.90  tff(decl_1849, type, genetic_linkage_mapping_1: $i > $o).
% 28.89/28.90  tff(decl_1850, type, gram_stain_1: $i > $o).
% 28.89/28.90  tff(decl_1851, type, in_situ_hybridization_1: $i > $o).
% 28.89/28.90  tff(decl_1852, type, in_vitro_hybridization_1: $i > $o).
% 28.89/28.90  tff(decl_1853, type, mark_recapture_method_1: $i > $o).
% 28.89/28.90  tff(decl_1854, type, microscopy_1: $i > $o).
% 28.89/28.90  tff(decl_1855, type, molecular_clock_1: $i > $o).
% 28.89/28.90  tff(decl_1856, type, nuclear_transplantation_1: $i > $o).
% 28.89/28.90  tff(decl_1857, type, population_viability_analysis_1: $i > $o).
% 28.89/28.90  tff(decl_1858, type, positron_emission_tomography_1: $i > $o).
% 28.89/28.90  tff(decl_1859, type, rule_of_addition_1: $i > $o).
% 28.89/28.90  tff(decl_1860, type, shotgun_sequencing_1: $i > $o).
% 28.89/28.90  tff(decl_1861, type, testcross_1: $i > $o).
% 28.89/28.90  tff(decl_1862, type, x_ray_crystallography_1: $i > $o).
% 28.89/28.90  tff(decl_1863, type, absorb_1: $i > $o).
% 28.89/28.90  tff(decl_1864, type, 'Absorb': $i).
% 28.89/28.90  tff(decl_1865, type, absorb: $i).
% 28.89/28.90  tff(decl_1866, type, take_in_1: $i > $o).
% 28.89/28.90  tff(decl_1867, type, eat_1: $i > $o).
% 28.89/28.90  tff(decl_1868, type, absorption_of_energy_by_electron_1: $i > $o).
% 28.89/28.90  tff(decl_1869, type, 'Absorbance-Scalar-Constant': $i).
% 28.89/28.90  tff(decl_1870, type, 'absorbance scalar constant': $i).
% 28.89/28.90  tff(decl_1871, type, 'absorbance-scalar-constant': $i).
% 28.89/28.90  tff(decl_1872, type, constant_1: $i > $o).
% 28.89/28.90  tff(decl_1873, type, absorbance_scale_1: $i > $o).
% 28.89/28.90  tff(decl_1874, type, 'Absorbance-Scale': $i).
% 28.89/28.90  tff(decl_1875, type, 'absorbance scale': $i).
% 28.89/28.90  tff(decl_1876, type, 'absorbance-scale': $i).
% 28.89/28.90  tff(decl_1877, type, scale_1: $i > $o).
% 28.89/28.90  tff(decl_1878, type, 'Absorbance-Value': $i).
% 28.89/28.90  tff(decl_1879, type, absorbancy: $i).
% 28.89/28.90  tff(decl_1880, type, absorbance: $i).
% 28.89/28.90  tff(decl_1881, type, 'absorbance value': $i).
% 28.89/28.90  tff(decl_1882, type, 'absorbance-value': $i).
% 28.89/28.90  tff(decl_1883, type, absorption_in_small_intestine_1: $i > $o).
% 28.89/28.90  tff(decl_1884, type, 'Absorption-In-Small-Intestine': $i).
% 28.89/28.90  tff(decl_1885, type, 'The uptake of mechanically and chemically digested nutrient molecules in the small intestine of animals.': $i).
% 28.89/28.90  tff(decl_1886, type, 'absorption in small intestine': $i).
% 28.89/28.90  tff(decl_1887, type, 'absorption-in-small-intestine': $i).
% 28.89/28.90  tff(decl_1888, type, digestive_process_1: $i > $o).
% 28.89/28.90  tff(decl_1889, type, 'Absorption-Of-Energy-By-Electron': $i).
% 28.89/28.90  tff(decl_1890, type, 'An electron can change its shell, but only by absorbing or losing an amount of energy equal to the difference in potential energy between the old shell and the new shell.': $i).
% 28.89/28.90  tff(decl_1891, type, 'absorption of energy by electron': $i).
% 28.89/28.90  tff(decl_1892, type, 'absorption-of-energy-by-electron': $i).
% 28.89/28.90  tff(decl_1893, type, fn_absorption_of_energy_by_electron_5: $i > $i).
% 28.89/28.90  tff(decl_1894, type, fn_absorption_of_energy_by_electron_7: $i > $i).
% 28.89/28.90  tff(decl_1895, type, fn_absorption_of_energy_by_electron_8: $i > $i).
% 28.89/28.90  tff(decl_1896, type, fn_absorption_of_energy_by_electron_9: $i > $i).
% 28.89/28.90  tff(decl_1897, type, fn_absorption_of_energy_by_electron_10: $i > $i).
% 28.89/28.90  tff(decl_1898, type, fn_absorption_of_energy_by_electron_11: $i > $i).
% 28.89/28.90  tff(decl_1899, type, fn_absorption_of_energy_by_electron_13: $i > $i).
% 28.89/28.90  tff(decl_1900, type, fn_absorption_of_energy_by_electron_14: $i > $i).
% 28.89/28.90  tff(decl_1901, type, fn_absorption_of_energy_by_electron_15: $i > $i).
% 28.89/28.90  tff(decl_1902, type, fn_absorption_of_energy_by_electron_16: $i > $i).
% 28.89/28.90  tff(decl_1903, type, fn_absorption_of_energy_by_electron_17: $i > $i).
% 28.89/28.90  tff(decl_1904, type, electron_1: $i > $o).
% 28.89/28.90  tff(decl_1905, type, fn_increase_2: $i > $i).
% 28.89/28.90  tff(decl_1906, type, property_node_1: $i > $o).
% 28.89/28.90  tff(decl_1907, type, fn_increase_3: $i > $i).
% 28.89/28.90  tff(decl_1908, type, fn_atom_14: $i > $i).
% 28.89/28.90  tff(decl_1909, type, 'EnergyAbsorbed': $i).
% 28.89/28.90  tff(decl_1910, type, called_2: ($i * $i) > $o).
% 28.89/28.90  tff(decl_1911, type, 'PE_Initial': $i).
% 28.89/28.90  tff(decl_1912, type, 'PE_Final': $i).
% 28.89/28.90  tff(decl_1913, type, fn_take_in_1: $i > $i).
% 28.89/28.90  tff(decl_1914, type, fn_move_into_2: $i > $i).
% 28.89/28.90  tff(decl_1915, type, fn_absorption_of_energy_by_electron_12: $i > $i).
% 28.89/28.90  tff(decl_1916, type, absorption_of_fats_in_small_intestine_1: $i > $o).
% 28.89/28.90  tff(decl_1917, type, 'Absorption-Of-Fats-In-Small-Intestine': $i).
% 28.89/28.90  tff(decl_1918, type, 'The uptake of small fatty acids by an organism that occurs in the small intestine during food processing.': $i).
% 28.89/28.90  tff(decl_1919, type, 'absorption of fats in small intestine': $i).
% 28.89/28.90  tff(decl_1920, type, 'absorption-of-fats-in-small-intestine': $i).
% 28.89/28.90  tff(decl_1921, type, absorption_spectrum_1: $i > $o).
% 28.89/28.90  tff(decl_1922, type, 'Absorption-Spectrum': $i).
% 28.89/28.90  tff(decl_1923, type, 'A range of wavelengths of visible light that can be absorbed by a particular pigment. This range is sometimes depicted in a graph with the same name.': $i).
% 28.89/28.90  tff(decl_1924, type, 'spectrum of absorption': $i).
% 28.89/28.90  tff(decl_1925, type, 'absorption spectrum': $i).
% 28.89/28.90  tff(decl_1926, type, 'absorption-spectrum': $i).
% 28.89/28.90  tff(decl_1927, type, graphical_representation_1: $i > $o).
% 28.89/28.90  tff(decl_1928, type, absorptive_process_1: $i > $o).
% 28.89/28.90  tff(decl_1929, type, 'Absorptive-Process': $i).
% 28.89/28.90  tff(decl_1930, type, 'Any process that occurs during absorption, the third stage of food processing in animals.': $i).
% 28.89/28.90  tff(decl_1931, type, 'absorptive process': $i).
% 28.89/28.90  tff(decl_1932, type, 'absorptive-process': $i).
% 28.89/28.90  tff(decl_1933, type, animal_process_1: $i > $o).
% 28.89/28.90  tff(decl_1934, type, abyssal_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1935, type, 'Abyssal-Zone': $i).
% 28.89/28.90  tff(decl_1936, type, 'Pelagic waters over the deepest parts of the ocean, at depths of 4000-6000 meters.': $i).
% 28.89/28.90  tff(decl_1937, type, abyss: $i).
% 28.89/28.90  tff(decl_1938, type, 'abyssal zone': $i).
% 28.89/28.90  tff(decl_1939, type, 'abyssal-zone': $i).
% 28.89/28.90  tff(decl_1940, type, aquatic_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1941, type, aphotic_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1942, type, benthic_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1943, type, deep_sea_hydrothermal_vent_1: $i > $o).
% 28.89/28.90  tff(decl_1944, type, estuary_1: $i > $o).
% 28.89/28.90  tff(decl_1945, type, eutrophic_lake_1: $i > $o).
% 28.89/28.90  tff(decl_1946, type, intertidal_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1947, type, limnetic_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1948, type, littoral_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1949, type, marine_benthic_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1950, type, neritic_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1951, type, oceanic_pelagic_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1952, type, oligotrophic_lake_1: $i > $o).
% 28.89/28.90  tff(decl_1953, type, photic_zone_1: $i > $o).
% 28.89/28.90  tff(decl_1954, type, acacia_tree_1: $i > $o).
% 28.89/28.90  tff(decl_1955, type, 'Acacia-Tree': $i).
% 28.89/28.90  tff(decl_1956, type, 'A tree or shrub of the genus Acacia.': $i).
% 28.89/28.90  tff(decl_1957, type, thorntree: $i).
% 28.89/28.90  tff(decl_1958, type, acacia: $i).
% 28.89/28.90  tff(decl_1959, type, 'tree of acacia': $i).
% 28.89/28.90  tff(decl_1960, type, 'acacia tree': $i).
% 28.89/28.90  tff(decl_1961, type, 'acacia-tree': $i).
% 28.89/28.90  tff(decl_1962, type, eudicot_1: $i > $o).
% 28.89/28.90  tff(decl_1963, type, acanthodian_1: $i > $o).
% 28.89/28.90  tff(decl_1964, type, 'Acanthodian': $i).
% 28.89/28.90  tff(decl_1965, type, 'Any of a group of extinct fishes that had features of both cartilaginous and bony fishes. Acanthodians appear in the fossil record from the Silurian to the Permian.': $i).
% 28.89/28.90  tff(decl_1966, type, acanthodian: $i).
% 28.89/28.90  tff(decl_1967, type, early_vertebrate_1: $i > $o).
% 28.89/28.90  tff(decl_1968, type, extinct_vertebrate_1: $i > $o).
% 28.89/28.90  tff(decl_1969, type, ammonite_1: $i > $o).
% 28.89/28.90  tff(decl_1970, type, anapsid_1: $i > $o).
% 28.89/28.90  tff(decl_1971, type, archaeopteryx_1: $i > $o).
% 28.89/28.90  tff(decl_1972, type, conodont_1: $i > $o).
% 28.89/28.90  tff(decl_1973, type, cooksonia_1: $i > $o).
% 28.89/28.90  tff(decl_1974, type, dinosaur_1: $i > $o).
% 28.89/28.90  tff(decl_1975, type, eurypterid_1: $i > $o).
% 28.89/28.90  tff(decl_1976, type, great_auk_1: $i > $o).
% 28.89/28.90  tff(decl_1977, type, neanderthal_1: $i > $o).
% 28.89/28.90  tff(decl_1978, type, paranthropus_boisei_1: $i > $o).
% 28.89/28.90  tff(decl_1979, type, parareptile_1: $i > $o).
% 28.89/28.90  tff(decl_1980, type, placoderm_1: $i > $o).
% 28.89/28.90  tff(decl_1981, type, pterosaur_1: $i > $o).
% 28.89/28.90  tff(decl_1982, type, trilobite_1: $i > $o).
% 28.89/28.90  tff(decl_1983, type, acceleration_magnitude_constant_1: $i > $o).
% 28.89/28.90  tff(decl_1984, type, 'Acceleration-Magnitude-Constant': $i).
% 28.89/28.90  tff(decl_1985, type, 'acceleration magnitude constant': $i).
% 28.89/28.90  tff(decl_1986, type, 'acceleration-magnitude-constant': $i).
% 28.89/28.90  tff(decl_1987, type, acceleration_magnitude_scale_1: $i > $o).
% 28.89/28.90  tff(decl_1988, type, 'Acceleration-Magnitude-Scale': $i).
% 28.89/28.90  tff(decl_1989, type, 'acceleration magnitude scale': $i).
% 28.89/28.90  tff(decl_1990, type, 'acceleration-magnitude-scale': $i).
% 28.89/28.90  tff(decl_1991, type, 'Acceleration-Magnitude-Value': $i).
% 28.89/28.90  tff(decl_1992, type, 'the rate of change of speed with respect to time': $i).
% 28.89/28.90  tff(decl_1993, type, 'magnitude of acceleration': $i).
% 28.89/28.90  tff(decl_1994, type, 'acceleration magnitude': $i).
% 28.89/28.90  tff(decl_1995, type, 'acceleration-magnitude': $i).
% 28.89/28.90  tff(decl_1996, type, quickening: $i).
% 28.89/28.90  tff(decl_1997, type, speedup: $i).
% 28.89/28.90  tff(decl_1998, type, accelerating: $i).
% 28.89/28.90  tff(decl_1999, type, acceleration: $i).
% 28.89/28.90  tff(decl_2000, type, 'acceleration magnitude value': $i).
% 28.89/28.90  tff(decl_2001, type, 'acceleration-magnitude-value': $i).
% 28.89/28.90  tff(decl_2002, type, magnitude_value_1: $i > $o).
% 28.89/28.90  tff(decl_2003, type, 'Acceptance-Constant': $i).
% 28.89/28.90  tff(decl_2004, type, 'constant of acceptance': $i).
% 28.89/28.90  tff(decl_2005, type, 'acceptance constant': $i).
% 28.89/28.90  tff(decl_2006, type, 'acceptance-constant': $i).
% 28.89/28.90  tff(decl_2007, type, 'Acceptance-Value': $i).
% 28.89/28.90  tff(decl_2008, type, acceptance: $i).
% 28.89/28.90  tff(decl_2009, type, 'value of acceptance': $i).
% 28.89/28.90  tff(decl_2010, type, 'acceptance value': $i).
% 28.89/28.90  tff(decl_2011, type, 'acceptance-value': $i).
% 28.89/28.90  tff(decl_2012, type, accessory_fruit_1: $i > $o).
% 28.89/28.90  tff(decl_2013, type, 'Accessory-Fruit': $i).
% 28.89/28.90  tff(decl_2014, type, 'A fruit in which some of the fleshy parts are not derived from the ovary, but from some other tissue.': $i).
% 28.89/28.90  tff(decl_2015, type, 'fruit of accessory': $i).
% 28.89/28.90  tff(decl_2016, type, 'accessory fruit': $i).
% 28.89/28.90  tff(decl_2017, type, 'accessory-fruit': $i).
% 28.89/28.90  tff(decl_2018, type, fruit_1: $i > $o).
% 28.89/28.90  tff(decl_2019, type, aggregate_fruit_1: $i > $o).
% 28.89/28.90  tff(decl_2020, type, accessory_pigment_1: $i > $o).
% 28.89/28.90  tff(decl_2021, type, 'Accessory-Pigment': $i).
% 28.89/28.90  tff(decl_2022, type, 'Antennae pigments found in photosynthetic organisms, that work in conjunction with other pigments to absorb light and transfer that light energy to photosystem chlorophyll.': $i).
% 28.89/28.90  tff(decl_2023, type, 'pigment of accessory': $i).
% 28.89/28.90  tff(decl_2024, type, 'accessory pigment': $i).
% 28.89/28.90  tff(decl_2025, type, 'accessory-pigment': $i).
% 28.89/28.90  tff(decl_2026, type, antenna_pigment_1: $i > $o).
% 28.89/28.90  tff(decl_2027, type, acclimatization_1: $i > $o).
% 28.89/28.90  tff(decl_2028, type, 'Acclimatization': $i).
% 28.89/28.90  tff(decl_2029, type, 'The physiological processes by which an organism adjusts to environmental change.': $i).
% 28.89/28.90  tff(decl_2030, type, acclimatize: $i).
% 28.89/28.90  tff(decl_2031, type, acclimatization: $i).
% 28.89/28.90  tff(decl_2032, type, homeostatic_response_1: $i > $o).
% 28.89/28.90  tff(decl_2033, type, biological_clock_1: $i > $o).
% 28.89/28.90  tff(decl_2034, type, hibernation_1: $i > $o).
% 28.89/28.90  tff(decl_2035, type, negative_feedback_1: $i > $o).
% 28.89/28.90  tff(decl_2036, type, plant_response_1: $i > $o).
% 28.89/28.90  tff(decl_2037, type, thermoregulation_1: $i > $o).
% 28.89/28.90  tff(decl_2038, type, acetaldehyde_1: $i > $o).
% 28.89/28.90  tff(decl_2039, type, 'Acetaldehyde': $i).
% 28.89/28.90  tff(decl_2040, type, 'Acetaldehyde is an organic compound with the formula CH3CHO. It is a type of aldehyde.': $i).
% 28.89/28.90  tff(decl_2041, type, ethanal: $i).
% 28.89/28.90  tff(decl_2042, type, acetaldehyde: $i).
% 28.89/28.90  tff(decl_2043, type, aldehyde_1: $i > $o).
% 28.89/28.90  tff(decl_2044, type, aldose_1: $i > $o).
% 28.89/28.90  tff(decl_2045, type, glyceraldehyde_3_phosphate_1: $i > $o).
% 28.89/28.90  tff(decl_2046, type, fn_acetaldehyde_1: $i > $i).
% 28.89/28.90  tff(decl_2047, type, fn_acetaldehyde_2: $i > $i).
% 28.89/28.90  tff(decl_2048, type, has_part_0: $i).
% 28.89/28.90  tff(decl_2049, type, carbon_0: $i).
% 28.89/28.90  tff(decl_2050, type, fn_aldehyde_5: $i > $i).
% 28.89/28.90  tff(decl_2051, type, fn_aldehyde_6: $i > $i).
% 28.89/28.90  tff(decl_2052, type, acetaldehyde_substance_1: $i > $o).
% 28.89/28.90  tff(decl_2053, type, 'Acetaldehyde-Substance': $i).
% 28.89/28.90  tff(decl_2054, type, 'Substance composed of acetaldehyde molecules.': $i).
% 28.89/28.90  tff(decl_2055, type, 'substance of acetaldehyde': $i).
% 28.89/28.90  tff(decl_2056, type, 'acetaldehyde substance': $i).
% 28.89/28.90  tff(decl_2057, type, 'acetaldehyde-substance': $i).
% 28.89/28.90  tff(decl_2058, type, fn_acetaldehyde_substance_1: $i > $i).
% 28.89/28.90  tff(decl_2059, type, fn_acetaldehyde_substance_2: $i > $i).
% 28.89/28.90  tff(decl_2060, type, fn_solubility_value_1: $i > $i).
% 28.89/28.90  tff(decl_2061, type, substance_0: $i).
% 28.89/28.90  tff(decl_2062, type, scalar_unit_class_2: ($i * $i) > $o).
% 28.89/28.90  tff(decl_2063, type, fn_acetaldehyde_substance_3: $i > $i).
% 28.89/28.90  tff(decl_2064, type, acetate_1: $i > $o).
% 28.89/28.90  tff(decl_2065, type, 'Acetate': $i).
% 28.89/28.90  tff(decl_2066, type, 'Acetate is a derivative of acetic acid. Two types of derivatives are known, salts and ester.': $i).
% 28.89/28.90  tff(decl_2067, type, acetate: $i).
% 28.89/28.90  tff(decl_2068, type, ester_1: $i > $o).
% 28.89/28.90  tff(decl_2069, type, alpha_ketoglutarate_1: $i > $o).
% 28.89/28.90  tff(decl_2070, type, citrate_1: $i > $o).
% 28.89/28.90  tff(decl_2071, type, fumarate_1: $i > $o).
% 28.89/28.90  tff(decl_2072, type, isocitrate_1: $i > $o).
% 28.89/28.90  tff(decl_2073, type, malate_1: $i > $o).
% 28.89/28.90  tff(decl_2074, type, oxaloacetate_1: $i > $o).
% 28.89/28.90  tff(decl_2075, type, succinate_1: $i > $o).
% 28.89/28.90  tff(decl_2076, type, fn_acetate_1: $i > $i).
% 28.89/28.90  tff(decl_2077, type, fn_organic_molecule_2: $i > $i).
% 28.89/28.90  tff(decl_2078, type, fn_ester_11: $i > $i).
% 28.89/28.90  tff(decl_2079, type, acetic_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2080, type, 'Acetic-Acid': $i).
% 28.89/28.90  tff(decl_2081, type, 'Acetic acid, CH3COOH, also known as ethanoic acid, is an organic acid that gives vinegar its sour taste and pungent smell. It is a weak acid, in that it is only a partially dissociated acid in an aqueous solution.': $i).
% 28.89/28.90  tff(decl_2082, type, 'acetic acid': $i).
% 28.89/28.90  tff(decl_2083, type, 'acetic-acid': $i).
% 28.89/28.90  tff(decl_2084, type, carboxylic_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2085, type, formic_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2086, type, pyruvic_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2087, type, fn_acetic_acid_1: $i > $i).
% 28.89/28.90  tff(decl_2088, type, fn_acetic_acid_3: $i > $i).
% 28.89/28.90  tff(decl_2089, type, fn_carboxylic_acid_9: $i > $i).
% 28.89/28.90  tff(decl_2090, type, acetone_1: $i > $o).
% 28.89/28.90  tff(decl_2091, type, 'Acetone': $i).
% 28.89/28.90  tff(decl_2092, type, 'Acetone is the organic compound with the formula (CH3)2CO. This colorless, mobile, flammable liquid is the simplest example of the ketones.': $i).
% 28.89/28.90  tff(decl_2093, type, acetone: $i).
% 28.89/28.90  tff(decl_2094, type, ketone_1: $i > $o).
% 28.89/28.90  tff(decl_2095, type, dihydroxyacetone_phosphate_1: $i > $o).
% 28.89/28.90  tff(decl_2096, type, ketose_1: $i > $o).
% 28.89/28.90  tff(decl_2097, type, fn_acetone_1: $i > $i).
% 28.89/28.90  tff(decl_2098, type, fn_ketone_10: $i > $i).
% 28.89/28.90  tff(decl_2099, type, fn_ketone_8: $i > $i).
% 28.89/28.90  tff(decl_2100, type, acetyl_coa_1: $i > $o).
% 28.89/28.90  tff(decl_2101, type, 'Acetyl-CoA': $i).
% 28.89/28.90  tff(decl_2102, type, 'Acetyl coenzyme A or acetyl-CoA is an important molecule in metabolism, used in many biochemical reactions. Its main function is to convey the carbon atoms within the acetyl group to the citric acid cycle to be oxidized for energy production. In chemical structure, acetyl-CoA is the thioester between coenzyme A (a thiol) and acetic acid (an acyl group carrier).': $i).
% 28.89/28.90  tff(decl_2103, type, 'acetyl coenzyme a': $i).
% 28.89/28.90  tff(decl_2104, type, 'acetyl-coenzyme-a': $i).
% 28.89/28.90  tff(decl_2105, type, 'acetyl coa': $i).
% 28.89/28.90  tff(decl_2106, type, 'acetyl-coa': $i).
% 28.89/28.90  tff(decl_2107, type, coenzyme_a_1: $i > $o).
% 28.89/28.90  tff(decl_2108, type, fadh2_1: $i > $o).
% 28.89/28.90  tff(decl_2109, type, nad_plus_1: $i > $o).
% 28.89/28.90  tff(decl_2110, type, nadh_1: $i > $o).
% 28.89/28.90  tff(decl_2111, type, nadp_plus_1: $i > $o).
% 28.89/28.90  tff(decl_2112, type, nadph_1: $i > $o).
% 28.89/28.90  tff(decl_2113, type, succinyl_coa_1: $i > $o).
% 28.89/28.90  tff(decl_2114, type, fn_acetyl_coa_1: $i > $i).
% 28.89/28.90  tff(decl_2115, type, fn_acetyl_coa_2: $i > $i).
% 28.89/28.90  tff(decl_2116, type, fn_acetyl_coa_6: $i > $i).
% 28.89/28.90  tff(decl_2117, type, fn_acetyl_coa_7: $i > $i).
% 28.89/28.90  tff(decl_2118, type, fn_acetyl_coa_8: $i > $i).
% 28.89/28.90  tff(decl_2119, type, fn_acetyl_coa_9: $i > $i).
% 28.89/28.90  tff(decl_2120, type, fn_acetyl_coa_10: $i > $i).
% 28.89/28.90  tff(decl_2121, type, hold_together_1: $i > $o).
% 28.89/28.90  tff(decl_2122, type, fn_acetyl_coa_11: $i > $i).
% 28.89/28.90  tff(decl_2123, type, fn_acetyl_coa_12: $i > $i).
% 28.89/28.90  tff(decl_2124, type, atomic_nucleus_1: $i > $o).
% 28.89/28.90  tff(decl_2125, type, fn_acetyl_coa_13: $i > $i).
% 28.89/28.90  tff(decl_2126, type, center_1: $i > $o).
% 28.89/28.90  tff(decl_2127, type, fn_acetyl_coa_14: $i > $i).
% 28.89/28.90  tff(decl_2128, type, fn_acetyl_coa_15: $i > $i).
% 28.89/28.90  tff(decl_2129, type, fn_acetyl_coa_16: $i > $i).
% 28.89/28.90  tff(decl_2130, type, fn_acetyl_coa_17: $i > $i).
% 28.89/28.90  tff(decl_2131, type, fn_acetyl_coa_18: $i > $i).
% 28.89/28.90  tff(decl_2132, type, ester_linkage_1: $i > $o).
% 28.89/28.90  tff(decl_2133, type, fn_acetyl_coa_19: $i > $i).
% 28.89/28.90  tff(decl_2134, type, fn_acetyl_coa_20: $i > $i).
% 28.89/28.90  tff(decl_2135, type, acetyl_group_1: $i > $o).
% 28.89/28.90  tff(decl_2136, type, fn_acetyl_coa_21: $i > $i).
% 28.89/28.90  tff(decl_2137, type, valence_electron_1: $i > $o).
% 28.89/28.90  tff(decl_2138, type, fn_acetyl_coa_22: $i > $i).
% 28.89/28.90  tff(decl_2139, type, fn_acetyl_coa_23: $i > $i).
% 28.89/28.90  tff(decl_2140, type, share_1: $i > $o).
% 28.89/28.90  tff(decl_2141, type, fn_acetyl_coa_24: $i > $i).
% 28.89/28.90  tff(decl_2142, type, unequal_sharing_1: $i > $o).
% 28.89/28.90  tff(decl_2143, type, fn_acetyl_coa_25: $i > $i).
% 28.89/28.90  tff(decl_2144, type, fn_acetyl_coa_26: $i > $i).
% 28.89/28.90  tff(decl_2145, type, fn_acetyl_coa_27: $i > $i).
% 28.89/28.90  tff(decl_2146, type, hold_1: $i > $o).
% 28.89/28.90  tff(decl_2147, type, fn_acetyl_coa_28: $i > $i).
% 28.89/28.90  tff(decl_2148, type, fn_acetyl_coa_29: $i > $i).
% 28.89/28.90  tff(decl_2149, type, fn_acetyl_coa_30: $i > $i).
% 28.89/28.90  tff(decl_2150, type, electron_shell_1: $i > $o).
% 28.89/28.90  tff(decl_2151, type, fn_acetyl_coa_31: $i > $i).
% 28.89/28.90  tff(decl_2152, type, fn_acetyl_coa_32: $i > $i).
% 28.89/28.90  tff(decl_2153, type, fn_acetyl_coa_33: $i > $i).
% 28.89/28.90  tff(decl_2154, type, carbonyl_group_1: $i > $o).
% 28.89/28.90  tff(decl_2155, type, fn_carboxyl_group_49: $i > $i).
% 28.89/28.90  tff(decl_2156, type, fn_carboxyl_group_46: $i > $i).
% 28.89/28.90  tff(decl_2157, type, fn_carboxyl_group_55: $i > $i).
% 28.89/28.90  tff(decl_2158, type, fn_acetyl_group_1: $i > $i).
% 28.89/28.90  tff(decl_2159, type, fn_carboxyl_group_45: $i > $i).
% 28.89/28.90  tff(decl_2160, type, fn_carboxyl_group_62: $i > $i).
% 28.89/28.90  tff(decl_2161, type, fn_carboxyl_group_21: $i > $i).
% 28.89/28.90  tff(decl_2162, type, fn_carboxyl_group_40: $i > $i).
% 28.89/28.90  tff(decl_2163, type, fn_covalent_bond_17: $i > $i).
% 28.89/28.90  tff(decl_2164, type, fn_ester_linkage_32: $i > $i).
% 28.89/28.90  tff(decl_2165, type, fn_carboxyl_group_66: $i > $i).
% 28.89/28.90  tff(decl_2166, type, fn_acetyl_group_6: $i > $i).
% 28.89/28.90  tff(decl_2167, type, fn_carboxyl_group_22: $i > $i).
% 28.89/28.90  tff(decl_2168, type, fn_ester_linkage_10: $i > $i).
% 28.89/28.90  tff(decl_2169, type, fn_carboxyl_group_63: $i > $i).
% 28.89/28.90  tff(decl_2170, type, fn_carboxyl_group_16: $i > $i).
% 28.89/28.90  tff(decl_2171, type, fn_acetyl_group_2: $i > $i).
% 28.89/28.90  tff(decl_2172, type, fn_acetyl_group_7: $i > $i).
% 28.89/28.90  tff(decl_2173, type, fn_carboxyl_group_20: $i > $i).
% 28.89/28.90  tff(decl_2174, type, fn_ester_linkage_44: $i > $i).
% 28.89/28.90  tff(decl_2175, type, fn_carboxyl_group_64: $i > $i).
% 28.89/28.90  tff(decl_2176, type, fn_carboxyl_group_18: $i > $i).
% 28.89/28.90  tff(decl_2177, type, fn_ester_linkage_19: $i > $i).
% 28.89/28.90  tff(decl_2178, type, fn_carboxyl_group_47: $i > $i).
% 28.89/28.90  tff(decl_2179, type, fn_carboxyl_group_67: $i > $i).
% 28.89/28.90  tff(decl_2180, type, fn_hold_2: $i > $i).
% 28.89/28.90  tff(decl_2181, type, fn_acetyl_group_3: $i > $i).
% 28.89/28.90  tff(decl_2182, type, fn_ester_linkage_28: $i > $i).
% 28.89/28.90  tff(decl_2183, type, fn_acetyl_group_5: $i > $i).
% 28.89/28.90  tff(decl_2184, type, fn_ester_linkage_27: $i > $i).
% 28.89/28.90  tff(decl_2185, type, fn_acetyl_group_4: $i > $i).
% 28.89/28.90  tff(decl_2186, type, "0": $i).
% 28.89/28.90  tff(decl_2187, type, fn_ester_9: $i > $i).
% 28.89/28.90  tff(decl_2188, type, fn_ester_10: $i > $i).
% 28.89/28.90  tff(decl_2189, type, fn_acetyl_coa_5: $i > $i).
% 28.89/28.90  tff(decl_2190, type, fn_ester_2: $i > $i).
% 28.89/28.90  tff(decl_2191, type, fn_acetyl_coa_4: $i > $i).
% 28.89/28.90  tff(decl_2192, type, fn_ester_1: $i > $i).
% 28.89/28.90  tff(decl_2193, type, fn_ester_8: $i > $i).
% 28.89/28.90  tff(decl_2194, type, fn_ester_15: $i > $i).
% 28.89/28.90  tff(decl_2195, type, fn_ester_14: $i > $i).
% 28.89/28.90  tff(decl_2196, type, fn_ester_3: $i > $i).
% 28.89/28.90  tff(decl_2197, type, fn_ester_6: $i > $i).
% 28.89/28.90  tff(decl_2198, type, fn_ester_5: $i > $i).
% 28.89/28.90  tff(decl_2199, type, fn_ester_4: $i > $i).
% 28.89/28.90  tff(decl_2200, type, fn_ester_7: $i > $i).
% 28.89/28.90  tff(decl_2201, type, fn_ester_13: $i > $i).
% 28.89/28.90  tff(decl_2202, type, fn_ester_12: $i > $i).
% 28.89/28.90  tff(decl_2203, type, 'Acetyl-Group': $i).
% 28.89/28.90  tff(decl_2204, type, 'A functional group comprised of a methyl group and carbon bound to a central oxygen atom.': $i).
% 28.89/28.90  tff(decl_2205, type, acetyl: $i).
% 28.89/28.90  tff(decl_2206, type, 'acetyl functional group': $i).
% 28.89/28.90  tff(decl_2207, type, 'group of acetyl': $i).
% 28.89/28.90  tff(decl_2208, type, 'acetyl group': $i).
% 28.89/28.90  tff(decl_2209, type, 'acetyl-group': $i).
% 28.89/28.90  tff(decl_2210, type, amino_group_1: $i > $o).
% 28.89/28.90  tff(decl_2211, type, hydroxyl_group_1: $i > $o).
% 28.89/28.90  tff(decl_2212, type, methyl_group_1: $i > $o).
% 28.89/28.90  tff(decl_2213, type, fn_acetyl_group_8: $i > $i).
% 28.89/28.90  tff(decl_2214, type, fn_acetyl_group_9: $i > $i).
% 28.89/28.90  tff(decl_2215, type, proton_1: $i > $o).
% 28.89/28.90  tff(decl_2216, type, fn_acetyl_group_10: $i > $i).
% 28.89/28.90  tff(decl_2217, type, fn_acetyl_group_11: $i > $i).
% 28.89/28.90  tff(decl_2218, type, fn_acetyl_group_12: $i > $i).
% 28.89/28.90  tff(decl_2219, type, fn_acetyl_group_13: $i > $i).
% 28.89/28.90  tff(decl_2220, type, fn_acetyl_group_14: $i > $i).
% 28.89/28.90  tff(decl_2221, type, fn_acetyl_group_15: $i > $i).
% 28.89/28.90  tff(decl_2222, type, fn_acetyl_group_16: $i > $i).
% 28.89/28.90  tff(decl_2223, type, fn_acetyl_group_17: $i > $i).
% 28.89/28.90  tff(decl_2224, type, fn_acetyl_group_18: $i > $i).
% 28.89/28.90  tff(decl_2225, type, fn_acetyl_group_19: $i > $i).
% 28.89/28.90  tff(decl_2226, type, fn_covalent_bond_4: $i > $i).
% 28.89/28.90  tff(decl_2227, type, fn_covalent_bond_14: $i > $i).
% 28.89/28.90  tff(decl_2228, type, fn_covalent_bond_12: $i > $i).
% 28.89/28.90  tff(decl_2229, type, fn_covalent_bond_11: $i > $i).
% 28.89/28.90  tff(decl_2230, type, fn_covalent_bond_21: $i > $i).
% 28.89/28.90  tff(decl_2231, type, fn_covalent_bond_23: $i > $i).
% 28.89/28.90  tff(decl_2232, type, fn_covalent_bond_24: $i > $i).
% 28.89/28.90  tff(decl_2233, type, fn_covalent_bond_22: $i > $i).
% 28.89/28.90  tff(decl_2234, type, fn_covalent_bond_15: $i > $i).
% 28.89/28.90  tff(decl_2235, type, fn_covalent_bond_18: $i > $i).
% 28.89/28.90  tff(decl_2236, type, acetylcholine_1: $i > $o).
% 28.89/28.90  tff(decl_2237, type, 'Acetylcholine': $i).
% 28.89/28.90  tff(decl_2238, type, 'One of the most common neurotransmitters of the peripheral and central nervous systems. It has an inhibitory effect on cardiac tissue and an excitatory effect on skeletal muscle.': $i).
% 28.89/28.90  tff(decl_2239, type, acetylcholine: $i).
% 28.89/28.90  tff(decl_2240, type, neurotransmitter_1: $i > $o).
% 28.89/28.90  tff(decl_2241, type, aspartic_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2242, type, catecholamine_1: $i > $o).
% 28.89/28.90  tff(decl_2243, type, neuropeptide_1: $i > $o).
% 28.89/28.90  tff(decl_2244, type, acetylcholinesterase_1: $i > $o).
% 28.89/28.90  tff(decl_2245, type, 'Acetylcholinesterase': $i).
% 28.89/28.90  tff(decl_2246, type, 'Acetylcholinesterase is a enzyme having serine residue at its active site and plays important role in nervous system.': $i).
% 28.89/28.90  tff(decl_2247, type, acetylcholinesterase: $i).
% 28.89/28.90  tff(decl_2248, type, hydrolase_1: $i > $o).
% 28.89/28.90  tff(decl_2249, type, fn_acetylcholinesterase_1: $i > $i).
% 28.89/28.90  tff(decl_2250, type, fn_acetylcholinesterase_2: $i > $i).
% 28.89/28.90  tff(decl_2251, type, monomer_1: $i > $o).
% 28.89/28.90  tff(decl_2252, type, amino_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2253, type, fn_acetylcholinesterase_3: $i > $i).
% 28.89/28.90  tff(decl_2254, type, fn_acetylcholinesterase_4: $i > $i).
% 28.89/28.90  tff(decl_2255, type, protein_domain_1: $i > $o).
% 28.89/28.90  tff(decl_2256, type, fn_acetylcholinesterase_5: $i > $i).
% 28.89/28.90  tff(decl_2257, type, r_group_1: $i > $o).
% 28.89/28.90  tff(decl_2258, type, fn_enzyme_2: $i > $i).
% 28.89/28.90  tff(decl_2259, type, fn_enzyme_4: $i > $i).
% 28.89/28.90  tff(decl_2260, type, fn_protein_enzyme_5: $i > $i).
% 28.89/28.90  tff(decl_2261, type, fn_protein_enzyme_11: $i > $i).
% 28.89/28.90  tff(decl_2262, type, fn_protein_enzyme_12: $i > $i).
% 28.89/28.90  tff(decl_2263, type, fn_protein_enzyme_10: $i > $i).
% 28.89/28.90  tff(decl_2264, type, achondroplasia_1: $i > $o).
% 28.89/28.90  tff(decl_2265, type, 'Achondroplasia': $i).
% 28.89/28.90  tff(decl_2266, type, 'A form of genetically determined dwarfism.': $i).
% 28.89/28.90  tff(decl_2267, type, dwarfism: $i).
% 28.89/28.90  tff(decl_2268, type, achondroplasia: $i).
% 28.89/28.90  tff(decl_2269, type, human_genetic_disorder_1: $i > $o).
% 28.89/28.90  tff(decl_2270, type, alkaptonuria_1: $i > $o).
% 28.89/28.90  tff(decl_2271, type, angelman_syndrome_1: $i > $o).
% 28.89/28.90  tff(decl_2272, type, cri_du_chat_syndrome_1: $i > $o).
% 28.89/28.90  tff(decl_2273, type, cystic_fibrosis_1: $i > $o).
% 28.89/28.90  tff(decl_2274, type, down_syndrome_1: $i > $o).
% 28.89/28.90  tff(decl_2275, type, huntingtons_disease_1: $i > $o).
% 28.89/28.90  tff(decl_2276, type, klinefelter_syndrome_1: $i > $o).
% 28.89/28.90  tff(decl_2277, type, multifactorial_genetic_disorder_1: $i > $o).
% 28.89/28.90  tff(decl_2278, type, phenylketonuria_1: $i > $o).
% 28.89/28.90  tff(decl_2279, type, polydactyly_1: $i > $o).
% 28.89/28.90  tff(decl_2280, type, prader_willi_syndrome_1: $i > $o).
% 28.89/28.90  tff(decl_2281, type, sex_linked_human_genetic_disorder_1: $i > $o).
% 28.89/28.90  tff(decl_2282, type, sickle_cell_anemia_1: $i > $o).
% 28.89/28.90  tff(decl_2283, type, tay_sachs_disease_1: $i > $o).
% 28.89/28.90  tff(decl_2284, type, triple_x_1: $i > $o).
% 28.89/28.90  tff(decl_2285, type, turner_syndrome_1: $i > $o).
% 28.89/28.90  tff(decl_2286, type, fn_achondroplasia_1: $i > $i).
% 28.89/28.90  tff(decl_2287, type, complete_dominance_1: $i > $o).
% 28.89/28.90  tff(decl_2288, type, fn_achondroplasia_2: $i > $i).
% 28.89/28.90  tff(decl_2289, type, dominant_allele_1: $i > $o).
% 28.89/28.90  tff(decl_2290, type, fn_inheritance_4: $i > $i).
% 28.89/28.90  tff(decl_2291, type, gene_1: $i > $o).
% 28.89/28.90  tff(decl_2292, type, fn_human_genetic_disorder_1: $i > $i).
% 28.89/28.90  tff(decl_2293, type, acid_1: $i > $o).
% 28.89/28.90  tff(decl_2294, type, 'Acid': $i).
% 28.89/28.90  tff(decl_2295, type, 'A chemical that is acidic.': $i).
% 28.89/28.90  tff(decl_2296, type, 'A substance that increases the hydrogen ion concentration of a solution.': $i).
% 28.89/28.90  tff(decl_2297, type, acid: $i).
% 28.89/28.90  tff(decl_2298, type, fn_acid_3: $i > $i).
% 28.89/28.90  tff(decl_2299, type, fn_acid_4: $i > $i).
% 28.89/28.90  tff(decl_2300, type, fn_acid_5: $i > $i).
% 28.89/28.90  tff(decl_2301, type, acid_compound_1: $i > $o).
% 28.89/28.90  tff(decl_2302, type, "7.0e0": $i).
% 28.89/28.90  tff(decl_2303, type, fn_chemical_3: $i > $i).
% 28.89/28.90  tff(decl_2304, type, acid_chyme_1: $i > $o).
% 28.89/28.90  tff(decl_2305, type, 'Acid-Chyme': $i).
% 28.89/28.90  tff(decl_2306, type, 'Chyme mixed with stomach acid as it enters the duodenum.': $i).
% 28.89/28.90  tff(decl_2307, type, 'chyme of acid': $i).
% 28.89/28.90  tff(decl_2308, type, 'acid chyme': $i).
% 28.89/28.90  tff(decl_2309, type, 'acid-chyme': $i).
% 28.89/28.90  tff(decl_2310, type, organic_entity_1: $i > $o).
% 28.89/28.90  tff(decl_2311, type, heterogeneous_mixture_1: $i > $o).
% 28.89/28.90  tff(decl_2312, type, suspension_1: $i > $o).
% 28.89/28.90  tff(decl_2313, type, detritus_1: $i > $o).
% 28.89/28.90  tff(decl_2314, type, feces_1: $i > $o).
% 28.89/28.90  tff(decl_2315, type, homogenate_1: $i > $o).
% 28.89/28.90  tff(decl_2316, type, homogeneous_mixture_1: $i > $o).
% 28.89/28.90  tff(decl_2317, type, loam_1: $i > $o).
% 28.89/28.90  tff(decl_2318, type, mesohyl_1: $i > $o).
% 28.89/28.90  tff(decl_2319, type, peat_1: $i > $o).
% 28.89/28.90  tff(decl_2320, type, protobiont_1: $i > $o).
% 28.89/28.90  tff(decl_2321, type, saliva_1: $i > $o).
% 28.89/28.90  tff(decl_2322, type, soil_1: $i > $o).
% 28.89/28.90  tff(decl_2323, type, topsoil_1: $i > $o).
% 28.89/28.90  tff(decl_2324, type, fn_acid_chyme_3: $i > $i).
% 28.89/28.90  tff(decl_2325, type, fn_acid_chyme_4: $i > $i).
% 28.89/28.90  tff(decl_2326, type, fn_acid_chyme_5: $i > $i).
% 28.89/28.90  tff(decl_2327, type, fn_acid_chyme_6: $i > $i).
% 28.89/28.90  tff(decl_2328, type, nutrient_1: $i > $o).
% 28.89/28.90  tff(decl_2329, type, fn_acid_chyme_7: $i > $i).
% 28.89/28.90  tff(decl_2330, type, fn_acid_chyme_8: $i > $i).
% 28.89/28.90  tff(decl_2331, type, gastric_juice_1: $i > $o).
% 28.89/28.90  tff(decl_2332, type, fn_acid_chyme_9: $i > $i).
% 28.89/28.90  tff(decl_2333, type, bolus_1: $i > $o).
% 28.89/28.90  tff(decl_2334, type, fn_acid_chyme_10: $i > $i).
% 28.89/28.90  tff(decl_2335, type, secretion_1: $i > $o).
% 28.89/28.90  tff(decl_2336, type, fn_acid_chyme_11: $i > $i).
% 28.89/28.90  tff(decl_2337, type, phospholipid_bilayer_1: $i > $o).
% 28.89/28.90  tff(decl_2338, type, fn_acid_chyme_12: $i > $i).
% 28.89/28.90  tff(decl_2339, type, membrane_protein_1: $i > $o).
% 28.89/28.90  tff(decl_2340, type, protein_1: $i > $o).
% 28.89/28.90  tff(decl_2341, type, polymer_1: $i > $o).
% 28.89/28.90  tff(decl_2342, type, fn_acid_chyme_13: $i > $i).
% 28.89/28.90  tff(decl_2343, type, transmembrane_protein_1: $i > $o).
% 28.89/28.90  tff(decl_2344, type, integral_protein_1: $i > $o).
% 28.89/28.90  tff(decl_2345, type, transport_protein_1: $i > $o).
% 28.89/28.90  tff(decl_2346, type, fn_acid_chyme_14: $i > $i).
% 28.89/28.90  tff(decl_2347, type, biomembrane_1: $i > $o).
% 28.89/28.90  tff(decl_2348, type, plasma_membrane_1: $i > $o).
% 28.89/28.90  tff(decl_2349, type, fn_acid_chyme_15: $i > $i).
% 28.89/28.90  tff(decl_2350, type, mixture_1: $i > $o).
% 28.89/28.90  tff(decl_2351, type, cytoplasm_1: $i > $o).
% 28.89/28.90  tff(decl_2352, type, fn_acid_chyme_16: $i > $i).
% 28.89/28.90  tff(decl_2353, type, nucleus_1: $i > $o).
% 28.89/28.90  tff(decl_2354, type, fn_acid_chyme_17: $i > $i).
% 28.89/28.90  tff(decl_2355, type, cell_1: $i > $o).
% 28.89/28.90  tff(decl_2356, type, animal_cell_1: $i > $o).
% 28.89/28.90  tff(decl_2357, type, eukaryotic_cell_1: $i > $o).
% 28.89/28.90  tff(decl_2358, type, fn_acid_chyme_18: $i > $i).
% 28.89/28.90  tff(decl_2359, type, gastric_gland_1: $i > $o).
% 28.89/28.90  tff(decl_2360, type, fn_acid_chyme_19: $i > $i).
% 28.89/28.90  tff(decl_2361, type, tissue_1: $i > $o).
% 28.89/28.90  tff(decl_2362, type, epithelium_1: $i > $o).
% 28.89/28.90  tff(decl_2363, type, fn_acid_chyme_20: $i > $i).
% 28.89/28.90  tff(decl_2364, type, stomach_1: $i > $o).
% 28.89/28.90  tff(decl_2365, type, fn_acid_chyme_21: $i > $i).
% 28.89/28.90  tff(decl_2366, type, secretor_1: $i > $o).
% 28.89/28.90  tff(decl_2367, type, fn_secretion_3: $i > $i).
% 28.89/28.90  tff(decl_2368, type, fn_eukaryotic_cell_31: $i > $i).
% 28.89/28.90  tff(decl_2369, type, fn_eukaryotic_cell_26: $i > $i).
% 28.89/28.90  tff(decl_2370, type, fn_eukaryotic_cell_29: $i > $i).
% 28.89/28.90  tff(decl_2371, type, fn_mixture_2: $i > $i).
% 28.89/28.90  tff(decl_2372, type, fn_mixture_1: $i > $i).
% 28.89/28.90  tff(decl_2373, type, fn_secretion_2: $i > $i).
% 28.89/28.90  tff(decl_2374, type, fn_stomach_19: $i > $i).
% 28.89/28.90  tff(decl_2375, type, fn_stomach_20: $i > $i).
% 28.89/28.90  tff(decl_2376, type, fn_stomach_8: $i > $i).
% 28.89/28.90  tff(decl_2377, type, fn_epithelium_98: $i > $i).
% 28.89/28.90  tff(decl_2378, type, fn_epithelium_83: $i > $i).
% 28.89/28.90  tff(decl_2379, type, fn_biomembrane_63: $i > $i).
% 28.89/28.90  tff(decl_2380, type, fn_plasma_membrane_71: $i > $i).
% 28.89/28.90  tff(decl_2381, type, fn_plasma_membrane_68: $i > $i).
% 28.89/28.90  tff(decl_2382, type, fn_plasma_membrane_4: $i > $i).
% 28.89/28.90  tff(decl_2383, type, fn_plasma_membrane_3: $i > $i).
% 28.89/28.90  tff(decl_2384, type, fn_plasma_membrane_54: $i > $i).
% 28.89/28.90  tff(decl_2385, type, fn_plasma_membrane_55: $i > $i).
% 28.89/28.90  tff(decl_2386, type, bolus_0: $i).
% 28.89/28.90  tff(decl_2387, type, 'MP2': $i).
% 28.89/28.90  tff(decl_2388, type, 'Acid-Compound': $i).
% 28.89/28.90  tff(decl_2389, type, 'A chemical entity that is acidic.': $i).
% 28.89/28.90  tff(decl_2390, type, 'compound of acid': $i).
% 28.89/28.90  tff(decl_2391, type, 'acid compound': $i).
% 28.89/28.90  tff(decl_2392, type, 'acid-compound': $i).
% 28.89/28.90  tff(decl_2393, type, compound_1: $i > $o).
% 28.89/28.90  tff(decl_2394, type, 'Acid-Dissociation-Reaction': $i).
% 28.89/28.90  tff(decl_2395, type, 'Dissociation reaction of an acid in a solution.': $i).
% 28.89/28.90  tff(decl_2396, type, convert: $i).
% 28.89/28.90  tff(decl_2397, type, 'acid dissociation reaction': $i).
% 28.89/28.90  tff(decl_2398, type, 'acid-dissociation-reaction': $i).
% 28.89/28.90  tff(decl_2399, type, reversible_reaction_1: $i > $o).
% 28.89/28.90  tff(decl_2400, type, chemical_dissociation_reaction_1: $i > $o).
% 28.89/28.90  tff(decl_2401, type, base_dissociation_reaction_1: $i > $o).
% 28.89/28.90  tff(decl_2402, type, fn_acid_dissociation_reaction_1: $i > $i).
% 28.89/28.90  tff(decl_2403, type, fn_acid_dissociation_reaction_5: $i > $i).
% 28.89/28.90  tff(decl_2404, type, chemical_energy_1: $i > $o).
% 28.89/28.90  tff(decl_2405, type, fn_acid_dissociation_reaction_6: $i > $i).
% 28.89/28.90  tff(decl_2406, type, fn_acid_dissociation_reaction_7: $i > $i).
% 28.89/28.90  tff(decl_2407, type, fn_acid_dissociation_reaction_8: $i > $i).
% 28.89/28.90  tff(decl_2408, type, fn_acid_dissociation_reaction_9: $i > $i).
% 28.89/28.90  tff(decl_2409, type, anion_1: $i > $o).
% 28.89/28.90  tff(decl_2410, type, fn_acid_dissociation_reaction_10: $i > $i).
% 28.89/28.90  tff(decl_2411, type, fn_acid_dissociation_reaction_11: $i > $i).
% 28.89/28.90  tff(decl_2412, type, fn_acid_dissociation_reaction_12: $i > $i).
% 28.89/28.90  tff(decl_2413, type, fn_acid_dissociation_reaction_13: $i > $i).
% 28.89/28.90  tff(decl_2414, type, acidic_solution_1: $i > $o).
% 28.89/28.90  tff(decl_2415, type, fn_acid_dissociation_reaction_14: $i > $i).
% 28.89/28.90  tff(decl_2416, type, water_1: $i > $o).
% 28.89/28.90  tff(decl_2417, type, fn_acid_dissociation_reaction_15: $i > $i).
% 28.89/28.90  tff(decl_2418, type, fn_acid_dissociation_reaction_16: $i > $i).
% 28.89/28.90  tff(decl_2419, type, hydrogen_ion_1: $i > $o).
% 28.89/28.90  tff(decl_2420, type, fn_acid_dissociation_reaction_17: $i > $i).
% 28.89/28.90  tff(decl_2421, type, reverse_reaction_1: $i > $o).
% 28.89/28.90  tff(decl_2422, type, fn_acid_dissociation_reaction_18: $i > $i).
% 28.89/28.90  tff(decl_2423, type, forward_reaction_1: $i > $o).
% 28.89/28.90  tff(decl_2424, type, fn_acidic_solution_32: $i > $i).
% 28.89/28.90  tff(decl_2425, type, fn_acidic_solution_31: $i > $i).
% 28.89/28.90  tff(decl_2426, type, fn_acidic_solution_21: $i > $i).
% 28.89/28.90  tff(decl_2427, type, fn_aqueous_solution_14: $i > $i).
% 28.89/28.90  tff(decl_2428, type, fn_acidic_solution_18: $i > $i).
% 28.89/28.90  tff(decl_2429, type, fn_dissolve_5: $i > $i).
% 28.89/28.90  tff(decl_2430, type, fn_acidic_solution_15: $i > $i).
% 28.89/28.90  tff(decl_2431, type, fn_acidic_solution_19: $i > $i).
% 28.89/28.90  tff(decl_2432, type, fn_reversible_reaction_7: $i > $i).
% 28.89/28.90  tff(decl_2433, type, fn_reversible_reaction_6: $i > $i).
% 28.89/28.90  tff(decl_2434, type, fn_acid_dissociation_reaction_4: $i > $i).
% 28.89/28.90  tff(decl_2435, type, fn_exergonic_reaction_2: $i > $i).
% 28.89/28.90  tff(decl_2436, type, fn_exergonic_reaction_6: $i > $i).
% 28.89/28.90  tff(decl_2437, type, fn_acid_dissociation_reaction_3: $i > $i).
% 28.89/28.90  tff(decl_2438, type, fn_exergonic_reaction_1: $i > $i).
% 28.89/28.90  tff(decl_2439, type, fn_exergonic_reaction_5: $i > $i).
% 28.89/28.90  tff(decl_2440, type, fn_exergonic_reaction_4: $i > $i).
% 28.89/28.90  tff(decl_2441, type, fn_exergonic_reaction_3: $i > $i).
% 28.89/28.90  tff(decl_2442, type, fn_reversible_reaction_5: $i > $i).
% 28.89/28.90  tff(decl_2443, type, fn_exergonic_reaction_10: $i > $i).
% 28.89/28.90  tff(decl_2444, type, fn_exergonic_reaction_11: $i > $i).
% 28.89/28.90  tff(decl_2445, type, acid_precipitation_1: $i > $o).
% 28.89/28.90  tff(decl_2446, type, 'Acid-Precipitation': $i).
% 28.89/28.90  tff(decl_2447, type, 'Acid precipitation refers to rain, snow, or fog with a pH lower (more acidic) than 5.2.': $i).
% 28.89/28.90  tff(decl_2448, type, 'acid rain': $i).
% 28.89/28.90  tff(decl_2449, type, 'acid-rain': $i).
% 28.89/28.90  tff(decl_2450, type, fall: $i).
% 28.89/28.90  tff(decl_2451, type, 'precipitation of acid': $i).
% 28.89/28.90  tff(decl_2452, type, 'acid precipitation': $i).
% 28.89/28.90  tff(decl_2453, type, 'acid-precipitation': $i).
% 28.89/28.90  tff(decl_2454, type, precipitation_1: $i > $o).
% 28.89/28.90  tff(decl_2455, type, human_driven_disturbance_1: $i > $o).
% 28.89/28.90  tff(decl_2456, type, red_tide_1: $i > $o).
% 28.89/28.90  tff(decl_2457, type, fn_acid_precipitation_1: $i > $i).
% 28.89/28.90  tff(decl_2458, type, fn_acid_precipitation_4: $i > $i).
% 28.89/28.90  tff(decl_2459, type, change_1: $i > $o).
% 28.89/28.90  tff(decl_2460, type, fn_acid_precipitation_5: $i > $i).
% 28.89/28.90  tff(decl_2461, type, nitric_oxide_1: $i > $o).
% 28.89/28.90  tff(decl_2462, type, fn_acid_precipitation_6: $i > $i).
% 28.89/28.90  tff(decl_2463, type, carbon_dioxide_1: $i > $o).
% 28.89/28.90  tff(decl_2464, type, fn_acid_precipitation_7: $i > $i).
% 28.89/28.90  tff(decl_2465, type, fn_acid_precipitation_8: $i > $i).
% 28.89/28.90  tff(decl_2466, type, fn_acid_precipitation_9: $i > $i).
% 28.89/28.90  tff(decl_2467, type, lake_1: $i > $o).
% 28.89/28.90  tff(decl_2468, type, fn_acid_precipitation_10: $i > $i).
% 28.89/28.90  tff(decl_2469, type, fn_acid_precipitation_11: $i > $i).
% 28.89/28.90  tff(decl_2470, type, fn_acid_precipitation_12: $i > $i).
% 28.89/28.90  tff(decl_2471, type, plant_1: $i > $o).
% 28.89/28.90  tff(decl_2472, type, fn_acid_precipitation_13: $i > $i).
% 28.89/28.90  tff(decl_2473, type, fn_acid_precipitation_14: $i > $i).
% 28.89/28.90  tff(decl_2474, type, algae_1: $i > $o).
% 28.89/28.90  tff(decl_2475, type, fn_acid_precipitation_15: $i > $i).
% 28.89/28.90  tff(decl_2476, type, cyanobacterium_1: $i > $o).
% 28.89/28.90  tff(decl_2477, type, fn_acid_precipitation_16: $i > $i).
% 28.89/28.90  tff(decl_2478, type, fn_acid_precipitation_17: $i > $i).
% 28.89/28.90  tff(decl_2479, type, fn_acid_precipitation_18: $i > $i).
% 28.89/28.90  tff(decl_2480, type, damage_1: $i > $o).
% 28.89/28.90  tff(decl_2481, type, fn_acid_precipitation_19: $i > $i).
% 28.89/28.90  tff(decl_2482, type, fn_acid_precipitation_20: $i > $i).
% 28.89/28.90  tff(decl_2483, type, fn_acid_precipitation_21: $i > $i).
% 28.89/28.90  tff(decl_2484, type, freshwater_biome_1: $i > $o).
% 28.89/28.90  tff(decl_2485, type, fn_acid_precipitation_22: $i > $i).
% 28.89/28.90  tff(decl_2486, type, fn_acid_precipitation_23: $i > $i).
% 28.89/28.90  tff(decl_2487, type, precipitation_form_1: $i > $o).
% 28.89/28.90  tff(decl_2488, type, fn_acid_precipitation_24: $i > $i).
% 28.89/28.90  tff(decl_2489, type, sulfuric_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2490, type, fn_acid_precipitation_25: $i > $i).
% 28.89/28.90  tff(decl_2491, type, fn_acid_precipitation_26: $i > $i).
% 28.89/28.90  tff(decl_2492, type, collide_1: $i > $o).
% 28.89/28.90  tff(decl_2493, type, fn_acid_precipitation_27: $i > $i).
% 28.89/28.90  tff(decl_2494, type, carbonic_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2495, type, fn_acid_precipitation_28: $i > $i).
% 28.89/28.90  tff(decl_2496, type, fn_acid_precipitation_29: $i > $i).
% 28.89/28.90  tff(decl_2497, type, fossil_fuel_1: $i > $o).
% 28.89/28.90  tff(decl_2498, type, fn_acid_precipitation_30: $i > $i).
% 28.89/28.90  tff(decl_2499, type, combustion_of_fossil_fuel_1: $i > $o).
% 28.89/28.90  tff(decl_2500, type, fn_acid_precipitation_31: $i > $i).
% 28.89/28.90  tff(decl_2501, type, hydrocarbon_molecule_1: $i > $o).
% 28.89/28.90  tff(decl_2502, type, fn_acid_precipitation_32: $i > $i).
% 28.89/28.90  tff(decl_2503, type, carbonic_acid_compound_1: $i > $o).
% 28.89/28.90  tff(decl_2504, type, fn_acid_precipitation_33: $i > $i).
% 28.89/28.90  tff(decl_2505, type, fn_acid_precipitation_34: $i > $i).
% 28.89/28.90  tff(decl_2506, type, nitric_acid_compound_1: $i > $o).
% 28.89/28.90  tff(decl_2507, type, fn_acid_precipitation_35: $i > $i).
% 28.89/28.90  tff(decl_2508, type, fn_acid_precipitation_36: $i > $i).
% 28.89/28.90  tff(decl_2509, type, fn_acid_precipitation_37: $i > $i).
% 28.89/28.90  tff(decl_2510, type, sulfur_dioxide_1: $i > $o).
% 28.89/28.90  tff(decl_2511, type, fn_acid_precipitation_38: $i > $i).
% 28.89/28.90  tff(decl_2512, type, sulfuric_acid_compound_1: $i > $o).
% 28.89/28.90  tff(decl_2513, type, fn_acid_precipitation_39: $i > $i).
% 28.89/28.90  tff(decl_2514, type, fn_acid_precipitation_40: $i > $i).
% 28.89/28.90  tff(decl_2515, type, water_molecule_1: $i > $o).
% 28.89/28.90  tff(decl_2516, type, fn_acid_precipitation_41: $i > $i).
% 28.89/28.90  tff(decl_2517, type, fn_acid_precipitation_42: $i > $i).
% 28.89/28.90  tff(decl_2518, type, fn_acid_precipitation_43: $i > $i).
% 28.89/28.90  tff(decl_2519, type, water_vapor_1: $i > $o).
% 28.89/28.90  tff(decl_2520, type, fn_acid_precipitation_44: $i > $i).
% 28.89/28.90  tff(decl_2521, type, fn_acid_precipitation_45: $i > $i).
% 28.89/28.90  tff(decl_2522, type, condense_1: $i > $o).
% 28.89/28.90  tff(decl_2523, type, fn_acid_precipitation_46: $i > $i).
% 28.89/28.90  tff(decl_2524, type, terrestrial_plant_1: $i > $o).
% 28.89/28.90  tff(decl_2525, type, fn_acid_precipitation_47: $i > $i).
% 28.89/28.90  tff(decl_2526, type, fn_acid_precipitation_48: $i > $i).
% 28.89/28.90  tff(decl_2527, type, fn_acid_precipitation_49: $i > $i).
% 28.89/28.90  tff(decl_2528, type, combustion_reaction_1: $i > $o).
% 28.89/28.90  tff(decl_2529, type, fn_acid_precipitation_50: $i > $i).
% 28.89/28.90  tff(decl_2530, type, fn_acid_precipitation_51: $i > $i).
% 28.89/28.90  tff(decl_2531, type, fn_acid_precipitation_52: $i > $i).
% 28.89/28.90  tff(decl_2532, type, nitric_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2533, type, fn_acid_precipitation_53: $i > $i).
% 28.89/28.90  tff(decl_2534, type, fn_acid_precipitation_54: $i > $i).
% 28.89/28.90  tff(decl_2535, type, fn_acid_precipitation_55: $i > $i).
% 28.89/28.90  tff(decl_2536, type, fn_acid_precipitation_56: $i > $i).
% 28.89/28.90  tff(decl_2537, type, fn_acid_precipitation_57: $i > $i).
% 28.89/28.90  tff(decl_2538, type, fn_acid_precipitation_58: $i > $i).
% 28.89/28.90  tff(decl_2539, type, fn_acid_precipitation_59: $i > $i).
% 28.89/28.90  tff(decl_2540, type, fn_acid_precipitation_60: $i > $i).
% 28.89/28.90  tff(decl_2541, type, fn_acid_precipitation_61: $i > $i).
% 28.89/28.90  tff(decl_2542, type, reducing_agent_1: $i > $o).
% 28.89/28.90  tff(decl_2543, type, fn_acid_precipitation_62: $i > $i).
% 28.89/28.90  tff(decl_2544, type, electron_donor_1: $i > $o).
% 28.89/28.90  tff(decl_2545, type, fn_acid_precipitation_63: $i > $i).
% 28.89/28.90  tff(decl_2546, type, fn_acid_precipitation_64: $i > $i).
% 28.89/28.90  tff(decl_2547, type, reduction_1: $i > $o).
% 28.89/28.90  tff(decl_2548, type, fn_acid_precipitation_65: $i > $i).
% 28.89/28.90  tff(decl_2549, type, oxidation_1: $i > $o).
% 28.89/28.90  tff(decl_2550, type, fn_acid_precipitation_66: $i > $i).
% 28.89/28.90  tff(decl_2551, type, oxygen_molecule_1: $i > $o).
% 28.89/28.90  tff(decl_2552, type, fn_impair_1: $i > $i).
% 28.89/28.90  tff(decl_2553, type, fn_chemical_reaction_2: $i > $i).
% 28.89/28.90  tff(decl_2554, type, fn_chemical_reaction_1: $i > $i).
% 28.89/28.90  tff(decl_2555, type, fn_dissolve_4: $i > $i).
% 28.89/28.90  tff(decl_2556, type, fn_reduction_5: $i > $i).
% 28.89/28.90  tff(decl_2557, type, fn_biome_2: $i > $i).
% 28.89/28.90  tff(decl_2558, type, fn_biome_1: $i > $i).
% 28.89/28.90  tff(decl_2559, type, fn_biome_4: $i > $i).
% 28.89/28.90  tff(decl_2560, type, fn_biome_3: $i > $i).
% 28.89/28.90  tff(decl_2561, type, fn_oxidation_8: $i > $i).
% 28.89/28.90  tff(decl_2562, type, fn_combustion_of_fossil_fuel_14: $i > $i).
% 28.89/28.90  tff(decl_2563, type, fn_combustion_of_fossil_fuel_4: $i > $i).
% 28.89/28.90  tff(decl_2564, type, fn_combustion_of_fossil_fuel_16: $i > $i).
% 28.89/28.90  tff(decl_2565, type, fn_combustion_of_fossil_fuel_15: $i > $i).
% 28.89/28.90  tff(decl_2566, type, fn_redox_reaction_12: $i > $i).
% 28.89/28.90  tff(decl_2567, type, fn_redox_reaction_16: $i > $i).
% 28.89/28.90  tff(decl_2568, type, fn_fossil_fuel_2: $i > $i).
% 28.89/28.90  tff(decl_2569, type, fn_water_vapor_1: $i > $i).
% 28.89/28.90  tff(decl_2570, type, fn_sulfuric_acid_1: $i > $i).
% 28.89/28.90  tff(decl_2571, type, fn_make_contact_1: $i > $i).
% 28.89/28.90  tff(decl_2572, type, fn_weak_acid_7: $i > $i).
% 28.89/28.90  tff(decl_2573, type, fn_make_contact_2: $i > $i).
% 28.89/28.90  tff(decl_2574, type, fn_carbonic_acid_2: $i > $i).
% 28.89/28.90  tff(decl_2575, type, fn_weak_acid_3: $i > $i).
% 28.89/28.90  tff(decl_2576, type, fn_combustion_of_fossil_fuel_1: $i > $i).
% 28.89/28.90  tff(decl_2577, type, fn_combustion_of_fossil_fuel_2: $i > $i).
% 28.89/28.90  tff(decl_2578, type, fn_reduction_4: $i > $i).
% 28.89/28.90  tff(decl_2579, type, fn_oxidation_9: $i > $i).
% 28.89/28.90  tff(decl_2580, type, fn_redox_reaction_7: $i > $i).
% 28.89/28.90  tff(decl_2581, type, fn_combustion_of_fossil_fuel_11: $i > $i).
% 28.89/28.90  tff(decl_2582, type, fn_reduction_1: $i > $i).
% 28.89/28.90  tff(decl_2583, type, fn_oxidation_10: $i > $i).
% 28.89/28.90  tff(decl_2584, type, fn_combustion_of_fossil_fuel_10: $i > $i).
% 28.89/28.90  tff(decl_2585, type, fn_reduction_3: $i > $i).
% 28.89/28.90  tff(decl_2586, type, fn_oxidation_7: $i > $i).
% 28.89/28.90  tff(decl_2587, type, fn_combustion_of_fossil_fuel_9: $i > $i).
% 28.89/28.90  tff(decl_2588, type, 'WM2': $i).
% 28.89/28.90  tff(decl_2589, type, 'WM3': $i).
% 28.89/28.90  tff(decl_2590, type, 'WM1': $i).
% 28.89/28.90  tff(decl_2591, type, "5.2e0": $i).
% 28.89/28.90  tff(decl_2592, type, '*strong': $i).
% 28.89/28.90  tff(decl_2593, type, fn_precipitation_5: $i > $i).
% 28.89/28.90  tff(decl_2594, type, fn_precipitation_4: $i > $i).
% 28.89/28.90  tff(decl_2595, type, fn_precipitation_3: $i > $i).
% 28.89/28.90  tff(decl_2596, type, fn_precipitation_6: $i > $i).
% 28.89/28.90  tff(decl_2597, type, fn_precipitation_7: $i > $i).
% 28.89/28.90  tff(decl_2598, type, acid_reflux_1: $i > $o).
% 28.89/28.90  tff(decl_2599, type, 'Acid-Reflux': $i).
% 28.89/28.90  tff(decl_2600, type, 'Potentially painful condition in which acid chyme from the stomach backflows into the lower end of the esophagus.': $i).
% 28.89/28.90  tff(decl_2601, type, 'reflux of acid': $i).
% 28.89/28.90  tff(decl_2602, type, 'acid reflux': $i).
% 28.89/28.90  tff(decl_2603, type, 'acid-reflux': $i).
% 28.89/28.90  tff(decl_2604, type, fn_acid_reflux_2: $i > $i).
% 28.89/28.90  tff(decl_2605, type, fn_acid_reflux_3: $i > $i).
% 28.89/28.90  tff(decl_2606, type, fn_acid_reflux_4: $i > $i).
% 28.89/28.90  tff(decl_2607, type, fn_acid_reflux_5: $i > $i).
% 28.89/28.90  tff(decl_2608, type, esophagus_1: $i > $o).
% 28.89/28.90  tff(decl_2609, type, move_0: $i).
% 28.89/28.90  tff(decl_2610, type, 'Acid-Role': $i).
% 28.89/28.90  tff(decl_2611, type, 'role of acid': $i).
% 28.89/28.90  tff(decl_2612, type, 'acid role': $i).
% 28.89/28.90  tff(decl_2613, type, 'acid-role': $i).
% 28.89/28.90  tff(decl_2614, type, acidic_amino_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2615, type, 'Acidic-Amino-Acid': $i).
% 28.89/28.90  tff(decl_2616, type, 'Amino acids which carry an overall negative charge due to the presence of negatively charged side chain.': $i).
% 28.89/28.90  tff(decl_2617, type, 'negatively charged amino acid': $i).
% 28.89/28.90  tff(decl_2618, type, 'negatively-charged-amino-acid': $i).
% 28.89/28.90  tff(decl_2619, type, 'acidic amino acid': $i).
% 28.89/28.90  tff(decl_2620, type, 'acidic-amino-acid': $i).
% 28.89/28.90  tff(decl_2621, type, electrically_charged_amino_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2622, type, fn_acidic_amino_acid_1: $i > $i).
% 28.89/28.90  tff(decl_2623, type, negatively_charged_region_1: $i > $o).
% 28.89/28.90  tff(decl_2624, type, fn_acidic_amino_acid_2: $i > $i).
% 28.89/28.90  tff(decl_2625, type, fn_acidic_amino_acid_6: $i > $i).
% 28.89/28.90  tff(decl_2626, type, fn_acidic_amino_acid_7: $i > $i).
% 28.89/28.90  tff(decl_2627, type, end_1: $i > $o).
% 28.89/28.90  tff(decl_2628, type, fn_acidic_amino_acid_8: $i > $i).
% 28.89/28.90  tff(decl_2629, type, fn_acidic_amino_acid_9: $i > $i).
% 28.89/28.90  tff(decl_2630, type, fn_acidic_amino_acid_10: $i > $i).
% 28.89/28.90  tff(decl_2631, type, fn_acidic_amino_acid_11: $i > $i).
% 28.89/28.90  tff(decl_2632, type, fn_acidic_amino_acid_12: $i > $i).
% 28.89/28.90  tff(decl_2633, type, fn_acidic_amino_acid_13: $i > $i).
% 28.89/28.90  tff(decl_2634, type, fn_acidic_amino_acid_14: $i > $i).
% 28.89/28.90  tff(decl_2635, type, fn_acidic_amino_acid_15: $i > $i).
% 28.89/28.90  tff(decl_2636, type, fn_acidic_amino_acid_16: $i > $i).
% 28.89/28.90  tff(decl_2637, type, fn_acidic_amino_acid_17: $i > $i).
% 28.89/28.90  tff(decl_2638, type, fn_acidic_amino_acid_18: $i > $i).
% 28.89/28.90  tff(decl_2639, type, fn_acidic_amino_acid_19: $i > $i).
% 28.89/28.90  tff(decl_2640, type, fn_acidic_amino_acid_20: $i > $i).
% 28.89/28.90  tff(decl_2641, type, fn_acidic_amino_acid_21: $i > $i).
% 28.89/28.90  tff(decl_2642, type, fn_acidic_amino_acid_22: $i > $i).
% 28.89/28.90  tff(decl_2643, type, fn_acidic_amino_acid_23: $i > $i).
% 28.89/28.90  tff(decl_2644, type, fn_acidic_amino_acid_24: $i > $i).
% 28.89/28.90  tff(decl_2645, type, fn_acidic_amino_acid_25: $i > $i).
% 28.89/28.90  tff(decl_2646, type, fn_acidic_amino_acid_26: $i > $i).
% 28.89/28.90  tff(decl_2647, type, fn_acidic_amino_acid_27: $i > $i).
% 28.89/28.90  tff(decl_2648, type, fn_acidic_amino_acid_28: $i > $i).
% 28.89/28.90  tff(decl_2649, type, fn_acidic_amino_acid_29: $i > $i).
% 28.89/28.90  tff(decl_2650, type, fn_acidic_amino_acid_30: $i > $i).
% 28.89/28.90  tff(decl_2651, type, fn_acidic_amino_acid_31: $i > $i).
% 28.89/28.90  tff(decl_2652, type, fn_acidic_amino_acid_32: $i > $i).
% 28.89/28.90  tff(decl_2653, type, fn_acidic_amino_acid_33: $i > $i).
% 28.89/28.90  tff(decl_2654, type, fn_acidic_amino_acid_34: $i > $i).
% 28.89/28.90  tff(decl_2655, type, fn_acidic_amino_acid_35: $i > $i).
% 28.89/28.90  tff(decl_2656, type, fn_acidic_amino_acid_36: $i > $i).
% 28.89/28.90  tff(decl_2657, type, fn_acidic_amino_acid_37: $i > $i).
% 28.89/28.90  tff(decl_2658, type, fn_acidic_amino_acid_38: $i > $i).
% 28.89/28.90  tff(decl_2659, type, fn_acidic_amino_acid_39: $i > $i).
% 28.89/28.90  tff(decl_2660, type, fn_acidic_amino_acid_40: $i > $i).
% 28.89/28.90  tff(decl_2661, type, fn_acidic_amino_acid_41: $i > $i).
% 28.89/28.90  tff(decl_2662, type, polar_side_chain_1: $i > $o).
% 28.89/28.90  tff(decl_2663, type, fn_acidic_amino_acid_42: $i > $i).
% 28.89/28.90  tff(decl_2664, type, fn_acidic_amino_acid_43: $i > $i).
% 28.89/28.90  tff(decl_2665, type, fn_acidic_amino_acid_44: $i > $i).
% 28.89/28.90  tff(decl_2666, type, fn_acidic_amino_acid_45: $i > $i).
% 28.89/28.90  tff(decl_2667, type, fn_acidic_amino_acid_46: $i > $i).
% 28.89/28.90  tff(decl_2668, type, nitrogen_1: $i > $o).
% 28.89/28.90  tff(decl_2669, type, fn_acidic_amino_acid_47: $i > $i).
% 28.89/28.90  tff(decl_2670, type, fn_acidic_amino_acid_48: $i > $i).
% 28.89/28.90  tff(decl_2671, type, fn_acidic_amino_acid_49: $i > $i).
% 28.89/28.90  tff(decl_2672, type, fn_acidic_amino_acid_50: $i > $i).
% 28.89/28.90  tff(decl_2673, type, fn_acidic_amino_acid_51: $i > $i).
% 28.89/28.90  tff(decl_2674, type, fn_acidic_amino_acid_52: $i > $i).
% 28.89/28.90  tff(decl_2675, type, fn_acidic_amino_acid_53: $i > $i).
% 28.89/28.90  tff(decl_2676, type, fn_acidic_amino_acid_54: $i > $i).
% 28.89/28.90  tff(decl_2677, type, fn_acidic_amino_acid_55: $i > $i).
% 28.89/28.90  tff(decl_2678, type, fn_acidic_amino_acid_56: $i > $i).
% 28.89/28.90  tff(decl_2679, type, fn_acidic_amino_acid_57: $i > $i).
% 28.89/28.90  tff(decl_2680, type, fn_acidic_amino_acid_58: $i > $i).
% 28.89/28.90  tff(decl_2681, type, fn_acidic_amino_acid_59: $i > $i).
% 28.89/28.90  tff(decl_2682, type, fn_acidic_amino_acid_60: $i > $i).
% 28.89/28.90  tff(decl_2683, type, fn_acidic_amino_acid_61: $i > $i).
% 28.89/28.90  tff(decl_2684, type, fn_acidic_amino_acid_62: $i > $i).
% 28.89/28.90  tff(decl_2685, type, fn_acidic_amino_acid_63: $i > $i).
% 28.89/28.90  tff(decl_2686, type, fn_acidic_amino_acid_64: $i > $i).
% 28.89/28.90  tff(decl_2687, type, fn_acidic_amino_acid_65: $i > $i).
% 28.89/28.90  tff(decl_2688, type, fn_acidic_amino_acid_66: $i > $i).
% 28.89/28.90  tff(decl_2689, type, fn_acidic_amino_acid_67: $i > $i).
% 28.89/28.90  tff(decl_2690, type, fn_acidic_amino_acid_68: $i > $i).
% 28.89/28.90  tff(decl_2691, type, fn_acidic_amino_acid_69: $i > $i).
% 28.89/28.90  tff(decl_2692, type, fn_acidic_amino_acid_70: $i > $i).
% 28.89/28.90  tff(decl_2693, type, fn_acidic_amino_acid_71: $i > $i).
% 28.89/28.90  tff(decl_2694, type, fn_acidic_amino_acid_72: $i > $i).
% 28.89/28.90  tff(decl_2695, type, fn_acidic_amino_acid_73: $i > $i).
% 28.89/28.90  tff(decl_2696, type, fn_acidic_amino_acid_74: $i > $i).
% 28.89/28.90  tff(decl_2697, type, fn_share_2: $i > $i).
% 28.89/28.90  tff(decl_2698, type, fn_atom_9: $i > $i).
% 28.89/28.90  tff(decl_2699, type, fn_share_3: $i > $i).
% 28.89/28.90  tff(decl_2700, type, fn_share_1: $i > $i).
% 28.89/28.90  tff(decl_2701, type, carboxyl_group_0: $i).
% 28.89/28.90  tff(decl_2702, type, fn_hydrophilic_amino_acid_24: $i > $i).
% 28.89/28.90  tff(decl_2703, type, fn_acidic_amino_acid_5: $i > $i).
% 28.89/28.90  tff(decl_2704, type, fn_molecule_6: $i > $i).
% 28.89/28.90  tff(decl_2705, type, fn_molecule_5: $i > $i).
% 28.89/28.90  tff(decl_2706, type, fn_acidic_amino_acid_3: $i > $i).
% 28.89/28.90  tff(decl_2707, type, fn_amino_acid_4: $i > $i).
% 28.89/28.90  tff(decl_2708, type, fn_acidic_amino_acid_4: $i > $i).
% 28.89/28.90  tff(decl_2709, type, fn_amino_acid_3: $i > $i).
% 28.89/28.90  tff(decl_2710, type, fn_amino_acid_5: $i > $i).
% 28.89/28.90  tff(decl_2711, type, fn_amino_acid_6: $i > $i).
% 28.89/28.90  tff(decl_2712, type, fn_amino_acid_7: $i > $i).
% 28.89/28.90  tff(decl_2713, type, fn_amino_acid_16: $i > $i).
% 28.89/28.90  tff(decl_2714, type, fn_hydrophilic_amino_acid_17: $i > $i).
% 28.89/28.90  tff(decl_2715, type, fn_hydrophilic_amino_acid_10: $i > $i).
% 28.89/28.90  tff(decl_2716, type, fn_hydrophilic_amino_acid_23: $i > $i).
% 28.89/28.90  tff(decl_2717, type, fn_hydrophilic_amino_acid_19: $i > $i).
% 28.89/28.90  tff(decl_2718, type, fn_hydrophilic_amino_acid_22: $i > $i).
% 28.89/28.90  tff(decl_2719, type, fn_hydrophilic_amino_acid_6: $i > $i).
% 28.89/28.90  tff(decl_2720, type, fn_hydrophilic_amino_acid_5: $i > $i).
% 28.89/28.90  tff(decl_2721, type, fn_hydrophilic_amino_acid_18: $i > $i).
% 28.89/28.90  tff(decl_2722, type, fn_hydrophilic_amino_acid_1: $i > $i).
% 28.89/28.90  tff(decl_2723, type, fn_hydrophilic_amino_acid_4: $i > $i).
% 28.89/28.90  tff(decl_2724, type, fn_hydrophilic_amino_acid_16: $i > $i).
% 28.89/28.90  tff(decl_2725, type, fn_hydrophilic_amino_acid_30: $i > $i).
% 28.89/28.90  tff(decl_2726, type, fn_hydrophilic_amino_acid_3: $i > $i).
% 28.89/28.90  tff(decl_2727, type, fn_hydrophilic_amino_acid_15: $i > $i).
% 28.89/28.90  tff(decl_2728, type, fn_hydrophilic_amino_acid_31: $i > $i).
% 28.89/28.90  tff(decl_2729, type, fn_hydrophilic_amino_acid_32: $i > $i).
% 28.89/28.90  tff(decl_2730, type, fn_hydrophilic_amino_acid_7: $i > $i).
% 28.89/28.90  tff(decl_2731, type, fn_hydrophilic_amino_acid_14: $i > $i).
% 28.89/28.90  tff(decl_2732, type, fn_hydrophilic_amino_acid_2: $i > $i).
% 28.89/28.90  tff(decl_2733, type, fn_hydrophilic_amino_acid_33: $i > $i).
% 28.89/28.90  tff(decl_2734, type, fn_hydrophilic_amino_acid_28: $i > $i).
% 28.89/28.90  tff(decl_2735, type, fn_hydrophilic_amino_acid_13: $i > $i).
% 28.89/28.90  tff(decl_2736, type, fn_hydrophilic_amino_acid_9: $i > $i).
% 28.89/28.90  tff(decl_2737, type, fn_hydrophilic_amino_acid_8: $i > $i).
% 28.89/28.90  tff(decl_2738, type, fn_hydrophilic_amino_acid_26: $i > $i).
% 28.89/28.90  tff(decl_2739, type, fn_hydrophilic_amino_acid_25: $i > $i).
% 28.89/28.90  tff(decl_2740, type, fn_hydrophilic_amino_acid_29: $i > $i).
% 28.89/28.90  tff(decl_2741, type, fn_hydrophilic_amino_acid_12: $i > $i).
% 28.89/28.90  tff(decl_2742, type, fn_hydrophilic_amino_acid_11: $i > $i).
% 28.89/28.90  tff(decl_2743, type, fn_hydrophilic_amino_acid_21: $i > $i).
% 28.89/28.90  tff(decl_2744, type, fn_hydrophilic_amino_acid_20: $i > $i).
% 28.89/28.90  tff(decl_2745, type, fn_hydrophilic_amino_acid_34: $i > $i).
% 28.89/28.90  tff(decl_2746, type, fn_hydrophilic_amino_acid_27: $i > $i).
% 28.89/28.90  tff(decl_2747, type, 'Acidic-Solution': $i).
% 28.89/28.90  tff(decl_2748, type, 'An aqueous solution containing more H+ ions than OH- ions. An aqueous solution with a pH less than 7.': $i).
% 28.89/28.90  tff(decl_2749, type, 'acidic solution': $i).
% 28.89/28.90  tff(decl_2750, type, 'acidic-solution': $i).
% 28.89/28.90  tff(decl_2751, type, sodium_chloride_solution_1: $i > $o).
% 28.89/28.90  tff(decl_2752, type, fn_acidic_solution_6: $i > $i).
% 28.89/28.90  tff(decl_2753, type, fn_acidic_solution_7: $i > $i).
% 28.89/28.90  tff(decl_2754, type, fn_acidic_solution_9: $i > $i).
% 28.89/28.90  tff(decl_2755, type, fn_acidic_solution_10: $i > $i).
% 28.89/28.90  tff(decl_2756, type, fn_acidic_solution_11: $i > $i).
% 28.89/28.90  tff(decl_2757, type, fn_acidic_solution_12: $i > $i).
% 28.89/28.90  tff(decl_2758, type, fn_acidic_solution_16: $i > $i).
% 28.89/28.90  tff(decl_2759, type, surface_1: $i > $o).
% 28.89/28.90  tff(decl_2760, type, fn_acidic_solution_17: $i > $i).
% 28.89/28.90  tff(decl_2761, type, add_1: $i > $o).
% 28.89/28.90  tff(decl_2762, type, fn_acidic_solution_20: $i > $i).
% 28.89/28.90  tff(decl_2763, type, hydroxide_ion_1: $i > $o).
% 28.89/28.90  tff(decl_2764, type, fn_acidic_solution_22: $i > $i).
% 28.89/28.90  tff(decl_2765, type, attract_1: $i > $o).
% 28.89/28.90  tff(decl_2766, type, fn_acidic_solution_23: $i > $i).
% 28.89/28.90  tff(decl_2767, type, hydrophilic_region_1: $i > $o).
% 28.89/28.90  tff(decl_2768, type, fn_acidic_solution_24: $i > $i).
% 28.89/28.90  tff(decl_2769, type, fn_acidic_solution_25: $i > $i).
% 28.89/28.90  tff(decl_2770, type, fn_acidic_solution_26: $i > $i).
% 28.89/28.90  tff(decl_2771, type, polar_covalent_bond_1: $i > $o).
% 28.89/28.90  tff(decl_2772, type, fn_acidic_solution_27: $i > $i).
% 28.89/28.90  tff(decl_2773, type, fn_acidic_solution_28: $i > $i).
% 28.89/28.90  tff(decl_2774, type, fn_acidic_solution_29: $i > $i).
% 28.89/28.90  tff(decl_2775, type, hydrophilic_compound_1: $i > $o).
% 28.89/28.90  tff(decl_2776, type, polar_molecule_1: $i > $o).
% 28.89/28.90  tff(decl_2777, type, fn_acidic_solution_30: $i > $i).
% 28.89/28.90  tff(decl_2778, type, heat_1: $i > $o).
% 28.89/28.90  tff(decl_2779, type, fn_add_2: $i > $i).
% 28.89/28.90  tff(decl_2780, type, fn_water_molecule_4: $i > $i).
% 28.89/28.90  tff(decl_2781, type, fn_water_molecule_3: $i > $i).
% 28.89/28.90  tff(decl_2782, type, fn_water_molecule_2: $i > $i).
% 28.89/28.90  tff(decl_2783, type, fn_water_molecule_1: $i > $i).
% 28.89/28.90  tff(decl_2784, type, fn_water_101: $i > $i).
% 28.89/28.90  tff(decl_2785, type, fn_water_14: $i > $i).
% 28.89/28.90  tff(decl_2786, type, fn_water_99: $i > $i).
% 28.89/28.90  tff(decl_2787, type, fn_add_1: $i > $i).
% 28.89/28.90  tff(decl_2788, type, fn_hydrophilic_compound_1: $i > $i).
% 28.89/28.90  tff(decl_2789, type, fn_water_110: $i > $i).
% 28.89/28.90  tff(decl_2790, type, fn_water_molecule_62: $i > $i).
% 28.89/28.90  tff(decl_2791, type, fn_water_113: $i > $i).
% 28.89/28.90  tff(decl_2792, type, fn_water_molecule_61: $i > $i).
% 28.89/28.90  tff(decl_2793, type, fn_polar_molecule_2: $i > $i).
% 28.89/28.90  tff(decl_2794, type, fn_water_molecule_64: $i > $i).
% 28.89/28.90  tff(decl_2795, type, fn_water_molecule_63: $i > $i).
% 28.89/28.90  tff(decl_2796, type, fn_water_106: $i > $i).
% 28.89/28.90  tff(decl_2797, type, fn_hydrophilic_compound_2: $i > $i).
% 28.89/28.90  tff(decl_2798, type, fn_water_molecule_75: $i > $i).
% 28.89/28.90  tff(decl_2799, type, fn_water_109: $i > $i).
% 28.89/28.90  tff(decl_2800, type, fn_water_105: $i > $i).
% 28.89/28.90  tff(decl_2801, type, fn_water_83: $i > $i).
% 28.89/28.90  tff(decl_2802, type, fn_water_98: $i > $i).
% 28.89/28.90  tff(decl_2803, type, "1": $i).
% 28.89/28.90  tff(decl_2804, type, fn_solution_6: $i > $i).
% 28.89/28.90  tff(decl_2805, type, fn_solution_5: $i > $i).
% 28.89/28.90  tff(decl_2806, type, fn_acidic_solution_13: $i > $i).
% 28.89/28.90  tff(decl_2807, type, fn_acidic_solution_14: $i > $i).
% 28.89/28.90  tff(decl_2808, type, weak_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2809, type, acidic_solution_of_weak_acid_1: $i > $o).
% 28.89/28.90  tff(decl_2810, type, fn_acidic_solution_of_weak_acid_2: $i > $i).
% 28.89/28.90  tff(decl_2811, type, 'Acidic-Solution-Of-Weak-Acid': $i).
% 28.89/28.90  tff(decl_2812, type, 'Solution containing a weak acid.': $i).
% 28.89/28.90  tff(decl_2813, type, 'weak acid solution': $i).
% 28.89/28.90  tff(decl_2814, type, 'solution of weak acid': $i).
% 28.89/28.90  tff(decl_2815, type, 'weakly acidic solution': $i).
% 28.89/28.90  tff(decl_2816, type, 'acidic solution of weak acid': $i).
% 28.89/28.90  tff(decl_2817, type, 'acidic-solution-of-weak-acid': $i).
% 28.89/28.90  tff(decl_2818, type, acoela_1: $i > $o).
% 28.89/28.90  tff(decl_2819, type, 'Acoela': $i).
% 28.89/28.90  tff(decl_2820, type, 'Order of marine flatworms characterized by the lack of a hindgut and anus and an unsegmented body plan.': $i).
% 28.89/28.90  tff(decl_2821, type, acoela: $i).
% 28.89/28.90  tff(decl_2822, type, fn_acoela_1: $i > $i).
% 28.89/28.90  tff(decl_2823, type, fn_acoela_2: $i > $i).
% 28.89/28.90  tff(decl_2824, type, fn_acoela_3: $i > $i).
% 28.89/28.90  tff(decl_2825, type, elimination_1: $i > $o).
% 28.89/28.90  tff(decl_2826, type, fn_acoela_4: $i > $i).
% 28.89/28.90  tff(decl_2827, type, pore_1: $i > $o).
% 28.89/28.90  tff(decl_2828, type, fn_acoela_5: $i > $i).
% 28.89/28.90  tff(decl_2829, type, food_absorption_1: $i > $o).
% 28.89/28.90  tff(decl_2830, type, fn_acoela_6: $i > $i).
% 28.89/28.90  tff(decl_2831, type, fn_acoela_7: $i > $i).
% 28.89/28.90  tff(decl_2832, type, fn_acoela_8: $i > $i).
% 28.89/28.90  tff(decl_2833, type, animal_nutritional_requirement_1: $i > $o).
% 28.89/28.90  tff(decl_2834, type, fn_acoela_9: $i > $i).
% 28.89/28.90  tff(decl_2835, type, fn_acoela_10: $i > $i).
% 28.89/28.90  tff(decl_2836, type, fn_acoela_11: $i > $i).
% 28.89/28.90  tff(decl_2837, type, fn_acoela_12: $i > $i).
% 28.89/28.90  tff(decl_2838, type, fn_acoela_13: $i > $i).
% 28.89/28.90  tff(decl_2839, type, fn_acoela_14: $i > $i).
% 28.89/28.90  tff(decl_2840, type, fn_acoela_15: $i > $i).
% 28.89/28.90  tff(decl_2841, type, move_out_of_1: $i > $o).
% 28.89/28.90  tff(decl_2842, type, fn_acoela_16: $i > $i).
% 28.89/28.90  tff(decl_2843, type, digestive_system_1: $i > $o).
% 28.89/28.90  tff(decl_2844, type, fn_acoela_17: $i > $i).
% 28.89/28.90  tff(decl_2845, type, fn_acoela_18: $i > $i).
% 28.89/28.90  tff(decl_2846, type, nutrition_1: $i > $o).
% 28.89/28.90  tff(decl_2847, type, fn_acoela_19: $i > $i).
% 28.89/28.90  tff(decl_2848, type, heterotroph_1: $i > $o).
% 28.89/28.90  tff(decl_2849, type, fn_acoela_20: $i > $i).
% 28.89/28.90  tff(decl_2850, type, agent_role_1: $i > $o).
% 28.89/28.90  tff(decl_2851, type, fn_acoela_21: $i > $i).
% 28.89/28.90  tff(decl_2852, type, fn_acoela_22: $i > $i).
% 28.89/28.90  tff(decl_2853, type, polypeptide_1: $i > $o).
% 28.89/28.90  tff(decl_2854, type, fn_acoela_23: $i > $i).
% 28.89/28.90  tff(decl_2855, type, fn_acoela_24: $i > $i).
% 28.89/28.90  tff(decl_2856, type, fn_acoela_25: $i > $i).
% 28.89/28.90  tff(decl_2857, type, fn_acoela_26: $i > $i).
% 28.89/28.90  tff(decl_2858, type, fn_acoela_27: $i > $i).
% 28.89/28.90  tff(decl_2859, type, carbohydrate_1: $i > $o).
% 28.89/28.90  tff(decl_2860, type, fn_acoela_28: $i > $i).
% 28.89/28.90  tff(decl_2861, type, fn_acoela_29: $i > $i).
% 28.89/28.90  tff(decl_2862, type, fn_move_out_of_2: $i > $i).
% 28.89/28.90  tff(decl_2863, type, fn_animal_nutritional_requirement_41: $i > $i).
% 28.89/28.90  tff(decl_2864, type, fn_animal_nutritional_requirement_35: $i > $i).
% 28.89/28.90  tff(decl_2865, type, fn_animal_nutritional_requirement_42: $i > $i).
% 28.89/28.90  tff(decl_2866, type, fn_animal_nutritional_requirement_34: $i > $i).
% 28.89/28.90  tff(decl_2867, type, fn_animal_nutritional_requirement_38: $i > $i).
% 28.89/28.90  tff(decl_2868, type, fn_animal_nutritional_requirement_40: $i > $i).
% 28.89/28.90  tff(decl_2869, type, fn_animal_nutritional_requirement_46: $i > $i).
% 28.89/28.90  tff(decl_2870, type, fn_animal_nutritional_requirement_53: $i > $i).
% 28.89/28.90  tff(decl_2871, type, fn_animal_nutritional_requirement_48: $i > $i).
% 28.89/28.90  tff(decl_2872, type, fn_animal_nutritional_requirement_61: $i > $i).
% 28.89/28.90  tff(decl_2873, type, fn_agent_role_1: $i > $i).
% 28.89/28.90  tff(decl_2874, type, fn_move_out_of_1: $i > $i).
% 28.89/28.90  tff(decl_2875, type, fn_animal_nutritional_requirement_6: $i > $i).
% 28.89/28.90  tff(decl_2876, type, fn_animal_nutritional_requirement_4: $i > $i).
% 28.89/28.90  tff(decl_2877, type, fn_animal_nutritional_requirement_54: $i > $i).
% 28.89/28.90  tff(decl_2878, type, fn_animal_nutritional_requirement_52: $i > $i).
% 28.89/28.90  tff(decl_2879, type, fn_animal_19: $i > $i).
% 28.89/28.90  tff(decl_2880, type, fn_animal_18: $i > $i).
% 28.89/28.90  tff(decl_2881, type, fn_animal_2: $i > $i).
% 28.89/28.90  tff(decl_2882, type, fn_animal_5: $i > $i).
% 28.89/28.90  tff(decl_2883, type, fn_organism_2: $i > $i).
% 28.89/28.90  tff(decl_2884, type, fn_organism_5: $i > $i).
% 28.89/28.90  tff(decl_2885, type, fn_organism_4: $i > $i).
% 28.89/28.90  tff(decl_2886, type, acrosomal_reaction_1: $i > $o).
% 28.89/28.90  tff(decl_2887, type, 'Acrosomal-Reaction': $i).
% 28.89/28.90  tff(decl_2888, type, 'Release of enzymes from the acrosome of a sperm near the zona pellucida of an egg.  The enzymes break through the outer coating of the egg and allow fertilization to occur.': $i).
% 28.89/28.90  tff(decl_2889, type, 'acrosomal reaction': $i).
% 28.89/28.90  tff(decl_2890, type, 'acrosomal-reaction': $i).
% 28.89/28.90  tff(decl_2891, type, animal_fertilization_1: $i > $o).
% 28.89/28.90  tff(decl_2892, type, conception_1: $i > $o).
% 28.89/28.90  tff(decl_2893, type, cortical_reaction_1: $i > $o).
% 28.89/28.90  tff(decl_2894, type, acrosome_1: $i > $o).
% 28.89/28.90  tff(decl_2895, type, 'Acrosome': $i).
% 28.89/28.90  tff(decl_2896, type, 'A caplike vesicle in the tip of a sperm that contains enzymes used to penetrate an egg\\s protective outer covering.': $i).
% 28.89/28.90  tff(decl_2897, type, acrosome: $i).
% 28.89/28.90  tff(decl_2898, type, vesicle_1: $i > $o).
% 28.89/28.90  tff(decl_2899, type, cortical_granule_1: $i > $o).
% 28.89/28.90  tff(decl_2900, type, lysosome_1: $i > $o).
% 28.89/28.90  tff(decl_2901, type, synaptic_vesicle_1: $i > $o).
% 28.89/28.90  tff(decl_2902, type, transport_vesicle_1: $i > $o).
% 28.89/28.90  tff(decl_2903, type, vacuole_1: $i > $o).
% 28.89/28.90  tff(decl_2904, type, fn_acrosome_1: $i > $i).
% 28.89/28.90  tff(decl_2905, type, sperm_cell_1: $i > $o).
% 28.89/28.90  tff(decl_2906, type, fn_vesicle_5: $i > $i).
% 28.89/28.90  tff(decl_2907, type, actin_1: $i > $o).
% 28.89/28.90  tff(decl_2908, type, 'Actin': $i).
% 28.89/28.90  tff(decl_2909, type, 'Actin is a globular protein found in all eukaryotic cells. It serves as the basic structural unit for microfilament and thin filaments': $i).
% 28.89/28.90  tff(decl_2910, type, actin: $i).
% 28.89/28.90  tff(decl_2911, type, globular_protein_1: $i > $o).
% 28.89/28.90  tff(decl_2912, type, fn_actin_1: $i > $i).
% 28.89/28.90  tff(decl_2913, type, fn_actin_2: $i > $i).
% 28.89/28.90  tff(decl_2914, type, fn_actin_3: $i > $i).
% 28.89/28.90  tff(decl_2915, type, polypeptide_0: $i).
% 28.89/28.90  tff(decl_2916, type, fn_polymer_8: $i > $i).
% 28.89/28.90  tff(decl_2917, type, fn_polymer_7: $i > $i).
% 28.89/28.90  tff(decl_2918, type, fn_polymer_4: $i > $i).
% 28.89/28.90  tff(decl_2919, type, fn_protein_9: $i > $i).
% 28.89/28.90  tff(decl_2920, type, actinium_1: $i > $o).
% 28.89/28.90  tff(decl_2921, type, 'Actinium': $i).
% 28.89/28.90  tff(decl_2922, type, 'Actinium is a metal atom with atomic number 89. It is represented by the symbol Ac.': $i).
% 28.89/28.90  tff(decl_2923, type, actinium: $i).
% 28.89/28.90  tff(decl_2924, type, ac: $i).
% 28.89/28.90  tff(decl_2925, type, metal_atom_1: $i > $o).
% 28.89/28.90  tff(decl_2926, type, fn_actinium_4: $i > $i).
% 28.89/28.90  tff(decl_2927, type, neutron_1: $i > $o).
% 28.89/28.90  tff(decl_2928, type, fn_actinium_5: $i > $i).
% 28.89/28.90  tff(decl_2929, type, fn_actinium_6: $i > $i).
% 28.89/28.90  tff(decl_2930, type, fn_actinium_7: $i > $i).
% 28.89/28.90  tff(decl_2931, type, fn_actinium_11: $i > $i).
% 28.89/28.90  tff(decl_2932, type, fn_actinium_12: $i > $i).
% 28.89/28.90  tff(decl_2933, type, fn_actinium_13: $i > $i).
% 28.89/28.90  tff(decl_2934, type, fn_actinium_14: $i > $i).
% 28.89/28.90  tff(decl_2935, type, "138": $i).
% 28.89/28.90  tff(decl_2936, type, neutron_0: $i).
% 28.89/28.90  tff(decl_2937, type, "89": $i).
% 28.89/28.90  tff(decl_2938, type, proton_0: $i).
% 28.89/28.90  tff(decl_2939, type, electron_0: $i).
% 28.89/28.90  tff(decl_2940, type, "3": $i).
% 28.89/28.90  tff(decl_2941, type, "1.1": $i).
% 28.89/28.90  tff(decl_2942, type, "227": $i).
% 28.89/28.90  tff(decl_2943, type, fn_actinium_9: $i > $i).
% 28.89/28.90  tff(decl_2944, type, fn_atom_12: $i > $i).
% 28.89/28.90  tff(decl_2945, type, fn_atom_17: $i > $i).
% 28.89/28.90  tff(decl_2946, type, fn_actinium_10: $i > $i).
% 28.89/28.90  tff(decl_2947, type, fn_atom_13: $i > $i).
% 28.89/28.90  tff(decl_2948, type, fn_atom_16: $i > $i).
% 28.89/28.90  tff(decl_2949, type, fn_actinium_8: $i > $i).
% 28.89/28.90  tff(decl_2950, type, fn_atom_1: $i > $i).
% 28.89/28.90  tff(decl_2951, type, fn_atom_5: $i > $i).
% 28.89/28.90  tff(decl_2952, type, actinopod_1: $i > $o).
% 28.89/28.90  tff(decl_2953, type, 'Actinopod': $i).
% 28.89/28.90  tff(decl_2954, type, 'An amoeboid protist whose pseudopods are reinforced by regular arrays of microtubules; examples include radiolarians and heliozoans.': $i).
% 28.89/28.90  tff(decl_2955, type, actinopod: $i).
% 28.89/28.90  tff(decl_2956, type, amoeba_1: $i > $o).
% 28.89/28.90  tff(decl_2957, type, actinopterygii_1: $i > $o).
% 28.89/28.90  tff(decl_2958, type, 'Actinopterygii': $i).
% 28.89/28.90  tff(decl_2959, type, 'The taxon comprising the ray-finned fishes.': $i).
% 28.89/28.90  tff(decl_2960, type, actinopterygii: $i).
% 28.89/28.90  tff(decl_2961, type, ray_finned_fish_1: $i > $o).
% 28.89/28.90  tff(decl_2962, type, sunfish_1: $i > $o).
% 28.89/28.90  tff(decl_2963, type, stickleback_1: $i > $o).
% 28.89/28.90  tff(decl_2964, type, 'Action': $i).
% 28.89/28.90  tff(decl_2965, type, 'work on': $i).
% 28.89/28.90  tff(decl_2966, type, make: $i).
% 28.89/28.90  tff(decl_2967, type, act: $i).
% 28.89/28.90  tff(decl_2968, type, do: $i).
% 28.89/28.91  tff(decl_2969, type, execute: $i).
% 28.89/28.91  tff(decl_2970, type, move: $i).
% 28.89/28.91  tff(decl_2971, type, perform: $i).
% 28.89/28.91  tff(decl_2972, type, work: $i).
% 28.89/28.91  tff(decl_2973, type, process: $i).
% 28.89/28.91  tff(decl_2974, type, action: $i).
% 28.89/28.91  tff(decl_2975, type, action_potential_1: $i > $o).
% 28.89/28.91  tff(decl_2976, type, 'Action-Potential': $i).
% 28.89/28.91  tff(decl_2977, type, 'A rapid change in the membrane potential of an excitable cell, caused by stimulus-triggered, selective opening and closing of voltage-sensitive gates in sodium and potassium ion channels.': $i).
% 28.89/28.91  tff(decl_2978, type, 'potential of action': $i).
% 28.89/28.91  tff(decl_2979, type, 'action potential': $i).
% 28.89/28.91  tff(decl_2980, type, 'action-potential': $i).
% 28.89/28.91  tff(decl_2981, type, change_in_membrane_potential_1: $i > $o).
% 28.89/28.91  tff(decl_2982, type, action_spectrum_1: $i > $o).
% 28.89/28.91  tff(decl_2983, type, 'Action-Spectrum': $i).
% 28.89/28.91  tff(decl_2984, type, 'A range of wavelengths of radiation that are most effective in promoting a particular process. This range is sometimes depicted in a graph with the same name.': $i).
% 28.89/28.91  tff(decl_2985, type, 'spectrum of action': $i).
% 28.89/28.91  tff(decl_2986, type, 'action spectrum': $i).
% 28.89/28.91  tff(decl_2987, type, 'action-spectrum': $i).
% 28.89/28.91  tff(decl_2988, type, age_structure_diagram_1: $i > $o).
% 28.89/28.91  tff(decl_2989, type, cell_lineage_1: $i > $o).
% 28.89/28.91  tff(decl_2990, type, cladogram_1: $i > $o).
% 28.89/28.91  tff(decl_2991, type, climograph_1: $i > $o).
% 28.89/28.91  tff(decl_2992, type, fate_map_1: $i > $o).
% 28.89/28.91  tff(decl_2993, type, genetic_map_1: $i > $o).
% 28.89/28.91  tff(decl_2994, type, genomic_representation_1: $i > $o).
% 28.89/28.91  tff(decl_2995, type, genotypic_ratio_1: $i > $o).
% 28.89/28.91  tff(decl_2996, type, life_table_1: $i > $o).
% 28.89/28.91  tff(decl_2997, type, pedigree_1: $i > $o).
% 28.89/28.91  tff(decl_2998, type, periodic_table_1: $i > $o).
% 28.89/28.91  tff(decl_2999, type, phenotypic_ratio_1: $i > $o).
% 28.89/28.91  tff(decl_3000, type, phylogenetic_tree_1: $i > $o).
% 28.89/28.91  tff(decl_3001, type, punnett_square_1: $i > $o).
% 28.89/28.91  tff(decl_3002, type, reproductive_table_1: $i > $o).
% 28.89/28.91  tff(decl_3003, type, species_area_curve_1: $i > $o).
% 28.89/28.91  tff(decl_3004, type, survivorship_curve_1: $i > $o).
% 28.89/28.91  tff(decl_3005, type, tree_of_life_1: $i > $o).
% 28.89/28.91  tff(decl_3006, type, activate_1: $i > $o).
% 28.89/28.91  tff(decl_3007, type, 'Activate': $i).
% 28.89/28.91  tff(decl_3008, type, activate: $i).
% 28.89/28.91  tff(decl_3009, type, enable: $i).
% 28.89/28.91  tff(decl_3010, type, reactivate: $i).
% 28.89/28.91  tff(decl_3011, type, set: $i).
% 28.89/28.91  tff(decl_3012, type, throw: $i).
% 28.89/28.91  tff(decl_3013, type, switch: $i).
% 28.89/28.91  tff(decl_3014, type, 'set up': $i).
% 28.89/28.91  tff(decl_3015, type, ready: $i).
% 28.89/28.91  tff(decl_3016, type, prepare: $i).
% 28.89/28.91  tff(decl_3017, type, 'gear up': $i).
% 28.89/28.91  tff(decl_3018, type, flip: $i).
% 28.89/28.91  tff(decl_3019, type, make_accessible_1: $i > $o).
% 28.89/28.91  tff(decl_3020, type, unobstruct_1: $i > $o).
% 28.89/28.91  tff(decl_3021, type, unblock_1: $i > $o).
% 28.89/28.91  tff(decl_3022, type, expose_1: $i > $o).
% 28.89/28.91  tff(decl_3023, type, 'Activation-Constant': $i).
% 28.89/28.91  tff(decl_3024, type, 'constant of activation': $i).
% 28.89/28.91  tff(decl_3025, type, 'activation constant': $i).
% 28.89/28.91  tff(decl_3026, type, 'activation-constant': $i).
% 28.89/28.91  tff(decl_3027, type, activation_energy_1: $i > $o).
% 28.89/28.91  tff(decl_3028, type, 'Activation-Energy': $i).
% 28.89/28.91  tff(decl_3029, type, 'Activation energy is the minimum amount of energy (heat, electromagnetic radiation, or electrical energy) required to activate atoms or molecules to a condition in which it is equally likely that they will undergo chemical reaction. In decomposition reactions, activation energy is proportional to the difficulty of breaking bonds.': $i).
% 28.89/28.91  tff(decl_3030, type, 'energy of activation': $i).
% 28.89/28.91  tff(decl_3031, type, 'energy-of-activation': $i).
% 28.89/28.91  tff(decl_3032, type, 'free energy of activation': $i).
% 28.89/28.91  tff(decl_3033, type, 'free-energy-of-activation': $i).
% 28.89/28.91  tff(decl_3034, type, ea: $i).
% 28.89/28.91  tff(decl_3035, type, 'activation energy': $i).
% 28.89/28.91  tff(decl_3036, type, 'activation-energy': $i).
% 28.89/28.91  tff(decl_3037, type, activation_of_atp_synthase_1: $i > $o).
% 28.89/28.91  tff(decl_3038, type, 'Activation-Of-ATP-Synthase': $i).
% 28.89/28.91  tff(decl_3039, type, 'Activation of the enzyme that catalyzes the reaction that forms ATP from ADP and inorganic phosphate.': $i).
% 28.89/28.91  tff(decl_3040, type, 'activation of atp synthase': $i).
% 28.89/28.91  tff(decl_3041, type, 'activation-of-atp-synthase': $i).
% 28.89/28.91  tff(decl_3042, type, cellular_process_1: $i > $o).
% 28.89/28.91  tff(decl_3043, type, fn_activation_of_atp_synthase_3: $i > $i).
% 28.89/28.91  tff(decl_3044, type, atp_synthase_1: $i > $o).
% 28.89/28.91  tff(decl_3045, type, fn_activation_of_atp_synthase_4: $i > $i).
% 28.89/28.91  tff(decl_3046, type, fn_activation_of_atp_synthase_5: $i > $i).
% 28.89/28.91  tff(decl_3047, type, fn_activation_of_atp_synthase_6: $i > $i).
% 28.89/28.91  tff(decl_3048, type, fn_activation_of_atp_synthase_7: $i > $i).
% 28.89/28.91  tff(decl_3049, type, activation_of_cyclin_dependent_kinase_1: $i > $o).
% 28.89/28.91  tff(decl_3050, type, 'Activation-Of-Cyclin-Dependent-Kinase': $i).
% 28.89/28.91  tff(decl_3051, type, 'The process of activating certain kinase molecules by the attachment of one or more cyclin molecules.': $i).
% 28.89/28.91  tff(decl_3052, type, 'activation of cyclin dependent kinase': $i).
% 28.89/28.91  tff(decl_3053, type, 'activation-of-cyclin-dependent-kinase': $i).
% 28.89/28.91  tff(decl_3054, type, fn_activation_of_cyclin_dependent_kinase_1: $i > $i).
% 28.89/28.91  tff(decl_3055, type, fn_activation_of_cyclin_dependent_kinase_3: $i > $i).
% 28.89/28.91  tff(decl_3056, type, fn_activation_of_cyclin_dependent_kinase_4: $i > $i).
% 28.89/28.91  tff(decl_3057, type, cyclin_dependent_kinase_1: $i > $o).
% 28.89/28.91  tff(decl_3058, type, fn_activation_of_cyclin_dependent_kinase_6: $i > $i).
% 28.89/28.91  tff(decl_3059, type, fn_activation_of_cyclin_dependent_kinase_7: $i > $i).
% 28.89/28.91  tff(decl_3060, type, cyclin_1: $i > $o).
% 28.89/28.91  tff(decl_3061, type, fn_activation_of_cyclin_dependent_kinase_8: $i > $i).
% 28.89/28.91  tff(decl_3062, type, fn_make_accessible_1: $i > $i).
% 28.89/28.91  tff(decl_3063, type, 'Activation-Value': $i).
% 28.89/28.91  tff(decl_3064, type, activation: $i).
% 28.89/28.91  tff(decl_3065, type, 'value of activation': $i).
% 28.89/28.91  tff(decl_3066, type, 'activation value': $i).
% 28.89/28.91  tff(decl_3067, type, 'activation-value': $i).
% 28.89/28.91  tff(decl_3068, type, activator_1: $i > $o).
% 28.89/28.91  tff(decl_3069, type, 'Activator': $i).
% 28.89/28.91  tff(decl_3070, type, 'A protein that binds to DNA and stimulates gene transcription. In prokaryotes, activators bind in or near the promoter; in eukaryotes, activators bind to control elements in enhancers.': $i).
% 28.89/28.91  tff(decl_3071, type, activator: $i).
% 28.89/28.91  tff(decl_3072, type, transcription_factor_1: $i > $o).
% 28.89/28.91  tff(decl_3073, type, homeodomain_protein_1: $i > $o).
% 28.89/28.91  tff(decl_3074, type, morphogen_1: $i > $o).
% 28.89/28.91  tff(decl_3075, type, muscle_specific_transcription_factor_1: $i > $o).
% 28.89/28.91  tff(decl_3076, type, p53_protein_1: $i > $o).
% 28.89/28.91  tff(decl_3077, type, fn_activator_1: $i > $i).
% 28.89/28.91  tff(decl_3078, type, enhancer_1: $i > $o).
% 28.89/28.91  tff(decl_3079, type, fn_activator_2: $i > $i).
% 28.89/28.91  tff(decl_3080, type, fn_transcription_factor_8: $i > $i).
% 28.89/28.91  tff(decl_3081, type, active_movement_of_ions_1: $i > $o).
% 28.89/28.91  tff(decl_3082, type, 'Active-Movement-Of-Ions': $i).
% 28.89/28.91  tff(decl_3083, type, 'The proteins mediate the movement of ions to move across a membrane.': $i).
% 28.89/28.91  tff(decl_3084, type, transport: $i).
% 28.89/28.91  tff(decl_3085, type, 'active movement of ion': $i).
% 28.89/28.91  tff(decl_3086, type, 'active-movement-of-ion': $i).
% 28.89/28.91  tff(decl_3087, type, active_transport_1: $i > $o).
% 28.89/28.91  tff(decl_3088, type, fn_active_movement_of_ions_1: $i > $i).
% 28.89/28.91  tff(decl_3089, type, fn_active_movement_of_ions_2: $i > $i).
% 28.89/28.91  tff(decl_3090, type, fn_active_movement_of_ions_3: $i > $i).
% 28.89/28.91  tff(decl_3091, type, fn_active_movement_of_ions_4: $i > $i).
% 28.89/28.91  tff(decl_3092, type, fn_active_movement_of_ions_5: $i > $i).
% 28.89/28.91  tff(decl_3093, type, fn_active_movement_of_ions_6: $i > $i).
% 28.89/28.91  tff(decl_3094, type, fn_active_movement_of_ions_7: $i > $i).
% 28.89/28.91  tff(decl_3095, type, fn_active_movement_of_ions_8: $i > $i).
% 28.89/28.91  tff(decl_3096, type, fn_active_movement_of_ions_9: $i > $i).
% 28.89/28.91  tff(decl_3097, type, fn_active_movement_of_ions_10: $i > $i).
% 28.89/28.91  tff(decl_3098, type, carrier_protein_1: $i > $o).
% 28.89/28.91  tff(decl_3099, type, fn_active_movement_of_ions_11: $i > $i).
% 28.89/28.91  tff(decl_3100, type, fn_active_movement_of_ions_12: $i > $i).
% 28.89/28.91  tff(decl_3101, type, hydrophilic_end_1: $i > $o).
% 28.89/28.91  tff(decl_3102, type, fn_active_movement_of_ions_13: $i > $i).
% 28.89/28.91  tff(decl_3103, type, outside_face_1: $i > $o).
% 28.89/28.91  tff(decl_3104, type, fn_active_movement_of_ions_14: $i > $i).
% 28.89/28.91  tff(decl_3105, type, fn_active_movement_of_ions_15: $i > $i).
% 28.89/28.91  tff(decl_3106, type, hydrophobic_region_1: $i > $o).
% 28.89/28.91  tff(decl_3107, type, fn_active_movement_of_ions_16: $i > $i).
% 28.89/28.91  tff(decl_3108, type, fn_active_movement_of_ions_17: $i > $i).
% 28.89/28.91  tff(decl_3109, type, fn_active_movement_of_ions_18: $i > $i).
% 28.89/28.91  tff(decl_3110, type, fn_active_movement_of_ions_19: $i > $i).
% 28.89/28.91  tff(decl_3111, type, membrane_1: $i > $o).
% 28.89/28.91  tff(decl_3112, type, fn_active_movement_of_ions_20: $i > $i).
% 28.89/28.91  tff(decl_3113, type, polar_amino_acid_1: $i > $o).
% 28.89/28.91  tff(decl_3114, type, fn_active_movement_of_ions_21: $i > $i).
% 28.89/28.91  tff(decl_3115, type, hydrophobic_amino_acid_1: $i > $o).
% 28.89/28.91  tff(decl_3116, type, fn_active_movement_of_ions_22: $i > $i).
% 28.89/28.91  tff(decl_3117, type, fn_active_movement_of_ions_23: $i > $i).
% 28.89/28.91  tff(decl_3118, type, fn_active_movement_of_ions_24: $i > $i).
% 28.89/28.91  tff(decl_3119, type, fn_active_movement_of_ions_25: $i > $i).
% 28.89/28.91  tff(decl_3120, type, fn_biomembrane_42: $i > $i).
% 28.89/28.91  tff(decl_3121, type, fn_phosphate_group_6: $i > $i).
% 28.89/28.91  tff(decl_3122, type, fn_carrier_protein_12: $i > $i).
% 28.89/28.91  tff(decl_3123, type, fn_carrier_protein_11: $i > $i).
% 28.89/28.91  tff(decl_3124, type, fn_carrier_protein_22: $i > $i).
% 28.89/28.91  tff(decl_3125, type, fn_carrier_protein_21: $i > $i).
% 28.89/28.91  tff(decl_3126, type, fn_carrier_protein_31: $i > $i).
% 28.89/28.91  tff(decl_3127, type, fn_carrier_protein_24: $i > $i).
% 28.89/28.91  tff(decl_3128, type, fn_carrier_protein_42: $i > $i).
% 28.89/28.91  tff(decl_3129, type, fn_carrier_protein_37: $i > $i).
% 28.89/28.91  tff(decl_3130, type, fn_carrier_protein_38: $i > $i).
% 28.89/28.91  tff(decl_3131, type, fn_carrier_protein_41: $i > $i).
% 28.89/28.91  tff(decl_3132, type, fn_biomembrane_47: $i > $i).
% 28.89/28.91  tff(decl_3133, type, fn_biomembrane_41: $i > $i).
% 28.89/28.91  tff(decl_3134, type, fn_integral_protein_29: $i > $i).
% 28.89/28.91  tff(decl_3135, type, fn_polymer_1: $i > $i).
% 28.89/28.91  tff(decl_3136, type, fn_phosphate_group_37: $i > $i).
% 28.89/28.91  tff(decl_3137, type, fn_phosphate_group_41: $i > $i).
% 28.89/28.91  tff(decl_3138, type, fn_phosphate_group_22: $i > $i).
% 28.89/28.91  tff(decl_3139, type, fn_carrier_protein_32: $i > $i).
% 28.89/28.91  tff(decl_3140, type, fn_phosphate_group_5: $i > $i).
% 28.89/28.91  tff(decl_3141, type, fn_polymer_6: $i > $i).
% 28.89/28.91  tff(decl_3142, type, fn_carrier_protein_33: $i > $i).
% 28.89/28.91  tff(decl_3143, type, fn_integral_protein_23: $i > $i).
% 28.89/28.91  tff(decl_3144, type, fn_carrier_protein_23: $i > $i).
% 28.89/28.91  tff(decl_3145, type, fn_integral_protein_6: $i > $i).
% 28.89/28.91  tff(decl_3146, type, fn_carrier_protein_30: $i > $i).
% 28.89/28.91  tff(decl_3147, type, fn_carrier_protein_34: $i > $i).
% 28.89/28.91  tff(decl_3148, type, fn_integral_protein_27: $i > $i).
% 28.89/28.91  tff(decl_3149, type, fn_carrier_protein_16: $i > $i).
% 28.89/28.91  tff(decl_3150, type, fn_transport_protein_35: $i > $i).
% 28.89/28.91  tff(decl_3151, type, fn_integral_protein_24: $i > $i).
% 28.89/28.91  tff(decl_3152, type, fn_carrier_protein_18: $i > $i).
% 28.89/28.91  tff(decl_3153, type, fn_expose_1: $i > $i).
% 28.89/28.91  tff(decl_3154, type, fn_biomembrane_54: $i > $i).
% 28.89/28.91  tff(decl_3155, type, fn_active_transport_19: $i > $i).
% 28.89/28.91  tff(decl_3156, type, fn_active_transport_18: $i > $i).
% 28.89/28.91  tff(decl_3157, type, fn_active_transport_26: $i > $i).
% 28.89/28.91  tff(decl_3158, type, fn_active_movement_of_ions_26: $i > $i).
% 28.89/28.91  tff(decl_3159, type, fn_active_movement_of_ions_27: $i > $i).
% 28.89/28.91  tff(decl_3160, type, active_repressor_1: $i > $o).
% 28.89/28.91  tff(decl_3161, type, 'Active-Repressor': $i).
% 28.89/28.91  tff(decl_3162, type, 'The active form of a repressor.': $i).
% 28.89/28.91  tff(decl_3163, type, 'active repressor': $i).
% 28.89/28.91  tff(decl_3164, type, 'active-repressor': $i).
% 28.89/28.91  tff(decl_3165, type, repressor_1: $i > $o).
% 28.89/28.91  tff(decl_3166, type, inactive_repressor_1: $i > $o).
% 28.89/28.91  tff(decl_3167, type, fn_active_repressor_1: $i > $i).
% 28.89/28.91  tff(decl_3168, type, binding_site_1: $i > $o).
% 28.89/28.91  tff(decl_3169, type, fn_active_repressor_2: $i > $i).
% 28.89/28.91  tff(decl_3170, type, block_1: $i > $o).
% 28.89/28.91  tff(decl_3171, type, fn_active_repressor_3: $i > $i).
% 28.89/28.91  tff(decl_3172, type, fn_active_repressor_8: $i > $i).
% 28.89/28.91  tff(decl_3173, type, fn_active_repressor_9: $i > $i).
% 28.89/28.91  tff(decl_3174, type, fn_active_repressor_10: $i > $i).
% 28.89/28.91  tff(decl_3175, type, fn_active_repressor_11: $i > $i).
% 28.89/28.91  tff(decl_3176, type, allosteric_site_1: $i > $o).
% 28.89/28.91  tff(decl_3177, type, fn_active_repressor_12: $i > $i).
% 28.89/28.91  tff(decl_3178, type, fn_active_repressor_13: $i > $i).
% 28.89/28.91  tff(decl_3179, type, fn_active_repressor_14: $i > $i).
% 28.89/28.91  tff(decl_3180, type, fn_active_repressor_15: $i > $i).
% 28.89/28.91  tff(decl_3181, type, fn_active_repressor_16: $i > $i).
% 28.89/28.91  tff(decl_3182, type, fn_active_repressor_17: $i > $i).
% 28.89/28.91  tff(decl_3183, type, fn_active_repressor_18: $i > $i).
% 28.89/28.91  tff(decl_3184, type, fn_active_repressor_19: $i > $i).
% 28.89/28.91  tff(decl_3185, type, conformational_change_1: $i > $o).
% 28.89/28.91  tff(decl_3186, type, fn_active_repressor_20: $i > $i).
% 28.89/28.91  tff(decl_3187, type, fn_active_repressor_21: $i > $i).
% 28.89/28.91  tff(decl_3188, type, fn_active_repressor_22: $i > $i).
% 28.89/28.91  tff(decl_3189, type, fn_active_repressor_23: $i > $i).
% 28.89/28.91  tff(decl_3190, type, fn_active_repressor_24: $i > $i).
% 28.89/28.91  tff(decl_3191, type, fn_active_repressor_25: $i > $i).
% 28.89/28.91  tff(decl_3192, type, fn_active_repressor_26: $i > $i).
% 28.89/28.91  tff(decl_3193, type, fn_active_repressor_27: $i > $i).
% 28.89/28.91  tff(decl_3194, type, operator_1: $i > $o).
% 28.89/28.91  tff(decl_3195, type, fn_active_repressor_28: $i > $i).
% 28.89/28.91  tff(decl_3196, type, fn_active_repressor_29: $i > $i).
% 28.89/28.91  tff(decl_3197, type, fn_conformational_change_4: $i > $i).
% 28.89/28.91  tff(decl_3198, type, fn_conformational_change_3: $i > $i).
% 28.89/28.91  tff(decl_3199, type, fn_active_repressor_7: $i > $i).
% 28.89/28.91  tff(decl_3200, type, fn_allosteric_protein_22: $i > $i).
% 28.89/28.91  tff(decl_3201, type, fn_active_repressor_6: $i > $i).
% 28.89/28.91  tff(decl_3202, type, fn_allosteric_protein_24: $i > $i).
% 28.89/28.91  tff(decl_3203, type, fn_active_repressor_5: $i > $i).
% 28.89/28.91  tff(decl_3204, type, fn_allosteric_protein_23: $i > $i).
% 28.89/28.91  tff(decl_3205, type, fn_active_repressor_4: $i > $i).
% 28.89/28.91  tff(decl_3206, type, fn_allosteric_protein_25: $i > $i).
% 28.89/28.91  tff(decl_3207, type, fn_allosteric_protein_19: $i > $i).
% 28.89/28.91  tff(decl_3208, type, fn_allosteric_protein_14: $i > $i).
% 28.89/28.91  tff(decl_3209, type, fn_allosteric_protein_11: $i > $i).
% 28.89/28.91  tff(decl_3210, type, fn_allosteric_protein_2: $i > $i).
% 28.89/28.91  tff(decl_3211, type, fn_allosteric_protein_6: $i > $i).
% 28.89/28.91  tff(decl_3212, type, fn_allosteric_protein_9: $i > $i).
% 28.89/28.91  tff(decl_3213, type, fn_allosteric_protein_7: $i > $i).
% 28.89/28.91  tff(decl_3214, type, fn_allosteric_protein_4: $i > $i).
% 28.89/28.91  tff(decl_3215, type, fn_allosteric_protein_10: $i > $i).
% 28.89/28.91  tff(decl_3216, type, fn_allosteric_protein_12: $i > $i).
% 28.89/28.91  tff(decl_3217, type, fn_allosteric_protein_18: $i > $i).
% 28.89/28.91  tff(decl_3218, type, fn_allosteric_protein_15: $i > $i).
% 28.89/28.91  tff(decl_3219, type, fn_allosteric_protein_16: $i > $i).
% 28.89/28.91  tff(decl_3220, type, fn_allosteric_protein_17: $i > $i).
% 28.89/28.91  tff(decl_3221, type, fn_allosteric_protein_3: $i > $i).
% 28.89/28.91  tff(decl_3222, type, fn_allosteric_protein_20: $i > $i).
% 28.89/28.91  tff(decl_3223, type, fn_allosteric_protein_13: $i > $i).
% 28.89/28.91  tff(decl_3224, type, fn_allosteric_protein_21: $i > $i).
% 28.89/28.91  tff(decl_3225, type, 'Active-Site': $i).
% 28.89/28.91  tff(decl_3226, type, 'The active site is part of an enzyme where substrates bind and undergo a chemical reaction.': $i).
% 28.89/28.91  tff(decl_3227, type, 'catalytic center': $i).
% 28.89/28.91  tff(decl_3228, type, 'catalytic-center': $i).
% 28.89/28.91  tff(decl_3229, type, 'enzyme catalytic center': $i).
% 28.89/28.91  tff(decl_3230, type, 'enzyme-catalytic-center': $i).
% 28.89/28.91  tff(decl_3231, type, 'active site': $i).
% 28.89/28.91  tff(decl_3232, type, 'active-site': $i).
% 28.89/28.91  tff(decl_3233, type, cavity_1: $i > $o).
% 28.89/28.91  tff(decl_3234, type, functional_region_1: $i > $o).
% 28.89/28.91  tff(decl_3235, type, alpha_helix_1: $i > $o).
% 28.89/28.91  tff(decl_3236, type, antigen_binding_site_1: $i > $o).
% 28.89/28.91  tff(decl_3237, type, epitope_1: $i > $o).
% 28.89/28.91  tff(decl_3238, type, 'Active-Transport': $i).
% 28.89/28.91  tff(decl_3239, type, 'Active transport is the movement of a substance against its concentration energy (from low to high concentration).': $i).
% 28.89/28.91  tff(decl_3240, type, 'active transport': $i).
% 28.89/28.91  tff(decl_3241, type, 'active-transport': $i).
% 28.89/28.91  tff(decl_3242, type, transport_work_1: $i > $o).
% 28.89/28.91  tff(decl_3243, type, endergonic_process_1: $i > $o).
% 28.89/28.91  tff(decl_3244, type, subcellular_movement_1: $i > $o).
% 28.89/28.91  tff(decl_3245, type, passive_transport_1: $i > $o).
% 28.89/28.91  tff(decl_3246, type, fn_active_transport_3: $i > $i).
% 28.89/28.91  tff(decl_3247, type, fn_active_transport_10: $i > $i).
% 28.89/28.91  tff(decl_3248, type, fn_active_transport_11: $i > $i).
% 28.89/28.91  tff(decl_3249, type, fn_active_transport_12: $i > $i).
% 28.89/28.91  tff(decl_3250, type, fn_active_transport_13: $i > $i).
% 28.89/28.91  tff(decl_3251, type, fn_active_transport_14: $i > $i).
% 28.89/28.91  tff(decl_3252, type, fn_active_transport_17: $i > $i).
% 28.89/28.91  tff(decl_3253, type, fn_active_transport_20: $i > $i).
% 28.89/28.91  tff(decl_3254, type, fn_active_transport_21: $i > $i).
% 28.89/28.91  tff(decl_3255, type, fn_active_transport_22: $i > $i).
% 28.89/28.91  tff(decl_3256, type, move_through_1: $i > $o).
% 28.89/28.91  tff(decl_3257, type, fn_active_transport_23: $i > $i).
% 28.89/28.91  tff(decl_3258, type, fn_active_transport_24: $i > $i).
% 28.89/28.91  tff(decl_3259, type, fn_active_transport_25: $i > $i).
% 28.89/28.91  tff(decl_3260, type, concentration_gradient_1: $i > $o).
% 28.89/28.91  tff(decl_3261, type, fn_concentration_gradient_8: $i > $i).
% 28.89/28.91  tff(decl_3262, type, fn_concentration_gradient_9: $i > $i).
% 28.89/28.91  tff(decl_3263, type, fn_biomembrane_55: $i > $i).
% 28.89/28.91  tff(decl_3264, type, fn_carrier_protein_4: $i > $i).
% 28.89/28.91  tff(decl_3265, type, fn_biomembrane_52: $i > $i).
% 28.89/28.91  tff(decl_3266, type, 'Concentration_OH': $i).
% 28.89/28.91  tff(decl_3267, type, 'Concentration_H': $i).
% 28.89/28.91  tff(decl_3268, type, 'Quantity_H': $i).
% 28.89/28.91  tff(decl_3269, type, 'Quantity_OH': $i).
% 28.89/28.91  tff(decl_3270, type, fn_subcellular_movement_1: $i > $i).
% 28.89/28.91  tff(decl_3271, type, fn_active_transport_16: $i > $i).
% 28.89/28.91  tff(decl_3272, type, fn_cellular_work_6: $i > $i).
% 28.89/28.91  tff(decl_3273, type, fn_cellular_work_5: $i > $i).
% 28.89/28.91  tff(decl_3274, type, active_transport_by_proton_pump_1: $i > $o).
% 28.89/28.91  tff(decl_3275, type, 'Active-Transport-By-Proton-Pump': $i).
% 28.89/28.91  tff(decl_3276, type, 'active transport by proton pump': $i).
% 28.89/28.91  tff(decl_3277, type, 'active-transport-by-proton-pump': $i).
% 28.89/28.91  tff(decl_3278, type, active_transport_using_atp_1: $i > $o).
% 28.89/28.91  tff(decl_3279, type, fn_active_transport_by_proton_pump_1: $i > $i).
% 28.89/28.91  tff(decl_3280, type, proton_motive_force_1: $i > $o).
% 28.89/28.91  tff(decl_3281, type, fn_active_transport_by_proton_pump_2: $i > $i).
% 28.89/28.91  tff(decl_3282, type, hydrogen_ion_gradient_1: $i > $o).
% 28.89/28.91  tff(decl_3283, type, fn_active_transport_by_proton_pump_3: $i > $i).
% 28.89/28.91  tff(decl_3284, type, fn_active_transport_by_proton_pump_4: $i > $i).
% 28.89/28.91  tff(decl_3285, type, proton_pump_1: $i > $o).
% 28.89/28.91  tff(decl_3286, type, fn_proton_pump_54: $i > $i).
% 28.89/28.91  tff(decl_3287, type, fn_proton_pump_36: $i > $i).
% 28.89/28.91  tff(decl_3288, type, active_transport_by_sodium_potassium_pump_1: $i > $o).
% 28.89/28.91  tff(decl_3289, type, 'Active-Transport-By-Sodium-Potassium-Pump': $i).
% 28.89/28.91  tff(decl_3290, type, 'Active movement of sodium ions and potassium ions across a plasma membrane.': $i).
% 28.89/28.91  tff(decl_3291, type, 'active transport by sodium potassium pump': $i).
% 28.89/28.91  tff(decl_3292, type, 'active-transport-by-sodium-potassium-pump': $i).
% 28.89/28.91  tff(decl_3293, type, fn_active_transport_by_sodium_potassium_pump_1: $i > $i).
% 28.89/28.91  tff(decl_3294, type, fn_active_transport_by_sodium_potassium_pump_2: $i > $i).
% 28.89/28.91  tff(decl_3295, type, fn_active_transport_by_sodium_potassium_pump_3: $i > $i).
% 28.89/28.91  tff(decl_3296, type, adp_1: $i > $o).
% 28.89/28.91  tff(decl_3297, type, fn_active_transport_by_sodium_potassium_pump_5: $i > $i).
% 28.89/28.91  tff(decl_3298, type, fn_active_transport_by_sodium_potassium_pump_6: $i > $i).
% 28.89/28.91  tff(decl_3299, type, electrochemical_gradient_1: $i > $o).
% 28.89/28.91  tff(decl_3300, type, fn_active_transport_by_sodium_potassium_pump_7: $i > $i).
% 28.89/28.91  tff(decl_3301, type, maintenance_1: $i > $o).
% 28.89/28.91  tff(decl_3302, type, fn_active_transport_by_sodium_potassium_pump_10: $i > $i).
% 28.89/28.91  tff(decl_3303, type, fn_active_transport_by_sodium_potassium_pump_11: $i > $i).
% 28.89/28.91  tff(decl_3304, type, fn_active_transport_by_sodium_potassium_pump_12: $i > $i).
% 28.89/28.91  tff(decl_3305, type, fn_active_transport_by_sodium_potassium_pump_13: $i > $i).
% 28.89/28.91  tff(decl_3306, type, fn_active_transport_by_sodium_potassium_pump_14: $i > $i).
% 28.89/28.91  tff(decl_3307, type, fn_active_transport_by_sodium_potassium_pump_15: $i > $i).
% 28.89/28.91  tff(decl_3308, type, fn_active_transport_by_sodium_potassium_pump_16: $i > $i).
% 28.89/28.91  tff(decl_3309, type, fn_active_transport_by_sodium_potassium_pump_17: $i > $i).
% 28.89/28.91  tff(decl_3310, type, fn_active_transport_by_sodium_potassium_pump_18: $i > $i).
% 28.89/28.91  tff(decl_3311, type, thermal_energy_1: $i > $o).
% 28.89/28.91  tff(decl_3312, type, fn_active_transport_by_sodium_potassium_pump_19: $i > $i).
% 28.89/28.91  tff(decl_3313, type, fn_active_transport_by_sodium_potassium_pump_20: $i > $i).
% 28.89/28.91  tff(decl_3314, type, fn_active_transport_by_sodium_potassium_pump_21: $i > $i).
% 28.89/28.91  tff(decl_3315, type, remove_1: $i > $o).
% 28.89/28.91  tff(decl_3316, type, fn_active_transport_by_sodium_potassium_pump_22: $i > $i).
% 28.89/28.91  tff(decl_3317, type, fn_active_transport_by_sodium_potassium_pump_23: $i > $i).
% 28.89/28.91  tff(decl_3318, type, fn_active_transport_by_sodium_potassium_pump_24: $i > $i).
% 28.89/28.91  tff(decl_3319, type, fn_active_transport_by_sodium_potassium_pump_25: $i > $i).
% 28.89/28.91  tff(decl_3320, type, fn_active_transport_by_sodium_potassium_pump_26: $i > $i).
% 28.89/28.91  tff(decl_3321, type, fn_active_transport_by_sodium_potassium_pump_27: $i > $i).
% 28.89/28.91  tff(decl_3322, type, fn_active_transport_by_sodium_potassium_pump_28: $i > $i).
% 28.89/28.91  tff(decl_3323, type, phosphate_ion_1: $i > $o).
% 28.89/28.91  tff(decl_3324, type, fn_active_transport_by_sodium_potassium_pump_29: $i > $i).
% 28.89/28.91  tff(decl_3325, type, fn_active_transport_by_sodium_potassium_pump_30: $i > $i).
% 28.89/28.91  tff(decl_3326, type, release_1: $i > $o).
% 28.89/28.91  tff(decl_3327, type, fn_active_transport_by_sodium_potassium_pump_33: $i > $i).
% 28.89/28.91  tff(decl_3328, type, fn_active_transport_by_sodium_potassium_pump_34: $i > $i).
% 28.89/28.91  tff(decl_3329, type, fn_active_transport_by_sodium_potassium_pump_35: $i > $i).
% 28.89/28.91  tff(decl_3330, type, potassium_ion_1: $i > $o).
% 28.89/28.91  tff(decl_3331, type, fn_active_transport_by_sodium_potassium_pump_36: $i > $i).
% 28.89/28.91  tff(decl_3332, type, fn_active_transport_by_sodium_potassium_pump_37: $i > $i).
% 28.89/28.91  tff(decl_3333, type, fn_active_transport_by_sodium_potassium_pump_38: $i > $i).
% 28.89/28.91  tff(decl_3334, type, fn_active_transport_by_sodium_potassium_pump_39: $i > $i).
% 28.89/28.91  tff(decl_3335, type, fn_active_transport_by_sodium_potassium_pump_40: $i > $i).
% 28.89/28.91  tff(decl_3336, type, fn_active_transport_by_sodium_potassium_pump_41: $i > $i).
% 28.89/28.91  tff(decl_3337, type, fn_active_transport_by_sodium_potassium_pump_42: $i > $i).
% 28.89/28.91  tff(decl_3338, type, fn_active_transport_by_sodium_potassium_pump_43: $i > $i).
% 28.89/28.91  tff(decl_3339, type, fn_active_transport_by_sodium_potassium_pump_44: $i > $i).
% 28.89/28.91  tff(decl_3340, type, fn_active_transport_by_sodium_potassium_pump_45: $i > $i).
% 28.89/28.91  tff(decl_3341, type, fn_active_transport_by_sodium_potassium_pump_46: $i > $i).
% 28.89/28.91  tff(decl_3342, type, fn_active_transport_by_sodium_potassium_pump_47: $i > $i).
% 28.89/28.91  tff(decl_3343, type, fn_active_transport_by_sodium_potassium_pump_48: $i > $i).
% 28.89/28.91  tff(decl_3344, type, fn_active_transport_by_sodium_potassium_pump_49: $i > $i).
% 28.89/28.91  tff(decl_3345, type, fn_active_transport_by_sodium_potassium_pump_50: $i > $i).
% 28.89/28.91  tff(decl_3346, type, fn_active_transport_by_sodium_potassium_pump_51: $i > $i).
% 28.89/28.91  tff(decl_3347, type, fn_active_transport_by_sodium_potassium_pump_52: $i > $i).
% 28.89/28.91  tff(decl_3348, type, fn_active_transport_by_sodium_potassium_pump_53: $i > $i).
% 28.89/28.91  tff(decl_3349, type, fn_active_transport_by_sodium_potassium_pump_54: $i > $i).
% 28.89/28.91  tff(decl_3350, type, fn_active_transport_by_sodium_potassium_pump_55: $i > $i).
% 28.89/28.91  tff(decl_3351, type, fn_active_transport_by_sodium_potassium_pump_56: $i > $i).
% 28.89/28.91  tff(decl_3352, type, fn_active_transport_by_sodium_potassium_pump_57: $i > $i).
% 28.89/28.91  tff(decl_3353, type, fn_active_transport_by_sodium_potassium_pump_58: $i > $i).
% 28.89/28.91  tff(decl_3354, type, fn_active_transport_by_sodium_potassium_pump_59: $i > $i).
% 28.89/28.91  tff(decl_3355, type, fn_active_transport_by_sodium_potassium_pump_60: $i > $i).
% 28.89/28.91  tff(decl_3356, type, fn_active_transport_by_sodium_potassium_pump_61: $i > $i).
% 28.89/28.91  tff(decl_3357, type, nucleoside_1: $i > $o).
% 28.89/28.91  tff(decl_3358, type, fn_active_transport_by_sodium_potassium_pump_62: $i > $i).
% 28.89/28.91  tff(decl_3359, type, pentose_1: $i > $o).
% 28.89/28.91  tff(decl_3360, type, ribose_1: $i > $o).
% 28.89/28.91  tff(decl_3361, type, fn_active_transport_by_sodium_potassium_pump_63: $i > $i).
% 28.89/28.91  tff(decl_3362, type, hydrophobic_compound_1: $i > $o).
% 28.89/28.91  tff(decl_3363, type, fn_active_transport_by_sodium_potassium_pump_64: $i > $i).
% 28.89/28.91  tff(decl_3364, type, fn_active_transport_by_sodium_potassium_pump_65: $i > $i).
% 28.89/28.91  tff(decl_3365, type, fn_active_transport_by_sodium_potassium_pump_66: $i > $i).
% 28.89/28.91  tff(decl_3366, type, fn_active_transport_by_sodium_potassium_pump_67: $i > $i).
% 28.89/28.91  tff(decl_3367, type, fn_active_transport_by_sodium_potassium_pump_68: $i > $i).
% 28.89/28.91  tff(decl_3368, type, fn_active_transport_by_sodium_potassium_pump_69: $i > $i).
% 28.89/28.91  tff(decl_3369, type, membrane_potential_1: $i > $o).
% 28.89/28.91  tff(decl_3370, type, fn_active_transport_by_sodium_potassium_pump_70: $i > $i).
% 28.89/28.91  tff(decl_3371, type, fn_active_transport_by_sodium_potassium_pump_71: $i > $i).
% 28.89/28.91  tff(decl_3372, type, fn_active_transport_by_sodium_potassium_pump_72: $i > $i).
% 28.89/28.91  tff(decl_3373, type, fn_active_transport_by_sodium_potassium_pump_73: $i > $i).
% 28.89/28.91  tff(decl_3374, type, fn_active_transport_by_sodium_potassium_pump_74: $i > $i).
% 28.89/28.91  tff(decl_3375, type, fn_active_transport_by_sodium_potassium_pump_75: $i > $i).
% 28.89/28.91  tff(decl_3376, type, fn_active_transport_by_sodium_potassium_pump_76: $i > $i).
% 28.89/28.91  tff(decl_3377, type, fn_active_transport_by_sodium_potassium_pump_77: $i > $i).
% 28.89/28.91  tff(decl_3378, type, fn_active_transport_by_sodium_potassium_pump_78: $i > $i).
% 28.89/28.91  tff(decl_3379, type, fn_active_transport_by_sodium_potassium_pump_79: $i > $i).
% 28.89/28.91  tff(decl_3380, type, sodium_ion_1: $i > $o).
% 28.89/28.91  tff(decl_3381, type, fn_active_transport_by_sodium_potassium_pump_80: $i > $i).
% 28.89/28.91  tff(decl_3382, type, protein_pump_1: $i > $o).
% 28.89/28.91  tff(decl_3383, type, electrogenic_pump_1: $i > $o).
% 28.89/28.91  tff(decl_3384, type, sodium_potassium_pump_1: $i > $o).
% 28.89/28.91  tff(decl_3385, type, fn_active_transport_by_sodium_potassium_pump_81: $i > $i).
% 28.89/28.91  tff(decl_3386, type, detach_1: $i > $o).
% 28.89/28.91  tff(decl_3387, type, fn_active_transport_by_sodium_potassium_pump_82: $i > $i).
% 28.89/28.91  tff(decl_3388, type, ribonucleotide_1: $i > $o).
% 28.89/28.91  tff(decl_3389, type, nucleoside_triphosphate_1: $i > $o).
% 28.89/28.91  tff(decl_3390, type, atp_1: $i > $o).
% 28.89/28.91  tff(decl_3391, type, fn_active_transport_by_sodium_potassium_pump_83: $i > $i).
% 28.89/28.91  tff(decl_3392, type, fn_active_transport_by_sodium_potassium_pump_84: $i > $i).
% 28.89/28.91  tff(decl_3393, type, fn_active_transport_by_sodium_potassium_pump_85: $i > $i).
% 28.89/28.91  tff(decl_3394, type, fn_active_transport_by_sodium_potassium_pump_86: $i > $i).
% 28.89/28.91  tff(decl_3395, type, fn_active_transport_by_sodium_potassium_pump_87: $i > $i).
% 28.89/28.91  tff(decl_3396, type, fn_active_transport_by_sodium_potassium_pump_88: $i > $i).
% 28.89/28.91  tff(decl_3397, type, fn_active_transport_by_sodium_potassium_pump_89: $i > $i).
% 28.89/28.91  tff(decl_3398, type, fn_active_transport_by_sodium_potassium_pump_90: $i > $i).
% 28.89/28.91  tff(decl_3399, type, fn_active_transport_by_sodium_potassium_pump_91: $i > $i).
% 28.89/28.91  tff(decl_3400, type, fn_active_transport_by_sodium_potassium_pump_92: $i > $i).
% 28.89/28.91  tff(decl_3401, type, fn_active_transport_by_sodium_potassium_pump_93: $i > $i).
% 28.89/28.91  tff(decl_3402, type, fn_active_transport_by_sodium_potassium_pump_94: $i > $i).
% 28.89/28.91  tff(decl_3403, type, fn_active_transport_by_sodium_potassium_pump_95: $i > $i).
% 28.89/28.91  tff(decl_3404, type, fn_active_transport_by_sodium_potassium_pump_96: $i > $i).
% 28.89/28.91  tff(decl_3405, type, fn_active_transport_by_sodium_potassium_pump_97: $i > $i).
% 28.89/28.91  tff(decl_3406, type, fn_active_transport_by_sodium_potassium_pump_98: $i > $i).
% 28.89/28.91  tff(decl_3407, type, fn_active_transport_by_sodium_potassium_pump_99: $i > $i).
% 28.89/28.91  tff(decl_3408, type, fn_active_transport_by_sodium_potassium_pump_100: $i > $i).
% 28.89/28.91  tff(decl_3409, type, fn_active_transport_by_sodium_potassium_pump_101: $i > $i).
% 28.89/28.91  tff(decl_3410, type, fn_active_transport_by_sodium_potassium_pump_102: $i > $i).
% 28.89/28.91  tff(decl_3411, type, fn_active_transport_by_sodium_potassium_pump_103: $i > $i).
% 28.89/28.91  tff(decl_3412, type, fn_active_transport_by_sodium_potassium_pump_104: $i > $i).
% 28.89/28.91  tff(decl_3413, type, fn_active_transport_by_sodium_potassium_pump_105: $i > $i).
% 28.89/28.91  tff(decl_3414, type, fn_active_transport_by_sodium_potassium_pump_106: $i > $i).
% 28.89/28.91  tff(decl_3415, type, fn_active_transport_by_sodium_potassium_pump_107: $i > $i).
% 28.89/28.91  tff(decl_3416, type, fn_active_transport_by_sodium_potassium_pump_112: $i > $i).
% 28.89/28.91  tff(decl_3417, type, fn_active_transport_by_sodium_potassium_pump_113: $i > $i).
% 28.89/28.91  tff(decl_3418, type, dephosphorylation_1: $i > $o).
% 28.89/28.91  tff(decl_3419, type, fn_active_transport_by_sodium_potassium_pump_114: $i > $i).
% 28.89/28.91  tff(decl_3420, type, fn_active_transport_by_sodium_potassium_pump_115: $i > $i).
% 28.89/28.91  tff(decl_3421, type, fn_active_transport_by_sodium_potassium_pump_116: $i > $i).
% 28.89/28.91  tff(decl_3422, type, fn_active_transport_by_sodium_potassium_pump_117: $i > $i).
% 28.89/28.91  tff(decl_3423, type, fn_active_transport_by_sodium_potassium_pump_118: $i > $i).
% 28.89/28.91  tff(decl_3424, type, fn_active_transport_using_atp_41: $i > $i).
% 28.89/28.91  tff(decl_3425, type, fn_active_transport_using_atp_26: $i > $i).
% 28.89/28.91  tff(decl_3426, type, fn_carrier_protein_8: $i > $i).
% 28.89/28.91  tff(decl_3427, type, fn_carrier_protein_13: $i > $i).
% 28.89/28.91  tff(decl_3428, type, fn_electrogenic_pump_2: $i > $i).
% 28.89/28.91  tff(decl_3429, type, fn_protein_pump_2: $i > $i).
% 28.89/28.91  tff(decl_3430, type, fn_active_transport_using_atp_91: $i > $i).
% 28.89/28.91  tff(decl_3431, type, fn_active_transport_using_atp_44: $i > $i).
% 28.89/28.91  tff(decl_3432, type, fn_active_transport_using_atp_47: $i > $i).
% 28.89/28.91  tff(decl_3433, type, fn_active_transport_using_atp_57: $i > $i).
% 28.89/28.91  tff(decl_3434, type, fn_active_transport_using_atp_51: $i > $i).
% 28.89/28.91  tff(decl_3435, type, fn_active_transport_using_atp_67: $i > $i).
% 28.89/28.91  tff(decl_3436, type, fn_sodium_potassium_pump_44: $i > $i).
% 28.89/28.91  tff(decl_3437, type, fn_sodium_potassium_pump_45: $i > $i).
% 28.89/28.91  tff(decl_3438, type, fn_sodium_potassium_pump_38: $i > $i).
% 28.89/28.91  tff(decl_3439, type, fn_sodium_potassium_pump_36: $i > $i).
% 28.89/28.91  tff(decl_3440, type, fn_sodium_potassium_pump_35: $i > $i).
% 28.89/28.91  tff(decl_3441, type, fn_sodium_potassium_pump_52: $i > $i).
% 28.89/28.91  tff(decl_3442, type, fn_atp_23: $i > $i).
% 28.89/28.91  tff(decl_3443, type, fn_atp_22: $i > $i).
% 28.89/28.91  tff(decl_3444, type, fn_atp_67: $i > $i).
% 28.89/28.91  tff(decl_3445, type, fn_atp_68: $i > $i).
% 28.89/28.91  tff(decl_3446, type, fn_atp_7: $i > $i).
% 28.89/28.91  tff(decl_3447, type, fn_atp_33: $i > $i).
% 28.89/28.91  tff(decl_3448, type, fn_detach_1: $i > $i).
% 28.89/28.91  tff(decl_3449, type, fn_block_1: $i > $i).
% 28.89/28.91  tff(decl_3450, type, fn_active_transport_using_atp_46: $i > $i).
% 28.89/28.91  tff(decl_3451, type, fn_electrogenic_pump_13: $i > $i).
% 28.89/28.91  tff(decl_3452, type, fn_electrogenic_pump_17: $i > $i).
% 28.89/28.91  tff(decl_3453, type, fn_active_transport_using_atp_24: $i > $i).
% 28.89/28.91  tff(decl_3454, type, fn_ribonucleotide_10: $i > $i).
% 28.89/28.91  tff(decl_3455, type, fn_active_transport_using_atp_63: $i > $i).
% 28.89/28.91  tff(decl_3456, type, fn_ribonucleotide_9: $i > $i).
% 28.89/28.91  tff(decl_3457, type, fn_active_transport_using_atp_69: $i > $i).
% 28.89/28.91  tff(decl_3458, type, fn_atp_28: $i > $i).
% 28.89/28.91  tff(decl_3459, type, fn_active_transport_using_atp_16: $i > $i).
% 28.89/28.91  tff(decl_3460, type, fn_active_transport_using_atp_49: $i > $i).
% 28.89/28.91  tff(decl_3461, type, fn_electrogenic_pump_11: $i > $i).
% 28.89/28.91  tff(decl_3462, type, fn_sodium_potassium_pump_28: $i > $i).
% 28.89/28.91  tff(decl_3463, type, fn_electrogenic_pump_15: $i > $i).
% 28.89/28.91  tff(decl_3464, type, fn_sodium_potassium_pump_26: $i > $i).
% 28.89/28.91  tff(decl_3465, type, fn_electrogenic_pump_14: $i > $i).
% 28.89/28.91  tff(decl_3466, type, fn_electrogenic_pump_19: $i > $i).
% 28.89/28.91  tff(decl_3467, type, fn_sodium_potassium_pump_22: $i > $i).
% 28.89/28.91  tff(decl_3468, type, fn_molecule_9: $i > $i).
% 28.89/28.91  tff(decl_3469, type, fn_sodium_potassium_pump_37: $i > $i).
% 28.89/28.91  tff(decl_3470, type, fn_sodium_potassium_pump_23: $i > $i).
% 28.89/28.91  tff(decl_3471, type, fn_sodium_potassium_pump_33: $i > $i).
% 28.89/28.91  tff(decl_3472, type, fn_electrogenic_pump_10: $i > $i).
% 28.89/28.91  tff(decl_3473, type, fn_sodium_potassium_pump_10: $i > $i).
% 28.89/28.91  tff(decl_3474, type, fn_electrogenic_pump_23: $i > $i).
% 28.89/28.91  tff(decl_3475, type, fn_sodium_potassium_pump_16: $i > $i).
% 28.89/28.91  tff(decl_3476, type, fn_electrogenic_pump_22: $i > $i).
% 28.89/28.91  tff(decl_3477, type, fn_sodium_potassium_pump_17: $i > $i).
% 28.89/28.91  tff(decl_3478, type, fn_electrogenic_pump_20: $i > $i).
% 28.89/28.91  tff(decl_3479, type, fn_sodium_potassium_pump_32: $i > $i).
% 28.89/28.91  tff(decl_3480, type, fn_detach_2: $i > $i).
% 28.89/28.91  tff(decl_3481, type, fn_phosphorylation_2: $i > $i).
% 28.89/28.91  tff(decl_3482, type, fn_dephosphorylation_11: $i > $i).
% 28.89/28.91  tff(decl_3483, type, fn_transmembrane_protein_5: $i > $i).
% 28.89/28.91  tff(decl_3484, type, fn_electrogenic_pump_4: $i > $i).
% 28.89/28.91  tff(decl_3485, type, fn_sodium_potassium_pump_51: $i > $i).
% 28.89/28.91  tff(decl_3486, type, fn_electrogenic_pump_37: $i > $i).
% 28.89/28.91  tff(decl_3487, type, fn_electrogenic_pump_32: $i > $i).
% 28.89/28.91  tff(decl_3488, type, fn_electrogenic_pump_34: $i > $i).
% 28.89/28.91  tff(decl_3489, type, fn_active_transport_using_atp_34: $i > $i).
% 28.89/28.91  tff(decl_3490, type, fn_electrogenic_pump_12: $i > $i).
% 28.89/28.91  tff(decl_3491, type, fn_active_transport_using_atp_35: $i > $i).
% 28.89/28.91  tff(decl_3492, type, fn_active_transport_using_atp_10: $i > $i).
% 28.89/28.91  tff(decl_3493, type, fn_electrogenic_pump_24: $i > $i).
% 28.89/28.91  tff(decl_3494, type, fn_carrier_protein_20: $i > $i).
% 28.89/28.91  tff(decl_3495, type, fn_sodium_potassium_pump_12: $i > $i).
% 28.89/28.91  tff(decl_3496, type, fn_sodium_potassium_pump_25: $i > $i).
% 28.89/28.91  tff(decl_3497, type, fn_sodium_potassium_pump_29: $i > $i).
% 28.89/28.91  tff(decl_3498, type, fn_sodium_potassium_pump_24: $i > $i).
% 28.89/28.91  tff(decl_3499, type, fn_sodium_potassium_pump_31: $i > $i).
% 28.89/28.91  tff(decl_3500, type, fn_sodium_potassium_pump_30: $i > $i).
% 28.89/28.91  tff(decl_3501, type, fn_sodium_potassium_pump_42: $i > $i).
% 28.89/28.91  tff(decl_3502, type, fn_electrogenic_pump_28: $i > $i).
% 28.89/28.91  tff(decl_3503, type, fn_decomposition_reaction_2: $i > $i).
% 28.89/28.91  tff(decl_3504, type, fn_decomposition_reaction_4: $i > $i).
% 28.89/28.91  tff(decl_3505, type, fn_transmembrane_protein_4: $i > $i).
% 28.89/28.91  tff(decl_3506, type, fn_protein_pump_3: $i > $i).
% 28.89/28.91  tff(decl_3507, type, fn_electrogenic_pump_30: $i > $i).
% 28.89/28.91  tff(decl_3508, type, fn_sodium_potassium_pump_41: $i > $i).
% 28.89/28.91  tff(decl_3509, type, fn_transport_protein_10: $i > $i).
% 28.89/28.91  tff(decl_3510, type, fn_transport_protein_34: $i > $i).
% 28.89/28.91  tff(decl_3511, type, fn_protein_pump_1: $i > $i).
% 28.89/28.91  tff(decl_3512, type, fn_electrogenic_pump_35: $i > $i).
% 28.89/28.91  tff(decl_3513, type, fn_electrogenic_pump_5: $i > $i).
% 28.89/28.91  tff(decl_3514, type, fn_sodium_potassium_pump_39: $i > $i).
% 28.89/28.91  tff(decl_3515, type, fn_sodium_potassium_pump_50: $i > $i).
% 28.89/28.91  tff(decl_3516, type, fn_active_transport_using_atp_23: $i > $i).
% 28.89/28.91  tff(decl_3517, type, fn_carrier_protein_19: $i > $i).
% 28.89/28.91  tff(decl_3518, type, fn_sodium_potassium_pump_21: $i > $i).
% 28.89/28.91  tff(decl_3519, type, fn_active_transport_using_atp_39: $i > $i).
% 28.89/28.91  tff(decl_3520, type, fn_electrogenic_pump_9: $i > $i).
% 28.89/28.91  tff(decl_3521, type, fn_carrier_protein_17: $i > $i).
% 28.89/28.91  tff(decl_3522, type, fn_sodium_potassium_pump_19: $i > $i).
% 28.89/28.91  tff(decl_3523, type, fn_active_transport_using_atp_31: $i > $i).
% 28.89/28.91  tff(decl_3524, type, fn_active_transport_using_atp_32: $i > $i).
% 28.89/28.91  tff(decl_3525, type, fn_active_transport_using_atp_48: $i > $i).
% 28.89/28.91  tff(decl_3526, type, fn_active_transport_using_atp_22: $i > $i).
% 28.89/28.91  tff(decl_3527, type, fn_atp_66: $i > $i).
% 28.89/28.91  tff(decl_3528, type, fn_nucleoside_20: $i > $i).
% 28.89/28.91  tff(decl_3529, type, fn_atp_50: $i > $i).
% 28.89/28.91  tff(decl_3530, type, fn_active_transport_using_atp_65: $i > $i).
% 28.89/28.91  tff(decl_3531, type, fn_atp_69: $i > $i).
% 28.89/28.91  tff(decl_3532, type, fn_nucleoside_triphosphate_30: $i > $i).
% 28.89/28.91  tff(decl_3533, type, fn_atp_31: $i > $i).
% 28.89/28.91  tff(decl_3534, type, fn_nucleoside_triphosphate_31: $i > $i).
% 28.89/28.91  tff(decl_3535, type, fn_atp_39: $i > $i).
% 28.89/28.91  tff(decl_3536, type, fn_ribonucleotide_17: $i > $i).
% 28.89/28.91  tff(decl_3537, type, fn_nucleoside_triphosphate_33: $i > $i).
% 28.89/28.91  tff(decl_3538, type, fn_atp_36: $i > $i).
% 28.89/28.91  tff(decl_3539, type, fn_ribonucleotide_12: $i > $i).
% 28.89/28.91  tff(decl_3540, type, fn_nucleoside_triphosphate_35: $i > $i).
% 28.89/28.91  tff(decl_3541, type, fn_atp_30: $i > $i).
% 28.89/28.91  tff(decl_3542, type, fn_active_transport_using_atp_64: $i > $i).
% 28.89/28.91  tff(decl_3543, type, fn_atp_25: $i > $i).
% 28.89/28.91  tff(decl_3544, type, fn_ribonucleotide_14: $i > $i).
% 28.89/28.91  tff(decl_3545, type, fn_nucleoside_triphosphate_27: $i > $i).
% 28.89/28.91  tff(decl_3546, type, fn_atp_34: $i > $i).
% 28.89/28.91  tff(decl_3547, type, fn_atp_32: $i > $i).
% 28.89/28.91  tff(decl_3548, type, fn_ribonucleotide_8: $i > $i).
% 28.89/28.91  tff(decl_3549, type, fn_ribonucleotide_16: $i > $i).
% 28.89/28.91  tff(decl_3550, type, fn_nucleoside_triphosphate_32: $i > $i).
% 28.89/28.91  tff(decl_3551, type, fn_nucleoside_triphosphate_29: $i > $i).
% 28.89/28.91  tff(decl_3552, type, fn_atp_37: $i > $i).
% 28.89/28.91  tff(decl_3553, type, fn_atp_35: $i > $i).
% 28.89/28.91  tff(decl_3554, type, fn_ribonucleotide_13: $i > $i).
% 28.89/28.91  tff(decl_3555, type, fn_nucleoside_triphosphate_28: $i > $i).
% 28.89/28.91  tff(decl_3556, type, fn_atp_29: $i > $i).
% 28.89/28.91  tff(decl_3557, type, fn_active_transport_using_atp_45: $i > $i).
% 28.89/28.91  tff(decl_3558, type, fn_active_transport_using_atp_53: $i > $i).
% 28.89/28.91  tff(decl_3559, type, fn_active_transport_using_atp_54: $i > $i).
% 28.89/28.91  tff(decl_3560, type, 'Terminal PO4 Group': $i).
% 28.89/28.91  tff(decl_3561, type, fn_cellular_work_12: $i > $i).
% 28.89/28.91  tff(decl_3562, type, fn_active_transport_by_sodium_potassium_pump_109: $i > $i).
% 28.89/28.91  tff(decl_3563, type, fn_active_transport_by_sodium_potassium_pump_108: $i > $i).
% 28.89/28.91  tff(decl_3564, type, fn_active_transport_by_sodium_potassium_pump_110: $i > $i).
% 28.89/28.91  tff(decl_3565, type, fn_active_transport_by_sodium_potassium_pump_111: $i > $i).
% 28.89/28.91  tff(decl_3566, type, fn_active_transport_by_sodium_potassium_pump_31: $i > $i).
% 28.89/28.91  tff(decl_3567, type, fn_active_transport_by_sodium_potassium_pump_32: $i > $i).
% 28.89/28.91  tff(decl_3568, type, fn_active_transport_by_sodium_potassium_pump_9: $i > $i).
% 28.89/28.91  tff(decl_3569, type, fn_active_transport_by_sodium_potassium_pump_8: $i > $i).
% 28.89/28.91  tff(decl_3570, type, fn_cellular_work_10: $i > $i).
% 28.89/28.91  tff(decl_3571, type, fn_cellular_work_16: $i > $i).
% 28.89/28.91  tff(decl_3572, type, 'Active-Transport-Using-ATP': $i).
% 28.89/28.91  tff(decl_3573, type, 'Active transport using ATP is the movement of a substance against its concentration energy (from low to high concentration) with the expenditure of the energy derived from ATP.': $i).
% 28.89/28.91  tff(decl_3574, type, 'active transport using atp': $i).
% 28.89/28.91  tff(decl_3575, type, 'active-transport-using-atp': $i).
% 28.89/28.91  tff(decl_3576, type, fn_active_transport_using_atp_3: $i > $i).
% 28.89/28.91  tff(decl_3577, type, fn_active_transport_using_atp_4: $i > $i).
% 28.89/28.91  tff(decl_3578, type, fn_active_transport_using_atp_5: $i > $i).
% 28.89/28.91  tff(decl_3579, type, fn_active_transport_using_atp_6: $i > $i).
% 28.89/28.91  tff(decl_3580, type, fn_active_transport_using_atp_7: $i > $i).
% 28.89/28.91  tff(decl_3581, type, fn_active_transport_using_atp_8: $i > $i).
% 28.89/28.91  tff(decl_3582, type, fn_active_transport_using_atp_9: $i > $i).
% 28.89/28.91  tff(decl_3583, type, fn_active_transport_using_atp_12: $i > $i).
% 28.89/28.91  tff(decl_3584, type, fn_active_transport_using_atp_13: $i > $i).
% 28.89/28.91  tff(decl_3585, type, resource_1: $i > $o).
% 28.89/28.91  tff(decl_3586, type, fn_active_transport_using_atp_14: $i > $i).
% 28.89/28.91  tff(decl_3587, type, fn_active_transport_using_atp_15: $i > $i).
% 28.89/28.91  tff(decl_3588, type, fn_active_transport_using_atp_17: $i > $i).
% 28.89/28.91  tff(decl_3589, type, fn_active_transport_using_atp_18: $i > $i).
% 28.89/28.91  tff(decl_3590, type, fn_active_transport_using_atp_19: $i > $i).
% 28.89/28.91  tff(decl_3591, type, fn_active_transport_using_atp_20: $i > $i).
% 28.89/28.91  tff(decl_3592, type, fn_active_transport_using_atp_21: $i > $i).
% 28.89/28.91  tff(decl_3593, type, fn_active_transport_using_atp_25: $i > $i).
% 28.89/28.91  tff(decl_3594, type, free_energy_1: $i > $o).
% 28.89/28.91  tff(decl_3595, type, fn_active_transport_using_atp_27: $i > $i).
% 28.89/28.91  tff(decl_3596, type, fn_active_transport_using_atp_28: $i > $i).
% 28.89/28.91  tff(decl_3597, type, fn_active_transport_using_atp_29: $i > $i).
% 28.89/28.91  tff(decl_3598, type, fn_active_transport_using_atp_30: $i > $i).
% 28.89/28.91  tff(decl_3599, type, fn_active_transport_using_atp_33: $i > $i).
% 28.89/28.91  tff(decl_3600, type, fn_active_transport_using_atp_36: $i > $i).
% 28.89/28.91  tff(decl_3601, type, fn_active_transport_using_atp_37: $i > $i).
% 28.89/28.91  tff(decl_3602, type, fn_active_transport_using_atp_38: $i > $i).
% 28.89/28.91  tff(decl_3603, type, fn_active_transport_using_atp_40: $i > $i).
% 28.89/28.91  tff(decl_3604, type, fn_active_transport_using_atp_43: $i > $i).
% 28.89/28.91  tff(decl_3605, type, fn_active_transport_using_atp_50: $i > $i).
% 28.89/28.91  tff(decl_3606, type, consume_1: $i > $o).
% 28.89/28.91  tff(decl_3607, type, fn_active_transport_using_atp_52: $i > $i).
% 28.89/28.91  tff(decl_3608, type, fn_active_transport_using_atp_55: $i > $i).
% 28.89/28.91  tff(decl_3609, type, fn_active_transport_using_atp_56: $i > $i).
% 28.89/28.91  tff(decl_3610, type, fn_active_transport_using_atp_58: $i > $i).
% 28.89/28.91  tff(decl_3611, type, fn_active_transport_using_atp_59: $i > $i).
% 28.89/28.91  tff(decl_3612, type, fn_active_transport_using_atp_60: $i > $i).
% 28.89/28.91  tff(decl_3613, type, fn_active_transport_using_atp_61: $i > $i).
% 28.89/28.91  tff(decl_3614, type, fn_active_transport_using_atp_62: $i > $i).
% 28.89/28.91  tff(decl_3615, type, fn_active_transport_using_atp_66: $i > $i).
% 28.89/28.91  tff(decl_3616, type, fn_active_transport_using_atp_68: $i > $i).
% 28.89/28.91  tff(decl_3617, type, fn_active_transport_using_atp_70: $i > $i).
% 28.89/28.91  tff(decl_3618, type, fn_active_transport_using_atp_71: $i > $i).
% 28.89/28.91  tff(decl_3619, type, fn_active_transport_using_atp_72: $i > $i).
% 28.89/28.91  tff(decl_3620, type, fn_active_transport_using_atp_73: $i > $i).
% 28.89/28.91  tff(decl_3621, type, fn_active_transport_using_atp_74: $i > $i).
% 28.89/28.91  tff(decl_3622, type, fn_active_transport_using_atp_75: $i > $i).
% 28.89/28.91  tff(decl_3623, type, fn_active_transport_using_atp_78: $i > $i).
% 28.89/28.91  tff(decl_3624, type, fn_active_transport_using_atp_79: $i > $i).
% 28.89/28.91  tff(decl_3625, type, fn_active_transport_using_atp_80: $i > $i).
% 28.89/28.91  tff(decl_3626, type, fn_active_transport_using_atp_81: $i > $i).
% 28.89/28.91  tff(decl_3627, type, fn_active_transport_using_atp_82: $i > $i).
% 28.89/28.91  tff(decl_3628, type, fn_active_transport_using_atp_83: $i > $i).
% 28.89/28.91  tff(decl_3629, type, fn_active_transport_using_atp_84: $i > $i).
% 28.89/28.91  tff(decl_3630, type, fn_active_transport_using_atp_85: $i > $i).
% 28.89/28.91  tff(decl_3631, type, fn_active_transport_using_atp_86: $i > $i).
% 28.89/28.91  tff(decl_3632, type, fn_active_transport_using_atp_87: $i > $i).
% 28.89/28.91  tff(decl_3633, type, fn_active_transport_using_atp_88: $i > $i).
% 28.89/28.91  tff(decl_3634, type, fn_active_transport_using_atp_92: $i > $i).
% 28.89/28.91  tff(decl_3635, type, fn_remove_2: $i > $i).
% 28.89/28.91  tff(decl_3636, type, fn_remove_1: $i > $i).
% 28.89/28.91  tff(decl_3637, type, fn_phosphorylation_3: $i > $i).
% 28.89/28.91  tff(decl_3638, type, fn_phosphorylation_4: $i > $i).
% 28.89/28.91  tff(decl_3639, type, fn_polyatomic_ion_1: $i > $i).
% 28.89/28.91  tff(decl_3640, type, fn_polyatomic_ion_2: $i > $i).
% 28.89/28.91  tff(decl_3641, type, fn_organic_molecule_1: $i > $i).
% 28.89/28.91  tff(decl_3642, type, fn_chemical_bond_1: $i > $i).
% 28.89/28.91  tff(decl_3643, type, fn_chemical_bond_4: $i > $i).
% 28.89/28.91  tff(decl_3644, type, fn_consume_2: $i > $i).
% 28.89/28.91  tff(decl_3645, type, fn_consume_1: $i > $i).
% 28.89/28.91  tff(decl_3646, type, fn_polar_molecule_3: $i > $i).
% 28.89/28.91  tff(decl_3647, type, fn_molecule_7: $i > $i).
% 28.89/28.91  tff(decl_3648, type, fn_chemical_bond_2: $i > $i).
% 28.89/28.91  tff(decl_3649, type, fn_biomembrane_98: $i > $i).
% 28.89/28.91  tff(decl_3650, type, fn_biomembrane_99: $i > $i).
% 28.89/28.91  tff(decl_3651, type, fn_transport_protein_11: $i > $i).
% 28.89/28.91  tff(decl_3652, type, fn_transport_protein_12: $i > $i).
% 28.89/28.91  tff(decl_3653, type, fn_phosphorylation_5: $i > $i).
% 28.89/28.91  tff(decl_3654, type, fn_biomembrane_102: $i > $i).
% 28.89/28.91  tff(decl_3655, type, fn_biomembrane_100: $i > $i).
% 28.89/28.91  tff(decl_3656, type, fn_biomembrane_101: $i > $i).
% 28.89/28.91  tff(decl_3657, type, fn_transport_protein_31: $i > $i).
% 28.89/28.91  tff(decl_3658, type, fn_ribonucleotide_7: $i > $i).
% 28.89/28.91  tff(decl_3659, type, fn_phosphorylation_1: $i > $i).
% 28.89/28.91  tff(decl_3660, type, fn_endergonic_process_3: $i > $i).
% 28.89/28.91  tff(decl_3661, type, fn_endergonic_process_4: $i > $i).
% 28.89/28.91  tff(decl_3662, type, fn_cellular_work_13: $i > $i).
% 28.89/28.91  tff(decl_3663, type, fn_cellular_work_11: $i > $i).
% 28.89/28.91  tff(decl_3664, type, fn_cellular_work_14: $i > $i).
% 28.89/28.91  tff(decl_3665, type, fn_cellular_work_15: $i > $i).
% 28.89/28.91  tff(decl_3666, type, fn_active_transport_using_atp_42: $i > $i).
% 28.89/28.91  tff(decl_3667, type, fn_active_transport_using_atp_89: $i > $i).
% 28.89/28.91  tff(decl_3668, type, fn_active_transport_using_atp_90: $i > $i).
% 28.89/28.91  tff(decl_3669, type, fn_active_transport_using_atp_11: $i > $i).
% 28.89/28.91  tff(decl_3670, type, fn_active_transport_using_atp_76: $i > $i).
% 28.89/28.91  tff(decl_3671, type, fn_active_transport_using_atp_77: $i > $i).
% 28.89/28.91  tff(decl_3672, type, activity_1: $i > $o).
% 28.89/28.91  tff(decl_3673, type, 'Activity': $i).
% 28.89/28.91  tff(decl_3674, type, 'a collection of related events, often to achieve a goal or produce a result, but less structured than a step-by-step process': $i).
% 28.89/28.91  tff(decl_3675, type, activity: $i).
% 28.89/28.91  tff(decl_3676, type, 'human action': $i).
% 28.89/28.91  tff(decl_3677, type, human_action: $i).
% 28.89/28.91  tff(decl_3678, type, 'human activity': $i).
% 28.89/28.91  tff(decl_3679, type, human_activity: $i).
% 28.89/28.91  tff(decl_3680, type, adaptation_1: $i > $o).
% 28.89/28.91  tff(decl_3681, type, 'Adaptation': $i).
% 28.89/28.91  tff(decl_3682, type, 'Inherited characteristic of an organism that enhances its survival and reproduction in specific environments.': $i).
% 28.89/28.91  tff(decl_3683, type, adapt: $i).
% 28.89/28.91  tff(decl_3684, type, adaptation: $i).
% 28.89/28.91  tff(decl_3685, type, evolutionary_process_1: $i > $o).
% 28.89/28.91  tff(decl_3686, type, adaptive_radiation_1: $i > $o).
% 28.89/28.91  tff(decl_3687, type, allopatric_speciation_1: $i > $o).
% 28.89/28.91  tff(decl_3688, type, bottleneck_effect_1: $i > $o).
% 28.89/28.91  tff(decl_3689, type, character_displacement_1: $i > $o).
% 28.89/28.91  tff(decl_3690, type, cladogenesis_1: $i > $o).
% 28.89/28.91  tff(decl_3691, type, convergent_evolution_1: $i > $o).
% 28.89/28.91  tff(decl_3692, type, endosymbiosis_1: $i > $o).
% 28.89/28.91  tff(decl_3693, type, gene_flow_1: $i > $o).
% 28.89/28.91  tff(decl_3694, type, genetic_drift_1: $i > $o).
% 28.89/28.91  tff(decl_3695, type, heterochrony_1: $i > $o).
% 28.89/28.91  tff(decl_3696, type, homology_1: $i > $o).
% 28.89/28.91  tff(decl_3697, type, mechanical_isolation_1: $i > $o).
% 28.89/28.91  tff(decl_3698, type, natural_selection_1: $i > $o).
% 28.89/28.91  tff(decl_3699, type, paedomorphosis_1: $i > $o).
% 28.89/28.91  tff(decl_3700, type, punctuated_equilibria_1: $i > $o).
% 28.89/28.91  tff(decl_3701, type, reproductive_isolation_1: $i > $o).
% 28.89/28.91  tff(decl_3702, type, selection_force_1: $i > $o).
% 28.89/28.91  tff(decl_3703, type, speciation_1: $i > $o).
% 28.89/28.91  tff(decl_3704, type, adaptive_immunity_1: $i > $o).
% 28.89/28.91  tff(decl_3705, type, 'Adaptive-Immunity': $i).
% 28.89/28.91  tff(decl_3706, type, 'A vertebrate-specific defense that is mediated by B lymphocytes (B Cells) and T lymphocytes (T cells). It exhibits specificity, memory, andself-nonself recognition.': $i).
% 28.89/28.91  tff(decl_3707, type, 'specific immunity': $i).
% 28.89/28.91  tff(decl_3708, type, 'specific-immunity': $i).
% 28.89/28.91  tff(decl_3709, type, 'acquired immunity': $i).
% 28.89/28.91  tff(decl_3710, type, 'acquired-immunity': $i).
% 28.89/28.91  tff(decl_3711, type, 'perform adaptive immunity': $i).
% 28.89/28.91  tff(decl_3712, type, 'adaptive immunity': $i).
% 28.89/28.91  tff(decl_3713, type, 'adaptive-immunity': $i).
% 28.89/28.91  tff(decl_3714, type, immune_response_1: $i > $o).
% 28.89/28.91  tff(decl_3715, type, adaptive_management_1: $i > $o).
% 28.89/28.91  tff(decl_3716, type, 'Adaptive-Management': $i).
% 28.89/28.91  tff(decl_3717, type, 'The use of experimentation to try different types of ecological management to see which works best.': $i).
% 28.89/28.91  tff(decl_3718, type, 'perform adaptive management': $i).
% 28.89/28.91  tff(decl_3719, type, 'adaptive management': $i).
% 28.89/28.91  tff(decl_3720, type, 'adaptive-management': $i).
% 28.89/28.91  tff(decl_3721, type, bioremediation_1: $i > $o).
% 28.89/28.91  tff(decl_3722, type, phytoremediation_1: $i > $o).
% 28.89/28.91  tff(decl_3723, type, 'Adaptive-Radiation': $i).
% 28.89/28.91  tff(decl_3724, type, 'The evolution of morphological and ecological diversity within a clade in response to the opening of new ecological niches. Often results in speciation.': $i).
% 28.89/28.91  tff(decl_3725, type, 'adaptive radiation': $i).
% 28.89/28.91  tff(decl_3726, type, 'adaptive-radiation': $i).
% 28.89/28.91  tff(decl_3727, type, cephalization_1: $i > $o).
% 28.89/28.91  tff(decl_3728, type, mimicry_1: $i > $o).
% 28.89/28.91  tff(decl_3729, type, 'Add': $i).
% 28.89/28.91  tff(decl_3730, type, add: $i).
% 28.89/28.91  tff(decl_3731, type, include: $i).
% 28.89/28.91  tff(decl_3732, type, join: $i).
% 28.89/28.91  tff(decl_3733, type, add_volumes_1: $i > $o).
% 28.89/28.91  tff(decl_3734, type, 'Add-Volumes': $i).
% 28.89/28.91  tff(decl_3735, type, 'a method to add the volumes of multiple volumes': $i).
% 28.89/28.91  tff(decl_3736, type, 'add volume': $i).
% 28.89/28.91  tff(decl_3737, type, 'add-volume': $i).
% 28.89/28.91  tff(decl_3738, type, method_1: $i > $o).
% 28.89/28.91  tff(decl_3739, type, adenine_1: $i > $o).
% 28.89/28.91  tff(decl_3740, type, 'Adenine': $i).
% 28.89/28.91  tff(decl_3741, type, 'One of the five most common nitrogenous bases which make up nucleotide monomers of nucleic acids. Adenine is present in both DNA and RNA.': $i).
% 28.89/28.91  tff(decl_3742, type, adenine: $i).
% 28.89/28.91  tff(decl_3743, type, purine_1: $i > $o).
% 28.89/28.91  tff(decl_3744, type, guanine_1: $i > $o).
% 28.89/28.91  tff(decl_3745, type, nitrogenous_base_present_in_dna_1: $i > $o).
% 28.89/28.91  tff(decl_3746, type, dna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3747, type, adenine_at_dna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3748, type, fn_adenine_at_dna_strand_2: $i > $i).
% 28.89/28.91  tff(decl_3749, type, 'Adenine-At-DNA-Strand': $i).
% 28.89/28.91  tff(decl_3750, type, 'Adenine (A, Ade) is a nucleobase (a purine derivative) which is present at DNA.': $i).
% 28.89/28.91  tff(decl_3751, type, 'adenine at dna strand': $i).
% 28.89/28.91  tff(decl_3752, type, 'adenine-at-dna-strand': $i).
% 28.89/28.91  tff(decl_3753, type, adenine_at_rna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3754, type, cytosine_at_dna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3755, type, guanine_at_dna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3756, type, thymine_1: $i > $o).
% 28.89/28.91  tff(decl_3757, type, fn_nitrogenous_base_present_in_dna_2: $i > $i).
% 28.89/28.91  tff(decl_3758, type, adenine_at_dna_strand_opposite_to_dna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3759, type, fn_adenine_at_dna_strand_opposite_to_dna_strand_3: $i > $i).
% 28.89/28.91  tff(decl_3760, type, fn_adenine_at_dna_strand_opposite_to_dna_strand_2: $i > $i).
% 28.89/28.91  tff(decl_3761, type, 'Adenine-At-DNA-Strand-Opposite-To-DNA-Strand': $i).
% 28.89/28.91  tff(decl_3762, type, 'Adenine is a nitrogenous base which is present at DNA strand and is present opposite to other DNA strand having thymine.': $i).
% 28.89/28.91  tff(decl_3763, type, 'adenine at dna strand opposite to dna strand': $i).
% 28.89/28.91  tff(decl_3764, type, 'adenine-at-dna-strand-opposite-to-dna-strand': $i).
% 28.89/28.91  tff(decl_3765, type, adenine_at_dna_strand_opposite_to_rna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3766, type, fn_adenine_at_dna_strand_opposite_to_dna_strand_4: $i > $i).
% 28.89/28.91  tff(decl_3767, type, thymine_at_dna_strand_opposite_to_dna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3768, type, rna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3769, type, fn_adenine_at_dna_strand_opposite_to_rna_strand_3: $i > $i).
% 28.89/28.91  tff(decl_3770, type, fn_adenine_at_dna_strand_opposite_to_rna_strand_5: $i > $i).
% 28.89/28.91  tff(decl_3771, type, uracil_at_rna_strand_opposite_to_dna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3772, type, fn_adenine_at_dna_strand_opposite_to_rna_strand_4: $i > $i).
% 28.89/28.91  tff(decl_3773, type, 'Adenine-At-DNA-Strand-Opposite-To-RNA-Strand': $i).
% 28.89/28.91  tff(decl_3774, type, 'Adenine is a nitrogenous base which is present at DNA strand and is present opposite to RNA strand having Uracil.': $i).
% 28.89/28.91  tff(decl_3775, type, 'adenine at dna strand opposite to rna strand': $i).
% 28.89/28.91  tff(decl_3776, type, 'adenine-at-dna-strand-opposite-to-rna-strand': $i).
% 28.89/28.91  tff(decl_3777, type, fn_nitrogenous_base_present_in_rna_2: $i > $i).
% 28.89/28.91  tff(decl_3778, type, nitrogenous_base_present_in_rna_1: $i > $o).
% 28.89/28.91  tff(decl_3779, type, fn_adenine_at_rna_strand_2: $i > $i).
% 28.89/28.91  tff(decl_3780, type, 'Adenine-At-RNA-Strand': $i).
% 28.89/28.91  tff(decl_3781, type, 'Adenine (A, Ade) is a nucleobase (a purine derivative) which is present at RNA.': $i).
% 28.89/28.91  tff(decl_3782, type, 'adenine at rna strand': $i).
% 28.89/28.91  tff(decl_3783, type, 'adenine-at-rna-strand': $i).
% 28.89/28.91  tff(decl_3784, type, cytosine_at_rna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3785, type, guanine_at_rna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3786, type, uracil_at_rna_strand_opposite_to_rna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3787, type, adenine_at_rna_strand_opposite_to_dna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3788, type, fn_adenine_at_rna_strand_opposite_to_dna_strand_2: $i > $i).
% 28.89/28.91  tff(decl_3789, type, fn_adenine_at_rna_strand_opposite_to_dna_strand_4: $i > $i).
% 28.89/28.91  tff(decl_3790, type, 'Adenine-At-RNA-Strand-Opposite-To-DNA-Strand': $i).
% 28.89/28.91  tff(decl_3791, type, 'Adenine is a nitrogenous base which is present at RNA strand and is present opposite to other DNA strand having thymine.': $i).
% 28.89/28.91  tff(decl_3792, type, 'adenine at rna strand opposite to dna strand': $i).
% 28.89/28.91  tff(decl_3793, type, 'adenine-at-rna-strand-opposite-to-dna-strand': $i).
% 28.89/28.91  tff(decl_3794, type, adenine_at_rna_strand_opposite_to_rna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3795, type, fn_adenine_at_rna_strand_opposite_to_dna_strand_3: $i > $i).
% 28.89/28.91  tff(decl_3796, type, thymine_at_dna_strand_opposite_to_rna_strand_1: $i > $o).
% 28.89/28.91  tff(decl_3797, type, fn_thymine_at_dna_strand_opposite_to_rna_strand_1: $i > $i).
% 28.89/28.91  tff(decl_3798, type, fn_adenine_at_rna_strand_opposite_to_rna_strand_2: $i > $i).
% 28.89/28.91  tff(decl_3799, type, fn_adenine_at_rna_strand_opposite_to_rna_strand_4: $i > $i).
% 28.89/28.91  tff(decl_3800, type, 'Adenine-At-RNA-Strand-Opposite-To-RNA-Strand': $i).
% 28.89/28.91  tff(decl_3801, type, 'Adenine is a nitrogenous base which is present at RNA strand and is present opposite to other RNA strand having Uracil.': $i).
% 28.89/28.91  tff(decl_3802, type, 'adenine at rna strand opposite to rna strand': $i).
% 28.89/28.91  tff(decl_3803, type, 'adenine-at-rna-strand-opposite-to-rna-strand': $i).
% 28.89/28.91  tff(decl_3804, type, fn_adenine_at_rna_strand_opposite_to_rna_strand_3: $i > $i).
% 28.89/28.91  tff(decl_3805, type, adenosine_1: $i > $o).
% 28.89/28.91  tff(decl_3806, type, 'Adenosine': $i).
% 28.89/28.91  tff(decl_3807, type, 'Nucleoside formed by the binding of adenine and ribose.': $i).
% 28.89/28.91  tff(decl_3808, type, adenosine: $i).
% 28.89/28.91  tff(decl_3809, type, fn_adenosine_1: $i > $i).
% 28.89/28.91  tff(decl_3810, type, fn_adenosine_2: $i > $i).
% 28.89/28.91  tff(decl_3811, type, fn_nucleoside_21: $i > $i).
% 28.89/28.91  tff(decl_3812, type, adenovirus_1: $i > $o).
% 28.89/28.91  tff(decl_3813, type, 'Adenovirus': $i).
% 28.89/28.91  tff(decl_3814, type, 'A virus with a poyhedral capsule with a glycoprotein at each vertex.': $i).
% 28.89/28.91  tff(decl_3815, type, adenovirus: $i).
% 28.89/28.91  tff(decl_3816, type, dna_virus_1: $i > $o).
% 28.89/28.91  tff(decl_3817, type, tumor_virus_1: $i > $o).
% 28.89/28.91  tff(decl_3818, type, animal_virus_1: $i > $o).
% 28.89/28.91  tff(decl_3819, type, papovavirus_1: $i > $o).
% 28.89/28.91  tff(decl_3820, type, hiv_1: $i > $o).
% 28.89/28.91  tff(decl_3821, type, cowpox_virus_1: $i > $o).
% 28.89/28.91  tff(decl_3822, type, hepatitis_b_virus_1: $i > $o).
% 28.89/28.91  tff(decl_3823, type, herpesvirus_1: $i > $o).
% 28.89/28.91  tff(decl_3824, type, adenylyl_cyclase_1: $i > $o).
% 28.89/28.91  tff(decl_3825, type, 'Adenylyl-Cyclase': $i).
% 28.89/28.91  tff(decl_3826, type, 'An enzyme which catalyzes the conversion of ATP to cyclic AMP.': $i).
% 28.89/28.91  tff(decl_3827, type, 'adenylyl cyclase': $i).
% 28.89/28.91  tff(decl_3828, type, 'adenylyl-cyclase': $i).
% 28.89/28.91  tff(decl_3829, type, lyase_1: $i > $o).
% 28.89/28.91  tff(decl_3830, type, fn_adenylyl_cyclase_1: $i > $i).
% 28.89/28.91  tff(decl_3831, type, fn_adenylyl_cyclase_2: $i > $i).
% 28.89/28.91  tff(decl_3832, type, fn_adenylyl_cyclase_3: $i > $i).
% 28.89/28.91  tff(decl_3833, type, fn_adenylyl_cyclase_4: $i > $i).
% 28.89/28.91  tff(decl_3834, type, fn_adenylyl_cyclase_5: $i > $i).
% 28.89/28.91  tff(decl_3835, type, fn_protein_14: $i > $i).
% 28.89/28.91  tff(decl_3836, type, fn_protein_8: $i > $i).
% 28.89/28.91  tff(decl_3837, type, adhesion_1: $i > $o).
% 28.89/28.91  tff(decl_3838, type, 'Adhesion': $i).
% 28.89/28.91  tff(decl_3839, type, 'The  sticking together of two dissimilar molecules resulting from molecular interactions between them.': $i).
% 28.89/28.91  tff(decl_3840, type, adhere: $i).
% 28.89/28.91  tff(decl_3841, type, adhesion: $i).
% 28.89/28.91  tff(decl_3842, type, cohesion_1: $i > $o).
% 28.89/28.91  tff(decl_3843, type, fn_adhesion_1: $i > $i).
% 28.89/28.91  tff(decl_3844, type, fn_adhesion_2: $i > $i).
% 28.89/28.91  tff(decl_3845, type, fn_attract_2: $i > $i).
% 28.89/28.91  tff(decl_3846, type, fn_attract_1: $i > $i).
% 28.89/28.91  tff(decl_3847, type, adipose_cell_1: $i > $o).
% 28.89/28.91  tff(decl_3848, type, 'Adipose-Cell': $i).
% 28.89/28.91  tff(decl_3849, type, 'A cell that contains fat as a stored form of energy': $i).
% 28.89/28.91  tff(decl_3850, type, 'adipose cell': $i).
% 28.89/28.91  tff(decl_3851, type, 'adipose-cell': $i).
% 28.89/28.91  tff(decl_3852, type, fn_adipose_cell_1: $i > $i).
% 28.89/28.91  tff(decl_3853, type, chromosome_arm_1: $i > $o).
% 28.89/28.91  tff(decl_3854, type, fn_adipose_cell_2: $i > $i).
% 28.89/28.91  tff(decl_3855, type, fn_adipose_cell_3: $i > $i).
% 28.89/28.91  tff(decl_3856, type, peroxisome_1: $i > $o).
% 28.89/28.91  tff(decl_3857, type, fn_adipose_cell_4: $i > $i).
% 28.89/28.91  tff(decl_3858, type, fn_adipose_cell_7: $i > $i).
% 28.89/28.91  tff(decl_3859, type, cellular_work_1: $i > $o).
% 28.89/28.91  tff(decl_3860, type, generation_of_hydrogen_ion_gradient_across_biomembrane_1: $i > $o).
% 28.89/28.91  tff(decl_3861, type, fn_adipose_cell_8: $i > $i).
% 28.89/28.91  tff(decl_3862, type, endoplasmic_reticulum_1: $i > $o).
% 28.89/28.91  tff(decl_3863, type, rough_endoplasmic_reticulum_1: $i > $o).
% 28.89/28.91  tff(decl_3864, type, fn_adipose_cell_9: $i > $i).
% 28.89/28.91  tff(decl_3865, type, smooth_endoplasmic_reticulum_1: $i > $o).
% 28.89/28.91  tff(decl_3866, type, fn_adipose_cell_10: $i > $i).
% 28.89/28.91  tff(decl_3867, type, support_1: $i > $o).
% 28.89/28.91  tff(decl_3868, type, fn_adipose_cell_11: $i > $i).
% 28.89/28.91  tff(decl_3869, type, fn_adipose_cell_12: $i > $i).
% 28.89/28.91  tff(decl_3870, type, fn_adipose_cell_13: $i > $i).
% 28.89/28.91  tff(decl_3871, type, fn_adipose_cell_14: $i > $i).
% 28.89/28.91  tff(decl_3872, type, fn_adipose_cell_15: $i > $i).
% 28.89/28.91  tff(decl_3873, type, fn_adipose_cell_16: $i > $i).
% 28.89/28.91  tff(decl_3874, type, produce_1: $i > $o).
% 28.89/28.91  tff(decl_3875, type, fn_adipose_cell_17: $i > $i).
% 28.89/28.91  tff(decl_3876, type, microtubule_1: $i > $o).
% 28.89/28.91  tff(decl_3877, type, fn_adipose_cell_18: $i > $i).
% 28.89/28.91  tff(decl_3878, type, fn_adipose_cell_19: $i > $i).
% 28.89/28.91  tff(decl_3879, type, telomere_1: $i > $o).
% 28.89/28.91  tff(decl_3880, type, fn_adipose_cell_20: $i > $i).
% 28.89/28.91  tff(decl_3881, type, fn_adipose_cell_21: $i > $i).
% 28.89/28.91  tff(decl_3882, type, fn_adipose_cell_22: $i > $i).
% 28.89/28.91  tff(decl_3883, type, coil_1: $i > $o).
% 28.89/28.91  tff(decl_3884, type, fn_adipose_cell_23: $i > $i).
% 28.89/28.91  tff(decl_3885, type, eukaryotic_chromosome_1: $i > $o).
% 28.89/28.91  tff(decl_3886, type, chromosome_1: $i > $o).
% 28.89/28.91  tff(decl_3887, type, fn_adipose_cell_24: $i > $i).
% 28.89/28.91  tff(decl_3888, type, centrosome_1: $i > $o).
% 28.89/28.91  tff(decl_3889, type, fn_adipose_cell_25: $i > $i).
% 28.89/28.91  tff(decl_3890, type, golgi_apparatus_1: $i > $o).
% 28.89/28.91  tff(decl_3891, type, fn_adipose_cell_26: $i > $i).
% 28.89/28.91  tff(decl_3892, type, hydrophobic_core_1: $i > $o).
% 28.89/28.91  tff(decl_3893, type, fn_adipose_cell_27: $i > $i).
% 28.89/28.91  tff(decl_3894, type, fn_adipose_cell_28: $i > $i).
% 28.89/28.91  tff(decl_3895, type, fn_adipose_cell_29: $i > $i).
% 28.89/28.91  tff(decl_3896, type, fn_adipose_cell_30: $i > $i).
% 28.89/28.91  tff(decl_3897, type, fn_adipose_cell_31: $i > $i).
% 28.89/28.91  tff(decl_3898, type, eukaryotic_ribosome_1: $i > $o).
% 28.89/28.91  tff(decl_3899, type, fn_adipose_cell_32: $i > $i).
% 28.89/28.91  tff(decl_3900, type, fn_adipose_cell_33: $i > $i).
% 28.89/28.91  tff(decl_3901, type, semiautonomous_organelle_1: $i > $o).
% 28.89/28.91  tff(decl_3902, type, organelle_1: $i > $o).
% 28.89/28.91  tff(decl_3903, type, mitochondrion_1: $i > $o).
% 28.89/28.91  tff(decl_3904, type, fn_adipose_cell_34: $i > $i).
% 28.89/28.91  tff(decl_3905, type, eukaryotic_cellular_respiration_1: $i > $o).
% 28.89/28.91  tff(decl_3906, type, fn_adipose_cell_35: $i > $i).
% 28.89/28.91  tff(decl_3907, type, cytosol_1: $i > $o).
% 28.89/28.91  tff(decl_3908, type, fn_adipose_cell_36: $i > $i).
% 28.89/28.91  tff(decl_3909, type, fn_adipose_cell_37: $i > $i).
% 28.89/28.91  tff(decl_3910, type, fn_adipose_cell_38: $i > $i).
% 28.89/28.91  tff(decl_3911, type, extracellular_side_1: $i > $o).
% 28.89/28.91  tff(decl_3912, type, fn_adipose_cell_39: $i > $i).
% 28.89/28.91  tff(decl_3913, type, fn_adipose_cell_40: $i > $i).
% 28.89/28.91  tff(decl_3914, type, animal_plasma_membrane_1: $i > $o).
% 28.89/28.91  tff(decl_3915, type, fn_adipose_cell_41: $i > $i).
% 28.89/28.91  tff(decl_3916, type, fat_substance_1: $i > $o).
% 28.89/28.91  tff(decl_3917, type, fn_adipose_cell_42: $i > $i).
% 28.89/28.91  tff(decl_3918, type, store_1: $i > $o).
% 28.89/28.91  tff(decl_3919, type, fn_adipose_cell_43: $i > $i).
% 28.89/28.91  tff(decl_3920, type, fuel_1: $i > $o).
% 28.89/28.91  tff(decl_3921, type, fn_adipose_cell_44: $i > $i).
% 28.89/28.91  tff(decl_3922, type, fat_1: $i > $o).
% 28.89/28.91  tff(decl_3923, type, fn_adipose_cell_45: $i > $i).
% 28.89/28.91  tff(decl_3924, type, fn_adipose_cell_46: $i > $i).
% 28.89/28.91  tff(decl_3925, type, integrin_1: $i > $o).
% 28.89/28.91  tff(decl_3926, type, fn_adipose_cell_47: $i > $i).
% 28.89/28.91  tff(decl_3927, type, fn_adipose_cell_48: $i > $i).
% 28.89/28.91  tff(decl_3928, type, fn_adipose_cell_49: $i > $i).
% 28.89/28.91  tff(decl_3929, type, fn_adipose_cell_50: $i > $i).
% 28.89/28.91  tff(decl_3930, type, catabolic_pathway_1: $i > $o).
% 28.89/28.91  tff(decl_3931, type, fn_adipose_cell_51: $i > $i).
% 28.89/28.91  tff(decl_3932, type, metabolic_pathway_1: $i > $o).
% 28.89/28.91  tff(decl_3933, type, synthesis_of_organic_molecule_1: $i > $o).
% 28.89/28.91  tff(decl_3934, type, anabolic_pathway_1: $i > $o).
% 28.89/28.91  tff(decl_3935, type, synthesis_of_atp_1: $i > $o).
% 28.89/28.91  tff(decl_3936, type, fn_adipose_cell_52: $i > $i).
% 28.89/28.91  tff(decl_3937, type, eukaryotic_oxidative_phosphorylation_1: $i > $o).
% 28.89/28.91  tff(decl_3938, type, fn_adipose_cell_53: $i > $i).
% 28.89/28.91  tff(decl_3939, type, electron_transport_chain_pathway_1: $i > $o).
% 28.89/28.91  tff(decl_3940, type, fn_store_1: $i > $i).
% 28.89/28.91  tff(decl_3941, type, fn_chromosome_6: $i > $i).
% 28.89/28.91  tff(decl_3942, type, fn_chromosome_8: $i > $i).
% 28.89/28.91  tff(decl_3943, type, fn_chromosome_3: $i > $i).
% 28.89/28.91  tff(decl_3944, type, fn_telomere_1: $i > $i).
% 28.89/28.91  tff(decl_3945, type, fn_fuel_5: $i > $i).
% 28.89/28.91  tff(decl_3946, type, fn_fuel_6: $i > $i).
% 28.89/28.91  tff(decl_3947, type, fn_fuel_8: $i > $i).
% 28.89/28.91  tff(decl_3948, type, fn_smooth_endoplasmic_reticulum_3: $i > $i).
% 28.89/28.91  tff(decl_3949, type, fn_smooth_endoplasmic_reticulum_11: $i > $i).
% 28.89/28.91  tff(decl_3950, type, fn_mitochondrion_159: $i > $i).
% 28.89/28.91  tff(decl_3951, type, fn_mitochondrion_52: $i > $i).
% 28.89/28.91  tff(decl_3952, type, fn_mitochondrion_55: $i > $i).
% 28.89/28.91  tff(decl_3953, type, fn_fuel_7: $i > $i).
% 28.89/28.91  tff(decl_3954, type, fn_fat_substance_1: $i > $i).
% 28.89/28.91  tff(decl_3955, type, fn_eukaryotic_chromosome_3: $i > $i).
% 28.89/28.91  tff(decl_3956, type, fn_chromosome_4: $i > $i).
% 28.89/28.91  tff(decl_3957, type, fn_telomere_3: $i > $i).
% 28.89/28.91  tff(decl_3958, type, fn_smooth_endoplasmic_reticulum_12: $i > $i).
% 28.89/28.91  tff(decl_3959, type, fn_smooth_endoplasmic_reticulum_10: $i > $i).
% 28.89/28.91  tff(decl_3960, type, fn_smooth_endoplasmic_reticulum_34: $i > $i).
% 28.89/28.91  tff(decl_3961, type, fn_mitochondrion_160: $i > $i).
% 28.89/28.91  tff(decl_3962, type, fn_store_2: $i > $i).
% 28.89/28.91  tff(decl_3963, type, fn_smooth_endoplasmic_reticulum_33: $i > $i).
% 28.89/28.91  tff(decl_3964, type, fn_mitochondrion_51: $i > $i).
% 28.89/28.91  tff(decl_3965, type, prokaryote_0: $i).
% 28.89/28.91  tff(decl_3966, type, 'MP1': $i).
% 28.89/28.91  tff(decl_3967, type, fn_animal_cell_88: $i > $i).
% 28.89/28.91  tff(decl_3968, type, fn_animal_cell_90: $i > $i).
% 28.89/28.91  tff(decl_3969, type, fn_adipose_cell_6: $i > $i).
% 28.89/28.91  tff(decl_3970, type, fn_animal_cell_49: $i > $i).
% 28.89/28.91  tff(decl_3971, type, fn_animal_cell_45: $i > $i).
% 28.89/28.91  tff(decl_3972, type, fn_animal_cell_22: $i > $i).
% 28.89/28.91  tff(decl_3973, type, fn_adipose_cell_5: $i > $i).
% 28.89/28.91  tff(decl_3974, type, fn_animal_cell_50: $i > $i).
% 28.89/28.91  tff(decl_3975, type, fn_animal_cell_56: $i > $i).
% 28.89/28.91  tff(decl_3976, type, fn_animal_cell_57: $i > $i).
% 28.89/28.91  tff(decl_3977, type, fn_animal_cell_76: $i > $i).
% 28.89/28.91  tff(decl_3978, type, fn_animal_cell_83: $i > $i).
% 28.89/28.91  tff(decl_3979, type, fn_animal_cell_13: $i > $i).
% 28.89/28.91  tff(decl_3980, type, fn_animal_cell_1: $i > $i).
% 28.89/28.91  tff(decl_3981, type, fn_animal_cell_81: $i > $i).
% 28.89/28.91  tff(decl_3982, type, fn_animal_cell_60: $i > $i).
% 28.89/28.91  tff(decl_3983, type, fn_animal_cell_80: $i > $i).
% 28.89/28.91  tff(decl_3984, type, fn_animal_cell_54: $i > $i).
% 28.89/28.91  tff(decl_3985, type, fn_animal_cell_53: $i > $i).
% 28.89/28.91  tff(decl_3986, type, fn_animal_cell_52: $i > $i).
% 28.89/28.91  tff(decl_3987, type, fn_animal_cell_55: $i > $i).
% 28.89/28.91  tff(decl_3988, type, fn_animal_cell_58: $i > $i).
% 28.89/28.91  tff(decl_3989, type, fn_animal_cell_78: $i > $i).
% 28.89/28.91  tff(decl_3990, type, fn_animal_cell_74: $i > $i).
% 28.89/28.91  tff(decl_3991, type, fn_animal_cell_64: $i > $i).
% 28.89/28.91  tff(decl_3992, type, fn_animal_cell_63: $i > $i).
% 28.89/28.91  tff(decl_3993, type, fn_animal_cell_61: $i > $i).
% 28.89/28.91  tff(decl_3994, type, fn_animal_cell_79: $i > $i).
% 28.89/28.91  tff(decl_3995, type, fn_animal_cell_62: $i > $i).
% 28.89/28.91  tff(decl_3996, type, fn_animal_cell_59: $i > $i).
% 28.89/28.91  tff(decl_3997, type, fn_animal_cell_21: $i > $i).
% 28.89/28.91  tff(decl_3998, type, fn_eukaryotic_cell_47: $i > $i).
% 28.89/28.91  tff(decl_3999, type, fn_animal_cell_84: $i > $i).
% 28.89/28.91  tff(decl_4000, type, fn_eukaryotic_cell_15: $i > $i).
% 28.89/28.91  tff(decl_4001, type, fn_animal_cell_75: $i > $i).
% 28.89/28.91  tff(decl_4002, type, fn_eukaryotic_cell_48: $i > $i).
% 28.89/28.91  tff(decl_4003, type, fn_animal_cell_85: $i > $i).
% 28.89/28.91  tff(decl_4004, type, fn_animal_cell_73: $i > $i).
% 28.89/28.91  tff(decl_4005, type, adipose_tissue_1: $i > $o).
% 28.89/28.91  tff(decl_4006, type, 'Adipose-Tissue': $i).
% 28.89/28.91  tff(decl_4007, type, 'A connective tissue that functions to insulate, cushion, and serve as an energy reserve; contains fat-storing cells called adipose cells or adipocytes.': $i).
% 28.89/28.91  tff(decl_4008, type, 'adipose tissue': $i).
% 28.89/28.91  tff(decl_4009, type, 'adipose-tissue': $i).
% 28.89/28.91  tff(decl_4010, type, connective_tissue_1: $i > $o).
% 28.89/28.91  tff(decl_4011, type, av_valve_1: $i > $o).
% 28.89/28.91  tff(decl_4012, type, bone_1: $i > $o).
% 28.89/28.91  tff(decl_4013, type, cartilage_1: $i > $o).
% 28.89/28.91  tff(decl_4014, type, fibrous_connective_tissue_1: $i > $o).
% 28.89/28.91  tff(decl_4015, type, loose_connective_tissue_1: $i > $o).
% 28.89/28.91  tff(decl_4016, type, sclera_1: $i > $o).
% 28.89/28.91  tff(decl_4017, type, semilunar_valve_1: $i > $o).
% 28.89/28.91  tff(decl_4018, type, submucosa_1: $i > $o).
% 28.89/28.91  tff(decl_4019, type, vocal_cord_1: $i > $o).
% 28.89/28.91  tff(decl_4020, type, fn_adipose_tissue_1: $i > $i).
% 28.89/28.91  tff(decl_4021, type, fn_adipose_tissue_2: $i > $i).
% 28.89/28.91  tff(decl_4022, type, barrier_1: $i > $o).
% 28.89/28.91  tff(decl_4023, type, fn_adipose_tissue_3: $i > $i).
% 28.89/28.91  tff(decl_4024, type, fn_adipose_tissue_4: $i > $i).
% 28.89/28.91  tff(decl_4025, type, animal_organ_1: $i > $o).
% 28.89/28.91  tff(decl_4026, type, fn_adipose_tissue_5: $i > $i).
% 28.89/28.91  tff(decl_4027, type, fn_adipose_tissue_6: $i > $i).
% 28.89/28.91  tff(decl_4028, type, fn_adipose_tissue_7: $i > $i).
% 28.89/28.91  tff(decl_4029, type, fn_adipose_tissue_8: $i > $i).
% 28.89/28.91  tff(decl_4030, type, fn_adipose_tissue_9: $i > $i).
% 28.89/28.91  tff(decl_4031, type, exchange_1: $i > $o).
% 28.89/28.91  tff(decl_4032, type, fn_adipose_tissue_10: $i > $i).
% 28.89/28.91  tff(decl_4033, type, fn_adipose_tissue_11: $i > $i).
% 28.89/28.91  tff(decl_4034, type, insulator_1: $i > $o).
% 28.89/28.91  tff(decl_4035, type, fn_insulator_1: $i > $i).
% 28.89/28.91  tff(decl_4036, type, fn_barrier_1: $i > $i).
% 28.89/28.91  tff(decl_4037, type, fn_exchange_1: $i > $i).
% 28.89/28.91  tff(decl_4038, type, fn_exchange_2: $i > $i).
% 28.89/28.91  tff(decl_4039, type, fn_tissue_1: $i > $i).
% 28.89/28.91  tff(decl_4040, type, administrative_district_1: $i > $o).
% 28.89/28.91  tff(decl_4041, type, 'Administrative-District': $i).
% 28.89/28.91  tff(decl_4042, type, 'a Territory delineated on administrative grounds': $i).
% 28.89/28.91  tff(decl_4043, type, 'administrative district': $i).
% 28.89/28.91  tff(decl_4044, type, administrative_district: $i).
% 28.89/28.91  tff(decl_4045, type, 'administrative division': $i).
% 28.89/28.91  tff(decl_4046, type, administrative_division: $i).
% 28.89/28.91  tff(decl_4047, type, 'territorial division': $i).
% 28.89/28.91  tff(decl_4048, type, territorial_division: $i).
% 28.89/28.91  tff(decl_4049, type, 'administrative-district': $i).
% 28.89/28.91  tff(decl_4050, type, territory_1: $i > $o).
% 28.89/28.91  tff(decl_4051, type, admit_1: $i > $o).
% 28.89/28.91  tff(decl_4052, type, 'Admit': $i).
% 28.89/28.91  tff(decl_4053, type, admit: $i).
% 28.89/28.91  tff(decl_4054, type, 'allow in': $i).
% 28.89/28.91  tff(decl_4055, type, allow_in: $i).
% 28.89/28.91  tff(decl_4056, type, 'let in': $i).
% 28.89/28.91  tff(decl_4057, type, let_in: $i).
% 28.89/28.91  tff(decl_4058, type, fn_admit_1: $i > $i).
% 28.89/28.91  tff(decl_4059, type, fn_admit_2: $i > $i).
% 28.89/28.91  tff(decl_4060, type, fn_admit_3: $i > $i).
% 28.89/28.91  tff(decl_4061, type, fn_unobstruct_1: $i > $i).
% 28.89/28.91  tff(decl_4062, type, 'ADP': $i).
% 28.89/28.91  tff(decl_4063, type, 'Adenosine diphosphate; a nucleotide typically found as the uncharged state that converts to ATP in energy reactions.': $i).
% 28.89/28.91  tff(decl_4064, type, 'adenosine diphosphate': $i).
% 28.89/28.91  tff(decl_4065, type, 'adenosine-diphosphate': $i).
% 28.89/28.91  tff(decl_4066, type, adp: $i).
% 28.89/28.91  tff(decl_4067, type, ribonucleoside_diphosphate_1: $i > $o).
% 28.89/28.91  tff(decl_4068, type, fn_adp_1: $i > $i).
% 28.89/28.91  tff(decl_4069, type, fn_adp_2: $i > $i).
% 28.89/28.91  tff(decl_4070, type, fn_adp_3: $i > $i).
% 28.89/28.91  tff(decl_4071, type, fn_adp_4: $i > $i).
% 28.89/28.91  tff(decl_4072, type, fn_adp_5: $i > $i).
% 28.89/28.91  tff(decl_4073, type, fn_adp_6: $i > $i).
% 28.89/28.91  tff(decl_4074, type, fn_adp_7: $i > $i).
% 28.89/28.91  tff(decl_4075, type, fn_adp_8: $i > $i).
% 28.89/28.91  tff(decl_4076, type, fn_adp_9: $i > $i).
% 28.89/28.91  tff(decl_4077, type, fn_adp_12: $i > $i).
% 28.89/28.91  tff(decl_4078, type, fn_adp_13: $i > $i).
% 28.89/28.91  tff(decl_4079, type, fn_adp_14: $i > $i).
% 28.89/28.91  tff(decl_4080, type, fn_adp_15: $i > $i).
% 28.89/28.91  tff(decl_4081, type, fn_adp_16: $i > $i).
% 28.89/28.91  tff(decl_4082, type, fn_adp_17: $i > $i).
% 28.89/28.91  tff(decl_4083, type, fn_adp_18: $i > $i).
% 28.89/28.91  tff(decl_4084, type, fn_adp_19: $i > $i).
% 28.89/28.91  tff(decl_4085, type, fn_adp_20: $i > $i).
% 28.89/28.91  tff(decl_4086, type, fn_adp_21: $i > $i).
% 28.89/28.91  tff(decl_4087, type, fn_adp_22: $i > $i).
% 28.89/28.91  tff(decl_4088, type, fn_adp_23: $i > $i).
% 28.89/28.91  tff(decl_4089, type, fn_adp_24: $i > $i).
% 28.89/28.91  tff(decl_4090, type, fn_adp_25: $i > $i).
% 28.89/28.91  tff(decl_4091, type, fn_adp_26: $i > $i).
% 28.89/28.91  tff(decl_4092, type, fn_adp_27: $i > $i).
% 28.89/28.91  tff(decl_4093, type, fn_adp_28: $i > $i).
% 28.89/28.91  tff(decl_4094, type, fn_adp_29: $i > $i).
% 28.89/28.91  tff(decl_4095, type, fn_adp_30: $i > $i).
% 28.89/28.91  tff(decl_4096, type, fn_adp_31: $i > $i).
% 28.89/28.91  tff(decl_4097, type, fn_adp_32: $i > $i).
% 28.89/28.91  tff(decl_4098, type, fn_adp_33: $i > $i).
% 28.89/28.91  tff(decl_4099, type, fn_adp_34: $i > $i).
% 28.89/28.91  tff(decl_4100, type, fn_adp_35: $i > $i).
% 28.89/28.91  tff(decl_4101, type, electronegative_element_1: $i > $o).
% 28.89/28.91  tff(decl_4102, type, fn_adp_36: $i > $i).
% 28.89/28.91  tff(decl_4103, type, fn_adp_37: $i > $i).
% 28.89/28.91  tff(decl_4104, type, fn_adp_38: $i > $i).
% 28.89/28.91  tff(decl_4105, type, fn_adp_39: $i > $i).
% 28.89/28.91  tff(decl_4106, type, fn_adp_40: $i > $i).
% 28.89/28.91  tff(decl_4107, type, fn_adp_41: $i > $i).
% 28.89/28.91  tff(decl_4108, type, fn_adp_42: $i > $i).
% 28.89/28.91  tff(decl_4109, type, fn_adp_43: $i > $i).
% 28.89/28.91  tff(decl_4110, type, fn_adp_44: $i > $i).
% 28.89/28.91  tff(decl_4111, type, fn_adp_45: $i > $i).
% 28.89/28.91  tff(decl_4112, type, fn_adp_46: $i > $i).
% 28.89/28.91  tff(decl_4113, type, fn_adp_47: $i > $i).
% 28.89/28.91  tff(decl_4114, type, fn_adp_48: $i > $i).
% 28.89/28.91  tff(decl_4115, type, fn_adp_49: $i > $i).
% 28.89/28.91  tff(decl_4116, type, fn_adp_50: $i > $i).
% 28.89/28.91  tff(decl_4117, type, fn_adp_51: $i > $i).
% 28.89/28.91  tff(decl_4118, type, fn_adp_52: $i > $i).
% 28.89/28.91  tff(decl_4119, type, fn_adp_53: $i > $i).
% 28.89/28.91  tff(decl_4120, type, fn_adp_54: $i > $i).
% 28.89/28.91  tff(decl_4121, type, fn_adp_55: $i > $i).
% 28.89/28.91  tff(decl_4122, type, fn_adp_56: $i > $i).
% 28.89/28.91  tff(decl_4123, type, fn_adp_57: $i > $i).
% 28.89/28.91  tff(decl_4124, type, fn_adp_58: $i > $i).
% 28.89/28.91  tff(decl_4125, type, fn_adp_59: $i > $i).
% 28.89/28.91  tff(decl_4126, type, fn_adp_60: $i > $i).
% 28.89/28.91  tff(decl_4127, type, fn_adp_61: $i > $i).
% 28.89/28.91  tff(decl_4128, type, fn_adp_62: $i > $i).
% 28.89/28.91  tff(decl_4129, type, fn_adp_63: $i > $i).
% 28.89/28.91  tff(decl_4130, type, fn_adp_64: $i > $i).
% 28.89/28.91  tff(decl_4131, type, fn_adp_65: $i > $i).
% 28.89/28.91  tff(decl_4132, type, fn_adp_66: $i > $i).
% 28.89/28.91  tff(decl_4133, type, fn_adp_67: $i > $i).
% 28.89/28.91  tff(decl_4134, type, fn_organic_molecule_3: $i > $i).
% 28.89/28.91  tff(decl_4135, type, fn_chemical_element_12: $i > $i).
% 28.89/28.91  tff(decl_4136, type, fn_nucleoside_7: $i > $i).
% 28.89/28.91  tff(decl_4137, type, fn_polar_covalent_bond_19: $i > $i).
% 28.89/28.91  tff(decl_4138, type, fn_polar_covalent_bond_18: $i > $i).
% 28.89/28.91  tff(decl_4139, type, fn_nucleoside_6: $i > $i).
% 28.89/28.91  tff(decl_4140, type, fn_aldose_11: $i > $i).
% 28.89/28.91  tff(decl_4141, type, fn_nucleoside_9: $i > $i).
% 28.89/28.91  tff(decl_4142, type, fn_carbohydrate_6: $i > $i).
% 28.89/28.91  tff(decl_4143, type, fn_polar_covalent_bond_16: $i > $i).
% 28.89/28.91  tff(decl_4144, type, fn_nucleoside_11: $i > $i).
% 28.89/28.91  tff(decl_4145, type, fn_carbohydrate_30: $i > $i).
% 28.89/28.91  tff(decl_4146, type, fn_polar_covalent_bond_17: $i > $i).
% 28.89/28.91  tff(decl_4147, type, fn_nucleoside_12: $i > $i).
% 28.89/28.91  tff(decl_4148, type, fn_carbohydrate_37: $i > $i).
% 28.89/28.91  tff(decl_4149, type, fn_nucleoside_10: $i > $i).
% 28.89/28.91  tff(decl_4150, type, fn_carbohydrate_36: $i > $i).
% 28.89/28.91  tff(decl_4151, type, fn_phosphate_group_3: $i > $i).
% 28.89/28.91  tff(decl_4152, type, fn_phosphate_group_20: $i > $i).
% 28.89/28.91  tff(decl_4153, type, fn_phosphate_group_35: $i > $i).
% 28.89/28.91  tff(decl_4154, type, fn_chemical_element_11: $i > $i).
% 28.89/28.91  tff(decl_4155, type, fn_phosphate_group_9: $i > $i).
% 28.89/28.91  tff(decl_4156, type, fn_phosphate_group_38: $i > $i).
% 28.89/28.91  tff(decl_4157, type, fn_phosphate_group_21: $i > $i).
% 28.89/28.91  tff(decl_4158, type, fn_phosphate_group_17: $i > $i).
% 28.89/28.91  tff(decl_4159, type, fn_phosphate_group_10: $i > $i).
% 28.89/28.91  tff(decl_4160, type, fn_phosphate_group_12: $i > $i).
% 28.89/28.91  tff(decl_4161, type, fn_phosphate_group_18: $i > $i).
% 28.89/28.91  tff(decl_4162, type, fn_phosphate_group_8: $i > $i).
% 28.89/28.91  tff(decl_4163, type, fn_phosphate_group_39: $i > $i).
% 28.89/28.91  tff(decl_4164, type, 'A4': $i).
% 28.89/28.91  tff(decl_4165, type, 'P1': $i).
% 28.89/28.91  tff(decl_4166, type, 'P2': $i).
% 28.89/28.91  tff(decl_4167, type, fn_nucleotide_24: $i > $i).
% 28.89/28.91  tff(decl_4168, type, fn_nucleoside_diphosphate_28: $i > $i).
% 28.89/28.91  tff(decl_4169, type, fn_nucleoside_diphosphate_8: $i > $i).
% 28.89/28.91  tff(decl_4170, type, fn_nucleoside_diphosphate_21: $i > $i).
% 28.89/28.91  tff(decl_4171, type, fn_nucleoside_diphosphate_26: $i > $i).
% 28.89/28.91  tff(decl_4172, type, fn_nucleoside_diphosphate_43: $i > $i).
% 28.89/28.91  tff(decl_4173, type, fn_nucleoside_diphosphate_37: $i > $i).
% 28.89/28.91  tff(decl_4174, type, fn_nucleoside_diphosphate_36: $i > $i).
% 28.89/28.91  tff(decl_4175, type, fn_nucleoside_diphosphate_45: $i > $i).
% 28.89/28.91  tff(decl_4176, type, fn_nucleoside_diphosphate_1: $i > $i).
% 28.89/28.91  tff(decl_4177, type, fn_nucleoside_diphosphate_3: $i > $i).
% 28.89/28.91  tff(decl_4178, type, fn_nucleoside_diphosphate_47: $i > $i).
% 28.89/28.91  tff(decl_4179, type, fn_adp_10: $i > $i).
% 28.89/28.91  tff(decl_4180, type, fn_nucleotide_53: $i > $i).
% 28.89/28.91  tff(decl_4181, type, fn_adp_11: $i > $i).
% 28.89/28.91  tff(decl_4182, type, fn_nucleotide_52: $i > $i).
% 28.89/28.91  tff(decl_4183, type, fn_nucleotide_4: $i > $i).
% 28.89/28.91  tff(decl_4184, type, fn_nucleotide_5: $i > $i).
% 28.89/28.91  tff(decl_4185, type, fn_nucleotide_6: $i > $i).
% 28.89/28.91  tff(decl_4186, type, fn_nucleotide_2: $i > $i).
% 28.89/28.91  tff(decl_4187, type, fn_ribonucleotide_6: $i > $i).
% 28.89/28.91  tff(decl_4188, type, fn_ribonucleotide_29: $i > $i).
% 28.89/28.91  tff(decl_4189, type, fn_ribonucleotide_23: $i > $i).
% 28.89/28.91  tff(decl_4190, type, fn_ribonucleotide_22: $i > $i).
% 28.89/28.91  tff(decl_4191, type, fn_ribonucleotide_27: $i > $i).
% 28.89/28.91  tff(decl_4192, type, fn_nucleoside_diphosphate_34: $i > $i).
% 28.89/28.91  tff(decl_4193, type, fn_ribonucleotide_11: $i > $i).
% 28.89/28.91  tff(decl_4194, type, fn_nucleoside_diphosphate_25: $i > $i).
% 28.89/28.91  tff(decl_4195, type, fn_nucleoside_diphosphate_27: $i > $i).
% 28.89/28.91  tff(decl_4196, type, fn_ribonucleotide_15: $i > $i).
% 28.89/28.91  tff(decl_4197, type, fn_nucleoside_diphosphate_32: $i > $i).
% 28.89/28.91  tff(decl_4198, type, fn_ribonucleotide_19: $i > $i).
% 28.89/28.91  tff(decl_4199, type, fn_ribonucleotide_4: $i > $i).
% 28.89/28.91  tff(decl_4200, type, fn_ribonucleotide_28: $i > $i).
% 28.89/28.91  tff(decl_4201, type, fn_ribonucleotide_2: $i > $i).
% 28.89/28.91  tff(decl_4202, type, fn_nucleoside_diphosphate_38: $i > $i).
% 28.89/28.91  tff(decl_4203, type, fn_nucleoside_diphosphate_33: $i > $i).
% 28.89/28.91  tff(decl_4204, type, fn_nucleoside_diphosphate_44: $i > $i).
% 28.89/28.91  tff(decl_4205, type, fn_ribonucleotide_24: $i > $i).
% 28.89/28.91  tff(decl_4206, type, fn_nucleoside_diphosphate_35: $i > $i).
% 28.89/28.91  tff(decl_4207, type, fn_nucleoside_diphosphate_41: $i > $i).
% 28.89/28.91  tff(decl_4208, type, fn_nucleoside_diphosphate_29: $i > $i).
% 28.89/28.91  tff(decl_4209, type, fn_nucleoside_diphosphate_30: $i > $i).
% 28.89/28.91  tff(decl_4210, type, fn_nucleoside_diphosphate_4: $i > $i).
% 28.89/28.91  tff(decl_4211, type, fn_nucleotide_13: $i > $i).
% 28.89/28.91  tff(decl_4212, type, fn_nucleotide_30: $i > $i).
% 28.89/28.91  tff(decl_4213, type, fn_nucleotide_10: $i > $i).
% 28.89/28.91  tff(decl_4214, type, fn_nucleotide_15: $i > $i).
% 28.89/28.91  tff(decl_4215, type, adrenal_cortex_1: $i > $o).
% 28.89/28.91  tff(decl_4216, type, 'Adrenal-Cortex': $i).
% 28.89/28.91  tff(decl_4217, type, 'The outer region of the adrenal gland, associated with endocrine activity rather than nervous system activity; mediates the body\\s response to stress.': $i).
% 28.89/28.91  tff(decl_4218, type, 'cortex of adrenal': $i).
% 28.89/28.91  tff(decl_4219, type, 'adrenal cortex': $i).
% 28.89/28.91  tff(decl_4220, type, 'adrenal-cortex': $i).
% 28.89/28.91  tff(decl_4221, type, organ_region_1: $i > $o).
% 28.89/28.91  tff(decl_4222, type, adrenal_gland_1: $i > $o).
% 28.89/28.91  tff(decl_4223, type, 'Adrenal-Gland': $i).
% 28.89/28.91  tff(decl_4224, type, 'One of a pair of endocrine glands that sit atop the kidneys in mammals. The adrenal glands release hormones in response to stress, synthesize corticosteroids and androgens, and affect kidney function by secreting the hormone aldosterone.': $i).
% 28.89/28.91  tff(decl_4225, type, 'gland of adrenal': $i).
% 28.89/28.91  tff(decl_4226, type, 'adrenal gland': $i).
% 28.89/28.91  tff(decl_4227, type, 'adrenal-gland': $i).
% 28.89/28.91  tff(decl_4228, type, endocrine_gland_1: $i > $o).
% 28.89/28.91  tff(decl_4229, type, parathyroid_gland_1: $i > $o).
% 28.89/28.91  tff(decl_4230, type, pineal_gland_1: $i > $o).
% 28.89/28.91  tff(decl_4231, type, pituitary_gland_1: $i > $o).
% 28.89/28.91  tff(decl_4232, type, thyroid_gland_1: $i > $o).
% 28.89/28.91  tff(decl_4233, type, adrenal_medulla_1: $i > $o).
% 28.89/28.91  tff(decl_4234, type, 'Adrenal-Medulla': $i).
% 28.89/28.91  tff(decl_4235, type, 'The inner portion of the adrenal gland, associated with nervous system secretions rather than endocrine secretions; secretes the neurotransmitters epinephrine, norepinephrine, and dopamine.': $i).
% 28.89/28.91  tff(decl_4236, type, 'medulla of adrenal': $i).
% 28.89/28.91  tff(decl_4237, type, 'adrenal medulla': $i).
% 28.89/28.91  tff(decl_4238, type, 'adrenal-medulla': $i).
% 28.89/28.91  tff(decl_4239, type, adrenocorticotropic_hormone_1: $i > $o).
% 28.89/28.91  tff(decl_4240, type, 'Adrenocorticotropic-Hormone': $i).
% 28.89/28.91  tff(decl_4241, type, 'A tropic hormone secreted by the anterior pituitary gland; mediates the production and release of corticosteroids by the adrenal cortex.': $i).
% 28.89/28.91  tff(decl_4242, type, 'adrenocorticotropic hormone': $i).
% 28.89/28.91  tff(decl_4243, type, 'adrenocorticotropic-hormone': $i).
% 28.89/28.91  tff(decl_4244, type, peptide_hormone_1: $i > $o).
% 28.89/28.91  tff(decl_4245, type, anp_1: $i > $o).
% 28.89/28.91  tff(decl_4246, type, antidiuretic_hormone_1: $i > $o).
% 28.89/28.91  tff(decl_4247, type, calcitonin_1: $i > $o).
% 28.89/28.91  tff(decl_4248, type, cholecystokinin_1: $i > $o).
% 28.89/28.91  tff(decl_4249, type, gastrin_1: $i > $o).
% 28.89/28.91  tff(decl_4250, type, glucagon_1: $i > $o).
% 28.89/28.91  tff(decl_4251, type, gonadotropin_releasing_hormone_1: $i > $o).
% 28.89/28.91  tff(decl_4252, type, melanocyte_stimulating_hormone_1: $i > $o).
% 28.89/28.91  tff(decl_4253, type, oxytocin_1: $i > $o).
% 28.89/28.91  tff(decl_4254, type, parathyroid_hormone_1: $i > $o).
% 28.89/28.91  tff(decl_4255, type, secretin_1: $i > $o).
% 28.89/28.91  tff(decl_4256, type, adult_1: $i > $o).
% 28.89/28.91  tff(decl_4257, type, 'Adult': $i).
% 28.89/28.91  tff(decl_4258, type, 'A fully developed organism from maturity onward is called as an adult.': $i).
% 28.89/28.91  tff(decl_4259, type, adult: $i).
% 28.89/28.91  tff(decl_4260, type, life_stage_1: $i > $o).
% 28.89/28.91  tff(decl_4261, type, adult_cell_1: $i > $o).
% 28.89/28.91  tff(decl_4262, type, 'Adult-Cell': $i).
% 28.89/28.91  tff(decl_4263, type, 'The cell of an adult of an organism.': $i).
% 28.89/28.91  tff(decl_4264, type, 'cell of an adult': $i).
% 28.89/28.91  tff(decl_4265, type, 'cell of adult': $i).
% 28.89/28.91  tff(decl_4266, type, 'adult cell': $i).
% 28.89/28.91  tff(decl_4267, type, 'adult-cell': $i).
% 28.89/28.91  tff(decl_4268, type, adult_stem_cell_1: $i > $o).
% 28.89/28.91  tff(decl_4269, type, 'Adult-Stem-Cell': $i).
% 28.89/28.91  tff(decl_4270, type, 'The stem cells of the adult of an organism.': $i).
% 28.89/28.91  tff(decl_4271, type, 'adult stem cell': $i).
% 28.89/28.91  tff(decl_4272, type, 'adult-stem-cell': $i).
% 28.89/28.91  tff(decl_4273, type, stem_cell_1: $i > $o).
% 28.89/28.91  tff(decl_4274, type, fn_adult_stem_cell_1: $i > $i).
% 28.89/28.91  tff(decl_4275, type, er_membrane_1: $i > $o).
% 28.89/28.91  tff(decl_4276, type, fn_adult_stem_cell_2: $i > $i).
% 28.89/28.91  tff(decl_4277, type, fn_adult_stem_cell_3: $i > $i).
% 28.89/28.91  tff(decl_4278, type, protein_enzyme_1: $i > $o).
% 28.89/28.91  tff(decl_4279, type, fn_adult_stem_cell_4: $i > $i).
% 28.89/28.91  tff(decl_4280, type, fn_adult_stem_cell_5: $i > $i).
% 28.89/28.91  tff(decl_4281, type, fn_adult_stem_cell_6: $i > $i).
% 28.89/28.91  tff(decl_4282, type, fn_adult_stem_cell_7: $i > $i).
% 28.89/28.91  tff(decl_4283, type, fn_adult_stem_cell_8: $i > $i).
% 28.89/28.91  tff(decl_4284, type, fn_adult_stem_cell_9: $i > $i).
% 28.89/28.91  tff(decl_4285, type, fn_adult_stem_cell_10: $i > $i).
% 28.89/28.91  tff(decl_4286, type, synthesis_reaction_1: $i > $o).
% 28.89/28.91  tff(decl_4287, type, synthesis_of_lipid_1: $i > $o).
% 28.89/28.91  tff(decl_4288, type, fn_adult_stem_cell_11: $i > $i).
% 28.89/28.91  tff(decl_4289, type, fn_adult_stem_cell_12: $i > $i).
% 28.89/28.91  tff(decl_4290, type, fn_adult_stem_cell_13: $i > $i).
% 28.89/28.91  tff(decl_4291, type, fn_adult_stem_cell_14: $i > $i).
% 28.89/28.91  tff(decl_4292, type, fn_adult_stem_cell_15: $i > $i).
% 28.89/28.91  tff(decl_4293, type, fn_adult_stem_cell_16: $i > $i).
% 28.89/28.91  tff(decl_4294, type, fn_adult_stem_cell_17: $i > $i).
% 28.89/28.91  tff(decl_4295, type, fn_adult_stem_cell_18: $i > $i).
% 28.89/28.91  tff(decl_4296, type, fn_adult_stem_cell_19: $i > $i).
% 28.89/28.91  tff(decl_4297, type, fn_adult_stem_cell_20: $i > $i).
% 28.89/28.91  tff(decl_4298, type, fn_adult_stem_cell_21: $i > $i).
% 28.89/28.91  tff(decl_4299, type, fn_adult_stem_cell_22: $i > $i).
% 28.89/28.91  tff(decl_4300, type, fn_adult_stem_cell_23: $i > $i).
% 28.89/28.91  tff(decl_4301, type, fn_adult_stem_cell_24: $i > $i).
% 28.89/28.91  tff(decl_4302, type, fn_adult_stem_cell_25: $i > $i).
% 28.89/28.91  tff(decl_4303, type, fn_adult_stem_cell_26: $i > $i).
% 28.89/28.91  tff(decl_4304, type, fn_adult_stem_cell_27: $i > $i).
% 28.89/28.91  tff(decl_4305, type, fn_adult_stem_cell_28: $i > $i).
% 28.89/28.91  tff(decl_4306, type, fn_adult_stem_cell_29: $i > $i).
% 28.89/28.91  tff(decl_4307, type, fn_adult_stem_cell_30: $i > $i).
% 28.89/28.91  tff(decl_4308, type, fn_adult_stem_cell_31: $i > $i).
% 28.89/28.91  tff(decl_4309, type, fn_adult_stem_cell_32: $i > $i).
% 28.89/28.91  tff(decl_4310, type, fn_adult_stem_cell_33: $i > $i).
% 28.89/28.91  tff(decl_4311, type, fn_adult_stem_cell_34: $i > $i).
% 28.89/28.91  tff(decl_4312, type, fn_adult_stem_cell_35: $i > $i).
% 28.89/28.91  tff(decl_4313, type, fn_adult_stem_cell_38: $i > $i).
% 28.89/28.91  tff(decl_4314, type, fn_adult_stem_cell_39: $i > $i).
% 28.89/28.91  tff(decl_4315, type, fn_adult_stem_cell_40: $i > $i).
% 28.89/28.91  tff(decl_4316, type, fn_adult_stem_cell_41: $i > $i).
% 28.89/28.91  tff(decl_4317, type, transfer_1: $i > $o).
% 28.89/28.91  tff(decl_4318, type, fn_adult_stem_cell_42: $i > $i).
% 28.89/28.91  tff(decl_4319, type, fn_adult_stem_cell_43: $i > $i).
% 28.89/28.91  tff(decl_4320, type, fn_adult_stem_cell_44: $i > $i).
% 28.89/28.91  tff(decl_4321, type, fn_adult_stem_cell_45: $i > $i).
% 28.89/28.91  tff(decl_4322, type, fn_rough_endoplasmic_reticulum_55: $i > $i).
% 28.89/28.91  tff(decl_4323, type, fn_endoplasmic_reticulum_25: $i > $i).
% 28.89/28.91  tff(decl_4324, type, fn_rough_endoplasmic_reticulum_52: $i > $i).
% 28.89/28.91  tff(decl_4325, type, fn_smooth_endoplasmic_reticulum_39: $i > $i).
% 28.89/28.91  tff(decl_4326, type, fn_smooth_endoplasmic_reticulum_23: $i > $i).
% 28.89/28.91  tff(decl_4327, type, fn_smooth_endoplasmic_reticulum_7: $i > $i).
% 28.89/28.91  tff(decl_4328, type, fn_smooth_endoplasmic_reticulum_49: $i > $i).
% 28.89/28.91  tff(decl_4329, type, fn_smooth_endoplasmic_reticulum_48: $i > $i).
% 28.89/28.91  tff(decl_4330, type, fn_smooth_endoplasmic_reticulum_8: $i > $i).
% 28.89/28.91  tff(decl_4331, type, fn_smooth_endoplasmic_reticulum_42: $i > $i).
% 28.89/28.91  tff(decl_4332, type, fn_rough_endoplasmic_reticulum_56: $i > $i).
% 28.89/28.91  tff(decl_4333, type, fn_rough_endoplasmic_reticulum_23: $i > $i).
% 28.89/28.91  tff(decl_4334, type, fn_rough_endoplasmic_reticulum_32: $i > $i).
% 28.89/28.91  tff(decl_4335, type, fn_rough_endoplasmic_reticulum_62: $i > $i).
% 28.89/28.91  tff(decl_4336, type, fn_adult_stem_cell_36: $i > $i).
% 28.89/28.91  tff(decl_4337, type, fn_stem_cell_39: $i > $i).
% 28.89/28.91  tff(decl_4338, type, fn_adult_stem_cell_37: $i > $i).
% 28.89/28.91  tff(decl_4339, type, fn_stem_cell_40: $i > $i).
% 28.89/28.91  tff(decl_4340, type, fn_stem_cell_30: $i > $i).
% 28.89/28.91  tff(decl_4341, type, fn_stem_cell_37: $i > $i).
% 28.89/28.91  tff(decl_4342, type, fn_stem_cell_24: $i > $i).
% 28.89/28.91  tff(decl_4343, type, fn_stem_cell_28: $i > $i).
% 28.89/28.91  tff(decl_4344, type, fn_stem_cell_29: $i > $i).
% 28.89/28.91  tff(decl_4345, type, fn_stem_cell_25: $i > $i).
% 28.89/28.91  tff(decl_4346, type, fn_stem_cell_31: $i > $i).
% 28.89/28.91  tff(decl_4347, type, fn_stem_cell_27: $i > $i).
% 28.89/28.91  tff(decl_4348, type, fn_stem_cell_38: $i > $i).
% 28.89/28.91  tff(decl_4349, type, fn_stem_cell_32: $i > $i).
% 28.89/28.91  tff(decl_4350, type, fn_stem_cell_13: $i > $i).
% 28.89/28.91  tff(decl_4351, type, fn_stem_cell_41: $i > $i).
% 28.89/28.91  tff(decl_4352, type, fn_animal_cell_82: $i > $i).
% 28.89/28.91  tff(decl_4353, type, fn_stem_cell_23: $i > $i).
% 28.89/28.91  tff(decl_4354, type, fn_stem_cell_33: $i > $i).
% 28.89/28.91  tff(decl_4355, type, fn_stem_cell_1: $i > $i).
% 28.89/28.91  tff(decl_4356, type, fn_stem_cell_14: $i > $i).
% 28.89/28.91  tff(decl_4357, type, fn_stem_cell_17: $i > $i).
% 28.89/28.91  tff(decl_4358, type, fn_stem_cell_16: $i > $i).
% 28.89/28.91  tff(decl_4359, type, fn_animal_cell_20: $i > $i).
% 28.89/28.91  tff(decl_4360, type, fn_stem_cell_43: $i > $i).
% 28.89/28.91  tff(decl_4361, type, fn_stem_cell_10: $i > $i).
% 28.89/28.91  tff(decl_4362, type, fn_stem_cell_2: $i > $i).
% 28.89/28.91  tff(decl_4363, type, fn_stem_cell_34: $i > $i).
% 28.89/28.91  tff(decl_4364, type, fn_stem_cell_3: $i > $i).
% 28.89/28.91  tff(decl_4365, type, fn_stem_cell_35: $i > $i).
% 28.89/28.91  tff(decl_4366, type, fn_animal_cell_18: $i > $i).
% 28.89/28.91  tff(decl_4367, type, fn_stem_cell_45: $i > $i).
% 28.89/28.91  tff(decl_4368, type, fn_stem_cell_21: $i > $i).
% 28.89/28.91  tff(decl_4369, type, fn_stem_cell_15: $i > $i).
% 28.89/28.91  tff(decl_4370, type, fn_stem_cell_42: $i > $i).
% 28.89/28.91  tff(decl_4371, type, fn_stem_cell_4: $i > $i).
% 28.89/28.91  tff(decl_4372, type, fn_stem_cell_26: $i > $i).
% 28.89/28.91  tff(decl_4373, type, fn_stem_cell_36: $i > $i).
% 28.89/28.91  tff(decl_4374, type, fn_animal_cell_19: $i > $i).
% 28.89/28.91  tff(decl_4375, type, fn_stem_cell_44: $i > $i).
% 28.89/28.91  tff(decl_4376, type, fn_eukaryotic_cell_25: $i > $i).
% 28.89/28.91  tff(decl_4377, type, fn_stem_cell_12: $i > $i).
% 28.89/28.91  tff(decl_4378, type, adulthood_1: $i > $o).
% 28.89/28.91  tff(decl_4379, type, 'Adulthood': $i).
% 28.89/28.91  tff(decl_4380, type, 'Adulthood is the period in development in which an organism has attained full physical and intellectual maturity.': $i).
% 28.89/28.91  tff(decl_4381, type, adulthood: $i).
% 28.89/28.91  tff(decl_4382, type, developmental_stage_1: $i > $o).
% 28.89/28.91  tff(decl_4383, type, algae_bloom_1: $i > $o).
% 28.89/28.91  tff(decl_4384, type, axes_formation_1: $i > $o).
% 28.89/28.91  tff(decl_4385, type, blastulation_1: $i > $o).
% 28.89/28.91  tff(decl_4386, type, eight_cell_stage_1: $i > $o).
% 28.89/28.91  tff(decl_4387, type, fetal_stage_1: $i > $o).
% 28.89/28.91  tff(decl_4388, type, follicular_phase_1: $i > $o).
% 28.89/28.91  tff(decl_4389, type, juvenile_stage_1: $i > $o).
% 28.89/28.91  tff(decl_4390, type, larval_stage_1: $i > $o).
% 28.89/28.91  tff(decl_4391, type, menopause_1: $i > $o).
% 28.89/28.91  tff(decl_4392, type, multinucleated_stage_1: $i > $o).
% 28.89/28.91  tff(decl_4393, type, segment_formation_1: $i > $o).
% 28.89/28.91  tff(decl_4394, type, sensitive_period_1: $i > $o).
% 28.89/28.91  tff(decl_4395, type, two_cell_stage_1: $i > $o).
% 28.89/28.91  tff(decl_4396, type, adventitious_root_1: $i > $o).
% 28.89/28.91  tff(decl_4397, type, 'Adventitious-Root': $i).
% 28.89/28.91  tff(decl_4398, type, 'A root that grows above ground from a stem or leaf.': $i).
% 28.89/28.91  tff(decl_4399, type, 'adventitious root': $i).
% 28.89/28.91  tff(decl_4400, type, 'adventitious-root': $i).
% 28.89/28.91  tff(decl_4401, type, root_1: $i > $o).
% 28.89/28.91  tff(decl_4402, type, carrot_1: $i > $o).
% 28.89/28.91  tff(decl_4403, type, fibrous_root_1: $i > $o).
% 28.89/28.91  tff(decl_4404, type, lateral_root_1: $i > $o).
% 28.89/28.91  tff(decl_4405, type, radicle_1: $i > $o).
% 28.89/28.91  tff(decl_4406, type, taproot_1: $i > $o).
% 28.89/28.91  tff(decl_4407, type, aerobe_1: $i > $o).
% 28.89/28.91  tff(decl_4408, type, 'Aerobe': $i).
% 28.89/28.91  tff(decl_4409, type, 'A cell or an organism which live in the presence of oxygen.': $i).
% 28.89/28.91  tff(decl_4410, type, aerobe: $i).
% 28.89/28.91  tff(decl_4411, type, fn_aerobe_1: $i > $i).
% 28.89/28.91  tff(decl_4412, type, energy_source_1: $i > $o).
% 28.89/28.91  tff(decl_4413, type, fn_aerobe_2: $i > $i).
% 28.89/28.91  tff(decl_4414, type, fn_aerobe_3: $i > $i).
% 28.89/28.91  tff(decl_4415, type, fn_aerobe_4: $i > $i).
% 28.89/28.91  tff(decl_4416, type, fn_aerobe_5: $i > $i).
% 28.89/28.91  tff(decl_4417, type, fn_aerobe_6: $i > $i).
% 28.89/28.91  tff(decl_4418, type, carbon_source_1: $i > $o).
% 28.89/28.91  tff(decl_4419, type, fn_aerobe_7: $i > $i).
% 28.89/28.91  tff(decl_4420, type, potassium_1: $i > $o).
% 28.89/28.91  tff(decl_4421, type, fn_aerobe_8: $i > $i).
% 28.89/28.91  tff(decl_4422, type, calcium_1: $i > $o).
% 28.89/28.91  tff(decl_4423, type, fn_aerobe_9: $i > $i).
% 28.89/28.91  tff(decl_4424, type, sulfur_1: $i > $o).
% 28.89/28.91  tff(decl_4425, type, fn_aerobe_10: $i > $i).
% 28.89/28.91  tff(decl_4426, type, fn_aerobe_11: $i > $i).
% 28.89/28.91  tff(decl_4427, type, fn_aerobe_12: $i > $i).
% 28.89/28.91  tff(decl_4428, type, fn_aerobe_13: $i > $i).
% 28.89/28.91  tff(decl_4429, type, fn_aerobe_14: $i > $i).
% 28.89/28.91  tff(decl_4430, type, fn_aerobe_15: $i > $i).
% 28.89/28.91  tff(decl_4431, type, iron_1: $i > $o).
% 28.89/28.91  tff(decl_4432, type, fn_aerobe_16: $i > $i).
% 28.89/28.91  tff(decl_4433, type, nutritional_requirement_1: $i > $o).
% 28.89/28.91  tff(decl_4434, type, fn_aerobe_17: $i > $i).
% 28.89/28.91  tff(decl_4435, type, fn_carbon_source_2: $i > $i).
% 28.89/28.91  tff(decl_4436, type, fn_nutritional_requirement_5: $i > $i).
% 28.89/28.91  tff(decl_4437, type, fn_nutritional_requirement_6: $i > $i).
% 28.89/28.91  tff(decl_4438, type, fn_nutritional_requirement_4: $i > $i).
% 28.89/28.91  tff(decl_4439, type, fn_nutritional_requirement_7: $i > $i).
% 28.89/28.91  tff(decl_4440, type, fn_nutritional_requirement_3: $i > $i).
% 28.89/28.91  tff(decl_4441, type, fn_nutritional_requirement_8: $i > $i).
% 28.89/28.91  tff(decl_4442, type, fn_nutritional_requirement_2: $i > $i).
% 28.89/28.91  tff(decl_4443, type, fn_nutritional_requirement_9: $i > $i).
% 28.89/28.91  tff(decl_4444, type, fn_nutritional_requirement_10: $i > $i).
% 28.89/28.91  tff(decl_4445, type, aerobic_condition_1: $i > $o).
% 28.89/28.91  tff(decl_4446, type, 'Aerobic-Condition': $i).
% 28.89/28.91  tff(decl_4447, type, 'A biological process which occurs in the presence of molecular oxygen.': $i).
% 28.89/28.91  tff(decl_4448, type, 'aerobic condition': $i).
% 28.89/28.91  tff(decl_4449, type, 'aerobic-condition': $i).
% 28.89/28.91  tff(decl_4450, type, condition_1: $i > $o).
% 28.89/28.91  tff(decl_4451, type, afferent_arteriole_1: $i > $o).
% 28.89/28.91  tff(decl_4452, type, 'Afferent-Arteriole': $i).
% 28.89/28.91  tff(decl_4453, type, 'In the kidney, the blood vessel supplying a nephron.': $i).
% 28.89/28.91  tff(decl_4454, type, 'afferent arteriole': $i).
% 28.89/28.91  tff(decl_4455, type, 'afferent-arteriole': $i).
% 28.89/28.91  tff(decl_4456, type, arteriole_1: $i > $o).
% 28.89/28.91  tff(decl_4457, type, efferent_arteriole_1: $i > $o).
% 28.89/28.91  tff(decl_4458, type, aflatoxin_1: $i > $o).
% 28.89/28.91  tff(decl_4459, type, 'Aflatoxin': $i).
% 28.89/28.91  tff(decl_4460, type, 'A class of carcinogenic substances secreted by some fungi.': $i).
% 28.89/28.91  tff(decl_4461, type, aflatoxin: $i).
% 28.89/28.91  tff(decl_4462, type, amine_1: $i > $o).
% 28.89/28.91  tff(decl_4463, type, antibiotic_1: $i > $o).
% 28.89/28.91  tff(decl_4464, type, carbon_monoxide_1: $i > $o).
% 28.89/28.91  tff(decl_4465, type, ddt_1: $i > $o).
% 28.89/28.91  tff(decl_4466, type, ice_1: $i > $o).
% 28.89/28.91  tff(decl_4467, type, nitroglycerine_1: $i > $o).
% 28.89/28.91  tff(decl_4468, type, opiate_1: $i > $o).
% 28.89/28.91  tff(decl_4469, type, fn_aflatoxin_1: $i > $i).
% 28.89/28.91  tff(decl_4470, type, fn_aflatoxin_2: $i > $i).
% 28.89/28.91  tff(decl_4471, type, fn_aflatoxin_3: $i > $i).
% 28.89/28.91  tff(decl_4472, type, fn_aflatoxin_4: $i > $i).
% 28.89/28.91  tff(decl_4473, type, toxin_1: $i > $o).
% 28.89/28.91  tff(decl_4474, type, fn_toxin_1: $i > $i).
% 28.89/28.91  tff(decl_4475, type, african_sleeping_sickness_1: $i > $o).
% 28.89/28.91  tff(decl_4476, type, 'African-Sleeping-Sickness': $i).
% 28.89/28.91  tff(decl_4477, type, 'A disease caused by the protozoan parasite Trypanosoma brucei, with a tse tse fly as the vector.': $i).
% 28.89/28.91  tff(decl_4478, type, 'human african trypanosomiasis': $i).
% 28.89/28.91  tff(decl_4479, type, 'human-african-trypanosomiasis': $i).
% 28.89/28.91  tff(decl_4480, type, 'sleeping sickness': $i).
% 28.89/28.91  tff(decl_4481, type, 'sleeping-sickness': $i).
% 28.89/28.91  tff(decl_4482, type, 'african lethargy': $i).
% 28.89/28.91  tff(decl_4483, type, 'african-lethargy': $i).
% 28.89/28.91  tff(decl_4484, type, 'congo trypanosomiasis': $i).
% 28.89/28.91  tff(decl_4485, type, 'congo-trypanosomiasis': $i).
% 28.89/28.91  tff(decl_4486, type, 'congo fever': $i).
% 28.89/28.91  tff(decl_4487, type, 'congo-fever': $i).
% 28.89/28.91  tff(decl_4488, type, 'african sleeping sickness': $i).
% 28.89/28.91  tff(decl_4489, type, 'african-sleeping-sickness': $i).
% 28.89/28.91  tff(decl_4490, type, protozoan_disease_1: $i > $o).
% 28.89/28.91  tff(decl_4491, type, aids_1: $i > $o).
% 28.89/28.91  tff(decl_4492, type, cholera_1: $i > $o).
% 28.89/28.91  tff(decl_4493, type, cowpox_1: $i > $o).
% 28.89/28.91  tff(decl_4494, type, encephalitis_1: $i > $o).
% 28.89/28.91  tff(decl_4495, type, gastric_ulcer_1: $i > $o).
% 28.89/28.91  tff(decl_4496, type, gonorrhea_1: $i > $o).
% 28.89/28.91  tff(decl_4497, type, hemorrhagic_fever_1: $i > $o).
% 28.89/28.91  tff(decl_4498, type, influenza_1: $i > $o).
% 28.89/28.91  tff(decl_4499, type, lyme_disease_1: $i > $o).
% 28.89/28.91  tff(decl_4500, type, malaria_1: $i > $o).
% 28.89/28.91  tff(decl_4501, type, mycosis_1: $i > $o).
% 28.89/28.91  tff(decl_4502, type, smallpox_1: $i > $o).
% 28.89/28.91  tff(decl_4503, type, tetanus_1: $i > $o).
% 28.89/28.91  tff(decl_4504, type, tobacco_mosaic_disease_1: $i > $o).
% 28.89/28.91  tff(decl_4505, type, tuberculosis_1: $i > $o).
% 28.89/28.91  tff(decl_4506, type, agar_1: $i > $o).
% 28.89/28.91  tff(decl_4507, type, 'Agar': $i).
% 28.89/28.91  tff(decl_4508, type, 'Agar or agar-agar is a gelatinous substance derived from a polysaccharide that accumulates in the cell walls of agarophyte red algae.': $i).
% 28.89/28.91  tff(decl_4509, type, 'agar agar': $i).
% 28.89/28.91  tff(decl_4510, type, agar: $i).
% 28.89/28.91  tff(decl_4511, type, semisolid_substance_1: $i > $o).
% 28.89/28.91  tff(decl_4512, type, agar_medium_1: $i > $o).
% 28.89/28.91  tff(decl_4513, type, 'Agar-Medium': $i).
% 28.89/28.91  tff(decl_4514, type, 'An example of bacterial growth medium is agar medium.': $i).
% 28.89/28.91  tff(decl_4515, type, 'medium of agar': $i).
% 28.89/28.91  tff(decl_4516, type, 'agar medium': $i).
% 28.89/28.91  tff(decl_4517, type, 'agar-medium': $i).
% 28.89/28.91  tff(decl_4518, type, culture_medium_1: $i > $o).
% 28.89/28.91  tff(decl_4519, type, fn_agar_medium_1: $i > $i).
% 28.89/28.91  tff(decl_4520, type, 'Age-Constant': $i).
% 28.89/28.91  tff(decl_4521, type, 'constant of age': $i).
% 28.89/28.91  tff(decl_4522, type, 'age constant': $i).
% 28.89/28.91  tff(decl_4523, type, 'age-constant': $i).
% 28.89/28.91  tff(decl_4524, type, age_scale_1: $i > $o).
% 28.89/28.91  tff(decl_4525, type, 'Age-Scale': $i).
% 28.89/28.91  tff(decl_4526, type, 'scale of age': $i).
% 28.89/28.91  tff(decl_4527, type, 'age scale': $i).
% 28.89/28.91  tff(decl_4528, type, 'age-scale': $i).
% 28.89/28.91  tff(decl_4529, type, age_structure_1: $i > $o).
% 28.89/28.91  tff(decl_4530, type, 'Age-Structure': $i).
% 28.89/28.91  tff(decl_4531, type, 'The proportion of individuals in each age class of a population.': $i).
% 28.89/28.91  tff(decl_4532, type, 'structure of age': $i).
% 28.89/28.91  tff(decl_4533, type, 'age structure': $i).
% 28.89/28.91  tff(decl_4534, type, 'age-structure': $i).
% 28.89/28.91  tff(decl_4535, type, population_ecology_1: $i > $o).
% 28.89/28.91  tff(decl_4536, type, sustainable_development_1: $i > $o).
% 28.89/28.91  tff(decl_4537, type, zero_population_growth_1: $i > $o).
% 28.89/28.91  tff(decl_4538, type, 'Age-Structure-Diagram': $i).
% 28.89/28.91  tff(decl_4539, type, 'A graphical illustration that shows the distribution of various age groups in a human population.': $i).
% 28.89/28.91  tff(decl_4540, type, 'age structure diagram': $i).
% 28.89/28.91  tff(decl_4541, type, 'age-structure diagram': $i).
% 28.89/28.91  tff(decl_4542, type, 'age-structure-diagram': $i).
% 28.89/28.91  tff(decl_4543, type, population_representation_1: $i > $o).
% 28.89/28.91  tff(decl_4544, type, 'Agent-Role': $i).
% 28.89/28.91  tff(decl_4545, type, agent: $i).
% 28.89/28.91  tff(decl_4546, type, 'causal agency': $i).
% 28.89/28.91  tff(decl_4547, type, causal_agency: $i).
% 28.89/28.91  tff(decl_4548, type, 'causal agent': $i).
% 28.89/28.91  tff(decl_4549, type, causal_agent: $i).
% 28.89/28.91  tff(decl_4550, type, cause: $i).
% 28.89/28.91  tff(decl_4551, type, 'role of agent': $i).
% 28.89/28.91  tff(decl_4552, type, 'agent role': $i).
% 28.89/28.91  tff(decl_4553, type, 'agent-role': $i).
% 28.89/28.91  tff(decl_4554, type, agentive_relation_1: $i > $o).
% 28.89/28.91  tff(decl_4555, type, 'Agentive-Relation': $i).
% 28.89/28.91  tff(decl_4556, type, 'agentive relation': $i).
% 28.89/28.91  tff(decl_4557, type, 'agentive-relation': $i).
% 28.89/28.91  tff(decl_4558, type, relation_1: $i > $o).
% 28.89/28.91  tff(decl_4559, type, agglutination_1: $i > $o).
% 28.89/28.91  tff(decl_4560, type, 'Agglutination': $i).
% 28.89/28.91  tff(decl_4561, type, 'Agglutination refers to the clumping or sticking together of various substances.': $i).
% 28.89/28.91  tff(decl_4562, type, agglutinate: $i).
% 28.89/28.91  tff(decl_4563, type, agglutination: $i).
% 28.89/28.91  tff(decl_4564, type, biological_process_1: $i > $o).
% 28.89/28.91  tff(decl_4565, type, 'Aggregate': $i).
% 28.89/28.91  tff(decl_4566, type, 'top level component for collections': $i).
% 28.89/28.91  tff(decl_4567, type, group: $i).
% 28.89/28.91  tff(decl_4568, type, whole: $i).
% 28.89/28.91  tff(decl_4569, type, 'whole thing': $i).
% 28.89/28.91  tff(decl_4570, type, whole_thing: $i).
% 28.89/28.91  tff(decl_4571, type, unit: $i).
% 28.89/28.91  tff(decl_4572, type, aggregate: $i).
% 28.89/28.91  tff(decl_4573, type, congeries: $i).
% 28.89/28.91  tff(decl_4574, type, conglomeration: $i).
% 28.89/28.91  tff(decl_4575, type, grouping: $i).
% 28.89/28.91  tff(decl_4576, type, complex: $i).
% 28.89/28.91  tff(decl_4577, type, 'Aggregate-Fruit': $i).
% 28.89/28.91  tff(decl_4578, type, 'A fruit that develops from multiple ovaries that have merged together within a single flower.': $i).
% 28.89/28.91  tff(decl_4579, type, 'fruit of aggregate': $i).
% 28.89/28.91  tff(decl_4580, type, 'aggregate fruit': $i).
% 28.89/28.91  tff(decl_4581, type, 'aggregate-fruit': $i).
% 28.89/28.91  tff(decl_4582, type, agonistic_behavior_1: $i > $o).
% 28.89/28.91  tff(decl_4583, type, 'Agonistic-Behavior': $i).
% 28.89/28.91  tff(decl_4584, type, 'Any animal behavior that results from competition for a limited resource.': $i).
% 28.89/28.91  tff(decl_4585, type, 'agonistic behavior': $i).
% 28.89/28.91  tff(decl_4586, type, 'agonistic-behavior': $i).
% 28.89/28.91  tff(decl_4587, type, social_behavior_1: $i > $o).
% 28.89/28.91  tff(decl_4588, type, agricultural_process_1: $i > $o).
% 28.89/28.91  tff(decl_4589, type, 'Agricultural-Process': $i).
% 28.89/28.91  tff(decl_4590, type, 'A process related to the production of food and goods through farming.': $i).
% 28.89/28.91  tff(decl_4591, type, 'agricultural process': $i).
% 28.89/28.91  tff(decl_4592, type, 'agricultural-process': $i).
% 28.89/28.91  tff(decl_4593, type, ecological_process_1: $i > $o).
% 28.89/28.91  tff(decl_4594, type, agricultural_product_1: $i > $o).
% 28.89/28.91  tff(decl_4595, type, 'Agricultural-Product': $i).
% 28.89/28.91  tff(decl_4596, type, 'A useful product, such as a food or textile, that comes from agriculture.': $i).
% 28.89/28.91  tff(decl_4597, type, 'agricultural product': $i).
% 28.89/28.91  tff(decl_4598, type, 'agricultural-product': $i).
% 28.89/28.91  tff(decl_4599, type, useful_product_1: $i > $o).
% 28.89/28.91  tff(decl_4600, type, fn_agricultural_product_1: $i > $i).
% 28.89/28.91  tff(decl_4601, type, fn_agricultural_product_2: $i > $i).
% 28.89/28.91  tff(decl_4602, type, fn_artifact_1: $i > $i).
% 28.89/28.91  tff(decl_4603, type, agrobacterium_tumefaciens_1: $i > $o).
% 28.89/28.91  tff(decl_4604, type, 'Agrobacterium-Tumefaciens': $i).
% 28.89/28.91  tff(decl_4605, type, 'A common soil bacterium, source of the Ti plasmid, which induces tumors in plants.': $i).
% 28.89/28.91  tff(decl_4606, type, 'agrobacterium tumefaciens': $i).
% 28.89/28.91  tff(decl_4607, type, 'agrobacterium tumefacien': $i).
% 28.89/28.91  tff(decl_4608, type, 'agrobacterium-tumefacien': $i).
% 28.89/28.91  tff(decl_4609, type, gram_negative_bacteria_1: $i > $o).
% 28.89/28.91  tff(decl_4610, type, salmonella_1: $i > $o).
% 28.89/28.91  tff(decl_4611, type, 'AIDS': $i).
% 28.89/28.91  tff(decl_4612, type, 'A disease of the human immune system caused by the human immunodeficiency virus (HIV). This condition progressively reduces the effectiveness of the immune system and leaves individuals susceptible to opportunistic infections and tumors.': $i).
% 28.89/28.91  tff(decl_4613, type, 'acquired immunodeficiency syndrome': $i).
% 28.89/28.91  tff(decl_4614, type, 'acquired-immunodeficiency-syndrome': $i).
% 28.89/28.91  tff(decl_4615, type, aids: $i).
% 28.89/28.91  tff(decl_4616, type, 'acquired immune deficiency syndrome': $i).
% 28.89/28.91  tff(decl_4617, type, 'acquired-immune-deficiency-syndrome': $i).
% 28.89/28.91  tff(decl_4618, type, aid: $i).
% 28.89/28.91  tff(decl_4619, type, viral_disease_1: $i > $o).
% 28.89/28.91  tff(decl_4620, type, 'Air': $i).
% 28.89/28.91  tff(decl_4621, type, air: $i).
% 28.89/28.91  tff(decl_4622, type, wind: $i).
% 28.89/28.91  tff(decl_4623, type, gas_substance_1: $i > $o).
% 28.89/28.91  tff(decl_4624, type, vapor_1: $i > $o).
% 28.89/28.91  tff(decl_4625, type, nitric_oxide_gas_1: $i > $o).
% 28.89/28.91  tff(decl_4626, type, air_space_1: $i > $o).
% 28.89/28.91  tff(decl_4627, type, 'Air-Space': $i).
% 28.89/28.91  tff(decl_4628, type, 'The space with air in it.': $i).
% 28.89/28.91  tff(decl_4629, type, 'air space': $i).
% 28.89/28.91  tff(decl_4630, type, 'space of air': $i).
% 28.89/28.91  tff(decl_4631, type, 'air-space': $i).
% 28.89/28.91  tff(decl_4632, type, space_1: $i > $o).
% 28.89/28.91  tff(decl_4633, type, fn_air_space_1: $i > $i).
% 28.89/28.91  tff(decl_4634, type, air_water_interface_1: $i > $o).
% 28.89/28.91  tff(decl_4635, type, 'Air-Water-Interface': $i).
% 28.89/28.91  tff(decl_4636, type, 'Region of contact between air and the surface of a body of water.': $i).
% 28.89/28.91  tff(decl_4637, type, 'air water interface': $i).
% 28.89/28.91  tff(decl_4638, type, 'air-water-interface': $i).
% 28.89/28.91  tff(decl_4639, type, alanine_1: $i > $o).
% 28.89/28.91  tff(decl_4640, type, 'Alanine': $i).
% 28.89/28.91  tff(decl_4641, type, 'One of the 20 most common amino acids that make up proteins.': $i).
% 28.89/28.91  tff(decl_4642, type, alanine: $i).
% 28.89/28.91  tff(decl_4643, type, fn_alanine_1: $i > $i).
% 28.89/28.91  tff(decl_4644, type, fn_alanine_2: $i > $i).
% 28.89/28.91  tff(decl_4645, type, fn_alanine_3: $i > $i).
% 28.89/28.91  tff(decl_4646, type, fn_alanine_4: $i > $i).
% 28.89/28.91  tff(decl_4647, type, fn_alanine_5: $i > $i).
% 28.89/28.91  tff(decl_4648, type, fn_alanine_6: $i > $i).
% 28.89/28.91  tff(decl_4649, type, fn_alanine_7: $i > $i).
% 28.89/28.91  tff(decl_4650, type, fn_alanine_8: $i > $i).
% 28.89/28.91  tff(decl_4651, type, fn_alanine_9: $i > $i).
% 28.89/28.91  tff(decl_4652, type, fn_alanine_10: $i > $i).
% 28.89/28.91  tff(decl_4653, type, equal_sharing_1: $i > $o).
% 28.89/28.91  tff(decl_4654, type, fn_alanine_11: $i > $i).
% 28.89/28.91  tff(decl_4655, type, fn_alanine_12: $i > $i).
% 28.89/28.91  tff(decl_4656, type, fn_alanine_13: $i > $i).
% 28.89/28.91  tff(decl_4657, type, fn_alanine_14: $i > $i).
% 28.89/28.91  tff(decl_4658, type, fn_alanine_15: $i > $i).
% 28.89/28.91  tff(decl_4659, type, fn_alanine_16: $i > $i).
% 28.89/28.91  tff(decl_4660, type, fn_alanine_17: $i > $i).
% 28.89/28.91  tff(decl_4661, type, fn_alanine_18: $i > $i).
% 28.89/28.91  tff(decl_4662, type, fn_alanine_19: $i > $i).
% 28.89/28.91  tff(decl_4663, type, fn_alanine_20: $i > $i).
% 28.89/28.91  tff(decl_4664, type, fn_alanine_21: $i > $i).
% 28.89/28.91  tff(decl_4665, type, fn_alanine_22: $i > $i).
% 28.89/28.91  tff(decl_4666, type, fn_alanine_23: $i > $i).
% 28.89/28.91  tff(decl_4667, type, fn_alanine_24: $i > $i).
% 28.89/28.91  tff(decl_4668, type, fn_alanine_25: $i > $i).
% 28.89/28.91  tff(decl_4669, type, fn_alanine_29: $i > $i).
% 28.89/28.91  tff(decl_4670, type, fn_alanine_30: $i > $i).
% 28.89/28.91  tff(decl_4671, type, fn_alanine_31: $i > $i).
% 28.89/28.91  tff(decl_4672, type, fn_alanine_32: $i > $i).
% 28.89/28.91  tff(decl_4673, type, fn_alanine_33: $i > $i).
% 28.89/28.91  tff(decl_4674, type, fn_alanine_34: $i > $i).
% 28.89/28.91  tff(decl_4675, type, fn_alanine_35: $i > $i).
% 28.89/28.91  tff(decl_4676, type, fn_alanine_36: $i > $i).
% 28.89/28.91  tff(decl_4677, type, fn_alanine_37: $i > $i).
% 28.89/28.91  tff(decl_4678, type, fn_alanine_38: $i > $i).
% 28.89/28.91  tff(decl_4679, type, fn_alanine_39: $i > $i).
% 28.89/28.91  tff(decl_4680, type, fn_alanine_40: $i > $i).
% 28.89/28.91  tff(decl_4681, type, fn_alanine_41: $i > $i).
% 28.89/28.91  tff(decl_4682, type, fn_alanine_42: $i > $i).
% 28.89/28.91  tff(decl_4683, type, fn_alanine_43: $i > $i).
% 28.89/28.91  tff(decl_4684, type, fn_alanine_44: $i > $i).
% 28.89/28.91  tff(decl_4685, type, fn_alanine_45: $i > $i).
% 28.89/28.91  tff(decl_4686, type, fn_alanine_46: $i > $i).
% 28.89/28.91  tff(decl_4687, type, fn_alanine_47: $i > $i).
% 28.89/28.91  tff(decl_4688, type, fn_alanine_48: $i > $i).
% 28.89/28.91  tff(decl_4689, type, fn_alanine_49: $i > $i).
% 28.89/28.91  tff(decl_4690, type, fn_alanine_50: $i > $i).
% 28.89/28.91  tff(decl_4691, type, fn_alanine_51: $i > $i).
% 28.89/28.91  tff(decl_4692, type, fn_alanine_52: $i > $i).
% 28.89/28.91  tff(decl_4693, type, fn_alanine_58: $i > $i).
% 28.89/28.91  tff(decl_4694, type, fn_alanine_59: $i > $i).
% 28.89/28.91  tff(decl_4695, type, fn_alanine_60: $i > $i).
% 28.89/28.91  tff(decl_4696, type, non_polar_side_chain_1: $i > $o).
% 28.89/28.91  tff(decl_4697, type, fn_alanine_61: $i > $i).
% 28.89/28.91  tff(decl_4698, type, fn_alanine_62: $i > $i).
% 28.89/28.91  tff(decl_4699, type, fn_alanine_63: $i > $i).
% 28.89/28.91  tff(decl_4700, type, fn_alanine_64: $i > $i).
% 28.89/28.91  tff(decl_4701, type, fn_alanine_65: $i > $i).
% 28.89/28.91  tff(decl_4702, type, fn_alanine_66: $i > $i).
% 28.89/28.91  tff(decl_4703, type, repel_1: $i > $o).
% 28.89/28.91  tff(decl_4704, type, fn_alanine_67: $i > $i).
% 28.89/28.91  tff(decl_4705, type, fn_alanine_68: $i > $i).
% 28.89/28.91  tff(decl_4706, type, fn_alanine_69: $i > $i).
% 28.89/28.92  tff(decl_4707, type, fn_alanine_70: $i > $i).
% 28.89/28.92  tff(decl_4708, type, fn_alanine_71: $i > $i).
% 28.89/28.92  tff(decl_4709, type, fn_alanine_72: $i > $i).
% 28.89/28.92  tff(decl_4710, type, fn_alanine_73: $i > $i).
% 28.89/28.92  tff(decl_4711, type, fn_alanine_74: $i > $i).
% 28.89/28.92  tff(decl_4712, type, fn_alanine_75: $i > $i).
% 28.89/28.92  tff(decl_4713, type, fn_alanine_76: $i > $i).
% 28.89/28.92  tff(decl_4714, type, fn_alanine_77: $i > $i).
% 28.89/28.92  tff(decl_4715, type, fn_alanine_78: $i > $i).
% 28.89/28.92  tff(decl_4716, type, fn_alanine_79: $i > $i).
% 28.89/28.92  tff(decl_4717, type, nonpolar_covalent_bond_1: $i > $o).
% 28.89/28.92  tff(decl_4718, type, fn_alanine_80: $i > $i).
% 28.89/28.92  tff(decl_4719, type, fn_alanine_81: $i > $i).
% 28.89/28.92  tff(decl_4720, type, pyruvate_1: $i > $o).
% 28.89/28.92  tff(decl_4721, type, fn_alanine_82: $i > $i).
% 28.89/28.92  tff(decl_4722, type, fn_alanine_83: $i > $i).
% 28.89/28.92  tff(decl_4723, type, fn_alanine_84: $i > $i).
% 28.89/28.92  tff(decl_4724, type, fn_alanine_85: $i > $i).
% 28.89/28.92  tff(decl_4725, type, fn_alanine_86: $i > $i).
% 28.89/28.92  tff(decl_4726, type, fn_alanine_87: $i > $i).
% 28.89/28.92  tff(decl_4727, type, fn_alanine_88: $i > $i).
% 28.89/28.92  tff(decl_4728, type, fn_alanine_89: $i > $i).
% 28.89/28.92  tff(decl_4729, type, fn_alanine_90: $i > $i).
% 28.89/28.92  tff(decl_4730, type, fn_alanine_91: $i > $i).
% 28.89/28.92  tff(decl_4731, type, fn_alanine_92: $i > $i).
% 28.89/28.92  tff(decl_4732, type, fn_alanine_93: $i > $i).
% 28.89/28.92  tff(decl_4733, type, fn_alanine_94: $i > $i).
% 28.89/28.92  tff(decl_4734, type, fn_alanine_95: $i > $i).
% 28.89/28.92  tff(decl_4735, type, fn_alanine_96: $i > $i).
% 28.89/28.92  tff(decl_4736, type, fn_alanine_97: $i > $i).
% 28.89/28.92  tff(decl_4737, type, fn_alanine_98: $i > $i).
% 28.89/28.92  tff(decl_4738, type, fn_alanine_99: $i > $i).
% 28.89/28.92  tff(decl_4739, type, fn_alanine_100: $i > $i).
% 28.89/28.92  tff(decl_4740, type, fn_alanine_101: $i > $i).
% 28.89/28.92  tff(decl_4741, type, fn_alanine_102: $i > $i).
% 28.89/28.92  tff(decl_4742, type, fn_alanine_103: $i > $i).
% 28.89/28.92  tff(decl_4743, type, fn_alanine_104: $i > $i).
% 28.89/28.92  tff(decl_4744, type, fn_alanine_105: $i > $i).
% 28.89/28.92  tff(decl_4745, type, fn_alanine_106: $i > $i).
% 28.89/28.92  tff(decl_4746, type, fn_alanine_107: $i > $i).
% 28.89/28.92  tff(decl_4747, type, fn_alanine_108: $i > $i).
% 28.89/28.92  tff(decl_4748, type, fn_nonpolar_covalent_bond_3: $i > $i).
% 28.89/28.92  tff(decl_4749, type, fn_nonpolar_covalent_bond_27: $i > $i).
% 28.89/28.92  tff(decl_4750, type, fn_nonpolar_covalent_bond_5: $i > $i).
% 28.89/28.92  tff(decl_4751, type, fn_carbon_9: $i > $i).
% 28.89/28.92  tff(decl_4752, type, fn_carbon_1: $i > $i).
% 28.89/28.92  tff(decl_4753, type, fn_carbon_11: $i > $i).
% 28.89/28.92  tff(decl_4754, type, fn_carbon_7: $i > $i).
% 28.89/28.92  tff(decl_4755, type, equation_big_node_1: $i > $o).
% 28.89/28.92  tff(decl_4756, type, fn_carbon_20: $i > $i).
% 28.89/28.92  tff(decl_4757, type, fn_oxygen_5: $i > $i).
% 28.89/28.92  tff(decl_4758, type, fn_nonpolar_covalent_bond_2: $i > $i).
% 28.89/28.92  tff(decl_4759, type, fn_nonpolar_covalent_bond_28: $i > $i).
% 28.89/28.92  tff(decl_4760, type, fn_nonpolar_covalent_bond_29: $i > $i).
% 28.89/28.92  tff(decl_4761, type, fn_nonpolar_covalent_bond_24: $i > $i).
% 28.89/28.92  tff(decl_4762, type, fn_nonpolar_covalent_bond_20: $i > $i).
% 28.89/28.92  tff(decl_4763, type, fn_carbon_10: $i > $i).
% 28.89/28.92  tff(decl_4764, type, fn_nonpolar_covalent_bond_26: $i > $i).
% 28.89/28.92  tff(decl_4765, type, fn_nonpolar_covalent_bond_22: $i > $i).
% 28.89/28.92  tff(decl_4766, type, fn_carbon_13: $i > $i).
% 28.89/28.92  tff(decl_4767, type, fn_nonpolar_covalent_bond_1: $i > $i).
% 28.89/28.92  tff(decl_4768, type, fn_carbon_2: $i > $i).
% 28.89/28.92  tff(decl_4769, type, fn_atom_11: $i > $i).
% 28.89/28.92  tff(decl_4770, type, fn_carbon_19: $i > $i).
% 28.89/28.92  tff(decl_4771, type, fn_carbon_16: $i > $i).
% 28.89/28.92  tff(decl_4772, type, fn_atom_18: $i > $i).
% 28.89/28.92  tff(decl_4773, type, fn_nonpolar_covalent_bond_23: $i > $i).
% 28.89/28.92  tff(decl_4774, type, fn_nonpolar_covalent_bond_19: $i > $i).
% 28.89/28.92  tff(decl_4775, type, fn_carbon_18: $i > $i).
% 28.89/28.92  tff(decl_4776, type, fn_atom_8: $i > $i).
% 28.89/28.92  tff(decl_4777, type, fn_carbon_17: $i > $i).
% 28.89/28.92  tff(decl_4778, type, 'Number_Proton': $i).
% 28.89/28.92  tff(decl_4779, type, 'Atomic_Number': $i).
% 28.89/28.92  tff(decl_4780, type, fn_alanine_57: $i > $i).
% 28.89/28.92  tff(decl_4781, type, fn_alanine_55: $i > $i).
% 28.89/28.92  tff(decl_4782, type, fn_alanine_54: $i > $i).
% 28.89/28.92  tff(decl_4783, type, fn_amino_acid_15: $i > $i).
% 28.89/28.92  tff(decl_4784, type, fn_amino_acid_18: $i > $i).
% 28.89/28.92  tff(decl_4785, type, fn_amino_acid_14: $i > $i).
% 28.89/28.92  tff(decl_4786, type, fn_amino_acid_27: $i > $i).
% 28.89/28.92  tff(decl_4787, type, fn_amino_acid_12: $i > $i).
% 28.89/28.92  tff(decl_4788, type, fn_amino_acid_10: $i > $i).
% 28.89/28.92  tff(decl_4789, type, fn_amino_acid_11: $i > $i).
% 28.89/28.92  tff(decl_4790, type, fn_amino_acid_24: $i > $i).
% 28.89/28.92  tff(decl_4791, type, fn_amino_acid_13: $i > $i).
% 28.89/28.92  tff(decl_4792, type, fn_amino_acid_22: $i > $i).
% 28.89/28.92  tff(decl_4793, type, fn_amino_acid_25: $i > $i).
% 28.89/28.92  tff(decl_4794, type, fn_hydrophobic_amino_acid_5: $i > $i).
% 28.89/28.92  tff(decl_4795, type, fn_hydrophobic_amino_acid_78: $i > $i).
% 28.89/28.92  tff(decl_4796, type, fn_hydrophobic_amino_acid_44: $i > $i).
% 28.89/28.92  tff(decl_4797, type, fn_hydrophobic_amino_acid_64: $i > $i).
% 28.89/28.92  tff(decl_4798, type, fn_hydrophobic_amino_acid_65: $i > $i).
% 28.89/28.92  tff(decl_4799, type, fn_hydrophobic_amino_acid_41: $i > $i).
% 28.89/28.92  tff(decl_4800, type, fn_hydrophobic_amino_acid_18: $i > $i).
% 28.89/28.92  tff(decl_4801, type, fn_hydrophobic_amino_acid_80: $i > $i).
% 28.89/28.92  tff(decl_4802, type, fn_hydrophobic_amino_acid_62: $i > $i).
% 28.89/28.92  tff(decl_4803, type, fn_hydrophobic_amino_acid_26: $i > $i).
% 28.89/28.92  tff(decl_4804, type, fn_hydrophobic_amino_acid_79: $i > $i).
% 28.89/28.92  tff(decl_4805, type, fn_hydrophobic_amino_acid_43: $i > $i).
% 28.89/28.92  tff(decl_4806, type, fn_hydrophobic_amino_acid_45: $i > $i).
% 28.89/28.92  tff(decl_4807, type, fn_hydrophobic_amino_acid_11: $i > $i).
% 28.89/28.92  tff(decl_4808, type, fn_hydrophobic_amino_acid_63: $i > $i).
% 28.89/28.92  tff(decl_4809, type, fn_hydrophobic_amino_acid_42: $i > $i).
% 28.89/28.92  tff(decl_4810, type, fn_hydrophobic_amino_acid_35: $i > $i).
% 28.89/28.92  tff(decl_4811, type, fn_hydrophobic_amino_acid_15: $i > $i).
% 28.89/28.92  tff(decl_4812, type, fn_hydrophobic_amino_acid_31: $i > $i).
% 28.89/28.92  tff(decl_4813, type, fn_hydrophobic_amino_acid_82: $i > $i).
% 28.89/28.92  tff(decl_4814, type, fn_hydrophobic_amino_acid_3: $i > $i).
% 28.89/28.92  tff(decl_4815, type, fn_hydrophobic_amino_acid_9: $i > $i).
% 28.89/28.92  tff(decl_4816, type, fn_hydrophobic_amino_acid_4: $i > $i).
% 28.89/28.92  tff(decl_4817, type, fn_hydrophobic_amino_acid_60: $i > $i).
% 28.89/28.92  tff(decl_4818, type, fn_hydrophobic_amino_acid_16: $i > $i).
% 28.89/28.92  tff(decl_4819, type, fn_hydrophobic_amino_acid_81: $i > $i).
% 28.89/28.92  tff(decl_4820, type, fn_hydrophobic_amino_acid_6: $i > $i).
% 28.89/28.92  tff(decl_4821, type, fn_hydrophobic_amino_acid_19: $i > $i).
% 28.89/28.92  tff(decl_4822, type, fn_hydrophobic_amino_acid_29: $i > $i).
% 28.89/28.92  tff(decl_4823, type, fn_hydrophobic_amino_acid_28: $i > $i).
% 28.89/28.92  tff(decl_4824, type, fn_hydrophobic_amino_acid_21: $i > $i).
% 28.89/28.92  tff(decl_4825, type, fn_hydrophobic_amino_acid_68: $i > $i).
% 28.89/28.92  tff(decl_4826, type, fn_hydrophobic_amino_acid_10: $i > $i).
% 28.89/28.92  tff(decl_4827, type, fn_hydrophobic_amino_acid_38: $i > $i).
% 28.89/28.92  tff(decl_4828, type, fn_hydrophobic_amino_acid_67: $i > $i).
% 28.89/28.92  tff(decl_4829, type, fn_hydrophobic_amino_acid_66: $i > $i).
% 28.89/28.92  tff(decl_4830, type, fn_hydrophobic_amino_acid_13: $i > $i).
% 28.89/28.92  tff(decl_4831, type, fn_hydrophobic_amino_acid_14: $i > $i).
% 28.89/28.92  tff(decl_4832, type, fn_hydrophobic_amino_acid_22: $i > $i).
% 28.89/28.92  tff(decl_4833, type, fn_hydrophobic_amino_acid_30: $i > $i).
% 28.89/28.92  tff(decl_4834, type, fn_hydrophobic_amino_acid_8: $i > $i).
% 28.89/28.92  tff(decl_4835, type, fn_hydrophobic_amino_acid_51: $i > $i).
% 28.89/28.92  tff(decl_4836, type, fn_hydrophobic_amino_acid_34: $i > $i).
% 28.89/28.92  tff(decl_4837, type, fn_hydrophobic_amino_acid_23: $i > $i).
% 28.89/28.92  tff(decl_4838, type, fn_hydrophobic_amino_acid_7: $i > $i).
% 28.89/28.92  tff(decl_4839, type, fn_hydrophobic_amino_acid_36: $i > $i).
% 28.89/28.92  tff(decl_4840, type, fn_hydrophobic_amino_acid_40: $i > $i).
% 28.89/28.92  tff(decl_4841, type, fn_hydrophobic_amino_acid_24: $i > $i).
% 28.89/28.92  tff(decl_4842, type, fn_hydrophobic_amino_acid_69: $i > $i).
% 28.89/28.92  tff(decl_4843, type, fn_hydrophobic_amino_acid_59: $i > $i).
% 28.89/28.92  tff(decl_4844, type, fn_hydrophobic_amino_acid_20: $i > $i).
% 28.89/28.92  tff(decl_4845, type, fn_hydrophobic_amino_acid_2: $i > $i).
% 28.89/28.92  tff(decl_4846, type, fn_hydrophobic_amino_acid_1: $i > $i).
% 28.89/28.92  tff(decl_4847, type, fn_hydrophobic_amino_acid_27: $i > $i).
% 28.89/28.92  tff(decl_4848, type, fn_alanine_28: $i > $i).
% 28.89/28.92  tff(decl_4849, type, fn_alanine_27: $i > $i).
% 28.89/28.92  tff(decl_4850, type, fn_alanine_56: $i > $i).
% 28.89/28.92  tff(decl_4851, type, fn_alanine_26: $i > $i).
% 28.89/28.92  tff(decl_4852, type, fn_alanine_53: $i > $i).
% 28.89/28.92  tff(decl_4853, type, albumin_1: $i > $o).
% 28.89/28.92  tff(decl_4854, type, 'Albumin': $i).
% 28.89/28.92  tff(decl_4855, type, 'The white part of an egg, which contains water and proteins.': $i).
% 28.89/28.92  tff(decl_4856, type, 'egg white': $i).
% 28.89/28.92  tff(decl_4857, type, 'egg-white': $i).
% 28.89/28.92  tff(decl_4858, type, albumin: $i).
% 28.89/28.92  tff(decl_4859, type, fn_albumin_1: $i > $i).
% 28.89/28.92  tff(decl_4860, type, fn_albumin_2: $i > $i).
% 28.89/28.92  tff(decl_4861, type, albuterol_1: $i > $o).
% 28.89/28.92  tff(decl_4862, type, 'Albuterol': $i).
% 28.89/28.92  tff(decl_4863, type, 'Albuterol is a bronchodilator that relaxes muscles in the airways and increases air flow to the lungs': $i).
% 28.89/28.92  tff(decl_4864, type, albuterol: $i).
% 28.89/28.92  tff(decl_4865, type, drug_1: $i > $o).
% 28.89/28.92  tff(decl_4866, type, albuterol_isomer_1: $i > $o).
% 28.89/28.92  tff(decl_4867, type, 'Albuterol-Isomer': $i).
% 28.89/28.92  tff(decl_4868, type, 'One of the two forms of albuterol, each with the same atomic parts, but different structure, shape and function.': $i).
% 28.89/28.92  tff(decl_4869, type, 'isomer of albuterol': $i).
% 28.89/28.92  tff(decl_4870, type, 'albuterol isomer': $i).
% 28.89/28.92  tff(decl_4871, type, 'albuterol-isomer': $i).
% 28.89/28.92  tff(decl_4872, type, isomer_1: $i > $o).
% 28.89/28.92  tff(decl_4873, type, fn_albuterol_isomer_1: $i > $i).
% 28.89/28.92  tff(decl_4874, type, alcohol_1: $i > $o).
% 28.89/28.92  tff(decl_4875, type, 'Alcohol': $i).
% 28.89/28.92  tff(decl_4876, type, 'An alcohol is an organic compound in which a hydroxyl functional group (-OH) is bound to a carbon atom, usually connected to other carbon or hydrogen atoms.': $i).
% 28.89/28.92  tff(decl_4877, type, 'r oh': $i).
% 28.89/28.92  tff(decl_4878, type, 'r-oh': $i).
% 28.89/28.92  tff(decl_4879, type, alcohol: $i).
% 28.89/28.92  tff(decl_4880, type, fn_alcohol_1: $i > $i).
% 28.89/28.92  tff(decl_4881, type, fn_alcohol_2: $i > $i).
% 28.89/28.92  tff(decl_4882, type, fn_alcohol_3: $i > $i).
% 28.89/28.92  tff(decl_4883, type, fn_alcohol_4: $i > $i).
% 28.89/28.92  tff(decl_4884, type, fn_alcohol_5: $i > $i).
% 28.89/28.92  tff(decl_4885, type, fn_alcohol_6: $i > $i).
% 28.89/28.92  tff(decl_4886, type, fn_alcohol_7: $i > $i).
% 28.89/28.92  tff(decl_4887, type, fn_alcohol_8: $i > $i).
% 28.89/28.92  tff(decl_4888, type, fn_alcohol_9: $i > $i).
% 28.89/28.92  tff(decl_4889, type, fn_alcohol_10: $i > $i).
% 28.89/28.92  tff(decl_4890, type, fn_hydroxyl_group_6: $i > $i).
% 28.89/28.92  tff(decl_4891, type, fn_carbon_skeleton_4: $i > $i).
% 28.89/28.92  tff(decl_4892, type, fn_hydroxyl_group_7: $i > $i).
% 28.89/28.92  tff(decl_4893, type, fn_carbon_skeleton_2: $i > $i).
% 28.89/28.92  tff(decl_4894, type, fn_hydroxyl_group_4: $i > $i).
% 28.89/28.92  tff(decl_4895, type, fn_carbon_skeleton_3: $i > $i).
% 28.89/28.92  tff(decl_4896, type, fn_alcohol_11: $i > $i).
% 28.89/28.92  tff(decl_4897, type, fn_molecule_2: $i > $i).
% 28.89/28.92  tff(decl_4898, type, fn_alcohol_12: $i > $i).
% 28.89/28.92  tff(decl_4899, type, fn_molecule_1: $i > $i).
% 28.89/28.92  tff(decl_4900, type, fn_molecule_8: $i > $i).
% 28.89/28.92  tff(decl_4901, type, fn_molecule_3: $i > $i).
% 28.89/28.92  tff(decl_4902, type, fn_molecule_4: $i > $i).
% 28.89/28.92  tff(decl_4903, type, fn_molecule_12: $i > $i).
% 28.89/28.92  tff(decl_4904, type, alcohol_dehydrogenase_1: $i > $o).
% 28.89/28.92  tff(decl_4905, type, 'Alcohol-Dehydrogenase': $i).
% 28.89/28.92  tff(decl_4906, type, 'Alcohol dehydrogenase catalyzes the oxidation of alcohols, using NAD+ or NADP+ as the electron acceptor.': $i).
% 28.89/28.92  tff(decl_4907, type, 'dehydrogenase of alcohol': $i).
% 28.89/28.92  tff(decl_4908, type, 'alcohol dehydrogenase': $i).
% 28.89/28.92  tff(decl_4909, type, 'alcohol-dehydrogenase': $i).
% 28.89/28.92  tff(decl_4910, type, dehydrogenase_1: $i > $o).
% 28.89/28.92  tff(decl_4911, type, fn_alcohol_dehydrogenase_5: $i > $i).
% 28.89/28.92  tff(decl_4912, type, fn_alcohol_dehydrogenase_6: $i > $i).
% 28.89/28.92  tff(decl_4913, type, fn_alcohol_dehydrogenase_7: $i > $i).
% 28.89/28.92  tff(decl_4914, type, fn_alcohol_dehydrogenase_8: $i > $i).
% 28.89/28.92  tff(decl_4915, type, fn_alcohol_dehydrogenase_9: $i > $i).
% 28.89/28.92  tff(decl_4916, type, fn_alcohol_dehydrogenase_10: $i > $i).
% 28.89/28.92  tff(decl_4917, type, fn_alcohol_dehydrogenase_11: $i > $i).
% 28.89/28.92  tff(decl_4918, type, fn_alcohol_dehydrogenase_12: $i > $i).
% 28.89/28.92  tff(decl_4919, type, fn_alcohol_dehydrogenase_13: $i > $i).
% 28.89/28.92  tff(decl_4920, type, fn_alcohol_dehydrogenase_14: $i > $i).
% 28.89/28.92  tff(decl_4921, type, fn_alcohol_dehydrogenase_15: $i > $i).
% 28.89/28.92  tff(decl_4922, type, fn_alcohol_dehydrogenase_16: $i > $i).
% 28.89/28.92  tff(decl_4923, type, fn_alcohol_dehydrogenase_17: $i > $i).
% 28.89/28.92  tff(decl_4924, type, fn_alcohol_dehydrogenase_18: $i > $i).
% 28.89/28.92  tff(decl_4925, type, fn_alcohol_dehydrogenase_19: $i > $i).
% 28.89/28.92  tff(decl_4926, type, fn_alcohol_dehydrogenase_20: $i > $i).
% 28.89/28.92  tff(decl_4927, type, fn_alcohol_dehydrogenase_21: $i > $i).
% 28.89/28.92  tff(decl_4928, type, fn_alcohol_dehydrogenase_22: $i > $i).
% 28.89/28.92  tff(decl_4929, type, fn_alcohol_dehydrogenase_23: $i > $i).
% 28.89/28.92  tff(decl_4930, type, fn_alcohol_dehydrogenase_24: $i > $i).
% 28.89/28.92  tff(decl_4931, type, redox_reaction_1: $i > $o).
% 28.89/28.92  tff(decl_4932, type, fn_alcohol_dehydrogenase_25: $i > $i).
% 28.89/28.92  tff(decl_4933, type, fn_alcohol_dehydrogenase_26: $i > $i).
% 28.89/28.92  tff(decl_4934, type, fn_alcohol_dehydrogenase_4: $i > $i).
% 28.89/28.92  tff(decl_4935, type, fn_dehydrogenase_41: $i > $i).
% 28.89/28.92  tff(decl_4936, type, fn_alcohol_dehydrogenase_3: $i > $i).
% 28.89/28.92  tff(decl_4937, type, fn_dehydrogenase_39: $i > $i).
% 28.89/28.92  tff(decl_4938, type, fn_alcohol_dehydrogenase_2: $i > $i).
% 28.89/28.92  tff(decl_4939, type, fn_dehydrogenase_40: $i > $i).
% 28.89/28.92  tff(decl_4940, type, fn_dehydrogenase_18: $i > $i).
% 28.89/28.92  tff(decl_4941, type, fn_alcohol_dehydrogenase_1: $i > $i).
% 28.89/28.92  tff(decl_4942, type, fn_dehydrogenase_38: $i > $i).
% 28.89/28.92  tff(decl_4943, type, fn_dehydrogenase_33: $i > $i).
% 28.89/28.92  tff(decl_4944, type, fn_dehydrogenase_10: $i > $i).
% 28.89/28.92  tff(decl_4945, type, fn_dehydrogenase_20: $i > $i).
% 28.89/28.92  tff(decl_4946, type, fn_dehydrogenase_28: $i > $i).
% 28.89/28.92  tff(decl_4947, type, fn_dehydrogenase_11: $i > $i).
% 28.89/28.92  tff(decl_4948, type, fn_dehydrogenase_14: $i > $i).
% 28.89/28.92  tff(decl_4949, type, fn_dehydrogenase_16: $i > $i).
% 28.89/28.92  tff(decl_4950, type, fn_dehydrogenase_15: $i > $i).
% 28.89/28.92  tff(decl_4951, type, fn_dehydrogenase_22: $i > $i).
% 28.89/28.92  tff(decl_4952, type, fn_dehydrogenase_12: $i > $i).
% 28.89/28.92  tff(decl_4953, type, fn_dehydrogenase_35: $i > $i).
% 28.89/28.92  tff(decl_4954, type, fn_dehydrogenase_36: $i > $i).
% 28.89/28.92  tff(decl_4955, type, fn_dehydrogenase_32: $i > $i).
% 28.89/28.92  tff(decl_4956, type, fn_dehydrogenase_37: $i > $i).
% 28.89/28.92  tff(decl_4957, type, fn_dehydrogenase_34: $i > $i).
% 28.89/28.92  tff(decl_4958, type, fn_dehydrogenase_13: $i > $i).
% 28.89/28.92  tff(decl_4959, type, fn_dehydrogenase_9: $i > $i).
% 28.89/28.92  tff(decl_4960, type, fn_dehydrogenase_17: $i > $i).
% 28.89/28.92  tff(decl_4961, type, fn_dehydrogenase_30: $i > $i).
% 28.89/28.92  tff(decl_4962, type, fn_dehydrogenase_29: $i > $i).
% 28.89/28.92  tff(decl_4963, type, alcohol_fermentation_1: $i > $o).
% 28.89/28.92  tff(decl_4964, type, 'Alcohol-Fermentation': $i).
% 28.89/28.92  tff(decl_4965, type, 'Glycolysis followed by the reduction of pyruvate to ethyl alcohol, regenerating NAD+ and releasing carbon dioxide.': $i).
% 28.89/28.92  tff(decl_4966, type, 'ethanol fermentation': $i).
% 28.89/28.92  tff(decl_4967, type, 'alcoholic fermentation': $i).
% 28.89/28.92  tff(decl_4968, type, ferment: $i).
% 28.89/28.92  tff(decl_4969, type, 'fermentation of alcohol': $i).
% 28.89/28.92  tff(decl_4970, type, 'alcohol fermentation': $i).
% 28.89/28.92  tff(decl_4971, type, 'alcohol-fermentation': $i).
% 28.89/28.92  tff(decl_4972, type, fermentation_1: $i > $o).
% 28.89/28.92  tff(decl_4973, type, lactic_acid_fermentation_1: $i > $o).
% 28.89/28.92  tff(decl_4974, type, fn_alcohol_fermentation_1: $i > $i).
% 28.89/28.92  tff(decl_4975, type, fn_alcohol_fermentation_2: $i > $i).
% 28.89/28.92  tff(decl_4976, type, nucleoside_monophosphate_1: $i > $o).
% 28.89/28.92  tff(decl_4977, type, fn_alcohol_fermentation_3: $i > $i).
% 28.89/28.92  tff(decl_4978, type, fn_alcohol_fermentation_4: $i > $i).
% 28.89/28.92  tff(decl_4979, type, fn_alcohol_fermentation_5: $i > $i).
% 28.89/28.92  tff(decl_4980, type, fn_alcohol_fermentation_6: $i > $i).
% 28.89/28.92  tff(decl_4981, type, condensation_reaction_1: $i > $o).
% 28.89/28.92  tff(decl_4982, type, dehydration_reaction_1: $i > $o).
% 28.89/28.92  tff(decl_4983, type, fn_alcohol_fermentation_7: $i > $i).
% 28.89/28.92  tff(decl_4984, type, fn_alcohol_fermentation_8: $i > $i).
% 28.89/28.92  tff(decl_4985, type, fn_alcohol_fermentation_9: $i > $i).
% 28.89/28.92  tff(decl_4986, type, fn_alcohol_fermentation_14: $i > $i).
% 28.89/28.92  tff(decl_4987, type, fn_alcohol_fermentation_15: $i > $i).
% 28.89/28.92  tff(decl_4988, type, fn_alcohol_fermentation_16: $i > $i).
% 28.89/28.92  tff(decl_4989, type, fn_alcohol_fermentation_17: $i > $i).
% 28.89/28.92  tff(decl_4990, type, fn_alcohol_fermentation_18: $i > $i).
% 28.89/28.92  tff(decl_4991, type, fn_alcohol_fermentation_19: $i > $i).
% 28.89/28.92  tff(decl_4992, type, fn_alcohol_fermentation_20: $i > $i).
% 28.89/28.92  tff(decl_4993, type, fn_alcohol_fermentation_21: $i > $i).
% 28.89/28.92  tff(decl_4994, type, three_phosphoglycerate_1: $i > $o).
% 28.89/28.92  tff(decl_4995, type, fn_alcohol_fermentation_22: $i > $i).
% 28.89/28.92  tff(decl_4996, type, fn_alcohol_fermentation_23: $i > $i).
% 28.89/28.92  tff(decl_4997, type, fn_alcohol_fermentation_24: $i > $i).
% 28.89/28.92  tff(decl_4998, type, fn_alcohol_fermentation_25: $i > $i).
% 28.89/28.92  tff(decl_4999, type, fn_alcohol_fermentation_28: $i > $i).
% 28.89/28.92  tff(decl_5000, type, fn_alcohol_fermentation_29: $i > $i).
% 28.89/28.92  tff(decl_5001, type, fn_alcohol_fermentation_30: $i > $i).
% 28.89/28.92  tff(decl_5002, type, fn_alcohol_fermentation_31: $i > $i).
% 28.89/28.92  tff(decl_5003, type, fn_alcohol_fermentation_32: $i > $i).
% 28.89/28.92  tff(decl_5004, type, fn_alcohol_fermentation_33: $i > $i).
% 28.89/28.92  tff(decl_5005, type, fn_alcohol_fermentation_34: $i > $i).
% 28.89/28.92  tff(decl_5006, type, fn_alcohol_fermentation_35: $i > $i).
% 28.89/28.92  tff(decl_5007, type, fn_alcohol_fermentation_36: $i > $i).
% 28.89/28.92  tff(decl_5008, type, vitamin_b3_1: $i > $o).
% 28.89/28.92  tff(decl_5009, type, fn_alcohol_fermentation_37: $i > $i).
% 28.89/28.92  tff(decl_5010, type, enzymatic_reaction_1: $i > $o).
% 28.89/28.92  tff(decl_5011, type, fn_alcohol_fermentation_38: $i > $i).
% 28.89/28.92  tff(decl_5012, type, isomerization_reaction_1: $i > $o).
% 28.89/28.92  tff(decl_5013, type, fn_alcohol_fermentation_39: $i > $i).
% 28.89/28.92  tff(decl_5014, type, substrate_level_phosphorylation_1: $i > $o).
% 28.89/28.92  tff(decl_5015, type, fn_alcohol_fermentation_40: $i > $i).
% 28.89/28.92  tff(decl_5016, type, fn_alcohol_fermentation_41: $i > $i).
% 28.89/28.92  tff(decl_5017, type, fn_alcohol_fermentation_42: $i > $i).
% 28.89/28.92  tff(decl_5018, type, waste_product_1: $i > $o).
% 28.89/28.92  tff(decl_5019, type, fn_alcohol_fermentation_43: $i > $i).
% 28.89/28.92  tff(decl_5020, type, fn_alcohol_fermentation_44: $i > $i).
% 28.89/28.92  tff(decl_5021, type, fn_alcohol_fermentation_45: $i > $i).
% 28.89/28.92  tff(decl_5022, type, decarboxylation_1: $i > $o).
% 28.89/28.92  tff(decl_5023, type, fn_alcohol_fermentation_46: $i > $i).
% 28.89/28.92  tff(decl_5024, type, glycolysis_1: $i > $o).
% 28.89/28.92  tff(decl_5025, type, fn_alcohol_fermentation_47: $i > $i).
% 28.89/28.92  tff(decl_5026, type, ethyl_alcohol_1: $i > $o).
% 28.89/28.92  tff(decl_5027, type, fn_alcohol_fermentation_48: $i > $i).
% 28.89/28.92  tff(decl_5028, type, fn_alcohol_fermentation_49: $i > $i).
% 28.89/28.92  tff(decl_5029, type, fn_alcohol_fermentation_50: $i > $i).
% 28.89/28.92  tff(decl_5030, type, waste_1: $i > $o).
% 28.89/28.92  tff(decl_5031, type, fn_alcohol_fermentation_51: $i > $i).
% 28.89/28.92  tff(decl_5032, type, fn_alcohol_fermentation_52: $i > $i).
% 28.89/28.92  tff(decl_5033, type, fn_alcohol_fermentation_53: $i > $i).
% 28.89/28.92  tff(decl_5034, type, monosaccharide_1: $i > $o).
% 28.89/28.92  tff(decl_5035, type, glucose_1: $i > $o).
% 28.89/28.92  tff(decl_5036, type, fn_alcohol_fermentation_55: $i > $i).
% 28.89/28.92  tff(decl_5037, type, fn_alcohol_fermentation_56: $i > $i).
% 28.89/28.92  tff(decl_5038, type, fn_alcohol_fermentation_57: $i > $i).
% 28.89/28.92  tff(decl_5039, type, fn_alcohol_fermentation_58: $i > $i).
% 28.89/28.92  tff(decl_5040, type, fn_alcohol_fermentation_59: $i > $i).
% 28.89/28.92  tff(decl_5041, type, fn_alcohol_fermentation_60: $i > $i).
% 28.89/28.92  tff(decl_5042, type, fn_alcohol_fermentation_61: $i > $i).
% 28.89/28.92  tff(decl_5043, type, fn_alcohol_fermentation_62: $i > $i).
% 28.89/28.92  tff(decl_5044, type, fn_alcohol_fermentation_63: $i > $i).
% 28.89/28.92  tff(decl_5045, type, fn_alcohol_fermentation_64: $i > $i).
% 28.89/28.92  tff(decl_5046, type, fn_alcohol_fermentation_65: $i > $i).
% 28.89/28.92  tff(decl_5047, type, energy_investment_phase_of_glycolysis_1: $i > $o).
% 28.89/28.92  tff(decl_5048, type, fn_alcohol_fermentation_69: $i > $i).
% 28.89/28.92  tff(decl_5049, type, fn_glycolysis_90: $i > $i).
% 28.89/28.92  tff(decl_5050, type, fn_glycolysis_84: $i > $i).
% 28.89/28.92  tff(decl_5051, type, fn_glycolysis_83: $i > $i).
% 28.89/28.92  tff(decl_5052, type, fn_glycolysis_89: $i > $i).
% 28.89/28.92  tff(decl_5053, type, fn_glycolysis_56: $i > $i).
% 28.89/28.92  tff(decl_5054, type, fn_glycolysis_28: $i > $i).
% 28.89/28.92  tff(decl_5055, type, fn_glycolysis_66: $i > $i).
% 28.89/28.92  tff(decl_5056, type, fn_glycolysis_67: $i > $i).
% 28.89/28.92  tff(decl_5057, type, fn_glycolysis_79: $i > $i).
% 28.89/28.92  tff(decl_5058, type, fn_catabolic_pathway_5: $i > $i).
% 28.89/28.92  tff(decl_5059, type, fn_redox_reaction_15: $i > $i).
% 28.89/28.92  tff(decl_5060, type, fn_redox_reaction_3: $i > $i).
% 28.89/28.92  tff(decl_5061, type, fn_redox_reaction_14: $i > $i).
% 28.89/28.92  tff(decl_5062, type, fn_redox_reaction_1: $i > $i).
% 28.89/28.92  tff(decl_5063, type, fn_redox_reaction_11: $i > $i).
% 28.89/28.92  tff(decl_5064, type, fn_nad_plus_6: $i > $i).
% 28.89/28.92  tff(decl_5065, type, fn_nad_plus_5: $i > $i).
% 28.89/28.92  tff(decl_5066, type, fn_nad_plus_7: $i > $i).
% 28.89/28.92  tff(decl_5067, type, fn_nad_plus_17: $i > $i).
% 28.89/28.92  tff(decl_5068, type, fn_nad_plus_16: $i > $i).
% 28.89/28.92  tff(decl_5069, type, fn_nad_plus_14: $i > $i).
% 28.89/28.92  tff(decl_5070, type, fn_nad_plus_4: $i > $i).
% 28.89/28.92  tff(decl_5071, type, fn_nad_plus_9: $i > $i).
% 28.89/28.92  tff(decl_5072, type, fn_nad_plus_3: $i > $i).
% 28.89/28.92  tff(decl_5073, type, fn_nad_plus_8: $i > $i).
% 28.89/28.92  tff(decl_5074, type, fn_waste_1: $i > $i).
% 28.89/28.92  tff(decl_5075, type, fn_decarboxylation_1: $i > $i).
% 28.89/28.92  tff(decl_5076, type, fn_glycolysis_108: $i > $i).
% 28.89/28.92  tff(decl_5077, type, fn_decomposition_reaction_5: $i > $i).
% 28.89/28.92  tff(decl_5078, type, fn_catabolic_pathway_9: $i > $i).
% 28.89/28.92  tff(decl_5079, type, fn_glycolysis_55: $i > $i).
% 28.89/28.92  tff(decl_5080, type, fn_glycolysis_88: $i > $i).
% 28.89/28.92  tff(decl_5081, type, fn_glycolysis_15: $i > $i).
% 28.89/28.92  tff(decl_5082, type, fn_glycolysis_77: $i > $i).
% 28.89/28.92  tff(decl_5083, type, fn_glycolysis_73: $i > $i).
% 28.89/28.92  tff(decl_5084, type, fn_synthesis_of_atp_26: $i > $i).
% 28.89/28.92  tff(decl_5085, type, fn_catabolic_pathway_1: $i > $i).
% 28.89/28.92  tff(decl_5086, type, fn_synthesis_of_atp_23: $i > $i).
% 28.89/28.92  tff(decl_5087, type, fn_glycolysis_80: $i > $i).
% 28.89/28.92  tff(decl_5088, type, fn_catabolic_pathway_2: $i > $i).
% 28.89/28.92  tff(decl_5089, type, fn_synthesis_of_atp_22: $i > $i).
% 28.89/28.92  tff(decl_5090, type, fn_glycolysis_81: $i > $i).
% 28.89/28.92  tff(decl_5091, type, fn_catabolic_pathway_4: $i > $i).
% 28.89/28.92  tff(decl_5092, type, fn_oxidation_1: $i > $i).
% 28.89/28.92  tff(decl_5093, type, fn_synthesis_of_atp_13: $i > $i).
% 28.89/28.92  tff(decl_5094, type, fn_glycolysis_75: $i > $i).
% 28.89/28.92  tff(decl_5095, type, fn_catabolic_pathway_10: $i > $i).
% 28.89/28.92  tff(decl_5096, type, fn_isomerization_reaction_2: $i > $i).
% 28.89/28.92  tff(decl_5097, type, fn_synthesis_of_organic_molecule_1: $i > $i).
% 28.89/28.92  tff(decl_5098, type, fn_glycolysis_69: $i > $i).
% 28.89/28.92  tff(decl_5099, type, fn_glycolysis_16: $i > $i).
% 28.89/28.92  tff(decl_5100, type, fn_glycolysis_68: $i > $i).
% 28.89/28.92  tff(decl_5101, type, fn_redox_reaction_13: $i > $i).
% 28.89/28.92  tff(decl_5102, type, fn_redox_reaction_2: $i > $i).
% 28.89/28.92  tff(decl_5103, type, fn_redox_reaction_10: $i > $i).
% 28.89/28.92  tff(decl_5104, type, fn_glycolysis_78: $i > $i).
% 28.89/28.92  tff(decl_5105, type, fn_isomerization_reaction_1: $i > $i).
% 28.89/28.92  tff(decl_5106, type, fn_glycolysis_74: $i > $i).
% 28.89/28.92  tff(decl_5107, type, fn_nad_plus_1: $i > $i).
% 28.89/28.92  tff(decl_5108, type, fn_glycolysis_27: $i > $i).
% 28.89/28.92  tff(decl_5109, type, fn_nad_plus_20: $i > $i).
% 28.89/28.92  tff(decl_5110, type, chemical_entity_0: $i).
% 28.89/28.92  tff(decl_5111, type, fn_alcohol_fermentation_26: $i > $i).
% 28.89/28.92  tff(decl_5112, type, fn_fermentation_6: $i > $i).
% 28.89/28.92  tff(decl_5113, type, fn_fermentation_49: $i > $i).
% 28.89/28.92  tff(decl_5114, type, fn_fermentation_58: $i > $i).
% 28.89/28.92  tff(decl_5115, type, fn_fermentation_31: $i > $i).
% 28.89/28.92  tff(decl_5116, type, fn_fermentation_47: $i > $i).
% 28.89/28.92  tff(decl_5117, type, fn_fermentation_4: $i > $i).
% 28.89/28.92  tff(decl_5118, type, fn_fermentation_24: $i > $i).
% 28.89/28.92  tff(decl_5119, type, fn_alcohol_fermentation_27: $i > $i).
% 28.89/28.92  tff(decl_5120, type, fn_fermentation_5: $i > $i).
% 28.89/28.92  tff(decl_5121, type, fn_fermentation_3: $i > $i).
% 28.89/28.92  tff(decl_5122, type, fn_fermentation_2: $i > $i).
% 28.89/28.92  tff(decl_5123, type, fn_fermentation_32: $i > $i).
% 28.89/28.92  tff(decl_5124, type, fn_fermentation_38: $i > $i).
% 28.89/28.92  tff(decl_5125, type, fn_fermentation_17: $i > $i).
% 28.89/28.92  tff(decl_5126, type, fn_fermentation_30: $i > $i).
% 28.89/28.92  tff(decl_5127, type, fn_fermentation_33: $i > $i).
% 28.89/28.92  tff(decl_5128, type, fn_alcohol_fermentation_10: $i > $i).
% 28.89/28.92  tff(decl_5129, type, fn_alcohol_fermentation_11: $i > $i).
% 28.89/28.92  tff(decl_5130, type, fn_alcohol_fermentation_54: $i > $i).
% 28.89/28.92  tff(decl_5131, type, fn_alcohol_fermentation_66: $i > $i).
% 28.89/28.92  tff(decl_5132, type, fn_alcohol_fermentation_12: $i > $i).
% 28.89/28.92  tff(decl_5133, type, fn_alcohol_fermentation_13: $i > $i).
% 28.89/28.92  tff(decl_5134, type, fn_alcohol_fermentation_68: $i > $i).
% 28.89/28.92  tff(decl_5135, type, fn_alcohol_fermentation_67: $i > $i).
% 28.89/28.92  tff(decl_5136, type, alcohol_fermentation_by_bacteria_1: $i > $o).
% 28.89/28.92  tff(decl_5137, type, 'Alcohol-Fermentation-By-Bacteria': $i).
% 28.89/28.92  tff(decl_5138, type, 'In bacteria, glycolysis  followed by the reduction of pyruvate to ethyl alcohol, regenerating NAD+ and releasing carbon dioxide.': $i).
% 28.89/28.92  tff(decl_5139, type, 'alcohol fermentation by bacterium': $i).
% 28.89/28.92  tff(decl_5140, type, 'alcohol-fermentation-by-bacteria': $i).
% 28.89/28.92  tff(decl_5141, type, alcohol_fermentation_by_yeast_1: $i > $o).
% 28.89/28.92  tff(decl_5142, type, 'Alcohol-Fermentation-By-Yeast': $i).
% 28.89/28.92  tff(decl_5143, type, 'Alcohol fermentation by yeast, is a biological process in which sugars such as glucose, fructose, and sucrose are converted into cellular energy and thereby produce ethanol and carbon dioxide as metabolic waste products. Yeasts perform this process in the absence of oxygen, ethanol fermentation is classified as anaerobic. Ethanol fermentation occurs in the production of alcoholic beverages and ethanol fuel, and in the rising of bread dough.': $i).
% 28.89/28.92  tff(decl_5144, type, 'alcohol fermentation by yeast': $i).
% 28.89/28.92  tff(decl_5145, type, 'alcohol-fermentation-by-yeast': $i).
% 28.89/28.92  tff(decl_5146, type, fn_alcohol_fermentation_by_yeast_1: $i > $i).
% 28.89/28.92  tff(decl_5147, type, fn_alcohol_fermentation_by_yeast_2: $i > $i).
% 28.89/28.92  tff(decl_5148, type, fn_alcohol_fermentation_by_yeast_3: $i > $i).
% 28.89/28.92  tff(decl_5149, type, fn_alcohol_fermentation_by_yeast_4: $i > $i).
% 28.89/28.92  tff(decl_5150, type, fn_alcohol_fermentation_by_yeast_5: $i > $i).
% 28.89/28.92  tff(decl_5151, type, fn_alcohol_fermentation_by_yeast_6: $i > $i).
% 28.89/28.92  tff(decl_5152, type, fn_alcohol_fermentation_by_yeast_7: $i > $i).
% 28.89/28.92  tff(decl_5153, type, fn_alcohol_fermentation_by_yeast_8: $i > $i).
% 28.89/28.92  tff(decl_5154, type, fn_alcohol_fermentation_by_yeast_9: $i > $i).
% 28.89/28.92  tff(decl_5155, type, fn_alcohol_fermentation_by_yeast_10: $i > $i).
% 28.89/28.92  tff(decl_5156, type, fn_alcohol_fermentation_by_yeast_11: $i > $i).
% 28.89/28.92  tff(decl_5157, type, fn_alcohol_fermentation_by_yeast_12: $i > $i).
% 28.89/28.92  tff(decl_5158, type, fn_alcohol_fermentation_by_yeast_13: $i > $i).
% 28.89/28.92  tff(decl_5159, type, fn_alcohol_fermentation_by_yeast_14: $i > $i).
% 28.89/28.92  tff(decl_5160, type, yeast_1: $i > $o).
% 28.89/28.92  tff(decl_5161, type, fn_alcohol_fermentation_by_yeast_15: $i > $i).
% 28.89/28.92  tff(decl_5162, type, fn_alcohol_fermentation_by_yeast_16: $i > $i).
% 28.89/28.92  tff(decl_5163, type, fn_alcohol_fermentation_by_yeast_17: $i > $i).
% 28.89/28.92  tff(decl_5164, type, fn_alcohol_fermentation_by_yeast_18: $i > $i).
% 28.89/28.92  tff(decl_5165, type, fn_alcohol_fermentation_by_yeast_19: $i > $i).
% 28.89/28.92  tff(decl_5166, type, fn_alcohol_fermentation_by_yeast_20: $i > $i).
% 28.89/28.92  tff(decl_5167, type, fn_alcohol_fermentation_by_yeast_21: $i > $i).
% 28.89/28.92  tff(decl_5168, type, fn_alcohol_fermentation_by_yeast_22: $i > $i).
% 28.89/28.92  tff(decl_5169, type, fn_alcohol_fermentation_by_yeast_23: $i > $i).
% 28.89/28.92  tff(decl_5170, type, fn_alcohol_fermentation_by_yeast_24: $i > $i).
% 28.89/28.92  tff(decl_5171, type, fn_alcohol_fermentation_by_yeast_25: $i > $i).
% 28.89/28.92  tff(decl_5172, type, fn_alcohol_fermentation_by_yeast_26: $i > $i).
% 28.89/28.92  tff(decl_5173, type, fn_alcohol_fermentation_by_yeast_27: $i > $i).
% 28.89/28.92  tff(decl_5174, type, fn_alcohol_fermentation_by_yeast_28: $i > $i).
% 28.89/28.92  tff(decl_5175, type, fn_alcohol_fermentation_by_yeast_29: $i > $i).
% 28.89/28.92  tff(decl_5176, type, fn_alcohol_fermentation_by_yeast_30: $i > $i).
% 28.89/28.92  tff(decl_5177, type, fn_alcohol_fermentation_by_yeast_31: $i > $i).
% 28.89/28.92  tff(decl_5178, type, fn_alcohol_fermentation_by_yeast_32: $i > $i).
% 28.89/28.92  tff(decl_5179, type, fn_alcohol_fermentation_by_yeast_33: $i > $i).
% 28.89/28.92  tff(decl_5180, type, fn_alcohol_fermentation_by_yeast_34: $i > $i).
% 28.89/28.92  tff(decl_5181, type, fn_alcohol_fermentation_by_yeast_35: $i > $i).
% 28.89/28.92  tff(decl_5182, type, fn_alcohol_fermentation_by_yeast_36: $i > $i).
% 28.89/28.92  tff(decl_5183, type, fn_glycolysis_8: $i > $i).
% 28.89/28.92  tff(decl_5184, type, fn_glycolysis_91: $i > $i).
% 28.89/28.92  tff(decl_5185, type, fn_glycolysis_53: $i > $i).
% 28.89/28.92  tff(decl_5186, type, fn_glycolysis_65: $i > $i).
% 28.89/28.92  tff(decl_5187, type, fn_glycolysis_82: $i > $i).
% 28.89/28.92  tff(decl_5188, type, fn_glycolysis_35: $i > $i).
% 28.89/28.92  tff(decl_5189, type, fn_glycolysis_70: $i > $i).
% 28.89/28.92  tff(decl_5190, type, fn_substrate_level_phosphorylation_5: $i > $i).
% 28.89/28.92  tff(decl_5191, type, fn_glycolysis_63: $i > $i).
% 28.89/28.92  tff(decl_5192, type, fn_glycolysis_13: $i > $i).
% 28.89/28.92  tff(decl_5193, type, fn_glycolysis_62: $i > $i).
% 28.89/28.92  tff(decl_5194, type, fn_metabolic_pathway_1: $i > $i).
% 28.89/28.92  tff(decl_5195, type, fn_catabolic_pathway_6: $i > $i).
% 28.89/28.92  tff(decl_5196, type, fn_catabolic_pathway_7: $i > $i).
% 28.89/28.92  tff(decl_5197, type, fn_catabolic_pathway_11: $i > $i).
% 28.89/28.92  tff(decl_5198, type, fn_alcohol_fermentation_by_yeast_37: $i > $i).
% 28.89/28.92  tff(decl_5199, type, alcohol_hormone_1: $i > $o).
% 28.89/28.92  tff(decl_5200, type, 'Alcohol-Hormone': $i).
% 28.89/28.92  tff(decl_5201, type, 'A hormone with one or more hydroxyl groups bound to carbon atoms.': $i).
% 28.89/28.92  tff(decl_5202, type, 'hormone of alcohol': $i).
% 28.89/28.92  tff(decl_5203, type, 'alcohol hormone': $i).
% 28.89/28.92  tff(decl_5204, type, 'alcohol-hormone': $i).
% 28.89/28.92  tff(decl_5205, type, alcoholic_beverage_1: $i > $o).
% 28.89/28.92  tff(decl_5206, type, glycerol_1: $i > $o).
% 28.89/28.92  tff(decl_5207, type, 'Alcoholic-Beverage': $i).
% 28.89/28.92  tff(decl_5208, type, 'An alcoholic beverage is a drink containing ethanol (commonly called alcohol). Alcoholic beverages are divided into three general classes: beers, wines, and spirits.': $i).
% 28.89/28.92  tff(decl_5209, type, 'beverage of alcoholic': $i).
% 28.89/28.92  tff(decl_5210, type, 'alcoholic beverage': $i).
% 28.89/28.92  tff(decl_5211, type, 'alcoholic-beverage': $i).
% 28.89/28.92  tff(decl_5212, type, fn_alcoholic_beverage_1: $i > $i).
% 28.89/28.92  tff(decl_5213, type, 'Aldehyde': $i).
% 28.89/28.92  tff(decl_5214, type, 'An aldehyde is an organic compound containing a formyl group.': $i).
% 28.89/28.92  tff(decl_5215, type, aldehyde: $i).
% 28.89/28.92  tff(decl_5216, type, fn_aldehyde_3: $i > $i).
% 28.89/28.92  tff(decl_5217, type, fn_aldehyde_4: $i > $i).
% 28.89/28.92  tff(decl_5218, type, fn_aldehyde_7: $i > $i).
% 28.89/28.92  tff(decl_5219, type, fn_aldehyde_8: $i > $i).
% 28.89/28.92  tff(decl_5220, type, fn_aldehyde_9: $i > $i).
% 28.89/28.92  tff(decl_5221, type, fn_aldehyde_10: $i > $i).
% 28.89/28.92  tff(decl_5222, type, fn_aldehyde_1: $i > $i).
% 28.89/28.92  tff(decl_5223, type, fn_aldehyde_2: $i > $i).
% 28.89/28.92  tff(decl_5224, type, aldolase_1: $i > $o).
% 28.89/28.92  tff(decl_5225, type, 'Aldolase': $i).
% 28.89/28.92  tff(decl_5226, type, 'An aldolase is an enzyme that cleaves an aldol.': $i).
% 28.89/28.92  tff(decl_5227, type, aldolase: $i).
% 28.89/28.92  tff(decl_5228, type, fn_aldolase_1: $i > $i).
% 28.89/28.92  tff(decl_5229, type, disulfide_bond_1: $i > $o).
% 28.89/28.92  tff(decl_5230, type, fn_aldolase_2: $i > $i).
% 28.89/28.92  tff(decl_5231, type, catalyst_1: $i > $o).
% 28.89/28.92  tff(decl_5232, type, fn_aldolase_3: $i > $i).
% 28.89/28.92  tff(decl_5233, type, fn_aldolase_4: $i > $i).
% 28.89/28.92  tff(decl_5234, type, fn_aldolase_5: $i > $i).
% 28.89/28.92  tff(decl_5235, type, fn_aldolase_6: $i > $i).
% 28.89/28.92  tff(decl_5236, type, fn_aldolase_7: $i > $i).
% 28.89/28.92  tff(decl_5237, type, fn_aldolase_8: $i > $i).
% 28.89/28.92  tff(decl_5238, type, fn_aldolase_9: $i > $i).
% 28.89/28.92  tff(decl_5239, type, fn_aldolase_10: $i > $i).
% 28.89/28.92  tff(decl_5240, type, fn_aldolase_11: $i > $i).
% 28.89/28.92  tff(decl_5241, type, fn_aldolase_12: $i > $i).
% 28.89/28.92  tff(decl_5242, type, fn_aldolase_13: $i > $i).
% 28.89/28.92  tff(decl_5243, type, fn_aldolase_14: $i > $i).
% 28.89/28.92  tff(decl_5244, type, fn_aldolase_15: $i > $i).
% 28.89/28.92  tff(decl_5245, type, fn_aldolase_16: $i > $i).
% 28.89/28.92  tff(decl_5246, type, fn_aldolase_17: $i > $i).
% 28.89/28.92  tff(decl_5247, type, fn_aldolase_18: $i > $i).
% 28.89/28.92  tff(decl_5248, type, fn_aldolase_19: $i > $i).
% 28.89/28.92  tff(decl_5249, type, fn_aldolase_20: $i > $i).
% 28.89/28.92  tff(decl_5250, type, fn_disulfide_bond_3: $i > $i).
% 28.89/28.92  tff(decl_5251, type, fn_enzyme_5: $i > $i).
% 28.89/28.92  tff(decl_5252, type, fn_enzyme_6: $i > $i).
% 28.89/28.92  tff(decl_5253, type, fn_protein_5: $i > $i).
% 28.89/28.92  tff(decl_5254, type, fn_protein_1: $i > $i).
% 28.89/28.92  tff(decl_5255, type, fn_protein_enzyme_9: $i > $i).
% 28.89/28.92  tff(decl_5256, type, fn_protein_enzyme_4: $i > $i).
% 28.89/28.92  tff(decl_5257, type, fn_protein_enzyme_3: $i > $i).
% 28.89/28.92  tff(decl_5258, type, fn_protein_enzyme_8: $i > $i).
% 28.89/28.92  tff(decl_5259, type, fn_protein_enzyme_7: $i > $i).
% 28.89/28.92  tff(decl_5260, type, fn_protein_enzyme_6: $i > $i).
% 28.89/28.92  tff(decl_5261, type, 'Aldose': $i).
% 28.89/28.92  tff(decl_5262, type, 'An aldose is a monosaccharide (a simple sugar) containing one aldehyde group per molecule and having a chemical formula of the form Cn(H2O)n.': $i).
% 28.89/28.92  tff(decl_5263, type, 'aldose sugar': $i).
% 28.89/28.92  tff(decl_5264, type, 'aldose-sugar': $i).
% 28.89/28.92  tff(decl_5265, type, aldose: $i).
% 28.89/28.92  tff(decl_5266, type, disaccharide_1: $i > $o).
% 28.89/28.92  tff(decl_5267, type, nucleic_acid_1: $i > $o).
% 28.89/28.92  tff(decl_5268, type, oligosaccharide_1: $i > $o).
% 28.89/28.92  tff(decl_5269, type, polysaccharide_1: $i > $o).
% 28.89/28.92  tff(decl_5270, type, proteasome_1: $i > $o).
% 28.89/28.92  tff(decl_5271, type, protein_dimer_1: $i > $o).
% 28.89/28.92  tff(decl_5272, type, sporopollenin_1: $i > $o).
% 28.89/28.92  tff(decl_5273, type, sister_chromatid_1: $i > $o).
% 28.89/28.92  tff(decl_5274, type, fn_aldose_1: $i > $i).
% 28.89/28.92  tff(decl_5275, type, fn_aldose_2: $i > $i).
% 28.89/28.92  tff(decl_5276, type, fn_aldose_3: $i > $i).
% 28.89/28.92  tff(decl_5277, type, fn_aldose_4: $i > $i).
% 28.89/28.92  tff(decl_5278, type, fn_aldose_5: $i > $i).
% 28.89/28.92  tff(decl_5279, type, fn_aldose_6: $i > $i).
% 28.89/28.92  tff(decl_5280, type, fn_aldose_7: $i > $i).
% 28.89/28.92  tff(decl_5281, type, fn_aldose_8: $i > $i).
% 28.89/28.92  tff(decl_5282, type, fn_aldose_9: $i > $i).
% 28.89/28.92  tff(decl_5283, type, fn_aldose_10: $i > $i).
% 28.89/28.92  tff(decl_5284, type, fn_carbonyl_group_8: $i > $i).
% 28.89/28.92  tff(decl_5285, type, fn_carbonyl_group_7: $i > $i).
% 28.89/28.92  tff(decl_5286, type, fn_carbonyl_group_9: $i > $i).
% 28.89/28.92  tff(decl_5287, type, fn_monosaccharide_16: $i > $i).
% 28.89/28.92  tff(decl_5288, type, fn_carbohydrate_34: $i > $i).
% 28.89/28.92  tff(decl_5289, type, fn_monosaccharide_17: $i > $i).
% 28.89/28.92  tff(decl_5290, type, fn_monosaccharide_12: $i > $i).
% 28.89/28.92  tff(decl_5291, type, fn_monosaccharide_10: $i > $i).
% 28.89/28.92  tff(decl_5292, type, fn_monosaccharide_13: $i > $i).
% 28.89/28.92  tff(decl_5293, type, fn_carbohydrate_38: $i > $i).
% 28.89/28.92  tff(decl_5294, type, fn_monosaccharide_18: $i > $i).
% 28.89/28.92  tff(decl_5295, type, fn_monosaccharide_9: $i > $i).
% 28.89/28.92  tff(decl_5296, type, fn_monosaccharide_5: $i > $i).
% 28.89/28.92  tff(decl_5297, type, fn_monosaccharide_6: $i > $i).
% 28.89/28.92  tff(decl_5298, type, fn_carbohydrate_39: $i > $i).
% 28.89/28.92  tff(decl_5299, type, fn_carbohydrate_32: $i > $i).
% 28.89/28.92  tff(decl_5300, type, fn_carbohydrate_33: $i > $i).
% 28.89/28.92  tff(decl_5301, type, aldosterone_1: $i > $o).
% 28.89/28.92  tff(decl_5302, type, 'Aldosterone': $i).
% 28.89/28.92  tff(decl_5303, type, 'A steroid hormone secreted by the adrenal cortex that acts to increase reabsorption of water and ions, particularly Na+ and K+, by the kidney.': $i).
% 28.89/28.92  tff(decl_5304, type, aldosterone: $i).
% 28.89/28.92  tff(decl_5305, type, steroid_hormone_1: $i > $o).
% 28.89/28.92  tff(decl_5306, type, brassinosteroid_1: $i > $o).
% 28.89/28.92  tff(decl_5307, type, corticosteroid_1: $i > $o).
% 28.89/28.92  tff(decl_5308, type, ecdysone_1: $i > $o).
% 28.89/28.92  tff(decl_5309, type, estradiol_1: $i > $o).
% 28.89/28.92  tff(decl_5310, type, progesterone_1: $i > $o).
% 28.89/28.92  tff(decl_5311, type, testosterone_1: $i > $o).
% 28.89/28.92  tff(decl_5312, type, 'Algae': $i).
% 28.89/28.92  tff(decl_5313, type, 'Algae are a large and diverse group of simple, typically autotrophic organisms, ranging from unicellular to multicellular forms.': $i).
% 28.89/28.92  tff(decl_5314, type, alga: $i).
% 28.89/28.92  tff(decl_5315, type, algae: $i).
% 28.89/28.92  tff(decl_5316, type, streptophyta_1: $i > $o).
% 28.89/28.92  tff(decl_5317, type, fn_algae_1: $i > $i).
% 28.89/28.92  tff(decl_5318, type, autotroph_1: $i > $o).
% 28.89/28.92  tff(decl_5319, type, fn_algae_2: $i > $i).
% 28.89/28.92  tff(decl_5320, type, fn_algae_3: $i > $i).
% 28.89/28.92  tff(decl_5321, type, fn_algae_4: $i > $i).
% 28.89/28.92  tff(decl_5322, type, fn_autotroph_11: $i > $i).
% 28.89/28.92  tff(decl_5323, type, 'Algae-Bloom': $i).
% 28.89/28.92  tff(decl_5324, type, 'Rapid growth of algae in response to sudden increases in limiting nutrients such as nitrogen and phosphorus which are often introduced by sources of human pollution .': $i).
% 28.89/28.92  tff(decl_5325, type, 'red tide': $i).
% 28.89/28.92  tff(decl_5326, type, 'red-tide': $i).
% 28.89/28.92  tff(decl_5327, type, 'algal bloom': $i).
% 28.89/28.92  tff(decl_5328, type, 'algal-bloom': $i).
% 28.89/28.92  tff(decl_5329, type, 'harmful algal bloom': $i).
% 28.89/28.92  tff(decl_5330, type, 'harmful-algal-bloom': $i).
% 28.89/28.92  tff(decl_5331, type, hab: $i).
% 28.89/28.92  tff(decl_5332, type, 'bloom of algae': $i).
% 28.89/28.92  tff(decl_5333, type, 'algae bloom': $i).
% 28.89/28.92  tff(decl_5334, type, 'algae-bloom': $i).
% 28.89/28.92  tff(decl_5335, type, growth_1: $i > $o).
% 28.89/28.92  tff(decl_5336, type, algal_cell_1: $i > $o).
% 28.89/28.92  tff(decl_5337, type, 'Algal-Cell': $i).
% 28.89/28.92  tff(decl_5338, type, 'An algal cell is the basic structural unit of algae.': $i).
% 28.89/28.92  tff(decl_5339, type, 'algal cell': $i).
% 28.89/28.92  tff(decl_5340, type, 'algal-cell': $i).
% 28.89/28.92  tff(decl_5341, type, walled_cell_1: $i > $o).
% 28.89/28.92  tff(decl_5342, type, plant_cell_1: $i > $o).
% 28.89/28.92  tff(decl_5343, type, fn_algal_cell_1: $i > $i).
% 28.89/28.92  tff(decl_5344, type, fn_algal_cell_2: $i > $i).
% 28.89/28.92  tff(decl_5345, type, enter_1: $i > $o).
% 28.89/28.92  tff(decl_5346, type, fn_algal_cell_3: $i > $i).
% 28.89/28.92  tff(decl_5347, type, hydrophilic_face_1: $i > $o).
% 28.89/28.92  tff(decl_5348, type, fn_algal_cell_4: $i > $i).
% 28.89/28.92  tff(decl_5349, type, fn_algal_cell_5: $i > $i).
% 28.89/28.92  tff(decl_5350, type, fn_algal_cell_8: $i > $i).
% 28.89/28.92  tff(decl_5351, type, mitochondrial_dna_1: $i > $o).
% 28.89/28.92  tff(decl_5352, type, fn_algal_cell_9: $i > $i).
% 28.89/28.92  tff(decl_5353, type, fn_algal_cell_10: $i > $i).
% 28.89/28.92  tff(decl_5354, type, fn_algal_cell_11: $i > $i).
% 28.89/28.92  tff(decl_5355, type, fn_algal_cell_12: $i > $i).
% 28.89/28.92  tff(decl_5356, type, fn_algal_cell_13: $i > $i).
% 28.89/28.92  tff(decl_5357, type, fn_algal_cell_14: $i > $i).
% 28.89/28.92  tff(decl_5358, type, fn_algal_cell_15: $i > $i).
% 28.89/28.92  tff(decl_5359, type, fn_algal_cell_16: $i > $i).
% 28.89/28.92  tff(decl_5360, type, facilitated_diffusion_of_polar_molecule_1: $i > $o).
% 28.89/28.92  tff(decl_5361, type, fn_algal_cell_17: $i > $i).
% 28.89/28.92  tff(decl_5362, type, fn_algal_cell_18: $i > $i).
% 28.89/28.92  tff(decl_5363, type, fn_algal_cell_19: $i > $i).
% 28.89/28.92  tff(decl_5364, type, fn_algal_cell_22: $i > $i).
% 28.89/28.92  tff(decl_5365, type, fn_algal_cell_23: $i > $i).
% 28.89/28.92  tff(decl_5366, type, fn_algal_cell_24: $i > $i).
% 28.89/28.92  tff(decl_5367, type, fn_algal_cell_25: $i > $i).
% 28.89/28.92  tff(decl_5368, type, fn_algal_cell_26: $i > $i).
% 28.89/28.92  tff(decl_5369, type, fn_algal_cell_27: $i > $i).
% 28.89/28.92  tff(decl_5370, type, fn_algal_cell_28: $i > $i).
% 28.89/28.92  tff(decl_5371, type, fn_algal_cell_29: $i > $i).
% 28.89/28.92  tff(decl_5372, type, fn_algal_cell_30: $i > $i).
% 28.89/28.92  tff(decl_5373, type, fn_algal_cell_31: $i > $i).
% 28.89/28.92  tff(decl_5374, type, fn_algal_cell_32: $i > $i).
% 28.89/28.92  tff(decl_5375, type, fn_algal_cell_33: $i > $i).
% 28.89/28.92  tff(decl_5376, type, fn_algal_cell_34: $i > $i).
% 28.89/28.92  tff(decl_5377, type, fn_algal_cell_35: $i > $i).
% 28.89/28.92  tff(decl_5378, type, fn_algal_cell_36: $i > $i).
% 28.89/28.92  tff(decl_5379, type, fn_algal_cell_37: $i > $i).
% 28.89/28.92  tff(decl_5380, type, phospholipid_1: $i > $o).
% 28.89/28.92  tff(decl_5381, type, fn_algal_cell_38: $i > $i).
% 28.89/28.92  tff(decl_5382, type, phospholipid_layer_1: $i > $o).
% 28.89/28.92  tff(decl_5383, type, fn_algal_cell_39: $i > $i).
% 28.89/28.92  tff(decl_5384, type, fn_algal_cell_40: $i > $i).
% 28.89/28.92  tff(decl_5385, type, fn_algal_cell_41: $i > $i).
% 28.89/28.92  tff(decl_5386, type, algal_cell_wall_1: $i > $o).
% 28.89/28.92  tff(decl_5387, type, fn_algal_cell_42: $i > $i).
% 28.89/28.92  tff(decl_5388, type, fn_algal_cell_43: $i > $i).
% 28.89/28.92  tff(decl_5389, type, fn_algal_cell_44: $i > $i).
% 28.89/28.92  tff(decl_5390, type, fn_algal_cell_45: $i > $i).
% 28.89/28.92  tff(decl_5391, type, lipid_1: $i > $o).
% 28.89/28.92  tff(decl_5392, type, glycolipid_1: $i > $o).
% 28.89/28.92  tff(decl_5393, type, fn_algal_cell_46: $i > $i).
% 28.89/28.92  tff(decl_5394, type, nuclear_membrane_1: $i > $o).
% 28.89/28.92  tff(decl_5395, type, fn_algal_cell_47: $i > $i).
% 28.89/28.92  tff(decl_5396, type, fn_algal_cell_48: $i > $i).
% 28.89/28.92  tff(decl_5397, type, fn_algal_cell_49: $i > $i).
% 28.89/28.92  tff(decl_5398, type, fn_algal_cell_50: $i > $i).
% 28.89/28.92  tff(decl_5399, type, fn_biomembrane_62: $i > $i).
% 28.89/28.92  tff(decl_5400, type, fn_glycolipid_7: $i > $i).
% 28.89/28.92  tff(decl_5401, type, fn_glycolipid_13: $i > $i).
% 28.89/28.92  tff(decl_5402, type, fn_endoplasmic_reticulum_31: $i > $i).
% 28.89/28.92  tff(decl_5403, type, fn_anabolic_pathway_6: $i > $i).
% 28.89/28.92  tff(decl_5404, type, fn_smooth_endoplasmic_reticulum_46: $i > $i).
% 28.89/28.92  tff(decl_5405, type, fn_smooth_endoplasmic_reticulum_15: $i > $i).
% 28.89/28.92  tff(decl_5406, type, fn_rough_endoplasmic_reticulum_22: $i > $i).
% 28.89/28.92  tff(decl_5407, type, fn_endoplasmic_reticulum_23: $i > $i).
% 28.89/28.92  tff(decl_5408, type, fn_endoplasmic_reticulum_14: $i > $i).
% 28.89/28.92  tff(decl_5409, type, fn_facilitated_diffusion_of_polar_molecule_5: $i > $i).
% 28.89/28.92  tff(decl_5410, type, fn_rough_endoplasmic_reticulum_27: $i > $i).
% 28.89/28.92  tff(decl_5411, type, fn_cell_wall_13: $i > $i).
% 28.89/28.92  tff(decl_5412, type, fn_endoplasmic_reticulum_11: $i > $i).
% 28.89/28.92  tff(decl_5413, type, fn_lipid_14: $i > $i).
% 28.89/28.92  tff(decl_5414, type, fn_glycolipid_4: $i > $i).
% 28.89/28.92  tff(decl_5415, type, fn_biomembrane_71: $i > $i).
% 28.89/28.92  tff(decl_5416, type, fn_rough_endoplasmic_reticulum_30: $i > $i).
% 28.89/28.92  tff(decl_5417, type, fn_smooth_endoplasmic_reticulum_24: $i > $i).
% 28.89/28.92  tff(decl_5418, type, fn_synthesis_of_lipid_2: $i > $i).
% 28.89/28.92  tff(decl_5419, type, fn_biomembrane_29: $i > $i).
% 28.89/28.92  tff(decl_5420, type, fn_smooth_endoplasmic_reticulum_47: $i > $i).
% 28.89/28.92  tff(decl_5421, type, fn_smooth_endoplasmic_reticulum_22: $i > $i).
% 28.89/28.92  tff(decl_5422, type, fn_biomembrane_67: $i > $i).
% 28.89/28.92  tff(decl_5423, type, fn_walled_cell_1: $i > $i).
% 28.89/28.92  tff(decl_5424, type, fn_algal_cell_20: $i > $i).
% 28.89/28.92  tff(decl_5425, type, fn_eukaryotic_cell_60: $i > $i).
% 28.89/28.92  tff(decl_5426, type, fn_algal_cell_21: $i > $i).
% 28.89/28.92  tff(decl_5427, type, fn_eukaryotic_cell_28: $i > $i).
% 28.89/28.92  tff(decl_5428, type, fn_eukaryotic_cell_21: $i > $i).
% 28.89/28.92  tff(decl_5429, type, fn_algal_cell_7: $i > $i).
% 28.89/28.92  tff(decl_5430, type, fn_eukaryotic_cell_7: $i > $i).
% 28.89/28.92  tff(decl_5431, type, fn_algal_cell_6: $i > $i).
% 28.89/28.92  tff(decl_5432, type, fn_eukaryotic_cell_8: $i > $i).
% 28.89/28.92  tff(decl_5433, type, fn_eukaryotic_cell_37: $i > $i).
% 28.89/28.92  tff(decl_5434, type, fn_eukaryotic_cell_16: $i > $i).
% 28.89/28.92  tff(decl_5435, type, fn_eukaryotic_cell_6: $i > $i).
% 28.89/28.92  tff(decl_5436, type, fn_eukaryotic_cell_33: $i > $i).
% 28.89/28.92  tff(decl_5437, type, fn_eukaryotic_cell_5: $i > $i).
% 28.89/28.92  tff(decl_5438, type, fn_eukaryotic_cell_56: $i > $i).
% 28.89/28.92  tff(decl_5439, type, fn_eukaryotic_cell_30: $i > $i).
% 28.89/28.92  tff(decl_5440, type, fn_eukaryotic_cell_23: $i > $i).
% 28.89/28.92  tff(decl_5441, type, fn_eukaryotic_cell_35: $i > $i).
% 28.89/28.92  tff(decl_5442, type, fn_eukaryotic_cell_34: $i > $i).
% 28.89/28.92  tff(decl_5443, type, fn_eukaryotic_cell_36: $i > $i).
% 28.89/28.92  tff(decl_5444, type, fn_eukaryotic_cell_20: $i > $i).
% 28.89/28.92  tff(decl_5445, type, fn_eukaryotic_cell_27: $i > $i).
% 28.89/28.92  tff(decl_5446, type, fn_eukaryotic_cell_59: $i > $i).
% 28.89/28.92  tff(decl_5447, type, fn_eukaryotic_cell_45: $i > $i).
% 28.89/28.92  tff(decl_5448, type, fn_eukaryotic_cell_19: $i > $i).
% 28.89/28.92  tff(decl_5449, type, fn_eukaryotic_cell_44: $i > $i).
% 28.89/28.92  tff(decl_5450, type, fn_eukaryotic_cell_41: $i > $i).
% 28.89/28.92  tff(decl_5451, type, fn_eukaryotic_cell_32: $i > $i).
% 28.89/28.92  tff(decl_5452, type, fn_eukaryotic_cell_50: $i > $i).
% 28.89/28.92  tff(decl_5453, type, fn_eukaryotic_cell_24: $i > $i).
% 28.89/28.92  tff(decl_5454, type, fn_eukaryotic_cell_42: $i > $i).
% 28.89/28.92  tff(decl_5455, type, 'Algal-Cell-Wall': $i).
% 28.89/28.92  tff(decl_5456, type, 'A rigid layer, surrounding the cells algae.  The composition of the cell wall varies depending on the type of algae.': $i).
% 28.89/28.92  tff(decl_5457, type, 'algal cell wall': $i).
% 28.89/28.92  tff(decl_5458, type, 'algal-cell-wall': $i).
% 28.89/28.92  tff(decl_5459, type, cell_wall_1: $i > $o).
% 28.89/28.92  tff(decl_5460, type, alimentary_canal_1: $i > $o).
% 28.89/28.92  tff(decl_5461, type, 'Alimentary-Canal': $i).
% 28.89/28.92  tff(decl_5462, type, 'In animals, a digestive tract consisting of a tube running between a mouth and an anus; also called a complete digestive tract.': $i).
% 28.89/28.92  tff(decl_5463, type, 'complete digestive system': $i).
% 28.89/28.92  tff(decl_5464, type, 'complete-digestive-system': $i).
% 28.89/28.92  tff(decl_5465, type, gut: $i).
% 28.89/28.92  tff(decl_5466, type, 'alimentary canal': $i).
% 28.89/28.92  tff(decl_5467, type, 'alimentary-canal': $i).
% 28.89/28.92  tff(decl_5468, type, digestive_tract_1: $i > $o).
% 28.89/28.92  tff(decl_5469, type, canal_1: $i > $o).
% 28.89/28.92  tff(decl_5470, type, fn_alimentary_canal_1: $i > $i).
% 28.89/28.92  tff(decl_5471, type, sphincter_1: $i > $o).
% 28.89/28.92  tff(decl_5472, type, fn_alimentary_canal_2: $i > $i).
% 28.89/28.92  tff(decl_5473, type, fn_alimentary_canal_3: $i > $i).
% 28.89/28.92  tff(decl_5474, type, fn_alimentary_canal_4: $i > $i).
% 28.89/28.92  tff(decl_5475, type, small_intestine_1: $i > $o).
% 28.89/28.92  tff(decl_5476, type, fn_alimentary_canal_5: $i > $i).
% 28.89/28.92  tff(decl_5477, type, mouth_1: $i > $o).
% 28.89/28.92  tff(decl_5478, type, fn_alimentary_canal_6: $i > $i).
% 28.89/28.92  tff(decl_5479, type, anus_1: $i > $o).
% 28.89/28.92  tff(decl_5480, type, fn_alimentary_canal_7: $i > $i).
% 28.89/28.92  tff(decl_5481, type, fn_alimentary_canal_9: $i > $i).
% 28.89/28.92  tff(decl_5482, type, fn_alimentary_canal_10: $i > $i).
% 28.89/28.92  tff(decl_5483, type, pyloric_sphincter_1: $i > $o).
% 28.89/28.92  tff(decl_5484, type, fn_alimentary_canal_11: $i > $i).
% 28.89/28.92  tff(decl_5485, type, fn_alimentary_canal_12: $i > $i).
% 28.89/28.92  tff(decl_5486, type, fn_alimentary_canal_13: $i > $i).
% 28.89/28.92  tff(decl_5487, type, large_intestine_1: $i > $o).
% 28.89/28.92  tff(decl_5488, type, fn_alimentary_canal_14: $i > $i).
% 28.89/28.92  tff(decl_5489, type, rectum_1: $i > $o).
% 28.89/28.92  tff(decl_5490, type, fn_alimentary_canal_15: $i > $i).
% 28.89/28.92  tff(decl_5491, type, fn_alimentary_canal_16: $i > $i).
% 28.89/28.92  tff(decl_5492, type, fn_large_intestine_2: $i > $i).
% 28.89/28.92  tff(decl_5493, type, fn_esophagus_2: $i > $i).
% 28.89/28.92  tff(decl_5494, type, fn_esophagus_1: $i > $i).
% 28.89/28.92  tff(decl_5495, type, fn_esophagus_3: $i > $i).
% 28.89/28.92  tff(decl_5496, type, fn_esophagus_5: $i > $i).
% 28.89/28.92  tff(decl_5497, type, fn_esophagus_4: $i > $i).
% 28.89/28.92  tff(decl_5498, type, fn_esophagus_8: $i > $i).
% 28.89/28.92  tff(decl_5499, type, digestive_organ_0: $i).
% 28.89/28.92  tff(decl_5500, type, 'E1': $i).
% 28.89/28.92  tff(decl_5501, type, 'E2': $i).
% 28.89/28.92  tff(decl_5502, type, 'SP5': $i).
% 28.89/28.92  tff(decl_5503, type, 'SP4': $i).
% 28.89/28.92  tff(decl_5504, type, 'SP3': $i).
% 28.89/28.92  tff(decl_5505, type, 'SP2': $i).
% 28.89/28.92  tff(decl_5506, type, 'SP1': $i).
% 28.89/28.92  tff(decl_5507, type, 'Alkaptonuria': $i).
% 28.89/28.92  tff(decl_5508, type, 'A hereditary disease in which urine turns black because of an inability to metabolize alkapton, which accumulates in the blood and is excreted in the urine.': $i).
% 28.89/28.92  tff(decl_5509, type, 'black urine disease': $i).
% 28.89/28.92  tff(decl_5510, type, 'black-urine-disease': $i).
% 28.89/28.92  tff(decl_5511, type, alcaptonuria: $i).
% 28.89/28.92  tff(decl_5512, type, alkaptonuria: $i).
% 28.89/28.92  tff(decl_5513, type, inborn_error_of_metabolism_1: $i > $o).
% 28.89/28.92  tff(decl_5514, type, allantois_1: $i > $o).
% 28.89/28.92  tff(decl_5515, type, 'Allantois': $i).
% 28.89/28.92  tff(decl_5516, type, 'One of four extraembryonic membranes; serves as a repository for the embryos nitrogenous waste and functions in gas exchange.': $i).
% 28.89/28.92  tff(decl_5517, type, allantois: $i).
% 28.89/28.92  tff(decl_5518, type, extraembryonic_membrane_1: $i > $o).
% 28.89/28.92  tff(decl_5519, type, amnion_1: $i > $o).
% 28.89/28.92  tff(decl_5520, type, chorion_1: $i > $o).
% 28.89/28.92  tff(decl_5521, type, yolk_sac_1: $i > $o).
% 28.89/28.92  tff(decl_5522, type, allee_effect_1: $i > $o).
% 28.89/28.92  tff(decl_5523, type, 'Allee-Effect': $i).
% 28.89/28.92  tff(decl_5524, type, 'A positive correlation between population density and individual fitness. First described by W.C. Allee, who showed experimentally that goldfish grew more rapidly in crowded tanks than in uncrowded tanks.': $i).
% 28.89/28.92  tff(decl_5525, type, 'allee effect': $i).
% 28.89/28.92  tff(decl_5526, type, 'allee-effect': $i).
% 28.89/28.92  tff(decl_5527, type, allele_1: $i > $o).
% 28.89/28.92  tff(decl_5528, type, 'Allele': $i).
% 28.89/28.92  tff(decl_5529, type, 'Any of the alternative versions of a gene that produce distinguishable phenotypic effects.': $i).
% 28.89/28.92  tff(decl_5530, type, 'variant of gene': $i).
% 28.89/28.92  tff(decl_5531, type, 'gene variant': $i).
% 28.89/28.92  tff(decl_5532, type, allele: $i).
% 28.89/28.92  tff(decl_5533, type, allele_i_1: $i > $o).
% 28.89/28.92  tff(decl_5534, type, 'Allele-i': $i).
% 28.89/28.92  tff(decl_5535, type, 'Recessive blood allele symbolizing the lack of the IA or IB allele.': $i).
% 28.89/28.92  tff(decl_5536, type, 'allele i': $i).
% 28.89/28.92  tff(decl_5537, type, 'allele-i': $i).
% 28.89/28.92  tff(decl_5538, type, blood_allele_1: $i > $o).
% 28.89/28.92  tff(decl_5539, type, ia_1: $i > $o).
% 28.89/28.92  tff(decl_5540, type, ib_1: $i > $o).
% 28.89/28.92  tff(decl_5541, type, allergy_1: $i > $o).
% 28.89/28.92  tff(decl_5542, type, 'Allergy': $i).
% 28.89/28.92  tff(decl_5543, type, 'A hypersensitivity to normally harmless environmental substances.': $i).
% 28.89/28.92  tff(decl_5544, type, 'show allergic reaction': $i).
% 28.89/28.92  tff(decl_5545, type, allergy: $i).
% 28.89/28.92  tff(decl_5546, type, allocate_resource_1: $i > $o).
% 28.89/28.92  tff(decl_5547, type, 'Allocate-Resource': $i).
% 28.89/28.92  tff(decl_5548, type, allocate: $i).
% 28.89/28.92  tff(decl_5549, type, apportion: $i).
% 28.89/28.92  tff(decl_5550, type, 'allocate resource': $i).
% 28.89/28.92  tff(decl_5551, type, 'allocate-resource': $i).
% 28.89/28.92  tff(decl_5552, type, fn_allocate_resource_1: $i > $i).
% 28.89/28.92  tff(decl_5553, type, fn_allocate_resource_2: $i > $i).
% 28.89/28.92  tff(decl_5554, type, allolactose_1: $i > $o).
% 28.89/28.92  tff(decl_5555, type, 'Allolactose': $i).
% 28.89/28.92  tff(decl_5556, type, 'A form of lactose that acts as the inducer for the lac operon.': $i).
% 28.89/28.92  tff(decl_5557, type, allolactose: $i).
% 28.89/28.92  tff(decl_5558, type, lactose_1: $i > $o).
% 28.89/28.92  tff(decl_5559, type, fn_allolactose_1: $i > $i).
% 28.89/28.92  tff(decl_5560, type, fn_allolactose_2: $i > $i).
% 28.89/28.92  tff(decl_5561, type, transcription_1: $i > $o).
% 28.89/28.92  tff(decl_5562, type, fn_allolactose_3: $i > $i).
% 28.89/28.92  tff(decl_5563, type, fn_allolactose_4: $i > $i).
% 28.89/28.92  tff(decl_5564, type, fn_allolactose_7: $i > $i).
% 28.89/28.92  tff(decl_5565, type, fn_allolactose_8: $i > $i).
% 28.89/28.92  tff(decl_5566, type, fn_allolactose_9: $i > $i).
% 28.89/28.92  tff(decl_5567, type, galactose_1: $i > $o).
% 28.89/28.92  tff(decl_5568, type, fn_allolactose_10: $i > $i).
% 28.89/28.92  tff(decl_5569, type, fn_allolactose_11: $i > $i).
% 28.89/28.92  tff(decl_5570, type, fn_allolactose_12: $i > $i).
% 28.89/28.92  tff(decl_5571, type, fn_allolactose_13: $i > $i).
% 28.89/28.92  tff(decl_5572, type, fn_allolactose_14: $i > $i).
% 28.89/28.92  tff(decl_5573, type, fn_allolactose_15: $i > $i).
% 28.89/28.92  tff(decl_5574, type, fn_allolactose_16: $i > $i).
% 28.89/28.92  tff(decl_5575, type, fn_allolactose_17: $i > $i).
% 28.89/28.92  tff(decl_5576, type, fn_allolactose_18: $i > $i).
% 28.89/28.92  tff(decl_5577, type, fn_allolactose_19: $i > $i).
% 28.89/28.92  tff(decl_5578, type, fn_allolactose_20: $i > $i).
% 28.89/28.92  tff(decl_5579, type, fn_allolactose_21: $i > $i).
% 28.89/28.92  tff(decl_5580, type, fn_allolactose_23: $i > $i).
% 28.89/28.92  tff(decl_5581, type, fn_allolactose_24: $i > $i).
% 28.89/28.92  tff(decl_5582, type, fn_allolactose_25: $i > $i).
% 28.89/28.92  tff(decl_5583, type, fn_allolactose_26: $i > $i).
% 28.89/28.92  tff(decl_5584, type, fn_allolactose_27: $i > $i).
% 28.89/28.92  tff(decl_5585, type, fn_allolactose_28: $i > $i).
% 28.89/28.92  tff(decl_5586, type, fn_allolactose_29: $i > $i).
% 28.89/28.92  tff(decl_5587, type, fn_allolactose_30: $i > $i).
% 28.89/28.92  tff(decl_5588, type, fn_allolactose_31: $i > $i).
% 28.89/28.92  tff(decl_5589, type, fn_allolactose_32: $i > $i).
% 28.89/28.92  tff(decl_5590, type, fn_allolactose_33: $i > $i).
% 28.89/28.92  tff(decl_5591, type, inducer_1: $i > $o).
% 28.89/28.92  tff(decl_5592, type, fn_allolactose_34: $i > $i).
% 28.89/28.92  tff(decl_5593, type, fn_allolactose_35: $i > $i).
% 28.89/28.92  tff(decl_5594, type, fn_hydrogen_8: $i > $i).
% 28.89/28.92  tff(decl_5595, type, fn_hydrogen_9: $i > $i).
% 28.89/28.92  tff(decl_5596, type, fn_inducer_6: $i > $i).
% 28.89/28.92  tff(decl_5597, type, fn_allosteric_protein_5: $i > $i).
% 28.89/28.92  tff(decl_5598, type, "1.00794": $i).
% 28.89/28.92  tff(decl_5599, type, fn_allolactose_22: $i > $i).
% 28.89/28.92  tff(decl_5600, type, fn_disaccharide_33: $i > $i).
% 28.89/28.92  tff(decl_5601, type, fn_allolactose_6: $i > $i).
% 28.89/28.92  tff(decl_5602, type, fn_lactose_83: $i > $i).
% 28.89/28.92  tff(decl_5603, type, fn_allolactose_5: $i > $i).
% 28.89/28.92  tff(decl_5604, type, fn_lactose_82: $i > $i).
% 28.89/28.92  tff(decl_5605, type, fn_lactose_53: $i > $i).
% 28.89/28.92  tff(decl_5606, type, fn_lactose_38: $i > $i).
% 28.89/28.92  tff(decl_5607, type, fn_lactose_48: $i > $i).
% 28.89/28.92  tff(decl_5608, type, fn_lactose_49: $i > $i).
% 28.89/28.92  tff(decl_5609, type, fn_lactose_47: $i > $i).
% 28.89/28.92  tff(decl_5610, type, fn_lactose_24: $i > $i).
% 28.89/28.92  tff(decl_5611, type, fn_lactose_35: $i > $i).
% 28.89/28.92  tff(decl_5612, type, fn_lactose_28: $i > $i).
% 28.89/28.92  tff(decl_5613, type, fn_lactose_27: $i > $i).
% 28.89/28.92  tff(decl_5614, type, fn_lactose_61: $i > $i).
% 28.89/28.92  tff(decl_5615, type, fn_disaccharide_7: $i > $i).
% 28.89/28.92  tff(decl_5616, type, fn_lactose_37: $i > $i).
% 28.89/28.92  tff(decl_5617, type, fn_lactose_36: $i > $i).
% 28.89/28.92  tff(decl_5618, type, fn_lactose_60: $i > $i).
% 28.89/28.92  tff(decl_5619, type, fn_disaccharide_34: $i > $i).
% 28.89/28.92  tff(decl_5620, type, fn_lactose_34: $i > $i).
% 28.89/28.92  tff(decl_5621, type, fn_lactose_81: $i > $i).
% 28.89/28.92  tff(decl_5622, type, fn_lactose_78: $i > $i).
% 28.89/28.92  tff(decl_5623, type, fn_lactose_79: $i > $i).
% 28.89/28.92  tff(decl_5624, type, fn_lactose_80: $i > $i).
% 28.89/28.92  tff(decl_5625, type, fn_disaccharide_14: $i > $i).
% 28.89/28.92  tff(decl_5626, type, fn_lactose_64: $i > $i).
% 28.89/28.92  tff(decl_5627, type, fn_lactose_52: $i > $i).
% 28.89/28.92  tff(decl_5628, type, fn_disaccharide_32: $i > $i).
% 28.89/28.92  tff(decl_5629, type, fn_disaccharide_13: $i > $i).
% 28.89/28.92  tff(decl_5630, type, fn_lactose_63: $i > $i).
% 28.89/28.92  tff(decl_5631, type, fn_lactose_26: $i > $i).
% 28.89/28.92  tff(decl_5632, type, fn_lactose_62: $i > $i).
% 28.89/28.92  tff(decl_5633, type, 'Allopatric-Speciation': $i).
% 28.89/28.92  tff(decl_5634, type, 'The formation of new species as a result of geographic isolation in an ancestral population.': $i).
% 28.89/28.92  tff(decl_5635, type, 'geographic speciation': $i).
% 28.89/28.92  tff(decl_5636, type, 'geographic-speciation': $i).
% 28.89/28.92  tff(decl_5637, type, 'allopatric speciation': $i).
% 28.89/28.92  tff(decl_5638, type, 'allopatric-speciation': $i).
% 28.89/28.92  tff(decl_5639, type, allopolyploid_1: $i > $o).
% 28.89/28.92  tff(decl_5640, type, 'Allopolyploid': $i).
% 28.89/28.92  tff(decl_5641, type, 'An individual with more than two chromosomes, whose chromosomes derive from different species.': $i).
% 28.89/28.92  tff(decl_5642, type, allopolyploid: $i).
% 28.89/28.92  tff(decl_5643, type, polyploidy_1: $i > $o).
% 28.89/28.92  tff(decl_5644, type, autopolyploid_1: $i > $o).
% 28.89/28.92  tff(decl_5645, type, monosomic_1: $i > $o).
% 28.89/28.92  tff(decl_5646, type, allosteric_enzyme_1: $i > $o).
% 28.89/28.92  tff(decl_5647, type, 'Allosteric-Enzyme': $i).
% 28.89/28.92  tff(decl_5648, type, 'Allosteric enzymes are enzymes which are regulated by the binding of regulatory molecules on sites separate from the active site.': $i).
% 28.89/28.92  tff(decl_5649, type, 'allosteric enzyme': $i).
% 28.89/28.92  tff(decl_5650, type, 'allosteric-enzyme': $i).
% 28.89/28.92  tff(decl_5651, type, fn_allosteric_enzyme_5: $i > $i).
% 28.89/28.92  tff(decl_5652, type, fn_allosteric_enzyme_6: $i > $i).
% 28.89/28.92  tff(decl_5653, type, fn_allosteric_enzyme_7: $i > $i).
% 28.89/28.92  tff(decl_5654, type, fn_allosteric_enzyme_8: $i > $i).
% 28.89/28.92  tff(decl_5655, type, fn_allosteric_enzyme_9: $i > $i).
% 28.89/28.92  tff(decl_5656, type, fn_allosteric_enzyme_10: $i > $i).
% 28.89/28.92  tff(decl_5657, type, fn_allosteric_enzyme_11: $i > $i).
% 28.89/28.92  tff(decl_5658, type, fn_allosteric_enzyme_14: $i > $i).
% 28.89/28.92  tff(decl_5659, type, fn_allosteric_enzyme_15: $i > $i).
% 28.89/28.92  tff(decl_5660, type, fn_allosteric_enzyme_16: $i > $i).
% 28.89/28.92  tff(decl_5661, type, fn_allosteric_enzyme_17: $i > $i).
% 28.89/28.92  tff(decl_5662, type, fn_allosteric_enzyme_18: $i > $i).
% 28.89/28.92  tff(decl_5663, type, fn_allosteric_enzyme_19: $i > $i).
% 28.89/28.92  tff(decl_5664, type, fn_allosteric_enzyme_20: $i > $i).
% 28.89/28.92  tff(decl_5665, type, fn_allosteric_enzyme_21: $i > $i).
% 28.89/28.92  tff(decl_5666, type, fn_allosteric_enzyme_13: $i > $i).
% 28.89/28.92  tff(decl_5667, type, fn_protein_10: $i > $i).
% 28.89/28.92  tff(decl_5668, type, allosteric_protein_1: $i > $o).
% 28.89/28.92  tff(decl_5669, type, 'Allosteric-Protein': $i).
% 28.89/28.92  tff(decl_5670, type, 'A protein  whose shape is changed when it binds to a particular molecule. In the new shape the protein\\s ability to react to a second molecule  is altered.': $i).
% 28.89/28.92  tff(decl_5671, type, 'allosteric protein': $i).
% 28.89/28.92  tff(decl_5672, type, 'allosteric-protein': $i).
% 28.89/28.92  tff(decl_5673, type, fn_allosteric_protein_1: $i > $i).
% 28.89/28.92  tff(decl_5674, type, regulator_molecule_1: $i > $o).
% 28.89/28.92  tff(decl_5675, type, fn_allosteric_protein_8: $i > $i).
% 28.89/28.92  tff(decl_5676, type, fn_regulator_molecule_3: $i > $i).
% 28.89/28.92  tff(decl_5677, type, fn_polymer_10: $i > $i).
% 28.89/28.92  tff(decl_5678, type, fn_protein_7: $i > $i).
% 28.89/28.92  tff(decl_5679, type, allosteric_regulation_1: $i > $o).
% 28.89/28.92  tff(decl_5680, type, 'Allosteric-Regulation': $i).
% 28.89/28.92  tff(decl_5681, type, 'The regulation of protein function by the binding of an effector molecule at a site other than the protein\\s active site.': $i).
% 28.89/28.92  tff(decl_5682, type, 'allosteric reaction': $i).
% 28.89/28.92  tff(decl_5683, type, 'allosteric-reaction': $i).
% 28.89/28.92  tff(decl_5684, type, 'allosteric regulation': $i).
% 28.89/28.92  tff(decl_5685, type, 'allosteric-regulation': $i).
% 28.89/28.92  tff(decl_5686, type, regulation_1: $i > $o).
% 28.89/28.92  tff(decl_5687, type, feedback_inhibition_1: $i > $o).
% 28.89/28.92  tff(decl_5688, type, fn_allosteric_regulation_1: $i > $i).
% 28.89/28.92  tff(decl_5689, type, fn_allosteric_regulation_2: $i > $i).
% 28.89/28.92  tff(decl_5690, type, fn_allosteric_regulation_3: $i > $i).
% 28.89/28.92  tff(decl_5691, type, fn_allosteric_regulation_4: $i > $i).
% 28.89/28.92  tff(decl_5692, type, fn_regulator_molecule_2: $i > $i).
% 28.89/28.92  tff(decl_5693, type, 'Allosteric-Site': $i).
% 28.89/28.92  tff(decl_5694, type, 'The site on an enzyme where a molecule other than substrate bind, thus changing the shape of the enzyme and influencing its ability to be active.': $i).
% 28.89/28.92  tff(decl_5695, type, 'regulatory site': $i).
% 28.89/28.92  tff(decl_5696, type, 'regulatory-site': $i).
% 28.89/28.92  tff(decl_5697, type, 'allosteric site': $i).
% 28.89/28.92  tff(decl_5698, type, 'allosteric-site': $i).
% 28.89/28.92  tff(decl_5699, type, receptor_site_1: $i > $o).
% 28.89/28.92  tff(decl_5700, type, alpha_1_comma_4_linkage_1: $i > $o).
% 28.89/28.92  tff(decl_5701, type, 'Alpha-1,4-Linkage': $i).
% 28.89/28.92  tff(decl_5702, type, 'A chemical bond between the number 1 and a number 4 carbon on two adjacent molecules where the oxygen atom from the hydroxyl group of the monosaccharide is below the plane of the molecule.': $i).
% 28.89/28.92  tff(decl_5703, type, 'alpha 1,4 linkage': $i).
% 28.89/28.92  tff(decl_5704, type, 'alpha-1,4-linkage': $i).
% 28.89/28.92  tff(decl_5705, type, glycosidic_linkage_1: $i > $o).
% 28.89/28.92  tff(decl_5706, type, beta_1_comma_4_linkage_1: $i > $o).
% 28.89/28.92  tff(decl_5707, type, fn_alpha_1_comma_4_linkage_11: $i > $i).
% 28.89/28.92  tff(decl_5708, type, fn_alpha_1_comma_4_linkage_12: $i > $i).
% 28.89/28.92  tff(decl_5709, type, fn_alpha_1_comma_4_linkage_13: $i > $i).
% 28.89/28.92  tff(decl_5710, type, fn_alpha_1_comma_4_linkage_14: $i > $i).
% 28.89/28.92  tff(decl_5711, type, fn_alpha_1_comma_4_linkage_15: $i > $i).
% 28.89/28.92  tff(decl_5712, type, fn_alpha_1_comma_4_linkage_16: $i > $i).
% 28.89/28.92  tff(decl_5713, type, fn_alpha_1_comma_4_linkage_17: $i > $i).
% 28.89/28.92  tff(decl_5714, type, asymmetrical_distribution_1: $i > $o).
% 28.89/28.92  tff(decl_5715, type, fn_alpha_1_comma_4_linkage_18: $i > $i).
% 28.89/28.92  tff(decl_5716, type, fn_alpha_1_comma_4_linkage_19: $i > $i).
% 28.89/28.92  tff(decl_5717, type, fn_alpha_1_comma_4_linkage_20: $i > $i).
% 28.89/28.92  tff(decl_5718, type, fn_alpha_1_comma_4_linkage_21: $i > $i).
% 28.89/28.92  tff(decl_5719, type, fn_alpha_1_comma_4_linkage_22: $i > $i).
% 28.89/28.92  tff(decl_5720, type, fn_alpha_1_comma_4_linkage_23: $i > $i).
% 28.89/28.92  tff(decl_5721, type, fn_alpha_1_comma_4_linkage_24: $i > $i).
% 28.89/28.92  tff(decl_5722, type, fn_alpha_1_comma_4_linkage_25: $i > $i).
% 28.89/28.92  tff(decl_5723, type, fn_alpha_1_comma_4_linkage_26: $i > $i).
% 28.89/28.92  tff(decl_5724, type, fn_alpha_1_comma_4_linkage_27: $i > $i).
% 28.89/28.92  tff(decl_5725, type, fn_alpha_1_comma_4_linkage_28: $i > $i).
% 28.89/28.92  tff(decl_5726, type, fn_alpha_1_comma_4_linkage_29: $i > $i).
% 28.89/28.92  tff(decl_5727, type, fn_alpha_1_comma_4_linkage_30: $i > $i).
% 28.89/28.92  tff(decl_5728, type, fn_alpha_1_comma_4_linkage_31: $i > $i).
% 28.89/28.92  tff(decl_5729, type, fn_alpha_1_comma_4_linkage_32: $i > $i).
% 28.89/28.92  tff(decl_5730, type, fn_alpha_1_comma_4_linkage_33: $i > $i).
% 28.89/28.92  tff(decl_5731, type, fn_alpha_1_comma_4_linkage_34: $i > $i).
% 28.89/28.92  tff(decl_5732, type, fn_alpha_1_comma_4_linkage_37: $i > $i).
% 28.89/28.92  tff(decl_5733, type, fn_alpha_1_comma_4_linkage_38: $i > $i).
% 28.89/28.92  tff(decl_5734, type, fn_alpha_1_comma_4_linkage_39: $i > $i).
% 28.89/28.92  tff(decl_5735, type, fn_alpha_1_comma_4_linkage_40: $i > $i).
% 28.89/28.92  tff(decl_5736, type, fn_alpha_1_comma_4_linkage_41: $i > $i).
% 28.89/28.92  tff(decl_5737, type, fn_alpha_1_comma_4_linkage_42: $i > $i).
% 28.89/28.92  tff(decl_5738, type, fn_alpha_1_comma_4_linkage_43: $i > $i).
% 28.89/28.92  tff(decl_5739, type, fn_alpha_1_comma_4_linkage_44: $i > $i).
% 28.89/28.92  tff(decl_5740, type, fn_alpha_1_comma_4_linkage_45: $i > $i).
% 28.89/28.92  tff(decl_5741, type, fn_alpha_1_comma_4_linkage_46: $i > $i).
% 28.89/28.92  tff(decl_5742, type, fn_alpha_1_comma_4_linkage_47: $i > $i).
% 28.89/28.92  tff(decl_5743, type, fn_alpha_1_comma_4_linkage_48: $i > $i).
% 28.89/28.92  tff(decl_5744, type, fn_alpha_1_comma_4_linkage_49: $i > $i).
% 28.89/28.92  tff(decl_5745, type, fn_alpha_1_comma_4_linkage_50: $i > $i).
% 28.89/28.92  tff(decl_5746, type, fn_alpha_1_comma_4_linkage_51: $i > $i).
% 28.89/28.92  tff(decl_5747, type, atomic_orbital_1: $i > $o).
% 28.89/28.92  tff(decl_5748, type, fn_alpha_1_comma_4_linkage_52: $i > $i).
% 28.89/28.92  tff(decl_5749, type, fn_alpha_1_comma_4_linkage_53: $i > $i).
% 28.89/28.92  tff(decl_5750, type, fn_alpha_1_comma_4_linkage_54: $i > $i).
% 28.89/28.92  tff(decl_5751, type, fn_carbon_8: $i > $i).
% 28.89/28.92  tff(decl_5752, type, fn_atom_10: $i > $i).
% 28.89/28.92  tff(decl_5753, type, fn_carbon_12: $i > $i).
% 28.89/28.92  tff(decl_5754, type, 'Number_Electron': $i).
% 28.89/28.92  tff(decl_5755, type, fn_polar_covalent_bond_10: $i > $i).
% 28.89/28.92  tff(decl_5756, type, fn_alpha_1_comma_4_linkage_3: $i > $i).
% 28.89/28.92  tff(decl_5757, type, fn_alpha_1_comma_4_linkage_35: $i > $i).
% 28.89/28.92  tff(decl_5758, type, fn_polar_covalent_bond_8: $i > $i).
% 28.89/28.92  tff(decl_5759, type, fn_polar_covalent_bond_6: $i > $i).
% 28.89/28.92  tff(decl_5760, type, fn_alpha_1_comma_4_linkage_36: $i > $i).
% 28.89/28.92  tff(decl_5761, type, fn_alpha_1_comma_4_linkage_2: $i > $i).
% 28.89/28.92  tff(decl_5762, type, fn_glycosidic_linkage_56: $i > $i).
% 28.89/28.92  tff(decl_5763, type, fn_glycosidic_linkage_14: $i > $i).
% 28.89/28.92  tff(decl_5764, type, fn_glycosidic_linkage_43: $i > $i).
% 28.89/28.92  tff(decl_5765, type, fn_glycosidic_linkage_16: $i > $i).
% 28.89/28.92  tff(decl_5766, type, fn_alpha_1_comma_4_linkage_10: $i > $i).
% 28.89/28.92  tff(decl_5767, type, fn_glycosidic_linkage_31: $i > $i).
% 28.89/28.92  tff(decl_5768, type, fn_glycosidic_linkage_67: $i > $i).
% 28.89/28.92  tff(decl_5769, type, fn_alpha_1_comma_4_linkage_9: $i > $i).
% 28.89/28.92  tff(decl_5770, type, fn_glycosidic_linkage_32: $i > $i).
% 28.89/28.92  tff(decl_5771, type, fn_glycosidic_linkage_44: $i > $i).
% 28.89/28.92  tff(decl_5772, type, fn_alpha_1_comma_4_linkage_8: $i > $i).
% 28.89/28.92  tff(decl_5773, type, fn_glycosidic_linkage_30: $i > $i).
% 28.89/28.92  tff(decl_5774, type, fn_alpha_1_comma_4_linkage_7: $i > $i).
% 28.89/28.92  tff(decl_5775, type, fn_glycosidic_linkage_2: $i > $i).
% 28.89/28.92  tff(decl_5776, type, fn_alpha_1_comma_4_linkage_5: $i > $i).
% 28.89/28.92  tff(decl_5777, type, fn_glycosidic_linkage_68: $i > $i).
% 28.89/28.92  tff(decl_5778, type, fn_alpha_1_comma_4_linkage_4: $i > $i).
% 28.89/28.92  tff(decl_5779, type, fn_glycosidic_linkage_69: $i > $i).
% 28.89/28.92  tff(decl_5780, type, fn_alpha_1_comma_4_linkage_1: $i > $i).
% 28.89/28.92  tff(decl_5781, type, fn_glycosidic_linkage_3: $i > $i).
% 28.89/28.92  tff(decl_5782, type, fn_glycosidic_linkage_57: $i > $i).
% 28.89/28.92  tff(decl_5783, type, fn_glycosidic_linkage_61: $i > $i).
% 28.89/28.92  tff(decl_5784, type, fn_alpha_1_comma_4_linkage_6: $i > $i).
% 28.89/28.92  tff(decl_5785, type, fn_glycosidic_linkage_70: $i > $i).
% 28.89/28.92  tff(decl_5786, type, fn_glycosidic_linkage_1: $i > $i).
% 28.89/28.92  tff(decl_5787, type, fn_glycosidic_linkage_71: $i > $i).
% 28.89/28.92  tff(decl_5788, type, fn_glycosidic_linkage_4: $i > $i).
% 28.89/28.92  tff(decl_5789, type, fn_glycosidic_linkage_21: $i > $i).
% 28.89/28.92  tff(decl_5790, type, fn_glycosidic_linkage_20: $i > $i).
% 28.89/28.92  tff(decl_5791, type, fn_glycosidic_linkage_15: $i > $i).
% 28.89/28.92  tff(decl_5792, type, fn_glycosidic_linkage_34: $i > $i).
% 28.89/28.92  tff(decl_5793, type, fn_glycosidic_linkage_66: $i > $i).
% 28.89/28.92  tff(decl_5794, type, fn_glycosidic_linkage_50: $i > $i).
% 28.89/28.92  tff(decl_5795, type, fn_glycosidic_linkage_33: $i > $i).
% 28.89/28.92  tff(decl_5796, type, fn_polar_covalent_bond_7: $i > $i).
% 28.89/28.92  tff(decl_5797, type, fn_glycosidic_linkage_60: $i > $i).
% 28.89/28.92  tff(decl_5798, type, fn_glycosidic_linkage_19: $i > $i).
% 28.89/28.92  tff(decl_5799, type, fn_glycosidic_linkage_35: $i > $i).
% 28.89/28.92  tff(decl_5800, type, fn_glycosidic_linkage_65: $i > $i).
% 28.89/28.92  tff(decl_5801, type, fn_glycosidic_linkage_51: $i > $i).
% 28.89/28.92  tff(decl_5802, type, fn_glycosidic_linkage_63: $i > $i).
% 28.89/28.92  tff(decl_5803, type, fn_glycosidic_linkage_64: $i > $i).
% 28.89/28.92  tff(decl_5804, type, fn_glycosidic_linkage_42: $i > $i).
% 28.89/28.92  tff(decl_5805, type, fn_glycosidic_linkage_27: $i > $i).
% 28.89/28.92  tff(decl_5806, type, fn_glycosidic_linkage_10: $i > $i).
% 28.89/28.92  tff(decl_5807, type, fn_glycosidic_linkage_36: $i > $i).
% 28.89/28.92  tff(decl_5808, type, fn_glycosidic_linkage_37: $i > $i).
% 28.89/28.92  tff(decl_5809, type, fn_glycosidic_linkage_9: $i > $i).
% 28.89/28.92  tff(decl_5810, type, fn_glycosidic_linkage_38: $i > $i).
% 28.89/28.92  tff(decl_5811, type, fn_glycosidic_linkage_11: $i > $i).
% 28.89/28.92  tff(decl_5812, type, fn_glycosidic_linkage_73: $i > $i).
% 28.89/28.92  tff(decl_5813, type, fn_glycosidic_linkage_13: $i > $i).
% 28.89/28.92  tff(decl_5814, type, fn_glycosidic_linkage_17: $i > $i).
% 28.89/28.92  tff(decl_5815, type, fn_glycosidic_linkage_45: $i > $i).
% 28.89/28.92  tff(decl_5816, type, fn_glycosidic_linkage_48: $i > $i).
% 28.89/28.92  tff(decl_5817, type, fn_glycosidic_linkage_62: $i > $i).
% 28.89/28.92  tff(decl_5818, type, fn_glycosidic_linkage_47: $i > $i).
% 28.89/28.92  tff(decl_5819, type, fn_glycosidic_linkage_49: $i > $i).
% 28.89/28.92  tff(decl_5820, type, fn_glycosidic_linkage_72: $i > $i).
% 28.89/28.92  tff(decl_5821, type, fn_glycosidic_linkage_18: $i > $i).
% 28.89/28.92  tff(decl_5822, type, fn_glycosidic_linkage_26: $i > $i).
% 28.89/28.92  tff(decl_5823, type, fn_glycosidic_linkage_46: $i > $i).
% 28.89/28.92  tff(decl_5824, type, fn_glycosidic_linkage_41: $i > $i).
% 28.89/28.92  tff(decl_5825, type, fn_glycosidic_linkage_74: $i > $i).
% 28.89/28.92  tff(decl_5826, type, fn_glycosidic_linkage_22: $i > $i).
% 28.89/28.92  tff(decl_5827, type, fn_polar_covalent_bond_9: $i > $i).
% 28.89/28.92  tff(decl_5828, type, fn_glycosidic_linkage_59: $i > $i).
% 28.89/28.92  tff(decl_5829, type, fn_glycosidic_linkage_58: $i > $i).
% 28.89/28.92  tff(decl_5830, type, fn_glycosidic_linkage_25: $i > $i).
% 28.89/28.92  tff(decl_5831, type, alpha_1_comma_6_linkage_1: $i > $o).
% 28.89/28.92  tff(decl_5832, type, 'Alpha-1,6-Linkage': $i).
% 28.89/28.92  tff(decl_5833, type, 'A chemical bond between the number 1 and a number 6 carbon on two adjacent molecules.': $i).
% 28.89/28.92  tff(decl_5834, type, 'alpha 1,6 linkage': $i).
% 28.89/28.92  tff(decl_5835, type, 'alpha-1,6-linkage': $i).
% 28.89/28.92  tff(decl_5836, type, alpha_cell_islet_of_langerhans_1: $i > $o).
% 28.89/28.92  tff(decl_5837, type, 'Alpha-Cell-Islet-Of-Langerhans': $i).
% 28.89/28.92  tff(decl_5838, type, 'Endocrine cells of the islets of Langerhans in the pancreas, which secrete glucagon and thus cause an increase in blood glucose level.': $i).
% 28.89/28.92  tff(decl_5839, type, 'alpha cell': $i).
% 28.89/28.92  tff(decl_5840, type, 'alpha-cell': $i).
% 28.89/28.92  tff(decl_5841, type, 'alpha cell islet of langerhans': $i).
% 28.89/28.92  tff(decl_5842, type, 'alpha cell islet of langerhan': $i).
% 28.89/28.92  tff(decl_5843, type, 'alpha-cell-islet-of-langerhan': $i).
% 28.89/28.92  tff(decl_5844, type, pancreas_cell_1: $i > $o).
% 28.89/28.92  tff(decl_5845, type, alpha_globin_1: $i > $o).
% 28.89/28.92  tff(decl_5846, type, 'Alpha-Globin': $i).
% 28.89/28.92  tff(decl_5847, type, 'Alpha globin (HBA) is a protein that, along with beta globin (HBB), makes up the most common form of hemoglobin in adult humans. The normal adult hemoglobin tetramer consists of two alpha chains and two beta chains.': $i).
% 28.89/28.92  tff(decl_5848, type, 'a globin': $i).
% 28.89/28.92  tff(decl_5849, type, 'a-globin': $i).
% 28.89/28.92  tff(decl_5850, type, hba: $i).
% 28.89/28.92  tff(decl_5851, type, 'alpha subunit of hemoglobin': $i).
% 28.89/28.92  tff(decl_5852, type, 'alpha-subunit-of-hemoglobin': $i).
% 28.89/28.92  tff(decl_5853, type, 'hemoglobin alpha subunit': $i).
% 28.89/28.92  tff(decl_5854, type, 'hemoglobin-alpha-subunit': $i).
% 28.89/28.92  tff(decl_5855, type, 'globin of alpha': $i).
% 28.89/28.92  tff(decl_5856, type, 'alpha globin': $i).
% 28.89/28.92  tff(decl_5857, type, 'alpha-globin': $i).
% 28.89/28.92  tff(decl_5858, type, globins_1: $i > $o).
% 28.89/28.92  tff(decl_5859, type, beta_globin_1: $i > $o).
% 28.89/28.92  tff(decl_5860, type, fn_alpha_globin_1: $i > $i).
% 28.89/28.92  tff(decl_5861, type, hemoglobin_1: $i > $o).
% 28.89/28.92  tff(decl_5862, type, alpha_globin_ancestral_gene_1: $i > $o).
% 28.89/28.92  tff(decl_5863, type, 'Alpha-Globin-Ancestral-Gene': $i).
% 28.89/28.92  tff(decl_5864, type, 'Ancestral gene source for the alpha globin ancestral gene and the beta globin ancestral gene.': $i).
% 28.89/28.92  tff(decl_5865, type, 'alpha globin ancestral gene': $i).
% 28.89/28.92  tff(decl_5866, type, 'alpha-globin-ancestral-gene': $i).
% 28.89/28.92  tff(decl_5867, type, globin_ancestral_gene_1: $i > $o).
% 28.89/28.92  tff(decl_5868, type, beta_globin_ancestral_gene_1: $i > $o).
% 28.89/28.92  tff(decl_5869, type, fn_alpha_globin_ancestral_gene_1: $i > $i).
% 28.89/28.92  tff(decl_5870, type, fn_alpha_globin_ancestral_gene_2: $i > $i).
% 28.89/28.92  tff(decl_5871, type, evolution_1: $i > $o).
% 28.89/28.92  tff(decl_5872, type, fn_alpha_globin_ancestral_gene_3: $i > $i).
% 28.89/28.92  tff(decl_5873, type, fn_globin_ancestral_gene_1: $i > $i).
% 28.89/28.92  tff(decl_5874, type, fn_globin_ancestral_gene_2: $i > $i).
% 28.89/28.92  tff(decl_5875, type, alpha_globin_gene_1: $i > $o).
% 28.89/28.92  tff(decl_5876, type, 'Alpha-Globin-Gene': $i).
% 28.89/28.92  tff(decl_5877, type, 'Gene that codes for the alpha globin protein.': $i).
% 28.89/28.92  tff(decl_5878, type, 'alpha globin gene': $i).
% 28.89/28.92  tff(decl_5879, type, 'alpha-globin-gene': $i).
% 28.89/28.92  tff(decl_5880, type, immunoglobulin_gene_1: $i > $o).
% 28.89/28.92  tff(decl_5881, type, alpha_glucose_1: $i > $o).
% 28.89/28.92  tff(decl_5882, type, 'Alpha-Glucose': $i).
% 28.89/28.92  tff(decl_5883, type, 'In alpha glucose the -H group of the rightmost Carbon atom (C1) is above the plane of the ring': $i).
% 28.89/28.92  tff(decl_5884, type, 'glucose of alpha': $i).
% 28.89/28.92  tff(decl_5885, type, 'alpha glucose': $i).
% 28.89/28.92  tff(decl_5886, type, 'alpha-glucose': $i).
% 28.89/28.92  tff(decl_5887, type, glucose_isomer_1: $i > $o).
% 28.89/28.92  tff(decl_5888, type, beta_glucose_1: $i > $o).
% 28.89/28.92  tff(decl_5889, type, fn_alpha_glucose_2: $i > $i).
% 28.89/28.92  tff(decl_5890, type, fn_alpha_glucose_3: $i > $i).
% 28.89/28.92  tff(decl_5891, type, fn_glucose_isomer_1: $i > $i).
% 28.89/28.92  tff(decl_5892, type, 'Alpha-Helix': $i).
% 28.89/28.92  tff(decl_5893, type, 'A coiled region constituting one form of the secondary structure of proteins, arising from a specific pattern of hydrogen bonding between atoms of the polypeptide backbone (not the side chains).': $i).
% 28.89/28.92  tff(decl_5894, type, 'a helix': $i).
% 28.89/28.92  tff(decl_5895, type, 'a-helix': $i).
% 28.89/28.92  tff(decl_5896, type, 'alpha helices': $i).
% 28.89/28.92  tff(decl_5897, type, 'alpha-helices': $i).
% 28.89/28.92  tff(decl_5898, type, 'a helices': $i).
% 28.89/28.92  tff(decl_5899, type, 'a-helices': $i).
% 28.89/28.92  tff(decl_5900, type, 'helix of alpha': $i).
% 28.89/28.92  tff(decl_5901, type, 'alpha helix': $i).
% 28.89/28.92  tff(decl_5902, type, 'alpha-helix': $i).
% 28.89/28.92  tff(decl_5903, type, secondary_protein_structure_1: $i > $o).
% 28.89/28.92  tff(decl_5904, type, fn_alpha_helix_2: $i > $i).
% 28.89/28.92  tff(decl_5905, type, alpha_keratin_1: $i > $o).
% 28.89/28.92  tff(decl_5906, type, 'Alpha-Keratin': $i).
% 28.89/28.92  tff(decl_5907, type, 'The form of the structural protein, keratin, that is rich in alpha helices.': $i).
% 28.89/28.92  tff(decl_5908, type, 'keratin of alpha': $i).
% 28.89/28.92  tff(decl_5909, type, 'alpha keratin': $i).
% 28.89/28.92  tff(decl_5910, type, 'alpha-keratin': $i).
% 28.89/28.92  tff(decl_5911, type, keratin_1: $i > $o).
% 28.89/28.92  tff(decl_5912, type, collagen_1: $i > $o).
% 28.89/28.92  tff(decl_5913, type, fibrin_1: $i > $o).
% 28.89/28.92  tff(decl_5914, type, fibronectin_1: $i > $o).
% 28.89/28.92  tff(decl_5915, type, histone_1: $i > $o).
% 28.89/28.92  tff(decl_5916, type, 'Alpha-Ketoglutarate': $i).
% 28.89/28.92  tff(decl_5917, type, 'Alpha ketoglutarate is an intermediate compound formed in citric acid cycle.': $i).
% 28.89/28.92  tff(decl_5918, type, 'alpha ketoglutarate': $i).
% 28.89/28.92  tff(decl_5919, type, 'alpha-ketoglutarate': $i).
% 28.89/28.92  tff(decl_5920, type, alpha_tubulin_1: $i > $o).
% 28.89/28.92  tff(decl_5921, type, 'Alpha-Tubulin': $i).
% 28.89/28.92  tff(decl_5922, type, 'Polypeptide subunit of tubulin protein.': $i).
% 28.89/28.92  tff(decl_5923, type, 'tubulin of alpha': $i).
% 28.89/28.92  tff(decl_5924, type, 'alpha tubulin': $i).
% 28.89/28.92  tff(decl_5925, type, 'alpha-tubulin': $i).
% 28.89/28.92  tff(decl_5926, type, fn_alpha_tubulin_7: $i > $i).
% 28.89/28.92  tff(decl_5927, type, fn_alpha_tubulin_8: $i > $i).
% 28.89/28.92  tff(decl_5928, type, fn_alpha_tubulin_9: $i > $i).
% 28.89/28.92  tff(decl_5929, type, fn_alpha_tubulin_10: $i > $i).
% 28.89/28.92  tff(decl_5930, type, fn_alpha_tubulin_11: $i > $i).
% 28.89/28.92  tff(decl_5931, type, fn_alpha_tubulin_12: $i > $i).
% 28.89/28.92  tff(decl_5932, type, fn_alpha_tubulin_13: $i > $i).
% 28.89/28.92  tff(decl_5933, type, fn_alpha_tubulin_14: $i > $i).
% 28.89/28.92  tff(decl_5934, type, fn_alpha_tubulin_15: $i > $i).
% 28.89/28.92  tff(decl_5935, type, fn_alpha_tubulin_16: $i > $i).
% 28.89/28.92  tff(decl_5936, type, fn_alpha_tubulin_17: $i > $i).
% 28.89/28.92  tff(decl_5937, type, fn_alpha_tubulin_18: $i > $i).
% 28.89/28.92  tff(decl_5938, type, fn_alpha_tubulin_19: $i > $i).
% 28.89/28.92  tff(decl_5939, type, fn_alpha_tubulin_20: $i > $i).
% 28.89/28.92  tff(decl_5940, type, fn_alpha_tubulin_21: $i > $i).
% 28.89/28.92  tff(decl_5941, type, fn_alpha_tubulin_22: $i > $i).
% 28.89/28.92  tff(decl_5942, type, fn_alpha_tubulin_23: $i > $i).
% 28.89/28.92  tff(decl_5943, type, fn_alpha_tubulin_24: $i > $i).
% 28.89/28.92  tff(decl_5944, type, fn_alpha_tubulin_25: $i > $i).
% 28.89/28.92  tff(decl_5945, type, fn_alpha_tubulin_26: $i > $i).
% 28.89/28.92  tff(decl_5946, type, fn_alpha_tubulin_27: $i > $i).
% 28.89/28.92  tff(decl_5947, type, fn_alpha_tubulin_28: $i > $i).
% 28.89/28.92  tff(decl_5948, type, fn_alpha_tubulin_29: $i > $i).
% 28.89/28.92  tff(decl_5949, type, fn_alpha_tubulin_30: $i > $i).
% 28.89/28.92  tff(decl_5950, type, fn_alpha_tubulin_31: $i > $i).
% 28.89/28.92  tff(decl_5951, type, fn_alpha_tubulin_32: $i > $i).
% 28.89/28.92  tff(decl_5952, type, fn_alpha_tubulin_33: $i > $i).
% 28.89/28.92  tff(decl_5953, type, fn_alpha_tubulin_34: $i > $i).
% 28.89/28.92  tff(decl_5954, type, fn_alpha_tubulin_35: $i > $i).
% 28.89/28.92  tff(decl_5955, type, fn_alpha_tubulin_36: $i > $i).
% 28.89/28.92  tff(decl_5956, type, fn_alpha_tubulin_37: $i > $i).
% 28.89/28.92  tff(decl_5957, type, fn_alpha_tubulin_38: $i > $i).
% 28.89/28.92  tff(decl_5958, type, fn_alpha_tubulin_39: $i > $i).
% 28.89/28.92  tff(decl_5959, type, fn_alpha_tubulin_40: $i > $i).
% 28.89/28.92  tff(decl_5960, type, fn_alpha_tubulin_41: $i > $i).
% 28.89/28.92  tff(decl_5961, type, fn_alpha_tubulin_42: $i > $i).
% 28.89/28.92  tff(decl_5962, type, fn_alpha_tubulin_43: $i > $i).
% 28.89/28.92  tff(decl_5963, type, fn_alpha_tubulin_44: $i > $i).
% 28.89/28.92  tff(decl_5964, type, fn_alpha_tubulin_45: $i > $i).
% 28.89/28.92  tff(decl_5965, type, fn_alpha_tubulin_46: $i > $i).
% 28.89/28.92  tff(decl_5966, type, fn_alpha_tubulin_47: $i > $i).
% 28.89/28.92  tff(decl_5967, type, fn_alpha_tubulin_48: $i > $i).
% 28.89/28.92  tff(decl_5968, type, fn_alpha_tubulin_49: $i > $i).
% 28.89/28.92  tff(decl_5969, type, fn_alpha_tubulin_50: $i > $i).
% 28.89/28.92  tff(decl_5970, type, fn_alpha_tubulin_51: $i > $i).
% 28.89/28.92  tff(decl_5971, type, fn_alpha_tubulin_54: $i > $i).
% 28.89/28.92  tff(decl_5972, type, fn_alpha_tubulin_55: $i > $i).
% 28.89/28.92  tff(decl_5973, type, fn_alpha_tubulin_56: $i > $i).
% 28.89/28.92  tff(decl_5974, type, fn_alpha_tubulin_57: $i > $i).
% 28.89/28.92  tff(decl_5975, type, fn_alpha_tubulin_58: $i > $i).
% 28.89/28.92  tff(decl_5976, type, fn_alpha_tubulin_59: $i > $i).
% 28.89/28.92  tff(decl_5977, type, fn_alpha_tubulin_60: $i > $i).
% 28.89/28.92  tff(decl_5978, type, fn_alpha_tubulin_61: $i > $i).
% 28.89/28.92  tff(decl_5979, type, fn_alpha_tubulin_62: $i > $i).
% 28.89/28.92  tff(decl_5980, type, fn_alpha_tubulin_63: $i > $i).
% 28.89/28.92  tff(decl_5981, type, fn_alpha_tubulin_64: $i > $i).
% 28.89/28.92  tff(decl_5982, type, fn_alpha_tubulin_65: $i > $i).
% 28.89/28.92  tff(decl_5983, type, fn_alpha_tubulin_66: $i > $i).
% 28.89/28.92  tff(decl_5984, type, fn_alpha_tubulin_67: $i > $i).
% 28.89/28.92  tff(decl_5985, type, fn_alpha_tubulin_68: $i > $i).
% 28.89/28.92  tff(decl_5986, type, fn_alpha_tubulin_69: $i > $i).
% 28.89/28.92  tff(decl_5987, type, fn_alpha_tubulin_70: $i > $i).
% 28.89/28.92  tff(decl_5988, type, fn_alpha_tubulin_71: $i > $i).
% 28.89/28.92  tff(decl_5989, type, fn_alpha_tubulin_72: $i > $i).
% 28.89/28.92  tff(decl_5990, type, fn_alpha_tubulin_73: $i > $i).
% 28.89/28.92  tff(decl_5991, type, fn_alpha_tubulin_74: $i > $i).
% 28.89/28.92  tff(decl_5992, type, fn_alpha_tubulin_75: $i > $i).
% 28.89/28.92  tff(decl_5993, type, fn_alpha_tubulin_76: $i > $i).
% 28.89/28.92  tff(decl_5994, type, fn_alpha_tubulin_77: $i > $i).
% 28.89/28.92  tff(decl_5995, type, fn_alpha_tubulin_78: $i > $i).
% 28.89/28.92  tff(decl_5996, type, fn_alpha_tubulin_79: $i > $i).
% 28.89/28.92  tff(decl_5997, type, fn_alpha_tubulin_80: $i > $i).
% 28.89/28.92  tff(decl_5998, type, fn_alpha_tubulin_81: $i > $i).
% 28.89/28.92  tff(decl_5999, type, fn_alpha_tubulin_82: $i > $i).
% 28.89/28.92  tff(decl_6000, type, tubulin_1: $i > $o).
% 28.89/28.92  tff(decl_6001, type, fn_alpha_tubulin_83: $i > $i).
% 28.89/28.92  tff(decl_6002, type, fn_alpha_tubulin_84: $i > $i).
% 28.89/28.92  tff(decl_6003, type, fn_alpha_tubulin_85: $i > $i).
% 28.89/28.92  tff(decl_6004, type, peptide_bond_1: $i > $o).
% 28.89/28.92  tff(decl_6005, type, fn_alpha_tubulin_86: $i > $i).
% 28.89/28.92  tff(decl_6006, type, fn_alpha_tubulin_87: $i > $i).
% 28.89/28.92  tff(decl_6007, type, fn_alpha_tubulin_88: $i > $i).
% 28.89/28.92  tff(decl_6008, type, fn_alpha_tubulin_89: $i > $i).
% 28.89/28.92  tff(decl_6009, type, fn_alpha_tubulin_90: $i > $i).
% 28.89/28.92  tff(decl_6010, type, fn_alpha_tubulin_91: $i > $i).
% 28.89/28.92  tff(decl_6011, type, fn_alpha_tubulin_92: $i > $i).
% 28.89/28.92  tff(decl_6012, type, fn_alpha_tubulin_93: $i > $i).
% 28.89/28.92  tff(decl_6013, type, fn_alpha_tubulin_94: $i > $i).
% 28.89/28.92  tff(decl_6014, type, fn_alpha_tubulin_95: $i > $i).
% 28.89/28.92  tff(decl_6015, type, fn_alpha_tubulin_96: $i > $i).
% 28.89/28.92  tff(decl_6016, type, fn_alpha_tubulin_97: $i > $i).
% 28.89/28.92  tff(decl_6017, type, fn_alpha_tubulin_98: $i > $i).
% 28.89/28.92  tff(decl_6018, type, second_electron_shell_1: $i > $o).
% 28.89/28.92  tff(decl_6019, type, fn_alpha_tubulin_99: $i > $i).
% 28.89/28.92  tff(decl_6020, type, fn_alpha_tubulin_100: $i > $i).
% 28.89/28.92  tff(decl_6021, type, fn_alpha_tubulin_101: $i > $i).
% 28.89/28.92  tff(decl_6022, type, fn_alpha_tubulin_102: $i > $i).
% 28.89/28.92  tff(decl_6023, type, fn_alpha_tubulin_103: $i > $i).
% 28.89/28.92  tff(decl_6024, type, fn_alpha_tubulin_104: $i > $i).
% 28.89/28.92  tff(decl_6025, type, fn_alpha_tubulin_105: $i > $i).
% 28.89/28.92  tff(decl_6026, type, fn_alpha_tubulin_106: $i > $i).
% 28.89/28.92  tff(decl_6027, type, fn_alpha_tubulin_107: $i > $i).
% 28.89/28.92  tff(decl_6028, type, fn_alpha_tubulin_108: $i > $i).
% 28.89/28.92  tff(decl_6029, type, fn_alpha_tubulin_109: $i > $i).
% 28.89/28.92  tff(decl_6030, type, fn_alpha_tubulin_110: $i > $i).
% 28.89/28.92  tff(decl_6031, type, fn_alpha_tubulin_111: $i > $i).
% 28.89/28.92  tff(decl_6032, type, fn_alpha_tubulin_112: $i > $i).
% 28.89/28.92  tff(decl_6033, type, fn_alpha_tubulin_113: $i > $i).
% 28.89/28.92  tff(decl_6034, type, fn_alpha_tubulin_115: $i > $i).
% 28.89/28.92  tff(decl_6035, type, fn_alpha_tubulin_116: $i > $i).
% 28.89/28.92  tff(decl_6036, type, fn_alpha_tubulin_117: $i > $i).
% 28.89/28.92  tff(decl_6037, type, fn_alpha_tubulin_118: $i > $i).
% 28.89/28.92  tff(decl_6038, type, fn_alpha_tubulin_119: $i > $i).
% 28.89/28.92  tff(decl_6039, type, fn_alpha_tubulin_120: $i > $i).
% 28.89/28.92  tff(decl_6040, type, fn_alpha_tubulin_121: $i > $i).
% 28.89/28.92  tff(decl_6041, type, fn_alpha_tubulin_122: $i > $i).
% 28.89/28.92  tff(decl_6042, type, fn_alpha_tubulin_123: $i > $i).
% 28.89/28.92  tff(decl_6043, type, fn_alpha_tubulin_124: $i > $i).
% 28.89/28.92  tff(decl_6044, type, fn_alpha_tubulin_125: $i > $i).
% 28.89/28.92  tff(decl_6045, type, fn_alpha_tubulin_126: $i > $i).
% 28.89/28.92  tff(decl_6046, type, fn_alpha_tubulin_127: $i > $i).
% 28.89/28.92  tff(decl_6047, type, fn_alpha_tubulin_128: $i > $i).
% 28.89/28.92  tff(decl_6048, type, fn_alpha_tubulin_129: $i > $i).
% 28.89/28.92  tff(decl_6049, type, fn_alpha_tubulin_130: $i > $i).
% 28.89/28.92  tff(decl_6050, type, fn_alpha_tubulin_131: $i > $i).
% 28.89/28.92  tff(decl_6051, type, fn_alpha_tubulin_132: $i > $i).
% 28.89/28.92  tff(decl_6052, type, fn_alpha_tubulin_133: $i > $i).
% 28.89/28.92  tff(decl_6053, type, fn_alpha_tubulin_134: $i > $i).
% 28.89/28.92  tff(decl_6054, type, fn_alpha_tubulin_135: $i > $i).
% 28.89/28.92  tff(decl_6055, type, fn_alpha_tubulin_136: $i > $i).
% 28.89/28.92  tff(decl_6056, type, fn_alpha_tubulin_137: $i > $i).
% 28.89/28.92  tff(decl_6057, type, fn_alpha_tubulin_138: $i > $i).
% 28.89/28.92  tff(decl_6058, type, fn_alpha_tubulin_139: $i > $i).
% 28.89/28.92  tff(decl_6059, type, fn_alpha_tubulin_140: $i > $i).
% 28.89/28.92  tff(decl_6060, type, fn_alpha_tubulin_141: $i > $i).
% 28.89/28.92  tff(decl_6061, type, fn_alpha_tubulin_142: $i > $i).
% 28.89/28.92  tff(decl_6062, type, fn_alpha_tubulin_143: $i > $i).
% 28.89/28.92  tff(decl_6063, type, fn_alpha_tubulin_144: $i > $i).
% 28.89/28.92  tff(decl_6064, type, fn_alpha_tubulin_145: $i > $i).
% 28.89/28.92  tff(decl_6065, type, fn_alpha_tubulin_146: $i > $i).
% 28.89/28.92  tff(decl_6066, type, fn_alpha_tubulin_147: $i > $i).
% 28.89/28.92  tff(decl_6067, type, fn_alpha_tubulin_148: $i > $i).
% 28.89/28.92  tff(decl_6068, type, fn_alpha_tubulin_149: $i > $i).
% 28.89/28.92  tff(decl_6069, type, fn_alpha_tubulin_150: $i > $i).
% 28.89/28.92  tff(decl_6070, type, fn_alpha_tubulin_151: $i > $i).
% 28.89/28.92  tff(decl_6071, type, fn_alpha_tubulin_152: $i > $i).
% 28.89/28.92  tff(decl_6072, type, fn_alpha_tubulin_153: $i > $i).
% 28.89/28.92  tff(decl_6073, type, fn_alpha_tubulin_154: $i > $i).
% 28.89/28.92  tff(decl_6074, type, fn_alpha_tubulin_155: $i > $i).
% 28.89/28.92  tff(decl_6075, type, fn_alpha_tubulin_156: $i > $i).
% 28.89/28.92  tff(decl_6076, type, fn_alpha_tubulin_157: $i > $i).
% 28.89/28.92  tff(decl_6077, type, fn_alpha_tubulin_158: $i > $i).
% 28.89/28.92  tff(decl_6078, type, fn_alpha_tubulin_159: $i > $i).
% 28.89/28.92  tff(decl_6079, type, fn_alpha_tubulin_160: $i > $i).
% 28.89/28.92  tff(decl_6080, type, fn_alpha_tubulin_161: $i > $i).
% 28.89/28.92  tff(decl_6081, type, fn_alpha_tubulin_162: $i > $i).
% 28.89/28.92  tff(decl_6082, type, fn_alpha_tubulin_163: $i > $i).
% 28.89/28.92  tff(decl_6083, type, fn_alpha_tubulin_164: $i > $i).
% 28.89/28.92  tff(decl_6084, type, fn_alpha_tubulin_165: $i > $i).
% 28.89/28.92  tff(decl_6085, type, fn_alpha_tubulin_166: $i > $i).
% 28.89/28.92  tff(decl_6086, type, fn_alpha_tubulin_167: $i > $i).
% 28.89/28.92  tff(decl_6087, type, fn_alpha_tubulin_168: $i > $i).
% 28.89/28.92  tff(decl_6088, type, fn_alpha_tubulin_169: $i > $i).
% 28.89/28.92  tff(decl_6089, type, fn_amino_group_29: $i > $i).
% 28.89/28.92  tff(decl_6090, type, fn_amino_group_30: $i > $i).
% 28.89/28.92  tff(decl_6091, type, fn_carboxyl_group_30: $i > $i).
% 28.89/28.92  tff(decl_6092, type, fn_carboxyl_group_54: $i > $i).
% 28.89/28.92  tff(decl_6093, type, fn_peptide_bond_4: $i > $i).
% 28.89/28.92  tff(decl_6094, type, fn_peptide_bond_9: $i > $i).
% 28.89/28.92  tff(decl_6095, type, fn_peptide_bond_10: $i > $i).
% 28.89/28.92  tff(decl_6096, type, fn_peptide_bond_3: $i > $i).
% 28.89/28.92  tff(decl_6097, type, fn_peptide_bond_40: $i > $i).
% 28.89/28.92  tff(decl_6098, type, fn_peptide_bond_39: $i > $i).
% 28.89/28.92  tff(decl_6099, type, fn_peptide_bond_29: $i > $i).
% 28.89/28.92  tff(decl_6100, type, fn_covalent_bond_9: $i > $i).
% 28.89/28.92  tff(decl_6101, type, fn_covalent_bond_8: $i > $i).
% 28.89/28.92  tff(decl_6102, type, fn_covalent_bond_16: $i > $i).
% 28.89/28.92  tff(decl_6103, type, fn_covalent_bond_1: $i > $i).
% 28.89/28.92  tff(decl_6104, type, fn_covalent_bond_10: $i > $i).
% 28.89/28.92  tff(decl_6105, type, fn_amino_group_35: $i > $i).
% 28.89/28.92  tff(decl_6106, type, fn_carboxyl_group_56: $i > $i).
% 28.89/28.92  tff(decl_6107, type, fn_peptide_bond_33: $i > $i).
% 28.89/28.92  tff(decl_6108, type, fn_peptide_bond_15: $i > $i).
% 28.89/28.92  tff(decl_6109, type, fn_amino_group_33: $i > $i).
% 28.89/28.92  tff(decl_6110, type, fn_peptide_bond_31: $i > $i).
% 28.89/28.92  tff(decl_6111, type, fn_peptide_bond_51: $i > $i).
% 28.89/28.92  tff(decl_6112, type, fn_peptide_bond_35: $i > $i).
% 28.89/28.92  tff(decl_6113, type, fn_peptide_bond_22: $i > $i).
% 28.89/28.92  tff(decl_6114, type, fn_peptide_bond_21: $i > $i).
% 28.89/28.92  tff(decl_6115, type, fn_hold_1: $i > $i).
% 28.89/28.92  tff(decl_6116, type, fn_peptide_bond_55: $i > $i).
% 28.89/28.92  tff(decl_6117, type, fn_amino_group_28: $i > $i).
% 28.89/28.92  tff(decl_6118, type, fn_peptide_bond_12: $i > $i).
% 28.89/28.92  tff(decl_6119, type, fn_covalent_bond_5: $i > $i).
% 28.89/28.92  tff(decl_6120, type, fn_peptide_bond_11: $i > $i).
% 28.89/28.92  tff(decl_6121, type, fn_covalent_bond_7: $i > $i).
% 28.89/28.92  tff(decl_6122, type, fn_peptide_bond_45: $i > $i).
% 28.89/28.92  tff(decl_6123, type, fn_covalent_bond_6: $i > $i).
% 28.89/28.92  tff(decl_6124, type, fn_peptide_bond_46: $i > $i).
% 28.89/28.92  tff(decl_6125, type, fn_peptide_bond_28: $i > $i).
% 28.89/28.92  tff(decl_6126, type, fn_peptide_bond_30: $i > $i).
% 28.89/28.92  tff(decl_6127, type, fn_covalent_bond_13: $i > $i).
% 28.89/28.92  tff(decl_6128, type, fn_peptide_bond_52: $i > $i).
% 28.89/28.92  tff(decl_6129, type, fn_amino_group_25: $i > $i).
% 28.89/28.92  tff(decl_6130, type, fn_peptide_bond_42: $i > $i).
% 28.89/28.92  tff(decl_6131, type, fn_peptide_bond_43: $i > $i).
% 28.89/28.92  tff(decl_6132, type, fn_peptide_bond_16: $i > $i).
% 28.89/28.92  tff(decl_6133, type, fn_peptide_bond_41: $i > $i).
% 28.89/28.92  tff(decl_6134, type, fn_carboxyl_group_58: $i > $i).
% 28.89/28.92  tff(decl_6135, type, fn_peptide_bond_18: $i > $i).
% 28.89/28.92  tff(decl_6136, type, fn_peptide_bond_47: $i > $i).
% 28.89/28.92  tff(decl_6137, type, fn_peptide_bond_27: $i > $i).
% 28.89/28.92  tff(decl_6138, type, fn_amino_group_32: $i > $i).
% 28.89/28.92  tff(decl_6139, type, fn_peptide_bond_23: $i > $i).
% 28.89/28.92  tff(decl_6140, type, fn_amino_group_22: $i > $i).
% 28.89/28.92  tff(decl_6141, type, fn_peptide_bond_24: $i > $i).
% 28.89/28.92  tff(decl_6142, type, fn_amino_group_20: $i > $i).
% 28.89/28.92  tff(decl_6143, type, fn_peptide_bond_34: $i > $i).
% 28.89/28.92  tff(decl_6144, type, fn_peptide_bond_50: $i > $i).
% 28.89/28.92  tff(decl_6145, type, fn_peptide_bond_53: $i > $i).
% 28.89/28.92  tff(decl_6146, type, fn_peptide_bond_32: $i > $i).
% 28.89/28.92  tff(decl_6147, type, fn_amino_group_23: $i > $i).
% 28.89/28.92  tff(decl_6148, type, fn_amino_group_19: $i > $i).
% 28.89/28.92  tff(decl_6149, type, fn_carboxyl_group_17: $i > $i).
% 28.89/28.92  tff(decl_6150, type, fn_peptide_bond_13: $i > $i).
% 28.89/28.92  tff(decl_6151, type, fn_amino_group_8: $i > $i).
% 28.89/28.92  tff(decl_6152, type, fn_amino_group_21: $i > $i).
% 28.89/28.92  tff(decl_6153, type, fn_peptide_bond_44: $i > $i).
% 28.89/28.92  tff(decl_6154, type, 'C=O': $i).
% 28.89/28.92  tff(decl_6155, type, "2.55": $i).
% 28.89/28.92  tff(decl_6156, type, "7": $i).
% 28.89/28.92  tff(decl_6157, type, fn_alpha_tubulin_6: $i > $i).
% 28.89/28.92  tff(decl_6158, type, fn_polymer_9: $i > $i).
% 28.89/28.92  tff(decl_6159, type, fn_alpha_tubulin_5: $i > $i).
% 28.89/28.92  tff(decl_6160, type, fn_alpha_tubulin_53: $i > $i).
% 28.89/28.92  tff(decl_6161, type, fn_alpha_tubulin_52: $i > $i).
% 28.89/28.92  tff(decl_6162, type, fn_polypeptide_113: $i > $i).
% 28.89/28.92  tff(decl_6163, type, fn_polypeptide_122: $i > $i).
% 28.89/28.92  tff(decl_6164, type, fn_polypeptide_111: $i > $i).
% 28.89/28.92  tff(decl_6165, type, fn_polypeptide_53: $i > $i).
% 28.89/28.92  tff(decl_6166, type, fn_polypeptide_52: $i > $i).
% 28.89/28.92  tff(decl_6167, type, fn_polypeptide_40: $i > $i).
% 28.89/28.92  tff(decl_6168, type, fn_polypeptide_87: $i > $i).
% 28.89/28.92  tff(decl_6169, type, fn_polypeptide_17: $i > $i).
% 28.89/28.92  tff(decl_6170, type, fn_polypeptide_55: $i > $i).
% 28.89/28.92  tff(decl_6171, type, fn_polypeptide_129: $i > $i).
% 28.89/28.92  tff(decl_6172, type, fn_polypeptide_112: $i > $i).
% 28.89/28.92  tff(decl_6173, type, fn_polypeptide_63: $i > $i).
% 28.89/28.92  tff(decl_6174, type, fn_polypeptide_41: $i > $i).
% 28.89/28.92  tff(decl_6175, type, fn_polypeptide_84: $i > $i).
% 28.89/28.92  tff(decl_6176, type, fn_polypeptide_37: $i > $i).
% 28.89/28.92  tff(decl_6177, type, fn_polypeptide_38: $i > $i).
% 28.89/28.92  tff(decl_6178, type, fn_polypeptide_103: $i > $i).
% 28.89/28.92  tff(decl_6179, type, fn_polypeptide_109: $i > $i).
% 28.89/28.92  tff(decl_6180, type, fn_polypeptide_118: $i > $i).
% 28.89/28.92  tff(decl_6181, type, fn_polypeptide_123: $i > $i).
% 28.89/28.92  tff(decl_6182, type, fn_polypeptide_121: $i > $i).
% 28.89/28.92  tff(decl_6183, type, fn_polypeptide_110: $i > $i).
% 28.89/28.92  tff(decl_6184, type, fn_polypeptide_102: $i > $i).
% 28.89/28.92  tff(decl_6185, type, fn_polypeptide_51: $i > $i).
% 28.89/28.92  tff(decl_6186, type, fn_polypeptide_78: $i > $i).
% 28.89/28.92  tff(decl_6187, type, fn_polypeptide_105: $i > $i).
% 28.89/28.92  tff(decl_6188, type, fn_polypeptide_104: $i > $i).
% 28.89/28.92  tff(decl_6189, type, fn_polypeptide_97: $i > $i).
% 28.89/28.92  tff(decl_6190, type, fn_polypeptide_56: $i > $i).
% 28.89/28.92  tff(decl_6191, type, fn_polypeptide_49: $i > $i).
% 28.89/28.92  tff(decl_6192, type, fn_polypeptide_99: $i > $i).
% 28.89/28.92  tff(decl_6193, type, fn_polypeptide_120: $i > $i).
% 28.89/28.92  tff(decl_6194, type, fn_polypeptide_127: $i > $i).
% 28.89/28.92  tff(decl_6195, type, fn_polypeptide_39: $i > $i).
% 28.89/28.92  tff(decl_6196, type, fn_polypeptide_98: $i > $i).
% 28.89/28.92  tff(decl_6197, type, fn_polypeptide_30: $i > $i).
% 28.89/28.92  tff(decl_6198, type, fn_polypeptide_31: $i > $i).
% 28.89/28.92  tff(decl_6199, type, fn_polypeptide_80: $i > $i).
% 28.89/28.92  tff(decl_6200, type, fn_polypeptide_94: $i > $i).
% 28.89/28.92  tff(decl_6201, type, fn_polypeptide_61: $i > $i).
% 28.89/28.92  tff(decl_6202, type, fn_polypeptide_44: $i > $i).
% 28.89/28.92  tff(decl_6203, type, fn_polypeptide_126: $i > $i).
% 28.89/28.92  tff(decl_6204, type, fn_polypeptide_90: $i > $i).
% 28.89/28.92  tff(decl_6205, type, fn_polypeptide_50: $i > $i).
% 28.89/28.92  tff(decl_6206, type, fn_polypeptide_96: $i > $i).
% 28.89/28.92  tff(decl_6207, type, fn_polypeptide_43: $i > $i).
% 28.89/28.92  tff(decl_6208, type, fn_polypeptide_42: $i > $i).
% 28.89/28.92  tff(decl_6209, type, fn_polypeptide_101: $i > $i).
% 28.89/28.92  tff(decl_6210, type, fn_polypeptide_54: $i > $i).
% 28.89/28.92  tff(decl_6211, type, fn_polypeptide_119: $i > $i).
% 28.89/28.92  tff(decl_6212, type, fn_polypeptide_107: $i > $i).
% 28.89/28.92  tff(decl_6213, type, fn_polypeptide_25: $i > $i).
% 28.89/28.92  tff(decl_6214, type, fn_polypeptide_108: $i > $i).
% 28.89/28.92  tff(decl_6215, type, fn_polypeptide_125: $i > $i).
% 28.89/28.92  tff(decl_6216, type, fn_polypeptide_128: $i > $i).
% 28.89/28.92  tff(decl_6217, type, fn_polypeptide_81: $i > $i).
% 28.89/28.92  tff(decl_6218, type, fn_polypeptide_106: $i > $i).
% 28.89/28.92  tff(decl_6219, type, fn_polypeptide_85: $i > $i).
% 28.89/28.92  tff(decl_6220, type, fn_polypeptide_48: $i > $i).
% 28.89/28.92  tff(decl_6221, type, fn_polypeptide_100: $i > $i).
% 28.89/28.92  tff(decl_6222, type, fn_polypeptide_82: $i > $i).
% 28.89/28.92  tff(decl_6223, type, fn_polypeptide_15: $i > $i).
% 28.89/28.92  tff(decl_6224, type, fn_polypeptide_83: $i > $i).
% 28.89/28.92  tff(decl_6225, type, fn_polypeptide_89: $i > $i).
% 28.89/28.92  tff(decl_6226, type, fn_polypeptide_91: $i > $i).
% 28.89/28.92  tff(decl_6227, type, fn_polypeptide_69: $i > $i).
% 28.89/28.92  tff(decl_6228, type, fn_polypeptide_130: $i > $i).
% 28.89/28.92  tff(decl_6229, type, fn_alpha_tubulin_170: $i > $i).
% 28.89/28.92  tff(decl_6230, type, fn_alpha_tubulin_171: $i > $i).
% 28.89/28.92  tff(decl_6231, type, fn_alpha_tubulin_172: $i > $i).
% 28.89/28.92  tff(decl_6232, type, fn_alpha_tubulin_114: $i > $i).
% 28.89/28.92  tff(decl_6233, type, fn_alpha_tubulin_173: $i > $i).
% 28.89/28.92  tff(decl_6234, type, alter_1: $i > $o).
% 28.89/28.92  tff(decl_6235, type, 'Alter': $i).
% 28.89/28.92  tff(decl_6236, type, 'Change or cause to change in character or composition.': $i).
% 28.89/28.92  tff(decl_6237, type, alter: $i).
% 28.89/28.92  tff(decl_6238, type, alter_genome_1: $i > $o).
% 28.89/28.92  tff(decl_6239, type, 'Alter-Genome': $i).
% 28.89/28.92  tff(decl_6240, type, 'Changing the genomic structure of an organism.': $i).
% 28.89/28.92  tff(decl_6241, type, 'genome of alter': $i).
% 28.89/28.92  tff(decl_6242, type, 'alter genome': $i).
% 28.89/28.92  tff(decl_6243, type, 'alter-genome': $i).
% 28.89/28.92  tff(decl_6244, type, change_sequence_1: $i > $o).
% 28.89/28.92  tff(decl_6245, type, fn_alter_genome_1: $i > $i).
% 28.89/28.92  tff(decl_6246, type, genome_1: $i > $o).
% 28.89/28.92  tff(decl_6247, type, alteration_of_mrna_ends_1: $i > $o).
% 28.89/28.92  tff(decl_6248, type, 'Alteration-of-mRNA-Ends': $i).
% 28.89/28.92  tff(decl_6249, type, 'Modification of pre-mRNA where the 5-prime end is capped off with a modified form of a guanine nucleotide and a poly(A) tail consisting of 50 to 250 nucleotides is added to the 3-prime end.': $i).
% 28.89/28.92  tff(decl_6250, type, 'alteration of mrna end': $i).
% 28.89/28.92  tff(decl_6251, type, 'alteration-of-mrna-end': $i).
% 28.89/28.92  tff(decl_6252, type, biochemical_change_1: $i > $o).
% 28.89/28.92  tff(decl_6253, type, conversion_to_isomer_1: $i > $o).
% 28.89/28.92  tff(decl_6254, type, detoxification_1: $i > $o).
% 28.89/28.92  tff(decl_6255, type, evaporation_1: $i > $o).
% 28.89/28.92  tff(decl_6256, type, fold_1: $i > $o).
% 28.89/28.92  tff(decl_6257, type, freezing_1: $i > $o).
% 28.89/28.92  tff(decl_6258, type, gene_therapy_1: $i > $o).
% 28.89/28.92  tff(decl_6259, type, melting_1: $i > $o).
% 28.89/28.92  tff(decl_6260, type, metamorphosis_1: $i > $o).
% 28.89/28.92  tff(decl_6261, type, mutation_1: $i > $o).
% 28.89/28.92  tff(decl_6262, type, post_translational_modification_1: $i > $o).
% 28.89/28.92  tff(decl_6263, type, refract_1: $i > $o).
% 28.89/28.92  tff(decl_6264, type, temperature_fluctuation_1: $i > $o).
% 28.89/28.92  tff(decl_6265, type, transformation_1: $i > $o).
% 28.89/28.92  tff(decl_6266, type, twist_1: $i > $o).
% 28.89/28.92  tff(decl_6267, type, fn_alteration_of_mrna_ends_1: $i > $i).
% 28.89/28.92  tff(decl_6268, type, fn_alteration_of_mrna_ends_2: $i > $i).
% 28.89/28.92  tff(decl_6269, type, fn_alteration_of_mrna_ends_3: $i > $i).
% 28.89/28.92  tff(decl_6270, type, fn_alteration_of_mrna_ends_4: $i > $i).
% 28.89/28.92  tff(decl_6271, type, fn_alteration_of_mrna_ends_5: $i > $i).
% 28.89/28.92  tff(decl_6272, type, five_prime_cap_1: $i > $o).
% 28.89/28.92  tff(decl_6273, type, fn_alteration_of_mrna_ends_6: $i > $i).
% 28.89/28.92  tff(decl_6274, type, pre_mrna_1: $i > $o).
% 28.89/28.92  tff(decl_6275, type, fn_alteration_of_mrna_ends_7: $i > $i).
% 28.89/28.92  tff(decl_6276, type, fn_alteration_of_mrna_ends_8: $i > $i).
% 28.89/28.92  tff(decl_6277, type, fn_alteration_of_mrna_ends_9: $i > $i).
% 28.89/28.92  tff(decl_6278, type, fn_alteration_of_mrna_ends_10: $i > $i).
% 28.89/28.92  tff(decl_6279, type, fn_alteration_of_mrna_ends_11: $i > $i).
% 28.89/28.92  tff(decl_6280, type, fn_alteration_of_mrna_ends_12: $i > $i).
% 28.89/28.92  tff(decl_6281, type, seven_methyl_guanosine_1: $i > $o).
% 28.89/28.92  tff(decl_6282, type, fn_alteration_of_mrna_ends_13: $i > $i).
% 28.89/28.92  tff(decl_6283, type, fn_alteration_of_mrna_ends_14: $i > $i).
% 28.89/28.92  tff(decl_6284, type, fn_rna_1: $i > $i).
% 28.89/28.92  tff(decl_6285, type, fn_pre_mrna_17: $i > $i).
% 28.89/28.92  tff(decl_6286, type, fn_pre_mrna_3: $i > $i).
% 28.89/28.92  tff(decl_6287, type, object_0: $i).
% 28.89/28.92  tff(decl_6288, type, "250": $i).
% 28.89/28.92  tff(decl_6289, type, adenine_0: $i).
% 28.89/28.92  tff(decl_6290, type, maxCardinality: ($i * $i * $i * $i) > $o).
% 28.89/28.92  tff(decl_6291, type, "50": $i).
% 28.89/28.92  tff(decl_6292, type, minCardinality: ($i * $i * $i * $i) > $o).
% 28.89/28.92  tff(decl_6293, type, alternating_generation_organ_1: $i > $o).
% 28.89/28.92  tff(decl_6294, type, 'Alternating-Generation-Organ': $i).
% 28.89/28.92  tff(decl_6295, type, 'Organ of plants which participates in the process of alternation of generations.': $i).
% 28.89/28.92  tff(decl_6296, type, 'alternating generation organ': $i).
% 28.89/28.92  tff(decl_6297, type, 'alternating-generation-organ': $i).
% 28.89/28.92  tff(decl_6298, type, plant_organ_1: $i > $o).
% 28.89/28.92  tff(decl_6299, type, sporophyte_1: $i > $o).
% 28.89/28.92  tff(decl_6300, type, life_cycle_process_1: $i > $o).
% 28.89/28.92  tff(decl_6301, type, gametophyte_1: $i > $o).
% 28.89/28.92  tff(decl_6302, type, alternation_of_generations_1: $i > $o).
% 28.89/28.92  tff(decl_6303, type, fn_alternation_of_generations_10: $i > $i).
% 28.89/28.92  tff(decl_6304, type, fn_alternation_of_generations_8: $i > $i).
% 28.89/28.92  tff(decl_6305, type, fn_alternation_of_generations_5: $i > $i).
% 28.89/28.92  tff(decl_6306, type, fn_alternation_of_generations_9: $i > $i).
% 28.89/28.92  tff(decl_6307, type, fn_alternation_of_generations_11: $i > $i).
% 28.89/28.92  tff(decl_6308, type, 'Alternation-Of-Generations': $i).
% 28.89/28.92  tff(decl_6309, type, 'In plants and some algae, a life cycle that has two multicellular phases: a haploid gametophyte and a diploid sporophyte.': $i).
% 28.89/28.92  tff(decl_6310, type, 'show alternation of generations': $i).
% 28.89/28.92  tff(decl_6311, type, 'alternation of generation': $i).
% 28.89/28.92  tff(decl_6312, type, 'alternation-of-generation': $i).
% 28.89/28.92  tff(decl_6313, type, fn_alternation_of_generations_1: $i > $i).
% 28.89/28.92  tff(decl_6314, type, mitosis_1: $i > $o).
% 28.89/28.92  tff(decl_6315, type, fn_alternation_of_generations_2: $i > $i).
% 28.89/28.92  tff(decl_6316, type, fertilization_1: $i > $o).
% 28.89/28.92  tff(decl_6317, type, fn_alternation_of_generations_3: $i > $i).
% 28.89/28.92  tff(decl_6318, type, fn_alternation_of_generations_4: $i > $i).
% 28.89/28.92  tff(decl_6319, type, meiosis_1: $i > $o).
% 28.89/28.92  tff(decl_6320, type, fn_alternation_of_generations_6: $i > $i).
% 28.89/28.92  tff(decl_6321, type, subevent_0: $i).
% 28.89/28.92  tff(decl_6322, type, mitosis_0: $i).
% 28.89/28.92  tff(decl_6323, type, alternative_rna_splicing_1: $i > $o).
% 28.89/28.92  tff(decl_6324, type, 'Alternative-RNA-Splicing': $i).
% 28.89/28.92  tff(decl_6325, type, 'A type of eukaryotic gene regulation at the RNA-processing level in which different mRNA molecules are produced from the same primary transcript, depending on which RNA segments are treated as exons and which as introns.': $i).
% 28.89/28.92  tff(decl_6326, type, splice: $i).
% 28.89/28.92  tff(decl_6327, type, 'alternative rna splicing': $i).
% 28.89/28.92  tff(decl_6328, type, 'alternative-rna-splicing': $i).
% 28.89/28.92  tff(decl_6329, type, rna_splicing_1: $i > $o).
% 28.89/28.92  tff(decl_6330, type, post_transcriptional_modification_of_rna_1: $i > $o).
% 28.89/28.92  tff(decl_6331, type, fn_alternative_rna_splicing_1: $i > $i).
% 28.89/28.92  tff(decl_6332, type, fn_alternative_rna_splicing_2: $i > $i).
% 28.89/28.92  tff(decl_6333, type, exon_1: $i > $o).
% 28.89/28.92  tff(decl_6334, type, fn_alternative_rna_splicing_3: $i > $i).
% 28.89/28.92  tff(decl_6335, type, eukaryotic_gene_regulation_1: $i > $o).
% 28.89/28.92  tff(decl_6336, type, fn_alternative_rna_splicing_4: $i > $i).
% 28.89/28.92  tff(decl_6337, type, fn_alternative_rna_splicing_5: $i > $i).
% 28.89/28.92  tff(decl_6338, type, fn_alternative_rna_splicing_6: $i > $i).
% 28.89/28.92  tff(decl_6339, type, fn_alternative_rna_splicing_7: $i > $i).
% 28.89/28.92  tff(decl_6340, type, fn_alternative_rna_splicing_8: $i > $i).
% 28.89/28.92  tff(decl_6341, type, fn_alternative_rna_splicing_9: $i > $i).
% 28.89/28.92  tff(decl_6342, type, rna_splicing_0: $i).
% 28.89/28.92  tff(decl_6343, type, result_0: $i).
% 28.89/28.92  tff(decl_6344, type, base_0: $i).
% 28.89/28.92  tff(decl_6345, type, gene_0: $i).
% 28.89/28.92  tff(decl_6346, type, altruism_1: $i > $o).
% 28.89/28.92  tff(decl_6347, type, 'Altruism': $i).
% 28.89/28.92  tff(decl_6348, type, 'Behavior that increases another individual\\s fitness at the risk of one\\s own fitness.': $i).
% 28.89/28.92  tff(decl_6349, type, behave: $i).
% 28.89/28.92  tff(decl_6350, type, altruism: $i).
% 28.89/28.92  tff(decl_6351, type, alu_element_1: $i > $o).
% 28.89/28.92  tff(decl_6352, type, 'Alu-Element': $i).
% 28.89/28.92  tff(decl_6353, type, 'An interspersed repeated sequence of DNA, typically about 300 units long': $i).
% 28.89/28.92  tff(decl_6354, type, 'alu element': $i).
% 28.89/28.92  tff(decl_6355, type, 'alu-element': $i).
% 28.89/28.92  tff(decl_6356, type, transposon_1: $i > $o).
% 28.89/28.92  tff(decl_6357, type, aluminum_1: $i > $o).
% 28.89/28.92  tff(decl_6358, type, 'Aluminum': $i).
% 28.89/28.92  tff(decl_6359, type, 'Aluminum is a metal atom with atomic number 13. It is represented by the symbol Al.': $i).
% 28.89/28.92  tff(decl_6360, type, aluminum: $i).
% 28.89/28.92  tff(decl_6361, type, 'Al': $i).
% 28.89/28.92  tff(decl_6362, type, fn_aluminum_4: $i > $i).
% 28.89/28.92  tff(decl_6363, type, fn_aluminum_5: $i > $i).
% 28.89/28.92  tff(decl_6364, type, fn_aluminum_6: $i > $i).
% 28.89/28.92  tff(decl_6365, type, fn_aluminum_7: $i > $i).
% 28.89/28.92  tff(decl_6366, type, fn_aluminum_11: $i > $i).
% 28.89/28.92  tff(decl_6367, type, fn_aluminum_12: $i > $i).
% 28.89/28.92  tff(decl_6368, type, fn_aluminum_13: $i > $i).
% 28.89/28.92  tff(decl_6369, type, fn_aluminum_14: $i > $i).
% 28.89/28.92  tff(decl_6370, type, "14": $i).
% 28.89/28.92  tff(decl_6371, type, "13": $i).
% 28.89/28.92  tff(decl_6372, type, "1.61": $i).
% 28.89/28.92  tff(decl_6373, type, "27": $i).
% 28.89/28.92  tff(decl_6374, type, "26.98": $i).
% 28.89/28.92  tff(decl_6375, type, fn_aluminum_9: $i > $i).
% 28.89/28.92  tff(decl_6376, type, fn_aluminum_10: $i > $i).
% 28.89/28.92  tff(decl_6377, type, fn_aluminum_8: $i > $i).
% 28.89/28.92  tff(decl_6378, type, alveolate_1: $i > $o).
% 28.89/28.92  tff(decl_6379, type, 'Alveolate': $i).
% 28.89/28.92  tff(decl_6380, type, 'One of a group of protistan phyla, characterized by the presence of flattened vesicles called alveoli under the plasma membrane.': $i).
% 28.89/28.92  tff(decl_6381, type, alveolata: $i).
% 28.89/28.92  tff(decl_6382, type, alveolate: $i).
% 28.89/28.92  tff(decl_6383, type, unicellular_organism_1: $i > $o).
% 28.89/28.92  tff(decl_6384, type, protist_cell_1: $i > $o).
% 28.89/28.92  tff(decl_6385, type, charophycean_1: $i > $o).
% 28.89/28.92  tff(decl_6386, type, chlorophyta_1: $i > $o).
% 28.89/28.92  tff(decl_6387, type, diplomonad_1: $i > $o).
% 28.89/28.92  tff(decl_6388, type, foraminiferan_1: $i > $o).
% 28.89/28.92  tff(decl_6389, type, freshwater_protist_1: $i > $o).
% 28.89/28.92  tff(decl_6390, type, oomycete_1: $i > $o).
% 28.89/28.92  tff(decl_6391, type, parabasalid_1: $i > $o).
% 28.89/28.92  tff(decl_6392, type, radiolarian_1: $i > $o).
% 28.89/28.92  tff(decl_6393, type, rhizaria_1: $i > $o).
% 28.89/28.92  tff(decl_6394, type, rhodophyte_1: $i > $o).
% 28.89/28.92  tff(decl_6395, type, seaweed_1: $i > $o).
% 28.89/28.92  tff(decl_6396, type, stramenopile_1: $i > $o).
% 28.89/28.92  tff(decl_6397, type, alveolus_1: $i > $o).
% 28.89/28.92  tff(decl_6398, type, 'Alveolus': $i).
% 28.89/28.92  tff(decl_6399, type, 'In mammalian lungs, the tiny vascularized dead-end sac where gas exchange occurs.': $i).
% 28.89/28.92  tff(decl_6400, type, 'air sac': $i).
% 28.89/28.92  tff(decl_6401, type, alveoli: $i).
% 28.89/28.92  tff(decl_6402, type, alveolus: $i).
% 28.89/28.92  tff(decl_6403, type, simple_squamous_epithelium_1: $i > $o).
% 28.89/28.92  tff(decl_6404, type, proximal_tubule_1: $i > $o).
% 28.89/28.92  tff(decl_6405, type, islets_of_langerhans_1: $i > $o).
% 28.89/28.92  tff(decl_6406, type, endometrium_1: $i > $o).
% 28.89/28.92  tff(decl_6407, type, corpus_luteum_1: $i > $o).
% 28.89/28.92  tff(decl_6408, type, collecting_duct_1: $i > $o).
% 28.89/28.92  tff(decl_6409, type, bronchus_1: $i > $o).
% 28.89/28.92  tff(decl_6410, type, bowmans_capsule_1: $i > $o).
% 28.89/28.92  tff(decl_6411, type, bronchiole_1: $i > $o).
% 28.89/28.92  tff(decl_6412, type, capillary_1: $i > $o).
% 28.89/28.92  tff(decl_6413, type, cervix_1: $i > $o).
% 28.89/28.92  tff(decl_6414, type, choroid_1: $i > $o).
% 28.89/28.92  tff(decl_6415, type, ciliary_body_1: $i > $o).
% 28.89/28.92  tff(decl_6416, type, conjunctiva_1: $i > $o).
% 28.89/28.92  tff(decl_6417, type, cornea_1: $i > $o).
% 28.89/28.92  tff(decl_6418, type, distal_tubule_1: $i > $o).
% 28.89/28.92  tff(decl_6419, type, ejaculatory_duct_1: $i > $o).
% 28.89/28.92  tff(decl_6420, type, endothelium_1: $i > $o).
% 28.89/28.92  tff(decl_6421, type, epidermis_1: $i > $o).
% 28.89/28.92  tff(decl_6422, type, glans_1: $i > $o).
% 28.89/28.92  tff(decl_6423, type, hymen_1: $i > $o).
% 28.89/28.92  tff(decl_6424, type, iris_1: $i > $o).
% 28.89/28.92  tff(decl_6425, type, lacteal_1: $i > $o).
% 28.89/28.92  tff(decl_6426, type, prepuce_1: $i > $o).
% 28.89/28.92  tff(decl_6427, type, renal_cortex_1: $i > $o).
% 28.89/28.92  tff(decl_6428, type, trophoblast_1: $i > $o).
% 28.89/28.92  tff(decl_6429, type, alzheimers_disease_1: $i > $o).
% 28.89/28.92  tff(decl_6430, type, 'Alzheimers-Disease': $i).
% 28.89/28.92  tff(decl_6431, type, 'An age-related dementia that worsens as a person ages. Symptoms include confusion, memory loss, and personality changes.': $i).
% 28.89/28.92  tff(decl_6432, type, 'disease of alzheimers': $i).
% 28.89/28.92  tff(decl_6433, type, 'alzheimers disease': $i).
% 28.89/28.92  tff(decl_6434, type, 'alzheimers-disease': $i).
% 28.89/28.92  tff(decl_6435, type, mental_or_brain_disorder_1: $i > $o).
% 28.89/28.92  tff(decl_6436, type, bipolar_disorder_1: $i > $o).
% 28.89/28.92  tff(decl_6437, type, creutzfeldt_jacob_disease_1: $i > $o).
% 28.89/28.92  tff(decl_6438, type, major_depression_1: $i > $o).
% 28.89/28.92  tff(decl_6439, type, multiple_sclerosis_1: $i > $o).
% 28.89/28.92  tff(decl_6440, type, parkinsons_disease_1: $i > $o).
% 28.89/28.92  tff(decl_6441, type, schizophrenia_1: $i > $o).
% 28.89/28.92  tff(decl_6442, type, alzheimers_disease_process_1: $i > $o).
% 28.89/28.92  tff(decl_6443, type, 'Alzheimers-Disease-Process': $i).
% 28.89/28.92  tff(decl_6444, type, 'Process related to the progression of Alzheimers disease.': $i).
% 28.89/28.92  tff(decl_6445, type, 'alzheimers disease process': $i).
% 28.89/28.92  tff(decl_6446, type, 'alzheimers-disease-process': $i).
% 28.89/28.92  tff(decl_6447, type, disease_process_1: $i > $o).
% 28.89/28.92  tff(decl_6448, type, fn_alzheimers_disease_process_1: $i > $i).
% 28.89/28.92  tff(decl_6449, type, nervous_system_1: $i > $o).
% 28.89/28.92  tff(decl_6450, type, amacrine_cell_1: $i > $o).
% 28.89/28.92  tff(decl_6451, type, 'Amacrine-Cell': $i).
% 28.89/28.92  tff(decl_6452, type, 'Interneurons in the retina that integrate information from other neurons before it is sent to the brain.': $i).
% 28.89/28.92  tff(decl_6453, type, 'amacrine cell': $i).
% 28.89/28.92  tff(decl_6454, type, 'amacrine-cell': $i).
% 28.89/28.92  tff(decl_6455, type, sensory_neuron_1: $i > $o).
% 28.89/28.92  tff(decl_6456, type, bipolar_cell_1: $i > $o).
% 28.89/28.92  tff(decl_6457, type, ganglion_cell_1: $i > $o).
% 28.89/28.92  tff(decl_6458, type, horizontal_cell_1: $i > $o).
% 28.89/28.92  tff(decl_6459, type, american_ginseng_1: $i > $o).
% 28.89/28.92  tff(decl_6460, type, 'American-Ginseng': $i).
% 28.89/28.92  tff(decl_6461, type, 'An herbaceous perennial plant, Panax quinquefolius, native to the eastern US and commonly used in Chinese herbal medicine.': $i).
% 28.89/28.92  tff(decl_6462, type, ginseng: $i).
% 28.89/28.92  tff(decl_6463, type, 'ginseng of american': $i).
% 28.89/28.92  tff(decl_6464, type, 'american ginseng': $i).
% 28.89/28.92  tff(decl_6465, type, 'american-ginseng': $i).
% 28.89/28.92  tff(decl_6466, type, americium_1: $i > $o).
% 28.89/28.92  tff(decl_6467, type, 'Americium': $i).
% 28.89/28.92  tff(decl_6468, type, 'Americium is a metal atom with atomic number 95. It is represented by the symbol Am.': $i).
% 28.89/28.92  tff(decl_6469, type, americium: $i).
% 28.89/28.92  tff(decl_6470, type, am: $i).
% 28.89/28.92  tff(decl_6471, type, fn_americium_3: $i > $i).
% 28.89/28.92  tff(decl_6472, type, fn_americium_4: $i > $i).
% 28.89/28.92  tff(decl_6473, type, fn_americium_5: $i > $i).
% 28.89/28.92  tff(decl_6474, type, fn_americium_9: $i > $i).
% 28.89/28.92  tff(decl_6475, type, fn_americium_10: $i > $i).
% 28.89/28.92  tff(decl_6476, type, fn_americium_11: $i > $i).
% 28.89/28.92  tff(decl_6477, type, fn_americium_12: $i > $i).
% 28.89/28.92  tff(decl_6478, type, "148": $i).
% 28.89/28.92  tff(decl_6479, type, "95": $i).
% 28.89/28.92  tff(decl_6480, type, "9": $i).
% 28.89/28.92  tff(decl_6481, type, "1.3": $i).
% 28.89/28.92  tff(decl_6482, type, "243": $i).
% 28.89/28.92  tff(decl_6483, type, fn_americium_7: $i > $i).
% 28.89/28.92  tff(decl_6484, type, fn_americium_8: $i > $i).
% 28.89/28.92  tff(decl_6485, type, fn_americium_6: $i > $i).
% 28.89/28.92  tff(decl_6486, type, 'Amine': $i).
% 28.89/28.92  tff(decl_6487, type, 'Organic compounds which contain an amino group.': $i).
% 28.89/28.92  tff(decl_6488, type, amine: $i).
% 28.89/28.92  tff(decl_6489, type, base_compound_1: $i > $o).
% 28.89/28.92  tff(decl_6490, type, nitrogenous_compound_1: $i > $o).
% 28.89/28.92  tff(decl_6491, type, fn_amine_1: $i > $i).
% 28.89/28.92  tff(decl_6492, type, 'Amino-Acid': $i).
% 28.89/28.92  tff(decl_6493, type, 'Organic molecule containing both an amino group and a  carboxyl group.  Alpha amino acids (those in which the amino and carboxyl groups are linked to the same  carbon atom) serve as the building blocks of proteins.': $i).
% 28.89/28.92  tff(decl_6494, type, 'The monomer of a polypeptide. An amino acid has a carboxyl group and an amino group, in addition to a side-chain specific to each amino acid.': $i).
% 28.89/28.92  tff(decl_6495, type, 'acid of amino': $i).
% 28.89/28.92  tff(decl_6496, type, 'amino acid': $i).
% 28.89/28.92  tff(decl_6497, type, 'amino-acid': $i).
% 28.89/28.92  tff(decl_6498, type, fn_amino_acid_1: $i > $i).
% 28.89/28.92  tff(decl_6499, type, fn_amino_acid_2: $i > $i).
% 28.89/28.92  tff(decl_6500, type, fn_amino_acid_8: $i > $i).
% 28.89/28.92  tff(decl_6501, type, fn_amino_acid_9: $i > $i).
% 28.89/28.92  tff(decl_6502, type, fn_amino_acid_17: $i > $i).
% 28.89/28.92  tff(decl_6503, type, fn_amino_acid_19: $i > $i).
% 28.89/28.92  tff(decl_6504, type, fn_amino_acid_20: $i > $i).
% 28.89/28.92  tff(decl_6505, type, fn_amino_acid_21: $i > $i).
% 28.89/28.92  tff(decl_6506, type, fn_amino_acid_23: $i > $i).
% 28.89/28.92  tff(decl_6507, type, fn_amino_acid_26: $i > $i).
% 28.89/28.92  tff(decl_6508, type, fn_amino_acid_28: $i > $i).
% 28.89/28.92  tff(decl_6509, type, fn_amino_group_24: $i > $i).
% 28.89/28.92  tff(decl_6510, type, amino_acid_hormone_1: $i > $o).
% 28.89/28.92  tff(decl_6511, type, 'Amino-Acid-Hormone': $i).
% 28.89/28.92  tff(decl_6512, type, 'A hormone derived from a single amino acid.': $i).
% 28.89/28.92  tff(decl_6513, type, 'amino acid hormone role': $i).
% 28.89/28.92  tff(decl_6514, type, 'amino-acid-hormone-role': $i).
% 28.89/28.92  tff(decl_6515, type, 'amino acid hormone': $i).
% 28.89/28.92  tff(decl_6516, type, 'amino-acid-hormone': $i).
% 28.89/28.92  tff(decl_6517, type, hormone_1: $i > $o).
% 28.89/28.92  tff(decl_6518, type, amino_acid_neurotransmitter_1: $i > $o).
% 28.89/28.92  tff(decl_6519, type, 'Amino-Acid-Neurotransmitter': $i).
% 28.89/28.92  tff(decl_6520, type, 'A neurotransmitter comprised of a single amino acid.': $i).
% 28.89/28.92  tff(decl_6521, type, 'amino acid neurotransmitter': $i).
% 28.89/28.92  tff(decl_6522, type, 'amino-acid-neurotransmitter': $i).
% 28.89/28.92  tff(decl_6523, type, amino_acid_sequence_1: $i > $o).
% 28.89/28.92  tff(decl_6524, type, 'Amino-Acid-Sequence': $i).
% 28.89/28.92  tff(decl_6525, type, 'A series of amino acids in a particular order determined by inherited genetic information.': $i).
% 28.89/28.92  tff(decl_6526, type, 'amino acid sequence': $i).
% 28.89/28.92  tff(decl_6527, type, 'amino-acid-sequence': $i).
% 28.89/28.92  tff(decl_6528, type, fn_amino_acid_sequence_1: $i > $i).
% 28.89/28.92  tff(decl_6529, type, fn_amino_acid_sequence_2: $i > $i).
% 28.89/28.92  tff(decl_6530, type, element_0: $i).
% 28.89/28.92  tff(decl_6531, type, amino_acid_0: $i).
% 28.89/28.92  tff(decl_6532, type, fn_sequence_1: $i > $i).
% 28.89/28.92  tff(decl_6533, type, fn_sequence_2: $i > $i).
% 28.89/28.92  tff(decl_6534, type, 'Amino-End': $i).
% 28.89/28.92  tff(decl_6535, type, 'The end of a polypeptide chain with an unbound amine group.': $i).
% 28.89/28.92  tff(decl_6536, type, 'n terminus': $i).
% 28.89/28.92  tff(decl_6537, type, 'n-terminus': $i).
% 28.89/28.92  tff(decl_6538, type, 'amino terminus': $i).
% 28.89/28.92  tff(decl_6539, type, 'amino-terminus': $i).
% 28.89/28.92  tff(decl_6540, type, 'n terminal end': $i).
% 28.89/28.92  tff(decl_6541, type, 'n-terminal-end': $i).
% 28.89/28.92  tff(decl_6542, type, 'amine terminus': $i).
% 28.89/28.92  tff(decl_6543, type, 'amine-terminus': $i).
% 28.89/28.92  tff(decl_6544, type, 'end of amino': $i).
% 28.89/28.92  tff(decl_6545, type, 'amino end': $i).
% 28.89/28.92  tff(decl_6546, type, 'amino-end': $i).
% 28.89/28.92  tff(decl_6547, type, molecular_region_1: $i > $o).
% 28.89/28.92  tff(decl_6548, type, hydrophobic_end_1: $i > $o).
% 28.89/28.92  tff(decl_6549, type, fn_amino_end_1: $i > $i).
% 28.89/28.92  tff(decl_6550, type, 'Amino-Group': $i).
% 28.89/28.92  tff(decl_6551, type, 'In chemistry, a functional group consisting of a nitrogen atom covalently bonded to two hydrogen atoms. In aqueous solutions amino groups act as a base, accepting a hydrogen atom from water and acquiring a +1 charge.': $i).
% 28.89/28.92  tff(decl_6552, type, nh2: $i).
% 28.89/28.92  tff(decl_6553, type, '-nh2': $i).
% 28.89/28.92  tff(decl_6554, type, 'group of amino': $i).
% 28.89/28.92  tff(decl_6555, type, 'amino group': $i).
% 28.89/28.92  tff(decl_6556, type, 'amino-group': $i).
% 28.89/28.92  tff(decl_6557, type, fn_amino_group_1: $i > $i).
% 28.89/28.92  tff(decl_6558, type, fn_amino_group_2: $i > $i).
% 28.89/28.92  tff(decl_6559, type, fn_amino_group_3: $i > $i).
% 28.89/28.92  tff(decl_6560, type, fn_amino_group_4: $i > $i).
% 28.89/28.92  tff(decl_6561, type, fn_amino_group_5: $i > $i).
% 28.89/28.92  tff(decl_6562, type, fn_amino_group_6: $i > $i).
% 28.89/28.92  tff(decl_6563, type, fn_amino_group_7: $i > $i).
% 28.89/28.92  tff(decl_6564, type, fn_amino_group_9: $i > $i).
% 28.89/28.92  tff(decl_6565, type, fn_amino_group_10: $i > $i).
% 28.89/28.92  tff(decl_6566, type, fn_amino_group_11: $i > $i).
% 28.89/28.92  tff(decl_6567, type, fn_amino_group_12: $i > $i).
% 28.89/28.92  tff(decl_6568, type, fn_amino_group_13: $i > $i).
% 28.89/28.92  tff(decl_6569, type, fn_amino_group_14: $i > $i).
% 28.89/28.92  tff(decl_6570, type, fn_amino_group_15: $i > $i).
% 28.89/28.92  tff(decl_6571, type, fn_amino_group_16: $i > $i).
% 28.89/28.92  tff(decl_6572, type, fn_amino_group_17: $i > $i).
% 28.89/28.92  tff(decl_6573, type, fn_amino_group_18: $i > $i).
% 28.89/28.92  tff(decl_6574, type, first_electron_shell_1: $i > $o).
% 28.89/28.92  tff(decl_6575, type, fn_amino_group_26: $i > $i).
% 28.89/28.92  tff(decl_6576, type, fn_amino_group_27: $i > $i).
% 28.89/28.92  tff(decl_6577, type, fn_amino_group_31: $i > $i).
% 28.89/28.92  tff(decl_6578, type, s_orbital_1: $i > $o).
% 28.89/28.92  tff(decl_6579, type, fn_amino_group_34: $i > $i).
% 28.89/28.92  tff(decl_6580, type, fn_first_electron_shell_3: $i > $i).
% 28.89/28.92  tff(decl_6581, type, fn_first_electron_shell_4: $i > $i).
% 28.89/28.92  tff(decl_6582, type, fn_hydrogen_6: $i > $i).
% 28.89/28.92  tff(decl_6583, type, fn_hydrogen_11: $i > $i).
% 28.89/28.92  tff(decl_6584, type, fn_atomic_nucleus_6: $i > $i).
% 28.89/28.92  tff(decl_6585, type, fn_atomic_nucleus_5: $i > $i).
% 28.89/28.92  tff(decl_6586, type, fn_atomic_nucleus_7: $i > $i).
% 28.89/28.92  tff(decl_6587, type, fn_nitrogen_18: $i > $i).
% 28.89/28.92  tff(decl_6588, type, fn_nitrogen_14: $i > $i).
% 28.89/28.92  tff(decl_6589, type, fn_nitrogen_9: $i > $i).
% 28.89/28.92  tff(decl_6590, type, fn_atomic_nucleus_4: $i > $i).
% 28.89/28.92  tff(decl_6591, type, fn_atomic_nucleus_8: $i > $i).
% 28.89/28.92  tff(decl_6592, type, fn_nitrogen_13: $i > $i).
% 28.89/28.92  tff(decl_6593, type, fn_first_electron_shell_5: $i > $i).
% 28.89/28.92  tff(decl_6594, type, fn_hydrogen_12: $i > $i).
% 28.89/28.92  tff(decl_6595, type, fn_hydrogen_16: $i > $i).
% 28.89/28.92  tff(decl_6596, type, fn_hydrogen_14: $i > $i).
% 28.89/28.92  tff(decl_6597, type, fn_atomic_nucleus_3: $i > $i).
% 28.89/28.92  tff(decl_6598, type, fn_hydrogen_10: $i > $i).
% 28.89/28.92  tff(decl_6599, type, fn_atomic_nucleus_1: $i > $i).
% 28.89/28.92  tff(decl_6600, type, fn_hydrogen_17: $i > $i).
% 28.89/28.92  tff(decl_6601, type, fn_atomic_nucleus_2: $i > $i).
% 28.89/28.92  tff(decl_6602, type, fn_hydrogen_15: $i > $i).
% 28.89/28.92  tff(decl_6603, type, fn_hydrogen_13: $i > $i).
% 28.89/28.92  tff(decl_6604, type, fn_atomic_nucleus_9: $i > $i).
% 28.89/28.92  tff(decl_6605, type, fn_nitrogen_11: $i > $i).
% 28.89/28.92  tff(decl_6606, type, fn_nitrogen_16: $i > $i).
% 28.89/28.92  tff(decl_6607, type, fn_nitrogen_10: $i > $i).
% 28.89/28.92  tff(decl_6608, type, fn_nitrogen_12: $i > $i).
% 28.89/28.92  tff(decl_6609, type, fn_amino_group_39: $i > $i).
% 28.89/28.92  tff(decl_6610, type, fn_amino_group_36: $i > $i).
% 28.89/28.92  tff(decl_6611, type, fn_amino_group_37: $i > $i).
% 28.89/28.92  tff(decl_6612, type, fn_amino_group_41: $i > $i).
% 28.89/28.92  tff(decl_6613, type, fn_amino_group_38: $i > $i).
% 28.89/28.92  tff(decl_6614, type, fn_amino_group_40: $i > $i).
% 28.89/28.92  tff(decl_6615, type, amino_peptidase_1: $i > $o).
% 28.89/28.92  tff(decl_6616, type, 'Amino-Peptidase': $i).
% 28.89/28.92  tff(decl_6617, type, 'Enzyme produced by the small intestine which catalyzes reactions involved in the digestion of proteins.': $i).
% 28.89/28.92  tff(decl_6618, type, 'peptidase of amino': $i).
% 28.89/28.92  tff(decl_6619, type, 'amino peptidase': $i).
% 28.89/28.92  tff(decl_6620, type, 'amino-peptidase': $i).
% 28.89/28.92  tff(decl_6621, type, protease_1: $i > $o).
% 28.89/28.92  tff(decl_6622, type, 'Aminoacyl-tRNA': $i).
% 28.89/28.92  tff(decl_6623, type, 'A mature tRNA molecule with the corresponding amino acid attached to its 3-prime end.': $i).
% 28.89/28.92  tff(decl_6624, type, 'activated amino acid': $i).
% 28.89/28.92  tff(decl_6625, type, 'activated-amino-acid': $i).
% 28.89/28.92  tff(decl_6626, type, 'aminoacyl trna': $i).
% 28.89/28.92  tff(decl_6627, type, 'aminoacyl-trna': $i).
% 28.89/28.92  tff(decl_6628, type, trna_1: $i > $o).
% 28.89/28.92  tff(decl_6629, type, initiator_trna_1: $i > $o).
% 28.89/28.92  tff(decl_6630, type, fn_aminoacyl_trna_1: $i > $i).
% 28.89/28.92  tff(decl_6631, type, aminoacyl_trna_synthetase_1: $i > $o).
% 28.89/28.92  tff(decl_6632, type, 'Aminoacyl-tRNA-Synthetase': $i).
% 28.89/28.92  tff(decl_6633, type, 'An enzyme that joins a specific amino acid to its appropriate tRNA molecule.': $i).
% 28.89/28.92  tff(decl_6634, type, 'aminoacyl trna synthetase': $i).
% 28.89/28.92  tff(decl_6635, type, 'aminoacyl-trna synthetase': $i).
% 28.89/28.92  tff(decl_6636, type, 'aminoacyl-trna-synthetase': $i).
% 28.89/28.92  tff(decl_6637, type, ligase_1: $i > $o).
% 28.89/28.92  tff(decl_6638, type, fn_aminoacyl_trna_synthetase_1: $i > $i).
% 28.89/28.92  tff(decl_6639, type, amp_1: $i > $o).
% 28.89/28.92  tff(decl_6640, type, fn_aminoacyl_trna_synthetase_2: $i > $i).
% 28.89/28.92  tff(decl_6641, type, pyrophosphate_1: $i > $o).
% 28.89/28.92  tff(decl_6642, type, fn_aminoacyl_trna_synthetase_3: $i > $i).
% 28.89/28.92  tff(decl_6643, type, break_1: $i > $o).
% 28.89/28.92  tff(decl_6644, type, fn_aminoacyl_trna_synthetase_4: $i > $i).
% 28.89/28.92  tff(decl_6645, type, fn_aminoacyl_trna_synthetase_5: $i > $i).
% 28.89/28.92  tff(decl_6646, type, fn_aminoacyl_trna_synthetase_6: $i > $i).
% 28.89/28.92  tff(decl_6647, type, fn_aminoacyl_trna_synthetase_7: $i > $i).
% 28.89/28.92  tff(decl_6648, type, fn_aminoacyl_trna_synthetase_8: $i > $i).
% 28.89/28.92  tff(decl_6649, type, fn_aminoacyl_trna_synthetase_9: $i > $i).
% 28.89/28.92  tff(decl_6650, type, fn_aminoacyl_trna_synthetase_10: $i > $i).
% 28.89/28.92  tff(decl_6651, type, fn_aminoacyl_trna_synthetase_11: $i > $i).
% 28.89/28.92  tff(decl_6652, type, fn_aminoacyl_trna_synthetase_12: $i > $i).
% 28.89/28.92  tff(decl_6653, type, fn_aminoacyl_trna_synthetase_13: $i > $i).
% 28.89/28.92  tff(decl_6654, type, fn_aminoacyl_trna_synthetase_14: $i > $i).
% 28.89/28.92  tff(decl_6655, type, fn_catalyst_2: $i > $i).
% 28.89/28.92  tff(decl_6656, type, ammonia_1: $i > $o).
% 28.89/28.92  tff(decl_6657, type, 'Ammonia': $i).
% 28.89/28.92  tff(decl_6658, type, 'Ammonia is a small molecule produced as a waste product of protein and nucliec acid breakdown. It is also synthesized by nitrogen-fixing bacteria from atmospheric nitrogen. Ammonia is a colorless gas with a pungent smell,and is very toxic.': $i).
% 28.89/28.92  tff(decl_6659, type, nh3: $i).
% 28.89/28.92  tff(decl_6660, type, ammonium: $i).
% 28.89/28.92  tff(decl_6661, type, ammonia: $i).
% 28.89/28.92  tff(decl_6662, type, covalent_compound_1: $i > $o).
% 28.89/28.92  tff(decl_6663, type, inorganic_molecule_1: $i > $o).
% 28.89/28.92  tff(decl_6664, type, fn_ammonia_1: $i > $i).
% 28.89/28.92  tff(decl_6665, type, fn_ammonia_2: $i > $i).
% 28.89/28.92  tff(decl_6666, type, fn_ammonia_3: $i > $i).
% 28.89/28.92  tff(decl_6667, type, potential_energy_1: $i > $o).
% 28.89/28.92  tff(decl_6668, type, fn_ammonia_5: $i > $i).
% 28.89/28.92  tff(decl_6669, type, fn_ammonia_6: $i > $i).
% 28.89/28.92  tff(decl_6670, type, fn_ammonia_7: $i > $i).
% 28.89/28.92  tff(decl_6671, type, fn_ammonia_8: $i > $i).
% 28.89/28.92  tff(decl_6672, type, fn_ammonia_9: $i > $i).
% 28.89/28.92  tff(decl_6673, type, fn_ammonia_10: $i > $i).
% 28.89/28.92  tff(decl_6674, type, fn_ammonia_11: $i > $i).
% 28.89/28.92  tff(decl_6675, type, fn_ammonia_12: $i > $i).
% 28.89/28.92  tff(decl_6676, type, take_1: $i > $o).
% 28.89/28.92  tff(decl_6677, type, fn_take_1: $i > $i).
% 28.89/28.92  tff(decl_6678, type, fn_obtain_1: $i > $i).
% 28.89/28.92  tff(decl_6679, type, hydrogen_0: $i).
% 28.89/28.92  tff(decl_6680, type, ammonia_gas_1: $i > $o).
% 28.89/28.92  tff(decl_6681, type, 'Ammonia-Gas': $i).
% 28.89/28.92  tff(decl_6682, type, 'Ammonia Gas is the gaseous form of the ammonia. It can be dissolved easily in water.': $i).
% 28.89/28.92  tff(decl_6683, type, 'gas of ammonia': $i).
% 28.89/28.92  tff(decl_6684, type, 'ammonia gas': $i).
% 28.89/28.92  tff(decl_6685, type, 'ammonia-gas': $i).
% 28.89/28.92  tff(decl_6686, type, weak_base_1: $i > $o).
% 28.89/28.92  tff(decl_6687, type, fn_ammonia_gas_1: $i > $i).
% 28.89/28.92  tff(decl_6688, type, ammonification_1: $i > $o).
% 28.89/28.92  tff(decl_6689, type, 'Ammonification': $i).
% 28.89/28.92  tff(decl_6690, type, 'A process of decomposition of organic nitrogen to ammonia.': $i).
% 28.89/28.92  tff(decl_6691, type, 'undergo ammonification': $i).
% 28.89/28.92  tff(decl_6692, type, ammonify: $i).
% 28.89/28.92  tff(decl_6693, type, ammonification: $i).
% 28.89/28.92  tff(decl_6694, type, decomposition_1: $i > $o).
% 28.89/28.92  tff(decl_6695, type, fn_ammonification_1: $i > $i).
% 28.89/28.92  tff(decl_6696, type, fn_ammonification_2: $i > $i).
% 28.89/28.92  tff(decl_6697, type, fn_ammonification_3: $i > $i).
% 28.89/28.92  tff(decl_6698, type, fn_ammonification_4: $i > $i).
% 28.89/28.92  tff(decl_6699, type, fn_ammonification_5: $i > $i).
% 28.89/28.92  tff(decl_6700, type, ammonifying_bacterium_1: $i > $o).
% 28.89/28.92  tff(decl_6701, type, fn_ammonifying_bacterium_9: $i > $i).
% 28.89/28.92  tff(decl_6702, type, fn_ammonifying_bacterium_14: $i > $i).
% 28.89/28.92  tff(decl_6703, type, fn_ammonifying_bacterium_5: $i > $i).
% 28.89/28.92  tff(decl_6704, type, fn_ammonifying_bacterium_10: $i > $i).
% 28.89/28.92  tff(decl_6705, type, fn_decomposition_2: $i > $i).
% 28.89/28.92  tff(decl_6706, type, 'Ammonifying-Bacterium': $i).
% 28.89/28.92  tff(decl_6707, type, 'A bacterium that converts forms of organic nitrogen present in detritus to ammonia. This is an important step of the nitrogen cycle.': $i).
% 28.89/28.92  tff(decl_6708, type, 'ammonifying bacterium': $i).
% 28.89/28.92  tff(decl_6709, type, 'ammonifying-bacterium': $i).
% 28.89/28.92  tff(decl_6710, type, bacterium_1: $i > $o).
% 28.89/28.92  tff(decl_6711, type, fn_ammonifying_bacterium_1: $i > $i).
% 28.89/28.92  tff(decl_6712, type, fn_ammonifying_bacterium_4: $i > $i).
% 28.89/28.92  tff(decl_6713, type, detritivore_1: $i > $o).
% 28.89/28.92  tff(decl_6714, type, fn_ammonifying_bacterium_6: $i > $i).
% 28.89/28.92  tff(decl_6715, type, population_1: $i > $o).
% 28.89/28.92  tff(decl_6716, type, fn_ammonifying_bacterium_7: $i > $i).
% 28.89/28.92  tff(decl_6717, type, biofilm_1: $i > $o).
% 28.89/28.92  tff(decl_6718, type, fn_ammonifying_bacterium_8: $i > $i).
% 28.89/28.92  tff(decl_6719, type, fn_ammonifying_bacterium_11: $i > $i).
% 28.89/28.92  tff(decl_6720, type, fn_ammonifying_bacterium_12: $i > $i).
% 28.89/28.92  tff(decl_6721, type, fn_ammonifying_bacterium_13: $i > $i).
% 28.89/28.92  tff(decl_6722, type, fn_ammonifying_bacterium_15: $i > $i).
% 28.89/28.92  tff(decl_6723, type, chemoheterotroph_1: $i > $o).
% 28.89/28.92  tff(decl_6724, type, fn_ammonifying_bacterium_16: $i > $i).
% 28.89/28.92  tff(decl_6725, type, fn_ammonifying_bacterium_17: $i > $i).
% 28.89/28.92  tff(decl_6726, type, fn_ammonifying_bacterium_18: $i > $i).
% 28.89/28.92  tff(decl_6727, type, fn_ammonifying_bacterium_19: $i > $i).
% 28.89/28.92  tff(decl_6728, type, fn_ammonifying_bacterium_20: $i > $i).
% 28.89/28.92  tff(decl_6729, type, fn_ammonifying_bacterium_21: $i > $i).
% 28.89/28.92  tff(decl_6730, type, fn_ammonifying_bacterium_22: $i > $i).
% 28.89/28.92  tff(decl_6731, type, genotype_1: $i > $o).
% 28.89/28.92  tff(decl_6732, type, fn_ammonifying_bacterium_23: $i > $i).
% 28.89/28.92  tff(decl_6733, type, prokaryotic_ribosome_1: $i > $o).
% 28.89/28.92  tff(decl_6734, type, fn_ammonifying_bacterium_24: $i > $i).
% 28.89/28.92  tff(decl_6735, type, fn_ammonifying_bacterium_25: $i > $i).
% 28.89/28.92  tff(decl_6736, type, fn_ammonifying_bacterium_28: $i > $i).
% 28.89/28.92  tff(decl_6737, type, nucleoid_1: $i > $o).
% 28.89/28.92  tff(decl_6738, type, fn_ammonifying_bacterium_29: $i > $i).
% 28.89/28.92  tff(decl_6739, type, prokaryotic_chromosome_1: $i > $o).
% 28.89/28.92  tff(decl_6740, type, fn_decomposition_3: $i > $i).
% 28.89/28.92  tff(decl_6741, type, fn_decomposition_4: $i > $i).
% 28.89/28.92  tff(decl_6742, type, fn_decomposition_5: $i > $i).
% 28.89/28.92  tff(decl_6743, type, fn_decomposition_6: $i > $i).
% 28.89/28.92  tff(decl_6744, type, fn_chemoheterotroph_4: $i > $i).
% 28.89/28.92  tff(decl_6745, type, fn_detritivore_13: $i > $i).
% 28.89/28.92  tff(decl_6746, type, fn_detritivore_14: $i > $i).
% 28.89/28.92  tff(decl_6747, type, fn_detritivore_12: $i > $i).
% 28.89/28.92  tff(decl_6748, type, fn_decomposition_10: $i > $i).
% 28.89/28.92  tff(decl_6749, type, fn_detritivore_16: $i > $i).
% 28.89/28.92  tff(decl_6750, type, fn_decomposition_14: $i > $i).
% 28.89/28.92  tff(decl_6751, type, fn_heterotroph_2: $i > $i).
% 28.89/28.92  tff(decl_6752, type, fn_decomposition_7: $i > $i).
% 28.89/28.92  tff(decl_6753, type, prokaryote_1: $i > $o).
% 28.89/28.92  tff(decl_6754, type, fn_detritivore_10: $i > $i).
% 28.89/28.92  tff(decl_6755, type, fn_ammonifying_bacterium_3: $i > $i).
% 28.89/28.92  tff(decl_6756, type, fn_organism_6: $i > $i).
% 28.89/28.92  tff(decl_6757, type, fn_ammonifying_bacterium_2: $i > $i).
% 28.89/28.92  tff(decl_6758, type, fn_organism_1: $i > $i).
% 28.89/28.92  tff(decl_6759, type, fn_prokaryote_10: $i > $i).
% 28.89/28.92  tff(decl_6760, type, fn_prokaryote_9: $i > $i).
% 28.89/28.92  tff(decl_6761, type, fn_prokaryote_18: $i > $i).
% 28.89/28.92  tff(decl_6762, type, fn_ammonifying_bacterium_27: $i > $i).
% 28.89/28.92  tff(decl_6763, type, fn_cell_23: $i > $i).
% 28.89/28.92  tff(decl_6764, type, fn_ammonifying_bacterium_26: $i > $i).
% 28.89/28.92  tff(decl_6765, type, fn_cell_10: $i > $i).
% 28.89/28.92  tff(decl_6766, type, fn_cell_26: $i > $i).
% 28.89/28.92  tff(decl_6767, type, fn_cell_4: $i > $i).
% 28.89/28.92  tff(decl_6768, type, fn_cell_22: $i > $i).
% 28.89/28.92  tff(decl_6769, type, fn_cell_11: $i > $i).
% 28.89/28.92  tff(decl_6770, type, fn_organism_3: $i > $i).
% 28.89/28.92  tff(decl_6771, type, fn_bacterium_13: $i > $i).
% 28.89/28.92  tff(decl_6772, type, fn_bacterium_5: $i > $i).
% 28.89/28.92  tff(decl_6773, type, fn_bacterium_14: $i > $i).
% 28.89/28.92  tff(decl_6774, type, fn_prokaryote_12: $i > $i).
% 28.89/28.92  tff(decl_6775, type, fn_bacterium_16: $i > $i).
% 28.89/28.92  tff(decl_6776, type, fn_bacterium_12: $i > $i).
% 28.89/28.92  tff(decl_6777, type, fn_bacterium_15: $i > $i).
% 28.89/28.92  tff(decl_6778, type, 'Ammonite': $i).
% 28.89/28.92  tff(decl_6779, type, 'A member of an extinct group of shelled cephalopods. Ammonites were major marine predators for hundreds of millions of years until their extinction at the end of the Cretaceous Period.': $i).
% 28.89/28.92  tff(decl_6780, type, ammonite: $i).
% 28.89/28.92  tff(decl_6781, type, early_invertebrate_1: $i > $o).
% 28.89/28.92  tff(decl_6782, type, extinct_invertebrate_1: $i > $o).
% 28.89/28.92  tff(decl_6783, type, annelid_1: $i > $o).
% 28.89/28.92  tff(decl_6784, type, arthropod_1: $i > $o).
% 28.89/28.92  tff(decl_6785, type, bryozoan_1: $i > $o).
% 28.89/28.92  tff(decl_6786, type, cnidaria_1: $i > $o).
% 28.89/28.92  tff(decl_6787, type, ctenophora_1: $i > $o).
% 28.89/28.92  tff(decl_6788, type, echinoderm_1: $i > $o).
% 28.89/28.92  tff(decl_6789, type, lophotrochozoan_1: $i > $o).
% 28.89/28.92  tff(decl_6790, type, mollusc_1: $i > $o).
% 28.89/28.92  tff(decl_6791, type, nematode_1: $i > $o).
% 28.89/28.92  tff(decl_6792, type, nemertea_1: $i > $o).
% 28.89/28.92  tff(decl_6793, type, phoronid_1: $i > $o).
% 28.89/28.92  tff(decl_6794, type, platyhelminthes_1: $i > $o).
% 28.89/28.92  tff(decl_6795, type, porifera_1: $i > $o).
% 28.89/28.92  tff(decl_6796, type, rotifer_1: $i > $o).
% 28.89/28.92  tff(decl_6797, type, amniocentesis_1: $i > $o).
% 28.89/28.92  tff(decl_6798, type, 'Amniocentesis': $i).
% 28.89/28.92  tff(decl_6799, type, 'A technique of prenatal diagnosis in which amniotic fluid, obtained by aspiration from a needle inserted into the uterus, is analyzed to detect certain genetic and congenital defects in the fetus.': $i).
% 28.89/28.92  tff(decl_6800, type, amniocentesis: $i).
% 28.89/28.92  tff(decl_6801, type, fetal_testing_1: $i > $o).
% 28.89/28.92  tff(decl_6802, type, chorionic_villus_sampling_1: $i > $o).
% 28.89/28.92  tff(decl_6803, type, fn_amniocentesis_1: $i > $i).
% 28.89/28.92  tff(decl_6804, type, placenta_1: $i > $o).
% 28.89/28.92  tff(decl_6805, type, fn_amniocentesis_2: $i > $i).
% 28.89/28.92  tff(decl_6806, type, fetus_cell_1: $i > $o).
% 28.89/28.92  tff(decl_6807, type, fn_amniocentesis_3: $i > $i).
% 28.89/28.92  tff(decl_6808, type, syringe_1: $i > $o).
% 28.89/28.92  tff(decl_6809, type, fn_amniocentesis_4: $i > $i).
% 28.89/28.92  tff(decl_6810, type, amniotic_fluid_1: $i > $o).
% 28.89/28.92  tff(decl_6811, type, fn_amniocentesis_5: $i > $i).
% 28.89/28.92  tff(decl_6812, type, collecting_1: $i > $o).
% 28.89/28.92  tff(decl_6813, type, fn_collecting_1: $i > $i).
% 28.89/28.92  tff(decl_6814, type, 'Amnion': $i).
% 28.89/28.92  tff(decl_6815, type, 'One of four extraembryonic membranes in an amniote egg. It surrounds a fluid-filled cavity that cushions the embryo.': $i).
% 28.89/28.92  tff(decl_6816, type, amnion: $i).
% 28.89/28.92  tff(decl_6817, type, amniote_1: $i > $o).
% 28.89/28.92  tff(decl_6818, type, 'Amniote': $i).
% 28.89/28.92  tff(decl_6819, type, 'Member of the clade of tetrapod vertebrates named for their unifying synapomorphy, the amniote egg, which contains multiple membrane that protect the developing embryo. Mammals, birds, and reptiles are amniotes.': $i).
% 28.89/28.92  tff(decl_6820, type, amniote: $i).
% 28.89/28.93  tff(decl_6821, type, tetrapod_1: $i > $o).
% 28.89/28.93  tff(decl_6822, type, amphibian_1: $i > $o).
% 28.89/28.93  tff(decl_6823, type, archosaur_1: $i > $o).
% 28.89/28.93  tff(decl_6824, type, amniotic_egg_1: $i > $o).
% 28.89/28.93  tff(decl_6825, type, 'Amniotic-Egg': $i).
% 28.89/28.93  tff(decl_6826, type, 'A shelled egg in which an embryo develops within a fluid-filled amniotic sac and is nourished by yolk. Produced by reptiles (including birds) and egg-laying mammals, it enables them to complete their life cycles on dry land.': $i).
% 28.89/28.93  tff(decl_6827, type, 'amniotic egg': $i).
% 28.89/28.93  tff(decl_6828, type, 'amniotic-egg': $i).
% 28.89/28.93  tff(decl_6829, type, shelled_egg_1: $i > $o).
% 28.89/28.93  tff(decl_6830, type, 'Amniotic-Fluid': $i).
% 28.89/28.93  tff(decl_6831, type, 'The nourishing and protecting liquid contained by the amniotic sac in which the growing embryo is suspended.': $i).
% 28.89/28.93  tff(decl_6832, type, 'amniotic fluid': $i).
% 28.89/28.93  tff(decl_6833, type, 'amniotic-fluid': $i).
% 28.89/28.93  tff(decl_6834, type, extra_cellular_fluid_1: $i > $o).
% 28.89/28.93  tff(decl_6835, type, aqueous_humor_1: $i > $o).
% 28.89/28.93  tff(decl_6836, type, bile_1: $i > $o).
% 28.89/28.93  tff(decl_6837, type, cerebrospinal_fluid_1: $i > $o).
% 28.89/28.93  tff(decl_6838, type, colloid_1: $i > $o).
% 28.89/28.93  tff(decl_6839, type, filtrate_1: $i > $o).
% 28.89/28.93  tff(decl_6840, type, hemolymph_1: $i > $o).
% 28.89/28.93  tff(decl_6841, type, interstitial_fluid_1: $i > $o).
% 28.89/28.93  tff(decl_6842, type, lymph_1: $i > $o).
% 28.89/28.93  tff(decl_6843, type, mucus_1: $i > $o).
% 28.89/28.93  tff(decl_6844, type, plasma_1: $i > $o).
% 28.89/28.93  tff(decl_6845, type, semen_1: $i > $o).
% 28.89/28.93  tff(decl_6846, type, sweat_1: $i > $o).
% 28.89/28.93  tff(decl_6847, type, urine_1: $i > $o).
% 28.89/28.93  tff(decl_6848, type, vitreous_humor_1: $i > $o).
% 28.89/28.93  tff(decl_6849, type, fn_amniotic_fluid_1: $i > $i).
% 28.89/28.93  tff(decl_6850, type, fetus_1: $i > $o).
% 28.89/28.93  tff(decl_6851, type, 'Amoeba': $i).
% 28.89/28.93  tff(decl_6852, type, 'A type of protist characterized by great flexibility and the presence of pseudopodia.': $i).
% 28.89/28.93  tff(decl_6853, type, ameboae: $i).
% 28.89/28.93  tff(decl_6854, type, rhizopods: $i).
% 28.89/28.93  tff(decl_6855, type, rhizopoda: $i).
% 28.89/28.93  tff(decl_6856, type, amoebozoan: $i).
% 28.89/28.93  tff(decl_6857, type, amoeba: $i).
% 28.89/28.93  tff(decl_6858, type, protist_1: $i > $o).
% 28.89/28.93  tff(decl_6859, type, dinoflagellate_1: $i > $o).
% 28.89/28.93  tff(decl_6860, type, fn_amoeba_1: $i > $i).
% 28.89/28.93  tff(decl_6861, type, fn_amoeba_2: $i > $i).
% 28.89/28.93  tff(decl_6862, type, glycoprotein_1: $i > $o).
% 28.89/28.93  tff(decl_6863, type, fn_amoeba_3: $i > $i).
% 28.89/28.93  tff(decl_6864, type, fn_amoeba_4: $i > $i).
% 28.89/28.93  tff(decl_6865, type, fn_amoeba_5: $i > $i).
% 28.89/28.93  tff(decl_6866, type, fn_amoeba_6: $i > $i).
% 28.89/28.93  tff(decl_6867, type, fn_amoeba_7: $i > $i).
% 28.89/28.93  tff(decl_6868, type, fn_amoeba_8: $i > $i).
% 28.89/28.93  tff(decl_6869, type, fn_amoeba_9: $i > $i).
% 28.89/28.93  tff(decl_6870, type, fn_amoeba_10: $i > $i).
% 28.89/28.93  tff(decl_6871, type, fn_amoeba_11: $i > $i).
% 28.89/28.93  tff(decl_6872, type, locomotion_1: $i > $o).
% 28.89/28.93  tff(decl_6873, type, fn_amoeba_12: $i > $i).
% 28.89/28.93  tff(decl_6874, type, pseudopodium_1: $i > $o).
% 28.89/28.93  tff(decl_6875, type, fn_amoeba_13: $i > $i).
% 28.89/28.93  tff(decl_6876, type, fn_amoeba_14: $i > $i).
% 28.89/28.93  tff(decl_6877, type, fn_amoeba_15: $i > $i).
% 28.89/28.93  tff(decl_6878, type, fn_amoeba_16: $i > $i).
% 28.89/28.93  tff(decl_6879, type, fn_amoeba_17: $i > $i).
% 28.89/28.93  tff(decl_6880, type, fn_amoeba_18: $i > $i).
% 28.89/28.93  tff(decl_6881, type, fn_amoeba_19: $i > $i).
% 28.89/28.93  tff(decl_6882, type, fn_amoeba_20: $i > $i).
% 28.89/28.93  tff(decl_6883, type, fn_amoeba_21: $i > $i).
% 28.89/28.93  tff(decl_6884, type, fn_amoeba_22: $i > $i).
% 28.89/28.93  tff(decl_6885, type, fn_amoeba_23: $i > $i).
% 28.89/28.93  tff(decl_6886, type, endergonic_reaction_1: $i > $o).
% 28.89/28.93  tff(decl_6887, type, fn_amoeba_24: $i > $i).
% 28.89/28.93  tff(decl_6888, type, fn_amoeba_25: $i > $i).
% 28.89/28.93  tff(decl_6889, type, fn_amoeba_26: $i > $i).
% 28.89/28.93  tff(decl_6890, type, fn_amoeba_27: $i > $i).
% 28.89/28.93  tff(decl_6891, type, fn_amoeba_28: $i > $i).
% 28.89/28.93  tff(decl_6892, type, fn_amoeba_29: $i > $i).
% 28.89/28.93  tff(decl_6893, type, fn_amoeba_30: $i > $i).
% 28.89/28.93  tff(decl_6894, type, fn_amoeba_31: $i > $i).
% 28.89/28.93  tff(decl_6895, type, fn_amoeba_32: $i > $i).
% 28.89/28.93  tff(decl_6896, type, fn_amoeba_33: $i > $i).
% 28.89/28.93  tff(decl_6897, type, fn_amoeba_34: $i > $i).
% 28.89/28.93  tff(decl_6898, type, synthesis_of_endomembranous_system_membrane_1: $i > $o).
% 28.89/28.93  tff(decl_6899, type, fn_amoeba_35: $i > $i).
% 28.89/28.93  tff(decl_6900, type, fn_amoeba_40: $i > $i).
% 28.89/28.93  tff(decl_6901, type, fn_amoeba_41: $i > $i).
% 28.89/28.93  tff(decl_6902, type, nuclear_lamina_1: $i > $o).
% 28.89/28.93  tff(decl_6903, type, fn_amoeba_42: $i > $i).
% 28.89/28.93  tff(decl_6904, type, phagocytosis_1: $i > $o).
% 28.89/28.93  tff(decl_6905, type, fn_amoeba_43: $i > $i).
% 28.89/28.93  tff(decl_6906, type, fusion_1: $i > $o).
% 28.89/28.93  tff(decl_6907, type, fn_amoeba_44: $i > $i).
% 28.89/28.93  tff(decl_6908, type, fn_amoeba_45: $i > $i).
% 28.89/28.93  tff(decl_6909, type, fn_amoeba_46: $i > $i).
% 28.89/28.93  tff(decl_6910, type, fn_amoeba_47: $i > $i).
% 28.89/28.93  tff(decl_6911, type, fn_amoeba_48: $i > $i).
% 28.89/28.93  tff(decl_6912, type, fn_amoeba_49: $i > $i).
% 28.89/28.93  tff(decl_6913, type, fn_amoeba_50: $i > $i).
% 28.89/28.93  tff(decl_6914, type, intracellular_digestion_1: $i > $o).
% 28.89/28.93  tff(decl_6915, type, fn_amoeba_51: $i > $i).
% 28.89/28.93  tff(decl_6916, type, fn_amoeba_52: $i > $i).
% 28.89/28.93  tff(decl_6917, type, fn_amoeba_53: $i > $i).
% 28.89/28.93  tff(decl_6918, type, food_vacuole_1: $i > $o).
% 28.89/28.93  tff(decl_6919, type, fn_amoeba_54: $i > $i).
% 28.89/28.93  tff(decl_6920, type, fn_amoeba_55: $i > $i).
% 28.89/28.93  tff(decl_6921, type, fn_phagocytosis_76: $i > $i).
% 28.89/28.93  tff(decl_6922, type, fn_phagocytosis_77: $i > $i).
% 28.89/28.93  tff(decl_6923, type, fn_phagocytosis_88: $i > $i).
% 28.89/28.93  tff(decl_6924, type, fn_phagocytosis_66: $i > $i).
% 28.89/28.93  tff(decl_6925, type, fn_phagocytosis_82: $i > $i).
% 28.89/28.93  tff(decl_6926, type, fn_phagocytosis_79: $i > $i).
% 28.89/28.93  tff(decl_6927, type, fn_phagocytosis_81: $i > $i).
% 28.89/28.93  tff(decl_6928, type, fn_plasma_membrane_6: $i > $i).
% 28.89/28.93  tff(decl_6929, type, fn_exchange_3: $i > $i).
% 28.89/28.93  tff(decl_6930, type, fn_exchange_4: $i > $i).
% 28.89/28.93  tff(decl_6931, type, fn_transport_protein_17: $i > $i).
% 28.89/28.93  tff(decl_6932, type, fn_transport_protein_14: $i > $i).
% 28.89/28.93  tff(decl_6933, type, fn_transmembrane_protein_6: $i > $i).
% 28.89/28.93  tff(decl_6934, type, fn_plasma_membrane_66: $i > $i).
% 28.89/28.93  tff(decl_6935, type, fn_transport_protein_18: $i > $i).
% 28.89/28.93  tff(decl_6936, type, fn_plasma_membrane_57: $i > $i).
% 28.89/28.93  tff(decl_6937, type, fn_plasma_membrane_65: $i > $i).
% 28.89/28.93  tff(decl_6938, type, fn_plasma_membrane_74: $i > $i).
% 28.89/28.93  tff(decl_6939, type, fn_integral_protein_9: $i > $i).
% 28.89/28.93  tff(decl_6940, type, fn_plasma_membrane_34: $i > $i).
% 28.89/28.93  tff(decl_6941, type, fn_synthesis_of_endomembranous_system_membrane_52: $i > $i).
% 28.89/28.93  tff(decl_6942, type, fn_phagocytosis_19: $i > $i).
% 28.89/28.93  tff(decl_6943, type, fn_synthesis_of_endomembranous_system_membrane_59: $i > $i).
% 28.89/28.93  tff(decl_6944, type, fn_rough_endoplasmic_reticulum_68: $i > $i).
% 28.89/28.93  tff(decl_6945, type, fn_synthesis_of_endomembranous_system_membrane_60: $i > $i).
% 28.89/28.93  tff(decl_6946, type, fn_rough_endoplasmic_reticulum_21: $i > $i).
% 28.89/28.93  tff(decl_6947, type, fn_phagocytosis_12: $i > $i).
% 28.89/28.93  tff(decl_6948, type, fn_rough_endoplasmic_reticulum_28: $i > $i).
% 28.89/28.93  tff(decl_6949, type, fn_cytoplasmic_side_1: $i > $i).
% 28.89/28.93  tff(decl_6950, type, fn_phagocytosis_71: $i > $i).
% 28.89/28.93  tff(decl_6951, type, fn_locomotion_1: $i > $i).
% 28.89/28.93  tff(decl_6952, type, fn_phagocytosis_70: $i > $i).
% 28.89/28.93  tff(decl_6953, type, fn_protist_cell_25: $i > $i).
% 28.89/28.93  tff(decl_6954, type, fn_amoeba_39: $i > $i).
% 28.89/28.93  tff(decl_6955, type, fn_amoeba_36: $i > $i).
% 28.89/28.93  tff(decl_6956, type, fn_protist_cell_9: $i > $i).
% 28.89/28.93  tff(decl_6957, type, fn_amoeba_37: $i > $i).
% 28.89/28.93  tff(decl_6958, type, fn_protist_cell_13: $i > $i).
% 28.89/28.93  tff(decl_6959, type, fn_amoeba_38: $i > $i).
% 28.89/28.93  tff(decl_6960, type, fn_protist_cell_12: $i > $i).
% 28.89/28.93  tff(decl_6961, type, fn_protist_cell_32: $i > $i).
% 28.89/28.93  tff(decl_6962, type, fn_protist_cell_11: $i > $i).
% 28.89/28.93  tff(decl_6963, type, fn_protist_cell_35: $i > $i).
% 28.89/28.93  tff(decl_6964, type, fn_protist_cell_33: $i > $i).
% 28.89/28.93  tff(decl_6965, type, fn_protist_cell_31: $i > $i).
% 28.89/28.93  tff(decl_6966, type, fn_protist_cell_34: $i > $i).
% 28.89/28.93  tff(decl_6967, type, fn_protist_cell_16: $i > $i).
% 28.89/28.93  tff(decl_6968, type, fn_protist_cell_17: $i > $i).
% 28.89/28.93  tff(decl_6969, type, fn_protist_cell_21: $i > $i).
% 28.89/28.93  tff(decl_6970, type, fn_protist_cell_26: $i > $i).
% 28.89/28.93  tff(decl_6971, type, fn_protist_cell_27: $i > $i).
% 28.89/28.93  tff(decl_6972, type, fn_protist_cell_10: $i > $i).
% 28.89/28.93  tff(decl_6973, type, fn_protist_cell_24: $i > $i).
% 28.89/28.93  tff(decl_6974, type, fn_protist_cell_19: $i > $i).
% 28.89/28.93  tff(decl_6975, type, fn_protist_cell_15: $i > $i).
% 28.89/28.93  tff(decl_6976, type, fn_protist_cell_18: $i > $i).
% 28.89/28.93  tff(decl_6977, type, fn_protist_cell_22: $i > $i).
% 28.89/28.93  tff(decl_6978, type, fn_protist_cell_28: $i > $i).
% 28.89/28.93  tff(decl_6979, type, fn_protist_cell_14: $i > $i).
% 28.89/28.93  tff(decl_6980, type, fn_protist_cell_23: $i > $i).
% 28.89/28.93  tff(decl_6981, type, fn_protist_cell_29: $i > $i).
% 28.89/28.93  tff(decl_6982, type, amoebocyte_1: $i > $o).
% 28.89/28.93  tff(decl_6983, type, 'Amoebocyte': $i).
% 28.89/28.93  tff(decl_6984, type, 'An animal cell that moves with pseudopodia similar to those of an amoeba. Depending on the species, an amoebocyte may be involved in the digestion and circulation of nutrients, collection of wastes, immune function, or differentiation to whatever cell type is needed at a particular moment.': $i).
% 28.89/28.93  tff(decl_6985, type, amoebocyte: $i).
% 28.89/28.93  tff(decl_6986, type, animal_development_cell_1: $i > $o).
% 28.89/28.93  tff(decl_6987, type, 'AMP': $i).
% 28.89/28.93  tff(decl_6988, type, 'A nucleotide made of one phosphate group, the sugar ribose, and adenosine.  AMP can be reversibly converted ADP and ATP by adding phosphate groups.': $i).
% 28.89/28.93  tff(decl_6989, type, 'adenosine monophosphate': $i).
% 28.89/28.93  tff(decl_6990, type, 'adenosine-monophosphate': $i).
% 28.89/28.93  tff(decl_6991, type, 'adenosine mono phosphate': $i).
% 28.89/28.93  tff(decl_6992, type, 'adenosine-mono-phosphate': $i).
% 28.89/28.93  tff(decl_6993, type, 'five prime adenylic acid': $i).
% 28.89/28.93  tff(decl_6994, type, 'five-prime-adenylic-acid': $i).
% 28.89/28.93  tff(decl_6995, type, amp: $i).
% 28.89/28.93  tff(decl_6996, type, fn_amp_4: $i > $i).
% 28.89/28.93  tff(decl_6997, type, fn_amp_5: $i > $i).
% 28.89/28.93  tff(decl_6998, type, fn_amp_6: $i > $i).
% 28.89/28.93  tff(decl_6999, type, fn_amp_7: $i > $i).
% 28.89/28.93  tff(decl_7000, type, fn_amp_8: $i > $i).
% 28.89/28.93  tff(decl_7001, type, fn_amp_9: $i > $i).
% 28.89/28.93  tff(decl_7002, type, fn_amp_10: $i > $i).
% 28.89/28.93  tff(decl_7003, type, fn_amp_11: $i > $i).
% 28.89/28.93  tff(decl_7004, type, fn_amp_12: $i > $i).
% 28.89/28.93  tff(decl_7005, type, fn_amp_13: $i > $i).
% 28.89/28.93  tff(decl_7006, type, fn_amp_14: $i > $i).
% 28.89/28.93  tff(decl_7007, type, fn_amp_15: $i > $i).
% 28.89/28.93  tff(decl_7008, type, fn_amp_16: $i > $i).
% 28.89/28.93  tff(decl_7009, type, fn_amp_17: $i > $i).
% 28.89/28.93  tff(decl_7010, type, fn_amp_18: $i > $i).
% 28.89/28.93  tff(decl_7011, type, fn_amp_19: $i > $i).
% 28.89/28.93  tff(decl_7012, type, fn_amp_20: $i > $i).
% 28.89/28.93  tff(decl_7013, type, fn_amp_21: $i > $i).
% 28.89/28.93  tff(decl_7014, type, fn_amp_22: $i > $i).
% 28.89/28.93  tff(decl_7015, type, fn_amp_23: $i > $i).
% 28.89/28.93  tff(decl_7016, type, fn_amp_24: $i > $i).
% 28.89/28.93  tff(decl_7017, type, fn_amp_25: $i > $i).
% 28.89/28.93  tff(decl_7018, type, fn_amp_26: $i > $i).
% 28.89/28.93  tff(decl_7019, type, fn_amp_27: $i > $i).
% 28.89/28.93  tff(decl_7020, type, fn_amp_28: $i > $i).
% 28.89/28.93  tff(decl_7021, type, fn_amp_29: $i > $i).
% 28.89/28.93  tff(decl_7022, type, fn_amp_30: $i > $i).
% 28.89/28.93  tff(decl_7023, type, fn_amp_31: $i > $i).
% 28.89/28.93  tff(decl_7024, type, fn_amp_32: $i > $i).
% 28.89/28.93  tff(decl_7025, type, fn_amp_33: $i > $i).
% 28.89/28.93  tff(decl_7026, type, fn_amp_34: $i > $i).
% 28.89/28.93  tff(decl_7027, type, fn_amp_35: $i > $i).
% 28.89/28.93  tff(decl_7028, type, fn_amp_36: $i > $i).
% 28.89/28.93  tff(decl_7029, type, fn_amp_37: $i > $i).
% 28.89/28.93  tff(decl_7030, type, fn_amp_38: $i > $i).
% 28.89/28.93  tff(decl_7031, type, fn_amp_39: $i > $i).
% 28.89/28.93  tff(decl_7032, type, fn_amp_40: $i > $i).
% 28.89/28.93  tff(decl_7033, type, fn_amp_41: $i > $i).
% 28.89/28.93  tff(decl_7034, type, fn_amp_42: $i > $i).
% 28.89/28.93  tff(decl_7035, type, fn_amp_43: $i > $i).
% 28.89/28.93  tff(decl_7036, type, fn_amp_44: $i > $i).
% 28.89/28.93  tff(decl_7037, type, fn_amp_45: $i > $i).
% 28.89/28.93  tff(decl_7038, type, fn_amp_46: $i > $i).
% 28.89/28.93  tff(decl_7039, type, fn_amp_47: $i > $i).
% 28.89/28.93  tff(decl_7040, type, fn_amp_48: $i > $i).
% 28.89/28.93  tff(decl_7041, type, fn_amp_49: $i > $i).
% 28.89/28.93  tff(decl_7042, type, fn_amp_50: $i > $i).
% 28.89/28.93  tff(decl_7043, type, fn_amp_51: $i > $i).
% 28.89/28.93  tff(decl_7044, type, fn_amp_52: $i > $i).
% 28.89/28.93  tff(decl_7045, type, fn_amp_53: $i > $i).
% 28.89/28.93  tff(decl_7046, type, fn_amp_54: $i > $i).
% 28.89/28.93  tff(decl_7047, type, fn_amp_55: $i > $i).
% 28.89/28.93  tff(decl_7048, type, fn_amp_56: $i > $i).
% 28.89/28.93  tff(decl_7049, type, fn_amp_57: $i > $i).
% 28.89/28.93  tff(decl_7050, type, fn_amp_58: $i > $i).
% 28.89/28.93  tff(decl_7051, type, fn_amp_59: $i > $i).
% 28.89/28.93  tff(decl_7052, type, fn_amp_60: $i > $i).
% 28.89/28.93  tff(decl_7053, type, fn_amp_61: $i > $i).
% 28.89/28.93  tff(decl_7054, type, fn_amp_62: $i > $i).
% 28.89/28.93  tff(decl_7055, type, fn_amp_63: $i > $i).
% 28.89/28.93  tff(decl_7056, type, fn_amp_64: $i > $i).
% 28.89/28.93  tff(decl_7057, type, fn_amp_65: $i > $i).
% 28.89/28.93  tff(decl_7058, type, fn_amp_66: $i > $i).
% 28.89/28.93  tff(decl_7059, type, fn_amp_67: $i > $i).
% 28.89/28.93  tff(decl_7060, type, fn_amp_68: $i > $i).
% 28.89/28.93  tff(decl_7061, type, fn_amp_69: $i > $i).
% 28.89/28.93  tff(decl_7062, type, fn_amp_70: $i > $i).
% 28.89/28.93  tff(decl_7063, type, fn_amp_71: $i > $i).
% 28.89/28.93  tff(decl_7064, type, fn_amp_72: $i > $i).
% 28.89/28.93  tff(decl_7065, type, fn_amp_73: $i > $i).
% 28.89/28.93  tff(decl_7066, type, fn_amp_74: $i > $i).
% 28.89/28.93  tff(decl_7067, type, fn_amp_75: $i > $i).
% 28.89/28.93  tff(decl_7068, type, fn_amp_76: $i > $i).
% 28.89/28.93  tff(decl_7069, type, fn_amp_79: $i > $i).
% 28.89/28.93  tff(decl_7070, type, fn_amp_80: $i > $i).
% 28.89/28.93  tff(decl_7071, type, fn_phosphate_group_36: $i > $i).
% 28.89/28.93  tff(decl_7072, type, fn_phosphate_group_13: $i > $i).
% 28.89/28.93  tff(decl_7073, type, fn_phosphate_group_16: $i > $i).
% 28.89/28.93  tff(decl_7074, type, fn_phosphate_group_40: $i > $i).
% 28.89/28.93  tff(decl_7075, type, fn_phosphate_group_14: $i > $i).
% 28.89/28.93  tff(decl_7076, type, fn_phosphate_group_11: $i > $i).
% 28.89/28.93  tff(decl_7077, type, fn_first_electron_shell_7: $i > $i).
% 28.89/28.93  tff(decl_7078, type, 'A2': $i).
% 28.89/28.93  tff(decl_7079, type, fn_nucleoside_monophosphate_7: $i > $i).
% 28.89/28.93  tff(decl_7080, type, fn_nucleoside_monophosphate_5: $i > $i).
% 28.89/28.93  tff(decl_7081, type, fn_nucleoside_monophosphate_62: $i > $i).
% 28.89/28.93  tff(decl_7082, type, fn_nucleoside_monophosphate_9: $i > $i).
% 28.89/28.93  tff(decl_7083, type, fn_nucleoside_monophosphate_63: $i > $i).
% 28.89/28.93  tff(decl_7084, type, fn_nucleoside_monophosphate_8: $i > $i).
% 28.89/28.93  tff(decl_7085, type, fn_nucleoside_monophosphate_19: $i > $i).
% 28.89/28.93  tff(decl_7086, type, fn_nucleoside_monophosphate_6: $i > $i).
% 28.89/28.93  tff(decl_7087, type, fn_nucleoside_monophosphate_33: $i > $i).
% 28.89/28.93  tff(decl_7088, type, fn_nucleoside_monophosphate_4: $i > $i).
% 28.89/28.93  tff(decl_7089, type, fn_nucleoside_monophosphate_3: $i > $i).
% 28.89/28.93  tff(decl_7090, type, fn_nucleoside_monophosphate_60: $i > $i).
% 28.89/28.93  tff(decl_7091, type, fn_nucleoside_monophosphate_15: $i > $i).
% 28.89/28.93  tff(decl_7092, type, fn_nucleoside_monophosphate_11: $i > $i).
% 28.89/28.93  tff(decl_7093, type, fn_nucleoside_monophosphate_65: $i > $i).
% 28.89/28.93  tff(decl_7094, type, fn_nucleoside_monophosphate_56: $i > $i).
% 28.89/28.93  tff(decl_7095, type, fn_nucleoside_monophosphate_39: $i > $i).
% 28.89/28.93  tff(decl_7096, type, fn_nucleoside_monophosphate_10: $i > $i).
% 28.89/28.93  tff(decl_7097, type, fn_nucleoside_monophosphate_55: $i > $i).
% 28.89/28.93  tff(decl_7098, type, fn_nucleoside_monophosphate_54: $i > $i).
% 28.89/28.93  tff(decl_7099, type, fn_amp_77: $i > $i).
% 28.89/28.93  tff(decl_7100, type, fn_nucleoside_monophosphate_36: $i > $i).
% 28.89/28.93  tff(decl_7101, type, fn_amp_78: $i > $i).
% 28.89/28.93  tff(decl_7102, type, fn_nucleoside_monophosphate_35: $i > $i).
% 28.89/28.93  tff(decl_7103, type, fn_nucleoside_monophosphate_64: $i > $i).
% 28.89/28.93  tff(decl_7104, type, fn_nucleoside_monophosphate_26: $i > $i).
% 28.89/28.93  tff(decl_7105, type, fn_nucleoside_monophosphate_30: $i > $i).
% 28.89/28.93  tff(decl_7106, type, fn_nucleoside_monophosphate_23: $i > $i).
% 28.89/28.93  tff(decl_7107, type, fn_nucleoside_monophosphate_57: $i > $i).
% 28.89/28.93  tff(decl_7108, type, fn_nucleoside_monophosphate_28: $i > $i).
% 28.89/28.93  tff(decl_7109, type, fn_nucleoside_monophosphate_22: $i > $i).
% 28.89/28.93  tff(decl_7110, type, fn_nucleoside_monophosphate_14: $i > $i).
% 28.89/28.93  tff(decl_7111, type, fn_nucleoside_monophosphate_13: $i > $i).
% 28.89/28.93  tff(decl_7112, type, fn_nucleoside_monophosphate_12: $i > $i).
% 28.89/28.93  tff(decl_7113, type, fn_nucleoside_monophosphate_17: $i > $i).
% 28.89/28.93  tff(decl_7114, type, fn_nucleoside_monophosphate_21: $i > $i).
% 28.89/28.93  tff(decl_7115, type, fn_nucleoside_monophosphate_29: $i > $i).
% 28.89/28.93  tff(decl_7116, type, fn_nucleoside_monophosphate_18: $i > $i).
% 28.89/28.93  tff(decl_7117, type, fn_nucleoside_monophosphate_32: $i > $i).
% 28.89/28.93  tff(decl_7118, type, fn_nucleoside_monophosphate_61: $i > $i).
% 28.89/28.93  tff(decl_7119, type, fn_nucleoside_monophosphate_42: $i > $i).
% 28.89/28.93  tff(decl_7120, type, fn_nucleotide_3: $i > $i).
% 28.89/28.93  tff(decl_7121, type, fn_nucleoside_monophosphate_25: $i > $i).
% 28.89/28.93  tff(decl_7122, type, fn_nucleoside_monophosphate_34: $i > $i).
% 28.89/28.93  tff(decl_7123, type, fn_nucleoside_monophosphate_20: $i > $i).
% 28.89/28.93  tff(decl_7124, type, fn_nucleoside_monophosphate_52: $i > $i).
% 28.89/28.93  tff(decl_7125, type, fn_nucleoside_monophosphate_16: $i > $i).
% 28.89/28.93  tff(decl_7126, type, fn_nucleoside_monophosphate_24: $i > $i).
% 28.89/28.93  tff(decl_7127, type, fn_nucleoside_monophosphate_27: $i > $i).
% 28.89/28.93  tff(decl_7128, type, fn_nucleotide_35: $i > $i).
% 28.89/28.93  tff(decl_7129, type, fn_nucleotide_29: $i > $i).
% 28.89/28.93  tff(decl_7130, type, fn_nucleotide_23: $i > $i).
% 28.89/28.93  tff(decl_7131, type, fn_amp_3: $i > $i).
% 28.89/28.93  tff(decl_7132, type, fn_amp_2: $i > $i).
% 28.89/28.93  tff(decl_7133, type, fn_amp_1: $i > $i).
% 28.89/28.93  tff(decl_7134, type, 'Amphibian': $i).
% 28.89/28.93  tff(decl_7135, type, 'An ectothermic tetrapod vertebrate of the class Amphibia, including frogs, toads, salamanders, and caecilians.': $i).
% 28.89/28.93  tff(decl_7136, type, amphibian: $i).
% 28.89/28.93  tff(decl_7137, type, amphipathic_molecule_1: $i > $o).
% 28.89/28.93  tff(decl_7138, type, 'Amphipathic-Molecule': $i).
% 28.89/28.93  tff(decl_7139, type, 'Molecules which contain both hydrophilic and hydrophobic region.': $i).
% 28.89/28.93  tff(decl_7140, type, 'amphiphile,': $i).
% 28.89/28.93  tff(decl_7141, type, 'amphiplilic molecule': $i).
% 28.89/28.93  tff(decl_7142, type, 'amphiplilic-molecule': $i).
% 28.89/28.93  tff(decl_7143, type, amphiphile: $i).
% 28.89/28.93  tff(decl_7144, type, amphipathic: $i).
% 28.89/28.93  tff(decl_7145, type, 'amphipathic molecule': $i).
% 28.89/28.93  tff(decl_7146, type, 'amphipathic-molecule': $i).
% 28.89/28.93  tff(decl_7147, type, fn_amphipathic_molecule_1: $i > $i).
% 28.89/28.93  tff(decl_7148, type, fn_amphipathic_molecule_2: $i > $i).
% 28.89/28.93  tff(decl_7149, type, fn_amphipathic_molecule_3: $i > $i).
% 28.89/28.93  tff(decl_7150, type, fn_amphipathic_molecule_4: $i > $i).
% 28.89/28.93  tff(decl_7151, type, fn_amphipathic_molecule_5: $i > $i).
% 28.89/28.93  tff(decl_7152, type, fn_amphipathic_molecule_6: $i > $i).
% 28.89/28.93  tff(decl_7153, type, fn_amphipathic_molecule_7: $i > $i).
% 28.89/28.93  tff(decl_7154, type, fn_amphipathic_molecule_8: $i > $i).
% 28.89/28.93  tff(decl_7155, type, fn_hydrophobic_region_2: $i > $i).
% 28.89/28.93  tff(decl_7156, type, fn_hydrophilic_region_2: $i > $i).
% 28.89/28.93  tff(decl_7157, type, fn_amphipathic_molecule_9: $i > $i).
% 28.89/28.93  tff(decl_7158, type, fn_amphipathic_molecule_10: $i > $i).
% 28.89/28.93  tff(decl_7159, type, amphoteric_substance_1: $i > $o).
% 28.89/28.93  tff(decl_7160, type, 'Amphoteric-Substance': $i).
% 28.89/28.93  tff(decl_7161, type, 'A substance capable of behaving as either an acid or a base.': $i).
% 28.89/28.93  tff(decl_7162, type, 'amphoteric substance': $i).
% 28.89/28.93  tff(decl_7163, type, 'amphoteric-substance': $i).
% 28.89/28.93  tff(decl_7164, type, ampicillin_1: $i > $o).
% 28.89/28.93  tff(decl_7165, type, 'Ampicillin': $i).
% 28.89/28.93  tff(decl_7166, type, 'An antibiotic that has been used extensively to treat bacterial infections.': $i).
% 28.89/28.93  tff(decl_7167, type, ampicillin: $i).
% 28.89/28.93  tff(decl_7168, type, antimicrobial_protein_1: $i > $o).
% 28.89/28.93  tff(decl_7169, type, erythromycin_1: $i > $o).
% 28.89/28.93  tff(decl_7170, type, penicillin_1: $i > $o).
% 28.89/28.93  tff(decl_7171, type, tetracycline_1: $i > $o).
% 28.89/28.93  tff(decl_7172, type, vancomycin_1: $i > $o).
% 28.89/28.93  tff(decl_7173, type, amplification_1: $i > $o).
% 28.89/28.93  tff(decl_7174, type, 'Amplification': $i).
% 28.89/28.93  tff(decl_7175, type, 'The increase in strength of a stimulus during transduction.': $i).
% 28.89/28.93  tff(decl_7176, type, amplify: $i).
% 28.89/28.93  tff(decl_7177, type, amplification: $i).
% 28.89/28.93  tff(decl_7178, type, nerve_related_intercellular_process_1: $i > $o).
% 28.89/28.93  tff(decl_7179, type, amygdala_1: $i > $o).
% 28.89/28.93  tff(decl_7180, type, 'Amygdala': $i).
% 28.89/28.93  tff(decl_7181, type, 'A group of neurons in the temporal lobe of the vertebrate brain, which play a role in memory and emotional responses. The amygdala is part of the limbic system.': $i).
% 28.89/28.93  tff(decl_7182, type, amygdala: $i).
% 28.89/28.93  tff(decl_7183, type, cerebrum_1: $i > $o).
% 28.89/28.93  tff(decl_7184, type, basal_nuclei_1: $i > $o).
% 28.89/28.93  tff(decl_7185, type, brainstem_1: $i > $o).
% 28.89/28.93  tff(decl_7186, type, breathing_control_center_1: $i > $o).
% 28.89/28.93  tff(decl_7187, type, cerebellum_1: $i > $o).
% 28.89/28.93  tff(decl_7188, type, cerebral_cortex_1: $i > $o).
% 28.89/28.93  tff(decl_7189, type, cerebral_hemisphere_1: $i > $o).
% 28.89/28.93  tff(decl_7190, type, corpus_callosum_1: $i > $o).
% 28.89/28.93  tff(decl_7191, type, amylase_1: $i > $o).
% 28.89/28.93  tff(decl_7192, type, 'Amylase': $i).
% 28.89/28.93  tff(decl_7193, type, 'Amylase is an enzyme capable of hydrolizing glycosidic linkages between glucose monomers in starch.': $i).
% 28.89/28.93  tff(decl_7194, type, amylase: $i).
% 28.89/28.93  tff(decl_7195, type, digestive_enzyme_1: $i > $o).
% 28.89/28.93  tff(decl_7196, type, fn_amylase_1: $i > $i).
% 28.89/28.93  tff(decl_7197, type, amylopectin_1: $i > $o).
% 28.89/28.93  tff(decl_7198, type, 'Amylopectin': $i).
% 28.89/28.93  tff(decl_7199, type, 'Amylopectin, a more complex starch, is a branched polymer with 1-6 linkages at the branch points.': $i).
% 28.89/28.93  tff(decl_7200, type, amylopectin: $i).
% 28.89/28.93  tff(decl_7201, type, starch_1: $i > $o).
% 28.89/28.93  tff(decl_7202, type, fn_amylopectin_2: $i > $i).
% 28.89/28.93  tff(decl_7203, type, fn_amylopectin_3: $i > $i).
% 28.89/28.93  tff(decl_7204, type, fn_amylopectin_5: $i > $i).
% 28.89/28.93  tff(decl_7205, type, fn_amylopectin_6: $i > $i).
% 28.89/28.93  tff(decl_7206, type, fn_amylopectin_7: $i > $i).
% 28.89/28.93  tff(decl_7207, type, fn_amylopectin_8: $i > $i).
% 28.89/28.93  tff(decl_7208, type, fn_amylopectin_9: $i > $i).
% 28.89/28.93  tff(decl_7209, type, fn_amylopectin_10: $i > $i).
% 28.89/28.93  tff(decl_7210, type, fn_amylopectin_12: $i > $i).
% 28.89/28.93  tff(decl_7211, type, fn_amylopectin_13: $i > $i).
% 28.89/28.93  tff(decl_7212, type, fn_amylopectin_14: $i > $i).
% 28.89/28.93  tff(decl_7213, type, fn_amylopectin_15: $i > $i).
% 28.89/28.93  tff(decl_7214, type, fn_amylopectin_16: $i > $i).
% 28.89/28.93  tff(decl_7215, type, fn_amylopectin_17: $i > $i).
% 28.89/28.93  tff(decl_7216, type, fn_amylopectin_18: $i > $i).
% 28.89/28.93  tff(decl_7217, type, fn_amylopectin_19: $i > $i).
% 28.89/28.93  tff(decl_7218, type, fn_amylopectin_22: $i > $i).
% 28.89/28.93  tff(decl_7219, type, fn_amylopectin_23: $i > $i).
% 28.89/28.93  tff(decl_7220, type, fn_amylopectin_24: $i > $i).
% 28.89/28.93  tff(decl_7221, type, fn_amylopectin_27: $i > $i).
% 28.89/28.93  tff(decl_7222, type, fn_amylopectin_29: $i > $i).
% 28.89/28.93  tff(decl_7223, type, fn_amylopectin_30: $i > $i).
% 28.89/28.93  tff(decl_7224, type, fn_amylopectin_31: $i > $i).
% 28.89/28.93  tff(decl_7225, type, fn_hydroxyl_group_1: $i > $i).
% 28.89/28.93  tff(decl_7226, type, fn_hydroxyl_group_2: $i > $i).
% 28.89/28.93  tff(decl_7227, type, starch_0: $i).
% 28.89/28.93  tff(decl_7228, type, fn_storage_polysaccharide_44: $i > $i).
% 28.89/28.93  tff(decl_7229, type, fn_storage_polysaccharide_41: $i > $i).
% 28.89/28.93  tff(decl_7230, type, fn_storage_polysaccharide_27: $i > $i).
% 28.89/28.93  tff(decl_7231, type, fn_amylopectin_25: $i > $i).
% 28.89/28.93  tff(decl_7232, type, fn_storage_polysaccharide_33: $i > $i).
% 28.89/28.93  tff(decl_7233, type, fn_storage_polysaccharide_55: $i > $i).
% 28.89/28.93  tff(decl_7234, type, fn_amylopectin_26: $i > $i).
% 28.89/28.93  tff(decl_7235, type, fn_storage_polysaccharide_34: $i > $i).
% 28.89/28.93  tff(decl_7236, type, fn_storage_polysaccharide_37: $i > $i).
% 28.89/28.93  tff(decl_7237, type, fn_storage_polysaccharide_36: $i > $i).
% 28.89/28.93  tff(decl_7238, type, fn_storage_polysaccharide_40: $i > $i).
% 28.89/28.93  tff(decl_7239, type, fn_storage_polysaccharide_79: $i > $i).
% 28.89/28.93  tff(decl_7240, type, fn_amylopectin_28: $i > $i).
% 28.89/28.93  tff(decl_7241, type, fn_starch_6: $i > $i).
% 28.89/28.93  tff(decl_7242, type, fn_amylopectin_20: $i > $i).
% 28.89/28.93  tff(decl_7243, type, fn_starch_55: $i > $i).
% 28.89/28.93  tff(decl_7244, type, fn_amylopectin_11: $i > $i).
% 28.89/28.93  tff(decl_7245, type, fn_starch_46: $i > $i).
% 28.89/28.93  tff(decl_7246, type, fn_starch_73: $i > $i).
% 28.89/28.93  tff(decl_7247, type, fn_amylopectin_21: $i > $i).
% 28.89/28.93  tff(decl_7248, type, fn_starch_54: $i > $i).
% 28.89/28.93  tff(decl_7249, type, fn_starch_5: $i > $i).
% 28.89/28.93  tff(decl_7250, type, fn_storage_polysaccharide_16: $i > $i).
% 28.89/28.93  tff(decl_7251, type, fn_starch_71: $i > $i).
% 28.89/28.93  tff(decl_7252, type, fn_storage_polysaccharide_42: $i > $i).
% 28.89/28.93  tff(decl_7253, type, fn_starch_104: $i > $i).
% 28.89/28.93  tff(decl_7254, type, fn_starch_59: $i > $i).
% 28.89/28.93  tff(decl_7255, type, fn_starch_51: $i > $i).
% 28.89/28.93  tff(decl_7256, type, fn_starch_70: $i > $i).
% 28.89/28.93  tff(decl_7257, type, fn_starch_60: $i > $i).
% 28.89/28.93  tff(decl_7258, type, fn_starch_65: $i > $i).
% 28.89/28.93  tff(decl_7259, type, fn_starch_34: $i > $i).
% 28.89/28.93  tff(decl_7260, type, fn_starch_47: $i > $i).
% 28.89/28.93  tff(decl_7261, type, fn_amylopectin_32: $i > $i).
% 28.89/28.93  tff(decl_7262, type, fn_starch_1: $i > $i).
% 28.89/28.93  tff(decl_7263, type, fn_starch_3: $i > $i).
% 28.89/28.93  tff(decl_7264, type, amyloplast_1: $i > $o).
% 28.89/28.93  tff(decl_7265, type, 'Amyloplast': $i).
% 28.89/28.93  tff(decl_7266, type, 'Amyloplasts are plastids which store starch (amylose).': $i).
% 28.89/28.93  tff(decl_7267, type, amyloplast: $i).
% 28.89/28.93  tff(decl_7268, type, plastid_1: $i > $o).
% 28.89/28.93  tff(decl_7269, type, chloroplast_1: $i > $o).
% 28.89/28.93  tff(decl_7270, type, chromoplast_1: $i > $o).
% 28.89/28.93  tff(decl_7271, type, plant_statolith_1: $i > $o).
% 28.89/28.93  tff(decl_7272, type, fn_amyloplast_1: $i > $i).
% 28.89/28.93  tff(decl_7273, type, fn_amyloplast_3: $i > $i).
% 28.89/28.93  tff(decl_7274, type, fn_amyloplast_4: $i > $i).
% 28.89/28.93  tff(decl_7275, type, fn_amyloplast_5: $i > $i).
% 28.89/28.93  tff(decl_7276, type, fn_amyloplast_6: $i > $i).
% 28.89/28.93  tff(decl_7277, type, amylose_1: $i > $o).
% 28.89/28.93  tff(decl_7278, type, fn_amyloplast_7: $i > $i).
% 28.89/28.93  tff(decl_7279, type, fn_amyloplast_8: $i > $i).
% 28.89/28.93  tff(decl_7280, type, fn_amyloplast_9: $i > $i).
% 28.89/28.93  tff(decl_7281, type, fn_plastid_5: $i > $i).
% 28.89/28.93  tff(decl_7282, type, fn_plastid_10: $i > $i).
% 28.89/28.93  tff(decl_7283, type, fn_plastid_9: $i > $i).
% 28.89/28.93  tff(decl_7284, type, 'Amylose': $i).
% 28.89/28.93  tff(decl_7285, type, 'Amylose is a type of carbohydrate. It is a linear polymer of glucose linked mainly by alpha (1-4) bonds. It is the simplest form of starch.': $i).
% 28.89/28.93  tff(decl_7286, type, amylose: $i).
% 28.89/28.93  tff(decl_7287, type, glycogen_1: $i > $o).
% 28.89/28.93  tff(decl_7288, type, noncellulose_polysaccharide_1: $i > $o).
% 28.89/28.93  tff(decl_7289, type, oligosaccharin_1: $i > $o).
% 28.89/28.93  tff(decl_7290, type, structural_polysaccharide_1: $i > $o).
% 28.89/28.93  tff(decl_7291, type, fn_amylose_1: $i > $i).
% 28.89/28.93  tff(decl_7292, type, fn_amylose_2: $i > $i).
% 28.89/28.93  tff(decl_7293, type, fn_amylose_4: $i > $i).
% 28.89/28.93  tff(decl_7294, type, fn_amylose_6: $i > $i).
% 28.89/28.93  tff(decl_7295, type, fn_amylose_8: $i > $i).
% 28.89/28.93  tff(decl_7296, type, fn_amylose_9: $i > $i).
% 28.89/28.93  tff(decl_7297, type, fn_amylose_11: $i > $i).
% 28.89/28.93  tff(decl_7298, type, fn_amylose_12: $i > $i).
% 28.89/28.93  tff(decl_7299, type, fn_amylose_13: $i > $i).
% 28.89/28.93  tff(decl_7300, type, fn_amylose_16: $i > $i).
% 28.89/28.93  tff(decl_7301, type, fn_amylose_17: $i > $i).
% 28.89/28.93  tff(decl_7302, type, fn_amylose_18: $i > $i).
% 28.89/28.93  tff(decl_7303, type, fn_amylose_19: $i > $i).
% 28.89/28.93  tff(decl_7304, type, fn_amylose_20: $i > $i).
% 28.89/28.93  tff(decl_7305, type, fn_amylose_21: $i > $i).
% 28.89/28.93  tff(decl_7306, type, fn_amylose_22: $i > $i).
% 28.89/28.93  tff(decl_7307, type, fn_amylose_23: $i > $i).
% 28.89/28.93  tff(decl_7308, type, fn_amylose_24: $i > $i).
% 28.89/28.93  tff(decl_7309, type, fn_amylose_25: $i > $i).
% 28.89/28.93  tff(decl_7310, type, fn_amylose_26: $i > $i).
% 28.89/28.93  tff(decl_7311, type, fn_amylose_27: $i > $i).
% 28.89/28.93  tff(decl_7312, type, fn_amylose_28: $i > $i).
% 28.89/28.93  tff(decl_7313, type, fn_amylose_29: $i > $i).
% 28.89/28.93  tff(decl_7314, type, fn_amylose_30: $i > $i).
% 28.89/28.93  tff(decl_7315, type, fn_amylose_31: $i > $i).
% 28.89/28.93  tff(decl_7316, type, fn_amylose_32: $i > $i).
% 28.89/28.93  tff(decl_7317, type, fn_amylose_33: $i > $i).
% 28.89/28.93  tff(decl_7318, type, fn_amylose_34: $i > $i).
% 28.89/28.93  tff(decl_7319, type, fn_amylose_35: $i > $i).
% 28.89/28.93  tff(decl_7320, type, fn_amylose_36: $i > $i).
% 28.89/28.93  tff(decl_7321, type, fn_amylose_37: $i > $i).
% 28.89/28.93  tff(decl_7322, type, fn_amylose_38: $i > $i).
% 28.89/28.93  tff(decl_7323, type, fn_amylose_44: $i > $i).
% 28.89/28.93  tff(decl_7324, type, fn_amylose_45: $i > $i).
% 28.89/28.93  tff(decl_7325, type, fn_amylose_46: $i > $i).
% 28.89/28.93  tff(decl_7326, type, fn_amylose_47: $i > $i).
% 28.89/28.93  tff(decl_7327, type, fn_amylose_48: $i > $i).
% 28.89/28.93  tff(decl_7328, type, fn_amylose_49: $i > $i).
% 28.89/28.93  tff(decl_7329, type, fn_amylose_52: $i > $i).
% 28.89/28.93  tff(decl_7330, type, fn_amylose_53: $i > $i).
% 28.89/28.93  tff(decl_7331, type, fn_amylose_54: $i > $i).
% 28.89/28.93  tff(decl_7332, type, fn_amylose_55: $i > $i).
% 28.89/28.93  tff(decl_7333, type, fn_amylose_56: $i > $i).
% 28.89/28.93  tff(decl_7334, type, fn_carbonyl_group_6: $i > $i).
% 28.89/28.93  tff(decl_7335, type, fn_carbonyl_group_10: $i > $i).
% 28.89/28.93  tff(decl_7336, type, fn_carbonyl_group_4: $i > $i).
% 28.89/28.93  tff(decl_7337, type, fn_hydroxyl_group_8: $i > $i).
% 28.89/28.93  tff(decl_7338, type, fn_hydroxyl_group_5: $i > $i).
% 28.89/28.93  tff(decl_7339, type, "3.44": $i).
% 28.89/28.93  tff(decl_7340, type, fn_polysaccharide_12: $i > $i).
% 28.89/28.93  tff(decl_7341, type, fn_amylose_14: $i > $i).
% 28.89/28.93  tff(decl_7342, type, fn_storage_polysaccharide_12: $i > $i).
% 28.89/28.93  tff(decl_7343, type, fn_amylose_50: $i > $i).
% 28.89/28.93  tff(decl_7344, type, fn_storage_polysaccharide_73: $i > $i).
% 28.89/28.93  tff(decl_7345, type, fn_amylose_51: $i > $i).
% 28.89/28.93  tff(decl_7346, type, fn_storage_polysaccharide_74: $i > $i).
% 28.89/28.93  tff(decl_7347, type, fn_amylose_42: $i > $i).
% 28.89/28.93  tff(decl_7348, type, fn_amylose_39: $i > $i).
% 28.89/28.93  tff(decl_7349, type, fn_storage_polysaccharide_51: $i > $i).
% 28.89/28.93  tff(decl_7350, type, fn_storage_polysaccharide_49: $i > $i).
% 28.89/28.93  tff(decl_7351, type, fn_storage_polysaccharide_71: $i > $i).
% 28.89/28.93  tff(decl_7352, type, fn_storage_polysaccharide_70: $i > $i).
% 28.89/28.93  tff(decl_7353, type, fn_storage_polysaccharide_69: $i > $i).
% 28.89/28.93  tff(decl_7354, type, fn_storage_polysaccharide_72: $i > $i).
% 28.89/28.93  tff(decl_7355, type, fn_starch_58: $i > $i).
% 28.89/28.93  tff(decl_7356, type, fn_amylose_43: $i > $i).
% 28.89/28.93  tff(decl_7357, type, fn_amylose_15: $i > $i).
% 28.89/28.93  tff(decl_7358, type, fn_amylose_10: $i > $i).
% 28.89/28.93  tff(decl_7359, type, fn_starch_2: $i > $i).
% 28.89/28.93  tff(decl_7360, type, fn_amylose_41: $i > $i).
% 28.89/28.93  tff(decl_7361, type, fn_polysaccharide_4: $i > $i).
% 28.89/28.93  tff(decl_7362, type, fn_amylose_40: $i > $i).
% 28.89/28.93  tff(decl_7363, type, fn_polysaccharide_13: $i > $i).
% 28.89/28.93  tff(decl_7364, type, fn_storage_polysaccharide_23: $i > $i).
% 28.89/28.93  tff(decl_7365, type, fn_starch_20: $i > $i).
% 28.89/28.93  tff(decl_7366, type, fn_carbohydrate_31: $i > $i).
% 28.89/28.93  tff(decl_7367, type, fn_carbohydrate_29: $i > $i).
% 28.89/28.93  tff(decl_7368, type, fn_storage_polysaccharide_46: $i > $i).
% 28.89/28.93  tff(decl_7369, type, fn_storage_polysaccharide_45: $i > $i).
% 28.89/28.93  tff(decl_7370, type, fn_starch_68: $i > $i).
% 28.89/28.93  tff(decl_7371, type, fn_storage_polysaccharide_52: $i > $i).
% 28.89/28.93  tff(decl_7372, type, fn_starch_52: $i > $i).
% 28.89/28.93  tff(decl_7373, type, fn_storage_polysaccharide_39: $i > $i).
% 28.89/28.93  tff(decl_7374, type, fn_starch_9: $i > $i).
% 28.89/28.93  tff(decl_7375, type, fn_storage_polysaccharide_43: $i > $i).
% 28.89/28.93  tff(decl_7376, type, fn_starch_67: $i > $i).
% 28.89/28.93  tff(decl_7377, type, fn_starch_66: $i > $i).
% 28.89/28.93  tff(decl_7378, type, fn_starch_61: $i > $i).
% 28.89/28.93  tff(decl_7379, type, fn_polysaccharide_16: $i > $i).
% 28.89/28.93  tff(decl_7380, type, fn_polysaccharide_11: $i > $i).
% 28.89/28.93  tff(decl_7381, type, fn_polysaccharide_26: $i > $i).
% 28.89/28.93  tff(decl_7382, type, 'Anabolic-Pathway': $i).
% 28.89/28.93  tff(decl_7383, type, 'The series of chemical reactions that constructs or synthesizes molecules from smaller units, usually requiring input of energy (ATP) in the process.': $i).
% 28.89/28.93  tff(decl_7384, type, 'anabolic reactions': $i).
% 28.89/28.93  tff(decl_7385, type, biosynthesis: $i).
% 28.89/28.93  tff(decl_7386, type, 'biosynthetic pathway': $i).
% 28.89/28.93  tff(decl_7387, type, 'biosynthetic-pathway': $i).
% 28.89/28.93  tff(decl_7388, type, 'take part in an anabolic pathway': $i).
% 28.89/28.93  tff(decl_7389, type, 'anabolic pathway': $i).
% 28.89/28.93  tff(decl_7390, type, 'anabolic-pathway': $i).
% 28.89/28.93  tff(decl_7391, type, renin_angiotensin_aldosterone_system_1: $i > $o).
% 28.89/28.93  tff(decl_7392, type, fn_anabolic_pathway_3: $i > $i).
% 28.89/28.93  tff(decl_7393, type, fn_anabolic_pathway_4: $i > $i).
% 28.89/28.93  tff(decl_7394, type, fn_anabolic_pathway_5: $i > $i).
% 28.89/28.93  tff(decl_7395, type, fn_endergonic_reaction_9: $i > $i).
% 28.89/28.93  tff(decl_7396, type, fn_endergonic_reaction_8: $i > $i).
% 28.89/28.93  tff(decl_7397, type, anabolism_1: $i > $o).
% 28.89/28.93  tff(decl_7398, type, 'Anabolism': $i).
% 28.89/28.93  tff(decl_7399, type, 'The class of chemical reactions that consume energy to construct larger molecules from smaller subunits.': $i).
% 28.89/28.93  tff(decl_7400, type, 'undergo anabolism': $i).
% 28.89/28.93  tff(decl_7401, type, anabolism: $i).
% 28.89/28.93  tff(decl_7402, type, metabolism_1: $i > $o).
% 28.89/28.93  tff(decl_7403, type, gene_amplification_1: $i > $o).
% 28.89/28.93  tff(decl_7404, type, antigen_presentation_1: $i > $o).
% 28.89/28.93  tff(decl_7405, type, catabolism_1: $i > $o).
% 28.89/28.93  tff(decl_7406, type, denaturation_1: $i > $o).
% 28.89/28.93  tff(decl_7407, type, dna_methylation_1: $i > $o).
% 28.89/28.93  tff(decl_7408, type, dynein_walking_1: $i > $o).
% 28.89/28.93  tff(decl_7409, type, genetic_process_1: $i > $o).
% 28.89/28.93  tff(decl_7410, type, protein_folding_1: $i > $o).
% 28.89/28.93  tff(decl_7411, type, fn_anabolism_3: $i > $i).
% 28.89/28.93  tff(decl_7412, type, fn_anabolism_4: $i > $i).
% 28.89/28.93  tff(decl_7413, type, fn_anabolism_5: $i > $i).
% 28.89/28.93  tff(decl_7414, type, fn_anabolism_6: $i > $i).
% 28.89/28.93  tff(decl_7415, type, anaerobe_1: $i > $o).
% 28.89/28.93  tff(decl_7416, type, 'Anaerobe': $i).
% 28.89/28.93  tff(decl_7417, type, 'A cell or an organism which can live in the absence of oxygen.': $i).
% 28.89/28.93  tff(decl_7418, type, 'anaerobic organism': $i).
% 28.89/28.93  tff(decl_7419, type, 'anaerobic-organism': $i).
% 28.89/28.93  tff(decl_7420, type, anaerobe: $i).
% 28.89/28.93  tff(decl_7421, type, fn_anaerobe_1: $i > $i).
% 28.89/28.93  tff(decl_7422, type, fn_anaerobe_2: $i > $i).
% 28.89/28.93  tff(decl_7423, type, fn_anaerobe_3: $i > $i).
% 28.89/28.93  tff(decl_7424, type, fn_anaerobe_4: $i > $i).
% 28.89/28.93  tff(decl_7425, type, fn_anaerobe_5: $i > $i).
% 28.89/28.93  tff(decl_7426, type, fn_anaerobe_6: $i > $i).
% 28.89/28.93  tff(decl_7427, type, fn_anaerobe_7: $i > $i).
% 28.89/28.93  tff(decl_7428, type, fn_anaerobe_8: $i > $i).
% 28.89/28.93  tff(decl_7429, type, fn_anaerobe_9: $i > $i).
% 28.89/28.93  tff(decl_7430, type, fn_anaerobe_10: $i > $i).
% 28.89/28.93  tff(decl_7431, type, fn_anaerobe_11: $i > $i).
% 28.89/28.93  tff(decl_7432, type, fn_anaerobe_12: $i > $i).
% 28.89/28.93  tff(decl_7433, type, fn_anaerobe_13: $i > $i).
% 28.89/28.93  tff(decl_7434, type, fn_anaerobe_14: $i > $i).
% 28.89/28.93  tff(decl_7435, type, fn_anaerobe_15: $i > $i).
% 28.89/28.93  tff(decl_7436, type, fn_anaerobe_16: $i > $i).
% 28.89/28.93  tff(decl_7437, type, fn_anaerobe_17: $i > $i).
% 28.89/28.93  tff(decl_7438, type, anaerobic_condition_1: $i > $o).
% 28.89/28.93  tff(decl_7439, type, 'Anaerobic-Condition': $i).
% 28.89/28.93  tff(decl_7440, type, 'A biological process which occurs in the absence of molecular oxygen.': $i).
% 28.89/28.93  tff(decl_7441, type, 'anaerobic condition': $i).
% 28.89/28.93  tff(decl_7442, type, 'anaerobic-condition': $i).
% 28.89/28.93  tff(decl_7443, type, anaerobic_respiration_1: $i > $o).
% 28.89/28.93  tff(decl_7444, type, 'Anaerobic-Respiration': $i).
% 28.89/28.93  tff(decl_7445, type, 'A catabolic pathway that occurs in the absence of molecular oxygen involving an electron transport chain and a different inorganic molecule other than oxygen as a final electron acceptor.': $i).
% 28.89/28.93  tff(decl_7446, type, 'perform unaerobic respiration': $i).
% 28.89/28.93  tff(decl_7447, type, 'anaerobic respiration': $i).
% 28.89/28.93  tff(decl_7448, type, 'anaerobic-respiration': $i).
% 28.89/28.93  tff(decl_7449, type, cellular_respiration_1: $i > $o).
% 28.89/28.93  tff(decl_7450, type, fn_anaerobic_respiration_1: $i > $i).
% 28.89/28.93  tff(decl_7451, type, fn_anaerobic_respiration_2: $i > $i).
% 28.89/28.93  tff(decl_7452, type, fn_anaerobic_respiration_3: $i > $i).
% 28.89/28.93  tff(decl_7453, type, fn_anaerobic_respiration_4: $i > $i).
% 28.89/28.93  tff(decl_7454, type, fn_anaerobic_respiration_5: $i > $i).
% 28.89/28.93  tff(decl_7455, type, fn_anaerobic_respiration_6: $i > $i).
% 28.89/28.93  tff(decl_7456, type, fn_anaerobic_respiration_7: $i > $i).
% 28.89/28.93  tff(decl_7457, type, fn_anaerobic_respiration_8: $i > $i).
% 28.89/28.93  tff(decl_7458, type, fn_anaerobic_respiration_9: $i > $i).
% 28.89/28.93  tff(decl_7459, type, fn_anaerobic_respiration_10: $i > $i).
% 28.89/28.93  tff(decl_7460, type, fn_anaerobic_respiration_11: $i > $i).
% 28.89/28.93  tff(decl_7461, type, fn_anaerobic_respiration_12: $i > $i).
% 28.89/28.93  tff(decl_7462, type, fn_anaerobic_respiration_13: $i > $i).
% 28.89/28.93  tff(decl_7463, type, final_electron_acceptor_1: $i > $o).
% 28.89/28.93  tff(decl_7464, type, fn_anaerobic_respiration_14: $i > $i).
% 28.89/28.93  tff(decl_7465, type, fn_anaerobic_respiration_15: $i > $i).
% 28.89/28.93  tff(decl_7466, type, electron_transport_chain_reaction_1: $i > $o).
% 28.89/28.93  tff(decl_7467, type, fn_anaerobic_respiration_16: $i > $i).
% 28.89/28.93  tff(decl_7468, type, fn_anaerobic_respiration_17: $i > $i).
% 28.89/28.93  tff(decl_7469, type, work_1: $i > $o).
% 28.89/28.93  tff(decl_7470, type, fn_electron_transport_chain_reaction_1: $i > $i).
% 28.89/28.93  tff(decl_7471, type, fn_electron_transport_chain_reaction_7: $i > $i).
% 28.89/28.93  tff(decl_7472, type, fn_electron_recipient_2: $i > $i).
% 28.89/28.93  tff(decl_7473, type, fn_glycolysis_34: $i > $i).
% 28.89/28.93  tff(decl_7474, type, fn_glycolysis_33: $i > $i).
% 28.89/28.93  tff(decl_7475, type, fn_release_2: $i > $i).
% 28.89/28.93  tff(decl_7476, type, fn_work_1: $i > $i).
% 28.89/28.93  tff(decl_7477, type, fn_electron_transport_chain_reaction_8: $i > $i).
% 28.89/28.93  tff(decl_7478, type, fn_glycolysis_21: $i > $i).
% 28.89/28.93  tff(decl_7479, type, fn_electron_transport_chain_reaction_15: $i > $i).
% 28.89/28.93  tff(decl_7480, type, fn_glycolysis_19: $i > $i).
% 28.89/28.93  tff(decl_7481, type, fn_electron_transport_chain_reaction_14: $i > $i).
% 28.89/28.93  tff(decl_7482, type, fn_glycolysis_22: $i > $i).
% 28.89/28.93  tff(decl_7483, type, fn_electron_transport_chain_reaction_16: $i > $i).
% 28.89/28.93  tff(decl_7484, type, fn_glycolysis_17: $i > $i).
% 28.89/28.93  tff(decl_7485, type, fn_electron_transport_chain_reaction_9: $i > $i).
% 28.89/28.93  tff(decl_7486, type, fn_catabolism_1: $i > $i).
% 28.89/28.93  tff(decl_7487, type, anagenesis_1: $i > $o).
% 28.89/28.93  tff(decl_7488, type, 'Anagenesis': $i).
% 28.89/28.93  tff(decl_7489, type, 'The accumulation of genetic differences within a lineage, that eventually results in a new species and renders the ancestral species extinct. This process is distinct from cladogenesis, where new lineages result from divergence with an ancestral lineage.': $i).
% 28.89/28.93  tff(decl_7490, type, 'phyletic evolution': $i).
% 28.89/28.93  tff(decl_7491, type, 'phyletic-evolution': $i).
% 28.89/28.93  tff(decl_7492, type, anagenesis: $i).
% 28.89/28.93  tff(decl_7493, type, analysis_1: $i > $o).
% 28.89/28.93  tff(decl_7494, type, 'Analysis': $i).
% 28.89/28.93  tff(decl_7495, type, analyze: $i).
% 28.89/28.93  tff(decl_7496, type, analysis: $i).
% 28.89/28.93  tff(decl_7497, type, investigation: $i).
% 28.89/28.93  tff(decl_7498, type, reasoning: $i).
% 28.89/28.93  tff(decl_7499, type, 'logical thinking': $i).
% 28.89/28.93  tff(decl_7500, type, logical_thinking: $i).
% 28.89/28.93  tff(decl_7501, type, 'abstract thought': $i).
% 28.89/28.93  tff(decl_7502, type, abstract_thought: $i).
% 28.89/28.93  tff(decl_7503, type, fn_analysis_1: $i > $i).
% 28.89/28.93  tff(decl_7504, type, anaphase_1: $i > $o).
% 28.89/28.93  tff(decl_7505, type, 'Anaphase': $i).
% 28.89/28.93  tff(decl_7506, type, 'The spindle fibres shorten and the centromere splits, separated sister chromatids are pulled along behind the centromeres.In the cytoplasm, the mitotic spindle begins to form. it is made of microtubules extending from the two centrosomes': $i).
% 28.89/28.93  tff(decl_7507, type, 'undergo anaphase': $i).
% 28.89/28.93  tff(decl_7508, type, anaphase: $i).
% 28.89/28.93  tff(decl_7509, type, mitotic_stage_1: $i > $o).
% 28.89/28.93  tff(decl_7510, type, fn_anaphase_2: $i > $i).
% 28.89/28.93  tff(decl_7511, type, fn_anaphase_3: $i > $i).
% 28.89/28.93  tff(decl_7512, type, separation_of_sister_chromatids_1: $i > $o).
% 28.89/28.93  tff(decl_7513, type, fn_anaphase_4: $i > $i).
% 28.89/28.93  tff(decl_7514, type, reeling_mechanism_1: $i > $o).
% 28.89/28.93  tff(decl_7515, type, fn_anaphase_5: $i > $i).
% 28.89/28.93  tff(decl_7516, type, pacman_mechanism_1: $i > $o).
% 28.89/28.93  tff(decl_7517, type, fn_anaphase_8: $i > $i).
% 28.89/28.93  tff(decl_7518, type, fn_anaphase_9: $i > $i).
% 28.89/28.93  tff(decl_7519, type, cell_elongation_during_anaphase_1: $i > $o).
% 28.89/28.93  tff(decl_7520, type, fn_anaphase_10: $i > $i).
% 28.89/28.93  tff(decl_7521, type, distribution_of_daughter_chromosomes_1: $i > $o).
% 28.89/28.93  tff(decl_7522, type, fn_anaphase_11: $i > $i).
% 28.89/28.93  tff(decl_7523, type, fn_anaphase_12: $i > $i).
% 28.89/28.93  tff(decl_7524, type, fn_anaphase_13: $i > $i).
% 28.89/28.93  tff(decl_7525, type, fn_anaphase_14: $i > $i).
% 28.89/28.93  tff(decl_7526, type, cell_elongation_1: $i > $o).
% 28.89/28.93  tff(decl_7527, type, fn_anaphase_15: $i > $i).
% 28.89/28.93  tff(decl_7528, type, fn_anaphase_16: $i > $i).
% 28.89/28.93  tff(decl_7529, type, fn_anaphase_17: $i > $i).
% 28.89/28.93  tff(decl_7530, type, fn_anaphase_18: $i > $i).
% 28.89/28.93  tff(decl_7531, type, fn_anaphase_19: $i > $i).
% 28.89/28.93  tff(decl_7532, type, fn_anaphase_20: $i > $i).
% 28.89/28.93  tff(decl_7533, type, fn_anaphase_21: $i > $i).
% 28.89/28.93  tff(decl_7534, type, fn_anaphase_22: $i > $i).
% 28.89/28.93  tff(decl_7535, type, fn_anaphase_23: $i > $i).
% 28.89/28.93  tff(decl_7536, type, fn_anaphase_24: $i > $i).
% 28.89/28.93  tff(decl_7537, type, fn_anaphase_25: $i > $i).
% 28.89/28.93  tff(decl_7538, type, fn_anaphase_26: $i > $i).
% 28.89/28.93  tff(decl_7539, type, fn_cell_elongation_during_anaphase_43: $i > $i).
% 28.89/28.93  tff(decl_7540, type, fn_cell_elongation_during_anaphase_44: $i > $i).
% 28.89/28.93  tff(decl_7541, type, fn_cell_elongation_during_anaphase_42: $i > $i).
% 28.89/28.93  tff(decl_7542, type, fn_cell_elongation_during_anaphase_35: $i > $i).
% 28.89/28.93  tff(decl_7543, type, fn_cell_elongation_during_anaphase_39: $i > $i).
% 28.89/28.93  tff(decl_7544, type, fn_cell_elongation_during_anaphase_36: $i > $i).
% 28.89/28.93  tff(decl_7545, type, fn_cell_elongation_during_anaphase_18: $i > $i).
% 28.89/28.93  tff(decl_7546, type, fn_cell_elongation_during_anaphase_6: $i > $i).
% 28.89/28.93  tff(decl_7547, type, fn_cell_elongation_during_anaphase_31: $i > $i).
% 28.89/28.93  tff(decl_7548, type, fn_cell_elongation_during_anaphase_40: $i > $i).
% 28.89/28.93  tff(decl_7549, type, fn_cell_elongation_during_anaphase_38: $i > $i).
% 28.89/28.93  tff(decl_7550, type, fn_cell_elongation_during_anaphase_37: $i > $i).
% 28.89/28.93  tff(decl_7551, type, fn_cell_elongation_during_anaphase_41: $i > $i).
% 28.89/28.93  tff(decl_7552, type, fn_cell_elongation_during_anaphase_13: $i > $i).
% 28.89/28.93  tff(decl_7553, type, fn_cell_elongation_during_anaphase_11: $i > $i).
% 28.89/28.93  tff(decl_7554, type, fn_cell_elongation_during_anaphase_12: $i > $i).
% 28.89/28.93  tff(decl_7555, type, fn_cell_elongation_during_anaphase_1: $i > $i).
% 28.89/28.93  tff(decl_7556, type, fn_mitotic_event_1: $i > $i).
% 28.89/28.93  tff(decl_7557, type, fn_cell_elongation_during_anaphase_21: $i > $i).
% 28.89/28.93  tff(decl_7558, type, mitotic_stage_0: $i).
% 28.89/28.93  tff(decl_7559, type, fn_mitotic_stage_1: $i > $i).
% 28.89/28.93  tff(decl_7560, type, fn_anaphase_7: $i > $i).
% 28.89/28.93  tff(decl_7561, type, fn_anaphase_6: $i > $i).
% 28.89/28.93  tff(decl_7562, type, anaphase_i_1: $i > $o).
% 28.89/28.93  tff(decl_7563, type, 'Anaphase-I': $i).
% 28.89/28.93  tff(decl_7564, type, 'During anaphase I phase of meiosis the mitotic spindle guides the movement of chromosomes toward the poles. The sister-chromatids remain attached at their centromere and move as a single unit while the homologous chromosome moves toward the opposite pole.': $i).
% 28.89/28.93  tff(decl_7565, type, 'undergo anaphase i': $i).
% 28.89/28.93  tff(decl_7566, type, 'undergo anaphase-i': $i).
% 28.89/28.93  tff(decl_7567, type, 'anaphase i': $i).
% 28.89/28.93  tff(decl_7568, type, 'anaphase-i': $i).
% 28.89/28.93  tff(decl_7569, type, meiotic_event_1: $i > $o).
% 28.89/28.93  tff(decl_7570, type, fn_anaphase_i_1: $i > $i).
% 28.89/28.93  tff(decl_7571, type, mitotic_spindle_1: $i > $o).
% 28.89/28.93  tff(decl_7572, type, fn_anaphase_i_2: $i > $i).
% 28.89/28.93  tff(decl_7573, type, kinetochore_microtubule_1: $i > $o).
% 28.89/28.93  tff(decl_7574, type, fn_anaphase_i_3: $i > $i).
% 28.89/28.93  tff(decl_7575, type, fn_anaphase_i_4: $i > $i).
% 28.89/28.93  tff(decl_7576, type, fn_anaphase_i_5: $i > $i).
% 28.89/28.93  tff(decl_7577, type, fn_anaphase_i_6: $i > $i).
% 28.89/28.93  tff(decl_7578, type, fn_anaphase_i_7: $i > $i).
% 28.89/28.93  tff(decl_7579, type, fn_anaphase_i_8: $i > $i).
% 28.89/28.93  tff(decl_7580, type, fn_anaphase_i_9: $i > $i).
% 28.89/28.93  tff(decl_7581, type, fn_anaphase_i_10: $i > $i).
% 28.89/28.93  tff(decl_7582, type, fn_anaphase_i_11: $i > $i).
% 28.89/28.93  tff(decl_7583, type, fn_anaphase_i_12: $i > $i).
% 28.89/28.93  tff(decl_7584, type, move_together_1: $i > $o).
% 28.89/28.93  tff(decl_7585, type, fn_anaphase_i_13: $i > $i).
% 28.89/28.93  tff(decl_7586, type, move_apart_1: $i > $o).
% 28.89/28.93  tff(decl_7587, type, fn_anaphase_i_14: $i > $i).
% 28.89/28.93  tff(decl_7588, type, homologous_chromosome_1: $i > $o).
% 28.89/28.93  tff(decl_7589, type, fn_anaphase_i_15: $i > $i).
% 28.89/28.93  tff(decl_7590, type, fn_anaphase_i_16: $i > $i).
% 28.89/28.93  tff(decl_7591, type, fn_anaphase_i_17: $i > $i).
% 28.89/28.93  tff(decl_7592, type, fn_anaphase_i_18: $i > $i).
% 28.89/28.93  tff(decl_7593, type, fn_anaphase_i_19: $i > $i).
% 28.89/28.93  tff(decl_7594, type, fn_anaphase_i_20: $i > $i).
% 28.89/28.93  tff(decl_7595, type, fn_anaphase_i_21: $i > $i).
% 28.89/28.93  tff(decl_7596, type, fn_move_together_1: $i > $i).
% 28.89/28.93  tff(decl_7597, type, fn_move_together_3: $i > $i).
% 28.89/28.93  tff(decl_7598, type, fn_move_apart_3: $i > $i).
% 28.89/28.93  tff(decl_7599, type, fn_cell_1: $i > $i).
% 28.89/28.93  tff(decl_7600, type, fn_chromatid_1: $i > $i).
% 28.89/28.93  tff(decl_7601, type, fn_move_apart_2: $i > $i).
% 28.89/28.93  tff(decl_7602, type, fn_move_apart_1: $i > $i).
% 28.89/28.93  tff(decl_7603, type, fn_move_together_2: $i > $i).
% 28.89/28.93  tff(decl_7604, type, anaphase_ii_1: $i > $o).
% 28.89/28.93  tff(decl_7605, type, 'Anaphase-II': $i).
% 28.89/28.93  tff(decl_7606, type, 'During anaphase II, the centromeres of the sister chromatids separate. The sister chromatids of each pair move toward the opposite poles of the cell.': $i).
% 28.89/28.93  tff(decl_7607, type, 'undergo anaphase ii': $i).
% 28.89/28.93  tff(decl_7608, type, 'undergo anaphase-ii': $i).
% 28.89/28.93  tff(decl_7609, type, 'anaphase ii': $i).
% 28.89/28.93  tff(decl_7610, type, 'anaphase-ii': $i).
% 28.89/28.93  tff(decl_7611, type, fn_anaphase_ii_1: $i > $i).
% 28.89/28.93  tff(decl_7612, type, fn_anaphase_ii_2: $i > $i).
% 28.89/28.93  tff(decl_7613, type, fn_anaphase_ii_3: $i > $i).
% 28.89/28.93  tff(decl_7614, type, fn_anaphase_ii_4: $i > $i).
% 28.89/28.93  tff(decl_7615, type, fn_anaphase_ii_5: $i > $i).
% 28.89/28.93  tff(decl_7616, type, fn_anaphase_ii_6: $i > $i).
% 28.89/28.93  tff(decl_7617, type, fn_anaphase_ii_7: $i > $i).
% 28.89/28.93  tff(decl_7618, type, fn_anaphase_ii_8: $i > $i).
% 28.89/28.93  tff(decl_7619, type, fn_anaphase_ii_9: $i > $i).
% 28.89/28.93  tff(decl_7620, type, fn_anaphase_ii_10: $i > $i).
% 28.89/28.93  tff(decl_7621, type, anaphase_promoting_complex_1: $i > $o).
% 28.89/28.93  tff(decl_7622, type, 'Anaphase-Promoting-Complex': $i).
% 28.89/28.93  tff(decl_7623, type, 'A group of molecules that triggers the eventual  breakup of kinetochores holding sister chromatids together and indicates the onset of anaphase.': $i).
% 28.89/28.93  tff(decl_7624, type, 'anaphase promoting complex': $i).
% 28.89/28.93  tff(decl_7625, type, 'anaphase-promoting complex': $i).
% 28.89/28.93  tff(decl_7626, type, 'anaphase-promoting-complex': $i).
% 28.89/28.93  tff(decl_7627, type, protein_complex_1: $i > $o).
% 28.89/28.93  tff(decl_7628, type, capsomere_1: $i > $o).
% 28.89/28.93  tff(decl_7629, type, complement_system_1: $i > $o).
% 28.89/28.93  tff(decl_7630, type, light_harvesting_complex_1: $i > $o).
% 28.89/28.93  tff(decl_7631, type, membrane_attack_complex_1: $i > $o).
% 28.89/28.93  tff(decl_7632, type, myofibril_1: $i > $o).
% 28.89/28.93  tff(decl_7633, type, protein_core_1: $i > $o).
% 28.89/28.93  tff(decl_7634, type, reaction_center_complex_1: $i > $o).
% 28.89/28.93  tff(decl_7635, type, rosette_cellulose_synthesizing_complex_1: $i > $o).
% 28.89/28.93  tff(decl_7636, type, thick_filament_1: $i > $o).
% 28.89/28.93  tff(decl_7637, type, thin_filament_1: $i > $o).
% 28.89/28.93  tff(decl_7638, type, troponin_complex_1: $i > $o).
% 28.89/28.93  tff(decl_7639, type, fn_anaphase_promoting_complex_1: $i > $i).
% 28.89/28.93  tff(decl_7640, type, cyclin_dependent_kinase_0: $i).
% 28.89/28.93  tff(decl_7641, type, cyclin_0: $i).
% 28.89/28.93  tff(decl_7642, type, fn_protein_complex_1: $i > $i).
% 28.89/28.93  tff(decl_7643, type, anaphylactic_shock_1: $i > $o).
% 28.89/28.93  tff(decl_7644, type, 'Anaphylactic-Shock': $i).
% 28.89/28.93  tff(decl_7645, type, 'A life-threatening allergic reaction to injected or ingested allergens.': $i).
% 28.89/28.93  tff(decl_7646, type, 'anaphylactic shock': $i).
% 28.89/28.93  tff(decl_7647, type, 'anaphylactic-shock': $i).
% 28.89/28.93  tff(decl_7648, type, immune_disorders_1: $i > $o).
% 28.89/28.93  tff(decl_7649, type, autoimmune_disease_1: $i > $o).
% 28.89/28.93  tff(decl_7650, type, 'Anapsid': $i).
% 28.89/28.93  tff(decl_7651, type, 'A group of extinct amniote vertebrates whose skulls do not have temporal openings.': $i).
% 28.89/28.93  tff(decl_7652, type, anapsid: $i).
% 28.89/28.93  tff(decl_7653, type, anatomical_appendage_1: $i > $o).
% 28.89/28.93  tff(decl_7654, type, 'Anatomical-Appendage': $i).
% 28.89/28.93  tff(decl_7655, type, 'An external body part, or natural prolongation, that protrudes from an organism\\s body.': $i).
% 28.89/28.93  tff(decl_7656, type, appendage: $i).
% 28.89/28.93  tff(decl_7657, type, 'appendage of anatomical': $i).
% 28.89/28.93  tff(decl_7658, type, 'anatomical appendage': $i).
% 28.89/28.93  tff(decl_7659, type, 'anatomical-appendage': $i).
% 28.89/28.93  tff(decl_7660, type, anatomical_structure_1: $i > $o).
% 28.89/28.93  tff(decl_7661, type, anatomical_region_1: $i > $o).
% 28.89/28.93  tff(decl_7662, type, 'Anatomical-Region': $i).
% 28.89/28.93  tff(decl_7663, type, 'Descriptive term referring to a specific location of an animal\\s body relative to its location to correct anatomical position.': $i).
% 28.89/28.93  tff(decl_7664, type, 'anatomical terms of location': $i).
% 28.89/28.93  tff(decl_7665, type, 'anatomical-terms-of-location': $i).
% 28.89/28.93  tff(decl_7666, type, 'region of anatomical': $i).
% 28.89/28.93  tff(decl_7667, type, 'anatomical region': $i).
% 28.89/28.93  tff(decl_7668, type, 'anatomical-region': $i).
% 28.89/28.93  tff(decl_7669, type, organismal_region_1: $i > $o).
% 28.89/28.93  tff(decl_7670, type, anatomical_space_1: $i > $o).
% 28.89/28.93  tff(decl_7671, type, 'Anatomical-Space': $i).
% 28.89/28.93  tff(decl_7672, type, 'A space surrounded by anatomical structures.': $i).
% 28.89/28.93  tff(decl_7673, type, 'space of anatomical': $i).
% 28.89/28.93  tff(decl_7674, type, 'anatomical space': $i).
% 28.89/28.93  tff(decl_7675, type, 'anatomical-space': $i).
% 28.89/28.93  tff(decl_7676, type, 'Anatomical-Structure': $i).
% 28.89/28.93  tff(decl_7677, type, 'Any structural feature of an organism.': $i).
% 28.89/28.93  tff(decl_7678, type, 'structure of anatomical': $i).
% 28.89/28.93  tff(decl_7679, type, 'anatomical structure': $i).
% 28.89/28.93  tff(decl_7680, type, 'anatomical-structure': $i).
% 28.89/28.93  tff(decl_7681, type, anatomist_1: $i > $o).
% 28.89/28.93  tff(decl_7682, type, 'Anatomist': $i).
% 28.89/28.93  tff(decl_7683, type, 'Person who studies anatomy and the relationships between anatomical parts, typically of the human body.': $i).
% 28.89/28.93  tff(decl_7684, type, anatomist: $i).
% 28.89/28.93  tff(decl_7685, type, biologist_1: $i > $o).
% 28.89/28.93  tff(decl_7686, type, anatomy_1: $i > $o).
% 28.89/28.93  tff(decl_7687, type, 'Anatomy': $i).
% 28.89/28.93  tff(decl_7688, type, 'The physical structure of an organism, or the study of this aspect of an organism.': $i).
% 28.89/28.93  tff(decl_7689, type, anatomize: $i).
% 28.89/28.93  tff(decl_7690, type, anatomy: $i).
% 28.89/28.93  tff(decl_7691, type, morphology_1: $i > $o).
% 28.89/28.93  tff(decl_7692, type, ancestral_gene_1: $i > $o).
% 28.89/28.93  tff(decl_7693, type, 'Ancestral-Gene': $i).
% 28.89/28.93  tff(decl_7694, type, 'The common genes that, through evolution, has produced resulting genomes.': $i).
% 28.89/28.93  tff(decl_7695, type, 'ancestral gene': $i).
% 28.89/28.93  tff(decl_7696, type, 'ancestral-gene': $i).
% 28.89/28.93  tff(decl_7697, type, fn_ancestral_gene_1: $i > $i).
% 28.89/28.93  tff(decl_7698, type, fn_ancestral_gene_2: $i > $i).
% 28.89/28.93  tff(decl_7699, type, anchor_1: $i > $o).
% 28.89/28.93  tff(decl_7700, type, 'Anchor': $i).
% 28.89/28.93  tff(decl_7701, type, 'Process of holding something stationary in order to provide support.': $i).
% 28.89/28.93  tff(decl_7702, type, anchor: $i).
% 28.89/28.93  tff(decl_7703, type, anchor_cell_1: $i > $o).
% 28.89/28.93  tff(decl_7704, type, 'Anchor-Cell': $i).
% 28.89/28.93  tff(decl_7705, type, 'In nematode worms, a cell in the gonad that initiates a cascade leading to the formation of structures in the female reproductive system.': $i).
% 28.89/28.93  tff(decl_7706, type, 'cell of anchor': $i).
% 28.89/28.93  tff(decl_7707, type, 'anchor cell': $i).
% 28.89/28.93  tff(decl_7708, type, 'anchor-cell': $i).
% 28.89/28.93  tff(decl_7709, type, reproductive_cell_1: $i > $o).
% 28.89/28.93  tff(decl_7710, type, anchor_cell_destruction_experiment_1: $i > $o).
% 28.89/28.93  tff(decl_7711, type, 'Anchor-Cell-Destruction-Experiment': $i).
% 28.89/28.93  tff(decl_7712, type, 'An experiment conducted to study destruction of the anchor cell with a laser beam. The vulva fails to form and the precursor cells simply become part of the worm\\s epidermis.': $i).
% 28.89/28.93  tff(decl_7713, type, 'perform an anchor cell destruction experiment': $i).
% 28.89/28.93  tff(decl_7714, type, 'anchor cell destruction experiment': $i).
% 28.89/28.93  tff(decl_7715, type, 'anchor-cell-destruction-experiment': $i).
% 28.89/28.93  tff(decl_7716, type, experiment_1: $i > $o).
% 28.89/28.93  tff(decl_7717, type, bicoid_protein_hypothesis_experiment_1: $i > $o).
% 28.89/28.93  tff(decl_7718, type, controlled_experiment_1: $i > $o).
% 28.89/28.93  tff(decl_7719, type, meselson_and_stahl_experiment_1: $i > $o).
% 28.89/28.93  tff(decl_7720, type, steward_experiment_on_carrot_1: $i > $o).
% 28.89/28.93  tff(decl_7721, type, study_on_drosophila_by_morgan_1: $i > $o).
% 28.89/28.93  tff(decl_7722, type, tomato_chimera_experiment_1: $i > $o).
% 28.89/28.93  tff(decl_7723, type, undifferentiated_cell_nucleus_transplantation_to_frog_egg_1: $i > $o).
% 28.89/28.93  tff(decl_7724, type, fn_anchor_cell_destruction_experiment_1: $i > $i).
% 28.89/28.93  tff(decl_7725, type, vulva_development_1: $i > $o).
% 28.89/28.93  tff(decl_7726, type, fn_anchor_cell_destruction_experiment_2: $i > $i).
% 28.89/28.93  tff(decl_7727, type, laser_light_1: $i > $o).
% 28.89/28.93  tff(decl_7728, type, fn_anchor_cell_destruction_experiment_3: $i > $i).
% 28.89/28.93  tff(decl_7729, type, vulval_precursor_cell_1: $i > $o).
% 28.89/28.93  tff(decl_7730, type, fn_anchor_cell_destruction_experiment_4: $i > $i).
% 28.89/28.93  tff(decl_7731, type, model_organism_1: $i > $o).
% 28.89/28.93  tff(decl_7732, type, fn_anchor_cell_destruction_experiment_5: $i > $i).
% 28.89/28.93  tff(decl_7733, type, destroy_1: $i > $o).
% 28.89/28.93  tff(decl_7734, type, fn_anchor_cell_destruction_experiment_6: $i > $i).
% 28.89/28.93  tff(decl_7735, type, fn_anchor_cell_destruction_experiment_7: $i > $i).
% 28.89/28.93  tff(decl_7736, type, fn_anchor_cell_destruction_experiment_8: $i > $i).
% 28.89/28.93  tff(decl_7737, type, fn_anchor_cell_destruction_experiment_9: $i > $i).
% 28.89/28.93  tff(decl_7738, type, scientist_1: $i > $o).
% 28.89/28.93  tff(decl_7739, type, fn_anchor_cell_destruction_experiment_10: $i > $i).
% 28.89/28.93  tff(decl_7740, type, caenorhabditis_elegans_1: $i > $o).
% 28.89/28.93  tff(decl_7741, type, fn_model_organism_6: $i > $i).
% 28.89/28.93  tff(decl_7742, type, fn_scientist_2: $i > $i).
% 28.89/28.93  tff(decl_7743, type, study_1: $i > $o).
% 28.89/28.93  tff(decl_7744, type, "6": $i).
% 28.89/28.93  tff(decl_7745, type, vulval_precursor_cell_0: $i).
% 28.89/28.93  tff(decl_7746, type, anchorage_dependence_1: $i > $o).
% 28.89/28.93  tff(decl_7747, type, 'Anchorage-Dependence': $i).
% 28.89/28.93  tff(decl_7748, type, 'Mechanism of regulation of cell division, in which contact with a substrate (such as a culture vial or tissue) is required in order for a cell to divide. Anchorage dependence prevents free-floating or isolated cells from dividing.': $i).
% 28.89/28.93  tff(decl_7749, type, 'dependence of anchorage': $i).
% 28.89/28.93  tff(decl_7750, type, 'anchorage dependence': $i).
% 28.89/28.93  tff(decl_7751, type, 'anchorage-dependence': $i).
% 28.89/28.93  tff(decl_7752, type, fn_anchorage_dependence_1: $i > $i).
% 28.89/28.93  tff(decl_7753, type, cell_division_1: $i > $o).
% 28.89/28.93  tff(decl_7754, type, fn_anchorage_dependence_2: $i > $i).
% 28.89/28.93  tff(decl_7755, type, fn_anchorage_dependence_3: $i > $i).
% 28.89/28.93  tff(decl_7756, type, fn_cell_division_3: $i > $i).
% 28.89/28.93  tff(decl_7757, type, anchoring_of_organelles_1: $i > $o).
% 28.89/28.93  tff(decl_7758, type, 'Anchoring-of-organelles': $i).
% 28.89/28.93  tff(decl_7759, type, 'Organelles are held in place by intermediate filaments, a component of the cytoskeleton.': $i).
% 28.89/28.93  tff(decl_7760, type, 'organelle anchoring': $i).
% 28.89/28.93  tff(decl_7761, type, 'anchoring of organelle': $i).
% 28.89/28.93  tff(decl_7762, type, 'anchoring-of-organelle': $i).
% 28.89/28.93  tff(decl_7763, type, fn_anchoring_of_organelles_1: $i > $i).
% 28.89/28.93  tff(decl_7764, type, cytoskeleton_1: $i > $o).
% 28.89/28.93  tff(decl_7765, type, fn_anchoring_of_organelles_2: $i > $i).
% 28.89/28.93  tff(decl_7766, type, fn_cytoskeleton_5: $i > $i).
% 28.89/28.93  tff(decl_7767, type, fn_support_1: $i > $i).
% 28.89/28.93  tff(decl_7768, type, androgen_1: $i > $o).
% 28.89/28.93  tff(decl_7769, type, 'Androgen': $i).
% 28.89/28.93  tff(decl_7770, type, 'A steroid hormone that binds to androgen receptors and stimulates and regulates the development and maintenance of male sexual characteristics.': $i).
% 28.89/28.93  tff(decl_7771, type, androgen: $i).
% 28.89/28.93  tff(decl_7772, type, sex_hormone_1: $i > $o).
% 28.89/28.93  tff(decl_7773, type, estrogen_1: $i > $o).
% 28.89/28.93  tff(decl_7774, type, cytokinin_1: $i > $o).
% 28.89/28.93  tff(decl_7775, type, progestin_1: $i > $o).
% 28.89/28.93  tff(decl_7776, type, aneuploidy_1: $i > $o).
% 28.89/28.93  tff(decl_7777, type, 'Aneuploidy': $i).
% 28.89/28.93  tff(decl_7778, type, 'An abnormal number of chromosomes.': $i).
% 28.89/28.93  tff(decl_7779, type, aneuploidy: $i).
% 28.89/28.93  tff(decl_7780, type, chromosomal_disorder_cell_1: $i > $o).
% 28.89/28.93  tff(decl_7781, type, 'Angelman-Syndrome': $i).
% 28.89/28.93  tff(decl_7782, type, 'A human genetic disorder caused by loss of the normal maternal expression of a gene on chromosome 15.': $i).
% 28.89/28.93  tff(decl_7783, type, 'angelman syndrome': $i).
% 28.89/28.93  tff(decl_7784, type, 'angelman-syndrome': $i).
% 28.89/28.93  tff(decl_7785, type, angiopserm_plant_development_1: $i > $o).
% 28.89/28.93  tff(decl_7786, type, 'Angiopserm-Plant-Development': $i).
% 28.89/28.93  tff(decl_7787, type, 'Angiosperm plant development includes the formation of a complete embryo from a zygote ; seed germination; the elaboration of a mature vegetative plant from the embryo; the formation of flowers, fruits, and seeds.': $i).
% 28.89/28.93  tff(decl_7788, type, develop: $i).
% 28.89/28.93  tff(decl_7789, type, 'angiopserm plant development': $i).
% 28.89/28.93  tff(decl_7790, type, 'angiopserm-plant-development': $i).
% 28.89/28.93  tff(decl_7791, type, plant_development_1: $i > $o).
% 28.89/28.93  tff(decl_7792, type, fn_angiopserm_plant_development_1: $i > $i).
% 28.89/28.93  tff(decl_7793, type, flower_development_1: $i > $o).
% 28.89/28.93  tff(decl_7794, type, angiosperm_1: $i > $o).
% 28.89/28.93  tff(decl_7795, type, 'Angiosperm': $i).
% 28.89/28.93  tff(decl_7796, type, 'The taxonomic grouping of flowering plants, which produce seeds inside a fleshy ovary, called a fruit.': $i).
% 28.89/28.93  tff(decl_7797, type, 'flowering plant': $i).
% 28.89/28.93  tff(decl_7798, type, 'flowering-plant': $i).
% 28.89/28.93  tff(decl_7799, type, anthophyta: $i).
% 28.89/28.93  tff(decl_7800, type, angiosperm: $i).
% 28.89/28.93  tff(decl_7801, type, seed_plant_1: $i > $o).
% 28.89/28.93  tff(decl_7802, type, gymnosperm_1: $i > $o).
% 28.89/28.93  tff(decl_7803, type, fn_angiosperm_1: $i > $i).
% 28.89/28.93  tff(decl_7804, type, flower_1: $i > $o).
% 28.89/28.93  tff(decl_7805, type, fn_angiosperm_2: $i > $i).
% 28.89/28.93  tff(decl_7806, type, fn_angiosperm_3: $i > $i).
% 28.89/28.93  tff(decl_7807, type, vessel_1: $i > $o).
% 28.89/28.93  tff(decl_7808, type, fn_angiosperm_4: $i > $i).
% 28.89/28.93  tff(decl_7809, type, tracheid_1: $i > $o).
% 28.89/28.93  tff(decl_7810, type, fn_angiosperm_5: $i > $i).
% 28.89/28.93  tff(decl_7811, type, xylem_1: $i > $o).
% 28.89/28.93  tff(decl_7812, type, fn_angiosperm_6: $i > $i).
% 28.89/28.93  tff(decl_7813, type, plant_vein_1: $i > $o).
% 28.89/28.93  tff(decl_7814, type, fn_angiosperm_7: $i > $i).
% 28.89/28.93  tff(decl_7815, type, fn_angiosperm_8: $i > $i).
% 28.89/28.93  tff(decl_7816, type, fn_angiosperm_9: $i > $i).
% 28.89/28.93  tff(decl_7817, type, vessel_element_1: $i > $o).
% 28.89/28.93  tff(decl_7818, type, fn_angiosperm_10: $i > $i).
% 28.89/28.93  tff(decl_7819, type, fn_angiosperm_11: $i > $i).
% 28.89/28.93  tff(decl_7820, type, fn_plant_vein_1: $i > $i).
% 28.89/28.93  tff(decl_7821, type, fn_root_5: $i > $i).
% 28.89/28.93  tff(decl_7822, type, fn_vessel_9: $i > $i).
% 28.89/28.93  tff(decl_7823, type, fn_xylem_15: $i > $i).
% 28.89/28.93  tff(decl_7824, type, fn_vessel_7: $i > $i).
% 28.89/28.93  tff(decl_7825, type, fn_vessel_15: $i > $i).
% 28.89/28.93  tff(decl_7826, type, fn_vessel_8: $i > $i).
% 28.89/28.93  tff(decl_7827, type, fn_seed_plant_15: $i > $i).
% 28.89/28.93  tff(decl_7828, type, 'Angle-Constant': $i).
% 28.89/28.93  tff(decl_7829, type, 'constant of angle': $i).
% 28.89/28.93  tff(decl_7830, type, 'angle constant': $i).
% 28.89/28.93  tff(decl_7831, type, 'angle-constant': $i).
% 28.89/28.93  tff(decl_7832, type, 'Angle-Value': $i).
% 28.89/28.93  tff(decl_7833, type, 'the angle of a Spatial-Entity': $i).
% 28.89/28.93  tff(decl_7834, type, way: $i).
% 28.89/28.93  tff(decl_7835, type, orientation: $i).
% 28.89/28.93  tff(decl_7836, type, meridian: $i).
% 28.89/28.93  tff(decl_7837, type, 'line of longitude': $i).
% 28.89/28.93  tff(decl_7838, type, longitude: $i).
% 28.89/28.93  tff(decl_7839, type, latitude: $i).
% 28.89/28.93  tff(decl_7840, type, direction: $i).
% 28.89/28.93  tff(decl_7841, type, angle: $i).
% 28.89/28.93  tff(decl_7842, type, 'value of angle': $i).
% 28.89/28.93  tff(decl_7843, type, 'angle value': $i).
% 28.89/28.93  tff(decl_7844, type, 'angle-value': $i).
% 28.89/28.93  tff(decl_7845, type, anhydrobiosis_1: $i > $o).
% 28.89/28.93  tff(decl_7846, type, 'Anhydrobiosis': $i).
% 28.89/28.93  tff(decl_7847, type, 'A form of cryptobiosis in which an organism loses almost all of its water and goes into a dormant state.': $i).
% 28.89/28.93  tff(decl_7848, type, anhydrobiosis: $i).
% 28.89/28.93  tff(decl_7849, type, 'Animacy-Constant': $i).
% 28.89/28.93  tff(decl_7850, type, 'animacy constant': $i).
% 28.89/28.93  tff(decl_7851, type, 'animacy-constant': $i).
% 28.89/28.93  tff(decl_7852, type, 'Animacy-Value': $i).
% 28.89/28.93  tff(decl_7853, type, 'the animacy of an Entity': $i).
% 28.89/28.93  tff(decl_7854, type, animateness: $i).
% 28.89/28.93  tff(decl_7855, type, aliveness: $i).
% 28.89/28.93  tff(decl_7856, type, liveness: $i).
% 28.89/28.93  tff(decl_7857, type, animacy: $i).
% 28.89/28.93  tff(decl_7858, type, 'animacy value': $i).
% 28.89/28.93  tff(decl_7859, type, 'animacy-value': $i).
% 28.89/28.93  tff(decl_7860, type, 'Animal': $i).
% 28.89/28.93  tff(decl_7861, type, 'a living entity capable of locomotion': $i).
% 28.89/28.93  tff(decl_7862, type, 'Animal is a kingdom of organisms like Plant, fungi and bacteria': $i).
% 28.89/28.93  tff(decl_7863, type, animal: $i).
% 28.89/28.93  tff(decl_7864, type, 'animate being': $i).
% 28.89/28.93  tff(decl_7865, type, animate_being: $i).
% 28.89/28.93  tff(decl_7866, type, beast: $i).
% 28.89/28.93  tff(decl_7867, type, brute: $i).
% 28.89/28.93  tff(decl_7868, type, creature: $i).
% 28.89/28.93  tff(decl_7869, type, fauna: $i).
% 28.89/28.93  tff(decl_7870, type, tiger: $i).
% 28.89/28.93  tff(decl_7871, type, eukaryote_1: $i > $o).
% 28.89/28.93  tff(decl_7872, type, multicellular_organism_1: $i > $o).
% 28.89/28.93  tff(decl_7873, type, fungus_1: $i > $o).
% 28.89/28.93  tff(decl_7874, type, fn_animal_1: $i > $i).
% 28.89/28.93  tff(decl_7875, type, fn_animal_3: $i > $i).
% 28.89/28.93  tff(decl_7876, type, fn_animal_4: $i > $i).
% 28.89/28.93  tff(decl_7877, type, circulatory_system_1: $i > $o).
% 28.89/28.93  tff(decl_7878, type, fn_animal_6: $i > $i).
% 28.89/28.93  tff(decl_7879, type, fn_animal_7: $i > $i).
% 28.89/28.93  tff(decl_7880, type, fn_animal_8: $i > $i).
% 28.89/28.93  tff(decl_7881, type, fn_animal_9: $i > $i).
% 28.89/28.93  tff(decl_7882, type, fn_animal_10: $i > $i).
% 28.89/28.93  tff(decl_7883, type, diet_1: $i > $o).
% 28.89/28.93  tff(decl_7884, type, fn_animal_11: $i > $i).
% 28.89/28.93  tff(decl_7885, type, fn_animal_12: $i > $i).
% 28.89/28.93  tff(decl_7886, type, fn_animal_13: $i > $i).
% 28.89/28.93  tff(decl_7887, type, fn_animal_14: $i > $i).
% 28.89/28.93  tff(decl_7888, type, fn_animal_15: $i > $i).
% 28.89/28.93  tff(decl_7889, type, fn_animal_16: $i > $i).
% 28.89/28.93  tff(decl_7890, type, fn_animal_17: $i > $i).
% 28.89/28.93  tff(decl_7891, type, fn_animal_20: $i > $i).
% 28.89/28.93  tff(decl_7892, type, fn_animal_21: $i > $i).
% 28.89/28.93  tff(decl_7893, type, fn_animal_22: $i > $i).
% 28.89/28.93  tff(decl_7894, type, fn_animal_23: $i > $i).
% 28.89/28.93  tff(decl_7895, type, fn_animal_24: $i > $i).
% 28.89/28.93  tff(decl_7896, type, fn_animal_25: $i > $i).
% 28.89/28.93  tff(decl_7897, type, fn_animal_26: $i > $i).
% 28.89/28.93  tff(decl_7898, type, fn_animal_nutritional_requirement_62: $i > $i).
% 28.89/28.93  tff(decl_7899, type, fn_heterotroph_5: $i > $i).
% 28.89/28.93  tff(decl_7900, type, fn_heterotroph_3: $i > $i).
% 28.89/28.93  tff(decl_7901, type, fn_carbohydrate_5: $i > $i).
% 28.89/28.93  tff(decl_7902, type, fn_multicellular_organism_1: $i > $i).
% 28.89/28.93  tff(decl_7903, type, fn_animal_28: $i > $i).
% 28.89/28.93  tff(decl_7904, type, fn_animal_27: $i > $i).
% 28.89/28.93  tff(decl_7905, type, animal_appendage_1: $i > $o).
% 28.89/28.93  tff(decl_7906, type, 'Animal-Appendage': $i).
% 28.89/28.93  tff(decl_7907, type, 'An external body part, or natural prolongation, that protrudes from an animal\\s body.': $i).
% 28.89/28.93  tff(decl_7908, type, 'appendage of animal': $i).
% 28.89/28.93  tff(decl_7909, type, 'animal appendage': $i).
% 28.89/28.93  tff(decl_7910, type, 'animal-appendage': $i).
% 28.89/28.93  tff(decl_7911, type, 'Animal-Cell': $i).
% 28.89/28.93  tff(decl_7912, type, 'A type of eukaryotic cell specific to animals.': $i).
% 28.89/28.93  tff(decl_7913, type, 'cell of animal': $i).
% 28.89/28.93  tff(decl_7914, type, 'animal cell': $i).
% 28.89/28.93  tff(decl_7915, type, 'animal-cell': $i).
% 28.89/28.93  tff(decl_7916, type, cell_without_cell_wall_1: $i > $o).
% 28.89/28.93  tff(decl_7917, type, fungal_cell_1: $i > $o).
% 28.89/28.93  tff(decl_7918, type, fn_animal_cell_4: $i > $i).
% 28.89/28.93  tff(decl_7919, type, fn_animal_cell_5: $i > $i).
% 28.89/28.93  tff(decl_7920, type, fn_animal_cell_6: $i > $i).
% 28.89/28.93  tff(decl_7921, type, fn_animal_cell_7: $i > $i).
% 28.89/28.93  tff(decl_7922, type, fn_animal_cell_8: $i > $i).
% 28.89/28.93  tff(decl_7923, type, fn_animal_cell_9: $i > $i).
% 28.89/28.93  tff(decl_7924, type, decomposition_reaction_1: $i > $o).
% 28.89/28.93  tff(decl_7925, type, fn_animal_cell_10: $i > $i).
% 28.89/28.93  tff(decl_7926, type, fn_animal_cell_11: $i > $i).
% 28.89/28.93  tff(decl_7927, type, fn_animal_cell_23: $i > $i).
% 28.89/28.93  tff(decl_7928, type, mitochondrial_membrane_1: $i > $o).
% 28.89/28.93  tff(decl_7929, type, fn_animal_cell_24: $i > $i).
% 28.89/28.93  tff(decl_7930, type, fn_animal_cell_25: $i > $i).
% 28.89/28.93  tff(decl_7931, type, mrna_1: $i > $o).
% 28.89/28.93  tff(decl_7932, type, fn_animal_cell_26: $i > $i).
% 28.89/28.93  tff(decl_7933, type, fn_animal_cell_27: $i > $i).
% 28.89/28.93  tff(decl_7934, type, fn_animal_cell_28: $i > $i).
% 28.89/28.93  tff(decl_7935, type, fn_animal_cell_29: $i > $i).
% 28.89/28.93  tff(decl_7936, type, energy_transformation_by_organism_1: $i > $o).
% 28.89/28.93  tff(decl_7937, type, fn_animal_cell_30: $i > $i).
% 28.89/28.93  tff(decl_7938, type, chemiosmosis_1: $i > $o).
% 28.89/28.93  tff(decl_7939, type, fn_animal_cell_31: $i > $i).
% 28.89/28.93  tff(decl_7940, type, fn_animal_cell_32: $i > $i).
% 28.89/28.93  tff(decl_7941, type, fn_animal_cell_33: $i > $i).
% 28.89/28.93  tff(decl_7942, type, fn_animal_cell_34: $i > $i).
% 28.89/28.93  tff(decl_7943, type, synthesis_of_protein_1: $i > $o).
% 28.89/28.93  tff(decl_7944, type, fn_animal_cell_35: $i > $i).
% 28.89/28.93  tff(decl_7945, type, translation_1: $i > $o).
% 28.89/28.93  tff(decl_7946, type, fn_animal_cell_36: $i > $i).
% 28.89/28.93  tff(decl_7947, type, fn_animal_cell_37: $i > $i).
% 28.89/28.93  tff(decl_7948, type, fn_animal_cell_38: $i > $i).
% 28.89/28.93  tff(decl_7949, type, fn_animal_cell_39: $i > $i).
% 28.89/28.93  tff(decl_7950, type, fn_animal_cell_40: $i > $i).
% 28.89/28.93  tff(decl_7951, type, fn_animal_cell_41: $i > $i).
% 28.89/28.93  tff(decl_7952, type, fn_animal_cell_42: $i > $i).
% 28.89/28.93  tff(decl_7953, type, reactant_1: $i > $o).
% 28.89/28.93  tff(decl_7954, type, fn_animal_cell_43: $i > $i).
% 28.89/28.93  tff(decl_7955, type, fn_animal_cell_44: $i > $i).
% 28.89/28.93  tff(decl_7956, type, fn_animal_cell_46: $i > $i).
% 28.89/28.93  tff(decl_7957, type, fn_animal_cell_47: $i > $i).
% 28.89/28.93  tff(decl_7958, type, fn_animal_cell_48: $i > $i).
% 28.89/28.93  tff(decl_7959, type, fatty_acid_1: $i > $o).
% 28.89/28.93  tff(decl_7960, type, fn_animal_cell_51: $i > $i).
% 28.89/28.93  tff(decl_7961, type, fn_animal_cell_65: $i > $i).
% 28.89/28.93  tff(decl_7962, type, fn_animal_cell_66: $i > $i).
% 28.89/28.93  tff(decl_7963, type, centriole_1: $i > $o).
% 28.89/28.93  tff(decl_7964, type, fn_animal_cell_67: $i > $i).
% 28.89/28.93  tff(decl_7965, type, fn_animal_cell_68: $i > $i).
% 28.89/28.93  tff(decl_7966, type, trimer_1: $i > $o).
% 28.89/28.93  tff(decl_7967, type, fn_animal_cell_69: $i > $i).
% 28.89/28.93  tff(decl_7968, type, fn_animal_cell_70: $i > $i).
% 28.89/28.93  tff(decl_7969, type, fn_animal_cell_71: $i > $i).
% 28.89/28.93  tff(decl_7970, type, fn_animal_cell_72: $i > $i).
% 28.89/28.93  tff(decl_7971, type, fn_animal_cell_77: $i > $i).
% 28.89/28.93  tff(decl_7972, type, extra_cellular_matrix_1: $i > $o).
% 28.89/28.93  tff(decl_7973, type, fn_animal_cell_86: $i > $i).
% 28.89/28.93  tff(decl_7974, type, fn_animal_cell_87: $i > $i).
% 28.89/28.93  tff(decl_7975, type, fn_animal_cell_89: $i > $i).
% 28.89/28.93  tff(decl_7976, type, fn_integrin_2: $i > $i).
% 28.89/28.93  tff(decl_7977, type, fn_golgi_apparatus_11: $i > $i).
% 28.89/28.93  tff(decl_7978, type, fn_golgi_apparatus_10: $i > $i).
% 28.89/28.93  tff(decl_7979, type, fn_golgi_apparatus_86: $i > $i).
% 28.89/28.93  tff(decl_7980, type, fn_golgi_apparatus_87: $i > $i).
% 28.89/28.93  tff(decl_7981, type, fn_golgi_apparatus_93: $i > $i).
% 28.89/28.93  tff(decl_7982, type, fn_golgi_apparatus_65: $i > $i).
% 28.89/28.93  tff(decl_7983, type, fn_centrosome_5: $i > $i).
% 28.89/28.93  tff(decl_7984, type, fn_mitochondrion_54: $i > $i).
% 28.89/28.93  tff(decl_7985, type, fn_reactant_3: $i > $i).
% 28.89/28.93  tff(decl_7986, type, fn_centrosome_2: $i > $i).
% 28.89/28.93  tff(decl_7987, type, fn_peroxisome_15: $i > $i).
% 28.89/28.93  tff(decl_7988, type, fn_peroxisome_14: $i > $i).
% 28.89/28.93  tff(decl_7989, type, fn_peroxisome_43: $i > $i).
% 28.89/28.93  tff(decl_7990, type, fn_peroxisome_12: $i > $i).
% 28.89/28.93  tff(decl_7991, type, fn_peroxisome_13: $i > $i).
% 28.89/28.93  tff(decl_7992, type, fn_mitochondrion_61: $i > $i).
% 28.89/28.93  tff(decl_7993, type, fn_mitochondrion_58: $i > $i).
% 28.89/28.93  tff(decl_7994, type, fn_mitochondrion_64: $i > $i).
% 28.89/28.93  tff(decl_7995, type, fn_mitochondrion_63: $i > $i).
% 28.89/28.93  tff(decl_7996, type, fn_mitochondrion_39: $i > $i).
% 28.89/28.93  tff(decl_7997, type, fn_mitochondrion_62: $i > $i).
% 28.89/28.93  tff(decl_7998, type, fn_mitochondrion_57: $i > $i).
% 28.89/28.93  tff(decl_7999, type, fn_mitochondrion_79: $i > $i).
% 28.89/28.93  tff(decl_8000, type, fn_mitochondrion_2: $i > $i).
% 28.89/28.93  tff(decl_8001, type, fn_mitochondrion_4: $i > $i).
% 28.89/28.93  tff(decl_8002, type, fn_mitochondrion_37: $i > $i).
% 28.89/28.93  tff(decl_8003, type, fn_mitochondrion_1: $i > $i).
% 28.89/28.93  tff(decl_8004, type, fn_mitochondrion_3: $i > $i).
% 28.89/28.93  tff(decl_8005, type, fn_centriole_10: $i > $i).
% 28.89/28.93  tff(decl_8006, type, fn_centrosome_3: $i > $i).
% 28.89/28.93  tff(decl_8007, type, fn_centriole_6: $i > $i).
% 28.89/28.93  tff(decl_8008, type, fn_centriole_7: $i > $i).
% 28.89/28.93  tff(decl_8009, type, fn_animal_plasma_membrane_51: $i > $i).
% 28.89/28.93  tff(decl_8010, type, fn_animal_plasma_membrane_66: $i > $i).
% 28.89/28.93  tff(decl_8011, type, fn_animal_plasma_membrane_52: $i > $i).
% 28.89/28.93  tff(decl_8012, type, fn_animal_plasma_membrane_77: $i > $i).
% 28.89/28.93  tff(decl_8013, type, fn_animal_plasma_membrane_55: $i > $i).
% 28.89/28.93  tff(decl_8014, type, fn_animal_plasma_membrane_67: $i > $i).
% 28.89/28.93  tff(decl_8015, type, fn_integrin_30: $i > $i).
% 28.89/28.93  tff(decl_8016, type, fn_animal_plasma_membrane_62: $i > $i).
% 28.89/28.93  tff(decl_8017, type, fn_animal_plasma_membrane_53: $i > $i).
% 28.89/28.93  tff(decl_8018, type, fn_integrin_8: $i > $i).
% 28.89/28.93  tff(decl_8019, type, fn_animal_plasma_membrane_47: $i > $i).
% 28.89/28.93  tff(decl_8020, type, fn_integrin_9: $i > $i).
% 28.89/28.93  tff(decl_8021, type, fn_animal_plasma_membrane_54: $i > $i).
% 28.89/28.93  tff(decl_8022, type, fn_integrin_29: $i > $i).
% 28.89/28.93  tff(decl_8023, type, fn_mitochondrial_matrix_5: $i > $i).
% 28.89/28.93  tff(decl_8024, type, fn_semiautonomous_organelle_2: $i > $i).
% 28.89/28.93  tff(decl_8025, type, fn_golgi_apparatus_15: $i > $i).
% 28.89/28.93  tff(decl_8026, type, fn_golgi_apparatus_90: $i > $i).
% 28.89/28.93  tff(decl_8027, type, fn_golgi_apparatus_91: $i > $i).
% 28.89/28.93  tff(decl_8028, type, fn_chemiosmosis_118: $i > $i).
% 28.89/28.93  tff(decl_8029, type, fn_animal_plasma_membrane_56: $i > $i).
% 28.89/28.93  tff(decl_8030, type, fn_integrin_6: $i > $i).
% 28.89/28.93  tff(decl_8031, type, fn_golgi_apparatus_22: $i > $i).
% 28.89/28.93  tff(decl_8032, type, fn_reactant_2: $i > $i).
% 28.89/28.93  tff(decl_8033, type, fn_peroxisome_32: $i > $i).
% 28.89/28.93  tff(decl_8034, type, fn_mitochondrial_matrix_4: $i > $i).
% 28.89/28.93  tff(decl_8035, type, fn_mitochondrial_matrix_6: $i > $i).
% 28.89/28.93  tff(decl_8036, type, fn_mitochondrion_38: $i > $i).
% 28.89/28.93  tff(decl_8037, type, fn_centriole_9: $i > $i).
% 28.89/28.93  tff(decl_8038, type, fn_centriole_11: $i > $i).
% 28.89/28.93  tff(decl_8039, type, fn_centriole_2: $i > $i).
% 28.89/28.93  tff(decl_8040, type, fn_centriole_8: $i > $i).
% 28.89/28.93  tff(decl_8041, type, fn_animal_cell_16: $i > $i).
% 28.89/28.93  tff(decl_8042, type, fn_animal_cell_17: $i > $i).
% 28.89/28.93  tff(decl_8043, type, fn_eukaryotic_cell_49: $i > $i).
% 28.89/28.93  tff(decl_8044, type, fn_eukaryotic_cell_61: $i > $i).
% 28.89/28.93  tff(decl_8045, type, fn_animal_cell_91: $i > $i).
% 28.89/28.93  tff(decl_8046, type, fn_animal_cell_92: $i > $i).
% 28.89/28.93  tff(decl_8047, type, fn_animal_cell_14: $i > $i).
% 28.89/28.93  tff(decl_8048, type, fn_animal_cell_15: $i > $i).
% 28.89/28.93  tff(decl_8049, type, animal_cell_centrosome_1: $i > $o).
% 28.89/28.93  tff(decl_8050, type, 'Animal-Cell-Centrosome': $i).
% 28.89/28.93  tff(decl_8051, type, 'Organelle in animal cells which serves as the main microtubule organizing center (MTOC).': $i).
% 28.89/28.93  tff(decl_8052, type, 'animal cell centrosome': $i).
% 28.89/28.93  tff(decl_8053, type, 'animal-cell-centrosome': $i).
% 28.89/28.93  tff(decl_8054, type, fn_animal_cell_centrosome_1: $i > $i).
% 28.89/28.93  tff(decl_8055, type, fn_animal_cell_centrosome_2: $i > $i).
% 28.89/28.93  tff(decl_8056, type, fn_animal_cell_centrosome_3: $i > $i).
% 28.89/28.93  tff(decl_8057, type, fn_animal_cell_centrosome_4: $i > $i).
% 28.89/28.93  tff(decl_8058, type, fn_animal_cell_centrosome_5: $i > $i).
% 28.89/28.93  tff(decl_8059, type, fn_animal_cell_centrosome_6: $i > $i).
% 28.89/28.93  tff(decl_8060, type, fn_animal_cell_centrosome_7: $i > $i).
% 28.89/28.93  tff(decl_8061, type, fn_animal_cell_centrosome_8: $i > $i).
% 28.89/28.93  tff(decl_8062, type, organizing_1: $i > $o).
% 28.89/28.93  tff(decl_8063, type, fn_animal_cell_centrosome_9: $i > $i).
% 28.89/28.93  tff(decl_8064, type, fn_centrosome_1: $i > $i).
% 28.89/28.93  tff(decl_8065, type, fn_centrosome_4: $i > $i).
% 28.89/28.93  tff(decl_8066, type, animal_cell_division_1: $i > $o).
% 28.89/28.93  tff(decl_8067, type, fn_animal_cell_division_9: $i > $i).
% 28.89/28.93  tff(decl_8068, type, 'Animal-Cell-Division': $i).
% 28.89/28.93  tff(decl_8069, type, 'Cell division in animals, signaled by calcium ions in a cell signal transduction event with growth factors.': $i).
% 28.89/28.93  tff(decl_8070, type, 'cell division in animals': $i).
% 28.89/28.93  tff(decl_8071, type, divide: $i).
% 28.89/28.93  tff(decl_8072, type, 'animal cell division': $i).
% 28.89/28.93  tff(decl_8073, type, 'animal-cell-division': $i).
% 28.89/28.93  tff(decl_8074, type, fn_animal_cell_division_1: $i > $i).
% 28.89/28.93  tff(decl_8075, type, fn_animal_cell_division_2: $i > $i).
% 28.89/28.93  tff(decl_8076, type, cell_signaling_1: $i > $o).
% 28.89/28.93  tff(decl_8077, type, fn_animal_cell_division_4: $i > $i).
% 28.89/28.93  tff(decl_8078, type, fn_animal_cell_division_5: $i > $i).
% 28.89/28.93  tff(decl_8079, type, fn_animal_cell_division_6: $i > $i).
% 28.89/28.93  tff(decl_8080, type, fn_animal_cell_division_7: $i > $i).
% 28.89/28.93  tff(decl_8081, type, replication_1: $i > $o).
% 28.89/28.93  tff(decl_8082, type, fn_animal_cell_division_8: $i > $i).
% 28.89/28.93  tff(decl_8083, type, fn_animal_cell_division_10: $i > $i).
% 28.89/28.93  tff(decl_8084, type, fn_cell_division_2: $i > $i).
% 28.89/28.93  tff(decl_8085, type, cell_growth_1: $i > $o).
% 28.89/28.93  tff(decl_8086, type, animal_cell_growth_1: $i > $o).
% 28.89/28.93  tff(decl_8087, type, fn_animal_cell_growth_3: $i > $i).
% 28.89/28.93  tff(decl_8088, type, 'Animal-Cell-Growth': $i).
% 28.89/28.93  tff(decl_8089, type, 'Cell growth in animals triggered by a growth factor at the surface of an animal cell.': $i).
% 28.89/28.93  tff(decl_8090, type, 'cell growth in animals': $i).
% 28.89/28.93  tff(decl_8091, type, grow: $i).
% 28.89/28.93  tff(decl_8092, type, 'animal cell growth': $i).
% 28.89/28.93  tff(decl_8093, type, 'animal-cell-growth': $i).
% 28.89/28.93  tff(decl_8094, type, fn_animal_cell_growth_1: $i > $i).
% 28.89/28.93  tff(decl_8095, type, fn_cell_growth_2: $i > $i).
% 28.89/28.93  tff(decl_8096, type, animal_cell_inside_hypertonic_solution_1: $i > $o).
% 28.89/28.93  tff(decl_8097, type, 'Animal-Cell-Inside-Hypertonic-Solution': $i).
% 28.89/28.93  tff(decl_8098, type, 'A hypertonic solution is a solution having a greater solute concentration than the cytosol. It contains a greater concentration of impermeable solutes on the external side of the membrane. When a cell  cytoplasm is bathed in a hypertonic solution the water will be drawn into the solution and out of the cell by osmosis. If water molecules continue to diffuse out of the cell, it will cause the cell to shrink, or crenate.': $i).
% 28.89/28.93  tff(decl_8099, type, 'animal cell inside hypertonic solution': $i).
% 28.89/28.93  tff(decl_8100, type, 'animal-cell-inside-hypertonic-solution': $i).
% 28.89/28.93  tff(decl_8101, type, cell_without_cell_wall_inside_hypertonic_solution_1: $i > $o).
% 28.89/28.93  tff(decl_8102, type, cell_without_cell_wall_inside_hypotonic_solution_1: $i > $o).
% 28.89/28.93  tff(decl_8103, type, hypotonic_solution_1: $i > $o).
% 28.89/28.93  tff(decl_8104, type, animal_cell_inside_hypotonic_solution_1: $i > $o).
% 28.89/28.93  tff(decl_8105, type, fn_animal_cell_inside_hypotonic_solution_2: $i > $i).
% 28.89/28.93  tff(decl_8106, type, 'Animal-Cell-Inside-Hypotonic-Solution': $i).
% 28.89/28.93  tff(decl_8107, type, 'An animal cell contained in a solution that has a lower concentration of solute than the cytoplasm of the cell.': $i).
% 28.89/28.93  tff(decl_8108, type, 'animal cell inside hypotonic solution': $i).
% 28.89/28.93  tff(decl_8109, type, 'animal-cell-inside-hypotonic-solution': $i).
% 28.89/28.93  tff(decl_8110, type, fn_cell_without_cell_wall_inside_hypotonic_solution_30: $i > $i).
% 28.89/28.93  tff(decl_8111, type, animal_cell_inside_isotonic_solution_1: $i > $o).
% 28.89/28.93  tff(decl_8112, type, 'Animal-Cell-Inside-Isotonic-Solution': $i).
% 28.89/28.93  tff(decl_8113, type, 'An animal cell contained in a solution where the concentration of solute is equal to that in the cell\\s cytoplasm.': $i).
% 28.89/28.93  tff(decl_8114, type, 'animal cell inside isotonic solution': $i).
% 28.89/28.93  tff(decl_8115, type, 'animal-cell-inside-isotonic-solution': $i).
% 28.89/28.93  tff(decl_8116, type, cell_without_cell_wall_inside_isotonic_solution_1: $i > $o).
% 28.89/28.93  tff(decl_8117, type, animal_cell_structure_1: $i > $o).
% 28.89/28.93  tff(decl_8118, type, 'Animal-Cell-Structure': $i).
% 28.89/28.93  tff(decl_8119, type, 'A structure at the cellular level found in animal cells': $i).
% 28.89/28.93  tff(decl_8120, type, 'structure of animal cell': $i).
% 28.89/28.93  tff(decl_8121, type, 'structure-of-animal-cell': $i).
% 28.89/28.93  tff(decl_8122, type, 'animal cell structure': $i).
% 28.89/28.93  tff(decl_8123, type, 'animal-cell-structure': $i).
% 28.89/28.93  tff(decl_8124, type, eukaryotic_cell_structure_1: $i > $o).
% 28.89/28.93  tff(decl_8125, type, animal_development_1: $i > $o).
% 28.89/28.93  tff(decl_8126, type, 'Animal-Development': $i).
% 28.89/28.93  tff(decl_8127, type, 'Animal development includes the processes that lead eventually to the formation of a new animal starting from cells derived from one or more parent individuals.': $i).
% 28.89/28.93  tff(decl_8128, type, 'development of animal': $i).
% 28.89/28.93  tff(decl_8129, type, 'animal development': $i).
% 28.89/28.93  tff(decl_8130, type, 'animal-development': $i).
% 28.89/28.93  tff(decl_8131, type, organismal_development_1: $i > $o).
% 28.89/28.93  tff(decl_8132, type, fn_animal_development_3: $i > $i).
% 28.89/28.93  tff(decl_8133, type, fn_animal_development_4: $i > $i).
% 28.89/28.93  tff(decl_8134, type, fn_animal_development_5: $i > $i).
% 28.89/28.93  tff(decl_8135, type, apoptosis_1: $i > $o).
% 28.89/28.93  tff(decl_8136, type, fn_animal_development_6: $i > $i).
% 28.89/28.93  tff(decl_8137, type, fn_animal_development_7: $i > $i).
% 28.89/28.93  tff(decl_8138, type, fn_animal_development_8: $i > $i).
% 28.89/28.93  tff(decl_8139, type, organ_1: $i > $o).
% 28.89/28.93  tff(decl_8140, type, fn_animal_development_9: $i > $i).
% 28.89/28.93  tff(decl_8141, type, gastrulation_1: $i > $o).
% 28.89/28.93  tff(decl_8142, type, fn_animal_development_10: $i > $i).
% 28.89/28.93  tff(decl_8143, type, organism_maturation_1: $i > $o).
% 28.89/28.93  tff(decl_8144, type, fn_animal_development_11: $i > $i).
% 28.89/28.93  tff(decl_8145, type, fn_animal_development_12: $i > $i).
% 28.89/28.93  tff(decl_8146, type, pattern_formation_1: $i > $o).
% 28.89/28.93  tff(decl_8147, type, fn_animal_development_13: $i > $i).
% 28.89/28.93  tff(decl_8148, type, fn_animal_development_14: $i > $i).
% 28.89/28.93  tff(decl_8149, type, fn_animal_development_15: $i > $i).
% 28.89/28.93  tff(decl_8150, type, fn_animal_development_16: $i > $i).
% 28.89/28.93  tff(decl_8151, type, embryonic_induction_1: $i > $o).
% 28.89/28.93  tff(decl_8152, type, fn_animal_development_17: $i > $i).
% 28.89/28.93  tff(decl_8153, type, fn_animal_development_18: $i > $i).
% 28.89/28.93  tff(decl_8154, type, fn_animal_development_19: $i > $i).
% 28.89/28.93  tff(decl_8155, type, fn_animal_development_20: $i > $i).
% 28.89/28.93  tff(decl_8156, type, fn_animal_development_21: $i > $i).
% 28.89/28.93  tff(decl_8157, type, fn_animal_development_22: $i > $i).
% 28.89/28.93  tff(decl_8158, type, fn_animal_development_23: $i > $i).
% 28.89/28.93  tff(decl_8159, type, tail_1: $i > $o).
% 28.89/28.93  tff(decl_8160, type, fn_animal_development_24: $i > $i).
% 28.89/28.93  tff(decl_8161, type, fn_animal_development_25: $i > $i).
% 28.89/28.93  tff(decl_8162, type, fn_animal_development_26: $i > $i).
% 28.89/28.93  tff(decl_8163, type, fn_animal_development_27: $i > $i).
% 28.89/28.93  tff(decl_8164, type, fn_animal_development_28: $i > $i).
% 28.89/28.93  tff(decl_8165, type, fn_animal_development_29: $i > $i).
% 28.89/28.93  tff(decl_8166, type, fn_animal_development_30: $i > $i).
% 28.89/28.93  tff(decl_8167, type, animal_life_cycle_1: $i > $o).
% 28.89/28.93  tff(decl_8168, type, fn_animal_development_31: $i > $i).
% 28.89/28.93  tff(decl_8169, type, fn_animal_development_32: $i > $i).
% 28.89/28.93  tff(decl_8170, type, damaged_cell_1: $i > $o).
% 28.89/28.93  tff(decl_8171, type, fn_animal_development_33: $i > $i).
% 28.89/28.93  tff(decl_8172, type, fn_animal_development_34: $i > $i).
% 28.89/28.93  tff(decl_8173, type, dead_cell_1: $i > $o).
% 28.89/28.93  tff(decl_8174, type, fn_animal_development_35: $i > $i).
% 28.89/28.93  tff(decl_8175, type, fn_animal_development_36: $i > $i).
% 28.89/28.93  tff(decl_8176, type, fn_animal_development_37: $i > $i).
% 28.89/28.93  tff(decl_8177, type, fn_animal_development_38: $i > $i).
% 28.89/28.93  tff(decl_8178, type, fn_animal_development_39: $i > $i).
% 28.89/28.93  tff(decl_8179, type, fn_animal_development_40: $i > $i).
% 28.89/28.93  tff(decl_8180, type, fn_animal_development_41: $i > $i).
% 28.89/28.93  tff(decl_8181, type, fn_embryogenesis_20: $i > $i).
% 28.89/28.93  tff(decl_8182, type, cell_differentiation_induction_1: $i > $o).
% 28.89/28.93  tff(decl_8183, type, fn_life_cycle_2: $i > $i).
% 28.89/28.93  tff(decl_8184, type, fn_pattern_formation_6: $i > $i).
% 28.89/28.93  tff(decl_8185, type, fn_eight_cell_stage_2: $i > $i).
% 28.89/28.93  tff(decl_8186, type, fn_eight_cell_stage_1: $i > $i).
% 28.89/28.93  tff(decl_8187, type, cellular_process_0: $i).
% 28.89/28.93  tff(decl_8188, type, fn_organismal_development_1: $i > $i).
% 28.89/28.93  tff(decl_8189, type, 'Animal-Development-Cell': $i).
% 28.89/28.93  tff(decl_8190, type, 'An animal cell that is involved in the process of development, either into a new organism, or into tissues or organs.': $i).
% 28.89/28.93  tff(decl_8191, type, 'animal development cell': $i).
% 28.89/28.93  tff(decl_8192, type, 'animal-development-cell': $i).
% 28.89/28.93  tff(decl_8193, type, 'Animal-Embryo': $i).
% 28.89/28.93  tff(decl_8194, type, 'The early developmental stage of an animal while it is in the egg or within the uterus of the mother is called an animal embryo.': $i).
% 28.89/28.93  tff(decl_8195, type, 'embryo of animal': $i).
% 28.89/28.93  tff(decl_8196, type, 'animal embryo': $i).
% 28.89/28.93  tff(decl_8197, type, 'animal-embryo': $i).
% 28.89/28.93  tff(decl_8198, type, fn_animal_embryo_1: $i > $i).
% 28.89/28.93  tff(decl_8199, type, fn_animal_embryo_2: $i > $i).
% 28.89/28.93  tff(decl_8200, type, interpret_1: $i > $o).
% 28.89/28.93  tff(decl_8201, type, fn_animal_embryo_3: $i > $i).
% 28.89/28.93  tff(decl_8202, type, convey_1: $i > $o).
% 28.89/28.93  tff(decl_8203, type, fn_animal_embryo_4: $i > $i).
% 28.89/28.93  tff(decl_8204, type, communicate_1: $i > $o).
% 28.89/28.93  tff(decl_8205, type, fn_animal_embryo_5: $i > $i).
% 28.89/28.93  tff(decl_8206, type, fn_animal_embryo_6: $i > $i).
% 28.89/28.93  tff(decl_8207, type, fn_animal_embryo_7: $i > $i).
% 28.89/28.93  tff(decl_8208, type, fn_animal_embryo_8: $i > $i).
% 28.89/28.93  tff(decl_8209, type, gap_junction_1: $i > $o).
% 28.89/28.93  tff(decl_8210, type, fn_animal_embryo_9: $i > $i).
% 28.89/28.93  tff(decl_8211, type, fn_gap_junction_9: $i > $i).
% 28.89/28.93  tff(decl_8212, type, fn_cell_30: $i > $i).
% 28.89/28.93  tff(decl_8213, type, fn_convey_1: $i > $i).
% 28.89/28.93  tff(decl_8214, type, fn_interpret_2: $i > $i).
% 28.89/28.93  tff(decl_8215, type, fn_communicate_1: $i > $i).
% 28.89/28.93  tff(decl_8216, type, fn_gap_junction_10: $i > $i).
% 28.89/28.93  tff(decl_8217, type, fn_embryo_1: $i > $i).
% 28.89/28.93  tff(decl_8218, type, 'Animal-Fertilization': $i).
% 28.89/28.93  tff(decl_8219, type, 'The union of haploid gametes to produce a diploid zygote in animals.': $i).
% 28.89/28.93  tff(decl_8220, type, fertilize: $i).
% 28.89/28.93  tff(decl_8221, type, 'fertilization of animal': $i).
% 28.89/28.93  tff(decl_8222, type, 'animal fertilization': $i).
% 28.89/28.93  tff(decl_8223, type, 'animal-fertilization': $i).
% 28.89/28.93  tff(decl_8224, type, animal_growth_1: $i > $o).
% 28.89/28.93  tff(decl_8225, type, 'Animal-Growth': $i).
% 28.89/28.93  tff(decl_8226, type, 'Series of events, including cell division, which result in the growth of an animal\\s body.': $i).
% 28.89/28.93  tff(decl_8227, type, 'growth of animal': $i).
% 28.89/28.93  tff(decl_8228, type, 'animal growth': $i).
% 28.89/28.93  tff(decl_8229, type, 'animal-growth': $i).
% 28.89/28.93  tff(decl_8230, type, macrophysiological_process_1: $i > $o).
% 28.89/28.93  tff(decl_8231, type, fn_animal_growth_1: $i > $i).
% 28.89/28.93  tff(decl_8232, type, fn_animal_growth_2: $i > $i).
% 28.89/28.93  tff(decl_8233, type, fn_animal_growth_5: $i > $i).
% 28.89/28.93  tff(decl_8234, type, fn_animal_growth_6: $i > $i).
% 28.89/28.93  tff(decl_8235, type, fn_animal_growth_7: $i > $i).
% 28.89/28.93  tff(decl_8236, type, cell_cycle_process_0: $i).
% 28.89/28.93  tff(decl_8237, type, animal_husbandry_1: $i > $o).
% 28.89/28.93  tff(decl_8238, type, 'Animal-Husbandry': $i).
% 28.89/28.93  tff(decl_8239, type, 'An agricultural process involving the breeding and care of animal livestock.': $i).
% 28.89/28.93  tff(decl_8240, type, 'husbandry of animal': $i).
% 28.89/28.93  tff(decl_8241, type, 'animal husbandry': $i).
% 28.89/28.93  tff(decl_8242, type, 'animal-husbandry': $i).
% 28.89/28.93  tff(decl_8243, type, crop_rotation_1: $i > $o).
% 28.89/28.93  tff(decl_8244, type, hydroponic_culture_1: $i > $o).
% 28.89/28.93  tff(decl_8245, type, irrigation_1: $i > $o).
% 28.89/28.93  tff(decl_8246, type, logging_1: $i > $o).
% 28.89/28.93  tff(decl_8247, type, monoculture_1: $i > $o).
% 28.89/28.93  tff(decl_8248, type, no_till_agriculture_1: $i > $o).
% 28.89/28.93  tff(decl_8249, type, sustainable_agriculture_1: $i > $o).
% 28.89/28.93  tff(decl_8250, type, vernalization_1: $i > $o).
% 28.89/28.93  tff(decl_8251, type, life_cycle_1: $i > $o).
% 28.89/28.93  tff(decl_8252, type, fn_animal_life_cycle_11: $i > $i).
% 28.89/28.93  tff(decl_8253, type, 'Animal-Life-Cycle': $i).
% 28.89/28.93  tff(decl_8254, type, 'The sequence of developmental stages an animal undergoes from one generation to the next beginning with the fusion of male and female gametes, then growth to reproductive maturity, and finally the animal\\s production of gametes.  The cycle begins again at this point, assuming the gametes are fertilized.': $i).
% 28.89/28.93  tff(decl_8255, type, 'undergo the animal life cycle': $i).
% 28.89/28.93  tff(decl_8256, type, 'animal life cycle': $i).
% 28.89/28.93  tff(decl_8257, type, 'animal-life-cycle': $i).
% 28.89/28.93  tff(decl_8258, type, determinate_growth_1: $i > $o).
% 28.89/28.93  tff(decl_8259, type, fungal_life_cycle_1: $i > $o).
% 28.89/28.93  tff(decl_8260, type, iteroparity_1: $i > $o).
% 28.89/28.93  tff(decl_8261, type, life_history_1: $i > $o).
% 28.89/28.93  tff(decl_8262, type, morphogenesis_1: $i > $o).
% 28.89/28.93  tff(decl_8263, type, muscle_cell_determination_1: $i > $o).
% 28.89/28.93  tff(decl_8264, type, plant_life_cycle_1: $i > $o).
% 28.89/28.93  tff(decl_8265, type, sexual_life_cycle_1: $i > $o).
% 28.89/28.93  tff(decl_8266, type, skeletal_muscle_cell_differentiation_1: $i > $o).
% 28.89/28.93  tff(decl_8267, type, fn_animal_life_cycle_1: $i > $i).
% 28.89/28.93  tff(decl_8268, type, fn_animal_life_cycle_2: $i > $i).
% 28.89/28.93  tff(decl_8269, type, cell_differentiation_1: $i > $o).
% 28.89/28.93  tff(decl_8270, type, fn_animal_life_cycle_3: $i > $i).
% 28.89/28.93  tff(decl_8271, type, sexual_intercourse_1: $i > $o).
% 28.89/28.93  tff(decl_8272, type, fn_animal_life_cycle_4: $i > $i).
% 28.89/28.93  tff(decl_8273, type, fn_animal_life_cycle_5: $i > $i).
% 28.89/28.93  tff(decl_8274, type, ovary_1: $i > $o).
% 28.89/28.93  tff(decl_8275, type, fn_animal_life_cycle_6: $i > $i).
% 28.89/28.93  tff(decl_8276, type, testes_1: $i > $o).
% 28.89/28.93  tff(decl_8277, type, fn_animal_life_cycle_8: $i > $i).
% 28.89/28.93  tff(decl_8278, type, fn_animal_life_cycle_9: $i > $i).
% 28.89/28.93  tff(decl_8279, type, fn_animal_life_cycle_10: $i > $i).
% 28.89/28.93  tff(decl_8280, type, zygote_1: $i > $o).
% 28.89/28.93  tff(decl_8281, type, fn_animal_life_cycle_12: $i > $i).
% 28.89/28.93  tff(decl_8282, type, fn_animal_life_cycle_13: $i > $i).
% 28.89/28.93  tff(decl_8283, type, fn_animal_life_cycle_14: $i > $i).
% 28.89/28.93  tff(decl_8284, type, diploid_cell_1: $i > $o).
% 28.89/28.93  tff(decl_8285, type, fn_animal_life_cycle_15: $i > $i).
% 28.89/28.93  tff(decl_8286, type, fn_animal_life_cycle_16: $i > $i).
% 28.89/28.93  tff(decl_8287, type, fn_fertilization_1: $i > $i).
% 28.89/28.93  tff(decl_8288, type, fn_meiosis_17: $i > $i).
% 28.89/28.93  tff(decl_8289, type, meiosis_0: $i).
% 28.89/28.93  tff(decl_8290, type, animal_meiotic_cycle_1: $i > $o).
% 28.89/28.93  tff(decl_8291, type, 'Animal-Meiotic-Cycle': $i).
% 28.89/28.93  tff(decl_8292, type, 'An ordered sequence of events in which a parent sex cell divides to make 4 daughter cells which are gametes.  The cell cycle includes interphase followed by meoisis (inclusive of cytokinesis).': $i).
% 28.89/28.93  tff(decl_8293, type, 'undergo the meiotic cell cycle': $i).
% 28.89/28.93  tff(decl_8294, type, 'animal meiotic cycle': $i).
% 28.89/28.93  tff(decl_8295, type, 'animal-meiotic-cycle': $i).
% 28.89/28.93  tff(decl_8296, type, meiotic_cell_cycle_1: $i > $o).
% 28.89/28.93  tff(decl_8297, type, fn_animal_meiotic_cycle_1: $i > $i).
% 28.89/28.93  tff(decl_8298, type, fn_animal_meiotic_cycle_2: $i > $i).
% 28.89/28.93  tff(decl_8299, type, fn_eukaryotic_cell_cycle_1: $i > $i).
% 28.89/28.93  tff(decl_8300, type, fn_eukaryotic_cell_cycle_3: $i > $i).
% 28.89/28.93  tff(decl_8301, type, animal_mitotic_cycle_1: $i > $o).
% 28.89/28.93  tff(decl_8302, type, 'Animal-Mitotic-Cycle': $i).
% 28.89/28.93  tff(decl_8303, type, 'An ordered sequence of events in which a parent somatic cell is divided to produce two somatic daughter cells.  The eukaryotic cell cycle is composed of interphase (including G1, S, and G2 subphases) and M phase (including mitosis and cytokinesis).': $i).
% 28.89/28.93  tff(decl_8304, type, 'undergo the mitotic cell cycle': $i).
% 28.89/28.93  tff(decl_8305, type, 'animal mitotic cycle': $i).
% 28.89/28.93  tff(decl_8306, type, 'animal-mitotic-cycle': $i).
% 28.89/28.93  tff(decl_8307, type, mitotic_cell_cycle_1: $i > $o).
% 28.89/28.93  tff(decl_8308, type, fn_animal_mitotic_cycle_1: $i > $i).
% 28.89/28.93  tff(decl_8309, type, fn_animal_mitotic_cycle_2: $i > $i).
% 28.89/28.93  tff(decl_8310, type, fn_animal_mitotic_cycle_3: $i > $i).
% 28.89/28.93  tff(decl_8311, type, fn_animal_mitotic_cycle_4: $i > $i).
% 28.89/28.93  tff(decl_8312, type, fn_animal_mitotic_cycle_5: $i > $i).
% 28.89/28.93  tff(decl_8313, type, fn_animal_mitotic_cycle_6: $i > $i).
% 28.89/28.93  tff(decl_8314, type, fn_animal_mitotic_cycle_7: $i > $i).
% 28.89/28.93  tff(decl_8315, type, fn_animal_mitotic_cycle_8: $i > $i).
% 28.89/28.93  tff(decl_8316, type, fn_animal_mitotic_cycle_9: $i > $i).
% 28.89/28.93  tff(decl_8317, type, fn_animal_mitotic_cycle_10: $i > $i).
% 28.89/28.93  tff(decl_8318, type, fn_animal_mitotic_cycle_13: $i > $i).
% 28.89/28.93  tff(decl_8319, type, fn_animal_mitotic_cycle_14: $i > $i).
% 28.89/28.93  tff(decl_8320, type, fn_animal_mitotic_cycle_15: $i > $i).
% 28.89/28.93  tff(decl_8321, type, fn_animal_mitotic_cycle_16: $i > $i).
% 28.89/28.93  tff(decl_8322, type, fn_animal_mitotic_cycle_17: $i > $i).
% 28.89/28.93  tff(decl_8323, type, copy_1: $i > $o).
% 28.89/28.93  tff(decl_8324, type, fn_animal_mitotic_cycle_18: $i > $i).
% 28.89/28.93  tff(decl_8325, type, fn_animal_mitotic_cycle_19: $i > $i).
% 28.89/28.93  tff(decl_8326, type, fn_animal_mitotic_cycle_20: $i > $i).
% 28.89/28.93  tff(decl_8327, type, fn_animal_mitotic_cycle_21: $i > $i).
% 28.89/28.93  tff(decl_8328, type, fn_animal_mitotic_cycle_22: $i > $i).
% 28.89/28.93  tff(decl_8329, type, fn_animal_mitotic_cycle_23: $i > $i).
% 28.89/28.93  tff(decl_8330, type, fn_animal_mitotic_cycle_24: $i > $i).
% 28.89/28.93  tff(decl_8331, type, diploid_chromosome_1: $i > $o).
% 28.89/28.93  tff(decl_8332, type, fn_animal_mitotic_cycle_25: $i > $i).
% 28.89/28.93  tff(decl_8333, type, fn_animal_mitotic_cycle_26: $i > $i).
% 28.89/28.93  tff(decl_8334, type, fn_animal_mitotic_cycle_27: $i > $i).
% 28.89/28.93  tff(decl_8335, type, interphase_1: $i > $o).
% 28.89/28.93  tff(decl_8336, type, fn_copy_1: $i > $i).
% 28.89/28.93  tff(decl_8337, type, centrosome_0: $i).
% 28.89/28.93  tff(decl_8338, type, fn_mitotic_cell_cycle_31: $i > $i).
% 28.89/28.93  tff(decl_8339, type, fn_mitotic_cell_cycle_28: $i > $i).
% 28.89/28.93  tff(decl_8340, type, fn_animal_mitotic_cycle_11: $i > $i).
% 28.89/28.93  tff(decl_8341, type, fn_mitotic_cell_cycle_2: $i > $i).
% 28.89/28.93  tff(decl_8342, type, fn_mitotic_cell_cycle_5: $i > $i).
% 28.89/28.93  tff(decl_8343, type, fn_animal_mitotic_cycle_12: $i > $i).
% 28.89/28.93  tff(decl_8344, type, fn_mitotic_cell_cycle_1: $i > $i).
% 28.89/28.93  tff(decl_8345, type, fn_mitotic_cell_cycle_3: $i > $i).
% 28.89/28.93  tff(decl_8346, type, fn_mitotic_cell_cycle_4: $i > $i).
% 28.89/28.93  tff(decl_8347, type, fn_mitotic_cell_cycle_18: $i > $i).
% 28.89/28.93  tff(decl_8348, type, fn_mitotic_cell_cycle_53: $i > $i).
% 28.89/28.93  tff(decl_8349, type, fn_mitotic_cell_cycle_26: $i > $i).
% 28.89/28.93  tff(decl_8350, type, fn_mitotic_cell_cycle_51: $i > $i).
% 28.89/28.93  tff(decl_8351, type, fn_mitotic_cell_cycle_11: $i > $i).
% 28.89/28.93  tff(decl_8352, type, fn_mitotic_cell_cycle_50: $i > $i).
% 28.89/28.93  tff(decl_8353, type, animal_mitotic_spindle_1: $i > $o).
% 28.89/28.93  tff(decl_8354, type, 'Animal-Mitotic-Spindle': $i).
% 28.89/28.93  tff(decl_8355, type, 'Spindle shaped structure which is responsible for the separation and segregation of the chromosomes during mitosis in animal cells.': $i).
% 28.89/28.93  tff(decl_8356, type, 'animal mitotic spindle': $i).
% 28.89/28.93  tff(decl_8357, type, 'animal-mitotic-spindle': $i).
% 28.89/28.93  tff(decl_8358, type, fn_animal_mitotic_spindle_1: $i > $i).
% 28.89/28.93  tff(decl_8359, type, aster_1: $i > $o).
% 28.89/28.93  tff(decl_8360, type, 'Animal-Nutritional-Requirement': $i).
% 28.89/28.93  tff(decl_8361, type, 'Chemicals and elements found in food that are needed by animals in order to sustain healthy life': $i).
% 28.89/28.93  tff(decl_8362, type, 'animal nutritional requirement': $i).
% 28.89/28.93  tff(decl_8363, type, 'animal-nutritional-requirement': $i).
% 28.89/28.93  tff(decl_8364, type, fn_animal_nutritional_requirement_3: $i > $i).
% 28.89/28.93  tff(decl_8365, type, fn_animal_nutritional_requirement_5: $i > $i).
% 28.89/28.93  tff(decl_8366, type, fn_animal_nutritional_requirement_7: $i > $i).
% 28.89/28.93  tff(decl_8367, type, fn_animal_nutritional_requirement_8: $i > $i).
% 28.89/28.93  tff(decl_8368, type, mineral_1: $i > $o).
% 28.89/28.93  tff(decl_8369, type, fn_animal_nutritional_requirement_9: $i > $i).
% 28.89/28.93  tff(decl_8370, type, vitamin_1: $i > $o).
% 28.89/28.93  tff(decl_8371, type, fn_animal_nutritional_requirement_10: $i > $i).
% 28.89/28.93  tff(decl_8372, type, fn_animal_nutritional_requirement_11: $i > $i).
% 28.89/28.93  tff(decl_8373, type, fn_animal_nutritional_requirement_12: $i > $i).
% 28.89/28.93  tff(decl_8374, type, phenylalanine_1: $i > $o).
% 28.89/28.93  tff(decl_8375, type, fn_animal_nutritional_requirement_13: $i > $i).
% 28.89/28.93  tff(decl_8376, type, methionine_1: $i > $o).
% 28.89/28.93  tff(decl_8377, type, fn_animal_nutritional_requirement_14: $i > $i).
% 28.89/28.93  tff(decl_8378, type, isoleucine_1: $i > $o).
% 28.89/28.93  tff(decl_8379, type, fn_animal_nutritional_requirement_15: $i > $i).
% 28.89/28.93  tff(decl_8380, type, threonine_1: $i > $o).
% 28.89/28.93  tff(decl_8381, type, fn_animal_nutritional_requirement_16: $i > $i).
% 28.89/28.93  tff(decl_8382, type, arginine_1: $i > $o).
% 28.89/28.93  tff(decl_8383, type, fn_animal_nutritional_requirement_17: $i > $i).
% 28.89/28.93  tff(decl_8384, type, leucine_1: $i > $o).
% 28.89/28.93  tff(decl_8385, type, fn_animal_nutritional_requirement_18: $i > $i).
% 28.89/28.93  tff(decl_8386, type, tryptophan_1: $i > $o).
% 28.89/28.93  tff(decl_8387, type, fn_animal_nutritional_requirement_19: $i > $i).
% 28.89/28.93  tff(decl_8388, type, valine_1: $i > $o).
% 28.89/28.93  tff(decl_8389, type, fn_animal_nutritional_requirement_20: $i > $i).
% 28.89/28.93  tff(decl_8390, type, fn_animal_nutritional_requirement_21: $i > $i).
% 28.89/28.93  tff(decl_8391, type, fn_animal_nutritional_requirement_22: $i > $i).
% 28.89/28.93  tff(decl_8392, type, fn_animal_nutritional_requirement_23: $i > $i).
% 28.89/28.93  tff(decl_8393, type, fn_animal_nutritional_requirement_24: $i > $i).
% 28.89/28.93  tff(decl_8394, type, fn_animal_nutritional_requirement_26: $i > $i).
% 28.89/28.93  tff(decl_8395, type, fn_animal_nutritional_requirement_27: $i > $i).
% 28.89/28.93  tff(decl_8396, type, unsaturated_fatty_acid_1: $i > $o).
% 28.89/28.93  tff(decl_8397, type, fn_animal_nutritional_requirement_31: $i > $i).
% 28.89/28.93  tff(decl_8398, type, fn_animal_nutritional_requirement_32: $i > $i).
% 28.89/28.93  tff(decl_8399, type, fn_animal_nutritional_requirement_33: $i > $i).
% 28.89/28.93  tff(decl_8400, type, fn_animal_nutritional_requirement_36: $i > $i).
% 28.89/28.93  tff(decl_8401, type, fn_animal_nutritional_requirement_37: $i > $i).
% 28.89/28.93  tff(decl_8402, type, fn_animal_nutritional_requirement_39: $i > $i).
% 28.89/28.93  tff(decl_8403, type, fn_animal_nutritional_requirement_43: $i > $i).
% 28.89/28.93  tff(decl_8404, type, fn_animal_nutritional_requirement_44: $i > $i).
% 28.89/28.93  tff(decl_8405, type, fn_animal_nutritional_requirement_45: $i > $i).
% 28.89/28.93  tff(decl_8406, type, fn_animal_nutritional_requirement_47: $i > $i).
% 28.89/28.93  tff(decl_8407, type, fn_animal_nutritional_requirement_49: $i > $i).
% 28.89/28.93  tff(decl_8408, type, fn_animal_nutritional_requirement_50: $i > $i).
% 28.89/28.93  tff(decl_8409, type, fn_animal_nutritional_requirement_51: $i > $i).
% 28.89/28.93  tff(decl_8410, type, fn_animal_nutritional_requirement_55: $i > $i).
% 28.89/28.93  tff(decl_8411, type, fn_animal_nutritional_requirement_56: $i > $i).
% 28.89/28.93  tff(decl_8412, type, fn_animal_nutritional_requirement_57: $i > $i).
% 28.89/28.93  tff(decl_8413, type, fn_animal_nutritional_requirement_58: $i > $i).
% 28.89/28.93  tff(decl_8414, type, fn_animal_nutritional_requirement_59: $i > $i).
% 28.89/28.93  tff(decl_8415, type, fn_animal_nutritional_requirement_60: $i > $i).
% 28.89/28.93  tff(decl_8416, type, fn_carbohydrate_35: $i > $i).
% 28.89/28.93  tff(decl_8417, type, "0.0e0": $i).
% 28.89/28.93  tff(decl_8418, type, mass_electron: $i).
% 28.89/28.93  tff(decl_8419, type, "1.0e0": $i).
% 28.89/28.93  tff(decl_8420, type, mass_proton: $i).
% 28.89/28.93  tff(decl_8421, type, 'Animal-Organ': $i).
% 28.89/28.93  tff(decl_8422, type, 'A collection of tissues working together in a structural unit in an animal\\s body.': $i).
% 28.89/28.93  tff(decl_8423, type, 'organ of animal': $i).
% 28.89/28.93  tff(decl_8424, type, 'animal organ': $i).
% 28.89/28.93  tff(decl_8425, type, 'animal-organ': $i).
% 28.89/28.93  tff(decl_8426, type, animal_orientation_1: $i > $o).
% 28.89/28.93  tff(decl_8427, type, 'Animal-Orientation': $i).
% 28.89/28.93  tff(decl_8428, type, 'When an animal detects compass directions and travels in a particular straight-line path for a certain distance or until it reaches its destination.': $i).
% 28.89/28.93  tff(decl_8429, type, 'orientation of animal': $i).
% 28.89/28.93  tff(decl_8430, type, 'animal orientation': $i).
% 28.89/28.93  tff(decl_8431, type, 'animal-orientation': $i).
% 28.89/28.93  tff(decl_8432, type, migration_1: $i > $o).
% 28.89/28.93  tff(decl_8433, type, piloting_1: $i > $o).
% 28.89/28.93  tff(decl_8434, type, navigation_1: $i > $o).
% 28.89/28.93  tff(decl_8435, type, 'Animal-Plasma-Membrane': $i).
% 28.89/28.93  tff(decl_8436, type, 'Plasma membrane found in animal cells': $i).
% 28.89/28.93  tff(decl_8437, type, 'animal cell membrane': $i).
% 28.89/28.93  tff(decl_8438, type, 'animal-cell-membrane': $i).
% 28.89/28.93  tff(decl_8439, type, 'animal membrane': $i).
% 28.89/28.93  tff(decl_8440, type, 'animal-membrane': $i).
% 28.89/28.93  tff(decl_8441, type, 'animal plasma membrane': $i).
% 28.89/28.93  tff(decl_8442, type, 'animal-plasma-membrane': $i).
% 28.89/28.93  tff(decl_8443, type, fn_animal_plasma_membrane_1: $i > $i).
% 28.89/28.93  tff(decl_8444, type, fn_animal_plasma_membrane_2: $i > $i).
% 28.89/28.93  tff(decl_8445, type, fn_animal_plasma_membrane_3: $i > $i).
% 28.89/28.93  tff(decl_8446, type, fn_animal_plasma_membrane_4: $i > $i).
% 28.89/28.93  tff(decl_8447, type, fn_animal_plasma_membrane_5: $i > $i).
% 28.89/28.93  tff(decl_8448, type, fn_animal_plasma_membrane_6: $i > $i).
% 28.89/28.93  tff(decl_8449, type, fn_animal_plasma_membrane_7: $i > $i).
% 28.89/28.93  tff(decl_8450, type, restrain_1: $i > $o).
% 28.89/28.93  tff(decl_8451, type, fn_animal_plasma_membrane_8: $i > $i).
% 28.89/28.93  tff(decl_8452, type, fn_animal_plasma_membrane_9: $i > $i).
% 28.89/28.93  tff(decl_8453, type, fn_animal_plasma_membrane_10: $i > $i).
% 28.89/28.93  tff(decl_8454, type, fn_animal_plasma_membrane_11: $i > $i).
% 28.89/28.93  tff(decl_8455, type, fn_animal_plasma_membrane_12: $i > $i).
% 28.89/28.93  tff(decl_8456, type, fn_animal_plasma_membrane_13: $i > $i).
% 28.89/28.93  tff(decl_8457, type, fn_animal_plasma_membrane_14: $i > $i).
% 28.89/28.93  tff(decl_8458, type, fn_animal_plasma_membrane_15: $i > $i).
% 28.89/28.93  tff(decl_8459, type, fn_animal_plasma_membrane_16: $i > $i).
% 28.89/28.93  tff(decl_8460, type, fn_animal_plasma_membrane_17: $i > $i).
% 28.89/28.93  tff(decl_8461, type, fn_animal_plasma_membrane_18: $i > $i).
% 28.89/28.93  tff(decl_8462, type, fn_animal_plasma_membrane_19: $i > $i).
% 28.89/28.93  tff(decl_8463, type, fn_animal_plasma_membrane_20: $i > $i).
% 28.89/28.93  tff(decl_8464, type, fn_animal_plasma_membrane_21: $i > $i).
% 28.89/28.93  tff(decl_8465, type, fn_animal_plasma_membrane_22: $i > $i).
% 28.89/28.93  tff(decl_8466, type, fn_animal_plasma_membrane_23: $i > $i).
% 28.89/28.93  tff(decl_8467, type, fn_animal_plasma_membrane_24: $i > $i).
% 28.89/28.93  tff(decl_8468, type, fn_animal_plasma_membrane_28: $i > $i).
% 28.89/28.93  tff(decl_8469, type, saturated_fatty_acid_1: $i > $o).
% 28.89/28.93  tff(decl_8470, type, fn_animal_plasma_membrane_29: $i > $i).
% 28.89/28.93  tff(decl_8471, type, fn_animal_plasma_membrane_30: $i > $i).
% 28.89/28.93  tff(decl_8472, type, fn_animal_plasma_membrane_31: $i > $i).
% 28.89/28.93  tff(decl_8473, type, fn_animal_plasma_membrane_32: $i > $i).
% 28.89/28.93  tff(decl_8474, type, fn_animal_plasma_membrane_33: $i > $i).
% 28.89/28.93  tff(decl_8475, type, fn_animal_plasma_membrane_34: $i > $i).
% 28.89/28.93  tff(decl_8476, type, fn_animal_plasma_membrane_35: $i > $i).
% 28.89/28.93  tff(decl_8477, type, fn_animal_plasma_membrane_36: $i > $i).
% 28.89/28.93  tff(decl_8478, type, fn_animal_plasma_membrane_37: $i > $i).
% 28.89/28.93  tff(decl_8479, type, hydrophilic_head_1: $i > $o).
% 28.89/28.93  tff(decl_8480, type, fn_animal_plasma_membrane_38: $i > $i).
% 28.89/28.93  tff(decl_8481, type, fn_animal_plasma_membrane_39: $i > $i).
% 28.89/28.93  tff(decl_8482, type, fn_animal_plasma_membrane_40: $i > $i).
% 28.89/28.93  tff(decl_8483, type, fn_animal_plasma_membrane_41: $i > $i).
% 28.89/28.93  tff(decl_8484, type, fn_animal_plasma_membrane_42: $i > $i).
% 28.89/28.93  tff(decl_8485, type, fn_animal_plasma_membrane_43: $i > $i).
% 28.89/28.93  tff(decl_8486, type, carbohydrate_side_chain_1: $i > $o).
% 28.89/28.93  tff(decl_8487, type, fn_animal_plasma_membrane_44: $i > $i).
% 28.89/28.93  tff(decl_8488, type, fn_animal_plasma_membrane_45: $i > $i).
% 28.89/28.93  tff(decl_8489, type, fn_animal_plasma_membrane_46: $i > $i).
% 28.89/28.93  tff(decl_8490, type, fn_animal_plasma_membrane_48: $i > $i).
% 28.89/28.93  tff(decl_8491, type, directed_motion_1: $i > $o).
% 28.89/28.93  tff(decl_8492, type, fn_animal_plasma_membrane_49: $i > $i).
% 28.89/28.93  tff(decl_8493, type, fn_animal_plasma_membrane_50: $i > $i).
% 28.89/28.93  tff(decl_8494, type, fn_animal_plasma_membrane_57: $i > $i).
% 28.89/28.93  tff(decl_8495, type, fn_animal_plasma_membrane_58: $i > $i).
% 28.89/28.93  tff(decl_8496, type, fn_animal_plasma_membrane_59: $i > $i).
% 28.89/28.93  tff(decl_8497, type, fn_animal_plasma_membrane_60: $i > $i).
% 28.89/28.93  tff(decl_8498, type, fn_animal_plasma_membrane_61: $i > $i).
% 28.89/28.93  tff(decl_8499, type, fn_animal_plasma_membrane_63: $i > $i).
% 28.89/28.93  tff(decl_8500, type, fn_animal_plasma_membrane_64: $i > $i).
% 28.89/28.93  tff(decl_8501, type, fn_animal_plasma_membrane_65: $i > $i).
% 28.89/28.93  tff(decl_8502, type, fn_animal_plasma_membrane_68: $i > $i).
% 28.89/28.93  tff(decl_8503, type, fn_animal_plasma_membrane_69: $i > $i).
% 28.89/28.93  tff(decl_8504, type, fn_animal_plasma_membrane_70: $i > $i).
% 28.89/28.93  tff(decl_8505, type, fn_animal_plasma_membrane_71: $i > $i).
% 28.89/28.93  tff(decl_8506, type, fn_animal_plasma_membrane_72: $i > $i).
% 28.89/28.93  tff(decl_8507, type, fn_animal_plasma_membrane_73: $i > $i).
% 28.89/28.93  tff(decl_8508, type, fn_animal_plasma_membrane_74: $i > $i).
% 28.89/28.93  tff(decl_8509, type, fn_animal_plasma_membrane_75: $i > $i).
% 28.89/28.93  tff(decl_8510, type, fn_animal_plasma_membrane_76: $i > $i).
% 28.89/28.93  tff(decl_8511, type, fn_animal_plasma_membrane_78: $i > $i).
% 28.89/28.93  tff(decl_8512, type, fn_animal_plasma_membrane_79: $i > $i).
% 28.89/28.93  tff(decl_8513, type, fn_animal_plasma_membrane_80: $i > $i).
% 28.89/28.93  tff(decl_8514, type, fn_animal_plasma_membrane_81: $i > $i).
% 28.89/28.93  tff(decl_8515, type, fn_animal_plasma_membrane_82: $i > $i).
% 28.89/28.93  tff(decl_8516, type, fn_animal_plasma_membrane_83: $i > $i).
% 28.89/28.93  tff(decl_8517, type, fn_animal_plasma_membrane_84: $i > $i).
% 28.89/28.93  tff(decl_8518, type, fn_animal_plasma_membrane_90: $i > $i).
% 28.89/28.93  tff(decl_8519, type, fn_animal_plasma_membrane_91: $i > $i).
% 28.89/28.93  tff(decl_8520, type, fn_animal_plasma_membrane_92: $i > $i).
% 28.89/28.93  tff(decl_8521, type, fn_animal_plasma_membrane_93: $i > $i).
% 28.89/28.93  tff(decl_8522, type, fn_animal_plasma_membrane_94: $i > $i).
% 28.89/28.93  tff(decl_8523, type, fn_animal_plasma_membrane_95: $i > $i).
% 28.89/28.93  tff(decl_8524, type, fn_animal_plasma_membrane_96: $i > $i).
% 28.89/28.93  tff(decl_8525, type, fn_animal_plasma_membrane_97: $i > $i).
% 28.89/28.93  tff(decl_8526, type, fn_animal_plasma_membrane_98: $i > $i).
% 28.89/28.93  tff(decl_8527, type, fn_animal_plasma_membrane_99: $i > $i).
% 28.89/28.93  tff(decl_8528, type, fn_animal_plasma_membrane_100: $i > $i).
% 28.89/28.93  tff(decl_8529, type, fn_animal_plasma_membrane_101: $i > $i).
% 28.89/28.93  tff(decl_8530, type, fn_animal_plasma_membrane_102: $i > $i).
% 28.89/28.93  tff(decl_8531, type, fn_animal_plasma_membrane_104: $i > $i).
% 28.89/28.93  tff(decl_8532, type, fn_animal_plasma_membrane_105: $i > $i).
% 28.89/28.93  tff(decl_8533, type, fn_animal_plasma_membrane_106: $i > $i).
% 28.89/28.93  tff(decl_8534, type, fn_animal_plasma_membrane_107: $i > $i).
% 28.89/28.93  tff(decl_8535, type, hydrophobic_face_1: $i > $o).
% 28.89/28.93  tff(decl_8536, type, fn_animal_plasma_membrane_108: $i > $i).
% 28.89/28.93  tff(decl_8537, type, fn_animal_plasma_membrane_109: $i > $i).
% 28.89/28.93  tff(decl_8538, type, fn_animal_plasma_membrane_110: $i > $i).
% 28.89/28.93  tff(decl_8539, type, fn_animal_plasma_membrane_111: $i > $i).
% 28.89/28.93  tff(decl_8540, type, fn_animal_plasma_membrane_112: $i > $i).
% 28.89/28.93  tff(decl_8541, type, fn_animal_plasma_membrane_113: $i > $i).
% 28.89/28.93  tff(decl_8542, type, fn_animal_plasma_membrane_114: $i > $i).
% 28.89/28.93  tff(decl_8543, type, fn_animal_plasma_membrane_115: $i > $i).
% 28.89/28.93  tff(decl_8544, type, fn_transport_protein_21: $i > $i).
% 28.89/28.93  tff(decl_8545, type, fn_transport_protein_7: $i > $i).
% 28.89/28.93  tff(decl_8546, type, fn_transport_protein_8: $i > $i).
% 28.89/28.93  tff(decl_8547, type, fn_transport_protein_6: $i > $i).
% 28.89/28.93  tff(decl_8548, type, fn_phospholipid_52: $i > $i).
% 28.89/28.93  tff(decl_8549, type, fn_phospholipid_60: $i > $i).
% 28.89/28.93  tff(decl_8550, type, fn_phospholipid_13: $i > $i).
% 28.89/28.93  tff(decl_8551, type, fn_phospholipid_81: $i > $i).
% 28.89/28.93  tff(decl_8552, type, fn_phospholipid_98: $i > $i).
% 28.89/28.93  tff(decl_8553, type, fn_phospholipid_3: $i > $i).
% 28.89/28.93  tff(decl_8554, type, fn_phospholipid_94: $i > $i).
% 28.89/28.93  tff(decl_8555, type, fn_phospholipid_83: $i > $i).
% 28.89/28.93  tff(decl_8556, type, fn_integral_protein_10: $i > $i).
% 28.89/28.93  tff(decl_8557, type, fn_integral_protein_34: $i > $i).
% 28.89/28.93  tff(decl_8558, type, fn_transport_protein_23: $i > $i).
% 28.89/28.93  tff(decl_8559, type, fn_integral_protein_20: $i > $i).
% 28.89/28.93  tff(decl_8560, type, fn_transport_protein_19: $i > $i).
% 28.89/28.93  tff(decl_8561, type, fn_membrane_protein_2: $i > $i).
% 28.89/28.93  tff(decl_8562, type, fn_integral_protein_25: $i > $i).
% 28.89/28.93  tff(decl_8563, type, fn_membrane_protein_1: $i > $i).
% 28.89/28.93  tff(decl_8564, type, fn_integral_protein_16: $i > $i).
% 28.89/28.93  tff(decl_8565, type, fn_transport_protein_20: $i > $i).
% 28.89/28.93  tff(decl_8566, type, fn_phospholipid_layer_2: $i > $i).
% 28.89/28.93  tff(decl_8567, type, fn_phospholipid_layer_14: $i > $i).
% 28.89/28.93  tff(decl_8568, type, fn_phospholipid_layer_12: $i > $i).
% 28.89/28.93  tff(decl_8569, type, fn_phospholipid_layer_9: $i > $i).
% 28.89/28.93  tff(decl_8570, type, fn_phospholipid_layer_7: $i > $i).
% 28.89/28.93  tff(decl_8571, type, fn_phospholipid_layer_18: $i > $i).
% 28.89/28.93  tff(decl_8572, type, fn_phospholipid_layer_19: $i > $i).
% 28.89/28.93  tff(decl_8573, type, fn_phospholipid_layer_1: $i > $i).
% 28.89/28.93  tff(decl_8574, type, fn_integral_protein_12: $i > $i).
% 28.89/28.93  tff(decl_8575, type, fn_phospholipid_layer_20: $i > $i).
% 28.89/28.93  tff(decl_8576, type, fn_phospholipid_layer_21: $i > $i).
% 28.89/28.93  tff(decl_8577, type, fn_phospholipid_70: $i > $i).
% 28.89/28.93  tff(decl_8578, type, fn_phospholipid_71: $i > $i).
% 28.89/28.93  tff(decl_8579, type, fn_phospholipid_99: $i > $i).
% 28.89/28.93  tff(decl_8580, type, fn_phospholipid_layer_17: $i > $i).
% 28.89/28.93  tff(decl_8581, type, fn_phospholipid_88: $i > $i).
% 28.89/28.93  tff(decl_8582, type, fn_phospholipid_89: $i > $i).
% 28.89/28.93  tff(decl_8583, type, fn_phospholipid_101: $i > $i).
% 28.89/28.93  tff(decl_8584, type, fn_phospholipid_59: $i > $i).
% 28.89/28.93  tff(decl_8585, type, fn_phospholipid_84: $i > $i).
% 28.89/28.93  tff(decl_8586, type, 'EL1': $i).
% 28.89/28.93  tff(decl_8587, type, 'P4': $i).
% 28.89/28.93  tff(decl_8588, type, lipid_0: $i).
% 28.89/28.93  tff(decl_8589, type, fn_plasma_membrane_70: $i > $i).
% 28.89/28.93  tff(decl_8590, type, fn_animal_plasma_membrane_103: $i > $i).
% 28.89/28.93  tff(decl_8591, type, fn_biomembrane_28: $i > $i).
% 28.89/28.93  tff(decl_8592, type, fn_biomembrane_13: $i > $i).
% 28.89/28.93  tff(decl_8593, type, fn_biomembrane_18: $i > $i).
% 28.89/28.93  tff(decl_8594, type, fn_biomembrane_21: $i > $i).
% 28.89/28.93  tff(decl_8595, type, fn_biomembrane_69: $i > $i).
% 28.89/28.93  tff(decl_8596, type, fn_biomembrane_66: $i > $i).
% 28.89/28.93  tff(decl_8597, type, fn_animal_plasma_membrane_27: $i > $i).
% 28.89/28.93  tff(decl_8598, type, fn_plasma_membrane_95: $i > $i).
% 28.89/28.93  tff(decl_8599, type, fn_animal_plasma_membrane_26: $i > $i).
% 28.89/28.93  tff(decl_8600, type, fn_plasma_membrane_93: $i > $i).
% 28.89/28.93  tff(decl_8601, type, fn_animal_plasma_membrane_87: $i > $i).
% 28.89/28.93  tff(decl_8602, type, fn_plasma_membrane_5: $i > $i).
% 28.89/28.93  tff(decl_8603, type, fn_animal_plasma_membrane_25: $i > $i).
% 28.89/28.93  tff(decl_8604, type, fn_plasma_membrane_90: $i > $i).
% 28.89/28.93  tff(decl_8605, type, fn_animal_plasma_membrane_89: $i > $i).
% 28.89/28.93  tff(decl_8606, type, fn_plasma_membrane_94: $i > $i).
% 28.89/28.93  tff(decl_8607, type, fn_plasma_membrane_1: $i > $i).
% 28.89/28.93  tff(decl_8608, type, fn_plasma_membrane_38: $i > $i).
% 28.89/28.93  tff(decl_8609, type, fn_plasma_membrane_36: $i > $i).
% 28.89/28.93  tff(decl_8610, type, fn_plasma_membrane_37: $i > $i).
% 28.89/28.93  tff(decl_8611, type, fn_plasma_membrane_40: $i > $i).
% 28.89/28.93  tff(decl_8612, type, fn_plasma_membrane_35: $i > $i).
% 28.89/28.93  tff(decl_8613, type, fn_plasma_membrane_87: $i > $i).
% 28.89/28.93  tff(decl_8614, type, fn_plasma_membrane_88: $i > $i).
% 28.89/28.93  tff(decl_8615, type, fn_plasma_membrane_84: $i > $i).
% 28.89/28.93  tff(decl_8616, type, fn_plasma_membrane_86: $i > $i).
% 28.89/28.93  tff(decl_8617, type, fn_plasma_membrane_52: $i > $i).
% 28.89/28.93  tff(decl_8618, type, fn_plasma_membrane_80: $i > $i).
% 28.89/28.93  tff(decl_8619, type, fn_plasma_membrane_96: $i > $i).
% 28.89/28.93  tff(decl_8620, type, fn_plasma_membrane_30: $i > $i).
% 28.89/28.93  tff(decl_8621, type, fn_plasma_membrane_31: $i > $i).
% 28.89/28.93  tff(decl_8622, type, fn_biomembrane_61: $i > $i).
% 28.89/28.93  tff(decl_8623, type, fn_plasma_membrane_78: $i > $i).
% 28.89/28.93  tff(decl_8624, type, fn_plasma_membrane_51: $i > $i).
% 28.89/28.93  tff(decl_8625, type, fn_plasma_membrane_77: $i > $i).
% 28.89/28.93  tff(decl_8626, type, fn_plasma_membrane_97: $i > $i).
% 28.89/28.93  tff(decl_8627, type, fn_plasma_membrane_82: $i > $i).
% 28.89/28.93  tff(decl_8628, type, fn_plasma_membrane_83: $i > $i).
% 28.89/28.93  tff(decl_8629, type, fn_biomembrane_75: $i > $i).
% 28.89/28.93  tff(decl_8630, type, fn_biomembrane_83: $i > $i).
% 28.89/28.93  tff(decl_8631, type, fn_plasma_membrane_81: $i > $i).
% 28.89/28.93  tff(decl_8632, type, fn_plasma_membrane_50: $i > $i).
% 28.89/28.93  tff(decl_8633, type, fn_plasma_membrane_89: $i > $i).
% 28.89/28.93  tff(decl_8634, type, fn_plasma_membrane_98: $i > $i).
% 28.89/28.93  tff(decl_8635, type, fn_plasma_membrane_73: $i > $i).
% 28.89/28.93  tff(decl_8636, type, fn_animal_plasma_membrane_85: $i > $i).
% 28.89/28.93  tff(decl_8637, type, fn_plasma_membrane_33: $i > $i).
% 28.89/28.93  tff(decl_8638, type, fn_animal_plasma_membrane_86: $i > $i).
% 28.89/28.93  tff(decl_8639, type, fn_animal_plasma_membrane_88: $i > $i).
% 28.89/28.93  tff(decl_8640, type, animal_pole_1: $i > $o).
% 28.89/28.93  tff(decl_8641, type, 'Animal-Pole': $i).
% 28.89/28.93  tff(decl_8642, type, 'The area of an egg that has the lowest concentration of yolk, opposite the vegetal pole which has the highest yolk concentration. Cells in the animal pole divide more rapidly than cells in the vegetal pole.': $i).
% 28.89/28.93  tff(decl_8643, type, 'pole of animal': $i).
% 28.89/28.93  tff(decl_8644, type, 'animal pole': $i).
% 28.89/28.93  tff(decl_8645, type, 'animal-pole': $i).
% 28.89/28.93  tff(decl_8646, type, pole_1: $i > $o).
% 28.89/28.93  tff(decl_8647, type, 'Animal-Process': $i).
% 28.89/28.93  tff(decl_8648, type, 'A process unique to animals.': $i).
% 28.89/28.93  tff(decl_8649, type, 'process of animal': $i).
% 28.89/28.93  tff(decl_8650, type, 'animal process': $i).
% 28.89/28.93  tff(decl_8651, type, 'animal-process': $i).
% 28.89/28.93  tff(decl_8652, type, 'Animal-Space': $i).
% 28.89/28.93  tff(decl_8653, type, 'A space in animals which is surrounded by anatomical structures.': $i).
% 28.89/28.93  tff(decl_8654, type, 'space of animal': $i).
% 28.89/28.93  tff(decl_8655, type, 'animal space': $i).
% 28.89/28.93  tff(decl_8656, type, 'animal-space': $i).
% 28.89/28.93  tff(decl_8657, type, animal_statolith_1: $i > $o).
% 28.89/28.93  tff(decl_8658, type, 'Animal-Statolith': $i).
% 28.89/28.93  tff(decl_8659, type, 'A mineralized concretion in the statocyst of invertebrate animals. Due to gravity, the statolith settles against sensory cilia within the cavity of the statocyst, giving the animal information about its body\\s orientation with respect to gravity.': $i).
% 28.89/28.93  tff(decl_8660, type, 'animal statolith': $i).
% 28.89/28.93  tff(decl_8661, type, 'animal-statolith': $i).
% 28.89/28.93  tff(decl_8662, type, fn_animal_statolith_1: $i > $i).
% 28.89/28.93  tff(decl_8663, type, animal_stem_cell_1: $i > $o).
% 28.89/28.93  tff(decl_8664, type, 'Animal-Stem-Cell': $i).
% 28.89/28.93  tff(decl_8665, type, 'Animal stem cells are biological cells found in animal, that can divide through mitosis and differentiate into diverse specialized cell types or can self renew to produce more stem cells.': $i).
% 28.89/28.93  tff(decl_8666, type, 'animal stem cell': $i).
% 28.89/28.93  tff(decl_8667, type, 'animal-stem-cell': $i).
% 28.89/28.93  tff(decl_8668, type, stem_cell_culturing_1: $i > $o).
% 28.89/28.93  tff(decl_8669, type, embryonic_stem_cell_1: $i > $o).
% 28.89/28.93  tff(decl_8670, type, animal_stem_cell_culturing_from_embryo_1: $i > $o).
% 28.89/28.93  tff(decl_8671, type, fn_animal_stem_cell_culturing_from_embryo_5: $i > $i).
% 28.89/28.93  tff(decl_8672, type, 'Animal-Stem-Cell-Culturing-From-Embryo': $i).
% 28.89/28.93  tff(decl_8673, type, 'The growing of the stem cells of animal from its embryo in laboratory.': $i).
% 28.89/28.93  tff(decl_8674, type, culture: $i).
% 28.89/28.93  tff(decl_8675, type, 'animal stem cell culturing from embryo': $i).
% 28.89/28.93  tff(decl_8676, type, 'animal-stem-cell-culturing-from-embryo': $i).
% 28.89/28.93  tff(decl_8677, type, animal_stem_cell_culturing_from_tissue_1: $i > $o).
% 28.89/28.93  tff(decl_8678, type, fn_animal_stem_cell_culturing_from_embryo_2: $i > $i).
% 28.89/28.93  tff(decl_8679, type, reproduce_1: $i > $o).
% 28.89/28.93  tff(decl_8680, type, fn_animal_stem_cell_culturing_from_embryo_3: $i > $i).
% 28.89/28.93  tff(decl_8681, type, fn_animal_stem_cell_culturing_from_embryo_4: $i > $i).
% 28.89/28.93  tff(decl_8682, type, fn_animal_stem_cell_culturing_from_embryo_6: $i > $i).
% 28.89/28.93  tff(decl_8683, type, fn_animal_stem_cell_culturing_from_embryo_7: $i > $i).
% 28.89/28.93  tff(decl_8684, type, culture_1: $i > $o).
% 28.89/28.93  tff(decl_8685, type, fn_reproduce_1: $i > $i).
% 28.89/28.93  tff(decl_8686, type, fn_embryonic_stem_cell_41: $i > $i).
% 28.89/28.93  tff(decl_8687, type, fn_reproduce_2: $i > $i).
% 28.89/28.93  tff(decl_8688, type, fn_culturing_4: $i > $i).
% 28.89/28.93  tff(decl_8689, type, fn_culturing_7: $i > $i).
% 28.89/28.93  tff(decl_8690, type, fn_stem_cell_culturing_2: $i > $i).
% 28.89/28.93  tff(decl_8691, type, fn_stem_cell_culturing_3: $i > $i).
% 28.89/28.93  tff(decl_8692, type, fn_animal_stem_cell_culturing_from_tissue_5: $i > $i).
% 28.89/28.93  tff(decl_8693, type, 'Animal-Stem-Cell-Culturing-From-Tissue': $i).
% 28.89/28.93  tff(decl_8694, type, 'The growing of the stem cells of animal from its tissue in laboratory.': $i).
% 28.89/28.93  tff(decl_8695, type, 'animal stem cell culturing from tissue': $i).
% 28.89/28.93  tff(decl_8696, type, 'animal-stem-cell-culturing-from-tissue': $i).
% 28.89/28.93  tff(decl_8697, type, fn_animal_stem_cell_culturing_from_tissue_1: $i > $i).
% 28.89/28.93  tff(decl_8698, type, fn_animal_stem_cell_culturing_from_tissue_3: $i > $i).
% 28.89/28.93  tff(decl_8699, type, fn_animal_stem_cell_culturing_from_tissue_4: $i > $i).
% 28.89/28.93  tff(decl_8700, type, fn_animal_stem_cell_culturing_from_tissue_6: $i > $i).
% 28.89/28.93  tff(decl_8701, type, fn_stem_cell_culturing_1: $i > $i).
% 28.89/28.93  tff(decl_8702, type, animal_storage_polysaccharide_1: $i > $o).
% 28.89/28.93  tff(decl_8703, type, 'Animal-Storage-Polysaccharide': $i).
% 28.89/28.93  tff(decl_8704, type, 'A polysaccharide used primarily for energy storage in animals.': $i).
% 28.89/28.93  tff(decl_8705, type, 'animal storage polysaccharide': $i).
% 28.89/28.93  tff(decl_8706, type, 'animal-storage-polysaccharide': $i).
% 28.89/28.93  tff(decl_8707, type, storage_polysaccharide_1: $i > $o).
% 28.89/28.93  tff(decl_8708, type, animal_structure_1: $i > $o).
% 28.89/28.93  tff(decl_8709, type, 'Animal-Structure': $i).
% 28.89/28.93  tff(decl_8710, type, 'Structures which make up the body of animals.': $i).
% 28.89/28.93  tff(decl_8711, type, 'structure of animal': $i).
% 28.89/28.93  tff(decl_8712, type, 'animal structure': $i).
% 28.89/28.93  tff(decl_8713, type, 'animal-structure': $i).
% 28.89/28.93  tff(decl_8714, type, animal_system_1: $i > $o).
% 28.89/28.93  tff(decl_8715, type, 'Animal-System': $i).
% 28.89/28.93  tff(decl_8716, type, 'A group of organs in animals that work together in performing vital body functions.': $i).
% 28.89/28.93  tff(decl_8717, type, 'system of animal': $i).
% 28.89/28.93  tff(decl_8718, type, 'animal system': $i).
% 28.89/28.93  tff(decl_8719, type, 'animal-system': $i).
% 28.89/28.93  tff(decl_8720, type, organ_system_1: $i > $o).
% 28.89/28.93  tff(decl_8721, type, animal_tissue_1: $i > $o).
% 28.89/28.93  tff(decl_8722, type, 'Animal-Tissue': $i).
% 28.89/28.93  tff(decl_8723, type, 'An organized collection of similar cells from the same origin, that carry out a specific function in an animal\\s body.': $i).
% 28.89/28.93  tff(decl_8724, type, 'tissue of animal': $i).
% 28.89/28.93  tff(decl_8725, type, 'animal tissue': $i).
% 28.89/28.93  tff(decl_8726, type, 'animal-tissue': $i).
% 28.89/28.93  tff(decl_8727, type, animal_transcription_factor_gene_1: $i > $o).
% 28.89/28.93  tff(decl_8728, type, 'Animal-Transcription-Factor-Gene': $i).
% 28.89/28.93  tff(decl_8729, type, 'A gene that codes for animal transcription factor.': $i).
% 28.89/28.93  tff(decl_8730, type, 'animal transcription factor gene': $i).
% 28.89/28.93  tff(decl_8731, type, 'animal-transcription-factor-gene': $i).
% 28.89/28.93  tff(decl_8732, type, transcription_factor_gene_1: $i > $o).
% 28.89/28.93  tff(decl_8733, type, yeast_transcription_factor_gene_1: $i > $o).
% 28.89/28.93  tff(decl_8734, type, animal_transport_1: $i > $o).
% 28.89/28.93  tff(decl_8735, type, 'Animal-Transport': $i).
% 28.89/28.93  tff(decl_8736, type, 'A process related to transport of materials in animals.': $i).
% 28.89/28.93  tff(decl_8737, type, 'transport of animal': $i).
% 28.89/28.93  tff(decl_8738, type, 'animal transport': $i).
% 28.89/28.93  tff(decl_8739, type, 'animal-transport': $i).
% 28.89/28.93  tff(decl_8740, type, 'Animal-Virus': $i).
% 28.89/28.93  tff(decl_8741, type, 'The study of animal viruses is important from a veterinary viewpoint and many of these viruses cause diseases that are economically devastating. Many animal viruses are also important from a human medical perspective. The emergence of the SARS virus in the human population, coming from an animal source, highlights the importance of animals in bearing infectious agents; avian influenza viruses can directly infect humans. In addition research into animal viruses has made an important contribution to our understanding of viruses in general, their replication, molecular biology, evolution and interaction with the host.': $i).
% 28.89/28.93  tff(decl_8742, type, 'virus of animal': $i).
% 28.89/28.93  tff(decl_8743, type, 'animal virus': $i).
% 28.89/28.93  tff(decl_8744, type, 'animal-virus': $i).
% 28.89/28.93  tff(decl_8745, type, virus_1: $i > $o).
% 28.89/28.93  tff(decl_8746, type, fn_animal_virus_1: $i > $i).
% 28.89/28.93  tff(decl_8747, type, fn_animal_virus_2: $i > $i).
% 28.89/28.93  tff(decl_8748, type, viral_envelope_1: $i > $o).
% 28.89/28.93  tff(decl_8749, type, fn_viral_envelope_17: $i > $i).
% 28.89/28.93  tff(decl_8750, type, 'Anion': $i).
% 28.89/28.93  tff(decl_8751, type, 'An anion is a negatively charged ion.': $i).
% 28.89/28.93  tff(decl_8752, type, anion: $i).
% 28.89/28.93  tff(decl_8753, type, fn_anion_1: $i > $i).
% 28.89/28.93  tff(decl_8754, type, fn_anion_2: $i > $i).
% 28.89/28.93  tff(decl_8755, type, gain_1: $i > $o).
% 28.89/28.93  tff(decl_8756, type, fn_anion_4: $i > $i).
% 28.89/28.93  tff(decl_8757, type, fn_anion_5: $i > $i).
% 28.89/28.93  tff(decl_8758, type, fn_anion_6: $i > $i).
% 28.89/28.93  tff(decl_8759, type, fn_atom_6: $i > $i).
% 28.89/28.93  tff(decl_8760, type, fn_atom_7: $i > $i).
% 28.89/28.93  tff(decl_8761, type, fn_anion_7: $i > $i).
% 28.89/28.93  tff(decl_8762, type, fn_ion_1: $i > $i).
% 28.89/28.93  tff(decl_8763, type, fn_ion_2: $i > $i).
% 28.89/28.93  tff(decl_8764, type, fn_anion_3: $i > $i).
% 28.89/28.93  tff(decl_8765, type, anion_substance_1: $i > $o).
% 28.89/28.93  tff(decl_8766, type, 'Anion-Substance': $i).
% 28.89/28.93  tff(decl_8767, type, 'A substance composed of anions.': $i).
% 28.89/28.93  tff(decl_8768, type, 'substance of anion': $i).
% 28.89/28.93  tff(decl_8769, type, 'anion substance': $i).
% 28.89/28.93  tff(decl_8770, type, 'anion-substance': $i).
% 28.89/28.93  tff(decl_8771, type, ionic_substance_1: $i > $o).
% 28.89/28.93  tff(decl_8772, type, cation_substance_1: $i > $o).
% 28.89/28.93  tff(decl_8773, type, fn_anion_substance_1: $i > $i).
% 28.89/28.93  tff(decl_8774, type, fn_anion_substance_2: $i > $i).
% 28.89/28.93  tff(decl_8775, type, chemical_0: $i).
% 28.89/28.93  tff(decl_8776, type, fn_ionic_substance_3: $i > $i).
% 28.89/28.93  tff(decl_8777, type, fn_anion_substance_3: $i > $i).
% 28.89/28.93  tff(decl_8778, type, annealing_1: $i > $o).
% 28.89/28.93  tff(decl_8779, type, 'Annealing': $i).
% 28.89/28.93  tff(decl_8780, type, 'Attaching of single-stranded DNS with DNA Primers at 60 degrees Celsius.  This is a subevent of PCR.': $i).
% 28.89/28.93  tff(decl_8781, type, anneal: $i).
% 28.89/28.93  tff(decl_8782, type, annealing: $i).
% 28.89/28.93  tff(decl_8783, type, base_pairing_1: $i > $o).
% 28.89/28.93  tff(decl_8784, type, intercellular_joining_1: $i > $o).
% 28.89/28.93  tff(decl_8785, type, ligand_binding_1: $i > $o).
% 28.89/28.93  tff(decl_8786, type, nucleic_acid_hybridization_1: $i > $o).
% 28.89/28.93  tff(decl_8787, type, fn_annealing_2: $i > $i).
% 28.89/28.93  tff(decl_8788, type, fn_annealing_3: $i > $i).
% 28.89/28.93  tff(decl_8789, type, fn_annealing_4: $i > $i).
% 28.89/28.93  tff(decl_8790, type, fn_annealing_5: $i > $i).
% 28.89/28.93  tff(decl_8791, type, fn_annealing_6: $i > $i).
% 28.89/28.93  tff(decl_8792, type, fn_annealing_7: $i > $i).
% 28.89/28.93  tff(decl_8793, type, polymerase_chain_reaction_1: $i > $o).
% 28.89/28.93  tff(decl_8794, type, fn_annealing_8: $i > $i).
% 28.89/28.93  tff(decl_8795, type, fn_annealing_9: $i > $i).
% 28.89/28.93  tff(decl_8796, type, dna_primer_1: $i > $o).
% 28.89/28.93  tff(decl_8797, type, fn_annealing_10: $i > $i).
% 28.89/28.93  tff(decl_8798, type, fn_synthesis_of_dna_strand_21: $i > $i).
% 28.89/28.93  tff(decl_8799, type, fn_heat_2: $i > $i).
% 28.89/28.93  tff(decl_8800, type, fn_heat_5: $i > $i).
% 28.89/28.93  tff(decl_8801, type, fn_heat_1: $i > $i).
% 28.89/28.93  tff(decl_8802, type, dna_strand_0: $i).
% 28.89/28.93  tff(decl_8803, type, "60.0e0": $i).
% 28.89/28.93  tff(decl_8804, type, fn_annealing_1: $i > $i).
% 28.89/28.93  tff(decl_8805, type, 'Annelid': $i).
% 28.89/28.93  tff(decl_8806, type, 'A segmented worm from the Phylum Annelida. Examples include polychaetes, earthworms, and leeches.': $i).
% 28.89/28.93  tff(decl_8807, type, 'segmented worm': $i).
% 28.89/28.93  tff(decl_8808, type, 'segmented-worm': $i).
% 28.89/28.93  tff(decl_8809, type, annelida: $i).
% 28.89/28.93  tff(decl_8810, type, annelid: $i).
% 28.89/28.93  tff(decl_8811, type, fn_annelid_2: $i > $i).
% 28.89/28.93  tff(decl_8812, type, fn_annelid_3: $i > $i).
% 28.89/28.93  tff(decl_8813, type, fn_annelid_4: $i > $i).
% 28.89/28.93  tff(decl_8814, type, fn_annelid_5: $i > $i).
% 28.89/28.93  tff(decl_8815, type, fn_annelid_6: $i > $i).
% 28.89/28.93  tff(decl_8816, type, fn_annelid_7: $i > $i).
% 28.89/28.93  tff(decl_8817, type, fn_annelid_8: $i > $i).
% 28.89/28.93  tff(decl_8818, type, fn_annelid_9: $i > $i).
% 28.89/28.93  tff(decl_8819, type, fn_annelid_10: $i > $i).
% 28.89/28.93  tff(decl_8820, type, fn_annelid_11: $i > $i).
% 28.89/28.93  tff(decl_8821, type, fn_annelid_12: $i > $i).
% 28.89/28.93  tff(decl_8822, type, fn_annelid_13: $i > $i).
% 28.89/28.93  tff(decl_8823, type, fn_annelid_14: $i > $i).
% 28.89/28.93  tff(decl_8824, type, fn_annelid_15: $i > $i).
% 28.89/28.93  tff(decl_8825, type, fn_annelid_16: $i > $i).
% 28.89/28.93  tff(decl_8826, type, fn_annelid_17: $i > $i).
% 28.89/28.93  tff(decl_8827, type, fn_annelid_18: $i > $i).
% 28.89/28.93  tff(decl_8828, type, fn_invertebrate_4: $i > $i).
% 28.89/28.93  tff(decl_8829, type, fn_invertebrate_1: $i > $i).
% 28.89/28.93  tff(decl_8830, type, fn_invertebrate_5: $i > $i).
% 28.89/28.93  tff(decl_8831, type, fn_invertebrate_3: $i > $i).
% 28.89/28.93  tff(decl_8832, type, fn_invertebrate_6: $i > $i).
% 28.89/28.93  tff(decl_8833, type, annual_1: $i > $o).
% 28.89/28.93  tff(decl_8834, type, 'Annual': $i).
% 28.89/28.93  tff(decl_8835, type, 'A flowering plant that completes its entire life cycle in a single year or growing season.': $i).
% 28.89/28.93  tff(decl_8836, type, 'annual plant': $i).
% 28.89/28.93  tff(decl_8837, type, annual: $i).
% 28.89/28.93  tff(decl_8838, type, anoplura_1: $i > $o).
% 28.89/28.93  tff(decl_8839, type, 'Anoplura': $i).
% 28.89/28.93  tff(decl_8840, type, 'Order of the class Insecta. Wingless ectoparasites with sucking mouthparts and flattened bodies.': $i).
% 28.89/28.93  tff(decl_8841, type, 'sucking louse': $i).
% 28.89/28.93  tff(decl_8842, type, 'sucking-louse': $i).
% 28.89/28.93  tff(decl_8843, type, anoplura: $i).
% 28.89/28.93  tff(decl_8844, type, insect_1: $i > $o).
% 28.89/28.93  tff(decl_8845, type, 'ANP': $i).
% 28.89/28.93  tff(decl_8846, type, 'Atrial natiuretic peptide is a polypeptide hormone secreted by cells in the atria of the heart in response to high blood pressure. Its actions reduce blood volume, increase the breakdown of lipids in the blood, and decreases sodium reabsorption in the kidney, all of which reduce blood pressure.': $i).
% 28.89/28.93  tff(decl_8847, type, 'atrial natriuretic peptide': $i).
% 28.89/28.93  tff(decl_8848, type, 'atrial-natriuretic-peptide': $i).
% 28.89/28.93  tff(decl_8849, type, 'atrial natriuretic factor': $i).
% 28.89/28.93  tff(decl_8850, type, 'atrial-natriuretic-factor': $i).
% 28.89/28.93  tff(decl_8851, type, 'atrial natriuretic hormone': $i).
% 28.89/28.93  tff(decl_8852, type, 'atrial-natriuretic-hormone': $i).
% 28.89/28.93  tff(decl_8853, type, anh: $i).
% 28.89/28.93  tff(decl_8854, type, anf: $i).
% 28.89/28.93  tff(decl_8855, type, atriopeptin: $i).
% 28.89/28.93  tff(decl_8856, type, anp: $i).
% 28.89/28.93  tff(decl_8857, type, ant_1: $i > $o).
% 28.89/28.93  tff(decl_8858, type, 'Ant': $i).
% 28.89/28.93  tff(decl_8859, type, 'Social insects of the Family Formicidae.': $i).
% 28.89/28.93  tff(decl_8860, type, ant: $i).
% 28.89/28.93  tff(decl_8861, type, hymenoptera_1: $i > $o).
% 28.89/28.93  tff(decl_8862, type, parasitoid_wasp_1: $i > $o).
% 28.89/28.93  tff(decl_8863, type, bee_1: $i > $o).
% 28.89/28.93  tff(decl_8864, type, antarctic_sea_1: $i > $o).
% 28.89/28.93  tff(decl_8865, type, 'Antarctic-Sea': $i).
% 28.89/28.93  tff(decl_8866, type, 'Sea in Antarctic Region.': $i).
% 28.89/28.93  tff(decl_8867, type, 'sea of antarctic': $i).
% 28.89/28.93  tff(decl_8868, type, 'antarctic sea': $i).
% 28.89/28.93  tff(decl_8869, type, 'antarctic-sea': $i).
% 28.89/28.93  tff(decl_8870, type, sea_1: $i > $o).
% 28.89/28.93  tff(decl_8871, type, tropical_sea_1: $i > $o).
% 28.89/28.93  tff(decl_8872, type, fn_antarctic_sea_1: $i > $i).
% 28.89/28.93  tff(decl_8873, type, antenna_1: $i > $o).
% 28.89/28.93  tff(decl_8874, type, 'Antenna': $i).
% 28.89/28.93  tff(decl_8875, type, 'A sensory organ on the head of arthropods such as crustaceans and insects.': $i).
% 28.89/28.93  tff(decl_8876, type, antennae: $i).
% 28.89/28.93  tff(decl_8877, type, antenna: $i).
% 28.89/28.93  tff(decl_8878, type, sensory_organ_1: $i > $o).
% 28.89/28.93  tff(decl_8879, type, invertebrate_appendage_1: $i > $o).
% 28.89/28.93  tff(decl_8880, type, cochlea_1: $i > $o).
% 28.89/28.93  tff(decl_8881, type, eye_cup_1: $i > $o).
% 28.89/28.93  tff(decl_8882, type, inner_ear_1: $i > $o).
% 28.89/28.93  tff(decl_8883, type, lateral_line_1: $i > $o).
% 28.89/28.93  tff(decl_8884, type, organ_of_corti_1: $i > $o).
% 28.89/28.93  tff(decl_8885, type, organ_of_equilibrium_1: $i > $o).
% 28.89/28.93  tff(decl_8886, type, 'Antenna-Pigment': $i).
% 28.89/28.93  tff(decl_8887, type, 'Photosynthetic pigments that capture light in other parts of the spectrum than chlorophyll a and passes this light energy on to chlorophyll a at the reaction center in the chloroplast.': $i).
% 28.89/28.93  tff(decl_8888, type, 'antennae pigment': $i).
% 28.89/28.93  tff(decl_8889, type, 'pigment of antenna': $i).
% 28.89/28.93  tff(decl_8890, type, 'antenna pigment': $i).
% 28.89/28.93  tff(decl_8891, type, 'antenna-pigment': $i).
% 28.89/28.93  tff(decl_8892, type, pigment_1: $i > $o).
% 28.89/28.93  tff(decl_8893, type, anterior_1: $i > $o).
% 28.89/28.93  tff(decl_8894, type, 'Anterior': $i).
% 28.89/28.93  tff(decl_8895, type, 'The anterior is the anatomical region near the head or front of an animal with a left and a right side (a bilateral animal).': $i).
% 28.89/28.93  tff(decl_8896, type, rostral: $i).
% 28.89/28.93  tff(decl_8897, type, 'cranial,': $i).
% 28.89/28.93  tff(decl_8898, type, cephalic: $i).
% 28.89/28.93  tff(decl_8899, type, cranial: $i).
% 28.89/28.93  tff(decl_8900, type, anterior: $i).
% 28.89/28.93  tff(decl_8901, type, anterior_end_1: $i > $o).
% 28.89/28.93  tff(decl_8902, type, 'Anterior-End': $i).
% 28.89/28.93  tff(decl_8903, type, 'The front side region.': $i).
% 28.89/28.93  tff(decl_8904, type, 'end of anterior': $i).
% 28.89/28.93  tff(decl_8905, type, 'anterior end': $i).
% 28.89/28.93  tff(decl_8906, type, 'anterior-end': $i).
% 28.89/28.93  tff(decl_8907, type, anterior_pituitary_1: $i > $o).
% 28.89/28.93  tff(decl_8908, type, 'Anterior-Pituitary': $i).
% 28.89/28.93  tff(decl_8909, type, 'The anterior portion of the pituitary gland, which secretes hormones that regulate physiological processes including growth and reproduction.': $i).
% 28.89/28.93  tff(decl_8910, type, adenohypophysis: $i).
% 28.89/28.93  tff(decl_8911, type, 'pituitary of anterior': $i).
% 28.89/28.93  tff(decl_8912, type, 'anterior pituitary': $i).
% 28.89/28.93  tff(decl_8913, type, 'anterior-pituitary': $i).
% 28.89/28.93  tff(decl_8914, type, secretory_organ_1: $i > $o).
% 28.89/28.93  tff(decl_8915, type, anterior_posterior_axis_1: $i > $o).
% 28.89/28.93  tff(decl_8916, type, 'Anterior-Posterior-Axis': $i).
% 28.89/28.93  tff(decl_8917, type, 'A body axis connecting the anterior end and posterior end.': $i).
% 28.89/28.93  tff(decl_8918, type, 'head tail axis': $i).
% 28.89/28.93  tff(decl_8919, type, 'anterior posterior axis': $i).
% 28.89/28.93  tff(decl_8920, type, 'anterior-posterior axis': $i).
% 28.89/28.93  tff(decl_8921, type, 'anterior-posterior-axis': $i).
% 28.89/28.93  tff(decl_8922, type, body_axis_1: $i > $o).
% 28.89/28.93  tff(decl_8923, type, dorsal_ventral_axis_1: $i > $o).
% 28.89/28.93  tff(decl_8924, type, anterior_structure_1: $i > $o).
% 28.89/28.93  tff(decl_8925, type, 'Anterior-Structure': $i).
% 28.89/28.93  tff(decl_8926, type, 'The structure situated before or at the front side.': $i).
% 28.89/28.93  tff(decl_8927, type, 'structure of anterior': $i).
% 28.89/28.93  tff(decl_8928, type, 'anterior structure': $i).
% 28.89/28.93  tff(decl_8929, type, 'anterior-structure': $i).
% 28.89/28.93  tff(decl_8930, type, fn_anterior_structure_1: $i > $i).
% 28.89/28.93  tff(decl_8931, type, fn_anterior_structure_2: $i > $i).
% 28.89/28.93  tff(decl_8932, type, anther_1: $i > $o).
% 28.89/28.93  tff(decl_8933, type, 'Anther': $i).
% 28.89/28.93  tff(decl_8934, type, 'In a flowering plant (angiosperm), the distal end of a stamen, where pollen is produced.': $i).
% 28.89/28.93  tff(decl_8935, type, anther: $i).
% 28.89/28.93  tff(decl_8936, type, flower_organ_1: $i > $o).
% 28.89/28.93  tff(decl_8937, type, 'Antheridium': $i).
% 28.89/28.93  tff(decl_8938, type, 'In plants, a structure in which male gametes develop.': $i).
% 28.89/28.93  tff(decl_8939, type, antheridia: $i).
% 28.89/28.93  tff(decl_8940, type, antheridium: $i).
% 28.89/28.93  tff(decl_8941, type, plant_space_1: $i > $o).
% 28.89/28.93  tff(decl_8942, type, anthozoan_1: $i > $o).
% 28.89/28.93  tff(decl_8943, type, 'Anthozoan': $i).
% 28.89/28.93  tff(decl_8944, type, 'An animal in the Phylum Cnidaria, Class Anthozoa.  Anthozoans include the sea anemones and corals. Unlike other cnidarians, they do not have a pelagic medusa stage in their life cycle.': $i).
% 28.89/28.93  tff(decl_8945, type, anthozoan: $i).
% 28.89/28.93  tff(decl_8946, type, cubozoan_1: $i > $o).
% 28.89/28.93  tff(decl_8947, type, hydra_1: $i > $o).
% 28.89/28.93  tff(decl_8948, type, hydrozoan_1: $i > $o).
% 28.89/28.93  tff(decl_8949, type, anthropoid_1: $i > $o).
% 28.89/28.93  tff(decl_8950, type, 'Anthropoid': $i).
% 28.89/28.93  tff(decl_8951, type, 'A member of a primate group that comprises the monkeys and apes.': $i).
% 28.89/28.93  tff(decl_8952, type, anthropoid: $i).
% 28.89/28.93  tff(decl_8953, type, primate_1: $i > $o).
% 28.89/28.93  tff(decl_8954, type, hominid_1: $i > $o).
% 28.89/28.93  tff(decl_8955, type, monkey_1: $i > $o).
% 28.89/28.93  tff(decl_8956, type, anti_antibiotic_gene_1: $i > $o).
% 28.89/28.93  tff(decl_8957, type, 'Anti-Antibiotic-Gene': $i).
% 28.89/28.93  tff(decl_8958, type, 'A gene that confers antibiotic resistance by coding for compounds that defeat the actions of the antibiotic.': $i).
% 28.89/28.93  tff(decl_8959, type, 'antibiotic resistance gene': $i).
% 28.89/28.93  tff(decl_8960, type, 'antibiotic-resistance-gene': $i).
% 28.89/28.93  tff(decl_8961, type, 'anti antibiotic gene': $i).
% 28.89/28.93  tff(decl_8962, type, 'anti-antibiotic-gene': $i).
% 28.89/28.93  tff(decl_8963, type, prokaryotic_gene_1: $i > $o).
% 28.89/28.93  tff(decl_8964, type, fn_anti_antibiotic_gene_1: $i > $i).
% 28.89/28.93  tff(decl_8965, type, code_for_1: $i > $o).
% 28.89/28.93  tff(decl_8966, type, fn_anti_antibiotic_gene_2: $i > $i).
% 28.89/28.93  tff(decl_8967, type, anti_antibiotic_protein_1: $i > $o).
% 28.89/28.93  tff(decl_8968, type, fn_code_for_2: $i > $i).
% 28.89/28.93  tff(decl_8969, type, fn_gene_13: $i > $i).
% 28.89/28.93  tff(decl_8970, type, 'Anti-Antibiotic-Protein': $i).
% 28.89/28.93  tff(decl_8971, type, 'A protein whose enzymatic properties allow it to breakdown antibiotic compounds.': $i).
% 28.89/28.93  tff(decl_8972, type, 'anti antibiotic protein': $i).
% 28.89/28.93  tff(decl_8973, type, 'anti-antibiotic-protein': $i).
% 28.89/28.93  tff(decl_8974, type, defensive_protein_1: $i > $o).
% 28.89/28.93  tff(decl_8975, type, fn_anti_antibiotic_protein_1: $i > $i).
% 28.89/28.93  tff(decl_8976, type, fn_anti_antibiotic_protein_2: $i > $i).
% 28.89/28.93  tff(decl_8977, type, fn_anti_antibiotic_protein_3: $i > $i).
% 28.89/28.93  tff(decl_8978, type, fn_anti_antibiotic_protein_4: $i > $i).
% 28.89/28.94  tff(decl_8979, type, fn_anti_antibiotic_protein_5: $i > $i).
% 28.89/28.94  tff(decl_8980, type, fn_anti_antibiotic_protein_7: $i > $i).
% 28.89/28.94  tff(decl_8981, type, fn_anti_antibiotic_protein_10: $i > $i).
% 28.89/28.94  tff(decl_8982, type, fn_anti_antibiotic_protein_11: $i > $i).
% 28.89/28.94  tff(decl_8983, type, fn_anti_antibiotic_protein_12: $i > $i).
% 28.89/28.94  tff(decl_8984, type, fn_anti_antibiotic_protein_13: $i > $i).
% 28.89/28.94  tff(decl_8985, type, fn_anti_antibiotic_protein_14: $i > $i).
% 28.89/28.94  tff(decl_8986, type, fn_anti_antibiotic_protein_15: $i > $i).
% 28.89/28.94  tff(decl_8987, type, fn_anti_antibiotic_protein_16: $i > $i).
% 28.89/28.94  tff(decl_8988, type, fn_anti_antibiotic_protein_17: $i > $i).
% 28.89/28.94  tff(decl_8989, type, fn_anti_antibiotic_protein_18: $i > $i).
% 28.89/28.94  tff(decl_8990, type, fn_anti_antibiotic_protein_19: $i > $i).
% 28.89/28.94  tff(decl_8991, type, fn_anti_antibiotic_protein_20: $i > $i).
% 28.89/28.94  tff(decl_8992, type, fn_anti_antibiotic_protein_21: $i > $i).
% 28.89/28.94  tff(decl_8993, type, fn_anti_antibiotic_protein_22: $i > $i).
% 28.89/28.94  tff(decl_8994, type, fn_anti_antibiotic_protein_23: $i > $i).
% 28.89/28.94  tff(decl_8995, type, fn_anti_antibiotic_protein_24: $i > $i).
% 28.89/28.94  tff(decl_8996, type, fn_anti_antibiotic_protein_25: $i > $i).
% 28.89/28.94  tff(decl_8997, type, fn_anti_antibiotic_protein_26: $i > $i).
% 28.89/28.94  tff(decl_8998, type, fn_anti_antibiotic_protein_27: $i > $i).
% 28.89/28.94  tff(decl_8999, type, fn_anti_antibiotic_protein_28: $i > $i).
% 28.89/28.94  tff(decl_9000, type, fn_anti_antibiotic_protein_29: $i > $i).
% 28.89/28.94  tff(decl_9001, type, chemical_digestion_1: $i > $o).
% 28.89/28.94  tff(decl_9002, type, fn_anti_antibiotic_protein_30: $i > $i).
% 28.89/28.94  tff(decl_9003, type, fn_anti_antibiotic_protein_31: $i > $i).
% 28.89/28.94  tff(decl_9004, type, fn_anti_antibiotic_protein_32: $i > $i).
% 28.89/28.94  tff(decl_9005, type, fn_anti_antibiotic_protein_33: $i > $i).
% 28.89/28.94  tff(decl_9006, type, fn_anti_antibiotic_protein_34: $i > $i).
% 28.89/28.94  tff(decl_9007, type, fn_anti_antibiotic_protein_35: $i > $i).
% 28.89/28.94  tff(decl_9008, type, fn_chemical_digestion_1: $i > $i).
% 28.89/28.94  tff(decl_9009, type, fn_chemical_digestion_2: $i > $i).
% 28.89/28.94  tff(decl_9010, type, 'Size_EntityBeingDigested': $i).
% 28.89/28.94  tff(decl_9011, type, antibacterial_agent_1: $i > $o).
% 28.89/28.94  tff(decl_9012, type, 'Antibacterial-Agent': $i).
% 28.89/28.94  tff(decl_9013, type, 'A poisonous substance that kills, inhibits reproduction, or inhibits development of bacteria.': $i).
% 28.89/28.94  tff(decl_9014, type, 'agent of antibacterial': $i).
% 28.89/28.94  tff(decl_9015, type, 'antibacterial agent': $i).
% 28.89/28.94  tff(decl_9016, type, 'antibacterial-agent': $i).
% 28.89/28.94  tff(decl_9017, type, 'Antibiotic': $i).
% 28.89/28.94  tff(decl_9018, type, 'A chemical that kills bacteria or inhibits their growth.': $i).
% 28.89/28.94  tff(decl_9019, type, antibacterial: $i).
% 28.89/28.94  tff(decl_9020, type, antibiotic: $i).
% 28.89/28.94  tff(decl_9021, type, fn_antibiotic_1: $i > $i).
% 28.89/28.94  tff(decl_9022, type, fn_antibiotic_2: $i > $i).
% 28.89/28.94  tff(decl_9023, type, fn_antibiotic_3: $i > $i).
% 28.89/28.94  tff(decl_9024, type, fn_antibiotic_4: $i > $i).
% 28.89/28.94  tff(decl_9025, type, inhibition_1: $i > $o).
% 28.89/28.94  tff(decl_9026, type, fn_antibiotic_5: $i > $i).
% 28.89/28.94  tff(decl_9027, type, enzyme_inhibitor_1: $i > $o).
% 28.89/28.94  tff(decl_9028, type, fn_antibiotic_6: $i > $i).
% 28.89/28.94  tff(decl_9029, type, enzyme_1: $i > $o).
% 28.89/28.94  tff(decl_9030, type, fn_antibiotic_7: $i > $i).
% 28.89/28.94  tff(decl_9031, type, fn_antibiotic_8: $i > $i).
% 28.89/28.94  tff(decl_9032, type, fn_antibiotic_9: $i > $i).
% 28.89/28.94  tff(decl_9033, type, fn_enzyme_inhibitor_6: $i > $i).
% 28.89/28.94  tff(decl_9034, type, fn_enzyme_inhibitor_5: $i > $i).
% 28.89/28.94  tff(decl_9035, type, fn_enzyme_inhibitor_1: $i > $i).
% 28.89/28.94  tff(decl_9036, type, fn_prokaryote_3: $i > $i).
% 28.89/28.94  tff(decl_9037, type, fn_enzyme_inhibitor_7: $i > $i).
% 28.89/28.94  tff(decl_9038, type, fn_enzyme_regulator_2: $i > $i).
% 28.89/28.94  tff(decl_9039, type, fn_enzyme_inhibitor_3: $i > $i).
% 28.89/28.94  tff(decl_9040, type, fn_enzyme_regulator_3: $i > $i).
% 28.89/28.94  tff(decl_9041, type, fn_enzyme_inhibitor_2: $i > $i).
% 28.89/28.94  tff(decl_9042, type, antibiotic_resistance_1: $i > $o).
% 28.89/28.94  tff(decl_9043, type, 'Antibiotic-Resistance': $i).
% 28.89/28.94  tff(decl_9044, type, 'The condition when bacteria have evolved the ability to survive exposure to one or more antibiotics.': $i).
% 28.89/28.94  tff(decl_9045, type, 'resistance of antibiotic': $i).
% 28.89/28.94  tff(decl_9046, type, 'antibiotic resistance': $i).
% 28.89/28.94  tff(decl_9047, type, 'antibiotic-resistance': $i).
% 28.89/28.94  tff(decl_9048, type, antibiotic_resistance_process_1: $i > $o).
% 28.89/28.94  tff(decl_9049, type, 'Antibiotic-Resistance-Process': $i).
% 28.89/28.94  tff(decl_9050, type, 'Any process by which a bacterial cell resists harm by an antibiotic substance.': $i).
% 28.89/28.94  tff(decl_9051, type, 'be resistant': $i).
% 28.89/28.94  tff(decl_9052, type, 'antibiotic resistance process': $i).
% 28.89/28.94  tff(decl_9053, type, 'antibiotic-resistance-process': $i).
% 28.89/28.94  tff(decl_9054, type, cell_survival_1: $i > $o).
% 28.89/28.94  tff(decl_9055, type, antibody_1: $i > $o).
% 28.89/28.94  tff(decl_9056, type, 'Antibody': $i).
% 28.89/28.94  tff(decl_9057, type, 'Also called immunoglobulin; a protein produced and secreted by plasma cells that recognizes and binds only to a particular antigen.': $i).
% 28.89/28.94  tff(decl_9058, type, ig: $i).
% 28.89/28.94  tff(decl_9059, type, immunoglobulin: $i).
% 28.89/28.94  tff(decl_9060, type, antibody: $i).
% 28.89/28.94  tff(decl_9061, type, immunoglobulin_protein_1: $i > $o).
% 28.89/28.94  tff(decl_9062, type, fn_antibody_1: $i > $i).
% 28.89/28.94  tff(decl_9063, type, vertebrate_1: $i > $o).
% 28.89/28.94  tff(decl_9064, type, fn_antibody_2: $i > $i).
% 28.89/28.94  tff(decl_9065, type, defense_1: $i > $o).
% 28.89/28.94  tff(decl_9066, type, fn_antibody_3: $i > $i).
% 28.89/28.94  tff(decl_9067, type, fn_antibody_8: $i > $i).
% 28.89/28.94  tff(decl_9068, type, fn_antibody_9: $i > $i).
% 28.89/28.94  tff(decl_9069, type, fn_antibody_10: $i > $i).
% 28.89/28.94  tff(decl_9070, type, fn_antibody_11: $i > $i).
% 28.89/28.94  tff(decl_9071, type, fn_antibody_12: $i > $i).
% 28.89/28.94  tff(decl_9072, type, fn_antibody_13: $i > $i).
% 28.89/28.94  tff(decl_9073, type, fn_antibody_14: $i > $i).
% 28.89/28.94  tff(decl_9074, type, fn_antibody_15: $i > $i).
% 28.89/28.94  tff(decl_9075, type, fn_antibody_16: $i > $i).
% 28.89/28.94  tff(decl_9076, type, fn_antibody_17: $i > $i).
% 28.89/28.94  tff(decl_9077, type, fn_antibody_18: $i > $i).
% 28.89/28.94  tff(decl_9078, type, fn_antibody_19: $i > $i).
% 28.89/28.94  tff(decl_9079, type, fn_antibody_20: $i > $i).
% 28.89/28.94  tff(decl_9080, type, fn_antibody_21: $i > $i).
% 28.89/28.94  tff(decl_9081, type, fn_antibody_22: $i > $i).
% 28.89/28.94  tff(decl_9082, type, fn_antibody_23: $i > $i).
% 28.89/28.94  tff(decl_9083, type, foreign_substance_1: $i > $o).
% 28.89/28.94  tff(decl_9084, type, fn_antibody_24: $i > $i).
% 28.89/28.94  tff(decl_9085, type, fn_antibody_25: $i > $i).
% 28.89/28.94  tff(decl_9086, type, fn_antibody_6: $i > $i).
% 28.89/28.94  tff(decl_9087, type, fn_antibody_4: $i > $i).
% 28.89/28.94  tff(decl_9088, type, fn_antibody_5: $i > $i).
% 28.89/28.94  tff(decl_9089, type, fn_antibody_7: $i > $i).
% 28.89/28.94  tff(decl_9090, type, anticodon_1: $i > $o).
% 28.89/28.94  tff(decl_9091, type, 'Anticodon': $i).
% 28.89/28.94  tff(decl_9092, type, 'A sequence of three nucleotides at one end of a tRNA molecule that recognizes and binds to the complementary codon on a mRNA transcript.': $i).
% 28.89/28.94  tff(decl_9093, type, 'anti codon': $i).
% 28.89/28.94  tff(decl_9094, type, anticodon: $i).
% 28.89/28.94  tff(decl_9095, type, 'genetic message': $i).
% 28.89/28.94  tff(decl_9096, type, fn_anticodon_1: $i > $i).
% 28.89/28.94  tff(decl_9097, type, fn_anticodon_2: $i > $i).
% 28.89/28.94  tff(decl_9098, type, recognize_1: $i > $o).
% 28.89/28.94  tff(decl_9099, type, fn_anticodon_3: $i > $i).
% 28.89/28.94  tff(decl_9100, type, codon_1: $i > $o).
% 28.89/28.94  tff(decl_9101, type, fn_perceive_1: $i > $i).
% 28.89/28.94  tff(decl_9102, type, codon_0: $i).
% 28.89/28.94  tff(decl_9103, type, 'Antidiuretic-Hormone': $i).
% 28.89/28.94  tff(decl_9104, type, 'A polypeptide hormone, also called vasopressin, secreted by the posterior pituitary in times of dehydration. It causes the body to increase water retention by increasing water absorption in the collecting ducts of the nephron.': $i).
% 28.89/28.94  tff(decl_9105, type, adh: $i).
% 28.89/28.94  tff(decl_9106, type, 'arginine vasopressin': $i).
% 28.89/28.94  tff(decl_9107, type, 'arginine-vasopressin': $i).
% 28.89/28.94  tff(decl_9108, type, avp: $i).
% 28.89/28.94  tff(decl_9109, type, vasopressin: $i).
% 28.89/28.94  tff(decl_9110, type, argipressin: $i).
% 28.89/28.94  tff(decl_9111, type, 'hormone of antidiuretic': $i).
% 28.89/28.94  tff(decl_9112, type, 'antidiuretic hormone': $i).
% 28.89/28.94  tff(decl_9113, type, 'antidiuretic-hormone': $i).
% 28.89/28.94  tff(decl_9114, type, pituitary_peptide_hormone_1: $i > $o).
% 28.89/28.94  tff(decl_9115, type, fn_antidiuretic_hormone_1: $i > $i).
% 28.89/28.94  tff(decl_9116, type, antigen_1: $i > $o).
% 28.89/28.94  tff(decl_9117, type, 'Antigen': $i).
% 28.89/28.94  tff(decl_9118, type, 'A substance that initiates an immune response by binding to receptors on B cells or T cells.': $i).
% 28.89/28.94  tff(decl_9119, type, antigen: $i).
% 28.89/28.94  tff(decl_9120, type, fn_antigen_1: $i > $i).
% 28.89/28.94  tff(decl_9121, type, 'Antigen-Binding-Site': $i).
% 28.89/28.94  tff(decl_9122, type, 'A molecular region at the tip of each branch of a Y-shaped antibody molecule; the antigen binding site recognizes and binds to a specific antigen molecule.': $i).
% 28.89/28.94  tff(decl_9123, type, 'antigen binding site': $i).
% 28.89/28.94  tff(decl_9124, type, 'antigen-binding site': $i).
% 28.89/28.94  tff(decl_9125, type, 'antigen-binding-site': $i).
% 28.89/28.94  tff(decl_9126, type, 'Antigen-Presentation': $i).
% 28.89/28.94  tff(decl_9127, type, 'The process by which a major histocompatibilty (MHC) molecule binds to an antigen molecule or fragment of a pathogen and presents it to the T cells of the immune system, which initiates an immune response.': $i).
% 28.89/28.94  tff(decl_9128, type, present: $i).
% 28.89/28.94  tff(decl_9129, type, 'presentation of antigen': $i).
% 28.89/28.94  tff(decl_9130, type, 'antigen presentation': $i).
% 28.89/28.94  tff(decl_9131, type, 'antigen-presentation': $i).
% 28.89/28.94  tff(decl_9132, type, antigen_presenting_cell_1: $i > $o).
% 28.89/28.94  tff(decl_9133, type, 'Antigen-Presenting-Cell': $i).
% 28.89/28.94  tff(decl_9134, type, 'A cell that ingests bacteria and viruses and then destroys them. Class II MHC molecules in these cells collect peptide remnants of this degradation and present them to helper T-cells.': $i).
% 28.89/28.94  tff(decl_9135, type, 'antigen presenting cell': $i).
% 28.89/28.94  tff(decl_9136, type, 'antigen-presenting cell': $i).
% 28.89/28.94  tff(decl_9137, type, 'antigen-presenting-cell': $i).
% 28.89/28.94  tff(decl_9138, type, immune_cell_1: $i > $o).
% 28.89/28.94  tff(decl_9139, type, effector_cell_1: $i > $o).
% 28.89/28.94  tff(decl_9140, type, eosinophil_1: $i > $o).
% 28.89/28.94  tff(decl_9141, type, mast_cell_1: $i > $o).
% 28.89/28.94  tff(decl_9142, type, natural_killer_cell_1: $i > $o).
% 28.89/28.94  tff(decl_9143, type, neutrophil_1: $i > $o).
% 28.89/28.94  tff(decl_9144, type, recombinant_immune_cell_1: $i > $o).
% 28.89/28.94  tff(decl_9145, type, antigen_receptor_1: $i > $o).
% 28.89/28.94  tff(decl_9146, type, 'Antigen-Receptor': $i).
% 28.89/28.94  tff(decl_9147, type, 'A polypeptide chain on the surface of B cells and T cells, that detects and binds to antigen molecules. This binding initiates an acquired immune response.': $i).
% 28.89/28.94  tff(decl_9148, type, 'receptor of antigen': $i).
% 28.89/28.94  tff(decl_9149, type, 'antigen receptor': $i).
% 28.89/28.94  tff(decl_9150, type, 'antigen-receptor': $i).
% 28.89/28.94  tff(decl_9151, type, receptor_protein_1: $i > $o).
% 28.89/28.94  tff(decl_9152, type, fn_antigen_receptor_1: $i > $i).
% 28.89/28.94  tff(decl_9153, type, fn_antigen_receptor_2: $i > $i).
% 28.89/28.94  tff(decl_9154, type, 'Antimicrobial-Protein': $i).
% 28.89/28.94  tff(decl_9155, type, 'A protein functioning in nonspecific defense by attacking microbes.': $i).
% 28.89/28.94  tff(decl_9156, type, 'protein of antimicrobial': $i).
% 28.89/28.94  tff(decl_9157, type, 'antimicrobial protein': $i).
% 28.89/28.94  tff(decl_9158, type, 'antimicrobial-protein': $i).
% 28.89/28.94  tff(decl_9159, type, antimony_1: $i > $o).
% 28.89/28.94  tff(decl_9160, type, 'Antimony': $i).
% 28.89/28.94  tff(decl_9161, type, 'Antimony is a metalloid atom with atomic number 51. It is represented by the symbol Sb.': $i).
% 28.89/28.94  tff(decl_9162, type, 'Sb': $i).
% 28.89/28.94  tff(decl_9163, type, antimony: $i).
% 28.89/28.94  tff(decl_9164, type, metalloid_atom_1: $i > $o).
% 28.89/28.94  tff(decl_9165, type, boron_1: $i > $o).
% 28.89/28.94  tff(decl_9166, type, fn_antimony_3: $i > $i).
% 28.89/28.94  tff(decl_9167, type, fn_antimony_4: $i > $i).
% 28.89/28.94  tff(decl_9168, type, fn_antimony_5: $i > $i).
% 28.89/28.94  tff(decl_9169, type, fn_antimony_8: $i > $i).
% 28.89/28.94  tff(decl_9170, type, fn_antimony_9: $i > $i).
% 28.89/28.94  tff(decl_9171, type, fn_antimony_10: $i > $i).
% 28.89/28.94  tff(decl_9172, type, fn_antimony_11: $i > $i).
% 28.89/28.94  tff(decl_9173, type, "51": $i).
% 28.89/28.94  tff(decl_9174, type, "71": $i).
% 28.89/28.94  tff(decl_9175, type, "5": $i).
% 28.89/28.94  tff(decl_9176, type, "2.05": $i).
% 28.89/28.94  tff(decl_9177, type, "122": $i).
% 28.89/28.94  tff(decl_9178, type, "121.8": $i).
% 28.89/28.94  tff(decl_9179, type, fn_antimony_7: $i > $i).
% 28.89/28.94  tff(decl_9180, type, fn_antimony_12: $i > $i).
% 28.89/28.94  tff(decl_9181, type, fn_antimony_6: $i > $i).
% 28.89/28.94  tff(decl_9182, type, antioxidant_1: $i > $o).
% 28.89/28.94  tff(decl_9183, type, 'Antioxidant': $i).
% 28.89/28.94  tff(decl_9184, type, 'A substance which removes oxidizing chemicals which may cause cellular damage.': $i).
% 28.89/28.94  tff(decl_9185, type, antioxidant: $i).
% 28.89/28.94  tff(decl_9186, type, antiparallel_arrangement_1: $i > $o).
% 28.89/28.94  tff(decl_9187, type, 'Antiparallel-Arrangement': $i).
% 28.89/28.94  tff(decl_9188, type, 'Two parallel objects oriented in the opposite direction from each other.': $i).
% 28.89/28.94  tff(decl_9189, type, 'anti parallel arrangement': $i).
% 28.89/28.94  tff(decl_9190, type, 'antiparallel arrangement': $i).
% 28.89/28.94  tff(decl_9191, type, 'antiparallel-arrangement': $i).
% 28.89/28.94  tff(decl_9192, type, relative_relationship_1: $i > $o).
% 28.89/28.94  tff(decl_9193, type, fn_antiparallel_arrangement_1: $i > $i).
% 28.89/28.94  tff(decl_9194, type, fn_antiparallel_arrangement_2: $i > $i).
% 28.89/28.94  tff(decl_9195, type, fn_antiparallel_arrangement_3: $i > $i).
% 28.89/28.94  tff(decl_9196, type, fn_antiparallel_arrangement_4: $i > $i).
% 28.89/28.94  tff(decl_9197, type, pyrimidine_1: $i > $o).
% 28.89/28.94  tff(decl_9198, type, fn_antiparallel_arrangement_5: $i > $i).
% 28.89/28.94  tff(decl_9199, type, parallel_dna_strand_1: $i > $o).
% 28.89/28.94  tff(decl_9200, type, fn_antiparallel_arrangement_6: $i > $i).
% 28.89/28.94  tff(decl_9201, type, antiparallel_dna_strand_1: $i > $o).
% 28.89/28.94  tff(decl_9202, type, fn_antiparallel_arrangement_7: $i > $i).
% 28.89/28.94  tff(decl_9203, type, fn_antiparallel_arrangement_8: $i > $i).
% 28.89/28.94  tff(decl_9204, type, hydrogen_bond_1: $i > $o).
% 28.89/28.94  tff(decl_9205, type, fn_antiparallel_arrangement_9: $i > $i).
% 28.89/28.94  tff(decl_9206, type, fn_chemical_bond_3: $i > $i).
% 28.89/28.94  tff(decl_9207, type, fn_information_1: $i > $i).
% 28.89/28.94  tff(decl_9208, type, 'Antiparallel-DNA-Strand': $i).
% 28.89/28.94  tff(decl_9209, type, 'A DNA molecule where the two strands are arranged in the opposite direction from each other.': $i).
% 28.89/28.94  tff(decl_9210, type, 'antiparallel dna strand': $i).
% 28.89/28.94  tff(decl_9211, type, 'antiparallel-dna-strand': $i).
% 28.89/28.94  tff(decl_9212, type, anuran_1: $i > $o).
% 28.89/28.94  tff(decl_9213, type, 'Anuran': $i).
% 28.89/28.94  tff(decl_9214, type, 'An order of amphibians amphibians (commonly referred to as frogs). Most frogs are characterized by long hind legs, a short body, webbed digits (fingers or toes), protruding eyes and the absence of a tail.': $i).
% 28.89/28.94  tff(decl_9215, type, frog: $i).
% 28.89/28.94  tff(decl_9216, type, anuran: $i).
% 28.89/28.94  tff(decl_9217, type, apodan_1: $i > $o).
% 28.89/28.94  tff(decl_9218, type, 'Anus': $i).
% 28.89/28.94  tff(decl_9219, type, 'Opening at the end of the alimentary canal through which solid waste is expelled from the body.': $i).
% 28.89/28.94  tff(decl_9220, type, anus: $i).
% 28.89/28.94  tff(decl_9221, type, ape_1: $i > $o).
% 28.89/28.94  tff(decl_9222, type, 'Ape': $i).
% 28.89/28.94  tff(decl_9223, type, 'An Old World anthropoid primates, which lack a tail and have longer arms compared to monkeys.': $i).
% 28.89/28.94  tff(decl_9224, type, ape: $i).
% 28.89/28.94  tff(decl_9225, type, chimpanzee_1: $i > $o).
% 28.89/28.94  tff(decl_9226, type, aphid_1: $i > $o).
% 28.89/28.94  tff(decl_9227, type, 'Aphid': $i).
% 28.89/28.94  tff(decl_9228, type, 'A type of insect which uses a needle-like mouthpart called a stylet to feed on phloem sap running in plant sieve-tube elements.': $i).
% 28.89/28.94  tff(decl_9229, type, 'plant louse': $i).
% 28.89/28.94  tff(decl_9230, type, 'plant-louse': $i).
% 28.89/28.94  tff(decl_9231, type, greenfly: $i).
% 28.89/28.94  tff(decl_9232, type, aphid: $i).
% 28.89/28.94  tff(decl_9233, type, hemiptera_1: $i > $o).
% 28.89/28.94  tff(decl_9234, type, beetle_1: $i > $o).
% 28.89/28.94  tff(decl_9235, type, caddisfly_1: $i > $o).
% 28.89/28.94  tff(decl_9236, type, dermaptera_1: $i > $o).
% 28.89/28.94  tff(decl_9237, type, diptera_1: $i > $o).
% 28.89/28.94  tff(decl_9238, type, isoptera_1: $i > $o).
% 28.89/28.94  tff(decl_9239, type, lepidoptera_1: $i > $o).
% 28.89/28.94  tff(decl_9240, type, mayfly_1: $i > $o).
% 28.89/28.94  tff(decl_9241, type, odonata_1: $i > $o).
% 28.89/28.94  tff(decl_9242, type, orthoptera_1: $i > $o).
% 28.89/28.94  tff(decl_9243, type, sucking_louse_1: $i > $o).
% 28.89/28.94  tff(decl_9244, type, fn_aphid_1: $i > $i).
% 28.89/28.94  tff(decl_9245, type, fluid_feeder_1: $i > $o).
% 28.89/28.94  tff(decl_9246, type, fn_fluid_feeder_6: $i > $i).
% 28.89/28.94  tff(decl_9247, type, 'Aphotic-Zone': $i).
% 28.89/28.94  tff(decl_9248, type, 'The depths of an ocean or lake where sunlight does not penetrate sufficiently to support photosynthesis.': $i).
% 28.89/28.94  tff(decl_9249, type, 'aphotic zone': $i).
% 28.89/28.94  tff(decl_9250, type, 'aphotic-zone': $i).
% 28.89/28.94  tff(decl_9251, type, apical_bud_1: $i > $o).
% 28.89/28.94  tff(decl_9252, type, 'Apical-Bud': $i).
% 28.89/28.94  tff(decl_9253, type, 'A bud at the terminal end of a plant shoot, which contains an apical meristem.': $i).
% 28.89/28.94  tff(decl_9254, type, 'apical bud': $i).
% 28.89/28.94  tff(decl_9255, type, 'apical-bud': $i).
% 28.89/28.94  tff(decl_9256, type, stem_organ_1: $i > $o).
% 28.89/28.94  tff(decl_9257, type, apical_dominance_1: $i > $o).
% 28.89/28.94  tff(decl_9258, type, 'Apical-Dominance': $i).
% 28.89/28.94  tff(decl_9259, type, 'The concentration of growth at the tip of a plant shoot, where a terminal bud partly inhibits the growth of axillary buds.': $i).
% 28.89/28.94  tff(decl_9260, type, 'apical dominance': $i).
% 28.89/28.94  tff(decl_9261, type, 'apical-dominance': $i).
% 28.89/28.94  tff(decl_9262, type, plant_growth_1: $i > $o).
% 28.89/28.94  tff(decl_9263, type, apical_ectodermal_ridge_1: $i > $o).
% 28.89/28.94  tff(decl_9264, type, 'Apical-Ectodermal-Ridge': $i).
% 28.89/28.94  tff(decl_9265, type, 'An area of thickened ectodermal cells at the distal end of each limb bud that acts as a signaling center to ensure proper development of the limb.': $i).
% 28.89/28.94  tff(decl_9266, type, 'apical ectodermal ridge': $i).
% 28.89/28.94  tff(decl_9267, type, 'apical-ectodermal-ridge': $i).
% 28.89/28.94  tff(decl_9268, type, dermal_tissue_1: $i > $o).
% 28.89/28.94  tff(decl_9269, type, bark_1: $i > $o).
% 28.89/28.94  tff(decl_9270, type, callus_1: $i > $o).
% 28.89/28.94  tff(decl_9271, type, calyptra_1: $i > $o).
% 28.89/28.94  tff(decl_9272, type, coleoptile_1: $i > $o).
% 28.89/28.94  tff(decl_9273, type, coleorhiza_1: $i > $o).
% 28.89/28.94  tff(decl_9274, type, endodermis_1: $i > $o).
% 28.89/28.94  tff(decl_9275, type, periderm_1: $i > $o).
% 28.89/28.94  tff(decl_9276, type, root_cap_1: $i > $o).
% 28.89/28.94  tff(decl_9277, type, seed_coat_1: $i > $o).
% 28.89/28.94  tff(decl_9278, type, apical_meristem_1: $i > $o).
% 28.89/28.94  tff(decl_9279, type, 'Apical-Meristem': $i).
% 28.89/28.94  tff(decl_9280, type, 'The growing tip of a plant shoot or root.  Cell division in apical meristems allows the shoot or root to grow longer.': $i).
% 28.89/28.94  tff(decl_9281, type, 'apical meristem': $i).
% 28.89/28.94  tff(decl_9282, type, 'apical-meristem': $i).
% 28.89/28.94  tff(decl_9283, type, meristem_1: $i > $o).
% 28.89/28.94  tff(decl_9284, type, embryonic_tissue_1: $i > $o).
% 28.89/28.94  tff(decl_9285, type, cork_cambium_1: $i > $o).
% 28.89/28.94  tff(decl_9286, type, floral_meristem_1: $i > $o).
% 28.89/28.94  tff(decl_9287, type, lateral_meristem_1: $i > $o).
% 28.89/28.94  tff(decl_9288, type, fn_apical_meristem_1: $i > $i).
% 28.89/28.94  tff(decl_9289, type, grow_1: $i > $o).
% 28.89/28.94  tff(decl_9290, type, fn_apical_meristem_2: $i > $i).
% 28.89/28.94  tff(decl_9291, type, apicomplexan_1: $i > $o).
% 28.89/28.94  tff(decl_9292, type, 'Apicomplexan': $i).
% 28.89/28.94  tff(decl_9293, type, 'A protist in the clade Apicomplexa, which are parasites of animals. Some cause diseases in humans; for example, the apicomplexan Plasmodium falciparum causes malaria.': $i).
% 28.89/28.94  tff(decl_9294, type, apicomplexan: $i).
% 28.89/28.94  tff(decl_9295, type, ciliate_1: $i > $o).
% 28.89/28.94  tff(decl_9296, type, 'Apodan': $i).
% 28.89/28.94  tff(decl_9297, type, 'A member of a group of legless amphibians, such as a caecilian.': $i).
% 28.89/28.94  tff(decl_9298, type, apodan: $i).
% 28.89/28.94  tff(decl_9299, type, apomixis_1: $i > $o).
% 28.89/28.94  tff(decl_9300, type, 'Apomixis': $i).
% 28.89/28.94  tff(decl_9301, type, 'In plants, the ability to reproduce from seeds that have not been fertilized by a male gamete.': $i).
% 28.89/28.94  tff(decl_9302, type, 'undergo apoximis': $i).
% 28.89/28.94  tff(decl_9303, type, apomixis: $i).
% 28.89/28.94  tff(decl_9304, type, asexual_reproduction_1: $i > $o).
% 28.89/28.94  tff(decl_9305, type, parthenogenesis_1: $i > $o).
% 28.89/28.94  tff(decl_9306, type, apoplast_1: $i > $o).
% 28.89/28.94  tff(decl_9307, type, 'Apoplast': $i).
% 28.89/28.94  tff(decl_9308, type, 'In plants, the continuum of cell walls plus the extracellular spaces.': $i).
% 28.89/28.94  tff(decl_9309, type, apoplast: $i).
% 28.89/28.94  tff(decl_9310, type, plant_region_1: $i > $o).
% 28.89/28.94  tff(decl_9311, type, fn_apoplast_1: $i > $i).
% 28.89/28.94  tff(decl_9312, type, fn_apoplast_2: $i > $i).
% 28.89/28.94  tff(decl_9313, type, plant_cell_wall_1: $i > $o).
% 28.89/28.94  tff(decl_9314, type, apoplastic_transport_1: $i > $o).
% 28.89/28.94  tff(decl_9315, type, 'Apoplastic-Transport': $i).
% 28.89/28.94  tff(decl_9316, type, 'Route of transport of water and solutes in vascular plants which follows a path external to the plant cell plasma membrane through the apoplast.': $i).
% 28.89/28.94  tff(decl_9317, type, 'apoplastic transport': $i).
% 28.89/28.94  tff(decl_9318, type, 'apoplastic-transport': $i).
% 28.89/28.94  tff(decl_9319, type, plant_transport_1: $i > $o).
% 28.89/28.94  tff(decl_9320, type, fn_apoplastic_transport_1: $i > $i).
% 28.89/28.94  tff(decl_9321, type, fn_apoplastic_transport_2: $i > $i).
% 28.89/28.94  tff(decl_9322, type, fn_apoplastic_transport_3: $i > $i).
% 28.89/28.94  tff(decl_9323, type, 'Apoptosis': $i).
% 28.89/28.94  tff(decl_9324, type, 'A program of controlled cell suicide, which is brought about by signals that trigger the activation of a cascade of suicide proteins in the cell destined to die.': $i).
% 28.89/28.94  tff(decl_9325, type, 'programmed cell death': $i).
% 28.89/28.94  tff(decl_9326, type, 'cause apoptosis': $i).
% 28.89/28.94  tff(decl_9327, type, 'self destruct': $i).
% 28.89/28.94  tff(decl_9328, type, 'self-destruct': $i).
% 28.89/28.94  tff(decl_9329, type, 'controlled cell death': $i).
% 28.89/28.94  tff(decl_9330, type, apoptosis: $i).
% 28.89/28.94  tff(decl_9331, type, fn_apoptosis_1: $i > $i).
% 28.89/28.94  tff(decl_9332, type, fn_apoptosis_2: $i > $i).
% 28.89/28.94  tff(decl_9333, type, fn_apoptosis_3: $i > $i).
% 28.89/28.94  tff(decl_9334, type, fn_apoptosis_4: $i > $i).
% 28.89/28.94  tff(decl_9335, type, fn_apoptosis_5: $i > $i).
% 28.89/28.94  tff(decl_9336, type, cellular_structure_1: $i > $o).
% 28.89/28.94  tff(decl_9337, type, fn_apoptosis_6: $i > $i).
% 28.89/28.94  tff(decl_9338, type, fn_apoptosis_7: $i > $i).
% 28.89/28.94  tff(decl_9339, type, fn_apoptosis_8: $i > $i).
% 28.89/28.94  tff(decl_9340, type, dna_polymerase_iii_1: $i > $o).
% 28.89/28.94  tff(decl_9341, type, fn_apoptosis_9: $i > $i).
% 28.89/28.94  tff(decl_9342, type, fn_apoptosis_10: $i > $i).
% 28.89/28.94  tff(decl_9343, type, fn_apoptosis_11: $i > $i).
% 28.89/28.94  tff(decl_9344, type, fn_apoptosis_12: $i > $i).
% 28.89/28.94  tff(decl_9345, type, fn_apoptosis_13: $i > $i).
% 28.89/28.94  tff(decl_9346, type, fn_apoptosis_14: $i > $i).
% 28.89/28.94  tff(decl_9347, type, fn_apoptosis_15: $i > $i).
% 28.89/28.94  tff(decl_9348, type, fn_apoptosis_16: $i > $i).
% 28.89/28.94  tff(decl_9349, type, fn_apoptosis_17: $i > $i).
% 28.89/28.94  tff(decl_9350, type, fn_apoptosis_18: $i > $i).
% 28.89/28.94  tff(decl_9351, type, fn_apoptosis_19: $i > $i).
% 28.89/28.94  tff(decl_9352, type, fn_apoptosis_20: $i > $i).
% 28.89/28.94  tff(decl_9353, type, fn_apoptosis_21: $i > $i).
% 28.89/28.94  tff(decl_9354, type, fn_apoptosis_22: $i > $i).
% 28.89/28.94  tff(decl_9355, type, fn_apoptosis_23: $i > $i).
% 28.89/28.94  tff(decl_9356, type, fn_apoptosis_24: $i > $i).
% 28.89/28.94  tff(decl_9357, type, fn_apoptosis_25: $i > $i).
% 28.89/28.94  tff(decl_9358, type, fn_apoptosis_26: $i > $i).
% 28.89/28.94  tff(decl_9359, type, fn_apoptosis_27: $i > $i).
% 28.89/28.94  tff(decl_9360, type, fn_apoptosis_28: $i > $i).
% 28.89/28.94  tff(decl_9361, type, fn_apoptosis_31: $i > $i).
% 28.89/28.94  tff(decl_9362, type, nuclease_1: $i > $o).
% 28.89/28.94  tff(decl_9363, type, fn_apoptosis_32: $i > $i).
% 28.89/28.94  tff(decl_9364, type, fn_apoptosis_33: $i > $i).
% 28.89/28.94  tff(decl_9365, type, fn_apoptosis_34: $i > $i).
% 28.89/28.94  tff(decl_9366, type, exergonic_reaction_1: $i > $o).
% 28.89/28.94  tff(decl_9367, type, fn_apoptosis_35: $i > $i).
% 28.89/28.94  tff(decl_9368, type, fn_apoptosis_36: $i > $i).
% 28.89/28.94  tff(decl_9369, type, phagocyte_1: $i > $o).
% 28.89/28.94  tff(decl_9370, type, fn_apoptosis_37: $i > $i).
% 28.89/28.94  tff(decl_9371, type, fn_apoptosis_38: $i > $i).
% 28.89/28.94  tff(decl_9372, type, fn_apoptosis_39: $i > $i).
% 28.89/28.94  tff(decl_9373, type, carry_1: $i > $o).
% 28.89/28.94  tff(decl_9374, type, fn_apoptosis_40: $i > $i).
% 28.89/28.94  tff(decl_9375, type, fn_apoptosis_41: $i > $i).
% 28.89/28.94  tff(decl_9376, type, fn_apoptosis_42: $i > $i).
% 28.89/28.94  tff(decl_9377, type, blebbing_1: $i > $o).
% 28.89/28.94  tff(decl_9378, type, fn_apoptosis_43: $i > $i).
% 28.89/28.94  tff(decl_9379, type, fn_apoptosis_44: $i > $i).
% 28.89/28.94  tff(decl_9380, type, fn_apoptosis_45: $i > $i).
% 28.89/28.94  tff(decl_9381, type, fn_apoptosis_46: $i > $i).
% 28.89/28.94  tff(decl_9382, type, fn_apoptosis_47: $i > $i).
% 28.89/28.94  tff(decl_9383, type, fn_apoptosis_48: $i > $i).
% 28.89/28.94  tff(decl_9384, type, fn_apoptosis_49: $i > $i).
% 28.89/28.94  tff(decl_9385, type, contract_1: $i > $o).
% 28.89/28.94  tff(decl_9386, type, fn_apoptosis_50: $i > $i).
% 28.89/28.94  tff(decl_9387, type, fn_apoptosis_51: $i > $i).
% 28.89/28.94  tff(decl_9388, type, fn_apoptosis_52: $i > $i).
% 28.89/28.94  tff(decl_9389, type, fn_apoptosis_53: $i > $i).
% 28.89/28.94  tff(decl_9390, type, fn_apoptosis_54: $i > $i).
% 28.89/28.94  tff(decl_9391, type, fn_apoptosis_55: $i > $i).
% 28.89/28.94  tff(decl_9392, type, fn_apoptosis_56: $i > $i).
% 28.89/28.94  tff(decl_9393, type, fn_apoptosis_57: $i > $i).
% 28.89/28.94  tff(decl_9394, type, fn_apoptosis_58: $i > $i).
% 28.89/28.94  tff(decl_9395, type, fn_apoptosis_59: $i > $i).
% 28.89/28.94  tff(decl_9396, type, fn_apoptosis_60: $i > $i).
% 28.89/28.94  tff(decl_9397, type, fn_apoptosis_61: $i > $i).
% 28.89/28.94  tff(decl_9398, type, fn_apoptosis_62: $i > $i).
% 28.89/28.94  tff(decl_9399, type, fn_apoptosis_63: $i > $i).
% 28.89/28.94  tff(decl_9400, type, fn_apoptosis_64: $i > $i).
% 28.89/28.94  tff(decl_9401, type, fn_apoptosis_65: $i > $i).
% 28.89/28.94  tff(decl_9402, type, fn_apoptosis_66: $i > $i).
% 28.89/28.94  tff(decl_9403, type, fn_apoptosis_67: $i > $i).
% 28.89/28.94  tff(decl_9404, type, fn_apoptosis_68: $i > $i).
% 28.89/28.94  tff(decl_9405, type, fn_apoptosis_69: $i > $i).
% 28.89/28.94  tff(decl_9406, type, fn_apoptosis_70: $i > $i).
% 28.89/28.94  tff(decl_9407, type, fn_apoptosis_71: $i > $i).
% 28.89/28.94  tff(decl_9408, type, fn_apoptosis_72: $i > $i).
% 28.89/28.94  tff(decl_9409, type, fn_apoptosis_73: $i > $i).
% 28.89/28.94  tff(decl_9410, type, motor_protein_1: $i > $o).
% 28.89/28.94  tff(decl_9411, type, fn_biomembrane_15: $i > $i).
% 28.89/28.94  tff(decl_9412, type, fn_produce_1: $i > $i).
% 28.89/28.94  tff(decl_9413, type, fn_nuclear_membrane_18: $i > $i).
% 28.89/28.94  tff(decl_9414, type, fn_intracellular_digestion_12: $i > $i).
% 28.89/28.94  tff(decl_9415, type, fn_intracellular_digestion_13: $i > $i).
% 28.89/28.94  tff(decl_9416, type, fn_food_vacuole_22: $i > $i).
% 28.89/28.94  tff(decl_9417, type, fn_hydrolysis_1: $i > $i).
% 28.89/28.94  tff(decl_9418, type, fn_nuclease_3: $i > $i).
% 28.89/28.94  tff(decl_9419, type, fn_nuclease_1: $i > $i).
% 28.89/28.94  tff(decl_9420, type, fn_protease_29: $i > $i).
% 28.89/28.94  tff(decl_9421, type, fn_protease_23: $i > $i).
% 28.89/28.94  tff(decl_9422, type, fn_protease_36: $i > $i).
% 28.89/28.94  tff(decl_9423, type, fn_vesicle_9: $i > $i).
% 28.89/28.94  tff(decl_9424, type, fn_cell_14: $i > $i).
% 28.89/28.94  tff(decl_9425, type, fn_cell_29: $i > $i).
% 28.89/28.94  tff(decl_9426, type, fn_cell_9: $i > $i).
% 28.89/28.94  tff(decl_9427, type, fn_cell_28: $i > $i).
% 28.89/28.94  tff(decl_9428, type, fn_cell_2: $i > $i).
% 28.89/28.94  tff(decl_9429, type, fn_cell_25: $i > $i).
% 28.89/28.94  tff(decl_9430, type, fn_cell_8: $i > $i).
% 28.89/28.94  tff(decl_9431, type, fn_food_vacuole_17: $i > $i).
% 28.89/28.94  tff(decl_9432, type, fn_er_membrane_32: $i > $i).
% 28.89/28.94  tff(decl_9433, type, fn_er_membrane_33: $i > $i).
% 28.89/28.94  tff(decl_9434, type, fn_hydrolysis_10: $i > $i).
% 28.89/28.94  tff(decl_9435, type, fn_hydrolysis_9: $i > $i).
% 28.89/28.94  tff(decl_9436, type, fn_intracellular_process_1: $i > $i).
% 28.89/28.94  tff(decl_9437, type, fn_blebbing_1: $i > $i).
% 28.89/28.94  tff(decl_9438, type, fn_nuclease_7: $i > $i).
% 28.89/28.94  tff(decl_9439, type, fn_nuclease_4: $i > $i).
% 28.89/28.94  tff(decl_9440, type, fn_hydrolysis_11: $i > $i).
% 28.89/28.94  tff(decl_9441, type, fn_nuclease_5: $i > $i).
% 28.89/28.94  tff(decl_9442, type, fn_nuclease_2: $i > $i).
% 28.89/28.94  tff(decl_9443, type, fn_protease_8: $i > $i).
% 28.89/28.94  tff(decl_9444, type, fn_food_vacuole_24: $i > $i).
% 28.89/28.94  tff(decl_9445, type, fn_hydrolase_1: $i > $i).
% 28.89/28.94  tff(decl_9446, type, fn_protease_17: $i > $i).
% 28.89/28.94  tff(decl_9447, type, fn_contract_4: $i > $i).
% 28.89/28.94  tff(decl_9448, type, fn_contract_1: $i > $i).
% 28.89/28.94  tff(decl_9449, type, fn_blebbing_2: $i > $i).
% 28.89/28.94  tff(decl_9450, type, raw_material_0: $i).
% 28.89/28.94  tff(decl_9451, type, cellular_structure_0: $i).
% 28.89/28.94  tff(decl_9452, type, fn_apoptosis_29: $i > $i).
% 28.89/28.94  tff(decl_9453, type, fn_apoptosis_30: $i > $i).
% 28.89/28.94  tff(decl_9454, type, appendix_1: $i > $o).
% 28.89/28.94  tff(decl_9455, type, 'Appendix': $i).
% 28.89/28.94  tff(decl_9456, type, 'A small, blind-ended extension of the vertebrate cecum that contains lymphoid cells and may contribute to immunity.': $i).
% 28.89/28.94  tff(decl_9457, type, appendix: $i).
% 28.89/28.94  tff(decl_9458, type, immune_organ_1: $i > $o).
% 28.89/28.94  tff(decl_9459, type, aquaporin_1: $i > $o).
% 28.89/28.94  tff(decl_9460, type, 'Aquaporin': $i).
% 28.89/28.94  tff(decl_9461, type, 'Aquaporins are proteins embedded in the cell membrane that regulate the flow of water.': $i).
% 28.89/28.94  tff(decl_9462, type, 'water channel protein': $i).
% 28.89/28.94  tff(decl_9463, type, 'water-channel-protein': $i).
% 28.89/28.94  tff(decl_9464, type, 'water pore': $i).
% 28.89/28.94  tff(decl_9465, type, 'water channel': $i).
% 28.89/28.94  tff(decl_9466, type, aquaporin: $i).
% 28.89/28.94  tff(decl_9467, type, channel_protein_1: $i > $o).
% 28.89/28.94  tff(decl_9468, type, fn_aquaporin_1: $i > $i).
% 28.89/28.94  tff(decl_9469, type, fn_aquaporin_2: $i > $i).
% 28.89/28.94  tff(decl_9470, type, fn_aquaporin_3: $i > $i).
% 28.89/28.94  tff(decl_9471, type, fn_aquaporin_4: $i > $i).
% 28.89/28.94  tff(decl_9472, type, fn_aquaporin_5: $i > $i).
% 28.89/28.94  tff(decl_9473, type, fn_aquaporin_6: $i > $i).
% 28.89/28.94  tff(decl_9474, type, fn_aquaporin_7: $i > $i).
% 28.89/28.94  tff(decl_9475, type, fn_aquaporin_8: $i > $i).
% 28.89/28.94  tff(decl_9476, type, fn_aquaporin_9: $i > $i).
% 28.89/28.94  tff(decl_9477, type, fn_aquaporin_10: $i > $i).
% 28.89/28.94  tff(decl_9478, type, fn_aquaporin_11: $i > $i).
% 28.89/28.94  tff(decl_9479, type, fn_aquaporin_12: $i > $i).
% 28.89/28.94  tff(decl_9480, type, fn_aquaporin_13: $i > $i).
% 28.89/28.94  tff(decl_9481, type, fn_aquaporin_14: $i > $i).
% 28.89/28.94  tff(decl_9482, type, fn_aquaporin_15: $i > $i).
% 28.89/28.94  tff(decl_9483, type, fn_aquaporin_16: $i > $i).
% 28.89/28.94  tff(decl_9484, type, fn_aquaporin_17: $i > $i).
% 28.89/28.94  tff(decl_9485, type, fn_aquaporin_18: $i > $i).
% 28.89/28.94  tff(decl_9486, type, fn_aquaporin_19: $i > $i).
% 28.89/28.94  tff(decl_9487, type, fn_aquaporin_20: $i > $i).
% 28.89/28.94  tff(decl_9488, type, fn_aquaporin_21: $i > $i).
% 28.89/28.94  tff(decl_9489, type, fn_aquaporin_22: $i > $i).
% 28.89/28.94  tff(decl_9490, type, fn_aquaporin_23: $i > $i).
% 28.89/28.94  tff(decl_9491, type, fn_aquaporin_24: $i > $i).
% 28.89/28.94  tff(decl_9492, type, fn_aquaporin_25: $i > $i).
% 28.89/28.94  tff(decl_9493, type, fn_aquaporin_26: $i > $i).
% 28.89/28.94  tff(decl_9494, type, fn_aquaporin_27: $i > $i).
% 28.89/28.94  tff(decl_9495, type, fn_aquaporin_28: $i > $i).
% 28.89/28.94  tff(decl_9496, type, fn_aquaporin_29: $i > $i).
% 28.89/28.94  tff(decl_9497, type, fn_aquaporin_30: $i > $i).
% 28.89/28.94  tff(decl_9498, type, fn_aquaporin_31: $i > $i).
% 28.89/28.94  tff(decl_9499, type, fn_aquaporin_32: $i > $i).
% 28.89/28.94  tff(decl_9500, type, fn_aquaporin_33: $i > $i).
% 28.89/28.94  tff(decl_9501, type, fn_aquaporin_34: $i > $i).
% 28.89/28.94  tff(decl_9502, type, fn_aquaporin_35: $i > $i).
% 28.89/28.94  tff(decl_9503, type, fn_aquaporin_36: $i > $i).
% 28.89/28.94  tff(decl_9504, type, fn_aquaporin_37: $i > $i).
% 28.89/28.94  tff(decl_9505, type, fn_aquaporin_38: $i > $i).
% 28.89/28.94  tff(decl_9506, type, fn_aquaporin_39: $i > $i).
% 28.89/28.94  tff(decl_9507, type, fn_aquaporin_40: $i > $i).
% 28.89/28.94  tff(decl_9508, type, fn_aquaporin_41: $i > $i).
% 28.89/28.94  tff(decl_9509, type, fn_aquaporin_42: $i > $i).
% 28.89/28.94  tff(decl_9510, type, fn_aquaporin_43: $i > $i).
% 28.89/28.94  tff(decl_9511, type, fn_aquaporin_44: $i > $i).
% 28.89/28.94  tff(decl_9512, type, fn_aquaporin_45: $i > $i).
% 28.89/28.94  tff(decl_9513, type, fn_aquaporin_46: $i > $i).
% 28.89/28.94  tff(decl_9514, type, fn_aquaporin_47: $i > $i).
% 28.89/28.94  tff(decl_9515, type, fn_aquaporin_48: $i > $i).
% 28.89/28.94  tff(decl_9516, type, fn_aquaporin_49: $i > $i).
% 28.89/28.94  tff(decl_9517, type, fn_aquaporin_50: $i > $i).
% 28.89/28.94  tff(decl_9518, type, fn_aquaporin_51: $i > $i).
% 28.89/28.94  tff(decl_9519, type, fn_aquaporin_52: $i > $i).
% 28.89/28.94  tff(decl_9520, type, fn_aquaporin_53: $i > $i).
% 28.89/28.94  tff(decl_9521, type, fn_aquaporin_54: $i > $i).
% 28.89/28.94  tff(decl_9522, type, hypertonic_solution_1: $i > $o).
% 28.89/28.94  tff(decl_9523, type, fn_aquaporin_55: $i > $i).
% 28.89/28.94  tff(decl_9524, type, fn_aquaporin_56: $i > $i).
% 28.89/28.94  tff(decl_9525, type, fn_aquaporin_57: $i > $i).
% 28.89/28.94  tff(decl_9526, type, fn_aquaporin_58: $i > $i).
% 28.89/28.94  tff(decl_9527, type, fn_aquaporin_59: $i > $i).
% 28.89/28.94  tff(decl_9528, type, fn_aquaporin_60: $i > $i).
% 28.89/28.94  tff(decl_9529, type, fn_aquaporin_61: $i > $i).
% 28.89/28.94  tff(decl_9530, type, fn_aquaporin_62: $i > $i).
% 28.89/28.94  tff(decl_9531, type, fn_aquaporin_63: $i > $i).
% 28.89/28.94  tff(decl_9532, type, fn_aquaporin_64: $i > $i).
% 28.89/28.94  tff(decl_9533, type, fn_aquaporin_65: $i > $i).
% 28.89/28.94  tff(decl_9534, type, fn_aquaporin_66: $i > $i).
% 28.89/28.94  tff(decl_9535, type, symmetrical_distribution_1: $i > $o).
% 28.89/28.94  tff(decl_9536, type, fn_aquaporin_67: $i > $i).
% 28.89/28.94  tff(decl_9537, type, thermal_motion_1: $i > $o).
% 28.89/28.94  tff(decl_9538, type, fn_aquaporin_68: $i > $i).
% 28.89/28.94  tff(decl_9539, type, fn_aquaporin_69: $i > $i).
% 28.89/28.94  tff(decl_9540, type, fn_aquaporin_70: $i > $i).
% 28.89/28.94  tff(decl_9541, type, fn_aquaporin_71: $i > $i).
% 28.89/28.94  tff(decl_9542, type, fn_aquaporin_72: $i > $i).
% 28.89/28.94  tff(decl_9543, type, fn_aquaporin_73: $i > $i).
% 28.89/28.94  tff(decl_9544, type, hydrophilic_channel_1: $i > $o).
% 28.89/28.94  tff(decl_9545, type, fn_aquaporin_74: $i > $i).
% 28.89/28.94  tff(decl_9546, type, fn_aquaporin_75: $i > $i).
% 28.89/28.94  tff(decl_9547, type, fn_aquaporin_76: $i > $i).
% 28.89/28.94  tff(decl_9548, type, fn_aquaporin_77: $i > $i).
% 28.89/28.94  tff(decl_9549, type, facilitated_diffusion_1: $i > $o).
% 28.89/28.94  tff(decl_9550, type, facilitated_diffusion_of_water_using_aquaporin_1: $i > $o).
% 28.89/28.94  tff(decl_9551, type, facilitated_diffusion_using_channel_protein_1: $i > $o).
% 28.89/28.94  tff(decl_9552, type, fn_aquaporin_78: $i > $i).
% 28.89/28.94  tff(decl_9553, type, fn_aquaporin_79: $i > $i).
% 28.89/28.94  tff(decl_9554, type, fn_aquaporin_80: $i > $i).
% 28.89/28.94  tff(decl_9555, type, fn_aquaporin_81: $i > $i).
% 28.89/28.94  tff(decl_9556, type, fn_aquaporin_82: $i > $i).
% 28.89/28.94  tff(decl_9557, type, fn_aquaporin_83: $i > $i).
% 28.89/28.94  tff(decl_9558, type, fn_aquaporin_84: $i > $i).
% 28.89/28.94  tff(decl_9559, type, fn_aquaporin_85: $i > $i).
% 28.89/28.94  tff(decl_9560, type, fn_aquaporin_86: $i > $i).
% 28.89/28.94  tff(decl_9561, type, fn_aquaporin_87: $i > $i).
% 28.89/28.94  tff(decl_9562, type, fn_aquaporin_88: $i > $i).
% 28.89/28.94  tff(decl_9563, type, fn_aquaporin_89: $i > $i).
% 28.89/28.94  tff(decl_9564, type, fn_aquaporin_90: $i > $i).
% 28.89/28.94  tff(decl_9565, type, fn_aquaporin_91: $i > $i).
% 28.89/28.94  tff(decl_9566, type, fn_aquaporin_92: $i > $i).
% 28.89/28.94  tff(decl_9567, type, fn_aquaporin_93: $i > $i).
% 28.89/28.94  tff(decl_9568, type, fn_aquaporin_94: $i > $i).
% 28.89/28.94  tff(decl_9569, type, fn_aquaporin_95: $i > $i).
% 28.89/28.94  tff(decl_9570, type, fn_aquaporin_96: $i > $i).
% 28.89/28.94  tff(decl_9571, type, fn_aquaporin_97: $i > $i).
% 28.89/28.94  tff(decl_9572, type, fn_aquaporin_98: $i > $i).
% 28.89/28.94  tff(decl_9573, type, fn_aquaporin_99: $i > $i).
% 28.89/28.94  tff(decl_9574, type, fn_aquaporin_100: $i > $i).
% 28.89/28.94  tff(decl_9575, type, fn_aquaporin_101: $i > $i).
% 28.89/28.94  tff(decl_9576, type, fn_aquaporin_102: $i > $i).
% 28.89/28.94  tff(decl_9577, type, fn_aquaporin_103: $i > $i).
% 28.89/28.94  tff(decl_9578, type, fn_hydrophilic_channel_1: $i > $i).
% 28.89/28.94  tff(decl_9579, type, fn_passive_transport_20: $i > $i).
% 28.89/28.94  tff(decl_9580, type, fn_passive_transport_29: $i > $i).
% 28.89/28.94  tff(decl_9581, type, fn_facilitated_diffusion_using_channel_protein_1: $i > $i).
% 28.89/28.94  tff(decl_9582, type, fn_passive_transport_1: $i > $i).
% 28.89/28.94  tff(decl_9583, type, fn_hypertonic_solution_5: $i > $i).
% 28.89/28.94  tff(decl_9584, type, fn_water_78: $i > $i).
% 28.89/28.94  tff(decl_9585, type, fn_facilitated_diffusion_of_water_using_aquaporin_2: $i > $i).
% 28.89/28.94  tff(decl_9586, type, fn_passive_transport_21: $i > $i).
% 28.89/28.94  tff(decl_9587, type, fn_biomembrane_105: $i > $i).
% 28.89/28.94  tff(decl_9588, type, fn_passive_transport_25: $i > $i).
% 28.89/28.94  tff(decl_9589, type, fn_facilitated_diffusion_of_water_using_aquaporin_9: $i > $i).
% 28.89/28.94  tff(decl_9590, type, fn_hydrophilic_channel_2: $i > $i).
% 28.89/28.94  tff(decl_9591, type, fn_facilitated_diffusion_using_channel_protein_14: $i > $i).
% 28.89/28.94  tff(decl_9592, type, fn_facilitated_diffusion_using_channel_protein_13: $i > $i).
% 28.89/28.94  tff(decl_9593, type, fn_water_96: $i > $i).
% 28.89/28.94  tff(decl_9594, type, fn_passive_transport_13: $i > $i).
% 28.89/28.94  tff(decl_9595, type, fn_water_95: $i > $i).
% 28.89/28.94  tff(decl_9596, type, fn_passive_transport_22: $i > $i).
% 28.89/28.94  tff(decl_9597, type, fn_facilitated_diffusion_of_water_using_aquaporin_4: $i > $i).
% 28.89/28.94  tff(decl_9598, type, fn_passive_transport_24: $i > $i).
% 28.89/28.94  tff(decl_9599, type, fn_facilitated_diffusion_using_channel_protein_2: $i > $i).
% 28.89/28.94  tff(decl_9600, type, fn_hypertonic_solution_6: $i > $i).
% 28.89/28.94  tff(decl_9601, type, fn_water_81: $i > $i).
% 28.89/28.94  tff(decl_9602, type, fn_hypertonic_solution_8: $i > $i).
% 28.89/28.94  tff(decl_9603, type, fn_hypertonic_solution_7: $i > $i).
% 28.89/28.94  tff(decl_9604, type, fn_water_80: $i > $i).
% 28.89/28.94  tff(decl_9605, type, fn_water_84: $i > $i).
% 28.89/28.94  tff(decl_9606, type, fn_thermal_motion_5: $i > $i).
% 28.89/28.94  tff(decl_9607, type, fn_passive_transport_14: $i > $i).
% 28.89/28.94  tff(decl_9608, type, fn_transmembrane_protein_2: $i > $i).
% 28.89/28.94  tff(decl_9609, type, fn_channel_protein_6: $i > $i).
% 28.89/28.94  tff(decl_9610, type, fn_channel_protein_3: $i > $i).
% 28.89/28.94  tff(decl_9611, type, fn_channel_protein_11: $i > $i).
% 28.89/28.94  tff(decl_9612, type, fn_channel_protein_4: $i > $i).
% 28.89/28.94  tff(decl_9613, type, fn_channel_protein_7: $i > $i).
% 28.89/28.94  tff(decl_9614, type, fn_transport_protein_15: $i > $i).
% 28.89/28.94  tff(decl_9615, type, fn_transport_protein_32: $i > $i).
% 28.89/28.94  tff(decl_9616, type, fn_integral_protein_7: $i > $i).
% 28.89/28.94  tff(decl_9617, type, fn_transport_protein_33: $i > $i).
% 28.89/28.94  tff(decl_9618, type, fn_transport_protein_4: $i > $i).
% 28.89/28.94  tff(decl_9619, type, fn_transport_protein_16: $i > $i).
% 28.89/28.94  tff(decl_9620, type, fn_channel_protein_5: $i > $i).
% 28.89/28.94  tff(decl_9621, type, fn_transport_protein_28: $i > $i).
% 28.89/28.94  tff(decl_9622, type, fn_channel_protein_8: $i > $i).
% 28.89/28.94  tff(decl_9623, type, aquatic_biogeochemical_cycle_1: $i > $o).
% 28.89/28.94  tff(decl_9624, type, 'Aquatic-Biogeochemical-Cycle': $i).
% 28.89/28.94  tff(decl_9625, type, 'Portion of a biogeochimal cycle which occurs in aquatic ecosystems. Biogeochemical cycles cycle chemicals through biotic and abiotic components of ecosystems.': $i).
% 28.89/28.94  tff(decl_9626, type, 'undergo the aquatic biogeochemical cycle': $i).
% 28.89/28.94  tff(decl_9627, type, 'aquatic biogeochemical cycle': $i).
% 28.89/28.94  tff(decl_9628, type, 'aquatic-biogeochemical-cycle': $i).
% 28.89/28.94  tff(decl_9629, type, biogeochemical_cycle_1: $i > $o).
% 28.89/28.94  tff(decl_9630, type, fn_aquatic_biogeochemical_cycle_1: $i > $i).
% 28.89/28.94  tff(decl_9631, type, fn_aquatic_biogeochemical_cycle_2: $i > $i).
% 28.89/28.94  tff(decl_9632, type, aquatic_ecosystem_1: $i > $o).
% 28.89/28.94  tff(decl_9633, type, fn_biogeochemical_cycle_2: $i > $i).
% 28.89/28.94  tff(decl_9634, type, fn_biogeochemical_cycle_1: $i > $i).
% 28.89/28.94  tff(decl_9635, type, 'Aquatic-Ecosystem': $i).
% 28.89/28.94  tff(decl_9636, type, 'An ecosystem, or collection of living organisms and the physical environment, that is located primarily in water.': $i).
% 28.89/28.94  tff(decl_9637, type, 'ecosystem of aquatic': $i).
% 28.89/28.94  tff(decl_9638, type, 'aquatic ecosystem': $i).
% 28.89/28.94  tff(decl_9639, type, 'aquatic-ecosystem': $i).
% 28.89/28.94  tff(decl_9640, type, ecosystem_1: $i > $o).
% 28.89/28.94  tff(decl_9641, type, fn_aquatic_ecosystem_3: $i > $i).
% 28.89/28.94  tff(decl_9642, type, fn_aquatic_ecosystem_4: $i > $i).
% 28.89/28.94  tff(decl_9643, type, fn_aquatic_ecosystem_5: $i > $i).
% 28.89/28.94  tff(decl_9644, type, limiting_nutrient_1: $i > $o).
% 28.89/28.94  tff(decl_9645, type, fn_aquatic_ecosystem_6: $i > $i).
% 28.89/28.94  tff(decl_9646, type, fn_aquatic_ecosystem_7: $i > $i).
% 28.89/28.94  tff(decl_9647, type, fn_aquatic_ecosystem_8: $i > $i).
% 28.89/28.94  tff(decl_9648, type, fn_aquatic_ecosystem_9: $i > $i).
% 28.89/28.94  tff(decl_9649, type, fn_aquatic_ecosystem_10: $i > $i).
% 28.89/28.94  tff(decl_9650, type, fn_aquatic_ecosystem_11: $i > $i).
% 28.89/28.94  tff(decl_9651, type, fn_aquatic_ecosystem_12: $i > $i).
% 28.89/28.94  tff(decl_9652, type, chemical_element_1: $i > $o).
% 28.89/28.94  tff(decl_9653, type, fn_ecosystem_10: $i > $i).
% 28.89/28.94  tff(decl_9654, type, fn_ecosystem_31: $i > $i).
% 28.89/28.94  tff(decl_9655, type, fn_ecosystem_19: $i > $i).
% 28.89/28.94  tff(decl_9656, type, aquatic_nitrogen_cycle_1: $i > $o).
% 28.89/28.94  tff(decl_9657, type, 'Aquatic-Nitrogen-Cycle': $i).
% 28.89/28.94  tff(decl_9658, type, 'The portion of the nitrogen cycle that occurs in water.': $i).
% 28.89/28.94  tff(decl_9659, type, 'undergo the aquatic nitrogen cycle': $i).
% 28.89/28.94  tff(decl_9660, type, 'aquatic nitrogen cycle': $i).
% 28.89/28.94  tff(decl_9661, type, 'aquatic-nitrogen-cycle': $i).
% 28.89/28.94  tff(decl_9662, type, fn_aquatic_nitrogen_cycle_1: $i > $i).
% 28.89/28.94  tff(decl_9663, type, fn_aquatic_nitrogen_cycle_2: $i > $i).
% 28.89/28.94  tff(decl_9664, type, biotic_factor_1: $i > $o).
% 28.89/28.94  tff(decl_9665, type, fn_aquatic_nitrogen_cycle_3: $i > $i).
% 28.89/28.94  tff(decl_9666, type, fn_aquatic_nitrogen_cycle_4: $i > $i).
% 28.89/28.94  tff(decl_9667, type, fn_aquatic_nitrogen_cycle_5: $i > $i).
% 28.89/28.94  tff(decl_9668, type, fn_aquatic_nitrogen_cycle_6: $i > $i).
% 28.89/28.94  tff(decl_9669, type, fn_aquatic_nitrogen_cycle_7: $i > $i).
% 28.89/28.94  tff(decl_9670, type, nitrification_1: $i > $o).
% 28.89/28.94  tff(decl_9671, type, fn_aquatic_nitrogen_cycle_8: $i > $i).
% 28.89/28.94  tff(decl_9672, type, fn_aquatic_nitrogen_cycle_9: $i > $i).
% 28.89/28.94  tff(decl_9673, type, death_1: $i > $o).
% 28.89/28.94  tff(decl_9674, type, fn_aquatic_nitrogen_cycle_10: $i > $i).
% 28.89/28.94  tff(decl_9675, type, fn_aquatic_nitrogen_cycle_11: $i > $i).
% 28.89/28.94  tff(decl_9676, type, fn_aquatic_nitrogen_cycle_12: $i > $i).
% 28.89/28.94  tff(decl_9677, type, fn_aquatic_nitrogen_cycle_13: $i > $i).
% 28.89/28.94  tff(decl_9678, type, dead_organism_1: $i > $o).
% 28.89/28.94  tff(decl_9679, type, fn_aquatic_nitrogen_cycle_14: $i > $i).
% 28.89/28.94  tff(decl_9680, type, fn_aquatic_nitrogen_cycle_15: $i > $i).
% 28.89/28.94  tff(decl_9681, type, fn_aquatic_nitrogen_cycle_16: $i > $i).
% 28.89/28.94  tff(decl_9682, type, fn_aquatic_nitrogen_cycle_17: $i > $i).
% 28.89/28.94  tff(decl_9683, type, fn_aquatic_nitrogen_cycle_18: $i > $i).
% 28.89/28.94  tff(decl_9684, type, fn_aquatic_nitrogen_cycle_19: $i > $i).
% 28.89/28.94  tff(decl_9685, type, nitrate_ion_1: $i > $o).
% 28.89/28.94  tff(decl_9686, type, fn_aquatic_nitrogen_cycle_20: $i > $i).
% 28.89/28.94  tff(decl_9687, type, no2_minus_1: $i > $o).
% 28.89/28.94  tff(decl_9688, type, fn_aquatic_nitrogen_cycle_21: $i > $i).
% 28.89/28.94  tff(decl_9689, type, fn_aquatic_nitrogen_cycle_22: $i > $i).
% 28.89/28.94  tff(decl_9690, type, fn_aquatic_nitrogen_cycle_23: $i > $i).
% 28.89/28.94  tff(decl_9691, type, oxidizing_agent_1: $i > $o).
% 28.89/28.94  tff(decl_9692, type, fn_aquatic_nitrogen_cycle_24: $i > $i).
% 28.89/28.94  tff(decl_9693, type, fn_aquatic_nitrogen_cycle_25: $i > $i).
% 28.89/28.94  tff(decl_9694, type, fn_aquatic_nitrogen_cycle_26: $i > $i).
% 28.89/28.94  tff(decl_9695, type, fn_aquatic_nitrogen_cycle_27: $i > $i).
% 28.89/28.94  tff(decl_9696, type, nh4_plus_1: $i > $o).
% 28.89/28.94  tff(decl_9697, type, fn_aquatic_nitrogen_cycle_28: $i > $i).
% 28.89/28.94  tff(decl_9698, type, fn_aquatic_nitrogen_cycle_29: $i > $i).
% 28.89/28.94  tff(decl_9699, type, fn_aquatic_nitrogen_cycle_30: $i > $i).
% 28.89/28.94  tff(decl_9700, type, nitrogen_fixation_1: $i > $o).
% 28.89/28.94  tff(decl_9701, type, fn_aquatic_nitrogen_cycle_31: $i > $i).
% 28.89/28.94  tff(decl_9702, type, fn_aquatic_nitrogen_cycle_32: $i > $i).
% 28.89/28.94  tff(decl_9703, type, nitrogen_fixing_bacterium_1: $i > $o).
% 28.89/28.94  tff(decl_9704, type, fn_aquatic_nitrogen_cycle_33: $i > $i).
% 28.89/28.94  tff(decl_9705, type, water_body_1: $i > $o).
% 28.89/28.94  tff(decl_9706, type, fn_aquatic_nitrogen_cycle_34: $i > $i).
% 28.89/28.94  tff(decl_9707, type, plankton_1: $i > $o).
% 28.89/28.94  tff(decl_9708, type, fn_aquatic_nitrogen_cycle_35: $i > $i).
% 28.89/28.94  tff(decl_9709, type, fn_aquatic_nitrogen_cycle_36: $i > $i).
% 28.89/28.94  tff(decl_9710, type, fn_aquatic_nitrogen_cycle_37: $i > $i).
% 28.89/28.94  tff(decl_9711, type, nitrogen_molecule_1: $i > $o).
% 28.89/28.94  tff(decl_9712, type, fn_aquatic_nitrogen_cycle_38: $i > $i).
% 28.89/28.94  tff(decl_9713, type, fn_aquatic_nitrogen_cycle_39: $i > $i).
% 28.89/28.94  tff(decl_9714, type, fn_aquatic_nitrogen_cycle_40: $i > $i).
% 28.89/28.94  tff(decl_9715, type, fn_aquatic_nitrogen_cycle_41: $i > $i).
% 28.89/28.94  tff(decl_9716, type, fn_death_1: $i > $i).
% 28.89/28.94  tff(decl_9717, type, fn_decomposition_1: $i > $i).
% 28.89/28.94  tff(decl_9718, type, fn_oxidation_11: $i > $i).
% 28.89/28.94  tff(decl_9719, type, fn_nitrification_2: $i > $i).
% 28.89/28.94  tff(decl_9720, type, fn_nitrification_3: $i > $i).
% 28.89/28.94  tff(decl_9721, type, fn_nitrification_11: $i > $i).
% 28.89/28.94  tff(decl_9722, type, fn_plankton_1: $i > $i).
% 28.89/28.94  tff(decl_9723, type, fn_death_2: $i > $i).
% 28.89/28.94  tff(decl_9724, type, fn_nitrogen_fixation_5: $i > $i).
% 28.89/28.94  tff(decl_9725, type, fn_nitrogen_fixation_1: $i > $i).
% 28.89/28.94  tff(decl_9726, type, fn_nitrogen_fixation_4: $i > $i).
% 28.89/28.94  tff(decl_9727, type, fn_nitrification_8: $i > $i).
% 28.89/28.94  tff(decl_9728, type, fn_nitrification_10: $i > $i).
% 28.89/28.94  tff(decl_9729, type, fn_nitrification_7: $i > $i).
% 28.89/28.94  tff(decl_9730, type, fn_electron_donor_2: $i > $i).
% 28.89/28.94  tff(decl_9731, type, fn_water_body_10: $i > $i).
% 28.89/28.94  tff(decl_9732, type, fn_water_body_5: $i > $i).
% 28.89/28.94  tff(decl_9733, type, fn_nitrification_6: $i > $i).
% 28.89/28.94  tff(decl_9734, type, fn_nitrification_12: $i > $i).
% 28.89/28.94  tff(decl_9735, type, fn_electron_donor_1: $i > $i).
% 28.89/28.94  tff(decl_9736, type, fn_nitrification_9: $i > $i).
% 28.89/28.94  tff(decl_9737, type, "-1.0e0": $i).
% 28.89/28.94  tff(decl_9738, type, aquatic_organism_1: $i > $o).
% 28.89/28.94  tff(decl_9739, type, 'Aquatic-Organism': $i).
% 28.89/28.94  tff(decl_9740, type, 'An organism that lives in water.': $i).
% 28.89/28.94  tff(decl_9741, type, 'organism of aquatic': $i).
% 28.89/28.94  tff(decl_9742, type, 'aquatic organism': $i).
% 28.89/28.94  tff(decl_9743, type, 'aquatic-organism': $i).
% 28.89/28.94  tff(decl_9744, type, 'Aquatic-Zone': $i).
% 28.89/28.94  tff(decl_9745, type, 'Specialized layer or region within an aquatic ecosystem which has unique properties, such as temperature and density. ZOnes often have unique communities of organisms.': $i).
% 28.89/28.94  tff(decl_9746, type, 'zone of aquatic': $i).
% 28.89/28.94  tff(decl_9747, type, 'aquatic zone': $i).
% 28.89/28.94  tff(decl_9748, type, 'aquatic-zone': $i).
% 28.89/28.94  tff(decl_9749, type, 'Aqueous-Humor': $i).
% 28.89/28.94  tff(decl_9750, type, 'Plasma-like liquid in the space between the lens and the cornea in the vertebrate eye; helps maintain the shape of the eye, supplies nutrients and oxygen to its tissues, and disposes of its wastes.': $i).
% 28.89/28.94  tff(decl_9751, type, 'aqueous humor': $i).
% 28.89/28.94  tff(decl_9752, type, 'aqueous-humor': $i).
% 28.89/28.94  tff(decl_9753, type, bodily_fluid_1: $i > $o).
% 28.89/28.94  tff(decl_9754, type, aqueous_salt_solution_1: $i > $o).
% 28.89/28.94  tff(decl_9755, type, 'Aqueous-Salt-Solution': $i).
% 28.89/28.94  tff(decl_9756, type, 'The salt crystal when placed in water dissolves as the attractions between its ions decrease.': $i).
% 28.89/28.94  tff(decl_9757, type, 'salt crystal in water': $i).
% 28.89/28.94  tff(decl_9758, type, 'aqueous salt solution': $i).
% 28.89/28.94  tff(decl_9759, type, 'aqueous-salt-solution': $i).
% 28.89/28.94  tff(decl_9760, type, salt_solution_1: $i > $o).
% 28.89/28.94  tff(decl_9761, type, sodium_chloride_crystal_1: $i > $o).
% 28.89/28.94  tff(decl_9762, type, fn_aqueous_salt_solution_1: $i > $i).
% 28.89/28.94  tff(decl_9763, type, fn_aqueous_salt_solution_2: $i > $i).
% 28.89/28.94  tff(decl_9764, type, fn_aqueous_salt_solution_3: $i > $i).
% 28.89/28.94  tff(decl_9765, type, ionic_bond_1: $i > $o).
% 28.89/28.94  tff(decl_9766, type, fn_aqueous_salt_solution_4: $i > $i).
% 28.89/28.94  tff(decl_9767, type, ionic_compound_1: $i > $o).
% 28.89/28.94  tff(decl_9768, type, fn_aqueous_salt_solution_6: $i > $i).
% 28.89/28.94  tff(decl_9769, type, fn_aqueous_salt_solution_7: $i > $i).
% 28.89/28.94  tff(decl_9770, type, fn_aqueous_salt_solution_8: $i > $i).
% 28.89/28.94  tff(decl_9771, type, solute_1: $i > $o).
% 28.89/28.94  tff(decl_9772, type, fn_aqueous_salt_solution_9: $i > $i).
% 28.89/28.94  tff(decl_9773, type, salt_substance_1: $i > $o).
% 28.89/28.94  tff(decl_9774, type, fn_ionic_compound_3: $i > $i).
% 28.89/28.94  tff(decl_9775, type, fn_ionic_bond_2: $i > $i).
% 28.89/28.94  tff(decl_9776, type, fn_ionic_bond_1: $i > $i).
% 28.89/28.94  tff(decl_9777, type, fn_solute_1: $i > $i).
% 28.89/28.94  tff(decl_9778, type, fn_ionic_bond_4: $i > $i).
% 28.89/28.94  tff(decl_9779, type, fn_ionic_bond_3: $i > $i).
% 28.89/28.94  tff(decl_9780, type, chemical_bond_0: $i).
% 28.89/28.94  tff(decl_9781, type, fn_salt_solution_2: $i > $i).
% 28.89/28.94  tff(decl_9782, type, fn_aqueous_salt_solution_5: $i > $i).
% 28.89/28.94  tff(decl_9783, type, 'Aqueous-Solution': $i).
% 28.89/28.94  tff(decl_9784, type, 'A solution in which water is the dissolving agent (i.e., solvent).': $i).
% 28.89/28.94  tff(decl_9785, type, 'aqueous solution': $i).
% 28.89/28.94  tff(decl_9786, type, 'aqueous-solution': $i).
% 28.89/28.94  tff(decl_9787, type, gel_1: $i > $o).
% 28.89/28.94  tff(decl_9788, type, fn_aqueous_solution_7: $i > $i).
% 28.89/28.94  tff(decl_9789, type, fn_aqueous_solution_10: $i > $i).
% 28.89/28.94  tff(decl_9790, type, fn_aqueous_solution_11: $i > $i).
% 28.89/28.94  tff(decl_9791, type, fn_aqueous_solution_12: $i > $i).
% 28.89/28.94  tff(decl_9792, type, fn_aqueous_solution_13: $i > $i).
% 28.89/28.94  tff(decl_9793, type, arabidopsis_1: $i > $o).
% 28.89/28.94  tff(decl_9794, type, 'Arabidopsis': $i).
% 28.89/28.94  tff(decl_9795, type, 'A member of the mustard family of plants, used as a model organism.': $i).
% 28.89/28.94  tff(decl_9796, type, 'arabidopsis thaliana': $i).
% 28.89/28.94  tff(decl_9797, type, 'arabidopsis-thaliana': $i).
% 28.89/28.94  tff(decl_9798, type, arabidopsis: $i).
% 28.89/28.94  tff(decl_9799, type, fn_arabidopsis_1: $i > $i).
% 28.89/28.94  tff(decl_9800, type, arabidopsis_development_1: $i > $o).
% 28.89/28.94  tff(decl_9801, type, 'Arabidopsis-Development': $i).
% 28.89/28.94  tff(decl_9802, type, 'Arabidopsis development includes the formation of a complete embryo from a zygote ; seed germination; the elaboration of a mature vegetative plant from the embryo; the formation of flowers, fruits, and seeds.': $i).
% 28.89/28.94  tff(decl_9803, type, 'development of arabidopsis': $i).
% 28.89/28.94  tff(decl_9804, type, 'arabidopsis development': $i).
% 28.89/28.94  tff(decl_9805, type, 'arabidopsis-development': $i).
% 28.89/28.94  tff(decl_9806, type, arabidopsis_thaliana_1: $i > $o).
% 28.89/28.94  tff(decl_9807, type, 'Arabidopsis-Thaliana': $i).
% 28.89/28.94  tff(decl_9808, type, 'Arabidopsis thaliana is a small flowering plant native to Europe, Asia, and northwestern Africa. A spring annual with a relatively short life cycle, Arabidopsis is popular as a model organism in plant biology and genetics.': $i).
% 28.89/28.94  tff(decl_9809, type, 'common wall cress': $i).
% 28.89/28.94  tff(decl_9810, type, drosophila_melanogaster_1: $i > $o).
% 28.89/28.94  tff(decl_9811, type, zebrafish_1: $i > $o).
% 28.89/28.94  tff(decl_9812, type, fn_arabidopsis_thaliana_1: $i > $i).
% 28.89/28.94  tff(decl_9813, type, molecular_genetics_1: $i > $o).
% 28.89/28.94  tff(decl_9814, type, arachnid_1: $i > $o).
% 28.89/28.94  tff(decl_9815, type, 'Arachnid': $i).
% 28.89/28.94  tff(decl_9816, type, 'A member of a major arthropod group, the cheliceriforms. Arachnids include spiders, scorpions, ticks, and mites.': $i).
% 28.89/28.94  tff(decl_9817, type, arachnid: $i).
% 28.89/28.94  tff(decl_9818, type, cheliceriform_1: $i > $o).
% 28.89/28.94  tff(decl_9819, type, arbuscular_mycorrhiza_1: $i > $o).
% 28.89/28.94  tff(decl_9820, type, 'Arbuscular-Mycorrhiza': $i).
% 28.89/28.94  tff(decl_9821, type, 'Association of a fungus with a plant root system in which the fungus penetrates the host (plant) cells plasma membranes.': $i).
% 28.89/28.94  tff(decl_9822, type, 'arbuscular mycorrhiza': $i).
% 28.89/28.94  tff(decl_9823, type, 'arbuscular-mycorrhiza': $i).
% 28.89/28.94  tff(decl_9824, type, mycorrhiza_1: $i > $o).
% 28.89/28.94  tff(decl_9825, type, arbuscular_mycorrhizal_fungus_1: $i > $o).
% 28.89/28.94  tff(decl_9826, type, 'Arbuscular-Mycorrhizal-Fungus': $i).
% 28.89/28.94  tff(decl_9827, type, 'The fungus that penetrates the cells of a plant\\s roots in an arbuscular mycorrhizal symbiosis.': $i).
% 28.89/28.94  tff(decl_9828, type, 'arbuscular mycorrhizal fungus': $i).
% 28.89/28.94  tff(decl_9829, type, 'arbuscular-mycorrhizal-fungus': $i).
% 28.89/28.94  tff(decl_9830, type, deuteromycete_1: $i > $o).
% 28.89/28.94  tff(decl_9831, type, coenocytic_fungus_1: $i > $o).
% 28.89/28.94  tff(decl_9832, type, mold_1: $i > $o).
% 28.89/28.94  tff(decl_9833, type, fn_arbuscular_mycorrhizal_fungus_1: $i > $i).
% 28.89/28.94  tff(decl_9834, type, archaea_1: $i > $o).
% 28.89/28.94  tff(decl_9835, type, 'Archaea': $i).
% 28.89/28.94  tff(decl_9836, type, 'Member of one of the two classes of prokaryotes, the other group being the bacterium.': $i).
% 28.89/28.94  tff(decl_9837, type, 'Prokaryote that is classified in the Archaea domain, one of two prokaryotic domains for Prokaryotes. The other domain is Bacteria.': $i).
% 28.89/28.94  tff(decl_9838, type, archaebacterium: $i).
% 28.89/28.94  tff(decl_9839, type, archaebacteria: $i).
% 28.89/28.94  tff(decl_9840, type, archaea: $i).
% 28.89/28.94  tff(decl_9841, type, 'Archaeopteryx': $i).
% 28.89/28.94  tff(decl_9842, type, 'A genus of extinct animal that is thought to represent a transitional state between feathered dinosaurs and modern birds.': $i).
% 28.89/28.94  tff(decl_9843, type, archaeopteryx: $i).
% 28.89/28.94  tff(decl_9844, type, reptile_1: $i > $o).
% 28.89/28.94  tff(decl_9845, type, crocodilia_1: $i > $o).
% 28.89/28.94  tff(decl_9846, type, lepidosaur_1: $i > $o).
% 28.89/28.94  tff(decl_9847, type, archaeplastid_1: $i > $o).
% 28.89/28.94  tff(decl_9848, type, 'Archaeplastid': $i).
% 28.89/28.94  tff(decl_9849, type, 'A monophyletic grouping of red algae, green algae, and land plants, descended from a protist ancestor. Proposed as one of five major categories of eukaryotic organisms in a current hypothesis of eukaryotic evolutionary history.': $i).
% 28.89/28.94  tff(decl_9850, type, archaeplastid: $i).
% 28.89/28.94  tff(decl_9851, type, eukaryotic_clade_1: $i > $o).
% 28.89/28.94  tff(decl_9852, type, excavata_1: $i > $o).
% 28.89/28.94  tff(decl_9853, type, unikonta_1: $i > $o).
% 28.89/28.94  tff(decl_9854, type, archaeplastida_1: $i > $o).
% 28.89/28.94  tff(decl_9855, type, 'Archaeplastida': $i).
% 28.89/28.94  tff(decl_9856, type, 'One of five supergroups of eukaryotes proposed in a current hypothesis of the evolutionary history of eukaryotes. This monophyletic group, which includes red algae, green algae, and land plants, descended from an ancient protist ancestor that engulfed a cyanobacterium.': $i).
% 28.89/28.94  tff(decl_9857, type, archaeplastida: $i).
% 28.89/28.94  tff(decl_9858, type, 'Archegonium': $i).
% 28.89/28.94  tff(decl_9859, type, 'In plants, a structure in which female gametes develop.': $i).
% 28.89/28.94  tff(decl_9860, type, archegonia: $i).
% 28.89/28.94  tff(decl_9861, type, archegonium: $i).
% 28.89/28.94  tff(decl_9862, type, archenteron_1: $i > $o).
% 28.89/28.94  tff(decl_9863, type, 'Archenteron': $i).
% 28.89/28.94  tff(decl_9864, type, 'The earliest animal gut, formed during gastrulation as an endoderm-lined cavity.': $i).
% 28.89/28.94  tff(decl_9865, type, archenteron: $i).
% 28.89/28.94  tff(decl_9866, type, developmental_space_1: $i > $o).
% 28.89/28.94  tff(decl_9867, type, coelom_1: $i > $o).
% 28.89/28.94  tff(decl_9868, type, mantle_cavity_1: $i > $o).
% 28.89/28.94  tff(decl_9869, type, rumen_1: $i > $o).
% 28.89/28.94  tff(decl_9870, type, architectural_structure_1: $i > $o).
% 28.89/28.94  tff(decl_9871, type, 'Architectural-Structure': $i).
% 28.89/28.94  tff(decl_9872, type, 'a stable, supported artifact': $i).
% 28.89/28.94  tff(decl_9873, type, construction: $i).
% 28.89/28.94  tff(decl_9874, type, structure: $i).
% 28.89/28.94  tff(decl_9875, type, 'architectural structure': $i).
% 28.89/28.94  tff(decl_9876, type, 'architectural-structure': $i).
% 28.89/28.94  tff(decl_9877, type, artifact_1: $i > $o).
% 28.89/28.94  tff(decl_9878, type, physical_document_1: $i > $o).
% 28.89/28.94  tff(decl_9879, type, furnishing_1: $i > $o).
% 28.89/28.94  tff(decl_9880, type, device_1: $i > $o).
% 28.89/28.94  tff(decl_9881, type, pharmaceutical_product_1: $i > $o).
% 28.89/28.94  tff(decl_9882, type, photographic_film_1: $i > $o).
% 28.89/28.94  tff(decl_9883, type, scientific_device_1: $i > $o).
% 28.89/28.94  tff(decl_9884, type, 'Archosaur': $i).
% 28.89/28.94  tff(decl_9885, type, 'A member of a group of diapsid amniotes that includes crocodiles, alligators, extinct dinosaurs, pterosaurs, and birds.': $i).
% 28.89/28.94  tff(decl_9886, type, archosaur: $i).
% 28.89/28.94  tff(decl_9887, type, 'Area-Constant': $i).
% 28.89/28.94  tff(decl_9888, type, 'constant of area': $i).
% 28.89/28.94  tff(decl_9889, type, 'area constant': $i).
% 28.89/28.94  tff(decl_9890, type, 'area-constant': $i).
% 28.89/28.94  tff(decl_9891, type, area_scale_1: $i > $o).
% 28.89/28.94  tff(decl_9892, type, 'Area-Scale': $i).
% 28.89/28.94  tff(decl_9893, type, 'scale of area': $i).
% 28.89/28.94  tff(decl_9894, type, 'area scale': $i).
% 28.89/28.94  tff(decl_9895, type, 'area-scale': $i).
% 28.89/28.94  tff(decl_9896, type, 'Area-Value': $i).
% 28.89/28.94  tff(decl_9897, type, 'area is a property for describing how big the two-dimensional extent of a Tangible-Entity is': $i).
% 28.89/28.94  tff(decl_9898, type, 'surface area': $i).
% 28.89/28.94  tff(decl_9899, type, expanse: $i).
% 28.89/28.94  tff(decl_9900, type, area: $i).
% 28.89/28.94  tff(decl_9901, type, 'value of area': $i).
% 28.89/28.94  tff(decl_9902, type, 'area value': $i).
% 28.89/28.94  tff(decl_9903, type, 'area-value': $i).
% 28.89/28.94  tff(decl_9904, type, 'Arginine': $i).
% 28.89/28.94  tff(decl_9905, type, arginine: $i).
% 28.89/28.94  tff(decl_9906, type, basic_amino_acid_1: $i > $o).
% 28.89/28.94  tff(decl_9907, type, argon_1: $i > $o).
% 28.89/28.94  tff(decl_9908, type, 'Argon': $i).
% 28.89/28.94  tff(decl_9909, type, 'Argon is a non metal atom with atomic number 18. It is represented by the symbol Ar.': $i).
% 28.89/28.94  tff(decl_9910, type, 'Ar': $i).
% 28.89/28.94  tff(decl_9911, type, argon: $i).
% 28.89/28.94  tff(decl_9912, type, inert_atom_1: $i > $o).
% 28.89/28.94  tff(decl_9913, type, neon_1: $i > $o).
% 28.89/28.94  tff(decl_9914, type, fn_argon_4: $i > $i).
% 28.89/28.94  tff(decl_9915, type, fn_argon_5: $i > $i).
% 28.89/28.94  tff(decl_9916, type, fn_argon_6: $i > $i).
% 28.89/28.94  tff(decl_9917, type, fn_argon_7: $i > $i).
% 28.89/28.94  tff(decl_9918, type, fn_argon_11: $i > $i).
% 28.89/28.94  tff(decl_9919, type, fn_argon_12: $i > $i).
% 28.89/28.94  tff(decl_9920, type, fn_argon_13: $i > $i).
% 28.89/28.94  tff(decl_9921, type, fn_argon_14: $i > $i).
% 28.89/28.94  tff(decl_9922, type, "22": $i).
% 28.89/28.94  tff(decl_9923, type, "18": $i).
% 28.89/28.94  tff(decl_9924, type, "8": $i).
% 28.89/28.94  tff(decl_9925, type, "40": $i).
% 28.89/28.94  tff(decl_9926, type, "39.95": $i).
% 28.89/28.94  tff(decl_9927, type, fn_argon_9: $i > $i).
% 28.89/28.94  tff(decl_9928, type, fn_argon_8: $i > $i).
% 28.89/28.94  tff(decl_9929, type, fn_argon_10: $i > $i).
% 28.89/28.94  tff(decl_9930, type, arithmetic_difference_1: $i > $o).
% 28.89/28.94  tff(decl_9931, type, 'Arithmetic-Difference': $i).
% 28.89/28.94  tff(decl_9932, type, difference: $i).
% 28.89/28.94  tff(decl_9933, type, 'difference of arithmetic': $i).
% 28.89/28.94  tff(decl_9934, type, 'arithmetic difference': $i).
% 28.89/28.94  tff(decl_9935, type, 'arithmetic-difference': $i).
% 28.89/28.94  tff(decl_9936, type, arithmetic_method_1: $i > $o).
% 28.89/28.94  tff(decl_9937, type, 'Arithmetic-Method': $i).
% 28.89/28.94  tff(decl_9938, type, 'method of arithmetic': $i).
% 28.89/28.94  tff(decl_9939, type, 'arithmetic method': $i).
% 28.89/28.94  tff(decl_9940, type, 'arithmetic-method': $i).
% 28.89/28.94  tff(decl_9941, type, arithmetic_product_1: $i > $o).
% 28.89/28.94  tff(decl_9942, type, 'Arithmetic-Product': $i).
% 28.89/28.94  tff(decl_9943, type, product: $i).
% 28.89/28.94  tff(decl_9944, type, 'mathematical product': $i).
% 28.89/28.94  tff(decl_9945, type, 'product of arithmetic': $i).
% 28.89/28.94  tff(decl_9946, type, 'arithmetic product': $i).
% 28.89/28.94  tff(decl_9947, type, 'arithmetic-product': $i).
% 28.89/28.94  tff(decl_9948, type, arithmetic_quotient_1: $i > $o).
% 28.89/28.94  tff(decl_9949, type, 'Arithmetic-Quotient': $i).
% 28.89/28.94  tff(decl_9950, type, quotient: $i).
% 28.89/28.94  tff(decl_9951, type, 'quotient of arithmetic': $i).
% 28.89/28.94  tff(decl_9952, type, 'arithmetic quotient': $i).
% 28.89/28.94  tff(decl_9953, type, 'arithmetic-quotient': $i).
% 28.89/28.94  tff(decl_9954, type, aromatic_hydrocarbon_1: $i > $o).
% 28.89/28.94  tff(decl_9955, type, 'Aromatic-Hydrocarbon': $i).
% 28.89/28.94  tff(decl_9956, type, 'Organic compounds which have carbon structures in ring formation with alternating single and double bonds.': $i).
% 28.89/28.94  tff(decl_9957, type, 'aromatic hydrocarbon': $i).
% 28.89/28.94  tff(decl_9958, type, 'aromatic-hydrocarbon': $i).
% 28.89/28.94  tff(decl_9959, type, arsenic_1: $i > $o).
% 28.89/28.94  tff(decl_9960, type, 'Arsenic': $i).
% 28.89/28.94  tff(decl_9961, type, 'Arsenic is a metalloid atom with atomic number 33. It is represented by the symbol As.': $i).
% 28.89/28.94  tff(decl_9962, type, 'As': $i).
% 28.89/28.94  tff(decl_9963, type, arsenic: $i).
% 28.89/28.94  tff(decl_9964, type, fn_arsenic_1: $i > $i).
% 28.89/28.94  tff(decl_9965, type, fn_arsenic_2: $i > $i).
% 28.89/28.94  tff(decl_9966, type, fn_arsenic_3: $i > $i).
% 28.89/28.94  tff(decl_9967, type, fn_arsenic_4: $i > $i).
% 28.89/28.94  tff(decl_9968, type, fn_arsenic_7: $i > $i).
% 28.89/28.94  tff(decl_9969, type, fn_arsenic_8: $i > $i).
% 28.89/28.94  tff(decl_9970, type, fn_arsenic_9: $i > $i).
% 28.89/28.94  tff(decl_9971, type, fn_arsenic_11: $i > $i).
% 28.89/28.94  tff(decl_9972, type, fn_arsenic_12: $i > $i).
% 28.89/28.94  tff(decl_9973, type, fn_arsenic_13: $i > $i).
% 28.89/28.94  tff(decl_9974, type, fn_arsenic_14: $i > $i).
% 28.89/28.94  tff(decl_9975, type, fn_arsenic_15: $i > $i).
% 28.89/28.94  tff(decl_9976, type, fn_arsenic_16: $i > $i).
% 28.89/28.94  tff(decl_9977, type, fn_arsenic_17: $i > $i).
% 28.89/28.94  tff(decl_9978, type, fn_arsenic_18: $i > $i).
% 28.89/28.94  tff(decl_9979, type, fn_arsenic_19: $i > $i).
% 28.89/28.94  tff(decl_9980, type, fn_electron_shell_3: $i > $i).
% 28.89/28.94  tff(decl_9981, type, fn_electron_shell_1: $i > $i).
% 28.89/28.94  tff(decl_9982, type, fn_electron_shell_2: $i > $i).
% 28.89/28.94  tff(decl_9983, type, "33": $i).
% 28.89/28.94  tff(decl_9984, type, "42": $i).
% 28.89/28.94  tff(decl_9985, type, "2.18": $i).
% 28.89/28.94  tff(decl_9986, type, "75": $i).
% 28.89/28.94  tff(decl_9987, type, "74.92": $i).
% 28.89/28.94  tff(decl_9988, type, fn_arsenic_21: $i > $i).
% 28.89/28.94  tff(decl_9989, type, fn_arsenic_22: $i > $i).
% 28.89/28.94  tff(decl_9990, type, fn_arsenic_20: $i > $i).
% 28.89/28.94  tff(decl_9991, type, fn_atom_3: $i > $i).
% 28.89/28.94  tff(decl_9992, type, fn_arsenic_10: $i > $i).
% 28.89/28.94  tff(decl_9993, type, fn_atom_4: $i > $i).
% 28.89/28.94  tff(decl_9994, type, 'Arteriole': $i).
% 28.89/28.94  tff(decl_9995, type, 'A small diameter blood vessel that carries blood between an artery and a capillary bed.': $i).
% 28.89/28.94  tff(decl_9996, type, arteriole: $i).
% 28.89/28.94  tff(decl_9997, type, artery_1: $i > $o).
% 28.89/28.94  tff(decl_9998, type, arteriosclerosis_1: $i > $o).
% 28.89/28.94  tff(decl_9999, type, 'Arteriosclerosis': $i).
% 28.89/28.94  tff(decl_10000, type, 'A hardening of the arteries that occurs when fat and/or mineral deposits accumulate and form structures called plaques in the walls of arteries.': $i).
% 28.89/28.94  tff(decl_10001, type, 'hardening of the arteries': $i).
% 28.89/28.94  tff(decl_10002, type, 'hardening-of-the-arteries': $i).
% 28.89/28.94  tff(decl_10003, type, arteriosclerosis: $i).
% 28.89/28.94  tff(decl_10004, type, cardiovascular_disease_1: $i > $o).
% 28.89/28.94  tff(decl_10005, type, atherosclerosis_1: $i > $o).
% 28.89/28.94  tff(decl_10006, type, stroke_1: $i > $o).
% 28.89/28.94  tff(decl_10007, type, thrombus_1: $i > $o).
% 28.89/28.94  tff(decl_10008, type, 'Artery': $i).
% 28.89/28.94  tff(decl_10009, type, 'A vessel that transports blood away from the heart to other parts of the body.': $i).
% 28.89/28.94  tff(decl_10010, type, artery: $i).
% 28.89/28.94  tff(decl_10011, type, blood_vessel_1: $i > $o).
% 28.89/28.94  tff(decl_10012, type, fn_artery_1: $i > $i).
% 28.89/28.94  tff(decl_10013, type, artery_wall_1: $i > $o).
% 28.89/28.94  tff(decl_10014, type, 'Artery-Wall': $i).
% 28.89/28.94  tff(decl_10015, type, 'The wall of an artery, consisting of three layers:  an outer layer of connective tissue, a middle layer of smooth muscle, and an inner layer of endothelial cells.': $i).
% 28.89/28.94  tff(decl_10016, type, 'wall of artery': $i).
% 28.89/28.94  tff(decl_10017, type, 'artery wall': $i).
% 28.89/28.94  tff(decl_10018, type, 'artery-wall': $i).
% 28.89/28.94  tff(decl_10019, type, 'Arthropod': $i).
% 28.89/28.94  tff(decl_10020, type, 'A segmented ecdysozoaan of the phylum Arthropoda, characterized by a jointed appendages and an exoskeleton that is molted periodically. Examples of arthropods include crustaceans, insects, spiders, and millipedes.': $i).
% 28.89/28.94  tff(decl_10021, type, arthropoda: $i).
% 28.89/28.94  tff(decl_10022, type, 'jointed appendage': $i).
% 28.89/28.94  tff(decl_10023, type, 'jointed-appendage': $i).
% 28.89/28.94  tff(decl_10024, type, arthropod: $i).
% 28.89/28.94  tff(decl_10025, type, bilaterally_symmetrical_animal_1: $i > $o).
% 28.89/28.94  tff(decl_10026, type, ecdysozoan_1: $i > $o).
% 28.89/28.94  tff(decl_10027, type, fn_arthropod_1: $i > $i).
% 28.89/28.94  tff(decl_10028, type, fn_arthropod_2: $i > $i).
% 28.89/28.94  tff(decl_10029, type, fn_arthropod_3: $i > $i).
% 28.89/28.94  tff(decl_10030, type, leg_1: $i > $o).
% 28.89/28.94  tff(decl_10031, type, fn_arthropod_4: $i > $i).
% 28.89/28.94  tff(decl_10032, type, fn_arthropod_5: $i > $i).
% 28.89/28.94  tff(decl_10033, type, fn_arthropod_6: $i > $i).
% 28.89/28.94  tff(decl_10034, type, fn_arthropod_7: $i > $i).
% 28.89/28.94  tff(decl_10035, type, fn_arthropod_8: $i > $i).
% 28.89/28.94  tff(decl_10036, type, exoskeleton_1: $i > $o).
% 28.89/28.94  tff(decl_10037, type, fn_exoskeleton_4: $i > $i).
% 28.89/28.94  tff(decl_10038, type, 'Artifact': $i).
% 28.89/28.94  tff(decl_10039, type, 'A man-made object': $i).
% 28.89/28.94  tff(decl_10040, type, artifact: $i).
% 28.89/28.94  tff(decl_10041, type, piece_of_substance_1: $i > $o).
% 28.89/28.94  tff(decl_10042, type, artificial_membrane_1: $i > $o).
% 28.89/28.94  tff(decl_10043, type, 'Artificial-Membrane': $i).
% 28.89/28.94  tff(decl_10044, type, 'Artificial or synthetic membrane, often used in laboratory experiments to provide selective permeability.': $i).
% 28.89/28.94  tff(decl_10045, type, 'synthetic membrane': $i).
% 28.89/28.94  tff(decl_10046, type, 'artificial membrane': $i).
% 28.89/28.94  tff(decl_10047, type, 'artificial-membrane': $i).
% 28.89/28.94  tff(decl_10048, type, artificial_selection_1: $i > $o).
% 28.89/28.94  tff(decl_10049, type, 'Artificial-Selection': $i).
% 28.89/28.94  tff(decl_10050, type, 'The intentional breeding of domesticated plants and animals for certain desirable traits.': $i).
% 28.89/28.94  tff(decl_10051, type, 'artificial selection': $i).
% 28.89/28.94  tff(decl_10052, type, 'artificial-selection': $i).
% 28.89/28.94  tff(decl_10053, type, artificial_selection_with_antibiotics_1: $i > $o).
% 28.89/28.94  tff(decl_10054, type, fn_artificial_selection_with_antibiotics_6: $i > $i).
% 28.89/28.94  tff(decl_10055, type, 'Artificial-Selection-With-Antibiotics': $i).
% 28.89/28.94  tff(decl_10056, type, 'Artificial selection using antibiotics.  The antibiotics kill untransformed bacterial cells in a culture, leaving only transformed bacterial cells.': $i).
% 28.89/28.94  tff(decl_10057, type, 'selection for transformed cells': $i).
% 28.89/28.94  tff(decl_10058, type, 'selection for transformation': $i).
% 28.89/28.94  tff(decl_10059, type, 'selection with antibiotics': $i).
% 28.89/28.94  tff(decl_10060, type, 'selection against untransformed cells': $i).
% 28.89/28.94  tff(decl_10061, type, select: $i).
% 28.89/28.94  tff(decl_10062, type, 'artificial selection with antibiotics': $i).
% 28.89/28.94  tff(decl_10063, type, 'artificial-selection-with-antibiotic': $i).
% 28.89/28.94  tff(decl_10064, type, autophagy_1: $i > $o).
% 28.89/28.94  tff(decl_10065, type, selective_degradation_1: $i > $o).
% 28.89/28.94  tff(decl_10066, type, fn_artificial_selection_with_antibiotics_2: $i > $i).
% 28.89/28.94  tff(decl_10067, type, culturing_1: $i > $o).
% 28.89/28.94  tff(decl_10068, type, fn_artificial_selection_with_antibiotics_3: $i > $i).
% 28.89/28.94  tff(decl_10069, type, untransformed_bacterial_cell_1: $i > $o).
% 28.89/28.94  tff(decl_10070, type, fn_artificial_selection_with_antibiotics_4: $i > $i).
% 28.89/28.94  tff(decl_10071, type, harm_1: $i > $o).
% 28.89/28.94  tff(decl_10072, type, fn_artificial_selection_with_antibiotics_5: $i > $i).
% 28.89/28.94  tff(decl_10073, type, fn_artificial_selection_with_antibiotics_7: $i > $i).
% 28.89/28.94  tff(decl_10074, type, transformed_bacterial_cell_1: $i > $o).
% 28.89/28.94  tff(decl_10075, type, fn_harm_1: $i > $i).
% 28.89/28.94  tff(decl_10076, type, artiodactyla_1: $i > $o).
% 28.89/28.94  tff(decl_10077, type, 'Artiodactyla': $i).
% 28.89/28.94  tff(decl_10078, type, 'Ungulates with an even number of toes. Species include sheep, cattle, pigs and deer.': $i).
% 28.89/28.94  tff(decl_10079, type, artiodactyla: $i).
% 28.89/28.94  tff(decl_10080, type, ungulate_1: $i > $o).
% 28.89/28.94  tff(decl_10081, type, perissodactyla_1: $i > $o).
% 28.89/28.94  tff(decl_10082, type, ascent_of_xylem_sap_1: $i > $o).
% 28.89/28.94  tff(decl_10083, type, 'Ascent-Of-Xylem-Sap': $i).
% 28.89/28.94  tff(decl_10084, type, 'Ascent of Xylem sap is the upward movement of water and minerals over long distances by bulk flow to the veins that branch throughout each leaf.': $i).
% 28.89/28.94  tff(decl_10085, type, ascend: $i).
% 28.89/28.94  tff(decl_10086, type, 'ascent of xylem sap': $i).
% 28.89/28.94  tff(decl_10087, type, 'ascent-of-xylem-sap': $i).
% 28.89/28.94  tff(decl_10088, type, fn_ascent_of_xylem_sap_2: $i > $i).
% 28.89/28.94  tff(decl_10089, type, fn_ascent_of_xylem_sap_4: $i > $i).
% 28.89/28.94  tff(decl_10090, type, fn_ascent_of_xylem_sap_5: $i > $i).
% 28.89/28.94  tff(decl_10091, type, shoot_1: $i > $o).
% 28.89/28.94  tff(decl_10092, type, fn_ascent_of_xylem_sap_6: $i > $i).
% 28.89/28.94  tff(decl_10093, type, fn_ascent_of_xylem_sap_7: $i > $i).
% 28.89/28.94  tff(decl_10094, type, transpirational_pull_1: $i > $o).
% 28.89/28.94  tff(decl_10095, type, fn_ascent_of_xylem_sap_8: $i > $i).
% 28.89/28.94  tff(decl_10096, type, bulk_flow_1: $i > $o).
% 28.89/28.94  tff(decl_10097, type, fn_ascent_of_xylem_sap_9: $i > $i).
% 28.89/28.94  tff(decl_10098, type, water_potential_gradient_1: $i > $o).
% 28.89/28.94  tff(decl_10099, type, fn_ascent_of_xylem_sap_10: $i > $i).
% 28.89/28.94  tff(decl_10100, type, fn_ascent_of_xylem_sap_11: $i > $i).
% 28.89/28.94  tff(decl_10101, type, fn_ascent_of_xylem_sap_12: $i > $i).
% 28.89/28.94  tff(decl_10102, type, fn_ascent_of_xylem_sap_13: $i > $i).
% 28.89/28.94  tff(decl_10103, type, fn_ascent_of_xylem_sap_14: $i > $i).
% 28.89/28.94  tff(decl_10104, type, fn_ascent_of_xylem_sap_15: $i > $i).
% 28.89/28.94  tff(decl_10105, type, fn_ascent_of_xylem_sap_16: $i > $i).
% 28.89/28.94  tff(decl_10106, type, xylem_sap_1: $i > $o).
% 28.89/28.94  tff(decl_10107, type, fn_ascent_of_xylem_sap_17: $i > $i).
% 28.89/28.94  tff(decl_10108, type, fn_ascent_of_xylem_sap_18: $i > $i).
% 28.89/28.94  tff(decl_10109, type, fn_ascent_of_xylem_sap_19: $i > $i).
% 28.89/28.94  tff(decl_10110, type, fn_ascent_of_xylem_sap_20: $i > $i).
% 28.89/28.94  tff(decl_10111, type, fn_ascent_of_xylem_sap_21: $i > $i).
% 28.89/28.94  tff(decl_10112, type, fn_ascent_of_xylem_sap_22: $i > $i).
% 28.89/28.94  tff(decl_10113, type, fn_ascent_of_xylem_sap_23: $i > $i).
% 28.89/28.94  tff(decl_10114, type, cellulose_1: $i > $o).
% 28.89/28.94  tff(decl_10115, type, fn_vascular_tissue_1: $i > $i).
% 28.89/28.94  tff(decl_10116, type, fn_plant_cell_82: $i > $i).
% 28.89/28.94  tff(decl_10117, type, fn_cellulose_34: $i > $i).
% 28.89/28.94  tff(decl_10118, type, fn_cellulose_37: $i > $i).
% 28.89/28.94  tff(decl_10119, type, fn_cellulose_35: $i > $i).
% 28.89/28.94  tff(decl_10120, type, fn_plant_cell_22: $i > $i).
% 28.89/28.94  tff(decl_10121, type, fn_cellulose_33: $i > $i).
% 28.89/28.94  tff(decl_10122, type, plant_transport_0: $i).
% 28.89/28.94  tff(decl_10123, type, ascocarp_1: $i > $o).
% 28.89/28.94  tff(decl_10124, type, 'Ascocarp': $i).
% 28.89/28.94  tff(decl_10125, type, 'The fruiting body of an ascomycete fungus.': $i).
% 28.89/28.94  tff(decl_10126, type, ascocarp: $i).
% 28.89/28.94  tff(decl_10127, type, fungal_organ_1: $i > $o).
% 28.89/28.94  tff(decl_10128, type, basidiocarp_1: $i > $o).
% 28.89/28.94  tff(decl_10129, type, truffle_1: $i > $o).
% 28.89/28.94  tff(decl_10130, type, ascomycete_1: $i > $o).
% 28.89/28.94  tff(decl_10131, type, 'Ascomycete': $i).
% 28.89/28.94  tff(decl_10132, type, 'Fungi from the phylum Ascomycota. The defining feature of the Ascomycota is the production of sexual spores in saclike asci (singular, ascus ).': $i).
% 28.89/28.94  tff(decl_10133, type, 'sac fungi': $i).
% 28.89/28.94  tff(decl_10134, type, 'sac-fungi': $i).
% 28.89/28.94  tff(decl_10135, type, ascomycete: $i).
% 28.89/28.94  tff(decl_10136, type, chytrid_1: $i > $o).
% 28.89/28.94  tff(decl_10137, type, club_fungus_1: $i > $o).
% 28.89/28.94  tff(decl_10138, type, glomeromycete_1: $i > $o).
% 28.89/28.94  tff(decl_10139, type, symbiotic_fungi_1: $i > $o).
% 28.89/28.94  tff(decl_10140, type, zygomycete_1: $i > $o).
% 28.89/28.94  tff(decl_10141, type, ascus_1: $i > $o).
% 28.89/28.94  tff(decl_10142, type, 'Ascus': $i).
% 28.89/28.94  tff(decl_10143, type, 'A capsule, containing usually 8 sexually produced ascospores, located at the distal end of a dikaryotic hypha in ascomycete fungi.': $i).
% 28.89/28.94  tff(decl_10144, type, ascus: $i).
% 28.89/28.94  tff(decl_10145, type, fungal_tissue_1: $i > $o).
% 28.89/28.94  tff(decl_10146, type, hypha_1: $i > $o).
% 28.89/28.94  tff(decl_10147, type, mycelium_1: $i > $o).
% 28.89/28.94  tff(decl_10148, type, zygosporangium_1: $i > $o).
% 28.89/28.94  tff(decl_10149, type, 'Asexual-Reproduction': $i).
% 28.89/28.94  tff(decl_10150, type, 'Any method of producing offspring from a single parent without the fusion of gametes. Examples of asexual reproduction include binary fission, budding, and fragmentation. The offspring of asexual reproduction are genetically identical to each other and to their parent.': $i).
% 28.89/28.94  tff(decl_10151, type, reproduce: $i).
% 28.89/28.94  tff(decl_10152, type, 'asexual reproduction': $i).
% 28.89/28.94  tff(decl_10153, type, 'asexual-reproduction': $i).
% 28.89/28.94  tff(decl_10154, type, sexual_reproduction_1: $i > $o).
% 28.89/28.94  tff(decl_10155, type, fn_asexual_reproduction_1: $i > $i).
% 28.89/28.94  tff(decl_10156, type, fn_asexual_reproduction_2: $i > $i).
% 28.89/28.94  tff(decl_10157, type, asian_ladybug_1: $i > $o).
% 28.89/28.94  tff(decl_10158, type, 'Asian-Ladybug': $i).
% 28.89/28.94  tff(decl_10159, type, 'A large coccinellid beetle originally native to eastern Asia, but which has been introduced to North America and Europe to control aphids and scale insects.': $i).
% 28.89/28.94  tff(decl_10160, type, 'ladybug of asian': $i).
% 28.89/28.94  tff(decl_10161, type, 'asian ladybug': $i).
% 28.89/28.94  tff(decl_10162, type, 'asian-ladybug': $i).
% 28.89/28.94  tff(decl_10163, type, bombardier_beetle_1: $i > $o).
% 28.89/28.94  tff(decl_10164, type, asparagine_1: $i > $o).
% 28.89/28.94  tff(decl_10165, type, 'Asparagine': $i).
% 28.89/28.94  tff(decl_10166, type, 'One of the 20 most common amino acids which make up proteins.': $i).
% 28.89/28.94  tff(decl_10167, type, asparagine: $i).
% 28.89/28.94  tff(decl_10168, type, fn_asparagine_1: $i > $i).
% 28.89/28.94  tff(decl_10169, type, fn_asparagine_2: $i > $i).
% 28.89/28.94  tff(decl_10170, type, fn_asparagine_5: $i > $i).
% 28.89/28.94  tff(decl_10171, type, fn_asparagine_6: $i > $i).
% 28.89/28.94  tff(decl_10172, type, fn_asparagine_7: $i > $i).
% 28.89/28.94  tff(decl_10173, type, fn_asparagine_8: $i > $i).
% 28.89/28.94  tff(decl_10174, type, polar_region_1: $i > $o).
% 28.89/28.94  tff(decl_10175, type, fn_asparagine_9: $i > $i).
% 28.89/28.94  tff(decl_10176, type, fn_asparagine_10: $i > $i).
% 28.89/28.94  tff(decl_10177, type, fn_asparagine_11: $i > $i).
% 28.89/28.94  tff(decl_10178, type, fn_asparagine_12: $i > $i).
% 28.89/28.94  tff(decl_10179, type, fn_asparagine_13: $i > $i).
% 28.89/28.94  tff(decl_10180, type, fn_asparagine_14: $i > $i).
% 28.89/28.94  tff(decl_10181, type, fn_asparagine_15: $i > $i).
% 28.89/28.94  tff(decl_10182, type, fn_asparagine_16: $i > $i).
% 28.89/28.94  tff(decl_10183, type, fn_asparagine_17: $i > $i).
% 28.89/28.94  tff(decl_10184, type, fn_asparagine_18: $i > $i).
% 28.89/28.94  tff(decl_10185, type, fn_asparagine_19: $i > $i).
% 28.89/28.94  tff(decl_10186, type, fn_asparagine_20: $i > $i).
% 28.89/28.94  tff(decl_10187, type, fn_asparagine_21: $i > $i).
% 28.89/28.94  tff(decl_10188, type, fn_asparagine_22: $i > $i).
% 28.89/28.94  tff(decl_10189, type, fn_asparagine_23: $i > $i).
% 28.89/28.94  tff(decl_10190, type, fn_asparagine_24: $i > $i).
% 28.89/28.94  tff(decl_10191, type, fn_asparagine_25: $i > $i).
% 28.89/28.94  tff(decl_10192, type, fn_asparagine_26: $i > $i).
% 28.89/28.94  tff(decl_10193, type, fn_asparagine_27: $i > $i).
% 28.89/28.94  tff(decl_10194, type, fn_asparagine_28: $i > $i).
% 28.89/28.94  tff(decl_10195, type, fn_asparagine_29: $i > $i).
% 28.89/28.94  tff(decl_10196, type, fn_asparagine_30: $i > $i).
% 28.89/28.94  tff(decl_10197, type, fn_asparagine_31: $i > $i).
% 28.89/28.94  tff(decl_10198, type, fn_asparagine_32: $i > $i).
% 28.89/28.94  tff(decl_10199, type, fn_asparagine_33: $i > $i).
% 28.89/28.94  tff(decl_10200, type, fn_asparagine_34: $i > $i).
% 28.89/28.94  tff(decl_10201, type, fn_asparagine_35: $i > $i).
% 28.89/28.94  tff(decl_10202, type, fn_asparagine_36: $i > $i).
% 28.89/28.94  tff(decl_10203, type, fn_asparagine_37: $i > $i).
% 28.89/28.94  tff(decl_10204, type, fn_asparagine_38: $i > $i).
% 28.89/28.94  tff(decl_10205, type, fn_asparagine_39: $i > $i).
% 28.89/28.94  tff(decl_10206, type, fn_asparagine_40: $i > $i).
% 28.89/28.94  tff(decl_10207, type, fn_asparagine_41: $i > $i).
% 28.89/28.94  tff(decl_10208, type, fn_asparagine_42: $i > $i).
% 28.89/28.94  tff(decl_10209, type, fn_asparagine_43: $i > $i).
% 28.89/28.94  tff(decl_10210, type, fn_asparagine_44: $i > $i).
% 28.89/28.94  tff(decl_10211, type, fn_asparagine_45: $i > $i).
% 28.89/28.94  tff(decl_10212, type, fn_asparagine_46: $i > $i).
% 28.89/28.94  tff(decl_10213, type, fn_asparagine_47: $i > $i).
% 28.89/28.94  tff(decl_10214, type, fn_asparagine_48: $i > $i).
% 28.89/28.94  tff(decl_10215, type, fn_asparagine_49: $i > $i).
% 28.89/28.94  tff(decl_10216, type, fn_asparagine_50: $i > $i).
% 28.89/28.94  tff(decl_10217, type, fn_carboxyl_group_57: $i > $i).
% 28.89/28.94  tff(decl_10218, type, fn_carboxyl_group_65: $i > $i).
% 28.89/28.94  tff(decl_10219, type, fn_polar_amino_acid_1: $i > $i).
% 28.89/28.94  tff(decl_10220, type, fn_polar_amino_acid_2: $i > $i).
% 28.89/28.94  tff(decl_10221, type, fn_asparagine_4: $i > $i).
% 28.89/28.94  tff(decl_10222, type, fn_asparagine_3: $i > $i).
% 28.89/28.94  tff(decl_10223, type, 'Aspartic-Acid': $i).
% 28.89/28.94  tff(decl_10224, type, 'One of the 20 most common amino acids which make up proteins. On its own, it also functions as a neurotransmitter.': $i).
% 28.89/28.94  tff(decl_10225, type, 'aspartic acid': $i).
% 28.89/28.94  tff(decl_10226, type, 'aspartic-acid': $i).
% 28.89/28.94  tff(decl_10227, type, fn_aspartic_acid_3: $i > $i).
% 28.89/28.94  tff(decl_10228, type, fn_aspartic_acid_4: $i > $i).
% 28.89/28.94  tff(decl_10229, type, fn_aspartic_acid_5: $i > $i).
% 28.89/28.94  tff(decl_10230, type, fn_aspartic_acid_6: $i > $i).
% 28.89/28.94  tff(decl_10231, type, fn_aspartic_acid_7: $i > $i).
% 28.89/28.94  tff(decl_10232, type, fn_aspartic_acid_8: $i > $i).
% 28.89/28.94  tff(decl_10233, type, fn_aspartic_acid_9: $i > $i).
% 28.89/28.94  tff(decl_10234, type, fn_aspartic_acid_10: $i > $i).
% 28.89/28.94  tff(decl_10235, type, fn_aspartic_acid_11: $i > $i).
% 28.89/28.94  tff(decl_10236, type, fn_aspartic_acid_12: $i > $i).
% 28.89/28.94  tff(decl_10237, type, fn_aspartic_acid_13: $i > $i).
% 28.89/28.94  tff(decl_10238, type, fn_aspartic_acid_14: $i > $i).
% 28.89/28.94  tff(decl_10239, type, fn_aspartic_acid_15: $i > $i).
% 28.89/28.94  tff(decl_10240, type, fn_aspartic_acid_16: $i > $i).
% 28.89/28.94  tff(decl_10241, type, fn_aspartic_acid_17: $i > $i).
% 28.89/28.94  tff(decl_10242, type, fn_aspartic_acid_18: $i > $i).
% 28.89/28.94  tff(decl_10243, type, fn_aspartic_acid_19: $i > $i).
% 28.89/28.94  tff(decl_10244, type, fn_aspartic_acid_20: $i > $i).
% 28.89/28.94  tff(decl_10245, type, fn_aspartic_acid_21: $i > $i).
% 28.89/28.94  tff(decl_10246, type, fn_aspartic_acid_2: $i > $i).
% 28.89/28.94  tff(decl_10247, type, fn_aspartic_acid_1: $i > $i).
% 28.89/28.94  tff(decl_10248, type, 'Assisted-Reproductive-Technology': $i).
% 28.89/28.94  tff(decl_10249, type, 'A general term for the methods used to achieve human pregnancy by artificial or partially artificial means, primarily to treat infertility.': $i).
% 28.89/28.94  tff(decl_10250, type, 'assisted reproductive technology': $i).
% 28.89/28.94  tff(decl_10251, type, 'assisted-reproductive-technology': $i).
% 28.89/28.94  tff(decl_10252, type, associative_learning_1: $i > $o).
% 28.89/28.94  tff(decl_10253, type, 'Associative-Learning': $i).
% 28.89/28.94  tff(decl_10254, type, 'The process by which an animal learns to form an association between two stimuli or between a stimulus and a behavior.': $i).
% 28.89/28.94  tff(decl_10255, type, 'associative learning': $i).
% 28.89/28.94  tff(decl_10256, type, 'associative-learning': $i).
% 28.89/28.94  tff(decl_10257, type, learning_1: $i > $o).
% 28.89/28.94  tff(decl_10258, type, habituation_1: $i > $o).
% 28.89/28.94  tff(decl_10259, type, social_learning_1: $i > $o).
% 28.89/28.94  tff(decl_10260, type, spatial_learning_1: $i > $o).
% 28.89/28.94  tff(decl_10261, type, assurance_1: $i > $o).
% 28.89/28.94  tff(decl_10262, type, 'Assurance': $i).
% 28.89/28.94  tff(decl_10263, type, 'a message expressing a commitment to do (or not do) something': $i).
% 28.89/28.94  tff(decl_10264, type, commitment: $i).
% 28.89/28.94  tff(decl_10265, type, dedication: $i).
% 28.89/28.94  tff(decl_10266, type, assurance: $i).
% 28.89/28.94  tff(decl_10267, type, astatine_1: $i > $o).
% 28.89/28.94  tff(decl_10268, type, 'Astatine': $i).
% 28.89/28.94  tff(decl_10269, type, 'Astatine is a metal atom with atomic number 85. It is represented by the symbol At.': $i).
% 28.89/28.94  tff(decl_10270, type, astatine: $i).
% 28.89/28.94  tff(decl_10271, type, fn_astatine_3: $i > $i).
% 28.89/28.94  tff(decl_10272, type, fn_astatine_4: $i > $i).
% 28.89/28.94  tff(decl_10273, type, fn_astatine_5: $i > $i).
% 28.89/28.94  tff(decl_10274, type, fn_astatine_9: $i > $i).
% 28.89/28.94  tff(decl_10275, type, fn_astatine_10: $i > $i).
% 28.89/28.94  tff(decl_10276, type, fn_astatine_11: $i > $i).
% 28.89/28.94  tff(decl_10277, type, fn_astatine_12: $i > $i).
% 28.89/28.94  tff(decl_10278, type, "125": $i).
% 28.89/28.94  tff(decl_10279, type, "85": $i).
% 28.89/28.94  tff(decl_10280, type, "2.2": $i).
% 28.89/28.94  tff(decl_10281, type, "210": $i).
% 28.89/28.94  tff(decl_10282, type, fn_astatine_7: $i > $i).
% 28.89/28.94  tff(decl_10283, type, fn_astatine_8: $i > $i).
% 28.89/28.94  tff(decl_10284, type, fn_astatine_6: $i > $i).
% 28.89/28.94  tff(decl_10285, type, 'Aster': $i).
% 28.89/28.94  tff(decl_10286, type, 'A star-shaped structure, comprised of short microtubules, that forms around each centrosome in an animal cell that is undergoing mitosis.': $i).
% 28.89/28.94  tff(decl_10287, type, 'astral rays': $i).
% 28.89/28.94  tff(decl_10288, type, 'astral-rays': $i).
% 28.89/28.94  tff(decl_10289, type, 'astral microtubules': $i).
% 28.89/28.94  tff(decl_10290, type, 'astral-microtubules': $i).
% 28.89/28.94  tff(decl_10291, type, aster: $i).
% 28.89/28.94  tff(decl_10292, type, axon_hillock_1: $i > $o).
% 28.89/28.94  tff(decl_10293, type, axon_1: $i > $o).
% 28.89/28.94  tff(decl_10294, type, cell_body_1: $i > $o).
% 28.89/28.94  tff(decl_10295, type, chromosomal_arrangement_1: $i > $o).
% 28.89/28.94  tff(decl_10296, type, dendrite_1: $i > $o).
% 28.89/28.94  tff(decl_10297, type, fertilization_envelope_1: $i > $o).
% 28.89/28.94  tff(decl_10298, type, fimbria_1: $i > $o).
% 28.89/28.94  tff(decl_10299, type, growth_cone_1: $i > $o).
% 28.89/28.94  tff(decl_10300, type, i_band_filament_1: $i > $o).
% 28.89/28.94  tff(decl_10301, type, myelin_sheath_1: $i > $o).
% 28.89/28.94  tff(decl_10302, type, node_of_ranvier_1: $i > $o).
% 28.89/28.94  tff(decl_10303, type, phragmoplast_1: $i > $o).
% 28.89/28.94  tff(decl_10304, type, platelet_1: $i > $o).
% 28.89/28.94  tff(decl_10305, type, preprophase_band_1: $i > $o).
% 28.89/28.94  tff(decl_10306, type, primary_cell_wall_1: $i > $o).
% 28.89/28.94  tff(decl_10307, type, root_hair_1: $i > $o).
% 28.89/28.94  tff(decl_10308, type, sarcomere_1: $i > $o).
% 28.89/28.94  tff(decl_10309, type, sex_pilus_1: $i > $o).
% 28.89/28.94  tff(decl_10310, type, statocyst_1: $i > $o).
% 28.89/28.94  tff(decl_10311, type, synaptic_terminal_1: $i > $o).
% 28.89/28.94  tff(decl_10312, type, transverse_tubule_1: $i > $o).
% 28.89/28.94  tff(decl_10313, type, z_line_filament_1: $i > $o).
% 28.89/28.94  tff(decl_10314, type, asteroid_1: $i > $o).
% 28.89/28.94  tff(decl_10315, type, 'Asteroid': $i).
% 28.89/28.94  tff(decl_10316, type, 'A big rock from outer space, whose landing on Earth could be a cataclysmic event; such a collision is associated with K/T boundary and extinction of dinosaurs.': $i).
% 28.89/28.94  tff(decl_10317, type, asteroid: $i).
% 28.89/28.94  tff(decl_10318, type, geologic_entity_1: $i > $o).
% 28.89/28.94  tff(decl_10319, type, asteroidea_1: $i > $o).
% 28.89/28.94  tff(decl_10320, type, 'Asteroidea': $i).
% 28.89/28.94  tff(decl_10321, type, 'Class of echinoderms that comprises the sea stars and sea daisies.': $i).
% 28.89/28.94  tff(decl_10322, type, asteroidea: $i).
% 28.89/28.94  tff(decl_10323, type, brittle_star_1: $i > $o).
% 28.89/28.94  tff(decl_10324, type, sea_cucumber_1: $i > $o).
% 28.89/28.94  tff(decl_10325, type, sea_daisy_1: $i > $o).
% 28.89/28.94  tff(decl_10326, type, sea_lily_1: $i > $o).
% 28.89/28.94  tff(decl_10327, type, sea_star_1: $i > $o).
% 28.89/28.94  tff(decl_10328, type, sea_urchin_1: $i > $o).
% 28.89/28.94  tff(decl_10329, type, astrocyte_1: $i > $o).
% 28.89/28.94  tff(decl_10330, type, 'Astrocyte': $i).
% 28.89/28.94  tff(decl_10331, type, 'Star-shaped glial cell found in the brain and spinal cord. Astrocytes provide biochemical support for the cells that form the blood-brain barrier, provide nutrients to neurons, and play a role in repairing damage to neural tissue.': $i).
% 28.89/28.94  tff(decl_10332, type, astrocyte: $i).
% 28.89/28.94  tff(decl_10333, type, glial_cell_1: $i > $o).
% 28.89/28.94  tff(decl_10334, type, oligodendrocyte_1: $i > $o).
% 28.89/28.94  tff(decl_10335, type, radial_glia_1: $i > $o).
% 28.89/28.94  tff(decl_10336, type, schwann_cell_1: $i > $o).
% 28.89/28.94  tff(decl_10337, type, asymmetrical_cell_division_1: $i > $o).
% 28.89/28.94  tff(decl_10338, type, 'Asymmetrical-Cell-Division': $i).
% 28.89/28.94  tff(decl_10339, type, 'A process in which one daughter cell receives more cytoplasm than the other following mitosis.': $i).
% 28.89/28.94  tff(decl_10340, type, 'divide asymmetrically': $i).
% 28.89/28.94  tff(decl_10341, type, 'asymmetrical cell division': $i).
% 28.89/28.94  tff(decl_10342, type, 'asymmetrical-cell-division': $i).
% 28.89/28.94  tff(decl_10343, type, 'Asymmetrical-Distribution': $i).
% 28.89/28.94  tff(decl_10344, type, 'Asymmeterical distribution refers to asymmetry or irregularity in the spatial arrangement or placement of parts or components.': $i).
% 28.89/28.94  tff(decl_10345, type, 'asymmetrical arrangement': $i).
% 28.89/28.94  tff(decl_10346, type, 'asymmetrical distribution': $i).
% 28.89/28.94  tff(decl_10347, type, 'asymmetrical-distribution': $i).
% 28.89/28.94  tff(decl_10348, type, distributing_1: $i > $o).
% 28.89/28.94  tff(decl_10349, type, 'Atherosclerosis': $i).
% 28.89/28.94  tff(decl_10350, type, 'The hardening of arteries caused by a build-up of fatty deposits called plaques in the inner walls of the arteries.': $i).
% 28.89/28.94  tff(decl_10351, type, atherosclerosis: $i).
% 28.89/28.94  tff(decl_10352, type, fn_atherosclerosis_1: $i > $i).
% 28.89/28.94  tff(decl_10353, type, saturated_fat_1: $i > $o).
% 28.89/28.94  tff(decl_10354, type, fn_atherosclerosis_2: $i > $i).
% 28.89/28.94  tff(decl_10355, type, atmosphere_1: $i > $o).
% 28.89/28.94  tff(decl_10356, type, 'Atmosphere': $i).
% 28.89/28.94  tff(decl_10357, type, 'Layer of gases that surrounds the Earth and is retained by Earth\\s gravity.': $i).
% 28.89/28.94  tff(decl_10358, type, atmosphere: $i).
% 28.89/28.94  tff(decl_10359, type, fn_atmosphere_1: $i > $i).
% 28.89/28.94  tff(decl_10360, type, n2_gas_1: $i > $o).
% 28.89/28.94  tff(decl_10361, type, fn_atmosphere_2: $i > $i).
% 28.89/28.94  tff(decl_10362, type, fn_atmosphere_3: $i > $i).
% 28.89/28.94  tff(decl_10363, type, co2_gas_1: $i > $o).
% 28.89/28.94  tff(decl_10364, type, fn_atmosphere_4: $i > $i).
% 28.89/28.94  tff(decl_10365, type, fn_atmosphere_5: $i > $i).
% 28.89/28.94  tff(decl_10366, type, fn_atmosphere_6: $i > $i).
% 28.89/28.94  tff(decl_10367, type, o2_gas_1: $i > $o).
% 28.89/28.94  tff(decl_10368, type, fn_greenhouse_gas_1: $i > $i).
% 28.89/28.94  tff(decl_10369, type, fn_chemical_2: $i > $i).
% 28.89/28.94  tff(decl_10370, type, fn_gas_substance_2: $i > $i).
% 28.89/28.94  tff(decl_10371, type, 'Atom': $i).
% 28.89/28.94  tff(decl_10372, type, 'An atom is the smallest representative particle of an element': $i).
% 28.89/28.94  tff(decl_10373, type, 'has isotope': $i).
% 28.89/28.94  tff(decl_10374, type, 'has-isotope': $i).
% 28.89/28.94  tff(decl_10375, type, 'has atom': $i).
% 28.89/28.94  tff(decl_10376, type, 'has-atom': $i).
% 28.89/28.94  tff(decl_10377, type, atom: $i).
% 28.89/28.94  tff(decl_10378, type, fn_atom_15: $i > $i).
% 28.89/28.94  tff(decl_10379, type, fn_atomic_weight_value_1: $i > $i).
% 28.89/28.94  tff(decl_10380, type, fn_kinetic_energy_2: $i > $i).
% 28.89/28.94  tff(decl_10381, type, atomic_entity_1: $i > $o).
% 28.89/28.94  tff(decl_10382, type, 'Atomic-Entity': $i).
% 28.89/28.94  tff(decl_10383, type, 'Components or categories of atoms.': $i).
% 28.89/28.94  tff(decl_10384, type, 'atomic entity': $i).
% 28.89/28.94  tff(decl_10385, type, 'atomic-entity': $i).
% 28.89/28.94  tff(decl_10386, type, atomic_mass_constant_1: $i > $o).
% 28.89/28.94  tff(decl_10387, type, 'Atomic-Mass-Constant': $i).
% 28.89/28.94  tff(decl_10388, type, 'atomic mass constant': $i).
% 28.89/28.94  tff(decl_10389, type, 'atomic-mass-constant': $i).
% 28.89/28.94  tff(decl_10390, type, 'Atomic-Mass-Value': $i).
% 28.89/28.94  tff(decl_10391, type, 'The sum of the number of protons and neutrons in the nucleus of an atom': $i).
% 28.89/28.94  tff(decl_10392, type, 'atomic mass': $i).
% 28.89/28.94  tff(decl_10393, type, 'number of mass': $i).
% 28.89/28.94  tff(decl_10394, type, 'mass number': $i).
% 28.89/28.94  tff(decl_10395, type, 'mass-number': $i).
% 28.89/28.94  tff(decl_10396, type, 'atomic mass value': $i).
% 28.89/28.94  tff(decl_10397, type, 'atomic-mass-value': $i).
% 28.89/28.94  tff(decl_10398, type, 'Atomic-Nucleus': $i).
% 28.89/28.94  tff(decl_10399, type, 'The central core of an atom, which contains protons and neutrons.': $i).
% 28.89/28.94  tff(decl_10400, type, 'atomic nucleus': $i).
% 28.89/28.94  tff(decl_10401, type, 'atomic-nucleus': $i).
% 28.89/28.94  tff(decl_10402, type, atomic_region_1: $i > $o).
% 28.89/28.94  tff(decl_10403, type, atomic_number_constant_1: $i > $o).
% 28.89/28.94  tff(decl_10404, type, 'Atomic-Number-Constant': $i).
% 28.89/28.94  tff(decl_10405, type, 'atomic number constant': $i).
% 28.89/28.94  tff(decl_10406, type, 'atomic-number-constant': $i).
% 28.89/28.94  tff(decl_10407, type, 'Atomic-Number-Value': $i).
% 28.89/28.94  tff(decl_10408, type, 'The number of protons in a nucleus. It determines the chemical properties of an element.': $i).
% 28.89/28.94  tff(decl_10409, type, 'atomic number': $i).
% 28.89/28.94  tff(decl_10410, type, 'atomic-number': $i).
% 28.89/28.94  tff(decl_10411, type, 'atomic number value': $i).
% 28.89/28.94  tff(decl_10412, type, 'atomic-number-value': $i).
% 28.89/28.94  tff(decl_10413, type, 'Atomic-Orbital': $i).
% 28.89/28.94  tff(decl_10414, type, 'The three-dimensional space where an electron is found 90% of the time.': $i).
% 28.89/28.94  tff(decl_10415, type, 'atomic orbital': $i).
% 28.89/28.94  tff(decl_10416, type, 'atomic-orbital': $i).
% 28.89/28.94  tff(decl_10417, type, 'Atomic-Region': $i).
% 28.89/28.94  tff(decl_10418, type, 'A region of the atom or atoms in a molecule including atomic parts such as electrons.': $i).
% 28.89/28.94  tff(decl_10419, type, 'atomic region': $i).
% 28.89/28.94  tff(decl_10420, type, 'atomic-region': $i).
% 28.89/28.94  tff(decl_10421, type, 'Atomic-Tracking': $i).
% 28.89/28.94  tff(decl_10422, type, 'A process of following particular atoms through a complex chemical pathway, such as following oxygen through photosynthesis.': $i).
% 28.89/28.94  tff(decl_10423, type, 'atomic tracking': $i).
% 28.89/28.94  tff(decl_10424, type, 'atomic-tracking': $i).
% 28.89/28.94  tff(decl_10425, type, technique_1: $i > $o).
% 28.89/28.94  tff(decl_10426, type, atomic_weight_constant_1: $i > $o).
% 28.89/28.94  tff(decl_10427, type, 'Atomic-Weight-Constant': $i).
% 28.89/28.94  tff(decl_10428, type, 'atomic weight constant': $i).
% 28.89/28.94  tff(decl_10429, type, 'atomic-weight-constant': $i).
% 28.89/28.94  tff(decl_10430, type, 'Atomic-Weight-Value': $i).
% 28.89/28.94  tff(decl_10431, type, 'The mass of a neutral atom of a nuclide. The atomic weight of an atom is the weight of the atom based on a scale where 12C = 12. The atomic weight of an element is the weighted average of each isotope.': $i).
% 28.89/28.94  tff(decl_10432, type, 'The ratio of the average mass of an atom of an element to the mass of carbon 12, which is assigned 12 atomic mass units.': $i).
% 28.89/28.94  tff(decl_10433, type, 'atomic weight': $i).
% 28.89/28.94  tff(decl_10434, type, 'atomic-weight': $i).
% 28.89/28.94  tff(decl_10435, type, 'relative atomic mass': $i).
% 28.89/28.94  tff(decl_10436, type, 'atomic weight value': $i).
% 28.89/28.94  tff(decl_10437, type, 'atomic-weight-value': $i).
% 28.89/28.94  tff(decl_10438, type, 'ATP': $i).
% 28.89/28.94  tff(decl_10439, type, 'ATP or Adenosine-5\\-Phosphate is a multifunctional nucleotide mainly used as an energy currency in intracellular energy transfer processes. The structure of this molecule consists of a purine base (adenine) attached to the 1\\ carbon atom of a pentose sugar (ribose).': $i).
% 28.89/28.94  tff(decl_10440, type, 'adenosine triphosphate': $i).
% 28.89/28.94  tff(decl_10441, type, 'adenosine 5\\ triphosphate': $i).
% 28.89/28.94  tff(decl_10442, type, 'adenosine-5\\-triphosphate': $i).
% 28.89/28.94  tff(decl_10443, type, 'adenosine-triphosphate': $i).
% 28.89/28.94  tff(decl_10444, type, atp: $i).
% 28.89/28.94  tff(decl_10445, type, ribonucleoside_triphosphate_1: $i > $o).
% 28.89/28.94  tff(decl_10446, type, fn_atp_1: $i > $i).
% 28.89/28.94  tff(decl_10447, type, fn_atp_2: $i > $i).
% 28.89/28.94  tff(decl_10448, type, fn_atp_3: $i > $i).
% 28.89/28.94  tff(decl_10449, type, fn_atp_5: $i > $i).
% 28.89/28.94  tff(decl_10450, type, fn_atp_6: $i > $i).
% 28.89/28.94  tff(decl_10451, type, fn_atp_8: $i > $i).
% 28.89/28.94  tff(decl_10452, type, o_minus_2_1: $i > $o).
% 28.89/28.94  tff(decl_10453, type, fn_atp_9: $i > $i).
% 28.89/28.94  tff(decl_10454, type, fn_atp_10: $i > $i).
% 28.89/28.94  tff(decl_10455, type, fn_atp_11: $i > $i).
% 28.89/28.94  tff(decl_10456, type, fn_atp_12: $i > $i).
% 28.89/28.94  tff(decl_10457, type, fn_atp_13: $i > $i).
% 28.89/28.94  tff(decl_10458, type, fn_atp_14: $i > $i).
% 28.89/28.94  tff(decl_10459, type, fn_atp_15: $i > $i).
% 28.89/28.94  tff(decl_10460, type, fn_atp_16: $i > $i).
% 28.89/28.94  tff(decl_10461, type, fn_atp_17: $i > $i).
% 28.89/28.94  tff(decl_10462, type, fn_atp_18: $i > $i).
% 28.89/28.94  tff(decl_10463, type, fn_atp_19: $i > $i).
% 28.89/28.94  tff(decl_10464, type, fn_atp_20: $i > $i).
% 28.89/28.94  tff(decl_10465, type, fn_atp_21: $i > $i).
% 28.89/28.94  tff(decl_10466, type, fn_atp_24: $i > $i).
% 28.89/28.94  tff(decl_10467, type, fn_atp_26: $i > $i).
% 28.89/28.94  tff(decl_10468, type, fn_atp_27: $i > $i).
% 28.89/28.94  tff(decl_10469, type, renewable_resource_1: $i > $o).
% 28.89/28.94  tff(decl_10470, type, fn_atp_38: $i > $i).
% 28.89/28.94  tff(decl_10471, type, fn_atp_40: $i > $i).
% 28.89/28.94  tff(decl_10472, type, fn_atp_41: $i > $i).
% 28.89/28.94  tff(decl_10473, type, fn_atp_42: $i > $i).
% 28.89/28.94  tff(decl_10474, type, fn_atp_43: $i > $i).
% 28.89/28.94  tff(decl_10475, type, fn_atp_44: $i > $i).
% 28.89/28.94  tff(decl_10476, type, fn_atp_45: $i > $i).
% 28.89/28.94  tff(decl_10477, type, fn_atp_46: $i > $i).
% 28.89/28.94  tff(decl_10478, type, fn_atp_47: $i > $i).
% 28.89/28.94  tff(decl_10479, type, fn_atp_48: $i > $i).
% 28.89/28.94  tff(decl_10480, type, fn_atp_49: $i > $i).
% 28.89/28.94  tff(decl_10481, type, fn_atp_51: $i > $i).
% 28.89/28.94  tff(decl_10482, type, fn_atp_52: $i > $i).
% 28.89/28.94  tff(decl_10483, type, fn_atp_53: $i > $i).
% 28.89/28.94  tff(decl_10484, type, fn_atp_54: $i > $i).
% 28.89/28.94  tff(decl_10485, type, fn_atp_55: $i > $i).
% 28.89/28.94  tff(decl_10486, type, fn_atp_56: $i > $i).
% 28.89/28.94  tff(decl_10487, type, fn_atp_57: $i > $i).
% 28.89/28.94  tff(decl_10488, type, fn_atp_58: $i > $i).
% 28.89/28.94  tff(decl_10489, type, fn_atp_59: $i > $i).
% 28.89/28.94  tff(decl_10490, type, fn_atp_60: $i > $i).
% 28.89/28.94  tff(decl_10491, type, fn_atp_61: $i > $i).
% 28.89/28.94  tff(decl_10492, type, fn_atp_62: $i > $i).
% 28.89/28.94  tff(decl_10493, type, fn_atp_63: $i > $i).
% 28.89/28.94  tff(decl_10494, type, fn_atp_64: $i > $i).
% 28.89/28.94  tff(decl_10495, type, fn_atp_65: $i > $i).
% 28.89/28.94  tff(decl_10496, type, fn_atp_70: $i > $i).
% 28.89/28.94  tff(decl_10497, type, fn_atp_71: $i > $i).
% 28.89/28.94  tff(decl_10498, type, fn_atp_72: $i > $i).
% 28.89/28.94  tff(decl_10499, type, fn_atp_73: $i > $i).
% 28.89/28.94  tff(decl_10500, type, fn_atp_74: $i > $i).
% 28.89/28.94  tff(decl_10501, type, fn_atp_75: $i > $i).
% 28.89/28.94  tff(decl_10502, type, fn_atp_76: $i > $i).
% 28.89/28.94  tff(decl_10503, type, fn_atp_77: $i > $i).
% 28.89/28.94  tff(decl_10504, type, fn_atp_78: $i > $i).
% 28.89/28.94  tff(decl_10505, type, fn_atp_79: $i > $i).
% 28.89/28.94  tff(decl_10506, type, fn_atp_80: $i > $i).
% 28.89/28.94  tff(decl_10507, type, fn_pentose_21: $i > $i).
% 28.89/28.94  tff(decl_10508, type, fn_second_electron_shell_21: $i > $i).
% 28.89/28.94  tff(decl_10509, type, fn_renewable_resource_1: $i > $i).
% 28.89/28.94  tff(decl_10510, type, fn_phosphate_group_19: $i > $i).
% 28.89/28.94  tff(decl_10511, type, "7.3e0": $i).
% 28.89/28.94  tff(decl_10512, type, fn_ribonucleotide_20: $i > $i).
% 28.89/28.94  tff(decl_10513, type, fn_ribonucleotide_3: $i > $i).
% 28.89/28.94  tff(decl_10514, type, fn_ribonucleotide_26: $i > $i).
% 28.89/28.94  tff(decl_10515, type, fn_ribonucleotide_18: $i > $i).
% 28.89/28.94  tff(decl_10516, type, fn_ribonucleotide_25: $i > $i).
% 28.89/28.94  tff(decl_10517, type, fn_nucleotide_36: $i > $i).
% 28.89/28.94  tff(decl_10518, type, fn_nucleoside_triphosphate_1: $i > $i).
% 28.89/28.94  tff(decl_10519, type, fn_nucleoside_triphosphate_19: $i > $i).
% 28.89/28.94  tff(decl_10520, type, fn_nucleoside_triphosphate_18: $i > $i).
% 28.89/28.94  tff(decl_10521, type, fn_nucleoside_triphosphate_17: $i > $i).
% 28.89/28.94  tff(decl_10522, type, fn_nucleoside_triphosphate_20: $i > $i).
% 28.89/28.94  tff(decl_10523, type, fn_nucleoside_triphosphate_11: $i > $i).
% 28.89/28.94  tff(decl_10524, type, fn_nucleoside_triphosphate_10: $i > $i).
% 28.89/28.94  tff(decl_10525, type, fn_nucleoside_triphosphate_25: $i > $i).
% 28.89/28.94  tff(decl_10526, type, fn_nucleoside_triphosphate_8: $i > $i).
% 28.89/28.94  tff(decl_10527, type, fn_nucleoside_triphosphate_13: $i > $i).
% 28.89/28.94  tff(decl_10528, type, fn_nucleoside_triphosphate_7: $i > $i).
% 28.89/28.94  tff(decl_10529, type, fn_nucleoside_triphosphate_3: $i > $i).
% 28.89/28.94  tff(decl_10530, type, fn_nucleoside_triphosphate_15: $i > $i).
% 28.89/28.94  tff(decl_10531, type, fn_nucleoside_triphosphate_23: $i > $i).
% 28.89/28.94  tff(decl_10532, type, fn_nucleoside_triphosphate_14: $i > $i).
% 28.89/28.94  tff(decl_10533, type, fn_nucleoside_triphosphate_16: $i > $i).
% 28.89/28.94  tff(decl_10534, type, fn_nucleoside_triphosphate_12: $i > $i).
% 28.89/28.94  tff(decl_10535, type, fn_nucleoside_triphosphate_34: $i > $i).
% 28.89/28.94  tff(decl_10536, type, atp_cycle_1: $i > $o).
% 28.89/28.94  tff(decl_10537, type, 'ATP-Cycle': $i).
% 28.89/28.94  tff(decl_10538, type, 'The ATP cycle comprises the conversion of ADP into ATP, when the cell needs energy and the conversion of ATP into ADP, when the cell needs to store energy.': $i).
% 28.89/28.94  tff(decl_10539, type, 'undergo the atp cycle': $i).
% 28.89/28.94  tff(decl_10540, type, 'cycle of atp': $i).
% 28.89/28.94  tff(decl_10541, type, 'atp cycle': $i).
% 28.89/28.94  tff(decl_10542, type, 'atp-cycle': $i).
% 28.89/28.94  tff(decl_10543, type, energy_coupling_1: $i > $o).
% 28.89/28.94  tff(decl_10544, type, cyclic_reaction_1: $i > $o).
% 28.89/28.94  tff(decl_10545, type, fn_atp_cycle_5: $i > $i).
% 28.89/28.94  tff(decl_10546, type, fn_atp_cycle_6: $i > $i).
% 28.89/28.94  tff(decl_10547, type, fn_atp_cycle_7: $i > $i).
% 28.89/28.94  tff(decl_10548, type, fn_atp_cycle_8: $i > $i).
% 28.89/28.94  tff(decl_10549, type, fn_atp_cycle_9: $i > $i).
% 28.89/28.94  tff(decl_10550, type, fn_atp_cycle_10: $i > $i).
% 28.89/28.94  tff(decl_10551, type, fn_atp_cycle_11: $i > $i).
% 28.89/28.94  tff(decl_10552, type, fn_atp_cycle_12: $i > $i).
% 28.89/28.94  tff(decl_10553, type, fn_atp_cycle_13: $i > $i).
% 28.89/28.94  tff(decl_10554, type, fn_atp_cycle_14: $i > $i).
% 28.89/28.94  tff(decl_10555, type, fn_atp_cycle_15: $i > $i).
% 28.89/28.94  tff(decl_10556, type, fn_atp_cycle_16: $i > $i).
% 28.89/28.94  tff(decl_10557, type, fn_atp_cycle_17: $i > $i).
% 28.89/28.94  tff(decl_10558, type, fn_atp_cycle_18: $i > $i).
% 28.89/28.94  tff(decl_10559, type, fn_atp_cycle_19: $i > $i).
% 28.89/28.94  tff(decl_10560, type, fn_atp_cycle_20: $i > $i).
% 28.89/28.94  tff(decl_10561, type, fn_atp_cycle_21: $i > $i).
% 28.89/28.94  tff(decl_10562, type, fn_atp_cycle_22: $i > $i).
% 28.89/28.94  tff(decl_10563, type, fn_atp_cycle_23: $i > $i).
% 28.89/28.94  tff(decl_10564, type, fn_atp_cycle_24: $i > $i).
% 28.89/28.94  tff(decl_10565, type, fn_atp_cycle_25: $i > $i).
% 28.89/28.94  tff(decl_10566, type, fn_atp_cycle_26: $i > $i).
% 28.89/28.94  tff(decl_10567, type, fn_atp_cycle_27: $i > $i).
% 28.89/28.94  tff(decl_10568, type, fn_atp_cycle_28: $i > $i).
% 28.89/28.94  tff(decl_10569, type, fn_atp_cycle_29: $i > $i).
% 28.89/28.94  tff(decl_10570, type, fn_atp_cycle_30: $i > $i).
% 28.89/28.94  tff(decl_10571, type, fn_atp_cycle_31: $i > $i).
% 28.89/28.94  tff(decl_10572, type, exergonic_process_1: $i > $o).
% 28.89/28.94  tff(decl_10573, type, dephosphorylation_of_atp_1: $i > $o).
% 28.89/28.94  tff(decl_10574, type, fn_atp_cycle_32: $i > $i).
% 28.89/28.94  tff(decl_10575, type, fn_atp_cycle_33: $i > $i).
% 28.89/28.94  tff(decl_10576, type, fn_atp_cycle_34: $i > $i).
% 28.89/28.94  tff(decl_10577, type, fn_atp_cycle_35: $i > $i).
% 28.89/28.94  tff(decl_10578, type, fn_atp_cycle_36: $i > $i).
% 28.89/28.94  tff(decl_10579, type, fn_atp_cycle_37: $i > $i).
% 28.89/28.94  tff(decl_10580, type, fn_atp_cycle_38: $i > $i).
% 28.89/28.94  tff(decl_10581, type, fn_atp_cycle_39: $i > $i).
% 28.89/28.94  tff(decl_10582, type, fn_atp_cycle_40: $i > $i).
% 28.89/28.94  tff(decl_10583, type, fn_atp_cycle_41: $i > $i).
% 28.89/28.94  tff(decl_10584, type, fn_atp_cycle_42: $i > $i).
% 28.89/28.94  tff(decl_10585, type, fn_atp_cycle_43: $i > $i).
% 28.89/28.94  tff(decl_10586, type, nucleoside_diphosphate_1: $i > $o).
% 28.89/28.94  tff(decl_10587, type, fn_atp_cycle_44: $i > $i).
% 28.89/28.94  tff(decl_10588, type, fn_atp_cycle_45: $i > $i).
% 28.89/28.94  tff(decl_10589, type, fn_atp_cycle_46: $i > $i).
% 28.89/28.94  tff(decl_10590, type, fn_atp_cycle_47: $i > $i).
% 28.89/28.94  tff(decl_10591, type, fn_atp_cycle_48: $i > $i).
% 28.89/28.94  tff(decl_10592, type, fn_atp_cycle_49: $i > $i).
% 28.89/28.94  tff(decl_10593, type, fn_atp_cycle_50: $i > $i).
% 28.89/28.94  tff(decl_10594, type, fn_atp_cycle_51: $i > $i).
% 28.89/28.94  tff(decl_10595, type, fn_atp_cycle_52: $i > $i).
% 28.89/28.94  tff(decl_10596, type, fn_atp_cycle_53: $i > $i).
% 28.89/28.94  tff(decl_10597, type, fn_atp_cycle_54: $i > $i).
% 28.89/28.94  tff(decl_10598, type, fn_atp_cycle_55: $i > $i).
% 28.89/28.94  tff(decl_10599, type, fn_atp_cycle_56: $i > $i).
% 28.89/28.94  tff(decl_10600, type, fn_dephosphorylation_of_atp_43: $i > $i).
% 28.89/28.94  tff(decl_10601, type, fn_dephosphorylation_of_atp_70: $i > $i).
% 28.89/28.94  tff(decl_10602, type, fn_dephosphorylation_of_atp_46: $i > $i).
% 28.89/28.94  tff(decl_10603, type, fn_dephosphorylation_of_atp_44: $i > $i).
% 28.89/28.94  tff(decl_10604, type, fn_dephosphorylation_of_atp_71: $i > $i).
% 28.89/28.94  tff(decl_10605, type, fn_dephosphorylation_of_atp_72: $i > $i).
% 28.89/28.94  tff(decl_10606, type, fn_synthesis_of_atp_27: $i > $i).
% 28.89/28.94  tff(decl_10607, type, fn_dephosphorylation_10: $i > $i).
% 28.89/28.94  tff(decl_10608, type, fn_hydrolysis_3: $i > $i).
% 28.89/28.94  tff(decl_10609, type, fn_nucleoside_5: $i > $i).
% 28.89/28.94  tff(decl_10610, type, fn_dephosphorylation_of_atp_56: $i > $i).
% 28.89/28.94  tff(decl_10611, type, fn_hydrolysis_8: $i > $i).
% 28.89/28.94  tff(decl_10612, type, fn_dephosphorylation_of_atp_47: $i > $i).
% 28.89/28.94  tff(decl_10613, type, fn_hydrolysis_5: $i > $i).
% 28.89/28.94  tff(decl_10614, type, fn_dephosphorylation_of_atp_48: $i > $i).
% 28.89/28.94  tff(decl_10615, type, fn_hydrolysis_4: $i > $i).
% 28.89/28.94  tff(decl_10616, type, fn_dephosphorylation_of_atp_49: $i > $i).
% 28.89/28.94  tff(decl_10617, type, fn_hydrolysis_6: $i > $i).
% 28.89/28.94  tff(decl_10618, type, fn_dephosphorylation_of_atp_45: $i > $i).
% 28.89/28.94  tff(decl_10619, type, fn_dephosphorylation_of_atp_2: $i > $i).
% 28.89/28.94  tff(decl_10620, type, fn_dephosphorylation_of_atp_73: $i > $i).
% 28.89/28.94  tff(decl_10621, type, fn_dephosphorylation_of_atp_74: $i > $i).
% 28.89/28.94  tff(decl_10622, type, fn_dephosphorylation_of_atp_55: $i > $i).
% 28.89/28.94  tff(decl_10623, type, fn_dephosphorylation_of_atp_51: $i > $i).
% 28.89/28.94  tff(decl_10624, type, fn_dephosphorylation_3: $i > $i).
% 28.89/28.94  tff(decl_10625, type, fn_dephosphorylation_of_atp_65: $i > $i).
% 28.89/28.94  tff(decl_10626, type, fn_dephosphorylation_7: $i > $i).
% 28.89/28.94  tff(decl_10627, type, fn_exergonic_process_3: $i > $i).
% 28.89/28.94  tff(decl_10628, type, fn_synthesis_of_atp_14: $i > $i).
% 28.89/28.94  tff(decl_10629, type, fn_synthesis_of_atp_16: $i > $i).
% 28.89/28.94  tff(decl_10630, type, fn_synthesis_of_atp_17: $i > $i).
% 28.89/28.94  tff(decl_10631, type, fn_synthesis_of_atp_15: $i > $i).
% 28.89/28.94  tff(decl_10632, type, fn_dephosphorylation_of_atp_60: $i > $i).
% 28.89/28.94  tff(decl_10633, type, fn_synthesis_of_atp_20: $i > $i).
% 28.89/28.94  tff(decl_10634, type, fn_synthesis_of_atp_19: $i > $i).
% 28.89/28.94  tff(decl_10635, type, fn_synthesis_of_atp_18: $i > $i).
% 28.89/28.94  tff(decl_10636, type, fn_synthesis_of_atp_21: $i > $i).
% 28.89/28.94  tff(decl_10637, type, fn_dephosphorylation_of_atp_53: $i > $i).
% 28.89/28.94  tff(decl_10638, type, fn_synthesis_of_atp_10: $i > $i).
% 28.89/28.94  tff(decl_10639, type, fn_dephosphorylation_of_atp_54: $i > $i).
% 28.89/28.94  tff(decl_10640, type, fn_dephosphorylation_of_atp_62: $i > $i).
% 28.89/28.94  tff(decl_10641, type, fn_energy_coupling_3: $i > $i).
% 28.89/28.94  tff(decl_10642, type, fn_energy_coupling_4: $i > $i).
% 28.89/28.94  tff(decl_10643, type, fn_energy_coupling_2: $i > $i).
% 28.89/28.94  tff(decl_10644, type, fn_atp_cycle_2: $i > $i).
% 28.89/28.94  tff(decl_10645, type, fn_atp_cycle_3: $i > $i).
% 28.89/28.94  tff(decl_10646, type, fn_atp_cycle_4: $i > $i).
% 28.89/28.94  tff(decl_10647, type, fn_atp_cycle_1: $i > $i).
% 28.89/28.94  tff(decl_10648, type, atp_hydrolyzing_transport_protein_1: $i > $o).
% 28.89/28.94  tff(decl_10649, type, 'ATP-Hydrolyzing-Transport-Protein': $i).
% 28.89/28.94  tff(decl_10650, type, 'Some transport proteins hydrolyze ATP as an energy source to actively pump substances across the membrane.': $i).
% 28.89/28.94  tff(decl_10651, type, 'atp hydrolyzing transport protein': $i).
% 28.89/28.94  tff(decl_10652, type, 'atp-hydrolyzing-transport-protein': $i).
% 28.89/28.94  tff(decl_10653, type, fn_atp_hydrolyzing_transport_protein_1: $i > $i).
% 28.89/28.94  tff(decl_10654, type, fn_atp_hydrolyzing_transport_protein_2: $i > $i).
% 28.89/28.94  tff(decl_10655, type, fn_atp_hydrolyzing_transport_protein_5: $i > $i).
% 28.89/28.94  tff(decl_10656, type, fn_atp_hydrolyzing_transport_protein_6: $i > $i).
% 28.89/28.94  tff(decl_10657, type, fn_atp_hydrolyzing_transport_protein_7: $i > $i).
% 28.89/28.94  tff(decl_10658, type, fn_atp_hydrolyzing_transport_protein_8: $i > $i).
% 28.89/28.94  tff(decl_10659, type, fn_atp_hydrolyzing_transport_protein_9: $i > $i).
% 28.89/28.94  tff(decl_10660, type, fn_atp_hydrolyzing_transport_protein_10: $i > $i).
% 28.89/28.94  tff(decl_10661, type, fn_atp_hydrolyzing_transport_protein_11: $i > $i).
% 28.89/28.94  tff(decl_10662, type, fn_biomembrane_76: $i > $i).
% 28.89/28.94  tff(decl_10663, type, fn_biomembrane_56: $i > $i).
% 28.89/28.94  tff(decl_10664, type, fn_atp_hydrolyzing_transport_protein_3: $i > $i).
% 28.89/28.94  tff(decl_10665, type, fn_atp_hydrolyzing_transport_protein_4: $i > $i).
% 28.89/28.94  tff(decl_10666, type, 'ATP-Synthase': $i).
% 28.89/28.94  tff(decl_10667, type, 'ATP synthase is a general term for an enzyme that can synthesize adenosine triphosphate (ATP) from adenosine diphosphate (ADP) and inorganic phosphate by using a form of energy. This energy is often in the form of protons moving down an electrochemical gradient, such as from the lumen into the stroma of chloroplasts or from the inter-membrane space into the matrix in mitochondria.': $i).
% 28.89/28.94  tff(decl_10668, type, 'atp synthase complex': $i).
% 28.89/28.94  tff(decl_10669, type, 'atp-synthase-complex': $i).
% 28.89/28.94  tff(decl_10670, type, 'atp synthase': $i).
% 28.89/28.94  tff(decl_10671, type, 'atp-synthase': $i).
% 28.89/28.94  tff(decl_10672, type, gated_channel_1: $i > $o).
% 28.89/28.94  tff(decl_10673, type, fn_atp_synthase_1: $i > $i).
% 28.89/28.94  tff(decl_10674, type, stator_1: $i > $o).
% 28.89/28.94  tff(decl_10675, type, fn_atp_synthase_4: $i > $i).
% 28.89/28.94  tff(decl_10676, type, fn_atp_synthase_5: $i > $i).
% 28.89/28.94  tff(decl_10677, type, fn_atp_synthase_6: $i > $i).
% 28.89/28.94  tff(decl_10678, type, fn_atp_synthase_8: $i > $i).
% 28.89/28.94  tff(decl_10679, type, fn_atp_synthase_11: $i > $i).
% 28.89/28.94  tff(decl_10680, type, fn_atp_synthase_12: $i > $i).
% 28.89/28.94  tff(decl_10681, type, fn_atp_synthase_13: $i > $i).
% 28.89/28.94  tff(decl_10682, type, rotor_1: $i > $o).
% 28.89/28.94  tff(decl_10683, type, fn_atp_synthase_14: $i > $i).
% 28.89/28.94  tff(decl_10684, type, fn_atp_synthase_15: $i > $i).
% 28.89/28.94  tff(decl_10685, type, fn_atp_synthase_16: $i > $i).
% 28.89/28.94  tff(decl_10686, type, fn_atp_synthase_21: $i > $i).
% 28.89/28.94  tff(decl_10687, type, fn_atp_synthase_22: $i > $i).
% 28.89/28.94  tff(decl_10688, type, fn_atp_synthase_23: $i > $i).
% 28.89/28.94  tff(decl_10689, type, fn_atp_synthase_24: $i > $i).
% 28.89/28.94  tff(decl_10690, type, fn_atp_synthase_25: $i > $i).
% 28.89/28.94  tff(decl_10691, type, fn_atp_synthase_26: $i > $i).
% 28.89/28.94  tff(decl_10692, type, fn_atp_synthase_27: $i > $i).
% 28.89/28.94  tff(decl_10693, type, fn_atp_synthase_28: $i > $i).
% 28.89/28.94  tff(decl_10694, type, fn_atp_synthase_29: $i > $i).
% 28.89/28.94  tff(decl_10695, type, fn_atp_synthase_30: $i > $i).
% 28.89/28.94  tff(decl_10696, type, fn_atp_synthase_31: $i > $i).
% 28.89/28.94  tff(decl_10697, type, fn_atp_synthase_32: $i > $i).
% 28.89/28.94  tff(decl_10698, type, knob_1: $i > $o).
% 28.89/28.94  tff(decl_10699, type, fn_atp_synthase_33: $i > $i).
% 28.89/28.94  tff(decl_10700, type, rod_1: $i > $o).
% 28.89/28.94  tff(decl_10701, type, fn_atp_synthase_34: $i > $i).
% 28.89/28.94  tff(decl_10702, type, fn_atp_synthase_35: $i > $i).
% 28.89/28.94  tff(decl_10703, type, fn_atp_synthase_36: $i > $i).
% 28.89/28.94  tff(decl_10704, type, fn_atp_synthase_37: $i > $i).
% 28.89/28.94  tff(decl_10705, type, fn_atp_synthase_38: $i > $i).
% 28.89/28.94  tff(decl_10706, type, fn_atp_synthase_39: $i > $i).
% 28.89/28.94  tff(decl_10707, type, fn_atp_synthase_40: $i > $i).
% 28.89/28.94  tff(decl_10708, type, fn_atp_synthase_41: $i > $i).
% 28.89/28.94  tff(decl_10709, type, fn_atp_synthase_42: $i > $i).
% 28.89/28.94  tff(decl_10710, type, fn_atp_synthase_44: $i > $i).
% 28.89/28.94  tff(decl_10711, type, fn_atp_synthase_45: $i > $i).
% 28.89/28.94  tff(decl_10712, type, fn_atp_synthase_46: $i > $i).
% 28.89/28.94  tff(decl_10713, type, fn_atp_synthase_47: $i > $i).
% 28.89/28.94  tff(decl_10714, type, fn_knob_1: $i > $i).
% 28.89/28.94  tff(decl_10715, type, fn_kinetic_energy_1: $i > $i).
% 28.89/28.94  tff(decl_10716, type, fn_passive_transport_7: $i > $i).
% 28.89/28.94  tff(decl_10717, type, fn_passive_transport_6: $i > $i).
% 28.89/28.94  tff(decl_10718, type, fn_synthesis_of_atp_6: $i > $i).
% 28.89/28.94  tff(decl_10719, type, fn_synthesis_of_atp_25: $i > $i).
% 28.89/28.94  tff(decl_10720, type, fn_synthesis_of_atp_24: $i > $i).
% 28.89/28.94  tff(decl_10721, type, fn_synthesis_of_atp_7: $i > $i).
% 28.89/28.94  tff(decl_10722, type, fn_synthesis_of_atp_8: $i > $i).
% 28.89/28.94  tff(decl_10723, type, fn_synthesis_of_atp_9: $i > $i).
% 28.89/28.94  tff(decl_10724, type, 'FE_p': $i).
% 28.89/28.94  tff(decl_10725, type, 'FE_r': $i).
% 28.89/28.94  tff(decl_10726, type, fn_atp_synthase_43: $i > $i).
% 28.89/28.94  tff(decl_10727, type, fn_atp_synthase_20: $i > $i).
% 28.89/28.94  tff(decl_10728, type, fn_atp_synthase_18: $i > $i).
% 28.89/28.94  tff(decl_10729, type, fn_atp_synthase_17: $i > $i).
% 28.89/28.94  tff(decl_10730, type, fn_atp_synthase_19: $i > $i).
% 28.89/28.94  tff(decl_10731, type, 'Atrium': $i).
% 28.89/28.94  tff(decl_10732, type, 'Receiving chamber of the vertebrate heart; blood from the body returns in veins to the atrium and is transferred to a ventricle.': $i).
% 28.89/28.94  tff(decl_10733, type, atria: $i).
% 28.89/28.94  tff(decl_10734, type, atrium: $i).
% 28.89/28.94  tff(decl_10735, type, organ_space_1: $i > $o).
% 28.89/28.94  tff(decl_10736, type, 'Attach': $i).
% 28.89/28.94  tff(decl_10737, type, attach: $i).
% 28.89/28.94  tff(decl_10738, type, connect: $i).
% 28.89/28.94  tff(decl_10739, type, link: $i).
% 28.89/28.94  tff(decl_10740, type, tie: $i).
% 28.89/28.94  tff(decl_10741, type, bond: $i).
% 28.89/28.94  tff(decl_10742, type, hold: $i).
% 28.89/28.94  tff(decl_10743, type, attack_1: $i > $o).
% 28.89/28.94  tff(decl_10744, type, 'Attack': $i).
% 28.89/28.94  tff(decl_10745, type, 'Aggressive action towards another.': $i).
% 28.89/28.94  tff(decl_10746, type, attack: $i).
% 28.89/28.94  tff(decl_10747, type, interact_1: $i > $o).
% 28.89/28.94  tff(decl_10748, type, fn_attack_1: $i > $i).
% 28.89/28.94  tff(decl_10749, type, 'Attract': $i).
% 28.89/28.94  tff(decl_10750, type, 'Exert a force on (a body) causing it to approach or prevent it from moving away': $i).
% 28.89/28.94  tff(decl_10751, type, 'affinity for': $i).
% 28.89/28.94  tff(decl_10752, type, 'has affinity': $i).
% 28.89/28.94  tff(decl_10753, type, attract: $i).
% 28.89/28.94  tff(decl_10754, type, cation_1: $i > $o).
% 28.89/28.94  tff(decl_10755, type, attraction_between_oppositely_charged_entities_1: $i > $o).
% 28.89/28.94  tff(decl_10756, type, attraction_between_anion_and_cation_1: $i > $o).
% 28.89/28.94  tff(decl_10757, type, fn_attraction_between_anion_and_cation_3: $i > $i).
% 28.89/28.94  tff(decl_10758, type, fn_attraction_between_anion_and_cation_2: $i > $i).
% 28.89/28.94  tff(decl_10759, type, 'Attraction-Between-Anion-And-Cation': $i).
% 28.89/28.94  tff(decl_10760, type, 'The Attraction Between A Cation And An Anion is Electrostatic attraction.': $i).
% 28.89/28.94  tff(decl_10761, type, 'attract each other': $i).
% 28.89/28.94  tff(decl_10762, type, 'attraction between anion and cation': $i).
% 28.89/28.94  tff(decl_10763, type, 'attraction-between-anion-and-cation': $i).
% 28.89/28.94  tff(decl_10764, type, fn_attraction_between_anion_and_cation_4: $i > $i).
% 28.89/28.94  tff(decl_10765, type, fn_ionic_bond_5: $i > $i).
% 28.89/28.94  tff(decl_10766, type, fn_ionic_bond_6: $i > $i).
% 28.89/28.94  tff(decl_10767, type, 'Attraction-Between-Oppositely-Charged-Entities': $i).
% 28.89/28.94  tff(decl_10768, type, 'It is the attraction between two oppositely charged entities.': $i).
% 28.89/28.94  tff(decl_10769, type, 'electrical attraction': $i).
% 28.89/28.94  tff(decl_10770, type, 'electrical-attraction': $i).
% 28.89/28.94  tff(decl_10771, type, 'attraction between oppositely charged entity': $i).
% 28.89/28.94  tff(decl_10772, type, 'attraction-between-oppositely-charged-entity': $i).
% 28.89/28.94  tff(decl_10773, type, fn_attraction_between_oppositely_charged_entities_1: $i > $i).
% 28.89/28.94  tff(decl_10774, type, fn_attraction_between_oppositely_charged_entities_2: $i > $i).
% 28.89/28.94  tff(decl_10775, type, fn_attraction_between_oppositely_charged_entities_3: $i > $i).
% 28.89/28.94  tff(decl_10776, type, fn_attraction_between_oppositely_charged_entities_4: $i > $i).
% 28.89/28.94  tff(decl_10777, type, fn_attraction_between_oppositely_charged_entities_7: $i > $i).
% 28.89/28.94  tff(decl_10778, type, auditory_space_1: $i > $o).
% 28.89/28.94  tff(decl_10779, type, 'Auditory-Space': $i).
% 28.89/28.94  tff(decl_10780, type, 'A space in the ear which is surrounded by anatomical structures.': $i).
% 28.89/28.94  tff(decl_10781, type, 'auditory space': $i).
% 28.89/28.94  tff(decl_10782, type, 'auditory-space': $i).
% 28.89/28.94  tff(decl_10783, type, aug_1: $i > $o).
% 28.89/28.94  tff(decl_10784, type, 'AUG': $i).
% 28.89/28.94  tff(decl_10785, type, 'A triplet of nucleotides present on the mRNA that codes for the amino acid, methionine, serves as the start or initiation codon for protein synthesis, and is the place where the first tRNA binds to the mRNA during translation.': $i).
% 28.89/28.94  tff(decl_10786, type, 'start codon': $i).
% 28.89/28.94  tff(decl_10787, type, aug: $i).
% 28.89/28.94  tff(decl_10788, type, start_codon_1: $i > $o).
% 28.89/28.94  tff(decl_10789, type, fn_aug_1: $i > $i).
% 28.89/28.94  tff(decl_10790, type, fn_aug_2: $i > $i).
% 28.89/28.94  tff(decl_10791, type, fn_aug_5: $i > $i).
% 28.89/28.94  tff(decl_10792, type, fn_aug_6: $i > $i).
% 28.89/28.94  tff(decl_10793, type, fn_aug_7: $i > $i).
% 28.89/28.94  tff(decl_10794, type, fn_aug_8: $i > $i).
% 28.89/28.94  tff(decl_10795, type, fn_aug_9: $i > $i).
% 28.89/28.94  tff(decl_10796, type, fn_aug_10: $i > $i).
% 28.89/28.94  tff(decl_10797, type, fn_aug_12: $i > $i).
% 28.89/28.94  tff(decl_10798, type, fn_aug_13: $i > $i).
% 28.89/28.94  tff(decl_10799, type, phosphodiester_bond_1: $i > $o).
% 28.89/28.94  tff(decl_10800, type, fn_phosphodiester_bond_44: $i > $i).
% 28.89/28.94  tff(decl_10801, type, fn_phosphodiester_bond_17: $i > $i).
% 28.89/28.94  tff(decl_10802, type, fn_phosphodiester_bond_1: $i > $i).
% 28.89/28.94  tff(decl_10803, type, fn_phosphodiester_bond_31: $i > $i).
% 28.89/28.94  tff(decl_10804, type, fn_phosphodiester_bond_26: $i > $i).
% 28.89/28.94  tff(decl_10805, type, fn_phosphodiester_bond_18: $i > $i).
% 28.89/28.94  tff(decl_10806, type, fn_phosphodiester_bond_14: $i > $i).
% 28.89/28.94  tff(decl_10807, type, fn_phosphodiester_bond_33: $i > $i).
% 28.89/28.94  tff(decl_10808, type, fn_phosphodiester_bond_20: $i > $i).
% 28.89/28.94  tff(decl_10809, type, fn_phosphodiester_bond_15: $i > $i).
% 28.89/28.94  tff(decl_10810, type, fn_phosphodiester_bond_16: $i > $i).
% 28.89/28.94  tff(decl_10811, type, fn_phosphodiester_bond_30: $i > $i).
% 28.89/28.94  tff(decl_10812, type, fn_phosphodiester_bond_29: $i > $i).
% 28.89/28.94  tff(decl_10813, type, fn_aug_4: $i > $i).
% 28.89/28.94  tff(decl_10814, type, fn_aug_3: $i > $i).
% 28.89/28.94  tff(decl_10815, type, fn_aug_11: $i > $i).
% 28.89/28.94  tff(decl_10816, type, aurelia_1: $i > $o).
% 28.89/28.94  tff(decl_10817, type, 'Aurelia': $i).
% 28.89/28.94  tff(decl_10818, type, 'A genus of scyphozoan jellies, commonly known as moon jellies.': $i).
% 28.89/28.94  tff(decl_10819, type, aurelia: $i).
% 28.89/28.94  tff(decl_10820, type, scyphozoan_1: $i > $o).
% 28.89/28.94  tff(decl_10821, type, australopithecine_1: $i > $o).
% 28.89/28.94  tff(decl_10822, type, 'Australopithecine': $i).
% 28.89/28.94  tff(decl_10823, type, 'A member from Australopithecus, a taxon of bipedal human ancestors.': $i).
% 28.89/28.94  tff(decl_10824, type, australopith: $i).
% 28.89/28.94  tff(decl_10825, type, australopithecine: $i).
% 28.89/28.94  tff(decl_10826, type, cro_magnon_1: $i > $o).
% 28.89/28.94  tff(decl_10827, type, homo_erectus_1: $i > $o).
% 28.89/28.94  tff(decl_10828, type, homo_ergaster_1: $i > $o).
% 28.89/28.94  tff(decl_10829, type, homo_habilis_1: $i > $o).
% 28.89/28.94  tff(decl_10830, type, homo_heidelbergensis_1: $i > $o).
% 28.89/28.94  tff(decl_10831, type, homo_sapiens_1: $i > $o).
% 28.89/28.94  tff(decl_10832, type, australopithecus_afarensis_1: $i > $o).
% 28.89/28.94  tff(decl_10833, type, 'Australopithecus-Afarensis': $i).
% 28.89/28.94  tff(decl_10834, type, 'A species of extinct hominin that lived between 3.9 and 2.9 million years ago.': $i).
% 28.89/28.94  tff(decl_10835, type, 'australopithecus afarensis': $i).
% 28.89/28.94  tff(decl_10836, type, 'australopithecus-afarensis': $i).
% 28.89/28.94  tff(decl_10837, type, australopithecus_africanus_1: $i > $o).
% 28.89/28.94  tff(decl_10838, type, 'Australopithecus-Africanus': $i).
% 28.89/28.94  tff(decl_10839, type, 'A species of extinct hominin that lived between 3.03 and 2.04 million years ago. This species walked fully erect (was bipedal) and had humanlike hands and teeth. However, the brain was only about one-third the size of a modern humans brain.': $i).
% 28.89/28.94  tff(decl_10840, type, 'australopithecus africanus': $i).
% 28.89/28.94  tff(decl_10841, type, 'australopithecus-africanus': $i).
% 28.89/28.94  tff(decl_10842, type, authorize_1: $i > $o).
% 28.89/28.94  tff(decl_10843, type, 'Authorize': $i).
% 28.89/28.94  tff(decl_10844, type, authorize: $i).
% 28.89/28.94  tff(decl_10845, type, authorise: $i).
% 28.89/28.94  tff(decl_10846, type, pass: $i).
% 28.89/28.94  tff(decl_10847, type, clear: $i).
% 28.89/28.94  tff(decl_10848, type, empower: $i).
% 28.89/28.94  tff(decl_10849, type, fn_authorize_1: $i > $i).
% 28.89/28.94  tff(decl_10850, type, authorized_1: $i > $o).
% 28.89/28.94  tff(decl_10851, type, 'Authorized': $i).
% 28.89/28.94  tff(decl_10852, type, authorized: $i).
% 28.89/28.94  tff(decl_10853, type, authorised: $i).
% 28.89/28.94  tff(decl_10854, type, cliche_1: $i > $o).
% 28.89/28.94  tff(decl_10855, type, autocrine_1: $i > $o).
% 28.89/28.94  tff(decl_10856, type, 'Autocrine': $i).
% 28.89/28.94  tff(decl_10857, type, 'Refers to a type of chemical signalling where the secreted molecule acts on the cell that secreted it.': $i).
% 28.89/28.94  tff(decl_10858, type, 'autocrine molecule': $i).
% 28.89/28.94  tff(decl_10859, type, autocrine: $i).
% 28.89/28.94  tff(decl_10860, type, autocrine_signaling_1: $i > $o).
% 28.89/28.94  tff(decl_10861, type, 'Autocrine-Signaling': $i).
% 28.89/28.94  tff(decl_10862, type, 'A process by which a cell secretes a substance that acts on itself to transmit a chemical message.': $i).
% 28.89/28.94  tff(decl_10863, type, signal: $i).
% 28.89/28.94  tff(decl_10864, type, 'signaling of autocrine': $i).
% 28.89/28.94  tff(decl_10865, type, 'autocrine signaling': $i).
% 28.89/28.94  tff(decl_10866, type, 'autocrine-signaling': $i).
% 28.89/28.94  tff(decl_10867, type, local_cell_communication_1: $i > $o).
% 28.89/28.94  tff(decl_10868, type, autodigestion_1: $i > $o).
% 28.89/28.94  tff(decl_10869, type, 'Autodigestion': $i).
% 28.89/28.94  tff(decl_10870, type, 'The destruction of a cell through the action of its own enzymes or the digestion of an enzyme by another molecule of the same enzyme.': $i).
% 28.89/28.94  tff(decl_10871, type, digest: $i).
% 28.89/28.94  tff(decl_10872, type, autodigestion: $i).
% 28.89/28.94  tff(decl_10873, type, fn_autodigestion_1: $i > $i).
% 28.89/28.94  tff(decl_10874, type, fn_autodigestion_2: $i > $i).
% 28.89/28.94  tff(decl_10875, type, 'Autoimmune-Disease': $i).
% 28.89/28.94  tff(decl_10876, type, 'Disease condition that arises when the body mounts an immune response against its own cells and tissues.': $i).
% 28.89/28.94  tff(decl_10877, type, 'autoimmune disease': $i).
% 28.89/28.94  tff(decl_10878, type, 'autoimmune-disease': $i).
% 28.89/28.94  tff(decl_10879, type, autoionization_of_water_1: $i > $o).
% 28.89/28.94  tff(decl_10880, type, 'Autoionization-Of-Water': $i).
% 28.89/28.94  tff(decl_10881, type, 'Autoionization of water is the reversible reaction during which water dissociates forming hydroxide (OH-) and hydronium (H3O+) ions and reforms water from these same ions at an equal rate.': $i).
% 28.89/28.94  tff(decl_10882, type, 'dissociation and formation of water molecule': $i).
% 28.89/28.94  tff(decl_10883, type, 'dissociation-and-formation-of-water-molecule': $i).
% 28.89/28.94  tff(decl_10884, type, 'self ionization of water': $i).
% 28.89/28.94  tff(decl_10885, type, 'self-ionization-of-water': $i).
% 28.89/28.94  tff(decl_10886, type, 'autodissociation of water': $i).
% 28.89/28.94  tff(decl_10887, type, 'autodissociation-of-water': $i).
% 28.89/28.94  tff(decl_10888, type, 'dissociation of water': $i).
% 28.89/28.94  tff(decl_10889, type, 'dissociation-of-water': $i).
% 28.89/28.94  tff(decl_10890, type, autoionize: $i).
% 28.89/28.94  tff(decl_10891, type, dissociate: $i).
% 28.89/28.94  tff(decl_10892, type, 'autoionization of water': $i).
% 28.89/28.94  tff(decl_10893, type, 'autoionization-of-water': $i).
% 28.89/28.94  tff(decl_10894, type, fn_autoionization_of_water_1: $i > $i).
% 28.89/28.94  tff(decl_10895, type, fn_autoionization_of_water_2: $i > $i).
% 28.89/28.94  tff(decl_10896, type, fn_autoionization_of_water_3: $i > $i).
% 28.89/28.94  tff(decl_10897, type, fn_autoionization_of_water_4: $i > $i).
% 28.89/28.94  tff(decl_10898, type, fn_autoionization_of_water_7: $i > $i).
% 28.89/28.94  tff(decl_10899, type, fn_autoionization_of_water_14: $i > $i).
% 28.89/28.94  tff(decl_10900, type, fn_autoionization_of_water_15: $i > $i).
% 28.89/28.94  tff(decl_10901, type, fn_autoionization_of_water_16: $i > $i).
% 28.89/28.94  tff(decl_10902, type, fn_autoionization_of_water_17: $i > $i).
% 28.89/28.94  tff(decl_10903, type, fn_autoionization_of_water_18: $i > $i).
% 28.89/28.94  tff(decl_10904, type, fn_autoionization_of_water_19: $i > $i).
% 28.89/28.94  tff(decl_10905, type, fn_autoionization_of_water_20: $i > $i).
% 28.89/28.94  tff(decl_10906, type, hydronium_ion_1: $i > $o).
% 28.89/28.94  tff(decl_10907, type, fn_autoionization_of_water_21: $i > $i).
% 28.89/28.94  tff(decl_10908, type, fn_autoionization_of_water_22: $i > $i).
% 28.89/28.94  tff(decl_10909, type, fn_autoionization_of_water_23: $i > $i).
% 28.89/28.94  tff(decl_10910, type, fn_autoionization_of_water_24: $i > $i).
% 28.89/28.94  tff(decl_10911, type, fn_autoionization_of_water_25: $i > $i).
% 28.89/28.94  tff(decl_10912, type, fn_reverse_reaction_8: $i > $i).
% 28.89/28.94  tff(decl_10913, type, fn_reverse_reaction_7: $i > $i).
% 28.89/28.94  tff(decl_10914, type, 'Quantity_H3O': $i).
% 28.89/28.94  tff(decl_10915, type, 'Concentration_H3O': $i).
% 28.89/28.94  tff(decl_10916, type, fn_chemical_equilibrium_reaction_6: $i > $i).
% 28.89/28.94  tff(decl_10917, type, fn_chemical_equilibrium_reaction_5: $i > $i).
% 28.89/28.94  tff(decl_10918, type, fn_chemical_equilibrium_reaction_4: $i > $i).
% 28.89/28.94  tff(decl_10919, type, fn_chemical_equilibrium_reaction_10: $i > $i).
% 28.89/28.94  tff(decl_10920, type, fn_chemical_equilibrium_reaction_9: $i > $i).
% 28.89/28.94  tff(decl_10921, type, automobile_1: $i > $o).
% 28.89/28.94  tff(decl_10922, type, 'Automobile': $i).
% 28.89/28.94  tff(decl_10923, type, 'Device used for transportation.': $i).
% 28.89/28.94  tff(decl_10924, type, car: $i).
% 28.89/28.94  tff(decl_10925, type, auto: $i).
% 28.89/28.94  tff(decl_10926, type, automobile: $i).
% 28.89/28.94  tff(decl_10927, type, centrifuge_1: $i > $o).
% 28.89/28.94  tff(decl_10928, type, needle_1: $i > $o).
% 28.89/28.94  tff(decl_10929, type, optical_device_1: $i > $o).
% 28.89/28.94  tff(decl_10930, type, test_tube_1: $i > $o).
% 28.89/28.94  tff(decl_10931, type, autonomic_nervous_1: $i > $o).
% 28.89/28.94  tff(decl_10932, type, 'Autonomic-Nervous': $i).
% 28.89/28.94  tff(decl_10933, type, 'Part of the vertebrate peripheral nervous system largely under subconscious control; it consists of the sympathetic, parasympathetic, and enteric divisions.  The autonomic nervous system regulates the body\\s internal environment.': $i).
% 28.89/28.94  tff(decl_10934, type, 'autonomic nervous': $i).
% 28.89/28.94  tff(decl_10935, type, 'autonomic-nervous': $i).
% 28.89/28.94  tff(decl_10936, type, peripheral_nervous_system_1: $i > $o).
% 28.89/28.94  tff(decl_10937, type, sensory_system_1: $i > $o).
% 28.89/28.94  tff(decl_10938, type, sensory_division_1: $i > $o).
% 28.89/28.94  tff(decl_10939, type, motor_system_1: $i > $o).
% 28.89/28.94  tff(decl_10940, type, 'Autophagy': $i).
% 28.89/28.94  tff(decl_10941, type, 'Autophagy is a catabolic process involving the degradation of a cell\\s own components through the lysosomal machinery. Lysosomal enzymes recycle the cell\\s organic material by this process.': $i).
% 28.89/28.94  tff(decl_10942, type, autophagocytosis: $i).
% 28.89/28.94  tff(decl_10943, type, 'self digestion': $i).
% 28.89/28.94  tff(decl_10944, type, degrade: $i).
% 28.89/28.94  tff(decl_10945, type, 'undergo autophagy': $i).
% 28.89/28.94  tff(decl_10946, type, destroy: $i).
% 28.89/28.94  tff(decl_10947, type, autophagy: $i).
% 28.89/28.94  tff(decl_10948, type, intracellular_process_1: $i > $o).
% 28.89/28.94  tff(decl_10949, type, fn_autophagy_1: $i > $i).
% 28.89/28.94  tff(decl_10950, type, fn_autophagy_2: $i > $i).
% 28.89/28.94  tff(decl_10951, type, fn_autophagy_3: $i > $i).
% 28.89/28.94  tff(decl_10952, type, fn_autophagy_4: $i > $i).
% 28.89/28.94  tff(decl_10953, type, take_apart_1: $i > $o).
% 28.89/28.94  tff(decl_10954, type, fn_autophagy_5: $i > $i).
% 28.89/28.94  tff(decl_10955, type, fn_autophagy_6: $i > $i).
% 28.89/28.94  tff(decl_10956, type, cellular_recycling_1: $i > $o).
% 28.89/28.94  tff(decl_10957, type, fn_autophagy_7: $i > $i).
% 28.89/28.94  tff(decl_10958, type, fn_autophagy_8: $i > $i).
% 28.89/28.94  tff(decl_10959, type, fn_autophagy_9: $i > $i).
% 28.89/28.94  tff(decl_10960, type, fn_autophagy_10: $i > $i).
% 28.89/28.94  tff(decl_10961, type, lysosomal_membrane_1: $i > $o).
% 28.89/28.94  tff(decl_10962, type, fn_autophagy_11: $i > $i).
% 28.89/28.94  tff(decl_10963, type, fn_autophagy_12: $i > $i).
% 28.89/28.94  tff(decl_10964, type, fn_autophagy_13: $i > $i).
% 28.89/28.94  tff(decl_10965, type, lysosomal_enzyme_1: $i > $o).
% 28.89/28.94  tff(decl_10966, type, fn_autophagy_14: $i > $i).
% 28.89/28.94  tff(decl_10967, type, fn_autophagy_15: $i > $i).
% 28.89/28.94  tff(decl_10968, type, impair_1: $i > $o).
% 28.89/28.94  tff(decl_10969, type, fn_autophagy_16: $i > $i).
% 28.89/28.94  tff(decl_10970, type, fn_autophagy_17: $i > $i).
% 28.89/28.94  tff(decl_10971, type, debris_1: $i > $o).
% 28.89/28.94  tff(decl_10972, type, fn_autophagy_18: $i > $i).
% 28.89/28.94  tff(decl_10973, type, fn_autophagy_19: $i > $i).
% 28.89/28.94  tff(decl_10974, type, fn_autophagy_20: $i > $i).
% 28.89/28.94  tff(decl_10975, type, fn_autophagy_21: $i > $i).
% 28.89/28.94  tff(decl_10976, type, fn_autophagy_22: $i > $i).
% 28.89/28.94  tff(decl_10977, type, fn_autophagy_23: $i > $i).
% 28.89/28.94  tff(decl_10978, type, fn_autophagy_24: $i > $i).
% 28.89/28.94  tff(decl_10979, type, fn_autophagy_25: $i > $i).
% 28.89/28.94  tff(decl_10980, type, send_1: $i > $o).
% 28.89/28.94  tff(decl_10981, type, fn_autophagy_26: $i > $i).
% 28.89/28.94  tff(decl_10982, type, fn_autophagy_27: $i > $i).
% 28.89/28.94  tff(decl_10983, type, fn_autophagy_28: $i > $i).
% 28.89/28.94  tff(decl_10984, type, fn_autophagy_29: $i > $i).
% 28.89/28.94  tff(decl_10985, type, fn_autophagy_30: $i > $i).
% 28.89/28.94  tff(decl_10986, type, fn_autophagy_31: $i > $i).
% 28.89/28.94  tff(decl_10987, type, fn_autophagy_32: $i > $i).
% 28.89/28.94  tff(decl_10988, type, fn_autophagy_33: $i > $i).
% 28.89/28.94  tff(decl_10989, type, fn_autophagy_34: $i > $i).
% 28.89/28.94  tff(decl_10990, type, fn_autophagy_35: $i > $i).
% 28.89/28.94  tff(decl_10991, type, fn_autophagy_36: $i > $i).
% 28.89/28.94  tff(decl_10992, type, fn_autophagy_37: $i > $i).
% 28.89/28.94  tff(decl_10993, type, fn_autophagy_38: $i > $i).
% 28.89/28.94  tff(decl_10994, type, fn_autophagy_39: $i > $i).
% 28.89/28.94  tff(decl_10995, type, fn_autophagy_40: $i > $i).
% 28.89/28.94  tff(decl_10996, type, fn_autophagy_41: $i > $i).
% 28.89/28.94  tff(decl_10997, type, fn_autophagy_42: $i > $i).
% 28.89/28.94  tff(decl_10998, type, fn_autophagy_43: $i > $i).
% 28.89/28.94  tff(decl_10999, type, fn_autophagy_44: $i > $i).
% 28.89/28.94  tff(decl_11000, type, fn_autophagy_45: $i > $i).
% 28.89/28.94  tff(decl_11001, type, fn_autophagy_46: $i > $i).
% 28.89/28.94  tff(decl_11002, type, fn_autophagy_49: $i > $i).
% 28.89/28.94  tff(decl_11003, type, fn_release_1: $i > $i).
% 28.89/28.94  tff(decl_11004, type, fn_debris_1: $i > $i).
% 28.89/28.94  tff(decl_11005, type, fn_lysosomal_membrane_6: $i > $i).
% 28.89/28.94  tff(decl_11006, type, fn_lysosomal_enzyme_17: $i > $i).
% 28.89/28.94  tff(decl_11007, type, fn_biomembrane_14: $i > $i).
% 28.89/28.94  tff(decl_11008, type, fn_organelle_2: $i > $i).
% 28.89/28.94  tff(decl_11009, type, fn_send_2: $i > $i).
% 28.89/28.94  tff(decl_11010, type, fn_organelle_1: $i > $i).
% 28.89/28.94  tff(decl_11011, type, 'RemoveOld': $i).
% 28.89/28.94  tff(decl_11012, type, 'AttachNew': $i).
% 28.89/28.94  tff(decl_11013, type, 'new entity': $i).
% 28.89/28.94  tff(decl_11014, type, 'old entity': $i).
% 28.89/28.94  tff(decl_11015, type, fn_autophagy_48: $i > $i).
% 28.89/28.94  tff(decl_11016, type, fn_autophagy_47: $i > $i).
% 28.89/28.94  tff(decl_11017, type, 'Autopolyploid': $i).
% 28.89/28.94  tff(decl_11018, type, 'An organism with more than two sets of chromosomes, all of which are derived from the same species.': $i).
% 28.89/28.94  tff(decl_11019, type, autopolyploid: $i).
% 28.89/28.94  tff(decl_11020, type, autoradiograph_1: $i > $o).
% 28.89/28.94  tff(decl_11021, type, 'Autoradiograph': $i).
% 28.89/28.94  tff(decl_11022, type, 'An image produced via autoradiography.': $i).
% 28.89/28.94  tff(decl_11023, type, autoradiograph: $i).
% 28.89/28.94  tff(decl_11024, type, image_1: $i > $o).
% 28.89/28.94  tff(decl_11025, type, 'Autoradiography': $i).
% 28.89/28.94  tff(decl_11026, type, 'A technique that identifies radioactively tagged molecules in cells to follow specific pathways.': $i).
% 28.89/28.94  tff(decl_11027, type, autoradiography: $i).
% 28.89/28.94  tff(decl_11028, type, autoreplication_1: $i > $o).
% 28.89/28.94  tff(decl_11029, type, 'Autoreplication': $i).
% 28.89/28.94  tff(decl_11030, type, 'The biological process in which a molecule or organelle copies itself, independent of the cell in which it is contained.': $i).
% 28.89/28.94  tff(decl_11031, type, autoreplicate: $i).
% 28.89/28.94  tff(decl_11032, type, autoreplication: $i).
% 28.89/28.94  tff(decl_11033, type, autoreplication_of_chloroplast_1: $i > $o).
% 28.89/28.94  tff(decl_11034, type, 'Autoreplication-Of-Chloroplast': $i).
% 28.89/28.94  tff(decl_11035, type, 'The biological process in which a chloroplast copies itself, independent of the cell in which it is contained.': $i).
% 28.89/28.94  tff(decl_11036, type, 'chloroplast autoreplication': $i).
% 28.89/28.94  tff(decl_11037, type, 'chloroplast-autoreplication': $i).
% 28.89/28.94  tff(decl_11038, type, 'autoreplication of chloroplast': $i).
% 28.89/28.94  tff(decl_11039, type, 'autoreplication-of-chloroplast': $i).
% 28.89/28.94  tff(decl_11040, type, autoreplication_of_semiautonomous_organelle_1: $i > $o).
% 28.89/28.94  tff(decl_11041, type, fn_autoreplication_of_chloroplast_1: $i > $i).
% 28.89/28.94  tff(decl_11042, type, fn_autoreplication_of_chloroplast_2: $i > $i).
% 28.89/28.94  tff(decl_11043, type, fn_autoreplication_of_semiautonomous_organelle_2: $i > $i).
% 28.89/28.94  tff(decl_11044, type, fn_autoreplication_of_semiautonomous_organelle_1: $i > $i).
% 28.89/28.94  tff(decl_11045, type, autoreplication_of_mitochondrion_1: $i > $o).
% 28.89/28.94  tff(decl_11046, type, 'Autoreplication-Of-Mitochondrion': $i).
% 28.89/28.94  tff(decl_11047, type, 'The biological process in which a mitochondrion copies itself, independent of the cell in which it is contained.': $i).
% 28.89/28.94  tff(decl_11048, type, 'mitochondrion autoreplication': $i).
% 28.89/28.94  tff(decl_11049, type, 'mitochondrion-autoreplication': $i).
% 28.89/28.94  tff(decl_11050, type, 'autoreplication of mitochondrion': $i).
% 28.89/28.94  tff(decl_11051, type, 'autoreplication-of-mitochondrion': $i).
% 28.89/28.94  tff(decl_11052, type, fn_autoreplication_of_mitochondrion_1: $i > $i).
% 28.89/28.94  tff(decl_11053, type, fn_autoreplication_of_mitochondrion_2: $i > $i).
% 28.89/28.94  tff(decl_11054, type, 'Autoreplication-Of-Semiautonomous-Organelle': $i).
% 28.89/28.94  tff(decl_11055, type, 'The biological process in which a semiautonomous organelle copies itself, independent of the cell in which it is contained.': $i).
% 28.89/28.94  tff(decl_11056, type, 'autoreplication of semiautonomous organelle': $i).
% 28.89/28.94  tff(decl_11057, type, 'autoreplication-of-semiautonomous-organelle': $i).
% 28.89/28.94  tff(decl_11058, type, autosomal_dominant_trait_1: $i > $o).
% 28.89/28.94  tff(decl_11059, type, 'Autosomal-Dominant-Trait': $i).
% 28.89/28.94  tff(decl_11060, type, 'A dominant genetic trait carried on the autosomes.': $i).
% 28.89/28.94  tff(decl_11061, type, 'autosomal dominant trait': $i).
% 28.89/28.94  tff(decl_11062, type, 'autosomal-dominant-trait': $i).
% 28.89/28.94  tff(decl_11063, type, dominant_phenotype_1: $i > $o).
% 28.89/28.94  tff(decl_11064, type, dominant_trait_1: $i > $o).
% 28.89/28.94  tff(decl_11065, type, blood_type_phenotype_1: $i > $o).
% 28.89/28.94  tff(decl_11066, type, codominant_1: $i > $o).
% 28.89/28.94  tff(decl_11067, type, multifactorial_phenotype_1: $i > $o).
% 28.89/28.94  tff(decl_11068, type, mutant_phenotype_1: $i > $o).
% 28.89/28.94  tff(decl_11069, type, mutant_type_1: $i > $o).
% 28.89/28.94  tff(decl_11070, type, parental_type_1: $i > $o).
% 28.89/28.94  tff(decl_11071, type, phenotype_of_offspring_1: $i > $o).
% 28.89/28.94  tff(decl_11072, type, phenotype_of_parent_1: $i > $o).
% 28.89/28.94  tff(decl_11073, type, trait_on_a_range_1: $i > $o).
% 28.89/28.94  tff(decl_11074, type, trait_on_a_scale_1: $i > $o).
% 28.89/28.94  tff(decl_11075, type, wild_type_1: $i > $o).
% 28.89/28.94  tff(decl_11076, type, x_chromosome_phenotype_dominant_1: $i > $o).
% 28.89/28.94  tff(decl_11077, type, x_chromosome_phenotype_recessive_1: $i > $o).
% 28.89/28.94  tff(decl_11078, type, fn_autosomal_dominant_trait_1: $i > $i).
% 28.89/28.94  tff(decl_11079, type, homozygous_dominant_1: $i > $o).
% 28.89/28.94  tff(decl_11080, type, fn_autosomal_dominant_trait_2: $i > $i).
% 28.89/28.94  tff(decl_11081, type, heterozygous_1: $i > $o).
% 28.89/28.94  tff(decl_11082, type, fn_autosomal_dominant_trait_3: $i > $i).
% 28.89/28.94  tff(decl_11083, type, fn_genotype_2: $i > $i).
% 28.89/28.94  tff(decl_11084, type, fn_genotype_1: $i > $i).
% 28.89/28.94  tff(decl_11085, type, phenotype_1: $i > $o).
% 28.89/28.94  tff(decl_11086, type, autosomal_recessive_trait_1: $i > $o).
% 28.89/28.94  tff(decl_11087, type, 'Autosomal-Recessive-Trait': $i).
% 28.89/28.94  tff(decl_11088, type, 'Recessive trait that is phenotypically apparent when two alleles for the trait are present.  The gene for the character is located on one of the autosomes.': $i).
% 28.89/28.94  tff(decl_11089, type, 'autosomal recessive trait': $i).
% 28.89/28.94  tff(decl_11090, type, 'autosomal-recessive-trait': $i).
% 28.89/28.94  tff(decl_11091, type, recessive_trait_1: $i > $o).
% 28.89/28.94  tff(decl_11092, type, fn_autosomal_recessive_trait_1: $i > $i).
% 28.89/28.94  tff(decl_11093, type, homozygous_recessive_1: $i > $o).
% 28.89/28.94  tff(decl_11094, type, fn_autosomal_recessive_trait_2: $i > $i).
% 28.89/28.94  tff(decl_11095, type, fn_character_2: $i > $i).
% 28.89/28.94  tff(decl_11096, type, autosome_1: $i > $o).
% 28.89/28.94  tff(decl_11097, type, 'Autosome': $i).
% 28.89/28.94  tff(decl_11098, type, 'A chromosome that is not a sex-determining chromosome.': $i).
% 28.89/28.94  tff(decl_11099, type, autosome: $i).
% 28.89/28.94  tff(decl_11100, type, yeast_artificial_chromosome_1: $i > $o).
% 28.89/28.94  tff(decl_11101, type, sex_chromosome_1: $i > $o).
% 28.89/28.94  tff(decl_11102, type, non_homologous_chromosome_1: $i > $o).
% 28.89/28.94  tff(decl_11103, type, chromosome_fragment_1: $i > $o).
% 28.89/28.94  tff(decl_11104, type, defective_chromosome_1: $i > $o).
% 28.89/28.94  tff(decl_11105, type, human_chromosome_1: $i > $o).
% 28.89/28.94  tff(decl_11106, type, 'Autotroph': $i).
% 28.89/28.94  tff(decl_11107, type, 'Organisms which do not consume other organisms for sources of energy or organic carbon. Autotrophs build their own organic molecules using solar energy or the oxidation of inorganic molecules for energy and carbon dioxide or dissolved carbon-containing compounds.': $i).
% 28.89/28.94  tff(decl_11108, type, 'autotrophic organism': $i).
% 28.89/28.94  tff(decl_11109, type, 'producer of biosphere': $i).
% 28.89/28.94  tff(decl_11110, type, producer: $i).
% 28.89/28.94  tff(decl_11111, type, autotroph: $i).
% 28.89/28.94  tff(decl_11112, type, fn_autotroph_1: $i > $i).
% 28.89/28.94  tff(decl_11113, type, fn_autotroph_2: $i > $i).
% 28.89/28.94  tff(decl_11114, type, fn_autotroph_3: $i > $i).
% 28.89/28.94  tff(decl_11115, type, fn_autotroph_4: $i > $i).
% 28.89/28.94  tff(decl_11116, type, fn_autotroph_5: $i > $i).
% 28.89/28.94  tff(decl_11117, type, fn_autotroph_6: $i > $i).
% 28.89/28.94  tff(decl_11118, type, fn_autotroph_7: $i > $i).
% 28.89/28.94  tff(decl_11119, type, fn_autotroph_8: $i > $i).
% 28.89/28.94  tff(decl_11120, type, fn_autotroph_9: $i > $i).
% 28.89/28.94  tff(decl_11121, type, obtain_1: $i > $o).
% 28.89/28.94  tff(decl_11122, type, fn_autotroph_10: $i > $i).
% 28.89/28.94  tff(decl_11123, type, fn_autotroph_12: $i > $i).
% 28.89/28.94  tff(decl_11124, type, fn_autotroph_13: $i > $i).
% 28.89/28.94  tff(decl_11125, type, fn_autotroph_14: $i > $i).
% 28.89/28.94  tff(decl_11126, type, fn_autotroph_15: $i > $i).
% 28.89/28.94  tff(decl_11127, type, fn_autotroph_16: $i > $i).
% 28.89/28.94  tff(decl_11128, type, fn_autotroph_17: $i > $i).
% 28.89/28.94  tff(decl_11129, type, fn_autotroph_18: $i > $i).
% 28.89/28.94  tff(decl_11130, type, fn_autotroph_19: $i > $i).
% 28.89/28.94  tff(decl_11131, type, fn_autotroph_20: $i > $i).
% 28.89/28.94  tff(decl_11132, type, fn_autotroph_21: $i > $i).
% 28.89/28.94  tff(decl_11133, type, fn_autotroph_22: $i > $i).
% 28.89/28.94  tff(decl_11134, type, auxin_1: $i > $o).
% 28.89/28.94  tff(decl_11135, type, 'Auxin': $i).
% 28.89/28.94  tff(decl_11136, type, 'A class of plant hormones that coordinate many growth and behavioral processes in a plant\\s life.': $i).
% 28.89/28.94  tff(decl_11137, type, auxin: $i).
% 28.89/28.94  tff(decl_11138, type, 'indoleacetic acid': $i).
% 28.89/28.94  tff(decl_11139, type, 'indoleacetic-acid': $i).
% 28.89/28.94  tff(decl_11140, type, iaa: $i).
% 28.89/28.94  tff(decl_11141, type, 'indole acetic acid': $i).
% 28.89/28.94  tff(decl_11142, type, 'indole-acetic-acid': $i).
% 28.89/28.94  tff(decl_11143, type, 'AV-Valve': $i).
% 28.89/28.94  tff(decl_11144, type, 'A valve between an atrium and a ventricle of the heart.': $i).
% 28.89/28.94  tff(decl_11145, type, 'atrioventricular valve': $i).
% 28.89/28.94  tff(decl_11146, type, 'atrioventricular-valve': $i).
% 28.89/28.94  tff(decl_11147, type, 'bicuspid valve': $i).
% 28.89/28.94  tff(decl_11148, type, 'bicuspid-valve': $i).
% 28.89/28.94  tff(decl_11149, type, 'tricuspid valve': $i).
% 28.89/28.94  tff(decl_11150, type, 'tricuspid-valve': $i).
% 28.89/28.94  tff(decl_11151, type, 'atroventricular valve': $i).
% 28.89/28.94  tff(decl_11152, type, 'atroventricular-valve': $i).
% 28.89/28.94  tff(decl_11153, type, 'av valve': $i).
% 28.89/28.94  tff(decl_11154, type, 'av-valve': $i).
% 28.89/28.94  tff(decl_11155, type, valve_1: $i > $o).
% 28.89/28.94  tff(decl_11156, type, avirulent_1: $i > $o).
% 28.89/28.94  tff(decl_11157, type, 'Avirulent': $i).
% 28.89/28.94  tff(decl_11158, type, 'Term describing a pathogen that can harm, but doesn\\t kill, its host.': $i).
% 28.89/28.94  tff(decl_11159, type, avirulent: $i).
% 28.89/28.94  tff(decl_11160, type, pathogen_1: $i > $o).
% 28.89/28.94  tff(decl_11161, type, opportunistic_pathogen_1: $i > $o).
% 28.89/28.94  tff(decl_11162, type, virulent_1: $i > $o).
% 28.89/28.94  tff(decl_11163, type, zoonotic_pathogen_1: $i > $o).
% 28.89/28.94  tff(decl_11164, type, 'Axes-Formation': $i).
% 28.89/28.94  tff(decl_11165, type, 'Formation of body axes like anterior posterior axi': $i).
% 28.89/28.94  tff(decl_11166, type, 'axis formation': $i).
% 28.89/28.94  tff(decl_11167, type, 'axes formation': $i).
% 28.89/28.94  tff(decl_11168, type, 'axes-formation': $i).
% 28.89/28.94  tff(decl_11169, type, fn_axes_formation_1: $i > $i).
% 28.89/28.94  tff(decl_11170, type, fn_axes_formation_2: $i > $i).
% 28.89/28.94  tff(decl_11171, type, fn_axes_formation_3: $i > $i).
% 28.89/28.94  tff(decl_11172, type, fn_axes_formation_4: $i > $i).
% 28.89/28.94  tff(decl_11173, type, fn_axes_formation_5: $i > $i).
% 28.89/28.94  tff(decl_11174, type, axillary_bud_1: $i > $o).
% 28.89/28.94  tff(decl_11175, type, 'Axillary-Bud': $i).
% 28.89/28.94  tff(decl_11176, type, 'In plants, an embryonic shoot that arises in the angle between a leaf and a stem. Axillary buds give rise to lateral shoots or branches.': $i).
% 28.89/28.94  tff(decl_11177, type, 'axillary bud': $i).
% 28.89/28.94  tff(decl_11178, type, 'axillary-bud': $i).
% 28.89/28.94  tff(decl_11179, type, plant_structure_1: $i > $o).
% 28.89/28.94  tff(decl_11180, type, ovule_1: $i > $o).
% 28.89/28.94  tff(decl_11181, type, peristome_1: $i > $o).
% 28.89/28.94  tff(decl_11182, type, petiole_1: $i > $o).
% 28.89/28.94  tff(decl_11183, type, pollen_grain_1: $i > $o).
% 28.89/28.94  tff(decl_11184, type, pollen_tube_1: $i > $o).
% 28.89/28.94  tff(decl_11185, type, 'Axon': $i).
% 28.89/28.94  tff(decl_11186, type, 'A typically long extension of a neuron that carries nerve impulses away from the cell body toward target cells.': $i).
% 28.89/28.94  tff(decl_11187, type, axon: $i).
% 28.89/28.94  tff(decl_11188, type, neuron_structure_1: $i > $o).
% 28.89/28.94  tff(decl_11189, type, fn_axon_1: $i > $i).
% 28.89/28.94  tff(decl_11190, type, nerve_cell_1: $i > $o).
% 28.89/28.94  tff(decl_11191, type, fn_axon_2: $i > $i).
% 28.89/28.94  tff(decl_11192, type, fn_axon_4: $i > $i).
% 28.89/28.94  tff(decl_11193, type, fn_axon_5: $i > $i).
% 28.89/28.94  tff(decl_11194, type, 'Axon-Hillock': $i).
% 28.89/28.94  tff(decl_11195, type, 'The conical region of a neurons axon where it joins the cell body; typically the region where nerve impulses are generated.': $i).
% 28.89/28.94  tff(decl_11196, type, 'hillock of axon': $i).
% 28.89/28.94  tff(decl_11197, type, 'axon hillock': $i).
% 28.89/28.94  tff(decl_11198, type, 'axon-hillock': $i).
% 28.89/28.94  tff(decl_11199, type, azide_1: $i > $o).
% 28.89/28.94  tff(decl_11200, type, 'Azide': $i).
% 28.89/28.94  tff(decl_11201, type, 'Anion of nitrogen with a minus 3 charge; also serves as a functional group in organic chemistry.': $i).
% 28.89/28.94  tff(decl_11202, type, azide: $i).
% 28.89/28.94  tff(decl_11203, type, polyatomic_ion_1: $i > $o).
% 28.89/28.94  tff(decl_11204, type, malonate_1: $i > $o).
% 28.89/28.94  tff(decl_11205, type, benzoate_1: $i > $o).
% 28.89/28.94  tff(decl_11206, type, carbonate_ion_1: $i > $o).
% 28.89/28.94  tff(decl_11207, type, cl_minus_1: $i > $o).
% 28.89/28.94  tff(decl_11208, type, sulfide_1: $i > $o).
% 28.89/28.94  tff(decl_11209, type, sulfate_1: $i > $o).
% 28.89/28.94  tff(decl_11210, type, bicarbonate_ion_1: $i > $o).
% 28.89/28.94  tff(decl_11211, type, organic_anion_1: $i > $o).
% 28.89/28.94  tff(decl_11212, type, fn_azide_2: $i > $i).
% 28.89/28.94  tff(decl_11213, type, "-3": $i).
% 28.89/28.94  tff(decl_11214, type, fn_azide_1: $i > $i).
% 28.89/28.94  tff(decl_11215, type, 'B-Antigen': $i).
% 28.89/28.94  tff(decl_11216, type, 'carbohydrate b': $i).
% 28.89/28.94  tff(decl_11217, type, 'carbohydrate-b': $i).
% 28.89/28.94  tff(decl_11218, type, 'antigen of b': $i).
% 28.89/28.94  tff(decl_11219, type, 'b antigen': $i).
% 28.89/28.94  tff(decl_11220, type, 'b-antigen': $i).
% 28.89/28.94  tff(decl_11221, type, b_cell_1: $i > $o).
% 28.89/28.94  tff(decl_11222, type, 'B-Cell': $i).
% 28.89/28.94  tff(decl_11223, type, 'The lymphocytes that complete their development in the bone marrow and become effector cells for the humoral immune response.': $i).
% 28.89/28.94  tff(decl_11224, type, 'b lymphocyte': $i).
% 28.89/28.94  tff(decl_11225, type, 'b cells': $i).
% 28.89/28.94  tff(decl_11226, type, 'cell of b': $i).
% 28.89/28.94  tff(decl_11227, type, 'b cell': $i).
% 28.89/28.94  tff(decl_11228, type, 'b-cell': $i).
% 28.89/28.94  tff(decl_11229, type, lymphocyte_1: $i > $o).
% 28.89/28.94  tff(decl_11230, type, fn_b_cell_1: $i > $i).
% 28.89/28.94  tff(decl_11231, type, dna_sequence_1: $i > $o).
% 28.89/28.94  tff(decl_11232, type, fn_b_cell_2: $i > $i).
% 28.89/28.94  tff(decl_11233, type, fn_b_cell_3: $i > $i).
% 28.89/28.94  tff(decl_11234, type, fn_b_cell_4: $i > $i).
% 28.89/28.94  tff(decl_11235, type, fn_b_cell_5: $i > $i).
% 28.89/28.94  tff(decl_11236, type, fn_b_cell_6: $i > $i).
% 28.89/28.94  tff(decl_11237, type, fn_b_cell_7: $i > $i).
% 28.89/28.94  tff(decl_11238, type, fn_b_cell_8: $i > $i).
% 28.89/28.94  tff(decl_11239, type, fn_b_cell_9: $i > $i).
% 28.89/28.94  tff(decl_11240, type, gene_related_aggregates_1: $i > $o).
% 28.89/28.94  tff(decl_11241, type, fn_b_cell_10: $i > $i).
% 28.89/28.94  tff(decl_11242, type, combine_1: $i > $o).
% 28.89/28.94  tff(decl_11243, type, fn_b_cell_11: $i > $i).
% 28.89/28.94  tff(decl_11244, type, fn_b_cell_12: $i > $i).
% 28.89/28.94  tff(decl_11245, type, fn_combine_1: $i > $i).
% 28.89/28.94  tff(decl_11246, type, fn_cell_differentiation_19: $i > $i).
% 28.89/28.94  tff(decl_11247, type, fn_cell_24: $i > $i).
% 28.89/28.94  tff(decl_11248, type, fn_gene_6: $i > $i).
% 28.89/28.94  tff(decl_11249, type, fn_combine_2: $i > $i).
% 28.89/28.94  tff(decl_11250, type, fn_gene_related_aggregates_1: $i > $i).
% 28.89/28.94  tff(decl_11251, type, fn_immunoglobulin_gene_9: $i > $i).
% 28.89/28.94  tff(decl_11252, type, immunoglobulin_protein_0: $i).
% 28.89/28.94  tff(decl_11253, type, b_cell_receptor_1: $i > $o).
% 28.89/28.94  tff(decl_11254, type, 'B-Cell-Receptor': $i).
% 28.89/28.94  tff(decl_11255, type, 'The antigen receptor on B cells: a Y-shaped, membrane-bound molecule consisting of two identical heavy chains and two identical light chains linked by disulfide bridges and containing two antigen-binding sites.': $i).
% 28.89/28.94  tff(decl_11256, type, 'b cell receptor': $i).
% 28.89/28.94  tff(decl_11257, type, 'b-cell-receptor': $i).
% 28.89/28.94  tff(decl_11258, type, fn_b_cell_receptor_1: $i > $i).
% 28.89/28.94  tff(decl_11259, type, fn_b_cell_receptor_2: $i > $i).
% 28.89/28.94  tff(decl_11260, type, fn_b_cell_receptor_3: $i > $i).
% 28.89/28.94  tff(decl_11261, type, fn_b_cell_receptor_4: $i > $i).
% 28.89/28.94  tff(decl_11262, type, fn_b_cell_receptor_5: $i > $i).
% 28.89/28.94  tff(decl_11263, type, fn_b_cell_receptor_6: $i > $i).
% 28.89/28.94  tff(decl_11264, type, fn_b_cell_receptor_7: $i > $i).
% 28.89/28.94  tff(decl_11265, type, fn_b_cell_receptor_8: $i > $i).
% 28.89/28.94  tff(decl_11266, type, fn_b_cell_receptor_9: $i > $i).
% 28.89/28.94  tff(decl_11267, type, fn_b_cell_receptor_10: $i > $i).
% 28.89/28.94  tff(decl_11268, type, fn_b_cell_receptor_11: $i > $i).
% 28.89/28.94  tff(decl_11269, type, fn_b_cell_receptor_12: $i > $i).
% 28.89/28.94  tff(decl_11270, type, fn_b_cell_receptor_13: $i > $i).
% 28.89/28.94  tff(decl_11271, type, fn_b_cell_receptor_14: $i > $i).
% 28.89/28.94  tff(decl_11272, type, fn_b_cell_receptor_15: $i > $i).
% 28.89/28.94  tff(decl_11273, type, fn_b_cell_receptor_16: $i > $i).
% 28.89/28.94  tff(decl_11274, type, fn_b_cell_receptor_17: $i > $i).
% 28.89/28.94  tff(decl_11275, type, fn_receptor_protein_3: $i > $i).
% 28.89/28.94  tff(decl_11276, type, fn_receptor_protein_4: $i > $i).
% 28.89/28.94  tff(decl_11277, type, fn_receptor_protein_5: $i > $i).
% 28.89/28.94  tff(decl_11278, type, b_galactosidase_1: $i > $o).
% 28.89/28.94  tff(decl_11279, type, 'B-Galactosidase': $i).
% 28.89/28.94  tff(decl_11280, type, 'Beta-Galactosidase is a hydrolase enzyme that catalyzes the hydrolysis of Beta-galactosides into monosaccharides.': $i).
% 28.89/28.94  tff(decl_11281, type, 'beta galactosidase': $i).
% 28.89/28.94  tff(decl_11282, type, 'beta-galactosidase': $i).
% 28.89/28.94  tff(decl_11283, type, 'b galactosidase': $i).
% 28.89/28.94  tff(decl_11284, type, 'b-galactosidase': $i).
% 28.89/28.94  tff(decl_11285, type, fn_b_galactosidase_1: $i > $i).
% 28.89/28.94  tff(decl_11286, type, fn_b_galactosidase_2: $i > $i).
% 28.89/28.94  tff(decl_11287, type, fn_b_galactosidase_3: $i > $i).
% 28.89/28.94  tff(decl_11288, type, fn_b_galactosidase_4: $i > $i).
% 28.89/28.94  tff(decl_11289, type, fn_b_galactosidase_5: $i > $i).
% 28.89/28.94  tff(decl_11290, type, ba_plus_2_1: $i > $o).
% 28.89/28.94  tff(decl_11291, type, 'Ba-Plus-2': $i).
% 28.89/28.94  tff(decl_11292, type, 'An Ion of Barium with 2 positive charge.': $i).
% 28.89/28.94  tff(decl_11293, type, barium: $i).
% 28.89/28.94  tff(decl_11294, type, 'ba plus 2': $i).
% 28.89/28.94  tff(decl_11295, type, 'ba-plus-2': $i).
% 28.89/28.94  tff(decl_11296, type, monoatomic_ion_1: $i > $o).
% 28.89/28.94  tff(decl_11297, type, ch3nh3_plus_1: $i > $o).
% 28.89/28.94  tff(decl_11298, type, cs_plus_1: $i > $o).
% 28.89/28.94  tff(decl_11299, type, pb_plus_2_1: $i > $o).
% 28.89/28.94  tff(decl_11300, type, fn_ba_plus_2_1: $i > $i).
% 28.89/28.94  tff(decl_11301, type, barium_1: $i > $o).
% 28.89/28.94  tff(decl_11302, type, fn_ba_plus_2_2: $i > $i).
% 28.89/28.94  tff(decl_11303, type, fn_ba_plus_2_3: $i > $i).
% 28.89/28.94  tff(decl_11304, type, lose_1: $i > $o).
% 28.89/28.94  tff(decl_11305, type, fn_ba_plus_2_4: $i > $i).
% 28.89/28.94  tff(decl_11306, type, fn_ba_plus_2_6: $i > $i).
% 28.89/28.94  tff(decl_11307, type, fn_ba_plus_2_7: $i > $i).
% 28.89/28.94  tff(decl_11308, type, fn_lose_1: $i > $i).
% 28.89/28.94  tff(decl_11309, type, "54": $i).
% 28.89/28.94  tff(decl_11310, type, "56": $i).
% 28.89/28.94  tff(decl_11311, type, fn_monoatomic_ion_1: $i > $i).
% 28.89/28.94  tff(decl_11312, type, fn_cation_1: $i > $i).
% 28.89/28.94  tff(decl_11313, type, fn_cation_7: $i > $i).
% 28.89/28.94  tff(decl_11314, type, fn_ba_plus_2_5: $i > $i).
% 28.89/28.94  tff(decl_11315, type, fn_cation_4: $i > $i).
% 28.89/28.94  tff(decl_11316, type, fn_cation_5: $i > $i).
% 28.89/28.94  tff(decl_11317, type, bacterial_artificial_chromosome_1: $i > $o).
% 28.89/28.94  tff(decl_11318, type, 'Bacterial-artificial-chromosome': $i).
% 28.89/28.94  tff(decl_11319, type, 'An artificial version of a bacterial chromosome that can carry inserts of 100,000 to 500,000 base pairs': $i).
% 28.89/28.94  tff(decl_11320, type, bac: $i).
% 28.89/28.94  tff(decl_11321, type, 'artificial version of bacterial chromosome': $i).
% 28.89/28.94  tff(decl_11322, type, 'artificial bacterial chromosome': $i).
% 28.89/28.94  tff(decl_11323, type, 'bacterial artificial chromosome': $i).
% 28.89/28.94  tff(decl_11324, type, 'bacterial-artificial-chromosome': $i).
% 28.89/28.94  tff(decl_11325, type, cloning_vector_1: $i > $o).
% 28.89/28.94  tff(decl_11326, type, cloning_phage_1: $i > $o).
% 28.89/28.94  tff(decl_11327, type, cloning_plasmid_1: $i > $o).
% 28.89/28.94  tff(decl_11328, type, expression_vector_1: $i > $o).
% 28.89/28.94  tff(decl_11329, type, fn_bacterial_artificial_chromosome_1: $i > $i).
% 28.89/28.94  tff(decl_11330, type, base_pair_1: $i > $o).
% 28.89/28.94  tff(decl_11331, type, fn_bacterial_artificial_chromosome_2: $i > $i).
% 28.89/28.94  tff(decl_11332, type, foreign_dna_1: $i > $o).
% 28.89/28.94  tff(decl_11333, type, fn_bacterial_artificial_chromosome_3: $i > $i).
% 28.89/28.94  tff(decl_11334, type, "500000": $i).
% 28.89/28.94  tff(decl_11335, type, base_pair_0: $i).
% 28.89/28.94  tff(decl_11336, type, fn_cloning_vector_4: $i > $i).
% 28.89/28.94  tff(decl_11337, type, fn_cloning_vector_5: $i > $i).
% 28.89/28.94  tff(decl_11338, type, bacterial_biofilm_1: $i > $o).
% 28.89/28.94  tff(decl_11339, type, 'Bacterial-Biofilm': $i).
% 28.89/28.94  tff(decl_11340, type, 'Aggregate of prokaryotic organisms which adhere to and grow on a surface.': $i).
% 28.89/28.94  tff(decl_11341, type, 'bacterial biofilm': $i).
% 28.89/28.94  tff(decl_11342, type, 'bacterial-biofilm': $i).
% 28.89/28.94  tff(decl_11343, type, fn_bacterial_biofilm_1: $i > $i).
% 28.89/28.94  tff(decl_11344, type, fn_bacterial_biofilm_2: $i > $i).
% 28.89/28.94  tff(decl_11345, type, fn_biofilm_2: $i > $i).
% 28.89/28.94  tff(decl_11346, type, fn_biofilm_1: $i > $i).
% 28.89/28.94  tff(decl_11347, type, bacterial_biofilm_formation_1: $i > $o).
% 28.89/28.94  tff(decl_11348, type, 'Bacterial-Biofilm-Formation': $i).
% 28.89/28.94  tff(decl_11349, type, 'The process of colonization and prokaryotic cell division that results in the production of a bacterial biofilm on a surface.': $i).
% 28.89/28.94  tff(decl_11350, type, form: $i).
% 28.89/28.94  tff(decl_11351, type, 'bacterial biofilm formation': $i).
% 28.89/28.94  tff(decl_11352, type, 'bacterial-biofilm-formation': $i).
% 28.89/28.94  tff(decl_11353, type, biofilm_formation_1: $i > $o).
% 28.89/28.94  tff(decl_11354, type, fn_bacterial_biofilm_formation_1: $i > $i).
% 28.89/28.94  tff(decl_11355, type, fn_biofilm_formation_7: $i > $i).
% 28.89/28.94  tff(decl_11356, type, bacterial_cell_inside_hypertonic_solution_1: $i > $o).
% 28.89/28.94  tff(decl_11357, type, 'Bacterial-Cell-Inside-Hypertonic-Solution': $i).
% 28.89/28.94  tff(decl_11358, type, 'When a bacterial cell is placed in hypertonic solution, the cell loses water as the cell wall collapses and water exits by osmosis.': $i).
% 28.89/28.94  tff(decl_11359, type, 'bacterial cell inside hypertonic solution': $i).
% 28.89/28.94  tff(decl_11360, type, 'bacterial-cell-inside-hypertonic-solution': $i).
% 28.89/28.94  tff(decl_11361, type, walled_cell_inside_hypertonic_solution_1: $i > $o).
% 28.89/28.94  tff(decl_11362, type, fungal_cell_inside_hypertonic_solution_1: $i > $o).
% 28.89/28.94  tff(decl_11363, type, plant_cell_inside_hypertonic_solution_1: $i > $o).
% 28.89/28.94  tff(decl_11364, type, fn_bacterial_cell_inside_hypertonic_solution_1: $i > $i).
% 28.89/28.94  tff(decl_11365, type, fn_bacterial_cell_inside_hypertonic_solution_2: $i > $i).
% 28.89/28.94  tff(decl_11366, type, fn_bacterial_cell_inside_hypertonic_solution_3: $i > $i).
% 28.89/28.94  tff(decl_11367, type, fn_bacterial_cell_inside_hypertonic_solution_4: $i > $i).
% 28.89/28.94  tff(decl_11368, type, fn_bacterial_cell_inside_hypertonic_solution_5: $i > $i).
% 28.89/28.94  tff(decl_11369, type, prokaryotic_electron_transport_chain_1: $i > $o).
% 28.89/28.94  tff(decl_11370, type, fn_bacterial_cell_inside_hypertonic_solution_6: $i > $i).
% 28.89/28.94  tff(decl_11371, type, fn_bacterial_cell_inside_hypertonic_solution_7: $i > $i).
% 28.89/28.94  tff(decl_11372, type, fn_bacterial_cell_inside_hypertonic_solution_8: $i > $i).
% 28.89/28.94  tff(decl_11373, type, fn_bacterial_cell_inside_hypertonic_solution_9: $i > $i).
% 28.89/28.94  tff(decl_11374, type, protoplast_1: $i > $o).
% 28.89/28.94  tff(decl_11375, type, fn_bacterial_cell_inside_hypertonic_solution_12: $i > $i).
% 28.89/28.94  tff(decl_11376, type, fn_bacterial_cell_inside_hypertonic_solution_13: $i > $i).
% 28.89/28.94  tff(decl_11377, type, fn_bacterial_cell_inside_hypertonic_solution_14: $i > $i).
% 28.89/28.94  tff(decl_11378, type, fn_bacterial_cell_inside_hypertonic_solution_15: $i > $i).
% 28.89/28.94  tff(decl_11379, type, fn_bacterial_cell_inside_hypertonic_solution_16: $i > $i).
% 28.89/28.94  tff(decl_11380, type, fn_bacterial_cell_inside_hypertonic_solution_17: $i > $i).
% 28.89/28.94  tff(decl_11381, type, fn_bacterial_cell_inside_hypertonic_solution_18: $i > $i).
% 28.89/28.94  tff(decl_11382, type, fn_bacterial_cell_inside_hypertonic_solution_19: $i > $i).
% 28.89/28.94  tff(decl_11383, type, fn_bacterial_cell_inside_hypertonic_solution_22: $i > $i).
% 28.89/28.94  tff(decl_11384, type, fn_bacterial_cell_inside_hypertonic_solution_23: $i > $i).
% 28.89/28.94  tff(decl_11385, type, fn_bacterial_cell_inside_hypertonic_solution_24: $i > $i).
% 28.89/28.94  tff(decl_11386, type, fn_bacterial_cell_inside_hypertonic_solution_25: $i > $i).
% 28.89/28.94  tff(decl_11387, type, fn_bacterial_cell_inside_hypertonic_solution_26: $i > $i).
% 28.89/28.94  tff(decl_11388, type, fn_bacterial_cell_inside_hypertonic_solution_27: $i > $i).
% 28.89/28.94  tff(decl_11389, type, fn_bacterial_cell_inside_hypertonic_solution_28: $i > $i).
% 28.89/28.94  tff(decl_11390, type, fn_bacterial_cell_inside_hypertonic_solution_29: $i > $i).
% 28.89/28.94  tff(decl_11391, type, fn_bacterial_cell_inside_hypertonic_solution_30: $i > $i).
% 28.89/28.94  tff(decl_11392, type, fn_bacterial_cell_inside_hypertonic_solution_31: $i > $i).
% 28.89/28.94  tff(decl_11393, type, fn_bacterial_cell_inside_hypertonic_solution_32: $i > $i).
% 28.89/28.94  tff(decl_11394, type, expand_1: $i > $o).
% 28.89/28.94  tff(decl_11395, type, fn_bacterial_cell_inside_hypertonic_solution_33: $i > $i).
% 28.89/28.94  tff(decl_11396, type, fn_bacterial_cell_inside_hypertonic_solution_34: $i > $i).
% 28.89/28.94  tff(decl_11397, type, fn_bacterial_cell_inside_hypertonic_solution_35: $i > $i).
% 28.89/28.94  tff(decl_11398, type, fn_bacterial_cell_inside_hypertonic_solution_36: $i > $i).
% 28.89/28.94  tff(decl_11399, type, fn_bacterial_cell_inside_hypertonic_solution_37: $i > $i).
% 28.89/28.94  tff(decl_11400, type, fn_bacterial_cell_inside_hypertonic_solution_38: $i > $i).
% 28.89/28.94  tff(decl_11401, type, fn_bacterial_cell_inside_hypertonic_solution_39: $i > $i).
% 28.89/28.94  tff(decl_11402, type, fn_bacterial_cell_inside_hypertonic_solution_40: $i > $i).
% 28.89/28.94  tff(decl_11403, type, fn_bacterial_cell_inside_hypertonic_solution_47: $i > $i).
% 28.89/28.94  tff(decl_11404, type, fn_bacterial_cell_inside_hypertonic_solution_48: $i > $i).
% 28.89/28.94  tff(decl_11405, type, fn_bacterial_cell_inside_hypertonic_solution_49: $i > $i).
% 28.89/28.94  tff(decl_11406, type, fn_bacterial_cell_inside_hypertonic_solution_50: $i > $i).
% 28.89/28.94  tff(decl_11407, type, fn_bacterial_cell_inside_hypertonic_solution_51: $i > $i).
% 28.89/28.94  tff(decl_11408, type, fn_bacterial_cell_inside_hypertonic_solution_52: $i > $i).
% 28.89/28.94  tff(decl_11409, type, fn_bacterial_cell_inside_hypertonic_solution_53: $i > $i).
% 28.89/28.94  tff(decl_11410, type, fn_bacterial_cell_inside_hypertonic_solution_54: $i > $i).
% 28.89/28.94  tff(decl_11411, type, fn_bacterial_cell_inside_hypertonic_solution_55: $i > $i).
% 28.89/28.94  tff(decl_11412, type, diffusion_of_anion_across_plasma_membrane_1: $i > $o).
% 28.89/28.94  tff(decl_11413, type, fn_bacterial_cell_inside_hypertonic_solution_56: $i > $i).
% 28.89/28.94  tff(decl_11414, type, fn_bacterial_cell_inside_hypertonic_solution_57: $i > $i).
% 28.89/28.94  tff(decl_11415, type, fn_bacterial_cell_inside_hypertonic_solution_58: $i > $i).
% 28.89/28.94  tff(decl_11416, type, fn_bacterial_cell_inside_hypertonic_solution_59: $i > $i).
% 28.89/28.94  tff(decl_11417, type, fn_bacterial_cell_inside_hypertonic_solution_60: $i > $i).
% 28.89/28.94  tff(decl_11418, type, fn_bacterial_cell_inside_hypertonic_solution_61: $i > $i).
% 28.89/28.94  tff(decl_11419, type, fn_bacterial_cell_inside_hypertonic_solution_62: $i > $i).
% 28.89/28.94  tff(decl_11420, type, fn_bacterial_cell_inside_hypertonic_solution_63: $i > $i).
% 28.89/28.94  tff(decl_11421, type, fn_bacterial_cell_inside_hypertonic_solution_64: $i > $i).
% 28.89/28.94  tff(decl_11422, type, osmosis_1: $i > $o).
% 28.89/28.94  tff(decl_11423, type, passive_transport_of_water_1: $i > $o).
% 28.89/28.94  tff(decl_11424, type, fn_bacterial_cell_inside_hypertonic_solution_65: $i > $i).
% 28.89/28.94  tff(decl_11425, type, fn_bacterial_cell_inside_hypertonic_solution_66: $i > $i).
% 28.89/28.94  tff(decl_11426, type, fn_bacterial_cell_inside_hypertonic_solution_67: $i > $i).
% 28.89/28.94  tff(decl_11427, type, fn_bacterial_cell_inside_hypertonic_solution_68: $i > $i).
% 28.89/28.94  tff(decl_11428, type, fn_bacterial_cell_inside_hypertonic_solution_69: $i > $i).
% 28.89/28.94  tff(decl_11429, type, fn_bacterial_cell_inside_hypertonic_solution_70: $i > $i).
% 28.89/28.94  tff(decl_11430, type, fn_bacterial_cell_inside_hypertonic_solution_71: $i > $i).
% 28.89/28.94  tff(decl_11431, type, fn_bacterial_cell_inside_hypertonic_solution_72: $i > $i).
% 28.89/28.94  tff(decl_11432, type, fn_bacterial_cell_inside_hypertonic_solution_73: $i > $i).
% 28.89/28.94  tff(decl_11433, type, fn_bacterial_cell_inside_hypertonic_solution_74: $i > $i).
% 28.89/28.94  tff(decl_11434, type, fn_bacterial_cell_inside_hypertonic_solution_75: $i > $i).
% 28.89/28.94  tff(decl_11435, type, fn_bacterial_cell_inside_hypertonic_solution_76: $i > $i).
% 28.89/28.94  tff(decl_11436, type, fn_bacterial_cell_inside_hypertonic_solution_77: $i > $i).
% 28.89/28.94  tff(decl_11437, type, fn_bacterial_cell_inside_hypertonic_solution_78: $i > $i).
% 28.89/28.94  tff(decl_11438, type, fn_bacterial_cell_inside_hypertonic_solution_79: $i > $i).
% 28.89/28.94  tff(decl_11439, type, fn_bacterial_cell_inside_hypertonic_solution_80: $i > $i).
% 28.89/28.94  tff(decl_11440, type, fn_bacterial_cell_inside_hypertonic_solution_81: $i > $i).
% 28.89/28.94  tff(decl_11441, type, fn_bacterial_cell_inside_hypertonic_solution_82: $i > $i).
% 28.89/28.94  tff(decl_11442, type, fn_bacterial_cell_inside_hypertonic_solution_83: $i > $i).
% 28.89/28.94  tff(decl_11443, type, fn_bacterial_cell_inside_hypertonic_solution_84: $i > $i).
% 28.89/28.94  tff(decl_11444, type, fn_bacterial_cell_inside_hypertonic_solution_85: $i > $i).
% 28.89/28.94  tff(decl_11445, type, fn_bacterial_cell_inside_hypertonic_solution_86: $i > $i).
% 28.89/28.94  tff(decl_11446, type, fn_bacterial_cell_inside_hypertonic_solution_87: $i > $i).
% 28.89/28.94  tff(decl_11447, type, fn_bacterial_cell_inside_hypertonic_solution_88: $i > $i).
% 28.89/28.94  tff(decl_11448, type, fn_bacterial_cell_inside_hypertonic_solution_89: $i > $i).
% 28.89/28.94  tff(decl_11449, type, fn_bacterial_cell_inside_hypertonic_solution_90: $i > $i).
% 28.89/28.94  tff(decl_11450, type, turgor_pressure_1: $i > $o).
% 28.89/28.94  tff(decl_11451, type, fn_bacterial_cell_inside_hypertonic_solution_91: $i > $i).
% 28.89/28.94  tff(decl_11452, type, fn_bacterial_cell_inside_hypertonic_solution_92: $i > $i).
% 28.89/28.94  tff(decl_11453, type, plasmolysis_1: $i > $o).
% 28.89/28.94  tff(decl_11454, type, fn_bacterial_cell_inside_hypertonic_solution_93: $i > $i).
% 28.89/28.94  tff(decl_11455, type, fn_bacterial_cell_inside_hypertonic_solution_94: $i > $i).
% 28.89/28.94  tff(decl_11456, type, fn_plasmolysis_9: $i > $i).
% 28.89/28.94  tff(decl_11457, type, fn_diffusion_of_anion_across_plasma_membrane_8: $i > $i).
% 28.89/28.94  tff(decl_11458, type, fn_decrease_1: $i > $i).
% 28.89/28.94  tff(decl_11459, type, fn_decrease_4: $i > $i).
% 28.89/28.94  tff(decl_11460, type, fn_hypotonic_solution_7: $i > $i).
% 28.89/28.94  tff(decl_11461, type, fn_water_107: $i > $i).
% 28.89/28.94  tff(decl_11462, type, fn_water_97: $i > $i).
% 28.89/28.94  tff(decl_11463, type, fn_water_76: $i > $i).
% 28.89/28.94  tff(decl_11464, type, fn_water_89: $i > $i).
% 28.89/28.94  tff(decl_11465, type, fn_water_88: $i > $i).
% 28.89/28.94  tff(decl_11466, type, fn_water_92: $i > $i).
% 28.89/28.94  tff(decl_11467, type, fn_water_93: $i > $i).
% 28.89/28.94  tff(decl_11468, type, fn_water_94: $i > $i).
% 28.89/28.94  tff(decl_11469, type, fn_water_87: $i > $i).
% 28.89/28.94  tff(decl_11470, type, fn_plasmolysis_16: $i > $i).
% 28.89/28.94  tff(decl_11471, type, fn_decrease_3: $i > $i).
% 28.89/28.94  tff(decl_11472, type, fn_plasmolysis_6: $i > $i).
% 28.89/28.94  tff(decl_11473, type, fn_plasmolysis_25: $i > $i).
% 28.89/28.94  tff(decl_11474, type, fn_metabolism_1: $i > $i).
% 28.89/28.94  tff(decl_11475, type, fn_cellular_work_2: $i > $i).
% 28.89/28.94  tff(decl_11476, type, fn_plasmolysis_5: $i > $i).
% 28.89/28.94  tff(decl_11477, type, fn_hypotonic_solution_4: $i > $i).
% 28.89/28.94  tff(decl_11478, type, fn_plasmolysis_19: $i > $i).
% 28.89/28.94  tff(decl_11479, type, fn_passive_transport_of_water_2: $i > $i).
% 28.89/28.94  tff(decl_11480, type, fn_hypotonic_solution_2: $i > $i).
% 28.89/28.94  tff(decl_11481, type, fn_passive_transport_26: $i > $i).
% 28.89/28.94  tff(decl_11482, type, fn_plasmolysis_8: $i > $i).
% 28.89/28.94  tff(decl_11483, type, fn_passive_transport_of_solute_3: $i > $i).
% 28.89/28.94  tff(decl_11484, type, fn_plasmolysis_28: $i > $i).
% 28.89/28.94  tff(decl_11485, type, fn_passive_transport_of_water_3: $i > $i).
% 28.89/28.94  tff(decl_11486, type, fn_diffusion_of_anion_across_plasma_membrane_35: $i > $i).
% 28.89/28.94  tff(decl_11487, type, fn_diffusion_of_anion_across_plasma_membrane_20: $i > $i).
% 28.89/28.94  tff(decl_11488, type, fn_passive_transport_23: $i > $i).
% 28.89/28.94  tff(decl_11489, type, fn_plasmolysis_22: $i > $i).
% 28.89/28.94  tff(decl_11490, type, fn_plasmolysis_27: $i > $i).
% 28.89/28.94  tff(decl_11491, type, fn_passive_transport_of_water_1: $i > $i).
% 28.89/28.94  tff(decl_11492, type, fn_plasmolysis_23: $i > $i).
% 28.89/28.94  tff(decl_11493, type, fn_hypotonic_solution_3: $i > $i).
% 28.89/28.94  tff(decl_11494, type, fn_plasmolysis_10: $i > $i).
% 28.89/28.94  tff(decl_11495, type, fn_osmosis_21: $i > $i).
% 28.89/28.94  tff(decl_11496, type, fn_plasmolysis_24: $i > $i).
% 28.89/28.94  tff(decl_11497, type, fn_plasmolysis_7: $i > $i).
% 28.89/28.94  tff(decl_11498, type, fn_diffusion_of_anion_across_plasma_membrane_28: $i > $i).
% 28.89/28.94  tff(decl_11499, type, 'Waterpotential': $i).
% 28.89/28.94  tff(decl_11500, type, fn_bacterial_cell_inside_hypertonic_solution_41: $i > $i).
% 28.89/28.94  tff(decl_11501, type, fn_bacterial_cell_inside_hypertonic_solution_46: $i > $i).
% 28.89/28.94  tff(decl_11502, type, fn_bacterium_1: $i > $i).
% 28.89/28.94  tff(decl_11503, type, fn_bacterium_3: $i > $i).
% 28.89/28.94  tff(decl_11504, type, fn_bacterium_8: $i > $i).
% 28.89/28.94  tff(decl_11505, type, fn_bacterium_11: $i > $i).
% 28.89/28.94  tff(decl_11506, type, fn_bacterial_cell_inside_hypertonic_solution_42: $i > $i).
% 28.89/28.94  tff(decl_11507, type, fn_bacterial_cell_inside_hypertonic_solution_43: $i > $i).
% 28.89/28.94  tff(decl_11508, type, fn_bacterial_cell_inside_hypertonic_solution_44: $i > $i).
% 28.89/28.94  tff(decl_11509, type, fn_walled_cell_inside_hypertonic_solution_15: $i > $i).
% 28.89/28.94  tff(decl_11510, type, fn_walled_cell_inside_hypertonic_solution_9: $i > $i).
% 28.89/28.94  tff(decl_11511, type, fn_bacterial_cell_inside_hypertonic_solution_11: $i > $i).
% 28.89/28.94  tff(decl_11512, type, fn_walled_cell_inside_hypertonic_solution_42: $i > $i).
% 28.89/28.94  tff(decl_11513, type, fn_bacterial_cell_inside_hypertonic_solution_10: $i > $i).
% 28.89/28.94  tff(decl_11514, type, fn_walled_cell_inside_hypertonic_solution_41: $i > $i).
% 28.89/28.94  tff(decl_11515, type, fn_walled_cell_inside_hypertonic_solution_21: $i > $i).
% 28.89/28.94  tff(decl_11516, type, fn_walled_cell_inside_hypertonic_solution_30: $i > $i).
% 28.89/28.94  tff(decl_11517, type, fn_walled_cell_inside_hypertonic_solution_40: $i > $i).
% 28.89/28.94  tff(decl_11518, type, fn_walled_cell_inside_hypertonic_solution_31: $i > $i).
% 28.89/28.94  tff(decl_11519, type, fn_walled_cell_inside_hypertonic_solution_32: $i > $i).
% 28.89/28.94  tff(decl_11520, type, fn_walled_cell_inside_hypertonic_solution_16: $i > $i).
% 28.89/28.94  tff(decl_11521, type, fn_walled_cell_inside_hypertonic_solution_6: $i > $i).
% 28.89/28.94  tff(decl_11522, type, fn_walled_cell_inside_hypertonic_solution_35: $i > $i).
% 28.89/28.94  tff(decl_11523, type, fn_walled_cell_inside_hypertonic_solution_7: $i > $i).
% 28.89/28.94  tff(decl_11524, type, fn_walled_cell_inside_hypertonic_solution_3: $i > $i).
% 28.89/28.94  tff(decl_11525, type, fn_walled_cell_inside_hypertonic_solution_18: $i > $i).
% 28.89/28.94  tff(decl_11526, type, fn_walled_cell_inside_hypertonic_solution_4: $i > $i).
% 28.89/28.94  tff(decl_11527, type, fn_walled_cell_inside_hypertonic_solution_29: $i > $i).
% 28.89/28.94  tff(decl_11528, type, fn_walled_cell_inside_hypertonic_solution_20: $i > $i).
% 28.89/28.94  tff(decl_11529, type, fn_walled_cell_inside_hypertonic_solution_39: $i > $i).
% 28.89/28.94  tff(decl_11530, type, fn_walled_cell_inside_hypertonic_solution_38: $i > $i).
% 28.89/28.94  tff(decl_11531, type, fn_walled_cell_inside_hypertonic_solution_11: $i > $i).
% 28.89/28.94  tff(decl_11532, type, fn_walled_cell_inside_hypertonic_solution_10: $i > $i).
% 28.89/28.94  tff(decl_11533, type, fn_walled_cell_inside_hypertonic_solution_24: $i > $i).
% 28.89/28.94  tff(decl_11534, type, fn_walled_cell_inside_hypertonic_solution_19: $i > $i).
% 28.89/28.94  tff(decl_11535, type, fn_walled_cell_inside_hypertonic_solution_17: $i > $i).
% 28.89/28.94  tff(decl_11536, type, fn_walled_cell_inside_hypertonic_solution_33: $i > $i).
% 28.89/28.94  tff(decl_11537, type, fn_walled_cell_inside_hypertonic_solution_34: $i > $i).
% 28.89/28.94  tff(decl_11538, type, fn_bacterial_cell_inside_hypertonic_solution_45: $i > $i).
% 28.89/28.94  tff(decl_11539, type, fn_bacterial_cell_inside_hypertonic_solution_20: $i > $i).
% 28.89/28.94  tff(decl_11540, type, fn_bacterial_cell_inside_hypertonic_solution_21: $i > $i).
% 28.89/28.94  tff(decl_11541, type, bacterial_disease_1: $i > $o).
% 28.89/28.94  tff(decl_11542, type, 'Bacterial-Disease': $i).
% 28.89/28.94  tff(decl_11543, type, 'Abnormal condition in an organism, caused by infection with bacteria.': $i).
% 28.89/28.94  tff(decl_11544, type, 'bacterial disease': $i).
% 28.89/28.94  tff(decl_11545, type, 'bacterial-disease': $i).
% 28.89/28.94  tff(decl_11546, type, infectious_disease_1: $i > $o).
% 28.89/28.94  tff(decl_11547, type, infection_1: $i > $o).
% 28.89/28.94  tff(decl_11548, type, bacterial_infection_1: $i > $o).
% 28.89/28.94  tff(decl_11549, type, fn_bacterial_infection_2: $i > $i).
% 28.89/28.94  tff(decl_11550, type, 'Bacterial-Infection': $i).
% 28.89/28.94  tff(decl_11551, type, 'Harmful colonization of an organism by pathogenic prokaryotes.': $i).
% 28.89/28.94  tff(decl_11552, type, 'infection caused by bacteria': $i).
% 28.89/28.94  tff(decl_11553, type, infect: $i).
% 28.89/28.94  tff(decl_11554, type, 'bacterial infection': $i).
% 28.89/28.94  tff(decl_11555, type, 'bacterial-infection': $i).
% 28.89/28.94  tff(decl_11556, type, fn_bacterial_infection_3: $i > $i).
% 28.89/28.94  tff(decl_11557, type, bacterial_infection_in_human_1: $i > $o).
% 28.89/28.94  tff(decl_11558, type, 'Bacterial-Infection-In-Human': $i).
% 28.89/28.94  tff(decl_11559, type, 'Bacterial infection in a human.': $i).
% 28.89/28.94  tff(decl_11560, type, 'human bacterial infection': $i).
% 28.89/28.94  tff(decl_11561, type, 'bacterial infection in human': $i).
% 28.89/28.94  tff(decl_11562, type, 'bacterial-infection-in-human': $i).
% 28.89/28.94  tff(decl_11563, type, human_genetic_order_1: $i > $o).
% 28.89/28.94  tff(decl_11564, type, fn_bacterial_infection_in_human_1: $i > $i).
% 28.89/28.94  tff(decl_11565, type, bacteriorhodopsin_1: $i > $o).
% 28.89/28.94  tff(decl_11566, type, 'Bacteriorhodopsin': $i).
% 28.89/28.94  tff(decl_11567, type, 'A purple-colored photosynthetic pigment that is most efficient at absorbing green light, embedded in the plasma membrane of some prokaryotes.': $i).
% 28.89/28.94  tff(decl_11568, type, bacteriorhodopsin: $i).
% 28.89/28.94  tff(decl_11569, type, 'Bacterium': $i).
% 28.89/28.94  tff(decl_11570, type, 'Member of one of the two classes of prokaryotes,                           the other group being the archaea.': $i).
% 28.89/28.94  tff(decl_11571, type, 'Bacterium is a prokaryotic organism.': $i).
% 28.89/28.94  tff(decl_11572, type, bacteria: $i).
% 28.89/28.94  tff(decl_11573, type, 'bacterial cell': $i).
% 28.89/28.94  tff(decl_11574, type, bacterium: $i).
% 28.89/28.94  tff(decl_11575, type, fn_bacterium_2: $i > $i).
% 28.89/28.94  tff(decl_11576, type, fn_bacterium_4: $i > $i).
% 28.89/28.94  tff(decl_11577, type, fn_bacterium_6: $i > $i).
% 28.89/28.94  tff(decl_11578, type, fn_bacterium_7: $i > $i).
% 28.89/28.94  tff(decl_11579, type, fn_bacterium_9: $i > $i).
% 28.89/28.94  tff(decl_11580, type, fn_bacterium_10: $i > $i).
% 28.89/28.94  tff(decl_11581, type, fn_prokaryotic_ribosome_1: $i > $i).
% 28.89/28.94  tff(decl_11582, type, fn_prokaryote_8: $i > $i).
% 28.89/28.94  tff(decl_11583, type, fn_prokaryote_16: $i > $i).
% 28.89/28.94  tff(decl_11584, type, fn_prokaryote_14: $i > $i).
% 28.89/28.94  tff(decl_11585, type, fn_prokaryote_13: $i > $i).
% 28.89/28.94  tff(decl_11586, type, bacteroid_1: $i > $o).
% 28.89/28.94  tff(decl_11587, type, 'Bacteroid': $i).
% 28.89/28.94  tff(decl_11588, type, 'An irregularly-shaped form of the bacterium Rhizobium found in the root nodules of legumes.': $i).
% 28.89/28.94  tff(decl_11589, type, bacteroid: $i).
% 28.89/28.94  tff(decl_11590, type, rhizobacterium_1: $i > $o).
% 28.89/28.94  tff(decl_11591, type, baculum_1: $i > $o).
% 28.89/28.94  tff(decl_11592, type, 'Baculum': $i).
% 28.89/28.94  tff(decl_11593, type, 'A bone in the penis of most mammals; aids in copulation by maintaining stiffness of the penis.': $i).
% 28.89/28.94  tff(decl_11594, type, baculum: $i).
% 28.89/28.94  tff(decl_11595, type, reproductive_organ_1: $i > $o).
% 28.89/28.94  tff(decl_11596, type, bag_1: $i > $o).
% 28.89/28.94  tff(decl_11597, type, 'Bag': $i).
% 28.89/28.94  tff(decl_11598, type, balance_equation_1: $i > $o).
% 28.89/28.94  tff(decl_11599, type, 'Balance-Equation': $i).
% 28.89/28.94  tff(decl_11600, type, 'a method to balance equations stoichiometrically': $i).
% 28.89/28.94  tff(decl_11601, type, 'equation of balance': $i).
% 28.89/28.94  tff(decl_11602, type, 'balance equation': $i).
% 28.89/28.94  tff(decl_11603, type, 'balance-equation': $i).
% 28.89/28.94  tff(decl_11604, type, balanced_polymorphism_1: $i > $o).
% 28.89/28.94  tff(decl_11605, type, 'Balanced-Polymorphism': $i).
% 28.89/28.94  tff(decl_11606, type, 'The ability of natural selection to maintain a stable proportion of two or more phenotypes in a population.': $i).
% 28.89/28.94  tff(decl_11607, type, 'balanced polymorphism': $i).
% 28.89/28.94  tff(decl_11608, type, 'balanced-polymorphism': $i).
% 28.89/28.94  tff(decl_11609, type, balancing_selection_1: $i > $o).
% 28.89/28.94  tff(decl_11610, type, 'Balancing-Selection': $i).
% 28.89/28.94  tff(decl_11611, type, 'Natural selection that acts against the mean value of a phenotype and thus maintains two or more phenotypes in a population.': $i).
% 28.89/28.94  tff(decl_11612, type, 'selection of balancing': $i).
% 28.89/28.94  tff(decl_11613, type, 'balancing selection': $i).
% 28.89/28.94  tff(decl_11614, type, 'balancing-selection': $i).
% 28.89/28.94  tff(decl_11615, type, directional_selection_1: $i > $o).
% 28.89/28.94  tff(decl_11616, type, disruptive_selection_1: $i > $o).
% 28.89/28.94  tff(decl_11617, type, baleen_1: $i > $o).
% 28.89/28.94  tff(decl_11618, type, 'Baleen': $i).
% 28.89/28.94  tff(decl_11619, type, 'Comb-like plates on the upper jaws of some whales which strain food (small invertebrates and fish) from the water when the whale feeds.': $i).
% 28.89/28.94  tff(decl_11620, type, baleen: $i).
% 28.89/28.94  tff(decl_11621, type, ball_and_socket_joint_1: $i > $o).
% 28.89/28.94  tff(decl_11622, type, 'Ball-And-Socket-Joint': $i).
% 28.89/28.94  tff(decl_11623, type, 'A skeletal joint consisting of a ball that rotates within the socket of another bone, allowing the limb to move freely in all directions.': $i).
% 28.89/28.94  tff(decl_11624, type, 'ball and socket joint': $i).
% 28.89/28.94  tff(decl_11625, type, 'ball-and-socket-joint': $i).
% 28.89/28.94  tff(decl_11626, type, joint_1: $i > $o).
% 28.89/28.94  tff(decl_11627, type, hinge_joint_1: $i > $o).
% 28.89/28.94  tff(decl_11628, type, pivot_joint_1: $i > $o).
% 28.89/28.94  tff(decl_11629, type, band_pattern_1: $i > $o).
% 28.89/28.94  tff(decl_11630, type, 'Band-Pattern': $i).
% 28.89/28.94  tff(decl_11631, type, 'A parttern of bands formed in agarose gel during electrophoresis.  Each band contains a specific group of DNA fragments common for polaroty, size, and/or wieght.': $i).
% 28.89/28.94  tff(decl_11632, type, 'pattern of band': $i).
% 28.89/28.94  tff(decl_11633, type, 'band pattern': $i).
% 28.89/28.94  tff(decl_11634, type, 'band-pattern': $i).
% 28.89/28.94  tff(decl_11635, type, map_unit_1: $i > $o).
% 28.89/28.94  tff(decl_11636, type, chiasma_1: $i > $o).
% 28.89/28.94  tff(decl_11637, type, distance_between_genes_1: $i > $o).
% 28.89/28.94  tff(decl_11638, type, nicks_in_damaged_dna_1: $i > $o).
% 28.89/28.94  tff(decl_11639, type, replication_fork_1: $i > $o).
% 28.89/28.94  tff(decl_11640, type, thermodynamic_system_1: $i > $o).
% 28.89/28.94  tff(decl_11641, type, fn_band_pattern_1: $i > $i).
% 28.89/28.94  tff(decl_11642, type, dna_piece_1: $i > $o).
% 28.89/28.94  tff(decl_11643, type, fn_band_pattern_2: $i > $i).
% 28.89/28.94  tff(decl_11644, type, restriction_fragment_analysis_1: $i > $o).
% 28.89/28.94  tff(decl_11645, type, fn_band_pattern_3: $i > $i).
% 28.89/28.94  tff(decl_11646, type, detect_1: $i > $o).
% 28.89/28.94  tff(decl_11647, type, fn_band_pattern_4: $i > $i).
% 28.89/28.94  tff(decl_11648, type, gel_electrophoresis_1: $i > $o).
% 28.89/28.94  tff(decl_11649, type, fn_gel_electrophoresis_1: $i > $i).
% 28.89/28.95  tff(decl_11650, type, dna_piece_0: $i).
% 28.89/28.95  tff(decl_11651, type, bandicoot_1: $i > $o).
% 28.89/28.95  tff(decl_11652, type, 'Bandicoot': $i).
% 28.89/28.95  tff(decl_11653, type, 'An small to medium-sized omnivorous Australian marsupial.': $i).
% 28.89/28.95  tff(decl_11654, type, bandicoot: $i).
% 28.89/28.95  tff(decl_11655, type, marsupial_1: $i > $o).
% 28.89/28.95  tff(decl_11656, type, kangaroo_1: $i > $o).
% 28.89/28.95  tff(decl_11657, type, barbiturate_1: $i > $o).
% 28.89/28.95  tff(decl_11658, type, 'Barbiturate': $i).
% 28.89/28.95  tff(decl_11659, type, 'Organic compound having powerful soporific effect. An overdose of this drug can be fatal.': $i).
% 28.89/28.95  tff(decl_11660, type, barbiturate: $i).
% 28.89/28.95  tff(decl_11661, type, chemotherapeutic_drug_1: $i > $o).
% 28.89/28.95  tff(decl_11662, type, 'Barium': $i).
% 28.89/28.95  tff(decl_11663, type, 'Barium is a metal atom with atomic number 56. It is represented by the symbol Ba.': $i).
% 28.89/28.95  tff(decl_11664, type, 'Ba': $i).
% 28.89/28.95  tff(decl_11665, type, cesium_1: $i > $o).
% 28.89/28.95  tff(decl_11666, type, indium_1: $i > $o).
% 28.89/28.95  tff(decl_11667, type, sodium_1: $i > $o).
% 28.89/28.95  tff(decl_11668, type, lead_1: $i > $o).
% 28.89/28.95  tff(decl_11669, type, polonium_1: $i > $o).
% 28.89/28.95  tff(decl_11670, type, fn_barium_1: $i > $i).
% 28.89/28.95  tff(decl_11671, type, fn_barium_2: $i > $i).
% 28.89/28.95  tff(decl_11672, type, fn_barium_3: $i > $i).
% 28.89/28.95  tff(decl_11673, type, fn_barium_4: $i > $i).
% 28.89/28.95  tff(decl_11674, type, fn_barium_10: $i > $i).
% 28.89/28.95  tff(decl_11675, type, fn_barium_11: $i > $i).
% 28.89/28.95  tff(decl_11676, type, fn_barium_12: $i > $i).
% 28.89/28.95  tff(decl_11677, type, fn_barium_13: $i > $i).
% 28.89/28.95  tff(decl_11678, type, fn_barium_14: $i > $i).
% 28.89/28.95  tff(decl_11679, type, "81": $i).
% 28.89/28.95  tff(decl_11680, type, "0.89": $i).
% 28.89/28.95  tff(decl_11681, type, "137": $i).
% 28.89/28.95  tff(decl_11682, type, "137.3": $i).
% 28.89/28.95  tff(decl_11683, type, fn_barium_15: $i > $i).
% 28.89/28.95  tff(decl_11684, type, fn_barium_9: $i > $i).
% 28.89/28.95  tff(decl_11685, type, fn_barium_8: $i > $i).
% 28.89/28.95  tff(decl_11686, type, 'Bark': $i).
% 28.89/28.95  tff(decl_11687, type, 'In a woody plant, all the tissues outside the vascular cambium. Bark consists of layers of periderm (cork) and secondary phloem.': $i).
% 28.89/28.95  tff(decl_11688, type, bark: $i).
% 28.89/28.95  tff(decl_11689, type, barnacle_1: $i > $o).
% 28.89/28.95  tff(decl_11690, type, 'Barnacle': $i).
% 28.89/28.95  tff(decl_11691, type, 'A type of arthropod belonging to the Subphylum Crustacea. Barnacles are sessile and exclusively marine, and tend to live in shallow and tidal waters. Their bodies are encased in a set of calcareous plates from which they extend their feathery thoracic legs for filter-feeding.': $i).
% 28.89/28.95  tff(decl_11692, type, barnacle: $i).
% 28.89/28.95  tff(decl_11693, type, crustacean_1: $i > $o).
% 28.89/28.95  tff(decl_11694, type, clawed_lobster_1: $i > $o).
% 28.89/28.95  tff(decl_11695, type, copepod_1: $i > $o).
% 28.89/28.95  tff(decl_11696, type, crayfish_1: $i > $o).
% 28.89/28.95  tff(decl_11697, type, decapod_1: $i > $o).
% 28.89/28.95  tff(decl_11698, type, isopod_1: $i > $o).
% 28.89/28.95  tff(decl_11699, type, krill_1: $i > $o).
% 28.89/28.95  tff(decl_11700, type, barr_body_1: $i > $o).
% 28.89/28.95  tff(decl_11701, type, 'Barr-Body': $i).
% 28.89/28.95  tff(decl_11702, type, 'A dense object lying along the inside of the nuclear envelope in cells of female mammals, representing a highly condensed, inactivated X chromosome.': $i).
% 28.89/28.95  tff(decl_11703, type, 'inactivated x chromosome': $i).
% 28.89/28.95  tff(decl_11704, type, 'barr body': $i).
% 28.89/28.95  tff(decl_11705, type, 'barr-body': $i).
% 28.89/28.95  tff(decl_11706, type, x_chromosome_1: $i > $o).
% 28.89/28.95  tff(decl_11707, type, x_chromosome_dominant_1: $i > $o).
% 28.89/28.95  tff(decl_11708, type, x_chromosome_recessive_1: $i > $o).
% 28.89/28.95  tff(decl_11709, type, fn_barr_body_1: $i > $i).
% 28.89/28.95  tff(decl_11710, type, fn_barr_body_2: $i > $i).
% 28.89/28.95  tff(decl_11711, type, fn_barr_body_3: $i > $i).
% 28.89/28.95  tff(decl_11712, type, barr_body_formation_1: $i > $o).
% 28.89/28.95  tff(decl_11713, type, fn_barr_body_4: $i > $i).
% 28.89/28.95  tff(decl_11714, type, fn_nucleus_13: $i > $i).
% 28.89/28.95  tff(decl_11715, type, fn_nucleus_6: $i > $i).
% 28.89/28.95  tff(decl_11716, type, 'Barr-Body-Formation': $i).
% 28.89/28.95  tff(decl_11717, type, 'Formation of a Barr-Body from a randomally selected X chromosome.': $i).
% 28.89/28.95  tff(decl_11718, type, 'x inactivation': $i).
% 28.89/28.95  tff(decl_11719, type, 'x-inactivation': $i).
% 28.89/28.95  tff(decl_11720, type, 'x chromosome inactivation': $i).
% 28.89/28.95  tff(decl_11721, type, 'x-chromosome-inactivation': $i).
% 28.89/28.95  tff(decl_11722, type, 'form a barr body': $i).
% 28.89/28.95  tff(decl_11723, type, 'barr body formation': $i).
% 28.89/28.95  tff(decl_11724, type, 'barr-body-formation': $i).
% 28.89/28.95  tff(decl_11725, type, synthesis_of_gamete_1: $i > $o).
% 28.89/28.95  tff(decl_11726, type, synthesis_of_lysosome_1: $i > $o).
% 28.89/28.95  tff(decl_11727, type, fn_barr_body_formation_1: $i > $i).
% 28.89/28.95  tff(decl_11728, type, fn_barr_body_formation_2: $i > $i).
% 28.89/28.95  tff(decl_11729, type, fn_barr_body_formation_3: $i > $i).
% 28.89/28.95  tff(decl_11730, type, fn_barr_body_formation_4: $i > $i).
% 28.89/28.95  tff(decl_11731, type, fn_barr_body_formation_5: $i > $i).
% 28.89/28.95  tff(decl_11732, type, xist_rna_1: $i > $o).
% 28.89/28.95  tff(decl_11733, type, fn_barr_body_formation_6: $i > $i).
% 28.89/28.95  tff(decl_11734, type, fn_barr_body_formation_7: $i > $i).
% 28.89/28.95  tff(decl_11735, type, xist_gene_1: $i > $o).
% 28.89/28.95  tff(decl_11736, type, fn_barr_body_formation_8: $i > $i).
% 28.89/28.95  tff(decl_11737, type, fn_barr_body_formation_9: $i > $i).
% 28.89/28.95  tff(decl_11738, type, fn_barr_body_formation_10: $i > $i).
% 28.89/28.95  tff(decl_11739, type, deactivate_1: $i > $o).
% 28.89/28.95  tff(decl_11740, type, fn_barr_body_formation_11: $i > $i).
% 28.89/28.95  tff(decl_11741, type, choose_at_random_1: $i > $o).
% 28.89/28.95  tff(decl_11742, type, fn_barr_body_formation_12: $i > $i).
% 28.89/28.95  tff(decl_11743, type, female_somatic_cell_1: $i > $o).
% 28.89/28.95  tff(decl_11744, type, fn_xist_gene_1: $i > $i).
% 28.89/28.95  tff(decl_11745, type, fn_xist_gene_2: $i > $i).
% 28.89/28.95  tff(decl_11746, type, fn_xist_rna_13: $i > $i).
% 28.89/28.95  tff(decl_11747, type, fn_xist_rna_14: $i > $i).
% 28.89/28.95  tff(decl_11748, type, fn_dna_methylation_10: $i > $i).
% 28.89/28.95  tff(decl_11749, type, fn_select_1: $i > $i).
% 28.89/28.95  tff(decl_11750, type, fn_xist_rna_15: $i > $i).
% 28.89/28.95  tff(decl_11751, type, fn_xist_rna_11: $i > $i).
% 28.89/28.95  tff(decl_11752, type, x_chromosome_0: $i).
% 28.89/28.95  tff(decl_11753, type, barr_body_mosaic_1: $i > $o).
% 28.89/28.95  tff(decl_11754, type, 'Barr-Body-Mosaic': $i).
% 28.89/28.95  tff(decl_11755, type, 'A female that consists of a mixture of cells each having had different X chromosomes inactivated during Barr-body formation.': $i).
% 28.89/28.95  tff(decl_11756, type, mosaicism: $i).
% 28.89/28.95  tff(decl_11757, type, 'female mosaicism': $i).
% 28.89/28.95  tff(decl_11758, type, 'barr body mosaicism': $i).
% 28.89/28.95  tff(decl_11759, type, 'barr body mosaic': $i).
% 28.89/28.95  tff(decl_11760, type, 'barr-body mosaic': $i).
% 28.89/28.95  tff(decl_11761, type, 'barr-body-mosaic': $i).
% 28.89/28.95  tff(decl_11762, type, fn_barr_body_mosaic_2: $i > $i).
% 28.89/28.95  tff(decl_11763, type, 'Barrier': $i).
% 28.89/28.95  tff(decl_11764, type, barrier: $i).
% 28.89/28.95  tff(decl_11765, type, obstruction: $i).
% 28.89/28.95  tff(decl_11766, type, impediment: $i).
% 28.89/28.95  tff(decl_11767, type, impedimenta: $i).
% 28.89/28.95  tff(decl_11768, type, bartholins_gland_1: $i > $o).
% 28.89/28.95  tff(decl_11769, type, 'Bartholins-Gland': $i).
% 28.89/28.95  tff(decl_11770, type, 'A gland near the vaginal opening that secretes mucus to lubricate the vagina.': $i).
% 28.89/28.95  tff(decl_11771, type, 'bartholins gland': $i).
% 28.89/28.95  tff(decl_11772, type, 'bartholins-gland': $i).
% 28.89/28.95  tff(decl_11773, type, gland_1: $i > $o).
% 28.89/28.95  tff(decl_11774, type, bulbourethral_gland_1: $i > $o).
% 28.89/28.95  tff(decl_11775, type, mammary_glands_1: $i > $o).
% 28.89/28.95  tff(decl_11776, type, prostate_gland_1: $i > $o).
% 28.89/28.95  tff(decl_11777, type, salivary_gland_1: $i > $o).
% 28.89/28.95  tff(decl_11778, type, seminal_vesicle_1: $i > $o).
% 28.89/28.95  tff(decl_11779, type, basal_angiosperm_1: $i > $o).
% 28.89/28.95  tff(decl_11780, type, 'Basal-Angiosperm': $i).
% 28.89/28.95  tff(decl_11781, type, 'One of the first plants to diverge from the earliest angiosperm. Examples include water lilies and star anise.': $i).
% 28.89/28.95  tff(decl_11782, type, 'basal angiosperm': $i).
% 28.89/28.95  tff(decl_11783, type, 'basal-angiosperm': $i).
% 28.89/28.95  tff(decl_11784, type, seedless_vascular_plant_1: $i > $o).
% 28.89/28.95  tff(decl_11785, type, basal_body_1: $i > $o).
% 28.89/28.95  tff(decl_11786, type, 'Basal-Body': $i).
% 28.89/28.95  tff(decl_11787, type, 'It is an organelle formed from centriole. It is found at the base of a eukaryotic cilium or flagellum. It is made up of microtubules arranged in the 9+2 arrangement. Centriole also has microtubules arranged in the same arrangement': $i).
% 28.89/28.95  tff(decl_11788, type, 'basal body': $i).
% 28.89/28.95  tff(decl_11789, type, 'basal-body': $i).
% 28.89/28.95  tff(decl_11790, type, fn_basal_body_1: $i > $i).
% 28.89/28.95  tff(decl_11791, type, periphery_1: $i > $o).
% 28.89/28.95  tff(decl_11792, type, fn_basal_body_2: $i > $i).
% 28.89/28.95  tff(decl_11793, type, fn_basal_body_3: $i > $i).
% 28.89/28.95  tff(decl_11794, type, microtubule_triplet_1: $i > $o).
% 28.89/28.95  tff(decl_11795, type, fn_basal_body_4: $i > $i).
% 28.89/28.95  tff(decl_11796, type, fn_basal_body_5: $i > $i).
% 28.89/28.95  tff(decl_11797, type, molecular_assembly_1: $i > $o).
% 28.89/28.95  tff(decl_11798, type, fn_basal_body_6: $i > $i).
% 28.89/28.95  tff(decl_11799, type, fn_basal_body_7: $i > $i).
% 28.89/28.95  tff(decl_11800, type, fn_basal_body_8: $i > $i).
% 28.89/28.95  tff(decl_11801, type, 'Basal-Nuclei': $i).
% 28.89/28.95  tff(decl_11802, type, 'A cluster of nuclei located in the base of the forebrain, associated with learning and movement.': $i).
% 28.89/28.95  tff(decl_11803, type, 'basal nucleus': $i).
% 28.89/28.95  tff(decl_11804, type, 'basal-nuclei': $i).
% 28.89/28.95  tff(decl_11805, type, base_1: $i > $o).
% 28.89/28.95  tff(decl_11806, type, 'Base': $i).
% 28.89/28.95  tff(decl_11807, type, 'A chemical that is basic.': $i).
% 28.89/28.95  tff(decl_11808, type, 'A substance that decreases the hydrogen ion concentration of a solution.': $i).
% 28.89/28.95  tff(decl_11809, type, base: $i).
% 28.89/28.95  tff(decl_11810, type, fn_base_1: $i > $i).
% 28.89/28.95  tff(decl_11811, type, fn_base_2: $i > $i).
% 28.89/28.95  tff(decl_11812, type, fn_base_5: $i > $i).
% 28.89/28.95  tff(decl_11813, type, 'Base-Compound': $i).
% 28.89/28.95  tff(decl_11814, type, 'Compound with basic properties.': $i).
% 28.89/28.95  tff(decl_11815, type, 'compound of base': $i).
% 28.89/28.95  tff(decl_11816, type, 'base compound': $i).
% 28.89/28.95  tff(decl_11817, type, 'base-compound': $i).
% 28.89/28.95  tff(decl_11818, type, 'Base-Dissociation-Reaction': $i).
% 28.89/28.95  tff(decl_11819, type, 'Dissociation reaction in which the hydroxide and remainder of the base separate.': $i).
% 28.89/28.95  tff(decl_11820, type, 'dissociation of base': $i).
% 28.89/28.95  tff(decl_11821, type, 'base dissociation reaction': $i).
% 28.89/28.95  tff(decl_11822, type, 'base-dissociation-reaction': $i).
% 28.89/28.95  tff(decl_11823, type, fn_base_dissociation_reaction_2: $i > $i).
% 28.89/28.95  tff(decl_11824, type, fn_base_dissociation_reaction_3: $i > $i).
% 28.89/28.95  tff(decl_11825, type, fn_base_dissociation_reaction_4: $i > $i).
% 28.89/28.95  tff(decl_11826, type, fn_base_dissociation_reaction_5: $i > $i).
% 28.89/28.95  tff(decl_11827, type, fn_base_dissociation_reaction_6: $i > $i).
% 28.89/28.95  tff(decl_11828, type, fn_base_dissociation_reaction_7: $i > $i).
% 28.89/28.95  tff(decl_11829, type, fn_base_dissociation_reaction_8: $i > $i).
% 28.89/28.95  tff(decl_11830, type, fn_base_dissociation_reaction_9: $i > $i).
% 28.89/28.95  tff(decl_11831, type, fn_base_dissociation_reaction_10: $i > $i).
% 28.89/28.95  tff(decl_11832, type, fn_base_dissociation_reaction_11: $i > $i).
% 28.89/28.95  tff(decl_11833, type, fn_base_dissociation_reaction_12: $i > $i).
% 28.89/28.95  tff(decl_11834, type, fn_base_dissociation_reaction_13: $i > $i).
% 28.89/28.95  tff(decl_11835, type, fn_base_dissociation_reaction_14: $i > $i).
% 28.89/28.95  tff(decl_11836, type, fn_base_dissociation_reaction_15: $i > $i).
% 28.89/28.95  tff(decl_11837, type, fn_base_dissociation_reaction_16: $i > $i).
% 28.89/28.95  tff(decl_11838, type, fn_base_dissociation_reaction_17: $i > $i).
% 28.89/28.95  tff(decl_11839, type, fn_base_dissociation_reaction_18: $i > $i).
% 28.89/28.95  tff(decl_11840, type, fn_forward_reaction_4: $i > $i).
% 28.89/28.95  tff(decl_11841, type, fn_forward_reaction_3: $i > $i).
% 28.89/28.95  tff(decl_11842, type, fn_forward_reaction_1: $i > $i).
% 28.89/28.95  tff(decl_11843, type, fn_forward_reaction_2: $i > $i).
% 28.89/28.95  tff(decl_11844, type, fn_forward_reaction_7: $i > $i).
% 28.89/28.95  tff(decl_11845, type, fn_forward_reaction_6: $i > $i).
% 28.89/28.95  tff(decl_11846, type, fn_forward_reaction_5: $i > $i).
% 28.89/28.95  tff(decl_11847, type, fn_base_dissociation_reaction_20: $i > $i).
% 28.89/28.95  tff(decl_11848, type, fn_base_dissociation_reaction_19: $i > $i).
% 28.89/28.95  tff(decl_11849, type, fn_base_dissociation_reaction_21: $i > $i).
% 28.89/28.95  tff(decl_11850, type, fn_base_dissociation_reaction_22: $i > $i).
% 28.89/28.95  tff(decl_11851, type, 'Base-Pair': $i).
% 28.89/28.95  tff(decl_11852, type, 'One of the pairs of nucleotide bases (a purine and pyrimidine) on complementary strands of DNA or RNA.': $i).
% 28.89/28.95  tff(decl_11853, type, 'complementary base pair': $i).
% 28.89/28.95  tff(decl_11854, type, 'nucelotide pair': $i).
% 28.89/28.95  tff(decl_11855, type, 'nucelotide-pair': $i).
% 28.89/28.95  tff(decl_11856, type, 'pair of base': $i).
% 28.89/28.95  tff(decl_11857, type, 'base pair': $i).
% 28.89/28.95  tff(decl_11858, type, 'base-pair': $i).
% 28.89/28.95  tff(decl_11859, type, fn_base_pair_1: $i > $i).
% 28.89/28.95  tff(decl_11860, type, fn_base_pair_2: $i > $i).
% 28.89/28.95  tff(decl_11861, type, pyrimidine_0: $i).
% 28.89/28.95  tff(decl_11862, type, purine_0: $i).
% 28.89/28.95  tff(decl_11863, type, base_pair_substitution_1: $i > $o).
% 28.89/28.95  tff(decl_11864, type, 'Base-Pair-Substitution': $i).
% 28.89/28.95  tff(decl_11865, type, 'A change in genetic material in which one nitrogenous base is substituted for another.': $i).
% 28.89/28.95  tff(decl_11866, type, substitute: $i).
% 28.89/28.95  tff(decl_11867, type, 'base pair substitution': $i).
% 28.89/28.95  tff(decl_11868, type, 'base-pair-substitution': $i).
% 28.89/28.95  tff(decl_11869, type, point_mutation_1: $i > $o).
% 28.89/28.95  tff(decl_11870, type, silent_mutation_1: $i > $o).
% 28.89/28.95  tff(decl_11871, type, nitrogenous_base_1: $i > $o).
% 28.89/28.95  tff(decl_11872, type, fn_base_pairing_3: $i > $i).
% 28.89/28.95  tff(decl_11873, type, fn_base_pairing_4: $i > $i).
% 28.89/28.95  tff(decl_11874, type, 'Base-pairing': $i).
% 28.89/28.95  tff(decl_11875, type, 'Base pairing is the process in which nitrogenous bases of complementary strands opposite to each other are joined. It can occur between complementary regions of DNA strands and RNA strands, including DNA to RNA, DNA to DNA, and RNA to RNA.': $i).
% 28.89/28.95  tff(decl_11876, type, pair: $i).
% 28.89/28.95  tff(decl_11877, type, 'pairing of base': $i).
% 28.89/28.95  tff(decl_11878, type, 'base pairing': $i).
% 28.89/28.95  tff(decl_11879, type, 'base-pairing': $i).
% 28.89/28.95  tff(decl_11880, type, fn_base_pairing_2: $i > $i).
% 28.89/28.95  tff(decl_11881, type, fn_base_pairing_5: $i > $i).
% 28.89/28.95  tff(decl_11882, type, base_pairing_between_adenine_and_thymine_1: $i > $o).
% 28.89/28.95  tff(decl_11883, type, fn_base_pairing_between_adenine_and_thymine_3: $i > $i).
% 28.89/28.95  tff(decl_11884, type, fn_base_pairing_between_adenine_and_thymine_2: $i > $i).
% 28.89/28.95  tff(decl_11885, type, 'Base-Pairing-Between-Adenine-And-Thymine': $i).
% 28.89/28.95  tff(decl_11886, type, 'Base pairing occurs between Adenine at one DNA strand and Thymine at comlementary DNA strand. Adenine (A) and Thymine (T) pairing involves 2 hydrogen bonds.': $i).
% 28.89/28.95  tff(decl_11887, type, 'a t base pairing': $i).
% 28.89/28.95  tff(decl_11888, type, 'a-t-base-pairing': $i).
% 28.89/28.95  tff(decl_11889, type, 'base pairing between adenine and thymine': $i).
% 28.89/28.95  tff(decl_11890, type, 'base-pairing-between-adenine-and-thymine': $i).
% 28.89/28.95  tff(decl_11891, type, base_pairing_between_adenine_and_uracil_1: $i > $o).
% 28.89/28.95  tff(decl_11892, type, base_pairing_between_cytosine_and_guanine_1: $i > $o).
% 28.89/28.95  tff(decl_11893, type, uracil_1: $i > $o).
% 28.89/28.95  tff(decl_11894, type, fn_base_pairing_between_adenine_and_uracil_2: $i > $i).
% 28.89/28.95  tff(decl_11895, type, fn_base_pairing_between_adenine_and_uracil_3: $i > $i).
% 28.89/28.95  tff(decl_11896, type, 'Base-Pairing-Between-Adenine-And-Uracil': $i).
% 28.89/28.95  tff(decl_11897, type, 'Base pairing occurs between Adenine and Uracil in RNA. There are 2 hydrogen bonds between Adenine and Uracil': $i).
% 28.89/28.95  tff(decl_11898, type, 'a u base pairing': $i).
% 28.89/28.95  tff(decl_11899, type, 'a-u-base-pairing': $i).
% 28.89/28.95  tff(decl_11900, type, 'base pairing between adenine and uracil': $i).
% 28.89/28.95  tff(decl_11901, type, 'base-pairing-between-adenine-and-uracil': $i).
% 28.89/28.95  tff(decl_11902, type, cytosine_1: $i > $o).
% 28.89/28.95  tff(decl_11903, type, fn_base_pairing_between_cytosine_and_guanine_3: $i > $i).
% 28.89/28.95  tff(decl_11904, type, fn_base_pairing_between_cytosine_and_guanine_2: $i > $i).
% 28.89/28.95  tff(decl_11905, type, 'Base-Pairing-Between-Cytosine-And-Guanine': $i).
% 28.89/28.95  tff(decl_11906, type, 'Base pairing occurs between Guanine present at nucleotides strand and Cytosine present at comlementary nucleotides strand. Guanine(G) and Cytosine (C) pairing involves 3 hydrogen bonds.': $i).
% 28.89/28.95  tff(decl_11907, type, 'c g base pairing': $i).
% 28.89/28.95  tff(decl_11908, type, 'c-g-base-pairing': $i).
% 28.89/28.95  tff(decl_11909, type, 'base pairing between cytosine and guanine': $i).
% 28.89/28.95  tff(decl_11910, type, 'base-pairing-between-cytosine-and-guanine': $i).
% 28.89/28.95  tff(decl_11911, type, fn_guanine_1: $i > $i).
% 28.89/28.95  tff(decl_11912, type, 'Base-Role': $i).
% 28.89/28.95  tff(decl_11913, type, 'role of base': $i).
% 28.89/28.95  tff(decl_11914, type, 'base role': $i).
% 28.89/28.95  tff(decl_11915, type, 'base-role': $i).
% 28.89/28.95  tff(decl_11916, type, basement_membrane_1: $i > $o).
% 28.89/28.95  tff(decl_11917, type, 'Basement-Membrane': $i).
% 28.89/28.95  tff(decl_11918, type, 'A mat of extracellular matrix at the base of epithelial tissue.': $i).
% 28.89/28.95  tff(decl_11919, type, 'membrane of basement': $i).
% 28.89/28.95  tff(decl_11920, type, 'basement membrane': $i).
% 28.89/28.95  tff(decl_11921, type, 'basement-membrane': $i).
% 28.89/28.95  tff(decl_11922, type, middle_lamella_1: $i > $o).
% 28.89/28.95  tff(decl_11923, type, zona_pellucida_1: $i > $o).
% 28.89/28.95  tff(decl_11924, type, 'Basic-Amino-Acid': $i).
% 28.89/28.95  tff(decl_11925, type, 'Amino acids which carry an overall positive charge due to the presence of a positively charged side chain.': $i).
% 28.89/28.95  tff(decl_11926, type, 'cation amino acid': $i).
% 28.89/28.95  tff(decl_11927, type, 'positively charged amino acid': $i).
% 28.89/28.95  tff(decl_11928, type, 'positively charged amino-acid': $i).
% 28.89/28.95  tff(decl_11929, type, 'basic amino acid': $i).
% 28.89/28.95  tff(decl_11930, type, 'basic-amino-acid': $i).
% 28.89/28.95  tff(decl_11931, type, fn_basic_amino_acid_1: $i > $i).
% 28.89/28.95  tff(decl_11932, type, fn_basic_amino_acid_2: $i > $i).
% 28.89/28.95  tff(decl_11933, type, positively_charged_region_1: $i > $o).
% 28.89/28.95  tff(decl_11934, type, fn_basic_amino_acid_6: $i > $i).
% 28.89/28.95  tff(decl_11935, type, fn_basic_amino_acid_7: $i > $i).
% 28.89/28.95  tff(decl_11936, type, fn_basic_amino_acid_8: $i > $i).
% 28.89/28.95  tff(decl_11937, type, fn_basic_amino_acid_9: $i > $i).
% 28.89/28.95  tff(decl_11938, type, fn_basic_amino_acid_10: $i > $i).
% 28.89/28.95  tff(decl_11939, type, fn_basic_amino_acid_11: $i > $i).
% 28.89/28.95  tff(decl_11940, type, fn_basic_amino_acid_12: $i > $i).
% 28.89/28.95  tff(decl_11941, type, fn_basic_amino_acid_13: $i > $i).
% 28.89/28.95  tff(decl_11942, type, fn_basic_amino_acid_14: $i > $i).
% 28.89/28.95  tff(decl_11943, type, fn_basic_amino_acid_15: $i > $i).
% 28.89/28.95  tff(decl_11944, type, fn_basic_amino_acid_16: $i > $i).
% 28.89/28.95  tff(decl_11945, type, fn_basic_amino_acid_17: $i > $i).
% 28.89/28.95  tff(decl_11946, type, fn_basic_amino_acid_18: $i > $i).
% 28.89/28.95  tff(decl_11947, type, fn_basic_amino_acid_19: $i > $i).
% 28.89/28.95  tff(decl_11948, type, fn_basic_amino_acid_20: $i > $i).
% 28.89/28.95  tff(decl_11949, type, fn_basic_amino_acid_21: $i > $i).
% 28.89/28.95  tff(decl_11950, type, fn_basic_amino_acid_22: $i > $i).
% 28.89/28.95  tff(decl_11951, type, fn_basic_amino_acid_23: $i > $i).
% 28.89/28.95  tff(decl_11952, type, fn_basic_amino_acid_24: $i > $i).
% 28.89/28.95  tff(decl_11953, type, fn_basic_amino_acid_25: $i > $i).
% 28.89/28.95  tff(decl_11954, type, fn_basic_amino_acid_26: $i > $i).
% 28.89/28.95  tff(decl_11955, type, fn_basic_amino_acid_27: $i > $i).
% 28.89/28.95  tff(decl_11956, type, fn_basic_amino_acid_28: $i > $i).
% 28.89/28.95  tff(decl_11957, type, fn_basic_amino_acid_29: $i > $i).
% 28.89/28.95  tff(decl_11958, type, fn_basic_amino_acid_30: $i > $i).
% 28.89/28.95  tff(decl_11959, type, fn_basic_amino_acid_31: $i > $i).
% 28.89/28.95  tff(decl_11960, type, fn_basic_amino_acid_32: $i > $i).
% 28.89/28.95  tff(decl_11961, type, fn_basic_amino_acid_33: $i > $i).
% 28.89/28.95  tff(decl_11962, type, fn_basic_amino_acid_34: $i > $i).
% 28.89/28.95  tff(decl_11963, type, fn_basic_amino_acid_35: $i > $i).
% 28.89/28.95  tff(decl_11964, type, fn_basic_amino_acid_36: $i > $i).
% 28.89/28.95  tff(decl_11965, type, fn_basic_amino_acid_37: $i > $i).
% 28.89/28.95  tff(decl_11966, type, fn_basic_amino_acid_38: $i > $i).
% 28.89/28.95  tff(decl_11967, type, fn_basic_amino_acid_39: $i > $i).
% 28.89/28.95  tff(decl_11968, type, fn_basic_amino_acid_40: $i > $i).
% 28.89/28.95  tff(decl_11969, type, fn_basic_amino_acid_41: $i > $i).
% 28.89/28.95  tff(decl_11970, type, fn_basic_amino_acid_42: $i > $i).
% 28.89/28.95  tff(decl_11971, type, fn_basic_amino_acid_43: $i > $i).
% 28.89/28.95  tff(decl_11972, type, fn_basic_amino_acid_44: $i > $i).
% 28.89/28.95  tff(decl_11973, type, fn_basic_amino_acid_45: $i > $i).
% 28.89/28.95  tff(decl_11974, type, fn_basic_amino_acid_46: $i > $i).
% 28.89/28.95  tff(decl_11975, type, fn_basic_amino_acid_47: $i > $i).
% 28.89/28.95  tff(decl_11976, type, fn_basic_amino_acid_3: $i > $i).
% 28.89/28.95  tff(decl_11977, type, fn_basic_amino_acid_5: $i > $i).
% 28.89/28.95  tff(decl_11978, type, fn_basic_amino_acid_4: $i > $i).
% 28.89/28.95  tff(decl_11979, type, basic_solution_1: $i > $o).
% 28.89/28.95  tff(decl_11980, type, 'Basic-Solution': $i).
% 28.89/28.95  tff(decl_11981, type, 'An aqueous solution containing more OH- ions than H+ ions. An aqueous solution with a pH greater than 7.': $i).
% 28.89/28.95  tff(decl_11982, type, 'solution of base': $i).
% 28.89/28.95  tff(decl_11983, type, 'solution of basic': $i).
% 28.89/28.95  tff(decl_11984, type, 'basic solution': $i).
% 28.89/28.95  tff(decl_11985, type, 'basic-solution': $i).
% 28.89/28.95  tff(decl_11986, type, buffered_solution_1: $i > $o).
% 28.89/28.95  tff(decl_11987, type, isotonic_solution_1: $i > $o).
% 28.89/28.95  tff(decl_11988, type, fn_basic_solution_3: $i > $i).
% 28.89/28.95  tff(decl_11989, type, fn_basic_solution_4: $i > $i).
% 28.89/28.95  tff(decl_11990, type, fn_basic_solution_6: $i > $i).
% 28.89/28.95  tff(decl_11991, type, fn_basic_solution_11: $i > $i).
% 28.89/28.95  tff(decl_11992, type, fn_basic_solution_12: $i > $i).
% 28.89/28.95  tff(decl_11993, type, fn_basic_solution_13: $i > $i).
% 28.89/28.95  tff(decl_11994, type, fn_basic_solution_14: $i > $i).
% 28.89/28.95  tff(decl_11995, type, fn_basic_solution_15: $i > $i).
% 28.89/28.95  tff(decl_11996, type, fn_basic_solution_16: $i > $i).
% 28.89/28.95  tff(decl_11997, type, fn_basic_solution_17: $i > $i).
% 28.89/28.95  tff(decl_11998, type, fn_basic_solution_18: $i > $i).
% 28.89/28.95  tff(decl_11999, type, fn_basic_solution_19: $i > $i).
% 28.89/28.95  tff(decl_12000, type, fn_basic_solution_21: $i > $i).
% 28.89/28.95  tff(decl_12001, type, fn_basic_solution_22: $i > $i).
% 28.89/28.95  tff(decl_12002, type, fn_basic_solution_23: $i > $i).
% 28.89/28.95  tff(decl_12003, type, fn_basic_solution_24: $i > $i).
% 28.89/28.95  tff(decl_12004, type, fn_basic_solution_25: $i > $i).
% 28.89/28.95  tff(decl_12005, type, fn_basic_solution_27: $i > $i).
% 28.89/28.95  tff(decl_12006, type, fn_basic_solution_28: $i > $i).
% 28.89/28.95  tff(decl_12007, type, fn_basic_solution_29: $i > $i).
% 28.89/28.95  tff(decl_12008, type, fn_basic_solution_30: $i > $i).
% 28.89/28.95  tff(decl_12009, type, fn_basic_solution_31: $i > $i).
% 28.89/28.95  tff(decl_12010, type, fn_basic_solution_32: $i > $i).
% 28.89/28.95  tff(decl_12011, type, fn_basic_solution_33: $i > $i).
% 28.89/28.95  tff(decl_12012, type, fn_increase_1: $i > $i).
% 28.89/28.95  tff(decl_12013, type, fn_increase_4: $i > $i).
% 28.89/28.95  tff(decl_12014, type, fn_base_dissociation_reaction_1: $i > $i).
% 28.89/28.95  tff(decl_12015, type, fn_basic_solution_20: $i > $i).
% 28.89/28.95  tff(decl_12016, type, fn_basic_solution_10: $i > $i).
% 28.89/28.95  tff(decl_12017, type, fn_basic_solution_9: $i > $i).
% 28.89/28.95  tff(decl_12018, type, fn_basic_solution_7: $i > $i).
% 28.89/28.95  tff(decl_12019, type, fn_basic_solution_26: $i > $i).
% 28.89/28.95  tff(decl_12020, type, fn_basic_solution_8: $i > $i).
% 28.89/28.95  tff(decl_12021, type, basic_solution_of_weak_base_1: $i > $o).
% 28.89/28.95  tff(decl_12022, type, 'Basic-Solution-Of-Weak-Base': $i).
% 28.89/28.95  tff(decl_12023, type, 'A solution that contains a weak base.': $i).
% 28.89/28.95  tff(decl_12024, type, 'solution of weak base': $i).
% 28.89/28.95  tff(decl_12025, type, 'solution-of-weak-base': $i).
% 28.89/28.95  tff(decl_12026, type, 'weak base solution': $i).
% 28.89/28.95  tff(decl_12027, type, 'weak-base-solution': $i).
% 28.89/28.95  tff(decl_12028, type, 'basic solution of weak base': $i).
% 28.89/28.95  tff(decl_12029, type, 'basic-solution-of-weak-base': $i).
% 28.89/28.95  tff(decl_12030, type, fn_basic_solution_of_weak_base_1: $i > $i).
% 28.89/28.95  tff(decl_12031, type, fn_basic_solution_of_weak_base_2: $i > $i).
% 28.89/28.95  tff(decl_12032, type, fn_basic_solution_of_weak_base_3: $i > $i).
% 28.89/28.95  tff(decl_12033, type, fn_basic_solution_of_weak_base_4: $i > $i).
% 28.89/28.95  tff(decl_12034, type, fn_basic_solution_of_weak_base_5: $i > $i).
% 28.89/28.95  tff(decl_12035, type, fn_basic_solution_of_weak_base_6: $i > $i).
% 28.89/28.95  tff(decl_12036, type, fn_basic_solution_of_weak_base_7: $i > $i).
% 28.89/28.95  tff(decl_12037, type, fn_basic_solution_of_weak_base_8: $i > $i).
% 28.89/28.95  tff(decl_12038, type, fn_basic_solution_of_weak_base_9: $i > $i).
% 28.89/28.95  tff(decl_12039, type, fn_basic_solution_of_weak_base_10: $i > $i).
% 28.89/28.95  tff(decl_12040, type, fn_basic_solution_of_weak_base_11: $i > $i).
% 28.89/28.95  tff(decl_12041, type, fn_basic_solution_of_weak_base_12: $i > $i).
% 28.89/28.95  tff(decl_12042, type, fn_basic_solution_of_weak_base_13: $i > $i).
% 28.89/28.95  tff(decl_12043, type, fn_basic_solution_of_weak_base_14: $i > $i).
% 28.89/28.95  tff(decl_12044, type, fn_water_1: $i > $i).
% 28.89/28.95  tff(decl_12045, type, fn_water_2: $i > $i).
% 28.89/28.95  tff(decl_12046, type, fn_basic_solution_of_weak_base_15: $i > $i).
% 28.89/28.95  tff(decl_12047, type, fn_basic_solution_of_weak_base_16: $i > $i).
% 28.89/28.95  tff(decl_12048, type, fn_basic_solution_5: $i > $i).
% 28.89/28.95  tff(decl_12049, type, fn_basic_solution_of_weak_base_17: $i > $i).
% 28.89/28.95  tff(decl_12050, type, fn_basic_solution_of_weak_base_18: $i > $i).
% 28.89/28.95  tff(decl_12051, type, fn_basic_solution_of_weak_base_19: $i > $i).
% 28.89/28.95  tff(decl_12052, type, 'Basidiocarp': $i).
% 28.89/28.95  tff(decl_12053, type, 'The multicellular structure on which spores are produced in the basidiomycete fungi. Mushrooms are basidiocarps.': $i).
% 28.89/28.95  tff(decl_12054, type, basidiocarp: $i).
% 28.89/28.95  tff(decl_12055, type, basidium_1: $i > $o).
% 28.89/28.95  tff(decl_12056, type, 'Basidium': $i).
% 28.89/28.95  tff(decl_12057, type, 'Microscopic spore-producing structure on the gills of a basidiocarp.': $i).
% 28.89/28.95  tff(decl_12058, type, basidia: $i).
% 28.89/28.95  tff(decl_12059, type, basidium: $i).
% 28.89/28.95  tff(decl_12060, type, fungal_appendage_1: $i > $o).
% 28.89/28.95  tff(decl_12061, type, basophil_1: $i > $o).
% 28.89/28.95  tff(decl_12062, type, 'Basophil': $i).
% 28.89/28.95  tff(decl_12063, type, 'A type of white blood cell that produces histamine and the anticoagulant heparin. Basophils participate in several types of inflammation, especially those that involve an allergic response.': $i).
% 28.89/28.95  tff(decl_12064, type, basophil: $i).
% 28.89/28.95  tff(decl_12065, type, leukocyte_1: $i > $o).
% 28.89/28.95  tff(decl_12066, type, bat_1: $i > $o).
% 28.89/28.95  tff(decl_12067, type, 'Bat': $i).
% 28.89/28.95  tff(decl_12068, type, 'Mammal of the order Chiroptera, whose hand forms a webbed wing. Bats are the only mammals capable of sustained flight.': $i).
% 28.89/28.95  tff(decl_12069, type, chiroptera: $i).
% 28.89/28.95  tff(decl_12070, type, bat: $i).
% 28.89/28.95  tff(decl_12071, type, placental_mammal_1: $i > $o).
% 28.89/28.95  tff(decl_12072, type, edentata_1: $i > $o).
% 28.89/28.95  tff(decl_12073, type, elephant_1: $i > $o).
% 28.89/28.95  tff(decl_12074, type, rodent_1: $i > $o).
% 28.89/28.95  tff(decl_12075, type, batesian_mimicry_1: $i > $o).
% 28.89/28.95  tff(decl_12076, type, 'Batesian-Mimicry': $i).
% 28.89/28.95  tff(decl_12077, type, 'A type of mimicry where a harmless species has evolved to resemble another species which is poisonous or otherwise harmful to predators.': $i).
% 28.89/28.95  tff(decl_12078, type, 'batesian mimicry': $i).
% 28.89/28.95  tff(decl_12079, type, 'batesian-mimicry': $i).
% 28.89/28.95  tff(decl_12080, type, mullerian_mimicry_1: $i > $o).
% 28.89/28.95  tff(decl_12081, type, bathroom_1: $i > $o).
% 28.89/28.95  tff(decl_12082, type, 'Bathroom': $i).
% 28.89/28.95  tff(decl_12083, type, bathroom: $i).
% 28.89/28.95  tff(decl_12084, type, bath: $i).
% 28.89/28.95  tff(decl_12085, type, room_1: $i > $o).
% 28.89/28.95  tff(decl_12086, type, hallway_1: $i > $o).
% 28.89/28.95  tff(decl_12087, type, elevator_1: $i > $o).
% 28.89/28.95  tff(decl_12088, type, be_accessible_1: $i > $o).
% 28.89/28.95  tff(decl_12089, type, 'Be-Accessible': $i).
% 28.89/28.95  tff(decl_12090, type, 'be accessible': $i).
% 28.89/28.95  tff(decl_12091, type, 'be-accessible': $i).
% 28.89/28.95  tff(decl_12092, type, fn_be_accessible_1: $i > $i).
% 28.89/28.95  tff(decl_12093, type, be_activated_1: $i > $o).
% 28.89/28.95  tff(decl_12094, type, 'Be-Activated': $i).
% 28.89/28.95  tff(decl_12095, type, activated: $i).
% 28.89/28.95  tff(decl_12096, type, active: $i).
% 28.89/28.95  tff(decl_12097, type, on: $i).
% 28.89/28.95  tff(decl_12098, type, 'be activated': $i).
% 28.89/28.95  tff(decl_12099, type, 'be-activated': $i).
% 28.89/28.95  tff(decl_12100, type, fn_be_activated_1: $i > $i).
% 28.89/28.95  tff(decl_12101, type, be_analogically_related_1: $i > $o).
% 28.89/28.95  tff(decl_12102, type, 'Be-Analogically-Related': $i).
% 28.89/28.95  tff(decl_12103, type, 'analogical relationship': $i).
% 28.89/28.95  tff(decl_12104, type, 'be analogically related': $i).
% 28.89/28.95  tff(decl_12105, type, 'be-analogically-related': $i).
% 28.89/28.95  tff(decl_12106, type, be_attached_to_1: $i > $o).
% 28.89/28.95  tff(decl_12107, type, 'Be-Attached-To': $i).
% 28.89/28.95  tff(decl_12108, type, attached: $i).
% 28.89/28.95  tff(decl_12109, type, 'be attached to': $i).
% 28.89/28.95  tff(decl_12110, type, 'be-attached-to': $i).
% 28.89/28.95  tff(decl_12111, type, be_available_1: $i > $o).
% 28.89/28.95  tff(decl_12112, type, 'Be-Available': $i).
% 28.89/28.95  tff(decl_12113, type, 'be available': $i).
% 28.89/28.95  tff(decl_12114, type, 'be-available': $i).
% 28.89/28.95  tff(decl_12115, type, fn_be_available_1: $i > $i).
% 28.89/28.95  tff(decl_12116, type, be_blocked_1: $i > $o).
% 28.89/28.95  tff(decl_12117, type, 'Be-Blocked': $i).
% 28.89/28.95  tff(decl_12118, type, blocked: $i).
% 28.89/28.95  tff(decl_12119, type, 'out of use': $i).
% 28.89/28.95  tff(decl_12120, type, out_of_use: $i).
% 28.89/28.95  tff(decl_12121, type, plugged: $i).
% 28.89/28.95  tff(decl_12122, type, closed: $i).
% 28.89/28.95  tff(decl_12123, type, 'be blocked': $i).
% 28.89/28.95  tff(decl_12124, type, 'be-blocked': $i).
% 28.89/28.95  tff(decl_12125, type, be_inaccessible_1: $i > $o).
% 28.89/28.95  tff(decl_12126, type, fn_be_blocked_1: $i > $i).
% 28.89/28.95  tff(decl_12127, type, fn_be_inaccessible_1: $i > $i).
% 28.89/28.95  tff(decl_12128, type, be_broken_1: $i > $o).
% 28.89/28.95  tff(decl_12129, type, 'Be-Broken': $i).
% 28.89/28.95  tff(decl_12130, type, broken: $i).
% 28.89/28.95  tff(decl_12131, type, busted: $i).
% 28.89/28.95  tff(decl_12132, type, 'be broken': $i).
% 28.89/28.95  tff(decl_12133, type, 'be-broken': $i).
% 28.89/28.95  tff(decl_12134, type, be_damaged_1: $i > $o).
% 28.89/28.95  tff(decl_12135, type, fn_be_broken_1: $i > $i).
% 28.89/28.95  tff(decl_12136, type, fn_be_damaged_1: $i > $i).
% 28.89/28.95  tff(decl_12137, type, be_closed_1: $i > $o).
% 28.89/28.95  tff(decl_12138, type, 'Be-Closed': $i).
% 28.89/28.95  tff(decl_12139, type, shut: $i).
% 28.89/28.95  tff(decl_12140, type, unopen: $i).
% 28.89/28.95  tff(decl_12141, type, 'be closed': $i).
% 28.89/28.95  tff(decl_12142, type, 'be-closed': $i).
% 28.89/28.95  tff(decl_12143, type, fn_be_closed_1: $i > $i).
% 28.89/28.95  tff(decl_12144, type, fn_be_closed_2: $i > $i).
% 28.89/28.95  tff(decl_12145, type, fn_be_closed_3: $i > $i).
% 28.89/28.95  tff(decl_12146, type, portal_covering_1: $i > $o).
% 28.89/28.95  tff(decl_12147, type, be_concealed_1: $i > $o).
% 28.89/28.95  tff(decl_12148, type, 'Be-Concealed': $i).
% 28.89/28.95  tff(decl_12149, type, concealed: $i).
% 28.89/28.95  tff(decl_12150, type, hidden: $i).
% 28.89/28.95  tff(decl_12151, type, 'out of sight': $i).
% 28.89/28.95  tff(decl_12152, type, out_of_sight: $i).
% 28.89/28.95  tff(decl_12153, type, 'be concealed': $i).
% 28.89/28.95  tff(decl_12154, type, 'be-concealed': $i).
% 28.89/28.95  tff(decl_12155, type, fn_be_concealed_1: $i > $i).
% 28.89/28.95  tff(decl_12156, type, be_confined_1: $i > $o).
% 28.89/28.95  tff(decl_12157, type, 'Be-Confined': $i).
% 28.89/28.95  tff(decl_12158, type, confined: $i).
% 28.89/28.95  tff(decl_12159, type, 'fenced in': $i).
% 28.89/28.95  tff(decl_12160, type, fenced_in: $i).
% 28.89/28.95  tff(decl_12161, type, penned: $i).
% 28.89/28.95  tff(decl_12162, type, 'be confined': $i).
% 28.89/28.95  tff(decl_12163, type, 'be-confined': $i).
% 28.89/28.95  tff(decl_12164, type, be_obstructed_1: $i > $o).
% 28.89/28.95  tff(decl_12165, type, fn_be_confined_1: $i > $i).
% 28.89/28.95  tff(decl_12166, type, fn_be_confined_2: $i > $i).
% 28.89/28.95  tff(decl_12167, type, fn_be_obstructed_1: $i > $i).
% 28.89/28.95  tff(decl_12168, type, 'Be-Contained': $i).
% 28.89/28.95  tff(decl_12169, type, contain: $i).
% 28.89/28.95  tff(decl_12170, type, bear: $i).
% 28.89/28.95  tff(decl_12171, type, carry: $i).
% 28.89/28.95  tff(decl_12172, type, 'be contained': $i).
% 28.89/28.95  tff(decl_12173, type, 'be-contained': $i).
% 28.89/28.95  tff(decl_12174, type, fn_be_contained_1: $i > $i).
% 28.89/28.95  tff(decl_12175, type, fn_be_contained_2: $i > $i).
% 28.89/28.95  tff(decl_12176, type, fn_be_contained_3: $i > $i).
% 28.89/28.95  tff(decl_12177, type, fn_be_contained_4: $i > $i).
% 28.89/28.95  tff(decl_12178, type, be_controlled_1: $i > $o).
% 28.89/28.95  tff(decl_12179, type, 'Be-Controlled': $i).
% 28.89/28.95  tff(decl_12180, type, controlled: $i).
% 28.89/28.95  tff(decl_12181, type, 'be controlled': $i).
% 28.89/28.95  tff(decl_12182, type, 'be-controlled': $i).
% 28.89/28.95  tff(decl_12183, type, fn_be_controlled_1: $i > $i).
% 28.89/28.95  tff(decl_12184, type, 'Be-Damaged': $i).
% 28.89/28.95  tff(decl_12185, type, 'be damaged': $i).
% 28.89/28.95  tff(decl_12186, type, 'be-damaged': $i).
% 28.89/28.95  tff(decl_12187, type, be_defeated_1: $i > $o).
% 28.89/28.95  tff(decl_12188, type, 'Be-Defeated': $i).
% 28.89/28.95  tff(decl_12189, type, lose: $i).
% 28.89/28.95  tff(decl_12190, type, 'defeated of be': $i).
% 28.89/28.95  tff(decl_12191, type, 'be defeated': $i).
% 28.89/28.95  tff(decl_12192, type, 'be-defeated': $i).
% 28.89/28.95  tff(decl_12193, type, fn_be_defeated_1: $i > $i).
% 28.89/28.95  tff(decl_12194, type, fn_be_defeated_2: $i > $i).
% 28.89/28.95  tff(decl_12195, type, contest_1: $i > $o).
% 28.89/28.95  tff(decl_12196, type, fn_be_defeated_3: $i > $i).
% 28.89/28.95  tff(decl_12197, type, loser_1: $i > $o).
% 28.89/28.95  tff(decl_12198, type, be_different_1: $i > $o).
% 28.89/28.95  tff(decl_12199, type, 'Be-Different': $i).
% 28.89/28.95  tff(decl_12200, type, different: $i).
% 28.89/28.95  tff(decl_12201, type, dissimilar: $i).
% 28.89/28.95  tff(decl_12202, type, unalike: $i).
% 28.89/28.95  tff(decl_12203, type, unlike: $i).
% 28.89/28.95  tff(decl_12204, type, 'be different': $i).
% 28.89/28.95  tff(decl_12205, type, 'be-different': $i).
% 28.89/28.95  tff(decl_12206, type, be_energetically_different_1: $i > $o).
% 28.89/28.95  tff(decl_12207, type, 'Be-Energetically-Different': $i).
% 28.89/28.95  tff(decl_12208, type, 'energetic difference': $i).
% 28.89/28.95  tff(decl_12209, type, 'be energetically different': $i).
% 28.89/28.95  tff(decl_12210, type, 'be-energetically-different': $i).
% 28.89/28.95  tff(decl_12211, type, be_energetically_related_1: $i > $o).
% 28.89/28.95  tff(decl_12212, type, 'Be-Energetically-Related': $i).
% 28.89/28.95  tff(decl_12213, type, 'energetic relationship': $i).
% 28.89/28.95  tff(decl_12214, type, 'be energetically related': $i).
% 28.89/28.95  tff(decl_12215, type, 'be-energetically-related': $i).
% 28.89/28.95  tff(decl_12216, type, be_functionally_different_1: $i > $o).
% 28.89/28.95  tff(decl_12217, type, 'Be-Functionally-Different': $i).
% 28.89/28.95  tff(decl_12218, type, 'functional difference': $i).
% 28.89/28.95  tff(decl_12219, type, 'be functionally different': $i).
% 28.89/28.95  tff(decl_12220, type, 'be-functionally-different': $i).
% 28.89/28.95  tff(decl_12221, type, be_functionally_related_1: $i > $o).
% 28.89/28.95  tff(decl_12222, type, 'Be-Functionally-Related': $i).
% 28.89/28.95  tff(decl_12223, type, 'functional relationship': $i).
% 28.89/28.95  tff(decl_12224, type, 'be functionally related': $i).
% 28.89/28.95  tff(decl_12225, type, 'be-functionally-related': $i).
% 28.89/28.95  tff(decl_12226, type, be_functionally_similar_1: $i > $o).
% 28.89/28.95  tff(decl_12227, type, 'Be-Functionally-Similar': $i).
% 28.89/28.95  tff(decl_12228, type, 'functional similarity': $i).
% 28.89/28.95  tff(decl_12229, type, 'be functionally similar': $i).
% 28.89/28.95  tff(decl_12230, type, 'be-functionally-similar': $i).
% 28.89/28.95  tff(decl_12231, type, be_held_1: $i > $o).
% 28.89/28.95  tff(decl_12232, type, 'Be-Held': $i).
% 28.89/28.95  tff(decl_12233, type, held: $i).
% 28.89/28.95  tff(decl_12234, type, 'be held': $i).
% 28.89/28.95  tff(decl_12235, type, 'be-held': $i).
% 28.89/28.95  tff(decl_12236, type, fn_be_held_1: $i > $i).
% 28.89/28.95  tff(decl_12237, type, fn_be_held_2: $i > $i).
% 28.89/28.95  tff(decl_12238, type, be_impacted_1: $i > $o).
% 28.89/28.95  tff(decl_12239, type, 'Be-Impacted': $i).
% 28.89/28.95  tff(decl_12240, type, impact: $i).
% 28.89/28.95  tff(decl_12241, type, 'be impacted': $i).
% 28.89/28.95  tff(decl_12242, type, 'be-impacted': $i).
% 28.89/28.95  tff(decl_12243, type, 'Be-Inaccessible': $i).
% 28.89/28.95  tff(decl_12244, type, 'be inaccessible': $i).
% 28.89/28.95  tff(decl_12245, type, 'be-inaccessible': $i).
% 28.89/28.95  tff(decl_12246, type, be_known_1: $i > $o).
% 28.89/28.95  tff(decl_12247, type, 'Be-Known': $i).
% 28.89/28.95  tff(decl_12248, type, know: $i).
% 28.89/28.95  tff(decl_12249, type, known: $i).
% 28.89/28.95  tff(decl_12250, type, familiar: $i).
% 28.89/28.95  tff(decl_12251, type, conversant: $i).
% 28.89/28.95  tff(decl_12252, type, versed: $i).
% 28.89/28.95  tff(decl_12253, type, knowledgeable: $i).
% 28.89/28.95  tff(decl_12254, type, intimate: $i).
% 28.89/28.95  tff(decl_12255, type, 'intimate with': $i).
% 28.89/28.95  tff(decl_12256, type, intimate_with: $i).
% 28.89/28.95  tff(decl_12257, type, 'knowledgeable about': $i).
% 28.89/28.95  tff(decl_12258, type, knowledgeable_about: $i).
% 28.89/28.95  tff(decl_12259, type, 'be known': $i).
% 28.89/28.95  tff(decl_12260, type, 'be-known': $i).
% 28.89/28.95  tff(decl_12261, type, fn_be_known_1: $i > $i).
% 28.89/28.95  tff(decl_12262, type, fn_be_known_2: $i > $i).
% 28.89/28.95  tff(decl_12263, type, 'Be-Obstructed': $i).
% 28.89/28.95  tff(decl_12264, type, obstructed: $i).
% 28.89/28.95  tff(decl_12265, type, 'be obstructed': $i).
% 28.89/28.95  tff(decl_12266, type, 'be-obstructed': $i).
% 28.89/28.95  tff(decl_12267, type, be_open_1: $i > $o).
% 28.89/28.95  tff(decl_12268, type, 'Be-Open': $i).
% 28.89/28.95  tff(decl_12269, type, open: $i).
% 28.89/28.95  tff(decl_12270, type, unfastened: $i).
% 28.89/28.95  tff(decl_12271, type, opened: $i).
% 28.89/28.95  tff(decl_12272, type, 'open of be': $i).
% 28.89/28.95  tff(decl_12273, type, 'be open': $i).
% 28.89/28.95  tff(decl_12274, type, 'be-open': $i).
% 28.89/28.95  tff(decl_12275, type, be_unblocked_1: $i > $o).
% 28.89/28.95  tff(decl_12276, type, fn_be_open_1: $i > $i).
% 28.89/28.95  tff(decl_12277, type, fn_be_open_2: $i > $i).
% 28.89/28.95  tff(decl_12278, type, portal_1: $i > $o).
% 28.89/28.95  tff(decl_12279, type, fn_conduit_1: $i > $i).
% 28.89/28.95  tff(decl_12280, type, fn_be_unblocked_1: $i > $i).
% 28.89/28.95  tff(decl_12281, type, be_qualitatively_different_1: $i > $o).
% 28.89/28.95  tff(decl_12282, type, 'Be-Qualitatively-Different': $i).
% 28.89/28.95  tff(decl_12283, type, 'qualitative difference': $i).
% 28.89/28.95  tff(decl_12284, type, 'be qualitatively different': $i).
% 28.89/28.95  tff(decl_12285, type, 'be-qualitatively-different': $i).
% 28.89/28.95  tff(decl_12286, type, be_qualitatively_related_1: $i > $o).
% 28.89/28.95  tff(decl_12287, type, 'Be-Qualitatively-Related': $i).
% 28.89/28.95  tff(decl_12288, type, 'qualitative relationship': $i).
% 28.89/28.95  tff(decl_12289, type, 'be qualitatively related': $i).
% 28.89/28.95  tff(decl_12290, type, 'be-qualitatively-related': $i).
% 28.89/28.95  tff(decl_12291, type, be_qualitatively_similar_1: $i > $o).
% 28.89/28.95  tff(decl_12292, type, 'Be-Qualitatively-Similar': $i).
% 28.89/28.95  tff(decl_12293, type, 'qualitative similarity': $i).
% 28.89/28.95  tff(decl_12294, type, 'be qualitatively similar': $i).
% 28.89/28.95  tff(decl_12295, type, 'be-qualitatively-similar': $i).
% 28.89/28.95  tff(decl_12296, type, be_related_1: $i > $o).
% 28.89/28.95  tff(decl_12297, type, 'Be-Related': $i).
% 28.89/28.95  tff(decl_12298, type, relation: $i).
% 28.89/28.95  tff(decl_12299, type, relationship: $i).
% 28.89/28.95  tff(decl_12300, type, 'be related': $i).
% 28.89/28.95  tff(decl_12301, type, 'be-related': $i).
% 28.89/28.95  tff(decl_12302, type, be_restrained_1: $i > $o).
% 28.89/28.95  tff(decl_12303, type, 'Be-Restrained': $i).
% 28.89/28.95  tff(decl_12304, type, restrained: $i).
% 28.89/28.95  tff(decl_12305, type, immobile: $i).
% 28.89/28.95  tff(decl_12306, type, immovable: $i).
% 28.89/28.95  tff(decl_12307, type, immoveable: $i).
% 28.89/28.95  tff(decl_12308, type, stabile: $i).
% 28.89/28.95  tff(decl_12309, type, unmovable: $i).
% 28.89/28.95  tff(decl_12310, type, fixed: $i).
% 28.89/28.95  tff(decl_12311, type, frozen: $i).
% 28.89/28.95  tff(decl_12312, type, 'be restrained': $i).
% 28.89/28.95  tff(decl_12313, type, 'be-restrained': $i).
% 28.89/28.95  tff(decl_12314, type, be_ruined_1: $i > $o).
% 28.89/28.95  tff(decl_12315, type, 'Be-Ruined': $i).
% 28.89/28.95  tff(decl_12316, type, irreparable: $i).
% 28.89/28.95  tff(decl_12317, type, 'be ruined': $i).
% 28.89/28.95  tff(decl_12318, type, 'be-ruined': $i).
% 28.89/28.95  tff(decl_12319, type, fn_be_ruined_1: $i > $i).
% 28.89/28.95  tff(decl_12320, type, be_sf_related_1: $i > $o).
% 28.89/28.95  tff(decl_12321, type, 'Be-SF-Related': $i).
% 28.89/28.95  tff(decl_12322, type, 'structural functional relationship': $i).
% 28.89/28.95  tff(decl_12323, type, 'structural-functional relationship': $i).
% 28.89/28.95  tff(decl_12324, type, 'be sf related': $i).
% 28.89/28.95  tff(decl_12325, type, 'be-sf-related': $i).
% 28.89/28.95  tff(decl_12326, type, be_shut_out_1: $i > $o).
% 28.89/28.95  tff(decl_12327, type, 'Be-Shut-Out': $i).
% 28.89/28.95  tff(decl_12328, type, external: $i).
% 28.89/28.95  tff(decl_12329, type, 'be shut out': $i).
% 28.89/28.95  tff(decl_12330, type, 'be-shut-out': $i).
% 28.89/28.95  tff(decl_12331, type, fn_be_shut_out_1: $i > $i).
% 28.89/28.95  tff(decl_12332, type, fn_be_shut_out_2: $i > $i).
% 28.89/28.95  tff(decl_12333, type, fn_be_shut_out_3: $i > $i).
% 28.89/28.95  tff(decl_12334, type, be_similar_1: $i > $o).
% 28.89/28.95  tff(decl_12335, type, 'Be-Similar': $i).
% 28.89/28.95  tff(decl_12336, type, similar: $i).
% 28.89/28.95  tff(decl_12337, type, alike: $i).
% 28.89/28.95  tff(decl_12338, type, same: $i).
% 28.89/28.95  tff(decl_12339, type, similarity: $i).
% 28.89/28.95  tff(decl_12340, type, like: $i).
% 28.89/28.95  tff(decl_12341, type, 'be similar': $i).
% 28.89/28.95  tff(decl_12342, type, 'be-similar': $i).
% 28.89/28.95  tff(decl_12343, type, be_sitting_1: $i > $o).
% 28.89/28.95  tff(decl_12344, type, 'Be-Sitting': $i).
% 28.89/28.95  tff(decl_12345, type, seated: $i).
% 28.89/28.95  tff(decl_12346, type, sitting: $i).
% 28.89/28.95  tff(decl_12347, type, 'sitting of be': $i).
% 28.89/28.95  tff(decl_12348, type, 'be sitting': $i).
% 28.89/28.95  tff(decl_12349, type, 'be-sitting': $i).
% 28.89/28.95  tff(decl_12350, type, fn_be_sitting_1: $i > $i).
% 28.89/28.95  tff(decl_12351, type, be_stable_1: $i > $o).
% 28.89/28.95  tff(decl_12352, type, 'Be-Stable': $i).
% 28.89/28.95  tff(decl_12353, type, stable: $i).
% 28.89/28.95  tff(decl_12354, type, static: $i).
% 28.89/28.95  tff(decl_12355, type, unchanging: $i).
% 28.89/28.95  tff(decl_12356, type, 'stable of be': $i).
% 28.89/28.95  tff(decl_12357, type, 'be stable': $i).
% 28.89/28.95  tff(decl_12358, type, 'be-stable': $i).
% 28.89/28.95  tff(decl_12359, type, fn_be_stable_1: $i > $i).
% 28.89/28.95  tff(decl_12360, type, be_standing_1: $i > $o).
% 28.89/28.95  tff(decl_12361, type, 'Be-Standing': $i).
% 28.89/28.95  tff(decl_12362, type, standing: $i).
% 28.89/28.95  tff(decl_12363, type, 'standing of be': $i).
% 28.89/28.95  tff(decl_12364, type, 'be standing': $i).
% 28.89/28.95  tff(decl_12365, type, 'be-standing': $i).
% 28.89/28.95  tff(decl_12366, type, fn_be_standing_1: $i > $i).
% 28.89/28.95  tff(decl_12367, type, be_stored_1: $i > $o).
% 28.89/28.95  tff(decl_12368, type, 'Be-Stored': $i).
% 28.89/28.95  tff(decl_12369, type, stored: $i).
% 28.89/28.95  tff(decl_12370, type, 'be stored': $i).
% 28.89/28.95  tff(decl_12371, type, 'be-stored': $i).
% 28.89/28.95  tff(decl_12372, type, fn_be_stored_1: $i > $i).
% 28.89/28.95  tff(decl_12373, type, fn_be_stored_2: $i > $i).
% 28.89/28.95  tff(decl_12374, type, fn_be_stored_3: $i > $i).
% 28.89/28.95  tff(decl_12375, type, be_structurally_different_1: $i > $o).
% 28.89/28.95  tff(decl_12376, type, 'Be-Structurally-Different': $i).
% 28.89/28.95  tff(decl_12377, type, 'structural difference': $i).
% 28.89/28.95  tff(decl_12378, type, 'be structurally different': $i).
% 28.89/28.95  tff(decl_12379, type, 'be-structurally-different': $i).
% 28.89/28.95  tff(decl_12380, type, be_structurally_related_1: $i > $o).
% 28.89/28.95  tff(decl_12381, type, 'Be-Structurally-Related': $i).
% 28.89/28.95  tff(decl_12382, type, 'structural relationship': $i).
% 28.89/28.95  tff(decl_12383, type, 'be structurally related': $i).
% 28.89/28.95  tff(decl_12384, type, 'be-structurally-related': $i).
% 28.89/28.95  tff(decl_12385, type, be_structurally_similar_1: $i > $o).
% 28.89/28.95  tff(decl_12386, type, 'Be-Structurally-Similar': $i).
% 28.89/28.95  tff(decl_12387, type, 'structural similarity': $i).
% 28.89/28.95  tff(decl_12388, type, 'be structurally similar': $i).
% 28.89/28.95  tff(decl_12389, type, 'be-structurally-similar': $i).
% 28.89/28.95  tff(decl_12390, type, be_supported_1: $i > $o).
% 28.89/28.95  tff(decl_12391, type, 'Be-Supported': $i).
% 28.89/28.95  tff(decl_12392, type, supported: $i).
% 28.89/28.95  tff(decl_12393, type, 'be supported': $i).
% 28.89/28.95  tff(decl_12394, type, 'be-supported': $i).
% 28.89/28.95  tff(decl_12395, type, fn_be_supported_1: $i > $i).
% 28.89/28.95  tff(decl_12396, type, 'Be-Touching': $i).
% 28.89/28.95  tff(decl_12397, type, touch: $i).
% 28.89/28.95  tff(decl_12398, type, meet: $i).
% 28.89/28.95  tff(decl_12399, type, adjoin: $i).
% 28.89/28.95  tff(decl_12400, type, contact: $i).
% 28.89/28.95  tff(decl_12401, type, 'touching of be': $i).
% 28.89/28.95  tff(decl_12402, type, 'be touching': $i).
% 28.89/28.95  tff(decl_12403, type, 'be-touching': $i).
% 28.89/28.95  tff(decl_12404, type, be_unavailable_1: $i > $o).
% 28.89/28.95  tff(decl_12405, type, 'Be-Unavailable': $i).
% 28.89/28.95  tff(decl_12406, type, 'be unavailable': $i).
% 28.89/28.95  tff(decl_12407, type, 'be-unavailable': $i).
% 28.89/28.95  tff(decl_12408, type, fn_be_unavailable_1: $i > $i).
% 28.89/28.95  tff(decl_12409, type, 'Be-Unblocked': $i).
% 28.89/28.95  tff(decl_12410, type, patent: $i).
% 28.89/28.95  tff(decl_12411, type, unclogged: $i).
% 28.89/28.95  tff(decl_12412, type, 'be unblocked': $i).
% 28.89/28.95  tff(decl_12413, type, 'be-unblocked': $i).
% 28.89/28.95  tff(decl_12414, type, be_victorious_1: $i > $o).
% 28.89/28.95  tff(decl_12415, type, 'Be-Victorious': $i).
% 28.89/28.95  tff(decl_12416, type, win: $i).
% 28.89/28.95  tff(decl_12417, type, 'be victorious': $i).
% 28.89/28.95  tff(decl_12418, type, 'be-victorious': $i).
% 28.89/28.95  tff(decl_12419, type, fn_be_victorious_1: $i > $i).
% 28.89/28.95  tff(decl_12420, type, fn_be_victorious_2: $i > $i).
% 28.89/28.95  tff(decl_12421, type, fn_be_victorious_3: $i > $i).
% 28.89/28.95  tff(decl_12422, type, winner_1: $i > $o).
% 28.89/28.95  tff(decl_12423, type, bean_1: $i > $o).
% 28.89/28.95  tff(decl_12424, type, 'Bean': $i).
% 28.89/28.95  tff(decl_12425, type, 'Bean is a common name for large plant seeds of several genera of the family Fabaceae (alternately Leguminosae) used for human food or animal feed.': $i).
% 28.89/28.95  tff(decl_12426, type, bean: $i).
% 28.89/28.95  tff(decl_12427, type, seed_1: $i > $o).
% 28.89/28.95  tff(decl_12428, type, bean_plant_1: $i > $o).
% 28.89/28.95  tff(decl_12429, type, 'Bean-Plant': $i).
% 28.89/28.95  tff(decl_12430, type, 'plant of bean': $i).
% 28.89/28.95  tff(decl_12431, type, 'bean plant': $i).
% 28.89/28.95  tff(decl_12432, type, 'bean-plant': $i).
% 28.89/28.95  tff(decl_12433, type, legume_1: $i > $o).
% 28.89/28.95  tff(decl_12434, type, food_plant_1: $i > $o).
% 28.89/28.95  tff(decl_12435, type, fn_bean_plant_1: $i > $i).
% 28.89/28.95  tff(decl_12436, type, environment_1: $i > $o).
% 28.89/28.95  tff(decl_12437, type, fn_bean_plant_2: $i > $i).
% 28.89/28.95  tff(decl_12438, type, fn_bean_plant_3: $i > $i).
% 28.89/28.95  tff(decl_12439, type, 'Bee': $i).
% 28.89/28.95  tff(decl_12440, type, 'Flying insects in the order Hymenoptera, ecologically important for their roles as pollinators and honey producers.': $i).
% 28.89/28.95  tff(decl_12441, type, bee: $i).
% 28.89/28.95  tff(decl_12442, type, beer_1: $i > $o).
% 28.89/28.95  tff(decl_12443, type, 'Beer': $i).
% 28.89/28.95  tff(decl_12444, type, 'Beer is the world\\s most widely consumed and probably the oldest of alcoholic beverages; it is the third most popular drink overall, after water and tea.': $i).
% 28.89/28.95  tff(decl_12445, type, beer: $i).
% 28.89/28.95  tff(decl_12446, type, fn_beer_1: $i > $i).
% 28.89/28.95  tff(decl_12447, type, fn_beer_2: $i > $i).
% 28.89/28.95  tff(decl_12448, type, fn_beer_3: $i > $i).
% 28.89/28.95  tff(decl_12449, type, fn_beer_4: $i > $i).
% 28.89/28.95  tff(decl_12450, type, maltose_1: $i > $o).
% 28.89/28.95  tff(decl_12451, type, fn_beer_5: $i > $i).
% 28.89/28.95  tff(decl_12452, type, fn_beer_6: $i > $i).
% 28.89/28.95  tff(decl_12453, type, fn_beer_7: $i > $i).
% 28.89/28.95  tff(decl_12454, type, 'Beetle': $i).
% 28.89/28.95  tff(decl_12455, type, 'An insect in the order Coleoptera, the largest taxon of animals. Beetles typically have their outer wings modified into hardened shells that cover the more delicate flight wings when the animal is not flying.': $i).
% 28.89/28.95  tff(decl_12456, type, beetle: $i).
% 28.89/28.95  tff(decl_12457, type, coleoptera_1: $i > $o).
% 28.89/28.95  tff(decl_12458, type, behavior_1: $i > $o).
% 28.89/28.95  tff(decl_12459, type, 'Behavior': $i).
% 28.89/28.95  tff(decl_12460, type, 'Within a body, the response of a physiological system under nervous control to a stimulus; likewise, an organism\\s range of actions and mannerisms in response to a stimulus.': $i).
% 28.89/28.95  tff(decl_12461, type, behavior: $i).
% 28.89/28.95  tff(decl_12462, type, behavioral_ecology_1: $i > $o).
% 28.89/28.95  tff(decl_12463, type, 'Behavioral-Ecology': $i).
% 28.89/28.95  tff(decl_12464, type, 'The study of evolutionary and ecological influences on animal behavior.': $i).
% 28.89/28.95  tff(decl_12465, type, 'behavioral ecology': $i).
% 28.89/28.95  tff(decl_12466, type, 'behavioral-ecology': $i).
% 28.89/28.95  tff(decl_12467, type, ecology_1: $i > $o).
% 28.89/28.95  tff(decl_12468, type, benign_tumor_1: $i > $o).
% 28.89/28.95  tff(decl_12469, type, 'Benign-Tumor': $i).
% 28.89/28.95  tff(decl_12470, type, 'A mass of abnormal cells that remains at the site of its origin and thus lacks the ability to metastasize.': $i).
% 28.89/28.95  tff(decl_12471, type, 'benign tumor': $i).
% 28.89/28.95  tff(decl_12472, type, 'benign-tumor': $i).
% 28.89/28.95  tff(decl_12473, type, tumor_1: $i > $o).
% 28.89/28.95  tff(decl_12474, type, fn_benign_tumor_1: $i > $i).
% 28.89/28.95  tff(decl_12475, type, fn_benign_tumor_3: $i > $i).
% 28.89/28.95  tff(decl_12476, type, fn_benign_tumor_4: $i > $i).
% 28.89/28.95  tff(decl_12477, type, harm_0: $i).
% 28.89/28.95  tff(decl_12478, type, benign_tumor_treatment_1: $i > $o).
% 28.89/28.95  tff(decl_12479, type, 'Benign-Tumor-Treatment': $i).
% 28.89/28.95  tff(decl_12480, type, 'A series of medical steps designed to reduce or eliminate the presence of benign tumors.': $i).
% 28.89/28.95  tff(decl_12481, type, 'benign tumor treatment': $i).
% 28.89/28.95  tff(decl_12482, type, 'benign-tumor-treatment': $i).
% 28.89/28.95  tff(decl_12483, type, medical_treatment_of_cancer_1: $i > $o).
% 28.89/28.95  tff(decl_12484, type, fn_benign_tumor_treatment_2: $i > $i).
% 28.89/28.95  tff(decl_12485, type, fn_benign_tumor_treatment_3: $i > $i).
% 28.89/28.95  tff(decl_12486, type, fn_benign_tumor_treatment_4: $i > $i).
% 28.89/28.95  tff(decl_12487, type, fn_benign_tumor_treatment_5: $i > $i).
% 28.89/28.95  tff(decl_12488, type, tumor_0: $i).
% 28.89/28.95  tff(decl_12489, type, 'Benthic-Zone': $i).
% 28.89/28.95  tff(decl_12490, type, 'The bottom surface of a marine or freshwater ecosystem.': $i).
% 28.89/28.95  tff(decl_12491, type, 'benthic zone': $i).
% 28.89/28.95  tff(decl_12492, type, 'benthic-zone': $i).
% 28.89/28.95  tff(decl_12493, type, benthos_1: $i > $o).
% 28.89/28.95  tff(decl_12494, type, 'Benthos': $i).
% 28.89/28.95  tff(decl_12495, type, 'The biological community in the benthic zone of a marine or freshwater ecosystem.': $i).
% 28.89/28.95  tff(decl_12496, type, benthos: $i).
% 28.89/28.95  tff(decl_12497, type, ecological_community_1: $i > $o).
% 28.89/28.95  tff(decl_12498, type, vegetation_1: $i > $o).
% 28.89/28.95  tff(decl_12499, type, 'Benzoate': $i).
% 28.89/28.95  tff(decl_12500, type, 'Anion resulting from the disassociation of Benzoic Acid': $i).
% 28.89/28.95  tff(decl_12501, type, benzoate: $i).
% 28.89/28.95  tff(decl_12502, type, fn_benzoate_1: $i > $i).
% 28.89/28.95  tff(decl_12503, type, "-1": $i).
% 28.89/28.95  tff(decl_12504, type, fn_benzoate_2: $i > $i).
% 28.89/28.95  tff(decl_12505, type, berkelium_1: $i > $o).
% 28.89/28.95  tff(decl_12506, type, 'Berkelium': $i).
% 28.89/28.95  tff(decl_12507, type, 'Berkelium is a metal atom with atomic number 97. It is represented by the symbol Bk.': $i).
% 28.89/28.95  tff(decl_12508, type, berkelium: $i).
% 28.89/28.95  tff(decl_12509, type, bk: $i).
% 28.89/28.95  tff(decl_12510, type, fn_berkelium_3: $i > $i).
% 28.89/28.95  tff(decl_12511, type, fn_berkelium_4: $i > $i).
% 28.89/28.95  tff(decl_12512, type, fn_berkelium_5: $i > $i).
% 28.89/28.95  tff(decl_12513, type, fn_berkelium_9: $i > $i).
% 28.89/28.95  tff(decl_12514, type, fn_berkelium_10: $i > $i).
% 28.89/28.95  tff(decl_12515, type, fn_berkelium_11: $i > $i).
% 28.89/28.95  tff(decl_12516, type, fn_berkelium_12: $i > $i).
% 28.89/28.95  tff(decl_12517, type, "150": $i).
% 28.89/28.95  tff(decl_12518, type, "97": $i).
% 28.89/28.95  tff(decl_12519, type, "11": $i).
% 28.89/28.95  tff(decl_12520, type, "247": $i).
% 28.89/28.95  tff(decl_12521, type, fn_berkelium_7: $i > $i).
% 28.89/28.95  tff(decl_12522, type, fn_berkelium_8: $i > $i).
% 28.89/28.95  tff(decl_12523, type, fn_berkelium_6: $i > $i).
% 28.89/28.95  tff(decl_12524, type, beryllium_1: $i > $o).
% 28.89/28.95  tff(decl_12525, type, 'Beryllium': $i).
% 28.89/28.95  tff(decl_12526, type, 'Beryllium is a metal atom with atomic number 4. It is represented by the symbol Be.': $i).
% 28.89/28.95  tff(decl_12527, type, beryllium: $i).
% 28.89/28.95  tff(decl_12528, type, 'Be': $i).
% 28.89/28.95  tff(decl_12529, type, fn_beryllium_4: $i > $i).
% 28.89/28.95  tff(decl_12530, type, fn_beryllium_5: $i > $i).
% 28.89/28.95  tff(decl_12531, type, fn_beryllium_6: $i > $i).
% 28.89/28.95  tff(decl_12532, type, fn_beryllium_7: $i > $i).
% 28.89/28.95  tff(decl_12533, type, fn_beryllium_11: $i > $i).
% 28.89/28.95  tff(decl_12534, type, fn_beryllium_12: $i > $i).
% 28.89/28.95  tff(decl_12535, type, fn_beryllium_13: $i > $i).
% 28.89/28.95  tff(decl_12536, type, fn_beryllium_14: $i > $i).
% 28.89/28.95  tff(decl_12537, type, "4": $i).
% 28.89/28.95  tff(decl_12538, type, "1.57": $i).
% 28.89/28.95  tff(decl_12539, type, "9.012": $i).
% 28.89/28.95  tff(decl_12540, type, fn_beryllium_9: $i > $i).
% 28.89/28.95  tff(decl_12541, type, fn_beryllium_10: $i > $i).
% 28.89/28.95  tff(decl_12542, type, fn_beryllium_8: $i > $i).
% 28.89/28.95  tff(decl_12543, type, 'Beta-1,4-Linkage': $i).
% 28.89/28.95  tff(decl_12544, type, 'A chemical bond between the number 1 and a number 4 carbon on two adjacent molecules where the oxygen atom from the hydroxyl group of the monosaccharide is above the plane of the molecule.': $i).
% 28.89/28.95  tff(decl_12545, type, 'beta 1,4 linkage': $i).
% 28.89/28.95  tff(decl_12546, type, 'beta-1,4-linkage': $i).
% 28.89/28.95  tff(decl_12547, type, beta_cell_islet_of_langerhans_1: $i > $o).
% 28.89/28.95  tff(decl_12548, type, 'Beta-Cell-Islet-Of-Langerhans': $i).
% 28.89/28.95  tff(decl_12549, type, 'Endocrine cells of the islets of Langerhans in the pancreas, which secrete insulin and thus cause an decrease in blood glucose level.': $i).
% 28.89/28.95  tff(decl_12550, type, 'beta cell': $i).
% 28.89/28.95  tff(decl_12551, type, 'beta-cell': $i).
% 28.89/28.95  tff(decl_12552, type, 'beta cell islet of langerhans': $i).
% 28.89/28.95  tff(decl_12553, type, 'beta cell islet of langerhan': $i).
% 28.89/28.95  tff(decl_12554, type, 'beta-cell-islet-of-langerhan': $i).
% 28.89/28.95  tff(decl_12555, type, 'Beta-Globin': $i).
% 28.89/28.95  tff(decl_12556, type, 'Beta globin (HBB) is a protein that, along with alpha globin (HBA), makes up the most common form of hemoglobin in adult humans. The normal adult hemoglobin tetramer consists of two alpha chains and two beta chains.': $i).
% 28.89/28.95  tff(decl_12557, type, hbb: $i).
% 28.89/28.95  tff(decl_12558, type, 'b globin': $i).
% 28.89/28.95  tff(decl_12559, type, 'b-globin': $i).
% 28.89/28.95  tff(decl_12560, type, 'globin of beta': $i).
% 28.89/28.95  tff(decl_12561, type, 'beta globin': $i).
% 28.89/28.95  tff(decl_12562, type, 'beta-globin': $i).
% 28.89/28.95  tff(decl_12563, type, fn_beta_globin_1: $i > $i).
% 28.89/28.95  tff(decl_12564, type, fn_beta_globin_2: $i > $i).
% 28.89/28.95  tff(decl_12565, type, fn_beta_globin_3: $i > $i).
% 28.89/28.95  tff(decl_12566, type, fn_beta_globin_4: $i > $i).
% 28.89/28.95  tff(decl_12567, type, fn_beta_globin_5: $i > $i).
% 28.89/28.95  tff(decl_12568, type, fn_beta_globin_6: $i > $i).
% 28.89/28.95  tff(decl_12569, type, fn_beta_globin_7: $i > $i).
% 28.89/28.95  tff(decl_12570, type, fn_beta_globin_8: $i > $i).
% 28.89/28.95  tff(decl_12571, type, fn_beta_globin_9: $i > $i).
% 28.89/28.95  tff(decl_12572, type, fn_beta_globin_10: $i > $i).
% 28.89/28.95  tff(decl_12573, type, fn_beta_globin_11: $i > $i).
% 28.89/28.95  tff(decl_12574, type, fn_beta_globin_12: $i > $i).
% 28.89/28.95  tff(decl_12575, type, fn_beta_globin_13: $i > $i).
% 28.89/28.95  tff(decl_12576, type, fn_beta_globin_14: $i > $i).
% 28.89/28.95  tff(decl_12577, type, fn_beta_globin_15: $i > $i).
% 28.89/28.95  tff(decl_12578, type, fn_beta_globin_16: $i > $i).
% 28.89/28.95  tff(decl_12579, type, fn_beta_globin_17: $i > $i).
% 28.89/28.95  tff(decl_12580, type, fn_beta_globin_18: $i > $i).
% 28.89/28.95  tff(decl_12581, type, fn_beta_globin_21: $i > $i).
% 28.89/28.95  tff(decl_12582, type, fn_beta_globin_22: $i > $i).
% 28.89/28.95  tff(decl_12583, type, fn_beta_globin_23: $i > $i).
% 28.89/28.95  tff(decl_12584, type, fn_beta_globin_24: $i > $i).
% 28.89/28.95  tff(decl_12585, type, fn_beta_globin_25: $i > $i).
% 28.89/28.95  tff(decl_12586, type, fn_beta_globin_26: $i > $i).
% 28.89/28.95  tff(decl_12587, type, fn_beta_globin_27: $i > $i).
% 28.89/28.95  tff(decl_12588, type, fn_beta_globin_28: $i > $i).
% 28.89/28.95  tff(decl_12589, type, fn_beta_globin_29: $i > $i).
% 28.89/28.95  tff(decl_12590, type, fn_beta_globin_30: $i > $i).
% 28.89/28.95  tff(decl_12591, type, fn_beta_globin_31: $i > $i).
% 28.89/28.95  tff(decl_12592, type, fn_beta_globin_32: $i > $i).
% 28.89/28.95  tff(decl_12593, type, fn_beta_globin_33: $i > $i).
% 28.89/28.95  tff(decl_12594, type, fn_beta_globin_34: $i > $i).
% 28.89/28.95  tff(decl_12595, type, fn_beta_globin_35: $i > $i).
% 28.89/28.95  tff(decl_12596, type, fn_beta_globin_36: $i > $i).
% 28.89/28.95  tff(decl_12597, type, fn_beta_globin_37: $i > $i).
% 28.89/28.95  tff(decl_12598, type, fn_beta_globin_38: $i > $i).
% 28.89/28.95  tff(decl_12599, type, fn_beta_globin_39: $i > $i).
% 28.89/28.95  tff(decl_12600, type, fn_beta_globin_40: $i > $i).
% 28.89/28.95  tff(decl_12601, type, fn_beta_globin_41: $i > $i).
% 28.89/28.95  tff(decl_12602, type, fn_beta_globin_42: $i > $i).
% 28.89/28.95  tff(decl_12603, type, fn_beta_globin_43: $i > $i).
% 28.89/28.95  tff(decl_12604, type, fn_beta_globin_44: $i > $i).
% 28.89/28.95  tff(decl_12605, type, fn_beta_globin_45: $i > $i).
% 28.89/28.95  tff(decl_12606, type, fn_beta_globin_46: $i > $i).
% 28.89/28.95  tff(decl_12607, type, fn_beta_globin_47: $i > $i).
% 28.89/28.95  tff(decl_12608, type, fn_beta_globin_48: $i > $i).
% 28.89/28.95  tff(decl_12609, type, fn_beta_globin_49: $i > $i).
% 28.89/28.95  tff(decl_12610, type, fn_beta_globin_50: $i > $i).
% 28.89/28.95  tff(decl_12611, type, fn_beta_globin_51: $i > $i).
% 28.89/28.95  tff(decl_12612, type, fn_beta_globin_52: $i > $i).
% 28.89/28.95  tff(decl_12613, type, fn_beta_globin_53: $i > $i).
% 28.89/28.95  tff(decl_12614, type, fn_beta_globin_54: $i > $i).
% 28.89/28.95  tff(decl_12615, type, fn_beta_globin_55: $i > $i).
% 28.89/28.95  tff(decl_12616, type, fn_beta_globin_56: $i > $i).
% 28.89/28.95  tff(decl_12617, type, fn_beta_globin_57: $i > $i).
% 28.89/28.95  tff(decl_12618, type, fn_beta_globin_58: $i > $i).
% 28.89/28.95  tff(decl_12619, type, fn_beta_globin_59: $i > $i).
% 28.89/28.95  tff(decl_12620, type, fn_beta_globin_60: $i > $i).
% 28.89/28.95  tff(decl_12621, type, fn_beta_globin_61: $i > $i).
% 28.89/28.95  tff(decl_12622, type, fn_beta_globin_62: $i > $i).
% 28.89/28.95  tff(decl_12623, type, fn_beta_globin_63: $i > $i).
% 28.89/28.95  tff(decl_12624, type, fn_beta_globin_64: $i > $i).
% 28.89/28.95  tff(decl_12625, type, fn_beta_globin_65: $i > $i).
% 28.89/28.95  tff(decl_12626, type, fn_beta_globin_66: $i > $i).
% 28.89/28.95  tff(decl_12627, type, fn_beta_globin_67: $i > $i).
% 28.89/28.95  tff(decl_12628, type, fn_beta_globin_68: $i > $i).
% 28.89/28.95  tff(decl_12629, type, fn_beta_globin_69: $i > $i).
% 28.89/28.95  tff(decl_12630, type, fn_beta_globin_70: $i > $i).
% 28.89/28.95  tff(decl_12631, type, fn_beta_globin_71: $i > $i).
% 28.89/28.95  tff(decl_12632, type, fn_beta_globin_72: $i > $i).
% 28.89/28.95  tff(decl_12633, type, fn_beta_globin_73: $i > $i).
% 28.89/28.95  tff(decl_12634, type, fn_beta_globin_74: $i > $i).
% 28.89/28.95  tff(decl_12635, type, fn_beta_globin_75: $i > $i).
% 28.89/28.95  tff(decl_12636, type, fn_beta_globin_76: $i > $i).
% 28.89/28.95  tff(decl_12637, type, fn_beta_globin_77: $i > $i).
% 28.89/28.95  tff(decl_12638, type, fn_beta_globin_78: $i > $i).
% 28.89/28.95  tff(decl_12639, type, fn_beta_globin_79: $i > $i).
% 28.89/28.95  tff(decl_12640, type, fn_beta_globin_80: $i > $i).
% 28.89/28.95  tff(decl_12641, type, fn_beta_globin_81: $i > $i).
% 28.89/28.95  tff(decl_12642, type, fn_beta_globin_82: $i > $i).
% 28.89/28.95  tff(decl_12643, type, fn_beta_globin_83: $i > $i).
% 28.89/28.95  tff(decl_12644, type, fn_beta_globin_84: $i > $i).
% 28.89/28.95  tff(decl_12645, type, fn_beta_globin_85: $i > $i).
% 28.89/28.95  tff(decl_12646, type, fn_peptide_bond_49: $i > $i).
% 28.89/28.95  tff(decl_12647, type, fn_peptide_bond_48: $i > $i).
% 28.89/28.95  tff(decl_12648, type, fn_peptide_bond_14: $i > $i).
% 28.89/28.95  tff(decl_12649, type, fn_peptide_bond_37: $i > $i).
% 28.89/28.95  tff(decl_12650, type, fn_peptide_bond_17: $i > $i).
% 28.89/28.95  tff(decl_12651, type, fn_beta_globin_19: $i > $i).
% 28.89/28.95  tff(decl_12652, type, fn_beta_globin_20: $i > $i).
% 28.89/28.95  tff(decl_12653, type, fn_polypeptide_115: $i > $i).
% 28.89/28.95  tff(decl_12654, type, 'Beta-Globin-Ancestral-Gene': $i).
% 28.89/28.95  tff(decl_12655, type, 'beta globin ancestral gene': $i).
% 28.89/28.95  tff(decl_12656, type, 'beta-globin-ancestral-gene': $i).
% 28.89/28.95  tff(decl_12657, type, fn_beta_globin_ancestral_gene_1: $i > $i).
% 28.89/28.95  tff(decl_12658, type, fn_beta_globin_ancestral_gene_2: $i > $i).
% 28.89/28.95  tff(decl_12659, type, beta_globin_gene_1: $i > $o).
% 28.89/28.95  tff(decl_12660, type, 'Beta-Globin-Gene': $i).
% 28.89/28.95  tff(decl_12661, type, 'Beta-Globin gene codes for the beta-globin part of the hemoglobin.': $i).
% 28.89/28.95  tff(decl_12662, type, 'beta globin gene': $i).
% 28.89/28.95  tff(decl_12663, type, 'beta-globin-gene': $i).
% 28.89/28.95  tff(decl_12664, type, fn_beta_globin_gene_1: $i > $i).
% 28.89/28.95  tff(decl_12665, type, fn_beta_globin_gene_2: $i > $i).
% 28.89/28.95  tff(decl_12666, type, fn_beta_globin_gene_3: $i > $i).
% 28.89/28.95  tff(decl_12667, type, fn_beta_globin_gene_4: $i > $i).
% 28.89/28.95  tff(decl_12668, type, fn_immunoglobulin_gene_35: $i > $i).
% 28.89/28.95  tff(decl_12669, type, fn_immunoglobulin_gene_34: $i > $i).
% 28.89/28.95  tff(decl_12670, type, fn_immunoglobulin_gene_28: $i > $i).
% 28.89/28.95  tff(decl_12671, type, beta_globin_pre_mrna_1: $i > $o).
% 28.89/28.95  tff(decl_12672, type, 'Beta-Globin-Pre-mRNA': $i).
% 28.89/28.95  tff(decl_12673, type, 'Beta-Globin pre-mRNA is the primary transcript formed after transcription of beta-globiin gene. This  transcript produces beta-globin polypeptide.': $i).
% 28.89/28.95  tff(decl_12674, type, 'beta globin pre mrna': $i).
% 28.89/28.95  tff(decl_12675, type, 'beta-globin-pre-mrna': $i).
% 28.89/28.95  tff(decl_12676, type, fn_beta_globin_pre_mrna_1: $i > $i).
% 28.89/28.95  tff(decl_12677, type, intron_1: $i > $o).
% 28.89/28.95  tff(decl_12678, type, exon_0: $i).
% 28.89/28.95  tff(decl_12679, type, fn_pre_mrna_6: $i > $i).
% 28.89/28.95  tff(decl_12680, type, 'Beta-Glucose': $i).
% 28.89/28.95  tff(decl_12681, type, 'In beta glucose the -H group of the rightmost Carbon atom (C1) is below the plane of the ring.': $i).
% 28.89/28.95  tff(decl_12682, type, 'glucose of beta': $i).
% 28.89/28.95  tff(decl_12683, type, 'beta glucose': $i).
% 28.89/28.95  tff(decl_12684, type, 'beta-glucose': $i).
% 28.89/28.95  tff(decl_12685, type, fn_beta_glucose_1: $i > $i).
% 28.89/28.95  tff(decl_12686, type, fn_beta_glucose_3: $i > $i).
% 28.89/28.95  tff(decl_12687, type, beta_oxidation_1: $i > $o).
% 28.89/28.95  tff(decl_12688, type, 'Beta-Oxidation': $i).
% 28.89/28.95  tff(decl_12689, type, 'Beta oxidation is the process by which fatty acids, in the form of Acyl-CoA molecules, are broken down in mitochondria and/or in peroxisomes to generate Acetyl-CoA, the entry molecule for the Citric Acid cycle.': $i).
% 28.89/28.95  tff(decl_12690, type, 'undergo beta oxidation': $i).
% 28.89/28.95  tff(decl_12691, type, 'undergo beta-oxidation': $i).
% 28.89/28.95  tff(decl_12692, type, 'oxidation of beta': $i).
% 28.89/28.95  tff(decl_12693, type, 'beta oxidation': $i).
% 28.89/28.95  tff(decl_12694, type, 'beta-oxidation': $i).
% 28.89/28.95  tff(decl_12695, type, fn_beta_oxidation_1: $i > $i).
% 28.89/28.95  tff(decl_12696, type, fn_beta_oxidation_4: $i > $i).
% 28.89/28.95  tff(decl_12697, type, fn_beta_oxidation_5: $i > $i).
% 28.89/28.95  tff(decl_12698, type, fn_beta_oxidation_6: $i > $i).
% 28.89/28.95  tff(decl_12699, type, fn_beta_oxidation_7: $i > $i).
% 28.89/28.95  tff(decl_12700, type, hydrocarbon_chain_1: $i > $o).
% 28.89/28.95  tff(decl_12701, type, fn_beta_oxidation_8: $i > $i).
% 28.89/28.95  tff(decl_12702, type, fn_beta_oxidation_9: $i > $i).
% 28.89/28.95  tff(decl_12703, type, fn_beta_oxidation_10: $i > $i).
% 28.89/28.95  tff(decl_12704, type, fn_fatty_acid_29: $i > $i).
% 28.89/28.95  tff(decl_12705, type, fn_beta_oxidation_2: $i > $i).
% 28.89/28.95  tff(decl_12706, type, fn_beta_oxidation_3: $i > $i).
% 28.89/28.95  tff(decl_12707, type, beta_sheet_1: $i > $o).
% 28.89/28.95  tff(decl_12708, type, 'Beta-Sheet': $i).
% 28.89/28.95  tff(decl_12709, type, 'One form of the secondary structure of proteins in which the polypeptide chain folds back and forth.  Two or more strands of the polypeptide chain lie side by side or parallel to each other (called beta strands) and are held together by hydrogen bonds between atoms of the polypeptide backbone (not the side chains).': $i).
% 28.89/28.95  tff(decl_12710, type, 'beta pleated sheet': $i).
% 28.89/28.95  tff(decl_12711, type, 'beta-pleated-sheet': $i).
% 28.89/28.95  tff(decl_12712, type, 'sheet of beta': $i).
% 28.89/28.95  tff(decl_12713, type, 'beta sheet': $i).
% 28.89/28.95  tff(decl_12714, type, 'beta-sheet': $i).
% 28.89/28.95  tff(decl_12715, type, beta_tubulin_1: $i > $o).
% 28.89/28.95  tff(decl_12716, type, 'Beta-Tubulin': $i).
% 28.89/28.95  tff(decl_12717, type, 'tubulin of beta': $i).
% 28.89/28.95  tff(decl_12718, type, 'beta tubulin': $i).
% 28.89/28.95  tff(decl_12719, type, 'beta-tubulin': $i).
% 28.89/28.95  tff(decl_12720, type, fn_beta_tubulin_4: $i > $i).
% 28.89/28.95  tff(decl_12721, type, fn_beta_tubulin_6: $i > $i).
% 28.89/28.95  tff(decl_12722, type, fn_beta_tubulin_7: $i > $i).
% 28.89/28.95  tff(decl_12723, type, fn_beta_tubulin_8: $i > $i).
% 28.89/28.95  tff(decl_12724, type, fn_beta_tubulin_9: $i > $i).
% 28.89/28.95  tff(decl_12725, type, fn_beta_tubulin_10: $i > $i).
% 28.89/28.95  tff(decl_12726, type, fn_beta_tubulin_11: $i > $i).
% 28.89/28.95  tff(decl_12727, type, fn_beta_tubulin_12: $i > $i).
% 28.89/28.95  tff(decl_12728, type, fn_beta_tubulin_13: $i > $i).
% 28.89/28.95  tff(decl_12729, type, fn_beta_tubulin_14: $i > $i).
% 28.89/28.95  tff(decl_12730, type, fn_beta_tubulin_15: $i > $i).
% 28.89/28.95  tff(decl_12731, type, fn_beta_tubulin_16: $i > $i).
% 28.89/28.95  tff(decl_12732, type, fn_beta_tubulin_17: $i > $i).
% 28.89/28.95  tff(decl_12733, type, fn_beta_tubulin_18: $i > $i).
% 28.89/28.95  tff(decl_12734, type, fn_beta_tubulin_19: $i > $i).
% 28.89/28.95  tff(decl_12735, type, fn_beta_tubulin_20: $i > $i).
% 28.89/28.95  tff(decl_12736, type, fn_beta_tubulin_25: $i > $i).
% 28.89/28.95  tff(decl_12737, type, fn_beta_tubulin_26: $i > $i).
% 28.89/28.95  tff(decl_12738, type, fn_beta_tubulin_27: $i > $i).
% 28.89/28.95  tff(decl_12739, type, fn_beta_tubulin_28: $i > $i).
% 28.89/28.95  tff(decl_12740, type, fn_beta_tubulin_29: $i > $i).
% 28.89/28.95  tff(decl_12741, type, fn_beta_tubulin_30: $i > $i).
% 28.89/28.95  tff(decl_12742, type, fn_beta_tubulin_31: $i > $i).
% 28.89/28.95  tff(decl_12743, type, fn_beta_tubulin_32: $i > $i).
% 28.89/28.95  tff(decl_12744, type, fn_beta_tubulin_33: $i > $i).
% 28.89/28.95  tff(decl_12745, type, fn_beta_tubulin_34: $i > $i).
% 28.89/28.95  tff(decl_12746, type, fn_beta_tubulin_35: $i > $i).
% 28.89/28.95  tff(decl_12747, type, fn_beta_tubulin_36: $i > $i).
% 28.89/28.95  tff(decl_12748, type, fn_beta_tubulin_37: $i > $i).
% 28.89/28.95  tff(decl_12749, type, fn_beta_tubulin_38: $i > $i).
% 28.89/28.95  tff(decl_12750, type, fn_beta_tubulin_39: $i > $i).
% 28.89/28.95  tff(decl_12751, type, fn_beta_tubulin_40: $i > $i).
% 28.89/28.95  tff(decl_12752, type, fn_beta_tubulin_41: $i > $i).
% 28.89/28.95  tff(decl_12753, type, fn_beta_tubulin_42: $i > $i).
% 28.89/28.95  tff(decl_12754, type, fn_beta_tubulin_43: $i > $i).
% 28.89/28.95  tff(decl_12755, type, fn_beta_tubulin_44: $i > $i).
% 28.89/28.95  tff(decl_12756, type, fn_beta_tubulin_45: $i > $i).
% 28.89/28.95  tff(decl_12757, type, fn_beta_tubulin_46: $i > $i).
% 28.89/28.95  tff(decl_12758, type, fn_beta_tubulin_47: $i > $i).
% 28.89/28.95  tff(decl_12759, type, fn_beta_tubulin_48: $i > $i).
% 28.89/28.95  tff(decl_12760, type, fn_beta_tubulin_49: $i > $i).
% 28.89/28.95  tff(decl_12761, type, fn_beta_tubulin_50: $i > $i).
% 28.89/28.95  tff(decl_12762, type, fn_beta_tubulin_51: $i > $i).
% 28.89/28.95  tff(decl_12763, type, fn_beta_tubulin_52: $i > $i).
% 28.89/28.95  tff(decl_12764, type, fn_beta_tubulin_53: $i > $i).
% 28.89/28.95  tff(decl_12765, type, fn_beta_tubulin_54: $i > $i).
% 28.89/28.95  tff(decl_12766, type, fn_beta_tubulin_55: $i > $i).
% 28.89/28.95  tff(decl_12767, type, fn_beta_tubulin_56: $i > $i).
% 28.89/28.95  tff(decl_12768, type, fn_beta_tubulin_57: $i > $i).
% 28.89/28.95  tff(decl_12769, type, fn_beta_tubulin_58: $i > $i).
% 28.89/28.95  tff(decl_12770, type, fn_beta_tubulin_59: $i > $i).
% 28.89/28.95  tff(decl_12771, type, fn_beta_tubulin_60: $i > $i).
% 28.89/28.95  tff(decl_12772, type, fn_beta_tubulin_61: $i > $i).
% 28.89/28.95  tff(decl_12773, type, fn_beta_tubulin_62: $i > $i).
% 28.89/28.95  tff(decl_12774, type, fn_beta_tubulin_63: $i > $i).
% 28.89/28.95  tff(decl_12775, type, fn_beta_tubulin_64: $i > $i).
% 28.89/28.95  tff(decl_12776, type, fn_beta_tubulin_65: $i > $i).
% 28.89/28.95  tff(decl_12777, type, fn_beta_tubulin_66: $i > $i).
% 28.89/28.95  tff(decl_12778, type, fn_beta_tubulin_67: $i > $i).
% 28.89/28.95  tff(decl_12779, type, fn_beta_tubulin_68: $i > $i).
% 28.89/28.95  tff(decl_12780, type, fn_beta_tubulin_69: $i > $i).
% 28.89/28.95  tff(decl_12781, type, fn_beta_tubulin_70: $i > $i).
% 28.89/28.95  tff(decl_12782, type, fn_beta_tubulin_71: $i > $i).
% 28.89/28.95  tff(decl_12783, type, fn_beta_tubulin_72: $i > $i).
% 28.89/28.95  tff(decl_12784, type, fn_beta_tubulin_73: $i > $i).
% 28.89/28.95  tff(decl_12785, type, fn_beta_tubulin_74: $i > $i).
% 28.89/28.95  tff(decl_12786, type, fn_beta_tubulin_75: $i > $i).
% 28.89/28.95  tff(decl_12787, type, fn_beta_tubulin_76: $i > $i).
% 28.89/28.95  tff(decl_12788, type, fn_beta_tubulin_77: $i > $i).
% 28.89/28.95  tff(decl_12789, type, fn_beta_tubulin_78: $i > $i).
% 28.89/28.95  tff(decl_12790, type, fn_beta_tubulin_79: $i > $i).
% 28.89/28.95  tff(decl_12791, type, fn_beta_tubulin_80: $i > $i).
% 28.89/28.95  tff(decl_12792, type, fn_beta_tubulin_81: $i > $i).
% 28.89/28.95  tff(decl_12793, type, fn_beta_tubulin_82: $i > $i).
% 28.89/28.95  tff(decl_12794, type, fn_beta_tubulin_83: $i > $i).
% 28.89/28.95  tff(decl_12795, type, fn_beta_tubulin_84: $i > $i).
% 28.89/28.95  tff(decl_12796, type, fn_beta_tubulin_85: $i > $i).
% 28.89/28.95  tff(decl_12797, type, fn_beta_tubulin_86: $i > $i).
% 28.89/28.95  tff(decl_12798, type, fn_beta_tubulin_87: $i > $i).
% 28.89/28.95  tff(decl_12799, type, fn_beta_tubulin_88: $i > $i).
% 28.89/28.95  tff(decl_12800, type, fn_beta_tubulin_89: $i > $i).
% 28.89/28.95  tff(decl_12801, type, fn_tubulin_19: $i > $i).
% 28.89/28.95  tff(decl_12802, type, fn_hydrogen_21: $i > $i).
% 28.89/28.95  tff(decl_12803, type, fn_beta_tubulin_23: $i > $i).
% 28.89/28.95  tff(decl_12804, type, fn_beta_tubulin_24: $i > $i).
% 28.89/28.95  tff(decl_12805, type, fn_beta_tubulin_22: $i > $i).
% 28.89/28.95  tff(decl_12806, type, fn_beta_tubulin_21: $i > $i).
% 28.89/28.95  tff(decl_12807, type, fn_polypeptide_22: $i > $i).
% 28.89/28.95  tff(decl_12808, type, fn_polypeptide_16: $i > $i).
% 28.89/28.95  tff(decl_12809, type, fn_polypeptide_19: $i > $i).
% 28.89/28.95  tff(decl_12810, type, fn_polypeptide_18: $i > $i).
% 28.89/28.95  tff(decl_12811, type, fn_polypeptide_24: $i > $i).
% 28.89/28.95  tff(decl_12812, type, fn_polypeptide_23: $i > $i).
% 28.89/28.95  tff(decl_12813, type, fn_beta_tubulin_91: $i > $i).
% 28.89/28.95  tff(decl_12814, type, fn_beta_tubulin_90: $i > $i).
% 28.89/28.95  tff(decl_12815, type, beta2_adrenergic_receptor_1: $i > $o).
% 28.89/28.95  tff(decl_12816, type, 'Beta2-Adrenergic-Receptor': $i).
% 28.89/28.95  tff(decl_12817, type, 'Receptor that plays a role in G-protein signal transduction pathways.': $i).
% 28.89/28.95  tff(decl_12818, type, 'beta2 adrenergic receptor': $i).
% 28.89/28.95  tff(decl_12819, type, 'beta2-adrenergic-receptor': $i).
% 28.89/28.95  tff(decl_12820, type, g_protein_coupled_receptor_1: $i > $o).
% 28.89/28.95  tff(decl_12821, type, 'Bicarbonate-Ion': $i).
% 28.89/28.95  tff(decl_12822, type, 'HCO3- that is used in biological systems as a buffer and neutralizes acids.': $i).
% 28.89/28.95  tff(decl_12823, type, 'ion of bicarbonate': $i).
% 28.89/28.95  tff(decl_12824, type, 'bicarbonate ion': $i).
% 28.89/28.95  tff(decl_12825, type, 'bicarbonate-ion': $i).
% 28.89/28.95  tff(decl_12826, type, fn_bicarbonate_ion_1: $i > $i).
% 28.89/28.95  tff(decl_12827, type, fn_bicarbonate_ion_2: $i > $i).
% 28.89/28.95  tff(decl_12828, type, fn_bicarbonate_ion_3: $i > $i).
% 28.89/28.95  tff(decl_12829, type, oxygen_0: $i).
% 28.89/28.95  tff(decl_12830, type, bicoid_1: $i > $o).
% 28.89/28.95  tff(decl_12831, type, 'Bicoid': $i).
% 28.89/28.95  tff(decl_12832, type, 'A maternal effect gene that is important for patterning the anterior end of Drosophila.': $i).
% 28.89/28.95  tff(decl_12833, type, bicoid: $i).
% 28.89/28.95  tff(decl_12834, type, maternal_effect_gene_1: $i > $o).
% 28.89/28.95  tff(decl_12835, type, bicoid_gene_1: $i > $o).
% 28.89/28.95  tff(decl_12836, type, 'Bicoid-Gene': $i).
% 28.89/28.95  tff(decl_12837, type, 'A kind of maternal-effect gene (as in bicoid gene) whose function is to code for products used for establishing the normal patterning of anterior parts (head and thorax) of the embryo.': $i).
% 28.89/28.95  tff(decl_12838, type, 'gene of bicoid': $i).
% 28.89/28.95  tff(decl_12839, type, 'bicoid gene': $i).
% 28.89/28.95  tff(decl_12840, type, 'bicoid-gene': $i).
% 28.89/28.95  tff(decl_12841, type, bicoid_gene_mutation_1: $i > $o).
% 28.89/28.95  tff(decl_12842, type, 'Bicoid-Gene-Mutation': $i).
% 28.89/28.95  tff(decl_12843, type, 'The mutation of bicoid gene.': $i).
% 28.89/28.95  tff(decl_12844, type, mutate: $i).
% 28.89/28.95  tff(decl_12845, type, 'bicoid gene mutation': $i).
% 28.89/28.95  tff(decl_12846, type, 'bicoid-gene-mutation': $i).
% 28.89/28.95  tff(decl_12847, type, maternal_effect_gene_mutation_1: $i > $o).
% 28.89/28.95  tff(decl_12848, type, fn_bicoid_gene_mutation_1: $i > $i).
% 28.89/28.95  tff(decl_12849, type, fn_bicoid_gene_mutation_2: $i > $i).
% 28.89/28.95  tff(decl_12850, type, stop_1: $i > $o).
% 28.89/28.95  tff(decl_12851, type, fn_bicoid_gene_mutation_3: $i > $i).
% 28.89/28.95  tff(decl_12852, type, fn_bicoid_gene_mutation_4: $i > $i).
% 28.89/28.95  tff(decl_12853, type, fn_bicoid_gene_mutation_5: $i > $i).
% 28.89/28.95  tff(decl_12854, type, fn_bicoid_gene_mutation_6: $i > $i).
% 28.89/28.95  tff(decl_12855, type, fn_bicoid_gene_mutation_7: $i > $i).
% 28.89/28.95  tff(decl_12856, type, fn_bicoid_gene_mutation_8: $i > $i).
% 28.89/28.95  tff(decl_12857, type, posterior_structure_1: $i > $o).
% 28.89/28.95  tff(decl_12858, type, fn_bicoid_gene_mutation_9: $i > $i).
% 28.89/28.95  tff(decl_12859, type, fn_bicoid_gene_mutation_10: $i > $i).
% 28.89/28.95  tff(decl_12860, type, fn_posterior_structure_2: $i > $i).
% 28.89/28.95  tff(decl_12861, type, posterior_structure_0: $i).
% 28.89/28.95  tff(decl_12862, type, fn_maternal_effect_gene_mutation_3: $i > $i).
% 28.89/28.95  tff(decl_12863, type, bicoid_mrna_1: $i > $o).
% 28.89/28.95  tff(decl_12864, type, 'Bicoid-mRNA': $i).
% 28.89/28.95  tff(decl_12865, type, 'The mRNA formed from the transcription of bicoid gene.': $i).
% 28.89/28.95  tff(decl_12866, type, 'mrna of bicoid': $i).
% 28.89/28.95  tff(decl_12867, type, 'bicoid mrna': $i).
% 28.89/28.95  tff(decl_12868, type, 'bicoid-mrna': $i).
% 28.89/28.95  tff(decl_12869, type, prokaryotic_mrna_1: $i > $o).
% 28.89/28.95  tff(decl_12870, type, fn_bicoid_mrna_1: $i > $i).
% 28.89/28.95  tff(decl_12871, type, fn_bicoid_mrna_2: $i > $i).
% 28.89/28.95  tff(decl_12872, type, fn_bicoid_mrna_4: $i > $i).
% 28.89/28.95  tff(decl_12873, type, synthesis_of_mrna_1: $i > $o).
% 28.89/28.95  tff(decl_12874, type, fn_bicoid_mrna_5: $i > $i).
% 28.89/28.95  tff(decl_12875, type, fn_bicoid_mrna_6: $i > $i).
% 28.89/28.95  tff(decl_12876, type, fn_bicoid_mrna_7: $i > $i).
% 28.89/28.95  tff(decl_12877, type, egg_1: $i > $o).
% 28.89/28.95  tff(decl_12878, type, fn_bicoid_mrna_8: $i > $i).
% 28.89/28.95  tff(decl_12879, type, fn_bicoid_mrna_9: $i > $i).
% 28.89/28.95  tff(decl_12880, type, fn_bicoid_mrna_10: $i > $i).
% 28.89/28.95  tff(decl_12881, type, bicoid_protein_1: $i > $o).
% 28.89/28.95  tff(decl_12882, type, fn_egg_2: $i > $i).
% 28.89/28.95  tff(decl_12883, type, fn_synthesis_of_protein_13: $i > $i).
% 28.89/28.95  tff(decl_12884, type, fn_synthesis_of_protein_16: $i > $i).
% 28.89/28.95  tff(decl_12885, type, fn_synthesis_of_rna_8: $i > $i).
% 28.89/28.95  tff(decl_12886, type, rna_1: $i > $o).
% 28.89/28.95  tff(decl_12887, type, fn_translation_7: $i > $i).
% 28.89/28.95  tff(decl_12888, type, fn_synthesis_of_mrna_3: $i > $i).
% 28.89/28.95  tff(decl_12889, type, 'Bicoid-Protein': $i).
% 28.89/28.95  tff(decl_12890, type, 'A protein from from translation of bicoid mRNA.': $i).
% 28.89/28.95  tff(decl_12891, type, 'protein of bicoid': $i).
% 28.89/28.95  tff(decl_12892, type, 'bicoid protein': $i).
% 28.89/28.95  tff(decl_12893, type, 'bicoid-protein': $i).
% 28.89/28.95  tff(decl_12894, type, fn_bicoid_protein_1: $i > $i).
% 28.89/28.95  tff(decl_12895, type, fn_morphogen_1: $i > $i).
% 28.89/28.95  tff(decl_12896, type, bicoid_protein_hypothesis_1: $i > $o).
% 28.89/28.95  tff(decl_12897, type, 'Bicoid-Protein-Hypothesis': $i).
% 28.89/28.95  tff(decl_12898, type, 'The bicoid protein is responsible for specifying the drosophila\\s anterior end according to Bicoid Protein hypothesis.': $i).
% 28.89/28.95  tff(decl_12899, type, 'bicoid protein hypothesis': $i).
% 28.89/28.95  tff(decl_12900, type, 'bicoid-protein-hypothesis': $i).
% 28.89/28.95  tff(decl_12901, type, hypothesis_1: $i > $o).
% 28.89/28.95  tff(decl_12902, type, individualistic_hypothesis_1: $i > $o).
% 28.89/28.95  tff(decl_12903, type, interactive_hypothesis_1: $i > $o).
% 28.89/28.95  tff(decl_12904, type, practice_hypothesis_of_play_1: $i > $o).
% 28.89/28.95  tff(decl_12905, type, snowball_earth_hypothesis_1: $i > $o).
% 28.89/28.95  tff(decl_12906, type, fn_bicoid_protein_hypothesis_1: $i > $i).
% 28.89/28.95  tff(decl_12907, type, fn_bicoid_protein_hypothesis_2: $i > $i).
% 28.89/28.95  tff(decl_12908, type, fruit_fly_1: $i > $o).
% 28.89/28.95  tff(decl_12909, type, fn_bicoid_protein_hypothesis_3: $i > $i).
% 28.89/28.95  tff(decl_12910, type, fn_bicoid_protein_hypothesis_4: $i > $i).
% 28.89/28.95  tff(decl_12911, type, 'Bicoid-Protein-Hypothesis-Experiment': $i).
% 28.89/28.95  tff(decl_12912, type, 'The experiment conducted to show bicoid protein is responsible for specifying the drosophila\\s anterior end according to Bicoid Protein hypothesis.': $i).
% 28.89/28.95  tff(decl_12913, type, 'bicoid protein hypothesis experiment': $i).
% 28.89/28.95  tff(decl_12914, type, 'bicoid-protein-hypothesis-experiment': $i).
% 28.89/28.95  tff(decl_12915, type, fn_bicoid_protein_hypothesis_experiment_1: $i > $i).
% 28.89/28.95  tff(decl_12916, type, fn_bicoid_protein_hypothesis_experiment_2: $i > $i).
% 28.89/28.95  tff(decl_12917, type, fn_bicoid_protein_hypothesis_experiment_3: $i > $i).
% 28.89/28.95  tff(decl_12918, type, fn_bicoid_protein_hypothesis_experiment_4: $i > $i).
% 28.89/28.95  tff(decl_12919, type, fn_bicoid_protein_hypothesis_experiment_5: $i > $i).
% 28.89/28.95  tff(decl_12920, type, fn_bicoid_protein_hypothesis_experiment_6: $i > $i).
% 28.89/28.95  tff(decl_12921, type, fn_bicoid_protein_hypothesis_experiment_7: $i > $i).
% 28.89/28.95  tff(decl_12922, type, inject_1: $i > $o).
% 28.89/28.95  tff(decl_12923, type, fn_bicoid_protein_hypothesis_experiment_8: $i > $i).
% 28.89/28.95  tff(decl_12924, type, fn_bicoid_protein_hypothesis_experiment_9: $i > $i).
% 28.89/28.95  tff(decl_12925, type, fn_bicoid_protein_hypothesis_experiment_10: $i > $i).
% 28.89/28.95  tff(decl_12926, type, fn_bicoid_protein_hypothesis_experiment_11: $i > $i).
% 28.89/28.95  tff(decl_12927, type, fn_bicoid_protein_hypothesis_experiment_12: $i > $i).
% 28.89/28.95  tff(decl_12928, type, site_0: $i).
% 28.89/28.95  tff(decl_12929, type, spatial_entity_0: $i).
% 28.89/28.95  tff(decl_12930, type, biennial_1: $i > $o).
% 28.89/28.95  tff(decl_12931, type, 'Biennial': $i).
% 28.89/28.95  tff(decl_12932, type, 'A flowering plant that requires two years to complete its life cycle.': $i).
% 28.89/28.95  tff(decl_12933, type, 'biennial plant': $i).
% 28.89/28.95  tff(decl_12934, type, biennial: $i).
% 28.89/28.95  tff(decl_12935, type, big_node_1: $i > $o).
% 28.89/28.95  tff(decl_12936, type, 'Big-Node': $i).
% 28.89/28.95  tff(decl_12937, type, 'big node': $i).
% 28.89/28.95  tff(decl_12938, type, 'big-node': $i).
% 28.89/28.95  tff(decl_12939, type, 'Bilaterally-Symmetrical-Animal': $i).
% 28.89/28.95  tff(decl_12940, type, 'An animal with bilateral body symmetry is called a bilaterally symmetrical animal.': $i).
% 28.89/28.95  tff(decl_12941, type, 'bilaterally symmetrical animal': $i).
% 28.89/28.95  tff(decl_12942, type, 'bilaterally-symmetrical-animal': $i).
% 28.89/28.95  tff(decl_12943, type, fn_bilaterally_symmetrical_animal_1: $i > $i).
% 28.89/28.95  tff(decl_12944, type, fn_bilaterally_symmetrical_animal_2: $i > $i).
% 28.89/28.95  tff(decl_12945, type, bilaterian_1: $i > $o).
% 28.89/28.95  tff(decl_12946, type, 'Bilaterian': $i).
% 28.89/28.95  tff(decl_12947, type, 'Member of a clade of animals with bilateral symmetry and three germ layers.': $i).
% 28.89/28.95  tff(decl_12948, type, bilaterian: $i).
% 28.89/28.95  tff(decl_12949, type, eumetazoan_1: $i > $o).
% 28.89/28.95  tff(decl_12950, type, chordate_1: $i > $o).
% 28.89/28.95  tff(decl_12951, type, invertebrate_1: $i > $o).
% 28.89/28.95  tff(decl_12952, type, radiata_1: $i > $o).
% 28.89/28.95  tff(decl_12953, type, triploblastic_1: $i > $o).
% 28.89/28.95  tff(decl_12954, type, 'Bile': $i).
% 28.89/28.95  tff(decl_12955, type, 'A bitter-tasting mixture of substances produced by the liver and stored in the gallbladder. Bile is secreted into the small intestine to aid in the digestion of fats.': $i).
% 28.89/28.95  tff(decl_12956, type, bile: $i).
% 28.89/28.95  tff(decl_12957, type, digestive_fluid_1: $i > $o).
% 28.89/28.95  tff(decl_12958, type, fn_bile_1: $i > $i).
% 28.89/28.95  tff(decl_12959, type, bile_salt_1: $i > $o).
% 28.89/28.95  tff(decl_12960, type, fn_bile_2: $i > $i).
% 28.89/28.95  tff(decl_12961, type, fn_bile_3: $i > $i).
% 28.89/28.95  tff(decl_12962, type, emulsifier_1: $i > $o).
% 28.89/28.95  tff(decl_12963, type, 'Bile-Salt': $i).
% 28.89/28.95  tff(decl_12964, type, 'Emulsifying agents present in bile which aid in digestion and absorption of lipids.': $i).
% 28.89/28.95  tff(decl_12965, type, 'salt of bile': $i).
% 28.89/28.95  tff(decl_12966, type, 'bile salt': $i).
% 28.89/28.95  tff(decl_12967, type, 'bile-salt': $i).
% 28.89/28.95  tff(decl_12968, type, binary_fission_1: $i > $o).
% 28.89/28.95  tff(decl_12969, type, 'Binary-Fission': $i).
% 28.89/28.95  tff(decl_12970, type, 'Binary fission is the form of asexual reproduction and cell division used by all prokaryotes, some protozoa, and some organelles within eukaryotic organisms. It results in the production of two identical daughter cells.': $i).
% 28.89/28.95  tff(decl_12971, type, 'undergo binary fission': $i).
% 28.89/28.95  tff(decl_12972, type, 'fission of binary': $i).
% 28.89/28.95  tff(decl_12973, type, 'binary fission': $i).
% 28.89/28.95  tff(decl_12974, type, 'binary-fission': $i).
% 28.89/28.95  tff(decl_12975, type, fn_binary_fission_2: $i > $i).
% 28.89/28.95  tff(decl_12976, type, fn_binary_fission_4: $i > $i).
% 28.89/28.95  tff(decl_12977, type, fn_binary_fission_5: $i > $i).
% 28.89/28.95  tff(decl_12978, type, fn_binary_fission_6: $i > $i).
% 28.89/28.95  tff(decl_12979, type, fn_binary_fission_7: $i > $i).
% 28.89/28.95  tff(decl_12980, type, fn_binary_fission_8: $i > $i).
% 28.89/28.95  tff(decl_12981, type, fn_binary_fission_9: $i > $i).
% 28.89/28.95  tff(decl_12982, type, fn_binary_fission_10: $i > $i).
% 28.89/28.95  tff(decl_12983, type, fn_binary_fission_11: $i > $i).
% 28.89/28.95  tff(decl_12984, type, fn_binary_fission_13: $i > $i).
% 28.89/28.95  tff(decl_12985, type, divide_1: $i > $o).
% 28.89/28.95  tff(decl_12986, type, fn_binary_fission_14: $i > $i).
% 28.89/28.95  tff(decl_12987, type, fn_binary_fission_15: $i > $i).
% 28.89/28.95  tff(decl_12988, type, fn_binary_fission_16: $i > $i).
% 28.89/28.95  tff(decl_12989, type, fn_binary_fission_17: $i > $i).
% 28.89/28.95  tff(decl_12990, type, fn_binary_fission_18: $i > $i).
% 28.89/28.95  tff(decl_12991, type, fn_binary_fission_19: $i > $i).
% 28.89/28.95  tff(decl_12992, type, fn_binary_fission_20: $i > $i).
% 28.89/28.95  tff(decl_12993, type, fn_binary_fission_21: $i > $i).
% 28.89/28.95  tff(decl_12994, type, fn_binary_fission_22: $i > $i).
% 28.89/28.95  tff(decl_12995, type, fn_binary_fission_23: $i > $i).
% 28.89/28.95  tff(decl_12996, type, fn_binary_fission_24: $i > $i).
% 28.89/28.95  tff(decl_12997, type, daughter_cell_1: $i > $o).
% 28.89/28.95  tff(decl_12998, type, fn_binary_fission_25: $i > $i).
% 28.89/28.95  tff(decl_12999, type, parent_cell_1: $i > $o).
% 28.89/28.95  tff(decl_13000, type, fn_cell_growth_1: $i > $i).
% 28.89/28.95  tff(decl_13001, type, size_obj: $i).
% 28.89/28.95  tff(decl_13002, type, fn_cell_division_5: $i > $i).
% 28.89/28.95  tff(decl_13003, type, fn_cell_division_6: $i > $i).
% 28.89/28.95  tff(decl_13004, type, fn_binary_fission_26: $i > $i).
% 28.89/28.95  tff(decl_13005, type, fn_binary_fission_28: $i > $i).
% 28.89/28.95  tff(decl_13006, type, fn_binary_fission_12: $i > $i).
% 28.89/28.95  tff(decl_13007, type, fn_binary_fission_27: $i > $i).
% 28.89/28.95  tff(decl_13008, type, binary_fission_in_amoeba_1: $i > $o).
% 28.89/28.95  tff(decl_13009, type, 'Binary-Fission-In-Amoeba': $i).
% 28.89/28.95  tff(decl_13010, type, 'Type of cellular division in amoebas which produces two identical daughter cells.': $i).
% 28.89/28.95  tff(decl_13011, type, 'binary fission in amoeba': $i).
% 28.89/28.95  tff(decl_13012, type, 'binary-fission-in-amoeba': $i).
% 28.89/28.95  tff(decl_13013, type, fn_binary_fission_in_amoeba_1: $i > $i).
% 28.89/28.95  tff(decl_13014, type, prophase_1: $i > $o).
% 28.89/28.95  tff(decl_13015, type, fn_binary_fission_in_amoeba_2: $i > $i).
% 28.89/28.95  tff(decl_13016, type, fn_binary_fission_in_amoeba_3: $i > $i).
% 28.89/28.95  tff(decl_13017, type, fn_binary_fission_in_amoeba_4: $i > $i).
% 28.89/28.95  tff(decl_13018, type, fn_binary_fission_in_amoeba_5: $i > $i).
% 28.89/28.95  tff(decl_13019, type, fn_binary_fission_in_amoeba_10: $i > $i).
% 28.89/28.95  tff(decl_13020, type, fn_binary_fission_in_amoeba_11: $i > $i).
% 28.89/28.95  tff(decl_13021, type, fn_binary_fission_in_amoeba_12: $i > $i).
% 28.89/28.95  tff(decl_13022, type, fn_binary_fission_in_amoeba_13: $i > $i).
% 28.89/28.95  tff(decl_13023, type, fn_binary_fission_in_amoeba_14: $i > $i).
% 28.89/28.95  tff(decl_13024, type, fn_binary_fission_in_amoeba_15: $i > $i).
% 28.89/28.95  tff(decl_13025, type, fn_binary_fission_in_amoeba_16: $i > $i).
% 28.89/28.95  tff(decl_13026, type, fn_binary_fission_in_amoeba_17: $i > $i).
% 28.89/28.95  tff(decl_13027, type, fn_binary_fission_in_amoeba_18: $i > $i).
% 28.89/28.95  tff(decl_13028, type, fn_binary_fission_in_amoeba_19: $i > $i).
% 28.89/28.95  tff(decl_13029, type, fn_binary_fission_in_amoeba_20: $i > $i).
% 28.89/28.95  tff(decl_13030, type, fn_binary_fission_in_amoeba_21: $i > $i).
% 28.89/28.95  tff(decl_13031, type, fn_binary_fission_in_amoeba_22: $i > $i).
% 28.89/28.95  tff(decl_13032, type, fn_binary_fission_in_amoeba_23: $i > $i).
% 28.89/28.95  tff(decl_13033, type, fn_binary_fission_in_amoeba_24: $i > $i).
% 28.89/28.95  tff(decl_13034, type, fn_binary_fission_in_amoeba_25: $i > $i).
% 28.89/28.95  tff(decl_13035, type, fn_binary_fission_in_amoeba_26: $i > $i).
% 28.89/28.95  tff(decl_13036, type, fn_binary_fission_in_amoeba_27: $i > $i).
% 28.89/28.95  tff(decl_13037, type, fn_binary_fission_in_amoeba_28: $i > $i).
% 28.89/28.95  tff(decl_13038, type, fn_binary_fission_in_amoeba_29: $i > $i).
% 28.89/28.95  tff(decl_13039, type, fn_binary_fission_in_amoeba_30: $i > $i).
% 28.89/28.95  tff(decl_13040, type, fn_binary_fission_in_amoeba_31: $i > $i).
% 28.89/28.95  tff(decl_13041, type, fn_binary_fission_in_amoeba_32: $i > $i).
% 28.89/28.95  tff(decl_13042, type, fn_binary_fission_in_amoeba_33: $i > $i).
% 28.89/28.95  tff(decl_13043, type, fn_binary_fission_in_amoeba_34: $i > $i).
% 28.89/28.95  tff(decl_13044, type, fn_binary_fission_in_amoeba_35: $i > $i).
% 28.89/28.95  tff(decl_13045, type, fn_binary_fission_in_amoeba_36: $i > $i).
% 28.89/28.95  tff(decl_13046, type, fn_mitosis_45: $i > $i).
% 28.89/28.95  tff(decl_13047, type, fn_mitosis_35: $i > $i).
% 28.89/28.95  tff(decl_13048, type, fn_mitosis_34: $i > $i).
% 28.89/28.95  tff(decl_13049, type, fn_mitosis_32: $i > $i).
% 28.89/28.95  tff(decl_13050, type, fn_protist_cell_30: $i > $i).
% 28.89/28.95  tff(decl_13051, type, fn_mitosis_3: $i > $i).
% 28.89/28.95  tff(decl_13052, type, fn_peroxisome_40: $i > $i).
% 28.89/28.95  tff(decl_13053, type, fn_mitosis_33: $i > $i).
% 28.89/28.95  tff(decl_13054, type, fn_mitosis_31: $i > $i).
% 28.89/28.95  tff(decl_13055, type, amoeba_0: $i).
% 28.89/28.95  tff(decl_13056, type, fn_binary_fission_in_amoeba_9: $i > $i).
% 28.89/28.95  tff(decl_13057, type, fn_binary_fission_in_amoeba_7: $i > $i).
% 28.89/28.95  tff(decl_13058, type, fn_binary_fission_in_amoeba_6: $i > $i).
% 28.89/28.95  tff(decl_13059, type, fn_binary_fission_in_amoeba_8: $i > $i).
% 28.89/28.95  tff(decl_13060, type, binary_fission_in_prokaryote_1: $i > $o).
% 28.89/28.95  tff(decl_13061, type, 'Binary-Fission-In-Prokaryote': $i).
% 28.89/28.95  tff(decl_13062, type, 'Binary fission is the form of asexual reproduction and cell division used by all prokaryotes. It results in the production of two identical prokaryote daughter cells.': $i).
% 28.89/28.95  tff(decl_13063, type, 'binary fission in prokaryote': $i).
% 28.89/28.95  tff(decl_13064, type, 'binary-fission-in-prokaryote': $i).
% 28.89/28.95  tff(decl_13065, type, fn_binary_fission_in_prokaryote_1: $i > $i).
% 28.89/28.95  tff(decl_13066, type, dna_replication_in_prokaryotes_1: $i > $o).
% 28.89/28.95  tff(decl_13067, type, fn_binary_fission_in_prokaryote_2: $i > $i).
% 28.89/28.95  tff(decl_13068, type, fn_binary_fission_in_prokaryote_3: $i > $i).
% 28.89/28.95  tff(decl_13069, type, fn_binary_fission_in_prokaryote_4: $i > $i).
% 28.89/28.95  tff(decl_13070, type, fn_binary_fission_in_prokaryote_5: $i > $i).
% 28.89/28.95  tff(decl_13071, type, fn_binary_fission_in_prokaryote_6: $i > $i).
% 28.89/28.95  tff(decl_13072, type, fn_binary_fission_in_prokaryote_7: $i > $i).
% 28.89/28.95  tff(decl_13073, type, fn_binary_fission_in_prokaryote_8: $i > $i).
% 28.89/28.95  tff(decl_13074, type, fn_binary_fission_in_prokaryote_9: $i > $i).
% 28.89/28.95  tff(decl_13075, type, fn_binary_fission_in_prokaryote_10: $i > $i).
% 28.89/28.95  tff(decl_13076, type, 'Binding-Site': $i).
% 28.89/28.95  tff(decl_13077, type, 'In biochemistry, a binding site is a region on a protein, DNA, or RNA to which specific other molecules and ions form a bond.': $i).
% 28.89/28.95  tff(decl_13078, type, 'site of binding': $i).
% 28.89/28.95  tff(decl_13079, type, 'binding site': $i).
% 28.89/28.95  tff(decl_13080, type, 'binding-site': $i).
% 28.89/28.95  tff(decl_13081, type, binomial_nomenclature_1: $i > $o).
% 28.89/28.95  tff(decl_13082, type, 'Binomial-Nomenclature': $i).
% 28.89/28.95  tff(decl_13083, type, 'The formal system of assigning two-part names to biological organisms. Each name consists of a genus and a species epithet. For example, Homo sapiens is the scientific name for humans.': $i).
% 28.89/28.95  tff(decl_13084, type, 'scientific name': $i).
% 28.89/28.95  tff(decl_13085, type, 'scientific-name': $i).
% 28.89/28.95  tff(decl_13086, type, 'nomenclature of binomial': $i).
% 28.89/28.95  tff(decl_13087, type, 'binomial nomenclature': $i).
% 28.89/28.95  tff(decl_13088, type, 'binomial-nomenclature': $i).
% 28.89/28.95  tff(decl_13089, type, taxonomy_1: $i > $o).
% 28.89/28.95  tff(decl_13090, type, branch_point_1: $i > $o).
% 28.89/28.95  tff(decl_13091, type, cladistics_1: $i > $o).
% 28.89/28.95  tff(decl_13092, type, deep_green_1: $i > $o).
% 28.89/28.95  tff(decl_13093, type, molecular_systematics_1: $i > $o).
% 28.89/28.95  tff(decl_13094, type, paraphyletic_1: $i > $o).
% 28.89/28.95  tff(decl_13095, type, phylocode_1: $i > $o).
% 28.89/28.95  tff(decl_13096, type, phylogenetic_bracketing_1: $i > $o).
% 28.89/28.95  tff(decl_13097, type, phylogeny_1: $i > $o).
% 28.89/28.95  tff(decl_13098, type, 'Biochemical-Change': $i).
% 28.89/28.95  tff(decl_13099, type, 'A change at the molecular, atomic or subcellular level in an organism.': $i).
% 28.89/28.95  tff(decl_13100, type, 'biochemical change': $i).
% 28.89/28.95  tff(decl_13101, type, 'biochemical-change': $i).
% 28.89/28.95  tff(decl_13102, type, biochemical_model_1: $i > $o).
% 28.89/28.95  tff(decl_13103, type, 'Biochemical-Model': $i).
% 28.89/28.95  tff(decl_13104, type, 'A model representating an biochemical theory or process.': $i).
% 28.89/28.95  tff(decl_13105, type, 'biochemical model': $i).
% 28.89/28.95  tff(decl_13106, type, 'biochemical-model': $i).
% 28.89/28.95  tff(decl_13107, type, model_1: $i > $o).
% 28.89/28.95  tff(decl_13108, type, biodiesel_production_1: $i > $o).
% 28.89/28.95  tff(decl_13109, type, 'Biodiesel-Production': $i).
% 28.89/28.95  tff(decl_13110, type, 'In biodiesel production, plants and algae utilize light energy to produce oils which serve as replacements or supplements for fossil fuels.': $i).
% 28.89/28.95  tff(decl_13111, type, produce: $i).
% 28.89/28.95  tff(decl_13112, type, 'biodiesel production': $i).
% 28.89/28.95  tff(decl_13113, type, 'biodiesel-production': $i).
% 28.89/28.95  tff(decl_13114, type, biofuel_production_1: $i > $o).
% 28.89/28.95  tff(decl_13115, type, fn_biodiesel_production_1: $i > $i).
% 28.89/28.95  tff(decl_13116, type, fn_biodiesel_production_2: $i > $i).
% 28.89/28.95  tff(decl_13117, type, fn_biodiesel_production_3: $i > $i).
% 28.89/28.95  tff(decl_13118, type, fn_biodiesel_production_4: $i > $i).
% 28.89/28.95  tff(decl_13119, type, fn_biodiesel_production_5: $i > $i).
% 28.89/28.95  tff(decl_13120, type, fn_biodiesel_production_6: $i > $i).
% 28.89/28.95  tff(decl_13121, type, fn_biodiesel_production_7: $i > $i).
% 28.89/28.95  tff(decl_13122, type, c4_photosynthesis_1: $i > $o).
% 28.89/28.95  tff(decl_13123, type, fn_biodiesel_production_8: $i > $i).
% 28.89/28.95  tff(decl_13124, type, oil_1: $i > $o).
% 28.89/28.95  tff(decl_13125, type, fn_biodiesel_production_9: $i > $i).
% 28.89/28.95  tff(decl_13126, type, fn_biodiesel_production_10: $i > $i).
% 28.89/28.95  tff(decl_13127, type, fn_biofuel_production_18: $i > $i).
% 28.89/28.95  tff(decl_13128, type, fn_biofuel_production_17: $i > $i).
% 28.89/28.95  tff(decl_13129, type, fn_biofuel_production_27: $i > $i).
% 28.89/28.95  tff(decl_13130, type, biodiversity_hot_spot_1: $i > $o).
% 28.89/28.95  tff(decl_13131, type, 'Biodiversity-Hot-Spot': $i).
% 28.89/28.95  tff(decl_13132, type, 'A relatively small area with an unusually high concentration of endemic species, many of which are endangered or otherwise threatened by human actions.': $i).
% 28.89/28.95  tff(decl_13133, type, 'biodiversity hot spot': $i).
% 28.89/28.95  tff(decl_13134, type, 'biodiversity hot-spot': $i).
% 28.89/28.95  tff(decl_13135, type, 'biodiversity-hot-spot': $i).
% 28.89/28.95  tff(decl_13136, type, ecological_region_1: $i > $o).
% 28.89/28.95  tff(decl_13137, type, bioenergetics_1: $i > $o).
% 28.89/28.95  tff(decl_13138, type, 'Bioenergetics': $i).
% 28.89/28.95  tff(decl_13139, type, 'Bioenergetics represents the processes whereby living matter obtains, stores, and uses energy for various purposes.': $i).
% 28.89/28.95  tff(decl_13140, type, 'analyze bioenergetically': $i).
% 28.89/28.95  tff(decl_13141, type, bioenergetics: $i).
% 28.89/28.95  tff(decl_13142, type, thermodynamics_1: $i > $o).
% 28.89/28.95  tff(decl_13143, type, fn_bioenergetics_1: $i > $i).
% 28.89/28.95  tff(decl_13144, type, fn_bioenergetics_2: $i > $i).
% 28.89/28.95  tff(decl_13145, type, fn_bioenergetics_3: $i > $i).
% 28.89/28.95  tff(decl_13146, type, fn_bioenergetics_4: $i > $i).
% 28.89/28.95  tff(decl_13147, type, fn_bioenergetics_5: $i > $i).
% 28.89/28.95  tff(decl_13148, type, fn_bioenergetics_6: $i > $i).
% 28.89/28.95  tff(decl_13149, type, fn_bioenergetics_7: $i > $i).
% 28.89/28.95  tff(decl_13150, type, fn_bioenergetics_8: $i > $i).
% 28.89/28.95  tff(decl_13151, type, exit_1: $i > $o).
% 28.89/28.95  tff(decl_13152, type, fn_bioenergetics_9: $i > $i).
% 28.89/28.95  tff(decl_13153, type, fn_bioenergetics_10: $i > $i).
% 28.89/28.95  tff(decl_13154, type, sunlight_1: $i > $o).
% 28.89/28.95  tff(decl_13155, type, fn_bioenergetics_11: $i > $i).
% 28.89/28.95  tff(decl_13156, type, fn_bioenergetics_12: $i > $i).
% 28.89/28.95  tff(decl_13157, type, fn_bioenergetics_13: $i > $i).
% 28.89/28.95  tff(decl_13158, type, fn_bioenergetics_14: $i > $i).
% 28.89/28.95  tff(decl_13159, type, fn_bioenergetics_15: $i > $i).
% 28.89/28.95  tff(decl_13160, type, fn_bioenergetics_16: $i > $i).
% 28.89/28.95  tff(decl_13161, type, energy_flow_in_ecosystem_1: $i > $o).
% 28.89/28.95  tff(decl_13162, type, fn_energy_flow_in_ecosystem_3: $i > $i).
% 28.89/28.95  tff(decl_13163, type, fn_energy_flow_in_ecosystem_5: $i > $i).
% 28.89/28.95  tff(decl_13164, type, fn_energy_flow_in_ecosystem_4: $i > $i).
% 28.89/28.95  tff(decl_13165, type, fn_energy_flow_in_ecosystem_1: $i > $i).
% 28.89/28.95  tff(decl_13166, type, fn_energy_flow_in_ecosystem_6: $i > $i).
% 28.89/28.95  tff(decl_13167, type, bioethanol_production_1: $i > $o).
% 28.89/28.95  tff(decl_13168, type, 'Bioethanol-Production': $i).
% 28.89/28.95  tff(decl_13169, type, 'In bioethanol production, plants utilize light energy to produce starch, which is converted by bacteria to ethanol. The ethanol serves as a replacement or supplement for fossil fuels.': $i).
% 28.89/28.95  tff(decl_13170, type, 'bioethanol production': $i).
% 28.89/28.95  tff(decl_13171, type, 'bioethanol-production': $i).
% 28.89/28.95  tff(decl_13172, type, fn_bioethanol_production_1: $i > $i).
% 28.89/28.95  tff(decl_13173, type, fn_bioethanol_production_2: $i > $i).
% 28.89/28.95  tff(decl_13174, type, fn_bioethanol_production_3: $i > $i).
% 28.89/28.95  tff(decl_13175, type, fn_bioethanol_production_4: $i > $i).
% 28.89/28.95  tff(decl_13176, type, fn_bioethanol_production_5: $i > $i).
% 28.89/28.95  tff(decl_13177, type, fn_bioethanol_production_6: $i > $i).
% 28.89/28.95  tff(decl_13178, type, isolation_1: $i > $o).
% 28.89/28.95  tff(decl_13179, type, fn_bioethanol_production_7: $i > $i).
% 28.89/28.95  tff(decl_13180, type, fn_bioethanol_production_8: $i > $i).
% 28.89/28.95  tff(decl_13181, type, fn_bioethanol_production_9: $i > $i).
% 28.89/28.95  tff(decl_13182, type, fn_bioethanol_production_10: $i > $i).
% 28.89/28.95  tff(decl_13183, type, fn_bioethanol_production_11: $i > $i).
% 28.89/28.95  tff(decl_13184, type, fn_bioethanol_production_12: $i > $i).
% 28.89/28.95  tff(decl_13185, type, fn_bioethanol_production_13: $i > $i).
% 28.89/28.95  tff(decl_13186, type, fn_bioethanol_production_14: $i > $i).
% 28.89/28.95  tff(decl_13187, type, laboratory_1: $i > $o).
% 28.89/28.95  tff(decl_13188, type, fn_bioethanol_production_15: $i > $i).
% 28.89/28.95  tff(decl_13189, type, fn_bioethanol_production_16: $i > $i).
% 28.89/28.95  tff(decl_13190, type, fn_bioethanol_production_17: $i > $i).
% 28.89/28.95  tff(decl_13191, type, photosynthesis_1: $i > $o).
% 28.89/28.95  tff(decl_13192, type, fn_bioethanol_production_18: $i > $i).
% 28.89/28.95  tff(decl_13193, type, fn_bioethanol_production_19: $i > $i).
% 28.89/28.95  tff(decl_13194, type, synthesis_of_carbohydrate_1: $i > $o).
% 28.89/28.95  tff(decl_13195, type, fn_bioethanol_production_20: $i > $i).
% 28.89/28.95  tff(decl_13196, type, fn_bioethanol_production_22: $i > $i).
% 28.89/28.95  tff(decl_13197, type, fn_bioethanol_production_23: $i > $i).
% 28.89/28.95  tff(decl_13198, type, fn_bioethanol_production_24: $i > $i).
% 28.89/28.95  tff(decl_13199, type, fn_bioethanol_production_25: $i > $i).
% 28.89/28.95  tff(decl_13200, type, fn_bioethanol_production_26: $i > $i).
% 28.89/28.95  tff(decl_13201, type, fn_bioethanol_production_27: $i > $i).
% 28.89/28.95  tff(decl_13202, type, fn_bioethanol_production_28: $i > $i).
% 28.89/28.95  tff(decl_13203, type, fn_culture_1: $i > $i).
% 28.89/28.95  tff(decl_13204, type, fn_culture_2: $i > $i).
% 28.89/28.95  tff(decl_13205, type, fn_synthesis_of_carbohydrate_2: $i > $i).
% 28.89/28.95  tff(decl_13206, type, molecule_0: $i).
% 28.89/28.95  tff(decl_13207, type, fn_bioethanol_production_21: $i > $i).
% 28.89/28.95  tff(decl_13208, type, fn_biofuel_production_2: $i > $i).
% 28.89/28.95  tff(decl_13209, type, fn_biofuel_production_1: $i > $i).
% 28.89/28.95  tff(decl_13210, type, 'Biofilm': $i).
% 28.89/28.95  tff(decl_13211, type, 'An aggregation of prokaryotes where the cells adhere to each other on a surface and engage in metabolic cooperation.': $i).
% 28.89/28.95  tff(decl_13212, type, biofilm: $i).
% 28.89/28.95  tff(decl_13213, type, fn_biofilm_3: $i > $i).
% 28.89/28.95  tff(decl_13214, type, 'Biofilm-Formation': $i).
% 28.89/28.95  tff(decl_13215, type, 'The process of colonization and cell division that results in the production of a biofilm on a surface.': $i).
% 28.89/28.95  tff(decl_13216, type, 'formation of biofilm': $i).
% 28.89/28.95  tff(decl_13217, type, 'biofilm formation': $i).
% 28.89/28.95  tff(decl_13218, type, 'biofilm-formation': $i).
% 28.89/28.95  tff(decl_13219, type, fn_biofilm_formation_1: $i > $i).
% 28.89/28.95  tff(decl_13220, type, fn_biofilm_formation_2: $i > $i).
% 28.89/28.95  tff(decl_13221, type, fn_biofilm_formation_3: $i > $i).
% 28.89/28.95  tff(decl_13222, type, fn_biofilm_formation_4: $i > $i).
% 28.89/28.95  tff(decl_13223, type, fn_biofilm_formation_5: $i > $i).
% 28.89/28.95  tff(decl_13224, type, fn_biofilm_formation_6: $i > $i).
% 28.89/28.95  tff(decl_13225, type, quorum_sensing_in_prokaryote_1: $i > $o).
% 28.89/28.95  tff(decl_13226, type, fn_biofilm_formation_8: $i > $i).
% 28.89/28.95  tff(decl_13227, type, go_to_1: $i > $o).
% 28.89/28.95  tff(decl_13228, type, fn_biofilm_formation_9: $i > $i).
% 28.89/28.95  tff(decl_13229, type, signal_generation_1: $i > $o).
% 28.89/28.95  tff(decl_13230, type, fn_biofilm_formation_10: $i > $i).
% 28.89/28.95  tff(decl_13231, type, fn_biofilm_formation_11: $i > $i).
% 28.89/28.95  tff(decl_13232, type, cell_communication_1: $i > $o).
% 28.89/28.95  tff(decl_13233, type, fn_biofilm_formation_12: $i > $i).
% 28.89/28.95  tff(decl_13234, type, fn_biofilm_formation_13: $i > $i).
% 28.89/28.95  tff(decl_13235, type, come_together_1: $i > $o).
% 28.89/28.95  tff(decl_13236, type, fn_biofilm_formation_14: $i > $i).
% 28.89/28.95  tff(decl_13237, type, sense_1: $i > $o).
% 28.89/28.95  tff(decl_13238, type, fn_biofilm_formation_15: $i > $i).
% 28.89/28.95  tff(decl_13239, type, fn_cell_communication_2: $i > $i).
% 28.89/28.95  tff(decl_13240, type, fn_quorum_sensing_in_prokaryote_8: $i > $i).
% 28.89/28.95  tff(decl_13241, type, fn_quorum_sensing_in_prokaryote_10: $i > $i).
% 28.89/28.95  tff(decl_13242, type, fn_quorum_sensing_in_prokaryote_12: $i > $i).
% 28.89/28.95  tff(decl_13243, type, fn_quorum_sensing_in_prokaryote_5: $i > $i).
% 28.89/28.95  tff(decl_13244, type, fn_quorum_sensing_in_prokaryote_9: $i > $i).
% 28.89/28.95  tff(decl_13245, type, fn_cell_signaling_4: $i > $i).
% 28.89/28.95  tff(decl_13246, type, fn_quorum_sensing_in_prokaryote_7: $i > $i).
% 28.89/28.95  tff(decl_13247, type, biofuel_1: $i > $o).
% 28.89/28.95  tff(decl_13248, type, 'Biofuel': $i).
% 28.89/28.95  tff(decl_13249, type, 'A combustible fuel derived from organic material.': $i).
% 28.89/28.95  tff(decl_13250, type, 'Biofuel-Production': $i).
% 28.89/28.95  tff(decl_13251, type, 'In biofuel production, living organisms utilize light energy to produce organic molecules which serve as replacements or supplements for fossil fuels.': $i).
% 28.89/28.95  tff(decl_13252, type, 'biofuel production': $i).
% 28.89/28.95  tff(decl_13253, type, 'biofuel-production': $i).
% 28.89/28.95  tff(decl_13254, type, fn_biofuel_production_5: $i > $i).
% 28.89/28.95  tff(decl_13255, type, fn_biofuel_production_6: $i > $i).
% 28.89/28.95  tff(decl_13256, type, fn_biofuel_production_9: $i > $i).
% 28.89/28.95  tff(decl_13257, type, fn_biofuel_production_10: $i > $i).
% 28.89/28.95  tff(decl_13258, type, fn_biofuel_production_11: $i > $i).
% 28.89/28.95  tff(decl_13259, type, fn_biofuel_production_12: $i > $i).
% 28.89/28.95  tff(decl_13260, type, fn_biofuel_production_13: $i > $i).
% 28.89/28.95  tff(decl_13261, type, fn_biofuel_production_14: $i > $i).
% 28.89/28.95  tff(decl_13262, type, fn_biofuel_production_15: $i > $i).
% 28.89/28.95  tff(decl_13263, type, fn_biofuel_production_16: $i > $i).
% 28.89/28.95  tff(decl_13264, type, fn_biofuel_production_19: $i > $i).
% 28.89/28.95  tff(decl_13265, type, sugar_1: $i > $o).
% 28.89/28.95  tff(decl_13266, type, fn_biofuel_production_20: $i > $i).
% 28.89/28.95  tff(decl_13267, type, fn_biofuel_production_21: $i > $i).
% 28.89/28.95  tff(decl_13268, type, fn_biofuel_production_22: $i > $i).
% 28.89/28.95  tff(decl_13269, type, fn_biofuel_production_23: $i > $i).
% 28.89/28.95  tff(decl_13270, type, replace_1: $i > $o).
% 28.89/28.95  tff(decl_13271, type, fn_biofuel_production_24: $i > $i).
% 28.89/28.95  tff(decl_13272, type, fn_biofuel_production_25: $i > $i).
% 28.89/28.95  tff(decl_13273, type, fn_biofuel_production_26: $i > $i).
% 28.89/28.95  tff(decl_13274, type, fn_biofuel_production_28: $i > $i).
% 28.89/28.95  tff(decl_13275, type, fn_biofuel_production_29: $i > $i).
% 28.89/28.95  tff(decl_13276, type, replenish_1: $i > $o).
% 28.89/28.95  tff(decl_13277, type, fn_biofuel_production_30: $i > $i).
% 28.89/28.95  tff(decl_13278, type, fn_biofuel_production_31: $i > $i).
% 28.89/28.95  tff(decl_13279, type, fn_biofuel_production_32: $i > $i).
% 28.89/28.95  tff(decl_13280, type, fn_biofuel_production_33: $i > $i).
% 28.89/28.95  tff(decl_13281, type, fn_biofuel_production_34: $i > $i).
% 28.89/28.95  tff(decl_13282, type, fn_biofuel_production_35: $i > $i).
% 28.89/28.95  tff(decl_13283, type, fn_biofuel_production_36: $i > $i).
% 28.89/28.95  tff(decl_13284, type, fn_biofuel_production_37: $i > $i).
% 28.89/28.95  tff(decl_13285, type, fn_biofuel_production_38: $i > $i).
% 28.89/28.95  tff(decl_13286, type, fn_biofuel_production_39: $i > $i).
% 28.89/28.95  tff(decl_13287, type, fn_biofuel_production_40: $i > $i).
% 28.89/28.95  tff(decl_13288, type, fn_biofuel_production_41: $i > $i).
% 28.89/28.95  tff(decl_13289, type, fn_replace_3: $i > $i).
% 28.89/28.95  tff(decl_13290, type, fn_replenish_2: $i > $i).
% 28.89/28.95  tff(decl_13291, type, fn_photosynthesis_54: $i > $i).
% 28.89/28.95  tff(decl_13292, type, fn_photosynthesis_57: $i > $i).
% 28.89/28.95  tff(decl_13293, type, fn_photosynthesis_5: $i > $i).
% 28.89/28.95  tff(decl_13294, type, fn_photosynthesis_6: $i > $i).
% 28.89/28.95  tff(decl_13295, type, fn_photosynthesis_56: $i > $i).
% 28.89/28.95  tff(decl_13296, type, fn_photosynthesis_55: $i > $i).
% 28.89/28.95  tff(decl_13297, type, fn_photosynthesis_46: $i > $i).
% 28.89/28.95  tff(decl_13298, type, fn_photosynthesis_53: $i > $i).
% 28.89/28.95  tff(decl_13299, type, fn_photosynthesis_52: $i > $i).
% 28.89/28.95  tff(decl_13300, type, fn_photosynthesis_51: $i > $i).
% 28.89/28.95  tff(decl_13301, type, fn_photosynthesis_24: $i > $i).
% 28.89/28.95  tff(decl_13302, type, fn_photosynthesis_32: $i > $i).
% 28.89/28.95  tff(decl_13303, type, fn_photosynthesis_50: $i > $i).
% 28.89/28.95  tff(decl_13304, type, fn_photosynthesis_3: $i > $i).
% 28.89/28.95  tff(decl_13305, type, fn_photosynthesis_4: $i > $i).
% 28.89/28.95  tff(decl_13306, type, fn_replace_1: $i > $i).
% 28.89/28.95  tff(decl_13307, type, fn_replace_2: $i > $i).
% 28.89/28.95  tff(decl_13308, type, fn_replenish_1: $i > $i).
% 28.89/28.95  tff(decl_13309, type, fn_photosynthesis_25: $i > $i).
% 28.89/28.95  tff(decl_13310, type, fn_photosynthesis_38: $i > $i).
% 28.89/28.95  tff(decl_13311, type, fn_photosynthesis_37: $i > $i).
% 28.89/28.95  tff(decl_13312, type, fn_biofuel_production_8: $i > $i).
% 28.89/28.95  tff(decl_13313, type, fn_biofuel_production_7: $i > $i).
% 28.89/28.95  tff(decl_13314, type, fn_biofuel_production_42: $i > $i).
% 28.89/28.95  tff(decl_13315, type, fn_biofuel_production_43: $i > $i).
% 28.89/28.95  tff(decl_13316, type, fn_biofuel_production_4: $i > $i).
% 28.89/28.95  tff(decl_13317, type, fn_biofuel_production_3: $i > $i).
% 28.89/28.95  tff(decl_13318, type, fn_biofuel_production_44: $i > $i).
% 28.89/28.95  tff(decl_13319, type, fn_biofuel_production_45: $i > $i).
% 28.89/28.95  tff(decl_13320, type, biogenic_amine_1: $i > $o).
% 28.89/28.95  tff(decl_13321, type, 'Biogenic-Amine': $i).
% 28.89/28.95  tff(decl_13322, type, 'A class of neurotransmitter derived from an amino acid.': $i).
% 28.89/28.95  tff(decl_13323, type, 'biogenic amine': $i).
% 28.89/28.95  tff(decl_13324, type, 'biogenic-amine': $i).
% 28.89/28.95  tff(decl_13325, type, glutamate_1: $i > $o).
% 28.89/28.95  tff(decl_13326, type, 'Biogeochemical-Cycle': $i).
% 28.89/28.95  tff(decl_13327, type, 'A physical and chemical pathway by which a chemical element or molecule moves through the biosphere.': $i).
% 28.89/28.95  tff(decl_13328, type, 'undergo the biogeochemical cycle': $i).
% 28.89/28.95  tff(decl_13329, type, 'biogeochemical cycle': $i).
% 28.89/28.95  tff(decl_13330, type, 'biogeochemical-cycle': $i).
% 28.89/28.95  tff(decl_13331, type, geologic_process_1: $i > $o).
% 28.89/28.95  tff(decl_13332, type, catastrophism_1: $i > $o).
% 28.89/28.95  tff(decl_13333, type, climate_1: $i > $o).
% 28.89/28.95  tff(decl_13334, type, continental_drift_1: $i > $o).
% 28.89/28.95  tff(decl_13335, type, plate_tectonics_1: $i > $o).
% 28.89/28.95  tff(decl_13336, type, uniformitarianism_1: $i > $o).
% 28.89/28.95  tff(decl_13337, type, biogeography_1: $i > $o).
% 28.89/28.95  tff(decl_13338, type, 'Biogeography': $i).
% 28.89/28.95  tff(decl_13339, type, 'The study of the distribution of organisms through time and across geographic space.': $i).
% 28.89/28.95  tff(decl_13340, type, biogeography: $i).
% 28.89/28.95  tff(decl_13341, type, bioinformatics_1: $i > $o).
% 28.89/28.95  tff(decl_13342, type, 'Bioinformatics': $i).
% 28.89/28.95  tff(decl_13343, type, 'A branch of biology that deals with the study of ways to store, retrieve, and analyze large biological data sets.': $i).
% 28.89/28.95  tff(decl_13344, type, 'perform bioinformatics': $i).
% 28.89/28.95  tff(decl_13345, type, bioinformatics: $i).
% 28.89/28.95  tff(decl_13346, type, biotechnology_1: $i > $o).
% 28.89/28.95  tff(decl_13347, type, biological_augmentation_1: $i > $o).
% 28.89/28.95  tff(decl_13348, type, 'Biological-Augmentation': $i).
% 28.89/28.95  tff(decl_13349, type, 'The practice in restoration ecology of using organisms to add essential materials to an ecosystem that has been degraded.': $i).
% 28.89/28.95  tff(decl_13350, type, 'augment biologically': $i).
% 28.89/28.95  tff(decl_13351, type, 'biological augmentation': $i).
% 28.89/28.95  tff(decl_13352, type, 'biological-augmentation': $i).
% 28.89/28.95  tff(decl_13353, type, 'Biological-Clock': $i).
% 28.89/28.95  tff(decl_13354, type, 'An endogenous timekeeper that governs an organism\\s physiological and behavioral rhythms. It marks the passage of time with or without external cues but often requires environmental cues maintain proper timing of physiological and behavioral events.': $i).
% 28.89/28.95  tff(decl_13355, type, 'biological clock': $i).
% 28.89/28.95  tff(decl_13356, type, 'biological-clock': $i).
% 28.89/28.95  tff(decl_13357, type, biological_fluid_1: $i > $o).
% 28.89/28.95  tff(decl_13358, type, 'Biological-Fluid': $i).
% 28.89/28.95  tff(decl_13359, type, 'The fluid substance present in a living organism.': $i).
% 28.89/28.95  tff(decl_13360, type, 'biological fluid': $i).
% 28.89/28.95  tff(decl_13361, type, 'biological-fluid': $i).
% 28.89/28.95  tff(decl_13362, type, vinegar_1: $i > $o).
% 28.89/28.95  tff(decl_13363, type, fn_biological_fluid_1: $i > $i).
% 28.89/28.95  tff(decl_13364, type, biological_magnification_1: $i > $o).
% 28.89/28.95  tff(decl_13365, type, 'Biological-Magnification': $i).
% 28.89/28.95  tff(decl_13366, type, 'The process by which a substance becomes more concentrated in higher trophic levels in a food chain. Biological magnification occurs due to persistance of the substance (i.e., it cannot be broken down by normal environmental or physiological processes), retention of the substance within organisms (i.e., it is not excreted), and food chain energetics.': $i).
% 28.89/28.95  tff(decl_13367, type, 'biological magnification': $i).
% 28.89/28.95  tff(decl_13368, type, 'biological-magnification': $i).
% 28.89/28.95  tff(decl_13369, type, 'Biological-Process': $i).
% 28.89/28.95  tff(decl_13370, type, 'Process related to living organisms.': $i).
% 28.89/28.95  tff(decl_13371, type, 'biological process': $i).
% 28.89/28.95  tff(decl_13372, type, 'biological-process': $i).
% 28.89/28.95  tff(decl_13373, type, 'Biological-Region': $i).
% 28.89/28.95  tff(decl_13374, type, 'A region of a biological entity.': $i).
% 28.89/28.95  tff(decl_13375, type, 'biological region': $i).
% 28.89/28.95  tff(decl_13376, type, 'biological-region': $i).
% 28.89/28.95  tff(decl_13377, type, biological_restoration_1: $i > $o).
% 28.89/28.95  tff(decl_13378, type, 'Biological-Restoration': $i).
% 28.89/28.95  tff(decl_13379, type, 'The active renewal of ecosystems which have been damaged due to pollution, agriculture, fire or other processes.': $i).
% 28.89/28.95  tff(decl_13380, type, 'biological restoration': $i).
% 28.89/28.95  tff(decl_13381, type, 'biological-restoration': $i).
% 28.89/28.95  tff(decl_13382, type, fn_biological_restoration_1: $i > $i).
% 28.89/28.95  tff(decl_13383, type, fn_biological_restoration_2: $i > $i).
% 28.89/28.95  tff(decl_13384, type, biological_species_1: $i > $o).
% 28.89/28.95  tff(decl_13385, type, 'Biological-Species': $i).
% 28.89/28.95  tff(decl_13386, type, 'A group of organisms that can interbreed in nature and produce viable, fertile offspring but are reproductively isolated from other organisms.': $i).
% 28.89/28.95  tff(decl_13387, type, 'biological species': $i).
% 28.89/28.95  tff(decl_13388, type, 'biological-specy': $i).
% 28.89/28.95  tff(decl_13389, type, species_1: $i > $o).
% 28.89/28.95  tff(decl_13390, type, 'Biologist': $i).
% 28.89/28.95  tff(decl_13391, type, 'A scientist who studies living organisms.': $i).
% 28.89/28.95  tff(decl_13392, type, biologist: $i).
% 28.89/28.95  tff(decl_13393, type, fn_biologist_1: $i > $i).
% 28.89/28.95  tff(decl_13394, type, fn_biologist_2: $i > $i).
% 28.89/28.95  tff(decl_13395, type, fn_biologist_3: $i > $i).
% 28.89/28.95  tff(decl_13396, type, fn_biologist_4: $i > $i).
% 28.89/28.95  tff(decl_13397, type, fn_biologist_5: $i > $i).
% 28.89/28.95  tff(decl_13398, type, fn_biologist_6: $i > $i).
% 28.89/28.95  tff(decl_13399, type, fn_biologist_7: $i > $i).
% 28.89/28.95  tff(decl_13400, type, fn_biologist_8: $i > $i).
% 28.89/28.95  tff(decl_13401, type, fn_biologist_9: $i > $i).
% 28.89/28.95  tff(decl_13402, type, fn_biologist_10: $i > $i).
% 28.89/28.95  tff(decl_13403, type, fn_biologist_11: $i > $i).
% 28.89/28.95  tff(decl_13404, type, fn_biologist_12: $i > $i).
% 28.89/28.95  tff(decl_13405, type, fn_biologist_13: $i > $i).
% 28.89/28.95  tff(decl_13406, type, fn_biologist_14: $i > $i).
% 28.89/28.95  tff(decl_13407, type, fn_biologist_15: $i > $i).
% 28.89/28.95  tff(decl_13408, type, fn_biologist_16: $i > $i).
% 28.89/28.95  tff(decl_13409, type, fn_biologist_17: $i > $i).
% 28.89/28.95  tff(decl_13410, type, fn_biologist_18: $i > $i).
% 28.89/28.95  tff(decl_13411, type, fn_biologist_19: $i > $i).
% 28.89/28.95  tff(decl_13412, type, fn_biologist_20: $i > $i).
% 28.89/28.95  tff(decl_13413, type, ingestion_1: $i > $o).
% 28.89/28.95  tff(decl_13414, type, fn_biologist_21: $i > $i).
% 28.89/28.95  tff(decl_13415, type, fn_biologist_22: $i > $i).
% 28.89/28.95  tff(decl_13416, type, fn_biologist_23: $i > $i).
% 28.89/28.95  tff(decl_13417, type, lining_1: $i > $o).
% 28.89/28.95  tff(decl_13418, type, fn_biologist_24: $i > $i).
% 28.89/28.95  tff(decl_13419, type, fn_biologist_25: $i > $i).
% 28.89/28.95  tff(decl_13420, type, fn_biologist_26: $i > $i).
% 28.89/28.95  tff(decl_13421, type, respiratory_system_1: $i > $o).
% 28.89/28.95  tff(decl_13422, type, fn_biologist_27: $i > $i).
% 28.89/28.95  tff(decl_13423, type, fn_biologist_28: $i > $i).
% 28.89/28.95  tff(decl_13424, type, fn_biologist_29: $i > $i).
% 28.89/28.95  tff(decl_13425, type, fn_biologist_30: $i > $i).
% 28.89/28.95  tff(decl_13426, type, fn_biologist_31: $i > $i).
% 28.89/28.95  tff(decl_13427, type, fn_biologist_32: $i > $i).
% 28.89/28.95  tff(decl_13428, type, bulk_feeder_1: $i > $o).
% 28.89/28.95  tff(decl_13429, type, fn_biologist_33: $i > $i).
% 28.89/28.95  tff(decl_13430, type, fn_biologist_34: $i > $i).
% 28.89/28.95  tff(decl_13431, type, pharynx_1: $i > $o).
% 28.89/28.95  tff(decl_13432, type, fn_biologist_35: $i > $i).
% 28.89/28.95  tff(decl_13433, type, fn_biologist_36: $i > $i).
% 28.89/28.95  tff(decl_13434, type, liver_1: $i > $o).
% 28.89/28.95  tff(decl_13435, type, fn_biologist_37: $i > $i).
% 28.89/28.95  tff(decl_13436, type, pancreas_1: $i > $o).
% 28.89/28.95  tff(decl_13437, type, fn_biologist_38: $i > $i).
% 28.89/28.95  tff(decl_13438, type, gallbladder_1: $i > $o).
% 28.89/28.95  tff(decl_13439, type, fn_biologist_39: $i > $i).
% 28.89/28.95  tff(decl_13440, type, heart_1: $i > $o).
% 28.89/28.95  tff(decl_13441, type, fn_biologist_40: $i > $i).
% 28.89/28.95  tff(decl_13442, type, trachea_1: $i > $o).
% 28.89/28.95  tff(decl_13443, type, fn_biologist_41: $i > $i).
% 28.89/28.95  tff(decl_13444, type, lung_1: $i > $o).
% 28.89/28.95  tff(decl_13445, type, fn_biologist_42: $i > $i).
% 28.89/28.95  tff(decl_13446, type, fn_biologist_43: $i > $i).
% 28.89/28.95  tff(decl_13447, type, fn_biologist_44: $i > $i).
% 28.89/28.95  tff(decl_13448, type, fn_biologist_45: $i > $i).
% 28.89/28.95  tff(decl_13449, type, fn_biologist_46: $i > $i).
% 28.89/28.95  tff(decl_13450, type, human_cell_1: $i > $o).
% 28.89/28.95  tff(decl_13451, type, mammalian_cell_1: $i > $o).
% 28.89/28.95  tff(decl_13452, type, fn_bulk_feeder_4: $i > $i).
% 28.89/28.95  tff(decl_13453, type, fn_bulk_feeder_3: $i > $i).
% 28.89/28.95  tff(decl_13454, type, "37.0e0": $i).
% 28.89/28.95  tff(decl_13455, type, 'M3': $i).
% 28.89/28.95  tff(decl_13456, type, 'Protist': $i).
% 28.89/28.95  tff(decl_13457, type, fn_biologist_47: $i > $i).
% 28.89/28.95  tff(decl_13458, type, fn_person_63: $i > $i).
% 28.89/28.95  tff(decl_13459, type, fn_biologist_48: $i > $i).
% 28.89/28.95  tff(decl_13460, type, fn_person_19: $i > $i).
% 28.89/28.95  tff(decl_13461, type, fn_person_46: $i > $i).
% 28.89/28.95  tff(decl_13462, type, fn_person_71: $i > $i).
% 28.89/28.95  tff(decl_13463, type, fn_person_69: $i > $i).
% 28.89/28.95  tff(decl_13464, type, fn_person_40: $i > $i).
% 28.89/28.95  tff(decl_13465, type, fn_person_18: $i > $i).
% 28.89/28.95  tff(decl_13466, type, fn_person_36: $i > $i).
% 28.89/28.95  tff(decl_13467, type, fn_person_73: $i > $i).
% 28.89/28.95  tff(decl_13468, type, fn_person_74: $i > $i).
% 28.89/28.95  tff(decl_13469, type, fn_mammal_50: $i > $i).
% 28.89/28.95  tff(decl_13470, type, fn_person_47: $i > $i).
% 28.89/28.95  tff(decl_13471, type, fn_person_31: $i > $i).
% 28.89/28.95  tff(decl_13472, type, fn_person_67: $i > $i).
% 28.89/28.95  tff(decl_13473, type, fn_mammal_82: $i > $i).
% 28.89/28.95  tff(decl_13474, type, fn_person_37: $i > $i).
% 28.89/28.95  tff(decl_13475, type, fn_person_30: $i > $i).
% 28.89/28.95  tff(decl_13476, type, fn_person_29: $i > $i).
% 28.89/28.95  tff(decl_13477, type, fn_person_27: $i > $i).
% 28.89/28.95  tff(decl_13478, type, fn_person_26: $i > $i).
% 28.89/28.95  tff(decl_13479, type, fn_person_25: $i > $i).
% 28.89/28.95  tff(decl_13480, type, fn_person_35: $i > $i).
% 28.89/28.95  tff(decl_13481, type, fn_person_24: $i > $i).
% 28.89/28.95  tff(decl_13482, type, fn_person_38: $i > $i).
% 28.89/28.95  tff(decl_13483, type, fn_person_23: $i > $i).
% 28.89/28.95  tff(decl_13484, type, fn_person_28: $i > $i).
% 28.89/28.95  tff(decl_13485, type, fn_person_22: $i > $i).
% 28.89/28.95  tff(decl_13486, type, fn_person_34: $i > $i).
% 28.89/28.95  tff(decl_13487, type, fn_person_21: $i > $i).
% 28.89/28.95  tff(decl_13488, type, fn_person_62: $i > $i).
% 28.89/28.95  tff(decl_13489, type, fn_person_39: $i > $i).
% 28.89/28.95  tff(decl_13490, type, fn_person_20: $i > $i).
% 28.89/28.95  tff(decl_13491, type, fn_person_65: $i > $i).
% 28.89/28.95  tff(decl_13492, type, fn_person_68: $i > $i).
% 28.89/28.95  tff(decl_13493, type, fn_person_64: $i > $i).
% 28.89/28.95  tff(decl_13494, type, fn_person_50: $i > $i).
% 28.89/28.95  tff(decl_13495, type, fn_person_72: $i > $i).
% 28.89/28.95  tff(decl_13496, type, fn_person_60: $i > $i).
% 28.89/28.95  tff(decl_13497, type, fn_person_33: $i > $i).
% 28.89/28.95  tff(decl_13498, type, fn_person_44: $i > $i).
% 28.89/28.95  tff(decl_13499, type, fn_person_32: $i > $i).
% 28.89/28.95  tff(decl_13500, type, fn_person_41: $i > $i).
% 28.89/28.95  tff(decl_13501, type, fn_person_49: $i > $i).
% 28.89/28.95  tff(decl_13502, type, fn_person_16: $i > $i).
% 28.89/28.95  tff(decl_13503, type, fn_person_8: $i > $i).
% 28.89/28.95  tff(decl_13504, type, fn_person_61: $i > $i).
% 28.89/28.95  tff(decl_13505, type, biology_1: $i > $o).
% 28.89/28.95  tff(decl_13506, type, 'Biology': $i).
% 28.89/28.95  tff(decl_13507, type, 'The scientific study of life.': $i).
% 28.89/28.95  tff(decl_13508, type, biology: $i).
% 28.89/28.95  tff(decl_13509, type, inquiry_1: $i > $o).
% 28.89/28.95  tff(decl_13510, type, bioluminescence_1: $i > $o).
% 28.89/28.95  tff(decl_13511, type, 'Bioluminescence': $i).
% 28.89/28.95  tff(decl_13512, type, 'The ability of an organism to produce and emit light.': $i).
% 28.89/28.95  tff(decl_13513, type, 'show bioluminescence': $i).
% 28.89/28.95  tff(decl_13514, type, bioluminescence: $i).
% 28.89/28.95  tff(decl_13515, type, fn_bioluminescence_1: $i > $i).
% 28.89/28.95  tff(decl_13516, type, light_1: $i > $o).
% 28.89/28.95  tff(decl_13517, type, fn_bioluminescence_2: $i > $i).
% 28.89/28.95  tff(decl_13518, type, fn_bioluminescence_3: $i > $i).
% 28.89/28.95  tff(decl_13519, type, biomanipulation_1: $i > $o).
% 28.89/28.95  tff(decl_13520, type, 'Biomanipulation': $i).
% 28.89/28.95  tff(decl_13521, type, 'The intentional introduction of higher-level consumers to a degraded aquatic ecosystem, to control algal blooms caused by eutrophication; an example of top-down control over community structure in an ecosystem.': $i).
% 28.89/28.95  tff(decl_13522, type, biomanipulation: $i).
% 28.89/28.95  tff(decl_13523, type, biomass_1: $i > $o).
% 28.89/28.95  tff(decl_13524, type, 'Biomass': $i).
% 28.89/28.95  tff(decl_13525, type, 'The total mass of living organisms in a given area at a given time.': $i).
% 28.89/28.95  tff(decl_13526, type, biomass: $i).
% 28.89/28.95  tff(decl_13527, type, biomass_pyramid_1: $i > $o).
% 28.89/28.95  tff(decl_13528, type, 'Biomass-Pyramid': $i).
% 28.89/28.95  tff(decl_13529, type, 'A diagram showing the distribution of mass among organisms at different trophic levels in an ecosystem.': $i).
% 28.89/28.95  tff(decl_13530, type, 'pyramid of biomass': $i).
% 28.89/28.95  tff(decl_13531, type, 'pyramid-of-biomass': $i).
% 28.89/28.95  tff(decl_13532, type, 'biomass pyramid': $i).
% 28.89/28.95  tff(decl_13533, type, 'biomass-pyramid': $i).
% 28.89/28.95  tff(decl_13534, type, ecological_pyramid_1: $i > $o).
% 28.89/28.95  tff(decl_13535, type, pyramid_of_numbers_1: $i > $o).
% 28.89/28.95  tff(decl_13536, type, pyramid_of_production_1: $i > $o).
% 28.89/28.95  tff(decl_13537, type, biome_1: $i > $o).
% 28.89/28.95  tff(decl_13538, type, 'Biome': $i).
% 28.89/28.95  tff(decl_13539, type, 'A large ecosystem, typically characterized by the predominant vegetation, climate, and the adaptations of the organisms living in that particular environment.': $i).
% 28.89/28.95  tff(decl_13540, type, biome: $i).
% 28.89/28.95  tff(decl_13541, type, fn_biome_5: $i > $i).
% 28.89/28.95  tff(decl_13542, type, fn_biome_6: $i > $i).
% 28.89/28.95  tff(decl_13543, type, visible_light_1: $i > $o).
% 28.89/28.95  tff(decl_13544, type, fn_biome_7: $i > $i).
% 28.89/28.95  tff(decl_13545, type, fn_biome_8: $i > $i).
% 28.89/28.95  tff(decl_13546, type, fn_biome_9: $i > $i).
% 28.89/28.95  tff(decl_13547, type, fn_biome_10: $i > $i).
% 28.89/28.95  tff(decl_13548, type, fn_biome_11: $i > $i).
% 28.89/28.95  tff(decl_13549, type, fn_biome_12: $i > $i).
% 28.89/28.95  tff(decl_13550, type, fn_biome_13: $i > $i).
% 28.89/28.95  tff(decl_13551, type, light_reaction_1: $i > $o).
% 28.89/28.95  tff(decl_13552, type, fn_biome_14: $i > $i).
% 28.89/28.95  tff(decl_13553, type, fn_biome_15: $i > $i).
% 28.89/28.95  tff(decl_13554, type, fn_biome_16: $i > $i).
% 28.89/28.95  tff(decl_13555, type, fn_biome_17: $i > $i).
% 28.89/28.95  tff(decl_13556, type, fn_photosynthesis_34: $i > $i).
% 28.89/28.95  tff(decl_13557, type, fn_cyanobacterium_17: $i > $i).
% 28.89/28.95  tff(decl_13558, type, fn_plant_18: $i > $i).
% 28.89/28.95  tff(decl_13559, type, fn_photosynthesis_35: $i > $i).
% 28.89/28.95  tff(decl_13560, type, fn_sunlight_1: $i > $i).
% 28.89/28.95  tff(decl_13561, type, fn_cyanobacterium_15: $i > $i).
% 28.89/28.95  tff(decl_13562, type, fn_plant_45: $i > $i).
% 28.89/28.95  tff(decl_13563, type, fn_plant_20: $i > $i).
% 28.89/28.95  tff(decl_13564, type, fn_light_reaction_45: $i > $i).
% 28.89/28.95  tff(decl_13565, type, fn_energy_transformation_by_organism_2: $i > $i).
% 28.89/28.95  tff(decl_13566, type, fn_light_reaction_50: $i > $i).
% 28.89/28.95  tff(decl_13567, type, fn_photosynthesis_31: $i > $i).
% 28.89/28.95  tff(decl_13568, type, fn_photosynthesis_40: $i > $i).
% 28.89/28.95  tff(decl_13569, type, fn_energy_transformation_by_organism_1: $i > $i).
% 28.89/28.95  tff(decl_13570, type, fn_photosynthesis_1: $i > $i).
% 28.89/28.95  tff(decl_13571, type, 'Biomembrane': $i).
% 28.89/28.95  tff(decl_13572, type, 'A biological membrane or biomembrane is an enclosing or separating membrane that acts as a selective barrier, within or around a cell.': $i).
% 28.89/28.95  tff(decl_13573, type, 'biological membrane': $i).
% 28.89/28.95  tff(decl_13574, type, 'biological-membrane': $i).
% 28.89/28.95  tff(decl_13575, type, 'cellular membrane': $i).
% 28.89/28.95  tff(decl_13576, type, 'cellular-membrane': $i).
% 28.89/28.95  tff(decl_13577, type, membrane: $i).
% 28.89/28.95  tff(decl_13578, type, biomembrane: $i).
% 28.89/28.95  tff(decl_13579, type, fn_biomembrane_1: $i > $i).
% 28.89/28.95  tff(decl_13580, type, fn_biomembrane_4: $i > $i).
% 28.89/28.95  tff(decl_13581, type, fn_biomembrane_8: $i > $i).
% 28.89/28.95  tff(decl_13582, type, fn_biomembrane_9: $i > $i).
% 28.89/28.95  tff(decl_13583, type, fn_biomembrane_10: $i > $i).
% 28.89/28.95  tff(decl_13584, type, fn_biomembrane_11: $i > $i).
% 28.89/28.95  tff(decl_13585, type, fn_biomembrane_16: $i > $i).
% 28.89/28.95  tff(decl_13586, type, fn_biomembrane_17: $i > $i).
% 28.89/28.95  tff(decl_13587, type, fn_biomembrane_20: $i > $i).
% 28.89/28.95  tff(decl_13588, type, fn_biomembrane_22: $i > $i).
% 28.89/28.95  tff(decl_13589, type, fn_biomembrane_23: $i > $i).
% 28.89/28.95  tff(decl_13590, type, fn_biomembrane_24: $i > $i).
% 28.89/28.95  tff(decl_13591, type, fn_biomembrane_25: $i > $i).
% 28.89/28.95  tff(decl_13592, type, fn_biomembrane_30: $i > $i).
% 28.89/28.95  tff(decl_13593, type, fn_biomembrane_31: $i > $i).
% 28.89/28.95  tff(decl_13594, type, fn_biomembrane_32: $i > $i).
% 28.89/28.95  tff(decl_13595, type, fn_biomembrane_33: $i > $i).
% 28.89/28.95  tff(decl_13596, type, fn_biomembrane_34: $i > $i).
% 28.89/28.95  tff(decl_13597, type, fn_biomembrane_35: $i > $i).
% 28.89/28.95  tff(decl_13598, type, fn_biomembrane_36: $i > $i).
% 28.89/28.95  tff(decl_13599, type, fn_biomembrane_43: $i > $i).
% 28.89/28.95  tff(decl_13600, type, fn_biomembrane_44: $i > $i).
% 28.89/28.95  tff(decl_13601, type, fn_biomembrane_48: $i > $i).
% 28.89/28.95  tff(decl_13602, type, fn_biomembrane_49: $i > $i).
% 28.89/28.95  tff(decl_13603, type, fn_biomembrane_50: $i > $i).
% 28.89/28.95  tff(decl_13604, type, fn_biomembrane_51: $i > $i).
% 28.89/28.95  tff(decl_13605, type, fn_biomembrane_53: $i > $i).
% 28.89/28.95  tff(decl_13606, type, fn_biomembrane_57: $i > $i).
% 28.89/28.95  tff(decl_13607, type, fn_biomembrane_58: $i > $i).
% 28.89/28.95  tff(decl_13608, type, fn_biomembrane_59: $i > $i).
% 28.89/28.95  tff(decl_13609, type, fn_biomembrane_60: $i > $i).
% 28.89/28.95  tff(decl_13610, type, fn_biomembrane_64: $i > $i).
% 28.89/28.95  tff(decl_13611, type, fn_biomembrane_65: $i > $i).
% 28.89/28.95  tff(decl_13612, type, fn_biomembrane_68: $i > $i).
% 28.89/28.95  tff(decl_13613, type, fn_biomembrane_70: $i > $i).
% 28.89/28.95  tff(decl_13614, type, fn_biomembrane_72: $i > $i).
% 28.89/28.95  tff(decl_13615, type, fn_biomembrane_73: $i > $i).
% 28.89/28.95  tff(decl_13616, type, fn_biomembrane_74: $i > $i).
% 28.89/28.95  tff(decl_13617, type, fn_biomembrane_77: $i > $i).
% 28.89/28.95  tff(decl_13618, type, fatty_acid_tail_1: $i > $o).
% 28.89/28.95  tff(decl_13619, type, fn_biomembrane_78: $i > $i).
% 28.89/28.95  tff(decl_13620, type, fn_biomembrane_79: $i > $i).
% 28.89/28.95  tff(decl_13621, type, fn_biomembrane_80: $i > $i).
% 28.89/28.95  tff(decl_13622, type, fn_biomembrane_81: $i > $i).
% 28.89/28.95  tff(decl_13623, type, fn_biomembrane_82: $i > $i).
% 28.89/28.95  tff(decl_13624, type, fn_biomembrane_84: $i > $i).
% 28.89/28.95  tff(decl_13625, type, fn_biomembrane_85: $i > $i).
% 28.89/28.95  tff(decl_13626, type, fn_biomembrane_86: $i > $i).
% 28.89/28.95  tff(decl_13627, type, fn_biomembrane_87: $i > $i).
% 28.89/28.95  tff(decl_13628, type, fn_biomembrane_88: $i > $i).
% 28.89/28.95  tff(decl_13629, type, fn_biomembrane_89: $i > $i).
% 28.89/28.95  tff(decl_13630, type, fn_biomembrane_90: $i > $i).
% 28.89/28.95  tff(decl_13631, type, fn_biomembrane_91: $i > $i).
% 28.89/28.95  tff(decl_13632, type, fn_biomembrane_92: $i > $i).
% 28.89/28.95  tff(decl_13633, type, fn_biomembrane_93: $i > $i).
% 28.89/28.95  tff(decl_13634, type, organic_acid_1: $i > $o).
% 28.89/28.95  tff(decl_13635, type, fn_biomembrane_94: $i > $i).
% 28.89/28.95  tff(decl_13636, type, fn_biomembrane_95: $i > $i).
% 28.89/28.95  tff(decl_13637, type, fn_biomembrane_96: $i > $i).
% 28.89/28.95  tff(decl_13638, type, fn_biomembrane_97: $i > $i).
% 28.89/28.95  tff(decl_13639, type, fn_phospholipid_bilayer_39: $i > $i).
% 28.89/28.95  tff(decl_13640, type, fn_phospholipid_bilayer_3: $i > $i).
% 28.89/28.95  tff(decl_13641, type, fn_phospholipid_bilayer_34: $i > $i).
% 28.89/28.95  tff(decl_13642, type, fn_phospholipid_bilayer_38: $i > $i).
% 28.89/28.95  tff(decl_13643, type, fn_phospholipid_bilayer_33: $i > $i).
% 28.89/28.95  tff(decl_13644, type, fn_phospholipid_105: $i > $i).
% 28.89/28.95  tff(decl_13645, type, fn_phospholipid_104: $i > $i).
% 28.89/28.95  tff(decl_13646, type, fn_phospholipid_43: $i > $i).
% 28.89/28.95  tff(decl_13647, type, fn_phospholipid_103: $i > $i).
% 28.89/28.95  tff(decl_13648, type, fn_phospholipid_44: $i > $i).
% 28.89/28.95  tff(decl_13649, type, fn_phospholipid_102: $i > $i).
% 28.89/28.95  tff(decl_13650, type, fn_phospholipid_91: $i > $i).
% 28.89/28.95  tff(decl_13651, type, fn_phospholipid_87: $i > $i).
% 28.89/28.95  tff(decl_13652, type, fn_phospholipid_bilayer_26: $i > $i).
% 28.89/28.95  tff(decl_13653, type, fn_phospholipid_92: $i > $i).
% 28.89/28.95  tff(decl_13654, type, fn_phospholipid_90: $i > $i).
% 28.89/28.95  tff(decl_13655, type, fn_phospholipid_bilayer_23: $i > $i).
% 28.89/28.95  tff(decl_13656, type, fn_phospholipid_bilayer_24: $i > $i).
% 28.89/28.95  tff(decl_13657, type, fn_phospholipid_bilayer_37: $i > $i).
% 28.89/28.95  tff(decl_13658, type, fn_phospholipid_97: $i > $i).
% 28.89/28.95  tff(decl_13659, type, fn_phospholipid_bilayer_32: $i > $i).
% 28.89/28.95  tff(decl_13660, type, fn_phospholipid_bilayer_19: $i > $i).
% 28.89/28.95  tff(decl_13661, type, fn_phospholipid_116: $i > $i).
% 28.89/28.95  tff(decl_13662, type, fn_phospholipid_80: $i > $i).
% 28.89/28.95  tff(decl_13663, type, physical_object_0: $i).
% 28.89/28.95  tff(decl_13664, type, "-50.0e0": $i).
% 28.89/28.95  tff(decl_13665, type, "-200.0e0": $i).
% 28.89/28.95  tff(decl_13666, type, fn_membrane_5: $i > $i).
% 28.89/28.95  tff(decl_13667, type, fn_membrane_4: $i > $i).
% 28.89/28.95  tff(decl_13668, type, fn_membrane_2: $i > $i).
% 28.89/28.95  tff(decl_13669, type, fn_membrane_1: $i > $i).
% 28.89/28.95  tff(decl_13670, type, fn_membrane_3: $i > $i).
% 28.89/28.95  tff(decl_13671, type, fn_biomembrane_104: $i > $i).
% 28.89/28.95  tff(decl_13672, type, fn_biomembrane_103: $i > $i).
% 28.89/28.95  tff(decl_13673, type, biomembrane_containing_double_lipid_bilayer_1: $i > $o).
% 28.89/28.95  tff(decl_13674, type, 'Biomembrane-Containing-Double-Lipid-Bilayer': $i).
% 28.89/28.95  tff(decl_13675, type, 'Biomembrane consisting of inner and outer membrane (each their own lipid bilayer).': $i).
% 28.89/28.95  tff(decl_13676, type, 'double membrane': $i).
% 28.89/28.95  tff(decl_13677, type, 'biomembrane containing double lipid bilayer': $i).
% 28.89/28.95  tff(decl_13678, type, 'biomembrane-containing-double-lipid-bilayer': $i).
% 28.89/28.95  tff(decl_13679, type, fn_biomembrane_containing_double_lipid_bilayer_1: $i > $i).
% 28.89/28.95  tff(decl_13680, type, outer_membrane_1: $i > $o).
% 28.89/28.95  tff(decl_13681, type, fn_biomembrane_containing_double_lipid_bilayer_2: $i > $i).
% 28.89/28.95  tff(decl_13682, type, inner_membrane_1: $i > $o).
% 28.89/28.95  tff(decl_13683, type, fn_biomembrane_containing_double_lipid_bilayer_3: $i > $i).
% 28.89/28.95  tff(decl_13684, type, fn_intermembrane_space_2: $i > $i).
% 28.89/28.95  tff(decl_13685, type, fn_intermembrane_space_1: $i > $i).
% 28.89/28.95  tff(decl_13686, type, phospholipid_bilayer_0: $i).
% 28.89/28.95  tff(decl_13687, type, biomolecular_process_1: $i > $o).
% 28.89/28.95  tff(decl_13688, type, 'Biomolecular-Process': $i).
% 28.89/28.95  tff(decl_13689, type, 'A process occuring within molecules that carry out the functions of life.': $i).
% 28.89/28.95  tff(decl_13690, type, 'biomolecular process': $i).
% 28.89/28.95  tff(decl_13691, type, 'biomolecular-process': $i).
% 28.89/28.95  tff(decl_13692, type, biophilia_1: $i > $o).
% 28.89/28.95  tff(decl_13693, type, 'Biophilia': $i).
% 28.89/28.95  tff(decl_13694, type, 'A state of appreciation for living things.': $i).
% 28.89/28.95  tff(decl_13695, type, biophilia: $i).
% 28.89/28.95  tff(decl_13696, type, 'Bioremediation': $i).
% 28.89/28.95  tff(decl_13697, type, 'The use of organisms\\ biochemical processes to removed pollutants from the environment and restore health to an ecosystem.': $i).
% 28.89/28.95  tff(decl_13698, type, 'perform bioremediation': $i).
% 28.89/28.95  tff(decl_13699, type, bioremediation: $i).
% 28.89/28.95  tff(decl_13700, type, fn_bioremediation_1: $i > $i).
% 28.89/28.95  tff(decl_13701, type, fn_bioremediation_2: $i > $i).
% 28.89/28.95  tff(decl_13702, type, fn_bioremediation_3: $i > $i).
% 28.89/28.95  tff(decl_13703, type, fn_bioremediation_4: $i > $i).
% 28.89/28.95  tff(decl_13704, type, fn_bioremediation_5: $i > $i).
% 28.89/28.95  tff(decl_13705, type, biosphere_1: $i > $o).
% 28.89/28.95  tff(decl_13706, type, 'Biosphere': $i).
% 28.89/28.95  tff(decl_13707, type, 'The global sum of all ecosystems on Earth.': $i).
% 28.89/28.95  tff(decl_13708, type, biosphere: $i).
% 28.89/28.95  tff(decl_13709, type, geographic_region_1: $i > $o).
% 28.89/28.95  tff(decl_13710, type, fn_biosphere_1: $i > $i).
% 28.89/28.95  tff(decl_13711, type, landscape_1: $i > $o).
% 28.89/28.95  tff(decl_13712, type, fn_biosphere_2: $i > $i).
% 28.89/28.95  tff(decl_13713, type, fn_biosphere_3: $i > $i).
% 28.89/28.95  tff(decl_13714, type, fn_biosphere_4: $i > $i).
% 28.89/28.95  tff(decl_13715, type, fn_biosphere_5: $i > $i).
% 28.89/28.95  tff(decl_13716, type, fn_biosphere_6: $i > $i).
% 28.89/28.95  tff(decl_13717, type, fn_chloroplast_79: $i > $i).
% 28.89/28.95  tff(decl_13718, type, fn_ecosystem_16: $i > $i).
% 28.89/28.95  tff(decl_13719, type, fn_ecosystem_15: $i > $i).
% 28.89/28.95  tff(decl_13720, type, ecosystem_0: $i).
% 28.89/28.95  tff(decl_13721, type, landscape_0: $i).
% 28.89/28.95  tff(decl_13722, type, 'Biotechnology': $i).
% 28.89/28.95  tff(decl_13723, type, 'The manipulation of organisms or their components to produce useful products.': $i).
% 28.89/28.95  tff(decl_13724, type, 'perform biotechnology': $i).
% 28.89/28.95  tff(decl_13725, type, biotechnology: $i).
% 28.89/28.95  tff(decl_13726, type, engineering_1: $i > $o).
% 28.89/28.95  tff(decl_13727, type, fn_biotechnology_1: $i > $i).
% 28.89/28.95  tff(decl_13728, type, fn_biotechnology_2: $i > $i).
% 28.89/28.95  tff(decl_13729, type, fn_biotechnology_3: $i > $i).
% 28.89/28.95  tff(decl_13730, type, fn_biotechnology_4: $i > $i).
% 28.89/28.95  tff(decl_13731, type, bioterrorism_1: $i > $o).
% 28.89/28.95  tff(decl_13732, type, 'Bioterrorism': $i).
% 28.89/28.95  tff(decl_13733, type, 'The deliberate release of pathogens or toxins into the environment, to cause fear or terror in individuals or populations.': $i).
% 28.89/28.95  tff(decl_13734, type, bioterrorism: $i).
% 28.89/28.95  tff(decl_13735, type, human_behavior_1: $i > $o).
% 28.89/28.95  tff(decl_13736, type, biotic_boundary_1: $i > $o).
% 28.89/28.95  tff(decl_13737, type, 'Biotic-Boundary': $i).
% 28.89/28.95  tff(decl_13738, type, 'The geographic area needed to sustain a particular organism, as opposed to a legal or political boundary.': $i).
% 28.89/28.95  tff(decl_13739, type, 'biotic boundary': $i).
% 28.89/28.95  tff(decl_13740, type, 'biotic-boundary': $i).
% 28.89/28.95  tff(decl_13741, type, 'Biotic-Factor': $i).
% 28.89/28.95  tff(decl_13742, type, 'Any living thing that affects other living things in an ecosystem.': $i).
% 28.89/28.95  tff(decl_13743, type, 'biotic factor': $i).
% 28.89/28.95  tff(decl_13744, type, 'biotic-factor': $i).
% 28.89/28.95  tff(decl_13745, type, bipedalism_1: $i > $o).
% 28.89/28.95  tff(decl_13746, type, 'Bipedalism': $i).
% 28.89/28.95  tff(decl_13747, type, 'The ability or practice of walking on two legs.': $i).
% 28.89/28.95  tff(decl_13748, type, bipedalism: $i).
% 28.89/28.95  tff(decl_13749, type, flight_1: $i > $o).
% 28.89/28.95  tff(decl_13750, type, 'Bipolar-Cell': $i).
% 28.89/28.95  tff(decl_13751, type, 'A neuron of the retina that sits between photoreceptor cells and ganglion cells, and transmits signals from the former to the latter.': $i).
% 28.89/28.95  tff(decl_13752, type, 'bipolar cell': $i).
% 28.89/28.95  tff(decl_13753, type, 'bipolar-cell': $i).
% 28.89/28.95  tff(decl_13754, type, 'Bipolar-Disorder': $i).
% 28.89/28.95  tff(decl_13755, type, 'A depressive mental illness characterized by swings of mood from high to low; also called manic-depressive disorder.': $i).
% 28.89/28.95  tff(decl_13756, type, 'bipolar disorder': $i).
% 28.89/28.95  tff(decl_13757, type, 'bipolar-disorder': $i).
% 28.89/28.95  tff(decl_13758, type, bird_1: $i > $o).
% 28.89/28.95  tff(decl_13759, type, 'Bird': $i).
% 28.89/28.95  tff(decl_13760, type, 'A member of a class of vertebrates characterized by wings, hollow bones, complex social behavior,  and a high metabolism adapted for flight.': $i).
% 28.89/28.95  tff(decl_13761, type, aves: $i).
% 28.89/28.95  tff(decl_13762, type, bird: $i).
% 28.89/28.95  tff(decl_13763, type, fn_bird_1: $i > $i).
% 28.89/28.95  tff(decl_13764, type, fn_bird_2: $i > $i).
% 28.89/28.95  tff(decl_13765, type, fn_bird_3: $i > $i).
% 28.89/28.95  tff(decl_13766, type, feather_1: $i > $o).
% 28.89/28.95  tff(decl_13767, type, fn_bird_4: $i > $i).
% 28.89/28.95  tff(decl_13768, type, fn_bird_5: $i > $i).
% 28.89/28.95  tff(decl_13769, type, molting_1: $i > $o).
% 28.89/28.95  tff(decl_13770, type, fn_bird_10: $i > $i).
% 28.89/28.95  tff(decl_13771, type, fn_bird_11: $i > $i).
% 28.89/28.95  tff(decl_13772, type, fn_bird_12: $i > $i).
% 28.89/28.95  tff(decl_13773, type, polymer_breakdown_1: $i > $o).
% 28.89/28.95  tff(decl_13774, type, fn_bird_13: $i > $i).
% 28.89/28.95  tff(decl_13775, type, fn_bird_14: $i > $i).
% 28.89/28.95  tff(decl_13776, type, fn_bird_15: $i > $i).
% 28.89/28.95  tff(decl_13777, type, fn_bird_16: $i > $i).
% 28.89/28.95  tff(decl_13778, type, fn_bird_17: $i > $i).
% 28.89/28.95  tff(decl_13779, type, fn_bird_18: $i > $i).
% 28.89/28.95  tff(decl_13780, type, fn_bird_19: $i > $i).
% 28.89/28.95  tff(decl_13781, type, cellulase_1: $i > $o).
% 28.89/28.95  tff(decl_13782, type, fn_bird_20: $i > $i).
% 28.89/28.95  tff(decl_13783, type, fn_bird_21: $i > $i).
% 28.89/28.95  tff(decl_13784, type, fn_bird_22: $i > $i).
% 28.89/28.95  tff(decl_13785, type, fn_bird_23: $i > $i).
% 28.89/28.95  tff(decl_13786, type, fn_bird_24: $i > $i).
% 28.89/28.95  tff(decl_13787, type, fn_bird_25: $i > $i).
% 28.89/28.95  tff(decl_13788, type, fn_bird_26: $i > $i).
% 28.89/28.95  tff(decl_13789, type, fn_bird_27: $i > $i).
% 28.89/28.95  tff(decl_13790, type, fn_bird_28: $i > $i).
% 28.89/28.95  tff(decl_13791, type, fn_bird_29: $i > $i).
% 28.89/28.95  tff(decl_13792, type, fn_bird_30: $i > $i).
% 28.89/28.95  tff(decl_13793, type, fn_bird_31: $i > $i).
% 28.89/28.95  tff(decl_13794, type, fn_bird_32: $i > $i).
% 28.89/28.95  tff(decl_13795, type, fn_bird_33: $i > $i).
% 28.89/28.95  tff(decl_13796, type, fn_bird_34: $i > $i).
% 28.89/28.95  tff(decl_13797, type, fn_bird_35: $i > $i).
% 28.89/28.95  tff(decl_13798, type, fn_bird_36: $i > $i).
% 28.89/28.95  tff(decl_13799, type, fn_bird_37: $i > $i).
% 28.89/28.95  tff(decl_13800, type, fn_bird_38: $i > $i).
% 28.89/28.95  tff(decl_13801, type, fn_bird_39: $i > $i).
% 28.89/28.95  tff(decl_13802, type, fn_bird_40: $i > $i).
% 28.89/28.95  tff(decl_13803, type, fn_bird_41: $i > $i).
% 28.89/28.95  tff(decl_13804, type, fn_bird_42: $i > $i).
% 28.89/28.95  tff(decl_13805, type, fn_bird_43: $i > $i).
% 28.89/28.95  tff(decl_13806, type, fn_bird_44: $i > $i).
% 28.89/28.95  tff(decl_13807, type, fn_bird_45: $i > $i).
% 28.89/28.95  tff(decl_13808, type, fn_bird_46: $i > $i).
% 28.89/28.95  tff(decl_13809, type, fn_bird_47: $i > $i).
% 28.89/28.95  tff(decl_13810, type, fn_bird_48: $i > $i).
% 28.89/28.95  tff(decl_13811, type, fn_bird_49: $i > $i).
% 28.89/28.95  tff(decl_13812, type, specialised_organ_0: $i).
% 28.89/28.95  tff(decl_13813, type, protein_0: $i).
% 28.89/28.95  tff(decl_13814, type, fn_vertebrate_20: $i > $i).
% 28.89/28.95  tff(decl_13815, type, fn_bird_8: $i > $i).
% 28.89/28.95  tff(decl_13816, type, fn_vertebrate_60: $i > $i).
% 28.89/28.95  tff(decl_13817, type, fn_vertebrate_3: $i > $i).
% 28.89/28.95  tff(decl_13818, type, fn_vertebrate_24: $i > $i).
% 28.89/28.95  tff(decl_13819, type, fn_vertebrate_23: $i > $i).
% 28.89/28.95  tff(decl_13820, type, fn_vertebrate_41: $i > $i).
% 28.89/28.95  tff(decl_13821, type, fn_vertebrate_55: $i > $i).
% 28.89/28.95  tff(decl_13822, type, fn_vertebrate_34: $i > $i).
% 28.89/28.95  tff(decl_13823, type, fn_vertebrate_47: $i > $i).
% 28.89/28.95  tff(decl_13824, type, fn_vertebrate_2: $i > $i).
% 28.89/28.95  tff(decl_13825, type, fn_vertebrate_53: $i > $i).
% 28.89/28.95  tff(decl_13826, type, fn_vertebrate_48: $i > $i).
% 28.89/28.95  tff(decl_13827, type, fn_vertebrate_35: $i > $i).
% 28.89/28.95  tff(decl_13828, type, fn_vertebrate_33: $i > $i).
% 28.89/28.95  tff(decl_13829, type, fn_vertebrate_25: $i > $i).
% 28.89/28.95  tff(decl_13830, type, fn_vertebrate_56: $i > $i).
% 28.89/28.95  tff(decl_13831, type, fn_vertebrate_16: $i > $i).
% 28.89/28.95  tff(decl_13832, type, fn_vertebrate_59: $i > $i).
% 28.89/28.95  tff(decl_13833, type, fn_vertebrate_15: $i > $i).
% 28.89/28.95  tff(decl_13834, type, fn_vertebrate_17: $i > $i).
% 28.89/28.95  tff(decl_13835, type, fn_bird_9: $i > $i).
% 28.89/28.95  tff(decl_13836, type, fn_vertebrate_61: $i > $i).
% 28.89/28.95  tff(decl_13837, type, fn_vertebrate_54: $i > $i).
% 28.89/28.95  tff(decl_13838, type, fn_vertebrate_57: $i > $i).
% 28.89/28.95  tff(decl_13839, type, fn_vertebrate_58: $i > $i).
% 28.89/28.95  tff(decl_13840, type, fn_vertebrate_18: $i > $i).
% 28.89/28.95  tff(decl_13841, type, fn_vertebrate_19: $i > $i).
% 28.89/28.95  tff(decl_13842, type, fn_vertebrate_4: $i > $i).
% 28.89/28.95  tff(decl_13843, type, fn_vertebrate_26: $i > $i).
% 28.89/28.95  tff(decl_13844, type, fn_vertebrate_40: $i > $i).
% 28.89/28.95  tff(decl_13845, type, fn_vertebrate_5: $i > $i).
% 28.89/28.95  tff(decl_13846, type, fn_vertebrate_6: $i > $i).
% 28.89/28.95  tff(decl_13847, type, bird_digestive_system_1: $i > $o).
% 28.89/28.95  tff(decl_13848, type, 'Bird-Digestive-System': $i).
% 28.89/28.95  tff(decl_13849, type, 'A system of organs in a bird\\s body which is responsible for the digestion and absorption of nutrients from food.': $i).
% 28.89/28.95  tff(decl_13850, type, 'bird digestive system': $i).
% 28.89/28.95  tff(decl_13851, type, 'bird-digestive-system': $i).
% 28.89/28.95  tff(decl_13852, type, bird_homeotic_gene_1: $i > $o).
% 28.89/28.95  tff(decl_13853, type, 'Bird-Homeotic-Gene': $i).
% 28.89/28.95  tff(decl_13854, type, 'Homeotic gene present in birds.': $i).
% 28.89/28.95  tff(decl_13855, type, 'bird homeotic gene': $i).
% 28.89/28.95  tff(decl_13856, type, 'bird-homeotic-gene': $i).
% 28.89/28.95  tff(decl_13857, type, vertebrate_homeotic_gene_1: $i > $o).
% 28.89/28.95  tff(decl_13858, type, fn_bird_homeotic_gene_1: $i > $i).
% 28.89/28.95  tff(decl_13859, type, fn_bird_homeotic_gene_2: $i > $i).
% 28.89/28.95  tff(decl_13860, type, fn_vertebrate_homeotic_gene_18: $i > $i).
% 28.89/28.95  tff(decl_13861, type, fn_vertebrate_homeotic_gene_20: $i > $i).
% 28.89/28.95  tff(decl_13862, type, bird_limb_development_1: $i > $o).
% 28.89/28.95  tff(decl_13863, type, 'Bird-Limb-Development': $i).
% 28.89/28.95  tff(decl_13864, type, 'The processes which direct the formation of the limbs during the embryonic development of a bird.': $i).
% 28.89/28.95  tff(decl_13865, type, 'bird limb development': $i).
% 28.89/28.95  tff(decl_13866, type, 'bird-limb-development': $i).
% 28.89/28.95  tff(decl_13867, type, limb_development_1: $i > $o).
% 28.89/28.95  tff(decl_13868, type, fn_bird_limb_development_1: $i > $i).
% 28.89/28.95  tff(decl_13869, type, fn_bird_limb_development_2: $i > $i).
% 28.89/28.95  tff(decl_13870, type, fn_bird_limb_development_3: $i > $i).
% 28.89/28.95  tff(decl_13871, type, toe_1: $i > $o).
% 28.89/28.95  tff(decl_13872, type, fn_bird_limb_development_5: $i > $i).
% 28.89/28.95  tff(decl_13873, type, fn_bird_limb_development_6: $i > $i).
% 28.89/28.95  tff(decl_13874, type, fn_bird_limb_development_7: $i > $i).
% 28.89/28.95  tff(decl_13875, type, fn_bird_limb_development_8: $i > $i).
% 28.89/28.95  tff(decl_13876, type, fn_bird_limb_development_9: $i > $i).
% 28.89/28.95  tff(decl_13877, type, fn_bird_limb_development_10: $i > $i).
% 28.89/28.95  tff(decl_13878, type, fn_bird_limb_development_11: $i > $i).
% 28.89/28.95  tff(decl_13879, type, fn_bird_limb_development_12: $i > $i).
% 28.89/28.95  tff(decl_13880, type, fn_bird_limb_development_13: $i > $i).
% 28.89/28.95  tff(decl_13881, type, fn_bird_limb_development_14: $i > $i).
% 28.89/28.95  tff(decl_13882, type, fn_bird_limb_development_15: $i > $i).
% 28.89/28.95  tff(decl_13883, type, fn_bird_limb_development_16: $i > $i).
% 28.89/28.95  tff(decl_13884, type, fn_bird_limb_development_17: $i > $i).
% 28.89/28.95  tff(decl_13885, type, fn_bird_limb_development_18: $i > $i).
% 28.89/28.95  tff(decl_13886, type, fn_bird_limb_development_19: $i > $i).
% 28.89/28.95  tff(decl_13887, type, fn_bird_limb_development_20: $i > $i).
% 28.89/28.95  tff(decl_13888, type, fn_bird_limb_development_21: $i > $i).
% 28.89/28.95  tff(decl_13889, type, fn_bird_limb_development_22: $i > $i).
% 28.89/28.95  tff(decl_13890, type, fn_bird_limb_development_23: $i > $i).
% 28.89/28.95  tff(decl_13891, type, fn_bird_limb_development_24: $i > $i).
% 28.89/28.95  tff(decl_13892, type, fn_bird_limb_development_25: $i > $i).
% 28.89/28.95  tff(decl_13893, type, fn_bird_limb_development_26: $i > $i).
% 28.89/28.95  tff(decl_13894, type, fn_bird_limb_development_27: $i > $i).
% 28.89/28.95  tff(decl_13895, type, fn_bird_limb_development_28: $i > $i).
% 28.89/28.95  tff(decl_13896, type, fn_bird_limb_development_29: $i > $i).
% 28.89/28.95  tff(decl_13897, type, fn_bird_limb_development_30: $i > $i).
% 28.89/28.95  tff(decl_13898, type, fn_bird_limb_development_33: $i > $i).
% 28.89/28.95  tff(decl_13899, type, fn_bird_limb_development_34: $i > $i).
% 28.89/28.95  tff(decl_13900, type, interdigital_tissue_1: $i > $o).
% 28.89/28.95  tff(decl_13901, type, fn_bird_limb_development_35: $i > $i).
% 28.89/28.95  tff(decl_13902, type, fn_intracellular_digestion_11: $i > $i).
% 28.89/28.95  tff(decl_13903, type, fn_limb_development_11: $i > $i).
% 28.89/28.95  tff(decl_13904, type, fn_limb_development_1: $i > $i).
% 28.89/28.95  tff(decl_13905, type, fn_limb_development_9: $i > $i).
% 28.89/28.95  tff(decl_13906, type, fn_limb_development_14: $i > $i).
% 28.89/28.95  tff(decl_13907, type, fn_limb_development_13: $i > $i).
% 28.89/28.95  tff(decl_13908, type, fn_limb_development_10: $i > $i).
% 28.89/28.95  tff(decl_13909, type, fn_bird_limb_development_31: $i > $i).
% 28.89/28.95  tff(decl_13910, type, fn_bird_limb_development_32: $i > $i).
% 28.89/28.95  tff(decl_13911, type, bird_song_1: $i > $o).
% 28.89/28.95  tff(decl_13912, type, 'Bird-Song': $i).
% 28.89/28.95  tff(decl_13913, type, 'Vocalizations used by birds to mark territory and advertise for mates.': $i).
% 28.89/28.95  tff(decl_13914, type, 'song of bird': $i).
% 28.89/28.95  tff(decl_13915, type, 'bird song': $i).
% 28.89/28.95  tff(decl_13916, type, 'bird-song': $i).
% 28.89/28.95  tff(decl_13917, type, language_1: $i > $o).
% 28.89/28.95  tff(decl_13918, type, natural_language_1: $i > $o).
% 28.89/28.95  tff(decl_13919, type, birth_control_1: $i > $o).
% 28.89/28.95  tff(decl_13920, type, 'Birth-Control': $i).
% 28.89/28.95  tff(decl_13921, type, 'The use of medications, devices, or sexual practices to prevent or reduce the probability of conception and pregnancy.': $i).
% 28.89/28.95  tff(decl_13922, type, 'control of birth': $i).
% 28.89/28.95  tff(decl_13923, type, 'birth control': $i).
% 28.89/28.95  tff(decl_13924, type, 'birth-control': $i).
% 28.89/28.95  tff(decl_13925, type, reproductive_behavior_1: $i > $o).
% 28.89/28.95  tff(decl_13926, type, birth_control_pill_1: $i > $o).
% 28.89/28.95  tff(decl_13927, type, 'Birth-Control-Pill': $i).
% 28.89/28.95  tff(decl_13928, type, 'A pill containing estrogen and/or progesterone that, when taken correctly, inhibits ovulation and thus acts an a contraceptive.': $i).
% 28.89/28.95  tff(decl_13929, type, 'birth control pill': $i).
% 28.89/28.95  tff(decl_13930, type, 'birth-control-pill': $i).
% 28.89/28.95  tff(decl_13931, type, prezygotic_barrier_1: $i > $o).
% 28.89/28.95  tff(decl_13932, type, reproductive_barrier_method_1: $i > $o).
% 28.89/28.95  tff(decl_13933, type, bismuth_1: $i > $o).
% 28.89/28.95  tff(decl_13934, type, 'Bismuth': $i).
% 28.89/28.95  tff(decl_13935, type, 'Bismuth is a metal atom with atomic number 83. It is represented by the symbol Bi.': $i).
% 28.89/28.95  tff(decl_13936, type, bismuth: $i).
% 28.89/28.95  tff(decl_13937, type, 'Bi': $i).
% 28.89/28.95  tff(decl_13938, type, fn_bismuth_3: $i > $i).
% 28.89/28.95  tff(decl_13939, type, fn_bismuth_4: $i > $i).
% 28.89/28.95  tff(decl_13940, type, fn_bismuth_5: $i > $i).
% 28.89/28.95  tff(decl_13941, type, fn_bismuth_9: $i > $i).
% 28.89/28.95  tff(decl_13942, type, fn_bismuth_10: $i > $i).
% 28.89/28.95  tff(decl_13943, type, fn_bismuth_11: $i > $i).
% 28.89/28.95  tff(decl_13944, type, fn_bismuth_12: $i > $i).
% 28.89/28.95  tff(decl_13945, type, "126": $i).
% 28.89/28.95  tff(decl_13946, type, "83": $i).
% 28.89/28.95  tff(decl_13947, type, "2.02": $i).
% 28.89/28.95  tff(decl_13948, type, "209": $i).
% 28.89/28.95  tff(decl_13949, type, fn_bismuth_7: $i > $i).
% 28.89/28.95  tff(decl_13950, type, fn_bismuth_8: $i > $i).
% 28.89/28.95  tff(decl_13951, type, fn_bismuth_6: $i > $i).
% 28.89/28.95  tff(decl_13952, type, bivalve_1: $i > $o).
% 28.89/28.95  tff(decl_13953, type, 'Bivalve': $i).
% 28.89/28.95  tff(decl_13954, type, 'A mollusc of the Class Bivalvia; examples include mussels, clams, oysters, and scallops.': $i).
% 28.89/28.95  tff(decl_13955, type, bivalve: $i).
% 28.89/28.95  tff(decl_13956, type, cephalopod_1: $i > $o).
% 28.89/28.95  tff(decl_13957, type, chiton_1: $i > $o).
% 28.89/28.95  tff(decl_13958, type, gastropod_1: $i > $o).
% 28.89/28.95  tff(decl_13959, type, black_bread_mold_1: $i > $o).
% 28.89/28.95  tff(decl_13960, type, 'Black-Bread-Mold': $i).
% 28.89/28.95  tff(decl_13961, type, 'A widely distributed zygomycete fungus, Rhizopus stolonifer, commonly found on the surface of bread.': $i).
% 28.89/28.95  tff(decl_13962, type, 'black bread mold': $i).
% 28.89/28.95  tff(decl_13963, type, 'black-bread-mold': $i).
% 28.89/28.95  tff(decl_13964, type, bread_mold_1: $i > $o).
% 28.89/28.95  tff(decl_13965, type, blade_1: $i > $o).
% 28.89/28.95  tff(decl_13966, type, 'Blade': $i).
% 28.89/28.95  tff(decl_13967, type, 'The thin, flattened structure of a seaweed that provides a majority of the surface area for photosynthesis. Also, the most flattened part of the leaf of a plant.': $i).
% 28.89/28.95  tff(decl_13968, type, blade: $i).
% 28.89/28.95  tff(decl_13969, type, 'Blastocoel': $i).
% 28.89/28.95  tff(decl_13970, type, 'The hollow, fluid-filled space that forms in the center of a blastula in early animal development.': $i).
% 28.89/28.95  tff(decl_13971, type, blastocoel: $i).
% 28.89/28.95  tff(decl_13972, type, blastocyst_1: $i > $o).
% 28.89/28.95  tff(decl_13973, type, 'Blastocyst': $i).
% 28.89/28.95  tff(decl_13974, type, 'The term used for the blastula stage in mammals and other vertebrates.': $i).
% 28.89/28.95  tff(decl_13975, type, blastocyst: $i).
% 28.89/28.95  tff(decl_13976, type, embryonic_stages_1: $i > $o).
% 28.89/28.95  tff(decl_13977, type, fn_blastocyst_1: $i > $i).
% 28.89/28.95  tff(decl_13978, type, blastodisc_1: $i > $o).
% 28.89/28.95  tff(decl_13979, type, 'Blastodisc': $i).
% 28.89/28.95  tff(decl_13980, type, 'In bird eggs, a cap of cells developed in early cleavage that sits on the yolk.': $i).
% 28.89/28.95  tff(decl_13981, type, blastodisc: $i).
% 28.89/28.95  tff(decl_13982, type, ensemble_1: $i > $o).
% 28.89/28.95  tff(decl_13983, type, blastomere_1: $i > $o).
% 28.89/28.95  tff(decl_13984, type, 'Blastomere': $i).
% 28.89/28.95  tff(decl_13985, type, 'A cell that derives from a cleavage division in early animal development.': $i).
% 28.89/28.95  tff(decl_13986, type, blastomere: $i).
% 28.89/28.95  tff(decl_13987, type, 'Blastopore': $i).
% 28.89/28.95  tff(decl_13988, type, 'In a gastrulating embryo, the opening to the archenteron. In protostomous animals the blastopore develops into the larval mouth, while in deuterostomous animals it develops into the anus.': $i).
% 28.89/28.95  tff(decl_13989, type, blastopore: $i).
% 28.89/28.95  tff(decl_13990, type, blastula_1: $i > $o).
% 28.89/28.95  tff(decl_13991, type, 'Blastula': $i).
% 28.89/28.95  tff(decl_13992, type, 'A hollow ball of cells created by cleavage divisions in the early embryonic development of animals.': $i).
% 28.89/28.95  tff(decl_13993, type, 'blastula stage': $i).
% 28.89/28.95  tff(decl_13994, type, blastula: $i).
% 28.89/28.95  tff(decl_13995, type, fn_blastula_1: $i > $i).
% 28.89/28.95  tff(decl_13996, type, fn_blastula_2: $i > $i).
% 28.89/28.95  tff(decl_13997, type, fluid_substance_1: $i > $o).
% 28.89/28.95  tff(decl_13998, type, fn_blastula_3: $i > $i).
% 28.89/28.95  tff(decl_13999, type, fn_blastula_4: $i > $i).
% 28.89/28.95  tff(decl_14000, type, 'Blastulation': $i).
% 28.89/28.95  tff(decl_14001, type, 'A stage of development in which a blastula is formed when the zygote unergoes cell division is called as blastula stage.': $i).
% 28.89/28.95  tff(decl_14002, type, 'undergo blastulation': $i).
% 28.89/28.95  tff(decl_14003, type, blastulation: $i).
% 28.89/28.95  tff(decl_14004, type, fn_blastulation_1: $i > $i).
% 28.89/28.95  tff(decl_14005, type, 'Blebbing': $i).
% 28.89/28.95  tff(decl_14006, type, 'During apoptosis, a process in which the cytoskeleton detaches from the plasma membrane, creating bulges in the cell called blebs. These blebs will later rupture as the cell dies.': $i).
% 28.89/28.95  tff(decl_14007, type, blebbing: $i).
% 28.89/28.95  tff(decl_14008, type, fn_blebbing_3: $i > $i).
% 28.89/28.95  tff(decl_14009, type, fn_blebbing_4: $i > $i).
% 28.89/28.95  tff(decl_14010, type, lobe_1: $i > $o).
% 28.89/28.95  tff(decl_14011, type, 'Block': $i).
% 28.89/28.95  tff(decl_14012, type, block: $i).
% 28.89/28.95  tff(decl_14013, type, bar: $i).
% 28.89/28.95  tff(decl_14014, type, barricade: $i).
% 28.89/28.95  tff(decl_14015, type, 'block off': $i).
% 28.89/28.95  tff(decl_14016, type, block_off: $i).
% 28.89/28.95  tff(decl_14017, type, 'block up': $i).
% 28.89/28.95  tff(decl_14018, type, block_up: $i).
% 28.89/28.95  tff(decl_14019, type, blockade: $i).
% 28.89/28.95  tff(decl_14020, type, 'choke up': $i).
% 28.89/28.95  tff(decl_14021, type, choke_up: $i).
% 28.89/28.95  tff(decl_14022, type, 'close up': $i).
% 28.89/28.95  tff(decl_14023, type, close_up: $i).
% 28.89/28.95  tff(decl_14024, type, impede: $i).
% 28.89/28.95  tff(decl_14025, type, jam: $i).
% 28.89/28.95  tff(decl_14026, type, lug: $i).
% 28.89/28.95  tff(decl_14027, type, obstruct: $i).
% 28.89/28.95  tff(decl_14028, type, occlude: $i).
% 28.89/28.95  tff(decl_14029, type, stuff: $i).
% 28.89/28.95  tff(decl_14030, type, occulude: $i).
% 28.89/28.95  tff(decl_14031, type, make_inaccessible_1: $i > $o).
% 28.89/28.95  tff(decl_14032, type, fn_make_inaccessible_1: $i > $i).
% 28.89/28.95  tff(decl_14033, type, blocking_of_cell_cycle_1: $i > $o).
% 28.89/28.95  tff(decl_14034, type, 'Blocking-of-cell-cycle': $i).
% 28.89/28.95  tff(decl_14035, type, 'The stopping of the cell cycle.': $i).
% 28.89/28.95  tff(decl_14036, type, 'blocking of cell cycle': $i).
% 28.89/28.95  tff(decl_14037, type, 'blocking-of-cell-cycle': $i).
% 28.89/28.95  tff(decl_14038, type, blood_1: $i > $o).
% 28.89/28.95  tff(decl_14039, type, 'Blood': $i).
% 28.89/28.95  tff(decl_14040, type, 'A type of connective tissue.  In humans, blood consists of red blood cells, white blood cells, and platelets suspended in a fluid matrix called plasma; blood circulates nutrients, wastes, respiratory gases, and hormones throughout the body.': $i).
% 28.89/28.95  tff(decl_14041, type, blood: $i).
% 28.89/28.95  tff(decl_14042, type, fn_blood_3: $i > $i).
% 28.89/28.95  tff(decl_14043, type, fn_blood_4: $i > $i).
% 28.89/28.95  tff(decl_14044, type, fn_blood_5: $i > $i).
% 28.89/28.95  tff(decl_14045, type, calcium_ion_1: $i > $o).
% 28.89/28.95  tff(decl_14046, type, fn_blood_6: $i > $i).
% 28.89/28.95  tff(decl_14047, type, fn_blood_7: $i > $i).
% 28.89/28.95  tff(decl_14048, type, clotting_factor_1: $i > $o).
% 28.89/28.95  tff(decl_14049, type, fn_blood_8: $i > $i).
% 28.89/28.95  tff(decl_14050, type, fn_blood_9: $i > $i).
% 28.89/28.95  tff(decl_14051, type, fn_blood_10: $i > $i).
% 28.89/28.95  tff(decl_14052, type, fn_blood_12: $i > $i).
% 28.89/28.95  tff(decl_14053, type, fn_blood_14: $i > $i).
% 28.89/28.95  tff(decl_14054, type, fn_blood_15: $i > $i).
% 28.89/28.95  tff(decl_14055, type, fn_blood_16: $i > $i).
% 28.89/28.95  tff(decl_14056, type, fn_blood_17: $i > $i).
% 28.89/28.95  tff(decl_14057, type, fn_blood_18: $i > $i).
% 28.89/28.95  tff(decl_14058, type, fn_blood_19: $i > $i).
% 28.89/28.95  tff(decl_14059, type, ph_maintenance_1: $i > $o).
% 28.89/28.95  tff(decl_14060, type, fn_blood_21: $i > $i).
% 28.89/28.95  tff(decl_14061, type, carbonic_acid_bicarbonate_buffer_1: $i > $o).
% 28.89/28.95  tff(decl_14062, type, fn_blood_22: $i > $i).
% 28.89/28.95  tff(decl_14063, type, solid_substance_1: $i > $o).
% 28.89/28.95  tff(decl_14064, type, fn_blood_23: $i > $i).
% 28.89/28.95  tff(decl_14065, type, erythrocyte_1: $i > $o).
% 28.89/28.95  tff(decl_14066, type, fn_blood_24: $i > $i).
% 28.89/28.95  tff(decl_14067, type, fn_blood_25: $i > $i).
% 28.89/28.95  tff(decl_14068, type, polar_substance_1: $i > $o).
% 28.89/28.95  tff(decl_14069, type, fn_blood_26: $i > $i).
% 28.89/28.95  tff(decl_14070, type, fn_buffered_solution_2: $i > $i).
% 28.89/28.95  tff(decl_14071, type, buffer_1: $i > $o).
% 28.89/28.95  tff(decl_14072, type, fn_buffer_3: $i > $i).
% 28.89/28.95  tff(decl_14073, type, 'Concentration_Ca2PlusRedbloodCell': $i).
% 28.89/28.95  tff(decl_14074, type, 'Concentration_Ca2PlusBlood': $i).
% 28.89/28.95  tff(decl_14075, type, fn_suspension_2: $i > $i).
% 28.89/28.95  tff(decl_14076, type, fn_suspension_1: $i > $i).
% 28.89/28.95  tff(decl_14077, type, fn_blood_20: $i > $i).
% 28.89/28.95  tff(decl_14078, type, fn_liquid_substance_1: $i > $i).
% 28.89/28.95  tff(decl_14079, type, fn_liquid_substance_2: $i > $i).
% 28.89/28.95  tff(decl_14080, type, fn_blood_11: $i > $i).
% 28.89/28.95  tff(decl_14081, type, fn_aqueous_solution_1: $i > $i).
% 28.89/28.95  tff(decl_14082, type, fn_blood_13: $i > $i).
% 28.89/28.95  tff(decl_14083, type, fn_aqueous_solution_9: $i > $i).
% 28.89/28.95  tff(decl_14084, type, 'Blood-Allele': $i).
% 28.89/28.95  tff(decl_14085, type, 'An allele coding for one of carbohydrates attached to the membrane surface of a red blood cell that determe the organism\\s blood group.': $i).
% 28.89/28.95  tff(decl_14086, type, 'allele of blood': $i).
% 28.89/28.95  tff(decl_14087, type, 'blood allele': $i).
% 28.89/28.95  tff(decl_14088, type, 'blood-allele': $i).
% 28.89/28.95  tff(decl_14089, type, blood_brain_barrier_1: $i > $o).
% 28.89/28.95  tff(decl_14090, type, 'Blood-Brain-Barrier': $i).
% 28.89/28.95  tff(decl_14091, type, 'A specialized system of capillary endothelial cells that protects the brain from harmful substances in the blood stream, while supplying the brain with the required nutrients for proper function.': $i).
% 28.89/28.95  tff(decl_14092, type, 'blood brain barrier': $i).
% 28.89/28.95  tff(decl_14093, type, 'blood-brain barrier': $i).
% 28.89/28.95  tff(decl_14094, type, 'blood-brain-barrier': $i).
% 28.89/28.95  tff(decl_14095, type, 'Blood-Carbohydrate': $i).
% 28.89/28.95  tff(decl_14096, type, 'A sugar (monosaccharide) or one of its dimers (disaccharides) or polymers (polysaccharides) that is attached to the membrane surface of a red blood cell.': $i).
% 28.89/28.95  tff(decl_14097, type, 'carbohydrate of blood': $i).
% 28.89/28.95  tff(decl_14098, type, 'blood carbohydrate': $i).
% 28.89/28.95  tff(decl_14099, type, 'blood-carbohydrate': $i).
% 28.89/28.95  tff(decl_14100, type, fn_blood_carbohydrate_1: $i > $i).
% 28.89/28.95  tff(decl_14101, type, fn_blood_carbohydrate_2: $i > $i).
% 28.89/28.95  tff(decl_14102, type, fn_blood_carbohydrate_4: $i > $i).
% 28.89/28.95  tff(decl_14103, type, fn_blood_carbohydrate_5: $i > $i).
% 28.89/28.95  tff(decl_14104, type, fn_blood_carbohydrate_6: $i > $i).
% 28.89/28.95  tff(decl_14105, type, fn_blood_carbohydrate_7: $i > $i).
% 28.89/28.95  tff(decl_14106, type, fn_blood_carbohydrate_8: $i > $i).
% 28.89/28.95  tff(decl_14107, type, fn_blood_carbohydrate_9: $i > $i).
% 28.89/28.95  tff(decl_14108, type, fn_blood_carbohydrate_10: $i > $i).
% 28.89/28.95  tff(decl_14109, type, fn_blood_carbohydrate_11: $i > $i).
% 28.89/28.95  tff(decl_14110, type, fn_blood_carbohydrate_12: $i > $i).
% 28.89/28.95  tff(decl_14111, type, fn_blood_carbohydrate_13: $i > $i).
% 28.89/28.95  tff(decl_14112, type, fn_blood_carbohydrate_14: $i > $i).
% 28.89/28.95  tff(decl_14113, type, fn_blood_carbohydrate_15: $i > $i).
% 28.89/28.95  tff(decl_14114, type, fn_blood_carbohydrate_16: $i > $i).
% 28.89/28.95  tff(decl_14115, type, fn_blood_carbohydrate_17: $i > $i).
% 28.89/28.95  tff(decl_14116, type, fn_blood_carbohydrate_18: $i > $i).
% 28.89/28.95  tff(decl_14117, type, fn_blood_carbohydrate_19: $i > $i).
% 28.89/28.95  tff(decl_14118, type, fn_blood_carbohydrate_20: $i > $i).
% 28.89/28.95  tff(decl_14119, type, fn_blood_carbohydrate_21: $i > $i).
% 28.89/28.95  tff(decl_14120, type, fn_blood_carbohydrate_22: $i > $i).
% 28.89/28.95  tff(decl_14121, type, fn_blood_carbohydrate_23: $i > $i).
% 28.89/28.95  tff(decl_14122, type, fn_blood_carbohydrate_24: $i > $i).
% 28.89/28.95  tff(decl_14123, type, fn_blood_carbohydrate_25: $i > $i).
% 28.89/28.95  tff(decl_14124, type, fn_blood_carbohydrate_26: $i > $i).
% 28.89/28.95  tff(decl_14125, type, fn_blood_carbohydrate_27: $i > $i).
% 28.89/28.95  tff(decl_14126, type, fn_blood_carbohydrate_28: $i > $i).
% 28.89/28.95  tff(decl_14127, type, fn_blood_carbohydrate_29: $i > $i).
% 28.89/28.95  tff(decl_14128, type, fn_blood_carbohydrate_30: $i > $i).
% 28.89/28.95  tff(decl_14129, type, fn_blood_carbohydrate_31: $i > $i).
% 28.89/28.95  tff(decl_14130, type, fn_blood_carbohydrate_32: $i > $i).
% 28.89/28.95  tff(decl_14131, type, fn_blood_carbohydrate_33: $i > $i).
% 28.89/28.95  tff(decl_14132, type, fn_blood_carbohydrate_34: $i > $i).
% 28.89/28.95  tff(decl_14133, type, fn_carbonyl_group_5: $i > $i).
% 28.89/28.95  tff(decl_14134, type, fn_polar_covalent_bond_3: $i > $i).
% 28.89/28.95  tff(decl_14135, type, fn_polar_covalent_bond_2: $i > $i).
% 28.89/28.95  tff(decl_14136, type, fn_polar_covalent_bond_1: $i > $i).
% 28.89/28.95  tff(decl_14137, type, fn_polar_covalent_bond_11: $i > $i).
% 28.89/28.95  tff(decl_14138, type, fn_polar_covalent_bond_12: $i > $i).
% 28.89/28.95  tff(decl_14139, type, "2.1": $i).
% 28.89/28.95  tff(decl_14140, type, fn_oligosaccharide_5: $i > $i).
% 28.89/28.95  tff(decl_14141, type, fn_oligosaccharide_10: $i > $i).
% 28.89/28.95  tff(decl_14142, type, fn_oligosaccharide_3: $i > $i).
% 28.89/28.95  tff(decl_14143, type, fn_oligosaccharide_2: $i > $i).
% 28.89/28.95  tff(decl_14144, type, fn_oligosaccharide_9: $i > $i).
% 28.89/28.95  tff(decl_14145, type, fn_oligosaccharide_4: $i > $i).
% 28.89/28.95  tff(decl_14146, type, fn_blood_carbohydrate_35: $i > $i).
% 28.89/28.95  tff(decl_14147, type, fn_carbohydrate_side_chain_19: $i > $i).
% 28.89/28.95  tff(decl_14148, type, fn_blood_carbohydrate_36: $i > $i).
% 28.89/28.95  tff(decl_14149, type, fn_carbohydrate_side_chain_21: $i > $i).
% 28.89/28.95  tff(decl_14150, type, fn_blood_carbohydrate_37: $i > $i).
% 28.89/28.95  tff(decl_14151, type, fn_carbohydrate_side_chain_20: $i > $i).
% 28.89/28.95  tff(decl_14152, type, fn_carbohydrate_side_chain_32: $i > $i).
% 28.89/28.95  tff(decl_14153, type, fn_carbohydrate_side_chain_12: $i > $i).
% 28.89/28.95  tff(decl_14154, type, fn_carbohydrate_side_chain_26: $i > $i).
% 28.89/28.95  tff(decl_14155, type, fn_carbohydrate_side_chain_27: $i > $i).
% 28.89/28.95  tff(decl_14156, type, fn_carbohydrate_side_chain_36: $i > $i).
% 28.89/28.95  tff(decl_14157, type, fn_carbohydrate_side_chain_30: $i > $i).
% 28.89/28.95  tff(decl_14158, type, fn_carbohydrate_side_chain_35: $i > $i).
% 28.89/28.95  tff(decl_14159, type, fn_carbohydrate_side_chain_37: $i > $i).
% 28.89/28.95  tff(decl_14160, type, fn_carbohydrate_side_chain_34: $i > $i).
% 28.89/28.95  tff(decl_14161, type, fn_carbohydrate_side_chain_28: $i > $i).
% 28.89/28.95  tff(decl_14162, type, fn_carbohydrate_side_chain_23: $i > $i).
% 28.89/28.95  tff(decl_14163, type, fn_carbohydrate_side_chain_31: $i > $i).
% 28.89/28.95  tff(decl_14164, type, fn_carbohydrate_side_chain_22: $i > $i).
% 28.89/28.95  tff(decl_14165, type, fn_carbohydrate_side_chain_25: $i > $i).
% 28.89/28.95  tff(decl_14166, type, fn_carbohydrate_side_chain_33: $i > $i).
% 28.89/28.95  tff(decl_14167, type, fn_carbohydrate_side_chain_24: $i > $i).
% 28.89/28.95  tff(decl_14168, type, fn_oligosaccharide_6: $i > $i).
% 28.89/28.95  tff(decl_14169, type, fn_carbohydrate_side_chain_29: $i > $i).
% 28.89/28.95  tff(decl_14170, type, blood_cell_1: $i > $o).
% 28.89/28.95  tff(decl_14171, type, 'Blood-Cell': $i).
% 28.89/28.95  tff(decl_14172, type, 'A blood cell, also called a hematocyte, is a cell of any type normally found in blood. In mammals, blood cells fall into three categories - Red blood cell, white blood cell, platelets.': $i).
% 28.89/28.95  tff(decl_14173, type, hematocyte: $i).
% 28.89/28.95  tff(decl_14174, type, 'cell of blood': $i).
% 28.89/28.95  tff(decl_14175, type, 'blood cell': $i).
% 28.89/28.95  tff(decl_14176, type, 'blood-cell': $i).
% 28.89/28.95  tff(decl_14177, type, fn_blood_cell_1: $i > $i).
% 28.89/28.95  tff(decl_14178, type, fn_blood_cell_2: $i > $i).
% 28.89/28.95  tff(decl_14179, type, fn_blood_cell_3: $i > $i).
% 28.89/28.95  tff(decl_14180, type, blood_sugar_regulation_1: $i > $o).
% 28.89/28.95  tff(decl_14181, type, 'Blood-Sugar-Regulation': $i).
% 28.89/28.95  tff(decl_14182, type, 'Blood sugar regulation is the process by which the levels of blood sugar, primarily glucose, are maintained by the body': $i).
% 28.89/28.95  tff(decl_14183, type, regulate: $i).
% 28.89/28.95  tff(decl_14184, type, 'blood sugar regulation': $i).
% 28.89/28.95  tff(decl_14185, type, 'blood-sugar-regulation': $i).
% 28.89/28.95  tff(decl_14186, type, fn_blood_sugar_regulation_1: $i > $i).
% 28.89/28.95  tff(decl_14187, type, fn_blood_sugar_regulation_2: $i > $i).
% 28.89/28.95  tff(decl_14188, type, fn_blood_sugar_regulation_3: $i > $i).
% 28.89/28.95  tff(decl_14189, type, blood_type_a_1: $i > $o).
% 28.89/28.95  tff(decl_14190, type, 'Blood-Type-A': $i).
% 28.89/28.95  tff(decl_14191, type, 'Blood type specified by carbohydrate A on the red blood cell\\s plasma membrane.': $i).
% 28.89/28.95  tff(decl_14192, type, 'blood type a': $i).
% 28.89/28.95  tff(decl_14193, type, 'blood-type-a': $i).
% 28.89/28.95  tff(decl_14194, type, blood_type_ab_1: $i > $o).
% 28.89/28.95  tff(decl_14195, type, blood_type_b_1: $i > $o).
% 28.89/28.95  tff(decl_14196, type, blood_type_o_1: $i > $o).
% 28.89/28.95  tff(decl_14197, type, fn_blood_type_a_1: $i > $i).
% 28.89/28.95  tff(decl_14198, type, fn_blood_type_a_2: $i > $i).
% 28.89/28.95  tff(decl_14199, type, fn_blood_type_a_8: $i > $i).
% 28.89/28.95  tff(decl_14200, type, fn_blood_type_a_9: $i > $i).
% 28.89/28.95  tff(decl_14201, type, fn_blood_type_a_10: $i > $i).
% 28.89/28.95  tff(decl_14202, type, fn_blood_type_a_12: $i > $i).
% 28.89/28.95  tff(decl_14203, type, fn_blood_type_a_13: $i > $i).
% 28.89/28.95  tff(decl_14204, type, fn_blood_type_a_14: $i > $i).
% 28.89/28.95  tff(decl_14205, type, fn_blood_type_a_15: $i > $i).
% 28.89/28.95  tff(decl_14206, type, fn_blood_type_a_16: $i > $i).
% 28.89/28.95  tff(decl_14207, type, fn_blood_type_a_17: $i > $i).
% 28.89/28.95  tff(decl_14208, type, fn_blood_type_a_18: $i > $i).
% 28.89/28.95  tff(decl_14209, type, fn_blood_type_a_19: $i > $i).
% 28.89/28.95  tff(decl_14210, type, fn_blood_type_a_20: $i > $i).
% 28.89/28.95  tff(decl_14211, type, fn_buffer_1: $i > $i).
% 28.89/28.95  tff(decl_14212, type, fn_carbonic_acid_bicarbonate_buffer_3: $i > $i).
% 28.89/28.95  tff(decl_14213, type, fn_blood_type_a_6: $i > $i).
% 28.89/28.95  tff(decl_14214, type, fn_blood_1: $i > $i).
% 28.89/28.95  tff(decl_14215, type, fn_blood_type_a_5: $i > $i).
% 28.89/28.95  tff(decl_14216, type, fn_blood_2: $i > $i).
% 28.89/28.95  tff(decl_14217, type, fn_blood_type_a_7: $i > $i).
% 28.89/28.95  tff(decl_14218, type, fn_blood_type_a_11: $i > $i).
% 28.89/28.95  tff(decl_14219, type, 'Blood-Type-AB': $i).
% 28.89/28.95  tff(decl_14220, type, 'Blood type specified by both blood carbohydrate A and blood carbohydrate B on the red blood cell\\s plasma membrane.': $i).
% 28.89/28.95  tff(decl_14221, type, 'blood type ab': $i).
% 28.89/28.95  tff(decl_14222, type, 'blood-type-ab': $i).
% 28.89/28.95  tff(decl_14223, type, 'Blood-Type-B': $i).
% 28.89/28.95  tff(decl_14224, type, 'Blood type specified by carbohydrate B on the red blood cell\\s plasma membrane.': $i).
% 28.89/28.95  tff(decl_14225, type, 'blood type b': $i).
% 28.89/28.95  tff(decl_14226, type, 'blood-type-b': $i).
% 28.89/28.95  tff(decl_14227, type, 'Blood-Type-Genotype': $i).
% 28.89/28.95  tff(decl_14228, type, 'The genetic makeup of an organism\\s blood type.': $i).
% 28.89/28.95  tff(decl_14229, type, 'blood group genotype': $i).
% 28.89/28.95  tff(decl_14230, type, 'blood-group-genotype': $i).
% 28.89/28.95  tff(decl_14231, type, 'abo group genotype': $i).
% 28.89/28.95  tff(decl_14232, type, 'abo-group-genotype': $i).
% 28.89/28.95  tff(decl_14233, type, 'blood type genotype': $i).
% 28.89/28.95  tff(decl_14234, type, 'blood-type-genotype': $i).
% 28.89/28.95  tff(decl_14235, type, blood_type_genotype_iaia_1: $i > $o).
% 28.89/28.95  tff(decl_14236, type, 'Blood-Type-Genotype-IAIA': $i).
% 28.89/28.95  tff(decl_14237, type, 'Allele coding for one of the blood carbohydrates.': $i).
% 28.89/28.95  tff(decl_14238, type, 'blood type genotype iaia': $i).
% 28.89/28.95  tff(decl_14239, type, 'blood-type-genotype-iaia': $i).
% 28.89/28.95  tff(decl_14240, type, fn_blood_type_genotype_iaia_1: $i > $i).
% 28.89/28.95  tff(decl_14241, type, fn_blood_type_genotype_iaia_2: $i > $i).
% 28.89/28.95  tff(decl_14242, type, ia_0: $i).
% 28.89/28.95  tff(decl_14243, type, 'Blood-Type-O': $i).
% 28.89/28.95  tff(decl_14244, type, 'Blood type specified by neither carbohydrate A nor carbohydrate B being found on the red blood cell\\s plasma membrane.': $i).
% 28.89/28.95  tff(decl_14245, type, 'blood type o': $i).
% 28.89/28.95  tff(decl_14246, type, 'blood-type-o': $i).
% 28.89/28.95  tff(decl_14247, type, 'Blood-Type-Phenotype': $i).
% 28.89/28.95  tff(decl_14248, type, 'The blood type of an organism as determined by the blood carbohydrate on the membrane surface of its red blood cells.': $i).
% 28.89/28.95  tff(decl_14249, type, 'blood type': $i).
% 28.89/28.95  tff(decl_14250, type, 'blood type phenotype': $i).
% 28.89/28.95  tff(decl_14251, type, 'blood-type-phenotype': $i).
% 28.89/28.95  tff(decl_14252, type, fn_blood_type_phenotype_1: $i > $i).
% 28.89/28.95  tff(decl_14253, type, determined_by_1: $i > $o).
% 28.89/28.95  tff(decl_14254, type, fn_blood_type_phenotype_2: $i > $i).
% 28.89/28.95  tff(decl_14255, type, 'Blood-Vessel': $i).
% 28.89/28.95  tff(decl_14256, type, 'The part of the circulatory system, including arteries, veins, and capillaries, that carries blood through out the body.': $i).
% 28.89/28.95  tff(decl_14257, type, 'vessel of blood': $i).
% 28.89/28.95  tff(decl_14258, type, 'blood vessel': $i).
% 28.89/28.95  tff(decl_14259, type, 'blood-vessel': $i).
% 28.89/28.95  tff(decl_14260, type, circulatory_organ_1: $i > $o).
% 28.89/28.95  tff(decl_14261, type, fn_blood_vessel_1: $i > $i).
% 28.89/28.95  tff(decl_14262, type, lumen_1: $i > $o).
% 28.89/28.95  tff(decl_14263, type, fn_blood_vessel_2: $i > $i).
% 28.89/28.95  tff(decl_14264, type, blotting_1: $i > $o).
% 28.89/28.95  tff(decl_14265, type, 'Blotting': $i).
% 28.89/28.95  tff(decl_14266, type, 'A method of transferring proteins, DNA or RNA, onto a solid support carrier.': $i).
% 28.89/28.95  tff(decl_14267, type, blot: $i).
% 28.89/28.95  tff(decl_14268, type, blotting: $i).
% 28.89/28.95  tff(decl_14269, type, capillary_action_1: $i > $o).
% 28.89/28.95  tff(decl_14270, type, fn_blotting_1: $i > $i).
% 28.89/28.95  tff(decl_14271, type, fn_blotting_2: $i > $i).
% 28.89/28.95  tff(decl_14272, type, fn_blotting_3: $i > $i).
% 28.89/28.95  tff(decl_14273, type, solid_support_1: $i > $o).
% 28.89/28.95  tff(decl_14274, type, fn_solid_support_1: $i > $i).
% 28.89/28.95  tff(decl_14275, type, fn_gel_electrophoresis_2: $i > $i).
% 28.89/28.95  tff(decl_14276, type, blue_green_light_1: $i > $o).
% 28.89/28.95  tff(decl_14277, type, 'Blue-Green-Light': $i).
% 28.89/28.95  tff(decl_14278, type, 'The portion of the electromagnetic spectrum that can be detected as blue-green by the human eye, ranging in wavelength from about 430 nm to 470 nm.': $i).
% 28.89/28.95  tff(decl_14279, type, 'blue green light': $i).
% 28.89/28.95  tff(decl_14280, type, 'blue-green-light': $i).
% 28.89/28.95  tff(decl_14281, type, fn_blue_green_light_1: $i > $i).
% 28.89/28.95  tff(decl_14282, type, fn_blue_green_light_2: $i > $i).
% 28.89/28.95  tff(decl_14283, type, fn_blue_green_light_3: $i > $i).
% 28.89/28.95  tff(decl_14284, type, fn_blue_green_light_8: $i > $i).
% 28.89/28.95  tff(decl_14285, type, "430.0e0": $i).
% 28.89/28.95  tff(decl_14286, type, "470.0e0": $i).
% 28.89/28.95  tff(decl_14287, type, fn_blue_green_light_7: $i > $i).
% 28.89/28.95  tff(decl_14288, type, fn_electromagnetic_energy_1: $i > $i).
% 28.89/28.95  tff(decl_14289, type, fn_electromagnetic_energy_4: $i > $i).
% 28.89/28.95  tff(decl_14290, type, blue_light_1: $i > $o).
% 28.89/28.95  tff(decl_14291, type, 'Blue-Light': $i).
% 28.89/28.95  tff(decl_14292, type, 'The portion of the electromagnetic spectrum that can be detected as blue by the human eye, ranging in wavelength from about 380 nm to 450 nm.': $i).
% 28.89/28.95  tff(decl_14293, type, 'light of blue': $i).
% 28.89/28.95  tff(decl_14294, type, 'blue light': $i).
% 28.89/28.95  tff(decl_14295, type, 'blue-light': $i).
% 28.89/28.95  tff(decl_14296, type, fn_blue_light_2: $i > $i).
% 28.89/28.95  tff(decl_14297, type, fn_blue_light_3: $i > $i).
% 28.89/28.95  tff(decl_14298, type, fn_blue_light_4: $i > $i).
% 28.89/28.95  tff(decl_14299, type, fn_blue_light_5: $i > $i).
% 28.89/28.95  tff(decl_14300, type, fn_blue_light_8: $i > $i).
% 28.89/28.95  tff(decl_14301, type, "450.0e0": $i).
% 28.89/28.95  tff(decl_14302, type, "520.0e0": $i).
% 28.89/28.95  tff(decl_14303, type, fn_blue_light_9: $i > $i).
% 28.89/28.95  tff(decl_14304, type, blue_light_photoreceptor_1: $i > $o).
% 28.89/28.95  tff(decl_14305, type, 'Blue-Light-Photoreceptor': $i).
% 28.89/28.95  tff(decl_14306, type, 'A type of photoreceptor that detects blue light and is responsible for initiating phototropism in plants.': $i).
% 28.89/28.95  tff(decl_14307, type, 'blue light photoreceptor': $i).
% 28.89/28.95  tff(decl_14308, type, 'blue-light photoreceptor': $i).
% 28.89/28.95  tff(decl_14309, type, 'blue-light-photoreceptor': $i).
% 28.89/28.95  tff(decl_14310, type, photoreceptor_1: $i > $o).
% 28.89/28.95  tff(decl_14311, type, cone_1: $i > $o).
% 28.89/28.95  tff(decl_14312, type, lyse_1: $i > $o).
% 28.89/28.95  tff(decl_14313, type, blunt_end_fragment_1: $i > $o).
% 28.89/28.95  tff(decl_14314, type, blunt_end_fragment_0: $i).
% 28.89/28.95  tff(decl_14315, type, blunt_cut_1: $i > $o).
% 28.89/28.95  tff(decl_14316, type, fn_blunt_cut_3: $i > $i).
% 28.89/28.95  tff(decl_14317, type, fn_blunt_cut_2: $i > $i).
% 28.89/28.95  tff(decl_14318, type, 'Blunt-Cut': $i).
% 28.89/28.95  tff(decl_14319, type, 'The result of a restriction enzyme\\s non-staggered breaking of the covalent phophodiester bonds of both DNA strands.': $i).
% 28.89/28.95  tff(decl_14320, type, cut: $i).
% 28.89/28.95  tff(decl_14321, type, 'blunt cut': $i).
% 28.89/28.95  tff(decl_14322, type, 'blunt-cut': $i).
% 28.89/28.95  tff(decl_14323, type, staggered_cut_1: $i > $o).
% 28.89/28.95  tff(decl_14324, type, fn_restriction_fragment_16: $i > $i).
% 28.89/28.95  tff(decl_14325, type, restriction_fragment_1: $i > $o).
% 28.89/28.96  tff(decl_14326, type, fn_blunt_end_fragment_4: $i > $i).
% 28.89/28.96  tff(decl_14327, type, 'Blunt-End-Fragment': $i).
% 28.89/28.96  tff(decl_14328, type, 'A single-stranded end of a double-stranded blunt cut restriction fragment.': $i).
% 28.89/28.96  tff(decl_14329, type, 'blunt end fragment': $i).
% 28.89/28.96  tff(decl_14330, type, 'blunt-end-fragment': $i).
% 28.89/28.96  tff(decl_14331, type, restriction_fragment_length_polymorphism_1: $i > $o).
% 28.89/28.96  tff(decl_14332, type, sticky_end_fragment_1: $i > $o).
% 28.89/28.96  tff(decl_14333, type, fn_blunt_end_fragment_2: $i > $i).
% 28.89/28.96  tff(decl_14334, type, fn_blunt_end_fragment_3: $i > $i).
% 28.89/28.96  tff(decl_14335, type, dna_ligase_1: $i > $o).
% 28.89/28.96  tff(decl_14336, type, fn_blunt_end_fragment_5: $i > $i).
% 28.89/28.96  tff(decl_14337, type, fn_blunt_end_fragment_6: $i > $i).
% 28.89/28.96  tff(decl_14338, type, recombinant_dna_1: $i > $o).
% 28.89/28.96  tff(decl_14339, type, fn_blunt_end_fragment_7: $i > $i).
% 28.89/28.96  tff(decl_14340, type, fn_dna_ligase_10: $i > $i).
% 28.89/28.96  tff(decl_14341, type, fn_dna_ligase_7: $i > $i).
% 28.89/28.96  tff(decl_14342, type, fn_recombinant_dna_18: $i > $i).
% 28.89/28.96  tff(decl_14343, type, fn_dna_ligase_12: $i > $i).
% 28.89/28.96  tff(decl_14344, type, bmp_4_1: $i > $o).
% 28.89/28.96  tff(decl_14345, type, 'BMP-4': $i).
% 28.89/28.96  tff(decl_14346, type, 'One of a group of bone morphogenic proteins (BMPs) involved in the growth and formation of bones and cartilage.': $i).
% 28.89/28.96  tff(decl_14347, type, 'bone morphogenetic proteins': $i).
% 28.89/28.96  tff(decl_14348, type, 'bone-morphogenetic-proteins': $i).
% 28.89/28.96  tff(decl_14349, type, bmp: $i).
% 28.89/28.96  tff(decl_14350, type, 'bmp 4': $i).
% 28.89/28.96  tff(decl_14351, type, 'bmp-4': $i).
% 28.89/28.96  tff(decl_14352, type, erythropoietin_1: $i > $o).
% 28.89/28.96  tff(decl_14353, type, growth_hormone_1: $i > $o).
% 28.89/28.96  tff(decl_14354, type, inhibin_1: $i > $o).
% 28.89/28.96  tff(decl_14355, type, leptin_1: $i > $o).
% 28.89/28.96  tff(decl_14356, type, prolactin_1: $i > $o).
% 28.89/28.96  tff(decl_14357, type, 'Bodily-Fluid': $i).
% 28.89/28.96  tff(decl_14358, type, 'A liquid which originates from the human body and includes those which leak out or are normally excreted or secreted.': $i).
% 28.89/28.96  tff(decl_14359, type, 'body fluid': $i).
% 28.89/28.96  tff(decl_14360, type, 'body-fluid': $i).
% 28.89/28.96  tff(decl_14361, type, 'bodily fluid': $i).
% 28.89/28.96  tff(decl_14362, type, 'bodily-fluid': $i).
% 28.89/28.96  tff(decl_14363, type, 'Body-Axis': $i).
% 28.89/28.96  tff(decl_14364, type, 'An imaginary longitudinal line through the vertical center of the body (head to feet) or one of its parts, or a line about which the body or a part rotates.': $i).
% 28.89/28.96  tff(decl_14365, type, 'axis of body': $i).
% 28.89/28.96  tff(decl_14366, type, 'body axis': $i).
% 28.89/28.96  tff(decl_14367, type, 'body-axis': $i).
% 28.89/28.96  tff(decl_14368, type, 'Body-Cavity': $i).
% 28.89/28.96  tff(decl_14369, type, 'A space, filled with air or fluid, between an animal\\s digestive tract and its body wall.': $i).
% 28.89/28.96  tff(decl_14370, type, 'cavity of body': $i).
% 28.89/28.96  tff(decl_14371, type, 'body cavity': $i).
% 28.89/28.96  tff(decl_14372, type, 'body-cavity': $i).
% 28.89/28.96  tff(decl_14373, type, body_plan_1: $i > $o).
% 28.89/28.96  tff(decl_14374, type, 'Body-Plan': $i).
% 28.89/28.96  tff(decl_14375, type, 'The': $i).
% 28.89/28.96  tff(decl_14376, type, 'plan of body': $i).
% 28.89/28.96  tff(decl_14377, type, 'body plan': $i).
% 28.89/28.96  tff(decl_14378, type, 'body-plan': $i).
% 28.89/28.96  tff(decl_14379, type, map_1: $i > $o).
% 28.89/28.96  tff(decl_14380, type, 'Body-Segment': $i).
% 28.89/28.96  tff(decl_14381, type, 'A segment of the body of an organism.': $i).
% 28.89/28.96  tff(decl_14382, type, 'segment of body': $i).
% 28.89/28.96  tff(decl_14383, type, 'body segment': $i).
% 28.89/28.96  tff(decl_14384, type, 'body-segment': $i).
% 28.89/28.96  tff(decl_14385, type, body_segment_pair_1: $i > $o).
% 28.89/28.96  tff(decl_14386, type, 'Body-Segment-Pair': $i).
% 28.89/28.96  tff(decl_14387, type, 'A pair of body segments.': $i).
% 28.89/28.96  tff(decl_14388, type, 'body segment pair': $i).
% 28.89/28.96  tff(decl_14389, type, 'body-segment-pair': $i).
% 28.89/28.96  tff(decl_14390, type, fn_body_segment_pair_1: $i > $i).
% 28.89/28.96  tff(decl_14391, type, body_segment_0: $i).
% 28.89/28.96  tff(decl_14392, type, body_wall_1: $i > $o).
% 28.89/28.96  tff(decl_14393, type, 'Body-Wall': $i).
% 28.89/28.96  tff(decl_14394, type, 'Layers of cells that make up the external surface of an animal\\s body.': $i).
% 28.89/28.96  tff(decl_14395, type, 'wall of body': $i).
% 28.89/28.96  tff(decl_14396, type, 'body wall': $i).
% 28.89/28.96  tff(decl_14397, type, 'body-wall': $i).
% 28.89/28.96  tff(decl_14398, type, bohr_shift_1: $i > $o).
% 28.89/28.96  tff(decl_14399, type, 'Bohr-Shift': $i).
% 28.89/28.96  tff(decl_14400, type, 'A decrease in the oxygen-binding ability of hemoglobin due to a decrease in blood pH. This results in a release of oxygen into active tissues.': $i).
% 28.89/28.96  tff(decl_14401, type, 'shift of bohr': $i).
% 28.89/28.96  tff(decl_14402, type, 'bohr shift': $i).
% 28.89/28.96  tff(decl_14403, type, 'bohr-shift': $i).
% 28.89/28.96  tff(decl_14404, type, bohrium_1: $i > $o).
% 28.89/28.96  tff(decl_14405, type, 'Bohrium': $i).
% 28.89/28.96  tff(decl_14406, type, 'Bohrium is a metal atom with atomic number 107. It is represented by the symbol Bh.': $i).
% 28.89/28.96  tff(decl_14407, type, bohrium: $i).
% 28.89/28.96  tff(decl_14408, type, 'Bh': $i).
% 28.89/28.96  tff(decl_14409, type, fn_bohrium_1: $i > $i).
% 28.89/28.96  tff(decl_14410, type, fn_bohrium_2: $i > $i).
% 28.89/28.96  tff(decl_14411, type, fn_bohrium_6: $i > $i).
% 28.89/28.96  tff(decl_14412, type, fn_bohrium_7: $i > $i).
% 28.89/28.96  tff(decl_14413, type, "157": $i).
% 28.89/28.96  tff(decl_14414, type, "107": $i).
% 28.89/28.96  tff(decl_14415, type, "264": $i).
% 28.89/28.96  tff(decl_14416, type, fn_bohrium_4: $i > $i).
% 28.89/28.96  tff(decl_14417, type, fn_bohrium_5: $i > $i).
% 28.89/28.96  tff(decl_14418, type, boiling_1: $i > $o).
% 28.89/28.96  tff(decl_14419, type, 'Boiling': $i).
% 28.89/28.96  tff(decl_14420, type, 'The phase change from liquid to gas, which occurs when a liquid is heated to its boiling point.': $i).
% 28.89/28.96  tff(decl_14421, type, boil: $i).
% 28.89/28.96  tff(decl_14422, type, boiling: $i).
% 28.89/28.96  tff(decl_14423, type, change_of_state_1: $i > $o).
% 28.89/28.96  tff(decl_14424, type, fn_boiling_1: $i > $i).
% 28.89/28.96  tff(decl_14425, type, fn_boiling_2: $i > $i).
% 28.89/28.96  tff(decl_14426, type, boiling_of_water_1: $i > $o).
% 28.89/28.96  tff(decl_14427, type, 'Boiling-Of-Water': $i).
% 28.89/28.96  tff(decl_14428, type, 'The phase change from liquid water to water vapor, which occurs when the temperature of liquid water reaches 100 degree Celsius.': $i).
% 28.89/28.96  tff(decl_14429, type, 'water boiling': $i).
% 28.89/28.96  tff(decl_14430, type, 'water-boiling': $i).
% 28.89/28.96  tff(decl_14431, type, 'boiling of water': $i).
% 28.89/28.96  tff(decl_14432, type, 'boiling-of-water': $i).
% 28.89/28.96  tff(decl_14433, type, fn_boiling_of_water_1: $i > $i).
% 28.89/28.96  tff(decl_14434, type, "100.0e0": $i).
% 28.89/28.96  tff(decl_14435, type, bolting_1: $i > $o).
% 28.89/28.96  tff(decl_14436, type, 'Bolting': $i).
% 28.89/28.96  tff(decl_14437, type, 'In agricultural or horticultural plants, the production of flowers before the edible crop is harvested. Bolting represents a diversion from producing edible tissues into producing flowers.': $i).
% 28.89/28.96  tff(decl_14438, type, bolting: $i).
% 28.89/28.96  tff(decl_14439, type, 'Bolus': $i).
% 28.89/28.96  tff(decl_14440, type, 'A mass of food that has been chewed and swallowed.': $i).
% 28.89/28.96  tff(decl_14441, type, bolus: $i).
% 28.89/28.96  tff(decl_14442, type, nitrogenous_waste_1: $i > $o).
% 28.89/28.96  tff(decl_14443, type, fn_bolus_2: $i > $i).
% 28.89/28.96  tff(decl_14444, type, 'Bombardier-Beetle': $i).
% 28.89/28.96  tff(decl_14445, type, 'One of a group of beetles that discharge spurts of noxious chemicals when disturbed.': $i).
% 28.89/28.96  tff(decl_14446, type, 'beetle of bombardier': $i).
% 28.89/28.96  tff(decl_14447, type, 'bombardier beetle': $i).
% 28.89/28.96  tff(decl_14448, type, 'bombardier-beetle': $i).
% 28.89/28.96  tff(decl_14449, type, 'Bone': $i).
% 28.89/28.96  tff(decl_14450, type, 'A type of dense connective tissue consisting of cells held in a collagen matrix impregnated with calcium salts. Bones form the endoskeleton of most vertebrate animals.': $i).
% 28.89/28.96  tff(decl_14451, type, bone: $i).
% 28.89/28.96  tff(decl_14452, type, fn_bone_1: $i > $i).
% 28.89/28.96  tff(decl_14453, type, fn_bone_2: $i > $i).
% 28.89/28.96  tff(decl_14454, type, vitamin_d_1: $i > $o).
% 28.89/28.96  tff(decl_14455, type, fn_bone_3: $i > $i).
% 28.89/28.96  tff(decl_14456, type, fn_bone_4: $i > $i).
% 28.89/28.96  tff(decl_14457, type, fn_bone_5: $i > $i).
% 28.89/28.96  tff(decl_14458, type, fn_bone_6: $i > $i).
% 28.89/28.96  tff(decl_14459, type, fn_bone_7: $i > $i).
% 28.89/28.96  tff(decl_14460, type, fn_glycoprotein_3: $i > $i).
% 28.89/28.96  tff(decl_14461, type, fn_glycoprotein_2: $i > $i).
% 28.89/28.96  tff(decl_14462, type, fn_glycoprotein_4: $i > $i).
% 28.89/28.96  tff(decl_14463, type, fn_glycoprotein_5: $i > $i).
% 28.89/28.96  tff(decl_14464, type, bone_cell_1: $i > $o).
% 28.89/28.96  tff(decl_14465, type, 'Bone-Cell': $i).
% 28.89/28.96  tff(decl_14466, type, 'Cells that make up bone tissue.': $i).
% 28.89/28.96  tff(decl_14467, type, osteoblast: $i).
% 28.89/28.96  tff(decl_14468, type, osteocyte: $i).
% 28.89/28.96  tff(decl_14469, type, 'cell of bone': $i).
% 28.89/28.96  tff(decl_14470, type, 'bone cell': $i).
% 28.89/28.96  tff(decl_14471, type, 'bone-cell': $i).
% 28.89/28.96  tff(decl_14472, type, fn_bone_cell_1: $i > $i).
% 28.89/28.96  tff(decl_14473, type, fn_bone_cell_2: $i > $i).
% 28.89/28.96  tff(decl_14474, type, fn_bone_cell_3: $i > $i).
% 28.89/28.96  tff(decl_14475, type, fn_bone_cell_4: $i > $i).
% 28.89/28.96  tff(decl_14476, type, fn_bone_cell_7: $i > $i).
% 28.89/28.96  tff(decl_14477, type, fn_bone_cell_8: $i > $i).
% 28.89/28.96  tff(decl_14478, type, fn_bone_cell_9: $i > $i).
% 28.89/28.96  tff(decl_14479, type, fn_bone_cell_10: $i > $i).
% 28.89/28.96  tff(decl_14480, type, fn_bone_cell_11: $i > $i).
% 28.89/28.96  tff(decl_14481, type, fn_bone_cell_12: $i > $i).
% 28.89/28.96  tff(decl_14482, type, fn_bone_cell_13: $i > $i).
% 28.89/28.96  tff(decl_14483, type, fn_bone_cell_14: $i > $i).
% 28.89/28.96  tff(decl_14484, type, fn_bone_cell_15: $i > $i).
% 28.89/28.96  tff(decl_14485, type, fn_bone_cell_16: $i > $i).
% 28.89/28.96  tff(decl_14486, type, fn_bone_cell_17: $i > $i).
% 28.89/28.96  tff(decl_14487, type, fn_bone_cell_18: $i > $i).
% 28.89/28.96  tff(decl_14488, type, fn_bone_cell_19: $i > $i).
% 28.89/28.96  tff(decl_14489, type, fn_bone_cell_20: $i > $i).
% 28.89/28.96  tff(decl_14490, type, fn_bone_cell_21: $i > $i).
% 28.89/28.96  tff(decl_14491, type, fn_bone_cell_22: $i > $i).
% 28.89/28.96  tff(decl_14492, type, fn_bone_cell_23: $i > $i).
% 28.89/28.96  tff(decl_14493, type, fn_bone_cell_24: $i > $i).
% 28.89/28.96  tff(decl_14494, type, fn_bone_cell_25: $i > $i).
% 28.89/28.96  tff(decl_14495, type, fn_bone_cell_26: $i > $i).
% 28.89/28.96  tff(decl_14496, type, fn_bone_cell_27: $i > $i).
% 28.89/28.96  tff(decl_14497, type, fn_bone_cell_28: $i > $i).
% 28.89/28.96  tff(decl_14498, type, fn_bone_cell_29: $i > $i).
% 28.89/28.96  tff(decl_14499, type, fn_bone_cell_30: $i > $i).
% 28.89/28.96  tff(decl_14500, type, fn_bone_cell_31: $i > $i).
% 28.89/28.96  tff(decl_14501, type, fn_bone_cell_32: $i > $i).
% 28.89/28.96  tff(decl_14502, type, fn_bone_cell_33: $i > $i).
% 28.89/28.96  tff(decl_14503, type, fn_bone_cell_34: $i > $i).
% 28.89/28.96  tff(decl_14504, type, fn_bone_cell_35: $i > $i).
% 28.89/28.96  tff(decl_14505, type, fn_bone_cell_36: $i > $i).
% 28.89/28.96  tff(decl_14506, type, fn_bone_cell_37: $i > $i).
% 28.89/28.96  tff(decl_14507, type, fn_bone_cell_38: $i > $i).
% 28.89/28.96  tff(decl_14508, type, fn_bone_cell_39: $i > $i).
% 28.89/28.96  tff(decl_14509, type, fn_bone_cell_40: $i > $i).
% 28.89/28.96  tff(decl_14510, type, fn_bone_cell_41: $i > $i).
% 28.89/28.96  tff(decl_14511, type, fn_bone_cell_42: $i > $i).
% 28.89/28.96  tff(decl_14512, type, fn_bone_cell_43: $i > $i).
% 28.89/28.96  tff(decl_14513, type, fn_bone_cell_44: $i > $i).
% 28.89/28.96  tff(decl_14514, type, fn_bone_cell_45: $i > $i).
% 28.89/28.96  tff(decl_14515, type, fn_bone_cell_46: $i > $i).
% 28.89/28.96  tff(decl_14516, type, fn_bone_cell_47: $i > $i).
% 28.89/28.96  tff(decl_14517, type, fn_bone_cell_48: $i > $i).
% 28.89/28.96  tff(decl_14518, type, fn_bone_cell_49: $i > $i).
% 28.89/28.96  tff(decl_14519, type, fn_bone_cell_50: $i > $i).
% 28.89/28.96  tff(decl_14520, type, fn_bone_cell_51: $i > $i).
% 28.89/28.96  tff(decl_14521, type, fn_bone_cell_52: $i > $i).
% 28.89/28.96  tff(decl_14522, type, fn_bone_cell_53: $i > $i).
% 28.89/28.96  tff(decl_14523, type, fn_bone_cell_54: $i > $i).
% 28.89/28.96  tff(decl_14524, type, fn_integrin_7: $i > $i).
% 28.89/28.96  tff(decl_14525, type, fn_fibronectin_45: $i > $i).
% 28.89/28.96  tff(decl_14526, type, fn_fibronectin_47: $i > $i).
% 28.89/28.96  tff(decl_14527, type, fn_fibronectin_53: $i > $i).
% 28.89/28.96  tff(decl_14528, type, fn_eukaryotic_cell_46: $i > $i).
% 28.89/28.96  tff(decl_14529, type, fn_bone_cell_6: $i > $i).
% 28.89/28.96  tff(decl_14530, type, fn_bone_cell_5: $i > $i).
% 28.89/28.96  tff(decl_14531, type, bone_formation_1: $i > $o).
% 28.89/28.96  tff(decl_14532, type, 'Bone-Formation': $i).
% 28.89/28.96  tff(decl_14533, type, 'The process in which minerals such as calcium are added to tissues to form bone. Bone formation occurs during development, growth and repair of bone tissue.': $i).
% 28.89/28.96  tff(decl_14534, type, 'formation of bone': $i).
% 28.89/28.96  tff(decl_14535, type, 'bone formation': $i).
% 28.89/28.96  tff(decl_14536, type, 'bone-formation': $i).
% 28.89/28.96  tff(decl_14537, type, fn_bone_formation_1: $i > $i).
% 28.89/28.96  tff(decl_14538, type, bone_marrow_1: $i > $o).
% 28.89/28.96  tff(decl_14539, type, 'Bone-Marrow': $i).
% 28.89/28.96  tff(decl_14540, type, 'Bone marrow is the flexible tissue found in the interior of bones. In humans, marrow in large bones produces new blood cells.': $i).
% 28.89/28.96  tff(decl_14541, type, 'marrow of bone': $i).
% 28.89/28.96  tff(decl_14542, type, 'bone marrow': $i).
% 28.89/28.96  tff(decl_14543, type, 'bone-marrow': $i).
% 28.89/28.96  tff(decl_14544, type, lymphatic_tissue_1: $i > $o).
% 28.89/28.96  tff(decl_14545, type, bony_fish_1: $i > $o).
% 28.89/28.96  tff(decl_14546, type, 'Bony-Fish': $i).
% 28.89/28.96  tff(decl_14547, type, 'A member of the clade Osteichthyes, fishes that have bony, rather than cartilaginous, skeletons.': $i).
% 28.89/28.96  tff(decl_14548, type, osteichthyan: $i).
% 28.89/28.96  tff(decl_14549, type, osteichthyes: $i).
% 28.89/28.96  tff(decl_14550, type, 'bony fish': $i).
% 28.89/28.96  tff(decl_14551, type, 'bony-fish': $i).
% 28.89/28.96  tff(decl_14552, type, fish_1: $i > $o).
% 28.89/28.96  tff(decl_14553, type, cartilaginous_fish_1: $i > $o).
% 28.89/28.96  tff(decl_14554, type, lobe_fin_fish_1: $i > $o).
% 28.89/28.96  tff(decl_14555, type, tetrapod_fish_1: $i > $o).
% 28.89/28.96  tff(decl_14556, type, book_lung_1: $i > $o).
% 28.89/28.96  tff(decl_14557, type, 'Book-Lung': $i).
% 28.89/28.96  tff(decl_14558, type, 'The respiratory structure of spiders and other terrestrial chelicerates, consisting of a stack of thin, vascularized, sheets of tissue hanging in an air-filled cavity.': $i).
% 28.89/28.96  tff(decl_14559, type, 'lung of book': $i).
% 28.89/28.96  tff(decl_14560, type, 'book lung': $i).
% 28.89/28.96  tff(decl_14561, type, 'book-lung': $i).
% 28.89/28.96  tff(decl_14562, type, respiratory_organ_1: $i > $o).
% 28.89/28.96  tff(decl_14563, type, boolean_1: $i > $o).
% 28.89/28.96  tff(decl_14564, type, 'Boolean': $i).
% 28.89/28.96  tff(decl_14565, type, boolean: $i).
% 28.89/28.96  tff(decl_14566, type, boom_and_bust_cycle_1: $i > $o).
% 28.89/28.96  tff(decl_14567, type, 'Boom-And-Bust-Cycle': $i).
% 28.89/28.96  tff(decl_14568, type, 'Regular fluctuations in population density.': $i).
% 28.89/28.96  tff(decl_14569, type, 'boom and bust cycle': $i).
% 28.89/28.96  tff(decl_14570, type, 'boom-and-bust-cycle': $i).
% 28.89/28.96  tff(decl_14571, type, population_process_1: $i > $o).
% 28.89/28.96  tff(decl_14572, type, borisy_experiment_1: $i > $o).
% 28.89/28.96  tff(decl_14573, type, 'Borisy-Experiment': $i).
% 28.89/28.96  tff(decl_14574, type, 'Experiment conducted by G. G. Borisy and collegues which investigated the mechanisms of microtubule shortening during mitosis.': $i).
% 28.89/28.96  tff(decl_14575, type, 'borisy experiment': $i).
% 28.89/28.96  tff(decl_14576, type, 'borisy-experiment': $i).
% 28.89/28.96  tff(decl_14577, type, fn_borisy_experiment_1: $i > $i).
% 28.89/28.96  tff(decl_14578, type, gary_borisy_1: $i > $o).
% 28.89/28.96  tff(decl_14579, type, 'Boron': $i).
% 28.89/28.96  tff(decl_14580, type, 'Boron is a metalloid atom with atomic number 5. It is represented by the symbol B.': $i).
% 28.89/28.96  tff(decl_14581, type, 'B': $i).
% 28.89/28.96  tff(decl_14582, type, boron: $i).
% 28.89/28.96  tff(decl_14583, type, fn_boron_1: $i > $i).
% 28.89/28.96  tff(decl_14584, type, fn_boron_2: $i > $i).
% 28.89/28.96  tff(decl_14585, type, fn_boron_3: $i > $i).
% 28.89/28.96  tff(decl_14586, type, fn_boron_4: $i > $i).
% 28.89/28.96  tff(decl_14587, type, fn_boron_8: $i > $i).
% 28.89/28.96  tff(decl_14588, type, fn_boron_9: $i > $i).
% 28.89/28.96  tff(decl_14589, type, fn_boron_11: $i > $i).
% 28.89/28.96  tff(decl_14590, type, fn_boron_12: $i > $i).
% 28.89/28.96  tff(decl_14591, type, fn_boron_13: $i > $i).
% 28.89/28.96  tff(decl_14592, type, fn_boron_14: $i > $i).
% 28.89/28.96  tff(decl_14593, type, fn_boron_15: $i > $i).
% 28.89/28.96  tff(decl_14594, type, fn_boron_16: $i > $i).
% 28.89/28.96  tff(decl_14595, type, "10.81": $i).
% 28.89/28.96  tff(decl_14596, type, "2.04": $i).
% 28.89/28.96  tff(decl_14597, type, 'AtomicNumber': $i).
% 28.89/28.96  tff(decl_14598, type, fn_boron_17: $i > $i).
% 28.89/28.96  tff(decl_14599, type, fn_boron_18: $i > $i).
% 28.89/28.96  tff(decl_14600, type, fn_boron_10: $i > $i).
% 28.89/28.96  tff(decl_14601, type, botanist_1: $i > $o).
% 28.89/28.96  tff(decl_14602, type, 'Botanist': $i).
% 28.89/28.96  tff(decl_14603, type, 'Scientist that does botany or studies plants.': $i).
% 28.89/28.96  tff(decl_14604, type, botanist: $i).
% 28.89/28.96  tff(decl_14605, type, botany_1: $i > $o).
% 28.89/28.96  tff(decl_14606, type, 'Botany': $i).
% 28.89/28.96  tff(decl_14607, type, 'Field of biology that involves study of plants.': $i).
% 28.89/28.96  tff(decl_14608, type, botanize: $i).
% 28.89/28.96  tff(decl_14609, type, botany: $i).
% 28.89/28.96  tff(decl_14610, type, 'Bottleneck-Effect': $i).
% 28.89/28.96  tff(decl_14611, type, 'A type of genetic drift that occurs when population size decreases drastically due to natural events or human actions. After a bottleneck event the remaining few organisms do not represent the genetic make-up of the original population.': $i).
% 28.89/28.96  tff(decl_14612, type, 'effect of bottleneck': $i).
% 28.89/28.96  tff(decl_14613, type, 'bottleneck effect': $i).
% 28.89/28.96  tff(decl_14614, type, 'bottleneck-effect': $i).
% 28.89/28.96  tff(decl_14615, type, bound_ribosome_1: $i > $o).
% 28.89/28.96  tff(decl_14616, type, 'Bound-Ribosome': $i).
% 28.89/28.96  tff(decl_14617, type, 'Bound ribosome is the ribosome attached to Rough endoplasmic reticulum. Bound ribosome is structurally similar to free ribosome and can also serve as free ribosome by getting detached from Rough Endoplasmic Reticulum': $i).
% 28.89/28.96  tff(decl_14618, type, 'ribosome of bound': $i).
% 28.89/28.96  tff(decl_14619, type, 'bound ribosome': $i).
% 28.89/28.96  tff(decl_14620, type, 'bound-ribosome': $i).
% 28.89/28.96  tff(decl_14621, type, free_ribosome_1: $i > $o).
% 28.89/28.96  tff(decl_14622, type, fn_bound_ribosome_1: $i > $i).
% 28.89/28.96  tff(decl_14623, type, fn_bound_ribosome_2: $i > $i).
% 28.89/28.96  tff(decl_14624, type, fn_bound_ribosome_3: $i > $i).
% 28.89/28.96  tff(decl_14625, type, fn_bound_ribosome_4: $i > $i).
% 28.89/28.96  tff(decl_14626, type, fn_er_membrane_28: $i > $i).
% 28.89/28.96  tff(decl_14627, type, fn_endoplasmic_reticulum_30: $i > $i).
% 28.89/28.96  tff(decl_14628, type, fn_er_membrane_13: $i > $i).
% 28.89/28.96  tff(decl_14629, type, 'Bowmans-Capsule': $i).
% 28.89/28.96  tff(decl_14630, type, 'An expanded, cup-shaped receptacle at the end of the nephron in a kidney, that surrounds the glomerulus and is the site where filtrate enters the nephron from the blood.': $i).
% 28.89/28.96  tff(decl_14631, type, 'bowmans capsule': $i).
% 28.89/28.96  tff(decl_14632, type, 'bowmans-capsule': $i).
% 28.89/28.96  tff(decl_14633, type, mixed_epithelial_tissue_1: $i > $o).
% 28.89/28.96  tff(decl_14634, type, brachiopod_1: $i > $o).
% 28.89/28.96  tff(decl_14635, type, 'Brachiopod': $i).
% 28.89/28.96  tff(decl_14636, type, 'A bivalved marine lophophorate. Its valves are dorsal and ventral, as opposed to the left and right valves of a bivalved mollusc.': $i).
% 28.89/28.96  tff(decl_14637, type, brachiopod: $i).
% 28.89/28.96  tff(decl_14638, type, ectoproct_1: $i > $o).
% 28.89/28.96  tff(decl_14639, type, brain_1: $i > $o).
% 28.89/28.96  tff(decl_14640, type, 'Brain': $i).
% 28.89/28.96  tff(decl_14641, type, 'One of two major organs of the central nervous system, the other being the spinal cord. The brain receives information from the rest of the body, interprets and integrates the information, and controls the body\\s responses to the environment.': $i).
% 28.89/28.96  tff(decl_14642, type, brain: $i).
% 28.89/28.96  tff(decl_14643, type, nervous_organ_1: $i > $o).
% 28.89/28.96  tff(decl_14644, type, fn_brain_1: $i > $i).
% 28.89/28.96  tff(decl_14645, type, fn_brain_2: $i > $i).
% 28.89/28.96  tff(decl_14646, type, fn_brain_3: $i > $i).
% 28.89/28.96  tff(decl_14647, type, fn_organ_1: $i > $i).
% 28.89/28.96  tff(decl_14648, type, brain_region_1: $i > $o).
% 28.89/28.96  tff(decl_14649, type, 'Brain-Region': $i).
% 28.89/28.96  tff(decl_14650, type, 'A region or structure in the vertebrate brain.': $i).
% 28.89/28.96  tff(decl_14651, type, 'region of brain': $i).
% 28.89/28.96  tff(decl_14652, type, 'brain region': $i).
% 28.89/28.96  tff(decl_14653, type, 'brain-region': $i).
% 28.89/28.96  tff(decl_14654, type, nervous_tissue_1: $i > $o).
% 28.89/28.96  tff(decl_14655, type, ganglion_1: $i > $o).
% 28.89/28.96  tff(decl_14656, type, gray_matter_1: $i > $o).
% 28.89/28.96  tff(decl_14657, type, nerve_circuit_1: $i > $o).
% 28.89/28.96  tff(decl_14658, type, neural_crest_1: $i > $o).
% 28.89/28.96  tff(decl_14659, type, neuromast_1: $i > $o).
% 28.89/28.96  tff(decl_14660, type, notochord_1: $i > $o).
% 28.89/28.96  tff(decl_14661, type, ommatidium_1: $i > $o).
% 28.89/28.96  tff(decl_14662, type, optic_nerve_1: $i > $o).
% 28.89/28.96  tff(decl_14663, type, retina_1: $i > $o).
% 28.89/28.96  tff(decl_14664, type, white_matter_1: $i > $o).
% 28.89/28.96  tff(decl_14665, type, 'Brainstem': $i).
% 28.89/28.96  tff(decl_14666, type, 'Region of the brain that connects the cerebrum to the spinal cord. It consists of the midbrain, pons, and medulla oblongata. The brainstem controls the life-support activities such as breathing and homeostasis, as well as coordination of movement and conduction of impulses from the spinal cord to higher brain centers.': $i).
% 28.89/28.96  tff(decl_14667, type, brainstem: $i).
% 28.89/28.96  tff(decl_14668, type, primary_visual_cortex_1: $i > $o).
% 28.89/28.96  tff(decl_14669, type, forebrain_1: $i > $o).
% 28.89/28.96  tff(decl_14670, type, hindbrain_1: $i > $o).
% 28.89/28.96  tff(decl_14671, type, hypothalamus_1: $i > $o).
% 28.89/28.96  tff(decl_14672, type, midbrain_1: $i > $o).
% 28.89/28.96  tff(decl_14673, type, posterior_pituitary_1: $i > $o).
% 28.89/28.96  tff(decl_14674, type, primary_motor_cortex_1: $i > $o).
% 28.89/28.96  tff(decl_14675, type, primary_somatosensory_cortex_1: $i > $o).
% 28.89/28.96  tff(decl_14676, type, suprachiasmatic_nucleus_1: $i > $o).
% 28.89/28.96  tff(decl_14677, type, thalamus_1: $i > $o).
% 28.89/28.96  tff(decl_14678, type, lateral_geniculate_1: $i > $o).
% 28.89/28.96  tff(decl_14679, type, 'Branch-Point': $i).
% 28.89/28.96  tff(decl_14680, type, 'The part of a phylogenetic tree that represents where an ancestor gives rise to two or more descendent taxa. In most cases a branch point is shown as a dichotomy, with two descendant taxa diverging at the branch point.': $i).
% 28.89/28.96  tff(decl_14681, type, dichotomy: $i).
% 28.89/28.96  tff(decl_14682, type, inquire: $i).
% 28.89/28.96  tff(decl_14683, type, 'point of branch': $i).
% 28.89/28.96  tff(decl_14684, type, 'branch point': $i).
% 28.89/28.96  tff(decl_14685, type, 'branch-point': $i).
% 28.89/28.96  tff(decl_14686, type, 'Brassinosteroid': $i).
% 28.89/28.96  tff(decl_14687, type, 'A type of plant steroid hormone, involved in a variety of plant processes including cell expansion and cell elongation, differentiation of vascular tissues, and pollen tube formation.': $i).
% 28.89/28.96  tff(decl_14688, type, brassinosteroid: $i).
% 28.89/28.96  tff(decl_14689, type, breach_1: $i > $o).
% 28.89/28.96  tff(decl_14690, type, 'Breach': $i).
% 28.89/28.96  tff(decl_14691, type, breach: $i).
% 28.89/28.96  tff(decl_14692, type, gap: $i).
% 28.89/28.96  tff(decl_14693, type, fn_breach_1: $i > $i).
% 28.89/28.96  tff(decl_14694, type, fn_breach_2: $i > $i).
% 28.89/28.96  tff(decl_14695, type, 'Bread-Mold': $i).
% 28.89/28.96  tff(decl_14696, type, 'Neurospora crassa, a species of mold of the phylum Ascomyceta.': $i).
% 28.89/28.96  tff(decl_14697, type, 'mold of bread': $i).
% 28.89/28.96  tff(decl_14698, type, 'bread mold': $i).
% 28.89/28.96  tff(decl_14699, type, 'bread-mold': $i).
% 28.89/28.96  tff(decl_14700, type, 'Break': $i).
% 28.89/28.96  tff(decl_14701, type, break: $i).
% 28.89/28.96  tff(decl_14702, type, 'break down': $i).
% 28.89/28.96  tff(decl_14703, type, break_down: $i).
% 28.89/28.96  tff(decl_14704, type, 'conk out': $i).
% 28.89/28.96  tff(decl_14705, type, conk_out: $i).
% 28.89/28.96  tff(decl_14706, type, die: $i).
% 28.89/28.96  tff(decl_14707, type, fail: $i).
% 28.89/28.96  tff(decl_14708, type, 'give out': $i).
% 28.89/28.96  tff(decl_14709, type, give_out: $i).
% 28.89/28.96  tff(decl_14710, type, 'give way': $i).
% 28.89/28.96  tff(decl_14711, type, give_way: $i).
% 28.89/28.96  tff(decl_14712, type, go: $i).
% 28.89/28.96  tff(decl_14713, type, 'break apart': $i).
% 28.89/28.96  tff(decl_14714, type, break_contact_1: $i > $o).
% 28.89/28.96  tff(decl_14715, type, 'Break-Contact': $i).
% 28.89/28.96  tff(decl_14716, type, 'let go': $i).
% 28.89/28.96  tff(decl_14717, type, let_go: $i).
% 28.89/28.96  tff(decl_14718, type, unwind: $i).
% 28.89/28.96  tff(decl_14719, type, 'break contact between': $i).
% 28.89/28.96  tff(decl_14720, type, 'contact of break': $i).
% 28.89/28.96  tff(decl_14721, type, 'break contact': $i).
% 28.89/28.96  tff(decl_14722, type, 'break-contact': $i).
% 28.89/28.96  tff(decl_14723, type, fn_break_contact_1: $i > $i).
% 28.89/28.96  tff(decl_14724, type, fn_break_contact_2: $i > $i).
% 28.89/28.96  tff(decl_14725, type, 'Breakability-Constant': $i).
% 28.89/28.96  tff(decl_14726, type, 'constant of breakability': $i).
% 28.89/28.96  tff(decl_14727, type, 'breakability constant': $i).
% 28.89/28.96  tff(decl_14728, type, 'breakability-constant': $i).
% 28.89/28.96  tff(decl_14729, type, breakability_scale_1: $i > $o).
% 28.89/28.96  tff(decl_14730, type, 'Breakability-Scale': $i).
% 28.89/28.96  tff(decl_14731, type, 'scale of breakability': $i).
% 28.89/28.96  tff(decl_14732, type, 'breakability scale': $i).
% 28.89/28.96  tff(decl_14733, type, 'breakability-scale': $i).
% 28.89/28.96  tff(decl_14734, type, 'Breakability-Value': $i).
% 28.89/28.96  tff(decl_14735, type, 'the breakability of an Entity': $i).
% 28.89/28.96  tff(decl_14736, type, fragility: $i).
% 28.89/28.96  tff(decl_14737, type, breakability: $i).
% 28.89/28.96  tff(decl_14738, type, 'value of breakability': $i).
% 28.89/28.96  tff(decl_14739, type, 'breakability value': $i).
% 28.89/28.96  tff(decl_14740, type, 'breakability-value': $i).
% 28.89/28.96  tff(decl_14741, type, breakfast_1: $i > $o).
% 28.89/28.96  tff(decl_14742, type, 'Breakfast': $i).
% 28.89/28.96  tff(decl_14743, type, breakfast: $i).
% 28.89/28.96  tff(decl_14744, type, meal_1: $i > $o).
% 28.89/28.96  tff(decl_14745, type, supper_1: $i > $o).
% 28.89/28.96  tff(decl_14746, type, lunch_1: $i > $o).
% 28.89/28.96  tff(decl_14747, type, dinner_1: $i > $o).
% 28.89/28.96  tff(decl_14748, type, brunch_1: $i > $o).
% 28.89/28.96  tff(decl_14749, type, breast_cancer_1: $i > $o).
% 28.89/28.96  tff(decl_14750, type, 'Breast-Cancer': $i).
% 28.89/28.96  tff(decl_14751, type, 'A form of cancer that begins in mammary tissue and may spread to other parts of the body.': $i).
% 28.89/28.96  tff(decl_14752, type, 'cancer of breast': $i).
% 28.89/28.96  tff(decl_14753, type, 'breast cancer': $i).
% 28.89/28.96  tff(decl_14754, type, 'breast-cancer': $i).
% 28.89/28.96  tff(decl_14755, type, cancer_1: $i > $o).
% 28.89/28.96  tff(decl_14756, type, burkitts_lymphoma_1: $i > $o).
% 28.89/28.96  tff(decl_14757, type, cml_1: $i > $o).
% 28.89/28.96  tff(decl_14758, type, leukemia_1: $i > $o).
% 28.89/28.96  tff(decl_14759, type, prostate_cancer_1: $i > $o).
% 28.89/28.96  tff(decl_14760, type, breathing_1: $i > $o).
% 28.89/28.96  tff(decl_14761, type, 'Breathing': $i).
% 28.89/28.96  tff(decl_14762, type, 'The process that brings air into and out of the lungs.': $i).
% 28.89/28.96  tff(decl_14763, type, breathe: $i).
% 28.89/28.96  tff(decl_14764, type, breathing: $i).
% 28.89/28.96  tff(decl_14765, type, gas_exchange_1: $i > $o).
% 28.89/28.96  tff(decl_14766, type, 'Breathing-Control-Center': $i).
% 28.89/28.96  tff(decl_14767, type, 'The pons and medulla oblongata, areas in the brain that control the organs involved in breathing.': $i).
% 28.89/28.96  tff(decl_14768, type, 'breathing control center': $i).
% 28.89/28.96  tff(decl_14769, type, 'breathing-control-center': $i).
% 28.89/28.96  tff(decl_14770, type, reticular_formation_1: $i > $o).
% 28.89/28.96  tff(decl_14771, type, bridge_1: $i > $o).
% 28.89/28.96  tff(decl_14772, type, 'Bridge': $i).
% 28.89/28.96  tff(decl_14773, type, 'an architectural structure that acts as conduit over a barrier': $i).
% 28.89/28.96  tff(decl_14774, type, bridge: $i).
% 28.89/28.96  tff(decl_14775, type, span: $i).
% 28.89/28.96  tff(decl_14776, type, wall_1: $i > $o).
% 28.89/28.96  tff(decl_14777, type, roof_1: $i > $o).
% 28.89/28.96  tff(decl_14778, type, platform_1: $i > $o).
% 28.89/28.96  tff(decl_14779, type, parkinglot_1: $i > $o).
% 28.89/28.96  tff(decl_14780, type, door_1: $i > $o).
% 28.89/28.96  tff(decl_14781, type, ceiling_1: $i > $o).
% 28.89/28.96  tff(decl_14782, type, building_1: $i > $o).
% 28.89/28.96  tff(decl_14783, type, building_complex_1: $i > $o).
% 28.89/28.96  tff(decl_14784, type, electrical_power_plant_1: $i > $o).
% 28.89/28.96  tff(decl_14785, type, factory_1: $i > $o).
% 28.89/28.96  tff(decl_14786, type, fn_bridge_1: $i > $i).
% 28.89/28.96  tff(decl_14787, type, fn_bridge_2: $i > $i).
% 28.89/28.96  tff(decl_14788, type, fn_bridge_3: $i > $i).
% 28.89/28.96  tff(decl_14789, type, brighten_1: $i > $o).
% 28.89/28.96  tff(decl_14790, type, 'Brighten': $i).
% 28.89/28.96  tff(decl_14791, type, brighten: $i).
% 28.89/28.96  tff(decl_14792, type, 'lighten up': $i).
% 28.89/28.96  tff(decl_14793, type, lighten_up: $i).
% 28.89/28.96  tff(decl_14794, type, lighten: $i).
% 28.89/28.96  tff(decl_14795, type, wet_1: $i > $o).
% 28.89/28.96  tff(decl_14796, type, increase_in_cell_size_1: $i > $o).
% 28.89/28.96  tff(decl_14797, type, increase_of_activation_energy_1: $i > $o).
% 28.89/28.96  tff(decl_14798, type, fn_brighten_1: $i > $i).
% 28.89/28.96  tff(decl_14799, type, fn_brighten_4: $i > $i).
% 28.89/28.96  tff(decl_14800, type, fn_brighten_5: $i > $i).
% 28.89/28.96  tff(decl_14801, type, fn_brighten_3: $i > $i).
% 28.89/28.96  tff(decl_14802, type, fn_brighten_2: $i > $i).
% 28.89/28.96  tff(decl_14803, type, brightfield_microscope_1: $i > $o).
% 28.89/28.96  tff(decl_14804, type, 'Brightfield-Microscope': $i).
% 28.89/28.96  tff(decl_14805, type, 'A type of light microscope that illuminates the entire field, so specimens must be stained.': $i).
% 28.89/28.96  tff(decl_14806, type, 'brightfield microscope': $i).
% 28.89/28.96  tff(decl_14807, type, 'brightfield-microscope': $i).
% 28.89/28.96  tff(decl_14808, type, light_microscope_1: $i > $o).
% 28.89/28.96  tff(decl_14809, type, phase_contrast_microscope_1: $i > $o).
% 28.89/28.96  tff(decl_14810, type, 'Brightness-Constant': $i).
% 28.89/28.96  tff(decl_14811, type, 'constant of brightness': $i).
% 28.89/28.96  tff(decl_14812, type, 'brightness constant': $i).
% 28.89/28.96  tff(decl_14813, type, 'brightness-constant': $i).
% 28.89/28.96  tff(decl_14814, type, brightness_scale_1: $i > $o).
% 28.89/28.96  tff(decl_14815, type, 'Brightness-Scale': $i).
% 28.89/28.96  tff(decl_14816, type, 'scale of brightness': $i).
% 28.89/28.96  tff(decl_14817, type, 'brightness scale': $i).
% 28.89/28.96  tff(decl_14818, type, 'brightness-scale': $i).
% 28.89/28.96  tff(decl_14819, type, 'Brightness-Value': $i).
% 28.89/28.96  tff(decl_14820, type, 'the brightness of a Tangible-Entity': $i).
% 28.89/28.96  tff(decl_14821, type, 'brightness level': $i).
% 28.89/28.96  tff(decl_14822, type, brightness: $i).
% 28.89/28.96  tff(decl_14823, type, luminosity: $i).
% 28.89/28.96  tff(decl_14824, type, luminance: $i).
% 28.89/28.96  tff(decl_14825, type, luminousness: $i).
% 28.89/28.96  tff(decl_14826, type, light: $i).
% 28.89/28.96  tff(decl_14827, type, 'value of brightness': $i).
% 28.89/28.96  tff(decl_14828, type, 'brightness value': $i).
% 28.89/28.96  tff(decl_14829, type, 'brightness-value': $i).
% 28.89/28.96  tff(decl_14830, type, 'Brittle-Star': $i).
% 28.89/28.96  tff(decl_14831, type, 'Any of a group of echinoderms from the class Ophiuroidea that superficially resemble sea stars. Brittle stars get their common name from the fact that their arms autotomize readily; they also differ from the sea stars in some aspects of their water vascular system and digestive system.': $i).
% 28.89/28.96  tff(decl_14832, type, 'star of brittle': $i).
% 28.89/28.96  tff(decl_14833, type, 'brittle star': $i).
% 28.89/28.96  tff(decl_14834, type, 'brittle-star': $i).
% 28.89/28.96  tff(decl_14835, type, bromine_1: $i > $o).
% 28.89/28.96  tff(decl_14836, type, 'Bromine': $i).
% 28.89/28.96  tff(decl_14837, type, 'Bromine is a non metal atom with atomic number 35. It is represented by the symbol Br.': $i).
% 28.89/28.96  tff(decl_14838, type, bromine: $i).
% 28.89/28.96  tff(decl_14839, type, 'Br': $i).
% 28.89/28.96  tff(decl_14840, type, non_metal_atom_1: $i > $o).
% 28.89/28.96  tff(decl_14841, type, fn_bromine_3: $i > $i).
% 28.89/28.96  tff(decl_14842, type, fn_bromine_4: $i > $i).
% 28.89/28.96  tff(decl_14843, type, fn_bromine_5: $i > $i).
% 28.89/28.96  tff(decl_14844, type, fn_bromine_9: $i > $i).
% 28.89/28.96  tff(decl_14845, type, fn_bromine_10: $i > $i).
% 28.89/28.96  tff(decl_14846, type, fn_bromine_11: $i > $i).
% 28.89/28.96  tff(decl_14847, type, fn_bromine_12: $i > $i).
% 28.89/28.96  tff(decl_14848, type, "45": $i).
% 28.89/28.96  tff(decl_14849, type, "35": $i).
% 28.89/28.96  tff(decl_14850, type, "2.96": $i).
% 28.89/28.96  tff(decl_14851, type, "80": $i).
% 28.89/28.96  tff(decl_14852, type, "79.9": $i).
% 28.89/28.96  tff(decl_14853, type, fn_bromine_7: $i > $i).
% 28.89/28.96  tff(decl_14854, type, fn_bromine_8: $i > $i).
% 28.89/28.96  tff(decl_14855, type, fn_bromine_6: $i > $i).
% 28.89/28.96  tff(decl_14856, type, 'Bronchiole': $i).
% 28.89/28.96  tff(decl_14857, type, 'Small, branched air passages that transport air to the alveoli of the lungs, where gas exchange occurs.': $i).
% 28.89/28.96  tff(decl_14858, type, bronchiole: $i).
% 28.89/28.96  tff(decl_14859, type, 'Bronchus': $i).
% 28.89/28.96  tff(decl_14860, type, 'One of two branches tubes that leads from the trachea into the lungs.': $i).
% 28.89/28.96  tff(decl_14861, type, 'bronchial tubes': $i).
% 28.89/28.96  tff(decl_14862, type, 'bronchial-tubes': $i).
% 28.89/28.96  tff(decl_14863, type, bronchus: $i).
% 28.89/28.96  tff(decl_14864, type, bronsted_lowry_acid_1: $i > $o).
% 28.89/28.96  tff(decl_14865, type, 'Bronsted-Lowry-Acid': $i).
% 28.89/28.96  tff(decl_14866, type, 'An ion or molecule that is able to donate a hydrogen ion to another ion or molecule': $i).
% 28.89/28.96  tff(decl_14867, type, 'bronsted lowry acid': $i).
% 28.89/28.96  tff(decl_14868, type, 'bronsted-lowry-acid': $i).
% 28.89/28.96  tff(decl_14869, type, bronsted_lowry_acid_compound_1: $i > $o).
% 28.89/28.96  tff(decl_14870, type, 'Bronsted-Lowry-Acid-Compound': $i).
% 28.89/28.96  tff(decl_14871, type, 'A chemical entity that donates H+.': $i).
% 28.89/28.96  tff(decl_14872, type, 'bronsted lowry acid compound': $i).
% 28.89/28.96  tff(decl_14873, type, 'bronsted-lowry-acid-compound': $i).
% 28.89/28.96  tff(decl_14874, type, c6h5cooh_1: $i > $o).
% 28.89/28.96  tff(decl_14875, type, ch2_cooh_2_1: $i > $o).
% 28.89/28.96  tff(decl_14876, type, salt_1: $i > $o).
% 28.89/28.96  tff(decl_14877, type, brown_alga_1: $i > $o).
% 28.89/28.96  tff(decl_14878, type, 'Brown-Alga': $i).
% 28.89/28.96  tff(decl_14879, type, 'A multicellular, photosynthetic protist, typically a brownish or olive-brown color due to carotenoid pigments. The largest seaweeds (giant kelps) are brown algae.': $i).
% 28.89/28.96  tff(decl_14880, type, 'alga of brown': $i).
% 28.89/28.96  tff(decl_14881, type, 'brown alga': $i).
% 28.89/28.96  tff(decl_14882, type, 'brown-alga': $i).
% 28.89/28.96  tff(decl_14883, type, golden_alga_1: $i > $o).
% 28.89/28.96  tff(decl_14884, type, brown_algae_1: $i > $o).
% 28.89/28.96  tff(decl_14885, type, 'Brown-Algae': $i).
% 28.89/28.96  tff(decl_14886, type, 'algae of brown': $i).
% 28.89/28.96  tff(decl_14887, type, 'brown algae': $i).
% 28.89/28.96  tff(decl_14888, type, 'brown-algae': $i).
% 28.89/28.96  tff(decl_14889, type, brown_fat_1: $i > $o).
% 28.89/28.96  tff(decl_14890, type, 'Brown-Fat': $i).
% 28.89/28.96  tff(decl_14891, type, 'Metabolically active adipose tissue which contributes to the generation of body heat.': $i).
% 28.89/28.96  tff(decl_14892, type, 'fat of brown': $i).
% 28.89/28.96  tff(decl_14893, type, 'brown fat': $i).
% 28.89/28.96  tff(decl_14894, type, 'brown-fat': $i).
% 28.89/28.96  tff(decl_14895, type, fn_brown_fat_2: $i > $i).
% 28.89/28.96  tff(decl_14896, type, fn_brown_fat_3: $i > $i).
% 28.89/28.96  tff(decl_14897, type, fn_brown_fat_4: $i > $i).
% 28.89/28.96  tff(decl_14898, type, fn_brown_fat_5: $i > $i).
% 28.89/28.96  tff(decl_14899, type, fn_brown_fat_6: $i > $i).
% 28.89/28.96  tff(decl_14900, type, fn_brown_fat_7: $i > $i).
% 28.89/28.96  tff(decl_14901, type, uncoupling_protein_1: $i > $o).
% 28.89/28.96  tff(decl_14902, type, fn_mitochondrial_membrane_37: $i > $i).
% 28.89/28.96  tff(decl_14903, type, fn_mitochondrial_membrane_35: $i > $i).
% 28.89/28.96  tff(decl_14904, type, semiautonomous_organelle_0: $i).
% 28.89/28.96  tff(decl_14905, type, fn_brown_fat_1: $i > $i).
% 28.89/28.96  tff(decl_14906, type, brown_headed_cowbird_1: $i > $o).
% 28.89/28.96  tff(decl_14907, type, 'Brown-Headed-Cowbird': $i).
% 28.89/28.96  tff(decl_14908, type, 'Molothrus ater, the most common brood parasitic bird in North America.': $i).
% 28.89/28.96  tff(decl_14909, type, 'brown headed cowbird': $i).
% 28.89/28.96  tff(decl_14910, type, 'brown-headed cowbird': $i).
% 28.89/28.96  tff(decl_14911, type, 'brown-headed-cowbird': $i).
% 28.89/28.96  tff(decl_14912, type, flightless_birds_1: $i > $o).
% 28.89/28.96  tff(decl_14913, type, florida_scrub_jay_1: $i > $o).
% 28.89/28.96  tff(decl_14914, type, galapagos_finch_1: $i > $o).
% 28.89/28.96  tff(decl_14915, type, greylag_geese_1: $i > $o).
% 28.89/28.96  tff(decl_14916, type, killdeer_1: $i > $o).
% 28.89/28.96  tff(decl_14917, type, ratite_1: $i > $o).
% 28.89/28.96  tff(decl_14918, type, red_cockaded_woodpecker_1: $i > $o).
% 28.89/28.96  tff(decl_14919, type, 'Brunch': $i).
% 28.89/28.96  tff(decl_14920, type, brunch: $i).
% 28.89/28.96  tff(decl_14921, type, bryophyte_1: $i > $o).
% 28.89/28.96  tff(decl_14922, type, 'Bryophyte': $i).
% 28.89/28.96  tff(decl_14923, type, 'A general term for plants which do not have extensive vascular tissue and lack other adaptations for terrestrial living.': $i).
% 28.89/28.96  tff(decl_14924, type, 'nonvascular plant': $i).
% 28.89/28.96  tff(decl_14925, type, 'nonvascular-plant': $i).
% 28.89/28.96  tff(decl_14926, type, bryophyte: $i).
% 28.89/28.96  tff(decl_14927, type, fn_bryophyte_1: $i > $i).
% 28.89/28.96  tff(decl_14928, type, seta_1: $i > $o).
% 28.89/28.96  tff(decl_14929, type, fn_bryophyte_2: $i > $i).
% 28.89/28.96  tff(decl_14930, type, bryophyte_sporangium_1: $i > $o).
% 28.89/28.96  tff(decl_14931, type, 'Bryophyte-Sporangium': $i).
% 28.89/28.96  tff(decl_14932, type, 'Multicellular organ in mosses, liverworts and hornworts which produces haploid cells through meiosis.': $i).
% 28.89/28.96  tff(decl_14933, type, capsule: $i).
% 28.89/28.96  tff(decl_14934, type, 'sporangium of bryophyte': $i).
% 28.89/28.96  tff(decl_14935, type, 'bryophyte sporangium': $i).
% 28.89/28.96  tff(decl_14936, type, 'bryophyte-sporangium': $i).
% 28.89/28.96  tff(decl_14937, type, sporangium_1: $i > $o).
% 28.89/28.96  tff(decl_14938, type, 'Bryozoan': $i).
% 28.89/28.96  tff(decl_14939, type, 'A member of the phylum Bryozoa, which comprises marine and freshwater colonial lophophorate animals.': $i).
% 28.89/28.96  tff(decl_14940, type, bryozoan: $i).
% 28.89/28.96  tff(decl_14941, type, fn_bryozoan_1: $i > $i).
% 28.89/28.96  tff(decl_14942, type, fn_bryozoan_4: $i > $i).
% 28.89/28.96  tff(decl_14943, type, fn_bryozoan_5: $i > $i).
% 28.89/28.96  tff(decl_14944, type, fn_bryozoan_6: $i > $i).
% 28.89/28.96  tff(decl_14945, type, fn_bryozoan_7: $i > $i).
% 28.89/28.96  tff(decl_14946, type, fn_bryozoan_8: $i > $i).
% 28.89/28.96  tff(decl_14947, type, fn_bryozoan_9: $i > $i).
% 28.89/28.96  tff(decl_14948, type, fn_bryozoan_10: $i > $i).
% 28.89/28.96  tff(decl_14949, type, fn_bryozoan_11: $i > $i).
% 28.89/28.96  tff(decl_14950, type, fn_bryozoan_12: $i > $i).
% 28.89/28.96  tff(decl_14951, type, fn_bryozoan_13: $i > $i).
% 28.89/28.96  tff(decl_14952, type, fn_bryozoan_14: $i > $i).
% 28.89/28.96  tff(decl_14953, type, fn_bryozoan_15: $i > $i).
% 28.89/28.96  tff(decl_14954, type, fn_bryozoan_16: $i > $i).
% 28.89/28.96  tff(decl_14955, type, fn_bryozoan_17: $i > $i).
% 28.89/28.96  tff(decl_14956, type, fn_bryozoan_18: $i > $i).
% 28.89/28.96  tff(decl_14957, type, fn_eumetazoan_21: $i > $i).
% 28.89/28.96  tff(decl_14958, type, fn_eumetazoan_20: $i > $i).
% 28.89/28.96  tff(decl_14959, type, fn_eumetazoan_28: $i > $i).
% 28.89/28.96  tff(decl_14960, type, fn_bryozoan_3: $i > $i).
% 28.89/28.96  tff(decl_14961, type, fn_bryozoan_2: $i > $i).
% 28.89/28.96  tff(decl_14962, type, fn_eumetazoan_6: $i > $i).
% 28.89/28.96  tff(decl_14963, type, fn_eumetazoan_2: $i > $i).
% 28.89/28.96  tff(decl_14964, type, fn_eumetazoan_22: $i > $i).
% 28.89/28.96  tff(decl_14965, type, budding_1: $i > $o).
% 28.89/28.96  tff(decl_14966, type, 'Budding': $i).
% 28.89/28.96  tff(decl_14967, type, 'A type of asexual reproduction in animals in which a parent produces an outgrowth of tissue (a bud) that eventually separates and begins an independent existence. Buds can separate to form clones, or remain interconnected to form colonies. In either case, buds are genetically identical to their parents.': $i).
% 28.89/28.96  tff(decl_14968, type, bud: $i).
% 28.89/28.96  tff(decl_14969, type, budding: $i).
% 28.89/28.96  tff(decl_14970, type, reproduction_1: $i > $o).
% 28.89/28.96  tff(decl_14971, type, cross_breeding_event_1: $i > $o).
% 28.89/28.96  tff(decl_14972, type, plant_reproduction_1: $i > $o).
% 28.89/28.96  tff(decl_14973, type, semelparity_1: $i > $o).
% 28.89/28.96  tff(decl_14974, type, vegetative_reproduction_1: $i > $o).
% 28.89/28.96  tff(decl_14975, type, 'Buffer': $i).
% 28.89/28.96  tff(decl_14976, type, 'A solution that contains a weak acid and its corresponding base.  A buffer minimizes change in pH when acids or bases are added to the solution.': $i).
% 28.89/28.96  tff(decl_14977, type, 'biological buffer': $i).
% 28.89/28.96  tff(decl_14978, type, 'biological-buffer': $i).
% 28.89/28.96  tff(decl_14979, type, buffer: $i).
% 28.89/28.96  tff(decl_14980, type, fn_buffer_2: $i > $i).
% 28.89/28.96  tff(decl_14981, type, fn_ph_maintenance_1: $i > $i).
% 28.89/28.96  tff(decl_14982, type, 'Buffered-Solution': $i).
% 28.89/28.96  tff(decl_14983, type, 'A solution that resists change in pH when acids or bases are added.  The solution may contain either a weak acid and its salt or a weak base and its salt.': $i).
% 28.89/28.96  tff(decl_14984, type, 'buffered solution': $i).
% 28.89/28.96  tff(decl_14985, type, 'buffered-solution': $i).
% 28.89/28.96  tff(decl_14986, type, 'Building': $i).
% 28.89/28.96  tff(decl_14987, type, 'an architectural structure playing a container, having a floor, rooms, walls and a roof': $i).
% 28.89/28.96  tff(decl_14988, type, building: $i).
% 28.89/28.96  tff(decl_14989, type, fn_building_1: $i > $i).
% 28.89/28.96  tff(decl_14990, type, fn_building_2: $i > $i).
% 28.89/28.96  tff(decl_14991, type, fn_building_3: $i > $i).
% 28.89/28.96  tff(decl_14992, type, floor_1: $i > $o).
% 28.89/28.96  tff(decl_14993, type, fn_building_4: $i > $i).
% 28.89/28.96  tff(decl_14994, type, fn_building_5: $i > $i).
% 28.89/28.96  tff(decl_14995, type, fn_floor_2: $i > $i).
% 28.89/28.96  tff(decl_14996, type, fn_roof_1: $i > $i).
% 28.89/28.96  tff(decl_14997, type, fn_floor_1: $i > $i).
% 28.89/28.96  tff(decl_14998, type, 'Building-Complex': $i).
% 28.89/28.96  tff(decl_14999, type, 'building complex': $i).
% 28.89/28.96  tff(decl_15000, type, building_complex: $i).
% 28.89/28.96  tff(decl_15001, type, 'complex of building': $i).
% 28.89/28.96  tff(decl_15002, type, 'building-complex': $i).
% 28.89/28.96  tff(decl_15003, type, bulb_1: $i > $o).
% 28.89/28.96  tff(decl_15004, type, 'Bulb': $i).
% 28.89/28.96  tff(decl_15005, type, 'In plants, a short stem with leaf bases.': $i).
% 28.89/28.96  tff(decl_15006, type, bulb: $i).
% 28.89/28.96  tff(decl_15007, type, root_organ_1: $i > $o).
% 28.89/28.96  tff(decl_15008, type, 'Bulbourethral-Gland': $i).
% 28.89/28.96  tff(decl_15009, type, 'A gland near the prostate gland, that secretes fluid into the urethra to neutralize any residual acidic urine and protect sperm cells.': $i).
% 28.89/28.96  tff(decl_15010, type, 'bulbourethral gland': $i).
% 28.89/28.96  tff(decl_15011, type, 'bulbourethral-gland': $i).
% 28.89/28.96  tff(decl_15012, type, 'Bulk-Feeder': $i).
% 28.89/28.96  tff(decl_15013, type, 'An animal that eats large pieces of other organisms or swallows them intact.': $i).
% 28.89/28.96  tff(decl_15014, type, 'feeder of bulk': $i).
% 28.89/28.96  tff(decl_15015, type, 'bulk feeder': $i).
% 28.89/28.96  tff(decl_15016, type, 'bulk-feeder': $i).
% 28.89/28.96  tff(decl_15017, type, feeder_1: $i > $o).
% 28.89/28.96  tff(decl_15018, type, fn_bulk_feeder_2: $i > $i).
% 28.89/28.96  tff(decl_15019, type, fn_bulk_feeder_5: $i > $i).
% 28.89/28.96  tff(decl_15020, type, fn_ingestion_3: $i > $i).
% 28.89/28.96  tff(decl_15021, type, fn_ingestion_1: $i > $i).
% 28.89/28.96  tff(decl_15022, type, tangible_entity_0: $i).
% 28.89/28.96  tff(decl_15023, type, bulk_feeding_1: $i > $o).
% 28.89/28.96  tff(decl_15024, type, 'Bulk-Feeding': $i).
% 28.89/28.96  tff(decl_15025, type, 'The process of ingesting large pieces of food.': $i).
% 28.89/28.96  tff(decl_15026, type, 'feeding of bulk': $i).
% 28.89/28.96  tff(decl_15027, type, 'bulk feeding': $i).
% 28.89/28.96  tff(decl_15028, type, 'bulk-feeding': $i).
% 28.89/28.96  tff(decl_15029, type, feeding_1: $i > $o).
% 28.89/28.96  tff(decl_15030, type, fluid_feeding_1: $i > $o).
% 28.89/28.96  tff(decl_15031, type, opportunistic_feeding_1: $i > $o).
% 28.89/28.96  tff(decl_15032, type, substrate_feeding_1: $i > $o).
% 28.89/28.96  tff(decl_15033, type, suspension_feeding_1: $i > $o).
% 28.89/28.96  tff(decl_15034, type, 'Bulk-Flow': $i).
% 28.89/28.96  tff(decl_15035, type, 'The movement of a fluid because of a pressure difference between two locations.': $i).
% 28.89/28.96  tff(decl_15036, type, 'flow of bulk': $i).
% 28.89/28.96  tff(decl_15037, type, 'bulk flow': $i).
% 28.89/28.96  tff(decl_15038, type, 'bulk-flow': $i).
% 28.89/28.96  tff(decl_15039, type, general_chemical_process_1: $i > $o).
% 28.89/28.96  tff(decl_15040, type, fn_bulk_flow_1: $i > $i).
% 28.89/28.96  tff(decl_15041, type, pressure_gradient_1: $i > $o).
% 28.89/28.96  tff(decl_15042, type, fn_bulk_flow_2: $i > $i).
% 28.89/28.96  tff(decl_15043, type, fn_bulk_flow_3: $i > $i).
% 28.89/28.96  tff(decl_15044, type, bulk_transport_1: $i > $o).
% 28.89/28.96  tff(decl_15045, type, 'Bulk-Transport': $i).
% 28.89/28.96  tff(decl_15046, type, 'The movement of large molecules, such as protein or polysaccharides, across the cell membrane through the use of vesicles.': $i).
% 28.89/28.96  tff(decl_15047, type, 'transport of bulk': $i).
% 28.89/28.96  tff(decl_15048, type, 'bulk transport': $i).
% 28.89/28.96  tff(decl_15049, type, 'bulk-transport': $i).
% 28.89/28.96  tff(decl_15050, type, fn_bulk_transport_1: $i > $i).
% 28.89/28.96  tff(decl_15051, type, fn_bulk_transport_2: $i > $i).
% 28.89/28.96  tff(decl_15052, type, fn_bulk_transport_3: $i > $i).
% 28.89/28.96  tff(decl_15053, type, fn_bulk_transport_4: $i > $i).
% 28.89/28.96  tff(decl_15054, type, fn_bulk_transport_5: $i > $i).
% 28.89/28.96  tff(decl_15055, type, fn_bulk_transport_6: $i > $i).
% 28.89/28.96  tff(decl_15056, type, fn_carry_1: $i > $i).
% 28.89/28.96  tff(decl_15057, type, bundle_sheath_1: $i > $o).
% 28.89/28.96  tff(decl_15058, type, 'Bundle-Sheath': $i).
% 28.89/28.96  tff(decl_15059, type, 'A layer or region of cells surrounding a vascular bundle.': $i).
% 28.89/28.96  tff(decl_15060, type, 'sheath of bundle': $i).
% 28.89/28.96  tff(decl_15061, type, 'bundle sheath': $i).
% 28.89/28.96  tff(decl_15062, type, 'bundle-sheath': $i).
% 28.89/28.96  tff(decl_15063, type, bundle_sheath_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15064, type, 'Bundle-Sheath-Cell': $i).
% 28.89/28.96  tff(decl_15065, type, 'A type of photosynthetic cell arranged into tightly packed sheaths around the veins of the leaf.': $i).
% 28.89/28.96  tff(decl_15066, type, 'bundle sheath cell': $i).
% 28.89/28.96  tff(decl_15067, type, 'bundle-sheath cell': $i).
% 28.89/28.96  tff(decl_15068, type, 'bundle-sheath-cell': $i).
% 28.89/28.96  tff(decl_15069, type, parenchyma_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15070, type, collenchyma_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15071, type, companion_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15072, type, fiber_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15073, type, fusiform_initials_1: $i > $o).
% 28.89/28.96  tff(decl_15074, type, guard_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15075, type, initial_meristem_1: $i > $o).
% 28.89/28.96  tff(decl_15076, type, mesophyll_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15077, type, placental_transfer_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15078, type, plant_cell_inside_hypotonic_solution_1: $i > $o).
% 28.89/28.96  tff(decl_15079, type, plant_cell_inside_isotonic_solution_1: $i > $o).
% 28.89/28.96  tff(decl_15080, type, rhizoid_1: $i > $o).
% 28.89/28.96  tff(decl_15081, type, sclereid_1: $i > $o).
% 28.89/28.96  tff(decl_15082, type, sclerenchyma_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15083, type, sieve_tube_element_1: $i > $o).
% 28.89/28.96  tff(decl_15084, type, fn_bundle_sheath_cell_1: $i > $i).
% 28.89/28.96  tff(decl_15085, type, 'Burkitts-Lymphoma': $i).
% 28.89/28.96  tff(decl_15086, type, 'A type of lymphatic cancer associated with the Epstein-Barr virus.': $i).
% 28.89/28.96  tff(decl_15087, type, 'burkitts lymphoma': $i).
% 28.89/28.96  tff(decl_15088, type, 'burkitts-lymphoma': $i).
% 28.89/28.96  tff(decl_15089, type, butter_1: $i > $o).
% 28.89/28.96  tff(decl_15090, type, 'Butter': $i).
% 28.89/28.96  tff(decl_15091, type, 'Butter is a dairy product made by churning fresh or fermented cream or milk.': $i).
% 28.89/28.96  tff(decl_15092, type, butter: $i).
% 28.89/28.96  tff(decl_15093, type, saturated_animal_fat_substance_1: $i > $o).
% 28.89/28.96  tff(decl_15094, type, lard_1: $i > $o).
% 28.89/28.96  tff(decl_15095, type, butterfly_1: $i > $o).
% 28.89/28.96  tff(decl_15096, type, 'Butterfly': $i).
% 28.89/28.96  tff(decl_15097, type, 'A mostly diurnal flying insect of the order Lepidoptera, the butterflies and moths.': $i).
% 28.89/28.96  tff(decl_15098, type, butterfly: $i).
% 28.89/28.96  tff(decl_15099, type, moth_1: $i > $o).
% 28.89/28.96  tff(decl_15100, type, buy_1: $i > $o).
% 28.89/28.96  tff(decl_15101, type, 'Buy': $i).
% 28.89/28.96  tff(decl_15102, type, buy: $i).
% 28.89/28.96  tff(decl_15103, type, purchase: $i).
% 28.89/28.96  tff(decl_15104, type, fn_buy_1: $i > $i).
% 28.89/28.96  tff(decl_15105, type, fn_buy_2: $i > $i).
% 28.89/28.96  tff(decl_15106, type, money_1: $i > $o).
% 28.89/28.96  tff(decl_15107, type, c3_photosynthesis_1: $i > $o).
% 28.89/28.96  tff(decl_15108, type, 'C3-Photosynthesis': $i).
% 28.89/28.96  tff(decl_15109, type, 'The C3 photosynthesis is called C3 because the CO2 is first incorporated into a 3-carbon compound.': $i).
% 28.89/28.96  tff(decl_15110, type, 'perform c3 photosynthesis': $i).
% 28.89/28.96  tff(decl_15111, type, 'perform c3-photosynthesis': $i).
% 28.89/28.96  tff(decl_15112, type, 'c3 photosynthesis': $i).
% 28.89/28.96  tff(decl_15113, type, 'c3-photosynthesis': $i).
% 28.89/28.96  tff(decl_15114, type, crassulacean_acid_metabolism_1: $i > $o).
% 28.89/28.96  tff(decl_15115, type, fn_c3_photosynthesis_1: $i > $i).
% 28.89/28.96  tff(decl_15116, type, fn_c3_photosynthesis_2: $i > $i).
% 28.89/28.96  tff(decl_15117, type, fn_c3_photosynthesis_3: $i > $i).
% 28.89/28.96  tff(decl_15118, type, fn_c3_photosynthesis_4: $i > $i).
% 28.89/28.96  tff(decl_15119, type, fn_c3_photosynthesis_5: $i > $i).
% 28.89/28.96  tff(decl_15120, type, fn_c3_photosynthesis_6: $i > $i).
% 28.89/28.96  tff(decl_15121, type, fn_c3_photosynthesis_7: $i > $i).
% 28.89/28.96  tff(decl_15122, type, fn_c3_photosynthesis_8: $i > $i).
% 28.89/28.96  tff(decl_15123, type, fn_c3_photosynthesis_9: $i > $i).
% 28.89/28.96  tff(decl_15124, type, fn_c3_photosynthesis_12: $i > $i).
% 28.89/28.96  tff(decl_15125, type, fn_c3_photosynthesis_13: $i > $i).
% 28.89/28.96  tff(decl_15126, type, fn_c3_photosynthesis_14: $i > $i).
% 28.89/28.96  tff(decl_15127, type, fn_c3_photosynthesis_15: $i > $i).
% 28.89/28.96  tff(decl_15128, type, fn_c3_photosynthesis_16: $i > $i).
% 28.89/28.96  tff(decl_15129, type, fn_c3_photosynthesis_17: $i > $i).
% 28.89/28.96  tff(decl_15130, type, fn_c3_photosynthesis_18: $i > $i).
% 28.89/28.96  tff(decl_15131, type, fn_c3_photosynthesis_19: $i > $i).
% 28.89/28.96  tff(decl_15132, type, fn_c3_photosynthesis_20: $i > $i).
% 28.89/28.96  tff(decl_15133, type, fn_c3_photosynthesis_21: $i > $i).
% 28.89/28.96  tff(decl_15134, type, fn_c3_photosynthesis_22: $i > $i).
% 28.89/28.96  tff(decl_15135, type, fn_c3_photosynthesis_23: $i > $i).
% 28.89/28.96  tff(decl_15136, type, fn_c3_photosynthesis_24: $i > $i).
% 28.89/28.96  tff(decl_15137, type, fn_c3_photosynthesis_25: $i > $i).
% 28.89/28.96  tff(decl_15138, type, fn_c3_photosynthesis_26: $i > $i).
% 28.89/28.96  tff(decl_15139, type, fn_c3_photosynthesis_27: $i > $i).
% 28.89/28.96  tff(decl_15140, type, fn_c3_photosynthesis_28: $i > $i).
% 28.89/28.96  tff(decl_15141, type, fn_c3_photosynthesis_29: $i > $i).
% 28.89/28.96  tff(decl_15142, type, fn_c3_photosynthesis_30: $i > $i).
% 28.89/28.96  tff(decl_15143, type, fn_c3_photosynthesis_31: $i > $i).
% 28.89/28.96  tff(decl_15144, type, fn_c3_photosynthesis_32: $i > $i).
% 28.89/28.96  tff(decl_15145, type, fn_c3_photosynthesis_34: $i > $i).
% 28.89/28.96  tff(decl_15146, type, fn_c3_photosynthesis_35: $i > $i).
% 28.89/28.96  tff(decl_15147, type, fn_c3_photosynthesis_36: $i > $i).
% 28.89/28.96  tff(decl_15148, type, fn_c3_photosynthesis_37: $i > $i).
% 28.89/28.96  tff(decl_15149, type, fn_c3_photosynthesis_38: $i > $i).
% 28.89/28.96  tff(decl_15150, type, fn_c3_photosynthesis_39: $i > $i).
% 28.89/28.96  tff(decl_15151, type, fn_c3_photosynthesis_40: $i > $i).
% 28.89/28.96  tff(decl_15152, type, linear_electron_flow_1: $i > $o).
% 28.89/28.96  tff(decl_15153, type, fn_c3_photosynthesis_41: $i > $i).
% 28.89/28.96  tff(decl_15154, type, fn_c3_photosynthesis_42: $i > $i).
% 28.89/28.96  tff(decl_15155, type, fn_c3_photosynthesis_43: $i > $i).
% 28.89/28.96  tff(decl_15156, type, fn_c3_photosynthesis_44: $i > $i).
% 28.89/28.96  tff(decl_15157, type, fn_c3_photosynthesis_45: $i > $i).
% 28.89/28.96  tff(decl_15158, type, fn_c3_photosynthesis_46: $i > $i).
% 28.89/28.96  tff(decl_15159, type, fn_c3_photosynthesis_47: $i > $i).
% 28.89/28.96  tff(decl_15160, type, thylakoid_membrane_1: $i > $o).
% 28.89/28.96  tff(decl_15161, type, fn_c3_photosynthesis_48: $i > $i).
% 28.89/28.96  tff(decl_15162, type, calvin_cycle_1: $i > $o).
% 28.89/28.96  tff(decl_15163, type, fn_c3_photosynthesis_49: $i > $i).
% 28.89/28.96  tff(decl_15164, type, fn_c3_photosynthesis_50: $i > $i).
% 28.89/28.96  tff(decl_15165, type, fn_c3_photosynthesis_51: $i > $i).
% 28.89/28.96  tff(decl_15166, type, fn_c3_photosynthesis_52: $i > $i).
% 28.89/28.96  tff(decl_15167, type, fn_c3_photosynthesis_53: $i > $i).
% 28.89/28.96  tff(decl_15168, type, fn_c3_photosynthesis_54: $i > $i).
% 28.89/28.96  tff(decl_15169, type, fn_c3_photosynthesis_55: $i > $i).
% 28.89/28.96  tff(decl_15170, type, regeneration_of_ribulose_bisphosphate_1: $i > $o).
% 28.89/28.96  tff(decl_15171, type, fn_c3_photosynthesis_56: $i > $i).
% 28.89/28.96  tff(decl_15172, type, reduction_in_calvin_cycle_1: $i > $o).
% 28.89/28.96  tff(decl_15173, type, fn_c3_photosynthesis_57: $i > $i).
% 28.89/28.96  tff(decl_15174, type, fn_c3_photosynthesis_58: $i > $i).
% 28.89/28.96  tff(decl_15175, type, fn_c3_photosynthesis_59: $i > $i).
% 28.89/28.96  tff(decl_15176, type, fn_c3_photosynthesis_60: $i > $i).
% 28.89/28.96  tff(decl_15177, type, fn_c3_photosynthesis_61: $i > $i).
% 28.89/28.96  tff(decl_15178, type, carbon_fixation_1: $i > $o).
% 28.89/28.96  tff(decl_15179, type, fn_c3_photosynthesis_62: $i > $i).
% 28.89/28.96  tff(decl_15180, type, fn_c3_photosynthesis_63: $i > $i).
% 28.89/28.96  tff(decl_15181, type, fn_c3_photosynthesis_64: $i > $i).
% 28.89/28.96  tff(decl_15182, type, fn_c3_photosynthesis_65: $i > $i).
% 28.89/28.96  tff(decl_15183, type, fn_c3_photosynthesis_66: $i > $i).
% 28.89/28.96  tff(decl_15184, type, fn_c3_photosynthesis_67: $i > $i).
% 28.89/28.96  tff(decl_15185, type, fn_c3_photosynthesis_68: $i > $i).
% 28.89/28.96  tff(decl_15186, type, fn_c3_photosynthesis_69: $i > $i).
% 28.89/28.96  tff(decl_15187, type, fn_c3_photosynthesis_70: $i > $i).
% 28.89/28.96  tff(decl_15188, type, fn_c3_photosynthesis_71: $i > $i).
% 28.89/28.96  tff(decl_15189, type, fn_c3_photosynthesis_72: $i > $i).
% 28.89/28.96  tff(decl_15190, type, fn_c3_photosynthesis_77: $i > $i).
% 28.89/28.96  tff(decl_15191, type, fn_c3_photosynthesis_78: $i > $i).
% 28.89/28.96  tff(decl_15192, type, fn_c3_photosynthesis_79: $i > $i).
% 28.89/28.96  tff(decl_15193, type, fn_c3_photosynthesis_80: $i > $i).
% 28.89/28.96  tff(decl_15194, type, fn_c3_photosynthesis_81: $i > $i).
% 28.89/28.96  tff(decl_15195, type, fn_c3_photosynthesis_82: $i > $i).
% 28.89/28.96  tff(decl_15196, type, fn_c3_photosynthesis_83: $i > $i).
% 28.89/28.96  tff(decl_15197, type, fn_c3_photosynthesis_84: $i > $i).
% 28.89/28.96  tff(decl_15198, type, fn_c3_photosynthesis_85: $i > $i).
% 28.89/28.96  tff(decl_15199, type, fn_c3_photosynthesis_86: $i > $i).
% 28.89/28.96  tff(decl_15200, type, fn_c3_photosynthesis_87: $i > $i).
% 28.89/28.96  tff(decl_15201, type, fn_c3_photosynthesis_88: $i > $i).
% 28.89/28.96  tff(decl_15202, type, fn_c3_photosynthesis_89: $i > $i).
% 28.89/28.96  tff(decl_15203, type, fn_c3_photosynthesis_90: $i > $i).
% 28.89/28.96  tff(decl_15204, type, photosystem_1: $i > $o).
% 28.89/28.96  tff(decl_15205, type, fn_c3_photosynthesis_91: $i > $i).
% 28.89/28.96  tff(decl_15206, type, fn_c3_photosynthesis_92: $i > $i).
% 28.89/28.96  tff(decl_15207, type, fn_c3_photosynthesis_93: $i > $i).
% 28.89/28.96  tff(decl_15208, type, thylakoid_1: $i > $o).
% 28.89/28.96  tff(decl_15209, type, fn_c3_photosynthesis_94: $i > $i).
% 28.89/28.96  tff(decl_15210, type, transmit_1: $i > $o).
% 28.89/28.96  tff(decl_15211, type, fn_c3_photosynthesis_95: $i > $i).
% 28.89/28.96  tff(decl_15212, type, green_light_1: $i > $o).
% 28.89/28.96  tff(decl_15213, type, fn_c3_photosynthesis_96: $i > $i).
% 28.89/28.96  tff(decl_15214, type, fn_c3_photosynthesis_97: $i > $i).
% 28.89/28.96  tff(decl_15215, type, yellow_light_1: $i > $o).
% 28.89/28.96  tff(decl_15216, type, fn_c3_photosynthesis_98: $i > $i).
% 28.89/28.96  tff(decl_15217, type, orange_light_1: $i > $o).
% 28.89/28.96  tff(decl_15218, type, fn_c3_photosynthesis_99: $i > $i).
% 28.89/28.96  tff(decl_15219, type, red_light_1: $i > $o).
% 28.89/28.96  tff(decl_15220, type, fn_c3_photosynthesis_100: $i > $i).
% 28.89/28.96  tff(decl_15221, type, violet_light_1: $i > $o).
% 28.89/28.96  tff(decl_15222, type, fn_c3_photosynthesis_101: $i > $i).
% 28.89/28.96  tff(decl_15223, type, fn_c3_photosynthesis_102: $i > $i).
% 28.89/28.96  tff(decl_15224, type, fn_c3_photosynthesis_103: $i > $i).
% 28.89/28.96  tff(decl_15225, type, fn_c3_photosynthesis_104: $i > $i).
% 28.89/28.96  tff(decl_15226, type, c3_plant_1: $i > $o).
% 28.89/28.96  tff(decl_15227, type, fn_c3_photosynthesis_105: $i > $i).
% 28.89/28.96  tff(decl_15228, type, porphyrin_1: $i > $o).
% 28.89/28.96  tff(decl_15229, type, chlorophyll_a_1: $i > $o).
% 28.89/28.96  tff(decl_15230, type, fn_c3_photosynthesis_106: $i > $i).
% 28.89/28.96  tff(decl_15231, type, stroma_1: $i > $o).
% 28.89/28.96  tff(decl_15232, type, fn_c3_photosynthesis_107: $i > $i).
% 28.89/28.96  tff(decl_15233, type, fn_c3_photosynthesis_108: $i > $i).
% 28.89/28.96  tff(decl_15234, type, fn_plant_cell_6: $i > $i).
% 28.89/28.96  tff(decl_15235, type, fn_light_reaction_53: $i > $i).
% 28.89/28.96  tff(decl_15236, type, fn_calvin_cycle_36: $i > $i).
% 28.89/28.96  tff(decl_15237, type, fn_chloroplast_26: $i > $i).
% 28.89/28.96  tff(decl_15238, type, fn_chloroplast_27: $i > $i).
% 28.89/28.96  tff(decl_15239, type, fn_chloroplast_66: $i > $i).
% 28.89/28.96  tff(decl_15240, type, fn_chloroplast_4: $i > $i).
% 28.89/28.96  tff(decl_15241, type, fn_chloroplast_67: $i > $i).
% 28.89/28.96  tff(decl_15242, type, fn_chloroplast_103: $i > $i).
% 28.89/28.96  tff(decl_15243, type, fn_chloroplast_68: $i > $i).
% 28.89/28.96  tff(decl_15244, type, fn_chloroplast_65: $i > $i).
% 28.89/28.96  tff(decl_15245, type, fn_chloroplast_63: $i > $i).
% 28.89/28.96  tff(decl_15246, type, fn_chloroplast_52: $i > $i).
% 28.89/28.96  tff(decl_15247, type, fn_chloroplast_35: $i > $i).
% 28.89/28.96  tff(decl_15248, type, fn_chloroplast_72: $i > $i).
% 28.89/28.96  tff(decl_15249, type, fn_chloroplast_64: $i > $i).
% 28.89/28.96  tff(decl_15250, type, fn_chloroplast_54: $i > $i).
% 28.89/28.96  tff(decl_15251, type, fn_chloroplast_53: $i > $i).
% 28.89/28.96  tff(decl_15252, type, fn_chloroplast_34: $i > $i).
% 28.89/28.96  tff(decl_15253, type, fn_chloroplast_71: $i > $i).
% 28.89/28.96  tff(decl_15254, type, fn_chloroplast_91: $i > $i).
% 28.89/28.96  tff(decl_15255, type, fn_chloroplast_96: $i > $i).
% 28.89/28.96  tff(decl_15256, type, fn_calvin_cycle_121: $i > $i).
% 28.89/28.96  tff(decl_15257, type, fn_calvin_cycle_122: $i > $i).
% 28.89/28.96  tff(decl_15258, type, fn_calvin_cycle_115: $i > $i).
% 28.89/28.96  tff(decl_15259, type, fn_calvin_cycle_114: $i > $i).
% 28.89/28.96  tff(decl_15260, type, fn_calvin_cycle_116: $i > $i).
% 28.89/28.96  tff(decl_15261, type, fn_calvin_cycle_113: $i > $i).
% 28.89/28.96  tff(decl_15262, type, fn_calvin_cycle_112: $i > $i).
% 28.89/28.96  tff(decl_15263, type, fn_calvin_cycle_118: $i > $i).
% 28.89/28.96  tff(decl_15264, type, fn_calvin_cycle_84: $i > $i).
% 28.89/28.96  tff(decl_15265, type, fn_calvin_cycle_119: $i > $i).
% 28.89/28.96  tff(decl_15266, type, fn_calvin_cycle_120: $i > $i).
% 28.89/28.96  tff(decl_15267, type, fn_calvin_cycle_70: $i > $i).
% 28.89/28.96  tff(decl_15268, type, fn_calvin_cycle_73: $i > $i).
% 28.89/28.96  tff(decl_15269, type, fn_calvin_cycle_69: $i > $i).
% 28.89/28.96  tff(decl_15270, type, fn_calvin_cycle_62: $i > $i).
% 28.89/28.96  tff(decl_15271, type, fn_endergonic_reaction_3: $i > $i).
% 28.89/28.96  tff(decl_15272, type, fn_light_reaction_59: $i > $i).
% 28.89/28.96  tff(decl_15273, type, fn_light_reaction_19: $i > $i).
% 28.89/28.96  tff(decl_15274, type, fn_light_reaction_13: $i > $i).
% 28.89/28.96  tff(decl_15275, type, fn_light_reaction_52: $i > $i).
% 28.89/28.96  tff(decl_15276, type, fn_calvin_cycle_30: $i > $i).
% 28.89/28.96  tff(decl_15277, type, fn_calvin_cycle_37: $i > $i).
% 28.89/28.96  tff(decl_15278, type, fn_chloroplast_58: $i > $i).
% 28.89/28.96  tff(decl_15279, type, fn_chloroplast_62: $i > $i).
% 28.89/28.96  tff(decl_15280, type, fn_chloroplast_102: $i > $i).
% 28.89/28.96  tff(decl_15281, type, fn_chloroplast_84: $i > $i).
% 28.89/28.96  tff(decl_15282, type, fn_chloroplast_81: $i > $i).
% 28.89/28.96  tff(decl_15283, type, fn_anabolic_pathway_1: $i > $i).
% 28.89/28.96  tff(decl_15284, type, fn_glucose_1: $i > $i).
% 28.89/28.96  tff(decl_15285, type, fn_calvin_cycle_117: $i > $i).
% 28.89/28.96  tff(decl_15286, type, fn_calvin_cycle_110: $i > $i).
% 28.89/28.96  tff(decl_15287, type, fn_calvin_cycle_111: $i > $i).
% 28.89/28.96  tff(decl_15288, type, fn_calvin_cycle_61: $i > $i).
% 28.89/28.96  tff(decl_15289, type, fn_calvin_cycle_60: $i > $i).
% 28.89/28.96  tff(decl_15290, type, fn_calvin_cycle_34: $i > $i).
% 28.89/28.96  tff(decl_15291, type, fn_calvin_cycle_57: $i > $i).
% 28.89/28.96  tff(decl_15292, type, fn_light_reaction_1: $i > $i).
% 28.89/28.96  tff(decl_15293, type, fn_calvin_cycle_82: $i > $i).
% 28.89/28.96  tff(decl_15294, type, fn_light_reaction_57: $i > $i).
% 28.89/28.96  tff(decl_15295, type, fn_electron_transport_chain_reaction_25: $i > $i).
% 28.89/28.96  tff(decl_15296, type, fn_calvin_cycle_77: $i > $i).
% 28.89/28.96  tff(decl_15297, type, fn_linear_electron_flow_99: $i > $i).
% 28.89/28.96  tff(decl_15298, type, fn_light_reaction_49: $i > $i).
% 28.89/28.96  tff(decl_15299, type, fn_calvin_cycle_89: $i > $i).
% 28.89/28.96  tff(decl_15300, type, fn_light_reaction_58: $i > $i).
% 28.89/28.96  tff(decl_15301, type, fn_chloroplast_78: $i > $i).
% 28.89/28.96  tff(decl_15302, type, fn_chloroplast_89: $i > $i).
% 28.89/28.96  tff(decl_15303, type, fn_light_reaction_47: $i > $i).
% 28.89/28.96  tff(decl_15304, type, fn_glucose_2: $i > $i).
% 28.89/28.96  tff(decl_15305, type, fn_chloroplast_86: $i > $i).
% 28.89/28.96  tff(decl_15306, type, fn_calvin_cycle_18: $i > $i).
% 28.89/28.96  tff(decl_15307, type, fn_calvin_cycle_59: $i > $i).
% 28.89/28.96  tff(decl_15308, type, fn_calvin_cycle_58: $i > $i).
% 28.89/28.96  tff(decl_15309, type, fn_chloroplast_88: $i > $i).
% 28.89/28.96  tff(decl_15310, type, fn_calvin_cycle_55: $i > $i).
% 28.89/28.96  tff(decl_15311, type, fn_linear_electron_flow_190: $i > $i).
% 28.89/28.96  tff(decl_15312, type, fn_light_reaction_12: $i > $i).
% 28.89/28.96  tff(decl_15313, type, fn_light_reaction_51: $i > $i).
% 28.89/28.96  tff(decl_15314, type, fn_chloroplast_77: $i > $i).
% 28.89/28.96  tff(decl_15315, type, fn_chloroplast_82: $i > $i).
% 28.89/28.96  tff(decl_15316, type, fn_linear_electron_flow_215: $i > $i).
% 28.89/28.96  tff(decl_15317, type, fn_light_reaction_54: $i > $i).
% 28.89/28.96  tff(decl_15318, type, 'MT1': $i).
% 28.89/28.96  tff(decl_15319, type, fn_photosynthesis_94: $i > $i).
% 28.89/28.96  tff(decl_15320, type, fn_photosynthesis_93: $i > $i).
% 28.89/28.96  tff(decl_15321, type, fn_photosynthesis_91: $i > $i).
% 28.89/28.96  tff(decl_15322, type, fn_photosynthesis_19: $i > $i).
% 28.89/28.96  tff(decl_15323, type, fn_photosynthesis_33: $i > $i).
% 28.89/28.96  tff(decl_15324, type, fn_photosynthesis_65: $i > $i).
% 28.89/28.96  tff(decl_15325, type, fn_photosynthesis_18: $i > $i).
% 28.89/28.96  tff(decl_15326, type, fn_c3_photosynthesis_33: $i > $i).
% 28.89/28.96  tff(decl_15327, type, fn_c3_photosynthesis_109: $i > $i).
% 28.89/28.96  tff(decl_15328, type, fn_c3_photosynthesis_110: $i > $i).
% 28.89/28.96  tff(decl_15329, type, fn_c3_photosynthesis_73: $i > $i).
% 28.89/28.96  tff(decl_15330, type, fn_c3_photosynthesis_74: $i > $i).
% 28.89/28.96  tff(decl_15331, type, fn_photosynthesis_92: $i > $i).
% 28.89/28.96  tff(decl_15332, type, fn_c3_photosynthesis_76: $i > $i).
% 28.89/28.96  tff(decl_15333, type, fn_photosynthesis_59: $i > $i).
% 28.89/28.96  tff(decl_15334, type, fn_photosynthesis_61: $i > $i).
% 28.89/28.96  tff(decl_15335, type, fn_photosynthesis_62: $i > $i).
% 28.89/28.96  tff(decl_15336, type, fn_c3_photosynthesis_75: $i > $i).
% 28.89/28.96  tff(decl_15337, type, fn_c3_photosynthesis_11: $i > $i).
% 28.89/28.96  tff(decl_15338, type, fn_c3_photosynthesis_10: $i > $i).
% 28.89/28.96  tff(decl_15339, type, fn_photosynthesis_58: $i > $i).
% 28.89/28.96  tff(decl_15340, type, fn_photosynthesis_64: $i > $i).
% 28.89/28.96  tff(decl_15341, type, fn_photosynthesis_11: $i > $i).
% 28.89/28.96  tff(decl_15342, type, fn_photosynthesis_36: $i > $i).
% 28.89/28.96  tff(decl_15343, type, 'C3-Plant': $i).
% 28.89/28.96  tff(decl_15344, type, 'A plant that fixes atmospheric CO2 directly into a 3-carbon molecule.': $i).
% 28.89/28.96  tff(decl_15345, type, 'c3 plant': $i).
% 28.89/28.96  tff(decl_15346, type, 'c3-plant': $i).
% 28.89/28.96  tff(decl_15347, type, fn_c3_plant_1: $i > $i).
% 28.89/28.96  tff(decl_15348, type, fn_c3_plant_2: $i > $i).
% 28.89/28.96  tff(decl_15349, type, photosystem_ii_1: $i > $o).
% 28.89/28.96  tff(decl_15350, type, fn_c3_plant_3: $i > $i).
% 28.89/28.96  tff(decl_15351, type, fn_c3_plant_4: $i > $i).
% 28.89/28.96  tff(decl_15352, type, fn_c3_plant_5: $i > $i).
% 28.89/28.96  tff(decl_15353, type, fn_c3_plant_8: $i > $i).
% 28.89/28.96  tff(decl_15354, type, fn_c3_plant_9: $i > $i).
% 28.89/28.96  tff(decl_15355, type, fn_c3_plant_11: $i > $i).
% 28.89/28.96  tff(decl_15356, type, fn_c3_plant_12: $i > $i).
% 28.89/28.96  tff(decl_15357, type, fn_c3_plant_13: $i > $i).
% 28.89/28.96  tff(decl_15358, type, fn_c3_plant_14: $i > $i).
% 28.89/28.96  tff(decl_15359, type, fn_c3_plant_15: $i > $i).
% 28.89/28.96  tff(decl_15360, type, fn_c3_plant_16: $i > $i).
% 28.89/28.96  tff(decl_15361, type, starch_storage_by_plant_1: $i > $o).
% 28.89/28.96  tff(decl_15362, type, fn_c3_plant_19: $i > $i).
% 28.89/28.96  tff(decl_15363, type, fn_c3_plant_20: $i > $i).
% 28.89/28.96  tff(decl_15364, type, fn_c3_plant_21: $i > $i).
% 28.89/28.96  tff(decl_15365, type, fn_c3_plant_22: $i > $i).
% 28.89/28.96  tff(decl_15366, type, fn_c3_plant_23: $i > $i).
% 28.89/28.96  tff(decl_15367, type, fn_c3_plant_24: $i > $i).
% 28.89/28.96  tff(decl_15368, type, fn_c3_plant_25: $i > $i).
% 28.89/28.96  tff(decl_15369, type, fn_c3_plant_26: $i > $i).
% 28.89/28.96  tff(decl_15370, type, fn_c3_plant_27: $i > $i).
% 28.89/28.96  tff(decl_15371, type, fn_c3_plant_28: $i > $i).
% 28.89/28.96  tff(decl_15372, type, fn_c3_plant_29: $i > $i).
% 28.89/28.96  tff(decl_15373, type, fn_c3_plant_30: $i > $i).
% 28.89/28.96  tff(decl_15374, type, fn_c3_plant_31: $i > $i).
% 28.89/28.96  tff(decl_15375, type, fn_c3_plant_32: $i > $i).
% 28.89/28.96  tff(decl_15376, type, fn_c3_plant_33: $i > $i).
% 28.89/28.96  tff(decl_15377, type, fn_c3_plant_34: $i > $i).
% 28.89/28.96  tff(decl_15378, type, fn_c3_plant_35: $i > $i).
% 28.89/28.96  tff(decl_15379, type, fn_c3_plant_36: $i > $i).
% 28.89/28.96  tff(decl_15380, type, cytoplasmic_streaming_1: $i > $o).
% 28.89/28.96  tff(decl_15381, type, fn_c3_plant_37: $i > $i).
% 28.89/28.96  tff(decl_15382, type, fn_c3_plant_38: $i > $i).
% 28.89/28.96  tff(decl_15383, type, fn_c3_plant_39: $i > $i).
% 28.89/28.96  tff(decl_15384, type, fn_c3_plant_44: $i > $i).
% 28.89/28.96  tff(decl_15385, type, fn_c3_plant_45: $i > $i).
% 28.89/28.96  tff(decl_15386, type, fn_c3_plant_46: $i > $i).
% 28.89/28.96  tff(decl_15387, type, fn_c3_plant_47: $i > $i).
% 28.89/28.96  tff(decl_15388, type, fn_c3_plant_48: $i > $i).
% 28.89/28.96  tff(decl_15389, type, fn_c3_plant_49: $i > $i).
% 28.89/28.96  tff(decl_15390, type, fn_c3_plant_50: $i > $i).
% 28.89/28.96  tff(decl_15391, type, fn_c3_plant_51: $i > $i).
% 28.89/28.96  tff(decl_15392, type, photosystem_i_1: $i > $o).
% 28.89/28.96  tff(decl_15393, type, fn_c3_plant_52: $i > $i).
% 28.89/28.96  tff(decl_15394, type, fn_c3_plant_53: $i > $i).
% 28.89/28.96  tff(decl_15395, type, fn_c3_plant_54: $i > $i).
% 28.89/28.96  tff(decl_15396, type, fn_c3_plant_55: $i > $i).
% 28.89/28.96  tff(decl_15397, type, fn_c3_plant_56: $i > $i).
% 28.89/28.96  tff(decl_15398, type, fn_c3_plant_57: $i > $i).
% 28.89/28.96  tff(decl_15399, type, fn_c3_plant_58: $i > $i).
% 28.89/28.96  tff(decl_15400, type, fn_c3_plant_59: $i > $i).
% 28.89/28.96  tff(decl_15401, type, fn_c3_plant_60: $i > $i).
% 28.89/28.96  tff(decl_15402, type, fn_c3_plant_61: $i > $i).
% 28.89/28.96  tff(decl_15403, type, fn_c3_plant_62: $i > $i).
% 28.89/28.96  tff(decl_15404, type, fn_c3_plant_63: $i > $i).
% 28.89/28.96  tff(decl_15405, type, fn_c3_plant_64: $i > $i).
% 28.89/28.96  tff(decl_15406, type, fn_c3_plant_65: $i > $i).
% 28.89/28.96  tff(decl_15407, type, fn_c3_plant_66: $i > $i).
% 28.89/28.96  tff(decl_15408, type, fn_c3_plant_67: $i > $i).
% 28.89/28.96  tff(decl_15409, type, photorespiration_1: $i > $o).
% 28.89/28.96  tff(decl_15410, type, fn_c3_plant_68: $i > $i).
% 28.89/28.96  tff(decl_15411, type, fn_c3_plant_70: $i > $i).
% 28.89/28.96  tff(decl_15412, type, fn_c3_plant_71: $i > $i).
% 28.89/28.96  tff(decl_15413, type, fn_c3_plant_72: $i > $i).
% 28.89/28.96  tff(decl_15414, type, fn_c3_plant_73: $i > $i).
% 28.89/28.96  tff(decl_15415, type, fn_c3_plant_74: $i > $i).
% 28.89/28.96  tff(decl_15416, type, fn_c3_plant_75: $i > $i).
% 28.89/28.96  tff(decl_15417, type, fn_c3_plant_76: $i > $i).
% 28.89/28.96  tff(decl_15418, type, fn_c3_plant_77: $i > $i).
% 28.89/28.96  tff(decl_15419, type, nonpolar_molecule_1: $i > $o).
% 28.89/28.96  tff(decl_15420, type, fn_c3_plant_78: $i > $i).
% 28.89/28.96  tff(decl_15421, type, fn_c3_plant_79: $i > $i).
% 28.89/28.96  tff(decl_15422, type, fn_c3_plant_80: $i > $i).
% 28.89/28.96  tff(decl_15423, type, fn_c3_plant_81: $i > $i).
% 28.89/28.96  tff(decl_15424, type, microfibril_1: $i > $o).
% 28.89/28.96  tff(decl_15425, type, fn_c3_plant_82: $i > $i).
% 28.89/28.96  tff(decl_15426, type, fn_c3_plant_83: $i > $i).
% 28.89/28.96  tff(decl_15427, type, fn_c3_plant_84: $i > $i).
% 28.89/28.96  tff(decl_15428, type, photoautotroph_1: $i > $o).
% 28.89/28.96  tff(decl_15429, type, fn_c3_plant_85: $i > $i).
% 28.89/28.96  tff(decl_15430, type, fn_c3_plant_86: $i > $i).
% 28.89/28.96  tff(decl_15431, type, fn_c3_plant_89: $i > $i).
% 28.89/28.96  tff(decl_15432, type, fn_c3_plant_90: $i > $i).
% 28.89/28.96  tff(decl_15433, type, fn_c3_plant_91: $i > $i).
% 28.89/28.96  tff(decl_15434, type, fn_c3_plant_92: $i > $i).
% 28.89/28.96  tff(decl_15435, type, photoprotection_in_plant_1: $i > $o).
% 28.89/28.96  tff(decl_15436, type, fn_c3_plant_93: $i > $i).
% 28.89/28.96  tff(decl_15437, type, fn_c3_plant_94: $i > $i).
% 28.89/28.96  tff(decl_15438, type, fn_c3_plant_95: $i > $i).
% 28.89/28.96  tff(decl_15439, type, fn_c3_plant_96: $i > $i).
% 28.89/28.96  tff(decl_15440, type, fn_c3_plant_97: $i > $i).
% 28.89/28.96  tff(decl_15441, type, fn_c3_plant_100: $i > $i).
% 28.89/28.96  tff(decl_15442, type, fn_c3_plant_101: $i > $i).
% 28.89/28.96  tff(decl_15443, type, fn_c3_plant_102: $i > $i).
% 28.89/28.96  tff(decl_15444, type, fn_c3_plant_103: $i > $i).
% 28.89/28.96  tff(decl_15445, type, fn_c3_plant_104: $i > $i).
% 28.89/28.96  tff(decl_15446, type, fn_c3_plant_105: $i > $i).
% 28.89/28.96  tff(decl_15447, type, fn_c3_plant_106: $i > $i).
% 28.89/28.96  tff(decl_15448, type, fn_c3_plant_107: $i > $i).
% 28.89/28.96  tff(decl_15449, type, p700_1: $i > $o).
% 28.89/28.96  tff(decl_15450, type, fn_c3_plant_108: $i > $i).
% 28.89/28.96  tff(decl_15451, type, fn_c3_plant_109: $i > $i).
% 28.89/28.96  tff(decl_15452, type, carotenoid_1: $i > $o).
% 28.89/28.96  tff(decl_15453, type, fn_c3_plant_110: $i > $i).
% 28.89/28.96  tff(decl_15454, type, fn_c3_plant_111: $i > $i).
% 28.89/28.96  tff(decl_15455, type, fn_c3_plant_112: $i > $i).
% 28.89/28.96  tff(decl_15456, type, fn_c3_plant_113: $i > $i).
% 28.89/28.96  tff(decl_15457, type, tuber_1: $i > $o).
% 28.89/28.96  tff(decl_15458, type, fn_photorespiration_9: $i > $i).
% 28.89/28.96  tff(decl_15459, type, fn_photorespiration_3: $i > $i).
% 28.89/28.96  tff(decl_15460, type, fn_photorespiration_4: $i > $i).
% 28.89/28.96  tff(decl_15461, type, fn_photosynthesis_30: $i > $i).
% 28.89/28.96  tff(decl_15462, type, fn_photosynthesis_66: $i > $i).
% 28.89/28.96  tff(decl_15463, type, fn_photosynthesis_71: $i > $i).
% 28.89/28.96  tff(decl_15464, type, fn_photosynthesis_72: $i > $i).
% 28.89/28.96  tff(decl_15465, type, fn_photosynthesis_67: $i > $i).
% 28.89/28.96  tff(decl_15466, type, fn_photosynthesis_73: $i > $i).
% 28.89/28.96  tff(decl_15467, type, fn_photosynthesis_74: $i > $i).
% 28.89/28.96  tff(decl_15468, type, fn_photosynthesis_75: $i > $i).
% 28.89/28.96  tff(decl_15469, type, fn_plant_cell_89: $i > $i).
% 28.89/28.96  tff(decl_15470, type, fn_plant_cell_73: $i > $i).
% 28.89/28.96  tff(decl_15471, type, fn_plant_cell_1: $i > $i).
% 28.89/28.96  tff(decl_15472, type, fn_plant_cell_72: $i > $i).
% 28.89/28.96  tff(decl_15473, type, fn_plant_cell_11: $i > $i).
% 28.89/28.96  tff(decl_15474, type, fn_plant_cell_74: $i > $i).
% 28.89/28.96  tff(decl_15475, type, fn_plant_cell_71: $i > $i).
% 28.89/28.96  tff(decl_15476, type, fn_nonpolar_molecule_3: $i > $i).
% 28.89/28.96  tff(decl_15477, type, fn_plasmodesmata_3: $i > $i).
% 28.89/28.96  tff(decl_15478, type, fn_plant_cell_wall_25: $i > $i).
% 28.89/28.96  tff(decl_15479, type, fn_plant_cell_wall_28: $i > $i).
% 28.89/28.96  tff(decl_15480, type, fn_plant_cell_wall_23: $i > $i).
% 28.89/28.96  tff(decl_15481, type, fn_plant_cell_wall_22: $i > $i).
% 28.89/28.96  tff(decl_15482, type, fn_carotenoid_18: $i > $i).
% 28.89/28.96  tff(decl_15483, type, fn_photosynthesis_68: $i > $i).
% 28.89/28.96  tff(decl_15484, type, fn_photosynthesis_69: $i > $i).
% 28.89/28.96  tff(decl_15485, type, fn_photosynthesis_70: $i > $i).
% 28.89/28.96  tff(decl_15486, type, fn_photoprotection_in_plant_1: $i > $i).
% 28.89/28.96  tff(decl_15487, type, fn_photosynthesis_41: $i > $i).
% 28.89/28.96  tff(decl_15488, type, fn_thylakoid_membrane_16: $i > $i).
% 28.89/28.96  tff(decl_15489, type, fn_cellular_respiration_43: $i > $i).
% 28.89/28.96  tff(decl_15490, type, fn_plant_cell_116: $i > $i).
% 28.89/28.96  tff(decl_15491, type, fn_cellular_respiration_56: $i > $i).
% 28.89/28.96  tff(decl_15492, type, fn_plant_cell_25: $i > $i).
% 28.89/28.96  tff(decl_15493, type, fn_colloid_4: $i > $i).
% 28.89/28.96  tff(decl_15494, type, fn_plant_cell_94: $i > $i).
% 28.89/28.96  tff(decl_15495, type, fn_smooth_endoplasmic_reticulum_37: $i > $i).
% 28.89/28.96  tff(decl_15496, type, fn_smooth_endoplasmic_reticulum_50: $i > $i).
% 28.89/28.96  tff(decl_15497, type, fn_thylakoid_membrane_9: $i > $i).
% 28.89/28.96  tff(decl_15498, type, fn_cellular_respiration_61: $i > $i).
% 28.89/28.96  tff(decl_15499, type, fn_plant_cell_63: $i > $i).
% 28.89/28.96  tff(decl_15500, type, fn_cellular_respiration_58: $i > $i).
% 28.89/28.96  tff(decl_15501, type, fn_cellular_respiration_59: $i > $i).
% 28.89/28.96  tff(decl_15502, type, fn_glycoprotein_17: $i > $i).
% 28.89/28.96  tff(decl_15503, type, fn_glycolipid_1: $i > $i).
% 28.89/28.96  tff(decl_15504, type, fn_glycoprotein_14: $i > $i).
% 28.89/28.96  tff(decl_15505, type, fn_photorespiration_40: $i > $i).
% 28.89/28.96  tff(decl_15506, type, fn_plant_cell_92: $i > $i).
% 28.89/28.96  tff(decl_15507, type, fn_cell_27: $i > $i).
% 28.89/28.96  tff(decl_15508, type, fn_plant_cell_83: $i > $i).
% 28.89/28.96  tff(decl_15509, type, fn_plant_cell_75: $i > $i).
% 28.89/28.96  tff(decl_15510, type, fn_smooth_endoplasmic_reticulum_36: $i > $i).
% 28.89/28.96  tff(decl_15511, type, fn_plant_cell_84: $i > $i).
% 28.89/28.96  tff(decl_15512, type, fn_plant_cell_91: $i > $i).
% 28.89/28.96  tff(decl_15513, type, fn_cytoplasm_8: $i > $i).
% 28.89/28.96  tff(decl_15514, type, fn_plant_cell_76: $i > $i).
% 28.89/28.96  tff(decl_15515, type, fn_eukaryotic_cell_39: $i > $i).
% 28.89/28.96  tff(decl_15516, type, fn_smooth_endoplasmic_reticulum_28: $i > $i).
% 28.89/28.96  tff(decl_15517, type, fn_plant_cell_77: $i > $i).
% 28.89/28.96  tff(decl_15518, type, fn_photorespiration_57: $i > $i).
% 28.89/28.96  tff(decl_15519, type, fn_cytoplasm_7: $i > $i).
% 28.89/28.96  tff(decl_15520, type, fn_plant_cell_wall_24: $i > $i).
% 28.89/28.96  tff(decl_15521, type, fn_plant_cell_wall_10: $i > $i).
% 28.89/28.96  tff(decl_15522, type, fn_plant_cell_wall_21: $i > $i).
% 28.89/28.96  tff(decl_15523, type, fn_plant_cell_21: $i > $i).
% 28.89/28.96  tff(decl_15524, type, fn_plant_cell_wall_27: $i > $i).
% 28.89/28.96  tff(decl_15525, type, fn_plant_cell_78: $i > $i).
% 28.89/28.96  tff(decl_15526, type, fn_plant_cell_wall_17: $i > $i).
% 28.89/28.96  tff(decl_15527, type, fn_plasmodesmata_9: $i > $i).
% 28.89/28.96  tff(decl_15528, type, fn_plant_cell_wall_26: $i > $i).
% 28.89/28.96  tff(decl_15529, type, fn_plasmodesmata_10: $i > $i).
% 28.89/28.96  tff(decl_15530, type, fn_c3_plant_69: $i > $i).
% 28.89/28.96  tff(decl_15531, type, fn_c3_plant_41: $i > $i).
% 28.89/28.96  tff(decl_15532, type, fn_c3_plant_40: $i > $i).
% 28.89/28.96  tff(decl_15533, type, fn_c3_plant_99: $i > $i).
% 28.89/28.96  tff(decl_15534, type, fn_c3_plant_98: $i > $i).
% 28.89/28.96  tff(decl_15535, type, fn_plant_10: $i > $i).
% 28.89/28.96  tff(decl_15536, type, fn_plant_4: $i > $i).
% 28.89/28.96  tff(decl_15537, type, fn_c3_plant_43: $i > $i).
% 28.89/28.96  tff(decl_15538, type, fn_c3_plant_42: $i > $i).
% 28.89/28.96  tff(decl_15539, type, fn_c3_plant_18: $i > $i).
% 28.89/28.96  tff(decl_15540, type, fn_c3_plant_17: $i > $i).
% 28.89/28.96  tff(decl_15541, type, fn_plant_46: $i > $i).
% 28.89/28.96  tff(decl_15542, type, fn_c3_plant_87: $i > $i).
% 28.89/28.96  tff(decl_15543, type, fn_plant_21: $i > $i).
% 28.89/28.96  tff(decl_15544, type, fn_c3_plant_88: $i > $i).
% 28.89/28.96  tff(decl_15545, type, fn_plant_22: $i > $i).
% 28.89/28.96  tff(decl_15546, type, fn_plant_17: $i > $i).
% 28.89/28.96  tff(decl_15547, type, fn_plant_11: $i > $i).
% 28.89/28.96  tff(decl_15548, type, fn_plant_12: $i > $i).
% 28.89/28.96  tff(decl_15549, type, fn_plant_16: $i > $i).
% 28.89/28.96  tff(decl_15550, type, fn_plant_19: $i > $i).
% 28.89/28.96  tff(decl_15551, type, fn_plant_13: $i > $i).
% 28.89/28.96  tff(decl_15552, type, fn_plant_15: $i > $i).
% 28.89/28.96  tff(decl_15553, type, fn_plant_14: $i > $i).
% 28.89/28.96  tff(decl_15554, type, fn_plant_34: $i > $i).
% 28.89/28.96  tff(decl_15555, type, c3h2o4_minus_2_1: $i > $o).
% 28.89/28.96  tff(decl_15556, type, 'C3H2O4-Minus-2': $i).
% 28.89/28.96  tff(decl_15557, type, 'c3h2o4 minus 2': $i).
% 28.89/28.96  tff(decl_15558, type, 'c3h2o4-minus-2': $i).
% 28.89/28.96  tff(decl_15559, type, fn_c3h2o4_minus_2_2: $i > $i).
% 28.89/28.96  tff(decl_15560, type, "-2": $i).
% 28.89/28.96  tff(decl_15561, type, fn_c3h2o4_minus_2_1: $i > $i).
% 28.89/28.96  tff(decl_15562, type, c3h8_1: $i > $o).
% 28.89/28.96  tff(decl_15563, type, 'C3H8': $i).
% 28.89/28.96  tff(decl_15564, type, 'Propane is a hydrocarbon, normally in a gaseous state and commonly used as a fuel.': $i).
% 28.89/28.96  tff(decl_15565, type, propane: $i).
% 28.89/28.96  tff(decl_15566, type, c3h8: $i).
% 28.89/28.96  tff(decl_15567, type, c3h8_substance_1: $i > $o).
% 28.89/28.96  tff(decl_15568, type, 'C3H8-Substance': $i).
% 28.89/28.96  tff(decl_15569, type, 'substance of c3h8': $i).
% 28.89/28.96  tff(decl_15570, type, 'c3h8 substance': $i).
% 28.89/28.96  tff(decl_15571, type, 'c3h8-substance': $i).
% 28.89/28.96  tff(decl_15572, type, hydrocarbon_substance_1: $i > $o).
% 28.89/28.96  tff(decl_15573, type, fn_c3h8_substance_1: $i > $i).
% 28.89/28.96  tff(decl_15574, type, fn_hydrocarbon_substance_1: $i > $i).
% 28.89/28.96  tff(decl_15575, type, 'C4-Photosynthesis': $i).
% 28.89/28.96  tff(decl_15576, type, 'The C4 photosynthesis is called C4 because the CO2 is first incorporated into a 4-carbon compound. PEP Carboxylase is the enzyme involved in the uptake of CO2.': $i).
% 28.89/28.96  tff(decl_15577, type, 'c4 pathway': $i).
% 28.89/28.96  tff(decl_15578, type, 'c4 photosynthesis': $i).
% 28.89/28.96  tff(decl_15579, type, 'c4-photosynthesis': $i).
% 28.89/28.96  tff(decl_15580, type, fn_c4_photosynthesis_1: $i > $i).
% 28.89/28.96  tff(decl_15581, type, fn_c4_photosynthesis_2: $i > $i).
% 28.89/28.96  tff(decl_15582, type, fn_c4_photosynthesis_3: $i > $i).
% 28.89/28.96  tff(decl_15583, type, fn_c4_photosynthesis_4: $i > $i).
% 28.89/28.96  tff(decl_15584, type, fn_c4_photosynthesis_5: $i > $i).
% 28.89/28.96  tff(decl_15585, type, fn_c4_photosynthesis_6: $i > $i).
% 28.89/28.96  tff(decl_15586, type, fn_c4_photosynthesis_7: $i > $i).
% 28.89/28.96  tff(decl_15587, type, fn_c4_photosynthesis_8: $i > $i).
% 28.89/28.96  tff(decl_15588, type, fn_c4_photosynthesis_11: $i > $i).
% 28.89/28.96  tff(decl_15589, type, fn_c4_photosynthesis_12: $i > $i).
% 28.89/28.96  tff(decl_15590, type, fn_c4_photosynthesis_13: $i > $i).
% 28.89/28.96  tff(decl_15591, type, fn_c4_photosynthesis_14: $i > $i).
% 28.89/28.96  tff(decl_15592, type, fn_c4_photosynthesis_15: $i > $i).
% 28.89/28.96  tff(decl_15593, type, fn_c4_photosynthesis_16: $i > $i).
% 28.89/28.96  tff(decl_15594, type, fn_c4_photosynthesis_17: $i > $i).
% 28.89/28.96  tff(decl_15595, type, fn_c4_photosynthesis_18: $i > $i).
% 28.89/28.96  tff(decl_15596, type, fn_c4_photosynthesis_19: $i > $i).
% 28.89/28.96  tff(decl_15597, type, fn_c4_photosynthesis_20: $i > $i).
% 28.89/28.96  tff(decl_15598, type, fn_c4_photosynthesis_21: $i > $i).
% 28.89/28.96  tff(decl_15599, type, fn_c4_photosynthesis_22: $i > $i).
% 28.89/28.96  tff(decl_15600, type, fn_c4_photosynthesis_23: $i > $i).
% 28.89/28.96  tff(decl_15601, type, phosphoenolpyruvate_1: $i > $o).
% 28.89/28.96  tff(decl_15602, type, fn_c4_photosynthesis_24: $i > $i).
% 28.89/28.96  tff(decl_15603, type, fn_c4_photosynthesis_25: $i > $i).
% 28.89/28.96  tff(decl_15604, type, pep_carboxylase_1: $i > $o).
% 28.89/28.96  tff(decl_15605, type, fn_c4_photosynthesis_26: $i > $i).
% 28.89/28.96  tff(decl_15606, type, fn_c4_photosynthesis_27: $i > $i).
% 28.89/28.96  tff(decl_15607, type, fn_c4_photosynthesis_28: $i > $i).
% 28.89/28.96  tff(decl_15608, type, fn_c4_photosynthesis_29: $i > $i).
% 28.89/28.96  tff(decl_15609, type, fn_c4_photosynthesis_30: $i > $i).
% 28.89/28.96  tff(decl_15610, type, fn_c4_photosynthesis_31: $i > $i).
% 28.89/28.96  tff(decl_15611, type, fn_c4_photosynthesis_32: $i > $i).
% 28.89/28.96  tff(decl_15612, type, fn_c4_photosynthesis_33: $i > $i).
% 28.89/28.96  tff(decl_15613, type, fn_c4_photosynthesis_34: $i > $i).
% 28.89/28.96  tff(decl_15614, type, fn_c4_photosynthesis_35: $i > $i).
% 28.89/28.96  tff(decl_15615, type, fn_c4_photosynthesis_36: $i > $i).
% 28.89/28.96  tff(decl_15616, type, dermal_tissue_system_1: $i > $o).
% 28.89/28.96  tff(decl_15617, type, fn_c4_photosynthesis_37: $i > $i).
% 28.89/28.96  tff(decl_15618, type, ground_tissue_system_1: $i > $o).
% 28.89/28.96  tff(decl_15619, type, fn_c4_photosynthesis_38: $i > $i).
% 28.89/28.96  tff(decl_15620, type, fn_c4_photosynthesis_39: $i > $i).
% 28.89/28.96  tff(decl_15621, type, fn_c4_photosynthesis_40: $i > $i).
% 28.89/28.96  tff(decl_15622, type, fn_c4_photosynthesis_41: $i > $i).
% 28.89/28.96  tff(decl_15623, type, fn_c4_photosynthesis_42: $i > $i).
% 28.89/28.96  tff(decl_15624, type, fn_c4_photosynthesis_43: $i > $i).
% 28.89/28.96  tff(decl_15625, type, fn_c4_photosynthesis_44: $i > $i).
% 28.89/28.96  tff(decl_15626, type, fn_c4_photosynthesis_45: $i > $i).
% 28.89/28.96  tff(decl_15627, type, fn_c4_photosynthesis_46: $i > $i).
% 28.89/28.96  tff(decl_15628, type, fn_c4_photosynthesis_47: $i > $i).
% 28.89/28.96  tff(decl_15629, type, ribulose_bisphosphate_1: $i > $o).
% 28.89/28.96  tff(decl_15630, type, fn_c4_photosynthesis_48: $i > $i).
% 28.89/28.96  tff(decl_15631, type, fn_c4_photosynthesis_49: $i > $i).
% 28.89/28.96  tff(decl_15632, type, transfer_of_malate_to_bundle_sheath_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15633, type, fn_c4_photosynthesis_50: $i > $i).
% 28.89/28.96  tff(decl_15634, type, leaf_1: $i > $o).
% 28.89/28.96  tff(decl_15635, type, fn_c4_photosynthesis_51: $i > $i).
% 28.89/28.96  tff(decl_15636, type, fn_c4_photosynthesis_52: $i > $i).
% 28.89/28.96  tff(decl_15637, type, cyclic_electron_flow_1: $i > $o).
% 28.89/28.96  tff(decl_15638, type, fn_c4_photosynthesis_53: $i > $i).
% 28.89/28.96  tff(decl_15639, type, fn_c4_photosynthesis_54: $i > $i).
% 28.89/28.96  tff(decl_15640, type, fn_c4_photosynthesis_55: $i > $i).
% 28.89/28.96  tff(decl_15641, type, fn_c4_photosynthesis_56: $i > $i).
% 28.89/28.96  tff(decl_15642, type, plant_metabolic_cell_1: $i > $o).
% 28.89/28.96  tff(decl_15643, type, fn_c4_photosynthesis_57: $i > $i).
% 28.89/28.96  tff(decl_15644, type, fn_c4_photosynthesis_58: $i > $i).
% 28.89/28.96  tff(decl_15645, type, fn_c4_photosynthesis_59: $i > $i).
% 28.89/28.96  tff(decl_15646, type, eukaryotic_calvin_cycle_1: $i > $o).
% 28.89/28.96  tff(decl_15647, type, fn_c4_photosynthesis_60: $i > $i).
% 28.89/28.96  tff(decl_15648, type, partial_closing_of_stoma_1: $i > $o).
% 28.89/28.96  tff(decl_15649, type, fn_c4_photosynthesis_61: $i > $i).
% 28.89/28.96  tff(decl_15650, type, fn_c4_photosynthesis_62: $i > $i).
% 28.89/28.96  tff(decl_15651, type, fn_c4_photosynthesis_63: $i > $i).
% 28.89/28.96  tff(decl_15652, type, fn_c4_photosynthesis_64: $i > $i).
% 28.89/28.96  tff(decl_15653, type, fn_c4_photosynthesis_65: $i > $i).
% 28.89/28.96  tff(decl_15654, type, fn_c4_photosynthesis_66: $i > $i).
% 28.89/28.96  tff(decl_15655, type, fn_c4_photosynthesis_67: $i > $i).
% 28.89/28.96  tff(decl_15656, type, fn_c4_photosynthesis_68: $i > $i).
% 28.89/28.96  tff(decl_15657, type, fn_c4_photosynthesis_69: $i > $i).
% 28.89/28.96  tff(decl_15658, type, fn_c4_photosynthesis_70: $i > $i).
% 28.89/28.96  tff(decl_15659, type, fn_c4_photosynthesis_71: $i > $i).
% 28.89/28.96  tff(decl_15660, type, fn_c4_photosynthesis_72: $i > $i).
% 28.89/28.96  tff(decl_15661, type, fn_c4_photosynthesis_73: $i > $i).
% 28.89/28.96  tff(decl_15662, type, fn_c4_photosynthesis_74: $i > $i).
% 28.89/28.96  tff(decl_15663, type, fn_c4_photosynthesis_75: $i > $i).
% 28.89/28.96  tff(decl_15664, type, fn_c4_photosynthesis_76: $i > $i).
% 28.89/28.96  tff(decl_15665, type, fn_c4_photosynthesis_77: $i > $i).
% 28.89/28.96  tff(decl_15666, type, fn_c4_photosynthesis_78: $i > $i).
% 28.89/28.96  tff(decl_15667, type, central_vacuole_1: $i > $o).
% 28.89/28.96  tff(decl_15668, type, fn_c4_photosynthesis_79: $i > $i).
% 28.89/28.96  tff(decl_15669, type, fn_c4_photosynthesis_80: $i > $i).
% 28.89/28.96  tff(decl_15670, type, fn_c4_photosynthesis_81: $i > $i).
% 28.89/28.96  tff(decl_15671, type, fn_c4_photosynthesis_82: $i > $i).
% 28.89/28.96  tff(decl_15672, type, fn_c4_photosynthesis_83: $i > $i).
% 28.89/28.96  tff(decl_15673, type, fn_c4_photosynthesis_84: $i > $i).
% 28.89/28.96  tff(decl_15674, type, fn_c4_photosynthesis_85: $i > $i).
% 28.89/28.96  tff(decl_15675, type, fn_c4_photosynthesis_86: $i > $i).
% 28.89/28.96  tff(decl_15676, type, mesophyll_1: $i > $o).
% 28.89/28.96  tff(decl_15677, type, palisade_mesophyll_1: $i > $o).
% 28.89/28.96  tff(decl_15678, type, fn_c4_photosynthesis_87: $i > $i).
% 28.89/28.96  tff(decl_15679, type, layer_1: $i > $o).
% 28.89/28.96  tff(decl_15680, type, fn_c4_photosynthesis_88: $i > $i).
% 28.89/28.96  tff(decl_15681, type, fn_c4_photosynthesis_89: $i > $i).
% 28.89/28.96  tff(decl_15682, type, fn_c4_photosynthesis_90: $i > $i).
% 28.89/28.96  tff(decl_15683, type, fn_c4_photosynthesis_91: $i > $i).
% 28.89/28.96  tff(decl_15684, type, fn_c4_photosynthesis_92: $i > $i).
% 28.89/28.96  tff(decl_15685, type, fn_c4_photosynthesis_94: $i > $i).
% 28.89/28.96  tff(decl_15686, type, fn_c4_photosynthesis_95: $i > $i).
% 28.89/28.96  tff(decl_15687, type, triose_1: $i > $o).
% 28.89/28.96  tff(decl_15688, type, fn_c4_photosynthesis_96: $i > $i).
% 28.89/28.96  tff(decl_15689, type, fn_c4_photosynthesis_97: $i > $i).
% 28.89/28.96  tff(decl_15690, type, fn_c4_photosynthesis_98: $i > $i).
% 28.89/28.96  tff(decl_15691, type, fn_c4_photosynthesis_101: $i > $i).
% 28.89/28.96  tff(decl_15692, type, fn_c4_photosynthesis_102: $i > $i).
% 28.89/28.96  tff(decl_15693, type, fn_c4_photosynthesis_103: $i > $i).
% 28.89/28.96  tff(decl_15694, type, fn_c4_photosynthesis_104: $i > $i).
% 28.89/28.96  tff(decl_15695, type, fn_c4_photosynthesis_105: $i > $i).
% 28.89/28.96  tff(decl_15696, type, fn_c4_photosynthesis_106: $i > $i).
% 28.89/28.96  tff(decl_15697, type, fn_c4_photosynthesis_107: $i > $i).
% 28.89/28.96  tff(decl_15698, type, fn_c4_photosynthesis_108: $i > $i).
% 28.89/28.96  tff(decl_15699, type, fn_c4_photosynthesis_109: $i > $i).
% 28.89/28.96  tff(decl_15700, type, fn_c4_photosynthesis_110: $i > $i).
% 28.89/28.96  tff(decl_15701, type, fn_c4_photosynthesis_113: $i > $i).
% 28.89/28.96  tff(decl_15702, type, fn_c4_photosynthesis_114: $i > $i).
% 28.89/28.96  tff(decl_15703, type, fn_c4_photosynthesis_115: $i > $i).
% 28.89/28.96  tff(decl_15704, type, fn_c4_photosynthesis_116: $i > $i).
% 28.89/28.96  tff(decl_15705, type, fn_c4_photosynthesis_117: $i > $i).
% 28.89/28.96  tff(decl_15706, type, fn_c4_photosynthesis_118: $i > $i).
% 28.89/28.96  tff(decl_15707, type, fn_c4_photosynthesis_119: $i > $i).
% 28.89/28.96  tff(decl_15708, type, fn_c4_photosynthesis_120: $i > $i).
% 28.89/28.96  tff(decl_15709, type, fn_c4_photosynthesis_121: $i > $i).
% 28.89/28.96  tff(decl_15710, type, fn_c4_photosynthesis_122: $i > $i).
% 28.89/28.96  tff(decl_15711, type, fn_c4_photosynthesis_123: $i > $i).
% 28.89/28.96  tff(decl_15712, type, fn_c4_photosynthesis_124: $i > $i).
% 28.89/28.96  tff(decl_15713, type, fn_c4_photosynthesis_125: $i > $i).
% 28.89/28.96  tff(decl_15714, type, fn_c4_photosynthesis_126: $i > $i).
% 28.89/28.96  tff(decl_15715, type, fn_c4_photosynthesis_127: $i > $i).
% 28.89/28.96  tff(decl_15716, type, fn_c4_photosynthesis_128: $i > $i).
% 28.89/28.96  tff(decl_15717, type, fn_c4_photosynthesis_129: $i > $i).
% 28.89/28.96  tff(decl_15718, type, fn_c4_photosynthesis_130: $i > $i).
% 28.89/28.96  tff(decl_15719, type, fn_c4_photosynthesis_131: $i > $i).
% 28.89/28.96  tff(decl_15720, type, fn_c4_photosynthesis_132: $i > $i).
% 28.89/28.96  tff(decl_15721, type, fn_c4_photosynthesis_133: $i > $i).
% 28.89/28.96  tff(decl_15722, type, fn_c4_photosynthesis_134: $i > $i).
% 28.89/28.96  tff(decl_15723, type, fn_c4_photosynthesis_135: $i > $i).
% 28.89/28.96  tff(decl_15724, type, fn_c4_photosynthesis_136: $i > $i).
% 28.89/28.96  tff(decl_15725, type, fn_c4_photosynthesis_137: $i > $i).
% 28.89/28.96  tff(decl_15726, type, fn_c4_photosynthesis_138: $i > $i).
% 28.89/28.96  tff(decl_15727, type, fn_c4_photosynthesis_146: $i > $i).
% 28.89/28.96  tff(decl_15728, type, fn_c4_photosynthesis_147: $i > $i).
% 28.89/28.96  tff(decl_15729, type, fn_c4_photosynthesis_148: $i > $i).
% 28.89/28.96  tff(decl_15730, type, fn_c4_photosynthesis_149: $i > $i).
% 28.89/28.96  tff(decl_15731, type, fn_c4_photosynthesis_150: $i > $i).
% 28.89/28.96  tff(decl_15732, type, fn_c4_photosynthesis_151: $i > $i).
% 28.89/28.96  tff(decl_15733, type, c4_plant_1: $i > $o).
% 28.89/28.96  tff(decl_15734, type, fn_c4_photosynthesis_152: $i > $i).
% 28.89/28.96  tff(decl_15735, type, fn_c4_photosynthesis_153: $i > $i).
% 28.89/28.96  tff(decl_15736, type, fn_c4_photosynthesis_154: $i > $i).
% 28.89/28.96  tff(decl_15737, type, fn_c4_photosynthesis_155: $i > $i).
% 28.89/28.96  tff(decl_15738, type, fn_c4_photosynthesis_156: $i > $i).
% 28.89/28.96  tff(decl_15739, type, fn_c4_photosynthesis_157: $i > $i).
% 28.89/28.96  tff(decl_15740, type, fn_c4_photosynthesis_158: $i > $i).
% 28.89/28.96  tff(decl_15741, type, granum_1: $i > $o).
% 28.89/28.96  tff(decl_15742, type, fn_c4_photosynthesis_159: $i > $i).
% 28.89/28.96  tff(decl_15743, type, fn_c4_photosynthesis_160: $i > $i).
% 28.89/28.96  tff(decl_15744, type, chloroplast_membrane_1: $i > $o).
% 28.89/28.96  tff(decl_15745, type, fn_c4_photosynthesis_161: $i > $i).
% 28.89/28.96  tff(decl_15746, type, fn_c4_photosynthesis_162: $i > $i).
% 28.89/28.96  tff(decl_15747, type, fn_c4_photosynthesis_163: $i > $i).
% 28.89/28.96  tff(decl_15748, type, fn_c4_photosynthesis_164: $i > $i).
% 28.89/28.96  tff(decl_15749, type, fn_c4_photosynthesis_165: $i > $i).
% 28.89/28.96  tff(decl_15750, type, fn_c4_photosynthesis_166: $i > $i).
% 28.89/28.96  tff(decl_15751, type, fn_c4_photosynthesis_167: $i > $i).
% 28.89/28.96  tff(decl_15752, type, fn_c4_photosynthesis_168: $i > $i).
% 28.89/28.96  tff(decl_15753, type, fn_c4_photosynthesis_169: $i > $i).
% 28.89/28.96  tff(decl_15754, type, fn_c4_photosynthesis_170: $i > $i).
% 28.89/28.96  tff(decl_15755, type, fn_c4_photosynthesis_171: $i > $i).
% 28.89/28.96  tff(decl_15756, type, fn_c4_photosynthesis_172: $i > $i).
% 28.89/28.96  tff(decl_15757, type, fn_c4_photosynthesis_173: $i > $i).
% 28.89/28.96  tff(decl_15758, type, fn_c4_photosynthesis_174: $i > $i).
% 28.89/28.96  tff(decl_15759, type, fn_c4_photosynthesis_175: $i > $i).
% 28.89/28.96  tff(decl_15760, type, fn_c4_photosynthesis_176: $i > $i).
% 28.89/28.96  tff(decl_15761, type, fn_c4_photosynthesis_177: $i > $i).
% 28.89/28.96  tff(decl_15762, type, fn_c4_photosynthesis_178: $i > $i).
% 28.89/28.96  tff(decl_15763, type, fn_c4_photosynthesis_179: $i > $i).
% 28.89/28.96  tff(decl_15764, type, fn_c4_photosynthesis_180: $i > $i).
% 28.89/28.96  tff(decl_15765, type, fn_c4_photosynthesis_181: $i > $i).
% 28.89/28.96  tff(decl_15766, type, fn_c4_photosynthesis_182: $i > $i).
% 28.89/28.96  tff(decl_15767, type, fn_c4_photosynthesis_183: $i > $i).
% 28.89/28.96  tff(decl_15768, type, fn_c4_photosynthesis_184: $i > $i).
% 28.89/28.96  tff(decl_15769, type, fn_c4_photosynthesis_185: $i > $i).
% 28.89/28.96  tff(decl_15770, type, fn_c4_photosynthesis_186: $i > $i).
% 28.89/28.96  tff(decl_15771, type, fn_c4_photosynthesis_187: $i > $i).
% 28.89/28.96  tff(decl_15772, type, fn_c4_photosynthesis_188: $i > $i).
% 28.89/28.96  tff(decl_15773, type, fn_c4_photosynthesis_189: $i > $i).
% 28.89/28.96  tff(decl_15774, type, fn_c4_photosynthesis_190: $i > $i).
% 28.89/28.96  tff(decl_15775, type, fn_c4_photosynthesis_191: $i > $i).
% 28.89/28.96  tff(decl_15776, type, fn_c4_photosynthesis_192: $i > $i).
% 28.89/28.96  tff(decl_15777, type, fn_c4_photosynthesis_193: $i > $i).
% 28.89/28.96  tff(decl_15778, type, fn_c4_photosynthesis_194: $i > $i).
% 28.89/28.96  tff(decl_15779, type, fn_c4_photosynthesis_195: $i > $i).
% 28.89/28.96  tff(decl_15780, type, oxidative_phosphorylation_1: $i > $o).
% 28.89/28.96  tff(decl_15781, type, fn_c4_photosynthesis_196: $i > $i).
% 28.89/28.96  tff(decl_15782, type, fn_c4_photosynthesis_197: $i > $i).
% 28.89/28.96  tff(decl_15783, type, fn_c4_photosynthesis_198: $i > $i).
% 28.89/28.96  tff(decl_15784, type, fn_c4_photosynthesis_199: $i > $i).
% 28.89/28.96  tff(decl_15785, type, fn_c4_photosynthesis_200: $i > $i).
% 28.89/28.96  tff(decl_15786, type, fn_c4_photosynthesis_201: $i > $i).
% 28.89/28.96  tff(decl_15787, type, fn_c4_photosynthesis_202: $i > $i).
% 28.89/28.96  tff(decl_15788, type, fn_c4_photosynthesis_203: $i > $i).
% 28.89/28.96  tff(decl_15789, type, fn_c4_photosynthesis_204: $i > $i).
% 28.89/28.96  tff(decl_15790, type, fn_c4_photosynthesis_205: $i > $i).
% 28.89/28.96  tff(decl_15791, type, fn_c4_photosynthesis_206: $i > $i).
% 28.89/28.96  tff(decl_15792, type, fn_c4_photosynthesis_207: $i > $i).
% 28.89/28.96  tff(decl_15793, type, fn_c4_photosynthesis_208: $i > $i).
% 28.89/28.96  tff(decl_15794, type, fn_c4_photosynthesis_209: $i > $i).
% 28.89/28.96  tff(decl_15795, type, fn_c4_photosynthesis_210: $i > $i).
% 28.89/28.96  tff(decl_15796, type, fn_c4_photosynthesis_211: $i > $i).
% 28.89/28.96  tff(decl_15797, type, fn_c4_photosynthesis_212: $i > $i).
% 28.89/28.96  tff(decl_15798, type, fn_c4_photosynthesis_213: $i > $i).
% 28.89/28.96  tff(decl_15799, type, fn_c4_photosynthesis_214: $i > $i).
% 28.89/28.96  tff(decl_15800, type, fn_c4_photosynthesis_215: $i > $i).
% 28.89/28.96  tff(decl_15801, type, fn_c4_photosynthesis_216: $i > $i).
% 28.89/28.96  tff(decl_15802, type, fn_c4_photosynthesis_217: $i > $i).
% 28.89/28.96  tff(decl_15803, type, fn_c4_photosynthesis_218: $i > $i).
% 28.89/28.96  tff(decl_15804, type, fn_c4_photosynthesis_219: $i > $i).
% 28.89/28.96  tff(decl_15805, type, fn_c4_photosynthesis_220: $i > $i).
% 28.89/28.96  tff(decl_15806, type, fn_c4_photosynthesis_221: $i > $i).
% 28.89/28.96  tff(decl_15807, type, fn_c4_photosynthesis_222: $i > $i).
% 28.89/28.96  tff(decl_15808, type, fn_c4_photosynthesis_223: $i > $i).
% 28.89/28.96  tff(decl_15809, type, fn_c4_photosynthesis_224: $i > $i).
% 28.89/28.96  tff(decl_15810, type, fn_c4_photosynthesis_225: $i > $i).
% 28.89/28.96  tff(decl_15811, type, fn_partial_closing_of_stoma_1: $i > $i).
% 28.89/28.96  tff(decl_15812, type, fn_partial_closing_of_stoma_9: $i > $i).
% 28.89/28.96  tff(decl_15813, type, fn_semiautonomous_organelle_8: $i > $i).
% 28.89/28.96  tff(decl_15814, type, fn_eukaryotic_calvin_cycle_40: $i > $i).
% 28.89/28.96  tff(decl_15815, type, fn_chloroplast_94: $i > $i).
% 28.89/28.96  tff(decl_15816, type, fn_chloroplast_95: $i > $i).
% 28.89/28.96  tff(decl_15817, type, fn_chloroplast_20: $i > $i).
% 28.89/28.96  tff(decl_15818, type, fn_chloroplast_19: $i > $i).
% 28.89/28.96  tff(decl_15819, type, fn_pep_carboxylase_53: $i > $i).
% 28.89/28.96  tff(decl_15820, type, fn_pep_carboxylase_39: $i > $i).
% 28.89/28.96  tff(decl_15821, type, fn_reduction_in_calvin_cycle_1: $i > $i).
% 28.89/28.96  tff(decl_15822, type, fn_reduction_in_calvin_cycle_2: $i > $i).
% 28.89/28.96  tff(decl_15823, type, fn_reduction_in_calvin_cycle_6: $i > $i).
% 28.89/28.96  tff(decl_15824, type, fn_light_reaction_4: $i > $i).
% 28.89/28.96  tff(decl_15825, type, fn_parenchyma_cell_32: $i > $i).
% 28.89/28.96  tff(decl_15826, type, fn_chloroplast_33: $i > $i).
% 28.89/28.96  tff(decl_15827, type, fn_chloroplast_80: $i > $i).
% 28.89/28.96  tff(decl_15828, type, fn_chloroplast_76: $i > $i).
% 28.89/28.96  tff(decl_15829, type, fn_chemiosmosis_34: $i > $i).
% 28.89/28.96  tff(decl_15830, type, fn_chemiosmosis_25: $i > $i).
% 28.89/28.96  tff(decl_15831, type, fn_chemiosmosis_36: $i > $i).
% 28.89/28.96  tff(decl_15832, type, fn_chemiosmosis_31: $i > $i).
% 28.89/28.96  tff(decl_15833, type, fn_chemiosmosis_24: $i > $i).
% 28.89/28.96  tff(decl_15834, type, fn_chemiosmosis_38: $i > $i).
% 28.89/28.96  tff(decl_15835, type, fn_chemiosmosis_45: $i > $i).
% 28.89/28.96  tff(decl_15836, type, fn_chemiosmosis_23: $i > $i).
% 28.89/28.96  tff(decl_15837, type, fn_chemiosmosis_46: $i > $i).
% 28.89/28.96  tff(decl_15838, type, fn_chemiosmosis_26: $i > $i).
% 28.89/28.96  tff(decl_15839, type, fn_chemiosmosis_35: $i > $i).
% 28.89/28.96  tff(decl_15840, type, fn_leaf_9: $i > $i).
% 28.89/28.96  tff(decl_15841, type, fn_leaf_5: $i > $i).
% 28.89/28.96  tff(decl_15842, type, fn_leaf_17: $i > $i).
% 28.89/28.96  tff(decl_15843, type, fn_leaf_6: $i > $i).
% 28.89/28.96  tff(decl_15844, type, fn_leaf_8: $i > $i).
% 28.89/28.96  tff(decl_15845, type, fn_parenchyma_cell_19: $i > $i).
% 28.89/28.96  tff(decl_15846, type, fn_parenchyma_cell_22: $i > $i).
% 28.89/28.96  tff(decl_15847, type, fn_parenchyma_cell_41: $i > $i).
% 28.89/28.96  tff(decl_15848, type, fn_parenchyma_cell_43: $i > $i).
% 28.89/28.96  tff(decl_15849, type, fn_parenchyma_cell_39: $i > $i).
% 28.89/28.96  tff(decl_15850, type, fn_parenchyma_cell_17: $i > $i).
% 28.89/28.96  tff(decl_15851, type, fn_parenchyma_cell_27: $i > $i).
% 28.89/28.96  tff(decl_15852, type, fn_parenchyma_cell_37: $i > $i).
% 28.89/28.96  tff(decl_15853, type, fn_parenchyma_cell_16: $i > $i).
% 28.89/28.96  tff(decl_15854, type, fn_parenchyma_cell_42: $i > $i).
% 28.89/28.96  tff(decl_15855, type, fn_parenchyma_cell_44: $i > $i).
% 28.89/28.96  tff(decl_15856, type, fn_parenchyma_cell_33: $i > $i).
% 28.89/28.96  tff(decl_15857, type, fn_parenchyma_cell_24: $i > $i).
% 28.89/28.96  tff(decl_15858, type, fn_parenchyma_cell_9: $i > $i).
% 28.89/28.96  tff(decl_15859, type, fn_parenchyma_cell_15: $i > $i).
% 28.89/28.96  tff(decl_15860, type, fn_parenchyma_cell_28: $i > $i).
% 28.89/28.96  tff(decl_15861, type, fn_parenchyma_cell_26: $i > $i).
% 28.89/28.96  tff(decl_15862, type, fn_parenchyma_cell_20: $i > $i).
% 28.89/28.96  tff(decl_15863, type, fn_parenchyma_cell_21: $i > $i).
% 28.89/28.96  tff(decl_15864, type, fn_transfer_of_malate_to_bundle_sheath_cell_4: $i > $i).
% 28.89/28.96  tff(decl_15865, type, fn_endergonic_reaction_4: $i > $i).
% 28.89/28.96  tff(decl_15866, type, fn_endergonic_reaction_5: $i > $i).
% 28.89/28.96  tff(decl_15867, type, fn_eukaryotic_calvin_cycle_63: $i > $i).
% 28.89/28.96  tff(decl_15868, type, fn_eukaryotic_calvin_cycle_15: $i > $i).
% 28.89/28.96  tff(decl_15869, type, fn_eukaryotic_calvin_cycle_10: $i > $i).
% 28.89/28.96  tff(decl_15870, type, fn_eukaryotic_calvin_cycle_69: $i > $i).
% 28.89/28.96  tff(decl_15871, type, fn_eukaryotic_calvin_cycle_48: $i > $i).
% 28.89/28.96  tff(decl_15872, type, fn_eukaryotic_calvin_cycle_62: $i > $i).
% 28.89/28.96  tff(decl_15873, type, fn_pep_carboxylase_41: $i > $i).
% 28.89/28.96  tff(decl_15874, type, fn_oxidoreductase_11: $i > $i).
% 28.89/28.96  tff(decl_15875, type, fn_pep_carboxylase_44: $i > $i).
% 28.89/28.96  tff(decl_15876, type, fn_eukaryotic_calvin_cycle_39: $i > $i).
% 28.89/28.96  tff(decl_15877, type, fn_vascular_plant_17: $i > $i).
% 28.89/28.96  tff(decl_15878, type, fn_eukaryotic_calvin_cycle_14: $i > $i).
% 28.89/28.96  tff(decl_15879, type, fn_pep_carboxylase_48: $i > $i).
% 28.89/28.96  tff(decl_15880, type, fn_three_phosphoglycerate_16: $i > $i).
% 28.89/28.96  tff(decl_15881, type, fn_vascular_plant_20: $i > $i).
% 28.89/28.96  tff(decl_15882, type, fn_eukaryotic_calvin_cycle_37: $i > $i).
% 28.89/28.96  tff(decl_15883, type, fn_plant_metabolic_cell_39: $i > $i).
% 28.89/28.96  tff(decl_15884, type, fn_parenchyma_cell_14: $i > $i).
% 28.89/28.96  tff(decl_15885, type, fn_plant_metabolic_cell_19: $i > $i).
% 28.89/28.96  tff(decl_15886, type, fn_parenchyma_cell_36: $i > $i).
% 28.89/28.96  tff(decl_15887, type, fn_transfer_of_malate_to_bundle_sheath_cell_1: $i > $i).
% 28.89/28.96  tff(decl_15888, type, fn_eukaryotic_calvin_cycle_43: $i > $i).
% 28.89/28.96  tff(decl_15889, type, fn_stroma_6: $i > $i).
% 28.89/28.96  tff(decl_15890, type, fn_chloroplast_74: $i > $i).
% 28.89/28.96  tff(decl_15891, type, fn_semiautonomous_organelle_6: $i > $i).
% 28.89/28.96  tff(decl_15892, type, fn_stroma_5: $i > $i).
% 28.89/28.96  tff(decl_15893, type, fn_chloroplast_55: $i > $i).
% 28.89/28.96  tff(decl_15894, type, fn_chloroplast_83: $i > $i).
% 28.89/28.96  tff(decl_15895, type, fn_stroma_1: $i > $i).
% 28.89/28.96  tff(decl_15896, type, fn_stroma_4: $i > $i).
% 28.89/28.96  tff(decl_15897, type, fn_chloroplast_30: $i > $i).
% 28.89/28.96  tff(decl_15898, type, fn_semiautonomous_organelle_7: $i > $i).
% 28.89/28.96  tff(decl_15899, type, fn_stroma_3: $i > $i).
% 28.89/28.96  tff(decl_15900, type, fn_stroma_7: $i > $i).
% 28.89/28.96  tff(decl_15901, type, fn_mesophyll_10: $i > $i).
% 28.89/28.96  tff(decl_15902, type, fn_mesophyll_5: $i > $i).
% 28.89/28.96  tff(decl_15903, type, fn_mesophyll_6: $i > $i).
% 28.89/28.96  tff(decl_15904, type, fn_leaf_44: $i > $i).
% 28.89/28.96  tff(decl_15905, type, fn_leaf_12: $i > $i).
% 28.89/28.96  tff(decl_15906, type, fn_plant_metabolic_cell_18: $i > $i).
% 28.89/28.96  tff(decl_15907, type, fn_plant_cell_58: $i > $i).
% 28.89/28.96  tff(decl_15908, type, fn_parenchyma_cell_38: $i > $i).
% 28.89/28.96  tff(decl_15909, type, fn_plant_metabolic_cell_21: $i > $i).
% 28.89/28.96  tff(decl_15910, type, fn_plant_cell_90: $i > $i).
% 28.89/28.96  tff(decl_15911, type, fn_parenchyma_cell_35: $i > $i).
% 28.89/28.96  tff(decl_15912, type, fn_plant_metabolic_cell_28: $i > $i).
% 28.89/28.96  tff(decl_15913, type, fn_parenchyma_cell_18: $i > $i).
% 28.89/28.96  tff(decl_15914, type, fn_plant_metabolic_cell_37: $i > $i).
% 28.89/28.96  tff(decl_15915, type, fn_parenchyma_cell_31: $i > $i).
% 28.89/28.96  tff(decl_15916, type, fn_plant_metabolic_cell_17: $i > $i).
% 28.89/28.96  tff(decl_15917, type, fn_parenchyma_cell_40: $i > $i).
% 28.89/28.96  tff(decl_15918, type, fn_plant_cell_95: $i > $i).
% 28.89/28.96  tff(decl_15919, type, fn_parenchyma_cell_12: $i > $i).
% 28.89/28.96  tff(decl_15920, type, fn_parenchyma_cell_13: $i > $i).
% 28.89/28.96  tff(decl_15921, type, fn_plant_metabolic_cell_22: $i > $i).
% 28.89/28.96  tff(decl_15922, type, fn_parenchyma_cell_34: $i > $i).
% 28.89/28.96  tff(decl_15923, type, fn_plant_metabolic_cell_35: $i > $i).
% 28.89/28.96  tff(decl_15924, type, fn_parenchyma_cell_25: $i > $i).
% 28.89/28.96  tff(decl_15925, type, fn_plant_cell_14: $i > $i).
% 28.89/28.96  tff(decl_15926, type, fn_plant_metabolic_cell_36: $i > $i).
% 28.89/28.96  tff(decl_15927, type, fn_parenchyma_cell_30: $i > $i).
% 28.89/28.96  tff(decl_15928, type, fn_plant_metabolic_cell_25: $i > $i).
% 28.89/28.96  tff(decl_15929, type, fn_parenchyma_cell_29: $i > $i).
% 28.89/28.96  tff(decl_15930, type, fn_parenchyma_cell_23: $i > $i).
% 28.89/28.96  tff(decl_15931, type, fn_transfer_of_malate_to_bundle_sheath_cell_2: $i > $i).
% 28.89/28.96  tff(decl_15932, type, fn_pep_carboxylase_42: $i > $i).
% 28.89/28.96  tff(decl_15933, type, fn_light_reaction_29: $i > $i).
% 28.89/28.96  tff(decl_15934, type, fn_chemiosmosis_37: $i > $i).
% 28.89/28.96  tff(decl_15935, type, fn_light_reaction_33: $i > $i).
% 28.89/28.96  tff(decl_15936, type, fn_chemiosmosis_41: $i > $i).
% 28.89/28.96  tff(decl_15937, type, fn_light_reaction_31: $i > $i).
% 28.89/28.96  tff(decl_15938, type, fn_chemiosmosis_39: $i > $i).
% 28.89/28.96  tff(decl_15939, type, fn_eukaryotic_calvin_cycle_65: $i > $i).
% 28.89/28.96  tff(decl_15940, type, fn_light_reaction_36: $i > $i).
% 28.89/28.96  tff(decl_15941, type, fn_triose_9: $i > $i).
% 28.89/28.96  tff(decl_15942, type, fn_triose_14: $i > $i).
% 28.89/28.96  tff(decl_15943, type, fn_chemiosmosis_44: $i > $i).
% 28.89/28.96  tff(decl_15944, type, fn_eukaryotic_calvin_cycle_67: $i > $i).
% 28.89/28.96  tff(decl_15945, type, fn_reverse_reaction_6: $i > $i).
% 28.89/28.96  tff(decl_15946, type, fn_reverse_reaction_5: $i > $i).
% 28.89/28.96  tff(decl_15947, type, fn_reduction_in_calvin_cycle_5: $i > $i).
% 28.89/28.96  tff(decl_15948, type, fn_light_reaction_48: $i > $i).
% 28.89/28.96  tff(decl_15949, type, fn_chemiosmosis_100: $i > $i).
% 28.89/28.96  tff(decl_15950, type, fn_pep_carboxylase_47: $i > $i).
% 28.89/28.96  tff(decl_15951, type, fn_c4_photosynthesis_100: $i > $i).
% 28.89/28.96  tff(decl_15952, type, fn_photosynthesis_60: $i > $i).
% 28.89/28.96  tff(decl_15953, type, fn_c4_photosynthesis_93: $i > $i).
% 28.89/28.96  tff(decl_15954, type, fn_photosynthesis_16: $i > $i).
% 28.89/28.96  tff(decl_15955, type, fn_photosynthesis_105: $i > $i).
% 28.89/28.96  tff(decl_15956, type, fn_photosynthesis_27: $i > $i).
% 28.89/28.96  tff(decl_15957, type, fn_c4_photosynthesis_144: $i > $i).
% 28.89/28.96  tff(decl_15958, type, fn_c4_photosynthesis_145: $i > $i).
% 28.89/28.96  tff(decl_15959, type, fn_c4_photosynthesis_99: $i > $i).
% 28.89/28.96  tff(decl_15960, type, fn_photosynthesis_104: $i > $i).
% 28.89/28.96  tff(decl_15961, type, fn_c4_photosynthesis_139: $i > $i).
% 28.89/28.96  tff(decl_15962, type, fn_photosynthesis_103: $i > $i).
% 28.89/28.96  tff(decl_15963, type, fn_photosynthesis_17: $i > $i).
% 28.89/28.96  tff(decl_15964, type, fn_photosynthesis_90: $i > $i).
% 28.89/28.96  tff(decl_15965, type, fn_c4_photosynthesis_228: $i > $i).
% 28.89/28.96  tff(decl_15966, type, fn_c4_photosynthesis_229: $i > $i).
% 28.89/28.96  tff(decl_15967, type, fn_photosynthesis_43: $i > $i).
% 28.89/28.96  tff(decl_15968, type, fn_c4_photosynthesis_140: $i > $i).
% 28.89/28.96  tff(decl_15969, type, fn_c4_photosynthesis_143: $i > $i).
% 28.89/28.96  tff(decl_15970, type, fn_c4_photosynthesis_142: $i > $i).
% 28.89/28.96  tff(decl_15971, type, fn_c4_photosynthesis_141: $i > $i).
% 28.89/28.96  tff(decl_15972, type, fn_c4_photosynthesis_226: $i > $i).
% 28.89/28.96  tff(decl_15973, type, fn_c4_photosynthesis_227: $i > $i).
% 28.89/28.96  tff(decl_15974, type, fn_c4_photosynthesis_112: $i > $i).
% 28.89/28.96  tff(decl_15975, type, fn_c4_photosynthesis_111: $i > $i).
% 28.89/28.96  tff(decl_15976, type, 'C4-Plant': $i).
% 28.89/28.96  tff(decl_15977, type, 'Any number of plant species which obtain atmospheric carbon using a four-carbon compound in a biochemical pathway that precedes the Calvin cycle.': $i).
% 28.89/28.96  tff(decl_15978, type, 'c4 plant': $i).
% 28.89/28.96  tff(decl_15979, type, 'c4-plant': $i).
% 28.89/28.96  tff(decl_15980, type, vascular_plant_1: $i > $o).
% 28.89/28.96  tff(decl_15981, type, fn_c4_plant_1: $i > $i).
% 28.89/28.96  tff(decl_15982, type, fn_c4_plant_5: $i > $i).
% 28.89/28.96  tff(decl_15983, type, fn_c4_plant_6: $i > $i).
% 28.89/28.96  tff(decl_15984, type, fn_c4_plant_7: $i > $i).
% 28.89/28.96  tff(decl_15985, type, fn_c4_plant_8: $i > $i).
% 28.89/28.96  tff(decl_15986, type, fn_c4_plant_9: $i > $i).
% 28.89/28.96  tff(decl_15987, type, fn_c4_plant_11: $i > $i).
% 28.89/28.96  tff(decl_15988, type, fn_c4_plant_12: $i > $i).
% 28.89/28.96  tff(decl_15989, type, fn_c4_plant_13: $i > $i).
% 28.89/28.96  tff(decl_15990, type, fn_c4_plant_14: $i > $i).
% 28.89/28.96  tff(decl_15991, type, fn_c4_plant_15: $i > $i).
% 28.89/28.96  tff(decl_15992, type, fn_c4_plant_16: $i > $i).
% 28.89/28.96  tff(decl_15993, type, fn_c4_plant_17: $i > $i).
% 28.89/28.96  tff(decl_15994, type, fn_c4_plant_18: $i > $i).
% 28.89/28.96  tff(decl_15995, type, fn_c4_plant_19: $i > $i).
% 28.89/28.96  tff(decl_15996, type, fn_c4_plant_20: $i > $i).
% 28.89/28.96  tff(decl_15997, type, fn_c4_plant_27: $i > $i).
% 28.89/28.96  tff(decl_15998, type, fn_c4_plant_28: $i > $i).
% 28.89/28.96  tff(decl_15999, type, fn_c4_plant_29: $i > $i).
% 28.89/28.96  tff(decl_16000, type, fn_c4_plant_30: $i > $i).
% 28.89/28.96  tff(decl_16001, type, fn_c4_plant_31: $i > $i).
% 28.89/28.96  tff(decl_16002, type, fn_c4_plant_32: $i > $i).
% 28.89/28.96  tff(decl_16003, type, fn_c4_plant_33: $i > $i).
% 28.89/28.96  tff(decl_16004, type, fn_c4_plant_34: $i > $i).
% 28.89/28.96  tff(decl_16005, type, fn_c4_plant_35: $i > $i).
% 28.89/28.96  tff(decl_16006, type, fn_c4_plant_36: $i > $i).
% 28.89/28.96  tff(decl_16007, type, fn_c4_plant_37: $i > $i).
% 28.89/28.96  tff(decl_16008, type, fn_c4_plant_40: $i > $i).
% 28.89/28.96  tff(decl_16009, type, fn_c4_plant_41: $i > $i).
% 28.89/28.96  tff(decl_16010, type, fn_c4_plant_42: $i > $i).
% 28.89/28.96  tff(decl_16011, type, fn_c4_plant_43: $i > $i).
% 28.89/28.96  tff(decl_16012, type, stem_1: $i > $o).
% 28.89/28.96  tff(decl_16013, type, fn_c4_plant_44: $i > $i).
% 28.89/28.96  tff(decl_16014, type, root_system_1: $i > $o).
% 28.89/28.96  tff(decl_16015, type, fn_c4_plant_45: $i > $i).
% 28.89/28.96  tff(decl_16016, type, fn_c4_plant_46: $i > $i).
% 28.89/28.96  tff(decl_16017, type, fn_c4_plant_47: $i > $i).
% 28.89/28.96  tff(decl_16018, type, fn_c4_plant_48: $i > $i).
% 28.89/28.96  tff(decl_16019, type, exocytosis_1: $i > $o).
% 28.89/28.96  tff(decl_16020, type, fn_c4_plant_49: $i > $i).
% 28.89/28.96  tff(decl_16021, type, fn_c4_plant_50: $i > $i).
% 28.89/28.96  tff(decl_16022, type, fn_c4_plant_51: $i > $i).
% 28.89/28.96  tff(decl_16023, type, fn_c4_plant_52: $i > $i).
% 28.89/28.96  tff(decl_16024, type, fn_c4_plant_53: $i > $i).
% 28.89/28.96  tff(decl_16025, type, fn_c4_plant_54: $i > $i).
% 28.89/28.96  tff(decl_16026, type, fn_c4_plant_55: $i > $i).
% 28.89/28.96  tff(decl_16027, type, fn_c4_plant_56: $i > $i).
% 28.89/28.96  tff(decl_16028, type, fn_c4_plant_57: $i > $i).
% 28.89/28.96  tff(decl_16029, type, fn_c4_plant_58: $i > $i).
% 28.89/28.96  tff(decl_16030, type, shoot_system_1: $i > $o).
% 28.89/28.96  tff(decl_16031, type, fn_c4_plant_59: $i > $i).
% 28.89/28.96  tff(decl_16032, type, fn_c4_plant_60: $i > $i).
% 28.89/28.96  tff(decl_16033, type, fn_c4_plant_61: $i > $i).
% 28.89/28.96  tff(decl_16034, type, fn_c4_plant_62: $i > $i).
% 28.89/28.96  tff(decl_16035, type, fn_c4_plant_63: $i > $i).
% 28.89/28.96  tff(decl_16036, type, fn_c4_plant_64: $i > $i).
% 28.89/28.96  tff(decl_16037, type, fn_c4_plant_65: $i > $i).
% 28.89/28.96  tff(decl_16038, type, vascular_tissue_system_1: $i > $o).
% 28.89/28.96  tff(decl_16039, type, fn_c4_plant_66: $i > $i).
% 28.89/28.96  tff(decl_16040, type, fn_c4_plant_67: $i > $i).
% 28.89/28.96  tff(decl_16041, type, fn_c4_plant_68: $i > $i).
% 28.89/28.96  tff(decl_16042, type, fn_c4_plant_69: $i > $i).
% 28.89/28.96  tff(decl_16043, type, fn_c4_plant_70: $i > $i).
% 28.89/28.96  tff(decl_16044, type, fn_c4_plant_71: $i > $i).
% 28.89/28.96  tff(decl_16045, type, fn_c4_plant_72: $i > $i).
% 28.89/28.96  tff(decl_16046, type, fn_c4_plant_73: $i > $i).
% 28.89/28.96  tff(decl_16047, type, waxy_cuticle_1: $i > $o).
% 28.89/28.96  tff(decl_16048, type, fn_c4_plant_74: $i > $i).
% 28.89/28.96  tff(decl_16049, type, spongy_mesophyll_1: $i > $o).
% 28.89/28.96  tff(decl_16050, type, fn_c4_plant_75: $i > $i).
% 28.89/28.96  tff(decl_16051, type, fn_c4_plant_76: $i > $i).
% 28.89/28.96  tff(decl_16052, type, fn_c4_plant_77: $i > $i).
% 28.89/28.96  tff(decl_16053, type, fn_c4_plant_78: $i > $i).
% 28.89/28.96  tff(decl_16054, type, fn_c4_plant_79: $i > $i).
% 28.89/28.96  tff(decl_16055, type, fn_c4_plant_80: $i > $i).
% 28.89/28.96  tff(decl_16056, type, fn_c4_plant_81: $i > $i).
% 28.89/28.96  tff(decl_16057, type, fn_c4_plant_82: $i > $i).
% 28.89/28.96  tff(decl_16058, type, fn_c4_plant_83: $i > $i).
% 28.89/28.96  tff(decl_16059, type, fn_c4_plant_84: $i > $i).
% 28.89/28.96  tff(decl_16060, type, fn_c4_plant_85: $i > $i).
% 28.89/28.96  tff(decl_16061, type, fn_c4_plant_86: $i > $i).
% 28.89/28.96  tff(decl_16062, type, fn_c4_plant_87: $i > $i).
% 28.89/28.96  tff(decl_16063, type, fn_c4_plant_88: $i > $i).
% 28.89/28.96  tff(decl_16064, type, fn_c4_plant_89: $i > $i).
% 28.89/28.96  tff(decl_16065, type, fn_c4_plant_90: $i > $i).
% 28.89/28.96  tff(decl_16066, type, fn_c4_plant_91: $i > $i).
% 28.89/28.96  tff(decl_16067, type, ion_channel_1: $i > $o).
% 28.89/28.96  tff(decl_16068, type, fn_c4_plant_92: $i > $i).
% 28.89/28.96  tff(decl_16069, type, fn_c4_plant_93: $i > $i).
% 28.89/28.96  tff(decl_16070, type, fn_c4_plant_94: $i > $i).
% 28.89/28.96  tff(decl_16071, type, fn_c4_plant_95: $i > $i).
% 28.89/28.96  tff(decl_16072, type, fn_c4_plant_96: $i > $i).
% 28.89/28.96  tff(decl_16073, type, fn_c4_plant_97: $i > $i).
% 28.89/28.96  tff(decl_16074, type, fn_c4_plant_98: $i > $i).
% 28.89/28.96  tff(decl_16075, type, fn_c4_plant_99: $i > $i).
% 28.89/28.96  tff(decl_16076, type, fn_c4_plant_100: $i > $i).
% 28.89/28.96  tff(decl_16077, type, fn_c4_plant_101: $i > $i).
% 28.89/28.96  tff(decl_16078, type, fn_c4_plant_102: $i > $i).
% 28.89/28.96  tff(decl_16079, type, fn_c4_plant_103: $i > $i).
% 28.89/28.96  tff(decl_16080, type, fn_c4_plant_104: $i > $i).
% 28.89/28.96  tff(decl_16081, type, fn_c4_plant_105: $i > $i).
% 28.89/28.96  tff(decl_16082, type, fn_c4_plant_106: $i > $i).
% 28.89/28.96  tff(decl_16083, type, pyruvate_oxidation_1: $i > $o).
% 28.89/28.96  tff(decl_16084, type, fn_microfibril_13: $i > $i).
% 28.89/28.96  tff(decl_16085, type, fn_stoma_10: $i > $i).
% 28.89/28.96  tff(decl_16086, type, fn_stoma_7: $i > $i).
% 28.89/28.96  tff(decl_16087, type, fn_stem_11: $i > $i).
% 28.89/28.96  tff(decl_16088, type, fn_pyruvate_oxidation_85: $i > $i).
% 28.89/28.96  tff(decl_16089, type, fn_plant_cell_68: $i > $i).
% 28.89/28.96  tff(decl_16090, type, fn_plant_cell_43: $i > $i).
% 28.89/28.96  tff(decl_16091, type, fn_plant_cell_44: $i > $i).
% 28.89/28.96  tff(decl_16092, type, fn_plant_cell_96: $i > $i).
% 28.89/28.96  tff(decl_16093, type, fn_plant_cell_98: $i > $i).
% 28.89/28.96  tff(decl_16094, type, fn_plant_cell_20: $i > $i).
% 28.89/28.96  tff(decl_16095, type, fn_plant_cell_65: $i > $i).
% 28.89/28.96  tff(decl_16096, type, fn_plant_cell_42: $i > $i).
% 28.89/28.96  tff(decl_16097, type, fn_plant_cell_99: $i > $i).
% 28.89/28.96  tff(decl_16098, type, fn_plant_cell_110: $i > $i).
% 28.89/28.96  tff(decl_16099, type, fn_plant_cell_67: $i > $i).
% 28.89/28.96  tff(decl_16100, type, fn_plant_cell_66: $i > $i).
% 28.89/28.96  tff(decl_16101, type, fn_plant_cell_64: $i > $i).
% 28.89/28.96  tff(decl_16102, type, fn_leaf_16: $i > $i).
% 28.89/28.96  tff(decl_16103, type, fn_leaf_14: $i > $i).
% 28.89/28.96  tff(decl_16104, type, fn_leaf_41: $i > $i).
% 28.89/28.96  tff(decl_16105, type, fn_leaf_45: $i > $i).
% 28.89/28.96  tff(decl_16106, type, fn_leaf_46: $i > $i).
% 28.89/28.96  tff(decl_16107, type, fn_leaf_7: $i > $i).
% 28.89/28.96  tff(decl_16108, type, fn_leaf_10: $i > $i).
% 28.89/28.96  tff(decl_16109, type, fn_leaf_48: $i > $i).
% 28.89/28.96  tff(decl_16110, type, fn_leaf_47: $i > $i).
% 28.89/28.96  tff(decl_16111, type, fn_leaf_35: $i > $i).
% 28.89/28.96  tff(decl_16112, type, fn_leaf_13: $i > $i).
% 28.89/28.96  tff(decl_16113, type, fn_eukaryotic_cellular_respiration_94: $i > $i).
% 28.89/28.96  tff(decl_16114, type, fn_eukaryotic_cellular_respiration_97: $i > $i).
% 28.89/28.96  tff(decl_16115, type, fn_exocytosis_35: $i > $i).
% 28.89/28.96  tff(decl_16116, type, fn_plant_cell_23: $i > $i).
% 28.89/28.96  tff(decl_16117, type, fn_microfibril_5: $i > $i).
% 28.89/28.96  tff(decl_16118, type, fn_microfibril_6: $i > $i).
% 28.89/28.96  tff(decl_16119, type, fn_exocytosis_26: $i > $i).
% 28.89/28.96  tff(decl_16120, type, fn_plant_cell_97: $i > $i).
% 28.89/28.96  tff(decl_16121, type, fn_leaf_51: $i > $i).
% 28.89/28.96  tff(decl_16122, type, fn_leaf_50: $i > $i).
% 28.89/28.96  tff(decl_16123, type, fn_stoma_5: $i > $i).
% 28.89/28.96  tff(decl_16124, type, fn_leaf_43: $i > $i).
% 28.89/28.96  tff(decl_16125, type, fn_stem_6: $i > $i).
% 28.89/28.96  tff(decl_16126, type, fn_plant_cell_59: $i > $i).
% 28.89/28.96  tff(decl_16127, type, fn_eukaryotic_cellular_respiration_101: $i > $i).
% 28.89/28.96  tff(decl_16128, type, fn_pyruvate_oxidation_84: $i > $i).
% 28.89/28.96  tff(decl_16129, type, fn_eukaryotic_cellular_respiration_42: $i > $i).
% 28.89/28.96  tff(decl_16130, type, fn_eukaryotic_cellular_respiration_111: $i > $i).
% 28.89/28.96  tff(decl_16131, type, fn_eukaryotic_cellular_respiration_62: $i > $i).
% 28.89/28.96  tff(decl_16132, type, fn_pyruvate_oxidation_7: $i > $i).
% 28.89/28.96  tff(decl_16133, type, fn_pyruvate_oxidation_3: $i > $i).
% 28.89/28.96  tff(decl_16134, type, fn_eukaryotic_cellular_respiration_68: $i > $i).
% 28.89/28.96  tff(decl_16135, type, region_0: $i).
% 28.89/28.96  tff(decl_16136, type, fn_c4_plant_26: $i > $i).
% 28.89/28.96  tff(decl_16137, type, fn_c4_plant_25: $i > $i).
% 28.89/28.96  tff(decl_16138, type, fn_plant_41: $i > $i).
% 28.89/28.96  tff(decl_16139, type, fn_c4_plant_24: $i > $i).
% 28.89/28.96  tff(decl_16140, type, fn_c4_plant_23: $i > $i).
% 28.89/28.96  tff(decl_16141, type, fn_c4_plant_22: $i > $i).
% 28.89/28.96  tff(decl_16142, type, fn_c4_plant_21: $i > $i).
% 28.89/28.96  tff(decl_16143, type, fn_plant_23: $i > $i).
% 28.89/28.96  tff(decl_16144, type, fn_plant_24: $i > $i).
% 28.89/28.96  tff(decl_16145, type, fn_plant_36: $i > $i).
% 28.89/28.96  tff(decl_16146, type, fn_plant_28: $i > $i).
% 28.89/28.96  tff(decl_16147, type, fn_plant_30: $i > $i).
% 28.89/28.96  tff(decl_16148, type, fn_plant_31: $i > $i).
% 28.89/28.96  tff(decl_16149, type, fn_plant_38: $i > $i).
% 28.89/28.96  tff(decl_16150, type, fn_c4_plant_39: $i > $i).
% 28.89/28.96  tff(decl_16151, type, fn_vascular_plant_22: $i > $i).
% 28.89/28.96  tff(decl_16152, type, fn_c4_plant_38: $i > $i).
% 28.89/28.96  tff(decl_16153, type, fn_vascular_plant_21: $i > $i).
% 28.89/28.96  tff(decl_16154, type, fn_vascular_plant_24: $i > $i).
% 28.89/28.96  tff(decl_16155, type, fn_vascular_plant_23: $i > $i).
% 28.89/28.96  tff(decl_16156, type, fn_vascular_plant_25: $i > $i).
% 28.89/28.96  tff(decl_16157, type, fn_vascular_plant_13: $i > $i).
% 28.89/28.96  tff(decl_16158, type, fn_vascular_plant_14: $i > $i).
% 28.89/28.96  tff(decl_16159, type, fn_vascular_plant_12: $i > $i).
% 28.89/28.96  tff(decl_16160, type, fn_vascular_plant_19: $i > $i).
% 28.89/28.96  tff(decl_16161, type, fn_vascular_plant_18: $i > $i).
% 28.89/28.96  tff(decl_16162, type, fn_vascular_plant_26: $i > $i).
% 28.89/28.96  tff(decl_16163, type, fn_vascular_plant_15: $i > $i).
% 28.89/28.96  tff(decl_16164, type, fn_vascular_plant_9: $i > $i).
% 28.89/28.96  tff(decl_16165, type, fn_vascular_plant_16: $i > $i).
% 28.89/28.96  tff(decl_16166, type, c7h5o2_minus_1: $i > $o).
% 28.89/28.96  tff(decl_16167, type, 'C7H5O2-Minus': $i).
% 28.89/28.96  tff(decl_16168, type, 'c7h5o2 minus': $i).
% 28.89/28.96  tff(decl_16169, type, 'c7h5o2-minus': $i).
% 28.89/28.96  tff(decl_16170, type, fn_c7h5o2_minus_1: $i > $i).
% 28.89/28.96  tff(decl_16171, type, fn_c7h5o2_minus_2: $i > $i).
% 28.89/28.96  tff(decl_16172, type, cabbage_plant_1: $i > $o).
% 28.89/28.96  tff(decl_16173, type, 'Cabbage-Plant': $i).
% 28.89/28.96  tff(decl_16174, type, 'Member of the Brassica plant family which produces heads of cabbage. Grown as an important food crop.': $i).
% 28.89/28.96  tff(decl_16175, type, 'plant of cabbage': $i).
% 28.89/28.96  tff(decl_16176, type, 'cabbage plant': $i).
% 28.89/28.96  tff(decl_16177, type, 'cabbage-plant': $i).
% 28.89/28.96  tff(decl_16178, type, cabinet_1: $i > $o).
% 28.89/28.96  tff(decl_16179, type, 'Cabinet': $i).
% 28.89/28.96  tff(decl_16180, type, cabinet: $i).
% 28.89/28.96  tff(decl_16181, type, furniture_1: $i > $o).
% 28.89/28.96  tff(decl_16182, type, shelf_1: $i > $o).
% 28.89/28.96  tff(decl_16183, type, drawer_1: $i > $o).
% 28.89/28.96  tff(decl_16184, type, cacti_spine_1: $i > $o).
% 28.89/28.96  tff(decl_16185, type, 'Cacti-Spine': $i).
% 28.89/28.96  tff(decl_16186, type, 'A modified leaf in cacti that creates a hard structure with a sharp, pointy end, which is generally used  to protect  against herbivores.': $i).
% 28.89/28.96  tff(decl_16187, type, needle: $i).
% 28.89/28.96  tff(decl_16188, type, spine: $i).
% 28.89/28.96  tff(decl_16189, type, 'cactus spine': $i).
% 28.89/28.96  tff(decl_16190, type, 'spine of cactus': $i).
% 28.89/28.96  tff(decl_16191, type, 'cacti spine': $i).
% 28.89/28.96  tff(decl_16192, type, 'cacti-spine': $i).
% 28.89/28.96  tff(decl_16193, type, plant_appendage_1: $i > $o).
% 28.89/28.96  tff(decl_16194, type, cactus_1: $i > $o).
% 28.89/28.96  tff(decl_16195, type, 'Cactus': $i).
% 28.89/28.96  tff(decl_16196, type, 'Cacti are succulent plants that live in dry areas.': $i).
% 28.89/28.96  tff(decl_16197, type, cacti: $i).
% 28.89/28.96  tff(decl_16198, type, cactus: $i).
% 28.89/28.96  tff(decl_16199, type, succulent_plant_1: $i > $o).
% 28.89/28.96  tff(decl_16200, type, pineapple_plant_1: $i > $o).
% 28.89/28.96  tff(decl_16201, type, fn_cactus_2: $i > $i).
% 28.89/28.96  tff(decl_16202, type, fn_cactus_5: $i > $i).
% 28.89/28.96  tff(decl_16203, type, fn_cactus_6: $i > $i).
% 28.89/28.96  tff(decl_16204, type, fn_cactus_7: $i > $i).
% 28.89/28.96  tff(decl_16205, type, fn_cactus_8: $i > $i).
% 28.89/28.96  tff(decl_16206, type, fn_cactus_9: $i > $i).
% 28.89/28.96  tff(decl_16207, type, fn_cactus_4: $i > $i).
% 28.89/28.96  tff(decl_16208, type, fn_succulent_plant_62: $i > $i).
% 28.89/28.96  tff(decl_16209, type, fn_cactus_3: $i > $i).
% 28.89/28.96  tff(decl_16210, type, fn_succulent_plant_63: $i > $i).
% 28.89/28.96  tff(decl_16211, type, fn_succulent_plant_60: $i > $i).
% 28.89/28.96  tff(decl_16212, type, fn_succulent_plant_59: $i > $i).
% 28.89/28.96  tff(decl_16213, type, fn_succulent_plant_61: $i > $i).
% 28.89/28.96  tff(decl_16214, type, 'Caddisfly': $i).
% 28.89/28.96  tff(decl_16215, type, 'Member of the insect order Trichoptera. Caddisflies have aquatic larvae.': $i).
% 28.89/28.96  tff(decl_16216, type, caddisfly: $i).
% 28.89/28.96  tff(decl_16217, type, trichoptera_1: $i > $o).
% 28.89/28.96  tff(decl_16218, type, cadherin_1: $i > $o).
% 28.89/28.96  tff(decl_16219, type, 'Cadherin': $i).
% 28.89/28.96  tff(decl_16220, type, 'A member of an important class of cell adhesion molecules that requires extracellular calcium ions for its function.': $i).
% 28.89/28.96  tff(decl_16221, type, cadherin: $i).
% 28.89/28.96  tff(decl_16222, type, cadmium_1: $i > $o).
% 28.89/28.96  tff(decl_16223, type, 'Cadmium': $i).
% 28.89/28.96  tff(decl_16224, type, 'Cadmium is a metal atom with atomic number 48. It is represented by the symbol Cd.': $i).
% 28.89/28.96  tff(decl_16225, type, cadmium: $i).
% 28.89/28.96  tff(decl_16226, type, 'Cd': $i).
% 28.89/28.96  tff(decl_16227, type, fn_cadmium_3: $i > $i).
% 28.89/28.96  tff(decl_16228, type, fn_cadmium_4: $i > $i).
% 28.89/28.96  tff(decl_16229, type, fn_cadmium_5: $i > $i).
% 28.89/28.96  tff(decl_16230, type, fn_cadmium_9: $i > $i).
% 28.89/28.96  tff(decl_16231, type, fn_cadmium_10: $i > $i).
% 28.89/28.96  tff(decl_16232, type, fn_cadmium_11: $i > $i).
% 28.89/28.96  tff(decl_16233, type, fn_cadmium_12: $i > $i).
% 28.89/28.96  tff(decl_16234, type, "64": $i).
% 28.89/28.96  tff(decl_16235, type, "48": $i).
% 28.89/28.96  tff(decl_16236, type, "1.69": $i).
% 28.89/28.96  tff(decl_16237, type, "112": $i).
% 28.89/28.96  tff(decl_16238, type, "112.4": $i).
% 28.89/28.96  tff(decl_16239, type, fn_cadmium_7: $i > $i).
% 28.89/28.96  tff(decl_16240, type, fn_cadmium_8: $i > $i).
% 28.89/28.96  tff(decl_16241, type, fn_cadmium_6: $i > $i).
% 28.89/28.96  tff(decl_16242, type, 'Caenorhabditis-Elegans': $i).
% 28.89/28.96  tff(decl_16243, type, 'A free-living, transparent nematode about 1 mm in length, which lives in temperate soil environments.  Used a model organism.': $i).
% 28.89/28.96  tff(decl_16244, type, 'c. elegans': $i).
% 28.89/28.96  tff(decl_16245, type, 'c elegans': $i).
% 28.89/28.96  tff(decl_16246, type, 'c-elegans': $i).
% 28.89/28.96  tff(decl_16247, type, 'caenorhabditis elegan': $i).
% 28.89/28.96  tff(decl_16248, type, 'caenorhabditis-elegan': $i).
% 28.89/28.96  tff(decl_16249, type, fn_caenorhabditis_elegans_2: $i > $i).
% 28.89/28.96  tff(decl_16250, type, fn_caenorhabditis_elegans_3: $i > $i).
% 28.89/28.96  tff(decl_16251, type, vulva_1: $i > $o).
% 28.89/28.96  tff(decl_16252, type, fn_caenorhabditis_elegans_4: $i > $i).
% 28.89/28.96  tff(decl_16253, type, fn_caenorhabditis_elegans_5: $i > $i).
% 28.89/28.96  tff(decl_16254, type, petri_dish_1: $i > $o).
% 28.89/28.96  tff(decl_16255, type, fn_caenorhabditis_elegans_6: $i > $i).
% 28.89/28.96  tff(decl_16256, type, fn_caenorhabditis_elegans_7: $i > $i).
% 28.89/28.96  tff(decl_16257, type, fn_caenorhabditis_elegans_8: $i > $i).
% 28.89/28.96  tff(decl_16258, type, fn_caenorhabditis_elegans_11: $i > $i).
% 28.89/28.96  tff(decl_16259, type, fn_caenorhabditis_elegans_12: $i > $i).
% 28.89/28.96  tff(decl_16260, type, fn_caenorhabditis_elegans_13: $i > $i).
% 28.89/28.96  tff(decl_16261, type, fn_caenorhabditis_elegans_14: $i > $i).
% 28.89/28.96  tff(decl_16262, type, fn_caenorhabditis_elegans_15: $i > $i).
% 28.89/28.96  tff(decl_16263, type, fn_caenorhabditis_elegans_16: $i > $i).
% 28.89/28.96  tff(decl_16264, type, fn_caenorhabditis_elegans_17: $i > $i).
% 28.89/28.96  tff(decl_16265, type, fn_scientist_1: $i > $i).
% 28.89/28.96  tff(decl_16266, type, "959": $i).
% 28.89/28.96  tff(decl_16267, type, cell_0: $i).
% 28.89/28.96  tff(decl_16268, type, nematode_0: $i).
% 28.89/28.96  tff(decl_16269, type, fn_caenorhabditis_elegans_10: $i > $i).
% 28.89/28.96  tff(decl_16270, type, fn_caenorhabditis_elegans_9: $i > $i).
% 28.89/28.96  tff(decl_16271, type, caenorhabditis_elegans_development_1: $i > $o).
% 28.89/28.96  tff(decl_16272, type, 'Caenorhabditis-Elegans-Development': $i).
% 28.89/28.96  tff(decl_16273, type, 'The macrophysiological process that involves the development of Caenorhabditis elegans.': $i).
% 28.89/28.96  tff(decl_16274, type, 'c elegans development': $i).
% 28.89/28.96  tff(decl_16275, type, 'caenorhabditis elegans development': $i).
% 28.89/28.96  tff(decl_16276, type, 'caenorhabditis-elegans-development': $i).
% 28.89/28.96  tff(decl_16277, type, fn_caenorhabditis_elegans_development_1: $i > $i).
% 28.89/28.96  tff(decl_16278, type, fn_caenorhabditis_elegans_development_2: $i > $i).
% 28.89/28.96  tff(decl_16279, type, fn_caenorhabditis_elegans_development_3: $i > $i).
% 28.89/28.96  tff(decl_16280, type, fn_caenorhabditis_elegans_development_4: $i > $i).
% 28.89/28.96  tff(decl_16281, type, fn_caenorhabditis_elegans_development_5: $i > $i).
% 28.89/28.96  tff(decl_16282, type, fn_caenorhabditis_elegans_development_6: $i > $i).
% 28.89/28.96  tff(decl_16283, type, fn_caenorhabditis_elegans_development_7: $i > $i).
% 28.89/28.96  tff(decl_16284, type, fn_caenorhabditis_elegans_development_8: $i > $i).
% 28.89/28.96  tff(decl_16285, type, fn_caenorhabditis_elegans_development_9: $i > $i).
% 28.89/28.96  tff(decl_16286, type, fn_caenorhabditis_elegans_development_10: $i > $i).
% 28.89/28.96  tff(decl_16287, type, fn_caenorhabditis_elegans_development_11: $i > $i).
% 28.89/28.96  tff(decl_16288, type, fn_caenorhabditis_elegans_development_12: $i > $i).
% 28.89/28.96  tff(decl_16289, type, cell_communication_leading_to_apoptosis_1: $i > $o).
% 28.89/28.96  tff(decl_16290, type, cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_1: $i > $o).
% 28.89/28.96  tff(decl_16291, type, fn_caenorhabditis_elegans_development_13: $i > $i).
% 28.89/28.96  tff(decl_16292, type, fn_caenorhabditis_elegans_development_14: $i > $i).
% 28.89/28.96  tff(decl_16293, type, fn_caenorhabditis_elegans_development_15: $i > $i).
% 28.89/28.96  tff(decl_16294, type, fn_caenorhabditis_elegans_development_16: $i > $i).
% 28.89/28.96  tff(decl_16295, type, fn_caenorhabditis_elegans_development_17: $i > $i).
% 28.89/28.96  tff(decl_16296, type, fn_caenorhabditis_elegans_development_18: $i > $i).
% 28.89/28.96  tff(decl_16297, type, fn_caenorhabditis_elegans_development_19: $i > $i).
% 28.89/28.96  tff(decl_16298, type, second_stage_larva_1: $i > $o).
% 28.89/28.96  tff(decl_16299, type, fn_caenorhabditis_elegans_development_20: $i > $i).
% 28.89/28.96  tff(decl_16300, type, embryonic_gonad_1: $i > $o).
% 28.89/28.96  tff(decl_16301, type, fn_caenorhabditis_elegans_development_21: $i > $i).
% 28.89/28.96  tff(decl_16302, type, fn_caenorhabditis_elegans_development_22: $i > $i).
% 28.89/28.96  tff(decl_16303, type, inner_vulva_1: $i > $o).
% 28.89/28.96  tff(decl_16304, type, fn_caenorhabditis_elegans_development_23: $i > $i).
% 28.89/28.96  tff(decl_16305, type, fn_caenorhabditis_elegans_development_24: $i > $i).
% 28.89/28.96  tff(decl_16306, type, fn_caenorhabditis_elegans_development_25: $i > $i).
% 28.89/28.96  tff(decl_16307, type, fn_caenorhabditis_elegans_development_26: $i > $i).
% 28.89/28.96  tff(decl_16308, type, fn_caenorhabditis_elegans_development_27: $i > $i).
% 28.89/28.96  tff(decl_16309, type, outer_vulva_1: $i > $o).
% 28.89/28.96  tff(decl_16310, type, fn_caenorhabditis_elegans_development_28: $i > $i).
% 28.89/28.96  tff(decl_16311, type, fn_caenorhabditis_elegans_development_29: $i > $i).
% 28.89/28.96  tff(decl_16312, type, fn_caenorhabditis_elegans_development_30: $i > $i).
% 28.89/28.96  tff(decl_16313, type, fn_caenorhabditis_elegans_development_31: $i > $i).
% 28.89/28.96  tff(decl_16314, type, fn_caenorhabditis_elegans_development_32: $i > $i).
% 28.89/28.96  tff(decl_16315, type, fn_caenorhabditis_elegans_development_33: $i > $i).
% 28.89/28.96  tff(decl_16316, type, fn_caenorhabditis_elegans_development_34: $i > $i).
% 28.89/28.96  tff(decl_16317, type, fn_caenorhabditis_elegans_development_35: $i > $i).
% 28.89/28.96  tff(decl_16318, type, fn_caenorhabditis_elegans_development_36: $i > $i).
% 28.89/28.96  tff(decl_16319, type, gene_expression_1: $i > $o).
% 28.89/28.96  tff(decl_16320, type, fn_caenorhabditis_elegans_development_37: $i > $i).
% 28.89/28.96  tff(decl_16321, type, gene_activation_1: $i > $o).
% 28.89/28.96  tff(decl_16322, type, fn_caenorhabditis_elegans_development_38: $i > $i).
% 28.89/28.96  tff(decl_16323, type, fn_caenorhabditis_elegans_development_39: $i > $i).
% 28.89/28.96  tff(decl_16324, type, signal_reception_1: $i > $o).
% 28.89/28.96  tff(decl_16325, type, fn_caenorhabditis_elegans_development_40: $i > $i).
% 28.89/28.96  tff(decl_16326, type, fn_caenorhabditis_elegans_development_41: $i > $i).
% 28.89/28.96  tff(decl_16327, type, fn_vulva_development_1: $i > $i).
% 28.89/28.96  tff(decl_16328, type, fn_gene_activation_7: $i > $i).
% 28.89/28.96  tff(decl_16329, type, fn_embryogenesis_25: $i > $i).
% 28.89/28.96  tff(decl_16330, type, fn_embryogenesis_52: $i > $i).
% 28.89/28.96  tff(decl_16331, type, fn_second_stage_larva_6: $i > $i).
% 28.89/28.96  tff(decl_16332, type, fn_second_stage_larva_9: $i > $i).
% 28.89/28.96  tff(decl_16333, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_51: $i > $i).
% 28.89/28.96  tff(decl_16334, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_43: $i > $i).
% 28.89/28.96  tff(decl_16335, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_72: $i > $i).
% 28.89/28.96  tff(decl_16336, type, fn_second_stage_larva_3: $i > $i).
% 28.89/28.96  tff(decl_16337, type, fn_cell_differentiation_induction_5: $i > $i).
% 28.89/28.96  tff(decl_16338, type, fn_second_stage_larva_4: $i > $i).
% 28.89/28.96  tff(decl_16339, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_53: $i > $i).
% 28.89/28.96  tff(decl_16340, type, fn_signal_reception_3: $i > $i).
% 28.89/28.96  tff(decl_16341, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_42: $i > $i).
% 28.89/28.96  tff(decl_16342, type, "131": $i).
% 28.89/28.96  tff(decl_16343, type, apoptosis_0: $i).
% 28.89/28.96  tff(decl_16344, type, 'CDI 1': $i).
% 28.89/28.96  tff(decl_16345, type, 'CDI 2': $i).
% 28.89/28.96  tff(decl_16346, type, 'Outer Vulva 1': $i).
% 28.89/28.96  tff(decl_16347, type, 'Outer Vulva 2': $i).
% 28.89/28.96  tff(decl_16348, type, 'CDI 3': $i).
% 28.89/28.96  tff(decl_16349, type, 'VPC 5': $i).
% 28.89/28.96  tff(decl_16350, type, 'VPC 4': $i).
% 28.89/28.96  tff(decl_16351, type, 'VPC 2': $i).
% 28.89/28.96  tff(decl_16352, type, calcification_1: $i > $o).
% 28.89/28.96  tff(decl_16353, type, 'Calcification': $i).
% 28.89/28.96  tff(decl_16354, type, 'The accumulation of calcium salts in soft tissues.': $i).
% 28.89/28.96  tff(decl_16355, type, calcify: $i).
% 28.89/28.96  tff(decl_16356, type, calcification: $i).
% 28.89/28.96  tff(decl_16357, type, fn_calcification_1: $i > $i).
% 28.89/28.96  tff(decl_16358, type, calcium_carbonate_1: $i > $o).
% 28.89/28.96  tff(decl_16359, type, fn_calcification_2: $i > $i).
% 28.89/28.96  tff(decl_16360, type, fn_calcification_3: $i > $i).
% 28.89/28.96  tff(decl_16361, type, fn_calcification_4: $i > $i).
% 28.89/28.96  tff(decl_16362, type, 'Calcitonin': $i).
% 28.89/28.96  tff(decl_16363, type, 'A polypeptide hormone produced by the thyroid gland. It reduces blood calcium by opposing the effect of parathyroid hormone.': $i).
% 28.89/28.96  tff(decl_16364, type, calcitonin: $i).
% 28.89/28.96  tff(decl_16365, type, thyroid_peptide_hormone_1: $i > $o).
% 28.89/28.96  tff(decl_16366, type, fn_calcitonin_1: $i > $i).
% 28.89/28.96  tff(decl_16367, type, 'Calcium': $i).
% 28.89/28.96  tff(decl_16368, type, 'Calcium is a metal atom with atomic number 20. It is represented by the symbol Ca.': $i).
% 28.89/28.96  tff(decl_16369, type, 'Ca': $i).
% 28.89/28.96  tff(decl_16370, type, calcium: $i).
% 28.89/28.96  tff(decl_16371, type, copper_1: $i > $o).
% 28.89/28.96  tff(decl_16372, type, magnesium_1: $i > $o).
% 28.89/28.96  tff(decl_16373, type, fn_calcium_1: $i > $i).
% 28.89/28.96  tff(decl_16374, type, fn_calcium_2: $i > $i).
% 28.89/28.96  tff(decl_16375, type, fn_calcium_3: $i > $i).
% 28.89/28.96  tff(decl_16376, type, fn_calcium_4: $i > $i).
% 28.89/28.96  tff(decl_16377, type, fn_calcium_5: $i > $i).
% 28.89/28.96  tff(decl_16378, type, fn_calcium_12: $i > $i).
% 28.89/28.96  tff(decl_16379, type, fn_calcium_13: $i > $i).
% 28.89/28.96  tff(decl_16380, type, fn_calcium_14: $i > $i).
% 28.89/28.96  tff(decl_16381, type, fn_calcium_15: $i > $i).
% 28.89/28.96  tff(decl_16382, type, fn_calcium_16: $i > $i).
% 28.89/28.96  tff(decl_16383, type, fn_calcium_17: $i > $i).
% 28.89/28.96  tff(decl_16384, type, fn_calcium_18: $i > $i).
% 28.89/28.96  tff(decl_16385, type, fn_calcium_19: $i > $i).
% 28.89/28.96  tff(decl_16386, type, fn_calcium_20: $i > $i).
% 28.89/28.96  tff(decl_16387, type, "40.08": $i).
% 28.89/28.96  tff(decl_16388, type, "20": $i).
% 28.89/28.96  tff(decl_16389, type, fn_calcium_11: $i > $i).
% 28.89/28.96  tff(decl_16390, type, fn_calcium_10: $i > $i).
% 28.89/28.96  tff(decl_16391, type, 'Calcium-Carbonate': $i).
% 28.89/28.96  tff(decl_16392, type, 'A mineral compound with the chemical formula CaCO3. It plays a role in animal nutrition, biological buffer systems, and the physical structure of some organisms.': $i).
% 28.89/28.96  tff(decl_16393, type, caco3: $i).
% 28.89/28.96  tff(decl_16394, type, 'carbonate of calcium': $i).
% 28.89/28.96  tff(decl_16395, type, 'calcium carbonate': $i).
% 28.89/28.96  tff(decl_16396, type, 'calcium-carbonate': $i).
% 28.89/28.96  tff(decl_16397, type, fn_calcium_carbonate_1: $i > $i).
% 28.89/28.96  tff(decl_16398, type, fn_calcium_carbonate_2: $i > $i).
% 28.89/28.96  tff(decl_16399, type, fn_ionic_compound_1: $i > $i).
% 28.89/28.96  tff(decl_16400, type, fn_ionic_compound_2: $i > $i).
% 28.89/28.96  tff(decl_16401, type, calcium_cycle_1: $i > $o).
% 28.89/28.96  tff(decl_16402, type, 'Calcium-Cycle': $i).
% 28.89/28.96  tff(decl_16403, type, 'Global biogeochemical processes which cycle calcium through the biotic and abiotic components of ecosystems.': $i).
% 28.89/28.96  tff(decl_16404, type, 'undergo the calcium cycle': $i).
% 28.89/28.96  tff(decl_16405, type, 'cycle of calcium': $i).
% 28.89/28.96  tff(decl_16406, type, 'calcium cycle': $i).
% 28.89/28.96  tff(decl_16407, type, 'calcium-cycle': $i).
% 28.89/28.96  tff(decl_16408, type, local_biogeochemical_cycle_1: $i > $o).
% 28.89/28.96  tff(decl_16409, type, fn_calcium_cycle_1: $i > $i).
% 28.89/28.96  tff(decl_16410, type, fn_calcium_cycle_2: $i > $i).
% 28.89/28.96  tff(decl_16411, type, fn_calcium_cycle_3: $i > $i).
% 28.89/28.96  tff(decl_16412, type, fn_calcium_cycle_4: $i > $i).
% 28.89/28.96  tff(decl_16413, type, fn_calcium_cycle_5: $i > $i).
% 28.89/28.96  tff(decl_16414, type, fn_calcium_cycle_6: $i > $i).
% 28.89/28.96  tff(decl_16415, type, fn_calcium_cycle_7: $i > $i).
% 28.89/28.96  tff(decl_16416, type, fn_calcium_cycle_8: $i > $i).
% 28.89/28.96  tff(decl_16417, type, fn_calcium_cycle_9: $i > $i).
% 28.89/28.96  tff(decl_16418, type, soil_solution_1: $i > $o).
% 28.89/28.96  tff(decl_16419, type, fn_calcium_cycle_10: $i > $i).
% 28.89/28.96  tff(decl_16420, type, fn_calcium_cycle_11: $i > $i).
% 28.89/28.96  tff(decl_16421, type, fn_root_hair_2: $i > $i).
% 28.89/28.96  tff(decl_16422, type, fn_root_hair_1: $i > $i).
% 28.89/28.96  tff(decl_16423, type, fn_root_hair_3: $i > $i).
% 28.89/28.96  tff(decl_16424, type, fn_soil_2: $i > $i).
% 28.89/28.96  tff(decl_16425, type, fn_soil_solution_1: $i > $i).
% 28.89/28.96  tff(decl_16426, type, fn_local_biogeochemical_cycle_2: $i > $i).
% 28.89/28.96  tff(decl_16427, type, 'Calcium-Ion': $i).
% 28.89/28.96  tff(decl_16428, type, 'A atom of calcium with a charge of 2+.': $i).
% 28.89/28.96  tff(decl_16429, type, 'ion of calcium': $i).
% 28.89/28.96  tff(decl_16430, type, 'calcium ion': $i).
% 28.89/28.96  tff(decl_16431, type, 'calcium-ion': $i).
% 28.89/28.96  tff(decl_16432, type, methyl_ion_1: $i > $o).
% 28.89/28.96  tff(decl_16433, type, metal_cation_1: $i > $o).
% 28.89/28.96  tff(decl_16434, type, magnesium_ion_1: $i > $o).
% 28.89/28.96  tff(decl_16435, type, fn_calcium_ion_1: $i > $i).
% 28.89/28.96  tff(decl_16436, type, fn_calcium_ion_2: $i > $i).
% 28.89/28.96  tff(decl_16437, type, fn_calcium_ion_3: $i > $i).
% 28.89/28.96  tff(decl_16438, type, fn_calcium_ion_5: $i > $i).
% 28.89/28.96  tff(decl_16439, type, fn_calcium_ion_6: $i > $i).
% 28.89/28.96  tff(decl_16440, type, "2.0e0": $i).
% 28.89/28.96  tff(decl_16441, type, fn_calcium_ion_4: $i > $i).
% 28.89/28.96  tff(decl_16442, type, californium_1: $i > $o).
% 28.89/28.96  tff(decl_16443, type, 'Californium': $i).
% 28.89/28.96  tff(decl_16444, type, 'Californium is a metal atom with atomic number 98. It is represented by the symbol Cf.': $i).
% 28.89/28.96  tff(decl_16445, type, californium: $i).
% 28.89/28.96  tff(decl_16446, type, cf: $i).
% 28.89/28.96  tff(decl_16447, type, fn_californium_3: $i > $i).
% 28.89/28.96  tff(decl_16448, type, fn_californium_4: $i > $i).
% 28.89/28.96  tff(decl_16449, type, fn_californium_5: $i > $i).
% 28.89/28.96  tff(decl_16450, type, fn_californium_9: $i > $i).
% 28.89/28.96  tff(decl_16451, type, fn_californium_10: $i > $i).
% 28.89/28.96  tff(decl_16452, type, fn_californium_11: $i > $i).
% 28.89/28.96  tff(decl_16453, type, fn_californium_12: $i > $i).
% 28.89/28.96  tff(decl_16454, type, "153": $i).
% 28.89/28.96  tff(decl_16455, type, "98": $i).
% 28.89/28.96  tff(decl_16456, type, "12": $i).
% 28.89/28.96  tff(decl_16457, type, "251": $i).
% 28.89/28.96  tff(decl_16458, type, fn_californium_7: $i > $i).
% 28.89/28.96  tff(decl_16459, type, fn_californium_8: $i > $i).
% 28.89/28.96  tff(decl_16460, type, fn_californium_6: $i > $i).
% 28.89/28.96  tff(decl_16461, type, 'Callus': $i).
% 28.89/28.96  tff(decl_16462, type, 'An area of skin that has become thick and toughened due to repeated friction, pressure, or other irritation.': $i).
% 28.89/28.96  tff(decl_16463, type, callus: $i).
% 28.89/28.96  tff(decl_16464, type, calmodulin_1: $i > $o).
% 28.89/28.96  tff(decl_16465, type, 'Calmodulin': $i).
% 28.89/28.96  tff(decl_16466, type, 'A calcium binding protein found in all eukaryotes.': $i).
% 28.89/28.96  tff(decl_16467, type, calmodulin: $i).
% 28.89/28.96  tff(decl_16468, type, relay_protein_1: $i > $o).
% 28.89/28.96  tff(decl_16469, type, g_protein_1: $i > $o).
% 28.89/28.96  tff(decl_16470, type, scaffolding_protein_1: $i > $o).
% 28.89/28.96  tff(decl_16471, type, fn_calmodulin_1: $i > $i).
% 28.89/28.96  tff(decl_16472, type, fn_calmodulin_2: $i > $i).
% 28.89/28.96  tff(decl_16473, type, signal_transduction_with_calmodulin_1: $i > $o).
% 28.89/28.96  tff(decl_16474, type, fn_calmodulin_3: $i > $i).
% 28.89/28.96  tff(decl_16475, type, relay_molecule_1: $i > $o).
% 28.89/28.96  tff(decl_16476, type, fn_relay_protein_1: $i > $i).
% 28.89/28.96  tff(decl_16477, type, 'Calvin-Cycle': $i).
% 28.89/28.96  tff(decl_16478, type, 'The Calvin cycle or Calvin Benson cycle or Reductive Pentose Phosphate cycle is a series of biochemical redox reactions that take place in the stroma of chloroplasts in photosynthetic organisms.': $i).
% 28.89/28.96  tff(decl_16479, type, 'calvin benson cycle': $i).
% 28.89/28.96  tff(decl_16480, type, 'reductive pentose phosphate cycle': $i).
% 28.89/28.96  tff(decl_16481, type, 'dark reaction': $i).
% 28.89/28.96  tff(decl_16482, type, 'calvin-benson-cycle': $i).
% 28.89/28.96  tff(decl_16483, type, 'dark cycle': $i).
% 28.89/28.96  tff(decl_16484, type, 'dark-cycle': $i).
% 28.89/28.96  tff(decl_16485, type, 'dark-reaction': $i).
% 28.89/28.96  tff(decl_16486, type, 'reductive-pentose-phosphate-cycle': $i).
% 28.89/28.96  tff(decl_16487, type, 'light independent reaction': $i).
% 28.89/28.96  tff(decl_16488, type, 'light-independent-reaction': $i).
% 28.89/28.96  tff(decl_16489, type, 'undergo the calvin cycle': $i).
% 28.89/28.96  tff(decl_16490, type, 'cycle of calvin': $i).
% 28.89/28.96  tff(decl_16491, type, 'calvin cycle': $i).
% 28.89/28.96  tff(decl_16492, type, 'calvin-cycle': $i).
% 28.89/28.96  tff(decl_16493, type, endocytosis_1: $i > $o).
% 28.89/28.96  tff(decl_16494, type, fn_calvin_cycle_3: $i > $i).
% 28.89/28.96  tff(decl_16495, type, fn_calvin_cycle_4: $i > $i).
% 28.89/28.96  tff(decl_16496, type, fn_calvin_cycle_5: $i > $i).
% 28.89/28.96  tff(decl_16497, type, fn_calvin_cycle_6: $i > $i).
% 28.89/28.96  tff(decl_16498, type, fn_calvin_cycle_7: $i > $i).
% 28.89/28.96  tff(decl_16499, type, fn_calvin_cycle_8: $i > $i).
% 28.89/28.96  tff(decl_16500, type, fn_calvin_cycle_9: $i > $i).
% 28.89/28.96  tff(decl_16501, type, fn_calvin_cycle_10: $i > $i).
% 28.89/28.96  tff(decl_16502, type, fn_calvin_cycle_11: $i > $i).
% 28.89/28.96  tff(decl_16503, type, fn_calvin_cycle_12: $i > $i).
% 28.89/28.96  tff(decl_16504, type, fn_calvin_cycle_13: $i > $i).
% 28.89/28.96  tff(decl_16505, type, fn_calvin_cycle_14: $i > $i).
% 28.89/28.96  tff(decl_16506, type, fn_calvin_cycle_16: $i > $i).
% 28.89/28.96  tff(decl_16507, type, fn_calvin_cycle_19: $i > $i).
% 28.89/28.96  tff(decl_16508, type, fn_calvin_cycle_20: $i > $i).
% 28.89/28.96  tff(decl_16509, type, fn_calvin_cycle_21: $i > $i).
% 28.89/28.96  tff(decl_16510, type, fn_calvin_cycle_23: $i > $i).
% 28.89/28.96  tff(decl_16511, type, fn_calvin_cycle_31: $i > $i).
% 28.89/28.96  tff(decl_16512, type, fn_calvin_cycle_32: $i > $i).
% 28.89/28.96  tff(decl_16513, type, fn_calvin_cycle_33: $i > $i).
% 28.89/28.96  tff(decl_16514, type, fn_calvin_cycle_38: $i > $i).
% 28.89/28.96  tff(decl_16515, type, fn_calvin_cycle_39: $i > $i).
% 28.89/28.96  tff(decl_16516, type, fn_calvin_cycle_40: $i > $i).
% 28.89/28.96  tff(decl_16517, type, fn_calvin_cycle_41: $i > $i).
% 28.89/28.96  tff(decl_16518, type, fn_calvin_cycle_42: $i > $i).
% 28.89/28.96  tff(decl_16519, type, fn_calvin_cycle_43: $i > $i).
% 28.89/28.96  tff(decl_16520, type, fn_calvin_cycle_44: $i > $i).
% 28.89/28.96  tff(decl_16521, type, fn_calvin_cycle_45: $i > $i).
% 28.89/28.96  tff(decl_16522, type, fn_calvin_cycle_46: $i > $i).
% 28.89/28.96  tff(decl_16523, type, fn_calvin_cycle_47: $i > $i).
% 28.89/28.96  tff(decl_16524, type, fn_calvin_cycle_48: $i > $i).
% 28.89/28.96  tff(decl_16525, type, fn_calvin_cycle_49: $i > $i).
% 28.89/28.96  tff(decl_16526, type, fn_calvin_cycle_50: $i > $i).
% 28.89/28.96  tff(decl_16527, type, fn_calvin_cycle_51: $i > $i).
% 28.89/28.96  tff(decl_16528, type, fn_calvin_cycle_52: $i > $i).
% 28.89/28.96  tff(decl_16529, type, fn_calvin_cycle_53: $i > $i).
% 28.89/28.96  tff(decl_16530, type, fn_calvin_cycle_54: $i > $i).
% 28.89/28.96  tff(decl_16531, type, fn_calvin_cycle_56: $i > $i).
% 28.89/28.96  tff(decl_16532, type, fn_calvin_cycle_63: $i > $i).
% 28.89/28.96  tff(decl_16533, type, fn_calvin_cycle_64: $i > $i).
% 28.89/28.96  tff(decl_16534, type, fn_calvin_cycle_65: $i > $i).
% 28.89/28.96  tff(decl_16535, type, fn_calvin_cycle_66: $i > $i).
% 28.89/28.96  tff(decl_16536, type, fn_calvin_cycle_67: $i > $i).
% 28.89/28.96  tff(decl_16537, type, fn_calvin_cycle_68: $i > $i).
% 28.89/28.96  tff(decl_16538, type, fn_calvin_cycle_71: $i > $i).
% 28.89/28.96  tff(decl_16539, type, fn_calvin_cycle_72: $i > $i).
% 28.89/28.96  tff(decl_16540, type, fn_calvin_cycle_74: $i > $i).
% 28.89/28.96  tff(decl_16541, type, fn_calvin_cycle_75: $i > $i).
% 28.89/28.96  tff(decl_16542, type, fn_calvin_cycle_76: $i > $i).
% 28.89/28.96  tff(decl_16543, type, fn_calvin_cycle_78: $i > $i).
% 28.89/28.96  tff(decl_16544, type, fn_calvin_cycle_79: $i > $i).
% 28.89/28.96  tff(decl_16545, type, fn_calvin_cycle_80: $i > $i).
% 28.89/28.96  tff(decl_16546, type, fn_calvin_cycle_81: $i > $i).
% 28.89/28.96  tff(decl_16547, type, fn_calvin_cycle_83: $i > $i).
% 28.89/28.96  tff(decl_16548, type, fn_calvin_cycle_85: $i > $i).
% 28.89/28.96  tff(decl_16549, type, fn_calvin_cycle_86: $i > $i).
% 28.89/28.96  tff(decl_16550, type, fn_calvin_cycle_87: $i > $i).
% 28.89/28.96  tff(decl_16551, type, fn_calvin_cycle_88: $i > $i).
% 28.89/28.96  tff(decl_16552, type, fn_calvin_cycle_92: $i > $i).
% 28.89/28.96  tff(decl_16553, type, fn_calvin_cycle_93: $i > $i).
% 28.89/28.96  tff(decl_16554, type, fn_calvin_cycle_94: $i > $i).
% 28.89/28.96  tff(decl_16555, type, fn_calvin_cycle_95: $i > $i).
% 28.89/28.96  tff(decl_16556, type, fn_calvin_cycle_96: $i > $i).
% 28.89/28.96  tff(decl_16557, type, fn_calvin_cycle_97: $i > $i).
% 28.89/28.96  tff(decl_16558, type, fn_calvin_cycle_98: $i > $i).
% 28.89/28.96  tff(decl_16559, type, fn_calvin_cycle_99: $i > $i).
% 28.89/28.96  tff(decl_16560, type, fn_calvin_cycle_100: $i > $i).
% 28.89/28.96  tff(decl_16561, type, fn_calvin_cycle_101: $i > $i).
% 28.89/28.96  tff(decl_16562, type, fn_calvin_cycle_102: $i > $i).
% 28.89/28.96  tff(decl_16563, type, fn_calvin_cycle_103: $i > $i).
% 28.89/28.96  tff(decl_16564, type, fn_calvin_cycle_104: $i > $i).
% 28.89/28.96  tff(decl_16565, type, fn_calvin_cycle_105: $i > $i).
% 28.89/28.96  tff(decl_16566, type, fn_calvin_cycle_106: $i > $i).
% 28.89/28.96  tff(decl_16567, type, fn_calvin_cycle_107: $i > $i).
% 28.89/28.96  tff(decl_16568, type, fn_regeneration_of_ribulose_bisphosphate_3: $i > $i).
% 28.89/28.96  tff(decl_16569, type, fn_carbon_fixation_4: $i > $i).
% 28.89/28.96  tff(decl_16570, type, fn_carbon_fixation_3: $i > $i).
% 28.89/28.96  tff(decl_16571, type, fn_reduction_in_calvin_cycle_8: $i > $i).
% 28.89/28.96  tff(decl_16572, type, fn_electron_3: $i > $i).
% 28.89/28.96  tff(decl_16573, type, fn_hydrophobic_compound_3: $i > $i).
% 28.89/28.96  tff(decl_16574, type, fn_hydrophobic_compound_2: $i > $i).
% 28.89/28.96  tff(decl_16575, type, fn_ketone_2: $i > $i).
% 28.89/28.96  tff(decl_16576, type, fn_ketone_1: $i > $i).
% 28.89/28.96  tff(decl_16577, type, fn_three_phosphoglycerate_19: $i > $i).
% 28.89/28.96  tff(decl_16578, type, fn_three_phosphoglycerate_20: $i > $i).
% 28.89/28.96  tff(decl_16579, type, fn_three_phosphoglycerate_5: $i > $i).
% 28.89/28.96  tff(decl_16580, type, fn_three_phosphoglycerate_1: $i > $i).
% 28.89/28.96  tff(decl_16581, type, fn_three_phosphoglycerate_15: $i > $i).
% 28.89/28.96  tff(decl_16582, type, fn_three_phosphoglycerate_2: $i > $i).
% 28.89/28.96  tff(decl_16583, type, fn_three_phosphoglycerate_14: $i > $i).
% 28.89/28.96  tff(decl_16584, type, fn_three_phosphoglycerate_6: $i > $i).
% 28.89/28.96  tff(decl_16585, type, fn_three_phosphoglycerate_10: $i > $i).
% 28.89/28.96  tff(decl_16586, type, fn_carbon_dioxide_6: $i > $i).
% 28.89/28.96  tff(decl_16587, type, fn_carbon_dioxide_2: $i > $i).
% 28.89/28.96  tff(decl_16588, type, fn_carbon_dioxide_5: $i > $i).
% 28.89/28.96  tff(decl_16589, type, fn_ribulose_bisphosphate_19: $i > $i).
% 28.89/28.96  tff(decl_16590, type, fn_carbon_fixation_1: $i > $i).
% 28.89/28.96  tff(decl_16591, type, fn_regeneration_of_ribulose_bisphosphate_4: $i > $i).
% 28.89/28.96  tff(decl_16592, type, fn_reduction_in_calvin_cycle_4: $i > $i).
% 28.89/28.96  tff(decl_16593, type, fn_regeneration_of_ribulose_bisphosphate_5: $i > $i).
% 28.89/28.96  tff(decl_16594, type, fn_reduction_in_calvin_cycle_16: $i > $i).
% 28.89/28.96  tff(decl_16595, type, fn_oxidizing_agent_1: $i > $i).
% 28.89/28.96  tff(decl_16596, type, fn_reduction_in_calvin_cycle_9: $i > $i).
% 28.89/28.96  tff(decl_16597, type, fn_pentose_5: $i > $i).
% 28.89/28.96  tff(decl_16598, type, fn_ketone_4: $i > $i).
% 28.89/28.96  tff(decl_16599, type, fn_pentose_4: $i > $i).
% 28.89/28.96  tff(decl_16600, type, fn_ketone_3: $i > $i).
% 28.89/28.96  tff(decl_16601, type, fn_pentose_6: $i > $i).
% 28.89/28.96  tff(decl_16602, type, fn_ketone_5: $i > $i).
% 28.89/28.96  tff(decl_16603, type, fn_pentose_7: $i > $i).
% 28.89/28.96  tff(decl_16604, type, fn_ketone_6: $i > $i).
% 28.89/28.96  tff(decl_16605, type, fn_carbon_fixation_5: $i > $i).
% 28.89/28.96  tff(decl_16606, type, fn_reduction_in_calvin_cycle_10: $i > $i).
% 28.89/28.96  tff(decl_16607, type, fn_three_phosphoglycerate_7: $i > $i).
% 28.89/28.96  tff(decl_16608, type, fn_three_phosphoglycerate_13: $i > $i).
% 28.89/28.96  tff(decl_16609, type, fn_three_phosphoglycerate_11: $i > $i).
% 28.89/28.96  tff(decl_16610, type, fn_three_phosphoglycerate_12: $i > $i).
% 28.89/28.96  tff(decl_16611, type, fn_three_phosphoglycerate_8: $i > $i).
% 28.89/28.96  tff(decl_16612, type, fn_three_phosphoglycerate_3: $i > $i).
% 28.89/28.96  tff(decl_16613, type, fn_three_phosphoglycerate_9: $i > $i).
% 28.89/28.96  tff(decl_16614, type, fn_three_phosphoglycerate_4: $i > $i).
% 28.89/28.96  tff(decl_16615, type, fn_carbon_dioxide_7: $i > $i).
% 28.89/28.96  tff(decl_16616, type, fn_carbon_dioxide_3: $i > $i).
% 28.89/28.96  tff(decl_16617, type, fn_carbon_fixation_6: $i > $i).
% 28.89/28.96  tff(decl_16618, type, fn_carbon_dioxide_1: $i > $i).
% 28.89/28.96  tff(decl_16619, type, fn_carbon_dioxide_4: $i > $i).
% 28.89/28.96  tff(decl_16620, type, fn_pentose_11: $i > $i).
% 28.89/28.96  tff(decl_16621, type, fn_ribulose_bisphosphate_21: $i > $i).
% 28.89/28.96  tff(decl_16622, type, fn_pentose_12: $i > $i).
% 28.89/28.96  tff(decl_16623, type, fn_ketone_11: $i > $i).
% 28.89/28.96  tff(decl_16624, type, fn_ribulose_bisphosphate_22: $i > $i).
% 28.89/28.96  tff(decl_16625, type, fn_ketone_9: $i > $i).
% 28.89/28.96  tff(decl_16626, type, fn_ribulose_bisphosphate_20: $i > $i).
% 28.89/28.96  tff(decl_16627, type, fn_pentose_10: $i > $i).
% 28.89/28.96  tff(decl_16628, type, fn_pentose_15: $i > $i).
% 28.89/28.96  tff(decl_16629, type, fn_ketone_12: $i > $i).
% 28.89/28.96  tff(decl_16630, type, fn_ribulose_bisphosphate_26: $i > $i).
% 28.89/28.96  tff(decl_16631, type, fn_ribulose_bisphosphate_25: $i > $i).
% 28.89/28.96  tff(decl_16632, type, fn_ketone_7: $i > $i).
% 28.89/28.96  tff(decl_16633, type, fn_ribulose_bisphosphate_18: $i > $i).
% 28.89/28.96  tff(decl_16634, type, fn_ribulose_bisphosphate_27: $i > $i).
% 28.89/28.96  tff(decl_16635, type, fn_ribulose_bisphosphate_23: $i > $i).
% 28.89/28.96  tff(decl_16636, type, fn_regeneration_of_ribulose_bisphosphate_2: $i > $i).
% 28.89/28.96  tff(decl_16637, type, fn_pentose_16: $i > $i).
% 28.89/28.96  tff(decl_16638, type, fn_ribulose_bisphosphate_24: $i > $i).
% 28.89/28.96  tff(decl_16639, type, energy_0: $i).
% 28.89/28.96  tff(decl_16640, type, fn_calvin_cycle_35: $i > $i).
% 28.89/28.96  tff(decl_16641, type, fn_anabolic_pathway_2: $i > $i).
% 28.89/28.96  tff(decl_16642, type, fn_calvin_cycle_29: $i > $i).
% 28.89/28.96  tff(decl_16643, type, fn_endergonic_reaction_7: $i > $i).
% 28.89/28.96  tff(decl_16644, type, fn_calvin_cycle_28: $i > $i).
% 28.89/28.96  tff(decl_16645, type, fn_endergonic_reaction_6: $i > $i).
% 28.89/28.96  tff(decl_16646, type, fn_endergonic_reaction_2: $i > $i).
% 28.89/28.96  tff(decl_16647, type, fn_calvin_cycle_109: $i > $i).
% 28.89/28.96  tff(decl_16648, type, fn_calvin_cycle_108: $i > $i).
% 28.89/28.96  tff(decl_16649, type, fn_calvin_cycle_91: $i > $i).
% 28.89/28.96  tff(decl_16650, type, fn_calvin_cycle_90: $i > $i).
% 28.89/28.96  tff(decl_16651, type, 'Calyptra': $i).
% 28.89/28.96  tff(decl_16652, type, 'A protective cap of gametophyte tissue in moss spores.': $i).
% 28.89/28.96  tff(decl_16653, type, calyptra: $i).
% 28.89/28.96  tff(decl_16654, type, cam_plant_1: $i > $o).
% 28.89/28.96  tff(decl_16655, type, 'CAM-Plant': $i).
% 28.89/28.96  tff(decl_16656, type, 'A plant that uses CAM photosynthesis as an adaptation to conserve water in arid conditions. Stomata are open at night and CO2 is taken in by the plant to be stored in an organic acid. During the day, stomata are closed and CO2 is released from the organic acid within the plant and used for photosynthesis.': $i).
% 28.89/28.96  tff(decl_16657, type, 'crassulacean acid metabolism plant': $i).
% 28.89/28.96  tff(decl_16658, type, 'crassulacean-acid-metabolism-plant': $i).
% 28.89/28.96  tff(decl_16659, type, cam: $i).
% 28.89/28.96  tff(decl_16660, type, 'crassulaceae plant': $i).
% 28.89/28.96  tff(decl_16661, type, 'plant of cam': $i).
% 28.89/28.96  tff(decl_16662, type, 'cam plant': $i).
% 28.89/28.96  tff(decl_16663, type, 'cam-plant': $i).
% 28.89/28.96  tff(decl_16664, type, fn_cam_plant_2: $i > $i).
% 28.89/28.96  tff(decl_16665, type, fn_cam_plant_3: $i > $i).
% 28.89/28.96  tff(decl_16666, type, fn_cam_plant_4: $i > $i).
% 28.89/28.96  tff(decl_16667, type, fn_cam_plant_5: $i > $i).
% 28.89/28.96  tff(decl_16668, type, fn_cam_plant_6: $i > $i).
% 28.89/28.96  tff(decl_16669, type, diurnal_closing_of_stoma_1: $i > $o).
% 28.89/28.96  tff(decl_16670, type, fn_cam_plant_7: $i > $i).
% 28.89/28.96  tff(decl_16671, type, fn_cam_plant_9: $i > $i).
% 28.89/28.96  tff(decl_16672, type, fn_cam_plant_12: $i > $i).
% 28.89/28.96  tff(decl_16673, type, fn_cam_plant_13: $i > $i).
% 28.89/28.96  tff(decl_16674, type, fn_cam_plant_14: $i > $i).
% 28.89/28.96  tff(decl_16675, type, fn_cam_plant_15: $i > $i).
% 28.89/28.96  tff(decl_16676, type, fn_cam_plant_22: $i > $i).
% 28.89/28.96  tff(decl_16677, type, fn_cam_plant_23: $i > $i).
% 28.89/28.96  tff(decl_16678, type, fn_cam_plant_24: $i > $i).
% 28.89/28.96  tff(decl_16679, type, fn_cam_plant_25: $i > $i).
% 28.89/28.96  tff(decl_16680, type, fn_cam_plant_26: $i > $i).
% 28.89/28.96  tff(decl_16681, type, fn_cam_plant_27: $i > $i).
% 28.89/28.96  tff(decl_16682, type, fn_cam_plant_28: $i > $i).
% 28.89/28.96  tff(decl_16683, type, fn_cam_plant_29: $i > $i).
% 28.89/28.96  tff(decl_16684, type, fn_cam_plant_30: $i > $i).
% 28.89/28.96  tff(decl_16685, type, electron_recipient_1: $i > $o).
% 28.89/28.96  tff(decl_16686, type, fn_cam_plant_31: $i > $i).
% 28.89/28.96  tff(decl_16687, type, fn_cam_plant_32: $i > $i).
% 28.89/28.96  tff(decl_16688, type, fn_cam_plant_33: $i > $i).
% 28.89/28.96  tff(decl_16689, type, fn_cam_plant_34: $i > $i).
% 28.89/28.96  tff(decl_16690, type, fn_cam_plant_35: $i > $i).
% 28.89/28.96  tff(decl_16691, type, fn_cam_plant_36: $i > $i).
% 28.89/28.96  tff(decl_16692, type, fn_cam_plant_37: $i > $i).
% 28.89/28.96  tff(decl_16693, type, fn_cam_plant_38: $i > $i).
% 28.89/28.96  tff(decl_16694, type, fn_cam_plant_39: $i > $i).
% 28.89/28.96  tff(decl_16695, type, fn_cam_plant_40: $i > $i).
% 28.89/28.96  tff(decl_16696, type, fn_cam_plant_41: $i > $i).
% 28.89/28.96  tff(decl_16697, type, fn_cam_plant_42: $i > $i).
% 28.89/28.96  tff(decl_16698, type, fn_cam_plant_43: $i > $i).
% 28.89/28.96  tff(decl_16699, type, fn_cam_plant_44: $i > $i).
% 28.89/28.96  tff(decl_16700, type, fn_cam_plant_45: $i > $i).
% 28.89/28.96  tff(decl_16701, type, fn_cam_plant_46: $i > $i).
% 28.89/28.96  tff(decl_16702, type, fn_cam_plant_47: $i > $i).
% 28.89/28.96  tff(decl_16703, type, fn_cam_plant_48: $i > $i).
% 28.89/28.96  tff(decl_16704, type, fn_cam_plant_49: $i > $i).
% 28.89/28.96  tff(decl_16705, type, fn_cam_plant_50: $i > $i).
% 28.89/28.96  tff(decl_16706, type, fn_cam_plant_51: $i > $i).
% 28.89/28.96  tff(decl_16707, type, fn_cam_plant_52: $i > $i).
% 28.89/28.96  tff(decl_16708, type, fn_cam_plant_53: $i > $i).
% 28.89/28.96  tff(decl_16709, type, fn_cam_plant_54: $i > $i).
% 28.89/28.96  tff(decl_16710, type, fn_cam_plant_55: $i > $i).
% 28.89/28.96  tff(decl_16711, type, fn_cam_plant_56: $i > $i).
% 28.89/28.96  tff(decl_16712, type, fn_cam_plant_57: $i > $i).
% 28.89/28.96  tff(decl_16713, type, fn_cam_plant_58: $i > $i).
% 28.89/28.96  tff(decl_16714, type, fn_cam_plant_59: $i > $i).
% 28.89/28.96  tff(decl_16715, type, fn_cam_plant_60: $i > $i).
% 28.89/28.96  tff(decl_16716, type, fn_cam_plant_65: $i > $i).
% 28.89/28.96  tff(decl_16717, type, fn_cam_plant_66: $i > $i).
% 28.89/28.96  tff(decl_16718, type, fn_cam_plant_67: $i > $i).
% 28.89/28.96  tff(decl_16719, type, fn_cam_plant_68: $i > $i).
% 28.89/28.96  tff(decl_16720, type, fn_cam_plant_69: $i > $i).
% 28.89/28.96  tff(decl_16721, type, fn_cam_plant_70: $i > $i).
% 28.89/28.96  tff(decl_16722, type, fn_cam_plant_71: $i > $i).
% 28.89/28.96  tff(decl_16723, type, fn_cam_plant_76: $i > $i).
% 28.89/28.96  tff(decl_16724, type, fn_cam_plant_77: $i > $i).
% 28.89/28.96  tff(decl_16725, type, fn_cam_plant_78: $i > $i).
% 28.89/28.96  tff(decl_16726, type, fn_cam_plant_79: $i > $i).
% 28.89/28.96  tff(decl_16727, type, fn_cam_plant_80: $i > $i).
% 28.89/28.96  tff(decl_16728, type, fn_cam_plant_81: $i > $i).
% 28.89/28.96  tff(decl_16729, type, fn_cam_plant_82: $i > $i).
% 28.89/28.96  tff(decl_16730, type, fn_cam_plant_83: $i > $i).
% 28.89/28.96  tff(decl_16731, type, fn_cam_plant_84: $i > $i).
% 28.89/28.96  tff(decl_16732, type, fn_cam_plant_85: $i > $i).
% 28.89/28.96  tff(decl_16733, type, fn_cam_plant_86: $i > $i).
% 28.89/28.96  tff(decl_16734, type, fn_cam_plant_87: $i > $i).
% 28.89/28.96  tff(decl_16735, type, fn_cam_plant_88: $i > $i).
% 28.89/28.96  tff(decl_16736, type, fn_cam_plant_89: $i > $i).
% 28.89/28.96  tff(decl_16737, type, fn_cam_plant_90: $i > $i).
% 28.89/28.96  tff(decl_16738, type, fn_cam_plant_91: $i > $i).
% 28.89/28.96  tff(decl_16739, type, fn_cam_plant_92: $i > $i).
% 28.89/28.96  tff(decl_16740, type, fn_cam_plant_93: $i > $i).
% 28.89/28.96  tff(decl_16741, type, fn_cam_plant_94: $i > $i).
% 28.89/28.96  tff(decl_16742, type, fn_cam_plant_95: $i > $i).
% 28.89/28.96  tff(decl_16743, type, fn_cam_plant_96: $i > $i).
% 28.89/28.96  tff(decl_16744, type, fn_cam_plant_97: $i > $i).
% 28.89/28.96  tff(decl_16745, type, fn_cam_plant_98: $i > $i).
% 28.89/28.96  tff(decl_16746, type, fn_cam_plant_99: $i > $i).
% 28.89/28.96  tff(decl_16747, type, fn_cam_plant_100: $i > $i).
% 28.89/28.96  tff(decl_16748, type, fn_cam_plant_101: $i > $i).
% 28.89/28.96  tff(decl_16749, type, fn_cam_plant_102: $i > $i).
% 28.89/28.96  tff(decl_16750, type, fn_cam_plant_103: $i > $i).
% 28.89/28.96  tff(decl_16751, type, fn_cam_plant_104: $i > $i).
% 28.89/28.96  tff(decl_16752, type, fn_cam_plant_105: $i > $i).
% 28.89/28.96  tff(decl_16753, type, fn_cam_plant_106: $i > $i).
% 28.89/28.96  tff(decl_16754, type, fn_cam_plant_107: $i > $i).
% 28.89/28.96  tff(decl_16755, type, fn_cam_plant_108: $i > $i).
% 28.89/28.96  tff(decl_16756, type, fn_cam_plant_109: $i > $i).
% 28.89/28.96  tff(decl_16757, type, closing_of_stoma_1: $i > $o).
% 28.89/28.96  tff(decl_16758, type, fn_cam_plant_110: $i > $i).
% 28.89/28.96  tff(decl_16759, type, fn_cam_plant_111: $i > $i).
% 28.89/28.96  tff(decl_16760, type, fn_cam_plant_112: $i > $i).
% 28.89/28.96  tff(decl_16761, type, fn_cam_plant_113: $i > $i).
% 28.89/28.96  tff(decl_16762, type, fn_cam_plant_114: $i > $i).
% 28.89/28.96  tff(decl_16763, type, fn_cam_plant_115: $i > $i).
% 28.89/28.96  tff(decl_16764, type, fn_cam_plant_116: $i > $i).
% 28.89/28.96  tff(decl_16765, type, fn_cam_plant_117: $i > $i).
% 28.89/28.96  tff(decl_16766, type, fn_cam_plant_118: $i > $i).
% 28.89/28.96  tff(decl_16767, type, fn_cam_plant_119: $i > $i).
% 28.89/28.96  tff(decl_16768, type, fn_cam_plant_120: $i > $i).
% 28.89/28.96  tff(decl_16769, type, fn_cam_plant_121: $i > $i).
% 28.89/28.96  tff(decl_16770, type, fn_cam_plant_122: $i > $i).
% 28.89/28.96  tff(decl_16771, type, fn_cam_plant_123: $i > $i).
% 28.89/28.96  tff(decl_16772, type, fn_cam_plant_124: $i > $i).
% 28.89/28.96  tff(decl_16773, type, fn_cam_plant_125: $i > $i).
% 28.89/28.96  tff(decl_16774, type, fn_cam_plant_126: $i > $i).
% 28.89/28.96  tff(decl_16775, type, fn_cam_plant_127: $i > $i).
% 28.89/28.96  tff(decl_16776, type, fn_cam_plant_128: $i > $i).
% 28.89/28.96  tff(decl_16777, type, fn_cam_plant_129: $i > $i).
% 28.89/28.96  tff(decl_16778, type, fn_cam_plant_130: $i > $i).
% 28.89/28.96  tff(decl_16779, type, fn_cam_plant_131: $i > $i).
% 28.89/28.96  tff(decl_16780, type, fn_cam_plant_132: $i > $i).
% 28.89/28.96  tff(decl_16781, type, citric_acid_cycle_1: $i > $o).
% 28.89/28.96  tff(decl_16782, type, fn_plasmodesmata_11: $i > $i).
% 28.89/28.96  tff(decl_16783, type, fn_eukaryotic_cellular_respiration_118: $i > $i).
% 28.89/28.96  tff(decl_16784, type, fn_eukaryotic_cellular_respiration_112: $i > $i).
% 28.89/28.96  tff(decl_16785, type, fn_eukaryotic_cellular_respiration_157: $i > $i).
% 28.89/28.96  tff(decl_16786, type, fn_eukaryotic_cellular_respiration_117: $i > $i).
% 28.89/28.96  tff(decl_16787, type, fn_eukaryotic_cellular_respiration_116: $i > $i).
% 28.89/28.96  tff(decl_16788, type, fn_eukaryotic_cellular_respiration_65: $i > $i).
% 28.89/28.96  tff(decl_16789, type, fn_crassulacean_acid_metabolism_64: $i > $i).
% 28.89/28.96  tff(decl_16790, type, fn_crassulacean_acid_metabolism_156: $i > $i).
% 28.89/28.96  tff(decl_16791, type, fn_crassulacean_acid_metabolism_157: $i > $i).
% 28.89/28.96  tff(decl_16792, type, fn_crassulacean_acid_metabolism_153: $i > $i).
% 28.89/28.96  tff(decl_16793, type, fn_crassulacean_acid_metabolism_34: $i > $i).
% 28.89/28.96  tff(decl_16794, type, fn_crassulacean_acid_metabolism_116: $i > $i).
% 28.89/28.96  tff(decl_16795, type, fn_crassulacean_acid_metabolism_152: $i > $i).
% 28.89/28.96  tff(decl_16796, type, fn_crassulacean_acid_metabolism_129: $i > $i).
% 28.89/28.96  tff(decl_16797, type, fn_crassulacean_acid_metabolism_63: $i > $i).
% 28.89/28.96  tff(decl_16798, type, fn_crassulacean_acid_metabolism_66: $i > $i).
% 28.89/28.96  tff(decl_16799, type, fn_crassulacean_acid_metabolism_77: $i > $i).
% 28.89/28.96  tff(decl_16800, type, fn_crassulacean_acid_metabolism_53: $i > $i).
% 28.89/28.96  tff(decl_16801, type, fn_crassulacean_acid_metabolism_58: $i > $i).
% 28.89/28.96  tff(decl_16802, type, fn_crassulacean_acid_metabolism_57: $i > $i).
% 28.89/28.96  tff(decl_16803, type, fn_crassulacean_acid_metabolism_163: $i > $i).
% 28.89/28.96  tff(decl_16804, type, fn_crassulacean_acid_metabolism_52: $i > $i).
% 28.89/28.96  tff(decl_16805, type, fn_crassulacean_acid_metabolism_59: $i > $i).
% 28.89/28.96  tff(decl_16806, type, fn_crassulacean_acid_metabolism_60: $i > $i).
% 28.89/28.96  tff(decl_16807, type, fn_crassulacean_acid_metabolism_145: $i > $i).
% 28.89/28.96  tff(decl_16808, type, fn_crassulacean_acid_metabolism_148: $i > $i).
% 28.89/28.96  tff(decl_16809, type, fn_crassulacean_acid_metabolism_105: $i > $i).
% 28.89/28.96  tff(decl_16810, type, fn_crassulacean_acid_metabolism_36: $i > $i).
% 28.89/28.96  tff(decl_16811, type, fn_crassulacean_acid_metabolism_151: $i > $i).
% 28.89/28.96  tff(decl_16812, type, fn_crassulacean_acid_metabolism_150: $i > $i).
% 28.89/28.96  tff(decl_16813, type, fn_crassulacean_acid_metabolism_68: $i > $i).
% 28.89/28.96  tff(decl_16814, type, fn_crassulacean_acid_metabolism_62: $i > $i).
% 28.89/28.96  tff(decl_16815, type, fn_crassulacean_acid_metabolism_37: $i > $i).
% 28.89/28.96  tff(decl_16816, type, fn_crassulacean_acid_metabolism_56: $i > $i).
% 28.89/28.96  tff(decl_16817, type, fn_crassulacean_acid_metabolism_107: $i > $i).
% 28.89/28.96  tff(decl_16818, type, fn_crassulacean_acid_metabolism_55: $i > $i).
% 28.89/28.96  tff(decl_16819, type, fn_crassulacean_acid_metabolism_98: $i > $i).
% 28.89/28.96  tff(decl_16820, type, fn_crassulacean_acid_metabolism_149: $i > $i).
% 28.89/28.96  tff(decl_16821, type, fn_crassulacean_acid_metabolism_101: $i > $i).
% 28.89/28.96  tff(decl_16822, type, fn_crassulacean_acid_metabolism_100: $i > $i).
% 28.89/28.96  tff(decl_16823, type, fn_crassulacean_acid_metabolism_93: $i > $i).
% 28.89/28.96  tff(decl_16824, type, fn_crassulacean_acid_metabolism_135: $i > $i).
% 28.89/28.96  tff(decl_16825, type, fn_crassulacean_acid_metabolism_104: $i > $i).
% 28.89/28.96  tff(decl_16826, type, fn_crassulacean_acid_metabolism_99: $i > $i).
% 28.89/28.96  tff(decl_16827, type, fn_crassulacean_acid_metabolism_16: $i > $i).
% 28.89/28.96  tff(decl_16828, type, fn_crassulacean_acid_metabolism_17: $i > $i).
% 28.89/28.96  tff(decl_16829, type, fn_crassulacean_acid_metabolism_90: $i > $i).
% 28.89/28.96  tff(decl_16830, type, fn_crassulacean_acid_metabolism_97: $i > $i).
% 28.89/28.96  tff(decl_16831, type, fn_crassulacean_acid_metabolism_96: $i > $i).
% 28.89/28.96  tff(decl_16832, type, fn_crassulacean_acid_metabolism_87: $i > $i).
% 28.89/28.96  tff(decl_16833, type, fn_crassulacean_acid_metabolism_65: $i > $i).
% 28.89/28.96  tff(decl_16834, type, fn_eukaryotic_cellular_respiration_82: $i > $i).
% 28.89/28.96  tff(decl_16835, type, fn_cellular_respiration_65: $i > $i).
% 28.89/28.96  tff(decl_16836, type, fn_eukaryotic_cellular_respiration_23: $i > $i).
% 28.89/28.96  tff(decl_16837, type, fn_eukaryotic_cellular_respiration_64: $i > $i).
% 28.89/28.96  tff(decl_16838, type, fn_plant_cell_115: $i > $i).
% 28.89/28.96  tff(decl_16839, type, fn_eukaryotic_cellular_respiration_95: $i > $i).
% 28.89/28.96  tff(decl_16840, type, fn_crassulacean_acid_metabolism_125: $i > $i).
% 28.89/28.96  tff(decl_16841, type, fn_crassulacean_acid_metabolism_139: $i > $i).
% 28.89/28.96  tff(decl_16842, type, fn_crassulacean_acid_metabolism_73: $i > $i).
% 28.89/28.96  tff(decl_16843, type, fn_crassulacean_acid_metabolism_40: $i > $i).
% 28.89/28.96  tff(decl_16844, type, fn_crassulacean_acid_metabolism_67: $i > $i).
% 28.89/28.96  tff(decl_16845, type, fn_crassulacean_acid_metabolism_41: $i > $i).
% 28.89/28.96  tff(decl_16846, type, fn_crassulacean_acid_metabolism_39: $i > $i).
% 28.89/28.96  tff(decl_16847, type, fn_crassulacean_acid_metabolism_35: $i > $i).
% 28.89/28.96  tff(decl_16848, type, fn_crassulacean_acid_metabolism_47: $i > $i).
% 28.89/28.96  tff(decl_16849, type, fn_photosynthesis_96: $i > $i).
% 28.89/28.96  tff(decl_16850, type, fn_crassulacean_acid_metabolism_48: $i > $i).
% 28.89/28.96  tff(decl_16851, type, fn_photosynthesis_99: $i > $i).
% 28.89/28.96  tff(decl_16852, type, fn_crassulacean_acid_metabolism_38: $i > $i).
% 28.89/28.96  tff(decl_16853, type, fn_crassulacean_acid_metabolism_138: $i > $i).
% 28.89/28.96  tff(decl_16854, type, fn_crassulacean_acid_metabolism_146: $i > $i).
% 28.89/28.96  tff(decl_16855, type, fn_crassulacean_acid_metabolism_102: $i > $i).
% 28.89/28.96  tff(decl_16856, type, fn_crassulacean_acid_metabolism_95: $i > $i).
% 28.89/28.96  tff(decl_16857, type, fn_crassulacean_acid_metabolism_72: $i > $i).
% 28.89/28.96  tff(decl_16858, type, fn_crassulacean_acid_metabolism_147: $i > $i).
% 28.89/28.96  tff(decl_16859, type, fn_plant_metabolic_cell_6: $i > $i).
% 28.89/28.96  tff(decl_16860, type, fn_crassulacean_acid_metabolism_94: $i > $i).
% 28.89/28.96  tff(decl_16861, type, fn_crassulacean_acid_metabolism_84: $i > $i).
% 28.89/28.96  tff(decl_16862, type, fn_crassulacean_acid_metabolism_134: $i > $i).
% 28.89/28.96  tff(decl_16863, type, fn_plant_metabolic_cell_7: $i > $i).
% 28.89/28.96  tff(decl_16864, type, fn_crassulacean_acid_metabolism_161: $i > $i).
% 28.89/28.96  tff(decl_16865, type, fn_crassulacean_acid_metabolism_106: $i > $i).
% 28.89/28.96  tff(decl_16866, type, fn_crassulacean_acid_metabolism_143: $i > $i).
% 28.89/28.96  tff(decl_16867, type, fn_parenchyma_cell_11: $i > $i).
% 28.89/28.96  tff(decl_16868, type, fn_crassulacean_acid_metabolism_114: $i > $i).
% 28.89/28.96  tff(decl_16869, type, fn_crassulacean_acid_metabolism_118: $i > $i).
% 28.89/28.96  tff(decl_16870, type, fn_crassulacean_acid_metabolism_88: $i > $i).
% 28.89/28.96  tff(decl_16871, type, fn_crassulacean_acid_metabolism_70: $i > $i).
% 28.89/28.96  tff(decl_16872, type, fn_crassulacean_acid_metabolism_119: $i > $i).
% 28.89/28.96  tff(decl_16873, type, fn_crassulacean_acid_metabolism_115: $i > $i).
% 28.89/28.96  tff(decl_16874, type, fn_crassulacean_acid_metabolism_120: $i > $i).
% 28.89/28.96  tff(decl_16875, type, fn_plant_29: $i > $i).
% 28.89/28.96  tff(decl_16876, type, fn_plant_7: $i > $i).
% 28.89/28.96  tff(decl_16877, type, fn_cam_plant_133: $i > $i).
% 28.89/28.96  tff(decl_16878, type, fn_cam_plant_134: $i > $i).
% 28.89/28.96  tff(decl_16879, type, fn_cam_plant_63: $i > $i).
% 28.89/28.96  tff(decl_16880, type, fn_cam_plant_61: $i > $i).
% 28.89/28.96  tff(decl_16881, type, fn_cam_plant_64: $i > $i).
% 28.89/28.96  tff(decl_16882, type, fn_cam_plant_73: $i > $i).
% 28.89/28.96  tff(decl_16883, type, fn_cam_plant_16: $i > $i).
% 28.89/28.96  tff(decl_16884, type, fn_cam_plant_72: $i > $i).
% 28.89/28.96  tff(decl_16885, type, fn_cam_plant_62: $i > $i).
% 28.89/28.96  tff(decl_16886, type, fn_cam_plant_18: $i > $i).
% 28.89/28.96  tff(decl_16887, type, fn_cam_plant_19: $i > $i).
% 28.89/28.96  tff(decl_16888, type, fn_cam_plant_17: $i > $i).
% 28.89/28.96  tff(decl_16889, type, fn_plant_32: $i > $i).
% 28.89/28.96  tff(decl_16890, type, fn_cam_plant_75: $i > $i).
% 28.89/28.96  tff(decl_16891, type, fn_cam_plant_10: $i > $i).
% 28.89/28.96  tff(decl_16892, type, fn_vascular_plant_1: $i > $i).
% 28.89/28.96  tff(decl_16893, type, fn_cam_plant_11: $i > $i).
% 28.89/28.96  tff(decl_16894, type, fn_vascular_plant_7: $i > $i).
% 28.89/28.96  tff(decl_16895, type, fn_cam_plant_74: $i > $i).
% 28.89/28.96  tff(decl_16896, type, fn_vascular_plant_8: $i > $i).
% 28.89/28.96  tff(decl_16897, type, fn_vascular_plant_2: $i > $i).
% 28.89/28.96  tff(decl_16898, type, fn_vascular_plant_11: $i > $i).
% 28.89/28.96  tff(decl_16899, type, fn_cam_plant_21: $i > $i).
% 28.89/28.96  tff(decl_16900, type, fn_plant_35: $i > $i).
% 28.89/28.96  tff(decl_16901, type, fn_cam_plant_20: $i > $i).
% 28.89/28.96  tff(decl_16902, type, cambium_1: $i > $o).
% 28.89/28.96  tff(decl_16903, type, 'Cambium': $i).
% 28.89/28.96  tff(decl_16904, type, 'Plant tissue layer which provides undifferentiated cells for growth.': $i).
% 28.89/28.96  tff(decl_16905, type, cambium: $i).
% 28.89/28.96  tff(decl_16906, type, camp_receptor_protein_1: $i > $o).
% 28.89/28.96  tff(decl_16907, type, 'CAMP-Receptor-Protein': $i).
% 28.89/28.96  tff(decl_16908, type, 'cAMP receptor protein is is a regulatory protein that binds cAMP, which causes a conformational change that allows the protein to bind tightly to a specific DNA sequence in the promoters of the genes it controls.': $i).
% 28.89/28.96  tff(decl_16909, type, crp: $i).
% 28.89/28.96  tff(decl_16910, type, 'camp receptor protein': $i).
% 28.89/28.96  tff(decl_16911, type, 'camp-receptor-protein': $i).
% 28.89/28.96  tff(decl_16912, type, regulatory_protein_1: $i > $o).
% 28.89/28.96  tff(decl_16913, type, cytokine_1: $i > $o).
% 28.89/28.96  tff(decl_16914, type, interferon_1: $i > $o).
% 28.89/28.96  tff(decl_16915, type, mpf_1: $i > $o).
% 28.89/28.96  tff(decl_16916, type, tropomyosin_1: $i > $o).
% 28.89/28.96  tff(decl_16917, type, ubiquitin_1: $i > $o).
% 28.89/28.96  tff(decl_16918, type, fn_camp_receptor_protein_1: $i > $i).
% 28.89/28.96  tff(decl_16919, type, transcription_elongation_1: $i > $o).
% 28.89/28.96  tff(decl_16920, type, fn_camp_receptor_protein_2: $i > $i).
% 28.89/28.96  tff(decl_16921, type, fn_camp_receptor_protein_3: $i > $i).
% 28.89/28.96  tff(decl_16922, type, fn_camp_receptor_protein_4: $i > $i).
% 28.89/28.96  tff(decl_16923, type, fn_camp_receptor_protein_5: $i > $i).
% 28.89/28.96  tff(decl_16924, type, lac_operon_1: $i > $o).
% 28.89/28.96  tff(decl_16925, type, fn_camp_receptor_protein_6: $i > $i).
% 28.89/28.96  tff(decl_16926, type, fn_camp_receptor_protein_7: $i > $i).
% 28.89/28.96  tff(decl_16927, type, fn_camp_receptor_protein_8: $i > $i).
% 28.89/28.96  tff(decl_16928, type, fn_camp_receptor_protein_9: $i > $i).
% 28.89/28.96  tff(decl_16929, type, fn_camp_receptor_protein_10: $i > $i).
% 28.89/28.96  tff(decl_16930, type, fn_camp_receptor_protein_11: $i > $i).
% 28.89/28.96  tff(decl_16931, type, fn_camp_receptor_protein_12: $i > $i).
% 28.89/28.96  tff(decl_16932, type, fn_camp_receptor_protein_13: $i > $i).
% 28.89/28.96  tff(decl_16933, type, fn_lac_operon_10: $i > $i).
% 28.89/28.96  tff(decl_16934, type, camp_receptor_protein_with_cyclic_amp_1: $i > $o).
% 28.89/28.96  tff(decl_16935, type, 'CAMP-Receptor-Protein-With-Cyclic-AMP': $i).
% 28.89/28.96  tff(decl_16936, type, 'The event during whiich cAMP is bound.  When cAMP binds to the alloseric site on cAMP receptor protein, the protein assumes its active shape and can bind to a specific site at the upstream end of the lac promoter.': $i).
% 28.89/28.96  tff(decl_16937, type, 'camp receptor protein with cyclic amp': $i).
% 28.89/28.96  tff(decl_16938, type, 'camp-receptor-protein-with-cyclic-amp': $i).
% 28.89/28.96  tff(decl_16939, type, positive_gene_regulation_1: $i > $o).
% 28.89/28.96  tff(decl_16940, type, fn_camp_receptor_protein_with_cyclic_amp_1: $i > $i).
% 28.89/28.96  tff(decl_16941, type, fn_camp_receptor_protein_with_cyclic_amp_2: $i > $i).
% 28.89/28.96  tff(decl_16942, type, fn_camp_receptor_protein_with_cyclic_amp_3: $i > $i).
% 28.89/28.96  tff(decl_16943, type, fn_camp_receptor_protein_with_cyclic_amp_4: $i > $i).
% 28.89/28.96  tff(decl_16944, type, fn_camp_receptor_protein_with_cyclic_amp_6: $i > $i).
% 28.89/28.96  tff(decl_16945, type, fn_camp_receptor_protein_with_cyclic_amp_8: $i > $i).
% 28.89/28.96  tff(decl_16946, type, fn_camp_receptor_protein_with_cyclic_amp_9: $i > $i).
% 28.89/28.96  tff(decl_16947, type, fn_camp_receptor_protein_with_cyclic_amp_11: $i > $i).
% 28.89/28.96  tff(decl_16948, type, fn_camp_receptor_protein_with_cyclic_amp_12: $i > $i).
% 28.89/28.96  tff(decl_16949, type, fn_camp_receptor_protein_with_cyclic_amp_13: $i > $i).
% 28.89/28.96  tff(decl_16950, type, fn_camp_receptor_protein_with_cyclic_amp_14: $i > $i).
% 28.89/28.96  tff(decl_16951, type, fn_camp_receptor_protein_with_cyclic_amp_15: $i > $i).
% 28.89/28.96  tff(decl_16952, type, fn_camp_receptor_protein_with_cyclic_amp_16: $i > $i).
% 28.89/28.96  tff(decl_16953, type, cyclic_amp_1: $i > $o).
% 28.89/28.96  tff(decl_16954, type, fn_camp_receptor_protein_with_cyclic_amp_17: $i > $i).
% 28.89/28.96  tff(decl_16955, type, fn_camp_receptor_protein_with_cyclic_amp_18: $i > $i).
% 28.89/28.96  tff(decl_16956, type, promoter_1: $i > $o).
% 28.89/28.96  tff(decl_16957, type, fn_camp_receptor_protein_with_cyclic_amp_19: $i > $i).
% 28.89/28.96  tff(decl_16958, type, fn_camp_receptor_protein_with_cyclic_amp_20: $i > $i).
% 28.89/28.96  tff(decl_16959, type, fn_camp_receptor_protein_with_cyclic_amp_21: $i > $i).
% 28.89/28.96  tff(decl_16960, type, fn_camp_receptor_protein_with_cyclic_amp_22: $i > $i).
% 28.89/28.96  tff(decl_16961, type, fn_camp_receptor_protein_with_cyclic_amp_23: $i > $i).
% 28.89/28.96  tff(decl_16962, type, fn_camp_receptor_protein_with_cyclic_amp_24: $i > $i).
% 28.89/28.96  tff(decl_16963, type, fn_fold_1: $i > $i).
% 28.89/28.96  tff(decl_16964, type, fn_cyclic_amp_92: $i > $i).
% 28.89/28.96  tff(decl_16965, type, fn_operon_5: $i > $i).
% 28.89/28.96  tff(decl_16966, type, fn_cyclic_amp_94: $i > $i).
% 28.89/28.96  tff(decl_16967, type, fn_cyclic_amp_93: $i > $i).
% 28.89/28.96  tff(decl_16968, type, lactose_0: $i).
% 28.89/28.96  tff(decl_16969, type, cyclic_amp_0: $i).
% 28.89/28.96  tff(decl_16970, type, glucose_0: $i).
% 28.89/28.96  tff(decl_16971, type, fn_positive_gene_regulation_3: $i > $i).
% 28.89/28.96  tff(decl_16972, type, fn_gene_regulation_1: $i > $i).
% 28.89/28.96  tff(decl_16973, type, fn_gene_regulation_2: $i > $i).
% 28.89/28.96  tff(decl_16974, type, fn_gene_regulation_3: $i > $i).
% 28.89/28.96  tff(decl_16975, type, 'Canal': $i).
% 28.89/28.96  tff(decl_16976, type, 'Tubular passage or channel that connects different regions of the body.': $i).
% 28.89/28.96  tff(decl_16977, type, canal: $i).
% 28.89/28.96  tff(decl_16978, type, canavanine_1: $i > $o).
% 28.89/28.96  tff(decl_16979, type, 'Canavanine': $i).
% 28.89/28.96  tff(decl_16980, type, 'An amino acid resembling arginine, used by plants as a defense chemical': $i).
% 28.89/28.96  tff(decl_16981, type, canavanine: $i).
% 28.89/28.96  tff(decl_16982, type, 'Cancer': $i).
% 28.89/28.96  tff(decl_16983, type, 'A disease condition involving the uncontrolled growth of abnormal cells in the body.': $i).
% 28.89/28.96  tff(decl_16984, type, 'uncontrolled cell growth': $i).
% 28.89/28.96  tff(decl_16985, type, 'uninhibited cell growth': $i).
% 28.89/28.96  tff(decl_16986, type, 'unregulated cell growth': $i).
% 28.89/28.96  tff(decl_16987, type, 'unrestricted cell division': $i).
% 28.89/28.96  tff(decl_16988, type, cancer: $i).
% 28.89/28.96  tff(decl_16989, type, disease_1: $i > $o).
% 28.89/28.96  tff(decl_16990, type, fn_cancer_1: $i > $i).
% 28.89/28.96  tff(decl_16991, type, cancer_cell_1: $i > $o).
% 28.89/28.96  tff(decl_16992, type, fn_cancer_2: $i > $i).
% 28.89/28.96  tff(decl_16993, type, fn_cancer_3: $i > $i).
% 28.89/28.96  tff(decl_16994, type, fn_cancer_4: $i > $i).
% 28.89/28.96  tff(decl_16995, type, fn_cancer_5: $i > $i).
% 28.89/28.96  tff(decl_16996, type, make_error_1: $i > $o).
% 28.89/28.96  tff(decl_16997, type, fn_cancer_6: $i > $i).
% 28.89/28.96  tff(decl_16998, type, cell_cycle_1: $i > $o).
% 28.89/28.96  tff(decl_16999, type, replication_0: $i).
% 28.89/28.96  tff(decl_17000, type, 'Cancer-Cell': $i).
% 28.89/28.96  tff(decl_17001, type, 'Abnormal cells that rapidly grow and divide without control and are able to invade other tissues and spread throughout the body.': $i).
% 28.89/28.96  tff(decl_17002, type, 'cell of cancer': $i).
% 28.89/28.96  tff(decl_17003, type, 'cancer cell': $i).
% 28.89/28.96  tff(decl_17004, type, 'cancer-cell': $i).
% 28.89/28.96  tff(decl_17005, type, cell_state_1: $i > $o).
% 28.89/28.96  tff(decl_17006, type, fn_cancer_cell_1: $i > $i).
% 28.89/28.96  tff(decl_17007, type, fn_cancer_cell_4: $i > $i).
% 28.89/28.96  tff(decl_17008, type, fn_cancer_cell_5: $i > $i).
% 28.89/28.96  tff(decl_17009, type, fn_cancer_cell_6: $i > $i).
% 28.89/28.96  tff(decl_17010, type, fn_cancer_cell_7: $i > $i).
% 28.89/28.96  tff(decl_17011, type, fn_cancer_cell_8: $i > $i).
% 28.89/28.96  tff(decl_17012, type, fn_cancer_cell_9: $i > $i).
% 28.89/28.96  tff(decl_17013, type, fn_cancer_cell_10: $i > $i).
% 28.89/28.96  tff(decl_17014, type, fn_cancer_cell_11: $i > $i).
% 28.89/28.96  tff(decl_17015, type, fn_cancer_cell_12: $i > $i).
% 28.89/28.96  tff(decl_17016, type, fn_cancer_cell_13: $i > $i).
% 28.89/28.96  tff(decl_17017, type, fn_cancer_cell_14: $i > $i).
% 28.89/28.96  tff(decl_17018, type, translocation_during_translation_1: $i > $o).
% 28.89/28.96  tff(decl_17019, type, fn_cancer_cell_15: $i > $i).
% 28.89/28.96  tff(decl_17020, type, oncogene_1: $i > $o).
% 28.89/28.96  tff(decl_17021, type, fn_cancer_cell_16: $i > $i).
% 28.89/28.96  tff(decl_17022, type, tumor_suppressor_gene_1: $i > $o).
% 28.89/28.96  tff(decl_17023, type, fn_cancer_cell_17: $i > $i).
% 28.89/28.96  tff(decl_17024, type, fn_cancer_cell_18: $i > $i).
% 28.89/28.96  tff(decl_17025, type, fn_cancer_cell_19: $i > $i).
% 28.89/28.96  tff(decl_17026, type, fn_cancer_cell_20: $i > $i).
% 28.89/28.96  tff(decl_17027, type, fn_cancer_cell_21: $i > $i).
% 28.89/28.96  tff(decl_17028, type, fn_cancer_cell_22: $i > $i).
% 28.89/28.96  tff(decl_17029, type, fn_cancer_cell_23: $i > $i).
% 28.89/28.96  tff(decl_17030, type, fn_cancer_cell_24: $i > $i).
% 28.89/28.96  tff(decl_17031, type, fn_cancer_cell_25: $i > $i).
% 28.89/28.96  tff(decl_17032, type, fn_cancer_cell_26: $i > $i).
% 28.89/28.96  tff(decl_17033, type, fn_cancer_cell_27: $i > $i).
% 28.89/28.96  tff(decl_17034, type, somatic_cell_1: $i > $o).
% 28.89/28.96  tff(decl_17035, type, fn_oncogene_8: $i > $i).
% 28.89/28.96  tff(decl_17036, type, fn_oncogene_18: $i > $i).
% 28.89/28.96  tff(decl_17037, type, fn_chromosome_5: $i > $i).
% 28.89/28.96  tff(decl_17038, type, fn_dna_strand_14: $i > $i).
% 28.89/28.96  tff(decl_17039, type, oncogene_0: $i).
% 28.89/28.96  tff(decl_17040, type, fn_cancer_cell_3: $i > $i).
% 28.89/28.96  tff(decl_17041, type, fn_cancer_cell_2: $i > $i).
% 28.89/28.96  tff(decl_17042, type, cancer_cell_gene_amplification_1: $i > $o).
% 28.89/28.96  tff(decl_17043, type, 'Cancer-Cell-Gene-Amplification': $i).
% 28.89/28.96  tff(decl_17044, type, 'A genetic change increasing the number of copies of the proto-oncogene in the cell through repeated gene duplication.': $i).
% 28.89/28.96  tff(decl_17045, type, 'protogene amplification': $i).
% 28.89/28.96  tff(decl_17046, type, 'cancer gene amplification': $i).
% 28.89/28.96  tff(decl_17047, type, 'cancer cell gene amplification': $i).
% 28.89/28.96  tff(decl_17048, type, 'cancer-cell-gene-amplification': $i).
% 28.89/28.96  tff(decl_17049, type, rrna_gene_amplification_1: $i > $o).
% 28.89/28.96  tff(decl_17050, type, fn_cancer_cell_gene_amplification_1: $i > $i).
% 28.89/28.96  tff(decl_17051, type, fn_cancer_cell_gene_amplification_2: $i > $i).
% 28.89/28.96  tff(decl_17052, type, fn_cancer_cell_gene_amplification_3: $i > $i).
% 28.89/28.96  tff(decl_17053, type, fn_cancer_cell_gene_amplification_4: $i > $i).
% 28.89/28.96  tff(decl_17054, type, fn_chemotherapeutic_drug_4: $i > $i).
% 28.89/28.96  tff(decl_17055, type, fn_chemotherapeutic_drug_3: $i > $i).
% 28.89/28.96  tff(decl_17056, type, fn_gene_amplification_4: $i > $i).
% 28.89/28.96  tff(decl_17057, type, fn_gene_amplification_2: $i > $i).
% 28.89/28.96  tff(decl_17058, type, canine_tooth_1: $i > $o).
% 28.89/28.96  tff(decl_17059, type, 'Canine-Tooth': $i).
% 28.89/28.96  tff(decl_17060, type, 'Relatively long, pointed tooth, located near the front of the mouth, specialized for holding, piercing  and tearing food.': $i).
% 28.89/28.96  tff(decl_17061, type, 'tooth of canine': $i).
% 28.89/28.96  tff(decl_17062, type, 'canine tooth': $i).
% 28.89/28.96  tff(decl_17063, type, 'canine-tooth': $i).
% 28.89/28.96  tff(decl_17064, type, tooth_1: $i > $o).
% 28.89/28.96  tff(decl_17065, type, fn_canine_tooth_1: $i > $i).
% 28.89/28.96  tff(decl_17066, type, fn_canine_tooth_3: $i > $i).
% 28.89/28.96  tff(decl_17067, type, food_1: $i > $o).
% 28.89/28.96  tff(decl_17068, type, fn_canine_tooth_4: $i > $i).
% 28.89/28.96  tff(decl_17069, type, fn_canine_tooth_5: $i > $i).
% 28.89/28.96  tff(decl_17070, type, shear_1: $i > $o).
% 28.89/28.96  tff(decl_17071, type, fn_food_3: $i > $i).
% 28.89/28.96  tff(decl_17072, type, canopy_1: $i > $o).
% 28.89/28.96  tff(decl_17073, type, 'Canopy': $i).
% 28.89/28.96  tff(decl_17074, type, 'The topmost layers of vegetation in a biome.': $i).
% 28.89/28.96  tff(decl_17075, type, canopy: $i).
% 28.89/28.96  tff(decl_17076, type, 'Capacity-Constant': $i).
% 28.89/28.96  tff(decl_17077, type, 'constant of capacity': $i).
% 28.89/28.96  tff(decl_17078, type, 'capacity constant': $i).
% 28.89/28.96  tff(decl_17079, type, 'capacity-constant': $i).
% 28.89/28.96  tff(decl_17080, type, capacity_scale_1: $i > $o).
% 28.89/28.96  tff(decl_17081, type, 'Capacity-Scale': $i).
% 28.89/28.96  tff(decl_17082, type, 'scale of capacity': $i).
% 28.89/28.96  tff(decl_17083, type, 'capacity scale': $i).
% 28.89/28.96  tff(decl_17084, type, 'capacity-scale': $i).
% 28.89/28.96  tff(decl_17085, type, 'Capacity-Value': $i).
% 28.89/28.96  tff(decl_17086, type, 'the capacity (potential for storing or accomodating) of a Tangible-Entity': $i).
% 28.89/28.96  tff(decl_17087, type, capacity: $i).
% 28.89/28.96  tff(decl_17088, type, 'value of capacity': $i).
% 28.89/28.96  tff(decl_17089, type, 'capacity value': $i).
% 28.89/28.96  tff(decl_17090, type, 'capacity-value': $i).
% 28.89/28.96  tff(decl_17091, type, 'Capillary': $i).
% 28.89/28.96  tff(decl_17092, type, 'The smallest blood vessel in the body, consisting of a single layer of epithelial cells. Capillaries enable the exchange of respiratory gases between body tissues and the blood stream.': $i).
% 28.89/28.96  tff(decl_17093, type, capillary: $i).
% 28.89/28.96  tff(decl_17094, type, fn_capillary_1: $i > $i).
% 28.89/28.96  tff(decl_17095, type, fn_capillary_3: $i > $i).
% 28.89/28.96  tff(decl_17096, type, fn_capillary_4: $i > $i).
% 28.89/28.96  tff(decl_17097, type, fn_capillary_5: $i > $i).
% 28.89/28.96  tff(decl_17098, type, fn_capillary_6: $i > $i).
% 28.89/28.96  tff(decl_17099, type, blood_vessel_0: $i).
% 28.89/28.96  tff(decl_17100, type, 'Capillary-Action': $i).
% 28.89/28.96  tff(decl_17101, type, 'The movement of a liquid along the surface of a solid caused by the attraction of molecules of the liquid to the molecules of the solid.': $i).
% 28.89/28.96  tff(decl_17102, type, 'action of capillary': $i).
% 28.89/28.96  tff(decl_17103, type, 'capillary action': $i).
% 28.89/28.96  tff(decl_17104, type, 'capillary-action': $i).
% 28.89/28.96  tff(decl_17105, type, load_1: $i > $o).
% 28.89/28.96  tff(decl_17106, type, implant_1: $i > $o).
% 28.89/28.96  tff(decl_17107, type, package_recombinants_in_capsid_1: $i > $o).
% 28.89/28.96  tff(decl_17108, type, capillary_bed_1: $i > $o).
% 28.89/28.96  tff(decl_17109, type, 'Capillary-Bed': $i).
% 28.89/28.96  tff(decl_17110, type, 'A reticulated system of capillaries surrounding a tissue or organ.': $i).
% 28.89/28.96  tff(decl_17111, type, 'bed of capillary': $i).
% 28.89/28.96  tff(decl_17112, type, 'capillary bed': $i).
% 28.89/28.96  tff(decl_17113, type, 'capillary-bed': $i).
% 28.89/28.96  tff(decl_17114, type, capillary_exchange_1: $i > $o).
% 28.89/28.96  tff(decl_17115, type, 'Capillary-Exchange': $i).
% 28.89/28.96  tff(decl_17116, type, 'Exchange between capillaries and interstitial fluid.': $i).
% 28.89/28.96  tff(decl_17117, type, 'exchange of capillary': $i).
% 28.89/28.96  tff(decl_17118, type, 'capillary exchange': $i).
% 28.89/28.96  tff(decl_17119, type, 'capillary-exchange': $i).
% 28.89/28.96  tff(decl_17120, type, cardiovascular_related_intercellular_process_1: $i > $o).
% 28.89/28.96  tff(decl_17121, type, capsid_1: $i > $o).
% 28.89/28.96  tff(decl_17122, type, 'Capsid': $i).
% 28.89/28.96  tff(decl_17123, type, 'The protein shell that encloses a viral genome. It may be rod-shaped, polyhedral, or more complex in shape.': $i).
% 28.89/28.96  tff(decl_17124, type, capsid: $i).
% 28.89/28.96  tff(decl_17125, type, coat_protein_1: $i > $o).
% 28.89/28.96  tff(decl_17126, type, fn_capsid_1: $i > $i).
% 28.89/28.96  tff(decl_17127, type, 'Capsomere': $i).
% 28.89/28.96  tff(decl_17128, type, 'The subunit of a capsid, which is the protein covering that protects the genetic material of a virus.': $i).
% 28.89/28.96  tff(decl_17129, type, capsomere: $i).
% 28.89/28.96  tff(decl_17130, type, capsule_1: $i > $o).
% 28.89/28.96  tff(decl_17131, type, 'Capsule': $i).
% 28.89/28.96  tff(decl_17132, type, 'Capsule is a layer present outside the cell wall of some prokaryotes.  Its primary function is to protect the cell.': $i).
% 28.89/28.96  tff(decl_17133, type, 'bacterial capsule': $i).
% 28.89/28.96  tff(decl_17134, type, 'prokaryote capsule': $i).
% 28.89/28.96  tff(decl_17135, type, 'cell capsule': $i).
% 28.89/28.96  tff(decl_17136, type, fn_capsule_1: $i > $i).
% 28.89/28.96  tff(decl_17137, type, fn_capsule_2: $i > $i).
% 28.89/28.96  tff(decl_17138, type, fn_capsule_3: $i > $i).
% 28.89/28.96  tff(decl_17139, type, fn_capsule_4: $i > $i).
% 28.89/28.96  tff(decl_17140, type, fn_capsule_5: $i > $i).
% 28.89/28.96  tff(decl_17141, type, fn_capsule_6: $i > $i).
% 28.89/28.96  tff(decl_17142, type, fn_capsule_7: $i > $i).
% 28.89/28.96  tff(decl_17143, type, fn_capsule_8: $i > $i).
% 28.89/28.96  tff(decl_17144, type, fn_capsule_9: $i > $i).
% 28.89/28.96  tff(decl_17145, type, fn_capsule_10: $i > $i).
% 28.89/28.96  tff(decl_17146, type, fn_capsule_11: $i > $i).
% 28.89/28.96  tff(decl_17147, type, fn_capsule_12: $i > $i).
% 28.89/28.96  tff(decl_17148, type, fn_capsule_13: $i > $i).
% 28.89/28.96  tff(decl_17149, type, fn_capsule_14: $i > $i).
% 28.89/28.96  tff(decl_17150, type, fn_capsule_15: $i > $i).
% 28.89/28.96  tff(decl_17151, type, fn_capsule_16: $i > $i).
% 28.89/28.96  tff(decl_17152, type, fn_capsule_17: $i > $i).
% 28.89/28.96  tff(decl_17153, type, fn_prokaryote_1: $i > $i).
% 28.89/28.96  tff(decl_17154, type, fn_prokaryote_15: $i > $i).
% 28.89/28.96  tff(decl_17155, type, fn_prokaryote_17: $i > $i).
% 28.89/28.96  tff(decl_17156, type, fn_prokaryote_7: $i > $i).
% 28.89/28.96  tff(decl_17157, type, fn_prokaryote_6: $i > $i).
% 28.89/28.96  tff(decl_17158, type, 'Carbohydrate': $i).
% 28.89/28.96  tff(decl_17159, type, 'A class of organic molecules that consists of carbon, hydrogen, and oxygen. Simple sugars are the monomers for more complex carbohydrates such as disaccharides and polysaccharides. Carbohydrates have structural, energy-source, and energy-storage functions in cells.': $i).
% 28.89/28.96  tff(decl_17160, type, carbohydrate: $i).
% 28.89/28.96  tff(decl_17161, type, fn_carbohydrate_2: $i > $i).
% 28.89/28.96  tff(decl_17162, type, fn_carbohydrate_3: $i > $i).
% 28.89/28.96  tff(decl_17163, type, fn_carbohydrate_4: $i > $i).
% 28.89/28.96  tff(decl_17164, type, fn_carbohydrate_7: $i > $i).
% 28.89/28.96  tff(decl_17165, type, fn_carbohydrate_8: $i > $i).
% 28.89/28.96  tff(decl_17166, type, fn_carbohydrate_9: $i > $i).
% 28.89/28.96  tff(decl_17167, type, fn_carbohydrate_10: $i > $i).
% 28.89/28.96  tff(decl_17168, type, fn_carbohydrate_11: $i > $i).
% 28.89/28.96  tff(decl_17169, type, fn_carbohydrate_12: $i > $i).
% 28.89/28.96  tff(decl_17170, type, fn_carbohydrate_13: $i > $i).
% 28.89/28.96  tff(decl_17171, type, fn_carbohydrate_14: $i > $i).
% 28.89/28.96  tff(decl_17172, type, fn_carbohydrate_15: $i > $i).
% 28.89/28.96  tff(decl_17173, type, fn_carbohydrate_16: $i > $i).
% 28.89/28.96  tff(decl_17174, type, fn_carbohydrate_17: $i > $i).
% 28.89/28.96  tff(decl_17175, type, fn_carbohydrate_18: $i > $i).
% 28.89/28.96  tff(decl_17176, type, fn_carbohydrate_19: $i > $i).
% 28.89/28.96  tff(decl_17177, type, fn_carbohydrate_20: $i > $i).
% 28.89/28.96  tff(decl_17178, type, fn_carbohydrate_21: $i > $i).
% 28.89/28.96  tff(decl_17179, type, fn_carbohydrate_22: $i > $i).
% 28.89/28.96  tff(decl_17180, type, fn_carbohydrate_23: $i > $i).
% 28.89/28.96  tff(decl_17181, type, fn_carbohydrate_24: $i > $i).
% 28.89/28.96  tff(decl_17182, type, fn_carbohydrate_25: $i > $i).
% 28.89/28.96  tff(decl_17183, type, fn_carbohydrate_26: $i > $i).
% 28.89/28.96  tff(decl_17184, type, fn_carbohydrate_27: $i > $i).
% 28.89/28.96  tff(decl_17185, type, fn_carbohydrate_28: $i > $i).
% 28.89/28.96  tff(decl_17186, type, fn_carbohydrate_40: $i > $i).
% 28.89/28.96  tff(decl_17187, type, fn_carbohydrate_41: $i > $i).
% 28.89/28.96  tff(decl_17188, type, fn_polar_covalent_bond_22: $i > $i).
% 28.89/28.96  tff(decl_17189, type, fn_polar_covalent_bond_4: $i > $i).
% 28.89/28.96  tff(decl_17190, type, fn_hydroxyl_group_11: $i > $i).
% 28.89/28.96  tff(decl_17191, type, fn_polar_covalent_bond_23: $i > $i).
% 28.89/28.96  tff(decl_17192, type, fn_hydrogen_1: $i > $i).
% 28.89/28.96  tff(decl_17193, type, fn_polar_covalent_bond_5: $i > $i).
% 28.89/28.96  tff(decl_17194, type, fn_hydroxyl_group_10: $i > $i).
% 28.89/28.96  tff(decl_17195, type, fn_hydroxyl_group_9: $i > $i).
% 28.89/28.96  tff(decl_17196, type, fn_polar_covalent_bond_14: $i > $i).
% 28.89/28.96  tff(decl_17197, type, fn_carbon_skeleton_1: $i > $i).
% 28.89/28.96  tff(decl_17198, type, fn_hydrogen_2: $i > $i).
% 28.89/28.96  tff(decl_17199, type, fn_polar_covalent_bond_21: $i > $i).
% 28.89/28.96  tff(decl_17200, type, fn_polar_covalent_bond_13: $i > $i).
% 28.89/28.96  tff(decl_17201, type, fn_carbohydrate_45: $i > $i).
% 28.89/28.96  tff(decl_17202, type, fn_carbohydrate_44: $i > $i).
% 28.89/28.96  tff(decl_17203, type, fn_carbohydrate_42: $i > $i).
% 28.89/28.96  tff(decl_17204, type, fn_carbohydrate_43: $i > $i).
% 28.89/28.96  tff(decl_17205, type, 'Carbohydrate-Side-Chain': $i).
% 28.89/28.96  tff(decl_17206, type, 'Carbohydrate side chain is a chain of carbohydrate attached to an entity. They are basically oligosaccharides.': $i).
% 28.89/28.96  tff(decl_17207, type, 'carbohydrate side chain': $i).
% 28.89/28.96  tff(decl_17208, type, 'carbohydrate-side-chain': $i).
% 28.89/28.96  tff(decl_17209, type, fn_carbohydrate_side_chain_1: $i > $i).
% 28.89/28.96  tff(decl_17210, type, fn_carbohydrate_side_chain_2: $i > $i).
% 28.89/28.96  tff(decl_17211, type, fn_carbohydrate_side_chain_4: $i > $i).
% 28.89/28.96  tff(decl_17212, type, fn_carbohydrate_side_chain_9: $i > $i).
% 28.89/28.96  tff(decl_17213, type, fn_carbohydrate_side_chain_10: $i > $i).
% 28.89/28.96  tff(decl_17214, type, fn_carbohydrate_side_chain_11: $i > $i).
% 28.89/28.96  tff(decl_17215, type, fn_carbohydrate_side_chain_13: $i > $i).
% 28.89/28.96  tff(decl_17216, type, fn_carbohydrate_side_chain_14: $i > $i).
% 28.89/28.96  tff(decl_17217, type, fn_carbohydrate_side_chain_16: $i > $i).
% 28.89/28.96  tff(decl_17218, type, fn_carbohydrate_side_chain_17: $i > $i).
% 28.89/28.96  tff(decl_17219, type, fn_carbohydrate_side_chain_18: $i > $i).
% 28.89/28.96  tff(decl_17220, type, fn_carbohydrate_side_chain_38: $i > $i).
% 28.89/28.96  tff(decl_17221, type, fn_carbohydrate_side_chain_39: $i > $i).
% 28.89/28.96  tff(decl_17222, type, fn_carbohydrate_side_chain_40: $i > $i).
% 28.89/28.96  tff(decl_17223, type, fn_carbohydrate_side_chain_41: $i > $i).
% 28.89/28.96  tff(decl_17224, type, fn_carbohydrate_side_chain_42: $i > $i).
% 28.89/28.96  tff(decl_17225, type, fn_carbohydrate_side_chain_43: $i > $i).
% 28.89/28.96  tff(decl_17226, type, fn_carbohydrate_side_chain_44: $i > $i).
% 28.89/28.96  tff(decl_17227, type, fn_carbohydrate_side_chain_45: $i > $i).
% 28.89/28.96  tff(decl_17228, type, fn_carbohydrate_side_chain_46: $i > $i).
% 28.89/28.96  tff(decl_17229, type, fn_carbohydrate_side_chain_47: $i > $i).
% 28.89/28.96  tff(decl_17230, type, fn_carbohydrate_side_chain_48: $i > $i).
% 28.89/28.96  tff(decl_17231, type, fn_carbohydrate_side_chain_49: $i > $i).
% 28.89/28.96  tff(decl_17232, type, fn_carbohydrate_side_chain_50: $i > $i).
% 28.89/28.96  tff(decl_17233, type, fn_carbohydrate_side_chain_51: $i > $i).
% 28.89/28.97  tff(decl_17234, type, fn_carbohydrate_side_chain_52: $i > $i).
% 28.89/28.97  tff(decl_17235, type, fn_carbohydrate_side_chain_53: $i > $i).
% 28.89/28.97  tff(decl_17236, type, fn_oxygen_6: $i > $i).
% 28.89/28.97  tff(decl_17237, type, fn_oxygen_12: $i > $i).
% 28.89/28.97  tff(decl_17238, type, fn_oxygen_19: $i > $i).
% 28.89/28.97  tff(decl_17239, type, fn_oxygen_20: $i > $i).
% 28.89/28.97  tff(decl_17240, type, fn_oxygen_10: $i > $i).
% 28.89/28.97  tff(decl_17241, type, fn_oxygen_21: $i > $i).
% 28.89/28.97  tff(decl_17242, type, fn_oxygen_14: $i > $i).
% 28.89/28.97  tff(decl_17243, type, fn_oxygen_17: $i > $i).
% 28.89/28.97  tff(decl_17244, type, fn_oxygen_18: $i > $i).
% 28.89/28.97  tff(decl_17245, type, fn_oxygen_11: $i > $i).
% 28.89/28.97  tff(decl_17246, type, fn_oxygen_9: $i > $i).
% 28.89/28.97  tff(decl_17247, type, fn_oxygen_1: $i > $i).
% 28.89/28.97  tff(decl_17248, type, fn_oxygen_8: $i > $i).
% 28.89/28.97  tff(decl_17249, type, fn_oxygen_7: $i > $i).
% 28.89/28.97  tff(decl_17250, type, fn_oxygen_13: $i > $i).
% 28.89/28.97  tff(decl_17251, type, fn_carbohydrate_side_chain_54: $i > $i).
% 28.89/28.97  tff(decl_17252, type, fn_carbohydrate_side_chain_55: $i > $i).
% 28.89/28.97  tff(decl_17253, type, fn_oligosaccharide_8: $i > $i).
% 28.89/28.97  tff(decl_17254, type, fn_oligosaccharide_7: $i > $i).
% 28.89/28.97  tff(decl_17255, type, fn_oligosaccharide_11: $i > $i).
% 28.89/28.97  tff(decl_17256, type, fn_oligosaccharide_12: $i > $i).
% 28.89/28.97  tff(decl_17257, type, fn_carbohydrate_side_chain_6: $i > $i).
% 28.89/28.97  tff(decl_17258, type, fn_carbohydrate_side_chain_7: $i > $i).
% 28.89/28.97  tff(decl_17259, type, fn_carbohydrate_side_chain_15: $i > $i).
% 28.89/28.97  tff(decl_17260, type, fn_carbohydrate_side_chain_5: $i > $i).
% 28.89/28.97  tff(decl_17261, type, fn_carbohydrate_side_chain_8: $i > $i).
% 28.89/28.97  tff(decl_17262, type, 'Carbon': $i).
% 28.89/28.97  tff(decl_17263, type, 'Carbon is a non metal atom with atomic number 6. It is represented by the symbol C.  It is tetravalent making four covalent chemical bonds.': $i).
% 28.89/28.97  tff(decl_17264, type, 'C': $i).
% 28.89/28.97  tff(decl_17265, type, carbon: $i).
% 28.89/28.97  tff(decl_17266, type, fn_carbon_3: $i > $i).
% 28.89/28.97  tff(decl_17267, type, fn_carbon_4: $i > $i).
% 28.89/28.97  tff(decl_17268, type, fn_carbon_5: $i > $i).
% 28.89/28.97  tff(decl_17269, type, fn_carbon_15: $i > $i).
% 28.89/28.97  tff(decl_17270, type, "4.0e0": $i).
% 28.89/28.97  tff(decl_17271, type, "12.01": $i).
% 28.89/28.97  tff(decl_17272, type, fn_carbon_14: $i > $i).
% 28.89/28.97  tff(decl_17273, type, fn_atom_2: $i > $i).
% 28.89/28.97  tff(decl_17274, type, carbon_12_1: $i > $o).
% 28.89/28.97  tff(decl_17275, type, 'Carbon-12': $i).
% 28.89/28.97  tff(decl_17276, type, 'Isotope of Carbon having 6 neutrons and 6 protons.': $i).
% 28.89/28.97  tff(decl_17277, type, 'c 12': $i).
% 28.89/28.97  tff(decl_17278, type, 'c-12': $i).
% 28.89/28.97  tff(decl_17279, type, '12 of carbon': $i).
% 28.89/28.97  tff(decl_17280, type, 'carbon 12': $i).
% 28.89/28.97  tff(decl_17281, type, 'carbon-12': $i).
% 28.89/28.97  tff(decl_17282, type, carbon_isotope_1: $i > $o).
% 28.89/28.97  tff(decl_17283, type, fn_carbon_12_2: $i > $i).
% 28.89/28.97  tff(decl_17284, type, fn_carbon_12_3: $i > $i).
% 28.89/28.97  tff(decl_17285, type, fn_carbon_12_10: $i > $i).
% 28.89/28.97  tff(decl_17286, type, fn_carbon_12_11: $i > $i).
% 28.89/28.97  tff(decl_17287, type, fn_carbon_12_12: $i > $i).
% 28.89/28.97  tff(decl_17288, type, fn_carbon_12_13: $i > $i).
% 28.89/28.97  tff(decl_17289, type, fn_carbon_12_15: $i > $i).
% 28.89/28.97  tff(decl_17290, type, fn_carbon_12_16: $i > $i).
% 28.89/28.97  tff(decl_17291, type, "12.0e0": $i).
% 28.89/28.97  tff(decl_17292, type, fn_carbon_12_9: $i > $i).
% 28.89/28.97  tff(decl_17293, type, fn_carbon_12_8: $i > $i).
% 28.89/28.97  tff(decl_17294, type, fn_carbon_12_6: $i > $i).
% 28.89/28.97  tff(decl_17295, type, fn_carbon_12_7: $i > $i).
% 28.89/28.97  tff(decl_17296, type, fn_carbon_12_5: $i > $i).
% 28.89/28.97  tff(decl_17297, type, fn_carbon_isotope_8: $i > $i).
% 28.89/28.97  tff(decl_17298, type, fn_carbon_12_14: $i > $i).
% 28.89/28.97  tff(decl_17299, type, carbon_13_1: $i > $o).
% 28.89/28.97  tff(decl_17300, type, 'Carbon-13': $i).
% 28.89/28.97  tff(decl_17301, type, 'Isotope of Carbon having 7 neutrons and 6 protons.': $i).
% 28.89/28.97  tff(decl_17302, type, '13 of carbon': $i).
% 28.89/28.97  tff(decl_17303, type, 'carbon 13': $i).
% 28.89/28.97  tff(decl_17304, type, 'carbon-13': $i).
% 28.89/28.97  tff(decl_17305, type, fn_carbon_13_1: $i > $i).
% 28.89/28.97  tff(decl_17306, type, fn_carbon_13_3: $i > $i).
% 28.89/28.97  tff(decl_17307, type, fn_carbon_13_10: $i > $i).
% 28.89/28.97  tff(decl_17308, type, fn_carbon_13_11: $i > $i).
% 28.89/28.97  tff(decl_17309, type, fn_carbon_13_12: $i > $i).
% 28.89/28.97  tff(decl_17310, type, fn_carbon_13_13: $i > $i).
% 28.89/28.97  tff(decl_17311, type, fn_carbon_13_14: $i > $i).
% 28.89/28.97  tff(decl_17312, type, fn_carbon_13_16: $i > $i).
% 28.89/28.97  tff(decl_17313, type, fn_carbon_13_17: $i > $i).
% 28.89/28.97  tff(decl_17314, type, "13.0e0": $i).
% 28.89/28.97  tff(decl_17315, type, "13.003e0": $i).
% 28.89/28.97  tff(decl_17316, type, fn_carbon_isotope_6: $i > $i).
% 28.89/28.97  tff(decl_17317, type, fn_carbon_13_9: $i > $i).
% 28.89/28.97  tff(decl_17318, type, fn_carbon_13_8: $i > $i).
% 28.89/28.97  tff(decl_17319, type, fn_carbon_13_6: $i > $i).
% 28.89/28.97  tff(decl_17320, type, fn_carbon_13_7: $i > $i).
% 28.89/28.97  tff(decl_17321, type, fn_carbon_13_5: $i > $i).
% 28.89/28.97  tff(decl_17322, type, fn_carbon_13_15: $i > $i).
% 28.89/28.97  tff(decl_17323, type, carbon_14_1: $i > $o).
% 28.89/28.97  tff(decl_17324, type, 'Carbon-14': $i).
% 28.89/28.97  tff(decl_17325, type, 'Isotope of Carbon having 8 neutrons and 6 protons.': $i).
% 28.89/28.97  tff(decl_17326, type, 'c 14': $i).
% 28.89/28.97  tff(decl_17327, type, 'c-14': $i).
% 28.89/28.97  tff(decl_17328, type, '14 of carbon': $i).
% 28.89/28.97  tff(decl_17329, type, 'carbon 14': $i).
% 28.89/28.97  tff(decl_17330, type, 'carbon-14': $i).
% 28.89/28.97  tff(decl_17331, type, radioactive_isotope_1: $i > $o).
% 28.89/28.97  tff(decl_17332, type, fn_carbon_14_2: $i > $i).
% 28.89/28.97  tff(decl_17333, type, fn_carbon_14_3: $i > $i).
% 28.89/28.97  tff(decl_17334, type, fn_carbon_14_4: $i > $i).
% 28.89/28.97  tff(decl_17335, type, fn_carbon_14_11: $i > $i).
% 28.89/28.97  tff(decl_17336, type, fn_carbon_14_12: $i > $i).
% 28.89/28.97  tff(decl_17337, type, fn_carbon_14_13: $i > $i).
% 28.89/28.97  tff(decl_17338, type, fn_carbon_14_15: $i > $i).
% 28.89/28.97  tff(decl_17339, type, fn_carbon_14_16: $i > $i).
% 28.89/28.97  tff(decl_17340, type, fn_carbon_14_17: $i > $i).
% 28.89/28.97  tff(decl_17341, type, fn_carbon_14_18: $i > $i).
% 28.89/28.97  tff(decl_17342, type, radioactivity_1: $i > $o).
% 28.89/28.97  tff(decl_17343, type, fn_carbon_14_19: $i > $i).
% 28.89/28.97  tff(decl_17344, type, fn_carbon_14_20: $i > $i).
% 28.89/28.97  tff(decl_17345, type, fn_carbon_14_21: $i > $i).
% 28.89/28.97  tff(decl_17346, type, fn_carbon_14_22: $i > $i).
% 28.89/28.97  tff(decl_17347, type, "14.0e0": $i).
% 28.89/28.97  tff(decl_17348, type, "14.003e0": $i).
% 28.89/28.97  tff(decl_17349, type, fn_radioactive_isotope_3: $i > $i).
% 28.89/28.97  tff(decl_17350, type, fn_carbon_14_8: $i > $i).
% 28.89/28.97  tff(decl_17351, type, fn_carbon_14_9: $i > $i).
% 28.89/28.97  tff(decl_17352, type, fn_carbon_14_7: $i > $i).
% 28.89/28.97  tff(decl_17353, type, fn_carbon_14_10: $i > $i).
% 28.89/28.97  tff(decl_17354, type, fn_carbon_14_6: $i > $i).
% 28.89/28.97  tff(decl_17355, type, fn_carbon_14_14: $i > $i).
% 28.89/28.97  tff(decl_17356, type, fn_carbon_isotope_9: $i > $i).
% 28.89/28.97  tff(decl_17357, type, fn_carbon_isotope_10: $i > $i).
% 28.89/28.97  tff(decl_17358, type, carbon_cycle_1: $i > $o).
% 28.89/28.97  tff(decl_17359, type, 'Carbon-Cycle': $i).
% 28.89/28.97  tff(decl_17360, type, 'Global biogeochemical processes which cycle carbon through biotic and abiotic components of ecosystems.': $i).
% 28.89/28.97  tff(decl_17361, type, 'undergo the carbon cycle': $i).
% 28.89/28.97  tff(decl_17362, type, 'cycle of carbon': $i).
% 28.89/28.97  tff(decl_17363, type, 'carbon cycle': $i).
% 28.89/28.97  tff(decl_17364, type, 'carbon-cycle': $i).
% 28.89/28.97  tff(decl_17365, type, global_biogeochemical_cycle_1: $i > $o).
% 28.89/28.97  tff(decl_17366, type, nitrogen_cycle_1: $i > $o).
% 28.89/28.97  tff(decl_17367, type, fn_carbon_cycle_1: $i > $i).
% 28.89/28.97  tff(decl_17368, type, fn_carbon_cycle_2: $i > $i).
% 28.89/28.97  tff(decl_17369, type, fn_carbon_cycle_3: $i > $i).
% 28.89/28.97  tff(decl_17370, type, fn_carbon_cycle_4: $i > $i).
% 28.89/28.97  tff(decl_17371, type, fn_carbon_cycle_5: $i > $i).
% 28.89/28.97  tff(decl_17372, type, fn_carbon_cycle_6: $i > $i).
% 28.89/28.97  tff(decl_17373, type, fn_carbon_cycle_7: $i > $i).
% 28.89/28.97  tff(decl_17374, type, fn_carbon_cycle_9: $i > $i).
% 28.89/28.97  tff(decl_17375, type, fn_carbon_cycle_10: $i > $i).
% 28.89/28.97  tff(decl_17376, type, fn_carbon_cycle_11: $i > $i).
% 28.89/28.97  tff(decl_17377, type, fn_carbon_cycle_12: $i > $i).
% 28.89/28.97  tff(decl_17378, type, fn_carbon_cycle_13: $i > $i).
% 28.89/28.97  tff(decl_17379, type, fn_carbon_cycle_14: $i > $i).
% 28.89/28.97  tff(decl_17380, type, fn_carbon_cycle_15: $i > $i).
% 28.89/28.97  tff(decl_17381, type, fn_carbon_cycle_16: $i > $i).
% 28.89/28.97  tff(decl_17382, type, fn_carbon_cycle_17: $i > $i).
% 28.89/28.97  tff(decl_17383, type, fn_carbon_cycle_18: $i > $i).
% 28.89/28.97  tff(decl_17384, type, fn_carbon_cycle_19: $i > $i).
% 28.89/28.97  tff(decl_17385, type, fn_carbon_cycle_20: $i > $i).
% 28.89/28.97  tff(decl_17386, type, fn_carbon_cycle_21: $i > $i).
% 28.89/28.97  tff(decl_17387, type, fn_carbon_cycle_22: $i > $i).
% 28.89/28.97  tff(decl_17388, type, fn_carbon_cycle_23: $i > $i).
% 28.89/28.97  tff(decl_17389, type, fn_carbon_cycle_24: $i > $i).
% 28.89/28.97  tff(decl_17390, type, fn_carbon_cycle_25: $i > $i).
% 28.89/28.97  tff(decl_17391, type, fn_carbon_cycle_26: $i > $i).
% 28.89/28.97  tff(decl_17392, type, fn_carbon_cycle_27: $i > $i).
% 28.89/28.97  tff(decl_17393, type, fn_carbon_cycle_28: $i > $i).
% 28.89/28.97  tff(decl_17394, type, fn_carbon_cycle_29: $i > $i).
% 28.89/28.97  tff(decl_17395, type, fn_carbon_cycle_30: $i > $i).
% 28.89/28.97  tff(decl_17396, type, fn_carbon_cycle_31: $i > $i).
% 28.89/28.97  tff(decl_17397, type, fn_carbon_cycle_32: $i > $i).
% 28.89/28.97  tff(decl_17398, type, fn_carbon_cycle_33: $i > $i).
% 28.89/28.97  tff(decl_17399, type, fn_carbon_cycle_34: $i > $i).
% 28.89/28.97  tff(decl_17400, type, fn_carbon_cycle_35: $i > $i).
% 28.89/28.97  tff(decl_17401, type, fn_carbon_cycle_36: $i > $i).
% 28.89/28.97  tff(decl_17402, type, primary_consumer_1: $i > $o).
% 28.89/28.97  tff(decl_17403, type, fn_carbon_cycle_37: $i > $i).
% 28.89/28.97  tff(decl_17404, type, fn_carbon_cycle_38: $i > $i).
% 28.89/28.97  tff(decl_17405, type, phytoplankton_1: $i > $o).
% 28.89/28.97  tff(decl_17406, type, fn_carbon_cycle_39: $i > $i).
% 28.89/28.97  tff(decl_17407, type, fn_carbon_cycle_40: $i > $i).
% 28.89/28.97  tff(decl_17408, type, fn_carbon_cycle_41: $i > $i).
% 28.89/28.97  tff(decl_17409, type, fn_carbon_cycle_42: $i > $i).
% 28.89/28.97  tff(decl_17410, type, fn_carbon_cycle_43: $i > $i).
% 28.89/28.97  tff(decl_17411, type, fn_carbon_cycle_44: $i > $i).
% 28.89/28.97  tff(decl_17412, type, decomposer_1: $i > $o).
% 28.89/28.97  tff(decl_17413, type, fn_carbon_cycle_45: $i > $i).
% 28.89/28.97  tff(decl_17414, type, fn_carbon_cycle_46: $i > $i).
% 28.89/28.97  tff(decl_17415, type, fn_carbon_cycle_47: $i > $i).
% 28.89/28.97  tff(decl_17416, type, fn_carbon_cycle_48: $i > $i).
% 28.89/28.97  tff(decl_17417, type, fn_carbon_cycle_49: $i > $i).
% 28.89/28.97  tff(decl_17418, type, fn_carbon_cycle_50: $i > $i).
% 28.89/28.97  tff(decl_17419, type, fn_carbon_cycle_51: $i > $i).
% 28.89/28.97  tff(decl_17420, type, fn_carbon_cycle_52: $i > $i).
% 28.89/28.97  tff(decl_17421, type, fn_carbon_cycle_53: $i > $i).
% 28.89/28.97  tff(decl_17422, type, fn_carbon_cycle_54: $i > $i).
% 28.89/28.97  tff(decl_17423, type, fn_carbon_cycle_55: $i > $i).
% 28.89/28.97  tff(decl_17424, type, fn_primary_consumer_3: $i > $i).
% 28.89/28.97  tff(decl_17425, type, fn_cell_wall_15: $i > $i).
% 28.89/28.97  tff(decl_17426, type, fn_photosynthesis_29: $i > $i).
% 28.89/28.97  tff(decl_17427, type, fn_cellular_respiration_60: $i > $i).
% 28.89/28.97  tff(decl_17428, type, fn_decomposer_1: $i > $i).
% 28.89/28.97  tff(decl_17429, type, fn_cell_wall_17: $i > $i).
% 28.89/28.97  tff(decl_17430, type, fn_photosynthesis_44: $i > $i).
% 28.89/28.97  tff(decl_17431, type, fn_glycolysis_9: $i > $i).
% 28.89/28.97  tff(decl_17432, type, fn_cellular_respiration_40: $i > $i).
% 28.89/28.97  tff(decl_17433, type, fn_cellular_respiration_55: $i > $i).
% 28.89/28.97  tff(decl_17434, type, fn_glycolysis_97: $i > $i).
% 28.89/28.97  tff(decl_17435, type, fn_cellular_respiration_41: $i > $i).
% 28.89/28.97  tff(decl_17436, type, fn_glycolysis_48: $i > $i).
% 28.89/28.97  tff(decl_17437, type, fn_cellular_respiration_46: $i > $i).
% 28.89/28.97  tff(decl_17438, type, fn_glycolysis_47: $i > $i).
% 28.89/28.97  tff(decl_17439, type, fn_cellular_respiration_47: $i > $i).
% 28.89/28.97  tff(decl_17440, type, fn_co2_gas_1: $i > $i).
% 28.89/28.97  tff(decl_17441, type, fn_chemical_1: $i > $i).
% 28.89/28.97  tff(decl_17442, type, fn_gas_substance_1: $i > $i).
% 28.89/28.97  tff(decl_17443, type, biogeochemical_cycle_0: $i).
% 28.89/28.97  tff(decl_17444, type, fn_carbon_cycle_58: $i > $i).
% 28.89/28.97  tff(decl_17445, type, fn_carbon_cycle_59: $i > $i).
% 28.89/28.97  tff(decl_17446, type, fn_carbon_cycle_56: $i > $i).
% 28.89/28.97  tff(decl_17447, type, fn_carbon_cycle_57: $i > $i).
% 28.89/28.97  tff(decl_17448, type, fn_carbon_cycle_60: $i > $i).
% 28.89/28.97  tff(decl_17449, type, carbon_dating_1: $i > $o).
% 28.89/28.97  tff(decl_17450, type, 'Carbon-Dating': $i).
% 28.89/28.97  tff(decl_17451, type, 'A method for determining the absolute ages of rocks and fossils, based on the half-life of carbon isotopes.': $i).
% 28.89/28.97  tff(decl_17452, type, 'dating of carbon': $i).
% 28.89/28.97  tff(decl_17453, type, 'carbon dating': $i).
% 28.89/28.97  tff(decl_17454, type, 'carbon-dating': $i).
% 28.89/28.97  tff(decl_17455, type, 'Carbon-Dioxide': $i).
% 28.89/28.97  tff(decl_17456, type, 'Carbon dioxide (chemical formula CO2) is an inorganic chemical compound composed of two oxygen atoms covalently bonded to a single carbon atom.': $i).
% 28.89/28.97  tff(decl_17457, type, co2: $i).
% 28.89/28.97  tff(decl_17458, type, 'dioxide of carbon': $i).
% 28.89/28.97  tff(decl_17459, type, 'carbon dioxide': $i).
% 28.89/28.97  tff(decl_17460, type, 'carbon-dioxide': $i).
% 28.89/28.97  tff(decl_17461, type, possesses_0: $i).
% 28.89/28.97  tff(decl_17462, type, double_bond_0: $i).
% 28.89/28.97  tff(decl_17463, type, 'Carbon-Fixation': $i).
% 28.89/28.97  tff(decl_17464, type, 'A biochemical process which results in the incorporation of CO2 into an organic molecule by an autotrophic organism.': $i).
% 28.89/28.97  tff(decl_17465, type, fix: $i).
% 28.89/28.97  tff(decl_17466, type, 'fixation of carbon': $i).
% 28.89/28.97  tff(decl_17467, type, 'carbon fixation': $i).
% 28.89/28.97  tff(decl_17468, type, 'carbon-fixation': $i).
% 28.89/28.97  tff(decl_17469, type, fixation_1: $i > $o).
% 28.89/28.97  tff(decl_17470, type, fn_carbon_fixation_2: $i > $i).
% 28.89/28.97  tff(decl_17471, type, fn_fixation_1: $i > $i).
% 28.89/28.97  tff(decl_17472, type, 'Carbon-Isotope': $i).
% 28.89/28.97  tff(decl_17473, type, 'One of several atomic forms of carbon, each with the same number of protons but different number of neutrons, thus differing in atomic mass.': $i).
% 28.89/28.97  tff(decl_17474, type, 'isotope of carbon': $i).
% 28.89/28.97  tff(decl_17475, type, 'carbon isotope': $i).
% 28.89/28.97  tff(decl_17476, type, 'carbon-isotope': $i).
% 28.89/28.97  tff(decl_17477, type, fn_carbon_isotope_1: $i > $i).
% 28.89/28.97  tff(decl_17478, type, fn_carbon_isotope_2: $i > $i).
% 28.89/28.97  tff(decl_17479, type, fn_carbon_isotope_3: $i > $i).
% 28.89/28.97  tff(decl_17480, type, fn_carbon_isotope_7: $i > $i).
% 28.89/28.97  tff(decl_17481, type, fn_second_electron_shell_18: $i > $i).
% 28.89/28.97  tff(decl_17482, type, fn_second_electron_shell_11: $i > $i).
% 28.89/28.97  tff(decl_17483, type, fn_second_electron_shell_12: $i > $i).
% 28.89/28.97  tff(decl_17484, type, fn_second_electron_shell_13: $i > $i).
% 28.89/28.97  tff(decl_17485, type, "2.55e0": $i).
% 28.89/28.97  tff(decl_17486, type, 'Carbon-Monoxide': $i).
% 28.89/28.97  tff(decl_17487, type, 'A colorless, odorless gas with the chemical formula CO.': $i).
% 28.89/28.97  tff(decl_17488, type, 'monoxide of carbon': $i).
% 28.89/28.97  tff(decl_17489, type, 'carbon monoxide': $i).
% 28.89/28.97  tff(decl_17490, type, 'carbon-monoxide': $i).
% 28.89/28.97  tff(decl_17491, type, 'Carbon-Skeleton': $i).
% 28.89/28.97  tff(decl_17492, type, 'Carbon skeleton of an organic compound  is, the chains, branches and/or rings of carbon atoms that form the basis of the structure of an organic molecule': $i).
% 28.89/28.97  tff(decl_17493, type, 'skeleton of carbon': $i).
% 28.89/28.97  tff(decl_17494, type, 'carbon skeleton': $i).
% 28.89/28.97  tff(decl_17495, type, 'carbon-skeleton': $i).
% 28.89/28.97  tff(decl_17496, type, fn_carbon_skeleton_5: $i > $i).
% 28.89/28.97  tff(decl_17497, type, 'Carbon-Source': $i).
% 28.89/28.97  tff(decl_17498, type, 'A carbon-source is the chemical entity which provide carbon.': $i).
% 28.89/28.97  tff(decl_17499, type, 'source of carbon': $i).
% 28.89/28.97  tff(decl_17500, type, 'carbon source': $i).
% 28.89/28.97  tff(decl_17501, type, 'carbon-source': $i).
% 28.89/28.97  tff(decl_17502, type, fn_carbon_source_1: $i > $i).
% 28.89/28.97  tff(decl_17503, type, fn_carbon_source_3: $i > $i).
% 28.89/28.97  tff(decl_17504, type, fn_carbon_source_4: $i > $i).
% 28.89/28.97  tff(decl_17505, type, fn_carbon_source_5: $i > $i).
% 28.89/28.97  tff(decl_17506, type, fn_carbon_source_6: $i > $i).
% 28.89/28.97  tff(decl_17507, type, fn_carbon_source_7: $i > $i).
% 28.89/28.97  tff(decl_17508, type, fn_carbon_source_8: $i > $i).
% 28.89/28.97  tff(decl_17509, type, 'Carbonate-Ion': $i).
% 28.89/28.97  tff(decl_17510, type, 'Polyatomic ion with a minus 2 charge, most commonly formed when carbon dioxide gas dissolves in water.': $i).
% 28.89/28.97  tff(decl_17511, type, 'ion of carbonate': $i).
% 28.89/28.97  tff(decl_17512, type, 'carbonate ion': $i).
% 28.89/28.97  tff(decl_17513, type, 'carbonate-ion': $i).
% 28.89/28.97  tff(decl_17514, type, fn_carbonate_ion_2: $i > $i).
% 28.89/28.97  tff(decl_17515, type, fn_carbonate_ion_1: $i > $i).
% 28.89/28.97  tff(decl_17516, type, 'Carbonic-Acid': $i).
% 28.89/28.97  tff(decl_17517, type, 'A weak organic acid with the chemical formula H2CO3. Carbonic acid is a key player in the regulation of blood pH, and carbonate equilibrium in aquatic ecosystems.': $i).
% 28.89/28.97  tff(decl_17518, type, 'carbonic acid': $i).
% 28.89/28.97  tff(decl_17519, type, 'carbonic-acid': $i).
% 28.89/28.97  tff(decl_17520, type, fn_carbonic_acid_3: $i > $i).
% 28.89/28.97  tff(decl_17521, type, fn_carbonic_acid_1: $i > $i).
% 28.89/28.97  tff(decl_17522, type, 'Carbonic-Acid-Bicarbonate-Buffer': $i).
% 28.89/28.97  tff(decl_17523, type, 'One of the buffers in human blood that regulates the pH of the blood.': $i).
% 28.89/28.97  tff(decl_17524, type, 'carbonic acid bicarbonate': $i).
% 28.89/28.97  tff(decl_17525, type, 'carbonic acid bicarbonate buffer': $i).
% 28.89/28.97  tff(decl_17526, type, 'carbonic-acid-bicarbonate-buffer': $i).
% 28.89/28.97  tff(decl_17527, type, fn_carbonic_acid_bicarbonate_buffer_1: $i > $i).
% 28.89/28.97  tff(decl_17528, type, fn_carbonic_acid_bicarbonate_buffer_2: $i > $i).
% 28.89/28.97  tff(decl_17529, type, 'Carbonic-Acid-Compound': $i).
% 28.89/28.97  tff(decl_17530, type, 'It is an organic compound with molecular formula H2CO3.': $i).
% 28.89/28.97  tff(decl_17531, type, 'carbonic acid compound': $i).
% 28.89/28.97  tff(decl_17532, type, 'carbonic-acid-compound': $i).
% 28.89/28.97  tff(decl_17533, type, fn_carbonic_acid_compound_1: $i > $i).
% 28.89/28.97  tff(decl_17534, type, fn_carbonic_acid_compound_2: $i > $i).
% 28.89/28.97  tff(decl_17535, type, fn_carbonic_acid_compound_3: $i > $i).
% 28.89/28.97  tff(decl_17536, type, 'Carbonyl-Group': $i).
% 28.89/28.97  tff(decl_17537, type, 'A carbonyl group is a functional group composed of a carbon atom double-bonded to an oxygen atom: C=O.': $i).
% 28.89/28.97  tff(decl_17538, type, 'CO': $i).
% 28.89/28.97  tff(decl_17539, type, 'co group': $i).
% 28.89/28.97  tff(decl_17540, type, 'co-group': $i).
% 28.89/28.97  tff(decl_17541, type, 'group of carbonyl': $i).
% 28.89/28.97  tff(decl_17542, type, 'carbonyl group': $i).
% 28.89/28.97  tff(decl_17543, type, 'carbonyl-group': $i).
% 28.89/28.97  tff(decl_17544, type, fn_carbonyl_group_1: $i > $i).
% 28.89/28.97  tff(decl_17545, type, fn_carbonyl_group_11: $i > $i).
% 28.89/28.97  tff(decl_17546, type, fn_carbonyl_group_12: $i > $i).
% 28.89/28.97  tff(decl_17547, type, fn_carbonyl_group_13: $i > $i).
% 28.89/28.97  tff(decl_17548, type, fn_carbonyl_group_14: $i > $i).
% 28.89/28.97  tff(decl_17549, type, fn_carbonyl_group_3: $i > $i).
% 28.89/28.97  tff(decl_17550, type, fn_carbonyl_group_2: $i > $i).
% 28.89/28.97  tff(decl_17551, type, 'Carboxyl-End': $i).
% 28.89/28.97  tff(decl_17552, type, 'The carboxyl end of a protein or polypeptide is the end of the amino acid chain terminated by a free carboxyl group.': $i).
% 28.89/28.97  tff(decl_17553, type, 'c terminus': $i).
% 28.89/28.97  tff(decl_17554, type, 'c-terminus': $i).
% 28.89/28.97  tff(decl_17555, type, 'carboxyl terminus': $i).
% 28.89/28.97  tff(decl_17556, type, 'carboxyl-terminus': $i).
% 28.89/28.97  tff(decl_17557, type, 'carboxy terminus': $i).
% 28.89/28.97  tff(decl_17558, type, 'carboxy-terminus': $i).
% 28.89/28.97  tff(decl_17559, type, 'c terminal': $i).
% 28.89/28.97  tff(decl_17560, type, 'c-terminal': $i).
% 28.89/28.97  tff(decl_17561, type, 'c terminal end': $i).
% 28.89/28.97  tff(decl_17562, type, 'c-terminal-end': $i).
% 28.89/28.97  tff(decl_17563, type, 'cooh terminus': $i).
% 28.89/28.97  tff(decl_17564, type, 'cooh-terminus': $i).
% 28.89/28.97  tff(decl_17565, type, 'end of carboxyl': $i).
% 28.89/28.97  tff(decl_17566, type, 'carboxyl end': $i).
% 28.89/28.97  tff(decl_17567, type, 'carboxyl-end': $i).
% 28.89/28.97  tff(decl_17568, type, fn_carboxyl_end_1: $i > $i).
% 28.89/28.97  tff(decl_17569, type, 'Carboxyl-Group': $i).
% 28.89/28.97  tff(decl_17570, type, 'A carboxyl group is a group of atoms found in some organic molecules such as organic acids which contains one carbon atom double-bonded to one oxygen atom and single bonded to a second oxygen atom which is part of a hydroxyl group.': $i).
% 28.89/28.97  tff(decl_17571, type, cooh: $i).
% 28.89/28.97  tff(decl_17572, type, '-cooh': $i).
% 28.89/28.97  tff(decl_17573, type, 'group of carboxyl': $i).
% 28.89/28.97  tff(decl_17574, type, 'carboxyl group': $i).
% 28.89/28.97  tff(decl_17575, type, 'carboxyl-group': $i).
% 28.89/28.97  tff(decl_17576, type, fn_carboxyl_group_7: $i > $i).
% 28.89/28.97  tff(decl_17577, type, fn_carboxyl_group_8: $i > $i).
% 28.89/28.97  tff(decl_17578, type, fn_carboxyl_group_9: $i > $i).
% 28.89/28.97  tff(decl_17579, type, fn_carboxyl_group_10: $i > $i).
% 28.89/28.97  tff(decl_17580, type, fn_carboxyl_group_11: $i > $i).
% 28.89/28.97  tff(decl_17581, type, fn_carboxyl_group_12: $i > $i).
% 28.89/28.97  tff(decl_17582, type, fn_carboxyl_group_13: $i > $i).
% 28.89/28.97  tff(decl_17583, type, fn_carboxyl_group_14: $i > $i).
% 28.89/28.97  tff(decl_17584, type, fn_carboxyl_group_15: $i > $i).
% 28.89/28.97  tff(decl_17585, type, fn_carboxyl_group_26: $i > $i).
% 28.89/28.97  tff(decl_17586, type, fn_carboxyl_group_27: $i > $i).
% 28.89/28.97  tff(decl_17587, type, fn_carboxyl_group_28: $i > $i).
% 28.89/28.97  tff(decl_17588, type, fn_carboxyl_group_29: $i > $i).
% 28.89/28.97  tff(decl_17589, type, fn_carboxyl_group_31: $i > $i).
% 28.89/28.97  tff(decl_17590, type, fn_carboxyl_group_32: $i > $i).
% 28.89/28.97  tff(decl_17591, type, fn_carboxyl_group_33: $i > $i).
% 28.89/28.97  tff(decl_17592, type, fn_carboxyl_group_34: $i > $i).
% 28.89/28.97  tff(decl_17593, type, fn_carboxyl_group_35: $i > $i).
% 28.89/28.97  tff(decl_17594, type, fn_carboxyl_group_36: $i > $i).
% 28.89/28.97  tff(decl_17595, type, fn_carboxyl_group_37: $i > $i).
% 28.89/28.97  tff(decl_17596, type, fn_carboxyl_group_38: $i > $i).
% 28.89/28.97  tff(decl_17597, type, fn_carboxyl_group_39: $i > $i).
% 28.89/28.97  tff(decl_17598, type, fn_carboxyl_group_41: $i > $i).
% 28.89/28.97  tff(decl_17599, type, fn_carboxyl_group_42: $i > $i).
% 28.89/28.97  tff(decl_17600, type, fn_carboxyl_group_43: $i > $i).
% 28.89/28.97  tff(decl_17601, type, fn_carboxyl_group_44: $i > $i).
% 28.89/28.97  tff(decl_17602, type, fn_carboxyl_group_48: $i > $i).
% 28.89/28.97  tff(decl_17603, type, fn_carboxyl_group_50: $i > $i).
% 28.89/28.97  tff(decl_17604, type, fn_carboxyl_group_51: $i > $i).
% 28.89/28.97  tff(decl_17605, type, fn_carboxyl_group_52: $i > $i).
% 28.89/28.97  tff(decl_17606, type, fn_carboxyl_group_53: $i > $i).
% 28.89/28.97  tff(decl_17607, type, fn_carboxyl_group_59: $i > $i).
% 28.89/28.97  tff(decl_17608, type, fn_carboxyl_group_60: $i > $i).
% 28.89/28.97  tff(decl_17609, type, fn_carboxyl_group_61: $i > $i).
% 28.89/28.97  tff(decl_17610, type, fn_carboxyl_group_68: $i > $i).
% 28.89/28.97  tff(decl_17611, type, fn_polar_covalent_bond_20: $i > $i).
% 28.89/28.97  tff(decl_17612, type, fn_polar_covalent_bond_15: $i > $i).
% 28.89/28.97  tff(decl_17613, type, fn_constant_motion_1: $i > $i).
% 28.89/28.97  tff(decl_17614, type, 'O-H': $i).
% 28.89/28.97  tff(decl_17615, type, 'C-O': $i).
% 28.89/28.97  tff(decl_17616, type, fn_carboxyl_group_76: $i > $i).
% 28.89/28.97  tff(decl_17617, type, fn_carboxyl_group_74: $i > $i).
% 28.89/28.97  tff(decl_17618, type, fn_carboxyl_group_72: $i > $i).
% 28.89/28.97  tff(decl_17619, type, fn_carboxyl_group_73: $i > $i).
% 28.89/28.97  tff(decl_17620, type, fn_carboxyl_group_77: $i > $i).
% 28.89/28.97  tff(decl_17621, type, fn_carboxyl_group_71: $i > $i).
% 28.89/28.97  tff(decl_17622, type, fn_carboxyl_group_75: $i > $i).
% 28.89/28.97  tff(decl_17623, type, carboxylate_ion_1: $i > $o).
% 28.89/28.97  tff(decl_17624, type, 'Carboxylate-Ion': $i).
% 28.89/28.97  tff(decl_17625, type, 'Polyatomic ion with a minus 1 charge, ionized form of carboxylic acid': $i).
% 28.89/28.97  tff(decl_17626, type, 'carboxylate ion': $i).
% 28.89/28.97  tff(decl_17627, type, 'carboxylate-ion': $i).
% 28.89/28.97  tff(decl_17628, type, fn_carboxylate_ion_1: $i > $i).
% 28.89/28.97  tff(decl_17629, type, fn_carboxylate_ion_2: $i > $i).
% 28.89/28.97  tff(decl_17630, type, fn_carboxylate_ion_3: $i > $i).
% 28.89/28.97  tff(decl_17631, type, 'Carboxylic-Acid': $i).
% 28.89/28.97  tff(decl_17632, type, 'Carboxylic acids are organic acids characterized by the presence of at least one carboxyl group.': $i).
% 28.89/28.97  tff(decl_17633, type, 'carboxylic acid': $i).
% 28.89/28.97  tff(decl_17634, type, 'carboxylic-acid': $i).
% 28.89/28.97  tff(decl_17635, type, fn_carboxylic_acid_1: $i > $i).
% 28.89/28.97  tff(decl_17636, type, fn_carboxylic_acid_2: $i > $i).
% 28.89/28.97  tff(decl_17637, type, fn_carboxylic_acid_3: $i > $i).
% 28.89/28.97  tff(decl_17638, type, fn_carboxylic_acid_4: $i > $i).
% 28.89/28.97  tff(decl_17639, type, fn_carboxylic_acid_5: $i > $i).
% 28.89/28.97  tff(decl_17640, type, fn_carboxylic_acid_6: $i > $i).
% 28.89/28.97  tff(decl_17641, type, fn_carboxylic_acid_7: $i > $i).
% 28.89/28.97  tff(decl_17642, type, fn_carboxylic_acid_8: $i > $i).
% 28.89/28.97  tff(decl_17643, type, fn_carboxylic_acid_10: $i > $i).
% 28.89/28.97  tff(decl_17644, type, fn_carboxylic_acid_11: $i > $i).
% 28.89/28.97  tff(decl_17645, type, fn_carboxylic_acid_12: $i > $i).
% 28.89/28.97  tff(decl_17646, type, fn_carboxylic_acid_13: $i > $i).
% 28.89/28.97  tff(decl_17647, type, fn_carboxylic_acid_14: $i > $i).
% 28.89/28.97  tff(decl_17648, type, fn_carboxylic_acid_15: $i > $i).
% 28.89/28.97  tff(decl_17649, type, fn_carboxylic_acid_16: $i > $i).
% 28.89/28.97  tff(decl_17650, type, fn_carboxylic_acid_17: $i > $i).
% 28.89/28.97  tff(decl_17651, type, fn_carboxylic_acid_18: $i > $i).
% 28.89/28.97  tff(decl_17652, type, fn_carboxylic_acid_19: $i > $i).
% 28.89/28.97  tff(decl_17653, type, fn_carboxylic_acid_20: $i > $i).
% 28.89/28.97  tff(decl_17654, type, fn_carboxylic_acid_21: $i > $i).
% 28.89/28.97  tff(decl_17655, type, fn_carboxylic_acid_22: $i > $i).
% 28.89/28.97  tff(decl_17656, type, fn_carboxylic_acid_23: $i > $i).
% 28.89/28.97  tff(decl_17657, type, fn_carboxylic_acid_24: $i > $i).
% 28.89/28.97  tff(decl_17658, type, fn_carboxylic_acid_25: $i > $i).
% 28.89/28.97  tff(decl_17659, type, fn_carboxylic_acid_26: $i > $i).
% 28.89/28.97  tff(decl_17660, type, fn_organic_acid_20: $i > $i).
% 28.89/28.97  tff(decl_17661, type, fn_organic_acid_2: $i > $i).
% 28.89/28.97  tff(decl_17662, type, fn_carboxylic_acid_27: $i > $i).
% 28.89/28.97  tff(decl_17663, type, fn_organic_acid_21: $i > $i).
% 28.89/28.97  tff(decl_17664, type, fn_organic_acid_11: $i > $i).
% 28.89/28.97  tff(decl_17665, type, fn_organic_acid_15: $i > $i).
% 28.89/28.97  tff(decl_17666, type, fn_organic_acid_1: $i > $i).
% 28.89/28.97  tff(decl_17667, type, fn_organic_acid_10: $i > $i).
% 28.89/28.97  tff(decl_17668, type, fn_organic_acid_19: $i > $i).
% 28.89/28.97  tff(decl_17669, type, fn_organic_acid_16: $i > $i).
% 28.89/28.97  tff(decl_17670, type, fn_organic_acid_17: $i > $i).
% 28.89/28.97  tff(decl_17671, type, fn_organic_acid_18: $i > $i).
% 28.89/28.97  tff(decl_17672, type, fn_organic_acid_13: $i > $i).
% 28.89/28.97  tff(decl_17673, type, fn_organic_acid_12: $i > $i).
% 28.89/28.97  tff(decl_17674, type, fn_organic_acid_14: $i > $i).
% 28.89/28.97  tff(decl_17675, type, carboxypeptidase_1: $i > $o).
% 28.89/28.97  tff(decl_17676, type, 'Carboxypeptidase': $i).
% 28.89/28.97  tff(decl_17677, type, 'An enzyme that digests proteins by removing one amino acid at a time.': $i).
% 28.89/28.97  tff(decl_17678, type, carboxypeptidase: $i).
% 28.89/28.97  tff(decl_17679, type, fn_carboxypeptidase_1: $i > $i).
% 28.89/28.97  tff(decl_17680, type, fn_carboxypeptidase_2: $i > $i).
% 28.89/28.97  tff(decl_17681, type, fn_carboxypeptidase_3: $i > $i).
% 28.89/28.97  tff(decl_17682, type, cofactor_1: $i > $o).
% 28.89/28.97  tff(decl_17683, type, fn_carboxypeptidase_4: $i > $i).
% 28.89/28.97  tff(decl_17684, type, fn_carboxypeptidase_5: $i > $i).
% 28.89/28.97  tff(decl_17685, type, fn_cofactor_1: $i > $i).
% 28.89/28.97  tff(decl_17686, type, cardiac_cycle_1: $i > $o).
% 28.89/28.97  tff(decl_17687, type, 'Cardiac-Cycle': $i).
% 28.89/28.97  tff(decl_17688, type, 'Any or all of the events pertaining to the flow of blood from the beginning of one heartbeat to the beginning of the next.': $i).
% 28.89/28.97  tff(decl_17689, type, 'cardiac cycle': $i).
% 28.89/28.97  tff(decl_17690, type, 'cardiac-cycle': $i).
% 28.89/28.97  tff(decl_17691, type, cardiovascular_process_1: $i > $o).
% 28.89/28.97  tff(decl_17692, type, countercurrent_multiplier_system_1: $i > $o).
% 28.89/28.97  tff(decl_17693, type, diastole_1: $i > $o).
% 28.89/28.97  tff(decl_17694, type, heart_attack_1: $i > $o).
% 28.89/28.97  tff(decl_17695, type, heart_murmur_1: $i > $o).
% 28.89/28.97  tff(decl_17696, type, hypertension_1: $i > $o).
% 28.89/28.97  tff(decl_17697, type, pulse_1: $i > $o).
% 28.89/28.97  tff(decl_17698, type, cardiac_muscle_1: $i > $o).
% 28.89/28.97  tff(decl_17699, type, 'Cardiac-Muscle': $i).
% 28.89/28.97  tff(decl_17700, type, 'A type of contractile striated muscle found in the walls of the heart. Cells of cardiac muscle are connected by intercalated discs, which allow impulses to travel between them for coordinated contraction.': $i).
% 28.89/28.97  tff(decl_17701, type, 'cardiac muscle': $i).
% 28.89/28.97  tff(decl_17702, type, 'cardiac-muscle': $i).
% 28.89/28.97  tff(decl_17703, type, striated_muscle_1: $i > $o).
% 28.89/28.97  tff(decl_17704, type, skeletal_muscle_1: $i > $o).
% 28.89/28.97  tff(decl_17705, type, fn_cardiac_muscle_1: $i > $i).
% 28.89/28.97  tff(decl_17706, type, fn_cardiac_muscle_2: $i > $i).
% 28.89/28.97  tff(decl_17707, type, fn_cardiac_muscle_4: $i > $i).
% 28.89/28.97  tff(decl_17708, type, fn_cardiac_muscle_5: $i > $i).
% 28.89/28.97  tff(decl_17709, type, fn_cardiac_muscle_6: $i > $i).
% 28.89/28.97  tff(decl_17710, type, fn_cardiac_muscle_7: $i > $i).
% 28.89/28.97  tff(decl_17711, type, fn_cardiac_muscle_8: $i > $i).
% 28.89/28.97  tff(decl_17712, type, fn_cardiac_muscle_9: $i > $i).
% 28.89/28.97  tff(decl_17713, type, fn_cardiac_muscle_10: $i > $i).
% 28.89/28.97  tff(decl_17714, type, fn_cardiac_muscle_11: $i > $i).
% 28.89/28.97  tff(decl_17715, type, fn_cardiac_muscle_12: $i > $i).
% 28.89/28.97  tff(decl_17716, type, fn_cardiac_muscle_13: $i > $i).
% 28.89/28.97  tff(decl_17717, type, fn_cardiac_muscle_14: $i > $i).
% 28.89/28.97  tff(decl_17718, type, fn_cardiac_muscle_15: $i > $i).
% 28.89/28.97  tff(decl_17719, type, fn_cardiac_muscle_3: $i > $i).
% 28.89/28.97  tff(decl_17720, type, cardinal_1: $i > $o).
% 28.89/28.97  tff(decl_17721, type, 'Cardinal': $i).
% 28.89/28.97  tff(decl_17722, type, cardinal: $i).
% 28.89/28.97  tff(decl_17723, type, cardinality_1: $i > $o).
% 28.89/28.97  tff(decl_17724, type, 'Cardinality': $i).
% 28.89/28.97  tff(decl_17725, type, 'Cardiovascular-Disease': $i).
% 28.89/28.97  tff(decl_17726, type, 'Any disease affecting the cardiovascular system.': $i).
% 28.89/28.97  tff(decl_17727, type, 'heart disease': $i).
% 28.89/28.97  tff(decl_17728, type, 'heart-disease': $i).
% 28.89/28.97  tff(decl_17729, type, 'cardiovascular disease': $i).
% 28.89/28.97  tff(decl_17730, type, 'cardiovascular-disease': $i).
% 28.89/28.97  tff(decl_17731, type, 'Cardiovascular-Process': $i).
% 28.89/28.97  tff(decl_17732, type, 'Any process related to the cardiovascular system.': $i).
% 28.89/28.97  tff(decl_17733, type, 'cardiovascular process': $i).
% 28.89/28.97  tff(decl_17734, type, 'cardiovascular-process': $i).
% 28.89/28.97  tff(decl_17735, type, 'Cardiovascular-Related-Intercellular-Process': $i).
% 28.89/28.97  tff(decl_17736, type, 'Intercellular process related to the cardiovascular system and its components.': $i).
% 28.89/28.97  tff(decl_17737, type, 'undergo cardiovascular related intercellular process': $i).
% 28.89/28.97  tff(decl_17738, type, 'cardiovascular related intercellular process': $i).
% 28.89/28.97  tff(decl_17739, type, 'cardiovascular-related-intercellular-process': $i).
% 28.89/28.97  tff(decl_17740, type, intercellular_process_1: $i > $o).
% 28.89/28.97  tff(decl_17741, type, cardiovascular_system_1: $i > $o).
% 28.89/28.97  tff(decl_17742, type, 'Cardiovascular-System': $i).
% 28.89/28.97  tff(decl_17743, type, 'A closed circulatory system consisting of a heart and blood vessels (veins, capillaries, and arteries).': $i).
% 28.89/28.97  tff(decl_17744, type, 'cardiovascular system': $i).
% 28.89/28.97  tff(decl_17745, type, 'cardiovascular-system': $i).
% 28.89/28.97  tff(decl_17746, type, closed_circulatory_system_1: $i > $o).
% 28.89/28.97  tff(decl_17747, type, carnivore_1: $i > $o).
% 28.89/28.97  tff(decl_17748, type, 'Carnivore': $i).
% 28.89/28.97  tff(decl_17749, type, 'An animal which primarily consumes other animals as a source of energy and nutrients.': $i).
% 28.89/28.97  tff(decl_17750, type, carnivore: $i).
% 28.89/28.97  tff(decl_17751, type, fn_carnivore_1: $i > $i).
% 28.89/28.97  tff(decl_17752, type, fn_carnivore_2: $i > $i).
% 28.89/28.97  tff(decl_17753, type, fn_carnivore_3: $i > $i).
% 28.89/28.97  tff(decl_17754, type, fn_carnivore_4: $i > $i).
% 28.89/28.97  tff(decl_17755, type, fn_carnivore_5: $i > $i).
% 28.89/28.97  tff(decl_17756, type, fn_carnivore_6: $i > $i).
% 28.89/28.97  tff(decl_17757, type, fn_carnivore_9: $i > $i).
% 28.89/28.97  tff(decl_17758, type, fn_carnivore_10: $i > $i).
% 28.89/28.97  tff(decl_17759, type, fn_carnivore_11: $i > $i).
% 28.89/28.97  tff(decl_17760, type, fn_carnivore_12: $i > $i).
% 28.89/28.97  tff(decl_17761, type, fn_carnivore_13: $i > $i).
% 28.89/28.97  tff(decl_17762, type, fn_carnivore_14: $i > $i).
% 28.89/28.97  tff(decl_17763, type, fn_eat_1: $i > $i).
% 28.89/28.97  tff(decl_17764, type, fn_food_4: $i > $i).
% 28.89/28.97  tff(decl_17765, type, fn_food_2: $i > $i).
% 28.89/28.97  tff(decl_17766, type, fn_eat_2: $i > $i).
% 28.89/28.97  tff(decl_17767, type, fn_food_1: $i > $i).
% 28.89/28.97  tff(decl_17768, type, fn_carnivore_8: $i > $i).
% 28.89/28.97  tff(decl_17769, type, fn_carnivore_7: $i > $i).
% 28.89/28.97  tff(decl_17770, type, 'Carotenoid': $i).
% 28.89/28.97  tff(decl_17771, type, 'A light-absorbing pigment, usually colored yellow or orange. Carotenoids broaden the wavelengths of light capable of providing energy for photosynthesis as well a absorbing excess light energy that would harm chlorophyll molecules.': $i).
% 28.89/28.97  tff(decl_17772, type, carotenoid: $i).
% 28.89/28.97  tff(decl_17773, type, phytochemical_1: $i > $o).
% 28.89/28.97  tff(decl_17774, type, chlorophyll_1: $i > $o).
% 28.89/28.97  tff(decl_17775, type, fn_carotenoid_2: $i > $i).
% 28.89/28.97  tff(decl_17776, type, fn_carotenoid_3: $i > $i).
% 28.89/28.97  tff(decl_17777, type, photoprotection_1: $i > $o).
% 28.89/28.97  tff(decl_17778, type, fn_carotenoid_4: $i > $i).
% 28.89/28.97  tff(decl_17779, type, fn_carotenoid_6: $i > $i).
% 28.89/28.97  tff(decl_17780, type, fn_carotenoid_9: $i > $i).
% 28.89/28.97  tff(decl_17781, type, fn_carotenoid_10: $i > $i).
% 28.89/28.97  tff(decl_17782, type, fn_carotenoid_11: $i > $i).
% 28.89/28.97  tff(decl_17783, type, fn_carotenoid_12: $i > $i).
% 28.89/28.97  tff(decl_17784, type, fn_carotenoid_13: $i > $i).
% 28.89/28.97  tff(decl_17785, type, fn_carotenoid_14: $i > $i).
% 28.89/28.97  tff(decl_17786, type, fn_carotenoid_15: $i > $i).
% 28.89/28.97  tff(decl_17787, type, fn_carotenoid_16: $i > $i).
% 28.89/28.97  tff(decl_17788, type, fn_carotenoid_17: $i > $i).
% 28.89/28.97  tff(decl_17789, type, fn_carotenoid_19: $i > $i).
% 28.89/28.97  tff(decl_17790, type, fn_violet_light_8: $i > $i).
% 28.89/28.97  tff(decl_17791, type, fn_phytochemical_4: $i > $i).
% 28.89/28.97  tff(decl_17792, type, fn_pigment_1: $i > $i).
% 28.89/28.97  tff(decl_17793, type, fn_pigment_2: $i > $i).
% 28.89/28.97  tff(decl_17794, type, fn_carotenoid_7: $i > $i).
% 28.89/28.97  tff(decl_17795, type, fn_phytochemical_2: $i > $i).
% 28.89/28.97  tff(decl_17796, type, fn_carotenoid_8: $i > $i).
% 28.89/28.97  tff(decl_17797, type, fn_phytochemical_1: $i > $i).
% 28.89/28.97  tff(decl_17798, type, fn_phytochemical_7: $i > $i).
% 28.89/28.97  tff(decl_17799, type, fn_phytochemical_5: $i > $i).
% 28.89/28.97  tff(decl_17800, type, fn_phytochemical_3: $i > $i).
% 28.89/28.97  tff(decl_17801, type, fn_phytochemical_10: $i > $i).
% 28.89/28.97  tff(decl_17802, type, fn_phytochemical_9: $i > $i).
% 28.89/28.97  tff(decl_17803, type, fn_phytochemical_6: $i > $i).
% 28.89/28.97  tff(decl_17804, type, carpel_1: $i > $o).
% 28.89/28.97  tff(decl_17805, type, 'Carpel': $i).
% 28.89/28.97  tff(decl_17806, type, 'The ovule-producing reproductive organ of a flower, consisting of the stigma, style, and ovary.': $i).
% 28.89/28.97  tff(decl_17807, type, carpel: $i).
% 28.89/28.97  tff(decl_17808, type, fn_carpel_1: $i > $i).
% 28.89/28.97  tff(decl_17809, type, fn_carpel_3: $i > $i).
% 28.89/28.97  tff(decl_17810, type, fn_carpel_4: $i > $i).
% 28.89/28.97  tff(decl_17811, type, carrier_1: $i > $o).
% 28.89/28.97  tff(decl_17812, type, 'Carrier': $i).
% 28.89/28.97  tff(decl_17813, type, carrier: $i).
% 28.89/28.97  tff(decl_17814, type, fn_carrier_1: $i > $i).
% 28.89/28.97  tff(decl_17815, type, carrier_as_genotype_1: $i > $o).
% 28.89/28.97  tff(decl_17816, type, 'Carrier-As-Genotype': $i).
% 28.89/28.97  tff(decl_17817, type, 'A heterozygote; one possessing both the dominant and recessive allele for a given trait.': $i).
% 28.89/28.97  tff(decl_17818, type, 'carrier genotype': $i).
% 28.89/28.97  tff(decl_17819, type, 'heterozygote genotype': $i).
% 28.89/28.97  tff(decl_17820, type, 'carrier as genotype': $i).
% 28.89/28.97  tff(decl_17821, type, 'carrier-as-genotype': $i).
% 28.89/28.97  tff(decl_17822, type, fn_carrier_as_genotype_1: $i > $i).
% 28.89/28.97  tff(decl_17823, type, 'Carrier-Protein': $i).
% 28.89/28.97  tff(decl_17824, type, 'Carrier proteins are proteins involved in the movement of ions, small molecules, or macromolecules, such as another protein, across a biological membrane.': $i).
% 28.89/28.97  tff(decl_17825, type, 'protein of carrier': $i).
% 28.89/28.97  tff(decl_17826, type, 'carrier protein': $i).
% 28.89/28.97  tff(decl_17827, type, 'carrier-protein': $i).
% 28.89/28.97  tff(decl_17828, type, fn_carrier_protein_2: $i > $i).
% 28.89/28.97  tff(decl_17829, type, fn_carrier_protein_3: $i > $i).
% 28.89/28.97  tff(decl_17830, type, fn_carrier_protein_5: $i > $i).
% 28.89/28.97  tff(decl_17831, type, fn_carrier_protein_6: $i > $i).
% 28.89/28.97  tff(decl_17832, type, fn_carrier_protein_7: $i > $i).
% 28.89/28.97  tff(decl_17833, type, facilitated_diffusion_using_carrier_protein_1: $i > $o).
% 28.89/28.97  tff(decl_17834, type, fn_carrier_protein_14: $i > $i).
% 28.89/28.97  tff(decl_17835, type, fn_carrier_protein_15: $i > $i).
% 28.89/28.97  tff(decl_17836, type, fn_carrier_protein_25: $i > $i).
% 28.89/28.97  tff(decl_17837, type, fn_carrier_protein_26: $i > $i).
% 28.89/28.97  tff(decl_17838, type, fn_carrier_protein_27: $i > $i).
% 28.89/28.97  tff(decl_17839, type, fn_carrier_protein_28: $i > $i).
% 28.89/28.97  tff(decl_17840, type, fn_carrier_protein_29: $i > $i).
% 28.89/28.97  tff(decl_17841, type, fn_carrier_protein_35: $i > $i).
% 28.89/28.97  tff(decl_17842, type, fn_carrier_protein_36: $i > $i).
% 28.89/28.97  tff(decl_17843, type, fn_carrier_protein_39: $i > $i).
% 28.89/28.97  tff(decl_17844, type, fn_carrier_protein_40: $i > $i).
% 28.89/28.97  tff(decl_17845, type, fn_facilitated_diffusion_using_carrier_protein_7: $i > $i).
% 28.89/28.97  tff(decl_17846, type, fn_facilitated_diffusion_using_carrier_protein_2: $i > $i).
% 28.89/28.97  tff(decl_17847, type, fn_facilitated_diffusion_using_carrier_protein_4: $i > $i).
% 28.89/28.97  tff(decl_17848, type, fn_facilitated_diffusion_using_carrier_protein_28: $i > $i).
% 28.89/28.97  tff(decl_17849, type, fn_facilitated_diffusion_using_carrier_protein_40: $i > $i).
% 28.89/28.97  tff(decl_17850, type, fn_facilitated_diffusion_using_carrier_protein_34: $i > $i).
% 28.89/28.97  tff(decl_17851, type, fn_facilitated_diffusion_using_carrier_protein_33: $i > $i).
% 28.89/28.97  tff(decl_17852, type, fn_protein_6: $i > $i).
% 28.89/28.97  tff(decl_17853, type, fn_transport_protein_29: $i > $i).
% 28.89/28.97  tff(decl_17854, type, fn_transport_protein_30: $i > $i).
% 28.89/28.97  tff(decl_17855, type, fn_carrier_protein_9: $i > $i).
% 28.89/28.97  tff(decl_17856, type, fn_transport_protein_22: $i > $i).
% 28.89/28.97  tff(decl_17857, type, fn_carrier_protein_10: $i > $i).
% 28.89/28.97  tff(decl_17858, type, fn_transport_protein_13: $i > $i).
% 28.89/28.97  tff(decl_17859, type, fn_transport_protein_5: $i > $i).
% 28.89/28.97  tff(decl_17860, type, fn_transport_protein_9: $i > $i).
% 28.89/28.97  tff(decl_17861, type, fn_transport_protein_27: $i > $i).
% 28.89/28.97  tff(decl_17862, type, fn_transport_protein_24: $i > $i).
% 28.89/28.97  tff(decl_17863, type, fn_transport_protein_25: $i > $i).
% 28.89/28.97  tff(decl_17864, type, fn_transport_protein_26: $i > $i).
% 28.89/28.97  tff(decl_17865, type, 'Carrot': $i).
% 28.89/28.97  tff(decl_17866, type, 'Deep orange edible root of the cultivatedcarrot plant.': $i).
% 28.89/28.97  tff(decl_17867, type, carrot: $i).
% 28.89/28.97  tff(decl_17868, type, carrot_plant_1: $i > $o).
% 28.89/28.97  tff(decl_17869, type, 'Carrot-Plant': $i).
% 28.89/28.97  tff(decl_17870, type, 'Carrot is a herbaceous, generally biennial plant of the Apiaceae family that produces an edible taproot. Among common varieties root shapes range from globular to long, with lower ends blunt to long-pointed.': $i).
% 28.89/28.97  tff(decl_17871, type, 'plant of carrot': $i).
% 28.89/28.97  tff(decl_17872, type, 'carrot plant': $i).
% 28.89/28.97  tff(decl_17873, type, 'carrot-plant': $i).
% 28.89/28.97  tff(decl_17874, type, dicot_1: $i > $o).
% 28.89/28.97  tff(decl_17875, type, fn_carrot_plant_1: $i > $i).
% 28.89/28.97  tff(decl_17876, type, fn_carrot_plant_2: $i > $i).
% 28.89/28.97  tff(decl_17877, type, fn_carrot_plant_3: $i > $i).
% 28.89/28.97  tff(decl_17878, type, fn_carrot_plant_4: $i > $i).
% 28.89/28.97  tff(decl_17879, type, fn_carrot_plant_5: $i > $i).
% 28.89/28.97  tff(decl_17880, type, cellulose_synthase_1: $i > $o).
% 28.89/28.97  tff(decl_17881, type, fn_carrot_plant_6: $i > $i).
% 28.89/28.97  tff(decl_17882, type, fn_carrot_plant_7: $i > $i).
% 28.89/28.97  tff(decl_17883, type, fn_carrot_plant_14: $i > $i).
% 28.89/28.97  tff(decl_17884, type, fn_carrot_plant_15: $i > $i).
% 28.89/28.97  tff(decl_17885, type, fn_carrot_plant_16: $i > $i).
% 28.89/28.97  tff(decl_17886, type, fn_carrot_plant_17: $i > $i).
% 28.89/28.97  tff(decl_17887, type, fn_carrot_plant_18: $i > $i).
% 28.89/28.97  tff(decl_17888, type, fn_carrot_plant_19: $i > $i).
% 28.89/28.97  tff(decl_17889, type, fn_carrot_plant_20: $i > $i).
% 28.89/28.97  tff(decl_17890, type, fn_carrot_plant_21: $i > $i).
% 28.89/28.97  tff(decl_17891, type, fn_carrot_plant_22: $i > $i).
% 28.89/28.97  tff(decl_17892, type, fn_carrot_plant_23: $i > $i).
% 28.89/28.97  tff(decl_17893, type, fn_carrot_plant_24: $i > $i).
% 28.89/28.97  tff(decl_17894, type, fn_carrot_plant_25: $i > $i).
% 28.89/28.97  tff(decl_17895, type, fn_carrot_plant_26: $i > $i).
% 28.89/28.97  tff(decl_17896, type, fn_carrot_plant_27: $i > $i).
% 28.89/28.97  tff(decl_17897, type, fn_carrot_plant_28: $i > $i).
% 28.89/28.97  tff(decl_17898, type, fn_carrot_plant_29: $i > $i).
% 28.89/28.97  tff(decl_17899, type, fn_carrot_plant_30: $i > $i).
% 28.89/28.97  tff(decl_17900, type, fn_carrot_plant_31: $i > $i).
% 28.89/28.97  tff(decl_17901, type, fn_carrot_plant_32: $i > $i).
% 28.89/28.97  tff(decl_17902, type, fn_carrot_plant_33: $i > $i).
% 28.89/28.97  tff(decl_17903, type, fn_carrot_plant_34: $i > $i).
% 28.89/28.97  tff(decl_17904, type, fn_carrot_plant_35: $i > $i).
% 28.89/28.97  tff(decl_17905, type, fn_carrot_plant_36: $i > $i).
% 28.89/28.97  tff(decl_17906, type, fn_carrot_plant_37: $i > $i).
% 28.89/28.97  tff(decl_17907, type, fn_carrot_plant_38: $i > $i).
% 28.89/28.97  tff(decl_17908, type, fn_carrot_plant_39: $i > $i).
% 28.89/28.97  tff(decl_17909, type, fn_carrot_plant_40: $i > $i).
% 28.89/28.97  tff(decl_17910, type, fn_carrot_plant_41: $i > $i).
% 28.89/28.97  tff(decl_17911, type, fn_carrot_plant_42: $i > $i).
% 28.89/28.97  tff(decl_17912, type, fn_carrot_plant_43: $i > $i).
% 28.89/28.97  tff(decl_17913, type, fn_carrot_plant_44: $i > $i).
% 28.89/28.97  tff(decl_17914, type, fn_carrot_plant_45: $i > $i).
% 28.89/28.97  tff(decl_17915, type, fn_carrot_plant_46: $i > $i).
% 28.89/28.97  tff(decl_17916, type, fn_carrot_plant_47: $i > $i).
% 28.89/28.97  tff(decl_17917, type, fn_carrot_plant_48: $i > $i).
% 28.89/28.97  tff(decl_17918, type, fn_carrot_plant_49: $i > $i).
% 28.89/28.97  tff(decl_17919, type, fn_carrot_plant_50: $i > $i).
% 28.89/28.97  tff(decl_17920, type, fn_carrot_plant_51: $i > $i).
% 28.89/28.97  tff(decl_17921, type, fn_carrot_plant_52: $i > $i).
% 28.89/28.97  tff(decl_17922, type, fn_carrot_plant_53: $i > $i).
% 28.89/28.97  tff(decl_17923, type, fn_carrot_plant_54: $i > $i).
% 28.89/28.97  tff(decl_17924, type, fn_carrot_plant_55: $i > $i).
% 28.89/28.97  tff(decl_17925, type, fn_carrot_plant_56: $i > $i).
% 28.89/28.97  tff(decl_17926, type, fn_photosynthesis_47: $i > $i).
% 28.89/28.97  tff(decl_17927, type, fn_starch_storage_by_plant_2: $i > $i).
% 28.89/28.97  tff(decl_17928, type, fn_starch_storage_by_plant_9: $i > $i).
% 28.89/28.97  tff(decl_17929, type, fn_root_33: $i > $i).
% 28.89/28.97  tff(decl_17930, type, fn_root_28: $i > $i).
% 28.89/28.97  tff(decl_17931, type, fn_starch_storage_by_plant_5: $i > $i).
% 28.89/28.97  tff(decl_17932, type, fn_starch_storage_by_plant_6: $i > $i).
% 28.89/28.97  tff(decl_17933, type, fn_starch_storage_by_plant_3: $i > $i).
% 28.89/28.97  tff(decl_17934, type, fn_seed_plant_3: $i > $i).
% 28.89/28.97  tff(decl_17935, type, fn_dicot_3: $i > $i).
% 28.89/28.97  tff(decl_17936, type, fn_dicot_2: $i > $i).
% 28.89/28.97  tff(decl_17937, type, fn_dicot_1: $i > $i).
% 28.89/28.97  tff(decl_17938, type, fn_carrot_plant_10: $i > $i).
% 28.89/28.97  tff(decl_17939, type, fn_carrot_plant_11: $i > $i).
% 28.89/28.97  tff(decl_17940, type, fn_carrot_plant_9: $i > $i).
% 28.89/28.97  tff(decl_17941, type, fn_carrot_plant_8: $i > $i).
% 28.89/28.97  tff(decl_17942, type, fn_carrot_plant_13: $i > $i).
% 28.89/28.97  tff(decl_17943, type, fn_carrot_plant_12: $i > $i).
% 28.89/28.97  tff(decl_17944, type, fn_carrot_plant_58: $i > $i).
% 28.89/28.97  tff(decl_17945, type, fn_seed_plant_17: $i > $i).
% 28.89/28.97  tff(decl_17946, type, fn_carrot_plant_57: $i > $i).
% 28.89/28.97  tff(decl_17947, type, fn_seed_plant_16: $i > $i).
% 28.89/28.97  tff(decl_17948, type, fn_seed_plant_9: $i > $i).
% 28.89/28.97  tff(decl_17949, type, fn_seed_plant_11: $i > $i).
% 28.89/28.97  tff(decl_17950, type, fn_seed_plant_4: $i > $i).
% 28.89/28.97  tff(decl_17951, type, fn_seed_plant_1: $i > $i).
% 28.89/28.97  tff(decl_17952, type, fn_seed_plant_10: $i > $i).
% 28.89/28.97  tff(decl_17953, type, fn_seed_plant_7: $i > $i).
% 28.89/28.97  tff(decl_17954, type, fn_seed_plant_13: $i > $i).
% 28.89/28.97  tff(decl_17955, type, fn_seed_plant_12: $i > $i).
% 28.89/28.97  tff(decl_17956, type, fn_seed_plant_6: $i > $i).
% 28.89/28.97  tff(decl_17957, type, fn_seed_plant_14: $i > $i).
% 28.89/28.97  tff(decl_17958, type, fn_seed_plant_2: $i > $i).
% 28.89/28.97  tff(decl_17959, type, fn_seed_plant_8: $i > $i).
% 28.89/28.97  tff(decl_17960, type, 'Carry': $i).
% 28.89/28.97  tff(decl_17961, type, pack: $i).
% 28.89/28.97  tff(decl_17962, type, take: $i).
% 28.89/28.97  tff(decl_17963, type, 'Cartilage': $i).
% 28.89/28.97  tff(decl_17964, type, 'A strong yet somewhat flexible type of connective tissue comprised of collagenous fibers embedded in a rubbery  protein-carbohydrate complex.': $i).
% 28.89/28.97  tff(decl_17965, type, cartilage: $i).
% 28.89/28.97  tff(decl_17966, type, 'Cartilaginous-Fish': $i).
% 28.89/28.97  tff(decl_17967, type, 'A fish from the clade Chondrichthyes, characterized by a skeleton made of cartilage rather than bone.': $i).
% 28.89/28.97  tff(decl_17968, type, chondrichthyan: $i).
% 28.89/28.97  tff(decl_17969, type, chondrichthyes: $i).
% 28.89/28.97  tff(decl_17970, type, 'cartilaginous fish': $i).
% 28.89/28.97  tff(decl_17971, type, 'cartilaginous-fish': $i).
% 28.89/28.97  tff(decl_17972, type, cascade_1: $i > $o).
% 28.89/28.97  tff(decl_17973, type, 'Cascade': $i).
% 28.89/28.97  tff(decl_17974, type, 'A series of reactions triggered by a single stimulus.': $i).
% 28.89/28.97  tff(decl_17975, type, 'signaling cascade': $i).
% 28.89/28.97  tff(decl_17976, type, cascade: $i).
% 28.89/28.97  tff(decl_17977, type, multi_step_reaction_1: $i > $o).
% 28.89/28.97  tff(decl_17978, type, fn_cascade_1: $i > $i).
% 28.89/28.97  tff(decl_17979, type, fn_cascade_2: $i > $i).
% 28.89/28.97  tff(decl_17980, type, fn_cascade_3: $i > $i).
% 28.89/28.97  tff(decl_17981, type, fn_cascade_4: $i > $i).
% 28.89/28.97  tff(decl_17982, type, casparian_strip_1: $i > $o).
% 28.89/28.97  tff(decl_17983, type, 'Casparian-Strip': $i).
% 28.89/28.97  tff(decl_17984, type, 'A ring of water-impermeable wax in the endodermal cells of plants. The Casparian strip blocks the passive flow of water and solutes into the stele.': $i).
% 28.89/28.97  tff(decl_17985, type, 'casparian strip': $i).
% 28.89/28.97  tff(decl_17986, type, 'casparian-strip': $i).
% 28.89/28.97  tff(decl_17987, type, cuticle_plant_1: $i > $o).
% 28.89/28.97  tff(decl_17988, type, fn_casparian_strip_1: $i > $i).
% 28.89/28.97  tff(decl_17989, type, suberin_1: $i > $o).
% 28.89/28.97  tff(decl_17990, type, fn_casparian_strip_2: $i > $i).
% 28.89/28.97  tff(decl_17991, type, fn_casparian_strip_3: $i > $i).
% 28.89/28.97  tff(decl_17992, type, fn_casparian_strip_4: $i > $i).
% 28.89/28.97  tff(decl_17993, type, endodermal_cell_1: $i > $o).
% 28.89/28.97  tff(decl_17994, type, fn_casparian_strip_5: $i > $i).
% 28.89/28.97  tff(decl_17995, type, fn_casparian_strip_6: $i > $i).
% 28.89/28.97  tff(decl_17996, type, fn_casparian_strip_7: $i > $i).
% 28.89/28.97  tff(decl_17997, type, fn_endodermal_cell_28: $i > $i).
% 28.89/28.97  tff(decl_17998, type, caspase_1: $i > $o).
% 28.89/28.97  tff(decl_17999, type, 'Caspase': $i).
% 28.89/28.97  tff(decl_18000, type, 'Caspases are a type of protease enzyme which play essential roles in apoptosis (programmed cell death).': $i).
% 28.89/28.97  tff(decl_18001, type, caspase: $i).
% 28.89/28.97  tff(decl_18002, type, 'Catabolic-Pathway': $i).
% 28.89/28.97  tff(decl_18003, type, 'A sequence of degradative chemical reactions that break down complex molecules into smaller units, usually releasing energy in the process.': $i).
% 28.89/28.97  tff(decl_18004, type, 'catabolic reactions': $i).
% 28.89/28.97  tff(decl_18005, type, 'breakdown pathway': $i).
% 28.89/28.97  tff(decl_18006, type, 'breakdown-pathway': $i).
% 28.89/28.97  tff(decl_18007, type, 'take part in a catabolic pathway': $i).
% 28.89/28.97  tff(decl_18008, type, 'catabolic pathway': $i).
% 28.89/28.97  tff(decl_18009, type, 'catabolic-pathway': $i).
% 28.89/28.97  tff(decl_18010, type, polymer_synthesis_1: $i > $o).
% 28.89/28.97  tff(decl_18011, type, fn_catabolic_pathway_3: $i > $i).
% 28.89/28.97  tff(decl_18012, type, fn_catabolic_pathway_8: $i > $i).
% 28.89/28.97  tff(decl_18013, type, fn_free_energy_2: $i > $i).
% 28.89/28.97  tff(decl_18014, type, fn_free_energy_1: $i > $i).
% 28.89/28.97  tff(decl_18015, type, 'Catabolism': $i).
% 28.89/28.97  tff(decl_18016, type, 'The class of chemical reactions that release energy by breaking down larger molecules into smaller subunits.': $i).
% 28.89/28.97  tff(decl_18017, type, 'undergo catabolism': $i).
% 28.89/28.97  tff(decl_18018, type, catabolize: $i).
% 28.89/28.97  tff(decl_18019, type, catabolism: $i).
% 28.89/28.97  tff(decl_18020, type, fn_catabolism_2: $i > $i).
% 28.89/28.97  tff(decl_18021, type, fn_catabolism_3: $i > $i).
% 28.89/28.97  tff(decl_18022, type, fn_catabolism_4: $i > $i).
% 28.89/28.97  tff(decl_18023, type, fn_catabolism_5: $i > $i).
% 28.89/28.97  tff(decl_18024, type, fn_catabolism_6: $i > $i).
% 28.89/28.97  tff(decl_18025, type, cellular_work_utilizing_atp_1: $i > $o).
% 28.89/28.97  tff(decl_18026, type, fn_catabolism_7: $i > $i).
% 28.89/28.97  tff(decl_18027, type, catalase_1: $i > $o).
% 28.89/28.97  tff(decl_18028, type, 'Catalase': $i).
% 28.89/28.97  tff(decl_18029, type, 'Catalase is an enzyme which catalyses the synthesis of Hydrogen peroxide': $i).
% 28.89/28.97  tff(decl_18030, type, peroxidase: $i).
% 28.89/28.97  tff(decl_18031, type, catalase: $i).
% 28.89/28.97  tff(decl_18032, type, oxidoreductase_1: $i > $o).
% 28.89/28.97  tff(decl_18033, type, fn_catalase_3: $i > $i).
% 28.89/28.97  tff(decl_18034, type, fn_catalase_4: $i > $i).
% 28.89/28.97  tff(decl_18035, type, fn_catalase_5: $i > $i).
% 28.89/28.97  tff(decl_18036, type, fn_catalase_6: $i > $i).
% 28.89/28.97  tff(decl_18037, type, fn_catalase_7: $i > $i).
% 28.89/28.97  tff(decl_18038, type, fn_catalase_8: $i > $i).
% 28.89/28.97  tff(decl_18039, type, fn_catalase_9: $i > $i).
% 28.89/28.97  tff(decl_18040, type, fn_catalase_10: $i > $i).
% 28.89/28.97  tff(decl_18041, type, fn_catalase_11: $i > $i).
% 28.89/28.97  tff(decl_18042, type, fn_catalase_12: $i > $i).
% 28.89/28.97  tff(decl_18043, type, fn_catalase_13: $i > $i).
% 28.89/28.97  tff(decl_18044, type, fn_catalase_14: $i > $i).
% 28.89/28.97  tff(decl_18045, type, fn_catalase_15: $i > $i).
% 28.89/28.97  tff(decl_18046, type, fn_catalase_2: $i > $i).
% 28.89/28.97  tff(decl_18047, type, fn_oxidoreductase_1: $i > $i).
% 28.89/28.97  tff(decl_18048, type, fn_oxidoreductase_5: $i > $i).
% 28.89/28.97  tff(decl_18049, type, fn_catalase_1: $i > $i).
% 28.89/28.97  tff(decl_18050, type, fn_oxidoreductase_2: $i > $i).
% 28.89/28.97  tff(decl_18051, type, fn_oxidoreductase_6: $i > $i).
% 28.89/28.97  tff(decl_18052, type, fn_oxidoreductase_8: $i > $i).
% 28.89/28.97  tff(decl_18053, type, fn_oxidoreductase_4: $i > $i).
% 28.89/28.97  tff(decl_18054, type, 'Catalyst': $i).
% 28.89/28.97  tff(decl_18055, type, 'A chemical compound that increases the rate of a biochemical reaction by lowering the required activation energy. Catalysts are not consumed by the reactions that they catalyze.': $i).
% 28.89/28.97  tff(decl_18056, type, catalyst: $i).
% 28.89/28.97  tff(decl_18057, type, fn_catalyst_1: $i > $i).
% 28.89/28.97  tff(decl_18058, type, 'Catastrophism': $i).
% 28.89/28.97  tff(decl_18059, type, 'The theory that the Earth has been affected throughout its history by sudden, violent events that had potentially world-wide effects, rather than by slow, incremental change.': $i).
% 28.89/28.97  tff(decl_18060, type, catastrophism: $i).
% 28.89/28.97  tff(decl_18061, type, 'Catecholamine': $i).
% 28.89/28.97  tff(decl_18062, type, 'A class of hormones and neurotransmitters that are synthesized biochemically from the amino acids phenylalanine or tyrosine. Epinephrine, norepinephrine, and dopamine are examples of catecholamines.': $i).
% 28.89/28.97  tff(decl_18063, type, catecholamine: $i).
% 28.89/28.97  tff(decl_18064, type, melatonin_1: $i > $o).
% 28.89/28.97  tff(decl_18065, type, t3_1: $i > $o).
% 28.89/28.97  tff(decl_18066, type, t4_1: $i > $o).
% 28.89/28.97  tff(decl_18067, type, serotonin_1: $i > $o).
% 28.89/28.97  tff(decl_18068, type, categorical_1: $i > $o).
% 28.89/28.97  tff(decl_18069, type, 'Categorical': $i).
% 28.89/28.97  tff(decl_18070, type, categorical: $i).
% 28.89/28.97  tff(decl_18071, type, caterpillar_1: $i > $o).
% 28.89/28.97  tff(decl_18072, type, 'Caterpillar': $i).
% 28.89/28.97  tff(decl_18073, type, 'Larval form of insect from the order Lepidoptera (moths and butterflies.)': $i).
% 28.89/28.97  tff(decl_18074, type, caterpillar: $i).
% 28.89/28.97  tff(decl_18075, type, fn_caterpillar_1: $i > $i).
% 28.89/28.97  tff(decl_18076, type, fn_caterpillar_2: $i > $i).
% 28.89/28.97  tff(decl_18077, type, fn_caterpillar_3: $i > $i).
% 28.89/28.97  tff(decl_18078, type, fn_caterpillar_4: $i > $i).
% 28.89/28.97  tff(decl_18079, type, substrate_feeder_1: $i > $o).
% 28.89/28.97  tff(decl_18080, type, fn_caterpillar_7: $i > $i).
% 28.89/28.97  tff(decl_18081, type, fn_caterpillar_8: $i > $i).
% 28.89/28.97  tff(decl_18082, type, fn_caterpillar_9: $i > $i).
% 28.89/28.97  tff(decl_18083, type, fn_caterpillar_10: $i > $i).
% 28.89/28.97  tff(decl_18084, type, fn_caterpillar_11: $i > $i).
% 28.89/28.97  tff(decl_18085, type, fn_caterpillar_12: $i > $i).
% 28.89/28.97  tff(decl_18086, type, fn_caterpillar_13: $i > $i).
% 28.89/28.97  tff(decl_18087, type, fn_caterpillar_14: $i > $i).
% 28.89/28.97  tff(decl_18088, type, fn_caterpillar_15: $i > $i).
% 28.89/28.97  tff(decl_18089, type, fn_caterpillar_16: $i > $i).
% 28.89/28.97  tff(decl_18090, type, fn_caterpillar_17: $i > $i).
% 28.89/28.97  tff(decl_18091, type, fn_caterpillar_18: $i > $i).
% 28.89/28.97  tff(decl_18092, type, fn_caterpillar_19: $i > $i).
% 28.89/28.97  tff(decl_18093, type, gastric_cecum_1: $i > $o).
% 28.89/28.97  tff(decl_18094, type, fn_caterpillar_20: $i > $i).
% 28.89/28.97  tff(decl_18095, type, fn_caterpillar_21: $i > $i).
% 28.89/28.97  tff(decl_18096, type, fn_caterpillar_22: $i > $i).
% 28.89/28.97  tff(decl_18097, type, fn_caterpillar_23: $i > $i).
% 28.89/28.97  tff(decl_18098, type, foregut_1: $i > $o).
% 28.89/28.97  tff(decl_18099, type, fn_caterpillar_24: $i > $i).
% 28.89/28.97  tff(decl_18100, type, midgut_1: $i > $o).
% 28.89/28.97  tff(decl_18101, type, fn_caterpillar_25: $i > $i).
% 28.89/28.97  tff(decl_18102, type, hindgut_1: $i > $o).
% 28.89/28.97  tff(decl_18103, type, fn_caterpillar_26: $i > $i).
% 28.89/28.97  tff(decl_18104, type, fn_caterpillar_27: $i > $i).
% 28.89/28.97  tff(decl_18105, type, fn_caterpillar_28: $i > $i).
% 28.89/28.97  tff(decl_18106, type, fn_caterpillar_29: $i > $i).
% 28.89/28.97  tff(decl_18107, type, fn_caterpillar_30: $i > $i).
% 28.89/28.97  tff(decl_18108, type, fn_caterpillar_31: $i > $i).
% 28.89/28.97  tff(decl_18109, type, fn_caterpillar_32: $i > $i).
% 28.89/28.97  tff(decl_18110, type, fn_caterpillar_33: $i > $i).
% 28.89/28.97  tff(decl_18111, type, fn_caterpillar_34: $i > $i).
% 28.89/28.97  tff(decl_18112, type, feed_1: $i > $o).
% 28.89/28.97  tff(decl_18113, type, fn_caterpillar_35: $i > $i).
% 28.89/28.97  tff(decl_18114, type, fn_caterpillar_36: $i > $i).
% 28.89/28.97  tff(decl_18115, type, fn_feed_4: $i > $i).
% 28.89/28.97  tff(decl_18116, type, fn_insect_20: $i > $i).
% 28.89/28.97  tff(decl_18117, type, fn_insect_16: $i > $i).
% 28.89/28.97  tff(decl_18118, type, fn_insect_15: $i > $i).
% 28.89/28.97  tff(decl_18119, type, fn_insect_22: $i > $i).
% 28.89/28.97  tff(decl_18120, type, fn_insect_23: $i > $i).
% 28.89/28.97  tff(decl_18121, type, fn_insect_25: $i > $i).
% 28.89/28.97  tff(decl_18122, type, fn_insect_5: $i > $i).
% 28.89/28.97  tff(decl_18123, type, fn_insect_17: $i > $i).
% 28.89/28.97  tff(decl_18124, type, fn_insect_21: $i > $i).
% 28.89/28.97  tff(decl_18125, type, fn_insect_18: $i > $i).
% 28.89/28.97  tff(decl_18126, type, fn_insect_11: $i > $i).
% 28.89/28.97  tff(decl_18127, type, fn_insect_13: $i > $i).
% 28.89/28.97  tff(decl_18128, type, fn_insect_12: $i > $i).
% 28.89/28.97  tff(decl_18129, type, fn_insect_6: $i > $i).
% 28.89/28.97  tff(decl_18130, type, fn_insect_3: $i > $i).
% 28.89/28.97  tff(decl_18131, type, fn_insect_4: $i > $i).
% 28.89/28.97  tff(decl_18132, type, fn_insect_14: $i > $i).
% 28.89/28.97  tff(decl_18133, type, fn_insect_9: $i > $i).
% 28.89/28.97  tff(decl_18134, type, fn_insect_19: $i > $i).
% 28.89/28.97  tff(decl_18135, type, 'Cation': $i).
% 28.89/28.97  tff(decl_18136, type, 'An ion that carries a positive charge due to a shortage of electrons.': $i).
% 28.89/28.97  tff(decl_18137, type, cation: $i).
% 28.89/28.97  tff(decl_18138, type, fn_cation_3: $i > $i).
% 28.89/28.97  tff(decl_18139, type, fn_cation_6: $i > $i).
% 28.89/28.97  tff(decl_18140, type, fn_cation_8: $i > $i).
% 28.89/28.97  tff(decl_18141, type, fn_cation_2: $i > $i).
% 28.89/28.97  tff(decl_18142, type, 'Cation-Substance': $i).
% 28.89/28.97  tff(decl_18143, type, 'substance of cation': $i).
% 28.89/28.97  tff(decl_18144, type, 'cation substance': $i).
% 28.89/28.97  tff(decl_18145, type, 'cation-substance': $i).
% 28.89/28.97  tff(decl_18146, type, fn_cation_substance_1: $i > $i).
% 28.89/28.97  tff(decl_18147, type, causal_relation_1: $i > $o).
% 28.89/28.97  tff(decl_18148, type, 'Causal-Relation': $i).
% 28.89/28.97  tff(decl_18149, type, 'A causal relation is a relation between two events, where one event enables or opposes the other. If a relation is a causal relation, then its inverse is also a causal relation.': $i).
% 28.89/28.97  tff(decl_18150, type, 'causal relation': $i).
% 28.89/28.97  tff(decl_18151, type, 'causal-relation': $i).
% 28.89/28.97  tff(decl_18152, type, cavitation_1: $i > $o).
% 28.89/28.97  tff(decl_18153, type, 'Cavitation': $i).
% 28.89/28.97  tff(decl_18154, type, 'The blocking of flow of xylem sap in vascular plants due to formation of bubbles in the xylem caused by drought or freezing.': $i).
% 28.89/28.97  tff(decl_18155, type, 'form a cavity': $i).
% 28.89/28.97  tff(decl_18156, type, cavitation: $i).
% 28.89/28.97  tff(decl_18157, type, physical_process_1: $i > $o).
% 28.89/28.97  tff(decl_18158, type, fn_cavitation_1: $i > $i).
% 28.89/28.97  tff(decl_18159, type, fn_cavitation_2: $i > $i).
% 28.89/28.97  tff(decl_18160, type, fn_cavitation_3: $i > $i).
% 28.89/28.97  tff(decl_18161, type, water_transport_in_plant_1: $i > $o).
% 28.89/28.97  tff(decl_18162, type, fn_cavitation_4: $i > $i).
% 28.89/28.97  tff(decl_18163, type, fn_cavitation_5: $i > $i).
% 28.89/28.97  tff(decl_18164, type, fn_cavitation_6: $i > $i).
% 28.89/28.97  tff(decl_18165, type, fn_cavitation_7: $i > $i).
% 28.89/28.97  tff(decl_18166, type, cortex_1: $i > $o).
% 28.89/28.97  tff(decl_18167, type, fn_cavitation_8: $i > $i).
% 28.89/28.97  tff(decl_18168, type, fn_cavitation_9: $i > $i).
% 28.89/28.97  tff(decl_18169, type, fn_cavitation_10: $i > $i).
% 28.89/28.97  tff(decl_18170, type, fn_water_transport_in_plant_5: $i > $i).
% 28.89/28.97  tff(decl_18171, type, fn_water_transport_in_plant_6: $i > $i).
% 28.89/28.97  tff(decl_18172, type, fn_root_13: $i > $i).
% 28.89/28.97  tff(decl_18173, type, fn_root_27: $i > $i).
% 28.89/28.97  tff(decl_18174, type, fn_root_30: $i > $i).
% 28.89/28.97  tff(decl_18175, type, 'Cavity': $i).
% 28.89/28.97  tff(decl_18176, type, 'An empty space within a solid object. In some cases a cavity is completely enclosed, and in other cases it may be open on one side.': $i).
% 28.89/28.97  tff(decl_18177, type, pit: $i).
% 28.89/28.97  tff(decl_18178, type, groove: $i).
% 28.89/28.97  tff(decl_18179, type, pocket: $i).
% 28.89/28.97  tff(decl_18180, type, cavity: $i).
% 28.89/28.97  tff(decl_18181, type, cd4_1: $i > $o).
% 28.89/28.97  tff(decl_18182, type, 'CD4': $i).
% 28.89/28.97  tff(decl_18183, type, 'A surface protein, present on most helper T cells, that binds to class II MHC molecules, enhancing the interaction between the T cell and an antigen-presenting cell.': $i).
% 28.89/28.97  tff(decl_18184, type, cd4: $i).
% 28.89/28.97  tff(decl_18185, type, cd8_1: $i > $o).
% 28.89/28.97  tff(decl_18186, type, 'CD8': $i).
% 28.89/28.97  tff(decl_18187, type, 'A surface protein, present on most cytotoxic T cells, that binds to class I MHC molecules, enhancing the interaction between the T cell and a target cell.': $i).
% 28.89/28.97  tff(decl_18188, type, cd8: $i).
% 28.89/28.97  tff(decl_18189, type, cdna_1: $i > $o).
% 28.89/28.97  tff(decl_18190, type, 'CDNA': $i).
% 28.89/28.97  tff(decl_18191, type, 'DNA that is synthesized from an RNA transcript by the action of the enzyme Reverse Transcriptase. CDNA corresponds to the exons of a gene.': $i).
% 28.89/28.97  tff(decl_18192, type, 'complementary dna': $i).
% 28.89/28.97  tff(decl_18193, type, 'eukaryotic dna without introns': $i).
% 28.89/28.97  tff(decl_18194, type, 'dna without introns': $i).
% 28.89/28.97  tff(decl_18195, type, 'coding dna': $i).
% 28.89/28.97  tff(decl_18196, type, 'coding sequence of dna': $i).
% 28.89/28.97  tff(decl_18197, type, 'coding sequence': $i).
% 28.89/28.97  tff(decl_18198, type, 'complementary-dna': $i).
% 28.89/28.97  tff(decl_18199, type, 'complementary dna strand': $i).
% 28.89/28.97  tff(decl_18200, type, 'complementary-dna-strand': $i).
% 28.89/28.97  tff(decl_18201, type, cdna: $i).
% 28.89/28.97  tff(decl_18202, type, fn_cdna_1: $i > $i).
% 28.89/28.97  tff(decl_18203, type, fn_cdna_2: $i > $i).
% 28.89/28.97  tff(decl_18204, type, fn_cdna_3: $i > $i).
% 28.89/28.97  tff(decl_18205, type, cdna_library_1: $i > $o).
% 28.89/28.97  tff(decl_18206, type, 'CDNA-Library': $i).
% 28.89/28.97  tff(decl_18207, type, 'A gene library containing clones that carry complementary DNA (cDNA) inserts. The library includes only the genes that were transcribed in the cells whose mRNA was isolated to make the cDNA.': $i).
% 28.89/28.97  tff(decl_18208, type, 'library of cdna': $i).
% 28.89/28.97  tff(decl_18209, type, 'cdna library': $i).
% 28.89/28.97  tff(decl_18210, type, 'cdna-library': $i).
% 28.89/28.97  tff(decl_18211, type, dna_library_1: $i > $o).
% 28.89/28.97  tff(decl_18212, type, genetic_code_1: $i > $o).
% 28.89/28.97  tff(decl_18213, type, suggestion_1: $i > $o).
% 28.89/28.97  tff(decl_18214, type, request_1: $i > $o).
% 28.89/28.97  tff(decl_18215, type, information_sequence_1: $i > $o).
% 28.89/28.97  tff(decl_18216, type, classification_unit_1: $i > $o).
% 28.89/28.97  tff(decl_18217, type, ethics_1: $i > $o).
% 28.89/28.97  tff(decl_18218, type, fossil_record_1: $i > $o).
% 28.89/28.97  tff(decl_18219, type, fn_cdna_library_1: $i > $i).
% 28.89/28.97  tff(decl_18220, type, fn_cdna_library_2: $i > $i).
% 28.89/28.97  tff(decl_18221, type, fn_cdna_library_3: $i > $i).
% 28.89/28.97  tff(decl_18222, type, fn_cdna_library_4: $i > $i).
% 28.89/28.97  tff(decl_18223, type, reverse_transcription_1: $i > $o).
% 28.89/28.97  tff(decl_18224, type, fn_cdna_library_5: $i > $i).
% 28.89/28.97  tff(decl_18225, type, fn_cdna_library_6: $i > $i).
% 28.89/28.97  tff(decl_18226, type, fn_cdna_library_7: $i > $i).
% 28.89/28.97  tff(decl_18227, type, fn_cdna_library_8: $i > $i).
% 28.89/28.97  tff(decl_18228, type, fn_polymer_synthesis_23: $i > $i).
% 28.89/28.97  tff(decl_18229, type, cecum_1: $i > $o).
% 28.89/28.97  tff(decl_18230, type, 'Cecum': $i).
% 28.89/28.97  tff(decl_18231, type, 'A blind-ending sac at the proximal end of the large intestine.': $i).
% 28.89/28.97  tff(decl_18232, type, ceca: $i).
% 28.89/28.97  tff(decl_18233, type, cecum: $i).
% 28.89/28.97  tff(decl_18234, type, ced_3_1: $i > $o).
% 28.89/28.97  tff(decl_18235, type, 'Ced-3': $i).
% 28.89/28.97  tff(decl_18236, type, 'Programmed cell death in the nematode C.elegans require ced-3 caspase activity.': $i).
% 28.89/28.97  tff(decl_18237, type, 'ced 3 caspase': $i).
% 28.89/28.97  tff(decl_18238, type, 'ced-3 caspase': $i).
% 28.89/28.97  tff(decl_18239, type, 'ced 3': $i).
% 28.89/28.97  tff(decl_18240, type, 'ced-3': $i).
% 28.89/28.97  tff(decl_18241, type, ced_3_gene_1: $i > $o).
% 28.89/28.97  tff(decl_18242, type, 'Ced-3-Gene': $i).
% 28.89/28.97  tff(decl_18243, type, 'Gene, first identified in C. elegans, which encodes the enzyme Caspase 3 (CED-3).': $i).
% 28.89/28.97  tff(decl_18244, type, 'ced 3 gene': $i).
% 28.89/28.97  tff(decl_18245, type, 'ced-3-gene': $i).
% 28.89/28.97  tff(decl_18246, type, fn_ced_3_gene_1: $i > $i).
% 28.89/28.97  tff(decl_18247, type, fn_ced_3_gene_2: $i > $i).
% 28.89/28.97  tff(decl_18248, type, ced_4_1: $i > $o).
% 28.89/28.97  tff(decl_18249, type, 'Ced-4': $i).
% 28.89/28.97  tff(decl_18250, type, 'Protein, first identified in C. elegans, which functions in signal transduction in the apoptosis pathway.': $i).
% 28.89/28.97  tff(decl_18251, type, 'ced 4': $i).
% 28.89/28.97  tff(decl_18252, type, 'ced-4': $i).
% 28.89/28.97  tff(decl_18253, type, ced_4_gene_1: $i > $o).
% 28.89/28.97  tff(decl_18254, type, 'Ced-4-Gene': $i).
% 28.89/28.97  tff(decl_18255, type, 'Gene, first identified in C. elegans, which encodes the enzyme Caspase 4 (CED-4).': $i).
% 28.89/28.97  tff(decl_18256, type, 'ced 4 gene': $i).
% 28.89/28.97  tff(decl_18257, type, 'ced-4-gene': $i).
% 28.89/28.97  tff(decl_18258, type, fn_ced_4_gene_1: $i > $i).
% 28.89/28.97  tff(decl_18259, type, fn_ced_4_gene_2: $i > $i).
% 28.89/28.97  tff(decl_18260, type, ced_9_1: $i > $o).
% 28.89/28.97  tff(decl_18261, type, 'Ced-9': $i).
% 28.89/28.97  tff(decl_18262, type, 'Protein, first identified in C. elegans, which functions as a master switch in signal transduction of the apoptosis pathway.': $i).
% 28.89/28.97  tff(decl_18263, type, 'ced 9': $i).
% 28.89/28.97  tff(decl_18264, type, 'ced-9': $i).
% 28.89/28.97  tff(decl_18265, type, 'Ceiling': $i).
% 28.89/28.97  tff(decl_18266, type, 'a horizontal architectural structure covering a room': $i).
% 28.89/28.97  tff(decl_18267, type, ceiling: $i).
% 28.89/28.97  tff(decl_18268, type, fn_ceiling_2: $i > $i).
% 28.89/28.97  tff(decl_18269, type, fn_ceiling_3: $i > $i).
% 28.89/28.97  tff(decl_18270, type, fn_ceiling_4: $i > $i).
% 28.89/28.97  tff(decl_18271, type, cover_1: $i > $o).
% 28.89/28.97  tff(decl_18272, type, entity_0: $i).
% 28.89/28.97  tff(decl_18273, type, celestial_body_1: $i > $o).
% 28.89/28.97  tff(decl_18274, type, 'Celestial-Body': $i).
% 28.89/28.97  tff(decl_18275, type, 'Objects of or relating to the sky.': $i).
% 28.89/28.97  tff(decl_18276, type, 'heavenly body': $i).
% 28.89/28.97  tff(decl_18277, type, 'heavenly-body': $i).
% 28.89/28.97  tff(decl_18278, type, 'celestial body': $i).
% 28.89/28.97  tff(decl_18279, type, 'celestial-body': $i).
% 28.89/28.97  tff(decl_18280, type, 'Cell': $i).
% 28.89/28.97  tff(decl_18281, type, 'The basic unit from which living organisms are made, consisting of an aqueous solution of organic molecules enclosed by a membrane.  All cells arise from existing cells, usually by a process of division into two.  (Alberts:ECB:G-3).': $i).
% 28.89/28.97  tff(decl_18282, type, 'The basic unit from which living organisms are made.': $i).
% 28.89/28.97  tff(decl_18283, type, cell: $i).
% 28.89/28.97  tff(decl_18284, type, fn_cell_5: $i > $i).
% 28.89/28.97  tff(decl_18285, type, fn_cell_7: $i > $i).
% 28.89/28.97  tff(decl_18286, type, fn_cell_13: $i > $i).
% 28.89/28.97  tff(decl_18287, type, fn_cell_18: $i > $i).
% 28.89/28.97  tff(decl_18288, type, fn_cell_19: $i > $i).
% 28.89/28.97  tff(decl_18289, type, fn_cell_20: $i > $i).
% 28.89/28.97  tff(decl_18290, type, fn_cell_21: $i > $i).
% 28.89/28.97  tff(decl_18291, type, cell_pole_0: $i).
% 28.89/28.97  tff(decl_18292, type, chromosome_0: $i).
% 28.89/28.97  tff(decl_18293, type, "0.1e0": $i).
% 28.89/28.97  tff(decl_18294, type, organism_0: $i).
% 28.89/28.97  tff(decl_18295, type, cell_adhesion_molecule_1: $i > $o).
% 28.89/28.97  tff(decl_18296, type, 'Cell-Adhesion-Molecule': $i).
% 28.89/28.97  tff(decl_18297, type, 'A transmembrane, cell-surface glycoprotein that binds to CAMs on other cells. The resulting cell-to-cell attachments contribute to stable tissue structure.': $i).
% 28.89/28.97  tff(decl_18298, type, 'cell adhesion molecule': $i).
% 28.89/28.97  tff(decl_18299, type, 'cell-adhesion-molecule': $i).
% 28.89/28.97  tff(decl_18300, type, glycoprotein_hormone_1: $i > $o).
% 28.89/28.97  tff(decl_18301, type, peptidoglycan_1: $i > $o).
% 28.89/28.97  tff(decl_18302, type, proteoglycan_1: $i > $o).
% 28.89/28.97  tff(decl_18303, type, fn_cell_adhesion_molecule_1: $i > $i).
% 28.89/28.97  tff(decl_18304, type, fn_cell_adhesion_molecule_2: $i > $i).
% 28.89/28.97  tff(decl_18305, type, fn_cell_adhesion_molecule_3: $i > $i).
% 28.89/28.97  tff(decl_18306, type, fn_cell_adhesion_molecule_4: $i > $i).
% 28.89/28.97  tff(decl_18307, type, fn_cell_adhesion_molecule_9: $i > $i).
% 28.89/28.97  tff(decl_18308, type, fn_cell_adhesion_molecule_10: $i > $i).
% 28.89/28.97  tff(decl_18309, type, fn_cell_adhesion_molecule_11: $i > $i).
% 28.89/28.97  tff(decl_18310, type, fn_cell_adhesion_molecule_12: $i > $i).
% 28.89/28.97  tff(decl_18311, type, fn_cell_adhesion_molecule_13: $i > $i).
% 28.89/28.97  tff(decl_18312, type, fn_cell_adhesion_molecule_14: $i > $i).
% 28.89/28.97  tff(decl_18313, type, fn_cell_adhesion_molecule_15: $i > $i).
% 28.89/28.97  tff(decl_18314, type, fn_cell_adhesion_molecule_16: $i > $i).
% 28.89/28.97  tff(decl_18315, type, fn_cell_adhesion_molecule_17: $i > $i).
% 28.89/28.97  tff(decl_18316, type, fn_cell_adhesion_molecule_18: $i > $i).
% 28.89/28.97  tff(decl_18317, type, fn_cell_adhesion_molecule_19: $i > $i).
% 28.89/28.97  tff(decl_18318, type, fn_cell_adhesion_molecule_20: $i > $i).
% 28.89/28.97  tff(decl_18319, type, fn_cell_adhesion_molecule_21: $i > $i).
% 28.89/28.97  tff(decl_18320, type, fn_cell_adhesion_molecule_22: $i > $i).
% 28.89/28.97  tff(decl_18321, type, fn_cell_adhesion_molecule_23: $i > $i).
% 28.89/28.97  tff(decl_18322, type, fn_cell_adhesion_molecule_24: $i > $i).
% 28.89/28.97  tff(decl_18323, type, fn_cell_adhesion_molecule_25: $i > $i).
% 28.89/28.97  tff(decl_18324, type, fn_cell_adhesion_molecule_26: $i > $i).
% 28.89/28.97  tff(decl_18325, type, fn_cell_adhesion_molecule_27: $i > $i).
% 28.89/28.97  tff(decl_18326, type, fn_cell_adhesion_molecule_28: $i > $i).
% 28.89/28.97  tff(decl_18327, type, fn_cell_adhesion_molecule_29: $i > $i).
% 28.89/28.97  tff(decl_18328, type, fn_cell_adhesion_molecule_30: $i > $i).
% 28.89/28.97  tff(decl_18329, type, fn_cell_adhesion_molecule_31: $i > $i).
% 28.89/28.97  tff(decl_18330, type, fn_integral_protein_33: $i > $i).
% 28.89/28.97  tff(decl_18331, type, fn_integral_protein_31: $i > $i).
% 28.89/28.97  tff(decl_18332, type, fn_integral_protein_5: $i > $i).
% 28.89/28.97  tff(decl_18333, type, fn_glycoprotein_18: $i > $i).
% 28.89/28.97  tff(decl_18334, type, fn_transmembrane_protein_3: $i > $i).
% 28.89/28.97  tff(decl_18335, type, fn_cell_adhesion_molecule_8: $i > $i).
% 28.89/28.97  tff(decl_18336, type, fn_glycoprotein_8: $i > $i).
% 28.89/28.97  tff(decl_18337, type, fn_integral_protein_32: $i > $i).
% 28.89/28.97  tff(decl_18338, type, fn_glycoprotein_1: $i > $i).
% 28.89/28.97  tff(decl_18339, type, fn_cell_adhesion_molecule_7: $i > $i).
% 28.89/28.97  tff(decl_18340, type, fn_glycoprotein_7: $i > $i).
% 28.89/28.97  tff(decl_18341, type, fn_cell_adhesion_molecule_6: $i > $i).
% 28.89/28.97  tff(decl_18342, type, fn_glycoprotein_6: $i > $i).
% 28.89/28.97  tff(decl_18343, type, fn_glycoprotein_11: $i > $i).
% 28.89/28.97  tff(decl_18344, type, fn_integral_protein_15: $i > $i).
% 28.89/28.97  tff(decl_18345, type, fn_glycoprotein_22: $i > $i).
% 28.89/28.97  tff(decl_18346, type, fn_integral_protein_19: $i > $i).
% 28.89/28.97  tff(decl_18347, type, fn_glycoprotein_21: $i > $i).
% 28.89/28.97  tff(decl_18348, type, fn_integral_protein_18: $i > $i).
% 28.89/28.97  tff(decl_18349, type, fn_glycoprotein_20: $i > $i).
% 28.89/28.97  tff(decl_18350, type, fn_integral_protein_17: $i > $i).
% 28.89/28.97  tff(decl_18351, type, fn_glycoprotein_23: $i > $i).
% 28.89/28.97  tff(decl_18352, type, fn_integral_protein_28: $i > $i).
% 28.89/28.97  tff(decl_18353, type, fn_glycoprotein_26: $i > $i).
% 28.89/28.97  tff(decl_18354, type, fn_integral_protein_14: $i > $i).
% 28.89/28.97  tff(decl_18355, type, fn_glycoprotein_10: $i > $i).
% 28.89/28.97  tff(decl_18356, type, fn_glycoprotein_25: $i > $i).
% 28.89/28.97  tff(decl_18357, type, fn_integral_protein_8: $i > $i).
% 28.89/28.97  tff(decl_18358, type, fn_glycoprotein_24: $i > $i).
% 28.89/28.97  tff(decl_18359, type, fn_cell_adhesion_molecule_5: $i > $i).
% 28.89/28.97  tff(decl_18360, type, fn_glycoprotein_9: $i > $i).
% 28.89/28.97  tff(decl_18361, type, fn_glycoprotein_12: $i > $i).
% 28.89/28.97  tff(decl_18362, type, fn_integral_protein_30: $i > $i).
% 28.89/28.97  tff(decl_18363, type, fn_glycoprotein_19: $i > $i).
% 28.89/28.97  tff(decl_18364, type, fn_integral_protein_13: $i > $i).
% 28.89/28.97  tff(decl_18365, type, fn_integral_protein_21: $i > $i).
% 28.89/28.97  tff(decl_18366, type, 'Cell-Body': $i).
% 28.89/28.97  tff(decl_18367, type, 'The portion of a neuron that houses the nucleus and other organelles but does not transmit nerve impulses.': $i).
% 28.89/28.97  tff(decl_18368, type, 'body of cell': $i).
% 28.89/28.97  tff(decl_18369, type, 'cell body': $i).
% 28.89/28.97  tff(decl_18370, type, 'cell-body': $i).
% 28.89/28.97  tff(decl_18371, type, cell_cell_recognition_1: $i > $o).
% 28.89/28.97  tff(decl_18372, type, 'Cell-Cell-Recognition': $i).
% 28.89/28.97  tff(decl_18373, type, 'Process in which a cell recognizes another cell through direct contact between outer cell structures that initiates a signal transduction event resulting in recognition of the cell being perceived.': $i).
% 28.89/28.97  tff(decl_18374, type, 'cell cell recognition': $i).
% 28.89/28.97  tff(decl_18375, type, 'cell-cell recognition': $i).
% 28.89/28.97  tff(decl_18376, type, recognize: $i).
% 28.89/28.97  tff(decl_18377, type, 'cell-cell-recognition': $i).
% 28.89/28.97  tff(decl_18378, type, fn_cell_cell_recognition_1: $i > $i).
% 28.89/28.97  tff(decl_18379, type, distinguishing_1: $i > $o).
% 28.89/28.97  tff(decl_18380, type, fn_cell_cell_recognition_2: $i > $i).
% 28.89/28.97  tff(decl_18381, type, fn_cell_cell_recognition_3: $i > $i).
% 28.89/28.97  tff(decl_18382, type, fn_cell_cell_recognition_6: $i > $i).
% 28.89/28.97  tff(decl_18383, type, fn_cell_cell_recognition_7: $i > $i).
% 28.89/28.97  tff(decl_18384, type, fn_cell_cell_recognition_8: $i > $i).
% 28.89/28.97  tff(decl_18385, type, fn_cell_cell_recognition_9: $i > $i).
% 28.89/28.97  tff(decl_18386, type, fn_cell_cell_recognition_10: $i > $i).
% 28.89/28.97  tff(decl_18387, type, fn_cell_cell_recognition_11: $i > $i).
% 28.89/28.97  tff(decl_18388, type, fn_cell_cell_recognition_12: $i > $i).
% 28.89/28.97  tff(decl_18389, type, fn_cell_cell_recognition_13: $i > $i).
% 28.89/28.97  tff(decl_18390, type, target_cell_1: $i > $o).
% 28.89/28.97  tff(decl_18391, type, fn_cell_cell_recognition_14: $i > $i).
% 28.89/28.97  tff(decl_18392, type, fn_cell_cell_recognition_15: $i > $i).
% 28.89/28.97  tff(decl_18393, type, fn_cell_cell_recognition_16: $i > $i).
% 28.89/28.97  tff(decl_18394, type, fn_cell_cell_recognition_17: $i > $i).
% 28.89/28.97  tff(decl_18395, type, chemical_marker_1: $i > $o).
% 28.89/28.97  tff(decl_18396, type, fn_cell_cell_recognition_18: $i > $i).
% 28.89/28.97  tff(decl_18397, type, fn_cell_cell_recognition_19: $i > $i).
% 28.89/28.97  tff(decl_18398, type, fn_cell_cell_recognition_20: $i > $i).
% 28.89/28.97  tff(decl_18399, type, fn_cell_cell_recognition_21: $i > $i).
% 28.89/28.97  tff(decl_18400, type, fn_cell_cell_recognition_22: $i > $i).
% 28.89/28.97  tff(decl_18401, type, fn_cell_cell_recognition_23: $i > $i).
% 28.89/28.97  tff(decl_18402, type, fn_cell_cell_recognition_24: $i > $i).
% 28.89/28.97  tff(decl_18403, type, fn_cell_cell_recognition_25: $i > $i).
% 28.89/28.97  tff(decl_18404, type, fn_cell_cell_recognition_26: $i > $i).
% 28.89/28.97  tff(decl_18405, type, fn_cell_cell_recognition_27: $i > $i).
% 28.89/28.97  tff(decl_18406, type, fn_cell_cell_recognition_28: $i > $i).
% 28.89/28.97  tff(decl_18407, type, fn_target_cell_1: $i > $i).
% 28.89/28.97  tff(decl_18408, type, fn_chemical_marker_2: $i > $i).
% 28.89/28.97  tff(decl_18409, type, fn_target_cell_3: $i > $i).
% 28.89/28.97  tff(decl_18410, type, fn_cell_cell_recognition_4: $i > $i).
% 28.89/28.97  tff(decl_18411, type, fn_cell_cell_recognition_5: $i > $i).
% 28.89/28.97  tff(decl_18412, type, 'Cell-Communication': $i).
% 28.89/28.97  tff(decl_18413, type, 'Process of communication between and within cells which involves generation and delivery of a chemical or electrical signal and the series of events leading to a response to that signal.': $i).
% 28.89/28.97  tff(decl_18414, type, communicate: $i).
% 28.89/28.97  tff(decl_18415, type, 'communicate with': $i).
% 28.89/28.97  tff(decl_18416, type, 'communication of cell': $i).
% 28.89/28.97  tff(decl_18417, type, 'cell communication': $i).
% 28.89/28.97  tff(decl_18418, type, 'cell-communication': $i).
% 28.89/28.97  tff(decl_18419, type, fn_cell_communication_1: $i > $i).
% 28.89/28.97  tff(decl_18420, type, fn_cell_communication_3: $i > $i).
% 28.89/28.97  tff(decl_18421, type, fn_cell_communication_4: $i > $i).
% 28.89/28.97  tff(decl_18422, type, fn_cell_communication_5: $i > $i).
% 28.89/28.97  tff(decl_18423, type, fn_signal_generation_4: $i > $i).
% 28.89/28.97  tff(decl_18424, type, fn_cell_signaling_5: $i > $i).
% 28.89/28.97  tff(decl_18425, type, fn_signal_generation_5: $i > $i).
% 28.89/28.97  tff(decl_18426, type, cell_communication_between_neurons_1: $i > $o).
% 28.89/28.97  tff(decl_18427, type, 'Cell-Communication-Between-Neurons': $i).
% 28.89/28.97  tff(decl_18428, type, 'Transmission of a stimulus from one neuron to another through a synapse.': $i).
% 28.89/28.97  tff(decl_18429, type, 'synaptic signaling between neurons': $i).
% 28.89/28.97  tff(decl_18430, type, 'cell communication between neuron': $i).
% 28.89/28.97  tff(decl_18431, type, 'cell-communication-between-neuron': $i).
% 28.89/28.97  tff(decl_18432, type, cell_communication_with_neurotransmitter_1: $i > $o).
% 28.89/28.97  tff(decl_18433, type, fn_cell_communication_between_neurons_1: $i > $i).
% 28.89/28.97  tff(decl_18434, type, fn_cell_communication_between_neurons_2: $i > $i).
% 28.89/28.97  tff(decl_18435, type, receptor_1: $i > $o).
% 28.89/28.97  tff(decl_18436, type, cell_surface_receptor_1: $i > $o).
% 28.89/28.97  tff(decl_18437, type, ligand_gated_ion_channel_1: $i > $o).
% 28.89/28.97  tff(decl_18438, type, fn_cell_communication_between_neurons_3: $i > $i).
% 28.89/28.97  tff(decl_18439, type, cell_signaling_with_plasma_membrane_receptor_1: $i > $o).
% 28.89/28.97  tff(decl_18440, type, cell_signaling_with_ion_channel_receptor_1: $i > $o).
% 28.89/28.97  tff(decl_18441, type, fn_cell_communication_between_neurons_4: $i > $i).
% 28.89/28.97  tff(decl_18442, type, electrical_signaling_1: $i > $o).
% 28.89/28.97  tff(decl_18443, type, fn_cell_communication_between_neurons_5: $i > $i).
% 28.89/28.97  tff(decl_18444, type, fn_cell_communication_between_neurons_6: $i > $i).
% 28.89/28.97  tff(decl_18445, type, signal_transduction_1: $i > $o).
% 28.89/28.97  tff(decl_18446, type, fn_cell_communication_between_neurons_7: $i > $i).
% 28.89/28.97  tff(decl_18447, type, cellular_response_1: $i > $o).
% 28.89/28.97  tff(decl_18448, type, fn_cell_communication_between_neurons_8: $i > $i).
% 28.89/28.97  tff(decl_18449, type, fn_cell_communication_between_neurons_9: $i > $i).
% 28.89/28.97  tff(decl_18450, type, fn_cell_communication_between_neurons_10: $i > $i).
% 28.89/28.97  tff(decl_18451, type, fn_cell_communication_between_neurons_11: $i > $i).
% 28.89/28.97  tff(decl_18452, type, facilitated_diffusion_of_ion_1: $i > $o).
% 28.89/28.97  tff(decl_18453, type, fn_cell_communication_between_neurons_12: $i > $i).
% 28.89/28.97  tff(decl_18454, type, fn_cell_communication_between_neurons_13: $i > $i).
% 28.89/28.97  tff(decl_18455, type, signal_transmission_1: $i > $o).
% 28.89/28.97  tff(decl_18456, type, fn_cell_signaling_with_ion_channel_receptor_29: $i > $i).
% 28.89/28.97  tff(decl_18457, type, fn_electrical_signaling_9: $i > $i).
% 28.89/28.97  tff(decl_18458, type, fn_cell_signaling_with_plasma_membrane_receptor_11: $i > $i).
% 28.89/28.97  tff(decl_18459, type, fn_cell_signaling_with_ion_channel_receptor_32: $i > $i).
% 28.89/28.97  tff(decl_18460, type, fn_cell_signaling_1: $i > $i).
% 28.89/28.97  tff(decl_18461, type, fn_electrical_signaling_4: $i > $i).
% 28.89/28.97  tff(decl_18462, type, fn_cell_signaling_3: $i > $i).
% 28.89/28.97  tff(decl_18463, type, fn_electrical_signaling_5: $i > $i).
% 28.89/28.97  tff(decl_18464, type, fn_cell_signaling_with_plasma_membrane_receptor_15: $i > $i).
% 28.89/28.97  tff(decl_18465, type, fn_cell_signaling_with_ion_channel_receptor_16: $i > $i).
% 28.89/28.97  tff(decl_18466, type, fn_electrical_signaling_8: $i > $i).
% 28.89/28.97  tff(decl_18467, type, fn_electrical_signaling_1: $i > $i).
% 28.89/28.97  tff(decl_18468, type, fn_cell_signaling_with_plasma_membrane_receptor_12: $i > $i).
% 28.89/28.97  tff(decl_18469, type, fn_cell_signaling_with_ion_channel_receptor_20: $i > $i).
% 28.89/28.97  tff(decl_18470, type, fn_electrical_signaling_2: $i > $i).
% 28.89/28.97  tff(decl_18471, type, fn_local_cell_communication_4: $i > $i).
% 28.89/28.97  tff(decl_18472, type, fn_local_cell_communication_7: $i > $i).
% 28.89/28.97  tff(decl_18473, type, fn_cell_communication_with_neurotransmitter_10: $i > $i).
% 28.89/28.97  tff(decl_18474, type, fn_local_cell_communication_5: $i > $i).
% 28.89/28.97  tff(decl_18475, type, fn_cell_communication_with_neurotransmitter_19: $i > $i).
% 28.89/28.97  tff(decl_18476, type, fn_cell_communication_with_neurotransmitter_16: $i > $i).
% 28.89/28.97  tff(decl_18477, type, fn_local_cell_communication_3: $i > $i).
% 28.89/28.97  tff(decl_18478, type, fn_cell_communication_with_neurotransmitter_20: $i > $i).
% 28.89/28.97  tff(decl_18479, type, fn_cell_communication_with_neurotransmitter_11: $i > $i).
% 28.89/28.97  tff(decl_18480, type, fn_cell_communication_with_neurotransmitter_8: $i > $i).
% 28.89/28.97  tff(decl_18481, type, fn_local_cell_communication_6: $i > $i).
% 28.89/28.97  tff(decl_18482, type, fn_cell_communication_with_neurotransmitter_15: $i > $i).
% 28.89/28.97  tff(decl_18483, type, fn_cell_communication_with_neurotransmitter_9: $i > $i).
% 28.89/28.97  tff(decl_18484, type, fn_cell_communication_with_neurotransmitter_13: $i > $i).
% 28.89/28.97  tff(decl_18485, type, cell_communication_between_neurons_leading_to_ion_inflow_1: $i > $o).
% 28.89/28.97  tff(decl_18486, type, 'Cell-Communication-Between-Neurons-Leading-to-Ion-Inflow': $i).
% 28.89/28.97  tff(decl_18487, type, 'Transmission of a stimulus from one neuron to another through a synapse resulting in the inflow of ions to the receiving neuron.': $i).
% 28.89/28.97  tff(decl_18488, type, 'synaptic signaling between neurons leading to ion inflow': $i).
% 28.89/28.97  tff(decl_18489, type, 'cell communication between neurons leading to ion inflow': $i).
% 28.89/28.97  tff(decl_18490, type, 'cell-communication-between-neurons-leading-to-ion-inflow': $i).
% 28.89/28.97  tff(decl_18491, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_1: $i > $i).
% 28.89/28.97  tff(decl_18492, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_2: $i > $i).
% 28.89/28.97  tff(decl_18493, type, chemical_signaling_1: $i > $o).
% 28.89/28.97  tff(decl_18494, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_3: $i > $i).
% 28.89/28.97  tff(decl_18495, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_4: $i > $i).
% 28.89/28.97  tff(decl_18496, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_5: $i > $i).
% 28.89/28.97  tff(decl_18497, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_6: $i > $i).
% 28.89/28.97  tff(decl_18498, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_7: $i > $i).
% 28.89/28.97  tff(decl_18499, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_8: $i > $i).
% 28.89/28.97  tff(decl_18500, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_9: $i > $i).
% 28.89/28.97  tff(decl_18501, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_10: $i > $i).
% 28.89/28.97  tff(decl_18502, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_11: $i > $i).
% 28.89/28.97  tff(decl_18503, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_12: $i > $i).
% 28.89/28.97  tff(decl_18504, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_13: $i > $i).
% 28.89/28.97  tff(decl_18505, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_14: $i > $i).
% 28.89/28.97  tff(decl_18506, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_15: $i > $i).
% 28.89/28.97  tff(decl_18507, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_16: $i > $i).
% 28.89/28.97  tff(decl_18508, type, dna_polymerase_i_1: $i > $o).
% 28.89/28.97  tff(decl_18509, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_17: $i > $i).
% 28.89/28.97  tff(decl_18510, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_18: $i > $i).
% 28.89/28.97  tff(decl_18511, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_19: $i > $i).
% 28.89/28.97  tff(decl_18512, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_20: $i > $i).
% 28.89/28.97  tff(decl_18513, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_21: $i > $i).
% 28.89/28.97  tff(decl_18514, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_22: $i > $i).
% 28.89/28.97  tff(decl_18515, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_23: $i > $i).
% 28.89/28.97  tff(decl_18516, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_24: $i > $i).
% 28.89/28.97  tff(decl_18517, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_25: $i > $i).
% 28.89/28.97  tff(decl_18518, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_26: $i > $i).
% 28.89/28.97  tff(decl_18519, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_27: $i > $i).
% 28.89/28.97  tff(decl_18520, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_28: $i > $i).
% 28.89/28.97  tff(decl_18521, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_29: $i > $i).
% 28.89/28.97  tff(decl_18522, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_30: $i > $i).
% 28.89/28.97  tff(decl_18523, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_31: $i > $i).
% 28.89/28.97  tff(decl_18524, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_32: $i > $i).
% 28.89/28.97  tff(decl_18525, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_33: $i > $i).
% 28.89/28.97  tff(decl_18526, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_34: $i > $i).
% 28.89/28.97  tff(decl_18527, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_35: $i > $i).
% 28.89/28.97  tff(decl_18528, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_36: $i > $i).
% 28.89/28.97  tff(decl_18529, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_39: $i > $i).
% 28.89/28.97  tff(decl_18530, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_40: $i > $i).
% 28.89/28.97  tff(decl_18531, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_41: $i > $i).
% 28.89/28.97  tff(decl_18532, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_42: $i > $i).
% 28.89/28.97  tff(decl_18533, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_43: $i > $i).
% 28.89/28.97  tff(decl_18534, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_44: $i > $i).
% 28.89/28.97  tff(decl_18535, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_45: $i > $i).
% 28.89/28.97  tff(decl_18536, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_46: $i > $i).
% 28.89/28.97  tff(decl_18537, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_47: $i > $i).
% 28.89/28.97  tff(decl_18538, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_48: $i > $i).
% 28.89/28.97  tff(decl_18539, type, fn_gated_channel_26: $i > $i).
% 28.89/28.97  tff(decl_18540, type, fn_gated_channel_32: $i > $i).
% 28.89/28.97  tff(decl_18541, type, fn_gated_channel_37: $i > $i).
% 28.89/28.97  tff(decl_18542, type, fn_gated_channel_29: $i > $i).
% 28.89/28.97  tff(decl_18543, type, fn_gated_channel_6: $i > $i).
% 28.89/28.97  tff(decl_18544, type, fn_gated_channel_22: $i > $i).
% 28.89/28.97  tff(decl_18545, type, fn_gated_channel_40: $i > $i).
% 28.89/28.97  tff(decl_18546, type, fn_gated_channel_24: $i > $i).
% 28.89/28.97  tff(decl_18547, type, fn_nerve_cell_21: $i > $i).
% 28.89/28.97  tff(decl_18548, type, fn_nerve_cell_44: $i > $i).
% 28.89/28.97  tff(decl_18549, type, fn_facilitated_diffusion_of_ion_29: $i > $i).
% 28.89/28.97  tff(decl_18550, type, fn_facilitated_diffusion_28: $i > $i).
% 28.89/28.97  tff(decl_18551, type, fn_ligand_gated_ion_channel_13: $i > $i).
% 28.89/28.97  tff(decl_18552, type, fn_gated_channel_7: $i > $i).
% 28.89/28.97  tff(decl_18553, type, fn_ligand_gated_ion_channel_10: $i > $i).
% 28.89/28.97  tff(decl_18554, type, fn_gated_channel_30: $i > $i).
% 28.89/28.97  tff(decl_18555, type, fn_gated_channel_25: $i > $i).
% 28.89/28.97  tff(decl_18556, type, fn_chemical_signaling_8: $i > $i).
% 28.89/28.97  tff(decl_18557, type, fn_facilitated_diffusion_37: $i > $i).
% 28.89/28.97  tff(decl_18558, type, fn_ligand_gated_ion_channel_9: $i > $i).
% 28.89/28.97  tff(decl_18559, type, fn_cell_signaling_with_ion_channel_receptor_30: $i > $i).
% 28.89/28.97  tff(decl_18560, type, fn_gated_channel_20: $i > $i).
% 28.89/28.97  tff(decl_18561, type, fn_cell_signaling_with_ion_channel_receptor_31: $i > $i).
% 28.89/28.97  tff(decl_18562, type, fn_cell_signaling_with_plasma_membrane_receptor_7: $i > $i).
% 28.89/28.97  tff(decl_18563, type, fn_cell_signaling_with_ion_channel_receptor_17: $i > $i).
% 28.89/28.97  tff(decl_18564, type, fn_facilitated_diffusion_25: $i > $i).
% 28.89/28.97  tff(decl_18565, type, fn_cell_signaling_2: $i > $i).
% 28.89/28.97  tff(decl_18566, type, fn_chemical_signaling_7: $i > $i).
% 28.89/28.97  tff(decl_18567, type, fn_nerve_cell_50: $i > $i).
% 28.89/28.97  tff(decl_18568, type, fn_cell_signaling_with_plasma_membrane_receptor_20: $i > $i).
% 28.89/28.97  tff(decl_18569, type, fn_cell_signaling_with_ion_channel_receptor_9: $i > $i).
% 28.89/28.97  tff(decl_18570, type, fn_cell_signaling_with_ion_channel_receptor_8: $i > $i).
% 28.89/28.97  tff(decl_18571, type, fn_nerve_cell_24: $i > $i).
% 28.89/28.97  tff(decl_18572, type, fn_cell_signaling_with_ion_channel_receptor_28: $i > $i).
% 28.89/28.97  tff(decl_18573, type, fn_nerve_cell_22: $i > $i).
% 28.89/28.97  tff(decl_18574, type, fn_gated_channel_13: $i > $i).
% 28.89/28.97  tff(decl_18575, type, fn_cell_signaling_with_plasma_membrane_receptor_22: $i > $i).
% 28.89/28.97  tff(decl_18576, type, fn_facilitated_diffusion_48: $i > $i).
% 28.89/28.97  tff(decl_18577, type, fn_cell_signaling_with_ion_channel_receptor_10: $i > $i).
% 28.89/28.97  tff(decl_18578, type, fn_nerve_cell_31: $i > $i).
% 28.89/28.97  tff(decl_18579, type, fn_cell_surface_receptor_1: $i > $i).
% 28.89/28.97  tff(decl_18580, type, fn_gated_channel_16: $i > $i).
% 28.89/28.97  tff(decl_18581, type, fn_cell_signaling_with_plasma_membrane_receptor_23: $i > $i).
% 28.89/28.97  tff(decl_18582, type, fn_facilitated_diffusion_49: $i > $i).
% 28.89/28.97  tff(decl_18583, type, fn_nerve_cell_35: $i > $i).
% 28.89/28.97  tff(decl_18584, type, fn_nerve_cell_43: $i > $i).
% 28.89/28.97  tff(decl_18585, type, fn_cellular_response_3: $i > $i).
% 28.89/28.97  tff(decl_18586, type, fn_eukaryotic_cell_4: $i > $i).
% 28.89/28.97  tff(decl_18587, type, fn_cellular_response_1: $i > $i).
% 28.89/28.97  tff(decl_18588, type, fn_chemical_signaling_6: $i > $i).
% 28.89/28.97  tff(decl_18589, type, fn_facilitated_diffusion_of_ion_23: $i > $i).
% 28.89/28.97  tff(decl_18590, type, fn_nerve_cell_51: $i > $i).
% 28.89/28.97  tff(decl_18591, type, fn_facilitated_diffusion_31: $i > $i).
% 28.89/28.97  tff(decl_18592, type, fn_gated_channel_19: $i > $i).
% 28.89/28.97  tff(decl_18593, type, fn_gated_channel_21: $i > $i).
% 28.89/28.97  tff(decl_18594, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_37: $i > $i).
% 28.89/28.97  tff(decl_18595, type, fn_cell_communication_between_neurons_leading_to_ion_inflow_38: $i > $i).
% 28.89/28.97  tff(decl_18596, type, fn_cell_communication_with_neurotransmitter_1: $i > $i).
% 28.89/28.97  tff(decl_18597, type, fn_cell_communication_with_neurotransmitter_17: $i > $i).
% 28.89/28.97  tff(decl_18598, type, fn_cell_communication_with_neurotransmitter_7: $i > $i).
% 28.89/28.97  tff(decl_18599, type, fn_cell_communication_with_neurotransmitter_14: $i > $i).
% 28.89/28.97  tff(decl_18600, type, cell_communication_between_neurons_leading_to_ion_outflow_1: $i > $o).
% 28.89/28.97  tff(decl_18601, type, 'Cell-Communication-Between-Neurons-Leading-to-Ion-Outflow': $i).
% 28.89/28.97  tff(decl_18602, type, 'Transmission of a stimulus from one neuron to another through a synapse resulting in the outflow of ions from the receiving neuron.': $i).
% 28.89/28.97  tff(decl_18603, type, 'synaptic signaling between neurons leading to ion outflow': $i).
% 28.89/28.97  tff(decl_18604, type, 'cell communication between neurons leading to ion outflow': $i).
% 28.89/28.97  tff(decl_18605, type, 'cell-communication-between-neurons-leading-to-ion-outflow': $i).
% 28.89/28.97  tff(decl_18606, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_1: $i > $i).
% 28.89/28.97  tff(decl_18607, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_2: $i > $i).
% 28.89/28.97  tff(decl_18608, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_3: $i > $i).
% 28.89/28.97  tff(decl_18609, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_4: $i > $i).
% 28.89/28.97  tff(decl_18610, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_5: $i > $i).
% 28.89/28.97  tff(decl_18611, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_6: $i > $i).
% 28.89/28.97  tff(decl_18612, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_7: $i > $i).
% 28.89/28.97  tff(decl_18613, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_8: $i > $i).
% 28.89/28.97  tff(decl_18614, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_9: $i > $i).
% 28.89/28.97  tff(decl_18615, type, gated_ion_channel_1: $i > $o).
% 28.89/28.97  tff(decl_18616, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_10: $i > $i).
% 28.89/28.97  tff(decl_18617, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_11: $i > $i).
% 28.89/28.97  tff(decl_18618, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_12: $i > $i).
% 28.89/28.97  tff(decl_18619, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_13: $i > $i).
% 28.89/28.97  tff(decl_18620, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_14: $i > $i).
% 28.89/28.97  tff(decl_18621, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_15: $i > $i).
% 28.89/28.97  tff(decl_18622, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_16: $i > $i).
% 28.89/28.97  tff(decl_18623, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_17: $i > $i).
% 28.89/28.97  tff(decl_18624, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_18: $i > $i).
% 28.89/28.97  tff(decl_18625, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_19: $i > $i).
% 28.89/28.97  tff(decl_18626, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_20: $i > $i).
% 28.89/28.97  tff(decl_18627, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_21: $i > $i).
% 28.89/28.97  tff(decl_18628, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_22: $i > $i).
% 28.89/28.97  tff(decl_18629, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_23: $i > $i).
% 28.89/28.97  tff(decl_18630, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_24: $i > $i).
% 28.89/28.97  tff(decl_18631, type, fn_cell_communication_between_neurons_leading_to_ion_outflow_25: $i > $i).
% 28.89/28.97  tff(decl_18632, type, fn_facilitated_diffusion_of_ion_26: $i > $i).
% 28.89/28.97  tff(decl_18633, type, fn_gated_ion_channel_5: $i > $i).
% 28.89/28.97  tff(decl_18634, type, fn_gated_channel_3: $i > $i).
% 28.89/28.97  tff(decl_18635, type, fn_facilitated_diffusion_55: $i > $i).
% 28.89/28.97  tff(decl_18636, type, fn_ligand_gated_ion_channel_7: $i > $i).
% 28.89/28.97  tff(decl_18637, type, fn_passive_transport_11: $i > $i).
% 28.89/28.97  tff(decl_18638, type, fn_passive_transport_12: $i > $i).
% 28.89/28.97  tff(decl_18639, type, fn_cytosol_1: $i > $i).
% 28.89/28.97  tff(decl_18640, type, cell_communication_event_1: $i > $o).
% 28.89/28.97  tff(decl_18641, type, 'Cell-Communication-Event': $i).
% 28.89/28.97  tff(decl_18642, type, 'Event which occurs during the process of cell communication.': $i).
% 28.89/28.97  tff(decl_18643, type, 'cell communication event': $i).
% 28.89/28.97  tff(decl_18644, type, 'cell-communication-event': $i).
% 28.89/28.97  tff(decl_18645, type, cell_communication_in_damaged_cell_leading_to_apoptosis_1: $i > $o).
% 28.89/28.97  tff(decl_18646, type, 'Cell-Communication-In-Damaged-Cell-Leading-To-Apoptosis': $i).
% 28.89/28.97  tff(decl_18647, type, 'Process of communication between and within cells which involves generation and delivery of a signal and the series of events leading to apoptosis of a damaged cell.': $i).
% 28.89/28.97  tff(decl_18648, type, 'communicate a death signal': $i).
% 28.89/28.97  tff(decl_18649, type, 'cell communication in damaged cell leading to apoptosis': $i).
% 28.89/28.97  tff(decl_18650, type, 'cell-communication-in-damaged-cell-leading-to-apoptosis': $i).
% 28.89/28.97  tff(decl_18651, type, fn_cell_communication_in_damaged_cell_leading_to_apoptosis_1: $i > $i).
% 28.89/28.97  tff(decl_18652, type, fn_cell_communication_leading_to_apoptosis_4: $i > $i).
% 28.89/28.97  tff(decl_18653, type, cell_communication_in_infected_cell_leading_to_apoptosis_1: $i > $o).
% 28.89/28.97  tff(decl_18654, type, 'Cell-Communication-In-Infected-Cell-Leading-To-Apoptosis': $i).
% 28.89/28.97  tff(decl_18655, type, 'Process of communication between and within cells which involves generation and delivery of a signal and the series of events leading to apoptosis of an infected cell.': $i).
% 28.89/28.97  tff(decl_18656, type, 'cell communication in infected cell leading to apoptosis': $i).
% 28.89/28.97  tff(decl_18657, type, 'cell-communication-in-infected-cell-leading-to-apoptosis': $i).
% 28.89/28.97  tff(decl_18658, type, fn_cell_communication_in_infected_cell_leading_to_apoptosis_1: $i > $i).
% 28.89/28.97  tff(decl_18659, type, infected_cell_1: $i > $o).
% 28.89/28.97  tff(decl_18660, type, cell_communication_in_plant_1: $i > $o).
% 28.89/28.97  tff(decl_18661, type, 'Cell-Communication-In-Plant': $i).
% 28.89/28.97  tff(decl_18662, type, 'Process of communication between and within plant cells which involves generation and delivery of a chemical or elictrical signal and the series of events leading to a response to that signal.': $i).
% 28.89/28.97  tff(decl_18663, type, 'cell communication in plant': $i).
% 28.89/28.97  tff(decl_18664, type, 'cell-communication-in-plant': $i).
% 28.89/28.97  tff(decl_18665, type, fn_cell_communication_in_plant_1: $i > $i).
% 28.89/28.97  tff(decl_18666, type, fn_cell_communication_in_plant_2: $i > $i).
% 28.89/28.97  tff(decl_18667, type, fn_cell_communication_in_plant_3: $i > $i).
% 28.89/28.97  tff(decl_18668, type, cell_communication_in_senescent_cell_leading_to_apoptosis_1: $i > $o).
% 28.89/28.97  tff(decl_18669, type, 'Cell-Communication-In-Senescent-Cell-Leading-To-Apoptosis': $i).
% 28.89/28.97  tff(decl_18670, type, 'Process of communication between and within cells which involves generation and delivery of a signal and the series of events leading to apoptosis of an old cell.': $i).
% 28.89/28.97  tff(decl_18671, type, 'cell communication in senescent cell leading to apoptosis': $i).
% 28.89/28.97  tff(decl_18672, type, 'cell-communication-in-senescent-cell-leading-to-apoptosis': $i).
% 28.89/28.97  tff(decl_18673, type, fn_cell_communication_in_senescent_cell_leading_to_apoptosis_1: $i > $i).
% 28.89/28.97  tff(decl_18674, type, senescent_cell_1: $i > $o).
% 28.89/28.97  tff(decl_18675, type, 'Cell-Communication-Leading-To-Apoptosis': $i).
% 28.89/28.97  tff(decl_18676, type, 'Process of communication between and within cells which involves generation and delivery of a  signal and the series of events leading to apoptosis, the response to the signal.': $i).
% 28.89/28.97  tff(decl_18677, type, 'cell communication leading to apoptosis': $i).
% 28.89/28.97  tff(decl_18678, type, 'cell-communication-leading-to-apoptosis': $i).
% 28.89/28.97  tff(decl_18679, type, fn_cell_communication_leading_to_apoptosis_1: $i > $i).
% 28.89/28.97  tff(decl_18680, type, death_signal_1: $i > $o).
% 28.89/28.97  tff(decl_18681, type, fn_cell_communication_leading_to_apoptosis_2: $i > $i).
% 28.89/28.97  tff(decl_18682, type, fn_cell_communication_leading_to_apoptosis_3: $i > $i).
% 28.89/28.97  tff(decl_18683, type, fn_cell_communication_leading_to_apoptosis_5: $i > $i).
% 28.89/28.97  tff(decl_18684, type, fn_cell_communication_leading_to_apoptosis_6: $i > $i).
% 28.89/28.97  tff(decl_18685, type, 'Cell-Communication-Leading-To-Apoptosis-In-Caenorhabditis-Elegans': $i).
% 28.89/28.97  tff(decl_18686, type, 'Process of communication between and within cells of C. elegans which involves generation and delivery of a  signal and the series of events leading to apoptosis, the response to the signal.': $i).
% 28.89/28.97  tff(decl_18687, type, 'cell communication leading to apoptosis in caenorhabditis elegan': $i).
% 28.89/28.97  tff(decl_18688, type, 'cell-communication-leading-to-apoptosis-in-caenorhabditis-elegan': $i).
% 28.89/28.97  tff(decl_18689, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_8: $i > $i).
% 28.89/28.97  tff(decl_18690, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_9: $i > $i).
% 28.89/28.97  tff(decl_18691, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_10: $i > $i).
% 28.89/28.97  tff(decl_18692, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_11: $i > $i).
% 28.89/28.97  tff(decl_18693, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_12: $i > $i).
% 28.89/28.97  tff(decl_18694, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_13: $i > $i).
% 28.89/28.97  tff(decl_18695, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_14: $i > $i).
% 28.89/28.97  tff(decl_18696, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_17: $i > $i).
% 28.89/28.97  tff(decl_18697, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_18: $i > $i).
% 28.89/28.97  tff(decl_18698, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_19: $i > $i).
% 28.89/28.97  tff(decl_18699, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_20: $i > $i).
% 28.89/28.97  tff(decl_18700, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_21: $i > $i).
% 28.89/28.97  tff(decl_18701, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_22: $i > $i).
% 28.89/28.97  tff(decl_18702, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_23: $i > $i).
% 28.89/28.97  tff(decl_18703, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_26: $i > $i).
% 28.89/28.97  tff(decl_18704, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_27: $i > $i).
% 28.89/28.97  tff(decl_18705, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_31: $i > $i).
% 28.89/28.97  tff(decl_18706, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_32: $i > $i).
% 28.89/28.97  tff(decl_18707, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_33: $i > $i).
% 28.89/28.97  tff(decl_18708, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_34: $i > $i).
% 28.89/28.97  tff(decl_18709, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_35: $i > $i).
% 28.89/28.97  tff(decl_18710, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_36: $i > $i).
% 28.89/28.97  tff(decl_18711, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_37: $i > $i).
% 28.89/28.97  tff(decl_18712, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_38: $i > $i).
% 28.89/28.97  tff(decl_18713, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_39: $i > $i).
% 28.89/28.97  tff(decl_18714, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_40: $i > $i).
% 28.89/28.97  tff(decl_18715, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_41: $i > $i).
% 28.89/28.97  tff(decl_18716, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_44: $i > $i).
% 28.89/28.97  tff(decl_18717, type, cell_signaling_event_1: $i > $o).
% 28.89/28.97  tff(decl_18718, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_45: $i > $i).
% 28.89/28.97  tff(decl_18719, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_46: $i > $i).
% 28.89/28.97  tff(decl_18720, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_47: $i > $i).
% 28.89/28.97  tff(decl_18721, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_48: $i > $i).
% 28.89/28.97  tff(decl_18722, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_49: $i > $i).
% 28.89/28.97  tff(decl_18723, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_50: $i > $i).
% 28.89/28.97  tff(decl_18724, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_52: $i > $i).
% 28.89/28.97  tff(decl_18725, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_54: $i > $i).
% 28.89/28.97  tff(decl_18726, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_55: $i > $i).
% 28.89/28.97  tff(decl_18727, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_56: $i > $i).
% 28.89/28.97  tff(decl_18728, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_57: $i > $i).
% 28.89/28.97  tff(decl_18729, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_58: $i > $i).
% 28.89/28.97  tff(decl_18730, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_59: $i > $i).
% 28.89/28.97  tff(decl_18731, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_60: $i > $i).
% 28.89/28.97  tff(decl_18732, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_61: $i > $i).
% 28.89/28.97  tff(decl_18733, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_62: $i > $i).
% 28.89/28.97  tff(decl_18734, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_63: $i > $i).
% 28.89/28.97  tff(decl_18735, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_64: $i > $i).
% 28.89/28.97  tff(decl_18736, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_65: $i > $i).
% 28.89/28.97  tff(decl_18737, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_66: $i > $i).
% 28.89/28.97  tff(decl_18738, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_67: $i > $i).
% 28.89/28.97  tff(decl_18739, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_68: $i > $i).
% 28.89/28.97  tff(decl_18740, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_69: $i > $i).
% 28.89/28.97  tff(decl_18741, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_70: $i > $i).
% 28.89/28.97  tff(decl_18742, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_71: $i > $i).
% 28.89/28.97  tff(decl_18743, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_73: $i > $i).
% 28.89/28.97  tff(decl_18744, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_74: $i > $i).
% 28.89/28.97  tff(decl_18745, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_75: $i > $i).
% 28.89/28.97  tff(decl_18746, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_76: $i > $i).
% 28.89/28.97  tff(decl_18747, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_77: $i > $i).
% 28.89/28.97  tff(decl_18748, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_78: $i > $i).
% 28.89/28.97  tff(decl_18749, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_79: $i > $i).
% 28.89/28.97  tff(decl_18750, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_80: $i > $i).
% 28.89/28.97  tff(decl_18751, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_81: $i > $i).
% 28.89/28.97  tff(decl_18752, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_82: $i > $i).
% 28.89/28.97  tff(decl_18753, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_83: $i > $i).
% 28.89/28.97  tff(decl_18754, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_84: $i > $i).
% 28.89/28.97  tff(decl_18755, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_85: $i > $i).
% 28.89/28.97  tff(decl_18756, type, fn_signal_transduction_6: $i > $i).
% 28.89/28.97  tff(decl_18757, type, fn_protease_18: $i > $i).
% 28.89/28.97  tff(decl_18758, type, fn_protease_22: $i > $i).
% 28.89/28.97  tff(decl_18759, type, fn_protease_1: $i > $i).
% 28.89/28.97  tff(decl_18760, type, fn_protease_5: $i > $i).
% 28.89/28.97  tff(decl_18761, type, fn_protease_31: $i > $i).
% 28.89/28.97  tff(decl_18762, type, fn_protease_2: $i > $i).
% 28.89/28.97  tff(decl_18763, type, fn_nematode_1: $i > $i).
% 28.89/28.97  tff(decl_18764, type, fn_nematode_3: $i > $i).
% 28.89/28.97  tff(decl_18765, type, fn_nematode_4: $i > $i).
% 28.89/28.97  tff(decl_18766, type, fn_cell_signaling_event_1: $i > $i).
% 28.89/28.97  tff(decl_18767, type, fn_ligand_binding_3: $i > $i).
% 28.89/28.97  tff(decl_18768, type, fn_protease_27: $i > $i).
% 28.89/28.97  tff(decl_18769, type, fn_protease_19: $i > $i).
% 28.89/28.97  tff(decl_18770, type, fn_protease_35: $i > $i).
% 28.89/28.97  tff(decl_18771, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_29: $i > $i).
% 28.89/28.97  tff(decl_18772, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_30: $i > $i).
% 28.89/28.97  tff(decl_18773, type, fn_cell_communication_leading_to_apoptosis_in_caenorhabditis_elegans_28: $i > $i).
% 28.89/28.97  tff(decl_18774, type, cell_communication_leading_to_apoptosis_in_mammal_1: $i > $o).
% 28.89/28.97  tff(decl_18775, type, 'Cell-Communication-Leading-To-Apoptosis-In-Mammal': $i).
% 28.89/28.97  tff(decl_18776, type, 'Process of communication between and within cells of  mammals which involves generation and delivery of a  signal and the series of events leading to apoptosis, the response to the signal.': $i).
% 28.89/28.97  tff(decl_18777, type, 'cell communication leading to apoptosis in mammal': $i).
% 28.89/28.97  tff(decl_18778, type, 'cell-communication-leading-to-apoptosis-in-mammal': $i).
% 28.89/28.97  tff(decl_18779, type, fn_cell_communication_leading_to_apoptosis_in_mammal_1: $i > $i).
% 28.89/28.97  tff(decl_18780, type, fn_cell_communication_leading_to_apoptosis_in_mammal_2: $i > $i).
% 28.89/28.97  tff(decl_18781, type, fn_cell_communication_leading_to_apoptosis_in_mammal_3: $i > $i).
% 28.89/28.97  tff(decl_18782, type, fn_cell_communication_leading_to_apoptosis_in_mammal_4: $i > $i).
% 28.89/28.97  tff(decl_18783, type, fn_cell_communication_leading_to_apoptosis_in_mammal_5: $i > $i).
% 28.89/28.97  tff(decl_18784, type, fn_cell_communication_leading_to_apoptosis_in_mammal_6: $i > $i).
% 28.89/28.97  tff(decl_18785, type, caspase_0: $i).
% 28.89/28.97  tff(decl_18786, type, cell_communication_leading_to_cell_division_1: $i > $o).
% 28.89/28.97  tff(decl_18787, type, 'Cell-Communication-Leading-To-Cell-Division': $i).
% 28.89/28.97  tff(decl_18788, type, 'Process of communication between and within cells which leads to cell division as cellular response.': $i).
% 28.89/28.97  tff(decl_18789, type, 'cell communication leading to cell division': $i).
% 28.89/28.97  tff(decl_18790, type, 'cell-communication-leading-to-cell-division': $i).
% 28.89/28.97  tff(decl_18791, type, cell_communication_with_endocrine_hormone_1: $i > $o).
% 28.89/28.97  tff(decl_18792, type, 'Cell-Communication-With-Endocrine-Hormone': $i).
% 28.89/28.97  tff(decl_18793, type, 'The process of cellular communication in animal cells in which the signal molecule is an endocrine hormone.': $i).
% 28.89/28.97  tff(decl_18794, type, 'hormone signaling': $i).
% 28.89/28.97  tff(decl_18795, type, 'endocrine signaling': $i).
% 28.89/28.97  tff(decl_18796, type, 'cell communication with endocrine hormone': $i).
% 28.89/28.97  tff(decl_18797, type, 'cell-communication-with-endocrine-hormone': $i).
% 28.89/28.97  tff(decl_18798, type, long_distance_cell_communication_1: $i > $o).
% 28.89/28.97  tff(decl_18799, type, fn_cell_communication_with_endocrine_hormone_1: $i > $i).
% 28.89/28.97  tff(decl_18800, type, fn_cell_communication_with_endocrine_hormone_2: $i > $i).
% 28.89/28.97  tff(decl_18801, type, fn_cell_communication_with_endocrine_hormone_3: $i > $i).
% 28.89/28.97  tff(decl_18802, type, fn_cell_communication_with_endocrine_hormone_4: $i > $i).
% 28.89/28.97  tff(decl_18803, type, fn_cell_communication_with_endocrine_hormone_5: $i > $i).
% 28.89/28.97  tff(decl_18804, type, fn_cell_communication_with_endocrine_hormone_6: $i > $i).
% 28.89/28.97  tff(decl_18805, type, fn_cell_communication_with_endocrine_hormone_7: $i > $i).
% 28.89/28.97  tff(decl_18806, type, signal_1: $i > $o).
% 28.89/28.97  tff(decl_18807, type, fn_cell_communication_with_endocrine_hormone_8: $i > $i).
% 28.89/28.97  tff(decl_18808, type, fn_cell_communication_with_endocrine_hormone_9: $i > $i).
% 28.89/28.97  tff(decl_18809, type, fn_cell_communication_with_endocrine_hormone_10: $i > $i).
% 28.89/28.97  tff(decl_18810, type, fn_cell_communication_with_endocrine_hormone_11: $i > $i).
% 28.89/28.97  tff(decl_18811, type, fn_cell_communication_with_endocrine_hormone_12: $i > $i).
% 28.89/28.97  tff(decl_18812, type, endocrine_cell_1: $i > $o).
% 28.89/28.97  tff(decl_18813, type, fn_cell_communication_with_endocrine_hormone_13: $i > $i).
% 28.89/28.97  tff(decl_18814, type, fn_cell_communication_with_endocrine_hormone_14: $i > $i).
% 28.89/28.97  tff(decl_18815, type, fn_cell_communication_with_endocrine_hormone_15: $i > $i).
% 28.89/28.97  tff(decl_18816, type, fn_cell_communication_with_endocrine_hormone_16: $i > $i).
% 28.89/28.97  tff(decl_18817, type, fn_secretory_cell_88: $i > $i).
% 28.89/28.97  tff(decl_18818, type, fn_signal_transmission_1: $i > $i).
% 28.89/28.97  tff(decl_18819, type, fn_transmit_1: $i > $i).
% 28.89/28.97  tff(decl_18820, type, fn_signal_transmission_2: $i > $i).
% 28.89/28.97  tff(decl_18821, type, fn_signal_transmission_3: $i > $i).
% 28.89/28.97  tff(decl_18822, type, fn_secretion_1: $i > $i).
% 28.89/28.97  tff(decl_18823, type, fn_signal_transmission_5: $i > $i).
% 28.89/28.97  tff(decl_18824, type, fn_long_distance_cell_communication_6: $i > $i).
% 28.89/28.97  tff(decl_18825, type, fn_long_distance_cell_communication_3: $i > $i).
% 28.89/28.97  tff(decl_18826, type, fn_long_distance_cell_communication_8: $i > $i).
% 28.89/28.97  tff(decl_18827, type, fn_long_distance_cell_communication_5: $i > $i).
% 28.89/28.97  tff(decl_18828, type, cell_communication_with_endocrine_hormone_leading_to_cell_division_1: $i > $o).
% 28.89/28.97  tff(decl_18829, type, 'Cell-Communication-With-Endocrine-Hormone-Leading-To-Cell-Division': $i).
% 28.89/28.97  tff(decl_18830, type, 'Process of cellular communication  with endocrine hormone messengers between and within cells which leads to cell division as cellular response.': $i).
% 28.89/28.97  tff(decl_18831, type, 'endocrine signaling leading to cell division': $i).
% 28.89/28.97  tff(decl_18832, type, 'cell communication with endocrine hormone leading to cell division': $i).
% 28.89/28.97  tff(decl_18833, type, 'cell-communication-with-endocrine-hormone-leading-to-cell-division': $i).
% 28.89/28.97  tff(decl_18834, type, fn_cell_communication_with_endocrine_hormone_leading_to_cell_division_1: $i > $i).
% 28.89/28.97  tff(decl_18835, type, fn_cell_communication_with_endocrine_hormone_leading_to_cell_division_2: $i > $i).
% 28.89/28.97  tff(decl_18836, type, cell_communication_with_endoplasmic_reticulum_signal_leading_to_apoptosis_1: $i > $o).
% 28.89/28.97  tff(decl_18837, type, 'Cell-Communication-With-Endoplasmic-Reticulum-Signal-Leading-To-Apoptosis': $i).
% 28.89/28.97  tff(decl_18838, type, 'Series of events which leads to programmed cell death (apoptosis) in a cell; in this case, the signal for apoptosis is generated internally by the endoplasmic reticulum.': $i).
% 28.89/28.97  tff(decl_18839, type, 'cell communication with endoplasmic reticulum signal leading to apoptosis': $i).
% 28.89/28.97  tff(decl_18840, type, 'cell-communication-with-endoplasmic-reticulum-signal-leading-to-apoptosis': $i).
% 28.89/28.97  tff(decl_18841, type, fn_cell_communication_with_endoplasmic_reticulum_signal_leading_to_apoptosis_1: $i > $i).
% 28.89/28.97  tff(decl_18842, type, fn_cell_communication_with_endoplasmic_reticulum_signal_leading_to_apoptosis_2: $i > $i).
% 28.89/28.97  tff(decl_18843, type, fn_cell_communication_with_endoplasmic_reticulum_signal_leading_to_apoptosis_3: $i > $i).
% 28.89/28.97  tff(decl_18844, type, fn_cell_communication_with_endoplasmic_reticulum_signal_leading_to_apoptosis_4: $i > $i).
% 28.89/28.97  tff(decl_18845, type, fn_cell_communication_with_endoplasmic_reticulum_signal_leading_to_apoptosis_5: $i > $i).
% 28.89/28.97  tff(decl_18846, type, fn_cell_communication_with_endoplasmic_reticulum_signal_leading_to_apoptosis_6: $i > $i).
% 28.89/28.97  tff(decl_18847, type, fn_cell_communication_with_endoplasmic_reticulum_signal_leading_to_apoptosis_7: $i > $i).
% 28.89/28.97  tff(decl_18848, type, fn_cell_communication_with_endoplasmic_reticulum_signal_leading_to_apoptosis_8: $i > $i).
% 28.89/28.97  tff(decl_18849, type, misfolded_protein_1: $i > $o).
% 28.89/28.97  tff(decl_18850, type, cell_communication_with_epinephrine_1: $i > $o).
% 28.89/28.97  tff(decl_18851, type, 'Cell-Communication-With-Epinephrine': $i).
% 28.89/28.97  tff(decl_18852, type, 'The process of cellular communication in animal cells in which the signal molecule is the hormone epinepherine.': $i).
% 28.89/28.97  tff(decl_18853, type, 'cell signaling with epinepherine': $i).
% 28.89/28.97  tff(decl_18854, type, 'cell communication with epinephrine': $i).
% 28.89/28.97  tff(decl_18855, type, 'cell-communication-with-epinephrine': $i).
% 28.89/28.97  tff(decl_18856, type, fn_cell_communication_with_epinephrine_3: $i > $i).
% 28.89/28.97  tff(decl_18857, type, fn_cell_communication_with_epinephrine_6: $i > $i).
% 28.89/28.97  tff(decl_18858, type, fn_cell_communication_with_epinephrine_7: $i > $i).
% 28.89/28.97  tff(decl_18859, type, fn_cell_communication_with_epinephrine_8: $i > $i).
% 28.89/28.97  tff(decl_18860, type, fn_cell_communication_with_epinephrine_10: $i > $i).
% 28.89/28.97  tff(decl_18861, type, fn_cell_communication_with_epinephrine_14: $i > $i).
% 28.89/28.97  tff(decl_18862, type, fn_cell_communication_with_epinephrine_15: $i > $i).
% 28.89/28.97  tff(decl_18863, type, fn_cell_communication_with_epinephrine_16: $i > $i).
% 28.89/28.97  tff(decl_18864, type, fn_cell_communication_with_epinephrine_17: $i > $i).
% 28.89/28.97  tff(decl_18865, type, fn_cell_communication_with_epinephrine_18: $i > $i).
% 28.89/28.97  tff(decl_18866, type, fn_cell_communication_with_epinephrine_19: $i > $i).
% 28.89/28.97  tff(decl_18867, type, fn_cell_communication_with_epinephrine_20: $i > $i).
% 28.89/28.97  tff(decl_18868, type, fn_cell_communication_with_epinephrine_21: $i > $i).
% 28.89/28.97  tff(decl_18869, type, fn_cell_communication_with_epinephrine_22: $i > $i).
% 28.89/28.97  tff(decl_18870, type, fn_cell_communication_with_epinephrine_23: $i > $i).
% 28.89/28.97  tff(decl_18871, type, fn_cell_communication_with_epinephrine_24: $i > $i).
% 28.89/28.97  tff(decl_18872, type, fn_cell_communication_with_epinephrine_25: $i > $i).
% 28.89/28.97  tff(decl_18873, type, fn_cell_communication_with_epinephrine_26: $i > $i).
% 28.89/28.97  tff(decl_18874, type, fn_cell_communication_with_epinephrine_27: $i > $i).
% 28.89/28.97  tff(decl_18875, type, fn_cell_communication_with_epinephrine_28: $i > $i).
% 28.89/28.97  tff(decl_18876, type, synthesis_of_camp_1: $i > $o).
% 28.89/28.97  tff(decl_18877, type, fn_cell_communication_with_epinephrine_29: $i > $i).
% 28.89/28.97  tff(decl_18878, type, fn_cell_communication_with_epinephrine_30: $i > $i).
% 28.89/28.97  tff(decl_18879, type, fn_cell_communication_with_epinephrine_31: $i > $i).
% 28.89/28.97  tff(decl_18880, type, fn_cell_communication_with_epinephrine_32: $i > $i).
% 28.89/28.97  tff(decl_18881, type, epinephrine_1: $i > $o).
% 28.89/28.97  tff(decl_18882, type, fn_cell_communication_with_epinephrine_33: $i > $i).
% 28.89/28.97  tff(decl_18883, type, fn_cell_communication_with_epinephrine_34: $i > $i).
% 28.89/28.97  tff(decl_18884, type, fn_cell_communication_with_epinephrine_35: $i > $i).
% 28.89/28.97  tff(decl_18885, type, fn_cell_communication_with_epinephrine_36: $i > $i).
% 28.89/28.97  tff(decl_18886, type, fn_cell_communication_with_epinephrine_37: $i > $i).
% 28.89/28.97  tff(decl_18887, type, fn_cell_communication_with_epinephrine_38: $i > $i).
% 28.89/28.97  tff(decl_18888, type, fn_cell_communication_with_epinephrine_39: $i > $i).
% 28.89/28.97  tff(decl_18889, type, fn_cell_communication_with_epinephrine_40: $i > $i).
% 28.89/28.97  tff(decl_18890, type, fn_cell_communication_with_epinephrine_41: $i > $i).
% 28.89/28.97  tff(decl_18891, type, fn_cell_communication_with_epinephrine_42: $i > $i).
% 28.89/28.97  tff(decl_18892, type, fn_cell_communication_with_epinephrine_43: $i > $i).
% 28.89/28.97  tff(decl_18893, type, cell_signaling_with_g_protein_coupled_receptor_1: $i > $o).
% 28.89/28.97  tff(decl_18894, type, cell_signaling_with_camp_and_g_protein_coupled_receptor_1: $i > $o).
% 28.89/28.97  tff(decl_18895, type, fn_cell_communication_with_epinephrine_44: $i > $i).
% 28.89/28.97  tff(decl_18896, type, fn_cell_communication_with_epinephrine_45: $i > $i).
% 28.89/28.97  tff(decl_18897, type, fn_cell_communication_with_epinephrine_46: $i > $i).
% 28.89/28.97  tff(decl_18898, type, fn_cell_communication_with_epinephrine_47: $i > $i).
% 28.89/28.97  tff(decl_18899, type, fn_cell_communication_with_epinephrine_48: $i > $i).
% 28.89/28.97  tff(decl_18900, type, fn_cell_signaling_with_g_protein_coupled_receptor_63: $i > $i).
% 28.89/28.97  tff(decl_18901, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_60: $i > $i).
% 28.89/28.97  tff(decl_18902, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_44: $i > $i).
% 28.89/28.97  tff(decl_18903, type, fn_cell_signaling_with_plasma_membrane_receptor_1: $i > $i).
% 28.89/28.97  tff(decl_18904, type, fn_cell_signaling_with_plasma_membrane_receptor_2: $i > $i).
% 28.89/28.97  tff(decl_18905, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_79: $i > $i).
% 28.89/28.97  tff(decl_18906, type, fn_cell_signaling_with_g_protein_coupled_receptor_99: $i > $i).
% 28.89/28.97  tff(decl_18907, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_82: $i > $i).
% 28.89/28.97  tff(decl_18908, type, fn_cell_signaling_with_g_protein_coupled_receptor_101: $i > $i).
% 28.89/28.97  tff(decl_18909, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_32: $i > $i).
% 28.89/28.97  tff(decl_18910, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_67: $i > $i).
% 28.89/28.97  tff(decl_18911, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_64: $i > $i).
% 28.89/28.97  tff(decl_18912, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_66: $i > $i).
% 28.89/28.97  tff(decl_18913, type, fn_cell_signaling_with_g_protein_coupled_receptor_64: $i > $i).
% 28.89/28.97  tff(decl_18914, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_59: $i > $i).
% 28.89/28.97  tff(decl_18915, type, fn_cell_signaling_with_g_protein_coupled_receptor_67: $i > $i).
% 28.89/28.97  tff(decl_18916, type, 'Concentration_cAMP_NormalCell': $i).
% 28.89/28.97  tff(decl_18917, type, 'Concentration_cAMP_SignalingCell': $i).
% 28.89/28.97  tff(decl_18918, type, fn_cell_communication_with_epinephrine_12: $i > $i).
% 28.89/28.97  tff(decl_18919, type, fn_cell_communication_with_epinephrine_11: $i > $i).
% 28.89/28.97  tff(decl_18920, type, fn_long_distance_cell_communication_4: $i > $i).
% 28.89/28.97  tff(decl_18921, type, fn_cell_communication_with_epinephrine_13: $i > $i).
% 28.89/28.97  tff(decl_18922, type, cell_communication_with_epinephrine_in_heart_cell_1: $i > $o).
% 28.89/28.97  tff(decl_18923, type, 'Cell-Communication-With-Epinephrine-In-Heart-Cell': $i).
% 28.89/28.97  tff(decl_18924, type, 'The process of cellular communication in animals in which the signal molecule is the hormone epinepherine and the target cell is a heart cell.': $i).
% 28.89/28.97  tff(decl_18925, type, 'endocrine signaling with epinepherine in heart cell': $i).
% 28.89/28.97  tff(decl_18926, type, 'cell communication with epinephrine in heart cell': $i).
% 28.89/28.97  tff(decl_18927, type, 'cell-communication-with-epinephrine-in-heart-cell': $i).
% 28.89/28.97  tff(decl_18928, type, fn_cell_communication_with_epinephrine_in_heart_cell_1: $i > $i).
% 28.89/28.97  tff(decl_18929, type, fn_cell_communication_with_epinephrine_in_heart_cell_2: $i > $i).
% 28.89/28.97  tff(decl_18930, type, fn_cell_communication_with_epinephrine_in_heart_cell_3: $i > $i).
% 28.89/28.97  tff(decl_18931, type, heart_beat_1: $i > $o).
% 28.89/28.97  tff(decl_18932, type, fn_cell_communication_with_epinephrine_in_heart_cell_4: $i > $i).
% 28.89/28.97  tff(decl_18933, type, muscle_contraction_1: $i > $o).
% 28.89/28.97  tff(decl_18934, type, fn_cell_communication_with_epinephrine_in_heart_cell_6: $i > $i).
% 28.89/28.97  tff(decl_18935, type, fn_cell_communication_with_epinephrine_in_heart_cell_7: $i > $i).
% 28.89/28.97  tff(decl_18936, type, fn_cell_communication_with_epinephrine_in_heart_cell_8: $i > $i).
% 28.89/28.97  tff(decl_18937, type, fn_cell_communication_with_epinephrine_in_heart_cell_9: $i > $i).
% 28.89/28.97  tff(decl_18938, type, fn_cell_communication_with_epinephrine_in_heart_cell_10: $i > $i).
% 28.89/28.97  tff(decl_18939, type, fn_cell_communication_with_epinephrine_in_heart_cell_11: $i > $i).
% 28.89/28.97  tff(decl_18940, type, fn_cell_communication_with_epinephrine_in_heart_cell_12: $i > $i).
% 28.89/28.97  tff(decl_18941, type, fn_cell_communication_with_epinephrine_in_heart_cell_13: $i > $i).
% 28.89/28.97  tff(decl_18942, type, fn_cell_communication_with_epinephrine_in_heart_cell_14: $i > $i).
% 28.89/28.97  tff(decl_18943, type, fn_cell_communication_with_epinephrine_in_heart_cell_15: $i > $i).
% 28.89/28.97  tff(decl_18944, type, fn_cell_communication_with_epinephrine_in_heart_cell_16: $i > $i).
% 28.89/28.97  tff(decl_18945, type, heart_cell_1: $i > $o).
% 28.89/28.97  tff(decl_18946, type, fn_cell_communication_with_epinephrine_in_heart_cell_17: $i > $i).
% 28.89/28.97  tff(decl_18947, type, fn_cell_communication_with_epinephrine_in_heart_cell_18: $i > $i).
% 28.89/28.97  tff(decl_18948, type, fn_cell_communication_with_epinephrine_in_heart_cell_19: $i > $i).
% 28.89/28.97  tff(decl_18949, type, fn_cell_communication_with_epinephrine_in_heart_cell_20: $i > $i).
% 28.89/28.97  tff(decl_18950, type, fn_cell_communication_with_epinephrine_in_heart_cell_21: $i > $i).
% 28.89/28.97  tff(decl_18951, type, fn_cell_communication_with_epinephrine_in_heart_cell_22: $i > $i).
% 28.89/28.97  tff(decl_18952, type, fn_cell_communication_with_epinephrine_in_heart_cell_23: $i > $i).
% 28.89/28.97  tff(decl_18953, type, fn_cell_communication_with_epinephrine_in_heart_cell_24: $i > $i).
% 28.89/28.97  tff(decl_18954, type, fn_cell_communication_with_epinephrine_in_heart_cell_25: $i > $i).
% 28.89/28.97  tff(decl_18955, type, fn_cell_communication_with_epinephrine_in_heart_cell_26: $i > $i).
% 28.89/28.97  tff(decl_18956, type, fn_cell_communication_with_epinephrine_in_heart_cell_27: $i > $i).
% 28.89/28.97  tff(decl_18957, type, fn_cell_communication_with_epinephrine_in_heart_cell_28: $i > $i).
% 28.89/28.97  tff(decl_18958, type, fn_cell_communication_with_epinephrine_in_heart_cell_30: $i > $i).
% 28.89/28.97  tff(decl_18959, type, fn_cell_communication_with_epinephrine_in_heart_cell_31: $i > $i).
% 28.89/28.97  tff(decl_18960, type, fn_cell_communication_with_epinephrine_in_heart_cell_32: $i > $i).
% 28.89/28.97  tff(decl_18961, type, cardiovascular_process_0: $i).
% 28.89/28.97  tff(decl_18962, type, fn_cell_communication_with_epinephrine_in_heart_cell_33: $i > $i).
% 28.89/28.97  tff(decl_18963, type, fn_cell_communication_with_epinephrine_5: $i > $i).
% 28.89/28.97  tff(decl_18964, type, fn_cell_communication_with_epinephrine_in_heart_cell_35: $i > $i).
% 28.89/28.97  tff(decl_18965, type, fn_cell_communication_with_epinephrine_9: $i > $i).
% 28.89/28.97  tff(decl_18966, type, fn_cell_communication_with_epinephrine_in_heart_cell_34: $i > $i).
% 28.89/28.97  tff(decl_18967, type, fn_cell_communication_with_epinephrine_2: $i > $i).
% 28.89/28.97  tff(decl_18968, type, fn_cell_communication_with_epinephrine_in_heart_cell_29: $i > $i).
% 28.89/28.97  tff(decl_18969, type, fn_cell_communication_with_epinephrine_4: $i > $i).
% 28.89/28.97  tff(decl_18970, type, cell_communication_with_epinephrine_in_liver_cell_1: $i > $o).
% 28.89/28.97  tff(decl_18971, type, 'Cell-Communication-With-Epinephrine-In-Liver-Cell': $i).
% 28.89/28.97  tff(decl_18972, type, 'The process of cellular communication in animals in which the signal molecule is the hormone epinepherine and the target cell is a liver cell.': $i).
% 28.89/28.97  tff(decl_18973, type, 'endocrine signaling with epinepherine in liver cell': $i).
% 28.89/28.97  tff(decl_18974, type, 'cell communication with epinephrine in liver cell': $i).
% 28.89/28.97  tff(decl_18975, type, 'cell-communication-with-epinephrine-in-liver-cell': $i).
% 28.89/28.97  tff(decl_18976, type, fn_cell_communication_with_epinephrine_in_liver_cell_4: $i > $i).
% 28.89/28.97  tff(decl_18977, type, fn_cell_communication_with_epinephrine_in_liver_cell_6: $i > $i).
% 28.89/28.97  tff(decl_18978, type, fn_cell_communication_with_epinephrine_in_liver_cell_7: $i > $i).
% 28.89/28.97  tff(decl_18979, type, fn_cell_communication_with_epinephrine_in_liver_cell_8: $i > $i).
% 28.89/28.97  tff(decl_18980, type, glycogen_phosphorylase_1: $i > $o).
% 28.89/28.97  tff(decl_18981, type, fn_cell_communication_with_epinephrine_in_liver_cell_9: $i > $i).
% 28.89/28.97  tff(decl_18982, type, fn_cell_communication_with_epinephrine_in_liver_cell_10: $i > $i).
% 28.89/28.97  tff(decl_18983, type, fn_cell_communication_with_epinephrine_in_liver_cell_13: $i > $i).
% 28.89/28.97  tff(decl_18984, type, fn_cell_communication_with_epinephrine_in_liver_cell_15: $i > $i).
% 28.89/28.97  tff(decl_18985, type, fn_cell_communication_with_epinephrine_in_liver_cell_19: $i > $i).
% 28.89/28.97  tff(decl_18986, type, fn_cell_communication_with_epinephrine_in_liver_cell_20: $i > $i).
% 28.89/28.97  tff(decl_18987, type, fn_cell_communication_with_epinephrine_in_liver_cell_25: $i > $i).
% 28.89/28.97  tff(decl_18988, type, fn_cell_communication_with_epinephrine_in_liver_cell_26: $i > $i).
% 28.89/28.97  tff(decl_18989, type, fn_cell_communication_with_epinephrine_in_liver_cell_30: $i > $i).
% 28.89/28.97  tff(decl_18990, type, fn_cell_communication_with_epinephrine_in_liver_cell_35: $i > $i).
% 28.89/28.97  tff(decl_18991, type, fn_cell_communication_with_epinephrine_in_liver_cell_39: $i > $i).
% 28.89/28.97  tff(decl_18992, type, fn_cell_communication_with_epinephrine_in_liver_cell_40: $i > $i).
% 28.89/28.97  tff(decl_18993, type, fn_cell_communication_with_epinephrine_in_liver_cell_46: $i > $i).
% 28.89/28.97  tff(decl_18994, type, fn_cell_communication_with_epinephrine_in_liver_cell_47: $i > $i).
% 28.89/28.97  tff(decl_18995, type, fn_cell_communication_with_epinephrine_in_liver_cell_48: $i > $i).
% 28.89/28.97  tff(decl_18996, type, fn_cell_communication_with_epinephrine_in_liver_cell_49: $i > $i).
% 28.89/28.97  tff(decl_18997, type, fn_cell_communication_with_epinephrine_in_liver_cell_50: $i > $i).
% 28.89/28.97  tff(decl_18998, type, fn_cell_communication_with_epinephrine_in_liver_cell_51: $i > $i).
% 28.89/28.97  tff(decl_18999, type, fn_cell_communication_with_epinephrine_in_liver_cell_52: $i > $i).
% 28.89/28.97  tff(decl_19000, type, fn_cell_communication_with_epinephrine_in_liver_cell_53: $i > $i).
% 28.89/28.97  tff(decl_19001, type, fn_cell_communication_with_epinephrine_in_liver_cell_54: $i > $i).
% 28.89/28.97  tff(decl_19002, type, fn_cell_communication_with_epinephrine_in_liver_cell_55: $i > $i).
% 28.89/28.97  tff(decl_19003, type, fn_cell_communication_with_epinephrine_in_liver_cell_56: $i > $i).
% 28.89/28.97  tff(decl_19004, type, fn_cell_communication_with_epinephrine_in_liver_cell_57: $i > $i).
% 28.89/28.97  tff(decl_19005, type, fn_cell_communication_with_epinephrine_in_liver_cell_58: $i > $i).
% 28.89/28.97  tff(decl_19006, type, fn_cell_communication_with_epinephrine_in_liver_cell_61: $i > $i).
% 28.89/28.97  tff(decl_19007, type, fn_cell_communication_with_epinephrine_in_liver_cell_62: $i > $i).
% 28.89/28.97  tff(decl_19008, type, fn_cell_communication_with_epinephrine_in_liver_cell_63: $i > $i).
% 28.89/28.97  tff(decl_19009, type, fn_cell_communication_with_epinephrine_in_liver_cell_64: $i > $i).
% 28.89/28.97  tff(decl_19010, type, fn_cell_communication_with_epinephrine_in_liver_cell_65: $i > $i).
% 28.89/28.97  tff(decl_19011, type, fn_cell_communication_with_epinephrine_in_liver_cell_66: $i > $i).
% 28.89/28.97  tff(decl_19012, type, fn_cell_communication_with_epinephrine_in_liver_cell_67: $i > $i).
% 28.89/28.97  tff(decl_19013, type, fn_cell_communication_with_epinephrine_in_liver_cell_68: $i > $i).
% 28.89/28.97  tff(decl_19014, type, fn_cell_communication_with_epinephrine_in_liver_cell_69: $i > $i).
% 28.89/28.97  tff(decl_19015, type, vertebrate_cell_1: $i > $o).
% 28.89/28.97  tff(decl_19016, type, liver_cell_1: $i > $o).
% 28.89/28.97  tff(decl_19017, type, fn_cell_communication_with_epinephrine_in_liver_cell_70: $i > $i).
% 28.89/28.97  tff(decl_19018, type, protein_kinase_1: $i > $o).
% 28.89/28.97  tff(decl_19019, type, fn_cell_communication_with_epinephrine_in_liver_cell_71: $i > $i).
% 28.89/28.97  tff(decl_19020, type, fn_cell_communication_with_epinephrine_in_liver_cell_72: $i > $i).
% 28.89/28.97  tff(decl_19021, type, fn_cell_communication_with_epinephrine_in_liver_cell_73: $i > $i).
% 28.89/28.97  tff(decl_19022, type, fn_cell_communication_with_epinephrine_in_liver_cell_74: $i > $i).
% 28.89/28.97  tff(decl_19023, type, fn_cell_communication_with_epinephrine_in_liver_cell_75: $i > $i).
% 28.89/28.97  tff(decl_19024, type, fn_cell_communication_with_epinephrine_in_liver_cell_76: $i > $i).
% 28.89/28.97  tff(decl_19025, type, phosphorylase_kinase_1: $i > $o).
% 28.89/28.97  tff(decl_19026, type, fn_cell_communication_with_epinephrine_in_liver_cell_77: $i > $i).
% 28.89/28.97  tff(decl_19027, type, fn_cell_communication_with_epinephrine_in_liver_cell_78: $i > $i).
% 28.89/28.97  tff(decl_19028, type, fn_cell_communication_with_epinephrine_in_liver_cell_79: $i > $i).
% 28.89/28.97  tff(decl_19029, type, protein_kinase_a_1: $i > $o).
% 28.89/28.97  tff(decl_19030, type, fn_cell_communication_with_epinephrine_in_liver_cell_80: $i > $i).
% 28.89/28.97  tff(decl_19031, type, fn_cell_communication_with_epinephrine_in_liver_cell_81: $i > $i).
% 28.89/28.97  tff(decl_19032, type, cytoplasmic_response_1: $i > $o).
% 28.89/28.97  tff(decl_19033, type, fn_cell_communication_with_epinephrine_in_liver_cell_82: $i > $i).
% 28.89/28.97  tff(decl_19034, type, glycogen_breakdown_1: $i > $o).
% 28.89/28.97  tff(decl_19035, type, fn_cell_communication_with_epinephrine_in_liver_cell_83: $i > $i).
% 28.89/28.97  tff(decl_19036, type, fn_cell_communication_with_epinephrine_in_liver_cell_84: $i > $i).
% 28.89/28.97  tff(decl_19037, type, fn_cell_communication_with_epinephrine_in_liver_cell_85: $i > $i).
% 28.89/28.97  tff(decl_19038, type, fn_cell_communication_with_epinephrine_in_liver_cell_86: $i > $i).
% 28.89/28.97  tff(decl_19039, type, fn_cell_communication_with_epinephrine_in_liver_cell_87: $i > $i).
% 28.89/28.97  tff(decl_19040, type, fn_cell_communication_with_epinephrine_in_liver_cell_88: $i > $i).
% 28.89/28.97  tff(decl_19041, type, fn_cell_communication_with_epinephrine_in_liver_cell_89: $i > $i).
% 28.89/28.97  tff(decl_19042, type, fn_cell_communication_with_epinephrine_in_liver_cell_90: $i > $i).
% 28.89/28.97  tff(decl_19043, type, fn_cell_communication_with_epinephrine_in_liver_cell_91: $i > $i).
% 28.89/28.97  tff(decl_19044, type, fn_cell_communication_with_epinephrine_in_liver_cell_92: $i > $i).
% 28.89/28.97  tff(decl_19045, type, fn_cell_communication_with_epinephrine_in_liver_cell_93: $i > $i).
% 28.89/28.97  tff(decl_19046, type, fn_cell_communication_with_epinephrine_in_liver_cell_94: $i > $i).
% 28.89/28.97  tff(decl_19047, type, fn_cell_communication_with_epinephrine_in_liver_cell_95: $i > $i).
% 28.89/28.97  tff(decl_19048, type, fn_cell_communication_with_epinephrine_in_liver_cell_96: $i > $i).
% 28.89/28.97  tff(decl_19049, type, fn_cell_communication_with_epinephrine_in_liver_cell_97: $i > $i).
% 28.89/28.97  tff(decl_19050, type, fn_cell_communication_with_epinephrine_in_liver_cell_98: $i > $i).
% 28.89/28.97  tff(decl_19051, type, fn_cell_communication_with_epinephrine_in_liver_cell_99: $i > $i).
% 28.89/28.97  tff(decl_19052, type, glucose_1_phosphate_1: $i > $o).
% 28.89/28.97  tff(decl_19053, type, fn_cell_communication_with_epinephrine_in_liver_cell_100: $i > $i).
% 28.89/28.97  tff(decl_19054, type, fn_cell_communication_with_epinephrine_in_liver_cell_101: $i > $i).
% 28.89/28.97  tff(decl_19055, type, fn_cell_communication_with_epinephrine_in_liver_cell_102: $i > $i).
% 28.89/28.97  tff(decl_19056, type, fn_cell_communication_with_epinephrine_in_liver_cell_103: $i > $i).
% 28.89/28.97  tff(decl_19057, type, fn_cell_communication_with_epinephrine_in_liver_cell_104: $i > $i).
% 28.89/28.97  tff(decl_19058, type, fn_cell_communication_with_epinephrine_in_liver_cell_107: $i > $i).
% 28.89/28.97  tff(decl_19059, type, fn_cell_communication_with_epinephrine_in_liver_cell_110: $i > $i).
% 28.89/28.97  tff(decl_19060, type, fn_cell_communication_with_epinephrine_in_liver_cell_111: $i > $i).
% 28.89/28.97  tff(decl_19061, type, fn_cell_communication_with_epinephrine_in_liver_cell_112: $i > $i).
% 28.89/28.97  tff(decl_19062, type, fn_cell_communication_with_epinephrine_in_liver_cell_113: $i > $i).
% 28.89/28.97  tff(decl_19063, type, fn_cell_communication_with_epinephrine_in_liver_cell_114: $i > $i).
% 28.89/28.97  tff(decl_19064, type, fn_cell_communication_with_epinephrine_in_liver_cell_115: $i > $i).
% 28.89/28.97  tff(decl_19065, type, fn_cell_communication_with_epinephrine_in_liver_cell_116: $i > $i).
% 28.89/28.97  tff(decl_19066, type, fn_cell_communication_with_epinephrine_in_liver_cell_117: $i > $i).
% 28.89/28.97  tff(decl_19067, type, fn_cell_communication_with_epinephrine_in_liver_cell_118: $i > $i).
% 28.89/28.97  tff(decl_19068, type, fn_cell_communication_with_epinephrine_in_liver_cell_119: $i > $i).
% 28.89/28.97  tff(decl_19069, type, fn_cell_communication_with_epinephrine_in_liver_cell_120: $i > $i).
% 28.89/28.97  tff(decl_19070, type, fn_cell_communication_with_epinephrine_in_liver_cell_121: $i > $i).
% 28.89/28.97  tff(decl_19071, type, fn_cell_communication_with_epinephrine_in_liver_cell_122: $i > $i).
% 28.89/28.97  tff(decl_19072, type, fn_cell_communication_with_epinephrine_in_liver_cell_123: $i > $i).
% 28.89/28.97  tff(decl_19073, type, fn_cell_communication_with_epinephrine_in_liver_cell_124: $i > $i).
% 28.89/28.97  tff(decl_19074, type, fn_cell_communication_with_epinephrine_in_liver_cell_125: $i > $i).
% 28.89/28.97  tff(decl_19075, type, fn_cell_communication_with_epinephrine_in_liver_cell_126: $i > $i).
% 28.89/28.97  tff(decl_19076, type, fn_cell_communication_with_epinephrine_in_liver_cell_127: $i > $i).
% 28.89/28.97  tff(decl_19077, type, fn_cell_communication_with_epinephrine_in_liver_cell_128: $i > $i).
% 28.89/28.97  tff(decl_19078, type, fn_cell_communication_with_epinephrine_in_liver_cell_129: $i > $i).
% 28.89/28.97  tff(decl_19079, type, fn_cell_communication_with_epinephrine_in_liver_cell_130: $i > $i).
% 28.89/28.97  tff(decl_19080, type, fn_cell_communication_with_epinephrine_in_liver_cell_131: $i > $i).
% 28.89/28.97  tff(decl_19081, type, fn_cell_communication_with_epinephrine_in_liver_cell_132: $i > $i).
% 28.89/28.97  tff(decl_19082, type, fn_cell_communication_with_epinephrine_in_liver_cell_133: $i > $i).
% 28.89/28.97  tff(decl_19083, type, fn_cell_communication_with_epinephrine_in_liver_cell_134: $i > $i).
% 28.89/28.97  tff(decl_19084, type, fn_cell_communication_with_epinephrine_in_liver_cell_135: $i > $i).
% 28.89/28.97  tff(decl_19085, type, fn_cell_communication_with_epinephrine_in_liver_cell_136: $i > $i).
% 28.89/28.97  tff(decl_19086, type, fn_cell_communication_with_epinephrine_in_liver_cell_137: $i > $i).
% 28.89/28.97  tff(decl_19087, type, fn_cell_communication_with_epinephrine_in_liver_cell_138: $i > $i).
% 28.89/28.97  tff(decl_19088, type, fn_cell_communication_with_epinephrine_in_liver_cell_139: $i > $i).
% 28.89/28.97  tff(decl_19089, type, fn_cell_communication_with_epinephrine_in_liver_cell_140: $i > $i).
% 28.89/28.97  tff(decl_19090, type, fn_cell_communication_with_epinephrine_in_liver_cell_141: $i > $i).
% 28.89/28.97  tff(decl_19091, type, fn_cell_communication_with_epinephrine_in_liver_cell_142: $i > $i).
% 28.89/28.97  tff(decl_19092, type, fn_cell_communication_with_epinephrine_in_liver_cell_143: $i > $i).
% 28.89/28.97  tff(decl_19093, type, fn_cell_communication_with_epinephrine_in_liver_cell_144: $i > $i).
% 28.89/28.97  tff(decl_19094, type, fn_cell_signaling_with_g_protein_coupled_receptor_95: $i > $i).
% 28.89/28.97  tff(decl_19095, type, fn_cell_signaling_with_g_protein_coupled_receptor_96: $i > $i).
% 28.89/28.97  tff(decl_19096, type, fn_g_protein_3: $i > $i).
% 28.89/28.97  tff(decl_19097, type, fn_g_protein_4: $i > $i).
% 28.89/28.97  tff(decl_19098, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_1: $i > $i).
% 28.89/28.97  tff(decl_19099, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_68: $i > $i).
% 28.89/28.97  tff(decl_19100, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_22: $i > $i).
% 28.89/28.97  tff(decl_19101, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_91: $i > $i).
% 28.89/28.97  tff(decl_19102, type, fn_liver_cell_78: $i > $i).
% 28.89/28.97  tff(decl_19103, type, fn_liver_cell_77: $i > $i).
% 28.89/28.97  tff(decl_19104, type, fn_liver_cell_65: $i > $i).
% 28.89/28.97  tff(decl_19105, type, fn_liver_cell_69: $i > $i).
% 28.89/28.97  tff(decl_19106, type, fn_liver_cell_68: $i > $i).
% 28.89/28.97  tff(decl_19107, type, fn_glycogen_breakdown_18: $i > $i).
% 28.89/28.97  tff(decl_19108, type, fn_liver_cell_104: $i > $i).
% 28.89/28.97  tff(decl_19109, type, fn_glycogen_phosphorylase_16: $i > $i).
% 28.89/28.97  tff(decl_19110, type, fn_glycogen_breakdown_16: $i > $i).
% 28.89/28.97  tff(decl_19111, type, fn_neurotransmitter_1: $i > $i).
% 28.89/28.97  tff(decl_19112, type, fn_glycogen_phosphorylase_7: $i > $i).
% 28.89/28.97  tff(decl_19113, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_37: $i > $i).
% 28.89/28.97  tff(decl_19114, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_87: $i > $i).
% 28.89/28.97  tff(decl_19115, type, fn_cell_signaling_with_g_protein_coupled_receptor_87: $i > $i).
% 28.89/28.97  tff(decl_19116, type, fn_cell_signaling_with_g_protein_coupled_receptor_89: $i > $i).
% 28.89/28.97  tff(decl_19117, type, fn_kinase_1: $i > $i).
% 28.89/28.97  tff(decl_19118, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_56: $i > $i).
% 28.89/28.97  tff(decl_19119, type, fn_g_protein_5: $i > $i).
% 28.89/28.97  tff(decl_19120, type, fn_cell_signaling_with_g_protein_coupled_receptor_7: $i > $i).
% 28.89/28.97  tff(decl_19121, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_4: $i > $i).
% 28.89/28.97  tff(decl_19122, type, fn_cell_signaling_with_g_protein_coupled_receptor_61: $i > $i).
% 28.89/28.97  tff(decl_19123, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_70: $i > $i).
% 28.89/28.97  tff(decl_19124, type, fn_cell_signaling_with_g_protein_coupled_receptor_94: $i > $i).
% 28.89/28.97  tff(decl_19125, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_71: $i > $i).
% 28.89/28.97  tff(decl_19126, type, fn_cell_signaling_with_g_protein_coupled_receptor_100: $i > $i).
% 28.89/28.97  tff(decl_19127, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_57: $i > $i).
% 28.89/28.97  tff(decl_19128, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_47: $i > $i).
% 28.89/28.97  tff(decl_19129, type, fn_cell_signaling_with_g_protein_coupled_receptor_28: $i > $i).
% 28.89/28.97  tff(decl_19130, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_92: $i > $i).
% 28.89/28.97  tff(decl_19131, type, fn_cell_signaling_with_g_protein_coupled_receptor_65: $i > $i).
% 28.89/28.97  tff(decl_19132, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_75: $i > $i).
% 28.89/28.97  tff(decl_19133, type, fn_cell_signaling_with_g_protein_coupled_receptor_66: $i > $i).
% 28.89/28.97  tff(decl_19134, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_88: $i > $i).
% 28.89/28.97  tff(decl_19135, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_45: $i > $i).
% 28.89/28.97  tff(decl_19136, type, fn_liver_cell_62: $i > $i).
% 28.89/28.97  tff(decl_19137, type, fn_liver_cell_58: $i > $i).
% 28.89/28.97  tff(decl_19138, type, fn_vertebrate_cell_27: $i > $i).
% 28.89/28.97  tff(decl_19139, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_58: $i > $i).
% 28.89/28.97  tff(decl_19140, type, fn_liver_cell_74: $i > $i).
% 28.89/28.97  tff(decl_19141, type, fn_g_protein_1: $i > $i).
% 28.89/28.97  tff(decl_19142, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_76: $i > $i).
% 28.89/28.97  tff(decl_19143, type, fn_cell_signaling_with_plasma_membrane_receptor_8: $i > $i).
% 28.89/28.97  tff(decl_19144, type, fn_liver_cell_80: $i > $i).
% 28.89/28.97  tff(decl_19145, type, fn_cell_signaling_with_plasma_membrane_receptor_21: $i > $i).
% 28.89/28.97  tff(decl_19146, type, fn_cell_signaling_with_g_protein_coupled_receptor_27: $i > $i).
% 28.89/28.97  tff(decl_19147, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_42: $i > $i).
% 28.89/28.97  tff(decl_19148, type, fn_cell_signaling_with_g_protein_coupled_receptor_29: $i > $i).
% 28.89/28.97  tff(decl_19149, type, fn_liver_cell_41: $i > $i).
% 28.89/28.97  tff(decl_19150, type, fn_cell_signaling_with_g_protein_coupled_receptor_109: $i > $i).
% 28.89/28.97  tff(decl_19151, type, fn_liver_cell_56: $i > $i).
% 28.89/28.97  tff(decl_19152, type, fn_liver_cell_79: $i > $i).
% 28.89/28.97  tff(decl_19153, type, fn_plasma_membrane_91: $i > $i).
% 28.89/28.97  tff(decl_19154, type, fn_cell_signaling_with_g_protein_coupled_receptor_103: $i > $i).
% 28.89/28.97  tff(decl_19155, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_43: $i > $i).
% 28.89/28.97  tff(decl_19156, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_63: $i > $i).
% 28.89/28.97  tff(decl_19157, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_62: $i > $i).
% 28.89/28.97  tff(decl_19158, type, fn_plasma_membrane_85: $i > $i).
% 28.89/28.97  tff(decl_19159, type, fn_cell_signaling_with_g_protein_coupled_receptor_30: $i > $i).
% 28.89/28.97  tff(decl_19160, type, fn_cell_signaling_with_g_protein_coupled_receptor_57: $i > $i).
% 28.89/28.97  tff(decl_19161, type, 'Quantity_GProtein': $i).
% 28.89/28.97  tff(decl_19162, type, 'Quantity_PhosphorylaseKinase': $i).
% 28.89/28.97  tff(decl_19163, type, 'Quantity_cAMP': $i).
% 28.89/28.97  tff(decl_19164, type, 'Quantity_ProteinKinaseA': $i).
% 28.89/28.97  tff(decl_19165, type, 'Quantity_GlycogenPhosphorylase': $i).
% 28.89/28.97  tff(decl_19166, type, 'Quantity_AdenylylCyclase': $i).
% 28.89/28.97  tff(decl_19167, type, phosphorylation_0: $i).
% 28.89/28.97  tff(decl_19168, type, 'Quantity_Glucose1Phosphate': $i).
% 28.89/28.97  tff(decl_19169, type, 'Quantity_Epinephrine': $i).
% 28.89/28.97  tff(decl_19170, type, 'Acyclase': $i).
% 28.89/28.97  tff(decl_19171, type, 'GPCR': $i).
% 28.89/28.97  tff(decl_19172, type, 'PKA': $i).
% 28.89/28.97  tff(decl_19173, type, fn_cell_communication_with_epinephrine_in_liver_cell_145: $i > $i).
% 28.89/28.97  tff(decl_19174, type, fn_cell_communication_with_epinephrine_in_liver_cell_146: $i > $i).
% 28.89/28.97  tff(decl_19175, type, fn_cell_communication_with_epinephrine_in_liver_cell_105: $i > $i).
% 28.89/28.97  tff(decl_19176, type, fn_cell_communication_with_epinephrine_in_liver_cell_147: $i > $i).
% 28.89/28.97  tff(decl_19177, type, fn_cell_communication_with_epinephrine_in_liver_cell_148: $i > $i).
% 28.89/28.97  tff(decl_19178, type, fn_cell_communication_with_epinephrine_in_liver_cell_60: $i > $i).
% 28.89/28.97  tff(decl_19179, type, fn_cell_communication_with_epinephrine_in_liver_cell_59: $i > $i).
% 28.89/28.97  tff(decl_19180, type, fn_cell_communication_with_epinephrine_in_liver_cell_44: $i > $i).
% 28.89/28.97  tff(decl_19181, type, fn_cell_communication_with_epinephrine_in_liver_cell_108: $i > $i).
% 28.89/28.97  tff(decl_19182, type, fn_cell_communication_with_epinephrine_in_liver_cell_109: $i > $i).
% 28.89/28.97  tff(decl_19183, type, fn_cell_communication_with_epinephrine_in_liver_cell_45: $i > $i).
% 28.89/28.97  tff(decl_19184, type, fn_cell_communication_with_epinephrine_in_liver_cell_106: $i > $i).
% 28.89/28.97  tff(decl_19185, type, cell_communication_with_epinephrine_in_muscle_cell_1: $i > $o).
% 28.89/28.97  tff(decl_19186, type, 'Cell-Communication-With-Epinephrine-In-Muscle-Cell': $i).
% 28.89/28.97  tff(decl_19187, type, 'The process of cellular communication in animals in which the signal molecule is the hormone epinepherine and the target cell is a muscle cell.': $i).
% 28.89/28.97  tff(decl_19188, type, 'endocrine signaling with epinepherine in muscle cell': $i).
% 28.89/28.97  tff(decl_19189, type, 'cell communication with epinephrine in muscle cell': $i).
% 28.89/28.97  tff(decl_19190, type, 'cell-communication-with-epinephrine-in-muscle-cell': $i).
% 28.89/28.97  tff(decl_19191, type, fn_cell_communication_with_epinephrine_in_muscle_cell_1: $i > $i).
% 28.89/28.97  tff(decl_19192, type, fn_cell_communication_with_epinephrine_in_muscle_cell_2: $i > $i).
% 28.89/28.97  tff(decl_19193, type, fn_cell_communication_with_epinephrine_in_muscle_cell_10: $i > $i).
% 28.89/28.97  tff(decl_19194, type, fn_cell_communication_with_epinephrine_in_muscle_cell_11: $i > $i).
% 28.89/28.97  tff(decl_19195, type, fn_cell_communication_with_epinephrine_in_muscle_cell_12: $i > $i).
% 28.89/28.97  tff(decl_19196, type, fn_cell_communication_with_epinephrine_in_muscle_cell_13: $i > $i).
% 28.89/28.97  tff(decl_19197, type, fn_cell_communication_with_epinephrine_in_muscle_cell_14: $i > $i).
% 28.89/28.97  tff(decl_19198, type, fn_cell_communication_with_epinephrine_in_muscle_cell_15: $i > $i).
% 28.89/28.97  tff(decl_19199, type, fn_cell_communication_with_epinephrine_in_muscle_cell_16: $i > $i).
% 28.89/28.97  tff(decl_19200, type, fn_cell_communication_with_epinephrine_in_muscle_cell_17: $i > $i).
% 28.89/28.97  tff(decl_19201, type, fn_cell_communication_with_epinephrine_in_muscle_cell_18: $i > $i).
% 28.89/28.97  tff(decl_19202, type, fn_cell_communication_with_epinephrine_in_muscle_cell_19: $i > $i).
% 28.89/28.97  tff(decl_19203, type, fn_cell_communication_with_epinephrine_in_muscle_cell_20: $i > $i).
% 28.89/28.97  tff(decl_19204, type, fn_cell_communication_with_epinephrine_in_muscle_cell_21: $i > $i).
% 28.89/28.97  tff(decl_19205, type, fn_cell_communication_with_epinephrine_in_muscle_cell_22: $i > $i).
% 28.89/28.97  tff(decl_19206, type, fn_cell_communication_with_epinephrine_in_muscle_cell_23: $i > $i).
% 28.89/28.97  tff(decl_19207, type, fn_cell_communication_with_epinephrine_in_muscle_cell_24: $i > $i).
% 28.89/28.97  tff(decl_19208, type, fn_cell_communication_with_epinephrine_in_muscle_cell_25: $i > $i).
% 28.89/28.97  tff(decl_19209, type, fn_cell_communication_with_epinephrine_in_muscle_cell_26: $i > $i).
% 28.89/28.97  tff(decl_19210, type, muscle_cell_1: $i > $o).
% 28.89/28.97  tff(decl_19211, type, fn_cell_communication_with_epinephrine_in_muscle_cell_27: $i > $i).
% 28.89/28.97  tff(decl_19212, type, fn_cell_communication_with_epinephrine_in_muscle_cell_28: $i > $i).
% 28.89/28.97  tff(decl_19213, type, fn_cell_communication_with_epinephrine_in_muscle_cell_30: $i > $i).
% 28.89/28.97  tff(decl_19214, type, fn_cell_communication_with_epinephrine_in_muscle_cell_31: $i > $i).
% 28.89/28.97  tff(decl_19215, type, fn_cell_communication_with_epinephrine_in_muscle_cell_32: $i > $i).
% 28.89/28.97  tff(decl_19216, type, fn_cell_communication_with_epinephrine_in_muscle_cell_33: $i > $i).
% 28.89/28.97  tff(decl_19217, type, fn_cell_communication_with_epinephrine_in_muscle_cell_34: $i > $i).
% 28.89/28.97  tff(decl_19218, type, fn_cell_communication_with_epinephrine_in_muscle_cell_35: $i > $i).
% 28.89/28.97  tff(decl_19219, type, fn_cell_communication_with_epinephrine_in_muscle_cell_36: $i > $i).
% 28.89/28.97  tff(decl_19220, type, fn_cell_communication_with_epinephrine_in_muscle_cell_37: $i > $i).
% 28.89/28.97  tff(decl_19221, type, fn_cell_communication_with_epinephrine_in_muscle_cell_38: $i > $i).
% 28.89/28.97  tff(decl_19222, type, fn_cell_communication_with_epinephrine_in_muscle_cell_39: $i > $i).
% 28.89/28.97  tff(decl_19223, type, fn_cell_communication_with_epinephrine_in_muscle_cell_41: $i > $i).
% 28.89/28.97  tff(decl_19224, type, fn_cell_communication_with_epinephrine_in_muscle_cell_9: $i > $i).
% 28.89/28.97  tff(decl_19225, type, fn_cell_communication_with_epinephrine_in_muscle_cell_40: $i > $i).
% 28.89/28.97  tff(decl_19226, type, fn_cell_communication_with_epinephrine_in_muscle_cell_8: $i > $i).
% 28.89/28.97  tff(decl_19227, type, fn_cell_communication_with_epinephrine_in_muscle_cell_29: $i > $i).
% 28.89/28.97  tff(decl_19228, type, fn_cell_communication_with_epinephrine_in_muscle_cell_7: $i > $i).
% 28.89/28.97  tff(decl_19229, type, cell_communication_with_estrogen_receptor_leading_to_cell_division_1: $i > $o).
% 28.89/28.97  tff(decl_19230, type, 'Cell-Communication-With-Estrogen-Receptor-Leading-To-Cell-Division': $i).
% 28.89/28.97  tff(decl_19231, type, 'Process of communication between and within cells which involves generation and delivery of an estrogen signal and the series of events leading to cell division as a response to that signal.': $i).
% 28.89/28.97  tff(decl_19232, type, 'cell communication with estrogen receptor leading to cell division': $i).
% 28.89/28.97  tff(decl_19233, type, 'cell-communication-with-estrogen-receptor-leading-to-cell-division': $i).
% 28.89/28.97  tff(decl_19234, type, fn_cell_communication_with_estrogen_receptor_leading_to_cell_division_1: $i > $i).
% 28.89/28.97  tff(decl_19235, type, estrogen_receptor_1: $i > $o).
% 28.89/28.97  tff(decl_19236, type, fn_cell_communication_with_estrogen_receptor_leading_to_cell_division_2: $i > $i).
% 28.89/28.97  tff(decl_19237, type, fn_cell_communication_with_estrogen_receptor_leading_to_cell_division_3: $i > $i).
% 28.89/28.97  tff(decl_19238, type, fn_cell_communication_with_estrogen_receptor_leading_to_cell_division_4: $i > $i).
% 28.89/28.97  tff(decl_19239, type, fn_signal_reception_4: $i > $i).
% 28.89/28.97  tff(decl_19240, type, fn_signal_reception_5: $i > $i).
% 28.89/28.97  tff(decl_19241, type, cell_communication_with_ethylene_1: $i > $o).
% 28.89/28.97  tff(decl_19242, type, 'Cell-Communication-With-Ethylene': $i).
% 28.89/28.97  tff(decl_19243, type, 'Process of communication between plant cells which uses ethylene as the signaling molecule.': $i).
% 28.89/28.97  tff(decl_19244, type, 'cell communication with ethylene': $i).
% 28.89/28.97  tff(decl_19245, type, 'cell-communication-with-ethylene': $i).
% 28.89/28.97  tff(decl_19246, type, hormonal_signaling_in_plant_1: $i > $o).
% 28.89/28.97  tff(decl_19247, type, fn_cell_communication_with_ethylene_1: $i > $i).
% 28.89/28.97  tff(decl_19248, type, fn_cell_communication_with_ethylene_2: $i > $i).
% 28.89/28.97  tff(decl_19249, type, fn_cell_communication_with_ethylene_3: $i > $i).
% 28.89/28.97  tff(decl_19250, type, fn_cell_communication_with_ethylene_4: $i > $i).
% 28.89/28.97  tff(decl_19251, type, fn_cell_communication_with_ethylene_5: $i > $i).
% 28.89/28.97  tff(decl_19252, type, fn_cell_communication_with_ethylene_6: $i > $i).
% 28.89/28.97  tff(decl_19253, type, fn_cell_communication_with_ethylene_7: $i > $i).
% 28.89/28.97  tff(decl_19254, type, fn_cell_communication_with_ethylene_8: $i > $i).
% 28.89/28.97  tff(decl_19255, type, fn_cell_communication_with_ethylene_9: $i > $i).
% 28.89/28.97  tff(decl_19256, type, fn_cell_communication_with_ethylene_10: $i > $i).
% 28.89/28.97  tff(decl_19257, type, fn_cell_communication_with_ethylene_11: $i > $i).
% 28.89/28.97  tff(decl_19258, type, fn_cell_communication_with_ethylene_12: $i > $i).
% 28.89/28.97  tff(decl_19259, type, ethylene_1: $i > $o).
% 28.89/28.97  tff(decl_19260, type, fn_cell_communication_with_ethylene_13: $i > $i).
% 28.89/28.97  tff(decl_19261, type, fn_cell_communication_with_ethylene_14: $i > $i).
% 28.89/28.97  tff(decl_19262, type, fn_cell_communication_with_ethylene_15: $i > $i).
% 28.89/28.97  tff(decl_19263, type, fn_cell_communication_with_ethylene_16: $i > $i).
% 28.89/28.97  tff(decl_19264, type, fn_cell_communication_with_ethylene_17: $i > $i).
% 28.89/28.97  tff(decl_19265, type, fn_cell_communication_with_ethylene_18: $i > $i).
% 28.89/28.97  tff(decl_19266, type, fn_cell_communication_with_ethylene_19: $i > $i).
% 28.89/28.97  tff(decl_19267, type, fn_cell_communication_with_ethylene_20: $i > $i).
% 28.89/28.97  tff(decl_19268, type, fn_cell_communication_with_ethylene_21: $i > $i).
% 28.89/28.97  tff(decl_19269, type, fn_cell_communication_with_ethylene_22: $i > $i).
% 28.89/28.97  tff(decl_19270, type, fn_release_3: $i > $i).
% 28.89/28.97  tff(decl_19271, type, fn_signal_reception_1: $i > $i).
% 28.89/28.97  tff(decl_19272, type, fn_signal_reception_8: $i > $i).
% 28.89/28.97  tff(decl_19273, type, fn_signal_reception_7: $i > $i).
% 28.89/28.97  tff(decl_19274, type, fn_signal_reception_6: $i > $i).
% 28.89/28.97  tff(decl_19275, type, fn_hormonal_signaling_in_plant_17: $i > $i).
% 28.89/28.97  tff(decl_19276, type, fn_hormonal_signaling_in_plant_14: $i > $i).
% 28.89/28.97  tff(decl_19277, type, fn_hormonal_signaling_in_plant_15: $i > $i).
% 28.89/28.97  tff(decl_19278, type, fn_hormonal_signaling_in_plant_7: $i > $i).
% 28.89/28.97  tff(decl_19279, type, fn_hormonal_signaling_in_plant_6: $i > $i).
% 28.89/28.97  tff(decl_19280, type, fn_hormonal_signaling_in_plant_16: $i > $i).
% 28.89/28.97  tff(decl_19281, type, fn_hormonal_signaling_in_plant_3: $i > $i).
% 28.89/28.97  tff(decl_19282, type, fn_hormonal_signaling_in_plant_11: $i > $i).
% 28.89/28.97  tff(decl_19283, type, fn_hormonal_signaling_in_plant_8: $i > $i).
% 28.89/28.97  tff(decl_19284, type, fn_hormonal_signaling_in_plant_12: $i > $i).
% 28.89/28.97  tff(decl_19285, type, fn_hormonal_signaling_in_plant_1: $i > $i).
% 28.89/28.97  tff(decl_19286, type, fn_hormonal_signaling_in_plant_9: $i > $i).
% 28.89/28.97  tff(decl_19287, type, fn_hormonal_signaling_in_plant_10: $i > $i).
% 28.89/28.97  tff(decl_19288, type, fn_hormonal_signaling_in_plant_5: $i > $i).
% 28.89/28.97  tff(decl_19289, type, fn_hormonal_signaling_in_plant_13: $i > $i).
% 28.89/28.97  tff(decl_19290, type, fn_hormonal_signaling_in_plant_4: $i > $i).
% 28.89/28.97  tff(decl_19291, type, fn_hormonal_signaling_in_plant_2: $i > $i).
% 28.89/28.97  tff(decl_19292, type, cell_communication_with_ethylene_in_vascular_plants_1: $i > $o).
% 28.89/28.97  tff(decl_19293, type, 'Cell-Communication-With-Ethylene-In-Vascular-Plants': $i).
% 28.89/28.97  tff(decl_19294, type, 'Process of communication between vascular plant cells which uses ethylene as the signaling molecule.': $i).
% 28.89/28.97  tff(decl_19295, type, 'cell communication with ethylene in vascular plant': $i).
% 28.89/28.97  tff(decl_19296, type, 'cell-communication-with-ethylene-in-vascular-plant': $i).
% 28.89/28.97  tff(decl_19297, type, fn_cell_communication_with_ethylene_in_vascular_plants_1: $i > $i).
% 28.89/28.97  tff(decl_19298, type, fn_cell_communication_with_ethylene_in_vascular_plants_2: $i > $i).
% 28.89/28.97  tff(decl_19299, type, fn_cell_communication_with_ethylene_in_vascular_plants_3: $i > $i).
% 28.89/28.97  tff(decl_19300, type, vascular_tissue_1: $i > $o).
% 28.89/28.97  tff(decl_19301, type, fn_cell_communication_with_ethylene_in_vascular_plants_4: $i > $i).
% 28.89/28.97  tff(decl_19302, type, fn_cell_communication_with_ethylene_in_vascular_plants_5: $i > $i).
% 28.89/28.97  tff(decl_19303, type, fn_cell_communication_with_ethylene_in_vascular_plants_6: $i > $i).
% 28.89/28.97  tff(decl_19304, type, fn_cell_communication_with_ethylene_in_vascular_plants_7: $i > $i).
% 28.89/28.97  tff(decl_19305, type, fn_cell_communication_with_ethylene_in_vascular_plants_8: $i > $i).
% 28.89/28.97  tff(decl_19306, type, fn_cell_communication_with_ethylene_in_vascular_plants_9: $i > $i).
% 28.89/28.97  tff(decl_19307, type, fn_cell_communication_with_ethylene_in_vascular_plants_10: $i > $i).
% 28.89/28.97  tff(decl_19308, type, fn_cell_communication_with_ethylene_in_vascular_plants_11: $i > $i).
% 28.89/28.97  tff(decl_19309, type, fn_cell_communication_with_ethylene_in_vascular_plants_12: $i > $i).
% 28.89/28.97  tff(decl_19310, type, fn_cell_communication_with_ethylene_in_vascular_plants_13: $i > $i).
% 28.89/28.97  tff(decl_19311, type, fn_cell_communication_with_ethylene_in_vascular_plants_14: $i > $i).
% 28.89/28.97  tff(decl_19312, type, fn_cell_communication_with_ethylene_in_vascular_plants_15: $i > $i).
% 28.89/28.97  tff(decl_19313, type, fn_cell_communication_with_ethylene_in_vascular_plants_16: $i > $i).
% 28.89/28.97  tff(decl_19314, type, fn_cell_communication_with_ethylene_in_vascular_plants_17: $i > $i).
% 28.89/28.97  tff(decl_19315, type, fn_cell_communication_with_ethylene_in_vascular_plants_18: $i > $i).
% 28.89/28.97  tff(decl_19316, type, fn_cell_communication_with_ethylene_in_vascular_plants_19: $i > $i).
% 28.89/28.97  tff(decl_19317, type, fn_cell_communication_with_ethylene_in_vascular_plants_20: $i > $i).
% 28.89/28.97  tff(decl_19318, type, fn_cell_communication_with_ethylene_in_vascular_plants_21: $i > $i).
% 28.89/28.97  tff(decl_19319, type, fn_cell_communication_with_ethylene_in_vascular_plants_22: $i > $i).
% 28.89/28.97  tff(decl_19320, type, cell_communication_with_external_signal_leading_to_apoptosis_1: $i > $o).
% 28.89/28.97  tff(decl_19321, type, 'Cell-Communication-With-External-Signal-Leading-To-Apoptosis': $i).
% 28.89/28.97  tff(decl_19322, type, 'Series of events which leads to programmed cell death (apoptosis) in a cell; in this case, the signal for apoptosis is generated externally by another cell.': $i).
% 28.89/28.97  tff(decl_19323, type, 'cell communication with external signal leading to apoptosis': $i).
% 28.89/28.97  tff(decl_19324, type, 'cell-communication-with-external-signal-leading-to-apoptosis': $i).
% 28.89/28.97  tff(decl_19325, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_5: $i > $i).
% 28.89/28.97  tff(decl_19326, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_6: $i > $i).
% 28.89/28.97  tff(decl_19327, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_7: $i > $i).
% 28.89/28.97  tff(decl_19328, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_8: $i > $i).
% 28.89/28.97  tff(decl_19329, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_9: $i > $i).
% 28.89/28.97  tff(decl_19330, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_10: $i > $i).
% 28.89/28.97  tff(decl_19331, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_13: $i > $i).
% 28.89/28.97  tff(decl_19332, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_14: $i > $i).
% 28.89/28.97  tff(decl_19333, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_15: $i > $i).
% 28.89/28.97  tff(decl_19334, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_16: $i > $i).
% 28.89/28.97  tff(decl_19335, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_17: $i > $i).
% 28.89/28.97  tff(decl_19336, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_18: $i > $i).
% 28.89/28.97  tff(decl_19337, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_19: $i > $i).
% 28.89/28.97  tff(decl_19338, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_20: $i > $i).
% 28.89/28.97  tff(decl_19339, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_21: $i > $i).
% 28.89/28.97  tff(decl_19340, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_22: $i > $i).
% 28.89/28.97  tff(decl_19341, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_23: $i > $i).
% 28.89/28.97  tff(decl_19342, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_24: $i > $i).
% 28.89/28.97  tff(decl_19343, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_25: $i > $i).
% 28.89/28.97  tff(decl_19344, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_26: $i > $i).
% 28.89/28.97  tff(decl_19345, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_27: $i > $i).
% 28.89/28.97  tff(decl_19346, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_28: $i > $i).
% 28.89/28.97  tff(decl_19347, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_29: $i > $i).
% 28.89/28.97  tff(decl_19348, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_30: $i > $i).
% 28.89/28.97  tff(decl_19349, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_31: $i > $i).
% 28.89/28.97  tff(decl_19350, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_32: $i > $i).
% 28.89/28.97  tff(decl_19351, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_33: $i > $i).
% 28.89/28.97  tff(decl_19352, type, fn_cell_communication_with_external_signal_leading_to_apoptosis_34: $i > $i).
% 28.89/28.97  tff(decl_19353, type, fn_transmit_2: $i > $i).
% 28.89/28.97  tff(decl_19354, type, cell_communication_with_growth_factor_1: $i > $o).
% 28.89/28.97  tff(decl_19355, type, 'Cell-Communication-With-Growth-Factor': $i).
% 28.89/28.97  tff(decl_19356, type, 'A type of local cellular communication in which a secretory cell releases paracrine hormones, which act only on nearby cells,  in order to initiate a cellular response.': $i).
% 28.89/28.97  tff(decl_19357, type, 'gf based signaling': $i).
% 28.89/28.97  tff(decl_19358, type, 'gf-based-signaling': $i).
% 28.89/28.97  tff(decl_19359, type, 'paracrine signaling with growth factor': $i).
% 28.89/28.97  tff(decl_19360, type, 'cell communication with growth factor': $i).
% 28.89/28.97  tff(decl_19361, type, 'cell-communication-with-growth-factor': $i).
% 28.89/28.97  tff(decl_19362, type, cell_communication_with_local_regulator_1: $i > $o).
% 28.89/28.97  tff(decl_19363, type, fn_cell_communication_with_growth_factor_1: $i > $i).
% 28.89/28.97  tff(decl_19364, type, fn_cell_communication_with_growth_factor_2: $i > $i).
% 28.89/28.97  tff(decl_19365, type, fn_cell_communication_with_growth_factor_5: $i > $i).
% 28.89/28.97  tff(decl_19366, type, fn_cell_communication_with_growth_factor_6: $i > $i).
% 28.89/28.97  tff(decl_19367, type, fn_cell_communication_with_growth_factor_7: $i > $i).
% 28.89/28.97  tff(decl_19368, type, fn_cell_communication_with_growth_factor_8: $i > $i).
% 28.89/28.97  tff(decl_19369, type, fn_cell_communication_with_growth_factor_9: $i > $i).
% 28.89/28.97  tff(decl_19370, type, fn_cell_communication_with_growth_factor_10: $i > $i).
% 28.89/28.97  tff(decl_19371, type, fn_cell_communication_with_growth_factor_11: $i > $i).
% 28.89/28.97  tff(decl_19372, type, fn_cell_communication_with_growth_factor_12: $i > $i).
% 28.89/28.97  tff(decl_19373, type, fn_cell_communication_with_growth_factor_13: $i > $i).
% 28.89/28.97  tff(decl_19374, type, fn_cell_communication_with_growth_factor_14: $i > $i).
% 28.89/28.97  tff(decl_19375, type, fn_cell_communication_with_growth_factor_15: $i > $i).
% 28.89/28.97  tff(decl_19376, type, fn_cell_communication_with_growth_factor_16: $i > $i).
% 28.89/28.97  tff(decl_19377, type, fn_cell_communication_with_growth_factor_18: $i > $i).
% 28.89/28.97  tff(decl_19378, type, fn_cell_communication_with_growth_factor_19: $i > $i).
% 28.89/28.97  tff(decl_19379, type, fn_cell_communication_with_growth_factor_20: $i > $i).
% 28.89/28.97  tff(decl_19380, type, fn_cell_communication_with_growth_factor_21: $i > $i).
% 28.89/28.97  tff(decl_19381, type, fn_cell_communication_with_growth_factor_22: $i > $i).
% 28.89/28.97  tff(decl_19382, type, fn_cell_communication_with_growth_factor_23: $i > $i).
% 28.89/28.97  tff(decl_19383, type, fn_cell_communication_with_growth_factor_24: $i > $i).
% 28.89/28.97  tff(decl_19384, type, fn_cell_communication_with_growth_factor_25: $i > $i).
% 28.89/28.97  tff(decl_19385, type, phosphorylation_cascade_1: $i > $o).
% 28.89/28.97  tff(decl_19386, type, fn_cell_communication_with_growth_factor_26: $i > $i).
% 28.89/28.97  tff(decl_19387, type, fn_cell_communication_with_growth_factor_27: $i > $i).
% 28.89/28.97  tff(decl_19388, type, fn_cell_communication_with_growth_factor_28: $i > $i).
% 28.89/28.97  tff(decl_19389, type, fn_cell_communication_with_growth_factor_29: $i > $i).
% 28.89/28.97  tff(decl_19390, type, fn_cell_communication_with_growth_factor_30: $i > $i).
% 28.89/28.97  tff(decl_19391, type, fn_cell_communication_with_growth_factor_31: $i > $i).
% 28.89/28.97  tff(decl_19392, type, fn_cell_communication_with_growth_factor_32: $i > $i).
% 28.89/28.97  tff(decl_19393, type, fn_cell_communication_with_growth_factor_33: $i > $i).
% 28.89/28.97  tff(decl_19394, type, fn_cell_communication_with_growth_factor_34: $i > $i).
% 28.89/28.97  tff(decl_19395, type, fn_cell_communication_with_growth_factor_35: $i > $i).
% 28.89/28.97  tff(decl_19396, type, fn_cell_communication_with_growth_factor_36: $i > $i).
% 28.89/28.97  tff(decl_19397, type, fn_cell_communication_with_growth_factor_37: $i > $i).
% 28.89/28.97  tff(decl_19398, type, fn_cell_communication_with_growth_factor_38: $i > $i).
% 28.89/28.97  tff(decl_19399, type, signal_transduction_with_phosphorylation_cascade_1: $i > $o).
% 28.89/28.97  tff(decl_19400, type, fn_cell_communication_with_growth_factor_39: $i > $i).
% 28.89/28.97  tff(decl_19401, type, growth_factor_1: $i > $o).
% 28.89/28.97  tff(decl_19402, type, fn_cell_communication_with_growth_factor_40: $i > $i).
% 28.89/28.97  tff(decl_19403, type, fn_cell_communication_with_growth_factor_41: $i > $i).
% 28.89/28.97  tff(decl_19404, type, fn_cell_communication_with_growth_factor_42: $i > $i).
% 28.89/28.97  tff(decl_19405, type, secretory_cell_1: $i > $o).
% 28.89/28.97  tff(decl_19406, type, fn_cell_communication_with_growth_factor_43: $i > $i).
% 28.89/28.97  tff(decl_19407, type, fn_cell_communication_with_growth_factor_44: $i > $i).
% 28.89/28.97  tff(decl_19408, type, fn_cell_communication_with_growth_factor_45: $i > $i).
% 28.89/28.97  tff(decl_19409, type, messenger_1: $i > $o).
% 28.89/28.97  tff(decl_19410, type, local_regulator_1: $i > $o).
% 28.89/28.97  tff(decl_19411, type, fn_cell_communication_with_growth_factor_46: $i > $i).
% 28.89/28.97  tff(decl_19412, type, fn_chemical_signaling_4: $i > $i).
% 28.89/28.97  tff(decl_19413, type, fn_chemical_signaling_5: $i > $i).
% 28.89/28.97  tff(decl_19414, type, fn_signal_transduction_with_phosphorylation_cascade_77: $i > $i).
% 28.89/28.97  tff(decl_19415, type, fn_signal_transduction_with_phosphorylation_cascade_64: $i > $i).
% 28.89/28.97  tff(decl_19416, type, fn_signal_transduction_with_phosphorylation_cascade_115: $i > $i).
% 28.89/28.97  tff(decl_19417, type, fn_signal_transduction_with_phosphorylation_cascade_121: $i > $i).
% 28.89/28.97  tff(decl_19418, type, fn_signal_transduction_with_phosphorylation_cascade_70: $i > $i).
% 28.89/28.97  tff(decl_19419, type, fn_signal_transduction_with_phosphorylation_cascade_106: $i > $i).
% 28.89/28.97  tff(decl_19420, type, fn_cell_signaling_with_plasma_membrane_receptor_10: $i > $i).
% 28.89/28.97  tff(decl_19421, type, fn_signal_transduction_with_phosphorylation_cascade_105: $i > $i).
% 28.89/28.97  tff(decl_19422, type, fn_signal_transduction_with_phosphorylation_cascade_107: $i > $i).
% 28.89/28.97  tff(decl_19423, type, fn_signal_transduction_with_phosphorylation_cascade_83: $i > $i).
% 28.89/28.97  tff(decl_19424, type, fn_signal_transduction_with_phosphorylation_cascade_69: $i > $i).
% 28.89/28.97  tff(decl_19425, type, fn_signal_transduction_with_phosphorylation_cascade_67: $i > $i).
% 28.89/28.97  tff(decl_19426, type, fn_signal_transduction_with_phosphorylation_cascade_104: $i > $i).
% 28.89/28.97  tff(decl_19427, type, fn_phosphorylation_cascade_2: $i > $i).
% 28.89/28.97  tff(decl_19428, type, fn_phosphorylation_cascade_3: $i > $i).
% 28.89/28.97  tff(decl_19429, type, fn_signal_transduction_with_phosphorylation_cascade_97: $i > $i).
% 28.89/28.97  tff(decl_19430, type, fn_cell_communication_with_local_regulator_5: $i > $i).
% 28.89/28.97  tff(decl_19431, type, fn_cell_communication_with_local_regulator_4: $i > $i).
% 28.89/28.97  tff(decl_19432, type, fn_cell_communication_with_local_regulator_7: $i > $i).
% 28.89/28.97  tff(decl_19433, type, fn_cell_communication_with_local_regulator_3: $i > $i).
% 28.89/28.97  tff(decl_19434, type, fn_cell_communication_with_local_regulator_8: $i > $i).
% 28.89/28.97  tff(decl_19435, type, fn_cell_communication_with_local_regulator_6: $i > $i).
% 28.89/28.97  tff(decl_19436, type, 'Cell-Communication-With-Local-Regulator': $i).
% 28.89/28.97  tff(decl_19437, type, 'Local signaing among cells where the messenger molecules travel only a short distance to affect cells in their immediate vicinity.': $i).
% 28.89/28.97  tff(decl_19438, type, 'paracrine signaling': $i).
% 28.89/28.97  tff(decl_19439, type, 'cell communication with local regulator': $i).
% 28.89/28.97  tff(decl_19440, type, 'cell-communication-with-local-regulator': $i).
% 28.89/28.97  tff(decl_19441, type, fn_cell_communication_with_local_regulator_2: $i > $i).
% 28.89/28.97  tff(decl_19442, type, fn_local_regulator_2: $i > $i).
% 28.89/28.97  tff(decl_19443, type, cell_communication_event_0: $i).
% 28.89/28.97  tff(decl_19444, type, cell_communication_with_mating_factor_a_1: $i > $o).
% 28.89/28.97  tff(decl_19445, type, 'Cell-Communication-With-Mating-Factor-A': $i).
% 28.89/28.97  tff(decl_19446, type, 'Process of communication between yeast cells which uses mating factor A as the signaling molecule.': $i).
% 28.89/28.97  tff(decl_19447, type, 'cell communication with mating factor a': $i).
% 28.89/28.97  tff(decl_19448, type, 'cell-communication-with-mating-factor-a': $i).
% 28.89/28.97  tff(decl_19449, type, fn_cell_communication_with_mating_factor_a_1: $i > $i).
% 28.89/28.97  tff(decl_19450, type, microfilament_elongation_1: $i > $o).
% 28.89/28.97  tff(decl_19451, type, fn_cell_communication_with_mating_factor_a_2: $i > $i).
% 28.89/28.97  tff(decl_19452, type, mating_type_a_1: $i > $o).
% 28.89/28.97  tff(decl_19453, type, fn_cell_communication_with_mating_factor_a_3: $i > $i).
% 28.89/28.97  tff(decl_19454, type, fn_cell_communication_with_mating_factor_a_4: $i > $i).
% 28.89/28.97  tff(decl_19455, type, mating_type_alpha_1: $i > $o).
% 28.89/28.97  tff(decl_19456, type, fn_cell_communication_with_mating_factor_a_5: $i > $i).
% 28.89/28.97  tff(decl_19457, type, cell_signaling_with_mating_factor_1: $i > $o).
% 28.89/28.97  tff(decl_19458, type, fn_cell_communication_with_mating_factor_a_6: $i > $i).
% 28.89/28.97  tff(decl_19459, type, shmoo_formation_1: $i > $o).
% 28.89/28.97  tff(decl_19460, type, fn_cell_communication_with_mating_factor_a_7: $i > $i).
% 28.89/28.97  tff(decl_19461, type, fn_cell_communication_with_mating_factor_a_8: $i > $i).
% 28.89/28.97  tff(decl_19462, type, mating_factor_a_1: $i > $o).
% 28.89/28.97  tff(decl_19463, type, fn_cell_signaling_with_mating_factor_85: $i > $i).
% 28.89/28.97  tff(decl_19464, type, fn_shmoo_formation_1: $i > $i).
% 28.89/28.97  tff(decl_19465, type, fn_cell_signaling_with_mating_factor_62: $i > $i).
% 28.89/28.97  tff(decl_19466, type, mating_factor_1: $i > $o).
% 28.89/28.97  tff(decl_19467, type, fn_shmoo_formation_2: $i > $i).
% 28.89/28.97  tff(decl_19468, type, cell_communication_with_mating_factor_alpha_1: $i > $o).
% 28.89/28.97  tff(decl_19469, type, 'Cell-Communication-With-Mating-Factor-Alpha': $i).
% 28.89/28.97  tff(decl_19470, type, 'Process of communication between yeast cells which uses mating factor Alpha as the signaling molecule.': $i).
% 28.89/28.97  tff(decl_19471, type, 'cell communication with mating factor alpha': $i).
% 28.89/28.97  tff(decl_19472, type, 'cell-communication-with-mating-factor-alpha': $i).
% 28.89/28.97  tff(decl_19473, type, fn_cell_communication_with_mating_factor_alpha_1: $i > $i).
% 28.89/28.97  tff(decl_19474, type, fn_cell_communication_with_mating_factor_alpha_2: $i > $i).
% 28.89/28.97  tff(decl_19475, type, fn_cell_communication_with_mating_factor_alpha_3: $i > $i).
% 28.89/28.97  tff(decl_19476, type, fn_cell_communication_with_mating_factor_alpha_4: $i > $i).
% 28.89/28.97  tff(decl_19477, type, fn_cell_communication_with_mating_factor_alpha_5: $i > $i).
% 28.89/28.97  tff(decl_19478, type, fn_cell_communication_with_mating_factor_alpha_6: $i > $i).
% 28.89/28.97  tff(decl_19479, type, fn_cell_communication_with_mating_factor_alpha_7: $i > $i).
% 28.89/28.97  tff(decl_19480, type, fn_cell_communication_with_mating_factor_alpha_8: $i > $i).
% 28.89/28.97  tff(decl_19481, type, fn_cell_communication_with_mating_factor_alpha_9: $i > $i).
% 28.89/28.97  tff(decl_19482, type, fn_cell_communication_with_mating_factor_alpha_10: $i > $i).
% 28.89/28.97  tff(decl_19483, type, fn_cell_communication_with_mating_factor_alpha_11: $i > $i).
% 28.89/28.97  tff(decl_19484, type, fn_cell_communication_with_mating_factor_alpha_12: $i > $i).
% 28.89/28.97  tff(decl_19485, type, fn_cell_communication_with_mating_factor_alpha_13: $i > $i).
% 28.89/28.97  tff(decl_19486, type, fn_cell_communication_with_mating_factor_alpha_14: $i > $i).
% 28.89/28.97  tff(decl_19487, type, fn_cell_communication_with_mating_factor_alpha_15: $i > $i).
% 28.89/28.97  tff(decl_19488, type, fn_cell_communication_with_mating_factor_alpha_16: $i > $i).
% 28.89/28.97  tff(decl_19489, type, fn_cell_communication_with_mating_factor_alpha_17: $i > $i).
% 28.89/28.97  tff(decl_19490, type, mating_factor_alpha_1: $i > $o).
% 28.89/28.97  tff(decl_19491, type, fn_cell_signaling_with_mating_factor_90: $i > $i).
% 28.89/28.97  tff(decl_19492, type, fn_cell_signaling_with_mating_factor_92: $i > $i).
% 28.89/28.97  tff(decl_19493, type, fn_cell_signaling_with_mating_factor_91: $i > $i).
% 28.89/28.97  tff(decl_19494, type, fn_cell_signaling_with_mating_factor_94: $i > $i).
% 28.89/28.97  tff(decl_19495, type, fn_cell_signaling_with_mating_factor_59: $i > $i).
% 28.89/28.97  tff(decl_19496, type, fn_cell_signaling_with_mating_factor_93: $i > $i).
% 28.89/28.97  tff(decl_19497, type, fn_cell_signaling_with_mating_factor_60: $i > $i).
% 28.89/28.97  tff(decl_19498, type, fn_cell_signaling_with_mating_factor_1: $i > $i).
% 28.89/28.97  tff(decl_19499, type, fn_cell_signaling_with_mating_factor_95: $i > $i).
% 28.89/28.97  tff(decl_19500, type, fn_cell_signaling_with_mating_factor_87: $i > $i).
% 28.89/28.97  tff(decl_19501, type, saccharomyces_cerevisiae_1: $i > $o).
% 28.89/28.97  tff(decl_19502, type, fn_cell_signaling_with_mating_factor_61: $i > $i).
% 28.89/28.97  tff(decl_19503, type, cell_communication_with_mitochondrial_signal_leading_to_apoptosis_1: $i > $o).
% 28.89/28.97  tff(decl_19504, type, 'Cell-Communication-With-Mitochondrial-Signal-Leading-To-Apoptosis': $i).
% 28.89/28.97  tff(decl_19505, type, 'Series of events which leads to programmed cell death (apoptosis) in a cell; in this case, the signal for apoptosis is generated internally by the mitochondria.': $i).
% 28.89/28.97  tff(decl_19506, type, 'cell communication with mitochondrial signal leading to apoptosis': $i).
% 28.89/28.97  tff(decl_19507, type, 'cell-communication-with-mitochondrial-signal-leading-to-apoptosis': $i).
% 28.89/28.97  tff(decl_19508, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_1: $i > $i).
% 28.89/28.97  tff(decl_19509, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_2: $i > $i).
% 28.89/28.97  tff(decl_19510, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_4: $i > $i).
% 28.89/28.97  tff(decl_19511, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_6: $i > $i).
% 28.89/28.97  tff(decl_19512, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_7: $i > $i).
% 28.89/28.97  tff(decl_19513, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_8: $i > $i).
% 28.89/28.97  tff(decl_19514, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_11: $i > $i).
% 28.89/28.97  tff(decl_19515, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_12: $i > $i).
% 28.89/28.97  tff(decl_19516, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_13: $i > $i).
% 28.89/28.97  tff(decl_19517, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_18: $i > $i).
% 28.89/28.97  tff(decl_19518, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_19: $i > $i).
% 28.89/28.97  tff(decl_19519, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_20: $i > $i).
% 28.89/28.97  tff(decl_19520, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_21: $i > $i).
% 28.89/28.97  tff(decl_19521, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_22: $i > $i).
% 28.89/28.97  tff(decl_19522, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_23: $i > $i).
% 28.89/28.97  tff(decl_19523, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_24: $i > $i).
% 28.89/28.97  tff(decl_19524, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_25: $i > $i).
% 28.89/28.97  tff(decl_19525, type, confine_1: $i > $o).
% 28.89/28.97  tff(decl_19526, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_26: $i > $i).
% 28.89/28.97  tff(decl_19527, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_27: $i > $i).
% 28.89/28.97  tff(decl_19528, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_28: $i > $i).
% 28.89/28.97  tff(decl_19529, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_29: $i > $i).
% 28.89/28.97  tff(decl_19530, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_30: $i > $i).
% 28.89/28.97  tff(decl_19531, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_31: $i > $i).
% 28.89/28.97  tff(decl_19532, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_32: $i > $i).
% 28.89/28.97  tff(decl_19533, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_33: $i > $i).
% 28.89/28.97  tff(decl_19534, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_34: $i > $i).
% 28.89/28.97  tff(decl_19535, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_35: $i > $i).
% 28.89/28.97  tff(decl_19536, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_36: $i > $i).
% 28.89/28.97  tff(decl_19537, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_37: $i > $i).
% 28.89/28.97  tff(decl_19538, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_38: $i > $i).
% 28.89/28.97  tff(decl_19539, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_39: $i > $i).
% 28.89/28.97  tff(decl_19540, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_40: $i > $i).
% 28.89/28.97  tff(decl_19541, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_41: $i > $i).
% 28.89/28.97  tff(decl_19542, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_42: $i > $i).
% 28.89/28.97  tff(decl_19543, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_43: $i > $i).
% 28.89/28.97  tff(decl_19544, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_44: $i > $i).
% 28.89/28.97  tff(decl_19545, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_45: $i > $i).
% 28.89/28.97  tff(decl_19546, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_46: $i > $i).
% 28.89/28.97  tff(decl_19547, type, cytochrome_c_1: $i > $o).
% 28.89/28.97  tff(decl_19548, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_47: $i > $i).
% 28.89/28.97  tff(decl_19549, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_48: $i > $i).
% 28.89/28.97  tff(decl_19550, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_49: $i > $i).
% 28.89/28.97  tff(decl_19551, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_50: $i > $i).
% 28.89/28.97  tff(decl_19552, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_51: $i > $i).
% 28.89/28.97  tff(decl_19553, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_52: $i > $i).
% 28.89/28.97  tff(decl_19554, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_53: $i > $i).
% 28.89/28.97  tff(decl_19555, type, fn_confine_2: $i > $i).
% 28.89/28.97  tff(decl_19556, type, fn_cellular_respiration_63: $i > $i).
% 28.89/28.97  tff(decl_19557, type, fn_eukaryotic_cellular_respiration_96: $i > $i).
% 28.89/28.97  tff(decl_19558, type, fn_semiautonomous_organelle_5: $i > $i).
% 28.89/28.97  tff(decl_19559, type, fn_eukaryotic_cellular_respiration_48: $i > $i).
% 28.89/28.97  tff(decl_19560, type, fn_confine_1: $i > $i).
% 28.89/28.97  tff(decl_19561, type, fn_eukaryotic_oxidative_phosphorylation_334: $i > $i).
% 28.89/28.97  tff(decl_19562, type, fn_oxidative_phosphorylation_15: $i > $i).
% 28.89/28.97  tff(decl_19563, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_16: $i > $i).
% 28.89/28.97  tff(decl_19564, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_17: $i > $i).
% 28.89/28.97  tff(decl_19565, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_14: $i > $i).
% 28.89/28.97  tff(decl_19566, type, fn_cell_communication_with_mitochondrial_signal_leading_to_apoptosis_15: $i > $i).
% 28.89/28.97  tff(decl_19567, type, 'Cell-Communication-With-Neurotransmitter': $i).
% 28.89/28.97  tff(decl_19568, type, 'Communication between two neurons or a neuron and a different effector cell via neurotransmitter molecules that diffuse across the synaptic gap between one cell and the other.': $i).
% 28.89/28.97  tff(decl_19569, type, 'synaptic signaling': $i).
% 28.89/28.97  tff(decl_19570, type, 'cell communication with neurotransmitter': $i).
% 28.89/28.97  tff(decl_19571, type, 'cell-communication-with-neurotransmitter': $i).
% 28.89/28.97  tff(decl_19572, type, microbial_cell_to_cell_communication_1: $i > $o).
% 28.89/28.97  tff(decl_19573, type, fn_cell_communication_with_neurotransmitter_2: $i > $i).
% 28.89/28.97  tff(decl_19574, type, open_1: $i > $o).
% 28.89/28.97  tff(decl_19575, type, fn_cell_communication_with_neurotransmitter_3: $i > $i).
% 28.89/28.97  tff(decl_19576, type, fn_cell_communication_with_neurotransmitter_5: $i > $i).
% 28.89/28.97  tff(decl_19577, type, fn_cell_communication_with_neurotransmitter_6: $i > $i).
% 28.89/28.97  tff(decl_19578, type, fn_cell_communication_with_neurotransmitter_12: $i > $i).
% 28.89/28.97  tff(decl_19579, type, fn_cell_communication_with_neurotransmitter_18: $i > $i).
% 28.89/28.97  tff(decl_19580, type, fn_signal_generation_2: $i > $i).
% 28.89/28.97  tff(decl_19581, type, fn_signal_generation_1: $i > $i).
% 28.89/28.97  tff(decl_19582, type, fn_synapse_4: $i > $i).
% 28.89/28.97  tff(decl_19583, type, fn_synapse_3: $i > $i).
% 28.89/28.97  tff(decl_19584, type, cell_communication_with_nuclear_signal_leading_to_apoptosis_1: $i > $o).
% 28.89/28.97  tff(decl_19585, type, 'Cell-Communication-With-Nuclear-Signal-Leading-To-Apoptosis': $i).
% 28.89/28.97  tff(decl_19586, type, 'Series of events which leads to programmed cell death (apoptosis) in a cell; in this case, the signal for apoptosis is generated internally by the nucleus.': $i).
% 28.89/28.97  tff(decl_19587, type, 'cell communication with nuclear signal leading to apoptosis': $i).
% 28.89/28.97  tff(decl_19588, type, 'cell-communication-with-nuclear-signal-leading-to-apoptosis': $i).
% 28.89/28.97  tff(decl_19589, type, fn_cell_communication_with_nuclear_signal_leading_to_apoptosis_1: $i > $i).
% 28.89/28.97  tff(decl_19590, type, irreparable_dna_damage_1: $i > $o).
% 28.89/28.97  tff(decl_19591, type, fn_cell_communication_with_nuclear_signal_leading_to_apoptosis_2: $i > $i).
% 28.89/28.97  tff(decl_19592, type, fn_cell_communication_with_nuclear_signal_leading_to_apoptosis_3: $i > $i).
% 28.89/28.97  tff(decl_19593, type, fn_cell_communication_with_nuclear_signal_leading_to_apoptosis_4: $i > $i).
% 28.89/28.97  tff(decl_19594, type, fn_cell_communication_with_nuclear_signal_leading_to_apoptosis_5: $i > $i).
% 28.89/28.97  tff(decl_19595, type, fn_cell_communication_with_nuclear_signal_leading_to_apoptosis_6: $i > $i).
% 28.89/28.97  tff(decl_19596, type, cell_communication_with_steroid_hormone_1: $i > $o).
% 28.89/28.97  tff(decl_19597, type, 'Cell-Communication-With-Steroid-Hormone': $i).
% 28.89/28.97  tff(decl_19598, type, 'The process of cellular communication in animals in which the signal molecule is a steroid hormone.': $i).
% 28.89/28.97  tff(decl_19599, type, 'endocrine signaling with steroid hormone': $i).
% 28.89/28.97  tff(decl_19600, type, 'cell communication with steroid hormone': $i).
% 28.89/28.97  tff(decl_19601, type, 'cell-communication-with-steroid-hormone': $i).
% 28.89/28.97  tff(decl_19602, type, fn_cell_communication_with_steroid_hormone_1: $i > $i).
% 28.89/28.97  tff(decl_19603, type, fn_cell_communication_with_steroid_hormone_2: $i > $i).
% 28.89/28.97  tff(decl_19604, type, fn_cell_communication_with_steroid_hormone_3: $i > $i).
% 28.89/28.97  tff(decl_19605, type, fn_cell_communication_with_steroid_hormone_4: $i > $i).
% 28.89/28.97  tff(decl_19606, type, fn_cell_communication_with_steroid_hormone_5: $i > $i).
% 28.89/28.97  tff(decl_19607, type, fn_cell_communication_with_steroid_hormone_6: $i > $i).
% 28.89/28.97  tff(decl_19608, type, intracellular_receptor_1: $i > $o).
% 28.89/28.97  tff(decl_19609, type, fn_cell_communication_with_steroid_hormone_7: $i > $i).
% 28.89/28.97  tff(decl_19610, type, fn_cell_communication_with_steroid_hormone_8: $i > $i).
% 28.89/28.97  tff(decl_19611, type, fn_cell_communication_with_steroid_hormone_9: $i > $i).
% 28.89/28.97  tff(decl_19612, type, fn_cell_communication_with_steroid_hormone_10: $i > $i).
% 28.89/28.97  tff(decl_19613, type, fn_cell_communication_with_steroid_hormone_11: $i > $i).
% 28.89/28.97  tff(decl_19614, type, fn_cell_communication_with_steroid_hormone_12: $i > $i).
% 28.89/28.97  tff(decl_19615, type, fn_cell_communication_with_steroid_hormone_13: $i > $i).
% 28.89/28.97  tff(decl_19616, type, fn_cell_communication_with_steroid_hormone_14: $i > $i).
% 28.89/28.97  tff(decl_19617, type, fn_cell_communication_with_steroid_hormone_15: $i > $i).
% 28.89/28.97  tff(decl_19618, type, fn_cell_communication_with_steroid_hormone_16: $i > $i).
% 28.89/28.97  tff(decl_19619, type, cell_signaling_with_intracellular_receptor_1: $i > $o).
% 28.89/28.97  tff(decl_19620, type, fn_cell_communication_with_steroid_hormone_17: $i > $i).
% 28.89/28.97  tff(decl_19621, type, fn_cell_communication_with_steroid_hormone_18: $i > $i).
% 28.89/28.97  tff(decl_19622, type, fn_cell_communication_with_steroid_hormone_19: $i > $i).
% 28.89/28.97  tff(decl_19623, type, medium_1: $i > $o).
% 28.89/28.97  tff(decl_19624, type, fn_cell_communication_with_steroid_hormone_20: $i > $i).
% 28.89/28.97  tff(decl_19625, type, fn_cell_communication_with_steroid_hormone_21: $i > $i).
% 28.89/28.97  tff(decl_19626, type, fn_cell_communication_with_steroid_hormone_22: $i > $i).
% 28.89/28.97  tff(decl_19627, type, fn_cell_signaling_with_intracellular_receptor_10: $i > $i).
% 28.89/28.97  tff(decl_19628, type, fn_cell_signaling_with_intracellular_receptor_13: $i > $i).
% 28.89/28.97  tff(decl_19629, type, fn_cell_signaling_with_intracellular_receptor_15: $i > $i).
% 28.89/28.97  tff(decl_19630, type, fn_medium_1: $i > $i).
% 28.89/28.97  tff(decl_19631, type, fn_cell_signaling_with_intracellular_receptor_7: $i > $i).
% 28.89/28.97  tff(decl_19632, type, fn_cell_signaling_with_intracellular_receptor_9: $i > $i).
% 28.89/28.97  tff(decl_19633, type, fn_cell_signaling_with_intracellular_receptor_14: $i > $i).
% 28.89/28.97  tff(decl_19634, type, fn_long_distance_cell_communication_7: $i > $i).
% 28.89/28.97  tff(decl_19635, type, cell_communication_with_testosterone_1: $i > $o).
% 28.89/28.97  tff(decl_19636, type, 'Cell-Communication-With-Testosterone': $i).
% 28.89/28.97  tff(decl_19637, type, 'The process of cellular communication in animals in which the signal molecule is testosterone.': $i).
% 28.89/28.97  tff(decl_19638, type, 'endocrine signaling with testosterone': $i).
% 28.89/28.97  tff(decl_19639, type, 'cell communication with testosterone': $i).
% 28.89/28.97  tff(decl_19640, type, 'cell-communication-with-testosterone': $i).
% 28.89/28.97  tff(decl_19641, type, fn_cell_communication_with_testosterone_1: $i > $i).
% 28.89/28.97  tff(decl_19642, type, fn_cell_communication_with_testosterone_2: $i > $i).
% 28.89/28.97  tff(decl_19643, type, fn_cell_communication_with_testosterone_3: $i > $i).
% 28.89/28.97  tff(decl_19644, type, fn_cell_communication_with_testosterone_4: $i > $i).
% 28.89/28.97  tff(decl_19645, type, fn_cell_communication_with_testosterone_5: $i > $i).
% 28.89/28.97  tff(decl_19646, type, fn_cell_communication_with_testosterone_6: $i > $i).
% 28.89/28.97  tff(decl_19647, type, fn_cell_communication_with_testosterone_7: $i > $i).
% 28.89/28.97  tff(decl_19648, type, fn_cell_communication_with_testosterone_8: $i > $i).
% 28.89/28.97  tff(decl_19649, type, fn_cell_communication_with_testosterone_9: $i > $i).
% 28.89/28.97  tff(decl_19650, type, fn_cell_communication_with_testosterone_10: $i > $i).
% 28.89/28.97  tff(decl_19651, type, fn_cell_communication_with_testosterone_11: $i > $i).
% 28.89/28.97  tff(decl_19652, type, signal_transduction_with_testosterone_1: $i > $o).
% 28.89/28.97  tff(decl_19653, type, fn_cell_communication_with_testosterone_12: $i > $i).
% 28.89/28.97  tff(decl_19654, type, signal_reception_with_testosterone_1: $i > $o).
% 28.89/28.97  tff(decl_19655, type, fn_cell_communication_with_testosterone_13: $i > $i).
% 28.89/28.97  tff(decl_19656, type, fn_cell_communication_with_testosterone_14: $i > $i).
% 28.89/28.97  tff(decl_19657, type, fn_cell_communication_with_testosterone_15: $i > $i).
% 28.89/28.97  tff(decl_19658, type, fn_cell_communication_with_testosterone_16: $i > $i).
% 28.89/28.97  tff(decl_19659, type, fn_cell_communication_with_testosterone_17: $i > $i).
% 28.89/28.97  tff(decl_19660, type, fn_cell_communication_with_testosterone_18: $i > $i).
% 28.89/28.97  tff(decl_19661, type, fn_cell_communication_with_testosterone_19: $i > $i).
% 28.89/28.97  tff(decl_19662, type, testosterone_receptor_1: $i > $o).
% 28.89/28.97  tff(decl_19663, type, fn_cell_communication_with_testosterone_20: $i > $i).
% 28.89/28.97  tff(decl_19664, type, fn_cell_communication_with_testosterone_21: $i > $i).
% 28.89/28.97  tff(decl_19665, type, fn_cell_communication_with_testosterone_22: $i > $i).
% 28.89/28.97  tff(decl_19666, type, fn_cell_communication_with_testosterone_23: $i > $i).
% 28.89/28.97  tff(decl_19667, type, fn_cell_communication_with_testosterone_24: $i > $i).
% 28.89/28.97  tff(decl_19668, type, fn_cell_communication_with_testosterone_25: $i > $i).
% 28.89/28.97  tff(decl_19669, type, steroid_1: $i > $o).
% 28.89/28.97  tff(decl_19670, type, fn_cell_communication_with_testosterone_26: $i > $i).
% 28.89/28.97  tff(decl_19671, type, fn_cell_communication_with_testosterone_27: $i > $i).
% 28.89/28.97  tff(decl_19672, type, fn_cell_communication_with_testosterone_28: $i > $i).
% 28.89/28.97  tff(decl_19673, type, fn_cell_communication_with_testosterone_29: $i > $i).
% 28.89/28.97  tff(decl_19674, type, fn_cell_communication_with_testosterone_30: $i > $i).
% 28.89/28.97  tff(decl_19675, type, chemical_messenger_1: $i > $o).
% 28.89/28.97  tff(decl_19676, type, fn_cell_communication_with_testosterone_31: $i > $i).
% 28.89/28.97  tff(decl_19677, type, fn_cell_communication_with_testosterone_32: $i > $i).
% 28.89/28.97  tff(decl_19678, type, sex_linked_gene_1: $i > $o).
% 28.89/28.97  tff(decl_19679, type, fn_cell_communication_with_testosterone_33: $i > $i).
% 28.89/28.97  tff(decl_19680, type, fn_cell_communication_with_testosterone_34: $i > $i).
% 28.89/28.97  tff(decl_19681, type, fn_cell_communication_with_testosterone_35: $i > $i).
% 28.89/28.97  tff(decl_19682, type, fn_cell_communication_with_testosterone_36: $i > $i).
% 28.89/28.97  tff(decl_19683, type, fn_cell_communication_with_testosterone_38: $i > $i).
% 28.89/28.97  tff(decl_19684, type, fn_cell_communication_with_testosterone_39: $i > $i).
% 28.89/28.97  tff(decl_19685, type, fn_cell_communication_with_testosterone_40: $i > $i).
% 28.89/28.97  tff(decl_19686, type, fn_cell_communication_with_testosterone_41: $i > $i).
% 28.89/28.97  tff(decl_19687, type, fn_cell_communication_with_testosterone_42: $i > $i).
% 28.89/28.97  tff(decl_19688, type, fn_cell_communication_with_testosterone_43: $i > $i).
% 28.89/28.97  tff(decl_19689, type, transcription_unit_1: $i > $o).
% 28.89/28.97  tff(decl_19690, type, fn_transcription_6: $i > $i).
% 28.89/28.97  tff(decl_19691, type, fn_transcription_19: $i > $i).
% 28.89/28.97  tff(decl_19692, type, fn_signal_reception_with_testosterone_3: $i > $i).
% 28.89/28.97  tff(decl_19693, type, fn_signal_reception_with_testosterone_23: $i > $i).
% 28.89/28.97  tff(decl_19694, type, fn_signal_transduction_with_testosterone_11: $i > $i).
% 28.89/28.97  tff(decl_19695, type, fn_cell_signaling_with_intracellular_receptor_5: $i > $i).
% 28.89/28.97  tff(decl_19696, type, fn_cell_signaling_with_intracellular_receptor_6: $i > $i).
% 28.89/28.97  tff(decl_19697, type, fn_transcription_21: $i > $i).
% 28.89/28.97  tff(decl_19698, type, fn_signal_reception_with_testosterone_1: $i > $i).
% 28.89/28.97  tff(decl_19699, type, fn_signal_reception_with_testosterone_7: $i > $i).
% 28.89/28.97  tff(decl_19700, type, fn_signal_reception_with_testosterone_8: $i > $i).
% 28.89/28.97  tff(decl_19701, type, fn_signal_reception_with_testosterone_9: $i > $i).
% 28.89/28.97  tff(decl_19702, type, fn_signal_reception_with_testosterone_11: $i > $i).
% 28.89/28.97  tff(decl_19703, type, fn_transcription_13: $i > $i).
% 28.89/28.97  tff(decl_19704, type, fn_signal_reception_with_testosterone_12: $i > $i).
% 28.89/28.97  tff(decl_19705, type, fn_transcription_22: $i > $i).
% 28.89/28.97  tff(decl_19706, type, fn_signal_reception_with_testosterone_10: $i > $i).
% 28.89/28.97  tff(decl_19707, type, fn_signal_transduction_with_testosterone_12: $i > $i).
% 28.89/28.97  tff(decl_19708, type, fn_hormone_4: $i > $i).
% 28.89/28.97  tff(decl_19709, type, fn_hormone_1: $i > $i).
% 28.89/28.97  tff(decl_19710, type, fn_testosterone_9: $i > $i).
% 28.89/28.97  tff(decl_19711, type, fn_steroid_12: $i > $i).
% 28.89/28.97  tff(decl_19712, type, fn_testosterone_12: $i > $i).
% 28.89/28.97  tff(decl_19713, type, fn_hormone_2: $i > $i).
% 28.89/28.97  tff(decl_19714, type, fn_testosterone_14: $i > $i).
% 28.89/28.97  tff(decl_19715, type, fn_signal_reception_with_testosterone_13: $i > $i).
% 28.89/28.97  tff(decl_19716, type, fn_cell_communication_with_testosterone_37: $i > $i).
% 28.89/28.97  tff(decl_19717, type, cell_communication_with_thyroid_hormone_1: $i > $o).
% 28.89/28.97  tff(decl_19718, type, 'Cell-Communication-With-Thyroid-Hormone': $i).
% 28.89/28.97  tff(decl_19719, type, 'The process of cellular communication in animals in which the signal molecule is thyroid hormone.': $i).
% 28.89/28.97  tff(decl_19720, type, 'endocrine signaling with thyroid hormone': $i).
% 28.89/28.97  tff(decl_19721, type, 'cell communication with thyroid hormone': $i).
% 28.89/28.97  tff(decl_19722, type, 'cell-communication-with-thyroid-hormone': $i).
% 28.89/28.97  tff(decl_19723, type, fn_cell_communication_with_thyroid_hormone_1: $i > $i).
% 28.89/28.97  tff(decl_19724, type, fn_cell_communication_with_thyroid_hormone_2: $i > $i).
% 28.89/28.97  tff(decl_19725, type, fn_cell_communication_with_thyroid_hormone_5: $i > $i).
% 28.89/28.97  tff(decl_19726, type, fn_cell_communication_with_thyroid_hormone_6: $i > $i).
% 28.89/28.97  tff(decl_19727, type, fn_cell_communication_with_thyroid_hormone_7: $i > $i).
% 28.89/28.97  tff(decl_19728, type, fn_cell_communication_with_thyroid_hormone_8: $i > $i).
% 28.89/28.97  tff(decl_19729, type, fn_cell_communication_with_thyroid_hormone_9: $i > $i).
% 28.89/28.97  tff(decl_19730, type, fn_cell_communication_with_thyroid_hormone_10: $i > $i).
% 28.89/28.97  tff(decl_19731, type, fn_cell_communication_with_thyroid_hormone_11: $i > $i).
% 28.89/28.97  tff(decl_19732, type, thyroid_hormone_receptor_1: $i > $o).
% 28.89/28.97  tff(decl_19733, type, fn_cell_communication_with_thyroid_hormone_12: $i > $i).
% 28.89/28.97  tff(decl_19734, type, fn_cell_communication_with_thyroid_hormone_13: $i > $i).
% 28.89/28.97  tff(decl_19735, type, fn_cell_communication_with_thyroid_hormone_14: $i > $i).
% 28.89/28.97  tff(decl_19736, type, fn_cell_communication_with_thyroid_hormone_15: $i > $i).
% 28.89/28.97  tff(decl_19737, type, fn_cell_communication_with_thyroid_hormone_16: $i > $i).
% 28.89/28.97  tff(decl_19738, type, fn_cell_communication_with_thyroid_hormone_17: $i > $i).
% 28.89/28.97  tff(decl_19739, type, fn_cell_communication_with_thyroid_hormone_18: $i > $i).
% 28.89/28.97  tff(decl_19740, type, fn_cell_communication_with_thyroid_hormone_19: $i > $i).
% 28.89/28.97  tff(decl_19741, type, fn_cell_communication_with_thyroid_hormone_20: $i > $i).
% 28.89/28.97  tff(decl_19742, type, fn_cell_communication_with_thyroid_hormone_21: $i > $i).
% 28.89/28.97  tff(decl_19743, type, thyroid_hormone_1: $i > $o).
% 28.89/28.97  tff(decl_19744, type, fn_cell_communication_with_thyroid_hormone_22: $i > $i).
% 28.89/28.97  tff(decl_19745, type, fn_cell_communication_with_thyroid_hormone_23: $i > $i).
% 28.89/28.97  tff(decl_19746, type, fn_cell_communication_with_thyroid_hormone_24: $i > $i).
% 28.89/28.97  tff(decl_19747, type, fn_cell_communication_with_thyroid_hormone_25: $i > $i).
% 28.89/28.97  tff(decl_19748, type, fn_cell_communication_with_thyroid_hormone_26: $i > $i).
% 28.89/28.97  tff(decl_19749, type, fn_cell_communication_with_thyroid_hormone_27: $i > $i).
% 28.89/28.97  tff(decl_19750, type, fn_cell_communication_with_thyroid_hormone_28: $i > $i).
% 28.89/28.97  tff(decl_19751, type, fn_nucleus_17: $i > $i).
% 28.89/28.97  tff(decl_19752, type, fn_receptor_protein_1: $i > $i).
% 28.89/28.97  tff(decl_19753, type, fn_signal_reception_9: $i > $i).
% 28.89/28.97  tff(decl_19754, type, fn_cell_communication_with_thyroid_hormone_4: $i > $i).
% 28.89/28.97  tff(decl_19755, type, fn_cell_communication_with_thyroid_hormone_3: $i > $i).
% 28.89/28.97  tff(decl_19756, type, cell_crawling_1: $i > $o).
% 28.89/28.97  tff(decl_19757, type, 'Cell-Crawling': $i).
% 28.89/28.97  tff(decl_19758, type, 'The movement of cells from one location to another during embryonic development, wound healing, and the immune response.': $i).
% 28.89/28.97  tff(decl_19759, type, crawl: $i).
% 28.89/28.97  tff(decl_19760, type, 'crawling of cell': $i).
% 28.89/28.97  tff(decl_19761, type, 'cell crawling': $i).
% 28.89/28.97  tff(decl_19762, type, 'cell-crawling': $i).
% 28.89/28.97  tff(decl_19763, type, development_related_intercellular_process_1: $i > $o).
% 28.89/28.97  tff(decl_19764, type, 'Cell-Cycle': $i).
% 28.89/28.97  tff(decl_19765, type, 'The ordered series of events that occur in the life of a cell leading to its division.': $i).
% 28.89/28.97  tff(decl_19766, type, 'cycle of cell': $i).
% 28.89/28.97  tff(decl_19767, type, 'cell cycle': $i).
% 28.89/28.97  tff(decl_19768, type, 'cell-cycle': $i).
% 28.89/28.97  tff(decl_19769, type, fn_cell_cycle_1: $i > $i).
% 28.89/28.97  tff(decl_19770, type, fn_cell_cycle_3: $i > $i).
% 28.89/28.97  tff(decl_19771, type, fn_cell_cycle_4: $i > $i).
% 28.89/28.97  tff(decl_19772, type, fn_cell_cycle_5: $i > $i).
% 28.89/28.97  tff(decl_19773, type, fn_cell_cycle_6: $i > $i).
% 28.89/28.97  tff(decl_19774, type, interphase_0: $i).
% 28.89/28.97  tff(decl_19775, type, cell_cycle_process_1: $i > $o).
% 28.89/28.97  tff(decl_19776, type, 'Cell-Cycle-Process': $i).
% 28.89/28.97  tff(decl_19777, type, 'Cellular process which relates to the cycle of a cell\\s growth and division (the cell cycle)': $i).
% 28.89/28.97  tff(decl_19778, type, 'undergo the cell cycle process': $i).
% 28.89/28.97  tff(decl_19779, type, 'cell cycle process': $i).
% 28.89/28.97  tff(decl_19780, type, 'cell-cycle-process': $i).
% 28.89/28.97  tff(decl_19781, type, cell_determination_1: $i > $o).
% 28.89/28.97  tff(decl_19782, type, 'Cell-Determination': $i).
% 28.89/28.97  tff(decl_19783, type, 'The progressive restriction of developmental potential in which the possible fate of each cell becomes more limited as an embryo develops. At the end of determination, a cell is committed to its fate.': $i).
% 28.89/28.97  tff(decl_19784, type, determination: $i).
% 28.89/28.97  tff(decl_19785, type, determine: $i).
% 28.89/28.97  tff(decl_19786, type, 'determination of cell': $i).
% 28.89/28.97  tff(decl_19787, type, 'cell determination': $i).
% 28.89/28.97  tff(decl_19788, type, 'cell-determination': $i).
% 28.89/28.97  tff(decl_19789, type, embryonic_process_1: $i > $o).
% 28.89/28.97  tff(decl_19790, type, childbirth_1: $i > $o).
% 28.89/28.97  tff(decl_19791, type, compaction_1: $i > $o).
% 28.89/28.97  tff(decl_19792, type, gestation_1: $i > $o).
% 28.89/28.97  tff(decl_19793, type, organogenesis_1: $i > $o).
% 28.89/28.97  tff(decl_19794, type, oviparous_1: $i > $o).
% 28.89/28.97  tff(decl_19795, type, ovoviviparous_1: $i > $o).
% 28.89/28.97  tff(decl_19796, type, ovulation_1: $i > $o).
% 28.89/28.97  tff(decl_19797, type, phase_change_1: $i > $o).
% 28.89/28.97  tff(decl_19798, type, primary_growth_1: $i > $o).
% 28.89/28.97  tff(decl_19799, type, protostome_development_1: $i > $o).
% 28.89/28.97  tff(decl_19800, type, radial_cleavage_1: $i > $o).
% 28.89/28.97  tff(decl_19801, type, senescence_1: $i > $o).
% 28.89/28.97  tff(decl_19802, type, torsion_1: $i > $o).
% 28.89/28.97  tff(decl_19803, type, viviparous_1: $i > $o).
% 28.89/28.97  tff(decl_19804, type, fn_cell_determination_1: $i > $i).
% 28.89/28.97  tff(decl_19805, type, fn_cell_determination_4: $i > $i).
% 28.89/28.97  tff(decl_19806, type, differentiated_embryonic_cell_1: $i > $o).
% 28.89/28.97  tff(decl_19807, type, fn_cell_determination_5: $i > $i).
% 28.89/28.97  tff(decl_19808, type, fn_cell_determination_6: $i > $i).
% 28.89/28.97  tff(decl_19809, type, fn_cell_determination_7: $i > $i).
% 28.89/28.97  tff(decl_19810, type, undifferentiated_cell_1: $i > $o).
% 28.89/28.97  tff(decl_19811, type, fn_cell_determination_8: $i > $i).
% 28.89/28.97  tff(decl_19812, type, fn_cell_determination_9: $i > $i).
% 28.89/28.97  tff(decl_19813, type, fn_cell_determination_10: $i > $i).
% 28.89/28.97  tff(decl_19814, type, master_control_gene_1: $i > $o).
% 28.89/28.97  tff(decl_19815, type, fn_cell_determination_11: $i > $i).
% 28.89/28.97  tff(decl_19816, type, fn_cell_determination_12: $i > $i).
% 28.89/28.97  tff(decl_19817, type, undifferentiated_embryonic_cell_1: $i > $o).
% 28.89/28.97  tff(decl_19818, type, fn_cell_determination_13: $i > $i).
% 28.89/28.97  tff(decl_19819, type, tissue_specific_protein_1: $i > $o).
% 28.89/28.97  tff(decl_19820, type, fn_cell_determination_14: $i > $i).
% 28.89/28.97  tff(decl_19821, type, fn_cell_determination_15: $i > $i).
% 28.89/28.97  tff(decl_19822, type, fn_gene_expression_6: $i > $i).
% 28.89/28.97  tff(decl_19823, type, fn_gene_expression_4: $i > $i).
% 28.89/28.97  tff(decl_19824, type, fn_gene_expression_2: $i > $i).
% 28.89/28.97  tff(decl_19825, type, 'Transcription Factor I': $i).
% 28.89/28.97  tff(decl_19826, type, 'Gene Expression 2': $i).
% 28.89/28.97  tff(decl_19827, type, 'Gene Expression 1': $i).
% 28.89/28.97  tff(decl_19828, type, 'Cell-Differentiation': $i).
% 28.89/28.97  tff(decl_19829, type, 'The sum of processes by which cells become structurally and functionally diverse during the development of a multicellular organism.': $i).
% 28.89/28.97  tff(decl_19830, type, 'cellular differentiation': $i).
% 28.89/28.97  tff(decl_19831, type, differentiation: $i).
% 28.89/28.97  tff(decl_19832, type, differentiate: $i).
% 28.89/28.97  tff(decl_19833, type, 'differentiation of cell': $i).
% 28.89/28.97  tff(decl_19834, type, 'cell differentiation': $i).
% 28.89/28.97  tff(decl_19835, type, 'cell-differentiation': $i).
% 28.89/28.97  tff(decl_19836, type, neural_signaling_1: $i > $o).
% 28.89/28.97  tff(decl_19837, type, fn_cell_differentiation_1: $i > $i).
% 28.89/28.97  tff(decl_19838, type, transcriptional_regulation_1: $i > $o).
% 28.89/28.97  tff(decl_19839, type, fn_cell_differentiation_2: $i > $i).
% 28.89/28.97  tff(decl_19840, type, fn_cell_differentiation_3: $i > $i).
% 28.89/28.97  tff(decl_19841, type, fn_cell_differentiation_4: $i > $i).
% 28.89/28.97  tff(decl_19842, type, fn_cell_differentiation_5: $i > $i).
% 28.89/28.97  tff(decl_19843, type, fn_cell_differentiation_6: $i > $i).
% 28.89/28.97  tff(decl_19844, type, fn_cell_differentiation_7: $i > $i).
% 28.89/28.97  tff(decl_19845, type, differentiated_cell_1: $i > $o).
% 28.89/28.97  tff(decl_19846, type, fn_cell_differentiation_8: $i > $i).
% 28.89/28.97  tff(decl_19847, type, structural_role_1: $i > $o).
% 28.89/28.97  tff(decl_19848, type, fn_cell_differentiation_9: $i > $i).
% 28.89/28.97  tff(decl_19849, type, fn_cell_differentiation_10: $i > $i).
% 28.89/28.97  tff(decl_19850, type, fn_cell_differentiation_11: $i > $i).
% 28.89/28.97  tff(decl_19851, type, fn_cell_differentiation_12: $i > $i).
% 28.89/28.97  tff(decl_19852, type, fn_cell_differentiation_13: $i > $i).
% 28.89/28.97  tff(decl_19853, type, fn_cell_differentiation_14: $i > $i).
% 28.89/28.97  tff(decl_19854, type, fn_cell_differentiation_15: $i > $i).
% 28.89/28.97  tff(decl_19855, type, fn_cell_differentiation_16: $i > $i).
% 28.89/28.97  tff(decl_19856, type, fn_cell_differentiation_17: $i > $i).
% 28.89/28.97  tff(decl_19857, type, fn_cell_differentiation_18: $i > $i).
% 28.89/28.97  tff(decl_19858, type, fn_cell_differentiation_20: $i > $i).
% 28.89/28.97  tff(decl_19859, type, fn_cell_differentiation_21: $i > $i).
% 28.89/28.97  tff(decl_19860, type, fn_cell_differentiation_22: $i > $i).
% 28.89/28.97  tff(decl_19861, type, fn_cell_differentiation_23: $i > $i).
% 28.89/28.97  tff(decl_19862, type, fn_cell_differentiation_24: $i > $i).
% 28.89/28.97  tff(decl_19863, type, fn_cell_differentiation_25: $i > $i).
% 28.89/28.97  tff(decl_19864, type, fn_cell_differentiation_26: $i > $i).
% 28.89/28.97  tff(decl_19865, type, fn_cell_differentiation_27: $i > $i).
% 28.89/28.97  tff(decl_19866, type, fn_cell_differentiation_28: $i > $i).
% 28.89/28.97  tff(decl_19867, type, cell_differentiation_for_tissue_formation_1: $i > $o).
% 28.89/28.97  tff(decl_19868, type, 'Cell-Differentiation-For-Tissue-Formation': $i).
% 28.89/28.97  tff(decl_19869, type, 'The process of differentiation in cells which occurs resulting in tissue formation is called cell differentiation for tissue formation.': $i).
% 28.89/28.97  tff(decl_19870, type, 'cell differentiation for tissue formation': $i).
% 28.89/28.97  tff(decl_19871, type, 'cell-differentiation-for-tissue-formation': $i).
% 28.89/28.97  tff(decl_19872, type, muscle_cell_differentiation_1: $i > $o).
% 28.89/28.97  tff(decl_19873, type, stem_cell_differentiation_1: $i > $o).
% 28.89/28.97  tff(decl_19874, type, fn_cell_differentiation_for_tissue_formation_1: $i > $i).
% 28.89/28.97  tff(decl_19875, type, fn_cell_differentiation_for_tissue_formation_2: $i > $i).
% 28.89/28.97  tff(decl_19876, type, fn_cell_differentiation_for_tissue_formation_3: $i > $i).
% 28.89/28.97  tff(decl_19877, type, 'Cell-Differentiation-Induction': $i).
% 28.89/28.97  tff(decl_19878, type, 'Induction, signaling from one group of cells to an adjacent group, that brings about differentiation.': $i).
% 28.89/28.97  tff(decl_19879, type, 'induce cell differentiation': $i).
% 28.89/28.97  tff(decl_19880, type, 'cell differentiation induction': $i).
% 28.89/28.97  tff(decl_19881, type, 'cell-differentiation-induction': $i).
% 28.89/28.97  tff(decl_19882, type, fn_cell_differentiation_induction_1: $i > $i).
% 28.89/28.97  tff(decl_19883, type, fn_cell_differentiation_induction_2: $i > $i).
% 28.89/28.97  tff(decl_19884, type, fn_cell_differentiation_induction_3: $i > $i).
% 28.89/28.97  tff(decl_19885, type, fn_cell_differentiation_induction_4: $i > $i).
% 28.89/28.97  tff(decl_19886, type, 'Cell-Division': $i).
% 28.89/28.97  tff(decl_19887, type, 'A process by which the parent cell divides into two or more daughter cells.': $i).
% 28.89/28.97  tff(decl_19888, type, 'cell reproduction': $i).
% 28.89/28.97  tff(decl_19889, type, 'division of cell': $i).
% 28.89/28.97  tff(decl_19890, type, 'cell division': $i).
% 28.89/28.97  tff(decl_19891, type, 'cell-division': $i).
% 28.89/28.97  tff(decl_19892, type, fn_cell_division_1: $i > $i).
% 28.89/28.97  tff(decl_19893, type, fn_cell_division_4: $i > $i).
% 28.89/28.97  tff(decl_19894, type, cell_division_in_diatom_1: $i > $o).
% 28.89/28.97  tff(decl_19895, type, 'Cell-Division-In-Diatom': $i).
% 28.89/28.97  tff(decl_19896, type, 'The process in diatoms by which the parent cell divides into two daughter cells.': $i).
% 28.89/28.97  tff(decl_19897, type, 'cell division in diatom': $i).
% 28.89/28.97  tff(decl_19898, type, 'cell-division-in-diatom': $i).
% 28.89/28.97  tff(decl_19899, type, fn_cell_division_in_diatom_1: $i > $i).
% 28.89/28.97  tff(decl_19900, type, fn_cell_division_in_diatom_2: $i > $i).
% 28.89/28.97  tff(decl_19901, type, diatom_1: $i > $o).
% 28.89/28.97  tff(decl_19902, type, fn_cell_division_in_diatom_3: $i > $i).
% 28.89/28.97  tff(decl_19903, type, fn_cell_division_in_diatom_4: $i > $i).
% 28.89/28.97  tff(decl_19904, type, fn_cell_division_in_diatom_5: $i > $i).
% 28.89/28.97  tff(decl_19905, type, nuclear_division_1: $i > $o).
% 28.89/28.97  tff(decl_19906, type, fn_cell_division_in_diatom_6: $i > $i).
% 28.89/28.97  tff(decl_19907, type, fn_cell_division_in_diatom_7: $i > $i).
% 28.89/28.97  tff(decl_19908, type, fn_cell_division_in_diatom_8: $i > $i).
% 28.89/28.97  tff(decl_19909, type, fn_cell_division_in_diatom_9: $i > $i).
% 28.89/28.97  tff(decl_19910, type, fn_cell_division_in_diatom_10: $i > $i).
% 28.89/28.97  tff(decl_19911, type, fn_cell_division_in_diatom_11: $i > $i).
% 28.89/28.97  tff(decl_19912, type, fn_cell_division_in_diatom_12: $i > $i).
% 28.89/28.97  tff(decl_19913, type, fn_cell_division_in_diatom_13: $i > $i).
% 28.89/28.97  tff(decl_19914, type, spindle_1: $i > $o).
% 28.89/28.97  tff(decl_19915, type, fn_cell_division_in_diatom_14: $i > $i).
% 28.89/28.97  tff(decl_19916, type, fn_cell_division_in_diatom_15: $i > $i).
% 28.89/28.97  tff(decl_19917, type, fn_cell_division_in_diatom_16: $i > $i).
% 28.89/28.97  tff(decl_19918, type, fn_diatom_44: $i > $i).
% 28.89/28.97  tff(decl_19919, type, fn_diatom_41: $i > $i).
% 28.89/28.97  tff(decl_19920, type, fn_nuclear_division_2: $i > $i).
% 28.89/28.97  tff(decl_19921, type, cell_division_in_dinoflagellate_1: $i > $o).
% 28.89/28.97  tff(decl_19922, type, 'Cell-Division-In-Dinoflagellate': $i).
% 28.89/28.97  tff(decl_19923, type, 'A process by which the parent dinoflagellate cell divides into two dinoflagellate daughter cells.': $i).
% 28.89/28.97  tff(decl_19924, type, 'cell division in dinoflagellate': $i).
% 28.89/28.97  tff(decl_19925, type, 'cell-division-in-dinoflagellate': $i).
% 28.89/28.97  tff(decl_19926, type, fn_cell_division_in_dinoflagellate_1: $i > $i).
% 28.89/28.97  tff(decl_19927, type, fn_cell_division_in_dinoflagellate_2: $i > $i).
% 28.89/28.97  tff(decl_19928, type, fn_cell_division_in_dinoflagellate_3: $i > $i).
% 28.89/28.97  tff(decl_19929, type, fn_cell_division_in_dinoflagellate_4: $i > $i).
% 28.89/28.97  tff(decl_19930, type, fn_cell_division_in_dinoflagellate_5: $i > $i).
% 28.89/28.97  tff(decl_19931, type, fn_cell_division_in_dinoflagellate_6: $i > $i).
% 28.89/28.97  tff(decl_19932, type, fn_cell_division_in_dinoflagellate_7: $i > $i).
% 28.89/28.97  tff(decl_19933, type, fn_cell_division_in_dinoflagellate_8: $i > $i).
% 28.89/28.97  tff(decl_19934, type, fn_cell_division_in_dinoflagellate_9: $i > $i).
% 28.89/28.97  tff(decl_19935, type, fn_cell_division_in_dinoflagellate_10: $i > $i).
% 28.89/28.97  tff(decl_19936, type, fn_cell_division_in_dinoflagellate_11: $i > $i).
% 28.89/28.97  tff(decl_19937, type, fn_cell_division_in_dinoflagellate_12: $i > $i).
% 28.89/28.97  tff(decl_19938, type, fn_cell_division_in_dinoflagellate_13: $i > $i).
% 28.89/28.97  tff(decl_19939, type, fn_cell_division_in_dinoflagellate_14: $i > $i).
% 28.89/28.97  tff(decl_19940, type, fn_cell_division_in_dinoflagellate_15: $i > $i).
% 28.89/28.97  tff(decl_19941, type, fn_cell_division_in_dinoflagellate_16: $i > $i).
% 28.89/28.97  tff(decl_19942, type, intermediate_filament_1: $i > $o).
% 28.89/28.97  tff(decl_19943, type, fn_cell_division_in_dinoflagellate_17: $i > $i).
% 28.89/28.97  tff(decl_19944, type, fn_cell_division_in_dinoflagellate_18: $i > $i).
% 28.89/28.97  tff(decl_19945, type, fn_cell_division_in_dinoflagellate_19: $i > $i).
% 28.89/28.97  tff(decl_19946, type, fn_cell_division_in_dinoflagellate_20: $i > $i).
% 28.89/28.97  tff(decl_19947, type, fn_cell_division_in_dinoflagellate_21: $i > $i).
% 28.89/28.97  tff(decl_19948, type, fn_cell_division_in_dinoflagellate_22: $i > $i).
% 28.89/28.97  tff(decl_19949, type, fn_cell_division_in_dinoflagellate_23: $i > $i).
% 28.89/28.97  tff(decl_19950, type, fn_cell_division_in_dinoflagellate_24: $i > $i).
% 28.89/28.97  tff(decl_19951, type, fn_cell_division_in_dinoflagellate_25: $i > $i).
% 28.89/28.97  tff(decl_19952, type, fn_cell_division_in_dinoflagellate_26: $i > $i).
% 28.89/28.97  tff(decl_19953, type, fn_cell_division_in_dinoflagellate_27: $i > $i).
% 28.89/28.97  tff(decl_19954, type, fn_cell_division_in_dinoflagellate_28: $i > $i).
% 28.89/28.97  tff(decl_19955, type, fn_cell_division_in_dinoflagellate_29: $i > $i).
% 28.89/28.97  tff(decl_19956, type, fn_cell_division_in_dinoflagellate_30: $i > $i).
% 28.89/28.97  tff(decl_19957, type, fn_cell_division_in_dinoflagellate_31: $i > $i).
% 28.89/28.97  tff(decl_19958, type, fn_cell_division_in_dinoflagellate_32: $i > $i).
% 28.89/28.97  tff(decl_19959, type, synthesis_of_rna_1: $i > $o).
% 28.89/28.97  tff(decl_19960, type, fn_cell_division_in_dinoflagellate_33: $i > $i).
% 28.89/28.97  tff(decl_19961, type, dna_replication_in_eukaryotes_1: $i > $o).
% 28.89/28.97  tff(decl_19962, type, fn_cell_division_in_dinoflagellate_34: $i > $i).
% 28.89/28.97  tff(decl_19963, type, fn_cell_division_in_dinoflagellate_35: $i > $i).
% 28.89/28.97  tff(decl_19964, type, nucleolus_1: $i > $o).
% 28.89/28.97  tff(decl_19965, type, fn_cell_division_in_dinoflagellate_36: $i > $i).
% 28.89/28.97  tff(decl_19966, type, fn_cell_division_in_dinoflagellate_37: $i > $i).
% 28.89/28.97  tff(decl_19967, type, fn_cell_division_in_dinoflagellate_38: $i > $i).
% 28.89/28.97  tff(decl_19968, type, fn_cell_division_in_dinoflagellate_39: $i > $i).
% 28.89/28.97  tff(decl_19969, type, fn_cell_division_in_dinoflagellate_40: $i > $i).
% 28.89/28.97  tff(decl_19970, type, fn_cell_division_in_dinoflagellate_41: $i > $i).
% 28.89/28.97  tff(decl_19971, type, fn_cell_division_in_dinoflagellate_42: $i > $i).
% 28.89/28.97  tff(decl_19972, type, fn_cell_division_in_dinoflagellate_43: $i > $i).
% 28.89/28.97  tff(decl_19973, type, fn_cell_division_in_dinoflagellate_44: $i > $i).
% 28.89/28.97  tff(decl_19974, type, fn_cell_division_in_dinoflagellate_45: $i > $i).
% 28.89/28.97  tff(decl_19975, type, fn_cell_division_in_dinoflagellate_46: $i > $i).
% 28.89/28.97  tff(decl_19976, type, fn_cell_division_in_dinoflagellate_47: $i > $i).
% 28.89/28.97  tff(decl_19977, type, fn_cell_division_in_dinoflagellate_48: $i > $i).
% 28.89/28.97  tff(decl_19978, type, fn_cell_division_in_dinoflagellate_49: $i > $i).
% 28.89/28.97  tff(decl_19979, type, fn_cell_division_in_dinoflagellate_50: $i > $i).
% 28.89/28.97  tff(decl_19980, type, fn_cell_division_in_dinoflagellate_51: $i > $i).
% 28.89/28.97  tff(decl_19981, type, fn_cell_division_in_dinoflagellate_52: $i > $i).
% 28.89/28.97  tff(decl_19982, type, fn_cell_division_in_dinoflagellate_53: $i > $i).
% 28.89/28.97  tff(decl_19983, type, fn_cell_division_in_dinoflagellate_54: $i > $i).
% 28.89/28.97  tff(decl_19984, type, fn_cell_division_in_dinoflagellate_55: $i > $i).
% 28.89/28.97  tff(decl_19985, type, fn_eukaryotic_chromosome_4: $i > $i).
% 28.89/28.97  tff(decl_19986, type, fn_eukaryotic_chromosome_5: $i > $i).
% 28.89/28.97  tff(decl_19987, type, fn_dinoflagellate_7: $i > $i).
% 28.89/28.97  tff(decl_19988, type, fn_dinoflagellate_35: $i > $i).
% 28.89/28.97  tff(decl_19989, type, fn_dinoflagellate_23: $i > $i).
% 28.89/28.97  tff(decl_19990, type, fn_dinoflagellate_36: $i > $i).
% 28.89/28.97  tff(decl_19991, type, fn_dinoflagellate_37: $i > $i).
% 28.89/28.97  tff(decl_19992, type, fn_dinoflagellate_20: $i > $i).
% 28.89/28.97  tff(decl_19993, type, fn_dinoflagellate_6: $i > $i).
% 28.89/28.97  tff(decl_19994, type, fn_dinoflagellate_30: $i > $i).
% 28.89/28.97  tff(decl_19995, type, fn_dinoflagellate_21: $i > $i).
% 28.89/28.97  tff(decl_19996, type, fn_dinoflagellate_19: $i > $i).
% 28.89/28.97  tff(decl_19997, type, fn_dinoflagellate_29: $i > $i).
% 28.89/28.97  tff(decl_19998, type, fn_dinoflagellate_27: $i > $i).
% 28.89/28.97  tff(decl_19999, type, fn_dinoflagellate_34: $i > $i).
% 28.89/28.97  tff(decl_20000, type, fn_dinoflagellate_33: $i > $i).
% 28.89/28.97  tff(decl_20001, type, fn_dinoflagellate_32: $i > $i).
% 28.89/28.97  tff(decl_20002, type, fn_dinoflagellate_28: $i > $i).
% 28.89/28.97  tff(decl_20003, type, fn_dinoflagellate_31: $i > $i).
% 28.89/28.97  tff(decl_20004, type, fn_dinoflagellate_18: $i > $i).
% 28.89/28.97  tff(decl_20005, type, fn_dinoflagellate_25: $i > $i).
% 28.89/28.97  tff(decl_20006, type, fn_dinoflagellate_26: $i > $i).
% 28.89/28.97  tff(decl_20007, type, fn_nucleus_3: $i > $i).
% 28.89/28.97  tff(decl_20008, type, fn_nucleus_9: $i > $i).
% 28.89/28.97  tff(decl_20009, type, fn_nucleus_15: $i > $i).
% 28.89/28.97  tff(decl_20010, type, fn_nucleus_11: $i > $i).
% 28.89/28.97  tff(decl_20011, type, fn_nucleus_18: $i > $i).
% 28.89/28.97  tff(decl_20012, type, fn_nucleus_5: $i > $i).
% 28.89/28.97  tff(decl_20013, type, fn_nucleus_16: $i > $i).
% 28.89/28.97  tff(decl_20014, type, fn_nucleus_14: $i > $i).
% 28.89/28.97  tff(decl_20015, type, fn_cytoskeleton_3: $i > $i).
% 28.89/28.97  tff(decl_20016, type, fn_cytoskeleton_8: $i > $i).
% 28.89/28.97  tff(decl_20017, type, fn_dinoflagellate_8: $i > $i).
% 28.89/28.97  tff(decl_20018, type, fn_cytoskeleton_9: $i > $i).
% 28.89/28.97  tff(decl_20019, type, fn_dinoflagellate_11: $i > $i).
% 28.89/28.97  tff(decl_20020, type, fn_cytoskeleton_7: $i > $i).
% 28.89/28.97  tff(decl_20021, type, fn_dinoflagellate_17: $i > $i).
% 28.89/28.97  tff(decl_20022, type, fn_cytoskeleton_6: $i > $i).
% 28.89/28.97  tff(decl_20023, type, fn_dinoflagellate_9: $i > $i).
% 28.89/28.97  tff(decl_20024, type, fn_nuclear_division_3: $i > $i).
% 28.89/28.97  tff(decl_20025, type, fn_dinoflagellate_10: $i > $i).
% 28.89/28.97  tff(decl_20026, type, fn_cell_division_in_dinoflagellate_56: $i > $i).
% 28.89/28.97  tff(decl_20027, type, fn_cell_division_in_dinoflagellate_57: $i > $i).
% 28.89/28.97  tff(decl_20028, type, fn_cell_division_in_dinoflagellate_58: $i > $i).
% 28.89/28.97  tff(decl_20029, type, fn_cell_division_in_dinoflagellate_59: $i > $i).
% 28.89/28.97  tff(decl_20030, type, cell_division_in_unicellular_organism_1: $i > $o).
% 28.89/28.97  tff(decl_20031, type, 'Cell-Division-In-Unicellular-Organism': $i).
% 28.89/28.97  tff(decl_20032, type, 'The process in unicellular organisms by which the parent cell divides into two daughter cells.': $i).
% 28.89/28.97  tff(decl_20033, type, 'cell division in unicellular organism': $i).
% 28.89/28.97  tff(decl_20034, type, 'cell-division-in-unicellular-organism': $i).
% 28.89/28.97  tff(decl_20035, type, fn_cell_division_in_unicellular_organism_1: $i > $i).
% 28.89/28.97  tff(decl_20036, type, fn_cell_division_in_unicellular_organism_2: $i > $i).
% 28.89/28.97  tff(decl_20037, type, cell_division_in_yeast_1: $i > $o).
% 28.89/28.97  tff(decl_20038, type, 'Cell-Division-In-Yeast': $i).
% 28.89/28.97  tff(decl_20039, type, 'The process in yeast by which the parent cell divides into two daughter cells.': $i).
% 28.89/28.97  tff(decl_20040, type, 'cell division in yeast': $i).
% 28.89/28.98  tff(decl_20041, type, 'cell-division-in-yeast': $i).
% 28.89/28.98  tff(decl_20042, type, fn_cell_division_in_yeast_1: $i > $i).
% 28.89/28.98  tff(decl_20043, type, fn_cell_division_in_yeast_2: $i > $i).
% 28.89/28.98  tff(decl_20044, type, fn_cell_division_in_yeast_3: $i > $i).
% 28.89/28.98  tff(decl_20045, type, kinetochore_1: $i > $o).
% 28.89/28.98  tff(decl_20046, type, fn_cell_division_in_yeast_4: $i > $i).
% 28.89/28.98  tff(decl_20047, type, fn_cell_division_in_yeast_5: $i > $i).
% 28.89/28.98  tff(decl_20048, type, yeast_0: $i).
% 28.89/28.98  tff(decl_20049, type, elongation_1: $i > $o).
% 28.89/28.98  tff(decl_20050, type, fn_cell_elongation_3: $i > $i).
% 28.89/28.98  tff(decl_20051, type, 'Cell-Elongation': $i).
% 28.89/28.98  tff(decl_20052, type, 'During cell division, the process in which the cytoskeletal elements of the cell cause the cell to elongate in preparation for division of the cytoplasm.': $i).
% 28.89/28.98  tff(decl_20053, type, 'cell expansion': $i).
% 28.89/28.98  tff(decl_20054, type, 'elongation of cell': $i).
% 28.89/28.98  tff(decl_20055, type, 'cell elongation': $i).
% 28.89/28.98  tff(decl_20056, type, 'cell-elongation': $i).
% 28.89/28.98  tff(decl_20057, type, fn_cell_elongation_1: $i > $i).
% 28.89/28.98  tff(decl_20058, type, nonkinetochore_microtubule_1: $i > $o).
% 28.89/28.98  tff(decl_20059, type, fn_cell_elongation_2: $i > $i).
% 28.89/28.98  tff(decl_20060, type, fn_cell_elongation_4: $i > $i).
% 28.89/28.98  tff(decl_20061, type, microtubule_elongation_1: $i > $o).
% 28.89/28.98  tff(decl_20062, type, 'Cell-Elongation-During-Anaphase': $i).
% 28.89/28.98  tff(decl_20063, type, 'During anaphase, the process in which a cell grows in length as preparation to dividing the cytoplasm, resulting in daughter cells.': $i).
% 28.89/28.98  tff(decl_20064, type, elongate: $i).
% 28.89/28.98  tff(decl_20065, type, 'cell elongation during anaphase': $i).
% 28.89/28.98  tff(decl_20066, type, 'cell-elongation-during-anaphase': $i).
% 28.89/28.98  tff(decl_20067, type, mitotic_event_1: $i > $o).
% 28.89/28.98  tff(decl_20068, type, fn_cell_elongation_during_anaphase_2: $i > $i).
% 28.89/28.98  tff(decl_20069, type, fn_cell_elongation_during_anaphase_3: $i > $i).
% 28.89/28.98  tff(decl_20070, type, fn_cell_elongation_during_anaphase_4: $i > $i).
% 28.89/28.98  tff(decl_20071, type, fn_cell_elongation_during_anaphase_5: $i > $i).
% 28.89/28.98  tff(decl_20072, type, fn_cell_elongation_during_anaphase_9: $i > $i).
% 28.89/28.98  tff(decl_20073, type, fn_cell_elongation_during_anaphase_10: $i > $i).
% 28.89/28.98  tff(decl_20074, type, fn_cell_elongation_during_anaphase_14: $i > $i).
% 28.89/28.98  tff(decl_20075, type, fn_cell_elongation_during_anaphase_15: $i > $i).
% 28.89/28.98  tff(decl_20076, type, fn_cell_elongation_during_anaphase_16: $i > $i).
% 28.89/28.98  tff(decl_20077, type, fn_cell_elongation_during_anaphase_17: $i > $i).
% 28.89/28.98  tff(decl_20078, type, fn_cell_elongation_during_anaphase_19: $i > $i).
% 28.89/28.98  tff(decl_20079, type, fn_cell_elongation_during_anaphase_20: $i > $i).
% 28.89/28.98  tff(decl_20080, type, fn_cell_elongation_during_anaphase_22: $i > $i).
% 28.89/28.98  tff(decl_20081, type, fn_cell_elongation_during_anaphase_23: $i > $i).
% 28.89/28.98  tff(decl_20082, type, fn_cell_elongation_during_anaphase_24: $i > $i).
% 28.89/28.98  tff(decl_20083, type, fn_cell_elongation_during_anaphase_25: $i > $i).
% 28.89/28.98  tff(decl_20084, type, fn_cell_elongation_during_anaphase_26: $i > $i).
% 28.89/28.98  tff(decl_20085, type, fn_cell_elongation_during_anaphase_27: $i > $i).
% 28.89/28.98  tff(decl_20086, type, fn_cell_elongation_during_anaphase_28: $i > $i).
% 28.89/28.98  tff(decl_20087, type, fn_cell_elongation_during_anaphase_29: $i > $i).
% 28.89/28.98  tff(decl_20088, type, fn_cell_elongation_during_anaphase_30: $i > $i).
% 28.89/28.98  tff(decl_20089, type, fn_cell_elongation_during_anaphase_33: $i > $i).
% 28.89/28.98  tff(decl_20090, type, fn_cell_elongation_during_anaphase_34: $i > $i).
% 28.89/28.98  tff(decl_20091, type, fn_microtubule_elongation_2: $i > $i).
% 28.89/28.98  tff(decl_20092, type, fn_motor_protein_14: $i > $i).
% 28.89/28.98  tff(decl_20093, type, fn_microtubule_elongation_1: $i > $i).
% 28.89/28.98  tff(decl_20094, type, fn_microtubule_10: $i > $i).
% 28.89/28.98  tff(decl_20095, type, fn_microtubule_4: $i > $i).
% 28.89/28.98  tff(decl_20096, type, fn_microtubule_7: $i > $i).
% 28.89/28.98  tff(decl_20097, type, fn_nonkinetochore_microtubule_2: $i > $i).
% 28.89/28.98  tff(decl_20098, type, fn_nonkinetochore_microtubule_1: $i > $i).
% 28.89/28.98  tff(decl_20099, type, fn_cytoskeleton_1: $i > $i).
% 28.89/28.98  tff(decl_20100, type, fn_cell_elongation_during_anaphase_45: $i > $i).
% 28.89/28.98  tff(decl_20101, type, fn_cell_elongation_during_anaphase_46: $i > $i).
% 28.89/28.98  tff(decl_20102, type, fn_cell_elongation_during_anaphase_32: $i > $i).
% 28.89/28.98  tff(decl_20103, type, 'Cell-Equator': $i).
% 28.89/28.98  tff(decl_20104, type, 'Cell-Equator is the middle region of a cell. Here the chromosomes come together at the metaphase': $i).
% 28.89/28.98  tff(decl_20105, type, 'cell equator': $i).
% 28.89/28.98  tff(decl_20106, type, 'cell\\s equator': $i).
% 28.89/28.98  tff(decl_20107, type, 'cell\\s-equator': $i).
% 28.89/28.98  tff(decl_20108, type, 'cell-equator': $i).
% 28.89/28.98  tff(decl_20109, type, 'equator of cell': $i).
% 28.89/28.98  tff(decl_20110, type, 'middle region of cell': $i).
% 28.89/28.98  tff(decl_20111, type, 'mid region of cell': $i).
% 28.89/28.98  tff(decl_20112, type, 'middle of cell': $i).
% 28.89/28.98  tff(decl_20113, type, cellular_region_1: $i > $o).
% 28.89/28.98  tff(decl_20114, type, fn_cell_equator_1: $i > $i).
% 28.89/28.98  tff(decl_20115, type, cell_fate_1: $i > $o).
% 28.89/28.98  tff(decl_20116, type, 'Cell-Fate': $i).
% 28.89/28.98  tff(decl_20117, type, 'The resulting form and function of a cell depending on its cytoplasmic contents, genotype, or position in the embryo.': $i).
% 28.89/28.98  tff(decl_20118, type, 'fate of cell': $i).
% 28.89/28.98  tff(decl_20119, type, 'cell fate': $i).
% 28.89/28.98  tff(decl_20120, type, 'cell-fate': $i).
% 28.89/28.98  tff(decl_20121, type, cell_fractionation_1: $i > $o).
% 28.89/28.98  tff(decl_20122, type, 'Cell-Fractionation': $i).
% 28.89/28.98  tff(decl_20123, type, 'A process by which a collection of cells is homogenized and then centrifuged to separate the different components by density.': $i).
% 28.89/28.98  tff(decl_20124, type, fractionate: $i).
% 28.89/28.98  tff(decl_20125, type, 'fractionation of cell': $i).
% 28.89/28.98  tff(decl_20126, type, 'cell fractionation': $i).
% 28.89/28.98  tff(decl_20127, type, 'cell-fractionation': $i).
% 28.89/28.98  tff(decl_20128, type, segregate_1: $i > $o).
% 28.89/28.98  tff(decl_20129, type, fn_cell_fractionation_1: $i > $i).
% 28.89/28.98  tff(decl_20130, type, fn_cell_fractionation_2: $i > $i).
% 28.89/28.98  tff(decl_20131, type, fn_cell_fractionation_3: $i > $i).
% 28.89/28.98  tff(decl_20132, type, pellet_1: $i > $o).
% 28.89/28.98  tff(decl_20133, type, fn_cell_fractionation_4: $i > $i).
% 28.89/28.98  tff(decl_20134, type, fn_cell_fractionation_5: $i > $i).
% 28.89/28.98  tff(decl_20135, type, homogenization_1: $i > $o).
% 28.89/28.98  tff(decl_20136, type, fn_cell_fractionation_6: $i > $i).
% 28.89/28.98  tff(decl_20137, type, fn_cell_fractionation_7: $i > $i).
% 28.89/28.98  tff(decl_20138, type, fn_cell_fractionation_8: $i > $i).
% 28.89/28.98  tff(decl_20139, type, fn_cell_fractionation_9: $i > $i).
% 28.89/28.98  tff(decl_20140, type, fn_cell_fractionation_10: $i > $i).
% 28.89/28.98  tff(decl_20141, type, supernatant_1: $i > $o).
% 28.89/28.98  tff(decl_20142, type, fn_cell_fractionation_11: $i > $i).
% 28.89/28.98  tff(decl_20143, type, fn_cell_fractionation_12: $i > $i).
% 28.89/28.98  tff(decl_20144, type, fn_cell_fractionation_13: $i > $i).
% 28.89/28.98  tff(decl_20145, type, fn_cell_fractionation_14: $i > $i).
% 28.89/28.98  tff(decl_20146, type, rotate_1: $i > $o).
% 28.89/28.98  tff(decl_20147, type, fn_cell_fractionation_15: $i > $i).
% 28.89/28.98  tff(decl_20148, type, centrifugation_1: $i > $o).
% 28.89/28.98  tff(decl_20149, type, fn_cell_fractionation_16: $i > $i).
% 28.89/28.98  tff(decl_20150, type, fn_cell_fractionation_17: $i > $i).
% 28.89/28.98  tff(decl_20151, type, fn_centrifugation_1: $i > $i).
% 28.89/28.98  tff(decl_20152, type, rotate_0: $i).
% 28.89/28.98  tff(decl_20153, type, remove_0: $i).
% 28.89/28.98  tff(decl_20154, type, fn_segregate_1: $i > $i).
% 28.89/28.98  tff(decl_20155, type, 'Cell-Growth': $i).
% 28.89/28.98  tff(decl_20156, type, 'The enlarging of the cell during interphase of the cell cycle in preparation for cell division where the cell produces proteins and cytoplasmic organelles and copies its chromosomes.': $i).
% 28.89/28.98  tff(decl_20157, type, 'growth of cell': $i).
% 28.89/28.98  tff(decl_20158, type, 'cell growth': $i).
% 28.89/28.98  tff(decl_20159, type, 'cell-growth': $i).
% 28.89/28.98  tff(decl_20160, type, 'Cell-Lineage': $i).
% 28.89/28.98  tff(decl_20161, type, 'The developmental history of blastomeres formed during cleavage.': $i).
% 28.89/28.98  tff(decl_20162, type, 'lineage of cell': $i).
% 28.89/28.98  tff(decl_20163, type, 'cell lineage': $i).
% 28.89/28.98  tff(decl_20164, type, 'cell-lineage': $i).
% 28.89/28.98  tff(decl_20165, type, representation_of_data_1: $i > $o).
% 28.89/28.98  tff(decl_20166, type, fn_cell_lineage_1: $i > $i).
% 28.89/28.98  tff(decl_20167, type, microscope_1: $i > $o).
% 28.89/28.98  tff(decl_20168, type, fn_cell_lineage_2: $i > $i).
% 28.89/28.98  tff(decl_20169, type, fn_cell_lineage_3: $i > $i).
% 28.89/28.98  tff(decl_20170, type, fn_cell_lineage_4: $i > $i).
% 28.89/28.98  tff(decl_20171, type, fn_cell_lineage_5: $i > $i).
% 28.89/28.98  tff(decl_20172, type, fn_cell_lineage_6: $i > $i).
% 28.89/28.98  tff(decl_20173, type, cell_mediated_immune_response_1: $i > $o).
% 28.89/28.98  tff(decl_20174, type, 'Cell-Mediated-Immune-Response': $i).
% 28.89/28.98  tff(decl_20175, type, 'An immune response that does not involve antibodies or complement, but instead responds to an antigen by activating macrophages, natural killer cells, and antigen-specific cytotoxic T-lymphocytes, and by releasing various cytokines.': $i).
% 28.89/28.98  tff(decl_20176, type, respond: $i).
% 28.89/28.98  tff(decl_20177, type, 'cell mediated immune response': $i).
% 28.89/28.98  tff(decl_20178, type, 'cell-mediated-immune-response': $i).
% 28.89/28.98  tff(decl_20179, type, immune_related_intercellular_process_1: $i > $o).
% 28.89/28.98  tff(decl_20180, type, fn_cell_mediated_immune_response_2: $i > $i).
% 28.89/28.98  tff(decl_20181, type, fn_cell_mediated_immune_response_3: $i > $i).
% 28.89/28.98  tff(decl_20182, type, cellular_response_0: $i).
% 28.89/28.98  tff(decl_20183, type, 'Cell-Opposite-Pole': $i).
% 28.89/28.98  tff(decl_20184, type, 'The cell has two poles equidistant from the equator. The poles are opposite to each other.': $i).
% 28.89/28.98  tff(decl_20185, type, 'cell opposite pole': $i).
% 28.89/28.98  tff(decl_20186, type, 'cell-opposite-pole': $i).
% 28.89/28.98  tff(decl_20187, type, cell_plate_1: $i > $o).
% 28.89/28.98  tff(decl_20188, type, 'Cell-Plate': $i).
% 28.89/28.98  tff(decl_20189, type, 'Cell-plate is a structure which forms at equatorial plane of a plant cell during cytokinesis. It helps in the division of the cytoplasm by forming a partition in the center of the dividing plant cell to eventually form two daughter cells': $i).
% 28.89/28.98  tff(decl_20190, type, 'plate of cell': $i).
% 28.89/28.98  tff(decl_20191, type, 'cell plate': $i).
% 28.89/28.98  tff(decl_20192, type, 'cell-plate': $i).
% 28.89/28.98  tff(decl_20193, type, fn_cell_plate_1: $i > $i).
% 28.89/28.98  tff(decl_20194, type, fn_cell_plate_2: $i > $i).
% 28.89/28.98  tff(decl_20195, type, fn_cell_plate_3: $i > $i).
% 28.89/28.98  tff(decl_20196, type, cell_plate_growth_1: $i > $o).
% 28.89/28.98  tff(decl_20197, type, 'Cell-Plate-Growth': $i).
% 28.89/28.98  tff(decl_20198, type, 'During mitosis in plant cells, the process of generating a new cell wall, which results in separation of the two daughter cells.': $i).
% 28.89/28.98  tff(decl_20199, type, 'cell plate growth': $i).
% 28.89/28.98  tff(decl_20200, type, 'cell-plate-growth': $i).
% 28.89/28.98  tff(decl_20201, type, fn_cell_plate_growth_1: $i > $i).
% 28.89/28.98  tff(decl_20202, type, fn_cell_plate_growth_2: $i > $i).
% 28.89/28.98  tff(decl_20203, type, fn_cell_plate_growth_3: $i > $i).
% 28.89/28.98  tff(decl_20204, type, fn_cell_plate_growth_4: $i > $i).
% 28.89/28.98  tff(decl_20205, type, fn_cell_plate_growth_5: $i > $i).
% 28.89/28.98  tff(decl_20206, type, fn_cell_plate_growth_6: $i > $i).
% 28.89/28.98  tff(decl_20207, type, fn_cell_plate_growth_7: $i > $i).
% 28.89/28.98  tff(decl_20208, type, fn_cell_plate_growth_8: $i > $i).
% 28.89/28.98  tff(decl_20209, type, fn_cell_plate_growth_9: $i > $i).
% 28.89/28.98  tff(decl_20210, type, fn_cell_plate_growth_10: $i > $i).
% 28.89/28.98  tff(decl_20211, type, fn_cell_plate_growth_11: $i > $i).
% 28.89/28.98  tff(decl_20212, type, fn_plant_cell_100: $i > $i).
% 28.89/28.98  tff(decl_20213, type, fn_plasma_membrane_69: $i > $i).
% 28.89/28.98  tff(decl_20214, type, 'Cell-Pole': $i).
% 28.89/28.98  tff(decl_20215, type, 'The cell has two poles equidistant from the equator. The poles are opposite to each other': $i).
% 28.89/28.98  tff(decl_20216, type, 'pole of cell': $i).
% 28.89/28.98  tff(decl_20217, type, 'cell pole': $i).
% 28.89/28.98  tff(decl_20218, type, 'cell-pole': $i).
% 28.89/28.98  tff(decl_20219, type, cell_preparation_for_next_signal_reception_1: $i > $o).
% 28.89/28.98  tff(decl_20220, type, 'Cell-Preparation-For-Next-Signal-Reception': $i).
% 28.89/28.98  tff(decl_20221, type, 'The decrease in the number of active receptors as the concentration of the signaling molecules decreases and the unbound receptors return to their inactive state.': $i).
% 28.89/28.98  tff(decl_20222, type, 'termination of cell signal': $i).
% 28.89/28.98  tff(decl_20223, type, 'cell preparation for next signal reception': $i).
% 28.89/28.98  tff(decl_20224, type, 'cell-preparation-for-next-signal-reception': $i).
% 28.89/28.98  tff(decl_20225, type, fn_cell_preparation_for_next_signal_reception_1: $i > $i).
% 28.89/28.98  tff(decl_20226, type, fn_cell_preparation_for_next_signal_reception_2: $i > $i).
% 28.89/28.98  tff(decl_20227, type, fn_cell_preparation_for_next_signal_reception_3: $i > $i).
% 28.89/28.98  tff(decl_20228, type, fn_cell_preparation_for_next_signal_reception_4: $i > $i).
% 28.89/28.98  tff(decl_20229, type, fn_cell_preparation_for_next_signal_reception_5: $i > $i).
% 28.89/28.98  tff(decl_20230, type, cell_sap_1: $i > $o).
% 28.89/28.98  tff(decl_20231, type, 'Cell-Sap': $i).
% 28.89/28.98  tff(decl_20232, type, 'Cell sap is the solution inside the central vacuole and it differs in composition from the cytosol.': $i).
% 28.89/28.98  tff(decl_20233, type, 'sap of cell': $i).
% 28.89/28.98  tff(decl_20234, type, 'cell sap': $i).
% 28.89/28.98  tff(decl_20235, type, 'cell-sap': $i).
% 28.89/28.98  tff(decl_20236, type, sap_1: $i > $o).
% 28.89/28.98  tff(decl_20237, type, fn_cell_sap_1: $i > $i).
% 28.89/28.98  tff(decl_20238, type, inorganic_ion_1: $i > $o).
% 28.89/28.98  tff(decl_20239, type, fn_cell_sap_2: $i > $i).
% 28.89/28.98  tff(decl_20240, type, fn_cell_sap_3: $i > $i).
% 28.89/28.98  tff(decl_20241, type, fn_cell_sap_4: $i > $i).
% 28.89/28.98  tff(decl_20242, type, fn_vesicle_10: $i > $i).
% 28.89/28.98  tff(decl_20243, type, fn_vacuole_2: $i > $i).
% 28.89/28.98  tff(decl_20244, type, cell_shape_change_1: $i > $o).
% 28.89/28.98  tff(decl_20245, type, 'Cell-Shape-Change': $i).
% 28.89/28.98  tff(decl_20246, type, 'Many cells move or change their shapes.': $i).
% 28.89/28.98  tff(decl_20247, type, change: $i).
% 28.89/28.98  tff(decl_20248, type, 'change shape': $i).
% 28.89/28.98  tff(decl_20249, type, 'cell shape change': $i).
% 28.89/28.98  tff(decl_20250, type, 'cell-shape-change': $i).
% 28.89/28.98  tff(decl_20251, type, fn_cell_shape_change_1: $i > $i).
% 28.89/28.98  tff(decl_20252, type, fn_cell_shape_change_2: $i > $i).
% 28.89/28.98  tff(decl_20253, type, fn_cell_shape_change_3: $i > $i).
% 28.89/28.98  tff(decl_20254, type, shape_changing_cell_1: $i > $o).
% 28.89/28.98  tff(decl_20255, type, fn_shape_changing_cell_6: $i > $i).
% 28.89/28.98  tff(decl_20256, type, fn_shape_changing_cell_1: $i > $i).
% 28.89/28.98  tff(decl_20257, type, 'Cell-Signaling': $i).
% 28.89/28.98  tff(decl_20258, type, 'A series of events associated with a cellular signal which includes reception of the signal, transduction (relay) of the signal, and a cellular response to the signal.': $i).
% 28.89/28.98  tff(decl_20259, type, 'cell cell communication': $i).
% 28.89/28.98  tff(decl_20260, type, 'cell signalling': $i).
% 28.89/28.98  tff(decl_20261, type, 'cell to cell communication': $i).
% 28.89/28.98  tff(decl_20262, type, 'signaling of cell': $i).
% 28.89/28.98  tff(decl_20263, type, 'cell signaling': $i).
% 28.89/28.98  tff(decl_20264, type, 'cell-signaling': $i).
% 28.89/28.98  tff(decl_20265, type, speech_1: $i > $o).
% 28.89/28.98  tff(decl_20266, type, 'Cell-Signaling-Event': $i).
% 28.89/28.98  tff(decl_20267, type, 'stage in cell signaling process.': $i).
% 28.89/28.98  tff(decl_20268, type, 'cell signaling event': $i).
% 28.89/28.98  tff(decl_20269, type, 'cell-signaling-event': $i).
% 28.89/28.98  tff(decl_20270, type, cell_signaling_in_plant_cell_1: $i > $o).
% 28.89/28.98  tff(decl_20271, type, 'Cell-Signaling-In-Plant-Cell': $i).
% 28.89/28.98  tff(decl_20272, type, 'The process of signal reception, signal transduction and cellular response to a chemical or electrical signal in plant cells.': $i).
% 28.89/28.98  tff(decl_20273, type, 'cell signaling in plant cell': $i).
% 28.89/28.98  tff(decl_20274, type, 'cell-signaling-in-plant-cell': $i).
% 28.89/28.98  tff(decl_20275, type, fn_cell_signaling_in_plant_cell_1: $i > $i).
% 28.89/28.98  tff(decl_20276, type, fn_cell_signaling_in_plant_cell_2: $i > $i).
% 28.89/28.98  tff(decl_20277, type, cell_signaling_leading_to_arterial_muscle_relaxation_1: $i > $o).
% 28.89/28.98  tff(decl_20278, type, 'Cell-Signaling-Leading-To-Arterial-Muscle-Relaxation': $i).
% 28.89/28.98  tff(decl_20279, type, 'Process of signaling between and within cells which leads to arterial muscle cell relaxation as cellular response.': $i).
% 28.89/28.98  tff(decl_20280, type, 'cell signaling leading to arterial muscle relaxation': $i).
% 28.89/28.98  tff(decl_20281, type, 'cell-signaling-leading-to-arterial-muscle-relaxation': $i).
% 28.89/28.98  tff(decl_20282, type, fn_cell_signaling_leading_to_arterial_muscle_relaxation_1: $i > $i).
% 28.89/28.98  tff(decl_20283, type, muscle_tissue_1: $i > $o).
% 28.89/28.98  tff(decl_20284, type, fn_cell_signaling_leading_to_arterial_muscle_relaxation_2: $i > $i).
% 28.89/28.98  tff(decl_20285, type, fn_cell_signaling_leading_to_arterial_muscle_relaxation_3: $i > $i).
% 28.89/28.98  tff(decl_20286, type, fn_cell_signaling_leading_to_arterial_muscle_relaxation_4: $i > $i).
% 28.89/28.98  tff(decl_20287, type, fn_cell_signaling_leading_to_arterial_muscle_relaxation_5: $i > $i).
% 28.89/28.98  tff(decl_20288, type, fn_cell_signaling_leading_to_arterial_muscle_relaxation_6: $i > $i).
% 28.89/28.98  tff(decl_20289, type, smooth_muscle_1: $i > $o).
% 28.89/28.98  tff(decl_20290, type, fn_cell_signaling_leading_to_arterial_muscle_relaxation_7: $i > $i).
% 28.89/28.98  tff(decl_20291, type, cyclic_gmp_1: $i > $o).
% 28.89/28.98  tff(decl_20292, type, fn_cell_signaling_leading_to_arterial_muscle_relaxation_8: $i > $i).
% 28.89/28.98  tff(decl_20293, type, fn_cell_signaling_leading_to_arterial_muscle_relaxation_9: $i > $i).
% 28.89/28.98  tff(decl_20294, type, muscle_relaxation_1: $i > $o).
% 28.89/28.98  tff(decl_20295, type, cell_signaling_using_testosterone_receptor_1: $i > $o).
% 28.89/28.98  tff(decl_20296, type, 'Cell-Signaling-Using-Testosterone-Receptor': $i).
% 28.89/28.98  tff(decl_20297, type, 'Testosterone receptors are found only in certain cells and is activated when testosterone binds to it.  Once active, the receptor enters the nucleus and turns on specific genes that control male sex characteristics.': $i).
% 28.89/28.98  tff(decl_20298, type, 'testosterone induced cell signaling': $i).
% 28.89/28.98  tff(decl_20299, type, 'testosterone-induced cell signaling': $i).
% 28.89/28.98  tff(decl_20300, type, 'cell signaling using testosterone receptor': $i).
% 28.89/28.98  tff(decl_20301, type, 'cell-signaling-using-testosterone-receptor': $i).
% 28.89/28.98  tff(decl_20302, type, fn_cell_signaling_using_testosterone_receptor_1: $i > $i).
% 28.89/28.98  tff(decl_20303, type, fn_cell_signaling_using_testosterone_receptor_2: $i > $i).
% 28.89/28.98  tff(decl_20304, type, cell_signaling_with_ca2_plus_1: $i > $o).
% 28.89/28.98  tff(decl_20305, type, 'Cell-Signaling-With-Ca2-Plus': $i).
% 28.89/28.98  tff(decl_20306, type, 'Process of signaling between and within cells which uses calcium ions as second messengers during signal transduction.': $i).
% 28.89/28.98  tff(decl_20307, type, 'cell signaling with ca2 plus': $i).
% 28.89/28.98  tff(decl_20308, type, 'cell-signaling-with-ca2-plus': $i).
% 28.89/28.98  tff(decl_20309, type, fn_cell_signaling_with_ca2_plus_1: $i > $i).
% 28.89/28.98  tff(decl_20310, type, signal_transduction_with_ca2_plus_1: $i > $o).
% 28.89/28.98  tff(decl_20311, type, cell_signaling_with_ca2_plus_and_ip3_1: $i > $o).
% 28.89/28.98  tff(decl_20312, type, 'Cell-Signaling-With-Ca2-Plus-And-IP3': $i).
% 28.89/28.98  tff(decl_20313, type, 'The process of signal reception, signal transduction and cellular response which involves calcium and IP3 second messengers.': $i).
% 28.89/28.98  tff(decl_20314, type, 'cell signaling with ca2 plus and ip3': $i).
% 28.89/28.98  tff(decl_20315, type, 'cell-signaling-with-ca2-plus-and-ip3': $i).
% 28.89/28.98  tff(decl_20316, type, fn_cell_signaling_with_ca2_plus_and_ip3_1: $i > $i).
% 28.89/28.98  tff(decl_20317, type, fn_cell_signaling_with_ca2_plus_and_ip3_2: $i > $i).
% 28.89/28.98  tff(decl_20318, type, fn_cell_signaling_with_ca2_plus_and_ip3_3: $i > $i).
% 28.89/28.98  tff(decl_20319, type, diacylglycerol_1: $i > $o).
% 28.89/28.98  tff(decl_20320, type, fn_cell_signaling_with_ca2_plus_and_ip3_4: $i > $i).
% 28.89/28.98  tff(decl_20321, type, fn_cell_signaling_with_ca2_plus_and_ip3_5: $i > $i).
% 28.89/28.98  tff(decl_20322, type, fn_cell_signaling_with_ca2_plus_and_ip3_8: $i > $i).
% 28.89/28.98  tff(decl_20323, type, fn_cell_signaling_with_ca2_plus_and_ip3_10: $i > $i).
% 28.89/28.98  tff(decl_20324, type, fn_cell_signaling_with_ca2_plus_and_ip3_12: $i > $i).
% 28.89/28.98  tff(decl_20325, type, fn_cell_signaling_with_ca2_plus_and_ip3_13: $i > $i).
% 28.89/28.98  tff(decl_20326, type, fn_cell_signaling_with_ca2_plus_and_ip3_14: $i > $i).
% 28.89/28.98  tff(decl_20327, type, fn_cell_signaling_with_ca2_plus_and_ip3_17: $i > $i).
% 28.89/28.98  tff(decl_20328, type, fn_cell_signaling_with_ca2_plus_and_ip3_18: $i > $i).
% 28.89/28.98  tff(decl_20329, type, fn_cell_signaling_with_ca2_plus_and_ip3_19: $i > $i).
% 28.89/28.98  tff(decl_20330, type, fn_cell_signaling_with_ca2_plus_and_ip3_20: $i > $i).
% 28.89/28.98  tff(decl_20331, type, fn_cell_signaling_with_ca2_plus_and_ip3_21: $i > $i).
% 28.89/28.98  tff(decl_20332, type, fn_cell_signaling_with_ca2_plus_and_ip3_22: $i > $i).
% 28.89/28.98  tff(decl_20333, type, fn_cell_signaling_with_ca2_plus_and_ip3_23: $i > $i).
% 28.89/28.98  tff(decl_20334, type, fn_cell_signaling_with_ca2_plus_and_ip3_24: $i > $i).
% 28.89/28.98  tff(decl_20335, type, fn_cell_signaling_with_ca2_plus_and_ip3_25: $i > $i).
% 28.89/28.98  tff(decl_20336, type, fn_cell_signaling_with_ca2_plus_and_ip3_26: $i > $i).
% 28.89/28.98  tff(decl_20337, type, fn_cell_signaling_with_ca2_plus_and_ip3_27: $i > $i).
% 28.89/28.98  tff(decl_20338, type, fn_cell_signaling_with_ca2_plus_and_ip3_28: $i > $i).
% 28.89/28.98  tff(decl_20339, type, fn_cell_signaling_with_ca2_plus_and_ip3_29: $i > $i).
% 28.89/28.98  tff(decl_20340, type, ip3_gated_calcium_ion_channel_1: $i > $o).
% 28.89/28.98  tff(decl_20341, type, fn_cell_signaling_with_ca2_plus_and_ip3_30: $i > $i).
% 28.89/28.98  tff(decl_20342, type, fn_cell_signaling_with_ca2_plus_and_ip3_31: $i > $i).
% 28.89/28.98  tff(decl_20343, type, fn_cell_signaling_with_ca2_plus_and_ip3_32: $i > $i).
% 28.89/28.98  tff(decl_20344, type, fn_cell_signaling_with_ca2_plus_and_ip3_33: $i > $i).
% 28.89/28.98  tff(decl_20345, type, fn_cell_signaling_with_ca2_plus_and_ip3_34: $i > $i).
% 28.89/28.98  tff(decl_20346, type, phospholipase_c_1: $i > $o).
% 28.89/28.98  tff(decl_20347, type, fn_cell_signaling_with_ca2_plus_and_ip3_35: $i > $i).
% 28.89/28.98  tff(decl_20348, type, inositol_trisphosphate_1: $i > $o).
% 28.89/28.98  tff(decl_20349, type, fn_cell_signaling_with_ca2_plus_and_ip3_36: $i > $i).
% 28.89/28.98  tff(decl_20350, type, fn_cell_signaling_with_ca2_plus_and_ip3_37: $i > $i).
% 28.89/28.98  tff(decl_20351, type, fn_cell_signaling_with_ca2_plus_and_ip3_38: $i > $i).
% 28.89/28.98  tff(decl_20352, type, fn_cell_signaling_with_ca2_plus_and_ip3_39: $i > $i).
% 28.89/28.98  tff(decl_20353, type, fn_cell_signaling_with_ca2_plus_and_ip3_40: $i > $i).
% 28.89/28.98  tff(decl_20354, type, fn_cell_signaling_with_ca2_plus_and_ip3_41: $i > $i).
% 28.89/28.98  tff(decl_20355, type, fn_cell_signaling_with_ca2_plus_and_ip3_42: $i > $i).
% 28.89/28.98  tff(decl_20356, type, phosphatidylinositol_bisphosphate_1: $i > $o).
% 28.89/28.98  tff(decl_20357, type, fn_cell_signaling_with_ca2_plus_and_ip3_43: $i > $i).
% 28.89/28.98  tff(decl_20358, type, fn_cell_signaling_with_ca2_plus_and_ip3_44: $i > $i).
% 28.89/28.98  tff(decl_20359, type, second_messenger_1: $i > $o).
% 28.89/28.98  tff(decl_20360, type, fn_cell_signaling_with_ca2_plus_and_ip3_45: $i > $i).
% 28.89/28.98  tff(decl_20361, type, fn_cell_signaling_with_ca2_plus_and_ip3_46: $i > $i).
% 28.89/28.98  tff(decl_20362, type, fn_cell_signaling_with_ca2_plus_and_ip3_47: $i > $i).
% 28.89/28.98  tff(decl_20363, type, fn_cell_signaling_with_ca2_plus_and_ip3_48: $i > $i).
% 28.89/28.98  tff(decl_20364, type, fn_cell_signaling_with_ca2_plus_and_ip3_49: $i > $i).
% 28.89/28.98  tff(decl_20365, type, fn_cell_signaling_with_ca2_plus_and_ip3_50: $i > $i).
% 28.89/28.98  tff(decl_20366, type, fn_cell_signaling_with_ca2_plus_and_ip3_51: $i > $i).
% 28.89/28.98  tff(decl_20367, type, fn_cell_signaling_with_ca2_plus_and_ip3_53: $i > $i).
% 28.89/28.98  tff(decl_20368, type, fn_cell_signaling_with_ca2_plus_and_ip3_54: $i > $i).
% 28.89/28.98  tff(decl_20369, type, fn_cell_signaling_with_ca2_plus_and_ip3_55: $i > $i).
% 28.89/28.98  tff(decl_20370, type, fn_cell_signaling_with_ca2_plus_and_ip3_56: $i > $i).
% 28.89/28.98  tff(decl_20371, type, fn_cell_signaling_with_ca2_plus_and_ip3_57: $i > $i).
% 28.89/28.98  tff(decl_20372, type, fn_cell_signaling_with_ca2_plus_and_ip3_58: $i > $i).
% 28.89/28.98  tff(decl_20373, type, fn_cell_signaling_with_ca2_plus_and_ip3_59: $i > $i).
% 28.89/28.98  tff(decl_20374, type, fn_cell_signaling_with_ca2_plus_and_ip3_60: $i > $i).
% 28.89/28.98  tff(decl_20375, type, fn_cell_signaling_with_ca2_plus_and_ip3_61: $i > $i).
% 28.89/28.98  tff(decl_20376, type, fn_cell_signaling_with_ca2_plus_and_ip3_62: $i > $i).
% 28.89/28.98  tff(decl_20377, type, fn_cell_signaling_with_ca2_plus_and_ip3_63: $i > $i).
% 28.89/28.98  tff(decl_20378, type, fn_cell_signaling_with_ca2_plus_and_ip3_64: $i > $i).
% 28.89/28.98  tff(decl_20379, type, fn_cell_signaling_with_ca2_plus_and_ip3_65: $i > $i).
% 28.89/28.98  tff(decl_20380, type, fn_cell_signaling_with_ca2_plus_and_ip3_66: $i > $i).
% 28.89/28.98  tff(decl_20381, type, fn_signal_transduction_with_second_messenger_1: $i > $i).
% 28.89/28.98  tff(decl_20382, type, fn_gated_ion_channel_6: $i > $i).
% 28.89/28.98  tff(decl_20383, type, fn_phospholipase_c_19: $i > $i).
% 28.89/28.98  tff(decl_20384, type, fn_hydrolysis_2: $i > $i).
% 28.89/28.98  tff(decl_20385, type, fn_second_messenger_3: $i > $i).
% 28.89/28.98  tff(decl_20386, type, fn_phospholipase_c_9: $i > $i).
% 28.89/28.98  tff(decl_20387, type, fn_phospholipase_c_5: $i > $i).
% 28.89/28.98  tff(decl_20388, type, fn_phospholipase_c_15: $i > $i).
% 28.89/28.98  tff(decl_20389, type, fn_cell_signaling_with_ca2_plus_and_ip3_52: $i > $i).
% 28.89/28.98  tff(decl_20390, type, fn_cell_signaling_with_plasma_membrane_receptor_19: $i > $i).
% 28.89/28.98  tff(decl_20391, type, cell_signaling_with_ca2_plus_and_ip3_and_gpcr_1: $i > $o).
% 28.89/28.98  tff(decl_20392, type, 'Cell-Signaling-With-Ca2-Plus-And-IP3-And-GPCR': $i).
% 28.89/28.98  tff(decl_20393, type, 'Process of signaling between and within cells which uses G-Protein Coupled Receptor as the cellular receptor during signal reception, and calcium ions and IP3 as second messengers during signal transduction.': $i).
% 28.89/28.98  tff(decl_20394, type, 'cell signaling with ca2 plus and ip3 and gpcr': $i).
% 28.89/28.98  tff(decl_20395, type, 'cell-signaling-with-ca2-plus-and-ip3-and-gpcr': $i).
% 28.89/28.98  tff(decl_20396, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_2: $i > $i).
% 28.89/28.98  tff(decl_20397, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_3: $i > $i).
% 28.89/28.98  tff(decl_20398, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_4: $i > $i).
% 28.89/28.98  tff(decl_20399, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_5: $i > $i).
% 28.89/28.98  tff(decl_20400, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_6: $i > $i).
% 28.89/28.98  tff(decl_20401, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_7: $i > $i).
% 28.89/28.98  tff(decl_20402, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_8: $i > $i).
% 28.89/28.98  tff(decl_20403, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_9: $i > $i).
% 28.89/28.98  tff(decl_20404, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_10: $i > $i).
% 28.89/28.98  tff(decl_20405, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_11: $i > $i).
% 28.89/28.98  tff(decl_20406, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_12: $i > $i).
% 28.89/28.98  tff(decl_20407, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_14: $i > $i).
% 28.89/28.98  tff(decl_20408, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_15: $i > $i).
% 28.89/28.98  tff(decl_20409, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_16: $i > $i).
% 28.89/28.98  tff(decl_20410, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_17: $i > $i).
% 28.89/28.98  tff(decl_20411, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_18: $i > $i).
% 28.89/28.98  tff(decl_20412, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_19: $i > $i).
% 28.89/28.98  tff(decl_20413, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_20: $i > $i).
% 28.89/28.98  tff(decl_20414, type, gdp_1: $i > $o).
% 28.89/28.98  tff(decl_20415, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_21: $i > $i).
% 28.89/28.98  tff(decl_20416, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_22: $i > $i).
% 28.89/28.98  tff(decl_20417, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_23: $i > $i).
% 28.89/28.98  tff(decl_20418, type, gtp_1: $i > $o).
% 28.89/28.98  tff(decl_20419, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_24: $i > $i).
% 28.89/28.98  tff(decl_20420, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_25: $i > $i).
% 28.89/28.98  tff(decl_20421, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_26: $i > $i).
% 28.89/28.98  tff(decl_20422, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_27: $i > $i).
% 28.89/28.98  tff(decl_20423, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_28: $i > $i).
% 28.89/28.98  tff(decl_20424, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_29: $i > $i).
% 28.89/28.98  tff(decl_20425, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_30: $i > $i).
% 28.89/28.98  tff(decl_20426, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_31: $i > $i).
% 28.89/28.98  tff(decl_20427, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_32: $i > $i).
% 28.89/28.98  tff(decl_20428, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_33: $i > $i).
% 28.89/28.98  tff(decl_20429, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_34: $i > $i).
% 28.89/28.98  tff(decl_20430, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_35: $i > $i).
% 28.89/28.98  tff(decl_20431, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_36: $i > $i).
% 28.89/28.98  tff(decl_20432, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_37: $i > $i).
% 28.89/28.98  tff(decl_20433, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_38: $i > $i).
% 28.89/28.98  tff(decl_20434, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_39: $i > $i).
% 28.89/28.98  tff(decl_20435, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_40: $i > $i).
% 28.89/28.98  tff(decl_20436, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_41: $i > $i).
% 28.89/28.98  tff(decl_20437, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_42: $i > $i).
% 28.89/28.98  tff(decl_20438, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_43: $i > $i).
% 28.89/28.98  tff(decl_20439, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_44: $i > $i).
% 28.89/28.98  tff(decl_20440, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_45: $i > $i).
% 28.89/28.98  tff(decl_20441, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_46: $i > $i).
% 28.89/28.98  tff(decl_20442, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_47: $i > $i).
% 28.89/28.98  tff(decl_20443, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_48: $i > $i).
% 28.89/28.98  tff(decl_20444, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_49: $i > $i).
% 28.89/28.98  tff(decl_20445, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_50: $i > $i).
% 28.89/28.98  tff(decl_20446, type, fn_signal_transduction_3: $i > $i).
% 28.89/28.98  tff(decl_20447, type, fn_signal_transduction_4: $i > $i).
% 28.89/28.98  tff(decl_20448, type, fn_signal_transduction_1: $i > $i).
% 28.89/28.98  tff(decl_20449, type, fn_phospholipase_c_8: $i > $i).
% 28.89/28.98  tff(decl_20450, type, fn_signal_transduction_7: $i > $i).
% 28.89/28.98  tff(decl_20451, type, 'Ip3': $i).
% 28.89/28.98  tff(decl_20452, type, 'IP3': $i).
% 28.89/28.98  tff(decl_20453, type, 'G-p': $i).
% 28.89/28.98  tff(decl_20454, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_gpcr_13: $i > $i).
% 28.89/28.98  tff(decl_20455, type, fn_chemical_signaling_3: $i > $i).
% 28.89/28.98  tff(decl_20456, type, fn_cell_signaling_with_plasma_membrane_receptor_16: $i > $i).
% 28.89/28.98  tff(decl_20457, type, fn_cell_signaling_with_plasma_membrane_receptor_17: $i > $i).
% 28.89/28.98  tff(decl_20458, type, cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_1: $i > $o).
% 28.89/28.98  tff(decl_20459, type, 'Cell-Signaling-With-Ca2-Plus-And-IP3-And-Receptor-Tyrosine-Kinase': $i).
% 28.89/28.98  tff(decl_20460, type, 'Process of signaling between and within cells which uses tyrosine kinase to phosphorylate proteins and calcium ions and IP3 as second messengers during signal transduction.': $i).
% 28.89/28.98  tff(decl_20461, type, 'cell signaling with ca2 plus and ip3 and receptor tyrosine kinase': $i).
% 28.89/28.98  tff(decl_20462, type, 'cell-signaling-with-ca2-plus-and-ip3-and-receptor-tyrosine-kinase': $i).
% 28.89/28.98  tff(decl_20463, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_1: $i > $i).
% 28.89/28.98  tff(decl_20464, type, tyrosine_1: $i > $o).
% 28.89/28.98  tff(decl_20465, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_3: $i > $i).
% 28.89/28.98  tff(decl_20466, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_4: $i > $i).
% 28.89/28.98  tff(decl_20467, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_5: $i > $i).
% 28.89/28.98  tff(decl_20468, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_6: $i > $i).
% 28.89/28.98  tff(decl_20469, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_8: $i > $i).
% 28.89/28.98  tff(decl_20470, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_9: $i > $i).
% 28.89/28.98  tff(decl_20471, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_12: $i > $i).
% 28.89/28.98  tff(decl_20472, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_13: $i > $i).
% 28.89/28.98  tff(decl_20473, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_14: $i > $i).
% 28.89/28.98  tff(decl_20474, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_15: $i > $i).
% 28.89/28.98  tff(decl_20475, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_16: $i > $i).
% 28.89/28.98  tff(decl_20476, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_19: $i > $i).
% 28.89/28.98  tff(decl_20477, type, receptor_tyrosine_kinase_dimer_1: $i > $o).
% 28.89/28.98  tff(decl_20478, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_20: $i > $i).
% 28.89/28.98  tff(decl_20479, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_21: $i > $i).
% 28.89/28.98  tff(decl_20480, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_22: $i > $i).
% 28.89/28.98  tff(decl_20481, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_23: $i > $i).
% 28.89/28.98  tff(decl_20482, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_24: $i > $i).
% 28.89/28.98  tff(decl_20483, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_25: $i > $i).
% 28.89/28.98  tff(decl_20484, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_26: $i > $i).
% 28.89/28.98  tff(decl_20485, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_27: $i > $i).
% 28.89/28.98  tff(decl_20486, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_28: $i > $i).
% 28.89/28.98  tff(decl_20487, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_29: $i > $i).
% 28.89/28.98  tff(decl_20488, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_30: $i > $i).
% 28.89/28.98  tff(decl_20489, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_31: $i > $i).
% 28.89/28.98  tff(decl_20490, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_32: $i > $i).
% 28.89/28.98  tff(decl_20491, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_33: $i > $i).
% 28.89/28.98  tff(decl_20492, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_34: $i > $i).
% 28.89/28.98  tff(decl_20493, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_35: $i > $i).
% 28.89/28.98  tff(decl_20494, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_36: $i > $i).
% 28.89/28.98  tff(decl_20495, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_37: $i > $i).
% 28.89/28.98  tff(decl_20496, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_38: $i > $i).
% 28.89/28.98  tff(decl_20497, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_39: $i > $i).
% 28.89/28.98  tff(decl_20498, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_40: $i > $i).
% 28.89/28.98  tff(decl_20499, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_41: $i > $i).
% 28.89/28.98  tff(decl_20500, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_42: $i > $i).
% 28.89/28.98  tff(decl_20501, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_43: $i > $i).
% 28.89/28.98  tff(decl_20502, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_44: $i > $i).
% 28.89/28.98  tff(decl_20503, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_45: $i > $i).
% 28.89/28.98  tff(decl_20504, type, receptor_tyrosine_kinase_1: $i > $o).
% 28.89/28.98  tff(decl_20505, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_46: $i > $i).
% 28.89/28.98  tff(decl_20506, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_47: $i > $i).
% 28.89/28.98  tff(decl_20507, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_48: $i > $i).
% 28.89/28.98  tff(decl_20508, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_49: $i > $i).
% 28.89/28.98  tff(decl_20509, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_50: $i > $i).
% 28.89/28.98  tff(decl_20510, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_51: $i > $i).
% 28.89/28.98  tff(decl_20511, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_52: $i > $i).
% 28.89/28.98  tff(decl_20512, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_53: $i > $i).
% 28.89/28.98  tff(decl_20513, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_54: $i > $i).
% 28.89/28.98  tff(decl_20514, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_55: $i > $i).
% 28.89/28.98  tff(decl_20515, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_56: $i > $i).
% 28.89/28.98  tff(decl_20516, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_57: $i > $i).
% 28.89/28.98  tff(decl_20517, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_58: $i > $i).
% 28.89/28.98  tff(decl_20518, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_59: $i > $i).
% 28.89/28.98  tff(decl_20519, type, dimerization_1: $i > $o).
% 28.89/28.98  tff(decl_20520, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_60: $i > $i).
% 28.89/28.98  tff(decl_20521, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_61: $i > $i).
% 28.89/28.98  tff(decl_20522, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_62: $i > $i).
% 28.89/28.98  tff(decl_20523, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_63: $i > $i).
% 28.89/28.98  tff(decl_20524, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_64: $i > $i).
% 28.89/28.98  tff(decl_20525, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_65: $i > $i).
% 28.89/28.98  tff(decl_20526, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_66: $i > $i).
% 28.89/28.98  tff(decl_20527, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_67: $i > $i).
% 28.89/28.98  tff(decl_20528, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_68: $i > $i).
% 28.89/28.98  tff(decl_20529, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_69: $i > $i).
% 28.89/28.98  tff(decl_20530, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_70: $i > $i).
% 28.89/28.98  tff(decl_20531, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_71: $i > $i).
% 28.89/28.98  tff(decl_20532, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_72: $i > $i).
% 28.89/28.98  tff(decl_20533, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_73: $i > $i).
% 28.89/28.98  tff(decl_20534, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_74: $i > $i).
% 28.89/28.98  tff(decl_20535, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_75: $i > $i).
% 28.89/28.98  tff(decl_20536, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_76: $i > $i).
% 28.89/28.98  tff(decl_20537, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_77: $i > $i).
% 28.89/28.98  tff(decl_20538, type, fn_dimerization_2: $i > $i).
% 28.89/28.98  tff(decl_20539, type, fn_dimerization_1: $i > $i).
% 28.89/28.98  tff(decl_20540, type, fn_receptor_tyrosine_kinase_dimer_1: $i > $i).
% 28.89/28.98  tff(decl_20541, type, fn_receptor_tyrosine_kinase_dimer_2: $i > $i).
% 28.89/28.98  tff(decl_20542, type, fn_receptor_tyrosine_kinase_10: $i > $i).
% 28.89/28.98  tff(decl_20543, type, fn_receptor_tyrosine_kinase_9: $i > $i).
% 28.89/28.98  tff(decl_20544, type, atp_0: $i).
% 28.89/28.98  tff(decl_20545, type, adp_0: $i).
% 28.89/28.98  tff(decl_20546, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_18: $i > $i).
% 28.89/28.98  tff(decl_20547, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_17: $i > $i).
% 28.89/28.98  tff(decl_20548, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_79: $i > $i).
% 28.89/28.98  tff(decl_20549, type, fn_cell_signaling_with_ca2_plus_and_ip3_and_receptor_tyrosine_kinase_78: $i > $i).
% 28.89/28.98  tff(decl_20550, type, cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_1: $i > $o).
% 28.89/28.98  tff(decl_20551, type, 'Cell-Signaling-With-Ca2-Plus-And-IP3-Leading-To-Animal-Cell-Division': $i).
% 28.89/28.98  tff(decl_20552, type, 'Cellular response to an external stimulus, in which IP3 mobilizes Ca2+ from storage organelles and induces division in animal cells.': $i).
% 28.89/28.98  tff(decl_20553, type, 'cell signaling with ca2 plus and ip3 leading to animal cell division': $i).
% 28.89/28.98  tff(decl_20554, type, 'cell-signaling-with-ca2-plus-and-ip3-leading-to-animal-cell-division': $i).
% 28.89/28.98  tff(decl_20555, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_1: $i > $i).
% 28.89/28.98  tff(decl_20556, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_2: $i > $i).
% 28.89/28.98  tff(decl_20557, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_3: $i > $i).
% 28.89/28.98  tff(decl_20558, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_4: $i > $i).
% 28.89/28.98  tff(decl_20559, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_5: $i > $i).
% 28.89/28.98  tff(decl_20560, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_6: $i > $i).
% 28.89/28.98  tff(decl_20561, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_7: $i > $i).
% 28.89/28.98  tff(decl_20562, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_8: $i > $i).
% 28.89/28.98  tff(decl_20563, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_9: $i > $i).
% 28.89/28.98  tff(decl_20564, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_10: $i > $i).
% 28.89/28.98  tff(decl_20565, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_11: $i > $i).
% 28.89/28.98  tff(decl_20566, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_12: $i > $i).
% 28.89/28.98  tff(decl_20567, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_13: $i > $i).
% 28.89/28.98  tff(decl_20568, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_14: $i > $i).
% 28.89/28.98  tff(decl_20569, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_15: $i > $i).
% 28.89/28.98  tff(decl_20570, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_16: $i > $i).
% 28.89/28.98  tff(decl_20571, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_17: $i > $i).
% 28.89/28.98  tff(decl_20572, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_18: $i > $i).
% 28.89/28.98  tff(decl_20573, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_19: $i > $i).
% 28.89/28.98  tff(decl_20574, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_20: $i > $i).
% 28.89/28.98  tff(decl_20575, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_21: $i > $i).
% 28.89/28.98  tff(decl_20576, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_22: $i > $i).
% 28.89/28.98  tff(decl_20577, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_23: $i > $i).
% 28.89/28.98  tff(decl_20578, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_24: $i > $i).
% 28.89/28.98  tff(decl_20579, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_25: $i > $i).
% 28.89/28.98  tff(decl_20580, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_26: $i > $i).
% 28.89/28.98  tff(decl_20581, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_27: $i > $i).
% 28.89/28.98  tff(decl_20582, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_28: $i > $i).
% 28.89/28.98  tff(decl_20583, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_29: $i > $i).
% 28.89/28.98  tff(decl_20584, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_30: $i > $i).
% 28.89/28.98  tff(decl_20585, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_32: $i > $i).
% 28.89/28.98  tff(decl_20586, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_animal_cell_division_31: $i > $i).
% 28.89/28.98  tff(decl_20587, type, cell_signaling_with_ca2_plus_and_ip3_leading_to_muscle_cell_contraction_1: $i > $o).
% 28.89/28.98  tff(decl_20588, type, 'Cell-Signaling-With-Ca2-Plus-And-IP3-Leading-To-Muscle-Cell-Contraction': $i).
% 28.89/28.98  tff(decl_20589, type, 'Cell signaling in which IP3 mobilizes Ca2+ from storage organelles; the increased Ca2+ in the cytoplasm of a muscle cell causes contraction of the muscle cell.': $i).
% 28.89/28.98  tff(decl_20590, type, 'cell signaling with ca2 plus and ip3 leading to muscle cell contraction': $i).
% 28.89/28.98  tff(decl_20591, type, 'cell-signaling-with-ca2-plus-and-ip3-leading-to-muscle-cell-contraction': $i).
% 28.89/28.98  tff(decl_20592, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_muscle_cell_contraction_1: $i > $i).
% 28.89/28.98  tff(decl_20593, type, cell_signaling_with_ca2_plus_and_ip3_leading_to_secretion_of_substance_1: $i > $o).
% 28.89/28.98  tff(decl_20594, type, 'Cell-Signaling-With-Ca2-Plus-And-IP3-Leading-To-Secretion-Of-Substance': $i).
% 28.89/28.98  tff(decl_20595, type, 'Cellular response to an external stimulus, in which IP3 mobilizes Ca2+ from storage organelles and induces the cell to secrete a substance.': $i).
% 28.89/28.98  tff(decl_20596, type, 'cell signaling with ca2 plus and ip3 leading to secretion of substance': $i).
% 28.89/28.98  tff(decl_20597, type, 'cell-signaling-with-ca2-plus-and-ip3-leading-to-secretion-of-substance': $i).
% 28.89/28.98  tff(decl_20598, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_secretion_of_substance_1: $i > $i).
% 28.89/28.98  tff(decl_20599, type, fn_cell_signaling_with_ca2_plus_and_ip3_leading_to_secretion_of_substance_2: $i > $i).
% 28.89/28.98  tff(decl_20600, type, cell_signaling_with_camp_1: $i > $o).
% 28.89/28.98  tff(decl_20601, type, 'Cell-Signaling-With-cAMP': $i).
% 28.89/28.98  tff(decl_20602, type, 'Gene regulation that promotes transcription in which cAMP (cyclic AMP) is the initiator.': $i).
% 28.89/28.98  tff(decl_20603, type, 'cell signaling with camp': $i).
% 28.89/28.98  tff(decl_20604, type, 'cell-signaling-with-camp': $i).
% 28.89/28.98  tff(decl_20605, type, fn_cell_signaling_with_camp_1: $i > $i).
% 28.89/28.98  tff(decl_20606, type, fn_cell_signaling_with_camp_2: $i > $i).
% 28.89/28.98  tff(decl_20607, type, fn_cell_signaling_with_camp_3: $i > $i).
% 28.89/28.98  tff(decl_20608, type, fn_cell_signaling_with_camp_4: $i > $i).
% 28.89/28.98  tff(decl_20609, type, fn_cell_signaling_with_camp_5: $i > $i).
% 28.89/28.98  tff(decl_20610, type, fn_cell_signaling_with_camp_6: $i > $i).
% 28.89/28.98  tff(decl_20611, type, fn_cell_signaling_with_camp_7: $i > $i).
% 28.89/28.98  tff(decl_20612, type, fn_cell_signaling_with_camp_8: $i > $i).
% 28.89/28.98  tff(decl_20613, type, fn_cell_signaling_with_camp_9: $i > $i).
% 28.89/28.98  tff(decl_20614, type, 'Cell-Signaling-With-cAMP-And-G-Protein-Coupled-Receptor': $i).
% 28.89/28.98  tff(decl_20615, type, 'Process of signaling between and within cells which uses cAMP and G protein as second messengers during signal transduction.': $i).
% 28.89/28.98  tff(decl_20616, type, 'cell signaling with camp and g protein coupled receptor': $i).
% 28.89/28.98  tff(decl_20617, type, 'cell-signaling-with-camp-and-g-protein-coupled-receptor': $i).
% 28.89/28.98  tff(decl_20618, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_3: $i > $i).
% 28.89/28.98  tff(decl_20619, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_6: $i > $i).
% 28.89/28.98  tff(decl_20620, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_9: $i > $i).
% 28.89/28.98  tff(decl_20621, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_10: $i > $i).
% 28.89/28.98  tff(decl_20622, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_11: $i > $i).
% 28.89/28.98  tff(decl_20623, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_12: $i > $i).
% 28.89/28.98  tff(decl_20624, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_15: $i > $i).
% 28.89/28.98  tff(decl_20625, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_16: $i > $i).
% 28.89/28.98  tff(decl_20626, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_19: $i > $i).
% 28.89/28.98  tff(decl_20627, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_20: $i > $i).
% 28.89/28.98  tff(decl_20628, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_23: $i > $i).
% 28.89/28.98  tff(decl_20629, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_24: $i > $i).
% 28.89/28.98  tff(decl_20630, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_25: $i > $i).
% 28.89/28.98  tff(decl_20631, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_26: $i > $i).
% 28.89/28.98  tff(decl_20632, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_27: $i > $i).
% 28.89/28.98  tff(decl_20633, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_28: $i > $i).
% 28.89/28.98  tff(decl_20634, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_29: $i > $i).
% 28.89/28.98  tff(decl_20635, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_30: $i > $i).
% 28.89/28.98  tff(decl_20636, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_31: $i > $i).
% 28.89/28.98  tff(decl_20637, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_33: $i > $i).
% 28.89/28.98  tff(decl_20638, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_34: $i > $i).
% 28.89/28.98  tff(decl_20639, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_38: $i > $i).
% 28.89/28.98  tff(decl_20640, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_39: $i > $i).
% 28.89/28.98  tff(decl_20641, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_40: $i > $i).
% 28.89/28.98  tff(decl_20642, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_41: $i > $i).
% 28.89/28.98  tff(decl_20643, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_46: $i > $i).
% 28.89/28.98  tff(decl_20644, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_48: $i > $i).
% 28.89/28.98  tff(decl_20645, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_49: $i > $i).
% 28.89/28.98  tff(decl_20646, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_50: $i > $i).
% 28.89/28.98  tff(decl_20647, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_51: $i > $i).
% 28.89/28.98  tff(decl_20648, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_52: $i > $i).
% 28.89/28.98  tff(decl_20649, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_53: $i > $i).
% 28.89/28.98  tff(decl_20650, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_54: $i > $i).
% 28.89/28.98  tff(decl_20651, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_55: $i > $i).
% 28.89/28.98  tff(decl_20652, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_61: $i > $i).
% 28.89/28.98  tff(decl_20653, type, inactivation_of_camp_1: $i > $o).
% 28.89/28.98  tff(decl_20654, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_65: $i > $i).
% 28.89/28.98  tff(decl_20655, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_69: $i > $i).
% 28.89/28.98  tff(decl_20656, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_72: $i > $i).
% 28.89/28.98  tff(decl_20657, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_73: $i > $i).
% 28.89/28.98  tff(decl_20658, type, protein_phosphatase_1: $i > $o).
% 28.89/28.98  tff(decl_20659, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_74: $i > $i).
% 28.89/28.98  tff(decl_20660, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_77: $i > $i).
% 28.89/28.98  tff(decl_20661, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_78: $i > $i).
% 28.89/28.98  tff(decl_20662, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_80: $i > $i).
% 28.89/28.98  tff(decl_20663, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_81: $i > $i).
% 28.89/28.98  tff(decl_20664, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_83: $i > $i).
% 28.89/28.98  tff(decl_20665, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_84: $i > $i).
% 28.89/28.98  tff(decl_20666, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_85: $i > $i).
% 28.89/28.98  tff(decl_20667, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_86: $i > $i).
% 28.89/28.98  tff(decl_20668, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_93: $i > $i).
% 28.89/28.98  tff(decl_20669, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_94: $i > $i).
% 28.89/28.98  tff(decl_20670, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_95: $i > $i).
% 28.89/28.98  tff(decl_20671, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_96: $i > $i).
% 28.89/28.98  tff(decl_20672, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_97: $i > $i).
% 28.89/28.98  tff(decl_20673, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_98: $i > $i).
% 28.89/28.98  tff(decl_20674, type, fn_protein_phosphatase_1: $i > $i).
% 28.89/28.98  tff(decl_20675, type, fn_protein_phosphatase_3: $i > $i).
% 28.89/28.98  tff(decl_20676, type, fn_protein_phosphatase_2: $i > $i).
% 28.89/28.98  tff(decl_20677, type, fn_inactivation_of_camp_1: $i > $i).
% 28.89/28.98  tff(decl_20678, type, fn_inactivation_of_camp_2: $i > $i).
% 28.89/28.98  tff(decl_20679, type, fn_inactivation_of_camp_17: $i > $i).
% 28.89/28.98  tff(decl_20680, type, fn_inactivation_of_camp_16: $i > $i).
% 28.89/28.98  tff(decl_20681, type, fn_inactivation_of_camp_15: $i > $i).
% 28.89/28.98  tff(decl_20682, type, fn_cyclic_amp_79: $i > $i).
% 28.89/28.98  tff(decl_20683, type, fn_cyclic_amp_115: $i > $i).
% 28.89/28.98  tff(decl_20684, type, fn_cyclic_amp_78: $i > $i).
% 28.89/28.98  tff(decl_20685, type, fn_synthesis_of_camp_7: $i > $i).
% 28.89/28.98  tff(decl_20686, type, fn_hydrolysis_17: $i > $i).
% 28.89/28.98  tff(decl_20687, type, fn_inactivation_of_camp_11: $i > $i).
% 28.89/28.98  tff(decl_20688, type, fn_inactivation_of_camp_14: $i > $i).
% 28.89/28.98  tff(decl_20689, type, fn_cyclic_amp_24: $i > $i).
% 28.89/28.98  tff(decl_20690, type, fn_cyclic_amp_9: $i > $i).
% 28.89/28.98  tff(decl_20691, type, fn_cyclic_amp_67: $i > $i).
% 28.89/28.98  tff(decl_20692, type, fn_cyclic_amp_68: $i > $i).
% 28.89/28.98  tff(decl_20693, type, fn_cyclic_amp_87: $i > $i).
% 28.89/28.98  tff(decl_20694, type, fn_cyclic_amp_85: $i > $i).
% 28.89/28.98  tff(decl_20695, type, fn_cyclic_amp_80: $i > $i).
% 28.89/28.98  tff(decl_20696, type, fn_cyclic_amp_83: $i > $i).
% 28.89/28.98  tff(decl_20697, type, fn_messenger_1: $i > $i).
% 28.89/28.98  tff(decl_20698, type, fn_synthesis_of_camp_11: $i > $i).
% 28.89/28.98  tff(decl_20699, type, fn_inactivation_of_camp_19: $i > $i).
% 28.89/28.98  tff(decl_20700, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_90: $i > $i).
% 28.89/28.98  tff(decl_20701, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_89: $i > $i).
% 28.89/28.98  tff(decl_20702, type, fn_cell_signaling_with_g_protein_coupled_receptor_105: $i > $i).
% 28.89/28.98  tff(decl_20703, type, fn_cell_signaling_with_g_protein_coupled_receptor_83: $i > $i).
% 28.89/28.98  tff(decl_20704, type, fn_cell_signaling_with_g_protein_coupled_receptor_106: $i > $i).
% 28.89/28.98  tff(decl_20705, type, fn_cell_signaling_with_g_protein_coupled_receptor_78: $i > $i).
% 28.89/28.98  tff(decl_20706, type, fn_cell_signaling_with_g_protein_coupled_receptor_59: $i > $i).
% 28.89/28.98  tff(decl_20707, type, fn_cell_signaling_with_g_protein_coupled_receptor_58: $i > $i).
% 28.89/28.98  tff(decl_20708, type, fn_cell_signaling_with_g_protein_coupled_receptor_32: $i > $i).
% 28.89/28.98  tff(decl_20709, type, fn_cell_signaling_with_g_protein_coupled_receptor_104: $i > $i).
% 28.89/28.98  tff(decl_20710, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_100: $i > $i).
% 28.89/28.98  tff(decl_20711, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_99: $i > $i).
% 28.89/28.98  tff(decl_20712, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_36: $i > $i).
% 28.89/28.98  tff(decl_20713, type, fn_cell_signaling_with_camp_and_g_protein_coupled_receptor_35: $i > $i).
% 28.89/28.98  tff(decl_20714, type, cell_signaling_with_cgmp_1: $i > $o).
% 28.89/28.98  tff(decl_20715, type, 'Cell-Signaling-With-cGMP': $i).
% 28.89/28.98  tff(decl_20716, type, 'Process of signaling between and within cells which uses cAMP as second messenger during signal transduction.': $i).
% 28.89/28.98  tff(decl_20717, type, 'cell signaling with cgmp': $i).
% 28.89/28.98  tff(decl_20718, type, 'cell-signaling-with-cgmp': $i).
% 28.89/28.98  tff(decl_20719, type, fn_cell_signaling_with_cgmp_1: $i > $i).
% 28.89/28.98  tff(decl_20720, type, fn_cell_signaling_with_cgmp_2: $i > $i).
% 28.89/28.98  tff(decl_20721, type, fn_cell_signaling_with_cgmp_3: $i > $i).
% 28.89/28.98  tff(decl_20722, type, 'Cell-Signaling-With-G-Protein-Coupled-Receptor': $i).
% 28.89/28.98  tff(decl_20723, type, 'A signal transduction pathway initiated by the binding of a signaling molecule to the receptor protein that binds GTP, which activates the G protein to which it is attached.': $i).
% 28.89/28.98  tff(decl_20724, type, 'g protein coupled cell signaling': $i).
% 28.89/28.98  tff(decl_20725, type, 'g-protein-coupled-cell-signaling': $i).
% 28.89/28.98  tff(decl_20726, type, 'g protein coupled signaling': $i).
% 28.89/28.98  tff(decl_20727, type, 'g-protein-coupled-signaling': $i).
% 28.89/28.98  tff(decl_20728, type, 'signal transduction with g protein': $i).
% 28.89/28.98  tff(decl_20729, type, 'signal transduction with g-protein': $i).
% 28.89/28.98  tff(decl_20730, type, 'cell signaling with g protein': $i).
% 28.89/28.98  tff(decl_20731, type, 'cell signaling with g-protein': $i).
% 28.89/28.98  tff(decl_20732, type, 'g protein signaling': $i).
% 28.89/28.98  tff(decl_20733, type, 'g-protein signaling': $i).
% 28.89/28.98  tff(decl_20734, type, 'cell signaling with g protein coupled receptor': $i).
% 28.89/28.98  tff(decl_20735, type, 'cell-signaling-with-g-protein-coupled-receptor': $i).
% 28.89/28.98  tff(decl_20736, type, fn_cell_signaling_with_g_protein_coupled_receptor_2: $i > $i).
% 28.89/28.98  tff(decl_20737, type, fn_cell_signaling_with_g_protein_coupled_receptor_8: $i > $i).
% 28.89/28.98  tff(decl_20738, type, fn_cell_signaling_with_g_protein_coupled_receptor_9: $i > $i).
% 28.89/28.98  tff(decl_20739, type, fn_cell_signaling_with_g_protein_coupled_receptor_11: $i > $i).
% 28.89/28.98  tff(decl_20740, type, fn_cell_signaling_with_g_protein_coupled_receptor_13: $i > $i).
% 28.89/28.98  tff(decl_20741, type, fn_cell_signaling_with_g_protein_coupled_receptor_14: $i > $i).
% 28.89/28.98  tff(decl_20742, type, fn_cell_signaling_with_g_protein_coupled_receptor_17: $i > $i).
% 28.89/28.98  tff(decl_20743, type, fn_cell_signaling_with_g_protein_coupled_receptor_18: $i > $i).
% 28.89/28.98  tff(decl_20744, type, fn_cell_signaling_with_g_protein_coupled_receptor_24: $i > $i).
% 28.89/28.98  tff(decl_20745, type, fn_cell_signaling_with_g_protein_coupled_receptor_25: $i > $i).
% 28.89/28.98  tff(decl_20746, type, fn_cell_signaling_with_g_protein_coupled_receptor_26: $i > $i).
% 28.89/28.98  tff(decl_20747, type, fn_cell_signaling_with_g_protein_coupled_receptor_31: $i > $i).
% 28.89/28.98  tff(decl_20748, type, fn_cell_signaling_with_g_protein_coupled_receptor_35: $i > $i).
% 28.89/28.98  tff(decl_20749, type, gtpase_1: $i > $o).
% 28.89/28.98  tff(decl_20750, type, fn_cell_signaling_with_g_protein_coupled_receptor_36: $i > $i).
% 28.89/28.98  tff(decl_20751, type, fn_cell_signaling_with_g_protein_coupled_receptor_37: $i > $i).
% 28.89/28.98  tff(decl_20752, type, fn_cell_signaling_with_g_protein_coupled_receptor_38: $i > $i).
% 28.89/28.98  tff(decl_20753, type, fn_cell_signaling_with_g_protein_coupled_receptor_39: $i > $i).
% 28.89/28.98  tff(decl_20754, type, fn_cell_signaling_with_g_protein_coupled_receptor_40: $i > $i).
% 28.89/28.98  tff(decl_20755, type, fn_cell_signaling_with_g_protein_coupled_receptor_41: $i > $i).
% 28.89/28.98  tff(decl_20756, type, fn_cell_signaling_with_g_protein_coupled_receptor_42: $i > $i).
% 28.89/28.98  tff(decl_20757, type, fn_cell_signaling_with_g_protein_coupled_receptor_43: $i > $i).
% 28.89/28.98  tff(decl_20758, type, fn_cell_signaling_with_g_protein_coupled_receptor_44: $i > $i).
% 28.89/28.98  tff(decl_20759, type, fn_cell_signaling_with_g_protein_coupled_receptor_45: $i > $i).
% 28.89/28.98  tff(decl_20760, type, fn_cell_signaling_with_g_protein_coupled_receptor_46: $i > $i).
% 28.89/28.98  tff(decl_20761, type, fn_cell_signaling_with_g_protein_coupled_receptor_47: $i > $i).
% 28.89/28.98  tff(decl_20762, type, fn_cell_signaling_with_g_protein_coupled_receptor_48: $i > $i).
% 28.89/28.98  tff(decl_20763, type, fn_cell_signaling_with_g_protein_coupled_receptor_49: $i > $i).
% 28.89/28.98  tff(decl_20764, type, fn_cell_signaling_with_g_protein_coupled_receptor_50: $i > $i).
% 28.89/28.98  tff(decl_20765, type, fn_cell_signaling_with_g_protein_coupled_receptor_51: $i > $i).
% 28.89/28.98  tff(decl_20766, type, fn_cell_signaling_with_g_protein_coupled_receptor_52: $i > $i).
% 28.89/28.98  tff(decl_20767, type, fn_cell_signaling_with_g_protein_coupled_receptor_53: $i > $i).
% 28.89/28.98  tff(decl_20768, type, fn_cell_signaling_with_g_protein_coupled_receptor_54: $i > $i).
% 28.89/28.98  tff(decl_20769, type, fn_cell_signaling_with_g_protein_coupled_receptor_55: $i > $i).
% 28.89/28.98  tff(decl_20770, type, fn_cell_signaling_with_g_protein_coupled_receptor_56: $i > $i).
% 28.89/28.98  tff(decl_20771, type, fn_cell_signaling_with_g_protein_coupled_receptor_60: $i > $i).
% 28.89/28.98  tff(decl_20772, type, fn_cell_signaling_with_g_protein_coupled_receptor_62: $i > $i).
% 28.89/28.98  tff(decl_20773, type, fn_cell_signaling_with_g_protein_coupled_receptor_68: $i > $i).
% 28.89/28.98  tff(decl_20774, type, fn_cell_signaling_with_g_protein_coupled_receptor_69: $i > $i).
% 28.89/28.98  tff(decl_20775, type, fn_cell_signaling_with_g_protein_coupled_receptor_70: $i > $i).
% 28.89/28.98  tff(decl_20776, type, fn_cell_signaling_with_g_protein_coupled_receptor_71: $i > $i).
% 28.89/28.98  tff(decl_20777, type, fn_cell_signaling_with_g_protein_coupled_receptor_72: $i > $i).
% 28.89/28.98  tff(decl_20778, type, fn_cell_signaling_with_g_protein_coupled_receptor_73: $i > $i).
% 28.89/28.98  tff(decl_20779, type, fn_cell_signaling_with_g_protein_coupled_receptor_74: $i > $i).
% 28.89/28.98  tff(decl_20780, type, fn_cell_signaling_with_g_protein_coupled_receptor_75: $i > $i).
% 28.89/28.98  tff(decl_20781, type, fn_cell_signaling_with_g_protein_coupled_receptor_76: $i > $i).
% 28.89/28.98  tff(decl_20782, type, fn_cell_signaling_with_g_protein_coupled_receptor_77: $i > $i).
% 28.89/28.98  tff(decl_20783, type, fn_cell_signaling_with_g_protein_coupled_receptor_79: $i > $i).
% 28.89/28.98  tff(decl_20784, type, fn_cell_signaling_with_g_protein_coupled_receptor_80: $i > $i).
% 28.89/28.98  tff(decl_20785, type, fn_cell_signaling_with_g_protein_coupled_receptor_81: $i > $i).
% 28.89/28.98  tff(decl_20786, type, fn_cell_signaling_with_g_protein_coupled_receptor_82: $i > $i).
% 28.89/28.98  tff(decl_20787, type, fn_cell_signaling_with_g_protein_coupled_receptor_84: $i > $i).
% 28.89/28.98  tff(decl_20788, type, fn_cell_signaling_with_g_protein_coupled_receptor_85: $i > $i).
% 28.89/28.98  tff(decl_20789, type, fn_cell_signaling_with_g_protein_coupled_receptor_86: $i > $i).
% 28.89/28.98  tff(decl_20790, type, fn_cell_signaling_with_g_protein_coupled_receptor_88: $i > $i).
% 28.89/28.98  tff(decl_20791, type, fn_cell_signaling_with_g_protein_coupled_receptor_90: $i > $i).
% 28.89/28.98  tff(decl_20792, type, fn_cell_signaling_with_g_protein_coupled_receptor_91: $i > $i).
% 28.89/28.98  tff(decl_20793, type, fn_cell_signaling_with_g_protein_coupled_receptor_92: $i > $i).
% 28.89/28.98  tff(decl_20794, type, fn_cell_signaling_with_g_protein_coupled_receptor_93: $i > $i).
% 28.89/28.98  tff(decl_20795, type, fn_cell_signaling_with_g_protein_coupled_receptor_97: $i > $i).
% 28.89/28.98  tff(decl_20796, type, fn_cell_signaling_with_g_protein_coupled_receptor_98: $i > $i).
% 28.89/28.98  tff(decl_20797, type, fn_cell_signaling_with_g_protein_coupled_receptor_102: $i > $i).
% 28.89/28.98  tff(decl_20798, type, fn_cell_signaling_with_g_protein_coupled_receptor_107: $i > $i).
% 28.89/28.98  tff(decl_20799, type, fn_cell_signaling_with_g_protein_coupled_receptor_108: $i > $i).
% 28.89/28.98  tff(decl_20800, type, fn_signal_transduction_5: $i > $i).
% 28.89/28.98  tff(decl_20801, type, fn_signal_transduction_2: $i > $i).
% 28.89/28.98  tff(decl_20802, type, fn_g_protein_2: $i > $i).
% 28.89/28.98  tff(decl_20803, type, fn_plasma_membrane_61: $i > $i).
% 28.89/28.98  tff(decl_20804, type, fn_plasma_membrane_64: $i > $i).
% 28.89/28.98  tff(decl_20805, type, fn_plasma_membrane_29: $i > $i).
% 28.89/28.98  tff(decl_20806, type, fn_plasma_membrane_18: $i > $i).
% 28.89/28.98  tff(decl_20807, type, fn_plasma_membrane_14: $i > $i).
% 28.89/28.98  tff(decl_20808, type, fn_plasma_membrane_28: $i > $i).
% 28.89/28.98  tff(decl_20809, type, fn_plasma_membrane_19: $i > $i).
% 28.89/28.98  tff(decl_20810, type, fn_plasma_membrane_15: $i > $i).
% 28.89/28.98  tff(decl_20811, type, fn_plasma_membrane_92: $i > $i).
% 28.89/28.98  tff(decl_20812, type, fn_plasma_membrane_63: $i > $i).
% 28.89/28.98  tff(decl_20813, type, fn_plasma_membrane_67: $i > $i).
% 28.89/28.98  tff(decl_20814, type, fn_plasma_membrane_62: $i > $i).
% 28.89/28.98  tff(decl_20815, type, fn_gtp_15: $i > $i).
% 28.89/28.98  tff(decl_20816, type, fn_gtpase_9: $i > $i).
% 28.89/28.98  tff(decl_20817, type, fn_dephosphorylation_12: $i > $i).
% 28.89/28.98  tff(decl_20818, type, fn_gtp_18: $i > $i).
% 28.89/28.98  tff(decl_20819, type, fn_gtpase_6: $i > $i).
% 28.89/28.98  tff(decl_20820, type, fn_gtp_17: $i > $i).
% 28.89/28.98  tff(decl_20821, type, fn_dephosphorylation_4: $i > $i).
% 28.89/28.98  tff(decl_20822, type, fn_gtp_20: $i > $i).
% 28.89/28.98  tff(decl_20823, type, fn_gtpase_3: $i > $i).
% 28.89/28.98  tff(decl_20824, type, fn_dephosphorylation_5: $i > $i).
% 28.89/28.98  tff(decl_20825, type, fn_gtp_21: $i > $i).
% 28.89/28.98  tff(decl_20826, type, fn_gtpase_4: $i > $i).
% 28.89/28.98  tff(decl_20827, type, fn_gtp_19: $i > $i).
% 28.89/28.98  tff(decl_20828, type, fn_gtpase_2: $i > $i).
% 28.89/28.98  tff(decl_20829, type, fn_gtpase_8: $i > $i).
% 28.89/28.98  tff(decl_20830, type, fn_cell_signaling_with_g_protein_coupled_receptor_23: $i > $i).
% 28.89/28.98  tff(decl_20831, type, fn_cell_signaling_with_g_protein_coupled_receptor_33: $i > $i).
% 28.89/28.98  tff(decl_20832, type, fn_cell_signaling_with_g_protein_coupled_receptor_34: $i > $i).
% 28.89/28.98  tff(decl_20833, type, fn_cell_signaling_with_g_protein_coupled_receptor_111: $i > $i).
% 28.89/28.98  tff(decl_20834, type, fn_cell_signaling_with_g_protein_coupled_receptor_110: $i > $i).
% 28.89/28.98  tff(decl_20835, type, fn_cell_signaling_with_g_protein_coupled_receptor_115: $i > $i).
% 28.89/28.98  tff(decl_20836, type, fn_cell_signaling_with_g_protein_coupled_receptor_114: $i > $i).
% 28.89/28.98  tff(decl_20837, type, fn_cell_signaling_with_g_protein_coupled_receptor_113: $i > $i).
% 28.89/28.98  tff(decl_20838, type, fn_cell_signaling_with_g_protein_coupled_receptor_112: $i > $i).
% 28.89/28.98  tff(decl_20839, type, 'Cell-Signaling-With-Intracellular-Receptor': $i).
% 28.89/28.98  tff(decl_20840, type, 'The process of signal reception, signal transduction and cellular response in which the receptor is located inside the cell.': $i).
% 28.89/28.98  tff(decl_20841, type, 'cell signaling with intracellular receptor': $i).
% 28.89/28.98  tff(decl_20842, type, 'cell-signaling-with-intracellular-receptor': $i).
% 28.89/28.98  tff(decl_20843, type, fn_cell_signaling_with_intracellular_receptor_1: $i > $i).
% 28.89/28.98  tff(decl_20844, type, fn_cell_signaling_with_intracellular_receptor_2: $i > $i).
% 28.89/28.98  tff(decl_20845, type, fn_cell_signaling_with_intracellular_receptor_8: $i > $i).
% 28.89/28.98  tff(decl_20846, type, fn_cell_signaling_with_intracellular_receptor_11: $i > $i).
% 28.89/28.98  tff(decl_20847, type, fn_cell_signaling_with_intracellular_receptor_12: $i > $i).
% 28.89/28.98  tff(decl_20848, type, cell_signaling_with_intracellular_receptor_and_hydrophobic_signal_1: $i > $o).
% 28.89/28.98  tff(decl_20849, type, 'Cell-Signaling-With-Intracellular-Receptor-And-Hydrophobic-Signal': $i).
% 28.89/28.98  tff(decl_20850, type, 'The process of signal reception, signal transduction and cellular response in which the receptor is located inside the cell and the signaling molecule is hydrophobic.': $i).
% 28.89/28.98  tff(decl_20851, type, 'cell signaling with intracellular receptor and hydrophobic signal': $i).
% 28.89/28.98  tff(decl_20852, type, 'cell-signaling-with-intracellular-receptor-and-hydrophobic-signal': $i).
% 28.89/28.98  tff(decl_20853, type, fn_cell_signaling_with_intracellular_receptor_and_hydrophobic_signal_2: $i > $i).
% 28.89/28.98  tff(decl_20854, type, fn_cell_signaling_with_intracellular_receptor_and_hydrophobic_signal_3: $i > $i).
% 28.89/28.98  tff(decl_20855, type, fn_cell_signaling_with_intracellular_receptor_and_hydrophobic_signal_1: $i > $i).
% 28.89/28.98  tff(decl_20856, type, cell_signaling_with_intracellular_receptor_and_small_molecule_1: $i > $o).
% 28.89/28.98  tff(decl_20857, type, 'Cell-Signaling-With-Intracellular-Receptor-And-Small-Molecule': $i).
% 28.89/28.98  tff(decl_20858, type, 'The process of signal reception, signal transduction and cellular response in which the receptor is located inside the cell and the signaling molecule is small in size.': $i).
% 28.89/28.98  tff(decl_20859, type, 'cell signaling with intracellular receptor and small molecule': $i).
% 28.89/28.98  tff(decl_20860, type, 'cell-signaling-with-intracellular-receptor-and-small-molecule': $i).
% 28.89/28.98  tff(decl_20861, type, 'Cell-Signaling-With-Ion-Channel-Receptor': $i).
% 28.89/28.98  tff(decl_20862, type, 'A process of signaling within a cell which uses ligand gated ion channels as mediators of various steps in the pathway.': $i).
% 28.89/28.98  tff(decl_20863, type, 'cell signaling with ion channel receptor': $i).
% 28.89/28.98  tff(decl_20864, type, 'cell-signaling-with-ion-channel-receptor': $i).
% 28.89/28.98  tff(decl_20865, type, fn_cell_signaling_with_ion_channel_receptor_2: $i > $i).
% 28.89/28.98  tff(decl_20866, type, fn_cell_signaling_with_ion_channel_receptor_6: $i > $i).
% 28.89/28.98  tff(decl_20867, type, fn_cell_signaling_with_ion_channel_receptor_7: $i > $i).
% 28.89/28.98  tff(decl_20868, type, fn_cell_signaling_with_ion_channel_receptor_11: $i > $i).
% 28.89/28.98  tff(decl_20869, type, fn_cell_signaling_with_ion_channel_receptor_12: $i > $i).
% 28.89/28.98  tff(decl_20870, type, fn_cell_signaling_with_ion_channel_receptor_13: $i > $i).
% 28.89/28.98  tff(decl_20871, type, fn_cell_signaling_with_ion_channel_receptor_14: $i > $i).
% 28.89/28.98  tff(decl_20872, type, fn_cell_signaling_with_ion_channel_receptor_15: $i > $i).
% 28.89/28.98  tff(decl_20873, type, fn_cell_signaling_with_ion_channel_receptor_18: $i > $i).
% 28.89/28.98  tff(decl_20874, type, fn_cell_signaling_with_ion_channel_receptor_19: $i > $i).
% 28.89/28.98  tff(decl_20875, type, fn_cell_signaling_with_ion_channel_receptor_21: $i > $i).
% 28.89/28.98  tff(decl_20876, type, fn_cell_signaling_with_ion_channel_receptor_22: $i > $i).
% 28.89/28.98  tff(decl_20877, type, fn_cell_signaling_with_ion_channel_receptor_23: $i > $i).
% 28.89/28.98  tff(decl_20878, type, fn_cell_signaling_with_ion_channel_receptor_24: $i > $i).
% 28.89/28.98  tff(decl_20879, type, fn_cell_signaling_with_ion_channel_receptor_25: $i > $i).
% 28.89/28.98  tff(decl_20880, type, fn_cell_signaling_with_ion_channel_receptor_26: $i > $i).
% 28.89/28.98  tff(decl_20881, type, fn_cell_signaling_with_ion_channel_receptor_27: $i > $i).
% 28.89/28.98  tff(decl_20882, type, fn_plasma_membrane_27: $i > $i).
% 28.89/28.98  tff(decl_20883, type, fn_plasma_membrane_20: $i > $i).
% 28.89/28.98  tff(decl_20884, type, fn_plasma_membrane_17: $i > $i).
% 28.89/28.98  tff(decl_20885, type, fn_plasma_membrane_16: $i > $i).
% 28.89/28.98  tff(decl_20886, type, fn_cell_signaling_with_ion_channel_receptor_5: $i > $i).
% 28.89/28.98  tff(decl_20887, type, fn_cell_signaling_with_ion_channel_receptor_33: $i > $i).
% 28.89/28.98  tff(decl_20888, type, fn_cell_signaling_with_ion_channel_receptor_4: $i > $i).
% 28.89/28.98  tff(decl_20889, type, fn_cell_signaling_with_ion_channel_receptor_34: $i > $i).
% 28.89/28.98  tff(decl_20890, type, fn_cell_signaling_with_ion_channel_receptor_35: $i > $i).
% 28.89/28.98  tff(decl_20891, type, fn_cell_signaling_with_ion_channel_receptor_3: $i > $i).
% 28.89/28.98  tff(decl_20892, type, 'Cell-Signaling-With-Mating-Factor': $i).
% 28.89/28.98  tff(decl_20893, type, 'Process of communication between yeast cells which uses mating factors as the signaling molecule.': $i).
% 28.89/28.98  tff(decl_20894, type, 'cell signaling with mating factor': $i).
% 28.89/28.98  tff(decl_20895, type, 'cell-signaling-with-mating-factor': $i).
% 28.89/28.98  tff(decl_20896, type, fn_cell_signaling_with_mating_factor_4: $i > $i).
% 28.89/28.98  tff(decl_20897, type, fn_cell_signaling_with_mating_factor_5: $i > $i).
% 28.89/28.98  tff(decl_20898, type, fn_cell_signaling_with_mating_factor_9: $i > $i).
% 28.89/28.98  tff(decl_20899, type, fn_cell_signaling_with_mating_factor_10: $i > $i).
% 28.89/28.98  tff(decl_20900, type, fn_cell_signaling_with_mating_factor_11: $i > $i).
% 28.89/28.98  tff(decl_20901, type, fn_cell_signaling_with_mating_factor_12: $i > $i).
% 28.89/28.98  tff(decl_20902, type, fn_cell_signaling_with_mating_factor_13: $i > $i).
% 28.89/28.98  tff(decl_20903, type, fn_cell_signaling_with_mating_factor_14: $i > $i).
% 28.89/28.98  tff(decl_20904, type, fn_cell_signaling_with_mating_factor_18: $i > $i).
% 28.89/28.98  tff(decl_20905, type, fn_cell_signaling_with_mating_factor_19: $i > $i).
% 28.89/28.98  tff(decl_20906, type, fn_cell_signaling_with_mating_factor_24: $i > $i).
% 28.89/28.98  tff(decl_20907, type, fn_cell_signaling_with_mating_factor_25: $i > $i).
% 28.89/28.98  tff(decl_20908, type, fn_cell_signaling_with_mating_factor_26: $i > $i).
% 28.89/28.98  tff(decl_20909, type, fn_cell_signaling_with_mating_factor_27: $i > $i).
% 28.89/28.98  tff(decl_20910, type, fn_cell_signaling_with_mating_factor_28: $i > $i).
% 28.89/28.98  tff(decl_20911, type, fn_cell_signaling_with_mating_factor_29: $i > $i).
% 28.89/28.98  tff(decl_20912, type, fn_cell_signaling_with_mating_factor_30: $i > $i).
% 28.89/28.98  tff(decl_20913, type, fn_cell_signaling_with_mating_factor_31: $i > $i).
% 28.89/28.98  tff(decl_20914, type, fn_cell_signaling_with_mating_factor_32: $i > $i).
% 28.89/28.98  tff(decl_20915, type, fn_cell_signaling_with_mating_factor_33: $i > $i).
% 28.89/28.98  tff(decl_20916, type, fn_cell_signaling_with_mating_factor_34: $i > $i).
% 28.89/28.98  tff(decl_20917, type, fn_cell_signaling_with_mating_factor_35: $i > $i).
% 28.89/28.98  tff(decl_20918, type, fn_cell_signaling_with_mating_factor_36: $i > $i).
% 28.89/28.98  tff(decl_20919, type, fn_cell_signaling_with_mating_factor_37: $i > $i).
% 28.89/28.98  tff(decl_20920, type, fn_cell_signaling_with_mating_factor_38: $i > $i).
% 28.89/28.98  tff(decl_20921, type, fn_cell_signaling_with_mating_factor_39: $i > $i).
% 28.89/28.98  tff(decl_20922, type, fn_cell_signaling_with_mating_factor_40: $i > $i).
% 28.89/28.98  tff(decl_20923, type, fn_cell_signaling_with_mating_factor_41: $i > $i).
% 28.89/28.98  tff(decl_20924, type, fn_cell_signaling_with_mating_factor_44: $i > $i).
% 28.89/28.98  tff(decl_20925, type, fn_cell_signaling_with_mating_factor_45: $i > $i).
% 28.89/28.98  tff(decl_20926, type, fn_cell_signaling_with_mating_factor_46: $i > $i).
% 28.89/28.98  tff(decl_20927, type, fn_cell_signaling_with_mating_factor_47: $i > $i).
% 28.89/28.98  tff(decl_20928, type, fn_cell_signaling_with_mating_factor_48: $i > $i).
% 28.89/28.98  tff(decl_20929, type, fn_cell_signaling_with_mating_factor_49: $i > $i).
% 28.89/28.98  tff(decl_20930, type, fn_cell_signaling_with_mating_factor_50: $i > $i).
% 28.89/28.98  tff(decl_20931, type, fn_cell_signaling_with_mating_factor_51: $i > $i).
% 28.89/28.98  tff(decl_20932, type, fn_cell_signaling_with_mating_factor_52: $i > $i).
% 28.89/28.98  tff(decl_20933, type, fn_cell_signaling_with_mating_factor_53: $i > $i).
% 28.89/28.98  tff(decl_20934, type, fn_cell_signaling_with_mating_factor_56: $i > $i).
% 28.89/28.98  tff(decl_20935, type, fn_cell_signaling_with_mating_factor_57: $i > $i).
% 28.89/28.98  tff(decl_20936, type, fn_cell_signaling_with_mating_factor_58: $i > $i).
% 28.89/28.98  tff(decl_20937, type, fn_cell_signaling_with_mating_factor_63: $i > $i).
% 28.89/28.98  tff(decl_20938, type, fn_cell_signaling_with_mating_factor_64: $i > $i).
% 28.89/28.98  tff(decl_20939, type, fn_cell_signaling_with_mating_factor_65: $i > $i).
% 28.89/28.98  tff(decl_20940, type, fn_cell_signaling_with_mating_factor_66: $i > $i).
% 28.89/28.98  tff(decl_20941, type, formin_1: $i > $o).
% 28.89/28.98  tff(decl_20942, type, fn_cell_signaling_with_mating_factor_67: $i > $i).
% 28.89/28.98  tff(decl_20943, type, fn_cell_signaling_with_mating_factor_68: $i > $i).
% 28.89/28.98  tff(decl_20944, type, fus3_1: $i > $o).
% 28.89/28.98  tff(decl_20945, type, fn_cell_signaling_with_mating_factor_69: $i > $i).
% 28.89/28.98  tff(decl_20946, type, fn_cell_signaling_with_mating_factor_70: $i > $i).
% 28.89/28.98  tff(decl_20947, type, fn_cell_signaling_with_mating_factor_71: $i > $i).
% 28.89/28.98  tff(decl_20948, type, fn_cell_signaling_with_mating_factor_72: $i > $i).
% 28.89/28.98  tff(decl_20949, type, fn_cell_signaling_with_mating_factor_73: $i > $i).
% 28.89/28.98  tff(decl_20950, type, fn_cell_signaling_with_mating_factor_74: $i > $i).
% 28.89/28.98  tff(decl_20951, type, fn_cell_signaling_with_mating_factor_75: $i > $i).
% 28.89/28.98  tff(decl_20952, type, fn_cell_signaling_with_mating_factor_76: $i > $i).
% 28.89/28.98  tff(decl_20953, type, fn_cell_signaling_with_mating_factor_77: $i > $i).
% 28.89/28.98  tff(decl_20954, type, fn_cell_signaling_with_mating_factor_78: $i > $i).
% 28.89/28.98  tff(decl_20955, type, fn_cell_signaling_with_mating_factor_79: $i > $i).
% 28.89/28.98  tff(decl_20956, type, fn_cell_signaling_with_mating_factor_80: $i > $i).
% 28.89/28.98  tff(decl_20957, type, fn_cell_signaling_with_mating_factor_81: $i > $i).
% 28.89/28.98  tff(decl_20958, type, fn_cell_signaling_with_mating_factor_82: $i > $i).
% 28.89/28.98  tff(decl_20959, type, fn_cell_signaling_with_mating_factor_83: $i > $i).
% 28.89/28.98  tff(decl_20960, type, fn_cell_signaling_with_mating_factor_84: $i > $i).
% 28.89/28.98  tff(decl_20961, type, fn_cell_signaling_with_mating_factor_86: $i > $i).
% 28.89/28.98  tff(decl_20962, type, fn_cell_signaling_with_mating_factor_88: $i > $i).
% 28.89/28.98  tff(decl_20963, type, fn_cell_signaling_with_mating_factor_89: $i > $i).
% 28.89/28.98  tff(decl_20964, type, fn_cell_signaling_with_mating_factor_96: $i > $i).
% 28.89/28.98  tff(decl_20965, type, fn_cell_signaling_with_mating_factor_97: $i > $i).
% 28.89/28.98  tff(decl_20966, type, fn_cell_signaling_with_mating_factor_98: $i > $i).
% 28.89/28.98  tff(decl_20967, type, fn_cell_signaling_with_mating_factor_99: $i > $i).
% 28.89/28.98  tff(decl_20968, type, fn_cell_signaling_with_mating_factor_100: $i > $i).
% 28.89/28.98  tff(decl_20969, type, fn_cell_signaling_with_mating_factor_101: $i > $i).
% 28.89/28.98  tff(decl_20970, type, fn_cell_signaling_with_mating_factor_102: $i > $i).
% 28.89/28.98  tff(decl_20971, type, fn_cell_signaling_with_mating_factor_103: $i > $i).
% 28.89/28.98  tff(decl_20972, type, fn_cell_signaling_with_mating_factor_104: $i > $i).
% 28.89/28.98  tff(decl_20973, type, fn_cell_signaling_with_mating_factor_105: $i > $i).
% 28.89/28.98  tff(decl_20974, type, fn_cell_signaling_with_mating_factor_106: $i > $i).
% 28.89/28.98  tff(decl_20975, type, fn_cell_signaling_with_mating_factor_107: $i > $i).
% 28.89/28.98  tff(decl_20976, type, fn_cell_signaling_with_mating_factor_108: $i > $i).
% 28.89/28.98  tff(decl_20977, type, fn_cell_signaling_with_mating_factor_109: $i > $i).
% 28.89/28.98  tff(decl_20978, type, fn_cell_signaling_with_mating_factor_110: $i > $i).
% 28.89/28.98  tff(decl_20979, type, fn_cell_signaling_with_mating_factor_111: $i > $i).
% 28.89/28.98  tff(decl_20980, type, fn_cell_signaling_with_mating_factor_112: $i > $i).
% 28.89/28.98  tff(decl_20981, type, fn_cell_signaling_with_mating_factor_113: $i > $i).
% 28.89/28.98  tff(decl_20982, type, fn_cell_signaling_with_mating_factor_114: $i > $i).
% 28.89/28.98  tff(decl_20983, type, fn_cell_signaling_with_mating_factor_115: $i > $i).
% 28.89/28.98  tff(decl_20984, type, fn_cell_signaling_with_mating_factor_116: $i > $i).
% 28.89/28.98  tff(decl_20985, type, fn_cell_signaling_with_mating_factor_117: $i > $i).
% 28.89/28.98  tff(decl_20986, type, fn_cell_signaling_with_mating_factor_118: $i > $i).
% 28.89/28.98  tff(decl_20987, type, fn_cell_signaling_with_mating_factor_119: $i > $i).
% 28.89/28.98  tff(decl_20988, type, fn_cell_signaling_with_mating_factor_120: $i > $i).
% 28.89/28.98  tff(decl_20989, type, fn_cell_signaling_with_mating_factor_121: $i > $i).
% 28.89/28.98  tff(decl_20990, type, fn_cell_signaling_with_mating_factor_122: $i > $i).
% 28.89/28.98  tff(decl_20991, type, fn_cell_signaling_with_mating_factor_125: $i > $i).
% 28.89/28.98  tff(decl_20992, type, fn_cell_signaling_with_mating_factor_126: $i > $i).
% 28.89/28.98  tff(decl_20993, type, fn_kinase_4: $i > $i).
% 28.89/28.98  tff(decl_20994, type, fn_signal_transduction_with_phosphorylation_cascade_108: $i > $i).
% 28.89/28.98  tff(decl_20995, type, fn_signal_transduction_with_phosphorylation_cascade_47: $i > $i).
% 28.89/28.98  tff(decl_20996, type, fn_signal_transduction_with_phosphorylation_cascade_46: $i > $i).
% 28.89/28.98  tff(decl_20997, type, fn_signal_transduction_with_phosphorylation_cascade_52: $i > $i).
% 28.89/28.98  tff(decl_20998, type, fn_signal_transduction_with_phosphorylation_cascade_63: $i > $i).
% 28.89/28.98  tff(decl_20999, type, fn_signal_transduction_with_phosphorylation_cascade_90: $i > $i).
% 28.89/28.98  tff(decl_21000, type, fn_signal_transduction_with_phosphorylation_cascade_103: $i > $i).
% 28.89/28.98  tff(decl_21001, type, fn_signal_transduction_with_phosphorylation_cascade_21: $i > $i).
% 28.89/28.98  tff(decl_21002, type, fn_fungal_cell_22: $i > $i).
% 28.89/28.98  tff(decl_21003, type, fn_fungal_cell_5: $i > $i).
% 28.89/28.98  tff(decl_21004, type, fn_fungal_cell_1: $i > $i).
% 28.89/28.98  tff(decl_21005, type, fn_fungal_cell_26: $i > $i).
% 28.89/28.98  tff(decl_21006, type, fn_fungal_cell_4: $i > $i).
% 28.89/28.98  tff(decl_21007, type, fn_fungal_cell_27: $i > $i).
% 28.89/28.98  tff(decl_21008, type, fn_fungal_cell_25: $i > $i).
% 28.89/28.98  tff(decl_21009, type, fn_fungal_cell_29: $i > $i).
% 28.89/28.98  tff(decl_21010, type, fn_kinase_5: $i > $i).
% 28.89/28.98  tff(decl_21011, type, fn_kinase_6: $i > $i).
% 28.89/28.98  tff(decl_21012, type, fn_signal_transduction_with_phosphorylation_cascade_68: $i > $i).
% 28.89/28.98  tff(decl_21013, type, fn_kinase_7: $i > $i).
% 28.89/28.98  tff(decl_21014, type, fn_signal_transduction_with_phosphorylation_cascade_49: $i > $i).
% 28.89/28.98  tff(decl_21015, type, fn_signal_transduction_with_phosphorylation_cascade_53: $i > $i).
% 28.89/28.98  tff(decl_21016, type, fn_signal_transduction_with_phosphorylation_cascade_16: $i > $i).
% 28.89/28.98  tff(decl_21017, type, fn_signal_transduction_with_phosphorylation_cascade_11: $i > $i).
% 28.89/28.98  tff(decl_21018, type, fn_yeast_6: $i > $i).
% 28.89/28.98  tff(decl_21019, type, fn_fungal_cell_8: $i > $i).
% 28.89/28.98  tff(decl_21020, type, fn_yeast_3: $i > $i).
% 28.89/28.98  tff(decl_21021, type, fn_fungal_cell_6: $i > $i).
% 28.89/28.98  tff(decl_21022, type, fn_fungal_cell_19: $i > $i).
% 28.89/28.98  tff(decl_21023, type, fn_fungal_cell_3: $i > $i).
% 28.89/28.98  tff(decl_21024, type, fn_fungal_cell_21: $i > $i).
% 28.89/28.98  tff(decl_21025, type, fn_fungal_cell_24: $i > $i).
% 28.89/28.98  tff(decl_21026, type, fn_fungal_cell_17: $i > $i).
% 28.89/28.98  tff(decl_21027, type, fn_signal_transduction_with_phosphorylation_cascade_96: $i > $i).
% 28.89/28.98  tff(decl_21028, type, fn_fungal_cell_16: $i > $i).
% 28.89/28.98  tff(decl_21029, type, fn_signal_transduction_with_phosphorylation_cascade_98: $i > $i).
% 28.89/28.98  tff(decl_21030, type, fn_signal_transduction_with_phosphorylation_cascade_62: $i > $i).
% 28.89/28.98  tff(decl_21031, type, fn_signal_transduction_with_phosphorylation_cascade_55: $i > $i).
% 28.89/28.98  tff(decl_21032, type, fn_dephosphorylation_6: $i > $i).
% 28.89/28.98  tff(decl_21033, type, fn_kinase_8: $i > $i).
% 28.89/28.98  tff(decl_21034, type, fn_cell_signaling_with_mating_factor_124: $i > $i).
% 28.89/28.98  tff(decl_21035, type, fn_cell_signaling_with_mating_factor_123: $i > $i).
% 28.89/28.98  tff(decl_21036, type, fn_cell_signaling_with_mating_factor_55: $i > $i).
% 28.89/28.98  tff(decl_21037, type, fn_cell_signaling_with_g_protein_coupled_receptor_19: $i > $i).
% 28.89/28.98  tff(decl_21038, type, fn_cell_signaling_with_mating_factor_54: $i > $i).
% 28.89/28.98  tff(decl_21039, type, fn_cell_signaling_with_g_protein_coupled_receptor_20: $i > $i).
% 28.89/28.98  tff(decl_21040, type, fn_cell_signaling_with_mating_factor_42: $i > $i).
% 28.89/28.98  tff(decl_21041, type, fn_cell_signaling_with_mating_factor_43: $i > $i).
% 28.89/28.98  tff(decl_21042, type, fn_cell_signaling_with_mating_factor_23: $i > $i).
% 28.89/28.98  tff(decl_21043, type, fn_cell_signaling_with_mating_factor_21: $i > $i).
% 28.89/28.98  tff(decl_21044, type, fn_cell_signaling_with_mating_factor_20: $i > $i).
% 28.89/28.98  tff(decl_21045, type, fn_cell_signaling_with_mating_factor_22: $i > $i).
% 28.89/28.98  tff(decl_21046, type, cell_signaling_with_nitric_oxide_1: $i > $o).
% 28.89/28.98  tff(decl_21047, type, 'Cell-Signaling-With-Nitric-Oxide': $i).
% 28.89/28.98  tff(decl_21048, type, 'The process of signal reception, signal transduction and cellular response in which the receptor is located inside the cell and the signaling molecule is nitric oxide.': $i).
% 28.89/28.98  tff(decl_21049, type, 'nitric oxide induced cell signaling': $i).
% 28.89/28.98  tff(decl_21050, type, 'nitric oxide-induced cell signaling': $i).
% 28.89/28.98  tff(decl_21051, type, 'cell signaling with nitric oxide': $i).
% 28.89/28.98  tff(decl_21052, type, 'cell-signaling-with-nitric-oxide': $i).
% 28.89/28.98  tff(decl_21053, type, fn_cell_signaling_with_nitric_oxide_1: $i > $i).
% 28.89/28.98  tff(decl_21054, type, fn_cell_signaling_with_nitric_oxide_2: $i > $i).
% 28.89/28.98  tff(decl_21055, type, fn_cell_signaling_with_nitric_oxide_3: $i > $i).
% 28.89/28.98  tff(decl_21056, type, fn_cell_signaling_with_nitric_oxide_4: $i > $i).
% 28.89/28.98  tff(decl_21057, type, fn_cell_signaling_with_nitric_oxide_5: $i > $i).
% 28.89/28.98  tff(decl_21058, type, fn_cell_signaling_with_nitric_oxide_6: $i > $i).
% 28.89/28.98  tff(decl_21059, type, fn_cell_signaling_with_nitric_oxide_7: $i > $i).
% 28.89/28.98  tff(decl_21060, type, fn_cell_signaling_with_nitric_oxide_8: $i > $i).
% 28.89/28.98  tff(decl_21061, type, fn_nitric_oxide_2: $i > $i).
% 28.89/28.98  tff(decl_21062, type, fn_cell_signaling_with_nitric_oxide_9: $i > $i).
% 28.89/28.98  tff(decl_21063, type, fn_cell_signaling_with_nitric_oxide_10: $i > $i).
% 28.89/28.98  tff(decl_21064, type, cell_signaling_with_phytochrome_in_plant_cell_1: $i > $o).
% 28.89/28.98  tff(decl_21065, type, 'Cell-Signaling-With-Phytochrome-In-Plant-cell': $i).
% 28.89/28.98  tff(decl_21066, type, 'The process of signal reception, signal transduction and cellular response in plant cells in which the receptor is phytochrome.': $i).
% 28.89/28.98  tff(decl_21067, type, 'cell signaling with phytochrome in plant cell': $i).
% 28.89/28.98  tff(decl_21068, type, 'cell-signaling-with-phytochrome-in-plant-cell': $i).
% 28.89/28.98  tff(decl_21069, type, fn_cell_signaling_with_phytochrome_in_plant_cell_1: $i > $i).
% 28.89/28.98  tff(decl_21070, type, phytochrome_1: $i > $o).
% 28.89/28.98  tff(decl_21071, type, fn_cell_signaling_with_phytochrome_in_plant_cell_2: $i > $i).
% 28.89/28.98  tff(decl_21072, type, cell_signaling_with_plant_hormone_leading_to_cell_division_1: $i > $o).
% 28.89/28.98  tff(decl_21073, type, 'Cell-Signaling-With-Plant-Hormone-Leading-To-Cell-Division': $i).
% 28.89/28.98  tff(decl_21074, type, 'Process of communication between and within plant cells which leads to cell division as cellular response.': $i).
% 28.89/28.98  tff(decl_21075, type, 'cell signaling with plant hormone leading to cell division': $i).
% 28.89/28.98  tff(decl_21076, type, 'cell-signaling-with-plant-hormone-leading-to-cell-division': $i).
% 28.89/28.98  tff(decl_21077, type, fn_cell_signaling_with_plant_hormone_leading_to_cell_division_1: $i > $i).
% 28.89/28.98  tff(decl_21078, type, fn_cell_signaling_with_plant_hormone_leading_to_cell_division_2: $i > $i).
% 28.89/28.98  tff(decl_21079, type, 'Cell-Signaling-With-Plasma-Membrane-Receptor': $i).
% 28.89/28.98  tff(decl_21080, type, 'The process of signal reception, signal transduction and cellular response in which the receptor is located on the plasma membrane.': $i).
% 28.89/28.98  tff(decl_21081, type, 'cell signaling with plasma membrane receptor': $i).
% 28.89/28.98  tff(decl_21082, type, 'cell-signaling-with-plasma-membrane-receptor': $i).
% 28.89/28.98  tff(decl_21083, type, fn_cell_signaling_with_plasma_membrane_receptor_3: $i > $i).
% 28.89/28.98  tff(decl_21084, type, fn_cell_signaling_with_plasma_membrane_receptor_4: $i > $i).
% 28.89/28.98  tff(decl_21085, type, fn_cell_signaling_with_plasma_membrane_receptor_9: $i > $i).
% 28.89/28.98  tff(decl_21086, type, ligand_1: $i > $o).
% 28.89/28.98  tff(decl_21087, type, fn_cell_signaling_with_plasma_membrane_receptor_13: $i > $i).
% 28.89/28.98  tff(decl_21088, type, fn_cell_signaling_with_plasma_membrane_receptor_18: $i > $i).
% 28.89/28.98  tff(decl_21089, type, fn_ligand_1: $i > $i).
% 28.89/28.98  tff(decl_21090, type, fn_cell_signaling_with_plasma_membrane_receptor_14: $i > $i).
% 28.89/28.98  tff(decl_21091, type, cell_signaling_with_receptor_tyrosine_kinase_1: $i > $o).
% 28.89/28.98  tff(decl_21092, type, 'Cell-Signaling-With-Receptor-Tyrosine-Kinase': $i).
% 28.89/28.98  tff(decl_21093, type, 'The process of signal reception, signal transduction and cellular response in which the receptor is tyrosine kinase.': $i).
% 28.89/28.98  tff(decl_21094, type, 'cell signaling with receptor tyrosine kinase': $i).
% 28.89/28.98  tff(decl_21095, type, 'cell-signaling-with-receptor-tyrosine-kinase': $i).
% 28.89/28.98  tff(decl_21096, type, fn_cell_signaling_with_receptor_tyrosine_kinase_2: $i > $i).
% 28.89/28.98  tff(decl_21097, type, fn_cell_signaling_with_receptor_tyrosine_kinase_3: $i > $i).
% 28.89/28.98  tff(decl_21098, type, fn_cell_signaling_with_receptor_tyrosine_kinase_4: $i > $i).
% 28.89/28.98  tff(decl_21099, type, fn_cell_signaling_with_receptor_tyrosine_kinase_5: $i > $i).
% 28.89/28.98  tff(decl_21100, type, fn_cell_signaling_with_receptor_tyrosine_kinase_6: $i > $i).
% 28.89/28.98  tff(decl_21101, type, fn_cell_signaling_with_receptor_tyrosine_kinase_7: $i > $i).
% 28.89/28.98  tff(decl_21102, type, fn_cell_signaling_with_receptor_tyrosine_kinase_8: $i > $i).
% 28.89/28.98  tff(decl_21103, type, fn_cell_signaling_with_receptor_tyrosine_kinase_11: $i > $i).
% 28.89/28.98  tff(decl_21104, type, fn_cell_signaling_with_receptor_tyrosine_kinase_12: $i > $i).
% 28.89/28.98  tff(decl_21105, type, fn_cell_signaling_with_receptor_tyrosine_kinase_16: $i > $i).
% 28.89/28.98  tff(decl_21106, type, fn_cell_signaling_with_receptor_tyrosine_kinase_17: $i > $i).
% 28.89/28.98  tff(decl_21107, type, fn_cell_signaling_with_receptor_tyrosine_kinase_18: $i > $i).
% 28.89/28.98  tff(decl_21108, type, fn_cell_signaling_with_receptor_tyrosine_kinase_19: $i > $i).
% 28.89/28.98  tff(decl_21109, type, fn_cell_signaling_with_receptor_tyrosine_kinase_20: $i > $i).
% 28.89/28.98  tff(decl_21110, type, fn_cell_signaling_with_receptor_tyrosine_kinase_21: $i > $i).
% 28.89/28.98  tff(decl_21111, type, fn_cell_signaling_with_receptor_tyrosine_kinase_24: $i > $i).
% 28.89/28.98  tff(decl_21112, type, fn_cell_signaling_with_receptor_tyrosine_kinase_27: $i > $i).
% 28.89/28.98  tff(decl_21113, type, fn_cell_signaling_with_receptor_tyrosine_kinase_28: $i > $i).
% 28.89/28.98  tff(decl_21114, type, fn_cell_signaling_with_receptor_tyrosine_kinase_29: $i > $i).
% 28.89/28.98  tff(decl_21115, type, fn_cell_signaling_with_receptor_tyrosine_kinase_30: $i > $i).
% 28.89/28.98  tff(decl_21116, type, fn_cell_signaling_with_receptor_tyrosine_kinase_31: $i > $i).
% 28.89/28.98  tff(decl_21117, type, fn_cell_signaling_with_receptor_tyrosine_kinase_32: $i > $i).
% 28.89/28.98  tff(decl_21118, type, fn_cell_signaling_with_receptor_tyrosine_kinase_33: $i > $i).
% 28.89/28.98  tff(decl_21119, type, fn_cell_signaling_with_receptor_tyrosine_kinase_34: $i > $i).
% 28.89/28.98  tff(decl_21120, type, fn_cell_signaling_with_receptor_tyrosine_kinase_35: $i > $i).
% 28.89/28.98  tff(decl_21121, type, fn_cell_signaling_with_receptor_tyrosine_kinase_36: $i > $i).
% 28.89/28.98  tff(decl_21122, type, fn_cell_signaling_with_receptor_tyrosine_kinase_37: $i > $i).
% 28.89/28.98  tff(decl_21123, type, fn_cell_signaling_with_receptor_tyrosine_kinase_38: $i > $i).
% 28.89/28.98  tff(decl_21124, type, fn_cell_signaling_with_receptor_tyrosine_kinase_39: $i > $i).
% 28.89/28.98  tff(decl_21125, type, fn_cell_signaling_with_receptor_tyrosine_kinase_40: $i > $i).
% 28.89/28.98  tff(decl_21126, type, fn_cell_signaling_with_receptor_tyrosine_kinase_41: $i > $i).
% 28.89/28.98  tff(decl_21127, type, fn_cell_signaling_with_receptor_tyrosine_kinase_42: $i > $i).
% 28.89/28.98  tff(decl_21128, type, fn_cell_signaling_with_receptor_tyrosine_kinase_43: $i > $i).
% 28.89/28.98  tff(decl_21129, type, tail_region_1: $i > $o).
% 28.89/28.98  tff(decl_21130, type, fn_cell_signaling_with_receptor_tyrosine_kinase_44: $i > $i).
% 28.89/28.98  tff(decl_21131, type, fn_cell_signaling_with_receptor_tyrosine_kinase_45: $i > $i).
% 28.89/28.98  tff(decl_21132, type, fn_cell_signaling_with_receptor_tyrosine_kinase_46: $i > $i).
% 28.89/28.98  tff(decl_21133, type, fn_cell_signaling_with_receptor_tyrosine_kinase_47: $i > $i).
% 28.89/28.98  tff(decl_21134, type, fn_cell_signaling_with_receptor_tyrosine_kinase_48: $i > $i).
% 28.89/28.98  tff(decl_21135, type, fn_cell_signaling_with_receptor_tyrosine_kinase_49: $i > $i).
% 28.89/28.98  tff(decl_21136, type, fn_cell_signaling_with_receptor_tyrosine_kinase_50: $i > $i).
% 28.89/28.98  tff(decl_21137, type, fn_cell_signaling_with_receptor_tyrosine_kinase_51: $i > $i).
% 28.89/28.98  tff(decl_21138, type, fn_cell_signaling_with_receptor_tyrosine_kinase_52: $i > $i).
% 28.89/28.98  tff(decl_21139, type, fn_cell_signaling_with_receptor_tyrosine_kinase_53: $i > $i).
% 28.89/28.98  tff(decl_21140, type, fn_cell_signaling_with_receptor_tyrosine_kinase_54: $i > $i).
% 28.89/28.98  tff(decl_21141, type, fn_cell_signaling_with_receptor_tyrosine_kinase_55: $i > $i).
% 28.89/28.98  tff(decl_21142, type, fn_cell_signaling_with_receptor_tyrosine_kinase_56: $i > $i).
% 28.89/28.98  tff(decl_21143, type, fn_cell_signaling_with_receptor_tyrosine_kinase_57: $i > $i).
% 28.89/28.98  tff(decl_21144, type, fn_cell_signaling_with_receptor_tyrosine_kinase_58: $i > $i).
% 28.89/28.98  tff(decl_21145, type, fn_cell_signaling_with_receptor_tyrosine_kinase_59: $i > $i).
% 28.89/28.98  tff(decl_21146, type, fn_cell_signaling_with_receptor_tyrosine_kinase_60: $i > $i).
% 28.89/28.98  tff(decl_21147, type, fn_cell_signaling_with_receptor_tyrosine_kinase_61: $i > $i).
% 28.89/28.98  tff(decl_21148, type, fn_cell_signaling_with_receptor_tyrosine_kinase_62: $i > $i).
% 28.89/28.98  tff(decl_21149, type, fn_cell_signaling_with_receptor_tyrosine_kinase_63: $i > $i).
% 28.89/28.98  tff(decl_21150, type, fn_cell_signaling_with_receptor_tyrosine_kinase_64: $i > $i).
% 28.89/28.98  tff(decl_21151, type, fn_cell_signaling_with_receptor_tyrosine_kinase_65: $i > $i).
% 28.89/28.98  tff(decl_21152, type, fn_cell_signaling_with_receptor_tyrosine_kinase_66: $i > $i).
% 28.89/28.98  tff(decl_21153, type, fn_cell_signaling_with_receptor_tyrosine_kinase_67: $i > $i).
% 28.89/28.98  tff(decl_21154, type, fn_cell_signaling_with_receptor_tyrosine_kinase_68: $i > $i).
% 28.89/28.98  tff(decl_21155, type, fn_cell_signaling_with_receptor_tyrosine_kinase_69: $i > $i).
% 28.89/28.98  tff(decl_21156, type, fn_cell_signaling_with_receptor_tyrosine_kinase_70: $i > $i).
% 28.89/28.98  tff(decl_21157, type, fn_cell_signaling_with_receptor_tyrosine_kinase_71: $i > $i).
% 28.89/28.98  tff(decl_21158, type, fn_cell_signaling_with_receptor_tyrosine_kinase_72: $i > $i).
% 28.89/28.98  tff(decl_21159, type, fn_cell_signaling_with_receptor_tyrosine_kinase_73: $i > $i).
% 28.89/28.98  tff(decl_21160, type, fn_cell_signaling_with_receptor_tyrosine_kinase_74: $i > $i).
% 28.89/28.98  tff(decl_21161, type, fn_cell_signaling_with_receptor_tyrosine_kinase_77: $i > $i).
% 28.89/28.98  tff(decl_21162, type, fn_cell_signaling_with_receptor_tyrosine_kinase_78: $i > $i).
% 28.89/28.98  tff(decl_21163, type, fn_cell_signaling_with_receptor_tyrosine_kinase_79: $i > $i).
% 28.89/28.98  tff(decl_21164, type, fn_cell_signaling_with_receptor_tyrosine_kinase_80: $i > $i).
% 28.89/28.98  tff(decl_21165, type, fn_cell_signaling_with_receptor_tyrosine_kinase_81: $i > $i).
% 28.89/28.98  tff(decl_21166, type, fn_cell_signaling_with_receptor_tyrosine_kinase_82: $i > $i).
% 28.89/28.98  tff(decl_21167, type, fn_cell_signaling_with_receptor_tyrosine_kinase_83: $i > $i).
% 28.89/28.98  tff(decl_21168, type, fn_cell_signaling_with_receptor_tyrosine_kinase_84: $i > $i).
% 28.89/28.98  tff(decl_21169, type, fn_cell_signaling_with_receptor_tyrosine_kinase_85: $i > $i).
% 28.89/28.98  tff(decl_21170, type, fn_cell_signaling_with_receptor_tyrosine_kinase_86: $i > $i).
% 28.89/28.98  tff(decl_21171, type, fn_cell_signaling_with_receptor_tyrosine_kinase_87: $i > $i).
% 28.89/28.98  tff(decl_21172, type, fn_cell_signaling_with_receptor_tyrosine_kinase_88: $i > $i).
% 28.89/28.98  tff(decl_21173, type, fn_cell_signaling_with_receptor_tyrosine_kinase_92: $i > $i).
% 28.89/28.98  tff(decl_21174, type, fn_receptor_tyrosine_kinase_3: $i > $i).
% 28.89/28.98  tff(decl_21175, type, fn_receptor_tyrosine_kinase_4: $i > $i).
% 28.89/28.98  tff(decl_21176, type, fn_plasma_membrane_12: $i > $i).
% 28.89/28.98  tff(decl_21177, type, fn_plasma_membrane_11: $i > $i).
% 28.89/28.98  tff(decl_21178, type, phosphorus_0: $i).
% 28.89/28.98  tff(decl_21179, type, signal_transduction_0: $i).
% 28.89/28.98  tff(decl_21180, type, agent_0: $i).
% 28.89/28.98  tff(decl_21181, type, fn_cell_signaling_with_receptor_tyrosine_kinase_91: $i > $i).
% 28.89/28.98  tff(decl_21182, type, fn_cell_signaling_with_receptor_tyrosine_kinase_75: $i > $i).
% 28.89/28.98  tff(decl_21183, type, fn_cell_signaling_with_receptor_tyrosine_kinase_76: $i > $i).
% 28.89/28.98  tff(decl_21184, type, fn_cell_signaling_with_receptor_tyrosine_kinase_89: $i > $i).
% 28.89/28.98  tff(decl_21185, type, fn_cell_signaling_with_receptor_tyrosine_kinase_90: $i > $i).
% 28.89/28.98  tff(decl_21186, type, fn_cell_signaling_with_receptor_tyrosine_kinase_25: $i > $i).
% 28.89/28.98  tff(decl_21187, type, fn_cell_signaling_with_receptor_tyrosine_kinase_26: $i > $i).
% 28.89/28.98  tff(decl_21188, type, cell_signaling_with_serine_threonine_kinase_1: $i > $o).
% 28.89/28.98  tff(decl_21189, type, 'Cell-Signaling-With-Serine-Threonine-Kinase': $i).
% 28.89/28.98  tff(decl_21190, type, 'Cell signaling which involves the activation of proteins through the phosphorylation of serine or threonine amino acids by serine-threonine kinase.': $i).
% 28.89/28.98  tff(decl_21191, type, 'cell signaling with serine threonine kinase': $i).
% 28.89/28.98  tff(decl_21192, type, 'cell-signaling-with-serine-threonine-kinase': $i).
% 28.89/28.98  tff(decl_21193, type, fn_cell_signaling_with_serine_threonine_kinase_1: $i > $i).
% 28.89/28.98  tff(decl_21194, type, fn_cell_signaling_with_serine_threonine_kinase_2: $i > $i).
% 28.89/28.98  tff(decl_21195, type, fn_cell_signaling_with_serine_threonine_kinase_3: $i > $i).
% 28.89/28.98  tff(decl_21196, type, fn_cell_signaling_with_serine_threonine_kinase_4: $i > $i).
% 28.89/28.98  tff(decl_21197, type, fn_cell_signaling_with_serine_threonine_kinase_5: $i > $i).
% 28.89/28.98  tff(decl_21198, type, serine_threonine_kinase_1: $i > $o).
% 28.89/28.98  tff(decl_21199, type, fn_cell_signaling_with_serine_threonine_kinase_6: $i > $i).
% 28.89/28.98  tff(decl_21200, type, fn_cell_signaling_with_serine_threonine_kinase_7: $i > $i).
% 28.89/28.98  tff(decl_21201, type, cell_signaling_with_serine_threonine_kinase_in_animal_cell_1: $i > $o).
% 28.89/28.98  tff(decl_21202, type, 'Cell-Signaling-With-Serine-Threonine-Kinase-In-Animal-Cell': $i).
% 28.89/28.98  tff(decl_21203, type, 'In animal cells, cell signaling which involves the activation of proteins through the phosphorylation of serine or threonine amino acids by serine-threonine kinase.': $i).
% 28.89/28.98  tff(decl_21204, type, 'cell signaling with serine threonine kinase in animal cell': $i).
% 28.89/28.98  tff(decl_21205, type, 'cell-signaling-with-serine-threonine-kinase-in-animal-cell': $i).
% 28.89/28.98  tff(decl_21206, type, fn_cell_signaling_with_serine_threonine_kinase_in_animal_cell_1: $i > $i).
% 28.89/28.98  tff(decl_21207, type, fn_cell_signaling_with_serine_threonine_kinase_in_animal_cell_2: $i > $i).
% 28.89/28.98  tff(decl_21208, type, cell_signaling_with_serine_threonine_kinase_in_fungal_cell_1: $i > $o).
% 28.89/28.98  tff(decl_21209, type, 'Cell-Signaling-With-Serine-Threonine-Kinase-In-Fungal-cell': $i).
% 28.89/28.98  tff(decl_21210, type, 'In fungal cells, cell signaling which involves the activation of proteins through the phosphorylation of serine or threonine amino acids by serine-threonine kinase.': $i).
% 28.89/28.98  tff(decl_21211, type, 'cell signaling with serine threonine kinase in fungal cell': $i).
% 28.89/28.98  tff(decl_21212, type, 'cell-signaling-with-serine-threonine-kinase-in-fungal-cell': $i).
% 28.89/28.98  tff(decl_21213, type, fn_cell_signaling_with_serine_threonine_kinase_in_fungal_cell_1: $i > $i).
% 28.89/28.98  tff(decl_21214, type, fn_cell_signaling_with_serine_threonine_kinase_in_fungal_cell_2: $i > $i).
% 28.89/28.98  tff(decl_21215, type, cell_signaling_with_serine_threonine_kinase_in_plant_cell_1: $i > $o).
% 28.89/28.98  tff(decl_21216, type, 'Cell-Signaling-With-Serine-Threonine-Kinase-In-Plant-Cell': $i).
% 28.89/28.98  tff(decl_21217, type, 'In plant cells, cell signaling which involves the activation of proteins through the phosphorylation of serine or threonine amino acids by serine-threonine kinase.': $i).
% 28.89/28.98  tff(decl_21218, type, 'cell signaling with serine threonine kinase in plant cell': $i).
% 28.89/28.98  tff(decl_21219, type, 'cell-signaling-with-serine-threonine-kinase-in-plant-cell': $i).
% 28.89/28.98  tff(decl_21220, type, fn_cell_signaling_with_serine_threonine_kinase_in_plant_cell_1: $i > $i).
% 28.89/28.98  tff(decl_21221, type, fn_cell_signaling_with_serine_threonine_kinase_in_plant_cell_2: $i > $i).
% 28.89/28.98  tff(decl_21222, type, cell_signaling_with_signal_amplification_1: $i > $o).
% 28.89/28.98  tff(decl_21223, type, 'Cell-Signaling-With-Signal-Amplification': $i).
% 28.89/28.98  tff(decl_21224, type, 'The process of signal reception, signal transduction and cellular response in which a series of amplification events greatly increase the resulting cellular response.': $i).
% 28.89/28.98  tff(decl_21225, type, 'cell signaling with signal amplification': $i).
% 28.89/28.98  tff(decl_21226, type, 'cell-signaling-with-signal-amplification': $i).
% 28.89/28.98  tff(decl_21227, type, fn_cell_signaling_with_signal_amplification_1: $i > $i).
% 28.89/28.98  tff(decl_21228, type, fn_cell_signaling_with_signal_amplification_4: $i > $i).
% 28.89/28.98  tff(decl_21229, type, fn_cell_signaling_with_signal_amplification_5: $i > $i).
% 28.89/28.98  tff(decl_21230, type, fn_cell_signaling_with_signal_amplification_6: $i > $i).
% 28.89/28.98  tff(decl_21231, type, signal_amplification_1: $i > $o).
% 28.89/28.98  tff(decl_21232, type, fn_cell_signaling_with_signal_amplification_7: $i > $i).
% 28.89/28.98  tff(decl_21233, type, fn_cell_signaling_with_signal_amplification_8: $i > $i).
% 28.89/28.98  tff(decl_21234, type, fn_signal_amplification_7: $i > $i).
% 28.89/28.98  tff(decl_21235, type, fn_signal_amplification_4: $i > $i).
% 28.89/28.98  tff(decl_21236, type, fn_signal_amplification_5: $i > $i).
% 28.89/28.98  tff(decl_21237, type, fn_cell_signaling_with_signal_amplification_3: $i > $i).
% 28.89/28.98  tff(decl_21238, type, cell_signaling_with_sodium_ion_1: $i > $o).
% 28.89/28.98  tff(decl_21239, type, 'Cell-Signaling-With-Sodium-Ion': $i).
% 28.89/28.98  tff(decl_21240, type, 'Process of signaling between and within cells which uses sodum ions as second messengers during signal transduction.': $i).
% 28.89/28.98  tff(decl_21241, type, 'cell signaling with sodium ion': $i).
% 28.89/28.98  tff(decl_21242, type, 'cell-signaling-with-sodium-ion': $i).
% 28.89/28.98  tff(decl_21243, type, fn_cell_signaling_with_sodium_ion_1: $i > $i).
% 28.89/28.98  tff(decl_21244, type, fn_cell_signaling_with_sodium_ion_2: $i > $i).
% 28.89/28.98  tff(decl_21245, type, fn_cell_signaling_with_sodium_ion_3: $i > $i).
% 28.89/28.98  tff(decl_21246, type, fn_cell_signaling_with_sodium_ion_4: $i > $i).
% 28.89/28.98  tff(decl_21247, type, fn_cell_signaling_with_sodium_ion_5: $i > $i).
% 28.89/28.98  tff(decl_21248, type, fn_cell_signaling_with_sodium_ion_6: $i > $i).
% 28.89/28.98  tff(decl_21249, type, fn_cell_signaling_with_sodium_ion_7: $i > $i).
% 28.89/28.98  tff(decl_21250, type, fn_cell_signaling_with_sodium_ion_8: $i > $i).
% 28.89/28.98  tff(decl_21251, type, fn_cell_signaling_with_sodium_ion_9: $i > $i).
% 28.89/28.98  tff(decl_21252, type, fn_cell_signaling_with_sodium_ion_10: $i > $i).
% 28.89/28.98  tff(decl_21253, type, fn_cell_signaling_with_sodium_ion_11: $i > $i).
% 28.89/28.98  tff(decl_21254, type, fn_cell_signaling_with_sodium_ion_12: $i > $i).
% 28.89/28.98  tff(decl_21255, type, fn_cell_signaling_with_sodium_ion_13: $i > $i).
% 28.89/28.98  tff(decl_21256, type, fn_cell_signaling_with_sodium_ion_14: $i > $i).
% 28.89/28.98  tff(decl_21257, type, fn_cell_signaling_with_sodium_ion_15: $i > $i).
% 28.89/28.98  tff(decl_21258, type, fn_cell_signaling_with_sodium_ion_16: $i > $i).
% 28.89/28.98  tff(decl_21259, type, cell_signaling_with_was_protein_1: $i > $o).
% 28.89/28.98  tff(decl_21260, type, 'Cell-Signaling-With-WAS-Protein': $i).
% 28.89/28.98  tff(decl_21261, type, 'The process of signal reception, signal transduction and cellular response in which WAS protein organizes the cytoskeleton so that the signal can be properly transducted.': $i).
% 28.89/28.98  tff(decl_21262, type, 'cell signaling with was protein': $i).
% 28.89/28.98  tff(decl_21263, type, 'cell-signaling-with-was-protein': $i).
% 28.89/28.98  tff(decl_21264, type, fn_cell_signaling_with_was_protein_1: $i > $i).
% 28.89/28.98  tff(decl_21265, type, fn_cell_signaling_with_was_protein_2: $i > $i).
% 28.89/28.98  tff(decl_21266, type, microfilament_1: $i > $o).
% 28.89/28.98  tff(decl_21267, type, fn_cell_signaling_with_was_protein_3: $i > $i).
% 28.89/28.98  tff(decl_21268, type, fn_cell_signaling_with_was_protein_4: $i > $i).
% 28.89/28.98  tff(decl_21269, type, fn_cell_signaling_with_was_protein_5: $i > $i).
% 28.89/28.98  tff(decl_21270, type, fn_cell_signaling_with_was_protein_6: $i > $i).
% 28.89/28.98  tff(decl_21271, type, was_protein_1: $i > $o).
% 28.89/28.98  tff(decl_21272, type, fn_cell_signaling_with_was_protein_7: $i > $i).
% 28.89/28.98  tff(decl_21273, type, fn_cell_signaling_with_was_protein_8: $i > $i).
% 28.89/28.98  tff(decl_21274, type, fn_cytoskeleton_2: $i > $i).
% 28.89/28.98  tff(decl_21275, type, 'Cell-State': $i).
% 28.89/28.98  tff(decl_21276, type, 'Cell states are specialized functions, properties, traits or abilities that cells have.': $i).
% 28.89/28.98  tff(decl_21277, type, 'state of cell': $i).
% 28.89/28.98  tff(decl_21278, type, 'state-of-cell': $i).
% 28.89/28.98  tff(decl_21279, type, 'cell state': $i).
% 28.89/28.98  tff(decl_21280, type, 'cell-state': $i).
% 28.89/28.98  tff(decl_21281, type, 'Cell-Surface-Receptor': $i).
% 28.89/28.98  tff(decl_21282, type, 'Receptor in cell signalling events which spans the plasma membrane.': $i).
% 28.89/28.98  tff(decl_21283, type, 'cell surface transmembrane receptor': $i).
% 28.89/28.98  tff(decl_21284, type, 'cell surface receptor': $i).
% 28.89/28.98  tff(decl_21285, type, 'cell-surface-receptor': $i).
% 28.89/28.98  tff(decl_21286, type, 'Cell-Survival': $i).
% 28.89/28.98  tff(decl_21287, type, 'Osmoregulation supports cell survival.': $i).
% 28.89/28.98  tff(decl_21288, type, survive: $i).
% 28.89/28.98  tff(decl_21289, type, 'survival of cell': $i).
% 28.89/28.98  tff(decl_21290, type, 'cell survival': $i).
% 28.89/28.98  tff(decl_21291, type, 'cell-survival': $i).
% 28.89/28.98  tff(decl_21292, type, fn_cell_survival_1: $i > $i).
% 28.89/28.98  tff(decl_21293, type, 'Cell-Wall': $i).
% 28.89/28.98  tff(decl_21294, type, 'A protective layer, external to the plasma membrane, found in plants, fungi, prokaryotes, and some unicellular protists. Cell walls are made from a variety of materials, including cellulose (in plants), peptidoglycan (in bacteria), chitin (fungi), and silica (diatoms).': $i).
% 28.89/28.98  tff(decl_21295, type, 'wall of cell': $i).
% 28.89/28.98  tff(decl_21296, type, 'cell wall': $i).
% 28.89/28.98  tff(decl_21297, type, 'cell-wall': $i).
% 28.89/28.98  tff(decl_21298, type, fn_cell_wall_2: $i > $i).
% 28.89/28.98  tff(decl_21299, type, fn_cell_wall_4: $i > $i).
% 28.89/28.98  tff(decl_21300, type, fn_cell_wall_5: $i > $i).
% 28.89/28.98  tff(decl_21301, type, fn_cell_wall_6: $i > $i).
% 28.89/28.98  tff(decl_21302, type, fn_cell_wall_7: $i > $i).
% 28.89/28.98  tff(decl_21303, type, fn_cell_wall_8: $i > $i).
% 28.89/28.98  tff(decl_21304, type, fn_cell_wall_9: $i > $i).
% 28.89/28.98  tff(decl_21305, type, fn_cell_wall_11: $i > $i).
% 28.89/28.98  tff(decl_21306, type, fn_cell_wall_12: $i > $i).
% 28.89/28.98  tff(decl_21307, type, fn_cell_wall_14: $i > $i).
% 28.89/28.98  tff(decl_21308, type, fn_cell_wall_16: $i > $i).
% 28.89/28.98  tff(decl_21309, type, cell_wall_material_1: $i > $o).
% 28.89/28.98  tff(decl_21310, type, 'Cell-Wall-Material': $i).
% 28.89/28.98  tff(decl_21311, type, 'It is the building material of cell wall.': $i).
% 28.89/28.98  tff(decl_21312, type, 'building material of cell wall': $i).
% 28.89/28.98  tff(decl_21313, type, 'material of cell wall': $i).
% 28.89/28.98  tff(decl_21314, type, 'cell wall material': $i).
% 28.89/28.98  tff(decl_21315, type, 'cell-wall-material': $i).
% 28.89/28.98  tff(decl_21316, type, 'Cell-Without-Cell-Wall': $i).
% 28.89/28.98  tff(decl_21317, type, 'A cell that does not have a cell wall.': $i).
% 28.89/28.98  tff(decl_21318, type, 'wall less cell': $i).
% 28.89/28.98  tff(decl_21319, type, 'wall-less-cell': $i).
% 28.89/28.98  tff(decl_21320, type, 'cell without cell wall': $i).
% 28.89/28.98  tff(decl_21321, type, 'cell without cell-wall': $i).
% 28.89/28.98  tff(decl_21322, type, 'cell-without-cell-wall': $i).
% 28.89/28.98  tff(decl_21323, type, 'Cell-Without-Cell-Wall-Inside-Hypertonic-Solution': $i).
% 28.89/28.98  tff(decl_21324, type, 'This is a condition in which a non walled cell is placed inside hypertonic solution': $i).
% 28.89/28.98  tff(decl_21325, type, 'cell without cell wall inside hypertonic solution': $i).
% 28.89/28.98  tff(decl_21326, type, 'cell without cell-wall inside hypertonic solution': $i).
% 28.89/28.98  tff(decl_21327, type, 'cell-without-cell-wall-inside-hypertonic-solution': $i).
% 28.89/28.98  tff(decl_21328, type, fn_cell_without_cell_wall_inside_hypertonic_solution_1: $i > $i).
% 28.89/28.98  tff(decl_21329, type, fn_cell_without_cell_wall_inside_hypertonic_solution_2: $i > $i).
% 28.89/28.98  tff(decl_21330, type, fn_cell_without_cell_wall_inside_hypertonic_solution_3: $i > $i).
% 28.89/28.98  tff(decl_21331, type, fn_cell_without_cell_wall_inside_hypertonic_solution_4: $i > $i).
% 28.89/28.98  tff(decl_21332, type, fn_cell_without_cell_wall_inside_hypertonic_solution_5: $i > $i).
% 28.89/28.98  tff(decl_21333, type, fn_cell_without_cell_wall_inside_hypertonic_solution_6: $i > $i).
% 28.89/28.98  tff(decl_21334, type, fn_cell_without_cell_wall_inside_hypertonic_solution_8: $i > $i).
% 28.89/28.98  tff(decl_21335, type, fn_cell_without_cell_wall_inside_hypertonic_solution_9: $i > $i).
% 28.89/28.98  tff(decl_21336, type, fn_cell_without_cell_wall_inside_hypertonic_solution_10: $i > $i).
% 28.89/28.98  tff(decl_21337, type, fn_cell_without_cell_wall_inside_hypertonic_solution_11: $i > $i).
% 28.89/28.98  tff(decl_21338, type, fn_cell_without_cell_wall_inside_hypertonic_solution_12: $i > $i).
% 28.89/28.98  tff(decl_21339, type, fn_cell_without_cell_wall_inside_hypertonic_solution_13: $i > $i).
% 28.89/28.98  tff(decl_21340, type, fn_cell_without_cell_wall_inside_hypertonic_solution_14: $i > $i).
% 28.89/28.98  tff(decl_21341, type, fn_cell_without_cell_wall_inside_hypertonic_solution_15: $i > $i).
% 28.89/28.98  tff(decl_21342, type, fn_cell_without_cell_wall_inside_hypertonic_solution_16: $i > $i).
% 28.89/28.98  tff(decl_21343, type, fn_cell_without_cell_wall_inside_hypertonic_solution_17: $i > $i).
% 28.89/28.98  tff(decl_21344, type, fn_cell_without_cell_wall_inside_hypertonic_solution_18: $i > $i).
% 28.89/28.98  tff(decl_21345, type, fn_cell_without_cell_wall_inside_hypertonic_solution_19: $i > $i).
% 28.89/28.98  tff(decl_21346, type, fn_cell_without_cell_wall_inside_hypertonic_solution_20: $i > $i).
% 28.89/28.98  tff(decl_21347, type, fn_cell_without_cell_wall_inside_hypertonic_solution_21: $i > $i).
% 28.89/28.98  tff(decl_21348, type, fn_cell_without_cell_wall_inside_hypertonic_solution_22: $i > $i).
% 28.89/28.98  tff(decl_21349, type, fn_cell_without_cell_wall_inside_hypertonic_solution_23: $i > $i).
% 28.89/28.98  tff(decl_21350, type, fn_cell_without_cell_wall_inside_hypertonic_solution_24: $i > $i).
% 28.89/28.98  tff(decl_21351, type, fn_cell_without_cell_wall_inside_hypertonic_solution_25: $i > $i).
% 28.89/28.98  tff(decl_21352, type, fn_hypotonic_solution_8: $i > $i).
% 28.89/28.98  tff(decl_21353, type, fn_hypotonic_solution_6: $i > $i).
% 28.89/28.98  tff(decl_21354, type, fn_cell_without_cell_wall_inside_hypertonic_solution_26: $i > $i).
% 28.89/28.98  tff(decl_21355, type, fn_cell_without_cell_wall_inside_hypertonic_solution_27: $i > $i).
% 28.89/28.98  tff(decl_21356, type, fn_cell_without_cell_wall_inside_hypertonic_solution_7: $i > $i).
% 28.89/28.98  tff(decl_21357, type, 'Cell-Without-Cell-Wall-Inside-Hypotonic-Solution': $i).
% 28.89/28.98  tff(decl_21358, type, 'This is the condition in which the unwalled cell is placed inside hypotonic solution': $i).
% 28.89/28.98  tff(decl_21359, type, 'cell without cell wall inside hypotonic solution': $i).
% 28.89/28.98  tff(decl_21360, type, 'cell without cell-wall inside hypotonic solution': $i).
% 28.89/28.98  tff(decl_21361, type, 'cell-without-cell-wall-inside-hypotonic-solution': $i).
% 28.89/28.98  tff(decl_21362, type, fn_cell_without_cell_wall_inside_hypotonic_solution_1: $i > $i).
% 28.89/28.98  tff(decl_21363, type, fn_cell_without_cell_wall_inside_hypotonic_solution_2: $i > $i).
% 28.89/28.98  tff(decl_21364, type, fn_cell_without_cell_wall_inside_hypotonic_solution_3: $i > $i).
% 28.89/28.98  tff(decl_21365, type, fn_cell_without_cell_wall_inside_hypotonic_solution_4: $i > $i).
% 28.89/28.98  tff(decl_21366, type, fn_cell_without_cell_wall_inside_hypotonic_solution_5: $i > $i).
% 28.89/28.98  tff(decl_21367, type, fn_cell_without_cell_wall_inside_hypotonic_solution_6: $i > $i).
% 28.89/28.98  tff(decl_21368, type, fn_cell_without_cell_wall_inside_hypotonic_solution_7: $i > $i).
% 28.89/28.98  tff(decl_21369, type, fn_cell_without_cell_wall_inside_hypotonic_solution_8: $i > $i).
% 28.89/28.98  tff(decl_21370, type, fn_cell_without_cell_wall_inside_hypotonic_solution_11: $i > $i).
% 28.89/28.98  tff(decl_21371, type, fn_cell_without_cell_wall_inside_hypotonic_solution_12: $i > $i).
% 28.89/28.98  tff(decl_21372, type, fn_cell_without_cell_wall_inside_hypotonic_solution_13: $i > $i).
% 28.89/28.98  tff(decl_21373, type, fn_cell_without_cell_wall_inside_hypotonic_solution_14: $i > $i).
% 28.89/28.98  tff(decl_21374, type, fn_cell_without_cell_wall_inside_hypotonic_solution_15: $i > $i).
% 28.89/28.98  tff(decl_21375, type, fn_cell_without_cell_wall_inside_hypotonic_solution_16: $i > $i).
% 28.89/28.98  tff(decl_21376, type, fn_cell_without_cell_wall_inside_hypotonic_solution_17: $i > $i).
% 28.89/28.98  tff(decl_21377, type, fn_cell_without_cell_wall_inside_hypotonic_solution_18: $i > $i).
% 28.89/28.98  tff(decl_21378, type, fn_cell_without_cell_wall_inside_hypotonic_solution_19: $i > $i).
% 28.89/28.98  tff(decl_21379, type, fn_cell_without_cell_wall_inside_hypotonic_solution_20: $i > $i).
% 28.89/28.98  tff(decl_21380, type, fn_cell_without_cell_wall_inside_hypotonic_solution_21: $i > $i).
% 28.89/28.98  tff(decl_21381, type, fn_cell_without_cell_wall_inside_hypotonic_solution_22: $i > $i).
% 28.89/28.98  tff(decl_21382, type, fn_cell_without_cell_wall_inside_hypotonic_solution_23: $i > $i).
% 28.89/28.98  tff(decl_21383, type, fn_cell_without_cell_wall_inside_hypotonic_solution_24: $i > $i).
% 28.89/28.98  tff(decl_21384, type, fn_cell_without_cell_wall_inside_hypotonic_solution_25: $i > $i).
% 28.89/28.98  tff(decl_21385, type, fn_cell_without_cell_wall_inside_hypotonic_solution_26: $i > $i).
% 28.89/28.98  tff(decl_21386, type, fn_cell_without_cell_wall_inside_hypotonic_solution_27: $i > $i).
% 28.89/28.98  tff(decl_21387, type, fn_cell_without_cell_wall_inside_hypotonic_solution_28: $i > $i).
% 28.89/28.98  tff(decl_21388, type, fn_cell_without_cell_wall_inside_hypotonic_solution_29: $i > $i).
% 28.89/28.98  tff(decl_21389, type, fn_cell_without_cell_wall_inside_hypotonic_solution_31: $i > $i).
% 28.89/28.98  tff(decl_21390, type, fn_cell_without_cell_wall_inside_hypotonic_solution_32: $i > $i).
% 28.89/28.98  tff(decl_21391, type, fn_cell_without_cell_wall_inside_hypotonic_solution_33: $i > $i).
% 28.89/28.98  tff(decl_21392, type, fn_cell_without_cell_wall_inside_hypotonic_solution_34: $i > $i).
% 28.89/28.98  tff(decl_21393, type, fn_cell_without_cell_wall_inside_hypotonic_solution_35: $i > $i).
% 28.89/28.98  tff(decl_21394, type, fn_expand_1: $i > $i).
% 28.89/28.98  tff(decl_21395, type, fn_cell_without_cell_wall_inside_hypotonic_solution_10: $i > $i).
% 28.89/28.98  tff(decl_21396, type, fn_cell_without_cell_wall_inside_hypotonic_solution_9: $i > $i).
% 28.89/28.98  tff(decl_21397, type, 'Cell-Without-Cell-Wall-Inside-Isotonic-Solution': $i).
% 28.89/28.98  tff(decl_21398, type, 'This is a situation in which in the unwalled cell is placed inside isotonic solution.': $i).
% 28.89/28.98  tff(decl_21399, type, 'cell without cell wall inside isotonic solution': $i).
% 28.89/28.98  tff(decl_21400, type, 'cell without cell-wall inside isotonic solution': $i).
% 28.89/28.98  tff(decl_21401, type, 'cell-without-cell-wall-inside-isotonic-solution': $i).
% 28.89/28.98  tff(decl_21402, type, fn_cell_without_cell_wall_inside_isotonic_solution_3: $i > $i).
% 28.89/28.98  tff(decl_21403, type, fn_cell_without_cell_wall_inside_isotonic_solution_4: $i > $i).
% 28.89/28.98  tff(decl_21404, type, fn_cell_without_cell_wall_inside_isotonic_solution_5: $i > $i).
% 28.89/28.98  tff(decl_21405, type, fn_cell_without_cell_wall_inside_isotonic_solution_6: $i > $i).
% 28.89/28.98  tff(decl_21406, type, fn_cell_without_cell_wall_inside_isotonic_solution_7: $i > $i).
% 28.89/28.98  tff(decl_21407, type, fn_cell_without_cell_wall_inside_isotonic_solution_8: $i > $i).
% 28.89/28.98  tff(decl_21408, type, fn_cell_without_cell_wall_inside_isotonic_solution_9: $i > $i).
% 28.89/28.98  tff(decl_21409, type, fn_cell_without_cell_wall_inside_isotonic_solution_10: $i > $i).
% 28.89/28.98  tff(decl_21410, type, fn_cell_without_cell_wall_inside_isotonic_solution_11: $i > $i).
% 28.89/28.98  tff(decl_21411, type, fn_cell_without_cell_wall_inside_isotonic_solution_12: $i > $i).
% 28.89/28.98  tff(decl_21412, type, fn_cell_without_cell_wall_inside_isotonic_solution_13: $i > $i).
% 28.89/28.98  tff(decl_21413, type, fn_cell_without_cell_wall_inside_isotonic_solution_14: $i > $i).
% 28.89/28.98  tff(decl_21414, type, fn_cell_without_cell_wall_inside_isotonic_solution_15: $i > $i).
% 28.89/28.98  tff(decl_21415, type, fn_cell_without_cell_wall_inside_isotonic_solution_16: $i > $i).
% 28.89/28.98  tff(decl_21416, type, fn_cell_without_cell_wall_inside_isotonic_solution_17: $i > $i).
% 28.89/28.98  tff(decl_21417, type, fn_cell_without_cell_wall_inside_isotonic_solution_18: $i > $i).
% 28.89/28.98  tff(decl_21418, type, fn_cell_without_cell_wall_inside_isotonic_solution_19: $i > $i).
% 28.89/28.98  tff(decl_21419, type, fn_cell_without_cell_wall_inside_isotonic_solution_20: $i > $i).
% 28.89/28.98  tff(decl_21420, type, fn_cell_without_cell_wall_inside_isotonic_solution_21: $i > $i).
% 28.89/28.98  tff(decl_21421, type, fn_cell_without_cell_wall_inside_isotonic_solution_22: $i > $i).
% 28.89/28.98  tff(decl_21422, type, fn_cell_without_cell_wall_inside_isotonic_solution_23: $i > $i).
% 28.89/28.98  tff(decl_21423, type, cellular_cloning_1: $i > $o).
% 28.89/28.98  tff(decl_21424, type, 'Cellular-Cloning': $i).
% 28.89/28.98  tff(decl_21425, type, 'Cloning a cell means to derive a population of cells from a single cell.': $i).
% 28.89/28.98  tff(decl_21426, type, clone: $i).
% 28.89/28.98  tff(decl_21427, type, 'cellular cloning': $i).
% 28.89/28.98  tff(decl_21428, type, 'cellular-cloning': $i).
% 28.89/28.98  tff(decl_21429, type, fn_cellular_cloning_1: $i > $i).
% 28.89/28.98  tff(decl_21430, type, fn_clone_2: $i > $i).
% 28.89/28.98  tff(decl_21431, type, cellular_fluid_1: $i > $o).
% 28.89/28.98  tff(decl_21432, type, 'Cellular-Fluid': $i).
% 28.89/28.98  tff(decl_21433, type, 'Fluid or semi-fluid components of the interior of cells and cellular organelles.': $i).
% 28.89/28.98  tff(decl_21434, type, 'cellular fluid': $i).
% 28.89/28.98  tff(decl_21435, type, 'cellular-fluid': $i).
% 28.89/28.98  tff(decl_21436, type, fn_cellular_fluid_1: $i > $i).
% 28.89/28.98  tff(decl_21437, type, fn_cellular_fluid_2: $i > $i).
% 28.89/28.98  tff(decl_21438, type, cellular_movement_1: $i > $o).
% 28.89/28.98  tff(decl_21439, type, 'Cellular-Movement': $i).
% 28.89/28.98  tff(decl_21440, type, 'Cell movement refers to all types of movement at the cellular level e.g Cellular locomotion.': $i).
% 28.89/28.98  tff(decl_21441, type, 'cell motility': $i).
% 28.89/28.98  tff(decl_21442, type, 'cell movement': $i).
% 28.89/28.98  tff(decl_21443, type, 'cellular movement': $i).
% 28.89/28.98  tff(decl_21444, type, 'cellular-movement': $i).
% 28.89/28.98  tff(decl_21445, type, fn_cellular_movement_1: $i > $i).
% 28.89/28.98  tff(decl_21446, type, fiber_1: $i > $o).
% 28.89/28.98  tff(decl_21447, type, fn_cellular_movement_2: $i > $i).
% 28.89/28.98  tff(decl_21448, type, fn_cellular_movement_3: $i > $i).
% 28.89/28.98  tff(decl_21449, type, fn_cellular_movement_4: $i > $i).
% 28.89/28.98  tff(decl_21450, type, fn_cellular_movement_5: $i > $i).
% 28.89/28.98  tff(decl_21451, type, fn_cellular_movement_6: $i > $i).
% 28.89/28.98  tff(decl_21452, type, fn_cellular_movement_7: $i > $i).
% 28.89/28.98  tff(decl_21453, type, fn_cellular_movement_8: $i > $i).
% 28.89/28.98  tff(decl_21454, type, cellular_potency_1: $i > $o).
% 28.89/28.98  tff(decl_21455, type, 'Cellular-Potency': $i).
% 28.89/28.98  tff(decl_21456, type, 'The degree to which a stem cell or mast cell can produce specialized daughter cells.': $i).
% 28.89/28.98  tff(decl_21457, type, 'cellular potency': $i).
% 28.89/28.98  tff(decl_21458, type, 'cellular-potency': $i).
% 28.89/28.98  tff(decl_21459, type, 'Cellular-Process': $i).
% 28.89/28.98  tff(decl_21460, type, 'Any process occurring at the cellular level.': $i).
% 28.89/28.98  tff(decl_21461, type, 'cellular activity': $i).
% 28.89/28.98  tff(decl_21462, type, 'undergo cellular process': $i).
% 28.89/28.98  tff(decl_21463, type, 'cellular process': $i).
% 28.89/28.98  tff(decl_21464, type, 'cellular-process': $i).
% 28.89/28.98  tff(decl_21465, type, 'Cellular-Recycling': $i).
% 28.89/28.98  tff(decl_21466, type, 'A process that uses the same molecule over and over to repeat reactions within cells, such as the recharging and re-use of ATP.': $i).
% 28.89/28.98  tff(decl_21467, type, recycle: $i).
% 28.89/28.98  tff(decl_21468, type, 'cellular recycling': $i).
% 28.89/28.98  tff(decl_21469, type, 'cellular-recycling': $i).
% 28.89/28.98  tff(decl_21470, type, cellular_recycling_of_atp_1: $i > $o).
% 28.89/28.98  tff(decl_21471, type, fn_cellular_recycling_of_atp_4: $i > $i).
% 28.89/28.98  tff(decl_21472, type, 'Cellular-Recycling-Of-ATP': $i).
% 28.89/28.98  tff(decl_21473, type, 'Cells recycle the ATP they use for work.': $i).
% 28.89/28.98  tff(decl_21474, type, 'atp recycling': $i).
% 28.89/28.98  tff(decl_21475, type, 'recycling of atp': $i).
% 28.89/28.98  tff(decl_21476, type, 'cellular recycling of atp': $i).
% 28.89/28.98  tff(decl_21477, type, 'cellular-recycling-of-atp': $i).
% 28.89/28.98  tff(decl_21478, type, recycling_of_amino_acid_1: $i > $o).
% 28.89/28.98  tff(decl_21479, type, fn_cellular_recycling_of_atp_2: $i > $i).
% 28.89/28.98  tff(decl_21480, type, fn_cellular_recycling_of_atp_3: $i > $i).
% 28.89/28.98  tff(decl_21481, type, fn_cellular_recycling_of_atp_5: $i > $i).
% 28.89/28.98  tff(decl_21482, type, fn_cellular_recycling_of_atp_6: $i > $i).
% 28.89/28.98  tff(decl_21483, type, 'Cellular-Region': $i).
% 28.89/28.98  tff(decl_21484, type, 'A region of an cellular entity.': $i).
% 28.89/28.98  tff(decl_21485, type, 'A region of a cellular or subcellular entity.': $i).
% 28.89/28.98  tff(decl_21486, type, 'cellular region': $i).
% 28.89/28.98  tff(decl_21487, type, 'cellular-region': $i).
% 28.89/28.98  tff(decl_21488, type, 'Cellular-Respiration': $i).
% 28.89/28.98  tff(decl_21489, type, 'Cellular respiration, also known as \\oxidative metabolism\\, is one of the key ways a cell gains useful energy.  In this process the glucose is broken down. There are also alternate cellular respiration pathways where the the orgamic molecule that is broken down differs from glucose. These alternate pathways are known as cellular respiration of fat, cellular respiration of protein, cellular respiration of complex carbohydrate.': $i).
% 28.89/28.98  tff(decl_21490, type, 'aerobic respiration': $i).
% 28.89/28.98  tff(decl_21491, type, 'aerobic-respiration': $i).
% 28.89/28.98  tff(decl_21492, type, 'perform cellular respiration': $i).
% 28.89/28.98  tff(decl_21493, type, 'cellular respiration': $i).
% 28.89/28.98  tff(decl_21494, type, 'cellular-respiration': $i).
% 28.89/28.98  tff(decl_21495, type, citric_acid_cycle_in_eukaryote_1: $i > $o).
% 28.89/28.98  tff(decl_21496, type, citric_acid_cycle_in_prokaryote_1: $i > $o).
% 28.89/28.98  tff(decl_21497, type, fn_cellular_respiration_1: $i > $i).
% 28.89/28.98  tff(decl_21498, type, fn_cellular_respiration_2: $i > $i).
% 28.89/28.98  tff(decl_21499, type, fn_cellular_respiration_3: $i > $i).
% 28.89/28.98  tff(decl_21500, type, fn_cellular_respiration_4: $i > $i).
% 28.89/28.98  tff(decl_21501, type, fn_cellular_respiration_5: $i > $i).
% 28.89/28.98  tff(decl_21502, type, fn_cellular_respiration_7: $i > $i).
% 28.89/28.98  tff(decl_21503, type, fn_cellular_respiration_9: $i > $i).
% 28.89/28.98  tff(decl_21504, type, fn_cellular_respiration_10: $i > $i).
% 28.89/28.98  tff(decl_21505, type, fn_cellular_respiration_12: $i > $i).
% 28.89/28.98  tff(decl_21506, type, fn_cellular_respiration_13: $i > $i).
% 28.89/28.98  tff(decl_21507, type, fn_cellular_respiration_19: $i > $i).
% 28.89/28.98  tff(decl_21508, type, fn_cellular_respiration_20: $i > $i).
% 28.89/28.98  tff(decl_21509, type, fn_cellular_respiration_21: $i > $i).
% 28.89/28.98  tff(decl_21510, type, fn_cellular_respiration_22: $i > $i).
% 28.89/28.98  tff(decl_21511, type, fn_cellular_respiration_23: $i > $i).
% 28.89/28.98  tff(decl_21512, type, fn_cellular_respiration_24: $i > $i).
% 28.89/28.98  tff(decl_21513, type, fn_cellular_respiration_25: $i > $i).
% 28.89/28.98  tff(decl_21514, type, fn_cellular_respiration_26: $i > $i).
% 28.89/28.98  tff(decl_21515, type, fn_cellular_respiration_27: $i > $i).
% 28.89/28.98  tff(decl_21516, type, fn_cellular_respiration_28: $i > $i).
% 28.89/28.98  tff(decl_21517, type, fn_cellular_respiration_29: $i > $i).
% 28.89/28.98  tff(decl_21518, type, fn_cellular_respiration_30: $i > $i).
% 28.89/28.98  tff(decl_21519, type, fn_cellular_respiration_31: $i > $i).
% 28.89/28.98  tff(decl_21520, type, fn_cellular_respiration_32: $i > $i).
% 28.89/28.98  tff(decl_21521, type, fn_cellular_respiration_33: $i > $i).
% 28.89/28.98  tff(decl_21522, type, fn_cellular_respiration_34: $i > $i).
% 28.89/28.98  tff(decl_21523, type, fn_cellular_respiration_35: $i > $i).
% 28.89/28.98  tff(decl_21524, type, fn_cellular_respiration_36: $i > $i).
% 28.89/28.98  tff(decl_21525, type, fn_cellular_respiration_37: $i > $i).
% 28.89/28.98  tff(decl_21526, type, fn_cellular_respiration_38: $i > $i).
% 28.89/28.98  tff(decl_21527, type, fn_cellular_respiration_39: $i > $i).
% 28.89/28.98  tff(decl_21528, type, fn_cellular_respiration_42: $i > $i).
% 28.89/28.98  tff(decl_21529, type, fn_cellular_respiration_44: $i > $i).
% 28.89/28.98  tff(decl_21530, type, fn_cellular_respiration_45: $i > $i).
% 28.89/28.98  tff(decl_21531, type, fn_cellular_respiration_48: $i > $i).
% 28.89/28.98  tff(decl_21532, type, fn_cellular_respiration_49: $i > $i).
% 28.89/28.98  tff(decl_21533, type, fn_cellular_respiration_50: $i > $i).
% 28.89/28.98  tff(decl_21534, type, fn_cellular_respiration_51: $i > $i).
% 28.89/28.98  tff(decl_21535, type, fn_cellular_respiration_52: $i > $i).
% 28.89/28.98  tff(decl_21536, type, fn_cellular_respiration_53: $i > $i).
% 28.89/28.98  tff(decl_21537, type, fn_cellular_respiration_54: $i > $i).
% 28.89/28.98  tff(decl_21538, type, fn_cellular_respiration_57: $i > $i).
% 28.89/28.98  tff(decl_21539, type, fn_cellular_respiration_62: $i > $i).
% 28.89/28.98  tff(decl_21540, type, fn_cellular_respiration_64: $i > $i).
% 28.89/28.98  tff(decl_21541, type, fn_cellular_respiration_66: $i > $i).
% 28.89/28.98  tff(decl_21542, type, fn_cellular_respiration_67: $i > $i).
% 28.89/28.98  tff(decl_21543, type, fn_cellular_respiration_68: $i > $i).
% 28.89/28.98  tff(decl_21544, type, fn_cellular_respiration_69: $i > $i).
% 28.89/28.98  tff(decl_21545, type, fn_cellular_respiration_70: $i > $i).
% 28.89/28.98  tff(decl_21546, type, fn_cellular_respiration_71: $i > $i).
% 28.89/28.98  tff(decl_21547, type, fn_cellular_respiration_72: $i > $i).
% 28.89/28.98  tff(decl_21548, type, fn_cellular_respiration_73: $i > $i).
% 28.89/28.98  tff(decl_21549, type, fn_cellular_respiration_74: $i > $i).
% 28.89/28.98  tff(decl_21550, type, fn_cellular_respiration_75: $i > $i).
% 28.89/28.98  tff(decl_21551, type, fn_cellular_respiration_76: $i > $i).
% 28.89/28.98  tff(decl_21552, type, fn_cellular_respiration_77: $i > $i).
% 28.89/28.98  tff(decl_21553, type, fn_cellular_respiration_78: $i > $i).
% 28.89/28.98  tff(decl_21554, type, fn_cellular_respiration_79: $i > $i).
% 28.89/28.98  tff(decl_21555, type, fn_electron_recipient_1: $i > $i).
% 28.89/28.98  tff(decl_21556, type, fn_pyruvate_oxidation_58: $i > $i).
% 28.89/28.98  tff(decl_21557, type, fn_pyruvate_oxidation_66: $i > $i).
% 28.89/28.98  tff(decl_21558, type, fn_glycolysis_64: $i > $i).
% 28.89/28.98  tff(decl_21559, type, fn_oxidative_phosphorylation_22: $i > $i).
% 28.89/28.98  tff(decl_21560, type, fn_oxidative_phosphorylation_71: $i > $i).
% 28.89/28.98  tff(decl_21561, type, fn_nadh_1: $i > $i).
% 28.89/28.98  tff(decl_21562, type, fn_nadh_8: $i > $i).
% 28.89/28.98  tff(decl_21563, type, fn_nadh_11: $i > $i).
% 28.89/28.98  tff(decl_21564, type, fn_nadh_2: $i > $i).
% 28.89/28.98  tff(decl_21565, type, fn_citric_acid_cycle_38: $i > $i).
% 28.89/28.98  tff(decl_21566, type, fn_citric_acid_cycle_126: $i > $i).
% 28.89/28.98  tff(decl_21567, type, fn_citric_acid_cycle_125: $i > $i).
% 28.89/28.98  tff(decl_21568, type, fn_citric_acid_cycle_124: $i > $i).
% 28.89/28.98  tff(decl_21569, type, fn_citric_acid_cycle_27: $i > $i).
% 28.89/28.98  tff(decl_21570, type, fn_citric_acid_cycle_5: $i > $i).
% 28.89/28.98  tff(decl_21571, type, fn_citric_acid_cycle_66: $i > $i).
% 28.89/28.98  tff(decl_21572, type, fn_citric_acid_cycle_37: $i > $i).
% 28.89/28.98  tff(decl_21573, type, fn_citric_acid_cycle_48: $i > $i).
% 28.89/28.98  tff(decl_21574, type, fn_citric_acid_cycle_57: $i > $i).
% 28.89/28.98  tff(decl_21575, type, fn_oxidative_phosphorylation_12: $i > $i).
% 28.89/28.98  tff(decl_21576, type, fn_oxidative_phosphorylation_51: $i > $i).
% 28.89/28.98  tff(decl_21577, type, fn_oxidative_phosphorylation_50: $i > $i).
% 28.89/28.98  tff(decl_21578, type, fn_pyruvate_oxidation_90: $i > $i).
% 28.89/28.98  tff(decl_21579, type, fn_pyruvate_oxidation_89: $i > $i).
% 28.89/28.98  tff(decl_21580, type, fn_pyruvate_oxidation_54: $i > $i).
% 28.89/28.98  tff(decl_21581, type, fn_pyruvate_oxidation_67: $i > $i).
% 28.89/28.98  tff(decl_21582, type, fn_citric_acid_cycle_9: $i > $i).
% 28.89/28.98  tff(decl_21583, type, fn_citric_acid_cycle_101: $i > $i).
% 28.89/28.98  tff(decl_21584, type, fn_citric_acid_cycle_116: $i > $i).
% 28.89/28.98  tff(decl_21585, type, fn_oxidative_phosphorylation_56: $i > $i).
% 28.89/28.98  tff(decl_21586, type, fn_citric_acid_cycle_19: $i > $i).
% 28.89/28.98  tff(decl_21587, type, fn_nadh_5: $i > $i).
% 28.89/28.98  tff(decl_21588, type, fn_citric_acid_cycle_105: $i > $i).
% 28.89/28.98  tff(decl_21589, type, fn_citric_acid_cycle_47: $i > $i).
% 28.89/28.98  tff(decl_21590, type, fn_citric_acid_cycle_109: $i > $i).
% 28.89/28.98  tff(decl_21591, type, fn_citric_acid_cycle_12: $i > $i).
% 28.89/28.98  tff(decl_21592, type, fn_citric_acid_cycle_17: $i > $i).
% 28.89/28.98  tff(decl_21593, type, fn_pyruvate_oxidation_87: $i > $i).
% 28.89/28.98  tff(decl_21594, type, fn_citric_acid_cycle_108: $i > $i).
% 28.89/28.98  tff(decl_21595, type, fn_citric_acid_cycle_113: $i > $i).
% 28.89/28.98  tff(decl_21596, type, fn_citric_acid_cycle_115: $i > $i).
% 28.89/28.98  tff(decl_21597, type, fn_citric_acid_cycle_107: $i > $i).
% 28.89/28.98  tff(decl_21598, type, fn_citric_acid_cycle_106: $i > $i).
% 28.89/28.98  tff(decl_21599, type, fn_citric_acid_cycle_72: $i > $i).
% 28.89/28.98  tff(decl_21600, type, event_0: $i).
% 28.89/28.98  tff(decl_21601, type, oxygen_molecule_0: $i).
% 28.89/28.98  tff(decl_21602, type, water_molecule_0: $i).
% 28.89/28.98  tff(decl_21603, type, carbon_dioxide_0: $i).
% 28.89/28.98  tff(decl_21604, type, "32": $i).
% 28.89/28.98  tff(decl_21605, type, fn_cellular_respiration_17: $i > $i).
% 28.89/28.98  tff(decl_21606, type, fn_cellular_respiration_15: $i > $i).
% 28.89/28.98  tff(decl_21607, type, fn_cellular_respiration_14: $i > $i).
% 28.89/28.98  tff(decl_21608, type, fn_cellular_respiration_16: $i > $i).
% 28.89/28.98  tff(decl_21609, type, fn_cellular_respiration_18: $i > $i).
% 28.89/28.98  tff(decl_21610, type, cellular_respiration_of_complex_carbohydrate_1: $i > $o).
% 28.89/28.98  tff(decl_21611, type, 'Cellular-Respiration-Of-Complex-Carbohydrate': $i).
% 28.89/28.98  tff(decl_21612, type, 'The sum of catabolic pathways, including aerobic and anaerobic respiration, that first break complex carbohydrate molecules into their constituent monomers, then further break down the monomers and use an electron transport chain to generate ATP.': $i).
% 28.89/28.98  tff(decl_21613, type, 'cellular respiration of complex carbohydrate': $i).
% 28.89/28.98  tff(decl_21614, type, 'cellular-respiration-of-complex-carbohydrate': $i).
% 28.89/28.98  tff(decl_21615, type, fn_cellular_respiration_of_complex_carbohydrate_1: $i > $i).
% 28.89/28.98  tff(decl_21616, type, fn_cellular_respiration_of_complex_carbohydrate_2: $i > $i).
% 28.89/28.98  tff(decl_21617, type, fn_cellular_respiration_of_complex_carbohydrate_3: $i > $i).
% 28.89/28.98  tff(decl_21618, type, fn_cellular_respiration_of_complex_carbohydrate_4: $i > $i).
% 28.89/28.98  tff(decl_21619, type, fn_cellular_respiration_of_complex_carbohydrate_5: $i > $i).
% 28.89/28.98  tff(decl_21620, type, fn_cellular_respiration_of_complex_carbohydrate_6: $i > $i).
% 28.89/28.98  tff(decl_21621, type, fn_cellular_respiration_of_complex_carbohydrate_7: $i > $i).
% 28.89/28.98  tff(decl_21622, type, fn_cellular_respiration_of_complex_carbohydrate_8: $i > $i).
% 28.89/28.98  tff(decl_21623, type, fn_cellular_respiration_of_complex_carbohydrate_9: $i > $i).
% 28.89/28.98  tff(decl_21624, type, fn_cellular_respiration_of_complex_carbohydrate_10: $i > $i).
% 28.89/28.98  tff(decl_21625, type, fn_cellular_respiration_of_complex_carbohydrate_13: $i > $i).
% 28.89/28.98  tff(decl_21626, type, fn_cellular_respiration_of_complex_carbohydrate_14: $i > $i).
% 28.89/28.98  tff(decl_21627, type, fn_cellular_respiration_of_complex_carbohydrate_15: $i > $i).
% 28.89/28.98  tff(decl_21628, type, fn_cellular_respiration_of_complex_carbohydrate_19: $i > $i).
% 28.89/28.98  tff(decl_21629, type, fn_cellular_respiration_of_complex_carbohydrate_20: $i > $i).
% 28.89/28.98  tff(decl_21630, type, fn_cellular_respiration_of_complex_carbohydrate_21: $i > $i).
% 28.89/28.98  tff(decl_21631, type, fn_cellular_respiration_of_complex_carbohydrate_22: $i > $i).
% 28.89/28.98  tff(decl_21632, type, fn_cellular_respiration_of_complex_carbohydrate_23: $i > $i).
% 28.89/28.98  tff(decl_21633, type, fn_cellular_respiration_of_complex_carbohydrate_24: $i > $i).
% 28.89/28.98  tff(decl_21634, type, fn_cellular_respiration_of_complex_carbohydrate_25: $i > $i).
% 28.89/28.98  tff(decl_21635, type, fn_cellular_respiration_of_complex_carbohydrate_26: $i > $i).
% 28.89/28.98  tff(decl_21636, type, fn_cellular_respiration_of_complex_carbohydrate_27: $i > $i).
% 28.89/28.98  tff(decl_21637, type, fn_cellular_respiration_of_complex_carbohydrate_28: $i > $i).
% 28.89/28.98  tff(decl_21638, type, fn_cellular_respiration_of_complex_carbohydrate_29: $i > $i).
% 28.89/28.98  tff(decl_21639, type, fn_cellular_respiration_of_complex_carbohydrate_30: $i > $i).
% 28.89/28.98  tff(decl_21640, type, fn_cellular_respiration_of_complex_carbohydrate_31: $i > $i).
% 28.89/28.98  tff(decl_21641, type, fn_cellular_respiration_of_complex_carbohydrate_32: $i > $i).
% 28.89/28.98  tff(decl_21642, type, fn_cellular_respiration_of_complex_carbohydrate_33: $i > $i).
% 28.89/28.98  tff(decl_21643, type, fn_cellular_respiration_of_complex_carbohydrate_34: $i > $i).
% 28.89/28.98  tff(decl_21644, type, fn_cellular_respiration_of_complex_carbohydrate_35: $i > $i).
% 28.89/28.98  tff(decl_21645, type, fn_cellular_respiration_of_complex_carbohydrate_36: $i > $i).
% 28.89/28.98  tff(decl_21646, type, fn_cellular_respiration_of_complex_carbohydrate_37: $i > $i).
% 28.89/28.98  tff(decl_21647, type, fn_cellular_respiration_of_complex_carbohydrate_38: $i > $i).
% 28.89/28.98  tff(decl_21648, type, fn_cellular_respiration_of_complex_carbohydrate_39: $i > $i).
% 28.89/28.98  tff(decl_21649, type, fn_cellular_respiration_of_complex_carbohydrate_40: $i > $i).
% 28.89/28.98  tff(decl_21650, type, fn_cellular_respiration_of_complex_carbohydrate_41: $i > $i).
% 28.89/28.98  tff(decl_21651, type, fn_cellular_respiration_of_complex_carbohydrate_42: $i > $i).
% 28.89/28.98  tff(decl_21652, type, fn_cellular_respiration_of_complex_carbohydrate_43: $i > $i).
% 28.89/28.98  tff(decl_21653, type, fn_cellular_respiration_of_complex_carbohydrate_44: $i > $i).
% 28.89/28.98  tff(decl_21654, type, fn_cellular_respiration_of_complex_carbohydrate_45: $i > $i).
% 28.89/28.98  tff(decl_21655, type, fn_cellular_respiration_of_complex_carbohydrate_46: $i > $i).
% 28.89/28.98  tff(decl_21656, type, fn_cellular_respiration_of_complex_carbohydrate_47: $i > $i).
% 28.89/28.98  tff(decl_21657, type, fn_cellular_respiration_of_complex_carbohydrate_48: $i > $i).
% 28.89/28.98  tff(decl_21658, type, fn_cellular_respiration_of_complex_carbohydrate_49: $i > $i).
% 28.89/28.98  tff(decl_21659, type, fn_hydrolysis_19: $i > $i).
% 28.89/28.98  tff(decl_21660, type, fn_hydrolysis_18: $i > $i).
% 28.89/28.98  tff(decl_21661, type, fn_hydrolysis_16: $i > $i).
% 28.89/28.98  tff(decl_21662, type, fn_hydrolysis_15: $i > $i).
% 28.89/28.98  tff(decl_21663, type, fn_hydrolysis_14: $i > $i).
% 28.89/28.98  tff(decl_21664, type, fn_cellular_respiration_of_complex_carbohydrate_12: $i > $i).
% 28.89/28.98  tff(decl_21665, type, fn_cellular_respiration_of_complex_carbohydrate_11: $i > $i).
% 28.89/28.98  tff(decl_21666, type, fn_cellular_respiration_of_complex_carbohydrate_16: $i > $i).
% 28.89/28.98  tff(decl_21667, type, fn_cellular_respiration_of_complex_carbohydrate_17: $i > $i).
% 28.89/28.98  tff(decl_21668, type, fn_cellular_respiration_of_complex_carbohydrate_18: $i > $i).
% 28.89/28.98  tff(decl_21669, type, fn_cellular_respiration_of_complex_carbohydrate_50: $i > $i).
% 28.89/28.98  tff(decl_21670, type, cellular_respiration_of_disaccharide_1: $i > $o).
% 28.89/28.98  tff(decl_21671, type, 'Cellular-Respiration-Of-Disaccharide': $i).
% 28.89/28.98  tff(decl_21672, type, 'Cellular respiration, also known as \\oxidative metabolism\\, is one of the key ways a cell gains useful energy.': $i).
% 28.89/28.98  tff(decl_21673, type, 'cellular respiration of disaccharide': $i).
% 28.89/28.98  tff(decl_21674, type, 'cellular-respiration-of-disaccharide': $i).
% 28.89/28.98  tff(decl_21675, type, cellular_respiration_using_starch_1: $i > $o).
% 28.89/28.98  tff(decl_21676, type, fn_cellular_respiration_of_disaccharide_1: $i > $i).
% 28.89/28.98  tff(decl_21677, type, fn_cellular_respiration_of_disaccharide_2: $i > $i).
% 28.89/28.98  tff(decl_21678, type, fn_cellular_respiration_of_disaccharide_3: $i > $i).
% 28.89/28.98  tff(decl_21679, type, fn_cellular_respiration_of_disaccharide_4: $i > $i).
% 28.89/28.98  tff(decl_21680, type, fn_cellular_respiration_of_disaccharide_5: $i > $i).
% 28.89/28.98  tff(decl_21681, type, fn_cellular_respiration_of_disaccharide_6: $i > $i).
% 28.89/28.98  tff(decl_21682, type, fn_cellular_respiration_of_disaccharide_7: $i > $i).
% 28.89/28.98  tff(decl_21683, type, fn_cellular_respiration_of_disaccharide_8: $i > $i).
% 28.89/28.98  tff(decl_21684, type, fn_cellular_respiration_of_disaccharide_9: $i > $i).
% 28.89/28.98  tff(decl_21685, type, fn_cellular_respiration_of_disaccharide_10: $i > $i).
% 28.89/28.98  tff(decl_21686, type, fn_cellular_respiration_of_disaccharide_11: $i > $i).
% 28.89/28.98  tff(decl_21687, type, fn_cellular_respiration_of_disaccharide_12: $i > $i).
% 28.89/28.98  tff(decl_21688, type, fn_cellular_respiration_of_disaccharide_13: $i > $i).
% 28.89/28.98  tff(decl_21689, type, fn_cellular_respiration_of_disaccharide_14: $i > $i).
% 28.89/28.98  tff(decl_21690, type, fn_cellular_respiration_of_disaccharide_15: $i > $i).
% 28.89/28.98  tff(decl_21691, type, fn_cellular_respiration_of_disaccharide_16: $i > $i).
% 28.89/28.98  tff(decl_21692, type, fn_cellular_respiration_of_disaccharide_17: $i > $i).
% 28.89/28.98  tff(decl_21693, type, fn_cellular_respiration_of_disaccharide_18: $i > $i).
% 28.89/28.98  tff(decl_21694, type, fn_cellular_respiration_of_disaccharide_19: $i > $i).
% 28.89/28.98  tff(decl_21695, type, fn_cellular_respiration_of_disaccharide_22: $i > $i).
% 28.89/28.98  tff(decl_21696, type, fn_cellular_respiration_of_disaccharide_23: $i > $i).
% 28.89/28.98  tff(decl_21697, type, fn_cellular_respiration_of_disaccharide_24: $i > $i).
% 28.89/28.98  tff(decl_21698, type, fn_cellular_respiration_of_disaccharide_25: $i > $i).
% 28.89/28.98  tff(decl_21699, type, fn_cellular_respiration_of_disaccharide_26: $i > $i).
% 28.89/28.98  tff(decl_21700, type, fn_cellular_respiration_of_disaccharide_27: $i > $i).
% 28.89/28.98  tff(decl_21701, type, fn_cellular_respiration_of_disaccharide_29: $i > $i).
% 28.89/28.98  tff(decl_21702, type, fn_cellular_respiration_of_disaccharide_30: $i > $i).
% 28.89/28.98  tff(decl_21703, type, fn_cellular_respiration_of_disaccharide_31: $i > $i).
% 28.89/28.98  tff(decl_21704, type, fructose_1_comma_6_bisphosphate_1: $i > $o).
% 28.89/28.98  tff(decl_21705, type, fn_cellular_respiration_of_disaccharide_32: $i > $i).
% 28.89/28.98  tff(decl_21706, type, fn_cellular_respiration_of_disaccharide_33: $i > $i).
% 28.89/28.98  tff(decl_21707, type, fn_cellular_respiration_of_disaccharide_34: $i > $i).
% 28.89/28.98  tff(decl_21708, type, fn_cellular_respiration_of_disaccharide_35: $i > $i).
% 28.89/28.98  tff(decl_21709, type, fn_cellular_respiration_of_disaccharide_36: $i > $i).
% 28.89/28.98  tff(decl_21710, type, fn_cellular_respiration_of_disaccharide_37: $i > $i).
% 28.89/28.98  tff(decl_21711, type, fn_cellular_respiration_of_disaccharide_38: $i > $i).
% 28.89/28.98  tff(decl_21712, type, fn_cellular_respiration_of_disaccharide_39: $i > $i).
% 28.89/28.98  tff(decl_21713, type, fn_cellular_respiration_of_disaccharide_40: $i > $i).
% 28.89/28.98  tff(decl_21714, type, fn_cellular_respiration_of_disaccharide_41: $i > $i).
% 28.89/28.98  tff(decl_21715, type, fn_cellular_respiration_of_disaccharide_42: $i > $i).
% 28.89/28.98  tff(decl_21716, type, fn_cellular_respiration_of_disaccharide_43: $i > $i).
% 28.89/28.98  tff(decl_21717, type, fn_cellular_respiration_of_disaccharide_44: $i > $i).
% 28.89/28.98  tff(decl_21718, type, fn_cellular_respiration_of_disaccharide_45: $i > $i).
% 28.89/28.98  tff(decl_21719, type, fn_cellular_respiration_of_disaccharide_46: $i > $i).
% 28.89/28.98  tff(decl_21720, type, fn_cellular_respiration_of_disaccharide_47: $i > $i).
% 28.89/28.98  tff(decl_21721, type, fn_cellular_respiration_of_disaccharide_48: $i > $i).
% 28.89/28.98  tff(decl_21722, type, fn_cellular_respiration_of_disaccharide_49: $i > $i).
% 28.89/28.98  tff(decl_21723, type, fn_cellular_respiration_of_disaccharide_50: $i > $i).
% 28.89/28.98  tff(decl_21724, type, fn_cellular_respiration_of_disaccharide_51: $i > $i).
% 28.89/28.98  tff(decl_21725, type, fn_cellular_respiration_of_disaccharide_52: $i > $i).
% 28.89/28.98  tff(decl_21726, type, fn_cellular_respiration_of_disaccharide_53: $i > $i).
% 28.89/28.98  tff(decl_21727, type, fn_cellular_respiration_of_disaccharide_54: $i > $i).
% 28.89/28.98  tff(decl_21728, type, fn_cellular_respiration_of_disaccharide_55: $i > $i).
% 28.89/28.98  tff(decl_21729, type, fn_cellular_respiration_of_disaccharide_56: $i > $i).
% 28.89/28.98  tff(decl_21730, type, fn_cellular_respiration_of_disaccharide_57: $i > $i).
% 28.89/28.98  tff(decl_21731, type, fn_cellular_respiration_of_disaccharide_58: $i > $i).
% 28.89/28.98  tff(decl_21732, type, fn_cellular_respiration_of_disaccharide_59: $i > $i).
% 28.89/28.98  tff(decl_21733, type, fn_cellular_respiration_of_disaccharide_60: $i > $i).
% 28.89/28.98  tff(decl_21734, type, fn_cellular_respiration_of_disaccharide_61: $i > $i).
% 28.89/28.98  tff(decl_21735, type, fn_cellular_respiration_of_disaccharide_62: $i > $i).
% 28.89/28.98  tff(decl_21736, type, fn_cellular_respiration_of_disaccharide_63: $i > $i).
% 28.89/28.98  tff(decl_21737, type, fn_cellular_respiration_of_disaccharide_64: $i > $i).
% 28.89/28.98  tff(decl_21738, type, fn_cellular_respiration_of_disaccharide_65: $i > $i).
% 28.89/28.98  tff(decl_21739, type, fn_cellular_respiration_of_disaccharide_66: $i > $i).
% 28.89/28.98  tff(decl_21740, type, fn_cellular_respiration_of_disaccharide_67: $i > $i).
% 28.89/28.98  tff(decl_21741, type, fn_cellular_respiration_of_disaccharide_68: $i > $i).
% 28.89/28.98  tff(decl_21742, type, fn_cellular_respiration_of_disaccharide_69: $i > $i).
% 28.89/28.98  tff(decl_21743, type, fn_cellular_respiration_of_disaccharide_70: $i > $i).
% 28.89/28.98  tff(decl_21744, type, fn_cellular_respiration_of_disaccharide_71: $i > $i).
% 28.89/28.98  tff(decl_21745, type, fn_cellular_respiration_of_disaccharide_72: $i > $i).
% 28.89/28.98  tff(decl_21746, type, fn_cellular_respiration_of_disaccharide_73: $i > $i).
% 28.89/28.98  tff(decl_21747, type, fn_cellular_respiration_of_disaccharide_74: $i > $i).
% 28.89/28.98  tff(decl_21748, type, fn_cellular_respiration_of_disaccharide_75: $i > $i).
% 28.89/28.98  tff(decl_21749, type, fn_cellular_respiration_of_disaccharide_76: $i > $i).
% 28.89/28.98  tff(decl_21750, type, fn_cellular_respiration_of_disaccharide_77: $i > $i).
% 28.89/28.98  tff(decl_21751, type, fn_cellular_respiration_of_disaccharide_78: $i > $i).
% 28.89/28.98  tff(decl_21752, type, fn_pyruvate_oxidation_77: $i > $i).
% 28.89/28.98  tff(decl_21753, type, fn_pyruvate_oxidation_38: $i > $i).
% 28.89/28.98  tff(decl_21754, type, fn_pyruvate_oxidation_65: $i > $i).
% 28.89/28.98  tff(decl_21755, type, fn_pyruvate_oxidation_11: $i > $i).
% 28.89/28.98  tff(decl_21756, type, fn_hydrolysis_7: $i > $i).
% 28.89/28.98  tff(decl_21757, type, fn_triose_13: $i > $i).
% 28.89/28.98  tff(decl_21758, type, fn_dihydroxyacetone_phosphate_2: $i > $i).
% 28.89/28.98  tff(decl_21759, type, fn_dihydroxyacetone_phosphate_4: $i > $i).
% 28.89/28.98  tff(decl_21760, type, fn_dihydroxyacetone_phosphate_10: $i > $i).
% 28.89/28.98  tff(decl_21761, type, fn_dihydroxyacetone_phosphate_8: $i > $i).
% 28.89/28.98  tff(decl_21762, type, fn_dihydroxyacetone_phosphate_9: $i > $i).
% 28.89/28.98  tff(decl_21763, type, fn_triose_8: $i > $i).
% 28.89/28.98  tff(decl_21764, type, fn_dihydroxyacetone_phosphate_7: $i > $i).
% 28.89/28.98  tff(decl_21765, type, fn_dihydroxyacetone_phosphate_1: $i > $i).
% 28.89/28.98  tff(decl_21766, type, fn_cellular_respiration_of_disaccharide_21: $i > $i).
% 28.89/28.98  tff(decl_21767, type, fn_cellular_respiration_of_disaccharide_20: $i > $i).
% 28.89/28.98  tff(decl_21768, type, fn_cellular_respiration_of_disaccharide_79: $i > $i).
% 28.89/28.98  tff(decl_21769, type, fn_cellular_respiration_of_disaccharide_80: $i > $i).
% 28.89/28.98  tff(decl_21770, type, fn_cellular_respiration_of_disaccharide_81: $i > $i).
% 28.89/28.98  tff(decl_21771, type, fn_cellular_respiration_of_disaccharide_28: $i > $i).
% 28.89/28.98  tff(decl_21772, type, cellular_respiration_of_fat_1: $i > $o).
% 28.89/28.98  tff(decl_21773, type, 'Cellular-Respiration-Of-Fat': $i).
% 28.89/28.98  tff(decl_21774, type, 'Carbohydrates, fats, and proteins can all be processed and consumed as fuel, it is traditional to learn the steps of cellular respiration by tracking the degradation of the sugar glucose': $i).
% 28.89/28.98  tff(decl_21775, type, 'cellular respiration of fat': $i).
% 28.89/28.98  tff(decl_21776, type, 'cellular-respiration-of-fat': $i).
% 28.89/28.98  tff(decl_21777, type, fn_cellular_respiration_of_fat_1: $i > $i).
% 28.89/28.98  tff(decl_21778, type, fn_cellular_respiration_of_fat_3: $i > $i).
% 28.89/28.98  tff(decl_21779, type, fn_cellular_respiration_of_fat_4: $i > $i).
% 28.89/28.98  tff(decl_21780, type, fn_cellular_respiration_of_fat_5: $i > $i).
% 28.89/28.98  tff(decl_21781, type, fn_cellular_respiration_of_fat_6: $i > $i).
% 28.89/28.98  tff(decl_21782, type, fn_cellular_respiration_of_fat_7: $i > $i).
% 28.89/28.98  tff(decl_21783, type, fn_cellular_respiration_of_fat_8: $i > $i).
% 28.89/28.98  tff(decl_21784, type, fn_cellular_respiration_of_fat_9: $i > $i).
% 28.89/28.98  tff(decl_21785, type, fn_cellular_respiration_of_fat_10: $i > $i).
% 28.89/28.98  tff(decl_21786, type, fn_cellular_respiration_of_fat_11: $i > $i).
% 28.89/28.98  tff(decl_21787, type, fn_cellular_respiration_of_fat_12: $i > $i).
% 28.89/28.98  tff(decl_21788, type, fn_cellular_respiration_of_fat_13: $i > $i).
% 28.89/28.98  tff(decl_21789, type, fn_cellular_respiration_of_fat_14: $i > $i).
% 28.89/28.98  tff(decl_21790, type, fn_cellular_respiration_of_fat_15: $i > $i).
% 28.89/28.98  tff(decl_21791, type, fn_cellular_respiration_of_fat_16: $i > $i).
% 28.89/28.98  tff(decl_21792, type, fn_cellular_respiration_of_fat_17: $i > $i).
% 28.89/28.98  tff(decl_21793, type, fn_cellular_respiration_of_fat_18: $i > $i).
% 28.89/28.98  tff(decl_21794, type, fn_cellular_respiration_of_fat_19: $i > $i).
% 28.89/28.98  tff(decl_21795, type, fn_cellular_respiration_of_fat_20: $i > $i).
% 28.89/28.98  tff(decl_21796, type, fn_cellular_respiration_of_fat_21: $i > $i).
% 28.89/28.98  tff(decl_21797, type, fn_cellular_respiration_of_fat_22: $i > $i).
% 28.89/28.98  tff(decl_21798, type, fn_cellular_respiration_of_fat_23: $i > $i).
% 28.89/28.98  tff(decl_21799, type, fn_cellular_respiration_of_fat_24: $i > $i).
% 28.89/28.98  tff(decl_21800, type, fn_cellular_respiration_of_fat_25: $i > $i).
% 28.89/28.98  tff(decl_21801, type, fn_cellular_respiration_of_fat_26: $i > $i).
% 28.89/28.98  tff(decl_21802, type, fn_cellular_respiration_of_fat_27: $i > $i).
% 28.89/28.98  tff(decl_21803, type, fn_cellular_respiration_of_fat_28: $i > $i).
% 28.89/28.98  tff(decl_21804, type, fn_cellular_respiration_of_fat_29: $i > $i).
% 28.89/28.98  tff(decl_21805, type, fn_cellular_respiration_of_fat_30: $i > $i).
% 28.89/28.98  tff(decl_21806, type, fn_cellular_respiration_of_fat_31: $i > $i).
% 28.89/28.98  tff(decl_21807, type, fn_cellular_respiration_of_fat_32: $i > $i).
% 28.89/28.98  tff(decl_21808, type, fn_cellular_respiration_of_fat_33: $i > $i).
% 28.89/28.98  tff(decl_21809, type, fn_cellular_respiration_of_fat_34: $i > $i).
% 28.89/28.98  tff(decl_21810, type, fn_cellular_respiration_of_fat_35: $i > $i).
% 28.89/28.98  tff(decl_21811, type, fn_cellular_respiration_of_fat_36: $i > $i).
% 28.89/28.98  tff(decl_21812, type, fn_cellular_respiration_of_fat_37: $i > $i).
% 28.89/28.98  tff(decl_21813, type, fn_cellular_respiration_of_fat_38: $i > $i).
% 28.89/28.98  tff(decl_21814, type, fn_cellular_respiration_of_fat_39: $i > $i).
% 28.89/28.98  tff(decl_21815, type, fn_cellular_respiration_of_fat_40: $i > $i).
% 28.89/28.98  tff(decl_21816, type, fn_cellular_respiration_of_fat_41: $i > $i).
% 28.89/28.98  tff(decl_21817, type, fad_1: $i > $o).
% 28.89/28.98  tff(decl_21818, type, fn_cellular_respiration_of_fat_42: $i > $i).
% 28.89/28.98  tff(decl_21819, type, fn_cellular_respiration_of_fat_43: $i > $i).
% 28.89/28.98  tff(decl_21820, type, fn_cellular_respiration_of_fat_44: $i > $i).
% 28.89/28.98  tff(decl_21821, type, fn_cellular_respiration_of_fat_45: $i > $i).
% 28.89/28.98  tff(decl_21822, type, fn_cellular_respiration_of_fat_46: $i > $i).
% 28.89/28.98  tff(decl_21823, type, fn_cellular_respiration_of_fat_48: $i > $i).
% 28.89/28.98  tff(decl_21824, type, fn_cellular_respiration_of_fat_49: $i > $i).
% 28.89/28.98  tff(decl_21825, type, fn_cellular_respiration_of_fat_50: $i > $i).
% 28.89/28.98  tff(decl_21826, type, fn_cellular_respiration_of_fat_51: $i > $i).
% 28.89/28.98  tff(decl_21827, type, fn_cellular_respiration_of_fat_52: $i > $i).
% 28.89/28.98  tff(decl_21828, type, fn_cellular_respiration_of_fat_53: $i > $i).
% 28.89/28.98  tff(decl_21829, type, fn_cellular_respiration_of_fat_54: $i > $i).
% 28.89/28.98  tff(decl_21830, type, fn_cellular_respiration_of_fat_55: $i > $i).
% 28.89/28.98  tff(decl_21831, type, fn_cellular_respiration_of_fat_56: $i > $i).
% 28.89/28.98  tff(decl_21832, type, fn_cellular_respiration_of_fat_57: $i > $i).
% 28.89/28.98  tff(decl_21833, type, lipase_1: $i > $o).
% 28.89/28.98  tff(decl_21834, type, fn_cellular_respiration_of_fat_58: $i > $i).
% 28.89/28.98  tff(decl_21835, type, fn_cellular_respiration_of_fat_59: $i > $i).
% 28.89/28.98  tff(decl_21836, type, fn_cellular_respiration_of_fat_60: $i > $i).
% 28.89/28.98  tff(decl_21837, type, fn_cellular_respiration_of_fat_61: $i > $i).
% 28.89/28.98  tff(decl_21838, type, fn_cellular_respiration_of_fat_62: $i > $i).
% 28.89/28.98  tff(decl_21839, type, fn_cellular_respiration_of_fat_63: $i > $i).
% 28.89/28.98  tff(decl_21840, type, fn_cellular_respiration_of_fat_64: $i > $i).
% 28.89/28.98  tff(decl_21841, type, fn_cellular_respiration_of_fat_65: $i > $i).
% 28.89/28.98  tff(decl_21842, type, fn_cellular_respiration_of_fat_66: $i > $i).
% 28.89/28.98  tff(decl_21843, type, fn_cellular_respiration_of_fat_67: $i > $i).
% 28.89/28.98  tff(decl_21844, type, fn_cellular_respiration_of_fat_68: $i > $i).
% 28.89/28.98  tff(decl_21845, type, fn_cellular_respiration_of_fat_69: $i > $i).
% 28.89/28.98  tff(decl_21846, type, fn_cellular_respiration_of_fat_70: $i > $i).
% 28.89/28.98  tff(decl_21847, type, fn_cellular_respiration_of_fat_71: $i > $i).
% 28.89/28.98  tff(decl_21848, type, fn_cellular_respiration_of_fat_72: $i > $i).
% 28.89/28.98  tff(decl_21849, type, fn_cellular_respiration_of_fat_73: $i > $i).
% 28.89/28.98  tff(decl_21850, type, fn_cellular_respiration_of_fat_74: $i > $i).
% 28.89/28.98  tff(decl_21851, type, fn_cellular_respiration_of_fat_75: $i > $i).
% 28.89/28.98  tff(decl_21852, type, fn_lipase_4: $i > $i).
% 28.89/28.98  tff(decl_21853, type, fn_oxidative_phosphorylation_10: $i > $i).
% 28.89/28.98  tff(decl_21854, type, fn_redox_reaction_8: $i > $i).
% 28.89/28.98  tff(decl_21855, type, fn_electron_transport_chain_pathway_12: $i > $i).
% 28.89/28.98  tff(decl_21856, type, fn_electron_transport_chain_pathway_20: $i > $i).
% 28.89/28.98  tff(decl_21857, type, fn_electron_transport_chain_pathway_21: $i > $i).
% 28.89/28.98  tff(decl_21858, type, fn_electron_transport_chain_pathway_22: $i > $i).
% 28.89/28.98  tff(decl_21859, type, fn_lipase_1: $i > $i).
% 28.89/28.98  tff(decl_21860, type, fn_oxidative_phosphorylation_9: $i > $i).
% 28.89/28.98  tff(decl_21861, type, fn_lipase_2: $i > $i).
% 28.89/28.98  tff(decl_21862, type, fn_electron_transport_chain_pathway_26: $i > $i).
% 28.89/28.98  tff(decl_21863, type, fn_electron_transport_chain_pathway_27: $i > $i).
% 28.89/28.98  tff(decl_21864, type, fn_electron_transport_chain_pathway_43: $i > $i).
% 28.89/28.98  tff(decl_21865, type, fn_electron_transport_chain_pathway_24: $i > $i).
% 28.89/28.98  tff(decl_21866, type, fn_electron_transport_chain_reaction_24: $i > $i).
% 28.89/28.98  tff(decl_21867, type, fn_electron_transport_chain_pathway_41: $i > $i).
% 28.89/28.98  tff(decl_21868, type, fn_cellular_respiration_of_fat_47: $i > $i).
% 28.89/28.98  tff(decl_21869, type, cellular_respiration_of_glycogen_1: $i > $o).
% 28.89/28.98  tff(decl_21870, type, 'Cellular-Respiration-Of-Glycogen': $i).
% 28.89/28.98  tff(decl_21871, type, 'Cellular respiration of Glycogen refers to oxidative metabolism of glycogen by which cell gains useful energy.': $i).
% 28.89/28.98  tff(decl_21872, type, 'cellular respiration of glycogen': $i).
% 28.89/28.98  tff(decl_21873, type, 'cellular-respiration-of-glycogen': $i).
% 28.89/28.98  tff(decl_21874, type, fn_cellular_respiration_of_glycogen_1: $i > $i).
% 28.89/28.98  tff(decl_21875, type, fn_cellular_respiration_of_glycogen_2: $i > $i).
% 28.89/28.98  tff(decl_21876, type, fn_cellular_respiration_of_glycogen_3: $i > $i).
% 28.89/28.98  tff(decl_21877, type, fn_cellular_respiration_of_glycogen_4: $i > $i).
% 28.89/28.98  tff(decl_21878, type, fn_cellular_respiration_of_glycogen_5: $i > $i).
% 28.89/28.98  tff(decl_21879, type, fn_cellular_respiration_of_glycogen_6: $i > $i).
% 28.89/28.98  tff(decl_21880, type, fn_cellular_respiration_of_glycogen_7: $i > $i).
% 28.89/28.98  tff(decl_21881, type, fn_cellular_respiration_of_glycogen_8: $i > $i).
% 28.89/28.98  tff(decl_21882, type, fn_cellular_respiration_of_glycogen_9: $i > $i).
% 28.89/28.98  tff(decl_21883, type, fn_cellular_respiration_of_glycogen_10: $i > $i).
% 28.89/28.98  tff(decl_21884, type, fn_cellular_respiration_of_glycogen_11: $i > $i).
% 28.89/28.98  tff(decl_21885, type, fn_cellular_respiration_of_glycogen_12: $i > $i).
% 28.89/28.98  tff(decl_21886, type, fn_cellular_respiration_of_glycogen_13: $i > $i).
% 28.89/28.98  tff(decl_21887, type, fn_cellular_respiration_of_glycogen_14: $i > $i).
% 28.89/28.98  tff(decl_21888, type, fn_cellular_respiration_of_glycogen_15: $i > $i).
% 28.89/28.98  tff(decl_21889, type, fn_cellular_respiration_of_glycogen_16: $i > $i).
% 28.89/28.98  tff(decl_21890, type, fn_cellular_respiration_of_glycogen_17: $i > $i).
% 28.89/28.98  tff(decl_21891, type, fn_cellular_respiration_of_glycogen_18: $i > $i).
% 28.89/28.98  tff(decl_21892, type, fn_cellular_respiration_of_glycogen_19: $i > $i).
% 28.89/28.98  tff(decl_21893, type, multienzyme_complex_1: $i > $o).
% 28.89/28.98  tff(decl_21894, type, fn_cellular_respiration_of_glycogen_20: $i > $i).
% 28.89/28.98  tff(decl_21895, type, fn_cellular_respiration_of_glycogen_21: $i > $i).
% 28.89/28.98  tff(decl_21896, type, fn_cellular_respiration_of_glycogen_22: $i > $i).
% 28.89/28.98  tff(decl_21897, type, fn_cellular_respiration_of_glycogen_23: $i > $i).
% 28.89/28.98  tff(decl_21898, type, fn_cellular_respiration_of_glycogen_24: $i > $i).
% 28.89/28.98  tff(decl_21899, type, fn_cellular_respiration_of_glycogen_25: $i > $i).
% 28.89/28.98  tff(decl_21900, type, fn_cellular_respiration_of_glycogen_26: $i > $i).
% 28.89/28.98  tff(decl_21901, type, fn_cellular_respiration_of_glycogen_27: $i > $i).
% 28.89/28.98  tff(decl_21902, type, fn_cellular_respiration_of_glycogen_28: $i > $i).
% 28.89/28.98  tff(decl_21903, type, fn_cellular_respiration_of_glycogen_29: $i > $i).
% 28.89/28.98  tff(decl_21904, type, fn_cellular_respiration_of_glycogen_30: $i > $i).
% 28.89/28.98  tff(decl_21905, type, fn_cellular_respiration_of_glycogen_31: $i > $i).
% 28.89/28.98  tff(decl_21906, type, fn_cellular_respiration_of_glycogen_32: $i > $i).
% 28.89/28.98  tff(decl_21907, type, fn_cellular_respiration_of_glycogen_33: $i > $i).
% 28.89/28.98  tff(decl_21908, type, fn_cellular_respiration_of_glycogen_34: $i > $i).
% 28.89/28.98  tff(decl_21909, type, fn_cellular_respiration_of_glycogen_35: $i > $i).
% 28.89/28.98  tff(decl_21910, type, fn_cellular_respiration_of_glycogen_36: $i > $i).
% 28.89/28.98  tff(decl_21911, type, fn_cellular_respiration_of_glycogen_37: $i > $i).
% 28.89/28.98  tff(decl_21912, type, fn_cellular_respiration_of_glycogen_38: $i > $i).
% 28.89/28.98  tff(decl_21913, type, fn_cellular_respiration_of_glycogen_39: $i > $i).
% 28.89/28.98  tff(decl_21914, type, fn_cellular_respiration_of_glycogen_40: $i > $i).
% 28.89/28.98  tff(decl_21915, type, fn_cellular_respiration_of_glycogen_41: $i > $i).
% 28.89/28.98  tff(decl_21916, type, fn_cellular_respiration_of_glycogen_42: $i > $i).
% 28.89/28.98  tff(decl_21917, type, fn_cellular_respiration_of_glycogen_43: $i > $i).
% 28.89/28.98  tff(decl_21918, type, fn_cellular_respiration_of_glycogen_44: $i > $i).
% 28.89/28.98  tff(decl_21919, type, fn_cellular_respiration_of_glycogen_45: $i > $i).
% 28.89/28.98  tff(decl_21920, type, fn_cellular_respiration_of_glycogen_46: $i > $i).
% 28.89/28.98  tff(decl_21921, type, fn_cellular_respiration_of_glycogen_47: $i > $i).
% 28.89/28.98  tff(decl_21922, type, fn_cellular_respiration_of_glycogen_48: $i > $i).
% 28.89/28.98  tff(decl_21923, type, fn_cellular_respiration_of_glycogen_49: $i > $i).
% 28.89/28.98  tff(decl_21924, type, fn_cellular_respiration_of_glycogen_50: $i > $i).
% 28.89/28.98  tff(decl_21925, type, fn_cellular_respiration_of_glycogen_51: $i > $i).
% 28.89/28.98  tff(decl_21926, type, fn_cellular_respiration_of_glycogen_52: $i > $i).
% 28.89/28.98  tff(decl_21927, type, fn_cellular_respiration_of_glycogen_53: $i > $i).
% 28.89/28.98  tff(decl_21928, type, fn_cellular_respiration_of_glycogen_54: $i > $i).
% 28.89/28.98  tff(decl_21929, type, fn_cellular_respiration_of_glycogen_55: $i > $i).
% 28.89/28.98  tff(decl_21930, type, fn_pyruvate_oxidation_10: $i > $i).
% 28.89/28.98  tff(decl_21931, type, fn_citric_acid_cycle_46: $i > $i).
% 28.89/28.98  tff(decl_21932, type, fn_citric_acid_cycle_45: $i > $i).
% 28.89/28.98  tff(decl_21933, type, fn_citric_acid_cycle_127: $i > $i).
% 28.89/28.98  tff(decl_21934, type, fn_citric_acid_cycle_123: $i > $i).
% 28.89/28.98  tff(decl_21935, type, fn_citric_acid_cycle_122: $i > $i).
% 28.89/28.98  tff(decl_21936, type, fn_citric_acid_cycle_128: $i > $i).
% 28.89/28.98  tff(decl_21937, type, fn_citric_acid_cycle_18: $i > $i).
% 28.89/28.98  tff(decl_21938, type, fn_citric_acid_cycle_6: $i > $i).
% 28.89/28.98  tff(decl_21939, type, fn_cellular_respiration_of_glycogen_61: $i > $i).
% 28.89/28.98  tff(decl_21940, type, fn_cellular_respiration_of_glycogen_62: $i > $i).
% 28.89/28.98  tff(decl_21941, type, fn_cellular_respiration_of_glycogen_56: $i > $i).
% 28.89/28.98  tff(decl_21942, type, fn_cellular_respiration_of_glycogen_57: $i > $i).
% 28.89/28.98  tff(decl_21943, type, fn_cellular_respiration_of_glycogen_58: $i > $i).
% 28.89/28.98  tff(decl_21944, type, fn_cellular_respiration_of_glycogen_59: $i > $i).
% 28.89/28.98  tff(decl_21945, type, fn_cellular_respiration_of_glycogen_60: $i > $i).
% 28.89/28.98  tff(decl_21946, type, fn_cellular_respiration_of_glycogen_63: $i > $i).
% 28.89/28.98  tff(decl_21947, type, cellular_respiration_of_protein_1: $i > $o).
% 28.89/28.98  tff(decl_21948, type, 'Cellular-Respiration-Of-Protein': $i).
% 28.89/28.98  tff(decl_21949, type, 'cellular respiration of protein': $i).
% 28.89/28.98  tff(decl_21950, type, 'cellular-respiration-of-protein': $i).
% 28.89/28.98  tff(decl_21951, type, fn_cellular_respiration_of_protein_1: $i > $i).
% 28.89/28.98  tff(decl_21952, type, fn_cellular_respiration_of_protein_2: $i > $i).
% 28.89/28.98  tff(decl_21953, type, fn_cellular_respiration_of_protein_3: $i > $i).
% 28.89/28.98  tff(decl_21954, type, fn_cellular_respiration_of_protein_4: $i > $i).
% 28.89/28.98  tff(decl_21955, type, fn_cellular_respiration_of_protein_5: $i > $i).
% 28.89/28.98  tff(decl_21956, type, fn_cellular_respiration_of_protein_9: $i > $i).
% 28.89/28.98  tff(decl_21957, type, fn_cellular_respiration_of_protein_10: $i > $i).
% 28.89/28.98  tff(decl_21958, type, fn_cellular_respiration_of_protein_11: $i > $i).
% 28.89/28.98  tff(decl_21959, type, fn_cellular_respiration_of_protein_12: $i > $i).
% 28.89/28.98  tff(decl_21960, type, fn_cellular_respiration_of_protein_13: $i > $i).
% 28.89/28.98  tff(decl_21961, type, fn_cellular_respiration_of_protein_14: $i > $i).
% 28.89/28.98  tff(decl_21962, type, fn_cellular_respiration_of_protein_15: $i > $i).
% 28.89/28.98  tff(decl_21963, type, fn_cellular_respiration_of_protein_16: $i > $i).
% 28.89/28.98  tff(decl_21964, type, fn_cellular_respiration_of_protein_17: $i > $i).
% 28.89/28.98  tff(decl_21965, type, fn_cellular_respiration_of_protein_18: $i > $i).
% 28.89/28.98  tff(decl_21966, type, fn_cellular_respiration_of_protein_19: $i > $i).
% 28.89/28.98  tff(decl_21967, type, fn_cellular_respiration_of_protein_20: $i > $i).
% 28.89/28.98  tff(decl_21968, type, fn_cellular_respiration_of_protein_21: $i > $i).
% 28.89/28.98  tff(decl_21969, type, fn_cellular_respiration_of_protein_22: $i > $i).
% 28.89/28.98  tff(decl_21970, type, fn_cellular_respiration_of_protein_23: $i > $i).
% 28.89/28.98  tff(decl_21971, type, fn_cellular_respiration_of_protein_24: $i > $i).
% 28.89/28.98  tff(decl_21972, type, fn_cellular_respiration_of_protein_25: $i > $i).
% 28.89/28.98  tff(decl_21973, type, fn_cellular_respiration_of_protein_26: $i > $i).
% 28.89/28.98  tff(decl_21974, type, deamination_1: $i > $o).
% 28.89/28.98  tff(decl_21975, type, fn_cellular_respiration_of_protein_27: $i > $i).
% 28.89/28.98  tff(decl_21976, type, fn_cellular_respiration_of_protein_28: $i > $i).
% 28.89/28.98  tff(decl_21977, type, fn_cellular_respiration_of_protein_29: $i > $i).
% 28.89/28.98  tff(decl_21978, type, fn_cellular_respiration_of_protein_30: $i > $i).
% 28.89/28.98  tff(decl_21979, type, fn_cellular_respiration_of_protein_31: $i > $i).
% 28.89/28.98  tff(decl_21980, type, fn_cellular_respiration_of_protein_32: $i > $i).
% 28.89/28.98  tff(decl_21981, type, fn_cellular_respiration_of_protein_33: $i > $i).
% 28.89/28.98  tff(decl_21982, type, fn_cellular_respiration_of_protein_34: $i > $i).
% 28.89/28.98  tff(decl_21983, type, fn_cellular_respiration_of_protein_35: $i > $i).
% 28.89/28.98  tff(decl_21984, type, fn_cellular_respiration_of_protein_36: $i > $i).
% 28.89/28.98  tff(decl_21985, type, fn_cellular_respiration_of_protein_37: $i > $i).
% 28.89/28.98  tff(decl_21986, type, fn_cellular_respiration_of_protein_38: $i > $i).
% 28.89/28.98  tff(decl_21987, type, fn_cellular_respiration_of_protein_39: $i > $i).
% 28.89/28.98  tff(decl_21988, type, fn_cellular_respiration_of_protein_40: $i > $i).
% 28.89/28.98  tff(decl_21989, type, fn_cellular_respiration_of_protein_41: $i > $i).
% 28.89/28.98  tff(decl_21990, type, fn_cellular_respiration_of_protein_42: $i > $i).
% 28.89/28.98  tff(decl_21991, type, fn_cellular_respiration_of_protein_43: $i > $i).
% 28.89/28.98  tff(decl_21992, type, fn_cellular_respiration_of_protein_44: $i > $i).
% 28.89/28.98  tff(decl_21993, type, fn_cellular_respiration_of_protein_45: $i > $i).
% 28.89/28.98  tff(decl_21994, type, fn_cellular_respiration_of_protein_46: $i > $i).
% 28.89/28.98  tff(decl_21995, type, fn_pyruvate_oxidation_47: $i > $i).
% 28.89/28.98  tff(decl_21996, type, fn_pyruvate_oxidation_57: $i > $i).
% 28.89/28.98  tff(decl_21997, type, fn_pyruvate_oxidation_91: $i > $i).
% 28.89/28.98  tff(decl_21998, type, fn_pyruvate_oxidation_79: $i > $i).
% 28.89/28.98  tff(decl_21999, type, fn_deamination_9: $i > $i).
% 28.89/28.98  tff(decl_22000, type, fn_pyruvate_oxidation_41: $i > $i).
% 28.89/28.98  tff(decl_22001, type, fn_pyruvate_oxidation_78: $i > $i).
% 28.89/28.98  tff(decl_22002, type, fn_pyruvate_oxidation_92: $i > $i).
% 28.89/28.98  tff(decl_22003, type, fn_cellular_respiration_of_protein_6: $i > $i).
% 28.89/28.98  tff(decl_22004, type, fn_cellular_respiration_of_protein_8: $i > $i).
% 28.89/28.98  tff(decl_22005, type, fn_cellular_respiration_of_protein_7: $i > $i).
% 28.89/28.98  tff(decl_22006, type, cellular_respiration_of_sucrose_1: $i > $o).
% 28.89/28.98  tff(decl_22007, type, 'Cellular-Respiration-Of-Sucrose': $i).
% 28.89/28.98  tff(decl_22008, type, 'cellular respiration of sucrose': $i).
% 28.89/28.98  tff(decl_22009, type, 'cellular-respiration-of-sucrose': $i).
% 28.89/28.98  tff(decl_22010, type, fn_cellular_respiration_of_sucrose_1: $i > $i).
% 28.89/28.98  tff(decl_22011, type, fn_cellular_respiration_of_sucrose_2: $i > $i).
% 28.89/28.98  tff(decl_22012, type, fn_cellular_respiration_of_sucrose_3: $i > $i).
% 28.89/28.98  tff(decl_22013, type, fn_cellular_respiration_of_sucrose_4: $i > $i).
% 28.89/28.98  tff(decl_22014, type, fn_cellular_respiration_of_sucrose_5: $i > $i).
% 28.89/28.98  tff(decl_22015, type, fn_cellular_respiration_of_sucrose_6: $i > $i).
% 28.89/28.98  tff(decl_22016, type, fn_cellular_respiration_of_sucrose_7: $i > $i).
% 28.89/28.98  tff(decl_22017, type, fn_cellular_respiration_of_sucrose_8: $i > $i).
% 28.89/28.98  tff(decl_22018, type, fn_cellular_respiration_of_sucrose_9: $i > $i).
% 28.89/28.98  tff(decl_22019, type, fn_cellular_respiration_of_sucrose_10: $i > $i).
% 28.89/28.98  tff(decl_22020, type, fn_cellular_respiration_of_sucrose_11: $i > $i).
% 28.89/28.98  tff(decl_22021, type, fn_cellular_respiration_of_sucrose_12: $i > $i).
% 28.89/28.98  tff(decl_22022, type, fn_cellular_respiration_of_sucrose_13: $i > $i).
% 28.89/28.98  tff(decl_22023, type, fn_cellular_respiration_of_sucrose_14: $i > $i).
% 28.89/28.98  tff(decl_22024, type, fn_cellular_respiration_of_sucrose_15: $i > $i).
% 28.89/28.98  tff(decl_22025, type, fn_cellular_respiration_of_sucrose_16: $i > $i).
% 28.89/28.98  tff(decl_22026, type, fn_cellular_respiration_of_sucrose_17: $i > $i).
% 28.89/28.98  tff(decl_22027, type, fn_cellular_respiration_of_sucrose_18: $i > $i).
% 28.89/28.98  tff(decl_22028, type, fn_cellular_respiration_of_sucrose_19: $i > $i).
% 28.89/28.98  tff(decl_22029, type, fn_cellular_respiration_of_sucrose_20: $i > $i).
% 28.89/28.98  tff(decl_22030, type, fn_cellular_respiration_of_sucrose_21: $i > $i).
% 28.89/28.98  tff(decl_22031, type, fn_cellular_respiration_of_sucrose_22: $i > $i).
% 28.89/28.98  tff(decl_22032, type, fn_cellular_respiration_of_sucrose_23: $i > $i).
% 28.89/28.98  tff(decl_22033, type, fn_cellular_respiration_of_sucrose_24: $i > $i).
% 28.89/28.98  tff(decl_22034, type, fn_cellular_respiration_of_sucrose_25: $i > $i).
% 28.89/28.98  tff(decl_22035, type, fn_cellular_respiration_of_sucrose_26: $i > $i).
% 28.89/28.98  tff(decl_22036, type, fn_cellular_respiration_of_sucrose_27: $i > $i).
% 28.89/28.98  tff(decl_22037, type, fn_cellular_respiration_of_sucrose_28: $i > $i).
% 28.89/28.98  tff(decl_22038, type, fn_cellular_respiration_of_sucrose_29: $i > $i).
% 28.89/28.98  tff(decl_22039, type, fn_cellular_respiration_of_sucrose_30: $i > $i).
% 28.89/28.98  tff(decl_22040, type, fn_cellular_respiration_of_sucrose_31: $i > $i).
% 28.89/28.98  tff(decl_22041, type, fn_cellular_respiration_of_sucrose_32: $i > $i).
% 28.89/28.98  tff(decl_22042, type, fn_cellular_respiration_of_sucrose_33: $i > $i).
% 28.89/28.98  tff(decl_22043, type, fn_cellular_respiration_of_sucrose_34: $i > $i).
% 28.89/28.98  tff(decl_22044, type, fn_cellular_respiration_of_sucrose_35: $i > $i).
% 28.89/28.98  tff(decl_22045, type, sucrose_1: $i > $o).
% 28.89/28.98  tff(decl_22046, type, fn_cellular_respiration_of_sucrose_36: $i > $i).
% 28.89/28.98  tff(decl_22047, type, fn_cellular_respiration_of_sucrose_37: $i > $i).
% 28.89/28.98  tff(decl_22048, type, fn_cellular_respiration_of_sucrose_38: $i > $i).
% 28.89/28.98  tff(decl_22049, type, fn_cellular_respiration_of_sucrose_39: $i > $i).
% 28.89/28.98  tff(decl_22050, type, fn_cellular_respiration_of_sucrose_40: $i > $i).
% 28.89/28.98  tff(decl_22051, type, fn_cellular_respiration_of_sucrose_41: $i > $i).
% 28.89/28.98  tff(decl_22052, type, fn_cellular_respiration_of_sucrose_42: $i > $i).
% 28.89/28.98  tff(decl_22053, type, fn_cellular_respiration_of_sucrose_43: $i > $i).
% 28.89/28.98  tff(decl_22054, type, fn_cellular_respiration_of_sucrose_44: $i > $i).
% 28.89/28.98  tff(decl_22055, type, fn_cellular_respiration_of_sucrose_45: $i > $i).
% 28.89/28.98  tff(decl_22056, type, fn_cellular_respiration_of_sucrose_46: $i > $i).
% 28.89/28.98  tff(decl_22057, type, fn_cellular_respiration_of_sucrose_47: $i > $i).
% 28.89/28.98  tff(decl_22058, type, fn_cellular_respiration_of_sucrose_48: $i > $i).
% 28.89/28.98  tff(decl_22059, type, fn_cellular_respiration_of_sucrose_49: $i > $i).
% 28.89/28.98  tff(decl_22060, type, fn_cellular_respiration_of_sucrose_50: $i > $i).
% 28.89/28.98  tff(decl_22061, type, fn_cellular_respiration_of_sucrose_51: $i > $i).
% 28.89/28.98  tff(decl_22062, type, fn_cellular_respiration_of_sucrose_52: $i > $i).
% 28.89/28.98  tff(decl_22063, type, fn_cellular_respiration_of_sucrose_53: $i > $i).
% 28.89/28.98  tff(decl_22064, type, fn_cellular_respiration_of_sucrose_54: $i > $i).
% 28.89/28.98  tff(decl_22065, type, fn_cellular_respiration_of_sucrose_58: $i > $i).
% 28.89/28.98  tff(decl_22066, type, fn_cellular_respiration_of_sucrose_59: $i > $i).
% 28.89/28.98  tff(decl_22067, type, fn_cellular_respiration_of_sucrose_60: $i > $i).
% 28.89/28.98  tff(decl_22068, type, fn_cellular_respiration_of_sucrose_61: $i > $i).
% 28.89/28.98  tff(decl_22069, type, fn_triose_6: $i > $i).
% 28.89/28.98  tff(decl_22070, type, fn_cellular_respiration_of_sucrose_63: $i > $i).
% 28.89/28.98  tff(decl_22071, type, fn_cellular_respiration_of_sucrose_62: $i > $i).
% 28.89/28.98  tff(decl_22072, type, fn_cellular_respiration_of_sucrose_55: $i > $i).
% 28.89/28.98  tff(decl_22073, type, fn_cellular_respiration_of_sucrose_57: $i > $i).
% 28.89/28.98  tff(decl_22074, type, fn_cellular_respiration_of_sucrose_56: $i > $i).
% 28.89/28.98  tff(decl_22075, type, 'Cellular-Respiration-Using-Starch': $i).
% 28.89/28.98  tff(decl_22076, type, 'cellular respiration using starch': $i).
% 28.89/28.98  tff(decl_22077, type, 'cellular-respiration-using-starch': $i).
% 28.89/28.98  tff(decl_22078, type, fn_cellular_respiration_using_starch_3: $i > $i).
% 28.89/28.98  tff(decl_22079, type, fn_cellular_respiration_using_starch_4: $i > $i).
% 28.89/28.98  tff(decl_22080, type, fn_cellular_respiration_using_starch_5: $i > $i).
% 28.89/28.98  tff(decl_22081, type, fn_cellular_respiration_using_starch_6: $i > $i).
% 28.89/28.98  tff(decl_22082, type, fn_cellular_respiration_using_starch_7: $i > $i).
% 28.89/28.98  tff(decl_22083, type, fn_cellular_respiration_using_starch_8: $i > $i).
% 28.89/28.98  tff(decl_22084, type, fn_cellular_respiration_using_starch_9: $i > $i).
% 28.89/28.98  tff(decl_22085, type, fn_cellular_respiration_using_starch_10: $i > $i).
% 28.89/28.98  tff(decl_22086, type, fn_cellular_respiration_using_starch_11: $i > $i).
% 28.89/28.98  tff(decl_22087, type, fn_cellular_respiration_using_starch_12: $i > $i).
% 28.89/28.98  tff(decl_22088, type, fn_cellular_respiration_using_starch_13: $i > $i).
% 28.89/28.98  tff(decl_22089, type, fn_cellular_respiration_using_starch_14: $i > $i).
% 28.89/28.98  tff(decl_22090, type, fn_cellular_respiration_using_starch_15: $i > $i).
% 28.89/28.98  tff(decl_22091, type, fn_cellular_respiration_using_starch_16: $i > $i).
% 28.89/28.98  tff(decl_22092, type, fn_cellular_respiration_using_starch_17: $i > $i).
% 28.89/28.98  tff(decl_22093, type, fn_cellular_respiration_using_starch_18: $i > $i).
% 28.89/28.98  tff(decl_22094, type, fn_cellular_respiration_using_starch_19: $i > $i).
% 28.89/28.98  tff(decl_22095, type, fn_cellular_respiration_using_starch_22: $i > $i).
% 28.89/28.98  tff(decl_22096, type, fn_cellular_respiration_using_starch_23: $i > $i).
% 28.89/28.98  tff(decl_22097, type, fn_cellular_respiration_using_starch_24: $i > $i).
% 28.89/28.98  tff(decl_22098, type, fn_cellular_respiration_using_starch_25: $i > $i).
% 28.89/28.98  tff(decl_22099, type, fn_cellular_respiration_using_starch_26: $i > $i).
% 28.89/28.98  tff(decl_22100, type, fn_cellular_respiration_using_starch_27: $i > $i).
% 28.89/28.98  tff(decl_22101, type, fn_cellular_respiration_using_starch_28: $i > $i).
% 28.89/28.98  tff(decl_22102, type, fn_cellular_respiration_using_starch_29: $i > $i).
% 28.89/28.98  tff(decl_22103, type, fn_cellular_respiration_using_starch_30: $i > $i).
% 28.89/28.98  tff(decl_22104, type, fn_cellular_respiration_using_starch_31: $i > $i).
% 28.89/28.98  tff(decl_22105, type, fn_cellular_respiration_using_starch_32: $i > $i).
% 28.89/28.98  tff(decl_22106, type, fn_cellular_respiration_using_starch_33: $i > $i).
% 28.89/28.98  tff(decl_22107, type, fn_cellular_respiration_using_starch_34: $i > $i).
% 28.89/28.98  tff(decl_22108, type, fn_cellular_respiration_using_starch_35: $i > $i).
% 28.89/28.98  tff(decl_22109, type, fn_cellular_respiration_using_starch_36: $i > $i).
% 28.89/28.98  tff(decl_22110, type, fn_cellular_respiration_using_starch_37: $i > $i).
% 28.89/28.98  tff(decl_22111, type, fn_cellular_respiration_using_starch_38: $i > $i).
% 28.89/28.98  tff(decl_22112, type, fn_cellular_respiration_using_starch_39: $i > $i).
% 28.89/28.98  tff(decl_22113, type, fn_cellular_respiration_using_starch_40: $i > $i).
% 28.89/28.98  tff(decl_22114, type, fn_cellular_respiration_using_starch_41: $i > $i).
% 28.89/28.98  tff(decl_22115, type, fn_cellular_respiration_using_starch_42: $i > $i).
% 28.89/28.98  tff(decl_22116, type, fn_cellular_respiration_using_starch_43: $i > $i).
% 28.89/28.98  tff(decl_22117, type, fn_cellular_respiration_using_starch_44: $i > $i).
% 28.89/28.98  tff(decl_22118, type, fn_cellular_respiration_using_starch_45: $i > $i).
% 28.89/28.98  tff(decl_22119, type, fn_cellular_respiration_using_starch_46: $i > $i).
% 28.89/28.98  tff(decl_22120, type, fn_cellular_respiration_using_starch_47: $i > $i).
% 28.89/28.98  tff(decl_22121, type, fn_cellular_respiration_using_starch_48: $i > $i).
% 28.89/28.98  tff(decl_22122, type, fn_cellular_respiration_using_starch_49: $i > $i).
% 28.89/28.98  tff(decl_22123, type, fn_cellular_respiration_using_starch_50: $i > $i).
% 28.89/28.98  tff(decl_22124, type, fn_cellular_respiration_using_starch_51: $i > $i).
% 28.89/28.98  tff(decl_22125, type, fn_cellular_respiration_using_starch_52: $i > $i).
% 28.89/28.98  tff(decl_22126, type, fn_cellular_respiration_using_starch_53: $i > $i).
% 28.89/28.98  tff(decl_22127, type, fn_cellular_respiration_using_starch_54: $i > $i).
% 28.89/28.98  tff(decl_22128, type, fn_cellular_respiration_using_starch_55: $i > $i).
% 28.89/28.98  tff(decl_22129, type, fn_cellular_respiration_using_starch_56: $i > $i).
% 28.89/28.98  tff(decl_22130, type, fn_cellular_respiration_using_starch_57: $i > $i).
% 28.89/28.98  tff(decl_22131, type, fn_cellular_respiration_using_starch_58: $i > $i).
% 28.89/28.98  tff(decl_22132, type, fn_cellular_respiration_using_starch_59: $i > $i).
% 28.89/28.98  tff(decl_22133, type, fn_cellular_respiration_using_starch_60: $i > $i).
% 28.89/28.98  tff(decl_22134, type, fn_cellular_respiration_using_starch_61: $i > $i).
% 28.89/28.98  tff(decl_22135, type, fn_cellular_respiration_using_starch_62: $i > $i).
% 28.89/28.98  tff(decl_22136, type, fn_cellular_respiration_using_starch_63: $i > $i).
% 28.89/28.98  tff(decl_22137, type, fn_cellular_respiration_using_starch_64: $i > $i).
% 28.89/28.98  tff(decl_22138, type, fn_cellular_respiration_using_starch_65: $i > $i).
% 28.89/28.98  tff(decl_22139, type, fn_cellular_respiration_using_starch_66: $i > $i).
% 28.89/28.98  tff(decl_22140, type, fn_cellular_respiration_using_starch_67: $i > $i).
% 28.89/28.98  tff(decl_22141, type, fn_cellular_respiration_using_starch_68: $i > $i).
% 28.89/28.98  tff(decl_22142, type, fn_cellular_respiration_using_starch_69: $i > $i).
% 28.89/28.98  tff(decl_22143, type, fn_cellular_respiration_using_starch_70: $i > $i).
% 28.89/28.98  tff(decl_22144, type, fn_cellular_respiration_using_starch_71: $i > $i).
% 28.89/28.98  tff(decl_22145, type, fn_cellular_respiration_using_starch_72: $i > $i).
% 28.89/28.98  tff(decl_22146, type, fn_cellular_respiration_using_starch_73: $i > $i).
% 28.89/28.98  tff(decl_22147, type, fn_cellular_respiration_using_starch_78: $i > $i).
% 28.89/28.98  tff(decl_22148, type, fn_cellular_respiration_using_starch_79: $i > $i).
% 28.89/28.98  tff(decl_22149, type, fn_dihydroxyacetone_phosphate_3: $i > $i).
% 28.89/28.98  tff(decl_22150, type, fn_glycolysis_5: $i > $i).
% 28.89/28.98  tff(decl_22151, type, fn_pyruvate_oxidation_52: $i > $i).
% 28.89/28.98  tff(decl_22152, type, fn_pyruvate_oxidation_2: $i > $i).
% 28.89/28.98  tff(decl_22153, type, fn_pyruvate_oxidation_4: $i > $i).
% 28.89/28.98  tff(decl_22154, type, fn_pyruvate_oxidation_5: $i > $i).
% 28.89/28.98  tff(decl_22155, type, fn_cellular_respiration_using_starch_76: $i > $i).
% 28.89/28.98  tff(decl_22156, type, fn_cellular_respiration_using_starch_77: $i > $i).
% 28.89/28.98  tff(decl_22157, type, fn_cellular_respiration_using_starch_20: $i > $i).
% 28.89/28.98  tff(decl_22158, type, fn_cellular_respiration_using_starch_21: $i > $i).
% 28.89/28.98  tff(decl_22159, type, fn_cellular_respiration_using_starch_74: $i > $i).
% 28.89/28.98  tff(decl_22160, type, fn_cellular_respiration_using_starch_75: $i > $i).
% 28.89/28.98  tff(decl_22161, type, 'Cellular-Response': $i).
% 28.89/28.98  tff(decl_22162, type, 'In cellular communication, the change in a specific cellular activity brought about by a transduced signal from outside the cell.': $i).
% 28.89/28.98  tff(decl_22163, type, response: $i).
% 28.89/28.98  tff(decl_22164, type, 'cellular response': $i).
% 28.89/28.98  tff(decl_22165, type, 'cellular-response': $i).
% 28.89/28.98  tff(decl_22166, type, fn_cellular_response_2: $i > $i).
% 28.89/28.98  tff(decl_22167, type, cellular_role_1: $i > $o).
% 28.89/28.98  tff(decl_22168, type, 'Cellular-Role': $i).
% 28.89/28.98  tff(decl_22169, type, 'Role played by a cell.': $i).
% 28.89/28.98  tff(decl_22170, type, 'cellular role': $i).
% 28.89/28.98  tff(decl_22171, type, 'cellular-role': $i).
% 28.89/28.98  tff(decl_22172, type, cellular_slime_mold_1: $i > $o).
% 28.89/28.98  tff(decl_22173, type, 'Cellular-Slime-Mold': $i).
% 28.89/28.98  tff(decl_22174, type, 'A type of protist whose life cycle includes unicellular amoeboid cells and aggregated reproductive bodies.': $i).
% 28.89/28.98  tff(decl_22175, type, 'cellular slime mold': $i).
% 28.89/28.98  tff(decl_22176, type, 'cellular-slime-mold': $i).
% 28.89/28.98  tff(decl_22177, type, mycetozoa_1: $i > $o).
% 28.89/28.98  tff(decl_22178, type, plasmodial_slime_mold_1: $i > $o).
% 28.89/28.98  tff(decl_22179, type, 'Cellular-Structure': $i).
% 28.89/28.98  tff(decl_22180, type, 'A structure on or inside a cell.': $i).
% 28.89/28.98  tff(decl_22181, type, 'cell structure': $i).
% 28.89/28.98  tff(decl_22182, type, 'cellular structure': $i).
% 28.89/28.98  tff(decl_22183, type, 'cellular-structure': $i).
% 28.89/28.98  tff(decl_22184, type, cellular_transport_1: $i > $o).
% 28.89/28.98  tff(decl_22185, type, 'Cellular-Transport': $i).
% 28.89/28.98  tff(decl_22186, type, 'Cellular process related to the transport of materials and water into, out of, and within the cell.': $i).
% 28.89/28.98  tff(decl_22187, type, 'cellular transport': $i).
% 28.89/28.98  tff(decl_22188, type, 'cellular-transport': $i).
% 28.89/28.98  tff(decl_22189, type, fn_cellular_transport_1: $i > $i).
% 28.89/28.98  tff(decl_22190, type, 'Cellular-Work': $i).
% 28.89/28.98  tff(decl_22191, type, 'The work done by cell.': $i).
% 28.89/28.98  tff(decl_22192, type, 'perform cellular work': $i).
% 28.89/28.98  tff(decl_22193, type, 'cellular work': $i).
% 28.89/28.98  tff(decl_22194, type, 'cellular-work': $i).
% 28.89/28.98  tff(decl_22195, type, fn_cellular_work_3: $i > $i).
% 28.89/28.98  tff(decl_22196, type, fn_cellular_work_8: $i > $i).
% 28.89/28.98  tff(decl_22197, type, fn_cellular_work_9: $i > $i).
% 28.89/28.98  tff(decl_22198, type, fn_cellular_respiration_6: $i > $i).
% 28.89/28.98  tff(decl_22199, type, fn_cellular_work_7: $i > $i).
% 28.89/28.98  tff(decl_22200, type, cellular_work_involving_phosphorylation_1: $i > $o).
% 28.89/28.98  tff(decl_22201, type, 'Cellular-Work-Involving-Phosphorylation': $i).
% 28.89/28.98  tff(decl_22202, type, 'Enzymes shift a phosphate group (P) from ATP to some other molecule, and this phosphorylated molecule undergoes a change that performs work.': $i).
% 28.89/28.98  tff(decl_22203, type, 'cellular work involving phosphorylation': $i).
% 28.89/28.98  tff(decl_22204, type, 'cellular-work-involving-phosphorylation': $i).
% 28.89/28.98  tff(decl_22205, type, fn_cellular_work_involving_phosphorylation_1: $i > $i).
% 28.89/28.98  tff(decl_22206, type, 'Cellular-Work-Utilizing-ATP': $i).
% 28.89/28.98  tff(decl_22207, type, 'Adenosine triphosphate is required as raw material for cellular work.': $i).
% 28.89/28.98  tff(decl_22208, type, 'cellular work utilizing atp': $i).
% 28.89/28.98  tff(decl_22209, type, 'cellular-work-utilizing-atp': $i).
% 28.89/28.98  tff(decl_22210, type, fn_cellular_work_utilizing_atp_1: $i > $i).
% 28.89/28.98  tff(decl_22211, type, fn_cellular_work_utilizing_atp_2: $i > $i).
% 28.89/28.98  tff(decl_22212, type, fn_cellular_work_utilizing_atp_7: $i > $i).
% 28.89/28.98  tff(decl_22213, type, inorganic_phosphate_1: $i > $o).
% 28.89/28.98  tff(decl_22214, type, fn_cellular_work_utilizing_atp_8: $i > $i).
% 28.89/28.98  tff(decl_22215, type, fn_cellular_work_utilizing_atp_9: $i > $i).
% 28.89/28.98  tff(decl_22216, type, fn_cellular_work_utilizing_atp_10: $i > $i).
% 28.89/28.98  tff(decl_22217, type, fn_cellular_work_utilizing_atp_11: $i > $i).
% 28.89/28.98  tff(decl_22218, type, fn_cellular_work_utilizing_atp_12: $i > $i).
% 28.89/28.98  tff(decl_22219, type, fn_cellular_work_utilizing_atp_13: $i > $i).
% 28.89/28.98  tff(decl_22220, type, fn_cellular_work_utilizing_atp_14: $i > $i).
% 28.89/28.98  tff(decl_22221, type, fn_cellular_work_utilizing_atp_15: $i > $i).
% 28.89/28.98  tff(decl_22222, type, fn_cellular_work_utilizing_atp_16: $i > $i).
% 28.89/28.98  tff(decl_22223, type, fn_cellular_work_utilizing_atp_17: $i > $i).
% 28.89/28.98  tff(decl_22224, type, fn_cellular_work_utilizing_atp_18: $i > $i).
% 28.89/28.98  tff(decl_22225, type, fn_cellular_work_utilizing_atp_19: $i > $i).
% 28.89/28.98  tff(decl_22226, type, fn_cellular_work_utilizing_atp_20: $i > $i).
% 28.89/28.98  tff(decl_22227, type, fn_cellular_work_utilizing_atp_21: $i > $i).
% 28.89/28.98  tff(decl_22228, type, fn_cellular_work_utilizing_atp_22: $i > $i).
% 28.89/28.98  tff(decl_22229, type, fn_cellular_work_utilizing_atp_23: $i > $i).
% 28.89/28.98  tff(decl_22230, type, fn_cellular_work_utilizing_atp_24: $i > $i).
% 28.89/28.98  tff(decl_22231, type, fn_cellular_work_utilizing_atp_25: $i > $i).
% 28.89/28.98  tff(decl_22232, type, fn_cellular_work_utilizing_atp_26: $i > $i).
% 28.89/28.98  tff(decl_22233, type, fn_cellular_work_utilizing_atp_27: $i > $i).
% 28.89/28.98  tff(decl_22234, type, fn_cellular_work_utilizing_atp_28: $i > $i).
% 28.89/28.98  tff(decl_22235, type, fn_cellular_work_utilizing_atp_29: $i > $i).
% 28.89/28.98  tff(decl_22236, type, fn_cellular_work_utilizing_atp_30: $i > $i).
% 28.89/28.98  tff(decl_22237, type, fn_cellular_work_utilizing_atp_31: $i > $i).
% 28.89/28.98  tff(decl_22238, type, fn_cellular_work_utilizing_atp_32: $i > $i).
% 28.89/28.98  tff(decl_22239, type, fn_cellular_work_utilizing_atp_33: $i > $i).
% 28.89/28.98  tff(decl_22240, type, fn_cellular_work_utilizing_atp_34: $i > $i).
% 28.89/28.98  tff(decl_22241, type, fn_cellular_work_utilizing_atp_35: $i > $i).
% 28.89/28.98  tff(decl_22242, type, fn_cellular_work_utilizing_atp_36: $i > $i).
% 28.89/28.98  tff(decl_22243, type, fn_cellular_work_utilizing_atp_37: $i > $i).
% 28.89/28.98  tff(decl_22244, type, fn_cellular_work_utilizing_atp_38: $i > $i).
% 28.89/28.98  tff(decl_22245, type, fn_cellular_work_utilizing_atp_39: $i > $i).
% 28.89/28.98  tff(decl_22246, type, fn_cellular_work_utilizing_atp_40: $i > $i).
% 28.89/28.98  tff(decl_22247, type, fn_cellular_work_utilizing_atp_41: $i > $i).
% 28.89/28.98  tff(decl_22248, type, fn_cellular_work_utilizing_atp_42: $i > $i).
% 28.89/28.98  tff(decl_22249, type, fn_cellular_work_utilizing_atp_43: $i > $i).
% 28.89/28.98  tff(decl_22250, type, fn_cellular_work_utilizing_atp_44: $i > $i).
% 28.89/28.98  tff(decl_22251, type, fn_cellular_work_utilizing_atp_45: $i > $i).
% 28.89/28.98  tff(decl_22252, type, fn_cellular_work_utilizing_atp_46: $i > $i).
% 28.89/28.98  tff(decl_22253, type, fn_cellular_work_utilizing_atp_47: $i > $i).
% 28.89/28.98  tff(decl_22254, type, fn_cellular_work_utilizing_atp_48: $i > $i).
% 28.89/28.98  tff(decl_22255, type, fn_dephosphorylation_of_atp_81: $i > $i).
% 28.89/28.98  tff(decl_22256, type, fn_dephosphorylation_of_atp_79: $i > $i).
% 28.89/28.98  tff(decl_22257, type, fn_dephosphorylation_of_atp_82: $i > $i).
% 28.89/28.98  tff(decl_22258, type, fn_dephosphorylation_of_atp_78: $i > $i).
% 28.89/28.98  tff(decl_22259, type, fn_dephosphorylation_of_atp_77: $i > $i).
% 28.89/28.98  tff(decl_22260, type, fn_dephosphorylation_of_atp_80: $i > $i).
% 28.89/28.98  tff(decl_22261, type, fn_dephosphorylation_of_atp_68: $i > $i).
% 28.89/28.98  tff(decl_22262, type, fn_dephosphorylation_of_atp_69: $i > $i).
% 28.89/28.98  tff(decl_22263, type, fn_dephosphorylation_of_atp_50: $i > $i).
% 28.89/28.98  tff(decl_22264, type, fn_dephosphorylation_of_atp_66: $i > $i).
% 28.89/28.98  tff(decl_22265, type, fn_dephosphorylation_of_atp_61: $i > $i).
% 28.89/28.98  tff(decl_22266, type, fn_dephosphorylation_of_atp_59: $i > $i).
% 28.89/28.98  tff(decl_22267, type, fn_dephosphorylation_of_atp_75: $i > $i).
% 28.89/28.98  tff(decl_22268, type, fn_dephosphorylation_of_atp_63: $i > $i).
% 28.89/28.98  tff(decl_22269, type, fn_dephosphorylation_of_atp_67: $i > $i).
% 28.89/28.98  tff(decl_22270, type, fn_dephosphorylation_of_atp_58: $i > $i).
% 28.89/28.98  tff(decl_22271, type, fn_dephosphorylation_of_atp_57: $i > $i).
% 28.89/28.98  tff(decl_22272, type, fn_dephosphorylation_of_atp_64: $i > $i).
% 28.89/28.98  tff(decl_22273, type, fn_dephosphorylation_of_atp_76: $i > $i).
% 28.89/28.98  tff(decl_22274, type, fn_cellular_work_utilizing_atp_5: $i > $i).
% 28.89/28.98  tff(decl_22275, type, fn_cellular_work_utilizing_atp_6: $i > $i).
% 28.89/28.98  tff(decl_22276, type, fn_cellular_work_utilizing_atp_3: $i > $i).
% 28.89/28.98  tff(decl_22277, type, fn_cellular_work_utilizing_atp_4: $i > $i).
% 28.89/28.98  tff(decl_22278, type, 'Cellulase': $i).
% 28.89/28.98  tff(decl_22279, type, 'An enzyme that catalyzes the hydrolysis of cellulose.': $i).
% 28.89/28.98  tff(decl_22280, type, cellulase: $i).
% 28.89/28.98  tff(decl_22281, type, 'Cellulose': $i).
% 28.89/28.98  tff(decl_22282, type, 'A polysaccharide consisting of glucose monomers joined by beta-glycosidic linkages. Cellulose is the structural component of plant cell walls.': $i).
% 28.89/28.98  tff(decl_22283, type, cellulose: $i).
% 28.89/28.98  tff(decl_22284, type, 'insoluble fibers': $i).
% 28.89/28.98  tff(decl_22285, type, chitin_1: $i > $o).
% 28.89/28.98  tff(decl_22286, type, fn_cellulose_1: $i > $i).
% 28.89/28.98  tff(decl_22287, type, fn_cellulose_2: $i > $i).
% 28.89/28.98  tff(decl_22288, type, fn_cellulose_4: $i > $i).
% 28.89/28.98  tff(decl_22289, type, fn_cellulose_5: $i > $i).
% 28.89/28.98  tff(decl_22290, type, fn_cellulose_8: $i > $i).
% 28.89/28.98  tff(decl_22291, type, fn_cellulose_9: $i > $i).
% 28.89/28.98  tff(decl_22292, type, fn_cellulose_10: $i > $i).
% 28.89/28.98  tff(decl_22293, type, fn_cellulose_11: $i > $i).
% 28.89/28.98  tff(decl_22294, type, fn_cellulose_12: $i > $i).
% 28.89/28.98  tff(decl_22295, type, fn_cellulose_13: $i > $i).
% 28.89/28.98  tff(decl_22296, type, fn_cellulose_14: $i > $i).
% 28.89/28.98  tff(decl_22297, type, fn_cellulose_16: $i > $i).
% 28.89/28.98  tff(decl_22298, type, fn_cellulose_17: $i > $i).
% 28.89/28.98  tff(decl_22299, type, fn_cellulose_18: $i > $i).
% 28.89/28.98  tff(decl_22300, type, fn_cellulose_19: $i > $i).
% 28.89/28.98  tff(decl_22301, type, fn_cellulose_20: $i > $i).
% 28.89/28.98  tff(decl_22302, type, fn_cellulose_21: $i > $i).
% 28.89/28.98  tff(decl_22303, type, fn_cellulose_22: $i > $i).
% 28.89/28.98  tff(decl_22304, type, fn_cellulose_23: $i > $i).
% 28.89/28.98  tff(decl_22305, type, fn_cellulose_24: $i > $i).
% 28.89/28.98  tff(decl_22306, type, fn_cellulose_25: $i > $i).
% 28.89/28.98  tff(decl_22307, type, fn_cellulose_26: $i > $i).
% 28.89/28.98  tff(decl_22308, type, fn_cellulose_27: $i > $i).
% 28.89/28.98  tff(decl_22309, type, fn_cellulose_28: $i > $i).
% 28.89/28.98  tff(decl_22310, type, fn_cellulose_29: $i > $i).
% 28.89/28.98  tff(decl_22311, type, fn_cellulose_30: $i > $i).
% 28.89/28.98  tff(decl_22312, type, fn_cellulose_31: $i > $i).
% 28.89/28.98  tff(decl_22313, type, fn_cellulose_32: $i > $i).
% 28.89/28.98  tff(decl_22314, type, fn_cellulose_36: $i > $i).
% 28.89/28.98  tff(decl_22315, type, fn_cellulose_38: $i > $i).
% 28.89/28.98  tff(decl_22316, type, fn_cellulose_39: $i > $i).
% 28.89/28.98  tff(decl_22317, type, fn_cellulose_40: $i > $i).
% 28.89/28.98  tff(decl_22318, type, fn_cellulose_41: $i > $i).
% 28.89/28.98  tff(decl_22319, type, fn_cellulose_42: $i > $i).
% 28.89/28.98  tff(decl_22320, type, fn_cellulose_43: $i > $i).
% 28.89/28.98  tff(decl_22321, type, fn_cellulose_44: $i > $i).
% 28.89/28.98  tff(decl_22322, type, fn_cellulose_45: $i > $i).
% 28.89/28.98  tff(decl_22323, type, fn_cellulose_46: $i > $i).
% 28.89/28.98  tff(decl_22324, type, fn_cellulose_47: $i > $i).
% 28.89/28.98  tff(decl_22325, type, fn_cellulose_48: $i > $i).
% 28.89/28.98  tff(decl_22326, type, fn_cellulose_53: $i > $i).
% 28.89/28.98  tff(decl_22327, type, fn_cellulose_54: $i > $i).
% 28.89/28.98  tff(decl_22328, type, fn_cellulose_55: $i > $i).
% 28.89/28.98  tff(decl_22329, type, fn_cellulose_56: $i > $i).
% 28.89/28.98  tff(decl_22330, type, fn_cellulose_57: $i > $i).
% 28.89/28.98  tff(decl_22331, type, fn_cellulose_58: $i > $i).
% 28.89/28.98  tff(decl_22332, type, fn_cellulose_59: $i > $i).
% 28.89/28.98  tff(decl_22333, type, fn_cellulose_60: $i > $i).
% 28.89/28.98  tff(decl_22334, type, fn_cellulose_61: $i > $i).
% 28.89/28.98  tff(decl_22335, type, fn_cellulose_62: $i > $i).
% 28.89/28.98  tff(decl_22336, type, fn_cellulose_63: $i > $i).
% 28.89/28.98  tff(decl_22337, type, fn_cellulose_64: $i > $i).
% 28.89/28.98  tff(decl_22338, type, fn_cellulose_65: $i > $i).
% 28.89/28.98  tff(decl_22339, type, fn_cellulose_66: $i > $i).
% 28.89/28.98  tff(decl_22340, type, fn_cellulose_67: $i > $i).
% 28.89/28.98  tff(decl_22341, type, fn_cellulose_68: $i > $i).
% 28.89/28.98  tff(decl_22342, type, fn_cellulose_69: $i > $i).
% 28.89/28.98  tff(decl_22343, type, fn_cellulose_70: $i > $i).
% 28.89/28.98  tff(decl_22344, type, fn_polysaccharide_24: $i > $i).
% 28.89/28.98  tff(decl_22345, type, fn_polysaccharide_23: $i > $i).
% 28.89/28.98  tff(decl_22346, type, fn_polar_molecule_4: $i > $i).
% 28.89/28.98  tff(decl_22347, type, fn_polar_molecule_1: $i > $i).
% 28.89/28.98  tff(decl_22348, type, fn_cellulose_49: $i > $i).
% 28.89/28.98  tff(decl_22349, type, fn_polysaccharide_17: $i > $i).
% 28.89/28.98  tff(decl_22350, type, fn_polysaccharide_29: $i > $i).
% 28.89/28.98  tff(decl_22351, type, fn_cellulose_50: $i > $i).
% 28.89/28.98  tff(decl_22352, type, fn_polysaccharide_19: $i > $i).
% 28.89/28.98  tff(decl_22353, type, fn_cellulose_51: $i > $i).
% 28.89/28.98  tff(decl_22354, type, fn_polysaccharide_20: $i > $i).
% 28.89/28.98  tff(decl_22355, type, fn_cellulose_15: $i > $i).
% 28.89/28.98  tff(decl_22356, type, fn_polysaccharide_10: $i > $i).
% 28.89/28.98  tff(decl_22357, type, fn_cellulose_71: $i > $i).
% 28.89/28.98  tff(decl_22358, type, fn_polysaccharide_2: $i > $i).
% 28.89/28.98  tff(decl_22359, type, fn_polysaccharide_28: $i > $i).
% 28.89/28.98  tff(decl_22360, type, fn_cellulose_72: $i > $i).
% 28.89/28.98  tff(decl_22361, type, fn_polysaccharide_1: $i > $i).
% 28.89/28.98  tff(decl_22362, type, fn_polysaccharide_22: $i > $i).
% 28.89/28.98  tff(decl_22363, type, fn_polysaccharide_21: $i > $i).
% 28.89/28.98  tff(decl_22364, type, fn_polysaccharide_27: $i > $i).
% 28.89/28.98  tff(decl_22365, type, fn_polysaccharide_18: $i > $i).
% 28.89/28.98  tff(decl_22366, type, fn_polysaccharide_14: $i > $i).
% 28.89/28.98  tff(decl_22367, type, fn_polysaccharide_25: $i > $i).
% 28.89/28.98  tff(decl_22368, type, fn_polysaccharide_3: $i > $i).
% 28.89/28.98  tff(decl_22369, type, fn_polysaccharide_7: $i > $i).
% 28.89/28.98  tff(decl_22370, type, fn_polysaccharide_6: $i > $i).
% 28.89/28.98  tff(decl_22371, type, fn_polysaccharide_5: $i > $i).
% 28.89/28.98  tff(decl_22372, type, fn_polysaccharide_8: $i > $i).
% 28.89/28.98  tff(decl_22373, type, fn_polysaccharide_15: $i > $i).
% 28.89/28.98  tff(decl_22374, type, fn_structural_polysaccharide_3: $i > $i).
% 28.89/28.98  tff(decl_22375, type, fn_structural_polysaccharide_1: $i > $i).
% 28.89/28.98  tff(decl_22376, type, fn_structural_polysaccharide_6: $i > $i).
% 28.89/28.98  tff(decl_22377, type, fn_structural_polysaccharide_4: $i > $i).
% 28.89/28.98  tff(decl_22378, type, fn_cellulose_52: $i > $i).
% 28.89/28.98  tff(decl_22379, type, cellulose_digesting_bacteria_1: $i > $o).
% 28.89/28.98  tff(decl_22380, type, 'Cellulose-Digesting-Bacteria': $i).
% 28.89/28.98  tff(decl_22381, type, 'Bacteria that break down cellulose; contained in the stomach of ruminants.': $i).
% 28.89/28.98  tff(decl_22382, type, 'cellulose digesting bacterium': $i).
% 28.89/28.98  tff(decl_22383, type, 'cellulose-digesting bacterium': $i).
% 28.89/28.98  tff(decl_22384, type, 'cellulose-digesting-bacteria': $i).
% 28.89/28.98  tff(decl_22385, type, escherichia_coli_1: $i > $o).
% 28.89/28.98  tff(decl_22386, type, gram_positive_bacteria_1: $i > $o).
% 28.89/28.98  tff(decl_22387, type, mycoplasma_1: $i > $o).
% 28.89/28.98  tff(decl_22388, type, fn_cellulose_digesting_bacteria_1: $i > $i).
% 28.89/28.98  tff(decl_22389, type, fn_cellulose_digesting_bacteria_2: $i > $i).
% 28.89/28.98  tff(decl_22390, type, cellulose_digestion_1: $i > $o).
% 28.89/28.98  tff(decl_22391, type, fn_cellulose_digesting_bacteria_3: $i > $i).
% 28.89/28.98  tff(decl_22392, type, fn_cellulose_digesting_bacteria_4: $i > $i).
% 28.89/28.98  tff(decl_22393, type, fn_cellulose_digesting_bacteria_5: $i > $i).
% 28.89/28.98  tff(decl_22394, type, fn_cellulose_digesting_bacteria_6: $i > $i).
% 28.89/28.98  tff(decl_22395, type, fn_cellulose_digesting_bacteria_7: $i > $i).
% 28.89/28.98  tff(decl_22396, type, fn_cellulose_digesting_bacteria_8: $i > $i).
% 28.89/28.98  tff(decl_22397, type, fn_cellulose_digesting_bacteria_9: $i > $i).
% 28.89/28.98  tff(decl_22398, type, fn_cellulose_digesting_bacteria_10: $i > $i).
% 28.89/28.98  tff(decl_22399, type, fn_cellulose_digesting_bacteria_11: $i > $i).
% 28.89/28.98  tff(decl_22400, type, fn_cellulose_digesting_bacteria_12: $i > $i).
% 28.89/28.98  tff(decl_22401, type, fn_cellulose_digesting_bacteria_13: $i > $i).
% 28.89/28.98  tff(decl_22402, type, fn_cellulose_digesting_bacteria_14: $i > $i).
% 28.89/28.98  tff(decl_22403, type, fn_cellulose_digesting_bacteria_15: $i > $i).
% 28.89/28.98  tff(decl_22404, type, fn_cellulose_digesting_bacteria_16: $i > $i).
% 28.89/28.98  tff(decl_22405, type, fn_cellulose_digesting_bacteria_17: $i > $i).
% 28.89/28.98  tff(decl_22406, type, fn_cellulose_digestion_4: $i > $i).
% 28.89/28.98  tff(decl_22407, type, fn_cellulose_digesting_bacteria_19: $i > $i).
% 28.89/28.98  tff(decl_22408, type, fn_cellulose_digesting_bacteria_18: $i > $i).
% 28.89/28.98  tff(decl_22409, type, fn_cellulose_digesting_bacteria_20: $i > $i).
% 28.89/28.98  tff(decl_22410, type, fn_cellulose_digesting_bacteria_21: $i > $i).
% 28.89/28.98  tff(decl_22411, type, cellulose_digesting_fungus_1: $i > $o).
% 28.89/28.98  tff(decl_22412, type, 'Cellulose-Digesting-Fungus': $i).
% 28.89/28.98  tff(decl_22413, type, 'Fungus that break down cellulose; contained in the stomach of ruminants.': $i).
% 28.89/28.98  tff(decl_22414, type, 'cellulose digesting fungus': $i).
% 28.89/28.98  tff(decl_22415, type, 'cellulose-digesting-fungus': $i).
% 28.89/28.98  tff(decl_22416, type, fn_cellulose_digesting_fungus_1: $i > $i).
% 28.89/28.98  tff(decl_22417, type, fn_cellulose_digesting_fungus_2: $i > $i).
% 28.89/28.98  tff(decl_22418, type, 'Cellulose-Digestion': $i).
% 28.89/28.98  tff(decl_22419, type, 'The process of digestion (breaking down) of cellulose.': $i).
% 28.89/28.98  tff(decl_22420, type, 'digestion of cellulose': $i).
% 28.89/28.98  tff(decl_22421, type, 'cellulose digestion': $i).
% 28.89/28.98  tff(decl_22422, type, 'cellulose-digestion': $i).
% 28.89/28.98  tff(decl_22423, type, fn_cellulose_digestion_1: $i > $i).
% 28.89/28.98  tff(decl_22424, type, fn_cellulose_digestion_3: $i > $i).
% 28.89/28.98  tff(decl_22425, type, fn_cellulose_digestion_5: $i > $i).
% 28.89/28.98  tff(decl_22426, type, fn_cellulose_digestion_6: $i > $i).
% 28.89/28.98  tff(decl_22427, type, fn_cellulose_digestion_7: $i > $i).
% 28.89/28.98  tff(decl_22428, type, fn_cellulose_digestion_9: $i > $i).
% 28.89/28.98  tff(decl_22429, type, fn_cellulose_digestion_10: $i > $i).
% 28.89/28.98  tff(decl_22430, type, fn_cellulose_digestion_11: $i > $i).
% 28.89/28.98  tff(decl_22431, type, fn_cellulose_digestion_12: $i > $i).
% 28.89/28.98  tff(decl_22432, type, fn_cellulose_digestion_13: $i > $i).
% 28.89/28.98  tff(decl_22433, type, fn_cellulose_digestion_14: $i > $i).
% 28.89/28.98  tff(decl_22434, type, fn_cellulose_digestion_15: $i > $i).
% 28.89/28.98  tff(decl_22435, type, fn_cellulose_digestion_16: $i > $i).
% 28.89/28.98  tff(decl_22436, type, fn_cellulose_digestion_17: $i > $i).
% 28.89/28.98  tff(decl_22437, type, fn_cellulose_digestion_18: $i > $i).
% 28.89/28.98  tff(decl_22438, type, fn_cellulose_digestion_19: $i > $i).
% 28.89/28.98  tff(decl_22439, type, fn_cellulose_digestion_20: $i > $i).
% 28.89/28.98  tff(decl_22440, type, fn_cellulose_digestion_21: $i > $i).
% 28.89/28.98  tff(decl_22441, type, fn_cellulose_digestion_22: $i > $i).
% 28.89/28.98  tff(decl_22442, type, fn_cellulose_digestion_23: $i > $i).
% 28.89/28.98  tff(decl_22443, type, fn_cellulose_digestion_24: $i > $i).
% 28.89/28.98  tff(decl_22444, type, fn_cellulose_digestion_8: $i > $i).
% 28.89/28.98  tff(decl_22445, type, 'Cellulose-Synthase': $i).
% 28.89/28.98  tff(decl_22446, type, 'Cellulose synthase is an enzyme which combines sugar residues to create the polysaccharide cellulose.': $i).
% 28.89/28.98  tff(decl_22447, type, 'cellulose synthase': $i).
% 28.89/28.98  tff(decl_22448, type, 'cellulose-synthase': $i).
% 28.89/28.98  tff(decl_22449, type, fn_cellulose_synthase_4: $i > $i).
% 28.89/28.98  tff(decl_22450, type, fn_cellulose_synthase_5: $i > $i).
% 28.89/28.98  tff(decl_22451, type, fn_cellulose_synthase_6: $i > $i).
% 28.89/28.98  tff(decl_22452, type, fn_cellulose_synthase_7: $i > $i).
% 28.89/28.98  tff(decl_22453, type, fn_cellulose_synthase_8: $i > $i).
% 28.89/28.98  tff(decl_22454, type, fn_cellulose_synthase_9: $i > $i).
% 28.89/28.98  tff(decl_22455, type, fn_cellulose_synthase_10: $i > $i).
% 28.89/28.98  tff(decl_22456, type, fn_cellulose_synthase_11: $i > $i).
% 28.89/28.98  tff(decl_22457, type, fn_cellulose_synthase_12: $i > $i).
% 28.89/28.98  tff(decl_22458, type, fn_cellulose_synthase_13: $i > $i).
% 28.89/28.98  tff(decl_22459, type, fn_cellulose_synthase_14: $i > $i).
% 28.89/28.98  tff(decl_22460, type, fn_cellulose_synthase_15: $i > $i).
% 28.89/28.98  tff(decl_22461, type, fn_cellulose_synthase_16: $i > $i).
% 28.89/28.98  tff(decl_22462, type, fn_cellulose_synthase_17: $i > $i).
% 28.89/28.98  tff(decl_22463, type, fn_cellulose_synthase_18: $i > $i).
% 28.89/28.98  tff(decl_22464, type, fn_cellulose_synthase_19: $i > $i).
% 28.89/28.98  tff(decl_22465, type, fn_cellulose_synthase_20: $i > $i).
% 28.89/28.98  tff(decl_22466, type, synthesis_of_cellulose_1: $i > $o).
% 28.89/28.98  tff(decl_22467, type, fn_cellulose_synthase_21: $i > $i).
% 28.89/28.98  tff(decl_22468, type, fn_cellulose_synthase_22: $i > $i).
% 28.89/28.98  tff(decl_22469, type, fn_cellulose_synthase_23: $i > $i).
% 28.89/28.98  tff(decl_22470, type, fn_cellulose_synthase_24: $i > $i).
% 28.89/28.98  tff(decl_22471, type, fn_cellulose_synthase_25: $i > $i).
% 28.89/28.98  tff(decl_22472, type, fn_cellulose_synthase_26: $i > $i).
% 28.89/28.98  tff(decl_22473, type, fn_cellulose_synthase_27: $i > $i).
% 28.89/28.98  tff(decl_22474, type, fn_cellulose_synthase_28: $i > $i).
% 28.89/28.98  tff(decl_22475, type, fn_polymer_synthesis_24: $i > $i).
% 28.89/28.98  tff(decl_22476, type, fn_polymer_synthesis_7: $i > $i).
% 28.89/28.98  tff(decl_22477, type, fn_polymer_synthesis_22: $i > $i).
% 28.89/28.98  tff(decl_22478, type, fn_polymer_synthesis_20: $i > $i).
% 28.89/28.98  tff(decl_22479, type, fn_enzyme_8: $i > $i).
% 28.89/28.98  tff(decl_22480, type, fn_enzyme_7: $i > $i).
% 28.89/28.98  tff(decl_22481, type, fn_cellulose_synthase_29: $i > $i).
% 28.89/28.98  tff(decl_22482, type, fn_cellulose_synthase_2: $i > $i).
% 28.89/28.98  tff(decl_22483, type, fn_cellulose_synthase_3: $i > $i).
% 28.89/28.98  tff(decl_22484, type, 'Center': $i).
% 28.89/28.98  tff(decl_22485, type, 'Middle region.': $i).
% 28.89/28.98  tff(decl_22486, type, centre: $i).
% 28.89/28.98  tff(decl_22487, type, middle: $i).
% 28.89/28.98  tff(decl_22488, type, center: $i).
% 28.89/28.98  tff(decl_22489, type, centipede_1: $i > $o).
% 28.89/28.98  tff(decl_22490, type, 'Centipede': $i).
% 28.89/28.98  tff(decl_22491, type, 'A terrestrial arthropod of the clade Chilopoda characterized by distinctly segmented bodies. Each body segment, of which there can be from 20 to 300, bears a pair of walking legs. The walking leg of the first body segment is modified into a forcipule, a venom claw used to capture prey.': $i).
% 28.89/28.98  tff(decl_22492, type, centipede: $i).
% 28.89/28.98  tff(decl_22493, type, myriapod_1: $i > $o).
% 28.89/28.98  tff(decl_22494, type, millipede_1: $i > $o).
% 28.89/28.98  tff(decl_22495, type, 'Central-Canal': $i).
% 28.89/28.98  tff(decl_22496, type, 'Canal running down the center of the spinal cord, filled with cerebrospinal fluid and continuous with the ventricular system of the brain.': $i).
% 28.89/28.98  tff(decl_22497, type, 'canal of central': $i).
% 28.89/28.98  tff(decl_22498, type, 'central canal': $i).
% 28.89/28.98  tff(decl_22499, type, 'central-canal': $i).
% 28.89/28.98  tff(decl_22500, type, central_dogma_1: $i > $o).
% 28.89/28.98  tff(decl_22501, type, 'Central-Dogma': $i).
% 28.89/28.98  tff(decl_22502, type, 'The theory that information flows from DNA to RNA to protein.': $i).
% 28.89/28.98  tff(decl_22503, type, 'flow of genetic information': $i).
% 28.89/28.98  tff(decl_22504, type, 'flow-of-genetic-information': $i).
% 28.89/28.98  tff(decl_22505, type, 'genetic information flow': $i).
% 28.89/28.98  tff(decl_22506, type, 'genetic-information-flow': $i).
% 28.89/28.98  tff(decl_22507, type, 'dogma of central': $i).
% 28.89/28.98  tff(decl_22508, type, 'central dogma': $i).
% 28.89/28.98  tff(decl_22509, type, 'central-dogma': $i).
% 28.89/28.98  tff(decl_22510, type, transmission_of_information_1: $i > $o).
% 28.89/28.98  tff(decl_22511, type, fn_central_dogma_1: $i > $i).
% 28.89/28.98  tff(decl_22512, type, fn_central_dogma_2: $i > $i).
% 28.89/28.98  tff(decl_22513, type, fn_central_dogma_3: $i > $i).
% 28.89/28.98  tff(decl_22514, type, fn_central_dogma_4: $i > $i).
% 28.89/28.98  tff(decl_22515, type, fn_central_dogma_5: $i > $i).
% 28.89/28.98  tff(decl_22516, type, fn_central_dogma_6: $i > $i).
% 28.89/28.98  tff(decl_22517, type, fn_central_dogma_7: $i > $i).
% 28.89/28.98  tff(decl_22518, type, fn_central_dogma_8: $i > $i).
% 28.89/28.98  tff(decl_22519, type, fn_central_dogma_9: $i > $i).
% 28.89/28.98  tff(decl_22520, type, fn_central_dogma_10: $i > $i).
% 28.89/28.98  tff(decl_22521, type, fn_central_dogma_11: $i > $i).
% 28.89/28.98  tff(decl_22522, type, fn_central_dogma_12: $i > $i).
% 28.89/28.98  tff(decl_22523, type, dna_replication_1: $i > $o).
% 28.89/28.98  tff(decl_22524, type, fn_central_dogma_13: $i > $i).
% 28.89/28.98  tff(decl_22525, type, fn_dna_replication_27: $i > $i).
% 28.89/28.98  tff(decl_22526, type, fn_synthesis_of_nucleic_acid_6: $i > $i).
% 28.89/28.98  tff(decl_22527, type, fn_dna_replication_23: $i > $i).
% 28.89/28.98  tff(decl_22528, type, central_nervous_system_1: $i > $o).
% 28.89/28.98  tff(decl_22529, type, 'Central-Nervous-System': $i).
% 28.89/28.98  tff(decl_22530, type, 'The brain and spinal cord of the vertebrate nervous system.': $i).
% 28.89/28.98  tff(decl_22531, type, 'central nervous system': $i).
% 28.89/28.98  tff(decl_22532, type, 'central nervous-system': $i).
% 28.89/28.98  tff(decl_22533, type, 'central-nervous-system': $i).
% 28.89/28.98  tff(decl_22534, type, enteric_division_1: $i > $o).
% 28.89/28.98  tff(decl_22535, type, nerve_net_1: $i > $o).
% 28.89/28.98  tff(decl_22536, type, 'Central-Vacuole': $i).
% 28.89/28.98  tff(decl_22537, type, 'Central vacuole is a prominent organelle in older plant cells. Its functions include storage and breakdown of waste products. It is generally the largest compartment of a plant cell': $i).
% 28.89/28.98  tff(decl_22538, type, 'vacuole of central': $i).
% 28.89/28.98  tff(decl_22539, type, 'central vacuole': $i).
% 28.89/28.98  tff(decl_22540, type, 'central-vacuole': $i).
% 28.89/28.98  tff(decl_22541, type, contractile_vacuole_1: $i > $o).
% 28.89/28.98  tff(decl_22542, type, fn_central_vacuole_1: $i > $i).
% 28.89/28.98  tff(decl_22543, type, fn_central_vacuole_4: $i > $i).
% 28.89/28.98  tff(decl_22544, type, fn_central_vacuole_5: $i > $i).
% 28.89/28.98  tff(decl_22545, type, fn_central_vacuole_6: $i > $i).
% 28.89/28.98  tff(decl_22546, type, fn_central_vacuole_7: $i > $i).
% 28.89/28.98  tff(decl_22547, type, fn_central_vacuole_8: $i > $i).
% 28.89/28.98  tff(decl_22548, type, fn_central_vacuole_9: $i > $i).
% 28.89/28.98  tff(decl_22549, type, fn_central_vacuole_10: $i > $i).
% 28.89/28.98  tff(decl_22550, type, fn_central_vacuole_11: $i > $i).
% 28.89/28.98  tff(decl_22551, type, fn_central_vacuole_12: $i > $i).
% 28.89/28.98  tff(decl_22552, type, fn_central_vacuole_14: $i > $i).
% 28.89/28.98  tff(decl_22553, type, fn_central_vacuole_16: $i > $i).
% 28.89/28.98  tff(decl_22554, type, fn_central_vacuole_17: $i > $i).
% 28.89/28.98  tff(decl_22555, type, fn_central_vacuole_18: $i > $i).
% 28.89/28.98  tff(decl_22556, type, tonoplast_1: $i > $o).
% 28.89/28.98  tff(decl_22557, type, fn_central_vacuole_19: $i > $i).
% 28.89/28.98  tff(decl_22558, type, fn_central_vacuole_20: $i > $i).
% 28.89/28.98  tff(decl_22559, type, fn_central_vacuole_21: $i > $i).
% 28.89/28.98  tff(decl_22560, type, fn_central_vacuole_22: $i > $i).
% 28.89/28.98  tff(decl_22561, type, fn_substance_4: $i > $i).
% 28.89/28.98  tff(decl_22562, type, fn_substance_3: $i > $i).
% 28.89/28.98  tff(decl_22563, type, vesicle_0: $i).
% 28.89/28.98  tff(decl_22564, type, fn_vacuole_9: $i > $i).
% 28.89/28.98  tff(decl_22565, type, fn_vacuole_7: $i > $i).
% 28.89/28.98  tff(decl_22566, type, fn_central_vacuole_15: $i > $i).
% 28.89/28.98  tff(decl_22567, type, fn_vacuole_5: $i > $i).
% 28.89/28.98  tff(decl_22568, type, fn_vacuole_4: $i > $i).
% 28.89/28.98  tff(decl_22569, type, fn_vacuole_6: $i > $i).
% 28.89/28.98  tff(decl_22570, type, fn_vacuole_3: $i > $i).
% 28.89/28.98  tff(decl_22571, type, fn_central_vacuole_13: $i > $i).
% 28.89/28.98  tff(decl_22572, type, 'Centrifugation': $i).
% 28.89/28.98  tff(decl_22573, type, 'The process of separating substances by the use of a centrifugal force. The instrument used for this is Centrifuge.': $i).
% 28.89/28.98  tff(decl_22574, type, 'undergo centrifugation': $i).
% 28.89/28.98  tff(decl_22575, type, centrifuge: $i).
% 28.89/28.98  tff(decl_22576, type, centrifugation: $i).
% 28.89/28.98  tff(decl_22577, type, fn_centrifugation_2: $i > $i).
% 28.89/28.98  tff(decl_22578, type, 'Centrifuge': $i).
% 28.89/28.98  tff(decl_22579, type, 'An apparatus that uses centrifugal force to separate particles from a suspension.': $i).
% 28.89/28.98  tff(decl_22580, type, 'Centriole': $i).
% 28.89/28.98  tff(decl_22581, type, 'Centriole is a subcellular organelle present in centrosome. It is involved in the organisation of the mitotic spindle and it has an important role in the cytokinesis. Centriole has a basic structure similar to Basal body': $i).
% 28.89/28.98  tff(decl_22582, type, centriole: $i).
% 28.89/28.98  tff(decl_22583, type, fn_centriole_3: $i > $i).
% 28.89/28.98  tff(decl_22584, type, fn_centriole_4: $i > $i).
% 28.89/28.98  tff(decl_22585, type, fn_centriole_5: $i > $i).
% 28.89/28.98  tff(decl_22586, type, trimer_0: $i).
% 28.89/28.98  tff(decl_22587, type, chromosome_region_1: $i > $o).
% 28.89/28.98  tff(decl_22588, type, fn_centromere_3: $i > $i).
% 28.89/28.98  tff(decl_22589, type, fn_centromere_2: $i > $i).
% 28.89/28.98  tff(decl_22590, type, 'Centromere': $i).
% 28.89/28.98  tff(decl_22591, type, 'Centromere is a region of chromosome where two identical sister chromatids (components of a replicated chromosome) are attached to each other': $i).
% 28.89/28.98  tff(decl_22592, type, centromere: $i).
% 28.89/28.98  tff(decl_22593, type, fn_centromere_1: $i > $i).
% 28.89/28.98  tff(decl_22594, type, 'Centrosome': $i).
% 28.89/28.98  tff(decl_22595, type, 'The centrosome is an organelle that serves as the main Microtubule Organizing Center (MTOC) of eukaryotic cells. Centrosomes play an important role during cell division.': $i).
% 28.89/28.98  tff(decl_22596, type, 'microtubule organising center': $i).
% 28.89/28.98  tff(decl_22597, type, 'microtubule organising centre': $i).
% 28.89/28.98  tff(decl_22598, type, 'microtubule organizing center': $i).
% 28.89/28.98  tff(decl_22599, type, 'microtubule organizing centre': $i).
% 28.89/28.98  tff(decl_22600, type, 'spindle pole': $i).
% 28.89/28.98  tff(decl_22601, type, 'spindle-pole': $i).
% 28.89/28.98  tff(decl_22602, type, mtoc: $i).
% 28.89/28.98  tff(decl_22603, type, 'microtubule-organizing-center': $i).
% 28.89/28.98  tff(decl_22604, type, centrosome: $i).
% 28.89/28.98  tff(decl_22605, type, microtubule_organizing_center_1: $i > $o).
% 28.89/28.98  tff(decl_22606, type, centriole_0: $i).
% 28.89/28.98  tff(decl_22607, type, fn_microtubule_organizing_center_1: $i > $i).
% 28.89/28.98  tff(decl_22608, type, fn_microtubule_organizing_center_5: $i > $i).
% 28.89/28.98  tff(decl_22609, type, 'Cephalization': $i).
% 28.89/28.98  tff(decl_22610, type, 'The formation of a head, bearing the majority of the sensory apparatus and the neural capacity to interpret and integrate sensory information, at the anterior end of the body.': $i).
% 28.89/28.98  tff(decl_22611, type, cephalization: $i).
% 28.89/28.98  tff(decl_22612, type, cephalochordate_1: $i > $o).
% 28.89/28.98  tff(decl_22613, type, 'Cephalochordate': $i).
% 28.89/28.98  tff(decl_22614, type, 'A member of the invertebrate chordate subphylum Cephalochordata, which retain the notochord throughout life and are represented by the lancelets.': $i).
% 28.89/28.98  tff(decl_22615, type, lancelet: $i).
% 28.89/28.98  tff(decl_22616, type, cephalochordate: $i).
% 28.89/28.98  tff(decl_22617, type, craniate_1: $i > $o).
% 28.89/28.98  tff(decl_22618, type, tunicate_1: $i > $o).
% 28.89/28.98  tff(decl_22619, type, 'Cephalopod': $i).
% 28.89/28.98  tff(decl_22620, type, 'A member of the molluscan class Cephalopoda, characterized by a high degree of cephalization and jet propulsion.  Octopuses, squids, cuttles, and nautiluses are examples of cephalopods.': $i).
% 28.89/28.98  tff(decl_22621, type, cephalopod: $i).
% 28.89/28.98  tff(decl_22622, type, 'Cerebellum': $i).
% 28.89/28.98  tff(decl_22623, type, 'A region of the vertebrate hindbrain, located dorsally, that plays an important role in motor control and balance.': $i).
% 28.89/28.98  tff(decl_22624, type, cerebellum: $i).
% 28.89/28.98  tff(decl_22625, type, medulla_oblongata_1: $i > $o).
% 28.89/28.98  tff(decl_22626, type, pons_1: $i > $o).
% 28.89/28.98  tff(decl_22627, type, reticular_system_1: $i > $o).
% 28.89/28.98  tff(decl_22628, type, 'Cerebral-Cortex': $i).
% 28.89/28.98  tff(decl_22629, type, 'The surface of the cerebrum, divided into left and right hemispheres. The cerebral cortex is the largest and most complex part of the mammalian brain, and is involved in memory, thought, attention, language, and consciousness.': $i).
% 28.89/28.98  tff(decl_22630, type, 'cerebral cortex': $i).
% 28.89/28.98  tff(decl_22631, type, 'cerebral-cortex': $i).
% 28.89/28.98  tff(decl_22632, type, 'Cerebral-Hemisphere': $i).
% 28.89/28.98  tff(decl_22633, type, 'The left or right side of the cerebrum of the mammalian brain.': $i).
% 28.89/28.98  tff(decl_22634, type, 'cerebral hemisphere': $i).
% 28.89/28.98  tff(decl_22635, type, 'cerebral-hemisphere': $i).
% 28.89/28.98  tff(decl_22636, type, 'Cerebrospinal-Fluid': $i).
% 28.89/28.98  tff(decl_22637, type, 'A colorless fluid that acts as a cushion for and nourishes the brain and spinal cord. Cerebrospinal fluid also protects tissues of the central nervous system from infection.': $i).
% 28.89/28.98  tff(decl_22638, type, 'cerebrospinal fluid': $i).
% 28.89/28.98  tff(decl_22639, type, 'cerebrospinal-fluid': $i).
% 28.89/28.98  tff(decl_22640, type, 'Cerebrum': $i).
% 28.89/28.98  tff(decl_22641, type, 'In humans, the most dorsal part of the forebrain, composed of the left and right hemispheres. The cerebrum is divided into multiple lobes: the temporal lobe, the parietal lobe, the occipital lobe, and the frontal lobe.': $i).
% 28.89/28.98  tff(decl_22642, type, cerebrum: $i).
% 28.89/28.98  tff(decl_22643, type, cerium_1: $i > $o).
% 28.89/28.98  tff(decl_22644, type, 'Cerium': $i).
% 28.89/28.98  tff(decl_22645, type, 'Cerium is a metal atom with atomic number 58. It is represented by the symbol Ce.': $i).
% 28.89/28.98  tff(decl_22646, type, cerium: $i).
% 28.89/28.98  tff(decl_22647, type, ce: $i).
% 28.89/28.98  tff(decl_22648, type, fn_cerium_3: $i > $i).
% 28.89/28.98  tff(decl_22649, type, fn_cerium_4: $i > $i).
% 28.89/28.98  tff(decl_22650, type, fn_cerium_5: $i > $i).
% 28.89/28.98  tff(decl_22651, type, fn_cerium_9: $i > $i).
% 28.89/28.98  tff(decl_22652, type, fn_cerium_10: $i > $i).
% 28.89/28.98  tff(decl_22653, type, fn_cerium_11: $i > $i).
% 28.89/28.98  tff(decl_22654, type, fn_cerium_12: $i > $i).
% 28.89/28.98  tff(decl_22655, type, "82": $i).
% 28.89/28.98  tff(decl_22656, type, "58": $i).
% 28.89/28.98  tff(decl_22657, type, "1.12": $i).
% 28.89/28.98  tff(decl_22658, type, "140": $i).
% 28.89/28.98  tff(decl_22659, type, "140.1": $i).
% 28.89/28.98  tff(decl_22660, type, fn_cerium_7: $i > $i).
% 28.89/28.98  tff(decl_22661, type, fn_cerium_8: $i > $i).
% 28.89/28.98  tff(decl_22662, type, fn_cerium_6: $i > $i).
% 28.89/28.98  tff(decl_22663, type, cervical_cap_1: $i > $o).
% 28.89/28.98  tff(decl_22664, type, 'Cervical-Cap': $i).
% 28.89/28.98  tff(decl_22665, type, 'A barrier form of contraception, which fits over the cervix and keeps sperm from entering the uterus.': $i).
% 28.89/28.98  tff(decl_22666, type, 'cervical cap': $i).
% 28.89/28.98  tff(decl_22667, type, 'cervical-cap': $i).
% 28.89/28.98  tff(decl_22668, type, condom_1: $i > $o).
% 28.89/28.98  tff(decl_22669, type, diaphragm_birth_control_1: $i > $o).
% 28.89/28.98  tff(decl_22670, type, 'Cervix': $i).
% 28.89/28.98  tff(decl_22671, type, 'The long, narrow part of the uterus where it joins the vagina.': $i).
% 28.89/28.98  tff(decl_22672, type, cervix: $i).
% 28.89/28.98  tff(decl_22673, type, columnlike_epithelium_1: $i > $o).
% 28.89/28.98  tff(decl_22674, type, 'Cesium': $i).
% 28.89/28.98  tff(decl_22675, type, 'Cesium is a metal atom with atomic number 55. It is represented by the symbol Cs.': $i).
% 28.89/28.98  tff(decl_22676, type, 'Cs': $i).
% 28.89/28.98  tff(decl_22677, type, cesium: $i).
% 28.89/28.98  tff(decl_22678, type, fn_cesium_1: $i > $i).
% 28.89/28.98  tff(decl_22679, type, fn_cesium_2: $i > $i).
% 28.89/28.98  tff(decl_22680, type, fn_cesium_3: $i > $i).
% 28.89/28.98  tff(decl_22681, type, fn_cesium_4: $i > $i).
% 28.89/28.98  tff(decl_22682, type, fn_cesium_10: $i > $i).
% 28.89/28.98  tff(decl_22683, type, fn_cesium_11: $i > $i).
% 28.89/28.98  tff(decl_22684, type, fn_cesium_12: $i > $i).
% 28.89/28.98  tff(decl_22685, type, fn_cesium_13: $i > $i).
% 28.89/28.98  tff(decl_22686, type, fn_cesium_14: $i > $i).
% 28.89/28.98  tff(decl_22687, type, fn_cs_plus_3: $i > $i).
% 28.89/28.98  tff(decl_22688, type, "55": $i).
% 28.89/28.98  tff(decl_22689, type, "78": $i).
% 28.89/28.98  tff(decl_22690, type, "0.79": $i).
% 28.89/28.98  tff(decl_22691, type, "133": $i).
% 28.89/28.98  tff(decl_22692, type, "132.9": $i).
% 28.89/28.98  tff(decl_22693, type, fn_cesium_15: $i > $i).
% 28.89/28.98  tff(decl_22694, type, fn_cesium_9: $i > $i).
% 28.89/28.98  tff(decl_22695, type, fn_cesium_8: $i > $i).
% 28.89/28.98  tff(decl_22696, type, cetacea_1: $i > $o).
% 28.89/28.98  tff(decl_22697, type, 'Cetacea': $i).
% 28.89/28.98  tff(decl_22698, type, 'A class of marine mammals including porpoises, dolphins, and whales.': $i).
% 28.89/28.98  tff(decl_22699, type, cetacea: $i).
% 28.89/28.98  tff(decl_22700, type, marine_mammal_1: $i > $o).
% 28.89/28.98  tff(decl_22701, type, ch3_minus_1: $i > $o).
% 28.89/28.98  tff(decl_22702, type, 'CH3-Minus': $i).
% 28.89/28.98  tff(decl_22703, type, 'The methanide ion, or the anion form of a methyl group.': $i).
% 28.89/28.98  tff(decl_22704, type, methyl: $i).
% 28.89/28.98  tff(decl_22705, type, 'ch3 minus': $i).
% 28.89/28.98  tff(decl_22706, type, 'ch3-minus': $i).
% 28.89/28.98  tff(decl_22707, type, fn_ch3_minus_2: $i > $i).
% 28.89/28.98  tff(decl_22708, type, fn_ch3_minus_1: $i > $i).
% 28.89/28.98  tff(decl_22709, type, ch3_plus_1: $i > $o).
% 28.89/28.98  tff(decl_22710, type, 'CH3-Plus': $i).
% 28.89/28.98  tff(decl_22711, type, 'The methylium cation, or the cation form of a methyl group.': $i).
% 28.89/28.98  tff(decl_22712, type, 'ch3 plus': $i).
% 28.89/28.98  tff(decl_22713, type, 'ch3-plus': $i).
% 28.89/28.98  tff(decl_22714, type, fn_ch3_plus_2: $i > $i).
% 28.89/28.98  tff(decl_22715, type, fn_ch3_plus_1: $i > $i).
% 28.89/28.98  tff(decl_22716, type, 'CH3NH3-Plus': $i).
% 28.89/28.98  tff(decl_22717, type, 'Methylammonium cation.': $i).
% 28.89/28.98  tff(decl_22718, type, 'ch3nh3+': $i).
% 28.89/28.98  tff(decl_22719, type, 'ch 3nh 3+': $i).
% 28.89/28.98  tff(decl_22720, type, 'ch_3nh_3+': $i).
% 28.89/28.98  tff(decl_22721, type, 'methylammonia ion': $i).
% 28.89/28.98  tff(decl_22722, type, 'methylammonium ion': $i).
% 28.89/28.98  tff(decl_22723, type, 'methylamonia cation': $i).
% 28.89/28.98  tff(decl_22724, type, methylammonium: $i).
% 28.89/28.98  tff(decl_22725, type, 'ch3nh3 plus': $i).
% 28.89/28.98  tff(decl_22726, type, 'ch3nh3-plus': $i).
% 28.89/28.98  tff(decl_22727, type, fn_ch3nh3_plus_2: $i > $i).
% 28.89/28.98  tff(decl_22728, type, fn_ch3nh3_plus_1: $i > $i).
% 28.89/28.98  tff(decl_22729, type, ch3nh3cl_1: $i > $o).
% 28.89/28.98  tff(decl_22730, type, 'CH3NH3Cl': $i).
% 28.89/28.98  tff(decl_22731, type, 'Methylammonium chloride, a main ingredient of permethrin, used in agricultural applications.': $i).
% 28.89/28.98  tff(decl_22732, type, ch3nh3cl: $i).
% 28.89/28.98  tff(decl_22733, type, 'methyl ammonium chloride': $i).
% 28.89/28.98  tff(decl_22734, type, 'methylammonium chloride': $i).
% 28.89/28.98  tff(decl_22735, type, sodium_chloride_1: $i > $o).
% 28.89/28.98  tff(decl_22736, type, nh4cl_1: $i > $o).
% 28.89/28.98  tff(decl_22737, type, fn_ch3nh3cl_1: $i > $i).
% 28.89/28.98  tff(decl_22738, type, fn_ch3nh3cl_2: $i > $i).
% 28.89/28.98  tff(decl_22739, type, 'Change': $i).
% 28.89/28.98  tff(decl_22740, type, modify: $i).
% 28.89/28.98  tff(decl_22741, type, vary: $i).
% 28.89/28.98  tff(decl_22742, type, change_chromosome_structure_1: $i > $o).
% 28.89/28.98  tff(decl_22743, type, 'Change-Chromosome-Structure': $i).
% 28.89/28.98  tff(decl_22744, type, 'An change in the structure of a chromosome due to an process error during mitosis.': $i).
% 28.89/28.98  tff(decl_22745, type, 'change chromosome structure': $i).
% 28.89/28.98  tff(decl_22746, type, 'change-chromosome-structure': $i).
% 28.89/28.98  tff(decl_22747, type, nucleic_acid_process_1: $i > $o).
% 28.89/28.98  tff(decl_22748, type, chromosomal_inheritance_1: $i > $o).
% 28.89/28.98  tff(decl_22749, type, fn_change_chromosome_structure_1: $i > $i).
% 28.89/28.98  tff(decl_22750, type, fn_change_chromosome_structure_2: $i > $i).
% 28.89/28.98  tff(decl_22751, type, 'Change-In-Membrane-Potential': $i).
% 28.89/28.98  tff(decl_22752, type, 'A change in the voltage across cell mebranes due to changes in the electrochemical gradient.': $i).
% 28.89/28.98  tff(decl_22753, type, 'change in membrane potential': $i).
% 28.89/28.98  tff(decl_22754, type, 'change-in-membrane-potential': $i).
% 28.89/28.98  tff(decl_22755, type, change_of_hydrogen_ion_concentration_in_cell_1: $i > $o).
% 28.89/28.98  tff(decl_22756, type, 'Change-Of-Hydrogen-Ion-Concentration-In-Cell': $i).
% 28.89/28.98  tff(decl_22757, type, 'An increase or decrease in the number of hydrogen (H+) ions.': $i).
% 28.89/28.98  tff(decl_22758, type, 'change of hydrogen ion concentration': $i).
% 28.89/28.98  tff(decl_22759, type, 'change of proton concentration': $i).
% 28.89/28.98  tff(decl_22760, type, 'change of h+ concentration': $i).
% 28.89/28.98  tff(decl_22761, type, 'change of [h+]': $i).
% 28.89/28.98  tff(decl_22762, type, 'change of hydrogen ion concentration in cell': $i).
% 28.89/28.98  tff(decl_22763, type, 'change-of-hydrogen-ion-concentration-in-cell': $i).
% 28.89/28.98  tff(decl_22764, type, fn_change_of_hydrogen_ion_concentration_in_cell_2: $i > $i).
% 28.89/28.98  tff(decl_22765, type, fn_change_of_hydrogen_ion_concentration_in_cell_3: $i > $i).
% 28.89/28.98  tff(decl_22766, type, fn_change_of_hydrogen_ion_concentration_in_cell_4: $i > $i).
% 28.89/28.98  tff(decl_22767, type, fn_change_of_hydrogen_ion_concentration_in_cell_5: $i > $i).
% 28.89/28.98  tff(decl_22768, type, fn_change_of_hydrogen_ion_concentration_in_cell_6: $i > $i).
% 28.89/28.98  tff(decl_22769, type, change_of_hydroxide_ion_concentration_in_cell_1: $i > $o).
% 28.89/28.98  tff(decl_22770, type, 'Change-Of-Hydroxide-Ion-Concentration-In-Cell': $i).
% 28.89/28.98  tff(decl_22771, type, 'An increase or decrease in the number of hydroxide (OH-) ions.': $i).
% 28.89/28.98  tff(decl_22772, type, 'change of hydroxide ion concentration': $i).
% 28.89/28.98  tff(decl_22773, type, 'change of hydroxide concentration': $i).
% 28.89/28.98  tff(decl_22774, type, 'change of oh  concentration': $i).
% 28.89/28.98  tff(decl_22775, type, 'change of oh- concentration': $i).
% 28.89/28.98  tff(decl_22776, type, 'change of [oh ]': $i).
% 28.89/28.98  tff(decl_22777, type, 'change of [oh-]': $i).
% 28.89/28.98  tff(decl_22778, type, 'change of hydroxide ion concentration in cell': $i).
% 28.89/28.98  tff(decl_22779, type, 'change-of-hydroxide-ion-concentration-in-cell': $i).
% 28.89/28.98  tff(decl_22780, type, fn_change_of_hydroxide_ion_concentration_in_cell_2: $i > $i).
% 28.89/28.98  tff(decl_22781, type, fn_change_of_hydroxide_ion_concentration_in_cell_3: $i > $i).
% 28.89/28.98  tff(decl_22782, type, fn_change_of_hydroxide_ion_concentration_in_cell_4: $i > $i).
% 28.89/28.98  tff(decl_22783, type, fn_change_of_hydroxide_ion_concentration_in_cell_5: $i > $i).
% 28.89/28.98  tff(decl_22784, type, fn_change_of_hydroxide_ion_concentration_in_cell_6: $i > $i).
% 28.89/28.98  tff(decl_22785, type, change_of_shape_1: $i > $o).
% 28.89/28.98  tff(decl_22786, type, 'Change-Of-Shape': $i).
% 28.89/28.98  tff(decl_22787, type, 'A change involving the shape or arrangement of an object.': $i).
% 28.89/28.98  tff(decl_22788, type, 'shape change': $i).
% 28.89/28.98  tff(decl_22789, type, 'shape-change': $i).
% 28.89/28.98  tff(decl_22790, type, 'change of shape': $i).
% 28.89/28.98  tff(decl_22791, type, 'change-of-shape': $i).
% 28.89/28.98  tff(decl_22792, type, 'Change-Of-State': $i).
% 28.89/28.98  tff(decl_22793, type, 'A change in which a substance or thing is transformed from one state to another': $i).
% 28.89/28.98  tff(decl_22794, type, 'change state': $i).
% 28.89/28.98  tff(decl_22795, type, 'state change': $i).
% 28.89/28.98  tff(decl_22796, type, 'state-change': $i).
% 28.89/28.98  tff(decl_22797, type, 'change of state': $i).
% 28.89/28.98  tff(decl_22798, type, 'change-of-state': $i).
% 28.89/28.98  tff(decl_22799, type, 'Change-Sequence': $i).
% 28.89/28.98  tff(decl_22800, type, 'Mutation that results in the change in sequence of DNA.': $i).
% 28.89/28.98  tff(decl_22801, type, 'dna sequence change': $i).
% 28.89/28.98  tff(decl_22802, type, 'sequence mutation': $i).
% 28.89/28.98  tff(decl_22803, type, 'sequence of change': $i).
% 28.89/28.98  tff(decl_22804, type, 'change sequence': $i).
% 28.89/28.98  tff(decl_22805, type, 'change-sequence': $i).
% 28.89/28.98  tff(decl_22806, type, 'Channel-Protein': $i).
% 28.89/28.98  tff(decl_22807, type, 'Protein forming an aqueous pore spanning the lipid bilayer of the cell membrane which when open allows certain solutes to traverse the membrane.': $i).
% 28.89/28.98  tff(decl_22808, type, 'protein of channel': $i).
% 28.89/28.98  tff(decl_22809, type, 'channel protein': $i).
% 28.89/28.98  tff(decl_22810, type, 'channel-protein': $i).
% 28.89/28.98  tff(decl_22811, type, fn_channel_protein_2: $i > $i).
% 28.89/28.98  tff(decl_22812, type, fn_channel_protein_9: $i > $i).
% 28.89/28.98  tff(decl_22813, type, fn_facilitated_diffusion_using_channel_protein_8: $i > $i).
% 28.89/28.98  tff(decl_22814, type, fn_channel_protein_10: $i > $i).
% 28.89/28.98  tff(decl_22815, type, chaparral_1: $i > $o).
% 28.89/28.98  tff(decl_22816, type, 'Chaparral': $i).
% 28.89/28.98  tff(decl_22817, type, 'A scrubland biome located in California and the northern part of the Baja Peninsula in Mexico. Chapparal is characterized by a Mediterranean climate (long, dry summers and mild, wet winters), wildfire, and drought-tolerant plants.': $i).
% 28.89/28.98  tff(decl_22818, type, chaparral: $i).
% 28.89/28.98  tff(decl_22819, type, terrestrial_biome_1: $i > $o).
% 28.89/28.98  tff(decl_22820, type, desert_1: $i > $o).
% 28.89/28.98  tff(decl_22821, type, northern_coniferous_1: $i > $o).
% 28.89/28.98  tff(decl_22822, type, savanna_1: $i > $o).
% 28.89/28.98  tff(decl_22823, type, temperate_broadleaf_forest_1: $i > $o).
% 28.89/28.98  tff(decl_22824, type, temperate_grassland_1: $i > $o).
% 28.89/28.98  tff(decl_22825, type, tropical_rain_forest_1: $i > $o).
% 28.89/28.98  tff(decl_22826, type, tropics_1: $i > $o).
% 28.89/28.98  tff(decl_22827, type, tundra_1: $i > $o).
% 28.89/28.98  tff(decl_22828, type, chaperonin_1: $i > $o).
% 28.89/28.98  tff(decl_22829, type, 'Chaperonin': $i).
% 28.89/28.98  tff(decl_22830, type, 'Protein molecules which help other proteins fold into their correct three-dimensional configuration.': $i).
% 28.89/28.98  tff(decl_22831, type, 'chaperonin protein complex': $i).
% 28.89/28.98  tff(decl_22832, type, 'chaperonin-protein-complex': $i).
% 28.89/28.98  tff(decl_22833, type, 'chaperone protein': $i).
% 28.89/28.98  tff(decl_22834, type, 'chaperone-protein': $i).
% 28.89/28.98  tff(decl_22835, type, chaperonin: $i).
% 28.89/28.98  tff(decl_22836, type, fn_chaperonin_3: $i > $i).
% 28.89/28.98  tff(decl_22837, type, fn_chaperonin_4: $i > $i).
% 28.89/28.98  tff(decl_22838, type, fn_chaperonin_5: $i > $i).
% 28.89/28.98  tff(decl_22839, type, fn_chaperonin_6: $i > $i).
% 28.89/28.98  tff(decl_22840, type, fn_chaperonin_7: $i > $i).
% 28.89/28.98  tff(decl_22841, type, fn_chaperonin_8: $i > $i).
% 28.89/28.98  tff(decl_22842, type, fn_chaperonin_9: $i > $i).
% 28.89/28.98  tff(decl_22843, type, character_1: $i > $o).
% 28.89/28.98  tff(decl_22844, type, 'Character': $i).
% 28.89/28.98  tff(decl_22845, type, 'A heritable feature': $i).
% 28.89/28.98  tff(decl_22846, type, 'quantitative character': $i).
% 28.89/28.98  tff(decl_22847, type, 'heritable feature': $i).
% 28.89/28.98  tff(decl_22848, type, character: $i).
% 28.89/28.98  tff(decl_22849, type, fn_character_1: $i > $i).
% 28.89/28.98  tff(decl_22850, type, fn_character_3: $i > $i).
% 28.89/28.98  tff(decl_22851, type, offspring_1: $i > $o).
% 28.89/28.98  tff(decl_22852, type, fn_organism_role_2: $i > $i).
% 28.89/28.98  tff(decl_22853, type, fn_inheritance_1: $i > $i).
% 28.89/28.98  tff(decl_22854, type, fn_organism_role_1: $i > $i).
% 28.89/28.98  tff(decl_22855, type, 'Character-Displacement': $i).
% 28.89/28.98  tff(decl_22856, type, 'The phenomenon where differences between closely related species are more pronounced when the species are in sympatry rather than allopatry.': $i).
% 28.89/28.98  tff(decl_22857, type, 'displacement of character': $i).
% 28.89/28.98  tff(decl_22858, type, 'character displacement': $i).
% 28.89/28.98  tff(decl_22859, type, 'character-displacement': $i).
% 28.89/28.98  tff(decl_22860, type, 'Charge-Categorical-Constant': $i).
% 28.89/28.98  tff(decl_22861, type, 'charge categorical constant': $i).
% 28.89/28.98  tff(decl_22862, type, 'charge-categorical-constant': $i).
% 28.89/28.98  tff(decl_22863, type, 'Charge-Value': $i).
% 28.89/28.98  tff(decl_22864, type, 'Refers to charge of an ion. Specifically, the charge on an ion is equal to a constant charge e multiplied by an integer from 1 to 15.': $i).
% 28.89/28.98  tff(decl_22865, type, charge: $i).
% 28.89/28.98  tff(decl_22866, type, 'value of charge': $i).
% 28.89/28.98  tff(decl_22867, type, 'charge value': $i).
% 28.89/28.98  tff(decl_22868, type, 'charge-value': $i).
% 28.89/28.98  tff(decl_22869, type, 'Charophycean': $i).
% 28.89/28.98  tff(decl_22870, type, 'A taxon of green algae, whose relationship to other photosynthetic organisms is unclear.': $i).
% 28.89/28.98  tff(decl_22871, type, charophycean: $i).
% 28.89/28.98  tff(decl_22872, type, checkpoint_1: $i > $o).
% 28.89/28.98  tff(decl_22873, type, 'Checkpoint': $i).
% 28.89/28.98  tff(decl_22874, type, 'Control mechanism that verifies whether or not the steps at each point of the cell cycle have been completed before the next phase begins.': $i).
% 28.89/28.98  tff(decl_22875, type, checkpoint: $i).
% 28.89/28.98  tff(decl_22876, type, regulation_of_cell_cycle_1: $i > $o).
% 28.89/28.98  tff(decl_22877, type, cheese_1: $i > $o).
% 28.89/28.98  tff(decl_22878, type, 'Cheese': $i).
% 28.89/28.98  tff(decl_22879, type, 'Cheese is a generic term for a diverse group of milk-based food products. Cheese is produced throughout the world in wide-ranging flavors, textures, and forms.': $i).
% 28.89/28.98  tff(decl_22880, type, cheese: $i).
% 28.89/28.98  tff(decl_22881, type, fn_cheese_1: $i > $i).
% 28.89/28.98  tff(decl_22882, type, lactate_1: $i > $o).
% 28.89/28.98  tff(decl_22883, type, fn_cheese_2: $i > $i).
% 28.89/28.98  tff(decl_22884, type, milk_1: $i > $o).
% 28.89/28.98  tff(decl_22885, type, fn_cheese_3: $i > $i).
% 28.89/28.98  tff(decl_22886, type, chelicera_1: $i > $o).
% 28.89/28.98  tff(decl_22887, type, 'Chelicera': $i).
% 28.89/28.98  tff(decl_22888, type, '(plural, chelicerae) The modified first head appendage of the Chelicerata (arachnids, horseshoe crabs, and pycnogonids), used as mouthparts and often claw-shaped.': $i).
% 28.89/28.98  tff(decl_22889, type, mouthparts: $i).
% 28.89/28.98  tff(decl_22890, type, fang: $i).
% 28.89/28.98  tff(decl_22891, type, chelicerae: $i).
% 28.89/28.98  tff(decl_22892, type, chelicera: $i).
% 28.89/28.98  tff(decl_22893, type, 'Cheliceriform': $i).
% 28.89/28.98  tff(decl_22894, type, 'An arthropod that has chelicerae and a body divided into a cephalothorax and an abdomen. Living cheliceriforms include sea spiders, horseshoe crabs, scorpions, ticks, and spiders.': $i).
% 28.89/28.98  tff(decl_22895, type, chelicerate: $i).
% 28.89/28.98  tff(decl_22896, type, cheliceriform: $i).
% 28.89/28.98  tff(decl_22897, type, daphnia_1: $i > $o).
% 28.89/28.98  tff(decl_22898, type, diplopode_1: $i > $o).
% 28.89/28.98  tff(decl_22899, type, hexapod_1: $i > $o).
% 28.89/28.98  tff(decl_22900, type, 'Chemical': $i).
% 28.89/28.98  tff(decl_22901, type, 'A Chemical is a substance described by chemical properties such as molecular composition and reactivity.': $i).
% 28.89/28.98  tff(decl_22902, type, 'solute-species': $i).
% 28.89/28.98  tff(decl_22903, type, 'species of solute': $i).
% 28.89/28.98  tff(decl_22904, type, 'solute species': $i).
% 28.89/28.98  tff(decl_22905, type, 'solute-specy': $i).
% 28.89/28.98  tff(decl_22906, type, chemical: $i).
% 28.89/28.98  tff(decl_22907, type, 'Chemical-Bond': $i).
% 28.89/28.98  tff(decl_22908, type, 'A chemical bond is an attraction between atoms or molecules and allows the formation of chemical compounds, which contain two or more atoms.': $i).
% 28.89/28.98  tff(decl_22909, type, possess: $i).
% 28.89/28.98  tff(decl_22910, type, 'chemical interaction': $i).
% 28.89/28.98  tff(decl_22911, type, 'chemical-interaction': $i).
% 28.89/28.98  tff(decl_22912, type, 'bond of chemical': $i).
% 28.89/28.98  tff(decl_22913, type, 'chemical bond': $i).
% 28.89/28.98  tff(decl_22914, type, 'chemical-bond': $i).
% 28.89/28.98  tff(decl_22915, type, 'Chemical-Digestion': $i).
% 28.89/28.98  tff(decl_22916, type, 'The enzymatic hydrolysis of food molecules into smaller molecules that can be absorbed and utilized by an organism.': $i).
% 28.89/28.98  tff(decl_22917, type, 'digestion of chemical': $i).
% 28.89/28.98  tff(decl_22918, type, 'chemical digestion': $i).
% 28.89/28.98  tff(decl_22919, type, 'chemical-digestion': $i).
% 28.89/28.98  tff(decl_22920, type, fn_chemical_digestion_3: $i > $i).
% 28.89/28.98  tff(decl_22921, type, chemical_digestion_in_mouth_1: $i > $o).
% 28.89/28.98  tff(decl_22922, type, 'Chemical-Digestion-In-Mouth': $i).
% 28.89/28.98  tff(decl_22923, type, 'The enzymatic hydrolysis of food molecules into smaller molecules which occurs in the mouth.': $i).
% 28.89/28.98  tff(decl_22924, type, 'chemical digestion in mouth': $i).
% 28.89/28.98  tff(decl_22925, type, 'chemical-digestion-in-mouth': $i).
% 28.89/28.98  tff(decl_22926, type, fn_chemical_digestion_in_mouth_1: $i > $i).
% 28.89/28.98  tff(decl_22927, type, fn_chemical_digestion_in_mouth_2: $i > $i).
% 28.89/28.98  tff(decl_22928, type, fn_chemical_digestion_in_mouth_5: $i > $i).
% 28.89/28.98  tff(decl_22929, type, fn_chemical_digestion_in_mouth_6: $i > $i).
% 28.89/28.98  tff(decl_22930, type, fn_chemical_digestion_in_mouth_7: $i > $i).
% 28.89/28.98  tff(decl_22931, type, fn_chemical_digestion_in_mouth_8: $i > $i).
% 28.89/28.98  tff(decl_22932, type, fn_chemical_digestion_in_mouth_9: $i > $i).
% 28.89/28.98  tff(decl_22933, type, fn_chemical_digestion_in_mouth_10: $i > $i).
% 28.89/28.98  tff(decl_22934, type, fn_chemical_digestion_in_mouth_11: $i > $i).
% 28.89/28.98  tff(decl_22935, type, fn_chemical_digestion_in_mouth_12: $i > $i).
% 28.89/28.98  tff(decl_22936, type, fn_chemical_digestion_in_mouth_13: $i > $i).
% 28.89/28.98  tff(decl_22937, type, fn_chemical_digestion_in_mouth_14: $i > $i).
% 28.89/28.98  tff(decl_22938, type, salivary_amylase_1: $i > $o).
% 28.89/28.98  tff(decl_22939, type, fn_chemical_digestion_in_mouth_15: $i > $i).
% 28.89/28.98  tff(decl_22940, type, fn_chemical_digestion_in_mouth_16: $i > $i).
% 28.89/28.98  tff(decl_22941, type, fn_chemical_digestion_in_mouth_17: $i > $i).
% 28.89/28.98  tff(decl_22942, type, fn_chemical_digestion_in_mouth_18: $i > $i).
% 28.89/28.98  tff(decl_22943, type, fn_saliva_5: $i > $i).
% 28.89/28.98  tff(decl_22944, type, fn_mouth_2: $i > $i).
% 28.89/28.98  tff(decl_22945, type, fn_salivary_gland_3: $i > $i).
% 28.89/28.98  tff(decl_22946, type, fn_chemical_digestion_in_mouth_21: $i > $i).
% 28.89/28.98  tff(decl_22947, type, fn_chemical_digestion_in_mouth_19: $i > $i).
% 28.89/28.98  tff(decl_22948, type, fn_chemical_digestion_in_mouth_20: $i > $i).
% 28.89/28.98  tff(decl_22949, type, chemical_digestion_in_small_intestine_1: $i > $o).
% 28.89/28.98  tff(decl_22950, type, 'Chemical-Digestion-In-Small-Intestine': $i).
% 28.89/28.98  tff(decl_22951, type, 'The enzymatic hydrolysis of food molecules into smaller molecules which occurs in the small intestine.': $i).
% 28.89/28.98  tff(decl_22952, type, 'chemical digestion in small intestine': $i).
% 28.89/28.98  tff(decl_22953, type, 'chemical-digestion-in-small-intestine': $i).
% 28.89/28.98  tff(decl_22954, type, fn_chemical_digestion_in_small_intestine_1: $i > $i).
% 28.89/28.98  tff(decl_22955, type, fn_chemical_digestion_in_small_intestine_2: $i > $i).
% 28.89/28.98  tff(decl_22956, type, fn_chemical_digestion_in_small_intestine_3: $i > $i).
% 28.89/28.98  tff(decl_22957, type, fn_chemical_digestion_in_small_intestine_4: $i > $i).
% 28.89/28.98  tff(decl_22958, type, fn_chemical_digestion_in_small_intestine_5: $i > $i).
% 28.89/28.98  tff(decl_22959, type, fn_chemical_digestion_in_small_intestine_6: $i > $i).
% 28.89/28.98  tff(decl_22960, type, fn_chemical_digestion_in_small_intestine_7: $i > $i).
% 28.89/28.98  tff(decl_22961, type, fn_chemical_digestion_in_small_intestine_8: $i > $i).
% 28.89/28.98  tff(decl_22962, type, monoglyceride_1: $i > $o).
% 28.89/28.98  tff(decl_22963, type, fn_chemical_digestion_in_small_intestine_9: $i > $i).
% 28.89/28.98  tff(decl_22964, type, fn_chemical_digestion_in_small_intestine_10: $i > $i).
% 28.89/28.98  tff(decl_22965, type, fn_chemical_digestion_in_small_intestine_18: $i > $i).
% 28.89/28.98  tff(decl_22966, type, pancreatic_amylase_1: $i > $o).
% 28.89/28.98  tff(decl_22967, type, fn_chemical_digestion_in_small_intestine_19: $i > $i).
% 28.89/28.98  tff(decl_22968, type, fn_chemical_digestion_in_small_intestine_20: $i > $i).
% 28.89/28.98  tff(decl_22969, type, fn_chemical_digestion_in_small_intestine_21: $i > $i).
% 28.89/28.98  tff(decl_22970, type, fn_chemical_digestion_in_small_intestine_22: $i > $i).
% 28.89/28.98  tff(decl_22971, type, fn_chemical_digestion_in_small_intestine_23: $i > $i).
% 28.89/28.98  tff(decl_22972, type, fn_chemical_digestion_in_small_intestine_24: $i > $i).
% 28.89/28.98  tff(decl_22973, type, fn_chemical_digestion_in_small_intestine_25: $i > $i).
% 28.89/28.98  tff(decl_22974, type, fn_chemical_digestion_in_small_intestine_26: $i > $i).
% 28.89/28.98  tff(decl_22975, type, fn_chemical_digestion_in_small_intestine_27: $i > $i).
% 28.89/28.98  tff(decl_22976, type, fn_chemical_digestion_in_small_intestine_28: $i > $i).
% 28.89/28.98  tff(decl_22977, type, fn_chemical_digestion_in_small_intestine_29: $i > $i).
% 28.89/28.98  tff(decl_22978, type, fn_chemical_digestion_in_small_intestine_30: $i > $i).
% 28.89/28.98  tff(decl_22979, type, fn_chemical_digestion_in_small_intestine_31: $i > $i).
% 28.89/28.98  tff(decl_22980, type, fn_chemical_digestion_in_small_intestine_32: $i > $i).
% 28.89/28.98  tff(decl_22981, type, fn_chemical_digestion_in_small_intestine_33: $i > $i).
% 28.89/28.98  tff(decl_22982, type, fn_chemical_digestion_in_small_intestine_34: $i > $i).
% 28.89/28.98  tff(decl_22983, type, fn_chemical_digestion_in_small_intestine_35: $i > $i).
% 28.89/28.98  tff(decl_22984, type, disaccharidase_1: $i > $o).
% 28.89/28.98  tff(decl_22985, type, fn_chemical_digestion_in_small_intestine_36: $i > $i).
% 28.89/28.98  tff(decl_22986, type, fn_chemical_digestion_in_small_intestine_37: $i > $i).
% 28.89/28.98  tff(decl_22987, type, fn_chemical_digestion_in_small_intestine_38: $i > $i).
% 28.89/28.98  tff(decl_22988, type, fn_chemical_digestion_in_small_intestine_39: $i > $i).
% 28.89/28.98  tff(decl_22989, type, fn_chemical_digestion_in_small_intestine_40: $i > $i).
% 28.89/28.98  tff(decl_22990, type, fn_chemical_digestion_in_small_intestine_41: $i > $i).
% 28.89/28.98  tff(decl_22991, type, fn_chemical_digestion_in_small_intestine_42: $i > $i).
% 28.89/28.98  tff(decl_22992, type, fn_chemical_digestion_in_small_intestine_43: $i > $i).
% 28.89/28.98  tff(decl_22993, type, fn_chemical_digestion_in_small_intestine_44: $i > $i).
% 28.89/28.98  tff(decl_22994, type, fn_chemical_digestion_in_small_intestine_45: $i > $i).
% 28.89/28.98  tff(decl_22995, type, fn_chemical_digestion_in_small_intestine_46: $i > $i).
% 28.89/28.98  tff(decl_22996, type, fn_chemical_digestion_in_small_intestine_47: $i > $i).
% 28.89/28.98  tff(decl_22997, type, fn_chemical_digestion_in_small_intestine_48: $i > $i).
% 28.89/28.98  tff(decl_22998, type, fn_chemical_digestion_in_small_intestine_49: $i > $i).
% 28.89/28.98  tff(decl_22999, type, fn_chemical_digestion_in_small_intestine_50: $i > $i).
% 28.89/28.98  tff(decl_23000, type, fn_chemical_digestion_in_small_intestine_51: $i > $i).
% 28.89/28.98  tff(decl_23001, type, fn_chemical_digestion_in_small_intestine_52: $i > $i).
% 28.89/28.98  tff(decl_23002, type, fn_chemical_digestion_in_small_intestine_53: $i > $i).
% 28.89/28.98  tff(decl_23003, type, fn_chemical_digestion_in_small_intestine_54: $i > $i).
% 28.89/28.98  tff(decl_23004, type, fn_chemical_digestion_in_small_intestine_55: $i > $i).
% 28.89/28.98  tff(decl_23005, type, fn_chemical_digestion_in_small_intestine_56: $i > $i).
% 28.89/28.98  tff(decl_23006, type, fn_chemical_digestion_in_small_intestine_57: $i > $i).
% 28.89/28.98  tff(decl_23007, type, fn_chemical_digestion_in_small_intestine_58: $i > $i).
% 28.89/28.98  tff(decl_23008, type, fn_chemical_digestion_in_small_intestine_61: $i > $i).
% 28.89/28.98  tff(decl_23009, type, fn_chemical_digestion_in_small_intestine_62: $i > $i).
% 28.89/28.98  tff(decl_23010, type, fn_chemical_digestion_in_small_intestine_63: $i > $i).
% 28.89/28.98  tff(decl_23011, type, fn_chemical_digestion_in_small_intestine_64: $i > $i).
% 28.89/28.98  tff(decl_23012, type, fn_chemical_digestion_in_small_intestine_65: $i > $i).
% 28.89/28.98  tff(decl_23013, type, fn_chemical_digestion_in_small_intestine_66: $i > $i).
% 28.89/28.98  tff(decl_23014, type, fn_chemical_digestion_in_small_intestine_67: $i > $i).
% 28.89/28.98  tff(decl_23015, type, fn_chemical_digestion_in_small_intestine_68: $i > $i).
% 28.89/28.98  tff(decl_23016, type, fn_chemical_digestion_in_small_intestine_69: $i > $i).
% 28.89/28.98  tff(decl_23017, type, fn_chemical_digestion_in_small_intestine_70: $i > $i).
% 28.89/28.98  tff(decl_23018, type, fn_chemical_digestion_in_small_intestine_71: $i > $i).
% 28.89/28.98  tff(decl_23019, type, fn_chemical_digestion_in_small_intestine_72: $i > $i).
% 28.89/28.98  tff(decl_23020, type, pancreatic_carboxypeptidase_1: $i > $o).
% 28.89/28.98  tff(decl_23021, type, fn_chemical_digestion_in_small_intestine_74: $i > $i).
% 28.89/28.98  tff(decl_23022, type, fn_chemical_digestion_in_small_intestine_75: $i > $i).
% 28.89/28.98  tff(decl_23023, type, fn_chemical_digestion_in_small_intestine_76: $i > $i).
% 28.89/28.98  tff(decl_23024, type, fn_chemical_digestion_in_small_intestine_77: $i > $i).
% 28.89/28.98  tff(decl_23025, type, fn_chemical_digestion_in_small_intestine_78: $i > $i).
% 28.89/28.98  tff(decl_23026, type, fn_chemical_digestion_in_small_intestine_79: $i > $i).
% 28.89/28.98  tff(decl_23027, type, dipeptidase_1: $i > $o).
% 28.89/28.98  tff(decl_23028, type, fn_chemical_digestion_in_small_intestine_80: $i > $i).
% 28.89/28.98  tff(decl_23029, type, fn_chemical_digestion_in_small_intestine_81: $i > $i).
% 28.89/28.98  tff(decl_23030, type, fn_chemical_digestion_in_small_intestine_82: $i > $i).
% 28.89/28.98  tff(decl_23031, type, fn_chemical_digestion_in_small_intestine_83: $i > $i).
% 28.89/28.99  tff(decl_23032, type, pancreatic_nuclease_1: $i > $o).
% 28.89/28.99  tff(decl_23033, type, fn_chemical_digestion_in_small_intestine_84: $i > $i).
% 28.89/28.99  tff(decl_23034, type, fn_chemical_digestion_in_small_intestine_85: $i > $i).
% 28.89/28.99  tff(decl_23035, type, fn_chemical_digestion_in_small_intestine_86: $i > $i).
% 28.89/28.99  tff(decl_23036, type, fn_chemical_digestion_in_small_intestine_87: $i > $i).
% 28.89/28.99  tff(decl_23037, type, fn_chemical_digestion_in_small_intestine_88: $i > $i).
% 28.89/28.99  tff(decl_23038, type, fn_chemical_digestion_in_small_intestine_89: $i > $i).
% 28.89/28.99  tff(decl_23039, type, fn_chemical_digestion_in_small_intestine_90: $i > $i).
% 28.89/28.99  tff(decl_23040, type, fn_chemical_digestion_in_small_intestine_91: $i > $i).
% 28.89/28.99  tff(decl_23041, type, fn_chemical_digestion_in_small_intestine_92: $i > $i).
% 28.89/28.99  tff(decl_23042, type, fn_chemical_digestion_in_small_intestine_93: $i > $i).
% 28.89/28.99  tff(decl_23043, type, fn_chemical_digestion_in_small_intestine_94: $i > $i).
% 28.89/28.99  tff(decl_23044, type, fn_chemical_digestion_in_small_intestine_95: $i > $i).
% 28.89/28.99  tff(decl_23045, type, fn_chemical_digestion_in_small_intestine_96: $i > $i).
% 28.89/28.99  tff(decl_23046, type, fn_chemical_digestion_in_small_intestine_97: $i > $i).
% 28.89/28.99  tff(decl_23047, type, fn_chemical_digestion_in_small_intestine_98: $i > $i).
% 28.89/28.99  tff(decl_23048, type, fn_chemical_digestion_in_small_intestine_99: $i > $i).
% 28.89/28.99  tff(decl_23049, type, fn_chemical_digestion_in_small_intestine_100: $i > $i).
% 28.89/28.99  tff(decl_23050, type, nucleotidase_1: $i > $o).
% 28.89/28.99  tff(decl_23051, type, fn_chemical_digestion_in_small_intestine_101: $i > $i).
% 28.89/28.99  tff(decl_23052, type, fn_chemical_digestion_in_small_intestine_102: $i > $i).
% 28.89/28.99  tff(decl_23053, type, fn_chemical_digestion_in_small_intestine_103: $i > $i).
% 28.89/28.99  tff(decl_23054, type, pancreatic_lipase_1: $i > $o).
% 28.89/28.99  tff(decl_23055, type, fn_chemical_digestion_in_small_intestine_104: $i > $i).
% 28.89/28.99  tff(decl_23056, type, fn_chemical_digestion_in_small_intestine_105: $i > $i).
% 28.89/28.99  tff(decl_23057, type, fn_chemical_digestion_in_small_intestine_106: $i > $i).
% 28.89/28.99  tff(decl_23058, type, 'Panc-Lipase': $i).
% 28.89/28.99  tff(decl_23059, type, 'PA': $i).
% 28.89/28.99  tff(decl_23060, type, 'DS': $i).
% 28.89/28.99  tff(decl_23061, type, 'Tr/ChyTr': $i).
% 28.89/28.99  tff(decl_23062, type, 'PCP': $i).
% 28.89/28.99  tff(decl_23063, type, 'CP/DiP/AP': $i).
% 28.89/28.99  tff(decl_23064, type, 'PN': $i).
% 28.89/28.99  tff(decl_23065, type, 'Nucleotidase': $i).
% 28.89/28.99  tff(decl_23066, type, fn_chemical_digestion_in_small_intestine_13: $i > $i).
% 28.89/28.99  tff(decl_23067, type, fn_chemical_digestion_in_small_intestine_14: $i > $i).
% 28.89/28.99  tff(decl_23068, type, fn_chemical_digestion_in_small_intestine_15: $i > $i).
% 28.89/28.99  tff(decl_23069, type, fn_chemical_digestion_in_small_intestine_107: $i > $i).
% 28.89/28.99  tff(decl_23070, type, fn_chemical_digestion_in_small_intestine_59: $i > $i).
% 28.89/28.99  tff(decl_23071, type, fn_chemical_digestion_in_small_intestine_108: $i > $i).
% 28.89/28.99  tff(decl_23072, type, fn_chemical_digestion_in_small_intestine_73: $i > $i).
% 28.89/28.99  tff(decl_23073, type, fn_chemical_digestion_in_small_intestine_109: $i > $i).
% 28.89/28.99  tff(decl_23074, type, fn_chemical_digestion_in_small_intestine_60: $i > $i).
% 28.89/28.99  tff(decl_23075, type, fn_chemical_digestion_in_small_intestine_11: $i > $i).
% 28.89/28.99  tff(decl_23076, type, fn_chemical_digestion_in_small_intestine_12: $i > $i).
% 28.89/28.99  tff(decl_23077, type, fn_chemical_digestion_in_small_intestine_17: $i > $i).
% 28.89/28.99  tff(decl_23078, type, fn_chemical_digestion_in_small_intestine_16: $i > $i).
% 28.89/28.99  tff(decl_23079, type, chemical_digestion_in_stomach_1: $i > $o).
% 28.89/28.99  tff(decl_23080, type, 'Chemical-Digestion-In-Stomach': $i).
% 28.89/28.99  tff(decl_23081, type, 'The enzymatic hydrolysis of food molecules into smaller molecules which occurs in the stomach.': $i).
% 28.89/28.99  tff(decl_23082, type, 'chemical digestion in stomach': $i).
% 28.89/28.99  tff(decl_23083, type, 'chemical-digestion-in-stomach': $i).
% 28.89/28.99  tff(decl_23084, type, fn_chemical_digestion_in_stomach_1: $i > $i).
% 28.89/28.99  tff(decl_23085, type, fn_chemical_digestion_in_stomach_2: $i > $i).
% 28.89/28.99  tff(decl_23086, type, fn_chemical_digestion_in_stomach_4: $i > $i).
% 28.89/28.99  tff(decl_23087, type, protein_denaturation_by_ph_change_1: $i > $o).
% 28.89/28.99  tff(decl_23088, type, fn_chemical_digestion_in_stomach_5: $i > $i).
% 28.89/28.99  tff(decl_23089, type, fn_chemical_digestion_in_stomach_6: $i > $i).
% 28.89/28.99  tff(decl_23090, type, denatured_protein_1: $i > $o).
% 28.89/28.99  tff(decl_23091, type, fn_chemical_digestion_in_stomach_7: $i > $i).
% 28.89/28.99  tff(decl_23092, type, fn_chemical_digestion_in_stomach_8: $i > $i).
% 28.89/28.99  tff(decl_23093, type, fn_chemical_digestion_in_stomach_9: $i > $i).
% 28.89/28.99  tff(decl_23094, type, fn_chemical_digestion_in_stomach_10: $i > $i).
% 28.89/28.99  tff(decl_23095, type, fn_chemical_digestion_in_stomach_11: $i > $i).
% 28.89/28.99  tff(decl_23096, type, fn_chemical_digestion_in_stomach_12: $i > $i).
% 28.89/28.99  tff(decl_23097, type, fn_chemical_digestion_in_stomach_13: $i > $i).
% 28.89/28.99  tff(decl_23098, type, fn_chemical_digestion_in_stomach_14: $i > $i).
% 28.89/28.99  tff(decl_23099, type, fn_chemical_digestion_in_stomach_15: $i > $i).
% 28.89/28.99  tff(decl_23100, type, fn_protein_denaturation_by_ph_change_8: $i > $i).
% 28.89/28.99  tff(decl_23101, type, fn_chemical_digestion_in_stomach_16: $i > $i).
% 28.89/28.99  tff(decl_23102, type, fn_chemical_digestion_in_stomach_17: $i > $i).
% 28.89/28.99  tff(decl_23103, type, 'Chemical-Dissociation-Reaction': $i).
% 28.89/28.99  tff(decl_23104, type, 'The process by which ionic compounds separate into their component ions.': $i).
% 28.89/28.99  tff(decl_23105, type, 'chemical dissociation reaction': $i).
% 28.89/28.99  tff(decl_23106, type, 'chemical-dissociation-reaction': $i).
% 28.89/28.99  tff(decl_23107, type, chemical_ecology_1: $i > $o).
% 28.89/28.99  tff(decl_23108, type, 'Chemical-Ecology': $i).
% 28.89/28.99  tff(decl_23109, type, 'The study of the chemicals involved in biological interactions.': $i).
% 28.89/28.99  tff(decl_23110, type, 'ecology of chemical': $i).
% 28.89/28.99  tff(decl_23111, type, 'chemical ecology': $i).
% 28.89/28.99  tff(decl_23112, type, 'chemical-ecology': $i).
% 28.89/28.99  tff(decl_23113, type, 'Chemical-Element': $i).
% 28.89/28.99  tff(decl_23114, type, 'A pure chemical substance consisting of one type of atom distinguished by its atomic number.': $i).
% 28.89/28.99  tff(decl_23115, type, element: $i).
% 28.89/28.99  tff(decl_23116, type, 'element of chemical': $i).
% 28.89/28.99  tff(decl_23117, type, 'chemical element': $i).
% 28.89/28.99  tff(decl_23118, type, 'chemical-element': $i).
% 28.89/28.99  tff(decl_23119, type, fn_chemical_element_5: $i > $i).
% 28.89/28.99  tff(decl_23120, type, fn_chemical_element_6: $i > $i).
% 28.89/28.99  tff(decl_23121, type, fn_chemical_element_7: $i > $i).
% 28.89/28.99  tff(decl_23122, type, fn_chemical_element_8: $i > $i).
% 28.89/28.99  tff(decl_23123, type, fn_chemical_element_9: $i > $i).
% 28.89/28.99  tff(decl_23124, type, fn_chemical_element_10: $i > $i).
% 28.89/28.99  tff(decl_23125, type, atom_0: $i).
% 28.89/28.99  tff(decl_23126, type, fn_chemical_element_4: $i > $i).
% 28.89/28.99  tff(decl_23127, type, fn_chemical_element_3: $i > $i).
% 28.89/28.99  tff(decl_23128, type, fn_chemical_element_2: $i > $i).
% 28.89/28.99  tff(decl_23129, type, fn_chemical_element_1: $i > $i).
% 28.89/28.99  tff(decl_23130, type, 'Chemical-Energy': $i).
% 28.89/28.99  tff(decl_23131, type, 'Energy produced by or stored in chemical properties or property differentials, such as chemical bonds, such as charge gradients, density gradients, etc.': $i).
% 28.89/28.99  tff(decl_23132, type, 'Chemical energy is the potential of a chemical substance to undergo a transformation through a chemical reaction or to transform other chemical substances.': $i).
% 28.89/28.99  tff(decl_23133, type, 'chemical energy': $i).
% 28.89/28.99  tff(decl_23134, type, chemical_energy: $i).
% 28.89/28.99  tff(decl_23135, type, 'energy of chemical': $i).
% 28.89/28.99  tff(decl_23136, type, 'chemical-energy': $i).
% 28.89/28.99  tff(decl_23137, type, 'Chemical-Entity': $i).
% 28.89/28.99  tff(decl_23138, type, 'A physical object that is the basic building blocks of Chemicals.': $i).
% 28.89/28.99  tff(decl_23139, type, 'reduced form': $i).
% 28.89/28.99  tff(decl_23140, type, 'has reduced form': $i).
% 28.89/28.99  tff(decl_23141, type, 'has-reduced-form': $i).
% 28.89/28.99  tff(decl_23142, type, 'oxidized form': $i).
% 28.89/28.99  tff(decl_23143, type, 'has oxidized form': $i).
% 28.89/28.99  tff(decl_23144, type, 'has-oxidized-form': $i).
% 28.89/28.99  tff(decl_23145, type, 'has isomer': $i).
% 28.89/28.99  tff(decl_23146, type, 'has-isomer': $i).
% 28.89/28.99  tff(decl_23147, type, substance: $i).
% 28.89/28.99  tff(decl_23148, type, 'entity of chemical': $i).
% 28.89/28.99  tff(decl_23149, type, 'chemical entity': $i).
% 28.89/28.99  tff(decl_23150, type, 'chemical-entity': $i).
% 28.89/28.99  tff(decl_23151, type, chemical_equation_expression_1: $i > $o).
% 28.89/28.99  tff(decl_23152, type, 'Chemical-Equation-Expression': $i).
% 28.89/28.99  tff(decl_23153, type, 'When a chemical reaction occurs, it can be described by an equation. This shows the chemicals that react (called the reactants) on the left-hand side, and the chemicals that they produce (called the products) on the right-hand side.': $i).
% 28.89/28.99  tff(decl_23154, type, 'chemical equation': $i).
% 28.89/28.99  tff(decl_23155, type, 'balanced equation': $i).
% 28.89/28.99  tff(decl_23156, type, 'chemical equation expression': $i).
% 28.89/28.99  tff(decl_23157, type, 'chemical-equation-expression': $i).
% 28.89/28.99  tff(decl_23158, type, km_class_1: $i > $o).
% 28.89/28.99  tff(decl_23159, type, chemical_equilibrium_1: $i > $o).
% 28.89/28.99  tff(decl_23160, type, 'Chemical-Equilibrium': $i).
% 28.89/28.99  tff(decl_23161, type, 'The state in a chemical reaction in which the forward and reverse reactions occur at the same rate. There are no net changes in concentrations of reactants or products.': $i).
% 28.89/28.99  tff(decl_23162, type, 'equilibrium of chemical': $i).
% 28.89/28.99  tff(decl_23163, type, 'chemical equilibrium': $i).
% 28.89/28.99  tff(decl_23164, type, 'chemical-equilibrium': $i).
% 28.89/28.99  tff(decl_23165, type, 'Chemical-Equilibrium-Reaction': $i).
% 28.89/28.99  tff(decl_23166, type, 'Chemical equilibrium occurs when opposing reactions are proceeding at equal rates.': $i).
% 28.89/28.99  tff(decl_23167, type, 'chemical equilibrium reaction': $i).
% 28.89/28.99  tff(decl_23168, type, 'chemical-equilibrium-reaction': $i).
% 28.89/28.99  tff(decl_23169, type, fn_chemical_equilibrium_reaction_2: $i > $i).
% 28.89/28.99  tff(decl_23170, type, fn_chemical_equilibrium_reaction_11: $i > $i).
% 28.89/28.99  tff(decl_23171, type, fn_chemical_equilibrium_reaction_12: $i > $i).
% 28.89/28.99  tff(decl_23172, type, fn_chemical_equilibrium_reaction_8: $i > $i).
% 28.89/28.99  tff(decl_23173, type, fn_reversible_reaction_1: $i > $i).
% 28.89/28.99  tff(decl_23174, type, fn_reversible_reaction_4: $i > $i).
% 28.89/28.99  tff(decl_23175, type, fn_chemical_equilibrium_reaction_7: $i > $i).
% 28.89/28.99  tff(decl_23176, type, fn_reversible_reaction_2: $i > $i).
% 28.89/28.99  tff(decl_23177, type, fn_reversible_reaction_3: $i > $i).
% 28.89/28.99  tff(decl_23178, type, chemical_formula_1: $i > $o).
% 28.89/28.99  tff(decl_23179, type, 'Chemical-Formula': $i).
% 28.89/28.99  tff(decl_23180, type, formula: $i).
% 28.89/28.99  tff(decl_23181, type, 'formula of chemical': $i).
% 28.89/28.99  tff(decl_23182, type, 'chemical formula': $i).
% 28.89/28.99  tff(decl_23183, type, 'chemical-formula': $i).
% 28.89/28.99  tff(decl_23184, type, 'Chemical-Marker': $i).
% 28.89/28.99  tff(decl_23185, type, 'Chemical tag used to label a chemical entity.': $i).
% 28.89/28.99  tff(decl_23186, type, 'marker of chemical': $i).
% 28.89/28.99  tff(decl_23187, type, 'chemical marker': $i).
% 28.89/28.99  tff(decl_23188, type, 'chemical-marker': $i).
% 28.89/28.99  tff(decl_23189, type, fn_chemical_marker_1: $i > $i).
% 28.89/28.99  tff(decl_23190, type, mark_1: $i > $o).
% 28.89/28.99  tff(decl_23191, type, 'Chemical-Messenger': $i).
% 28.89/28.99  tff(decl_23192, type, 'A chemical that is used in signaling between cells.  This chemical binds to cells, relaying a signal message.': $i).
% 28.89/28.99  tff(decl_23193, type, 'molecular messenger': $i).
% 28.89/28.99  tff(decl_23194, type, 'chemical signal': $i).
% 28.89/28.99  tff(decl_23195, type, 'signal molecule': $i).
% 28.89/28.99  tff(decl_23196, type, 'signal messenger': $i).
% 28.89/28.99  tff(decl_23197, type, 'messenger of chemical': $i).
% 28.89/28.99  tff(decl_23198, type, 'chemical messenger': $i).
% 28.89/28.99  tff(decl_23199, type, 'chemical-messenger': $i).
% 28.89/28.99  tff(decl_23200, type, 'Chemical-Polarity-Constant': $i).
% 28.89/28.99  tff(decl_23201, type, 'chemical polarity constant': $i).
% 28.89/28.99  tff(decl_23202, type, 'chemical-polarity-constant': $i).
% 28.89/28.99  tff(decl_23203, type, 'Chemical-Polarity-Value': $i).
% 28.89/28.99  tff(decl_23204, type, polarity: $i).
% 28.89/28.99  tff(decl_23205, type, sign: $i).
% 28.89/28.99  tff(decl_23206, type, 'polarity of chemical': $i).
% 28.89/28.99  tff(decl_23207, type, 'chemical polarity': $i).
% 28.89/28.99  tff(decl_23208, type, 'chemical-polarity': $i).
% 28.89/28.99  tff(decl_23209, type, 'chemical polarity value': $i).
% 28.89/28.99  tff(decl_23210, type, 'chemical-polarity-value': $i).
% 28.89/28.99  tff(decl_23211, type, 'Chemical-Reaction': $i).
% 28.89/28.99  tff(decl_23212, type, 'A chemical reaction is a process in which one or more chemical entities are converted into others. This differs from reaction in that energy can be used as a raw material or result.': $i).
% 28.89/28.99  tff(decl_23213, type, 'reaction of chemical': $i).
% 28.89/28.99  tff(decl_23214, type, 'chemical reaction': $i).
% 28.89/28.99  tff(decl_23215, type, 'chemical-reaction': $i).
% 28.89/28.99  tff(decl_23216, type, chemical_reaction_between_methane_and_oxygen_1: $i > $o).
% 28.89/28.99  tff(decl_23217, type, 'Chemical-Reaction-Between-Methane-And-Oxygen': $i).
% 28.89/28.99  tff(decl_23218, type, 'A type of combustion reaction which produces carbon dioxide and water.': $i).
% 28.89/28.99  tff(decl_23219, type, 'chemical reaction between methane and oxygen': $i).
% 28.89/28.99  tff(decl_23220, type, 'chemical-reaction-between-methane-and-oxygen': $i).
% 28.89/28.99  tff(decl_23221, type, fn_chemical_reaction_between_methane_and_oxygen_1: $i > $i).
% 28.89/28.99  tff(decl_23222, type, fn_chemical_reaction_between_methane_and_oxygen_2: $i > $i).
% 28.89/28.99  tff(decl_23223, type, fn_chemical_reaction_between_methane_and_oxygen_3: $i > $i).
% 28.89/28.99  tff(decl_23224, type, fn_chemical_reaction_between_methane_and_oxygen_4: $i > $i).
% 28.89/28.99  tff(decl_23225, type, fn_chemical_reaction_between_methane_and_oxygen_5: $i > $i).
% 28.89/28.99  tff(decl_23226, type, fn_chemical_reaction_between_methane_and_oxygen_6: $i > $i).
% 28.89/28.99  tff(decl_23227, type, fn_chemical_reaction_between_methane_and_oxygen_7: $i > $i).
% 28.89/28.99  tff(decl_23228, type, fn_chemical_reaction_between_methane_and_oxygen_8: $i > $i).
% 28.89/28.99  tff(decl_23229, type, fn_chemical_reaction_between_methane_and_oxygen_9: $i > $i).
% 28.89/28.99  tff(decl_23230, type, fn_chemical_reaction_between_methane_and_oxygen_10: $i > $i).
% 28.89/28.99  tff(decl_23231, type, methane_1: $i > $o).
% 28.89/28.99  tff(decl_23232, type, fn_chemical_reaction_between_methane_and_oxygen_11: $i > $i).
% 28.89/28.99  tff(decl_23233, type, fn_chemical_reaction_between_methane_and_oxygen_12: $i > $i).
% 28.89/28.99  tff(decl_23234, type, chemical_representation_1: $i > $o).
% 28.89/28.99  tff(decl_23235, type, 'Chemical-Representation': $i).
% 28.89/28.99  tff(decl_23236, type, 'A method of representing chemical data.': $i).
% 28.89/28.99  tff(decl_23237, type, 'representation of chemical': $i).
% 28.89/28.99  tff(decl_23238, type, 'chemical representation': $i).
% 28.89/28.99  tff(decl_23239, type, 'chemical-representation': $i).
% 28.89/28.99  tff(decl_23240, type, 'Chemical-Signaling': $i).
% 28.89/28.99  tff(decl_23241, type, 'The process of transmitting a message from one cell to another.  The three stages are reception, transduction, and response.': $i).
% 28.89/28.99  tff(decl_23242, type, 'signaling of chemical': $i).
% 28.89/28.99  tff(decl_23243, type, 'chemical signaling': $i).
% 28.89/28.99  tff(decl_23244, type, 'chemical-signaling': $i).
% 28.89/28.99  tff(decl_23245, type, fn_chemical_signaling_1: $i > $i).
% 28.89/28.99  tff(decl_23246, type, fn_chemical_signaling_2: $i > $i).
% 28.89/28.99  tff(decl_23247, type, chemical_stability_1: $i > $o).
% 28.89/28.99  tff(decl_23248, type, 'Chemical-Stability': $i).
% 28.89/28.99  tff(decl_23249, type, 'A state in which chemicals are resistant to change.': $i).
% 28.89/28.99  tff(decl_23250, type, 'stability of chemical': $i).
% 28.89/28.99  tff(decl_23251, type, 'chemical stability': $i).
% 28.89/28.99  tff(decl_23252, type, 'chemical-stability': $i).
% 28.89/28.99  tff(decl_23253, type, 'Chemical-Stability-Constant': $i).
% 28.89/28.99  tff(decl_23254, type, 'chemical stability constant': $i).
% 28.89/28.99  tff(decl_23255, type, 'chemical-stability-constant': $i).
% 28.89/28.99  tff(decl_23256, type, 'Chemical-Stability-Value': $i).
% 28.89/28.99  tff(decl_23257, type, stability: $i).
% 28.89/28.99  tff(decl_23258, type, 'chemical stability value': $i).
% 28.89/28.99  tff(decl_23259, type, 'chemical-stability-value': $i).
% 28.89/28.99  tff(decl_23260, type, chemical_work_1: $i > $o).
% 28.89/28.99  tff(decl_23261, type, 'Chemical-Work': $i).
% 28.89/28.99  tff(decl_23262, type, 'Work done by change in the internal energy of a body by alterations of the composition.': $i).
% 28.89/28.99  tff(decl_23263, type, 'perform chemical work': $i).
% 28.89/28.99  tff(decl_23264, type, 'work of chemical': $i).
% 28.89/28.99  tff(decl_23265, type, 'chemical work': $i).
% 28.89/28.99  tff(decl_23266, type, 'chemical-work': $i).
% 28.89/28.99  tff(decl_23267, type, 'Chemiosmosis': $i).
% 28.89/28.99  tff(decl_23268, type, 'Chemiosmosis is the movement of ions across a selectively-permeable membrane, through a channel protein, ATP synthase down their electrochemical gradient. More specifically, it relates to the generation of ATP by the movement of hydrogen ions across a membrane during cellular respiration.': $i).
% 28.89/28.99  tff(decl_23269, type, 'perform chemiosmosis': $i).
% 28.89/28.99  tff(decl_23270, type, chemiosmosis: $i).
% 28.89/28.99  tff(decl_23271, type, diffusion_of_water_across_membrane_separating_two_isotonic_solution_1: $i > $o).
% 28.89/28.99  tff(decl_23272, type, fn_chemiosmosis_1: $i > $i).
% 28.89/28.99  tff(decl_23273, type, fn_chemiosmosis_2: $i > $i).
% 28.89/28.99  tff(decl_23274, type, fn_chemiosmosis_3: $i > $i).
% 28.89/28.99  tff(decl_23275, type, fn_chemiosmosis_4: $i > $i).
% 28.89/28.99  tff(decl_23276, type, fn_chemiosmosis_5: $i > $i).
% 28.89/28.99  tff(decl_23277, type, fn_chemiosmosis_6: $i > $i).
% 28.89/28.99  tff(decl_23278, type, fn_chemiosmosis_7: $i > $i).
% 28.89/28.99  tff(decl_23279, type, fn_chemiosmosis_9: $i > $i).
% 28.89/28.99  tff(decl_23280, type, fn_chemiosmosis_10: $i > $i).
% 28.89/28.99  tff(decl_23281, type, fn_chemiosmosis_11: $i > $i).
% 28.89/28.99  tff(decl_23282, type, fn_chemiosmosis_12: $i > $i).
% 28.89/28.99  tff(decl_23283, type, fn_chemiosmosis_13: $i > $i).
% 28.89/28.99  tff(decl_23284, type, fn_chemiosmosis_14: $i > $i).
% 28.89/28.99  tff(decl_23285, type, fn_chemiosmosis_15: $i > $i).
% 28.89/28.99  tff(decl_23286, type, fn_chemiosmosis_16: $i > $i).
% 28.89/28.99  tff(decl_23287, type, fn_chemiosmosis_17: $i > $i).
% 28.89/28.99  tff(decl_23288, type, fn_chemiosmosis_18: $i > $i).
% 28.89/28.99  tff(decl_23289, type, fn_chemiosmosis_19: $i > $i).
% 28.89/28.99  tff(decl_23290, type, fn_chemiosmosis_20: $i > $i).
% 28.89/28.99  tff(decl_23291, type, fn_chemiosmosis_21: $i > $i).
% 28.89/28.99  tff(decl_23292, type, fn_chemiosmosis_22: $i > $i).
% 28.89/28.99  tff(decl_23293, type, fn_chemiosmosis_30: $i > $i).
% 28.89/28.99  tff(decl_23294, type, fn_chemiosmosis_32: $i > $i).
% 28.89/28.99  tff(decl_23295, type, fn_chemiosmosis_33: $i > $i).
% 28.89/28.99  tff(decl_23296, type, fn_chemiosmosis_40: $i > $i).
% 28.89/28.99  tff(decl_23297, type, fn_chemiosmosis_42: $i > $i).
% 28.89/28.99  tff(decl_23298, type, fn_chemiosmosis_43: $i > $i).
% 28.89/28.99  tff(decl_23299, type, fn_chemiosmosis_47: $i > $i).
% 28.89/28.99  tff(decl_23300, type, fn_chemiosmosis_48: $i > $i).
% 28.89/28.99  tff(decl_23301, type, fn_chemiosmosis_49: $i > $i).
% 28.89/28.99  tff(decl_23302, type, fn_chemiosmosis_50: $i > $i).
% 28.89/28.99  tff(decl_23303, type, fn_chemiosmosis_51: $i > $i).
% 28.89/28.99  tff(decl_23304, type, fn_chemiosmosis_52: $i > $i).
% 28.89/28.99  tff(decl_23305, type, fn_chemiosmosis_53: $i > $i).
% 28.89/28.99  tff(decl_23306, type, fn_chemiosmosis_54: $i > $i).
% 28.89/28.99  tff(decl_23307, type, fn_chemiosmosis_55: $i > $i).
% 28.89/28.99  tff(decl_23308, type, fn_chemiosmosis_56: $i > $i).
% 28.89/28.99  tff(decl_23309, type, fn_chemiosmosis_57: $i > $i).
% 28.89/28.99  tff(decl_23310, type, fn_chemiosmosis_58: $i > $i).
% 28.89/28.99  tff(decl_23311, type, fn_chemiosmosis_59: $i > $i).
% 28.89/28.99  tff(decl_23312, type, fn_chemiosmosis_60: $i > $i).
% 28.89/28.99  tff(decl_23313, type, fn_chemiosmosis_61: $i > $i).
% 28.89/28.99  tff(decl_23314, type, fn_chemiosmosis_62: $i > $i).
% 28.89/28.99  tff(decl_23315, type, fn_chemiosmosis_63: $i > $i).
% 28.89/28.99  tff(decl_23316, type, fn_chemiosmosis_64: $i > $i).
% 28.89/28.99  tff(decl_23317, type, fn_chemiosmosis_65: $i > $i).
% 28.89/28.99  tff(decl_23318, type, fn_chemiosmosis_70: $i > $i).
% 28.89/28.99  tff(decl_23319, type, fn_chemiosmosis_71: $i > $i).
% 28.89/28.99  tff(decl_23320, type, fn_chemiosmosis_72: $i > $i).
% 28.89/28.99  tff(decl_23321, type, fn_chemiosmosis_73: $i > $i).
% 28.89/28.99  tff(decl_23322, type, fn_chemiosmosis_74: $i > $i).
% 28.89/28.99  tff(decl_23323, type, fn_chemiosmosis_75: $i > $i).
% 28.89/28.99  tff(decl_23324, type, fn_chemiosmosis_76: $i > $i).
% 28.89/28.99  tff(decl_23325, type, fn_chemiosmosis_77: $i > $i).
% 28.89/28.99  tff(decl_23326, type, fn_chemiosmosis_78: $i > $i).
% 28.89/28.99  tff(decl_23327, type, fn_chemiosmosis_79: $i > $i).
% 28.89/28.99  tff(decl_23328, type, fn_chemiosmosis_80: $i > $i).
% 28.89/28.99  tff(decl_23329, type, fn_chemiosmosis_81: $i > $i).
% 28.89/28.99  tff(decl_23330, type, fn_chemiosmosis_82: $i > $i).
% 28.89/28.99  tff(decl_23331, type, fn_chemiosmosis_83: $i > $i).
% 28.89/28.99  tff(decl_23332, type, fn_chemiosmosis_84: $i > $i).
% 28.89/28.99  tff(decl_23333, type, fn_chemiosmosis_85: $i > $i).
% 28.89/28.99  tff(decl_23334, type, fn_chemiosmosis_87: $i > $i).
% 28.89/28.99  tff(decl_23335, type, fn_chemiosmosis_91: $i > $i).
% 28.89/28.99  tff(decl_23336, type, fn_chemiosmosis_92: $i > $i).
% 28.89/28.99  tff(decl_23337, type, fn_chemiosmosis_93: $i > $i).
% 28.89/28.99  tff(decl_23338, type, fn_chemiosmosis_94: $i > $i).
% 28.89/28.99  tff(decl_23339, type, fn_chemiosmosis_95: $i > $i).
% 28.89/28.99  tff(decl_23340, type, fn_chemiosmosis_96: $i > $i).
% 28.89/28.99  tff(decl_23341, type, fn_chemiosmosis_97: $i > $i).
% 28.89/28.99  tff(decl_23342, type, fn_chemiosmosis_98: $i > $i).
% 28.89/28.99  tff(decl_23343, type, fn_chemiosmosis_99: $i > $i).
% 28.89/28.99  tff(decl_23344, type, fn_chemiosmosis_101: $i > $i).
% 28.89/28.99  tff(decl_23345, type, fn_chemiosmosis_102: $i > $i).
% 28.89/28.99  tff(decl_23346, type, fn_chemiosmosis_103: $i > $i).
% 28.89/28.99  tff(decl_23347, type, fn_chemiosmosis_104: $i > $i).
% 28.89/28.99  tff(decl_23348, type, fn_chemiosmosis_105: $i > $i).
% 28.89/28.99  tff(decl_23349, type, fn_chemiosmosis_106: $i > $i).
% 28.89/28.99  tff(decl_23350, type, fn_chemiosmosis_107: $i > $i).
% 28.89/28.99  tff(decl_23351, type, fn_chemiosmosis_108: $i > $i).
% 28.89/28.99  tff(decl_23352, type, fn_chemiosmosis_109: $i > $i).
% 28.89/28.99  tff(decl_23353, type, fn_chemiosmosis_111: $i > $i).
% 28.89/28.99  tff(decl_23354, type, fn_chemiosmosis_112: $i > $i).
% 28.89/28.99  tff(decl_23355, type, fn_chemiosmosis_114: $i > $i).
% 28.89/28.99  tff(decl_23356, type, fn_chemiosmosis_115: $i > $i).
% 28.89/28.99  tff(decl_23357, type, fn_chemiosmosis_116: $i > $i).
% 28.89/28.99  tff(decl_23358, type, fn_chemiosmosis_117: $i > $i).
% 28.89/28.99  tff(decl_23359, type, fn_chemiosmosis_119: $i > $i).
% 28.89/28.99  tff(decl_23360, type, spontaneous_change_1: $i > $o).
% 28.89/28.99  tff(decl_23361, type, fn_chemiosmosis_120: $i > $i).
% 28.89/28.99  tff(decl_23362, type, fn_chemiosmosis_121: $i > $i).
% 28.89/28.99  tff(decl_23363, type, fn_chemiosmosis_122: $i > $i).
% 28.89/28.99  tff(decl_23364, type, fn_chemiosmosis_123: $i > $i).
% 28.89/28.99  tff(decl_23365, type, fn_stator_2: $i > $i).
% 28.89/28.99  tff(decl_23366, type, fn_decrease_2: $i > $i).
% 28.89/28.99  tff(decl_23367, type, fn_generation_of_hydrogen_ion_gradient_across_biomembrane_2: $i > $i).
% 28.89/28.99  tff(decl_23368, type, fn_passive_transport_15: $i > $i).
% 28.89/28.99  tff(decl_23369, type, fn_passive_transport_19: $i > $i).
% 28.89/28.99  tff(decl_23370, type, fn_facilitated_diffusion_52: $i > $i).
% 28.89/28.99  tff(decl_23371, type, fn_facilitated_diffusion_50: $i > $i).
% 28.89/28.99  tff(decl_23372, type, fn_facilitated_diffusion_51: $i > $i).
% 28.89/28.99  tff(decl_23373, type, fn_gradient_1: $i > $i).
% 28.89/28.99  tff(decl_23374, type, fn_spontaneous_change_8: $i > $i).
% 28.89/28.99  tff(decl_23375, type, fn_facilitated_diffusion_26: $i > $i).
% 28.89/28.99  tff(decl_23376, type, fn_generation_of_hydrogen_ion_gradient_across_biomembrane_3: $i > $i).
% 28.89/28.99  tff(decl_23377, type, fn_knob_5: $i > $i).
% 28.89/28.99  tff(decl_23378, type, fn_spontaneous_change_9: $i > $i).
% 28.89/28.99  tff(decl_23379, type, fn_passive_transport_16: $i > $i).
% 28.89/28.99  tff(decl_23380, type, fn_gradient_5: $i > $i).
% 28.89/28.99  tff(decl_23381, type, fn_passive_transport_30: $i > $i).
% 28.89/28.99  tff(decl_23382, type, fn_gradient_3: $i > $i).
% 28.89/28.99  tff(decl_23383, type, fn_electrochemical_gradient_18: $i > $i).
% 28.89/28.99  tff(decl_23384, type, fn_passive_transport_28: $i > $i).
% 28.89/28.99  tff(decl_23385, type, fn_gradient_2: $i > $i).
% 28.89/28.99  tff(decl_23386, type, fn_spontaneous_change_7: $i > $i).
% 28.89/28.99  tff(decl_23387, type, fn_passive_transport_18: $i > $i).
% 28.89/28.99  tff(decl_23388, type, fn_passive_transport_17: $i > $i).
% 28.89/28.99  tff(decl_23389, type, fn_generation_of_hydrogen_ion_gradient_across_biomembrane_6: $i > $i).
% 28.89/28.99  tff(decl_23390, type, fn_generation_of_hydrogen_ion_gradient_across_biomembrane_5: $i > $i).
% 28.89/28.99  tff(decl_23391, type, 'PE_EG': $i).
% 28.89/28.99  tff(decl_23392, type, 'EG': $i).
% 28.89/28.99  tff(decl_23393, type, 'HC1': $i).
% 28.89/28.99  tff(decl_23394, type, fn_chemiosmosis_113: $i > $i).
% 28.89/28.99  tff(decl_23395, type, fn_chemiosmosis_29: $i > $i).
% 28.89/28.99  tff(decl_23396, type, fn_chemiosmosis_86: $i > $i).
% 28.89/28.99  tff(decl_23397, type, fn_chemiosmosis_110: $i > $i).
% 28.89/28.99  tff(decl_23398, type, fn_chemiosmosis_68: $i > $i).
% 28.89/28.99  tff(decl_23399, type, fn_chemiosmosis_67: $i > $i).
% 28.89/28.99  tff(decl_23400, type, fn_chemiosmosis_66: $i > $i).
% 28.89/28.99  tff(decl_23401, type, fn_chemiosmosis_69: $i > $i).
% 28.89/28.99  tff(decl_23402, type, fn_chemiosmosis_28: $i > $i).
% 28.89/28.99  tff(decl_23403, type, fn_chemiosmosis_27: $i > $i).
% 28.89/28.99  tff(decl_23404, type, fn_chemiosmosis_90: $i > $i).
% 28.89/28.99  tff(decl_23405, type, fn_chemiosmosis_89: $i > $i).
% 28.89/28.99  tff(decl_23406, type, fn_chemiosmosis_88: $i > $i).
% 28.89/28.99  tff(decl_23407, type, chemistry_concept_1: $i > $o).
% 28.89/28.99  tff(decl_23408, type, 'Chemistry-Concept': $i).
% 28.89/28.99  tff(decl_23409, type, 'A concept related to chemistry and chemical changes.': $i).
% 28.89/28.99  tff(decl_23410, type, 'concept of chemistry': $i).
% 28.89/28.99  tff(decl_23411, type, 'chemistry concept': $i).
% 28.89/28.99  tff(decl_23412, type, 'chemistry-concept': $i).
% 28.89/28.99  tff(decl_23413, type, chemoautotroph_1: $i > $o).
% 28.89/28.99  tff(decl_23414, type, 'Chemoautotroph': $i).
% 28.89/28.99  tff(decl_23415, type, 'An organism that needs only carbon dioxide as a carbon source but obtains energy by oxidizing inorganic substances.': $i).
% 28.89/28.99  tff(decl_23416, type, fn_chemoautotroph_1: $i > $i).
% 28.89/28.99  tff(decl_23417, type, fn_chemoautotroph_2: $i > $i).
% 28.89/28.99  tff(decl_23418, type, fn_chemoautotroph_3: $i > $i).
% 28.89/28.99  tff(decl_23419, type, fn_chemoautotroph_4: $i > $i).
% 28.89/28.99  tff(decl_23420, type, fn_chemoautotroph_5: $i > $i).
% 28.89/28.99  tff(decl_23421, type, fn_chemoautotroph_6: $i > $i).
% 28.89/28.99  tff(decl_23422, type, 'Chemoheterotroph': $i).
% 28.89/28.99  tff(decl_23423, type, 'An organism that must consume organic molecules for both carbon and energy.': $i).
% 28.89/28.99  tff(decl_23424, type, chemoheterotroph: $i).
% 28.89/28.99  tff(decl_23425, type, obligate_aerobe_1: $i > $o).
% 28.89/28.99  tff(decl_23426, type, parasite_1: $i > $o).
% 28.89/28.99  tff(decl_23427, type, photoheterotroph_1: $i > $o).
% 28.89/28.99  tff(decl_23428, type, secondary_consumer_1: $i > $o).
% 28.89/28.99  tff(decl_23429, type, tertiary_consumer_1: $i > $o).
% 28.89/28.99  tff(decl_23430, type, fn_chemoheterotroph_1: $i > $i).
% 28.89/28.99  tff(decl_23431, type, fn_chemoheterotroph_2: $i > $i).
% 28.89/28.99  tff(decl_23432, type, fn_chemoheterotroph_3: $i > $i).
% 28.89/28.99  tff(decl_23433, type, fn_heterotroph_4: $i > $i).
% 28.89/28.99  tff(decl_23434, type, chemoreceptor_1: $i > $o).
% 28.89/28.99  tff(decl_23435, type, 'Chemoreceptor': $i).
% 28.89/28.99  tff(decl_23436, type, 'A sensory receptor that detects a chemical stimulus, such as a solute or an odorant, and transduces it into an action potential.': $i).
% 28.89/28.99  tff(decl_23437, type, chemoreceptor: $i).
% 28.89/28.99  tff(decl_23438, type, sensory_receptor_1: $i > $o).
% 28.89/28.99  tff(decl_23439, type, electromagnetic_receptor_1: $i > $o).
% 28.89/28.99  tff(decl_23440, type, exteroceptor_1: $i > $o).
% 28.89/28.99  tff(decl_23441, type, mechanoreceptor_1: $i > $o).
% 28.89/28.99  tff(decl_23442, type, nociceptor_1: $i > $o).
% 28.89/28.99  tff(decl_23443, type, pain_receptor_1: $i > $o).
% 28.89/28.99  tff(decl_23444, type, thermoreceptor_1: $i > $o).
% 28.89/28.99  tff(decl_23445, type, chemotaxis_1: $i > $o).
% 28.89/28.99  tff(decl_23446, type, 'Chemotaxis': $i).
% 28.89/28.99  tff(decl_23447, type, 'Movement of a cell or a unicellular organism in response to a chemical in the environment.': $i).
% 28.89/28.99  tff(decl_23448, type, 'undergo chemotaxis': $i).
% 28.89/28.99  tff(decl_23449, type, chemotaxis: $i).
% 28.89/28.99  tff(decl_23450, type, 'Chemotherapeutic-Drug': $i).
% 28.89/28.99  tff(decl_23451, type, 'A chemical with anti-cancer properties used to treat cancer.': $i).
% 28.89/28.99  tff(decl_23452, type, chemotherapy: $i).
% 28.89/28.99  tff(decl_23453, type, 'chemotherapeutic drug': $i).
% 28.89/28.99  tff(decl_23454, type, 'chemotherapeutic-drug': $i).
% 28.89/28.99  tff(decl_23455, type, fn_chemotherapeutic_drug_1: $i > $i).
% 28.89/28.99  tff(decl_23456, type, fn_chemotherapeutic_drug_2: $i > $i).
% 28.89/28.99  tff(decl_23457, type, chemotherapy_1: $i > $o).
% 28.89/28.99  tff(decl_23458, type, 'Chemotherapy': $i).
% 28.89/28.99  tff(decl_23459, type, 'Chemical, systemic reatment for cancer which targets and destroys rapidly dividing cells.': $i).
% 28.89/28.99  tff(decl_23460, type, fn_chemotherapy_1: $i > $i).
% 28.89/28.99  tff(decl_23461, type, fn_chemotherapy_2: $i > $i).
% 28.89/28.99  tff(decl_23462, type, fn_chemotherapy_3: $i > $i).
% 28.89/28.99  tff(decl_23463, type, chew_1: $i > $o).
% 28.89/28.99  tff(decl_23464, type, 'Chew': $i).
% 28.89/28.99  tff(decl_23465, type, 'The process of using teeth to bite and grind food particles into smaller pieces to aid swallowing and digestion.': $i).
% 28.89/28.99  tff(decl_23466, type, chew: $i).
% 28.89/28.99  tff(decl_23467, type, mechanical_digestion_1: $i > $o).
% 28.89/28.99  tff(decl_23468, type, 'Chiasma': $i).
% 28.89/28.99  tff(decl_23469, type, 'A chiasma in genetics, is thought to be the point where two homologous non-sister chromatids exchange genetic material during chromosomal crossover during meiosis.': $i).
% 28.89/28.99  tff(decl_23470, type, chiasmata: $i).
% 28.89/28.99  tff(decl_23471, type, chiasma: $i).
% 28.89/28.99  tff(decl_23472, type, chicken_1: $i > $o).
% 28.89/28.99  tff(decl_23473, type, 'Chicken': $i).
% 28.89/28.99  tff(decl_23474, type, 'Species of domesticated bird widely raised for meat and eggs. Scientific name is Gallus gallus domesticus.': $i).
% 28.89/28.99  tff(decl_23475, type, chicken: $i).
% 28.89/28.99  tff(decl_23476, type, fn_chicken_1: $i > $i).
% 28.89/28.99  tff(decl_23477, type, fn_chicken_2: $i > $i).
% 28.89/28.99  tff(decl_23478, type, chief_cell_1: $i > $o).
% 28.89/28.99  tff(decl_23479, type, 'Chief-Cell': $i).
% 28.89/28.99  tff(decl_23480, type, 'Secretory cell found in the lining of the stomach which produces and secretes pepsinogen (the inactive form of the digestive enzyme pepsin) into the lumen of the stomach.': $i).
% 28.89/28.99  tff(decl_23481, type, 'cell of chief': $i).
% 28.89/28.99  tff(decl_23482, type, 'chief cell': $i).
% 28.89/28.99  tff(decl_23483, type, 'chief-cell': $i).
% 28.89/28.99  tff(decl_23484, type, fn_chief_cell_1: $i > $i).
% 28.89/28.99  tff(decl_23485, type, fn_chief_cell_2: $i > $i).
% 28.89/28.99  tff(decl_23486, type, fn_chief_cell_3: $i > $i).
% 28.89/28.99  tff(decl_23487, type, fn_chief_cell_4: $i > $i).
% 28.89/28.99  tff(decl_23488, type, fn_chief_cell_7: $i > $i).
% 28.89/28.99  tff(decl_23489, type, synthesis_of_glycoprotein_1: $i > $o).
% 28.89/28.99  tff(decl_23490, type, fn_chief_cell_8: $i > $i).
% 28.89/28.99  tff(decl_23491, type, fn_chief_cell_9: $i > $i).
% 28.89/28.99  tff(decl_23492, type, fn_chief_cell_10: $i > $i).
% 28.89/28.99  tff(decl_23493, type, fn_chief_cell_11: $i > $i).
% 28.89/28.99  tff(decl_23494, type, fn_chief_cell_12: $i > $i).
% 28.89/28.99  tff(decl_23495, type, fn_chief_cell_13: $i > $i).
% 28.89/28.99  tff(decl_23496, type, fn_chief_cell_14: $i > $i).
% 28.89/28.99  tff(decl_23497, type, fn_chief_cell_15: $i > $i).
% 28.89/28.99  tff(decl_23498, type, fn_chief_cell_16: $i > $i).
% 28.89/28.99  tff(decl_23499, type, fn_chief_cell_17: $i > $i).
% 28.89/28.99  tff(decl_23500, type, fn_chief_cell_20: $i > $i).
% 28.89/28.99  tff(decl_23501, type, fn_chief_cell_21: $i > $i).
% 28.89/28.99  tff(decl_23502, type, synthesis_of_membrane_protein_1: $i > $o).
% 28.89/28.99  tff(decl_23503, type, fn_chief_cell_22: $i > $i).
% 28.89/28.99  tff(decl_23504, type, fn_chief_cell_23: $i > $i).
% 28.89/28.99  tff(decl_23505, type, fn_chief_cell_24: $i > $i).
% 28.89/28.99  tff(decl_23506, type, fn_chief_cell_25: $i > $i).
% 28.89/28.99  tff(decl_23507, type, fn_chief_cell_26: $i > $i).
% 28.89/28.99  tff(decl_23508, type, fn_chief_cell_27: $i > $i).
% 28.89/28.99  tff(decl_23509, type, fn_chief_cell_28: $i > $i).
% 28.89/28.99  tff(decl_23510, type, fn_chief_cell_29: $i > $i).
% 28.89/28.99  tff(decl_23511, type, fn_chief_cell_30: $i > $i).
% 28.89/28.99  tff(decl_23512, type, fn_chief_cell_31: $i > $i).
% 28.89/28.99  tff(decl_23513, type, fn_chief_cell_32: $i > $i).
% 28.89/28.99  tff(decl_23514, type, fn_chief_cell_33: $i > $i).
% 28.89/28.99  tff(decl_23515, type, fn_chief_cell_34: $i > $i).
% 28.89/28.99  tff(decl_23516, type, fn_chief_cell_35: $i > $i).
% 28.89/28.99  tff(decl_23517, type, fn_chief_cell_36: $i > $i).
% 28.89/28.99  tff(decl_23518, type, fn_chief_cell_37: $i > $i).
% 28.89/28.99  tff(decl_23519, type, fn_chief_cell_38: $i > $i).
% 28.89/28.99  tff(decl_23520, type, fn_chief_cell_39: $i > $i).
% 28.89/28.99  tff(decl_23521, type, fn_chief_cell_40: $i > $i).
% 28.89/28.99  tff(decl_23522, type, fn_chief_cell_41: $i > $i).
% 28.89/28.99  tff(decl_23523, type, fn_chief_cell_42: $i > $i).
% 28.89/28.99  tff(decl_23524, type, fn_chief_cell_43: $i > $i).
% 28.89/28.99  tff(decl_23525, type, fn_chief_cell_44: $i > $i).
% 28.89/28.99  tff(decl_23526, type, fn_chief_cell_45: $i > $i).
% 28.89/28.99  tff(decl_23527, type, receive_1: $i > $o).
% 28.89/28.99  tff(decl_23528, type, fn_chief_cell_46: $i > $i).
% 28.89/28.99  tff(decl_23529, type, fn_chief_cell_47: $i > $i).
% 28.89/28.99  tff(decl_23530, type, fn_chief_cell_48: $i > $i).
% 28.89/28.99  tff(decl_23531, type, fn_chief_cell_49: $i > $i).
% 28.89/28.99  tff(decl_23532, type, fn_chief_cell_50: $i > $i).
% 28.89/28.99  tff(decl_23533, type, fn_chief_cell_51: $i > $i).
% 28.89/28.99  tff(decl_23534, type, fn_chief_cell_52: $i > $i).
% 28.89/28.99  tff(decl_23535, type, fn_chief_cell_53: $i > $i).
% 28.89/28.99  tff(decl_23536, type, pepsinogen_1: $i > $o).
% 28.89/28.99  tff(decl_23537, type, fn_chief_cell_54: $i > $i).
% 28.89/28.99  tff(decl_23538, type, fn_chief_cell_55: $i > $i).
% 28.89/28.99  tff(decl_23539, type, fn_chief_cell_56: $i > $i).
% 28.89/28.99  tff(decl_23540, type, fn_chief_cell_57: $i > $i).
% 28.89/28.99  tff(decl_23541, type, fn_chief_cell_58: $i > $i).
% 28.89/28.99  tff(decl_23542, type, fn_chief_cell_59: $i > $i).
% 28.89/28.99  tff(decl_23543, type, fn_chief_cell_60: $i > $i).
% 28.89/28.99  tff(decl_23544, type, fn_chief_cell_61: $i > $i).
% 28.89/28.99  tff(decl_23545, type, fn_chief_cell_62: $i > $i).
% 28.89/28.99  tff(decl_23546, type, fn_chief_cell_63: $i > $i).
% 28.89/28.99  tff(decl_23547, type, fn_chief_cell_64: $i > $i).
% 28.89/28.99  tff(decl_23548, type, fn_chief_cell_65: $i > $i).
% 28.89/28.99  tff(decl_23549, type, fn_chief_cell_66: $i > $i).
% 28.89/28.99  tff(decl_23550, type, fn_chief_cell_67: $i > $i).
% 28.89/28.99  tff(decl_23551, type, fn_chief_cell_68: $i > $i).
% 28.89/28.99  tff(decl_23552, type, fn_chief_cell_69: $i > $i).
% 28.89/28.99  tff(decl_23553, type, fn_chief_cell_70: $i > $i).
% 28.89/28.99  tff(decl_23554, type, fn_chief_cell_71: $i > $i).
% 28.89/28.99  tff(decl_23555, type, fn_chief_cell_72: $i > $i).
% 28.89/28.99  tff(decl_23556, type, fn_chief_cell_73: $i > $i).
% 28.89/28.99  tff(decl_23557, type, fn_ribosome_2: $i > $i).
% 28.89/28.99  tff(decl_23558, type, fn_stomach_16: $i > $i).
% 28.89/28.99  tff(decl_23559, type, fn_exocytosis_25: $i > $i).
% 28.89/28.99  tff(decl_23560, type, fn_exocytosis_47: $i > $i).
% 28.89/28.99  tff(decl_23561, type, fn_synthesis_of_protein_10: $i > $i).
% 28.89/28.99  tff(decl_23562, type, fn_synthesis_of_membrane_protein_25: $i > $i).
% 28.89/28.99  tff(decl_23563, type, fn_exocytosis_30: $i > $i).
% 28.89/28.99  tff(decl_23564, type, fn_exocytosis_24: $i > $i).
% 28.89/28.99  tff(decl_23565, type, fn_exocytosis_18: $i > $i).
% 28.89/28.99  tff(decl_23566, type, fn_exocytosis_48: $i > $i).
% 28.89/28.99  tff(decl_23567, type, fn_smooth_endoplasmic_reticulum_13: $i > $i).
% 28.89/28.99  tff(decl_23568, type, fn_synthesis_of_protein_11: $i > $i).
% 28.89/28.99  tff(decl_23569, type, fn_exocytosis_33: $i > $i).
% 28.89/28.99  tff(decl_23570, type, fn_secretory_cell_65: $i > $i).
% 28.89/28.99  tff(decl_23571, type, fn_secretory_cell_60: $i > $i).
% 28.89/28.99  tff(decl_23572, type, fn_secretory_cell_40: $i > $i).
% 28.89/28.99  tff(decl_23573, type, fn_secretory_cell_78: $i > $i).
% 28.89/28.99  tff(decl_23574, type, fn_secretory_cell_83: $i > $i).
% 28.89/28.99  tff(decl_23575, type, fn_secretory_cell_59: $i > $i).
% 28.89/28.99  tff(decl_23576, type, fn_secretory_cell_81: $i > $i).
% 28.89/28.99  tff(decl_23577, type, fn_secretory_cell_82: $i > $i).
% 28.89/28.99  tff(decl_23578, type, fn_secretory_cell_77: $i > $i).
% 28.89/28.99  tff(decl_23579, type, fn_secretory_cell_75: $i > $i).
% 28.89/28.99  tff(decl_23580, type, fn_secretory_cell_79: $i > $i).
% 28.89/28.99  tff(decl_23581, type, fn_secretory_cell_85: $i > $i).
% 28.89/28.99  tff(decl_23582, type, fn_secretory_cell_62: $i > $i).
% 28.89/28.99  tff(decl_23583, type, fn_chief_cell_19: $i > $i).
% 28.89/28.99  tff(decl_23584, type, fn_secretory_cell_74: $i > $i).
% 28.89/28.99  tff(decl_23585, type, fn_chief_cell_18: $i > $i).
% 28.89/28.99  tff(decl_23586, type, fn_secretory_cell_73: $i > $i).
% 28.89/28.99  tff(decl_23587, type, fn_secretory_cell_15: $i > $i).
% 28.89/28.99  tff(decl_23588, type, fn_secretory_cell_25: $i > $i).
% 28.89/28.99  tff(decl_23589, type, fn_secretory_cell_35: $i > $i).
% 28.89/28.99  tff(decl_23590, type, fn_secretory_cell_39: $i > $i).
% 28.89/28.99  tff(decl_23591, type, fn_secretory_cell_38: $i > $i).
% 28.89/28.99  tff(decl_23592, type, fn_secretory_cell_36: $i > $i).
% 28.89/28.99  tff(decl_23593, type, fn_secretory_cell_37: $i > $i).
% 28.89/28.99  tff(decl_23594, type, fn_secretory_cell_33: $i > $i).
% 28.89/28.99  tff(decl_23595, type, fn_secretory_cell_30: $i > $i).
% 28.89/28.99  tff(decl_23596, type, fn_secretory_cell_34: $i > $i).
% 28.89/28.99  tff(decl_23597, type, fn_secretory_cell_44: $i > $i).
% 28.89/28.99  tff(decl_23598, type, fn_secretory_cell_41: $i > $i).
% 28.89/28.99  tff(decl_23599, type, fn_secretory_cell_69: $i > $i).
% 28.89/28.99  tff(decl_23600, type, fn_secretory_cell_68: $i > $i).
% 28.89/28.99  tff(decl_23601, type, fn_secretory_cell_71: $i > $i).
% 28.89/28.99  tff(decl_23602, type, fn_secretory_cell_43: $i > $i).
% 28.89/28.99  tff(decl_23603, type, fn_secretory_cell_67: $i > $i).
% 28.89/28.99  tff(decl_23604, type, fn_secretory_cell_70: $i > $i).
% 28.89/28.99  tff(decl_23605, type, fn_secretory_cell_72: $i > $i).
% 28.89/28.99  tff(decl_23606, type, fn_secretory_cell_42: $i > $i).
% 28.89/28.99  tff(decl_23607, type, fn_secretory_cell_24: $i > $i).
% 28.89/28.99  tff(decl_23608, type, fn_secretory_cell_29: $i > $i).
% 28.89/28.99  tff(decl_23609, type, fn_secretory_cell_32: $i > $i).
% 28.89/28.99  tff(decl_23610, type, fn_secretory_cell_87: $i > $i).
% 28.89/28.99  tff(decl_23611, type, fn_secretory_cell_28: $i > $i).
% 28.89/28.99  tff(decl_23612, type, fn_secretory_cell_55: $i > $i).
% 28.89/28.99  tff(decl_23613, type, fn_secretory_cell_52: $i > $i).
% 28.89/28.99  tff(decl_23614, type, fn_secretory_cell_64: $i > $i).
% 28.89/28.99  tff(decl_23615, type, fn_secretory_cell_66: $i > $i).
% 28.89/28.99  tff(decl_23616, type, fn_secretory_cell_63: $i > $i).
% 28.89/28.99  tff(decl_23617, type, fn_secretory_cell_54: $i > $i).
% 28.89/28.99  tff(decl_23618, type, fn_secretory_cell_76: $i > $i).
% 28.89/28.99  tff(decl_23619, type, fn_secretory_cell_1: $i > $i).
% 28.89/28.99  tff(decl_23620, type, fn_secretory_cell_31: $i > $i).
% 28.89/28.99  tff(decl_23621, type, fn_secretory_cell_84: $i > $i).
% 28.89/28.99  tff(decl_23622, type, fn_secretory_cell_86: $i > $i).
% 28.89/28.99  tff(decl_23623, type, fn_secretory_cell_57: $i > $i).
% 28.89/28.99  tff(decl_23624, type, fn_secretory_cell_53: $i > $i).
% 28.89/28.99  tff(decl_23625, type, fn_secretory_cell_58: $i > $i).
% 28.89/28.99  tff(decl_23626, type, 'Childbirth': $i).
% 28.89/28.99  tff(decl_23627, type, 'The culmination of a human pregnancy, ending with the expulsion of an infant from the mother\\s uterus.': $i).
% 28.89/28.99  tff(decl_23628, type, childbirth: $i).
% 28.89/28.99  tff(decl_23629, type, female_reproductive_cycle_events_1: $i > $o).
% 28.89/28.99  tff(decl_23630, type, chimera_1: $i > $o).
% 28.89/28.99  tff(decl_23631, type, 'Chimera': $i).
% 28.89/28.99  tff(decl_23632, type, 'An organism (usually an animal) with a mix of genetially different cells from different origins.': $i).
% 28.89/28.99  tff(decl_23633, type, chimera: $i).
% 28.89/28.99  tff(decl_23634, type, chimera_plant_1: $i > $o).
% 28.89/28.99  tff(decl_23635, type, 'Chimera-Plant': $i).
% 28.89/28.99  tff(decl_23636, type, 'Plants with a mixture of genetically different cells.': $i).
% 28.89/28.99  tff(decl_23637, type, 'plant of chimera': $i).
% 28.89/28.99  tff(decl_23638, type, 'chimera plant': $i).
% 28.89/28.99  tff(decl_23639, type, 'chimera-plant': $i).
% 28.89/28.99  tff(decl_23640, type, 'Chimpanzee': $i).
% 28.89/28.99  tff(decl_23641, type, 'One of two species of extant apes in the genus Pan.  Scientific name is Pan troglodytes.': $i).
% 28.89/28.99  tff(decl_23642, type, chimpanzee: $i).
% 28.89/28.99  tff(decl_23643, type, fn_chimpanzee_1: $i > $i).
% 28.89/28.99  tff(decl_23644, type, non_motile_cilium_1: $i > $o).
% 28.89/28.99  tff(decl_23645, type, fn_chimpanzee_2: $i > $i).
% 28.89/28.99  tff(decl_23646, type, fn_vertebrate_cell_5: $i > $i).
% 28.89/28.99  tff(decl_23647, type, eukaryotic_chromosome_0: $i).
% 28.89/28.99  tff(decl_23648, type, fn_mammal_75: $i > $i).
% 28.89/28.99  tff(decl_23649, type, 'Chitin': $i).
% 28.89/28.99  tff(decl_23650, type, 'Chitin is a long-chain polymer of a N-acetylglucosamine, a derivative of glucose, and is found in many places throughout the natural world.': $i).
% 28.89/28.99  tff(decl_23651, type, chitin: $i).
% 28.89/28.99  tff(decl_23652, type, fn_chitin_3: $i > $i).
% 28.89/28.99  tff(decl_23653, type, fn_chitin_4: $i > $i).
% 28.89/28.99  tff(decl_23654, type, fn_chitin_5: $i > $i).
% 28.89/28.99  tff(decl_23655, type, fn_chitin_7: $i > $i).
% 28.89/28.99  tff(decl_23656, type, fn_chitin_8: $i > $i).
% 28.89/28.99  tff(decl_23657, type, fn_chitin_13: $i > $i).
% 28.89/28.99  tff(decl_23658, type, fn_chitin_14: $i > $i).
% 28.89/28.99  tff(decl_23659, type, fn_chitin_15: $i > $i).
% 28.89/28.99  tff(decl_23660, type, fn_chitin_16: $i > $i).
% 28.89/28.99  tff(decl_23661, type, fn_chitin_17: $i > $i).
% 28.89/28.99  tff(decl_23662, type, fn_chitin_18: $i > $i).
% 28.89/28.99  tff(decl_23663, type, fn_chitin_19: $i > $i).
% 28.89/28.99  tff(decl_23664, type, fn_chitin_20: $i > $i).
% 28.89/28.99  tff(decl_23665, type, fn_chitin_21: $i > $i).
% 28.89/28.99  tff(decl_23666, type, fn_chitin_22: $i > $i).
% 28.89/28.99  tff(decl_23667, type, fn_chitin_23: $i > $i).
% 28.89/28.99  tff(decl_23668, type, fn_chitin_24: $i > $i).
% 28.89/28.99  tff(decl_23669, type, fn_chitin_25: $i > $i).
% 28.89/28.99  tff(decl_23670, type, fn_chitin_26: $i > $i).
% 28.89/28.99  tff(decl_23671, type, fn_chitin_27: $i > $i).
% 28.89/28.99  tff(decl_23672, type, fn_chitin_28: $i > $i).
% 28.89/28.99  tff(decl_23673, type, fn_chitin_29: $i > $i).
% 28.89/28.99  tff(decl_23674, type, fn_chitin_30: $i > $i).
% 28.89/28.99  tff(decl_23675, type, fn_chitin_31: $i > $i).
% 28.89/28.99  tff(decl_23676, type, fn_chitin_32: $i > $i).
% 28.89/28.99  tff(decl_23677, type, fn_chitin_33: $i > $i).
% 28.89/28.99  tff(decl_23678, type, fn_chitin_34: $i > $i).
% 28.89/28.99  tff(decl_23679, type, fn_chitin_35: $i > $i).
% 28.89/28.99  tff(decl_23680, type, fn_chitin_36: $i > $i).
% 28.89/28.99  tff(decl_23681, type, fn_chitin_37: $i > $i).
% 28.89/28.99  tff(decl_23682, type, fn_chitin_38: $i > $i).
% 28.89/28.99  tff(decl_23683, type, fn_chitin_39: $i > $i).
% 28.89/28.99  tff(decl_23684, type, fn_chitin_40: $i > $i).
% 28.89/28.99  tff(decl_23685, type, fn_chitin_41: $i > $i).
% 28.89/28.99  tff(decl_23686, type, fn_chitin_42: $i > $i).
% 28.89/28.99  tff(decl_23687, type, fn_chitin_12: $i > $i).
% 28.89/28.99  tff(decl_23688, type, fn_chitin_11: $i > $i).
% 28.89/28.99  tff(decl_23689, type, fn_chitin_10: $i > $i).
% 28.89/28.99  tff(decl_23690, type, fn_chitin_9: $i > $i).
% 28.89/28.99  tff(decl_23691, type, fn_polysaccharide_9: $i > $i).
% 28.89/28.99  tff(decl_23692, type, fn_chitin_43: $i > $i).
% 28.89/28.99  tff(decl_23693, type, fn_chitin_6: $i > $i).
% 28.89/28.99  tff(decl_23694, type, fn_chitin_44: $i > $i).
% 28.89/28.99  tff(decl_23695, type, 'Chiton': $i).
% 28.89/28.99  tff(decl_23696, type, 'Member of the molluscan class Polyplacophora, characterized by a dorso-ventrally flattened body and a shell divided into eight dorsal plates.': $i).
% 28.89/28.99  tff(decl_23697, type, chiton: $i).
% 28.89/28.99  tff(decl_23698, type, chlamydia_1: $i > $o).
% 28.89/28.99  tff(decl_23699, type, 'Chlamydia': $i).
% 28.89/28.99  tff(decl_23700, type, 'Parasitic gram negative bacteria that has to live inside animals to access resources.': $i).
% 28.89/28.99  tff(decl_23701, type, chlamydia: $i).
% 28.89/28.99  tff(decl_23702, type, chloride_ion_substance_1: $i > $o).
% 28.89/28.99  tff(decl_23703, type, 'Chloride-Ion-Substance': $i).
% 28.89/28.99  tff(decl_23704, type, 'Substance consisting of chlorine ions.': $i).
% 28.89/28.99  tff(decl_23705, type, 'chloride ion substance': $i).
% 28.89/28.99  tff(decl_23706, type, 'chloride-ion-substance': $i).
% 28.89/28.99  tff(decl_23707, type, fn_chloride_ion_substance_1: $i > $i).
% 28.89/28.99  tff(decl_23708, type, chlorine_1: $i > $o).
% 28.89/28.99  tff(decl_23709, type, 'Chlorine': $i).
% 28.89/28.99  tff(decl_23710, type, 'Chlorine is a non metal atom with atomic number 17. It is represented by the symbol Cl.': $i).
% 28.89/28.99  tff(decl_23711, type, 'Cl': $i).
% 28.89/28.99  tff(decl_23712, type, chlorine: $i).
% 28.89/28.99  tff(decl_23713, type, iodine_1: $i > $o).
% 28.89/28.99  tff(decl_23714, type, fn_chlorine_1: $i > $i).
% 28.89/28.99  tff(decl_23715, type, fn_chlorine_2: $i > $i).
% 28.89/28.99  tff(decl_23716, type, fn_chlorine_3: $i > $i).
% 28.89/28.99  tff(decl_23717, type, fn_chlorine_8: $i > $i).
% 28.89/28.99  tff(decl_23718, type, fn_chlorine_9: $i > $i).
% 28.89/28.99  tff(decl_23719, type, fn_chlorine_10: $i > $i).
% 28.89/28.99  tff(decl_23720, type, fn_chlorine_11: $i > $i).
% 28.89/28.99  tff(decl_23721, type, fn_chlorine_12: $i > $i).
% 28.89/28.99  tff(decl_23722, type, fn_cl_minus_4: $i > $i).
% 28.89/28.99  tff(decl_23723, type, "17": $i).
% 28.89/28.99  tff(decl_23724, type, "3.16": $i).
% 28.89/28.99  tff(decl_23725, type, "35.45": $i).
% 28.89/28.99  tff(decl_23726, type, fn_chlorine_13: $i > $i).
% 28.89/28.99  tff(decl_23727, type, fn_chlorine_7: $i > $i).
% 28.89/28.99  tff(decl_23728, type, fn_chlorine_6: $i > $i).
% 28.89/28.99  tff(decl_23729, type, chloroflexus_1: $i > $o).
% 28.89/28.99  tff(decl_23730, type, 'Chloroflexus': $i).
% 28.89/28.99  tff(decl_23731, type, 'A member of the photosynthetic green non-sulfur bacteria, found in hot springs.': $i).
% 28.89/28.99  tff(decl_23732, type, chloroflexus: $i).
% 28.89/28.99  tff(decl_23733, type, fn_chloroflexus_1: $i > $i).
% 28.89/28.99  tff(decl_23734, type, fn_chloroflexus_2: $i > $i).
% 28.89/28.99  tff(decl_23735, type, fn_chloroflexus_3: $i > $i).
% 28.89/28.99  tff(decl_23736, type, fn_chloroflexus_4: $i > $i).
% 28.89/28.99  tff(decl_23737, type, fn_chloroflexus_5: $i > $i).
% 28.89/28.99  tff(decl_23738, type, fn_chloroflexus_6: $i > $i).
% 28.89/28.99  tff(decl_23739, type, fn_chloroflexus_7: $i > $i).
% 28.89/28.99  tff(decl_23740, type, fn_chloroflexus_8: $i > $i).
% 28.89/28.99  tff(decl_23741, type, fn_chloroflexus_9: $i > $i).
% 28.89/28.99  tff(decl_23742, type, fn_chloroflexus_10: $i > $i).
% 28.89/28.99  tff(decl_23743, type, fn_chloroflexus_11: $i > $i).
% 28.89/28.99  tff(decl_23744, type, fn_chloroflexus_12: $i > $i).
% 28.89/28.99  tff(decl_23745, type, fn_chloroflexus_13: $i > $i).
% 28.89/28.99  tff(decl_23746, type, fn_chloroflexus_14: $i > $i).
% 28.89/28.99  tff(decl_23747, type, fn_chloroflexus_15: $i > $i).
% 28.89/28.99  tff(decl_23748, type, fn_chloroflexus_16: $i > $i).
% 28.89/28.99  tff(decl_23749, type, fn_chloroflexus_17: $i > $i).
% 28.89/28.99  tff(decl_23750, type, fn_chloroflexus_18: $i > $i).
% 28.89/28.99  tff(decl_23751, type, fn_chloroflexus_19: $i > $i).
% 28.89/28.99  tff(decl_23752, type, fn_chloroflexus_20: $i > $i).
% 28.89/28.99  tff(decl_23753, type, fn_chloroflexus_21: $i > $i).
% 28.89/28.99  tff(decl_23754, type, chloroform_1: $i > $o).
% 28.89/28.99  tff(decl_23755, type, 'Chloroform': $i).
% 28.89/28.99  tff(decl_23756, type, 'Chloroform is an organic compound with formula CHCl3.': $i).
% 28.89/28.99  tff(decl_23757, type, chcl3: $i).
% 28.89/28.99  tff(decl_23758, type, chloroform: $i).
% 28.89/28.99  tff(decl_23759, type, nonpolar_substance_1: $i > $o).
% 28.89/28.99  tff(decl_23760, type, fn_chloroform_1: $i > $i).
% 28.89/28.99  tff(decl_23761, type, solvent_1: $i > $o).
% 28.89/28.99  tff(decl_23762, type, fn_solvent_1: $i > $i).
% 28.89/28.99  tff(decl_23763, type, 'Chlorophyll': $i).
% 28.89/28.99  tff(decl_23764, type, 'A group of green pigments found in chloroplast of photosynthetic organisms; there are four naturally occurring forms.': $i).
% 28.89/28.99  tff(decl_23765, type, 'green pigment': $i).
% 28.89/28.99  tff(decl_23766, type, 'green-pigment': $i).
% 28.89/28.99  tff(decl_23767, type, 'photosynthetic pigment': $i).
% 28.89/28.99  tff(decl_23768, type, 'photosynthetic-pigment': $i).
% 28.89/28.99  tff(decl_23769, type, 'chlorophyll molecule': $i).
% 28.89/28.99  tff(decl_23770, type, chlorophyll: $i).
% 28.89/28.99  tff(decl_23771, type, photosynthetic_pigment_1: $i > $o).
% 28.89/28.99  tff(decl_23772, type, fn_chlorophyll_2: $i > $i).
% 28.89/28.99  tff(decl_23773, type, fn_chlorophyll_3: $i > $i).
% 28.89/28.99  tff(decl_23774, type, fn_chlorophyll_4: $i > $i).
% 28.89/28.99  tff(decl_23775, type, fn_chlorophyll_5: $i > $i).
% 28.89/28.99  tff(decl_23776, type, fn_chlorophyll_6: $i > $i).
% 28.89/28.99  tff(decl_23777, type, fn_chlorophyll_7: $i > $i).
% 28.89/28.99  tff(decl_23778, type, fn_chlorophyll_8: $i > $i).
% 28.89/28.99  tff(decl_23779, type, violet_blue_light_1: $i > $o).
% 28.89/28.99  tff(decl_23780, type, fn_chlorophyll_9: $i > $i).
% 28.89/28.99  tff(decl_23781, type, fn_chlorophyll_10: $i > $i).
% 28.89/28.99  tff(decl_23782, type, fn_chlorophyll_11: $i > $i).
% 28.89/28.99  tff(decl_23783, type, fn_red_light_10: $i > $i).
% 28.89/28.99  tff(decl_23784, type, fn_porphyrin_5: $i > $i).
% 28.89/28.99  tff(decl_23785, type, 'Chlorophyll-A': $i).
% 28.89/28.99  tff(decl_23786, type, 'Chlorophyll a is a specific form of chlorophyll used in oxygenic photosynthesis.': $i).
% 28.89/28.99  tff(decl_23787, type, 'chlorophyll a': $i).
% 28.89/28.99  tff(decl_23788, type, 'chlorophyll-a': $i).
% 28.89/28.99  tff(decl_23789, type, chlorophyll_b_1: $i > $o).
% 28.89/28.99  tff(decl_23790, type, fn_chlorophyll_a_1: $i > $i).
% 28.89/28.99  tff(decl_23791, type, fn_chlorophyll_a_2: $i > $i).
% 28.89/28.99  tff(decl_23792, type, fn_chlorophyll_a_3: $i > $i).
% 28.89/28.99  tff(decl_23793, type, fn_chlorophyll_a_5: $i > $i).
% 28.89/28.99  tff(decl_23794, type, fn_chlorophyll_a_6: $i > $i).
% 28.89/28.99  tff(decl_23795, type, fn_chlorophyll_a_7: $i > $i).
% 28.89/28.99  tff(decl_23796, type, fn_chlorophyll_a_10: $i > $i).
% 28.89/28.99  tff(decl_23797, type, fn_chlorophyll_a_11: $i > $i).
% 28.89/28.99  tff(decl_23798, type, fn_chlorophyll_a_12: $i > $i).
% 28.89/28.99  tff(decl_23799, type, fn_chlorophyll_a_13: $i > $i).
% 28.89/28.99  tff(decl_23800, type, fn_chlorophyll_a_14: $i > $i).
% 28.89/28.99  tff(decl_23801, type, fn_chlorophyll_a_15: $i > $i).
% 28.89/28.99  tff(decl_23802, type, fn_chlorophyll_a_16: $i > $i).
% 28.89/28.99  tff(decl_23803, type, fn_chlorophyll_a_17: $i > $i).
% 28.89/28.99  tff(decl_23804, type, fn_chlorophyll_a_18: $i > $i).
% 28.89/28.99  tff(decl_23805, type, fn_chlorophyll_a_19: $i > $i).
% 28.89/28.99  tff(decl_23806, type, fn_chlorophyll_a_20: $i > $i).
% 28.89/28.99  tff(decl_23807, type, fn_chlorophyll_a_21: $i > $i).
% 28.89/28.99  tff(decl_23808, type, fn_chlorophyll_a_22: $i > $i).
% 28.89/28.99  tff(decl_23809, type, fn_chlorophyll_a_23: $i > $i).
% 28.89/28.99  tff(decl_23810, type, fn_chlorophyll_a_24: $i > $i).
% 28.89/28.99  tff(decl_23811, type, fn_chlorophyll_a_25: $i > $i).
% 28.89/28.99  tff(decl_23812, type, fn_chlorophyll_a_26: $i > $i).
% 28.89/28.99  tff(decl_23813, type, fn_chlorophyll_a_27: $i > $i).
% 28.89/28.99  tff(decl_23814, type, fn_chlorophyll_a_28: $i > $i).
% 28.89/28.99  tff(decl_23815, type, fn_chlorophyll_a_29: $i > $i).
% 28.89/28.99  tff(decl_23816, type, fn_chlorophyll_a_30: $i > $i).
% 28.89/28.99  tff(decl_23817, type, fn_chlorophyll_a_31: $i > $i).
% 28.89/28.99  tff(decl_23818, type, fn_chlorophyll_a_32: $i > $i).
% 28.89/28.99  tff(decl_23819, type, fn_chlorophyll_a_33: $i > $i).
% 28.89/28.99  tff(decl_23820, type, fn_chlorophyll_a_34: $i > $i).
% 28.89/28.99  tff(decl_23821, type, fn_chlorophyll_a_35: $i > $i).
% 28.89/28.99  tff(decl_23822, type, fn_chlorophyll_a_36: $i > $i).
% 28.89/28.99  tff(decl_23823, type, fn_chlorophyll_a_37: $i > $i).
% 28.89/28.99  tff(decl_23824, type, fn_chlorophyll_a_38: $i > $i).
% 28.89/28.99  tff(decl_23825, type, fn_chlorophyll_a_39: $i > $i).
% 28.89/28.99  tff(decl_23826, type, fn_chlorophyll_a_42: $i > $i).
% 28.89/28.99  tff(decl_23827, type, fn_chlorophyll_a_43: $i > $i).
% 28.89/28.99  tff(decl_23828, type, fn_hydrogen_7: $i > $i).
% 28.89/28.99  tff(decl_23829, type, fn_methyl_group_20: $i > $i).
% 28.89/28.99  tff(decl_23830, type, fn_methyl_group_12: $i > $i).
% 28.89/28.99  tff(decl_23831, type, fn_methyl_group_11: $i > $i).
% 28.89/28.99  tff(decl_23832, type, fn_chlorophyll_a_40: $i > $i).
% 28.89/28.99  tff(decl_23833, type, fn_hydrocarbon_molecule_6: $i > $i).
% 28.89/28.99  tff(decl_23834, type, fn_chlorophyll_a_41: $i > $i).
% 28.89/28.99  tff(decl_23835, type, fn_hydrocarbon_molecule_5: $i > $i).
% 28.89/28.99  tff(decl_23836, type, fn_hydrocarbon_molecule_30: $i > $i).
% 28.89/28.99  tff(decl_23837, type, fn_hydrocarbon_molecule_27: $i > $i).
% 28.89/28.99  tff(decl_23838, type, fn_hydrocarbon_molecule_28: $i > $i).
% 28.89/28.99  tff(decl_23839, type, fn_hydrocarbon_molecule_29: $i > $i).
% 28.89/28.99  tff(decl_23840, type, fn_hydrocarbon_molecule_25: $i > $i).
% 28.89/28.99  tff(decl_23841, type, fn_hydrocarbon_molecule_20: $i > $i).
% 28.89/28.99  tff(decl_23842, type, fn_hydrocarbon_molecule_17: $i > $i).
% 28.89/28.99  tff(decl_23843, type, fn_hydrocarbon_molecule_11: $i > $i).
% 28.89/28.99  tff(decl_23844, type, fn_hydrocarbon_molecule_8: $i > $i).
% 28.89/28.99  tff(decl_23845, type, fn_hydrocarbon_molecule_22: $i > $i).
% 28.89/28.99  tff(decl_23846, type, fn_hydrocarbon_molecule_21: $i > $i).
% 28.89/28.99  tff(decl_23847, type, fn_hydrocarbon_molecule_14: $i > $i).
% 28.89/28.99  tff(decl_23848, type, fn_hydrocarbon_molecule_16: $i > $i).
% 28.89/28.99  tff(decl_23849, type, fn_hydrocarbon_molecule_15: $i > $i).
% 28.89/28.99  tff(decl_23850, type, fn_chlorophyll_a_4: $i > $i).
% 28.89/28.99  tff(decl_23851, type, fn_chlorophyll_1: $i > $i).
% 28.89/28.99  tff(decl_23852, type, fn_chlorophyll_a_8: $i > $i).
% 28.89/28.99  tff(decl_23853, type, fn_chlorophyll_a_9: $i > $i).
% 28.89/28.99  tff(decl_23854, type, 'Chlorophyll-B': $i).
% 28.89/28.99  tff(decl_23855, type, 'Chlorophyll b is a form of chlorophyll. Chlorophyll b helps in photosynthesis by absorbing light energy and it is more soluble than chlorophyll a because of its carbonyl group. Its color is green.': $i).
% 28.89/28.99  tff(decl_23856, type, 'b of chlorophyll': $i).
% 28.89/28.99  tff(decl_23857, type, 'chlorophyll b': $i).
% 28.89/28.99  tff(decl_23858, type, 'chlorophyll-b': $i).
% 28.89/28.99  tff(decl_23859, type, fn_chlorophyll_b_1: $i > $i).
% 28.89/28.99  tff(decl_23860, type, fn_chlorophyll_b_2: $i > $i).
% 28.89/28.99  tff(decl_23861, type, fn_chlorophyll_b_3: $i > $i).
% 28.89/28.99  tff(decl_23862, type, fn_chlorophyll_b_4: $i > $i).
% 28.89/28.99  tff(decl_23863, type, fn_chlorophyll_b_6: $i > $i).
% 28.89/28.99  tff(decl_23864, type, fn_chlorophyll_b_7: $i > $i).
% 28.89/28.99  tff(decl_23865, type, fn_chlorophyll_b_10: $i > $i).
% 28.89/28.99  tff(decl_23866, type, fn_chlorophyll_b_11: $i > $i).
% 28.89/28.99  tff(decl_23867, type, fn_chlorophyll_b_12: $i > $i).
% 28.89/28.99  tff(decl_23868, type, fn_chlorophyll_b_13: $i > $i).
% 28.89/28.99  tff(decl_23869, type, fn_chlorophyll_b_14: $i > $i).
% 28.89/28.99  tff(decl_23870, type, fn_chlorophyll_b_19: $i > $i).
% 28.89/28.99  tff(decl_23871, type, fn_chlorophyll_b_20: $i > $i).
% 28.89/28.99  tff(decl_23872, type, fn_chlorophyll_b_21: $i > $i).
% 28.89/28.99  tff(decl_23873, type, fn_chlorophyll_b_22: $i > $i).
% 28.89/28.99  tff(decl_23874, type, fn_chlorophyll_b_23: $i > $i).
% 28.89/28.99  tff(decl_23875, type, fn_chlorophyll_b_24: $i > $i).
% 28.89/28.99  tff(decl_23876, type, fn_chlorophyll_b_25: $i > $i).
% 28.89/28.99  tff(decl_23877, type, fn_chlorophyll_b_26: $i > $i).
% 28.89/28.99  tff(decl_23878, type, fn_chlorophyll_b_27: $i > $i).
% 28.89/28.99  tff(decl_23879, type, fn_chlorophyll_b_28: $i > $i).
% 28.89/28.99  tff(decl_23880, type, fn_chlorophyll_b_29: $i > $i).
% 28.89/28.99  tff(decl_23881, type, fn_chlorophyll_b_30: $i > $i).
% 28.89/28.99  tff(decl_23882, type, fn_chlorophyll_b_31: $i > $i).
% 28.89/28.99  tff(decl_23883, type, fn_chlorophyll_b_32: $i > $i).
% 28.89/28.99  tff(decl_23884, type, fn_chlorophyll_b_33: $i > $i).
% 28.89/28.99  tff(decl_23885, type, fn_chlorophyll_b_34: $i > $i).
% 28.89/28.99  tff(decl_23886, type, fn_chlorophyll_b_35: $i > $i).
% 28.89/28.99  tff(decl_23887, type, fn_chlorophyll_b_36: $i > $i).
% 28.89/28.99  tff(decl_23888, type, fn_chlorophyll_b_37: $i > $i).
% 28.89/28.99  tff(decl_23889, type, fn_chlorophyll_b_38: $i > $i).
% 28.89/28.99  tff(decl_23890, type, fn_chlorophyll_b_39: $i > $i).
% 28.89/28.99  tff(decl_23891, type, fn_chlorophyll_b_40: $i > $i).
% 28.89/28.99  tff(decl_23892, type, fn_chlorophyll_b_41: $i > $i).
% 28.89/28.99  tff(decl_23893, type, fn_chlorophyll_b_42: $i > $i).
% 28.89/28.99  tff(decl_23894, type, fn_chlorophyll_b_43: $i > $i).
% 28.89/28.99  tff(decl_23895, type, fn_chlorophyll_b_44: $i > $i).
% 28.89/28.99  tff(decl_23896, type, fn_chlorophyll_b_45: $i > $i).
% 28.89/28.99  tff(decl_23897, type, fn_chlorophyll_b_46: $i > $i).
% 28.89/28.99  tff(decl_23898, type, fn_chlorophyll_b_47: $i > $i).
% 28.89/28.99  tff(decl_23899, type, fn_chlorophyll_b_48: $i > $i).
% 28.89/28.99  tff(decl_23900, type, fn_chlorophyll_b_49: $i > $i).
% 28.89/28.99  tff(decl_23901, type, fn_chlorophyll_b_50: $i > $i).
% 28.89/28.99  tff(decl_23902, type, fn_chlorophyll_b_51: $i > $i).
% 28.89/28.99  tff(decl_23903, type, fn_chlorophyll_b_52: $i > $i).
% 28.89/28.99  tff(decl_23904, type, fn_porphyrin_6: $i > $i).
% 28.89/28.99  tff(decl_23905, type, fn_porphyrin_7: $i > $i).
% 28.89/28.99  tff(decl_23906, type, fn_chlorophyll_b_18: $i > $i).
% 28.89/28.99  tff(decl_23907, type, fn_hydrocarbon_molecule_18: $i > $i).
% 28.89/28.99  tff(decl_23908, type, fn_chlorophyll_b_17: $i > $i).
% 28.89/28.99  tff(decl_23909, type, fn_hydrocarbon_molecule_24: $i > $i).
% 28.89/28.99  tff(decl_23910, type, fn_hydrocarbon_molecule_19: $i > $i).
% 28.89/28.99  tff(decl_23911, type, fn_hydrocarbon_molecule_23: $i > $i).
% 28.89/28.99  tff(decl_23912, type, fn_chlorophyll_b_5: $i > $i).
% 28.89/28.99  tff(decl_23913, type, fn_chlorophyll_b_16: $i > $i).
% 28.89/28.99  tff(decl_23914, type, fn_chlorophyll_b_15: $i > $i).
% 28.89/28.99  tff(decl_23915, type, fn_chlorophyll_b_8: $i > $i).
% 28.89/28.99  tff(decl_23916, type, fn_chlorophyll_b_9: $i > $i).
% 28.89/28.99  tff(decl_23917, type, 'Chlorophyta': $i).
% 28.89/28.99  tff(decl_23918, type, 'A division of green algae; includes about 7000 species of mostly aquatic photosynthetic eukaryotic organisms.': $i).
% 28.89/28.99  tff(decl_23919, type, 'green alga': $i).
% 28.89/28.99  tff(decl_23920, type, 'green-alga': $i).
% 28.89/28.99  tff(decl_23921, type, 'green algae': $i).
% 28.89/28.99  tff(decl_23922, type, 'green-algae': $i).
% 28.89/28.99  tff(decl_23923, type, chlorophyta: $i).
% 28.89/28.99  tff(decl_23924, type, 'Chloroplast': $i).
% 28.89/28.99  tff(decl_23925, type, 'A membrane-bound organelle found in eukaryotic photosynthetic organisms such as plants and protists, that absorb energy from sunlight and uses it to fix CO2 into organic molecules.': $i).
% 28.89/28.99  tff(decl_23926, type, chloroplast: $i).
% 28.89/28.99  tff(decl_23927, type, fn_chloroplast_3: $i > $i).
% 28.89/28.99  tff(decl_23928, type, fn_chloroplast_5: $i > $i).
% 28.89/28.99  tff(decl_23929, type, fn_chloroplast_6: $i > $i).
% 28.89/28.99  tff(decl_23930, type, fn_chloroplast_8: $i > $i).
% 28.89/28.99  tff(decl_23931, type, fn_chloroplast_9: $i > $i).
% 28.89/28.99  tff(decl_23932, type, fn_chloroplast_10: $i > $i).
% 28.89/28.99  tff(decl_23933, type, fn_chloroplast_12: $i > $i).
% 28.89/28.99  tff(decl_23934, type, fn_chloroplast_13: $i > $i).
% 28.89/28.99  tff(decl_23935, type, fn_chloroplast_16: $i > $i).
% 28.89/28.99  tff(decl_23936, type, fn_chloroplast_17: $i > $i).
% 28.89/28.99  tff(decl_23937, type, fn_chloroplast_18: $i > $i).
% 28.89/28.99  tff(decl_23938, type, fn_chloroplast_22: $i > $i).
% 28.89/28.99  tff(decl_23939, type, fn_chloroplast_23: $i > $i).
% 28.89/28.99  tff(decl_23940, type, fn_chloroplast_24: $i > $i).
% 28.89/28.99  tff(decl_23941, type, fn_chloroplast_25: $i > $i).
% 28.89/28.99  tff(decl_23942, type, fn_chloroplast_31: $i > $i).
% 28.89/28.99  tff(decl_23943, type, fn_chloroplast_32: $i > $i).
% 28.89/28.99  tff(decl_23944, type, fn_chloroplast_36: $i > $i).
% 28.89/28.99  tff(decl_23945, type, fn_chloroplast_37: $i > $i).
% 28.89/28.99  tff(decl_23946, type, fn_chloroplast_38: $i > $i).
% 28.89/28.99  tff(decl_23947, type, fn_chloroplast_39: $i > $i).
% 28.89/28.99  tff(decl_23948, type, fn_chloroplast_40: $i > $i).
% 28.89/28.99  tff(decl_23949, type, fn_chloroplast_41: $i > $i).
% 28.89/28.99  tff(decl_23950, type, fn_chloroplast_42: $i > $i).
% 28.89/28.99  tff(decl_23951, type, fn_chloroplast_43: $i > $i).
% 28.89/28.99  tff(decl_23952, type, fn_chloroplast_44: $i > $i).
% 28.89/28.99  tff(decl_23953, type, fn_chloroplast_45: $i > $i).
% 28.89/28.99  tff(decl_23954, type, fn_chloroplast_46: $i > $i).
% 28.89/28.99  tff(decl_23955, type, fn_chloroplast_47: $i > $i).
% 28.89/28.99  tff(decl_23956, type, fn_chloroplast_48: $i > $i).
% 28.89/28.99  tff(decl_23957, type, fn_chloroplast_49: $i > $i).
% 28.89/28.99  tff(decl_23958, type, fn_chloroplast_50: $i > $i).
% 28.89/28.99  tff(decl_23959, type, fn_chloroplast_51: $i > $i).
% 28.89/28.99  tff(decl_23960, type, fn_chloroplast_56: $i > $i).
% 28.89/28.99  tff(decl_23961, type, fn_chloroplast_57: $i > $i).
% 28.89/28.99  tff(decl_23962, type, fn_chloroplast_59: $i > $i).
% 28.89/28.99  tff(decl_23963, type, fn_chloroplast_60: $i > $i).
% 28.89/28.99  tff(decl_23964, type, fn_chloroplast_61: $i > $i).
% 28.89/28.99  tff(decl_23965, type, fn_chloroplast_69: $i > $i).
% 28.89/28.99  tff(decl_23966, type, fn_chloroplast_70: $i > $i).
% 28.89/28.99  tff(decl_23967, type, fn_chloroplast_73: $i > $i).
% 28.89/28.99  tff(decl_23968, type, fn_chloroplast_75: $i > $i).
% 28.89/28.99  tff(decl_23969, type, fn_chloroplast_85: $i > $i).
% 28.89/28.99  tff(decl_23970, type, fn_chloroplast_87: $i > $i).
% 28.89/28.99  tff(decl_23971, type, product_1: $i > $o).
% 28.89/28.99  tff(decl_23972, type, fn_chloroplast_90: $i > $i).
% 28.89/28.99  tff(decl_23973, type, fn_chloroplast_92: $i > $i).
% 28.89/28.99  tff(decl_23974, type, fn_chloroplast_93: $i > $i).
% 28.89/28.99  tff(decl_23975, type, fn_chloroplast_97: $i > $i).
% 28.89/28.99  tff(decl_23976, type, fn_chloroplast_98: $i > $i).
% 28.89/28.99  tff(decl_23977, type, fn_chloroplast_99: $i > $i).
% 28.89/28.99  tff(decl_23978, type, fn_chloroplast_100: $i > $i).
% 28.89/28.99  tff(decl_23979, type, fn_chloroplast_101: $i > $i).
% 28.89/28.99  tff(decl_23980, type, fn_chloroplast_104: $i > $i).
% 28.89/28.99  tff(decl_23981, type, fn_chloroplast_105: $i > $i).
% 28.89/28.99  tff(decl_23982, type, fn_chloroplast_106: $i > $i).
% 28.89/28.99  tff(decl_23983, type, fn_chloroplast_107: $i > $i).
% 28.89/28.99  tff(decl_23984, type, fn_chloroplast_108: $i > $i).
% 28.89/28.99  tff(decl_23985, type, fn_chloroplast_110: $i > $i).
% 28.89/28.99  tff(decl_23986, type, fn_chloroplast_111: $i > $i).
% 28.89/28.99  tff(decl_23987, type, fn_energy_transformation_by_organism_3: $i > $i).
% 28.89/28.99  tff(decl_23988, type, fn_photosystem_2: $i > $i).
% 28.89/28.99  tff(decl_23989, type, fn_porphyrin_1: $i > $i).
% 28.89/28.99  tff(decl_23990, type, fn_porphyrin_2: $i > $i).
% 28.89/28.99  tff(decl_23991, type, fn_chloroplast_membrane_39: $i > $i).
% 28.89/28.99  tff(decl_23992, type, fn_visible_light_14: $i > $i).
% 28.89/28.99  tff(decl_23993, type, fn_visible_light_17: $i > $i).
% 28.89/28.99  tff(decl_23994, type, fn_visible_light_19: $i > $i).
% 28.89/28.99  tff(decl_23995, type, fn_visible_light_15: $i > $i).
% 28.89/28.99  tff(decl_23996, type, fn_light_harvesting_complex_19: $i > $i).
% 28.89/28.99  tff(decl_23997, type, fn_thylakoid_2: $i > $i).
% 28.89/28.99  tff(decl_23998, type, fn_orange_light_8: $i > $i).
% 28.89/28.99  tff(decl_23999, type, fn_yellow_light_8: $i > $i).
% 28.89/28.99  tff(decl_24000, type, fn_product_1: $i > $i).
% 28.89/28.99  tff(decl_24001, type, fn_light_harvesting_complex_4: $i > $i).
% 28.89/28.99  tff(decl_24002, type, fn_light_harvesting_complex_14: $i > $i).
% 28.89/28.99  tff(decl_24003, type, fn_light_harvesting_complex_13: $i > $i).
% 28.89/28.99  tff(decl_24004, type, fn_light_harvesting_complex_18: $i > $i).
% 28.89/28.99  tff(decl_24005, type, fn_light_harvesting_complex_15: $i > $i).
% 28.89/28.99  tff(decl_24006, type, fn_light_harvesting_complex_16: $i > $i).
% 28.89/28.99  tff(decl_24007, type, fn_light_harvesting_complex_17: $i > $i).
% 28.89/28.99  tff(decl_24008, type, fn_violet_light_1: $i > $i).
% 28.89/28.99  tff(decl_24009, type, fn_red_light_1: $i > $i).
% 28.89/28.99  tff(decl_24010, type, fn_orange_light_1: $i > $i).
% 28.89/28.99  tff(decl_24011, type, fn_yellow_light_1: $i > $i).
% 28.89/28.99  tff(decl_24012, type, fn_light_harvesting_complex_5: $i > $i).
% 28.89/28.99  tff(decl_24013, type, fn_light_harvesting_complex_20: $i > $i).
% 28.89/28.99  tff(decl_24014, type, fn_thylakoid_3: $i > $i).
% 28.89/28.99  tff(decl_24015, type, fn_thylakoid_5: $i > $i).
% 28.89/28.99  tff(decl_24016, type, fn_chloroplast_membrane_27: $i > $i).
% 28.89/28.99  tff(decl_24017, type, fn_thylakoid_4: $i > $i).
% 28.89/28.99  tff(decl_24018, type, fn_chloroplast_membrane_30: $i > $i).
% 28.89/28.99  tff(decl_24019, type, fn_chloroplast_membrane_40: $i > $i).
% 28.89/28.99  tff(decl_24020, type, fn_thylakoid_1: $i > $i).
% 28.89/28.99  tff(decl_24021, type, "2.0": $i).
% 28.89/28.99  tff(decl_24022, type, fn_chloroplast_109: $i > $i).
% 28.89/28.99  tff(decl_24023, type, fn_chloroplast_29: $i > $i).
% 28.89/28.99  tff(decl_24024, type, fn_chloroplast_28: $i > $i).
% 28.89/28.99  tff(decl_24025, type, chloroplast_dna_1: $i > $o).
% 28.89/28.99  tff(decl_24026, type, 'Chloroplast-DNA': $i).
% 28.89/28.99  tff(decl_24027, type, 'It is the DNA molecule present in a Chloroplast. It encodes for the protein and makes Chloroplast semiautonomous by providing for it to reproduce itself.': $i).
% 28.89/28.99  tff(decl_24028, type, 'dna of chloroplast': $i).
% 28.89/28.99  tff(decl_24029, type, 'chloroplast dna': $i).
% 28.89/28.99  tff(decl_24030, type, 'chloroplast-dna': $i).
% 28.89/28.99  tff(decl_24031, type, chloroplast_gene_1: $i > $o).
% 28.89/28.99  tff(decl_24032, type, 'Chloroplast-Gene': $i).
% 28.89/28.99  tff(decl_24033, type, 'Autonomously replicating DNA within the chloroplast containing genes for proteins synthesized for the chloroplast.': $i).
% 28.89/28.99  tff(decl_24034, type, 'gene of chloroplast': $i).
% 28.89/28.99  tff(decl_24035, type, 'chloroplast gene': $i).
% 28.89/28.99  tff(decl_24036, type, 'chloroplast-gene': $i).
% 28.89/28.99  tff(decl_24037, type, extranuclear_gene_1: $i > $o).
% 28.89/28.99  tff(decl_24038, type, mitochondrial_gene_1: $i > $o).
% 28.89/28.99  tff(decl_24039, type, 'Chloroplast-Membrane': $i).
% 28.89/28.99  tff(decl_24040, type, 'Chloroplast-Membrane is the membrane which covers the chloroplast. It is composed of two membranes, the inner-membrane and the outer-membrane.': $i).
% 28.89/28.99  tff(decl_24041, type, 'membrane of chloroplast': $i).
% 28.89/28.99  tff(decl_24042, type, 'chloroplast membrane': $i).
% 28.89/28.99  tff(decl_24043, type, 'chloroplast-membrane': $i).
% 28.89/28.99  tff(decl_24044, type, fn_chloroplast_membrane_2: $i > $i).
% 28.89/28.99  tff(decl_24045, type, fn_chloroplast_membrane_3: $i > $i).
% 28.89/28.99  tff(decl_24046, type, fn_chloroplast_membrane_8: $i > $i).
% 28.89/28.99  tff(decl_24047, type, fn_chloroplast_membrane_9: $i > $i).
% 28.89/28.99  tff(decl_24048, type, fn_chloroplast_membrane_10: $i > $i).
% 28.89/28.99  tff(decl_24049, type, fn_chloroplast_membrane_11: $i > $i).
% 28.89/28.99  tff(decl_24050, type, fn_chloroplast_membrane_12: $i > $i).
% 28.89/28.99  tff(decl_24051, type, fn_chloroplast_membrane_13: $i > $i).
% 28.89/28.99  tff(decl_24052, type, fn_chloroplast_membrane_14: $i > $i).
% 28.89/28.99  tff(decl_24053, type, fn_chloroplast_membrane_15: $i > $i).
% 28.89/28.99  tff(decl_24054, type, fn_chloroplast_membrane_16: $i > $i).
% 28.89/28.99  tff(decl_24055, type, fn_chloroplast_membrane_17: $i > $i).
% 28.89/28.99  tff(decl_24056, type, fn_chloroplast_membrane_18: $i > $i).
% 28.89/28.99  tff(decl_24057, type, fn_chloroplast_membrane_19: $i > $i).
% 28.89/28.99  tff(decl_24058, type, fn_chloroplast_membrane_20: $i > $i).
% 28.89/28.99  tff(decl_24059, type, fn_chloroplast_membrane_21: $i > $i).
% 28.89/28.99  tff(decl_24060, type, fn_chloroplast_membrane_22: $i > $i).
% 28.89/28.99  tff(decl_24061, type, fn_chloroplast_membrane_23: $i > $i).
% 28.89/28.99  tff(decl_24062, type, fn_chloroplast_membrane_24: $i > $i).
% 28.89/28.99  tff(decl_24063, type, fn_chloroplast_membrane_25: $i > $i).
% 28.89/28.99  tff(decl_24064, type, fn_chloroplast_membrane_26: $i > $i).
% 28.89/28.99  tff(decl_24065, type, fn_chloroplast_membrane_28: $i > $i).
% 28.89/28.99  tff(decl_24066, type, fn_chloroplast_membrane_29: $i > $i).
% 28.89/28.99  tff(decl_24067, type, fn_chloroplast_membrane_31: $i > $i).
% 28.89/28.99  tff(decl_24068, type, fn_chloroplast_membrane_32: $i > $i).
% 28.89/28.99  tff(decl_24069, type, fn_chloroplast_membrane_33: $i > $i).
% 28.89/28.99  tff(decl_24070, type, fn_chloroplast_membrane_34: $i > $i).
% 28.89/28.99  tff(decl_24071, type, fn_chloroplast_membrane_35: $i > $i).
% 28.89/28.99  tff(decl_24072, type, fn_chloroplast_membrane_36: $i > $i).
% 28.89/28.99  tff(decl_24073, type, fn_chloroplast_membrane_37: $i > $i).
% 28.89/28.99  tff(decl_24074, type, fn_chloroplast_membrane_38: $i > $i).
% 28.89/28.99  tff(decl_24075, type, fn_chloroplast_membrane_41: $i > $i).
% 28.89/28.99  tff(decl_24076, type, fn_chloroplast_membrane_42: $i > $i).
% 28.89/28.99  tff(decl_24077, type, fn_chloroplast_membrane_43: $i > $i).
% 28.89/28.99  tff(decl_24078, type, fn_chloroplast_membrane_44: $i > $i).
% 28.89/28.99  tff(decl_24079, type, fn_chloroplast_membrane_45: $i > $i).
% 28.89/28.99  tff(decl_24080, type, fn_chloroplast_membrane_46: $i > $i).
% 28.89/28.99  tff(decl_24081, type, fn_chloroplast_membrane_47: $i > $i).
% 28.89/28.99  tff(decl_24082, type, fn_chloroplast_membrane_48: $i > $i).
% 28.89/28.99  tff(decl_24083, type, fn_restrain_1: $i > $i).
% 28.89/28.99  tff(decl_24084, type, fn_confine_3: $i > $i).
% 28.89/28.99  tff(decl_24085, type, fn_plastid_1: $i > $i).
% 28.89/28.99  tff(decl_24086, type, fn_plastid_3: $i > $i).
% 28.89/28.99  tff(decl_24087, type, fn_glycolipid_3: $i > $i).
% 28.89/28.99  tff(decl_24088, type, fn_chloroplast_membrane_7: $i > $i).
% 28.89/28.99  tff(decl_24089, type, fn_biomembrane_39: $i > $i).
% 28.89/28.99  tff(decl_24090, type, fn_chloroplast_membrane_6: $i > $i).
% 28.89/28.99  tff(decl_24091, type, fn_biomembrane_3: $i > $i).
% 28.89/28.99  tff(decl_24092, type, fn_chloroplast_membrane_5: $i > $i).
% 28.89/28.99  tff(decl_24093, type, fn_biomembrane_19: $i > $i).
% 28.89/28.99  tff(decl_24094, type, fn_chloroplast_membrane_4: $i > $i).
% 28.89/28.99  tff(decl_24095, type, fn_biomembrane_26: $i > $i).
% 28.89/28.99  tff(decl_24096, type, chlostridium_botulinum_1: $i > $o).
% 28.89/28.99  tff(decl_24097, type, 'Chlostridium-Botulinum': $i).
% 28.89/28.99  tff(decl_24098, type, 'Endospore forming rod shaped bacterium which is reposbible for botulism infection. It is an obligate anaerobe which produces a powerful toxin.': $i).
% 28.89/28.99  tff(decl_24099, type, 'chlostridium botulinum': $i).
% 28.89/28.99  tff(decl_24100, type, 'chlostridium-botulinum': $i).
% 28.89/28.99  tff(decl_24101, type, fn_chlostridium_botulinum_1: $i > $i).
% 28.89/28.99  tff(decl_24102, type, fn_chlostridium_botulinum_2: $i > $i).
% 28.89/28.99  tff(decl_24103, type, fn_chlostridium_botulinum_3: $i > $i).
% 28.89/28.99  tff(decl_24104, type, fn_chlostridium_botulinum_4: $i > $i).
% 28.89/28.99  tff(decl_24105, type, fn_chlostridium_botulinum_5: $i > $i).
% 28.89/28.99  tff(decl_24106, type, fn_chlostridium_botulinum_6: $i > $i).
% 28.89/28.99  tff(decl_24107, type, fn_chlostridium_botulinum_7: $i > $i).
% 28.89/28.99  tff(decl_24108, type, fn_chlostridium_botulinum_8: $i > $i).
% 28.89/28.99  tff(decl_24109, type, fn_chlostridium_botulinum_9: $i > $i).
% 28.89/28.99  tff(decl_24110, type, fn_chlostridium_botulinum_10: $i > $i).
% 28.89/28.99  tff(decl_24111, type, fn_chlostridium_botulinum_11: $i > $i).
% 28.89/28.99  tff(decl_24112, type, fn_chlostridium_botulinum_12: $i > $i).
% 28.89/28.99  tff(decl_24113, type, fn_chlostridium_botulinum_13: $i > $i).
% 28.89/28.99  tff(decl_24114, type, fn_chlostridium_botulinum_14: $i > $i).
% 28.89/28.99  tff(decl_24115, type, fn_chlostridium_botulinum_15: $i > $i).
% 28.89/28.99  tff(decl_24116, type, fn_chlostridium_botulinum_17: $i > $i).
% 28.89/28.99  tff(decl_24117, type, fn_chlostridium_botulinum_16: $i > $i).
% 28.89/28.99  tff(decl_24118, type, fn_chlostridium_botulinum_19: $i > $i).
% 28.89/28.99  tff(decl_24119, type, fn_chlostridium_botulinum_18: $i > $i).
% 28.89/28.99  tff(decl_24120, type, choanocyte_1: $i > $o).
% 28.89/28.99  tff(decl_24121, type, 'Choanocyte': $i).
% 28.89/28.99  tff(decl_24122, type, 'A flagellated cell that lines the internal cavity of sponges and creates the feeding current. Also called collar cells.': $i).
% 28.89/28.99  tff(decl_24123, type, choanocyte: $i).
% 28.89/28.99  tff(decl_24124, type, invertebrate_cell_1: $i > $o).
% 28.89/28.99  tff(decl_24125, type, fn_choanocyte_1: $i > $i).
% 28.89/28.99  tff(decl_24126, type, fn_choanocyte_2: $i > $i).
% 28.89/28.99  tff(decl_24127, type, fn_choanocyte_3: $i > $i).
% 28.89/28.99  tff(decl_24128, type, fn_choanocyte_4: $i > $i).
% 28.89/28.99  tff(decl_24129, type, fn_choanocyte_5: $i > $i).
% 28.89/28.99  tff(decl_24130, type, fn_choanocyte_6: $i > $i).
% 28.89/28.99  tff(decl_24131, type, fn_choanocyte_7: $i > $i).
% 28.89/28.99  tff(decl_24132, type, fn_choanocyte_8: $i > $i).
% 28.89/28.99  tff(decl_24133, type, fn_choanocyte_9: $i > $i).
% 28.89/28.99  tff(decl_24134, type, fn_choanocyte_12: $i > $i).
% 28.89/28.99  tff(decl_24135, type, fn_choanocyte_13: $i > $i).
% 28.89/28.99  tff(decl_24136, type, fn_choanocyte_14: $i > $i).
% 28.89/28.99  tff(decl_24137, type, fn_choanocyte_15: $i > $i).
% 28.89/28.99  tff(decl_24138, type, fn_choanocyte_16: $i > $i).
% 28.89/28.99  tff(decl_24139, type, fn_choanocyte_17: $i > $i).
% 28.89/28.99  tff(decl_24140, type, fn_choanocyte_18: $i > $i).
% 28.89/28.99  tff(decl_24141, type, fn_choanocyte_19: $i > $i).
% 28.89/28.99  tff(decl_24142, type, fn_choanocyte_20: $i > $i).
% 28.89/28.99  tff(decl_24143, type, fn_choanocyte_21: $i > $i).
% 28.89/28.99  tff(decl_24144, type, fn_choanocyte_22: $i > $i).
% 28.89/28.99  tff(decl_24145, type, fn_choanocyte_23: $i > $i).
% 28.89/28.99  tff(decl_24146, type, fn_choanocyte_24: $i > $i).
% 28.89/28.99  tff(decl_24147, type, fn_choanocyte_25: $i > $i).
% 28.89/28.99  tff(decl_24148, type, fn_choanocyte_26: $i > $i).
% 28.89/28.99  tff(decl_24149, type, fn_choanocyte_27: $i > $i).
% 28.89/28.99  tff(decl_24150, type, fn_choanocyte_28: $i > $i).
% 28.89/28.99  tff(decl_24151, type, fn_choanocyte_29: $i > $i).
% 28.89/28.99  tff(decl_24152, type, flagellum_1: $i > $o).
% 28.89/28.99  tff(decl_24153, type, fn_choanocyte_30: $i > $i).
% 28.89/28.99  tff(decl_24154, type, fn_choanocyte_31: $i > $i).
% 28.89/28.99  tff(decl_24155, type, fn_choanocyte_32: $i > $i).
% 28.89/28.99  tff(decl_24156, type, fn_choanocyte_33: $i > $i).
% 28.89/28.99  tff(decl_24157, type, fn_choanocyte_34: $i > $i).
% 28.89/28.99  tff(decl_24158, type, fn_choanocyte_35: $i > $i).
% 28.89/28.99  tff(decl_24159, type, fn_choanocyte_36: $i > $i).
% 28.89/28.99  tff(decl_24160, type, fn_choanocyte_37: $i > $i).
% 28.89/28.99  tff(decl_24161, type, fn_choanocyte_38: $i > $i).
% 28.89/28.99  tff(decl_24162, type, fn_choanocyte_39: $i > $i).
% 28.89/28.99  tff(decl_24163, type, fn_choanocyte_40: $i > $i).
% 28.89/28.99  tff(decl_24164, type, fn_choanocyte_41: $i > $i).
% 28.89/28.99  tff(decl_24165, type, fn_choanocyte_42: $i > $i).
% 28.89/28.99  tff(decl_24166, type, fn_choanocyte_43: $i > $i).
% 28.89/28.99  tff(decl_24167, type, fn_choanocyte_44: $i > $i).
% 28.89/28.99  tff(decl_24168, type, fn_choanocyte_45: $i > $i).
% 28.89/28.99  tff(decl_24169, type, fn_choanocyte_46: $i > $i).
% 28.89/28.99  tff(decl_24170, type, fn_choanocyte_47: $i > $i).
% 28.89/28.99  tff(decl_24171, type, fn_phagocytosis_98: $i > $i).
% 28.89/28.99  tff(decl_24172, type, fn_phagocytosis_97: $i > $i).
% 28.89/28.99  tff(decl_24173, type, fn_phagocytosis_91: $i > $i).
% 28.89/28.99  tff(decl_24174, type, fn_phagocytosis_92: $i > $i).
% 28.89/28.99  tff(decl_24175, type, fn_phagocytosis_94: $i > $i).
% 28.89/28.99  tff(decl_24176, type, fn_phagocytosis_49: $i > $i).
% 28.89/28.99  tff(decl_24177, type, fn_phagocytosis_7: $i > $i).
% 28.89/28.99  tff(decl_24178, type, fn_flagellum_35: $i > $i).
% 28.89/28.99  tff(decl_24179, type, fn_phagocytosis_8: $i > $i).
% 28.89/28.99  tff(decl_24180, type, fn_eukaryotic_cell_53: $i > $i).
% 28.89/28.99  tff(decl_24181, type, fn_eukaryotic_cell_9: $i > $i).
% 28.89/28.99  tff(decl_24182, type, fn_eukaryotic_cell_10: $i > $i).
% 28.89/28.99  tff(decl_24183, type, fn_choanocyte_11: $i > $i).
% 28.89/28.99  tff(decl_24184, type, fn_choanocyte_10: $i > $i).
% 28.89/28.99  tff(decl_24185, type, 'Cholecystokinin': $i).
% 28.89/28.99  tff(decl_24186, type, 'A digestive hormone (enterogastrome) that causes the gall bladder to contract and secrete bile into the duodenum.': $i).
% 28.89/28.99  tff(decl_24187, type, cholecystokinin: $i).
% 28.89/28.99  tff(decl_24188, type, digestive_peptide_hormone_1: $i > $o).
% 28.89/28.99  tff(decl_24189, type, fn_cholecystokinin_1: $i > $i).
% 28.89/28.99  tff(decl_24190, type, 'Cholera': $i).
% 28.89/28.99  tff(decl_24191, type, 'An infectious disease of the small intestine caused by the bacterium Vibrio cholerae. Main symptoms are watery diarrhea and vomiting.': $i).
% 28.89/28.99  tff(decl_24192, type, cholera: $i).
% 28.89/28.99  tff(decl_24193, type, cholera_process_1: $i > $o).
% 28.89/28.99  tff(decl_24194, type, 'Cholera-Process': $i).
% 28.89/28.99  tff(decl_24195, type, 'Process related to the progression of cholera.': $i).
% 28.89/28.99  tff(decl_24196, type, 'cause disease': $i).
% 28.89/28.99  tff(decl_24197, type, 'process of cholera': $i).
% 28.89/28.99  tff(decl_24198, type, 'cholera process': $i).
% 28.89/28.99  tff(decl_24199, type, 'cholera-process': $i).
% 28.89/28.99  tff(decl_24200, type, fn_cholera_process_2: $i > $i).
% 28.89/28.99  tff(decl_24201, type, fn_cholera_process_3: $i > $i).
% 28.89/28.99  tff(decl_24202, type, fn_cholera_process_5: $i > $i).
% 28.89/28.99  tff(decl_24203, type, fn_cholera_process_6: $i > $i).
% 28.89/28.99  tff(decl_24204, type, fn_cholera_process_7: $i > $i).
% 28.89/28.99  tff(decl_24205, type, vibrio_cholerae_1: $i > $o).
% 28.89/28.99  tff(decl_24206, type, fn_cholera_process_8: $i > $i).
% 28.89/28.99  tff(decl_24207, type, fn_cholera_process_9: $i > $i).
% 28.89/28.99  tff(decl_24208, type, fn_cholera_process_10: $i > $i).
% 28.89/28.99  tff(decl_24209, type, fn_cholera_process_11: $i > $i).
% 28.89/28.99  tff(decl_24210, type, fn_cholera_process_12: $i > $i).
% 28.89/28.99  tff(decl_24211, type, fn_cholera_process_13: $i > $i).
% 28.89/28.99  tff(decl_24212, type, fn_cholera_process_14: $i > $i).
% 28.89/28.99  tff(decl_24213, type, cholera_toxin_1: $i > $o).
% 28.89/28.99  tff(decl_24214, type, fn_cholera_process_15: $i > $i).
% 28.89/28.99  tff(decl_24215, type, fn_cholera_process_16: $i > $i).
% 28.89/28.99  tff(decl_24216, type, fn_cholera_process_17: $i > $i).
% 28.89/28.99  tff(decl_24217, type, fn_cholera_process_18: $i > $i).
% 28.89/28.99  tff(decl_24218, type, fn_cholera_process_19: $i > $i).
% 28.89/28.99  tff(decl_24219, type, fn_cholera_process_20: $i > $i).
% 28.89/28.99  tff(decl_24220, type, fn_cholera_process_21: $i > $i).
% 28.89/28.99  tff(decl_24221, type, fn_cholera_process_22: $i > $i).
% 28.89/28.99  tff(decl_24222, type, fn_cholera_process_23: $i > $i).
% 28.89/28.99  tff(decl_24223, type, fn_cholera_process_24: $i > $i).
% 28.89/28.99  tff(decl_24224, type, fn_cholera_process_25: $i > $i).
% 28.89/28.99  tff(decl_24225, type, fn_person_15: $i > $i).
% 28.89/28.99  tff(decl_24226, type, fn_small_intestine_32: $i > $i).
% 28.89/28.99  tff(decl_24227, type, fn_small_intestine_22: $i > $i).
% 28.89/28.99  tff(decl_24228, type, fn_osmosis_22: $i > $i).
% 28.89/28.99  tff(decl_24229, type, amp_0: $i).
% 28.89/28.99  tff(decl_24230, type, 'Cholera-Toxin': $i).
% 28.89/28.99  tff(decl_24231, type, 'Toxin produced by the bacteria Vibrio cholerae which results in the symptoms of the cholera.': $i).
% 28.89/28.99  tff(decl_24232, type, 'toxin of cholera': $i).
% 28.89/28.99  tff(decl_24233, type, 'cholera toxin': $i).
% 28.89/28.99  tff(decl_24234, type, 'cholera-toxin': $i).
% 28.89/28.99  tff(decl_24235, type, cholesterol_1: $i > $o).
% 28.89/28.99  tff(decl_24236, type, 'Cholesterol': $i).
% 28.89/28.99  tff(decl_24237, type, 'Cholesterol is a waxy steroid metabolite found in the cell membranes and transported in the blood plasma of all animals': $i).
% 28.89/28.99  tff(decl_24238, type, cholesterol: $i).
% 28.89/28.99  tff(decl_24239, type, fn_cholesterol_1: $i > $i).
% 28.89/28.99  tff(decl_24240, type, fn_cholesterol_3: $i > $i).
% 28.89/28.99  tff(decl_24241, type, fn_cholesterol_4: $i > $i).
% 28.89/28.99  tff(decl_24242, type, fn_cholesterol_5: $i > $i).
% 28.89/28.99  tff(decl_24243, type, cyclopentane_1: $i > $o).
% 28.89/28.99  tff(decl_24244, type, fn_cholesterol_6: $i > $i).
% 28.89/28.99  tff(decl_24245, type, fn_cholesterol_7: $i > $i).
% 28.89/28.99  tff(decl_24246, type, fn_cholesterol_8: $i > $i).
% 28.89/28.99  tff(decl_24247, type, fn_steroid_15: $i > $i).
% 28.89/28.99  tff(decl_24248, type, fn_steroid_9: $i > $i).
% 28.89/28.99  tff(decl_24249, type, fn_steroid_10: $i > $i).
% 28.89/28.99  tff(decl_24250, type, fn_steroid_11: $i > $i).
% 28.89/28.99  tff(decl_24251, type, fn_steroid_13: $i > $i).
% 28.89/28.99  tff(decl_24252, type, choline_1: $i > $o).
% 28.89/28.99  tff(decl_24253, type, 'Choline': $i).
% 28.89/28.99  tff(decl_24254, type, 'B-complex vitamin that is the precursor to the neurotransmitter acetylcholine.': $i).
% 28.89/28.99  tff(decl_24255, type, choline: $i).
% 28.89/28.99  tff(decl_24256, type, vitamin_b_1: $i > $o).
% 28.89/28.99  tff(decl_24257, type, chondrocyte_1: $i > $o).
% 28.89/28.99  tff(decl_24258, type, 'Chondrocyte': $i).
% 28.89/28.99  tff(decl_24259, type, 'Cells in cartilage that secrete chondroitin.': $i).
% 28.89/28.99  tff(decl_24260, type, chondrocyte: $i).
% 28.89/28.99  tff(decl_24261, type, fn_chondrocyte_1: $i > $i).
% 28.89/28.99  tff(decl_24262, type, fn_chondrocyte_2: $i > $i).
% 28.89/28.99  tff(decl_24263, type, fn_chondrocyte_3: $i > $i).
% 28.89/28.99  tff(decl_24264, type, 'Choose-At-Random': $i).
% 28.89/28.99  tff(decl_24265, type, 'Choose at random refers to selection with  no specific pattern.': $i).
% 28.89/28.99  tff(decl_24266, type, 'choose at random': $i).
% 28.89/28.99  tff(decl_24267, type, 'choose-at-random': $i).
% 28.89/28.99  tff(decl_24268, type, select_1: $i > $o).
% 28.89/28.99  tff(decl_24269, type, 'Chordate': $i).
% 28.89/28.99  tff(decl_24270, type, 'A member of the phylum Chordata, a group of invertebrate and vertebrate animals that have, at some point in their development, all of the following features:  a notochord, pharyngeal gill slits, a post-anal tail, and a dorsal hollow nerve cord.': $i).
% 28.89/28.99  tff(decl_24271, type, chordate: $i).
% 28.89/28.99  tff(decl_24272, type, 'Chorion': $i).
% 28.89/28.99  tff(decl_24273, type, 'The outermost of four extraembryonic membranes. It functions in gas exchange and contributes to the formation of the mammalian placenta.': $i).
% 28.89/28.99  tff(decl_24274, type, chorion: $i).
% 28.89/28.99  tff(decl_24275, type, 'Chorionic-Villus-Sampling': $i).
% 28.89/28.99  tff(decl_24276, type, 'A technique of prenatal diagnosis in which a small sample of the fetal portion of the placenta is removed and analyzed to detect certain genetic and congenital defects in the fetus.': $i).
% 28.89/28.99  tff(decl_24277, type, cvs: $i).
% 28.89/28.99  tff(decl_24278, type, 'chorionic villus sampling': $i).
% 28.89/28.99  tff(decl_24279, type, 'chorionic-villus-sampling': $i).
% 28.89/28.99  tff(decl_24280, type, fn_chorionic_villus_sampling_1: $i > $i).
% 28.89/28.99  tff(decl_24281, type, suction_tube_1: $i > $o).
% 28.89/28.99  tff(decl_24282, type, fn_chorionic_villus_sampling_2: $i > $i).
% 28.89/28.99  tff(decl_24283, type, fn_chorionic_villus_sampling_3: $i > $i).
% 28.89/28.99  tff(decl_24284, type, fn_chorionic_villus_sampling_4: $i > $i).
% 28.89/28.99  tff(decl_24285, type, fn_chorionic_villus_sampling_5: $i > $i).
% 28.89/28.99  tff(decl_24286, type, 'Choroid': $i).
% 28.89/28.99  tff(decl_24287, type, 'The vascular layer of the vertebrate eye, lying between the retina and the sclera.': $i).
% 28.89/28.99  tff(decl_24288, type, choroid: $i).
% 28.89/28.99  tff(decl_24289, type, chromalveolata_1: $i > $o).
% 28.89/28.99  tff(decl_24290, type, 'Chromalveolata': $i).
% 28.89/28.99  tff(decl_24291, type, 'One of five supergroups of eukaryotes proposed in a current hypothesis of the evolutionary history of eukaryotes. Chromalveolates may have originated by secondary endosymbiosis and include two large protist clades, the alveolates and the stramenopiles. See also Excavata, Rhizaria, Archaeplastida, and Unikonta.': $i).
% 28.89/28.99  tff(decl_24292, type, chromalveolata: $i).
% 28.89/28.99  tff(decl_24293, type, chromalveolate_1: $i > $o).
% 28.89/28.99  tff(decl_24294, type, 'Chromalveolate': $i).
% 28.89/28.99  tff(decl_24295, type, 'An array of diverse eukaryotic organisms grouped together as a clade in one hypothesis of evolutionary relationships among eukaryotes. Two large protistan groups, the stramenopiles and alveolates, are considered chromalveolates under this hypothesis. Recent studies indicate that the chromalveolates are not a monophyletic group as originally hypothesized.': $i).
% 28.89/28.99  tff(decl_24296, type, chromalveolate: $i).
% 28.89/28.99  tff(decl_24297, type, chromatid_1: $i > $o).
% 28.89/28.99  tff(decl_24298, type, 'Chromatid': $i).
% 28.89/28.99  tff(decl_24299, type, 'Half of a diploid chromosome when  the chromosome is in its most dense (and visible) state. When a chromatid is attached to another chromatid at the centromere, they are collectively called sister chromatids.': $i).
% 28.89/28.99  tff(decl_24300, type, 'sister chromatids': $i).
% 28.89/28.99  tff(decl_24301, type, chromosome: $i).
% 28.89/28.99  tff(decl_24302, type, 'sister chromatid': $i).
% 28.89/28.99  tff(decl_24303, type, chromatid: $i).
% 28.89/28.99  tff(decl_24304, type, fn_chromatid_2: $i > $i).
% 28.89/28.99  tff(decl_24305, type, fn_chromatid_3: $i > $i).
% 28.89/28.99  tff(decl_24306, type, fn_chromatid_4: $i > $i).
% 28.89/28.99  tff(decl_24307, type, fn_chromatid_7: $i > $i).
% 28.89/28.99  tff(decl_24308, type, fn_chromatid_8: $i > $i).
% 28.89/28.99  tff(decl_24309, type, dna_0: $i).
% 28.89/28.99  tff(decl_24310, type, dna_double_helix_0: $i).
% 28.89/28.99  tff(decl_24311, type, chromatin_packing_1: $i > $o).
% 28.89/28.99  tff(decl_24312, type, 'Chromatin-Packing': $i).
% 28.89/28.99  tff(decl_24313, type, 'The means for packing DNA into chromatin.': $i).
% 28.89/28.99  tff(decl_24314, type, 'chromatin fiber formation': $i).
% 28.89/28.99  tff(decl_24315, type, 'chromatin fiber packing': $i).
% 28.89/28.99  tff(decl_24316, type, 'packing of chromatin': $i).
% 28.89/28.99  tff(decl_24317, type, 'chromatin packing': $i).
% 28.89/28.99  tff(decl_24318, type, 'chromatin-packing': $i).
% 28.89/28.99  tff(decl_24319, type, fn_chromatin_packing_1: $i > $i).
% 28.89/28.99  tff(decl_24320, type, h1_1: $i > $o).
% 28.89/28.99  tff(decl_24321, type, fn_chromatin_packing_2: $i > $i).
% 28.89/28.99  tff(decl_24322, type, fn_chromatin_packing_3: $i > $i).
% 28.89/28.99  tff(decl_24323, type, looped_domains_1: $i > $o).
% 28.89/28.99  tff(decl_24324, type, fn_chromatin_packing_4: $i > $i).
% 28.89/28.99  tff(decl_24325, type, eukaryotic_chromatin_1: $i > $o).
% 28.89/28.99  tff(decl_24326, type, heterochromatin_1: $i > $o).
% 28.89/28.99  tff(decl_24327, type, fn_chromatin_packing_5: $i > $i).
% 28.89/28.99  tff(decl_24328, type, fn_chromatin_packing_6: $i > $i).
% 28.89/28.99  tff(decl_24329, type, nucleosome_1: $i > $o).
% 28.89/28.99  tff(decl_24330, type, fn_chromatin_packing_7: $i > $i).
% 28.89/28.99  tff(decl_24331, type, fn_chromatin_packing_8: $i > $i).
% 28.89/28.99  tff(decl_24332, type, fn_chromatin_packing_9: $i > $i).
% 28.89/28.99  tff(decl_24333, type, fn_chromatin_packing_10: $i > $i).
% 28.89/28.99  tff(decl_24334, type, fn_chromatin_packing_11: $i > $i).
% 28.89/28.99  tff(decl_24335, type, euchromatin_1: $i > $o).
% 28.89/28.99  tff(decl_24336, type, fn_chromatin_packing_12: $i > $i).
% 28.89/28.99  tff(decl_24337, type, fn_looped_domains_5: $i > $i).
% 28.89/28.99  tff(decl_24338, type, fn_looped_domains_11: $i > $i).
% 28.89/28.99  tff(decl_24339, type, fn_looped_domains_10: $i > $i).
% 28.89/28.99  tff(decl_24340, type, fn_looped_domains_9: $i > $i).
% 28.89/28.99  tff(decl_24341, type, fn_looped_domains_1: $i > $i).
% 28.89/28.99  tff(decl_24342, type, fn_nucleosome_4: $i > $i).
% 28.89/28.99  tff(decl_24343, type, fn_nucleosome_3: $i > $i).
% 28.89/28.99  tff(decl_24344, type, chromium_1: $i > $o).
% 28.89/28.99  tff(decl_24345, type, 'Chromium': $i).
% 28.89/28.99  tff(decl_24346, type, 'Chromium is a metal atom with atomic number 24. It is represented by the symbol Cr.': $i).
% 28.89/28.99  tff(decl_24347, type, chromium: $i).
% 28.89/28.99  tff(decl_24348, type, 'Cr': $i).
% 28.89/28.99  tff(decl_24349, type, fn_chromium_3: $i > $i).
% 28.89/28.99  tff(decl_24350, type, fn_chromium_4: $i > $i).
% 28.89/28.99  tff(decl_24351, type, fn_chromium_5: $i > $i).
% 28.89/28.99  tff(decl_24352, type, fn_chromium_9: $i > $i).
% 28.89/28.99  tff(decl_24353, type, fn_chromium_10: $i > $i).
% 28.89/28.99  tff(decl_24354, type, fn_chromium_11: $i > $i).
% 28.89/28.99  tff(decl_24355, type, fn_chromium_12: $i > $i).
% 28.89/28.99  tff(decl_24356, type, "28": $i).
% 28.89/28.99  tff(decl_24357, type, "24": $i).
% 28.89/28.99  tff(decl_24358, type, "1.66": $i).
% 28.89/28.99  tff(decl_24359, type, "52": $i).
% 28.89/28.99  tff(decl_24360, type, fn_chromium_7: $i > $i).
% 28.89/28.99  tff(decl_24361, type, fn_chromium_8: $i > $i).
% 28.89/28.99  tff(decl_24362, type, fn_chromium_6: $i > $i).
% 28.89/28.99  tff(decl_24363, type, 'Chromoplast': $i).
% 28.89/28.99  tff(decl_24364, type, 'Chromoplasts are plastids having pigments that give colour to fruits and flowers.': $i).
% 28.89/28.99  tff(decl_24365, type, chromoplast: $i).
% 28.89/28.99  tff(decl_24366, type, 'Chromosomal-Arrangement': $i).
% 28.89/28.99  tff(decl_24367, type, 'A particular way chromosomes are arranged.': $i).
% 28.89/28.99  tff(decl_24368, type, 'chromosomal arrangement': $i).
% 28.89/28.99  tff(decl_24369, type, 'chromosomal-arrangement': $i).
% 28.89/28.99  tff(decl_24370, type, chromosomal_disorder_1: $i > $o).
% 28.89/28.99  tff(decl_24371, type, 'Chromosomal-Disorder': $i).
% 28.89/28.99  tff(decl_24372, type, 'A genetic disorder resulting from changes in chromosome number or large changes in chromosome structure.': $i).
% 28.89/28.99  tff(decl_24373, type, 'chromosome anomaly': $i).
% 28.89/28.99  tff(decl_24374, type, 'chromosome-anomaly': $i).
% 28.89/28.99  tff(decl_24375, type, 'chromosome aberration': $i).
% 28.89/28.99  tff(decl_24376, type, 'chromosome-aberration': $i).
% 28.89/28.99  tff(decl_24377, type, 'chromosomal disorder': $i).
% 28.89/28.99  tff(decl_24378, type, 'chromosomal-disorder': $i).
% 28.89/28.99  tff(decl_24379, type, 'Chromosomal-Disorder-Cell': $i).
% 28.89/28.99  tff(decl_24380, type, 'A cell with an inappropriate number of chromosomes for its species.': $i).
% 28.89/28.99  tff(decl_24381, type, 'cell showing chromosome disorder': $i).
% 28.89/28.99  tff(decl_24382, type, 'cell-showing-chromosome-disorder': $i).
% 28.89/28.99  tff(decl_24383, type, 'cell with aneuploidy': $i).
% 28.89/28.99  tff(decl_24384, type, 'cell-with-aneuploidy': $i).
% 28.89/28.99  tff(decl_24385, type, 'chromosomal disorder cell': $i).
% 28.89/28.99  tff(decl_24386, type, 'chromosomal-disorder-cell': $i).
% 28.89/28.99  tff(decl_24387, type, 'Chromosomal-Inheritance': $i).
% 28.89/28.99  tff(decl_24388, type, 'Inheritance of an entire chromosome or large section of a chromosome.': $i).
% 28.89/28.99  tff(decl_24389, type, inherit: $i).
% 28.89/28.99  tff(decl_24390, type, 'chromosomal inheritance': $i).
% 28.89/28.99  tff(decl_24391, type, 'chromosomal-inheritance': $i).
% 28.89/28.99  tff(decl_24392, type, fn_chromosomal_inheritance_1: $i > $i).
% 28.89/28.99  tff(decl_24393, type, fn_chromosomal_inheritance_2: $i > $i).
% 28.89/28.99  tff(decl_24394, type, fn_chromosomal_inheritance_3: $i > $i).
% 28.89/28.99  tff(decl_24395, type, fn_chromosomal_inheritance_4: $i > $i).
% 28.89/28.99  tff(decl_24396, type, fn_chromosomal_inheritance_5: $i > $i).
% 28.89/28.99  tff(decl_24397, type, parent_1: $i > $o).
% 28.89/28.99  tff(decl_24398, type, fn_chromosomal_inheritance_6: $i > $i).
% 28.89/28.99  tff(decl_24399, type, fn_parent_3: $i > $i).
% 28.89/28.99  tff(decl_24400, type, fn_gene_15: $i > $i).
% 28.89/28.99  tff(decl_24401, type, fn_inheritance_3: $i > $i).
% 28.89/28.99  tff(decl_24402, type, chromosomal_translocation_1: $i > $o).
% 28.89/28.99  tff(decl_24403, type, 'Chromosomal-Translocation': $i).
% 28.89/28.99  tff(decl_24404, type, 'A translocation moves a segment from one chromosome to another, nonhomologous one.': $i).
% 28.89/28.99  tff(decl_24405, type, translocation: $i).
% 28.89/28.99  tff(decl_24406, type, translocate: $i).
% 28.89/28.99  tff(decl_24407, type, 'chromosomal translocation': $i).
% 28.89/28.99  tff(decl_24408, type, 'chromosomal-translocation': $i).
% 28.89/28.99  tff(decl_24409, type, translocation_1: $i > $o).
% 28.89/28.99  tff(decl_24410, type, deletion_of_chromosome_fragment_1: $i > $o).
% 28.89/28.99  tff(decl_24411, type, duplication_of_chromosome_fragment_1: $i > $o).
% 28.89/28.99  tff(decl_24412, type, inversion_of_chromosome_fragment_1: $i > $o).
% 28.89/28.99  tff(decl_24413, type, fn_chromosomal_translocation_1: $i > $i).
% 28.89/28.99  tff(decl_24414, type, fn_chromosomal_translocation_2: $i > $i).
% 28.89/28.99  tff(decl_24415, type, fn_chromosomal_translocation_3: $i > $i).
% 28.89/28.99  tff(decl_24416, type, fn_chromosomal_translocation_4: $i > $i).
% 28.89/28.99  tff(decl_24417, type, fn_chromosomal_translocation_5: $i > $i).
% 28.89/28.99  tff(decl_24418, type, 'Chromosome': $i).
% 28.89/28.99  tff(decl_24419, type, 'A chromosome is an organized structure of DNA and protein that is found in cells. It is a single piece of coiled DNA containing many genes, regulatory elements and other nucleotide sequences': $i).
% 28.89/28.99  tff(decl_24420, type, chromosomes: $i).
% 28.89/28.99  tff(decl_24421, type, 'chromosome pair': $i).
% 28.89/28.99  tff(decl_24422, type, 'pair of chromosomes': $i).
% 28.89/28.99  tff(decl_24423, type, chromatin: $i).
% 28.89/28.99  tff(decl_24424, type, fn_chromosome_2: $i > $i).
% 28.89/28.99  tff(decl_24425, type, fn_chromosome_7: $i > $i).
% 28.89/28.99  tff(decl_24426, type, fn_chromosome_9: $i > $i).
% 28.89/28.99  tff(decl_24427, type, deoxyribonucleoside_monophosphate_1: $i > $o).
% 28.89/28.99  tff(decl_24428, type, fn_chromosome_10: $i > $i).
% 28.89/28.99  tff(decl_24429, type, fn_chromosome_11: $i > $i).
% 28.89/28.99  tff(decl_24430, type, fn_chromosome_12: $i > $i).
% 28.89/28.99  tff(decl_24431, type, fn_chromosome_13: $i > $i).
% 28.89/28.99  tff(decl_24432, type, fn_chromosome_14: $i > $i).
% 28.89/28.99  tff(decl_24433, type, fn_coil_1: $i > $i).
% 28.89/28.99  tff(decl_24434, type, fn_dna_strand_68: $i > $i).
% 28.89/28.99  tff(decl_24435, type, fn_dna_strand_60: $i > $i).
% 28.89/28.99  tff(decl_24436, type, fn_dna_strand_66: $i > $i).
% 28.89/28.99  tff(decl_24437, type, fn_dna_strand_65: $i > $i).
% 28.89/28.99  tff(decl_24438, type, fn_dna_strand_62: $i > $i).
% 28.89/28.99  tff(decl_24439, type, fn_dna_strand_54: $i > $i).
% 28.89/28.99  tff(decl_24440, type, fn_origin_of_replication_1: $i > $i).
% 28.89/28.99  tff(decl_24441, type, fn_dna_2: $i > $i).
% 28.89/28.99  tff(decl_24442, type, fn_dna_11: $i > $i).
% 28.89/28.99  tff(decl_24443, type, centromere_0: $i).
% 28.89/28.99  tff(decl_24444, type, chromosome_21_1: $i > $o).
% 28.89/28.99  tff(decl_24445, type, 'Chromosome-21': $i).
% 28.89/28.99  tff(decl_24446, type, 'One of the 44 autosomes in the nucleus of a typical human somatic cell.': $i).
% 28.89/28.99  tff(decl_24447, type, '21 of chromosome': $i).
% 28.89/28.99  tff(decl_24448, type, 'chromosome 21': $i).
% 28.89/28.99  tff(decl_24449, type, 'chromosome-21': $i).
% 28.89/28.99  tff(decl_24450, type, chromosome_alignment_1: $i > $o).
% 28.89/28.99  tff(decl_24451, type, 'Chromosome-Alignment': $i).
% 28.89/28.99  tff(decl_24452, type, 'During mitosis and meiosis, the process in which the set of chromosomes in the cell is aligned on the metaphase plate.': $i).
% 28.89/28.99  tff(decl_24453, type, align: $i).
% 28.89/28.99  tff(decl_24454, type, 'alignment of chromosome': $i).
% 28.89/28.99  tff(decl_24455, type, 'chromosome alignment': $i).
% 28.89/28.99  tff(decl_24456, type, 'chromosome-alignment': $i).
% 28.89/28.99  tff(decl_24457, type, fn_chromosome_alignment_1: $i > $i).
% 28.89/28.99  tff(decl_24458, type, fn_chromosome_alignment_2: $i > $i).
% 28.89/28.99  tff(decl_24459, type, fn_chromosome_alignment_3: $i > $i).
% 28.89/28.99  tff(decl_24460, type, fn_chromosome_alignment_6: $i > $i).
% 28.89/28.99  tff(decl_24461, type, fn_chromosome_alignment_7: $i > $i).
% 28.89/28.99  tff(decl_24462, type, fn_chromosome_alignment_8: $i > $i).
% 28.89/28.99  tff(decl_24463, type, fn_chromosome_alignment_9: $i > $i).
% 28.89/28.99  tff(decl_24464, type, fn_chromosome_alignment_10: $i > $i).
% 28.89/28.99  tff(decl_24465, type, fn_chromosome_alignment_11: $i > $i).
% 28.89/28.99  tff(decl_24466, type, fn_chromosome_alignment_12: $i > $i).
% 28.89/28.99  tff(decl_24467, type, fn_chromosome_alignment_13: $i > $i).
% 28.89/28.99  tff(decl_24468, type, condensed_diploid_chromosome_1: $i > $o).
% 28.89/28.99  tff(decl_24469, type, fn_chromosome_alignment_14: $i > $i).
% 28.89/28.99  tff(decl_24470, type, fn_chromosome_alignment_15: $i > $i).
% 28.89/28.99  tff(decl_24471, type, fn_chromosome_alignment_16: $i > $i).
% 28.89/28.99  tff(decl_24472, type, fn_chromosome_alignment_17: $i > $i).
% 28.89/28.99  tff(decl_24473, type, fn_chromosome_alignment_18: $i > $i).
% 28.89/28.99  tff(decl_24474, type, fn_kinetochore_1: $i > $i).
% 28.89/28.99  tff(decl_24475, type, fn_kinetochore_2: $i > $i).
% 28.89/28.99  tff(decl_24476, type, fn_kinetochore_25: $i > $i).
% 28.89/28.99  tff(decl_24477, type, 'Chromosome-Arm': $i).
% 28.89/28.99  tff(decl_24478, type, 'Regions of chromosomes on either side of the centromere, used in the identification of chromosome regions and location of genes.': $i).
% 28.89/28.99  tff(decl_24479, type, 'arm of chromosome': $i).
% 28.89/28.99  tff(decl_24480, type, 'chromosome arm': $i).
% 28.89/28.99  tff(decl_24481, type, 'chromosome-arm': $i).
% 28.89/28.99  tff(decl_24482, type, 'Chromosome-Fragment': $i).
% 28.89/28.99  tff(decl_24483, type, 'A section of a chromosome that becomes separated.': $i).
% 28.89/28.99  tff(decl_24484, type, 'fragment of chromosome': $i).
% 28.89/28.99  tff(decl_24485, type, 'chromosome fragment': $i).
% 28.89/28.99  tff(decl_24486, type, 'chromosome-fragment': $i).
% 28.89/28.99  tff(decl_24487, type, recombinant_chromosome_1: $i > $o).
% 28.89/28.99  tff(decl_24488, type, 'Chromosome-Region': $i).
% 28.89/28.99  tff(decl_24489, type, 'A region of a chromosome or DNA molecule.': $i).
% 28.89/28.99  tff(decl_24490, type, 'region of chromosome': $i).
% 28.89/28.99  tff(decl_24491, type, 'chromosome region': $i).
% 28.89/28.99  tff(decl_24492, type, 'chromosome-region': $i).
% 28.89/28.99  tff(decl_24493, type, chromosome_theory_1: $i > $o).
% 28.89/28.99  tff(decl_24494, type, 'Chromosome-Theory': $i).
% 28.89/28.99  tff(decl_24495, type, 'According to the chromosome theory of inheritance, Mendelian genes have specific loci on chromosomes, and it is the chromosomes that undergo segregation and independent assortment.': $i).
% 28.89/28.99  tff(decl_24496, type, 'chromosomal theory of inheritance': $i).
% 28.89/28.99  tff(decl_24497, type, 'chromosome theory of inheritance': $i).
% 28.89/28.99  tff(decl_24498, type, 'theory of chromosome': $i).
% 28.89/28.99  tff(decl_24499, type, 'chromosome theory': $i).
% 28.89/28.99  tff(decl_24500, type, 'chromosome-theory': $i).
% 28.89/28.99  tff(decl_24501, type, fn_chromosome_theory_1: $i > $i).
% 28.89/28.99  tff(decl_24502, type, fn_chromosome_theory_2: $i > $i).
% 28.89/28.99  tff(decl_24503, type, fn_chromosome_theory_3: $i > $i).
% 28.89/28.99  tff(decl_24504, type, fn_chromosome_theory_4: $i > $i).
% 28.89/28.99  tff(decl_24505, type, chylomicron_1: $i > $o).
% 28.89/28.99  tff(decl_24506, type, 'Chylomicron': $i).
% 28.89/28.99  tff(decl_24507, type, 'A type of lipoprotein that transports dietary lipids from the intestines to other tissues of the body.': $i).
% 28.89/28.99  tff(decl_24508, type, chylomicron: $i).
% 28.89/28.99  tff(decl_24509, type, subcellular_assembly_1: $i > $o).
% 28.89/28.99  tff(decl_24510, type, thylakoid_electron_transport_chain_1: $i > $o).
% 28.89/28.99  tff(decl_24511, type, cytochrome_complex_1: $i > $o).
% 28.89/28.99  tff(decl_24512, type, electron_shuttle_system_1: $i > $o).
% 28.89/28.99  tff(decl_24513, type, electron_transport_chain_1: $i > $o).
% 28.89/28.99  tff(decl_24514, type, signal_recognition_particle_1: $i > $o).
% 28.89/28.99  tff(decl_24515, type, fn_chylomicron_2: $i > $i).
% 28.89/28.99  tff(decl_24516, type, fn_chylomicron_3: $i > $i).
% 28.89/28.99  tff(decl_24517, type, fn_chylomicron_4: $i > $i).
% 28.89/28.99  tff(decl_24518, type, fn_chylomicron_5: $i > $i).
% 28.89/28.99  tff(decl_24519, type, fn_chylomicron_6: $i > $i).
% 28.89/28.99  tff(decl_24520, type, fn_chylomicron_7: $i > $i).
% 28.89/28.99  tff(decl_24521, type, fn_chylomicron_8: $i > $i).
% 28.89/28.99  tff(decl_24522, type, subcellular_assembly_0: $i).
% 28.89/28.99  tff(decl_24523, type, fn_chylomicron_9: $i > $i).
% 28.89/28.99  tff(decl_24524, type, chymotrypsin_1: $i > $o).
% 28.89/28.99  tff(decl_24525, type, 'Chymotrypsin': $i).
% 28.89/28.99  tff(decl_24526, type, 'A digestive enzyme, found in pancreatic juice, that breaks polypeptides into shorter chains.': $i).
% 28.89/28.99  tff(decl_24527, type, chymotrypsin: $i).
% 28.89/28.99  tff(decl_24528, type, fn_chymotrypsin_1: $i > $i).
% 28.89/28.99  tff(decl_24529, type, fn_chymotrypsin_2: $i > $i).
% 28.89/28.99  tff(decl_24530, type, fn_chymotrypsin_3: $i > $i).
% 28.89/28.99  tff(decl_24531, type, fn_chymotrypsin_4: $i > $i).
% 28.89/28.99  tff(decl_24532, type, leave_1: $i > $o).
% 28.89/28.99  tff(decl_24533, type, fn_chymotrypsin_5: $i > $i).
% 28.89/28.99  tff(decl_24534, type, fn_chymotrypsin_6: $i > $i).
% 28.89/28.99  tff(decl_24535, type, fn_chymotrypsin_7: $i > $i).
% 28.89/28.99  tff(decl_24536, type, fn_chymotrypsin_8: $i > $i).
% 28.89/28.99  tff(decl_24537, type, fn_leave_1: $i > $i).
% 28.89/28.99  tff(decl_24538, type, 'Chytrid': $i).
% 28.89/28.99  tff(decl_24539, type, 'A fungus from the phylum Chytridiomycota, a group of primarly aquatic fungi with flagellated zoospores.  The chytrids are the most ancestral fungi.': $i).
% 28.89/28.99  tff(decl_24540, type, chytrid: $i).
% 28.89/28.99  tff(decl_24541, type, 'Ciliary-Body': $i).
% 28.89/28.99  tff(decl_24542, type, 'A portion of the vertebrate eye associated with the lens. It produces the clear, watery aqueous humor that fills the anterior cavity of the eye.': $i).
% 28.89/28.99  tff(decl_24543, type, 'ciliary body': $i).
% 28.89/28.99  tff(decl_24544, type, 'ciliary-body': $i).
% 28.89/28.99  tff(decl_24545, type, 'Ciliate': $i).
% 28.89/28.99  tff(decl_24546, type, 'A protozoan that locomotes by means of cilia.': $i).
% 28.89/28.99  tff(decl_24547, type, ciliate: $i).
% 28.89/28.99  tff(decl_24548, type, fn_ciliate_1: $i > $i).
% 28.89/28.99  tff(decl_24549, type, cilium_1: $i > $o).
% 28.89/28.99  tff(decl_24550, type, 'Cilium': $i).
% 28.89/28.99  tff(decl_24551, type, 'An organelle of some eukaryotic cells; a cilium extends from the body of the cell. Cilia can have locomotory or sensory functions.': $i).
% 28.89/28.99  tff(decl_24552, type, cilia: $i).
% 28.89/28.99  tff(decl_24553, type, cilium: $i).
% 28.89/28.99  tff(decl_24554, type, fn_cilium_1: $i > $i).
% 28.89/28.99  tff(decl_24555, type, fn_cilium_4: $i > $i).
% 28.89/28.99  tff(decl_24556, type, fn_cilium_5: $i > $i).
% 28.89/28.99  tff(decl_24557, type, fn_cilium_6: $i > $i).
% 28.89/28.99  tff(decl_24558, type, fn_cilium_8: $i > $i).
% 28.89/28.99  tff(decl_24559, type, fn_cilium_9: $i > $i).
% 28.89/28.99  tff(decl_24560, type, fn_cilium_10: $i > $i).
% 28.89/28.99  tff(decl_24561, type, flagellum_0: $i).
% 28.89/28.99  tff(decl_24562, type, circadian_rhythm_1: $i > $o).
% 28.89/28.99  tff(decl_24563, type, 'Circadian-Rhythm': $i).
% 28.89/28.99  tff(decl_24564, type, 'Any biological process that occurs on an endogenous rhythm of about 24 hours. Such rhythms persist even in the absence of external cues. All organisms so far studied have circadian rhythms.': $i).
% 28.89/28.99  tff(decl_24565, type, 'circadian rhythm': $i).
% 28.89/28.99  tff(decl_24566, type, 'circadian-rhythm': $i).
% 28.89/28.99  tff(decl_24567, type, circuit_1: $i > $o).
% 28.89/28.99  tff(decl_24568, type, 'Circuit': $i).
% 28.89/28.99  tff(decl_24569, type, 'A closed anatomical or physiological pathway which returns to the starting point.': $i).
% 28.89/28.99  tff(decl_24570, type, circuit: $i).
% 28.89/28.99  tff(decl_24571, type, circular_dna_1: $i > $o).
% 28.89/28.99  tff(decl_24572, type, 'Circular-DNA': $i).
% 28.89/28.99  tff(decl_24573, type, 'Circular stucture of DNA.  Found in viruses, bacteria and archaea as well as in eukaryotic cells in the form of either mitochondrial DNA or plastid DNA.': $i).
% 28.89/28.99  tff(decl_24574, type, plasmid: $i).
% 28.89/28.99  tff(decl_24575, type, 'extranuclear dna': $i).
% 28.89/28.99  tff(decl_24576, type, 'extranuclear-dna': $i).
% 28.89/28.99  tff(decl_24577, type, 'dna of circular': $i).
% 28.89/28.99  tff(decl_24578, type, 'circular dna': $i).
% 28.89/28.99  tff(decl_24579, type, 'circular-dna': $i).
% 28.89/28.99  tff(decl_24580, type, fn_circular_dna_1: $i > $i).
% 28.89/28.99  tff(decl_24581, type, 'Circulatory-Organ': $i).
% 28.89/28.99  tff(decl_24582, type, 'Organ of the animal circulatory system.': $i).
% 28.89/28.99  tff(decl_24583, type, 'circulatory organ': $i).
% 28.89/28.99  tff(decl_24584, type, 'circulatory-organ': $i).
% 28.89/28.99  tff(decl_24585, type, 'Circulatory-System': $i).
% 28.89/28.99  tff(decl_24586, type, 'An organ system linking the aqueous environment of the body cells to the organs that exchange gases, absorb nutrients and dispose of wastes.  A circulatory system ans three basic components: a circulatory fluid, a set of interconnecting vessels, and a muscular pump.': $i).
% 28.89/28.99  tff(decl_24587, type, 'circulatory system': $i).
% 28.89/28.99  tff(decl_24588, type, 'circulatory-system': $i).
% 28.89/28.99  tff(decl_24589, type, fn_circulatory_system_1: $i > $i).
% 28.89/28.99  tff(decl_24590, type, circumference_constant_1: $i > $o).
% 28.89/28.99  tff(decl_24591, type, 'Circumference-Constant': $i).
% 28.89/28.99  tff(decl_24592, type, 'constant of circumference': $i).
% 28.89/28.99  tff(decl_24593, type, 'circumference constant': $i).
% 28.89/28.99  tff(decl_24594, type, 'circumference-constant': $i).
% 28.89/28.99  tff(decl_24595, type, circumference_scale_1: $i > $o).
% 28.89/28.99  tff(decl_24596, type, 'Circumference-Scale': $i).
% 28.89/28.99  tff(decl_24597, type, 'scale of circumference': $i).
% 28.89/28.99  tff(decl_24598, type, 'circumference scale': $i).
% 28.89/28.99  tff(decl_24599, type, 'circumference-scale': $i).
% 28.89/28.99  tff(decl_24600, type, 'Cis-Face': $i).
% 28.89/28.99  tff(decl_24601, type, 'Cis face serves as receiving region of the golgi for transport vesicles.': $i).
% 28.89/28.99  tff(decl_24602, type, 'cis face': $i).
% 28.89/28.99  tff(decl_24603, type, 'cis-face': $i).
% 28.89/28.99  tff(decl_24604, type, subcellular_region_1: $i > $o).
% 28.89/28.99  tff(decl_24605, type, face_region_1: $i > $o).
% 28.89/28.99  tff(decl_24606, type, fn_cis_face_1: $i > $i).
% 28.89/28.99  tff(decl_24607, type, cisterna_1: $i > $o).
% 28.89/28.99  tff(decl_24608, type, fn_cis_face_2: $i > $i).
% 28.89/28.99  tff(decl_24609, type, fn_cis_face_3: $i > $i).
% 28.89/28.99  tff(decl_24610, type, fn_cis_face_4: $i > $i).
% 28.89/28.99  tff(decl_24611, type, fn_cis_face_5: $i > $i).
% 28.89/28.99  tff(decl_24612, type, fn_cis_face_6: $i > $i).
% 28.89/28.99  tff(decl_24613, type, fn_cis_face_7: $i > $i).
% 28.89/28.99  tff(decl_24614, type, fn_cis_face_8: $i > $i).
% 28.89/28.99  tff(decl_24615, type, fn_cis_face_9: $i > $i).
% 28.89/28.99  tff(decl_24616, type, fn_cis_face_10: $i > $i).
% 28.89/28.99  tff(decl_24617, type, fn_cis_face_11: $i > $i).
% 28.89/28.99  tff(decl_24618, type, fn_cis_face_12: $i > $i).
% 28.89/28.99  tff(decl_24619, type, fn_cis_face_13: $i > $i).
% 28.89/28.99  tff(decl_24620, type, fn_cis_face_14: $i > $i).
% 28.89/28.99  tff(decl_24621, type, fn_cis_face_15: $i > $i).
% 28.89/28.99  tff(decl_24622, type, fn_cis_face_16: $i > $i).
% 28.89/28.99  tff(decl_24623, type, fn_cis_face_19: $i > $i).
% 28.89/28.99  tff(decl_24624, type, fn_cis_face_20: $i > $i).
% 28.89/28.99  tff(decl_24625, type, fn_cis_face_21: $i > $i).
% 28.89/28.99  tff(decl_24626, type, deliver_1: $i > $o).
% 28.89/28.99  tff(decl_24627, type, fn_cis_face_22: $i > $i).
% 28.89/28.99  tff(decl_24628, type, fn_cis_face_23: $i > $i).
% 28.89/28.99  tff(decl_24629, type, fn_cis_face_24: $i > $i).
% 28.89/28.99  tff(decl_24630, type, fn_cis_face_25: $i > $i).
% 28.89/28.99  tff(decl_24631, type, fn_cis_face_26: $i > $i).
% 28.89/28.99  tff(decl_24632, type, fn_cis_face_27: $i > $i).
% 28.89/28.99  tff(decl_24633, type, fn_cis_face_28: $i > $i).
% 28.89/28.99  tff(decl_24634, type, fn_cis_face_29: $i > $i).
% 28.89/28.99  tff(decl_24635, type, fn_cis_face_30: $i > $i).
% 28.89/28.99  tff(decl_24636, type, fn_cis_face_31: $i > $i).
% 28.89/28.99  tff(decl_24637, type, fn_cis_face_32: $i > $i).
% 28.89/28.99  tff(decl_24638, type, fn_cis_face_33: $i > $i).
% 28.89/28.99  tff(decl_24639, type, fn_cis_face_34: $i > $i).
% 28.89/28.99  tff(decl_24640, type, fn_cis_face_35: $i > $i).
% 28.89/28.99  tff(decl_24641, type, fn_cis_face_36: $i > $i).
% 28.89/28.99  tff(decl_24642, type, fn_cis_face_37: $i > $i).
% 28.89/28.99  tff(decl_24643, type, fn_cis_face_38: $i > $i).
% 28.89/28.99  tff(decl_24644, type, fn_cis_face_39: $i > $i).
% 28.89/28.99  tff(decl_24645, type, fn_cis_face_40: $i > $i).
% 28.89/28.99  tff(decl_24646, type, fn_cis_face_41: $i > $i).
% 28.89/28.99  tff(decl_24647, type, fn_cis_face_42: $i > $i).
% 28.89/28.99  tff(decl_24648, type, fn_cis_face_43: $i > $i).
% 28.89/28.99  tff(decl_24649, type, fn_cis_face_44: $i > $i).
% 28.89/28.99  tff(decl_24650, type, fn_cis_face_45: $i > $i).
% 28.89/28.99  tff(decl_24651, type, fn_cis_face_46: $i > $i).
% 28.89/28.99  tff(decl_24652, type, fn_cis_face_47: $i > $i).
% 28.89/28.99  tff(decl_24653, type, fn_cis_face_48: $i > $i).
% 28.89/28.99  tff(decl_24654, type, fn_cis_face_49: $i > $i).
% 28.89/28.99  tff(decl_24655, type, fn_cis_face_50: $i > $i).
% 28.89/28.99  tff(decl_24656, type, fn_cis_face_51: $i > $i).
% 28.89/28.99  tff(decl_24657, type, fn_cis_face_52: $i > $i).
% 28.89/28.99  tff(decl_24658, type, fn_cis_face_53: $i > $i).
% 28.89/28.99  tff(decl_24659, type, fn_cis_face_54: $i > $i).
% 28.89/28.99  tff(decl_24660, type, fn_cis_face_55: $i > $i).
% 28.89/28.99  tff(decl_24661, type, fn_cis_face_56: $i > $i).
% 28.89/28.99  tff(decl_24662, type, fn_cis_face_57: $i > $i).
% 28.89/28.99  tff(decl_24663, type, fn_cis_face_58: $i > $i).
% 28.89/28.99  tff(decl_24664, type, fn_cis_face_59: $i > $i).
% 28.89/28.99  tff(decl_24665, type, fn_cis_face_60: $i > $i).
% 28.89/28.99  tff(decl_24666, type, fn_cis_face_61: $i > $i).
% 28.89/28.99  tff(decl_24667, type, fn_cis_face_62: $i > $i).
% 28.89/28.99  tff(decl_24668, type, fn_cis_face_63: $i > $i).
% 28.89/28.99  tff(decl_24669, type, fn_cis_face_64: $i > $i).
% 28.89/28.99  tff(decl_24670, type, fn_cis_face_65: $i > $i).
% 28.89/28.99  tff(decl_24671, type, fn_cis_face_66: $i > $i).
% 28.89/28.99  tff(decl_24672, type, fn_exocytosis_23: $i > $i).
% 28.89/28.99  tff(decl_24673, type, fn_exocytosis_27: $i > $i).
% 28.89/28.99  tff(decl_24674, type, fn_exocytosis_36: $i > $i).
% 28.89/28.99  tff(decl_24675, type, fn_rough_endoplasmic_reticulum_83: $i > $i).
% 28.89/28.99  tff(decl_24676, type, fn_rough_endoplasmic_reticulum_85: $i > $i).
% 28.89/28.99  tff(decl_24677, type, fn_transport_vesicle_5: $i > $i).
% 28.89/28.99  tff(decl_24678, type, fn_transport_vesicle_6: $i > $i).
% 28.89/28.99  tff(decl_24679, type, fn_transport_vesicle_1: $i > $i).
% 28.89/28.99  tff(decl_24680, type, fn_rough_endoplasmic_reticulum_84: $i > $i).
% 28.89/28.99  tff(decl_24681, type, fn_rough_endoplasmic_reticulum_51: $i > $i).
% 28.89/28.99  tff(decl_24682, type, fn_rough_endoplasmic_reticulum_47: $i > $i).
% 28.89/28.99  tff(decl_24683, type, fn_rough_endoplasmic_reticulum_39: $i > $i).
% 28.89/28.99  tff(decl_24684, type, fn_rough_endoplasmic_reticulum_76: $i > $i).
% 28.89/28.99  tff(decl_24685, type, fn_rough_endoplasmic_reticulum_58: $i > $i).
% 28.89/28.99  tff(decl_24686, type, fn_transport_vesicle_9: $i > $i).
% 28.89/28.99  tff(decl_24687, type, fn_deliver_1: $i > $i).
% 28.89/28.99  tff(decl_24688, type, fn_receive_1: $i > $i).
% 28.89/28.99  tff(decl_24689, type, fn_rough_endoplasmic_reticulum_13: $i > $i).
% 28.89/28.99  tff(decl_24690, type, fn_endoplasmic_reticulum_40: $i > $i).
% 28.89/28.99  tff(decl_24691, type, fn_transport_vesicle_4: $i > $i).
% 28.89/28.99  tff(decl_24692, type, fn_transport_vesicle_8: $i > $i).
% 28.89/28.99  tff(decl_24693, type, fn_transport_vesicle_7: $i > $i).
% 28.89/28.99  tff(decl_24694, type, fn_cis_face_18: $i > $i).
% 28.89/28.99  tff(decl_24695, type, fn_cis_face_17: $i > $i).
% 28.89/28.99  tff(decl_24696, type, 'Cisterna': $i).
% 28.89/28.99  tff(decl_24697, type, 'Cisternae are flattened membranous tubules and sacs. They are structural components of ER and Golgi': $i).
% 28.89/28.99  tff(decl_24698, type, cisterna: $i).
% 28.89/28.99  tff(decl_24699, type, 'Cisternal-Space': $i).
% 28.89/28.99  tff(decl_24700, type, 'It is the region of a cisternae or ER or Golgi which is enclosed by membrane': $i).
% 28.89/28.99  tff(decl_24701, type, 'cisternal space': $i).
% 28.89/28.99  tff(decl_24702, type, 'cisternal-space': $i).
% 28.89/28.99  tff(decl_24703, type, fn_cisternal_space_1: $i > $i).
% 28.89/28.99  tff(decl_24704, type, 'Citrate': $i).
% 28.89/28.99  tff(decl_24705, type, 'A citrate is the conjugate base of citric acid or  ester of citric acid.': $i).
% 28.89/28.99  tff(decl_24706, type, citrate: $i).
% 28.89/28.99  tff(decl_24707, type, fn_citrate_1: $i > $i).
% 28.89/28.99  tff(decl_24708, type, citric_acid_1: $i > $o).
% 28.89/28.99  tff(decl_24709, type, fn_citrate_2: $i > $i).
% 28.89/28.99  tff(decl_24710, type, fn_citrate_3: $i > $i).
% 28.89/28.99  tff(decl_24711, type, 'Citric-Acid': $i).
% 28.89/28.99  tff(decl_24712, type, 'Citric acid is an organic acid. Its conjugate base Citrate is an important intermediate in Citric acid cycle.': $i).
% 28.89/28.99  tff(decl_24713, type, 'citric acid': $i).
% 28.89/28.99  tff(decl_24714, type, 'citric-acid': $i).
% 28.89/28.99  tff(decl_24715, type, 'Citric-Acid-Cycle': $i).
% 28.89/28.99  tff(decl_24716, type, 'A series of enzyme-catalyzed chemical reactions resulting in the reduction of citrate to carbon dioxide.': $i).
% 28.89/28.99  tff(decl_24717, type, 'krebs cycle': $i).
% 28.89/28.99  tff(decl_24718, type, 'krebs-cycle': $i).
% 28.89/28.99  tff(decl_24719, type, 'tca cycle': $i).
% 28.89/28.99  tff(decl_24720, type, 'tricarboxylic acid cycle': $i).
% 28.89/28.99  tff(decl_24721, type, 'tricarboxylic-acid-cycle': $i).
% 28.89/28.99  tff(decl_24722, type, 'tca-cycle': $i).
% 28.89/28.99  tff(decl_24723, type, 'szent gyorgyi krebs cycle': $i).
% 28.89/28.99  tff(decl_24724, type, 'szent-gyorgyi-krebs-cycle': $i).
% 28.89/28.99  tff(decl_24725, type, 'undergo citric acid cycle': $i).
% 28.89/28.99  tff(decl_24726, type, 'citric acid cycle': $i).
% 28.89/28.99  tff(decl_24727, type, 'citric-acid-cycle': $i).
% 28.89/28.99  tff(decl_24728, type, fn_citric_acid_cycle_3: $i > $i).
% 28.89/28.99  tff(decl_24729, type, fn_citric_acid_cycle_4: $i > $i).
% 28.89/28.99  tff(decl_24730, type, fn_citric_acid_cycle_7: $i > $i).
% 28.89/28.99  tff(decl_24731, type, fn_citric_acid_cycle_8: $i > $i).
% 28.89/28.99  tff(decl_24732, type, fn_citric_acid_cycle_10: $i > $i).
% 28.89/28.99  tff(decl_24733, type, fn_citric_acid_cycle_11: $i > $i).
% 28.89/28.99  tff(decl_24734, type, fn_citric_acid_cycle_13: $i > $i).
% 28.89/28.99  tff(decl_24735, type, fn_citric_acid_cycle_14: $i > $i).
% 28.89/28.99  tff(decl_24736, type, fn_citric_acid_cycle_15: $i > $i).
% 28.89/28.99  tff(decl_24737, type, fn_citric_acid_cycle_16: $i > $i).
% 28.89/28.99  tff(decl_24738, type, fn_citric_acid_cycle_20: $i > $i).
% 28.89/28.99  tff(decl_24739, type, fn_citric_acid_cycle_21: $i > $i).
% 28.89/28.99  tff(decl_24740, type, fn_citric_acid_cycle_30: $i > $i).
% 28.89/28.99  tff(decl_24741, type, fn_citric_acid_cycle_31: $i > $i).
% 28.89/28.99  tff(decl_24742, type, fn_citric_acid_cycle_32: $i > $i).
% 28.89/28.99  tff(decl_24743, type, fn_citric_acid_cycle_33: $i > $i).
% 28.89/28.99  tff(decl_24744, type, fn_citric_acid_cycle_34: $i > $i).
% 28.89/28.99  tff(decl_24745, type, fn_citric_acid_cycle_35: $i > $i).
% 28.89/28.99  tff(decl_24746, type, fn_citric_acid_cycle_36: $i > $i).
% 28.89/28.99  tff(decl_24747, type, fn_citric_acid_cycle_49: $i > $i).
% 28.89/28.99  tff(decl_24748, type, fn_citric_acid_cycle_50: $i > $i).
% 28.89/28.99  tff(decl_24749, type, fn_citric_acid_cycle_51: $i > $i).
% 28.89/28.99  tff(decl_24750, type, fn_citric_acid_cycle_52: $i > $i).
% 28.89/28.99  tff(decl_24751, type, fn_citric_acid_cycle_53: $i > $i).
% 28.89/28.99  tff(decl_24752, type, fn_citric_acid_cycle_54: $i > $i).
% 28.89/28.99  tff(decl_24753, type, fn_citric_acid_cycle_55: $i > $i).
% 28.89/28.99  tff(decl_24754, type, fn_citric_acid_cycle_56: $i > $i).
% 28.89/28.99  tff(decl_24755, type, fn_citric_acid_cycle_58: $i > $i).
% 28.89/28.99  tff(decl_24756, type, fn_citric_acid_cycle_59: $i > $i).
% 28.89/28.99  tff(decl_24757, type, fn_citric_acid_cycle_60: $i > $i).
% 28.89/28.99  tff(decl_24758, type, fn_citric_acid_cycle_61: $i > $i).
% 28.89/28.99  tff(decl_24759, type, fn_citric_acid_cycle_62: $i > $i).
% 28.89/28.99  tff(decl_24760, type, fn_citric_acid_cycle_63: $i > $i).
% 28.89/28.99  tff(decl_24761, type, fn_citric_acid_cycle_64: $i > $i).
% 28.89/28.99  tff(decl_24762, type, fn_citric_acid_cycle_65: $i > $i).
% 28.89/28.99  tff(decl_24763, type, fn_citric_acid_cycle_67: $i > $i).
% 28.89/28.99  tff(decl_24764, type, fn_citric_acid_cycle_68: $i > $i).
% 28.89/28.99  tff(decl_24765, type, fn_citric_acid_cycle_69: $i > $i).
% 28.89/28.99  tff(decl_24766, type, fn_citric_acid_cycle_70: $i > $i).
% 28.89/28.99  tff(decl_24767, type, fn_citric_acid_cycle_71: $i > $i).
% 28.89/28.99  tff(decl_24768, type, fn_citric_acid_cycle_73: $i > $i).
% 28.89/28.99  tff(decl_24769, type, fn_citric_acid_cycle_74: $i > $i).
% 28.89/28.99  tff(decl_24770, type, fn_citric_acid_cycle_75: $i > $i).
% 28.89/28.99  tff(decl_24771, type, fn_citric_acid_cycle_76: $i > $i).
% 28.89/28.99  tff(decl_24772, type, fn_citric_acid_cycle_77: $i > $i).
% 28.89/28.99  tff(decl_24773, type, fn_citric_acid_cycle_78: $i > $i).
% 28.89/28.99  tff(decl_24774, type, fn_citric_acid_cycle_79: $i > $i).
% 28.89/28.99  tff(decl_24775, type, fn_citric_acid_cycle_80: $i > $i).
% 28.89/28.99  tff(decl_24776, type, fn_citric_acid_cycle_81: $i > $i).
% 28.89/28.99  tff(decl_24777, type, fn_citric_acid_cycle_82: $i > $i).
% 28.89/28.99  tff(decl_24778, type, fn_citric_acid_cycle_83: $i > $i).
% 28.89/28.99  tff(decl_24779, type, fn_citric_acid_cycle_84: $i > $i).
% 28.89/28.99  tff(decl_24780, type, fn_citric_acid_cycle_85: $i > $i).
% 28.89/28.99  tff(decl_24781, type, fn_citric_acid_cycle_86: $i > $i).
% 28.89/28.99  tff(decl_24782, type, fn_citric_acid_cycle_87: $i > $i).
% 28.89/28.99  tff(decl_24783, type, fn_citric_acid_cycle_88: $i > $i).
% 28.89/28.99  tff(decl_24784, type, fn_citric_acid_cycle_89: $i > $i).
% 28.89/28.99  tff(decl_24785, type, fn_citric_acid_cycle_90: $i > $i).
% 28.89/28.99  tff(decl_24786, type, fn_citric_acid_cycle_91: $i > $i).
% 28.89/28.99  tff(decl_24787, type, fn_citric_acid_cycle_92: $i > $i).
% 28.89/28.99  tff(decl_24788, type, fn_citric_acid_cycle_93: $i > $i).
% 28.89/28.99  tff(decl_24789, type, fn_citric_acid_cycle_94: $i > $i).
% 28.89/28.99  tff(decl_24790, type, fn_citric_acid_cycle_95: $i > $i).
% 28.89/28.99  tff(decl_24791, type, fn_citric_acid_cycle_96: $i > $i).
% 28.89/28.99  tff(decl_24792, type, fn_citric_acid_cycle_97: $i > $i).
% 28.89/28.99  tff(decl_24793, type, fn_citric_acid_cycle_98: $i > $i).
% 28.89/28.99  tff(decl_24794, type, fn_citric_acid_cycle_99: $i > $i).
% 28.89/28.99  tff(decl_24795, type, hydration_1: $i > $o).
% 28.89/28.99  tff(decl_24796, type, fn_citric_acid_cycle_100: $i > $i).
% 28.89/28.99  tff(decl_24797, type, fn_citric_acid_cycle_102: $i > $i).
% 28.89/28.99  tff(decl_24798, type, fn_citric_acid_cycle_103: $i > $i).
% 28.89/28.99  tff(decl_24799, type, fn_citric_acid_cycle_104: $i > $i).
% 28.89/28.99  tff(decl_24800, type, fn_citric_acid_cycle_110: $i > $i).
% 28.89/28.99  tff(decl_24801, type, fn_citric_acid_cycle_111: $i > $i).
% 28.89/28.99  tff(decl_24802, type, fn_citric_acid_cycle_112: $i > $i).
% 28.89/28.99  tff(decl_24803, type, fn_citric_acid_cycle_114: $i > $i).
% 28.89/28.99  tff(decl_24804, type, fn_citric_acid_cycle_117: $i > $i).
% 28.89/28.99  tff(decl_24805, type, fn_citric_acid_cycle_118: $i > $i).
% 28.89/28.99  tff(decl_24806, type, fn_citric_acid_cycle_119: $i > $i).
% 28.89/28.99  tff(decl_24807, type, fn_citric_acid_cycle_120: $i > $i).
% 28.89/28.99  tff(decl_24808, type, fn_citric_acid_cycle_121: $i > $i).
% 28.89/28.99  tff(decl_24809, type, fn_citric_acid_cycle_129: $i > $i).
% 28.89/28.99  tff(decl_24810, type, fn_citric_acid_cycle_130: $i > $i).
% 28.89/28.99  tff(decl_24811, type, fn_citric_acid_cycle_131: $i > $i).
% 28.89/28.99  tff(decl_24812, type, fn_citric_acid_cycle_132: $i > $i).
% 28.89/28.99  tff(decl_24813, type, fn_citric_acid_cycle_133: $i > $i).
% 28.89/28.99  tff(decl_24814, type, fn_citric_acid_cycle_134: $i > $i).
% 28.89/28.99  tff(decl_24815, type, fn_citric_acid_cycle_135: $i > $i).
% 28.89/28.99  tff(decl_24816, type, fn_citric_acid_cycle_136: $i > $i).
% 28.89/28.99  tff(decl_24817, type, fn_citric_acid_cycle_137: $i > $i).
% 28.89/28.99  tff(decl_24818, type, fn_decarboxylation_2: $i > $i).
% 28.89/28.99  tff(decl_24819, type, fn_oxidation_6: $i > $i).
% 28.89/28.99  tff(decl_24820, type, fn_oxidation_5: $i > $i).
% 28.89/28.99  tff(decl_24821, type, fn_oxidation_2: $i > $i).
% 28.89/28.99  tff(decl_24822, type, fn_oxidation_3: $i > $i).
% 28.89/28.99  tff(decl_24823, type, fn_oxidation_4: $i > $i).
% 28.89/28.99  tff(decl_24824, type, fn_hydration_2: $i > $i).
% 28.89/28.99  tff(decl_24825, type, fn_hydration_4: $i > $i).
% 28.89/28.99  tff(decl_24826, type, fn_condensation_reaction_3: $i > $i).
% 28.89/28.99  tff(decl_24827, type, fn_dehydration_reaction_6: $i > $i).
% 28.89/28.99  tff(decl_24828, type, fn_dehydration_reaction_1: $i > $i).
% 28.89/28.99  tff(decl_24829, type, fn_condensation_reaction_2: $i > $i).
% 28.89/28.99  tff(decl_24830, type, fn_dehydration_reaction_8: $i > $i).
% 28.89/28.99  tff(decl_24831, type, fn_condensation_reaction_1: $i > $i).
% 28.89/28.99  tff(decl_24832, type, fn_dehydration_reaction_7: $i > $i).
% 28.89/28.99  tff(decl_24833, type, nadh_0: $i).
% 28.89/28.99  tff(decl_24834, type, fadh2_0: $i).
% 28.89/28.99  tff(decl_24835, type, oxaloacetate_0: $i).
% 28.89/28.99  tff(decl_24836, type, nad_plus_0: $i).
% 28.89/28.99  tff(decl_24837, type, fn_citric_acid_cycle_40: $i > $i).
% 28.89/28.99  tff(decl_24838, type, fn_citric_acid_cycle_39: $i > $i).
% 28.89/28.99  tff(decl_24839, type, fn_citric_acid_cycle_44: $i > $i).
% 28.89/28.99  tff(decl_24840, type, fn_citric_acid_cycle_43: $i > $i).
% 28.89/28.99  tff(decl_24841, type, fn_citric_acid_cycle_29: $i > $i).
% 28.89/28.99  tff(decl_24842, type, fn_citric_acid_cycle_28: $i > $i).
% 28.89/28.99  tff(decl_24843, type, fn_citric_acid_cycle_42: $i > $i).
% 28.89/28.99  tff(decl_24844, type, fn_citric_acid_cycle_41: $i > $i).
% 28.89/28.99  tff(decl_24845, type, 'Citric-Acid-Cycle-In-Eukaryote': $i).
% 28.89/28.99  tff(decl_24846, type, 'A chemical cycle, occuring in the mitochondrion of eukaryotes, involving eight steps that completes the metabolic breakdown of glucose molecules begun in glycolysis by oxidizing acetyl CoA to carbon dioxide; the second major stage in cellular respiration.': $i).
% 28.89/28.99  tff(decl_24847, type, 'citric acid cycle in eukaryote': $i).
% 28.89/28.99  tff(decl_24848, type, 'citric-acid-cycle-in-eukaryote': $i).
% 28.89/28.99  tff(decl_24849, type, fn_citric_acid_cycle_in_eukaryote_1: $i > $i).
% 28.89/28.99  tff(decl_24850, type, fn_citric_acid_cycle_in_eukaryote_2: $i > $i).
% 28.89/28.99  tff(decl_24851, type, crista_1: $i > $o).
% 28.89/28.99  tff(decl_24852, type, fn_citric_acid_cycle_in_eukaryote_3: $i > $i).
% 28.89/28.99  tff(decl_24853, type, fn_citric_acid_cycle_in_eukaryote_4: $i > $i).
% 28.89/28.99  tff(decl_24854, type, fn_citric_acid_cycle_in_eukaryote_5: $i > $i).
% 28.89/28.99  tff(decl_24855, type, fn_citric_acid_cycle_in_eukaryote_6: $i > $i).
% 28.89/28.99  tff(decl_24856, type, fn_citric_acid_cycle_in_eukaryote_7: $i > $i).
% 28.89/28.99  tff(decl_24857, type, fn_citric_acid_cycle_in_eukaryote_8: $i > $i).
% 28.89/28.99  tff(decl_24858, type, fn_citric_acid_cycle_in_eukaryote_9: $i > $i).
% 28.89/28.99  tff(decl_24859, type, fn_citric_acid_cycle_in_eukaryote_10: $i > $i).
% 28.89/28.99  tff(decl_24860, type, fn_citric_acid_cycle_in_eukaryote_11: $i > $i).
% 28.89/28.99  tff(decl_24861, type, fn_citric_acid_cycle_in_eukaryote_12: $i > $i).
% 28.89/28.99  tff(decl_24862, type, fn_citric_acid_cycle_in_eukaryote_13: $i > $i).
% 28.89/28.99  tff(decl_24863, type, fn_citric_acid_cycle_in_eukaryote_14: $i > $i).
% 28.89/28.99  tff(decl_24864, type, fn_citric_acid_cycle_in_eukaryote_22: $i > $i).
% 28.89/28.99  tff(decl_24865, type, fn_citric_acid_cycle_in_eukaryote_23: $i > $i).
% 28.89/28.99  tff(decl_24866, type, fn_citric_acid_cycle_in_eukaryote_24: $i > $i).
% 28.89/28.99  tff(decl_24867, type, fn_citric_acid_cycle_in_eukaryote_25: $i > $i).
% 28.89/28.99  tff(decl_24868, type, fn_citric_acid_cycle_in_eukaryote_26: $i > $i).
% 28.89/28.99  tff(decl_24869, type, fn_citric_acid_cycle_in_eukaryote_27: $i > $i).
% 28.89/28.99  tff(decl_24870, type, fn_citric_acid_cycle_in_eukaryote_28: $i > $i).
% 28.89/28.99  tff(decl_24871, type, fn_citric_acid_cycle_in_eukaryote_29: $i > $i).
% 28.89/28.99  tff(decl_24872, type, fn_citric_acid_cycle_in_eukaryote_30: $i > $i).
% 28.89/28.99  tff(decl_24873, type, fn_citric_acid_cycle_in_eukaryote_31: $i > $i).
% 28.89/28.99  tff(decl_24874, type, fn_citric_acid_cycle_in_eukaryote_32: $i > $i).
% 28.89/28.99  tff(decl_24875, type, fn_citric_acid_cycle_in_eukaryote_33: $i > $i).
% 28.89/28.99  tff(decl_24876, type, fn_citric_acid_cycle_in_eukaryote_34: $i > $i).
% 28.89/28.99  tff(decl_24877, type, fn_citric_acid_cycle_in_eukaryote_35: $i > $i).
% 28.89/28.99  tff(decl_24878, type, fn_citric_acid_cycle_in_eukaryote_36: $i > $i).
% 28.89/28.99  tff(decl_24879, type, fn_citric_acid_cycle_in_eukaryote_37: $i > $i).
% 28.89/28.99  tff(decl_24880, type, fn_citric_acid_cycle_in_eukaryote_38: $i > $i).
% 28.89/28.99  tff(decl_24881, type, fn_citric_acid_cycle_in_eukaryote_39: $i > $i).
% 28.89/28.99  tff(decl_24882, type, fn_citric_acid_cycle_in_eukaryote_40: $i > $i).
% 28.89/28.99  tff(decl_24883, type, fn_citric_acid_cycle_in_eukaryote_41: $i > $i).
% 28.89/28.99  tff(decl_24884, type, fn_citric_acid_cycle_in_eukaryote_42: $i > $i).
% 28.89/28.99  tff(decl_24885, type, fn_citric_acid_cycle_in_eukaryote_43: $i > $i).
% 28.89/28.99  tff(decl_24886, type, fn_citric_acid_cycle_in_eukaryote_44: $i > $i).
% 28.89/28.99  tff(decl_24887, type, fn_citric_acid_cycle_in_eukaryote_45: $i > $i).
% 28.89/28.99  tff(decl_24888, type, fn_citric_acid_cycle_in_eukaryote_46: $i > $i).
% 28.89/28.99  tff(decl_24889, type, fn_citric_acid_cycle_in_eukaryote_47: $i > $i).
% 28.89/28.99  tff(decl_24890, type, fn_citric_acid_cycle_in_eukaryote_48: $i > $i).
% 28.89/28.99  tff(decl_24891, type, fn_citric_acid_cycle_in_eukaryote_49: $i > $i).
% 28.89/28.99  tff(decl_24892, type, fn_citric_acid_cycle_in_eukaryote_50: $i > $i).
% 28.89/28.99  tff(decl_24893, type, fn_citric_acid_cycle_in_eukaryote_51: $i > $i).
% 28.89/28.99  tff(decl_24894, type, fn_citric_acid_cycle_in_eukaryote_52: $i > $i).
% 28.89/28.99  tff(decl_24895, type, fn_citric_acid_cycle_in_eukaryote_53: $i > $i).
% 28.89/28.99  tff(decl_24896, type, fn_citric_acid_cycle_in_eukaryote_54: $i > $i).
% 28.89/28.99  tff(decl_24897, type, fn_citric_acid_cycle_in_eukaryote_55: $i > $i).
% 28.89/28.99  tff(decl_24898, type, fn_citric_acid_cycle_in_eukaryote_56: $i > $i).
% 28.89/28.99  tff(decl_24899, type, fn_citric_acid_cycle_in_eukaryote_57: $i > $i).
% 28.89/28.99  tff(decl_24900, type, fn_citric_acid_cycle_in_eukaryote_58: $i > $i).
% 28.89/28.99  tff(decl_24901, type, fn_citric_acid_cycle_in_eukaryote_59: $i > $i).
% 28.89/28.99  tff(decl_24902, type, fn_citric_acid_cycle_in_eukaryote_60: $i > $i).
% 28.89/28.99  tff(decl_24903, type, fn_citric_acid_cycle_in_eukaryote_61: $i > $i).
% 28.89/28.99  tff(decl_24904, type, fn_citric_acid_cycle_in_eukaryote_62: $i > $i).
% 28.89/28.99  tff(decl_24905, type, fn_citric_acid_cycle_in_eukaryote_63: $i > $i).
% 28.89/28.99  tff(decl_24906, type, fn_citric_acid_cycle_in_eukaryote_64: $i > $i).
% 28.89/28.99  tff(decl_24907, type, fn_citric_acid_cycle_in_eukaryote_65: $i > $i).
% 28.89/28.99  tff(decl_24908, type, fn_citric_acid_cycle_in_eukaryote_66: $i > $i).
% 28.89/28.99  tff(decl_24909, type, fn_citric_acid_cycle_in_eukaryote_67: $i > $i).
% 28.89/28.99  tff(decl_24910, type, fn_citric_acid_cycle_in_eukaryote_68: $i > $i).
% 28.89/28.99  tff(decl_24911, type, fn_citric_acid_cycle_in_eukaryote_69: $i > $i).
% 28.89/28.99  tff(decl_24912, type, fn_citric_acid_cycle_in_eukaryote_70: $i > $i).
% 28.89/28.99  tff(decl_24913, type, fn_citric_acid_cycle_in_eukaryote_71: $i > $i).
% 28.89/28.99  tff(decl_24914, type, fn_citric_acid_cycle_in_eukaryote_72: $i > $i).
% 28.89/28.99  tff(decl_24915, type, fn_citric_acid_cycle_in_eukaryote_73: $i > $i).
% 28.89/28.99  tff(decl_24916, type, fn_citric_acid_cycle_in_eukaryote_74: $i > $i).
% 28.89/28.99  tff(decl_24917, type, fn_citric_acid_cycle_in_eukaryote_75: $i > $i).
% 28.89/28.99  tff(decl_24918, type, fn_citric_acid_cycle_in_eukaryote_76: $i > $i).
% 28.89/28.99  tff(decl_24919, type, fn_citric_acid_cycle_in_eukaryote_77: $i > $i).
% 28.89/28.99  tff(decl_24920, type, fn_citric_acid_cycle_in_eukaryote_78: $i > $i).
% 28.89/28.99  tff(decl_24921, type, fn_citric_acid_cycle_in_eukaryote_79: $i > $i).
% 28.89/28.99  tff(decl_24922, type, fn_citric_acid_cycle_in_eukaryote_80: $i > $i).
% 28.89/28.99  tff(decl_24923, type, fn_citric_acid_cycle_in_eukaryote_81: $i > $i).
% 28.89/28.99  tff(decl_24924, type, fn_citric_acid_cycle_in_eukaryote_82: $i > $i).
% 28.89/28.99  tff(decl_24925, type, fn_citric_acid_cycle_in_eukaryote_83: $i > $i).
% 28.89/28.99  tff(decl_24926, type, fn_citric_acid_cycle_in_eukaryote_84: $i > $i).
% 28.89/28.99  tff(decl_24927, type, fn_citric_acid_cycle_in_eukaryote_85: $i > $i).
% 28.89/28.99  tff(decl_24928, type, fn_citric_acid_cycle_in_eukaryote_86: $i > $i).
% 28.89/28.99  tff(decl_24929, type, fn_citric_acid_cycle_in_eukaryote_87: $i > $i).
% 28.89/28.99  tff(decl_24930, type, fn_citric_acid_cycle_in_eukaryote_88: $i > $i).
% 28.89/28.99  tff(decl_24931, type, fn_citric_acid_cycle_in_eukaryote_89: $i > $i).
% 28.89/28.99  tff(decl_24932, type, fn_citric_acid_cycle_in_eukaryote_90: $i > $i).
% 28.89/28.99  tff(decl_24933, type, fn_citric_acid_cycle_in_eukaryote_91: $i > $i).
% 28.89/28.99  tff(decl_24934, type, fn_citric_acid_cycle_in_eukaryote_92: $i > $i).
% 28.89/28.99  tff(decl_24935, type, fn_citric_acid_cycle_in_eukaryote_93: $i > $i).
% 28.89/28.99  tff(decl_24936, type, fn_citric_acid_cycle_in_eukaryote_94: $i > $i).
% 28.89/28.99  tff(decl_24937, type, fn_citric_acid_cycle_in_eukaryote_95: $i > $i).
% 28.89/28.99  tff(decl_24938, type, fn_citric_acid_cycle_in_eukaryote_96: $i > $i).
% 28.89/28.99  tff(decl_24939, type, fn_citric_acid_cycle_in_eukaryote_97: $i > $i).
% 28.89/28.99  tff(decl_24940, type, fn_citric_acid_cycle_in_eukaryote_98: $i > $i).
% 28.89/28.99  tff(decl_24941, type, fn_citric_acid_cycle_in_eukaryote_99: $i > $i).
% 28.89/28.99  tff(decl_24942, type, fn_citric_acid_cycle_in_eukaryote_100: $i > $i).
% 28.89/28.99  tff(decl_24943, type, fn_citric_acid_cycle_in_eukaryote_101: $i > $i).
% 28.89/28.99  tff(decl_24944, type, fn_citric_acid_cycle_in_eukaryote_102: $i > $i).
% 28.89/28.99  tff(decl_24945, type, fn_citric_acid_cycle_in_eukaryote_103: $i > $i).
% 28.89/28.99  tff(decl_24946, type, fn_citric_acid_cycle_in_eukaryote_104: $i > $i).
% 28.89/28.99  tff(decl_24947, type, fn_citric_acid_cycle_in_eukaryote_105: $i > $i).
% 28.89/28.99  tff(decl_24948, type, fn_citric_acid_cycle_in_eukaryote_106: $i > $i).
% 28.89/28.99  tff(decl_24949, type, fn_citric_acid_cycle_in_eukaryote_107: $i > $i).
% 28.89/28.99  tff(decl_24950, type, fn_citric_acid_cycle_in_eukaryote_108: $i > $i).
% 28.89/28.99  tff(decl_24951, type, fn_citric_acid_cycle_in_eukaryote_109: $i > $i).
% 28.89/28.99  tff(decl_24952, type, fn_citric_acid_cycle_in_eukaryote_110: $i > $i).
% 28.89/28.99  tff(decl_24953, type, fn_dehydration_reaction_5: $i > $i).
% 28.89/28.99  tff(decl_24954, type, fn_hydration_3: $i > $i).
% 28.89/28.99  tff(decl_24955, type, fn_dehydrogenase_25: $i > $i).
% 28.89/28.99  tff(decl_24956, type, fn_isocitrate_1: $i > $i).
% 28.89/28.99  tff(decl_24957, type, fn_protein_13: $i > $i).
% 28.89/28.99  tff(decl_24958, type, fn_protein_12: $i > $i).
% 28.89/28.99  tff(decl_24959, type, fn_dehydration_reaction_2: $i > $i).
% 28.89/28.99  tff(decl_24960, type, fn_dehydration_reaction_4: $i > $i).
% 28.89/28.99  tff(decl_24961, type, fn_dehydration_reaction_3: $i > $i).
% 28.89/28.99  tff(decl_24962, type, fn_dehydrogenase_19: $i > $i).
% 28.89/28.99  tff(decl_24963, type, fn_citric_acid_cycle_in_eukaryote_21: $i > $i).
% 28.89/28.99  tff(decl_24964, type, fn_citric_acid_cycle_in_eukaryote_20: $i > $i).
% 28.89/28.99  tff(decl_24965, type, fn_citric_acid_cycle_in_eukaryote_18: $i > $i).
% 28.89/28.99  tff(decl_24966, type, fn_citric_acid_cycle_in_eukaryote_17: $i > $i).
% 28.89/28.99  tff(decl_24967, type, fn_citric_acid_cycle_in_eukaryote_19: $i > $i).
% 28.89/28.99  tff(decl_24968, type, fn_citric_acid_cycle_in_eukaryote_16: $i > $i).
% 28.89/28.99  tff(decl_24969, type, fn_citric_acid_cycle_in_eukaryote_15: $i > $i).
% 28.89/28.99  tff(decl_24970, type, fn_citric_acid_cycle_in_prokaryote_2: $i > $i).
% 28.89/28.99  tff(decl_24971, type, 'Citric-Acid-Cycle-In-Prokaryote': $i).
% 28.89/28.99  tff(decl_24972, type, 'A chemical cycle, occuring in the cytosol of prokaryotes, involving eight steps that completes the metabolic breakdown of glucose molecules begun in glycolysis by oxidizing acetyl CoA to carbon dioxide; the second major stage in cellular respiration.': $i).
% 28.89/28.99  tff(decl_24973, type, 'citric acid cycle in prokaryote': $i).
% 28.89/28.99  tff(decl_24974, type, 'citric-acid-cycle-in-prokaryote': $i).
% 28.89/28.99  tff(decl_24975, type, fn_citric_acid_cycle_in_prokaryote_3: $i > $i).
% 28.89/28.99  tff(decl_24976, type, city_1: $i > $o).
% 28.89/28.99  tff(decl_24977, type, 'City': $i).
% 28.89/28.99  tff(decl_24978, type, city: $i).
% 28.89/28.99  tff(decl_24979, type, metropolis: $i).
% 28.89/28.99  tff(decl_24980, type, 'urban center': $i).
% 28.89/28.99  tff(decl_24981, type, urban_center: $i).
% 28.89/28.99  tff(decl_24982, type, province_1: $i > $o).
% 28.89/28.99  tff(decl_24983, type, political_state_1: $i > $o).
% 28.89/28.99  tff(decl_24984, type, county_1: $i > $o).
% 28.89/28.99  tff(decl_24985, type, country_1: $i > $o).
% 28.89/28.99  tff(decl_24986, type, 'Cl-Minus': $i).
% 28.89/28.99  tff(decl_24987, type, 'The chloride ion of chlorine. The chloride ion readily forms water-soluble salts, such as sodium chloride (NaCl).': $i).
% 28.89/28.99  tff(decl_24988, type, 'chloride ion': $i).
% 28.89/28.99  tff(decl_24989, type, 'chloride-ion': $i).
% 28.89/28.99  tff(decl_24990, type, chloride: $i).
% 28.89/28.99  tff(decl_24991, type, 'minus of cl': $i).
% 28.89/28.99  tff(decl_24992, type, 'cl minus': $i).
% 28.89/28.99  tff(decl_24993, type, 'cl-minus': $i).
% 28.89/28.99  tff(decl_24994, type, fn_cl_minus_1: $i > $i).
% 28.89/28.99  tff(decl_24995, type, fn_cl_minus_2: $i > $i).
% 28.89/28.99  tff(decl_24996, type, fn_cl_minus_3: $i > $i).
% 28.89/28.99  tff(decl_24997, type, fn_cl_minus_5: $i > $i).
% 28.89/28.99  tff(decl_24998, type, fn_cl_minus_6: $i > $i).
% 28.89/28.99  tff(decl_24999, type, fn_cl_minus_7: $i > $i).
% 28.89/28.99  tff(decl_25000, type, fn_cl_minus_8: $i > $i).
% 28.89/28.99  tff(decl_25001, type, cl2_gas_1: $i > $o).
% 28.89/28.99  tff(decl_25002, type, 'Cl2-Gas': $i).
% 28.89/28.99  tff(decl_25003, type, 'The gaseous, diatomic form of the element chlorine': $i).
% 28.89/28.99  tff(decl_25004, type, 'cl2 gas': $i).
% 28.89/28.99  tff(decl_25005, type, 'cl2-gas': $i).
% 28.89/28.99  tff(decl_25006, type, fn_cl2_gas_1: $i > $i).
% 28.89/28.99  tff(decl_25007, type, clade_1: $i > $o).
% 28.89/28.99  tff(decl_25008, type, 'Clade': $i).
% 28.89/28.99  tff(decl_25009, type, 'A monophyletic group, consisting of an ancestral species and all of its descendants.': $i).
% 28.89/28.99  tff(decl_25010, type, monophyletic: $i).
% 28.89/28.99  tff(decl_25011, type, 'monophyletic taxon': $i).
% 28.89/28.99  tff(decl_25012, type, 'monophyletic-taxon': $i).
% 28.89/28.99  tff(decl_25013, type, clade: $i).
% 28.89/28.99  tff(decl_25014, type, 'Cladistics': $i).
% 28.89/28.99  tff(decl_25015, type, 'A method of biological classification that places organisms into groups based on their shared unique characters. Organisms within a group, or clade, are considered to be closely related to each other and more distantly related to other organisms.': $i).
% 28.89/28.99  tff(decl_25016, type, cladistics: $i).
% 28.89/28.99  tff(decl_25017, type, systematics_1: $i > $o).
% 28.89/28.99  tff(decl_25018, type, 'Cladogenesis': $i).
% 28.89/28.99  tff(decl_25019, type, 'Branching evolution, in which a new species buds off from a parent species': $i).
% 28.89/28.99  tff(decl_25020, type, cladogenesis: $i).
% 28.89/28.99  tff(decl_25021, type, 'Cladogram': $i).
% 28.89/28.99  tff(decl_25022, type, 'In cladistics, a cladogram is a diagram used to depict relationships among organisms.': $i).
% 28.89/28.99  tff(decl_25023, type, cladogram: $i).
% 28.89/28.99  tff(decl_25024, type, evolutionary_representation_1: $i > $o).
% 28.89/28.99  tff(decl_25025, type, 'Class': $i).
% 28.89/28.99  tff(decl_25026, type, class: $i).
% 28.89/28.99  tff(decl_25027, type, class_as_classification_1: $i > $o).
% 28.89/28.99  tff(decl_25028, type, 'Class-As-Classification': $i).
% 28.89/28.99  tff(decl_25029, type, 'In Linnean taxonomy, the taxonomic category below the level of phylum and above the level of order.': $i).
% 28.89/28.99  tff(decl_25030, type, 'class as classification': $i).
% 28.89/28.99  tff(decl_25031, type, 'class-as-classification': $i).
% 28.89/28.99  tff(decl_25032, type, taxon_1: $i > $o).
% 28.89/28.99  tff(decl_25033, type, class_definition_viewpoint_1: $i > $o).
% 28.89/28.99  tff(decl_25034, type, 'Class-Definition-Viewpoint': $i).
% 28.89/28.99  tff(decl_25035, type, 'class definition viewpoint': $i).
% 28.89/28.99  tff(decl_25036, type, 'class-definition-viewpoint': $i).
% 28.89/28.99  tff(decl_25037, type, viewpoint_1: $i > $o).
% 28.89/28.99  tff(decl_25038, type, class_i_mhc_molecule_1: $i > $o).
% 28.89/28.99  tff(decl_25039, type, 'Class-I-MHC-Molecule': $i).
% 28.89/28.99  tff(decl_25040, type, 'A type of MHC molecule found on the surface of nearly all nucleated cells and that functions in identification of infected cells by cytotoxic T ells.': $i).
% 28.89/28.99  tff(decl_25041, type, 'class i mhc molecule': $i).
% 28.89/28.99  tff(decl_25042, type, 'class-i-mhc-molecule': $i).
% 28.89/28.99  tff(decl_25043, type, major_histocompatibility_complex_protein_1: $i > $o).
% 28.89/28.99  tff(decl_25044, type, class_ii_mhc_molecule_1: $i > $o).
% 28.89/28.99  tff(decl_25045, type, 'Class-II-MHC-Molecule': $i).
% 28.89/28.99  tff(decl_25046, type, 'A type of MHC molecule found only on antigen-presenting cells such as B cells, dendritic cells, and macrophages.': $i).
% 28.89/28.99  tff(decl_25047, type, 'class ii mhc molecule': $i).
% 28.89/28.99  tff(decl_25048, type, 'class-ii-mhc-molecule': $i).
% 28.89/28.99  tff(decl_25049, type, classical_conditioning_1: $i > $o).
% 28.89/28.99  tff(decl_25050, type, 'Classical-Conditioning': $i).
% 28.89/28.99  tff(decl_25051, type, 'A type of associative learning in which an arbitrary stimulus (the conditioned stimulus) becomes associated with a second, unconditioned, stimulus.': $i).
% 28.89/28.99  tff(decl_25052, type, 'classical conditioning': $i).
% 28.89/28.99  tff(decl_25053, type, 'classical-conditioning': $i).
% 28.89/28.99  tff(decl_25054, type, operant_conditioning_1: $i > $o).
% 28.89/28.99  tff(decl_25055, type, classification_system_1: $i > $o).
% 28.89/28.99  tff(decl_25056, type, 'Classification-System': $i).
% 28.89/28.99  tff(decl_25057, type, 'A system for categorizing organisms.': $i).
% 28.89/28.99  tff(decl_25058, type, 'system of classification': $i).
% 28.89/28.99  tff(decl_25059, type, 'classification system': $i).
% 28.89/28.99  tff(decl_25060, type, 'classification-system': $i).
% 28.89/28.99  tff(decl_25061, type, 'Classification-Unit': $i).
% 28.89/28.99  tff(decl_25062, type, 'Group assigned to a group of things living or not, related spatially, genetically, phenotypically, behaviorally, or temporally.': $i).
% 28.89/28.99  tff(decl_25063, type, 'unit of classification': $i).
% 28.89/28.99  tff(decl_25064, type, 'classification unit': $i).
% 28.89/28.99  tff(decl_25065, type, 'classification-unit': $i).
% 28.89/28.99  tff(decl_25066, type, genomic_library_1: $i > $o).
% 28.89/28.99  tff(decl_25067, type, positional_information_1: $i > $o).
% 28.89/28.99  tff(decl_25068, type, proximate_causation_1: $i > $o).
% 28.89/28.99  tff(decl_25069, type, representation_1: $i > $o).
% 28.89/28.99  tff(decl_25070, type, rna_world_1: $i > $o).
% 28.89/28.99  tff(decl_25071, type, scientific_laws_1: $i > $o).
% 28.89/28.99  tff(decl_25072, type, 'Clawed-Lobster': $i).
% 28.89/28.99  tff(decl_25073, type, 'A crustacean of the family Homaridae, characterized by a long body, muscular tail, and the anteriormost pair of thoracic walking legs modified into large claws.': $i).
% 28.89/28.99  tff(decl_25074, type, 'clawed lobster': $i).
% 28.89/28.99  tff(decl_25075, type, 'clawed-lobster': $i).
% 28.89/28.99  tff(decl_25076, type, cleavage_1: $i > $o).
% 28.89/28.99  tff(decl_25077, type, 'Cleavage': $i).
% 28.89/28.99  tff(decl_25078, type, '(1) In animal cells, the process of cytokinesis that results in the pinching in of the plasma membrane. (2) In early animal development, a series of rapid cell divisions that occur without growth, resulting in a multi-celled embryo that is roughly the same size as the original zygote.': $i).
% 28.89/28.99  tff(decl_25079, type, 'undergo cleavage': $i).
% 28.89/28.99  tff(decl_25080, type, cleave: $i).
% 28.89/28.99  tff(decl_25081, type, cleavage: $i).
% 28.89/28.99  tff(decl_25082, type, cytokinesis_1: $i > $o).
% 28.89/28.99  tff(decl_25083, type, fn_cleavage_1: $i > $i).
% 28.89/28.99  tff(decl_25084, type, fn_cleavage_2: $i > $i).
% 28.89/28.99  tff(decl_25085, type, fn_cleavage_3: $i > $i).
% 28.89/28.99  tff(decl_25086, type, fn_cleavage_4: $i > $i).
% 28.89/28.99  tff(decl_25087, type, fn_cleavage_5: $i > $i).
% 28.89/28.99  tff(decl_25088, type, fn_cleavage_6: $i > $i).
% 28.89/28.99  tff(decl_25089, type, fn_cleavage_7: $i > $i).
% 28.89/28.99  tff(decl_25090, type, fn_cleavage_8: $i > $i).
% 28.89/28.99  tff(decl_25091, type, fn_cleavage_9: $i > $i).
% 28.89/28.99  tff(decl_25092, type, contractile_ring_1: $i > $o).
% 28.89/28.99  tff(decl_25093, type, fn_cleavage_10: $i > $i).
% 28.89/28.99  tff(decl_25094, type, fn_cleavage_11: $i > $i).
% 28.89/28.99  tff(decl_25095, type, myosin_1: $i > $o).
% 28.89/28.99  tff(decl_25096, type, fn_cleavage_12: $i > $i).
% 28.89/28.99  tff(decl_25097, type, fn_contractile_ring_6: $i > $i).
% 28.89/28.99  tff(decl_25098, type, fn_contractile_ring_5: $i > $i).
% 28.89/28.99  tff(decl_25099, type, fn_cleavage_furrow_7: $i > $i).
% 28.89/28.99  tff(decl_25100, type, fn_cleavage_furrow_1: $i > $i).
% 28.89/28.99  tff(decl_25101, type, animal_cell_0: $i).
% 28.89/28.99  tff(decl_25102, type, daughter_cell_0: $i).
% 28.89/28.99  tff(decl_25103, type, 'Cleavage-Furrow': $i).
% 28.89/28.99  tff(decl_25104, type, '(1) A shallow groove that marks the beginning of cleavage in an animal cell. (2) A shallow groove that forms in the surface of a cell in the area of the metaphase plate.': $i).
% 28.89/28.99  tff(decl_25105, type, 'furrow of cleavage': $i).
% 28.89/28.99  tff(decl_25106, type, 'cleavage furrow': $i).
% 28.89/28.99  tff(decl_25107, type, 'cleavage-furrow': $i).
% 28.89/28.99  tff(decl_25108, type, fn_cleavage_furrow_2: $i > $i).
% 28.89/28.99  tff(decl_25109, type, fn_cleavage_furrow_4: $i > $i).
% 28.89/28.99  tff(decl_25110, type, fn_cleavage_furrow_5: $i > $i).
% 28.89/28.99  tff(decl_25111, type, fn_cleavage_furrow_6: $i > $i).
% 28.89/28.99  tff(decl_25112, type, animal_cell_structure_0: $i).
% 28.89/28.99  tff(decl_25113, type, clib_slot_group_1: $i > $o).
% 28.89/28.99  tff(decl_25114, type, 'CLIB-Slot-Group': $i).
% 28.89/28.99  tff(decl_25115, type, 'clib slot group': $i).
% 28.89/28.99  tff(decl_25116, type, 'clib-slot-group': $i).
% 28.89/28.99  tff(decl_25117, type, km_slot_group_1: $i > $o).
% 28.89/28.99  tff(decl_25118, type, 'Cliche': $i).
% 28.89/28.99  tff(decl_25119, type, cliche: $i).
% 28.89/28.99  tff(decl_25120, type, 'Climate': $i).
% 28.89/28.99  tff(decl_25121, type, 'Long-term weather patterns associated with a defined geographical location.': $i).
% 28.89/28.99  tff(decl_25122, type, acclimate: $i).
% 28.89/28.99  tff(decl_25123, type, climate: $i).
% 28.89/28.99  tff(decl_25124, type, climate_change_1: $i > $o).
% 28.89/28.99  tff(decl_25125, type, 'Climate-Change': $i).
% 28.89/28.99  tff(decl_25126, type, 'Significant and persistent change in the distribution of weather patterns over periods of time from decades to millenia.': $i).
% 28.89/28.99  tff(decl_25127, type, 'change of climate': $i).
% 28.89/28.99  tff(decl_25128, type, 'climate change': $i).
% 28.89/28.99  tff(decl_25129, type, 'climate-change': $i).
% 28.89/28.99  tff(decl_25130, type, 'Climograph': $i).
% 28.89/28.99  tff(decl_25131, type, 'A graph of monthly temperature and precipitation levels at a particlar location.': $i).
% 28.89/28.99  tff(decl_25132, type, climatogram: $i).
% 28.89/28.99  tff(decl_25133, type, climatograph: $i).
% 28.89/28.99  tff(decl_25134, type, climograph: $i).
% 28.89/28.99  tff(decl_25135, type, cline_1: $i > $o).
% 28.89/28.99  tff(decl_25136, type, 'Cline': $i).
% 28.89/28.99  tff(decl_25137, type, 'A transition zone between two biomes, which represents a graded change in biological composition along a geographic axis.': $i).
% 28.89/28.99  tff(decl_25138, type, cline: $i).
% 28.89/28.99  tff(decl_25139, type, clitoris_1: $i > $o).
% 28.89/28.99  tff(decl_25140, type, 'Clitoris': $i).
% 28.89/28.99  tff(decl_25141, type, 'Female sexual organ extending from the upper intersection of the labia minora to the base of the pubic bone. One of the primary organs of sexual arousal in humans.': $i).
% 28.89/28.99  tff(decl_25142, type, clitoris: $i).
% 28.89/28.99  tff(decl_25143, type, 'Cloaca': $i).
% 28.89/28.99  tff(decl_25144, type, 'A common opening that serves the digestive, urinary, and reproductive tracts. Found in birds, reptiles, and many invertebrates.': $i).
% 28.89/28.99  tff(decl_25145, type, cloaca: $i).
% 28.89/28.99  tff(decl_25146, type, clonal_selection_1: $i > $o).
% 28.89/28.99  tff(decl_25147, type, 'Clonal-Selection': $i).
% 28.89/28.99  tff(decl_25148, type, 'Process by which an antigen molecule binds to and activates only the lymphocytes that are specific to that particular antigen. The selected lymphocytes proliferate to produce a clone of (effector) antibody-producing cells and a clone of memory cells. The effector and memory cells are specific only to the stimulating antigen.': $i).
% 28.89/28.99  tff(decl_25149, type, 'clonal selection': $i).
% 28.89/28.99  tff(decl_25150, type, 'clonal-selection': $i).
% 28.89/28.99  tff(decl_25151, type, 'Clone': $i).
% 28.89/28.99  tff(decl_25152, type, 'A group of genetically identical cells or organisms derived from a single cell or individual by some kind of asexual reproduction.': $i).
% 28.89/28.99  tff(decl_25153, type, 'genetic duplicate': $i).
% 28.89/28.99  tff(decl_25154, type, fn_cloning_2: $i > $i).
% 28.89/28.99  tff(decl_25155, type, cloned_dna_1: $i > $o).
% 28.89/28.99  tff(decl_25156, type, 'Cloned-DNA': $i).
% 28.89/28.99  tff(decl_25157, type, 'DNA that is an identical copy of another piece of DNA.  Produced through a cloning process.': $i).
% 28.89/28.99  tff(decl_25158, type, 'dna clone': $i).
% 28.89/28.99  tff(decl_25159, type, 'dna-clone': $i).
% 28.89/28.99  tff(decl_25160, type, 'cloned dna': $i).
% 28.89/28.99  tff(decl_25161, type, 'cloned-dna': $i).
% 28.89/28.99  tff(decl_25162, type, fn_cloned_dna_1: $i > $i).
% 28.89/28.99  tff(decl_25163, type, fn_cloned_dna_2: $i > $i).
% 28.89/28.99  tff(decl_25164, type, 'Cloned-Embryo': $i).
% 28.89/28.99  tff(decl_25165, type, 'An embryo which is a clone of another embryo is called as cloned embryo.': $i).
% 28.89/28.99  tff(decl_25166, type, 'embryo clone': $i).
% 28.89/28.99  tff(decl_25167, type, 'cloned embryo': $i).
% 28.89/28.99  tff(decl_25168, type, 'cloned-embryo': $i).
% 28.89/28.99  tff(decl_25169, type, cloned_gene_1: $i > $o).
% 28.89/28.99  tff(decl_25170, type, 'Cloned-Gene': $i).
% 28.89/28.99  tff(decl_25171, type, 'Clone DNA that is the result of copying a gene.': $i).
% 28.89/28.99  tff(decl_25172, type, 'gene clone': $i).
% 28.89/28.99  tff(decl_25173, type, 'gene-clone': $i).
% 28.89/28.99  tff(decl_25174, type, 'cloned gene': $i).
% 28.89/28.99  tff(decl_25175, type, 'cloned-gene': $i).
% 28.89/28.99  tff(decl_25176, type, fn_cloned_gene_1: $i > $i).
% 28.89/28.99  tff(decl_25177, type, fn_cloned_gene_2: $i > $i).
% 28.89/28.99  tff(decl_25178, type, fn_cloning_3: $i > $i).
% 28.89/28.99  tff(decl_25179, type, 'Cloning': $i).
% 28.89/28.99  tff(decl_25180, type, 'DNA cloning: the process by which well-defined segments of DNA are copied multiple times.  Organismal cloning: the process by which an entire organism that is genetically identical to the parent that donated the cell is created.': $i).
% 28.89/28.99  tff(decl_25181, type, cloning: $i).
% 28.89/28.99  tff(decl_25182, type, cloning_eukaryotic_gene_1: $i > $o).
% 28.89/28.99  tff(decl_25183, type, 'Cloning-Eukaryotic-Gene': $i).
% 28.89/28.99  tff(decl_25184, type, 'The process by which identical copies of eukaryotic genes are made.': $i).
% 28.89/28.99  tff(decl_25185, type, 'gene cloning': $i).
% 28.89/28.99  tff(decl_25186, type, 'cloning eukaryotic gene': $i).
% 28.89/28.99  tff(decl_25187, type, 'cloning-eukaryotic-gene': $i).
% 28.89/28.99  tff(decl_25188, type, fn_cloning_eukaryotic_gene_1: $i > $i).
% 28.89/28.99  tff(decl_25189, type, identify_cell_clones_with_gene_of_interest_1: $i > $o).
% 28.89/28.99  tff(decl_25190, type, fn_cloning_eukaryotic_gene_2: $i > $i).
% 28.89/28.99  tff(decl_25191, type, fn_cloning_eukaryotic_gene_3: $i > $i).
% 28.89/28.99  tff(decl_25192, type, fn_cloning_eukaryotic_gene_4: $i > $i).
% 28.89/28.99  tff(decl_25193, type, dna_transfer_1: $i > $o).
% 28.89/28.99  tff(decl_25194, type, fn_cloning_eukaryotic_gene_5: $i > $i).
% 28.89/28.99  tff(decl_25195, type, isolation_of_gene_source_dna_1: $i > $o).
% 28.89/28.99  tff(decl_25196, type, fn_cloning_eukaryotic_gene_6: $i > $i).
% 28.89/28.99  tff(decl_25197, type, isolation_of_vector_1: $i > $o).
% 28.89/28.99  tff(decl_25198, type, fn_cloning_eukaryotic_gene_7: $i > $i).
% 28.89/28.99  tff(decl_25199, type, fn_cloning_eukaryotic_gene_8: $i > $i).
% 28.89/28.99  tff(decl_25200, type, fn_cloning_eukaryotic_gene_9: $i > $i).
% 28.89/28.99  tff(decl_25201, type, fn_cloning_eukaryotic_gene_10: $i > $i).
% 28.89/28.99  tff(decl_25202, type, fn_cloning_eukaryotic_gene_11: $i > $i).
% 28.89/28.99  tff(decl_25203, type, genetic_recombination_in_lab_of_fragments_1: $i > $o).
% 28.89/28.99  tff(decl_25204, type, fn_cloning_eukaryotic_gene_12: $i > $i).
% 28.89/28.99  tff(decl_25205, type, eukaryotic_gene_1: $i > $o).
% 28.89/28.99  tff(decl_25206, type, fn_genetic_recombination_in_lab_of_fragments_12: $i > $i).
% 28.89/28.99  tff(decl_25207, type, fn_genetic_recombination_in_lab_of_fragments_11: $i > $i).
% 28.89/28.99  tff(decl_25208, type, fn_genetic_recombination_in_lab_of_fragments_13: $i > $i).
% 28.89/28.99  tff(decl_25209, type, fn_genetic_recombination_in_lab_of_fragments_2: $i > $i).
% 28.89/28.99  tff(decl_25210, type, plasmid_1: $i > $o).
% 28.89/28.99  tff(decl_25211, type, genetic_engineering_1: $i > $o).
% 28.89/28.99  tff(decl_25212, type, cloning_eukaryotic_gene_in_bacterial_plasmid_1: $i > $o).
% 28.89/28.99  tff(decl_25213, type, fn_cloning_eukaryotic_gene_in_bacterial_plasmid_1: $i > $i).
% 28.89/28.99  tff(decl_25214, type, fn_cloning_eukaryotic_gene_in_bacterial_plasmid_3: $i > $i).
% 28.89/28.99  tff(decl_25215, type, 'Cloning-Eukaryotic-Gene-In-Bacterial-Plasmid': $i).
% 28.89/28.99  tff(decl_25216, type, 'The process of using a bacterial plasmid to produce a clone of a eukaryotic gene.': $i).
% 28.89/28.99  tff(decl_25217, type, 'gene cloning using bacterial plasmid': $i).
% 28.89/28.99  tff(decl_25218, type, 'cloning eukaryotic gene in bacterial plasmid': $i).
% 28.89/28.99  tff(decl_25219, type, 'cloning-eukaryotic-gene-in-bacterial-plasmid': $i).
% 28.89/28.99  tff(decl_25220, type, cloning_eukaryotic_gene_in_cloning_phage_1: $i > $o).
% 28.89/28.99  tff(decl_25221, type, synthesis_of_artificial_eukaryotic_genes_without_introns_1: $i > $o).
% 28.89/28.99  tff(decl_25222, type, fn_cloning_eukaryotic_gene_in_bacterial_plasmid_4: $i > $i).
% 28.89/28.99  tff(decl_25223, type, isolation_of_vector_plasmid_1: $i > $o).
% 28.89/28.99  tff(decl_25224, type, fn_cloning_eukaryotic_gene_in_cloning_phage_5: $i > $i).
% 28.89/28.99  tff(decl_25225, type, fn_cloning_eukaryotic_gene_in_cloning_phage_3: $i > $i).
% 28.89/28.99  tff(decl_25226, type, 'Cloning-Eukaryotic-Gene-In-Cloning-Phage': $i).
% 28.89/28.99  tff(decl_25227, type, 'Process of cloning eukaryotic genes in which the cloning vector is a phage.  Recombinants containing the gene of interest are packaged in a capsid, then used in a viral infection to replicate these genes.': $i).
% 28.89/28.99  tff(decl_25228, type, 'gene cloning using phage': $i).
% 28.89/28.99  tff(decl_25229, type, 'cloning using bacteriophage': $i).
% 28.89/28.99  tff(decl_25230, type, 'gene cloning with bacteriophage': $i).
% 28.89/28.99  tff(decl_25231, type, 'gene cloning using virus': $i).
% 28.89/28.99  tff(decl_25232, type, 'gene cloning with phage': $i).
% 28.89/28.99  tff(decl_25233, type, 'gene cloning with virus': $i).
% 28.89/28.99  tff(decl_25234, type, 'cloning eukaryotic gene in cloning phage': $i).
% 28.89/28.99  tff(decl_25235, type, 'cloning-eukaryotic-gene-in-cloning-phage': $i).
% 28.89/28.99  tff(decl_25236, type, fn_cloning_eukaryotic_gene_in_cloning_phage_1: $i > $i).
% 28.89/28.99  tff(decl_25237, type, fn_cloning_eukaryotic_gene_in_cloning_phage_2: $i > $i).
% 28.89/28.99  tff(decl_25238, type, viral_infection_1: $i > $o).
% 28.89/28.99  tff(decl_25239, type, phage_reproduction_cycle_1: $i > $o).
% 28.89/28.99  tff(decl_25240, type, fn_cloning_eukaryotic_gene_in_cloning_phage_6: $i > $i).
% 28.89/28.99  tff(decl_25241, type, 'Cloning-Phage': $i).
% 28.89/28.99  tff(decl_25242, type, 'Cloning vector that is also a phage.': $i).
% 28.89/28.99  tff(decl_25243, type, 'bacteriophage cloning vector': $i).
% 28.89/28.99  tff(decl_25244, type, 'cloning vector': $i).
% 28.89/28.99  tff(decl_25245, type, 'phage of cloning': $i).
% 28.89/28.99  tff(decl_25246, type, 'cloning phage': $i).
% 28.89/28.99  tff(decl_25247, type, 'cloning-phage': $i).
% 28.89/28.99  tff(decl_25248, type, phage_1: $i > $o).
% 28.89/28.99  tff(decl_25249, type, 'Cloning-Plasmid': $i).
% 28.89/28.99  tff(decl_25250, type, 'Often used as a cloning vector in genetic engineering.  The plasmid is used to carry foreign DNA from a test tube into a host cell and replicate there.': $i).
% 28.89/28.99  tff(decl_25251, type, 'bacterial plasmid for cloning': $i).
% 28.89/28.99  tff(decl_25252, type, 'cloning bacterial plasmid': $i).
% 28.89/28.99  tff(decl_25253, type, 'plasmid vector': $i).
% 28.89/28.99  tff(decl_25254, type, 'plasmid of cloning': $i).
% 28.89/28.99  tff(decl_25255, type, 'cloning plasmid': $i).
% 28.89/28.99  tff(decl_25256, type, 'cloning-plasmid': $i).
% 28.89/28.99  tff(decl_25257, type, fn_cloning_plasmid_1: $i > $i).
% 28.89/28.99  tff(decl_25258, type, 'Cloning-Vector': $i).
% 28.89/28.99  tff(decl_25259, type, 'In genetic engineering, a DNA molecule that can carry foreign DNA into a host cell and replicate there. Cloning vectors include plasmids that move recombinant DNA from a test tube back into a cell and viruses that transfer recombinant DNA by infection.': $i).
% 28.89/28.99  tff(decl_25260, type, 'vector of cloning': $i).
% 28.89/28.99  tff(decl_25261, type, 'cloning-vector': $i).
% 28.89/28.99  tff(decl_25262, type, fn_cloning_vector_1: $i > $i).
% 28.89/28.99  tff(decl_25263, type, fn_cloning_vector_2: $i > $i).
% 28.89/28.99  tff(decl_25264, type, fn_cloning_vector_3: $i > $i).
% 28.89/28.99  tff(decl_25265, type, fn_cloning_vector_6: $i > $i).
% 28.89/28.99  tff(decl_25266, type, fn_genomic_library_4: $i > $i).
% 28.89/28.99  tff(decl_25267, type, fn_genomic_library_3: $i > $i).
% 28.89/28.99  tff(decl_25268, type, close_1: $i > $o).
% 28.89/28.99  tff(decl_25269, type, 'Close': $i).
% 28.89/28.99  tff(decl_25270, type, close: $i).
% 28.89/28.99  tff(decl_25271, type, fn_close_1: $i > $i).
% 28.89/28.99  tff(decl_25272, type, fn_close_2: $i > $i).
% 28.89/28.99  tff(decl_25273, type, fn_close_3: $i > $i).
% 28.89/28.99  tff(decl_25274, type, 'Closed-Circulatory-System': $i).
% 28.89/28.99  tff(decl_25275, type, 'A circulatory system in which blood is always enclosed in vessels and does not circulate directly over body tissues.': $i).
% 28.89/28.99  tff(decl_25276, type, 'closed circulatory system': $i).
% 28.89/28.99  tff(decl_25277, type, 'closed-circulatory-system': $i).
% 28.89/28.99  tff(decl_25278, type, closed_system_1: $i > $o).
% 28.89/28.99  tff(decl_25279, type, 'Closed-system': $i).
% 28.89/28.99  tff(decl_25280, type, 'A closed system is a system that can exchange heat and work (for example, energy), but not matter, with its surroundings': $i).
% 28.89/28.99  tff(decl_25281, type, 'system of closed': $i).
% 28.89/28.99  tff(decl_25282, type, 'closed system': $i).
% 28.89/28.99  tff(decl_25283, type, 'closed-system': $i).
% 28.89/28.99  tff(decl_25284, type, cognitive_map_1: $i > $o).
% 28.89/28.99  tff(decl_25285, type, ecological_model_1: $i > $o).
% 28.89/28.99  tff(decl_25286, type, five_kingdom_system_1: $i > $o).
% 28.89/28.99  tff(decl_25287, type, fluid_mosaic_model_1: $i > $o).
% 28.89/28.99  tff(decl_25288, type, molecular_formula_1: $i > $o).
% 28.89/28.99  tff(decl_25289, type, open_system_1: $i > $o).
% 28.89/28.99  tff(decl_25290, type, redundancy_model_1: $i > $o).
% 28.89/28.99  tff(decl_25291, type, rivet_model_1: $i > $o).
% 28.89/28.99  tff(decl_25292, type, sandwich_model_1: $i > $o).
% 28.89/28.99  tff(decl_25293, type, stable_system_1: $i > $o).
% 28.89/28.99  tff(decl_25294, type, unstable_system_1: $i > $o).
% 28.89/28.99  tff(decl_25295, type, 'Closing-Of-Stoma': $i).
% 28.89/28.99  tff(decl_25296, type, 'The closing of pores found in the leaf and stem epidermis of plants.': $i).
% 28.89/28.99  tff(decl_25297, type, 'stoma closing': $i).
% 28.89/28.99  tff(decl_25298, type, 'stoma-closing': $i).
% 28.89/28.99  tff(decl_25299, type, 'closing of stoma': $i).
% 28.89/28.99  tff(decl_25300, type, 'closing-of-stoma': $i).
% 28.89/28.99  tff(decl_25301, type, fn_closing_of_stoma_2: $i > $i).
% 28.89/28.99  tff(decl_25302, type, fn_closing_of_stoma_4: $i > $i).
% 28.89/28.99  tff(decl_25303, type, fn_closing_of_stoma_5: $i > $i).
% 28.89/28.99  tff(decl_25304, type, fn_closing_of_stoma_6: $i > $i).
% 28.89/28.99  tff(decl_25305, type, fn_closing_of_stoma_7: $i > $i).
% 28.89/28.99  tff(decl_25306, type, fn_closing_of_stoma_8: $i > $i).
% 28.89/28.99  tff(decl_25307, type, fn_closing_of_stoma_9: $i > $i).
% 28.89/28.99  tff(decl_25308, type, fn_closing_of_stoma_10: $i > $i).
% 28.89/28.99  tff(decl_25309, type, fn_closing_of_stoma_11: $i > $i).
% 28.89/28.99  tff(decl_25310, type, fn_closing_of_stoma_12: $i > $i).
% 28.89/28.99  tff(decl_25311, type, fn_closing_of_stoma_13: $i > $i).
% 28.89/28.99  tff(decl_25312, type, fn_closing_of_stoma_14: $i > $i).
% 28.89/28.99  tff(decl_25313, type, fn_closing_of_stoma_15: $i > $i).
% 28.89/28.99  tff(decl_25314, type, fn_closing_of_stoma_16: $i > $i).
% 28.89/28.99  tff(decl_25315, type, fn_closing_of_stoma_17: $i > $i).
% 28.89/28.99  tff(decl_25316, type, fn_closing_of_stoma_18: $i > $i).
% 28.89/28.99  tff(decl_25317, type, transpiration_1: $i > $o).
% 28.89/28.99  tff(decl_25318, type, fn_closing_of_stoma_19: $i > $i).
% 28.89/28.99  tff(decl_25319, type, fn_closing_of_stoma_20: $i > $i).
% 28.89/28.99  tff(decl_25320, type, fn_closing_of_stoma_21: $i > $i).
% 28.89/28.99  tff(decl_25321, type, fn_closing_of_stoma_24: $i > $i).
% 28.89/28.99  tff(decl_25322, type, fn_closing_of_stoma_25: $i > $i).
% 28.89/28.99  tff(decl_25323, type, flaccid_cell_1: $i > $o).
% 28.89/28.99  tff(decl_25324, type, fn_closing_of_stoma_26: $i > $i).
% 28.89/28.99  tff(decl_25325, type, fn_closing_of_stoma_28: $i > $i).
% 28.89/28.99  tff(decl_25326, type, epidermal_cell_1: $i > $o).
% 28.89/28.99  tff(decl_25327, type, fn_closing_of_stoma_29: $i > $i).
% 28.89/28.99  tff(decl_25328, type, fn_closing_of_stoma_30: $i > $i).
% 28.89/28.99  tff(decl_25329, type, fn_closing_of_stoma_31: $i > $i).
% 28.89/28.99  tff(decl_25330, type, fn_closing_of_stoma_32: $i > $i).
% 28.89/28.99  tff(decl_25331, type, potassium_gated_channel_1: $i > $o).
% 28.89/28.99  tff(decl_25332, type, fn_closing_of_stoma_33: $i > $i).
% 28.89/28.99  tff(decl_25333, type, fn_closing_of_stoma_34: $i > $i).
% 28.89/28.99  tff(decl_25334, type, fn_closing_of_stoma_35: $i > $i).
% 28.89/28.99  tff(decl_25335, type, fn_closing_of_stoma_36: $i > $i).
% 28.89/28.99  tff(decl_25336, type, fn_closing_of_stoma_37: $i > $i).
% 28.89/28.99  tff(decl_25337, type, fn_closing_of_stoma_38: $i > $i).
% 28.89/28.99  tff(decl_25338, type, fn_closing_of_stoma_39: $i > $i).
% 28.89/28.99  tff(decl_25339, type, fn_closing_of_stoma_40: $i > $i).
% 28.89/28.99  tff(decl_25340, type, fn_closing_of_stoma_41: $i > $i).
% 28.89/28.99  tff(decl_25341, type, fn_closing_of_stoma_42: $i > $i).
% 28.89/28.99  tff(decl_25342, type, fn_closing_of_stoma_43: $i > $i).
% 28.89/28.99  tff(decl_25343, type, fn_closing_of_stoma_44: $i > $i).
% 28.89/28.99  tff(decl_25344, type, fn_closing_of_stoma_45: $i > $i).
% 28.89/28.99  tff(decl_25345, type, fn_closing_of_stoma_46: $i > $i).
% 28.89/28.99  tff(decl_25346, type, fn_closing_of_stoma_47: $i > $i).
% 28.89/28.99  tff(decl_25347, type, fn_closing_of_stoma_48: $i > $i).
% 28.89/28.99  tff(decl_25348, type, fn_closing_of_stoma_49: $i > $i).
% 28.89/28.99  tff(decl_25349, type, fn_closing_of_stoma_50: $i > $i).
% 28.89/28.99  tff(decl_25350, type, fn_closing_of_stoma_51: $i > $i).
% 28.89/28.99  tff(decl_25351, type, fn_closing_of_stoma_52: $i > $i).
% 28.89/28.99  tff(decl_25352, type, fn_closing_of_stoma_53: $i > $i).
% 28.89/28.99  tff(decl_25353, type, fn_closing_of_stoma_54: $i > $i).
% 28.89/28.99  tff(decl_25354, type, fn_closing_of_stoma_56: $i > $i).
% 28.89/28.99  tff(decl_25355, type, fn_closing_of_stoma_57: $i > $i).
% 28.89/28.99  tff(decl_25356, type, fn_closing_of_stoma_58: $i > $i).
% 28.89/28.99  tff(decl_25357, type, fn_closing_of_stoma_59: $i > $i).
% 28.89/28.99  tff(decl_25358, type, fn_closing_of_stoma_60: $i > $i).
% 28.89/28.99  tff(decl_25359, type, fn_closing_of_stoma_61: $i > $i).
% 28.89/28.99  tff(decl_25360, type, fn_closing_of_stoma_62: $i > $i).
% 28.89/28.99  tff(decl_25361, type, fn_closing_of_stoma_63: $i > $i).
% 28.89/28.99  tff(decl_25362, type, fn_closing_of_stoma_64: $i > $i).
% 28.89/28.99  tff(decl_25363, type, fn_gated_ion_channel_4: $i > $i).
% 28.89/28.99  tff(decl_25364, type, fn_spongy_mesophyll_1: $i > $i).
% 28.89/28.99  tff(decl_25365, type, fn_epidermis_4: $i > $i).
% 28.89/28.99  tff(decl_25366, type, fn_plant_cell_9: $i > $i).
% 28.89/28.99  tff(decl_25367, type, fn_leaf_38: $i > $i).
% 28.89/28.99  tff(decl_25368, type, fn_guard_cell_11: $i > $i).
% 28.89/28.99  tff(decl_25369, type, fn_stoma_9: $i > $i).
% 28.89/28.99  tff(decl_25370, type, fn_guard_cell_23: $i > $i).
% 28.89/28.99  tff(decl_25371, type, fn_guard_cell_19: $i > $i).
% 28.89/28.99  tff(decl_25372, type, fn_leaf_53: $i > $i).
% 28.89/28.99  tff(decl_25373, type, fn_stoma_2: $i > $i).
% 28.89/28.99  tff(decl_25374, type, fn_leaf_52: $i > $i).
% 28.89/28.99  tff(decl_25375, type, fn_stoma_1: $i > $i).
% 28.89/28.99  tff(decl_25376, type, fn_stoma_11: $i > $i).
% 28.89/28.99  tff(decl_25377, type, fn_closing_of_stoma_55: $i > $i).
% 28.89/28.99  tff(decl_25378, type, fn_closing_of_stoma_65: $i > $i).
% 28.89/28.99  tff(decl_25379, type, clostridium_botulinum_1: $i > $o).
% 28.89/28.99  tff(decl_25380, type, 'Clostridium-Botulinum': $i).
% 28.89/28.99  tff(decl_25381, type, 'A  Gram-positive rod-shaped bacterium that produces several toxins, including the neurotoxins responsible for botulism.': $i).
% 28.89/28.99  tff(decl_25382, type, 'botulinum of clostridium': $i).
% 28.89/28.99  tff(decl_25383, type, 'clostridium botulinum': $i).
% 28.89/28.99  tff(decl_25384, type, 'clostridium-botulinum': $i).
% 28.89/28.99  tff(decl_25385, type, streptococcus_pneumoniae_1: $i > $o).
% 28.89/28.99  tff(decl_25386, type, clotting_1: $i > $o).
% 28.89/28.99  tff(decl_25387, type, 'Clotting': $i).
% 28.89/28.99  tff(decl_25388, type, 'A process in which the protein fibrinogen is converted to fibrin and aggregates in an area to clog an open wound.': $i).
% 28.89/28.99  tff(decl_25389, type, clot: $i).
% 28.89/28.99  tff(decl_25390, type, clotting: $i).
% 28.89/28.99  tff(decl_25391, type, 'Clotting-Factor': $i).
% 28.89/28.99  tff(decl_25392, type, 'Clotting factors include blood proteins (eg, prothrombin, factor VIII) that promote blood coagulation.': $i).
% 28.89/28.99  tff(decl_25393, type, 'blood clotting factor': $i).
% 28.89/28.99  tff(decl_25394, type, 'blood clotting protein': $i).
% 28.89/28.99  tff(decl_25395, type, 'clotting protein': $i).
% 28.89/28.99  tff(decl_25396, type, 'clotting agent': $i).
% 28.89/28.99  tff(decl_25397, type, 'factor of clotting': $i).
% 28.89/28.99  tff(decl_25398, type, 'clotting factor': $i).
% 28.89/28.99  tff(decl_25399, type, 'clotting-factor': $i).
% 28.89/28.99  tff(decl_25400, type, fn_clotting_factor_2: $i > $i).
% 28.89/28.99  tff(decl_25401, type, fn_clotting_factor_3: $i > $i).
% 28.89/28.99  tff(decl_25402, type, fn_clotting_factor_4: $i > $i).
% 28.89/28.99  tff(decl_25403, type, clotting_factor_0: $i).
% 28.89/28.99  tff(decl_25404, type, 'Club-Fungus': $i).
% 28.89/28.99  tff(decl_25405, type, 'Basidiomycota, or club fungi, are filamentous fungi composed of hyphae (except for those forming yeasts), and reproducing sexually via the formation of specialized club-shaped end cells called basidia that normally bear external meiospores.': $i).
% 28.89/28.99  tff(decl_25406, type, 'club fungi': $i).
% 28.89/28.99  tff(decl_25407, type, 'club-fungi': $i).
% 28.89/28.99  tff(decl_25408, type, basidiomycote: $i).
% 28.89/28.99  tff(decl_25409, type, basidiomycetes: $i).
% 28.89/28.99  tff(decl_25410, type, 'fungus of club': $i).
% 28.89/28.99  tff(decl_25411, type, 'club fungus': $i).
% 28.89/28.99  tff(decl_25412, type, 'club-fungus': $i).
% 28.89/28.99  tff(decl_25413, type, fn_club_fungus_1: $i > $i).
% 28.89/28.99  tff(decl_25414, type, clumping_1: $i > $o).
% 28.89/28.99  tff(decl_25415, type, 'Clumping': $i).
% 28.89/28.99  tff(decl_25416, type, 'A type of population dispersion in which groups are clustered in defined spaces rather than randomly dispersed.': $i).
% 28.89/28.99  tff(decl_25417, type, clump: $i).
% 28.89/28.99  tff(decl_25418, type, clumping: $i).
% 28.89/28.99  tff(decl_25419, type, 'CML': $i).
% 28.89/28.99  tff(decl_25420, type, 'CML is an acronym for chronic myelogenous leukemia, a type of cancer associated with reciprocal chromosomal translocations in developing white blood cells.': $i).
% 28.89/28.99  tff(decl_25421, type, 'chronic myelogenous leukemia': $i).
% 28.89/28.99  tff(decl_25422, type, 'chronic-myelogenous-leukemia': $i).
% 28.89/28.99  tff(decl_25423, type, 'chronic granulocytic leukemia': $i).
% 28.89/28.99  tff(decl_25424, type, 'chronic-granulocytic-leukemia': $i).
% 28.89/28.99  tff(decl_25425, type, cml: $i).
% 28.89/28.99  tff(decl_25426, type, cnida_1: $i > $o).
% 28.89/28.99  tff(decl_25427, type, 'Cnida': $i).
% 28.89/28.99  tff(decl_25428, type, 'Capsule-like organelle of cnidocyte cells capable of exploding outwards.': $i).
% 28.89/28.99  tff(decl_25429, type, cnida: $i).
% 28.89/28.99  tff(decl_25430, type, 'Cnidaria': $i).
% 28.89/28.99  tff(decl_25431, type, 'A phylum of animals characterized by diploblastic body structure, a two-way gut, and stinging cells (cnidocytes) that are used for defense and prey capture. Cnidarians come in two body forms: a pelagic medusa and a benthic polyp.': $i).
% 28.89/28.99  tff(decl_25432, type, cnidaria: $i).
% 28.89/28.99  tff(decl_25433, type, fn_cnidaria_1: $i > $i).
% 28.89/28.99  tff(decl_25434, type, predation_1: $i > $o).
% 28.89/28.99  tff(decl_25435, type, fn_cnidaria_2: $i > $i).
% 28.89/28.99  tff(decl_25436, type, cnidocyte_1: $i > $o).
% 28.89/28.99  tff(decl_25437, type, fn_cnidaria_3: $i > $i).
% 28.89/28.99  tff(decl_25438, type, fn_cnidaria_4: $i > $i).
% 28.89/28.99  tff(decl_25439, type, digestion_1: $i > $o).
% 28.89/28.99  tff(decl_25440, type, fn_cnidaria_5: $i > $i).
% 28.89/28.99  tff(decl_25441, type, fn_cnidaria_6: $i > $i).
% 28.89/28.99  tff(decl_25442, type, sac_1: $i > $o).
% 28.89/28.99  tff(decl_25443, type, fn_cnidaria_7: $i > $i).
% 28.89/28.99  tff(decl_25444, type, fn_cnidaria_8: $i > $i).
% 28.89/28.99  tff(decl_25445, type, fn_cnidaria_9: $i > $i).
% 28.89/28.99  tff(decl_25446, type, fn_cnidaria_10: $i > $i).
% 28.89/28.99  tff(decl_25447, type, fn_cnidaria_11: $i > $i).
% 28.89/28.99  tff(decl_25448, type, fn_cnidaria_14: $i > $i).
% 28.89/28.99  tff(decl_25449, type, fn_cnidaria_15: $i > $i).
% 28.89/28.99  tff(decl_25450, type, fn_cnidaria_16: $i > $i).
% 28.89/28.99  tff(decl_25451, type, tentacle_1: $i > $o).
% 28.89/28.99  tff(decl_25452, type, fn_cnidaria_17: $i > $i).
% 28.89/28.99  tff(decl_25453, type, fn_cnidaria_18: $i > $i).
% 28.89/28.99  tff(decl_25454, type, fn_cnidaria_19: $i > $i).
% 28.89/28.99  tff(decl_25455, type, gastrodermal_cell_1: $i > $o).
% 28.89/28.99  tff(decl_25456, type, fn_cnidaria_20: $i > $i).
% 28.89/28.99  tff(decl_25457, type, fn_cnidaria_21: $i > $i).
% 28.89/28.99  tff(decl_25458, type, fn_cnidaria_22: $i > $i).
% 28.89/28.99  tff(decl_25459, type, fn_cnidaria_23: $i > $i).
% 28.89/28.99  tff(decl_25460, type, fn_cnidaria_24: $i > $i).
% 28.89/28.99  tff(decl_25461, type, fn_cnidaria_25: $i > $i).
% 28.89/28.99  tff(decl_25462, type, gastrodermis_1: $i > $o).
% 28.89/28.99  tff(decl_25463, type, fn_cnidaria_26: $i > $i).
% 28.89/28.99  tff(decl_25464, type, fn_cnidaria_27: $i > $i).
% 28.89/28.99  tff(decl_25465, type, fn_cnidaria_28: $i > $i).
% 28.89/28.99  tff(decl_25466, type, fn_cnidaria_29: $i > $i).
% 28.89/28.99  tff(decl_25467, type, fn_cnidaria_30: $i > $i).
% 28.89/28.99  tff(decl_25468, type, push_1: $i > $o).
% 28.89/28.99  tff(decl_25469, type, fn_cnidaria_31: $i > $i).
% 28.89/28.99  tff(decl_25470, type, fn_cnidaria_32: $i > $i).
% 28.89/28.99  tff(decl_25471, type, fn_cnidaria_33: $i > $i).
% 28.89/28.99  tff(decl_25472, type, fn_push_2: $i > $i).
% 28.89/28.99  tff(decl_25473, type, fn_push_3: $i > $i).
% 28.89/28.99  tff(decl_25474, type, fn_gastrovascular_cavity_2: $i > $i).
% 28.89/28.99  tff(decl_25475, type, fn_gastrovascular_cavity_1: $i > $i).
% 28.89/28.99  tff(decl_25476, type, fn_gastrodermis_1: $i > $i).
% 28.89/28.99  tff(decl_25477, type, cnidocyte_0: $i).
% 28.89/28.99  tff(decl_25478, type, tentacle_0: $i).
% 28.89/28.99  tff(decl_25479, type, fn_cnidaria_12: $i > $i).
% 28.89/28.99  tff(decl_25480, type, fn_cnidaria_13: $i > $i).
% 28.89/28.99  tff(decl_25481, type, 'Cnidocyte': $i).
% 28.89/28.99  tff(decl_25482, type, 'A specialized cell produced only by animals in the phylum Cnidaria. A cnidocyte contains a capsule (cnida) which in turn contains a coiiled thread (nematocyst) that injects toxins into the flesh of prey and predators. Cnidocytes are distributed on the animal\\s tentacles and, in some cases, the gut; they are used for prey capture, defense, and aggression.': $i).
% 28.89/28.99  tff(decl_25483, type, cnidocyte: $i).
% 28.89/28.99  tff(decl_25484, type, fn_cnidocyte_1: $i > $i).
% 28.89/28.99  tff(decl_25485, type, fn_cnidocyte_2: $i > $i).
% 28.89/28.99  tff(decl_25486, type, fn_cnidocyte_3: $i > $i).
% 28.89/28.99  tff(decl_25487, type, fn_cnidocyte_4: $i > $i).
% 28.89/28.99  tff(decl_25488, type, fn_cnidocyte_5: $i > $i).
% 28.89/28.99  tff(decl_25489, type, 'CO2-Gas': $i).
% 28.89/28.99  tff(decl_25490, type, 'Carbon dioxide gas is the gaseous form of the carbon dioxide. It is easily soluble in water.': $i).
% 28.89/28.99  tff(decl_25491, type, 'gas of co2': $i).
% 28.89/28.99  tff(decl_25492, type, 'co2 gas': $i).
% 28.89/28.99  tff(decl_25493, type, 'co2-gas': $i).
% 28.89/28.99  tff(decl_25494, type, greenhouse_gas_1: $i > $o).
% 28.89/28.99  tff(decl_25495, type, fn_co2_gas_2: $i > $i).
% 28.89/28.99  tff(decl_25496, type, gas_substance_0: $i).
% 28.89/28.99  tff(decl_25497, type, fn_co2_gas_3: $i > $i).
% 28.89/28.99  tff(decl_25498, type, co3_minus_2_1: $i > $o).
% 28.89/28.99  tff(decl_25499, type, 'CO3-Minus-2': $i).
% 28.89/28.99  tff(decl_25500, type, 'The carbonate ion, which forms salts with a variety of cations such as calcium (Ca2+) and iron (Fe2+).': $i).
% 28.89/28.99  tff(decl_25501, type, carbonate: $i).
% 28.89/28.99  tff(decl_25502, type, 'co3 minus 2': $i).
% 28.89/28.99  tff(decl_25503, type, 'co3-minus-2': $i).
% 28.89/28.99  tff(decl_25504, type, fn_co3_minus_2_2: $i > $i).
% 28.89/28.99  tff(decl_25505, type, fn_co3_minus_2_3: $i > $i).
% 28.89/28.99  tff(decl_25506, type, fn_co3_minus_2_4: $i > $i).
% 28.89/28.99  tff(decl_25507, type, fn_co3_minus_2_5: $i > $i).
% 28.89/28.99  tff(decl_25508, type, fn_co3_minus_2_1: $i > $i).
% 28.89/28.99  tff(decl_25509, type, fn_co3_minus_2_6: $i > $i).
% 28.89/28.99  tff(decl_25510, type, coal_1: $i > $o).
% 28.89/28.99  tff(decl_25511, type, 'Coal': $i).
% 28.89/28.99  tff(decl_25512, type, 'A compressed, solid form of fossil fuel formed from the remains of organisms that died hundreds of millions of years ago.': $i).
% 28.89/28.99  tff(decl_25513, type, coal: $i).
% 28.89/28.99  tff(decl_25514, type, coastal_ecosystem_1: $i > $o).
% 28.89/28.99  tff(decl_25515, type, 'Coastal-Ecosystem': $i).
% 28.89/28.99  tff(decl_25516, type, 'An ecosystem where land meets the sea.': $i).
% 28.89/28.99  tff(decl_25517, type, 'coastal region': $i).
% 28.89/28.99  tff(decl_25518, type, 'coastal-region': $i).
% 28.89/28.99  tff(decl_25519, type, 'coastal ecosystem': $i).
% 28.89/28.99  tff(decl_25520, type, 'coastal-ecosystem': $i).
% 28.89/28.99  tff(decl_25521, type, terrestrial_ecosystem_1: $i > $o).
% 28.89/28.99  tff(decl_25522, type, fn_coastal_ecosystem_2: $i > $i).
% 28.89/28.99  tff(decl_25523, type, fn_coastal_ecosystem_3: $i > $i).
% 28.89/28.99  tff(decl_25524, type, fn_coastal_ecosystem_5: $i > $i).
% 28.89/28.99  tff(decl_25525, type, fn_coastal_ecosystem_7: $i > $i).
% 28.89/28.99  tff(decl_25526, type, fn_coastal_ecosystem_8: $i > $i).
% 28.89/28.99  tff(decl_25527, type, fn_coastal_ecosystem_10: $i > $i).
% 28.89/28.99  tff(decl_25528, type, fn_coastal_ecosystem_11: $i > $i).
% 28.89/28.99  tff(decl_25529, type, fn_coastal_ecosystem_12: $i > $i).
% 28.89/28.99  tff(decl_25530, type, fn_coastal_ecosystem_13: $i > $i).
% 28.89/28.99  tff(decl_25531, type, fn_coastal_ecosystem_15: $i > $i).
% 28.89/28.99  tff(decl_25532, type, fn_coastal_ecosystem_16: $i > $i).
% 28.89/28.99  tff(decl_25533, type, fn_coastal_ecosystem_17: $i > $i).
% 28.89/28.99  tff(decl_25534, type, fn_coastal_ecosystem_18: $i > $i).
% 28.89/28.99  tff(decl_25535, type, fn_coastal_ecosystem_19: $i > $i).
% 28.89/28.99  tff(decl_25536, type, cool_1: $i > $o).
% 28.89/28.99  tff(decl_25537, type, fn_coastal_ecosystem_20: $i > $i).
% 28.89/28.99  tff(decl_25538, type, fn_water_body_6: $i > $i).
% 28.89/28.99  tff(decl_25539, type, fn_water_17: $i > $i).
% 28.89/28.99  tff(decl_25540, type, fn_water_18: $i > $i).
% 28.89/28.99  tff(decl_25541, type, fn_cool_1: $i > $i).
% 28.89/28.99  tff(decl_25542, type, fn_cool_4: $i > $i).
% 28.89/28.99  tff(decl_25543, type, fn_heat_4: $i > $i).
% 28.89/28.99  tff(decl_25544, type, heat_0: $i).
% 28.89/28.99  tff(decl_25545, type, water_body_0: $i).
% 28.89/28.99  tff(decl_25546, type, fn_coastal_ecosystem_14: $i > $i).
% 28.89/28.99  tff(decl_25547, type, 'Coat-Protein': $i).
% 28.89/28.99  tff(decl_25548, type, 'The proteins which make up the outer coat of a virus, coated vesicles and other membrane-bound structures.': $i).
% 28.89/28.99  tff(decl_25549, type, 'protein of coat': $i).
% 28.89/28.99  tff(decl_25550, type, 'coat protein': $i).
% 28.89/28.99  tff(decl_25551, type, 'coat-protein': $i).
% 28.89/28.99  tff(decl_25552, type, coated_pit_1: $i > $o).
% 28.89/28.99  tff(decl_25553, type, 'Coated-Pit': $i).
% 28.89/28.99  tff(decl_25554, type, 'A cell surface depression that is coated with clathrin on its cytoplasmic surface and functions in receptor-mediated endocytosis.': $i).
% 28.89/28.99  tff(decl_25555, type, 'coated pit': $i).
% 28.89/28.99  tff(decl_25556, type, 'coated-pit': $i).
% 28.89/28.99  tff(decl_25557, type, fn_coated_pit_1: $i > $i).
% 28.89/28.99  tff(decl_25558, type, fn_coated_pit_2: $i > $i).
% 28.89/28.99  tff(decl_25559, type, fn_coated_pit_3: $i > $i).
% 28.89/28.99  tff(decl_25560, type, receptor_mediated_endocytosis_1: $i > $o).
% 28.89/28.99  tff(decl_25561, type, fn_coated_pit_4: $i > $i).
% 28.89/28.99  tff(decl_25562, type, fn_coated_pit_5: $i > $i).
% 28.89/28.99  tff(decl_25563, type, protein_layer_1: $i > $o).
% 28.89/28.99  tff(decl_25564, type, fn_protein_layer_1: $i > $i).
% 28.89/28.99  tff(decl_25565, type, fn_endocytosis_13: $i > $i).
% 28.89/28.99  tff(decl_25566, type, fn_receptor_mediated_endocytosis_96: $i > $i).
% 28.89/28.99  tff(decl_25567, type, fn_endocytosis_25: $i > $i).
% 28.89/28.99  tff(decl_25568, type, fn_endocytosis_18: $i > $i).
% 28.89/28.99  tff(decl_25569, type, coated_vesicle_1: $i > $o).
% 28.89/28.99  tff(decl_25570, type, 'Coated-Vesicle': $i).
% 28.89/28.99  tff(decl_25571, type, 'Coated-vesicle is formed as a result of intake of a receptor bound molecule by the process of pinocytosis. It bears the receptor bound molecule on its surface.': $i).
% 28.89/28.99  tff(decl_25572, type, 'coated vesicle': $i).
% 28.89/28.99  tff(decl_25573, type, 'coated-vesicle': $i).
% 28.89/28.99  tff(decl_25574, type, fn_coated_vesicle_1: $i > $i).
% 28.89/28.99  tff(decl_25575, type, fn_coated_vesicle_2: $i > $i).
% 28.89/28.99  tff(decl_25576, type, fn_coated_vesicle_3: $i > $i).
% 28.89/28.99  tff(decl_25577, type, fn_coated_vesicle_4: $i > $i).
% 28.89/28.99  tff(decl_25578, type, fn_coated_vesicle_5: $i > $i).
% 28.89/28.99  tff(decl_25579, type, fn_coated_vesicle_6: $i > $i).
% 28.89/28.99  tff(decl_25580, type, fn_receptor_mediated_endocytosis_85: $i > $i).
% 28.89/28.99  tff(decl_25581, type, fn_receptor_mediated_endocytosis_10: $i > $i).
% 28.89/28.99  tff(decl_25582, type, fn_endocytosis_21: $i > $i).
% 28.89/28.99  tff(decl_25583, type, fn_receptor_mediated_endocytosis_86: $i > $i).
% 28.89/28.99  tff(decl_25584, type, cobalt_1: $i > $o).
% 28.89/28.99  tff(decl_25585, type, 'Cobalt': $i).
% 28.89/28.99  tff(decl_25586, type, 'Cobalt is a metal atom with atomic number 27. It is represented by the symbol Co.': $i).
% 28.89/28.99  tff(decl_25587, type, cobalt: $i).
% 28.89/28.99  tff(decl_25588, type, 'Co': $i).
% 28.89/28.99  tff(decl_25589, type, fn_cobalt_3: $i > $i).
% 28.89/28.99  tff(decl_25590, type, fn_cobalt_4: $i > $i).
% 28.89/28.99  tff(decl_25591, type, fn_cobalt_5: $i > $i).
% 28.89/28.99  tff(decl_25592, type, fn_cobalt_9: $i > $i).
% 28.89/28.99  tff(decl_25593, type, fn_cobalt_10: $i > $i).
% 28.89/28.99  tff(decl_25594, type, fn_cobalt_11: $i > $i).
% 28.89/28.99  tff(decl_25595, type, fn_cobalt_12: $i > $i).
% 28.89/28.99  tff(decl_25596, type, "1.88": $i).
% 28.89/28.99  tff(decl_25597, type, "59": $i).
% 28.89/28.99  tff(decl_25598, type, "58.93": $i).
% 28.89/28.99  tff(decl_25599, type, fn_cobalt_7: $i > $i).
% 28.89/28.99  tff(decl_25600, type, fn_cobalt_8: $i > $i).
% 28.89/28.99  tff(decl_25601, type, fn_cobalt_6: $i > $i).
% 28.89/28.99  tff(decl_25602, type, coccus_1: $i > $o).
% 28.89/28.99  tff(decl_25603, type, 'Coccus': $i).
% 28.89/28.99  tff(decl_25604, type, 'A bacterium with a spherical shape.': $i).
% 28.89/28.99  tff(decl_25605, type, coccus: $i).
% 28.89/28.99  tff(decl_25606, type, heterocyte_1: $i > $o).
% 28.89/28.99  tff(decl_25607, type, proteobacteria_1: $i > $o).
% 28.89/28.99  tff(decl_25608, type, spirochete_1: $i > $o).
% 28.89/28.99  tff(decl_25609, type, 'Cochlea': $i).
% 28.89/28.99  tff(decl_25610, type, 'A portion of the inner ear that resembles a coiled snail shell and is the organ of hearing in mammals.': $i).
% 28.89/28.99  tff(decl_25611, type, cochlea: $i).
% 28.89/28.99  tff(decl_25612, type, cockroach_1: $i > $o).
% 28.89/28.99  tff(decl_25613, type, 'Cockroach': $i).
% 28.89/28.99  tff(decl_25614, type, 'An insect in the order Blattaria.': $i).
% 28.89/28.99  tff(decl_25615, type, cockroach: $i).
% 28.89/28.99  tff(decl_25616, type, cricket_1: $i > $o).
% 28.89/28.99  tff(decl_25617, type, grasshopper_1: $i > $o).
% 28.89/28.99  tff(decl_25618, type, cocoon_1: $i > $o).
% 28.89/28.99  tff(decl_25619, type, 'Cocoon': $i).
% 28.89/28.99  tff(decl_25620, type, 'A casing made by insect larva.': $i).
% 28.89/28.99  tff(decl_25621, type, cocoon: $i).
% 28.89/28.99  tff(decl_25622, type, fn_cocoon_1: $i > $i).
% 28.89/28.99  tff(decl_25623, type, structural_protein_1: $i > $o).
% 28.89/28.99  tff(decl_25624, type, cod_liver_oil_1: $i > $o).
% 28.89/28.99  tff(decl_25625, type, 'Cod-Liver-Oil': $i).
% 28.89/28.99  tff(decl_25626, type, 'Cod liver oil is a nutritional supplement derived from liver of cod fish. It has high levels of the omega-3 fatty acids, EPA and DHA, and very high levels of vitamin A and vitamin D.': $i).
% 28.89/28.99  tff(decl_25627, type, 'cod liver oil': $i).
% 28.89/28.99  tff(decl_25628, type, 'cod-liver-oil': $i).
% 28.89/28.99  tff(decl_25629, type, fish_fat_1: $i > $o).
% 28.89/28.99  tff(decl_25630, type, 'Code-For': $i).
% 28.89/28.99  tff(decl_25631, type, 'information, in form of a code': $i).
% 28.89/28.99  tff(decl_25632, type, encode: $i).
% 28.89/28.99  tff(decl_25633, type, 'code for': $i).
% 28.89/28.99  tff(decl_25634, type, 'code-for': $i).
% 28.89/28.99  tff(decl_25635, type, fn_code_for_1: $i > $i).
% 28.89/28.99  tff(decl_25636, type, coding_for_amino_acid_1: $i > $o).
% 28.89/28.99  tff(decl_25637, type, 'Coding-For-Amino-Acid': $i).
% 28.89/28.99  tff(decl_25638, type, 'A tri-nucleotide sequence, called a codon, that specifies a particular amino acid.': $i).
% 28.89/28.99  tff(decl_25639, type, code: $i).
% 28.89/28.99  tff(decl_25640, type, 'coding for amino acid': $i).
% 28.89/28.99  tff(decl_25641, type, 'coding-for-amino-acid': $i).
% 28.89/28.99  tff(decl_25642, type, fn_coding_for_amino_acid_1: $i > $i).
% 28.89/28.99  tff(decl_25643, type, fn_coding_for_amino_acid_2: $i > $i).
% 28.89/28.99  tff(decl_25644, type, fn_coding_for_amino_acid_3: $i > $i).
% 28.89/28.99  tff(decl_25645, type, fn_coding_for_amino_acid_4: $i > $i).
% 28.89/28.99  tff(decl_25646, type, fn_coding_for_amino_acid_6: $i > $i).
% 28.89/28.99  tff(decl_25647, type, 'Qn': $i).
% 28.89/28.99  tff(decl_25648, type, 'Qa': $i).
% 28.89/28.99  tff(decl_25649, type, coding_segment_1: $i > $o).
% 28.89/28.99  tff(decl_25650, type, 'Coding-segment': $i).
% 28.89/28.99  tff(decl_25651, type, 'Coding segment is a sequence of ribonucleotides on mRNA which serves as the template for synthesis of a polypeptide/protein': $i).
% 28.89/28.99  tff(decl_25652, type, 'coding-segment': $i).
% 28.89/28.99  tff(decl_25653, type, 'coding segment': $i).
% 28.89/28.99  tff(decl_25654, type, 'segment of coding': $i).
% 28.89/28.99  tff(decl_25655, type, rna_sequence_1: $i > $o).
% 28.89/28.99  tff(decl_25656, type, leader_segment_1: $i > $o).
% 28.89/28.99  tff(decl_25657, type, telomere_with_3_prime_overhang_1: $i > $o).
% 28.89/28.99  tff(decl_25658, type, terminator_sequence_1: $i > $o).
% 28.89/28.99  tff(decl_25659, type, 'Codominance': $i).
% 28.89/28.99  tff(decl_25660, type, 'The situation in which the phenotypes of both alleles are exhibited in the heterozygote because both alleles affect the phenotype in separate, distinguishable ways.': $i).
% 28.89/28.99  tff(decl_25661, type, codominate: $i).
% 28.89/28.99  tff(decl_25662, type, codominance: $i).
% 28.89/28.99  tff(decl_25663, type, fn_codominance_1: $i > $i).
% 28.89/28.99  tff(decl_25664, type, fn_codominance_2: $i > $i).
% 28.89/28.99  tff(decl_25665, type, fn_codominance_3: $i > $i).
% 28.89/28.99  tff(decl_25666, type, fn_codominance_4: $i > $i).
% 28.89/28.99  tff(decl_25667, type, fn_codominance_5: $i > $i).
% 28.89/28.99  tff(decl_25668, type, fn_codominance_6: $i > $i).
% 28.89/28.99  tff(decl_25669, type, fn_codominance_7: $i > $i).
% 28.89/28.99  tff(decl_25670, type, fn_codominance_8: $i > $i).
% 28.89/28.99  tff(decl_25671, type, fn_phenotype_1: $i > $i).
% 28.89/28.99  tff(decl_25672, type, trait_1: $i > $o).
% 28.89/28.99  tff(decl_25673, type, codominance_cross_breeding_event_1: $i > $o).
% 28.89/28.99  tff(decl_25674, type, 'Codominance-Cross-Breeding-Event': $i).
% 28.89/28.99  tff(decl_25675, type, 'Mating of two individuals, with expression of codominant alleles being investigated.': $i).
% 28.89/28.99  tff(decl_25676, type, crossbreed: $i).
% 28.89/28.99  tff(decl_25677, type, 'codominance cross breeding event': $i).
% 28.89/28.99  tff(decl_25678, type, 'codominance-cross-breeding-event': $i).
% 28.89/28.99  tff(decl_25679, type, complete_dominance_cross_breeding_event_1: $i > $o).
% 28.89/28.99  tff(decl_25680, type, homozygous_dominant_cross_1: $i > $o).
% 28.89/28.99  tff(decl_25681, type, homozygous_recessive_cross_1: $i > $o).
% 28.89/28.99  tff(decl_25682, type, hybridization_1: $i > $o).
% 28.89/28.99  tff(decl_25683, type, incomplete_dominance_cross_breeding_event_1: $i > $o).
% 28.89/28.99  tff(decl_25684, type, sex_linkage_cross_breeding_event_1: $i > $o).
% 28.89/28.99  tff(decl_25685, type, fn_codominance_cross_breeding_event_1: $i > $i).
% 28.89/28.99  tff(decl_25686, type, fn_cross_breeding_event_6: $i > $i).
% 28.89/28.99  tff(decl_25687, type, 'Codominant': $i).
% 28.89/28.99  tff(decl_25688, type, 'The heterozygous condition in which the phenotypes of both alleles are exhibited in the heterozygote because both alleles affect the phenotype in separate, distinguishable ways.': $i).
% 28.89/28.99  tff(decl_25689, type, 'heterozygous trait codominance': $i).
% 28.89/28.99  tff(decl_25690, type, 'heterozygous-trait-codominance': $i).
% 28.89/28.99  tff(decl_25691, type, codominant: $i).
% 28.89/28.99  tff(decl_25692, type, fn_codominant_1: $i > $i).
% 28.89/28.99  tff(decl_25693, type, fn_codominant_2: $i > $i).
% 28.89/28.99  tff(decl_25694, type, fn_codominant_3: $i > $i).
% 28.89/28.99  tff(decl_25695, type, 'Codon': $i).
% 28.89/28.99  tff(decl_25696, type, 'A three-nucleotide sequence of DNA or mRNA that specifies a particular amino acid or termination signal; the basic unit of the genetic code.': $i).
% 28.89/28.99  tff(decl_25697, type, 'A group of three consecutive nucleotides of DNA or mRNA that codes for either a specific amino acid or a signal to end translation.': $i).
% 28.89/28.99  tff(decl_25698, type, 'nucleotide triplet': $i).
% 28.89/28.99  tff(decl_25699, type, codon: $i).
% 28.89/28.99  tff(decl_25700, type, nucleic_acid_sequence_1: $i > $o).
% 28.89/28.99  tff(decl_25701, type, fn_codon_1: $i > $i).
% 28.89/28.99  tff(decl_25702, type, fn_codon_2: $i > $i).
% 28.89/28.99  tff(decl_25703, type, fn_nucleic_acid_sequence_6: $i > $i).
% 28.89/28.99  tff(decl_25704, type, fn_nucleic_acid_sequence_5: $i > $i).
% 28.89/28.99  tff(decl_25705, type, rna_codon_1: $i > $o).
% 28.89/28.99  tff(decl_25706, type, fn_codon_recognition_7: $i > $i).
% 28.89/28.99  tff(decl_25707, type, 'Codon-Recognition': $i).
% 28.89/28.99  tff(decl_25708, type, 'Codon recognition is the process of attachment of an anticodon, which is part of a tRNA to its complementary codon, the codon being part of mRNA': $i).
% 28.89/28.99  tff(decl_25709, type, 'recognition of codon': $i).
% 28.89/28.99  tff(decl_25710, type, 'codon recognition': $i).
% 28.89/28.99  tff(decl_25711, type, 'codon-recognition': $i).
% 28.89/28.99  tff(decl_25712, type, compare_genes_1: $i > $o).
% 28.89/28.99  tff(decl_25713, type, distinguishing_defective_chromosome_1: $i > $o).
% 28.89/28.99  tff(decl_25714, type, dna_proofreading_1: $i > $o).
% 28.89/28.99  tff(decl_25715, type, identify_cell_by_protein_expression_1: $i > $o).
% 28.89/28.99  tff(decl_25716, type, fn_codon_recognition_1: $i > $i).
% 28.89/28.99  tff(decl_25717, type, fn_codon_recognition_4: $i > $i).
% 28.89/28.99  tff(decl_25718, type, elongation_factor_1: $i > $o).
% 28.89/28.99  tff(decl_25719, type, fn_codon_recognition_5: $i > $i).
% 28.89/28.99  tff(decl_25720, type, fn_codon_recognition_10: $i > $i).
% 28.89/28.99  tff(decl_25721, type, fn_codon_recognition_12: $i > $i).
% 28.89/28.99  tff(decl_25722, type, gtp_0: $i).
% 28.89/28.99  tff(decl_25723, type, 'Coefficient-Value': $i).
% 28.89/28.99  tff(decl_25724, type, 'a quantity (usually a numerical constant) which is multiplied by another quantity following it in an expression; e.g. in the algebraic expression 4 x 2 - 6 x, the coefficient of (the first term) x 2 is 4 and the coefficient of (the second term) x is -6.': $i).
% 28.89/28.99  tff(decl_25725, type, coefficient: $i).
% 28.89/28.99  tff(decl_25726, type, 'value of coefficient': $i).
% 28.89/28.99  tff(decl_25727, type, 'coefficient value': $i).
% 28.89/28.99  tff(decl_25728, type, 'coefficient-value': $i).
% 28.89/28.99  tff(decl_25729, type, coelocanth_1: $i > $o).
% 28.89/28.99  tff(decl_25730, type, 'Coelocanth': $i).
% 28.89/28.99  tff(decl_25731, type, 'Either of two living species of a single genus of lobe-finned fish.': $i).
% 28.89/28.99  tff(decl_25732, type, coelocanth: $i).
% 28.89/28.99  tff(decl_25733, type, 'Coelom': $i).
% 28.89/28.99  tff(decl_25734, type, 'An internal fluid-filled body cavity lined with mesodermal tissue.': $i).
% 28.89/28.99  tff(decl_25735, type, coelom: $i).
% 28.89/28.99  tff(decl_25736, type, 'Coenocytic-Fungus': $i).
% 28.89/28.99  tff(decl_25737, type, 'A fungus that lacks septa and whose mycelium thus consists of a continuous mass of cytoplasm that may contain hundreds of nuclei.': $i).
% 28.89/28.99  tff(decl_25738, type, 'coenocytic fungus': $i).
% 28.89/28.99  tff(decl_25739, type, 'coenocytic-fungus': $i).
% 29.20/28.99  tff(decl_25740, type, fn_coenocytic_fungus_1: $i > $i).
% 29.20/28.99  tff(decl_25741, type, coenzyme_1: $i > $o).
% 29.20/28.99  tff(decl_25742, type, 'Coenzyme': $i).
% 29.20/28.99  tff(decl_25743, type, 'Coenzymes are organic compounds required for the activity of some enzymes; most are derived from vitamins. Coenzymes that remain tightly bound to the enzyme at all times are sometimes known as prosthetic groups; non-protein components of the enzyme molecule.': $i).
% 29.20/28.99  tff(decl_25744, type, coenzyme: $i).
% 29.20/28.99  tff(decl_25745, type, corepressor_1: $i > $o).
% 29.20/28.99  tff(decl_25746, type, prosthetic_group_1: $i > $o).
% 29.20/28.99  tff(decl_25747, type, fn_coenzyme_1: $i > $i).
% 29.20/28.99  tff(decl_25748, type, 'Coenzyme-A': $i).
% 29.20/28.99  tff(decl_25749, type, 'Coenzyme A (CoA, CoASH, or HSCoA) is a coenzyme, notable for its role in the synthesis and oxidation of fatty acids, and the oxidation of pyruvate in the citric acid cycle.': $i).
% 29.20/28.99  tff(decl_25750, type, 's coa': $i).
% 29.20/28.99  tff(decl_25751, type, 's-coa': $i).
% 29.20/28.99  tff(decl_25752, type, 'coenzyme a': $i).
% 29.20/28.99  tff(decl_25753, type, 'coenzyme-a': $i).
% 29.20/28.99  tff(decl_25754, type, fn_coenzyme_a_1: $i > $i).
% 29.20/28.99  tff(decl_25755, type, vitamin_b5_1: $i > $o).
% 29.20/28.99  tff(decl_25756, type, fn_coenzyme_a_4: $i > $i).
% 29.20/28.99  tff(decl_25757, type, fn_coenzyme_a_5: $i > $i).
% 29.20/28.99  tff(decl_25758, type, fn_coenzyme_a_6: $i > $i).
% 29.20/28.99  tff(decl_25759, type, fn_coenzyme_a_7: $i > $i).
% 29.20/28.99  tff(decl_25760, type, fn_coenzyme_a_8: $i > $i).
% 29.20/28.99  tff(decl_25761, type, fn_coenzyme_a_9: $i > $i).
% 29.20/28.99  tff(decl_25762, type, fn_coenzyme_a_10: $i > $i).
% 29.20/28.99  tff(decl_25763, type, fn_coenzyme_a_11: $i > $i).
% 29.20/28.99  tff(decl_25764, type, sulfhydryl_group_1: $i > $o).
% 29.20/28.99  tff(decl_25765, type, fn_coenzyme_a_12: $i > $i).
% 29.20/28.99  tff(decl_25766, type, fn_coenzyme_a_3: $i > $i).
% 29.20/28.99  tff(decl_25767, type, fn_coenzyme_a_2: $i > $i).
% 29.20/28.99  tff(decl_25768, type, 'Cofactor': $i).
% 29.20/28.99  tff(decl_25769, type, 'Any nonprotein molecule or ion that is required for the proper functioning of an enzyme. Cofactors can be permanently bound to the active site or may bind loosely with the substrate during catalysis.': $i).
% 29.20/28.99  tff(decl_25770, type, cofactor: $i).
% 29.20/28.99  tff(decl_25771, type, instrument_role_1: $i > $o).
% 29.20/28.99  tff(decl_25772, type, fn_instrument_role_1: $i > $i).
% 29.20/28.99  tff(decl_25773, type, cognition_1: $i > $o).
% 29.20/28.99  tff(decl_25774, type, 'Cognition': $i).
% 29.20/28.99  tff(decl_25775, type, 'A group of mental processes including production and understanding of language, memory, learning, problem solving, reasoning, and decision making.': $i).
% 29.20/28.99  tff(decl_25776, type, cognition: $i).
% 29.20/28.99  tff(decl_25777, type, learned_behavior_1: $i > $o).
% 29.20/28.99  tff(decl_25778, type, cognitive_activity_1: $i > $o).
% 29.20/28.99  tff(decl_25779, type, 'Cognitive-Activity': $i).
% 29.20/28.99  tff(decl_25780, type, 'Activities related to the information processing abilities of humans.': $i).
% 29.20/28.99  tff(decl_25781, type, 'cognitive activity': $i).
% 29.20/28.99  tff(decl_25782, type, 'cognitive-activity': $i).
% 29.20/28.99  tff(decl_25783, type, 'Cognitive-Map': $i).
% 29.20/28.99  tff(decl_25784, type, 'A representation in the brain of the spatial relationships between objects in an animal\\s environment.': $i).
% 29.20/28.99  tff(decl_25785, type, 'cognitive map': $i).
% 29.20/28.99  tff(decl_25786, type, 'cognitive-map': $i).
% 29.20/28.99  tff(decl_25787, type, cohesin_1: $i > $o).
% 29.20/28.99  tff(decl_25788, type, 'Cohesin': $i).
% 29.20/28.99  tff(decl_25789, type, 'A protein complex which attaches sister chromatids to each other during cell division.': $i).
% 29.20/28.99  tff(decl_25790, type, cohesin: $i).
% 29.20/28.99  tff(decl_25791, type, 'Cohesion': $i).
% 29.20/28.99  tff(decl_25792, type, 'The binding together of like molecules, often by hydrogen bonds.': $i).
% 29.20/28.99  tff(decl_25793, type, cohere: $i).
% 29.20/28.99  tff(decl_25794, type, cohesion: $i).
% 29.20/28.99  tff(decl_25795, type, fn_cohesion_1: $i > $i).
% 29.20/28.99  tff(decl_25796, type, fn_cohesion_2: $i > $i).
% 29.20/28.99  tff(decl_25797, type, fn_cohesion_3: $i > $i).
% 29.20/28.99  tff(decl_25798, type, cohort_1: $i > $o).
% 29.20/28.99  tff(decl_25799, type, 'Cohort': $i).
% 29.20/28.99  tff(decl_25800, type, 'In demographics, a group of individuals experiencing the same events at the same time.': $i).
% 29.20/28.99  tff(decl_25801, type, cohort: $i).
% 29.20/28.99  tff(decl_25802, type, ecological_grouping_1: $i > $o).
% 29.20/28.99  tff(decl_25803, type, 'Coil': $i).
% 29.20/28.99  tff(decl_25804, type, 'A coil is a series of loops. A coiled coil is a structure where the coil itself is in turn also looping.': $i).
% 29.20/28.99  tff(decl_25805, type, wrap: $i).
% 29.20/28.99  tff(decl_25806, type, coil: $i).
% 29.20/28.99  tff(decl_25807, type, coitus_1: $i > $o).
% 29.20/28.99  tff(decl_25808, type, 'Coitus': $i).
% 29.20/28.99  tff(decl_25809, type, 'Sexual intercourse between a male and a female, involving the insertion of a penis into a vagina.': $i).
% 29.20/28.99  tff(decl_25810, type, coitus: $i).
% 29.20/28.99  tff(decl_25811, type, cold_1: $i > $o).
% 29.20/28.99  tff(decl_25812, type, 'Cold': $i).
% 29.20/28.99  tff(decl_25813, type, 'Condition involving the absence of heat.': $i).
% 29.20/28.99  tff(decl_25814, type, condition: $i).
% 29.20/28.99  tff(decl_25815, type, cold: $i).
% 29.20/28.99  tff(decl_25816, type, 'Coleoptera': $i).
% 29.20/28.99  tff(decl_25817, type, 'Order of the class Insecta having two pairs of wings and an armored exoskeleton.': $i).
% 29.20/28.99  tff(decl_25818, type, beetles: $i).
% 29.20/28.99  tff(decl_25819, type, coleoptera: $i).
% 29.20/28.99  tff(decl_25820, type, 'Coleoptile': $i).
% 29.20/28.99  tff(decl_25821, type, 'In monocots, the protective sheath covering an emerging shoot.': $i).
% 29.20/28.99  tff(decl_25822, type, coleoptile: $i).
% 29.20/28.99  tff(decl_25823, type, 'Coleorhiza': $i).
% 29.20/28.99  tff(decl_25824, type, 'In monocots, the protective covering of an emerging root.': $i).
% 29.20/28.99  tff(decl_25825, type, coleorhiza: $i).
% 29.20/28.99  tff(decl_25826, type, 'Collagen': $i).
% 29.20/28.99  tff(decl_25827, type, 'The most abundant glycoprotein found in many animal tissues located in the extracellular matrix. Collagen forms strong fibers.': $i).
% 29.20/28.99  tff(decl_25828, type, collagen: $i).
% 29.20/28.99  tff(decl_25829, type, fibrous_protein_1: $i > $o).
% 29.20/28.99  tff(decl_25830, type, 'Collecting': $i).
% 29.20/28.99  tff(decl_25831, type, gather: $i).
% 29.20/28.99  tff(decl_25832, type, collect: $i).
% 29.20/28.99  tff(decl_25833, type, accumulate: $i).
% 29.20/28.99  tff(decl_25834, type, amass: $i).
% 29.20/28.99  tff(decl_25835, type, compile: $i).
% 29.20/28.99  tff(decl_25836, type, garner: $i).
% 29.20/28.99  tff(decl_25837, type, collection: $i).
% 29.20/28.99  tff(decl_25838, type, collecting: $i).
% 29.20/28.99  tff(decl_25839, type, assembling: $i).
% 29.20/28.99  tff(decl_25840, type, aggregation: $i).
% 29.20/28.99  tff(decl_25841, type, 'Collecting-Duct': $i).
% 29.20/28.99  tff(decl_25842, type, 'In the kidney, a system of tubules and ducts connecting the nephrons to the ureter.  It is involved in salt and fluid balance.': $i).
% 29.20/28.99  tff(decl_25843, type, 'duct of collecting': $i).
% 29.20/28.99  tff(decl_25844, type, 'collecting duct': $i).
% 29.20/28.99  tff(decl_25845, type, 'collecting-duct': $i).
% 29.20/28.99  tff(decl_25846, type, duct_1: $i > $o).
% 29.20/28.99  tff(decl_25847, type, cuboidal_epithelium_1: $i > $o).
% 29.20/28.99  tff(decl_25848, type, 'Collenchyma-Cell': $i).
% 29.20/28.99  tff(decl_25849, type, 'Type of elongate plant cell that has irregularly thickened walls and provides structural support for growing stems and leaves.': $i).
% 29.20/28.99  tff(decl_25850, type, 'collenchyma cell': $i).
% 29.20/28.99  tff(decl_25851, type, 'collenchyma-cell': $i).
% 29.20/28.99  tff(decl_25852, type, plant_support_cell_1: $i > $o).
% 29.20/28.99  tff(decl_25853, type, 'Collide': $i).
% 29.20/28.99  tff(decl_25854, type, collide: $i).
% 29.20/28.99  tff(decl_25855, type, clash: $i).
% 29.20/28.99  tff(decl_25856, type, 'collide with': $i).
% 29.20/28.99  tff(decl_25857, type, collide_with: $i).
% 29.20/28.99  tff(decl_25858, type, hit: $i).
% 29.20/28.99  tff(decl_25859, type, strike: $i).
% 29.20/28.99  tff(decl_25860, type, 'impinge on': $i).
% 29.20/28.99  tff(decl_25861, type, impinge_on: $i).
% 29.20/28.99  tff(decl_25862, type, 'run into': $i).
% 29.20/28.99  tff(decl_25863, type, run_into: $i).
% 29.20/28.99  tff(decl_25864, type, 'cause to collide': $i).
% 29.20/28.99  tff(decl_25865, type, colloblast_1: $i > $o).
% 29.20/28.99  tff(decl_25866, type, 'Colloblast': $i).
% 29.20/28.99  tff(decl_25867, type, 'Adhesive cell produced only by animals of the phylum Ctenophora. Colloblasts are located on the tentacles of ctenophores and are used in prey capture. Unlike cnidocytes, colloblasts do not inject toxins.': $i).
% 29.20/28.99  tff(decl_25868, type, 'lasso cells': $i).
% 29.20/28.99  tff(decl_25869, type, 'lasso-cells': $i).
% 29.20/28.99  tff(decl_25870, type, colloblast: $i).
% 29.20/28.99  tff(decl_25871, type, 'Colloid': $i).
% 29.20/28.99  tff(decl_25872, type, 'A stable solution of fine particles in a liquid.': $i).
% 29.20/28.99  tff(decl_25873, type, colloid: $i).
% 29.20/28.99  tff(decl_25874, type, fn_colloid_1: $i > $i).
% 29.20/28.99  tff(decl_25875, type, fn_colloid_2: $i > $i).
% 29.20/28.99  tff(decl_25876, type, fn_colloid_5: $i > $i).
% 29.20/28.99  tff(decl_25877, type, fn_colloid_6: $i > $i).
% 29.20/28.99  tff(decl_25878, type, colon_1: $i > $o).
% 29.20/28.99  tff(decl_25879, type, 'Colon': $i).
% 29.20/28.99  tff(decl_25880, type, 'The most distal section of the vertebrate digestive tract; functions in the absorption of water and formation of feces.': $i).
% 29.20/28.99  tff(decl_25881, type, colon: $i).
% 29.20/28.99  tff(decl_25882, type, fn_colon_1: $i > $i).
% 29.20/28.99  tff(decl_25883, type, colon_cancer_1: $i > $o).
% 29.20/28.99  tff(decl_25884, type, 'Colon-Cancer': $i).
% 29.20/28.99  tff(decl_25885, type, 'Cancer that arises from benign, mushroom-shaped polyps in the large intestine that develop into cancer over time.  It is the fourth most common form of cancer in the United States, and the third leading cause of cancer-related death in the Western world.': $i).
% 29.20/28.99  tff(decl_25886, type, 'colorectal cancer': $i).
% 29.20/28.99  tff(decl_25887, type, 'colorectal-cancer': $i).
% 29.20/28.99  tff(decl_25888, type, crc: $i).
% 29.20/28.99  tff(decl_25889, type, 'bowel cancer': $i).
% 29.20/28.99  tff(decl_25890, type, 'bowel-cancer': $i).
% 29.20/28.99  tff(decl_25891, type, 'large bowel cancer': $i).
% 29.20/28.99  tff(decl_25892, type, 'cancer of colon': $i).
% 29.20/28.99  tff(decl_25893, type, 'colon cancer': $i).
% 29.20/28.99  tff(decl_25894, type, 'colon-cancer': $i).
% 29.20/28.99  tff(decl_25895, type, fn_colon_cancer_1: $i > $i).
% 29.20/28.99  tff(decl_25896, type, dna_repair_1: $i > $o).
% 29.20/28.99  tff(decl_25897, type, fn_colon_cancer_2: $i > $i).
% 29.20/28.99  tff(decl_25898, type, color_blindness_1: $i > $o).
% 29.20/28.99  tff(decl_25899, type, 'Color-Blindness': $i).
% 29.20/28.99  tff(decl_25900, type, 'A sex-linked genetic disorder resulting in the inability to discern one or more colors.': $i).
% 29.20/28.99  tff(decl_25901, type, 'blindness of color': $i).
% 29.20/28.99  tff(decl_25902, type, 'color blindness': $i).
% 29.20/28.99  tff(decl_25903, type, 'color-blindness': $i).
% 29.20/28.99  tff(decl_25904, type, duchenne_muscular_dystrophy_1: $i > $o).
% 29.20/28.99  tff(decl_25905, type, hemophilia_1: $i > $o).
% 29.20/28.99  tff(decl_25906, type, 'Color-Constant': $i).
% 29.20/28.99  tff(decl_25907, type, 'chromatic color': $i).
% 29.20/28.99  tff(decl_25908, type, chromatic_color: $i).
% 29.20/28.99  tff(decl_25909, type, 'constant of color': $i).
% 29.20/28.99  tff(decl_25910, type, 'color constant': $i).
% 29.20/28.99  tff(decl_25911, type, 'color-constant': $i).
% 29.20/28.99  tff(decl_25912, type, 'Color-Value': $i).
% 29.20/28.99  tff(decl_25913, type, 'color is a property for describing a Tangible-Entity\\s colors.': $i).
% 29.20/28.99  tff(decl_25914, type, vividness: $i).
% 29.20/28.99  tff(decl_25915, type, coloring: $i).
% 29.20/28.99  tff(decl_25916, type, colouring: $i).
% 29.20/28.99  tff(decl_25917, type, colour: $i).
% 29.20/28.99  tff(decl_25918, type, color: $i).
% 29.20/28.99  tff(decl_25919, type, 'value of color': $i).
% 29.20/28.99  tff(decl_25920, type, 'color value': $i).
% 29.20/28.99  tff(decl_25921, type, 'color-value': $i).
% 29.20/28.99  tff(decl_25922, type, color_vision_1: $i > $o).
% 29.20/28.99  tff(decl_25923, type, 'Color-Vision': $i).
% 29.20/28.99  tff(decl_25924, type, 'The ability to distinguish between different wavelengths of light that are emitted, refracted, or reflected by objects.': $i).
% 29.20/28.99  tff(decl_25925, type, 'vision of color': $i).
% 29.20/28.99  tff(decl_25926, type, 'color vision': $i).
% 29.20/28.99  tff(decl_25927, type, 'color-vision': $i).
% 29.20/28.99  tff(decl_25928, type, sight_1: $i > $o).
% 29.20/28.99  tff(decl_25929, type, de_etiolation_1: $i > $o).
% 29.20/28.99  tff(decl_25930, type, gustation_1: $i > $o).
% 29.20/28.99  tff(decl_25931, type, lateral_line_system_1: $i > $o).
% 29.20/28.99  tff(decl_25932, type, olfaction_1: $i > $o).
% 29.20/28.99  tff(decl_25933, type, perception_1: $i > $o).
% 29.20/28.99  tff(decl_25934, type, sensation_1: $i > $o).
% 29.20/28.99  tff(decl_25935, type, sensory_reception_1: $i > $o).
% 29.20/28.99  tff(decl_25936, type, touch_1: $i > $o).
% 29.20/28.99  tff(decl_25937, type, coloring_pigment_1: $i > $o).
% 29.20/28.99  tff(decl_25938, type, 'Coloring-pigment': $i).
% 29.20/28.99  tff(decl_25939, type, 'The coloring pigments present in vacuole help to attract pollinating insects to flowers': $i).
% 29.20/28.99  tff(decl_25940, type, 'coloring pigments': $i).
% 29.20/28.99  tff(decl_25941, type, 'pigment of coloring': $i).
% 29.20/28.99  tff(decl_25942, type, 'coloring pigment': $i).
% 29.20/28.99  tff(decl_25943, type, 'coloring-pigment': $i).
% 29.20/28.99  tff(decl_25944, type, 'Columnlike-Epithelium': $i).
% 29.20/28.99  tff(decl_25945, type, 'Epithelial tissue that has a column shape (either simple, stratified, or pseudostratified).': $i).
% 29.20/28.99  tff(decl_25946, type, 'columnar epithelium': $i).
% 29.20/28.99  tff(decl_25947, type, 'columnar-epithelium': $i).
% 29.20/28.99  tff(decl_25948, type, 'columnlike epithelium': $i).
% 29.20/28.99  tff(decl_25949, type, 'columnlike-epithelium': $i).
% 29.20/28.99  tff(decl_25950, type, stratified_squamous_epithelium_1: $i > $o).
% 29.20/28.99  tff(decl_25951, type, transport_epithelium_1: $i > $o).
% 29.20/28.99  tff(decl_25952, type, 'Combine': $i).
% 29.20/28.99  tff(decl_25953, type, 'It refers to getting into a state of unity or to merge.': $i).
% 29.20/28.99  tff(decl_25954, type, combine: $i).
% 29.20/28.99  tff(decl_25955, type, 'Combustion-Of-Fossil-Fuel': $i).
% 29.20/28.99  tff(decl_25956, type, 'The combustion of fossil fuels such as gasoline, coal, and oil to produce energy.': $i).
% 29.20/28.99  tff(decl_25957, type, 'burning of fossil fuel': $i).
% 29.20/28.99  tff(decl_25958, type, burn: $i).
% 29.20/28.99  tff(decl_25959, type, 'combustion of fossil fuel': $i).
% 29.20/28.99  tff(decl_25960, type, 'combustion-of-fossil-fuel': $i).
% 29.20/28.99  tff(decl_25961, type, fn_combustion_of_fossil_fuel_3: $i > $i).
% 29.20/28.99  tff(decl_25962, type, fn_combustion_of_fossil_fuel_5: $i > $i).
% 29.20/28.99  tff(decl_25963, type, fn_combustion_of_fossil_fuel_6: $i > $i).
% 29.20/28.99  tff(decl_25964, type, fn_combustion_of_fossil_fuel_7: $i > $i).
% 29.20/28.99  tff(decl_25965, type, fn_combustion_of_fossil_fuel_8: $i > $i).
% 29.20/28.99  tff(decl_25966, type, fn_combustion_of_fossil_fuel_12: $i > $i).
% 29.20/28.99  tff(decl_25967, type, fn_combustion_of_fossil_fuel_13: $i > $i).
% 29.20/28.99  tff(decl_25968, type, 'Combustion-Reaction': $i).
% 29.20/28.99  tff(decl_25969, type, 'In combustion reactions, a hydrocarbon reacts with oxygen to form carbon dioxide and water.': $i).
% 29.20/28.99  tff(decl_25970, type, burning: $i).
% 29.20/28.99  tff(decl_25971, type, 'reaction of combustion': $i).
% 29.20/28.99  tff(decl_25972, type, 'combustion reaction': $i).
% 29.20/28.99  tff(decl_25973, type, 'combustion-reaction': $i).
% 29.20/28.99  tff(decl_25974, type, 'Come-Together': $i).
% 29.20/28.99  tff(decl_25975, type, assemble: $i).
% 29.20/28.99  tff(decl_25976, type, forgather: $i).
% 29.20/28.99  tff(decl_25977, type, foregather: $i).
% 29.20/28.99  tff(decl_25978, type, associate: $i).
% 29.20/28.99  tff(decl_25979, type, 'come into contact': $i).
% 29.20/28.99  tff(decl_25980, type, 'cause to come together': $i).
% 29.20/28.99  tff(decl_25981, type, 'come together': $i).
% 29.20/28.99  tff(decl_25982, type, 'come-together': $i).
% 29.20/28.99  tff(decl_25983, type, fn_come_together_1: $i > $i).
% 29.20/28.99  tff(decl_25984, type, fn_come_together_2: $i > $i).
% 29.20/28.99  tff(decl_25985, type, fn_come_together_3: $i > $i).
% 29.20/28.99  tff(decl_25986, type, command_1: $i > $o).
% 29.20/28.99  tff(decl_25987, type, 'Command': $i).
% 29.20/28.99  tff(decl_25988, type, command: $i).
% 29.20/28.99  tff(decl_25989, type, require: $i).
% 29.20/28.99  tff(decl_25990, type, compel: $i).
% 29.20/28.99  tff(decl_25991, type, order: $i).
% 29.20/28.99  tff(decl_25992, type, tell: $i).
% 29.20/28.99  tff(decl_25993, type, enjoin: $i).
% 29.20/28.99  tff(decl_25994, type, express_1: $i > $o).
% 29.20/28.99  tff(decl_25995, type, fn_command_1: $i > $i).
% 29.20/28.99  tff(decl_25996, type, commensalism_1: $i > $o).
% 29.20/28.99  tff(decl_25997, type, 'Commensalism': $i).
% 29.20/28.99  tff(decl_25998, type, 'An ecological relationship between two organisms where one benefits and the other is not affected.': $i).
% 29.20/28.99  tff(decl_25999, type, 'show commensalism': $i).
% 29.20/28.99  tff(decl_26000, type, commensalism: $i).
% 29.20/28.99  tff(decl_26001, type, symbiosis_1: $i > $o).
% 29.20/28.99  tff(decl_26002, type, mutualism_1: $i > $o).
% 29.20/28.99  tff(decl_26003, type, committed_cell_1: $i > $o).
% 29.20/28.99  tff(decl_26004, type, 'Committed-Cell': $i).
% 29.20/28.99  tff(decl_26005, type, 'A cell at any point in the process of development is irreversibly committed to its final fate is said to be determined and is called as committed cell.': $i).
% 29.20/28.99  tff(decl_26006, type, 'committed cell': $i).
% 29.20/28.99  tff(decl_26007, type, 'committed-cell': $i).
% 29.20/28.99  tff(decl_26008, type, fn_committed_cell_1: $i > $i).
% 29.20/28.99  tff(decl_26009, type, committee_1: $i > $o).
% 29.20/28.99  tff(decl_26010, type, 'Committee': $i).
% 29.20/28.99  tff(decl_26011, type, committee: $i).
% 29.20/28.99  tff(decl_26012, type, commission: $i).
% 29.20/28.99  tff(decl_26013, type, workgroup_1: $i > $o).
% 29.20/28.99  tff(decl_26014, type, 'Communicate': $i).
% 29.20/28.99  tff(decl_26015, type, 'pass on': $i).
% 29.20/28.99  tff(decl_26016, type, pass_on: $i).
% 29.20/28.99  tff(decl_26017, type, 'put across': $i).
% 29.20/28.99  tff(decl_26018, type, put_across: $i).
% 29.20/28.99  tff(decl_26019, type, intercommunicate: $i).
% 29.20/28.99  tff(decl_26020, type, convey: $i).
% 29.20/28.99  tff(decl_26021, type, transmit: $i).
% 29.20/28.99  tff(decl_26022, type, fn_communicate_2: $i > $i).
% 29.20/28.99  tff(decl_26023, type, fn_communicate_3: $i > $i).
% 29.20/28.99  tff(decl_26024, type, communication_1: $i > $o).
% 29.20/28.99  tff(decl_26025, type, 'Communication': $i).
% 29.20/28.99  tff(decl_26026, type, 'The transmission of information between organisms or between cells within a multicellular organism.': $i).
% 29.20/28.99  tff(decl_26027, type, communication: $i).
% 29.20/28.99  tff(decl_26028, type, communication_by_direct_contact_1: $i > $o).
% 29.20/28.99  tff(decl_26029, type, 'Communication-By-Direct-Contact': $i).
% 29.20/28.99  tff(decl_26030, type, 'Type of cellular communication in which cells interact through surface-molecules or cell junctions.': $i).
% 29.20/28.99  tff(decl_26031, type, 'communication by direct contact': $i).
% 29.20/28.99  tff(decl_26032, type, 'communication-by-direct-contact': $i).
% 29.20/28.99  tff(decl_26033, type, fn_communication_by_direct_contact_1: $i > $i).
% 29.20/28.99  tff(decl_26034, type, fn_communication_by_direct_contact_2: $i > $i).
% 29.20/28.99  tff(decl_26035, type, fn_communication_by_direct_contact_3: $i > $i).
% 29.20/28.99  tff(decl_26036, type, fn_communication_by_direct_contact_4: $i > $i).
% 29.20/28.99  tff(decl_26037, type, fn_communication_by_direct_contact_5: $i > $i).
% 29.20/28.99  tff(decl_26038, type, fn_communication_by_direct_contact_6: $i > $i).
% 29.20/28.99  tff(decl_26039, type, fn_communication_by_direct_contact_7: $i > $i).
% 29.20/28.99  tff(decl_26040, type, fn_communication_by_direct_contact_8: $i > $i).
% 29.20/28.99  tff(decl_26041, type, fn_communication_by_direct_contact_9: $i > $i).
% 29.20/28.99  tff(decl_26042, type, fn_communication_by_direct_contact_10: $i > $i).
% 29.20/28.99  tff(decl_26043, type, communication_through_cell_cell_recognition_1: $i > $o).
% 29.20/28.99  tff(decl_26044, type, 'Communication-Through-Cell-Cell-Recognition': $i).
% 29.20/28.99  tff(decl_26045, type, 'Process of communication between cells which results from direct contact.': $i).
% 29.20/28.99  tff(decl_26046, type, 'communication through cell cell recognition': $i).
% 29.20/28.99  tff(decl_26047, type, 'communication-through-cell-cell-recognition': $i).
% 29.20/28.99  tff(decl_26048, type, fn_communication_through_cell_cell_recognition_1: $i > $i).
% 29.20/28.99  tff(decl_26049, type, fn_communication_through_cell_cell_recognition_2: $i > $i).
% 29.20/28.99  tff(decl_26050, type, fn_communication_through_cell_cell_recognition_3: $i > $i).
% 29.20/28.99  tff(decl_26051, type, fn_communication_through_cell_cell_recognition_4: $i > $i).
% 29.20/28.99  tff(decl_26052, type, fn_communication_through_cell_cell_recognition_5: $i > $i).
% 29.20/28.99  tff(decl_26053, type, fn_communication_through_cell_cell_recognition_6: $i > $i).
% 29.20/28.99  tff(decl_26054, type, fn_communication_through_cell_cell_recognition_7: $i > $i).
% 29.20/28.99  tff(decl_26055, type, fn_communication_through_cell_cell_recognition_8: $i > $i).
% 29.20/28.99  tff(decl_26056, type, fn_communication_through_cell_cell_recognition_9: $i > $i).
% 29.20/28.99  tff(decl_26057, type, fn_communication_through_cell_cell_recognition_10: $i > $i).
% 29.20/28.99  tff(decl_26058, type, fn_communication_through_cell_cell_recognition_11: $i > $i).
% 29.20/28.99  tff(decl_26059, type, fn_communication_through_cell_cell_recognition_12: $i > $i).
% 29.20/28.99  tff(decl_26060, type, fn_communication_through_cell_cell_recognition_13: $i > $i).
% 29.20/28.99  tff(decl_26061, type, fn_communication_through_cell_cell_recognition_14: $i > $i).
% 29.20/28.99  tff(decl_26062, type, fn_communication_through_cell_cell_recognition_15: $i > $i).
% 29.20/28.99  tff(decl_26063, type, fn_communication_through_cell_cell_recognition_16: $i > $i).
% 29.20/28.99  tff(decl_26064, type, communication_through_cell_junction_1: $i > $o).
% 29.20/28.99  tff(decl_26065, type, 'Communication-Through-Cell-Junction': $i).
% 29.20/28.99  tff(decl_26066, type, 'A type of cellular communication in which signaling molecules pass from one cell to another through cell junctions.': $i).
% 29.20/28.99  tff(decl_26067, type, 'communication through cell junction': $i).
% 29.20/28.99  tff(decl_26068, type, 'communication-through-cell-junction': $i).
% 29.20/28.99  tff(decl_26069, type, fn_communication_through_cell_junction_1: $i > $i).
% 29.20/28.99  tff(decl_26070, type, fn_communication_through_cell_junction_2: $i > $i).
% 29.20/28.99  tff(decl_26071, type, fn_communication_through_cell_junction_3: $i > $i).
% 29.20/28.99  tff(decl_26072, type, fn_communication_through_cell_junction_4: $i > $i).
% 29.20/28.99  tff(decl_26073, type, fn_communication_through_cell_junction_5: $i > $i).
% 29.20/28.99  tff(decl_26074, type, fn_communication_through_cell_junction_6: $i > $i).
% 29.20/28.99  tff(decl_26075, type, fn_communication_through_cell_junction_7: $i > $i).
% 29.20/28.99  tff(decl_26076, type, fn_communication_through_cell_junction_8: $i > $i).
% 29.20/28.99  tff(decl_26077, type, fn_communication_through_cell_junction_9: $i > $i).
% 29.20/28.99  tff(decl_26078, type, fn_communication_through_cell_junction_10: $i > $i).
% 29.20/28.99  tff(decl_26079, type, fn_communication_through_cell_junction_11: $i > $i).
% 29.20/28.99  tff(decl_26080, type, fn_communication_through_cell_junction_12: $i > $i).
% 29.20/28.99  tff(decl_26081, type, intercellular_junction_1: $i > $o).
% 29.20/28.99  tff(decl_26082, type, fn_communication_through_cell_junction_13: $i > $i).
% 29.20/28.99  tff(decl_26083, type, fn_communication_through_cell_junction_14: $i > $i).
% 29.20/28.99  tff(decl_26084, type, fn_communication_through_cell_junction_15: $i > $i).
% 29.20/28.99  tff(decl_26085, type, fn_communication_through_cell_junction_16: $i > $i).
% 29.20/28.99  tff(decl_26086, type, fn_communication_through_cell_junction_17: $i > $i).
% 29.20/28.99  tff(decl_26087, type, fn_communication_through_cell_junction_18: $i > $i).
% 29.20/28.99  tff(decl_26088, type, fn_communication_through_cell_junction_19: $i > $i).
% 29.20/28.99  tff(decl_26089, type, fn_intercellular_junction_2: $i > $i).
% 29.20/28.99  tff(decl_26090, type, fn_intercellular_junction_1: $i > $i).
% 29.20/28.99  tff(decl_26091, type, communication_through_cell_junction_in_animal_1: $i > $o).
% 29.20/28.99  tff(decl_26092, type, 'Communication-Through-Cell-Junction-In-Animal': $i).
% 29.20/28.99  tff(decl_26093, type, 'Communication through gap junctions, a type of animal cell junction.': $i).
% 29.20/28.99  tff(decl_26094, type, 'communication through cell junction in animal': $i).
% 29.20/28.99  tff(decl_26095, type, 'communication-through-cell-junction-in-animal': $i).
% 29.20/28.99  tff(decl_26096, type, fn_communication_through_cell_junction_in_animal_1: $i > $i).
% 29.20/28.99  tff(decl_26097, type, fn_communication_through_cell_junction_in_animal_2: $i > $i).
% 29.20/28.99  tff(decl_26098, type, fn_communication_through_cell_junction_in_animal_3: $i > $i).
% 29.20/28.99  tff(decl_26099, type, fn_communication_through_cell_junction_in_animal_4: $i > $i).
% 29.20/28.99  tff(decl_26100, type, fn_communication_through_cell_junction_in_animal_5: $i > $i).
% 29.20/28.99  tff(decl_26101, type, fn_communication_through_cell_junction_in_animal_6: $i > $i).
% 29.20/28.99  tff(decl_26102, type, fn_communication_through_cell_junction_in_animal_7: $i > $i).
% 29.20/28.99  tff(decl_26103, type, fn_communication_through_cell_junction_in_animal_8: $i > $i).
% 29.20/28.99  tff(decl_26104, type, fn_communication_through_cell_junction_in_animal_9: $i > $i).
% 29.20/28.99  tff(decl_26105, type, fn_communication_through_cell_junction_in_animal_10: $i > $i).
% 29.20/28.99  tff(decl_26106, type, fn_communication_through_cell_junction_in_animal_11: $i > $i).
% 29.20/28.99  tff(decl_26107, type, fn_communication_through_cell_junction_in_animal_12: $i > $i).
% 29.20/28.99  tff(decl_26108, type, communication_through_cell_junction_in_plant_1: $i > $o).
% 29.20/28.99  tff(decl_26109, type, 'Communication-Through-Cell-Junction-In-Plant': $i).
% 29.20/28.99  tff(decl_26110, type, 'Communication through plasmodesmata, a type of plant cell junction.': $i).
% 29.20/28.99  tff(decl_26111, type, 'communication through cell junction in plant': $i).
% 29.20/28.99  tff(decl_26112, type, 'communication-through-cell-junction-in-plant': $i).
% 29.20/28.99  tff(decl_26113, type, fn_communication_through_cell_junction_in_plant_1: $i > $i).
% 29.20/28.99  tff(decl_26114, type, fn_communication_through_cell_junction_in_plant_2: $i > $i).
% 29.20/28.99  tff(decl_26115, type, fn_communication_through_cell_junction_in_plant_3: $i > $i).
% 29.20/28.99  tff(decl_26116, type, fn_communication_through_cell_junction_in_plant_6: $i > $i).
% 29.20/28.99  tff(decl_26117, type, fn_communication_through_cell_junction_in_plant_7: $i > $i).
% 29.20/28.99  tff(decl_26118, type, fn_communication_through_cell_junction_in_plant_8: $i > $i).
% 29.20/28.99  tff(decl_26119, type, fn_communication_through_cell_junction_in_plant_9: $i > $i).
% 29.20/28.99  tff(decl_26120, type, fn_communication_through_cell_junction_in_plant_10: $i > $i).
% 29.20/28.99  tff(decl_26121, type, fn_communication_through_cell_junction_in_plant_11: $i > $i).
% 29.20/28.99  tff(decl_26122, type, fn_communication_through_cell_junction_in_plant_12: $i > $i).
% 29.20/28.99  tff(decl_26123, type, fn_communication_through_cell_junction_in_plant_13: $i > $i).
% 29.20/28.99  tff(decl_26124, type, fn_communication_through_cell_junction_in_plant_14: $i > $i).
% 29.20/28.99  tff(decl_26125, type, fn_communication_through_cell_junction_in_plant_15: $i > $i).
% 29.20/28.99  tff(decl_26126, type, fn_communication_through_cell_junction_in_plant_16: $i > $i).
% 29.20/28.99  tff(decl_26127, type, fn_communication_through_cell_junction_in_plant_17: $i > $i).
% 29.20/28.99  tff(decl_26128, type, fn_communication_through_cell_junction_in_plant_18: $i > $i).
% 29.20/28.99  tff(decl_26129, type, fn_communication_through_cell_junction_in_plant_19: $i > $i).
% 29.20/28.99  tff(decl_26130, type, fn_communication_through_cell_junction_in_plant_20: $i > $i).
% 29.20/28.99  tff(decl_26131, type, fn_communication_through_cell_junction_in_plant_21: $i > $i).
% 29.20/28.99  tff(decl_26132, type, fn_communication_through_cell_junction_in_plant_22: $i > $i).
% 29.20/28.99  tff(decl_26133, type, fn_communication_through_cell_junction_in_plant_23: $i > $i).
% 29.20/28.99  tff(decl_26134, type, fn_communication_through_cell_junction_in_plant_24: $i > $i).
% 29.20/28.99  tff(decl_26135, type, fn_communication_through_cell_junction_in_plant_25: $i > $i).
% 29.20/28.99  tff(decl_26136, type, fn_communication_through_cell_junction_in_plant_26: $i > $i).
% 29.20/28.99  tff(decl_26137, type, fn_plant_cell_57: $i > $i).
% 29.20/28.99  tff(decl_26138, type, fn_plant_cell_56: $i > $i).
% 29.20/28.99  tff(decl_26139, type, fn_plant_cell_61: $i > $i).
% 29.20/28.99  tff(decl_26140, type, fn_plant_cell_62: $i > $i).
% 29.20/28.99  tff(decl_26141, type, fn_plant_cell_60: $i > $i).
% 29.20/28.99  tff(decl_26142, type, fn_communication_through_cell_junction_in_plant_5: $i > $i).
% 29.20/28.99  tff(decl_26143, type, fn_communication_through_cell_junction_in_plant_4: $i > $i).
% 29.20/28.99  tff(decl_26144, type, 'Community': $i).
% 29.20/28.99  tff(decl_26145, type, 'a group of people with something in common': $i).
% 29.20/28.99  tff(decl_26146, type, people: $i).
% 29.20/28.99  tff(decl_26147, type, community: $i).
% 29.20/28.99  tff(decl_26148, type, community_ecology_1: $i > $o).
% 29.20/28.99  tff(decl_26149, type, 'Community-Ecology': $i).
% 29.20/28.99  tff(decl_26150, type, 'The study of interactions between species in a biological community.': $i).
% 29.20/28.99  tff(decl_26151, type, 'ecology of community': $i).
% 29.20/28.99  tff(decl_26152, type, 'community ecology': $i).
% 29.20/28.99  tff(decl_26153, type, 'community-ecology': $i).
% 29.20/28.99  tff(decl_26154, type, 'Compaction': $i).
% 29.20/28.99  tff(decl_26155, type, 'A process in early animal embryonic development in which cells on the outer surface of the morula become tightly bound together due to the formation of gap junctions and desmosomes.': $i).
% 29.20/28.99  tff(decl_26156, type, compact: $i).
% 29.20/28.99  tff(decl_26157, type, compaction: $i).
% 29.20/28.99  tff(decl_26158, type, 'Companion-Cell': $i).
% 29.20/28.99  tff(decl_26159, type, 'A specialized parenchyma cell found in the phloem of angiosperms. Companion cells contain the typical nucleus and cytoplasm of plant cells and carry out the metabolic activities to support the sieve-tube elements.': $i).
% 29.20/28.99  tff(decl_26160, type, 'cell of companion': $i).
% 29.20/28.99  tff(decl_26161, type, 'companion cell': $i).
% 29.20/28.99  tff(decl_26162, type, 'companion-cell': $i).
% 29.20/28.99  tff(decl_26163, type, company_1: $i > $o).
% 29.20/28.99  tff(decl_26164, type, 'Company': $i).
% 29.20/28.99  tff(decl_26165, type, 'a private business organization': $i).
% 29.20/28.99  tff(decl_26166, type, company: $i).
% 29.20/29.00  tff(decl_26167, type, business: $i).
% 29.20/29.00  tff(decl_26168, type, concern: $i).
% 29.20/29.00  tff(decl_26169, type, 'business concern': $i).
% 29.20/29.00  tff(decl_26170, type, business_concern: $i).
% 29.20/29.00  tff(decl_26171, type, 'business organization': $i).
% 29.20/29.00  tff(decl_26172, type, business_organization: $i).
% 29.20/29.00  tff(decl_26173, type, 'business organisation': $i).
% 29.20/29.00  tff(decl_26174, type, business_organisation: $i).
% 29.20/29.00  tff(decl_26175, type, institution_1: $i > $o).
% 29.20/29.00  tff(decl_26176, type, educational_institution_1: $i > $o).
% 29.20/29.00  tff(decl_26177, type, 'Compare-Genes': $i).
% 29.20/29.00  tff(decl_26178, type, 'The process of comparing the genes from two different organisms provides evidence for evolution and support for domain classification.': $i).
% 29.20/29.00  tff(decl_26179, type, 'compare genes from two organisms': $i).
% 29.20/29.00  tff(decl_26180, type, compare: $i).
% 29.20/29.00  tff(decl_26181, type, 'compare gene': $i).
% 29.20/29.00  tff(decl_26182, type, 'compare-gene': $i).
% 29.20/29.00  tff(decl_26183, type, fn_compare_genes_1: $i > $i).
% 29.20/29.00  tff(decl_26184, type, fn_compare_genes_2: $i > $i).
% 29.20/29.00  tff(decl_26185, type, fn_compare_genes_3: $i > $i).
% 29.20/29.00  tff(decl_26186, type, domain_1: $i > $o).
% 29.20/29.00  tff(decl_26187, type, fn_compare_genes_4: $i > $i).
% 29.20/29.00  tff(decl_26188, type, fn_compare_genes_5: $i > $i).
% 29.20/29.00  tff(decl_26189, type, fn_compare_genes_6: $i > $i).
% 29.20/29.00  tff(decl_26190, type, fn_compare_genes_7: $i > $i).
% 29.20/29.00  tff(decl_26191, type, fn_compare_genes_8: $i > $i).
% 29.20/29.00  tff(decl_26192, type, fn_compare_genes_9: $i > $i).
% 29.20/29.00  tff(decl_26193, type, fn_compare_genes_10: $i > $i).
% 29.20/29.00  tff(decl_26194, type, compete_1: $i > $o).
% 29.20/29.00  tff(decl_26195, type, 'Compete': $i).
% 29.20/29.00  tff(decl_26196, type, compete: $i).
% 29.20/29.00  tff(decl_26197, type, vie: $i).
% 29.20/29.00  tff(decl_26198, type, contend: $i).
% 29.20/29.00  tff(decl_26199, type, fn_compete_1: $i > $i).
% 29.20/29.00  tff(decl_26200, type, fn_compete_2: $i > $i).
% 29.20/29.00  tff(decl_26201, type, contestant_1: $i > $o).
% 29.20/29.00  tff(decl_26202, type, competition_1: $i > $o).
% 29.20/29.00  tff(decl_26203, type, 'Competition': $i).
% 29.20/29.00  tff(decl_26204, type, 'A contest between two or more individuals for a resource that is limited.': $i).
% 29.20/29.00  tff(decl_26205, type, competition: $i).
% 29.20/29.00  tff(decl_26206, type, species_interactions_1: $i > $o).
% 29.20/29.00  tff(decl_26207, type, herbivory_1: $i > $o).
% 29.20/29.00  tff(decl_26208, type, competitive_inhibition_1: $i > $o).
% 29.20/29.00  tff(decl_26209, type, 'Competitive-Inhibition': $i).
% 29.20/29.00  tff(decl_26210, type, 'Competitive inhibition is a form of enzyme inhibition where binding of the inhibitor to the active site on the enzyme prevents binding of the substrate and vice versa.': $i).
% 29.20/29.00  tff(decl_26211, type, 'competitive inhibition': $i).
% 29.20/29.00  tff(decl_26212, type, 'competitive-inhibition': $i).
% 29.20/29.00  tff(decl_26213, type, non_competitive_inhibition_1: $i > $o).
% 29.20/29.00  tff(decl_26214, type, fn_competitive_inhibition_1: $i > $i).
% 29.20/29.00  tff(decl_26215, type, fn_competitive_inhibition_2: $i > $i).
% 29.20/29.00  tff(decl_26216, type, fn_competitive_inhibition_3: $i > $i).
% 29.20/29.00  tff(decl_26217, type, fn_competitive_inhibition_4: $i > $i).
% 29.20/29.00  tff(decl_26218, type, fn_competitive_inhibition_5: $i > $i).
% 29.20/29.00  tff(decl_26219, type, fn_competitive_inhibition_6: $i > $i).
% 29.20/29.00  tff(decl_26220, type, fn_competitive_inhibition_7: $i > $i).
% 29.20/29.00  tff(decl_26221, type, fn_competitive_inhibition_8: $i > $i).
% 29.20/29.00  tff(decl_26222, type, fn_competitive_inhibition_9: $i > $i).
% 29.20/29.00  tff(decl_26223, type, fn_competitive_inhibition_10: $i > $i).
% 29.20/29.00  tff(decl_26224, type, fn_competitive_inhibition_11: $i > $i).
% 29.20/29.00  tff(decl_26225, type, fn_competitive_inhibition_12: $i > $i).
% 29.20/29.00  tff(decl_26226, type, fn_competitive_inhibition_13: $i > $i).
% 29.20/29.00  tff(decl_26227, type, fn_competitive_inhibition_14: $i > $i).
% 29.20/29.00  tff(decl_26228, type, fn_competitive_inhibition_16: $i > $i).
% 29.20/29.00  tff(decl_26229, type, competitive_inhibitor_1: $i > $o).
% 29.20/29.00  tff(decl_26230, type, fn_competitive_inhibition_15: $i > $i).
% 29.20/29.00  tff(decl_26231, type, 'Competitive-Inhibitor': $i).
% 29.20/29.00  tff(decl_26232, type, 'A competitive inhibitor is any compound which closely resembles the chemical structure and molecular geometry of the substrate. The inhibitor competes for the same active site as the substrate molecule. The inhibitor may interact with the enzyme at the active site, but no reaction takes place. The inhibitor is stuck on the enzyme and prevents any substrate molecules from reacting with the enzyme. However, a competitive inhibition is usually reversible if sufficient substrate molecules are available to ultimately displace the inhibitor. Therefore, the amount of enzyme inhibition depends upon the inhibitor concentration, substrate concentration, and the relative affinities of the inhibitor and substrate for the active site.': $i).
% 29.20/29.00  tff(decl_26233, type, 'competitive inhibitor': $i).
% 29.20/29.00  tff(decl_26234, type, 'competitive-inhibitor': $i).
% 29.20/29.00  tff(decl_26235, type, fn_competitive_inhibitor_1: $i > $i).
% 29.20/29.00  tff(decl_26236, type, fn_competitive_inhibitor_2: $i > $i).
% 29.20/29.00  tff(decl_26237, type, complement_fixation_1: $i > $o).
% 29.20/29.00  tff(decl_26238, type, 'Complement-Fixation': $i).
% 29.20/29.00  tff(decl_26239, type, 'The process of activation of the complement system by antibody-antigen complexes.': $i).
% 29.20/29.00  tff(decl_26240, type, 'perform complement fixation': $i).
% 29.20/29.00  tff(decl_26241, type, 'fixation of complement': $i).
% 29.20/29.00  tff(decl_26242, type, 'complement fixation': $i).
% 29.20/29.00  tff(decl_26243, type, 'complement-fixation': $i).
% 29.20/29.00  tff(decl_26244, type, 'Complement-System': $i).
% 29.20/29.00  tff(decl_26245, type, 'A set of about 30 proteins in the blood that amplify the inflammatory response and increase phagocytosis and lysis of extracellular pathogens.': $i).
% 29.20/29.00  tff(decl_26246, type, 'system of complement': $i).
% 29.20/29.00  tff(decl_26247, type, 'complement system': $i).
% 29.20/29.00  tff(decl_26248, type, 'complement-system': $i).
% 29.20/29.00  tff(decl_26249, type, 'Complete-Dominance': $i).
% 29.20/29.00  tff(decl_26250, type, 'The situation in which the phenotypes of the heterozygote and dominant homozygote are indistinguishable.': $i).
% 29.20/29.00  tff(decl_26251, type, 'show complete dominance': $i).
% 29.20/29.00  tff(decl_26252, type, 'complete dominance': $i).
% 29.20/29.00  tff(decl_26253, type, 'complete-dominance': $i).
% 29.20/29.00  tff(decl_26254, type, 'Complete-Dominance-Cross-Breeding-Event': $i).
% 29.20/29.00  tff(decl_26255, type, 'A kind of dominance wherein the dominant allele completely masks the effect of the recessive allele in heterozygous condition in a cross breeding event.': $i).
% 29.20/29.00  tff(decl_26256, type, 'complete dominance cross breeding event': $i).
% 29.20/29.00  tff(decl_26257, type, 'complete-dominance-cross-breeding-event': $i).
% 29.20/29.00  tff(decl_26258, type, fn_complete_dominance_cross_breeding_event_1: $i > $i).
% 29.20/29.00  tff(decl_26259, type, complete_dominant_allele_1: $i > $o).
% 29.20/29.00  tff(decl_26260, type, 'Complete-Dominant-Allele': $i).
% 29.20/29.00  tff(decl_26261, type, 'The version of a gene that masks the expression of the other version of the same gene when both are present as in a heterozygote.': $i).
% 29.20/29.00  tff(decl_26262, type, 'complete dominant allele': $i).
% 29.20/29.00  tff(decl_26263, type, 'complete-dominant-allele': $i).
% 29.20/29.00  tff(decl_26264, type, complete_flower_1: $i > $o).
% 29.20/29.00  tff(decl_26265, type, 'Complete-Flower': $i).
% 29.20/29.00  tff(decl_26266, type, 'A flower that has all four basic floral organs: sepals, petals, stamens, and carpels.': $i).
% 29.20/29.00  tff(decl_26267, type, 'complete flower': $i).
% 29.20/29.00  tff(decl_26268, type, 'complete-flower': $i).
% 29.20/29.00  tff(decl_26269, type, incomplete_flower_1: $i > $o).
% 29.20/29.00  tff(decl_26270, type, complete_metamorphosis_1: $i > $o).
% 29.20/29.00  tff(decl_26271, type, 'Complete-Metamorphosis': $i).
% 29.20/29.00  tff(decl_26272, type, 'The transformation from a larval form into a very different adult form. The larval and adult forms typically eat different foods and live in different habitats, reducing competition within a life cycle for limited resources.': $i).
% 29.20/29.00  tff(decl_26273, type, metamorphose: $i).
% 29.20/29.00  tff(decl_26274, type, 'complete metamorphosis': $i).
% 29.20/29.00  tff(decl_26275, type, 'complete-metamorphosis': $i).
% 29.20/29.00  tff(decl_26276, type, incomplete_metamorphosis_1: $i > $o).
% 29.20/29.00  tff(decl_26277, type, complete_valence_shell_1: $i > $o).
% 29.20/29.00  tff(decl_26278, type, 'Complete-Valence-Shell': $i).
% 29.20/29.00  tff(decl_26279, type, 'The outermost energy shell of an atom that is filled to capacity.': $i).
% 29.20/29.00  tff(decl_26280, type, 'completed valence shell': $i).
% 29.20/29.00  tff(decl_26281, type, 'complete outer shell': $i).
% 29.20/29.00  tff(decl_26282, type, 'full outer shell': $i).
% 29.20/29.00  tff(decl_26283, type, 'filled outer shell': $i).
% 29.20/29.00  tff(decl_26284, type, 'closed shell': $i).
% 29.20/29.00  tff(decl_26285, type, 'complete valence shell': $i).
% 29.20/29.00  tff(decl_26286, type, 'complete-valence-shell': $i).
% 29.20/29.00  tff(decl_26287, type, valence_shell_1: $i > $o).
% 29.20/29.00  tff(decl_26288, type, incomplete_valence_shell_1: $i > $o).
% 29.20/29.00  tff(decl_26289, type, composite_transposon_1: $i > $o).
% 29.20/29.00  tff(decl_26290, type, 'Composite-Transposon': $i).
% 29.20/29.00  tff(decl_26291, type, 'large sequence transposons containing genes and other inserted sequences.': $i).
% 29.20/29.00  tff(decl_26292, type, 'complex transposon': $i).
% 29.20/29.00  tff(decl_26293, type, 'complex-transposon': $i).
% 29.20/29.00  tff(decl_26294, type, 'transposon of composite': $i).
% 29.20/29.00  tff(decl_26295, type, 'composite transposon': $i).
% 29.20/29.00  tff(decl_26296, type, 'composite-transposon': $i).
% 29.20/29.00  tff(decl_26297, type, insertion_sequences_1: $i > $o).
% 29.20/29.00  tff(decl_26298, type, retrotransposon_1: $i > $o).
% 29.20/29.00  tff(decl_26299, type, fn_composite_transposon_1: $i > $i).
% 29.20/29.00  tff(decl_26300, type, fn_composite_transposon_2: $i > $i).
% 29.20/29.00  tff(decl_26301, type, fn_composite_transposon_3: $i > $i).
% 29.20/29.00  tff(decl_26302, type, fn_composite_transposon_4: $i > $i).
% 29.20/29.00  tff(decl_26303, type, fn_composite_transposon_5: $i > $i).
% 29.20/29.00  tff(decl_26304, type, 'Compound': $i).
% 29.20/29.00  tff(decl_26305, type, 'Compound is a chemical formed when two or more different elements combine, either through covalent or ionic bonding. A compound possesses emergent property because of the constituent elements in a fixed ratio.': $i).
% 29.20/29.00  tff(decl_26306, type, compound: $i).
% 29.20/29.00  tff(decl_26307, type, compound_eye_1: $i > $o).
% 29.20/29.00  tff(decl_26308, type, 'Compound-Eye': $i).
% 29.20/29.00  tff(decl_26309, type, 'A type of eye found only in some arthropods, consisting of up to several thousand individual light-detecting units called ommatidia. Compound eyes excel at detecting motion.': $i).
% 29.20/29.00  tff(decl_26310, type, 'eye of compound': $i).
% 29.20/29.00  tff(decl_26311, type, 'compound eye': $i).
% 29.20/29.00  tff(decl_26312, type, 'compound-eye': $i).
% 29.20/29.00  tff(decl_26313, type, eye_1: $i > $o).
% 29.20/29.00  tff(decl_26314, type, single_lens_eye_1: $i > $o).
% 29.20/29.00  tff(decl_26315, type, compute_balanced_equation_1: $i > $o).
% 29.20/29.00  tff(decl_26316, type, 'Compute-Balanced-Equation': $i).
% 29.20/29.00  tff(decl_26317, type, compute_chemical_formula_of_ionic_compound_1: $i > $o).
% 29.20/29.00  tff(decl_26318, type, 'Compute-Chemical-Formula-of-Ionic-Compound': $i).
% 29.20/29.00  tff(decl_26319, type, compute_concentration_change_constant_1: $i > $o).
% 29.20/29.00  tff(decl_26320, type, 'Compute-Concentration-Change-Constant': $i).
% 29.20/29.00  tff(decl_26321, type, compute_concentration_from_quantity_and_volume_1: $i > $o).
% 29.20/29.00  tff(decl_26322, type, 'Compute-Concentration-from-Quantity-and-Volume': $i).
% 29.20/29.00  tff(decl_26323, type, compute_equilibrium_constant_1: $i > $o).
% 29.20/29.00  tff(decl_26324, type, 'Compute-Equilibrium-Constant': $i).
% 29.20/29.00  tff(decl_26325, type, compute_equilibrium_expression_1: $i > $o).
% 29.20/29.00  tff(decl_26326, type, 'Compute-Equilibrium-Expression': $i).
% 29.20/29.00  tff(decl_26327, type, compute_equilibrium_position_1: $i > $o).
% 29.20/29.00  tff(decl_26328, type, 'Compute-Equilibrium-Position': $i).
% 29.20/29.00  tff(decl_26329, type, compute_ionic_compound_parts_from_nested_formula_1: $i > $o).
% 29.20/29.00  tff(decl_26330, type, 'Compute-Ionic-Compound-Parts-from-Nested-Formula': $i).
% 29.20/29.00  tff(decl_26331, type, compute_maximum_1: $i > $o).
% 29.20/29.00  tff(decl_26332, type, 'Compute-Maximum': $i).
% 29.20/29.00  tff(decl_26333, type, 'given a list of values, return the maximum': $i).
% 29.20/29.00  tff(decl_26334, type, 'compute maximum': $i).
% 29.20/29.00  tff(decl_26335, type, 'compute-maximum': $i).
% 29.20/29.00  tff(decl_26336, type, compute_minimum_1: $i > $o).
% 29.20/29.00  tff(decl_26337, type, 'Compute-Minimum': $i).
% 29.20/29.00  tff(decl_26338, type, 'given a list of values, return the minimum value': $i).
% 29.20/29.00  tff(decl_26339, type, 'compute minimum': $i).
% 29.20/29.00  tff(decl_26340, type, 'compute-minimum': $i).
% 29.20/29.00  tff(decl_26341, type, compute_qualitative_maximum_1: $i > $o).
% 29.20/29.00  tff(decl_26342, type, 'Compute-Qualitative-Maximum': $i).
% 29.20/29.00  tff(decl_26343, type, 'compute qualitative maximum': $i).
% 29.20/29.00  tff(decl_26344, type, 'compute-qualitative-maximum': $i).
% 29.20/29.00  tff(decl_26345, type, compute_qualitative_minimum_1: $i > $o).
% 29.20/29.00  tff(decl_26346, type, 'Compute-Qualitative-Minimum': $i).
% 29.20/29.00  tff(decl_26347, type, 'compute qualitative minimum': $i).
% 29.20/29.00  tff(decl_26348, type, 'compute-qualitative-minimum': $i).
% 29.20/29.00  tff(decl_26349, type, compute_quantitative_maximum_1: $i > $o).
% 29.20/29.00  tff(decl_26350, type, 'Compute-Quantitative-Maximum': $i).
% 29.20/29.00  tff(decl_26351, type, 'compute quantitative maximum': $i).
% 29.20/29.00  tff(decl_26352, type, 'compute-quantitative-maximum': $i).
% 29.20/29.00  tff(decl_26353, type, compute_quantitative_minimum_1: $i > $o).
% 29.20/29.00  tff(decl_26354, type, 'Compute-Quantitative-Minimum': $i).
% 29.20/29.00  tff(decl_26355, type, 'compute quantitative minimum': $i).
% 29.20/29.00  tff(decl_26356, type, 'compute-quantitative-minimum': $i).
% 29.20/29.00  tff(decl_26357, type, compute_quantity_from_concentration_and_volume_1: $i > $o).
% 29.20/29.00  tff(decl_26358, type, 'Compute-Quantity-from-Concentration-and-Volume': $i).
% 29.20/29.00  tff(decl_26359, type, compute_quantity_from_reaction_1: $i > $o).
% 29.20/29.00  tff(decl_26360, type, 'Compute-Quantity-from-Reaction': $i).
% 29.20/29.00  tff(decl_26361, type, compute_quantity_of_chemical_in_chemical_1: $i > $o).
% 29.20/29.00  tff(decl_26362, type, 'Compute-Quantity-of-Chemical-in-Chemical': $i).
% 29.20/29.00  tff(decl_26363, type, compute_quantity_of_chemical_in_chemicals_1: $i > $o).
% 29.20/29.00  tff(decl_26364, type, 'Compute-Quantity-of-Chemical-in-Chemicals': $i).
% 29.20/29.00  tff(decl_26365, type, compute_volume_from_concentration_and_quantity_1: $i > $o).
% 29.20/29.00  tff(decl_26366, type, 'Compute-Volume-from-Concentration-and-Quantity': $i).
% 29.20/29.00  tff(decl_26367, type, conceal_1: $i > $o).
% 29.20/29.00  tff(decl_26368, type, 'Conceal': $i).
% 29.20/29.00  tff(decl_26369, type, conceal: $i).
% 29.20/29.00  tff(decl_26370, type, hide: $i).
% 29.20/29.00  tff(decl_26371, type, fn_conceal_1: $i > $i).
% 29.20/29.00  tff(decl_26372, type, 'Concentration-Constant': $i).
% 29.20/29.00  tff(decl_26373, type, 'constant of concentration': $i).
% 29.20/29.00  tff(decl_26374, type, 'concentration constant': $i).
% 29.20/29.00  tff(decl_26375, type, 'concentration-constant': $i).
% 29.20/29.00  tff(decl_26376, type, 'Concentration-Gradient': $i).
% 29.20/29.00  tff(decl_26377, type, 'A gradient is a measurement of how much something changes as you move from one region to another. So a concentration gradient is a measurement of how the concentration of something changes from one place to another.': $i).
% 29.20/29.00  tff(decl_26378, type, 'chemical force': $i).
% 29.20/29.00  tff(decl_26379, type, 'chemical-force': $i).
% 29.20/29.00  tff(decl_26380, type, 'gradient of concentration': $i).
% 29.20/29.00  tff(decl_26381, type, 'concentration gradient': $i).
% 29.20/29.00  tff(decl_26382, type, 'concentration-gradient': $i).
% 29.20/29.00  tff(decl_26383, type, fn_concentration_gradient_3: $i > $i).
% 29.20/29.00  tff(decl_26384, type, fn_concentration_gradient_4: $i > $i).
% 29.20/29.00  tff(decl_26385, type, fn_concentration_gradient_5: $i > $i).
% 29.20/29.00  tff(decl_26386, type, fn_concentration_gradient_6: $i > $i).
% 29.20/29.00  tff(decl_26387, type, fn_concentration_gradient_7: $i > $i).
% 29.20/29.00  tff(decl_26388, type, fn_concentration_gradient_10: $i > $i).
% 29.20/29.00  tff(decl_26389, type, concentration_maintenance_transport_1: $i > $o).
% 29.20/29.00  tff(decl_26390, type, 'Concentration-Maintenance-Transport': $i).
% 29.20/29.00  tff(decl_26391, type, 'Cellular transport which specifically functions to maintain concentrations of crucial ions in cells': $i).
% 29.20/29.00  tff(decl_26392, type, 'concentration maintenance transport': $i).
% 29.20/29.00  tff(decl_26393, type, 'concentration-maintenance-transport': $i).
% 29.20/29.00  tff(decl_26394, type, fn_concentration_maintenance_transport_1: $i > $i).
% 29.20/29.00  tff(decl_26395, type, fn_concentration_maintenance_transport_2: $i > $i).
% 29.20/29.00  tff(decl_26396, type, fn_concentration_maintenance_transport_3: $i > $i).
% 29.20/29.00  tff(decl_26397, type, fn_concentration_maintenance_transport_4: $i > $i).
% 29.20/29.00  tff(decl_26398, type, fn_concentration_maintenance_transport_5: $i > $i).
% 29.20/29.00  tff(decl_26399, type, fn_concentration_maintenance_transport_6: $i > $i).
% 29.20/29.00  tff(decl_26400, type, fn_concentration_maintenance_transport_7: $i > $i).
% 29.20/29.00  tff(decl_26401, type, fn_concentration_maintenance_transport_8: $i > $i).
% 29.20/29.00  tff(decl_26402, type, fn_concentration_maintenance_transport_9: $i > $i).
% 29.20/29.00  tff(decl_26403, type, concentration_scale_1: $i > $o).
% 29.20/29.00  tff(decl_26404, type, 'Concentration-Scale': $i).
% 29.20/29.00  tff(decl_26405, type, 'scale of concentration': $i).
% 29.20/29.00  tff(decl_26406, type, 'concentration scale': $i).
% 29.20/29.00  tff(decl_26407, type, 'concentration-scale': $i).
% 29.20/29.00  tff(decl_26408, type, 'Concentration-Value': $i).
% 29.20/29.00  tff(decl_26409, type, 'concentration is a property describing the amount of a component in a given volume': $i).
% 29.20/29.00  tff(decl_26410, type, 'concentration of equilibrium': $i).
% 29.20/29.00  tff(decl_26411, type, 'equilibrium concentration': $i).
% 29.20/29.00  tff(decl_26412, type, 'equilibrium-concentration': $i).
% 29.20/29.00  tff(decl_26413, type, concentration: $i).
% 29.20/29.00  tff(decl_26414, type, 'value of concentration': $i).
% 29.20/29.00  tff(decl_26415, type, 'concentration value': $i).
% 29.20/29.00  tff(decl_26416, type, 'concentration-value': $i).
% 29.20/29.00  tff(decl_26417, type, concept_word_frame_1: $i > $o).
% 29.20/29.00  tff(decl_26418, type, 'Concept-Word-Frame': $i).
% 29.20/29.00  tff(decl_26419, type, 'The word and frame information associated with a concept. A concept word frame consists of a word and its part of speech. For verbs, it contains syntactic frame information, which is used to realize the concept as a sentence': $i).
% 29.20/29.00  tff(decl_26420, type, 'concept word frame': $i).
% 29.20/29.00  tff(decl_26421, type, 'concept-word-frame': $i).
% 29.20/29.00  tff(decl_26422, type, 'Conception': $i).
% 29.20/29.00  tff(decl_26423, type, 'The fertilization of an egg by a sperm.': $i).
% 29.20/29.00  tff(decl_26424, type, conceive: $i).
% 29.20/29.00  tff(decl_26425, type, conception: $i).
% 29.20/29.00  tff(decl_26426, type, 'Conceptual-Entity': $i).
% 29.20/29.00  tff(decl_26427, type, 'An entity bearing conceptual content, such as a message or a bit of information.': $i).
% 29.20/29.00  tff(decl_26428, type, abstraction: $i).
% 29.20/29.00  tff(decl_26429, type, 'conceptual entity': $i).
% 29.20/29.00  tff(decl_26430, type, 'conceptual-entity': $i).
% 29.20/29.00  tff(decl_26431, type, intangible_entity_1: $i > $o).
% 29.20/29.00  tff(decl_26432, type, 'Condensation-Reaction': $i).
% 29.20/29.00  tff(decl_26433, type, 'A type of chemical reaction in which two molecules are joined to form a larger molecule, combined with the loss of a small molecule, often water.': $i).
% 29.20/29.00  tff(decl_26434, type, condensation: $i).
% 29.20/29.00  tff(decl_26435, type, 'reaction of condensation': $i).
% 29.20/29.00  tff(decl_26436, type, 'condensation reaction': $i).
% 29.20/29.00  tff(decl_26437, type, 'condensation-reaction': $i).
% 29.20/29.00  tff(decl_26438, type, 'Condense': $i).
% 29.20/29.00  tff(decl_26439, type, condense: $i).
% 29.20/29.00  tff(decl_26440, type, concentrate: $i).
% 29.20/29.00  tff(decl_26441, type, contract: $i).
% 29.20/29.00  tff(decl_26442, type, compress: $i).
% 29.20/29.00  tff(decl_26443, type, 'pack together': $i).
% 29.20/29.00  tff(decl_26444, type, focus: $i).
% 29.20/29.00  tff(decl_26445, type, fn_condense_1: $i > $i).
% 29.20/29.00  tff(decl_26446, type, fn_condense_4: $i > $i).
% 29.20/29.00  tff(decl_26447, type, fn_condense_5: $i > $i).
% 29.20/29.00  tff(decl_26448, type, fn_condense_3: $i > $i).
% 29.20/29.00  tff(decl_26449, type, fn_condense_2: $i > $i).
% 29.20/29.00  tff(decl_26450, type, condensed_chromosome_1: $i > $o).
% 29.20/29.00  tff(decl_26451, type, 'Condensed-Chromosome': $i).
% 29.20/29.00  tff(decl_26452, type, 'State of a chromosome during cell division in which the diffuse chromatin has pulled together and become more dense, rendering the normally invisible chromosomes visible under a light microscope.': $i).
% 29.20/29.00  tff(decl_26453, type, 'condensed chromosome': $i).
% 29.20/29.00  tff(decl_26454, type, 'condensed-chromosome': $i).
% 29.20/29.00  tff(decl_26455, type, fn_condensed_chromosome_1: $i > $i).
% 29.20/29.00  tff(decl_26456, type, 'Condensed-Diploid-Chromosome': $i).
% 29.20/29.00  tff(decl_26457, type, 'State of a diploid chromosome during cell division in which the diffuse chromatin has pulled together and become more dense, rendering the normally invisible chromosomes visible under a light microscope.': $i).
% 29.20/29.00  tff(decl_26458, type, 'condensed diploid chromosome': $i).
% 29.20/29.00  tff(decl_26459, type, 'condensed-diploid-chromosome': $i).
% 29.20/29.00  tff(decl_26460, type, fn_condensed_diploid_chromosome_1: $i > $i).
% 29.20/29.00  tff(decl_26461, type, fn_condensed_diploid_chromosome_2: $i > $i).
% 29.20/29.00  tff(decl_26462, type, fn_condensed_diploid_chromosome_3: $i > $i).
% 29.20/29.00  tff(decl_26463, type, 'Condition': $i).
% 29.20/29.00  tff(decl_26464, type, condition_node_1: $i > $o).
% 29.20/29.00  tff(decl_26465, type, 'Condition-Node': $i).
% 29.20/29.00  tff(decl_26466, type, 'node of condition': $i).
% 29.20/29.00  tff(decl_26467, type, 'condition node': $i).
% 29.20/29.00  tff(decl_26468, type, 'condition-node': $i).
% 29.20/29.00  tff(decl_26469, type, 'Condom': $i).
% 29.20/29.00  tff(decl_26470, type, 'A thin, latex rubber or natural membrane sheath that fits over the penis and worn during sexual activity to prevent pregnancy and the transmission of sexually transmitted disease.': $i).
% 29.20/29.00  tff(decl_26471, type, condom: $i).
% 29.20/29.00  tff(decl_26472, type, conduction_1: $i > $o).
% 29.20/29.00  tff(decl_26473, type, 'Conduction': $i).
% 29.20/29.00  tff(decl_26474, type, 'The transfer of heat between objects that are in direct contact with each other.': $i).
% 29.20/29.00  tff(decl_26475, type, conduct: $i).
% 29.20/29.00  tff(decl_26476, type, conduction: $i).
% 29.20/29.00  tff(decl_26477, type, heat_transfer_1: $i > $o).
% 29.20/29.00  tff(decl_26478, type, fn_conduction_1: $i > $i).
% 29.20/29.00  tff(decl_26479, type, fn_conduction_2: $i > $i).
% 29.20/29.00  tff(decl_26480, type, fn_heat_transfer_7: $i > $i).
% 29.20/29.00  tff(decl_26481, type, fn_heat_transfer_6: $i > $i).
% 29.20/29.00  tff(decl_26482, type, 'Conductivity-Constant': $i).
% 29.20/29.00  tff(decl_26483, type, 'constant of conductivity': $i).
% 29.20/29.00  tff(decl_26484, type, 'conductivity constant': $i).
% 29.20/29.00  tff(decl_26485, type, 'conductivity-constant': $i).
% 29.20/29.00  tff(decl_26486, type, conductivity_scale_1: $i > $o).
% 29.20/29.00  tff(decl_26487, type, 'Conductivity-Scale': $i).
% 29.20/29.00  tff(decl_26488, type, 'scale of conductivity': $i).
% 29.20/29.00  tff(decl_26489, type, 'conductivity scale': $i).
% 29.20/29.00  tff(decl_26490, type, 'conductivity-scale': $i).
% 29.20/29.00  tff(decl_26491, type, 'Conductivity-Value': $i).
% 29.20/29.00  tff(decl_26492, type, 'A measure of the resistance of water to electrical flow; this resistance is a direct measure of the salinity of water, and it can be measured accurately with a conductivity sensor.': $i).
% 29.20/29.00  tff(decl_26493, type, conductivity: $i).
% 29.20/29.00  tff(decl_26494, type, 'value of conductivity': $i).
% 29.20/29.00  tff(decl_26495, type, 'conductivity value': $i).
% 29.20/29.00  tff(decl_26496, type, 'conductivity-value': $i).
% 29.20/29.00  tff(decl_26497, type, 'Conduit': $i).
% 29.20/29.00  tff(decl_26498, type, conduit: $i).
% 29.20/29.00  tff(decl_26499, type, 'Cone': $i).
% 29.20/29.00  tff(decl_26500, type, 'A photoreceptor cell in the retina of the eye that is sensitive to color.': $i).
% 29.20/29.00  tff(decl_26501, type, cone: $i).
% 29.20/29.00  tff(decl_26502, type, 'Confine': $i).
% 29.20/29.00  tff(decl_26503, type, confine: $i).
% 29.20/29.00  tff(decl_26504, type, enclose: $i).
% 29.20/29.00  tff(decl_26505, type, 'hold in': $i).
% 29.20/29.00  tff(decl_26506, type, hold_in: $i).
% 29.20/29.00  tff(decl_26507, type, obstruct_1: $i > $o).
% 29.20/29.00  tff(decl_26508, type, fn_obstruct_1: $i > $i).
% 29.20/29.00  tff(decl_26509, type, confirm_1: $i > $o).
% 29.20/29.00  tff(decl_26510, type, 'Confirm': $i).
% 29.20/29.00  tff(decl_26511, type, 'To affirm or support a hypothesis or theory with  evidence.': $i).
% 29.20/29.00  tff(decl_26512, type, confirm: $i).
% 29.20/29.00  tff(decl_26513, type, confocal_microscopy_1: $i > $o).
% 29.20/29.00  tff(decl_26514, type, 'Confocal-Microscopy': $i).
% 29.20/29.00  tff(decl_26515, type, 'An optical imaging technique used to increase optical resolution and contrast of a micrograph by using point illumination and a spatial pinhole to eliminate out-of-focus light in specimens that are thicker than the focal plane. It enables the reconstruction of three-dimensional structures from the obtained images.': $i).
% 29.20/29.00  tff(decl_26516, type, 'confocal microscopy': $i).
% 29.20/29.00  tff(decl_26517, type, 'confocal-microscopy': $i).
% 29.20/29.00  tff(decl_26518, type, light_microscopy_1: $i > $o).
% 29.20/29.00  tff(decl_26519, type, electron_microscopy_1: $i > $o).
% 29.20/29.00  tff(decl_26520, type, fn_confocal_microscopy_1: $i > $i).
% 29.20/29.00  tff(decl_26521, type, fn_confocal_microscopy_2: $i > $i).
% 29.20/29.00  tff(decl_26522, type, specimen_stained_with_fluorescent_substance_1: $i > $o).
% 29.20/29.00  tff(decl_26523, type, fn_confocal_microscopy_3: $i > $i).
% 29.20/29.00  tff(decl_26524, type, optical_sectioning_1: $i > $o).
% 29.20/29.00  tff(decl_26525, type, fn_optical_sectioning_2: $i > $i).
% 29.20/29.00  tff(decl_26526, type, fn_microscopy_1: $i > $i).
% 29.20/29.00  tff(decl_26527, type, 'Conformational-Change': $i).
% 29.20/29.00  tff(decl_26528, type, 'The alteration in the shape of a protein as a result of change in the environment (pH, temperature, ionic strength) or the binding of a ligand to a receptor or the binding of substrate to an enzyme.': $i).
% 29.20/29.00  tff(decl_26529, type, 'conformational change': $i).
% 29.20/29.00  tff(decl_26530, type, 'change in conformation': $i).
% 29.20/29.00  tff(decl_26531, type, 'conformational-change': $i).
% 29.20/29.00  tff(decl_26532, type, fn_conformational_change_2: $i > $i).
% 29.20/29.00  tff(decl_26533, type, fn_conformational_change_5: $i > $i).
% 29.20/29.00  tff(decl_26534, type, conformer_1: $i > $o).
% 29.20/29.00  tff(decl_26535, type, 'Conformer': $i).
% 29.20/29.00  tff(decl_26536, type, 'An organism whose internal condition varies with changes in external conditions.': $i).
% 29.20/29.00  tff(decl_26537, type, conformer: $i).
% 29.20/29.00  tff(decl_26538, type, congenital_disease_1: $i > $o).
% 29.20/29.00  tff(decl_26539, type, 'Congenital-Disease': $i).
% 29.20/29.00  tff(decl_26540, type, 'Congenital disorder involves defects in or damage to a developing fetus. It may be the result of genetic abnormalities, the intrauterine (uterus) environment, errors of morphogenesis, or a chromosomal abnormality.': $i).
% 29.20/29.00  tff(decl_26541, type, 'congenital disease': $i).
% 29.20/29.00  tff(decl_26542, type, 'congenital-disease': $i).
% 29.20/29.00  tff(decl_26543, type, conidium_1: $i > $o).
% 29.20/29.00  tff(decl_26544, type, 'Conidium': $i).
% 29.20/29.00  tff(decl_26545, type, 'An asexual spore produced by ascomycetes.': $i).
% 29.20/29.00  tff(decl_26546, type, conidia: $i).
% 29.20/29.00  tff(decl_26547, type, spore_1: $i > $o).
% 29.20/29.00  tff(decl_26548, type, megaspore_1: $i > $o).
% 29.20/29.00  tff(decl_26549, type, microspore_1: $i > $o).
% 29.20/29.00  tff(decl_26550, type, plant_spore_1: $i > $o).
% 29.20/29.00  tff(decl_26551, type, zoospore_1: $i > $o).
% 29.20/29.00  tff(decl_26552, type, conifer_1: $i > $o).
% 29.20/29.00  tff(decl_26553, type, 'Conifer': $i).
% 29.20/29.00  tff(decl_26554, type, 'A member of the gymnosperm phylum Conifera.  Most, including pines and first, are cone-bearing trees.': $i).
% 29.20/29.00  tff(decl_26555, type, conifer: $i).
% 29.20/29.00  tff(decl_26556, type, woody_plant_1: $i > $o).
% 29.20/29.00  tff(decl_26557, type, cycad_1: $i > $o).
% 29.20/29.00  tff(decl_26558, type, conjugation_1: $i > $o).
% 29.20/29.00  tff(decl_26559, type, 'Conjugation': $i).
% 29.20/29.00  tff(decl_26560, type, 'In prokaryotes, the direct transfer of DNA between two cells (of the same or different species) that are temporarily joined. In ciliates, a sexual process in which two cells exchange haploid micronuclei.': $i).
% 29.20/29.00  tff(decl_26561, type, conjugate: $i).
% 29.20/29.00  tff(decl_26562, type, conjugation: $i).
% 29.20/29.00  tff(decl_26563, type, transduction_gene_transfer_1: $i > $o).
% 29.20/29.00  tff(decl_26564, type, transformation_in_bacterial_genetics_1: $i > $o).
% 29.20/29.00  tff(decl_26565, type, fn_conjugation_2: $i > $i).
% 29.20/29.00  tff(decl_26566, type, fn_conjugation_3: $i > $i).
% 29.20/29.00  tff(decl_26567, type, fn_conjugation_4: $i > $i).
% 29.20/29.00  tff(decl_26568, type, fn_conjugation_5: $i > $i).
% 29.20/29.00  tff(decl_26569, type, sex_pili_1: $i > $o).
% 29.20/29.00  tff(decl_26570, type, fn_conjugation_6: $i > $i).
% 29.20/29.00  tff(decl_26571, type, fn_conjugation_7: $i > $i).
% 29.20/29.00  tff(decl_26572, type, fn_conjugation_8: $i > $i).
% 29.20/29.00  tff(decl_26573, type, fn_pili_5: $i > $i).
% 29.20/29.00  tff(decl_26574, type, fn_pili_4: $i > $i).
% 29.20/29.00  tff(decl_26575, type, 'Conjunctiva': $i).
% 29.20/29.00  tff(decl_26576, type, 'A layer of epithelial cells that secretes a mucuc membrance covering the outer surface of the eye, keeping it moist.': $i).
% 29.20/29.00  tff(decl_26577, type, conjunctiva: $i).
% 29.20/29.00  tff(decl_26578, type, 'Connective-Tissue': $i).
% 29.20/29.00  tff(decl_26579, type, 'A type of animal tissue that supports, connects, or separates different tissues and organs of the body.': $i).
% 29.20/29.00  tff(decl_26580, type, 'tissue of connective': $i).
% 29.20/29.00  tff(decl_26581, type, 'connective tissue': $i).
% 29.20/29.00  tff(decl_26582, type, 'connective-tissue': $i).
% 29.20/29.00  tff(decl_26583, type, connector_1: $i > $o).
% 29.20/29.00  tff(decl_26584, type, 'Connector': $i).
% 29.20/29.00  tff(decl_26585, type, connector: $i).
% 29.20/29.00  tff(decl_26586, type, connection: $i).
% 29.20/29.00  tff(decl_26587, type, connexion: $i).
% 29.20/29.00  tff(decl_26588, type, connecter: $i).
% 29.20/29.00  tff(decl_26589, type, connective: $i).
% 29.20/29.00  tff(decl_26590, type, fastener: $i).
% 29.20/29.00  tff(decl_26591, type, fastening: $i).
% 29.20/29.00  tff(decl_26592, type, holdfast: $i).
% 29.20/29.00  tff(decl_26593, type, nexus: $i).
% 29.20/29.00  tff(decl_26594, type, fn_connector_1: $i > $i).
% 29.20/29.00  tff(decl_26595, type, 'Conodont': $i).
% 29.20/29.00  tff(decl_26596, type, 'One of a group of extinct eel-like chordates, which had large eyes, rayed fins, and a notochord. Conodonts are known primarily from their fossilized teeth.': $i).
% 29.20/29.00  tff(decl_26597, type, conodont: $i).
% 29.20/29.00  tff(decl_26598, type, conservation_biology_1: $i > $o).
% 29.20/29.00  tff(decl_26599, type, 'Conservation-Biology': $i).
% 29.20/29.00  tff(decl_26600, type, 'The scientific study of Earth\\s biodiversity with the goal of protecting species, habitats, and ecosystems from excessive extinction.': $i).
% 29.20/29.00  tff(decl_26601, type, 'biology of conservation': $i).
% 29.20/29.00  tff(decl_26602, type, 'conservation biology': $i).
% 29.20/29.00  tff(decl_26603, type, 'conservation-biology': $i).
% 29.20/29.00  tff(decl_26604, type, conservation_of_energy_1: $i > $o).
% 29.20/29.00  tff(decl_26605, type, fn_conservation_of_energy_3: $i > $i).
% 29.20/29.00  tff(decl_26606, type, fn_conservation_of_energy_2: $i > $i).
% 29.20/29.00  tff(decl_26607, type, 'Conservation-Of-Energy': $i).
% 29.20/29.00  tff(decl_26608, type, '1) In conservation ecology, the process of judicious use of available energy resources. 2) In physics and chemistry, the law that states that the total amount of energy in a system remains constant over time.': $i).
% 29.20/29.00  tff(decl_26609, type, conserve: $i).
% 29.20/29.00  tff(decl_26610, type, 'energy conservation': $i).
% 29.20/29.00  tff(decl_26611, type, 'energy-conservation': $i).
% 29.20/29.00  tff(decl_26612, type, 'conservation of energy': $i).
% 29.20/29.00  tff(decl_26613, type, 'conservation-of-energy': $i).
% 29.20/29.00  tff(decl_26614, type, conservative_model_1: $i > $o).
% 29.20/29.00  tff(decl_26615, type, 'Conservative-model': $i).
% 29.20/29.00  tff(decl_26616, type, 'Conservative replication would leave intact the original DNA molecule and generate a completely new molecule.': $i).
% 29.20/29.00  tff(decl_26617, type, 'model of conservative': $i).
% 29.20/29.00  tff(decl_26618, type, 'conservative model': $i).
% 29.20/29.00  tff(decl_26619, type, 'conservative-model': $i).
% 29.20/29.00  tff(decl_26620, type, 'Consistency-Constant': $i).
% 29.20/29.00  tff(decl_26621, type, 'constant of consistency': $i).
% 29.20/29.00  tff(decl_26622, type, 'consistency constant': $i).
% 29.20/29.00  tff(decl_26623, type, 'consistency-constant': $i).
% 29.20/29.00  tff(decl_26624, type, 'Consistency-Value': $i).
% 29.20/29.00  tff(decl_26625, type, 'the degree of firmness, density, viscosity, or resistance to movement or separation of constituent particles': $i).
% 29.20/29.00  tff(decl_26626, type, consistence: $i).
% 29.20/29.00  tff(decl_26627, type, body: $i).
% 29.20/29.00  tff(decl_26628, type, consistency: $i).
% 29.20/29.00  tff(decl_26629, type, 'value of consistency': $i).
% 29.20/29.00  tff(decl_26630, type, 'consistency value': $i).
% 29.20/29.00  tff(decl_26631, type, 'consistency-value': $i).
% 29.20/29.00  tff(decl_26632, type, 'Constant': $i).
% 29.20/29.00  tff(decl_26633, type, constant: $i).
% 29.20/29.00  tff(decl_26634, type, constant_exclusion_set_1: $i > $o).
% 29.20/29.00  tff(decl_26635, type, 'Constant-Exclusion-Set': $i).
% 29.20/29.00  tff(decl_26636, type, 'constant exclusion set': $i).
% 29.20/29.00  tff(decl_26637, type, 'constant-exclusion-set': $i).
% 29.20/29.00  tff(decl_26638, type, 'Constant-Motion': $i).
% 29.20/29.00  tff(decl_26639, type, 'It refers to the continuous act, process, or state of changing place or position or movement.': $i).
% 29.20/29.00  tff(decl_26640, type, 'motion of constant': $i).
% 29.20/29.00  tff(decl_26641, type, 'constant motion': $i).
% 29.20/29.00  tff(decl_26642, type, 'constant-motion': $i).
% 29.20/29.00  tff(decl_26643, type, constant_region_1: $i > $o).
% 29.20/29.00  tff(decl_26644, type, 'Constant-Region': $i).
% 29.20/29.00  tff(decl_26645, type, 'A region on an immunoglobulin polypeptide chain which is the same for all antibodies of a particular class.': $i).
% 29.20/29.00  tff(decl_26646, type, 'c region': $i).
% 29.20/29.00  tff(decl_26647, type, 'region of constant': $i).
% 29.20/29.00  tff(decl_26648, type, 'constant region': $i).
% 29.20/29.00  tff(decl_26649, type, 'constant-region': $i).
% 29.20/29.00  tff(decl_26650, type, fn_constant_region_1: $i > $i).
% 29.20/29.00  tff(decl_26651, type, fn_constant_region_2: $i > $i).
% 29.20/29.00  tff(decl_26652, type, fn_constant_region_3: $i > $i).
% 29.20/29.00  tff(decl_26653, type, fn_constant_region_4: $i > $i).
% 29.20/29.00  tff(decl_26654, type, fn_constant_region_5: $i > $i).
% 29.20/29.00  tff(decl_26655, type, constant_region_dna_sequence_1: $i > $o).
% 29.20/29.00  tff(decl_26656, type, 'Constant-Region-DNA-Sequence': $i).
% 29.20/29.00  tff(decl_26657, type, 'A sequence of DNA providing the code for the constant region on an immunoglobulin polypeptide chain.': $i).
% 29.20/29.00  tff(decl_26658, type, 'constant region dna sequence': $i).
% 29.20/29.00  tff(decl_26659, type, 'constant-region-dna-sequence': $i).
% 29.20/29.00  tff(decl_26660, type, eukaryote_dna_sequence_1: $i > $o).
% 29.20/29.00  tff(decl_26661, type, tata_box_1: $i > $o).
% 29.20/29.00  tff(decl_26662, type, control_element_1: $i > $o).
% 29.20/29.00  tff(decl_26663, type, episome_1: $i > $o).
% 29.20/29.00  tff(decl_26664, type, genetic_marker_1: $i > $o).
% 29.20/29.00  tff(decl_26665, type, pseudogene_1: $i > $o).
% 29.20/29.00  tff(decl_26666, type, restriction_site_1: $i > $o).
% 29.20/29.00  tff(decl_26667, type, ttaggg_1: $i > $o).
% 29.20/29.00  tff(decl_26668, type, fn_constant_region_dna_sequence_3: $i > $i).
% 29.20/29.00  tff(decl_26669, type, fn_constant_region_dna_sequence_4: $i > $i).
% 29.20/29.00  tff(decl_26670, type, fn_constant_region_dna_sequence_5: $i > $i).
% 29.20/29.00  tff(decl_26671, type, fn_constant_region_dna_sequence_6: $i > $i).
% 29.20/29.00  tff(decl_26672, type, fn_constant_region_dna_sequence_7: $i > $i).
% 29.20/29.00  tff(decl_26673, type, fn_constant_region_dna_sequence_8: $i > $i).
% 29.20/29.00  tff(decl_26674, type, fn_constant_region_dna_sequence_9: $i > $i).
% 29.20/29.00  tff(decl_26675, type, fn_constant_region_dna_sequence_10: $i > $i).
% 29.20/29.00  tff(decl_26676, type, fn_constant_region_dna_sequence_11: $i > $i).
% 29.20/29.00  tff(decl_26677, type, fn_constant_region_dna_sequence_12: $i > $i).
% 29.20/29.00  tff(decl_26678, type, fn_constant_region_dna_sequence_13: $i > $i).
% 29.20/29.00  tff(decl_26679, type, fn_constant_region_dna_sequence_14: $i > $i).
% 29.20/29.00  tff(decl_26680, type, fn_constant_region_dna_sequence_15: $i > $i).
% 29.20/29.00  tff(decl_26681, type, fn_constant_region_dna_sequence_16: $i > $i).
% 29.20/29.00  tff(decl_26682, type, fn_constant_region_dna_sequence_17: $i > $i).
% 29.20/29.00  tff(decl_26683, type, construction_1: $i > $o).
% 29.20/29.00  tff(decl_26684, type, 'Construction': $i).
% 29.20/29.00  tff(decl_26685, type, construct: $i).
% 29.20/29.00  tff(decl_26686, type, 'creating from raw materials': $i).
% 29.20/29.00  tff(decl_26687, type, creating_from_raw_materials: $i).
% 29.20/29.00  tff(decl_26688, type, create: $i).
% 29.20/29.00  tff(decl_26689, type, 'Consume': $i).
% 29.20/29.00  tff(decl_26690, type, consume: $i).
% 29.20/29.00  tff(decl_26691, type, 'eat up': $i).
% 29.20/29.00  tff(decl_26692, type, eat_up: $i).
% 29.20/29.00  tff(decl_26693, type, 'use up': $i).
% 29.20/29.00  tff(decl_26694, type, use_up: $i).
% 29.20/29.00  tff(decl_26695, type, eat: $i).
% 29.20/29.00  tff(decl_26696, type, deplete: $i).
% 29.20/29.00  tff(decl_26697, type, exhaust: $i).
% 29.20/29.00  tff(decl_26698, type, 'run through': $i).
% 29.20/29.00  tff(decl_26699, type, run_through: $i).
% 29.20/29.00  tff(decl_26700, type, 'wipe out': $i).
% 29.20/29.00  tff(decl_26701, type, wipe_out: $i).
% 29.20/29.00  tff(decl_26702, type, consumers_1: $i > $o).
% 29.20/29.00  tff(decl_26703, type, 'Consumers': $i).
% 29.20/29.00  tff(decl_26704, type, 'Group of organisms in an ecosystem which feeds on other organisms.': $i).
% 29.20/29.00  tff(decl_26705, type, consumer: $i).
% 29.20/29.00  tff(decl_26706, type, trophic_level_1: $i > $o).
% 29.20/29.00  tff(decl_26707, type, contained_volume_1: $i > $o).
% 29.20/29.00  tff(decl_26708, type, 'Contained-Volume': $i).
% 29.20/29.00  tff(decl_26709, type, 'A specified volume of something contained within a limited space.': $i).
% 29.20/29.00  tff(decl_26710, type, 'contained volume': $i).
% 29.20/29.00  tff(decl_26711, type, 'contained-volume': $i).
% 29.20/29.00  tff(decl_26712, type, 'Container': $i).
% 29.20/29.00  tff(decl_26713, type, container: $i).
% 29.20/29.00  tff(decl_26714, type, 'Contest': $i).
% 29.20/29.00  tff(decl_26715, type, contest: $i).
% 29.20/29.00  tff(decl_26716, type, game: $i).
% 29.20/29.00  tff(decl_26717, type, conflict: $i).
% 29.20/29.00  tff(decl_26718, type, struggle: $i).
% 29.20/29.00  tff(decl_26719, type, battle: $i).
% 29.20/29.00  tff(decl_26720, type, fight: $i).
% 29.20/29.00  tff(decl_26721, type, engagement: $i).
% 29.20/29.00  tff(decl_26722, type, 'Contestant': $i).
% 29.20/29.00  tff(decl_26723, type, contestant: $i).
% 29.20/29.00  tff(decl_26724, type, 'Continental-Drift': $i).
% 29.20/29.00  tff(decl_26725, type, 'The slow movement of the continental plates across Earths surface.': $i).
% 29.20/29.00  tff(decl_26726, type, 'continental drift': $i).
% 29.20/29.00  tff(decl_26727, type, 'continental-drift': $i).
% 29.20/29.00  tff(decl_26728, type, continental_shelf_1: $i > $o).
% 29.20/29.00  tff(decl_26729, type, 'Continental-Shelf': $i).
% 29.20/29.00  tff(decl_26730, type, 'The edge of a continent which is under relatively shallow water and is adjacent to the shore of an ocean or sea.': $i).
% 29.20/29.00  tff(decl_26731, type, 'continental shelf': $i).
% 29.20/29.00  tff(decl_26732, type, 'continental-shelf': $i).
% 29.20/29.00  tff(decl_26733, type, contraception_1: $i > $o).
% 29.20/29.00  tff(decl_26734, type, 'Contraception': $i).
% 29.20/29.00  tff(decl_26735, type, 'Methods or devices used to prevent pregnancy.': $i).
% 29.20/29.00  tff(decl_26736, type, contraception: $i).
% 29.20/29.00  tff(decl_26737, type, postzygotic_barrier_1: $i > $o).
% 29.20/29.00  tff(decl_26738, type, contraceptive_procedure_1: $i > $o).
% 29.20/29.00  tff(decl_26739, type, 'Contraceptive-Procedure': $i).
% 29.20/29.00  tff(decl_26740, type, 'A medical procedure designed to prevent pregnancy.': $i).
% 29.20/29.00  tff(decl_26741, type, 'birth control procedure': $i).
% 29.20/29.00  tff(decl_26742, type, 'birth-control-procedure': $i).
% 29.20/29.00  tff(decl_26743, type, 'procedure of contraceptive': $i).
% 29.20/29.00  tff(decl_26744, type, 'contraceptive procedure': $i).
% 29.20/29.00  tff(decl_26745, type, 'contraceptive-procedure': $i).
% 29.20/29.00  tff(decl_26746, type, 'Contract': $i).
% 29.20/29.00  tff(decl_26747, type, shrink: $i).
% 29.20/29.00  tff(decl_26748, type, shrivel: $i).
% 29.20/29.00  tff(decl_26749, type, dry_1: $i > $o).
% 29.20/29.00  tff(decl_26750, type, dim_1: $i > $o).
% 29.20/29.00  tff(decl_26751, type, fn_contract_5: $i > $i).
% 29.20/29.00  tff(decl_26752, type, fn_contract_3: $i > $i).
% 29.20/29.00  tff(decl_26753, type, fn_contract_2: $i > $i).
% 29.20/29.00  tff(decl_26754, type, 'Contractile-Ring': $i).
% 29.20/29.00  tff(decl_26755, type, 'Contractile ring is a ring structure made up of myosin and actin microfilaments which is formed at mid-region of the animal cell. It brings about cytokinesis (division of cytoplasm to result in two daughter cells)': $i).
% 29.20/29.00  tff(decl_26756, type, 'contractile ring': $i).
% 29.20/29.00  tff(decl_26757, type, 'contractile-ring': $i).
% 29.20/29.00  tff(decl_26758, type, fn_contractile_ring_1: $i > $i).
% 29.20/29.00  tff(decl_26759, type, fn_contractile_ring_2: $i > $i).
% 29.20/29.00  tff(decl_26760, type, fn_contractile_ring_3: $i > $i).
% 29.20/29.00  tff(decl_26761, type, fn_contractile_ring_4: $i > $i).
% 29.20/29.00  tff(decl_26762, type, fn_microfilament_24: $i > $i).
% 29.20/29.00  tff(decl_26763, type, fn_microfilament_23: $i > $i).
% 29.20/29.00  tff(decl_26764, type, fn_microfilament_27: $i > $i).
% 29.20/29.00  tff(decl_26765, type, 'Contractile-Vacuole': $i).
% 29.20/29.00  tff(decl_26766, type, 'Contractile Vacuole is a membranous sac involved in osmoregulation. It is most commonly found in protists.': $i).
% 29.20/29.00  tff(decl_26767, type, 'contractile vacuole': $i).
% 29.20/29.00  tff(decl_26768, type, 'contractile-vacuole': $i).
% 29.20/29.00  tff(decl_26769, type, fn_contractile_vacuole_2: $i > $i).
% 29.20/29.00  tff(decl_26770, type, fn_contractile_vacuole_3: $i > $i).
% 29.20/29.00  tff(decl_26771, type, fn_contractile_vacuole_4: $i > $i).
% 29.20/29.00  tff(decl_26772, type, fn_contractile_vacuole_5: $i > $i).
% 29.20/29.00  tff(decl_26773, type, fn_contractile_vacuole_6: $i > $i).
% 29.20/29.00  tff(decl_26774, type, fn_contractile_vacuole_9: $i > $i).
% 29.20/29.00  tff(decl_26775, type, fn_contractile_vacuole_10: $i > $i).
% 29.20/29.00  tff(decl_26776, type, fn_contractile_vacuole_11: $i > $i).
% 29.20/29.00  tff(decl_26777, type, fn_contractile_vacuole_12: $i > $i).
% 29.20/29.00  tff(decl_26778, type, fn_contractile_vacuole_13: $i > $i).
% 29.20/29.00  tff(decl_26779, type, fn_contractile_vacuole_14: $i > $i).
% 29.20/29.00  tff(decl_26780, type, fn_contractile_vacuole_15: $i > $i).
% 29.20/29.00  tff(decl_26781, type, fn_contractile_vacuole_16: $i > $i).
% 29.20/29.00  tff(decl_26782, type, fn_contractile_vacuole_17: $i > $i).
% 29.20/29.00  tff(decl_26783, type, fn_contractile_vacuole_18: $i > $i).
% 29.20/29.00  tff(decl_26784, type, fn_contractile_vacuole_19: $i > $i).
% 29.20/29.00  tff(decl_26785, type, fn_contractile_vacuole_20: $i > $i).
% 29.20/29.00  tff(decl_26786, type, fn_contractile_vacuole_21: $i > $i).
% 29.20/29.00  tff(decl_26787, type, fn_contractile_vacuole_22: $i > $i).
% 29.20/29.00  tff(decl_26788, type, fn_contractile_vacuole_23: $i > $i).
% 29.20/29.00  tff(decl_26789, type, fn_contractile_vacuole_24: $i > $i).
% 29.20/29.00  tff(decl_26790, type, fn_contractile_vacuole_25: $i > $i).
% 29.20/29.00  tff(decl_26791, type, fn_contractile_vacuole_26: $i > $i).
% 29.20/29.00  tff(decl_26792, type, fn_contractile_vacuole_27: $i > $i).
% 29.20/29.00  tff(decl_26793, type, osmoregulation_1: $i > $o).
% 29.20/29.00  tff(decl_26794, type, fn_contractile_vacuole_28: $i > $i).
% 29.20/29.00  tff(decl_26795, type, fn_contractile_vacuole_29: $i > $i).
% 29.20/29.00  tff(decl_26796, type, fn_contractile_vacuole_30: $i > $i).
% 29.20/29.00  tff(decl_26797, type, fn_contractile_vacuole_31: $i > $i).
% 29.20/29.00  tff(decl_26798, type, fn_contractile_vacuole_32: $i > $i).
% 29.20/29.00  tff(decl_26799, type, fn_contractile_vacuole_33: $i > $i).
% 29.20/29.00  tff(decl_26800, type, fn_contractile_vacuole_34: $i > $i).
% 29.20/29.00  tff(decl_26801, type, fn_store_3: $i > $i).
% 29.20/29.00  tff(decl_26802, type, fn_osmoregulation_19: $i > $i).
% 29.20/29.00  tff(decl_26803, type, fn_osmoregulation_3: $i > $i).
% 29.20/29.00  tff(decl_26804, type, fn_osmoregulation_4: $i > $i).
% 29.20/29.00  tff(decl_26805, type, fn_osmoregulation_21: $i > $i).
% 29.20/29.00  tff(decl_26806, type, fn_osmoregulation_2: $i > $i).
% 29.20/29.00  tff(decl_26807, type, fn_vesicle_7: $i > $i).
% 29.20/29.00  tff(decl_26808, type, fn_vesicle_6: $i > $i).
% 29.20/29.00  tff(decl_26809, type, fn_contractile_vacuole_8: $i > $i).
% 29.20/29.00  tff(decl_26810, type, fn_contractile_vacuole_7: $i > $i).
% 29.20/29.00  tff(decl_26811, type, fn_vesicle_8: $i > $i).
% 29.20/29.00  tff(decl_26812, type, fn_vacuole_10: $i > $i).
% 29.20/29.00  tff(decl_26813, type, fn_vacuole_11: $i > $i).
% 29.20/29.00  tff(decl_26814, type, 'Control-Element': $i).
% 29.20/29.00  tff(decl_26815, type, 'A segment of noncoding DNA that helps regulate transcription of a gene by binding a transcription factor. Multiple control elements are present in a eukaryotic gene?s enhancer.': $i).
% 29.20/29.00  tff(decl_26816, type, 'element of control': $i).
% 29.20/29.00  tff(decl_26817, type, 'control element': $i).
% 29.20/29.00  tff(decl_26818, type, 'control-element': $i).
% 29.20/29.00  tff(decl_26819, type, variable_region_dna_sequence_1: $i > $o).
% 29.20/29.00  tff(decl_26820, type, fn_control_element_1: $i > $i).
% 29.20/29.00  tff(decl_26821, type, fn_control_element_2: $i > $i).
% 29.20/29.00  tff(decl_26822, type, control_group_1: $i > $o).
% 29.20/29.00  tff(decl_26823, type, 'Control-Group': $i).
% 29.20/29.00  tff(decl_26824, type, 'An experimental group not subject to the experimental treatment, used for comparison of effectiveness.': $i).
% 29.20/29.00  tff(decl_26825, type, 'group of control': $i).
% 29.20/29.00  tff(decl_26826, type, 'control group': $i).
% 29.20/29.00  tff(decl_26827, type, 'control-group': $i).
% 29.20/29.00  tff(decl_26828, type, experimental_group_1: $i > $o).
% 29.20/29.00  tff(decl_26829, type, control_of_endocytosis_1: $i > $o).
% 29.20/29.00  tff(decl_26830, type, 'Control-Of-Endocytosis': $i).
% 29.20/29.00  tff(decl_26831, type, 'The plasma membrane controls traffic into and out of the cell it surrounds.': $i).
% 29.20/29.00  tff(decl_26832, type, 'control endocytosis': $i).
% 29.20/29.00  tff(decl_26833, type, 'endocytosis control': $i).
% 29.20/29.00  tff(decl_26834, type, 'endocytosis-control': $i).
% 29.20/29.00  tff(decl_26835, type, 'control of endocytosis': $i).
% 29.20/29.00  tff(decl_26836, type, 'control-of-endocytosis': $i).
% 29.20/29.00  tff(decl_26837, type, fn_control_of_endocytosis_3: $i > $i).
% 29.20/29.00  tff(decl_26838, type, fn_control_of_endocytosis_4: $i > $i).
% 29.20/29.00  tff(decl_26839, type, fn_control_of_endocytosis_5: $i > $i).
% 29.20/29.00  tff(decl_26840, type, fn_control_of_endocytosis_6: $i > $i).
% 29.20/29.00  tff(decl_26841, type, gene_regulation_1: $i > $o).
% 29.20/29.00  tff(decl_26842, type, control_of_eukaryotic_translation_initiation_1: $i > $o).
% 29.20/29.00  tff(decl_26843, type, fn_control_of_eukaryotic_translation_initiation_2: $i > $i).
% 29.20/29.00  tff(decl_26844, type, 'Control-Of-Eukaryotic-Translation-Initiation': $i).
% 29.20/29.00  tff(decl_26845, type, 'Translation control mechanism that blocks the initiation stage of polypeptide synthesis.': $i).
% 29.20/29.00  tff(decl_26846, type, 'control eukaryotic translation initiation': $i).
% 29.20/29.00  tff(decl_26847, type, 'control of eukaryotic translation initiation': $i).
% 29.20/29.00  tff(decl_26848, type, 'control-of-eukaryotic-translation-initiation': $i).
% 29.20/29.00  tff(decl_26849, type, polygenic_inheritance_1: $i > $o).
% 29.20/29.00  tff(decl_26850, type, proofreading_of_dna_replication_1: $i > $o).
% 29.20/29.00  tff(decl_26851, type, rna_interference_1: $i > $o).
% 29.20/29.00  tff(decl_26852, type, transduction_1: $i > $o).
% 29.20/29.00  tff(decl_26853, type, transformation_of_cell_to_cancerous_cell_1: $i > $o).
% 29.20/29.00  tff(decl_26854, type, fn_control_of_eukaryotic_translation_initiation_3: $i > $i).
% 29.20/29.00  tff(decl_26855, type, fn_control_of_eukaryotic_translation_initiation_4: $i > $i).
% 29.20/29.00  tff(decl_26856, type, fn_control_of_eukaryotic_translation_initiation_5: $i > $i).
% 29.20/29.00  tff(decl_26857, type, fn_control_of_eukaryotic_translation_initiation_6: $i > $i).
% 29.20/29.00  tff(decl_26858, type, fn_control_of_eukaryotic_translation_initiation_7: $i > $i).
% 29.20/29.00  tff(decl_26859, type, development_1: $i > $o).
% 29.20/29.00  tff(decl_26860, type, fn_control_of_eukaryotic_translation_initiation_8: $i > $i).
% 29.20/29.00  tff(decl_26861, type, eukaryotic_gene_expression_1: $i > $o).
% 29.20/29.00  tff(decl_26862, type, fn_control_of_eukaryotic_translation_initiation_9: $i > $i).
% 29.20/29.00  tff(decl_26863, type, eukaryotic_translation_1: $i > $o).
% 29.20/29.00  tff(decl_26864, type, fn_control_of_eukaryotic_translation_initiation_10: $i > $i).
% 29.20/29.00  tff(decl_26865, type, fn_control_of_eukaryotic_translation_initiation_11: $i > $i).
% 29.20/29.00  tff(decl_26866, type, fn_control_of_eukaryotic_translation_initiation_12: $i > $i).
% 29.20/29.00  tff(decl_26867, type, fn_control_of_eukaryotic_translation_initiation_13: $i > $i).
% 29.20/29.00  tff(decl_26868, type, fn_control_of_eukaryotic_translation_initiation_14: $i > $i).
% 29.20/29.00  tff(decl_26869, type, fn_control_of_eukaryotic_translation_initiation_15: $i > $i).
% 29.20/29.00  tff(decl_26870, type, fn_control_of_eukaryotic_translation_initiation_16: $i > $i).
% 29.20/29.00  tff(decl_26871, type, translation_initiation_1: $i > $o).
% 29.20/29.00  tff(decl_26872, type, fn_eukaryotic_translation_29: $i > $i).
% 29.20/29.00  tff(decl_26873, type, fn_mrna_34: $i > $i).
% 29.20/29.00  tff(decl_26874, type, control_of_exocytosis_1: $i > $o).
% 29.20/29.00  tff(decl_26875, type, 'Control-Of-Exocytosis': $i).
% 29.20/29.00  tff(decl_26876, type, 'control exocytosis': $i).
% 29.20/29.00  tff(decl_26877, type, 'exocytosis control': $i).
% 29.20/29.00  tff(decl_26878, type, 'exocytosis-control': $i).
% 29.20/29.00  tff(decl_26879, type, 'control of exocytosis': $i).
% 29.20/29.00  tff(decl_26880, type, 'control-of-exocytosis': $i).
% 29.20/29.00  tff(decl_26881, type, fn_control_of_exocytosis_1: $i > $i).
% 29.20/29.00  tff(decl_26882, type, fn_control_of_exocytosis_2: $i > $i).
% 29.20/29.00  tff(decl_26883, type, control_of_glycolysis_1: $i > $o).
% 29.20/29.00  tff(decl_26884, type, 'Control-Of-Glycolysis': $i).
% 29.20/29.00  tff(decl_26885, type, 'The control of the process of glycolysis, which includes positive and negative feedback mechanisms.': $i).
% 29.20/29.00  tff(decl_26886, type, 'control glycolysis': $i).
% 29.20/29.00  tff(decl_26887, type, 'glycolysis control': $i).
% 29.20/29.00  tff(decl_26888, type, 'glycolysis-control': $i).
% 29.20/29.00  tff(decl_26889, type, 'control of glycolysis': $i).
% 29.20/29.00  tff(decl_26890, type, 'control-of-glycolysis': $i).
% 29.20/29.00  tff(decl_26891, type, fn_control_of_glycolysis_1: $i > $i).
% 29.20/29.00  tff(decl_26892, type, fn_control_of_glycolysis_2: $i > $i).
% 29.20/29.00  tff(decl_26893, type, phosphofructokinase_1: $i > $o).
% 29.20/29.00  tff(decl_26894, type, fn_control_of_glycolysis_3: $i > $i).
% 29.20/29.00  tff(decl_26895, type, feedback_inhibition_of_glycolysis_by_atp_1: $i > $o).
% 29.20/29.00  tff(decl_26896, type, fn_control_of_glycolysis_4: $i > $i).
% 29.20/29.00  tff(decl_26897, type, feedback_inhibition_of_glycolysis_by_citrate_1: $i > $o).
% 29.20/29.00  tff(decl_26898, type, feedback_inhibition_of_glycolysis_1: $i > $o).
% 29.20/29.00  tff(decl_26899, type, fn_control_of_glycolysis_5: $i > $i).
% 29.20/29.00  tff(decl_26900, type, fn_control_of_glycolysis_6: $i > $i).
% 29.20/29.00  tff(decl_26901, type, fn_phosphofructokinase_27: $i > $i).
% 29.20/29.00  tff(decl_26902, type, fn_feedback_inhibition_of_glycolysis_by_atp_1: $i > $i).
% 29.20/29.00  tff(decl_26903, type, fn_feedback_inhibition_of_glycolysis_by_atp_2: $i > $i).
% 29.20/29.00  tff(decl_26904, type, fn_feedback_inhibition_of_glycolysis_2: $i > $i).
% 29.20/29.00  tff(decl_26905, type, fn_phosphofructokinase_19: $i > $i).
% 29.20/29.00  tff(decl_26906, type, fn_phosphofructokinase_18: $i > $i).
% 29.20/29.00  tff(decl_26907, type, fn_phosphofructokinase_4: $i > $i).
% 29.20/29.00  tff(decl_26908, type, 'Controlled-Experiment': $i).
% 29.20/29.00  tff(decl_26909, type, 'An experiment that compares an experimental group to a control group that is identical except for the factor that is being tested.': $i).
% 29.20/29.00  tff(decl_26910, type, experiment: $i).
% 29.20/29.00  tff(decl_26911, type, 'experiment of controlled': $i).
% 29.20/29.00  tff(decl_26912, type, 'controlled experiment': $i).
% 29.20/29.00  tff(decl_26913, type, 'controlled-experiment': $i).
% 29.20/29.00  tff(decl_26914, type, convection_1: $i > $o).
% 29.20/29.00  tff(decl_26915, type, 'Convection': $i).
% 29.20/29.00  tff(decl_26916, type, 'The collective movement of masses of molecules within a fluid substance.': $i).
% 29.20/29.00  tff(decl_26917, type, convect: $i).
% 29.20/29.00  tff(decl_26918, type, convection: $i).
% 29.20/29.00  tff(decl_26919, type, 'Convergent-Evolution': $i).
% 29.20/29.00  tff(decl_26920, type, 'The evolution of similar traits in independent, non-related, evolutionary lineages.': $i).
% 29.20/29.00  tff(decl_26921, type, 'convergent evolution': $i).
% 29.20/29.00  tff(decl_26922, type, 'convergent-evolution': $i).
% 29.20/29.00  tff(decl_26923, type, convergent_extension_1: $i > $o).
% 29.20/29.00  tff(decl_26924, type, 'Convergent-Extension': $i).
% 29.20/29.00  tff(decl_26925, type, 'A process in embryonic development in which the cells of a tissue rearrange themselves to converge (become narrow) along one axis and extend (become longer) along the perpendicular axis.': $i).
% 29.20/29.00  tff(decl_26926, type, 'convergent extension': $i).
% 29.20/29.00  tff(decl_26927, type, 'convergent-extension': $i).
% 29.20/29.00  tff(decl_26928, type, conversion_of_camp_to_atp_1: $i > $o).
% 29.20/29.00  tff(decl_26929, type, 'Conversion-Of-cAMP-To-ATP': $i).
% 29.20/29.00  tff(decl_26930, type, 'Synthesis of ATP by phosphodiesterase decomposing cyclic AMP to AMP, then phosphate groups being bound to AMP.': $i).
% 29.20/29.00  tff(decl_26931, type, 'camp being converted to atp': $i).
% 29.20/29.00  tff(decl_26932, type, 'conversion of camp to atp': $i).
% 29.20/29.00  tff(decl_26933, type, 'conversion-of-camp-to-atp': $i).
% 29.20/29.00  tff(decl_26934, type, fn_conversion_of_camp_to_atp_1: $i > $i).
% 29.20/29.00  tff(decl_26935, type, fn_conversion_of_camp_to_atp_6: $i > $i).
% 29.20/29.00  tff(decl_26936, type, fn_conversion_of_camp_to_atp_7: $i > $i).
% 29.20/29.00  tff(decl_26937, type, fn_conversion_of_camp_to_atp_8: $i > $i).
% 29.20/29.00  tff(decl_26938, type, fn_conversion_of_camp_to_atp_9: $i > $i).
% 29.20/29.00  tff(decl_26939, type, fn_conversion_of_camp_to_atp_10: $i > $i).
% 29.20/29.00  tff(decl_26940, type, cyclic_nucleotide_phosphodiesterase_1: $i > $o).
% 29.20/29.00  tff(decl_26941, type, fn_conversion_of_camp_to_atp_11: $i > $i).
% 29.20/29.00  tff(decl_26942, type, fn_conversion_of_camp_to_atp_12: $i > $i).
% 29.20/29.00  tff(decl_26943, type, fn_conversion_of_camp_to_atp_13: $i > $i).
% 29.20/29.00  tff(decl_26944, type, fn_conversion_of_camp_to_atp_14: $i > $i).
% 29.20/29.00  tff(decl_26945, type, fn_conversion_of_camp_to_atp_15: $i > $i).
% 29.20/29.00  tff(decl_26946, type, fn_conversion_of_camp_to_atp_16: $i > $i).
% 29.20/29.00  tff(decl_26947, type, fn_conversion_of_camp_to_atp_17: $i > $i).
% 29.20/29.00  tff(decl_26948, type, fn_conversion_of_camp_to_atp_18: $i > $i).
% 29.20/29.00  tff(decl_26949, type, fn_conversion_of_camp_to_atp_19: $i > $i).
% 29.20/29.00  tff(decl_26950, type, fn_conversion_of_camp_to_atp_20: $i > $i).
% 29.20/29.00  tff(decl_26951, type, fn_conversion_of_camp_to_atp_21: $i > $i).
% 29.20/29.00  tff(decl_26952, type, fn_conversion_of_camp_to_atp_22: $i > $i).
% 29.20/29.00  tff(decl_26953, type, fn_conversion_of_camp_to_atp_23: $i > $i).
% 29.20/29.00  tff(decl_26954, type, fn_conversion_of_camp_to_atp_5: $i > $i).
% 29.20/29.00  tff(decl_26955, type, fn_conversion_of_camp_to_atp_4: $i > $i).
% 29.20/29.00  tff(decl_26956, type, fn_conversion_of_camp_to_atp_3: $i > $i).
% 29.20/29.00  tff(decl_26957, type, fn_conversion_of_camp_to_atp_2: $i > $i).
% 29.20/29.00  tff(decl_26958, type, conversion_of_carbohydrate_to_fat_1: $i > $o).
% 29.20/29.00  tff(decl_26959, type, 'Conversion-Of-Carbohydrate-To-Fat': $i).
% 29.20/29.00  tff(decl_26960, type, 'The catabolic change of fat molecules to carbohydrates in order to harvest the energy stored in the fat molecules.': $i).
% 29.20/29.00  tff(decl_26961, type, 'conversion of carbohydrate to fat': $i).
% 29.20/29.00  tff(decl_26962, type, 'conversion-of-carbohydrate-to-fat': $i).
% 29.20/29.00  tff(decl_26963, type, fn_conversion_of_carbohydrate_to_fat_1: $i > $i).
% 29.20/29.00  tff(decl_26964, type, fn_conversion_of_carbohydrate_to_fat_2: $i > $i).
% 29.20/29.00  tff(decl_26965, type, fn_conversion_of_carbohydrate_to_fat_5: $i > $i).
% 29.20/29.00  tff(decl_26966, type, fn_conversion_of_carbohydrate_to_fat_6: $i > $i).
% 29.20/29.00  tff(decl_26967, type, fn_conversion_of_carbohydrate_to_fat_7: $i > $i).
% 29.20/29.00  tff(decl_26968, type, fn_conversion_of_carbohydrate_to_fat_8: $i > $i).
% 29.20/29.00  tff(decl_26969, type, fn_conversion_of_carbohydrate_to_fat_9: $i > $i).
% 29.20/29.00  tff(decl_26970, type, fn_conversion_of_carbohydrate_to_fat_10: $i > $i).
% 29.20/29.00  tff(decl_26971, type, fn_conversion_of_carbohydrate_to_fat_11: $i > $i).
% 29.20/29.00  tff(decl_26972, type, fn_conversion_of_carbohydrate_to_fat_12: $i > $i).
% 29.20/29.00  tff(decl_26973, type, fn_conversion_of_carbohydrate_to_fat_4: $i > $i).
% 29.20/29.00  tff(decl_26974, type, fn_conversion_of_carbohydrate_to_fat_3: $i > $i).
% 29.20/29.00  tff(decl_26975, type, conversion_of_lactate_to_pyruvate_by_liver_cell_1: $i > $o).
% 29.20/29.00  tff(decl_26976, type, 'Conversion-Of-Lactate-To-Pyruvate-By-Liver-Cell': $i).
% 29.20/29.00  tff(decl_26977, type, 'The chemical change of the excess lactate produced during lactic acid fermentation, allowing the pyruvate to enter the mitochondria in the liver cells, where oxygen is present, and complete cellular respiration.': $i).
% 29.20/29.00  tff(decl_26978, type, 'conversion of lactate to pyruvate by liver cell': $i).
% 29.20/29.00  tff(decl_26979, type, 'conversion-of-lactate-to-pyruvate-by-liver-cell': $i).
% 29.20/29.00  tff(decl_26980, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_3: $i > $i).
% 29.20/29.00  tff(decl_26981, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_4: $i > $i).
% 29.20/29.00  tff(decl_26982, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_5: $i > $i).
% 29.20/29.00  tff(decl_26983, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_6: $i > $i).
% 29.20/29.00  tff(decl_26984, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_7: $i > $i).
% 29.20/29.00  tff(decl_26985, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_8: $i > $i).
% 29.20/29.00  tff(decl_26986, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_9: $i > $i).
% 29.20/29.00  tff(decl_26987, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_10: $i > $i).
% 29.20/29.00  tff(decl_26988, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_11: $i > $i).
% 29.20/29.00  tff(decl_26989, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_12: $i > $i).
% 29.20/29.00  tff(decl_26990, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_13: $i > $i).
% 29.20/29.00  tff(decl_26991, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_14: $i > $i).
% 29.20/29.00  tff(decl_26992, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_15: $i > $i).
% 29.20/29.00  tff(decl_26993, type, lactic_acid_fermentation_in_muscle_cell_1: $i > $o).
% 29.20/29.00  tff(decl_26994, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_16: $i > $i).
% 29.20/29.00  tff(decl_26995, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_17: $i > $i).
% 29.20/29.00  tff(decl_26996, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_18: $i > $i).
% 29.20/29.00  tff(decl_26997, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_19: $i > $i).
% 29.20/29.00  tff(decl_26998, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_20: $i > $i).
% 29.20/29.00  tff(decl_26999, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_21: $i > $i).
% 29.20/29.00  tff(decl_27000, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_22: $i > $i).
% 29.20/29.00  tff(decl_27001, type, fn_lactic_acid_fermentation_in_muscle_cell_29: $i > $i).
% 29.20/29.00  tff(decl_27002, type, fn_liver_cell_93: $i > $i).
% 29.20/29.00  tff(decl_27003, type, fn_lactic_acid_fermentation_in_muscle_cell_26: $i > $i).
% 29.20/29.00  tff(decl_27004, type, fn_lactic_acid_fermentation_in_muscle_cell_21: $i > $i).
% 29.20/29.00  tff(decl_27005, type, fn_lactic_acid_fermentation_in_muscle_cell_24: $i > $i).
% 29.20/29.00  tff(decl_27006, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_1: $i > $i).
% 29.20/29.00  tff(decl_27007, type, fn_conversion_of_lactate_to_pyruvate_by_liver_cell_2: $i > $i).
% 29.20/29.00  tff(decl_27008, type, conversion_of_protein_to_fat_1: $i > $o).
% 29.20/29.00  tff(decl_27009, type, 'Conversion-Of-Protein-To-Fat': $i).
% 29.20/29.00  tff(decl_27010, type, 'Excess dietary protein cannot be stored; it is converted to fat for storage.': $i).
% 29.20/29.00  tff(decl_27011, type, 'conversion of protein to fat': $i).
% 29.20/29.00  tff(decl_27012, type, 'conversion-of-protein-to-fat': $i).
% 29.20/29.00  tff(decl_27013, type, fn_conversion_of_protein_to_fat_1: $i > $i).
% 29.20/29.00  tff(decl_27014, type, fn_conversion_of_protein_to_fat_2: $i > $i).
% 29.20/29.00  tff(decl_27015, type, fn_conversion_of_protein_to_fat_5: $i > $i).
% 29.20/29.00  tff(decl_27016, type, fn_conversion_of_protein_to_fat_6: $i > $i).
% 29.20/29.00  tff(decl_27017, type, fn_conversion_of_protein_to_fat_7: $i > $i).
% 29.20/29.00  tff(decl_27018, type, fn_conversion_of_protein_to_fat_8: $i > $i).
% 29.20/29.00  tff(decl_27019, type, fn_conversion_of_protein_to_fat_9: $i > $i).
% 29.20/29.00  tff(decl_27020, type, fn_conversion_of_protein_to_fat_10: $i > $i).
% 29.20/29.00  tff(decl_27021, type, fn_conversion_of_protein_to_fat_4: $i > $i).
% 29.20/29.00  tff(decl_27022, type, fn_conversion_of_protein_to_fat_3: $i > $i).
% 29.20/29.00  tff(decl_27023, type, conversion_of_pyruvate_to_lactate_1: $i > $o).
% 29.20/29.00  tff(decl_27024, type, fn_conversion_of_pyruvate_to_lactate_8: $i > $i).
% 29.20/29.00  tff(decl_27025, type, 'Conversion-of-Pyruvate-to-Lactate': $i).
% 29.20/29.00  tff(decl_27026, type, 'In lactic acid fermentation, pyruvate is converted directly into lactic acid by NADH.': $i).
% 29.20/29.00  tff(decl_27027, type, 'conversion of pyruvate to lactate': $i).
% 29.20/29.00  tff(decl_27028, type, 'conversion-of-pyruvate-to-lactate': $i).
% 29.20/29.00  tff(decl_27029, type, fn_conversion_of_pyruvate_to_lactate_1: $i > $i).
% 29.20/29.00  tff(decl_27030, type, fn_conversion_of_pyruvate_to_lactate_2: $i > $i).
% 29.20/29.00  tff(decl_27031, type, fn_conversion_of_pyruvate_to_lactate_3: $i > $i).
% 29.20/29.00  tff(decl_27032, type, fn_conversion_of_pyruvate_to_lactate_4: $i > $i).
% 29.20/29.00  tff(decl_27033, type, fn_conversion_of_pyruvate_to_lactate_5: $i > $i).
% 29.20/29.00  tff(decl_27034, type, fn_conversion_of_pyruvate_to_lactate_6: $i > $i).
% 29.20/29.00  tff(decl_27035, type, fn_conversion_of_pyruvate_to_lactate_9: $i > $i).
% 29.20/29.00  tff(decl_27036, type, fn_conversion_of_pyruvate_to_lactate_10: $i > $i).
% 29.20/29.00  tff(decl_27037, type, fn_conversion_of_pyruvate_to_lactate_11: $i > $i).
% 29.20/29.00  tff(decl_27038, type, fn_conversion_of_pyruvate_to_lactate_12: $i > $i).
% 29.20/29.00  tff(decl_27039, type, fn_conversion_of_pyruvate_to_lactate_13: $i > $i).
% 29.20/29.00  tff(decl_27040, type, fn_conversion_of_pyruvate_to_lactate_14: $i > $i).
% 29.20/29.00  tff(decl_27041, type, fn_conversion_of_pyruvate_to_lactate_15: $i > $i).
% 29.20/29.00  tff(decl_27042, type, fn_conversion_of_pyruvate_to_lactate_16: $i > $i).
% 29.20/29.00  tff(decl_27043, type, fn_conversion_of_pyruvate_to_lactate_17: $i > $i).
% 29.20/29.00  tff(decl_27044, type, fn_conversion_of_pyruvate_to_lactate_18: $i > $i).
% 29.20/29.00  tff(decl_27045, type, fn_conversion_of_pyruvate_to_lactate_19: $i > $i).
% 29.20/29.00  tff(decl_27046, type, fn_conversion_of_pyruvate_to_lactate_20: $i > $i).
% 29.20/29.00  tff(decl_27047, type, fn_conversion_of_pyruvate_to_lactate_21: $i > $i).
% 29.20/29.00  tff(decl_27048, type, conversion_of_succinyl_coa_to_succinate_in_animal_cell_1: $i > $o).
% 29.20/29.00  tff(decl_27049, type, 'Conversion-Of-Succinyl-CoA-To-Succinate-In-Animal-Cell': $i).
% 29.20/29.00  tff(decl_27050, type, 'Intermediate step in the citric acid cycle taking place in many animal tissue cells, in which a phosphate group is transferred to a molecule of GDP, displacing CoA from Succinyl CoA to produce a molecule of GTP and a molecule of succinate.': $i).
% 29.20/29.00  tff(decl_27051, type, 'conversion of succinyl coa to succinate in animal cell': $i).
% 29.20/29.00  tff(decl_27052, type, 'conversion-of-succinyl-coa-to-succinate-in-animal-cell': $i).
% 29.20/29.00  tff(decl_27053, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_1: $i > $i).
% 29.20/29.00  tff(decl_27054, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_2: $i > $i).
% 29.20/29.00  tff(decl_27055, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_3: $i > $i).
% 29.20/29.00  tff(decl_27056, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_4: $i > $i).
% 29.20/29.00  tff(decl_27057, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_5: $i > $i).
% 29.20/29.00  tff(decl_27058, type, synthesis_of_gtp_1: $i > $o).
% 29.20/29.00  tff(decl_27059, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_6: $i > $i).
% 29.20/29.00  tff(decl_27060, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_7: $i > $i).
% 29.20/29.00  tff(decl_27061, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_8: $i > $i).
% 29.20/29.00  tff(decl_27062, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_9: $i > $i).
% 29.20/29.00  tff(decl_27063, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_10: $i > $i).
% 29.20/29.00  tff(decl_27064, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_11: $i > $i).
% 29.20/29.00  tff(decl_27065, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_12: $i > $i).
% 29.20/29.00  tff(decl_27066, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_13: $i > $i).
% 29.20/29.00  tff(decl_27067, type, fn_substrate_level_phosphorylation_19: $i > $i).
% 29.20/29.00  tff(decl_27068, type, fn_substrate_level_phosphorylation_6: $i > $i).
% 29.20/29.00  tff(decl_27069, type, fn_synthesis_of_gtp_9: $i > $i).
% 29.20/29.00  tff(decl_27070, type, fn_synthesis_of_gtp_3: $i > $i).
% 29.20/29.00  tff(decl_27071, type, fn_substrate_level_phosphorylation_15: $i > $i).
% 29.20/29.00  tff(decl_27072, type, fn_substrate_level_phosphorylation_16: $i > $i).
% 29.20/29.00  tff(decl_27073, type, fn_conversion_of_succinyl_coa_to_succinate_in_animal_cell_14: $i > $i).
% 29.20/29.00  tff(decl_27074, type, 'Conversion-To-Isomer': $i).
% 29.20/29.00  tff(decl_27075, type, 'Molecules are rearranged to convert to their isomers.': $i).
% 29.20/29.00  tff(decl_27076, type, 'conversion to isomer': $i).
% 29.20/29.00  tff(decl_27077, type, 'conversion-to-isomer': $i).
% 29.20/29.00  tff(decl_27078, type, fn_conversion_to_isomer_1: $i > $i).
% 29.20/29.00  tff(decl_27079, type, fn_conversion_to_isomer_2: $i > $i).
% 29.20/29.00  tff(decl_27080, type, 'Convey': $i).
% 29.20/29.00  tff(decl_27081, type, impart: $i).
% 29.20/29.00  tff(decl_27082, type, express: $i).
% 29.20/29.00  tff(decl_27083, type, fn_convey_2: $i > $i).
% 29.20/29.00  tff(decl_27084, type, fn_convey_3: $i > $i).
% 29.20/29.00  tff(decl_27085, type, fn_convey_4: $i > $i).
% 29.20/29.00  tff(decl_27086, type, 'Cooksonia': $i).
% 29.20/29.00  tff(decl_27087, type, 'The earliest land plant known to have vascular tissue, thus representing the transitional form between nonvascular bryophytes and true vascular plants. Cooksonia is extinct and known only from fossilized sporophytes.': $i).
% 29.20/29.00  tff(decl_27088, type, cooksonia: $i).
% 29.20/29.00  tff(decl_27089, type, extinct_plant_1: $i > $o).
% 29.20/29.00  tff(decl_27090, type, 'Cool': $i).
% 29.20/29.00  tff(decl_27091, type, cool: $i).
% 29.20/29.00  tff(decl_27092, type, chill: $i).
% 29.20/29.00  tff(decl_27093, type, 'cool down': $i).
% 29.20/29.00  tff(decl_27094, type, cool_down: $i).
% 29.20/29.00  tff(decl_27095, type, microtubule_shortening_1: $i > $o).
% 29.20/29.00  tff(decl_27096, type, fn_cool_5: $i > $i).
% 29.20/29.00  tff(decl_27097, type, fn_cool_3: $i > $i).
% 29.20/29.00  tff(decl_27098, type, fn_cool_2: $i > $i).
% 29.20/29.00  tff(decl_27099, type, cool_object_1: $i > $o).
% 29.20/29.00  tff(decl_27100, type, 'Cool-Object': $i).
% 29.20/29.00  tff(decl_27101, type, 'An object that is cool.': $i).
% 29.20/29.00  tff(decl_27102, type, 'object of cool': $i).
% 29.20/29.00  tff(decl_27103, type, 'cool object': $i).
% 29.20/29.00  tff(decl_27104, type, 'cool-object': $i).
% 29.20/29.00  tff(decl_27105, type, physical_object_state_1: $i > $o).
% 29.20/29.00  tff(decl_27106, type, cooperativity_1: $i > $o).
% 29.20/29.00  tff(decl_27107, type, 'Cooperativity': $i).
% 29.20/29.00  tff(decl_27108, type, 'Cooperativity is a phenomenon displayed by enzymes or receptors that have multiple binding sites where the affinity of the binding sites for a ligand is increased, positive cooperativity, or decreased, negative cooperativity. Cooperativity mechanism amplifies the response of enzymes to substrates': $i).
% 29.20/29.00  tff(decl_27109, type, cooperativity: $i).
% 29.20/29.00  tff(decl_27110, type, fn_cooperativity_3: $i > $i).
% 29.20/29.00  tff(decl_27111, type, fn_cooperativity_4: $i > $i).
% 29.20/29.00  tff(decl_27112, type, fn_cooperativity_5: $i > $i).
% 29.20/29.00  tff(decl_27113, type, fn_cooperativity_6: $i > $i).
% 29.20/29.00  tff(decl_27114, type, fn_cooperativity_7: $i > $i).
% 29.20/29.00  tff(decl_27115, type, coordinate_gene_expression_1: $i > $o).
% 29.20/29.00  tff(decl_27116, type, 'Coordinate-Gene-Expression': $i).
% 29.20/29.00  tff(decl_27117, type, 'The process whereby a cell coordinates the expression of multiple genes through the association of a specific control element or collection of control elements with every gene of a dispersed group.': $i).
% 29.20/29.00  tff(decl_27118, type, 'eukaryotic coodinate gene expression': $i).
% 29.20/29.00  tff(decl_27119, type, 'coordinate gene expression in eukaryotes': $i).
% 29.20/29.00  tff(decl_27120, type, 'coordinate gene expression': $i).
% 29.20/29.00  tff(decl_27121, type, 'coordinate-gene-expression': $i).
% 29.20/29.00  tff(decl_27122, type, fn_coordinate_gene_expression_1: $i > $i).
% 29.20/29.00  tff(decl_27123, type, transcription_initiation_1: $i > $o).
% 29.20/29.00  tff(decl_27124, type, fn_coordinate_gene_expression_2: $i > $i).
% 29.20/29.00  tff(decl_27125, type, fn_coordinate_gene_expression_3: $i > $i).
% 29.20/29.00  tff(decl_27126, type, fn_coordinate_gene_expression_4: $i > $i).
% 29.20/29.00  tff(decl_27127, type, fn_coordinate_gene_expression_5: $i > $i).
% 29.20/29.00  tff(decl_27128, type, fn_coordinate_gene_expression_6: $i > $i).
% 29.20/29.00  tff(decl_27129, type, fn_coordinate_gene_expression_7: $i > $i).
% 29.20/29.00  tff(decl_27130, type, fn_coordinate_gene_expression_8: $i > $i).
% 29.20/29.00  tff(decl_27131, type, fn_coordinate_gene_expression_9: $i > $i).
% 29.20/29.00  tff(decl_27132, type, fn_coordinate_gene_expression_10: $i > $i).
% 29.20/29.00  tff(decl_27133, type, fn_coordinate_gene_expression_11: $i > $i).
% 29.20/29.00  tff(decl_27134, type, protein_enzyme_0: $i).
% 29.20/29.00  tff(decl_27135, type, fn_gene_expression_3: $i > $i).
% 29.20/29.00  tff(decl_27136, type, coordinate_gene_expression_by_growth_factor_1: $i > $o).
% 29.20/29.00  tff(decl_27137, type, 'Coordinate-Gene-Expression-By-Growth-Factor': $i).
% 29.20/29.00  tff(decl_27138, type, 'A type of Coordinate Gene Expression in which the signal is a growth factor, and receptor is a growth factor receptor.': $i).
% 29.20/29.00  tff(decl_27139, type, 'coordinate gene expression by growth factor': $i).
% 29.20/29.00  tff(decl_27140, type, 'coordinate-gene-expression-by-growth-factor': $i).
% 29.20/29.00  tff(decl_27141, type, coordinate_gene_expression_in_prokaryote_1: $i > $o).
% 29.20/29.00  tff(decl_27142, type, fn_coordinate_gene_expression_by_growth_factor_1: $i > $i).
% 29.20/29.00  tff(decl_27143, type, fn_coordinate_gene_expression_by_growth_factor_2: $i > $i).
% 29.20/29.00  tff(decl_27144, type, fn_coordinate_gene_expression_by_growth_factor_3: $i > $i).
% 29.20/29.00  tff(decl_27145, type, fn_coordinate_gene_expression_by_growth_factor_4: $i > $i).
% 29.20/29.00  tff(decl_27146, type, fn_coordinate_gene_expression_by_growth_factor_5: $i > $i).
% 29.20/29.00  tff(decl_27147, type, fn_coordinate_gene_expression_by_growth_factor_6: $i > $i).
% 29.20/29.00  tff(decl_27148, type, growth_factor_receptor_1: $i > $o).
% 29.20/29.00  tff(decl_27149, type, fn_coordinate_gene_expression_in_prokaryote_2: $i > $i).
% 29.20/29.00  tff(decl_27150, type, 'Coordinate-Gene-Expression-In-Prokaryote': $i).
% 29.20/29.00  tff(decl_27151, type, 'The process whereby a prokaryotic cell coordinates the expression of multiple genes through the association of a specific control element or collection of control elements with every gene of a dispersed group.': $i).
% 29.20/29.00  tff(decl_27152, type, 'prokaryote coordinate gene expression': $i).
% 29.20/29.00  tff(decl_27153, type, 'prokaryotic coordinate gene expression': $i).
% 29.20/29.00  tff(decl_27154, type, 'coordinate gene expression in prokaryote': $i).
% 29.20/29.00  tff(decl_27155, type, 'coordinate-gene-expression-in-prokaryote': $i).
% 29.20/29.00  tff(decl_27156, type, fn_coordinate_gene_expression_in_prokaryote_3: $i > $i).
% 29.20/29.00  tff(decl_27157, type, operon_1: $i > $o).
% 29.20/29.00  tff(decl_27158, type, regulatory_gene_1: $i > $o).
% 29.20/29.00  tff(decl_27159, type, 'Copepod': $i).
% 29.20/29.00  tff(decl_27160, type, 'A small aquatic crustacean that is important in pelagic food webs. Copepods make up a large portion of biomass in marine and freshwater pelagic ecosystems.': $i).
% 29.20/29.00  tff(decl_27161, type, copepod: $i).
% 29.20/29.00  tff(decl_27162, type, copernicium_1: $i > $o).
% 29.20/29.00  tff(decl_27163, type, 'Copernicium': $i).
% 29.20/29.00  tff(decl_27164, type, 'Copernicium is a metal atom with atomic number 112. It is represented by the symbol Cn.': $i).
% 29.20/29.00  tff(decl_27165, type, copernicium: $i).
% 29.20/29.00  tff(decl_27166, type, cn: $i).
% 29.20/29.00  tff(decl_27167, type, fn_copernicium_1: $i > $i).
% 29.20/29.00  tff(decl_27168, type, fn_copernicium_2: $i > $i).
% 29.20/29.00  tff(decl_27169, type, fn_copernicium_6: $i > $i).
% 29.20/29.00  tff(decl_27170, type, fn_copernicium_7: $i > $i).
% 29.20/29.00  tff(decl_27171, type, "173": $i).
% 29.20/29.00  tff(decl_27172, type, "285": $i).
% 29.20/29.00  tff(decl_27173, type, fn_copernicium_4: $i > $i).
% 29.20/29.00  tff(decl_27174, type, fn_copernicium_5: $i > $i).
% 29.20/29.00  tff(decl_27175, type, 'Copper': $i).
% 29.20/29.00  tff(decl_27176, type, 'Copper is a metal atom with atomic number 29. It is represented by the symbol Cu.': $i).
% 29.20/29.00  tff(decl_27177, type, 'Cu': $i).
% 29.20/29.00  tff(decl_27178, type, copper: $i).
% 29.20/29.00  tff(decl_27179, type, fn_copper_3: $i > $i).
% 29.20/29.00  tff(decl_27180, type, fn_copper_4: $i > $i).
% 29.20/29.00  tff(decl_27181, type, fn_copper_5: $i > $i).
% 29.20/29.00  tff(decl_27182, type, fn_copper_9: $i > $i).
% 29.20/29.00  tff(decl_27183, type, fn_copper_10: $i > $i).
% 29.20/29.00  tff(decl_27184, type, fn_copper_11: $i > $i).
% 29.20/29.00  tff(decl_27185, type, fn_copper_12: $i > $i).
% 29.20/29.00  tff(decl_27186, type, "29": $i).
% 29.20/29.00  tff(decl_27187, type, "1.9": $i).
% 29.20/29.00  tff(decl_27188, type, "63.55": $i).
% 29.20/29.00  tff(decl_27189, type, fn_copper_7: $i > $i).
% 29.20/29.00  tff(decl_27190, type, fn_copper_8: $i > $i).
% 29.20/29.00  tff(decl_27191, type, fn_copper_6: $i > $i).
% 29.20/29.00  tff(decl_27192, type, coprophage_1: $i > $o).
% 29.20/29.00  tff(decl_27193, type, 'Coprophage': $i).
% 29.20/29.00  tff(decl_27194, type, 'Animal which eats feces,  either its own or those of another animal.': $i).
% 29.20/29.00  tff(decl_27195, type, fn_coprophage_1: $i > $i).
% 29.20/29.00  tff(decl_27196, type, fn_coprophage_2: $i > $i).
% 29.20/29.00  tff(decl_27197, type, fn_coprophage_3: $i > $i).
% 29.20/29.00  tff(decl_27198, type, fn_coprophage_4: $i > $i).
% 29.20/29.00  tff(decl_27199, type, fn_coprophage_5: $i > $i).
% 29.20/29.00  tff(decl_27200, type, fn_coprophage_6: $i > $i).
% 29.20/29.00  tff(decl_27201, type, fn_coprophage_7: $i > $i).
% 29.20/29.00  tff(decl_27202, type, fn_coprophage_8: $i > $i).
% 29.20/29.00  tff(decl_27203, type, 'Copy': $i).
% 29.20/29.00  tff(decl_27204, type, copy: $i).
% 29.20/29.00  tff(decl_27205, type, 're create': $i).
% 29.20/29.00  tff(decl_27206, type, 're-create': $i).
% 29.20/29.00  tff(decl_27207, type, duplicate: $i).
% 29.20/29.00  tff(decl_27208, type, replicate: $i).
% 29.20/29.00  tff(decl_27209, type, fn_copy_2: $i > $i).
% 29.20/29.00  tff(decl_27210, type, template_1: $i > $o).
% 29.20/29.00  tff(decl_27211, type, fn_template_1: $i > $i).
% 29.20/29.00  tff(decl_27212, type, coral_1: $i > $o).
% 29.20/29.00  tff(decl_27213, type, 'Coral': $i).
% 29.20/29.00  tff(decl_27214, type, 'A solitary or colonial marine anthozoan that has a life cycle involving only the polyp stage (i.e., no medusa stage). In tropical seas, corals form a mutualistic relationship with photosynthetic endosymbionts (zooxanthellae), which allows them to produce coral reefs.': $i).
% 29.20/29.00  tff(decl_27215, type, coral: $i).
% 29.20/29.00  tff(decl_27216, type, fn_coral_1: $i > $i).
% 29.20/29.00  tff(decl_27217, type, coral_reef_1: $i > $o).
% 29.20/29.00  tff(decl_27218, type, 'Coral-Reef': $i).
% 29.20/29.00  tff(decl_27219, type, 'Typically a warm-water, tropical ecosystem dominated by the hard skeletal structures secreted primarily by the resident cnidarians. Some reefs also exist in cold, deep waters.': $i).
% 29.20/29.00  tff(decl_27220, type, 'reef of coral': $i).
% 29.20/29.00  tff(decl_27221, type, 'coral reef': $i).
% 29.20/29.00  tff(decl_27222, type, 'coral-reef': $i).
% 29.20/29.00  tff(decl_27223, type, marine_biome_1: $i > $o).
% 29.20/29.00  tff(decl_27224, type, coral_reef_calcification_1: $i > $o).
% 29.20/29.00  tff(decl_27225, type, 'Coral-Reef-Calcification': $i).
% 29.20/29.00  tff(decl_27226, type, 'The secretion and deposition of CaCO3 by coral polyps. Over time, the accumulation of CaCO3 forms a coral reef.': $i).
% 29.20/29.00  tff(decl_27227, type, 'coral reef calcification': $i).
% 29.20/29.00  tff(decl_27228, type, 'coral-reef-calcification': $i).
% 29.20/29.00  tff(decl_27229, type, fn_coral_reef_calcification_1: $i > $i).
% 29.20/29.00  tff(decl_27230, type, fn_coral_reef_calcification_2: $i > $i).
% 29.20/29.00  tff(decl_27231, type, fn_coral_reef_calcification_3: $i > $i).
% 29.20/29.00  tff(decl_27232, type, cord_1: $i > $o).
% 29.20/29.00  tff(decl_27233, type, 'Cord': $i).
% 29.20/29.00  tff(decl_27234, type, 'Tubular bundle of tissue, cells, or proteins.': $i).
% 29.20/29.00  tff(decl_27235, type, cord: $i).
% 29.20/29.00  tff(decl_27236, type, 'Corepressor': $i).
% 29.20/29.00  tff(decl_27237, type, 'A small molecule that binds to a bacterial repressor protein and changes its shape, allowing it to switch an operon off.': $i).
% 29.20/29.00  tff(decl_27238, type, corepressor: $i).
% 29.20/29.00  tff(decl_27239, type, 'Cork-Cambium': $i).
% 29.20/29.00  tff(decl_27240, type, 'A meristematic tissue in woody plants that is one of several layers that make up the plant\\s bark. Cork cambium produces cork cells, which have thick, tough cell walls.': $i).
% 29.20/29.00  tff(decl_27241, type, 'cambium of cork': $i).
% 29.20/29.00  tff(decl_27242, type, 'cork cambium': $i).
% 29.20/29.00  tff(decl_27243, type, 'cork-cambium': $i).
% 29.20/29.00  tff(decl_27244, type, corn_1: $i > $o).
% 29.20/29.00  tff(decl_27245, type, 'Corn': $i).
% 29.20/29.00  tff(decl_27246, type, 'A common monocot vascular plant.': $i).
% 29.20/29.00  tff(decl_27247, type, maize: $i).
% 29.20/29.00  tff(decl_27248, type, 'zea mays': $i).
% 29.20/29.00  tff(decl_27249, type, corn: $i).
% 29.20/29.00  tff(decl_27250, type, fn_corn_2: $i > $i).
% 29.20/29.00  tff(decl_27251, type, fn_corn_3: $i > $i).
% 29.20/29.00  tff(decl_27252, type, corn_genome_1: $i > $o).
% 29.20/29.00  tff(decl_27253, type, 'Corn-Genome': $i).
% 29.20/29.00  tff(decl_27254, type, 'One of the eukaryotic organisms for which researchers have sequenced the entire genome.': $i).
% 29.20/29.00  tff(decl_27255, type, 'zea mays genome': $i).
% 29.20/29.00  tff(decl_27256, type, 'maize genome': $i).
% 29.20/29.00  tff(decl_27257, type, 'genome of corn': $i).
% 29.20/29.00  tff(decl_27258, type, 'corn genome': $i).
% 29.20/29.00  tff(decl_27259, type, 'corn-genome': $i).
% 29.20/29.00  tff(decl_27260, type, eukaryotic_genome_1: $i > $o).
% 29.20/29.00  tff(decl_27261, type, fn_corn_genome_1: $i > $i).
% 29.20/29.00  tff(decl_27262, type, corn_oil_1: $i > $o).
% 29.20/29.00  tff(decl_27263, type, 'Corn-Oil': $i).
% 29.20/29.00  tff(decl_27264, type, 'Corn oil or Maize oil is oil extracted from the germ of corn (maize). Its main use is in cooking, where its high smoke point makes refined corn oil a valuable frying oil.': $i).
% 29.20/29.00  tff(decl_27265, type, 'oil of corn': $i).
% 29.20/29.00  tff(decl_27266, type, 'corn oil': $i).
% 29.20/29.00  tff(decl_27267, type, 'corn-oil': $i).
% 29.20/29.00  tff(decl_27268, type, plant_fat_1: $i > $o).
% 29.20/29.00  tff(decl_27269, type, corn_plant_1: $i > $o).
% 29.20/29.00  tff(decl_27270, type, 'Corn-Plant': $i).
% 29.20/29.00  tff(decl_27271, type, 'Corn (Zea mays), also called Indian corn, or maize, in agriculture, cereal plant of the tribe Maydeae of the grass family Poaceae, originating in the Americas, and its edible grain.': $i).
% 29.20/29.00  tff(decl_27272, type, 'plant of corn': $i).
% 29.20/29.00  tff(decl_27273, type, 'corn plant': $i).
% 29.20/29.00  tff(decl_27274, type, 'corn-plant': $i).
% 29.20/29.00  tff(decl_27275, type, sugarcane_plant_1: $i > $o).
% 29.20/29.00  tff(decl_27276, type, fn_corn_plant_1: $i > $i).
% 29.20/29.00  tff(decl_27277, type, fn_corn_plant_2: $i > $i).
% 29.20/29.00  tff(decl_27278, type, fn_corn_plant_3: $i > $i).
% 29.20/29.00  tff(decl_27279, type, fn_corn_plant_4: $i > $i).
% 29.20/29.00  tff(decl_27280, type, fn_corn_plant_5: $i > $i).
% 29.20/29.00  tff(decl_27281, type, fn_corn_plant_6: $i > $i).
% 29.20/29.00  tff(decl_27282, type, fn_corn_plant_7: $i > $i).
% 29.20/29.00  tff(decl_27283, type, fn_corn_plant_8: $i > $i).
% 29.20/29.00  tff(decl_27284, type, 'Cornea': $i).
% 29.20/29.00  tff(decl_27285, type, 'The transparent frontal portion of the sclera, which covers the iris and pupil and admits light into the vertebrate eye.': $i).
% 29.20/29.00  tff(decl_27286, type, cornea: $i).
% 29.20/29.00  tff(decl_27287, type, corporation_1: $i > $o).
% 29.20/29.00  tff(decl_27288, type, 'Corporation': $i).
% 29.20/29.00  tff(decl_27289, type, 'an incorporated company': $i).
% 29.20/29.00  tff(decl_27290, type, corporation: $i).
% 29.20/29.00  tff(decl_27291, type, corp: $i).
% 29.20/29.00  tff(decl_27292, type, 'Corpus-Callosum': $i).
% 29.20/29.00  tff(decl_27293, type, 'A band of nerve fibers that connects the left and right hemispheres of the mammalian cerebrum and facilitates communication between the hemispheres.': $i).
% 29.20/29.00  tff(decl_27294, type, 'corpus callosum': $i).
% 29.20/29.00  tff(decl_27295, type, 'corpus-callosum': $i).
% 29.20/29.00  tff(decl_27296, type, 'Corpus-Luteum': $i).
% 29.20/29.00  tff(decl_27297, type, 'A tissue in the ovary consisting of the post-ovulatory collapsed follicle; secretes the hormone progesterone.': $i).
% 29.20/29.00  tff(decl_27298, type, 'corpora lutea': $i).
% 29.20/29.00  tff(decl_27299, type, 'corpora-lutea': $i).
% 29.20/29.00  tff(decl_27300, type, 'yellow body': $i).
% 29.20/29.00  tff(decl_27301, type, 'yellow-body': $i).
% 29.20/29.00  tff(decl_27302, type, 'corpus luteum': $i).
% 29.20/29.00  tff(decl_27303, type, 'corpus-luteum': $i).
% 29.20/29.00  tff(decl_27304, type, glandular_epithelium_1: $i > $o).
% 29.20/29.00  tff(decl_27305, type, 'Cortex': $i).
% 29.20/29.00  tff(decl_27306, type, 'In plants, the cortex is the outer layer of the stem or root, between the epidermis on the outside and the endodermis on the inside.': $i).
% 29.20/29.00  tff(decl_27307, type, cortex: $i).
% 29.20/29.00  tff(decl_27308, type, ground_tissue_1: $i > $o).
% 29.20/29.00  tff(decl_27309, type, pith_1: $i > $o).
% 29.20/29.00  tff(decl_27310, type, plasmodium_1: $i > $o).
% 29.20/29.00  tff(decl_27311, type, symplast_1: $i > $o).
% 29.20/29.00  tff(decl_27312, type, cortex_region_1: $i > $o).
% 29.20/29.00  tff(decl_27313, type, 'Cortex-Region': $i).
% 29.20/29.00  tff(decl_27314, type, 'The region of a cell that lies just under the plasma membrane.': $i).
% 29.20/29.00  tff(decl_27315, type, 'region of cortex': $i).
% 29.20/29.00  tff(decl_27316, type, 'cortex region': $i).
% 29.20/29.00  tff(decl_27317, type, 'cortex-region': $i).
% 29.20/29.00  tff(decl_27318, type, 'Cortical-Granule': $i).
% 29.20/29.00  tff(decl_27319, type, 'A vesicle containing enzymes and other macromolecules located in the cortex (the region just under the plasma membrane) of an egg. Cortical granules undergo exocytosis during the cortical reaction.': $i).
% 29.20/29.00  tff(decl_27320, type, 'cortical granule': $i).
% 29.20/29.00  tff(decl_27321, type, 'cortical-granule': $i).
% 29.20/29.00  tff(decl_27322, type, fn_cortical_granule_1: $i > $i).
% 29.20/29.00  tff(decl_27323, type, egg_cell_1: $i > $o).
% 29.20/29.00  tff(decl_27324, type, cortical_nephron_1: $i > $o).
% 29.20/29.00  tff(decl_27325, type, 'Cortical-Nephron': $i).
% 29.20/29.00  tff(decl_27326, type, 'A nephron whose loop of Henle is located almost completely within the renal cortex.': $i).
% 29.20/29.00  tff(decl_27327, type, 'cortical nephron': $i).
% 29.20/29.00  tff(decl_27328, type, 'cortical-nephron': $i).
% 29.20/29.00  tff(decl_27329, type, nephron_1: $i > $o).
% 29.20/29.00  tff(decl_27330, type, juxtamedullary_nephron_1: $i > $o).
% 29.20/29.00  tff(decl_27331, type, 'Cortical-Reaction': $i).
% 29.20/29.00  tff(decl_27332, type, 'Exocytosis of enzymes and other macromolecules from cortical granules in the egg cytoplasm during fertilization, leading to the formation of a fertilization envelope.': $i).
% 29.20/29.00  tff(decl_27333, type, 'cortical reaction': $i).
% 29.20/29.00  tff(decl_27334, type, 'cortical-reaction': $i).
% 29.20/29.00  tff(decl_27335, type, 'Corticosteroid': $i).
% 29.20/29.00  tff(decl_27336, type, 'A class of chemical that includes the steroid hormones naturally produced and secreted by the adrenal cortex.': $i).
% 29.20/29.00  tff(decl_27337, type, corticosteroid: $i).
% 29.20/29.00  tff(decl_27338, type, cotransport_1: $i > $o).
% 29.20/29.00  tff(decl_27339, type, 'Cotransport': $i).
% 29.20/29.00  tff(decl_27340, type, 'Co-transport, also known as coupled transport or secondary active transport, refers to the simultaneous or sequential passive transfer of molecules or ions across biological membranes in a fixed ratio.': $i).
% 29.20/29.00  tff(decl_27341, type, 'co transport': $i).
% 29.20/29.00  tff(decl_27342, type, 'co-transport': $i).
% 29.20/29.00  tff(decl_27343, type, cotransport: $i).
% 29.20/29.00  tff(decl_27344, type, 'coupled transport': $i).
% 29.20/29.00  tff(decl_27345, type, 'secondary active transport': $i).
% 29.20/29.00  tff(decl_27346, type, fn_cotransport_1: $i > $i).
% 29.20/29.00  tff(decl_27347, type, fn_cotransport_2: $i > $i).
% 29.20/29.00  tff(decl_27348, type, fn_cotransport_3: $i > $i).
% 29.20/29.00  tff(decl_27349, type, fn_cotransport_4: $i > $i).
% 29.20/29.00  tff(decl_27350, type, fn_cotransport_5: $i > $i).
% 29.20/29.00  tff(decl_27351, type, fn_cotransport_6: $i > $i).
% 29.20/29.00  tff(decl_27352, type, fn_cotransport_7: $i > $i).
% 29.20/29.00  tff(decl_27353, type, fn_cotransport_8: $i > $i).
% 29.20/29.00  tff(decl_27354, type, fn_cotransport_9: $i > $i).
% 29.20/29.00  tff(decl_27355, type, fn_cotransport_10: $i > $i).
% 29.20/29.00  tff(decl_27356, type, fn_cotransport_11: $i > $i).
% 29.20/29.00  tff(decl_27357, type, fn_cotransport_12: $i > $i).
% 29.20/29.00  tff(decl_27358, type, fn_cotransport_13: $i > $i).
% 29.20/29.00  tff(decl_27359, type, fn_cotransport_14: $i > $i).
% 29.20/29.00  tff(decl_27360, type, fn_cotransport_15: $i > $i).
% 29.20/29.00  tff(decl_27361, type, fn_cotransport_16: $i > $i).
% 29.20/29.00  tff(decl_27362, type, fn_cotransport_17: $i > $i).
% 29.20/29.00  tff(decl_27363, type, fn_cotransport_18: $i > $i).
% 29.20/29.00  tff(decl_27364, type, fn_cotransport_19: $i > $i).
% 29.20/29.00  tff(decl_27365, type, fn_cotransport_20: $i > $i).
% 29.20/29.00  tff(decl_27366, type, fn_cotransport_21: $i > $i).
% 29.20/29.00  tff(decl_27367, type, fn_cotransport_22: $i > $i).
% 29.20/29.00  tff(decl_27368, type, fn_cotransport_23: $i > $i).
% 29.20/29.00  tff(decl_27369, type, fn_cotransport_24: $i > $i).
% 29.20/29.00  tff(decl_27370, type, fn_cotransport_25: $i > $i).
% 29.20/29.00  tff(decl_27371, type, fn_cotransport_26: $i > $i).
% 29.20/29.00  tff(decl_27372, type, fn_cotransport_27: $i > $i).
% 29.20/29.00  tff(decl_27373, type, fn_cotransport_28: $i > $i).
% 29.20/29.00  tff(decl_27374, type, fn_cotransport_29: $i > $i).
% 29.20/29.00  tff(decl_27375, type, fn_cotransport_30: $i > $i).
% 29.20/29.00  tff(decl_27376, type, fn_cotransport_31: $i > $i).
% 29.20/29.00  tff(decl_27377, type, fn_cotransport_32: $i > $i).
% 29.20/29.00  tff(decl_27378, type, fn_cotransport_33: $i > $i).
% 29.20/29.00  tff(decl_27379, type, fn_cotransport_34: $i > $i).
% 29.20/29.00  tff(decl_27380, type, fn_cotransport_35: $i > $i).
% 29.20/29.00  tff(decl_27381, type, fn_cotransport_36: $i > $i).
% 29.20/29.00  tff(decl_27382, type, fn_cotransport_37: $i > $i).
% 29.20/29.00  tff(decl_27383, type, fn_cotransport_38: $i > $i).
% 29.20/29.00  tff(decl_27384, type, fn_cotransport_39: $i > $i).
% 29.20/29.00  tff(decl_27385, type, fn_cotransport_40: $i > $i).
% 29.20/29.00  tff(decl_27386, type, fn_cotransport_41: $i > $i).
% 29.20/29.00  tff(decl_27387, type, fn_cotransport_42: $i > $i).
% 29.20/29.00  tff(decl_27388, type, fn_cotransport_43: $i > $i).
% 29.20/29.00  tff(decl_27389, type, fn_cotransport_44: $i > $i).
% 29.20/29.00  tff(decl_27390, type, fn_cotransport_45: $i > $i).
% 29.20/29.00  tff(decl_27391, type, fn_cotransport_46: $i > $i).
% 29.20/29.00  tff(decl_27392, type, fn_cotransport_47: $i > $i).
% 29.20/29.00  tff(decl_27393, type, fn_cotransport_48: $i > $i).
% 29.20/29.00  tff(decl_27394, type, fn_cotransport_49: $i > $i).
% 29.20/29.00  tff(decl_27395, type, fn_cotransport_50: $i > $i).
% 29.20/29.00  tff(decl_27396, type, fn_cotransport_51: $i > $i).
% 29.20/29.00  tff(decl_27397, type, fn_cotransport_52: $i > $i).
% 29.20/29.00  tff(decl_27398, type, fn_cotransport_53: $i > $i).
% 29.20/29.00  tff(decl_27399, type, cotransporter_1: $i > $o).
% 29.20/29.00  tff(decl_27400, type, fn_cotransport_54: $i > $i).
% 29.20/29.00  tff(decl_27401, type, fn_cotransport_59: $i > $i).
% 29.20/29.00  tff(decl_27402, type, fn_cotransport_60: $i > $i).
% 29.20/29.00  tff(decl_27403, type, fn_facilitated_diffusion_using_carrier_protein_35: $i > $i).
% 29.20/29.00  tff(decl_27404, type, fn_facilitated_diffusion_using_carrier_protein_45: $i > $i).
% 29.20/29.00  tff(decl_27405, type, fn_facilitated_diffusion_using_carrier_protein_10: $i > $i).
% 29.20/29.00  tff(decl_27406, type, fn_facilitated_diffusion_using_carrier_protein_8: $i > $i).
% 29.20/29.00  tff(decl_27407, type, fn_facilitated_diffusion_using_carrier_protein_14: $i > $i).
% 29.20/29.00  tff(decl_27408, type, fn_facilitated_diffusion_using_carrier_protein_32: $i > $i).
% 29.20/29.00  tff(decl_27409, type, fn_facilitated_diffusion_using_carrier_protein_19: $i > $i).
% 29.20/29.00  tff(decl_27410, type, fn_facilitated_diffusion_using_carrier_protein_12: $i > $i).
% 29.20/29.00  tff(decl_27411, type, fn_facilitated_diffusion_using_carrier_protein_18: $i > $i).
% 29.20/29.00  tff(decl_27412, type, fn_facilitated_diffusion_using_carrier_protein_25: $i > $i).
% 29.20/29.00  tff(decl_27413, type, fn_facilitated_diffusion_using_carrier_protein_48: $i > $i).
% 29.20/29.00  tff(decl_27414, type, fn_facilitated_diffusion_using_carrier_protein_9: $i > $i).
% 29.20/29.00  tff(decl_27415, type, 'AT2': $i).
% 29.20/29.00  tff(decl_27416, type, 'AT1': $i).
% 29.20/29.00  tff(decl_27417, type, fn_cotransport_56: $i > $i).
% 29.20/29.00  tff(decl_27418, type, fn_cotransport_57: $i > $i).
% 29.20/29.00  tff(decl_27419, type, fn_cotransport_58: $i > $i).
% 29.20/29.00  tff(decl_27420, type, fn_cotransport_55: $i > $i).
% 29.20/29.00  tff(decl_27421, type, cotransport_of_sucrose_and_hydrogen_ion_by_plant_cell_1: $i > $o).
% 29.20/29.00  tff(decl_27422, type, 'Cotransport-Of-Sucrose-And-Hydrogen-Ion-By-Plant-Cell': $i).
% 29.20/29.00  tff(decl_27423, type, 'The simultaneous movement of sucrose and hydrogen ions across a membrane in opposite directions.': $i).
% 29.20/29.00  tff(decl_27424, type, 'cotransport of sucrose and hydrogen ion by plant cell': $i).
% 29.20/29.00  tff(decl_27425, type, 'cotransport-of-sucrose-and-hydrogen-ion-by-plant-cell': $i).
% 29.20/29.00  tff(decl_27426, type, uptake_of_nutrient_by_plant_cell_using_proton_pump_1: $i > $o).
% 29.20/29.00  tff(decl_27427, type, fn_cotransport_of_sucrose_and_hydrogen_ion_by_plant_cell_1: $i > $i).
% 29.20/29.00  tff(decl_27428, type, fn_cotransport_of_sucrose_and_hydrogen_ion_by_plant_cell_2: $i > $i).
% 29.20/29.00  tff(decl_27429, type, fn_cotransport_of_sucrose_and_hydrogen_ion_by_plant_cell_3: $i > $i).
% 29.20/29.00  tff(decl_27430, type, sucrose_hydrogen_ion_cotransporter_1: $i > $o).
% 29.20/29.00  tff(decl_27431, type, fn_cotransport_of_sucrose_and_hydrogen_ion_by_plant_cell_4: $i > $i).
% 29.20/29.00  tff(decl_27432, type, fn_cotransport_of_sucrose_and_hydrogen_ion_by_plant_cell_5: $i > $i).
% 29.20/29.00  tff(decl_27433, type, fn_cotransport_of_sucrose_and_hydrogen_ion_by_plant_cell_6: $i > $i).
% 29.20/29.00  tff(decl_27434, type, fn_cotransport_of_sucrose_and_hydrogen_ion_by_plant_cell_7: $i > $i).
% 29.20/29.00  tff(decl_27435, type, fn_cotransport_of_sucrose_and_hydrogen_ion_by_plant_cell_8: $i > $i).
% 29.20/29.00  tff(decl_27436, type, fn_cotransport_of_sucrose_and_hydrogen_ion_by_plant_cell_9: $i > $i).
% 29.20/29.00  tff(decl_27437, type, fn_cotransporter_10: $i > $i).
% 29.20/29.00  tff(decl_27438, type, fn_cotransporter_16: $i > $i).
% 29.20/29.00  tff(decl_27439, type, fn_sucrose_hydrogen_ion_cotransporter_7: $i > $i).
% 29.20/29.00  tff(decl_27440, type, fn_cotransporter_12: $i > $i).
% 29.20/29.00  tff(decl_27441, type, fn_sucrose_hydrogen_ion_cotransporter_34: $i > $i).
% 29.20/29.00  tff(decl_27442, type, cotransport_using_proton_pump_1: $i > $o).
% 29.20/29.00  tff(decl_27443, type, fn_cotransporter_4: $i > $i).
% 29.20/29.00  tff(decl_27444, type, fn_sucrose_hydrogen_ion_cotransporter_28: $i > $i).
% 29.20/29.00  tff(decl_27445, type, fn_uptake_of_nutrient_by_cell_using_proton_pump_3: $i > $i).
% 29.20/29.00  tff(decl_27446, type, fn_uptake_of_nutrient_by_cell_using_proton_pump_4: $i > $i).
% 29.20/29.00  tff(decl_27447, type, fn_uptake_of_nutrient_by_cell_using_proton_pump_5: $i > $i).
% 29.20/29.00  tff(decl_27448, type, fn_uptake_of_nutrient_by_plant_cell_using_proton_pump_1: $i > $i).
% 29.20/29.00  tff(decl_27449, type, fn_uptake_of_nutrient_by_plant_cell_using_proton_pump_8: $i > $i).
% 29.20/29.00  tff(decl_27450, type, fn_uptake_of_nutrient_by_plant_cell_using_proton_pump_4: $i > $i).
% 29.20/29.00  tff(decl_27451, type, fn_uptake_of_nutrient_by_plant_cell_using_proton_pump_2: $i > $i).
% 29.20/29.00  tff(decl_27452, type, fn_uptake_of_nutrient_by_cell_using_proton_pump_6: $i > $i).
% 29.20/29.00  tff(decl_27453, type, fn_uptake_of_nutrient_by_plant_cell_using_proton_pump_5: $i > $i).
% 29.20/29.00  tff(decl_27454, type, fn_uptake_of_nutrient_by_cell_using_proton_pump_8: $i > $i).
% 29.20/29.00  tff(decl_27455, type, fn_uptake_of_nutrient_by_cell_using_proton_pump_7: $i > $i).
% 29.20/29.00  tff(decl_27456, type, fn_uptake_of_nutrient_by_plant_cell_using_proton_pump_7: $i > $i).
% 29.20/29.00  tff(decl_27457, type, fn_uptake_of_nutrient_by_plant_cell_using_proton_pump_6: $i > $i).
% 29.20/29.00  tff(decl_27458, type, 'Cotransport-Using-Proton-Pump': $i).
% 29.20/29.00  tff(decl_27459, type, 'Coupled transport across the plasma membrane where H+ ions coupled with another substance diffuse across the plasma membrane down the H+ gradient.  A proton pump generates potential energy on one side of the membrane by forming an area of high H+ concentration that is used to drive the transport of another substance as H+ diffuses through a specific cotransport protein.': $i).
% 29.20/29.00  tff(decl_27460, type, 'cotransport using proton pump': $i).
% 29.20/29.00  tff(decl_27461, type, 'cotransport-using-proton-pump': $i).
% 29.20/29.00  tff(decl_27462, type, fn_cotransport_using_proton_pump_1: $i > $i).
% 29.20/29.00  tff(decl_27463, type, fn_cotransport_using_proton_pump_2: $i > $i).
% 29.20/29.00  tff(decl_27464, type, fn_cotransport_using_proton_pump_3: $i > $i).
% 29.20/29.00  tff(decl_27465, type, fn_cotransport_using_proton_pump_4: $i > $i).
% 29.20/29.00  tff(decl_27466, type, fn_cotransport_using_proton_pump_5: $i > $i).
% 29.20/29.00  tff(decl_27467, type, fn_cotransport_using_proton_pump_6: $i > $i).
% 29.20/29.00  tff(decl_27468, type, fn_cotransport_using_proton_pump_7: $i > $i).
% 29.20/29.00  tff(decl_27469, type, fn_cotransport_using_proton_pump_8: $i > $i).
% 29.20/29.00  tff(decl_27470, type, fn_cotransport_using_proton_pump_9: $i > $i).
% 29.20/29.00  tff(decl_27471, type, fn_cotransport_using_proton_pump_10: $i > $i).
% 29.20/29.00  tff(decl_27472, type, fn_cotransport_using_proton_pump_11: $i > $i).
% 29.20/29.00  tff(decl_27473, type, fn_cotransport_using_proton_pump_12: $i > $i).
% 29.20/29.00  tff(decl_27474, type, fn_cotransport_using_proton_pump_13: $i > $i).
% 29.20/29.00  tff(decl_27475, type, fn_cotransport_using_proton_pump_14: $i > $i).
% 29.20/29.00  tff(decl_27476, type, fn_cotransport_using_proton_pump_15: $i > $i).
% 29.20/29.00  tff(decl_27477, type, fn_cotransport_using_proton_pump_16: $i > $i).
% 29.20/29.00  tff(decl_27478, type, fn_cotransport_using_proton_pump_17: $i > $i).
% 29.20/29.00  tff(decl_27479, type, fn_cotransport_using_proton_pump_18: $i > $i).
% 29.20/29.00  tff(decl_27480, type, fn_cotransport_using_proton_pump_19: $i > $i).
% 29.20/29.00  tff(decl_27481, type, fn_cotransport_using_proton_pump_20: $i > $i).
% 29.20/29.00  tff(decl_27482, type, fn_electrogenic_pump_40: $i > $i).
% 29.20/29.00  tff(decl_27483, type, fn_proton_pump_68: $i > $i).
% 29.20/29.00  tff(decl_27484, type, fn_proton_pump_24: $i > $i).
% 29.20/29.00  tff(decl_27485, type, fn_proton_pump_59: $i > $i).
% 29.20/29.00  tff(decl_27486, type, fn_proton_pump_42: $i > $i).
% 29.20/29.00  tff(decl_27487, type, fn_proton_pump_25: $i > $i).
% 29.20/29.00  tff(decl_27488, type, fn_proton_pump_76: $i > $i).
% 29.20/29.00  tff(decl_27489, type, 'Cotransporter': $i).
% 29.20/29.00  tff(decl_27490, type, 'A transport protein responsible for simultaneous moving across of molecules across a membrane is called cotransporter.': $i).
% 29.20/29.00  tff(decl_27491, type, cotransporter: $i).
% 29.20/29.00  tff(decl_27492, type, fn_cotransporter_1: $i > $i).
% 29.20/29.00  tff(decl_27493, type, fn_cotransporter_2: $i > $i).
% 29.20/29.00  tff(decl_27494, type, fn_cotransporter_3: $i > $i).
% 29.20/29.00  tff(decl_27495, type, fn_cotransporter_5: $i > $i).
% 29.20/29.00  tff(decl_27496, type, fn_cotransporter_6: $i > $i).
% 29.20/29.00  tff(decl_27497, type, fn_cotransporter_7: $i > $i).
% 29.20/29.00  tff(decl_27498, type, fn_cotransporter_8: $i > $i).
% 29.20/29.00  tff(decl_27499, type, fn_cotransporter_9: $i > $i).
% 29.20/29.00  tff(decl_27500, type, fn_cotransporter_11: $i > $i).
% 29.20/29.00  tff(decl_27501, type, fn_cotransporter_13: $i > $i).
% 29.20/29.00  tff(decl_27502, type, fn_cotransporter_14: $i > $i).
% 29.20/29.00  tff(decl_27503, type, fn_cotransporter_15: $i > $i).
% 29.20/29.00  tff(decl_27504, type, cotton_1: $i > $o).
% 29.20/29.00  tff(decl_27505, type, 'Cotton': $i).
% 29.20/29.00  tff(decl_27506, type, 'The cloth or fabric that is produced from cotton plants.': $i).
% 29.20/29.00  tff(decl_27507, type, cotton: $i).
% 29.20/29.00  tff(decl_27508, type, fn_cotton_1: $i > $i).
% 29.20/29.00  tff(decl_27509, type, fn_cotton_2: $i > $i).
% 29.20/29.00  tff(decl_27510, type, fn_cotton_3: $i > $i).
% 29.20/29.00  tff(decl_27511, type, fn_cotton_4: $i > $i).
% 29.20/29.00  tff(decl_27512, type, fn_hydrophilic_substance_1: $i > $i).
% 29.20/29.00  tff(decl_27513, type, fn_polar_substance_1: $i > $i).
% 29.20/29.00  tff(decl_27514, type, cotton_plant_1: $i > $o).
% 29.20/29.00  tff(decl_27515, type, 'Cotton-Plant': $i).
% 29.20/29.00  tff(decl_27516, type, 'Agriculturally important plant which is the source for cotton used in clothing and industry.': $i).
% 29.20/29.00  tff(decl_27517, type, 'plant of cotton': $i).
% 29.20/29.00  tff(decl_27518, type, 'cotton plant': $i).
% 29.20/29.00  tff(decl_27519, type, 'cotton-plant': $i).
% 29.20/29.00  tff(decl_27520, type, fn_cotton_plant_1: $i > $i).
% 29.20/29.00  tff(decl_27521, type, cotyledon_1: $i > $o).
% 29.20/29.00  tff(decl_27522, type, 'Cotyledon': $i).
% 29.20/29.00  tff(decl_27523, type, 'A seed leaf formed in an angiosperm embryo. Some species have two cotyledons, while others have only one.': $i).
% 29.20/29.00  tff(decl_27524, type, cotyledon: $i).
% 29.20/29.00  tff(decl_27525, type, megaphyll_1: $i > $o).
% 29.20/29.00  tff(decl_27526, type, microphyll_1: $i > $o).
% 29.20/29.00  tff(decl_27527, type, sepal_1: $i > $o).
% 29.20/29.00  tff(decl_27528, type, sporophyll_1: $i > $o).
% 29.20/29.00  tff(decl_27529, type, fn_cotyledon_2: $i > $i).
% 29.20/29.00  tff(decl_27530, type, fn_cotyledon_3: $i > $i).
% 29.20/29.00  tff(decl_27531, type, fn_cotyledon_4: $i > $i).
% 29.20/29.00  tff(decl_27532, type, fn_cotyledon_5: $i > $i).
% 29.20/29.00  tff(decl_27533, type, fn_cotyledon_6: $i > $i).
% 29.20/29.00  tff(decl_27534, type, fn_cotyledon_7: $i > $i).
% 29.20/29.00  tff(decl_27535, type, fn_cotyledon_8: $i > $i).
% 29.20/29.00  tff(decl_27536, type, fn_cotyledon_9: $i > $i).
% 29.20/29.00  tff(decl_27537, type, fn_cotyledon_10: $i > $i).
% 29.20/29.00  tff(decl_27538, type, fn_cotyledon_11: $i > $i).
% 29.20/29.00  tff(decl_27539, type, fn_cotyledon_12: $i > $i).
% 29.20/29.00  tff(decl_27540, type, fn_cotyledon_13: $i > $i).
% 29.20/29.00  tff(decl_27541, type, fn_cotyledon_14: $i > $i).
% 29.20/29.00  tff(decl_27542, type, fn_cotyledon_15: $i > $i).
% 29.20/29.00  tff(decl_27543, type, fn_cotyledon_16: $i > $i).
% 29.20/29.00  tff(decl_27544, type, fn_cotyledon_17: $i > $i).
% 29.20/29.00  tff(decl_27545, type, fn_cotyledon_18: $i > $i).
% 29.20/29.00  tff(decl_27546, type, fn_cotyledon_19: $i > $i).
% 29.20/29.00  tff(decl_27547, type, fn_cotyledon_20: $i > $i).
% 29.20/29.00  tff(decl_27548, type, fn_cotyledon_21: $i > $i).
% 29.20/29.00  tff(decl_27549, type, fn_epidermis_1: $i > $i).
% 29.20/29.00  tff(decl_27550, type, plant_organ_0: $i).
% 29.20/29.00  tff(decl_27551, type, count_viewpoint_1: $i > $o).
% 29.20/29.00  tff(decl_27552, type, 'Count-Viewpoint': $i).
% 29.20/29.00  tff(decl_27553, type, 'viewpoint of count': $i).
% 29.20/29.00  tff(decl_27554, type, 'count viewpoint': $i).
% 29.20/29.00  tff(decl_27555, type, 'count-viewpoint': $i).
% 29.20/29.00  tff(decl_27556, type, countercurrent_exchange_1: $i > $o).
% 29.20/29.00  tff(decl_27557, type, 'Countercurrent-Exchange': $i).
% 29.20/29.00  tff(decl_27558, type, 'Transfer of heat between two fluids moving in opposite directions. As an example, blood within a filament of a fish\\s gill flows in the opposite direction of water moving over the filament; this maximizes the diffusion of oxygen from the water into the blood.': $i).
% 29.20/29.00  tff(decl_27559, type, 'exchange of countercurrent': $i).
% 29.20/29.00  tff(decl_27560, type, 'countercurrent exchange': $i).
% 29.20/29.00  tff(decl_27561, type, 'countercurrent-exchange': $i).
% 29.20/29.00  tff(decl_27562, type, respiratory_process_1: $i > $o).
% 29.20/29.00  tff(decl_27563, type, 'Countercurrent-Multiplier-System': $i).
% 29.20/29.00  tff(decl_27564, type, 'A countercurrent exchange system in which concentration gradients are established by active transport.': $i).
% 29.20/29.00  tff(decl_27565, type, 'countercurrent multiplier system': $i).
% 29.20/29.00  tff(decl_27566, type, 'countercurrent-multiplier-system': $i).
% 29.20/29.00  tff(decl_27567, type, 'Country': $i).
% 29.20/29.00  tff(decl_27568, type, country: $i).
% 29.20/29.00  tff(decl_27569, type, state: $i).
% 29.20/29.00  tff(decl_27570, type, land: $i).
% 29.20/29.00  tff(decl_27571, type, 'County': $i).
% 29.20/29.00  tff(decl_27572, type, county: $i).
% 29.20/29.00  tff(decl_27573, type, coupled_transcription_and_translation_1: $i > $o).
% 29.20/29.00  tff(decl_27574, type, 'Coupled-Transcription-And-Translation': $i).
% 29.20/29.00  tff(decl_27575, type, 'A process in prokaryotes in which transcription and translation take place simultaneously.': $i).
% 29.20/29.00  tff(decl_27576, type, 'coupled transcription and translation': $i).
% 29.20/29.00  tff(decl_27577, type, 'coupled-transcription-and-translation': $i).
% 29.20/29.00  tff(decl_27578, type, courtship_1: $i > $o).
% 29.20/29.00  tff(decl_27579, type, 'Courtship': $i).
% 29.20/29.00  tff(decl_27580, type, 'The processes by which an individual selects a partner for mating purposes.': $i).
% 29.20/29.00  tff(decl_27581, type, courtship: $i).
% 29.20/29.00  tff(decl_27582, type, 'Covalent-Bond': $i).
% 29.20/29.00  tff(decl_27583, type, 'A covalent bond is a form of chemical bonding that is characterized by the sharing of pairs of electrons between atoms, and other covalent bonds. In short, the stable balance of attractive and repulsive forces between atoms when they share electrons is known as covalent bonding.': $i).
% 29.20/29.00  tff(decl_27584, type, 'covalently bond': $i).
% 29.20/29.00  tff(decl_27585, type, 'covalently-bond': $i).
% 29.20/29.00  tff(decl_27586, type, 'covalent bond': $i).
% 29.20/29.00  tff(decl_27587, type, 'covalent-bond': $i).
% 29.20/29.00  tff(decl_27588, type, hydrophobic_interaction_1: $i > $o).
% 29.20/29.00  tff(decl_27589, type, fn_covalent_bond_2: $i > $i).
% 29.20/29.00  tff(decl_27590, type, 'Covalent-Compound': $i).
% 29.20/29.00  tff(decl_27591, type, 'Compound composed of two or more different types of atoms which are covalently bonded to each other.': $i).
% 29.20/29.00  tff(decl_27592, type, 'molecular compound': $i).
% 29.20/29.00  tff(decl_27593, type, 'covalent compound': $i).
% 29.20/29.00  tff(decl_27594, type, 'covalent-compound': $i).
% 29.20/29.00  tff(decl_27595, type, 'Cover': $i).
% 29.20/29.00  tff(decl_27596, type, 'a barrier that prevents movement downward to something from above': $i).
% 29.20/29.00  tff(decl_27597, type, cover: $i).
% 29.20/29.00  tff(decl_27598, type, top: $i).
% 29.20/29.00  tff(decl_27599, type, 'Cowpox': $i).
% 29.20/29.00  tff(decl_27600, type, 'A skin disease caused by the cowpox virus.': $i).
% 29.20/29.00  tff(decl_27601, type, cowpox: $i).
% 29.20/29.00  tff(decl_27602, type, 'Cowpox-Virus': $i).
% 29.20/29.00  tff(decl_27603, type, 'A virus causing the disease cowpox, which is similar to but much milder than smallpox.': $i).
% 29.20/29.00  tff(decl_27604, type, 'virus of cowpox': $i).
% 29.20/29.00  tff(decl_27605, type, 'cowpox virus': $i).
% 29.20/29.00  tff(decl_27606, type, 'cowpox-virus': $i).
% 29.20/29.00  tff(decl_27607, type, crab_1: $i > $o).
% 29.20/29.00  tff(decl_27608, type, 'Crab': $i).
% 29.20/29.00  tff(decl_27609, type, 'A decopod crustacean in which the abdomen is reduced and curved under the thorax.': $i).
% 29.20/29.00  tff(decl_27610, type, crab: $i).
% 29.20/29.00  tff(decl_27611, type, cranial_nerve_1: $i > $o).
% 29.20/29.00  tff(decl_27612, type, 'Cranial-Nerve': $i).
% 29.20/29.00  tff(decl_27613, type, 'A nerve that originates in the brain and terminates in an organ of the head or upper body.': $i).
% 29.20/29.00  tff(decl_27614, type, 'nerve of cranial': $i).
% 29.20/29.00  tff(decl_27615, type, 'cranial nerve': $i).
% 29.20/29.00  tff(decl_27616, type, 'cranial-nerve': $i).
% 29.20/29.00  tff(decl_27617, type, nerve_1: $i > $o).
% 29.20/29.00  tff(decl_27618, type, spinal_nerve_1: $i > $o).
% 29.20/29.00  tff(decl_27619, type, 'Craniate': $i).
% 29.20/29.00  tff(decl_27620, type, 'A chordate animal with a head. Craniates include lampreys and hagfishes, bony and cartilaginous fishes, and tetrapods.': $i).
% 29.20/29.00  tff(decl_27621, type, craniate: $i).
% 29.20/29.00  tff(decl_27622, type, fn_craniate_1: $i > $i).
% 29.20/29.00  tff(decl_27623, type, fn_craniate_2: $i > $i).
% 29.20/29.00  tff(decl_27624, type, fn_craniate_3: $i > $i).
% 29.20/29.00  tff(decl_27625, type, fn_craniate_4: $i > $i).
% 29.20/29.00  tff(decl_27626, type, fn_craniate_5: $i > $i).
% 29.20/29.00  tff(decl_27627, type, fn_craniate_6: $i > $i).
% 29.20/29.00  tff(decl_27628, type, fn_craniate_7: $i > $i).
% 29.20/29.00  tff(decl_27629, type, fn_craniate_8: $i > $i).
% 29.20/29.00  tff(decl_27630, type, fn_craniate_9: $i > $i).
% 29.20/29.00  tff(decl_27631, type, fn_craniate_10: $i > $i).
% 29.20/29.00  tff(decl_27632, type, fn_craniate_11: $i > $i).
% 29.20/29.00  tff(decl_27633, type, fn_craniate_12: $i > $i).
% 29.20/29.00  tff(decl_27634, type, fn_craniate_13: $i > $i).
% 29.20/29.00  tff(decl_27635, type, fn_craniate_14: $i > $i).
% 29.20/29.00  tff(decl_27636, type, fn_craniate_15: $i > $i).
% 29.20/29.00  tff(decl_27637, type, fn_craniate_16: $i > $i).
% 29.20/29.00  tff(decl_27638, type, fn_craniate_17: $i > $i).
% 29.20/29.00  tff(decl_27639, type, fn_craniate_18: $i > $i).
% 29.20/29.00  tff(decl_27640, type, fn_craniate_19: $i > $i).
% 29.20/29.00  tff(decl_27641, type, fn_eumetazoan_8: $i > $i).
% 29.20/29.00  tff(decl_27642, type, fn_eumetazoan_9: $i > $i).
% 29.20/29.00  tff(decl_27643, type, fn_eumetazoan_1: $i > $i).
% 29.20/29.00  tff(decl_27644, type, crassula_erecta_1: $i > $o).
% 29.20/29.00  tff(decl_27645, type, 'Crassula-Erecta': $i).
% 29.20/29.00  tff(decl_27646, type, 'Crassula erecta is commonly called pygmy weed. It is a native of dry, sandy regions in the western United States.': $i).
% 29.20/29.00  tff(decl_27647, type, 'pygmy weed': $i).
% 29.20/29.00  tff(decl_27648, type, 'pygmy-weed': $i).
% 29.20/29.00  tff(decl_27649, type, 'crassula erecta': $i).
% 29.20/29.00  tff(decl_27650, type, 'crassula-erecta': $i).
% 29.20/29.00  tff(decl_27651, type, 'Crassulacean-Acid-Metabolism': $i).
% 29.20/29.00  tff(decl_27652, type, 'Type of photosynthesis that evolved as an adaptation to arid conditions.  Stomata are open at night and CO2 is taken in by the plant to be stored in an organic acid. During the day, stomata are closed and CO2 is released from the organic acid within the plant and used for photosynthesis.': $i).
% 29.20/29.00  tff(decl_27653, type, 'cam pathway': $i).
% 29.20/29.00  tff(decl_27654, type, 'crassulacean acid metabolism pathway': $i).
% 29.20/29.00  tff(decl_27655, type, 'perform crassulacean acid metabolism': $i).
% 29.20/29.00  tff(decl_27656, type, 'crassulacean acid metabolism': $i).
% 29.20/29.00  tff(decl_27657, type, 'crassulacean-acid-metabolism': $i).
% 29.20/29.00  tff(decl_27658, type, fn_crassulacean_acid_metabolism_1: $i > $i).
% 29.20/29.00  tff(decl_27659, type, fn_crassulacean_acid_metabolism_2: $i > $i).
% 29.20/29.00  tff(decl_27660, type, fn_crassulacean_acid_metabolism_3: $i > $i).
% 29.20/29.00  tff(decl_27661, type, fn_crassulacean_acid_metabolism_4: $i > $i).
% 29.20/29.00  tff(decl_27662, type, fn_crassulacean_acid_metabolism_5: $i > $i).
% 29.20/29.00  tff(decl_27663, type, fn_crassulacean_acid_metabolism_6: $i > $i).
% 29.20/29.00  tff(decl_27664, type, fn_crassulacean_acid_metabolism_7: $i > $i).
% 29.20/29.00  tff(decl_27665, type, fn_crassulacean_acid_metabolism_8: $i > $i).
% 29.20/29.00  tff(decl_27666, type, fn_crassulacean_acid_metabolism_9: $i > $i).
% 29.20/29.00  tff(decl_27667, type, fn_crassulacean_acid_metabolism_10: $i > $i).
% 29.20/29.00  tff(decl_27668, type, fn_crassulacean_acid_metabolism_11: $i > $i).
% 29.20/29.00  tff(decl_27669, type, fn_crassulacean_acid_metabolism_12: $i > $i).
% 29.20/29.00  tff(decl_27670, type, fn_crassulacean_acid_metabolism_13: $i > $i).
% 29.20/29.00  tff(decl_27671, type, fn_crassulacean_acid_metabolism_14: $i > $i).
% 29.20/29.00  tff(decl_27672, type, fn_crassulacean_acid_metabolism_15: $i > $i).
% 29.20/29.00  tff(decl_27673, type, fn_crassulacean_acid_metabolism_18: $i > $i).
% 29.20/29.00  tff(decl_27674, type, fn_crassulacean_acid_metabolism_19: $i > $i).
% 29.20/29.00  tff(decl_27675, type, fn_crassulacean_acid_metabolism_20: $i > $i).
% 29.20/29.00  tff(decl_27676, type, fn_crassulacean_acid_metabolism_21: $i > $i).
% 29.20/29.00  tff(decl_27677, type, fn_crassulacean_acid_metabolism_22: $i > $i).
% 29.20/29.00  tff(decl_27678, type, fn_crassulacean_acid_metabolism_23: $i > $i).
% 29.20/29.00  tff(decl_27679, type, fn_crassulacean_acid_metabolism_24: $i > $i).
% 29.20/29.00  tff(decl_27680, type, fn_crassulacean_acid_metabolism_25: $i > $i).
% 29.20/29.00  tff(decl_27681, type, fn_crassulacean_acid_metabolism_26: $i > $i).
% 29.20/29.00  tff(decl_27682, type, fn_crassulacean_acid_metabolism_27: $i > $i).
% 29.20/29.00  tff(decl_27683, type, fn_crassulacean_acid_metabolism_28: $i > $i).
% 29.20/29.00  tff(decl_27684, type, fn_crassulacean_acid_metabolism_29: $i > $i).
% 29.20/29.00  tff(decl_27685, type, fn_crassulacean_acid_metabolism_30: $i > $i).
% 29.20/29.00  tff(decl_27686, type, fn_crassulacean_acid_metabolism_31: $i > $i).
% 29.20/29.00  tff(decl_27687, type, fn_crassulacean_acid_metabolism_32: $i > $i).
% 29.20/29.00  tff(decl_27688, type, fn_crassulacean_acid_metabolism_33: $i > $i).
% 29.20/29.00  tff(decl_27689, type, fn_crassulacean_acid_metabolism_42: $i > $i).
% 29.20/29.00  tff(decl_27690, type, fn_crassulacean_acid_metabolism_43: $i > $i).
% 29.20/29.00  tff(decl_27691, type, fn_crassulacean_acid_metabolism_44: $i > $i).
% 29.20/29.00  tff(decl_27692, type, fn_crassulacean_acid_metabolism_45: $i > $i).
% 29.20/29.00  tff(decl_27693, type, fn_crassulacean_acid_metabolism_46: $i > $i).
% 29.20/29.00  tff(decl_27694, type, fn_crassulacean_acid_metabolism_49: $i > $i).
% 29.20/29.00  tff(decl_27695, type, fn_crassulacean_acid_metabolism_50: $i > $i).
% 29.20/29.00  tff(decl_27696, type, fn_crassulacean_acid_metabolism_51: $i > $i).
% 29.20/29.00  tff(decl_27697, type, fn_crassulacean_acid_metabolism_54: $i > $i).
% 29.20/29.00  tff(decl_27698, type, fn_crassulacean_acid_metabolism_61: $i > $i).
% 29.20/29.00  tff(decl_27699, type, fn_crassulacean_acid_metabolism_69: $i > $i).
% 29.20/29.00  tff(decl_27700, type, fn_crassulacean_acid_metabolism_71: $i > $i).
% 29.20/29.00  tff(decl_27701, type, fn_crassulacean_acid_metabolism_74: $i > $i).
% 29.20/29.00  tff(decl_27702, type, fn_crassulacean_acid_metabolism_75: $i > $i).
% 29.20/29.00  tff(decl_27703, type, fn_crassulacean_acid_metabolism_76: $i > $i).
% 29.20/29.00  tff(decl_27704, type, fn_crassulacean_acid_metabolism_78: $i > $i).
% 29.20/29.00  tff(decl_27705, type, fn_crassulacean_acid_metabolism_79: $i > $i).
% 29.20/29.00  tff(decl_27706, type, fn_crassulacean_acid_metabolism_80: $i > $i).
% 29.20/29.00  tff(decl_27707, type, fn_crassulacean_acid_metabolism_81: $i > $i).
% 29.20/29.00  tff(decl_27708, type, fn_crassulacean_acid_metabolism_82: $i > $i).
% 29.20/29.00  tff(decl_27709, type, fn_crassulacean_acid_metabolism_83: $i > $i).
% 29.20/29.00  tff(decl_27710, type, fn_crassulacean_acid_metabolism_85: $i > $i).
% 29.20/29.00  tff(decl_27711, type, fn_crassulacean_acid_metabolism_86: $i > $i).
% 29.20/29.00  tff(decl_27712, type, fn_crassulacean_acid_metabolism_89: $i > $i).
% 29.20/29.00  tff(decl_27713, type, fn_crassulacean_acid_metabolism_91: $i > $i).
% 29.20/29.00  tff(decl_27714, type, fn_crassulacean_acid_metabolism_92: $i > $i).
% 29.20/29.00  tff(decl_27715, type, fn_crassulacean_acid_metabolism_103: $i > $i).
% 29.20/29.00  tff(decl_27716, type, fn_crassulacean_acid_metabolism_108: $i > $i).
% 29.20/29.00  tff(decl_27717, type, fn_crassulacean_acid_metabolism_109: $i > $i).
% 29.20/29.00  tff(decl_27718, type, fn_crassulacean_acid_metabolism_110: $i > $i).
% 29.20/29.00  tff(decl_27719, type, fn_crassulacean_acid_metabolism_111: $i > $i).
% 29.20/29.00  tff(decl_27720, type, fn_crassulacean_acid_metabolism_112: $i > $i).
% 29.20/29.00  tff(decl_27721, type, fn_crassulacean_acid_metabolism_113: $i > $i).
% 29.20/29.00  tff(decl_27722, type, fn_crassulacean_acid_metabolism_117: $i > $i).
% 29.20/29.00  tff(decl_27723, type, fn_crassulacean_acid_metabolism_121: $i > $i).
% 29.20/29.00  tff(decl_27724, type, fn_crassulacean_acid_metabolism_122: $i > $i).
% 29.20/29.00  tff(decl_27725, type, fn_crassulacean_acid_metabolism_123: $i > $i).
% 29.20/29.00  tff(decl_27726, type, fn_crassulacean_acid_metabolism_124: $i > $i).
% 29.20/29.00  tff(decl_27727, type, fn_crassulacean_acid_metabolism_126: $i > $i).
% 29.20/29.00  tff(decl_27728, type, fn_crassulacean_acid_metabolism_127: $i > $i).
% 29.20/29.00  tff(decl_27729, type, fn_crassulacean_acid_metabolism_128: $i > $i).
% 29.20/29.00  tff(decl_27730, type, fn_crassulacean_acid_metabolism_130: $i > $i).
% 29.20/29.00  tff(decl_27731, type, fn_crassulacean_acid_metabolism_131: $i > $i).
% 29.20/29.00  tff(decl_27732, type, fn_crassulacean_acid_metabolism_132: $i > $i).
% 29.20/29.00  tff(decl_27733, type, fn_crassulacean_acid_metabolism_133: $i > $i).
% 29.20/29.00  tff(decl_27734, type, fn_crassulacean_acid_metabolism_136: $i > $i).
% 29.20/29.00  tff(decl_27735, type, fn_crassulacean_acid_metabolism_137: $i > $i).
% 29.20/29.00  tff(decl_27736, type, fn_crassulacean_acid_metabolism_140: $i > $i).
% 29.20/29.00  tff(decl_27737, type, fn_crassulacean_acid_metabolism_141: $i > $i).
% 29.20/29.00  tff(decl_27738, type, fn_crassulacean_acid_metabolism_142: $i > $i).
% 29.20/29.00  tff(decl_27739, type, fn_crassulacean_acid_metabolism_144: $i > $i).
% 29.20/29.00  tff(decl_27740, type, fn_crassulacean_acid_metabolism_158: $i > $i).
% 29.20/29.00  tff(decl_27741, type, fn_crassulacean_acid_metabolism_159: $i > $i).
% 29.20/29.00  tff(decl_27742, type, fn_crassulacean_acid_metabolism_162: $i > $i).
% 29.20/29.00  tff(decl_27743, type, fn_crassulacean_acid_metabolism_164: $i > $i).
% 29.20/29.00  tff(decl_27744, type, fn_crassulacean_acid_metabolism_165: $i > $i).
% 29.20/29.00  tff(decl_27745, type, fn_crassulacean_acid_metabolism_166: $i > $i).
% 29.20/29.00  tff(decl_27746, type, fn_crassulacean_acid_metabolism_167: $i > $i).
% 29.20/29.00  tff(decl_27747, type, fn_crassulacean_acid_metabolism_168: $i > $i).
% 29.20/29.00  tff(decl_27748, type, fn_crassulacean_acid_metabolism_169: $i > $i).
% 29.20/29.00  tff(decl_27749, type, fn_reduction_2: $i > $i).
% 29.20/29.00  tff(decl_27750, type, fn_stoma_8: $i > $i).
% 29.20/29.00  tff(decl_27751, type, fn_thylakoid_membrane_3: $i > $i).
% 29.20/29.00  tff(decl_27752, type, fn_thylakoid_membrane_1: $i > $i).
% 29.20/29.00  tff(decl_27753, type, fn_plant_cell_81: $i > $i).
% 29.20/29.00  tff(decl_27754, type, fn_eukaryotic_calvin_cycle_1: $i > $i).
% 29.20/29.00  tff(decl_27755, type, fn_light_reaction_3: $i > $i).
% 29.20/29.00  tff(decl_27756, type, fn_plant_cell_29: $i > $i).
% 29.20/29.00  tff(decl_27757, type, fn_plant_metabolic_cell_5: $i > $i).
% 29.20/29.00  tff(decl_27758, type, fn_plant_cell_79: $i > $i).
% 29.20/29.00  tff(decl_27759, type, fn_eukaryotic_calvin_cycle_2: $i > $i).
% 29.20/29.00  tff(decl_27760, type, fn_transpiration_21: $i > $i).
% 29.20/29.00  tff(decl_27761, type, fn_thylakoid_membrane_8: $i > $i).
% 29.20/29.00  tff(decl_27762, type, fn_thylakoid_membrane_12: $i > $i).
% 29.20/29.00  tff(decl_27763, type, fn_thylakoid_membrane_13: $i > $i).
% 29.20/29.00  tff(decl_27764, type, fn_thylakoid_membrane_14: $i > $i).
% 29.20/29.00  tff(decl_27765, type, fn_crassulacean_acid_metabolism_154: $i > $i).
% 29.20/29.00  tff(decl_27766, type, fn_crassulacean_acid_metabolism_155: $i > $i).
% 29.20/29.00  tff(decl_27767, type, fn_photosynthesis_42: $i > $i).
% 29.20/29.00  tff(decl_27768, type, fn_crassulacean_acid_metabolism_160: $i > $i).
% 29.20/29.00  tff(decl_27769, type, fn_photosynthesis_101: $i > $i).
% 29.20/29.00  tff(decl_27770, type, fn_photosynthesis_108: $i > $i).
% 29.20/29.00  tff(decl_27771, type, fn_photosynthesis_107: $i > $i).
% 29.20/29.00  tff(decl_27772, type, fn_photosynthesis_95: $i > $i).
% 29.20/29.00  tff(decl_27773, type, fn_photosynthesis_100: $i > $i).
% 29.20/29.00  tff(decl_27774, type, fn_photosynthesis_97: $i > $i).
% 29.20/29.00  tff(decl_27775, type, fn_photosynthesis_98: $i > $i).
% 29.20/29.00  tff(decl_27776, type, fn_photosynthesis_102: $i > $i).
% 29.20/29.00  tff(decl_27777, type, 'Crayfish': $i).
% 29.20/29.00  tff(decl_27778, type, 'A small freshwater crustacean resembling a clawed lobster.': $i).
% 29.20/29.00  tff(decl_27779, type, crayfish: $i).
% 29.20/29.00  tff(decl_27780, type, 'Create': $i).
% 29.20/29.00  tff(decl_27781, type, appear: $i).
% 29.20/29.00  tff(decl_27782, type, reappear: $i).
% 29.20/29.00  tff(decl_27783, type, 're appear': $i).
% 29.20/29.00  tff(decl_27784, type, 're-appear': $i).
% 29.20/29.00  tff(decl_27785, type, initiate: $i).
% 29.20/29.00  tff(decl_27786, type, create_transgenic_animal_1: $i > $o).
% 29.20/29.00  tff(decl_27787, type, 'Create-Transgenic-Animal': $i).
% 29.20/29.00  tff(decl_27788, type, 'To create an animal whose genome contains a gene introduced from another organism of the same of a different species.': $i).
% 29.20/29.00  tff(decl_27789, type, 'create transgenic animal': $i).
% 29.20/29.00  tff(decl_27790, type, 'create-transgenic-animal': $i).
% 29.20/29.00  tff(decl_27791, type, fn_create_transgenic_animal_2: $i > $i).
% 29.20/29.00  tff(decl_27792, type, fn_create_transgenic_animal_3: $i > $i).
% 29.20/29.00  tff(decl_27793, type, fn_create_transgenic_animal_6: $i > $i).
% 29.20/29.00  tff(decl_27794, type, fn_create_transgenic_animal_7: $i > $i).
% 29.20/29.00  tff(decl_27795, type, fn_create_transgenic_animal_8: $i > $i).
% 29.20/29.00  tff(decl_27796, type, fn_create_transgenic_animal_9: $i > $i).
% 29.20/29.00  tff(decl_27797, type, fn_create_transgenic_animal_10: $i > $i).
% 29.20/29.00  tff(decl_27798, type, fn_create_transgenic_animal_11: $i > $i).
% 29.20/29.00  tff(decl_27799, type, fn_create_transgenic_animal_12: $i > $i).
% 29.20/29.00  tff(decl_27800, type, transgenic_organism_1: $i > $o).
% 29.20/29.00  tff(decl_27801, type, fn_create_transgenic_animal_13: $i > $i).
% 29.20/29.00  tff(decl_27802, type, fn_create_transgenic_animal_14: $i > $i).
% 29.20/29.00  tff(decl_27803, type, fn_create_transgenic_animal_15: $i > $i).
% 29.20/29.00  tff(decl_27804, type, fn_create_transgenic_animal_16: $i > $i).
% 29.20/29.00  tff(decl_27805, type, fn_create_transgenic_animal_17: $i > $i).
% 29.20/29.00  tff(decl_27806, type, fn_create_transgenic_animal_18: $i > $i).
% 29.20/29.00  tff(decl_27807, type, fn_create_transgenic_animal_19: $i > $i).
% 29.20/29.00  tff(decl_27808, type, inject_dna_with_needle_1: $i > $o).
% 29.20/29.00  tff(decl_27809, type, fn_create_transgenic_animal_20: $i > $i).
% 29.20/29.00  tff(decl_27810, type, fn_create_transgenic_animal_21: $i > $i).
% 29.20/29.00  tff(decl_27811, type, fn_create_transgenic_animal_22: $i > $i).
% 29.20/29.00  tff(decl_27812, type, fn_create_transgenic_animal_23: $i > $i).
% 29.20/29.00  tff(decl_27813, type, fn_create_transgenic_animal_24: $i > $i).
% 29.20/29.00  tff(decl_27814, type, recombinant_plasmid_1: $i > $o).
% 29.20/29.00  tff(decl_27815, type, fn_create_transgenic_animal_25: $i > $i).
% 29.20/29.00  tff(decl_27816, type, fn_create_transgenic_animal_26: $i > $i).
% 29.20/29.00  tff(decl_27817, type, fn_create_transgenic_animal_27: $i > $i).
% 29.20/29.00  tff(decl_27818, type, fn_create_transgenic_animal_28: $i > $i).
% 29.20/29.00  tff(decl_27819, type, fn_create_transgenic_animal_29: $i > $i).
% 29.20/29.00  tff(decl_27820, type, fn_fertilization_2: $i > $i).
% 29.20/29.00  tff(decl_27821, type, gamete_1: $i > $o).
% 29.20/29.00  tff(decl_27822, type, fn_get_free_dna_into_cell_7: $i > $i).
% 29.20/29.00  tff(decl_27823, type, fn_get_free_dna_into_cell_5: $i > $i).
% 29.20/29.00  tff(decl_27824, type, fn_get_free_dna_into_cell_2: $i > $i).
% 29.20/29.00  tff(decl_27825, type, fn_get_free_dna_into_cell_6: $i > $i).
% 29.20/29.00  tff(decl_27826, type, creator_1: $i > $o).
% 29.20/29.00  tff(decl_27827, type, 'Creator': $i).
% 29.20/29.00  tff(decl_27828, type, creator: $i).
% 29.20/29.00  tff(decl_27829, type, fn_creator_1: $i > $i).
% 29.20/29.00  tff(decl_27830, type, fn_creator_2: $i > $i).
% 29.20/29.00  tff(decl_27831, type, crenarchaeota_1: $i > $o).
% 29.20/29.00  tff(decl_27832, type, 'Crenarchaeota': $i).
% 29.20/29.00  tff(decl_27833, type, 'A taxon of archaea including sulfur eaters and some extreme thermophiles.': $i).
% 29.20/29.00  tff(decl_27834, type, crenarchaeota: $i).
% 29.20/29.00  tff(decl_27835, type, euryarchaeota_1: $i > $o).
% 29.20/29.00  tff(decl_27836, type, cretinism_1: $i > $o).
% 29.20/29.00  tff(decl_27837, type, 'Cretinism': $i).
% 29.20/29.00  tff(decl_27838, type, 'A condition of stunted physical and mental development due to congenital thyroid deficiency.': $i).
% 29.20/29.00  tff(decl_27839, type, cretinism: $i).
% 29.20/29.00  tff(decl_27840, type, metabolic_disorder_1: $i > $o).
% 29.20/29.00  tff(decl_27841, type, hypopituitarism_1: $i > $o).
% 29.20/29.00  tff(decl_27842, type, gigantism_1: $i > $o).
% 29.20/29.00  tff(decl_27843, type, hyperthyroidism_1: $i > $o).
% 29.20/29.00  tff(decl_27844, type, mitochondrial_myopathy_1: $i > $o).
% 29.20/29.00  tff(decl_27845, type, diabetes_mellitus_1: $i > $o).
% 29.20/29.00  tff(decl_27846, type, 'Creutzfeldt-Jacob-Disease': $i).
% 29.20/29.00  tff(decl_27847, type, 'A prion-based neurological disorder in which the brain tissue becomes spongey. The disease is progressive and always fatal.': $i).
% 29.20/29.00  tff(decl_27848, type, 'creutzfeldt jacob disease': $i).
% 29.20/29.00  tff(decl_27849, type, 'creutzfeldt-jacob-disease': $i).
% 29.20/29.00  tff(decl_27850, type, 'Cri-Du-Chat-Syndrome': $i).
% 29.20/29.00  tff(decl_27851, type, 'A disorder stemming from a missing portion of chromosome 5; causes mental retardation and other symptoms.': $i).
% 29.20/29.00  tff(decl_27852, type, 'cri du chat syndrome': $i).
% 29.20/29.00  tff(decl_27853, type, 'cri-du-chat-syndrome': $i).
% 29.20/29.00  tff(decl_27854, type, 'Cricket': $i).
% 29.20/29.00  tff(decl_27855, type, 'Insect of the family Gryllidae, which resemble grasshoppers. Crickets have long antennae and powerful hind legs for jumping, and are generally nocturnal.': $i).
% 29.20/29.00  tff(decl_27856, type, cricket: $i).
% 29.20/29.00  tff(decl_27857, type, 'Crista': $i).
% 29.20/29.00  tff(decl_27858, type, 'The cristae are the foldings of the inner mitochondrial membrane which gives the inner membrane a large surface area that enhances the productivity of cellular respiration.': $i).
% 29.20/29.00  tff(decl_27859, type, cristae: $i).
% 29.20/29.00  tff(decl_27860, type, crista: $i).
% 29.20/29.00  tff(decl_27861, type, fn_crista_2: $i > $i).
% 29.20/29.00  tff(decl_27862, type, fn_crista_5: $i > $i).
% 29.20/29.00  tff(decl_27863, type, fn_crista_6: $i > $i).
% 29.20/29.00  tff(decl_27864, type, fn_crista_7: $i > $i).
% 29.20/29.00  tff(decl_27865, type, fn_crista_8: $i > $i).
% 29.20/29.00  tff(decl_27866, type, fn_crista_9: $i > $i).
% 29.20/29.00  tff(decl_27867, type, fn_crista_10: $i > $i).
% 29.20/29.00  tff(decl_27868, type, fn_crista_11: $i > $i).
% 29.20/29.00  tff(decl_27869, type, fn_crista_12: $i > $i).
% 29.20/29.00  tff(decl_27870, type, fn_crista_13: $i > $i).
% 29.20/29.00  tff(decl_27871, type, fn_crista_14: $i > $i).
% 29.20/29.00  tff(decl_27872, type, fn_crista_15: $i > $i).
% 29.20/29.00  tff(decl_27873, type, fn_crista_16: $i > $i).
% 29.20/29.00  tff(decl_27874, type, fn_crista_17: $i > $i).
% 29.20/29.00  tff(decl_27875, type, fn_crista_19: $i > $i).
% 29.20/29.00  tff(decl_27876, type, fn_crista_20: $i > $i).
% 29.20/29.00  tff(decl_27877, type, fn_crista_21: $i > $i).
% 29.20/29.00  tff(decl_27878, type, fn_crista_22: $i > $i).
% 29.20/29.00  tff(decl_27879, type, fn_crista_23: $i > $i).
% 29.20/29.00  tff(decl_27880, type, fn_crista_24: $i > $i).
% 29.20/29.00  tff(decl_27881, type, fn_crista_25: $i > $i).
% 29.20/29.00  tff(decl_27882, type, fn_crista_26: $i > $i).
% 29.20/29.00  tff(decl_27883, type, fn_crista_27: $i > $i).
% 29.20/29.00  tff(decl_27884, type, fn_crista_28: $i > $i).
% 29.20/29.00  tff(decl_27885, type, fn_crista_29: $i > $i).
% 29.20/29.00  tff(decl_27886, type, fn_crista_30: $i > $i).
% 29.20/29.00  tff(decl_27887, type, fn_crista_31: $i > $i).
% 29.20/29.00  tff(decl_27888, type, fn_crista_32: $i > $i).
% 29.20/29.00  tff(decl_27889, type, fn_crista_33: $i > $i).
% 29.20/29.00  tff(decl_27890, type, fn_crista_34: $i > $i).
% 29.20/29.00  tff(decl_27891, type, fn_crista_35: $i > $i).
% 29.20/29.00  tff(decl_27892, type, fn_crista_36: $i > $i).
% 29.20/29.00  tff(decl_27893, type, fn_crista_37: $i > $i).
% 29.20/29.00  tff(decl_27894, type, fn_crista_38: $i > $i).
% 29.20/29.00  tff(decl_27895, type, fn_crista_39: $i > $i).
% 29.20/29.00  tff(decl_27896, type, fn_eukaryotic_cellular_respiration_60: $i > $i).
% 29.20/29.00  tff(decl_27897, type, fn_eukaryotic_cellular_respiration_143: $i > $i).
% 29.20/29.00  tff(decl_27898, type, fn_eukaryotic_cellular_respiration_119: $i > $i).
% 29.20/29.00  tff(decl_27899, type, fn_eukaryotic_cellular_respiration_47: $i > $i).
% 29.20/29.00  tff(decl_27900, type, fn_eukaryotic_cellular_respiration_145: $i > $i).
% 29.20/29.00  tff(decl_27901, type, fn_eukaryotic_cellular_respiration_61: $i > $i).
% 29.20/29.00  tff(decl_27902, type, fn_eukaryotic_cellular_respiration_140: $i > $i).
% 29.20/29.00  tff(decl_27903, type, fn_eukaryotic_cellular_respiration_141: $i > $i).
% 29.20/29.00  tff(decl_27904, type, fn_eukaryotic_cellular_respiration_59: $i > $i).
% 29.20/29.00  tff(decl_27905, type, fn_eukaryotic_cellular_respiration_144: $i > $i).
% 29.20/29.00  tff(decl_27906, type, fn_eukaryotic_cellular_respiration_139: $i > $i).
% 29.20/29.00  tff(decl_27907, type, fn_eukaryotic_cellular_respiration_131: $i > $i).
% 29.20/29.00  tff(decl_27908, type, fn_eukaryotic_cellular_respiration_153: $i > $i).
% 29.20/29.00  tff(decl_27909, type, fn_mitochondrion_118: $i > $i).
% 29.20/29.00  tff(decl_27910, type, fn_eukaryotic_cellular_respiration_103: $i > $i).
% 29.20/29.00  tff(decl_27911, type, fn_mitochondrion_53: $i > $i).
% 29.20/29.00  tff(decl_27912, type, fn_eukaryotic_cellular_respiration_104: $i > $i).
% 29.20/29.00  tff(decl_27913, type, fn_eukaryotic_cellular_respiration_79: $i > $i).
% 29.20/29.00  tff(decl_27914, type, fn_eukaryotic_cellular_respiration_15: $i > $i).
% 29.20/29.00  tff(decl_27915, type, fn_mitochondrion_154: $i > $i).
% 29.20/29.00  tff(decl_27916, type, fn_mitochondrion_71: $i > $i).
% 29.20/29.00  tff(decl_27917, type, fn_eukaryotic_cellular_respiration_149: $i > $i).
% 29.20/29.00  tff(decl_27918, type, fn_mitochondrion_72: $i > $i).
% 29.20/29.00  tff(decl_27919, type, fn_eukaryotic_cellular_respiration_136: $i > $i).
% 29.20/29.00  tff(decl_27920, type, fn_mitochondrion_156: $i > $i).
% 29.20/29.00  tff(decl_27921, type, fn_eukaryotic_cellular_respiration_99: $i > $i).
% 29.20/29.00  tff(decl_27922, type, fn_eukaryotic_cellular_respiration_150: $i > $i).
% 29.20/29.00  tff(decl_27923, type, fn_crista_3: $i > $i).
% 29.20/29.00  tff(decl_27924, type, fn_crista_18: $i > $i).
% 29.20/29.00  tff(decl_27925, type, fn_crista_4: $i > $i).
% 29.20/29.00  tff(decl_27926, type, 'Cro-Magnon': $i).
% 29.20/29.00  tff(decl_27927, type, 'Informal name of the first modern humans to appear in Europe, about 43,000 years before present.': $i).
% 29.20/29.00  tff(decl_27928, type, 'cro magnon': $i).
% 29.20/29.00  tff(decl_27929, type, 'cro-magnon': $i).
% 29.20/29.00  tff(decl_27930, type, 'Crocodilia': $i).
% 29.20/29.00  tff(decl_27931, type, 'Large group of reptiles whose living members include alligators, crocodiles, caimans, and gharials.': $i).
% 29.20/29.00  tff(decl_27932, type, crocodilia: $i).
% 29.20/29.00  tff(decl_27933, type, crop_1: $i > $o).
% 29.20/29.00  tff(decl_27934, type, 'Crop': $i).
% 29.20/29.00  tff(decl_27935, type, 'Expanded portion of the alimentary canal found in some animals which is used to store food temporarily prior to digestion.': $i).
% 29.20/29.00  tff(decl_27936, type, crop: $i).
% 29.20/29.00  tff(decl_27937, type, 'Crop-Rotation': $i).
% 29.20/29.00  tff(decl_27938, type, 'The practice of growing a sequence of different crops in the same location throughout successive growing seasons.': $i).
% 29.20/29.00  tff(decl_27939, type, 'rotation of crop': $i).
% 29.20/29.00  tff(decl_27940, type, 'crop rotation': $i).
% 29.20/29.00  tff(decl_27941, type, 'crop-rotation': $i).
% 29.20/29.00  tff(decl_27942, type, 'Cross-breeding-event': $i).
% 29.20/29.00  tff(decl_27943, type, 'It refers to the reproduction (of an organism) by mating of individuals of different breeds, varieties, or species or to hybridize.': $i).
% 29.20/29.00  tff(decl_27944, type, cross: $i).
% 29.20/29.00  tff(decl_27945, type, mating: $i).
% 29.20/29.00  tff(decl_27946, type, breeding: $i).
% 29.20/29.00  tff(decl_27947, type, 'cross breeding event': $i).
% 29.20/29.00  tff(decl_27948, type, 'cross-breeding-event': $i).
% 29.20/29.00  tff(decl_27949, type, fn_cross_breeding_event_1: $i > $i).
% 29.20/29.00  tff(decl_27950, type, fn_cross_breeding_event_4: $i > $i).
% 29.20/29.00  tff(decl_27951, type, fn_cross_breeding_event_5: $i > $i).
% 29.20/29.00  tff(decl_27952, type, fn_cross_breeding_event_7: $i > $i).
% 29.20/29.00  tff(decl_27953, type, predict_1: $i > $o).
% 29.20/29.00  tff(decl_27954, type, fn_cross_breeding_event_8: $i > $i).
% 29.20/29.00  tff(decl_27955, type, fn_cross_breeding_event_9: $i > $i).
% 29.20/29.00  tff(decl_27956, type, fn_cross_breeding_event_10: $i > $i).
% 29.20/29.00  tff(decl_27957, type, fn_cross_breeding_event_11: $i > $i).
% 29.20/29.00  tff(decl_27958, type, fn_cross_breeding_event_12: $i > $i).
% 29.20/29.00  tff(decl_27959, type, fn_cross_breeding_event_13: $i > $i).
% 29.20/29.00  tff(decl_27960, type, fn_cross_breeding_event_14: $i > $i).
% 29.20/29.00  tff(decl_27961, type, fn_reproduction_3: $i > $i).
% 29.20/29.00  tff(decl_27962, type, cross_fostering_1: $i > $o).
% 29.20/29.00  tff(decl_27963, type, 'Cross-Fostering': $i).
% 29.20/29.00  tff(decl_27964, type, 'The practice of removing offspring from their parents to be raised by adults of another species.': $i).
% 29.20/29.00  tff(decl_27965, type, 'fostering of cross': $i).
% 29.20/29.00  tff(decl_27966, type, 'cross fostering': $i).
% 29.20/29.00  tff(decl_27967, type, 'cross-fostering': $i).
% 29.20/29.00  tff(decl_27968, type, cross_fostering_study_1: $i > $o).
% 29.20/29.00  tff(decl_27969, type, 'Cross-Fostering-Study': $i).
% 29.20/29.00  tff(decl_27970, type, 'A type of study in which offspring are removed from their parents and raised by surrogates. The purpose of such studies is to determine the effects of genetics and environment on various aspects of phenotype.': $i).
% 29.20/29.00  tff(decl_27971, type, 'cross fostering study': $i).
% 29.20/29.00  tff(decl_27972, type, 'cross-fostering-study': $i).
% 29.20/29.00  tff(decl_27973, type, ethology_1: $i > $o).
% 29.20/29.00  tff(decl_27974, type, crossing_over_1: $i > $o).
% 29.20/29.00  tff(decl_27975, type, 'Crossing-Over': $i).
% 29.20/29.00  tff(decl_27976, type, 'Chromosomal crossover (or crossing over) is the exchange of genetic material between homologous chromosomes. This often occurs during prophase 1 of meiosis. The chromosomes produced after crossing over are not identical to their homologues': $i).
% 29.20/29.00  tff(decl_27977, type, recombination: $i).
% 29.20/29.00  tff(decl_27978, type, 'cross over': $i).
% 29.20/29.00  tff(decl_27979, type, 'over of crossing': $i).
% 29.20/29.00  tff(decl_27980, type, 'crossing over': $i).
% 29.20/29.00  tff(decl_27981, type, 'crossing-over': $i).
% 29.20/29.00  tff(decl_27982, type, fn_crossing_over_1: $i > $i).
% 29.20/29.00  tff(decl_27983, type, fn_crossing_over_2: $i > $i).
% 29.20/29.00  tff(decl_27984, type, fn_crossing_over_3: $i > $i).
% 29.20/29.00  tff(decl_27985, type, fn_crossing_over_4: $i > $i).
% 29.20/29.00  tff(decl_27986, type, fn_crossing_over_5: $i > $i).
% 29.20/29.00  tff(decl_27987, type, fn_crossing_over_6: $i > $i).
% 29.20/29.00  tff(decl_27988, type, tetrad_1: $i > $o).
% 29.20/29.00  tff(decl_27989, type, fn_crossing_over_7: $i > $i).
% 29.20/29.00  tff(decl_27990, type, fn_crossing_over_8: $i > $i).
% 29.20/29.00  tff(decl_27991, type, synaptonemal_complex_1: $i > $o).
% 29.20/29.00  tff(decl_27992, type, fn_crossing_over_9: $i > $i).
% 29.20/29.00  tff(decl_27993, type, fn_crossing_over_10: $i > $i).
% 29.20/29.00  tff(decl_27994, type, fn_crossing_over_11: $i > $i).
% 29.20/29.00  tff(decl_27995, type, fn_crossing_over_12: $i > $i).
% 29.20/29.00  tff(decl_27996, type, fn_crossing_over_13: $i > $i).
% 29.20/29.00  tff(decl_27997, type, fn_crossing_over_14: $i > $i).
% 29.20/29.00  tff(decl_27998, type, fn_crossing_over_15: $i > $i).
% 29.20/29.00  tff(decl_27999, type, fn_crossing_over_16: $i > $i).
% 29.20/29.00  tff(decl_28000, type, fn_crossing_over_17: $i > $i).
% 29.20/29.00  tff(decl_28001, type, fn_crossing_over_18: $i > $i).
% 29.20/29.00  tff(decl_28002, type, fn_crossing_over_19: $i > $i).
% 29.20/29.00  tff(decl_28003, type, fn_crossing_over_20: $i > $i).
% 29.20/29.00  tff(decl_28004, type, fn_crossing_over_21: $i > $i).
% 29.20/29.00  tff(decl_28005, type, fn_crossing_over_22: $i > $i).
% 29.20/29.00  tff(decl_28006, type, fn_crossing_over_23: $i > $i).
% 29.20/29.00  tff(decl_28007, type, fn_crossing_over_24: $i > $i).
% 29.20/29.00  tff(decl_28008, type, fn_crossing_over_25: $i > $i).
% 29.20/29.00  tff(decl_28009, type, fn_crossing_over_26: $i > $i).
% 29.20/29.00  tff(decl_28010, type, fn_crossing_over_27: $i > $i).
% 29.20/29.00  tff(decl_28011, type, fn_crossing_over_28: $i > $i).
% 29.20/29.00  tff(decl_28012, type, fn_crossing_over_29: $i > $i).
% 29.20/29.00  tff(decl_28013, type, fn_crossing_over_30: $i > $i).
% 29.20/29.00  tff(decl_28014, type, fn_crossing_over_31: $i > $i).
% 29.20/29.00  tff(decl_28015, type, fn_crossing_over_32: $i > $i).
% 29.20/29.00  tff(decl_28016, type, fn_crossing_over_33: $i > $i).
% 29.20/29.00  tff(decl_28017, type, fn_crossing_over_34: $i > $i).
% 29.20/29.00  tff(decl_28018, type, fn_crossing_over_35: $i > $i).
% 29.20/29.00  tff(decl_28019, type, fn_crossing_over_36: $i > $i).
% 29.20/29.00  tff(decl_28020, type, fn_crossing_over_37: $i > $i).
% 29.20/29.00  tff(decl_28021, type, fn_crossing_over_38: $i > $i).
% 29.20/29.00  tff(decl_28022, type, fn_crossing_over_39: $i > $i).
% 29.20/29.00  tff(decl_28023, type, fn_crossing_over_40: $i > $i).
% 29.20/29.00  tff(decl_28024, type, fn_crossing_over_41: $i > $i).
% 29.20/29.00  tff(decl_28025, type, fn_crossing_over_42: $i > $i).
% 29.20/29.00  tff(decl_28026, type, fn_crossing_over_43: $i > $i).
% 29.20/29.00  tff(decl_28027, type, fn_nucleic_acid_34: $i > $i).
% 29.20/29.00  tff(decl_28028, type, fn_nucleic_acid_33: $i > $i).
% 29.20/29.00  tff(decl_28029, type, fn_nucleic_acid_29: $i > $i).
% 29.20/29.00  tff(decl_28030, type, fn_nucleic_acid_28: $i > $i).
% 29.20/29.00  tff(decl_28031, type, fn_nucleic_acid_20: $i > $i).
% 29.20/29.00  tff(decl_28032, type, fn_crossing_over_50: $i > $i).
% 29.20/29.00  tff(decl_28033, type, fn_crossing_over_51: $i > $i).
% 29.20/29.00  tff(decl_28034, type, fn_crossing_over_49: $i > $i).
% 29.20/29.00  tff(decl_28035, type, fn_crossing_over_48: $i > $i).
% 29.20/29.00  tff(decl_28036, type, fn_crossing_over_46: $i > $i).
% 29.20/29.00  tff(decl_28037, type, fn_crossing_over_47: $i > $i).
% 29.20/29.00  tff(decl_28038, type, fn_crossing_over_45: $i > $i).
% 29.20/29.00  tff(decl_28039, type, fn_crossing_over_44: $i > $i).
% 29.20/29.00  tff(decl_28040, type, crossing_over_of_genes_1: $i > $o).
% 29.20/29.00  tff(decl_28041, type, 'Crossing-Over-of-Genes': $i).
% 29.20/29.00  tff(decl_28042, type, 'The exchange of genetic material within genes between homologous chromosomes.': $i).
% 29.20/29.00  tff(decl_28043, type, 'crossing over of gene': $i).
% 29.20/29.00  tff(decl_28044, type, 'crossing-over-of-gene': $i).
% 29.20/29.00  tff(decl_28045, type, crush_1: $i > $o).
% 29.20/29.00  tff(decl_28046, type, 'Crush': $i).
% 29.20/29.00  tff(decl_28047, type, 'To break by the application of pressure or squeezing, resulting in small fragments or powder.': $i).
% 29.20/29.00  tff(decl_28048, type, crush: $i).
% 29.20/29.00  tff(decl_28049, type, 'Crustacean': $i).
% 29.20/29.00  tff(decl_28050, type, 'Member of the arthropod subphylum Crustacea, a group of primarily aquatic animals including crabs, lobsters, copepods, water fleas, barnacles, and many others.': $i).
% 29.20/29.00  tff(decl_28051, type, crustacean: $i).
% 29.20/29.00  tff(decl_28052, type, crypt_1: $i > $o).
% 29.20/29.00  tff(decl_28053, type, 'Crypt': $i).
% 29.20/29.00  tff(decl_28054, type, 'Crypt is an adaptation that reduces the rate of transpiration by protecting the stomata from hot, dry wind.': $i).
% 29.20/29.00  tff(decl_28055, type, crypt: $i).
% 29.20/29.00  tff(decl_28056, type, fn_crypt_2: $i > $i).
% 29.20/29.00  tff(decl_28057, type, fn_crypt_3: $i > $i).
% 29.20/29.00  tff(decl_28058, type, fn_crypt_4: $i > $i).
% 29.20/29.00  tff(decl_28059, type, fn_water_evaporation_19: $i > $i).
% 29.20/29.00  tff(decl_28060, type, fn_water_evaporation_16: $i > $i).
% 29.20/29.00  tff(decl_28061, type, fn_crypt_1: $i > $i).
% 29.20/29.00  tff(decl_28062, type, cryptochrome_1: $i > $o).
% 29.20/29.00  tff(decl_28063, type, 'Cryptochrome': $i).
% 29.20/29.00  tff(decl_28064, type, 'A class of proteins sensitive to blue light, found in plants and animals. Cryptochromes are involved in circadian rhythms in plants and animals.': $i).
% 29.20/29.00  tff(decl_28065, type, cryptochrome: $i).
% 29.20/29.00  tff(decl_28066, type, 'Cs-Plus': $i).
% 29.20/29.00  tff(decl_28067, type, 'An Ion of Cesium with 1 positive charge.': $i).
% 29.20/29.00  tff(decl_28068, type, caesium: $i).
% 29.20/29.00  tff(decl_28069, type, 'plus of cs': $i).
% 29.20/29.00  tff(decl_28070, type, 'cs plus': $i).
% 29.20/29.00  tff(decl_28071, type, 'cs-plus': $i).
% 29.20/29.00  tff(decl_28072, type, fn_cs_plus_1: $i > $i).
% 29.20/29.00  tff(decl_28073, type, fn_cs_plus_2: $i > $i).
% 29.20/29.00  tff(decl_28074, type, fn_cs_plus_4: $i > $i).
% 29.20/29.00  tff(decl_28075, type, fn_cs_plus_6: $i > $i).
% 29.20/29.00  tff(decl_28076, type, fn_cs_plus_5: $i > $i).
% 29.20/29.00  tff(decl_28077, type, 'Ctenophora': $i).
% 29.20/29.00  tff(decl_28078, type, 'A phylum of animals characterized by a gelatinous body, modified radial symmetry, light-refracting comb rows of cilia, and colloblasts (sticky cells used to capture prey).': $i).
% 29.20/29.00  tff(decl_28079, type, ctenophore: $i).
% 29.20/29.00  tff(decl_28080, type, 'comb jellies': $i).
% 29.20/29.00  tff(decl_28081, type, 'comb-jellies': $i).
% 29.20/29.00  tff(decl_28082, type, ctenophora: $i).
% 29.20/29.00  tff(decl_28083, type, fn_ctenophora_1: $i > $i).
% 29.20/29.00  tff(decl_28084, type, fn_ctenophora_4: $i > $i).
% 29.20/29.00  tff(decl_28085, type, fn_ctenophora_5: $i > $i).
% 29.20/29.00  tff(decl_28086, type, fn_ctenophora_6: $i > $i).
% 29.20/29.00  tff(decl_28087, type, fn_ctenophora_7: $i > $i).
% 29.20/29.00  tff(decl_28088, type, fn_ctenophora_8: $i > $i).
% 29.20/29.00  tff(decl_28089, type, fn_ctenophora_9: $i > $i).
% 29.20/29.00  tff(decl_28090, type, fn_ctenophora_10: $i > $i).
% 29.20/29.00  tff(decl_28091, type, fn_ctenophora_11: $i > $i).
% 29.20/29.00  tff(decl_28092, type, fn_ctenophora_12: $i > $i).
% 29.20/29.00  tff(decl_28093, type, fn_ctenophora_13: $i > $i).
% 29.20/29.00  tff(decl_28094, type, fn_ctenophora_14: $i > $i).
% 29.20/29.00  tff(decl_28095, type, fn_ctenophora_15: $i > $i).
% 29.20/29.00  tff(decl_28096, type, fn_ctenophora_16: $i > $i).
% 29.20/29.00  tff(decl_28097, type, fn_ctenophora_17: $i > $i).
% 29.20/29.00  tff(decl_28098, type, fn_ctenophora_18: $i > $i).
% 29.20/29.00  tff(decl_28099, type, fn_ctenophora_3: $i > $i).
% 29.20/29.00  tff(decl_28100, type, fn_ctenophora_2: $i > $i).
% 29.20/29.00  tff(decl_28101, type, 'Cuboidal-Epithelium': $i).
% 29.20/29.00  tff(decl_28102, type, 'A type of epithetial tissue consisting of cube-shaped cells and specialized for secretion and absorption.': $i).
% 29.20/29.00  tff(decl_28103, type, 'cuboidal epithelium': $i).
% 29.20/29.00  tff(decl_28104, type, 'cuboidal-epithelium': $i).
% 29.20/29.00  tff(decl_28105, type, 'Cubozoan': $i).
% 29.20/29.00  tff(decl_28106, type, 'Member of a cnidarian taxon whose cnidocytes are especially toxic; known as sea wasps and box jellies.': $i).
% 29.20/29.00  tff(decl_28107, type, cubozoan: $i).
% 29.20/29.00  tff(decl_28108, type, cud_1: $i > $o).
% 29.20/29.00  tff(decl_28109, type, 'Cud': $i).
% 29.20/29.00  tff(decl_28110, type, 'In ruminant digestion, the cud is the partially digested, regurgitated and then reswallowed bolus of food that has been chewed a second time.': $i).
% 29.20/29.00  tff(decl_28111, type, cud: $i).
% 29.20/29.00  tff(decl_28112, type, 'Culture': $i).
% 29.20/29.00  tff(decl_28113, type, 'A microbiological culture, or microbial culture, is population of microbial cells grown in predetermined culture media under controlled laboratory conditions.': $i).
% 29.20/29.00  tff(decl_28114, type, fn_culturing_3: $i > $i).
% 29.20/29.00  tff(decl_28115, type, fn_culturing_2: $i > $i).
% 29.20/29.00  tff(decl_28116, type, 'Culture-Medium': $i).
% 29.20/29.00  tff(decl_28117, type, 'A liquid or gel designed to support the growth of microorganisms or cells or small plants. There are different types of media for growing different types of cells.': $i).
% 29.20/29.00  tff(decl_28118, type, 'nutrient medium': $i).
% 29.20/29.00  tff(decl_28119, type, 'growth medium': $i).
% 29.20/29.00  tff(decl_28120, type, 'medium of culture': $i).
% 29.20/29.00  tff(decl_28121, type, 'culture medium': $i).
% 29.20/29.00  tff(decl_28122, type, 'culture-medium': $i).
% 29.20/29.00  tff(decl_28123, type, fn_culture_medium_1: $i > $i).
% 29.20/29.00  tff(decl_28124, type, fn_culture_medium_2: $i > $i).
% 29.20/29.00  tff(decl_28125, type, cultured_stem_cell_1: $i > $o).
% 29.20/29.00  tff(decl_28126, type, 'Cultured-Stem-Cell': $i).
% 29.20/29.00  tff(decl_28127, type, 'The stem cell cultured in the laboratory.': $i).
% 29.20/29.00  tff(decl_28128, type, 'cultured stem cell': $i).
% 29.20/29.00  tff(decl_28129, type, 'cultured-stem-cell': $i).
% 29.20/29.00  tff(decl_28130, type, 'Culturing': $i).
% 29.20/29.00  tff(decl_28131, type, 'Culturing is an act of spawning, incubation, hatching, or rearing in a hatchery or other artificial production facility such as a spawning channel or spawning beach.': $i).
% 29.20/29.00  tff(decl_28132, type, culturing: $i).
% 29.20/29.00  tff(decl_28133, type, fn_culturing_1: $i > $i).
% 29.20/29.00  tff(decl_28134, type, fn_culturing_5: $i > $i).
% 29.20/29.00  tff(decl_28135, type, fn_culturing_6: $i > $i).
% 29.20/29.00  tff(decl_28136, type, curium_1: $i > $o).
% 29.20/29.00  tff(decl_28137, type, 'Curium': $i).
% 29.20/29.00  tff(decl_28138, type, 'Curium is a metal atom with atomic number 96. It is represented by the symbol Cm.': $i).
% 29.20/29.00  tff(decl_28139, type, curium: $i).
% 29.20/29.00  tff(decl_28140, type, cm: $i).
% 29.20/29.00  tff(decl_28141, type, fn_curium_3: $i > $i).
% 29.20/29.00  tff(decl_28142, type, fn_curium_4: $i > $i).
% 29.20/29.00  tff(decl_28143, type, fn_curium_5: $i > $i).
% 29.20/29.00  tff(decl_28144, type, fn_curium_9: $i > $i).
% 29.20/29.00  tff(decl_28145, type, fn_curium_10: $i > $i).
% 29.20/29.00  tff(decl_28146, type, fn_curium_11: $i > $i).
% 29.20/29.00  tff(decl_28147, type, fn_curium_12: $i > $i).
% 29.20/29.00  tff(decl_28148, type, "151": $i).
% 29.20/29.00  tff(decl_28149, type, "96": $i).
% 29.20/29.00  tff(decl_28150, type, fn_curium_7: $i > $i).
% 29.20/29.00  tff(decl_28151, type, fn_curium_8: $i > $i).
% 29.20/29.00  tff(decl_28152, type, fn_curium_6: $i > $i).
% 29.20/29.00  tff(decl_28153, type, cushion_1: $i > $o).
% 29.20/29.00  tff(decl_28154, type, 'Cushion': $i).
% 29.20/29.00  tff(decl_28155, type, 'Cushion protect things against mechanical force.': $i).
% 29.20/29.00  tff(decl_28156, type, cushion: $i).
% 29.20/29.00  tff(decl_28157, type, fn_cushion_1: $i > $i).
% 29.20/29.00  tff(decl_28158, type, fn_cushion_2: $i > $i).
% 29.20/29.00  tff(decl_28159, type, 'Cuticle-Plant': $i).
% 29.20/29.00  tff(decl_28160, type, 'A protective, hydrophobic covering produced by epidermal cells of leaves. The cuticle minimizes water loss.': $i).
% 29.20/29.00  tff(decl_28161, type, 'plant of cuticle': $i).
% 29.20/29.00  tff(decl_28162, type, 'cuticle plant': $i).
% 29.20/29.00  tff(decl_28163, type, 'cuticle-plant': $i).
% 29.20/29.00  tff(decl_28164, type, wax_1: $i > $o).
% 29.20/29.00  tff(decl_28165, type, 'Cyanobacterium': $i).
% 29.20/29.00  tff(decl_28166, type, 'One of a phylum of bacteria that gains energy via photosynthesis.': $i).
% 29.20/29.00  tff(decl_28167, type, 'blue green algae': $i).
% 29.20/29.00  tff(decl_28168, type, 'blue-green-algae': $i).
% 29.20/29.00  tff(decl_28169, type, cyanobacterium: $i).
% 29.20/29.00  tff(decl_28170, type, photosynthetic_prokaryote_1: $i > $o).
% 29.20/29.00  tff(decl_28171, type, fn_cyanobacterium_3: $i > $i).
% 29.20/29.00  tff(decl_28172, type, fn_cyanobacterium_4: $i > $i).
% 29.20/29.00  tff(decl_28173, type, fn_cyanobacterium_5: $i > $i).
% 29.20/29.00  tff(decl_28174, type, fn_cyanobacterium_6: $i > $i).
% 29.20/29.00  tff(decl_28175, type, fn_cyanobacterium_7: $i > $i).
% 29.20/29.00  tff(decl_28176, type, fn_cyanobacterium_8: $i > $i).
% 29.20/29.00  tff(decl_28177, type, fn_cyanobacterium_9: $i > $i).
% 29.20/29.00  tff(decl_28178, type, fn_cyanobacterium_14: $i > $i).
% 29.20/29.00  tff(decl_28179, type, fn_cyanobacterium_16: $i > $i).
% 29.20/29.00  tff(decl_28180, type, fn_cyanobacterium_18: $i > $i).
% 29.20/29.00  tff(decl_28181, type, fn_cyanobacterium_19: $i > $i).
% 29.20/29.00  tff(decl_28182, type, fn_cyanobacterium_20: $i > $i).
% 29.20/29.00  tff(decl_28183, type, fn_cyanobacterium_21: $i > $i).
% 29.20/29.00  tff(decl_28184, type, fn_cyanobacterium_22: $i > $i).
% 29.20/29.00  tff(decl_28185, type, fn_cyanobacterium_23: $i > $i).
% 29.20/29.00  tff(decl_28186, type, fn_cyanobacterium_24: $i > $i).
% 29.20/29.00  tff(decl_28187, type, fn_cyanobacterium_25: $i > $i).
% 29.20/29.00  tff(decl_28188, type, fn_cyanobacterium_26: $i > $i).
% 29.20/29.00  tff(decl_28189, type, fn_cyanobacterium_27: $i > $i).
% 29.20/29.00  tff(decl_28190, type, fn_cyanobacterium_28: $i > $i).
% 29.20/29.00  tff(decl_28191, type, fn_cyanobacterium_29: $i > $i).
% 29.20/29.00  tff(decl_28192, type, fn_cyanobacterium_30: $i > $i).
% 29.20/29.00  tff(decl_28193, type, fn_cyanobacterium_31: $i > $i).
% 29.20/29.00  tff(decl_28194, type, fn_cyanobacterium_32: $i > $i).
% 29.20/29.00  tff(decl_28195, type, fn_cyanobacterium_33: $i > $i).
% 29.20/29.00  tff(decl_28196, type, fn_cyanobacterium_34: $i > $i).
% 29.20/29.00  tff(decl_28197, type, fn_cyanobacterium_35: $i > $i).
% 29.20/29.00  tff(decl_28198, type, fn_photoautotroph_5: $i > $i).
% 29.20/29.00  tff(decl_28199, type, fn_photoautotroph_25: $i > $i).
% 29.20/29.00  tff(decl_28200, type, fn_photoautotroph_19: $i > $i).
% 29.20/29.00  tff(decl_28201, type, fn_photoautotroph_17: $i > $i).
% 29.20/29.00  tff(decl_28202, type, fn_photoautotroph_18: $i > $i).
% 29.20/29.00  tff(decl_28203, type, fn_photosynthetic_prokaryote_14: $i > $i).
% 29.20/29.00  tff(decl_28204, type, fn_photosynthetic_prokaryote_2: $i > $i).
% 29.20/29.00  tff(decl_28205, type, fn_cyanobacterium_12: $i > $i).
% 29.20/29.00  tff(decl_28206, type, fn_photosynthetic_prokaryote_29: $i > $i).
% 29.20/29.00  tff(decl_28207, type, fn_cyanobacterium_13: $i > $i).
% 29.20/29.00  tff(decl_28208, type, fn_photosynthetic_prokaryote_26: $i > $i).
% 29.20/29.00  tff(decl_28209, type, fn_cyanobacterium_11: $i > $i).
% 29.20/29.00  tff(decl_28210, type, fn_photosynthetic_prokaryote_27: $i > $i).
% 29.20/29.00  tff(decl_28211, type, fn_photosynthetic_prokaryote_3: $i > $i).
% 29.20/29.00  tff(decl_28212, type, fn_cyanobacterium_10: $i > $i).
% 29.20/29.00  tff(decl_28213, type, fn_photosynthetic_prokaryote_28: $i > $i).
% 29.20/29.00  tff(decl_28214, type, fn_photosynthetic_prokaryote_24: $i > $i).
% 29.20/29.00  tff(decl_28215, type, fn_photosynthetic_prokaryote_25: $i > $i).
% 29.20/29.00  tff(decl_28216, type, fn_photosynthetic_prokaryote_10: $i > $i).
% 29.20/29.00  tff(decl_28217, type, fn_photosynthetic_prokaryote_8: $i > $i).
% 29.20/29.00  tff(decl_28218, type, fn_photosynthetic_prokaryote_9: $i > $i).
% 29.20/29.00  tff(decl_28219, type, fn_photosynthetic_prokaryote_4: $i > $i).
% 29.20/29.00  tff(decl_28220, type, fn_photosynthetic_prokaryote_1: $i > $i).
% 29.20/29.00  tff(decl_28221, type, fn_photosynthetic_prokaryote_30: $i > $i).
% 29.20/29.00  tff(decl_28222, type, fn_photosynthetic_prokaryote_31: $i > $i).
% 29.20/29.00  tff(decl_28223, type, fn_photosynthetic_prokaryote_12: $i > $i).
% 29.20/29.00  tff(decl_28224, type, fn_photosynthetic_prokaryote_5: $i > $i).
% 29.20/29.00  tff(decl_28225, type, fn_photosynthetic_prokaryote_11: $i > $i).
% 29.20/29.00  tff(decl_28226, type, fn_photosynthetic_prokaryote_6: $i > $i).
% 29.20/29.00  tff(decl_28227, type, 'Cycad': $i).
% 29.20/29.00  tff(decl_28228, type, 'A phylum of gymnosperms with approximately 130 known species. Cycads have large cones and palm-like leaves.': $i).
% 29.20/29.00  tff(decl_28229, type, cycad: $i).
% 29.20/29.00  tff(decl_28230, type, fn_cycad_1: $i > $i).
% 29.20/29.00  tff(decl_28231, type, fn_cycad_4: $i > $i).
% 29.20/29.00  tff(decl_28232, type, fn_cycad_5: $i > $i).
% 29.20/29.00  tff(decl_28233, type, fn_cycad_6: $i > $i).
% 29.20/29.00  tff(decl_28234, type, fn_cycad_7: $i > $i).
% 29.20/29.00  tff(decl_28235, type, fn_cycad_8: $i > $i).
% 29.20/29.00  tff(decl_28236, type, fn_cycad_15: $i > $i).
% 29.20/29.00  tff(decl_28237, type, fn_cycad_16: $i > $i).
% 29.20/29.00  tff(decl_28238, type, fn_cycad_17: $i > $i).
% 29.20/29.00  tff(decl_28239, type, fn_cycad_18: $i > $i).
% 29.20/29.00  tff(decl_28240, type, fn_cycad_19: $i > $i).
% 29.20/29.00  tff(decl_28241, type, fn_cycad_20: $i > $i).
% 29.20/29.00  tff(decl_28242, type, fn_cycad_21: $i > $i).
% 29.20/29.00  tff(decl_28243, type, fn_cycad_22: $i > $i).
% 29.20/29.00  tff(decl_28244, type, fn_cycad_23: $i > $i).
% 29.20/29.00  tff(decl_28245, type, fn_cycad_24: $i > $i).
% 29.20/29.00  tff(decl_28246, type, fn_cycad_25: $i > $i).
% 29.20/29.00  tff(decl_28247, type, fn_cycad_26: $i > $i).
% 29.20/29.00  tff(decl_28248, type, fn_cycad_27: $i > $i).
% 29.20/29.00  tff(decl_28249, type, fn_cycad_28: $i > $i).
% 29.20/29.00  tff(decl_28250, type, fn_cycad_29: $i > $i).
% 29.20/29.00  tff(decl_28251, type, fn_cycad_30: $i > $i).
% 29.20/29.00  tff(decl_28252, type, fn_cycad_31: $i > $i).
% 29.20/29.00  tff(decl_28253, type, fn_cycad_32: $i > $i).
% 29.20/29.00  tff(decl_28254, type, fn_cycad_33: $i > $i).
% 29.20/29.00  tff(decl_28255, type, fn_cycad_34: $i > $i).
% 29.20/29.00  tff(decl_28256, type, fn_cycad_35: $i > $i).
% 29.20/29.00  tff(decl_28257, type, fn_cycad_36: $i > $i).
% 29.20/29.00  tff(decl_28258, type, fn_cycad_37: $i > $i).
% 29.20/29.00  tff(decl_28259, type, fn_cycad_38: $i > $i).
% 29.20/29.00  tff(decl_28260, type, fn_cycad_39: $i > $i).
% 29.20/29.00  tff(decl_28261, type, fn_cycad_40: $i > $i).
% 29.20/29.00  tff(decl_28262, type, fn_cycad_41: $i > $i).
% 29.20/29.00  tff(decl_28263, type, fn_cycad_42: $i > $i).
% 29.20/29.00  tff(decl_28264, type, fn_cycad_43: $i > $i).
% 29.20/29.00  tff(decl_28265, type, fn_cycad_44: $i > $i).
% 29.20/29.00  tff(decl_28266, type, fn_cycad_45: $i > $i).
% 29.20/29.00  tff(decl_28267, type, fn_cycad_46: $i > $i).
% 29.20/29.00  tff(decl_28268, type, fn_cycad_49: $i > $i).
% 29.20/29.00  tff(decl_28269, type, fn_cycad_50: $i > $i).
% 29.20/29.00  tff(decl_28270, type, fn_cycad_51: $i > $i).
% 29.20/29.00  tff(decl_28271, type, fn_cycad_52: $i > $i).
% 29.20/29.00  tff(decl_28272, type, fn_cycad_53: $i > $i).
% 29.20/29.00  tff(decl_28273, type, fn_shoot_1: $i > $i).
% 29.20/29.00  tff(decl_28274, type, vascular_plant_0: $i).
% 29.20/29.00  tff(decl_28275, type, fn_cycad_12: $i > $i).
% 29.20/29.00  tff(decl_28276, type, fn_cycad_11: $i > $i).
% 29.20/29.00  tff(decl_28277, type, fn_cycad_10: $i > $i).
% 29.20/29.00  tff(decl_28278, type, fn_cycad_9: $i > $i).
% 29.20/29.00  tff(decl_28279, type, fn_cycad_14: $i > $i).
% 29.20/29.00  tff(decl_28280, type, fn_cycad_13: $i > $i).
% 29.20/29.00  tff(decl_28281, type, fn_cycad_47: $i > $i).
% 29.20/29.00  tff(decl_28282, type, fn_gymnosperm_7: $i > $i).
% 29.20/29.00  tff(decl_28283, type, fn_cycad_48: $i > $i).
% 29.20/29.00  tff(decl_28284, type, fn_gymnosperm_6: $i > $i).
% 29.20/29.00  tff(decl_28285, type, fn_cycad_3: $i > $i).
% 29.20/29.00  tff(decl_28286, type, fn_gymnosperm_16: $i > $i).
% 29.20/29.00  tff(decl_28287, type, fn_gymnosperm_15: $i > $i).
% 29.20/29.00  tff(decl_28288, type, fn_woody_plant_7: $i > $i).
% 29.20/29.00  tff(decl_28289, type, fn_gymnosperm_22: $i > $i).
% 29.20/29.00  tff(decl_28290, type, fn_woody_plant_9: $i > $i).
% 29.20/29.00  tff(decl_28291, type, fn_gymnosperm_11: $i > $i).
% 29.20/29.00  tff(decl_28292, type, fn_woody_plant_12: $i > $i).
% 29.20/29.00  tff(decl_28293, type, fn_gymnosperm_8: $i > $i).
% 29.20/29.00  tff(decl_28294, type, fn_woody_plant_18: $i > $i).
% 29.20/29.00  tff(decl_28295, type, fn_gymnosperm_2: $i > $i).
% 29.20/29.00  tff(decl_28296, type, fn_woody_plant_15: $i > $i).
% 29.20/29.00  tff(decl_28297, type, fn_gymnosperm_5: $i > $i).
% 29.20/29.00  tff(decl_28298, type, fn_woody_plant_8: $i > $i).
% 29.20/29.00  tff(decl_28299, type, fn_gymnosperm_19: $i > $i).
% 29.20/29.00  tff(decl_28300, type, fn_woody_plant_6: $i > $i).
% 29.20/29.00  tff(decl_28301, type, fn_gymnosperm_23: $i > $i).
% 29.20/29.00  tff(decl_28302, type, fn_gymnosperm_14: $i > $i).
% 29.20/29.00  tff(decl_28303, type, fn_woody_plant_17: $i > $i).
% 29.20/29.00  tff(decl_28304, type, fn_gymnosperm_3: $i > $i).
% 29.20/29.00  tff(decl_28305, type, fn_woody_plant_4: $i > $i).
% 29.20/29.00  tff(decl_28306, type, fn_gymnosperm_20: $i > $i).
% 29.20/29.00  tff(decl_28307, type, fn_woody_plant_16: $i > $i).
% 29.20/29.00  tff(decl_28308, type, fn_gymnosperm_4: $i > $i).
% 29.20/29.00  tff(decl_28309, type, fn_woody_plant_5: $i > $i).
% 29.20/29.00  tff(decl_28310, type, fn_gymnosperm_13: $i > $i).
% 29.20/29.00  tff(decl_28311, type, fn_woody_plant_3: $i > $i).
% 29.20/29.00  tff(decl_28312, type, fn_gymnosperm_21: $i > $i).
% 29.20/29.00  tff(decl_28313, type, fn_woody_plant_10: $i > $i).
% 29.20/29.00  tff(decl_28314, type, fn_gymnosperm_9: $i > $i).
% 29.20/29.00  tff(decl_28315, type, fn_woody_plant_11: $i > $i).
% 29.20/29.00  tff(decl_28316, type, fn_gymnosperm_10: $i > $i).
% 29.20/29.00  tff(decl_28317, type, 'Cyclic-AMP': $i).
% 29.20/29.00  tff(decl_28318, type, 'Cyclic adenosine monophosphate, a ring-shaped molecule made from ATP that is a common intracellular signaling molecule (second messenger) in eukaryotic cells. It is also a regulator of some bacterial operons.': $i).
% 29.20/29.00  tff(decl_28319, type, camp: $i).
% 29.20/29.00  tff(decl_28320, type, '3\\ 5\\ cyclic adenosine monophosphate': $i).
% 29.20/29.00  tff(decl_28321, type, '3\\-5\\-cyclic-adenosine-monophosphate': $i).
% 29.20/29.00  tff(decl_28322, type, 'cyclic adenosine monophosphate': $i).
% 29.20/29.00  tff(decl_28323, type, 'cyclic amp': $i).
% 29.20/29.00  tff(decl_28324, type, 'cyclic-amp': $i).
% 29.20/29.00  tff(decl_28325, type, fn_cyclic_amp_3: $i > $i).
% 29.20/29.00  tff(decl_28326, type, fn_cyclic_amp_7: $i > $i).
% 29.20/29.00  tff(decl_28327, type, fn_cyclic_amp_8: $i > $i).
% 29.20/29.00  tff(decl_28328, type, fn_cyclic_amp_10: $i > $i).
% 29.20/29.00  tff(decl_28329, type, fn_cyclic_amp_11: $i > $i).
% 29.20/29.00  tff(decl_28330, type, fn_cyclic_amp_12: $i > $i).
% 29.20/29.00  tff(decl_28331, type, fn_cyclic_amp_13: $i > $i).
% 29.20/29.00  tff(decl_28332, type, fn_cyclic_amp_14: $i > $i).
% 29.20/29.00  tff(decl_28333, type, fn_cyclic_amp_15: $i > $i).
% 29.20/29.00  tff(decl_28334, type, fn_cyclic_amp_16: $i > $i).
% 29.20/29.00  tff(decl_28335, type, fn_cyclic_amp_17: $i > $i).
% 29.20/29.00  tff(decl_28336, type, fn_cyclic_amp_18: $i > $i).
% 29.20/29.00  tff(decl_28337, type, fn_cyclic_amp_19: $i > $i).
% 29.20/29.00  tff(decl_28338, type, fn_cyclic_amp_20: $i > $i).
% 29.20/29.00  tff(decl_28339, type, fn_cyclic_amp_21: $i > $i).
% 29.20/29.00  tff(decl_28340, type, fn_cyclic_amp_22: $i > $i).
% 29.20/29.00  tff(decl_28341, type, fn_cyclic_amp_23: $i > $i).
% 29.20/29.00  tff(decl_28342, type, fn_cyclic_amp_25: $i > $i).
% 29.20/29.00  tff(decl_28343, type, fn_cyclic_amp_26: $i > $i).
% 29.20/29.00  tff(decl_28344, type, fn_cyclic_amp_27: $i > $i).
% 29.20/29.00  tff(decl_28345, type, fn_cyclic_amp_28: $i > $i).
% 29.20/29.00  tff(decl_28346, type, fn_cyclic_amp_29: $i > $i).
% 29.20/29.00  tff(decl_28347, type, fn_cyclic_amp_30: $i > $i).
% 29.20/29.00  tff(decl_28348, type, fn_cyclic_amp_31: $i > $i).
% 29.20/29.00  tff(decl_28349, type, fn_cyclic_amp_32: $i > $i).
% 29.20/29.00  tff(decl_28350, type, fn_cyclic_amp_33: $i > $i).
% 29.20/29.00  tff(decl_28351, type, fn_cyclic_amp_34: $i > $i).
% 29.20/29.00  tff(decl_28352, type, fn_cyclic_amp_35: $i > $i).
% 29.20/29.00  tff(decl_28353, type, fn_cyclic_amp_36: $i > $i).
% 29.20/29.00  tff(decl_28354, type, fn_cyclic_amp_37: $i > $i).
% 29.20/29.00  tff(decl_28355, type, fn_cyclic_amp_38: $i > $i).
% 29.20/29.00  tff(decl_28356, type, fn_cyclic_amp_39: $i > $i).
% 29.20/29.00  tff(decl_28357, type, fn_cyclic_amp_40: $i > $i).
% 29.20/29.00  tff(decl_28358, type, fn_cyclic_amp_41: $i > $i).
% 29.20/29.00  tff(decl_28359, type, fn_cyclic_amp_42: $i > $i).
% 29.20/29.00  tff(decl_28360, type, fn_cyclic_amp_43: $i > $i).
% 29.20/29.00  tff(decl_28361, type, fn_cyclic_amp_44: $i > $i).
% 29.20/29.00  tff(decl_28362, type, fn_cyclic_amp_45: $i > $i).
% 29.20/29.00  tff(decl_28363, type, fn_cyclic_amp_46: $i > $i).
% 29.20/29.00  tff(decl_28364, type, fn_cyclic_amp_47: $i > $i).
% 29.20/29.00  tff(decl_28365, type, fn_cyclic_amp_48: $i > $i).
% 29.20/29.00  tff(decl_28366, type, fn_cyclic_amp_49: $i > $i).
% 29.20/29.00  tff(decl_28367, type, fn_cyclic_amp_50: $i > $i).
% 29.20/29.00  tff(decl_28368, type, fn_cyclic_amp_51: $i > $i).
% 29.20/29.00  tff(decl_28369, type, fn_cyclic_amp_52: $i > $i).
% 29.20/29.00  tff(decl_28370, type, fn_cyclic_amp_53: $i > $i).
% 29.20/29.00  tff(decl_28371, type, fn_cyclic_amp_54: $i > $i).
% 29.20/29.00  tff(decl_28372, type, fn_cyclic_amp_55: $i > $i).
% 29.20/29.00  tff(decl_28373, type, fn_cyclic_amp_56: $i > $i).
% 29.20/29.00  tff(decl_28374, type, fn_cyclic_amp_57: $i > $i).
% 29.20/29.00  tff(decl_28375, type, fn_cyclic_amp_58: $i > $i).
% 29.20/29.00  tff(decl_28376, type, fn_cyclic_amp_59: $i > $i).
% 29.20/29.00  tff(decl_28377, type, fn_cyclic_amp_60: $i > $i).
% 29.20/29.00  tff(decl_28378, type, fn_cyclic_amp_61: $i > $i).
% 29.20/29.00  tff(decl_28379, type, fn_cyclic_amp_62: $i > $i).
% 29.20/29.00  tff(decl_28380, type, fn_cyclic_amp_63: $i > $i).
% 29.20/29.00  tff(decl_28381, type, fn_cyclic_amp_64: $i > $i).
% 29.20/29.00  tff(decl_28382, type, fn_cyclic_amp_65: $i > $i).
% 29.20/29.00  tff(decl_28383, type, fn_cyclic_amp_66: $i > $i).
% 29.20/29.00  tff(decl_28384, type, fn_cyclic_amp_69: $i > $i).
% 29.20/29.00  tff(decl_28385, type, fn_cyclic_amp_70: $i > $i).
% 29.20/29.00  tff(decl_28386, type, fn_cyclic_amp_71: $i > $i).
% 29.20/29.00  tff(decl_28387, type, fn_cyclic_amp_72: $i > $i).
% 29.20/29.00  tff(decl_28388, type, fn_cyclic_amp_73: $i > $i).
% 29.20/29.00  tff(decl_28389, type, fn_cyclic_amp_74: $i > $i).
% 29.20/29.00  tff(decl_28390, type, fn_cyclic_amp_75: $i > $i).
% 29.20/29.00  tff(decl_28391, type, fn_cyclic_amp_76: $i > $i).
% 29.20/29.00  tff(decl_28392, type, fn_cyclic_amp_77: $i > $i).
% 29.20/29.00  tff(decl_28393, type, fn_cyclic_amp_81: $i > $i).
% 29.20/29.00  tff(decl_28394, type, fn_cyclic_amp_82: $i > $i).
% 29.20/29.00  tff(decl_28395, type, fn_cyclic_amp_84: $i > $i).
% 29.20/29.00  tff(decl_28396, type, fn_cyclic_amp_86: $i > $i).
% 29.20/29.00  tff(decl_28397, type, fn_cyclic_amp_88: $i > $i).
% 29.20/29.00  tff(decl_28398, type, fn_cyclic_amp_89: $i > $i).
% 29.20/29.00  tff(decl_28399, type, fn_cyclic_amp_90: $i > $i).
% 29.20/29.00  tff(decl_28400, type, fn_cyclic_amp_91: $i > $i).
% 29.20/29.00  tff(decl_28401, type, fn_cyclic_amp_95: $i > $i).
% 29.20/29.00  tff(decl_28402, type, fn_cyclic_amp_96: $i > $i).
% 29.20/29.00  tff(decl_28403, type, fn_cyclic_amp_100: $i > $i).
% 29.20/29.00  tff(decl_28404, type, fn_cyclic_amp_101: $i > $i).
% 29.20/29.00  tff(decl_28405, type, fn_cyclic_amp_102: $i > $i).
% 29.20/29.00  tff(decl_28406, type, fn_cyclic_amp_103: $i > $i).
% 29.20/29.00  tff(decl_28407, type, fn_cyclic_amp_104: $i > $i).
% 29.20/29.00  tff(decl_28408, type, fn_cyclic_amp_105: $i > $i).
% 29.20/29.00  tff(decl_28409, type, fn_cyclic_amp_106: $i > $i).
% 29.20/29.00  tff(decl_28410, type, fn_cyclic_amp_107: $i > $i).
% 29.20/29.00  tff(decl_28411, type, fn_cyclic_amp_108: $i > $i).
% 29.20/29.00  tff(decl_28412, type, fn_cyclic_amp_109: $i > $i).
% 29.20/29.00  tff(decl_28413, type, fn_cyclic_amp_110: $i > $i).
% 29.20/29.00  tff(decl_28414, type, fn_cyclic_amp_111: $i > $i).
% 29.20/29.00  tff(decl_28415, type, fn_cyclic_amp_112: $i > $i).
% 29.20/29.00  tff(decl_28416, type, fn_cyclic_amp_113: $i > $i).
% 29.20/29.00  tff(decl_28417, type, fn_cyclic_amp_114: $i > $i).
% 29.20/29.00  tff(decl_28418, type, fn_cyclic_amp_116: $i > $i).
% 29.20/29.00  tff(decl_28419, type, organic_molecule_0: $i).
% 29.20/29.00  tff(decl_28420, type, fn_cyclic_amp_97: $i > $i).
% 29.20/29.00  tff(decl_28421, type, fn_cyclic_amp_6: $i > $i).
% 29.20/29.00  tff(decl_28422, type, fn_nucleoside_monophosphate_40: $i > $i).
% 29.20/29.00  tff(decl_28423, type, fn_nucleoside_monophosphate_45: $i > $i).
% 29.20/29.00  tff(decl_28424, type, fn_nucleoside_monophosphate_44: $i > $i).
% 29.20/29.00  tff(decl_28425, type, fn_nucleoside_monophosphate_43: $i > $i).
% 29.20/29.00  tff(decl_28426, type, fn_cyclic_amp_98: $i > $i).
% 29.20/29.00  tff(decl_28427, type, fn_cyclic_amp_99: $i > $i).
% 29.20/29.00  tff(decl_28428, type, fn_cyclic_amp_5: $i > $i).
% 29.20/29.00  tff(decl_28429, type, fn_cyclic_amp_4: $i > $i).
% 29.20/29.00  tff(decl_28430, type, 'Cyclic-Electron-Flow': $i).
% 29.20/29.00  tff(decl_28431, type, 'A pathway during photosynthesis by which electrons are not passed to Photosystem II but instead are passed to an electron transport chain and and then returned to Photosystem I. Cyclic electron flow produces ATP but not NADPH or O2.': $i).
% 29.20/29.00  tff(decl_28432, type, 'cyclic electron pathway': $i).
% 29.20/29.00  tff(decl_28433, type, 'cyclic-electron-pathway': $i).
% 29.20/29.00  tff(decl_28434, type, 'perform cyclic electron flow': $i).
% 29.20/29.00  tff(decl_28435, type, 'transfer energy': $i).
% 29.20/29.00  tff(decl_28436, type, 'cyclic electron flow': $i).
% 29.20/29.00  tff(decl_28437, type, 'cyclic-electron-flow': $i).
% 29.20/29.00  tff(decl_28438, type, fn_cyclic_electron_flow_4: $i > $i).
% 29.20/29.00  tff(decl_28439, type, fn_cyclic_electron_flow_5: $i > $i).
% 29.20/29.00  tff(decl_28440, type, fn_cyclic_electron_flow_6: $i > $i).
% 29.20/29.00  tff(decl_28441, type, fn_cyclic_electron_flow_7: $i > $i).
% 29.20/29.00  tff(decl_28442, type, p700_plus__1: $i > $o).
% 29.20/29.00  tff(decl_28443, type, fn_cyclic_electron_flow_8: $i > $i).
% 29.20/29.00  tff(decl_28444, type, fn_cyclic_electron_flow_9: $i > $i).
% 29.20/29.00  tff(decl_28445, type, fn_cyclic_electron_flow_10: $i > $i).
% 29.20/29.00  tff(decl_28446, type, light_transmission_1: $i > $o).
% 29.20/29.00  tff(decl_28447, type, fn_cyclic_electron_flow_11: $i > $i).
% 29.20/29.00  tff(decl_28448, type, fn_cyclic_electron_flow_12: $i > $i).
% 29.20/29.00  tff(decl_28449, type, fn_cyclic_electron_flow_15: $i > $i).
% 29.20/29.00  tff(decl_28450, type, fn_cyclic_electron_flow_16: $i > $i).
% 29.20/29.00  tff(decl_28451, type, fn_cyclic_electron_flow_19: $i > $i).
% 29.20/29.00  tff(decl_28452, type, fn_cyclic_electron_flow_23: $i > $i).
% 29.20/29.00  tff(decl_28453, type, fn_cyclic_electron_flow_24: $i > $i).
% 29.20/29.00  tff(decl_28454, type, fn_cyclic_electron_flow_25: $i > $i).
% 29.20/29.00  tff(decl_28455, type, fn_cyclic_electron_flow_26: $i > $i).
% 29.20/29.00  tff(decl_28456, type, fn_cyclic_electron_flow_27: $i > $i).
% 29.20/29.00  tff(decl_28457, type, fn_cyclic_electron_flow_28: $i > $i).
% 29.20/29.00  tff(decl_28458, type, fn_cyclic_electron_flow_29: $i > $i).
% 29.20/29.00  tff(decl_28459, type, fn_cyclic_electron_flow_30: $i > $i).
% 29.20/29.00  tff(decl_28460, type, fn_cyclic_electron_flow_31: $i > $i).
% 29.20/29.00  tff(decl_28461, type, fn_cyclic_electron_flow_32: $i > $i).
% 29.20/29.00  tff(decl_28462, type, fn_cyclic_electron_flow_33: $i > $i).
% 29.20/29.00  tff(decl_28463, type, fn_cyclic_electron_flow_36: $i > $i).
% 29.20/29.00  tff(decl_28464, type, fn_cyclic_electron_flow_37: $i > $i).
% 29.20/29.00  tff(decl_28465, type, fn_cyclic_electron_flow_38: $i > $i).
% 29.20/29.00  tff(decl_28466, type, fn_cyclic_electron_flow_39: $i > $i).
% 29.20/29.00  tff(decl_28467, type, fn_cyclic_electron_flow_40: $i > $i).
% 29.20/29.00  tff(decl_28468, type, plastocyanin_1: $i > $o).
% 29.20/29.00  tff(decl_28469, type, fn_cyclic_electron_flow_41: $i > $i).
% 29.20/29.00  tff(decl_28470, type, fn_cyclic_electron_flow_42: $i > $i).
% 29.20/29.00  tff(decl_28471, type, fn_cyclic_electron_flow_43: $i > $i).
% 29.20/29.00  tff(decl_28472, type, fn_cyclic_electron_flow_44: $i > $i).
% 29.20/29.00  tff(decl_28473, type, fn_cyclic_electron_flow_45: $i > $i).
% 29.20/29.00  tff(decl_28474, type, fn_cyclic_electron_flow_46: $i > $i).
% 29.20/29.00  tff(decl_28475, type, fn_cyclic_electron_flow_47: $i > $i).
% 29.20/29.00  tff(decl_28476, type, fn_cyclic_electron_flow_48: $i > $i).
% 29.20/29.00  tff(decl_28477, type, fn_cyclic_electron_flow_49: $i > $i).
% 29.20/29.00  tff(decl_28478, type, fn_cyclic_electron_flow_50: $i > $i).
% 29.20/29.00  tff(decl_28479, type, fn_cyclic_electron_flow_56: $i > $i).
% 29.20/29.00  tff(decl_28480, type, fn_cyclic_electron_flow_57: $i > $i).
% 29.20/29.00  tff(decl_28481, type, fn_cyclic_electron_flow_58: $i > $i).
% 29.20/29.00  tff(decl_28482, type, fn_cyclic_electron_flow_59: $i > $i).
% 29.20/29.00  tff(decl_28483, type, fn_cyclic_electron_flow_60: $i > $i).
% 29.20/29.00  tff(decl_28484, type, fn_cyclic_electron_flow_61: $i > $i).
% 29.20/29.00  tff(decl_28485, type, fn_cyclic_electron_flow_62: $i > $i).
% 29.20/29.00  tff(decl_28486, type, fn_cyclic_electron_flow_63: $i > $i).
% 29.20/29.00  tff(decl_28487, type, fn_cyclic_electron_flow_64: $i > $i).
% 29.20/29.00  tff(decl_28488, type, fn_cyclic_electron_flow_65: $i > $i).
% 29.20/29.00  tff(decl_28489, type, fn_cyclic_electron_flow_66: $i > $i).
% 29.20/29.00  tff(decl_28490, type, fn_cyclic_electron_flow_67: $i > $i).
% 29.20/29.00  tff(decl_28491, type, fn_cyclic_electron_flow_68: $i > $i).
% 29.20/29.00  tff(decl_28492, type, fn_cyclic_electron_flow_69: $i > $i).
% 29.20/29.00  tff(decl_28493, type, fn_cyclic_electron_flow_70: $i > $i).
% 29.20/29.00  tff(decl_28494, type, fn_cyclic_electron_flow_71: $i > $i).
% 29.20/29.00  tff(decl_28495, type, fn_cyclic_electron_flow_72: $i > $i).
% 29.20/29.00  tff(decl_28496, type, fn_cyclic_electron_flow_73: $i > $i).
% 29.20/29.00  tff(decl_28497, type, fn_cyclic_electron_flow_74: $i > $i).
% 29.20/29.00  tff(decl_28498, type, fn_cyclic_electron_flow_75: $i > $i).
% 29.20/29.00  tff(decl_28499, type, fn_cyclic_electron_flow_76: $i > $i).
% 29.20/29.00  tff(decl_28500, type, fn_cyclic_electron_flow_77: $i > $i).
% 29.20/29.00  tff(decl_28501, type, fn_cyclic_electron_flow_78: $i > $i).
% 29.20/29.00  tff(decl_28502, type, fn_cyclic_electron_flow_79: $i > $i).
% 29.20/29.00  tff(decl_28503, type, fn_cyclic_electron_flow_80: $i > $i).
% 29.20/29.00  tff(decl_28504, type, fn_cyclic_electron_flow_81: $i > $i).
% 29.20/29.00  tff(decl_28505, type, fn_cyclic_electron_flow_82: $i > $i).
% 29.20/29.00  tff(decl_28506, type, fn_cyclic_electron_flow_83: $i > $i).
% 29.20/29.00  tff(decl_28507, type, fn_cyclic_electron_flow_84: $i > $i).
% 29.20/29.00  tff(decl_28508, type, primary_electron_acceptor_1: $i > $o).
% 29.20/29.00  tff(decl_28509, type, fn_cyclic_electron_flow_85: $i > $i).
% 29.20/29.00  tff(decl_28510, type, fn_cyclic_electron_flow_86: $i > $i).
% 29.20/29.00  tff(decl_28511, type, fn_cyclic_electron_flow_87: $i > $i).
% 29.20/29.00  tff(decl_28512, type, fn_cyclic_electron_flow_88: $i > $i).
% 29.20/29.00  tff(decl_28513, type, ferredoxin_1: $i > $o).
% 29.20/29.00  tff(decl_28514, type, fn_cyclic_electron_flow_89: $i > $i).
% 29.20/29.00  tff(decl_28515, type, fn_cyclic_electron_flow_90: $i > $i).
% 29.20/29.00  tff(decl_28516, type, fn_cyclic_electron_flow_91: $i > $i).
% 29.20/29.00  tff(decl_28517, type, fn_cyclic_electron_flow_92: $i > $i).
% 29.20/29.00  tff(decl_28518, type, fn_cyclic_electron_flow_93: $i > $i).
% 29.20/29.00  tff(decl_28519, type, fn_cyclic_electron_flow_94: $i > $i).
% 29.20/29.00  tff(decl_28520, type, fn_cyclic_electron_flow_95: $i > $i).
% 29.20/29.00  tff(decl_28521, type, fn_cyclic_electron_flow_96: $i > $i).
% 29.20/29.00  tff(decl_28522, type, fn_cyclic_electron_flow_97: $i > $i).
% 29.20/29.00  tff(decl_28523, type, fn_cyclic_electron_flow_98: $i > $i).
% 29.20/29.00  tff(decl_28524, type, fn_cyclic_electron_flow_99: $i > $i).
% 29.20/29.00  tff(decl_28525, type, fn_cyclic_electron_flow_100: $i > $i).
% 29.20/29.00  tff(decl_28526, type, fn_cyclic_electron_flow_101: $i > $i).
% 29.20/29.00  tff(decl_28527, type, fn_cyclic_electron_flow_102: $i > $i).
% 29.20/29.00  tff(decl_28528, type, fn_cyclic_electron_flow_103: $i > $i).
% 29.20/29.00  tff(decl_28529, type, light_reflection_1: $i > $o).
% 29.20/29.00  tff(decl_28530, type, fn_cyclic_electron_flow_104: $i > $i).
% 29.20/29.00  tff(decl_28531, type, fn_cyclic_electron_flow_105: $i > $i).
% 29.20/29.00  tff(decl_28532, type, fn_cyclic_electron_flow_106: $i > $i).
% 29.20/29.00  tff(decl_28533, type, fn_cyclic_electron_flow_107: $i > $i).
% 29.20/29.00  tff(decl_28534, type, fn_cyclic_electron_flow_108: $i > $i).
% 29.20/29.00  tff(decl_28535, type, fn_cyclic_electron_flow_109: $i > $i).
% 29.20/29.00  tff(decl_28536, type, fn_cyclic_electron_flow_110: $i > $i).
% 29.20/29.00  tff(decl_28537, type, fn_cyclic_electron_flow_111: $i > $i).
% 29.20/29.00  tff(decl_28538, type, fn_cyclic_electron_flow_112: $i > $i).
% 29.20/29.00  tff(decl_28539, type, fn_cyclic_electron_flow_113: $i > $i).
% 29.20/29.00  tff(decl_28540, type, fn_cyclic_electron_flow_114: $i > $i).
% 29.20/29.00  tff(decl_28541, type, fn_cyclic_electron_flow_115: $i > $i).
% 29.20/29.00  tff(decl_28542, type, fn_cyclic_electron_flow_116: $i > $i).
% 29.20/29.00  tff(decl_28543, type, fn_cyclic_electron_flow_117: $i > $i).
% 29.20/29.00  tff(decl_28544, type, fn_cyclic_electron_flow_118: $i > $i).
% 29.20/29.00  tff(decl_28545, type, fn_cyclic_electron_flow_120: $i > $i).
% 29.20/29.00  tff(decl_28546, type, fn_cyclic_electron_flow_121: $i > $i).
% 29.20/29.00  tff(decl_28547, type, fn_cyclic_electron_flow_122: $i > $i).
% 29.20/29.00  tff(decl_28548, type, fn_cyclic_electron_flow_123: $i > $i).
% 29.20/29.00  tff(decl_28549, type, fn_cyclic_electron_flow_124: $i > $i).
% 29.20/29.00  tff(decl_28550, type, fn_cyclic_electron_flow_125: $i > $i).
% 29.20/29.00  tff(decl_28551, type, fn_cyclic_electron_flow_126: $i > $i).
% 29.20/29.00  tff(decl_28552, type, fn_cyclic_electron_flow_127: $i > $i).
% 29.20/29.00  tff(decl_28553, type, fn_cyclic_electron_flow_128: $i > $i).
% 29.20/29.00  tff(decl_28554, type, fn_cyclic_electron_flow_129: $i > $i).
% 29.20/29.00  tff(decl_28555, type, fn_cyclic_electron_flow_131: $i > $i).
% 29.20/29.00  tff(decl_28556, type, fn_cyclic_electron_flow_132: $i > $i).
% 29.20/29.00  tff(decl_28557, type, fn_cyclic_electron_flow_133: $i > $i).
% 29.20/29.00  tff(decl_28558, type, fn_cyclic_electron_flow_135: $i > $i).
% 29.20/29.00  tff(decl_28559, type, fn_cyclic_electron_flow_136: $i > $i).
% 29.20/29.00  tff(decl_28560, type, fn_cyclic_electron_flow_137: $i > $i).
% 29.20/29.00  tff(decl_28561, type, fn_cyclic_electron_flow_138: $i > $i).
% 29.20/29.00  tff(decl_28562, type, fn_cyclic_electron_flow_139: $i > $i).
% 29.20/29.00  tff(decl_28563, type, fn_cyclic_electron_flow_140: $i > $i).
% 29.20/29.00  tff(decl_28564, type, fn_electron_transport_chain_1: $i > $i).
% 29.20/29.00  tff(decl_28565, type, fn_electron_transport_chain_5: $i > $i).
% 29.20/29.00  tff(decl_28566, type, fn_p700_25: $i > $i).
% 29.20/29.00  tff(decl_28567, type, fn_p700_14: $i > $i).
% 29.20/29.00  tff(decl_28568, type, fn_p700_27: $i > $i).
% 29.20/29.00  tff(decl_28569, type, fn_p700_26: $i > $i).
% 29.20/29.00  tff(decl_28570, type, fn_p700_15: $i > $i).
% 29.20/29.00  tff(decl_28571, type, fn_p700_12: $i > $i).
% 29.20/29.00  tff(decl_28572, type, fn_photosystem_i_10: $i > $i).
% 29.20/29.00  tff(decl_28573, type, fn_photosystem_i_21: $i > $i).
% 29.20/29.00  tff(decl_28574, type, fn_reducing_agent_1: $i > $i).
% 29.20/29.00  tff(decl_28575, type, fn_reducing_agent_2: $i > $i).
% 29.20/29.00  tff(decl_28576, type, fn_electron_transport_chain_4: $i > $i).
% 29.20/29.00  tff(decl_28577, type, fn_p700_plus__1: $i > $i).
% 29.20/29.00  tff(decl_28578, type, fn_electron_transport_chain_3: $i > $i).
% 29.20/29.00  tff(decl_28579, type, fn_electron_transport_chain_2: $i > $i).
% 29.20/29.00  tff(decl_28580, type, fn_p700_28: $i > $i).
% 29.20/29.00  tff(decl_28581, type, fn_light_reflection_1: $i > $i).
% 29.20/29.00  tff(decl_28582, type, fn_p700_13: $i > $i).
% 29.20/29.00  tff(decl_28583, type, fn_electron_transport_chain_reaction_6: $i > $i).
% 29.20/29.00  tff(decl_28584, type, fn_cyclic_electron_flow_55: $i > $i).
% 29.20/29.00  tff(decl_28585, type, fn_cyclic_electron_flow_35: $i > $i).
% 29.20/29.00  tff(decl_28586, type, fn_electron_transport_chain_reaction_20: $i > $i).
% 29.20/29.00  tff(decl_28587, type, fn_cyclic_electron_flow_22: $i > $i).
% 29.20/29.00  tff(decl_28588, type, fn_electron_transport_chain_reaction_26: $i > $i).
% 29.20/29.00  tff(decl_28589, type, fn_cyclic_electron_flow_51: $i > $i).
% 29.20/29.00  tff(decl_28590, type, fn_electron_transport_chain_reaction_18: $i > $i).
% 29.20/29.00  tff(decl_28591, type, fn_electron_transport_chain_reaction_11: $i > $i).
% 29.20/29.00  tff(decl_28592, type, fn_electron_transport_chain_reaction_12: $i > $i).
% 29.20/29.00  tff(decl_28593, type, fn_cyclic_electron_flow_21: $i > $i).
% 29.20/29.00  tff(decl_28594, type, fn_electron_transport_chain_reaction_27: $i > $i).
% 29.20/29.00  tff(decl_28595, type, fn_electron_transport_chain_reaction_21: $i > $i).
% 29.20/29.00  tff(decl_28596, type, fn_electron_transport_chain_reaction_22: $i > $i).
% 29.20/29.00  tff(decl_28597, type, fn_electron_transport_chain_reaction_23: $i > $i).
% 29.20/29.00  tff(decl_28598, type, fn_electron_transport_chain_reaction_13: $i > $i).
% 29.20/29.00  tff(decl_28599, type, fn_electron_transport_chain_reaction_4: $i > $i).
% 29.20/29.00  tff(decl_28600, type, fn_cyclic_electron_flow_34: $i > $i).
% 29.20/29.00  tff(decl_28601, type, fn_cyclic_electron_flow_54: $i > $i).
% 29.20/29.00  tff(decl_28602, type, fn_cyclic_electron_flow_130: $i > $i).
% 29.20/29.00  tff(decl_28603, type, fn_cyclic_electron_flow_134: $i > $i).
% 29.20/29.00  tff(decl_28604, type, fn_cyclic_electron_flow_119: $i > $i).
% 29.20/29.00  tff(decl_28605, type, fn_cyclic_electron_flow_53: $i > $i).
% 29.20/29.00  tff(decl_28606, type, fn_cyclic_electron_flow_52: $i > $i).
% 29.20/29.00  tff(decl_28607, type, 'Cyclic-GMP': $i).
% 29.20/29.00  tff(decl_28608, type, 'CGMP (Cyclic guanosine monophosphate) is a nucleotide which acts as a second messenger in many important cell signaling pathways.': $i).
% 29.20/29.00  tff(decl_28609, type, 'cyclic guanosine monophosphate': $i).
% 29.20/29.00  tff(decl_28610, type, cgmp: $i).
% 29.20/29.00  tff(decl_28611, type, 'cyclic gmp': $i).
% 29.20/29.00  tff(decl_28612, type, 'cyclic-gmp': $i).
% 29.20/29.00  tff(decl_28613, type, gmp_1: $i > $o).
% 29.20/29.00  tff(decl_28614, type, 'Cyclic-Nucleotide-Phosphodiesterase': $i).
% 29.20/29.00  tff(decl_28615, type, 'One of a group of enzymes that break the phosphodiester bond in cAMP, thus converting cAMP to AMP.': $i).
% 29.20/29.00  tff(decl_28616, type, phosphodiesterase: $i).
% 29.20/29.00  tff(decl_28617, type, 'cyclic nucleotide phosphodiesterase': $i).
% 29.20/29.00  tff(decl_28618, type, 'cyclic-nucleotide-phosphodiesterase': $i).
% 29.20/29.00  tff(decl_28619, type, phosphodiesterase_1: $i > $o).
% 29.20/29.00  tff(decl_28620, type, fn_cyclic_nucleotide_phosphodiesterase_1: $i > $i).
% 29.20/29.00  tff(decl_28621, type, fn_cyclic_nucleotide_phosphodiesterase_2: $i > $i).
% 29.20/29.00  tff(decl_28622, type, 'Cyclic-Reaction': $i).
% 29.20/29.00  tff(decl_28623, type, 'A reaction that when finished regenerates the original reactants.': $i).
% 29.20/29.00  tff(decl_28624, type, 'cyclic reaction': $i).
% 29.20/29.00  tff(decl_28625, type, 'cyclic-reaction': $i).
% 29.20/29.00  tff(decl_28626, type, 'Cyclin': $i).
% 29.20/29.00  tff(decl_28627, type, 'Family of proteins that regulate the progression of cells through the cell cycle.': $i).
% 29.20/29.00  tff(decl_28628, type, cyclin: $i).
% 29.20/29.00  tff(decl_28629, type, 'Cyclin-Dependent-Kinase': $i).
% 29.20/29.00  tff(decl_28630, type, 'An enzyme that activates the protein cyclin by phosphorylating it. Plays a role in regulating the cell cycle.': $i).
% 29.20/29.00  tff(decl_28631, type, cdk: $i).
% 29.20/29.00  tff(decl_28632, type, 'cyclin dependent kinase': $i).
% 29.20/29.00  tff(decl_28633, type, 'cyclin-dependent-kinase': $i).
% 29.20/29.00  tff(decl_28634, type, kinase_1: $i > $o).
% 29.20/29.00  tff(decl_28635, type, cytoplasmic_protein_kinase_1: $i > $o).
% 29.20/29.00  tff(decl_28636, type, tyrosine_kinase_1: $i > $o).
% 29.20/29.00  tff(decl_28637, type, cyclohexane_1: $i > $o).
% 29.20/29.00  tff(decl_28638, type, 'Cyclohexane': $i).
% 29.20/29.00  tff(decl_28639, type, 'Hexane molecule in a ring or cyclic form.': $i).
% 29.20/29.00  tff(decl_28640, type, hexane: $i).
% 29.20/29.00  tff(decl_28641, type, cyclohexane: $i).
% 29.20/29.00  tff(decl_28642, type, 'Cyclopentane': $i).
% 29.20/29.00  tff(decl_28643, type, 'Pentane molecule in a ring or cyclic form.': $i).
% 29.20/29.00  tff(decl_28644, type, pentane: $i).
% 29.20/29.00  tff(decl_28645, type, cyclopentane: $i).
% 29.20/29.00  tff(decl_28646, type, cysteine_1: $i > $o).
% 29.20/29.00  tff(decl_28647, type, 'Cysteine': $i).
% 29.20/29.00  tff(decl_28648, type, cysteine: $i).
% 29.20/29.00  tff(decl_28649, type, fn_cysteine_1: $i > $i).
% 29.20/29.00  tff(decl_28650, type, fn_cysteine_2: $i > $i).
% 29.20/29.00  tff(decl_28651, type, fn_cysteine_3: $i > $i).
% 29.20/29.00  tff(decl_28652, type, fn_cysteine_4: $i > $i).
% 29.20/29.00  tff(decl_28653, type, fn_cysteine_5: $i > $i).
% 29.20/29.00  tff(decl_28654, type, fn_cysteine_6: $i > $i).
% 29.20/29.00  tff(decl_28655, type, fn_cysteine_7: $i > $i).
% 29.20/29.00  tff(decl_28656, type, fn_cysteine_8: $i > $i).
% 29.20/29.00  tff(decl_28657, type, fn_cysteine_9: $i > $i).
% 29.20/29.00  tff(decl_28658, type, fn_cysteine_10: $i > $i).
% 29.20/29.00  tff(decl_28659, type, fn_cysteine_11: $i > $i).
% 29.20/29.00  tff(decl_28660, type, fn_cysteine_12: $i > $i).
% 29.20/29.00  tff(decl_28661, type, fn_cysteine_13: $i > $i).
% 29.20/29.00  tff(decl_28662, type, fn_cysteine_14: $i > $i).
% 29.20/29.00  tff(decl_28663, type, fn_cysteine_15: $i > $i).
% 29.20/29.00  tff(decl_28664, type, fn_cysteine_16: $i > $i).
% 29.20/29.00  tff(decl_28665, type, fn_cysteine_17: $i > $i).
% 29.20/29.00  tff(decl_28666, type, fn_cysteine_18: $i > $i).
% 29.20/29.00  tff(decl_28667, type, fn_cysteine_19: $i > $i).
% 29.20/29.00  tff(decl_28668, type, fn_cysteine_20: $i > $i).
% 29.20/29.00  tff(decl_28669, type, fn_cysteine_21: $i > $i).
% 29.20/29.00  tff(decl_28670, type, fn_cysteine_22: $i > $i).
% 29.20/29.00  tff(decl_28671, type, fn_cysteine_23: $i > $i).
% 29.20/29.00  tff(decl_28672, type, fn_cysteine_24: $i > $i).
% 29.20/29.00  tff(decl_28673, type, fn_cysteine_25: $i > $i).
% 29.20/29.00  tff(decl_28674, type, fn_cysteine_26: $i > $i).
% 29.20/29.00  tff(decl_28675, type, fn_cysteine_27: $i > $i).
% 29.20/29.00  tff(decl_28676, type, fn_cysteine_28: $i > $i).
% 29.20/29.00  tff(decl_28677, type, fn_cysteine_29: $i > $i).
% 29.20/29.00  tff(decl_28678, type, fn_cysteine_30: $i > $i).
% 29.20/29.00  tff(decl_28679, type, fn_cysteine_31: $i > $i).
% 29.20/29.00  tff(decl_28680, type, fn_cysteine_32: $i > $i).
% 29.20/29.00  tff(decl_28681, type, fn_cysteine_33: $i > $i).
% 29.20/29.00  tff(decl_28682, type, fn_cysteine_34: $i > $i).
% 29.20/29.00  tff(decl_28683, type, fn_cysteine_35: $i > $i).
% 29.20/29.00  tff(decl_28684, type, fn_cysteine_36: $i > $i).
% 29.20/29.00  tff(decl_28685, type, fn_cysteine_37: $i > $i).
% 29.20/29.00  tff(decl_28686, type, fn_cysteine_38: $i > $i).
% 29.20/29.00  tff(decl_28687, type, fn_cysteine_39: $i > $i).
% 29.20/29.00  tff(decl_28688, type, fn_cysteine_40: $i > $i).
% 29.20/29.00  tff(decl_28689, type, fn_cysteine_41: $i > $i).
% 29.20/29.00  tff(decl_28690, type, fn_cysteine_42: $i > $i).
% 29.20/29.00  tff(decl_28691, type, fn_cysteine_43: $i > $i).
% 29.20/29.00  tff(decl_28692, type, fn_cysteine_44: $i > $i).
% 29.20/29.00  tff(decl_28693, type, fn_cysteine_45: $i > $i).
% 29.20/29.00  tff(decl_28694, type, fn_hydrogen_19: $i > $i).
% 29.20/29.00  tff(decl_28695, type, sulfur_0: $i).
% 29.20/29.00  tff(decl_28696, type, fn_cysteine_47: $i > $i).
% 29.20/29.00  tff(decl_28697, type, fn_cysteine_46: $i > $i).
% 29.20/29.00  tff(decl_28698, type, 'Cystic-Fibrosis': $i).
% 29.20/29.00  tff(decl_28699, type, 'A human genetic disorder caused by a recessive allele for a chloride channel protein; characterized by an excessive secretion of mucus and consequent vulnerability to infection; fatal if untreated.': $i).
% 29.20/29.00  tff(decl_28700, type, mucoviscidosis: $i).
% 29.20/29.00  tff(decl_28701, type, 'cystic fibrosis': $i).
% 29.20/29.00  tff(decl_28702, type, 'cystic-fibrosis': $i).
% 29.20/29.00  tff(decl_28703, type, fn_cystic_fibrosis_1: $i > $i).
% 29.20/29.00  tff(decl_28704, type, recessive_allele_1: $i > $o).
% 29.20/29.00  tff(decl_28705, type, fn_cystic_fibrosis_2: $i > $i).
% 29.20/29.00  tff(decl_28706, type, cystinuria_1: $i > $o).
% 29.20/29.00  tff(decl_28707, type, 'Cystinuria': $i).
% 29.20/29.00  tff(decl_28708, type, 'Genetic disorder in which faulty transport proteins result in positively charged amino acids not being reabsorbed in the kidneys, leading to kidney stones.': $i).
% 29.20/29.00  tff(decl_28709, type, cystinuria: $i).
% 29.20/29.00  tff(decl_28710, type, cytochrome_1: $i > $o).
% 29.20/29.00  tff(decl_28711, type, 'Cytochrome': $i).
% 29.20/29.00  tff(decl_28712, type, 'Cytochromes are, in general, membrane-bound hemoproteins that contain heme groups and carry out electron transport.They are found either as monomeric proteins (e.g., cytochrome c) or as subunits of bigger enzymatic complexes that catalyze redox reactions. They are found in the mitochondrial inner membrane and endoplasmic reticulum of eukaryotes, in the chloroplasts of plants, in photosynthetic microorganisms, and in bacteria.': $i).
% 29.20/29.00  tff(decl_28713, type, cyt: $i).
% 29.20/29.00  tff(decl_28714, type, cytochrome: $i).
% 29.20/29.00  tff(decl_28715, type, fn_cytochrome_1: $i > $i).
% 29.20/29.00  tff(decl_28716, type, fn_cytochrome_2: $i > $i).
% 29.20/29.00  tff(decl_28717, type, heme_1: $i > $o).
% 29.20/29.00  tff(decl_28718, type, fn_cytochrome_3: $i > $i).
% 29.20/29.00  tff(decl_28719, type, electron_carrier_1: $i > $o).
% 29.20/29.00  tff(decl_28720, type, fn_cytochrome_4: $i > $i).
% 29.20/29.00  tff(decl_28721, type, fn_cytochrome_5: $i > $i).
% 29.20/29.00  tff(decl_28722, type, fn_cytochrome_6: $i > $i).
% 29.20/29.00  tff(decl_28723, type, fn_cytochrome_7: $i > $i).
% 29.20/29.00  tff(decl_28724, type, fn_cytochrome_8: $i > $i).
% 29.20/29.00  tff(decl_28725, type, fn_cytochrome_9: $i > $i).
% 29.20/29.00  tff(decl_28726, type, fn_cytochrome_10: $i > $i).
% 29.20/29.00  tff(decl_28727, type, fn_cytochrome_11: $i > $i).
% 29.20/29.00  tff(decl_28728, type, fn_cytochrome_12: $i > $i).
% 29.20/29.00  tff(decl_28729, type, fn_cytochrome_13: $i > $i).
% 29.20/29.00  tff(decl_28730, type, fn_cytochrome_14: $i > $i).
% 29.20/29.00  tff(decl_28731, type, fn_cytochrome_15: $i > $i).
% 29.20/29.00  tff(decl_28732, type, fn_cytochrome_16: $i > $i).
% 29.20/29.00  tff(decl_28733, type, fn_cytochrome_17: $i > $i).
% 29.20/29.00  tff(decl_28734, type, fn_cytochrome_18: $i > $i).
% 29.20/29.00  tff(decl_28735, type, fn_electron_carrier_1: $i > $i).
% 29.20/29.00  tff(decl_28736, type, fn_cytochrome_22: $i > $i).
% 29.20/29.00  tff(decl_28737, type, fn_cytochrome_20: $i > $i).
% 29.20/29.00  tff(decl_28738, type, fn_cytochrome_21: $i > $i).
% 29.20/29.00  tff(decl_28739, type, fn_cytochrome_19: $i > $i).
% 29.20/29.00  tff(decl_28740, type, cytochrome_a_1: $i > $o).
% 29.20/29.00  tff(decl_28741, type, 'Cytochrome-A': $i).
% 29.20/29.00  tff(decl_28742, type, 'Cytochromes (electron-transporting proteins) in which the haem prosthetic group is haem a, i.e., the iron chelate of cytoporphyrin ix.': $i).
% 29.20/29.00  tff(decl_28743, type, 'cytochrome a': $i).
% 29.20/29.00  tff(decl_28744, type, 'cytochrome-a': $i).
% 29.20/29.00  tff(decl_28745, type, cytochrome_a3_1: $i > $o).
% 29.20/29.00  tff(decl_28746, type, cytochrome_b_1: $i > $o).
% 29.20/29.00  tff(decl_28747, type, cytochrome_c1_1: $i > $o).
% 29.20/29.00  tff(decl_28748, type, 'Cytochrome-A3': $i).
% 29.20/29.00  tff(decl_28749, type, 'The last electron carrier of the electron transport chain which transfers its electron to oxygen.': $i).
% 29.20/29.00  tff(decl_28750, type, 'cyt a3': $i).
% 29.20/29.00  tff(decl_28751, type, 'cytochrome a3': $i).
% 29.20/29.00  tff(decl_28752, type, 'cytochrome-a3': $i).
% 29.20/29.00  tff(decl_28753, type, 'Cytochrome-B': $i).
% 29.20/29.00  tff(decl_28754, type, 'Cytochrome b/b6 is the main subunit of transmembrane cytochrome bc1 and b6f complexes. In addition, it commonly refers to a region of mtDNA used for population genetics and phylogenetics.': $i).
% 29.20/29.00  tff(decl_28755, type, 'cyt b': $i).
% 29.20/29.00  tff(decl_28756, type, 'cyt-b': $i).
% 29.20/29.00  tff(decl_28757, type, 'b of cytochrome': $i).
% 29.20/29.00  tff(decl_28758, type, 'cytochrome b': $i).
% 29.20/29.00  tff(decl_28759, type, 'cytochrome-b': $i).
% 29.20/29.00  tff(decl_28760, type, 'Cytochrome-C': $i).
% 29.20/29.00  tff(decl_28761, type, 'A key electron carrier protein of the electron transport chain located within the inner membrane of the mitochondrion that transfers electrons between complexes III and IV.': $i).
% 29.20/29.00  tff(decl_28762, type, 'cyt c': $i).
% 29.20/29.00  tff(decl_28763, type, 'cyt-c': $i).
% 29.20/29.00  tff(decl_28764, type, 'c of cytochrome': $i).
% 29.20/29.00  tff(decl_28765, type, 'cytochrome c': $i).
% 29.20/29.00  tff(decl_28766, type, 'cytochrome-c': $i).
% 29.20/29.00  tff(decl_28767, type, fn_cytochrome_c_1: $i > $i).
% 29.20/29.00  tff(decl_28768, type, fn_cytochrome_c_2: $i > $i).
% 29.20/29.00  tff(decl_28769, type, 'Cytochrome-C1': $i).
% 29.20/29.00  tff(decl_28770, type, 'Cytochrome C1 is formed in the cytosol and targeted to the mitochondrial intermembrane space. It is one of the constituents of complex III, which forms the third proton pump in the mitochondrial electron transport chain.': $i).
% 29.20/29.00  tff(decl_28771, type, 'cytochrome c1': $i).
% 29.20/29.00  tff(decl_28772, type, 'cytochrome-c1': $i).
% 29.20/29.00  tff(decl_28773, type, 'Cytochrome-Complex': $i).
% 29.20/29.00  tff(decl_28774, type, 'An assembly of iron-containing proteins which functions in the transport of electrons during photosynthesis and cellular respiration.': $i).
% 29.20/29.00  tff(decl_28775, type, 'complex of cytochrome': $i).
% 29.20/29.00  tff(decl_28776, type, 'cytochrome complex': $i).
% 29.20/29.00  tff(decl_28777, type, 'cytochrome-complex': $i).
% 29.20/29.00  tff(decl_28778, type, fn_cytochrome_complex_1: $i > $i).
% 29.20/29.00  tff(decl_28779, type, fn_cytochrome_complex_2: $i > $i).
% 29.20/29.00  tff(decl_28780, type, cytogenetic_map_1: $i > $o).
% 29.20/29.00  tff(decl_28781, type, 'Cytogenetic-Map': $i).
% 29.20/29.00  tff(decl_28782, type, 'A chart of a chromosome that locates genes with respect to chromosomal features distinguishable in a microscope.': $i).
% 29.20/29.00  tff(decl_28783, type, 'cytological map': $i).
% 29.20/29.00  tff(decl_28784, type, 'cytological-map': $i).
% 29.20/29.00  tff(decl_28785, type, 'cytogenetic map': $i).
% 29.20/29.00  tff(decl_28786, type, 'cytogenetic-map': $i).
% 29.20/29.00  tff(decl_28787, type, data_1: $i > $o).
% 29.20/29.00  tff(decl_28788, type, 'Cytokine': $i).
% 29.20/29.00  tff(decl_28789, type, 'A protein secreted by various types of cells, including helper T cells and macrophages, that modulate the functions of other cells of the immune system.': $i).
% 29.20/29.00  tff(decl_28790, type, cytokine: $i).
% 29.20/29.00  tff(decl_28791, type, 'Cytokinesis': $i).
% 29.20/29.00  tff(decl_28792, type, 'The division of cytoplasm into two daughter cells following nuclear division.': $i).
% 29.20/29.00  tff(decl_28793, type, 'undergo cytokinesis': $i).
% 29.20/29.00  tff(decl_28794, type, cytokinesis: $i).
% 29.20/29.00  tff(decl_28795, type, fn_cytokinesis_1: $i > $i).
% 29.20/29.00  tff(decl_28796, type, fn_cytokinesis_2: $i > $i).
% 29.20/29.00  tff(decl_28797, type, fn_cytokinesis_3: $i > $i).
% 29.20/29.00  tff(decl_28798, type, eukaryotic_cell_0: $i).
% 29.20/29.00  tff(decl_28799, type, cytokinesis_in_animal_cell_1: $i > $o).
% 29.20/29.00  tff(decl_28800, type, 'Cytokinesis-In-Animal-Cell': $i).
% 29.20/29.00  tff(decl_28801, type, 'The division of cytoplasm into two daughter cells following nuclear division in animal cells.': $i).
% 29.20/29.00  tff(decl_28802, type, 'cytokinesis in animal cell': $i).
% 29.20/29.00  tff(decl_28803, type, 'cytokinesis-in-animal-cell': $i).
% 29.20/29.00  tff(decl_28804, type, cytokinesis_in_plant_cell_1: $i > $o).
% 29.20/29.00  tff(decl_28805, type, fn_cytokinesis_in_animal_cell_1: $i > $i).
% 29.20/29.00  tff(decl_28806, type, fn_cytokinesis_in_animal_cell_2: $i > $i).
% 29.20/29.00  tff(decl_28807, type, fn_cytokinesis_in_animal_cell_3: $i > $i).
% 29.20/29.00  tff(decl_28808, type, fn_cytokinesis_in_animal_cell_4: $i > $i).
% 29.20/29.00  tff(decl_28809, type, fn_cytokinesis_in_animal_cell_5: $i > $i).
% 29.20/29.00  tff(decl_28810, type, fn_cytokinesis_in_animal_cell_6: $i > $i).
% 29.20/29.00  tff(decl_28811, type, deepen_1: $i > $o).
% 29.20/29.00  tff(decl_28812, type, fn_cytokinesis_in_animal_cell_7: $i > $i).
% 29.20/29.00  tff(decl_28813, type, fn_cytokinesis_in_animal_cell_8: $i > $i).
% 29.20/29.00  tff(decl_28814, type, fn_cytokinesis_in_animal_cell_9: $i > $i).
% 29.20/29.00  tff(decl_28815, type, fn_cytokinesis_in_animal_cell_10: $i > $i).
% 29.20/29.00  tff(decl_28816, type, fn_cytokinesis_in_animal_cell_11: $i > $i).
% 29.20/29.00  tff(decl_28817, type, fn_cytokinesis_in_animal_cell_12: $i > $i).
% 29.20/29.00  tff(decl_28818, type, formation_of_cleavage_furrow_1: $i > $o).
% 29.20/29.00  tff(decl_28819, type, fn_cytokinesis_in_animal_cell_13: $i > $i).
% 29.20/29.00  tff(decl_28820, type, fn_cytokinesis_in_animal_cell_14: $i > $i).
% 29.20/29.00  tff(decl_28821, type, fn_cytokinesis_in_animal_cell_15: $i > $i).
% 29.20/29.00  tff(decl_28822, type, fn_cytokinesis_in_animal_cell_16: $i > $i).
% 29.20/29.00  tff(decl_28823, type, fn_cytokinesis_in_animal_cell_17: $i > $i).
% 29.20/29.00  tff(decl_28824, type, fn_cytokinesis_in_animal_cell_18: $i > $i).
% 29.20/29.00  tff(decl_28825, type, fn_cytokinesis_in_animal_cell_19: $i > $i).
% 29.20/29.00  tff(decl_28826, type, fn_cytokinesis_in_animal_cell_20: $i > $i).
% 29.20/29.00  tff(decl_28827, type, fn_cytokinesis_in_animal_cell_21: $i > $i).
% 29.20/29.00  tff(decl_28828, type, fn_cytokinesis_in_animal_cell_22: $i > $i).
% 29.20/29.00  tff(decl_28829, type, fn_cytokinesis_in_animal_cell_23: $i > $i).
% 29.20/29.00  tff(decl_28830, type, fn_formation_of_cleavage_furrow_2: $i > $i).
% 29.20/29.00  tff(decl_28831, type, fn_formation_of_cleavage_furrow_4: $i > $i).
% 29.20/29.00  tff(decl_28832, type, fn_formation_of_cleavage_furrow_1: $i > $i).
% 29.20/29.00  tff(decl_28833, type, fn_formation_of_cleavage_furrow_3: $i > $i).
% 29.20/29.00  tff(decl_28834, type, fn_cytokinesis_in_animal_cell_24: $i > $i).
% 29.20/29.00  tff(decl_28835, type, 'Cytokinesis-In-Plant-Cell': $i).
% 29.20/29.00  tff(decl_28836, type, 'The division of cytoplasm into two daughter cells following nuclear division in plant cells.': $i).
% 29.20/29.00  tff(decl_28837, type, 'cytokinesis in plant cell': $i).
% 29.20/29.00  tff(decl_28838, type, 'cytokinesis-in-plant-cell': $i).
% 29.20/29.00  tff(decl_28839, type, fn_cytokinesis_in_plant_cell_1: $i > $i).
% 29.20/29.00  tff(decl_28840, type, fn_cytokinesis_in_plant_cell_2: $i > $i).
% 29.20/29.00  tff(decl_28841, type, fn_cytokinesis_in_plant_cell_3: $i > $i).
% 29.20/29.00  tff(decl_28842, type, fn_cytokinesis_in_plant_cell_4: $i > $i).
% 29.20/29.00  tff(decl_28843, type, fn_cytokinesis_in_plant_cell_5: $i > $i).
% 29.20/29.00  tff(decl_28844, type, fn_cytokinesis_in_plant_cell_6: $i > $i).
% 29.20/29.00  tff(decl_28845, type, fn_cytokinesis_in_plant_cell_7: $i > $i).
% 29.20/29.00  tff(decl_28846, type, fn_cytokinesis_in_plant_cell_8: $i > $i).
% 29.20/29.00  tff(decl_28847, type, fn_cytokinesis_in_plant_cell_9: $i > $i).
% 29.20/29.00  tff(decl_28848, type, fn_cytokinesis_in_plant_cell_10: $i > $i).
% 29.20/29.00  tff(decl_28849, type, fn_cytokinesis_in_plant_cell_11: $i > $i).
% 29.20/29.00  tff(decl_28850, type, fn_cytokinesis_in_plant_cell_12: $i > $i).
% 29.20/29.00  tff(decl_28851, type, fn_cytokinesis_in_plant_cell_13: $i > $i).
% 29.20/29.00  tff(decl_28852, type, fn_cytokinesis_in_plant_cell_14: $i > $i).
% 29.20/29.00  tff(decl_28853, type, formation_of_cell_plate_1: $i > $o).
% 29.20/29.00  tff(decl_28854, type, fn_cytokinesis_in_plant_cell_15: $i > $i).
% 29.20/29.00  tff(decl_28855, type, fn_cytokinesis_in_plant_cell_16: $i > $i).
% 29.20/29.00  tff(decl_28856, type, fn_cytokinesis_in_plant_cell_17: $i > $i).
% 29.20/29.00  tff(decl_28857, type, fn_cytokinesis_in_plant_cell_18: $i > $i).
% 29.20/29.00  tff(decl_28858, type, fn_cytokinesis_in_plant_cell_19: $i > $i).
% 29.20/29.00  tff(decl_28859, type, fn_cytokinesis_in_plant_cell_20: $i > $i).
% 29.20/29.00  tff(decl_28860, type, fn_cytokinesis_in_plant_cell_21: $i > $i).
% 29.20/29.00  tff(decl_28861, type, fn_cytokinesis_in_plant_cell_22: $i > $i).
% 29.20/29.00  tff(decl_28862, type, fn_cytokinesis_in_plant_cell_23: $i > $i).
% 29.20/29.00  tff(decl_28863, type, fn_cytokinesis_in_plant_cell_24: $i > $i).
% 29.20/29.00  tff(decl_28864, type, fn_cytokinesis_in_plant_cell_25: $i > $i).
% 29.20/29.00  tff(decl_28865, type, fn_cytokinesis_in_plant_cell_26: $i > $i).
% 29.20/29.00  tff(decl_28866, type, fn_cytokinesis_in_plant_cell_27: $i > $i).
% 29.20/29.00  tff(decl_28867, type, fn_cytokinesis_in_plant_cell_28: $i > $i).
% 29.20/29.00  tff(decl_28868, type, fn_cytokinesis_in_plant_cell_29: $i > $i).
% 29.20/29.00  tff(decl_28869, type, fn_cytokinesis_in_plant_cell_30: $i > $i).
% 29.20/29.00  tff(decl_28870, type, fn_cytokinesis_in_plant_cell_31: $i > $i).
% 29.20/29.00  tff(decl_28871, type, fn_cytokinesis_in_plant_cell_32: $i > $i).
% 29.20/29.00  tff(decl_28872, type, fn_cytokinesis_in_plant_cell_33: $i > $i).
% 29.20/29.00  tff(decl_28873, type, fn_cytokinesis_in_plant_cell_34: $i > $i).
% 29.20/29.00  tff(decl_28874, type, fn_formation_of_cell_plate_14: $i > $i).
% 29.20/29.00  tff(decl_28875, type, fn_formation_of_cell_plate_15: $i > $i).
% 29.20/29.00  tff(decl_28876, type, fn_formation_of_cell_plate_10: $i > $i).
% 29.20/29.00  tff(decl_28877, type, fn_formation_of_cell_plate_5: $i > $i).
% 29.20/29.00  tff(decl_28878, type, fn_formation_of_cell_plate_2: $i > $i).
% 29.20/29.00  tff(decl_28879, type, formation_of_cleavage_furrow_0: $i).
% 29.20/29.00  tff(decl_28880, type, plant_cell_0: $i).
% 29.20/29.00  tff(decl_28881, type, 'Cytokinin': $i).
% 29.20/29.00  tff(decl_28882, type, 'A plant hormone that promotes cell division in roots and shoots. Cytokinins are also involved in apical dominance, growth of axillarly buds, and leaf senescence.': $i).
% 29.20/29.00  tff(decl_28883, type, cytokinin: $i).
% 29.20/29.00  tff(decl_28884, type, 'Cytoplasm': $i).
% 29.20/29.00  tff(decl_28885, type, 'Cytoplasm is the part of a cell that is enclosed within the cell membrane. This part of the cell is the site for most of the cellular processes. In eukaryotic cells, the cytoplasm contains organelles.': $i).
% 29.20/29.00  tff(decl_28886, type, cytoplasm: $i).
% 29.20/29.00  tff(decl_28887, type, fn_cytoplasm_2: $i > $i).
% 29.20/29.00  tff(decl_28888, type, fn_cytoplasm_3: $i > $i).
% 29.20/29.00  tff(decl_28889, type, fn_cytoplasm_4: $i > $i).
% 29.20/29.00  tff(decl_28890, type, fn_cytoplasm_5: $i > $i).
% 29.20/29.00  tff(decl_28891, type, fn_cytoplasm_6: $i > $i).
% 29.20/29.00  tff(decl_28892, type, cytoplasmic_channel_1: $i > $o).
% 29.20/29.00  tff(decl_28893, type, 'Cytoplasmic-Channel': $i).
% 29.20/29.00  tff(decl_28894, type, 'A region of a cell junction that allows the sharing and exchange of materials in the  cytoplasm of two or more cells.': $i).
% 29.20/29.00  tff(decl_28895, type, 'communicating junctions': $i).
% 29.20/29.00  tff(decl_28896, type, 'gap junctions': $i).
% 29.20/29.00  tff(decl_28897, type, 'hydrophilic channel': $i).
% 29.20/29.00  tff(decl_28898, type, 'cytoplasmic channel': $i).
% 29.20/29.00  tff(decl_28899, type, 'cytoplasmic-channel': $i).
% 29.20/29.00  tff(decl_28900, type, cytoplasmic_determinant_1: $i > $o).
% 29.20/29.00  tff(decl_28901, type, 'Cytoplasmic-Determinant': $i).
% 29.20/29.00  tff(decl_28902, type, 'A substance, commonly a piece of RNA or a protein, that is placed by the mother into an egg and which affects early development by regulating the expression of genes that affect cell fates.': $i).
% 29.20/29.00  tff(decl_28903, type, 'cytoplasmic determinant': $i).
% 29.20/29.00  tff(decl_28904, type, 'cytoplasmic-determinant': $i).
% 29.20/29.00  tff(decl_28905, type, fn_cytoplasmic_determinant_1: $i > $i).
% 29.20/29.00  tff(decl_28906, type, fn_cytoplasmic_determinant_2: $i > $i).
% 29.20/29.00  tff(decl_28907, type, 'Cytoplasmic-Protein-Kinase': $i).
% 29.20/29.00  tff(decl_28908, type, 'A type of  protein kinase which is specifically found in cytoplasm of the cell.': $i).
% 29.20/29.00  tff(decl_28909, type, 'cytoplasmic protein kinase': $i).
% 29.20/29.00  tff(decl_28910, type, 'cytoplasmic-protein-kinase': $i).
% 29.20/29.00  tff(decl_28911, type, fn_cytoplasmic_protein_kinase_1: $i > $i).
% 29.20/29.00  tff(decl_28912, type, fn_cytoplasmic_protein_kinase_2: $i > $i).
% 29.20/29.00  tff(decl_28913, type, fn_cytoplasmic_protein_kinase_3: $i > $i).
% 29.20/29.00  tff(decl_28914, type, fn_cytoplasmic_protein_kinase_4: $i > $i).
% 29.20/29.00  tff(decl_28915, type, 'Cytoplasmic-Response': $i).
% 29.20/29.00  tff(decl_28916, type, 'During a cell signalling event, a cellular response which occurs in the cytoplasm of the cell.': $i).
% 29.20/29.00  tff(decl_28917, type, 'cytoplasmic response': $i).
% 29.20/29.00  tff(decl_28918, type, 'cytoplasmic-response': $i).
% 29.20/29.00  tff(decl_28919, type, 'Cytoplasmic-Side': $i).
% 29.20/29.00  tff(decl_28920, type, 'Cytoplasmic side is the interior side of membrane facing the cytoplasm.': $i).
% 29.20/29.00  tff(decl_28921, type, 'cytoplasmic side': $i).
% 29.20/29.00  tff(decl_28922, type, 'cytoplasmic-side': $i).
% 29.20/29.00  tff(decl_28923, type, 'Cytoplasmic-Streaming': $i).
% 29.20/29.00  tff(decl_28924, type, 'The circular flow of cytoplasm within a plant or fungal cell.': $i).
% 29.20/29.00  tff(decl_28925, type, 'perform cytoplasmic streaming': $i).
% 29.20/29.00  tff(decl_28926, type, circulate: $i).
% 29.20/29.00  tff(decl_28927, type, 'cytoplasmic streaming': $i).
% 29.20/29.00  tff(decl_28928, type, 'cytoplasmic-streaming': $i).
% 29.20/29.00  tff(decl_28929, type, fn_cytoplasmic_streaming_1: $i > $i).
% 29.20/29.00  tff(decl_28930, type, fn_cytoplasmic_streaming_2: $i > $i).
% 29.20/29.00  tff(decl_28931, type, fn_cytoplasmic_streaming_4: $i > $i).
% 29.20/29.00  tff(decl_28932, type, fn_cytoplasmic_streaming_5: $i > $i).
% 29.20/29.00  tff(decl_28933, type, fn_cytoplasmic_streaming_6: $i > $i).
% 29.20/29.00  tff(decl_28934, type, fn_cytoplasmic_streaming_7: $i > $i).
% 29.20/29.00  tff(decl_28935, type, fn_cytoplasmic_streaming_8: $i > $i).
% 29.20/29.00  tff(decl_28936, type, fn_cytoplasmic_streaming_9: $i > $i).
% 29.20/29.00  tff(decl_28937, type, fn_cytoplasmic_streaming_10: $i > $i).
% 29.20/29.00  tff(decl_28938, type, fn_cytoplasmic_streaming_11: $i > $i).
% 29.20/29.00  tff(decl_28939, type, fn_cytoplasmic_streaming_12: $i > $i).
% 29.20/29.00  tff(decl_28940, type, 'Cytosine': $i).
% 29.20/29.00  tff(decl_28941, type, 'One of the five most common nitrogenous bases which make up nucleotide monomers of nucleic acids. Cytosine is present in both DNA and RNA.': $i).
% 29.20/29.00  tff(decl_28942, type, cytosine: $i).
% 29.20/29.00  tff(decl_28943, type, fn_cytosine_1: $i > $i).
% 29.20/29.00  tff(decl_28944, type, fn_cytosine_at_dna_strand_2: $i > $i).
% 29.20/29.00  tff(decl_28945, type, 'Cytosine-At-DNA-Strand': $i).
% 29.20/29.00  tff(decl_28946, type, 'A nitrogenous base from the pyrimidine family when attached to deoxyribose and a phosphate group forms a nucleotide for DNA molecules.': $i).
% 29.20/29.00  tff(decl_28947, type, 'cytosine at dna strand': $i).
% 29.20/29.00  tff(decl_28948, type, 'cytosine-at-dna-strand': $i).
% 29.20/29.00  tff(decl_28949, type, cytosine_at_dna_strand_opposite_to_dna_strand_1: $i > $o).
% 29.20/29.00  tff(decl_28950, type, fn_cytosine_at_dna_strand_opposite_to_dna_strand_3: $i > $i).
% 29.20/29.00  tff(decl_28951, type, fn_cytosine_at_dna_strand_opposite_to_dna_strand_2: $i > $i).
% 29.20/29.00  tff(decl_28952, type, 'Cytosine-At-DNA-Strand-Opposite-To-DNA-Strand': $i).
% 29.20/29.00  tff(decl_28953, type, 'Cytosine is a nitrogenous base which is present at DNA strand and is present opposite to other DNA strand having Guanine.': $i).
% 29.20/29.00  tff(decl_28954, type, 'cytosine at dna strand opposite to dna strand': $i).
% 29.20/29.00  tff(decl_28955, type, 'cytosine-at-dna-strand-opposite-to-dna-strand': $i).
% 29.20/29.00  tff(decl_28956, type, cytosine_at_dna_strand_opposite_to_rna_strand_1: $i > $o).
% 29.20/29.00  tff(decl_28957, type, fn_cytosine_at_dna_strand_opposite_to_dna_strand_4: $i > $i).
% 29.20/29.00  tff(decl_28958, type, guanine_at_dna_strand_opposite_to_dna_strand_1: $i > $o).
% 29.20/29.00  tff(decl_28959, type, fn_guanine_at_dna_strand_opposite_to_dna_strand_4: $i > $i).
% 29.20/29.00  tff(decl_28960, type, fn_guanine_at_dna_strand_opposite_to_dna_strand_3: $i > $i).
% 29.20/29.00  tff(decl_28961, type, fn_guanine_at_dna_strand_opposite_to_dna_strand_2: $i > $i).
% 29.20/29.00  tff(decl_28962, type, fn_cytosine_at_dna_strand_opposite_to_rna_strand_2: $i > $i).
% 29.20/29.00  tff(decl_28963, type, fn_cytosine_at_dna_strand_opposite_to_rna_strand_3: $i > $i).
% 29.20/29.00  tff(decl_28964, type, 'Cytosine-At-DNA-Strand-Opposite-To-RNA-Strand': $i).
% 29.20/29.00  tff(decl_28965, type, 'Cytosine is a nitrogenous base which is present at DNA strand and is present opposite to RNA strand having Guanine.': $i).
% 29.20/29.00  tff(decl_28966, type, 'cytosine at dna strand opposite to rna strand': $i).
% 29.20/29.00  tff(decl_28967, type, 'cytosine-at-dna-strand-opposite-to-rna-strand': $i).
% 29.20/29.00  tff(decl_28968, type, fn_cytosine_at_dna_strand_opposite_to_rna_strand_4: $i > $i).
% 29.20/29.00  tff(decl_28969, type, guanine_at_rna_strand_opposite_to_dna_strand_1: $i > $o).
% 29.20/29.00  tff(decl_28970, type, fn_guanine_at_rna_strand_opposite_to_dna_strand_3: $i > $i).
% 29.20/29.00  tff(decl_28971, type, fn_guanine_at_rna_strand_opposite_to_dna_strand_2: $i > $i).
% 29.20/29.00  tff(decl_28972, type, fn_guanine_at_rna_strand_opposite_to_dna_strand_4: $i > $i).
% 29.20/29.00  tff(decl_28973, type, fn_cytosine_at_rna_strand_2: $i > $i).
% 29.20/29.00  tff(decl_28974, type, 'Cytosine-At-RNA-Strand': $i).
% 29.20/29.00  tff(decl_28975, type, 'Cytosine (C) is a nucleobase (a pyrimidine derivative) which is present at RNA.': $i).
% 29.20/29.00  tff(decl_28976, type, 'cytosine at rna strand': $i).
% 29.20/29.00  tff(decl_28977, type, 'cytosine-at-rna-strand': $i).
% 29.20/29.00  tff(decl_28978, type, cytosine_at_rna_strand_opposite_to_dna_strand_1: $i > $o).
% 29.20/29.00  tff(decl_28979, type, fn_cytosine_at_rna_strand_opposite_to_dna_strand_11: $i > $i).
% 29.20/29.00  tff(decl_28980, type, fn_cytosine_at_rna_strand_opposite_to_dna_strand_2: $i > $i).
% 29.20/29.00  tff(decl_28981, type, 'Cytosine-At-RNA-Strand-Opposite-To-DNA-Strand': $i).
% 29.20/29.00  tff(decl_28982, type, 'Cytosine is a nitrogenous base which is present at RNA strand and is present opposite to other DNA strand having Guanine.': $i).
% 29.20/29.00  tff(decl_28983, type, 'cytosine at rna strand opposite to dna strand': $i).
% 29.20/29.00  tff(decl_28984, type, 'cytosine-at-rna-strand-opposite-to-dna-strand': $i).
% 29.20/29.00  tff(decl_28985, type, cytosine_at_rna_strand_opposite_to_rna_strand_1: $i > $o).
% 29.20/29.00  tff(decl_28986, type, fn_cytosine_at_rna_strand_opposite_to_dna_strand_3: $i > $i).
% 29.20/29.00  tff(decl_28987, type, fn_cytosine_at_rna_strand_opposite_to_dna_strand_4: $i > $i).
% 29.20/29.00  tff(decl_28988, type, fn_cytosine_at_rna_strand_opposite_to_dna_strand_5: $i > $i).
% 29.20/29.00  tff(decl_28989, type, ribonucleoside_monophosphate_1: $i > $o).
% 29.20/29.00  tff(decl_28990, type, fn_cytosine_at_rna_strand_opposite_to_dna_strand_6: $i > $i).
% 29.20/29.00  tff(decl_28991, type, fn_cytosine_at_rna_strand_opposite_to_dna_strand_7: $i > $i).
% 29.20/29.00  tff(decl_28992, type, fn_cytosine_at_rna_strand_opposite_to_dna_strand_8: $i > $i).
% 29.20/29.00  tff(decl_28993, type, fn_cytosine_at_rna_strand_opposite_to_dna_strand_9: $i > $i).
% 29.20/29.00  tff(decl_28994, type, sugar_phosphate_backbone_1: $i > $o).
% 29.20/29.00  tff(decl_28995, type, fn_cytosine_at_rna_strand_opposite_to_dna_strand_10: $i > $i).
% 29.20/29.00  tff(decl_28996, type, guanine_at_dna_strand_opposite_to_rna_strand_1: $i > $o).
% 29.20/29.00  tff(decl_28997, type, fn_guanine_at_dna_strand_2: $i > $i).
% 29.20/29.00  tff(decl_28998, type, fn_rna_strand_40: $i > $i).
% 29.20/29.00  tff(decl_28999, type, fn_rna_strand_39: $i > $i).
% 29.20/29.00  tff(decl_29000, type, fn_nucleic_acid_19: $i > $i).
% 29.20/29.00  tff(decl_29001, type, fn_rna_strand_38: $i > $i).
% 29.20/29.00  tff(decl_29002, type, fn_sugar_phosphate_backbone_1: $i > $i).
% 29.20/29.00  tff(decl_29003, type, fn_cytosine_at_rna_strand_opposite_to_rna_strand_2: $i > $i).
% 29.20/29.00  tff(decl_29004, type, fn_cytosine_at_rna_strand_opposite_to_rna_strand_3: $i > $i).
% 29.20/29.00  tff(decl_29005, type, 'Cytosine-At-RNA-Strand-Opposite-To-RNA-Strand': $i).
% 29.20/29.00  tff(decl_29006, type, 'Cytosine is a nitrogenous base which is present at RNA strand and is present opposite to other RNA strand having Guanine.': $i).
% 29.20/29.00  tff(decl_29007, type, 'cytosine at rna strand opposite to rna strand': $i).
% 29.20/29.00  tff(decl_29008, type, 'cytosine-at-rna-strand-opposite-to-rna-strand': $i).
% 29.20/29.00  tff(decl_29009, type, fn_cytosine_at_rna_strand_opposite_to_rna_strand_4: $i > $i).
% 29.20/29.00  tff(decl_29010, type, guanine_at_rna_strand_opposite_to_rna_strand_1: $i > $o).
% 29.20/29.00  tff(decl_29011, type, fn_guanine_at_rna_strand_2: $i > $i).
% 29.20/29.00  tff(decl_29012, type, cytoskeletal_rearrangement_1: $i > $o).
% 29.20/29.00  tff(decl_29013, type, 'Cytoskeletal-Rearrangement': $i).
% 29.20/29.00  tff(decl_29014, type, 'Dynamic dismantling and reassembly of the cytoskeleton allowing the cell to change shape or to move.': $i).
% 29.20/29.00  tff(decl_29015, type, rearrange: $i).
% 29.20/29.00  tff(decl_29016, type, 'cytoskeletal rearrangement': $i).
% 29.20/29.00  tff(decl_29017, type, 'cytoskeletal-rearrangement': $i).
% 29.20/29.00  tff(decl_29018, type, rearrangement_1: $i > $o).
% 29.20/29.00  tff(decl_29019, type, 'Cytoskeleton': $i).
% 29.20/29.00  tff(decl_29020, type, 'The cytoskeleton is a cellular scaffolding or skeleton contained within the cytoplasm. The cytoskeleton is present in all cells. The cytoskeleton is comprised of Intermediate filament, Microtubules and Microfilament': $i).
% 29.20/29.00  tff(decl_29021, type, cytoskeleton: $i).
% 29.20/29.00  tff(decl_29022, type, fn_cytoskeleton_4: $i > $i).
% 29.20/29.00  tff(decl_29023, type, fn_structural_role_1: $i > $i).
% 29.20/29.00  tff(decl_29024, type, fn_structural_role_2: $i > $i).
% 29.20/29.00  tff(decl_29025, type, 'Cytosol': $i).
% 29.20/29.00  tff(decl_29026, type, 'Cytosol is the liquid found inside cells. In eukaryotes, the cytosol is separated from the contents of the organelles suspended in the cytosol by their membranes': $i).
% 29.20/29.00  tff(decl_29027, type, 'intracellular fluid': $i).
% 29.20/29.00  tff(decl_29028, type, 'cytoplasmic matrix': $i).
% 29.20/29.00  tff(decl_29029, type, cytosol: $i).
% 29.20/29.00  tff(decl_29030, type, cytotoxic_t_1: $i > $o).
% 29.20/29.00  tff(decl_29031, type, 'Cytotoxic-T': $i).
% 29.20/29.00  tff(decl_29032, type, 'A type of lymphocyte that kills cancer cells and cells infected with virusus and bacteria.': $i).
% 29.20/29.00  tff(decl_29033, type, 'cytotoxic t': $i).
% 29.20/29.00  tff(decl_29034, type, 'cytotoxic-t': $i).
% 29.20/29.00  tff(decl_29035, type, t_cells_1: $i > $o).
% 29.20/29.00  tff(decl_29036, type, plasma_cell_1: $i > $o).
% 29.20/29.00  tff(decl_29037, type, helper_t_1: $i > $o).
% 29.20/29.00  tff(decl_29038, type, memory_cell_1: $i > $o).
% 29.20/29.00  tff(decl_29039, type, 'Damage': $i).
% 29.20/29.00  tff(decl_29040, type, damage: $i).
% 29.20/29.00  tff(decl_29041, type, fn_damaged_cell_2: $i > $i).
% 29.20/29.00  tff(decl_29042, type, 'Damaged-Cell': $i).
% 29.20/29.00  tff(decl_29043, type, 'A cell that results from damage is called as damaged cell.': $i).
% 29.20/29.00  tff(decl_29044, type, 'cell showing damage': $i).
% 29.20/29.00  tff(decl_29045, type, 'cell-showing-damage': $i).
% 29.20/29.00  tff(decl_29046, type, 'damaged cell': $i).
% 29.20/29.00  tff(decl_29047, type, 'damaged-cell': $i).
% 29.20/29.00  tff(decl_29048, type, damaged_dna_strand_1: $i > $o).
% 29.20/29.00  tff(decl_29049, type, 'Damaged-DNA-Strand': $i).
% 29.20/29.00  tff(decl_29050, type, 'A DNA strand that has been damaged by harmful chemicals, radiation, or replication error.': $i).
% 29.20/29.00  tff(decl_29051, type, 'defective dna strand': $i).
% 29.20/29.00  tff(decl_29052, type, 'defective-dna-strand': $i).
% 29.20/29.00  tff(decl_29053, type, 'damaged dna strand': $i).
% 29.20/29.00  tff(decl_29054, type, 'damaged-dna-strand': $i).
% 29.20/29.00  tff(decl_29055, type, damselfly_1: $i > $o).
% 29.20/29.00  tff(decl_29056, type, 'Damselfly': $i).
% 29.20/29.00  tff(decl_29057, type, 'An insect in the order Odonata. Damselflies resemble dragonflies but hold their wings parallel to the body, while dragonfly wings are held perpendicular to the axis of the body.': $i).
% 29.20/29.00  tff(decl_29058, type, damselfly: $i).
% 29.20/29.00  tff(decl_29059, type, dragonfly_1: $i > $o).
% 29.20/29.00  tff(decl_29060, type, 'Daphnia': $i).
% 29.20/29.00  tff(decl_29061, type, 'Genus of freshwater planktonic crustaceans, notable for their ability to reproduce very rapidly via parthenogenesis during favorable conditions.': $i).
% 29.20/29.00  tff(decl_29062, type, daphnia: $i).
% 29.20/29.00  tff(decl_29063, type, darmstadtium_1: $i > $o).
% 29.20/29.00  tff(decl_29064, type, 'Darmstadtium': $i).
% 29.20/29.00  tff(decl_29065, type, 'Darmstadtium is a metal atom with atomic number 110. It is represented by the symbol Ds.': $i).
% 29.20/29.00  tff(decl_29066, type, darmstadtium: $i).
% 29.20/29.00  tff(decl_29067, type, ds: $i).
% 29.20/29.00  tff(decl_29068, type, fn_darmstadtium_1: $i > $i).
% 29.20/29.00  tff(decl_29069, type, fn_darmstadtium_2: $i > $i).
% 29.20/29.00  tff(decl_29070, type, fn_darmstadtium_6: $i > $i).
% 29.20/29.00  tff(decl_29071, type, fn_darmstadtium_7: $i > $i).
% 29.20/29.00  tff(decl_29072, type, "161": $i).
% 29.20/29.00  tff(decl_29073, type, "110": $i).
% 29.20/29.00  tff(decl_29074, type, "271": $i).
% 29.20/29.00  tff(decl_29075, type, fn_darmstadtium_4: $i > $i).
% 29.20/29.00  tff(decl_29076, type, fn_darmstadtium_5: $i > $i).
% 29.20/29.00  tff(decl_29077, type, 'Data': $i).
% 29.20/29.00  tff(decl_29078, type, 'Recorded quantitative or qualitative observations.': $i).
% 29.20/29.00  tff(decl_29079, type, data: $i).
% 29.20/29.00  tff(decl_29080, type, daughter_1: $i > $o).
% 29.20/29.00  tff(decl_29081, type, 'Daughter': $i).
% 29.20/29.00  tff(decl_29082, type, 'Daughter is produced at end of a division or reproduction.': $i).
% 29.20/29.00  tff(decl_29083, type, daughter: $i).
% 29.20/29.00  tff(decl_29084, type, organism_role_1: $i > $o).
% 29.20/29.00  tff(decl_29085, type, 'Daughter-Cell': $i).
% 29.20/29.00  tff(decl_29086, type, 'Cell produced through cell division.': $i).
% 29.20/29.00  tff(decl_29087, type, 'cell of daughter': $i).
% 29.20/29.00  tff(decl_29088, type, 'daughter cell': $i).
% 29.20/29.00  tff(decl_29089, type, 'daughter-cell': $i).
% 29.20/29.00  tff(decl_29090, type, daughter_nucleus_1: $i > $o).
% 29.20/29.00  tff(decl_29091, type, 'Daughter-Nucleus': $i).
% 29.20/29.00  tff(decl_29092, type, 'A nucleus produced as a result of the process of mitosis.': $i).
% 29.20/29.00  tff(decl_29093, type, 'nucleus of daughter': $i).
% 29.20/29.00  tff(decl_29094, type, 'daughter nucleus': $i).
% 29.20/29.00  tff(decl_29095, type, 'daughter-nucleus': $i).
% 29.20/29.00  tff(decl_29096, type, daughter_strands_1: $i > $o).
% 29.20/29.00  tff(decl_29097, type, 'Daughter-strands': $i).
% 29.20/29.00  tff(decl_29098, type, 'Daughter strands are the new DNA strands obtained after replication of parental DNA strands': $i).
% 29.20/29.00  tff(decl_29099, type, 'new dna strand': $i).
% 29.20/29.00  tff(decl_29100, type, 'daughter strands': $i).
% 29.20/29.00  tff(decl_29101, type, 'daughter strand': $i).
% 29.20/29.00  tff(decl_29102, type, 'daughter-strand': $i).
% 29.20/29.00  tff(decl_29103, type, 'Day-Constant': $i).
% 29.20/29.00  tff(decl_29104, type, 'constant of day': $i).
% 29.20/29.00  tff(decl_29105, type, 'day constant': $i).
% 29.20/29.00  tff(decl_29106, type, 'day-constant': $i).
% 29.20/29.00  tff(decl_29107, type, day_neutral_plant_1: $i > $o).
% 29.20/29.00  tff(decl_29108, type, 'Day-Neutral-Plant': $i).
% 29.20/29.00  tff(decl_29109, type, 'A plant which flowers when it reaches a certain stage of maturity, regardless of day length at that time.': $i).
% 29.20/29.00  tff(decl_29110, type, 'day neutral plant': $i).
% 29.20/29.00  tff(decl_29111, type, 'day-neutral plant': $i).
% 29.20/29.00  tff(decl_29112, type, 'day-neutral-plant': $i).
% 29.20/29.00  tff(decl_29113, type, flowering_control_plant_1: $i > $o).
% 29.20/29.00  tff(decl_29114, type, db_gene_1: $i > $o).
% 29.20/29.00  tff(decl_29115, type, 'Db-Gene': $i).
% 29.20/29.00  tff(decl_29116, type, 'Gene which codes for the receptor protein on the hormone leptin. This gene and its product, originally discovered in mice, plays an important role in the regulation of appetitie in mammals.': $i).
% 29.20/29.00  tff(decl_29117, type, 'db gene': $i).
% 29.20/29.00  tff(decl_29118, type, 'db-gene': $i).
% 29.20/29.00  tff(decl_29119, type, fn_db_gene_1: $i > $i).
% 29.20/29.00  tff(decl_29120, type, fn_db_gene_2: $i > $i).
% 29.20/29.00  tff(decl_29121, type, fn_db_gene_3: $i > $i).
% 29.20/29.00  tff(decl_29122, type, fn_db_gene_4: $i > $i).
% 29.20/29.00  tff(decl_29123, type, fn_db_gene_5: $i > $i).
% 29.20/29.00  tff(decl_29124, type, fn_db_gene_6: $i > $i).
% 29.20/29.00  tff(decl_29125, type, fn_db_gene_7: $i > $i).
% 29.20/29.00  tff(decl_29126, type, fn_db_gene_8: $i > $i).
% 29.20/29.00  tff(decl_29127, type, fn_db_gene_9: $i > $i).
% 29.20/29.00  tff(decl_29128, type, fn_db_gene_10: $i > $i).
% 29.20/29.00  tff(decl_29129, type, fn_db_gene_11: $i > $i).
% 29.20/29.00  tff(decl_29130, type, fn_gene_17: $i > $i).
% 29.20/29.00  tff(decl_29131, type, fn_gene_16: $i > $i).
% 29.20/29.00  tff(decl_29132, type, 'DDT': $i).
% 29.20/29.00  tff(decl_29133, type, 'DDT is an insecticide that is also toxic to animals and humans': $i).
% 29.20/29.00  tff(decl_29134, type, dichlorodiphenyltrichloroethane: $i).
% 29.20/29.00  tff(decl_29135, type, ddt: $i).
% 29.20/29.00  tff(decl_29136, type, fn_ddt_1: $i > $i).
% 29.20/29.00  tff(decl_29137, type, fn_ddt_2: $i > $i).
% 29.20/29.00  tff(decl_29138, type, insecticide_1: $i > $o).
% 29.20/29.00  tff(decl_29139, type, fn_ddt_3: $i > $i).
% 29.20/29.00  tff(decl_29140, type, fn_ddt_4: $i > $i).
% 29.20/29.00  tff(decl_29141, type, fn_ddt_5: $i > $i).
% 29.20/29.00  tff(decl_29142, type, 'De-Etiolation': $i).
% 29.20/29.00  tff(decl_29143, type, 'Also known as greening, de-etiolation includes a series of physiological changes, such as the production of chlorophyll which occurs in a plant in response to sunlight.': $i).
% 29.20/29.00  tff(decl_29144, type, greening: $i).
% 29.20/29.00  tff(decl_29145, type, 'de etiolate': $i).
% 29.20/29.00  tff(decl_29146, type, 'de-etiolate': $i).
% 29.20/29.00  tff(decl_29147, type, 'de etiolation': $i).
% 29.20/29.00  tff(decl_29148, type, 'de-etiolation': $i).
% 29.20/29.00  tff(decl_29149, type, plant_intercellular_process_1: $i > $o).
% 29.20/29.00  tff(decl_29150, type, deacetylation_1: $i > $o).
% 29.20/29.00  tff(decl_29151, type, 'Deacetylation': $i).
% 29.20/29.00  tff(decl_29152, type, 'The removal of an acetyl group from a compound.': $i).
% 29.20/29.00  tff(decl_29153, type, deacetylate: $i).
% 29.20/29.00  tff(decl_29154, type, deacetylation: $i).
% 29.20/29.00  tff(decl_29155, type, fn_deacetylation_1: $i > $i).
% 29.20/29.00  tff(decl_29156, type, 'Deactivate': $i).
% 29.20/29.00  tff(decl_29157, type, deactivate: $i).
% 29.20/29.00  tff(decl_29158, type, disable: $i).
% 29.20/29.00  tff(decl_29159, type, disenable: $i).
% 29.20/29.00  tff(decl_29160, type, inactivate: $i).
% 29.20/29.00  tff(decl_29161, type, incapacitate: $i).
% 29.20/29.00  tff(decl_29162, type, 'Dead-Cell': $i).
% 29.20/29.00  tff(decl_29163, type, 'Remains of living cell.': $i).
% 29.20/29.00  tff(decl_29164, type, 'lost cell': $i).
% 29.20/29.00  tff(decl_29165, type, 'nonliving cell': $i).
% 29.20/29.00  tff(decl_29166, type, 'nonliving-cell': $i).
% 29.20/29.00  tff(decl_29167, type, 'cell of dead': $i).
% 29.20/29.00  tff(decl_29168, type, 'dead cell': $i).
% 29.20/29.00  tff(decl_29169, type, 'dead-cell': $i).
% 29.20/29.00  tff(decl_29170, type, non_living_entity_1: $i > $o).
% 29.20/29.00  tff(decl_29171, type, 'Dead-Organism': $i).
% 29.20/29.00  tff(decl_29172, type, 'The organism which is not living.': $i).
% 29.20/29.00  tff(decl_29173, type, 'nonliving organism': $i).
% 29.20/29.00  tff(decl_29174, type, 'nonliving-organism': $i).
% 29.20/29.00  tff(decl_29175, type, 'organism of dead': $i).
% 29.20/29.00  tff(decl_29176, type, 'dead organism': $i).
% 29.20/29.00  tff(decl_29177, type, 'dead-organism': $i).
% 29.20/29.00  tff(decl_29178, type, fn_dead_organism_1: $i > $i).
% 29.20/29.00  tff(decl_29179, type, fn_dead_organism_2: $i > $i).
% 29.20/29.00  tff(decl_29180, type, 'Deamination': $i).
% 29.20/29.00  tff(decl_29181, type, 'Deamination is the removal of an amine group from a molecule. Enzymes which catalyse this reaction are called deaminases.': $i).
% 29.20/29.00  tff(decl_29182, type, deaminate: $i).
% 29.20/29.00  tff(decl_29183, type, deamination: $i).
% 29.20/29.00  tff(decl_29184, type, fn_deamination_1: $i > $i).
% 29.20/29.00  tff(decl_29185, type, fn_deamination_2: $i > $i).
% 29.20/29.00  tff(decl_29186, type, fn_deamination_3: $i > $i).
% 29.20/29.00  tff(decl_29187, type, fn_deamination_4: $i > $i).
% 29.20/29.00  tff(decl_29188, type, fn_deamination_5: $i > $i).
% 29.20/29.00  tff(decl_29189, type, fn_deamination_6: $i > $i).
% 29.20/29.00  tff(decl_29190, type, fn_deamination_7: $i > $i).
% 29.20/29.00  tff(decl_29191, type, fn_deamination_8: $i > $i).
% 29.20/29.00  tff(decl_29192, type, 'Death': $i).
% 29.20/29.00  tff(decl_29193, type, 'The event of dying or departure from life.': $i).
% 29.20/29.00  tff(decl_29194, type, death: $i).
% 29.20/29.00  tff(decl_29195, type, 'Death-Signal': $i).
% 29.20/29.00  tff(decl_29196, type, 'Cell signal which carries the message which induces programmed cell death (apoptosis).': $i).
% 29.20/29.00  tff(decl_29197, type, 'signal of death': $i).
% 29.20/29.00  tff(decl_29198, type, 'death signal': $i).
% 29.20/29.00  tff(decl_29199, type, 'death-signal': $i).
% 29.20/29.00  tff(decl_29200, type, 'Debris': $i).
% 29.20/29.00  tff(decl_29201, type, 'Debris is rubble, wreckage, and discarded garbage/refuse/trash, scattered remains of something destroyed, or, in geology, large rock fragments left by a melting glacier, etc.': $i).
% 29.20/29.00  tff(decl_29202, type, debris: $i).
% 29.20/29.00  tff(decl_29203, type, 'Decapod': $i).
% 29.20/29.00  tff(decl_29204, type, 'A member of the group of crustaceans that includes lobsters, crayfishes, crabs, and shrimps.': $i).
% 29.20/29.00  tff(decl_29205, type, decapod: $i).
% 29.20/29.00  tff(decl_29206, type, 'Decarboxylation': $i).
% 29.20/29.00  tff(decl_29207, type, 'Chemical reaction which involves the removal of carbon dioxide from the reactant.': $i).
% 29.20/29.00  tff(decl_29208, type, decarboxylate: $i).
% 29.20/29.00  tff(decl_29209, type, decarboxylation: $i).
% 29.20/29.00  tff(decl_29210, type, deceive_1: $i > $o).
% 29.20/29.00  tff(decl_29211, type, 'Deceive': $i).
% 29.20/29.00  tff(decl_29212, type, deceive: $i).
% 29.20/29.00  tff(decl_29213, type, 'lead on': $i).
% 29.20/29.00  tff(decl_29214, type, lead_on: $i).
% 29.20/29.00  tff(decl_29215, type, delude: $i).
% 29.20/29.00  tff(decl_29216, type, cozen: $i).
% 29.20/29.00  tff(decl_29217, type, betray: $i).
% 29.20/29.00  tff(decl_29218, type, 'lead astray': $i).
% 29.20/29.00  tff(decl_29219, type, lead_astray: $i).
% 29.20/29.00  tff(decl_29220, type, lie: $i).
% 29.20/29.00  tff(decl_29221, type, lie_1: $i > $o).
% 29.20/29.00  tff(decl_29222, type, fn_deceive_1: $i > $i).
% 29.20/29.00  tff(decl_29223, type, fn_deceive_2: $i > $i).
% 29.20/29.00  tff(decl_29224, type, fn_deceive_3: $i > $i).
% 29.20/29.00  tff(decl_29225, type, fn_interpret_1: $i > $i).
% 29.20/29.00  tff(decl_29226, type, fn_express_1: $i > $i).
% 29.20/29.00  tff(decl_29227, type, 'Decomposer': $i).
% 29.20/29.00  tff(decl_29228, type, 'Decomposers (or saprotrophs) are organisms that break down dead or decaying organisms, and in doing so carry out the natural process of decomposition. Like herbivores and predators, decomposers are heterotrophic, meaning that they use organic substrates to get their energy, carbon and nutrients for growth and development. Decomposers use deceased organisms and non-living organic compounds as their food source.': $i).
% 29.20/29.00  tff(decl_29229, type, saprotroph: $i).
% 29.20/29.00  tff(decl_29230, type, decomposer: $i).
% 29.20/29.00  tff(decl_29231, type, obligate_anaerobe_1: $i > $o).
% 29.20/29.00  tff(decl_29232, type, fn_decomposer_2: $i > $i).
% 29.20/29.00  tff(decl_29233, type, fn_decomposer_3: $i > $i).
% 29.20/29.00  tff(decl_29234, type, fn_decomposer_4: $i > $i).
% 29.20/29.00  tff(decl_29235, type, fn_decomposer_5: $i > $i).
% 29.20/29.00  tff(decl_29236, type, fn_decomposer_6: $i > $i).
% 29.20/29.00  tff(decl_29237, type, decomposers_1: $i > $o).
% 29.20/29.00  tff(decl_29238, type, 'Decomposers': $i).
% 29.20/29.00  tff(decl_29239, type, 'Group of organisms in an ecosystem which derives energy and nutrients from detritus through the process of decomposition.': $i).
% 29.20/29.00  tff(decl_29240, type, 'Decomposition': $i).
% 29.20/29.00  tff(decl_29241, type, 'A process of decomposing dead organic material into its constituent nutrients.': $i).
% 29.20/29.00  tff(decl_29242, type, decompose: $i).
% 29.20/29.00  tff(decl_29243, type, decomposition: $i).
% 29.20/29.00  tff(decl_29244, type, fn_decomposition_8: $i > $i).
% 29.20/29.00  tff(decl_29245, type, fn_decomposition_9: $i > $i).
% 29.20/29.00  tff(decl_29246, type, fn_decomposition_11: $i > $i).
% 29.20/29.00  tff(decl_29247, type, fn_decomposition_12: $i > $i).
% 29.20/29.00  tff(decl_29248, type, fn_decomposition_13: $i > $i).
% 29.20/29.00  tff(decl_29249, type, fn_fungus_1: $i > $i).
% 29.20/29.00  tff(decl_29250, type, 'Decomposition-Reaction': $i).
% 29.20/29.00  tff(decl_29251, type, 'A decomposition reaction is a chemical reaction in which one compound is split into two or more chemical subunits.': $i).
% 29.20/29.00  tff(decl_29252, type, 'reaction of decomposition': $i).
% 29.20/29.00  tff(decl_29253, type, 'decomposition reaction': $i).
% 29.20/29.00  tff(decl_29254, type, 'decomposition-reaction': $i).
% 29.20/29.00  tff(decl_29255, type, fn_decomposition_reaction_1: $i > $i).
% 29.20/29.00  tff(decl_29256, type, fn_decomposition_reaction_3: $i > $i).
% 29.20/29.00  tff(decl_29257, type, 'Decrease': $i).
% 29.20/29.00  tff(decl_29258, type, decrease: $i).
% 29.20/29.00  tff(decl_29259, type, diminish: $i).
% 29.20/29.00  tff(decl_29260, type, lessen: $i).
% 29.20/29.00  tff(decl_29261, type, minify: $i).
% 29.20/29.00  tff(decl_29262, type, shorten: $i).
% 29.20/29.00  tff(decl_29263, type, deductive_reasoning_1: $i > $o).
% 29.20/29.00  tff(decl_29264, type, 'Deductive-Reasoning': $i).
% 29.20/29.00  tff(decl_29265, type, 'The process of reasoning from a general premise to a specific prediction.': $i).
% 29.20/29.00  tff(decl_29266, type, 'deductive reasoning': $i).
% 29.20/29.00  tff(decl_29267, type, 'deductive-reasoning': $i).
% 29.20/29.00  tff(decl_29268, type, scientific_method_1: $i > $o).
% 29.20/29.00  tff(decl_29269, type, 'Deep-Green': $i).
% 29.20/29.00  tff(decl_29270, type, 'An international research initiative that consists of several research groups focusing on some aspect of green plant phylogeny or systematics. These research groups are collectively known as the Green Plant Phylogeny Research Coordination Group (GPPRCG).': $i).
% 29.20/29.00  tff(decl_29271, type, 'green of deep': $i).
% 29.20/29.00  tff(decl_29272, type, 'deep green': $i).
% 29.20/29.00  tff(decl_29273, type, 'deep-green': $i).
% 29.20/29.00  tff(decl_29274, type, 'Deep-Sea-Hydrothermal-Vent': $i).
% 29.20/29.00  tff(decl_29275, type, 'Crack in the crust of the ocean floor near the ocean ridge systems. Vents discharge super-hot and sulfide-rich water into the ocean and are the basis for a chemosynthesis-based deep-sea ecosystem.': $i).
% 29.20/29.00  tff(decl_29276, type, 'deep sea hot spring': $i).
% 29.20/29.01  tff(decl_29277, type, 'deep-sea-hot-spring': $i).
% 29.20/29.01  tff(decl_29278, type, 'deep sea volcanic spring': $i).
% 29.20/29.01  tff(decl_29279, type, 'deep-sea-volcanic-spring': $i).
% 29.20/29.01  tff(decl_29280, type, 'black smoker': $i).
% 29.20/29.01  tff(decl_29281, type, 'black-smoker': $i).
% 29.20/29.01  tff(decl_29282, type, 'deep sea hydrothermal vent': $i).
% 29.20/29.01  tff(decl_29283, type, 'deep-sea hydrothermal vent': $i).
% 29.20/29.01  tff(decl_29284, type, 'deep-sea-hydrothermal-vent': $i).
% 29.20/29.01  tff(decl_29285, type, fn_deep_sea_hydrothermal_vent_1: $i > $i).
% 29.20/29.01  tff(decl_29286, type, fn_deep_sea_hydrothermal_vent_2: $i > $i).
% 29.20/29.01  tff(decl_29287, type, producers_1: $i > $o).
% 29.20/29.01  tff(decl_29288, type, fn_deep_sea_hydrothermal_vent_3: $i > $i).
% 29.20/29.01  tff(decl_29289, type, fn_deep_sea_hydrothermal_vent_4: $i > $i).
% 29.20/29.01  tff(decl_29290, type, fn_deep_sea_hydrothermal_vent_5: $i > $i).
% 29.20/29.01  tff(decl_29291, type, fn_deep_sea_hydrothermal_vent_6: $i > $i).
% 29.20/29.01  tff(decl_29292, type, fn_deep_sea_hydrothermal_vent_8: $i > $i).
% 29.20/29.01  tff(decl_29293, type, fn_deep_sea_hydrothermal_vent_9: $i > $i).
% 29.20/29.01  tff(decl_29294, type, fn_electromagnetic_energy_2: $i > $i).
% 29.20/29.01  tff(decl_29295, type, fn_electromagnetic_energy_3: $i > $i).
% 29.20/29.01  tff(decl_29296, type, fn_ecosystem_9: $i > $i).
% 29.20/29.01  tff(decl_29297, type, fn_deep_sea_hydrothermal_vent_7: $i > $i).
% 29.20/29.01  tff(decl_29298, type, fn_ecosystem_30: $i > $i).
% 29.20/29.01  tff(decl_29299, type, fn_ecosystem_2: $i > $i).
% 29.20/29.01  tff(decl_29300, type, fn_ecosystem_21: $i > $i).
% 29.20/29.01  tff(decl_29301, type, fn_ecosystem_18: $i > $i).
% 29.20/29.01  tff(decl_29302, type, 'Deepen': $i).
% 29.20/29.01  tff(decl_29303, type, 'Increase in depth.': $i).
% 29.20/29.01  tff(decl_29304, type, deepen: $i).
% 29.20/29.01  tff(decl_29305, type, 'Defective-Chromosome': $i).
% 29.20/29.01  tff(decl_29306, type, 'A chromosome that has become defective due to mutation or any other cellular processes.': $i).
% 29.20/29.01  tff(decl_29307, type, 'defective chromosome': $i).
% 29.20/29.01  tff(decl_29308, type, 'defective-chromosome': $i).
% 29.20/29.01  tff(decl_29309, type, 'Defense': $i).
% 29.20/29.01  tff(decl_29310, type, protect: $i).
% 29.20/29.01  tff(decl_29311, type, defend: $i).
% 29.20/29.01  tff(decl_29312, type, defense: $i).
% 29.20/29.01  tff(decl_29313, type, protection: $i).
% 29.20/29.01  tff(decl_29314, type, 'Defensive-Protein': $i).
% 29.20/29.01  tff(decl_29315, type, 'Proteins acting as defensive agents are called defensive proteins.': $i).
% 29.20/29.01  tff(decl_29316, type, 'protein of defensive': $i).
% 29.20/29.01  tff(decl_29317, type, 'defensive protein': $i).
% 29.20/29.01  tff(decl_29318, type, 'defensive-protein': $i).
% 29.20/29.01  tff(decl_29319, type, deforestation_1: $i > $o).
% 29.20/29.01  tff(decl_29320, type, 'Deforestation': $i).
% 29.20/29.01  tff(decl_29321, type, 'The clearance of forests by logging and/or burning, on land that is then converted to non-forest use.': $i).
% 29.20/29.01  tff(decl_29322, type, deforest: $i).
% 29.20/29.01  tff(decl_29323, type, deforestation: $i).
% 29.20/29.01  tff(decl_29324, type, degenerative_model_1: $i > $o).
% 29.20/29.01  tff(decl_29325, type, 'Degenerative-model': $i).
% 29.20/29.01  tff(decl_29326, type, 'Degenerative model refers to model used to study progressive impairment of both the structure and function of part of the body.': $i).
% 29.20/29.01  tff(decl_29327, type, 'degenerative model': $i).
% 29.20/29.01  tff(decl_29328, type, 'degenerative-model': $i).
% 29.20/29.01  tff(decl_29329, type, in_situ_1: $i > $o).
% 29.20/29.01  tff(decl_29330, type, degradation_1: $i > $o).
% 29.20/29.01  tff(decl_29331, type, 'Degradation': $i).
% 29.20/29.01  tff(decl_29332, type, 'A process of decomposition which occurs in stages over time.': $i).
% 29.20/29.01  tff(decl_29333, type, degradation: $i).
% 29.20/29.01  tff(decl_29334, type, degranulation_1: $i > $o).
% 29.20/29.01  tff(decl_29335, type, 'Degranulation': $i).
% 29.20/29.01  tff(decl_29336, type, 'The release of histamines and other inflammatory agents from the vesicles of certain cells of the immune system.': $i).
% 29.20/29.01  tff(decl_29337, type, degranulate: $i).
% 29.20/29.01  tff(decl_29338, type, degranulation: $i).
% 29.20/29.01  tff(decl_29339, type, 'Dehydration-Reaction': $i).
% 29.20/29.01  tff(decl_29340, type, 'A dehydration reaction is defined as a chemical reaction that involves the loss of water from the reacting molecule. Dehydration reactions are a subset of elimination reactions.': $i).
% 29.20/29.01  tff(decl_29341, type, 'dehydration synthesis': $i).
% 29.20/29.01  tff(decl_29342, type, 'reaction of dehydration': $i).
% 29.20/29.01  tff(decl_29343, type, 'dehydration reaction': $i).
% 29.20/29.01  tff(decl_29344, type, 'dehydration-reaction': $i).
% 29.20/29.01  tff(decl_29345, type, 'Dehydrogenase': $i).
% 29.20/29.01  tff(decl_29346, type, 'A dehydrogenase (also called DHO in the literature) is an enzyme that oxidizes a substrate by transferring one or more hydrides (H?) to an acceptor, usually NAD+/NADP+ or a flavin coenzyme such as FAD or FMN.': $i).
% 29.20/29.01  tff(decl_29347, type, dho: $i).
% 29.20/29.01  tff(decl_29348, type, dehydrogenase: $i).
% 29.20/29.01  tff(decl_29349, type, fn_dehydrogenase_4: $i > $i).
% 29.20/29.01  tff(decl_29350, type, fn_dehydrogenase_5: $i > $i).
% 29.20/29.01  tff(decl_29351, type, fn_dehydrogenase_6: $i > $i).
% 29.20/29.01  tff(decl_29352, type, fn_dehydrogenase_7: $i > $i).
% 29.20/29.01  tff(decl_29353, type, fn_dehydrogenase_8: $i > $i).
% 29.20/29.01  tff(decl_29354, type, fn_dehydrogenase_21: $i > $i).
% 29.20/29.01  tff(decl_29355, type, fn_dehydrogenase_23: $i > $i).
% 29.20/29.01  tff(decl_29356, type, fn_dehydrogenase_24: $i > $i).
% 29.20/29.01  tff(decl_29357, type, substrate_1: $i > $o).
% 29.20/29.01  tff(decl_29358, type, fn_dehydrogenase_26: $i > $i).
% 29.20/29.01  tff(decl_29359, type, fn_dehydrogenase_27: $i > $i).
% 29.20/29.01  tff(decl_29360, type, fn_dehydrogenase_31: $i > $i).
% 29.20/29.01  tff(decl_29361, type, hydrogen_ion_0: $i).
% 29.20/29.01  tff(decl_29362, type, fn_oxidoreductase_3: $i > $i).
% 29.20/29.01  tff(decl_29363, type, fn_oxidoreductase_12: $i > $i).
% 29.20/29.01  tff(decl_29364, type, deletion_1: $i > $o).
% 29.20/29.01  tff(decl_29365, type, 'Deletion': $i).
% 29.20/29.01  tff(decl_29366, type, 'A deficiency in a chromosome resulting from the loss of a fragment through breakage. (2) A mutational loss of one or more nucleotide pairs from a gene.': $i).
% 29.20/29.01  tff(decl_29367, type, delete: $i).
% 29.20/29.01  tff(decl_29368, type, deletion: $i).
% 29.20/29.01  tff(decl_29369, type, fn_deletion_1: $i > $i).
% 29.20/29.01  tff(decl_29370, type, 'Deletion-Of-Chromosome-Fragment': $i).
% 29.20/29.01  tff(decl_29371, type, 'An alteration of chromosome structure that occurs when a chromosomal fragment lacking a centromere is lost during cell division.': $i).
% 29.20/29.01  tff(decl_29372, type, 'deletion of chromosome fragment': $i).
% 29.20/29.01  tff(decl_29373, type, 'deletion-of-chromosome-fragment': $i).
% 29.20/29.01  tff(decl_29374, type, fn_deletion_of_chromosome_fragment_1: $i > $i).
% 29.20/29.01  tff(decl_29375, type, fn_deletion_of_chromosome_fragment_2: $i > $i).
% 29.20/29.01  tff(decl_29376, type, fn_deletion_of_chromosome_fragment_3: $i > $i).
% 29.20/29.01  tff(decl_29377, type, 'Deliver': $i).
% 29.20/29.01  tff(decl_29378, type, 'get in': $i).
% 29.20/29.01  tff(decl_29379, type, deliver: $i).
% 29.20/29.01  tff(decl_29380, type, 'hand over': $i).
% 29.20/29.01  tff(decl_29381, type, hand_over: $i).
% 29.20/29.01  tff(decl_29382, type, get_in: $i).
% 29.20/29.01  tff(decl_29383, type, render: $i).
% 29.20/29.01  tff(decl_29384, type, 'turn in': $i).
% 29.20/29.01  tff(decl_29385, type, turn_in: $i).
% 29.20/29.01  tff(decl_29386, type, delta_formin_yeast_1: $i > $o).
% 29.20/29.01  tff(decl_29387, type, 'Delta-Formin-Yeast': $i).
% 29.20/29.01  tff(decl_29388, type, 'Modified strain of yeast cells which lacks the gene to produce formin, a molecule which plays a role in the formation of shmoos during yeast mating. This strain was used to study the signaling events involved in yeast mating.': $i).
% 29.20/29.01  tff(decl_29389, type, 'delta formin yeast': $i).
% 29.20/29.01  tff(decl_29390, type, 'delta-formin-yeast': $i).
% 29.20/29.01  tff(decl_29391, type, delta_fus3_yeast_1: $i > $o).
% 29.20/29.01  tff(decl_29392, type, 'Delta-Fus3-Yeast': $i).
% 29.20/29.01  tff(decl_29393, type, 'Modified strain of yeast cells which lacks the gene to produce fus 3 kinase, a molecule which plays a role in the formation of shmoos during yeast mating. This strain was used to study the signaling events involved in yeast mating.': $i).
% 29.20/29.01  tff(decl_29394, type, 'delta fus3 yeast': $i).
% 29.20/29.01  tff(decl_29395, type, 'delta-fus3-yeast': $i).
% 29.20/29.01  tff(decl_29396, type, demographic_transition_1: $i > $o).
% 29.20/29.01  tff(decl_29397, type, 'Demographic-Transition': $i).
% 29.20/29.01  tff(decl_29398, type, 'A shift from rapid population growth in which birth rate outpaces death rate to zero population growth characterized by low birth and death rates.': $i).
% 29.20/29.01  tff(decl_29399, type, 'transition of demographic': $i).
% 29.20/29.01  tff(decl_29400, type, 'demographic transition': $i).
% 29.20/29.01  tff(decl_29401, type, 'demographic-transition': $i).
% 29.20/29.01  tff(decl_29402, type, demography_1: $i > $o).
% 29.20/29.01  tff(decl_29403, type, emigration_1: $i > $o).
% 29.20/29.01  tff(decl_29404, type, immigration_1: $i > $o).
% 29.20/29.01  tff(decl_29405, type, 'Demography': $i).
% 29.20/29.01  tff(decl_29406, type, 'The study of statistics relating to births and deaths in populations.': $i).
% 29.20/29.01  tff(decl_29407, type, demography: $i).
% 29.20/29.01  tff(decl_29408, type, exponential_population_growth_1: $i > $o).
% 29.20/29.01  tff(decl_29409, type, extinction_vortex_1: $i > $o).
% 29.20/29.01  tff(decl_29410, type, logistic_population_growth_1: $i > $o).
% 29.20/29.01  tff(decl_29411, type, propagation_1: $i > $o).
% 29.20/29.01  tff(decl_29412, type, 'Denaturation': $i).
% 29.20/29.01  tff(decl_29413, type, 'A process by which proteins and nucleic acids lose their tertiary and secondary structure and become biologically inactive. Denaturation occurs under conditions of extreme temperature, pH, or salt concentration.': $i).
% 29.20/29.01  tff(decl_29414, type, denature: $i).
% 29.20/29.01  tff(decl_29415, type, denaturation: $i).
% 29.20/29.01  tff(decl_29416, type, fn_denaturation_1: $i > $i).
% 29.20/29.01  tff(decl_29417, type, fn_denaturation_2: $i > $i).
% 29.20/29.01  tff(decl_29418, type, denaturation_agent_1: $i > $o).
% 29.20/29.01  tff(decl_29419, type, 'Denaturation-Agent': $i).
% 29.20/29.01  tff(decl_29420, type, 'A force or chemical that disrupts the hydrogen bonds and side chain interactions in a protein, causing the protein to unfold.': $i).
% 29.20/29.01  tff(decl_29421, type, 'denaturing agent': $i).
% 29.20/29.01  tff(decl_29422, type, 'denaturing-agent': $i).
% 29.20/29.01  tff(decl_29423, type, 'agent of denaturation': $i).
% 29.20/29.01  tff(decl_29424, type, 'denaturation agent': $i).
% 29.20/29.01  tff(decl_29425, type, 'denaturation-agent': $i).
% 29.20/29.01  tff(decl_29426, type, fn_denaturation_agent_1: $i > $i).
% 29.20/29.01  tff(decl_29427, type, denature_dna_1: $i > $o).
% 29.20/29.01  tff(decl_29428, type, 'Denature-DNA': $i).
% 29.20/29.01  tff(decl_29429, type, 'Denaturation of double-stranded DNA that results in two single strands of DNA. In this process, heat breaks the strands apart, preventing them from hydrogen bonding.': $i).
% 29.20/29.01  tff(decl_29430, type, 'dna denaturation': $i).
% 29.20/29.01  tff(decl_29431, type, 'dna of denature': $i).
% 29.20/29.01  tff(decl_29432, type, 'denature dna': $i).
% 29.20/29.01  tff(decl_29433, type, 'denature-dna': $i).
% 29.20/29.01  tff(decl_29434, type, protein_denaturation_1: $i > $o).
% 29.20/29.01  tff(decl_29435, type, fn_denature_dna_1: $i > $i).
% 29.20/29.01  tff(decl_29436, type, fn_denature_dna_2: $i > $i).
% 29.20/29.01  tff(decl_29437, type, fn_denature_dna_3: $i > $i).
% 29.20/29.01  tff(decl_29438, type, fn_denature_dna_4: $i > $i).
% 29.20/29.01  tff(decl_29439, type, fn_denature_dna_5: $i > $i).
% 29.20/29.01  tff(decl_29440, type, fn_denature_dna_6: $i > $i).
% 29.20/29.01  tff(decl_29441, type, fn_denature_dna_7: $i > $i).
% 29.20/29.01  tff(decl_29442, type, "95.0e0": $i).
% 29.20/29.01  tff(decl_29443, type, fn_denature_dna_8: $i > $i).
% 29.20/29.01  tff(decl_29444, type, 'Denatured-Protein': $i).
% 29.20/29.01  tff(decl_29445, type, 'A biolgically inactive protein that has lost its functional conformation by exposure to a destabilizing agent such as heat or detergent.': $i).
% 29.20/29.01  tff(decl_29446, type, 'denatured protein': $i).
% 29.20/29.01  tff(decl_29447, type, 'denatured-protein': $i).
% 29.20/29.01  tff(decl_29448, type, 'Dendrite': $i).
% 29.20/29.01  tff(decl_29449, type, 'A branched extension of the soma of a neuron, that receives electrochemical stimulation from other neurons.': $i).
% 29.20/29.01  tff(decl_29450, type, dendrite: $i).
% 29.20/29.01  tff(decl_29451, type, fn_dendrite_1: $i > $i).
% 29.20/29.01  tff(decl_29452, type, fn_dendrite_2: $i > $i).
% 29.20/29.01  tff(decl_29453, type, fn_dendrite_3: $i > $i).
% 29.20/29.01  tff(decl_29454, type, dendritic_cell_1: $i > $o).
% 29.20/29.01  tff(decl_29455, type, 'Dendritic-Cell': $i).
% 29.20/29.01  tff(decl_29456, type, 'Cells of the immune system that present antigens to helper T cells and thus initiate a primary immune response.': $i).
% 29.20/29.01  tff(decl_29457, type, 'dendritic cell': $i).
% 29.20/29.01  tff(decl_29458, type, 'dendritic-cell': $i).
% 29.20/29.01  tff(decl_29459, type, denitrification_1: $i > $o).
% 29.20/29.01  tff(decl_29460, type, 'Denitrification': $i).
% 29.20/29.01  tff(decl_29461, type, 'The biological process of reducing nitrate through a number of intermediate forms and, ultimately, to molecular nitrogen. The only organisms capable of denitrification are certain prokaryotes.': $i).
% 29.20/29.01  tff(decl_29462, type, denitrify: $i).
% 29.20/29.01  tff(decl_29463, type, denitrification: $i).
% 29.20/29.01  tff(decl_29464, type, fn_denitrification_1: $i > $i).
% 29.20/29.01  tff(decl_29465, type, fn_denitrification_2: $i > $i).
% 29.20/29.01  tff(decl_29466, type, fn_denitrification_3: $i > $i).
% 29.20/29.01  tff(decl_29467, type, fn_denitrification_4: $i > $i).
% 29.20/29.01  tff(decl_29468, type, fn_denitrification_5: $i > $i).
% 29.20/29.01  tff(decl_29469, type, fn_denitrification_6: $i > $i).
% 29.20/29.01  tff(decl_29470, type, fn_denitrification_7: $i > $i).
% 29.20/29.01  tff(decl_29471, type, denitrifying_bacterium_1: $i > $o).
% 29.20/29.01  tff(decl_29472, type, fn_n2_gas_1: $i > $i).
% 29.20/29.01  tff(decl_29473, type, 'Denitrifying-Bacterium': $i).
% 29.20/29.01  tff(decl_29474, type, 'A type of bacterium that converts forms of inorganic nitrogen to nitrogen gas.': $i).
% 29.20/29.01  tff(decl_29475, type, 'denitrifying bacterium': $i).
% 29.20/29.01  tff(decl_29476, type, 'denitrifying-bacterium': $i).
% 29.20/29.01  tff(decl_29477, type, fn_denitrifying_bacterium_1: $i > $i).
% 29.20/29.01  tff(decl_29478, type, fn_denitrifying_bacterium_2: $i > $i).
% 29.20/29.01  tff(decl_29479, type, fn_denitrifying_bacterium_3: $i > $i).
% 29.20/29.01  tff(decl_29480, type, fn_denitrifying_bacterium_8: $i > $i).
% 29.20/29.01  tff(decl_29481, type, fn_denitrifying_bacterium_9: $i > $i).
% 29.20/29.01  tff(decl_29482, type, fn_denitrifying_bacterium_10: $i > $i).
% 29.20/29.01  tff(decl_29483, type, fn_denitrifying_bacterium_11: $i > $i).
% 29.20/29.01  tff(decl_29484, type, fn_denitrifying_bacterium_12: $i > $i).
% 29.20/29.01  tff(decl_29485, type, fn_denitrifying_bacterium_13: $i > $i).
% 29.20/29.01  tff(decl_29486, type, fn_denitrifying_bacterium_14: $i > $i).
% 29.20/29.01  tff(decl_29487, type, fn_denitrifying_bacterium_15: $i > $i).
% 29.20/29.01  tff(decl_29488, type, fn_denitrifying_bacterium_16: $i > $i).
% 29.20/29.01  tff(decl_29489, type, fn_denitrifying_bacterium_17: $i > $i).
% 29.20/29.01  tff(decl_29490, type, fn_denitrifying_bacterium_18: $i > $i).
% 29.20/29.01  tff(decl_29491, type, fn_denitrifying_bacterium_19: $i > $i).
% 29.20/29.01  tff(decl_29492, type, fn_denitrifying_bacterium_20: $i > $i).
% 29.20/29.01  tff(decl_29493, type, fn_denitrifying_bacterium_21: $i > $i).
% 29.20/29.01  tff(decl_29494, type, fn_denitrifying_bacterium_7: $i > $i).
% 29.20/29.01  tff(decl_29495, type, fn_denitrifying_bacterium_4: $i > $i).
% 29.20/29.01  tff(decl_29496, type, fn_denitrifying_bacterium_6: $i > $i).
% 29.20/29.01  tff(decl_29497, type, fn_denitrifying_bacterium_5: $i > $i).
% 29.20/29.01  tff(decl_29498, type, 'Density-Constant': $i).
% 29.20/29.01  tff(decl_29499, type, 'constant of density': $i).
% 29.20/29.01  tff(decl_29500, type, 'density constant': $i).
% 29.20/29.01  tff(decl_29501, type, 'density-constant': $i).
% 29.20/29.01  tff(decl_29502, type, density_dependent_inhibition_1: $i > $o).
% 29.20/29.01  tff(decl_29503, type, 'Density-Dependent-Inhibition': $i).
% 29.20/29.01  tff(decl_29504, type, 'The observed phenomenon that causes animal cells to cease dividing when they become crowded.': $i).
% 29.20/29.01  tff(decl_29505, type, 'density dependent inhibition': $i).
% 29.20/29.01  tff(decl_29506, type, 'density-dependent-inhibition': $i).
% 29.20/29.01  tff(decl_29507, type, density_scale_1: $i > $o).
% 29.20/29.01  tff(decl_29508, type, 'Density-Scale': $i).
% 29.20/29.01  tff(decl_29509, type, 'scale of density': $i).
% 29.20/29.01  tff(decl_29510, type, 'density scale': $i).
% 29.20/29.01  tff(decl_29511, type, 'density-scale': $i).
% 29.20/29.01  tff(decl_29512, type, 'Density-Value': $i).
% 29.20/29.01  tff(decl_29513, type, 'the quantity per unit volume, unit area, or unit length': $i).
% 29.20/29.01  tff(decl_29514, type, denseness: $i).
% 29.20/29.01  tff(decl_29515, type, density: $i).
% 29.20/29.01  tff(decl_29516, type, 'value of density': $i).
% 29.20/29.01  tff(decl_29517, type, 'density value': $i).
% 29.20/29.01  tff(decl_29518, type, 'density-value': $i).
% 29.20/29.01  tff(decl_29519, type, dental_cavity_1: $i > $o).
% 29.20/29.01  tff(decl_29520, type, 'Dental-Cavity': $i).
% 29.20/29.01  tff(decl_29521, type, 'Hole produced through demineralization and destruction of the hard tissue of the teeth, brought about by acids produced by bacteria living in the mouth.': $i).
% 29.20/29.01  tff(decl_29522, type, 'dental cavity': $i).
% 29.20/29.01  tff(decl_29523, type, 'dental-cavity': $i).
% 29.20/29.01  tff(decl_29524, type, dental_cavity_formation_1: $i > $o).
% 29.20/29.01  tff(decl_29525, type, 'Dental-Cavity-Formation': $i).
% 29.20/29.01  tff(decl_29526, type, 'Process of demineralization and destruction of the hard tissue of the teeth, brought about by acids produced by bacteria living in the mouth.': $i).
% 29.20/29.01  tff(decl_29527, type, 'dental cavity formation': $i).
% 29.20/29.01  tff(decl_29528, type, 'dental-cavity-formation': $i).
% 29.20/29.01  tff(decl_29529, type, fn_dental_cavity_formation_1: $i > $i).
% 29.20/29.01  tff(decl_29530, type, fn_dental_cavity_formation_2: $i > $i).
% 29.20/29.01  tff(decl_29531, type, dental_plaque_1: $i > $o).
% 29.20/29.01  tff(decl_29532, type, fn_dental_cavity_formation_3: $i > $i).
% 29.20/29.01  tff(decl_29533, type, fn_dental_cavity_formation_4: $i > $i).
% 29.20/29.01  tff(decl_29534, type, fn_dental_plaque_1: $i > $i).
% 29.20/29.01  tff(decl_29535, type, fn_dental_plaque_2: $i > $i).
% 29.20/29.01  tff(decl_29536, type, 'Dental-Plaque': $i).
% 29.20/29.01  tff(decl_29537, type, 'Hardened, yellowish material which forms on teeth as a result of continual action of bacterial biofilms.': $i).
% 29.20/29.01  tff(decl_29538, type, 'dental plaque': $i).
% 29.20/29.01  tff(decl_29539, type, 'dental-plaque': $i).
% 29.20/29.01  tff(decl_29540, type, dental_plaque_formation_1: $i > $o).
% 29.20/29.01  tff(decl_29541, type, 'Dental-Plaque-Formation': $i).
% 29.20/29.01  tff(decl_29542, type, 'The formation of a hardened layer which forms on teeth as a result of continual action of bacterial biofilms.': $i).
% 29.20/29.01  tff(decl_29543, type, 'dental plaque formation': $i).
% 29.20/29.01  tff(decl_29544, type, 'dental-plaque-formation': $i).
% 29.20/29.01  tff(decl_29545, type, fn_dental_plaque_formation_1: $i > $i).
% 29.20/29.01  tff(decl_29546, type, fn_dental_plaque_formation_2: $i > $i).
% 29.20/29.01  tff(decl_29547, type, fn_dental_plaque_formation_3: $i > $i).
% 29.20/29.01  tff(decl_29548, type, dentition_1: $i > $o).
% 29.20/29.01  tff(decl_29549, type, 'Dentition': $i).
% 29.20/29.01  tff(decl_29550, type, 'An animal\\s assortment of teeth.': $i).
% 29.20/29.01  tff(decl_29551, type, dentition: $i).
% 29.20/29.01  tff(decl_29552, type, fn_dentition_1: $i > $i).
% 29.20/29.01  tff(decl_29553, type, tooth_0: $i).
% 29.20/29.01  tff(decl_29554, type, deoxyribonuclease_1: $i > $o).
% 29.20/29.01  tff(decl_29555, type, 'Deoxyribonuclease': $i).
% 29.20/29.01  tff(decl_29556, type, 'Enzymes which catalyze the hydrolytic cleavage of phosphodiester bonds in the DNA backbone.': $i).
% 29.20/29.01  tff(decl_29557, type, dnase: $i).
% 29.20/29.01  tff(decl_29558, type, 'dna nuclease': $i).
% 29.20/29.01  tff(decl_29559, type, deoxyribonuclease: $i).
% 29.20/29.01  tff(decl_29560, type, 'Deoxyribonucleoside-Monophosphate': $i).
% 29.20/29.01  tff(decl_29561, type, 'The chemical reactions and pathways resulting in the formation of a deoxyribonucleoside monophosphate, a glycosamine consisting of a base linked to a deoxyribose sugar esterified with phosphate on its glycose moiety.': $i).
% 29.20/29.01  tff(decl_29562, type, 'deoxyribonucleoside monophosphate': $i).
% 29.20/29.01  tff(decl_29563, type, 'deoxyribonucleoside-monophosphate': $i).
% 29.20/29.01  tff(decl_29564, type, deoxyribonucleotide_1: $i > $o).
% 29.20/29.01  tff(decl_29565, type, deoxyribonucleoside_triphosphate_1: $i > $o).
% 29.20/29.01  tff(decl_29566, type, 'Deoxyribonucleoside-Triphosphate': $i).
% 29.20/29.01  tff(decl_29567, type, 'The chemical reactions and pathways resulting in the formation of a deoxyribonucleoside triphosphate, a compound consisting of a nucleobase linked to a deoxyribose sugar esterified with triphosphate on the sugar.': $i).
% 29.20/29.01  tff(decl_29568, type, 'deoxyribonucleoside triphosphate': $i).
% 29.20/29.01  tff(decl_29569, type, 'deoxyribonucleoside-triphosphate': $i).
% 29.20/29.01  tff(decl_29570, type, 'Deoxyribonucleotide': $i).
% 29.20/29.01  tff(decl_29571, type, 'Deoxyribonucleotide is a part of DNA. It is comprised of Deoxyribose sugar, nitrogenous bases and phosphate group.': $i).
% 29.20/29.01  tff(decl_29572, type, 'deoxy ribonucleotide': $i).
% 29.20/29.01  tff(decl_29573, type, 'dna nucleotide': $i).
% 29.20/29.01  tff(decl_29574, type, 'dna-nucleotide': $i).
% 29.20/29.01  tff(decl_29575, type, deoxyribonucleotide: $i).
% 29.20/29.01  tff(decl_29576, type, fn_deoxyribonucleotide_1: $i > $i).
% 29.20/29.01  tff(decl_29577, type, fn_deoxyribonucleotide_2: $i > $i).
% 29.20/29.01  tff(decl_29578, type, fn_deoxyribonucleotide_3: $i > $i).
% 29.20/29.01  tff(decl_29579, type, fn_deoxyribonucleotide_4: $i > $i).
% 29.20/29.01  tff(decl_29580, type, fn_deoxyribonucleotide_5: $i > $i).
% 29.20/29.01  tff(decl_29581, type, fn_deoxyribonucleotide_6: $i > $i).
% 29.20/29.01  tff(decl_29582, type, fn_deoxyribonucleotide_7: $i > $i).
% 29.20/29.01  tff(decl_29583, type, fn_deoxyribonucleotide_8: $i > $i).
% 29.20/29.01  tff(decl_29584, type, deoxyribose_1: $i > $o).
% 29.20/29.01  tff(decl_29585, type, fn_deoxyribonucleotide_9: $i > $i).
% 29.20/29.01  tff(decl_29586, type, fn_deoxyribonucleotide_10: $i > $i).
% 29.20/29.01  tff(decl_29587, type, fn_deoxyribonucleotide_11: $i > $i).
% 29.20/29.01  tff(decl_29588, type, fn_deoxyribonucleotide_12: $i > $i).
% 29.20/29.01  tff(decl_29589, type, fn_deoxyribonucleotide_13: $i > $i).
% 29.20/29.01  tff(decl_29590, type, fn_deoxyribonucleotide_14: $i > $i).
% 29.20/29.01  tff(decl_29591, type, fn_deoxyribonucleotide_15: $i > $i).
% 29.20/29.01  tff(decl_29592, type, fn_deoxyribonucleotide_16: $i > $i).
% 29.20/29.01  tff(decl_29593, type, fn_deoxyribonucleotide_17: $i > $i).
% 29.20/29.01  tff(decl_29594, type, fn_deoxyribonucleotide_18: $i > $i).
% 29.20/29.01  tff(decl_29595, type, fn_deoxyribonucleotide_19: $i > $i).
% 29.20/29.01  tff(decl_29596, type, fn_deoxyribonucleotide_20: $i > $i).
% 29.20/29.01  tff(decl_29597, type, fn_deoxyribonucleotide_21: $i > $i).
% 29.20/29.01  tff(decl_29598, type, fn_deoxyribonucleotide_22: $i > $i).
% 29.20/29.01  tff(decl_29599, type, fn_deoxyribonucleotide_23: $i > $i).
% 29.20/29.01  tff(decl_29600, type, fn_deoxyribonucleotide_24: $i > $i).
% 29.20/29.01  tff(decl_29601, type, fn_deoxyribonucleotide_25: $i > $i).
% 29.20/29.01  tff(decl_29602, type, fn_deoxyribonucleotide_26: $i > $i).
% 29.20/29.01  tff(decl_29603, type, fn_deoxyribonucleotide_27: $i > $i).
% 29.20/29.01  tff(decl_29604, type, fn_nucleotide_20: $i > $i).
% 29.20/29.01  tff(decl_29605, type, fn_nucleotide_33: $i > $i).
% 29.20/29.01  tff(decl_29606, type, fn_nucleotide_34: $i > $i).
% 29.20/29.01  tff(decl_29607, type, fn_nucleotide_26: $i > $i).
% 29.20/29.01  tff(decl_29608, type, fn_nucleotide_16: $i > $i).
% 29.20/29.01  tff(decl_29609, type, fn_nucleotide_9: $i > $i).
% 29.20/29.01  tff(decl_29610, type, 'Deoxyribose': $i).
% 29.20/29.01  tff(decl_29611, type, 'Deoxyribose is a deoxy sugar derived from the pentose sugar ribose by the replacement of the hydroxyl group at the 2 position with hydrogen resulting in loss of one oxygen atom. It is basic structural unit of DNA': $i).
% 29.20/29.01  tff(decl_29612, type, '2 deoxyribose': $i).
% 29.20/29.01  tff(decl_29613, type, '2-deoxyribose': $i).
% 29.20/29.01  tff(decl_29614, type, 'd deoxyribose': $i).
% 29.20/29.01  tff(decl_29615, type, 'd-deoxyribose': $i).
% 29.20/29.01  tff(decl_29616, type, '2 deoxy d erythropentose thyminose': $i).
% 29.20/29.01  tff(decl_29617, type, '2-deoxy-d-erythropentose thyminose': $i).
% 29.20/29.01  tff(decl_29618, type, 'deoxyribose sugar': $i).
% 29.20/29.01  tff(decl_29619, type, '2 deoxy d erythro pentose thyminose': $i).
% 29.20/29.01  tff(decl_29620, type, '2-deoxy-d-erythro-pentose-thyminose': $i).
% 29.20/29.01  tff(decl_29621, type, deoxyribose: $i).
% 29.20/29.01  tff(decl_29622, type, department_1: $i > $o).
% 29.20/29.01  tff(decl_29623, type, 'Department': $i).
% 29.20/29.01  tff(decl_29624, type, 'an organization that is part of an institution': $i).
% 29.20/29.01  tff(decl_29625, type, department: $i).
% 29.20/29.01  tff(decl_29626, type, section: $i).
% 29.20/29.01  tff(decl_29627, type, group_1: $i > $o).
% 29.20/29.01  tff(decl_29628, type, 'Dephosphorylation': $i).
% 29.20/29.01  tff(decl_29629, type, 'Dephosphorylation is the removal of a phosphate (PO4) group from a protein or other organic molecule.': $i).
% 29.20/29.01  tff(decl_29630, type, dephosphorylate: $i).
% 29.20/29.01  tff(decl_29631, type, dephosphorylation: $i).
% 29.20/29.01  tff(decl_29632, type, fn_dephosphorylation_1: $i > $i).
% 29.20/29.01  tff(decl_29633, type, fn_dephosphorylation_2: $i > $i).
% 29.20/29.01  tff(decl_29634, type, fn_dephosphorylation_8: $i > $i).
% 29.20/29.01  tff(decl_29635, type, fn_dephosphorylation_9: $i > $i).
% 29.20/29.01  tff(decl_29636, type, fn_dephosphorylation_13: $i > $i).
% 29.20/29.01  tff(decl_29637, type, fn_dephosphorylation_14: $i > $i).
% 29.20/29.01  tff(decl_29638, type, fn_dephosphorylation_15: $i > $i).
% 29.20/29.01  tff(decl_29639, type, fn_dephosphorylation_16: $i > $i).
% 29.20/29.01  tff(decl_29640, type, fn_dephosphorylation_17: $i > $i).
% 29.20/29.01  tff(decl_29641, type, fn_dephosphorylation_18: $i > $i).
% 29.20/29.01  tff(decl_29642, type, fn_dephosphorylation_19: $i > $i).
% 29.20/29.01  tff(decl_29643, type, 'Dephosphorylation-Of-ATP': $i).
% 29.20/29.01  tff(decl_29644, type, 'The loss of one of three phosphate groups from a molecule of ATP.  This allows the release of energy contained in the bond between the phosphate groups.': $i).
% 29.20/29.01  tff(decl_29645, type, 'hydrolysis of atp': $i).
% 29.20/29.01  tff(decl_29646, type, 'hydrolysis-of-atp': $i).
% 29.20/29.01  tff(decl_29647, type, 'atp dephosphorylation': $i).
% 29.20/29.01  tff(decl_29648, type, 'atp-dephosphorylation': $i).
% 29.20/29.01  tff(decl_29649, type, 'dephosphorylation of atp': $i).
% 29.20/29.01  tff(decl_29650, type, 'dephosphorylation-of-atp': $i).
% 29.20/29.01  tff(decl_29651, type, fn_dephosphorylation_of_atp_1: $i > $i).
% 29.20/29.01  tff(decl_29652, type, fn_dephosphorylation_of_atp_3: $i > $i).
% 29.20/29.01  tff(decl_29653, type, fn_dephosphorylation_of_atp_4: $i > $i).
% 29.20/29.01  tff(decl_29654, type, fn_dephosphorylation_of_atp_5: $i > $i).
% 29.20/29.01  tff(decl_29655, type, fn_dephosphorylation_of_atp_6: $i > $i).
% 29.20/29.01  tff(decl_29656, type, fn_dephosphorylation_of_atp_7: $i > $i).
% 29.20/29.01  tff(decl_29657, type, fn_dephosphorylation_of_atp_17: $i > $i).
% 29.20/29.01  tff(decl_29658, type, fn_dephosphorylation_of_atp_18: $i > $i).
% 29.20/29.01  tff(decl_29659, type, fn_dephosphorylation_of_atp_19: $i > $i).
% 29.20/29.01  tff(decl_29660, type, fn_dephosphorylation_of_atp_20: $i > $i).
% 29.20/29.01  tff(decl_29661, type, fn_dephosphorylation_of_atp_21: $i > $i).
% 29.20/29.01  tff(decl_29662, type, fn_dephosphorylation_of_atp_22: $i > $i).
% 29.20/29.01  tff(decl_29663, type, fn_dephosphorylation_of_atp_23: $i > $i).
% 29.20/29.01  tff(decl_29664, type, fn_dephosphorylation_of_atp_24: $i > $i).
% 29.20/29.01  tff(decl_29665, type, fn_dephosphorylation_of_atp_25: $i > $i).
% 29.20/29.01  tff(decl_29666, type, fn_dephosphorylation_of_atp_26: $i > $i).
% 29.20/29.01  tff(decl_29667, type, fn_dephosphorylation_of_atp_27: $i > $i).
% 29.20/29.01  tff(decl_29668, type, fn_dephosphorylation_of_atp_28: $i > $i).
% 29.20/29.01  tff(decl_29669, type, fn_dephosphorylation_of_atp_29: $i > $i).
% 29.20/29.01  tff(decl_29670, type, fn_dephosphorylation_of_atp_30: $i > $i).
% 29.20/29.01  tff(decl_29671, type, fn_dephosphorylation_of_atp_31: $i > $i).
% 29.20/29.01  tff(decl_29672, type, fn_dephosphorylation_of_atp_32: $i > $i).
% 29.20/29.01  tff(decl_29673, type, fn_dephosphorylation_of_atp_33: $i > $i).
% 29.20/29.01  tff(decl_29674, type, fn_dephosphorylation_of_atp_34: $i > $i).
% 29.20/29.01  tff(decl_29675, type, fn_dephosphorylation_of_atp_35: $i > $i).
% 29.20/29.01  tff(decl_29676, type, fn_dephosphorylation_of_atp_36: $i > $i).
% 29.20/29.01  tff(decl_29677, type, fn_dephosphorylation_of_atp_37: $i > $i).
% 29.20/29.01  tff(decl_29678, type, fn_dephosphorylation_of_atp_38: $i > $i).
% 29.20/29.01  tff(decl_29679, type, fn_dephosphorylation_of_atp_39: $i > $i).
% 29.20/29.01  tff(decl_29680, type, fn_dephosphorylation_of_atp_40: $i > $i).
% 29.20/29.01  tff(decl_29681, type, fn_dephosphorylation_of_atp_41: $i > $i).
% 29.20/29.01  tff(decl_29682, type, fn_dephosphorylation_of_atp_42: $i > $i).
% 29.20/29.01  tff(decl_29683, type, fn_dephosphorylation_of_atp_52: $i > $i).
% 29.20/29.01  tff(decl_29684, type, phosphatase_1: $i > $o).
% 29.20/29.01  tff(decl_29685, type, fn_dephosphorylation_of_atp_83: $i > $i).
% 29.20/29.01  tff(decl_29686, type, fn_dephosphorylation_of_atp_84: $i > $i).
% 29.20/29.01  tff(decl_29687, type, fn_dephosphorylation_of_atp_85: $i > $i).
% 29.20/29.01  tff(decl_29688, type, fn_dephosphorylation_of_atp_86: $i > $i).
% 29.20/29.01  tff(decl_29689, type, fn_dephosphorylation_of_atp_87: $i > $i).
% 29.20/29.01  tff(decl_29690, type, fn_dephosphorylation_of_atp_88: $i > $i).
% 29.20/29.01  tff(decl_29691, type, fn_dephosphorylation_of_atp_89: $i > $i).
% 29.20/29.01  tff(decl_29692, type, fn_water_molecule_76: $i > $i).
% 29.20/29.01  tff(decl_29693, type, fn_water_molecule_33: $i > $i).
% 29.20/29.01  tff(decl_29694, type, fn_water_molecule_13: $i > $i).
% 29.20/29.01  tff(decl_29695, type, fn_water_molecule_35: $i > $i).
% 29.20/29.01  tff(decl_29696, type, fn_water_molecule_34: $i > $i).
% 29.20/29.01  tff(decl_29697, type, fn_water_molecule_36: $i > $i).
% 29.20/29.01  tff(decl_29698, type, fn_water_molecule_42: $i > $i).
% 29.20/29.01  tff(decl_29699, type, fn_water_molecule_48: $i > $i).
% 29.20/29.01  tff(decl_29700, type, fn_water_molecule_16: $i > $i).
% 29.20/29.01  tff(decl_29701, type, fn_water_molecule_39: $i > $i).
% 29.20/29.01  tff(decl_29702, type, fn_water_molecule_73: $i > $i).
% 29.20/29.01  tff(decl_29703, type, fn_nucleoside_triphosphate_5: $i > $i).
% 29.20/29.01  tff(decl_29704, type, fn_nucleoside_triphosphate_22: $i > $i).
% 29.20/29.01  tff(decl_29705, type, fn_nucleoside_triphosphate_6: $i > $i).
% 29.20/29.01  tff(decl_29706, type, fn_nucleoside_triphosphate_21: $i > $i).
% 29.20/29.01  tff(decl_29707, type, fn_water_molecule_38: $i > $i).
% 29.20/29.01  tff(decl_29708, type, fn_water_molecule_27: $i > $i).
% 29.20/29.01  tff(decl_29709, type, fn_water_molecule_46: $i > $i).
% 29.20/29.01  tff(decl_29710, type, fn_water_molecule_18: $i > $i).
% 29.20/29.01  tff(decl_29711, type, fn_water_molecule_54: $i > $i).
% 29.20/29.01  tff(decl_29712, type, fn_water_molecule_40: $i > $i).
% 29.20/29.01  tff(decl_29713, type, fn_water_molecule_26: $i > $i).
% 29.20/29.01  tff(decl_29714, type, fn_water_molecule_47: $i > $i).
% 29.20/29.01  tff(decl_29715, type, fn_water_molecule_72: $i > $i).
% 29.20/29.01  tff(decl_29716, type, fn_water_molecule_45: $i > $i).
% 29.20/29.01  tff(decl_29717, type, fn_water_molecule_44: $i > $i).
% 29.20/29.01  tff(decl_29718, type, fn_water_molecule_66: $i > $i).
% 29.20/29.01  tff(decl_29719, type, fn_water_molecule_50: $i > $i).
% 29.20/29.01  tff(decl_29720, type, fn_water_molecule_43: $i > $i).
% 29.20/29.01  tff(decl_29721, type, fn_water_molecule_51: $i > $i).
% 29.20/29.01  tff(decl_29722, type, fn_dephosphorylation_of_atp_13: $i > $i).
% 29.20/29.01  tff(decl_29723, type, fn_dephosphorylation_of_atp_14: $i > $i).
% 29.20/29.01  tff(decl_29724, type, fn_dephosphorylation_of_atp_16: $i > $i).
% 29.20/29.01  tff(decl_29725, type, fn_dephosphorylation_of_atp_12: $i > $i).
% 29.20/29.01  tff(decl_29726, type, fn_dephosphorylation_of_atp_11: $i > $i).
% 29.20/29.01  tff(decl_29727, type, fn_dephosphorylation_of_atp_10: $i > $i).
% 29.20/29.01  tff(decl_29728, type, fn_dephosphorylation_of_atp_9: $i > $i).
% 29.20/29.01  tff(decl_29729, type, fn_dephosphorylation_of_atp_8: $i > $i).
% 29.20/29.01  tff(decl_29730, type, fn_dephosphorylation_of_atp_15: $i > $i).
% 29.20/29.01  tff(decl_29731, type, dephosphorylation_of_glucose_6_phosphate_1: $i > $o).
% 29.20/29.01  tff(decl_29732, type, 'Dephosphorylation-Of-Glucose-6-Phosphate': $i).
% 29.20/29.01  tff(decl_29733, type, 'The removal of a phosphate (PO4) group from glucose-6-phosphate.': $i).
% 29.20/29.01  tff(decl_29734, type, 'dephosphorylation of glucose 6 phosphate': $i).
% 29.20/29.01  tff(decl_29735, type, 'dephosphorylation-of-glucose-6-phosphate': $i).
% 29.20/29.01  tff(decl_29736, type, fn_dephosphorylation_of_glucose_6_phosphate_1: $i > $i).
% 29.20/29.01  tff(decl_29737, type, fn_dephosphorylation_of_glucose_6_phosphate_2: $i > $i).
% 29.20/29.01  tff(decl_29738, type, fn_dephosphorylation_of_glucose_6_phosphate_3: $i > $i).
% 29.20/29.01  tff(decl_29739, type, glucose_6_phosphate_1: $i > $o).
% 29.20/29.01  tff(decl_29740, type, depletion_1: $i > $o).
% 29.20/29.01  tff(decl_29741, type, 'Depletion': $i).
% 29.20/29.01  tff(decl_29742, type, 'The exhaustion of a resource.': $i).
% 29.20/29.01  tff(decl_29743, type, depletion: $i).
% 29.20/29.01  tff(decl_29744, type, depolarization_1: $i > $o).
% 29.20/29.01  tff(decl_29745, type, 'Depolarization': $i).
% 29.20/29.01  tff(decl_29746, type, 'An alteration of a cell\\s membrane potential so that the magnitude of the difference in charge between the inside and the outside of the cell is reduced.': $i).
% 29.20/29.01  tff(decl_29747, type, depolarize: $i).
% 29.20/29.01  tff(decl_29748, type, depolarization: $i).
% 29.20/29.01  tff(decl_29749, type, deposit_feeder_1: $i > $o).
% 29.20/29.01  tff(decl_29750, type, 'Deposit-Feeder': $i).
% 29.20/29.01  tff(decl_29751, type, 'A heterotroph that obtains nutrients by consuming detritus (decomposing organic matter).': $i).
% 29.20/29.01  tff(decl_29752, type, detritivore: $i).
% 29.20/29.01  tff(decl_29753, type, 'detritus feeder': $i).
% 29.20/29.01  tff(decl_29754, type, 'detritus-feeder': $i).
% 29.20/29.01  tff(decl_29755, type, saprophage: $i).
% 29.20/29.01  tff(decl_29756, type, 'feeder of deposit': $i).
% 29.20/29.01  tff(decl_29757, type, 'deposit feeder': $i).
% 29.20/29.01  tff(decl_29758, type, 'deposit-feeder': $i).
% 29.20/29.01  tff(decl_29759, type, 'Depth-Constant': $i).
% 29.20/29.01  tff(decl_29760, type, 'constant of depth': $i).
% 29.20/29.01  tff(decl_29761, type, 'depth constant': $i).
% 29.20/29.01  tff(decl_29762, type, 'depth-constant': $i).
% 29.20/29.01  tff(decl_29763, type, depth_scale_1: $i > $o).
% 29.20/29.01  tff(decl_29764, type, 'Depth-Scale': $i).
% 29.20/29.01  tff(decl_29765, type, 'scale of depth': $i).
% 29.20/29.01  tff(decl_29766, type, 'depth scale': $i).
% 29.20/29.01  tff(decl_29767, type, 'depth-scale': $i).
% 29.20/29.01  tff(decl_29768, type, 'Dermal-Tissue': $i).
% 29.20/29.01  tff(decl_29769, type, 'The protective outer coating over the younger parts of a plant.': $i).
% 29.20/29.01  tff(decl_29770, type, 'dermal tissue': $i).
% 29.20/29.01  tff(decl_29771, type, 'dermal-tissue': $i).
% 29.20/29.01  tff(decl_29772, type, plant_specific_tissue_1: $i > $o).
% 29.20/29.01  tff(decl_29773, type, 'Dermal-Tissue-System': $i).
% 29.20/29.01  tff(decl_29774, type, 'The dermal tissue system is the plants outer protective covering.': $i).
% 29.20/29.01  tff(decl_29775, type, 'dermal tissue system': $i).
% 29.20/29.01  tff(decl_29776, type, 'dermal-tissue-system': $i).
% 29.20/29.01  tff(decl_29777, type, tissue_system_1: $i > $o).
% 29.20/29.01  tff(decl_29778, type, 'Dermaptera': $i).
% 29.20/29.01  tff(decl_29779, type, 'An insect order with members known as Earwigs found throughout the Americas, Eurasia and Australia.': $i).
% 29.20/29.01  tff(decl_29780, type, earwigs: $i).
% 29.20/29.01  tff(decl_29781, type, dermaptera: $i).
% 29.20/29.01  tff(decl_29782, type, 'Desert': $i).
% 29.20/29.01  tff(decl_29783, type, 'A large terrestrial region that receives very little precipitation.': $i).
% 29.20/29.01  tff(decl_29784, type, desert: $i).
% 29.20/29.01  tff(decl_29785, type, fn_desert_2: $i > $i).
% 29.20/29.01  tff(decl_29786, type, fn_desert_3: $i > $i).
% 29.20/29.01  tff(decl_29787, type, fn_desert_4: $i > $i).
% 29.20/29.01  tff(decl_29788, type, fn_desert_5: $i > $i).
% 29.20/29.01  tff(decl_29789, type, fn_desert_6: $i > $i).
% 29.20/29.01  tff(decl_29790, type, fn_desert_7: $i > $i).
% 29.20/29.01  tff(decl_29791, type, fn_desert_8: $i > $i).
% 29.20/29.01  tff(decl_29792, type, fn_desert_9: $i > $i).
% 29.20/29.01  tff(decl_29793, type, fn_desert_10: $i > $i).
% 29.20/29.01  tff(decl_29794, type, fn_desert_11: $i > $i).
% 29.20/29.01  tff(decl_29795, type, ground_1: $i > $o).
% 29.20/29.01  tff(decl_29796, type, fn_desert_12: $i > $i).
% 29.20/29.01  tff(decl_29797, type, fn_desert_13: $i > $i).
% 29.20/29.01  tff(decl_29798, type, fn_desert_14: $i > $i).
% 29.20/29.01  tff(decl_29799, type, fn_desert_15: $i > $i).
% 29.20/29.01  tff(decl_29800, type, fn_desert_16: $i > $i).
% 29.20/29.01  tff(decl_29801, type, fn_desert_17: $i > $i).
% 29.20/29.01  tff(decl_29802, type, fn_desert_18: $i > $i).
% 29.20/29.01  tff(decl_29803, type, fn_desert_19: $i > $i).
% 29.20/29.01  tff(decl_29804, type, fn_desert_20: $i > $i).
% 29.20/29.01  tff(decl_29805, type, fn_desert_21: $i > $i).
% 29.20/29.01  tff(decl_29806, type, fn_desert_22: $i > $i).
% 29.20/29.01  tff(decl_29807, type, fn_desert_23: $i > $i).
% 29.20/29.01  tff(decl_29808, type, fn_desert_24: $i > $i).
% 29.20/29.01  tff(decl_29809, type, fn_soil_1: $i > $i).
% 29.20/29.01  tff(decl_29810, type, fn_plant_25: $i > $i).
% 29.20/29.01  tff(decl_29811, type, fn_plant_37: $i > $i).
% 29.20/29.01  tff(decl_29812, type, fn_ecosystem_17: $i > $i).
% 29.20/29.01  tff(decl_29813, type, fn_ecosystem_4: $i > $i).
% 29.20/29.01  tff(decl_29814, type, fn_ecosystem_3: $i > $i).
% 29.20/29.01  tff(decl_29815, type, desert_plant_1: $i > $o).
% 29.20/29.01  tff(decl_29816, type, 'Desert-Plant': $i).
% 29.20/29.01  tff(decl_29817, type, 'Plants which live in desert biomes.': $i).
% 29.20/29.01  tff(decl_29818, type, 'plant of desert': $i).
% 29.20/29.01  tff(decl_29819, type, 'desert plant': $i).
% 29.20/29.01  tff(decl_29820, type, 'desert-plant': $i).
% 29.20/29.01  tff(decl_29821, type, xerophyte_1: $i > $o).
% 29.20/29.01  tff(decl_29822, type, fn_desert_plant_3: $i > $i).
% 29.20/29.01  tff(decl_29823, type, fn_desert_plant_4: $i > $i).
% 29.20/29.01  tff(decl_29824, type, fn_desert_plant_5: $i > $i).
% 29.20/29.01  tff(decl_29825, type, fn_desert_plant_6: $i > $i).
% 29.20/29.01  tff(decl_29826, type, fn_desert_plant_7: $i > $i).
% 29.20/29.01  tff(decl_29827, type, fn_desert_plant_8: $i > $i).
% 29.20/29.01  tff(decl_29828, type, fn_desert_plant_9: $i > $i).
% 29.20/29.01  tff(decl_29829, type, fn_desert_plant_10: $i > $i).
% 29.20/29.01  tff(decl_29830, type, fn_desert_plant_11: $i > $i).
% 29.20/29.01  tff(decl_29831, type, fn_desert_plant_12: $i > $i).
% 29.20/29.01  tff(decl_29832, type, fn_desert_plant_1: $i > $i).
% 29.20/29.01  tff(decl_29833, type, fn_desert_plant_2: $i > $i).
% 29.20/29.01  tff(decl_29834, type, desmosome_1: $i > $o).
% 29.20/29.01  tff(decl_29835, type, 'Desmosome': $i).
% 29.20/29.01  tff(decl_29836, type, 'A type of intercellular junction that occurs in animal cells and functions to bind adjacent cells together.': $i).
% 29.20/29.01  tff(decl_29837, type, desmosome: $i).
% 29.20/29.01  tff(decl_29838, type, intercalated_disc_1: $i > $o).
% 29.20/29.01  tff(decl_29839, type, tight_junction_1: $i > $o).
% 29.20/29.01  tff(decl_29840, type, fn_desmosome_1: $i > $i).
% 29.20/29.01  tff(decl_29841, type, fn_desmosome_2: $i > $i).
% 29.20/29.01  tff(decl_29842, type, fn_desmosome_3: $i > $i).
% 29.20/29.01  tff(decl_29843, type, fn_desmosome_4: $i > $i).
% 29.20/29.01  tff(decl_29844, type, fn_desmosome_5: $i > $i).
% 29.20/29.01  tff(decl_29845, type, fn_desmosome_6: $i > $i).
% 29.20/29.01  tff(decl_29846, type, fn_desmosome_7: $i > $i).
% 29.20/29.01  tff(decl_29847, type, fn_desmosome_8: $i > $i).
% 29.20/29.01  tff(decl_29848, type, 'Destroy': $i).
% 29.20/29.01  tff(decl_29849, type, destruct: $i).
% 29.20/29.01  tff(decl_29850, type, ruin: $i).
% 29.20/29.01  tff(decl_29851, type, demolish: $i).
% 29.20/29.01  tff(decl_29852, type, disappear: $i).
% 29.20/29.01  tff(decl_29853, type, destruction_1: $i > $o).
% 29.20/29.01  tff(decl_29854, type, 'Destruction': $i).
% 29.20/29.01  tff(decl_29855, type, 'Detach': $i).
% 29.20/29.01  tff(decl_29856, type, detach: $i).
% 29.20/29.01  tff(decl_29857, type, 'come off': $i).
% 29.20/29.01  tff(decl_29858, type, come_off: $i).
% 29.20/29.01  tff(decl_29859, type, 'come away': $i).
% 29.20/29.01  tff(decl_29860, type, come_away: $i).
% 29.20/29.01  tff(decl_29861, type, separate: $i).
% 29.20/29.01  tff(decl_29862, type, disjoin: $i).
% 29.20/29.01  tff(decl_29863, type, detailed_instance_1: $i > $o).
% 29.20/29.01  tff(decl_29864, type, 'Detailed-Instance': $i).
% 29.20/29.01  tff(decl_29865, type, 'Instances of this class are things that do not necessarily exist but serve to represent what is within the scope of non-abnormal posssibility.  Instances of this class should be instance of another class which we refer to here as the reference class.  The name of instances of this class should be of the form *Detailed-Instance-of-Foo\\ such that Foo corresponds to its reference class.  For example, to express the fact that It is not unusual for some laptop computers to have a sound card\\ one could reify *Detailed-Instance-of-Laptop-Computer and assert that it has a Sound-Card as a part.  In contrast, see Typical-Instance.': $i).
% 29.20/29.01  tff(decl_29866, type, 'detailed instance': $i).
% 29.20/29.01  tff(decl_29867, type, 'detailed-instance': $i).
% 29.20/29.01  tff(decl_29868, type, 'Detect': $i).
% 29.20/29.01  tff(decl_29869, type, 'An action to discover the true character or discover or determine the existence or presence of an entity.': $i).
% 29.20/29.01  tff(decl_29870, type, detect: $i).
% 29.20/29.01  tff(decl_29871, type, measure_1: $i > $o).
% 29.20/29.01  tff(decl_29872, type, detector_1: $i > $o).
% 29.20/29.01  tff(decl_29873, type, 'Detector': $i).
% 29.20/29.01  tff(decl_29874, type, 'Instrument which determines the flow of electromagnetic energy.': $i).
% 29.20/29.01  tff(decl_29875, type, detector: $i).
% 29.20/29.01  tff(decl_29876, type, deterioration_1: $i > $o).
% 29.20/29.01  tff(decl_29877, type, 'Deterioration': $i).
% 29.20/29.01  tff(decl_29878, type, deteriorate: $i).
% 29.20/29.01  tff(decl_29879, type, devolve: $i).
% 29.20/29.01  tff(decl_29880, type, degenerate: $i).
% 29.20/29.01  tff(decl_29881, type, decay: $i).
% 29.20/29.01  tff(decl_29882, type, disintegrate: $i).
% 29.20/29.01  tff(decl_29883, type, deterioration: $i).
% 29.20/29.01  tff(decl_29884, type, impairment: $i).
% 29.20/29.01  tff(decl_29885, type, disintegration: $i).
% 29.20/29.01  tff(decl_29886, type, distintegrate: $i).
% 29.20/29.01  tff(decl_29887, type, determinate_cleavage_1: $i > $o).
% 29.20/29.01  tff(decl_29888, type, 'Determinate-Cleavage': $i).
% 29.20/29.01  tff(decl_29889, type, 'In animals,  a type of embryonic development in which the developmental fate of each cell is determined very early.': $i).
% 29.20/29.01  tff(decl_29890, type, 'undergo determinate cleavage': $i).
% 29.20/29.01  tff(decl_29891, type, 'determinate cleavage': $i).
% 29.20/29.01  tff(decl_29892, type, 'determinate-cleavage': $i).
% 29.20/29.01  tff(decl_29893, type, holoblastic_cleavage_1: $i > $o).
% 29.20/29.01  tff(decl_29894, type, indeterminate_cleavage_1: $i > $o).
% 29.20/29.01  tff(decl_29895, type, meroblastic_cleavage_1: $i > $o).
% 29.20/29.01  tff(decl_29896, type, spiral_cleavage_1: $i > $o).
% 29.20/29.01  tff(decl_29897, type, 'Determinate-Growth': $i).
% 29.20/29.01  tff(decl_29898, type, 'Growth that stops when a genetically determined size or developmental state has been reached.': $i).
% 29.20/29.01  tff(decl_29899, type, 'determinate growth': $i).
% 29.20/29.01  tff(decl_29900, type, 'determinate-growth': $i).
% 29.20/29.01  tff(decl_29901, type, developmental_process_1: $i > $o).
% 29.20/29.01  tff(decl_29902, type, indeterminate_growth_1: $i > $o).
% 29.20/29.01  tff(decl_29903, type, life_cycle_of_drosophila_1: $i > $o).
% 29.20/29.01  tff(decl_29904, type, determine_order_1: $i > $o).
% 29.20/29.01  tff(decl_29905, type, 'Determine-Order': $i).
% 29.20/29.01  tff(decl_29906, type, 'A process that determines the sequential order of a series of entities.': $i).
% 29.20/29.01  tff(decl_29907, type, maintain: $i).
% 29.20/29.01  tff(decl_29908, type, 'determine order': $i).
% 29.20/29.01  tff(decl_29909, type, 'determine-order': $i).
% 29.20/29.01  tff(decl_29910, type, fn_determine_order_1: $i > $i).
% 29.20/29.01  tff(decl_29911, type, research_1: $i > $o).
% 29.20/29.01  tff(decl_29912, type, fn_determine_order_2: $i > $i).
% 29.20/29.01  tff(decl_29913, type, fn_determine_order_3: $i > $i).
% 29.20/29.01  tff(decl_29914, type, fn_determine_order_4: $i > $i).
% 29.20/29.01  tff(decl_29915, type, fn_determine_order_5: $i > $i).
% 29.20/29.01  tff(decl_29916, type, 'Determined-By': $i).
% 29.20/29.01  tff(decl_29917, type, 'A state is determined by a set of conditions.': $i).
% 29.20/29.01  tff(decl_29918, type, interact: $i).
% 29.20/29.01  tff(decl_29919, type, 'determined by': $i).
% 29.20/29.01  tff(decl_29920, type, 'determined-by': $i).
% 29.20/29.01  tff(decl_29921, type, 'Detoxification': $i).
% 29.20/29.01  tff(decl_29922, type, 'Detoxification is the process in which toxic molecules, such as poisons, drugs and alcohol, are chemically modified and flushed from the body': $i).
% 29.20/29.01  tff(decl_29923, type, detoxify: $i).
% 29.20/29.01  tff(decl_29924, type, detoxification: $i).
% 29.20/29.01  tff(decl_29925, type, fn_detoxification_2: $i > $i).
% 29.20/29.01  tff(decl_29926, type, fn_detoxification_3: $i > $i).
% 29.20/29.01  tff(decl_29927, type, fn_detoxification_4: $i > $i).
% 29.20/29.01  tff(decl_29928, type, fn_detoxification_5: $i > $i).
% 29.20/29.01  tff(decl_29929, type, fn_detoxification_7: $i > $i).
% 29.20/29.01  tff(decl_29930, type, fn_detoxification_8: $i > $i).
% 29.20/29.01  tff(decl_29931, type, fn_detoxification_9: $i > $i).
% 29.20/29.01  tff(decl_29932, type, fn_detoxification_11: $i > $i).
% 29.20/29.01  tff(decl_29933, type, fn_detoxification_12: $i > $i).
% 29.20/29.01  tff(decl_29934, type, fn_detoxification_13: $i > $i).
% 29.20/29.01  tff(decl_29935, type, fn_detoxification_14: $i > $i).
% 29.20/29.01  tff(decl_29936, type, fn_detoxification_15: $i > $i).
% 29.20/29.01  tff(decl_29937, type, fn_detoxification_16: $i > $i).
% 29.20/29.01  tff(decl_29938, type, fn_detoxification_6: $i > $i).
% 29.20/29.01  tff(decl_29939, type, fn_detoxification_10: $i > $i).
% 29.20/29.01  tff(decl_29940, type, 'Detritivore': $i).
% 29.20/29.01  tff(decl_29941, type, 'A consumer that obtains energy and nutrients from nonliving organic sources such as carcasses, plant debris, and fecal matter.': $i).
% 29.20/29.01  tff(decl_29942, type, fn_detritivore_1: $i > $i).
% 29.20/29.01  tff(decl_29943, type, fn_detritivore_2: $i > $i).
% 29.20/29.01  tff(decl_29944, type, fn_detritivore_3: $i > $i).
% 29.20/29.01  tff(decl_29945, type, fn_detritivore_4: $i > $i).
% 29.20/29.01  tff(decl_29946, type, fn_detritivore_5: $i > $i).
% 29.20/29.01  tff(decl_29947, type, fn_detritivore_6: $i > $i).
% 29.20/29.01  tff(decl_29948, type, fn_detritivore_7: $i > $i).
% 29.20/29.01  tff(decl_29949, type, fn_detritivore_8: $i > $i).
% 29.20/29.01  tff(decl_29950, type, fn_detritivore_9: $i > $i).
% 29.20/29.01  tff(decl_29951, type, fn_detritivore_11: $i > $i).
% 29.20/29.01  tff(decl_29952, type, fn_detritivore_15: $i > $i).
% 29.20/29.01  tff(decl_29953, type, fn_detritivore_17: $i > $i).
% 29.20/29.01  tff(decl_29954, type, fn_detritivore_18: $i > $i).
% 29.20/29.01  tff(decl_29955, type, fn_detritivore_19: $i > $i).
% 29.20/29.01  tff(decl_29956, type, 'Detritus': $i).
% 29.20/29.01  tff(decl_29957, type, 'Organic matter that is non-living.': $i).
% 29.20/29.01  tff(decl_29958, type, 'organic litter': $i).
% 29.20/29.01  tff(decl_29959, type, detritus: $i).
% 29.20/29.01  tff(decl_29960, type, 'Deuteromycete': $i).
% 29.20/29.01  tff(decl_29961, type, 'An artificial group of fungi with no known sexual stage.': $i).
% 29.20/29.01  tff(decl_29962, type, deuteromycete: $i).
% 29.20/29.01  tff(decl_29963, type, deuterostome_development_1: $i > $o).
% 29.20/29.01  tff(decl_29964, type, 'Deuterostome-Development': $i).
% 29.20/29.01  tff(decl_29965, type, 'In animals, a developmental pathway in which the blastopore becomes the anus, with the mouth breaking through on the other end of the embryo. Deuterostomes often have radial cleavage and develop their coelom from mesodermal outpocketings of the archenteron.': $i).
% 29.20/29.01  tff(decl_29966, type, 'deuterostome development': $i).
% 29.20/29.01  tff(decl_29967, type, 'deuterostome-development': $i).
% 29.20/29.01  tff(decl_29968, type, drosophila_development_1: $i > $o).
% 29.20/29.01  tff(decl_29969, type, deuterostomia_1: $i > $o).
% 29.20/29.01  tff(decl_29970, type, 'Deuterostomia': $i).
% 29.20/29.01  tff(decl_29971, type, 'Subphylum of animals characterized by the presence of the deuterostome pattern of development, in which the first body opening becomes the anus.': $i).
% 29.20/29.01  tff(decl_29972, type, deuterostomia: $i).
% 29.20/29.01  tff(decl_29973, type, fn_deuterostomia_1: $i > $i).
% 29.20/29.01  tff(decl_29974, type, fn_deuterostomia_2: $i > $i).
% 29.20/29.01  tff(decl_29975, type, fn_deuterostomia_3: $i > $i).
% 29.20/29.01  tff(decl_29976, type, fn_deuterostomia_4: $i > $i).
% 29.20/29.01  tff(decl_29977, type, fn_deuterostomia_5: $i > $i).
% 29.20/29.01  tff(decl_29978, type, fn_deuterostomia_6: $i > $i).
% 29.20/29.01  tff(decl_29979, type, fn_deuterostomia_7: $i > $i).
% 29.20/29.01  tff(decl_29980, type, fn_deuterostomia_8: $i > $i).
% 29.20/29.01  tff(decl_29981, type, fn_deuterostomia_9: $i > $i).
% 29.20/29.01  tff(decl_29982, type, fn_deuterostomia_10: $i > $i).
% 29.20/29.01  tff(decl_29983, type, 'Development': $i).
% 29.20/29.01  tff(decl_29984, type, development: $i).
% 29.20/29.01  tff(decl_29985, type, improvement: $i).
% 29.20/29.01  tff(decl_29986, type, development_in_eukaryote_1: $i > $o).
% 29.20/29.01  tff(decl_29987, type, 'Development-In-Eukaryote': $i).
% 29.20/29.01  tff(decl_29988, type, 'Eukaryote development includes the processes that lead eventually to the formation of a new eukaryote starting from cells derived from one or more parent individuals.': $i).
% 29.20/29.01  tff(decl_29989, type, 'development in eukaryote': $i).
% 29.20/29.01  tff(decl_29990, type, 'development-in-eukaryote': $i).
% 29.20/29.01  tff(decl_29991, type, fn_development_in_eukaryote_1: $i > $i).
% 29.20/29.01  tff(decl_29992, type, fn_development_in_eukaryote_2: $i > $i).
% 29.20/29.01  tff(decl_29993, type, fn_development_in_eukaryote_3: $i > $i).
% 29.20/29.01  tff(decl_29994, type, 'Development-Related-Intercellular-Process': $i).
% 29.20/29.01  tff(decl_29995, type, 'Intercellular process related to the development of an organism.': $i).
% 29.20/29.01  tff(decl_29996, type, 'undergo development related intercellular process': $i).
% 29.20/29.01  tff(decl_29997, type, 'development related intercellular process': $i).
% 29.20/29.01  tff(decl_29998, type, 'development-related-intercellular-process': $i).
% 29.20/29.01  tff(decl_29999, type, development_related_mutation_1: $i > $o).
% 29.20/29.01  tff(decl_30000, type, 'Development-Related-Mutation': $i).
% 29.20/29.01  tff(decl_30001, type, 'Mutations in the genome that affect development of an organism.': $i).
% 29.20/29.01  tff(decl_30002, type, 'development related mutation': $i).
% 29.20/29.01  tff(decl_30003, type, 'development-related-mutation': $i).
% 29.20/29.01  tff(decl_30004, type, developmental_biology_1: $i > $o).
% 29.20/29.01  tff(decl_30005, type, 'Developmental-Biology': $i).
% 29.20/29.01  tff(decl_30006, type, 'Developmental biology is the study of the process by which organisms grow and develop. Modern developmental biology studies the genetic control of cell growth, differentiation and morphogenesis, which is the process that gives rise to tissues, organs and anatomy.': $i).
% 29.20/29.01  tff(decl_30007, type, 'study developmental biology': $i).
% 29.20/29.01  tff(decl_30008, type, 'developmental biology': $i).
% 29.20/29.01  tff(decl_30009, type, 'developmental-biology': $i).
% 29.20/29.01  tff(decl_30010, type, fn_developmental_biology_1: $i > $i).
% 29.20/29.01  tff(decl_30011, type, fn_developmental_biology_2: $i > $i).
% 29.20/29.01  tff(decl_30012, type, developmental_gene_1: $i > $o).
% 29.20/29.01  tff(decl_30013, type, 'Developmental-Gene': $i).
% 29.20/29.01  tff(decl_30014, type, 'A gene playing role in organismal development.': $i).
% 29.20/29.01  tff(decl_30015, type, 'developmental gene': $i).
% 29.20/29.01  tff(decl_30016, type, 'developmental-gene': $i).
% 29.20/29.01  tff(decl_30017, type, developmental_genetics_1: $i > $o).
% 29.20/29.01  tff(decl_30018, type, 'Developmental-Genetics': $i).
% 29.20/29.01  tff(decl_30019, type, 'Developmental genetics studies the effect that genes have in a phenotype, given normal or abnormal epigenetic parameters.': $i).
% 29.20/29.01  tff(decl_30020, type, 'developmental genetics': $i).
% 29.20/29.01  tff(decl_30021, type, 'developmental-genetic': $i).
% 29.20/29.01  tff(decl_30022, type, genetics_1: $i > $o).
% 29.20/29.01  tff(decl_30023, type, mendelian_genetics_1: $i > $o).
% 29.20/29.01  tff(decl_30024, type, non_mendelian_genetics_1: $i > $o).
% 29.20/29.01  tff(decl_30025, type, 'Developmental-Process': $i).
% 29.20/29.01  tff(decl_30026, type, 'A process related to the development of organisms.': $i).
% 29.20/29.01  tff(decl_30027, type, 'developmental process': $i).
% 29.20/29.01  tff(decl_30028, type, 'developmental-process': $i).
% 29.20/29.01  tff(decl_30029, type, 'Developmental-Space': $i).
% 29.20/29.01  tff(decl_30030, type, 'Region iin an organism which is related to developmental processes.': $i).
% 29.20/29.01  tff(decl_30031, type, 'developmental space': $i).
% 29.20/29.01  tff(decl_30032, type, 'developmental-space': $i).
% 29.20/29.01  tff(decl_30033, type, 'Developmental-Stage': $i).
% 29.20/29.01  tff(decl_30034, type, 'A particular stage in the development of an organism.': $i).
% 29.20/29.01  tff(decl_30035, type, 'undergo the developmental stage': $i).
% 29.20/29.01  tff(decl_30036, type, 'developmental stage': $i).
% 29.20/29.01  tff(decl_30037, type, 'developmental-stage': $i).
% 29.20/29.01  tff(decl_30038, type, 'Device': $i).
% 29.20/29.01  tff(decl_30039, type, 'an artifact with an instrumental purpose': $i).
% 29.20/29.01  tff(decl_30040, type, device: $i).
% 29.20/29.01  tff(decl_30041, type, instrumentality: $i).
% 29.20/29.01  tff(decl_30042, type, instrumentation: $i).
% 29.20/29.01  tff(decl_30043, type, fn_device_1: $i > $i).
% 29.20/29.01  tff(decl_30044, type, 'Diabetes-Mellitus': $i).
% 29.20/29.01  tff(decl_30045, type, 'A group of diseases in which a patient has abnormally high levels of blood sugar. It can be due to insufficient production of insulin by the pancreas, or to cells\\ failure to respond to the insulin that is produced.': $i).
% 29.20/29.01  tff(decl_30046, type, 'diabetes mellitus': $i).
% 29.20/29.01  tff(decl_30047, type, 'diabetes-mellitus': $i).
% 29.20/29.01  tff(decl_30048, type, 'Diacylglycerol': $i).
% 29.20/29.01  tff(decl_30049, type, 'A second messenger produced by the cleavage of a certain kind of phospholipid in the plasma membrane.': $i).
% 29.20/29.01  tff(decl_30050, type, dag: $i).
% 29.20/29.01  tff(decl_30051, type, 'diacyl glycerol': $i).
% 29.20/29.01  tff(decl_30052, type, diacylglycerol: $i).
% 29.20/29.01  tff(decl_30053, type, diagnosis_1: $i > $o).
% 29.20/29.01  tff(decl_30054, type, 'Diagnosis': $i).
% 29.20/29.01  tff(decl_30055, type, 'The identification of the nature and cause of a disease or medical condition.': $i).
% 29.20/29.01  tff(decl_30056, type, diagnose: $i).
% 29.20/29.01  tff(decl_30057, type, diagnosis: $i).
% 29.20/29.01  tff(decl_30058, type, medicine_1: $i > $o).
% 29.20/29.01  tff(decl_30059, type, fn_diagnosis_1: $i > $i).
% 29.20/29.01  tff(decl_30060, type, fn_diagnosis_2: $i > $i).
% 29.20/29.01  tff(decl_30061, type, renal_disease_1: $i > $o).
% 29.20/29.01  tff(decl_30062, type, diagnosis_of_renal_disease_1: $i > $o).
% 29.20/29.01  tff(decl_30063, type, fn_diagnosis_of_renal_disease_6: $i > $i).
% 29.20/29.01  tff(decl_30064, type, 'Diagnosis-Of-Renal-Disease': $i).
% 29.20/29.01  tff(decl_30065, type, 'A medical condition in which the kidneys fail to adequately filter toxins and waste products from the blood. The two forms are acute kidney injury and chronic kidney disease.': $i).
% 29.20/29.01  tff(decl_30066, type, 'diagnosis of renal failure': $i).
% 29.20/29.01  tff(decl_30067, type, 'diagnosis of kidney failure': $i).
% 29.20/29.01  tff(decl_30068, type, 'renal insufficiency': $i).
% 29.20/29.01  tff(decl_30069, type, 'diagnosis of renal disease': $i).
% 29.20/29.01  tff(decl_30070, type, 'diagnosis-of-renal-disease': $i).
% 29.20/29.01  tff(decl_30071, type, fn_diagnosis_of_renal_disease_2: $i > $i).
% 29.20/29.01  tff(decl_30072, type, fn_diagnosis_of_renal_disease_3: $i > $i).
% 29.20/29.01  tff(decl_30073, type, fn_diagnosis_of_renal_disease_4: $i > $i).
% 29.20/29.01  tff(decl_30074, type, fn_diagnosis_of_renal_disease_5: $i > $i).
% 29.20/29.01  tff(decl_30075, type, fn_diagnosis_of_renal_disease_7: $i > $i).
% 29.20/29.01  tff(decl_30076, type, excretion_1: $i > $o).
% 29.20/29.01  tff(decl_30077, type, fn_diagnosis_of_renal_disease_8: $i > $i).
% 29.20/29.01  tff(decl_30078, type, radioactive_tracer_1: $i > $o).
% 29.20/29.01  tff(decl_30079, type, fn_diagnosis_of_renal_disease_9: $i > $i).
% 29.20/29.01  tff(decl_30080, type, fn_excretion_3: $i > $i).
% 29.20/29.01  tff(decl_30081, type, fn_excretion_5: $i > $i).
% 29.20/29.01  tff(decl_30082, type, diagnostic_procedure_1: $i > $o).
% 29.20/29.01  tff(decl_30083, type, 'Diagnostic-Procedure': $i).
% 29.20/29.01  tff(decl_30084, type, 'Medical procedure which provides information to assist in the making of a diagnosis.': $i).
% 29.20/29.01  tff(decl_30085, type, 'diagnostic procedure': $i).
% 29.20/29.01  tff(decl_30086, type, 'diagnostic-procedure': $i).
% 29.20/29.01  tff(decl_30087, type, diameter_constant_1: $i > $o).
% 29.20/29.01  tff(decl_30088, type, 'Diameter-Constant': $i).
% 29.20/29.01  tff(decl_30089, type, 'constant of diameter': $i).
% 29.20/29.01  tff(decl_30090, type, 'diameter constant': $i).
% 29.20/29.01  tff(decl_30091, type, 'diameter-constant': $i).
% 29.20/29.01  tff(decl_30092, type, diameter_scale_1: $i > $o).
% 29.20/29.01  tff(decl_30093, type, 'Diameter-Scale': $i).
% 29.20/29.01  tff(decl_30094, type, 'scale of diameter': $i).
% 29.20/29.01  tff(decl_30095, type, 'diameter scale': $i).
% 29.20/29.01  tff(decl_30096, type, 'diameter-scale': $i).
% 29.20/29.01  tff(decl_30097, type, 'Diaphragm-Birth-Control': $i).
% 29.20/29.01  tff(decl_30098, type, 'A soft silicone or latex dome that is inserted into the upper vagina before sexual intercourse. The diaphragm forms a seal against the upper walls of the vagina and acts as a barrier to conception.': $i).
% 29.20/29.01  tff(decl_30099, type, 'diaphragm birth control': $i).
% 29.20/29.01  tff(decl_30100, type, 'diaphragm-birth-control': $i).
% 29.20/29.01  tff(decl_30101, type, diaphragm_muscle_tissue_1: $i > $o).
% 29.20/29.01  tff(decl_30102, type, 'Diaphragm-Muscle-Tissue': $i).
% 29.20/29.01  tff(decl_30103, type, 'A sheet of skeletal muscle that separates the thoracic and abdominal cavities in mammals. Contraction of the diaphragm increases the volume of the lungs and draws air into the lungs for breathing.': $i).
% 29.20/29.01  tff(decl_30104, type, diaphragm: $i).
% 29.20/29.01  tff(decl_30105, type, 'diaphragm muscle tissue': $i).
% 29.20/29.01  tff(decl_30106, type, 'diaphragm-muscle-tissue': $i).
% 29.20/29.01  tff(decl_30107, type, diapsid_1: $i > $o).
% 29.20/29.01  tff(decl_30108, type, 'Diapsid': $i).
% 29.20/29.01  tff(decl_30109, type, 'Member of a clade of amniote animals characterized by having two temporal openings on each side of the skull. Examples include the lepidosaurs and archosaurs.': $i).
% 29.20/29.01  tff(decl_30110, type, diapsid: $i).
% 29.20/29.01  tff(decl_30111, type, synapsid_1: $i > $o).
% 29.20/29.01  tff(decl_30112, type, 'Diastole': $i).
% 29.20/29.01  tff(decl_30113, type, 'Point in the cardiac cycle in which the heart relaxes and refills with blood.': $i).
% 29.20/29.01  tff(decl_30114, type, diastole: $i).
% 29.20/29.01  tff(decl_30115, type, 'Diatom': $i).
% 29.20/29.01  tff(decl_30116, type, 'Diatoms are a major group of algae, and are one of the most common types of phytoplankton.': $i).
% 29.20/29.01  tff(decl_30117, type, diatom: $i).
% 29.20/29.01  tff(decl_30118, type, fn_diatom_1: $i > $i).
% 29.20/29.01  tff(decl_30119, type, fn_diatom_3: $i > $i).
% 29.20/29.01  tff(decl_30120, type, fn_diatom_4: $i > $i).
% 29.20/29.01  tff(decl_30121, type, fn_diatom_5: $i > $i).
% 29.20/29.01  tff(decl_30122, type, fn_diatom_6: $i > $i).
% 29.20/29.01  tff(decl_30123, type, fn_diatom_7: $i > $i).
% 29.20/29.01  tff(decl_30124, type, fn_diatom_8: $i > $i).
% 29.20/29.01  tff(decl_30125, type, fn_diatom_9: $i > $i).
% 29.20/29.01  tff(decl_30126, type, fn_diatom_10: $i > $i).
% 29.20/29.01  tff(decl_30127, type, fn_diatom_11: $i > $i).
% 29.20/29.01  tff(decl_30128, type, fn_diatom_12: $i > $i).
% 29.20/29.01  tff(decl_30129, type, fn_diatom_13: $i > $i).
% 29.20/29.01  tff(decl_30130, type, fn_diatom_18: $i > $i).
% 29.20/29.01  tff(decl_30131, type, fn_diatom_19: $i > $i).
% 29.20/29.01  tff(decl_30132, type, fn_diatom_20: $i > $i).
% 29.20/29.01  tff(decl_30133, type, fn_diatom_21: $i > $i).
% 29.20/29.01  tff(decl_30134, type, fn_diatom_22: $i > $i).
% 29.20/29.01  tff(decl_30135, type, fn_diatom_23: $i > $i).
% 29.20/29.01  tff(decl_30136, type, fn_diatom_24: $i > $i).
% 29.20/29.01  tff(decl_30137, type, fn_diatom_25: $i > $i).
% 29.20/29.01  tff(decl_30138, type, fn_diatom_26: $i > $i).
% 29.20/29.01  tff(decl_30139, type, fn_diatom_27: $i > $i).
% 29.20/29.01  tff(decl_30140, type, fn_diatom_28: $i > $i).
% 29.20/29.01  tff(decl_30141, type, fn_diatom_29: $i > $i).
% 29.20/29.01  tff(decl_30142, type, fn_diatom_30: $i > $i).
% 29.20/29.01  tff(decl_30143, type, fn_diatom_31: $i > $i).
% 29.20/29.01  tff(decl_30144, type, fn_diatom_32: $i > $i).
% 29.20/29.01  tff(decl_30145, type, fn_diatom_33: $i > $i).
% 29.20/29.01  tff(decl_30146, type, fn_diatom_34: $i > $i).
% 29.20/29.01  tff(decl_30147, type, fn_diatom_35: $i > $i).
% 29.20/29.01  tff(decl_30148, type, fn_diatom_36: $i > $i).
% 29.20/29.01  tff(decl_30149, type, fn_diatom_37: $i > $i).
% 29.20/29.01  tff(decl_30150, type, fn_diatom_38: $i > $i).
% 29.20/29.01  tff(decl_30151, type, fn_diatom_39: $i > $i).
% 29.20/29.01  tff(decl_30152, type, fn_diatom_40: $i > $i).
% 29.20/29.01  tff(decl_30153, type, fn_diatom_42: $i > $i).
% 29.20/29.01  tff(decl_30154, type, fn_diatom_43: $i > $i).
% 29.20/29.01  tff(decl_30155, type, fn_diatom_45: $i > $i).
% 29.20/29.01  tff(decl_30156, type, "30.0e0": $i).
% 29.20/29.01  tff(decl_30157, type, fn_diatom_17: $i > $i).
% 29.20/29.01  tff(decl_30158, type, fn_diatom_16: $i > $i).
% 29.20/29.01  tff(decl_30159, type, fn_protist_cell_5: $i > $i).
% 29.20/29.01  tff(decl_30160, type, fn_protist_cell_7: $i > $i).
% 29.20/29.01  tff(decl_30161, type, fn_protist_cell_3: $i > $i).
% 29.20/29.01  tff(decl_30162, type, fn_protist_cell_6: $i > $i).
% 29.20/29.01  tff(decl_30163, type, fn_protist_cell_2: $i > $i).
% 29.20/29.01  tff(decl_30164, type, fn_protist_cell_4: $i > $i).
% 29.20/29.01  tff(decl_30165, type, fn_protist_cell_8: $i > $i).
% 29.20/29.01  tff(decl_30166, type, fn_protist_cell_20: $i > $i).
% 29.20/29.01  tff(decl_30167, type, fn_diatom_14: $i > $i).
% 29.20/29.01  tff(decl_30168, type, fn_diatom_15: $i > $i).
% 29.20/29.01  tff(decl_30169, type, 'Dicot': $i).
% 29.20/29.01  tff(decl_30170, type, 'A descriptive term used to refer to angiosperms that have two cotyledons, or embryonic seed leaves.': $i).
% 29.20/29.01  tff(decl_30171, type, dicot: $i).
% 29.20/29.01  tff(decl_30172, type, diencephalon_1: $i > $o).
% 29.20/29.01  tff(decl_30173, type, 'Diencephalon': $i).
% 29.20/29.01  tff(decl_30174, type, 'Region of the brain located in the central portion which houses the thalamus and hypothalamus.': $i).
% 29.20/29.01  tff(decl_30175, type, diencephalon: $i).
% 29.20/29.01  tff(decl_30176, type, 'Diet': $i).
% 29.20/29.01  tff(decl_30177, type, 'The group of foods which make up the source of nutrition for an animal.': $i).
% 29.20/29.01  tff(decl_30178, type, diet: $i).
% 29.20/29.01  tff(decl_30179, type, differential_gene_expression_1: $i > $o).
% 29.20/29.01  tff(decl_30180, type, 'Differential-Gene-Expression': $i).
% 29.20/29.01  tff(decl_30181, type, 'Differential gene expression refers to the selective expression of specific genes across cell types in a multicellular organism.': $i).
% 29.20/29.01  tff(decl_30182, type, 'differential gene expression': $i).
% 29.20/29.01  tff(decl_30183, type, 'differential-gene-expression': $i).
% 29.20/29.01  tff(decl_30184, type, fn_differential_gene_expression_3: $i > $i).
% 29.20/29.01  tff(decl_30185, type, fn_differential_gene_expression_4: $i > $i).
% 29.20/29.01  tff(decl_30186, type, fn_differential_gene_expression_5: $i > $i).
% 29.20/29.01  tff(decl_30187, type, fn_differential_gene_expression_6: $i > $i).
% 29.20/29.01  tff(decl_30188, type, fn_differential_gene_expression_7: $i > $i).
% 29.20/29.01  tff(decl_30189, type, fn_differential_gene_expression_8: $i > $i).
% 29.20/29.01  tff(decl_30190, type, fn_differential_gene_expression_9: $i > $i).
% 29.20/29.01  tff(decl_30191, type, fn_differential_gene_expression_10: $i > $i).
% 29.20/29.01  tff(decl_30192, type, fn_differential_gene_expression_11: $i > $i).
% 29.20/29.01  tff(decl_30193, type, fn_differential_gene_expression_12: $i > $i).
% 29.20/29.01  tff(decl_30194, type, 'Gene expression 1': $i).
% 29.20/29.01  tff(decl_30195, type, gene_expression_0: $i).
% 29.20/29.01  tff(decl_30196, type, gene_activation_0: $i).
% 29.20/29.01  tff(decl_30197, type, 'Gene expression 2': $i).
% 29.20/29.01  tff(decl_30198, type, 'Differentiated-Cell': $i).
% 29.20/29.01  tff(decl_30199, type, 'A differentiated cell is a cell in a multicellular organism that is specialized in its functions, which it may perform in a certain organ or tissue.': $i).
% 29.20/29.01  tff(decl_30200, type, 'differentiated cell': $i).
% 29.20/29.01  tff(decl_30201, type, 'differentiated-cell': $i).
% 29.20/29.01  tff(decl_30202, type, fn_differentiated_cell_1: $i > $i).
% 29.20/29.01  tff(decl_30203, type, fn_differentiated_cell_2: $i > $i).
% 29.20/29.01  tff(decl_30204, type, fn_differentiated_cell_3: $i > $i).
% 29.20/29.01  tff(decl_30205, type, fn_differentiated_cell_4: $i > $i).
% 29.20/29.01  tff(decl_30206, type, fn_differentiated_cell_5: $i > $i).
% 29.20/29.01  tff(decl_30207, type, fn_differentiated_cell_6: $i > $i).
% 29.20/29.01  tff(decl_30208, type, fn_differentiated_cell_7: $i > $i).
% 29.20/29.01  tff(decl_30209, type, fn_differentiated_cell_8: $i > $i).
% 29.20/29.01  tff(decl_30210, type, fn_differentiated_cell_9: $i > $i).
% 29.20/29.01  tff(decl_30211, type, fn_differentiated_cell_10: $i > $i).
% 29.20/29.01  tff(decl_30212, type, fn_differentiated_cell_11: $i > $i).
% 29.20/29.01  tff(decl_30213, type, fn_differentiated_cell_12: $i > $i).
% 29.20/29.01  tff(decl_30214, type, fn_differentiated_cell_13: $i > $i).
% 29.20/29.01  tff(decl_30215, type, fn_differentiated_cell_14: $i > $i).
% 29.20/29.01  tff(decl_30216, type, fn_differentiated_cell_15: $i > $i).
% 29.20/29.01  tff(decl_30217, type, fn_differentiated_cell_16: $i > $i).
% 29.20/29.01  tff(decl_30218, type, fn_differentiated_cell_17: $i > $i).
% 29.20/29.01  tff(decl_30219, type, fn_differentiated_cell_18: $i > $i).
% 29.20/29.01  tff(decl_30220, type, fn_differentiated_cell_19: $i > $i).
% 29.20/29.01  tff(decl_30221, type, fn_differentiated_cell_20: $i > $i).
% 29.20/29.01  tff(decl_30222, type, fn_differentiated_cell_21: $i > $i).
% 29.20/29.01  tff(decl_30223, type, fn_differentiated_cell_22: $i > $i).
% 29.20/29.01  tff(decl_30224, type, fn_differentiated_cell_23: $i > $i).
% 29.20/29.01  tff(decl_30225, type, fn_differentiated_cell_24: $i > $i).
% 29.20/29.01  tff(decl_30226, type, fn_differentiated_cell_25: $i > $i).
% 29.20/29.01  tff(decl_30227, type, fn_differentiated_cell_26: $i > $i).
% 29.20/29.01  tff(decl_30228, type, fn_differentiated_cell_27: $i > $i).
% 29.20/29.01  tff(decl_30229, type, fn_differentiated_cell_28: $i > $i).
% 29.20/29.01  tff(decl_30230, type, fn_differentiated_cell_29: $i > $i).
% 29.20/29.01  tff(decl_30231, type, fn_differentiated_cell_30: $i > $i).
% 29.20/29.01  tff(decl_30232, type, fn_differentiated_cell_31: $i > $i).
% 29.20/29.01  tff(decl_30233, type, fn_differentiated_cell_32: $i > $i).
% 29.20/29.01  tff(decl_30234, type, fn_differentiated_cell_33: $i > $i).
% 29.20/29.01  tff(decl_30235, type, fn_differentiated_cell_34: $i > $i).
% 29.20/29.01  tff(decl_30236, type, fn_differentiated_cell_35: $i > $i).
% 29.20/29.01  tff(decl_30237, type, fn_differentiated_cell_36: $i > $i).
% 29.20/29.01  tff(decl_30238, type, fn_differentiated_cell_37: $i > $i).
% 29.20/29.01  tff(decl_30239, type, fn_differentiated_cell_40: $i > $i).
% 29.20/29.01  tff(decl_30240, type, fn_differentiated_cell_41: $i > $i).
% 29.20/29.01  tff(decl_30241, type, fn_differentiated_cell_42: $i > $i).
% 29.20/29.01  tff(decl_30242, type, fn_differentiated_cell_43: $i > $i).
% 29.20/29.01  tff(decl_30243, type, fn_differentiated_cell_44: $i > $i).
% 29.20/29.01  tff(decl_30244, type, fn_differentiated_cell_45: $i > $i).
% 29.20/29.01  tff(decl_30245, type, fn_eukaryotic_cell_43: $i > $i).
% 29.20/29.01  tff(decl_30246, type, fn_differentiated_cell_39: $i > $i).
% 29.20/29.01  tff(decl_30247, type, fn_differentiated_cell_38: $i > $i).
% 29.20/29.01  tff(decl_30248, type, differentiated_cell_nuclear_transplantation_1: $i > $o).
% 29.20/29.01  tff(decl_30249, type, 'Differentiated-Cell-Nuclear-Transplantation': $i).
% 29.20/29.01  tff(decl_30250, type, 'The technique of placing a nucleus from differentiated cell into an enucleated cell.': $i).
% 29.20/29.01  tff(decl_30251, type, transplant: $i).
% 29.20/29.01  tff(decl_30252, type, 'differentiated cell nuclear transplantation': $i).
% 29.20/29.01  tff(decl_30253, type, 'differentiated-cell-nuclear-transplantation': $i).
% 29.20/29.01  tff(decl_30254, type, fn_differentiated_cell_nuclear_transplantation_1: $i > $i).
% 29.20/29.01  tff(decl_30255, type, fn_differentiated_cell_nuclear_transplantation_2: $i > $i).
% 29.20/29.01  tff(decl_30256, type, fn_differentiated_cell_nuclear_transplantation_3: $i > $i).
% 29.20/29.01  tff(decl_30257, type, enucleated_cell_1: $i > $o).
% 29.20/29.01  tff(decl_30258, type, fn_nuclear_transplantation_2: $i > $i).
% 29.20/29.01  tff(decl_30259, type, fn_nuclear_transplantation_1: $i > $i).
% 29.20/29.01  tff(decl_30260, type, fn_nuclear_transplantation_3: $i > $i).
% 29.20/29.01  tff(decl_30261, type, 'Differentiated-Embryonic-Cell': $i).
% 29.20/29.01  tff(decl_30262, type, 'A differentiated cell of the embryo.': $i).
% 29.20/29.01  tff(decl_30263, type, 'differentiated embryonic cell': $i).
% 29.20/29.01  tff(decl_30264, type, 'differentiated-embryonic-cell': $i).
% 29.20/29.01  tff(decl_30265, type, embryonic_cell_1: $i > $o).
% 29.20/29.01  tff(decl_30266, type, mammary_cell_1: $i > $o).
% 29.20/29.01  tff(decl_30267, type, myoblast_1: $i > $o).
% 29.20/29.01  tff(decl_30268, type, diffusion_1: $i > $o).
% 29.20/29.01  tff(decl_30269, type, 'Diffusion': $i).
% 29.20/29.01  tff(decl_30270, type, 'Diffusion describes the spread of particles through random motion from regions of higher concentration to regions of lower concentration. Diffusion happens as a result of thermal motion.': $i).
% 29.20/29.01  tff(decl_30271, type, 'downhill diffusion': $i).
% 29.20/29.01  tff(decl_30272, type, 'downhill-diffusion': $i).
% 29.20/29.01  tff(decl_30273, type, diffuse: $i).
% 29.20/29.01  tff(decl_30274, type, diffusion: $i).
% 29.20/29.01  tff(decl_30275, type, fn_diffusion_1: $i > $i).
% 29.20/29.01  tff(decl_30276, type, fn_diffusion_2: $i > $i).
% 29.20/29.01  tff(decl_30277, type, fn_diffusion_3: $i > $i).
% 29.20/29.01  tff(decl_30278, type, fn_diffusion_4: $i > $i).
% 29.20/29.01  tff(decl_30279, type, fn_diffusion_5: $i > $i).
% 29.20/29.01  tff(decl_30280, type, fn_diffusion_6: $i > $i).
% 29.20/29.01  tff(decl_30281, type, fn_diffusion_7: $i > $i).
% 29.20/29.01  tff(decl_30282, type, 'Diffusion-Of-Anion-Across-Plasma-Membrane': $i).
% 29.20/29.01  tff(decl_30283, type, 'The condition inside of the cell is negative compared to the outside, the membrane potential favors the passive transport of cations into the cell and anions out of the cell.': $i).
% 29.20/29.01  tff(decl_30284, type, 'diffusion of anion across plasma membrane': $i).
% 29.20/29.01  tff(decl_30285, type, 'diffusion-of-anion-across-plasma-membrane': $i).
% 29.20/29.01  tff(decl_30286, type, diffusion_of_cation_across_plasma_membrane_1: $i > $o).
% 29.20/29.01  tff(decl_30287, type, fn_diffusion_of_anion_across_plasma_membrane_1: $i > $i).
% 29.20/29.01  tff(decl_30288, type, fn_diffusion_of_anion_across_plasma_membrane_2: $i > $i).
% 29.20/29.01  tff(decl_30289, type, fn_diffusion_of_anion_across_plasma_membrane_7: $i > $i).
% 29.20/29.01  tff(decl_30290, type, fn_diffusion_of_anion_across_plasma_membrane_9: $i > $i).
% 29.20/29.01  tff(decl_30291, type, fn_diffusion_of_anion_across_plasma_membrane_10: $i > $i).
% 29.20/29.01  tff(decl_30292, type, fn_diffusion_of_anion_across_plasma_membrane_11: $i > $i).
% 29.20/29.01  tff(decl_30293, type, fn_diffusion_of_anion_across_plasma_membrane_12: $i > $i).
% 29.20/29.01  tff(decl_30294, type, fn_diffusion_of_anion_across_plasma_membrane_13: $i > $i).
% 29.20/29.01  tff(decl_30295, type, fn_diffusion_of_anion_across_plasma_membrane_14: $i > $i).
% 29.20/29.01  tff(decl_30296, type, fn_diffusion_of_anion_across_plasma_membrane_15: $i > $i).
% 29.20/29.01  tff(decl_30297, type, fn_diffusion_of_anion_across_plasma_membrane_16: $i > $i).
% 29.20/29.01  tff(decl_30298, type, fn_diffusion_of_anion_across_plasma_membrane_17: $i > $i).
% 29.20/29.01  tff(decl_30299, type, fn_diffusion_of_anion_across_plasma_membrane_18: $i > $i).
% 29.20/29.01  tff(decl_30300, type, fn_diffusion_of_anion_across_plasma_membrane_19: $i > $i).
% 29.20/29.01  tff(decl_30301, type, fn_diffusion_of_anion_across_plasma_membrane_21: $i > $i).
% 29.20/29.01  tff(decl_30302, type, fn_diffusion_of_anion_across_plasma_membrane_22: $i > $i).
% 29.20/29.01  tff(decl_30303, type, fn_diffusion_of_anion_across_plasma_membrane_23: $i > $i).
% 29.20/29.01  tff(decl_30304, type, fn_diffusion_of_anion_across_plasma_membrane_24: $i > $i).
% 29.20/29.01  tff(decl_30305, type, fn_diffusion_of_anion_across_plasma_membrane_25: $i > $i).
% 29.20/29.01  tff(decl_30306, type, fn_diffusion_of_anion_across_plasma_membrane_26: $i > $i).
% 29.20/29.01  tff(decl_30307, type, fn_diffusion_of_anion_across_plasma_membrane_27: $i > $i).
% 29.20/29.01  tff(decl_30308, type, fn_diffusion_of_anion_across_plasma_membrane_29: $i > $i).
% 29.20/29.01  tff(decl_30309, type, fn_diffusion_of_anion_across_plasma_membrane_30: $i > $i).
% 29.20/29.01  tff(decl_30310, type, fn_diffusion_of_anion_across_plasma_membrane_31: $i > $i).
% 29.20/29.01  tff(decl_30311, type, fn_diffusion_of_anion_across_plasma_membrane_32: $i > $i).
% 29.20/29.01  tff(decl_30312, type, fn_diffusion_of_anion_across_plasma_membrane_33: $i > $i).
% 29.20/29.01  tff(decl_30313, type, fn_diffusion_of_anion_across_plasma_membrane_34: $i > $i).
% 29.20/29.01  tff(decl_30314, type, fn_diffusion_of_anion_across_plasma_membrane_36: $i > $i).
% 29.20/29.01  tff(decl_30315, type, fn_diffusion_of_anion_across_plasma_membrane_37: $i > $i).
% 29.20/29.01  tff(decl_30316, type, fn_diffusion_of_anion_across_plasma_membrane_38: $i > $i).
% 29.20/29.01  tff(decl_30317, type, fn_diffusion_of_anion_across_plasma_membrane_39: $i > $i).
% 29.20/29.01  tff(decl_30318, type, fn_diffusion_of_anion_across_plasma_membrane_40: $i > $i).
% 29.20/29.01  tff(decl_30319, type, fn_diffusion_of_anion_across_plasma_membrane_41: $i > $i).
% 29.20/29.01  tff(decl_30320, type, fn_diffusion_of_anion_across_plasma_membrane_42: $i > $i).
% 29.20/29.01  tff(decl_30321, type, fn_diffusion_of_anion_across_plasma_membrane_45: $i > $i).
% 29.20/29.01  tff(decl_30322, type, fn_diffusion_of_anion_across_plasma_membrane_46: $i > $i).
% 29.20/29.01  tff(decl_30323, type, fn_diffusion_of_anion_across_plasma_membrane_47: $i > $i).
% 29.20/29.01  tff(decl_30324, type, fn_diffusion_of_anion_across_plasma_membrane_48: $i > $i).
% 29.20/29.01  tff(decl_30325, type, fn_diffusion_of_anion_across_plasma_membrane_49: $i > $i).
% 29.20/29.01  tff(decl_30326, type, fn_thermal_motion_6: $i > $i).
% 29.20/29.01  tff(decl_30327, type, fn_facilitated_diffusion_34: $i > $i).
% 29.20/29.01  tff(decl_30328, type, fn_facilitated_diffusion_45: $i > $i).
% 29.20/29.01  tff(decl_30329, type, fn_facilitated_diffusion_15: $i > $i).
% 29.20/29.01  tff(decl_30330, type, fn_facilitated_diffusion_17: $i > $i).
% 29.20/29.01  tff(decl_30331, type, fn_facilitated_diffusion_6: $i > $i).
% 29.20/29.01  tff(decl_30332, type, fn_facilitated_diffusion_14: $i > $i).
% 29.20/29.01  tff(decl_30333, type, fn_facilitated_diffusion_16: $i > $i).
% 29.20/29.01  tff(decl_30334, type, fn_facilitated_diffusion_of_ion_25: $i > $i).
% 29.20/29.01  tff(decl_30335, type, fn_diffusion_of_anion_across_plasma_membrane_43: $i > $i).
% 29.20/29.01  tff(decl_30336, type, fn_diffusion_of_anion_across_plasma_membrane_44: $i > $i).
% 29.20/29.01  tff(decl_30337, type, fn_facilitated_diffusion_47: $i > $i).
% 29.20/29.01  tff(decl_30338, type, fn_diffusion_of_anion_across_plasma_membrane_6: $i > $i).
% 29.20/29.01  tff(decl_30339, type, fn_diffusion_of_anion_across_plasma_membrane_5: $i > $i).
% 29.20/29.01  tff(decl_30340, type, fn_diffusion_of_anion_across_plasma_membrane_4: $i > $i).
% 29.20/29.01  tff(decl_30341, type, fn_diffusion_of_anion_across_plasma_membrane_3: $i > $i).
% 29.20/29.01  tff(decl_30342, type, fn_facilitated_diffusion_5: $i > $i).
% 29.20/29.01  tff(decl_30343, type, diffusion_of_carbon_dioxide_across_cell_membrane_1: $i > $o).
% 29.20/29.01  tff(decl_30344, type, 'Diffusion-of-Carbon-Dioxide-Across-Cell-Membrane': $i).
% 29.20/29.01  tff(decl_30345, type, 'The passive movement of carbon dioxide from an area of high concentration on one side of the membrane to an area of lower concentration on the other side of the membrane.': $i).
% 29.20/29.01  tff(decl_30346, type, 'diffusion of co2': $i).
% 29.20/29.01  tff(decl_30347, type, 'diffusion of carbon dioxide': $i).
% 29.20/29.01  tff(decl_30348, type, 'diffusion of carbon dioxide across cell membrane': $i).
% 29.20/29.01  tff(decl_30349, type, 'diffusion-of-carbon-dioxide-across-cell-membrane': $i).
% 29.20/29.01  tff(decl_30350, type, movement_of_hydrophobic_molecule_across_biomembrane_1: $i > $o).
% 29.20/29.01  tff(decl_30351, type, fn_diffusion_of_carbon_dioxide_across_cell_membrane_1: $i > $i).
% 29.20/29.01  tff(decl_30352, type, fn_diffusion_of_carbon_dioxide_across_cell_membrane_2: $i > $i).
% 29.20/29.01  tff(decl_30353, type, fn_diffusion_of_carbon_dioxide_across_cell_membrane_3: $i > $i).
% 29.20/29.01  tff(decl_30354, type, fn_diffusion_of_carbon_dioxide_across_cell_membrane_4: $i > $i).
% 29.20/29.01  tff(decl_30355, type, fn_diffusion_of_carbon_dioxide_across_cell_membrane_5: $i > $i).
% 29.20/29.01  tff(decl_30356, type, fn_diffusion_of_carbon_dioxide_across_cell_membrane_6: $i > $i).
% 29.20/29.01  tff(decl_30357, type, fn_diffusion_of_carbon_dioxide_across_cell_membrane_7: $i > $i).
% 29.20/29.01  tff(decl_30358, type, fn_diffusion_of_carbon_dioxide_across_cell_membrane_8: $i > $i).
% 29.20/29.01  tff(decl_30359, type, 'Diffusion-Of-Cation-Across-Plasma-Membrane': $i).
% 29.20/29.01  tff(decl_30360, type, 'diffusion of cation across plasma membrane': $i).
% 29.20/29.01  tff(decl_30361, type, 'diffusion-of-cation-across-plasma-membrane': $i).
% 29.20/29.01  tff(decl_30362, type, fn_diffusion_of_cation_across_plasma_membrane_1: $i > $i).
% 29.20/29.01  tff(decl_30363, type, fn_diffusion_of_cation_across_plasma_membrane_2: $i > $i).
% 29.20/29.01  tff(decl_30364, type, fn_diffusion_of_cation_across_plasma_membrane_3: $i > $i).
% 29.20/29.01  tff(decl_30365, type, fn_diffusion_of_cation_across_plasma_membrane_4: $i > $i).
% 29.20/29.01  tff(decl_30366, type, fn_diffusion_of_cation_across_plasma_membrane_5: $i > $i).
% 29.20/29.01  tff(decl_30367, type, fn_diffusion_of_cation_across_plasma_membrane_6: $i > $i).
% 29.20/29.01  tff(decl_30368, type, fn_diffusion_of_cation_across_plasma_membrane_7: $i > $i).
% 29.20/29.01  tff(decl_30369, type, fn_diffusion_of_cation_across_plasma_membrane_8: $i > $i).
% 29.20/29.01  tff(decl_30370, type, fn_diffusion_of_cation_across_plasma_membrane_9: $i > $i).
% 29.20/29.01  tff(decl_30371, type, fn_diffusion_of_cation_across_plasma_membrane_10: $i > $i).
% 29.20/29.01  tff(decl_30372, type, fn_diffusion_of_cation_across_plasma_membrane_11: $i > $i).
% 29.20/29.01  tff(decl_30373, type, fn_diffusion_of_cation_across_plasma_membrane_12: $i > $i).
% 29.20/29.01  tff(decl_30374, type, fn_diffusion_of_cation_across_plasma_membrane_13: $i > $i).
% 29.20/29.01  tff(decl_30375, type, fn_diffusion_of_cation_across_plasma_membrane_14: $i > $i).
% 29.20/29.01  tff(decl_30376, type, fn_diffusion_of_cation_across_plasma_membrane_15: $i > $i).
% 29.20/29.01  tff(decl_30377, type, fn_diffusion_of_cation_across_plasma_membrane_16: $i > $i).
% 29.20/29.01  tff(decl_30378, type, fn_diffusion_of_cation_across_plasma_membrane_17: $i > $i).
% 29.20/29.01  tff(decl_30379, type, fn_diffusion_of_cation_across_plasma_membrane_18: $i > $i).
% 29.20/29.01  tff(decl_30380, type, fn_diffusion_of_cation_across_plasma_membrane_19: $i > $i).
% 29.20/29.01  tff(decl_30381, type, fn_diffusion_of_cation_across_plasma_membrane_20: $i > $i).
% 29.20/29.01  tff(decl_30382, type, fn_diffusion_of_cation_across_plasma_membrane_21: $i > $i).
% 29.20/29.01  tff(decl_30383, type, fn_diffusion_of_cation_across_plasma_membrane_22: $i > $i).
% 29.20/29.01  tff(decl_30384, type, fn_diffusion_of_cation_across_plasma_membrane_23: $i > $i).
% 29.20/29.01  tff(decl_30385, type, fn_diffusion_of_cation_across_plasma_membrane_24: $i > $i).
% 29.20/29.01  tff(decl_30386, type, fn_diffusion_of_cation_across_plasma_membrane_25: $i > $i).
% 29.20/29.01  tff(decl_30387, type, fn_diffusion_of_cation_across_plasma_membrane_26: $i > $i).
% 29.20/29.01  tff(decl_30388, type, fn_diffusion_of_cation_across_plasma_membrane_27: $i > $i).
% 29.20/29.01  tff(decl_30389, type, fn_diffusion_of_cation_across_plasma_membrane_28: $i > $i).
% 29.20/29.01  tff(decl_30390, type, fn_diffusion_of_cation_across_plasma_membrane_29: $i > $i).
% 29.20/29.01  tff(decl_30391, type, fn_diffusion_of_cation_across_plasma_membrane_30: $i > $i).
% 29.20/29.01  tff(decl_30392, type, fn_diffusion_of_cation_across_plasma_membrane_31: $i > $i).
% 29.20/29.01  tff(decl_30393, type, fn_diffusion_of_cation_across_plasma_membrane_32: $i > $i).
% 29.20/29.01  tff(decl_30394, type, fn_diffusion_of_cation_across_plasma_membrane_33: $i > $i).
% 29.20/29.01  tff(decl_30395, type, fn_diffusion_of_cation_across_plasma_membrane_34: $i > $i).
% 29.20/29.01  tff(decl_30396, type, fn_diffusion_of_cation_across_plasma_membrane_35: $i > $i).
% 29.20/29.01  tff(decl_30397, type, fn_diffusion_of_cation_across_plasma_membrane_36: $i > $i).
% 29.20/29.01  tff(decl_30398, type, fn_diffusion_of_cation_across_plasma_membrane_37: $i > $i).
% 29.20/29.01  tff(decl_30399, type, fn_diffusion_of_cation_across_plasma_membrane_38: $i > $i).
% 29.20/29.01  tff(decl_30400, type, fn_diffusion_of_cation_across_plasma_membrane_39: $i > $i).
% 29.20/29.01  tff(decl_30401, type, fn_diffusion_of_cation_across_plasma_membrane_40: $i > $i).
% 29.20/29.01  tff(decl_30402, type, fn_diffusion_of_cation_across_plasma_membrane_41: $i > $i).
% 29.20/29.01  tff(decl_30403, type, fn_diffusion_of_cation_across_plasma_membrane_42: $i > $i).
% 29.20/29.01  tff(decl_30404, type, fn_diffusion_of_cation_across_plasma_membrane_47: $i > $i).
% 29.20/29.01  tff(decl_30405, type, fn_diffusion_of_cation_across_plasma_membrane_48: $i > $i).
% 29.20/29.01  tff(decl_30406, type, fn_diffusion_of_cation_across_plasma_membrane_49: $i > $i).
% 29.20/29.01  tff(decl_30407, type, fn_diffusion_of_cation_across_plasma_membrane_50: $i > $i).
% 29.20/29.01  tff(decl_30408, type, fn_diffusion_of_cation_across_plasma_membrane_51: $i > $i).
% 29.20/29.01  tff(decl_30409, type, fn_diffusion_of_cation_across_plasma_membrane_52: $i > $i).
% 29.20/29.01  tff(decl_30410, type, fn_diffusion_of_cation_across_plasma_membrane_53: $i > $i).
% 29.20/29.01  tff(decl_30411, type, fn_diffusion_of_cation_across_plasma_membrane_54: $i > $i).
% 29.20/29.01  tff(decl_30412, type, fn_diffusion_of_cation_across_plasma_membrane_55: $i > $i).
% 29.20/29.01  tff(decl_30413, type, fn_diffusion_of_cation_across_plasma_membrane_56: $i > $i).
% 29.20/29.01  tff(decl_30414, type, fn_diffusion_of_cation_across_plasma_membrane_57: $i > $i).
% 29.20/29.01  tff(decl_30415, type, fn_diffusion_of_cation_across_plasma_membrane_58: $i > $i).
% 29.20/29.01  tff(decl_30416, type, fn_diffusion_of_cation_across_plasma_membrane_59: $i > $i).
% 29.20/29.01  tff(decl_30417, type, fn_diffusion_of_cation_across_plasma_membrane_60: $i > $i).
% 29.20/29.01  tff(decl_30418, type, fn_diffusion_of_cation_across_plasma_membrane_61: $i > $i).
% 29.20/29.01  tff(decl_30419, type, fn_diffusion_of_cation_across_plasma_membrane_62: $i > $i).
% 29.20/29.01  tff(decl_30420, type, fn_facilitated_diffusion_38: $i > $i).
% 29.20/29.01  tff(decl_30421, type, fn_facilitated_diffusion_39: $i > $i).
% 29.20/29.01  tff(decl_30422, type, fn_facilitated_diffusion_44: $i > $i).
% 29.20/29.01  tff(decl_30423, type, fn_diffusion_of_cation_across_plasma_membrane_63: $i > $i).
% 29.20/29.01  tff(decl_30424, type, fn_diffusion_of_cation_across_plasma_membrane_64: $i > $i).
% 29.20/29.01  tff(decl_30425, type, fn_diffusion_of_cation_across_plasma_membrane_66: $i > $i).
% 29.20/29.01  tff(decl_30426, type, fn_diffusion_of_cation_across_plasma_membrane_65: $i > $i).
% 29.20/29.01  tff(decl_30427, type, fn_diffusion_of_cation_across_plasma_membrane_44: $i > $i).
% 29.20/29.01  tff(decl_30428, type, fn_diffusion_of_cation_across_plasma_membrane_45: $i > $i).
% 29.20/29.01  tff(decl_30429, type, fn_diffusion_of_cation_across_plasma_membrane_46: $i > $i).
% 29.20/29.01  tff(decl_30430, type, fn_diffusion_of_cation_across_plasma_membrane_43: $i > $i).
% 29.20/29.01  tff(decl_30431, type, fn_facilitated_diffusion_35: $i > $i).
% 29.20/29.01  tff(decl_30432, type, fn_facilitated_diffusion_54: $i > $i).
% 29.20/29.01  tff(decl_30433, type, fn_facilitated_diffusion_53: $i > $i).
% 29.20/29.01  tff(decl_30434, type, diffusion_of_dye_in_water_1: $i > $o).
% 29.20/29.01  tff(decl_30435, type, 'Diffusion-Of-Dye-In-Water': $i).
% 29.20/29.01  tff(decl_30436, type, 'Diffusion of dye in water increases entropy by producing a more random mixture than exists when there are localized concentrations of the dye.': $i).
% 29.20/29.01  tff(decl_30437, type, 'diffusion of dye in water': $i).
% 29.20/29.01  tff(decl_30438, type, 'diffusion-of-dye-in-water': $i).
% 29.20/29.01  tff(decl_30439, type, diffusion_of_solute_in_water_1: $i > $o).
% 29.20/29.01  tff(decl_30440, type, diffusion_of_oxygen_across_plasma_membrane_1: $i > $o).
% 29.20/29.01  tff(decl_30441, type, 'Diffusion-of-Oxygen-Across-Plasma-Membrane': $i).
% 29.20/29.01  tff(decl_30442, type, 'The passive movement of oxygen from an area of high concentration on one side of the membrane to an area of lower concentration on the other side of the plasma membrane.': $i).
% 29.20/29.01  tff(decl_30443, type, 'diffusion of oxygen across plasma membrane': $i).
% 29.20/29.01  tff(decl_30444, type, 'diffusion-of-oxygen-across-plasma-membrane': $i).
% 29.20/29.01  tff(decl_30445, type, fn_diffusion_of_oxygen_across_plasma_membrane_1: $i > $i).
% 29.20/29.01  tff(decl_30446, type, fn_diffusion_of_oxygen_across_plasma_membrane_2: $i > $i).
% 29.20/29.01  tff(decl_30447, type, fn_diffusion_of_oxygen_across_plasma_membrane_3: $i > $i).
% 29.20/29.01  tff(decl_30448, type, fn_diffusion_of_oxygen_across_plasma_membrane_4: $i > $i).
% 29.20/29.01  tff(decl_30449, type, fn_diffusion_of_oxygen_across_plasma_membrane_5: $i > $i).
% 29.20/29.01  tff(decl_30450, type, fn_diffusion_of_oxygen_across_plasma_membrane_6: $i > $i).
% 29.20/29.01  tff(decl_30451, type, fn_diffusion_of_oxygen_across_plasma_membrane_7: $i > $i).
% 29.20/29.01  tff(decl_30452, type, fn_diffusion_of_oxygen_across_plasma_membrane_8: $i > $i).
% 29.20/29.01  tff(decl_30453, type, fn_diffusion_of_oxygen_across_plasma_membrane_9: $i > $i).
% 29.20/29.01  tff(decl_30454, type, fn_diffusion_of_oxygen_across_plasma_membrane_10: $i > $i).
% 29.20/29.01  tff(decl_30455, type, fn_diffusion_of_oxygen_across_plasma_membrane_11: $i > $i).
% 29.20/29.01  tff(decl_30456, type, fn_diffusion_of_oxygen_across_plasma_membrane_12: $i > $i).
% 29.20/29.01  tff(decl_30457, type, fn_diffusion_of_oxygen_across_plasma_membrane_13: $i > $i).
% 29.20/29.01  tff(decl_30458, type, random_motion_1: $i > $o).
% 29.20/29.01  tff(decl_30459, type, diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_1: $i > $o).
% 29.20/29.01  tff(decl_30460, type, 'Diffusion-Of-Sodium-Ion-Across-Plasma-Membrane-Of-Nerve-Cell': $i).
% 29.20/29.01  tff(decl_30461, type, 'Sodium ions then fall down their electrochemical gradient, driven by the concentration gradient of Na+ and by the attraction of cations to the negative side of the membrane.': $i).
% 29.20/29.01  tff(decl_30462, type, 'diffusion of sodium ion across plasma membrane of nerve cell': $i).
% 29.20/29.01  tff(decl_30463, type, 'diffusion-of-sodium-ion-across-plasma-membrane-of-nerve-cell': $i).
% 29.20/29.01  tff(decl_30464, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_1: $i > $i).
% 29.20/29.01  tff(decl_30465, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_2: $i > $i).
% 29.20/29.01  tff(decl_30466, type, stimulus_1: $i > $o).
% 29.20/29.01  tff(decl_30467, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_3: $i > $i).
% 29.20/29.01  tff(decl_30468, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_4: $i > $i).
% 29.20/29.01  tff(decl_30469, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_5: $i > $i).
% 29.20/29.01  tff(decl_30470, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_6: $i > $i).
% 29.20/29.01  tff(decl_30471, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_7: $i > $i).
% 29.20/29.01  tff(decl_30472, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_8: $i > $i).
% 29.20/29.01  tff(decl_30473, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_9: $i > $i).
% 29.20/29.01  tff(decl_30474, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_10: $i > $i).
% 29.20/29.01  tff(decl_30475, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_11: $i > $i).
% 29.20/29.01  tff(decl_30476, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_12: $i > $i).
% 29.20/29.01  tff(decl_30477, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_13: $i > $i).
% 29.20/29.01  tff(decl_30478, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_14: $i > $i).
% 29.20/29.01  tff(decl_30479, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_19: $i > $i).
% 29.20/29.01  tff(decl_30480, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_20: $i > $i).
% 29.20/29.01  tff(decl_30481, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_21: $i > $i).
% 29.20/29.01  tff(decl_30482, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_22: $i > $i).
% 29.20/29.01  tff(decl_30483, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_23: $i > $i).
% 29.20/29.01  tff(decl_30484, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_24: $i > $i).
% 29.20/29.01  tff(decl_30485, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_25: $i > $i).
% 29.20/29.01  tff(decl_30486, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_26: $i > $i).
% 29.20/29.01  tff(decl_30487, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_27: $i > $i).
% 29.20/29.01  tff(decl_30488, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_28: $i > $i).
% 29.20/29.01  tff(decl_30489, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_32: $i > $i).
% 29.20/29.01  tff(decl_30490, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_33: $i > $i).
% 29.20/29.01  tff(decl_30491, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_34: $i > $i).
% 29.20/29.01  tff(decl_30492, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_35: $i > $i).
% 29.20/29.01  tff(decl_30493, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_36: $i > $i).
% 29.20/29.01  tff(decl_30494, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_37: $i > $i).
% 29.20/29.01  tff(decl_30495, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_38: $i > $i).
% 29.20/29.01  tff(decl_30496, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_39: $i > $i).
% 29.20/29.01  tff(decl_30497, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_40: $i > $i).
% 29.20/29.01  tff(decl_30498, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_41: $i > $i).
% 29.20/29.01  tff(decl_30499, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_42: $i > $i).
% 29.20/29.01  tff(decl_30500, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_43: $i > $i).
% 29.20/29.01  tff(decl_30501, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_44: $i > $i).
% 29.20/29.01  tff(decl_30502, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_45: $i > $i).
% 29.20/29.01  tff(decl_30503, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_46: $i > $i).
% 29.20/29.01  tff(decl_30504, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_47: $i > $i).
% 29.20/29.01  tff(decl_30505, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_48: $i > $i).
% 29.20/29.01  tff(decl_30506, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_49: $i > $i).
% 29.20/29.01  tff(decl_30507, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_50: $i > $i).
% 29.20/29.01  tff(decl_30508, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_51: $i > $i).
% 29.20/29.01  tff(decl_30509, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_52: $i > $i).
% 29.20/29.01  tff(decl_30510, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_53: $i > $i).
% 29.20/29.01  tff(decl_30511, type, sodium_channel_1: $i > $o).
% 29.20/29.01  tff(decl_30512, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_54: $i > $i).
% 29.20/29.01  tff(decl_30513, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_55: $i > $i).
% 29.20/29.01  tff(decl_30514, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_56: $i > $i).
% 29.20/29.01  tff(decl_30515, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_57: $i > $i).
% 29.20/29.01  tff(decl_30516, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_58: $i > $i).
% 29.20/29.01  tff(decl_30517, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_59: $i > $i).
% 29.20/29.01  tff(decl_30518, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_60: $i > $i).
% 29.20/29.01  tff(decl_30519, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_61: $i > $i).
% 29.20/29.01  tff(decl_30520, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_62: $i > $i).
% 29.20/29.01  tff(decl_30521, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_63: $i > $i).
% 29.20/29.01  tff(decl_30522, type, fn_gated_channel_4: $i > $i).
% 29.20/29.01  tff(decl_30523, type, fn_gated_channel_39: $i > $i).
% 29.20/29.01  tff(decl_30524, type, fn_gated_channel_17: $i > $i).
% 29.20/29.01  tff(decl_30525, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_16: $i > $i).
% 29.20/29.01  tff(decl_30526, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_17: $i > $i).
% 29.20/29.01  tff(decl_30527, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_15: $i > $i).
% 29.20/29.01  tff(decl_30528, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_18: $i > $i).
% 29.20/29.01  tff(decl_30529, type, fn_facilitated_diffusion_13: $i > $i).
% 29.20/29.01  tff(decl_30530, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_30: $i > $i).
% 29.20/29.01  tff(decl_30531, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_29: $i > $i).
% 29.20/29.01  tff(decl_30532, type, fn_diffusion_of_sodium_ion_across_plasma_membrane_of_nerve_cell_31: $i > $i).
% 29.20/29.01  tff(decl_30533, type, fn_passive_transport_27: $i > $i).
% 29.20/29.01  tff(decl_30534, type, 'Diffusion-Of-Solute-In-Water': $i).
% 29.20/29.01  tff(decl_30535, type, 'Diffusion of a solute in water increases entropy by producing a more random mixture than exists when there are localized concentrations of the solute.': $i).
% 29.20/29.01  tff(decl_30536, type, 'diffusion of solute in water': $i).
% 29.20/29.01  tff(decl_30537, type, 'diffusion-of-solute-in-water': $i).
% 29.20/29.01  tff(decl_30538, type, fn_diffusion_of_solute_in_water_1: $i > $i).
% 29.20/29.01  tff(decl_30539, type, 'Diffusion-Of-Water-Across-Membrane-Separating-Two-Isotonic-Solution': $i).
% 29.20/29.01  tff(decl_30540, type, 'The condition when the two solutions are isotonic, water moves across a membrane separating the solutions at an equal rate in both directions; that is, there is no net osmosis between isotonic solutions.': $i).
% 29.20/29.01  tff(decl_30541, type, 'diffusion of water across membrane separating two isotonic solution': $i).
% 29.20/29.01  tff(decl_30542, type, 'diffusion-of-water-across-membrane-separating-two-isotonic-solution': $i).
% 29.20/29.01  tff(decl_30543, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_5: $i > $i).
% 29.20/29.01  tff(decl_30544, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_6: $i > $i).
% 29.20/29.01  tff(decl_30545, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_7: $i > $i).
% 29.20/29.01  tff(decl_30546, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_8: $i > $i).
% 29.20/29.01  tff(decl_30547, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_9: $i > $i).
% 29.20/29.01  tff(decl_30548, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_10: $i > $i).
% 29.20/29.01  tff(decl_30549, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_11: $i > $i).
% 29.20/29.01  tff(decl_30550, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_12: $i > $i).
% 29.20/29.01  tff(decl_30551, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_13: $i > $i).
% 29.20/29.01  tff(decl_30552, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_14: $i > $i).
% 29.20/29.01  tff(decl_30553, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_16: $i > $i).
% 29.20/29.01  tff(decl_30554, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_17: $i > $i).
% 29.20/29.01  tff(decl_30555, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_20: $i > $i).
% 29.20/29.01  tff(decl_30556, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_21: $i > $i).
% 29.20/29.01  tff(decl_30557, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_22: $i > $i).
% 29.20/29.01  tff(decl_30558, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_23: $i > $i).
% 29.20/29.01  tff(decl_30559, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_24: $i > $i).
% 29.20/29.01  tff(decl_30560, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_25: $i > $i).
% 29.20/29.01  tff(decl_30561, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_26: $i > $i).
% 29.20/29.01  tff(decl_30562, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_27: $i > $i).
% 29.20/29.01  tff(decl_30563, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_28: $i > $i).
% 29.20/29.01  tff(decl_30564, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_29: $i > $i).
% 29.20/29.01  tff(decl_30565, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_30: $i > $i).
% 29.20/29.01  tff(decl_30566, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_31: $i > $i).
% 29.20/29.01  tff(decl_30567, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_32: $i > $i).
% 29.20/29.01  tff(decl_30568, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_33: $i > $i).
% 29.20/29.01  tff(decl_30569, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_34: $i > $i).
% 29.20/29.01  tff(decl_30570, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_35: $i > $i).
% 29.20/29.01  tff(decl_30571, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_36: $i > $i).
% 29.20/29.01  tff(decl_30572, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_37: $i > $i).
% 29.20/29.01  tff(decl_30573, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_38: $i > $i).
% 29.20/29.01  tff(decl_30574, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_39: $i > $i).
% 29.20/29.01  tff(decl_30575, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_40: $i > $i).
% 29.20/29.01  tff(decl_30576, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_41: $i > $i).
% 29.20/29.01  tff(decl_30577, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_42: $i > $i).
% 29.20/29.01  tff(decl_30578, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_43: $i > $i).
% 29.20/29.01  tff(decl_30579, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_44: $i > $i).
% 29.20/29.01  tff(decl_30580, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_45: $i > $i).
% 29.20/29.01  tff(decl_30581, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_46: $i > $i).
% 29.20/29.01  tff(decl_30582, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_47: $i > $i).
% 29.20/29.01  tff(decl_30583, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_48: $i > $i).
% 29.20/29.01  tff(decl_30584, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_49: $i > $i).
% 29.20/29.01  tff(decl_30585, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_50: $i > $i).
% 29.20/29.01  tff(decl_30586, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_54: $i > $i).
% 29.20/29.01  tff(decl_30587, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_56: $i > $i).
% 29.20/29.01  tff(decl_30588, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_57: $i > $i).
% 29.20/29.01  tff(decl_30589, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_58: $i > $i).
% 29.20/29.01  tff(decl_30590, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_59: $i > $i).
% 29.20/29.01  tff(decl_30591, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_60: $i > $i).
% 29.20/29.01  tff(decl_30592, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_61: $i > $i).
% 29.20/29.01  tff(decl_30593, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_62: $i > $i).
% 29.20/29.01  tff(decl_30594, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_63: $i > $i).
% 29.20/29.01  tff(decl_30595, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_64: $i > $i).
% 29.20/29.01  tff(decl_30596, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_65: $i > $i).
% 29.20/29.01  tff(decl_30597, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_66: $i > $i).
% 29.20/29.01  tff(decl_30598, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_67: $i > $i).
% 29.20/29.01  tff(decl_30599, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_68: $i > $i).
% 29.20/29.01  tff(decl_30600, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_69: $i > $i).
% 29.20/29.01  tff(decl_30601, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_70: $i > $i).
% 29.20/29.01  tff(decl_30602, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_71: $i > $i).
% 29.20/29.01  tff(decl_30603, type, fn_water_molecule_74: $i > $i).
% 29.20/29.01  tff(decl_30604, type, fn_water_30: $i > $i).
% 29.20/29.01  tff(decl_30605, type, 'Rate_MoveThrough2': $i).
% 29.20/29.01  tff(decl_30606, type, 'Rate_MoveThrough1': $i).
% 29.20/29.01  tff(decl_30607, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_53: $i > $i).
% 29.20/29.01  tff(decl_30608, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_52: $i > $i).
% 29.20/29.01  tff(decl_30609, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_15: $i > $i).
% 29.20/29.01  tff(decl_30610, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_19: $i > $i).
% 29.20/29.01  tff(decl_30611, type, fn_osmosis_2: $i > $i).
% 29.20/29.01  tff(decl_30612, type, fn_osmosis_25: $i > $i).
% 29.20/29.01  tff(decl_30613, type, fn_osmosis_1: $i > $i).
% 29.20/29.01  tff(decl_30614, type, fn_osmosis_24: $i > $i).
% 29.20/29.01  tff(decl_30615, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_55: $i > $i).
% 29.20/29.01  tff(decl_30616, type, fn_osmosis_16: $i > $i).
% 29.20/29.01  tff(decl_30617, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_51: $i > $i).
% 29.20/29.01  tff(decl_30618, type, fn_osmosis_18: $i > $i).
% 29.20/29.01  tff(decl_30619, type, fn_osmosis_15: $i > $i).
% 29.20/29.01  tff(decl_30620, type, fn_osmosis_17: $i > $i).
% 29.20/29.01  tff(decl_30621, type, fn_osmosis_20: $i > $i).
% 29.20/29.01  tff(decl_30622, type, fn_diffusion_of_water_across_membrane_separating_two_isotonic_solution_18: $i > $i).
% 29.20/29.01  tff(decl_30623, type, 'Digestion': $i).
% 29.20/29.01  tff(decl_30624, type, 'Digestion is the mechanical and chemical breaking down of food into smaller components, to a form that can be absorbed, for instance, by a blood stream. Digestion is a form of catabolism': $i).
% 29.20/29.01  tff(decl_30625, type, digestion: $i).
% 29.20/29.01  tff(decl_30626, type, fn_digestion_1: $i > $i).
% 29.20/29.01  tff(decl_30627, type, 'Digestive-Enzyme': $i).
% 29.20/29.01  tff(decl_30628, type, 'Enzymes that break down macromolecules into simpler molecules during digestion.': $i).
% 29.20/29.01  tff(decl_30629, type, 'digestive enzyme': $i).
% 29.20/29.01  tff(decl_30630, type, 'digestive-enzyme': $i).
% 29.20/29.01  tff(decl_30631, type, secretory_protein_1: $i > $o).
% 29.20/29.01  tff(decl_30632, type, insulin_1: $i > $o).
% 29.20/29.01  tff(decl_30633, type, ribonuclease_1: $i > $o).
% 29.20/29.01  tff(decl_30634, type, 'Digestive-Fluid': $i).
% 29.20/29.01  tff(decl_30635, type, 'Liquids in organisms which aid in the process of digestion.': $i).
% 29.20/29.01  tff(decl_30636, type, 'digestive fluid': $i).
% 29.20/29.01  tff(decl_30637, type, 'digestive-fluid': $i).
% 29.20/29.01  tff(decl_30638, type, secreted_fluid_1: $i > $o).
% 29.20/29.01  tff(decl_30639, type, digestive_hormone_1: $i > $o).
% 29.20/29.01  tff(decl_30640, type, 'Digestive-Hormone': $i).
% 29.20/29.01  tff(decl_30641, type, 'A hormone that aids and regulates the digestion processes in mammals.': $i).
% 29.20/29.01  tff(decl_30642, type, 'digestive hormone': $i).
% 29.20/29.01  tff(decl_30643, type, 'digestive-hormone': $i).
% 29.20/29.01  tff(decl_30644, type, 'Digestive-Organ': $i).
% 29.20/29.01  tff(decl_30645, type, 'Organ which is part of the digestive system of animals.': $i).
% 29.20/29.01  tff(decl_30646, type, 'digestive organ': $i).
% 29.20/29.01  tff(decl_30647, type, 'digestive-organ': $i).
% 29.20/29.01  tff(decl_30648, type, 'Digestive-Peptide-Hormone': $i).
% 29.20/29.01  tff(decl_30649, type, 'Peptide hormones secreted by the thyroid gland.': $i).
% 29.20/29.01  tff(decl_30650, type, 'digestive peptide hormone': $i).
% 29.20/29.01  tff(decl_30651, type, 'digestive-peptide-hormone': $i).
% 29.20/29.01  tff(decl_30652, type, 'Digestive-Process': $i).
% 29.20/29.01  tff(decl_30653, type, 'A process which occurs during digestion, the second stage of food processing in animals.': $i).
% 29.20/29.01  tff(decl_30654, type, 'digestive process': $i).
% 29.20/29.01  tff(decl_30655, type, 'digestive-process': $i).
% 29.20/29.01  tff(decl_30656, type, 'Digestive-System': $i).
% 29.20/29.01  tff(decl_30657, type, 'A system of organs responsible for the digestion and absorption of nutrients from food.': $i).
% 29.20/29.01  tff(decl_30658, type, 'digestive system': $i).
% 29.20/29.01  tff(decl_30659, type, 'digestive-system': $i).
% 29.20/29.01  tff(decl_30660, type, fn_digestive_system_1: $i > $i).
% 29.20/29.01  tff(decl_30661, type, 'Digestive-Tract': $i).
% 29.20/29.01  tff(decl_30662, type, 'The organs through which food and liquids pass when they are swallowed, digested, and eliminated.': $i).
% 29.20/29.01  tff(decl_30663, type, 'digestive tract': $i).
% 29.20/29.01  tff(decl_30664, type, 'digestive-tract': $i).
% 29.20/29.01  tff(decl_30665, type, digit_1: $i > $o).
% 29.20/29.01  tff(decl_30666, type, 'Digit': $i).
% 29.20/29.01  tff(decl_30667, type, 'In vertebrate anatomy, a digit is one of the appendages of the hand or foot, such as a toe or finger.': $i).
% 29.20/29.01  tff(decl_30668, type, digit: $i).
% 29.20/29.01  tff(decl_30669, type, dihybrid_1: $i > $o).
% 29.20/29.01  tff(decl_30670, type, 'Dihybrid': $i).
% 29.20/29.01  tff(decl_30671, type, 'An organism that is heterozygous with respect to two genes of interest. All the offspring from a cross between parents doubly homozygous for different alleles are dihybrids. For example, parents of genotypes AABB and aabb produce a dihybrid of genotype AaBb.': $i).
% 29.20/29.01  tff(decl_30672, type, dihybrid: $i).
% 29.20/29.01  tff(decl_30673, type, hybrid_1: $i > $o).
% 29.20/29.01  tff(decl_30674, type, monohybrid_1: $i > $o).
% 29.20/29.01  tff(decl_30675, type, fn_dihybrid_1: $i > $i).
% 29.20/29.01  tff(decl_30676, type, homozygous_1: $i > $o).
% 29.20/29.01  tff(decl_30677, type, fn_dihybrid_2: $i > $i).
% 29.20/29.01  tff(decl_30678, type, fn_dihybrid_3: $i > $i).
% 29.20/29.01  tff(decl_30679, type, fn_dihybrid_4: $i > $i).
% 29.20/29.01  tff(decl_30680, type, homozygous_0: $i).
% 29.20/29.01  tff(decl_30681, type, dihybrid_epistasis_1: $i > $o).
% 29.20/29.01  tff(decl_30682, type, 'Dihybrid-Epistasis': $i).
% 29.20/29.01  tff(decl_30683, type, 'A dihybrid cross which includes epistatic interaction.': $i).
% 29.20/29.01  tff(decl_30684, type, 'epistasis of dihybrid': $i).
% 29.20/29.01  tff(decl_30685, type, 'dihybrid epistasis': $i).
% 29.20/29.01  tff(decl_30686, type, 'dihybrid-epistasis': $i).
% 29.20/29.01  tff(decl_30687, type, epistasis_1: $i > $o).
% 29.20/29.01  tff(decl_30688, type, fn_dihybrid_epistasis_1: $i > $i).
% 29.20/29.01  tff(decl_30689, type, mating_1: $i > $o).
% 29.20/29.01  tff(decl_30690, type, fn_dihybrid_epistasis_2: $i > $i).
% 29.20/29.01  tff(decl_30691, type, fn_dihybrid_epistasis_3: $i > $i).
% 29.20/29.01  tff(decl_30692, type, fn_dihybrid_epistasis_4: $i > $i).
% 29.20/29.01  tff(decl_30693, type, fn_dihybrid_epistasis_5: $i > $i).
% 29.20/29.01  tff(decl_30694, type, fn_dihybrid_epistasis_6: $i > $i).
% 29.20/29.01  tff(decl_30695, type, fn_dihybrid_epistasis_8: $i > $i).
% 29.20/29.01  tff(decl_30696, type, fn_dihybrid_epistasis_10: $i > $i).
% 29.20/29.01  tff(decl_30697, type, fn_dihybrid_epistasis_11: $i > $i).
% 29.20/29.01  tff(decl_30698, type, fn_dihybrid_epistasis_12: $i > $i).
% 29.20/29.01  tff(decl_30699, type, fn_dihybrid_epistasis_13: $i > $i).
% 29.20/29.01  tff(decl_30700, type, fn_dihybrid_epistasis_14: $i > $i).
% 29.20/29.01  tff(decl_30701, type, fn_dihybrid_epistasis_15: $i > $i).
% 29.20/29.01  tff(decl_30702, type, fn_dihybrid_epistasis_16: $i > $i).
% 29.20/29.01  tff(decl_30703, type, fn_dihybrid_epistasis_17: $i > $i).
% 29.20/29.01  tff(decl_30704, type, heterozygote_1: $i > $o).
% 29.20/29.01  tff(decl_30705, type, fn_dihybrid_epistasis_18: $i > $i).
% 29.20/29.01  tff(decl_30706, type, fn_dihybrid_epistasis_19: $i > $i).
% 29.20/29.01  tff(decl_30707, type, fn_dihybrid_epistasis_20: $i > $i).
% 29.20/29.01  tff(decl_30708, type, fn_express_3: $i > $i).
% 29.20/29.01  tff(decl_30709, type, 'Dihydroxyacetone-Phosphate': $i).
% 29.20/29.01  tff(decl_30710, type, 'Dihydroxyacetone phosphate (DHAP) is a biochemical compound involved in many reactions, from the Calvin cycle in plants to the ether-lipid biosynthesis process in Leishmania mexicana. Its major biochemical role is in the glycolysis metabolic pathway.': $i).
% 29.20/29.01  tff(decl_30711, type, dhap: $i).
% 29.20/29.01  tff(decl_30712, type, 'dihydroxyacetone phosphate': $i).
% 29.20/29.01  tff(decl_30713, type, 'dihydroxyacetone-phosphate': $i).
% 29.20/29.01  tff(decl_30714, type, fn_dihydroxyacetone_phosphate_5: $i > $i).
% 29.20/29.01  tff(decl_30715, type, fn_dihydroxyacetone_phosphate_6: $i > $i).
% 29.20/29.01  tff(decl_30716, type, fn_dihydroxyacetone_phosphate_11: $i > $i).
% 29.20/29.01  tff(decl_30717, type, fn_dihydroxyacetone_phosphate_12: $i > $i).
% 29.20/29.01  tff(decl_30718, type, fn_dihydroxyacetone_phosphate_13: $i > $i).
% 29.20/29.01  tff(decl_30719, type, synthesis_of_fat_1: $i > $o).
% 29.20/29.01  tff(decl_30720, type, fn_triose_10: $i > $i).
% 29.20/29.01  tff(decl_30721, type, fn_triose_7: $i > $i).
% 29.20/29.01  tff(decl_30722, type, fn_triose_11: $i > $i).
% 29.20/29.01  tff(decl_30723, type, fn_triose_12: $i > $i).
% 29.20/29.01  tff(decl_30724, type, dikaryotic_1: $i > $o).
% 29.20/29.01  tff(decl_30725, type, 'Dikaryotic': $i).
% 29.20/29.01  tff(decl_30726, type, 'Said of a fungal mycelium in which each cell contains two haploid nuclei that do not fuse.': $i).
% 29.20/29.01  tff(decl_30727, type, dikaryotic: $i).
% 29.20/29.01  tff(decl_30728, type, heterokaryon_1: $i > $o).
% 29.20/29.01  tff(decl_30729, type, 'Dim': $i).
% 29.20/29.01  tff(decl_30730, type, dim: $i).
% 29.20/29.01  tff(decl_30731, type, dip: $i).
% 29.20/29.01  tff(decl_30732, type, darken: $i).
% 29.20/29.01  tff(decl_30733, type, fn_dim_1: $i > $i).
% 29.20/29.01  tff(decl_30734, type, fn_dim_4: $i > $i).
% 29.20/29.01  tff(decl_30735, type, fn_dim_5: $i > $i).
% 29.20/29.01  tff(decl_30736, type, fn_dim_3: $i > $i).
% 29.20/29.01  tff(decl_30737, type, fn_dim_2: $i > $i).
% 29.20/29.01  tff(decl_30738, type, 'Dimension-Constant': $i).
% 29.20/29.01  tff(decl_30739, type, 'constant of dimension': $i).
% 29.20/29.01  tff(decl_30740, type, 'dimension constant': $i).
% 29.20/29.01  tff(decl_30741, type, 'dimension-constant': $i).
% 29.20/29.01  tff(decl_30742, type, 'Dimension-Value': $i).
% 29.20/29.01  tff(decl_30743, type, dimension: $i).
% 29.20/29.01  tff(decl_30744, type, 'value of dimension': $i).
% 29.20/29.01  tff(decl_30745, type, 'dimension value': $i).
% 29.20/29.01  tff(decl_30746, type, 'dimension-value': $i).
% 29.20/29.01  tff(decl_30747, type, dimer_1: $i > $o).
% 29.20/29.01  tff(decl_30748, type, 'Dimer': $i).
% 29.20/29.01  tff(decl_30749, type, 'A molecule made up of two smaller, identical molecules.': $i).
% 29.20/29.01  tff(decl_30750, type, dimer: $i).
% 29.20/29.01  tff(decl_30751, type, fn_dimer_1: $i > $i).
% 29.20/29.01  tff(decl_30752, type, fn_dimer_2: $i > $i).
% 29.20/29.01  tff(decl_30753, type, 'Dimerization': $i).
% 29.20/29.01  tff(decl_30754, type, 'The formation of a chemical dimer from two identical subunits.': $i).
% 29.20/29.01  tff(decl_30755, type, dimerization: $i).
% 29.20/29.01  tff(decl_30756, type, fn_dimerization_3: $i > $i).
% 29.20/29.01  tff(decl_30757, type, 'Dinner': $i).
% 29.20/29.01  tff(decl_30758, type, dinner: $i).
% 29.20/29.01  tff(decl_30759, type, 'dinner party': $i).
% 29.20/29.01  tff(decl_30760, type, dinner_party: $i).
% 29.20/29.01  tff(decl_30761, type, 'Dinoflagellate': $i).
% 29.20/29.01  tff(decl_30762, type, 'The dinoflagellates  are a large group of flagellate protists. Most are marine plankton, but they are common in fresh water habitats as well.': $i).
% 29.20/29.01  tff(decl_30763, type, dinoflagellate: $i).
% 29.20/29.01  tff(decl_30764, type, fn_dinoflagellate_1: $i > $i).
% 29.20/29.01  tff(decl_30765, type, fn_dinoflagellate_3: $i > $i).
% 29.20/29.01  tff(decl_30766, type, fn_dinoflagellate_4: $i > $i).
% 29.20/29.01  tff(decl_30767, type, fn_dinoflagellate_5: $i > $i).
% 29.20/29.01  tff(decl_30768, type, fn_dinoflagellate_12: $i > $i).
% 29.20/29.01  tff(decl_30769, type, fn_dinoflagellate_13: $i > $i).
% 29.20/29.01  tff(decl_30770, type, fn_dinoflagellate_14: $i > $i).
% 29.20/29.01  tff(decl_30771, type, fn_dinoflagellate_15: $i > $i).
% 29.20/29.01  tff(decl_30772, type, fn_dinoflagellate_16: $i > $i).
% 29.20/29.01  tff(decl_30773, type, fn_dinoflagellate_22: $i > $i).
% 29.20/29.01  tff(decl_30774, type, fn_dinoflagellate_24: $i > $i).
% 29.20/29.01  tff(decl_30775, type, 'Dinosaur': $i).
% 29.20/29.01  tff(decl_30776, type, 'Member of a very diverse clade of reptiles demonstrating a remarkable diversity of morphology and habitat. Most went extinct at the end of the Cretaceous; the only extant dinosaurs are the birds.': $i).
% 29.20/29.01  tff(decl_30777, type, dinosaur: $i).
% 29.20/29.01  tff(decl_30778, type, dinucleotide_1: $i > $o).
% 29.20/29.01  tff(decl_30779, type, 'Dinucleotide': $i).
% 29.20/29.01  tff(decl_30780, type, 'A molecule consisting of two nucleotides connected by their phosphate groups.': $i).
% 29.20/29.01  tff(decl_30781, type, dinucleotide: $i).
% 29.20/29.01  tff(decl_30782, type, dionaea_muscipula_1: $i > $o).
% 29.20/29.01  tff(decl_30783, type, 'Dionaea-Muscipula': $i).
% 29.20/29.01  tff(decl_30784, type, 'Dionaea muscipula, (Venus flytrap) is an insectivorous plant that catches and digests animal prey.': $i).
% 29.20/29.01  tff(decl_30785, type, 'dionaea muscipula': $i).
% 29.20/29.01  tff(decl_30786, type, 'dionaea-muscipula': $i).
% 29.20/29.01  tff(decl_30787, type, fn_dionaea_muscipula_1: $i > $i).
% 29.20/29.01  tff(decl_30788, type, fn_dionaea_muscipula_3: $i > $i).
% 29.20/29.01  tff(decl_30789, type, fn_dionaea_muscipula_4: $i > $i).
% 29.20/29.01  tff(decl_30790, type, fn_dionaea_muscipula_5: $i > $i).
% 29.20/29.01  tff(decl_30791, type, fn_dionaea_muscipula_6: $i > $i).
% 29.20/29.01  tff(decl_30792, type, fn_dionaea_muscipula_7: $i > $i).
% 29.20/29.01  tff(decl_30793, type, fn_dionaea_muscipula_8: $i > $i).
% 29.20/29.01  tff(decl_30794, type, fn_dionaea_muscipula_9: $i > $i).
% 29.20/29.01  tff(decl_30795, type, fn_dionaea_muscipula_10: $i > $i).
% 29.20/29.01  tff(decl_30796, type, fn_dionaea_muscipula_11: $i > $i).
% 29.20/29.01  tff(decl_30797, type, fn_dionaea_muscipula_12: $i > $i).
% 29.20/29.01  tff(decl_30798, type, fn_dionaea_muscipula_13: $i > $i).
% 29.20/29.01  tff(decl_30799, type, fn_dionaea_muscipula_14: $i > $i).
% 29.20/29.01  tff(decl_30800, type, fn_dionaea_muscipula_15: $i > $i).
% 29.20/29.01  tff(decl_30801, type, fn_dionaea_muscipula_16: $i > $i).
% 29.20/29.01  tff(decl_30802, type, fn_shoot_2: $i > $i).
% 29.20/29.01  tff(decl_30803, type, action_0: $i).
% 29.20/29.01  tff(decl_30804, type, 'Dipeptidase': $i).
% 29.20/29.01  tff(decl_30805, type, 'Enzyme produced by the small intestine which hydrolyzes the bond between dipeptides during the chemical digestion of proteins.': $i).
% 29.20/29.01  tff(decl_30806, type, dipeptidase: $i).
% 29.20/29.01  tff(decl_30807, type, 'Diploid-Cell': $i).
% 29.20/29.01  tff(decl_30808, type, 'A diploid cell carries the normal complement of two complementary sets of chromosomes in diploid organims.': $i).
% 29.20/29.01  tff(decl_30809, type, '2n cell': $i).
% 29.20/29.01  tff(decl_30810, type, '2n-cell': $i).
% 29.20/29.01  tff(decl_30811, type, 'cell of diploid': $i).
% 29.20/29.01  tff(decl_30812, type, 'diploid cell': $i).
% 29.20/29.01  tff(decl_30813, type, 'diploid-cell': $i).
% 29.20/29.01  tff(decl_30814, type, fn_diploid_cell_1: $i > $i).
% 29.20/29.01  tff(decl_30815, type, locus_1: $i > $o).
% 29.20/29.01  tff(decl_30816, type, fn_diploid_cell_2: $i > $i).
% 29.20/29.01  tff(decl_30817, type, 'Diploid-Chromosome': $i).
% 29.20/29.01  tff(decl_30818, type, 'Chromosome which consists of two sister chromatids. Diploid chromosomes are produces during the S phase of the cell cycle prior to cell division.': $i).
% 29.20/29.01  tff(decl_30819, type, 'chromosome of diploid': $i).
% 29.20/29.01  tff(decl_30820, type, 'diploid chromosome': $i).
% 29.20/29.01  tff(decl_30821, type, 'diploid-chromosome': $i).
% 29.20/29.01  tff(decl_30822, type, fn_diploid_chromosome_1: $i > $i).
% 29.20/29.01  tff(decl_30823, type, fn_diploid_chromosome_2: $i > $i).
% 29.20/29.01  tff(decl_30824, type, fn_diploid_chromosome_3: $i > $i).
% 29.20/29.01  tff(decl_30825, type, fn_diploid_chromosome_4: $i > $i).
% 29.20/29.01  tff(decl_30826, type, fn_diploid_chromosome_5: $i > $i).
% 29.20/29.01  tff(decl_30827, type, fn_diploid_chromosome_6: $i > $i).
% 29.20/29.01  tff(decl_30828, type, fn_diploid_chromosome_7: $i > $i).
% 29.20/29.01  tff(decl_30829, type, fn_diploid_chromosome_8: $i > $i).
% 29.20/29.01  tff(decl_30830, type, fn_eukaryotic_chromosome_1: $i > $i).
% 29.20/29.01  tff(decl_30831, type, fn_eukaryotic_chromosome_2: $i > $i).
% 29.20/29.01  tff(decl_30832, type, diploid_number_1: $i > $o).
% 29.20/29.01  tff(decl_30833, type, 'Diploid-Number': $i).
% 29.20/29.01  tff(decl_30834, type, 'The number of chromosomes pesent in somatic cells of diploid organisms, abbreviated 2n.': $i).
% 29.20/29.01  tff(decl_30835, type, 'number of diploid': $i).
% 29.20/29.01  tff(decl_30836, type, 'diploid number': $i).
% 29.20/29.01  tff(decl_30837, type, 'diploid-number': $i).
% 29.20/29.01  tff(decl_30838, type, haploid_number_1: $i > $o).
% 29.20/29.01  tff(decl_30839, type, fn_diploid_number_3: $i > $i).
% 29.20/29.01  tff(decl_30840, type, fn_diploid_number_6: $i > $i).
% 29.20/29.01  tff(decl_30841, type, fn_haploid_number_1: $i > $i).
% 29.20/29.01  tff(decl_30842, type, 'Haploid': $i).
% 29.20/29.01  tff(decl_30843, type, 'Diploid': $i).
% 29.20/29.01  tff(decl_30844, type, fn_diploid_number_5: $i > $i).
% 29.20/29.01  tff(decl_30845, type, diploid_organism_1: $i > $o).
% 29.20/29.01  tff(decl_30846, type, 'Diploid-Organism': $i).
% 29.20/29.01  tff(decl_30847, type, 'An organism whose cells contain two homologous chromosomes (2n), one set inherited from each parent.': $i).
% 29.20/29.01  tff(decl_30848, type, 'organism of diploid': $i).
% 29.20/29.01  tff(decl_30849, type, 'diploid organism': $i).
% 29.20/29.01  tff(decl_30850, type, 'diploid-organism': $i).
% 29.20/29.01  tff(decl_30851, type, recombinant_1: $i > $o).
% 29.20/29.01  tff(decl_30852, type, 'Diplomonad': $i).
% 29.20/29.01  tff(decl_30853, type, 'A unicellular protist that has two nuclei and four flagella per cell. Many are parasitic.': $i).
% 29.20/29.01  tff(decl_30854, type, diplomonad: $i).
% 29.20/29.01  tff(decl_30855, type, fn_diplomonad_1: $i > $i).
% 29.20/29.01  tff(decl_30856, type, fn_diplomonad_2: $i > $i).
% 29.20/29.01  tff(decl_30857, type, fn_diplomonad_3: $i > $i).
% 29.20/29.01  tff(decl_30858, type, fn_diplomonad_4: $i > $i).
% 29.20/29.01  tff(decl_30859, type, fn_diplomonad_5: $i > $i).
% 29.20/29.01  tff(decl_30860, type, fn_diplomonad_6: $i > $i).
% 29.20/29.01  tff(decl_30861, type, fn_diplomonad_7: $i > $i).
% 29.20/29.01  tff(decl_30862, type, fn_diplomonad_8: $i > $i).
% 29.20/29.01  tff(decl_30863, type, fn_diplomonad_9: $i > $i).
% 29.20/29.01  tff(decl_30864, type, fn_diplomonad_10: $i > $i).
% 29.20/29.01  tff(decl_30865, type, fn_diplomonad_11: $i > $i).
% 29.20/29.01  tff(decl_30866, type, fn_diplomonad_12: $i > $i).
% 29.20/29.01  tff(decl_30867, type, fn_diplomonad_13: $i > $i).
% 29.20/29.01  tff(decl_30868, type, fn_diplomonad_14: $i > $i).
% 29.20/29.01  tff(decl_30869, type, fn_diplomonad_15: $i > $i).
% 29.20/29.01  tff(decl_30870, type, fn_diplomonad_16: $i > $i).
% 29.20/29.01  tff(decl_30871, type, fn_diplomonad_17: $i > $i).
% 29.20/29.01  tff(decl_30872, type, fn_diplomonad_18: $i > $i).
% 29.20/29.01  tff(decl_30873, type, fn_diplomonad_19: $i > $i).
% 29.20/29.01  tff(decl_30874, type, fn_diplomonad_20: $i > $i).
% 29.20/29.01  tff(decl_30875, type, fn_diplomonad_21: $i > $i).
% 29.20/29.01  tff(decl_30876, type, fn_diplomonad_22: $i > $i).
% 29.20/29.01  tff(decl_30877, type, fn_diplomonad_23: $i > $i).
% 29.20/29.01  tff(decl_30878, type, fn_diplomonad_24: $i > $i).
% 29.20/29.01  tff(decl_30879, type, fn_diplomonad_29: $i > $i).
% 29.20/29.01  tff(decl_30880, type, fn_diplomonad_30: $i > $i).
% 29.20/29.01  tff(decl_30881, type, fn_diplomonad_31: $i > $i).
% 29.20/29.01  tff(decl_30882, type, fn_golgi_apparatus_88: $i > $i).
% 29.20/29.01  tff(decl_30883, type, fn_golgi_apparatus_89: $i > $i).
% 29.20/29.01  tff(decl_30884, type, fn_golgi_apparatus_92: $i > $i).
% 29.20/29.01  tff(decl_30885, type, fn_golgi_apparatus_82: $i > $i).
% 29.20/29.01  tff(decl_30886, type, fn_diplomonad_28: $i > $i).
% 29.20/29.01  tff(decl_30887, type, fn_diplomonad_27: $i > $i).
% 29.20/29.01  tff(decl_30888, type, fn_diplomonad_25: $i > $i).
% 29.20/29.01  tff(decl_30889, type, fn_diplomonad_26: $i > $i).
% 29.20/29.01  tff(decl_30890, type, 'Diplopode': $i).
% 29.20/29.01  tff(decl_30891, type, 'Member of an arthropod taxon characterized by a conspicuously segmented body, with each segment bearing two pairs of legs; for example, millipedes.': $i).
% 29.20/29.01  tff(decl_30892, type, millipede: $i).
% 29.20/29.01  tff(decl_30893, type, diplopode: $i).
% 29.20/29.01  tff(decl_30894, type, dipole_dipole_interaction_1: $i > $o).
% 29.20/29.01  tff(decl_30895, type, 'Dipole-Dipole-Interaction': $i).
% 29.20/29.01  tff(decl_30896, type, 'A weak, attractive force between two polar molecules in close proximity to each other. The positive end of one polar molecule is attracted to the negative end of another polar molecule.': $i).
% 29.20/29.01  tff(decl_30897, type, 'dipole dipole interaction': $i).
% 29.20/29.01  tff(decl_30898, type, 'dipole-dipole-interaction': $i).
% 29.20/29.01  tff(decl_30899, type, weak_interaction_1: $i > $o).
% 29.20/29.01  tff(decl_30900, type, 'Diptera': $i).
% 29.20/29.01  tff(decl_30901, type, 'An order of insects that possesses two pairs of wings, including flies and mosquitos.': $i).
% 29.20/29.01  tff(decl_30902, type, diptera: $i).
% 29.20/29.01  tff(decl_30903, type, direct_repeats_1: $i > $o).
% 29.20/29.01  tff(decl_30904, type, 'Direct-Repeats': $i).
% 29.20/29.01  tff(decl_30905, type, 'Genetic sequences consisting of a specific sequence repeated at least twice.': $i).
% 29.20/29.01  tff(decl_30906, type, 'direct repeats': $i).
% 29.20/29.01  tff(decl_30907, type, 'direct repeat': $i).
% 29.20/29.01  tff(decl_30908, type, 'direct-repeat': $i).
% 29.20/29.01  tff(decl_30909, type, fn_directed_motion_1: $i > $i).
% 29.20/29.01  tff(decl_30910, type, 'Directed-Motion': $i).
% 29.20/29.01  tff(decl_30911, type, 'The movement has a specific direction.': $i).
% 29.20/29.01  tff(decl_30912, type, 'directed motion': $i).
% 29.20/29.01  tff(decl_30913, type, 'directed-motion': $i).
% 29.20/29.01  tff(decl_30914, type, 'Direction-Constant': $i).
% 29.20/29.01  tff(decl_30915, type, 'constant of direction': $i).
% 29.20/29.01  tff(decl_30916, type, 'direction constant': $i).
% 29.20/29.01  tff(decl_30917, type, 'direction-constant': $i).
% 29.20/29.01  tff(decl_30918, type, direction_scale_1: $i > $o).
% 29.20/29.01  tff(decl_30919, type, 'Direction-Scale': $i).
% 29.20/29.01  tff(decl_30920, type, 'scale of direction': $i).
% 29.20/29.01  tff(decl_30921, type, 'direction scale': $i).
% 29.20/29.01  tff(decl_30922, type, 'direction-scale': $i).
% 29.20/29.01  tff(decl_30923, type, 'Directional-Selection': $i).
% 29.20/29.01  tff(decl_30924, type, 'Natural selection in which a single phenotype is favored, which causes the overall mean value for the phenotypic range to shift in one direction.': $i).
% 29.20/29.01  tff(decl_30925, type, 'directional selection': $i).
% 29.20/29.01  tff(decl_30926, type, 'directional-selection': $i).
% 29.20/29.01  tff(decl_30927, type, 'Disaccharidase': $i).
% 29.20/29.01  tff(decl_30928, type, 'Enzyme which catalyzes the hydrolysis od disaccharides into monosaccharides.': $i).
% 29.20/29.01  tff(decl_30929, type, disaccharidase: $i).
% 29.20/29.01  tff(decl_30930, type, 'Disaccharide': $i).
% 29.20/29.01  tff(decl_30931, type, 'Disaccharides are made of two monosaccharides; for example, sucrose, table sugar, is made of the monosaccharides glucose and fructose.': $i).
% 29.20/29.01  tff(decl_30932, type, 'di saccharide': $i).
% 29.20/29.01  tff(decl_30933, type, 'di-saccharide': $i).
% 29.20/29.01  tff(decl_30934, type, disaccharide: $i).
% 29.20/29.01  tff(decl_30935, type, fn_disaccharide_1: $i > $i).
% 29.20/29.01  tff(decl_30936, type, fn_disaccharide_2: $i > $i).
% 29.20/29.01  tff(decl_30937, type, fn_disaccharide_3: $i > $i).
% 29.20/29.01  tff(decl_30938, type, fn_disaccharide_4: $i > $i).
% 29.20/29.01  tff(decl_30939, type, fn_disaccharide_5: $i > $i).
% 29.20/29.01  tff(decl_30940, type, fn_disaccharide_6: $i > $i).
% 29.20/29.01  tff(decl_30941, type, fn_disaccharide_8: $i > $i).
% 29.20/29.01  tff(decl_30942, type, fn_disaccharide_9: $i > $i).
% 29.20/29.01  tff(decl_30943, type, fn_disaccharide_10: $i > $i).
% 29.20/29.01  tff(decl_30944, type, fn_disaccharide_11: $i > $i).
% 29.20/29.01  tff(decl_30945, type, fn_disaccharide_12: $i > $i).
% 29.20/29.01  tff(decl_30946, type, fn_disaccharide_16: $i > $i).
% 29.20/29.01  tff(decl_30947, type, fn_disaccharide_17: $i > $i).
% 29.20/29.01  tff(decl_30948, type, fn_disaccharide_18: $i > $i).
% 29.20/29.01  tff(decl_30949, type, fn_disaccharide_19: $i > $i).
% 29.20/29.01  tff(decl_30950, type, fn_disaccharide_20: $i > $i).
% 29.20/29.01  tff(decl_30951, type, fn_disaccharide_21: $i > $i).
% 29.20/29.01  tff(decl_30952, type, fn_disaccharide_22: $i > $i).
% 29.20/29.01  tff(decl_30953, type, fn_disaccharide_23: $i > $i).
% 29.20/29.01  tff(decl_30954, type, fn_disaccharide_24: $i > $i).
% 29.20/29.01  tff(decl_30955, type, fn_disaccharide_25: $i > $i).
% 29.20/29.01  tff(decl_30956, type, fn_disaccharide_26: $i > $i).
% 29.20/29.01  tff(decl_30957, type, fn_disaccharide_27: $i > $i).
% 29.20/29.01  tff(decl_30958, type, fn_disaccharide_28: $i > $i).
% 29.20/29.01  tff(decl_30959, type, fn_disaccharide_29: $i > $i).
% 29.20/29.01  tff(decl_30960, type, fn_disaccharide_30: $i > $i).
% 29.20/29.01  tff(decl_30961, type, fn_disaccharide_31: $i > $i).
% 29.20/29.01  tff(decl_30962, type, fn_disaccharide_35: $i > $i).
% 29.20/29.01  tff(decl_30963, type, fn_disaccharide_36: $i > $i).
% 29.20/29.01  tff(decl_30964, type, fn_disaccharide_37: $i > $i).
% 29.20/29.01  tff(decl_30965, type, fn_disaccharide_38: $i > $i).
% 29.20/29.01  tff(decl_30966, type, fn_disaccharide_39: $i > $i).
% 29.20/29.01  tff(decl_30967, type, fn_disaccharide_40: $i > $i).
% 29.20/29.01  tff(decl_30968, type, fn_disaccharide_41: $i > $i).
% 29.20/29.01  tff(decl_30969, type, fn_disaccharide_42: $i > $i).
% 29.20/29.01  tff(decl_30970, type, fn_disaccharide_43: $i > $i).
% 29.20/29.01  tff(decl_30971, type, fn_disaccharide_44: $i > $i).
% 29.20/29.01  tff(decl_30972, type, fn_disaccharide_45: $i > $i).
% 29.20/29.01  tff(decl_30973, type, fn_disaccharide_46: $i > $i).
% 29.20/29.01  tff(decl_30974, type, fn_disaccharide_47: $i > $i).
% 29.20/29.01  tff(decl_30975, type, fn_disaccharide_48: $i > $i).
% 29.20/29.01  tff(decl_30976, type, monosaccharide_0: $i).
% 29.20/29.01  tff(decl_30977, type, carbohydrate_0: $i).
% 29.20/29.01  tff(decl_30978, type, fn_disaccharide_15: $i > $i).
% 29.20/29.01  tff(decl_30979, type, fn_disaccharide_49: $i > $i).
% 29.20/29.01  tff(decl_30980, type, fn_disaccharide_50: $i > $i).
% 29.20/29.01  tff(decl_30981, type, fn_disaccharide_51: $i > $i).
% 29.20/29.01  tff(decl_30982, type, fn_disaccharide_52: $i > $i).
% 29.20/29.01  tff(decl_30983, type, disappear_1: $i > $o).
% 29.20/29.01  tff(decl_30984, type, 'Disappear': $i).
% 29.20/29.01  tff(decl_30985, type, 'To become invisible or unnoticeable.': $i).
% 29.20/29.01  tff(decl_30986, type, discourse_1: $i > $o).
% 29.20/29.01  tff(decl_30987, type, 'Discourse': $i).
% 29.20/29.01  tff(decl_30988, type, 'a communicative exchange': $i).
% 29.20/29.01  tff(decl_30989, type, discourse: $i).
% 29.20/29.01  tff(decl_30990, type, session_1: $i > $o).
% 29.20/29.01  tff(decl_30991, type, discussion_1: $i > $o).
% 29.20/29.01  tff(decl_30992, type, discovery_1: $i > $o).
% 29.20/29.01  tff(decl_30993, type, 'Discovery': $i).
% 29.20/29.01  tff(decl_30994, type, discover: $i).
% 29.20/29.01  tff(decl_30995, type, discovery: $i).
% 29.20/29.01  tff(decl_30996, type, find: $i).
% 29.20/29.01  tff(decl_30997, type, uncovering: $i).
% 29.20/29.01  tff(decl_30998, type, discovery_science_1: $i > $o).
% 29.20/29.01  tff(decl_30999, type, 'Discovery-Science': $i).
% 29.20/29.01  tff(decl_31000, type, 'The process of scientific inquiry that focuses on describing nature.': $i).
% 29.20/29.01  tff(decl_31001, type, 'science of discovery': $i).
% 29.20/29.01  tff(decl_31002, type, 'discovery science': $i).
% 29.20/29.01  tff(decl_31003, type, 'discovery-science': $i).
% 29.20/29.01  tff(decl_31004, type, science_as_process_1: $i > $o).
% 29.20/29.01  tff(decl_31005, type, discrete_character_1: $i > $o).
% 29.20/29.01  tff(decl_31006, type, 'Discrete-Character': $i).
% 29.20/29.01  tff(decl_31007, type, 'A trait that can be classified on an either-or basis, usually because it is determined by a single gene locus with different alleles that affect distinct phenotypes.': $i).
% 29.20/29.01  tff(decl_31008, type, 'discrete character': $i).
% 29.20/29.01  tff(decl_31009, type, 'discrete-character': $i).
% 29.20/29.01  tff(decl_31010, type, 'Discussion': $i).
% 29.20/29.01  tff(decl_31011, type, 'a discourse between two or more conversants with free-flowing dialog on a particular topic or topics': $i).
% 29.20/29.01  tff(decl_31012, type, discussion: $i).
% 29.20/29.01  tff(decl_31013, type, treatment: $i).
% 29.20/29.01  tff(decl_31014, type, 'give and take': $i).
% 29.20/29.01  tff(decl_31015, type, 'give-and-take': $i).
% 29.20/29.01  tff(decl_31016, type, word: $i).
% 29.20/29.01  tff(decl_31017, type, discuss: $i).
% 29.20/29.01  tff(decl_31018, type, 'Disease': $i).
% 29.20/29.01  tff(decl_31019, type, 'An abnormal condition that causes improper function in the body of an organism.': $i).
% 29.20/29.01  tff(decl_31020, type, disorder: $i).
% 29.20/29.01  tff(decl_31021, type, illness: $i).
% 29.20/29.01  tff(decl_31022, type, disease: $i).
% 29.20/29.01  tff(decl_31023, type, 'Disease-Process': $i).
% 29.20/29.01  tff(decl_31024, type, 'Process related to the progression of a disease.': $i).
% 29.20/29.01  tff(decl_31025, type, 'process of disease': $i).
% 29.20/29.01  tff(decl_31026, type, 'disease process': $i).
% 29.20/29.01  tff(decl_31027, type, 'disease-process': $i).
% 29.20/29.01  tff(decl_31028, type, dispersal_1: $i > $o).
% 29.20/29.01  tff(decl_31029, type, 'Dispersal': $i).
% 29.20/29.01  tff(decl_31030, type, 'Movement of individuals or gametes away from their parental population. Dispersal allows individuals to colonize new areas and can result in expanded geographic ranges.': $i).
% 29.20/29.01  tff(decl_31031, type, disperse: $i).
% 29.20/29.01  tff(decl_31032, type, dispersal: $i).
% 29.20/29.01  tff(decl_31033, type, dispersion_1: $i > $o).
% 29.20/29.01  tff(decl_31034, type, disperse_1: $i > $o).
% 29.20/29.01  tff(decl_31035, type, 'Disperse': $i).
% 29.20/29.01  tff(decl_31036, type, 'break up': $i).
% 29.20/29.01  tff(decl_31037, type, break_up: $i).
% 29.20/29.01  tff(decl_31038, type, dispel: $i).
% 29.20/29.01  tff(decl_31039, type, dissipate: $i).
% 29.20/29.01  tff(decl_31040, type, scatter: $i).
% 29.20/29.01  tff(decl_31041, type, 'spread out': $i).
% 29.20/29.01  tff(decl_31042, type, spread_out: $i).
% 29.20/29.01  tff(decl_31043, type, fn_disperse_1: $i > $i).
% 29.20/29.01  tff(decl_31044, type, fn_disperse_2: $i > $i).
% 29.20/29.01  tff(decl_31045, type, fn_disperse_3: $i > $i).
% 29.20/29.01  tff(decl_31046, type, 'Dispersion': $i).
% 29.20/29.01  tff(decl_31047, type, 'The pattern of distribution of individuals within a defined geographic space.': $i).
% 29.20/29.01  tff(decl_31048, type, dispersion: $i).
% 29.20/29.01  tff(decl_31049, type, dispersive_model_1: $i > $o).
% 29.20/29.01  tff(decl_31050, type, 'Dispersive-model': $i).
% 29.20/29.01  tff(decl_31051, type, 'Dispersive replication would produce two DNA molecules with sections of both old and new DNA interspersed along each strand': $i).
% 29.20/29.01  tff(decl_31052, type, 'dispersive model': $i).
% 29.20/29.01  tff(decl_31053, type, 'dispersive-model': $i).
% 29.20/29.01  tff(decl_31054, type, fn_dispersive_model_1: $i > $i).
% 29.20/29.01  tff(decl_31055, type, fn_dispersive_model_2: $i > $i).
% 29.20/29.01  tff(decl_31056, type, fn_dispersive_model_3: $i > $i).
% 29.20/29.01  tff(decl_31057, type, fn_dispersive_model_4: $i > $i).
% 29.20/29.01  tff(decl_31058, type, fn_dispersive_model_5: $i > $i).
% 29.20/29.01  tff(decl_31059, type, 'Disruptive-Selection': $i).
% 29.20/29.01  tff(decl_31060, type, 'Natural selection in which individuals with intermediate phenotypes are selected against. As a result, individuals on both extremes of a phenotypic range are favored.': $i).
% 29.20/29.01  tff(decl_31061, type, 'disruptive selection': $i).
% 29.20/29.01  tff(decl_31062, type, 'disruptive-selection': $i).
% 29.20/29.01  tff(decl_31063, type, dissolution_of_salt_molecule_in_water_1: $i > $o).
% 29.20/29.01  tff(decl_31064, type, 'Dissolution-Of-Salt-Molecule-In-Water': $i).
% 29.20/29.01  tff(decl_31065, type, 'Dissolving an ionic compound (salt).  The component ions of the compound separate in solution to form ions.': $i).
% 29.20/29.01  tff(decl_31066, type, 'dissolving of salt in water': $i).
% 29.20/29.01  tff(decl_31067, type, dissolve: $i).
% 29.20/29.01  tff(decl_31068, type, 'dissolution of salt molecule in water': $i).
% 29.20/29.01  tff(decl_31069, type, 'dissolution-of-salt-molecule-in-water': $i).
% 29.20/29.01  tff(decl_31070, type, fn_dissolution_of_salt_molecule_in_water_1: $i > $i).
% 29.20/29.01  tff(decl_31071, type, fn_dissolution_of_salt_molecule_in_water_2: $i > $i).
% 29.20/29.01  tff(decl_31072, type, fn_dissolution_of_salt_molecule_in_water_3: $i > $i).
% 29.20/29.01  tff(decl_31073, type, fn_dissolution_of_salt_molecule_in_water_4: $i > $i).
% 29.20/29.01  tff(decl_31074, type, fn_dissolution_of_salt_molecule_in_water_5: $i > $i).
% 29.20/29.01  tff(decl_31075, type, fn_dissolution_of_salt_molecule_in_water_6: $i > $i).
% 29.20/29.01  tff(decl_31076, type, fn_dissolution_of_salt_molecule_in_water_7: $i > $i).
% 29.20/29.01  tff(decl_31077, type, fn_dissolve_1: $i > $i).
% 29.20/29.01  tff(decl_31078, type, fn_dissolve_3: $i > $i).
% 29.20/29.01  tff(decl_31079, type, fn_dissolve_6: $i > $i).
% 29.20/29.01  tff(decl_31080, type, fn_dissolve_7: $i > $i).
% 29.20/29.01  tff(decl_31081, type, dissolution_of_sugar_molecule_in_water_1: $i > $o).
% 29.20/29.01  tff(decl_31082, type, 'Dissolution-Of-Sugar-Molecule-In-Water': $i).
% 29.20/29.01  tff(decl_31083, type, 'The dissolving of sugar molecules.': $i).
% 29.20/29.01  tff(decl_31084, type, 'dissolving of sugar in water': $i).
% 29.20/29.01  tff(decl_31085, type, 'dissolution of sugar molecule in water': $i).
% 29.20/29.01  tff(decl_31086, type, 'dissolution-of-sugar-molecule-in-water': $i).
% 29.20/29.01  tff(decl_31087, type, fn_dissolution_of_sugar_molecule_in_water_1: $i > $i).
% 29.20/29.01  tff(decl_31088, type, fn_dissolution_of_sugar_molecule_in_water_2: $i > $i).
% 29.20/29.01  tff(decl_31089, type, fn_dissolution_of_sugar_molecule_in_water_3: $i > $i).
% 29.20/29.01  tff(decl_31090, type, sugar_substance_1: $i > $o).
% 29.20/29.01  tff(decl_31091, type, fn_dissolution_of_sugar_molecule_in_water_4: $i > $i).
% 29.20/29.01  tff(decl_31092, type, sugar_solution_1: $i > $o).
% 29.20/29.01  tff(decl_31093, type, fn_dissolution_of_sugar_molecule_in_water_5: $i > $i).
% 29.20/29.01  tff(decl_31094, type, 'Dissolve': $i).
% 29.20/29.01  tff(decl_31095, type, 'A dissolve event creates a solution from two substances.': $i).
% 29.20/29.01  tff(decl_31096, type, fn_dissolve_2: $i > $i).
% 29.20/29.01  tff(decl_31097, type, distal_1: $i > $o).
% 29.22/29.01  tff(decl_31098, type, 'Distal': $i).
% 29.22/29.01  tff(decl_31099, type, 'Region of appendages farthest away from the trunk or core of the body.  Opposite of proximal.': $i).
% 29.22/29.01  tff(decl_31100, type, distal: $i).
% 29.22/29.01  tff(decl_31101, type, 'Distal-Tubule': $i).
% 29.22/29.01  tff(decl_31102, type, 'The portion of a nephron between the loop of Henle and the collecting duct.': $i).
% 29.22/29.01  tff(decl_31103, type, dct: $i).
% 29.22/29.01  tff(decl_31104, type, 'distal convoluted tubule': $i).
% 29.22/29.01  tff(decl_31105, type, 'distal-convoluted-tubule': $i).
% 29.22/29.01  tff(decl_31106, type, 'tubule of distal': $i).
% 29.22/29.01  tff(decl_31107, type, 'distal tubule': $i).
% 29.22/29.01  tff(decl_31108, type, 'distal-tubule': $i).
% 29.22/29.01  tff(decl_31109, type, tubule_1: $i > $o).
% 29.22/29.01  tff(decl_31110, type, labia_minora_1: $i > $o).
% 29.22/29.01  tff(decl_31111, type, loop_of_henle_1: $i > $o).
% 29.22/29.01  tff(decl_31112, type, 'Distance-Between-Genes': $i).
% 29.22/29.01  tff(decl_31113, type, 'Relative distance between genes.': $i).
% 29.22/29.01  tff(decl_31114, type, 'distance between gene': $i).
% 29.22/29.01  tff(decl_31115, type, 'distance-between-gene': $i).
% 29.22/29.01  tff(decl_31116, type, 'Distance-Constant': $i).
% 29.22/29.01  tff(decl_31117, type, 'constant of distance': $i).
% 29.22/29.01  tff(decl_31118, type, 'distance constant': $i).
% 29.22/29.01  tff(decl_31119, type, 'distance-constant': $i).
% 29.22/29.01  tff(decl_31120, type, distance_scale_1: $i > $o).
% 29.22/29.01  tff(decl_31121, type, 'Distance-Scale': $i).
% 29.22/29.01  tff(decl_31122, type, 'scale of distance': $i).
% 29.22/29.01  tff(decl_31123, type, 'distance scale': $i).
% 29.22/29.01  tff(decl_31124, type, 'distance-scale': $i).
% 29.22/29.01  tff(decl_31125, type, distilled_water_1: $i > $o).
% 29.22/29.01  tff(decl_31126, type, 'Distilled-Water': $i).
% 29.22/29.01  tff(decl_31127, type, 'Water that is been boiled to steam and condensed into a clean container to remove impurities.': $i).
% 29.22/29.01  tff(decl_31128, type, 'distilled water': $i).
% 29.22/29.01  tff(decl_31129, type, 'distilled-water': $i).
% 29.22/29.01  tff(decl_31130, type, 'Distinguishing': $i).
% 29.22/29.01  tff(decl_31131, type, 'Determine the difference between things, in order to recognize, identify, or classify them': $i).
% 29.22/29.01  tff(decl_31132, type, distinguish: $i).
% 29.22/29.01  tff(decl_31133, type, mark: $i).
% 29.22/29.01  tff(decl_31134, type, identify: $i).
% 29.22/29.01  tff(decl_31135, type, distinction: $i).
% 29.22/29.01  tff(decl_31136, type, distinguishing: $i).
% 29.22/29.01  tff(decl_31137, type, 'Distinguishing-Defective-Chromosome': $i).
% 29.22/29.01  tff(decl_31138, type, 'An act to identify defective chromosome by means of karyotyping.': $i).
% 29.22/29.01  tff(decl_31139, type, 'distinguishing defective chromosome': $i).
% 29.22/29.01  tff(decl_31140, type, 'distinguishing-defective-chromosome': $i).
% 29.22/29.01  tff(decl_31141, type, fn_distinguishing_defective_chromosome_1: $i > $i).
% 29.22/29.01  tff(decl_31142, type, fn_distinguishing_defective_chromosome_2: $i > $i).
% 29.22/29.01  tff(decl_31143, type, fn_distinguishing_defective_chromosome_3: $i > $i).
% 29.22/29.01  tff(decl_31144, type, karyotyping_1: $i > $o).
% 29.22/29.01  tff(decl_31145, type, 'Distributing': $i).
% 29.22/29.01  tff(decl_31146, type, distribute: $i).
% 29.22/29.01  tff(decl_31147, type, spread: $i).
% 29.22/29.01  tff(decl_31148, type, distribution: $i).
% 29.22/29.01  tff(decl_31149, type, distributing: $i).
% 29.22/29.01  tff(decl_31150, type, 'Distribution-Of-Daughter-Chromosomes': $i).
% 29.22/29.01  tff(decl_31151, type, 'During mitosis, the process in which microtubule shortening in the spindle moves each complete set of chromosomes to opposite cell poles prior to cytokinesis.': $i).
% 29.22/29.01  tff(decl_31152, type, 'distribution of daughter chromosome': $i).
% 29.22/29.01  tff(decl_31153, type, 'distribution-of-daughter-chromosome': $i).
% 29.22/29.01  tff(decl_31154, type, fn_distribution_of_daughter_chromosomes_1: $i > $i).
% 29.22/29.01  tff(decl_31155, type, fn_distribution_of_daughter_chromosomes_2: $i > $i).
% 29.22/29.01  tff(decl_31156, type, fn_distribution_of_daughter_chromosomes_3: $i > $i).
% 29.22/29.01  tff(decl_31157, type, fn_distribution_of_daughter_chromosomes_4: $i > $i).
% 29.22/29.01  tff(decl_31158, type, fn_distribution_of_daughter_chromosomes_5: $i > $i).
% 29.22/29.01  tff(decl_31159, type, fn_distribution_of_daughter_chromosomes_6: $i > $i).
% 29.22/29.01  tff(decl_31160, type, fn_distribution_of_daughter_chromosomes_7: $i > $i).
% 29.22/29.01  tff(decl_31161, type, fn_distribution_of_daughter_chromosomes_8: $i > $i).
% 29.22/29.01  tff(decl_31162, type, fn_distribution_of_daughter_chromosomes_9: $i > $i).
% 29.22/29.01  tff(decl_31163, type, fn_distribution_of_daughter_chromosomes_10: $i > $i).
% 29.22/29.01  tff(decl_31164, type, fn_distribution_of_daughter_chromosomes_11: $i > $i).
% 29.22/29.01  tff(decl_31165, type, fn_distribution_of_daughter_chromosomes_12: $i > $i).
% 29.22/29.01  tff(decl_31166, type, fn_distribution_of_daughter_chromosomes_13: $i > $i).
% 29.22/29.01  tff(decl_31167, type, fn_distribution_of_daughter_chromosomes_14: $i > $i).
% 29.22/29.01  tff(decl_31168, type, fn_distribution_of_daughter_chromosomes_15: $i > $i).
% 29.22/29.01  tff(decl_31169, type, fn_distribution_of_daughter_chromosomes_16: $i > $i).
% 29.22/29.01  tff(decl_31170, type, fn_distribution_of_daughter_chromosomes_17: $i > $i).
% 29.22/29.01  tff(decl_31171, type, fn_distribution_of_daughter_chromosomes_18: $i > $i).
% 29.22/29.01  tff(decl_31172, type, fn_distribution_of_daughter_chromosomes_19: $i > $i).
% 29.22/29.01  tff(decl_31173, type, fn_distribution_of_daughter_chromosomes_20: $i > $i).
% 29.22/29.01  tff(decl_31174, type, fn_distribution_of_daughter_chromosomes_21: $i > $i).
% 29.22/29.01  tff(decl_31175, type, fn_distribution_of_daughter_chromosomes_22: $i > $i).
% 29.22/29.01  tff(decl_31176, type, fn_microtubule_shortening_3: $i > $i).
% 29.22/29.01  tff(decl_31177, type, fn_microtubule_shortening_4: $i > $i).
% 29.22/29.01  tff(decl_31178, type, fn_kinetochore_24: $i > $i).
% 29.22/29.01  tff(decl_31179, type, fn_microtubule_shortening_2: $i > $i).
% 29.22/29.01  tff(decl_31180, type, disturbance_1: $i > $o).
% 29.22/29.01  tff(decl_31181, type, 'Disturbance': $i).
% 29.22/29.01  tff(decl_31182, type, 'A temporary perturbation away from average environmental conditions that causes  major change in the biological makeup of an ecosystem. Examples include fire, flood, and insect outbreaks.': $i).
% 29.22/29.01  tff(decl_31183, type, disturb: $i).
% 29.22/29.01  tff(decl_31184, type, disturbance: $i).
% 29.22/29.01  tff(decl_31185, type, 'Disulfide-Bond': $i).
% 29.22/29.01  tff(decl_31186, type, 'The disulfide bond is a covalent bond, usually derived by the coupling of two thiol groups. The linkage is also called an SS-bond or disulfide bridge.': $i).
% 29.22/29.01  tff(decl_31187, type, 'disulfide bridge': $i).
% 29.22/29.01  tff(decl_31188, type, 'disulfide-bridge': $i).
% 29.22/29.01  tff(decl_31189, type, 'disulphide bond': $i).
% 29.22/29.01  tff(decl_31190, type, 'disulphide bridge': $i).
% 29.22/29.01  tff(decl_31191, type, 'disulphide-bridge': $i).
% 29.22/29.01  tff(decl_31192, type, 'disulfide bond': $i).
% 29.22/29.01  tff(decl_31193, type, 'disulfide-bond': $i).
% 29.22/29.01  tff(decl_31194, type, fn_disulfide_bond_1: $i > $i).
% 29.22/29.01  tff(decl_31195, type, fn_disulfide_bond_2: $i > $i).
% 29.22/29.01  tff(decl_31196, type, fn_disulfide_bond_4: $i > $i).
% 29.22/29.01  tff(decl_31197, type, fn_disulfide_bond_5: $i > $i).
% 29.22/29.01  tff(decl_31198, type, fn_disulfide_bond_6: $i > $i).
% 29.22/29.01  tff(decl_31199, type, fn_disulfide_bond_7: $i > $i).
% 29.22/29.01  tff(decl_31200, type, fn_disulfide_bond_8: $i > $i).
% 29.22/29.01  tff(decl_31201, type, 'Diurnal-Closing-of-Stoma': $i).
% 29.22/29.01  tff(decl_31202, type, 'Stomata are openings in a plant\\s leaves that allow for gas exchange between the plant and the atmosphere.  The plants close their stomata daily in response to light, carbon dioxide depletion, and an internal clock in guard cells.': $i).
% 29.22/29.01  tff(decl_31203, type, 'closing of stomata at night': $i).
% 29.22/29.01  tff(decl_31204, type, 'stoma closing at night': $i).
% 29.22/29.01  tff(decl_31205, type, 'stoma opening during day': $i).
% 29.22/29.01  tff(decl_31206, type, 'close diurnally': $i).
% 29.22/29.01  tff(decl_31207, type, 'diurnal closing of stoma': $i).
% 29.22/29.01  tff(decl_31208, type, 'diurnal-closing-of-stoma': $i).
% 29.22/29.01  tff(decl_31209, type, dive_1: $i > $o).
% 29.22/29.01  tff(decl_31210, type, 'Dive': $i).
% 29.22/29.01  tff(decl_31211, type, dive: $i).
% 29.22/29.01  tff(decl_31212, type, let_fall_1: $i > $o).
% 29.22/29.01  tff(decl_31213, type, fn_dive_1: $i > $i).
% 29.22/29.01  tff(decl_31214, type, fn_dive_2: $i > $i).
% 29.22/29.01  tff(decl_31215, type, propel_1: $i > $o).
% 29.22/29.01  tff(decl_31216, type, fn_let_fall_3: $i > $i).
% 29.22/29.01  tff(decl_31217, type, fn_let_fall_1: $i > $i).
% 29.22/29.01  tff(decl_31218, type, 'Divide': $i).
% 29.22/29.01  tff(decl_31219, type, 'carve up': $i).
% 29.22/29.01  tff(decl_31220, type, carve_up: $i).
% 29.22/29.01  tff(decl_31221, type, dissever: $i).
% 29.22/29.01  tff(decl_31222, type, split: $i).
% 29.22/29.01  tff(decl_31223, type, 'split up': $i).
% 29.22/29.01  tff(decl_31224, type, split_up: $i).
% 29.22/29.01  tff(decl_31225, type, dividing_eukaryotic_cell_1: $i > $o).
% 29.22/29.01  tff(decl_31226, type, 'Dividing-Eukaryotic-Cell': $i).
% 29.22/29.01  tff(decl_31227, type, 'A eukaryotic cell that is involved in the process of mitosis or meiosis.': $i).
% 29.22/29.01  tff(decl_31228, type, 'eukaryotic cell undergoing cell division': $i).
% 29.22/29.01  tff(decl_31229, type, 'eukaryotic-cell-undergoing-cell division': $i).
% 29.22/29.01  tff(decl_31230, type, 'dividing eukaryotic cell': $i).
% 29.22/29.01  tff(decl_31231, type, 'dividing-eukaryotic-cell': $i).
% 29.22/29.01  tff(decl_31232, type, 'DNA': $i).
% 29.22/29.01  tff(decl_31233, type, 'The molecule that encodes genetic instructions for the development and function of living organisms. It takes the shape of a double-stranded helix, each strand consisting of a series of nucleotide monomers. The nucleotide monomers contain a deoxyribose sugar and one of four nitrogenous bases: adenine (A), guanine (G), cytosine (C), or thymine (T).': $i).
% 29.22/29.01  tff(decl_31234, type, 'deoxyribonucleic acid': $i).
% 29.22/29.01  tff(decl_31235, type, 'deoxy ribonucleic acid': $i).
% 29.22/29.01  tff(decl_31236, type, 'deoxy-ribonucleic acid': $i).
% 29.22/29.01  tff(decl_31237, type, 'dna molecule': $i).
% 29.22/29.01  tff(decl_31238, type, 'dna-molecule': $i).
% 29.22/29.01  tff(decl_31239, type, 'genetic material': $i).
% 29.22/29.01  tff(decl_31240, type, 'genetic-material': $i).
% 29.22/29.01  tff(decl_31241, type, 'dna double helix': $i).
% 29.22/29.01  tff(decl_31242, type, 'dna-double-helix': $i).
% 29.22/29.01  tff(decl_31243, type, 'double helical dna': $i).
% 29.22/29.01  tff(decl_31244, type, 'double-helical-dna': $i).
% 29.22/29.01  tff(decl_31245, type, 'deoxyribonucleic-acid': $i).
% 29.22/29.01  tff(decl_31246, type, dna: $i).
% 29.22/29.01  tff(decl_31247, type, fn_dna_1: $i > $i).
% 29.22/29.01  tff(decl_31248, type, fn_dna_3: $i > $i).
% 29.22/29.01  tff(decl_31249, type, fn_dna_4: $i > $i).
% 29.22/29.01  tff(decl_31250, type, fn_dna_5: $i > $i).
% 29.22/29.01  tff(decl_31251, type, fn_dna_6: $i > $i).
% 29.22/29.01  tff(decl_31252, type, fn_dna_7: $i > $i).
% 29.22/29.01  tff(decl_31253, type, fn_dna_8: $i > $i).
% 29.22/29.01  tff(decl_31254, type, fn_dna_9: $i > $i).
% 29.22/29.01  tff(decl_31255, type, fn_dna_10: $i > $i).
% 29.22/29.01  tff(decl_31256, type, fn_dna_12: $i > $i).
% 29.22/29.01  tff(decl_31257, type, fn_dna_13: $i > $i).
% 29.22/29.01  tff(decl_31258, type, fn_dna_14: $i > $i).
% 29.22/29.01  tff(decl_31259, type, fn_dna_15: $i > $i).
% 29.22/29.01  tff(decl_31260, type, fn_nucleic_acid_15: $i > $i).
% 29.22/29.01  tff(decl_31261, type, fn_nucleic_acid_16: $i > $i).
% 29.22/29.01  tff(decl_31262, type, dna_binding_domain_1: $i > $o).
% 29.22/29.01  tff(decl_31263, type, 'DNA-Binding-Domain': $i).
% 29.22/29.01  tff(decl_31264, type, 'A part of a protein\\s three-dimensional structure that binds to DNA.': $i).
% 29.22/29.01  tff(decl_31265, type, 'dna binding domain': $i).
% 29.22/29.01  tff(decl_31266, type, 'dna-binding domain': $i).
% 29.22/29.01  tff(decl_31267, type, 'dna-binding-domain': $i).
% 29.22/29.01  tff(decl_31268, type, variable_domain_1: $i > $o).
% 29.22/29.01  tff(decl_31269, type, dna_breakdown_1: $i > $o).
% 29.22/29.01  tff(decl_31270, type, 'DNA-Breakdown': $i).
% 29.22/29.01  tff(decl_31271, type, 'The process in which DNA breaks down into their simpler components.': $i).
% 29.22/29.01  tff(decl_31272, type, 'breakdown of dna': $i).
% 29.22/29.01  tff(decl_31273, type, 'dna breakdown': $i).
% 29.22/29.01  tff(decl_31274, type, 'dna-breakdown': $i).
% 29.22/29.01  tff(decl_31275, type, fn_dna_breakdown_1: $i > $i).
% 29.22/29.01  tff(decl_31276, type, fn_dna_breakdown_2: $i > $i).
% 29.22/29.01  tff(decl_31277, type, fn_dna_breakdown_3: $i > $i).
% 29.22/29.01  tff(decl_31278, type, fn_dna_breakdown_4: $i > $i).
% 29.22/29.01  tff(decl_31279, type, fn_dna_breakdown_5: $i > $i).
% 29.22/29.01  tff(decl_31280, type, fn_dna_breakdown_6: $i > $i).
% 29.22/29.01  tff(decl_31281, type, fn_dna_breakdown_7: $i > $i).
% 29.22/29.01  tff(decl_31282, type, fn_dna_breakdown_8: $i > $i).
% 29.22/29.01  tff(decl_31283, type, fn_dna_breakdown_9: $i > $i).
% 29.22/29.01  tff(decl_31284, type, fn_dna_breakdown_10: $i > $i).
% 29.22/29.01  tff(decl_31285, type, fn_dna_breakdown_11: $i > $i).
% 29.22/29.01  tff(decl_31286, type, fn_dna_breakdown_12: $i > $i).
% 29.22/29.01  tff(decl_31287, type, fn_dna_breakdown_13: $i > $i).
% 29.22/29.01  tff(decl_31288, type, fn_dna_breakdown_14: $i > $i).
% 29.22/29.01  tff(decl_31289, type, fn_dna_breakdown_15: $i > $i).
% 29.22/29.01  tff(decl_31290, type, fn_dna_breakdown_16: $i > $i).
% 29.22/29.01  tff(decl_31291, type, fn_dna_breakdown_17: $i > $i).
% 29.22/29.01  tff(decl_31292, type, fn_dna_breakdown_18: $i > $i).
% 29.22/29.01  tff(decl_31293, type, fn_hydrolysis_13: $i > $i).
% 29.22/29.01  tff(decl_31294, type, fn_polymer_breakdown_2: $i > $i).
% 29.22/29.01  tff(decl_31295, type, fn_dna_breakdown_19: $i > $i).
% 29.22/29.01  tff(decl_31296, type, fn_dna_breakdown_20: $i > $i).
% 29.22/29.01  tff(decl_31297, type, dna_chip_1: $i > $o).
% 29.22/29.01  tff(decl_31298, type, 'DNA-Chip': $i).
% 29.22/29.01  tff(decl_31299, type, 'A high density array of short DNA molecules bound to a solid surface for use in probing a biological sample to determine gene expression, marker pattern or nucleotide sequence of DNA.': $i).
% 29.22/29.01  tff(decl_31300, type, 'chip of dna': $i).
% 29.22/29.01  tff(decl_31301, type, 'dna chip': $i).
% 29.22/29.01  tff(decl_31302, type, 'dna-chip': $i).
% 29.22/29.01  tff(decl_31303, type, pet_scanner_1: $i > $o).
% 29.22/29.01  tff(decl_31304, type, spectrophotometer_1: $i > $o).
% 29.22/29.01  tff(decl_31305, type, dna_codon_1: $i > $o).
% 29.22/29.01  tff(decl_31306, type, 'DNA-Codon': $i).
% 29.22/29.01  tff(decl_31307, type, 'A DNA codon is three nucleotides in a DNA molecule whose sequence of nitrogenous bases coldes for one specific amino acid.': $i).
% 29.22/29.01  tff(decl_31308, type, 'codon of dna': $i).
% 29.22/29.01  tff(decl_31309, type, 'dna codon': $i).
% 29.22/29.01  tff(decl_31310, type, 'dna-codon': $i).
% 29.22/29.01  tff(decl_31311, type, fn_dna_codon_1: $i > $i).
% 29.22/29.01  tff(decl_31312, type, fn_dna_codon_4: $i > $i).
% 29.22/29.01  tff(decl_31313, type, fn_dna_codon_5: $i > $i).
% 29.22/29.01  tff(decl_31314, type, fn_dna_codon_6: $i > $i).
% 29.22/29.01  tff(decl_31315, type, fn_dna_codon_7: $i > $i).
% 29.22/29.01  tff(decl_31316, type, fn_dna_codon_8: $i > $i).
% 29.22/29.01  tff(decl_31317, type, fn_dna_codon_9: $i > $i).
% 29.22/29.01  tff(decl_31318, type, fn_dna_codon_3: $i > $i).
% 29.22/29.01  tff(decl_31319, type, fn_nucleic_acid_sequence_4: $i > $i).
% 29.22/29.01  tff(decl_31320, type, fn_dna_codon_2: $i > $i).
% 29.22/29.01  tff(decl_31321, type, fn_nucleic_acid_sequence_3: $i > $i).
% 29.22/29.01  tff(decl_31322, type, fn_nucleic_acid_sequence_1: $i > $i).
% 29.22/29.01  tff(decl_31323, type, fn_nucleic_acid_sequence_2: $i > $i).
% 29.22/29.01  tff(decl_31324, type, dna_damage_1: $i > $o).
% 29.22/29.01  tff(decl_31325, type, 'DNA-Damage': $i).
% 29.22/29.01  tff(decl_31326, type, 'Injuries to the DNA that change the normal structure of the molecule which can result in a mutation or can block DNA replication.': $i).
% 29.22/29.01  tff(decl_31327, type, 'damage of dna': $i).
% 29.22/29.01  tff(decl_31328, type, 'dna damage': $i).
% 29.22/29.01  tff(decl_31329, type, 'dna-damage': $i).
% 29.22/29.01  tff(decl_31330, type, fn_dna_damage_1: $i > $i).
% 29.22/29.01  tff(decl_31331, type, fn_dna_damage_2: $i > $i).
% 29.22/29.01  tff(decl_31332, type, fn_dna_damage_3: $i > $i).
% 29.22/29.01  tff(decl_31333, type, fn_dna_damage_4: $i > $i).
% 29.22/29.01  tff(decl_31334, type, fn_dna_damage_5: $i > $i).
% 29.22/29.01  tff(decl_31335, type, fn_dna_damage_6: $i > $i).
% 29.22/29.01  tff(decl_31336, type, fn_dna_damage_7: $i > $i).
% 29.22/29.01  tff(decl_31337, type, dna_double_helix_1: $i > $o).
% 29.22/29.01  tff(decl_31338, type, 'DNA-Double-Helix': $i).
% 29.22/29.01  tff(decl_31339, type, 'The native shape of DNA molecules, in which two polynucleotide strands in antiparallel orientation spiral around an imaginary central axis.': $i).
% 29.22/29.01  tff(decl_31340, type, fn_dna_double_helix_3: $i > $i).
% 29.22/29.01  tff(decl_31341, type, fn_dna_double_helix_4: $i > $i).
% 29.22/29.01  tff(decl_31342, type, fn_dna_double_helix_5: $i > $i).
% 29.22/29.01  tff(decl_31343, type, fn_dna_double_helix_6: $i > $i).
% 29.22/29.01  tff(decl_31344, type, fn_dna_double_helix_8: $i > $i).
% 29.22/29.01  tff(decl_31345, type, fn_dna_double_helix_9: $i > $i).
% 29.22/29.01  tff(decl_31346, type, fn_dna_double_helix_10: $i > $i).
% 29.22/29.01  tff(decl_31347, type, fn_dna_double_helix_11: $i > $i).
% 29.22/29.01  tff(decl_31348, type, fn_dna_double_helix_12: $i > $i).
% 29.22/29.01  tff(decl_31349, type, fn_dna_double_helix_13: $i > $i).
% 29.22/29.01  tff(decl_31350, type, fn_dna_double_helix_14: $i > $i).
% 29.22/29.01  tff(decl_31351, type, fn_dna_double_helix_15: $i > $i).
% 29.22/29.01  tff(decl_31352, type, fn_dna_double_helix_16: $i > $i).
% 29.22/29.01  tff(decl_31353, type, fn_dna_double_helix_17: $i > $i).
% 29.22/29.01  tff(decl_31354, type, fn_dna_double_helix_18: $i > $i).
% 29.22/29.01  tff(decl_31355, type, fn_dna_strand_11: $i > $i).
% 29.22/29.01  tff(decl_31356, type, fn_dna_strand_12: $i > $i).
% 29.22/29.01  tff(decl_31357, type, dna_elongation_1: $i > $o).
% 29.22/29.01  tff(decl_31358, type, 'DNA-Elongation': $i).
% 29.22/29.01  tff(decl_31359, type, 'The process of DNA elongation occurs at the replication fork, present at the end of each replication bubble': $i).
% 29.22/29.01  tff(decl_31360, type, 'elongation of dna': $i).
% 29.22/29.01  tff(decl_31361, type, 'dna elongation': $i).
% 29.22/29.01  tff(decl_31362, type, 'dna-elongation': $i).
% 29.22/29.01  tff(decl_31363, type, dna_replication_phase_1: $i > $o).
% 29.22/29.01  tff(decl_31364, type, fn_dna_elongation_1: $i > $i).
% 29.22/29.01  tff(decl_31365, type, fn_dna_elongation_2: $i > $i).
% 29.22/29.01  tff(decl_31366, type, fn_dna_elongation_3: $i > $i).
% 29.22/29.01  tff(decl_31367, type, fn_dna_elongation_4: $i > $i).
% 29.22/29.01  tff(decl_31368, type, dna_polymerase_1: $i > $o).
% 29.22/29.01  tff(decl_31369, type, fn_dna_elongation_5: $i > $i).
% 29.22/29.01  tff(decl_31370, type, fn_dna_elongation_6: $i > $i).
% 29.22/29.01  tff(decl_31371, type, synthesis_of_leading_strand_1: $i > $o).
% 29.22/29.01  tff(decl_31372, type, fn_dna_elongation_7: $i > $i).
% 29.22/29.01  tff(decl_31373, type, synthesis_of_lagging_strand_1: $i > $o).
% 29.22/29.01  tff(decl_31374, type, fn_dna_elongation_8: $i > $i).
% 29.22/29.01  tff(decl_31375, type, lagging_strand_1: $i > $o).
% 29.22/29.01  tff(decl_31376, type, fn_dna_elongation_9: $i > $i).
% 29.22/29.01  tff(decl_31377, type, leading_strand_1: $i > $o).
% 29.22/29.01  tff(decl_31378, type, fn_synthesis_of_lagging_strand_37: $i > $i).
% 29.22/29.01  tff(decl_31379, type, fn_synthesis_of_leading_strand_63: $i > $i).
% 29.22/29.01  tff(decl_31380, type, dna_fingerprint_1: $i > $o).
% 29.22/29.01  tff(decl_31381, type, 'DNA-Fingerprint': $i).
% 29.22/29.01  tff(decl_31382, type, 'An individual\\s unique sequence of DNA base pairs, determined by exposing a sample of the person\\s DNA to molecular probes.': $i).
% 29.22/29.01  tff(decl_31383, type, 'genetic fingerprint': $i).
% 29.22/29.01  tff(decl_31384, type, 'fingerprint of dna': $i).
% 29.22/29.01  tff(decl_31385, type, 'dna fingerprint': $i).
% 29.22/29.01  tff(decl_31386, type, 'dna-fingerprint': $i).
% 29.22/29.01  tff(decl_31387, type, dna_fingerprinting_1: $i > $o).
% 29.22/29.01  tff(decl_31388, type, 'DNA-Fingerprinting': $i).
% 29.22/29.01  tff(decl_31389, type, 'The process of using genetic markers to create specific banding patterns at particular loci which can be used to identify individuals.': $i).
% 29.22/29.01  tff(decl_31390, type, fingerpring: $i).
% 29.22/29.01  tff(decl_31391, type, 'fingerprinting of dna': $i).
% 29.22/29.01  tff(decl_31392, type, 'dna fingerprinting': $i).
% 29.22/29.01  tff(decl_31393, type, 'dna-fingerprinting': $i).
% 29.22/29.01  tff(decl_31394, type, fn_dna_hypermethylation_1: $i > $i).
% 29.22/29.01  tff(decl_31395, type, 'DNA-Hypermethylation': $i).
% 29.22/29.01  tff(decl_31396, type, 'The addition of a large number of methyl groups to DNA bases, usually cytosine, in the chromosomes of plants, animals, and fungi to inactivate genes.': $i).
% 29.22/29.01  tff(decl_31397, type, hypermethylate: $i).
% 29.22/29.01  tff(decl_31398, type, 'dna hypermethylation': $i).
% 29.22/29.01  tff(decl_31399, type, 'dna-hypermethylation': $i).
% 29.22/29.01  tff(decl_31400, type, fn_dna_hypermethylation_4: $i > $i).
% 29.22/29.01  tff(decl_31401, type, fn_dna_hypermethylation_5: $i > $i).
% 29.22/29.01  tff(decl_31402, type, fn_dna_hypermethylation_6: $i > $i).
% 29.22/29.01  tff(decl_31403, type, dna_methylation_0: $i).
% 29.22/29.01  tff(decl_31404, type, 'DNA-Library': $i).
% 29.22/29.01  tff(decl_31405, type, 'A group of information containing many cloned genes.': $i).
% 29.22/29.01  tff(decl_31406, type, 'library of dna': $i).
% 29.22/29.01  tff(decl_31407, type, 'dna library': $i).
% 29.22/29.01  tff(decl_31408, type, 'dna-library': $i).
% 29.22/29.01  tff(decl_31409, type, species_concept_1: $i > $o).
% 29.22/29.01  tff(decl_31410, type, fn_dna_library_1: $i > $i).
% 29.22/29.01  tff(decl_31411, type, 'DNA-Ligase': $i).
% 29.22/29.01  tff(decl_31412, type, 'The enzyme that catalyzes the formation of a phosphodiester bond between the 3\\ end of one piece of DNA and the 5\\ end of another.': $i).
% 29.22/29.01  tff(decl_31413, type, 'ligase of dna': $i).
% 29.22/29.01  tff(decl_31414, type, 'dna ligase': $i).
% 29.22/29.01  tff(decl_31415, type, 'dna-ligase': $i).
% 29.22/29.01  tff(decl_31416, type, fn_dna_ligase_1: $i > $i).
% 29.22/29.01  tff(decl_31417, type, recombinant_dna_technology_1: $i > $o).
% 29.22/29.01  tff(decl_31418, type, fn_dna_ligase_2: $i > $i).
% 29.22/29.01  tff(decl_31419, type, novel_dna_sequence_1: $i > $o).
% 29.22/29.01  tff(decl_31420, type, fn_dna_ligase_3: $i > $i).
% 29.22/29.01  tff(decl_31421, type, fn_dna_ligase_4: $i > $i).
% 29.22/29.01  tff(decl_31422, type, fn_dna_ligase_5: $i > $i).
% 29.22/29.01  tff(decl_31423, type, fn_dna_ligase_6: $i > $i).
% 29.22/29.01  tff(decl_31424, type, fn_dna_ligase_8: $i > $i).
% 29.22/29.01  tff(decl_31425, type, okazaki_fragments_1: $i > $o).
% 29.22/29.01  tff(decl_31426, type, fn_dna_ligase_9: $i > $i).
% 29.22/29.01  tff(decl_31427, type, fn_dna_ligase_11: $i > $i).
% 29.22/29.01  tff(decl_31428, type, fn_dna_ligase_13: $i > $i).
% 29.22/29.01  tff(decl_31429, type, fn_dna_ligase_14: $i > $i).
% 29.22/29.01  tff(decl_31430, type, fn_dna_ligase_15: $i > $i).
% 29.22/29.01  tff(decl_31431, type, fn_dna_ligase_16: $i > $i).
% 29.22/29.01  tff(decl_31432, type, fn_dna_ligase_17: $i > $i).
% 29.22/29.01  tff(decl_31433, type, fn_dna_ligase_18: $i > $i).
% 29.22/29.01  tff(decl_31434, type, fn_ligase_1: $i > $i).
% 29.22/29.01  tff(decl_31435, type, 'DNA-Mapping': $i).
% 29.22/29.01  tff(decl_31436, type, 'A technique to map the base pair sequence of a genome.': $i).
% 29.22/29.01  tff(decl_31437, type, 'genome mapping': $i).
% 29.22/29.01  tff(decl_31438, type, map: $i).
% 29.22/29.01  tff(decl_31439, type, 'mapping of dna': $i).
% 29.22/29.01  tff(decl_31440, type, 'dna mapping': $i).
% 29.22/29.01  tff(decl_31441, type, 'dna-mapping': $i).
% 29.22/29.01  tff(decl_31442, type, dna_technique_1: $i > $o).
% 29.22/29.01  tff(decl_31443, type, fn_dna_mapping_1: $i > $i).
% 29.22/29.01  tff(decl_31444, type, 'DNA-Methylation': $i).
% 29.22/29.01  tff(decl_31445, type, 'The attachment of methyl groups (--CH3) to DNA bases after DNA is synthesized, usually regulating the expression of genes.': $i).
% 29.22/29.01  tff(decl_31446, type, methylate: $i).
% 29.22/29.01  tff(decl_31447, type, 'methylation of dna': $i).
% 29.22/29.01  tff(decl_31448, type, 'dna methylation': $i).
% 29.22/29.01  tff(decl_31449, type, 'dna-methylation': $i).
% 29.22/29.01  tff(decl_31450, type, methylation_1: $i > $o).
% 29.22/29.01  tff(decl_31451, type, fn_dna_methylation_1: $i > $i).
% 29.22/29.01  tff(decl_31452, type, fn_dna_methylation_2: $i > $i).
% 29.22/29.01  tff(decl_31453, type, fn_dna_methylation_3: $i > $i).
% 29.22/29.01  tff(decl_31454, type, genomic_imprinting_1: $i > $o).
% 29.22/29.01  tff(decl_31455, type, fn_dna_methylation_4: $i > $i).
% 29.22/29.01  tff(decl_31456, type, fn_dna_methylation_5: $i > $i).
% 29.22/29.01  tff(decl_31457, type, fn_dna_methylation_6: $i > $i).
% 29.22/29.01  tff(decl_31458, type, fn_dna_methylation_7: $i > $i).
% 29.22/29.01  tff(decl_31459, type, gene_inactivation_1: $i > $o).
% 29.22/29.01  tff(decl_31460, type, fn_dna_methylation_8: $i > $i).
% 29.22/29.01  tff(decl_31461, type, restriction_nuclease_1: $i > $o).
% 29.22/29.01  tff(decl_31462, type, fn_dna_methylation_9: $i > $i).
% 29.22/29.01  tff(decl_31463, type, fn_dna_methylation_11: $i > $i).
% 29.22/29.01  tff(decl_31464, type, methylated_dna_1: $i > $o).
% 29.22/29.01  tff(decl_31465, type, fn_dna_methylation_12: $i > $i).
% 29.22/29.01  tff(decl_31466, type, fn_dna_methylation_13: $i > $i).
% 29.22/29.01  tff(decl_31467, type, fn_dna_methylation_14: $i > $i).
% 29.22/29.01  tff(decl_31468, type, fn_dna_methylation_15: $i > $i).
% 29.22/29.01  tff(decl_31469, type, fn_restriction_nuclease_26: $i > $i).
% 29.22/29.01  tff(decl_31470, type, fn_methylated_dna_1: $i > $i).
% 29.22/29.01  tff(decl_31471, type, fn_methylated_dna_5: $i > $i).
% 29.22/29.01  tff(decl_31472, type, 'DNA-Microarray': $i).
% 29.22/29.01  tff(decl_31473, type, 'A method used to detect and measure the expression of thousands of genes simultaneously. Small spots of DNA fixed to a glass slide are hybridized with labeled samples of cDNA which can then be detected by their labels.': $i).
% 29.22/29.01  tff(decl_31474, type, 'perform dna microarray analysis': $i).
% 29.22/29.01  tff(decl_31475, type, 'dna microarray': $i).
% 29.22/29.01  tff(decl_31476, type, 'dna-microarray': $i).
% 29.22/29.01  tff(decl_31477, type, 'DNA-Piece': $i).
% 29.22/29.01  tff(decl_31478, type, 'Small pieces of DNA that make up the entire DNA strand.': $i).
% 29.22/29.01  tff(decl_31479, type, 'piece of dna': $i).
% 29.22/29.01  tff(decl_31480, type, 'dna piece': $i).
% 29.22/29.01  tff(decl_31481, type, 'dna-piece': $i).
% 29.22/29.01  tff(decl_31482, type, 'DNA-Polymerase': $i).
% 29.22/29.01  tff(decl_31483, type, 'An enzyme that catalyzes the addition of a nucleotide to the 3\\ end of a nucleic acid chain.': $i).
% 29.22/29.01  tff(decl_31484, type, 'polymerase of dna': $i).
% 29.22/29.01  tff(decl_31485, type, 'dna polymerase': $i).
% 29.22/29.01  tff(decl_31486, type, 'dna-polymerase': $i).
% 29.22/29.01  tff(decl_31487, type, polymerase_1: $i > $o).
% 29.22/29.01  tff(decl_31488, type, fn_dna_polymerase_9: $i > $i).
% 29.22/29.01  tff(decl_31489, type, fn_dna_polymerase_12: $i > $i).
% 29.22/29.01  tff(decl_31490, type, fn_dna_polymerase_13: $i > $i).
% 29.22/29.01  tff(decl_31491, type, fn_dna_polymerase_14: $i > $i).
% 29.22/29.01  tff(decl_31492, type, fn_dna_polymerase_15: $i > $i).
% 29.22/29.01  tff(decl_31493, type, fn_dna_polymerase_16: $i > $i).
% 29.22/29.01  tff(decl_31494, type, fn_dna_polymerase_17: $i > $i).
% 29.22/29.01  tff(decl_31495, type, fn_dna_polymerase_18: $i > $i).
% 29.22/29.01  tff(decl_31496, type, fn_dna_polymerase_19: $i > $i).
% 29.22/29.01  tff(decl_31497, type, fn_dna_polymerase_20: $i > $i).
% 29.22/29.01  tff(decl_31498, type, fn_dna_polymerase_21: $i > $i).
% 29.22/29.01  tff(decl_31499, type, fn_dna_polymerase_22: $i > $i).
% 29.22/29.01  tff(decl_31500, type, fn_dna_polymerase_24: $i > $i).
% 29.22/29.01  tff(decl_31501, type, fn_dna_polymerase_25: $i > $i).
% 29.22/29.01  tff(decl_31502, type, fn_dna_polymerase_26: $i > $i).
% 29.22/29.01  tff(decl_31503, type, fn_dna_polymerase_27: $i > $i).
% 29.22/29.01  tff(decl_31504, type, fn_dna_polymerase_28: $i > $i).
% 29.22/29.01  tff(decl_31505, type, fn_dna_polymerase_29: $i > $i).
% 29.22/29.01  tff(decl_31506, type, fn_dna_polymerase_30: $i > $i).
% 29.22/29.01  tff(decl_31507, type, fn_dna_polymerase_31: $i > $i).
% 29.22/29.01  tff(decl_31508, type, fn_dna_polymerase_32: $i > $i).
% 29.22/29.01  tff(decl_31509, type, fn_dna_polymerase_33: $i > $i).
% 29.22/29.01  tff(decl_31510, type, fn_dna_polymerase_34: $i > $i).
% 29.22/29.01  tff(decl_31511, type, fn_dna_polymerase_35: $i > $i).
% 29.22/29.01  tff(decl_31512, type, fn_dna_polymerase_36: $i > $i).
% 29.22/29.01  tff(decl_31513, type, fn_dna_polymerase_37: $i > $i).
% 29.22/29.01  tff(decl_31514, type, fn_dna_polymerase_38: $i > $i).
% 29.22/29.01  tff(decl_31515, type, fn_dna_polymerase_39: $i > $i).
% 29.22/29.01  tff(decl_31516, type, fn_dna_polymerase_40: $i > $i).
% 29.22/29.01  tff(decl_31517, type, fn_dna_polymerase_41: $i > $i).
% 29.22/29.01  tff(decl_31518, type, fn_dna_polymerase_42: $i > $i).
% 29.22/29.01  tff(decl_31519, type, fn_dna_polymerase_43: $i > $i).
% 29.22/29.01  tff(decl_31520, type, fn_dna_polymerase_44: $i > $i).
% 29.22/29.01  tff(decl_31521, type, fn_dna_polymerase_45: $i > $i).
% 29.22/29.01  tff(decl_31522, type, fn_dna_polymerase_46: $i > $i).
% 29.22/29.01  tff(decl_31523, type, fn_dna_polymerase_47: $i > $i).
% 29.22/29.01  tff(decl_31524, type, fn_dna_polymerase_48: $i > $i).
% 29.22/29.01  tff(decl_31525, type, fn_dna_polymerase_49: $i > $i).
% 29.22/29.01  tff(decl_31526, type, fn_dna_polymerase_50: $i > $i).
% 29.22/29.01  tff(decl_31527, type, 'DNA-Polymerase-I': $i).
% 29.22/29.01  tff(decl_31528, type, 'An enzyme that synthesizes DNA nucleotides to replace RNA primer nucleotides on each of the Okazaki fragments on the lagging strand of the DNA molecule.': $i).
% 29.22/29.01  tff(decl_31529, type, 'dna pol i': $i).
% 29.22/29.01  tff(decl_31530, type, 'dna-pol-i': $i).
% 29.22/29.01  tff(decl_31531, type, 'dna polymerase i': $i).
% 29.22/29.01  tff(decl_31532, type, 'dna-polymerase-i': $i).
% 29.22/29.01  tff(decl_31533, type, dna_polymerase_ii_1: $i > $o).
% 29.22/29.01  tff(decl_31534, type, taq_polymerase_1: $i > $o).
% 29.22/29.01  tff(decl_31535, type, 'DNA-Polymerase-II': $i).
% 29.22/29.01  tff(decl_31536, type, 'An enzyme, secondary to DNA polymerase I, involved in DNA repair.': $i).
% 29.22/29.01  tff(decl_31537, type, 'dna pol ii': $i).
% 29.22/29.01  tff(decl_31538, type, 'dna-pol-ii': $i).
% 29.22/29.01  tff(decl_31539, type, 'dna polymerase ii': $i).
% 29.22/29.01  tff(decl_31540, type, 'dna-polymerase-ii': $i).
% 29.22/29.01  tff(decl_31541, type, 'DNA-Polymerase-III': $i).
% 29.22/29.01  tff(decl_31542, type, 'An enzyme that synthesizes DNA by adding nucleotides to the end of the RNA primer and complementary to the parental, template DNA strand.': $i).
% 29.22/29.01  tff(decl_31543, type, 'dna pol iii': $i).
% 29.22/29.01  tff(decl_31544, type, 'dna-pol-iii': $i).
% 29.22/29.01  tff(decl_31545, type, 'dna polymerase iii': $i).
% 29.22/29.01  tff(decl_31546, type, 'dna-polymerase-iii': $i).
% 29.22/29.01  tff(decl_31547, type, fn_dna_polymerase_iii_1: $i > $i).
% 29.22/29.01  tff(decl_31548, type, fn_synthesis_of_leading_strand_68: $i > $i).
% 29.22/29.01  tff(decl_31549, type, dna_primase_1: $i > $o).
% 29.22/29.01  tff(decl_31550, type, 'DNA-Primase': $i).
% 29.22/29.01  tff(decl_31551, type, 'An enzyme that catalyzes the synthesis of a short segment (called a primer) of RNA or DNA that is complementary to a single-stranded DNA template.': $i).
% 29.22/29.01  tff(decl_31552, type, primase: $i).
% 29.22/29.01  tff(decl_31553, type, 'dna primase': $i).
% 29.22/29.01  tff(decl_31554, type, 'dna-primase': $i).
% 29.22/29.01  tff(decl_31555, type, transferase_1: $i > $o).
% 29.22/29.01  tff(decl_31556, type, fn_dna_primase_1: $i > $i).
% 29.22/29.01  tff(decl_31557, type, fn_dna_primase_2: $i > $i).
% 29.22/29.01  tff(decl_31558, type, fn_dna_primase_3: $i > $i).
% 29.22/29.01  tff(decl_31559, type, fn_dna_primase_4: $i > $i).
% 29.22/29.01  tff(decl_31560, type, fn_dna_primase_5: $i > $i).
% 29.22/29.01  tff(decl_31561, type, fn_dna_primase_6: $i > $i).
% 29.22/29.01  tff(decl_31562, type, fn_dna_primase_7: $i > $i).
% 29.22/29.01  tff(decl_31563, type, fn_dna_primase_8: $i > $i).
% 29.22/29.01  tff(decl_31564, type, fn_dna_primase_9: $i > $i).
% 29.22/29.01  tff(decl_31565, type, fn_dna_primase_10: $i > $i).
% 29.22/29.01  tff(decl_31566, type, fn_dna_primase_11: $i > $i).
% 29.22/29.01  tff(decl_31567, type, fn_dna_primase_12: $i > $i).
% 29.22/29.01  tff(decl_31568, type, fn_dna_primase_13: $i > $i).
% 29.22/29.01  tff(decl_31569, type, fn_dna_primase_14: $i > $i).
% 29.22/29.01  tff(decl_31570, type, fn_dna_primase_15: $i > $i).
% 29.22/29.01  tff(decl_31571, type, fn_dna_primase_16: $i > $i).
% 29.22/29.01  tff(decl_31572, type, fn_dna_primase_17: $i > $i).
% 29.22/29.01  tff(decl_31573, type, fn_dna_primase_18: $i > $i).
% 29.22/29.01  tff(decl_31574, type, fn_dna_primase_19: $i > $i).
% 29.22/29.01  tff(decl_31575, type, fn_dna_primase_20: $i > $i).
% 29.22/29.01  tff(decl_31576, type, 'DNA-Primer': $i).
% 29.22/29.01  tff(decl_31577, type, 'Primer is a strand of nucleic acid that serves as a starting point for DNA synthesis. They are required because the enzymes that catalyze replication, DNA polymerases, can only add new nucleotides to an existing strand of DNA. The polymerase starts replication at the 3\\-end of the primer, and copies the opposite strand.': $i).
% 29.22/29.01  tff(decl_31578, type, 'primer of dna': $i).
% 29.22/29.01  tff(decl_31579, type, 'dna primer': $i).
% 29.22/29.01  tff(decl_31580, type, 'dna-primer': $i).
% 29.22/29.01  tff(decl_31581, type, primer_1: $i > $o).
% 29.22/29.01  tff(decl_31582, type, rna_primer_1: $i > $o).
% 29.22/29.01  tff(decl_31583, type, fn_dna_primer_1: $i > $i).
% 29.22/29.01  tff(decl_31584, type, fn_dna_primer_2: $i > $i).
% 29.22/29.01  tff(decl_31585, type, fn_dna_primer_3: $i > $i).
% 29.22/29.01  tff(decl_31586, type, fn_dna_primer_4: $i > $i).
% 29.22/29.01  tff(decl_31587, type, fn_dna_primer_5: $i > $i).
% 29.22/29.01  tff(decl_31588, type, fn_dna_primer_6: $i > $i).
% 29.22/29.01  tff(decl_31589, type, fn_dna_primer_7: $i > $i).
% 29.22/29.01  tff(decl_31590, type, fn_dna_primer_8: $i > $i).
% 29.22/29.01  tff(decl_31591, type, fn_dna_primer_9: $i > $i).
% 29.22/29.01  tff(decl_31592, type, fn_dna_primer_10: $i > $i).
% 29.22/29.01  tff(decl_31593, type, fn_dna_primer_11: $i > $i).
% 29.22/29.01  tff(decl_31594, type, fn_dna_primer_12: $i > $i).
% 29.22/29.01  tff(decl_31595, type, fn_dna_primer_13: $i > $i).
% 29.22/29.01  tff(decl_31596, type, fn_dna_primer_14: $i > $i).
% 29.22/29.01  tff(decl_31597, type, fn_dna_primer_15: $i > $i).
% 29.22/29.01  tff(decl_31598, type, fn_dna_primer_16: $i > $i).
% 29.22/29.01  tff(decl_31599, type, fn_dna_primer_17: $i > $i).
% 29.22/29.01  tff(decl_31600, type, fn_dna_primer_18: $i > $i).
% 29.22/29.01  tff(decl_31601, type, fn_dna_primer_19: $i > $i).
% 29.22/29.01  tff(decl_31602, type, fn_dna_primer_20: $i > $i).
% 29.22/29.01  tff(decl_31603, type, fn_dna_primer_21: $i > $i).
% 29.22/29.01  tff(decl_31604, type, fn_dna_primer_22: $i > $i).
% 29.22/29.01  tff(decl_31605, type, fn_dna_primer_23: $i > $i).
% 29.22/29.01  tff(decl_31606, type, fn_dna_primer_24: $i > $i).
% 29.22/29.01  tff(decl_31607, type, fn_dna_primer_25: $i > $i).
% 29.22/29.01  tff(decl_31608, type, fn_dna_primer_26: $i > $i).
% 29.22/29.01  tff(decl_31609, type, fn_primer_3: $i > $i).
% 29.22/29.01  tff(decl_31610, type, fn_primer_2: $i > $i).
% 29.22/29.01  tff(decl_31611, type, 'DNA-Proofreading': $i).
% 29.22/29.01  tff(decl_31612, type, 'Error correction of newly-synthesized DNA where DNA polymerase reverses its direction by one base pair of DNA and excises the incorrect base pair and replaces it with the correct base pair.  Not all DNA polymerases have the ability to proofread.': $i).
% 29.22/29.01  tff(decl_31613, type, proofread: $i).
% 29.22/29.01  tff(decl_31614, type, 'dna proofreading': $i).
% 29.22/29.01  tff(decl_31615, type, 'dna-proofreading': $i).
% 29.22/29.01  tff(decl_31616, type, fn_dna_proofreading_1: $i > $i).
% 29.22/29.01  tff(decl_31617, type, fn_dna_proofreading_2: $i > $i).
% 29.22/29.01  tff(decl_31618, type, increase_in_accuracy_of_dna_replication_1: $i > $o).
% 29.22/29.01  tff(decl_31619, type, fn_dna_proofreading_3: $i > $i).
% 29.22/29.01  tff(decl_31620, type, fn_dna_proofreading_4: $i > $i).
% 29.22/29.01  tff(decl_31621, type, fn_dna_proofreading_5: $i > $i).
% 29.22/29.01  tff(decl_31622, type, fn_dna_proofreading_6: $i > $i).
% 29.22/29.01  tff(decl_31623, type, fn_dna_repair_8: $i > $i).
% 29.22/29.01  tff(decl_31624, type, fn_dna_replication_3: $i > $i).
% 29.22/29.01  tff(decl_31625, type, fn_increase_in_accuracy_of_dna_replication_2: $i > $i).
% 29.22/29.01  tff(decl_31626, type, 'DNA-Repair': $i).
% 29.22/29.01  tff(decl_31627, type, 'DNA repair refers to a collection of processes by which a cell identifies and corrects damage to the DNA molecules that encode its genome.': $i).
% 29.22/29.01  tff(decl_31628, type, repair: $i).
% 29.22/29.01  tff(decl_31629, type, 'repair of dna': $i).
% 29.22/29.01  tff(decl_31630, type, 'dna repair': $i).
% 29.22/29.01  tff(decl_31631, type, 'dna-repair': $i).
% 29.22/29.01  tff(decl_31632, type, repair_1: $i > $o).
% 29.22/29.01  tff(decl_31633, type, fn_dna_repair_1: $i > $i).
% 29.22/29.01  tff(decl_31634, type, fn_dna_repair_2: $i > $i).
% 29.22/29.01  tff(decl_31635, type, repair_enzyme_1: $i > $o).
% 29.22/29.01  tff(decl_31636, type, fn_dna_repair_3: $i > $i).
% 29.22/29.01  tff(decl_31637, type, fn_dna_repair_4: $i > $i).
% 29.22/29.01  tff(decl_31638, type, fn_dna_repair_5: $i > $i).
% 29.22/29.01  tff(decl_31639, type, fn_dna_repair_6: $i > $i).
% 29.22/29.01  tff(decl_31640, type, fn_dna_repair_7: $i > $i).
% 29.22/29.01  tff(decl_31641, type, fn_repair_1: $i > $i).
% 29.22/29.01  tff(decl_31642, type, 'DNA-Replication': $i).
% 29.22/29.01  tff(decl_31643, type, 'DNA replication is process by which a cell\\s DNA makes its own exact copy. The DNA\\s two strands serve as templates for the synthesis of a complementary daughter strand for themselves. The daughter strand remains attached to their template parental strand to result in new DNA copy having parental strand and the newly synthesized as its component strands. This model of replication is called \\semiconservative model of DNA replication\\. The process involves \\DNA polymerase\\ and primase\\ enzymes.': $i).
% 29.22/29.01  tff(decl_31644, type, 'dna synthesis': $i).
% 29.22/29.01  tff(decl_31645, type, 'dna-synthesis': $i).
% 29.22/29.01  tff(decl_31646, type, 'replication of dna': $i).
% 29.22/29.01  tff(decl_31647, type, 'dna replication': $i).
% 29.22/29.01  tff(decl_31648, type, 'dna-replication': $i).
% 29.22/29.01  tff(decl_31649, type, synthesis_of_nucleic_acid_1: $i > $o).
% 29.22/29.01  tff(decl_31650, type, fn_dna_replication_2: $i > $i).
% 29.22/29.01  tff(decl_31651, type, dna_replication_termination_1: $i > $o).
% 29.22/29.01  tff(decl_31652, type, fn_dna_replication_4: $i > $i).
% 29.22/29.01  tff(decl_31653, type, mismatch_repair_1: $i > $o).
% 29.22/29.01  tff(decl_31654, type, fn_dna_replication_5: $i > $i).
% 29.22/29.01  tff(decl_31655, type, fn_dna_replication_6: $i > $i).
% 29.22/29.01  tff(decl_31656, type, fn_dna_replication_7: $i > $i).
% 29.22/29.01  tff(decl_31657, type, fn_dna_replication_8: $i > $i).
% 29.22/29.01  tff(decl_31658, type, fn_dna_replication_9: $i > $i).
% 29.22/29.01  tff(decl_31659, type, fn_dna_replication_10: $i > $i).
% 29.22/29.01  tff(decl_31660, type, fn_dna_replication_12: $i > $i).
% 29.22/29.01  tff(decl_31661, type, fn_dna_replication_13: $i > $i).
% 29.22/29.01  tff(decl_31662, type, fn_dna_replication_14: $i > $i).
% 29.22/29.01  tff(decl_31663, type, fn_dna_replication_15: $i > $i).
% 29.22/29.01  tff(decl_31664, type, fn_dna_replication_16: $i > $i).
% 29.22/29.01  tff(decl_31665, type, fn_dna_replication_17: $i > $i).
% 29.22/29.01  tff(decl_31666, type, fn_dna_replication_18: $i > $i).
% 29.22/29.01  tff(decl_31667, type, fn_dna_replication_19: $i > $i).
% 29.22/29.01  tff(decl_31668, type, fn_dna_replication_20: $i > $i).
% 29.22/29.01  tff(decl_31669, type, fn_dna_replication_21: $i > $i).
% 29.22/29.01  tff(decl_31670, type, fn_dna_replication_22: $i > $i).
% 29.22/29.01  tff(decl_31671, type, dna_replication_initiation_1: $i > $o).
% 29.22/29.01  tff(decl_31672, type, fn_dna_replication_24: $i > $i).
% 29.22/29.01  tff(decl_31673, type, fn_dna_replication_25: $i > $i).
% 29.22/29.01  tff(decl_31674, type, fn_dna_replication_26: $i > $i).
% 29.22/29.01  tff(decl_31675, type, helicase_1: $i > $o).
% 29.22/29.01  tff(decl_31676, type, fn_dna_replication_28: $i > $i).
% 29.22/29.01  tff(decl_31677, type, fn_dna_replication_29: $i > $i).
% 29.22/29.01  tff(decl_31678, type, fn_dna_replication_30: $i > $i).
% 29.22/29.01  tff(decl_31679, type, fn_dna_replication_31: $i > $i).
% 29.22/29.01  tff(decl_31680, type, fn_dna_replication_32: $i > $i).
% 29.22/29.01  tff(decl_31681, type, fn_dna_replication_33: $i > $i).
% 29.22/29.01  tff(decl_31682, type, fn_dna_replication_initiation_14: $i > $i).
% 29.22/29.01  tff(decl_31683, type, fn_polymer_synthesis_11: $i > $i).
% 29.22/29.01  tff(decl_31684, type, fn_polymer_synthesis_19: $i > $i).
% 29.22/29.01  tff(decl_31685, type, fn_synthesis_of_nucleic_acid_10: $i > $i).
% 29.22/29.01  tff(decl_31686, type, fn_polymer_synthesis_15: $i > $i).
% 29.22/29.01  tff(decl_31687, type, fn_polymer_synthesis_12: $i > $i).
% 29.22/29.01  tff(decl_31688, type, fn_synthesis_of_nucleic_acid_12: $i > $i).
% 29.22/29.01  tff(decl_31689, type, fn_synthesis_of_nucleic_acid_11: $i > $i).
% 29.22/29.01  tff(decl_31690, type, fn_synthesis_of_nucleic_acid_14: $i > $i).
% 29.22/29.01  tff(decl_31691, type, fn_synthesis_of_nucleic_acid_8: $i > $i).
% 29.22/29.01  tff(decl_31692, type, fn_synthesis_of_nucleic_acid_7: $i > $i).
% 29.22/29.01  tff(decl_31693, type, fn_synthesis_of_nucleic_acid_9: $i > $i).
% 29.22/29.01  tff(decl_31694, type, fn_synthesis_of_nucleic_acid_13: $i > $i).
% 29.22/29.01  tff(decl_31695, type, 'DNA-Replication-In-Eukaryotes': $i).
% 29.22/29.01  tff(decl_31696, type, 'The process in which existing DNA acts as a template for the cell to make a copy of the DNA . Replication in eukaryotes occurs during the S phase of the cell cycle and is regulated by cyclin-dependent kinases.': $i).
% 29.22/29.01  tff(decl_31697, type, 'replication in eukaryotes': $i).
% 29.22/29.01  tff(decl_31698, type, 'dna replication in eukaryote': $i).
% 29.22/29.01  tff(decl_31699, type, 'dna-replication-in-eukaryote': $i).
% 29.22/29.01  tff(decl_31700, type, fn_dna_replication_in_eukaryotes_1: $i > $i).
% 29.22/29.01  tff(decl_31701, type, fn_dna_replication_in_eukaryotes_2: $i > $i).
% 29.22/29.01  tff(decl_31702, type, fn_dna_replication_in_eukaryotes_3: $i > $i).
% 29.22/29.01  tff(decl_31703, type, fn_dna_replication_in_eukaryotes_4: $i > $i).
% 29.22/29.01  tff(decl_31704, type, fn_dna_replication_in_eukaryotes_5: $i > $i).
% 29.22/29.01  tff(decl_31705, type, fn_dna_replication_in_eukaryotes_6: $i > $i).
% 29.22/29.01  tff(decl_31706, type, fn_dna_replication_in_eukaryotes_8: $i > $i).
% 29.22/29.01  tff(decl_31707, type, fn_dna_replication_in_eukaryotes_9: $i > $i).
% 29.22/29.01  tff(decl_31708, type, fn_dna_replication_in_eukaryotes_10: $i > $i).
% 29.22/29.01  tff(decl_31709, type, fn_dna_replication_in_eukaryotes_12: $i > $i).
% 29.22/29.01  tff(decl_31710, type, fn_dna_replication_in_eukaryotes_13: $i > $i).
% 29.22/29.01  tff(decl_31711, type, fn_dna_replication_in_eukaryotes_14: $i > $i).
% 29.22/29.01  tff(decl_31712, type, fn_dna_replication_in_eukaryotes_15: $i > $i).
% 29.22/29.01  tff(decl_31713, type, fn_dna_replication_in_eukaryotes_16: $i > $i).
% 29.22/29.01  tff(decl_31714, type, dna_with_shortened_telomere_1: $i > $o).
% 29.22/29.01  tff(decl_31715, type, fn_dna_replication_in_eukaryotes_17: $i > $i).
% 29.22/29.01  tff(decl_31716, type, fn_dna_replication_in_eukaryotes_18: $i > $i).
% 29.22/29.01  tff(decl_31717, type, fn_dna_replication_in_eukaryotes_19: $i > $i).
% 29.22/29.01  tff(decl_31718, type, fn_dna_replication_in_eukaryotes_20: $i > $i).
% 29.22/29.01  tff(decl_31719, type, fn_dna_replication_in_eukaryotes_21: $i > $i).
% 29.22/29.01  tff(decl_31720, type, telomerase_1: $i > $o).
% 29.22/29.01  tff(decl_31721, type, fn_dna_replication_in_eukaryotes_22: $i > $i).
% 29.22/29.01  tff(decl_31722, type, fn_dna_replication_in_eukaryotes_23: $i > $i).
% 29.22/29.01  tff(decl_31723, type, fn_dna_replication_in_eukaryotes_24: $i > $i).
% 29.22/29.01  tff(decl_31724, type, fn_dna_replication_in_eukaryotes_25: $i > $i).
% 29.22/29.01  tff(decl_31725, type, fn_dna_replication_in_eukaryotes_26: $i > $i).
% 29.22/29.01  tff(decl_31726, type, fn_dna_replication_in_eukaryotes_27: $i > $i).
% 29.22/29.01  tff(decl_31727, type, fn_dna_replication_in_eukaryotes_28: $i > $i).
% 29.22/29.01  tff(decl_31728, type, fn_dna_replication_in_eukaryotes_29: $i > $i).
% 29.22/29.01  tff(decl_31729, type, fn_dna_replication_in_eukaryotes_30: $i > $i).
% 29.22/29.01  tff(decl_31730, type, fn_dna_replication_in_eukaryotes_31: $i > $i).
% 29.22/29.01  tff(decl_31731, type, fn_dna_replication_in_eukaryotes_32: $i > $i).
% 29.22/29.01  tff(decl_31732, type, fn_dna_replication_in_eukaryotes_33: $i > $i).
% 29.22/29.01  tff(decl_31733, type, fn_dna_replication_in_eukaryotes_34: $i > $i).
% 29.22/29.01  tff(decl_31734, type, fn_dna_replication_in_eukaryotes_35: $i > $i).
% 29.22/29.01  tff(decl_31735, type, fn_dna_replication_in_eukaryotes_36: $i > $i).
% 29.22/29.01  tff(decl_31736, type, fn_dna_replication_in_eukaryotes_37: $i > $i).
% 29.22/29.01  tff(decl_31737, type, fn_dna_replication_in_eukaryotes_38: $i > $i).
% 29.22/29.01  tff(decl_31738, type, fn_dna_replication_in_eukaryotes_39: $i > $i).
% 29.22/29.01  tff(decl_31739, type, fn_dna_replication_in_eukaryotes_40: $i > $i).
% 29.22/29.01  tff(decl_31740, type, fn_dna_replication_in_eukaryotes_41: $i > $i).
% 29.22/29.01  tff(decl_31741, type, fn_dna_replication_in_eukaryotes_42: $i > $i).
% 29.22/29.01  tff(decl_31742, type, fn_dna_replication_in_eukaryotes_43: $i > $i).
% 29.22/29.01  tff(decl_31743, type, fn_dna_replication_in_eukaryotes_44: $i > $i).
% 29.22/29.01  tff(decl_31744, type, fn_dna_replication_in_eukaryotes_45: $i > $i).
% 29.22/29.01  tff(decl_31745, type, fn_telomerase_3: $i > $i).
% 29.22/29.01  tff(decl_31746, type, fn_telomerase_4: $i > $i).
% 29.22/29.01  tff(decl_31747, type, fn_polymer_2: $i > $i).
% 29.22/29.01  tff(decl_31748, type, fn_telomerase_10: $i > $i).
% 29.22/29.01  tff(decl_31749, type, fn_polymer_3: $i > $i).
% 29.22/29.01  tff(decl_31750, type, fn_dna_replication_in_eukaryotes_11: $i > $i).
% 29.22/29.01  tff(decl_31751, type, fn_dna_replication_in_eukaryotes_7: $i > $i).
% 29.22/29.01  tff(decl_31752, type, fn_dna_replication_in_eukaryotes_47: $i > $i).
% 29.22/29.01  tff(decl_31753, type, fn_dna_replication_1: $i > $i).
% 29.22/29.01  tff(decl_31754, type, fn_dna_replication_in_eukaryotes_46: $i > $i).
% 29.22/29.01  tff(decl_31755, type, 'DNA-Replication-In-Prokaryotes': $i).
% 29.22/29.01  tff(decl_31756, type, 'The process by which a cell makes an exact copy of its DNA. In prokaryotes is bi-directional and originates at a single origin of replication (OriC).': $i).
% 29.22/29.01  tff(decl_31757, type, 'replication in prokaryotes': $i).
% 29.22/29.01  tff(decl_31758, type, 'dna replication in prokaryote': $i).
% 29.22/29.01  tff(decl_31759, type, 'dna-replication-in-prokaryote': $i).
% 29.22/29.01  tff(decl_31760, type, fn_dna_replication_in_prokaryotes_3: $i > $i).
% 29.22/29.01  tff(decl_31761, type, fn_dna_replication_in_prokaryotes_4: $i > $i).
% 29.22/29.01  tff(decl_31762, type, fn_dna_replication_in_prokaryotes_5: $i > $i).
% 29.22/29.01  tff(decl_31763, type, fn_dna_replication_in_prokaryotes_6: $i > $i).
% 29.22/29.01  tff(decl_31764, type, fn_dna_replication_in_prokaryotes_7: $i > $i).
% 29.22/29.01  tff(decl_31765, type, fn_dna_replication_in_prokaryotes_8: $i > $i).
% 29.22/29.01  tff(decl_31766, type, fn_dna_replication_in_prokaryotes_9: $i > $i).
% 29.22/29.01  tff(decl_31767, type, fn_dna_replication_in_prokaryotes_10: $i > $i).
% 29.22/29.01  tff(decl_31768, type, fn_dna_replication_in_prokaryotes_11: $i > $i).
% 29.22/29.01  tff(decl_31769, type, fn_dna_replication_in_prokaryotes_12: $i > $i).
% 29.22/29.01  tff(decl_31770, type, fn_dna_replication_in_prokaryotes_13: $i > $i).
% 29.22/29.01  tff(decl_31771, type, fn_dna_replication_in_prokaryotes_14: $i > $i).
% 29.22/29.01  tff(decl_31772, type, fn_dna_replication_in_prokaryotes_15: $i > $i).
% 29.22/29.01  tff(decl_31773, type, fn_dna_replication_in_prokaryotes_16: $i > $i).
% 29.22/29.01  tff(decl_31774, type, fn_dna_replication_in_prokaryotes_2: $i > $i).
% 29.22/29.01  tff(decl_31775, type, fn_synthesis_of_nucleic_acid_1: $i > $i).
% 29.22/29.01  tff(decl_31776, type, fn_synthesis_of_nucleic_acid_2: $i > $i).
% 29.22/29.01  tff(decl_31777, type, fn_dna_replication_in_prokaryotes_1: $i > $i).
% 29.22/29.01  tff(decl_31778, type, 'DNA-Replication-Initiation': $i).
% 29.22/29.01  tff(decl_31779, type, 'The events that begin the cell\\s process of copying its DNA, including unwinding of the DNA at the origin of replication, synthesis of new DNA strands, and the formation of a replication fork.': $i).
% 29.22/29.01  tff(decl_31780, type, 'replication initiation': $i).
% 29.22/29.01  tff(decl_31781, type, 'dna replication initiation': $i).
% 29.22/29.01  tff(decl_31782, type, 'initiate replication': $i).
% 29.22/29.01  tff(decl_31783, type, 'dna-replication-initiation': $i).
% 29.22/29.01  tff(decl_31784, type, fn_dna_replication_initiation_1: $i > $i).
% 29.22/29.01  tff(decl_31785, type, fn_dna_replication_initiation_2: $i > $i).
% 29.22/29.01  tff(decl_31786, type, fn_dna_replication_initiation_3: $i > $i).
% 29.22/29.01  tff(decl_31787, type, fn_dna_replication_initiation_4: $i > $i).
% 29.22/29.01  tff(decl_31788, type, fn_dna_replication_initiation_5: $i > $i).
% 29.22/29.01  tff(decl_31789, type, fn_dna_replication_initiation_6: $i > $i).
% 29.22/29.01  tff(decl_31790, type, rna_priming_1: $i > $o).
% 29.22/29.01  tff(decl_31791, type, fn_dna_replication_initiation_7: $i > $i).
% 29.22/29.01  tff(decl_31792, type, fn_dna_replication_initiation_8: $i > $i).
% 29.22/29.01  tff(decl_31793, type, fn_dna_replication_initiation_9: $i > $i).
% 29.22/29.01  tff(decl_31794, type, fn_dna_replication_initiation_10: $i > $i).
% 29.22/29.01  tff(decl_31795, type, fn_dna_replication_initiation_11: $i > $i).
% 29.22/29.01  tff(decl_31796, type, fn_dna_replication_initiation_12: $i > $i).
% 29.22/29.01  tff(decl_31797, type, fn_dna_replication_initiation_13: $i > $i).
% 29.22/29.01  tff(decl_31798, type, fn_dna_replication_initiation_15: $i > $i).
% 29.22/29.01  tff(decl_31799, type, fn_dna_replication_initiation_16: $i > $i).
% 29.22/29.01  tff(decl_31800, type, replication_initiator_protein_1: $i > $o).
% 29.22/29.01  tff(decl_31801, type, fn_dna_replication_initiation_17: $i > $i).
% 29.22/29.01  tff(decl_31802, type, replication_bubble_1: $i > $o).
% 29.22/29.01  tff(decl_31803, type, fn_dna_replication_initiation_18: $i > $i).
% 29.22/29.01  tff(decl_31804, type, fn_dna_replication_initiation_19: $i > $i).
% 29.22/29.01  tff(decl_31805, type, fn_dna_replication_initiation_20: $i > $i).
% 29.22/29.01  tff(decl_31806, type, fn_dna_replication_initiation_21: $i > $i).
% 29.22/29.01  tff(decl_31807, type, fn_dna_replication_initiation_22: $i > $i).
% 29.22/29.01  tff(decl_31808, type, fn_dna_replication_initiation_23: $i > $i).
% 29.22/29.01  tff(decl_31809, type, fn_dna_replication_initiation_24: $i > $i).
% 29.22/29.01  tff(decl_31810, type, single_strand_binding_protein_1: $i > $o).
% 29.22/29.01  tff(decl_31811, type, fn_dna_replication_initiation_25: $i > $i).
% 29.22/29.01  tff(decl_31812, type, fn_dna_replication_initiation_26: $i > $i).
% 29.22/29.01  tff(decl_31813, type, fn_dna_replication_initiation_27: $i > $i).
% 29.22/29.01  tff(decl_31814, type, fn_dna_replication_initiation_28: $i > $i).
% 29.22/29.01  tff(decl_31815, type, fn_dna_replication_initiation_29: $i > $i).
% 29.22/29.01  tff(decl_31816, type, fn_dna_replication_initiation_30: $i > $i).
% 29.22/29.01  tff(decl_31817, type, fn_dna_replication_initiation_31: $i > $i).
% 29.22/29.01  tff(decl_31818, type, fn_dna_replication_initiation_32: $i > $i).
% 29.22/29.01  tff(decl_31819, type, fn_helicase_3: $i > $i).
% 29.22/29.01  tff(decl_31820, type, pyrophosphate_0: $i).
% 29.22/29.01  tff(decl_31821, type, origin_of_replication_0: $i).
% 29.22/29.01  tff(decl_31822, type, add_0: $i).
% 29.22/29.01  tff(decl_31823, type, 'DNA-Replication-Phase': $i).
% 29.22/29.01  tff(decl_31824, type, 'Phase of DNA Replication': $i).
% 29.22/29.01  tff(decl_31825, type, 'undergo the dna replication phase': $i).
% 29.22/29.01  tff(decl_31826, type, 'undergo the dna-replication phase': $i).
% 29.22/29.01  tff(decl_31827, type, 'dna replication phase': $i).
% 29.22/29.01  tff(decl_31828, type, 'dna-replication-phase': $i).
% 29.22/29.01  tff(decl_31829, type, 'DNA-Replication-Termination': $i).
% 29.22/29.01  tff(decl_31830, type, 'The completion of the cell\\s process of copying its DNA.': $i).
% 29.22/29.01  tff(decl_31831, type, 'terminate replication': $i).
% 29.22/29.01  tff(decl_31832, type, 'dna replication termination': $i).
% 29.22/29.01  tff(decl_31833, type, 'dna-replication-termination': $i).
% 29.22/29.01  tff(decl_31834, type, dna_replication_termination_in_eukaryotes_1: $i > $o).
% 29.22/29.01  tff(decl_31835, type, fn_dna_replication_termination_in_eukaryotes_6: $i > $i).
% 29.22/29.01  tff(decl_31836, type, 'DNA-Replication-Termination-In-Eukaryotes': $i).
% 29.22/29.01  tff(decl_31837, type, 'DNA replication completes in eukaryotes with Telomerase enzyme extending the 3\\ end of one of the DNA strand to complete it while Primase and DNA polymerase completing the synthesis of second DNA strand': $i).
% 29.22/29.01  tff(decl_31838, type, 'dna replication termination in eukaryote': $i).
% 29.22/29.01  tff(decl_31839, type, 'dna-replication-termination-in-eukaryote': $i).
% 29.22/29.01  tff(decl_31840, type, fn_dna_replication_termination_in_eukaryotes_1: $i > $i).
% 29.22/29.01  tff(decl_31841, type, fn_dna_replication_termination_in_eukaryotes_2: $i > $i).
% 29.22/29.01  tff(decl_31842, type, fn_dna_replication_termination_in_eukaryotes_3: $i > $i).
% 29.22/29.01  tff(decl_31843, type, parental_strands_1: $i > $o).
% 29.22/29.01  tff(decl_31844, type, fn_dna_replication_termination_in_eukaryotes_4: $i > $i).
% 29.22/29.01  tff(decl_31845, type, fn_dna_replication_termination_in_eukaryotes_5: $i > $i).
% 29.22/29.01  tff(decl_31846, type, fn_dna_replication_termination_in_eukaryotes_8: $i > $i).
% 29.22/29.01  tff(decl_31847, type, fn_dna_replication_termination_in_eukaryotes_9: $i > $i).
% 29.22/29.01  tff(decl_31848, type, fn_dna_replication_termination_in_eukaryotes_10: $i > $i).
% 29.22/29.01  tff(decl_31849, type, fn_dna_replication_termination_in_eukaryotes_11: $i > $i).
% 29.22/29.01  tff(decl_31850, type, daughter_strands_0: $i).
% 29.22/29.01  tff(decl_31851, type, 'DNA-Sequence': $i).
% 29.22/29.01  tff(decl_31852, type, 'DNA sequence is a sequence of DNA which performs a specific function based on the specific pattern of arrangement of its deoxyribonucleotide components along its length.': $i).
% 29.22/29.01  tff(decl_31853, type, 'sequence of dna': $i).
% 29.22/29.01  tff(decl_31854, type, 'dna sequence': $i).
% 29.22/29.01  tff(decl_31855, type, 'dna-sequence': $i).
% 29.22/29.01  tff(decl_31856, type, fn_dna_sequence_1: $i > $i).
% 29.22/29.01  tff(decl_31857, type, fn_dna_sequence_2: $i > $i).
% 29.22/29.01  tff(decl_31858, type, dna_sequencing_1: $i > $o).
% 29.22/29.01  tff(decl_31859, type, 'DNA-Sequencing': $i).
% 29.22/29.01  tff(decl_31860, type, 'A method for determining the order of the nucleotide bases (adenine, guanine, cytosine, and thymine) in a molecule of DNA.': $i).
% 29.22/29.01  tff(decl_31861, type, sequence: $i).
% 29.22/29.01  tff(decl_31862, type, 'dna sequencing': $i).
% 29.22/29.01  tff(decl_31863, type, 'dna-sequencing': $i).
% 29.22/29.01  tff(decl_31864, type, fn_dna_sequencing_1: $i > $i).
% 29.22/29.01  tff(decl_31865, type, fn_dna_sequencing_2: $i > $i).
% 29.22/29.01  tff(decl_31866, type, fn_dna_sequencing_3: $i > $i).
% 29.22/29.01  tff(decl_31867, type, sequencing_machine_1: $i > $o).
% 29.22/29.01  tff(decl_31868, type, fn_dna_sequencing_4: $i > $i).
% 29.22/29.01  tff(decl_31869, type, fn_dna_sequencing_5: $i > $i).
% 29.22/29.01  tff(decl_31870, type, fn_dna_sequencing_6: $i > $i).
% 29.22/29.01  tff(decl_31871, type, 'DNA-Strand': $i).
% 29.22/29.01  tff(decl_31872, type, 'DNA strand is a strand of the DNA having a double helical structure': $i).
% 29.22/29.01  tff(decl_31873, type, 'strand of dna': $i).
% 29.22/29.01  tff(decl_31874, type, 'dna strand': $i).
% 29.22/29.01  tff(decl_31875, type, 'dna-strand': $i).
% 29.22/29.01  tff(decl_31876, type, nucleic_acid_strand_1: $i > $o).
% 29.22/29.01  tff(decl_31877, type, fn_dna_strand_1: $i > $i).
% 29.22/29.01  tff(decl_31878, type, fn_dna_strand_2: $i > $i).
% 29.22/29.01  tff(decl_31879, type, fn_dna_strand_3: $i > $i).
% 29.22/29.01  tff(decl_31880, type, fn_dna_strand_4: $i > $i).
% 29.22/29.01  tff(decl_31881, type, fn_dna_strand_5: $i > $i).
% 29.22/29.01  tff(decl_31882, type, fn_dna_strand_6: $i > $i).
% 29.22/29.01  tff(decl_31883, type, fn_dna_strand_7: $i > $i).
% 29.22/29.01  tff(decl_31884, type, fn_dna_strand_8: $i > $i).
% 29.22/29.01  tff(decl_31885, type, fn_dna_strand_9: $i > $i).
% 29.22/29.01  tff(decl_31886, type, fn_dna_strand_10: $i > $i).
% 29.22/29.01  tff(decl_31887, type, fn_dna_strand_13: $i > $i).
% 29.22/29.01  tff(decl_31888, type, fn_dna_strand_15: $i > $i).
% 29.22/29.01  tff(decl_31889, type, fn_dna_strand_16: $i > $i).
% 29.22/29.01  tff(decl_31890, type, fn_dna_strand_17: $i > $i).
% 29.22/29.01  tff(decl_31891, type, fn_dna_strand_18: $i > $i).
% 29.22/29.01  tff(decl_31892, type, fn_dna_strand_19: $i > $i).
% 29.22/29.01  tff(decl_31893, type, fn_dna_strand_20: $i > $i).
% 29.22/29.01  tff(decl_31894, type, fn_dna_strand_21: $i > $i).
% 29.22/29.01  tff(decl_31895, type, fn_dna_strand_22: $i > $i).
% 29.22/29.01  tff(decl_31896, type, fn_dna_strand_27: $i > $i).
% 29.22/29.01  tff(decl_31897, type, fn_dna_strand_28: $i > $i).
% 29.22/29.01  tff(decl_31898, type, fn_dna_strand_29: $i > $i).
% 29.22/29.01  tff(decl_31899, type, fn_dna_strand_30: $i > $i).
% 29.22/29.01  tff(decl_31900, type, fn_dna_strand_31: $i > $i).
% 29.22/29.01  tff(decl_31901, type, fn_dna_strand_32: $i > $i).
% 29.22/29.01  tff(decl_31902, type, fn_dna_strand_33: $i > $i).
% 29.22/29.01  tff(decl_31903, type, fn_dna_strand_34: $i > $i).
% 29.22/29.01  tff(decl_31904, type, fn_dna_strand_35: $i > $i).
% 29.22/29.01  tff(decl_31905, type, fn_dna_strand_37: $i > $i).
% 29.22/29.01  tff(decl_31906, type, fn_dna_strand_38: $i > $i).
% 29.22/29.01  tff(decl_31907, type, fn_dna_strand_39: $i > $i).
% 29.22/29.01  tff(decl_31908, type, fn_dna_strand_40: $i > $i).
% 29.22/29.01  tff(decl_31909, type, fn_dna_strand_41: $i > $i).
% 29.22/29.01  tff(decl_31910, type, fn_dna_strand_42: $i > $i).
% 29.22/29.01  tff(decl_31911, type, fn_dna_strand_43: $i > $i).
% 29.22/29.01  tff(decl_31912, type, fn_dna_strand_44: $i > $i).
% 29.22/29.01  tff(decl_31913, type, fn_dna_strand_45: $i > $i).
% 29.22/29.01  tff(decl_31914, type, fn_dna_strand_46: $i > $i).
% 29.22/29.01  tff(decl_31915, type, fn_dna_strand_47: $i > $i).
% 29.22/29.01  tff(decl_31916, type, fn_dna_strand_49: $i > $i).
% 29.22/29.01  tff(decl_31917, type, fn_dna_strand_50: $i > $i).
% 29.22/29.01  tff(decl_31918, type, fn_dna_strand_51: $i > $i).
% 29.22/29.01  tff(decl_31919, type, fn_dna_strand_52: $i > $i).
% 29.22/29.01  tff(decl_31920, type, fn_dna_strand_53: $i > $i).
% 29.22/29.01  tff(decl_31921, type, fn_dna_strand_55: $i > $i).
% 29.22/29.01  tff(decl_31922, type, fn_dna_strand_56: $i > $i).
% 29.22/29.01  tff(decl_31923, type, fn_dna_strand_57: $i > $i).
% 29.22/29.01  tff(decl_31924, type, fn_dna_strand_58: $i > $i).
% 29.22/29.01  tff(decl_31925, type, fn_dna_strand_59: $i > $i).
% 29.22/29.01  tff(decl_31926, type, fn_dna_strand_61: $i > $i).
% 29.22/29.01  tff(decl_31927, type, fn_dna_strand_63: $i > $i).
% 29.22/29.01  tff(decl_31928, type, fn_dna_strand_64: $i > $i).
% 29.22/29.01  tff(decl_31929, type, fn_dna_strand_67: $i > $i).
% 29.22/29.01  tff(decl_31930, type, fn_dna_strand_69: $i > $i).
% 29.22/29.01  tff(decl_31931, type, fn_dna_strand_70: $i > $i).
% 29.22/29.01  tff(decl_31932, type, fn_dna_strand_71: $i > $i).
% 29.22/29.01  tff(decl_31933, type, fn_dna_strand_72: $i > $i).
% 29.22/29.01  tff(decl_31934, type, fn_dna_strand_73: $i > $i).
% 29.22/29.01  tff(decl_31935, type, fn_dna_strand_74: $i > $i).
% 29.22/29.01  tff(decl_31936, type, fn_dna_strand_75: $i > $i).
% 29.22/29.01  tff(decl_31937, type, fn_dna_strand_76: $i > $i).
% 29.22/29.01  tff(decl_31938, type, fn_dna_strand_83: $i > $i).
% 29.22/29.01  tff(decl_31939, type, fn_dna_strand_84: $i > $i).
% 29.22/29.01  tff(decl_31940, type, fn_dna_strand_85: $i > $i).
% 29.22/29.01  tff(decl_31941, type, fn_dna_strand_86: $i > $i).
% 29.22/29.01  tff(decl_31942, type, fn_dna_strand_87: $i > $i).
% 29.22/29.01  tff(decl_31943, type, fn_dna_strand_88: $i > $i).
% 29.22/29.01  tff(decl_31944, type, fn_dna_strand_89: $i > $i).
% 29.22/29.01  tff(decl_31945, type, fn_phosphodiester_bond_6: $i > $i).
% 29.22/29.01  tff(decl_31946, type, fn_phosphodiester_bond_27: $i > $i).
% 29.22/29.01  tff(decl_31947, type, deoxyribonucleoside_monophosphate_0: $i).
% 29.22/29.01  tff(decl_31948, type, fn_nucleic_acid_35: $i > $i).
% 29.22/29.01  tff(decl_31949, type, fn_dna_strand_79: $i > $i).
% 29.22/29.01  tff(decl_31950, type, fn_dna_strand_80: $i > $i).
% 29.22/29.01  tff(decl_31951, type, fn_dna_strand_77: $i > $i).
% 29.22/29.01  tff(decl_31952, type, fn_dna_strand_78: $i > $i).
% 29.22/29.01  tff(decl_31953, type, fn_dna_strand_26: $i > $i).
% 29.22/29.01  tff(decl_31954, type, fn_nucleic_acid_32: $i > $i).
% 29.22/29.01  tff(decl_31955, type, fn_dna_strand_25: $i > $i).
% 29.22/29.01  tff(decl_31956, type, fn_nucleic_acid_31: $i > $i).
% 29.22/29.01  tff(decl_31957, type, fn_dna_strand_82: $i > $i).
% 29.22/29.01  tff(decl_31958, type, fn_dna_strand_23: $i > $i).
% 29.22/29.01  tff(decl_31959, type, fn_nucleic_acid_30: $i > $i).
% 29.22/29.01  tff(decl_31960, type, fn_nucleic_acid_12: $i > $i).
% 29.22/29.01  tff(decl_31961, type, fn_nucleic_acid_23: $i > $i).
% 29.22/29.01  tff(decl_31962, type, fn_dna_strand_24: $i > $i).
% 29.22/29.01  tff(decl_31963, type, fn_nucleic_acid_36: $i > $i).
% 29.22/29.01  tff(decl_31964, type, fn_dna_strand_81: $i > $i).
% 29.22/29.01  tff(decl_31965, type, fn_nucleic_acid_11: $i > $i).
% 29.22/29.01  tff(decl_31966, type, fn_nucleic_acid_25: $i > $i).
% 29.22/29.01  tff(decl_31967, type, fn_nucleic_acid_22: $i > $i).
% 29.22/29.01  tff(decl_31968, type, fn_nucleic_acid_26: $i > $i).
% 29.22/29.01  tff(decl_31969, type, fn_nucleic_acid_6: $i > $i).
% 29.22/29.01  tff(decl_31970, type, fn_nucleic_acid_27: $i > $i).
% 29.22/29.01  tff(decl_31971, type, fn_nucleic_acid_24: $i > $i).
% 29.22/29.01  tff(decl_31972, type, fn_nucleic_acid_10: $i > $i).
% 29.22/29.01  tff(decl_31973, type, fn_nucleic_acid_9: $i > $i).
% 29.22/29.01  tff(decl_31974, type, fn_nucleic_acid_7: $i > $i).
% 29.22/29.01  tff(decl_31975, type, fn_dna_strand_36: $i > $i).
% 29.22/29.01  tff(decl_31976, type, fn_nucleic_acid_8: $i > $i).
% 29.22/29.01  tff(decl_31977, type, fn_dna_strand_48: $i > $i).
% 29.22/29.01  tff(decl_31978, type, 'DNA-Technique': $i).
% 29.22/29.01  tff(decl_31979, type, 'Laboratory techniques used when working with DNA': $i).
% 29.22/29.01  tff(decl_31980, type, 'technique of dna': $i).
% 29.22/29.01  tff(decl_31981, type, 'dna technique': $i).
% 29.22/29.01  tff(decl_31982, type, 'dna-technique': $i).
% 29.22/29.01  tff(decl_31983, type, dna_template_1: $i > $o).
% 29.22/29.01  tff(decl_31984, type, 'DNA-Template': $i).
% 29.22/29.01  tff(decl_31985, type, 'A DNA strand that acts as a template for DNA replication or for transcription.': $i).
% 29.22/29.01  tff(decl_31986, type, 'template strand': $i).
% 29.22/29.01  tff(decl_31987, type, 'template-strand': $i).
% 29.22/29.01  tff(decl_31988, type, 'template of dna': $i).
% 29.22/29.01  tff(decl_31989, type, 'dna template': $i).
% 29.22/29.01  tff(decl_31990, type, 'dna-template': $i).
% 29.22/29.01  tff(decl_31991, type, fn_dna_template_1: $i > $i).
% 29.22/29.01  tff(decl_31992, type, fn_dna_template_2: $i > $i).
% 29.22/29.01  tff(decl_31993, type, fn_dna_template_3: $i > $i).
% 29.22/29.01  tff(decl_31994, type, fn_dna_transfer_7: $i > $i).
% 29.22/29.01  tff(decl_31995, type, 'DNA-Transfer': $i).
% 29.22/29.01  tff(decl_31996, type, 'Transfer of DNA fragment from one bacterial cell to another bacterial cell resulting in a recombinant bacteria.': $i).
% 29.22/29.01  tff(decl_31997, type, 'natural process of recombination in bacteria': $i).
% 29.22/29.01  tff(decl_31998, type, 'natural processes of recombination in bacteria': $i).
% 29.22/29.01  tff(decl_31999, type, 'bacterial gene transfer': $i).
% 29.22/29.01  tff(decl_32000, type, transfer: $i).
% 29.22/29.01  tff(decl_32001, type, 'transfer of dna': $i).
% 29.22/29.01  tff(decl_32002, type, 'dna transfer': $i).
% 29.22/29.01  tff(decl_32003, type, 'dna-transfer': $i).
% 29.22/29.01  tff(decl_32004, type, fn_dna_transfer_1: $i > $i).
% 29.22/29.01  tff(decl_32005, type, recombination_1: $i > $o).
% 29.22/29.01  tff(decl_32006, type, fn_dna_transfer_2: $i > $i).
% 29.22/29.01  tff(decl_32007, type, fn_dna_transfer_3: $i > $i).
% 29.22/29.01  tff(decl_32008, type, fn_dna_transfer_4: $i > $i).
% 29.22/29.01  tff(decl_32009, type, fn_dna_transfer_5: $i > $i).
% 29.22/29.01  tff(decl_32010, type, genetic_variation_1: $i > $o).
% 29.22/29.01  tff(decl_32011, type, 'DNA-Virus': $i).
% 29.22/29.01  tff(decl_32012, type, 'A virus whose genetic material is DNA.': $i).
% 29.22/29.01  tff(decl_32013, type, 'virus of dna': $i).
% 29.22/29.01  tff(decl_32014, type, 'dna virus': $i).
% 29.22/29.01  tff(decl_32015, type, 'dna-virus': $i).
% 29.22/29.01  tff(decl_32016, type, fn_dna_virus_1: $i > $i).
% 29.22/29.01  tff(decl_32017, type, fn_dna_virus_2: $i > $i).
% 29.22/29.01  tff(decl_32018, type, 'DNA-With-Shortened-Telomere': $i).
% 29.22/29.01  tff(decl_32019, type, 'The shortening of the telomere regions of the chromosomes which are located at the ends of each chromosome.': $i).
% 29.22/29.01  tff(decl_32020, type, 'dna with shortened telomere': $i).
% 29.22/29.01  tff(decl_32021, type, 'dna-with-shortened-telomere': $i).
% 29.22/29.01  tff(decl_32022, type, fn_dna_with_shortened_telomere_1: $i > $i).
% 29.22/29.01  tff(decl_32023, type, fn_dna_with_shortened_telomere_2: $i > $i).
% 29.22/29.01  tff(decl_32024, type, fn_dna_with_shortened_telomere_4: $i > $i).
% 29.22/29.01  tff(decl_32025, type, fn_dna_with_shortened_telomere_5: $i > $i).
% 29.22/29.01  tff(decl_32026, type, fn_dna_with_shortened_telomere_6: $i > $i).
% 29.22/29.01  tff(decl_32027, type, fn_dna_with_shortened_telomere_7: $i > $i).
% 29.22/29.01  tff(decl_32028, type, fn_dna_with_shortened_telomere_8: $i > $i).
% 29.22/29.01  tff(decl_32029, type, fn_dna_with_shortened_telomere_9: $i > $i).
% 29.22/29.01  tff(decl_32030, type, fn_dna_with_shortened_telomere_10: $i > $i).
% 29.22/29.01  tff(decl_32031, type, fn_dna_with_shortened_telomere_11: $i > $i).
% 29.22/29.01  tff(decl_32032, type, fn_dna_with_shortened_telomere_12: $i > $i).
% 29.22/29.01  tff(decl_32033, type, fn_dna_with_shortened_telomere_13: $i > $i).
% 29.22/29.01  tff(decl_32034, type, fn_dna_with_shortened_telomere_14: $i > $i).
% 29.22/29.01  tff(decl_32035, type, fn_dna_with_shortened_telomere_15: $i > $i).
% 29.22/29.01  tff(decl_32036, type, fn_dna_with_shortened_telomere_16: $i > $i).
% 29.22/29.01  tff(decl_32037, type, fn_dna_with_shortened_telomere_17: $i > $i).
% 29.22/29.01  tff(decl_32038, type, fn_dna_with_shortened_telomere_18: $i > $i).
% 29.22/29.01  tff(decl_32039, type, fn_telomere_5: $i > $i).
% 29.22/29.01  tff(decl_32040, type, fn_telomere_8: $i > $i).
% 29.22/29.01  tff(decl_32041, type, telomere_0: $i).
% 29.22/29.01  tff(decl_32042, type, fn_dna_with_shortened_telomere_3: $i > $i).
% 29.22/29.01  tff(decl_32043, type, fn_dna_with_shortened_telomere_19: $i > $i).
% 29.22/29.01  tff(decl_32044, type, fn_dna_with_shortened_telomere_22: $i > $i).
% 29.22/29.01  tff(decl_32045, type, fn_dna_with_shortened_telomere_21: $i > $i).
% 29.22/29.01  tff(decl_32046, type, fn_dna_with_shortened_telomere_20: $i > $i).
% 29.22/29.01  tff(decl_32047, type, document_1: $i > $o).
% 29.22/29.01  tff(decl_32048, type, 'Document': $i).
% 29.22/29.01  tff(decl_32049, type, 'a written message': $i).
% 29.22/29.01  tff(decl_32050, type, document: $i).
% 29.22/29.01  tff(decl_32051, type, 'written document': $i).
% 29.22/29.01  tff(decl_32052, type, written_document: $i).
% 29.22/29.01  tff(decl_32053, type, papers: $i).
% 29.22/29.01  tff(decl_32054, type, message_field_1: $i > $o).
% 29.22/29.01  tff(decl_32055, type, recording_1: $i > $o).
% 29.22/29.01  tff(decl_32056, type, fn_document_1: $i > $i).
% 29.22/29.01  tff(decl_32057, type, write_1: $i > $o).
% 29.22/29.01  tff(decl_32058, type, dolly_cloning_1: $i > $o).
% 29.22/29.01  tff(decl_32059, type, 'Dolly-Cloning': $i).
% 29.22/29.01  tff(decl_32060, type, 'Dolly, a cloned sheep, was the first reported production of a healthy clone proving that a cell taken from a specific part of the body could recreate a whole individual.': $i).
% 29.22/29.01  tff(decl_32061, type, 'cloning of dolly': $i).
% 29.22/29.01  tff(decl_32062, type, 'dolly cloning': $i).
% 29.22/29.01  tff(decl_32063, type, 'dolly-cloning': $i).
% 29.22/29.01  tff(decl_32064, type, mammal_cloning_1: $i > $o).
% 29.22/29.01  tff(decl_32065, type, fn_dolly_cloning_1: $i > $i).
% 29.22/29.01  tff(decl_32066, type, g0_phase_1: $i > $o).
% 29.22/29.01  tff(decl_32067, type, fn_dolly_cloning_2: $i > $i).
% 29.22/29.01  tff(decl_32068, type, fn_dolly_cloning_3: $i > $i).
% 29.22/29.01  tff(decl_32069, type, fn_dolly_cloning_4: $i > $i).
% 29.22/29.01  tff(decl_32070, type, fn_dolly_cloning_5: $i > $i).
% 29.22/29.01  tff(decl_32071, type, fn_dolly_cloning_6: $i > $i).
% 29.22/29.01  tff(decl_32072, type, fn_dolly_cloning_7: $i > $i).
% 29.22/29.01  tff(decl_32073, type, fn_dolly_cloning_8: $i > $i).
% 29.22/29.01  tff(decl_32074, type, fn_dolly_cloning_9: $i > $i).
% 29.22/29.01  tff(decl_32075, type, fn_dolly_cloning_10: $i > $i).
% 29.22/29.01  tff(decl_32076, type, fn_dolly_cloning_11: $i > $i).
% 29.22/29.01  tff(decl_32077, type, fn_dolly_cloning_12: $i > $i).
% 29.22/29.01  tff(decl_32078, type, fn_dolly_cloning_13: $i > $i).
% 29.22/29.01  tff(decl_32079, type, fn_dolly_cloning_14: $i > $i).
% 29.22/29.01  tff(decl_32080, type, fn_dolly_cloning_15: $i > $i).
% 29.22/29.01  tff(decl_32081, type, fn_mammal_cloning_8: $i > $i).
% 29.22/29.01  tff(decl_32082, type, fn_mammal_cloning_9: $i > $i).
% 29.22/29.01  tff(decl_32083, type, fn_mammal_cloning_14: $i > $i).
% 29.22/29.01  tff(decl_32084, type, fn_mammal_cloning_7: $i > $i).
% 29.22/29.01  tff(decl_32085, type, fn_mammal_cloning_19: $i > $i).
% 29.22/29.01  tff(decl_32086, type, fn_mammal_cloning_24: $i > $i).
% 29.22/29.01  tff(decl_32087, type, fn_mammal_cloning_15: $i > $i).
% 29.22/29.01  tff(decl_32088, type, fn_mammal_cloning_11: $i > $i).
% 29.22/29.01  tff(decl_32089, type, fn_mammal_cloning_25: $i > $i).
% 29.22/29.01  tff(decl_32090, type, fn_mammal_cloning_17: $i > $i).
% 29.22/29.01  tff(decl_32091, type, fn_mammal_cloning_16: $i > $i).
% 29.22/29.01  tff(decl_32092, type, fn_mammal_cloning_13: $i > $i).
% 29.22/29.01  tff(decl_32093, type, fn_mammal_cloning_18: $i > $i).
% 29.22/29.01  tff(decl_32094, type, 'Domain': $i).
% 29.22/29.01  tff(decl_32095, type, 'In biological taxonomy, a category higher than the kingdom level. Modern taxonomists currently recognize three biological domains: Bacteria, Archaea, and Eukarya.': $i).
% 29.22/29.01  tff(decl_32096, type, domain: $i).
% 29.22/29.01  tff(decl_32097, type, domain_bacteria_1: $i > $o).
% 29.22/29.01  tff(decl_32098, type, 'Domain-Bacteria': $i).
% 29.22/29.01  tff(decl_32099, type, 'One of two prokaryotic domains, the other being Archaea.': $i).
% 29.22/29.01  tff(decl_32100, type, eubacteria: $i).
% 29.22/29.01  tff(decl_32101, type, 'domain bacteria': $i).
% 29.22/29.01  tff(decl_32102, type, 'bacteria of domain': $i).
% 29.22/29.01  tff(decl_32103, type, 'domain bacterium': $i).
% 29.22/29.01  tff(decl_32104, type, 'domain-bacteria': $i).
% 29.22/29.01  tff(decl_32105, type, dominance_hierarchy_1: $i > $o).
% 29.22/29.01  tff(decl_32106, type, 'Dominance-Hierarchy': $i).
% 29.22/29.01  tff(decl_32107, type, 'A linear pecking order of animals, where position in the order dictates one\\s social position in the group.': $i).
% 29.22/29.01  tff(decl_32108, type, 'hierarchy of dominance': $i).
% 29.22/29.01  tff(decl_32109, type, 'dominance hierarchy': $i).
% 29.22/29.01  tff(decl_32110, type, 'dominance-hierarchy': $i).
% 29.22/29.01  tff(decl_32111, type, dominant_1: $i > $o).
% 29.22/29.01  tff(decl_32112, type, 'Dominant': $i).
% 29.22/29.01  tff(decl_32113, type, 'Genotype in which one copy of the allele is sufficient to yield a phenotype of the trait.': $i).
% 29.22/29.01  tff(decl_32114, type, dominant: $i).
% 29.22/29.01  tff(decl_32115, type, recessive_1: $i > $o).
% 29.22/29.01  tff(decl_32116, type, 'Dominant-Allele': $i).
% 29.22/29.01  tff(decl_32117, type, 'An allele that is fully expressed in the phenotype of a heterozygote.': $i).
% 29.22/29.01  tff(decl_32118, type, 'allele of dominant': $i).
% 29.22/29.01  tff(decl_32119, type, 'dominant allele': $i).
% 29.22/29.01  tff(decl_32120, type, 'dominant-allele': $i).
% 29.22/29.01  tff(decl_32121, type, dominant_male_1: $i > $o).
% 29.22/29.01  tff(decl_32122, type, 'Dominant-Male': $i).
% 29.22/29.01  tff(decl_32123, type, 'A male who has the dominant allele for an X chromosome gene.': $i).
% 29.22/29.01  tff(decl_32124, type, 'male of dominant': $i).
% 29.22/29.01  tff(decl_32125, type, 'dominant male': $i).
% 29.22/29.01  tff(decl_32126, type, 'dominant-male': $i).
% 29.22/29.01  tff(decl_32127, type, heterozygous_female_1: $i > $o).
% 29.22/29.01  tff(decl_32128, type, homozygous_dominant_female_1: $i > $o).
% 29.22/29.01  tff(decl_32129, type, recessive_male_1: $i > $o).
% 29.22/29.01  tff(decl_32130, type, x_dominant_and_y_1: $i > $o).
% 29.22/29.01  tff(decl_32131, type, fn_dominant_male_1: $i > $i).
% 29.22/29.01  tff(decl_32132, type, fn_dominant_male_2: $i > $i).
% 29.22/29.01  tff(decl_32133, type, 'Dominant-Phenotype': $i).
% 29.22/29.01  tff(decl_32134, type, 'The phenotype of a genotype containing the dominant allele; the parental phenotype that is expressed in a heterozygote,': $i).
% 29.22/29.01  tff(decl_32135, type, 'phenotype of dominant': $i).
% 29.22/29.01  tff(decl_32136, type, 'dominant phenotype': $i).
% 29.22/29.01  tff(decl_32137, type, 'dominant-phenotype': $i).
% 29.22/29.01  tff(decl_32138, type, dominant_species_1: $i > $o).
% 29.22/29.01  tff(decl_32139, type, 'Dominant-Species': $i).
% 29.22/29.01  tff(decl_32140, type, 'A species whose abundance or biomass is substantially higher than other species in the community. Many ecological communities are defined by their dominant species, which can control the abundance and distribution of other species.': $i).
% 29.22/29.01  tff(decl_32141, type, 'dominant-species': $i).
% 29.22/29.01  tff(decl_32142, type, 'species of dominant': $i).
% 29.22/29.01  tff(decl_32143, type, 'dominant species': $i).
% 29.22/29.01  tff(decl_32144, type, 'dominant-specy': $i).
% 29.22/29.01  tff(decl_32145, type, fn_dominant_species_1: $i > $i).
% 29.22/29.01  tff(decl_32146, type, 'Dominant-Trait': $i).
% 29.22/29.01  tff(decl_32147, type, 'A genetic trait in which one copy of the gene is sufficient to yield a phenotype of the trait.': $i).
% 29.22/29.01  tff(decl_32148, type, 'trait of dominant': $i).
% 29.22/29.01  tff(decl_32149, type, 'dominant trait': $i).
% 29.22/29.01  tff(decl_32150, type, 'dominant-trait': $i).
% 29.22/29.01  tff(decl_32151, type, heterozygous_trait_incomplete_dominance_1: $i > $o).
% 29.22/29.01  tff(decl_32152, type, fn_dominant_trait_1: $i > $i).
% 29.22/29.01  tff(decl_32153, type, fn_dominant_trait_2: $i > $i).
% 29.22/29.01  tff(decl_32154, type, fn_dominant_trait_3: $i > $i).
% 29.22/29.01  tff(decl_32155, type, fn_gene_14: $i > $i).
% 29.22/29.01  tff(decl_32156, type, dominant_allele_0: $i).
% 29.22/29.01  tff(decl_32157, type, donate_1: $i > $o).
% 29.22/29.01  tff(decl_32158, type, 'Donate': $i).
% 29.22/29.01  tff(decl_32159, type, donate: $i).
% 29.22/29.01  tff(decl_32160, type, give: $i).
% 29.22/29.01  tff(decl_32161, type, give_1: $i > $o).
% 29.22/29.01  tff(decl_32162, type, fn_donate_1: $i > $i).
% 29.22/29.01  tff(decl_32163, type, donor_role_1: $i > $o).
% 29.22/29.01  tff(decl_32164, type, 'Donor-Role': $i).
% 29.22/29.01  tff(decl_32165, type, donor: $i).
% 29.22/29.01  tff(decl_32166, type, giver: $i).
% 29.22/29.01  tff(decl_32167, type, presenter: $i).
% 29.22/29.01  tff(decl_32168, type, 'role of donor': $i).
% 29.22/29.01  tff(decl_32169, type, 'donor role': $i).
% 29.22/29.01  tff(decl_32170, type, 'donor-role': $i).
% 29.22/29.01  tff(decl_32171, type, fn_donor_role_1: $i > $i).
% 29.22/29.01  tff(decl_32172, type, 'Door': $i).
% 29.22/29.01  tff(decl_32173, type, 'an architectural structure that is part of another architectural structure and playing a portal-covering': $i).
% 29.22/29.01  tff(decl_32174, type, door: $i).
% 29.22/29.01  tff(decl_32175, type, fn_door_1: $i > $i).
% 29.22/29.01  tff(decl_32176, type, fn_door_2: $i > $i).
% 29.22/29.01  tff(decl_32177, type, dopamine_1: $i > $o).
% 29.22/29.01  tff(decl_32178, type, 'Dopamine': $i).
% 29.22/29.01  tff(decl_32179, type, 'A catecholamine neurotransmitter.': $i).
% 29.22/29.01  tff(decl_32180, type, dopamine: $i).
% 29.22/29.01  tff(decl_32181, type, norepinephrine_1: $i > $o).
% 29.22/29.01  tff(decl_32182, type, dormancy_1: $i > $o).
% 29.22/29.01  tff(decl_32183, type, 'Dormancy': $i).
% 29.22/29.01  tff(decl_32184, type, 'A period in an organism\\s life cycle when growth, development, and activity are temporarily stopped.': $i).
% 29.22/29.01  tff(decl_32185, type, dormancy: $i).
% 29.22/29.01  tff(decl_32186, type, dorsal_1: $i > $o).
% 29.22/29.01  tff(decl_32187, type, 'Dorsal': $i).
% 29.22/29.01  tff(decl_32188, type, 'Region on the back of the body.  Opposite of ventral.': $i).
% 29.22/29.01  tff(decl_32189, type, back: $i).
% 29.22/29.01  tff(decl_32190, type, dorsal: $i).
% 29.22/29.01  tff(decl_32191, type, dorsal_lip_1: $i > $o).
% 29.22/29.01  tff(decl_32192, type, 'Dorsal-Lip': $i).
% 29.22/29.01  tff(decl_32193, type, 'In amphibian embryos, the dorsal edge of the blastopore, which is important in establishing the neural tube and logitudinal axis.': $i).
% 29.22/29.01  tff(decl_32194, type, 'lip of dorsal': $i).
% 29.22/29.01  tff(decl_32195, type, 'dorsal lip': $i).
% 29.22/29.01  tff(decl_32196, type, 'dorsal-lip': $i).
% 29.22/29.01  tff(decl_32197, type, embryonic_region_1: $i > $o).
% 29.22/29.01  tff(decl_32198, type, 'Dorsal-Ventral-Axis': $i).
% 29.22/29.01  tff(decl_32199, type, 'A body axis connecting the dorsal and ventral side.': $i).
% 29.22/29.01  tff(decl_32200, type, 'back belly axis': $i).
% 29.22/29.01  tff(decl_32201, type, 'dorsal ventral axis': $i).
% 29.22/29.01  tff(decl_32202, type, 'dorsal-ventral axis': $i).
% 29.22/29.01  tff(decl_32203, type, 'dorsal-ventral-axis': $i).
% 29.22/29.01  tff(decl_32204, type, 'Double-Bond': $i).
% 29.22/29.01  tff(decl_32205, type, 'A type of covalent bond in which two pairs of valence electrons are shared between two atoms.': $i).
% 29.22/29.01  tff(decl_32206, type, 'double covalent bond': $i).
% 29.22/29.01  tff(decl_32207, type, 'double-covalent-bond': $i).
% 29.22/29.01  tff(decl_32208, type, 'bond of double': $i).
% 29.22/29.01  tff(decl_32209, type, 'double bond': $i).
% 29.22/29.01  tff(decl_32210, type, 'double-bond': $i).
% 29.22/29.01  tff(decl_32211, type, double_circulation_1: $i > $o).
% 29.22/29.01  tff(decl_32212, type, 'Double-Circulation': $i).
% 29.22/29.01  tff(decl_32213, type, 'In vertebrate circulatory systems, the condition of having separate pulmonary and systemic loops, with blood passing through the heart at the end of each loop.': $i).
% 29.22/29.01  tff(decl_32214, type, 'circulation of double': $i).
% 29.22/29.01  tff(decl_32215, type, 'double circulation': $i).
% 29.22/29.01  tff(decl_32216, type, 'double-circulation': $i).
% 29.22/29.01  tff(decl_32217, type, single_circulation_1: $i > $o).
% 29.22/29.01  tff(decl_32218, type, double_fertilization_1: $i > $o).
% 29.22/29.01  tff(decl_32219, type, 'Double-Fertilization': $i).
% 29.22/29.01  tff(decl_32220, type, 'Fertilization mechanism in angiosperms in which the female gametophyte joins with two sperm. One sperm fertilizes the egg cell to produce the zygote and the other sperm joins with the two polar haploid nuclei of the female gametophyte to form the endosperm.': $i).
% 29.22/29.01  tff(decl_32221, type, 'undergo double fertilization': $i).
% 29.22/29.01  tff(decl_32222, type, 'fertilization of double': $i).
% 29.22/29.01  tff(decl_32223, type, 'double fertilization': $i).
% 29.22/29.01  tff(decl_32224, type, 'double-fertilization': $i).
% 29.22/29.01  tff(decl_32225, type, plant_fertilization_1: $i > $o).
% 29.22/29.01  tff(decl_32226, type, 'Down-Syndrome': $i).
% 29.22/29.01  tff(decl_32227, type, 'Trisomy 21; a human genetic disease in which patients have three copies of chromsome 21. Down Syndrome is characterized by some degree of mental retardation and a variety of physical defects.': $i).
% 29.22/29.01  tff(decl_32228, type, 'trisomy 21': $i).
% 29.22/29.01  tff(decl_32229, type, 'trisomy-21': $i).
% 29.22/29.01  tff(decl_32230, type, 'syndrome of down': $i).
% 29.22/29.01  tff(decl_32231, type, 'down syndrome': $i).
% 29.22/29.01  tff(decl_32232, type, 'down-syndrome': $i).
% 29.22/29.01  tff(decl_32233, type, fn_down_syndrome_1: $i > $i).
% 29.22/29.01  tff(decl_32234, type, fn_down_syndrome_2: $i > $i).
% 29.22/29.01  tff(decl_32235, type, fn_down_syndrome_3: $i > $i).
% 29.22/29.01  tff(decl_32236, type, has_condition_1: $i > $o).
% 29.22/29.01  tff(decl_32237, type, chromosome_21_0: $i).
% 29.22/29.01  tff(decl_32238, type, downy_mildew_1: $i > $o).
% 29.22/29.01  tff(decl_32239, type, 'Downy-Mildew': $i).
% 29.22/29.01  tff(decl_32240, type, 'Group of molds from the Peronosporaceae, which cause disease in agricultural and other plants.': $i).
% 29.22/29.01  tff(decl_32241, type, oomycota: $i).
% 29.22/29.01  tff(decl_32242, type, 'downy mildew': $i).
% 29.22/29.01  tff(decl_32243, type, 'downy-mildew': $i).
% 29.22/29.01  tff(decl_32244, type, 'Dragonfly': $i).
% 29.22/29.01  tff(decl_32245, type, 'An insect of the order Odonata, distinguised from damselfies by the habit of holding their wings perpendicular to the body when at rest. Dragonflies have large compound eyes and hunt their insect prey on the wing.': $i).
% 29.22/29.01  tff(decl_32246, type, dragonfly: $i).
% 29.22/29.01  tff(decl_32247, type, 'Drawer': $i).
% 29.22/29.01  tff(decl_32248, type, drawer: $i).
% 29.22/29.01  tff(decl_32249, type, 'Drosophila-Development': $i).
% 29.22/29.01  tff(decl_32250, type, 'Drosophila development includes the processes that lead eventually to the formation of a drosophila.': $i).
% 29.22/29.01  tff(decl_32251, type, 'development of drosophila': $i).
% 29.22/29.01  tff(decl_32252, type, 'drosophila development': $i).
% 29.22/29.01  tff(decl_32253, type, 'drosophila-development': $i).
% 29.22/29.01  tff(decl_32254, type, fn_drosophila_development_1: $i > $i).
% 29.22/29.01  tff(decl_32255, type, fn_drosophila_development_2: $i > $i).
% 29.22/29.01  tff(decl_32256, type, fn_drosophila_development_3: $i > $i).
% 29.22/29.01  tff(decl_32257, type, fn_drosophila_development_6: $i > $i).
% 29.22/29.01  tff(decl_32258, type, fn_drosophila_development_7: $i > $i).
% 29.22/29.01  tff(decl_32259, type, fn_drosophila_development_8: $i > $i).
% 29.22/29.01  tff(decl_32260, type, transcription_of_bicoid_gene_1: $i > $o).
% 29.22/29.01  tff(decl_32261, type, fn_drosophila_development_9: $i > $i).
% 29.22/29.01  tff(decl_32262, type, fn_drosophila_development_10: $i > $i).
% 29.22/29.01  tff(decl_32263, type, fn_drosophila_development_11: $i > $i).
% 29.22/29.01  tff(decl_32264, type, fn_drosophila_development_12: $i > $i).
% 29.22/29.01  tff(decl_32265, type, nurse_cell_1: $i > $o).
% 29.22/29.01  tff(decl_32266, type, fn_drosophila_development_13: $i > $i).
% 29.22/29.01  tff(decl_32267, type, fn_drosophila_development_14: $i > $i).
% 29.22/29.01  tff(decl_32268, type, fn_drosophila_development_15: $i > $i).
% 29.22/29.01  tff(decl_32269, type, posterior_end_1: $i > $o).
% 29.22/29.01  tff(decl_32270, type, fn_drosophila_development_16: $i > $i).
% 29.22/29.01  tff(decl_32271, type, fn_drosophila_development_17: $i > $i).
% 29.22/29.01  tff(decl_32272, type, fn_drosophila_development_18: $i > $i).
% 29.22/29.01  tff(decl_32273, type, fn_drosophila_development_19: $i > $i).
% 29.22/29.01  tff(decl_32274, type, pupa_1: $i > $o).
% 29.22/29.01  tff(decl_32275, type, fn_drosophila_development_20: $i > $i).
% 29.22/29.01  tff(decl_32276, type, fn_drosophila_development_21: $i > $i).
% 29.22/29.01  tff(decl_32277, type, fn_drosophila_development_22: $i > $i).
% 29.22/29.01  tff(decl_32278, type, fn_drosophila_development_23: $i > $i).
% 29.22/29.01  tff(decl_32279, type, fn_drosophila_development_24: $i > $i).
% 29.22/29.01  tff(decl_32280, type, fn_drosophila_development_25: $i > $i).
% 29.22/29.01  tff(decl_32281, type, pupal_case_1: $i > $o).
% 29.22/29.01  tff(decl_32282, type, fn_drosophila_development_26: $i > $i).
% 29.22/29.01  tff(decl_32283, type, fn_drosophila_development_27: $i > $i).
% 29.22/29.01  tff(decl_32284, type, fn_drosophila_development_28: $i > $i).
% 29.22/29.01  tff(decl_32285, type, maturation_1: $i > $o).
% 29.22/29.01  tff(decl_32286, type, fn_drosophila_development_29: $i > $i).
% 29.22/29.01  tff(decl_32287, type, fn_drosophila_development_30: $i > $i).
% 29.22/29.01  tff(decl_32288, type, fn_drosophila_development_31: $i > $i).
% 29.22/29.01  tff(decl_32289, type, follicle_cell_1: $i > $o).
% 29.22/29.01  tff(decl_32290, type, fn_drosophila_development_32: $i > $i).
% 29.22/29.01  tff(decl_32291, type, fn_drosophila_development_33: $i > $i).
% 29.22/29.01  tff(decl_32292, type, fn_drosophila_development_34: $i > $i).
% 29.22/29.01  tff(decl_32293, type, fn_drosophila_development_35: $i > $i).
% 29.22/29.01  tff(decl_32294, type, fn_drosophila_development_36: $i > $i).
% 29.22/29.01  tff(decl_32295, type, fn_drosophila_development_37: $i > $i).
% 29.22/29.01  tff(decl_32296, type, fn_drosophila_development_38: $i > $i).
% 29.22/29.01  tff(decl_32297, type, fn_drosophila_development_39: $i > $i).
% 29.22/29.01  tff(decl_32298, type, fn_drosophila_development_40: $i > $i).
% 29.22/29.01  tff(decl_32299, type, fn_drosophila_development_41: $i > $i).
% 29.22/29.01  tff(decl_32300, type, egg_laying_process_1: $i > $o).
% 29.22/29.01  tff(decl_32301, type, fn_drosophila_development_42: $i > $i).
% 29.22/29.01  tff(decl_32302, type, s_phase_1: $i > $o).
% 29.22/29.01  tff(decl_32303, type, fn_drosophila_development_43: $i > $i).
% 29.22/29.01  tff(decl_32304, type, fn_drosophila_development_44: $i > $i).
% 29.22/29.01  tff(decl_32305, type, fn_drosophila_development_45: $i > $i).
% 29.22/29.01  tff(decl_32306, type, fn_drosophila_development_46: $i > $i).
% 29.22/29.01  tff(decl_32307, type, fn_drosophila_development_47: $i > $i).
% 29.22/29.01  tff(decl_32308, type, fn_drosophila_development_48: $i > $i).
% 29.22/29.01  tff(decl_32309, type, fn_drosophila_development_49: $i > $i).
% 29.22/29.01  tff(decl_32310, type, fn_drosophila_development_50: $i > $i).
% 29.22/29.01  tff(decl_32311, type, fn_drosophila_development_51: $i > $i).
% 29.22/29.01  tff(decl_32312, type, fn_drosophila_development_52: $i > $i).
% 29.22/29.01  tff(decl_32313, type, gene_activation_cascade_1: $i > $o).
% 29.22/29.01  tff(decl_32314, type, fn_drosophila_development_53: $i > $i).
% 29.22/29.01  tff(decl_32315, type, fn_drosophila_development_54: $i > $i).
% 29.22/29.01  tff(decl_32316, type, yolk_1: $i > $o).
% 29.22/29.01  tff(decl_32317, type, fn_drosophila_development_55: $i > $i).
% 29.22/29.01  tff(decl_32318, type, fn_drosophila_development_56: $i > $i).
% 29.22/29.01  tff(decl_32319, type, egg_shell_1: $i > $o).
% 29.22/29.01  tff(decl_32320, type, fn_drosophila_development_57: $i > $i).
% 29.22/29.01  tff(decl_32321, type, fn_drosophila_development_58: $i > $i).
% 29.22/29.01  tff(decl_32322, type, fn_drosophila_development_60: $i > $i).
% 29.22/29.01  tff(decl_32323, type, fn_drosophila_development_61: $i > $i).
% 29.22/29.01  tff(decl_32324, type, fn_drosophila_development_62: $i > $i).
% 29.22/29.01  tff(decl_32325, type, fn_drosophila_development_63: $i > $i).
% 29.22/29.01  tff(decl_32326, type, fn_drosophila_development_64: $i > $i).
% 29.22/29.01  tff(decl_32327, type, fn_drosophila_development_65: $i > $i).
% 29.22/29.01  tff(decl_32328, type, fn_drosophila_development_66: $i > $i).
% 29.22/29.01  tff(decl_32329, type, fn_drosophila_development_67: $i > $i).
% 29.22/29.01  tff(decl_32330, type, fn_drosophila_development_68: $i > $i).
% 29.22/29.01  tff(decl_32331, type, fn_drosophila_development_69: $i > $i).
% 29.22/29.01  tff(decl_32332, type, fn_drosophila_development_70: $i > $i).
% 29.22/29.01  tff(decl_32333, type, fn_drosophila_development_71: $i > $i).
% 29.22/29.01  tff(decl_32334, type, fn_drosophila_development_72: $i > $i).
% 29.22/29.01  tff(decl_32335, type, fn_drosophila_development_73: $i > $i).
% 29.22/29.01  tff(decl_32336, type, fn_drosophila_development_74: $i > $i).
% 29.22/29.01  tff(decl_32337, type, fn_drosophila_development_75: $i > $i).
% 29.22/29.01  tff(decl_32338, type, fn_drosophila_development_76: $i > $i).
% 29.22/29.01  tff(decl_32339, type, fn_drosophila_development_77: $i > $i).
% 29.22/29.01  tff(decl_32340, type, fn_drosophila_development_78: $i > $i).
% 29.22/29.01  tff(decl_32341, type, fn_drosophila_development_79: $i > $i).
% 29.22/29.01  tff(decl_32342, type, fn_drosophila_development_80: $i > $i).
% 29.22/29.01  tff(decl_32343, type, fn_drosophila_development_81: $i > $i).
% 29.22/29.01  tff(decl_32344, type, fn_drosophila_development_82: $i > $i).
% 29.22/29.01  tff(decl_32345, type, fn_drosophila_development_83: $i > $i).
% 29.22/29.01  tff(decl_32346, type, fn_drosophila_development_84: $i > $i).
% 29.22/29.01  tff(decl_32347, type, fn_drosophila_development_85: $i > $i).
% 29.22/29.01  tff(decl_32348, type, fn_drosophila_development_86: $i > $i).
% 29.22/29.01  tff(decl_32349, type, fn_drosophila_development_87: $i > $i).
% 29.22/29.01  tff(decl_32350, type, fn_drosophila_development_88: $i > $i).
% 29.22/29.01  tff(decl_32351, type, fn_drosophila_development_89: $i > $i).
% 29.22/29.01  tff(decl_32352, type, fn_drosophila_development_90: $i > $i).
% 29.22/29.01  tff(decl_32353, type, fn_drosophila_development_91: $i > $i).
% 29.22/29.01  tff(decl_32354, type, fn_drosophila_development_92: $i > $i).
% 29.22/29.01  tff(decl_32355, type, fn_drosophila_development_93: $i > $i).
% 29.22/29.01  tff(decl_32356, type, fn_drosophila_development_94: $i > $i).
% 29.22/29.01  tff(decl_32357, type, fn_drosophila_development_95: $i > $i).
% 29.22/29.01  tff(decl_32358, type, fn_drosophila_development_96: $i > $i).
% 29.22/29.01  tff(decl_32359, type, fn_drosophila_development_97: $i > $i).
% 29.22/29.01  tff(decl_32360, type, fn_drosophila_development_98: $i > $i).
% 29.22/29.01  tff(decl_32361, type, fn_drosophila_development_99: $i > $i).
% 29.22/29.01  tff(decl_32362, type, fn_drosophila_development_100: $i > $i).
% 29.22/29.01  tff(decl_32363, type, fn_drosophila_development_101: $i > $i).
% 29.22/29.01  tff(decl_32364, type, fn_drosophila_development_102: $i > $i).
% 29.22/29.01  tff(decl_32365, type, fn_drosophila_development_103: $i > $i).
% 29.22/29.01  tff(decl_32366, type, fn_drosophila_development_104: $i > $i).
% 29.22/29.01  tff(decl_32367, type, fn_drosophila_development_105: $i > $i).
% 29.22/29.01  tff(decl_32368, type, fn_drosophila_development_106: $i > $i).
% 29.22/29.01  tff(decl_32369, type, fn_drosophila_development_107: $i > $i).
% 29.22/29.01  tff(decl_32370, type, fn_drosophila_development_108: $i > $i).
% 29.22/29.01  tff(decl_32371, type, fn_drosophila_development_109: $i > $i).
% 29.22/29.01  tff(decl_32372, type, larva_hatching_1: $i > $o).
% 29.22/29.01  tff(decl_32373, type, fn_drosophila_development_110: $i > $i).
% 29.22/29.01  tff(decl_32374, type, fn_drosophila_development_111: $i > $i).
% 29.22/29.01  tff(decl_32375, type, larva_1: $i > $o).
% 29.22/29.01  tff(decl_32376, type, fn_drosophila_development_112: $i > $i).
% 29.22/29.01  tff(decl_32377, type, fn_drosophila_development_113: $i > $i).
% 29.22/29.01  tff(decl_32378, type, fn_drosophila_development_114: $i > $i).
% 29.22/29.01  tff(decl_32379, type, fn_drosophila_development_115: $i > $i).
% 29.22/29.01  tff(decl_32380, type, fn_drosophila_development_116: $i > $i).
% 29.22/29.01  tff(decl_32381, type, fn_drosophila_development_117: $i > $i).
% 29.22/29.01  tff(decl_32382, type, fn_drosophila_development_118: $i > $i).
% 29.22/29.01  tff(decl_32383, type, fn_drosophila_development_119: $i > $i).
% 29.22/29.01  tff(decl_32384, type, fn_drosophila_development_120: $i > $i).
% 29.22/29.01  tff(decl_32385, type, fn_drosophila_development_121: $i > $i).
% 29.22/29.01  tff(decl_32386, type, fn_drosophila_development_122: $i > $i).
% 29.22/29.01  tff(decl_32387, type, fn_drosophila_development_123: $i > $i).
% 29.22/29.01  tff(decl_32388, type, fn_drosophila_development_124: $i > $i).
% 29.22/29.01  tff(decl_32389, type, fn_drosophila_development_125: $i > $i).
% 29.22/29.01  tff(decl_32390, type, fn_drosophila_development_126: $i > $i).
% 29.22/29.01  tff(decl_32391, type, fn_drosophila_development_127: $i > $i).
% 29.22/29.01  tff(decl_32392, type, fn_drosophila_development_128: $i > $i).
% 29.22/29.01  tff(decl_32393, type, fn_drosophila_development_129: $i > $i).
% 29.22/29.01  tff(decl_32394, type, fn_drosophila_development_130: $i > $i).
% 29.22/29.01  tff(decl_32395, type, fn_drosophila_development_131: $i > $i).
% 29.22/29.01  tff(decl_32396, type, fn_drosophila_development_132: $i > $i).
% 29.22/29.01  tff(decl_32397, type, oogenesis_1: $i > $o).
% 29.22/29.01  tff(decl_32398, type, fn_drosophila_development_133: $i > $i).
% 29.22/29.01  tff(decl_32399, type, fn_drosophila_development_134: $i > $i).
% 29.22/29.01  tff(decl_32400, type, fn_drosophila_development_135: $i > $i).
% 29.22/29.01  tff(decl_32401, type, fn_drosophila_development_136: $i > $i).
% 29.22/29.01  tff(decl_32402, type, homeotic_gene_1: $i > $o).
% 29.22/29.01  tff(decl_32403, type, fn_drosophila_development_137: $i > $i).
% 29.22/29.01  tff(decl_32404, type, fn_drosophila_development_138: $i > $i).
% 29.22/29.01  tff(decl_32405, type, fn_drosophila_development_139: $i > $i).
% 29.22/29.01  tff(decl_32406, type, fn_drosophila_development_140: $i > $i).
% 29.22/29.01  tff(decl_32407, type, fn_drosophila_development_141: $i > $i).
% 29.22/29.01  tff(decl_32408, type, gap_gene_1: $i > $o).
% 29.22/29.01  tff(decl_32409, type, fn_drosophila_development_142: $i > $i).
% 29.22/29.01  tff(decl_32410, type, fn_drosophila_development_143: $i > $i).
% 29.22/29.01  tff(decl_32411, type, fn_drosophila_development_144: $i > $i).
% 29.22/29.01  tff(decl_32412, type, fn_drosophila_development_145: $i > $i).
% 29.22/29.01  tff(decl_32413, type, fn_drosophila_development_146: $i > $i).
% 29.22/29.01  tff(decl_32414, type, segment_polarity_gene_1: $i > $o).
% 29.22/29.01  tff(decl_32415, type, fn_drosophila_development_147: $i > $i).
% 29.22/29.01  tff(decl_32416, type, fn_drosophila_development_148: $i > $i).
% 29.22/29.01  tff(decl_32417, type, fn_drosophila_development_149: $i > $i).
% 29.22/29.01  tff(decl_32418, type, fn_drosophila_development_150: $i > $i).
% 29.22/29.01  tff(decl_32419, type, fn_drosophila_development_151: $i > $i).
% 29.22/29.01  tff(decl_32420, type, fn_drosophila_development_152: $i > $i).
% 29.22/29.01  tff(decl_32421, type, pair_rule_gene_1: $i > $o).
% 29.22/29.01  tff(decl_32422, type, fn_drosophila_development_153: $i > $i).
% 29.22/29.01  tff(decl_32423, type, fn_drosophila_development_154: $i > $i).
% 29.22/29.01  tff(decl_32424, type, fn_drosophila_development_155: $i > $i).
% 29.22/29.01  tff(decl_32425, type, fn_drosophila_development_156: $i > $i).
% 29.22/29.01  tff(decl_32426, type, fn_drosophila_development_157: $i > $i).
% 29.22/29.01  tff(decl_32427, type, segmentation_gene_1: $i > $o).
% 29.22/29.01  tff(decl_32428, type, fn_drosophila_development_158: $i > $i).
% 29.22/29.01  tff(decl_32429, type, fn_drosophila_development_159: $i > $i).
% 29.22/29.01  tff(decl_32430, type, fn_drosophila_development_160: $i > $i).
% 29.22/29.01  tff(decl_32431, type, fn_drosophila_development_161: $i > $i).
% 29.22/29.01  tff(decl_32432, type, fn_drosophila_development_162: $i > $i).
% 29.22/29.01  tff(decl_32433, type, fn_drosophila_development_163: $i > $i).
% 29.22/29.01  tff(decl_32434, type, fn_drosophila_development_164: $i > $i).
% 29.22/29.01  tff(decl_32435, type, fn_drosophila_development_165: $i > $i).
% 29.22/29.01  tff(decl_32436, type, fn_drosophila_development_166: $i > $i).
% 29.22/29.01  tff(decl_32437, type, shell_1: $i > $o).
% 29.22/29.01  tff(decl_32438, type, fn_drosophila_development_167: $i > $i).
% 29.22/29.01  tff(decl_32439, type, fn_drosophila_development_168: $i > $i).
% 29.22/29.01  tff(decl_32440, type, fn_drosophila_development_169: $i > $i).
% 29.22/29.01  tff(decl_32441, type, fn_drosophila_development_170: $i > $i).
% 29.22/29.01  tff(decl_32442, type, fn_drosophila_development_171: $i > $i).
% 29.22/29.01  tff(decl_32443, type, fn_drosophila_development_172: $i > $i).
% 29.22/29.01  tff(decl_32444, type, fn_drosophila_development_173: $i > $i).
% 29.22/29.01  tff(decl_32445, type, fn_drosophila_development_174: $i > $i).
% 29.22/29.01  tff(decl_32446, type, fn_drosophila_development_175: $i > $i).
% 29.22/29.01  tff(decl_32447, type, fn_drosophila_development_176: $i > $i).
% 29.22/29.01  tff(decl_32448, type, fn_drosophila_development_177: $i > $i).
% 29.22/29.01  tff(decl_32449, type, fn_metamorphosis_1: $i > $i).
% 29.22/29.01  tff(decl_32450, type, fn_multinucleated_stage_2: $i > $i).
% 29.22/29.01  tff(decl_32451, type, multinucleated_cell_1: $i > $o).
% 29.22/29.01  tff(decl_32452, type, fn_ovary_1: $i > $i).
% 29.22/29.01  tff(decl_32453, type, fn_segment_formation_2: $i > $i).
% 29.22/29.01  tff(decl_32454, type, fn_nurse_cell_2: $i > $i).
% 29.22/29.01  tff(decl_32455, type, fn_nurse_cell_3: $i > $i).
% 29.22/29.01  tff(decl_32456, type, fn_larva_hatching_3: $i > $i).
% 29.22/29.01  tff(decl_32457, type, fn_embryogenesis_41: $i > $i).
% 29.22/29.01  tff(decl_32458, type, fn_embryogenesis_16: $i > $i).
% 29.22/29.01  tff(decl_32459, type, fn_embryogenesis_29: $i > $i).
% 29.22/29.01  tff(decl_32460, type, fn_synthesis_of_mrna_2: $i > $i).
% 29.22/29.01  tff(decl_32461, type, fn_gene_activation_8: $i > $i).
% 29.22/29.01  tff(decl_32462, type, fn_gene_activation_9: $i > $i).
% 29.22/29.01  tff(decl_32463, type, fn_gene_activation_10: $i > $i).
% 29.22/29.01  tff(decl_32464, type, fn_larva_hatching_1: $i > $i).
% 29.22/29.01  tff(decl_32465, type, fn_segmentation_gene_2: $i > $i).
% 29.22/29.01  tff(decl_32466, type, fn_embryogenesis_33: $i > $i).
% 29.22/29.01  tff(decl_32467, type, fn_positional_information_2: $i > $i).
% 29.22/29.01  tff(decl_32468, type, fn_embryogenesis_43: $i > $i).
% 29.22/29.01  tff(decl_32469, type, "10": $i).
% 29.22/29.01  tff(decl_32470, type, s_phase_0: $i).
% 29.22/29.01  tff(decl_32471, type, gap_gene_0: $i).
% 29.22/29.01  tff(decl_32472, type, 'Transcription factor 3': $i).
% 29.22/29.01  tff(decl_32473, type, 'Transcription factor 2': $i).
% 29.22/29.01  tff(decl_32474, type, 'Trnascription factor 1': $i).
% 29.22/29.01  tff(decl_32475, type, drosophila_homeotic_gene_1: $i > $o).
% 29.22/29.01  tff(decl_32476, type, 'Drosophila-Homeotic-Gene': $i).
% 29.22/29.01  tff(decl_32477, type, 'Homeotic gene present in fruit fly.': $i).
% 29.22/29.01  tff(decl_32478, type, 'drosophila homeotic gene': $i).
% 29.22/29.01  tff(decl_32479, type, 'drosophila-homeotic-gene': $i).
% 29.22/29.01  tff(decl_32480, type, insect_homeotic_gene_1: $i > $o).
% 29.22/29.01  tff(decl_32481, type, 'Drosophila-Melanogaster': $i).
% 29.22/29.01  tff(decl_32482, type, 'A species of Diptera, or the order of flies, in the family Drosophilidae. The species is commonly known as the common fruit fly or vinegar fly. This species is one of the most commonly used model organisms in biology': $i).
% 29.22/29.01  tff(decl_32483, type, 'd. melanogaster': $i).
% 29.22/29.01  tff(decl_32484, type, 'drosophila melanogaster': $i).
% 29.22/29.01  tff(decl_32485, type, fruitfly: $i).
% 29.22/29.01  tff(decl_32486, type, 'drosophila-melanogaster': $i).
% 29.22/29.01  tff(decl_32487, type, fn_drosophila_melanogaster_1: $i > $i).
% 29.22/29.01  tff(decl_32488, type, fn_drosophila_melanogaster_2: $i > $i).
% 29.22/29.01  tff(decl_32489, type, fn_drosophila_melanogaster_3: $i > $i).
% 29.22/29.01  tff(decl_32490, type, linkage_map_1: $i > $o).
% 29.22/29.01  tff(decl_32491, type, fn_drosophila_melanogaster_4: $i > $i).
% 29.22/29.01  tff(decl_32492, type, fn_drosophila_melanogaster_6: $i > $i).
% 29.22/29.01  tff(decl_32493, type, fn_drosophila_melanogaster_7: $i > $i).
% 29.22/29.01  tff(decl_32494, type, fn_drosophila_melanogaster_8: $i > $i).
% 29.22/29.01  tff(decl_32495, type, fn_drosophila_melanogaster_9: $i > $i).
% 29.22/29.01  tff(decl_32496, type, fn_drosophila_melanogaster_10: $i > $i).
% 29.22/29.01  tff(decl_32497, type, fn_drosophila_melanogaster_15: $i > $i).
% 29.22/29.01  tff(decl_32498, type, fn_drosophila_melanogaster_16: $i > $i).
% 29.22/29.01  tff(decl_32499, type, fn_drosophila_melanogaster_17: $i > $i).
% 29.22/29.01  tff(decl_32500, type, fn_drosophila_melanogaster_19: $i > $i).
% 29.22/29.01  tff(decl_32501, type, fn_drosophila_melanogaster_20: $i > $i).
% 29.22/29.01  tff(decl_32502, type, fn_drosophila_melanogaster_21: $i > $i).
% 29.22/29.01  tff(decl_32503, type, fn_drosophila_melanogaster_22: $i > $i).
% 29.22/29.01  tff(decl_32504, type, fn_drosophila_melanogaster_23: $i > $i).
% 29.22/29.01  tff(decl_32505, type, fn_drosophila_melanogaster_24: $i > $i).
% 29.22/29.01  tff(decl_32506, type, fn_drosophila_melanogaster_25: $i > $i).
% 29.22/29.01  tff(decl_32507, type, fn_drosophila_melanogaster_26: $i > $i).
% 29.22/29.01  tff(decl_32508, type, fn_drosophila_melanogaster_27: $i > $i).
% 29.22/29.01  tff(decl_32509, type, fn_drosophila_melanogaster_28: $i > $i).
% 29.22/29.01  tff(decl_32510, type, fn_drosophila_melanogaster_29: $i > $i).
% 29.22/29.01  tff(decl_32511, type, fn_drosophila_melanogaster_30: $i > $i).
% 29.22/29.01  tff(decl_32512, type, fn_drosophila_melanogaster_31: $i > $i).
% 29.22/29.01  tff(decl_32513, type, fn_drosophila_melanogaster_32: $i > $i).
% 29.22/29.01  tff(decl_32514, type, fn_drosophila_melanogaster_33: $i > $i).
% 29.22/29.01  tff(decl_32515, type, fn_drosophila_melanogaster_34: $i > $i).
% 29.22/29.01  tff(decl_32516, type, fn_drosophila_melanogaster_35: $i > $i).
% 29.22/29.01  tff(decl_32517, type, fn_drosophila_melanogaster_36: $i > $i).
% 29.22/29.01  tff(decl_32518, type, fn_drosophila_melanogaster_37: $i > $i).
% 29.22/29.01  tff(decl_32519, type, fn_drosophila_melanogaster_38: $i > $i).
% 29.22/29.01  tff(decl_32520, type, fn_drosophila_melanogaster_39: $i > $i).
% 29.22/29.01  tff(decl_32521, type, fn_drosophila_melanogaster_40: $i > $i).
% 29.22/29.01  tff(decl_32522, type, fn_drosophila_melanogaster_41: $i > $i).
% 29.22/29.01  tff(decl_32523, type, fn_drosophila_melanogaster_42: $i > $i).
% 29.22/29.01  tff(decl_32524, type, fn_drosophila_melanogaster_43: $i > $i).
% 29.22/29.01  tff(decl_32525, type, fn_drosophila_melanogaster_44: $i > $i).
% 29.22/29.01  tff(decl_32526, type, reproduce_0: $i).
% 29.22/29.01  tff(decl_32527, type, animal_0: $i).
% 29.22/29.01  tff(decl_32528, type, fn_fruit_fly_6: $i > $i).
% 29.22/29.01  tff(decl_32529, type, fn_drosophila_melanogaster_45: $i > $i).
% 29.22/29.01  tff(decl_32530, type, fn_fruit_fly_2: $i > $i).
% 29.22/29.01  tff(decl_32531, type, fn_fruit_fly_5: $i > $i).
% 29.22/29.01  tff(decl_32532, type, fn_drosophila_melanogaster_46: $i > $i).
% 29.22/29.01  tff(decl_32533, type, fn_fruit_fly_1: $i > $i).
% 29.22/29.01  tff(decl_32534, type, fn_fruit_fly_17: $i > $i).
% 29.22/29.01  tff(decl_32535, type, fn_fruit_fly_23: $i > $i).
% 29.22/29.01  tff(decl_32536, type, fn_fruit_fly_31: $i > $i).
% 29.22/29.01  tff(decl_32537, type, fn_fruit_fly_24: $i > $i).
% 29.22/29.01  tff(decl_32538, type, fn_fruit_fly_18: $i > $i).
% 29.22/29.01  tff(decl_32539, type, fn_fruit_fly_28: $i > $i).
% 29.22/29.01  tff(decl_32540, type, fn_fruit_fly_37: $i > $i).
% 29.22/29.01  tff(decl_32541, type, fn_fruit_fly_13: $i > $i).
% 29.22/29.01  tff(decl_32542, type, fn_fruit_fly_27: $i > $i).
% 29.22/29.01  tff(decl_32543, type, fn_fruit_fly_38: $i > $i).
% 29.22/29.01  tff(decl_32544, type, fn_fruit_fly_11: $i > $i).
% 29.22/29.01  tff(decl_32545, type, fn_fruit_fly_10: $i > $i).
% 29.22/29.01  tff(decl_32546, type, fn_fruit_fly_25: $i > $i).
% 29.22/29.01  tff(decl_32547, type, fn_fruit_fly_21: $i > $i).
% 29.22/29.01  tff(decl_32548, type, fn_fruit_fly_39: $i > $i).
% 29.22/29.01  tff(decl_32549, type, fn_fruit_fly_26: $i > $i).
% 29.22/29.01  tff(decl_32550, type, fn_fruit_fly_36: $i > $i).
% 29.22/29.01  tff(decl_32551, type, fn_fruit_fly_29: $i > $i).
% 29.22/29.01  tff(decl_32552, type, fn_fruit_fly_30: $i > $i).
% 29.22/29.01  tff(decl_32553, type, drought_1: $i > $o).
% 29.22/29.01  tff(decl_32554, type, 'Drought': $i).
% 29.22/29.01  tff(decl_32555, type, 'Extended period of time in which precipitation is below normal in an ecosystem.': $i).
% 29.22/29.01  tff(decl_32556, type, drought: $i).
% 29.22/29.01  tff(decl_32557, type, 'Drug': $i).
% 29.22/29.01  tff(decl_32558, type, 'Drug is a chemical substance which is introduced into the body of an organism affects the processes of the mind or body': $i).
% 29.22/29.01  tff(decl_32559, type, drug: $i).
% 29.22/29.01  tff(decl_32560, type, drug_resistance_1: $i > $o).
% 29.22/29.01  tff(decl_32561, type, 'Drug-Resistance': $i).
% 29.22/29.01  tff(decl_32562, type, 'The reduction in effectiveness of an antimicrobial drug, due to the microbes\\ evolved ability to overcome the intended effects of the drug.': $i).
% 29.22/29.01  tff(decl_32563, type, 'resistance of drug': $i).
% 29.22/29.01  tff(decl_32564, type, 'drug resistance': $i).
% 29.22/29.01  tff(decl_32565, type, 'drug-resistance': $i).
% 29.22/29.01  tff(decl_32566, type, drug_resistance_process_1: $i > $o).
% 29.22/29.01  tff(decl_32567, type, 'Drug-Resistance-Process': $i).
% 29.22/29.01  tff(decl_32568, type, 'The process by which pathogens evolve resistance to drugs meant to harm them.': $i).
% 29.22/29.01  tff(decl_32569, type, 'drug resistance process': $i).
% 29.22/29.01  tff(decl_32570, type, 'drug-resistance-process': $i).
% 29.22/29.01  tff(decl_32571, type, 'Dry': $i).
% 29.22/29.01  tff(decl_32572, type, dry: $i).
% 29.22/29.01  tff(decl_32573, type, 'dry out': $i).
% 29.22/29.01  tff(decl_32574, type, dry_out: $i).
% 29.22/29.01  tff(decl_32575, type, fn_dry_1: $i > $i).
% 29.22/29.01  tff(decl_32576, type, fn_dry_4: $i > $i).
% 29.22/29.01  tff(decl_32577, type, fn_dry_5: $i > $i).
% 29.22/29.01  tff(decl_32578, type, fn_dry_3: $i > $i).
% 29.22/29.01  tff(decl_32579, type, fn_dry_2: $i > $i).
% 29.22/29.01  tff(decl_32580, type, dubnium_1: $i > $o).
% 29.22/29.01  tff(decl_32581, type, 'Dubnium': $i).
% 29.22/29.01  tff(decl_32582, type, 'Dubnium is a metal atom with atomic number 105. It is represented by the symbol Db.': $i).
% 29.22/29.01  tff(decl_32583, type, dubnium: $i).
% 29.22/29.01  tff(decl_32584, type, 'Db': $i).
% 29.22/29.01  tff(decl_32585, type, fn_dubnium_1: $i > $i).
% 29.22/29.01  tff(decl_32586, type, fn_dubnium_2: $i > $i).
% 29.22/29.01  tff(decl_32587, type, fn_dubnium_6: $i > $i).
% 29.22/29.01  tff(decl_32588, type, fn_dubnium_7: $i > $i).
% 29.22/29.01  tff(decl_32589, type, "105": $i).
% 29.22/29.01  tff(decl_32590, type, "262": $i).
% 29.22/29.01  tff(decl_32591, type, fn_dubnium_4: $i > $i).
% 29.22/29.01  tff(decl_32592, type, fn_dubnium_5: $i > $i).
% 29.22/29.01  tff(decl_32593, type, 'Duchenne-Muscular-Dystrophy': $i).
% 29.22/29.01  tff(decl_32594, type, 'A human genetic disease caused by a sex-linked recessive allele; characterized by progressive weakening and a loss of muscle tissue.': $i).
% 29.22/29.01  tff(decl_32595, type, 'duchenne muscular dystrophy': $i).
% 29.22/29.01  tff(decl_32596, type, 'duchenne-muscular-dystrophy': $i).
% 29.22/29.01  tff(decl_32597, type, duck_1: $i > $o).
% 29.22/29.01  tff(decl_32598, type, 'Duck': $i).
% 29.22/29.01  tff(decl_32599, type, 'Common name for a water bird of the  Anatidae family, characterized by web feet adapted for swimming and a serrated bill for clipping aquatic vegetation.': $i).
% 29.22/29.01  tff(decl_32600, type, duck: $i).
% 29.22/29.01  tff(decl_32601, type, fn_duck_1: $i > $i).
% 29.22/29.01  tff(decl_32602, type, webbed_toe_1: $i > $o).
% 29.22/29.01  tff(decl_32603, type, 'Duct': $i).
% 29.22/29.01  tff(decl_32604, type, 'A channel that leads from a gland or an organ.': $i).
% 29.22/29.01  tff(decl_32605, type, duct: $i).
% 29.22/29.01  tff(decl_32606, type, 'Duodenum': $i).
% 29.22/29.01  tff(decl_32607, type, 'The proximal section of the small intestine. The duodenum has secretory functions.': $i).
% 29.22/29.01  tff(decl_32608, type, duodenum: $i).
% 29.22/29.01  tff(decl_32609, type, fn_duodenum_1: $i > $i).
% 29.22/29.01  tff(decl_32610, type, duplicate_1: $i > $o).
% 29.22/29.01  tff(decl_32611, type, 'Duplicate': $i).
% 29.22/29.01  tff(decl_32612, type, duplication_1: $i > $o).
% 29.22/29.01  tff(decl_32613, type, 'Duplication': $i).
% 29.22/29.01  tff(decl_32614, type, 'Abnormal chromosome structure due to fusion with a piece from a homologous chromosome, resulting in the duplication of a fragment of chromosome.': $i).
% 29.22/29.01  tff(decl_32615, type, duplication: $i).
% 29.22/29.01  tff(decl_32616, type, 'Duplication-Of-Chromosome-Fragment': $i).
% 29.22/29.01  tff(decl_32617, type, 'An alteration of chromosome structure that occurs during meiosis if a lost chromosomal fragment becomes attached as an extra segment to a sister chromatid.': $i).
% 29.22/29.01  tff(decl_32618, type, 'duplication of chromosome fragment': $i).
% 29.22/29.01  tff(decl_32619, type, 'duplication-of-chromosome-fragment': $i).
% 29.22/29.01  tff(decl_32620, type, repeated_gene_duplication_1: $i > $o).
% 29.22/29.01  tff(decl_32621, type, fn_duplication_of_chromosome_fragment_1: $i > $i).
% 29.22/29.01  tff(decl_32622, type, fn_duplication_of_chromosome_fragment_2: $i > $i).
% 29.22/29.01  tff(decl_32623, type, fn_duplication_of_chromosome_fragment_3: $i > $i).
% 29.22/29.01  tff(decl_32624, type, 'Duration-Constant': $i).
% 29.22/29.01  tff(decl_32625, type, 'constant of duration': $i).
% 29.22/29.01  tff(decl_32626, type, 'duration constant': $i).
% 29.22/29.01  tff(decl_32627, type, 'duration-constant': $i).
% 29.22/29.01  tff(decl_32628, type, duration_scale_1: $i > $o).
% 29.22/29.01  tff(decl_32629, type, 'Duration-Scale': $i).
% 29.22/29.01  tff(decl_32630, type, 'scale of duration': $i).
% 29.22/29.01  tff(decl_32631, type, 'duration scale': $i).
% 29.22/29.01  tff(decl_32632, type, 'duration-scale': $i).
% 29.22/29.01  tff(decl_32633, type, 'Duration-Value': $i).
% 29.22/29.01  tff(decl_32634, type, 'duration of an Event of Time-Interval': $i).
% 29.22/29.01  tff(decl_32635, type, length: $i).
% 29.22/29.01  tff(decl_32636, type, time: $i).
% 29.22/29.01  tff(decl_32637, type, continuance: $i).
% 29.22/29.01  tff(decl_32638, type, duration: $i).
% 29.22/29.01  tff(decl_32639, type, age: $i).
% 29.22/29.01  tff(decl_32640, type, 'total duration': $i).
% 29.22/29.01  tff(decl_32641, type, 'value of duration': $i).
% 29.22/29.01  tff(decl_32642, type, 'duration value': $i).
% 29.22/29.01  tff(decl_32643, type, 'duration-value': $i).
% 29.22/29.01  tff(decl_32644, type, dye_1: $i > $o).
% 29.22/29.01  tff(decl_32645, type, 'Dye': $i).
% 29.22/29.01  tff(decl_32646, type, 'A solution containing colored pigments which is used to stain a material or substrate.': $i).
% 29.22/29.01  tff(decl_32647, type, dye: $i).
% 29.22/29.01  tff(decl_32648, type, dynein_1: $i > $o).
% 29.22/29.01  tff(decl_32649, type, 'Dynein': $i).
% 29.22/29.01  tff(decl_32650, type, 'Large motor proteins located in cilia and flagella that are responsible for the bending movements of the organelle.': $i).
% 29.22/29.01  tff(decl_32651, type, dynein: $i).
% 29.22/29.01  tff(decl_32652, type, molecular_motor_1: $i > $o).
% 29.22/29.01  tff(decl_32653, type, fn_dynein_1: $i > $i).
% 29.22/29.01  tff(decl_32654, type, fn_dynein_6: $i > $i).
% 29.22/29.01  tff(decl_32655, type, fn_dynein_7: $i > $i).
% 29.22/29.01  tff(decl_32656, type, fn_dynein_8: $i > $i).
% 29.22/29.01  tff(decl_32657, type, fn_dynein_9: $i > $i).
% 29.22/29.01  tff(decl_32658, type, fn_dynein_10: $i > $i).
% 29.22/29.01  tff(decl_32659, type, fn_dynein_11: $i > $i).
% 29.22/29.01  tff(decl_32660, type, fn_dynein_12: $i > $i).
% 29.22/29.01  tff(decl_32661, type, fn_dynein_13: $i > $i).
% 29.22/29.01  tff(decl_32662, type, fn_dynein_14: $i > $i).
% 29.22/29.01  tff(decl_32663, type, fn_dynein_15: $i > $i).
% 29.22/29.01  tff(decl_32664, type, fn_dynein_16: $i > $i).
% 29.22/29.01  tff(decl_32665, type, fn_dynein_17: $i > $i).
% 29.22/29.01  tff(decl_32666, type, fn_dynein_18: $i > $i).
% 29.22/29.01  tff(decl_32667, type, fn_dynein_19: $i > $i).
% 29.22/29.01  tff(decl_32668, type, fn_dynein_20: $i > $i).
% 29.22/29.01  tff(decl_32669, type, fn_dynein_21: $i > $i).
% 29.22/29.01  tff(decl_32670, type, fn_dynein_22: $i > $i).
% 29.22/29.01  tff(decl_32671, type, fn_dynein_23: $i > $i).
% 29.22/29.01  tff(decl_32672, type, fn_dynein_24: $i > $i).
% 29.22/29.01  tff(decl_32673, type, fn_dynein_walking_11: $i > $i).
% 29.22/29.01  tff(decl_32674, type, fn_dynein_4: $i > $i).
% 29.22/29.01  tff(decl_32675, type, fn_motor_protein_27: $i > $i).
% 29.22/29.01  tff(decl_32676, type, fn_dynein_5: $i > $i).
% 29.22/29.01  tff(decl_32677, type, fn_motor_protein_25: $i > $i).
% 29.22/29.01  tff(decl_32678, type, fn_dynein_3: $i > $i).
% 29.22/29.01  tff(decl_32679, type, fn_motor_protein_26: $i > $i).
% 29.22/29.01  tff(decl_32680, type, fn_dynein_2: $i > $i).
% 29.22/29.01  tff(decl_32681, type, fn_motor_protein_28: $i > $i).
% 29.22/29.01  tff(decl_32682, type, fn_motor_protein_10: $i > $i).
% 29.22/29.01  tff(decl_32683, type, fn_motor_protein_9: $i > $i).
% 29.22/29.01  tff(decl_32684, type, fn_motor_protein_8: $i > $i).
% 29.22/29.01  tff(decl_32685, type, fn_motor_protein_6: $i > $i).
% 29.22/29.01  tff(decl_32686, type, fn_motor_protein_12: $i > $i).
% 29.22/29.01  tff(decl_32687, type, fn_motor_protein_17: $i > $i).
% 29.22/29.01  tff(decl_32688, type, fn_motor_protein_22: $i > $i).
% 29.22/29.01  tff(decl_32689, type, fn_motor_protein_11: $i > $i).
% 29.22/29.01  tff(decl_32690, type, fn_motor_protein_3: $i > $i).
% 29.22/29.01  tff(decl_32691, type, fn_motor_protein_20: $i > $i).
% 29.22/29.01  tff(decl_32692, type, fn_motor_protein_19: $i > $i).
% 29.22/29.01  tff(decl_32693, type, fn_motor_protein_18: $i > $i).
% 29.22/29.01  tff(decl_32694, type, fn_motor_protein_21: $i > $i).
% 29.22/29.01  tff(decl_32695, type, fn_motor_protein_13: $i > $i).
% 29.22/29.01  tff(decl_32696, type, fn_motor_protein_24: $i > $i).
% 29.22/29.01  tff(decl_32697, type, fn_motor_protein_16: $i > $i).
% 29.22/29.01  tff(decl_32698, type, fn_motor_protein_23: $i > $i).
% 29.22/29.01  tff(decl_32699, type, 'Dynein-Walking': $i).
% 29.22/29.01  tff(decl_32700, type, 'Dynein proteins connect adjacent microtubule doublets in cilia and flagella and appear to': $i).
% 29.22/29.01  tff(decl_32701, type, walk: $i).
% 29.22/29.01  tff(decl_32702, type, 'walking of dynein': $i).
% 29.22/29.01  tff(decl_32703, type, 'dynein walking': $i).
% 29.22/29.01  tff(decl_32704, type, 'dynein-walking': $i).
% 29.22/29.01  tff(decl_32705, type, fn_dynein_walking_1: $i > $i).
% 29.22/29.01  tff(decl_32706, type, fn_dynein_walking_4: $i > $i).
% 29.22/29.01  tff(decl_32707, type, fn_dynein_walking_5: $i > $i).
% 29.22/29.01  tff(decl_32708, type, microtubule_doublet_1: $i > $o).
% 29.22/29.01  tff(decl_32709, type, fn_dynein_walking_6: $i > $i).
% 29.22/29.01  tff(decl_32710, type, fn_dynein_walking_7: $i > $i).
% 29.22/29.01  tff(decl_32711, type, fn_dynein_walking_8: $i > $i).
% 29.22/29.01  tff(decl_32712, type, fn_dynein_walking_9: $i > $i).
% 29.22/29.01  tff(decl_32713, type, fn_dynein_walking_10: $i > $i).
% 29.22/29.01  tff(decl_32714, type, fn_dynein_walking_12: $i > $i).
% 29.22/29.01  tff(decl_32715, type, fn_dynein_walking_13: $i > $i).
% 29.22/29.01  tff(decl_32716, type, fn_slide_2: $i > $i).
% 29.22/29.01  tff(decl_32717, type, fn_slide_1: $i > $i).
% 29.22/29.01  tff(decl_32718, type, fn_motor_protein_1: $i > $i).
% 29.22/29.01  tff(decl_32719, type, fn_motor_protein_2: $i > $i).
% 29.22/29.01  tff(decl_32720, type, fn_dynein_walking_3: $i > $i).
% 29.22/29.01  tff(decl_32721, type, fn_dynein_walking_2: $i > $i).
% 29.22/29.01  tff(decl_32722, type, dysprosium_1: $i > $o).
% 29.22/29.01  tff(decl_32723, type, 'Dysprosium': $i).
% 29.22/29.01  tff(decl_32724, type, 'Dysprosium is a metal atom with atomic number 66. It is represented by the symbol Dy.': $i).
% 29.22/29.01  tff(decl_32725, type, dysprosium: $i).
% 29.22/29.01  tff(decl_32726, type, dy: $i).
% 29.22/29.01  tff(decl_32727, type, fn_dysprosium_4: $i > $i).
% 29.22/29.01  tff(decl_32728, type, fn_dysprosium_5: $i > $i).
% 29.22/29.01  tff(decl_32729, type, fn_dysprosium_6: $i > $i).
% 29.22/29.01  tff(decl_32730, type, fn_dysprosium_7: $i > $i).
% 29.22/29.01  tff(decl_32731, type, fn_dysprosium_11: $i > $i).
% 29.22/29.01  tff(decl_32732, type, fn_dysprosium_12: $i > $i).
% 29.22/29.01  tff(decl_32733, type, fn_dysprosium_13: $i > $i).
% 29.22/29.01  tff(decl_32734, type, fn_dysprosium_14: $i > $i).
% 29.22/29.01  tff(decl_32735, type, "66": $i).
% 29.22/29.01  tff(decl_32736, type, "1.22": $i).
% 29.22/29.01  tff(decl_32737, type, "163": $i).
% 29.22/29.01  tff(decl_32738, type, "162.5": $i).
% 29.22/29.02  tff(decl_32739, type, fn_dysprosium_9: $i > $i).
% 29.22/29.02  tff(decl_32740, type, fn_dysprosium_10: $i > $i).
% 29.22/29.02  tff(decl_32741, type, fn_dysprosium_8: $i > $i).
% 29.22/29.02  tff(decl_32742, type, 'E-Site': $i).
% 29.22/29.02  tff(decl_32743, type, 'The site on the ribosome where the tRNA that has just                        given up the growing polypeptide chain dissociates                        from the ribosome.': $i).
% 29.22/29.02  tff(decl_32744, type, 'The third of three RNA binding sites on a ribisome that binds a tRNA molecule that has just transferred its amino acid to the growing polypeptide chain before it exits the ribisome.': $i).
% 29.22/29.02  tff(decl_32745, type, 'exit site': $i).
% 29.22/29.02  tff(decl_32746, type, 'exit-site': $i).
% 29.22/29.02  tff(decl_32747, type, 'site of e': $i).
% 29.22/29.02  tff(decl_32748, type, 'e site': $i).
% 29.22/29.02  tff(decl_32749, type, 'e-site': $i).
% 29.22/29.02  tff(decl_32750, type, fn_e_site_1: $i > $i).
% 29.22/29.02  tff(decl_32751, type, fn_e_site_2: $i > $i).
% 29.22/29.02  tff(decl_32752, type, fn_e_site_3: $i > $i).
% 29.22/29.02  tff(decl_32753, type, fn_e_site_4: $i > $i).
% 29.22/29.02  tff(decl_32754, type, fn_e_site_5: $i > $i).
% 29.22/29.02  tff(decl_32755, type, fn_e_site_6: $i > $i).
% 29.22/29.02  tff(decl_32756, type, five_prime_end_of_mrna_1: $i > $o).
% 29.22/29.02  tff(decl_32757, type, fn_e_site_7: $i > $i).
% 29.22/29.02  tff(decl_32758, type, ear_1: $i > $o).
% 29.22/29.02  tff(decl_32759, type, 'Ear': $i).
% 29.22/29.02  tff(decl_32760, type, 'The vertebrate sense organ for hearing and equilibrium.': $i).
% 29.22/29.02  tff(decl_32761, type, ear: $i).
% 29.22/29.02  tff(decl_32762, type, early_atherosclerosis_1: $i > $o).
% 29.22/29.02  tff(decl_32763, type, 'Early-Atherosclerosis': $i).
% 29.22/29.02  tff(decl_32764, type, 'Cholesterol accumulates in the blood, where it contributes to early atherosclerosis (the buildup of fat deposits on blood vessel linings).': $i).
% 29.22/29.02  tff(decl_32765, type, 'arteriosclerotic vascular disease': $i).
% 29.22/29.02  tff(decl_32766, type, 'arteriosclerotic-vascular-disease': $i).
% 29.22/29.02  tff(decl_32767, type, asvd: $i).
% 29.22/29.02  tff(decl_32768, type, 'early atherosclerosis': $i).
% 29.22/29.02  tff(decl_32769, type, 'early-atherosclerosis': $i).
% 29.22/29.02  tff(decl_32770, type, 'Early-Embryo': $i).
% 29.22/29.02  tff(decl_32771, type, 'An embryo in the early stages of development is called as early embryo.': $i).
% 29.22/29.02  tff(decl_32772, type, 'early embryo': $i).
% 29.22/29.02  tff(decl_32773, type, 'early-embryo': $i).
% 29.22/29.02  tff(decl_32774, type, fn_early_embryo_1: $i > $i).
% 29.22/29.02  tff(decl_32775, type, 'Early-Invertebrate': $i).
% 29.22/29.02  tff(decl_32776, type, 'An invertebrate which appeared early in the geological record.': $i).
% 29.22/29.02  tff(decl_32777, type, 'early invertebrate': $i).
% 29.22/29.02  tff(decl_32778, type, 'early-invertebrate': $i).
% 29.22/29.02  tff(decl_32779, type, early_prokaryote_1: $i > $o).
% 29.22/29.02  tff(decl_32780, type, 'Early-Prokaryote': $i).
% 29.22/29.02  tff(decl_32781, type, 'Early prokaryotes were Earth\\s sole inhabitants from at least 3.5 billion years ago to about 2.1 billion years ago.': $i).
% 29.22/29.02  tff(decl_32782, type, 'early prokaryote': $i).
% 29.22/29.02  tff(decl_32783, type, 'early-prokaryote': $i).
% 29.22/29.02  tff(decl_32784, type, 'Early-vertebrate': $i).
% 29.22/29.02  tff(decl_32785, type, 'A vertebrate which appeared early in the geological record.': $i).
% 29.22/29.02  tff(decl_32786, type, 'early vertebrate': $i).
% 29.22/29.02  tff(decl_32787, type, 'early-vertebrate': $i).
% 29.22/29.02  tff(decl_32788, type, earth_1: $i > $o).
% 29.22/29.02  tff(decl_32789, type, 'Earth': $i).
% 29.22/29.02  tff(decl_32790, type, 'Earth (or the Earth) is the third planet from the Sun and the densest and fifth-largest of the eight planets in the Solar System': $i).
% 29.22/29.02  tff(decl_32791, type, terra: $i).
% 29.22/29.02  tff(decl_32792, type, earth: $i).
% 29.22/29.02  tff(decl_32793, type, fn_earth_1: $i > $i).
% 29.22/29.02  tff(decl_32794, type, fn_earth_2: $i > $i).
% 29.22/29.02  tff(decl_32795, type, fn_earth_3: $i > $i).
% 29.22/29.02  tff(decl_32796, type, gravity_1: $i > $o).
% 29.22/29.02  tff(decl_32797, type, fn_earth_4: $i > $i).
% 29.22/29.02  tff(decl_32798, type, fn_earth_5: $i > $i).
% 29.22/29.02  tff(decl_32799, type, fn_earth_6: $i > $i).
% 29.22/29.02  tff(decl_32800, type, fn_earth_7: $i > $i).
% 29.22/29.02  tff(decl_32801, type, fn_earth_8: $i > $i).
% 29.22/29.02  tff(decl_32802, type, fn_temperature_fluctuation_3: $i > $i).
% 29.22/29.02  tff(decl_32803, type, earth_pole_1: $i > $o).
% 29.22/29.02  tff(decl_32804, type, 'Earth-Pole': $i).
% 29.22/29.02  tff(decl_32805, type, 'One of the two poles on Earth (North and South Pole).  The poles mark the ends of the axis that the Earth spins on.': $i).
% 29.22/29.02  tff(decl_32806, type, 'earth\\s poles': $i).
% 29.22/29.02  tff(decl_32807, type, 'pole of earth': $i).
% 29.22/29.02  tff(decl_32808, type, 'earth pole': $i).
% 29.22/29.02  tff(decl_32809, type, 'earth-pole': $i).
% 29.22/29.02  tff(decl_32810, type, glacier_1: $i > $o).
% 29.22/29.02  tff(decl_32811, type, tropical_region_1: $i > $o).
% 29.22/29.02  tff(decl_32812, type, earthworm_1: $i > $o).
% 29.22/29.02  tff(decl_32813, type, 'Earthworm': $i).
% 29.22/29.02  tff(decl_32814, type, 'A segmented worm of the phylum Annelida, commonly found living in soil.': $i).
% 29.22/29.02  tff(decl_32815, type, earthworm: $i).
% 29.22/29.02  tff(decl_32816, type, oligochaete_1: $i > $o).
% 29.22/29.02  tff(decl_32817, type, fn_earthworm_1: $i > $i).
% 29.22/29.02  tff(decl_32818, type, fn_earthworm_2: $i > $i).
% 29.22/29.02  tff(decl_32819, type, extracellular_digestion_1: $i > $o).
% 29.22/29.02  tff(decl_32820, type, fn_earthworm_3: $i > $i).
% 29.22/29.02  tff(decl_32821, type, fn_earthworm_4: $i > $i).
% 29.22/29.02  tff(decl_32822, type, fn_earthworm_5: $i > $i).
% 29.22/29.02  tff(decl_32823, type, fn_earthworm_6: $i > $i).
% 29.22/29.02  tff(decl_32824, type, fn_earthworm_7: $i > $i).
% 29.22/29.02  tff(decl_32825, type, fn_earthworm_8: $i > $i).
% 29.22/29.02  tff(decl_32826, type, intestine_1: $i > $o).
% 29.22/29.02  tff(decl_32827, type, fn_earthworm_9: $i > $i).
% 29.22/29.02  tff(decl_32828, type, fn_earthworm_10: $i > $i).
% 29.22/29.02  tff(decl_32829, type, fn_earthworm_11: $i > $i).
% 29.22/29.02  tff(decl_32830, type, gizzard_1: $i > $o).
% 29.22/29.02  tff(decl_32831, type, fn_earthworm_12: $i > $i).
% 29.22/29.02  tff(decl_32832, type, fn_earthworm_13: $i > $i).
% 29.22/29.02  tff(decl_32833, type, fn_earthworm_14: $i > $i).
% 29.22/29.02  tff(decl_32834, type, fn_earthworm_15: $i > $i).
% 29.22/29.02  tff(decl_32835, type, fn_earthworm_16: $i > $i).
% 29.22/29.02  tff(decl_32836, type, fn_earthworm_17: $i > $i).
% 29.22/29.02  tff(decl_32837, type, fn_earthworm_18: $i > $i).
% 29.22/29.02  tff(decl_32838, type, fn_earthworm_19: $i > $i).
% 29.22/29.02  tff(decl_32839, type, fn_earthworm_20: $i > $i).
% 29.22/29.02  tff(decl_32840, type, fn_earthworm_21: $i > $i).
% 29.22/29.02  tff(decl_32841, type, fn_earthworm_22: $i > $i).
% 29.22/29.02  tff(decl_32842, type, fn_earthworm_23: $i > $i).
% 29.22/29.02  tff(decl_32843, type, fn_earthworm_24: $i > $i).
% 29.22/29.02  tff(decl_32844, type, fn_earthworm_25: $i > $i).
% 29.22/29.02  tff(decl_32845, type, fn_earthworm_26: $i > $i).
% 29.22/29.02  tff(decl_32846, type, fn_earthworm_27: $i > $i).
% 29.22/29.02  tff(decl_32847, type, fn_earthworm_28: $i > $i).
% 29.22/29.02  tff(decl_32848, type, fn_earthworm_29: $i > $i).
% 29.22/29.02  tff(decl_32849, type, fn_earthworm_30: $i > $i).
% 29.22/29.02  tff(decl_32850, type, fn_feces_1: $i > $i).
% 29.22/29.02  tff(decl_32851, type, earthworm_digestive_system_1: $i > $o).
% 29.22/29.02  tff(decl_32852, type, 'Earthworm-Digestive-System': $i).
% 29.22/29.02  tff(decl_32853, type, 'A system of organs in a earthworm\\s body which is responsible for the digestion and absorption of nutrients from food.': $i).
% 29.22/29.02  tff(decl_32854, type, 'earthworm digestive system': $i).
% 29.22/29.02  tff(decl_32855, type, 'earthworm-digestive-system': $i).
% 29.22/29.02  tff(decl_32856, type, fn_earthworm_digestive_system_1: $i > $i).
% 29.22/29.02  tff(decl_32857, type, fn_earthworm_digestive_system_2: $i > $i).
% 29.22/29.02  tff(decl_32858, type, fn_earthworm_digestive_system_3: $i > $i).
% 29.22/29.02  tff(decl_32859, type, fn_earthworm_digestive_system_4: $i > $i).
% 29.22/29.02  tff(decl_32860, type, fn_earthworm_digestive_system_5: $i > $i).
% 29.22/29.02  tff(decl_32861, type, fn_earthworm_digestive_system_6: $i > $i).
% 29.22/29.02  tff(decl_32862, type, fn_earthworm_digestive_system_7: $i > $i).
% 29.22/29.02  tff(decl_32863, type, fn_earthworm_digestive_system_8: $i > $i).
% 29.22/29.02  tff(decl_32864, type, fn_earthworm_digestive_system_12: $i > $i).
% 29.22/29.02  tff(decl_32865, type, fn_earthworm_digestive_system_14: $i > $i).
% 29.22/29.02  tff(decl_32866, type, fn_earthworm_digestive_system_15: $i > $i).
% 29.22/29.02  tff(decl_32867, type, fn_earthworm_digestive_system_16: $i > $i).
% 29.22/29.02  tff(decl_32868, type, fn_earthworm_digestive_system_17: $i > $i).
% 29.22/29.02  tff(decl_32869, type, muscle_1: $i > $o).
% 29.22/29.02  tff(decl_32870, type, tissue_0: $i).
% 29.22/29.02  tff(decl_32871, type, organ_0: $i).
% 29.22/29.02  tff(decl_32872, type, 'Eat': $i).
% 29.22/29.02  tff(decl_32873, type, feed: $i).
% 29.22/29.02  tff(decl_32874, type, fn_eat_3: $i > $i).
% 29.22/29.02  tff(decl_32875, type, eating_by_protist_1: $i > $o).
% 29.22/29.02  tff(decl_32876, type, 'Eating-By-Protist': $i).
% 29.22/29.02  tff(decl_32877, type, 'An act representing feed: take in food by protist': $i).
% 29.22/29.02  tff(decl_32878, type, 'eating by protist': $i).
% 29.22/29.02  tff(decl_32879, type, 'eating-by-protist': $i).
% 29.22/29.02  tff(decl_32880, type, fn_eating_by_protist_1: $i > $i).
% 29.22/29.02  tff(decl_32881, type, fn_eating_by_protist_2: $i > $i).
% 29.22/29.02  tff(decl_32882, type, fn_eating_by_protist_3: $i > $i).
% 29.22/29.02  tff(decl_32883, type, fn_eating_by_protist_4: $i > $i).
% 29.22/29.02  tff(decl_32884, type, fn_eating_by_protist_5: $i > $i).
% 29.22/29.02  tff(decl_32885, type, fn_eating_by_protist_6: $i > $i).
% 29.22/29.02  tff(decl_32886, type, fn_eating_by_protist_7: $i > $i).
% 29.22/29.02  tff(decl_32887, type, fn_eating_by_protist_8: $i > $i).
% 29.22/29.02  tff(decl_32888, type, fn_eating_by_protist_9: $i > $i).
% 29.22/29.02  tff(decl_32889, type, fn_eating_by_protist_10: $i > $i).
% 29.22/29.02  tff(decl_32890, type, fn_eating_by_protist_11: $i > $i).
% 29.22/29.02  tff(decl_32891, type, ebola_virus_1: $i > $o).
% 29.22/29.02  tff(decl_32892, type, 'Ebola-Virus': $i).
% 29.22/29.02  tff(decl_32893, type, 'A virus that that causes hemorrhagic fever, an often fatal syndrome characterized by fever, vomiting, massive bleeding, and circulatory system collapse.': $i).
% 29.22/29.02  tff(decl_32894, type, 'virus of ebola': $i).
% 29.22/29.02  tff(decl_32895, type, 'ebola virus': $i).
% 29.22/29.02  tff(decl_32896, type, 'ebola-virus': $i).
% 29.22/29.02  tff(decl_32897, type, rna_virus_1: $i > $o).
% 29.22/29.02  tff(decl_32898, type, hantavirus_1: $i > $o).
% 29.22/29.02  tff(decl_32899, type, influenza_virus_1: $i > $o).
% 29.22/29.02  tff(decl_32900, type, nipah_virus_1: $i > $o).
% 29.22/29.02  tff(decl_32901, type, retrovirus_1: $i > $o).
% 29.22/29.02  tff(decl_32902, type, rna_virus_class_iv_1: $i > $o).
% 29.22/29.02  tff(decl_32903, type, rna_virus_class_v_1: $i > $o).
% 29.22/29.02  tff(decl_32904, type, 'Ecdysone': $i).
% 29.22/29.02  tff(decl_32905, type, 'A steroid hormone, secreted by the prothoracic glands, that triggers molting in arthropods.': $i).
% 29.22/29.02  tff(decl_32906, type, ecdysone: $i).
% 29.22/29.02  tff(decl_32907, type, 'Ecdysozoan': $i).
% 29.22/29.02  tff(decl_32908, type, 'Member of a group of protostome animal phyla, including arthropods and nematodes, that molt their exoskeleton. The grouping is also supported by molecular evidence.': $i).
% 29.22/29.02  tff(decl_32909, type, ecdysozoan: $i).
% 29.22/29.02  tff(decl_32910, type, echidna_1: $i > $o).
% 29.22/29.02  tff(decl_32911, type, 'Echidna': $i).
% 29.22/29.02  tff(decl_32912, type, 'Also known as spiny ant eaters. Echidnas are monotremes (egg-laying mammals) that superficially resemble hedgehogs.': $i).
% 29.22/29.02  tff(decl_32913, type, echidna: $i).
% 29.22/29.02  tff(decl_32914, type, monotreme_1: $i > $o).
% 29.22/29.02  tff(decl_32915, type, 'Echinoderm': $i).
% 29.22/29.02  tff(decl_32916, type, 'Member of the phylum Echinodermata, a group of sessils marine invertebrates characterized by pentaradial symmetry as adults, bilateral symmetry as larvae, and a unique water vascular system. Echinoderms include sea stars, brittle stars, sea urchins, sand dollars, sea cucumbers, and feather stars.': $i).
% 29.22/29.02  tff(decl_32917, type, echinoderm: $i).
% 29.22/29.02  tff(decl_32918, type, 'Ecological-Community': $i).
% 29.22/29.02  tff(decl_32919, type, 'All the organisms that inhabit a particular area; an assemblage of populations of different species living close enough together for potential interaction.': $i).
% 29.22/29.02  tff(decl_32920, type, 'community as ecological grouping': $i).
% 29.22/29.02  tff(decl_32921, type, 'ecological community': $i).
% 29.22/29.02  tff(decl_32922, type, 'ecological-community': $i).
% 29.22/29.02  tff(decl_32923, type, fn_ecological_community_1: $i > $i).
% 29.22/29.02  tff(decl_32924, type, fn_ecological_community_2: $i > $i).
% 29.22/29.02  tff(decl_32925, type, fn_ecological_community_3: $i > $i).
% 29.22/29.02  tff(decl_32926, type, fn_ecological_community_4: $i > $i).
% 29.22/29.02  tff(decl_32927, type, fn_ecological_community_5: $i > $i).
% 29.22/29.02  tff(decl_32928, type, 'Ecological-Grouping': $i).
% 29.22/29.02  tff(decl_32929, type, 'Groups of individuals or areas related by their interactions with each other and the environment.': $i).
% 29.22/29.02  tff(decl_32930, type, 'ecological grouping': $i).
% 29.22/29.02  tff(decl_32931, type, 'ecological-grouping': $i).
% 29.22/29.02  tff(decl_32932, type, ingroup_1: $i > $o).
% 29.22/29.02  tff(decl_32933, type, outgroup_1: $i > $o).
% 29.22/29.02  tff(decl_32934, type, polyphyletic_1: $i > $o).
% 29.22/29.02  tff(decl_32935, type, 'Ecological-Model': $i).
% 29.22/29.02  tff(decl_32936, type, 'A model representating an ecological theory or process.': $i).
% 29.22/29.02  tff(decl_32937, type, 'ecological model': $i).
% 29.22/29.02  tff(decl_32938, type, 'ecological-model': $i).
% 29.22/29.02  tff(decl_32939, type, ecological_niche_1: $i > $o).
% 29.22/29.02  tff(decl_32940, type, 'Ecological-Niche': $i).
% 29.22/29.02  tff(decl_32941, type, 'A description of how an individual or speces responds to the distribution of biotic and abiotic factors in the environment, and how it in turns alters the distribution of those factors.': $i).
% 29.22/29.02  tff(decl_32942, type, 'ecological niche': $i).
% 29.22/29.02  tff(decl_32943, type, 'ecological-niche': $i).
% 29.22/29.02  tff(decl_32944, type, keystone_species_1: $i > $o).
% 29.22/29.02  tff(decl_32945, type, pollinator_1: $i > $o).
% 29.22/29.02  tff(decl_32946, type, 'Ecological-Process': $i).
% 29.22/29.02  tff(decl_32947, type, 'Any process that occurs at the level of ecosystems.': $i).
% 29.22/29.02  tff(decl_32948, type, 'ecological process': $i).
% 29.22/29.02  tff(decl_32949, type, 'ecological-process': $i).
% 29.22/29.02  tff(decl_32950, type, 'Ecological-Pyramid': $i).
% 29.22/29.02  tff(decl_32951, type, 'A diagram that represents the productivity or biomass of each trophic level in a particular ecosystem.': $i).
% 29.22/29.02  tff(decl_32952, type, 'ecological pyramid': $i).
% 29.22/29.02  tff(decl_32953, type, 'ecological-pyramid': $i).
% 29.22/29.02  tff(decl_32954, type, trophic_cascade_model_1: $i > $o).
% 29.22/29.02  tff(decl_32955, type, trophic_structure_1: $i > $o).
% 29.22/29.02  tff(decl_32956, type, 'Ecological-Region': $i).
% 29.22/29.02  tff(decl_32957, type, 'A region of an ecological entity.': $i).
% 29.22/29.02  tff(decl_32958, type, 'ecological region': $i).
% 29.22/29.02  tff(decl_32959, type, 'ecological-region': $i).
% 29.22/29.02  tff(decl_32960, type, ecological_relationship_1: $i > $o).
% 29.22/29.02  tff(decl_32961, type, 'Ecological-Relationship': $i).
% 29.22/29.02  tff(decl_32962, type, 'ecological relationship': $i).
% 29.22/29.02  tff(decl_32963, type, 'ecological-relationship': $i).
% 29.22/29.02  tff(decl_32964, type, fn_ecological_relationship_1: $i > $i).
% 29.22/29.02  tff(decl_32965, type, fn_ecological_relationship_2: $i > $i).
% 29.22/29.02  tff(decl_32966, type, 'Ecological-Role': $i).
% 29.22/29.02  tff(decl_32967, type, 'Roles specifically related to ecology and ecosystems.': $i).
% 29.22/29.02  tff(decl_32968, type, 'ecological role': $i).
% 29.22/29.02  tff(decl_32969, type, 'ecological-role': $i).
% 29.22/29.02  tff(decl_32970, type, ecological_species_1: $i > $o).
% 29.22/29.02  tff(decl_32971, type, 'Ecological-Species': $i).
% 29.22/29.02  tff(decl_32972, type, 'A group of organisms in an ecosystem that interact in similar ways with the abiotic and biotic factors of their environment.': $i).
% 29.22/29.02  tff(decl_32973, type, 'ecological species': $i).
% 29.22/29.02  tff(decl_32974, type, 'ecological-specy': $i).
% 29.22/29.02  tff(decl_32975, type, ecological_species_concept_1: $i > $o).
% 29.22/29.02  tff(decl_32976, type, 'Ecological-Species-Concept': $i).
% 29.22/29.02  tff(decl_32977, type, 'A definition of species in terms of ecological niche, the sum of how members of the species interact with the nonliving and living parts of their environment.': $i).
% 29.22/29.02  tff(decl_32978, type, 'ecological species concept': $i).
% 29.22/29.02  tff(decl_32979, type, 'ecological-species-concept': $i).
% 29.22/29.02  tff(decl_32980, type, morphological_species_concept_1: $i > $o).
% 29.22/29.02  tff(decl_32981, type, paleontological_species_concept_1: $i > $o).
% 29.22/29.02  tff(decl_32982, type, phylogenetic_species_concept_1: $i > $o).
% 29.22/29.02  tff(decl_32983, type, ecological_succession_1: $i > $o).
% 29.22/29.02  tff(decl_32984, type, 'Ecological-Succession': $i).
% 29.22/29.02  tff(decl_32985, type, 'The transition of species composition of a community following a disturbance; the establishment of a biological community in a previously barren area.': $i).
% 29.22/29.02  tff(decl_32986, type, 'ecological succession': $i).
% 29.22/29.02  tff(decl_32987, type, 'ecological-succession': $i).
% 29.22/29.02  tff(decl_32988, type, 'Ecology': $i).
% 29.22/29.02  tff(decl_32989, type, 'The study of interactions between organisms and their environment.': $i).
% 29.22/29.02  tff(decl_32990, type, ecology: $i).
% 29.22/29.02  tff(decl_32991, type, ecori_1: $i > $o).
% 29.22/29.02  tff(decl_32992, type, 'EcoRI': $i).
% 29.22/29.02  tff(decl_32993, type, 'EcoRI is an endonuclease enzyme isolated from strains of E. coli.  It is used as a restriction enzyme.': $i).
% 29.22/29.02  tff(decl_32994, type, 'eco r one': $i).
% 29.22/29.02  tff(decl_32995, type, ecori: $i).
% 29.22/29.02  tff(decl_32996, type, 'Ecosystem': $i).
% 29.22/29.02  tff(decl_32997, type, 'The sum total of biotic and abiotic components in a given area.': $i).
% 29.22/29.02  tff(decl_32998, type, ecosystem: $i).
% 29.22/29.02  tff(decl_32999, type, fn_ecosystem_1: $i > $i).
% 29.22/29.02  tff(decl_33000, type, fn_ecosystem_5: $i > $i).
% 29.22/29.02  tff(decl_33001, type, fn_ecosystem_6: $i > $i).
% 29.22/29.02  tff(decl_33002, type, fn_ecosystem_7: $i > $i).
% 29.22/29.02  tff(decl_33003, type, fn_ecosystem_8: $i > $i).
% 29.22/29.02  tff(decl_33004, type, fn_ecosystem_11: $i > $i).
% 29.22/29.02  tff(decl_33005, type, fn_ecosystem_12: $i > $i).
% 29.22/29.02  tff(decl_33006, type, fn_ecosystem_13: $i > $i).
% 29.22/29.02  tff(decl_33007, type, fn_ecosystem_14: $i > $i).
% 29.22/29.02  tff(decl_33008, type, fn_ecosystem_20: $i > $i).
% 29.22/29.02  tff(decl_33009, type, fn_ecosystem_22: $i > $i).
% 29.22/29.02  tff(decl_33010, type, fn_ecosystem_23: $i > $i).
% 29.22/29.02  tff(decl_33011, type, fn_ecosystem_24: $i > $i).
% 29.22/29.02  tff(decl_33012, type, fn_ecosystem_25: $i > $i).
% 29.22/29.02  tff(decl_33013, type, fn_ecosystem_26: $i > $i).
% 29.22/29.02  tff(decl_33014, type, fn_ecosystem_27: $i > $i).
% 29.22/29.02  tff(decl_33015, type, fn_ecosystem_28: $i > $i).
% 29.22/29.02  tff(decl_33016, type, fn_ecosystem_29: $i > $i).
% 29.22/29.02  tff(decl_33017, type, ecosystem_ecology_1: $i > $o).
% 29.22/29.02  tff(decl_33018, type, 'Ecosystem-Ecology': $i).
% 29.22/29.02  tff(decl_33019, type, 'The study of interactions among the biotic and abiotic elements within an ecosystem.': $i).
% 29.22/29.02  tff(decl_33020, type, 'ecology of ecosystem': $i).
% 29.22/29.02  tff(decl_33021, type, 'ecosystem ecology': $i).
% 29.22/29.02  tff(decl_33022, type, 'ecosystem-ecology': $i).
% 29.22/29.02  tff(decl_33023, type, ecosystem_fragmentation_1: $i > $o).
% 29.22/29.02  tff(decl_33024, type, 'Ecosystem-Fragmentation': $i).
% 29.22/29.02  tff(decl_33025, type, 'The fragmentation of ecosystems due to geologic processes or human behaviors.': $i).
% 29.22/29.02  tff(decl_33026, type, 'fragmentation of ecosystem': $i).
% 29.22/29.02  tff(decl_33027, type, 'ecosystem fragmentation': $i).
% 29.22/29.02  tff(decl_33028, type, 'ecosystem-fragmentation': $i).
% 29.22/29.02  tff(decl_33029, type, ecosystem_service_1: $i > $o).
% 29.22/29.02  tff(decl_33030, type, 'Ecosystem-Service': $i).
% 29.22/29.02  tff(decl_33031, type, 'A process occuring within an ecosystem that directly or indirectly benefits humankind.': $i).
% 29.22/29.02  tff(decl_33032, type, 'service of ecosystem': $i).
% 29.22/29.02  tff(decl_33033, type, 'ecosystem service': $i).
% 29.22/29.02  tff(decl_33034, type, 'ecosystem-service': $i).
% 29.22/29.02  tff(decl_33035, type, nonequilibrium_model_1: $i > $o).
% 29.22/29.02  tff(decl_33036, type, gross_primary_production_1: $i > $o).
% 29.22/29.02  tff(decl_33037, type, ecotherm_1: $i > $o).
% 29.22/29.02  tff(decl_33038, type, 'Ecotherm': $i).
% 29.22/29.02  tff(decl_33039, type, 'Animal which maintains its body temperature largely through external enironmental means, such as warmth from the sun or cooling from shade.': $i).
% 29.22/29.02  tff(decl_33040, type, ecotone_1: $i > $o).
% 29.22/29.02  tff(decl_33041, type, 'Ecotone': $i).
% 29.22/29.02  tff(decl_33042, type, 'A transition zone between two biomes, where different biological communities meet and interact.': $i).
% 29.22/29.02  tff(decl_33043, type, ecotone: $i).
% 29.22/29.02  tff(decl_33044, type, ectoderm_1: $i > $o).
% 29.22/29.02  tff(decl_33045, type, 'Ectoderm': $i).
% 29.22/29.02  tff(decl_33046, type, 'The outermost of three embryonic germ layers in animals, giving rise to the outer covering of the body. In vertebrates, ectoderm also gives rise to structures of the nervous system, lining of the mouth and anus, and epidermal skin coverings (hair, feathers, and scales).': $i).
% 29.22/29.02  tff(decl_33047, type, ectoderm: $i).
% 29.22/29.02  tff(decl_33048, type, germ_layer_1: $i > $o).
% 29.22/29.02  tff(decl_33049, type, mesoderm_1: $i > $o).
% 29.22/29.02  tff(decl_33050, type, endoderm_1: $i > $o).
% 29.22/29.02  tff(decl_33051, type, ectomycorrhiza_1: $i > $o).
% 29.22/29.02  tff(decl_33052, type, 'Ectomycorrhiza': $i).
% 29.22/29.02  tff(decl_33053, type, 'Association of a fungus with a plant root system in which the fungus surrounds the roots but does not cause invagination of the host (plant) cells plasma membranes.': $i).
% 29.22/29.02  tff(decl_33054, type, ectomycorrhiza: $i).
% 29.22/29.02  tff(decl_33055, type, ectomycorrhizal_fungus_1: $i > $o).
% 29.22/29.02  tff(decl_33056, type, 'Ectomycorrhizal-Fungus': $i).
% 29.22/29.02  tff(decl_33057, type, 'A fungus that forms an ectomycorrhizal relationship with a plant root system.': $i).
% 29.22/29.02  tff(decl_33058, type, 'ectomycorrhizal fungus': $i).
% 29.22/29.02  tff(decl_33059, type, 'ectomycorrhizal-fungus': $i).
% 29.22/29.02  tff(decl_33060, type, endophyte_1: $i > $o).
% 29.22/29.02  tff(decl_33061, type, fn_ectomycorrhizal_fungus_1: $i > $i).
% 29.22/29.02  tff(decl_33062, type, ectoparasite_1: $i > $o).
% 29.22/29.02  tff(decl_33063, type, 'Ectoparasite': $i).
% 29.22/29.02  tff(decl_33064, type, 'A parasite that lives on and feeds from the external surface of the host\\s body.': $i).
% 29.22/29.02  tff(decl_33065, type, ectoparasite: $i).
% 29.22/29.02  tff(decl_33066, type, endoparasite_1: $i > $o).
% 29.22/29.02  tff(decl_33067, type, parasitoid_1: $i > $o).
% 29.22/29.02  tff(decl_33068, type, 'Ectoproct': $i).
% 29.22/29.02  tff(decl_33069, type, 'Sessile, colonial animal of the phylum Bryozoa.': $i).
% 29.22/29.02  tff(decl_33070, type, ectoproct: $i).
% 29.22/29.02  tff(decl_33071, type, ectothermy_1: $i > $o).
% 29.22/29.02  tff(decl_33072, type, 'Ectothermy': $i).
% 29.22/29.02  tff(decl_33073, type, 'Regulation of body temperature using primarily external heat sources.': $i).
% 29.22/29.02  tff(decl_33074, type, ectothermic: $i).
% 29.22/29.02  tff(decl_33075, type, 'cold blooded': $i).
% 29.22/29.02  tff(decl_33076, type, 'cold-blooded': $i).
% 29.22/29.02  tff(decl_33077, type, ectothermy: $i).
% 29.22/29.02  tff(decl_33078, type, endothermic_1: $i > $o).
% 29.22/29.02  tff(decl_33079, type, 'Edentata': $i).
% 29.22/29.02  tff(decl_33080, type, 'A polyphyletic grouping of mammals that includes armadillos, anteaters, sloths, and aardvarks.': $i).
% 29.22/29.02  tff(decl_33081, type, xenarthra: $i).
% 29.22/29.02  tff(decl_33082, type, edentata: $i).
% 29.22/29.02  tff(decl_33083, type, ediacaran_biota_1: $i > $o).
% 29.22/29.02  tff(decl_33084, type, 'Ediacaran-Biota': $i).
% 29.22/29.02  tff(decl_33085, type, 'A group of soft-bodied eukaryotic organisms that existed in the Ediacaran Period (about 635-542 million years ago). The Ediacaran fossils are enigmatic and difficult to place in groups of known organisms.': $i).
% 29.22/29.02  tff(decl_33086, type, 'ediacaran biota': $i).
% 29.22/29.02  tff(decl_33087, type, 'ediacaran-biota': $i).
% 29.22/29.02  tff(decl_33088, type, edit_1: $i > $o).
% 29.22/29.02  tff(decl_33089, type, 'Edit': $i).
% 29.22/29.02  tff(decl_33090, type, edit: $i).
% 29.22/29.02  tff(decl_33091, type, redact: $i).
% 29.22/29.02  tff(decl_33092, type, revise: $i).
% 29.22/29.02  tff(decl_33093, type, rewrite: $i).
% 29.22/29.02  tff(decl_33094, type, fn_edit_1: $i > $i).
% 29.22/29.02  tff(decl_33095, type, 'Educational-Institution': $i).
% 29.22/29.02  tff(decl_33096, type, 'an institution for teaching, studying, research, etc.': $i).
% 29.22/29.02  tff(decl_33097, type, 'educational institution': $i).
% 29.22/29.02  tff(decl_33098, type, educational_institution: $i).
% 29.22/29.02  tff(decl_33099, type, school: $i).
% 29.22/29.02  tff(decl_33100, type, 'educational-institution': $i).
% 29.22/29.02  tff(decl_33101, type, effect_of_pdgf_on_cell_division_1: $i > $o).
% 29.22/29.02  tff(decl_33102, type, 'Effect-Of-PDGF-On-Cell-Division': $i).
% 29.22/29.02  tff(decl_33103, type, 'PDGF, or platelet derived growth factor, acts as a signaling molecule which promotes cell division.': $i).
% 29.22/29.02  tff(decl_33104, type, 'effect of pdgf on cell division': $i).
% 29.22/29.02  tff(decl_33105, type, 'effect-of-pdgf-on-cell-division': $i).
% 29.22/29.02  tff(decl_33106, type, fn_effect_of_pdgf_on_cell_division_5: $i > $i).
% 29.22/29.02  tff(decl_33107, type, incubation_1: $i > $o).
% 29.22/29.02  tff(decl_33108, type, fn_effect_of_pdgf_on_cell_division_6: $i > $i).
% 29.22/29.02  tff(decl_33109, type, fn_effect_of_pdgf_on_cell_division_7: $i > $i).
% 29.22/29.02  tff(decl_33110, type, fn_effect_of_pdgf_on_cell_division_8: $i > $i).
% 29.22/29.02  tff(decl_33111, type, fn_effect_of_pdgf_on_cell_division_9: $i > $i).
% 29.22/29.02  tff(decl_33112, type, fn_effect_of_pdgf_on_cell_division_10: $i > $i).
% 29.22/29.02  tff(decl_33113, type, fn_effect_of_pdgf_on_cell_division_11: $i > $i).
% 29.22/29.02  tff(decl_33114, type, fn_effect_of_pdgf_on_cell_division_12: $i > $i).
% 29.22/29.02  tff(decl_33115, type, fn_effect_of_pdgf_on_cell_division_13: $i > $i).
% 29.22/29.02  tff(decl_33116, type, fn_effect_of_pdgf_on_cell_division_14: $i > $i).
% 29.22/29.02  tff(decl_33117, type, fn_effect_of_pdgf_on_cell_division_15: $i > $i).
% 29.22/29.02  tff(decl_33118, type, fn_effect_of_pdgf_on_cell_division_16: $i > $i).
% 29.22/29.02  tff(decl_33119, type, fn_effect_of_pdgf_on_cell_division_17: $i > $i).
% 29.22/29.02  tff(decl_33120, type, fn_effect_of_pdgf_on_cell_division_18: $i > $i).
% 29.22/29.02  tff(decl_33121, type, fn_effect_of_pdgf_on_cell_division_19: $i > $i).
% 29.22/29.02  tff(decl_33122, type, piece_of_tissue_1: $i > $o).
% 29.22/29.02  tff(decl_33123, type, fn_effect_of_pdgf_on_cell_division_20: $i > $i).
% 29.22/29.02  tff(decl_33124, type, fn_effect_of_pdgf_on_cell_division_21: $i > $i).
% 29.22/29.02  tff(decl_33125, type, fn_effect_of_pdgf_on_cell_division_22: $i > $i).
% 29.22/29.02  tff(decl_33126, type, fn_effect_of_pdgf_on_cell_division_23: $i > $i).
% 29.22/29.02  tff(decl_33127, type, fn_effect_of_pdgf_on_cell_division_24: $i > $i).
% 29.22/29.02  tff(decl_33128, type, fibroblast_1: $i > $o).
% 29.22/29.02  tff(decl_33129, type, fn_effect_of_pdgf_on_cell_division_25: $i > $i).
% 29.22/29.02  tff(decl_33130, type, fn_effect_of_pdgf_on_cell_division_26: $i > $i).
% 29.22/29.02  tff(decl_33131, type, fn_effect_of_pdgf_on_cell_division_27: $i > $i).
% 29.22/29.02  tff(decl_33132, type, fn_effect_of_pdgf_on_cell_division_28: $i > $i).
% 29.22/29.02  tff(decl_33133, type, fn_effect_of_pdgf_on_cell_division_29: $i > $i).
% 29.22/29.02  tff(decl_33134, type, platelet_derived_growth_factor_1: $i > $o).
% 29.22/29.02  tff(decl_33135, type, fn_effect_of_pdgf_on_cell_division_30: $i > $i).
% 29.22/29.02  tff(decl_33136, type, fn_effect_of_pdgf_on_cell_division_31: $i > $i).
% 29.22/29.02  tff(decl_33137, type, fn_effect_of_pdgf_on_cell_division_32: $i > $i).
% 29.22/29.02  tff(decl_33138, type, fn_piece_of_tissue_1: $i > $i).
% 29.22/29.02  tff(decl_33139, type, piece_of_tissue_0: $i).
% 29.22/29.02  tff(decl_33140, type, fibroblast_0: $i).
% 29.22/29.02  tff(decl_33141, type, "24.0e0": $i).
% 29.22/29.02  tff(decl_33142, type, 'Effector-Cell': $i).
% 29.22/29.02  tff(decl_33143, type, '(1) The cell in a muscle, gland, or organ that responds to a stimulus from a neuron. (2) In the immune system, a white blood cell that has gone through clonal selection and can mediate an acquired immune response.': $i).
% 29.22/29.02  tff(decl_33144, type, 'cell of effector': $i).
% 29.22/29.02  tff(decl_33145, type, 'effector cell': $i).
% 29.22/29.02  tff(decl_33146, type, 'effector-cell': $i).
% 29.22/29.02  tff(decl_33147, type, 'Efferent-Arteriole': $i).
% 29.22/29.02  tff(decl_33148, type, 'In the kidney, the blood vessel draining a nephron.': $i).
% 29.22/29.02  tff(decl_33149, type, 'efferent arteriole': $i).
% 29.22/29.02  tff(decl_33150, type, 'efferent-arteriole': $i).
% 29.22/29.02  tff(decl_33151, type, 'Egg': $i).
% 29.22/29.02  tff(decl_33152, type, 'An egg is a reproductive structure in animals within which the embryo first begins to develop. Eggs may contain nutrients for the developing embryo, as well as a hardened shell for protection.': $i).
% 29.22/29.02  tff(decl_33153, type, ovum: $i).
% 29.22/29.02  tff(decl_33154, type, 'unfertilized egg': $i).
% 29.22/29.02  tff(decl_33155, type, 'unfertilized egg cell': $i).
% 29.22/29.02  tff(decl_33156, type, egg: $i).
% 29.22/29.02  tff(decl_33157, type, fn_egg_1: $i > $i).
% 29.22/29.02  tff(decl_33158, type, egg_activation_1: $i > $o).
% 29.22/29.02  tff(decl_33159, type, 'Egg-Activation': $i).
% 29.22/29.02  tff(decl_33160, type, 'A sharp increase in an animal egg\\s metabolic activities due to calcium entry into the egg in response to sperm penetration. Egg activation includes the cortical reaction, the reactivation of meiosis, and DNA synthesis.': $i).
% 29.22/29.02  tff(decl_33161, type, 'activation of egg': $i).
% 29.22/29.02  tff(decl_33162, type, 'egg activation': $i).
% 29.22/29.02  tff(decl_33163, type, 'egg-activation': $i).
% 29.22/29.02  tff(decl_33164, type, 'Egg-Cell': $i).
% 29.22/29.02  tff(decl_33165, type, 'An egg cell is the female gamete or female sex cell.': $i).
% 29.22/29.02  tff(decl_33166, type, 'cell of egg': $i).
% 29.22/29.02  tff(decl_33167, type, 'egg cell': $i).
% 29.22/29.02  tff(decl_33168, type, 'egg-cell': $i).
% 29.22/29.02  tff(decl_33169, type, egg_laying_animal_1: $i > $o).
% 29.22/29.02  tff(decl_33170, type, 'Egg-Laying-Animal': $i).
% 29.22/29.02  tff(decl_33171, type, 'An animal producing egg during thr process of reproduction is an egg laying animal.': $i).
% 29.22/29.02  tff(decl_33172, type, 'oviparous animal': $i).
% 29.22/29.02  tff(decl_33173, type, 'egg laying animal': $i).
% 29.22/29.02  tff(decl_33174, type, 'egg-laying-animal': $i).
% 29.22/29.02  tff(decl_33175, type, fn_egg_laying_animal_1: $i > $i).
% 29.22/29.02  tff(decl_33176, type, fn_egg_laying_process_1: $i > $i).
% 29.22/29.02  tff(decl_33177, type, 'Egg-Laying-Process': $i).
% 29.22/29.02  tff(decl_33178, type, 'The process of an animal producing egg during the process of reproduction is an egg laying process.': $i).
% 29.22/29.02  tff(decl_33179, type, oviposition: $i).
% 29.22/29.02  tff(decl_33180, type, lay: $i).
% 29.22/29.02  tff(decl_33181, type, 'egg laying process': $i).
% 29.22/29.02  tff(decl_33182, type, 'egg-laying-process': $i).
% 29.22/29.02  tff(decl_33183, type, reproductive_process_1: $i > $o).
% 29.22/29.02  tff(decl_33184, type, fn_reproduction_2: $i > $i).
% 29.22/29.02  tff(decl_33185, type, 'Egg-Shell': $i).
% 29.22/29.02  tff(decl_33186, type, 'An outer covering around the zygote of the egg is called egg shell.': $i).
% 29.22/29.02  tff(decl_33187, type, 'shell of egg': $i).
% 29.22/29.02  tff(decl_33188, type, 'egg shell': $i).
% 29.22/29.02  tff(decl_33189, type, 'egg-shell': $i).
% 29.22/29.02  tff(decl_33190, type, 'Eight-Cell-Embryo': $i).
% 29.22/29.02  tff(decl_33191, type, 'An embryo that has divided into eight cells is called an eight cell embryo.': $i).
% 29.22/29.02  tff(decl_33192, type, 'eight cell embryo': $i).
% 29.22/29.02  tff(decl_33193, type, 'eight-cell-embryo': $i).
% 29.22/29.02  tff(decl_33194, type, fn_eight_cell_embryo_1: $i > $i).
% 29.22/29.02  tff(decl_33195, type, 'Eight-Cell-Stage': $i).
% 29.22/29.02  tff(decl_33196, type, 'The developmental stage of an organism where the embryo has divided into eight cells is called an eight cell stage.': $i).
% 29.22/29.02  tff(decl_33197, type, 'undergo the eight cell stage': $i).
% 29.22/29.02  tff(decl_33198, type, 'eight cell stage': $i).
% 29.22/29.02  tff(decl_33199, type, 'eight-cell-stage': $i).
% 29.22/29.02  tff(decl_33200, type, einsteinium_1: $i > $o).
% 29.22/29.02  tff(decl_33201, type, 'Einsteinium': $i).
% 29.22/29.02  tff(decl_33202, type, 'Einsteinium is a metal atom with atomic number 99. It is represented by the symbol Es.': $i).
% 29.22/29.02  tff(decl_33203, type, einsteinium: $i).
% 29.22/29.02  tff(decl_33204, type, es: $i).
% 29.22/29.02  tff(decl_33205, type, fn_einsteinium_3: $i > $i).
% 29.22/29.02  tff(decl_33206, type, fn_einsteinium_4: $i > $i).
% 29.22/29.02  tff(decl_33207, type, fn_einsteinium_5: $i > $i).
% 29.22/29.02  tff(decl_33208, type, fn_einsteinium_9: $i > $i).
% 29.22/29.02  tff(decl_33209, type, fn_einsteinium_10: $i > $i).
% 29.22/29.02  tff(decl_33210, type, fn_einsteinium_11: $i > $i).
% 29.22/29.02  tff(decl_33211, type, fn_einsteinium_12: $i > $i).
% 29.22/29.02  tff(decl_33212, type, "99": $i).
% 29.22/29.02  tff(decl_33213, type, "252": $i).
% 29.22/29.02  tff(decl_33214, type, fn_einsteinium_7: $i > $i).
% 29.22/29.02  tff(decl_33215, type, fn_einsteinium_8: $i > $i).
% 29.22/29.02  tff(decl_33216, type, fn_einsteinium_6: $i > $i).
% 29.22/29.02  tff(decl_33217, type, ejaculation_1: $i > $o).
% 29.22/29.02  tff(decl_33218, type, 'Ejaculation': $i).
% 29.22/29.02  tff(decl_33219, type, 'The forceful ejection of semen from the male reproductive tract.': $i).
% 29.22/29.02  tff(decl_33220, type, ejaculate: $i).
% 29.22/29.02  tff(decl_33221, type, ejaculation: $i).
% 29.22/29.02  tff(decl_33222, type, 'Ejaculatory-Duct': $i).
% 29.22/29.02  tff(decl_33223, type, 'In mammals, short paired tubes that transport semen from the vas deferens to the urethra. The ejaculatory ducts pass through the prostate gland and open into the urethra.': $i).
% 29.22/29.02  tff(decl_33224, type, 'ductus ejaculatorii': $i).
% 29.22/29.02  tff(decl_33225, type, 'ductus-ejaculatorii': $i).
% 29.22/29.02  tff(decl_33226, type, 'ejaculatory duct': $i).
% 29.22/29.02  tff(decl_33227, type, 'ejaculatory-duct': $i).
% 29.22/29.02  tff(decl_33228, type, electric_current_1: $i > $o).
% 29.22/29.02  tff(decl_33229, type, 'Electric-Current': $i).
% 29.22/29.02  tff(decl_33230, type, 'Flow of electric charge through a medium.': $i).
% 29.22/29.02  tff(decl_33231, type, 'current of electric': $i).
% 29.22/29.02  tff(decl_33232, type, 'electric current': $i).
% 29.22/29.02  tff(decl_33233, type, 'electric-current': $i).
% 29.22/29.02  tff(decl_33234, type, fn_electric_current_1: $i > $i).
% 29.22/29.02  tff(decl_33235, type, fn_electric_current_2: $i > $i).
% 29.22/29.02  tff(decl_33236, type, galvanometer_1: $i > $o).
% 29.22/29.02  tff(decl_33237, type, electric_current_pulse_1: $i > $o).
% 29.22/29.02  tff(decl_33238, type, 'Electric-Current-Pulse': $i).
% 29.22/29.02  tff(decl_33239, type, 'The pulses of electric current.': $i).
% 29.22/29.02  tff(decl_33240, type, 'pulse of electric current': $i).
% 29.22/29.02  tff(decl_33241, type, 'pulse of electrical current': $i).
% 29.22/29.02  tff(decl_33242, type, 'electric current pulse': $i).
% 29.22/29.02  tff(decl_33243, type, 'electric-current-pulse': $i).
% 29.22/29.02  tff(decl_33244, type, electric_force_1: $i > $o).
% 29.22/29.02  tff(decl_33245, type, 'Electric-Force': $i).
% 29.22/29.02  tff(decl_33246, type, 'A force exerted by electrically charged particles.': $i).
% 29.22/29.02  tff(decl_33247, type, 'force of electric': $i).
% 29.22/29.02  tff(decl_33248, type, 'electric force': $i).
% 29.22/29.02  tff(decl_33249, type, 'electric-force': $i).
% 29.22/29.02  tff(decl_33250, type, 'Electrical-Power-Plant': $i).
% 29.22/29.02  tff(decl_33251, type, 'Man-made system that generates, manages, and dispenses power to communities.': $i).
% 29.22/29.02  tff(decl_33252, type, 'power plant': $i).
% 29.22/29.02  tff(decl_33253, type, 'electrical power plant': $i).
% 29.22/29.02  tff(decl_33254, type, 'electrical-power-plant': $i).
% 29.22/29.02  tff(decl_33255, type, electrical_signal_1: $i > $o).
% 29.22/29.02  tff(decl_33256, type, 'Electrical-Signal': $i).
% 29.22/29.02  tff(decl_33257, type, 'A change in membrane voltage across the membrane of a neuron caused by depolarization initiated by a stimulus.': $i).
% 29.22/29.02  tff(decl_33258, type, 'electrical signal': $i).
% 29.22/29.02  tff(decl_33259, type, 'electrical-signal': $i).
% 29.22/29.02  tff(decl_33260, type, elicitor_1: $i > $o).
% 29.22/29.02  tff(decl_33261, type, florigen_1: $i > $o).
% 29.22/29.02  tff(decl_33262, type, 'Electrical-Signaling': $i).
% 29.22/29.02  tff(decl_33263, type, 'A mode of long-distance communication by neurons.': $i).
% 29.22/29.02  tff(decl_33264, type, 'nerve signaling': $i).
% 29.22/29.02  tff(decl_33265, type, 'neural signaling': $i).
% 29.22/29.02  tff(decl_33266, type, 'electrical signaling': $i).
% 29.22/29.02  tff(decl_33267, type, 'electrical-signaling': $i).
% 29.22/29.02  tff(decl_33268, type, fn_electrical_signaling_3: $i > $i).
% 29.22/29.02  tff(decl_33269, type, fn_electrical_signaling_6: $i > $i).
% 29.22/29.02  tff(decl_33270, type, fn_electrical_signaling_7: $i > $i).
% 29.22/29.02  tff(decl_33271, type, fn_electrical_signaling_10: $i > $i).
% 29.22/29.02  tff(decl_33272, type, fn_electrical_signaling_11: $i > $i).
% 29.22/29.02  tff(decl_33273, type, fn_electrical_signaling_12: $i > $i).
% 29.22/29.02  tff(decl_33274, type, fn_long_distance_cell_communication_9: $i > $i).
% 29.22/29.02  tff(decl_33275, type, electrical_synapse_1: $i > $o).
% 29.22/29.02  tff(decl_33276, type, 'Electrical-Synapse': $i).
% 29.22/29.02  tff(decl_33277, type, 'Synapses that allow action potentials to spread directly from the presynaptic cell to the postsynaptic cell.': $i).
% 29.22/29.02  tff(decl_33278, type, 'electrical synapse': $i).
% 29.22/29.02  tff(decl_33279, type, 'electrical-synapse': $i).
% 29.22/29.02  tff(decl_33280, type, 'Electrically-Charged-Amino-Acid': $i).
% 29.22/29.02  tff(decl_33281, type, 'An amino acid has hydrophillic properties due to the presence of an electrically charged side chain.': $i).
% 29.22/29.02  tff(decl_33282, type, 'electrically charged amino acid': $i).
% 29.22/29.02  tff(decl_33283, type, 'electrically-charged-amino-acid': $i).
% 29.22/29.02  tff(decl_33284, type, hydrophilic_amino_acid_1: $i > $o).
% 29.22/29.02  tff(decl_33285, type, 'Electrocardiogram': $i).
% 29.22/29.02  tff(decl_33286, type, 'A medical test that records the electrical activity of the heart.': $i).
% 29.22/29.02  tff(decl_33287, type, electrocardiogram: $i).
% 29.22/29.02  tff(decl_33288, type, 'Electrochemical-Gradient': $i).
% 29.22/29.02  tff(decl_33289, type, 'An electrochemical gradient is a spatial variation of both electrical potential and chemical concentration across a membrane.': $i).
% 29.22/29.02  tff(decl_33290, type, 'ion gradient': $i).
% 29.22/29.02  tff(decl_33291, type, 'ion-gradient': $i).
% 29.22/29.02  tff(decl_33292, type, 'electrochemical gradient': $i).
% 29.22/29.02  tff(decl_33293, type, 'electrochemical-gradient': $i).
% 29.22/29.02  tff(decl_33294, type, fn_electrochemical_gradient_2: $i > $i).
% 29.22/29.02  tff(decl_33295, type, fn_electrochemical_gradient_11: $i > $i).
% 29.22/29.02  tff(decl_33296, type, fn_electrochemical_gradient_12: $i > $i).
% 29.22/29.02  tff(decl_33297, type, fn_electrochemical_gradient_13: $i > $i).
% 29.22/29.02  tff(decl_33298, type, fn_electrochemical_gradient_14: $i > $i).
% 29.22/29.02  tff(decl_33299, type, fn_electrochemical_gradient_15: $i > $i).
% 29.22/29.02  tff(decl_33300, type, fn_electrochemical_gradient_16: $i > $i).
% 29.22/29.02  tff(decl_33301, type, fn_electrochemical_gradient_17: $i > $i).
% 29.22/29.02  tff(decl_33302, type, fn_gradient_4: $i > $i).
% 29.22/29.02  tff(decl_33303, type, 'CG': $i).
% 29.22/29.02  tff(decl_33304, type, 'MP': $i).
% 29.22/29.02  tff(decl_33305, type, 'PE_MP': $i).
% 29.22/29.02  tff(decl_33306, type, 'PE_CG': $i).
% 29.22/29.02  tff(decl_33307, type, fn_electrochemical_gradient_10: $i > $i).
% 29.22/29.02  tff(decl_33308, type, fn_electrochemical_gradient_8: $i > $i).
% 29.22/29.02  tff(decl_33309, type, fn_electrochemical_gradient_7: $i > $i).
% 29.22/29.02  tff(decl_33310, type, fn_electrochemical_gradient_19: $i > $i).
% 29.22/29.02  tff(decl_33311, type, fn_electrochemical_gradient_6: $i > $i).
% 29.22/29.02  tff(decl_33312, type, fn_electrochemical_gradient_9: $i > $i).
% 29.22/29.02  tff(decl_33313, type, 'Electrogenic-Pump': $i).
% 29.22/29.02  tff(decl_33314, type, 'Ion pump that generates net charge flow as a result of its activity. The sodium potassium exchange pump transports two potassium ions inward across the cell membrane for each three sodiums transported outward. This produces a net outward current that contributes to the internal negativity of the cell.': $i).
% 29.22/29.02  tff(decl_33315, type, 'ion pump': $i).
% 29.22/29.02  tff(decl_33316, type, 'ion-pump': $i).
% 29.22/29.02  tff(decl_33317, type, 'electrogenic pump': $i).
% 29.22/29.02  tff(decl_33318, type, 'electrogenic-pump': $i).
% 29.22/29.02  tff(decl_33319, type, fn_electrogenic_pump_1: $i > $i).
% 29.22/29.02  tff(decl_33320, type, fn_electrogenic_pump_3: $i > $i).
% 29.22/29.02  tff(decl_33321, type, fn_electrogenic_pump_6: $i > $i).
% 29.22/29.02  tff(decl_33322, type, fn_electrogenic_pump_7: $i > $i).
% 29.22/29.02  tff(decl_33323, type, fn_electrogenic_pump_8: $i > $i).
% 29.22/29.02  tff(decl_33324, type, fn_electrogenic_pump_16: $i > $i).
% 29.22/29.02  tff(decl_33325, type, fn_electrogenic_pump_18: $i > $i).
% 29.22/29.02  tff(decl_33326, type, fn_electrogenic_pump_21: $i > $i).
% 29.22/29.02  tff(decl_33327, type, fn_electrogenic_pump_25: $i > $i).
% 29.22/29.02  tff(decl_33328, type, fn_electrogenic_pump_26: $i > $i).
% 29.22/29.02  tff(decl_33329, type, fn_electrogenic_pump_27: $i > $i).
% 29.22/29.02  tff(decl_33330, type, fn_electrogenic_pump_29: $i > $i).
% 29.22/29.02  tff(decl_33331, type, fn_electrogenic_pump_31: $i > $i).
% 29.22/29.02  tff(decl_33332, type, fn_electrogenic_pump_33: $i > $i).
% 29.22/29.02  tff(decl_33333, type, fn_facilitated_diffusion_24: $i > $i).
% 29.22/29.02  tff(decl_33334, type, fn_facilitated_diffusion_23: $i > $i).
% 29.22/29.02  tff(decl_33335, type, fn_facilitated_diffusion_22: $i > $i).
% 29.22/29.02  tff(decl_33336, type, fn_facilitated_diffusion_21: $i > $i).
% 29.22/29.02  tff(decl_33337, type, fn_facilitated_diffusion_40: $i > $i).
% 29.22/29.02  tff(decl_33338, type, fn_facilitated_diffusion_32: $i > $i).
% 29.22/29.02  tff(decl_33339, type, fn_facilitated_diffusion_30: $i > $i).
% 29.22/29.02  tff(decl_33340, type, fn_facilitated_diffusion_29: $i > $i).
% 29.22/29.02  tff(decl_33341, type, fn_facilitated_diffusion_33: $i > $i).
% 29.22/29.02  tff(decl_33342, type, fn_facilitated_diffusion_42: $i > $i).
% 29.22/29.02  tff(decl_33343, type, fn_facilitated_diffusion_43: $i > $i).
% 29.22/29.02  tff(decl_33344, type, fn_facilitated_diffusion_36: $i > $i).
% 29.22/29.02  tff(decl_33345, type, fn_facilitated_diffusion_41: $i > $i).
% 29.22/29.02  tff(decl_33346, type, fn_facilitated_diffusion_27: $i > $i).
% 29.22/29.02  tff(decl_33347, type, fn_facilitated_diffusion_46: $i > $i).
% 29.22/29.02  tff(decl_33348, type, fn_membrane_potential_2: $i > $i).
% 29.22/29.02  tff(decl_33349, type, fn_electrogenic_pump_36: $i > $i).
% 29.22/29.02  tff(decl_33350, type, fn_electrogenic_pump_38: $i > $i).
% 29.22/29.02  tff(decl_33351, type, fn_electrogenic_pump_39: $i > $i).
% 29.22/29.02  tff(decl_33352, type, fn_protein_pump_5: $i > $i).
% 29.22/29.02  tff(decl_33353, type, fn_protein_pump_4: $i > $i).
% 29.22/29.02  tff(decl_33354, type, electrolyte_1: $i > $o).
% 29.22/29.02  tff(decl_33355, type, 'Electrolyte': $i).
% 29.22/29.02  tff(decl_33356, type, 'A solute that produces ions in a solution': $i).
% 29.22/29.02  tff(decl_33357, type, electrolyte: $i).
% 29.22/29.02  tff(decl_33358, type, electrolyte_entity_1: $i > $o).
% 29.22/29.02  tff(decl_33359, type, 'Electrolyte-Entity': $i).
% 29.22/29.02  tff(decl_33360, type, 'An electrolyte is a solute that produces ions in solution; an electrolytic solution conducts an electric current.': $i).
% 29.22/29.02  tff(decl_33361, type, 'entity of electrolyte': $i).
% 29.22/29.02  tff(decl_33362, type, 'electrolyte entity': $i).
% 29.22/29.02  tff(decl_33363, type, 'electrolyte-entity': $i).
% 29.22/29.02  tff(decl_33364, type, 'Electrolyte-Status-Constant': $i).
% 29.22/29.02  tff(decl_33365, type, 'electrolyte status constant': $i).
% 29.22/29.02  tff(decl_33366, type, 'electrolyte-status-constant': $i).
% 29.22/29.02  tff(decl_33367, type, 'Electrolyte-Status-Value': $i).
% 29.22/29.02  tff(decl_33368, type, 'The degree of ionization for a solution, e.g. non-electrolyte, weak-electrolyte, or strong-electrolyte.': $i).
% 29.22/29.02  tff(decl_33369, type, 'status of electrolyte': $i).
% 29.22/29.02  tff(decl_33370, type, 'electrolyte status': $i).
% 29.22/29.02  tff(decl_33371, type, 'electrolyte-status': $i).
% 29.22/29.02  tff(decl_33372, type, 'electrolyte status value': $i).
% 29.22/29.02  tff(decl_33373, type, 'electrolyte-status-value': $i).
% 29.22/29.02  tff(decl_33374, type, electromagnet_1: $i > $o).
% 29.22/29.02  tff(decl_33375, type, 'Electromagnet': $i).
% 29.22/29.02  tff(decl_33376, type, 'A type of magnet whose magnetic field is produced by the flow of electric current.': $i).
% 29.22/29.02  tff(decl_33377, type, 'electromagnetic lens': $i).
% 29.22/29.02  tff(decl_33378, type, 'electromagnetic-lens': $i).
% 29.22/29.02  tff(decl_33379, type, electromagnet: $i).
% 29.22/29.02  tff(decl_33380, type, lens_1: $i > $o).
% 29.22/29.02  tff(decl_33381, type, glass_lens_1: $i > $o).
% 29.22/29.02  tff(decl_33382, type, electromagnetic_energy_1: $i > $o).
% 29.22/29.02  tff(decl_33383, type, 'Electromagnetic-Energy': $i).
% 29.22/29.02  tff(decl_33384, type, 'The energy that comes from electromagnetic radiation.': $i).
% 29.22/29.02  tff(decl_33385, type, 'electromagnetic radiation': $i).
% 29.22/29.02  tff(decl_33386, type, 'electromagnetic-radiation': $i).
% 29.22/29.02  tff(decl_33387, type, 'electromagentic wave': $i).
% 29.22/29.02  tff(decl_33388, type, 'electromagnetic energy': $i).
% 29.22/29.02  tff(decl_33389, type, 'electromagnetic-energy': $i).
% 29.22/29.02  tff(decl_33390, type, radiation_1: $i > $o).
% 29.22/29.02  tff(decl_33391, type, electromagnetic_process_1: $i > $o).
% 29.22/29.02  tff(decl_33392, type, 'Electromagnetic-Process': $i).
% 29.22/29.02  tff(decl_33393, type, 'A process related to electromagnetic radiation.': $i).
% 29.22/29.02  tff(decl_33394, type, 'electromagnetic process': $i).
% 29.22/29.02  tff(decl_33395, type, 'electromagnetic-process': $i).
% 29.22/29.02  tff(decl_33396, type, 'Electromagnetic-Receptor': $i).
% 29.22/29.02  tff(decl_33397, type, 'A sensory receptor that responds to electromagnetic energy such as light, magnetism, or electricity.': $i).
% 29.22/29.02  tff(decl_33398, type, 'electromagnetic receptor': $i).
% 29.22/29.02  tff(decl_33399, type, 'electromagnetic-receptor': $i).
% 29.22/29.02  tff(decl_33400, type, electromagnetic_spectrum_1: $i > $o).
% 29.22/29.02  tff(decl_33401, type, 'Electromagnetic-Spectrum': $i).
% 29.22/29.02  tff(decl_33402, type, 'The full range of electromagnetic radiation which varies greatly in wavelength.': $i).
% 29.22/29.02  tff(decl_33403, type, 'electromagnetic spectrum': $i).
% 29.22/29.02  tff(decl_33404, type, 'electromagnetic-spectrum': $i).
% 29.22/29.02  tff(decl_33405, type, spectrum_1: $i > $o).
% 29.22/29.02  tff(decl_33406, type, fn_electromagnetic_spectrum_1: $i > $i).
% 29.22/29.02  tff(decl_33407, type, radio_waves_1: $i > $o).
% 29.22/29.02  tff(decl_33408, type, fn_electromagnetic_spectrum_2: $i > $i).
% 29.22/29.02  tff(decl_33409, type, microwaves_1: $i > $o).
% 29.22/29.02  tff(decl_33410, type, fn_electromagnetic_spectrum_3: $i > $i).
% 29.22/29.02  tff(decl_33411, type, fn_electromagnetic_spectrum_4: $i > $i).
% 29.22/29.02  tff(decl_33412, type, gamma_rays_1: $i > $o).
% 29.22/29.02  tff(decl_33413, type, fn_electromagnetic_spectrum_5: $i > $i).
% 29.22/29.02  tff(decl_33414, type, x_rays_1: $i > $o).
% 29.22/29.02  tff(decl_33415, type, fn_electromagnetic_spectrum_6: $i > $i).
% 29.22/29.02  tff(decl_33416, type, ultraviolet_rays_1: $i > $o).
% 29.22/29.02  tff(decl_33417, type, fn_electromagnetic_spectrum_7: $i > $i).
% 29.22/29.02  tff(decl_33418, type, infrared_rays_1: $i > $o).
% 29.22/29.02  tff(decl_33419, type, fn_visible_light_7: $i > $i).
% 29.22/29.02  tff(decl_33420, type, fn_infrared_rays_5: $i > $i).
% 29.22/29.02  tff(decl_33421, type, fn_ultraviolet_rays_5: $i > $i).
% 29.22/29.02  tff(decl_33422, type, fn_radio_waves_7: $i > $i).
% 29.22/29.02  tff(decl_33423, type, fn_x_rays_1: $i > $i).
% 29.22/29.02  tff(decl_33424, type, fn_microwaves_1: $i > $i).
% 29.22/29.02  tff(decl_33425, type, fn_gamma_rays_7: $i > $i).
% 29.22/29.02  tff(decl_33426, type, 'Electron': $i).
% 29.22/29.02  tff(decl_33427, type, 'A subatomic particle that carries a charge of -1. An atom has one or more electrons orbiting its nucleus.': $i).
% 29.22/29.02  tff(decl_33428, type, electron: $i).
% 29.22/29.02  tff(decl_33429, type, subatomic_particle_1: $i > $o).
% 29.22/29.02  tff(decl_33430, type, fn_electron_1: $i > $i).
% 29.22/29.02  tff(decl_33431, type, fn_electron_4: $i > $i).
% 29.22/29.02  tff(decl_33432, type, fn_electron_6: $i > $i).
% 29.22/29.02  tff(decl_33433, type, fn_electron_8: $i > $i).
% 29.22/29.02  tff(decl_33434, type, electron_beam_1: $i > $o).
% 29.22/29.02  tff(decl_33435, type, 'Electron-Beam': $i).
% 29.22/29.02  tff(decl_33436, type, 'A stream of electrons observed in a vacuum or in gas.': $i).
% 29.22/29.02  tff(decl_33437, type, 'beam of electron': $i).
% 29.22/29.02  tff(decl_33438, type, 'electron beam': $i).
% 29.22/29.02  tff(decl_33439, type, 'electron-beam': $i).
% 29.22/29.02  tff(decl_33440, type, radioactive_emissions_1: $i > $o).
% 29.22/29.02  tff(decl_33441, type, fn_electron_beam_1: $i > $i).
% 29.22/29.02  tff(decl_33442, type, fn_electron_beam_2: $i > $i).
% 29.22/29.02  tff(decl_33443, type, 'Electron-Carrier': $i).
% 29.22/29.02  tff(decl_33444, type, 'Coenzyme in a pathway that accepts high-energy electrons.': $i).
% 29.22/29.02  tff(decl_33445, type, 'carrier of electron': $i).
% 29.22/29.02  tff(decl_33446, type, 'electron carrier': $i).
% 29.22/29.02  tff(decl_33447, type, 'electron-carrier': $i).
% 29.22/29.02  tff(decl_33448, type, fn_electron_carrier_2: $i > $i).
% 29.22/29.02  tff(decl_33449, type, fn_electron_carrier_3: $i > $i).
% 29.22/29.02  tff(decl_33450, type, electron_carrier_of_cellular_respiration_1: $i > $o).
% 29.22/29.02  tff(decl_33451, type, 'Electron-carrier-of-Cellular-Respiration': $i).
% 29.22/29.02  tff(decl_33452, type, 'A coenzyme that accepts electrons stripped from glucose at various steps of cellular respiration, then gives them up in the electron transport chain.  These coenzymes include NAD+ and FAD+, which become NADH and FADH2 when they carry electrons.': $i).
% 29.22/29.02  tff(decl_33453, type, 'electron carrier of cellular respiration': $i).
% 29.22/29.02  tff(decl_33454, type, 'electron-carrier-of-cellular-respiration': $i).
% 29.22/29.02  tff(decl_33455, type, electron_carrier_of_photosynthesis_1: $i > $o).
% 29.22/29.02  tff(decl_33456, type, 'Electron-carrier-of-Photosynthesis': $i).
% 29.22/29.02  tff(decl_33457, type, 'A coenzyme, NADP+, that accepts electrons from the electron transport chain in photosynthesis, then gives them up in the Calvin Cycle, in order to make sugar.': $i).
% 29.22/29.02  tff(decl_33458, type, 'nadp+ of photosynthesis': $i).
% 29.22/29.02  tff(decl_33459, type, 'nadph of photosynthesis': $i).
% 29.22/29.02  tff(decl_33460, type, nadph: $i).
% 29.22/29.02  tff(decl_33461, type, 'nadp+': $i).
% 29.22/29.02  tff(decl_33462, type, 'electron carrier of photosynthesis': $i).
% 29.22/29.02  tff(decl_33463, type, 'electron-carrier-of-photosynthesis': $i).
% 29.22/29.02  tff(decl_33464, type, electron_configuration_1: $i > $o).
% 29.22/29.02  tff(decl_33465, type, 'Electron-Configuration': $i).
% 29.22/29.02  tff(decl_33466, type, 'The distribution of electrons in an atom\\s electron orbitals.': $i).
% 29.22/29.02  tff(decl_33467, type, 'configuration of electron': $i).
% 29.22/29.02  tff(decl_33468, type, 'electron configuration': $i).
% 29.22/29.02  tff(decl_33469, type, 'electron-configuration': $i).
% 29.22/29.02  tff(decl_33470, type, 'Electron-Donor': $i).
% 29.22/29.02  tff(decl_33471, type, 'An electron donor is a role played by a chemical entity that donates electrons to another compound.': $i).
% 29.22/29.02  tff(decl_33472, type, 'donor of electron': $i).
% 29.22/29.02  tff(decl_33473, type, 'electron donor': $i).
% 29.22/29.02  tff(decl_33474, type, 'electron-donor': $i).
% 29.22/29.02  tff(decl_33475, type, electron_microscope_1: $i > $o).
% 29.22/29.02  tff(decl_33476, type, 'Electron-Microscope': $i).
% 29.22/29.02  tff(decl_33477, type, 'A microscope that has a thousand times the resolving power of a light microscope. A transmission electron microscope (TEM) is used to study the internal structure of thin sections of cells and a scanning electron microscope (SEM) is used to study the fine details of cell surfaces. Electron microscopy requires a specimen to be fixed onto a slide and cannot be used to examine living specimens.': $i).
% 29.22/29.02  tff(decl_33478, type, 'microscope of electron': $i).
% 29.22/29.02  tff(decl_33479, type, 'electron microscope': $i).
% 29.22/29.02  tff(decl_33480, type, 'electron-microscope': $i).
% 29.22/29.02  tff(decl_33481, type, transmission_electron_microscope_1: $i > $o).
% 29.22/29.02  tff(decl_33482, type, fn_electron_microscope_1: $i > $i).
% 29.22/29.02  tff(decl_33483, type, fn_electron_microscope_2: $i > $i).
% 29.22/29.02  tff(decl_33484, type, 'Electron-Microscopy': $i).
% 29.22/29.02  tff(decl_33485, type, 'Electron microscopy uses the electron microscope, a type of microscope that produces an electronically-magnified image of a specimen for detailed observation.': $i).
% 29.22/29.02  tff(decl_33486, type, 'microscopy of electron': $i).
% 29.22/29.02  tff(decl_33487, type, 'electron microscopy': $i).
% 29.22/29.02  tff(decl_33488, type, 'electron-microscopy': $i).
% 29.22/29.02  tff(decl_33489, type, fn_electron_microscopy_1: $i > $i).
% 29.22/29.02  tff(decl_33490, type, fn_electron_microscopy_2: $i > $i).
% 29.22/29.02  tff(decl_33491, type, fn_electron_microscopy_3: $i > $i).
% 29.22/29.02  tff(decl_33492, type, fn_electron_microscopy_4: $i > $i).
% 29.22/29.02  tff(decl_33493, type, see_1: $i > $o).
% 29.22/29.02  tff(decl_33494, type, fn_electron_microscopy_5: $i > $i).
% 29.22/29.02  tff(decl_33495, type, fn_electron_microscopy_6: $i > $i).
% 29.22/29.02  tff(decl_33496, type, fn_electron_microscopy_7: $i > $i).
% 29.22/29.02  tff(decl_33497, type, fn_electron_microscopy_8: $i > $i).
% 29.22/29.02  tff(decl_33498, type, fn_electron_microscopy_9: $i > $i).
% 29.22/29.02  tff(decl_33499, type, fn_electron_microscopy_10: $i > $i).
% 29.22/29.02  tff(decl_33500, type, fn_electron_microscopy_11: $i > $i).
% 29.22/29.02  tff(decl_33501, type, fn_sense_1: $i > $i).
% 29.22/29.02  tff(decl_33502, type, fn_microscopy_5: $i > $i).
% 29.22/29.02  tff(decl_33503, type, 'Electron-Recipient': $i).
% 29.22/29.02  tff(decl_33504, type, 'An electron recipient is a role played by an object that accepts electrons from another compound.': $i).
% 29.22/29.02  tff(decl_33505, type, 'electron acceptor': $i).
% 29.22/29.02  tff(decl_33506, type, 'electron-acceptor': $i).
% 29.22/29.02  tff(decl_33507, type, 'recipient of electron': $i).
% 29.22/29.02  tff(decl_33508, type, 'electron recipient': $i).
% 29.22/29.02  tff(decl_33509, type, 'electron-recipient': $i).
% 29.22/29.02  tff(decl_33510, type, recipient_role_1: $i > $o).
% 29.22/29.02  tff(decl_33511, type, fn_recipient_role_1: $i > $i).
% 29.22/29.02  tff(decl_33512, type, 'Electron-Shell': $i).
% 29.22/29.02  tff(decl_33513, type, 'One of the energy levels at which electrons can exist in an atom. Each electron shell has a characteristic average distance away from the nucleus of the atom.': $i).
% 29.22/29.02  tff(decl_33514, type, 'energy level': $i).
% 29.22/29.02  tff(decl_33515, type, 'energy-level': $i).
% 29.22/29.02  tff(decl_33516, type, 'electron energy level': $i).
% 29.22/29.02  tff(decl_33517, type, 'electron-energy-level': $i).
% 29.22/29.02  tff(decl_33518, type, 'shell of electron': $i).
% 29.22/29.02  tff(decl_33519, type, 'electron shell': $i).
% 29.22/29.02  tff(decl_33520, type, 'electron-shell': $i).
% 29.22/29.02  tff(decl_33521, type, orbital_1: $i > $o).
% 29.22/29.02  tff(decl_33522, type, 'Electron-Shuttle-System': $i).
% 29.22/29.02  tff(decl_33523, type, 'An electron shuttle system is a molecular assembly that can transport electrons  inside cell. The two electrons of NADH captured in glycolysis must be conveyed into the mitochondrion by one of several electron shuttle systems.': $i).
% 29.22/29.02  tff(decl_33524, type, 'electron shuttle system': $i).
% 29.22/29.02  tff(decl_33525, type, 'electron-shuttle-system': $i).
% 29.22/29.02  tff(decl_33526, type, electron_transport_assembly_1: $i > $o).
% 29.22/29.02  tff(decl_33527, type, fn_electron_shuttle_system_1: $i > $i).
% 29.22/29.02  tff(decl_33528, type, fn_electron_shuttle_system_2: $i > $i).
% 29.22/29.02  tff(decl_33529, type, fn_electron_shuttle_system_3: $i > $i).
% 29.22/29.02  tff(decl_33530, type, fn_electron_shuttle_system_4: $i > $i).
% 29.22/29.02  tff(decl_33531, type, fn_electron_shuttle_system_5: $i > $i).
% 29.22/29.02  tff(decl_33532, type, fn_electron_shuttle_system_6: $i > $i).
% 29.22/29.02  tff(decl_33533, type, fn_electron_shuttle_system_7: $i > $i).
% 29.22/29.02  tff(decl_33534, type, fn_electron_shuttle_system_8: $i > $i).
% 29.22/29.02  tff(decl_33535, type, fn_electron_shuttle_system_9: $i > $i).
% 29.22/29.02  tff(decl_33536, type, fn_electron_shuttle_system_10: $i > $i).
% 29.22/29.02  tff(decl_33537, type, fn_electron_shuttle_system_11: $i > $i).
% 29.22/29.02  tff(decl_33538, type, fn_electron_shuttle_system_12: $i > $i).
% 29.22/29.02  tff(decl_33539, type, fn_electron_shuttle_system_13: $i > $i).
% 29.22/29.02  tff(decl_33540, type, fn_electron_shuttle_system_14: $i > $i).
% 29.22/29.02  tff(decl_33541, type, fn_electron_shuttle_system_15: $i > $i).
% 29.22/29.02  tff(decl_33542, type, fn_electron_shuttle_system_16: $i > $i).
% 29.22/29.02  tff(decl_33543, type, fn_electron_shuttle_system_17: $i > $i).
% 29.22/29.02  tff(decl_33544, type, fn_electron_shuttle_system_18: $i > $i).
% 29.22/29.02  tff(decl_33545, type, fn_electron_shuttle_system_19: $i > $i).
% 29.22/29.02  tff(decl_33546, type, fn_fad_3: $i > $i).
% 29.22/29.02  tff(decl_33547, type, donor_0: $i).
% 29.22/29.02  tff(decl_33548, type, 'Electron-Transport-Assembly': $i).
% 29.22/29.02  tff(decl_33549, type, 'A molecular assembly which shuttles electrons to do cellular work.Light-Harvesting-Complexes have parts including electron transport assemblies, antenna pigments, and accessory pigments.': $i).
% 29.22/29.02  tff(decl_33550, type, 'electron transport assembly': $i).
% 29.22/29.02  tff(decl_33551, type, 'electron-transport-assembly': $i).
% 29.22/29.02  tff(decl_33552, type, 'Electron-Transport-Chain': $i).
% 29.22/29.02  tff(decl_33553, type, 'A series of membrane proteins that couples electron transfer from a donor molecule (such as NADH) to a acceptor molecule (such as O2) with the transfer of protons across a membrane.  Electron transport chains are used to capture the energy from sunlight in photosynthesis, and from redox reactions such as cellular respiration.': $i).
% 29.22/29.02  tff(decl_33554, type, 'group of transport molecules at thylakoid membrane of chloroplast': $i).
% 29.22/29.02  tff(decl_33555, type, 'respiratory chain': $i).
% 29.22/29.02  tff(decl_33556, type, 'respiratory-chain': $i).
% 29.22/29.02  tff(decl_33557, type, 'electron transport chain': $i).
% 29.22/29.02  tff(decl_33558, type, 'electron-transport-chain': $i).
% 29.22/29.02  tff(decl_33559, type, fn_electron_transport_chain_6: $i > $i).
% 29.22/29.02  tff(decl_33560, type, fn_electron_transport_chain_7: $i > $i).
% 29.22/29.02  tff(decl_33561, type, fn_electron_transport_chain_8: $i > $i).
% 29.22/29.02  tff(decl_33562, type, fn_electron_transport_chain_9: $i > $i).
% 29.22/29.02  tff(decl_33563, type, protein_complex_0: $i).
% 29.22/29.02  tff(decl_33564, type, 'Electron-Transport-Chain-Pathway': $i).
% 29.22/29.02  tff(decl_33565, type, 'The process in which energy is released from electron carriers in a stepwise manner through a series of redox reactions along an electron transport chain. The released energy is used to pump protons across a membrane, resulting in a proton motive force which can perform cellular work.': $i).
% 29.22/29.02  tff(decl_33566, type, 'electron transport chain pathway': $i).
% 29.22/29.02  tff(decl_33567, type, 'electron-transport-chain-pathway': $i).
% 29.22/29.02  tff(decl_33568, type, fn_electron_transport_chain_pathway_1: $i > $i).
% 29.22/29.02  tff(decl_33569, type, fn_electron_transport_chain_pathway_4: $i > $i).
% 29.22/29.02  tff(decl_33570, type, fn_electron_transport_chain_pathway_5: $i > $i).
% 29.22/29.02  tff(decl_33571, type, fn_electron_transport_chain_pathway_6: $i > $i).
% 29.22/29.02  tff(decl_33572, type, fn_electron_transport_chain_pathway_7: $i > $i).
% 29.22/29.02  tff(decl_33573, type, fn_electron_transport_chain_pathway_8: $i > $i).
% 29.22/29.02  tff(decl_33574, type, fn_electron_transport_chain_pathway_9: $i > $i).
% 29.22/29.02  tff(decl_33575, type, fn_electron_transport_chain_pathway_10: $i > $i).
% 29.22/29.02  tff(decl_33576, type, fn_electron_transport_chain_pathway_11: $i > $i).
% 29.22/29.02  tff(decl_33577, type, fn_electron_transport_chain_pathway_13: $i > $i).
% 29.22/29.02  tff(decl_33578, type, fn_electron_transport_chain_pathway_14: $i > $i).
% 29.22/29.02  tff(decl_33579, type, fn_electron_transport_chain_pathway_19: $i > $i).
% 29.22/29.02  tff(decl_33580, type, fn_electron_transport_chain_pathway_23: $i > $i).
% 29.22/29.02  tff(decl_33581, type, fn_electron_transport_chain_pathway_25: $i > $i).
% 29.22/29.02  tff(decl_33582, type, fn_electron_transport_chain_pathway_28: $i > $i).
% 29.22/29.02  tff(decl_33583, type, fn_electron_transport_chain_pathway_29: $i > $i).
% 29.22/29.02  tff(decl_33584, type, fn_electron_transport_chain_pathway_30: $i > $i).
% 29.22/29.02  tff(decl_33585, type, fn_electron_transport_chain_pathway_31: $i > $i).
% 29.22/29.02  tff(decl_33586, type, fn_electron_transport_chain_pathway_32: $i > $i).
% 29.22/29.02  tff(decl_33587, type, fn_electron_transport_chain_pathway_33: $i > $i).
% 29.22/29.02  tff(decl_33588, type, fn_electron_transport_chain_pathway_34: $i > $i).
% 29.22/29.02  tff(decl_33589, type, fn_electron_transport_chain_pathway_35: $i > $i).
% 29.22/29.02  tff(decl_33590, type, fn_electron_transport_chain_pathway_36: $i > $i).
% 29.22/29.02  tff(decl_33591, type, fn_electron_transport_chain_pathway_37: $i > $i).
% 29.22/29.02  tff(decl_33592, type, fn_electron_transport_chain_pathway_38: $i > $i).
% 29.22/29.02  tff(decl_33593, type, fn_electron_transport_chain_pathway_39: $i > $i).
% 29.22/29.02  tff(decl_33594, type, fn_electron_transport_chain_pathway_40: $i > $i).
% 29.22/29.02  tff(decl_33595, type, fn_electron_transport_chain_pathway_42: $i > $i).
% 29.22/29.02  tff(decl_33596, type, fn_electron_transport_chain_pathway_44: $i > $i).
% 29.22/29.02  tff(decl_33597, type, fn_electron_transport_chain_reaction_5: $i > $i).
% 29.22/29.02  tff(decl_33598, type, 'FADH2': $i).
% 29.22/29.02  tff(decl_33599, type, 'NADH': $i).
% 29.22/29.02  tff(decl_33600, type, fn_electron_transport_chain_pathway_3: $i > $i).
% 29.22/29.02  tff(decl_33601, type, fn_electron_transport_chain_pathway_2: $i > $i).
% 29.22/29.02  tff(decl_33602, type, fn_electron_transport_chain_pathway_18: $i > $i).
% 29.22/29.02  tff(decl_33603, type, fn_electron_transport_chain_pathway_17: $i > $i).
% 29.22/29.02  tff(decl_33604, type, fn_electron_transport_chain_pathway_15: $i > $i).
% 29.22/29.02  tff(decl_33605, type, fn_electron_transport_chain_pathway_16: $i > $i).
% 29.22/29.02  tff(decl_33606, type, 'Electron-Transport-Chain-Reaction': $i).
% 29.22/29.02  tff(decl_33607, type, 'An electron transport chain (ETC) couples a reaction between an electron donor (such as NADH) and an electron acceptor (such as O2) to the transfer of H+ ions across a membrane, through a set of mediating biochemical reactions. These H+ ions are used to produce adenosine triphosphate (ATP), the main energy intermediate in living organisms, as they move back across the membrane. Electron transport chains are used for extracting energy from sunlight (photosynthesis) and from redox reactions such as the oxidation of sugars (respiration).': $i).
% 29.22/29.02  tff(decl_33608, type, 'etc reaction': $i).
% 29.22/29.02  tff(decl_33609, type, 'etc-reaction': $i).
% 29.22/29.02  tff(decl_33610, type, 'electron transport chain reaction': $i).
% 29.22/29.02  tff(decl_33611, type, 'electron-transport-chain-reaction': $i).
% 29.22/29.02  tff(decl_33612, type, fn_electron_transport_chain_reaction_2: $i > $i).
% 29.22/29.02  tff(decl_33613, type, fn_electron_transport_chain_reaction_3: $i > $i).
% 29.22/29.02  tff(decl_33614, type, fn_electron_transport_chain_reaction_10: $i > $i).
% 29.22/29.02  tff(decl_33615, type, fn_electron_transport_chain_reaction_17: $i > $i).
% 29.22/29.02  tff(decl_33616, type, redox_reaction_0: $i).
% 29.22/29.02  tff(decl_33617, type, fn_electron_transport_chain_reaction_19: $i > $i).
% 29.22/29.02  tff(decl_33618, type, electron_transport_chain_reaction_in_prokaryote_1: $i > $o).
% 29.22/29.02  tff(decl_33619, type, 'Electron-Transport-Chain-Reaction-In-Prokaryote': $i).
% 29.22/29.02  tff(decl_33620, type, 'An electron transport chain (ETC) couples a reaction between an electron donor (such as NADH) and an electron acceptor (such as O2) to the transfer of H+ ions across the plasma membrane of a prokaryote, through a set of mediating biochemical reactions. These H+ ions are used to produce adenosine triphosphate (ATP), the main energy intermediate in living organisms, as they move back across the plasma membrane of the prokaryote. Electron transport chains are used for extracting energy from sunlight (photosynthesis) and from redox reactions such as the oxidation of sugars (respiration).': $i).
% 29.22/29.02  tff(decl_33621, type, 'electron transport chain reaction in prokaryote': $i).
% 29.22/29.02  tff(decl_33622, type, 'electron-transport-chain-reaction-in-prokaryote': $i).
% 29.22/29.02  tff(decl_33623, type, fn_electron_transport_chain_reaction_in_prokaryote_1: $i > $i).
% 29.22/29.02  tff(decl_33624, type, fn_electron_transport_chain_reaction_in_prokaryote_2: $i > $i).
% 29.22/29.02  tff(decl_33625, type, fn_electron_transport_chain_reaction_in_prokaryote_3: $i > $i).
% 29.22/29.02  tff(decl_33626, type, fn_electron_transport_chain_reaction_in_prokaryote_4: $i > $i).
% 29.22/29.02  tff(decl_33627, type, fn_electron_transport_chain_reaction_in_prokaryote_5: $i > $i).
% 29.22/29.02  tff(decl_33628, type, fn_electron_transport_chain_reaction_in_prokaryote_6: $i > $i).
% 29.22/29.02  tff(decl_33629, type, fn_electron_transport_chain_reaction_in_prokaryote_7: $i > $i).
% 29.22/29.02  tff(decl_33630, type, fn_electron_transport_chain_reaction_in_prokaryote_8: $i > $i).
% 29.22/29.02  tff(decl_33631, type, fn_electron_transport_chain_reaction_in_prokaryote_9: $i > $i).
% 29.22/29.02  tff(decl_33632, type, fn_electron_transport_chain_reaction_in_prokaryote_10: $i > $i).
% 29.22/29.02  tff(decl_33633, type, fn_electron_transport_chain_reaction_in_prokaryote_11: $i > $i).
% 29.22/29.02  tff(decl_33634, type, fn_electron_transport_chain_reaction_in_prokaryote_12: $i > $i).
% 29.22/29.02  tff(decl_33635, type, fn_electron_transport_chain_reaction_in_prokaryote_13: $i > $i).
% 29.22/29.02  tff(decl_33636, type, fn_electron_transport_chain_reaction_in_prokaryote_14: $i > $i).
% 29.22/29.02  tff(decl_33637, type, fn_electron_transport_chain_reaction_in_prokaryote_15: $i > $i).
% 29.22/29.02  tff(decl_33638, type, fn_electron_transport_chain_reaction_in_prokaryote_16: $i > $i).
% 29.22/29.02  tff(decl_33639, type, fn_electron_transport_chain_reaction_in_prokaryote_17: $i > $i).
% 29.22/29.02  tff(decl_33640, type, fn_electron_transport_chain_reaction_in_prokaryote_18: $i > $i).
% 29.22/29.02  tff(decl_33641, type, fn_electron_transport_chain_reaction_in_prokaryote_19: $i > $i).
% 29.22/29.02  tff(decl_33642, type, fn_electron_transport_chain_reaction_in_prokaryote_20: $i > $i).
% 29.22/29.02  tff(decl_33643, type, fn_electron_transport_chain_reaction_in_prokaryote_21: $i > $i).
% 29.22/29.02  tff(decl_33644, type, fn_electron_transport_chain_reaction_in_prokaryote_22: $i > $i).
% 29.22/29.02  tff(decl_33645, type, fn_electron_transport_chain_reaction_in_prokaryote_25: $i > $i).
% 29.22/29.02  tff(decl_33646, type, fn_electron_transport_chain_reaction_in_prokaryote_26: $i > $i).
% 29.22/29.02  tff(decl_33647, type, fn_electron_transport_chain_reaction_in_prokaryote_27: $i > $i).
% 29.22/29.02  tff(decl_33648, type, fn_electron_transport_chain_reaction_in_prokaryote_28: $i > $i).
% 29.22/29.02  tff(decl_33649, type, fn_electron_transport_chain_reaction_in_prokaryote_29: $i > $i).
% 29.22/29.02  tff(decl_33650, type, fn_electron_transport_chain_reaction_in_prokaryote_30: $i > $i).
% 29.22/29.02  tff(decl_33651, type, fn_electron_transport_chain_reaction_in_prokaryote_31: $i > $i).
% 29.22/29.02  tff(decl_33652, type, fn_electron_transport_chain_reaction_in_prokaryote_32: $i > $i).
% 29.22/29.02  tff(decl_33653, type, fn_electron_transport_chain_reaction_in_prokaryote_24: $i > $i).
% 29.22/29.02  tff(decl_33654, type, fn_electron_transport_chain_reaction_in_prokaryote_23: $i > $i).
% 29.22/29.02  tff(decl_33655, type, 'Electronegative-Element': $i).
% 29.22/29.02  tff(decl_33656, type, 'A pure chemical substance composed of entirely one kind of atom with the power to attract electrons to themselves.': $i).
% 29.22/29.02  tff(decl_33657, type, 'electronegative element': $i).
% 29.22/29.02  tff(decl_33658, type, 'electronegative-element': $i).
% 29.22/29.02  tff(decl_33659, type, 'Electronegativity-Constant': $i).
% 29.22/29.02  tff(decl_33660, type, 'constant of electronegativity': $i).
% 29.22/29.02  tff(decl_33661, type, 'electronegativity constant': $i).
% 29.22/29.02  tff(decl_33662, type, 'electronegativity-constant': $i).
% 29.22/29.02  tff(decl_33663, type, electronegativity_scale_1: $i > $o).
% 29.22/29.02  tff(decl_33664, type, 'Electronegativity-Scale': $i).
% 29.22/29.02  tff(decl_33665, type, 'scale of electronegativity': $i).
% 29.22/29.02  tff(decl_33666, type, 'electronegativity scale': $i).
% 29.22/29.02  tff(decl_33667, type, 'electronegativity-scale': $i).
% 29.22/29.02  tff(decl_33668, type, 'Electronegativity-Value': $i).
% 29.22/29.02  tff(decl_33669, type, 'A measurement of how much an atom tends to steal electrons from atoms that it\\s bonded to. Elements at the top right of the periodic table (excluding the noble gases) are very electronegative while atoms in the bottom left are not very electronegative (aka electropositive).': $i).
% 29.22/29.02  tff(decl_33670, type, electronegativity: $i).
% 29.22/29.02  tff(decl_33671, type, 'value of electronegativity': $i).
% 29.22/29.02  tff(decl_33672, type, 'electronegativity value': $i).
% 29.22/29.02  tff(decl_33673, type, 'electronegativity-value': $i).
% 29.22/29.02  tff(decl_33674, type, electroporation_1: $i > $o).
% 29.22/29.02  tff(decl_33675, type, 'Electroporation': $i).
% 29.22/29.02  tff(decl_33676, type, 'A technique to introduce recombinant DNA into cells by applying a brief electrical pulse to a solution containing the cells. The pulse creates temporary holes in the cells plasma membranes, through which DNA can enter.': $i).
% 29.22/29.02  tff(decl_33677, type, 'perform electroporation': $i).
% 29.22/29.02  tff(decl_33678, type, electroporation: $i).
% 29.22/29.02  tff(decl_33679, type, 'Elephant': $i).
% 29.22/29.02  tff(decl_33680, type, 'Large land mammals of the order Proboscidea, including African bush elephants, African forest elephants, and Asian elephants.': $i).
% 29.22/29.02  tff(decl_33681, type, elephant: $i).
% 29.22/29.02  tff(decl_33682, type, fn_elephant_1: $i > $i).
% 29.22/29.02  tff(decl_33683, type, fn_elephant_2: $i > $i).
% 29.22/29.02  tff(decl_33684, type, 'Elevator': $i).
% 29.22/29.02  tff(decl_33685, type, elevator: $i).
% 29.22/29.02  tff(decl_33686, type, lift: $i).
% 29.22/29.02  tff(decl_33687, type, 'Elicitor': $i).
% 29.22/29.02  tff(decl_33688, type, 'In plants, a molecule that induces the production of other compounds.': $i).
% 29.22/29.02  tff(decl_33689, type, 'Elimination': $i).
% 29.22/29.02  tff(decl_33690, type, 'The final stage of food processing in animals, in which undigested material is passed out of th digestive system.': $i).
% 29.22/29.02  tff(decl_33691, type, eliminate: $i).
% 29.22/29.02  tff(decl_33692, type, elimination: $i).
% 29.22/29.02  tff(decl_33693, type, 'Elongation': $i).
% 29.22/29.02  tff(decl_33694, type, 'The phase of polypeptide synthesis in which amino acids are added one at a time. There are three steps to elongation:  codon recognition, formation of the new peptide bond, and translocation of the ribosome along the mRNA transcript.': $i).
% 29.22/29.02  tff(decl_33695, type, elongation: $i).
% 29.22/29.02  tff(decl_33696, type, 'Elongation-Factor': $i).
% 29.22/29.02  tff(decl_33697, type, 'Elongation factors are proteins involved at various events of the elongation phase of the translation process (Synthesis of polypeptide)': $i).
% 29.22/29.02  tff(decl_33698, type, 'elongation factor': $i).
% 29.22/29.02  tff(decl_33699, type, 'elongation-factor': $i).
% 29.22/29.02  tff(decl_33700, type, ef: $i).
% 29.22/29.02  tff(decl_33701, type, 'factor of elongation': $i).
% 29.22/29.02  tff(decl_33702, type, fn_elongation_factor_1: $i > $i).
% 29.22/29.02  tff(decl_33703, type, embody_1: $i > $o).
% 29.22/29.02  tff(decl_33704, type, 'Embody': $i).
% 29.22/29.02  tff(decl_33705, type, embody: $i).
% 29.22/29.02  tff(decl_33706, type, fn_embody_1: $i > $i).
% 29.22/29.02  tff(decl_33707, type, fn_embody_2: $i > $i).
% 29.22/29.02  tff(decl_33708, type, embolus_1: $i > $o).
% 29.22/29.02  tff(decl_33709, type, 'Embolus': $i).
% 29.22/29.02  tff(decl_33710, type, 'Any detached mass (solid, liquid, or gaseous) carried by circulation, which is capable of clogging arterial capillary beds.': $i).
% 29.22/29.02  tff(decl_33711, type, embolus: $i).
% 29.22/29.02  tff(decl_33712, type, 'Embryo': $i).
% 29.22/29.02  tff(decl_33713, type, 'A multicellular diploid eukaryote in its earliest stage of development, from the time of first cell division until birth, hatching, or germination. In humans, it is called an embryo until about eight weeks after fertilization, and from then it is instead called a fetus.': $i).
% 29.22/29.02  tff(decl_33714, type, embryo: $i).
% 29.22/29.02  tff(decl_33715, type, embryo_sac_1: $i > $o).
% 29.22/29.02  tff(decl_33716, type, 'Embryo-Sac': $i).
% 29.22/29.02  tff(decl_33717, type, 'In angiosperms, the megagametophyte of female plants, which produces one or several egg cells, depending on species.': $i).
% 29.22/29.02  tff(decl_33718, type, 'sac of embryo': $i).
% 29.22/29.02  tff(decl_33719, type, 'embryo sac': $i).
% 29.22/29.02  tff(decl_33720, type, 'embryo-sac': $i).
% 29.22/29.02  tff(decl_33721, type, 'Embryogenesis': $i).
% 29.22/29.02  tff(decl_33722, type, 'Embryogenesis is the process by which the embryo is formed and develops, until it develops into a fetus.': $i).
% 29.22/29.02  tff(decl_33723, type, 'embryonic development': $i).
% 29.22/29.02  tff(decl_33724, type, 'embryonic-development': $i).
% 29.22/29.02  tff(decl_33725, type, 'embryonic stage': $i).
% 29.22/29.02  tff(decl_33726, type, 'embryonic-stage': $i).
% 29.22/29.02  tff(decl_33727, type, 'embryo stage': $i).
% 29.22/29.02  tff(decl_33728, type, 'embryogenic development': $i).
% 29.22/29.02  tff(decl_33729, type, 'embryogenic-development': $i).
% 29.22/29.02  tff(decl_33730, type, 'embryogenic stage': $i).
% 29.22/29.02  tff(decl_33731, type, 'embryogenic-stage': $i).
% 29.22/29.02  tff(decl_33732, type, 'embryo-stage': $i).
% 29.22/29.02  tff(decl_33733, type, 'embryonic period': $i).
% 29.22/29.02  tff(decl_33734, type, 'embryonic-period': $i).
% 29.22/29.02  tff(decl_33735, type, 'embryonic phase': $i).
% 29.22/29.02  tff(decl_33736, type, 'embryonic-phase': $i).
% 29.22/29.02  tff(decl_33737, type, 'undergo embryogenesis': $i).
% 29.22/29.02  tff(decl_33738, type, embryogenesis: $i).
% 29.22/29.02  tff(decl_33739, type, fn_embryogenesis_2: $i > $i).
% 29.22/29.02  tff(decl_33740, type, fn_embryogenesis_3: $i > $i).
% 29.22/29.02  tff(decl_33741, type, fn_embryogenesis_4: $i > $i).
% 29.22/29.02  tff(decl_33742, type, fn_embryogenesis_5: $i > $i).
% 29.22/29.02  tff(decl_33743, type, organ_development_1: $i > $o).
% 29.22/29.02  tff(decl_33744, type, fn_embryogenesis_6: $i > $i).
% 29.22/29.02  tff(decl_33745, type, fn_embryogenesis_7: $i > $i).
% 29.22/29.02  tff(decl_33746, type, fn_embryogenesis_9: $i > $i).
% 29.22/29.02  tff(decl_33747, type, fn_embryogenesis_10: $i > $i).
% 29.22/29.02  tff(decl_33748, type, fn_embryogenesis_11: $i > $i).
% 29.22/29.02  tff(decl_33749, type, fn_embryogenesis_12: $i > $i).
% 29.22/29.02  tff(decl_33750, type, fn_embryogenesis_13: $i > $i).
% 29.22/29.02  tff(decl_33751, type, fn_embryogenesis_14: $i > $i).
% 29.22/29.02  tff(decl_33752, type, fn_embryogenesis_15: $i > $i).
% 29.22/29.02  tff(decl_33753, type, fn_embryogenesis_17: $i > $i).
% 29.22/29.02  tff(decl_33754, type, fn_embryogenesis_18: $i > $i).
% 29.22/29.02  tff(decl_33755, type, fn_embryogenesis_19: $i > $i).
% 29.22/29.02  tff(decl_33756, type, fn_embryogenesis_21: $i > $i).
% 29.22/29.02  tff(decl_33757, type, fn_embryogenesis_22: $i > $i).
% 29.22/29.02  tff(decl_33758, type, fn_embryogenesis_23: $i > $i).
% 29.22/29.02  tff(decl_33759, type, fn_embryogenesis_24: $i > $i).
% 29.22/29.02  tff(decl_33760, type, fn_embryogenesis_26: $i > $i).
% 29.22/29.02  tff(decl_33761, type, fn_embryogenesis_27: $i > $i).
% 29.22/29.02  tff(decl_33762, type, fn_embryogenesis_28: $i > $i).
% 29.22/29.02  tff(decl_33763, type, fn_embryogenesis_31: $i > $i).
% 29.22/29.02  tff(decl_33764, type, fn_embryogenesis_32: $i > $i).
% 29.22/29.02  tff(decl_33765, type, fn_embryogenesis_34: $i > $i).
% 29.22/29.02  tff(decl_33766, type, fn_embryogenesis_35: $i > $i).
% 29.22/29.02  tff(decl_33767, type, fn_embryogenesis_36: $i > $i).
% 29.22/29.02  tff(decl_33768, type, fn_embryogenesis_37: $i > $i).
% 29.22/29.02  tff(decl_33769, type, fn_embryogenesis_38: $i > $i).
% 29.22/29.02  tff(decl_33770, type, fn_embryogenesis_39: $i > $i).
% 29.22/29.02  tff(decl_33771, type, fn_embryogenesis_40: $i > $i).
% 29.22/29.02  tff(decl_33772, type, fn_embryogenesis_42: $i > $i).
% 29.22/29.02  tff(decl_33773, type, fn_embryogenesis_44: $i > $i).
% 29.22/29.02  tff(decl_33774, type, fn_embryogenesis_45: $i > $i).
% 29.22/29.02  tff(decl_33775, type, fn_embryogenesis_46: $i > $i).
% 29.22/29.02  tff(decl_33776, type, fn_embryogenesis_47: $i > $i).
% 29.22/29.02  tff(decl_33777, type, fn_embryogenesis_48: $i > $i).
% 29.22/29.02  tff(decl_33778, type, fn_embryogenesis_49: $i > $i).
% 29.22/29.02  tff(decl_33779, type, fn_embryogenesis_50: $i > $i).
% 29.22/29.02  tff(decl_33780, type, fn_embryogenesis_53: $i > $i).
% 29.22/29.02  tff(decl_33781, type, fn_embryogenesis_54: $i > $i).
% 29.22/29.02  tff(decl_33782, type, fn_embryogenesis_55: $i > $i).
% 29.22/29.02  tff(decl_33783, type, m_phase_1: $i > $o).
% 29.22/29.02  tff(decl_33784, type, fn_embryogenesis_56: $i > $i).
% 29.22/29.02  tff(decl_33785, type, fn_embryogenesis_57: $i > $i).
% 29.22/29.02  tff(decl_33786, type, fn_embryogenesis_58: $i > $i).
% 29.22/29.02  tff(decl_33787, type, fn_m_phase_20: $i > $i).
% 29.22/29.02  tff(decl_33788, type, fn_morphogenesis_4: $i > $i).
% 29.22/29.02  tff(decl_33789, type, fn_embryonic_induction_9: $i > $i).
% 29.22/29.02  tff(decl_33790, type, fn_two_cell_stage_1: $i > $i).
% 29.22/29.02  tff(decl_33791, type, 'Cell Differentiation 1': $i).
% 29.22/29.02  tff(decl_33792, type, 'Cytoplasmic determinant 2': $i).
% 29.22/29.02  tff(decl_33793, type, 'Cytoplasmic Determinant 1': $i).
% 29.22/29.02  tff(decl_33794, type, 'Cell Division 2': $i).
% 29.22/29.02  tff(decl_33795, type, 'Cell Division 1': $i).
% 29.22/29.02  tff(decl_33796, type, 'Cell Differentiation 2': $i).
% 29.22/29.02  tff(decl_33797, type, 'Cell Differentiation 3': $i).
% 29.22/29.02  tff(decl_33798, type, 'Cell Differentiation 4': $i).
% 29.22/29.02  tff(decl_33799, type, biological_process_0: $i).
% 29.22/29.02  tff(decl_33800, type, 'Embryoid': $i).
% 29.22/29.02  tff(decl_33801, type, 'A mass of plant or animal tissue that resembles an embryo is called as embryoid.': $i).
% 29.22/29.02  tff(decl_33802, type, embryoid: $i).
% 29.22/29.02  tff(decl_33803, type, fn_embryoid_1: $i > $i).
% 29.22/29.02  tff(decl_33804, type, embryology_1: $i > $o).
% 29.22/29.02  tff(decl_33805, type, 'Embryology': $i).
% 29.22/29.02  tff(decl_33806, type, 'The study of the early growth and development of animals, from the fertilization of the egg to the larval or fetus stage.': $i).
% 29.22/29.02  tff(decl_33807, type, embryology: $i).
% 29.22/29.02  tff(decl_33808, type, embryonic_brain_region_1: $i > $o).
% 29.22/29.02  tff(decl_33809, type, 'Embryonic-Brain-Region': $i).
% 29.22/29.02  tff(decl_33810, type, 'Bulges in the neural tube in the developing embryo that will develop into the four regions of the adult brain.': $i).
% 29.22/29.02  tff(decl_33811, type, 'embryonic brain region': $i).
% 29.22/29.02  tff(decl_33812, type, 'embryonic-brain-region': $i).
% 29.22/29.02  tff(decl_33813, type, 'Embryonic-Cell': $i).
% 29.22/29.02  tff(decl_33814, type, 'The cell of an embryo.': $i).
% 29.22/29.02  tff(decl_33815, type, 'embryonic cell': $i).
% 29.22/29.02  tff(decl_33816, type, 'embryonic-cell': $i).
% 29.22/29.02  tff(decl_33817, type, 'Embryonic-Gonad': $i).
% 29.22/29.02  tff(decl_33818, type, 'In animals, germ-line progenitors associate with gonadal somatic cells to form the embryonic gonads.': $i).
% 29.22/29.02  tff(decl_33819, type, 'embryonic gonad': $i).
% 29.22/29.02  tff(decl_33820, type, 'embryonic-gonad': $i).
% 29.22/29.02  tff(decl_33821, type, 'Embryonic-Induction': $i).
% 29.22/29.02  tff(decl_33822, type, 'The influence of one cell group (inducer) over a neighboring cell group (induced) during.': $i).
% 29.22/29.02  tff(decl_33823, type, 'embryonic induction': $i).
% 29.22/29.02  tff(decl_33824, type, 'embryonic-induction': $i).
% 29.22/29.02  tff(decl_33825, type, fn_embryonic_induction_1: $i > $i).
% 29.22/29.02  tff(decl_33826, type, fn_embryonic_induction_2: $i > $i).
% 29.22/29.02  tff(decl_33827, type, fn_embryonic_induction_3: $i > $i).
% 29.22/29.02  tff(decl_33828, type, fn_embryonic_induction_4: $i > $i).
% 29.22/29.02  tff(decl_33829, type, fn_embryonic_induction_5: $i > $i).
% 29.22/29.02  tff(decl_33830, type, fn_embryonic_induction_6: $i > $i).
% 29.22/29.02  tff(decl_33831, type, fn_embryonic_induction_7: $i > $i).
% 29.22/29.02  tff(decl_33832, type, fn_embryonic_induction_8: $i > $i).
% 29.22/29.02  tff(decl_33833, type, fn_embryonic_induction_10: $i > $i).
% 29.22/29.02  tff(decl_33834, type, fn_embryonic_induction_11: $i > $i).
% 29.22/29.02  tff(decl_33835, type, fn_embryonic_induction_12: $i > $i).
% 29.22/29.02  tff(decl_33836, type, embryonic_lethal_1: $i > $o).
% 29.22/29.02  tff(decl_33837, type, 'Embryonic-Lethal': $i).
% 29.22/29.02  tff(decl_33838, type, 'A mutation whose phenotype results in the death of an embryo or larva.': $i).
% 29.22/29.02  tff(decl_33839, type, 'embryonic lethal': $i).
% 29.22/29.02  tff(decl_33840, type, 'embryonic-lethal': $i).
% 29.22/29.02  tff(decl_33841, type, fn_embryonic_lethal_1: $i > $i).
% 29.22/29.02  tff(decl_33842, type, embryonic_morphogenesis_1: $i > $o).
% 29.22/29.02  tff(decl_33843, type, 'Embryonic-Morphogenesis': $i).
% 29.22/29.02  tff(decl_33844, type, 'Embryonic morphogenesis is the biological process that causes an embryo to develop its shape. It is one of three fundamental aspects of developmental biology along with the control of cell growth and cellular differentiation.': $i).
% 29.22/29.02  tff(decl_33845, type, 'embryonic morphogenesis': $i).
% 29.22/29.02  tff(decl_33846, type, 'embryonic-morphogenesis': $i).
% 29.22/29.02  tff(decl_33847, type, fn_embryonic_morphogenesis_1: $i > $i).
% 29.22/29.02  tff(decl_33848, type, embryonic_morphogenesis_in_animal_1: $i > $o).
% 29.22/29.02  tff(decl_33849, type, 'Embryonic-Morphogenesis-In-Animal': $i).
% 29.22/29.02  tff(decl_33850, type, 'Embryonic morphogenesis in animal is the biological process that causes an animal embryo to develop its shape. It is one of three fundamental aspects of developmental biology along with the control of cell growth and cellular differentiation.': $i).
% 29.22/29.02  tff(decl_33851, type, 'embryonic morphogenesis in animal': $i).
% 29.22/29.02  tff(decl_33852, type, 'embryonic-morphogenesis-in-animal': $i).
% 29.22/29.02  tff(decl_33853, type, fn_embryonic_morphogenesis_in_animal_1: $i > $i).
% 29.22/29.02  tff(decl_33854, type, morphogenetic_movement_1: $i > $o).
% 29.22/29.02  tff(decl_33855, type, fn_embryonic_morphogenesis_in_animal_2: $i > $i).
% 29.22/29.02  tff(decl_33856, type, fn_embryonic_morphogenesis_in_animal_3: $i > $i).
% 29.22/29.02  tff(decl_33857, type, 'Embryonic-Process': $i).
% 29.22/29.02  tff(decl_33858, type, 'Process related to the development of the embryo stage.': $i).
% 29.22/29.02  tff(decl_33859, type, 'embryonic process': $i).
% 29.22/29.02  tff(decl_33860, type, 'embryonic-process': $i).
% 29.22/29.02  tff(decl_33861, type, 'Embryonic-Region': $i).
% 29.22/29.02  tff(decl_33862, type, 'The region of an embryo is called as embryonic region.': $i).
% 29.22/29.02  tff(decl_33863, type, 'embryonic region': $i).
% 29.22/29.02  tff(decl_33864, type, 'embryonic-region': $i).
% 29.22/29.02  tff(decl_33865, type, 'Embryonic-Stages': $i).
% 29.22/29.02  tff(decl_33866, type, 'Stages of a developing animal embryo.': $i).
% 29.22/29.02  tff(decl_33867, type, 'stages of embryo development': $i).
% 29.22/29.02  tff(decl_33868, type, 'stages-of-embryo-development': $i).
% 29.22/29.02  tff(decl_33869, type, 'Embryonic-Stem-Cell': $i).
% 29.22/29.02  tff(decl_33870, type, 'The stem cells of the embryo of an organism is called embryonic stem cell.': $i).
% 29.22/29.02  tff(decl_33871, type, 'embryonic stem cell': $i).
% 29.22/29.02  tff(decl_33872, type, 'embryonic-stem-cell': $i).
% 29.22/29.02  tff(decl_33873, type, fn_embryonic_stem_cell_1: $i > $i).
% 29.22/29.02  tff(decl_33874, type, fn_embryonic_stem_cell_2: $i > $i).
% 29.22/29.02  tff(decl_33875, type, fn_embryonic_stem_cell_3: $i > $i).
% 29.22/29.02  tff(decl_33876, type, fn_embryonic_stem_cell_4: $i > $i).
% 29.22/29.02  tff(decl_33877, type, fn_embryonic_stem_cell_5: $i > $i).
% 29.22/29.02  tff(decl_33878, type, fn_embryonic_stem_cell_6: $i > $i).
% 29.22/29.02  tff(decl_33879, type, fn_embryonic_stem_cell_7: $i > $i).
% 29.22/29.02  tff(decl_33880, type, fn_embryonic_stem_cell_8: $i > $i).
% 29.22/29.02  tff(decl_33881, type, fn_embryonic_stem_cell_9: $i > $i).
% 29.22/29.02  tff(decl_33882, type, fn_embryonic_stem_cell_12: $i > $i).
% 29.22/29.02  tff(decl_33883, type, fn_embryonic_stem_cell_13: $i > $i).
% 29.22/29.02  tff(decl_33884, type, fn_embryonic_stem_cell_14: $i > $i).
% 29.22/29.02  tff(decl_33885, type, fn_embryonic_stem_cell_15: $i > $i).
% 29.22/29.02  tff(decl_33886, type, fn_embryonic_stem_cell_16: $i > $i).
% 29.22/29.02  tff(decl_33887, type, fn_embryonic_stem_cell_17: $i > $i).
% 29.22/29.02  tff(decl_33888, type, fn_embryonic_stem_cell_18: $i > $i).
% 29.22/29.02  tff(decl_33889, type, fn_embryonic_stem_cell_19: $i > $i).
% 29.22/29.02  tff(decl_33890, type, fn_embryonic_stem_cell_20: $i > $i).
% 29.22/29.02  tff(decl_33891, type, fn_embryonic_stem_cell_21: $i > $i).
% 29.22/29.02  tff(decl_33892, type, fn_embryonic_stem_cell_22: $i > $i).
% 29.22/29.02  tff(decl_33893, type, fn_embryonic_stem_cell_23: $i > $i).
% 29.22/29.02  tff(decl_33894, type, fn_embryonic_stem_cell_24: $i > $i).
% 29.22/29.02  tff(decl_33895, type, fn_embryonic_stem_cell_25: $i > $i).
% 29.22/29.02  tff(decl_33896, type, fn_embryonic_stem_cell_26: $i > $i).
% 29.22/29.02  tff(decl_33897, type, fn_embryonic_stem_cell_27: $i > $i).
% 29.22/29.02  tff(decl_33898, type, fn_embryonic_stem_cell_28: $i > $i).
% 29.22/29.02  tff(decl_33899, type, fn_embryonic_stem_cell_29: $i > $i).
% 29.22/29.02  tff(decl_33900, type, fn_embryonic_stem_cell_30: $i > $i).
% 29.22/29.02  tff(decl_33901, type, fn_embryonic_stem_cell_31: $i > $i).
% 29.22/29.02  tff(decl_33902, type, fn_embryonic_stem_cell_32: $i > $i).
% 29.22/29.02  tff(decl_33903, type, fn_embryonic_stem_cell_33: $i > $i).
% 29.22/29.02  tff(decl_33904, type, fn_embryonic_stem_cell_34: $i > $i).
% 29.22/29.02  tff(decl_33905, type, fn_embryonic_stem_cell_35: $i > $i).
% 29.22/29.02  tff(decl_33906, type, fn_embryonic_stem_cell_36: $i > $i).
% 29.22/29.02  tff(decl_33907, type, fn_embryonic_stem_cell_37: $i > $i).
% 29.22/29.02  tff(decl_33908, type, fn_embryonic_stem_cell_38: $i > $i).
% 29.22/29.02  tff(decl_33909, type, fn_embryonic_stem_cell_39: $i > $i).
% 29.22/29.02  tff(decl_33910, type, fn_embryonic_stem_cell_40: $i > $i).
% 29.22/29.02  tff(decl_33911, type, fn_embryonic_stem_cell_42: $i > $i).
% 29.22/29.02  tff(decl_33912, type, fn_embryonic_stem_cell_43: $i > $i).
% 29.22/29.02  tff(decl_33913, type, fn_embryonic_stem_cell_44: $i > $i).
% 29.22/29.02  tff(decl_33914, type, fn_embryonic_stem_cell_45: $i > $i).
% 29.22/29.02  tff(decl_33915, type, fn_embryonic_stem_cell_46: $i > $i).
% 29.22/29.02  tff(decl_33916, type, fn_embryonic_stem_cell_47: $i > $i).
% 29.22/29.02  tff(decl_33917, type, fn_embryonic_stem_cell_11: $i > $i).
% 29.22/29.02  tff(decl_33918, type, fn_embryonic_stem_cell_10: $i > $i).
% 29.22/29.02  tff(decl_33919, type, fn_stem_cell_18: $i > $i).
% 29.22/29.02  tff(decl_33920, type, fn_stem_cell_20: $i > $i).
% 29.22/29.02  tff(decl_33921, type, fn_stem_cell_19: $i > $i).
% 29.22/29.02  tff(decl_33922, type, fn_stem_cell_5: $i > $i).
% 29.22/29.02  tff(decl_33923, type, 'Embryonic-Tissue': $i).
% 29.22/29.02  tff(decl_33924, type, 'The tissue in an embryo is called as embryonic tissue.': $i).
% 29.22/29.02  tff(decl_33925, type, 'embryonic tissue': $i).
% 29.22/29.02  tff(decl_33926, type, 'embryonic-tissue': $i).
% 29.22/29.02  tff(decl_33927, type, emergent_property_1: $i > $o).
% 29.22/29.02  tff(decl_33928, type, 'Emergent-Property': $i).
% 29.22/29.02  tff(decl_33929, type, 'A notably different property that arises with each step upward in the hierarchy of life, owing to the arrangement and interactions of parts as complexity increases.': $i).
% 29.22/29.02  tff(decl_33930, type, 'emergent property': $i).
% 29.22/29.02  tff(decl_33931, type, 'emergent-property': $i).
% 29.22/29.02  tff(decl_33932, type, emerging_virus_1: $i > $o).
% 29.22/29.02  tff(decl_33933, type, 'Emerging-Virus': $i).
% 29.22/29.02  tff(decl_33934, type, 'An emerging virus  is a term applied to a newly discovered virus.': $i).
% 29.22/29.02  tff(decl_33935, type, 'emerging virus': $i).
% 29.22/29.02  tff(decl_33936, type, 'emerging-virus': $i).
% 29.22/29.02  tff(decl_33937, type, fn_emerging_virus_1: $i > $i).
% 29.22/29.02  tff(decl_33938, type, fn_emerging_virus_2: $i > $i).
% 29.22/29.02  tff(decl_33939, type, fn_emerging_virus_3: $i > $i).
% 29.22/29.02  tff(decl_33940, type, fn_emerging_virus_4: $i > $i).
% 29.22/29.02  tff(decl_33941, type, fn_emerging_virus_5: $i > $i).
% 29.22/29.02  tff(decl_33942, type, fn_emerging_virus_6: $i > $i).
% 29.22/29.02  tff(decl_33943, type, fn_emerging_virus_7: $i > $i).
% 29.22/29.02  tff(decl_33944, type, fn_emerging_virus_8: $i > $i).
% 29.22/29.02  tff(decl_33945, type, fn_emerging_virus_9: $i > $i).
% 29.22/29.02  tff(decl_33946, type, fn_viral_infection_15: $i > $i).
% 29.22/29.02  tff(decl_33947, type, fn_virus_22: $i > $i).
% 29.22/29.02  tff(decl_33948, type, 'Emigration': $i).
% 29.22/29.02  tff(decl_33949, type, 'Migration out of a population.': $i).
% 29.22/29.02  tff(decl_33950, type, emigrate: $i).
% 29.22/29.02  tff(decl_33951, type, emigration: $i).
% 29.22/29.02  tff(decl_33952, type, emit_1: $i > $o).
% 29.22/29.02  tff(decl_33953, type, 'Emit': $i).
% 29.22/29.02  tff(decl_33954, type, emit: $i).
% 29.22/29.02  tff(decl_33955, type, 'give off': $i).
% 29.22/29.02  tff(decl_33956, type, give_off: $i).
% 29.22/29.02  tff(decl_33957, type, emotion_1: $i > $o).
% 29.22/29.02  tff(decl_33958, type, 'Emotion': $i).
% 29.22/29.02  tff(decl_33959, type, 'An affective state of consciousness such as joy, anger, fear, etc. distinguished from volitional and cognitive states of consciousness.': $i).
% 29.22/29.02  tff(decl_33960, type, emote: $i).
% 29.22/29.02  tff(decl_33961, type, emotion: $i).
% 29.22/29.02  tff(decl_33962, type, emulsification_1: $i > $o).
% 29.22/29.02  tff(decl_33963, type, 'Emulsification': $i).
% 29.22/29.02  tff(decl_33964, type, 'The mixing of a lipid substance with an aqueous substance, in which the fat droplets are very small and prevented from coalescing into larger particles.': $i).
% 29.22/29.02  tff(decl_33965, type, emulsification: $i).
% 29.22/29.02  tff(decl_33966, type, 'Emulsifier': $i).
% 29.22/29.02  tff(decl_33967, type, 'A chemical which stabilizes a mixture of liquids and prevents their separation.': $i).
% 29.22/29.02  tff(decl_33968, type, emulsifier: $i).
% 29.22/29.02  tff(decl_33969, type, 'Encephalitis': $i).
% 29.22/29.02  tff(decl_33970, type, 'An acute inflammation of the brain.': $i).
% 29.22/29.02  tff(decl_33971, type, encephalitis: $i).
% 29.22/29.02  tff(decl_33972, type, 'End': $i).
% 29.22/29.02  tff(decl_33973, type, 'The either extremity of something that has length.': $i).
% 29.22/29.02  tff(decl_33974, type, end: $i).
% 29.22/29.02  tff(decl_33975, type, end_replication_problem_1: $i > $o).
% 29.22/29.02  tff(decl_33976, type, 'End-replication-problem': $i).
% 29.22/29.02  tff(decl_33977, type, 'The shortening of the DNA molecules with each round of DNA replication due to the gap that is left at the 5\\ end of each new strand because DNA polymerase can only add nucleotides to a 3\\ end.': $i).
% 29.22/29.02  tff(decl_33978, type, 'end replication problem': $i).
% 29.22/29.02  tff(decl_33979, type, 'end-replication-problem': $i).
% 29.22/29.02  tff(decl_33980, type, endangered_species_1: $i > $o).
% 29.22/29.02  tff(decl_33981, type, 'Endangered-Species': $i).
% 29.22/29.02  tff(decl_33982, type, 'A population facing a high risk of extinction due to low population numbers or changing environmental conditions.': $i).
% 29.22/29.02  tff(decl_33983, type, 'endangered species': $i).
% 29.22/29.02  tff(decl_33984, type, 'endangered-specy': $i).
% 29.22/29.02  tff(decl_33985, type, endemic_1: $i > $o).
% 29.22/29.02  tff(decl_33986, type, 'Endemic': $i).
% 29.22/29.02  tff(decl_33987, type, 'In ecology, refers to a species that occurs only in a specific, comparatively small geographic area.': $i).
% 29.22/29.02  tff(decl_33988, type, endemic: $i).
% 29.22/29.02  tff(decl_33989, type, 'Endergonic-Process': $i).
% 29.22/29.02  tff(decl_33990, type, 'A process in which free energy is absorbed from the surroundings': $i).
% 29.22/29.02  tff(decl_33991, type, 'non spontaneous process': $i).
% 29.22/29.02  tff(decl_33992, type, 'non-spontaneous-process': $i).
% 29.22/29.02  tff(decl_33993, type, 'endergonic process': $i).
% 29.22/29.02  tff(decl_33994, type, 'endergonic-process': $i).
% 29.22/29.02  tff(decl_33995, type, energy_related_process_1: $i > $o).
% 29.22/29.02  tff(decl_33996, type, fn_endergonic_process_1: $i > $i).
% 29.22/29.02  tff(decl_33997, type, exergonic_process_0: $i).
% 29.22/29.02  tff(decl_33998, type, energy_reaction_1: $i > $o).
% 29.22/29.02  tff(decl_33999, type, fn_endergonic_reaction_10: $i > $i).
% 29.22/29.02  tff(decl_34000, type, 'Endergonic-Reaction': $i).
% 29.22/29.02  tff(decl_34001, type, 'An endergonic reaction (also called an unfavorable reaction or a nonspontaneous reaction) is a chemical reaction in which the standard change in free energy is positive, and energy is absorbed': $i).
% 29.22/29.02  tff(decl_34002, type, 'non spontaneous reaction,': $i).
% 29.22/29.02  tff(decl_34003, type, 'non-spontaneous reaction,': $i).
% 29.22/29.02  tff(decl_34004, type, 'unfavorable reaction': $i).
% 29.22/29.02  tff(decl_34005, type, 'unfavorable-reaction': $i).
% 29.22/29.02  tff(decl_34006, type, 'nonspontaneous reaction': $i).
% 29.22/29.02  tff(decl_34007, type, 'nonspontaneous-reaction': $i).
% 29.22/29.02  tff(decl_34008, type, 'non spontaneous reaction': $i).
% 29.22/29.02  tff(decl_34009, type, 'non-spontaneous reaction': $i).
% 29.22/29.02  tff(decl_34010, type, 'endergonic reaction': $i).
% 29.22/29.02  tff(decl_34011, type, 'endergonic-reaction': $i).
% 29.22/29.02  tff(decl_34012, type, exergonic_reaction_0: $i).
% 29.22/29.02  tff(decl_34013, type, fn_endergonic_reaction_11: $i > $i).
% 29.22/29.02  tff(decl_34014, type, fn_endergonic_process_2: $i > $i).
% 29.22/29.02  tff(decl_34015, type, 'Endocrine-Cell': $i).
% 29.22/29.02  tff(decl_34016, type, 'Cells that regulate reproduction, development, energy metabolism, growth, and behavior via cell signaling by secreting hormones, a type of chemical messenger.': $i).
% 29.22/29.02  tff(decl_34017, type, 'cell of endocrine system': $i).
% 29.22/29.02  tff(decl_34018, type, 'cell-of-endocrine-system': $i).
% 29.22/29.02  tff(decl_34019, type, 'cell of endocrine': $i).
% 29.22/29.02  tff(decl_34020, type, 'endocrine cell': $i).
% 29.22/29.02  tff(decl_34021, type, 'endocrine-cell': $i).
% 29.22/29.02  tff(decl_34022, type, 'Endocrine-Gland': $i).
% 29.22/29.02  tff(decl_34023, type, 'A gland that secretes hormones directly into the blood rather than through a duct.': $i).
% 29.22/29.02  tff(decl_34024, type, 'gland of endocrine': $i).
% 29.22/29.02  tff(decl_34025, type, 'endocrine gland': $i).
% 29.22/29.02  tff(decl_34026, type, 'endocrine-gland': $i).
% 29.22/29.02  tff(decl_34027, type, endocrine_system_1: $i > $o).
% 29.22/29.02  tff(decl_34028, type, 'Endocrine-System': $i).
% 29.22/29.02  tff(decl_34029, type, 'The internal system of hormone-secreting ductless endocrine glands, hormones, and the molecular markers on target cells, that function together to achieve and maintain homeostasis.': $i).
% 29.22/29.02  tff(decl_34030, type, 'system of endocrine': $i).
% 29.22/29.02  tff(decl_34031, type, 'endocrine system': $i).
% 29.22/29.02  tff(decl_34032, type, 'endocrine-system': $i).
% 29.22/29.02  tff(decl_34033, type, 'Endocytosis': $i).
% 29.22/29.02  tff(decl_34034, type, 'Endocytosis is the process by which cells absorb molecules (such as proteins) by engulfing them. It is used by all cells of the body because most substances important to them are large polar molecules that cannot pass through the hydrophobic plasma or cell membrane.': $i).
% 29.22/29.02  tff(decl_34035, type, endocytosis: $i).
% 29.22/29.02  tff(decl_34036, type, fn_endocytosis_2: $i > $i).
% 29.22/29.02  tff(decl_34037, type, fn_endocytosis_3: $i > $i).
% 29.22/29.02  tff(decl_34038, type, fn_endocytosis_4: $i > $i).
% 29.22/29.02  tff(decl_34039, type, fn_endocytosis_5: $i > $i).
% 29.22/29.02  tff(decl_34040, type, fn_endocytosis_6: $i > $i).
% 29.22/29.02  tff(decl_34041, type, fn_endocytosis_7: $i > $i).
% 29.22/29.02  tff(decl_34042, type, fn_endocytosis_8: $i > $i).
% 29.22/29.02  tff(decl_34043, type, fn_endocytosis_9: $i > $i).
% 29.22/29.02  tff(decl_34044, type, fn_endocytosis_10: $i > $i).
% 29.22/29.02  tff(decl_34045, type, fn_endocytosis_12: $i > $i).
% 29.22/29.02  tff(decl_34046, type, fn_endocytosis_14: $i > $i).
% 29.22/29.02  tff(decl_34047, type, fn_endocytosis_15: $i > $i).
% 29.22/29.02  tff(decl_34048, type, fn_endocytosis_16: $i > $i).
% 29.22/29.02  tff(decl_34049, type, fn_endocytosis_17: $i > $i).
% 29.22/29.02  tff(decl_34050, type, fn_endocytosis_19: $i > $i).
% 29.22/29.02  tff(decl_34051, type, fn_endocytosis_20: $i > $i).
% 29.22/29.02  tff(decl_34052, type, fn_endocytosis_22: $i > $i).
% 29.22/29.02  tff(decl_34053, type, fn_endocytosis_23: $i > $i).
% 29.22/29.02  tff(decl_34054, type, fn_endocytosis_24: $i > $i).
% 29.22/29.02  tff(decl_34055, type, fn_endocytosis_26: $i > $i).
% 29.22/29.02  tff(decl_34056, type, fn_cell_3: $i > $i).
% 29.22/29.02  tff(decl_34057, type, fn_endocytosis_27: $i > $i).
% 29.22/29.02  tff(decl_34058, type, fn_endocytosis_11: $i > $i).
% 29.22/29.02  tff(decl_34059, type, 'Endoderm': $i).
% 29.22/29.02  tff(decl_34060, type, 'The innermost of three embryonic germ layers in animals, giving rise to the archenteron. In vertebrates, the endoderm also gives rise to the lining of the digestive tract and to the liver, lungs, and pancreas.': $i).
% 29.22/29.02  tff(decl_34061, type, endoderm: $i).
% 29.22/29.02  tff(decl_34062, type, 'Endodermal-Cell': $i).
% 29.22/29.02  tff(decl_34063, type, 'The single layer of plant cells that is located between the cortex and the vascular (xylem and phloem) tissues.': $i).
% 29.22/29.02  tff(decl_34064, type, 'endodermal cell': $i).
% 29.22/29.02  tff(decl_34065, type, 'endodermal-cell': $i).
% 29.22/29.02  tff(decl_34066, type, fn_endodermal_cell_1: $i > $i).
% 29.22/29.02  tff(decl_34067, type, fn_endodermal_cell_2: $i > $i).
% 29.22/29.02  tff(decl_34068, type, fn_endodermal_cell_3: $i > $i).
% 29.22/29.02  tff(decl_34069, type, fn_endodermal_cell_4: $i > $i).
% 29.22/29.02  tff(decl_34070, type, fn_endodermal_cell_5: $i > $i).
% 29.22/29.02  tff(decl_34071, type, fn_endodermal_cell_6: $i > $i).
% 29.22/29.02  tff(decl_34072, type, fn_endodermal_cell_7: $i > $i).
% 29.22/29.02  tff(decl_34073, type, fn_endodermal_cell_8: $i > $i).
% 29.22/29.02  tff(decl_34074, type, fn_endodermal_cell_9: $i > $i).
% 29.22/29.02  tff(decl_34075, type, fn_endodermal_cell_10: $i > $i).
% 29.22/29.02  tff(decl_34076, type, fn_endodermal_cell_11: $i > $i).
% 29.22/29.02  tff(decl_34077, type, fn_endodermal_cell_12: $i > $i).
% 29.22/29.02  tff(decl_34078, type, fn_endodermal_cell_13: $i > $i).
% 29.22/29.02  tff(decl_34079, type, fn_endodermal_cell_14: $i > $i).
% 29.22/29.02  tff(decl_34080, type, fn_endodermal_cell_15: $i > $i).
% 29.22/29.02  tff(decl_34081, type, fn_endodermal_cell_16: $i > $i).
% 29.22/29.02  tff(decl_34082, type, fn_endodermal_cell_17: $i > $i).
% 29.22/29.02  tff(decl_34083, type, fn_endodermal_cell_18: $i > $i).
% 29.22/29.02  tff(decl_34084, type, fn_endodermal_cell_19: $i > $i).
% 29.22/29.02  tff(decl_34085, type, fn_endodermal_cell_20: $i > $i).
% 29.22/29.02  tff(decl_34086, type, fn_endodermal_cell_21: $i > $i).
% 29.22/29.02  tff(decl_34087, type, fn_endodermal_cell_22: $i > $i).
% 29.22/29.02  tff(decl_34088, type, fn_endodermal_cell_23: $i > $i).
% 29.22/29.02  tff(decl_34089, type, fn_endodermal_cell_24: $i > $i).
% 29.22/29.02  tff(decl_34090, type, fn_endodermal_cell_25: $i > $i).
% 29.22/29.02  tff(decl_34091, type, fn_endodermal_cell_26: $i > $i).
% 29.22/29.02  tff(decl_34092, type, fn_endodermal_cell_27: $i > $i).
% 29.22/29.02  tff(decl_34093, type, fn_endodermal_cell_29: $i > $i).
% 29.22/29.02  tff(decl_34094, type, fn_endodermal_cell_30: $i > $i).
% 29.22/29.02  tff(decl_34095, type, fn_endodermal_cell_33: $i > $i).
% 29.22/29.02  tff(decl_34096, type, fn_endodermal_cell_34: $i > $i).
% 29.22/29.02  tff(decl_34097, type, fn_endodermal_cell_35: $i > $i).
% 29.22/29.02  tff(decl_34098, type, fn_endodermal_cell_36: $i > $i).
% 29.22/29.02  tff(decl_34099, type, fn_endodermal_cell_37: $i > $i).
% 29.22/29.02  tff(decl_34100, type, fn_endodermis_1: $i > $i).
% 29.22/29.02  tff(decl_34101, type, fn_endodermal_cell_31: $i > $i).
% 29.22/29.02  tff(decl_34102, type, fn_endodermal_cell_32: $i > $i).
% 29.22/29.02  tff(decl_34103, type, fn_plant_cell_93: $i > $i).
% 29.22/29.02  tff(decl_34104, type, fn_plant_cell_87: $i > $i).
% 29.22/29.02  tff(decl_34105, type, fn_plant_cell_27: $i > $i).
% 29.22/29.02  tff(decl_34106, type, fn_plant_cell_24: $i > $i).
% 29.22/29.02  tff(decl_34107, type, fn_plant_cell_80: $i > $i).
% 29.22/29.02  tff(decl_34108, type, fn_plant_cell_15: $i > $i).
% 29.22/29.02  tff(decl_34109, type, 'Endodermis': $i).
% 29.22/29.02  tff(decl_34110, type, 'The innermost layer of cortex in some plants. It forms a cylinder one cell thick that functions as a boundary between the cortex itself and the stele.': $i).
% 29.22/29.02  tff(decl_34111, type, endodermis: $i).
% 29.22/29.02  tff(decl_34112, type, endomembranous_system_1: $i > $o).
% 29.22/29.02  tff(decl_34113, type, 'Endomembranous-System': $i).
% 29.22/29.02  tff(decl_34114, type, 'The collection of membranes inside and surrounding a eukaryotic cell, related either through direct physical contact or by the transfer of membranous vesicles; includes the plasma membrane, the nuclear envelope, the smooth and rough endoplasmic reticulum, the Golgi apparatus, lysosomes, vesicles, and vacuoles.': $i).
% 29.22/29.02  tff(decl_34115, type, 'endomembrane system': $i).
% 29.22/29.02  tff(decl_34116, type, 'endomembrane-system': $i).
% 29.22/29.02  tff(decl_34117, type, endomembrane: $i).
% 29.22/29.02  tff(decl_34118, type, 'endomembranous system': $i).
% 29.22/29.02  tff(decl_34119, type, 'endomembranous-system': $i).
% 29.22/29.02  tff(decl_34120, type, fn_endomembranous_system_1: $i > $i).
% 29.22/29.02  tff(decl_34121, type, fn_endomembranous_system_2: $i > $i).
% 29.22/29.02  tff(decl_34122, type, fn_endomembranous_system_3: $i > $i).
% 29.22/29.02  tff(decl_34123, type, fn_endomembranous_system_4: $i > $i).
% 29.22/29.02  tff(decl_34124, type, fn_endomembranous_system_5: $i > $i).
% 29.22/29.02  tff(decl_34125, type, fn_endomembranous_system_6: $i > $i).
% 29.22/29.02  tff(decl_34126, type, fn_endomembranous_system_7: $i > $i).
% 29.22/29.02  tff(decl_34127, type, fn_endomembranous_system_8: $i > $i).
% 29.22/29.02  tff(decl_34128, type, fn_endomembranous_system_9: $i > $i).
% 29.22/29.02  tff(decl_34129, type, fn_endomembranous_system_10: $i > $i).
% 29.22/29.02  tff(decl_34130, type, fn_endomembranous_system_11: $i > $i).
% 29.22/29.02  tff(decl_34131, type, fn_endomembranous_system_12: $i > $i).
% 29.22/29.02  tff(decl_34132, type, fn_endomembranous_system_13: $i > $i).
% 29.22/29.02  tff(decl_34133, type, fn_endomembranous_system_14: $i > $i).
% 29.22/29.02  tff(decl_34134, type, fn_endomembranous_system_15: $i > $i).
% 29.22/29.02  tff(decl_34135, type, fn_endomembranous_system_16: $i > $i).
% 29.22/29.02  tff(decl_34136, type, fn_endomembranous_system_17: $i > $i).
% 29.22/29.02  tff(decl_34137, type, fn_endomembranous_system_18: $i > $i).
% 29.22/29.02  tff(decl_34138, type, fn_endomembranous_system_19: $i > $i).
% 29.22/29.02  tff(decl_34139, type, fn_endomembranous_system_20: $i > $i).
% 29.22/29.02  tff(decl_34140, type, fn_endomembranous_system_21: $i > $i).
% 29.22/29.02  tff(decl_34141, type, fn_endomembranous_system_22: $i > $i).
% 29.22/29.02  tff(decl_34142, type, fn_endomembranous_system_23: $i > $i).
% 29.22/29.02  tff(decl_34143, type, fn_endomembranous_system_24: $i > $i).
% 29.22/29.02  tff(decl_34144, type, fn_endomembranous_system_25: $i > $i).
% 29.22/29.02  tff(decl_34145, type, fn_endomembranous_system_26: $i > $i).
% 29.22/29.02  tff(decl_34146, type, fn_endomembranous_system_27: $i > $i).
% 29.22/29.02  tff(decl_34147, type, fn_endomembranous_system_28: $i > $i).
% 29.22/29.02  tff(decl_34148, type, fn_endomembranous_system_29: $i > $i).
% 29.22/29.02  tff(decl_34149, type, fn_endomembranous_system_30: $i > $i).
% 29.22/29.02  tff(decl_34150, type, fn_endomembranous_system_31: $i > $i).
% 29.22/29.02  tff(decl_34151, type, fn_endomembranous_system_32: $i > $i).
% 29.22/29.02  tff(decl_34152, type, fn_endomembranous_system_33: $i > $i).
% 29.22/29.02  tff(decl_34153, type, fn_endomembranous_system_34: $i > $i).
% 29.22/29.02  tff(decl_34154, type, fn_endomembranous_system_35: $i > $i).
% 29.22/29.02  tff(decl_34155, type, fn_endomembranous_system_36: $i > $i).
% 29.22/29.02  tff(decl_34156, type, fn_endomembranous_system_37: $i > $i).
% 29.22/29.02  tff(decl_34157, type, fn_endomembranous_system_38: $i > $i).
% 29.22/29.02  tff(decl_34158, type, fn_endomembranous_system_39: $i > $i).
% 29.22/29.02  tff(decl_34159, type, fn_endomembranous_system_40: $i > $i).
% 29.22/29.02  tff(decl_34160, type, fn_endomembranous_system_41: $i > $i).
% 29.22/29.02  tff(decl_34161, type, fn_endomembranous_system_42: $i > $i).
% 29.22/29.02  tff(decl_34162, type, fn_endomembranous_system_43: $i > $i).
% 29.22/29.02  tff(decl_34163, type, fn_endomembranous_system_44: $i > $i).
% 29.22/29.02  tff(decl_34164, type, fn_endomembranous_system_45: $i > $i).
% 29.22/29.02  tff(decl_34165, type, fn_endomembranous_system_46: $i > $i).
% 29.22/29.02  tff(decl_34166, type, fn_endomembranous_system_47: $i > $i).
% 29.22/29.02  tff(decl_34167, type, fn_endomembranous_system_48: $i > $i).
% 29.22/29.02  tff(decl_34168, type, fn_endomembranous_system_49: $i > $i).
% 29.22/29.02  tff(decl_34169, type, fn_endomembranous_system_50: $i > $i).
% 29.22/29.02  tff(decl_34170, type, fn_endomembranous_system_51: $i > $i).
% 29.22/29.02  tff(decl_34171, type, fn_endomembranous_system_52: $i > $i).
% 29.22/29.02  tff(decl_34172, type, fn_endomembranous_system_53: $i > $i).
% 29.22/29.02  tff(decl_34173, type, movement_of_endomembranous_system_membrane_1: $i > $o).
% 29.22/29.02  tff(decl_34174, type, fn_endomembranous_system_54: $i > $i).
% 29.22/29.02  tff(decl_34175, type, fn_endomembranous_system_55: $i > $i).
% 29.22/29.02  tff(decl_34176, type, fn_endomembranous_system_56: $i > $i).
% 29.22/29.02  tff(decl_34177, type, fn_endomembranous_system_57: $i > $i).
% 29.22/29.02  tff(decl_34178, type, fn_endomembranous_system_58: $i > $i).
% 29.22/29.02  tff(decl_34179, type, fn_movement_of_endomembranous_system_membrane_6: $i > $i).
% 29.22/29.02  tff(decl_34180, type, fn_movement_of_endomembranous_system_membrane_10: $i > $i).
% 29.22/29.02  tff(decl_34181, type, fn_synthesis_of_endomembranous_system_membrane_103: $i > $i).
% 29.22/29.02  tff(decl_34182, type, fn_synthesis_of_endomembranous_system_membrane_99: $i > $i).
% 29.22/29.02  tff(decl_34183, type, fn_synthesis_of_endomembranous_system_membrane_104: $i > $i).
% 29.22/29.02  tff(decl_34184, type, fn_synthesis_of_endomembranous_system_membrane_105: $i > $i).
% 29.22/29.02  tff(decl_34185, type, fn_synthesis_of_endomembranous_system_membrane_85: $i > $i).
% 29.22/29.02  tff(decl_34186, type, fn_synthesis_of_endomembranous_system_membrane_84: $i > $i).
% 29.22/29.02  tff(decl_34187, type, fn_synthesis_of_endomembranous_system_membrane_62: $i > $i).
% 29.22/29.02  tff(decl_34188, type, fn_movement_of_endomembranous_system_membrane_5: $i > $i).
% 29.22/29.02  tff(decl_34189, type, fn_movement_of_endomembranous_system_membrane_16: $i > $i).
% 29.22/29.02  tff(decl_34190, type, fn_movement_of_endomembranous_system_membrane_14: $i > $i).
% 29.22/29.02  tff(decl_34191, type, fn_synthesis_of_endomembranous_system_membrane_69: $i > $i).
% 29.22/29.02  tff(decl_34192, type, fn_movement_of_endomembranous_system_membrane_15: $i > $i).
% 29.22/29.02  tff(decl_34193, type, fn_synthesis_of_endomembranous_system_membrane_67: $i > $i).
% 29.22/29.02  tff(decl_34194, type, fn_go_to_1: $i > $i).
% 29.22/29.02  tff(decl_34195, type, fn_movement_of_endomembranous_system_membrane_8: $i > $i).
% 29.22/29.02  tff(decl_34196, type, fn_synthesis_of_endomembranous_system_membrane_63: $i > $i).
% 29.22/29.02  tff(decl_34197, type, fn_movement_of_endomembranous_system_membrane_3: $i > $i).
% 29.22/29.02  tff(decl_34198, type, fn_synthesis_of_endomembranous_system_membrane_65: $i > $i).
% 29.22/29.02  tff(decl_34199, type, fn_synthesis_of_endomembranous_system_membrane_53: $i > $i).
% 29.22/29.02  tff(decl_34200, type, fn_movement_of_endomembranous_system_membrane_13: $i > $i).
% 29.22/29.02  tff(decl_34201, type, fn_synthesis_of_endomembranous_system_membrane_66: $i > $i).
% 29.22/29.02  tff(decl_34202, type, fn_movement_of_endomembranous_system_membrane_4: $i > $i).
% 29.22/29.02  tff(decl_34203, type, fn_synthesis_of_endomembranous_system_membrane_50: $i > $i).
% 29.22/29.02  tff(decl_34204, type, fn_movement_of_endomembranous_system_membrane_11: $i > $i).
% 29.22/29.02  tff(decl_34205, type, fn_vacuole_12: $i > $i).
% 29.22/29.02  tff(decl_34206, type, fn_synthesis_of_endomembranous_system_membrane_28: $i > $i).
% 29.22/29.02  tff(decl_34207, type, fn_movement_of_endomembranous_system_membrane_2: $i > $i).
% 29.22/29.02  tff(decl_34208, type, fn_synthesis_of_endomembranous_system_membrane_51: $i > $i).
% 29.22/29.02  tff(decl_34209, type, fn_synthesis_of_endomembranous_system_membrane_54: $i > $i).
% 29.22/29.02  tff(decl_34210, type, fn_movement_of_endomembranous_system_membrane_9: $i > $i).
% 29.22/29.02  tff(decl_34211, type, fn_synthesis_of_endomembranous_system_membrane_64: $i > $i).
% 29.22/29.02  tff(decl_34212, type, endometriosis_1: $i > $o).
% 29.22/29.02  tff(decl_34213, type, 'Endometriosis': $i).
% 29.22/29.02  tff(decl_34214, type, 'A medical condition in which endometrial tissue grows outside of the uterus.': $i).
% 29.22/29.02  tff(decl_34215, type, endometriosis: $i).
% 29.22/29.02  tff(decl_34216, type, 'Endometrium': $i).
% 29.22/29.02  tff(decl_34217, type, 'The innermost glandular lining of the mammalian uterus.': $i).
% 29.22/29.02  tff(decl_34218, type, endometrium: $i).
% 29.22/29.02  tff(decl_34219, type, labia_majora_1: $i > $o).
% 29.22/29.02  tff(decl_34220, type, endomycorrhizae_1: $i > $o).
% 29.22/29.02  tff(decl_34221, type, 'Endomycorrhizae': $i).
% 29.22/29.02  tff(decl_34222, type, 'A form of mycorrhiza in which the hyphae of the fungus penetrate the cortex of the root cells.': $i).
% 29.22/29.02  tff(decl_34223, type, endomycorrhizae: $i).
% 29.22/29.02  tff(decl_34224, type, 'Endoparasite': $i).
% 29.22/29.02  tff(decl_34225, type, 'A parasite that lives within the body of its host.': $i).
% 29.22/29.02  tff(decl_34226, type, endoparasite: $i).
% 29.22/29.02  tff(decl_34227, type, 'Endophyte': $i).
% 29.22/29.02  tff(decl_34228, type, 'An endosymbiotic bacterium or fungus that lives at least part of its life within a plant but does not harm it.': $i).
% 29.22/29.02  tff(decl_34229, type, endophyte: $i).
% 29.22/29.02  tff(decl_34230, type, 'Endoplasmic-Reticulum': $i).
% 29.22/29.02  tff(decl_34231, type, 'Endoplasmic reticulum (ER) is an eukaryotic organelle primarily composed of tubules, vesicles, and cisternae which form its thread-like membranous labyrinth. There are two types of ER: RER (Rough endoplasmic reticulum, bearing ribosomes on their surface) and SER(Smooth Endoplasmic reticulum, lacking ribosomes on their surface). An ER serves as a region of synthesis and transition from one part of cell to another for many cellular molecules like protein, glycoprotein, lipids etc. ER has a bilayered membrane which is continuous with the nuclear membrane': $i).
% 29.22/29.02  tff(decl_34232, type, er: $i).
% 29.22/29.02  tff(decl_34233, type, 'endoplasmic reticulum': $i).
% 29.22/29.02  tff(decl_34234, type, 'endoplasmic-reticulum': $i).
% 29.22/29.02  tff(decl_34235, type, fn_endoplasmic_reticulum_1: $i > $i).
% 29.22/29.02  tff(decl_34236, type, fn_endoplasmic_reticulum_2: $i > $i).
% 29.22/29.02  tff(decl_34237, type, fn_endoplasmic_reticulum_3: $i > $i).
% 29.22/29.02  tff(decl_34238, type, fn_endoplasmic_reticulum_4: $i > $i).
% 29.22/29.02  tff(decl_34239, type, fn_endoplasmic_reticulum_5: $i > $i).
% 29.22/29.02  tff(decl_34240, type, fn_endoplasmic_reticulum_6: $i > $i).
% 29.22/29.02  tff(decl_34241, type, fn_endoplasmic_reticulum_7: $i > $i).
% 29.22/29.02  tff(decl_34242, type, fn_endoplasmic_reticulum_8: $i > $i).
% 29.22/29.02  tff(decl_34243, type, fn_endoplasmic_reticulum_12: $i > $i).
% 29.22/29.02  tff(decl_34244, type, fn_endoplasmic_reticulum_13: $i > $i).
% 29.22/29.02  tff(decl_34245, type, fn_endoplasmic_reticulum_15: $i > $i).
% 29.22/29.02  tff(decl_34246, type, fn_endoplasmic_reticulum_16: $i > $i).
% 29.22/29.02  tff(decl_34247, type, fn_endoplasmic_reticulum_17: $i > $i).
% 29.22/29.02  tff(decl_34248, type, fn_endoplasmic_reticulum_18: $i > $i).
% 29.22/29.02  tff(decl_34249, type, fn_endoplasmic_reticulum_19: $i > $i).
% 29.22/29.02  tff(decl_34250, type, fn_endoplasmic_reticulum_20: $i > $i).
% 29.22/29.02  tff(decl_34251, type, fn_endoplasmic_reticulum_21: $i > $i).
% 29.22/29.02  tff(decl_34252, type, fn_endoplasmic_reticulum_22: $i > $i).
% 29.22/29.02  tff(decl_34253, type, fn_endoplasmic_reticulum_24: $i > $i).
% 29.22/29.02  tff(decl_34254, type, fn_endoplasmic_reticulum_26: $i > $i).
% 29.22/29.02  tff(decl_34255, type, intracellular_material_1: $i > $o).
% 29.22/29.02  tff(decl_34256, type, fn_endoplasmic_reticulum_27: $i > $i).
% 29.22/29.02  tff(decl_34257, type, fn_endoplasmic_reticulum_28: $i > $i).
% 29.22/29.02  tff(decl_34258, type, fn_endoplasmic_reticulum_29: $i > $i).
% 29.22/29.02  tff(decl_34259, type, fn_endoplasmic_reticulum_32: $i > $i).
% 29.22/29.02  tff(decl_34260, type, fn_endoplasmic_reticulum_33: $i > $i).
% 29.22/29.02  tff(decl_34261, type, fn_endoplasmic_reticulum_34: $i > $i).
% 29.22/29.02  tff(decl_34262, type, fn_endoplasmic_reticulum_35: $i > $i).
% 29.22/29.02  tff(decl_34263, type, fn_endoplasmic_reticulum_36: $i > $i).
% 29.22/29.02  tff(decl_34264, type, fn_endoplasmic_reticulum_37: $i > $i).
% 29.22/29.02  tff(decl_34265, type, fn_endoplasmic_reticulum_38: $i > $i).
% 29.22/29.02  tff(decl_34266, type, fn_endoplasmic_reticulum_39: $i > $i).
% 29.22/29.02  tff(decl_34267, type, fn_endoplasmic_reticulum_41: $i > $i).
% 29.22/29.02  tff(decl_34268, type, fn_er_membrane_29: $i > $i).
% 29.22/29.02  tff(decl_34269, type, fn_nuclear_membrane_19: $i > $i).
% 29.22/29.02  tff(decl_34270, type, fn_nuclear_membrane_21: $i > $i).
% 29.22/29.02  tff(decl_34271, type, fn_er_membrane_7: $i > $i).
% 29.22/29.02  tff(decl_34272, type, endorphin_1: $i > $o).
% 29.22/29.02  tff(decl_34273, type, 'Endorphin': $i).
% 29.22/29.02  tff(decl_34274, type, 'Opioid molecules produced by the anterior pituitary and the hypothalamus that act as neurotransmitters. Endorphins provide pain relief and an overall sense of well-being.': $i).
% 29.22/29.02  tff(decl_34275, type, endorphin: $i).
% 29.22/29.02  tff(decl_34276, type, substance_p_1: $i > $o).
% 29.22/29.02  tff(decl_34277, type, fn_endorphin_1: $i > $i).
% 29.22/29.02  tff(decl_34278, type, fn_endorphin_2: $i > $i).
% 29.22/29.02  tff(decl_34279, type, fn_endorphin_3: $i > $i).
% 29.22/29.02  tff(decl_34280, type, fn_endorphin_4: $i > $i).
% 29.22/29.02  tff(decl_34281, type, fn_endorphin_5: $i > $i).
% 29.22/29.02  tff(decl_34282, type, fn_endorphin_6: $i > $i).
% 29.22/29.02  tff(decl_34283, type, fn_endorphin_7: $i > $i).
% 29.22/29.02  tff(decl_34284, type, endorphin_receptor_1: $i > $o).
% 29.22/29.02  tff(decl_34285, type, fn_endorphin_8: $i > $i).
% 29.22/29.02  tff(decl_34286, type, fn_nervous_system_1: $i > $i).
% 29.22/29.02  tff(decl_34287, type, 'Endorphin-Receptor': $i).
% 29.22/29.02  tff(decl_34288, type, 'Endorphin-receptor sites are present on nerve endings in the brain.': $i).
% 29.22/29.02  tff(decl_34289, type, 'receptor of endorphin': $i).
% 29.22/29.02  tff(decl_34290, type, 'endorphin receptor': $i).
% 29.22/29.02  tff(decl_34291, type, 'endorphin-receptor': $i).
% 29.22/29.02  tff(decl_34292, type, endoskeleton_1: $i > $o).
% 29.22/29.02  tff(decl_34293, type, 'Endoskeleton': $i).
% 29.22/29.02  tff(decl_34294, type, 'A skeletal support system that is buried within the soft tissues of an animal.  Sponges, echinoderms, and vertebrates have endoskeletons.': $i).
% 29.22/29.02  tff(decl_34295, type, endoskeleton: $i).
% 29.22/29.02  tff(decl_34296, type, skeleton_1: $i > $o).
% 29.22/29.02  tff(decl_34297, type, hydrostatic_skeleton_1: $i > $o).
% 29.22/29.02  tff(decl_34298, type, endosperm_1: $i > $o).
% 29.22/29.02  tff(decl_34299, type, 'Endosperm': $i).
% 29.22/29.02  tff(decl_34300, type, 'In angiosperms, a nutrient-rich tissue formed by the union of a sperm with two polar nuclei during double fertilization. The endosperm provides nourishment to the developing embryo in angiosperm seeds.': $i).
% 29.22/29.02  tff(decl_34301, type, endosperm: $i).
% 29.22/29.02  tff(decl_34302, type, integument_1: $i > $o).
% 29.22/29.02  tff(decl_34303, type, leaf_primordium_1: $i > $o).
% 29.22/29.02  tff(decl_34304, type, phloem_1: $i > $o).
% 29.22/29.02  tff(decl_34305, type, primary_plant_body_1: $i > $o).
% 29.22/29.02  tff(decl_34306, type, primary_plant_1: $i > $o).
% 29.22/29.02  tff(decl_34307, type, protonema_1: $i > $o).
% 29.22/29.02  tff(decl_34308, type, receptacle_1: $i > $o).
% 29.22/29.02  tff(decl_34309, type, fn_endosperm_1: $i > $i).
% 29.22/29.02  tff(decl_34310, type, fn_endosperm_2: $i > $i).
% 29.22/29.02  tff(decl_34311, type, fn_endosperm_3: $i > $i).
% 29.22/29.02  tff(decl_34312, type, fn_endosperm_4: $i > $i).
% 29.22/29.02  tff(decl_34313, type, fn_endosperm_5: $i > $i).
% 29.22/29.02  tff(decl_34314, type, fn_endosperm_6: $i > $i).
% 29.22/29.02  tff(decl_34315, type, endospore_1: $i > $o).
% 29.22/29.02  tff(decl_34316, type, 'Endospore': $i).
% 29.22/29.02  tff(decl_34317, type, 'A dormant, thick-walled non-reproductive cell produced by some bacteria when exposed to harsh conditions. Endospores can lie dormant for many years and be revived when the environment becomes favorable again.': $i).
% 29.22/29.02  tff(decl_34318, type, endospore: $i).
% 29.22/29.02  tff(decl_34319, type, 'Endosymbiosis': $i).
% 29.22/29.02  tff(decl_34320, type, 'A process in which a unicellular organism (the host) engulfs another cell, which lives within the host cell and ultimately becomes an organelle in the host cell; also refers to the hypothesis that mitochondria and plastids were formerly small prokaryotes that began living within larger cells.': $i).
% 29.22/29.02  tff(decl_34321, type, 'endosymbiont hypothesis': $i).
% 29.22/29.02  tff(decl_34322, type, 'endosymbiont theory': $i).
% 29.22/29.02  tff(decl_34323, type, 'primary endosymbiosis': $i).
% 29.22/29.02  tff(decl_34324, type, endosymbiosis: $i).
% 29.22/29.02  tff(decl_34325, type, endothelin_1: $i > $o).
% 29.22/29.02  tff(decl_34326, type, 'Endothelin': $i).
% 29.22/29.02  tff(decl_34327, type, 'A peptide produced by a blood vessels endothelium that causes the vessel to constrict, thereby raising blood pressure.': $i).
% 29.22/29.02  tff(decl_34328, type, endothelin: $i).
% 29.22/29.02  tff(decl_34329, type, heavy_chain_1: $i > $o).
% 29.22/29.02  tff(decl_34330, type, light_chain_1: $i > $o).
% 29.22/29.02  tff(decl_34331, type, polypeptide_segment_1: $i > $o).
% 29.22/29.02  tff(decl_34332, type, signal_peptide_1: $i > $o).
% 29.22/29.02  tff(decl_34333, type, 'Endothelium': $i).
% 29.22/29.02  tff(decl_34334, type, 'The thin layer of cells that lines the inner surfaces of blood vessels.': $i).
% 29.22/29.02  tff(decl_34335, type, endothelium: $i).
% 29.22/29.02  tff(decl_34336, type, 'Endothermic': $i).
% 29.22/29.02  tff(decl_34337, type, 'Able to regulate body temperature using primarily the heat generated by metabolism. Endothermic animals typically have a body temperature that is higher than that of the surrounding environment.': $i).
% 29.22/29.02  tff(decl_34338, type, endothermic: $i).
% 29.22/29.02  tff(decl_34339, type, 'warm blooded': $i).
% 29.22/29.02  tff(decl_34340, type, 'warm-blooded': $i).
% 29.22/29.02  tff(decl_34341, type, endothermic_organism_1: $i > $o).
% 29.22/29.02  tff(decl_34342, type, 'Endothermic-Organism': $i).
% 29.22/29.02  tff(decl_34343, type, 'Endothermic organisms are the organisms that are warmed by heat generated by their own metabolism. This heat usually maintains a relatively stable body temperature higher than that of external environment.': $i).
% 29.22/29.02  tff(decl_34344, type, 'organism of endothermic': $i).
% 29.22/29.02  tff(decl_34345, type, 'endothermic organism': $i).
% 29.22/29.02  tff(decl_34346, type, 'endothermic-organism': $i).
% 29.22/29.02  tff(decl_34347, type, fn_endothermic_organism_1: $i > $i).
% 29.22/29.02  tff(decl_34348, type, endotoxin_1: $i > $o).
% 29.22/29.02  tff(decl_34349, type, 'Endotoxin': $i).
% 29.22/29.02  tff(decl_34350, type, 'Toxic component of the outer cell membrane of some Gram-negative bacteria. The toxin is released to th environment only when the bacterial cell dies.': $i).
% 29.22/29.02  tff(decl_34351, type, endotoxin: $i).
% 29.22/29.02  tff(decl_34352, type, 'Energy': $i).
% 29.22/29.02  tff(decl_34353, type, 'The capacity to do work.': $i).
% 29.22/29.02  tff(decl_34354, type, 'Energy is the capacity to do work.': $i).
% 29.22/29.02  tff(decl_34355, type, energy: $i).
% 29.22/29.02  tff(decl_34356, type, energy_budget_1: $i > $o).
% 29.22/29.02  tff(decl_34357, type, 'Energy-Budget': $i).
% 29.22/29.02  tff(decl_34358, type, 'The way that an organism allocates energy to manage all the processes of life.': $i).
% 29.22/29.02  tff(decl_34359, type, 'budget of energy': $i).
% 29.22/29.02  tff(decl_34360, type, 'energy budget': $i).
% 29.22/29.02  tff(decl_34361, type, 'energy-budget': $i).
% 29.22/29.02  tff(decl_34362, type, 'Energy-Constant': $i).
% 29.22/29.02  tff(decl_34363, type, 'constant of energy': $i).
% 29.22/29.02  tff(decl_34364, type, 'energy constant': $i).
% 29.22/29.02  tff(decl_34365, type, 'energy-constant': $i).
% 29.22/29.02  tff(decl_34366, type, 'Energy-Coupling': $i).
% 29.22/29.02  tff(decl_34367, type, 'Energy coupling describes how cells use energy harvested from exergonic biochemical reactions, usually in the form of ATP, to power endergonic reactions.': $i).
% 29.22/29.02  tff(decl_34368, type, 'coupling of energy': $i).
% 29.22/29.02  tff(decl_34369, type, 'energy coupling': $i).
% 29.22/29.02  tff(decl_34370, type, 'energy-coupling': $i).
% 29.22/29.02  tff(decl_34371, type, energy_flow_1: $i > $o).
% 29.22/29.02  tff(decl_34372, type, 'Energy-Flow': $i).
% 29.22/29.02  tff(decl_34373, type, 'The process of energy being transfered throughout a system.': $i).
% 29.22/29.02  tff(decl_34374, type, 'flow of energy': $i).
% 29.22/29.02  tff(decl_34375, type, 'energy flow': $i).
% 29.22/29.02  tff(decl_34376, type, 'energy-flow': $i).
% 29.22/29.02  tff(decl_34377, type, 'Energy-Flow-In-Ecosystem': $i).
% 29.22/29.02  tff(decl_34378, type, 'The process of flow of energy within ecosystem is called energy flow in ecosystem.': $i).
% 29.22/29.02  tff(decl_34379, type, 'energy flow in ecosystem': $i).
% 29.22/29.02  tff(decl_34380, type, 'energy-flow-in-ecosystem': $i).
% 29.22/29.02  tff(decl_34381, type, fn_energy_flow_in_ecosystem_2: $i > $i).
% 29.22/29.02  tff(decl_34382, type, 'Energy-Investment-Phase-Of-Glycolysis': $i).
% 29.22/29.02  tff(decl_34383, type, 'The first half of glycolysis, which consists of a series of chemical reactions, in which there is a net expenditure of energy.': $i).
% 29.22/29.02  tff(decl_34384, type, 'undergo energy investment phase of glycolysis': $i).
% 29.22/29.02  tff(decl_34385, type, 'energy investment phase of glycolysis': $i).
% 29.22/29.02  tff(decl_34386, type, 'energy-investment-phase-of-glycolysis': $i).
% 29.22/29.02  tff(decl_34387, type, fn_energy_investment_phase_of_glycolysis_5: $i > $i).
% 29.22/29.02  tff(decl_34388, type, fn_energy_investment_phase_of_glycolysis_6: $i > $i).
% 29.22/29.02  tff(decl_34389, type, fn_energy_investment_phase_of_glycolysis_7: $i > $i).
% 29.22/29.02  tff(decl_34390, type, fn_energy_investment_phase_of_glycolysis_8: $i > $i).
% 29.22/29.02  tff(decl_34391, type, fn_energy_investment_phase_of_glycolysis_9: $i > $i).
% 29.22/29.02  tff(decl_34392, type, fn_energy_investment_phase_of_glycolysis_12: $i > $i).
% 29.22/29.02  tff(decl_34393, type, fn_energy_investment_phase_of_glycolysis_13: $i > $i).
% 29.22/29.02  tff(decl_34394, type, fn_energy_investment_phase_of_glycolysis_14: $i > $i).
% 29.22/29.02  tff(decl_34395, type, fn_energy_investment_phase_of_glycolysis_15: $i > $i).
% 29.22/29.02  tff(decl_34396, type, fn_energy_investment_phase_of_glycolysis_16: $i > $i).
% 29.22/29.02  tff(decl_34397, type, fn_energy_investment_phase_of_glycolysis_17: $i > $i).
% 29.22/29.02  tff(decl_34398, type, fn_energy_investment_phase_of_glycolysis_18: $i > $i).
% 29.22/29.02  tff(decl_34399, type, fn_energy_investment_phase_of_glycolysis_19: $i > $i).
% 29.22/29.02  tff(decl_34400, type, fn_energy_investment_phase_of_glycolysis_20: $i > $i).
% 29.22/29.02  tff(decl_34401, type, isomerase_1: $i > $o).
% 29.22/29.02  tff(decl_34402, type, fn_energy_investment_phase_of_glycolysis_21: $i > $i).
% 29.22/29.02  tff(decl_34403, type, fn_energy_investment_phase_of_glycolysis_22: $i > $i).
% 29.22/29.02  tff(decl_34404, type, fn_energy_investment_phase_of_glycolysis_23: $i > $i).
% 29.22/29.02  tff(decl_34405, type, fn_energy_investment_phase_of_glycolysis_24: $i > $i).
% 29.22/29.02  tff(decl_34406, type, fn_energy_investment_phase_of_glycolysis_25: $i > $i).
% 29.22/29.02  tff(decl_34407, type, fn_energy_investment_phase_of_glycolysis_26: $i > $i).
% 29.22/29.02  tff(decl_34408, type, fn_energy_investment_phase_of_glycolysis_27: $i > $i).
% 29.22/29.02  tff(decl_34409, type, fn_energy_investment_phase_of_glycolysis_28: $i > $i).
% 29.22/29.02  tff(decl_34410, type, fn_energy_investment_phase_of_glycolysis_29: $i > $i).
% 29.22/29.02  tff(decl_34411, type, fn_energy_investment_phase_of_glycolysis_30: $i > $i).
% 29.22/29.02  tff(decl_34412, type, fn_energy_investment_phase_of_glycolysis_31: $i > $i).
% 29.22/29.02  tff(decl_34413, type, fructose_6_phosphate_1: $i > $o).
% 29.22/29.02  tff(decl_34414, type, fn_energy_investment_phase_of_glycolysis_32: $i > $i).
% 29.22/29.02  tff(decl_34415, type, fn_energy_investment_phase_of_glycolysis_33: $i > $i).
% 29.22/29.02  tff(decl_34416, type, fn_energy_investment_phase_of_glycolysis_34: $i > $i).
% 29.22/29.02  tff(decl_34417, type, fn_energy_investment_phase_of_glycolysis_35: $i > $i).
% 29.22/29.02  tff(decl_34418, type, fn_energy_investment_phase_of_glycolysis_36: $i > $i).
% 29.22/29.02  tff(decl_34419, type, hexokinase_1: $i > $o).
% 29.22/29.02  tff(decl_34420, type, fn_energy_investment_phase_of_glycolysis_37: $i > $i).
% 29.22/29.02  tff(decl_34421, type, phosphoglucoisomerase_1: $i > $o).
% 29.22/29.02  tff(decl_34422, type, fn_energy_investment_phase_of_glycolysis_38: $i > $i).
% 29.22/29.02  tff(decl_34423, type, fn_energy_investment_phase_of_glycolysis_39: $i > $i).
% 29.22/29.02  tff(decl_34424, type, fn_energy_investment_phase_of_glycolysis_40: $i > $i).
% 29.22/29.02  tff(decl_34425, type, fn_hexokinase_8: $i > $i).
% 29.22/29.02  tff(decl_34426, type, fn_hexokinase_6: $i > $i).
% 29.22/29.02  tff(decl_34427, type, fn_forward_reaction_8: $i > $i).
% 29.22/29.02  tff(decl_34428, type, fn_glucose_6_phosphate_26: $i > $i).
% 29.22/29.02  tff(decl_34429, type, fn_phosphofructokinase_17: $i > $i).
% 29.22/29.02  tff(decl_34430, type, fn_phosphofructokinase_51: $i > $i).
% 29.22/29.02  tff(decl_34431, type, fn_phosphofructokinase_24: $i > $i).
% 29.22/29.02  tff(decl_34432, type, fn_phosphofructokinase_28: $i > $i).
% 29.22/29.02  tff(decl_34433, type, fn_glucose_6_phosphate_24: $i > $i).
% 29.22/29.02  tff(decl_34434, type, fn_hexokinase_9: $i > $i).
% 29.22/29.02  tff(decl_34435, type, fn_glucose_6_phosphate_25: $i > $i).
% 29.22/29.02  tff(decl_34436, type, "23.9e0": $i).
% 29.22/29.02  tff(decl_34437, type, "-14.2e0": $i).
% 29.22/29.02  tff(decl_34438, type, "1.67e0": $i).
% 29.22/29.02  tff(decl_34439, type, "-16.7e0": $i).
% 29.22/29.02  tff(decl_34440, type, "7.56e0": $i).
% 29.22/29.02  tff(decl_34441, type, glyceraldehyde_3_phosphate_0: $i).
% 29.22/29.02  tff(decl_34442, type, "2.23e0": $i).
% 29.22/29.02  tff(decl_34443, type, fn_energy_investment_phase_of_glycolysis_11: $i > $i).
% 29.22/29.02  tff(decl_34444, type, fn_exergonic_reaction_9: $i > $i).
% 29.22/29.02  tff(decl_34445, type, fn_exergonic_reaction_8: $i > $i).
% 29.22/29.02  tff(decl_34446, type, fn_energy_investment_phase_of_glycolysis_41: $i > $i).
% 29.22/29.02  tff(decl_34447, type, fn_energy_investment_phase_of_glycolysis_42: $i > $i).
% 29.22/29.02  tff(decl_34448, type, energy_payoff_phase_of_glycolysis_1: $i > $o).
% 29.22/29.02  tff(decl_34449, type, 'Energy-Payoff-Phase-Of-Glycolysis': $i).
% 29.22/29.02  tff(decl_34450, type, 'The second phase of glycolysis, consisting of a series of chemical reactions, in which ATP is ultimately produced.': $i).
% 29.22/29.02  tff(decl_34451, type, 'undergo energy payoff phase of glycolysis': $i).
% 29.22/29.02  tff(decl_34452, type, 'energy payoff phase of glycolysis': $i).
% 29.22/29.02  tff(decl_34453, type, 'energy-payoff-phase-of-glycolysis': $i).
% 29.22/29.02  tff(decl_34454, type, fn_energy_payoff_phase_of_glycolysis_2: $i > $i).
% 29.22/29.02  tff(decl_34455, type, fn_energy_payoff_phase_of_glycolysis_3: $i > $i).
% 29.22/29.02  tff(decl_34456, type, fn_energy_payoff_phase_of_glycolysis_4: $i > $i).
% 29.22/29.02  tff(decl_34457, type, fn_energy_payoff_phase_of_glycolysis_5: $i > $i).
% 29.22/29.02  tff(decl_34458, type, fn_energy_payoff_phase_of_glycolysis_6: $i > $i).
% 29.22/29.02  tff(decl_34459, type, fn_energy_payoff_phase_of_glycolysis_9: $i > $i).
% 29.22/29.02  tff(decl_34460, type, fn_energy_payoff_phase_of_glycolysis_10: $i > $i).
% 29.22/29.02  tff(decl_34461, type, fn_energy_payoff_phase_of_glycolysis_11: $i > $i).
% 29.22/29.02  tff(decl_34462, type, fn_energy_payoff_phase_of_glycolysis_12: $i > $i).
% 29.22/29.02  tff(decl_34463, type, fn_energy_payoff_phase_of_glycolysis_13: $i > $i).
% 29.22/29.02  tff(decl_34464, type, fn_energy_payoff_phase_of_glycolysis_14: $i > $i).
% 29.22/29.02  tff(decl_34465, type, fn_energy_payoff_phase_of_glycolysis_15: $i > $i).
% 29.22/29.02  tff(decl_34466, type, fn_energy_payoff_phase_of_glycolysis_16: $i > $i).
% 29.22/29.02  tff(decl_34467, type, phosphoglycerokinase_1: $i > $o).
% 29.22/29.02  tff(decl_34468, type, fn_energy_payoff_phase_of_glycolysis_17: $i > $i).
% 29.22/29.02  tff(decl_34469, type, fn_energy_payoff_phase_of_glycolysis_20: $i > $i).
% 29.22/29.02  tff(decl_34470, type, fn_energy_payoff_phase_of_glycolysis_21: $i > $i).
% 29.22/29.02  tff(decl_34471, type, fn_energy_payoff_phase_of_glycolysis_22: $i > $i).
% 29.22/29.02  tff(decl_34472, type, fn_energy_payoff_phase_of_glycolysis_23: $i > $i).
% 29.22/29.02  tff(decl_34473, type, fn_energy_payoff_phase_of_glycolysis_24: $i > $i).
% 29.22/29.02  tff(decl_34474, type, fn_energy_payoff_phase_of_glycolysis_25: $i > $i).
% 29.22/29.02  tff(decl_34475, type, fn_energy_payoff_phase_of_glycolysis_26: $i > $i).
% 29.22/29.02  tff(decl_34476, type, fn_energy_payoff_phase_of_glycolysis_27: $i > $i).
% 29.22/29.02  tff(decl_34477, type, fn_energy_payoff_phase_of_glycolysis_28: $i > $i).
% 29.22/29.02  tff(decl_34478, type, fn_energy_payoff_phase_of_glycolysis_29: $i > $i).
% 29.22/29.02  tff(decl_34479, type, fn_energy_payoff_phase_of_glycolysis_30: $i > $i).
% 29.22/29.02  tff(decl_34480, type, fn_energy_payoff_phase_of_glycolysis_31: $i > $i).
% 29.22/29.02  tff(decl_34481, type, fn_energy_payoff_phase_of_glycolysis_32: $i > $i).
% 29.22/29.02  tff(decl_34482, type, fn_energy_payoff_phase_of_glycolysis_33: $i > $i).
% 29.22/29.02  tff(decl_34483, type, fn_energy_payoff_phase_of_glycolysis_34: $i > $i).
% 29.22/29.02  tff(decl_34484, type, fn_energy_payoff_phase_of_glycolysis_35: $i > $i).
% 29.22/29.02  tff(decl_34485, type, phosphoglyceromutase_1: $i > $o).
% 29.22/29.02  tff(decl_34486, type, fn_energy_payoff_phase_of_glycolysis_36: $i > $i).
% 29.22/29.02  tff(decl_34487, type, enolase_1: $i > $o).
% 29.22/29.02  tff(decl_34488, type, fn_energy_payoff_phase_of_glycolysis_37: $i > $i).
% 29.22/29.02  tff(decl_34489, type, pyruvate_kinase_1: $i > $o).
% 29.22/29.02  tff(decl_34490, type, fn_energy_payoff_phase_of_glycolysis_38: $i > $i).
% 29.22/29.02  tff(decl_34491, type, fn_energy_payoff_phase_of_glycolysis_39: $i > $i).
% 29.22/29.02  tff(decl_34492, type, fn_energy_payoff_phase_of_glycolysis_40: $i > $i).
% 29.22/29.02  tff(decl_34493, type, fn_energy_payoff_phase_of_glycolysis_41: $i > $i).
% 29.22/29.02  tff(decl_34494, type, fn_energy_payoff_phase_of_glycolysis_42: $i > $i).
% 29.22/29.02  tff(decl_34495, type, fn_energy_payoff_phase_of_glycolysis_43: $i > $i).
% 29.22/29.02  tff(decl_34496, type, fn_energy_payoff_phase_of_glycolysis_44: $i > $i).
% 29.22/29.02  tff(decl_34497, type, fn_energy_payoff_phase_of_glycolysis_45: $i > $i).
% 29.22/29.02  tff(decl_34498, type, fn_energy_payoff_phase_of_glycolysis_46: $i > $i).
% 29.22/29.02  tff(decl_34499, type, fn_energy_payoff_phase_of_glycolysis_47: $i > $i).
% 29.22/29.02  tff(decl_34500, type, fn_energy_payoff_phase_of_glycolysis_48: $i > $i).
% 29.22/29.02  tff(decl_34501, type, fn_energy_payoff_phase_of_glycolysis_49: $i > $i).
% 29.22/29.02  tff(decl_34502, type, fn_energy_payoff_phase_of_glycolysis_50: $i > $i).
% 29.22/29.02  tff(decl_34503, type, fn_energy_payoff_phase_of_glycolysis_51: $i > $i).
% 29.22/29.02  tff(decl_34504, type, two_phosphoglycerate_1: $i > $o).
% 29.22/29.02  tff(decl_34505, type, fn_energy_payoff_phase_of_glycolysis_52: $i > $i).
% 29.22/29.02  tff(decl_34506, type, fn_energy_payoff_phase_of_glycolysis_53: $i > $i).
% 29.22/29.02  tff(decl_34507, type, fn_energy_payoff_phase_of_glycolysis_54: $i > $i).
% 29.22/29.02  tff(decl_34508, type, fn_energy_payoff_phase_of_glycolysis_56: $i > $i).
% 29.22/29.02  tff(decl_34509, type, fn_energy_payoff_phase_of_glycolysis_57: $i > $i).
% 29.22/29.02  tff(decl_34510, type, fn_energy_payoff_phase_of_glycolysis_59: $i > $i).
% 29.22/29.02  tff(decl_34511, type, fn_energy_payoff_phase_of_glycolysis_60: $i > $i).
% 29.22/29.02  tff(decl_34512, type, fn_energy_payoff_phase_of_glycolysis_61: $i > $i).
% 29.22/29.02  tff(decl_34513, type, fn_energy_payoff_phase_of_glycolysis_62: $i > $i).
% 29.22/29.02  tff(decl_34514, type, triose_phosphate_dehydrogenase_1: $i > $o).
% 29.22/29.02  tff(decl_34515, type, fn_energy_payoff_phase_of_glycolysis_63: $i > $i).
% 29.22/29.02  tff(decl_34516, type, fn_energy_payoff_phase_of_glycolysis_64: $i > $i).
% 29.22/29.02  tff(decl_34517, type, fn_energy_payoff_phase_of_glycolysis_65: $i > $i).
% 29.22/29.02  tff(decl_34518, type, fn_energy_payoff_phase_of_glycolysis_66: $i > $i).
% 29.22/29.02  tff(decl_34519, type, fn_energy_payoff_phase_of_glycolysis_67: $i > $i).
% 29.22/29.02  tff(decl_34520, type, fn_energy_payoff_phase_of_glycolysis_68: $i > $i).
% 29.22/29.02  tff(decl_34521, type, fn_energy_payoff_phase_of_glycolysis_69: $i > $i).
% 29.22/29.02  tff(decl_34522, type, fn_energy_payoff_phase_of_glycolysis_70: $i > $i).
% 29.22/29.02  tff(decl_34523, type, fn_energy_payoff_phase_of_glycolysis_71: $i > $i).
% 29.22/29.02  tff(decl_34524, type, fn_energy_payoff_phase_of_glycolysis_72: $i > $i).
% 29.22/29.02  tff(decl_34525, type, fn_energy_payoff_phase_of_glycolysis_73: $i > $i).
% 29.22/29.02  tff(decl_34526, type, fn_energy_payoff_phase_of_glycolysis_74: $i > $i).
% 29.22/29.02  tff(decl_34527, type, fn_energy_payoff_phase_of_glycolysis_75: $i > $i).
% 29.22/29.02  tff(decl_34528, type, fn_energy_payoff_phase_of_glycolysis_76: $i > $i).
% 29.22/29.02  tff(decl_34529, type, fn_energy_payoff_phase_of_glycolysis_81: $i > $i).
% 29.22/29.02  tff(decl_34530, type, fn_energy_payoff_phase_of_glycolysis_82: $i > $i).
% 29.22/29.02  tff(decl_34531, type, fn_energy_payoff_phase_of_glycolysis_83: $i > $i).
% 29.22/29.02  tff(decl_34532, type, fn_energy_payoff_phase_of_glycolysis_84: $i > $i).
% 29.22/29.02  tff(decl_34533, type, fn_energy_payoff_phase_of_glycolysis_85: $i > $i).
% 29.22/29.02  tff(decl_34534, type, fn_energy_payoff_phase_of_glycolysis_86: $i > $i).
% 29.22/29.02  tff(decl_34535, type, fn_energy_payoff_phase_of_glycolysis_87: $i > $i).
% 29.22/29.02  tff(decl_34536, type, fn_energy_payoff_phase_of_glycolysis_88: $i > $i).
% 29.22/29.02  tff(decl_34537, type, fn_energy_payoff_phase_of_glycolysis_89: $i > $i).
% 29.22/29.02  tff(decl_34538, type, fn_energy_payoff_phase_of_glycolysis_90: $i > $i).
% 29.22/29.02  tff(decl_34539, type, fn_energy_payoff_phase_of_glycolysis_91: $i > $i).
% 29.22/29.02  tff(decl_34540, type, fn_energy_payoff_phase_of_glycolysis_92: $i > $i).
% 29.22/29.02  tff(decl_34541, type, fn_energy_payoff_phase_of_glycolysis_93: $i > $i).
% 29.22/29.02  tff(decl_34542, type, fn_energy_payoff_phase_of_glycolysis_94: $i > $i).
% 29.22/29.02  tff(decl_34543, type, fn_energy_payoff_phase_of_glycolysis_95: $i > $i).
% 29.22/29.02  tff(decl_34544, type, fn_energy_payoff_phase_of_glycolysis_96: $i > $i).
% 29.22/29.02  tff(decl_34545, type, fn_energy_payoff_phase_of_glycolysis_97: $i > $i).
% 29.22/29.02  tff(decl_34546, type, fn_energy_payoff_phase_of_glycolysis_98: $i > $i).
% 29.22/29.02  tff(decl_34547, type, fn_energy_payoff_phase_of_glycolysis_99: $i > $i).
% 29.22/29.02  tff(decl_34548, type, fn_energy_payoff_phase_of_glycolysis_104: $i > $i).
% 29.22/29.02  tff(decl_34549, type, fn_pyruvate_kinase_9: $i > $i).
% 29.22/29.02  tff(decl_34550, type, fn_phosphoglyceromutase_1: $i > $i).
% 29.22/29.02  tff(decl_34551, type, fn_synthesis_of_atp_11: $i > $i).
% 29.22/29.02  tff(decl_34552, type, fn_synthesis_of_atp_12: $i > $i).
% 29.22/29.02  tff(decl_34553, type, fn_substrate_level_phosphorylation_17: $i > $i).
% 29.22/29.02  tff(decl_34554, type, fn_substrate_level_phosphorylation_18: $i > $i).
% 29.22/29.02  tff(decl_34555, type, fn_substrate_level_phosphorylation_12: $i > $i).
% 29.22/29.02  tff(decl_34556, type, fn_substrate_level_phosphorylation_13: $i > $i).
% 29.22/29.02  tff(decl_34557, type, fn_substrate_level_phosphorylation_14: $i > $i).
% 29.22/29.02  tff(decl_34558, type, fn_nad_plus_18: $i > $i).
% 29.22/29.02  tff(decl_34559, type, fn_triose_phosphate_dehydrogenase_2: $i > $i).
% 29.22/29.02  tff(decl_34560, type, fn_triose_phosphate_dehydrogenase_1: $i > $i).
% 29.22/29.02  tff(decl_34561, type, fn_triose_phosphate_dehydrogenase_10: $i > $i).
% 29.22/29.02  tff(decl_34562, type, fn_triose_phosphate_dehydrogenase_5: $i > $i).
% 29.22/29.02  tff(decl_34563, type, fn_triose_phosphate_dehydrogenase_9: $i > $i).
% 29.22/29.02  tff(decl_34564, type, fn_substrate_level_phosphorylation_4: $i > $i).
% 29.22/29.02  tff(decl_34565, type, fn_triose_phosphate_dehydrogenase_7: $i > $i).
% 29.22/29.02  tff(decl_34566, type, fn_substrate_level_phosphorylation_20: $i > $i).
% 29.22/29.02  tff(decl_34567, type, fn_substrate_level_phosphorylation_7: $i > $i).
% 29.22/29.02  tff(decl_34568, type, fn_substrate_level_phosphorylation_10: $i > $i).
% 29.22/29.02  tff(decl_34569, type, fn_substrate_level_phosphorylation_1: $i > $i).
% 29.22/29.02  tff(decl_34570, type, fn_substrate_level_phosphorylation_8: $i > $i).
% 29.22/29.02  tff(decl_34571, type, fn_substrate_level_phosphorylation_9: $i > $i).
% 29.22/29.02  tff(decl_34572, type, fn_substrate_level_phosphorylation_11: $i > $i).
% 29.22/29.02  tff(decl_34573, type, fn_substrate_level_phosphorylation_2: $i > $i).
% 29.22/29.02  tff(decl_34574, type, fn_substrate_level_phosphorylation_3: $i > $i).
% 29.22/29.02  tff(decl_34575, type, fn_triose_phosphate_dehydrogenase_6: $i > $i).
% 29.22/29.02  tff(decl_34576, type, fn_triose_phosphate_dehydrogenase_13: $i > $i).
% 29.22/29.02  tff(decl_34577, type, fn_triose_phosphate_dehydrogenase_4: $i > $i).
% 29.22/29.02  tff(decl_34578, type, fn_triose_phosphate_dehydrogenase_3: $i > $i).
% 29.22/29.02  tff(decl_34579, type, "-38.1e0": $i).
% 29.22/29.02  tff(decl_34580, type, two_phosphoglycerate_0: $i).
% 29.22/29.02  tff(decl_34581, type, pyruvate_0: $i).
% 29.22/29.02  tff(decl_34582, type, phosphate_ion_0: $i).
% 29.22/29.02  tff(decl_34583, type, phosphoenolpyruvate_0: $i).
% 29.22/29.02  tff(decl_34584, type, three_phosphoglycerate_0: $i).
% 29.22/29.02  tff(decl_34585, type, "-18.9e0": $i).
% 29.22/29.02  tff(decl_34586, type, "4.4e0": $i).
% 29.22/29.02  tff(decl_34587, type, fn_energy_payoff_phase_of_glycolysis_8: $i > $i).
% 29.22/29.02  tff(decl_34588, type, fn_energy_payoff_phase_of_glycolysis_7: $i > $i).
% 29.22/29.02  tff(decl_34589, type, fn_energy_payoff_phase_of_glycolysis_58: $i > $i).
% 29.22/29.02  tff(decl_34590, type, fn_energy_payoff_phase_of_glycolysis_55: $i > $i).
% 29.22/29.02  tff(decl_34591, type, fn_energy_payoff_phase_of_glycolysis_100: $i > $i).
% 29.22/29.02  tff(decl_34592, type, fn_energy_payoff_phase_of_glycolysis_101: $i > $i).
% 29.22/29.02  tff(decl_34593, type, fn_energy_payoff_phase_of_glycolysis_102: $i > $i).
% 29.22/29.02  tff(decl_34594, type, fn_energy_payoff_phase_of_glycolysis_103: $i > $i).
% 29.22/29.02  tff(decl_34595, type, fn_energy_payoff_phase_of_glycolysis_79: $i > $i).
% 29.22/29.02  tff(decl_34596, type, fn_energy_payoff_phase_of_glycolysis_80: $i > $i).
% 29.22/29.02  tff(decl_34597, type, fn_energy_payoff_phase_of_glycolysis_19: $i > $i).
% 29.22/29.02  tff(decl_34598, type, fn_energy_payoff_phase_of_glycolysis_18: $i > $i).
% 29.22/29.02  tff(decl_34599, type, fn_energy_payoff_phase_of_glycolysis_77: $i > $i).
% 29.22/29.02  tff(decl_34600, type, fn_energy_payoff_phase_of_glycolysis_78: $i > $i).
% 29.22/29.02  tff(decl_34601, type, energy_polarity_scale_1: $i > $o).
% 29.22/29.02  tff(decl_34602, type, 'Energy-Polarity-Scale': $i).
% 29.22/29.02  tff(decl_34603, type, 'energy polarity scale': $i).
% 29.22/29.02  tff(decl_34604, type, 'energy-polarity-scale': $i).
% 29.22/29.02  tff(decl_34605, type, 'Energy-Reaction': $i).
% 29.22/29.02  tff(decl_34606, type, 'A reaction that describes changes in energy.': $i).
% 29.22/29.02  tff(decl_34607, type, 'reaction of energy': $i).
% 29.22/29.02  tff(decl_34608, type, 'energy reaction': $i).
% 29.22/29.02  tff(decl_34609, type, 'energy-reaction': $i).
% 29.22/29.02  tff(decl_34610, type, 'Energy-Related-Process': $i).
% 29.22/29.02  tff(decl_34611, type, 'A process related to the movement or exchange of energy or heat.': $i).
% 29.22/29.02  tff(decl_34612, type, 'energy related process': $i).
% 29.22/29.02  tff(decl_34613, type, 'energy-related-process': $i).
% 29.22/29.02  tff(decl_34614, type, 'Energy-Source': $i).
% 29.22/29.02  tff(decl_34615, type, 'The source of energy for the life processes of an organism.': $i).
% 29.22/29.02  tff(decl_34616, type, 'source of energy': $i).
% 29.22/29.02  tff(decl_34617, type, 'energy source': $i).
% 29.22/29.02  tff(decl_34618, type, 'energy-source': $i).
% 29.22/29.02  tff(decl_34619, type, 'Energy-Transformation-by-Organism': $i).
% 29.22/29.02  tff(decl_34620, type, 'It is the process of transformation of energy by an organism.': $i).
% 29.22/29.02  tff(decl_34621, type, transform: $i).
% 29.22/29.02  tff(decl_34622, type, 'energy transformation by organism': $i).
% 29.22/29.02  tff(decl_34623, type, 'energy-transformation-by-organism': $i).
% 29.22/29.02  tff(decl_34624, type, engelmanns_experiment_1: $i > $o).
% 29.22/29.02  tff(decl_34625, type, 'Engelmanns-Experiment': $i).
% 29.22/29.02  tff(decl_34626, type, 'Experiment conductied by Theodor W. Englemann which helped reveal which wavelengths of light are photosynthetically important.': $i).
% 29.22/29.02  tff(decl_34627, type, 'engelmann\\s experiment': $i).
% 29.22/29.02  tff(decl_34628, type, 'engelmanns experiment': $i).
% 29.22/29.02  tff(decl_34629, type, 'engelmanns-experiment': $i).
% 29.22/29.02  tff(decl_34630, type, fn_engelmanns_experiment_5: $i > $i).
% 29.22/29.02  tff(decl_34631, type, fn_engelmanns_experiment_6: $i > $i).
% 29.22/29.02  tff(decl_34632, type, fn_engelmanns_experiment_7: $i > $i).
% 29.22/29.02  tff(decl_34633, type, fn_engelmanns_experiment_8: $i > $i).
% 29.22/29.02  tff(decl_34634, type, fn_engelmanns_experiment_9: $i > $i).
% 29.22/29.02  tff(decl_34635, type, fn_engelmanns_experiment_10: $i > $i).
% 29.22/29.02  tff(decl_34636, type, fn_engelmanns_experiment_11: $i > $i).
% 29.22/29.02  tff(decl_34637, type, fn_engelmanns_experiment_12: $i > $i).
% 29.22/29.02  tff(decl_34638, type, fn_engelmanns_experiment_13: $i > $i).
% 29.22/29.02  tff(decl_34639, type, fn_engelmanns_experiment_14: $i > $i).
% 29.22/29.02  tff(decl_34640, type, fn_engelmanns_experiment_15: $i > $i).
% 29.22/29.02  tff(decl_34641, type, fn_engelmanns_experiment_16: $i > $i).
% 29.22/29.02  tff(decl_34642, type, fn_engelmanns_experiment_17: $i > $i).
% 29.22/29.02  tff(decl_34643, type, fn_engelmanns_experiment_18: $i > $i).
% 29.22/29.02  tff(decl_34644, type, fn_engelmanns_experiment_19: $i > $i).
% 29.22/29.02  tff(decl_34645, type, prism_1: $i > $o).
% 29.22/29.02  tff(decl_34646, type, fn_engelmanns_experiment_20: $i > $i).
% 29.22/29.02  tff(decl_34647, type, fn_engelmanns_experiment_21: $i > $i).
% 29.22/29.02  tff(decl_34648, type, spectrophotometry_1: $i > $o).
% 29.22/29.02  tff(decl_34649, type, fn_engelmanns_experiment_22: $i > $i).
% 29.22/29.02  tff(decl_34650, type, fn_engelmanns_experiment_23: $i > $i).
% 29.22/29.02  tff(decl_34651, type, fn_engelmanns_experiment_24: $i > $i).
% 29.22/29.02  tff(decl_34652, type, fn_engelmanns_experiment_25: $i > $i).
% 29.22/29.02  tff(decl_34653, type, fn_engelmanns_experiment_26: $i > $i).
% 29.22/29.02  tff(decl_34654, type, fn_engelmanns_experiment_27: $i > $i).
% 29.22/29.02  tff(decl_34655, type, fn_engelmanns_experiment_28: $i > $i).
% 29.22/29.02  tff(decl_34656, type, fn_engelmanns_experiment_29: $i > $i).
% 29.22/29.02  tff(decl_34657, type, fn_engelmanns_experiment_30: $i > $i).
% 29.22/29.02  tff(decl_34658, type, fn_engelmanns_experiment_31: $i > $i).
% 29.22/29.02  tff(decl_34659, type, fn_engelmanns_experiment_32: $i > $i).
% 29.22/29.02  tff(decl_34660, type, fn_engelmanns_experiment_33: $i > $i).
% 29.22/29.02  tff(decl_34661, type, fn_engelmanns_experiment_34: $i > $i).
% 29.22/29.02  tff(decl_34662, type, fn_engelmanns_experiment_35: $i > $i).
% 29.22/29.02  tff(decl_34663, type, fn_engelmanns_experiment_36: $i > $i).
% 29.22/29.02  tff(decl_34664, type, fn_engelmanns_experiment_37: $i > $i).
% 29.22/29.02  tff(decl_34665, type, fn_engelmanns_experiment_38: $i > $i).
% 29.22/29.02  tff(decl_34666, type, fn_engelmanns_experiment_39: $i > $i).
% 29.22/29.02  tff(decl_34667, type, fn_engelmanns_experiment_40: $i > $i).
% 29.22/29.02  tff(decl_34668, type, fn_engelmanns_experiment_41: $i > $i).
% 29.22/29.02  tff(decl_34669, type, fn_engelmanns_experiment_42: $i > $i).
% 29.22/29.02  tff(decl_34670, type, fn_engelmanns_experiment_43: $i > $i).
% 29.22/29.02  tff(decl_34671, type, 'Engineering': $i).
% 29.22/29.02  tff(decl_34672, type, technology: $i).
% 29.22/29.02  tff(decl_34673, type, application: $i).
% 29.22/29.02  tff(decl_34674, type, profession: $i).
% 29.22/29.02  tff(decl_34675, type, engineer: $i).
% 29.22/29.02  tff(decl_34676, type, engineering: $i).
% 29.22/29.02  tff(decl_34677, type, 'Enhancer': $i).
% 29.22/29.02  tff(decl_34678, type, 'A segment of eukaryotic DNA containing multiple control elements, usually located far from the gene whose transcription it regulates.': $i).
% 29.22/29.02  tff(decl_34679, type, enhancer: $i).
% 29.22/29.02  tff(decl_34680, type, proximal_control_element_1: $i > $o).
% 29.22/29.02  tff(decl_34681, type, fn_enhancer_1: $i > $i).
% 29.22/29.02  tff(decl_34682, type, fn_enhancer_2: $i > $i).
% 29.22/29.02  tff(decl_34683, type, fn_enhancer_3: $i > $i).
% 29.22/29.02  tff(decl_34684, type, fn_enhancer_4: $i > $i).
% 29.22/29.02  tff(decl_34685, type, fn_enhancer_5: $i > $i).
% 29.22/29.02  tff(decl_34686, type, fn_enhancer_6: $i > $i).
% 29.22/29.02  tff(decl_34687, type, fn_enhancer_7: $i > $i).
% 29.22/29.02  tff(decl_34688, type, fn_enhancer_8: $i > $i).
% 29.22/29.02  tff(decl_34689, type, fn_enhancer_9: $i > $i).
% 29.22/29.02  tff(decl_34690, type, fn_enhancer_10: $i > $i).
% 29.22/29.02  tff(decl_34691, type, fn_enhancer_11: $i > $i).
% 29.22/29.02  tff(decl_34692, type, fn_enhancer_12: $i > $i).
% 29.22/29.02  tff(decl_34693, type, fn_enhancer_13: $i > $i).
% 29.22/29.02  tff(decl_34694, type, fn_enhancer_14: $i > $i).
% 29.22/29.02  tff(decl_34695, type, fn_intron_6: $i > $i).
% 29.22/29.02  tff(decl_34696, type, 'Enolase': $i).
% 29.22/29.02  tff(decl_34697, type, 'An enzyme that removes a molecule of water from 2-phosphoglyceric acid to form phosphoenolpyruvic acid (PEP).': $i).
% 29.22/29.02  tff(decl_34698, type, 'phosphopyruvate dehydratase': $i).
% 29.22/29.02  tff(decl_34699, type, 'phosphopyruvate-dehydratase': $i).
% 29.22/29.02  tff(decl_34700, type, enolase: $i).
% 29.22/29.02  tff(decl_34701, type, fn_enolase_1: $i > $i).
% 29.22/29.02  tff(decl_34702, type, fn_enolase_2: $i > $i).
% 29.22/29.02  tff(decl_34703, type, fn_enolase_3: $i > $i).
% 29.22/29.02  tff(decl_34704, type, fn_enolase_4: $i > $i).
% 29.22/29.02  tff(decl_34705, type, fn_enolase_5: $i > $i).
% 29.22/29.02  tff(decl_34706, type, fn_enolase_6: $i > $i).
% 29.22/29.02  tff(decl_34707, type, fn_enolase_7: $i > $i).
% 29.22/29.02  tff(decl_34708, type, fn_enolase_8: $i > $i).
% 29.22/29.02  tff(decl_34709, type, fn_enolase_9: $i > $i).
% 29.22/29.02  tff(decl_34710, type, fn_enolase_10: $i > $i).
% 29.22/29.02  tff(decl_34711, type, fn_enolase_11: $i > $i).
% 29.22/29.02  tff(decl_34712, type, fn_enolase_12: $i > $i).
% 29.22/29.02  tff(decl_34713, type, fn_enolase_13: $i > $i).
% 29.22/29.02  tff(decl_34714, type, fn_enolase_14: $i > $i).
% 29.22/29.02  tff(decl_34715, type, fn_enolase_15: $i > $i).
% 29.22/29.02  tff(decl_34716, type, fn_enolase_16: $i > $i).
% 29.22/29.02  tff(decl_34717, type, fn_enolase_17: $i > $i).
% 29.22/29.02  tff(decl_34718, type, fn_enolase_18: $i > $i).
% 29.22/29.02  tff(decl_34719, type, fn_enolase_19: $i > $i).
% 29.22/29.02  tff(decl_34720, type, fn_enolase_20: $i > $i).
% 29.22/29.02  tff(decl_34721, type, 'Ensemble': $i).
% 29.22/29.02  tff(decl_34722, type, 'A collection of distinct structures which function together to carry out some task, as the respiratory enzyme complex on mitochondrial membranes.': $i).
% 29.22/29.02  tff(decl_34723, type, ensemble: $i).
% 29.22/29.02  tff(decl_34724, type, 'tout ensemble': $i).
% 29.22/29.02  tff(decl_34725, type, tout_ensemble: $i).
% 29.22/29.02  tff(decl_34726, type, 'Enter': $i).
% 29.22/29.02  tff(decl_34727, type, 'move into': $i).
% 29.22/29.02  tff(decl_34728, type, 'go into': $i).
% 29.22/29.02  tff(decl_34729, type, 'go in': $i).
% 29.22/29.02  tff(decl_34730, type, 'get into': $i).
% 29.22/29.02  tff(decl_34731, type, 'come in': $i).
% 29.22/29.02  tff(decl_34732, type, enter: $i).
% 29.22/29.02  tff(decl_34733, type, come_in: $i).
% 29.22/29.02  tff(decl_34734, type, get_into: $i).
% 29.22/29.02  tff(decl_34735, type, go_into: $i).
% 29.22/29.02  tff(decl_34736, type, go_in: $i).
% 29.22/29.02  tff(decl_34737, type, move_into: $i).
% 29.22/29.02  tff(decl_34738, type, 'Enteric-Division': $i).
% 29.22/29.02  tff(decl_34739, type, 'System of neurons in the digestive tract, including the gallbladder and panceas. It is regulated by the parasympathetic and sympathetic division of the autonomic nervous system.': $i).
% 29.22/29.02  tff(decl_34740, type, 'enteric division': $i).
% 29.22/29.02  tff(decl_34741, type, 'enteric-division': $i).
% 29.22/29.02  tff(decl_34742, type, enterogastrone_1: $i > $o).
% 29.22/29.02  tff(decl_34743, type, 'Enterogastrone': $i).
% 29.22/29.02  tff(decl_34744, type, 'A class of gastrointestinal hormones released from the duodenum in response to the presence of lipids.  Includes CCK and secretin.': $i).
% 29.22/29.02  tff(decl_34745, type, enterogastrone: $i).
% 29.22/29.02  tff(decl_34746, type, enteropeptidase_1: $i > $o).
% 29.22/29.02  tff(decl_34747, type, 'Enteropeptidase': $i).
% 29.22/29.02  tff(decl_34748, type, 'An intestinal enzyme that directly or indirectly triggers activation of digestive enzymes within the intestinal lumen.': $i).
% 29.22/29.02  tff(decl_34749, type, enterokinase: $i).
% 29.22/29.02  tff(decl_34750, type, enteropeptidase: $i).
% 29.22/29.02  tff(decl_34751, type, fn_enteropeptidase_1: $i > $i).
% 29.22/29.02  tff(decl_34752, type, 'Entity': $i).
% 29.22/29.02  tff(decl_34753, type, part: $i).
% 29.22/29.02  tff(decl_34754, type, value: $i).
% 29.22/29.02  tff(decl_34755, type, 'user equation expression': $i).
% 29.22/29.02  tff(decl_34756, type, 'user-equation-expression': $i).
% 29.22/29.02  tff(decl_34757, type, resultant_role: $i).
% 29.22/29.02  tff(decl_34758, type, 'resultant role': $i).
% 29.22/29.02  tff(decl_34759, type, 'recycled during': $i).
% 29.22/29.02  tff(decl_34760, type, 'recycled-during': $i).
% 29.22/29.02  tff(decl_34761, type, recipient_role: $i).
% 29.22/29.02  tff(decl_34762, type, 'recipient role': $i).
% 29.22/29.02  tff(decl_34763, type, recipient: $i).
% 29.22/29.02  tff(decl_34764, type, 'previous element': $i).
% 29.22/29.02  tff(decl_34765, type, participant: $i).
% 29.22/29.02  tff(decl_34766, type, affected_role: $i).
% 29.22/29.02  tff(decl_34767, type, patient_role: $i).
% 29.22/29.02  tff(decl_34768, type, 'affected role': $i).
% 29.22/29.02  tff(decl_34769, type, 'patient role': $i).
% 29.22/29.02  tff(decl_34770, type, 'next element': $i).
% 29.22/29.02  tff(decl_34771, type, 'next-element': $i).
% 29.22/29.02  tff(decl_34772, type, instrumental_role: $i).
% 29.22/29.02  tff(decl_34773, type, 'instrumental role': $i).
% 29.22/29.02  tff(decl_34774, type, tool: $i).
% 29.22/29.02  tff(decl_34775, type, instrument: $i).
% 29.22/29.02  tff(decl_34776, type, 'has structure': $i).
% 29.22/29.02  tff(decl_34777, type, 'has-structure': $i).
% 29.22/29.02  tff(decl_34778, type, 'element of first': $i).
% 29.22/29.02  tff(decl_34779, type, 'first element': $i).
% 29.22/29.02  tff(decl_34780, type, 'first-element': $i).
% 29.22/29.02  tff(decl_34781, type, experiencer: $i).
% 29.22/29.02  tff(decl_34782, type, 'equation use': $i).
% 29.22/29.02  tff(decl_34783, type, 'equation-use': $i).
% 29.22/29.02  tff(decl_34784, type, 'symbol of equation': $i).
% 29.22/29.02  tff(decl_34785, type, 'equation symbol': $i).
% 29.22/29.02  tff(decl_34786, type, 'equation-symbol': $i).
% 29.22/29.02  tff(decl_34787, type, 'expression of equation': $i).
% 29.22/29.02  tff(decl_34788, type, 'equation expression': $i).
% 29.22/29.02  tff(decl_34789, type, 'equation-expression': $i).
% 29.22/29.02  tff(decl_34790, type, 'base object': $i).
% 29.22/29.02  tff(decl_34791, type, agentive_role: $i).
% 29.22/29.02  tff(decl_34792, type, 'agentive role': $i).
% 29.22/29.02  tff(decl_34793, type, actor: $i).
% 29.22/29.02  tff(decl_34794, type, doer: $i).
% 29.22/29.02  tff(decl_34795, type, worker: $i).
% 29.22/29.02  tff(decl_34796, type, object: $i).
% 29.22/29.02  tff(decl_34797, type, entity: $i).
% 29.22/29.02  tff(decl_34798, type, entityproperty_1: $i > $o).
% 29.22/29.02  tff(decl_34799, type, 'EntityProperty': $i).
% 29.22/29.02  tff(decl_34800, type, entityproperty: $i).
% 29.22/29.02  tff(decl_34801, type, property_1: $i > $o).
% 29.22/29.02  tff(decl_34802, type, entrance_1: $i > $o).
% 29.22/29.02  tff(decl_34803, type, 'Entrance': $i).
% 29.22/29.02  tff(decl_34804, type, entrance: $i).
% 29.22/29.02  tff(decl_34805, type, entranceway: $i).
% 29.22/29.02  tff(decl_34806, type, entryway: $i).
% 29.22/29.02  tff(decl_34807, type, entry: $i).
% 29.22/29.02  tff(decl_34808, type, entree: $i).
% 29.22/29.02  tff(decl_34809, type, outlet_1: $i > $o).
% 29.22/29.02  tff(decl_34810, type, entry_of_arsenic_in_groundwater_1: $i > $o).
% 29.22/29.02  tff(decl_34811, type, 'Entry-Of-Arsenic-In-Groundwater': $i).
% 29.22/29.02  tff(decl_34812, type, 'Contamination of groundwater due to naturally occurring high concentrations of arsenic in deep wells.': $i).
% 29.22/29.02  tff(decl_34813, type, 'entry of arsenic in groundwater': $i).
% 29.22/29.02  tff(decl_34814, type, 'entry-of-arsenic-in-groundwater': $i).
% 29.22/29.02  tff(decl_34815, type, fn_entry_of_arsenic_in_groundwater_1: $i > $i).
% 29.22/29.02  tff(decl_34816, type, fn_entry_of_arsenic_in_groundwater_2: $i > $i).
% 29.22/29.02  tff(decl_34817, type, fn_entry_of_arsenic_in_groundwater_3: $i > $i).
% 29.22/29.02  tff(decl_34818, type, groundwater_1: $i > $o).
% 29.22/29.02  tff(decl_34819, type, fn_entry_of_arsenic_in_groundwater_4: $i > $i).
% 29.22/29.02  tff(decl_34820, type, entry_of_glucose_in_liver_cell_1: $i > $o).
% 29.22/29.02  tff(decl_34821, type, 'Entry-Of-Glucose-In-Liver-Cell': $i).
% 29.22/29.02  tff(decl_34822, type, 'Glucose carried in blood to the human liver enters liver cells rapidly through specific transport proteins in the plasma membrane.': $i).
% 29.22/29.02  tff(decl_34823, type, 'entry of glucose in liver cell': $i).
% 29.22/29.02  tff(decl_34824, type, 'entry-of-glucose-in-liver-cell': $i).
% 29.22/29.02  tff(decl_34825, type, fn_entry_of_glucose_in_liver_cell_1: $i > $i).
% 29.22/29.02  tff(decl_34826, type, fn_entry_of_glucose_in_liver_cell_2: $i > $i).
% 29.22/29.02  tff(decl_34827, type, fn_entry_of_glucose_in_liver_cell_3: $i > $i).
% 29.22/29.02  tff(decl_34828, type, fn_entry_of_glucose_in_liver_cell_4: $i > $i).
% 29.22/29.02  tff(decl_34829, type, fn_entry_of_glucose_in_liver_cell_5: $i > $i).
% 29.22/29.02  tff(decl_34830, type, fn_entry_of_glucose_in_liver_cell_6: $i > $i).
% 29.22/29.02  tff(decl_34831, type, fn_entry_of_glucose_in_liver_cell_7: $i > $i).
% 29.22/29.02  tff(decl_34832, type, fn_entry_of_glucose_in_liver_cell_8: $i > $i).
% 29.22/29.02  tff(decl_34833, type, fn_entry_of_glucose_in_liver_cell_9: $i > $i).
% 29.22/29.02  tff(decl_34834, type, 'Enucleated-Cell': $i).
% 29.22/29.02  tff(decl_34835, type, 'An enucleated cell is a cell where the nucleus, and thus all genetic information, has been removed.': $i).
% 29.22/29.02  tff(decl_34836, type, 'enucleated cell': $i).
% 29.22/29.02  tff(decl_34837, type, 'enucleated-cell': $i).
% 29.22/29.02  tff(decl_34838, type, fn_enucleated_cell_1: $i > $i).
% 29.22/29.02  tff(decl_34839, type, fn_enucleated_cell_2: $i > $i).
% 29.22/29.02  tff(decl_34840, type, 'Environment': $i).
% 29.22/29.02  tff(decl_34841, type, 'All living and nonliving things that occur naturally on the Earth or in some region of the Earth.': $i).
% 29.22/29.02  tff(decl_34842, type, surrounding: $i).
% 29.22/29.02  tff(decl_34843, type, environment: $i).
% 29.22/29.02  tff(decl_34844, type, 'Enzymatic-Reaction': $i).
% 29.22/29.02  tff(decl_34845, type, 'A chemical reaction that is catalyzed by an enzyme.': $i).
% 29.22/29.02  tff(decl_34846, type, 'enzymatic reaction': $i).
% 29.22/29.02  tff(decl_34847, type, 'enzymatic-reaction': $i).
% 29.22/29.02  tff(decl_34848, type, fn_enzymatic_reaction_3: $i > $i).
% 29.22/29.02  tff(decl_34849, type, fn_enzymatic_reaction_4: $i > $i).
% 29.22/29.02  tff(decl_34850, type, fn_enzymatic_reaction_5: $i > $i).
% 29.22/29.02  tff(decl_34851, type, fn_enzymatic_reaction_7: $i > $i).
% 29.22/29.02  tff(decl_34852, type, fn_enzymatic_reaction_8: $i > $i).
% 29.22/29.02  tff(decl_34853, type, fn_enzymatic_reaction_9: $i > $i).
% 29.22/29.02  tff(decl_34854, type, fn_enzymatic_reaction_10: $i > $i).
% 29.22/29.02  tff(decl_34855, type, fn_enzymatic_reaction_11: $i > $i).
% 29.22/29.02  tff(decl_34856, type, enzyme_substrate_complex_1: $i > $o).
% 29.22/29.02  tff(decl_34857, type, fn_enzymatic_reaction_12: $i > $i).
% 29.22/29.02  tff(decl_34858, type, fn_enzymatic_reaction_13: $i > $i).
% 29.22/29.02  tff(decl_34859, type, fn_enzymatic_reaction_14: $i > $i).
% 29.22/29.02  tff(decl_34860, type, fn_enzymatic_reaction_15: $i > $i).
% 29.22/29.02  tff(decl_34861, type, fn_enzymatic_reaction_16: $i > $i).
% 29.22/29.02  tff(decl_34862, type, fn_enzymatic_reaction_17: $i > $i).
% 29.22/29.02  tff(decl_34863, type, fn_enzyme_substrate_complex_2: $i > $i).
% 29.22/29.02  tff(decl_34864, type, fn_enzyme_substrate_complex_9: $i > $i).
% 29.22/29.02  tff(decl_34865, type, 'Enzyme': $i).
% 29.22/29.02  tff(decl_34866, type, 'An enzyme is a macromolecule that acts as a catalyst, a chemical agent that speeds up a reaction without being consumed by the reaction.': $i).
% 29.22/29.02  tff(decl_34867, type, enzymes: $i).
% 29.22/29.02  tff(decl_34868, type, enzyme: $i).
% 29.22/29.02  tff(decl_34869, type, fn_enzyme_1: $i > $i).
% 29.22/29.02  tff(decl_34870, type, fn_enzyme_9: $i > $i).
% 29.22/29.02  tff(decl_34871, type, fn_enzyme_3: $i > $i).
% 29.22/29.02  tff(decl_34872, type, enzyme_activator_1: $i > $o).
% 29.22/29.02  tff(decl_34873, type, 'Enzyme-Activator': $i).
% 29.22/29.02  tff(decl_34874, type, 'Enzyme activators are molecules that bind to enzymes and increase their activity. These molecules are often involved in the allosteric regulation of enzymes in the control of metabolism.': $i).
% 29.22/29.02  tff(decl_34875, type, 'activator of enzyme': $i).
% 29.22/29.02  tff(decl_34876, type, 'enzyme activator': $i).
% 29.22/29.02  tff(decl_34877, type, 'enzyme-activator': $i).
% 29.22/29.02  tff(decl_34878, type, enzyme_regulator_1: $i > $o).
% 29.22/29.02  tff(decl_34879, type, fn_enzyme_activator_1: $i > $i).
% 29.22/29.02  tff(decl_34880, type, fn_enzyme_activator_2: $i > $i).
% 29.22/29.02  tff(decl_34881, type, fn_enzyme_activator_3: $i > $i).
% 29.22/29.02  tff(decl_34882, type, fn_enzyme_activator_4: $i > $i).
% 29.22/29.02  tff(decl_34883, type, fn_enzyme_activator_5: $i > $i).
% 29.22/29.02  tff(decl_34884, type, fn_enzyme_activator_6: $i > $i).
% 29.22/29.02  tff(decl_34885, type, fn_enzyme_activator_7: $i > $i).
% 29.22/29.02  tff(decl_34886, type, enzyme_complement_1: $i > $o).
% 29.22/29.02  tff(decl_34887, type, 'Enzyme-Complement': $i).
% 29.22/29.02  tff(decl_34888, type, 'It refers to complementation of a small fragment of enzyme to inactive/mutant enzyme forming a stable heteromeric enzyme complex.': $i).
% 29.22/29.02  tff(decl_34889, type, 'complement of enzyme': $i).
% 29.22/29.02  tff(decl_34890, type, 'enzyme complement': $i).
% 29.22/29.02  tff(decl_34891, type, 'enzyme-complement': $i).
% 29.22/29.02  tff(decl_34892, type, 'Enzyme-Inhibitor': $i).
% 29.22/29.02  tff(decl_34893, type, 'Enzyme inhibitors are molecules that bind to enzymes and decrease their activity.': $i).
% 29.22/29.02  tff(decl_34894, type, 'inhibitor of enzyme': $i).
% 29.22/29.02  tff(decl_34895, type, 'enzyme inhibitor': $i).
% 29.22/29.02  tff(decl_34896, type, 'enzyme-inhibitor': $i).
% 29.22/29.02  tff(decl_34897, type, inhibitor_1: $i > $o).
% 29.22/29.02  tff(decl_34898, type, fn_enzyme_inhibitor_4: $i > $i).
% 29.22/29.02  tff(decl_34899, type, fn_enzyme_regulator_1: $i > $i).
% 29.22/29.02  tff(decl_34900, type, fn_inhibitor_2: $i > $i).
% 29.22/29.02  tff(decl_34901, type, fn_inhibitor_3: $i > $i).
% 29.22/29.02  tff(decl_34902, type, 'Enzyme-Regulator': $i).
% 29.22/29.02  tff(decl_34903, type, 'A chemical compound which serves to regulate or control enzymatic activity.': $i).
% 29.22/29.02  tff(decl_34904, type, 'regulator of enzyme': $i).
% 29.22/29.02  tff(decl_34905, type, 'enzyme regulator': $i).
% 29.22/29.02  tff(decl_34906, type, 'enzyme-regulator': $i).
% 29.22/29.02  tff(decl_34907, type, 'Enzyme-Substrate-Complex': $i).
% 29.22/29.02  tff(decl_34908, type, 'The complex formed during a chemical reaction (involving only one substrate), when the substrate molecule binds to the active site of the particular enzyme': $i).
% 29.22/29.02  tff(decl_34909, type, 'enzyme substrate complex': $i).
% 29.22/29.02  tff(decl_34910, type, 'enzyme-substrate complex': $i).
% 29.22/29.02  tff(decl_34911, type, 'enzyme-substrate-complex': $i).
% 29.22/29.02  tff(decl_34912, type, protein_related_aggregates_1: $i > $o).
% 29.22/29.02  tff(decl_34913, type, fn_enzyme_substrate_complex_1: $i > $i).
% 29.22/29.02  tff(decl_34914, type, fn_enzyme_substrate_complex_3: $i > $i).
% 29.22/29.02  tff(decl_34915, type, fn_enzyme_substrate_complex_4: $i > $i).
% 29.22/29.02  tff(decl_34916, type, fn_enzyme_substrate_complex_5: $i > $i).
% 29.22/29.02  tff(decl_34917, type, fn_enzyme_substrate_complex_6: $i > $i).
% 29.22/29.02  tff(decl_34918, type, fn_enzyme_substrate_complex_7: $i > $i).
% 29.22/29.02  tff(decl_34919, type, fn_enzyme_substrate_complex_8: $i > $i).
% 29.22/29.02  tff(decl_34920, type, fn_enzyme_substrate_complex_10: $i > $i).
% 29.22/29.02  tff(decl_34921, type, fn_enzyme_substrate_complex_11: $i > $i).
% 29.22/29.02  tff(decl_34922, type, enzyme_synthesis_1: $i > $o).
% 29.22/29.02  tff(decl_34923, type, fn_enzyme_synthesis_2: $i > $i).
% 29.22/29.02  tff(decl_34924, type, 'Enzyme-Synthesis': $i).
% 29.22/29.02  tff(decl_34925, type, 'The formation of an enzyme, a biological catalyst which is a type of protein.': $i).
% 29.22/29.02  tff(decl_34926, type, synthesize: $i).
% 29.22/29.02  tff(decl_34927, type, 'synthesis of enzyme': $i).
% 29.22/29.02  tff(decl_34928, type, 'enzyme synthesis': $i).
% 29.22/29.02  tff(decl_34929, type, 'enzyme-synthesis': $i).
% 29.22/29.02  tff(decl_34930, type, synthesis_of_human_protein_in_bacteria_1: $i > $o).
% 29.22/29.02  tff(decl_34931, type, synthesis_of_insulin_1: $i > $o).
% 29.22/29.02  tff(decl_34932, type, 'Eosinophil': $i).
% 29.22/29.02  tff(decl_34933, type, 'A type of white blood cell with low phagocytic activity that is thought to play a role in defense against parasitic worms by releasing enzymes toxic to these invaders.': $i).
% 29.22/29.02  tff(decl_34934, type, eosinophil: $i).
% 29.22/29.02  tff(decl_34935, type, ephemeroptera_1: $i > $o).
% 29.22/29.02  tff(decl_34936, type, 'Ephemeroptera': $i).
% 29.22/29.02  tff(decl_34937, type, 'Order of the class Insecta having a short lifespan, aquatic larvae, and membranous wings.': $i).
% 29.22/29.02  tff(decl_34938, type, mayflies: $i).
% 29.22/29.02  tff(decl_34939, type, ephemeroptera: $i).
% 29.22/29.02  tff(decl_34940, type, epiblast_1: $i > $o).
% 29.22/29.02  tff(decl_34941, type, 'Epiblast': $i).
% 29.22/29.02  tff(decl_34942, type, 'Tissue type derived from the inner cell mass in mammals or the blastodisc in birds or reptiles.': $i).
% 29.22/29.02  tff(decl_34943, type, epiblast: $i).
% 29.22/29.02  tff(decl_34944, type, epicotyl_1: $i > $o).
% 29.22/29.02  tff(decl_34945, type, 'Epicotyl': $i).
% 29.22/29.02  tff(decl_34946, type, 'In an angiosperm, the region of the shoot above the cotyledon and below the first pair of leaves.': $i).
% 29.22/29.02  tff(decl_34947, type, epicotyl: $i).
% 29.22/29.02  tff(decl_34948, type, epidemic_1: $i > $o).
% 29.22/29.02  tff(decl_34949, type, 'Epidemic': $i).
% 29.22/29.02  tff(decl_34950, type, 'Occurrence of a human disease that is greater than expected based on recent experience.': $i).
% 29.22/29.02  tff(decl_34951, type, epidemic: $i).
% 29.22/29.02  tff(decl_34952, type, epidemiology_1: $i > $o).
% 29.22/29.02  tff(decl_34953, type, 'Epidemiology': $i).
% 29.22/29.02  tff(decl_34954, type, 'The study of human health and disease at the population level.': $i).
% 29.22/29.02  tff(decl_34955, type, epidemiology: $i).
% 29.22/29.02  tff(decl_34956, type, 'Epidermal-Cell': $i).
% 29.22/29.02  tff(decl_34957, type, 'Epidermal cells are cells that make up the epidermis.': $i).
% 29.22/29.02  tff(decl_34958, type, 'epidermal cell': $i).
% 29.22/29.02  tff(decl_34959, type, 'epidermal-cell': $i).
% 29.22/29.02  tff(decl_34960, type, epidermal_growth_factor_1: $i > $o).
% 29.22/29.02  tff(decl_34961, type, 'Epidermal-Growth-Factor': $i).
% 29.22/29.02  tff(decl_34962, type, 'A protein that stimulates epidermal development.': $i).
% 29.22/29.02  tff(decl_34963, type, egf: $i).
% 29.22/29.02  tff(decl_34964, type, 'epidermal growth factor': $i).
% 29.22/29.02  tff(decl_34965, type, 'epidermal growth-factor': $i).
% 29.22/29.02  tff(decl_34966, type, 'epidermal-growth-factor': $i).
% 29.22/29.02  tff(decl_34967, type, 'Epidermis': $i).
% 29.22/29.02  tff(decl_34968, type, 'The outermost layer of tightly packed cells in an animal or plant body. The epidermis forms a boundary between the internal and external environments.': $i).
% 29.22/29.02  tff(decl_34969, type, skin: $i).
% 29.22/29.02  tff(decl_34970, type, epidermis: $i).
% 29.22/29.02  tff(decl_34971, type, seminiferous_tubule_1: $i > $o).
% 29.22/29.02  tff(decl_34972, type, fn_epidermis_2: $i > $i).
% 29.22/29.02  tff(decl_34973, type, fn_epidermis_3: $i > $i).
% 29.22/29.02  tff(decl_34974, type, epididymis_1: $i > $o).
% 29.22/29.02  tff(decl_34975, type, 'Epididymis': $i).
% 29.22/29.02  tff(decl_34976, type, 'A coiled tubule in male amniotes that transfers sperm from the testis to the vas deferens. The epididymis is the site of sperm maturation.': $i).
% 29.22/29.02  tff(decl_34977, type, epididymis: $i).
% 29.22/29.02  tff(decl_34978, type, epigenesis_1: $i > $o).
% 29.22/29.02  tff(decl_34979, type, 'Epigenesis': $i).
% 29.22/29.02  tff(decl_34980, type, 'The theory that an individual is developed by successive differentiation of an unstructured egg rather than by a simple enlarging of a preformed entity.': $i).
% 29.22/29.02  tff(decl_34981, type, epigenesis: $i).
% 29.22/29.02  tff(decl_34982, type, theory_1: $i > $o).
% 29.22/29.02  tff(decl_34983, type, gradualism_theory_1: $i > $o).
% 29.22/29.02  tff(decl_34984, type, lamarcks_theory_of_evolution_1: $i > $o).
% 29.22/29.02  tff(decl_34985, type, epigenetic_inheritance_1: $i > $o).
% 29.22/29.02  tff(decl_34986, type, 'Epigenetic-Inheritance': $i).
% 29.22/29.02  tff(decl_34987, type, 'The inheritance of changes in gene expression or cellular-level phenotype that are heritable but not directly due to variation in nucleotide sequence.': $i).
% 29.22/29.02  tff(decl_34988, type, 'inherit epigenetically': $i).
% 29.22/29.02  tff(decl_34989, type, 'epigenetic inheritance': $i).
% 29.22/29.02  tff(decl_34990, type, 'epigenetic-inheritance': $i).
% 29.22/29.02  tff(decl_34991, type, epiglottis_1: $i > $o).
% 29.22/29.02  tff(decl_34992, type, 'Epiglottis': $i).
% 29.22/29.02  tff(decl_34993, type, 'Flap of cartilage which closes during swallowing to direct food into the esophagus and  prevent it from entering the airway.': $i).
% 29.22/29.02  tff(decl_34994, type, epiglottis: $i).
% 29.22/29.02  tff(decl_34995, type, fn_epiglottis_1: $i > $i).
% 29.22/29.02  tff(decl_34996, type, 'Epinephrine': $i).
% 29.22/29.02  tff(decl_34997, type, 'A catecholamine that acts as both a hormone and a neurotransmitter. When secreted as a hormone by the adrenal glands it is a crucial component of the flight-or-fight response. Also known as adrenalin.': $i).
% 29.22/29.02  tff(decl_34998, type, epinephrine: $i).
% 29.22/29.02  tff(decl_34999, type, adrenaline: $i).
% 29.22/29.02  tff(decl_35000, type, epiphyte_1: $i > $o).
% 29.22/29.02  tff(decl_35001, type, 'Epiphyte': $i).
% 29.22/29.02  tff(decl_35002, type, 'A plant that receives water and nutrients from the air and precipitation, but grows on the surface of another plant, using it only for support.': $i).
% 29.22/29.02  tff(decl_35003, type, epiphyte: $i).
% 29.22/29.02  tff(decl_35004, type, 'Episome': $i).
% 29.22/29.02  tff(decl_35005, type, 'Episomes are plasmids that can integrate themselves into the chromosomal DNA of the host organism.': $i).
% 29.22/29.02  tff(decl_35006, type, episome: $i).
% 29.22/29.02  tff(decl_35007, type, fn_episome_1: $i > $i).
% 29.22/29.02  tff(decl_35008, type, fn_episome_2: $i > $i).
% 29.22/29.02  tff(decl_35009, type, fn_episome_3: $i > $i).
% 29.22/29.02  tff(decl_35010, type, 'Epistasis': $i).
% 29.22/29.02  tff(decl_35011, type, 'A type of gene interaction in which one gene alters the phenotypic effects of another gene that is independently inherited.': $i).
% 29.22/29.02  tff(decl_35012, type, epistasis: $i).
% 29.22/29.02  tff(decl_35013, type, gene_interactions_1: $i > $o).
% 29.22/29.02  tff(decl_35014, type, gene_cloning_1: $i > $o).
% 29.22/29.02  tff(decl_35015, type, gene_for_gene_recognition_1: $i > $o).
% 29.22/29.02  tff(decl_35016, type, histone_acetylation_1: $i > $o).
% 29.22/29.02  tff(decl_35017, type, horizontal_gene_transfer_1: $i > $o).
% 29.22/29.02  tff(decl_35018, type, fn_epistasis_1: $i > $i).
% 29.22/29.02  tff(decl_35019, type, fn_epistasis_2: $i > $i).
% 29.22/29.02  tff(decl_35020, type, epithelial_cell_1: $i > $o).
% 29.22/29.02  tff(decl_35021, type, 'Epithelial-Cell': $i).
% 29.22/29.02  tff(decl_35022, type, 'Cell which makes up epithelial tissues.': $i).
% 29.22/29.02  tff(decl_35023, type, 'epithelial cell': $i).
% 29.22/29.02  tff(decl_35024, type, 'epithelial-cell': $i).
% 29.22/29.02  tff(decl_35025, type, 'Epithelium': $i).
% 29.22/29.02  tff(decl_35026, type, 'Epithelium is a type of animal tissue which lines the surface of the body and various structures throughout the body.': $i).
% 29.22/29.02  tff(decl_35027, type, 'simple epithelium': $i).
% 29.22/29.02  tff(decl_35028, type, 'simple-epithelium': $i).
% 29.22/29.02  tff(decl_35029, type, 'epithelial tissue': $i).
% 29.22/29.02  tff(decl_35030, type, 'epithelial-tissue': $i).
% 29.22/29.02  tff(decl_35031, type, epithelium: $i).
% 29.22/29.02  tff(decl_35032, type, fn_epithelium_1: $i > $i).
% 29.22/29.02  tff(decl_35033, type, fn_epithelium_16: $i > $i).
% 29.22/29.02  tff(decl_35034, type, fn_epithelium_17: $i > $i).
% 29.22/29.02  tff(decl_35035, type, fn_epithelium_18: $i > $i).
% 29.22/29.02  tff(decl_35036, type, fn_epithelium_19: $i > $i).
% 29.22/29.02  tff(decl_35037, type, fn_epithelium_20: $i > $i).
% 29.22/29.02  tff(decl_35038, type, fn_epithelium_21: $i > $i).
% 29.22/29.02  tff(decl_35039, type, fn_epithelium_22: $i > $i).
% 29.22/29.02  tff(decl_35040, type, fn_epithelium_23: $i > $i).
% 29.22/29.02  tff(decl_35041, type, fn_epithelium_24: $i > $i).
% 29.22/29.02  tff(decl_35042, type, fn_epithelium_25: $i > $i).
% 29.22/29.02  tff(decl_35043, type, fn_epithelium_26: $i > $i).
% 29.22/29.02  tff(decl_35044, type, fn_epithelium_27: $i > $i).
% 29.22/29.02  tff(decl_35045, type, fn_epithelium_28: $i > $i).
% 29.22/29.02  tff(decl_35046, type, fn_epithelium_29: $i > $i).
% 29.22/29.02  tff(decl_35047, type, fn_epithelium_30: $i > $i).
% 29.22/29.02  tff(decl_35048, type, fn_epithelium_31: $i > $i).
% 29.22/29.02  tff(decl_35049, type, fn_epithelium_32: $i > $i).
% 29.22/29.02  tff(decl_35050, type, fn_epithelium_33: $i > $i).
% 29.22/29.02  tff(decl_35051, type, fn_epithelium_34: $i > $i).
% 29.22/29.02  tff(decl_35052, type, fn_epithelium_35: $i > $i).
% 29.22/29.02  tff(decl_35053, type, fn_epithelium_36: $i > $i).
% 29.22/29.02  tff(decl_35054, type, fn_epithelium_37: $i > $i).
% 29.22/29.02  tff(decl_35055, type, fn_epithelium_38: $i > $i).
% 29.22/29.02  tff(decl_35056, type, fn_epithelium_39: $i > $i).
% 29.22/29.02  tff(decl_35057, type, fn_epithelium_40: $i > $i).
% 29.22/29.02  tff(decl_35058, type, fn_epithelium_41: $i > $i).
% 29.22/29.02  tff(decl_35059, type, fn_epithelium_42: $i > $i).
% 29.22/29.02  tff(decl_35060, type, fn_epithelium_43: $i > $i).
% 29.22/29.02  tff(decl_35061, type, fn_epithelium_44: $i > $i).
% 29.22/29.02  tff(decl_35062, type, fn_epithelium_45: $i > $i).
% 29.22/29.02  tff(decl_35063, type, fn_epithelium_46: $i > $i).
% 29.22/29.02  tff(decl_35064, type, fn_epithelium_47: $i > $i).
% 29.22/29.02  tff(decl_35065, type, fn_epithelium_48: $i > $i).
% 29.22/29.02  tff(decl_35066, type, fn_epithelium_49: $i > $i).
% 29.22/29.02  tff(decl_35067, type, fn_epithelium_50: $i > $i).
% 29.22/29.02  tff(decl_35068, type, fn_epithelium_51: $i > $i).
% 29.22/29.02  tff(decl_35069, type, fn_epithelium_52: $i > $i).
% 29.22/29.02  tff(decl_35070, type, fn_epithelium_53: $i > $i).
% 29.22/29.02  tff(decl_35071, type, fn_epithelium_54: $i > $i).
% 29.22/29.02  tff(decl_35072, type, fn_epithelium_55: $i > $i).
% 29.22/29.02  tff(decl_35073, type, fn_epithelium_56: $i > $i).
% 29.22/29.02  tff(decl_35074, type, fn_epithelium_57: $i > $i).
% 29.22/29.02  tff(decl_35075, type, fn_epithelium_58: $i > $i).
% 29.22/29.02  tff(decl_35076, type, fn_epithelium_59: $i > $i).
% 29.22/29.02  tff(decl_35077, type, fn_epithelium_60: $i > $i).
% 29.22/29.02  tff(decl_35078, type, fn_epithelium_61: $i > $i).
% 29.22/29.02  tff(decl_35079, type, fn_epithelium_62: $i > $i).
% 29.22/29.02  tff(decl_35080, type, fn_epithelium_63: $i > $i).
% 29.22/29.02  tff(decl_35081, type, fn_epithelium_64: $i > $i).
% 29.22/29.02  tff(decl_35082, type, fn_epithelium_65: $i > $i).
% 29.22/29.02  tff(decl_35083, type, fn_epithelium_66: $i > $i).
% 29.22/29.02  tff(decl_35084, type, fn_epithelium_67: $i > $i).
% 29.22/29.02  tff(decl_35085, type, fn_epithelium_68: $i > $i).
% 29.22/29.02  tff(decl_35086, type, fn_epithelium_69: $i > $i).
% 29.22/29.02  tff(decl_35087, type, fn_epithelium_70: $i > $i).
% 29.22/29.02  tff(decl_35088, type, fn_epithelium_71: $i > $i).
% 29.22/29.02  tff(decl_35089, type, fn_epithelium_72: $i > $i).
% 29.22/29.02  tff(decl_35090, type, fn_epithelium_73: $i > $i).
% 29.22/29.02  tff(decl_35091, type, fn_epithelium_74: $i > $i).
% 29.22/29.02  tff(decl_35092, type, fn_epithelium_75: $i > $i).
% 29.22/29.02  tff(decl_35093, type, fn_epithelium_76: $i > $i).
% 29.22/29.02  tff(decl_35094, type, fn_epithelium_77: $i > $i).
% 29.22/29.02  tff(decl_35095, type, fn_epithelium_78: $i > $i).
% 29.22/29.02  tff(decl_35096, type, fn_epithelium_79: $i > $i).
% 29.22/29.02  tff(decl_35097, type, fn_epithelium_80: $i > $i).
% 29.22/29.02  tff(decl_35098, type, fn_epithelium_81: $i > $i).
% 29.22/29.02  tff(decl_35099, type, fn_epithelium_82: $i > $i).
% 29.22/29.02  tff(decl_35100, type, fn_epithelium_84: $i > $i).
% 29.22/29.02  tff(decl_35101, type, fn_epithelium_85: $i > $i).
% 29.22/29.02  tff(decl_35102, type, fn_epithelium_86: $i > $i).
% 29.22/29.02  tff(decl_35103, type, fn_epithelium_87: $i > $i).
% 29.22/29.02  tff(decl_35104, type, fn_epithelium_88: $i > $i).
% 29.22/29.02  tff(decl_35105, type, fn_epithelium_89: $i > $i).
% 29.22/29.02  tff(decl_35106, type, fn_epithelium_90: $i > $i).
% 29.22/29.02  tff(decl_35107, type, fn_epithelium_91: $i > $i).
% 29.22/29.02  tff(decl_35108, type, fn_epithelium_92: $i > $i).
% 29.22/29.02  tff(decl_35109, type, fn_epithelium_93: $i > $i).
% 29.22/29.02  tff(decl_35110, type, fn_epithelium_94: $i > $i).
% 29.22/29.02  tff(decl_35111, type, fn_epithelium_95: $i > $i).
% 29.22/29.02  tff(decl_35112, type, fn_epithelium_96: $i > $i).
% 29.22/29.02  tff(decl_35113, type, fn_epithelium_97: $i > $i).
% 29.22/29.02  tff(decl_35114, type, fn_plasma_membrane_72: $i > $i).
% 29.22/29.02  tff(decl_35115, type, fn_tight_junction_18: $i > $i).
% 29.22/29.02  tff(decl_35116, type, fn_tight_junction_61: $i > $i).
% 29.22/29.02  tff(decl_35117, type, fn_tight_junction_23: $i > $i).
% 29.22/29.02  tff(decl_35118, type, fn_tight_junction_19: $i > $i).
% 29.22/29.02  tff(decl_35119, type, fn_tight_junction_64: $i > $i).
% 29.22/29.02  tff(decl_35120, type, fn_tight_junction_17: $i > $i).
% 29.22/29.02  tff(decl_35121, type, fn_epithelium_9: $i > $i).
% 29.22/29.02  tff(decl_35122, type, fn_epithelium_10: $i > $i).
% 29.22/29.02  tff(decl_35123, type, fn_epithelium_8: $i > $i).
% 29.22/29.02  tff(decl_35124, type, fn_epithelium_6: $i > $i).
% 29.22/29.02  tff(decl_35125, type, fn_epithelium_7: $i > $i).
% 29.22/29.02  tff(decl_35126, type, fn_epithelium_11: $i > $i).
% 29.22/29.02  tff(decl_35127, type, fn_epithelium_13: $i > $i).
% 29.22/29.02  tff(decl_35128, type, fn_epithelium_12: $i > $i).
% 29.22/29.02  tff(decl_35129, type, fn_epithelium_5: $i > $i).
% 29.22/29.02  tff(decl_35130, type, fn_epithelium_3: $i > $i).
% 29.22/29.02  tff(decl_35131, type, fn_epithelium_2: $i > $i).
% 29.22/29.02  tff(decl_35132, type, fn_epithelium_4: $i > $i).
% 29.22/29.02  tff(decl_35133, type, fn_epithelium_15: $i > $i).
% 29.22/29.02  tff(decl_35134, type, fn_epithelium_14: $i > $i).
% 29.22/29.02  tff(decl_35135, type, 'Epitope': $i).
% 29.22/29.02  tff(decl_35136, type, 'Also known as an antigenic determinant, an epitope is the part of an antigen that is recognized by the immune system, particularly B cells, T cells, and antibodies.': $i).
% 29.22/29.02  tff(decl_35137, type, epitope: $i).
% 29.22/29.02  tff(decl_35138, type, epstein_barr_virus_1: $i > $o).
% 29.22/29.02  tff(decl_35139, type, 'Epstein-Barr-Virus': $i).
% 29.22/29.02  tff(decl_35140, type, 'A herpesvirus that is responsible for mononucleosis and Burkitts lymphoma.': $i).
% 29.22/29.02  tff(decl_35141, type, 'epstein barr virus': $i).
% 29.22/29.02  tff(decl_35142, type, 'epstein-barr-virus': $i).
% 29.22/29.02  tff(decl_35143, type, 'Equal-Sharing': $i).
% 29.22/29.02  tff(decl_35144, type, 'It refers to division or apportion, esp equally.': $i).
% 29.22/29.02  tff(decl_35145, type, share: $i).
% 29.22/29.02  tff(decl_35146, type, 'sharing of equal': $i).
% 29.22/29.02  tff(decl_35147, type, 'equal sharing': $i).
% 29.22/29.02  tff(decl_35148, type, 'equal-sharing': $i).
% 29.22/29.02  tff(decl_35149, type, 'Equation-Big-Node': $i).
% 29.22/29.02  tff(decl_35150, type, 'equation big node': $i).
% 29.22/29.02  tff(decl_35151, type, 'equation-big-node': $i).
% 29.22/29.02  tff(decl_35152, type, group_node_1: $i > $o).
% 29.22/29.02  tff(decl_35153, type, 'Equation-Set': $i).
% 29.22/29.02  tff(decl_35154, type, equation: $i).
% 29.22/29.02  tff(decl_35155, type, 'equation set': $i).
% 29.22/29.02  tff(decl_35156, type, 'equation-set': $i).
% 29.22/29.02  tff(decl_35157, type, equational_cell_division_1: $i > $o).
% 29.22/29.02  tff(decl_35158, type, 'Equational-Cell-Division': $i).
% 29.22/29.02  tff(decl_35159, type, 'A type of cell division in which the number of chromosomes remains constant.': $i).
% 29.22/29.02  tff(decl_35160, type, 'divide equationally': $i).
% 29.22/29.02  tff(decl_35161, type, 'equational cell division': $i).
% 29.22/29.02  tff(decl_35162, type, 'equational-cell-division': $i).
% 29.22/29.02  tff(decl_35163, type, equilibrium_1: $i > $o).
% 29.22/29.02  tff(decl_35164, type, 'Equilibrium': $i).
% 29.22/29.02  tff(decl_35165, type, 'A condition in which all acting influences are canceled by others, resulting in a stable, balanced, or unchanging system.': $i).
% 29.22/29.02  tff(decl_35166, type, equilibrize: $i).
% 29.22/29.02  tff(decl_35167, type, equilibrium: $i).
% 29.22/29.02  tff(decl_35168, type, equilibrium_constant_expression_1: $i > $o).
% 29.22/29.02  tff(decl_35169, type, 'Equilibrium-Constant-Expression': $i).
% 29.22/29.02  tff(decl_35170, type, 'The expression that describes the relationship among the concentrations (or partial pressures) of the substances present in a system at equlibrium.': $i).
% 29.22/29.02  tff(decl_35171, type, 'equilibrium constant expression': $i).
% 29.22/29.02  tff(decl_35172, type, 'equilibrium-constant-expression': $i).
% 29.22/29.02  tff(decl_35173, type, 'Equilibrium-Constant-Value': $i).
% 29.22/29.02  tff(decl_35174, type, 'equilibrium constant': $i).
% 29.22/29.02  tff(decl_35175, type, ki: $i).
% 29.22/29.02  tff(decl_35176, type, keq: $i).
% 29.22/29.02  tff(decl_35177, type, kb: $i).
% 29.22/29.02  tff(decl_35178, type, ka: $i).
% 29.22/29.02  tff(decl_35179, type, 'default kb': $i).
% 29.22/29.02  tff(decl_35180, type, 'default-kb': $i).
% 29.22/29.02  tff(decl_35181, type, 'default ka': $i).
% 29.22/29.02  tff(decl_35182, type, 'default-ka': $i).
% 29.22/29.02  tff(decl_35183, type, 'equilibrium constant value': $i).
% 29.22/29.02  tff(decl_35184, type, 'equilibrium-constant-value': $i).
% 29.22/29.02  tff(decl_35185, type, 'ER-Membrane': $i).
% 29.22/29.02  tff(decl_35186, type, 'ER membrane acts as a barrier enclosing the enzymes and other components in the endoplasmic reticulum of the eukaryotic cells': $i).
% 29.22/29.02  tff(decl_35187, type, 'membrane of er': $i).
% 29.22/29.02  tff(decl_35188, type, 'er membrane': $i).
% 29.22/29.02  tff(decl_35189, type, 'er-membrane': $i).
% 29.22/29.02  tff(decl_35190, type, fn_er_membrane_1: $i > $i).
% 29.22/29.02  tff(decl_35191, type, fn_er_membrane_2: $i > $i).
% 29.22/29.02  tff(decl_35192, type, fn_er_membrane_3: $i > $i).
% 29.22/29.02  tff(decl_35193, type, fn_er_membrane_4: $i > $i).
% 29.22/29.02  tff(decl_35194, type, fn_er_membrane_5: $i > $i).
% 29.22/29.02  tff(decl_35195, type, fn_er_membrane_6: $i > $i).
% 29.22/29.02  tff(decl_35196, type, fn_er_membrane_8: $i > $i).
% 29.22/29.02  tff(decl_35197, type, fn_er_membrane_9: $i > $i).
% 29.22/29.02  tff(decl_35198, type, fn_er_membrane_10: $i > $i).
% 29.22/29.02  tff(decl_35199, type, fn_er_membrane_11: $i > $i).
% 29.22/29.02  tff(decl_35200, type, fn_er_membrane_12: $i > $i).
% 29.22/29.02  tff(decl_35201, type, fn_er_membrane_14: $i > $i).
% 29.22/29.02  tff(decl_35202, type, fn_er_membrane_15: $i > $i).
% 29.22/29.02  tff(decl_35203, type, fn_er_membrane_16: $i > $i).
% 29.22/29.02  tff(decl_35204, type, fn_er_membrane_17: $i > $i).
% 29.22/29.02  tff(decl_35205, type, fn_er_membrane_18: $i > $i).
% 29.22/29.02  tff(decl_35206, type, fn_er_membrane_19: $i > $i).
% 29.22/29.02  tff(decl_35207, type, fn_er_membrane_20: $i > $i).
% 29.22/29.02  tff(decl_35208, type, fn_er_membrane_21: $i > $i).
% 29.22/29.02  tff(decl_35209, type, fn_er_membrane_22: $i > $i).
% 29.22/29.02  tff(decl_35210, type, fn_er_membrane_23: $i > $i).
% 29.22/29.02  tff(decl_35211, type, fn_er_membrane_24: $i > $i).
% 29.22/29.02  tff(decl_35212, type, fn_er_membrane_25: $i > $i).
% 29.22/29.02  tff(decl_35213, type, fn_er_membrane_26: $i > $i).
% 29.22/29.02  tff(decl_35214, type, fn_er_membrane_27: $i > $i).
% 29.22/29.02  tff(decl_35215, type, fn_er_membrane_30: $i > $i).
% 29.22/29.02  tff(decl_35216, type, fn_er_membrane_31: $i > $i).
% 29.22/29.02  tff(decl_35217, type, fn_er_membrane_34: $i > $i).
% 29.22/29.02  tff(decl_35218, type, fn_er_membrane_35: $i > $i).
% 29.22/29.02  tff(decl_35219, type, fn_er_membrane_36: $i > $i).
% 29.22/29.02  tff(decl_35220, type, fn_er_membrane_37: $i > $i).
% 29.22/29.02  tff(decl_35221, type, fn_er_membrane_38: $i > $i).
% 29.22/29.02  tff(decl_35222, type, fn_er_membrane_39: $i > $i).
% 29.22/29.02  tff(decl_35223, type, fn_er_membrane_40: $i > $i).
% 29.22/29.02  tff(decl_35224, type, fn_er_membrane_44: $i > $i).
% 29.22/29.02  tff(decl_35225, type, fn_er_membrane_45: $i > $i).
% 29.22/29.02  tff(decl_35226, type, fn_er_membrane_47: $i > $i).
% 29.22/29.02  tff(decl_35227, type, fn_er_membrane_48: $i > $i).
% 29.22/29.02  tff(decl_35228, type, fn_phospholipid_layer_15: $i > $i).
% 29.22/29.02  tff(decl_35229, type, fn_phospholipid_bilayer_35: $i > $i).
% 29.22/29.02  tff(decl_35230, type, fn_phospholipid_bilayer_36: $i > $i).
% 29.22/29.02  tff(decl_35231, type, fn_er_membrane_41: $i > $i).
% 29.22/29.02  tff(decl_35232, type, fn_er_membrane_43: $i > $i).
% 29.22/29.02  tff(decl_35233, type, fn_er_membrane_46: $i > $i).
% 29.22/29.02  tff(decl_35234, type, fn_er_membrane_42: $i > $i).
% 29.22/29.02  tff(decl_35235, type, erbium_1: $i > $o).
% 29.22/29.02  tff(decl_35236, type, 'Erbium': $i).
% 29.22/29.02  tff(decl_35237, type, 'Erbium is a metal atom with atomic number 68. It is represented by the symbol Er.': $i).
% 29.22/29.02  tff(decl_35238, type, erbium: $i).
% 29.22/29.02  tff(decl_35239, type, fn_erbium_4: $i > $i).
% 29.22/29.02  tff(decl_35240, type, fn_erbium_5: $i > $i).
% 29.22/29.02  tff(decl_35241, type, fn_erbium_6: $i > $i).
% 29.22/29.02  tff(decl_35242, type, fn_erbium_7: $i > $i).
% 29.22/29.02  tff(decl_35243, type, fn_erbium_11: $i > $i).
% 29.22/29.02  tff(decl_35244, type, fn_erbium_12: $i > $i).
% 29.22/29.02  tff(decl_35245, type, fn_erbium_13: $i > $i).
% 29.22/29.02  tff(decl_35246, type, fn_erbium_14: $i > $i).
% 29.22/29.02  tff(decl_35247, type, "68": $i).
% 29.22/29.02  tff(decl_35248, type, "1.24": $i).
% 29.22/29.02  tff(decl_35249, type, "167": $i).
% 29.22/29.02  tff(decl_35250, type, "167.3": $i).
% 29.22/29.02  tff(decl_35251, type, fn_erbium_9: $i > $i).
% 29.22/29.02  tff(decl_35252, type, fn_erbium_10: $i > $i).
% 29.22/29.02  tff(decl_35253, type, fn_erbium_8: $i > $i).
% 29.22/29.02  tff(decl_35254, type, 'Erythrocyte': $i).
% 29.22/29.02  tff(decl_35255, type, 'An erythrocyte is also known as a red blood cell. The primary physiological role of an erythrocyte is to transport oxygen.': $i).
% 29.22/29.02  tff(decl_35256, type, 'red blood cell': $i).
% 29.22/29.02  tff(decl_35257, type, rbc: $i).
% 29.22/29.02  tff(decl_35258, type, erythrocyte: $i).
% 29.22/29.02  tff(decl_35259, type, fn_erythrocyte_1: $i > $i).
% 29.22/29.02  tff(decl_35260, type, fn_erythrocyte_2: $i > $i).
% 29.22/29.02  tff(decl_35261, type, fn_erythrocyte_3: $i > $i).
% 29.22/29.02  tff(decl_35262, type, fn_erythrocyte_4: $i > $i).
% 29.22/29.02  tff(decl_35263, type, fn_erythrocyte_5: $i > $i).
% 29.22/29.02  tff(decl_35264, type, fn_erythrocyte_6: $i > $i).
% 29.22/29.02  tff(decl_35265, type, fn_erythrocyte_7: $i > $i).
% 29.22/29.02  tff(decl_35266, type, fn_erythrocyte_8: $i > $i).
% 29.22/29.02  tff(decl_35267, type, fn_erythrocyte_9: $i > $i).
% 29.22/29.02  tff(decl_35268, type, fn_erythrocyte_10: $i > $i).
% 29.22/29.02  tff(decl_35269, type, fn_erythrocyte_11: $i > $i).
% 29.22/29.02  tff(decl_35270, type, fn_erythrocyte_12: $i > $i).
% 29.22/29.02  tff(decl_35271, type, fn_erythrocyte_13: $i > $i).
% 29.22/29.02  tff(decl_35272, type, fn_erythrocyte_16: $i > $i).
% 29.22/29.02  tff(decl_35273, type, fn_erythrocyte_17: $i > $i).
% 29.22/29.02  tff(decl_35274, type, fn_erythrocyte_18: $i > $i).
% 29.22/29.02  tff(decl_35275, type, fn_erythrocyte_19: $i > $i).
% 29.22/29.02  tff(decl_35276, type, fn_erythrocyte_20: $i > $i).
% 29.22/29.02  tff(decl_35277, type, fn_erythrocyte_21: $i > $i).
% 29.22/29.02  tff(decl_35278, type, fn_erythrocyte_22: $i > $i).
% 29.22/29.02  tff(decl_35279, type, fn_erythrocyte_23: $i > $i).
% 29.22/29.02  tff(decl_35280, type, fn_erythrocyte_24: $i > $i).
% 29.22/29.02  tff(decl_35281, type, pore_complex_1: $i > $o).
% 29.22/29.02  tff(decl_35282, type, fn_erythrocyte_25: $i > $i).
% 29.22/29.02  tff(decl_35283, type, fn_erythrocyte_26: $i > $i).
% 29.22/29.02  tff(decl_35284, type, fn_erythrocyte_28: $i > $i).
% 29.22/29.02  tff(decl_35285, type, nuclear_pore_1: $i > $o).
% 29.22/29.02  tff(decl_35286, type, fn_erythrocyte_29: $i > $i).
% 29.22/29.02  tff(decl_35287, type, fn_erythrocyte_30: $i > $i).
% 29.22/29.02  tff(decl_35288, type, fn_erythrocyte_31: $i > $i).
% 29.22/29.02  tff(decl_35289, type, fn_erythrocyte_32: $i > $i).
% 29.22/29.02  tff(decl_35290, type, fn_erythrocyte_33: $i > $i).
% 29.22/29.02  tff(decl_35291, type, fn_erythrocyte_34: $i > $i).
% 29.22/29.02  tff(decl_35292, type, fn_erythrocyte_35: $i > $i).
% 29.22/29.02  tff(decl_35293, type, fn_erythrocyte_36: $i > $i).
% 29.22/29.02  tff(decl_35294, type, fn_erythrocyte_37: $i > $i).
% 29.22/29.02  tff(decl_35295, type, fn_erythrocyte_38: $i > $i).
% 29.22/29.02  tff(decl_35296, type, fn_erythrocyte_39: $i > $i).
% 29.22/29.02  tff(decl_35297, type, fn_erythrocyte_40: $i > $i).
% 29.22/29.02  tff(decl_35298, type, fn_erythrocyte_41: $i > $i).
% 29.22/29.02  tff(decl_35299, type, fn_erythrocyte_42: $i > $i).
% 29.22/29.02  tff(decl_35300, type, fn_erythrocyte_43: $i > $i).
% 29.22/29.02  tff(decl_35301, type, fn_erythrocyte_44: $i > $i).
% 29.22/29.02  tff(decl_35302, type, fn_erythrocyte_45: $i > $i).
% 29.22/29.02  tff(decl_35303, type, fn_erythrocyte_46: $i > $i).
% 29.22/29.02  tff(decl_35304, type, fn_erythrocyte_47: $i > $i).
% 29.22/29.02  tff(decl_35305, type, fn_erythrocyte_48: $i > $i).
% 29.22/29.02  tff(decl_35306, type, fn_erythrocyte_49: $i > $i).
% 29.22/29.02  tff(decl_35307, type, fn_erythrocyte_50: $i > $i).
% 29.22/29.02  tff(decl_35308, type, fn_erythrocyte_51: $i > $i).
% 29.22/29.02  tff(decl_35309, type, fn_erythrocyte_52: $i > $i).
% 29.22/29.02  tff(decl_35310, type, fn_erythrocyte_53: $i > $i).
% 29.22/29.02  tff(decl_35311, type, fn_erythrocyte_54: $i > $i).
% 29.22/29.02  tff(decl_35312, type, fn_erythrocyte_55: $i > $i).
% 29.22/29.02  tff(decl_35313, type, fn_erythrocyte_56: $i > $i).
% 29.22/29.02  tff(decl_35314, type, fn_erythrocyte_57: $i > $i).
% 29.22/29.02  tff(decl_35315, type, fn_erythrocyte_58: $i > $i).
% 29.22/29.02  tff(decl_35316, type, fn_erythrocyte_59: $i > $i).
% 29.22/29.02  tff(decl_35317, type, fn_erythrocyte_60: $i > $i).
% 29.22/29.02  tff(decl_35318, type, fn_erythrocyte_61: $i > $i).
% 29.22/29.02  tff(decl_35319, type, fn_erythrocyte_62: $i > $i).
% 29.22/29.02  tff(decl_35320, type, fn_erythrocyte_63: $i > $i).
% 29.22/29.02  tff(decl_35321, type, fn_erythrocyte_64: $i > $i).
% 29.22/29.02  tff(decl_35322, type, fn_erythrocyte_65: $i > $i).
% 29.22/29.02  tff(decl_35323, type, fn_erythrocyte_66: $i > $i).
% 29.22/29.02  tff(decl_35324, type, fn_erythrocyte_67: $i > $i).
% 29.22/29.02  tff(decl_35325, type, fn_erythrocyte_68: $i > $i).
% 29.22/29.02  tff(decl_35326, type, fn_erythrocyte_69: $i > $i).
% 29.22/29.02  tff(decl_35327, type, fn_erythrocyte_72: $i > $i).
% 29.22/29.02  tff(decl_35328, type, fn_erythrocyte_73: $i > $i).
% 29.22/29.02  tff(decl_35329, type, fn_erythrocyte_74: $i > $i).
% 29.22/29.02  tff(decl_35330, type, fn_erythrocyte_75: $i > $i).
% 29.22/29.02  tff(decl_35331, type, fn_erythrocyte_76: $i > $i).
% 29.22/29.02  tff(decl_35332, type, fn_erythrocyte_77: $i > $i).
% 29.22/29.02  tff(decl_35333, type, fn_erythrocyte_78: $i > $i).
% 29.22/29.02  tff(decl_35334, type, fn_erythrocyte_79: $i > $i).
% 29.22/29.02  tff(decl_35335, type, fn_erythrocyte_80: $i > $i).
% 29.22/29.02  tff(decl_35336, type, fn_erythrocyte_81: $i > $i).
% 29.22/29.02  tff(decl_35337, type, fn_heme_2: $i > $i).
% 29.22/29.02  tff(decl_35338, type, fn_pore_complex_2: $i > $i).
% 29.22/29.02  tff(decl_35339, type, fn_hemoglobin_3: $i > $i).
% 29.22/29.02  tff(decl_35340, type, fn_hemoglobin_2: $i > $i).
% 29.22/29.02  tff(decl_35341, type, fn_hemoglobin_7: $i > $i).
% 29.22/29.02  tff(decl_35342, type, fn_hemoglobin_11: $i > $i).
% 29.22/29.02  tff(decl_35343, type, fn_fibronectin_44: $i > $i).
% 29.22/29.02  tff(decl_35344, type, fn_fibronectin_37: $i > $i).
% 29.22/29.02  tff(decl_35345, type, fn_pore_complex_5: $i > $i).
% 29.22/29.02  tff(decl_35346, type, fn_hemoglobin_10: $i > $i).
% 29.22/29.02  tff(decl_35347, type, fn_hemoglobin_12: $i > $i).
% 29.22/29.02  tff(decl_35348, type, fn_synthesis_of_endomembranous_system_membrane_70: $i > $i).
% 29.22/29.02  tff(decl_35349, type, fn_pore_complex_7: $i > $i).
% 29.22/29.02  tff(decl_35350, type, fn_hemoglobin_1: $i > $i).
% 29.22/29.02  tff(decl_35351, type, fn_erythrocyte_27: $i > $i).
% 29.22/29.02  tff(decl_35352, type, fn_eukaryotic_cell_38: $i > $i).
% 29.22/29.02  tff(decl_35353, type, fn_eukaryotic_cell_40: $i > $i).
% 29.22/29.02  tff(decl_35354, type, fn_eukaryotic_cell_17: $i > $i).
% 29.22/29.02  tff(decl_35355, type, fn_erythrocyte_70: $i > $i).
% 29.22/29.02  tff(decl_35356, type, fn_erythrocyte_71: $i > $i).
% 29.22/29.02  tff(decl_35357, type, fn_erythrocyte_14: $i > $i).
% 29.22/29.02  tff(decl_35358, type, fn_vertebrate_cell_29: $i > $i).
% 29.22/29.02  tff(decl_35359, type, fn_erythrocyte_15: $i > $i).
% 29.22/29.02  tff(decl_35360, type, fn_vertebrate_cell_28: $i > $i).
% 29.22/29.02  tff(decl_35361, type, fn_vertebrate_cell_17: $i > $i).
% 29.22/29.02  tff(decl_35362, type, fn_vertebrate_cell_15: $i > $i).
% 29.22/29.02  tff(decl_35363, type, fn_vertebrate_cell_16: $i > $i).
% 29.22/29.02  tff(decl_35364, type, fn_vertebrate_cell_12: $i > $i).
% 29.22/29.02  tff(decl_35365, type, fn_vertebrate_cell_14: $i > $i).
% 29.22/29.02  tff(decl_35366, type, fn_vertebrate_cell_13: $i > $i).
% 29.22/29.02  tff(decl_35367, type, fn_vertebrate_cell_10: $i > $i).
% 29.22/29.02  tff(decl_35368, type, fn_vertebrate_cell_7: $i > $i).
% 29.22/29.02  tff(decl_35369, type, fn_vertebrate_cell_8: $i > $i).
% 29.22/29.02  tff(decl_35370, type, fn_vertebrate_cell_30: $i > $i).
% 29.22/29.02  tff(decl_35371, type, fn_vertebrate_cell_24: $i > $i).
% 29.22/29.02  tff(decl_35372, type, fn_vertebrate_cell_11: $i > $i).
% 29.22/29.02  tff(decl_35373, type, fn_vertebrate_cell_25: $i > $i).
% 29.22/29.02  tff(decl_35374, type, fn_vertebrate_cell_3: $i > $i).
% 29.22/29.02  tff(decl_35375, type, fn_vertebrate_cell_18: $i > $i).
% 29.22/29.02  tff(decl_35376, type, fn_vertebrate_cell_32: $i > $i).
% 29.22/29.02  tff(decl_35377, type, fn_vertebrate_cell_6: $i > $i).
% 29.22/29.02  tff(decl_35378, type, fn_vertebrate_cell_26: $i > $i).
% 29.22/29.02  tff(decl_35379, type, fn_vertebrate_cell_2: $i > $i).
% 29.22/29.02  tff(decl_35380, type, fn_vertebrate_cell_1: $i > $i).
% 29.22/29.02  tff(decl_35381, type, fn_vertebrate_cell_20: $i > $i).
% 29.22/29.02  tff(decl_35382, type, fn_vertebrate_cell_19: $i > $i).
% 29.22/29.02  tff(decl_35383, type, fn_vertebrate_cell_4: $i > $i).
% 29.22/29.02  tff(decl_35384, type, fn_vertebrate_cell_31: $i > $i).
% 29.22/29.02  tff(decl_35385, type, fn_vertebrate_cell_21: $i > $i).
% 29.22/29.02  tff(decl_35386, type, fn_vertebrate_cell_9: $i > $i).
% 29.22/29.02  tff(decl_35387, type, fn_vertebrate_cell_23: $i > $i).
% 29.22/29.02  tff(decl_35388, type, fn_vertebrate_cell_22: $i > $i).
% 29.22/29.02  tff(decl_35389, type, 'Erythromycin': $i).
% 29.22/29.02  tff(decl_35390, type, 'An antibiotic used to treat certain infections caused by bacteria.': $i).
% 29.22/29.02  tff(decl_35391, type, erythromycin: $i).
% 29.22/29.02  tff(decl_35392, type, 'Erythropoietin': $i).
% 29.22/29.02  tff(decl_35393, type, 'A glycoprotein hormone that controls the production of red blood cells. It also plays a role in wound healing and the brain\\s response to neuronal injury.': $i).
% 29.22/29.02  tff(decl_35394, type, erythropoietin: $i).
% 29.22/29.02  tff(decl_35395, type, epo: $i).
% 29.22/29.02  tff(decl_35396, type, hematopoietin: $i).
% 29.22/29.02  tff(decl_35397, type, hemopoietin: $i).
% 29.22/29.02  tff(decl_35398, type, 'Escherichia-Coli': $i).
% 29.22/29.02  tff(decl_35399, type, 'A Gram-negative bacterium that is commonly part of the normal flora in the intestines of endothermic animals. Many strains of E. coli are harmless, but some cause food poisoning in humans.': $i).
% 29.22/29.02  tff(decl_35400, type, 'e.coli': $i).
% 29.22/29.02  tff(decl_35401, type, 'gram negative bacteria': $i).
% 29.22/29.02  tff(decl_35402, type, 'gram-negative-bacteria': $i).
% 29.22/29.02  tff(decl_35403, type, 'e. coli': $i).
% 29.22/29.02  tff(decl_35404, type, 'e.-coli': $i).
% 29.22/29.02  tff(decl_35405, type, 'escherichia coli': $i).
% 29.22/29.02  tff(decl_35406, type, 'escherichia-coli': $i).
% 29.22/29.02  tff(decl_35407, type, fn_escherichia_coli_1: $i > $i).
% 29.22/29.02  tff(decl_35408, type, fn_escherichia_coli_7: $i > $i).
% 29.22/29.02  tff(decl_35409, type, fn_escherichia_coli_8: $i > $i).
% 29.22/29.02  tff(decl_35410, type, fn_escherichia_coli_9: $i > $i).
% 29.22/29.02  tff(decl_35411, type, fn_escherichia_coli_10: $i > $i).
% 29.22/29.02  tff(decl_35412, type, fn_escherichia_coli_11: $i > $i).
% 29.22/29.02  tff(decl_35413, type, fn_escherichia_coli_12: $i > $i).
% 29.22/29.02  tff(decl_35414, type, fn_escherichia_coli_13: $i > $i).
% 29.22/29.02  tff(decl_35415, type, fn_escherichia_coli_14: $i > $i).
% 29.22/29.02  tff(decl_35416, type, fn_escherichia_coli_15: $i > $i).
% 29.22/29.02  tff(decl_35417, type, fn_escherichia_coli_16: $i > $i).
% 29.22/29.02  tff(decl_35418, type, fn_escherichia_coli_17: $i > $i).
% 29.22/29.02  tff(decl_35419, type, fn_escherichia_coli_18: $i > $i).
% 29.22/29.02  tff(decl_35420, type, fn_escherichia_coli_19: $i > $i).
% 29.22/29.02  tff(decl_35421, type, fn_escherichia_coli_20: $i > $i).
% 29.22/29.02  tff(decl_35422, type, fn_escherichia_coli_21: $i > $i).
% 29.22/29.02  tff(decl_35423, type, fn_escherichia_coli_3: $i > $i).
% 29.22/29.02  tff(decl_35424, type, fn_escherichia_coli_4: $i > $i).
% 29.22/29.02  tff(decl_35425, type, fn_escherichia_coli_5: $i > $i).
% 29.22/29.02  tff(decl_35426, type, fn_escherichia_coli_6: $i > $i).
% 29.22/29.02  tff(decl_35427, type, 'Esophagus': $i).
% 29.22/29.02  tff(decl_35428, type, 'A muscular tube that conducts food, via peristalsis, from the pharynx to the stomach.': $i).
% 29.22/29.02  tff(decl_35429, type, esophagus: $i).
% 29.22/29.02  tff(decl_35430, type, fn_esophagus_6: $i > $i).
% 29.22/29.02  tff(decl_35431, type, fn_esophagus_7: $i > $i).
% 29.22/29.02  tff(decl_35432, type, fn_esophagus_9: $i > $i).
% 29.22/29.02  tff(decl_35433, type, fn_esophagus_10: $i > $i).
% 29.22/29.02  tff(decl_35434, type, fn_esophagus_11: $i > $i).
% 29.22/29.02  tff(decl_35435, type, peristalsis_1: $i > $o).
% 29.22/29.02  tff(decl_35436, type, fn_peristalsis_8: $i > $i).
% 29.22/29.02  tff(decl_35437, type, fn_peristalsis_2: $i > $i).
% 29.22/29.02  tff(decl_35438, type, fn_peristalsis_6: $i > $i).
% 29.22/29.02  tff(decl_35439, type, fn_peristalsis_1: $i > $i).
% 29.22/29.02  tff(decl_35440, type, essential_amino_acid_1: $i > $o).
% 29.22/29.02  tff(decl_35441, type, 'Essential-Amino-Acid': $i).
% 29.22/29.02  tff(decl_35442, type, 'An amino acid that cannot be synthesized by the body and thus must be supplied in the diet.': $i).
% 29.22/29.02  tff(decl_35443, type, 'essential amino acid': $i).
% 29.22/29.02  tff(decl_35444, type, 'essential-amino-acid': $i).
% 29.22/29.02  tff(decl_35445, type, fn_essential_amino_acid_1: $i > $i).
% 29.22/29.02  tff(decl_35446, type, fn_essential_amino_acid_2: $i > $i).
% 29.22/29.02  tff(decl_35447, type, fn_essential_amino_acid_3: $i > $i).
% 29.22/29.02  tff(decl_35448, type, fn_essential_amino_acid_4: $i > $i).
% 29.22/29.02  tff(decl_35449, type, fn_essential_amino_acid_5: $i > $i).
% 29.22/29.02  tff(decl_35450, type, fn_essential_amino_acid_8: $i > $i).
% 29.22/29.02  tff(decl_35451, type, fn_essential_amino_acid_9: $i > $i).
% 29.22/29.02  tff(decl_35452, type, fn_essential_amino_acid_10: $i > $i).
% 29.22/29.02  tff(decl_35453, type, fn_essential_amino_acid_11: $i > $i).
% 29.22/29.02  tff(decl_35454, type, fn_essential_amino_acid_12: $i > $i).
% 29.22/29.02  tff(decl_35455, type, fn_essential_amino_acid_13: $i > $i).
% 29.22/29.02  tff(decl_35456, type, fn_essential_amino_acid_14: $i > $i).
% 29.22/29.02  tff(decl_35457, type, fn_essential_amino_acid_15: $i > $i).
% 29.22/29.02  tff(decl_35458, type, fn_essential_amino_acid_16: $i > $i).
% 29.22/29.02  tff(decl_35459, type, fn_essential_amino_acid_17: $i > $i).
% 29.22/29.02  tff(decl_35460, type, fn_essential_amino_acid_18: $i > $i).
% 29.22/29.02  tff(decl_35461, type, fn_essential_amino_acid_19: $i > $i).
% 29.22/29.02  tff(decl_35462, type, fn_essential_amino_acid_20: $i > $i).
% 29.22/29.02  tff(decl_35463, type, fn_essential_amino_acid_21: $i > $i).
% 29.22/29.02  tff(decl_35464, type, fn_essential_amino_acid_22: $i > $i).
% 29.22/29.02  tff(decl_35465, type, fn_essential_amino_acid_23: $i > $i).
% 29.22/29.02  tff(decl_35466, type, fn_essential_amino_acid_24: $i > $i).
% 29.22/29.02  tff(decl_35467, type, fn_essential_amino_acid_25: $i > $i).
% 29.22/29.02  tff(decl_35468, type, fn_essential_amino_acid_26: $i > $i).
% 29.22/29.02  tff(decl_35469, type, fn_essential_amino_acid_27: $i > $i).
% 29.22/29.02  tff(decl_35470, type, fn_essential_amino_acid_28: $i > $i).
% 29.22/29.02  tff(decl_35471, type, fn_essential_amino_acid_29: $i > $i).
% 29.22/29.02  tff(decl_35472, type, fn_essential_amino_acid_30: $i > $i).
% 29.22/29.02  tff(decl_35473, type, fn_essential_amino_acid_31: $i > $i).
% 29.22/29.02  tff(decl_35474, type, fn_essential_amino_acid_32: $i > $i).
% 29.22/29.02  tff(decl_35475, type, fn_essential_amino_acid_33: $i > $i).
% 29.22/29.02  tff(decl_35476, type, fn_essential_amino_acid_34: $i > $i).
% 29.22/29.02  tff(decl_35477, type, fn_essential_amino_acid_35: $i > $i).
% 29.22/29.02  tff(decl_35478, type, fn_essential_amino_acid_36: $i > $i).
% 29.22/29.02  tff(decl_35479, type, fn_essential_amino_acid_37: $i > $i).
% 29.22/29.02  tff(decl_35480, type, fn_essential_amino_acid_38: $i > $i).
% 29.22/29.02  tff(decl_35481, type, fn_essential_amino_acid_39: $i > $i).
% 29.22/29.02  tff(decl_35482, type, fn_essential_amino_acid_40: $i > $i).
% 29.22/29.02  tff(decl_35483, type, fn_essential_amino_acid_41: $i > $i).
% 29.22/29.02  tff(decl_35484, type, fn_essential_amino_acid_42: $i > $i).
% 29.22/29.02  tff(decl_35485, type, fn_essential_amino_acid_43: $i > $i).
% 29.22/29.02  tff(decl_35486, type, fn_essential_amino_acid_44: $i > $i).
% 29.22/29.02  tff(decl_35487, type, fn_essential_amino_acid_6: $i > $i).
% 29.22/29.02  tff(decl_35488, type, fn_essential_amino_acid_7: $i > $i).
% 29.22/29.02  tff(decl_35489, type, essential_chemical_element_for_life_1: $i > $o).
% 29.22/29.02  tff(decl_35490, type, 'Essential-Chemical-Element-For-Life': $i).
% 29.22/29.02  tff(decl_35491, type, 'The essential chemical elements for life are carbon, calcium, hydrogen, nitrogen, oxygen, phosphorus, potassium, sulfur.': $i).
% 29.22/29.02  tff(decl_35492, type, 'chemical elements essential for life': $i).
% 29.22/29.02  tff(decl_35493, type, 'chemical elements important for life': $i).
% 29.22/29.02  tff(decl_35494, type, 'essential chemical element for life': $i).
% 29.22/29.02  tff(decl_35495, type, 'essential-chemical-element-for-life': $i).
% 29.22/29.02  tff(decl_35496, type, fn_essential_chemical_element_for_life_1: $i > $i).
% 29.22/29.02  tff(decl_35497, type, essential_chemical_entity_1: $i > $o).
% 29.22/29.02  tff(decl_35498, type, 'Essential-Chemical-Entity': $i).
% 29.22/29.02  tff(decl_35499, type, 'In plants, a chemical element required for the plant to grow from a seed and complete its lifecycle, producing another generation in the form of seeds.': $i).
% 29.22/29.02  tff(decl_35500, type, 'essential chemical entity': $i).
% 29.22/29.02  tff(decl_35501, type, 'essential-chemical-entity': $i).
% 29.22/29.02  tff(decl_35502, type, essential_fatty_acid_1: $i > $o).
% 29.22/29.02  tff(decl_35503, type, 'Essential-Fatty-Acid': $i).
% 29.22/29.02  tff(decl_35504, type, 'A fatty acid that an animal requires but cannot synthesize. It therefore must be obtained in the diet.': $i).
% 29.22/29.02  tff(decl_35505, type, 'essential fatty acid': $i).
% 29.22/29.02  tff(decl_35506, type, 'essential-fatty-acid': $i).
% 29.22/29.02  tff(decl_35507, type, fn_essential_fatty_acid_1: $i > $i).
% 29.22/29.02  tff(decl_35508, type, fn_essential_fatty_acid_2: $i > $i).
% 29.22/29.02  tff(decl_35509, type, fn_essential_fatty_acid_3: $i > $i).
% 29.22/29.02  tff(decl_35510, type, fn_essential_fatty_acid_4: $i > $i).
% 29.22/29.02  tff(decl_35511, type, fn_essential_fatty_acid_5: $i > $i).
% 29.22/29.02  tff(decl_35512, type, fn_essential_fatty_acid_6: $i > $i).
% 29.22/29.02  tff(decl_35513, type, fn_essential_fatty_acid_7: $i > $i).
% 29.22/29.02  tff(decl_35514, type, fn_essential_fatty_acid_8: $i > $i).
% 29.22/29.02  tff(decl_35515, type, fn_essential_fatty_acid_9: $i > $i).
% 29.22/29.02  tff(decl_35516, type, fn_essential_fatty_acid_10: $i > $i).
% 29.22/29.02  tff(decl_35517, type, fn_essential_fatty_acid_11: $i > $i).
% 29.22/29.02  tff(decl_35518, type, fn_essential_fatty_acid_12: $i > $i).
% 29.22/29.02  tff(decl_35519, type, fn_essential_fatty_acid_13: $i > $i).
% 29.22/29.02  tff(decl_35520, type, fn_essential_fatty_acid_14: $i > $i).
% 29.22/29.02  tff(decl_35521, type, fn_essential_fatty_acid_15: $i > $i).
% 29.22/29.02  tff(decl_35522, type, fn_essential_fatty_acid_16: $i > $i).
% 29.22/29.02  tff(decl_35523, type, fn_essential_fatty_acid_17: $i > $i).
% 29.22/29.02  tff(decl_35524, type, fn_essential_fatty_acid_18: $i > $i).
% 29.22/29.02  tff(decl_35525, type, fn_essential_fatty_acid_19: $i > $i).
% 29.22/29.02  tff(decl_35526, type, fn_essential_fatty_acid_20: $i > $i).
% 29.22/29.02  tff(decl_35527, type, fn_essential_fatty_acid_21: $i > $i).
% 29.22/29.02  tff(decl_35528, type, fn_essential_fatty_acid_22: $i > $i).
% 29.22/29.02  tff(decl_35529, type, fn_essential_fatty_acid_23: $i > $i).
% 29.22/29.02  tff(decl_35530, type, fn_essential_fatty_acid_24: $i > $i).
% 29.22/29.02  tff(decl_35531, type, fn_essential_fatty_acid_25: $i > $i).
% 29.22/29.02  tff(decl_35532, type, fn_essential_fatty_acid_26: $i > $i).
% 29.22/29.02  tff(decl_35533, type, fn_essential_fatty_acid_27: $i > $i).
% 29.22/29.02  tff(decl_35534, type, fn_essential_fatty_acid_28: $i > $i).
% 29.22/29.02  tff(decl_35535, type, fn_essential_fatty_acid_29: $i > $i).
% 29.22/29.02  tff(decl_35536, type, fn_essential_fatty_acid_30: $i > $i).
% 29.22/29.02  tff(decl_35537, type, fn_essential_fatty_acid_31: $i > $i).
% 29.22/29.02  tff(decl_35538, type, fn_essential_fatty_acid_32: $i > $i).
% 29.22/29.02  tff(decl_35539, type, fn_essential_fatty_acid_33: $i > $i).
% 29.22/29.02  tff(decl_35540, type, fn_essential_fatty_acid_34: $i > $i).
% 29.22/29.02  tff(decl_35541, type, p_orbital_1: $i > $o).
% 29.22/29.02  tff(decl_35542, type, fn_essential_fatty_acid_35: $i > $i).
% 29.22/29.02  tff(decl_35543, type, fn_essential_fatty_acid_36: $i > $i).
% 29.22/29.02  tff(decl_35544, type, fn_essential_fatty_acid_37: $i > $i).
% 29.22/29.02  tff(decl_35545, type, fn_essential_fatty_acid_38: $i > $i).
% 29.22/29.02  tff(decl_35546, type, fn_essential_fatty_acid_39: $i > $i).
% 29.22/29.02  tff(decl_35547, type, fn_essential_fatty_acid_40: $i > $i).
% 29.22/29.02  tff(decl_35548, type, fn_essential_fatty_acid_41: $i > $i).
% 29.22/29.02  tff(decl_35549, type, fn_essential_fatty_acid_42: $i > $i).
% 29.22/29.02  tff(decl_35550, type, fn_second_electron_shell_5: $i > $i).
% 29.22/29.02  tff(decl_35551, type, fn_second_electron_shell_1: $i > $i).
% 29.22/29.02  tff(decl_35552, type, fn_second_electron_shell_14: $i > $i).
% 29.22/29.02  tff(decl_35553, type, fn_second_electron_shell_9: $i > $i).
% 29.22/29.02  tff(decl_35554, type, fn_fatty_acid_41: $i > $i).
% 29.22/29.02  tff(decl_35555, type, fn_fatty_acid_37: $i > $i).
% 29.22/29.02  tff(decl_35556, type, fn_fatty_acid_35: $i > $i).
% 29.22/29.02  tff(decl_35557, type, fn_fatty_acid_19: $i > $i).
% 29.22/29.02  tff(decl_35558, type, fn_fatty_acid_17: $i > $i).
% 29.22/29.02  tff(decl_35559, type, fn_fatty_acid_38: $i > $i).
% 29.22/29.02  tff(decl_35560, type, fn_fatty_acid_63: $i > $i).
% 29.22/29.02  tff(decl_35561, type, fn_fatty_acid_12: $i > $i).
% 29.22/29.02  tff(decl_35562, type, fn_fatty_acid_11: $i > $i).
% 29.22/29.02  tff(decl_35563, type, fn_fatty_acid_3: $i > $i).
% 29.22/29.02  tff(decl_35564, type, fn_fatty_acid_40: $i > $i).
% 29.22/29.02  tff(decl_35565, type, fn_fatty_acid_66: $i > $i).
% 29.22/29.02  tff(decl_35566, type, fn_fatty_acid_43: $i > $i).
% 29.22/29.02  tff(decl_35567, type, fn_fatty_acid_64: $i > $i).
% 29.22/29.02  tff(decl_35568, type, fn_fatty_acid_58: $i > $i).
% 29.22/29.02  tff(decl_35569, type, fn_fatty_acid_26: $i > $i).
% 29.22/29.02  tff(decl_35570, type, fn_fatty_acid_15: $i > $i).
% 29.22/29.02  tff(decl_35571, type, fn_fatty_acid_31: $i > $i).
% 29.22/29.02  tff(decl_35572, type, fn_fatty_acid_32: $i > $i).
% 29.22/29.02  tff(decl_35573, type, fn_fatty_acid_20: $i > $i).
% 29.22/29.02  tff(decl_35574, type, fn_fatty_acid_21: $i > $i).
% 29.22/29.02  tff(decl_35575, type, fn_fatty_acid_62: $i > $i).
% 29.22/29.02  tff(decl_35576, type, fn_fatty_acid_16: $i > $i).
% 29.22/29.02  tff(decl_35577, type, fn_fatty_acid_57: $i > $i).
% 29.22/29.02  tff(decl_35578, type, fn_fatty_acid_14: $i > $i).
% 29.22/29.02  tff(decl_35579, type, fn_fatty_acid_61: $i > $i).
% 29.22/29.02  tff(decl_35580, type, fn_fatty_acid_24: $i > $i).
% 29.22/29.02  tff(decl_35581, type, fn_fatty_acid_22: $i > $i).
% 29.22/29.02  tff(decl_35582, type, fn_fatty_acid_36: $i > $i).
% 29.22/29.02  tff(decl_35583, type, fn_fatty_acid_23: $i > $i).
% 29.22/29.02  tff(decl_35584, type, fn_fatty_acid_33: $i > $i).
% 29.22/29.02  tff(decl_35585, type, fn_fatty_acid_34: $i > $i).
% 29.22/29.02  tff(decl_35586, type, fn_fatty_acid_44: $i > $i).
% 29.22/29.02  tff(decl_35587, type, fn_fatty_acid_27: $i > $i).
% 29.22/29.02  tff(decl_35588, type, 'Ester': $i).
% 29.22/29.02  tff(decl_35589, type, 'An organic compound formed when the hydrogen of an acid is replaced by an alkyl or other organic group. Many naturally occurring fats and essential oils are esters of fatty acids.': $i).
% 29.22/29.02  tff(decl_35590, type, ester: $i).
% 29.22/29.02  tff(decl_35591, type, 'Ester-Linkage': $i).
% 29.22/29.02  tff(decl_35592, type, 'The bonding between fatty acids and glycerol that characterizes true fats.': $i).
% 29.22/29.02  tff(decl_35593, type, 'ester bond': $i).
% 29.22/29.02  tff(decl_35594, type, 'ester-bond': $i).
% 29.22/29.02  tff(decl_35595, type, 'linkage of ester': $i).
% 29.22/29.02  tff(decl_35596, type, 'ester linkage': $i).
% 29.22/29.02  tff(decl_35597, type, 'ester-linkage': $i).
% 29.22/29.02  tff(decl_35598, type, fn_ester_linkage_6: $i > $i).
% 29.22/29.02  tff(decl_35599, type, fn_ester_linkage_7: $i > $i).
% 29.22/29.02  tff(decl_35600, type, fn_ester_linkage_8: $i > $i).
% 29.22/29.02  tff(decl_35601, type, fn_ester_linkage_9: $i > $i).
% 29.22/29.02  tff(decl_35602, type, fn_ester_linkage_11: $i > $i).
% 29.22/29.02  tff(decl_35603, type, fn_ester_linkage_12: $i > $i).
% 29.22/29.02  tff(decl_35604, type, fn_ester_linkage_13: $i > $i).
% 29.22/29.02  tff(decl_35605, type, fn_ester_linkage_14: $i > $i).
% 29.22/29.02  tff(decl_35606, type, fn_ester_linkage_15: $i > $i).
% 29.22/29.02  tff(decl_35607, type, fn_ester_linkage_20: $i > $i).
% 29.22/29.02  tff(decl_35608, type, fn_ester_linkage_21: $i > $i).
% 29.22/29.02  tff(decl_35609, type, fn_ester_linkage_22: $i > $i).
% 29.22/29.02  tff(decl_35610, type, fn_ester_linkage_24: $i > $i).
% 29.22/29.02  tff(decl_35611, type, fn_ester_linkage_25: $i > $i).
% 29.22/29.02  tff(decl_35612, type, fn_ester_linkage_26: $i > $i).
% 29.22/29.02  tff(decl_35613, type, fn_ester_linkage_29: $i > $i).
% 29.22/29.02  tff(decl_35614, type, fn_ester_linkage_30: $i > $i).
% 29.22/29.02  tff(decl_35615, type, fn_ester_linkage_31: $i > $i).
% 29.22/29.02  tff(decl_35616, type, fn_ester_linkage_33: $i > $i).
% 29.22/29.02  tff(decl_35617, type, fn_ester_linkage_34: $i > $i).
% 29.22/29.02  tff(decl_35618, type, fn_ester_linkage_35: $i > $i).
% 29.22/29.02  tff(decl_35619, type, fn_ester_linkage_37: $i > $i).
% 29.22/29.02  tff(decl_35620, type, fn_ester_linkage_38: $i > $i).
% 29.22/29.02  tff(decl_35621, type, fn_ester_linkage_39: $i > $i).
% 29.22/29.02  tff(decl_35622, type, fn_ester_linkage_40: $i > $i).
% 29.22/29.02  tff(decl_35623, type, fn_ester_linkage_41: $i > $i).
% 29.22/29.02  tff(decl_35624, type, fn_ester_linkage_42: $i > $i).
% 29.22/29.02  tff(decl_35625, type, fn_ester_linkage_43: $i > $i).
% 29.22/29.02  tff(decl_35626, type, fn_ester_linkage_45: $i > $i).
% 29.22/29.02  tff(decl_35627, type, fn_first_electron_shell_2: $i > $i).
% 29.22/29.02  tff(decl_35628, type, fn_first_electron_shell_1: $i > $i).
% 29.22/29.02  tff(decl_35629, type, fn_first_electron_shell_6: $i > $i).
% 29.22/29.02  tff(decl_35630, type, fn_second_electron_shell_19: $i > $i).
% 29.22/29.02  tff(decl_35631, type, fn_second_electron_shell_20: $i > $i).
% 29.22/29.02  tff(decl_35632, type, fn_ester_linkage_16: $i > $i).
% 29.22/29.02  tff(decl_35633, type, fn_ester_linkage_18: $i > $i).
% 29.22/29.02  tff(decl_35634, type, fn_ester_linkage_17: $i > $i).
% 29.22/29.02  tff(decl_35635, type, fn_ester_linkage_49: $i > $i).
% 29.22/29.02  tff(decl_35636, type, fn_ester_linkage_23: $i > $i).
% 29.22/29.02  tff(decl_35637, type, fn_ester_linkage_47: $i > $i).
% 29.22/29.02  tff(decl_35638, type, fn_ester_linkage_48: $i > $i).
% 29.22/29.02  tff(decl_35639, type, fn_ester_linkage_36: $i > $i).
% 29.22/29.02  tff(decl_35640, type, fn_ester_linkage_46: $i > $i).
% 29.22/29.02  tff(decl_35641, type, estivation_1: $i > $o).
% 29.22/29.02  tff(decl_35642, type, 'Estivation': $i).
% 29.22/29.02  tff(decl_35643, type, 'A type of torpor (a physiological state in which activity is low and metabolism decreases) that happens in the summer.': $i).
% 29.22/29.02  tff(decl_35644, type, estivate: $i).
% 29.22/29.02  tff(decl_35645, type, estivation: $i).
% 29.22/29.02  tff(decl_35646, type, torpor_1: $i > $o).
% 29.22/29.02  tff(decl_35647, type, 'Estradiol': $i).
% 29.22/29.02  tff(decl_35648, type, 'Estradiol is an important type of estrogen, or female sex hormone which promote the development and maintenance of the female reproductive system.': $i).
% 29.22/29.02  tff(decl_35649, type, estradiol: $i).
% 29.22/29.02  tff(decl_35650, type, fn_estradiol_3: $i > $i).
% 29.22/29.02  tff(decl_35651, type, fn_estradiol_4: $i > $i).
% 29.22/29.02  tff(decl_35652, type, fn_estradiol_5: $i > $i).
% 29.22/29.02  tff(decl_35653, type, fn_estradiol_6: $i > $i).
% 29.22/29.02  tff(decl_35654, type, fn_estradiol_7: $i > $i).
% 29.22/29.02  tff(decl_35655, type, fn_estradiol_8: $i > $i).
% 29.22/29.02  tff(decl_35656, type, fn_estradiol_9: $i > $i).
% 29.22/29.02  tff(decl_35657, type, fn_estradiol_10: $i > $i).
% 29.22/29.02  tff(decl_35658, type, fn_estradiol_11: $i > $i).
% 29.22/29.02  tff(decl_35659, type, fn_estradiol_12: $i > $i).
% 29.22/29.02  tff(decl_35660, type, fn_estradiol_13: $i > $i).
% 29.22/29.02  tff(decl_35661, type, fn_estradiol_14: $i > $i).
% 29.22/29.02  tff(decl_35662, type, fn_estradiol_2: $i > $i).
% 29.22/29.02  tff(decl_35663, type, fn_steroid_4: $i > $i).
% 29.22/29.02  tff(decl_35664, type, fn_estradiol_1: $i > $i).
% 29.22/29.02  tff(decl_35665, type, fn_steroid_3: $i > $i).
% 29.22/29.02  tff(decl_35666, type, fn_steroid_5: $i > $i).
% 29.22/29.02  tff(decl_35667, type, fn_steroid_8: $i > $i).
% 29.22/29.02  tff(decl_35668, type, fn_steroid_7: $i > $i).
% 29.22/29.02  tff(decl_35669, type, fn_steroid_6: $i > $i).
% 29.22/29.02  tff(decl_35670, type, fn_steroid_14: $i > $i).
% 29.22/29.02  tff(decl_35671, type, fn_steroid_16: $i > $i).
% 29.22/29.02  tff(decl_35672, type, fn_hormone_3: $i > $i).
% 29.22/29.02  tff(decl_35673, type, 'Estrogen': $i).
% 29.22/29.02  tff(decl_35674, type, 'A class of steroid hormones that are responsible for the development and maintenance of female function in mammals.': $i).
% 29.22/29.02  tff(decl_35675, type, estrogen: $i).
% 29.22/29.02  tff(decl_35676, type, 'Estrogen-Receptor': $i).
% 29.22/29.02  tff(decl_35677, type, 'Receptor that binds estrogen.': $i).
% 29.22/29.02  tff(decl_35678, type, 'receptor to estrogen': $i).
% 29.22/29.02  tff(decl_35679, type, 'receptor of estrogen': $i).
% 29.22/29.02  tff(decl_35680, type, 'estrogen receptor': $i).
% 29.22/29.02  tff(decl_35681, type, 'estrogen-receptor': $i).
% 29.22/29.02  tff(decl_35682, type, nuclear_receptor_1: $i > $o).
% 29.22/29.02  tff(decl_35683, type, estrous_cycle_1: $i > $o).
% 29.22/29.02  tff(decl_35684, type, 'Estrous-Cycle': $i).
% 29.22/29.02  tff(decl_35685, type, 'A reproductive cycle that occurs in most female mammals. In animals that undergo estrous cycles, the nonpregnant endometrial layer is resorbed instead of shed, and females are sexually responsive only at the midpoint of the cycle, called estrus.': $i).
% 29.22/29.02  tff(decl_35686, type, 'estrous cycle': $i).
% 29.22/29.02  tff(decl_35687, type, 'estrous-cycle': $i).
% 29.22/29.02  tff(decl_35688, type, 'Estuary': $i).
% 29.22/29.02  tff(decl_35689, type, 'An area where fresh water merges with the ocean, often a river delta.': $i).
% 29.22/29.02  tff(decl_35690, type, estuary: $i).
% 29.22/29.02  tff(decl_35691, type, ethane_1: $i > $o).
% 29.22/29.02  tff(decl_35692, type, 'Ethane': $i).
% 29.22/29.02  tff(decl_35693, type, 'A hydrocarbon composed of two carbon atoms and six hydrogen atoms.': $i).
% 29.22/29.02  tff(decl_35694, type, ethane: $i).
% 29.22/29.02  tff(decl_35695, type, ethanol_substance_1: $i > $o).
% 29.22/29.02  tff(decl_35696, type, 'Ethanol-Substance': $i).
% 29.22/29.02  tff(decl_35697, type, 'Ethanol is a volatile, flammable, colorless liquid substance. It is a type of alcohol found in alcoholic beverages.': $i).
% 29.22/29.02  tff(decl_35698, type, 'substance of ethanol': $i).
% 29.22/29.02  tff(decl_35699, type, 'ethanol substance': $i).
% 29.22/29.02  tff(decl_35700, type, 'ethanol-substance': $i).
% 29.22/29.02  tff(decl_35701, type, fn_ethanol_substance_1: $i > $i).
% 29.22/29.02  tff(decl_35702, type, fn_ethanol_substance_2: $i > $i).
% 29.22/29.02  tff(decl_35703, type, fn_ethanol_substance_4: $i > $i).
% 29.22/29.02  tff(decl_35704, type, "200.0e0": $i).
% 29.22/29.02  tff(decl_35705, type, fn_ethanol_substance_5: $i > $i).
% 29.22/29.02  tff(decl_35706, type, ether_1: $i > $o).
% 29.22/29.02  tff(decl_35707, type, 'Ether': $i).
% 29.22/29.02  tff(decl_35708, type, 'Ethers are  organic compounds that contain an ether group  an oxygen atom connected to two alkyl or aryl groups.': $i).
% 29.22/29.02  tff(decl_35709, type, ether: $i).
% 29.22/29.02  tff(decl_35710, type, fn_ether_1: $i > $i).
% 29.22/29.02  tff(decl_35711, type, 'Ethics': $i).
% 29.22/29.02  tff(decl_35712, type, 'A system of moral principles.': $i).
% 29.22/29.02  tff(decl_35713, type, ethics: $i).
% 29.22/29.02  tff(decl_35714, type, ethic: $i).
% 29.22/29.02  tff(decl_35715, type, 'Ethology': $i).
% 29.22/29.02  tff(decl_35716, type, 'The scientific study of how animals behave, particularly in their natural environments.': $i).
% 29.22/29.02  tff(decl_35717, type, ethology: $i).
% 29.22/29.02  tff(decl_35718, type, 'Ethyl-Alcohol': $i).
% 29.22/29.02  tff(decl_35719, type, 'Ethanol is a volatile, flammable, colorless liquid substance with the chemical formula C2H5OH. It is a type of alcohol found in alcoholic beverages.': $i).
% 29.22/29.02  tff(decl_35720, type, ethanol: $i).
% 29.22/29.02  tff(decl_35721, type, 'alcohol of ethyl': $i).
% 29.22/29.02  tff(decl_35722, type, 'ethyl alcohol': $i).
% 29.22/29.02  tff(decl_35723, type, 'ethyl-alcohol': $i).
% 29.22/29.02  tff(decl_35724, type, fn_ethyl_alcohol_1: $i > $i).
% 29.22/29.02  tff(decl_35725, type, fn_ethyl_alcohol_2: $i > $i).
% 29.22/29.02  tff(decl_35726, type, fn_ethyl_alcohol_4: $i > $i).
% 29.22/29.02  tff(decl_35727, type, fn_ethyl_alcohol_5: $i > $i).
% 29.22/29.02  tff(decl_35728, type, fn_ethyl_alcohol_7: $i > $i).
% 29.22/29.02  tff(decl_35729, type, fn_ethyl_alcohol_9: $i > $i).
% 29.22/29.02  tff(decl_35730, type, fn_ethyl_alcohol_10: $i > $i).
% 29.22/29.02  tff(decl_35731, type, fn_ethyl_alcohol_15: $i > $i).
% 29.22/29.02  tff(decl_35732, type, fn_ethyl_alcohol_16: $i > $i).
% 29.22/29.02  tff(decl_35733, type, fn_ethyl_alcohol_17: $i > $i).
% 29.22/29.02  tff(decl_35734, type, fn_ethyl_alcohol_18: $i > $i).
% 29.22/29.02  tff(decl_35735, type, fn_ethyl_alcohol_19: $i > $i).
% 29.22/29.02  tff(decl_35736, type, fn_ethyl_alcohol_20: $i > $i).
% 29.22/29.02  tff(decl_35737, type, fn_ethyl_alcohol_21: $i > $i).
% 29.22/29.02  tff(decl_35738, type, fn_ethyl_alcohol_22: $i > $i).
% 29.22/29.02  tff(decl_35739, type, fn_ethyl_alcohol_23: $i > $i).
% 29.22/29.02  tff(decl_35740, type, fn_ethyl_alcohol_24: $i > $i).
% 29.22/29.02  tff(decl_35741, type, fn_ethyl_alcohol_25: $i > $i).
% 29.22/29.02  tff(decl_35742, type, fn_ethyl_alcohol_26: $i > $i).
% 29.22/29.02  tff(decl_35743, type, fn_ethyl_alcohol_27: $i > $i).
% 29.22/29.02  tff(decl_35744, type, fn_ethyl_alcohol_28: $i > $i).
% 29.22/29.02  tff(decl_35745, type, fn_ethyl_alcohol_29: $i > $i).
% 29.22/29.02  tff(decl_35746, type, fn_ethyl_alcohol_30: $i > $i).
% 29.22/29.02  tff(decl_35747, type, fn_ethyl_alcohol_31: $i > $i).
% 29.22/29.02  tff(decl_35748, type, fn_ethyl_alcohol_32: $i > $i).
% 29.22/29.02  tff(decl_35749, type, fn_ethyl_alcohol_33: $i > $i).
% 29.22/29.02  tff(decl_35750, type, 'Ethylene': $i).
% 29.22/29.02  tff(decl_35751, type, 'The only gaseous plant hormone. Among its many effects are response to mechanical stress, programmed cell death, leaf abscission, and fruit ripening.': $i).
% 29.22/29.02  tff(decl_35752, type, 'ripening gas': $i).
% 29.22/29.02  tff(decl_35753, type, 'ethylene gas,': $i).
% 29.22/29.02  tff(decl_35754, type, 'ethylene gas': $i).
% 29.22/29.02  tff(decl_35755, type, c2h4: $i).
% 29.22/29.02  tff(decl_35756, type, ethylene: $i).
% 29.22/29.02  tff(decl_35757, type, fn_ethylene_1: $i > $i).
% 29.22/29.02  tff(decl_35758, type, 'Euchromatin': $i).
% 29.22/29.02  tff(decl_35759, type, 'The less condensed form of eukaryotic chromatin that is available for transcription.': $i).
% 29.22/29.02  tff(decl_35760, type, euchromatin: $i).
% 29.22/29.02  tff(decl_35761, type, fn_euchromatin_1: $i > $i).
% 29.22/29.02  tff(decl_35762, type, nuclear_matrix_1: $i > $o).
% 29.22/29.02  tff(decl_35763, type, fn_euchromatin_2: $i > $i).
% 29.22/29.02  tff(decl_35764, type, fn_euchromatin_3: $i > $i).
% 29.22/29.02  tff(decl_35765, type, fn_euchromatin_4: $i > $i).
% 29.22/29.02  tff(decl_35766, type, fn_euchromatin_5: $i > $i).
% 29.22/29.02  tff(decl_35767, type, fn_euchromatin_6: $i > $i).
% 29.22/29.02  tff(decl_35768, type, fn_euchromatin_7: $i > $i).
% 29.22/29.02  tff(decl_35769, type, fn_euchromatin_9: $i > $i).
% 29.22/29.02  tff(decl_35770, type, fn_euchromatin_10: $i > $i).
% 29.22/29.02  tff(decl_35771, type, fn_euchromatin_11: $i > $i).
% 29.22/29.02  tff(decl_35772, type, fn_eukaryotic_chromatin_8: $i > $i).
% 29.22/29.02  tff(decl_35773, type, euchromatin_0: $i).
% 29.22/29.02  tff(decl_35774, type, fn_euchromatin_8: $i > $i).
% 29.22/29.02  tff(decl_35775, type, fn_chromosome_1: $i > $i).
% 29.22/29.02  tff(decl_35776, type, fn_eukaryotic_chromatin_14: $i > $i).
% 29.22/29.02  tff(decl_35777, type, fn_eukaryotic_chromatin_13: $i > $i).
% 29.22/29.02  tff(decl_35778, type, fn_eukaryotic_chromatin_2: $i > $i).
% 29.22/29.02  tff(decl_35779, type, fn_eukaryotic_chromatin_12: $i > $i).
% 29.22/29.02  tff(decl_35780, type, fn_eukaryotic_chromatin_1: $i > $i).
% 29.22/29.02  tff(decl_35781, type, 'Eudicot': $i).
% 29.22/29.02  tff(decl_35782, type, 'Member of a large clade of angiosperms that have two cotyledons, or embryonic seed leaves.': $i).
% 29.22/29.02  tff(decl_35783, type, eudicot: $i).
% 29.22/29.02  tff(decl_35784, type, fn_eudicot_1: $i > $i).
% 29.22/29.02  tff(decl_35785, type, fn_eudicot_2: $i > $i).
% 29.22/29.02  tff(decl_35786, type, fn_eudicot_4: $i > $i).
% 29.22/29.02  tff(decl_35787, type, fn_eudicot_5: $i > $i).
% 29.22/29.02  tff(decl_35788, type, fn_eudicot_8: $i > $i).
% 29.22/29.02  tff(decl_35789, type, fn_eudicot_9: $i > $i).
% 29.22/29.02  tff(decl_35790, type, fn_eudicot_10: $i > $i).
% 29.22/29.02  tff(decl_35791, type, fn_eudicot_11: $i > $i).
% 29.22/29.02  tff(decl_35792, type, fn_eudicot_18: $i > $i).
% 29.22/29.02  tff(decl_35793, type, fn_eudicot_19: $i > $i).
% 29.22/29.02  tff(decl_35794, type, fn_eudicot_20: $i > $i).
% 29.22/29.02  tff(decl_35795, type, fn_eudicot_21: $i > $i).
% 29.22/29.02  tff(decl_35796, type, fn_eudicot_22: $i > $i).
% 29.22/29.02  tff(decl_35797, type, fn_eudicot_23: $i > $i).
% 29.22/29.02  tff(decl_35798, type, fn_eudicot_24: $i > $i).
% 29.22/29.02  tff(decl_35799, type, fn_eudicot_25: $i > $i).
% 29.22/29.02  tff(decl_35800, type, fn_eudicot_26: $i > $i).
% 29.22/29.02  tff(decl_35801, type, fn_eudicot_27: $i > $i).
% 29.22/29.02  tff(decl_35802, type, fn_eudicot_28: $i > $i).
% 29.22/29.02  tff(decl_35803, type, fn_eudicot_29: $i > $i).
% 29.22/29.02  tff(decl_35804, type, fn_eudicot_30: $i > $i).
% 29.22/29.02  tff(decl_35805, type, fn_eudicot_31: $i > $i).
% 29.22/29.02  tff(decl_35806, type, fn_eudicot_32: $i > $i).
% 29.22/29.02  tff(decl_35807, type, fn_eudicot_33: $i > $i).
% 29.22/29.02  tff(decl_35808, type, fn_eudicot_34: $i > $i).
% 29.22/29.02  tff(decl_35809, type, fn_eudicot_35: $i > $i).
% 29.22/29.02  tff(decl_35810, type, fn_eudicot_36: $i > $i).
% 29.22/29.02  tff(decl_35811, type, fn_eudicot_37: $i > $i).
% 29.22/29.02  tff(decl_35812, type, fn_eudicot_38: $i > $i).
% 29.22/29.02  tff(decl_35813, type, fn_eudicot_39: $i > $i).
% 29.22/29.02  tff(decl_35814, type, fn_eudicot_40: $i > $i).
% 29.22/29.02  tff(decl_35815, type, fn_eudicot_41: $i > $i).
% 29.22/29.02  tff(decl_35816, type, fn_eudicot_42: $i > $i).
% 29.22/29.02  tff(decl_35817, type, fn_eudicot_43: $i > $i).
% 29.22/29.02  tff(decl_35818, type, fn_eudicot_44: $i > $i).
% 29.22/29.02  tff(decl_35819, type, fn_eudicot_45: $i > $i).
% 29.22/29.02  tff(decl_35820, type, fn_eudicot_46: $i > $i).
% 29.22/29.02  tff(decl_35821, type, fn_eudicot_47: $i > $i).
% 29.22/29.02  tff(decl_35822, type, fn_eudicot_48: $i > $i).
% 29.22/29.02  tff(decl_35823, type, fn_eudicot_49: $i > $i).
% 29.22/29.02  tff(decl_35824, type, fn_eudicot_52: $i > $i).
% 29.22/29.02  tff(decl_35825, type, fn_eudicot_53: $i > $i).
% 29.22/29.02  tff(decl_35826, type, fn_eudicot_54: $i > $i).
% 29.22/29.02  tff(decl_35827, type, fn_eudicot_55: $i > $i).
% 29.22/29.02  tff(decl_35828, type, fn_eudicot_56: $i > $i).
% 29.22/29.02  tff(decl_35829, type, fn_eudicot_57: $i > $i).
% 29.22/29.02  tff(decl_35830, type, fn_eudicot_7: $i > $i).
% 29.22/29.02  tff(decl_35831, type, fn_eudicot_6: $i > $i).
% 29.22/29.02  tff(decl_35832, type, fn_eudicot_14: $i > $i).
% 29.22/29.02  tff(decl_35833, type, fn_eudicot_15: $i > $i).
% 29.22/29.02  tff(decl_35834, type, fn_eudicot_13: $i > $i).
% 29.22/29.02  tff(decl_35835, type, fn_eudicot_12: $i > $i).
% 29.22/29.02  tff(decl_35836, type, fn_eudicot_17: $i > $i).
% 29.22/29.02  tff(decl_35837, type, fn_eudicot_16: $i > $i).
% 29.22/29.02  tff(decl_35838, type, fn_eudicot_50: $i > $i).
% 29.22/29.02  tff(decl_35839, type, fn_eudicot_51: $i > $i).
% 29.22/29.02  tff(decl_35840, type, euglena_1: $i > $o).
% 29.22/29.02  tff(decl_35841, type, 'Euglena': $i).
% 29.22/29.02  tff(decl_35842, type, 'A genus of unicellular protists, of the class Euglenoidea of the phylum Euglenozoa.': $i).
% 29.22/29.02  tff(decl_35843, type, euglena: $i).
% 29.22/29.02  tff(decl_35844, type, euglenid_1: $i > $o).
% 29.22/29.02  tff(decl_35845, type, kinetoplastid_1: $i > $o).
% 29.22/29.02  tff(decl_35846, type, trypanosome_1: $i > $o).
% 29.22/29.02  tff(decl_35847, type, fn_euglena_2: $i > $i).
% 29.22/29.02  tff(decl_35848, type, fn_euglena_3: $i > $i).
% 29.22/29.02  tff(decl_35849, type, fn_euglena_4: $i > $i).
% 29.22/29.02  tff(decl_35850, type, fn_euglena_5: $i > $i).
% 29.22/29.02  tff(decl_35851, type, fn_euglena_6: $i > $i).
% 29.22/29.02  tff(decl_35852, type, fn_euglena_7: $i > $i).
% 29.22/29.02  tff(decl_35853, type, fn_euglena_8: $i > $i).
% 29.22/29.02  tff(decl_35854, type, fn_euglena_9: $i > $i).
% 29.22/29.02  tff(decl_35855, type, fn_euglena_10: $i > $i).
% 29.22/29.02  tff(decl_35856, type, fn_euglena_11: $i > $i).
% 29.22/29.02  tff(decl_35857, type, fn_euglena_12: $i > $i).
% 29.22/29.02  tff(decl_35858, type, fn_euglena_13: $i > $i).
% 29.22/29.02  tff(decl_35859, type, fn_euglena_14: $i > $i).
% 29.22/29.02  tff(decl_35860, type, fn_euglena_15: $i > $i).
% 29.22/29.02  tff(decl_35861, type, fn_euglena_16: $i > $i).
% 29.22/29.02  tff(decl_35862, type, fn_euglena_17: $i > $i).
% 29.22/29.02  tff(decl_35863, type, fn_euglena_18: $i > $i).
% 29.22/29.02  tff(decl_35864, type, fn_euglena_19: $i > $i).
% 29.22/29.02  tff(decl_35865, type, fn_euglena_20: $i > $i).
% 29.22/29.02  tff(decl_35866, type, fn_euglena_21: $i > $i).
% 29.22/29.02  tff(decl_35867, type, fn_euglena_22: $i > $i).
% 29.22/29.02  tff(decl_35868, type, fn_euglena_23: $i > $i).
% 29.22/29.02  tff(decl_35869, type, fn_euglena_24: $i > $i).
% 29.22/29.02  tff(decl_35870, type, fn_euglena_25: $i > $i).
% 29.22/29.02  tff(decl_35871, type, fn_euglena_26: $i > $i).
% 29.22/29.02  tff(decl_35872, type, fn_euglena_27: $i > $i).
% 29.22/29.02  tff(decl_35873, type, fn_euglena_28: $i > $i).
% 29.22/29.02  tff(decl_35874, type, fn_euglena_29: $i > $i).
% 29.22/29.02  tff(decl_35875, type, fn_euglena_30: $i > $i).
% 29.22/29.02  tff(decl_35876, type, fn_euglena_31: $i > $i).
% 29.22/29.02  tff(decl_35877, type, fn_euglena_36: $i > $i).
% 29.22/29.02  tff(decl_35878, type, fn_euglena_37: $i > $i).
% 29.22/29.02  tff(decl_35879, type, biomembrane_0: $i).
% 29.22/29.02  tff(decl_35880, type, fn_euglena_32: $i > $i).
% 29.22/29.02  tff(decl_35881, type, fn_euglenozoan_5: $i > $i).
% 29.22/29.02  tff(decl_35882, type, fn_euglena_34: $i > $i).
% 29.22/29.02  tff(decl_35883, type, fn_euglenozoan_7: $i > $i).
% 29.22/29.02  tff(decl_35884, type, fn_euglenozoan_24: $i > $i).
% 29.22/29.02  tff(decl_35885, type, fn_euglena_35: $i > $i).
% 29.22/29.02  tff(decl_35886, type, fn_euglenozoan_8: $i > $i).
% 29.22/29.02  tff(decl_35887, type, fn_euglena_33: $i > $i).
% 29.22/29.02  tff(decl_35888, type, fn_euglenozoan_6: $i > $i).
% 29.22/29.02  tff(decl_35889, type, fn_euglenozoan_13: $i > $i).
% 29.22/29.02  tff(decl_35890, type, fn_euglenozoan_15: $i > $i).
% 29.22/29.02  tff(decl_35891, type, fn_euglenozoan_23: $i > $i).
% 29.22/29.02  tff(decl_35892, type, fn_euglenozoan_16: $i > $i).
% 29.22/29.02  tff(decl_35893, type, fn_euglenozoan_18: $i > $i).
% 29.22/29.02  tff(decl_35894, type, fn_euglenozoan_10: $i > $i).
% 29.22/29.02  tff(decl_35895, type, fn_euglenozoan_20: $i > $i).
% 29.22/29.03  tff(decl_35896, type, fn_euglenozoan_31: $i > $i).
% 29.22/29.03  tff(decl_35897, type, fn_euglenozoan_19: $i > $i).
% 29.22/29.03  tff(decl_35898, type, fn_euglenozoan_3: $i > $i).
% 29.22/29.03  tff(decl_35899, type, fn_euglenozoan_28: $i > $i).
% 29.22/29.03  tff(decl_35900, type, fn_euglenozoan_14: $i > $i).
% 29.22/29.03  tff(decl_35901, type, fn_euglenozoan_17: $i > $i).
% 29.22/29.03  tff(decl_35902, type, fn_euglenozoan_9: $i > $i).
% 29.22/29.03  tff(decl_35903, type, fn_euglenozoan_34: $i > $i).
% 29.22/29.03  tff(decl_35904, type, fn_euglenozoan_12: $i > $i).
% 29.22/29.03  tff(decl_35905, type, fn_euglenozoan_25: $i > $i).
% 29.22/29.03  tff(decl_35906, type, fn_euglenozoan_11: $i > $i).
% 29.22/29.03  tff(decl_35907, type, fn_euglenozoan_21: $i > $i).
% 29.22/29.03  tff(decl_35908, type, fn_euglenozoan_26: $i > $i).
% 29.22/29.03  tff(decl_35909, type, fn_euglenozoan_22: $i > $i).
% 29.22/29.03  tff(decl_35910, type, fn_euglenozoan_30: $i > $i).
% 29.22/29.03  tff(decl_35911, type, 'Euglenid': $i).
% 29.22/29.03  tff(decl_35912, type, 'Member of a group of flagellated protists, distinguished by the presence of a layer of proteinaceous strips lying under the plasma membrane that give the cell its shape.': $i).
% 29.22/29.03  tff(decl_35913, type, euglenid: $i).
% 29.22/29.03  tff(decl_35914, type, euglenozoan_1: $i > $o).
% 29.22/29.03  tff(decl_35915, type, 'Euglenozoan': $i).
% 29.22/29.03  tff(decl_35916, type, 'Member of a clade of flagellated protists; can be photosynthetic, heterotrophic, or parasitic.': $i).
% 29.22/29.03  tff(decl_35917, type, euglenozoan: $i).
% 29.22/29.03  tff(decl_35918, type, fn_euglenozoan_1: $i > $i).
% 29.22/29.03  tff(decl_35919, type, fn_euglenozoan_2: $i > $i).
% 29.22/29.03  tff(decl_35920, type, fn_euglenozoan_4: $i > $i).
% 29.22/29.03  tff(decl_35921, type, fn_euglenozoan_27: $i > $i).
% 29.22/29.03  tff(decl_35922, type, fn_euglenozoan_29: $i > $i).
% 29.22/29.03  tff(decl_35923, type, fn_euglenozoan_32: $i > $i).
% 29.22/29.03  tff(decl_35924, type, fn_euglenozoan_33: $i > $i).
% 29.22/29.03  tff(decl_35925, type, eukarya_1: $i > $o).
% 29.22/29.03  tff(decl_35926, type, 'Eukarya': $i).
% 29.22/29.03  tff(decl_35927, type, 'The taxonomic category above kingdom level which includes all eukaryotic organisms.': $i).
% 29.22/29.03  tff(decl_35928, type, eukarya: $i).
% 29.22/29.03  tff(decl_35929, type, 'Eukaryote': $i).
% 29.22/29.03  tff(decl_35930, type, 'Living organism composed of one or more cells with a                        distinct nucleus and cytoplasm.': $i).
% 29.22/29.03  tff(decl_35931, type, 'Member of the domain Eukarya, which includes all eukaryotic organisms.': $i).
% 29.22/29.03  tff(decl_35932, type, eukaryote: $i).
% 29.22/29.03  tff(decl_35933, type, 'Eukaryote-DNA-Sequence': $i).
% 29.22/29.03  tff(decl_35934, type, 'A DNA sequence found only in eukaryotes.': $i).
% 29.22/29.03  tff(decl_35935, type, 'eukaryote dna sequence': $i).
% 29.22/29.03  tff(decl_35936, type, 'eukaryote-dna-sequence': $i).
% 29.22/29.03  tff(decl_35937, type, 'Eukaryotic-Calvin-Cycle': $i).
% 29.22/29.03  tff(decl_35938, type, 'It is the calvin cycle taking place in Eukaryotic photosynthetic cell. Here the calvin cycle reactions take place in Stroma.': $i).
% 29.22/29.03  tff(decl_35939, type, 'undergo the eukaryotic calvin cycle': $i).
% 29.22/29.03  tff(decl_35940, type, 'eukaryotic calvin cycle': $i).
% 29.22/29.03  tff(decl_35941, type, 'eukaryotic-calvin-cycle': $i).
% 29.22/29.03  tff(decl_35942, type, fn_eukaryotic_calvin_cycle_3: $i > $i).
% 29.22/29.03  tff(decl_35943, type, fn_eukaryotic_calvin_cycle_4: $i > $i).
% 29.22/29.03  tff(decl_35944, type, fn_eukaryotic_calvin_cycle_5: $i > $i).
% 29.22/29.03  tff(decl_35945, type, fn_eukaryotic_calvin_cycle_8: $i > $i).
% 29.22/29.03  tff(decl_35946, type, fn_eukaryotic_calvin_cycle_9: $i > $i).
% 29.22/29.03  tff(decl_35947, type, fn_eukaryotic_calvin_cycle_16: $i > $i).
% 29.22/29.03  tff(decl_35948, type, fn_eukaryotic_calvin_cycle_17: $i > $i).
% 29.22/29.03  tff(decl_35949, type, fn_eukaryotic_calvin_cycle_18: $i > $i).
% 29.22/29.03  tff(decl_35950, type, fn_eukaryotic_calvin_cycle_19: $i > $i).
% 29.22/29.03  tff(decl_35951, type, fn_eukaryotic_calvin_cycle_20: $i > $i).
% 29.22/29.03  tff(decl_35952, type, fn_eukaryotic_calvin_cycle_21: $i > $i).
% 29.22/29.03  tff(decl_35953, type, fn_eukaryotic_calvin_cycle_22: $i > $i).
% 29.22/29.03  tff(decl_35954, type, fn_eukaryotic_calvin_cycle_23: $i > $i).
% 29.22/29.03  tff(decl_35955, type, fn_eukaryotic_calvin_cycle_24: $i > $i).
% 29.22/29.03  tff(decl_35956, type, fn_eukaryotic_calvin_cycle_25: $i > $i).
% 29.22/29.03  tff(decl_35957, type, fn_eukaryotic_calvin_cycle_26: $i > $i).
% 29.22/29.03  tff(decl_35958, type, fn_eukaryotic_calvin_cycle_27: $i > $i).
% 29.22/29.03  tff(decl_35959, type, fn_eukaryotic_calvin_cycle_28: $i > $i).
% 29.22/29.03  tff(decl_35960, type, fn_eukaryotic_calvin_cycle_29: $i > $i).
% 29.22/29.03  tff(decl_35961, type, fn_eukaryotic_calvin_cycle_30: $i > $i).
% 29.22/29.03  tff(decl_35962, type, fn_eukaryotic_calvin_cycle_31: $i > $i).
% 29.22/29.03  tff(decl_35963, type, fn_eukaryotic_calvin_cycle_32: $i > $i).
% 29.22/29.03  tff(decl_35964, type, fn_eukaryotic_calvin_cycle_33: $i > $i).
% 29.22/29.03  tff(decl_35965, type, fn_eukaryotic_calvin_cycle_34: $i > $i).
% 29.22/29.03  tff(decl_35966, type, fn_eukaryotic_calvin_cycle_35: $i > $i).
% 29.22/29.03  tff(decl_35967, type, fn_eukaryotic_calvin_cycle_36: $i > $i).
% 29.22/29.03  tff(decl_35968, type, fn_eukaryotic_calvin_cycle_38: $i > $i).
% 29.22/29.03  tff(decl_35969, type, fn_eukaryotic_calvin_cycle_41: $i > $i).
% 29.22/29.03  tff(decl_35970, type, fn_eukaryotic_calvin_cycle_42: $i > $i).
% 29.22/29.03  tff(decl_35971, type, fn_eukaryotic_calvin_cycle_44: $i > $i).
% 29.22/29.03  tff(decl_35972, type, fn_eukaryotic_calvin_cycle_45: $i > $i).
% 29.22/29.03  tff(decl_35973, type, fn_eukaryotic_calvin_cycle_46: $i > $i).
% 29.22/29.03  tff(decl_35974, type, fn_eukaryotic_calvin_cycle_47: $i > $i).
% 29.22/29.03  tff(decl_35975, type, fn_eukaryotic_calvin_cycle_49: $i > $i).
% 29.22/29.03  tff(decl_35976, type, fn_eukaryotic_calvin_cycle_50: $i > $i).
% 29.22/29.03  tff(decl_35977, type, fn_eukaryotic_calvin_cycle_51: $i > $i).
% 29.22/29.03  tff(decl_35978, type, fn_eukaryotic_calvin_cycle_52: $i > $i).
% 29.22/29.03  tff(decl_35979, type, fn_eukaryotic_calvin_cycle_53: $i > $i).
% 29.22/29.03  tff(decl_35980, type, fn_eukaryotic_calvin_cycle_54: $i > $i).
% 29.22/29.03  tff(decl_35981, type, fn_eukaryotic_calvin_cycle_55: $i > $i).
% 29.22/29.03  tff(decl_35982, type, fn_eukaryotic_calvin_cycle_56: $i > $i).
% 29.22/29.03  tff(decl_35983, type, fn_eukaryotic_calvin_cycle_57: $i > $i).
% 29.22/29.03  tff(decl_35984, type, fn_eukaryotic_calvin_cycle_58: $i > $i).
% 29.22/29.03  tff(decl_35985, type, fn_eukaryotic_calvin_cycle_59: $i > $i).
% 29.22/29.03  tff(decl_35986, type, fn_eukaryotic_calvin_cycle_60: $i > $i).
% 29.22/29.03  tff(decl_35987, type, fn_eukaryotic_calvin_cycle_61: $i > $i).
% 29.22/29.03  tff(decl_35988, type, fn_eukaryotic_calvin_cycle_64: $i > $i).
% 29.22/29.03  tff(decl_35989, type, fn_eukaryotic_calvin_cycle_66: $i > $i).
% 29.22/29.03  tff(decl_35990, type, fn_eukaryotic_calvin_cycle_68: $i > $i).
% 29.22/29.03  tff(decl_35991, type, fn_three_phosphoglycerate_18: $i > $i).
% 29.22/29.03  tff(decl_35992, type, fn_three_phosphoglycerate_17: $i > $i).
% 29.22/29.03  tff(decl_35993, type, fn_eukaryotic_calvin_cycle_70: $i > $i).
% 29.22/29.03  tff(decl_35994, type, fn_calvin_cycle_1: $i > $i).
% 29.22/29.03  tff(decl_35995, type, fn_eukaryotic_calvin_cycle_71: $i > $i).
% 29.22/29.03  tff(decl_35996, type, fn_calvin_cycle_2: $i > $i).
% 29.22/29.03  tff(decl_35997, type, fn_eukaryotic_calvin_cycle_11: $i > $i).
% 29.22/29.03  tff(decl_35998, type, fn_calvin_cycle_17: $i > $i).
% 29.22/29.03  tff(decl_35999, type, fn_eukaryotic_calvin_cycle_72: $i > $i).
% 29.22/29.03  tff(decl_36000, type, fn_eukaryotic_calvin_cycle_7: $i > $i).
% 29.22/29.03  tff(decl_36001, type, fn_eukaryotic_calvin_cycle_73: $i > $i).
% 29.22/29.03  tff(decl_36002, type, fn_eukaryotic_calvin_cycle_6: $i > $i).
% 29.22/29.03  tff(decl_36003, type, fn_eukaryotic_calvin_cycle_12: $i > $i).
% 29.22/29.03  tff(decl_36004, type, fn_eukaryotic_calvin_cycle_13: $i > $i).
% 29.22/29.03  tff(decl_36005, type, 'Eukaryotic-Cell': $i).
% 29.22/29.03  tff(decl_36006, type, 'Eukaryotic cells contain complex structures enclosed within membranes. Almost all species of large organisms are eukaryotes, including animals, plants and fungi, although most species of eukaryotic protists are microorganisms.The defining membrane-bound structure that sets eukaryotic cells apart from prokaryotic cells is the nucleus. Eukaryotic cells are typically much larger than prokaryotes': $i).
% 29.22/29.03  tff(decl_36007, type, 'eukaryotic cell': $i).
% 29.22/29.03  tff(decl_36008, type, 'eukaryotic-cell': $i).
% 29.22/29.03  tff(decl_36009, type, fn_eukaryotic_cell_1: $i > $i).
% 29.22/29.03  tff(decl_36010, type, fn_eukaryotic_cell_2: $i > $i).
% 29.22/29.03  tff(decl_36011, type, fn_eukaryotic_cell_3: $i > $i).
% 29.22/29.03  tff(decl_36012, type, fn_eukaryotic_cell_13: $i > $i).
% 29.22/29.03  tff(decl_36013, type, fn_eukaryotic_cell_14: $i > $i).
% 29.22/29.03  tff(decl_36014, type, fn_eukaryotic_cell_18: $i > $i).
% 29.22/29.03  tff(decl_36015, type, fn_eukaryotic_cell_22: $i > $i).
% 29.22/29.03  tff(decl_36016, type, fn_eukaryotic_cell_51: $i > $i).
% 29.22/29.03  tff(decl_36017, type, fn_eukaryotic_cell_52: $i > $i).
% 29.22/29.03  tff(decl_36018, type, fn_eukaryotic_cell_54: $i > $i).
% 29.22/29.03  tff(decl_36019, type, fn_eukaryotic_cell_55: $i > $i).
% 29.22/29.03  tff(decl_36020, type, fn_eukaryotic_cell_57: $i > $i).
% 29.22/29.03  tff(decl_36021, type, fn_eukaryotic_cell_58: $i > $i).
% 29.22/29.03  tff(decl_36022, type, fn_mitochondrial_dna_26: $i > $i).
% 29.22/29.03  tff(decl_36023, type, "10.0e0": $i).
% 29.22/29.03  tff(decl_36024, type, fn_eukaryotic_cell_12: $i > $i).
% 29.22/29.03  tff(decl_36025, type, fn_cell_17: $i > $i).
% 29.22/29.03  tff(decl_36026, type, fn_eukaryotic_cell_11: $i > $i).
% 29.22/29.03  tff(decl_36027, type, fn_cell_16: $i > $i).
% 29.22/29.03  tff(decl_36028, type, eukaryotic_cell_cycle_1: $i > $o).
% 29.22/29.03  tff(decl_36029, type, 'Eukaryotic-Cell-Cycle': $i).
% 29.22/29.03  tff(decl_36030, type, 'An ordered sequence of events in the life of a cell, from its origin in the division of a parent cell until its own division into two.  The eukaryotic cell cycle is composed of interphase, (including G1, S & G2 subphases) and M phase (including mitosis and cytokinesis).': $i).
% 29.22/29.03  tff(decl_36031, type, 'undergo the eukaryotic cell cycle': $i).
% 29.22/29.03  tff(decl_36032, type, 'eukaryotic cell cycle': $i).
% 29.22/29.03  tff(decl_36033, type, 'eukaryotic-cell-cycle': $i).
% 29.22/29.03  tff(decl_36034, type, gametogenesis_1: $i > $o).
% 29.22/29.03  tff(decl_36035, type, prokaryotic_cell_cycle_1: $i > $o).
% 29.22/29.03  tff(decl_36036, type, 'Eukaryotic-Cell-Structure': $i).
% 29.22/29.03  tff(decl_36037, type, 'A structure at the cellular level found in Eukaryotes.': $i).
% 29.22/29.03  tff(decl_36038, type, 'structure of eukaryote': $i).
% 29.22/29.03  tff(decl_36039, type, 'structure-of-eukaryote': $i).
% 29.22/29.03  tff(decl_36040, type, 'eukaryote structure': $i).
% 29.22/29.03  tff(decl_36041, type, 'eukaryote-structure': $i).
% 29.22/29.03  tff(decl_36042, type, 'eukaryotic cell structure': $i).
% 29.22/29.03  tff(decl_36043, type, 'eukaryotic-cell-structure': $i).
% 29.22/29.03  tff(decl_36044, type, 'Eukaryotic-Cellular-Respiration': $i).
% 29.22/29.03  tff(decl_36045, type, 'The catabolic pathways of aerobic respiration, which break down organic molecules for the production of ATP. A total of 30 ATP are produced in this process. The step of pyruvate oxidation takes place in mitochondria.': $i).
% 29.22/29.03  tff(decl_36046, type, 'eukaryotic cellular respiration': $i).
% 29.22/29.03  tff(decl_36047, type, 'eukaryotic-cellular-respiration': $i).
% 29.22/29.03  tff(decl_36048, type, fn_eukaryotic_cellular_respiration_1: $i > $i).
% 29.22/29.03  tff(decl_36049, type, fn_eukaryotic_cellular_respiration_2: $i > $i).
% 29.22/29.03  tff(decl_36050, type, fn_eukaryotic_cellular_respiration_3: $i > $i).
% 29.22/29.03  tff(decl_36051, type, fn_eukaryotic_cellular_respiration_4: $i > $i).
% 29.22/29.03  tff(decl_36052, type, fn_eukaryotic_cellular_respiration_5: $i > $i).
% 29.22/29.03  tff(decl_36053, type, fn_eukaryotic_cellular_respiration_6: $i > $i).
% 29.22/29.03  tff(decl_36054, type, fn_eukaryotic_cellular_respiration_7: $i > $i).
% 29.22/29.03  tff(decl_36055, type, fn_eukaryotic_cellular_respiration_8: $i > $i).
% 29.22/29.03  tff(decl_36056, type, fn_eukaryotic_cellular_respiration_9: $i > $i).
% 29.22/29.03  tff(decl_36057, type, fn_eukaryotic_cellular_respiration_10: $i > $i).
% 29.22/29.03  tff(decl_36058, type, fn_eukaryotic_cellular_respiration_11: $i > $i).
% 29.22/29.03  tff(decl_36059, type, fn_eukaryotic_cellular_respiration_12: $i > $i).
% 29.22/29.03  tff(decl_36060, type, fn_eukaryotic_cellular_respiration_13: $i > $i).
% 29.22/29.03  tff(decl_36061, type, fn_eukaryotic_cellular_respiration_14: $i > $i).
% 29.22/29.03  tff(decl_36062, type, fn_eukaryotic_cellular_respiration_22: $i > $i).
% 29.22/29.03  tff(decl_36063, type, fn_eukaryotic_cellular_respiration_24: $i > $i).
% 29.22/29.03  tff(decl_36064, type, fn_eukaryotic_cellular_respiration_25: $i > $i).
% 29.22/29.03  tff(decl_36065, type, fn_eukaryotic_cellular_respiration_26: $i > $i).
% 29.22/29.03  tff(decl_36066, type, fn_eukaryotic_cellular_respiration_27: $i > $i).
% 29.22/29.03  tff(decl_36067, type, fn_eukaryotic_cellular_respiration_28: $i > $i).
% 29.22/29.03  tff(decl_36068, type, fn_eukaryotic_cellular_respiration_29: $i > $i).
% 29.22/29.03  tff(decl_36069, type, fn_eukaryotic_cellular_respiration_30: $i > $i).
% 29.22/29.03  tff(decl_36070, type, fn_eukaryotic_cellular_respiration_31: $i > $i).
% 29.22/29.03  tff(decl_36071, type, fn_eukaryotic_cellular_respiration_32: $i > $i).
% 29.22/29.03  tff(decl_36072, type, fn_eukaryotic_cellular_respiration_33: $i > $i).
% 29.22/29.03  tff(decl_36073, type, fn_eukaryotic_cellular_respiration_34: $i > $i).
% 29.22/29.03  tff(decl_36074, type, fn_eukaryotic_cellular_respiration_35: $i > $i).
% 29.22/29.03  tff(decl_36075, type, fn_eukaryotic_cellular_respiration_36: $i > $i).
% 29.22/29.03  tff(decl_36076, type, fn_eukaryotic_cellular_respiration_37: $i > $i).
% 29.22/29.03  tff(decl_36077, type, fn_eukaryotic_cellular_respiration_38: $i > $i).
% 29.22/29.03  tff(decl_36078, type, fn_eukaryotic_cellular_respiration_39: $i > $i).
% 29.22/29.03  tff(decl_36079, type, fn_eukaryotic_cellular_respiration_40: $i > $i).
% 29.22/29.03  tff(decl_36080, type, fn_eukaryotic_cellular_respiration_41: $i > $i).
% 29.22/29.03  tff(decl_36081, type, fn_eukaryotic_cellular_respiration_49: $i > $i).
% 29.22/29.03  tff(decl_36082, type, fn_eukaryotic_cellular_respiration_50: $i > $i).
% 29.22/29.03  tff(decl_36083, type, fn_eukaryotic_cellular_respiration_51: $i > $i).
% 29.22/29.03  tff(decl_36084, type, fn_eukaryotic_cellular_respiration_52: $i > $i).
% 29.22/29.03  tff(decl_36085, type, fn_eukaryotic_cellular_respiration_53: $i > $i).
% 29.22/29.03  tff(decl_36086, type, fn_eukaryotic_cellular_respiration_54: $i > $i).
% 29.22/29.03  tff(decl_36087, type, fn_eukaryotic_cellular_respiration_55: $i > $i).
% 29.22/29.03  tff(decl_36088, type, fn_eukaryotic_cellular_respiration_56: $i > $i).
% 29.22/29.03  tff(decl_36089, type, fn_eukaryotic_cellular_respiration_57: $i > $i).
% 29.22/29.03  tff(decl_36090, type, fn_eukaryotic_cellular_respiration_58: $i > $i).
% 29.22/29.03  tff(decl_36091, type, fn_eukaryotic_cellular_respiration_63: $i > $i).
% 29.22/29.03  tff(decl_36092, type, fn_eukaryotic_cellular_respiration_66: $i > $i).
% 29.22/29.03  tff(decl_36093, type, fn_eukaryotic_cellular_respiration_67: $i > $i).
% 29.22/29.03  tff(decl_36094, type, fn_eukaryotic_cellular_respiration_69: $i > $i).
% 29.22/29.03  tff(decl_36095, type, fn_eukaryotic_cellular_respiration_70: $i > $i).
% 29.22/29.03  tff(decl_36096, type, fn_eukaryotic_cellular_respiration_71: $i > $i).
% 29.22/29.03  tff(decl_36097, type, fn_eukaryotic_cellular_respiration_72: $i > $i).
% 29.22/29.03  tff(decl_36098, type, fn_eukaryotic_cellular_respiration_73: $i > $i).
% 29.22/29.03  tff(decl_36099, type, fn_eukaryotic_cellular_respiration_74: $i > $i).
% 29.22/29.03  tff(decl_36100, type, fn_eukaryotic_cellular_respiration_75: $i > $i).
% 29.22/29.03  tff(decl_36101, type, fn_eukaryotic_cellular_respiration_76: $i > $i).
% 29.22/29.03  tff(decl_36102, type, fn_eukaryotic_cellular_respiration_77: $i > $i).
% 29.22/29.03  tff(decl_36103, type, fn_eukaryotic_cellular_respiration_78: $i > $i).
% 29.22/29.03  tff(decl_36104, type, fn_eukaryotic_cellular_respiration_80: $i > $i).
% 29.22/29.03  tff(decl_36105, type, fn_eukaryotic_cellular_respiration_83: $i > $i).
% 29.22/29.03  tff(decl_36106, type, fn_eukaryotic_cellular_respiration_84: $i > $i).
% 29.22/29.03  tff(decl_36107, type, fn_eukaryotic_cellular_respiration_85: $i > $i).
% 29.22/29.03  tff(decl_36108, type, fn_eukaryotic_cellular_respiration_86: $i > $i).
% 29.22/29.03  tff(decl_36109, type, fn_eukaryotic_cellular_respiration_87: $i > $i).
% 29.22/29.03  tff(decl_36110, type, fn_eukaryotic_cellular_respiration_88: $i > $i).
% 29.22/29.03  tff(decl_36111, type, fn_eukaryotic_cellular_respiration_89: $i > $i).
% 29.22/29.03  tff(decl_36112, type, fn_eukaryotic_cellular_respiration_90: $i > $i).
% 29.22/29.03  tff(decl_36113, type, fn_eukaryotic_cellular_respiration_91: $i > $i).
% 29.22/29.03  tff(decl_36114, type, fn_eukaryotic_cellular_respiration_92: $i > $i).
% 29.22/29.03  tff(decl_36115, type, fn_eukaryotic_cellular_respiration_93: $i > $i).
% 29.22/29.03  tff(decl_36116, type, fn_eukaryotic_cellular_respiration_98: $i > $i).
% 29.22/29.03  tff(decl_36117, type, fn_eukaryotic_cellular_respiration_100: $i > $i).
% 29.22/29.03  tff(decl_36118, type, fn_eukaryotic_cellular_respiration_102: $i > $i).
% 29.22/29.03  tff(decl_36119, type, fn_eukaryotic_cellular_respiration_105: $i > $i).
% 29.22/29.03  tff(decl_36120, type, fn_eukaryotic_cellular_respiration_106: $i > $i).
% 29.22/29.03  tff(decl_36121, type, fn_eukaryotic_cellular_respiration_107: $i > $i).
% 29.22/29.03  tff(decl_36122, type, fn_eukaryotic_cellular_respiration_108: $i > $i).
% 29.22/29.03  tff(decl_36123, type, fn_eukaryotic_cellular_respiration_109: $i > $i).
% 29.22/29.03  tff(decl_36124, type, fn_eukaryotic_cellular_respiration_110: $i > $i).
% 29.22/29.03  tff(decl_36125, type, fn_eukaryotic_cellular_respiration_114: $i > $i).
% 29.22/29.03  tff(decl_36126, type, fn_eukaryotic_cellular_respiration_120: $i > $i).
% 29.22/29.03  tff(decl_36127, type, fn_eukaryotic_cellular_respiration_121: $i > $i).
% 29.22/29.03  tff(decl_36128, type, fn_eukaryotic_cellular_respiration_122: $i > $i).
% 29.22/29.03  tff(decl_36129, type, fn_eukaryotic_cellular_respiration_123: $i > $i).
% 29.22/29.03  tff(decl_36130, type, fn_eukaryotic_cellular_respiration_124: $i > $i).
% 29.22/29.03  tff(decl_36131, type, fn_eukaryotic_cellular_respiration_125: $i > $i).
% 29.22/29.03  tff(decl_36132, type, fn_eukaryotic_cellular_respiration_126: $i > $i).
% 29.22/29.03  tff(decl_36133, type, fn_eukaryotic_cellular_respiration_127: $i > $i).
% 29.22/29.03  tff(decl_36134, type, fn_eukaryotic_cellular_respiration_128: $i > $i).
% 29.22/29.03  tff(decl_36135, type, fn_eukaryotic_cellular_respiration_129: $i > $i).
% 29.22/29.03  tff(decl_36136, type, fn_eukaryotic_cellular_respiration_130: $i > $i).
% 29.22/29.03  tff(decl_36137, type, fn_eukaryotic_cellular_respiration_132: $i > $i).
% 29.22/29.03  tff(decl_36138, type, fn_eukaryotic_cellular_respiration_133: $i > $i).
% 29.22/29.03  tff(decl_36139, type, fn_eukaryotic_cellular_respiration_134: $i > $i).
% 29.22/29.03  tff(decl_36140, type, fn_eukaryotic_cellular_respiration_135: $i > $i).
% 29.22/29.03  tff(decl_36141, type, fn_eukaryotic_cellular_respiration_137: $i > $i).
% 29.22/29.03  tff(decl_36142, type, fn_eukaryotic_cellular_respiration_138: $i > $i).
% 29.22/29.03  tff(decl_36143, type, fn_eukaryotic_cellular_respiration_142: $i > $i).
% 29.22/29.03  tff(decl_36144, type, fn_eukaryotic_cellular_respiration_146: $i > $i).
% 29.22/29.03  tff(decl_36145, type, fn_eukaryotic_cellular_respiration_147: $i > $i).
% 29.22/29.03  tff(decl_36146, type, fn_eukaryotic_cellular_respiration_148: $i > $i).
% 29.22/29.03  tff(decl_36147, type, fn_eukaryotic_cellular_respiration_151: $i > $i).
% 29.22/29.03  tff(decl_36148, type, fn_eukaryotic_cellular_respiration_152: $i > $i).
% 29.22/29.03  tff(decl_36149, type, fn_eukaryotic_cellular_respiration_156: $i > $i).
% 29.22/29.03  tff(decl_36150, type, fn_glycolysis_100: $i > $i).
% 29.22/29.03  tff(decl_36151, type, fn_pyruvate_oxidation_1: $i > $i).
% 29.22/29.03  tff(decl_36152, type, fn_pyruvate_oxidation_50: $i > $i).
% 29.22/29.03  tff(decl_36153, type, fn_eukaryotic_oxidative_phosphorylation_374: $i > $i).
% 29.22/29.03  tff(decl_36154, type, fn_mitochondrial_membrane_20: $i > $i).
% 29.22/29.03  tff(decl_36155, type, fn_mitochondrial_membrane_33: $i > $i).
% 29.22/29.03  tff(decl_36156, type, fn_nadh_10: $i > $i).
% 29.22/29.03  tff(decl_36157, type, fn_nadh_9: $i > $i).
% 29.22/29.03  tff(decl_36158, type, fn_nadh_12: $i > $i).
% 29.22/29.03  tff(decl_36159, type, fn_nadh_7: $i > $i).
% 29.22/29.03  tff(decl_36160, type, fn_nadh_13: $i > $i).
% 29.22/29.03  tff(decl_36161, type, fn_nadh_6: $i > $i).
% 29.22/29.03  tff(decl_36162, type, fn_mitochondrion_18: $i > $i).
% 29.22/29.03  tff(decl_36163, type, fn_mitochondrion_88: $i > $i).
% 29.22/29.03  tff(decl_36164, type, fn_mitochondrion_146: $i > $i).
% 29.22/29.03  tff(decl_36165, type, fn_oxidative_phosphorylation_44: $i > $i).
% 29.22/29.03  tff(decl_36166, type, fn_mitochondrion_78: $i > $i).
% 29.22/29.03  tff(decl_36167, type, fn_oxidative_phosphorylation_19: $i > $i).
% 29.22/29.03  tff(decl_36168, type, fn_mitochondrion_137: $i > $i).
% 29.22/29.03  tff(decl_36169, type, fn_eukaryotic_oxidative_phosphorylation_186: $i > $i).
% 29.22/29.03  tff(decl_36170, type, fn_eukaryotic_oxidative_phosphorylation_335: $i > $i).
% 29.22/29.03  tff(decl_36171, type, fn_mitochondrion_153: $i > $i).
% 29.22/29.03  tff(decl_36172, type, fn_oxidative_phosphorylation_17: $i > $i).
% 29.22/29.03  tff(decl_36173, type, fn_eukaryotic_oxidative_phosphorylation_333: $i > $i).
% 29.22/29.03  tff(decl_36174, type, fn_mitochondrion_77: $i > $i).
% 29.22/29.03  tff(decl_36175, type, fn_oxidative_phosphorylation_43: $i > $i).
% 29.22/29.03  tff(decl_36176, type, fn_eukaryotic_oxidative_phosphorylation_187: $i > $i).
% 29.22/29.03  tff(decl_36177, type, fn_mitochondrion_67: $i > $i).
% 29.22/29.03  tff(decl_36178, type, fn_eukaryotic_oxidative_phosphorylation_203: $i > $i).
% 29.22/29.03  tff(decl_36179, type, fn_eukaryotic_oxidative_phosphorylation_191: $i > $i).
% 29.22/29.03  tff(decl_36180, type, fn_oxidative_phosphorylation_27: $i > $i).
% 29.22/29.03  tff(decl_36181, type, fn_eukaryotic_oxidative_phosphorylation_184: $i > $i).
% 29.22/29.03  tff(decl_36182, type, fn_oxidative_phosphorylation_24: $i > $i).
% 29.22/29.03  tff(decl_36183, type, fn_oxidative_phosphorylation_20: $i > $i).
% 29.22/29.03  tff(decl_36184, type, fn_eukaryotic_oxidative_phosphorylation_323: $i > $i).
% 29.22/29.03  tff(decl_36185, type, fn_oxidative_phosphorylation_48: $i > $i).
% 29.22/29.03  tff(decl_36186, type, fn_eukaryotic_oxidative_phosphorylation_328: $i > $i).
% 29.22/29.03  tff(decl_36187, type, fn_eukaryotic_oxidative_phosphorylation_373: $i > $i).
% 29.22/29.03  tff(decl_36188, type, fn_eukaryotic_oxidative_phosphorylation_375: $i > $i).
% 29.22/29.03  tff(decl_36189, type, fn_eukaryotic_oxidative_phosphorylation_197: $i > $i).
% 29.22/29.03  tff(decl_36190, type, fn_mitochondrion_138: $i > $i).
% 29.22/29.03  tff(decl_36191, type, fn_oxidative_phosphorylation_40: $i > $i).
% 29.22/29.03  tff(decl_36192, type, fn_eukaryotic_oxidative_phosphorylation_185: $i > $i).
% 29.22/29.03  tff(decl_36193, type, fn_eukaryotic_oxidative_phosphorylation_117: $i > $i).
% 29.22/29.03  tff(decl_36194, type, fn_eukaryotic_oxidative_phosphorylation_204: $i > $i).
% 29.22/29.03  tff(decl_36195, type, fn_eukaryotic_oxidative_phosphorylation_325: $i > $i).
% 29.22/29.03  tff(decl_36196, type, fn_oxidative_phosphorylation_45: $i > $i).
% 29.22/29.03  tff(decl_36197, type, fn_eukaryotic_oxidative_phosphorylation_329: $i > $i).
% 29.22/29.03  tff(decl_36198, type, fn_eukaryotic_oxidative_phosphorylation_331: $i > $i).
% 29.22/29.03  tff(decl_36199, type, fn_mitochondrion_74: $i > $i).
% 29.22/29.03  tff(decl_36200, type, fn_oxidative_phosphorylation_18: $i > $i).
% 29.22/29.03  tff(decl_36201, type, fn_eukaryotic_oxidative_phosphorylation_327: $i > $i).
% 29.22/29.03  tff(decl_36202, type, fn_mitochondrion_90: $i > $i).
% 29.22/29.03  tff(decl_36203, type, fn_mitochondrial_membrane_86: $i > $i).
% 29.22/29.03  tff(decl_36204, type, fn_mitochondrion_110: $i > $i).
% 29.22/29.03  tff(decl_36205, type, fn_mitochondrial_membrane_31: $i > $i).
% 29.22/29.03  tff(decl_36206, type, fn_eukaryotic_oxidative_phosphorylation_322: $i > $i).
% 29.22/29.03  tff(decl_36207, type, fn_mitochondrial_membrane_32: $i > $i).
% 29.22/29.03  tff(decl_36208, type, fn_mitochondrial_membrane_43: $i > $i).
% 29.22/29.03  tff(decl_36209, type, fn_mitochondrial_membrane_19: $i > $i).
% 29.22/29.03  tff(decl_36210, type, fn_mitochondrial_membrane_18: $i > $i).
% 29.22/29.03  tff(decl_36211, type, fn_mitochondrial_membrane_52: $i > $i).
% 29.22/29.03  tff(decl_36212, type, fn_mitochondrion_89: $i > $i).
% 29.22/29.03  tff(decl_36213, type, fn_mitochondrial_membrane_84: $i > $i).
% 29.22/29.03  tff(decl_36214, type, fn_mitochondrial_membrane_7: $i > $i).
% 29.22/29.03  tff(decl_36215, type, fn_mitochondrion_120: $i > $i).
% 29.22/29.03  tff(decl_36216, type, fn_eukaryotic_oxidative_phosphorylation_383: $i > $i).
% 29.22/29.03  tff(decl_36217, type, fn_mitochondrial_membrane_74: $i > $i).
% 29.22/29.03  tff(decl_36218, type, fn_mitochondrion_121: $i > $i).
% 29.22/29.03  tff(decl_36219, type, fn_eukaryotic_oxidative_phosphorylation_87: $i > $i).
% 29.22/29.03  tff(decl_36220, type, fn_mitochondrial_membrane_75: $i > $i).
% 29.22/29.03  tff(decl_36221, type, fn_eukaryotic_oxidative_phosphorylation_384: $i > $i).
% 29.22/29.03  tff(decl_36222, type, fn_mitochondrial_membrane_30: $i > $i).
% 29.22/29.03  tff(decl_36223, type, fn_eukaryotic_oxidative_phosphorylation_326: $i > $i).
% 29.22/29.03  tff(decl_36224, type, fn_pyruvate_oxidation_81: $i > $i).
% 29.22/29.03  tff(decl_36225, type, fn_mitochondrial_membrane_67: $i > $i).
% 29.22/29.03  tff(decl_36226, type, fn_eukaryotic_oxidative_phosphorylation_188: $i > $i).
% 29.22/29.03  tff(decl_36227, type, fn_mitochondrial_membrane_69: $i > $i).
% 29.22/29.03  tff(decl_36228, type, fn_oxidative_phosphorylation_33: $i > $i).
% 29.22/29.03  tff(decl_36229, type, fn_eukaryotic_oxidative_phosphorylation_200: $i > $i).
% 29.22/29.03  tff(decl_36230, type, fn_mitochondrion_70: $i > $i).
% 29.22/29.03  tff(decl_36231, type, fn_eukaryotic_oxidative_phosphorylation_199: $i > $i).
% 29.22/29.03  tff(decl_36232, type, fn_mitochondrial_membrane_72: $i > $i).
% 29.22/29.03  tff(decl_36233, type, fn_eukaryotic_oxidative_phosphorylation_198: $i > $i).
% 29.22/29.03  tff(decl_36234, type, fn_mitochondrion_59: $i > $i).
% 29.22/29.03  tff(decl_36235, type, fn_oxidative_phosphorylation_14: $i > $i).
% 29.22/29.03  tff(decl_36236, type, fn_eukaryotic_oxidative_phosphorylation_118: $i > $i).
% 29.22/29.03  tff(decl_36237, type, fn_eukaryotic_oxidative_phosphorylation_192: $i > $i).
% 29.22/29.03  tff(decl_36238, type, fn_mitochondrial_membrane_36: $i > $i).
% 29.22/29.03  tff(decl_36239, type, fn_eukaryotic_oxidative_phosphorylation_336: $i > $i).
% 29.22/29.03  tff(decl_36240, type, 'MT2': $i).
% 29.22/29.03  tff(decl_36241, type, fn_eukaryotic_cellular_respiration_158: $i > $i).
% 29.22/29.03  tff(decl_36242, type, fn_cellular_respiration_11: $i > $i).
% 29.22/29.03  tff(decl_36243, type, fn_eukaryotic_cellular_respiration_115: $i > $i).
% 29.22/29.03  tff(decl_36244, type, fn_eukaryotic_cellular_respiration_113: $i > $i).
% 29.22/29.03  tff(decl_36245, type, fn_eukaryotic_cellular_respiration_81: $i > $i).
% 29.22/29.03  tff(decl_36246, type, fn_eukaryotic_cellular_respiration_43: $i > $i).
% 29.22/29.03  tff(decl_36247, type, fn_eukaryotic_cellular_respiration_44: $i > $i).
% 29.22/29.03  tff(decl_36248, type, fn_eukaryotic_cellular_respiration_155: $i > $i).
% 29.22/29.03  tff(decl_36249, type, fn_eukaryotic_cellular_respiration_154: $i > $i).
% 29.22/29.03  tff(decl_36250, type, fn_eukaryotic_cellular_respiration_45: $i > $i).
% 29.22/29.03  tff(decl_36251, type, fn_eukaryotic_cellular_respiration_46: $i > $i).
% 29.22/29.03  tff(decl_36252, type, fn_eukaryotic_cellular_respiration_16: $i > $i).
% 29.22/29.03  tff(decl_36253, type, fn_eukaryotic_cellular_respiration_17: $i > $i).
% 29.22/29.03  tff(decl_36254, type, fn_eukaryotic_cellular_respiration_21: $i > $i).
% 29.22/29.03  tff(decl_36255, type, fn_eukaryotic_cellular_respiration_18: $i > $i).
% 29.22/29.03  tff(decl_36256, type, fn_eukaryotic_cellular_respiration_19: $i > $i).
% 29.22/29.03  tff(decl_36257, type, fn_eukaryotic_cellular_respiration_20: $i > $i).
% 29.22/29.03  tff(decl_36258, type, 'Eukaryotic-Chromatin': $i).
% 29.22/29.03  tff(decl_36259, type, 'The genetic material composed of DNA and histone protein that condense to form chromosomes during eukaryotic cell division.': $i).
% 29.22/29.03  tff(decl_36260, type, 'eukaryotic chromatin': $i).
% 29.22/29.03  tff(decl_36261, type, 'eukaryotic-chromatin': $i).
% 29.22/29.03  tff(decl_36262, type, prokaryotic_chromatin_1: $i > $o).
% 29.22/29.03  tff(decl_36263, type, fn_eukaryotic_chromatin_3: $i > $i).
% 29.22/29.03  tff(decl_36264, type, fn_eukaryotic_chromatin_5: $i > $i).
% 29.22/29.03  tff(decl_36265, type, fn_eukaryotic_chromatin_6: $i > $i).
% 29.22/29.03  tff(decl_36266, type, fn_eukaryotic_chromatin_7: $i > $i).
% 29.22/29.03  tff(decl_36267, type, fn_eukaryotic_chromatin_15: $i > $i).
% 29.22/29.03  tff(decl_36268, type, prokaryotic_chromatin_0: $i).
% 29.22/29.03  tff(decl_36269, type, 'Eukaryotic-Chromosome': $i).
% 29.22/29.03  tff(decl_36270, type, 'A chromosome present in eukaryotic cells.': $i).
% 29.22/29.03  tff(decl_36271, type, 'eukaryotic chromosome': $i).
% 29.22/29.03  tff(decl_36272, type, 'eukaryotic-chromosome': $i).
% 29.22/29.03  tff(decl_36273, type, fn_eukaryotic_chromosome_6: $i > $i).
% 29.22/29.03  tff(decl_36274, type, nucleic_acid_0: $i).
% 29.22/29.03  tff(decl_36275, type, fn_eukaryotic_chromosome_7: $i > $i).
% 29.22/29.03  tff(decl_36276, type, eukaryotic_cilium_1: $i > $o).
% 29.22/29.03  tff(decl_36277, type, 'Eukaryotic-Cilium': $i).
% 29.22/29.03  tff(decl_36278, type, 'Cilium present on the eukaryotic cell.': $i).
% 29.22/29.03  tff(decl_36279, type, 'eukaryotic cilia': $i).
% 29.22/29.03  tff(decl_36280, type, 'eukaryotic cilium': $i).
% 29.22/29.03  tff(decl_36281, type, 'eukaryotic-cilium': $i).
% 29.22/29.03  tff(decl_36282, type, fn_eukaryotic_cilium_1: $i > $i).
% 29.22/29.03  tff(decl_36283, type, fn_eukaryotic_cilium_2: $i > $i).
% 29.22/29.03  tff(decl_36284, type, fn_eukaryotic_cilium_3: $i > $i).
% 29.22/29.03  tff(decl_36285, type, fn_eukaryotic_cilium_4: $i > $i).
% 29.22/29.03  tff(decl_36286, type, fn_eukaryotic_cilium_5: $i > $i).
% 29.22/29.03  tff(decl_36287, type, fn_eukaryotic_cilium_6: $i > $i).
% 29.22/29.03  tff(decl_36288, type, microtubule_doublet_0: $i).
% 29.22/29.03  tff(decl_36289, type, 'MD2': $i).
% 29.22/29.03  tff(decl_36290, type, 'MD1': $i).
% 29.22/29.03  tff(decl_36291, type, 'Eukaryotic-Clade': $i).
% 29.22/29.03  tff(decl_36292, type, 'The group of eukaryotic species that includes an ancestral species and all its descendants.': $i).
% 29.22/29.03  tff(decl_36293, type, 'eukaryotic clade': $i).
% 29.22/29.03  tff(decl_36294, type, 'eukaryotic-clade': $i).
% 29.22/29.03  tff(decl_36295, type, eukaryotic_flagellum_1: $i > $o).
% 29.22/29.03  tff(decl_36296, type, 'Eukaryotic-Flagellum': $i).
% 29.22/29.03  tff(decl_36297, type, 'Flagellum present at the eukaryotic cell.': $i).
% 29.22/29.03  tff(decl_36298, type, 'eukaryotic flagellum': $i).
% 29.22/29.03  tff(decl_36299, type, 'eukaryotic-flagellum': $i).
% 29.22/29.03  tff(decl_36300, type, fn_eukaryotic_flagellum_1: $i > $i).
% 29.22/29.03  tff(decl_36301, type, 'Eukaryotic-Gene': $i).
% 29.22/29.03  tff(decl_36302, type, 'A gene of a eukaryotic organism.': $i).
% 29.22/29.03  tff(decl_36303, type, 'eukaryotic gene': $i).
% 29.22/29.03  tff(decl_36304, type, 'eukaryotic-gene': $i).
% 29.22/29.03  tff(decl_36305, type, eukaryotic_gene_activation_1: $i > $o).
% 29.22/29.03  tff(decl_36306, type, 'Eukaryotic-Gene-Activation': $i).
% 29.22/29.03  tff(decl_36307, type, 'The process of activation of a eukaryotic gene so that it is expressed at a particular time and location.': $i).
% 29.22/29.03  tff(decl_36308, type, 'eukaryotic gene activation': $i).
% 29.22/29.03  tff(decl_36309, type, 'eukaryotic-gene-activation': $i).
% 29.22/29.03  tff(decl_36310, type, fn_eukaryotic_gene_activation_1: $i > $i).
% 29.22/29.03  tff(decl_36311, type, fn_eukaryotic_gene_expression_1: $i > $i).
% 29.22/29.03  tff(decl_36312, type, 'Eukaryotic-Gene-Expression': $i).
% 29.22/29.03  tff(decl_36313, type, 'The process by which DNA directs the synthesis of proteins or, in some cases, just RNAs, in eukaryotic cells.': $i).
% 29.22/29.03  tff(decl_36314, type, 'eukaryotic gene expression': $i).
% 29.22/29.03  tff(decl_36315, type, 'eukaryotic-gene-expression': $i).
% 29.22/29.03  tff(decl_36316, type, 'Eukaryotic-Gene-Regulation': $i).
% 29.22/29.03  tff(decl_36317, type, 'The regulation of gene transcription in eukaryotic cells.': $i).
% 29.22/29.03  tff(decl_36318, type, 'eukaryotic regulation of transcription': $i).
% 29.22/29.03  tff(decl_36319, type, 'eukaryotic transcription regulation': $i).
% 29.22/29.03  tff(decl_36320, type, 'eukaryotic gene regulation': $i).
% 29.22/29.03  tff(decl_36321, type, 'eukaryotic-gene-regulation': $i).
% 29.22/29.03  tff(decl_36322, type, fn_eukaryotic_gene_regulation_1: $i > $i).
% 29.22/29.03  tff(decl_36323, type, 'Eukaryotic-Genome': $i).
% 29.22/29.03  tff(decl_36324, type, 'The complete complement of a eukaryotic organism\\s genes along with its noncoding nucleic acid sequences.': $i).
% 29.22/29.03  tff(decl_36325, type, 'eukaryotic genome': $i).
% 29.22/29.03  tff(decl_36326, type, 'eukaryotic-genome': $i).
% 29.22/29.03  tff(decl_36327, type, eukaryotic_lagging_strand_1: $i > $o).
% 29.22/29.03  tff(decl_36328, type, 'Eukaryotic-Lagging-Strand': $i).
% 29.22/29.03  tff(decl_36329, type, 'The eukaryotic lagging strand is the new discontinuous complementary DNA strand synthesized along the template strand as the overall direction of replication is opposite to the lagging strand\\s 5\\ to 3\\ direction.': $i).
% 29.22/29.03  tff(decl_36330, type, 'eukaryotic lagging strand': $i).
% 29.22/29.03  tff(decl_36331, type, 'eukaryotic-lagging-strand': $i).
% 29.22/29.03  tff(decl_36332, type, fn_eukaryotic_lagging_strand_1: $i > $i).
% 29.22/29.03  tff(decl_36333, type, fn_eukaryotic_lagging_strand_2: $i > $i).
% 29.22/29.03  tff(decl_36334, type, fn_eukaryotic_lagging_strand_3: $i > $i).
% 29.22/29.03  tff(decl_36335, type, fn_eukaryotic_lagging_strand_4: $i > $i).
% 29.22/29.03  tff(decl_36336, type, fn_eukaryotic_lagging_strand_5: $i > $i).
% 29.22/29.03  tff(decl_36337, type, fn_eukaryotic_lagging_strand_6: $i > $i).
% 29.22/29.03  tff(decl_36338, type, fn_eukaryotic_lagging_strand_7: $i > $i).
% 29.22/29.03  tff(decl_36339, type, fn_nucleoside_8: $i > $i).
% 29.22/29.03  tff(decl_36340, type, eukaryotic_light_reaction_1: $i > $o).
% 29.22/29.03  tff(decl_36341, type, 'Eukaryotic-Light-Reaction': $i).
% 29.22/29.03  tff(decl_36342, type, 'The light-dependent reactions of photosynthesis in a eukaryotic organism.': $i).
% 29.22/29.03  tff(decl_36343, type, 'eukaryotic light reaction': $i).
% 29.22/29.03  tff(decl_36344, type, 'eukaryotic-light-reaction': $i).
% 29.22/29.03  tff(decl_36345, type, fn_eukaryotic_light_reaction_1: $i > $i).
% 29.22/29.03  tff(decl_36346, type, fn_eukaryotic_light_reaction_2: $i > $i).
% 29.22/29.03  tff(decl_36347, type, fn_eukaryotic_light_reaction_3: $i > $i).
% 29.22/29.03  tff(decl_36348, type, fn_eukaryotic_light_reaction_4: $i > $i).
% 29.22/29.03  tff(decl_36349, type, fn_eukaryotic_light_reaction_5: $i > $i).
% 29.22/29.03  tff(decl_36350, type, fn_eukaryotic_light_reaction_6: $i > $i).
% 29.22/29.03  tff(decl_36351, type, fn_eukaryotic_light_reaction_7: $i > $i).
% 29.22/29.03  tff(decl_36352, type, fn_eukaryotic_light_reaction_8: $i > $i).
% 29.22/29.03  tff(decl_36353, type, fn_eukaryotic_light_reaction_9: $i > $i).
% 29.22/29.03  tff(decl_36354, type, fn_eukaryotic_light_reaction_10: $i > $i).
% 29.22/29.03  tff(decl_36355, type, fn_eukaryotic_light_reaction_11: $i > $i).
% 29.22/29.03  tff(decl_36356, type, fn_eukaryotic_light_reaction_12: $i > $i).
% 29.22/29.03  tff(decl_36357, type, fn_eukaryotic_light_reaction_13: $i > $i).
% 29.22/29.03  tff(decl_36358, type, fn_eukaryotic_light_reaction_14: $i > $i).
% 29.22/29.03  tff(decl_36359, type, fn_eukaryotic_light_reaction_15: $i > $i).
% 29.22/29.03  tff(decl_36360, type, fn_eukaryotic_light_reaction_16: $i > $i).
% 29.22/29.03  tff(decl_36361, type, fn_eukaryotic_light_reaction_17: $i > $i).
% 29.22/29.03  tff(decl_36362, type, fn_eukaryotic_light_reaction_18: $i > $i).
% 29.22/29.03  tff(decl_36363, type, fn_thylakoid_space_4: $i > $i).
% 29.22/29.03  tff(decl_36364, type, fn_granum_2: $i > $i).
% 29.22/29.03  tff(decl_36365, type, fn_granum_3: $i > $i).
% 29.22/29.03  tff(decl_36366, type, fn_granum_1: $i > $i).
% 29.22/29.03  tff(decl_36367, type, fn_facilitated_diffusion_of_ion_27: $i > $i).
% 29.22/29.03  tff(decl_36368, type, fn_thylakoid_space_3: $i > $i).
% 29.22/29.03  tff(decl_36369, type, fn_thylakoid_space_2: $i > $i).
% 29.22/29.03  tff(decl_36370, type, eukaryotic_light_reaction_with_cyclic_electron_flow_1: $i > $o).
% 29.22/29.03  tff(decl_36371, type, 'Eukaryotic-Light-Reaction-With-Cyclic-Electron-Flow': $i).
% 29.22/29.03  tff(decl_36372, type, 'The flow of electrons from Photosystem I to ferredoxin to cytochrome complex to plastocyanin and back to Photosystem I.': $i).
% 29.22/29.03  tff(decl_36373, type, 'eukaryotic light reaction with cyclic electron flow': $i).
% 29.22/29.03  tff(decl_36374, type, 'eukaryotic-light-reaction-with-cyclic-electron-flow': $i).
% 29.22/29.03  tff(decl_36375, type, fn_eukaryotic_light_reaction_with_cyclic_electron_flow_1: $i > $i).
% 29.22/29.03  tff(decl_36376, type, eukaryotic_light_reaction_with_linear_electron_flow_1: $i > $o).
% 29.22/29.03  tff(decl_36377, type, 'Eukaryotic-Light-Reaction-With-Linear-Electron-Flow': $i).
% 29.22/29.03  tff(decl_36378, type, 'The path of electron flow through Photosystems I and II during the light-dependent reactions of photosynthesis in eukaryotic organisms. Linear electron flow produces ATP, NAPDH, and O2.': $i).
% 29.22/29.03  tff(decl_36379, type, 'eukaryotic light reaction with linear electron flow': $i).
% 29.22/29.03  tff(decl_36380, type, 'eukaryotic-light-reaction-with-linear-electron-flow': $i).
% 29.22/29.03  tff(decl_36381, type, fn_eukaryotic_light_reaction_with_linear_electron_flow_1: $i > $i).
% 29.22/29.03  tff(decl_36382, type, 'Eukaryotic-Oxidative-Phosphorylation': $i).
% 29.22/29.03  tff(decl_36383, type, 'Oxidative phosphorylation in eukaryote is a metabolic pathway that uses energy released by the oxidation of nutrients to produce adenosine triphosphate (ATP) in eukaryote.': $i).
% 29.22/29.03  tff(decl_36384, type, 'eukaryotic oxidative phosphorylation': $i).
% 29.22/29.03  tff(decl_36385, type, 'eukaryotic-oxidative-phosphorylation': $i).
% 29.22/29.03  tff(decl_36386, type, prokaryotic_oxidative_phosphorylation_1: $i > $o).
% 29.22/29.03  tff(decl_36387, type, fn_eukaryotic_oxidative_phosphorylation_6: $i > $i).
% 29.22/29.03  tff(decl_36388, type, fn_eukaryotic_oxidative_phosphorylation_7: $i > $i).
% 29.22/29.03  tff(decl_36389, type, fn_eukaryotic_oxidative_phosphorylation_8: $i > $i).
% 29.22/29.03  tff(decl_36390, type, fn_eukaryotic_oxidative_phosphorylation_9: $i > $i).
% 29.22/29.03  tff(decl_36391, type, fn_eukaryotic_oxidative_phosphorylation_10: $i > $i).
% 29.22/29.03  tff(decl_36392, type, fn_eukaryotic_oxidative_phosphorylation_14: $i > $i).
% 29.22/29.03  tff(decl_36393, type, fn_eukaryotic_oxidative_phosphorylation_20: $i > $i).
% 29.22/29.03  tff(decl_36394, type, fn_eukaryotic_oxidative_phosphorylation_21: $i > $i).
% 29.22/29.03  tff(decl_36395, type, fn_eukaryotic_oxidative_phosphorylation_22: $i > $i).
% 29.22/29.03  tff(decl_36396, type, fn_eukaryotic_oxidative_phosphorylation_23: $i > $i).
% 29.22/29.03  tff(decl_36397, type, fn_eukaryotic_oxidative_phosphorylation_24: $i > $i).
% 29.22/29.03  tff(decl_36398, type, fn_eukaryotic_oxidative_phosphorylation_26: $i > $i).
% 29.22/29.03  tff(decl_36399, type, fn_eukaryotic_oxidative_phosphorylation_29: $i > $i).
% 29.22/29.03  tff(decl_36400, type, fn_eukaryotic_oxidative_phosphorylation_30: $i > $i).
% 29.22/29.03  tff(decl_36401, type, fn_eukaryotic_oxidative_phosphorylation_33: $i > $i).
% 29.22/29.03  tff(decl_36402, type, fn_eukaryotic_oxidative_phosphorylation_34: $i > $i).
% 29.22/29.03  tff(decl_36403, type, fn_eukaryotic_oxidative_phosphorylation_37: $i > $i).
% 29.22/29.03  tff(decl_36404, type, fn_eukaryotic_oxidative_phosphorylation_38: $i > $i).
% 29.22/29.03  tff(decl_36405, type, fn_eukaryotic_oxidative_phosphorylation_41: $i > $i).
% 29.22/29.03  tff(decl_36406, type, fn_eukaryotic_oxidative_phosphorylation_42: $i > $i).
% 29.22/29.03  tff(decl_36407, type, fn_eukaryotic_oxidative_phosphorylation_44: $i > $i).
% 29.22/29.03  tff(decl_36408, type, fn_eukaryotic_oxidative_phosphorylation_46: $i > $i).
% 29.22/29.03  tff(decl_36409, type, fn_eukaryotic_oxidative_phosphorylation_47: $i > $i).
% 29.22/29.03  tff(decl_36410, type, fn_eukaryotic_oxidative_phosphorylation_48: $i > $i).
% 29.22/29.03  tff(decl_36411, type, fn_eukaryotic_oxidative_phosphorylation_49: $i > $i).
% 29.22/29.03  tff(decl_36412, type, fn_eukaryotic_oxidative_phosphorylation_50: $i > $i).
% 29.22/29.03  tff(decl_36413, type, fn_eukaryotic_oxidative_phosphorylation_51: $i > $i).
% 29.22/29.03  tff(decl_36414, type, fn_eukaryotic_oxidative_phosphorylation_53: $i > $i).
% 29.22/29.03  tff(decl_36415, type, fn_eukaryotic_oxidative_phosphorylation_55: $i > $i).
% 29.22/29.03  tff(decl_36416, type, fn_eukaryotic_oxidative_phosphorylation_57: $i > $i).
% 29.22/29.03  tff(decl_36417, type, fn_eukaryotic_oxidative_phosphorylation_58: $i > $i).
% 29.22/29.03  tff(decl_36418, type, fn_eukaryotic_oxidative_phosphorylation_59: $i > $i).
% 29.22/29.03  tff(decl_36419, type, fn_eukaryotic_oxidative_phosphorylation_63: $i > $i).
% 29.22/29.03  tff(decl_36420, type, fn_eukaryotic_oxidative_phosphorylation_65: $i > $i).
% 29.22/29.03  tff(decl_36421, type, fn_eukaryotic_oxidative_phosphorylation_66: $i > $i).
% 29.22/29.03  tff(decl_36422, type, fn_eukaryotic_oxidative_phosphorylation_67: $i > $i).
% 29.22/29.03  tff(decl_36423, type, fn_eukaryotic_oxidative_phosphorylation_68: $i > $i).
% 29.22/29.03  tff(decl_36424, type, fn_eukaryotic_oxidative_phosphorylation_69: $i > $i).
% 29.22/29.03  tff(decl_36425, type, fn_eukaryotic_oxidative_phosphorylation_70: $i > $i).
% 29.22/29.03  tff(decl_36426, type, fn_eukaryotic_oxidative_phosphorylation_71: $i > $i).
% 29.22/29.03  tff(decl_36427, type, fn_eukaryotic_oxidative_phosphorylation_79: $i > $i).
% 29.22/29.03  tff(decl_36428, type, fn_eukaryotic_oxidative_phosphorylation_82: $i > $i).
% 29.22/29.03  tff(decl_36429, type, fn_eukaryotic_oxidative_phosphorylation_83: $i > $i).
% 29.22/29.03  tff(decl_36430, type, fn_eukaryotic_oxidative_phosphorylation_84: $i > $i).
% 29.22/29.03  tff(decl_36431, type, fn_eukaryotic_oxidative_phosphorylation_88: $i > $i).
% 29.22/29.03  tff(decl_36432, type, fn_eukaryotic_oxidative_phosphorylation_89: $i > $i).
% 29.22/29.03  tff(decl_36433, type, fn_eukaryotic_oxidative_phosphorylation_90: $i > $i).
% 29.22/29.03  tff(decl_36434, type, fn_eukaryotic_oxidative_phosphorylation_91: $i > $i).
% 29.22/29.03  tff(decl_36435, type, fn_eukaryotic_oxidative_phosphorylation_92: $i > $i).
% 29.22/29.03  tff(decl_36436, type, fn_eukaryotic_oxidative_phosphorylation_93: $i > $i).
% 29.22/29.03  tff(decl_36437, type, fn_eukaryotic_oxidative_phosphorylation_94: $i > $i).
% 29.22/29.03  tff(decl_36438, type, fn_eukaryotic_oxidative_phosphorylation_95: $i > $i).
% 29.22/29.03  tff(decl_36439, type, fn_eukaryotic_oxidative_phosphorylation_96: $i > $i).
% 29.22/29.03  tff(decl_36440, type, multiprotein_complex_iv_1: $i > $o).
% 29.22/29.03  tff(decl_36441, type, fn_eukaryotic_oxidative_phosphorylation_97: $i > $i).
% 29.22/29.03  tff(decl_36442, type, fn_eukaryotic_oxidative_phosphorylation_98: $i > $i).
% 29.22/29.03  tff(decl_36443, type, fn_eukaryotic_oxidative_phosphorylation_99: $i > $i).
% 29.22/29.03  tff(decl_36444, type, multiprotein_complex_i_1: $i > $o).
% 29.22/29.03  tff(decl_36445, type, fn_eukaryotic_oxidative_phosphorylation_100: $i > $i).
% 29.22/29.03  tff(decl_36446, type, multiprotein_complex_ii_1: $i > $o).
% 29.22/29.03  tff(decl_36447, type, fn_eukaryotic_oxidative_phosphorylation_101: $i > $i).
% 29.22/29.03  tff(decl_36448, type, multiprotein_complex_iii_1: $i > $o).
% 29.22/29.03  tff(decl_36449, type, fn_eukaryotic_oxidative_phosphorylation_102: $i > $i).
% 29.22/29.03  tff(decl_36450, type, fn_eukaryotic_oxidative_phosphorylation_103: $i > $i).
% 29.22/29.03  tff(decl_36451, type, fn_eukaryotic_oxidative_phosphorylation_104: $i > $i).
% 29.22/29.03  tff(decl_36452, type, fn_eukaryotic_oxidative_phosphorylation_105: $i > $i).
% 29.22/29.03  tff(decl_36453, type, fn_eukaryotic_oxidative_phosphorylation_106: $i > $i).
% 29.22/29.03  tff(decl_36454, type, fn_eukaryotic_oxidative_phosphorylation_107: $i > $i).
% 29.22/29.03  tff(decl_36455, type, fn_eukaryotic_oxidative_phosphorylation_108: $i > $i).
% 29.22/29.03  tff(decl_36456, type, fn_eukaryotic_oxidative_phosphorylation_109: $i > $i).
% 29.22/29.03  tff(decl_36457, type, fn_eukaryotic_oxidative_phosphorylation_110: $i > $i).
% 29.22/29.03  tff(decl_36458, type, fn_eukaryotic_oxidative_phosphorylation_111: $i > $i).
% 29.22/29.03  tff(decl_36459, type, fn_eukaryotic_oxidative_phosphorylation_112: $i > $i).
% 29.22/29.03  tff(decl_36460, type, mitochondrial_electron_transport_chain_1: $i > $o).
% 29.22/29.03  tff(decl_36461, type, fn_eukaryotic_oxidative_phosphorylation_113: $i > $i).
% 29.22/29.03  tff(decl_36462, type, fn_eukaryotic_oxidative_phosphorylation_114: $i > $i).
% 29.22/29.03  tff(decl_36463, type, fn_eukaryotic_oxidative_phosphorylation_115: $i > $i).
% 29.22/29.03  tff(decl_36464, type, fn_eukaryotic_oxidative_phosphorylation_116: $i > $i).
% 29.22/29.03  tff(decl_36465, type, fn_eukaryotic_oxidative_phosphorylation_119: $i > $i).
% 29.22/29.03  tff(decl_36466, type, fn_eukaryotic_oxidative_phosphorylation_126: $i > $i).
% 29.22/29.03  tff(decl_36467, type, fn_eukaryotic_oxidative_phosphorylation_127: $i > $i).
% 29.22/29.03  tff(decl_36468, type, fn_eukaryotic_oxidative_phosphorylation_128: $i > $i).
% 29.22/29.03  tff(decl_36469, type, fn_eukaryotic_oxidative_phosphorylation_129: $i > $i).
% 29.22/29.03  tff(decl_36470, type, fn_eukaryotic_oxidative_phosphorylation_130: $i > $i).
% 29.22/29.03  tff(decl_36471, type, fn_eukaryotic_oxidative_phosphorylation_131: $i > $i).
% 29.22/29.03  tff(decl_36472, type, fn_eukaryotic_oxidative_phosphorylation_132: $i > $i).
% 29.22/29.03  tff(decl_36473, type, fn_eukaryotic_oxidative_phosphorylation_133: $i > $i).
% 29.22/29.03  tff(decl_36474, type, fn_eukaryotic_oxidative_phosphorylation_134: $i > $i).
% 29.22/29.03  tff(decl_36475, type, fn_eukaryotic_oxidative_phosphorylation_135: $i > $i).
% 29.22/29.03  tff(decl_36476, type, fn_eukaryotic_oxidative_phosphorylation_136: $i > $i).
% 29.22/29.03  tff(decl_36477, type, fn_eukaryotic_oxidative_phosphorylation_137: $i > $i).
% 29.22/29.03  tff(decl_36478, type, fn_eukaryotic_oxidative_phosphorylation_138: $i > $i).
% 29.22/29.03  tff(decl_36479, type, fn_eukaryotic_oxidative_phosphorylation_139: $i > $i).
% 29.22/29.03  tff(decl_36480, type, fn_eukaryotic_oxidative_phosphorylation_140: $i > $i).
% 29.22/29.03  tff(decl_36481, type, fn_eukaryotic_oxidative_phosphorylation_141: $i > $i).
% 29.22/29.03  tff(decl_36482, type, fn_eukaryotic_oxidative_phosphorylation_142: $i > $i).
% 29.22/29.03  tff(decl_36483, type, fn_eukaryotic_oxidative_phosphorylation_143: $i > $i).
% 29.22/29.03  tff(decl_36484, type, fn_eukaryotic_oxidative_phosphorylation_144: $i > $i).
% 29.22/29.03  tff(decl_36485, type, fn_eukaryotic_oxidative_phosphorylation_145: $i > $i).
% 29.22/29.03  tff(decl_36486, type, fn_eukaryotic_oxidative_phosphorylation_146: $i > $i).
% 29.22/29.03  tff(decl_36487, type, fn_eukaryotic_oxidative_phosphorylation_147: $i > $i).
% 29.22/29.03  tff(decl_36488, type, fn_eukaryotic_oxidative_phosphorylation_148: $i > $i).
% 29.22/29.03  tff(decl_36489, type, fn_eukaryotic_oxidative_phosphorylation_149: $i > $i).
% 29.22/29.03  tff(decl_36490, type, fn_eukaryotic_oxidative_phosphorylation_150: $i > $i).
% 29.22/29.03  tff(decl_36491, type, fn_eukaryotic_oxidative_phosphorylation_151: $i > $i).
% 29.22/29.03  tff(decl_36492, type, fn_eukaryotic_oxidative_phosphorylation_152: $i > $i).
% 29.22/29.03  tff(decl_36493, type, fn_eukaryotic_oxidative_phosphorylation_153: $i > $i).
% 29.22/29.03  tff(decl_36494, type, fn_eukaryotic_oxidative_phosphorylation_154: $i > $i).
% 29.22/29.03  tff(decl_36495, type, fn_eukaryotic_oxidative_phosphorylation_155: $i > $i).
% 29.22/29.03  tff(decl_36496, type, fn_eukaryotic_oxidative_phosphorylation_156: $i > $i).
% 29.22/29.03  tff(decl_36497, type, fn_eukaryotic_oxidative_phosphorylation_157: $i > $i).
% 29.22/29.03  tff(decl_36498, type, fn_eukaryotic_oxidative_phosphorylation_158: $i > $i).
% 29.22/29.03  tff(decl_36499, type, fn_eukaryotic_oxidative_phosphorylation_159: $i > $i).
% 29.22/29.03  tff(decl_36500, type, fn_eukaryotic_oxidative_phosphorylation_160: $i > $i).
% 29.22/29.03  tff(decl_36501, type, fn_eukaryotic_oxidative_phosphorylation_161: $i > $i).
% 29.22/29.03  tff(decl_36502, type, fn_eukaryotic_oxidative_phosphorylation_162: $i > $i).
% 29.22/29.03  tff(decl_36503, type, fn_eukaryotic_oxidative_phosphorylation_163: $i > $i).
% 29.22/29.03  tff(decl_36504, type, fn_eukaryotic_oxidative_phosphorylation_164: $i > $i).
% 29.22/29.03  tff(decl_36505, type, fn_eukaryotic_oxidative_phosphorylation_165: $i > $i).
% 29.22/29.03  tff(decl_36506, type, fn_eukaryotic_oxidative_phosphorylation_166: $i > $i).
% 29.22/29.03  tff(decl_36507, type, fn_eukaryotic_oxidative_phosphorylation_167: $i > $i).
% 29.22/29.03  tff(decl_36508, type, fn_eukaryotic_oxidative_phosphorylation_168: $i > $i).
% 29.22/29.03  tff(decl_36509, type, fn_eukaryotic_oxidative_phosphorylation_171: $i > $i).
% 29.22/29.03  tff(decl_36510, type, fn_eukaryotic_oxidative_phosphorylation_172: $i > $i).
% 29.22/29.03  tff(decl_36511, type, fn_eukaryotic_oxidative_phosphorylation_173: $i > $i).
% 29.22/29.03  tff(decl_36512, type, fn_eukaryotic_oxidative_phosphorylation_174: $i > $i).
% 29.22/29.03  tff(decl_36513, type, iron_sulfur_protein_1: $i > $o).
% 29.22/29.03  tff(decl_36514, type, fn_eukaryotic_oxidative_phosphorylation_175: $i > $i).
% 29.22/29.03  tff(decl_36515, type, fn_eukaryotic_oxidative_phosphorylation_176: $i > $i).
% 29.22/29.03  tff(decl_36516, type, fn_eukaryotic_oxidative_phosphorylation_177: $i > $i).
% 29.22/29.03  tff(decl_36517, type, fn_eukaryotic_oxidative_phosphorylation_178: $i > $i).
% 29.22/29.03  tff(decl_36518, type, fn_eukaryotic_oxidative_phosphorylation_179: $i > $i).
% 29.22/29.03  tff(decl_36519, type, fn_eukaryotic_oxidative_phosphorylation_180: $i > $i).
% 29.22/29.03  tff(decl_36520, type, fn_eukaryotic_oxidative_phosphorylation_181: $i > $i).
% 29.22/29.03  tff(decl_36521, type, fn_eukaryotic_oxidative_phosphorylation_182: $i > $i).
% 29.22/29.03  tff(decl_36522, type, fn_eukaryotic_oxidative_phosphorylation_183: $i > $i).
% 29.22/29.03  tff(decl_36523, type, fn_eukaryotic_oxidative_phosphorylation_189: $i > $i).
% 29.22/29.03  tff(decl_36524, type, fn_eukaryotic_oxidative_phosphorylation_190: $i > $i).
% 29.22/29.03  tff(decl_36525, type, fn_eukaryotic_oxidative_phosphorylation_193: $i > $i).
% 29.22/29.03  tff(decl_36526, type, fn_eukaryotic_oxidative_phosphorylation_194: $i > $i).
% 29.22/29.03  tff(decl_36527, type, fn_eukaryotic_oxidative_phosphorylation_195: $i > $i).
% 29.22/29.03  tff(decl_36528, type, fn_eukaryotic_oxidative_phosphorylation_196: $i > $i).
% 29.22/29.03  tff(decl_36529, type, fn_eukaryotic_oxidative_phosphorylation_201: $i > $i).
% 29.22/29.03  tff(decl_36530, type, fn_eukaryotic_oxidative_phosphorylation_202: $i > $i).
% 29.22/29.03  tff(decl_36531, type, fn_eukaryotic_oxidative_phosphorylation_205: $i > $i).
% 29.22/29.03  tff(decl_36532, type, fn_eukaryotic_oxidative_phosphorylation_206: $i > $i).
% 29.22/29.03  tff(decl_36533, type, fn_eukaryotic_oxidative_phosphorylation_207: $i > $i).
% 29.22/29.03  tff(decl_36534, type, fn_eukaryotic_oxidative_phosphorylation_208: $i > $i).
% 29.22/29.03  tff(decl_36535, type, fn_eukaryotic_oxidative_phosphorylation_209: $i > $i).
% 29.22/29.03  tff(decl_36536, type, fn_eukaryotic_oxidative_phosphorylation_210: $i > $i).
% 29.22/29.03  tff(decl_36537, type, fn_eukaryotic_oxidative_phosphorylation_211: $i > $i).
% 29.22/29.03  tff(decl_36538, type, fn_eukaryotic_oxidative_phosphorylation_212: $i > $i).
% 29.22/29.03  tff(decl_36539, type, fn_eukaryotic_oxidative_phosphorylation_215: $i > $i).
% 29.22/29.03  tff(decl_36540, type, fn_eukaryotic_oxidative_phosphorylation_216: $i > $i).
% 29.22/29.03  tff(decl_36541, type, fn_eukaryotic_oxidative_phosphorylation_217: $i > $i).
% 29.22/29.03  tff(decl_36542, type, fn_eukaryotic_oxidative_phosphorylation_218: $i > $i).
% 29.22/29.03  tff(decl_36543, type, fn_eukaryotic_oxidative_phosphorylation_219: $i > $i).
% 29.22/29.03  tff(decl_36544, type, fn_eukaryotic_oxidative_phosphorylation_220: $i > $i).
% 29.22/29.03  tff(decl_36545, type, fn_eukaryotic_oxidative_phosphorylation_221: $i > $i).
% 29.22/29.03  tff(decl_36546, type, fn_eukaryotic_oxidative_phosphorylation_222: $i > $i).
% 29.22/29.03  tff(decl_36547, type, fn_eukaryotic_oxidative_phosphorylation_223: $i > $i).
% 29.22/29.03  tff(decl_36548, type, fn_eukaryotic_oxidative_phosphorylation_228: $i > $i).
% 29.22/29.03  tff(decl_36549, type, fn_eukaryotic_oxidative_phosphorylation_229: $i > $i).
% 29.22/29.03  tff(decl_36550, type, fn_eukaryotic_oxidative_phosphorylation_230: $i > $i).
% 29.22/29.03  tff(decl_36551, type, fn_eukaryotic_oxidative_phosphorylation_231: $i > $i).
% 29.22/29.03  tff(decl_36552, type, fn_eukaryotic_oxidative_phosphorylation_232: $i > $i).
% 29.22/29.03  tff(decl_36553, type, fn_eukaryotic_oxidative_phosphorylation_233: $i > $i).
% 29.22/29.03  tff(decl_36554, type, fn_eukaryotic_oxidative_phosphorylation_234: $i > $i).
% 29.22/29.03  tff(decl_36555, type, fn_eukaryotic_oxidative_phosphorylation_235: $i > $i).
% 29.22/29.03  tff(decl_36556, type, fn_eukaryotic_oxidative_phosphorylation_236: $i > $i).
% 29.22/29.03  tff(decl_36557, type, fn_eukaryotic_oxidative_phosphorylation_237: $i > $i).
% 29.22/29.03  tff(decl_36558, type, fn_eukaryotic_oxidative_phosphorylation_238: $i > $i).
% 29.22/29.03  tff(decl_36559, type, fn_eukaryotic_oxidative_phosphorylation_239: $i > $i).
% 29.22/29.03  tff(decl_36560, type, fn_eukaryotic_oxidative_phosphorylation_240: $i > $i).
% 29.22/29.03  tff(decl_36561, type, fn_eukaryotic_oxidative_phosphorylation_241: $i > $i).
% 29.22/29.03  tff(decl_36562, type, fn_eukaryotic_oxidative_phosphorylation_242: $i > $i).
% 29.22/29.03  tff(decl_36563, type, fn_eukaryotic_oxidative_phosphorylation_243: $i > $i).
% 29.22/29.03  tff(decl_36564, type, fn_eukaryotic_oxidative_phosphorylation_244: $i > $i).
% 29.22/29.03  tff(decl_36565, type, fn_eukaryotic_oxidative_phosphorylation_245: $i > $i).
% 29.22/29.03  tff(decl_36566, type, fn_eukaryotic_oxidative_phosphorylation_248: $i > $i).
% 29.22/29.03  tff(decl_36567, type, fn_eukaryotic_oxidative_phosphorylation_249: $i > $i).
% 29.22/29.03  tff(decl_36568, type, fn_eukaryotic_oxidative_phosphorylation_250: $i > $i).
% 29.22/29.03  tff(decl_36569, type, fn_eukaryotic_oxidative_phosphorylation_251: $i > $i).
% 29.22/29.03  tff(decl_36570, type, fn_eukaryotic_oxidative_phosphorylation_252: $i > $i).
% 29.22/29.03  tff(decl_36571, type, fn_eukaryotic_oxidative_phosphorylation_253: $i > $i).
% 29.22/29.03  tff(decl_36572, type, fn_eukaryotic_oxidative_phosphorylation_254: $i > $i).
% 29.22/29.03  tff(decl_36573, type, fn_eukaryotic_oxidative_phosphorylation_255: $i > $i).
% 29.22/29.03  tff(decl_36574, type, fn_eukaryotic_oxidative_phosphorylation_258: $i > $i).
% 29.22/29.03  tff(decl_36575, type, fn_eukaryotic_oxidative_phosphorylation_259: $i > $i).
% 29.22/29.03  tff(decl_36576, type, fn_eukaryotic_oxidative_phosphorylation_260: $i > $i).
% 29.22/29.03  tff(decl_36577, type, fn_eukaryotic_oxidative_phosphorylation_261: $i > $i).
% 29.22/29.03  tff(decl_36578, type, fn_eukaryotic_oxidative_phosphorylation_262: $i > $i).
% 29.22/29.03  tff(decl_36579, type, fn_eukaryotic_oxidative_phosphorylation_263: $i > $i).
% 29.22/29.03  tff(decl_36580, type, fn_eukaryotic_oxidative_phosphorylation_264: $i > $i).
% 29.22/29.03  tff(decl_36581, type, fn_eukaryotic_oxidative_phosphorylation_265: $i > $i).
% 29.22/29.03  tff(decl_36582, type, fn_eukaryotic_oxidative_phosphorylation_268: $i > $i).
% 29.22/29.03  tff(decl_36583, type, fn_eukaryotic_oxidative_phosphorylation_269: $i > $i).
% 29.22/29.03  tff(decl_36584, type, fn_eukaryotic_oxidative_phosphorylation_270: $i > $i).
% 29.22/29.03  tff(decl_36585, type, fn_eukaryotic_oxidative_phosphorylation_271: $i > $i).
% 29.22/29.03  tff(decl_36586, type, fn_eukaryotic_oxidative_phosphorylation_272: $i > $i).
% 29.22/29.03  tff(decl_36587, type, fn_eukaryotic_oxidative_phosphorylation_273: $i > $i).
% 29.22/29.03  tff(decl_36588, type, fn_eukaryotic_oxidative_phosphorylation_274: $i > $i).
% 29.22/29.03  tff(decl_36589, type, fn_eukaryotic_oxidative_phosphorylation_275: $i > $i).
% 29.22/29.03  tff(decl_36590, type, fn_eukaryotic_oxidative_phosphorylation_276: $i > $i).
% 29.22/29.03  tff(decl_36591, type, fn_eukaryotic_oxidative_phosphorylation_277: $i > $i).
% 29.22/29.03  tff(decl_36592, type, fn_eukaryotic_oxidative_phosphorylation_278: $i > $i).
% 29.22/29.03  tff(decl_36593, type, fn_eukaryotic_oxidative_phosphorylation_279: $i > $i).
% 29.22/29.03  tff(decl_36594, type, fn_eukaryotic_oxidative_phosphorylation_282: $i > $i).
% 29.22/29.03  tff(decl_36595, type, fn_eukaryotic_oxidative_phosphorylation_283: $i > $i).
% 29.22/29.03  tff(decl_36596, type, fn_eukaryotic_oxidative_phosphorylation_284: $i > $i).
% 29.22/29.03  tff(decl_36597, type, fn_eukaryotic_oxidative_phosphorylation_285: $i > $i).
% 29.22/29.03  tff(decl_36598, type, fn_eukaryotic_oxidative_phosphorylation_286: $i > $i).
% 29.22/29.03  tff(decl_36599, type, fn_eukaryotic_oxidative_phosphorylation_287: $i > $i).
% 29.22/29.03  tff(decl_36600, type, fn_eukaryotic_oxidative_phosphorylation_288: $i > $i).
% 29.22/29.03  tff(decl_36601, type, fn_eukaryotic_oxidative_phosphorylation_289: $i > $i).
% 29.22/29.03  tff(decl_36602, type, fn_eukaryotic_oxidative_phosphorylation_290: $i > $i).
% 29.22/29.03  tff(decl_36603, type, fn_eukaryotic_oxidative_phosphorylation_291: $i > $i).
% 29.22/29.03  tff(decl_36604, type, fn_eukaryotic_oxidative_phosphorylation_294: $i > $i).
% 29.22/29.03  tff(decl_36605, type, ubiquinone_1: $i > $o).
% 29.22/29.03  tff(decl_36606, type, fn_eukaryotic_oxidative_phosphorylation_295: $i > $i).
% 29.22/29.03  tff(decl_36607, type, fn_eukaryotic_oxidative_phosphorylation_296: $i > $i).
% 29.22/29.03  tff(decl_36608, type, fn_eukaryotic_oxidative_phosphorylation_297: $i > $i).
% 29.22/29.03  tff(decl_36609, type, fn_eukaryotic_oxidative_phosphorylation_298: $i > $i).
% 29.22/29.03  tff(decl_36610, type, fn_eukaryotic_oxidative_phosphorylation_299: $i > $i).
% 29.22/29.03  tff(decl_36611, type, fn_eukaryotic_oxidative_phosphorylation_300: $i > $i).
% 29.22/29.03  tff(decl_36612, type, fn_eukaryotic_oxidative_phosphorylation_301: $i > $i).
% 29.22/29.03  tff(decl_36613, type, fn_eukaryotic_oxidative_phosphorylation_302: $i > $i).
% 29.22/29.03  tff(decl_36614, type, fn_eukaryotic_oxidative_phosphorylation_303: $i > $i).
% 29.22/29.03  tff(decl_36615, type, fn_eukaryotic_oxidative_phosphorylation_304: $i > $i).
% 29.22/29.03  tff(decl_36616, type, fn_eukaryotic_oxidative_phosphorylation_305: $i > $i).
% 29.22/29.03  tff(decl_36617, type, fn_eukaryotic_oxidative_phosphorylation_308: $i > $i).
% 29.22/29.03  tff(decl_36618, type, fn_eukaryotic_oxidative_phosphorylation_309: $i > $i).
% 29.22/29.03  tff(decl_36619, type, fn_eukaryotic_oxidative_phosphorylation_310: $i > $i).
% 29.22/29.03  tff(decl_36620, type, fn_eukaryotic_oxidative_phosphorylation_311: $i > $i).
% 29.22/29.03  tff(decl_36621, type, fn_eukaryotic_oxidative_phosphorylation_312: $i > $i).
% 29.22/29.03  tff(decl_36622, type, fn_eukaryotic_oxidative_phosphorylation_313: $i > $i).
% 29.22/29.03  tff(decl_36623, type, fn_eukaryotic_oxidative_phosphorylation_314: $i > $i).
% 29.22/29.03  tff(decl_36624, type, fn_eukaryotic_oxidative_phosphorylation_315: $i > $i).
% 29.22/29.03  tff(decl_36625, type, fn_eukaryotic_oxidative_phosphorylation_316: $i > $i).
% 29.22/29.03  tff(decl_36626, type, fn_eukaryotic_oxidative_phosphorylation_317: $i > $i).
% 29.22/29.03  tff(decl_36627, type, fn_eukaryotic_oxidative_phosphorylation_318: $i > $i).
% 29.22/29.03  tff(decl_36628, type, fn_eukaryotic_oxidative_phosphorylation_319: $i > $i).
% 29.22/29.03  tff(decl_36629, type, fn_eukaryotic_oxidative_phosphorylation_320: $i > $i).
% 29.22/29.03  tff(decl_36630, type, fn_eukaryotic_oxidative_phosphorylation_321: $i > $i).
% 29.22/29.03  tff(decl_36631, type, fn_eukaryotic_oxidative_phosphorylation_324: $i > $i).
% 29.22/29.03  tff(decl_36632, type, fn_eukaryotic_oxidative_phosphorylation_330: $i > $i).
% 29.22/29.03  tff(decl_36633, type, fn_eukaryotic_oxidative_phosphorylation_332: $i > $i).
% 29.22/29.03  tff(decl_36634, type, fn_eukaryotic_oxidative_phosphorylation_337: $i > $i).
% 29.22/29.03  tff(decl_36635, type, fn_eukaryotic_oxidative_phosphorylation_338: $i > $i).
% 29.22/29.03  tff(decl_36636, type, fn_eukaryotic_oxidative_phosphorylation_339: $i > $i).
% 29.22/29.03  tff(decl_36637, type, fn_eukaryotic_oxidative_phosphorylation_340: $i > $i).
% 29.22/29.03  tff(decl_36638, type, fn_eukaryotic_oxidative_phosphorylation_341: $i > $i).
% 29.22/29.03  tff(decl_36639, type, fn_eukaryotic_oxidative_phosphorylation_342: $i > $i).
% 29.22/29.03  tff(decl_36640, type, fn_eukaryotic_oxidative_phosphorylation_343: $i > $i).
% 29.22/29.03  tff(decl_36641, type, fn_eukaryotic_oxidative_phosphorylation_344: $i > $i).
% 29.22/29.03  tff(decl_36642, type, fn_eukaryotic_oxidative_phosphorylation_345: $i > $i).
% 29.22/29.03  tff(decl_36643, type, fn_eukaryotic_oxidative_phosphorylation_346: $i > $i).
% 29.22/29.03  tff(decl_36644, type, fn_eukaryotic_oxidative_phosphorylation_347: $i > $i).
% 29.22/29.03  tff(decl_36645, type, fn_eukaryotic_oxidative_phosphorylation_348: $i > $i).
% 29.22/29.03  tff(decl_36646, type, fn_eukaryotic_oxidative_phosphorylation_349: $i > $i).
% 29.22/29.03  tff(decl_36647, type, flavoprotein_1: $i > $o).
% 29.22/29.03  tff(decl_36648, type, fn_eukaryotic_oxidative_phosphorylation_350: $i > $i).
% 29.22/29.03  tff(decl_36649, type, fn_eukaryotic_oxidative_phosphorylation_351: $i > $i).
% 29.22/29.03  tff(decl_36650, type, fn_eukaryotic_oxidative_phosphorylation_352: $i > $i).
% 29.22/29.03  tff(decl_36651, type, fn_eukaryotic_oxidative_phosphorylation_353: $i > $i).
% 29.22/29.03  tff(decl_36652, type, fn_eukaryotic_oxidative_phosphorylation_354: $i > $i).
% 29.22/29.03  tff(decl_36653, type, fn_eukaryotic_oxidative_phosphorylation_355: $i > $i).
% 29.22/29.03  tff(decl_36654, type, fn_eukaryotic_oxidative_phosphorylation_356: $i > $i).
% 29.22/29.03  tff(decl_36655, type, fn_eukaryotic_oxidative_phosphorylation_361: $i > $i).
% 29.22/29.03  tff(decl_36656, type, fn_eukaryotic_oxidative_phosphorylation_362: $i > $i).
% 29.22/29.03  tff(decl_36657, type, fn_eukaryotic_oxidative_phosphorylation_363: $i > $i).
% 29.22/29.03  tff(decl_36658, type, fn_eukaryotic_oxidative_phosphorylation_364: $i > $i).
% 29.22/29.03  tff(decl_36659, type, fn_eukaryotic_oxidative_phosphorylation_365: $i > $i).
% 29.22/29.03  tff(decl_36660, type, fn_eukaryotic_oxidative_phosphorylation_366: $i > $i).
% 29.22/29.03  tff(decl_36661, type, fn_eukaryotic_oxidative_phosphorylation_367: $i > $i).
% 29.22/29.03  tff(decl_36662, type, fn_eukaryotic_oxidative_phosphorylation_368: $i > $i).
% 29.22/29.03  tff(decl_36663, type, fn_eukaryotic_oxidative_phosphorylation_369: $i > $i).
% 29.22/29.03  tff(decl_36664, type, fn_eukaryotic_oxidative_phosphorylation_370: $i > $i).
% 29.22/29.03  tff(decl_36665, type, fn_eukaryotic_oxidative_phosphorylation_371: $i > $i).
% 29.22/29.03  tff(decl_36666, type, fn_eukaryotic_oxidative_phosphorylation_372: $i > $i).
% 29.22/29.03  tff(decl_36667, type, fn_eukaryotic_oxidative_phosphorylation_376: $i > $i).
% 29.22/29.03  tff(decl_36668, type, fn_eukaryotic_oxidative_phosphorylation_377: $i > $i).
% 29.22/29.03  tff(decl_36669, type, fn_eukaryotic_oxidative_phosphorylation_378: $i > $i).
% 29.22/29.03  tff(decl_36670, type, fn_eukaryotic_oxidative_phosphorylation_379: $i > $i).
% 29.22/29.03  tff(decl_36671, type, fn_eukaryotic_oxidative_phosphorylation_380: $i > $i).
% 29.22/29.03  tff(decl_36672, type, fn_eukaryotic_oxidative_phosphorylation_381: $i > $i).
% 29.22/29.03  tff(decl_36673, type, fn_eukaryotic_oxidative_phosphorylation_382: $i > $i).
% 29.22/29.03  tff(decl_36674, type, fn_eukaryotic_oxidative_phosphorylation_385: $i > $i).
% 29.22/29.03  tff(decl_36675, type, fn_eukaryotic_oxidative_phosphorylation_386: $i > $i).
% 29.22/29.03  tff(decl_36676, type, fn_eukaryotic_oxidative_phosphorylation_387: $i > $i).
% 29.22/29.03  tff(decl_36677, type, fn_eukaryotic_oxidative_phosphorylation_388: $i > $i).
% 29.22/29.03  tff(decl_36678, type, fn_eukaryotic_oxidative_phosphorylation_389: $i > $i).
% 29.22/29.03  tff(decl_36679, type, fn_eukaryotic_oxidative_phosphorylation_390: $i > $i).
% 29.22/29.03  tff(decl_36680, type, fn_eukaryotic_oxidative_phosphorylation_391: $i > $i).
% 29.22/29.03  tff(decl_36681, type, fn_eukaryotic_oxidative_phosphorylation_396: $i > $i).
% 29.22/29.03  tff(decl_36682, type, fn_eukaryotic_oxidative_phosphorylation_397: $i > $i).
% 29.22/29.03  tff(decl_36683, type, fn_eukaryotic_oxidative_phosphorylation_398: $i > $i).
% 29.22/29.03  tff(decl_36684, type, fn_eukaryotic_oxidative_phosphorylation_399: $i > $i).
% 29.22/29.03  tff(decl_36685, type, fn_eukaryotic_oxidative_phosphorylation_400: $i > $i).
% 29.22/29.03  tff(decl_36686, type, fn_eukaryotic_oxidative_phosphorylation_401: $i > $i).
% 29.22/29.03  tff(decl_36687, type, fn_eukaryotic_oxidative_phosphorylation_402: $i > $i).
% 29.22/29.03  tff(decl_36688, type, fn_eukaryotic_oxidative_phosphorylation_403: $i > $i).
% 29.22/29.03  tff(decl_36689, type, fn_eukaryotic_oxidative_phosphorylation_404: $i > $i).
% 29.22/29.03  tff(decl_36690, type, fn_eukaryotic_oxidative_phosphorylation_405: $i > $i).
% 29.22/29.03  tff(decl_36691, type, fn_eukaryotic_oxidative_phosphorylation_408: $i > $i).
% 29.22/29.03  tff(decl_36692, type, fn_eukaryotic_oxidative_phosphorylation_409: $i > $i).
% 29.22/29.03  tff(decl_36693, type, fn_eukaryotic_oxidative_phosphorylation_410: $i > $i).
% 29.22/29.03  tff(decl_36694, type, fn_eukaryotic_oxidative_phosphorylation_411: $i > $i).
% 29.22/29.03  tff(decl_36695, type, fn_eukaryotic_oxidative_phosphorylation_412: $i > $i).
% 29.22/29.03  tff(decl_36696, type, fn_eukaryotic_oxidative_phosphorylation_413: $i > $i).
% 29.22/29.03  tff(decl_36697, type, fn_eukaryotic_oxidative_phosphorylation_414: $i > $i).
% 29.22/29.03  tff(decl_36698, type, fn_eukaryotic_oxidative_phosphorylation_415: $i > $i).
% 29.22/29.03  tff(decl_36699, type, fn_eukaryotic_oxidative_phosphorylation_416: $i > $i).
% 29.22/29.03  tff(decl_36700, type, fn_eukaryotic_oxidative_phosphorylation_419: $i > $i).
% 29.22/29.03  tff(decl_36701, type, fn_eukaryotic_oxidative_phosphorylation_420: $i > $i).
% 29.22/29.03  tff(decl_36702, type, fn_eukaryotic_oxidative_phosphorylation_421: $i > $i).
% 29.22/29.03  tff(decl_36703, type, fn_eukaryotic_oxidative_phosphorylation_422: $i > $i).
% 29.22/29.03  tff(decl_36704, type, fn_eukaryotic_oxidative_phosphorylation_423: $i > $i).
% 29.22/29.03  tff(decl_36705, type, fn_eukaryotic_oxidative_phosphorylation_424: $i > $i).
% 29.22/29.03  tff(decl_36706, type, fn_eukaryotic_oxidative_phosphorylation_425: $i > $i).
% 29.22/29.03  tff(decl_36707, type, fn_eukaryotic_oxidative_phosphorylation_426: $i > $i).
% 29.22/29.03  tff(decl_36708, type, fn_eukaryotic_oxidative_phosphorylation_427: $i > $i).
% 29.22/29.03  tff(decl_36709, type, fn_eukaryotic_oxidative_phosphorylation_428: $i > $i).
% 29.22/29.03  tff(decl_36710, type, fn_eukaryotic_oxidative_phosphorylation_429: $i > $i).
% 29.22/29.03  tff(decl_36711, type, fn_eukaryotic_oxidative_phosphorylation_430: $i > $i).
% 29.22/29.03  tff(decl_36712, type, fn_eukaryotic_oxidative_phosphorylation_431: $i > $i).
% 29.22/29.03  tff(decl_36713, type, fn_eukaryotic_oxidative_phosphorylation_432: $i > $i).
% 29.22/29.03  tff(decl_36714, type, fn_eukaryotic_oxidative_phosphorylation_433: $i > $i).
% 29.22/29.03  tff(decl_36715, type, fn_eukaryotic_oxidative_phosphorylation_434: $i > $i).
% 29.22/29.03  tff(decl_36716, type, fn_eukaryotic_oxidative_phosphorylation_435: $i > $i).
% 29.22/29.03  tff(decl_36717, type, fn_eukaryotic_oxidative_phosphorylation_436: $i > $i).
% 29.22/29.03  tff(decl_36718, type, fn_eukaryotic_oxidative_phosphorylation_437: $i > $i).
% 29.22/29.03  tff(decl_36719, type, fn_eukaryotic_oxidative_phosphorylation_438: $i > $i).
% 29.22/29.03  tff(decl_36720, type, fn_eukaryotic_oxidative_phosphorylation_439: $i > $i).
% 29.22/29.03  tff(decl_36721, type, fn_eukaryotic_oxidative_phosphorylation_440: $i > $i).
% 29.22/29.03  tff(decl_36722, type, fn_eukaryotic_oxidative_phosphorylation_441: $i > $i).
% 29.22/29.03  tff(decl_36723, type, fn_eukaryotic_oxidative_phosphorylation_442: $i > $i).
% 29.22/29.03  tff(decl_36724, type, fn_eukaryotic_oxidative_phosphorylation_443: $i > $i).
% 29.22/29.03  tff(decl_36725, type, fn_eukaryotic_oxidative_phosphorylation_444: $i > $i).
% 29.22/29.03  tff(decl_36726, type, fn_eukaryotic_oxidative_phosphorylation_445: $i > $i).
% 29.22/29.03  tff(decl_36727, type, fn_hypotonic_solution_1: $i > $i).
% 29.22/29.03  tff(decl_36728, type, fn_hypotonic_solution_5: $i > $i).
% 29.22/29.03  tff(decl_36729, type, fn_mitochondrial_membrane_4: $i > $i).
% 29.22/29.03  tff(decl_36730, type, fn_mitochondrial_membrane_3: $i > $i).
% 29.22/29.03  tff(decl_36731, type, fn_mitochondrial_membrane_10: $i > $i).
% 29.22/29.03  tff(decl_36732, type, fn_mitochondrial_membrane_38: $i > $i).
% 29.22/29.03  tff(decl_36733, type, fn_mitochondrial_membrane_6: $i > $i).
% 29.22/29.03  tff(decl_36734, type, fn_mitochondrial_membrane_5: $i > $i).
% 29.22/29.03  tff(decl_36735, type, fn_mitochondrial_electron_transport_chain_4: $i > $i).
% 29.22/29.03  tff(decl_36736, type, fn_mitochondrial_electron_transport_chain_5: $i > $i).
% 29.22/29.03  tff(decl_36737, type, fn_mitochondrial_electron_transport_chain_7: $i > $i).
% 29.22/29.03  tff(decl_36738, type, fn_mitochondrial_electron_transport_chain_3: $i > $i).
% 29.22/29.03  tff(decl_36739, type, fn_mitochondrial_electron_transport_chain_2: $i > $i).
% 29.22/29.03  tff(decl_36740, type, fn_redox_reaction_9: $i > $i).
% 29.22/29.03  tff(decl_36741, type, fn_fadh2_6: $i > $i).
% 29.22/29.03  tff(decl_36742, type, fn_fadh2_10: $i > $i).
% 29.22/29.03  tff(decl_36743, type, fn_fadh2_4: $i > $i).
% 29.22/29.03  tff(decl_36744, type, fn_fadh2_8: $i > $i).
% 29.22/29.03  tff(decl_36745, type, fn_fadh2_9: $i > $i).
% 29.22/29.03  tff(decl_36746, type, fn_fadh2_3: $i > $i).
% 29.22/29.03  tff(decl_36747, type, fn_fadh2_7: $i > $i).
% 29.22/29.03  tff(decl_36748, type, fn_fadh2_2: $i > $i).
% 29.22/29.03  tff(decl_36749, type, fn_fadh2_5: $i > $i).
% 29.22/29.03  tff(decl_36750, type, fn_multiprotein_complex_iii_4: $i > $i).
% 29.22/29.03  tff(decl_36751, type, fn_multiprotein_complex_iii_3: $i > $i).
% 29.22/29.03  tff(decl_36752, type, fn_passive_transport_10: $i > $i).
% 29.22/29.03  tff(decl_36753, type, fn_mitochondrial_electron_transport_chain_10: $i > $i).
% 29.22/29.03  tff(decl_36754, type, fn_mitochondrial_electron_transport_chain_18: $i > $i).
% 29.22/29.03  tff(decl_36755, type, fn_mitochondrial_electron_transport_chain_9: $i > $i).
% 29.22/29.03  tff(decl_36756, type, fn_generation_of_hydrogen_ion_gradient_across_biomembrane_1: $i > $i).
% 29.22/29.03  tff(decl_36757, type, fn_generation_of_hydrogen_ion_gradient_across_biomembrane_4: $i > $i).
% 29.22/29.03  tff(decl_36758, type, fn_mitochondrial_membrane_42: $i > $i).
% 29.22/29.03  tff(decl_36759, type, fn_mitochondrial_membrane_68: $i > $i).
% 29.22/29.03  tff(decl_36760, type, fn_mitochondrial_membrane_63: $i > $i).
% 29.22/29.03  tff(decl_36761, type, fn_mitochondrial_membrane_64: $i > $i).
% 29.22/29.03  tff(decl_36762, type, fn_mitochondrial_membrane_60: $i > $i).
% 29.22/29.03  tff(decl_36763, type, fn_mitochondrial_membrane_70: $i > $i).
% 29.22/29.03  tff(decl_36764, type, fn_mitochondrial_electron_transport_chain_8: $i > $i).
% 29.22/29.03  tff(decl_36765, type, fn_facilitated_diffusion_of_ion_28: $i > $i).
% 29.22/29.03  tff(decl_36766, type, fn_mitochondrial_electron_transport_chain_13: $i > $i).
% 29.22/29.03  tff(decl_36767, type, fn_mitochondrial_electron_transport_chain_11: $i > $i).
% 29.22/29.03  tff(decl_36768, type, fn_semiautonomous_organelle_1: $i > $i).
% 29.22/29.03  tff(decl_36769, type, fn_multiprotein_complex_ii_2: $i > $i).
% 29.22/29.03  tff(decl_36770, type, fn_mitochondrial_membrane_41: $i > $i).
% 29.22/29.03  tff(decl_36771, type, fn_mitochondrial_electron_transport_chain_19: $i > $i).
% 29.22/29.03  tff(decl_36772, type, fn_multiprotein_complex_iv_1: $i > $i).
% 29.22/29.03  tff(decl_36773, type, fn_multiprotein_complex_iv_3: $i > $i).
% 29.22/29.03  tff(decl_36774, type, fn_mitochondrial_membrane_13: $i > $i).
% 29.22/29.03  tff(decl_36775, type, fn_multiprotein_complex_i_2: $i > $i).
% 29.22/29.03  tff(decl_36776, type, fn_multiprotein_complex_i_1: $i > $i).
% 29.22/29.03  tff(decl_36777, type, fn_mitochondrial_membrane_16: $i > $i).
% 29.22/29.03  tff(decl_36778, type, fn_fadh2_1: $i > $i).
% 29.22/29.03  tff(decl_36779, type, fn_multiprotein_complex_iii_5: $i > $i).
% 29.22/29.03  tff(decl_36780, type, fn_mitochondrial_membrane_14: $i > $i).
% 29.22/29.03  tff(decl_36781, type, fn_multiprotein_complex_iii_1: $i > $i).
% 29.22/29.03  tff(decl_36782, type, fn_multiprotein_complex_iii_2: $i > $i).
% 29.22/29.03  tff(decl_36783, type, 'R2': $i).
% 29.22/29.03  tff(decl_36784, type, 'R3': $i).
% 29.22/29.03  tff(decl_36785, type, 'R4': $i).
% 29.22/29.03  tff(decl_36786, type, 'R5': $i).
% 29.22/29.03  tff(decl_36787, type, 'R6': $i).
% 29.22/29.03  tff(decl_36788, type, 'R7': $i).
% 29.22/29.03  tff(decl_36789, type, 'R8': $i).
% 29.22/29.03  tff(decl_36790, type, 'R9': $i).
% 29.22/29.03  tff(decl_36791, type, 'R10': $i).
% 29.22/29.03  tff(decl_36792, type, 'R1': $i).
% 29.22/29.03  tff(decl_36793, type, cytochrome_a3_0: $i).
% 29.22/29.03  tff(decl_36794, type, recipient_0: $i).
% 29.22/29.03  tff(decl_36795, type, 'R11': $i).
% 29.22/29.03  tff(decl_36796, type, 'R16': $i).
% 29.22/29.03  tff(decl_36797, type, 'R15': $i).
% 29.22/29.03  tff(decl_36798, type, 'R14': $i).
% 29.22/29.03  tff(decl_36799, type, 'R13': $i).
% 29.22/29.03  tff(decl_36800, type, 'R12': $i).
% 29.22/29.03  tff(decl_36801, type, 'R17': $i).
% 29.22/29.03  tff(decl_36802, type, 'R19': $i).
% 29.22/29.03  tff(decl_36803, type, 'R18': $i).
% 29.22/29.03  tff(decl_36804, type, 'HC2': $i).
% 29.22/29.03  tff(decl_36805, type, fn_eukaryotic_oxidative_phosphorylation_281: $i > $i).
% 29.22/29.03  tff(decl_36806, type, fn_eukaryotic_oxidative_phosphorylation_280: $i > $i).
% 29.22/29.03  tff(decl_36807, type, fn_eukaryotic_oxidative_phosphorylation_257: $i > $i).
% 29.22/29.03  tff(decl_36808, type, fn_eukaryotic_oxidative_phosphorylation_256: $i > $i).
% 29.22/29.03  tff(decl_36809, type, fn_eukaryotic_oxidative_phosphorylation_446: $i > $i).
% 29.22/29.03  tff(decl_36810, type, fn_eukaryotic_oxidative_phosphorylation_447: $i > $i).
% 29.22/29.03  tff(decl_36811, type, fn_eukaryotic_oxidative_phosphorylation_406: $i > $i).
% 29.22/29.03  tff(decl_36812, type, fn_eukaryotic_oxidative_phosphorylation_407: $i > $i).
% 29.22/29.03  tff(decl_36813, type, fn_eukaryotic_oxidative_phosphorylation_451: $i > $i).
% 29.22/29.03  tff(decl_36814, type, fn_eukaryotic_oxidative_phosphorylation_124: $i > $i).
% 29.22/29.03  tff(decl_36815, type, fn_eukaryotic_oxidative_phosphorylation_247: $i > $i).
% 29.22/29.03  tff(decl_36816, type, fn_eukaryotic_oxidative_phosphorylation_417: $i > $i).
% 29.22/29.03  tff(decl_36817, type, fn_eukaryotic_oxidative_phosphorylation_266: $i > $i).
% 29.22/29.03  tff(decl_36818, type, fn_eukaryotic_oxidative_phosphorylation_125: $i > $i).
% 29.22/29.03  tff(decl_36819, type, fn_eukaryotic_oxidative_phosphorylation_450: $i > $i).
% 29.22/29.03  tff(decl_36820, type, fn_eukaryotic_oxidative_phosphorylation_449: $i > $i).
% 29.22/29.03  tff(decl_36821, type, fn_eukaryotic_oxidative_phosphorylation_448: $i > $i).
% 29.22/29.03  tff(decl_36822, type, fn_eukaryotic_oxidative_phosphorylation_267: $i > $i).
% 29.22/29.03  tff(decl_36823, type, fn_oxidative_phosphorylation_32: $i > $i).
% 29.22/29.03  tff(decl_36824, type, fn_oxidative_phosphorylation_41: $i > $i).
% 29.22/29.03  tff(decl_36825, type, fn_oxidative_phosphorylation_47: $i > $i).
% 29.22/29.03  tff(decl_36826, type, fn_oxidative_phosphorylation_2: $i > $i).
% 29.22/29.03  tff(decl_36827, type, fn_oxidative_phosphorylation_11: $i > $i).
% 29.22/29.03  tff(decl_36828, type, fn_oxidative_phosphorylation_23: $i > $i).
% 29.22/29.03  tff(decl_36829, type, fn_oxidative_phosphorylation_42: $i > $i).
% 29.22/29.03  tff(decl_36830, type, fn_oxidative_phosphorylation_46: $i > $i).
% 29.22/29.03  tff(decl_36831, type, fn_oxidative_phosphorylation_21: $i > $i).
% 29.22/29.03  tff(decl_36832, type, fn_oxidative_phosphorylation_6: $i > $i).
% 29.22/29.03  tff(decl_36833, type, fn_oxidative_phosphorylation_13: $i > $i).
% 29.22/29.03  tff(decl_36834, type, fn_oxidative_phosphorylation_28: $i > $i).
% 29.22/29.03  tff(decl_36835, type, fn_oxidative_phosphorylation_8: $i > $i).
% 29.22/29.03  tff(decl_36836, type, fn_eukaryotic_oxidative_phosphorylation_81: $i > $i).
% 29.22/29.03  tff(decl_36837, type, fn_eukaryotic_oxidative_phosphorylation_80: $i > $i).
% 29.22/29.03  tff(decl_36838, type, fn_eukaryotic_oxidative_phosphorylation_86: $i > $i).
% 29.22/29.03  tff(decl_36839, type, fn_eukaryotic_oxidative_phosphorylation_85: $i > $i).
% 29.22/29.03  tff(decl_36840, type, fn_eukaryotic_oxidative_phosphorylation_357: $i > $i).
% 29.22/29.03  tff(decl_36841, type, fn_oxidative_phosphorylation_31: $i > $i).
% 29.22/29.03  tff(decl_36842, type, fn_oxidative_phosphorylation_16: $i > $i).
% 29.22/29.03  tff(decl_36843, type, fn_eukaryotic_oxidative_phosphorylation_358: $i > $i).
% 29.22/29.03  tff(decl_36844, type, fn_eukaryotic_oxidative_phosphorylation_418: $i > $i).
% 29.22/29.03  tff(decl_36845, type, fn_eukaryotic_oxidative_phosphorylation_393: $i > $i).
% 29.22/29.03  tff(decl_36846, type, fn_eukaryotic_oxidative_phosphorylation_395: $i > $i).
% 29.22/29.03  tff(decl_36847, type, fn_eukaryotic_oxidative_phosphorylation_394: $i > $i).
% 29.22/29.03  tff(decl_36848, type, fn_eukaryotic_oxidative_phosphorylation_392: $i > $i).
% 29.22/29.03  tff(decl_36849, type, fn_eukaryotic_oxidative_phosphorylation_359: $i > $i).
% 29.22/29.03  tff(decl_36850, type, fn_eukaryotic_oxidative_phosphorylation_360: $i > $i).
% 29.22/29.03  tff(decl_36851, type, fn_eukaryotic_oxidative_phosphorylation_121: $i > $i).
% 29.22/29.03  tff(decl_36852, type, fn_eukaryotic_oxidative_phosphorylation_120: $i > $i).
% 29.22/29.03  tff(decl_36853, type, fn_eukaryotic_oxidative_phosphorylation_307: $i > $i).
% 29.22/29.03  tff(decl_36854, type, fn_eukaryotic_oxidative_phosphorylation_306: $i > $i).
% 29.22/29.03  tff(decl_36855, type, fn_eukaryotic_oxidative_phosphorylation_123: $i > $i).
% 29.22/29.03  tff(decl_36856, type, fn_eukaryotic_oxidative_phosphorylation_227: $i > $i).
% 29.22/29.03  tff(decl_36857, type, fn_eukaryotic_oxidative_phosphorylation_226: $i > $i).
% 29.22/29.03  tff(decl_36858, type, fn_eukaryotic_oxidative_phosphorylation_225: $i > $i).
% 29.22/29.03  tff(decl_36859, type, fn_eukaryotic_oxidative_phosphorylation_224: $i > $i).
% 29.22/29.03  tff(decl_36860, type, fn_eukaryotic_oxidative_phosphorylation_246: $i > $i).
% 29.22/29.03  tff(decl_36861, type, fn_eukaryotic_oxidative_phosphorylation_122: $i > $i).
% 29.22/29.03  tff(decl_36862, type, fn_eukaryotic_oxidative_phosphorylation_292: $i > $i).
% 29.22/29.03  tff(decl_36863, type, fn_eukaryotic_oxidative_phosphorylation_293: $i > $i).
% 29.22/29.03  tff(decl_36864, type, fn_eukaryotic_oxidative_phosphorylation_214: $i > $i).
% 29.22/29.03  tff(decl_36865, type, fn_eukaryotic_oxidative_phosphorylation_213: $i > $i).
% 29.22/29.03  tff(decl_36866, type, fn_eukaryotic_oxidative_phosphorylation_170: $i > $i).
% 29.22/29.03  tff(decl_36867, type, fn_eukaryotic_oxidative_phosphorylation_169: $i > $i).
% 29.22/29.03  tff(decl_36868, type, eukaryotic_pyruvate_oxidation_1: $i > $o).
% 29.22/29.03  tff(decl_36869, type, 'Eukaryotic-Pyruvate-Oxidation': $i).
% 29.22/29.03  tff(decl_36870, type, 'The oxidative conversion of pyruvate into acetyl-CoA which occurs inside Mitochondrion of a eukaryotic cell is referred to as the eukaryotic pyruvate oxidation. It is catalyzed by the pyruvate dehydrogenase complex.': $i).
% 29.22/29.03  tff(decl_36871, type, 'eukaryotic pyruvate oxidation': $i).
% 29.22/29.03  tff(decl_36872, type, 'eukaryotic-pyruvate-oxidation': $i).
% 29.22/29.03  tff(decl_36873, type, fn_eukaryotic_pyruvate_oxidation_1: $i > $i).
% 29.22/29.03  tff(decl_36874, type, fn_eukaryotic_pyruvate_oxidation_2: $i > $i).
% 29.22/29.03  tff(decl_36875, type, fn_eukaryotic_pyruvate_oxidation_3: $i > $i).
% 29.22/29.03  tff(decl_36876, type, fn_eukaryotic_pyruvate_oxidation_4: $i > $i).
% 29.22/29.03  tff(decl_36877, type, fn_eukaryotic_pyruvate_oxidation_5: $i > $i).
% 29.22/29.03  tff(decl_36878, type, fn_eukaryotic_pyruvate_oxidation_6: $i > $i).
% 29.22/29.03  tff(decl_36879, type, fn_eukaryotic_pyruvate_oxidation_7: $i > $i).
% 29.22/29.03  tff(decl_36880, type, fn_eukaryotic_pyruvate_oxidation_8: $i > $i).
% 29.22/29.03  tff(decl_36881, type, fn_eukaryotic_pyruvate_oxidation_9: $i > $i).
% 29.22/29.03  tff(decl_36882, type, fn_eukaryotic_pyruvate_oxidation_10: $i > $i).
% 29.22/29.03  tff(decl_36883, type, fn_eukaryotic_pyruvate_oxidation_13: $i > $i).
% 29.22/29.03  tff(decl_36884, type, fn_eukaryotic_pyruvate_oxidation_14: $i > $i).
% 29.22/29.03  tff(decl_36885, type, fn_eukaryotic_pyruvate_oxidation_15: $i > $i).
% 29.22/29.03  tff(decl_36886, type, fn_eukaryotic_pyruvate_oxidation_16: $i > $i).
% 29.22/29.03  tff(decl_36887, type, fn_eukaryotic_pyruvate_oxidation_17: $i > $i).
% 29.22/29.03  tff(decl_36888, type, fn_eukaryotic_pyruvate_oxidation_18: $i > $i).
% 29.22/29.03  tff(decl_36889, type, fn_eukaryotic_pyruvate_oxidation_19: $i > $i).
% 29.22/29.03  tff(decl_36890, type, fn_eukaryotic_pyruvate_oxidation_20: $i > $i).
% 29.22/29.03  tff(decl_36891, type, fn_eukaryotic_pyruvate_oxidation_21: $i > $i).
% 29.22/29.03  tff(decl_36892, type, fn_eukaryotic_pyruvate_oxidation_22: $i > $i).
% 29.22/29.03  tff(decl_36893, type, fn_eukaryotic_pyruvate_oxidation_23: $i > $i).
% 29.22/29.03  tff(decl_36894, type, fn_eukaryotic_pyruvate_oxidation_24: $i > $i).
% 29.22/29.03  tff(decl_36895, type, fn_eukaryotic_pyruvate_oxidation_25: $i > $i).
% 29.22/29.03  tff(decl_36896, type, fn_eukaryotic_pyruvate_oxidation_26: $i > $i).
% 29.22/29.03  tff(decl_36897, type, fn_eukaryotic_pyruvate_oxidation_27: $i > $i).
% 29.22/29.03  tff(decl_36898, type, fn_eukaryotic_pyruvate_oxidation_28: $i > $i).
% 29.22/29.03  tff(decl_36899, type, fn_eukaryotic_pyruvate_oxidation_29: $i > $i).
% 29.22/29.03  tff(decl_36900, type, fn_eukaryotic_pyruvate_oxidation_30: $i > $i).
% 29.22/29.03  tff(decl_36901, type, fn_eukaryotic_pyruvate_oxidation_31: $i > $i).
% 29.22/29.03  tff(decl_36902, type, fn_eukaryotic_pyruvate_oxidation_32: $i > $i).
% 29.22/29.03  tff(decl_36903, type, fn_eukaryotic_pyruvate_oxidation_33: $i > $i).
% 29.22/29.03  tff(decl_36904, type, fn_eukaryotic_pyruvate_oxidation_34: $i > $i).
% 29.22/29.03  tff(decl_36905, type, fn_eukaryotic_pyruvate_oxidation_35: $i > $i).
% 29.22/29.03  tff(decl_36906, type, fn_eukaryotic_pyruvate_oxidation_36: $i > $i).
% 29.22/29.03  tff(decl_36907, type, fn_eukaryotic_pyruvate_oxidation_37: $i > $i).
% 29.22/29.03  tff(decl_36908, type, fn_eukaryotic_pyruvate_oxidation_38: $i > $i).
% 29.22/29.03  tff(decl_36909, type, fn_eukaryotic_pyruvate_oxidation_39: $i > $i).
% 29.22/29.03  tff(decl_36910, type, fn_eukaryotic_pyruvate_oxidation_40: $i > $i).
% 29.22/29.03  tff(decl_36911, type, fn_eukaryotic_pyruvate_oxidation_41: $i > $i).
% 29.22/29.03  tff(decl_36912, type, fn_eukaryotic_pyruvate_oxidation_42: $i > $i).
% 29.22/29.03  tff(decl_36913, type, fn_eukaryotic_pyruvate_oxidation_43: $i > $i).
% 29.22/29.03  tff(decl_36914, type, fn_eukaryotic_pyruvate_oxidation_44: $i > $i).
% 29.22/29.03  tff(decl_36915, type, fn_eukaryotic_pyruvate_oxidation_45: $i > $i).
% 29.22/29.03  tff(decl_36916, type, fn_eukaryotic_pyruvate_oxidation_46: $i > $i).
% 29.22/29.03  tff(decl_36917, type, fn_eukaryotic_pyruvate_oxidation_47: $i > $i).
% 29.22/29.03  tff(decl_36918, type, fn_eukaryotic_pyruvate_oxidation_48: $i > $i).
% 29.22/29.03  tff(decl_36919, type, fn_eukaryotic_pyruvate_oxidation_49: $i > $i).
% 29.22/29.03  tff(decl_36920, type, fn_eukaryotic_pyruvate_oxidation_50: $i > $i).
% 29.22/29.03  tff(decl_36921, type, fn_eukaryotic_pyruvate_oxidation_52: $i > $i).
% 29.22/29.03  tff(decl_36922, type, fn_eukaryotic_pyruvate_oxidation_53: $i > $i).
% 29.22/29.03  tff(decl_36923, type, fn_eukaryotic_pyruvate_oxidation_54: $i > $i).
% 29.22/29.03  tff(decl_36924, type, fn_eukaryotic_pyruvate_oxidation_55: $i > $i).
% 29.22/29.03  tff(decl_36925, type, fn_eukaryotic_pyruvate_oxidation_56: $i > $i).
% 29.22/29.03  tff(decl_36926, type, fn_eukaryotic_pyruvate_oxidation_57: $i > $i).
% 29.22/29.03  tff(decl_36927, type, fn_eukaryotic_pyruvate_oxidation_58: $i > $i).
% 29.22/29.03  tff(decl_36928, type, fn_eukaryotic_pyruvate_oxidation_59: $i > $i).
% 29.22/29.03  tff(decl_36929, type, fn_eukaryotic_pyruvate_oxidation_60: $i > $i).
% 29.22/29.03  tff(decl_36930, type, fn_eukaryotic_pyruvate_oxidation_61: $i > $i).
% 29.22/29.03  tff(decl_36931, type, fn_eukaryotic_pyruvate_oxidation_62: $i > $i).
% 29.22/29.03  tff(decl_36932, type, fn_eukaryotic_pyruvate_oxidation_63: $i > $i).
% 29.22/29.03  tff(decl_36933, type, fn_eukaryotic_pyruvate_oxidation_64: $i > $i).
% 29.22/29.03  tff(decl_36934, type, fn_eukaryotic_pyruvate_oxidation_65: $i > $i).
% 29.22/29.03  tff(decl_36935, type, fn_eukaryotic_pyruvate_oxidation_66: $i > $i).
% 29.22/29.03  tff(decl_36936, type, fn_eukaryotic_pyruvate_oxidation_67: $i > $i).
% 29.22/29.03  tff(decl_36937, type, fn_eukaryotic_pyruvate_oxidation_68: $i > $i).
% 29.22/29.03  tff(decl_36938, type, fn_eukaryotic_pyruvate_oxidation_69: $i > $i).
% 29.22/29.03  tff(decl_36939, type, fn_eukaryotic_pyruvate_oxidation_70: $i > $i).
% 29.22/29.03  tff(decl_36940, type, fn_eukaryotic_pyruvate_oxidation_71: $i > $i).
% 29.22/29.03  tff(decl_36941, type, fn_eukaryotic_pyruvate_oxidation_72: $i > $i).
% 29.22/29.03  tff(decl_36942, type, fn_eukaryotic_pyruvate_oxidation_73: $i > $i).
% 29.22/29.03  tff(decl_36943, type, fn_eukaryotic_pyruvate_oxidation_74: $i > $i).
% 29.22/29.03  tff(decl_36944, type, fn_eukaryotic_pyruvate_oxidation_75: $i > $i).
% 29.22/29.03  tff(decl_36945, type, fn_eukaryotic_pyruvate_oxidation_76: $i > $i).
% 29.22/29.03  tff(decl_36946, type, fn_eukaryotic_pyruvate_oxidation_77: $i > $i).
% 29.22/29.03  tff(decl_36947, type, fn_eukaryotic_pyruvate_oxidation_78: $i > $i).
% 29.22/29.03  tff(decl_36948, type, fn_eukaryotic_pyruvate_oxidation_79: $i > $i).
% 29.22/29.03  tff(decl_36949, type, fn_eukaryotic_pyruvate_oxidation_80: $i > $i).
% 29.22/29.03  tff(decl_36950, type, fn_eukaryotic_pyruvate_oxidation_81: $i > $i).
% 29.22/29.03  tff(decl_36951, type, fn_eukaryotic_pyruvate_oxidation_82: $i > $i).
% 29.22/29.03  tff(decl_36952, type, fn_eukaryotic_pyruvate_oxidation_83: $i > $i).
% 29.22/29.03  tff(decl_36953, type, fn_eukaryotic_pyruvate_oxidation_84: $i > $i).
% 29.22/29.03  tff(decl_36954, type, fn_eukaryotic_pyruvate_oxidation_85: $i > $i).
% 29.22/29.03  tff(decl_36955, type, fn_eukaryotic_pyruvate_oxidation_86: $i > $i).
% 29.22/29.03  tff(decl_36956, type, fn_eukaryotic_pyruvate_oxidation_87: $i > $i).
% 29.22/29.03  tff(decl_36957, type, fn_eukaryotic_pyruvate_oxidation_88: $i > $i).
% 29.22/29.03  tff(decl_36958, type, fn_eukaryotic_pyruvate_oxidation_89: $i > $i).
% 29.22/29.03  tff(decl_36959, type, fn_eukaryotic_pyruvate_oxidation_90: $i > $i).
% 29.22/29.03  tff(decl_36960, type, fn_eukaryotic_pyruvate_oxidation_91: $i > $i).
% 29.22/29.03  tff(decl_36961, type, fn_eukaryotic_pyruvate_oxidation_92: $i > $i).
% 29.22/29.03  tff(decl_36962, type, fn_eukaryotic_pyruvate_oxidation_93: $i > $i).
% 29.22/29.03  tff(decl_36963, type, fn_eukaryotic_pyruvate_oxidation_94: $i > $i).
% 29.22/29.03  tff(decl_36964, type, fn_eukaryotic_pyruvate_oxidation_95: $i > $i).
% 29.22/29.03  tff(decl_36965, type, fn_eukaryotic_pyruvate_oxidation_96: $i > $i).
% 29.22/29.03  tff(decl_36966, type, fn_eukaryotic_pyruvate_oxidation_97: $i > $i).
% 29.22/29.03  tff(decl_36967, type, fn_eukaryotic_pyruvate_oxidation_98: $i > $i).
% 29.22/29.03  tff(decl_36968, type, fn_eukaryotic_pyruvate_oxidation_99: $i > $i).
% 29.22/29.03  tff(decl_36969, type, fn_eukaryotic_pyruvate_oxidation_100: $i > $i).
% 29.22/29.03  tff(decl_36970, type, fn_nad_plus_10: $i > $i).
% 29.22/29.03  tff(decl_36971, type, fn_nad_plus_2: $i > $i).
% 29.22/29.03  tff(decl_36972, type, fn_nad_plus_11: $i > $i).
% 29.22/29.03  tff(decl_36973, type, fn_nad_plus_15: $i > $i).
% 29.22/29.03  tff(decl_36974, type, fn_nad_plus_19: $i > $i).
% 29.22/29.03  tff(decl_36975, type, fn_pyruvate_oxidation_82: $i > $i).
% 29.22/29.03  tff(decl_36976, type, fn_pyruvate_oxidation_25: $i > $i).
% 29.22/29.03  tff(decl_36977, type, fn_pyruvate_oxidation_20: $i > $i).
% 29.22/29.03  tff(decl_36978, type, fn_eukaryotic_pyruvate_oxidation_51: $i > $i).
% 29.22/29.03  tff(decl_36979, type, fn_pyruvate_oxidation_24: $i > $i).
% 29.22/29.03  tff(decl_36980, type, fn_pyruvate_oxidation_60: $i > $i).
% 29.22/29.03  tff(decl_36981, type, fn_eukaryotic_pyruvate_oxidation_12: $i > $i).
% 29.22/29.03  tff(decl_36982, type, fn_pyruvate_oxidation_14: $i > $i).
% 29.22/29.03  tff(decl_36983, type, fn_eukaryotic_pyruvate_oxidation_11: $i > $i).
% 29.22/29.03  tff(decl_36984, type, fn_pyruvate_oxidation_13: $i > $i).
% 29.22/29.03  tff(decl_36985, type, fn_pyruvate_oxidation_62: $i > $i).
% 29.22/29.03  tff(decl_36986, type, fn_eukaryotic_pyruvate_oxidation_104: $i > $i).
% 29.22/29.03  tff(decl_36987, type, fn_pyruvate_oxidation_30: $i > $i).
% 29.22/29.03  tff(decl_36988, type, fn_pyruvate_oxidation_61: $i > $i).
% 29.22/29.03  tff(decl_36989, type, fn_pyruvate_oxidation_63: $i > $i).
% 29.22/29.03  tff(decl_36990, type, fn_pyruvate_oxidation_86: $i > $i).
% 29.22/29.03  tff(decl_36991, type, fn_pyruvate_oxidation_59: $i > $i).
% 29.22/29.03  tff(decl_36992, type, fn_pyruvate_oxidation_64: $i > $i).
% 29.22/29.03  tff(decl_36993, type, fn_pyruvate_oxidation_8: $i > $i).
% 29.22/29.03  tff(decl_36994, type, fn_pyruvate_oxidation_88: $i > $i).
% 29.22/29.03  tff(decl_36995, type, fn_pyruvate_oxidation_74: $i > $i).
% 29.22/29.03  tff(decl_36996, type, fn_pyruvate_oxidation_35: $i > $i).
% 29.22/29.03  tff(decl_36997, type, fn_pyruvate_oxidation_15: $i > $i).
% 29.22/29.03  tff(decl_36998, type, fn_pyruvate_oxidation_22: $i > $i).
% 29.22/29.03  tff(decl_36999, type, fn_pyruvate_oxidation_27: $i > $i).
% 29.22/29.03  tff(decl_37000, type, fn_pyruvate_oxidation_28: $i > $i).
% 29.22/29.03  tff(decl_37001, type, fn_pyruvate_oxidation_21: $i > $i).
% 29.22/29.03  tff(decl_37002, type, fn_pyruvate_oxidation_32: $i > $i).
% 29.22/29.03  tff(decl_37003, type, fn_pyruvate_oxidation_33: $i > $i).
% 29.22/29.03  tff(decl_37004, type, fn_pyruvate_oxidation_19: $i > $i).
% 29.22/29.03  tff(decl_37005, type, fn_pyruvate_oxidation_31: $i > $i).
% 29.22/29.03  tff(decl_37006, type, fn_eukaryotic_pyruvate_oxidation_103: $i > $i).
% 29.22/29.03  tff(decl_37007, type, fn_pyruvate_oxidation_29: $i > $i).
% 29.22/29.03  tff(decl_37008, type, fn_pyruvate_oxidation_36: $i > $i).
% 29.22/29.03  tff(decl_37009, type, fn_pyruvate_oxidation_37: $i > $i).
% 29.22/29.03  tff(decl_37010, type, fn_pyruvate_oxidation_34: $i > $i).
% 29.22/29.03  tff(decl_37011, type, fn_pyruvate_oxidation_23: $i > $i).
% 29.22/29.03  tff(decl_37012, type, fn_eukaryotic_pyruvate_oxidation_102: $i > $i).
% 29.22/29.03  tff(decl_37013, type, fn_eukaryotic_pyruvate_oxidation_101: $i > $i).
% 29.22/29.03  tff(decl_37014, type, 'Eukaryotic-Ribosome': $i).
% 29.22/29.03  tff(decl_37015, type, 'These are the ribosome molecule found in an Eukaryote. They are slightly larger than the ribosomes found in Prokaryotes': $i).
% 29.22/29.03  tff(decl_37016, type, 'eukaryotic ribosome': $i).
% 29.22/29.03  tff(decl_37017, type, 'eukaryotic-ribosome': $i).
% 29.22/29.03  tff(decl_37018, type, fn_eukaryotic_ribosome_2: $i > $i).
% 29.22/29.03  tff(decl_37019, type, prokaryotic_ribosome_0: $i).
% 29.22/29.03  tff(decl_37020, type, fn_eukaryotic_ribosome_1: $i > $i).
% 29.22/29.03  tff(decl_37021, type, fn_ribosome_1: $i > $i).
% 29.22/29.03  tff(decl_37022, type, fn_ribosome_5: $i > $i).
% 29.22/29.03  tff(decl_37023, type, eukaryotic_transcription_1: $i > $o).
% 29.22/29.03  tff(decl_37024, type, fn_eukaryotic_transcription_3: $i > $i).
% 29.22/29.03  tff(decl_37025, type, 'Eukaryotic-Transcription': $i).
% 29.22/29.03  tff(decl_37026, type, 'The synthesis of RNA using a DNA template in the nucleus of the cell.': $i).
% 29.22/29.03  tff(decl_37027, type, 'transcription in eukaryotes': $i).
% 29.22/29.03  tff(decl_37028, type, transcribe: $i).
% 29.22/29.03  tff(decl_37029, type, 'eukaryotic transcription': $i).
% 29.22/29.03  tff(decl_37030, type, 'eukaryotic-transcription': $i).
% 29.22/29.03  tff(decl_37031, type, fn_eukaryotic_transcription_1: $i > $i).
% 29.22/29.03  tff(decl_37032, type, fn_eukaryotic_transcription_4: $i > $i).
% 29.22/29.03  tff(decl_37033, type, transcription_termination_in_eukaryotes_1: $i > $o).
% 29.22/29.03  tff(decl_37034, type, fn_eukaryotic_transcription_5: $i > $i).
% 29.22/29.03  tff(decl_37035, type, eukaryotic_transcription_initiation_1: $i > $o).
% 29.22/29.03  tff(decl_37036, type, fn_transcription_20: $i > $i).
% 29.22/29.03  tff(decl_37037, type, fn_transcription_1: $i > $i).
% 29.22/29.03  tff(decl_37038, type, 'Eukaryotic-Transcription-Initiation': $i).
% 29.22/29.03  tff(decl_37039, type, 'The events that begin the process of RNA synthesis including the binding of RNA polymerase to a collection of proteins, called transcription factors, that are bound to the DNA molecule at the promotor sequence .': $i).
% 29.22/29.03  tff(decl_37040, type, 'eukaryotic transcription initiation': $i).
% 29.22/29.03  tff(decl_37041, type, 'eukaryotic-transcription-initiation': $i).
% 29.22/29.03  tff(decl_37042, type, fn_eukaryotic_transcription_initiation_1: $i > $i).
% 29.22/29.03  tff(decl_37043, type, fn_eukaryotic_transcription_initiation_2: $i > $i).
% 29.22/29.03  tff(decl_37044, type, fn_eukaryotic_transcription_initiation_3: $i > $i).
% 29.22/29.03  tff(decl_37045, type, fn_eukaryotic_transcription_initiation_4: $i > $i).
% 29.22/29.03  tff(decl_37046, type, fn_eukaryotic_transcription_initiation_5: $i > $i).
% 29.22/29.03  tff(decl_37047, type, fn_eukaryotic_transcription_initiation_6: $i > $i).
% 29.22/29.03  tff(decl_37048, type, fn_eukaryotic_transcription_initiation_7: $i > $i).
% 29.22/29.03  tff(decl_37049, type, fn_eukaryotic_transcription_initiation_8: $i > $i).
% 29.22/29.03  tff(decl_37050, type, fn_eukaryotic_transcription_initiation_9: $i > $i).
% 29.22/29.03  tff(decl_37051, type, rna_polymerase_1: $i > $o).
% 29.22/29.03  tff(decl_37052, type, fn_eukaryotic_transcription_initiation_10: $i > $i).
% 29.22/29.03  tff(decl_37053, type, fn_transcription_initiation_5: $i > $i).
% 29.22/29.03  tff(decl_37054, type, fn_transcription_initiation_7: $i > $i).
% 29.22/29.03  tff(decl_37055, type, 'Eukaryotic-Translation': $i).
% 29.22/29.03  tff(decl_37056, type, 'The synthesis of a polypeptide using the genetic information encoded in an mRNA molecule.  The nucleotide code is translated into a particular sequence of amino acids.': $i).
% 29.22/29.03  tff(decl_37057, type, 'protein synthesis in eukaryotes': $i).
% 29.22/29.03  tff(decl_37058, type, 'translation in eukaryotes': $i).
% 29.22/29.03  tff(decl_37059, type, 'translation in eukaryotic cell': $i).
% 29.22/29.03  tff(decl_37060, type, 'eukaryotic translation': $i).
% 29.22/29.03  tff(decl_37061, type, 'eukaryotic-translation': $i).
% 29.22/29.03  tff(decl_37062, type, fn_eukaryotic_translation_1: $i > $i).
% 29.22/29.03  tff(decl_37063, type, fn_eukaryotic_translation_2: $i > $i).
% 29.22/29.03  tff(decl_37064, type, fn_eukaryotic_translation_3: $i > $i).
% 29.22/29.03  tff(decl_37065, type, polyadenylation_1: $i > $o).
% 29.22/29.03  tff(decl_37066, type, fn_eukaryotic_translation_4: $i > $i).
% 29.22/29.03  tff(decl_37067, type, fn_eukaryotic_translation_5: $i > $i).
% 29.22/29.03  tff(decl_37068, type, fn_eukaryotic_translation_6: $i > $i).
% 29.22/29.03  tff(decl_37069, type, fn_eukaryotic_translation_8: $i > $i).
% 29.22/29.03  tff(decl_37070, type, fn_eukaryotic_translation_9: $i > $i).
% 29.22/29.03  tff(decl_37071, type, fn_eukaryotic_translation_10: $i > $i).
% 29.22/29.03  tff(decl_37072, type, fn_eukaryotic_translation_11: $i > $i).
% 29.22/29.03  tff(decl_37073, type, fn_eukaryotic_translation_12: $i > $i).
% 29.22/29.03  tff(decl_37074, type, fn_eukaryotic_translation_13: $i > $i).
% 29.22/29.03  tff(decl_37075, type, fn_eukaryotic_translation_14: $i > $i).
% 29.22/29.03  tff(decl_37076, type, fn_eukaryotic_translation_18: $i > $i).
% 29.22/29.03  tff(decl_37077, type, fn_eukaryotic_translation_19: $i > $i).
% 29.22/29.03  tff(decl_37078, type, fn_eukaryotic_translation_20: $i > $i).
% 29.22/29.03  tff(decl_37079, type, fn_eukaryotic_translation_21: $i > $i).
% 29.22/29.03  tff(decl_37080, type, fn_eukaryotic_translation_22: $i > $i).
% 29.22/29.03  tff(decl_37081, type, fn_eukaryotic_translation_23: $i > $i).
% 29.22/29.03  tff(decl_37082, type, fn_eukaryotic_translation_24: $i > $i).
% 29.22/29.03  tff(decl_37083, type, fn_eukaryotic_translation_25: $i > $i).
% 29.22/29.03  tff(decl_37084, type, fn_eukaryotic_translation_26: $i > $i).
% 29.22/29.03  tff(decl_37085, type, fn_eukaryotic_translation_27: $i > $i).
% 29.22/29.03  tff(decl_37086, type, translation_elongation_1: $i > $o).
% 29.22/29.03  tff(decl_37087, type, fn_eukaryotic_translation_28: $i > $i).
% 29.22/29.03  tff(decl_37088, type, translation_termination_1: $i > $o).
% 29.22/29.03  tff(decl_37089, type, fn_eukaryotic_translation_30: $i > $i).
% 29.22/29.03  tff(decl_37090, type, fn_eukaryotic_translation_31: $i > $i).
% 29.22/29.03  tff(decl_37091, type, fn_eukaryotic_translation_32: $i > $i).
% 29.22/29.03  tff(decl_37092, type, fn_eukaryotic_translation_33: $i > $i).
% 29.22/29.03  tff(decl_37093, type, fn_eukaryotic_translation_34: $i > $i).
% 29.22/29.03  tff(decl_37094, type, fn_eukaryotic_translation_35: $i > $i).
% 29.22/29.03  tff(decl_37095, type, fn_eukaryotic_translation_16: $i > $i).
% 29.22/29.03  tff(decl_37096, type, fn_polymer_synthesis_6: $i > $i).
% 29.22/29.03  tff(decl_37097, type, fn_eukaryotic_translation_15: $i > $i).
% 29.22/29.03  tff(decl_37098, type, fn_polymer_synthesis_5: $i > $i).
% 29.22/29.03  tff(decl_37099, type, fn_polymer_synthesis_9: $i > $i).
% 29.22/29.03  tff(decl_37100, type, fn_polymer_synthesis_10: $i > $i).
% 29.22/29.03  tff(decl_37101, type, fn_translation_27: $i > $i).
% 29.22/29.03  tff(decl_37102, type, fn_polymer_synthesis_18: $i > $i).
% 29.22/29.03  tff(decl_37103, type, fn_translation_18: $i > $i).
% 29.22/29.03  tff(decl_37104, type, fn_translation_11: $i > $i).
% 29.22/29.03  tff(decl_37105, type, fn_translation_15: $i > $i).
% 29.22/29.03  tff(decl_37106, type, fn_translation_13: $i > $i).
% 29.22/29.03  tff(decl_37107, type, fn_eukaryotic_translation_17: $i > $i).
% 29.22/29.03  tff(decl_37108, type, fn_translation_37: $i > $i).
% 29.22/29.03  tff(decl_37109, type, fn_eukaryotic_translation_7: $i > $i).
% 29.22/29.03  tff(decl_37110, type, fn_translation_10: $i > $i).
% 29.22/29.03  tff(decl_37111, type, fn_translation_26: $i > $i).
% 29.22/29.03  tff(decl_37112, type, fn_translation_29: $i > $i).
% 29.22/29.03  tff(decl_37113, type, fn_translation_36: $i > $i).
% 29.22/29.03  tff(decl_37114, type, fn_translation_14: $i > $i).
% 29.22/29.03  tff(decl_37115, type, fn_translation_28: $i > $i).
% 29.22/29.03  tff(decl_37116, type, fn_translation_16: $i > $i).
% 29.22/29.03  tff(decl_37117, type, fn_translation_12: $i > $i).
% 29.22/29.03  tff(decl_37118, type, fn_translation_23: $i > $i).
% 29.22/29.03  tff(decl_37119, type, fn_translation_19: $i > $i).
% 29.22/29.03  tff(decl_37120, type, fn_translation_8: $i > $i).
% 29.22/29.03  tff(decl_37121, type, fn_translation_20: $i > $i).
% 29.22/29.03  tff(decl_37122, type, fn_translation_17: $i > $i).
% 29.22/29.03  tff(decl_37123, type, 'Eumetazoan': $i).
% 29.22/29.03  tff(decl_37124, type, 'Any animal that has true tissues.': $i).
% 29.22/29.03  tff(decl_37125, type, eumetazoa: $i).
% 29.22/29.03  tff(decl_37126, type, eumetazoan: $i).
% 29.22/29.03  tff(decl_37127, type, fn_eumetazoan_3: $i > $i).
% 29.22/29.03  tff(decl_37128, type, fn_eumetazoan_4: $i > $i).
% 29.22/29.03  tff(decl_37129, type, fn_eumetazoan_5: $i > $i).
% 29.22/29.03  tff(decl_37130, type, fn_eumetazoan_7: $i > $i).
% 29.22/29.03  tff(decl_37131, type, fn_eumetazoan_10: $i > $i).
% 29.22/29.03  tff(decl_37132, type, fn_eumetazoan_11: $i > $i).
% 29.22/29.03  tff(decl_37133, type, fn_eumetazoan_12: $i > $i).
% 29.22/29.03  tff(decl_37134, type, fn_eumetazoan_13: $i > $i).
% 29.22/29.03  tff(decl_37135, type, fn_eumetazoan_14: $i > $i).
% 29.22/29.03  tff(decl_37136, type, fn_eumetazoan_15: $i > $i).
% 29.22/29.03  tff(decl_37137, type, fn_eumetazoan_16: $i > $i).
% 29.22/29.03  tff(decl_37138, type, fn_eumetazoan_17: $i > $i).
% 29.22/29.03  tff(decl_37139, type, fn_eumetazoan_18: $i > $i).
% 29.22/29.03  tff(decl_37140, type, fn_eumetazoan_19: $i > $i).
% 29.22/29.03  tff(decl_37141, type, fn_eumetazoan_23: $i > $i).
% 29.22/29.03  tff(decl_37142, type, fn_eumetazoan_24: $i > $i).
% 29.22/29.03  tff(decl_37143, type, fn_eumetazoan_25: $i > $i).
% 29.22/29.03  tff(decl_37144, type, fn_eumetazoan_26: $i > $i).
% 29.22/29.03  tff(decl_37145, type, fn_eumetazoan_27: $i > $i).
% 29.22/29.03  tff(decl_37146, type, fn_eumetazoan_29: $i > $i).
% 29.22/29.03  tff(decl_37147, type, europium_1: $i > $o).
% 29.22/29.03  tff(decl_37148, type, 'Europium': $i).
% 29.22/29.03  tff(decl_37149, type, 'Europium is a metal atom with atomic number 63. It is represented by the symbol Eu.': $i).
% 29.22/29.03  tff(decl_37150, type, europium: $i).
% 29.22/29.03  tff(decl_37151, type, eu: $i).
% 29.22/29.03  tff(decl_37152, type, fn_europium_3: $i > $i).
% 29.22/29.03  tff(decl_37153, type, fn_europium_4: $i > $i).
% 29.22/29.03  tff(decl_37154, type, fn_europium_5: $i > $i).
% 29.22/29.03  tff(decl_37155, type, fn_europium_9: $i > $i).
% 29.22/29.03  tff(decl_37156, type, fn_europium_10: $i > $i).
% 29.22/29.03  tff(decl_37157, type, fn_europium_11: $i > $i).
% 29.22/29.03  tff(decl_37158, type, fn_europium_12: $i > $i).
% 29.22/29.03  tff(decl_37159, type, "63": $i).
% 29.22/29.03  tff(decl_37160, type, "1.2": $i).
% 29.22/29.03  tff(decl_37161, type, "152": $i).
% 29.22/29.03  tff(decl_37162, type, fn_europium_7: $i > $i).
% 29.22/29.03  tff(decl_37163, type, fn_europium_8: $i > $i).
% 29.22/29.03  tff(decl_37164, type, fn_europium_6: $i > $i).
% 29.22/29.03  tff(decl_37165, type, 'Euryarchaeota': $i).
% 29.22/29.03  tff(decl_37166, type, 'Phylum of archaen organisms, including methanogens, halophiles, and some thermophiles.': $i).
% 29.22/29.03  tff(decl_37167, type, euryarchaeota: $i).
% 29.22/29.03  tff(decl_37168, type, euryhaline_1: $i > $o).
% 29.22/29.03  tff(decl_37169, type, 'Euryhaline': $i).
% 29.22/29.03  tff(decl_37170, type, 'Able to tolerate substantial changes in external osmolarity.': $i).
% 29.22/29.03  tff(decl_37171, type, euryhaline: $i).
% 29.22/29.03  tff(decl_37172, type, regulator_animal_1: $i > $o).
% 29.22/29.03  tff(decl_37173, type, fn_euryhaline_1: $i > $i).
% 29.22/29.03  tff(decl_37174, type, osmoregulator_1: $i > $o).
% 29.22/29.03  tff(decl_37175, type, fn_osmoregulator_3: $i > $i).
% 29.22/29.03  tff(decl_37176, type, 'Eurypterid': $i).
% 29.22/29.03  tff(decl_37177, type, 'Member of an extinct group of chelicerates called sea scorpions.': $i).
% 29.22/29.03  tff(decl_37178, type, 'water scorpion': $i).
% 29.22/29.03  tff(decl_37179, type, 'water-scorpion': $i).
% 29.22/29.03  tff(decl_37180, type, eurypterid: $i).
% 29.22/29.03  tff(decl_37181, type, eustachian_tube_1: $i > $o).
% 29.22/29.03  tff(decl_37182, type, 'Eustachian-Tube': $i).
% 29.22/29.03  tff(decl_37183, type, 'The tube that links the middle ear and the nasopharynx.': $i).
% 29.22/29.03  tff(decl_37184, type, 'eustachian tube': $i).
% 29.22/29.03  tff(decl_37185, type, 'eustachian-tube': $i).
% 29.22/29.03  tff(decl_37186, type, eutherian_1: $i > $o).
% 29.22/29.03  tff(decl_37187, type, 'Eutherian': $i).
% 29.22/29.03  tff(decl_37188, type, 'A placental mammal, in which embryonic and fetal development occur within the uterus.': $i).
% 29.22/29.03  tff(decl_37189, type, eutherian: $i).
% 29.22/29.03  tff(decl_37190, type, mammal_1: $i > $o).
% 29.22/29.03  tff(decl_37191, type, insectivora_1: $i > $o).
% 29.22/29.03  tff(decl_37192, type, lagomorpha_1: $i > $o).
% 29.22/29.03  tff(decl_37193, type, 'Eutrophic-Lake': $i).
% 29.22/29.03  tff(decl_37194, type, 'A lake that has a high rate of biological productivity supported by a high rate of nutrient cycling.': $i).
% 29.22/29.03  tff(decl_37195, type, 'eutrophic lake': $i).
% 29.22/29.03  tff(decl_37196, type, 'eutrophic-lake': $i).
% 29.22/29.03  tff(decl_37197, type, eutrophication_1: $i > $o).
% 29.22/29.03  tff(decl_37198, type, 'Eutrophication': $i).
% 29.22/29.03  tff(decl_37199, type, 'A process by which nutrients such as phosphate and nitrate become highly concentrated in a body of water. This results in rapid population increases of cyanobacteria and phytoplankton.': $i).
% 29.22/29.03  tff(decl_37200, type, eutrophication: $i).
% 29.22/29.03  tff(decl_37201, type, 'Evaporation': $i).
% 29.22/29.03  tff(decl_37202, type, 'A state change during which a liquid substance becomes a gas.': $i).
% 29.22/29.03  tff(decl_37203, type, vaporisation: $i).
% 29.22/29.03  tff(decl_37204, type, vaporization: $i).
% 29.22/29.03  tff(decl_37205, type, vaporise: $i).
% 29.22/29.03  tff(decl_37206, type, vaporize: $i).
% 29.22/29.03  tff(decl_37207, type, evaporate: $i).
% 29.22/29.03  tff(decl_37208, type, evaporation: $i).
% 29.22/29.03  tff(decl_37209, type, fn_evaporation_3: $i > $i).
% 29.22/29.03  tff(decl_37210, type, fn_evaporation_4: $i > $i).
% 29.22/29.03  tff(decl_37211, type, fn_evaporation_5: $i > $i).
% 29.22/29.03  tff(decl_37212, type, fn_evaporation_6: $i > $i).
% 29.22/29.03  tff(decl_37213, type, fn_evaporation_7: $i > $i).
% 29.22/29.03  tff(decl_37214, type, fn_evaporation_8: $i > $i).
% 29.22/29.03  tff(decl_37215, type, fn_evaporation_10: $i > $i).
% 29.22/29.03  tff(decl_37216, type, fn_evaporation_11: $i > $i).
% 29.22/29.03  tff(decl_37217, type, fn_evaporation_12: $i > $i).
% 29.22/29.03  tff(decl_37218, type, fn_evaporation_13: $i > $i).
% 29.22/29.03  tff(decl_37219, type, fn_evaporation_14: $i > $i).
% 29.22/29.03  tff(decl_37220, type, fn_evaporation_15: $i > $i).
% 29.22/29.03  tff(decl_37221, type, fn_evaporation_16: $i > $i).
% 29.22/29.03  tff(decl_37222, type, fn_evaporation_17: $i > $i).
% 29.22/29.03  tff(decl_37223, type, fn_evaporation_18: $i > $i).
% 29.22/29.03  tff(decl_37224, type, fn_evaporation_19: $i > $i).
% 29.22/29.03  tff(decl_37225, type, fn_evaporation_20: $i > $i).
% 29.22/29.03  tff(decl_37226, type, fn_evaporation_21: $i > $i).
% 29.22/29.03  tff(decl_37227, type, fn_evaporation_22: $i > $i).
% 29.22/29.03  tff(decl_37228, type, fn_evaporation_23: $i > $i).
% 29.22/29.03  tff(decl_37229, type, fn_evaporation_24: $i > $i).
% 29.22/29.03  tff(decl_37230, type, fn_evaporation_25: $i > $i).
% 29.22/29.03  tff(decl_37231, type, fn_evaporation_26: $i > $i).
% 29.22/29.03  tff(decl_37232, type, evaporation_by_heat_1: $i > $o).
% 29.22/29.03  tff(decl_37233, type, 'Evaporation-By-Heat': $i).
% 29.22/29.03  tff(decl_37234, type, 'The vaporization of a liquid from its surface caused by the application of heat to the liquid.': $i).
% 29.22/29.03  tff(decl_37235, type, 'evaporation by heat': $i).
% 29.22/29.03  tff(decl_37236, type, 'evaporation-by-heat': $i).
% 29.22/29.03  tff(decl_37237, type, fn_evaporation_by_heat_3: $i > $i).
% 29.22/29.03  tff(decl_37238, type, fn_evaporation_by_heat_4: $i > $i).
% 29.22/29.03  tff(decl_37239, type, fn_evaporation_by_heat_5: $i > $i).
% 29.22/29.03  tff(decl_37240, type, fn_evaporation_by_heat_6: $i > $i).
% 29.22/29.03  tff(decl_37241, type, fn_evaporation_by_heat_7: $i > $i).
% 29.22/29.03  tff(decl_37242, type, fn_evaporation_by_heat_8: $i > $i).
% 29.22/29.03  tff(decl_37243, type, fn_evaporation_by_heat_9: $i > $i).
% 29.22/29.03  tff(decl_37244, type, fn_evaporation_by_heat_10: $i > $i).
% 29.22/29.03  tff(decl_37245, type, fn_evaporation_by_heat_11: $i > $i).
% 29.22/29.03  tff(decl_37246, type, fn_evaporation_by_heat_12: $i > $i).
% 29.22/29.03  tff(decl_37247, type, fn_evaporation_by_heat_13: $i > $i).
% 29.22/29.03  tff(decl_37248, type, fn_evaporation_by_heat_16: $i > $i).
% 29.22/29.03  tff(decl_37249, type, fn_evaporation_by_heat_14: $i > $i).
% 29.22/29.03  tff(decl_37250, type, fn_evaporation_2: $i > $i).
% 29.22/29.03  tff(decl_37251, type, fn_evaporation_by_heat_17: $i > $i).
% 29.22/29.03  tff(decl_37252, type, fn_evaporation_1: $i > $i).
% 29.22/29.03  tff(decl_37253, type, fn_evaporation_by_heat_15: $i > $i).
% 29.22/29.03  tff(decl_37254, type, fn_evaporation_9: $i > $i).
% 29.22/29.03  tff(decl_37255, type, evaporative_cooling_1: $i > $o).
% 29.22/29.03  tff(decl_37256, type, 'Evaporative-Cooling': $i).
% 29.22/29.03  tff(decl_37257, type, 'Water evaporates from the surface of the liquid, resulting in cooling of the remaining water.': $i).
% 29.22/29.03  tff(decl_37258, type, 'cooling of water body': $i).
% 29.22/29.03  tff(decl_37259, type, 'cooling of body with water': $i).
% 29.22/29.03  tff(decl_37260, type, 'cooling through evaporation': $i).
% 29.22/29.03  tff(decl_37261, type, 'evaporative cooling': $i).
% 29.22/29.03  tff(decl_37262, type, 'evaporative-cooling': $i).
% 29.22/29.03  tff(decl_37263, type, fn_evaporative_cooling_1: $i > $i).
% 29.22/29.03  tff(decl_37264, type, fn_evaporative_cooling_2: $i > $i).
% 29.22/29.03  tff(decl_37265, type, fn_evaporative_cooling_5: $i > $i).
% 29.22/29.03  tff(decl_37266, type, fn_evaporative_cooling_6: $i > $i).
% 29.22/29.03  tff(decl_37267, type, fn_evaporative_cooling_7: $i > $i).
% 29.22/29.03  tff(decl_37268, type, fn_evaporative_cooling_8: $i > $i).
% 29.22/29.03  tff(decl_37269, type, fn_evaporative_cooling_9: $i > $i).
% 29.22/29.03  tff(decl_37270, type, fn_evaporative_cooling_10: $i > $i).
% 29.22/29.03  tff(decl_37271, type, fn_evaporative_cooling_11: $i > $i).
% 29.22/29.03  tff(decl_37272, type, fn_evaporative_cooling_12: $i > $i).
% 29.22/29.03  tff(decl_37273, type, fn_evaporative_cooling_13: $i > $i).
% 29.22/29.03  tff(decl_37274, type, fn_evaporative_cooling_14: $i > $i).
% 29.22/29.03  tff(decl_37275, type, fn_evaporative_cooling_3: $i > $i).
% 29.22/29.03  tff(decl_37276, type, fn_evaporative_cooling_16: $i > $i).
% 29.22/29.03  tff(decl_37277, type, fn_evaporative_cooling_15: $i > $i).
% 29.22/29.03  tff(decl_37278, type, fn_evaporative_cooling_4: $i > $i).
% 29.22/29.03  tff(decl_37279, type, evaporative_cooling_from_human_skin_1: $i > $o).
% 29.22/29.03  tff(decl_37280, type, 'Evaporative-Cooling-From-Human-Skin': $i).
% 29.22/29.03  tff(decl_37281, type, 'The cooling of the bodies of terrestrial animals by the evaporation of water (sweat) from their skin.': $i).
% 29.22/29.03  tff(decl_37282, type, sweating: $i).
% 29.22/29.03  tff(decl_37283, type, perspiring: $i).
% 29.22/29.03  tff(decl_37284, type, 'evaporative cooling from human skin': $i).
% 29.22/29.03  tff(decl_37285, type, 'evaporative-cooling-from-human-skin': $i).
% 29.22/29.03  tff(decl_37286, type, evaporative_cooling_in_terrestrial_organism_1: $i > $o).
% 29.22/29.03  tff(decl_37287, type, evaporative_cooling_from_leaf_1: $i > $o).
% 29.22/29.03  tff(decl_37288, type, fn_evaporative_cooling_from_human_skin_1: $i > $i).
% 29.22/29.03  tff(decl_37289, type, skin_1: $i > $o).
% 29.22/29.03  tff(decl_37290, type, fn_evaporative_cooling_from_human_skin_2: $i > $i).
% 29.22/29.03  tff(decl_37291, type, fn_evaporative_cooling_from_human_skin_3: $i > $i).
% 29.22/29.03  tff(decl_37292, type, fn_evaporative_cooling_from_human_skin_4: $i > $i).
% 29.22/29.03  tff(decl_37293, type, fn_evaporative_cooling_from_human_skin_5: $i > $i).
% 29.22/29.03  tff(decl_37294, type, fn_evaporative_cooling_from_human_skin_6: $i > $i).
% 29.22/29.03  tff(decl_37295, type, fn_evaporative_cooling_from_human_skin_7: $i > $i).
% 29.22/29.03  tff(decl_37296, type, water_evaporation_1: $i > $o).
% 29.22/29.03  tff(decl_37297, type, fn_evaporative_cooling_in_terrestrial_organism_4: $i > $i).
% 29.22/29.03  tff(decl_37298, type, fn_evaporative_cooling_in_terrestrial_organism_5: $i > $i).
% 29.22/29.03  tff(decl_37299, type, fn_evaporative_cooling_in_terrestrial_organism_3: $i > $i).
% 29.22/29.03  tff(decl_37300, type, fn_evaporative_cooling_from_human_skin_8: $i > $i).
% 29.22/29.03  tff(decl_37301, type, 'Evaporative-Cooling-From-Leaf': $i).
% 29.22/29.03  tff(decl_37302, type, 'Evaporation of water from the xylem in the leaf into the atmosphere to keep the leaf from burning in the sun.': $i).
% 29.22/29.03  tff(decl_37303, type, 'evaporative cooling from leaf': $i).
% 29.22/29.03  tff(decl_37304, type, 'evaporative-cooling-from-leaf': $i).
% 29.22/29.03  tff(decl_37305, type, fn_evaporative_cooling_from_leaf_1: $i > $i).
% 29.22/29.03  tff(decl_37306, type, fn_evaporative_cooling_from_leaf_2: $i > $i).
% 29.22/29.03  tff(decl_37307, type, fn_evaporative_cooling_from_leaf_3: $i > $i).
% 29.22/29.03  tff(decl_37308, type, fn_evaporative_cooling_from_leaf_4: $i > $i).
% 29.22/29.03  tff(decl_37309, type, fn_evaporative_cooling_from_leaf_5: $i > $i).
% 29.22/29.03  tff(decl_37310, type, fn_evaporative_cooling_from_leaf_6: $i > $i).
% 29.22/29.03  tff(decl_37311, type, fn_evaporative_cooling_from_leaf_8: $i > $i).
% 29.22/29.03  tff(decl_37312, type, fn_evaporative_cooling_from_leaf_7: $i > $i).
% 29.22/29.03  tff(decl_37313, type, evaporative_cooling_in_lake_1: $i > $o).
% 29.22/29.03  tff(decl_37314, type, 'Evaporative-Cooling-In-Lake': $i).
% 29.22/29.03  tff(decl_37315, type, 'Evaporation of water from the surface of the lake cooling the lake.  This contributes to the stability of temperature in the lake.': $i).
% 29.22/29.03  tff(decl_37316, type, 'evaporative cooling in lake': $i).
% 29.22/29.03  tff(decl_37317, type, 'evaporative-cooling-in-lake': $i).
% 29.22/29.03  tff(decl_37318, type, evaporative_cooling_of_water_1: $i > $o).
% 29.22/29.03  tff(decl_37319, type, evaporative_cooling_in_pond_1: $i > $o).
% 29.22/29.03  tff(decl_37320, type, fn_evaporative_cooling_in_lake_1: $i > $i).
% 29.22/29.03  tff(decl_37321, type, fn_evaporative_cooling_in_lake_2: $i > $i).
% 29.22/29.03  tff(decl_37322, type, fn_evaporative_cooling_in_lake_5: $i > $i).
% 29.22/29.03  tff(decl_37323, type, fn_evaporative_cooling_in_lake_6: $i > $i).
% 29.22/29.03  tff(decl_37324, type, fn_evaporative_cooling_in_lake_7: $i > $i).
% 29.22/29.03  tff(decl_37325, type, fn_evaporative_cooling_in_lake_8: $i > $i).
% 29.22/29.03  tff(decl_37326, type, fn_evaporative_cooling_in_lake_3: $i > $i).
% 29.22/29.03  tff(decl_37327, type, fn_evaporative_cooling_in_lake_4: $i > $i).
% 29.22/29.03  tff(decl_37328, type, pond_1: $i > $o).
% 29.22/29.03  tff(decl_37329, type, fn_evaporative_cooling_in_pond_2: $i > $i).
% 29.22/29.03  tff(decl_37330, type, 'Evaporative-Cooling-In-Pond': $i).
% 29.22/29.03  tff(decl_37331, type, 'Evaporation of water from the surface of the pond cooling the pond.  This contributes to the stability of temperature in the pond.': $i).
% 29.22/29.03  tff(decl_37332, type, 'evaporative cooling in pond': $i).
% 29.22/29.03  tff(decl_37333, type, 'evaporative-cooling-in-pond': $i).
% 29.22/29.03  tff(decl_37334, type, fn_evaporative_cooling_in_pond_1: $i > $i).
% 29.22/29.03  tff(decl_37335, type, fn_evaporative_cooling_in_pond_4: $i > $i).
% 29.22/29.03  tff(decl_37336, type, fn_evaporative_cooling_in_pond_5: $i > $i).
% 29.22/29.03  tff(decl_37337, type, fn_evaporative_cooling_in_pond_6: $i > $i).
% 29.22/29.03  tff(decl_37338, type, fn_evaporative_cooling_in_pond_7: $i > $i).
% 29.22/29.03  tff(decl_37339, type, fn_evaporative_cooling_in_pond_11: $i > $i).
% 29.22/29.03  tff(decl_37340, type, terrestrial_organism_1: $i > $o).
% 29.22/29.03  tff(decl_37341, type, 'Evaporative-Cooling-In-Terrestrial-Organism': $i).
% 29.22/29.03  tff(decl_37342, type, 'Evaporation of water from the surface of a land-dwelling organism.  This contributes to the stability of temperature in the organism.': $i).
% 29.22/29.03  tff(decl_37343, type, 'evaporative cooling in terrestrial organism': $i).
% 29.22/29.03  tff(decl_37344, type, 'evaporative-cooling-in-terrestrial-organism': $i).
% 29.22/29.03  tff(decl_37345, type, fn_evaporative_cooling_in_terrestrial_organism_2: $i > $i).
% 29.22/29.03  tff(decl_37346, type, fn_evaporative_cooling_of_water_1: $i > $i).
% 29.22/29.03  tff(decl_37347, type, 'Evaporative-Cooling-Of-Water': $i).
% 29.22/29.03  tff(decl_37348, type, 'The process in which the surface of an object becomes cooler during evaporation, a result of the molecules with the greatest kinetic energy changing from the liquid to the gaseous state.': $i).
% 29.22/29.03  tff(decl_37349, type, 'evaporative cooling of water': $i).
% 29.22/29.03  tff(decl_37350, type, 'evaporative-cooling-of-water': $i).
% 29.22/29.03  tff(decl_37351, type, evapotranspiration_1: $i > $o).
% 29.22/29.03  tff(decl_37352, type, 'Evapotranspiration': $i).
% 29.22/29.03  tff(decl_37353, type, 'The total evaporation of water from an ecosystem, including evaporation from soil and the outside of plants, as well as the transpiration of water from within plants through stomata.': $i).
% 29.22/29.03  tff(decl_37354, type, evapotranspiration: $i).
% 29.22/29.03  tff(decl_37355, type, water_cycle_process_1: $i > $o).
% 29.22/29.03  tff(decl_37356, type, fn_evapotranspiration_1: $i > $i).
% 29.22/29.03  tff(decl_37357, type, fn_evapotranspiration_2: $i > $i).
% 29.22/29.03  tff(decl_37358, type, fn_evapotranspiration_3: $i > $i).
% 29.22/29.03  tff(decl_37359, type, fn_evapotranspiration_7: $i > $i).
% 29.22/29.03  tff(decl_37360, type, fn_evapotranspiration_8: $i > $i).
% 29.22/29.03  tff(decl_37361, type, fn_evapotranspiration_9: $i > $i).
% 29.22/29.03  tff(decl_37362, type, fn_evapotranspiration_10: $i > $i).
% 29.22/29.03  tff(decl_37363, type, fn_evapotranspiration_11: $i > $i).
% 29.22/29.03  tff(decl_37364, type, fn_evapotranspiration_12: $i > $i).
% 29.22/29.03  tff(decl_37365, type, fn_evapotranspiration_13: $i > $i).
% 29.22/29.03  tff(decl_37366, type, fn_evapotranspiration_14: $i > $i).
% 29.22/29.03  tff(decl_37367, type, fn_evapotranspiration_15: $i > $i).
% 29.22/29.03  tff(decl_37368, type, fn_evapotranspiration_16: $i > $i).
% 29.22/29.03  tff(decl_37369, type, fn_evapotranspiration_17: $i > $i).
% 29.22/29.03  tff(decl_37370, type, fn_evapotranspiration_18: $i > $i).
% 29.22/29.03  tff(decl_37371, type, fn_evapotranspiration_19: $i > $i).
% 29.22/29.03  tff(decl_37372, type, fn_evapotranspiration_20: $i > $i).
% 29.22/29.03  tff(decl_37373, type, fn_evapotranspiration_21: $i > $i).
% 29.22/29.03  tff(decl_37374, type, fn_evapotranspiration_22: $i > $i).
% 29.22/29.03  tff(decl_37375, type, fn_evapotranspiration_23: $i > $i).
% 29.22/29.03  tff(decl_37376, type, fn_evapotranspiration_24: $i > $i).
% 29.22/29.03  tff(decl_37377, type, fn_water_79: $i > $i).
% 29.22/29.03  tff(decl_37378, type, fn_evapotranspiration_26: $i > $i).
% 29.22/29.03  tff(decl_37379, type, fn_evapotranspiration_5: $i > $i).
% 29.22/29.03  tff(decl_37380, type, fn_evapotranspiration_6: $i > $i).
% 29.22/29.03  tff(decl_37381, type, fn_evapotranspiration_25: $i > $i).
% 29.22/29.03  tff(decl_37382, type, 'Event': $i).
% 29.22/29.03  tff(decl_37383, type, measure: $i).
% 29.22/29.03  tff(decl_37384, type, role: $i).
% 29.22/29.03  tff(decl_37385, type, support: $i).
% 29.22/29.03  tff(decl_37386, type, 'sub event': $i).
% 29.22/29.03  tff(decl_37387, type, 'sub-event': $i).
% 29.22/29.03  tff(decl_37388, type, phase: $i).
% 29.22/29.03  tff(decl_37389, type, step: $i).
% 29.22/29.03  tff(decl_37390, type, stage: $i).
% 29.22/29.03  tff(decl_37391, type, pathway: $i).
% 29.22/29.03  tff(decl_37392, type, subevent: $i).
% 29.22/29.03  tff(decl_37393, type, prevent: $i).
% 29.22/29.03  tff(decl_37394, type, 'previous event': $i).
% 29.22/29.03  tff(decl_37395, type, objective: $i).
% 29.22/29.03  tff(decl_37396, type, 'next event': $i).
% 29.22/29.03  tff(decl_37397, type, 'next-event': $i).
% 29.22/29.03  tff(decl_37398, type, inhibit: $i).
% 29.22/29.03  tff(decl_37399, type, 'event of in': $i).
% 29.22/29.03  tff(decl_37400, type, 'in event': $i).
% 29.22/29.03  tff(decl_37401, type, 'in-event': $i).
% 29.22/29.03  tff(decl_37402, type, 'has goal': $i).
% 29.22/29.03  tff(decl_37403, type, 'has-goal': $i).
% 29.22/29.03  tff(decl_37404, type, purpose: $i).
% 29.22/29.03  tff(decl_37405, type, function: $i).
% 29.22/29.03  tff(decl_37406, type, 'has function': $i).
% 29.22/29.03  tff(decl_37407, type, 'has-function': $i).
% 29.22/29.03  tff(decl_37408, type, 'first step': $i).
% 29.22/29.03  tff(decl_37409, type, 'first subevent': $i).
% 29.22/29.03  tff(decl_37410, type, 'first-subevent': $i).
% 29.22/29.03  tff(decl_37411, type, facilitate: $i).
% 29.22/29.03  tff(decl_37412, type, during: $i).
% 29.22/29.03  tff(decl_37413, type, mean: $i).
% 29.22/29.03  tff(decl_37414, type, means: $i).
% 29.22/29.03  tff(decl_37415, type, 'by means of': $i).
% 29.22/29.03  tff(decl_37416, type, 'by-means-of': $i).
% 29.22/29.03  tff(decl_37417, type, event: $i).
% 29.22/29.03  tff(decl_37418, type, eventproperty_1: $i > $o).
% 29.22/29.03  tff(decl_37419, type, 'EventProperty': $i).
% 29.22/29.03  tff(decl_37420, type, eventproperty: $i).
% 29.22/29.03  tff(decl_37421, type, 'Evolution': $i).
% 29.22/29.03  tff(decl_37422, type, 'Descent with modification; the idea that living species are descendants of ancestral species that were different from the present-day ones; also defined more narrowly as the change in the genetic composition of a population from generation to generation.': $i).
% 29.22/29.03  tff(decl_37423, type, evolve: $i).
% 29.22/29.03  tff(decl_37424, type, evolution: $i).
% 29.22/29.03  tff(decl_37425, type, evolution_of_mitosis_hypothesis_1: $i > $o).
% 29.22/29.03  tff(decl_37426, type, 'Evolution-Of-Mitosis-Hypothesis': $i).
% 29.22/29.03  tff(decl_37427, type, 'Hypothesis which seeks to explain the origin of eukaryotic evolution by comparing it to binary fission in prokaryotes.': $i).
% 29.22/29.03  tff(decl_37428, type, 'evolution of mitosis hypothesis': $i).
% 29.22/29.03  tff(decl_37429, type, 'evolution-of-mitosis-hypothesis': $i).
% 29.22/29.03  tff(decl_37430, type, evolutionary_developmental_biology_1: $i > $o).
% 29.22/29.03  tff(decl_37431, type, 'Evolutionary-Developmental-Biology': $i).
% 29.22/29.03  tff(decl_37432, type, 'The interface between evolutionary biology and the study of how organisms develop.  Involves the comparison of development in related groups of organisms and the formation of hypotheses as to how developmental processes evolved.': $i).
% 29.22/29.03  tff(decl_37433, type, 'evolutionary developmental biology': $i).
% 29.22/29.03  tff(decl_37434, type, 'evolutionary-developmental-biology': $i).
% 29.22/29.03  tff(decl_37435, type, human_evolution_1: $i > $o).
% 29.22/29.03  tff(decl_37436, type, macroevolution_1: $i > $o).
% 29.22/29.03  tff(decl_37437, type, microevolution_1: $i > $o).
% 29.22/29.03  tff(decl_37438, type, 'Evolutionary-Process': $i).
% 29.22/29.03  tff(decl_37439, type, 'A process related to biological evolution.': $i).
% 29.22/29.03  tff(decl_37440, type, 'evolutionary process': $i).
% 29.22/29.03  tff(decl_37441, type, 'evolutionary-process': $i).
% 29.22/29.03  tff(decl_37442, type, 'Evolutionary-Representation': $i).
% 29.22/29.03  tff(decl_37443, type, 'A method of representing evolutionary data.': $i).
% 29.22/29.03  tff(decl_37444, type, 'evolutionary representation': $i).
% 29.22/29.03  tff(decl_37445, type, 'evolutionary-representation': $i).
% 29.22/29.03  tff(decl_37446, type, exaptation_1: $i > $o).
% 29.22/29.03  tff(decl_37447, type, 'Exaptation': $i).
% 29.22/29.03  tff(decl_37448, type, 'A structure that has evolved for a certain function but is co-opted for a different function.': $i).
% 29.22/29.03  tff(decl_37449, type, exaptation: $i).
% 29.22/29.03  tff(decl_37450, type, 'Excavata': $i).
% 29.22/29.03  tff(decl_37451, type, 'One of five major groups of eukaryotic organisms proposed in a current taxonomic scheme. Most excavates have two or more flagella and a characteristic ventral feeding groove.': $i).
% 29.22/29.03  tff(decl_37452, type, excavata: $i).
% 29.22/29.03  tff(decl_37453, type, 'Exchange': $i).
% 29.22/29.03  tff(decl_37454, type, 'The act of changing one thing for another thing.': $i).
% 29.22/29.03  tff(decl_37455, type, exchange: $i).
% 29.22/29.03  tff(decl_37456, type, excited_nerve_cell_1: $i > $o).
% 29.22/29.03  tff(decl_37457, type, 'Excited-Nerve-Cell': $i).
% 29.22/29.03  tff(decl_37458, type, 'Nerve cells when excited are called excited nerve cell.': $i).
% 29.22/29.03  tff(decl_37459, type, 'excited nerve cell': $i).
% 29.22/29.03  tff(decl_37460, type, 'excited nerve-cell': $i).
% 29.22/29.03  tff(decl_37461, type, 'excited-nerve-cell': $i).
% 29.22/29.03  tff(decl_37462, type, resting_nerve_cell_1: $i > $o).
% 29.22/29.03  tff(decl_37463, type, excreted_fluid_1: $i > $o).
% 29.22/29.03  tff(decl_37464, type, 'Excreted-Fluid': $i).
% 29.22/29.03  tff(decl_37465, type, 'Fluids which are produced and eliminated from an organism as waste.': $i).
% 29.22/29.03  tff(decl_37466, type, 'excreted fluid': $i).
% 29.22/29.03  tff(decl_37467, type, 'excreted-fluid': $i).
% 29.22/29.03  tff(decl_37468, type, 'Excretion': $i).
% 29.22/29.03  tff(decl_37469, type, 'Excretion is the removal of waste products from an organism.': $i).
% 29.22/29.03  tff(decl_37470, type, excrete: $i).
% 29.22/29.03  tff(decl_37471, type, excretion: $i).
% 29.22/29.03  tff(decl_37472, type, fn_excretion_1: $i > $i).
% 29.22/29.03  tff(decl_37473, type, fn_excretion_2: $i > $i).
% 29.22/29.03  tff(decl_37474, type, fn_excretion_4: $i > $i).
% 29.22/29.03  tff(decl_37475, type, excretion_of_nitrogenous_waste_by_animal_1: $i > $o).
% 29.22/29.03  tff(decl_37476, type, 'Excretion-Of-Nitrogenous-Waste-By-Animal': $i).
% 29.22/29.03  tff(decl_37477, type, 'Excretion of nitrogenous wastes is the process by which nitrogenous waste products of metabolism and other non-useful materials are eliminated from an organism in the form of ammonia, urea or other waste products.': $i).
% 29.22/29.03  tff(decl_37478, type, 'excretion of nitrogenous waste by animal': $i).
% 29.22/29.03  tff(decl_37479, type, 'excretion-of-nitrogenous-waste-by-animal': $i).
% 29.22/29.03  tff(decl_37480, type, fn_excretion_of_nitrogenous_waste_by_animal_1: $i > $i).
% 29.22/29.03  tff(decl_37481, type, urea_1: $i > $o).
% 29.22/29.03  tff(decl_37482, type, fn_excretion_of_nitrogenous_waste_by_animal_2: $i > $i).
% 29.22/29.03  tff(decl_37483, type, fn_excretion_of_nitrogenous_waste_by_animal_3: $i > $i).
% 29.22/29.03  tff(decl_37484, type, excretory_organ_1: $i > $o).
% 29.22/29.03  tff(decl_37485, type, 'Excretory-Organ': $i).
% 29.22/29.03  tff(decl_37486, type, 'Organ which is part of the excretory system of animals.': $i).
% 29.22/29.03  tff(decl_37487, type, 'excretory organ': $i).
% 29.22/29.03  tff(decl_37488, type, 'excretory-organ': $i).
% 29.22/29.03  tff(decl_37489, type, excretory_system_1: $i > $o).
% 29.22/29.03  tff(decl_37490, type, 'Excretory-System': $i).
% 29.22/29.03  tff(decl_37491, type, 'A system of organs responsible for the maintaneance of water balance and the removal of nitrogenous waste products of metabolism.': $i).
% 29.22/29.03  tff(decl_37492, type, 'excretory system': $i).
% 29.22/29.03  tff(decl_37493, type, 'excretory-system': $i).
% 29.22/29.03  tff(decl_37494, type, 'Exergonic-Process': $i).
% 29.22/29.03  tff(decl_37495, type, 'A process in which there is a net release of free energy.': $i).
% 29.22/29.03  tff(decl_37496, type, 'spontaneous process': $i).
% 29.22/29.03  tff(decl_37497, type, 'spontaneous-process': $i).
% 29.22/29.03  tff(decl_37498, type, 'undergo exergonic process': $i).
% 29.22/29.03  tff(decl_37499, type, release: $i).
% 29.22/29.03  tff(decl_37500, type, 'exergonic process': $i).
% 29.22/29.03  tff(decl_37501, type, 'exergonic-process': $i).
% 29.22/29.03  tff(decl_37502, type, fn_exergonic_process_2: $i > $i).
% 29.22/29.03  tff(decl_37503, type, endergonic_process_0: $i).
% 29.22/29.03  tff(decl_37504, type, 'Exergonic-Reaction': $i).
% 29.22/29.03  tff(decl_37505, type, 'An exergonic reaction is a chemical reaction where the change in the Gibbs free energy is negative, indicating a spontaneous reaction.': $i).
% 29.22/29.03  tff(decl_37506, type, 'favorable reaction': $i).
% 29.22/29.03  tff(decl_37507, type, 'favorable-reaction': $i).
% 29.22/29.03  tff(decl_37508, type, 'spontaneous reaction': $i).
% 29.22/29.03  tff(decl_37509, type, 'spontaneous-reaction': $i).
% 29.22/29.03  tff(decl_37510, type, 'exergonic reaction': $i).
% 29.22/29.03  tff(decl_37511, type, 'exergonic-reaction': $i).
% 29.22/29.03  tff(decl_37512, type, endergonic_reaction_0: $i).
% 29.22/29.03  tff(decl_37513, type, fn_exergonic_process_1: $i > $i).
% 29.22/29.03  tff(decl_37514, type, 'Exit': $i).
% 29.22/29.03  tff(decl_37515, type, 'go out': $i).
% 29.22/29.03  tff(decl_37516, type, 'get out': $i).
% 29.22/29.03  tff(decl_37517, type, exit: $i).
% 29.22/29.03  tff(decl_37518, type, go_out: $i).
% 29.22/29.03  tff(decl_37519, type, get_out: $i).
% 29.22/29.03  tff(decl_37520, type, leave: $i).
% 29.22/29.03  tff(decl_37521, type, withdraw_1: $i > $o).
% 29.22/29.03  tff(decl_37522, type, exocrine_gland_1: $i > $o).
% 29.22/29.03  tff(decl_37523, type, 'Exocrine-Gland': $i).
% 29.22/29.03  tff(decl_37524, type, 'Glands which have ducts to carry secreted substances onto body surfaces or into body cavities.': $i).
% 29.22/29.03  tff(decl_37525, type, 'exocrine gland': $i).
% 29.22/29.03  tff(decl_37526, type, 'exocrine-gland': $i).
% 29.22/29.03  tff(decl_37527, type, 'Exocytosis': $i).
% 29.22/29.03  tff(decl_37528, type, 'Exocytosis is the durable process by which a cell directs the contents of secretory vesicles out of the cell membrane. These membrane-bound vesicles contain soluble proteins to be secreted to the extracellular environment, as well as membrane proteins and lipids that are sent to become components of the cell membrane.': $i).
% 29.22/29.03  tff(decl_37529, type, 'reverse pino cytosis': $i).
% 29.22/29.03  tff(decl_37530, type, 'reverse-pino-cytosis': $i).
% 29.22/29.03  tff(decl_37531, type, 'perform exocytosis': $i).
% 29.22/29.03  tff(decl_37532, type, exocytosis: $i).
% 29.22/29.03  tff(decl_37533, type, fn_exocytosis_1: $i > $i).
% 29.22/29.03  tff(decl_37534, type, fn_exocytosis_2: $i > $i).
% 29.22/29.03  tff(decl_37535, type, fn_exocytosis_3: $i > $i).
% 29.22/29.03  tff(decl_37536, type, fn_exocytosis_4: $i > $i).
% 29.22/29.03  tff(decl_37537, type, fn_exocytosis_5: $i > $i).
% 29.22/29.03  tff(decl_37538, type, fn_exocytosis_7: $i > $i).
% 29.22/29.03  tff(decl_37539, type, fn_exocytosis_8: $i > $i).
% 29.22/29.03  tff(decl_37540, type, fn_exocytosis_9: $i > $i).
% 29.22/29.03  tff(decl_37541, type, fn_exocytosis_10: $i > $i).
% 29.22/29.03  tff(decl_37542, type, fn_exocytosis_11: $i > $i).
% 29.22/29.03  tff(decl_37543, type, fn_exocytosis_12: $i > $i).
% 29.22/29.03  tff(decl_37544, type, fn_exocytosis_13: $i > $i).
% 29.22/29.03  tff(decl_37545, type, fn_exocytosis_14: $i > $i).
% 29.22/29.03  tff(decl_37546, type, fn_exocytosis_15: $i > $i).
% 29.22/29.03  tff(decl_37547, type, fn_exocytosis_16: $i > $i).
% 29.22/29.03  tff(decl_37548, type, fn_exocytosis_17: $i > $i).
% 29.22/29.03  tff(decl_37549, type, fn_exocytosis_19: $i > $i).
% 29.22/29.03  tff(decl_37550, type, fn_exocytosis_20: $i > $i).
% 29.22/29.03  tff(decl_37551, type, fn_exocytosis_21: $i > $i).
% 29.22/29.03  tff(decl_37552, type, fn_exocytosis_22: $i > $i).
% 29.22/29.03  tff(decl_37553, type, fn_exocytosis_28: $i > $i).
% 29.22/29.03  tff(decl_37554, type, fn_exocytosis_29: $i > $i).
% 29.22/29.03  tff(decl_37555, type, fn_exocytosis_31: $i > $i).
% 29.22/29.03  tff(decl_37556, type, fn_exocytosis_32: $i > $i).
% 29.22/29.03  tff(decl_37557, type, fn_exocytosis_34: $i > $i).
% 29.22/29.03  tff(decl_37558, type, fn_exocytosis_37: $i > $i).
% 29.22/29.03  tff(decl_37559, type, fn_exocytosis_38: $i > $i).
% 29.22/29.03  tff(decl_37560, type, fn_exocytosis_39: $i > $i).
% 29.22/29.03  tff(decl_37561, type, fn_exocytosis_40: $i > $i).
% 29.22/29.03  tff(decl_37562, type, fn_exocytosis_41: $i > $i).
% 29.22/29.03  tff(decl_37563, type, fn_exocytosis_42: $i > $i).
% 29.22/29.03  tff(decl_37564, type, fn_exocytosis_43: $i > $i).
% 29.22/29.03  tff(decl_37565, type, fn_exocytosis_44: $i > $i).
% 29.22/29.03  tff(decl_37566, type, fn_exocytosis_45: $i > $i).
% 29.22/29.03  tff(decl_37567, type, fn_exocytosis_46: $i > $i).
% 29.22/29.03  tff(decl_37568, type, exocytosis_of_polysaccharide_across_plasma_membrane_1: $i > $o).
% 29.22/29.03  tff(decl_37569, type, 'Exocytosis-Of-Polysaccharide-Across-Plasma-Membrane': $i).
% 29.22/29.03  tff(decl_37570, type, 'The cellular secretion of sugar polymer molecules by the fusion of vesicles containing them with the plasma membrane.': $i).
% 29.22/29.03  tff(decl_37571, type, 'exocytosis of polysaccharide across plasma membrane': $i).
% 29.22/29.03  tff(decl_37572, type, 'exocytosis-of-polysaccharide-across-plasma-membrane': $i).
% 29.22/29.03  tff(decl_37573, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_1: $i > $i).
% 29.22/29.03  tff(decl_37574, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_2: $i > $i).
% 29.22/29.03  tff(decl_37575, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_3: $i > $i).
% 29.22/29.03  tff(decl_37576, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_4: $i > $i).
% 29.22/29.03  tff(decl_37577, type, phosphorylation_of_protein_1: $i > $o).
% 29.22/29.03  tff(decl_37578, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_5: $i > $i).
% 29.22/29.03  tff(decl_37579, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_6: $i > $i).
% 29.22/29.03  tff(decl_37580, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_7: $i > $i).
% 29.22/29.03  tff(decl_37581, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_8: $i > $i).
% 29.22/29.03  tff(decl_37582, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_9: $i > $i).
% 29.22/29.03  tff(decl_37583, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_10: $i > $i).
% 29.22/29.03  tff(decl_37584, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_11: $i > $i).
% 29.22/29.03  tff(decl_37585, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_12: $i > $i).
% 29.22/29.03  tff(decl_37586, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_13: $i > $i).
% 29.22/29.03  tff(decl_37587, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_14: $i > $i).
% 29.22/29.03  tff(decl_37588, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_15: $i > $i).
% 29.22/29.03  tff(decl_37589, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_16: $i > $i).
% 29.22/29.03  tff(decl_37590, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_17: $i > $i).
% 29.22/29.03  tff(decl_37591, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_18: $i > $i).
% 29.22/29.03  tff(decl_37592, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_19: $i > $i).
% 29.22/29.03  tff(decl_37593, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_20: $i > $i).
% 29.22/29.03  tff(decl_37594, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_21: $i > $i).
% 29.22/29.03  tff(decl_37595, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_22: $i > $i).
% 29.22/29.03  tff(decl_37596, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_24: $i > $i).
% 29.22/29.03  tff(decl_37597, type, fn_exocytosis_of_polysaccharide_across_plasma_membrane_23: $i > $i).
% 29.22/29.03  tff(decl_37598, type, exoenzyme_1: $i > $o).
% 29.22/29.03  tff(decl_37599, type, 'Exoenzyme': $i).
% 29.22/29.03  tff(decl_37600, type, 'An enzyme secreted outside a cell, and that functions outside the secreting cell.': $i).
% 29.22/29.03  tff(decl_37601, type, exoenzyme: $i).
% 29.22/29.03  tff(decl_37602, type, 'Exon': $i).
% 29.22/29.03  tff(decl_37603, type, '(1) A nucleotide sequence in a primary RNA transcript that remains after RNA processing. (2) The region of DNA from which this sequence was transcribed.': $i).
% 29.22/29.03  tff(decl_37604, type, exon: $i).
% 29.22/29.03  tff(decl_37605, type, fn_exon_1: $i > $i).
% 29.22/29.03  tff(decl_37606, type, 'Exoskeleton': $i).
% 29.22/29.03  tff(decl_37607, type, 'An external skeleton which occurs in certain animals and functions in protection and for attachment of muscles.': $i).
% 29.22/29.03  tff(decl_37608, type, exoskeleton: $i).
% 29.22/29.03  tff(decl_37609, type, fn_exoskeleton_2: $i > $i).
% 29.22/29.03  tff(decl_37610, type, fn_exoskeleton_3: $i > $i).
% 29.22/29.03  tff(decl_37611, type, fn_exoskeleton_5: $i > $i).
% 29.22/29.03  tff(decl_37612, type, exotoxin_1: $i > $o).
% 29.22/29.03  tff(decl_37613, type, 'Exotoxin': $i).
% 29.22/29.03  tff(decl_37614, type, 'A toxic protein secreted by bacteria and other pathogens and damages the host by destroying cells or disrupting cellular metabolism. Examples include the botulinum toxin produced by Clostridium botulinum and the diphtheria toxin produced by Corynebacterium diphtheriae.': $i).
% 29.22/29.03  tff(decl_37615, type, exotoxin: $i).
% 29.22/29.03  tff(decl_37616, type, 'Expand': $i).
% 29.22/29.03  tff(decl_37617, type, expand: $i).
% 29.22/29.03  tff(decl_37618, type, enlarge: $i).
% 29.22/29.03  tff(decl_37619, type, magnify: $i).
% 29.22/29.03  tff(decl_37620, type, fn_expand_4: $i > $i).
% 29.22/29.03  tff(decl_37621, type, fn_expand_5: $i > $i).
% 29.22/29.03  tff(decl_37622, type, fn_expand_3: $i > $i).
% 29.22/29.03  tff(decl_37623, type, fn_expand_2: $i > $i).
% 29.22/29.03  tff(decl_37624, type, expansin_1: $i > $o).
% 29.22/29.03  tff(decl_37625, type, 'Expansin': $i).
% 29.22/29.03  tff(decl_37626, type, 'Expansin is a class of plant enzymes that break hydrogen bonds between plant cell consituents such as cellulose which enable plants cells to grow.': $i).
% 29.22/29.03  tff(decl_37627, type, expansin: $i).
% 29.22/29.03  tff(decl_37628, type, 'Experiment': $i).
% 29.22/29.03  tff(decl_37629, type, 'An act or operation undertaken in order to discover some unknown principle or effect, or to test, establish, or illustrate some suggest or known truth; practical test; proof.': $i).
% 29.22/29.03  tff(decl_37630, type, 'Experimental-Group': $i).
% 29.22/29.03  tff(decl_37631, type, 'In an experiment, the group of test subjects that is subjected to the experimental treatment, as opposed to the control group.': $i).
% 29.22/29.03  tff(decl_37632, type, 'experimental group': $i).
% 29.22/29.03  tff(decl_37633, type, 'experimental-group': $i).
% 29.22/29.03  tff(decl_37634, type, 'Exponential-Population-Growth': $i).
% 29.22/29.03  tff(decl_37635, type, 'A model of population growth in which the population continuously doubles each generation.': $i).
% 29.22/29.03  tff(decl_37636, type, 'exponential population growth': $i).
% 29.22/29.03  tff(decl_37637, type, 'exponential-population-growth': $i).
% 29.22/29.03  tff(decl_37638, type, 'Expose': $i).
% 29.22/29.03  tff(decl_37639, type, expose: $i).
% 29.22/29.03  tff(decl_37640, type, disclose: $i).
% 29.22/29.03  tff(decl_37641, type, display: $i).
% 29.22/29.03  tff(decl_37642, type, exhibit: $i).
% 29.22/29.03  tff(decl_37643, type, 'Express': $i).
% 29.22/29.03  tff(decl_37644, type, show: $i).
% 29.22/29.03  tff(decl_37645, type, evince: $i).
% 29.22/29.03  tff(decl_37646, type, utter: $i).
% 29.22/29.03  tff(decl_37647, type, fn_express_2: $i > $i).
% 29.22/29.03  tff(decl_37648, type, 'Expression-Vector': $i).
% 29.22/29.03  tff(decl_37649, type, 'A plasmid genetically engineered to contain the promotor sequences upstream of the sequence (gene) of interest, allowing the gene to be expessed when the plasmid is inserted into a host cell.': $i).
% 29.22/29.03  tff(decl_37650, type, 'vector of expression': $i).
% 29.22/29.03  tff(decl_37651, type, 'expression vector': $i).
% 29.22/29.03  tff(decl_37652, type, 'expression-vector': $i).
% 29.22/29.03  tff(decl_37653, type, fn_expression_vector_1: $i > $i).
% 29.22/29.03  tff(decl_37654, type, fn_expression_vector_2: $i > $i).
% 29.22/29.03  tff(decl_37655, type, fn_expression_vector_3: $i > $i).
% 29.22/29.03  tff(decl_37656, type, fn_expression_vector_4: $i > $i).
% 29.22/29.03  tff(decl_37657, type, fn_expression_vector_5: $i > $i).
% 29.22/29.03  tff(decl_37658, type, fn_expression_vector_6: $i > $i).
% 29.22/29.03  tff(decl_37659, type, fn_expression_vector_7: $i > $i).
% 29.22/29.03  tff(decl_37660, type, fn_expression_vector_8: $i > $i).
% 29.22/29.03  tff(decl_37661, type, fn_expression_vector_9: $i > $i).
% 29.22/29.03  tff(decl_37662, type, fn_expression_vector_10: $i > $i).
% 29.22/29.03  tff(decl_37663, type, fn_expression_vector_11: $i > $i).
% 29.22/29.03  tff(decl_37664, type, fn_expression_vector_12: $i > $i).
% 29.22/29.03  tff(decl_37665, type, extension_of_replication_bubble_1: $i > $o).
% 29.22/29.03  tff(decl_37666, type, 'Extension-of-Replication-Bubble': $i).
% 29.22/29.03  tff(decl_37667, type, 'The elongation of the open section of the chromosome between the replication forks that is open for DNA replication.': $i).
% 29.22/29.03  tff(decl_37668, type, extend: $i).
% 29.22/29.03  tff(decl_37669, type, 'extension of replication bubble': $i).
% 29.22/29.03  tff(decl_37670, type, 'extension-of-replication-bubble': $i).
% 29.22/29.03  tff(decl_37671, type, fn_extension_of_replication_bubble_1: $i > $i).
% 29.22/29.03  tff(decl_37672, type, fn_extension_of_replication_bubble_2: $i > $i).
% 29.22/29.03  tff(decl_37673, type, fn_replication_fork_1: $i > $i).
% 29.22/29.03  tff(decl_37674, type, extensive_work_by_human_1: $i > $o).
% 29.22/29.03  tff(decl_37675, type, fn_extensive_work_by_human_2: $i > $i).
% 29.22/29.03  tff(decl_37676, type, 'Extensive-Work-By-Human': $i).
% 29.22/29.03  tff(decl_37677, type, 'Work done by a person that requires a major physical effort, such as running or climbing.': $i).
% 29.22/29.03  tff(decl_37678, type, 'human working hard': $i).
% 29.22/29.03  tff(decl_37679, type, 'human-working-hard': $i).
% 29.22/29.03  tff(decl_37680, type, 'human exercising hard': $i).
% 29.22/29.03  tff(decl_37681, type, 'human-exercising-hard': $i).
% 29.22/29.03  tff(decl_37682, type, 'perform extensive work': $i).
% 29.22/29.03  tff(decl_37683, type, 'extensive work by human': $i).
% 29.22/29.03  tff(decl_37684, type, 'extensive-work-by-human': $i).
% 29.22/29.03  tff(decl_37685, type, fn_extensive_work_by_human_3: $i > $i).
% 29.22/29.03  tff(decl_37686, type, external_fertilization_1: $i > $o).
% 29.22/29.03  tff(decl_37687, type, 'External-Fertilization': $i).
% 29.22/29.03  tff(decl_37688, type, 'Fertilization that takes place between gametes that have been discharged into the environment.': $i).
% 29.22/29.03  tff(decl_37689, type, 'fertilization of external': $i).
% 29.22/29.03  tff(decl_37690, type, 'external fertilization': $i).
% 29.22/29.03  tff(decl_37691, type, 'external-fertilization': $i).
% 29.22/29.03  tff(decl_37692, type, 'Exteroceptor': $i).
% 29.22/29.03  tff(decl_37693, type, 'A class of sensory receptors that detect stimuli outside the body such as heat, light, pressure, and chemicals.': $i).
% 29.22/29.03  tff(decl_37694, type, exteroceptor: $i).
% 29.22/29.03  tff(decl_37695, type, extinct_bird_1: $i > $o).
% 29.22/29.03  tff(decl_37696, type, 'Extinct-Bird': $i).
% 29.22/29.03  tff(decl_37697, type, 'A group of birds which existed in the past but has no currently living members.': $i).
% 29.22/29.03  tff(decl_37698, type, 'extinct bird': $i).
% 29.22/29.03  tff(decl_37699, type, 'extinct-bird': $i).
% 29.22/29.03  tff(decl_37700, type, extinct_hominid_1: $i > $o).
% 29.22/29.03  tff(decl_37701, type, 'Extinct-Hominid': $i).
% 29.22/29.03  tff(decl_37702, type, 'A group of hominids which existed in the past but has no currently living members.': $i).
% 29.22/29.03  tff(decl_37703, type, 'extinct hominid': $i).
% 29.22/29.03  tff(decl_37704, type, 'extinct-hominid': $i).
% 29.22/29.03  tff(decl_37705, type, 'Extinct-Invertebrate': $i).
% 29.22/29.03  tff(decl_37706, type, 'A group of invertebrates which existed in the past but has no currently living members.': $i).
% 29.22/29.03  tff(decl_37707, type, 'extinct invertebrate': $i).
% 29.22/29.03  tff(decl_37708, type, 'extinct-invertebrate': $i).
% 29.22/29.03  tff(decl_37709, type, extinct_species_1: $i > $o).
% 29.22/29.03  tff(decl_37710, type, 'Extinct-Plant': $i).
% 29.22/29.03  tff(decl_37711, type, 'A group of plants which existed in the past but has no currently living members.': $i).
% 29.22/29.03  tff(decl_37712, type, 'extinct plant': $i).
% 29.22/29.03  tff(decl_37713, type, 'extinct-plant': $i).
% 29.22/29.03  tff(decl_37714, type, 'Extinct-Species': $i).
% 29.22/29.03  tff(decl_37715, type, 'A group of organisms which existed in the past but has no currently living members.': $i).
% 29.22/29.03  tff(decl_37716, type, 'extinct species': $i).
% 29.22/29.03  tff(decl_37717, type, 'extinct-specy': $i).
% 29.22/29.03  tff(decl_37718, type, 'Extinct-Vertebrate': $i).
% 29.22/29.03  tff(decl_37719, type, 'A group of vertebrates which existed in the past but has no currently living members.': $i).
% 29.22/29.03  tff(decl_37720, type, 'extinct vertebrate': $i).
% 29.22/29.03  tff(decl_37721, type, 'extinct-vertebrate': $i).
% 29.22/29.03  tff(decl_37722, type, extinction_1: $i > $o).
% 29.22/29.03  tff(decl_37723, type, 'Extinction': $i).
% 29.22/29.03  tff(decl_37724, type, 'The end of a lineage of organisms.': $i).
% 29.22/29.03  tff(decl_37725, type, extinguish: $i).
% 29.22/29.03  tff(decl_37726, type, extinction: $i).
% 29.22/29.03  tff(decl_37727, type, 'Extinction-Vortex': $i).
% 29.22/29.03  tff(decl_37728, type, 'A downward population trend in which the effects of small population size (e.g., inbreeding and genetic drift) combine to cause an already-small population to shrink further.  Unless the spiral is reversed, the population will go extinct.': $i).
% 29.22/29.03  tff(decl_37729, type, 'vortex of extinction': $i).
% 29.22/29.03  tff(decl_37730, type, 'extinction vortex': $i).
% 29.22/29.03  tff(decl_37731, type, 'extinction-vortex': $i).
% 29.22/29.03  tff(decl_37732, type, 'Extra-Cellular-Fluid': $i).
% 29.22/29.03  tff(decl_37733, type, 'Extracellular fluid (ECF) usually denotes all body fluid outside of cells.': $i).
% 29.22/29.03  tff(decl_37734, type, 'extracellular fluid': $i).
% 29.22/29.03  tff(decl_37735, type, 'extra cellular fluid': $i).
% 29.22/29.03  tff(decl_37736, type, 'extra-cellular-fluid': $i).
% 29.22/29.03  tff(decl_37737, type, fn_extra_cellular_fluid_1: $i > $i).
% 29.22/29.03  tff(decl_37738, type, fn_extra_cellular_fluid_2: $i > $i).
% 29.22/29.03  tff(decl_37739, type, fn_extra_cellular_fluid_3: $i > $i).
% 29.22/29.03  tff(decl_37740, type, fn_extra_cellular_fluid_4: $i > $i).
% 29.22/29.03  tff(decl_37741, type, 'Extra-Cellular-Matrix': $i).
% 29.22/29.03  tff(decl_37742, type, 'The extracellular matrix (ECM) is the extracellular part of animal tissue that usually provides structural support to the animal cells in addition to performing various other important functions. The extracellular matrix is the defining feature of connective tissue in animals.': $i).
% 29.22/29.03  tff(decl_37743, type, 'extracellular matrix': $i).
% 29.22/29.03  tff(decl_37744, type, 'extracellular-matrix': $i).
% 29.22/29.03  tff(decl_37745, type, ecm: $i).
% 29.22/29.03  tff(decl_37746, type, 'extra cellular matrix': $i).
% 29.22/29.03  tff(decl_37747, type, 'extra-cellular-matrix': $i).
% 29.22/29.03  tff(decl_37748, type, fn_extra_cellular_matrix_1: $i > $i).
% 29.22/29.03  tff(decl_37749, type, fn_extra_cellular_matrix_2: $i > $i).
% 29.22/29.03  tff(decl_37750, type, fn_extra_cellular_matrix_3: $i > $i).
% 29.22/29.03  tff(decl_37751, type, fn_extra_cellular_matrix_5: $i > $i).
% 29.22/29.03  tff(decl_37752, type, fn_extra_cellular_matrix_9: $i > $i).
% 29.22/29.03  tff(decl_37753, type, fn_extra_cellular_matrix_10: $i > $i).
% 29.22/29.03  tff(decl_37754, type, fn_extra_cellular_matrix_11: $i > $i).
% 29.22/29.03  tff(decl_37755, type, fn_extra_cellular_matrix_12: $i > $i).
% 29.22/29.03  tff(decl_37756, type, fn_extra_cellular_matrix_13: $i > $i).
% 29.22/29.03  tff(decl_37757, type, fn_extra_cellular_matrix_14: $i > $i).
% 29.22/29.03  tff(decl_37758, type, fn_extra_cellular_matrix_15: $i > $i).
% 29.22/29.03  tff(decl_37759, type, fn_extra_cellular_matrix_16: $i > $i).
% 29.22/29.03  tff(decl_37760, type, fn_extra_cellular_matrix_17: $i > $i).
% 29.22/29.03  tff(decl_37761, type, fn_extra_cellular_matrix_18: $i > $i).
% 29.22/29.03  tff(decl_37762, type, fn_extra_cellular_matrix_19: $i > $i).
% 29.22/29.03  tff(decl_37763, type, fn_extra_cellular_matrix_20: $i > $i).
% 29.22/29.03  tff(decl_37764, type, fn_extra_cellular_matrix_21: $i > $i).
% 29.22/29.03  tff(decl_37765, type, fn_extra_cellular_matrix_22: $i > $i).
% 29.22/29.03  tff(decl_37766, type, fn_integrin_36: $i > $i).
% 29.22/29.03  tff(decl_37767, type, fn_integrin_5: $i > $i).
% 29.22/29.03  tff(decl_37768, type, fn_integrin_39: $i > $i).
% 29.22/29.03  tff(decl_37769, type, fn_integrin_10: $i > $i).
% 29.22/29.03  tff(decl_37770, type, 'Concentration_Ca2PlusAnimalCell': $i).
% 29.22/29.03  tff(decl_37771, type, 'Concentration_Ca2PlusExtraCellularMatrix': $i).
% 29.22/29.03  tff(decl_37772, type, 'Extracellular-Digestion': $i).
% 29.22/29.03  tff(decl_37773, type, 'Digestion of food in which enzymes are secreted from cells onto the food, which is thus broken down outside the cells. Such digestion occurs within the lumen of a digestive tract organ that is continuous with the outside of the animal\\s body.': $i).
% 29.22/29.03  tff(decl_37774, type, 'extracellular digestion': $i).
% 29.22/29.03  tff(decl_37775, type, 'extracellular-digestion': $i).
% 29.22/29.03  tff(decl_37776, type, fn_extracellular_digestion_1: $i > $i).
% 29.22/29.03  tff(decl_37777, type, 'Extracellular-Side': $i).
% 29.22/29.03  tff(decl_37778, type, 'Region on the outside of a cell.': $i).
% 29.22/29.03  tff(decl_37779, type, 'extracellular side': $i).
% 29.22/29.03  tff(decl_37780, type, 'extracellular-side': $i).
% 29.22/29.03  tff(decl_37781, type, 'Extraembryonic-Membrane': $i).
% 29.22/29.03  tff(decl_37782, type, 'One of the four membranes--yolk sac, amnion, chorion, and allantois--located external to the embryo and which support the embryo as it develops. Found in reptiles (including birds) and mammals.': $i).
% 29.22/29.03  tff(decl_37783, type, 'extraembryonic membrane': $i).
% 29.22/29.03  tff(decl_37784, type, 'extraembryonic-membrane': $i).
% 29.22/29.03  tff(decl_37785, type, 'Extranuclear-Gene': $i).
% 29.22/29.03  tff(decl_37786, type, 'Eukaryotic genes that are located in mitochondria or plant plastids that do not display Mendelian inheritance.': $i).
% 29.22/29.03  tff(decl_37787, type, 'cytoplasmic gene': $i).
% 29.22/29.03  tff(decl_37788, type, 'cytoplasmic-gene': $i).
% 29.22/29.03  tff(decl_37789, type, 'extranuclear gene': $i).
% 29.22/29.03  tff(decl_37790, type, 'extranuclear-gene': $i).
% 29.22/29.03  tff(decl_37791, type, fn_extranuclear_gene_1: $i > $i).
% 29.22/29.03  tff(decl_37792, type, fn_extranuclear_gene_3: $i > $i).
% 29.22/29.03  tff(decl_37793, type, fn_extranuclear_gene_4: $i > $i).
% 29.22/29.03  tff(decl_37794, type, fn_extranuclear_gene_2: $i > $i).
% 29.22/29.03  tff(decl_37795, type, extreme_halophile_1: $i > $o).
% 29.22/29.03  tff(decl_37796, type, 'Extreme-Halophile': $i).
% 29.22/29.03  tff(decl_37797, type, 'An organism that survives and thrives in a highly saline environment such as the Dead Sea or the Great Salt Lake.': $i).
% 29.22/29.03  tff(decl_37798, type, 'halophile of extreme': $i).
% 29.22/29.03  tff(decl_37799, type, 'extreme halophile': $i).
% 29.22/29.03  tff(decl_37800, type, 'extreme-halophile': $i).
% 29.22/29.03  tff(decl_37801, type, extremophile_1: $i > $o).
% 29.22/29.03  tff(decl_37802, type, extreme_thermophile_1: $i > $o).
% 29.22/29.03  tff(decl_37803, type, 'Extreme-Thermophile': $i).
% 29.22/29.03  tff(decl_37804, type, 'An organism that thrives in hot environments (often 60-80 deg C or hotter).': $i).
% 29.22/29.03  tff(decl_37805, type, 'Extremophile': $i).
% 29.22/29.03  tff(decl_37806, type, 'An organism that lives in an environment whose conditions are so extreme that few other species can survive there. Extremophiles include extreme halophiles and extreme thermophiles.': $i).
% 29.22/29.03  tff(decl_37807, type, fn_extremophile_1: $i > $i).
% 29.22/29.03  tff(decl_37808, type, 'Eye': $i).
% 29.22/29.03  tff(decl_37809, type, 'An eye is a light-detecting organ present in many animals which operates to help produce the sense of vision.': $i).
% 29.22/29.03  tff(decl_37810, type, eye: $i).
% 29.22/29.03  tff(decl_37811, type, 'Eye-Cup': $i).
% 29.22/29.03  tff(decl_37812, type, 'A simple eye used to detect light and dark, found in planarians and some other invertebrates.': $i).
% 29.22/29.03  tff(decl_37813, type, 'cup of eye': $i).
% 29.22/29.03  tff(decl_37814, type, 'eye cup': $i).
% 29.22/29.03  tff(decl_37815, type, 'eye-cup': $i).
% 29.22/29.03  tff(decl_37816, type, f_plus_cell_1: $i > $o).
% 29.22/29.03  tff(decl_37817, type, 'F+Cell': $i).
% 29.22/29.03  tff(decl_37818, type, 'F+ bacteria possess F factor as a plasmid independent of the bacterial genome. The F plasmid contains only F factor DNA and no DNA from the bacterial genome.': $i).
% 29.22/29.03  tff(decl_37819, type, 'f+ donor': $i).
% 29.22/29.03  tff(decl_37820, type, 'f donor': $i).
% 29.22/29.03  tff(decl_37821, type, 'hfr donor': $i).
% 29.22/29.03  tff(decl_37822, type, hfr: $i).
% 29.22/29.03  tff(decl_37823, type, 'f factor cell': $i).
% 29.22/29.03  tff(decl_37824, type, 'f-factor-cell': $i).
% 29.22/29.03  tff(decl_37825, type, 'f+cell': $i).
% 29.22/29.03  tff(decl_37826, type, fn_f_plus_cell_1: $i > $i).
% 29.22/29.03  tff(decl_37827, type, f_plasmid_1: $i > $o).
% 29.22/29.03  tff(decl_37828, type, fn_f_plus_cell_2: $i > $i).
% 29.22/29.03  tff(decl_37829, type, fn_f_plus_cell_3: $i > $i).
% 29.22/29.03  tff(decl_37830, type, fn_f_plus_cell_4: $i > $i).
% 29.22/29.03  tff(decl_37831, type, fn_f_plus_cell_5: $i > $i).
% 29.22/29.03  tff(decl_37832, type, fn_f_plus_cell_6: $i > $i).
% 29.22/29.03  tff(decl_37833, type, fn_f_plus_cell_7: $i > $i).
% 29.22/29.03  tff(decl_37834, type, f_cell_1: $i > $o).
% 29.22/29.03  tff(decl_37835, type, 'F-Cell': $i).
% 29.22/29.03  tff(decl_37836, type, 'Cells that lack F plasmids are called F-negative or F-minus (F-) and as such can function as recipient cells.': $i).
% 29.22/29.03  tff(decl_37837, type, 'cell missing f plasmid': $i).
% 29.22/29.03  tff(decl_37838, type, 'f minus cell': $i).
% 29.22/29.03  tff(decl_37839, type, 'f-minus-cell': $i).
% 29.22/29.03  tff(decl_37840, type, 'cell of f': $i).
% 29.22/29.03  tff(decl_37841, type, 'f cell': $i).
% 29.22/29.03  tff(decl_37842, type, 'f-cell': $i).
% 29.22/29.03  tff(decl_37843, type, fn_f_cell_1: $i > $i).
% 29.22/29.03  tff(decl_37844, type, fn_f_cell_2: $i > $i).
% 29.22/29.03  tff(decl_37845, type, fn_f_cell_3: $i > $i).
% 29.22/29.03  tff(decl_37846, type, f_factor_1: $i > $o).
% 29.22/29.03  tff(decl_37847, type, 'F-Factor': $i).
% 29.22/29.03  tff(decl_37848, type, 'The F factor is a segment of DNA in bacteria which codes for the ability to form pili for bacterial conjugation. The f factor may exist as part of a separate plasmid or be contained within the bacterial chromosome.': $i).
% 29.22/29.03  tff(decl_37849, type, 'factor of f': $i).
% 29.22/29.03  tff(decl_37850, type, 'f factor': $i).
% 29.22/29.03  tff(decl_37851, type, 'f-factor': $i).
% 29.22/29.03  tff(decl_37852, type, prokaryote_dna_sequence_1: $i > $o).
% 29.22/29.03  tff(decl_37853, type, fn_f_factor_1: $i > $i).
% 29.22/29.03  tff(decl_37854, type, fn_f_factor_2: $i > $i).
% 29.22/29.03  tff(decl_37855, type, fn_f_factor_3: $i > $i).
% 29.22/29.03  tff(decl_37856, type, fn_f_factor_4: $i > $i).
% 29.22/29.03  tff(decl_37857, type, fn_f_factor_7: $i > $i).
% 29.22/29.03  tff(decl_37858, type, fn_f_factor_8: $i > $i).
% 29.22/29.03  tff(decl_37859, type, fn_f_factor_9: $i > $i).
% 29.22/29.03  tff(decl_37860, type, fn_f_factor_10: $i > $i).
% 29.22/29.03  tff(decl_37861, type, fn_f_factor_11: $i > $i).
% 29.22/29.03  tff(decl_37862, type, fn_f_factor_12: $i > $i).
% 29.22/29.03  tff(decl_37863, type, fn_f_factor_13: $i > $i).
% 29.22/29.03  tff(decl_37864, type, fn_f_factor_14: $i > $i).
% 29.22/29.03  tff(decl_37865, type, fn_f_factor_15: $i > $i).
% 29.22/29.03  tff(decl_37866, type, 'F-Plasmid': $i).
% 29.22/29.03  tff(decl_37867, type, 'The plasmid form of the F factor.': $i).
% 29.22/29.03  tff(decl_37868, type, 'plasmid of f': $i).
% 29.22/29.03  tff(decl_37869, type, 'f plasmid': $i).
% 29.22/29.03  tff(decl_37870, type, 'f-plasmid': $i).
% 29.22/29.03  tff(decl_37871, type, r_plasmid_1: $i > $o).
% 29.22/29.03  tff(decl_37872, type, ti_plasmid_1: $i > $o).
% 29.22/29.03  tff(decl_37873, type, fn_f_plasmid_1: $i > $i).
% 29.22/29.03  tff(decl_37874, type, fn_f_plasmid_2: $i > $i).
% 29.22/29.03  tff(decl_37875, type, fn_f_plasmid_3: $i > $i).
% 29.22/29.03  tff(decl_37876, type, fn_f_plasmid_4: $i > $i).
% 29.22/29.03  tff(decl_37877, type, fn_f_plasmid_5: $i > $i).
% 29.22/29.03  tff(decl_37878, type, fn_f_plasmid_8: $i > $i).
% 29.22/29.03  tff(decl_37879, type, fn_f_plasmid_9: $i > $i).
% 29.22/29.03  tff(decl_37880, type, fn_f_plasmid_10: $i > $i).
% 29.22/29.03  tff(decl_37881, type, fn_f_plasmid_11: $i > $i).
% 29.22/29.03  tff(decl_37882, type, fn_f_plasmid_12: $i > $i).
% 29.22/29.03  tff(decl_37883, type, random_recombination_1: $i > $o).
% 29.22/29.03  tff(decl_37884, type, fn_f_plasmid_13: $i > $i).
% 29.22/29.03  tff(decl_37885, type, fn_f_plasmid_14: $i > $i).
% 29.22/29.03  tff(decl_37886, type, fn_f_plasmid_15: $i > $i).
% 29.22/29.03  tff(decl_37887, type, fn_f_plasmid_16: $i > $i).
% 29.22/29.03  tff(decl_37888, type, fn_f_plasmid_17: $i > $i).
% 29.22/29.03  tff(decl_37889, type, fn_f_plasmid_18: $i > $i).
% 29.22/29.03  tff(decl_37890, type, fn_f_plasmid_19: $i > $i).
% 29.22/29.03  tff(decl_37891, type, fn_f_plasmid_20: $i > $i).
% 29.22/29.03  tff(decl_37892, type, "25": $i).
% 29.22/29.03  tff(decl_37893, type, f1_generation_1: $i > $o).
% 29.22/29.03  tff(decl_37894, type, 'F1-Generation': $i).
% 29.22/29.03  tff(decl_37895, type, 'The first filial, or hybrid, offspring in a series of genetic crosses.': $i).
% 29.22/29.03  tff(decl_37896, type, 'f1 generation': $i).
% 29.22/29.03  tff(decl_37897, type, 'f1-generation': $i).
% 29.22/29.03  tff(decl_37898, type, generation_1: $i > $o).
% 29.22/29.03  tff(decl_37899, type, p_generation_1: $i > $o).
% 29.22/29.03  tff(decl_37900, type, fn_f1_generation_1: $i > $i).
% 29.22/29.03  tff(decl_37901, type, self_pollination_1: $i > $o).
% 29.22/29.03  tff(decl_37902, type, fn_f1_generation_2: $i > $i).
% 29.22/29.03  tff(decl_37903, type, fn_f1_generation_3: $i > $i).
% 29.22/29.03  tff(decl_37904, type, f2_generation_1: $i > $o).
% 29.22/29.03  tff(decl_37905, type, fn_f1_generation_4: $i > $i).
% 29.22/29.03  tff(decl_37906, type, fn_f2_generation_1: $i > $i).
% 29.22/29.03  tff(decl_37907, type, fn_f2_generation_2: $i > $i).
% 29.22/29.03  tff(decl_37908, type, fn_generation_6: $i > $i).
% 29.22/29.03  tff(decl_37909, type, fn_generation_5: $i > $i).
% 29.22/29.03  tff(decl_37910, type, 'F2-Generation': $i).
% 29.22/29.03  tff(decl_37911, type, 'Offspring resulting from interbreeding of the hybrid F1 generation.': $i).
% 29.22/29.03  tff(decl_37912, type, 'f2 generation': $i).
% 29.22/29.03  tff(decl_37913, type, 'f2-generation': $i).
% 29.22/29.03  tff(decl_37914, type, fn_f2_generation_3: $i > $i).
% 29.22/29.03  tff(decl_37915, type, 'Face-Region': $i).
% 29.22/29.03  tff(decl_37916, type, 'Refers to any of the surfaces of a molecule, organ or other object.': $i).
% 29.22/29.03  tff(decl_37917, type, 'region of face': $i).
% 29.22/29.03  tff(decl_37918, type, 'face region': $i).
% 29.22/29.03  tff(decl_37919, type, 'face-region': $i).
% 29.22/29.03  tff(decl_37920, type, 'Facilitated-Diffusion': $i).
% 29.22/29.03  tff(decl_37921, type, 'Facilitated diffusion (also known as facilitated transport or passive-mediated transport) is a process of passive transport, facilitated by integral proteins. Facilitated diffusion is the spontaneous passage of molecules or ions across a biological membrane passing through specific transmembrane integral proteins. The facilitated diffusion may occur either across biological membranes or through aqueous compartments of an organism.': $i).
% 29.22/29.03  tff(decl_37922, type, 'facilitated diffusion': $i).
% 29.22/29.03  tff(decl_37923, type, 'facilitated-diffusion': $i).
% 29.22/29.03  tff(decl_37924, type, fn_facilitated_diffusion_7: $i > $i).
% 29.22/29.03  tff(decl_37925, type, fn_facilitated_diffusion_8: $i > $i).
% 29.22/29.03  tff(decl_37926, type, fn_facilitated_diffusion_9: $i > $i).
% 29.22/29.03  tff(decl_37927, type, fn_facilitated_diffusion_10: $i > $i).
% 29.22/29.03  tff(decl_37928, type, fn_facilitated_diffusion_11: $i > $i).
% 29.22/29.03  tff(decl_37929, type, fn_facilitated_diffusion_12: $i > $i).
% 29.22/29.03  tff(decl_37930, type, fn_facilitated_diffusion_18: $i > $i).
% 29.22/29.03  tff(decl_37931, type, fn_facilitated_diffusion_19: $i > $i).
% 29.22/29.03  tff(decl_37932, type, fn_facilitated_diffusion_20: $i > $i).
% 29.22/29.03  tff(decl_37933, type, fn_integral_protein_35: $i > $i).
% 29.22/29.03  tff(decl_37934, type, fn_integral_protein_36: $i > $i).
% 29.22/29.03  tff(decl_37935, type, fn_integral_protein_37: $i > $i).
% 29.22/29.03  tff(decl_37936, type, fn_facilitated_diffusion_4: $i > $i).
% 29.22/29.03  tff(decl_37937, type, fn_facilitated_diffusion_1: $i > $i).
% 29.22/29.03  tff(decl_37938, type, fn_facilitated_diffusion_2: $i > $i).
% 29.22/29.03  tff(decl_37939, type, fn_facilitated_diffusion_3: $i > $i).
% 29.22/29.03  tff(decl_37940, type, facilitated_diffusion_of_hydrated_ions_1: $i > $o).
% 29.22/29.03  tff(decl_37941, type, 'Facilitated-Diffusion-Of-Hydrated-Ions': $i).
% 29.22/29.03  tff(decl_37942, type, 'The process of moving of a hydrated ions across a biomembrane.': $i).
% 29.22/29.03  tff(decl_37943, type, 'facilitated diffusion of hydrated ion': $i).
% 29.22/29.03  tff(decl_37944, type, 'facilitated-diffusion-of-hydrated-ion': $i).
% 29.22/29.03  tff(decl_37945, type, fn_facilitated_diffusion_of_hydrated_ions_1: $i > $i).
% 29.22/29.03  tff(decl_37946, type, fn_facilitated_diffusion_of_hydrated_ions_3: $i > $i).
% 29.22/29.03  tff(decl_37947, type, fn_facilitated_diffusion_of_hydrated_ions_4: $i > $i).
% 29.22/29.03  tff(decl_37948, type, fn_facilitated_diffusion_of_hydrated_ions_5: $i > $i).
% 29.22/29.03  tff(decl_37949, type, fn_facilitated_diffusion_of_hydrated_ions_6: $i > $i).
% 29.22/29.03  tff(decl_37950, type, fn_facilitated_diffusion_of_hydrated_ions_7: $i > $i).
% 29.22/29.03  tff(decl_37951, type, fn_facilitated_diffusion_of_hydrated_ions_8: $i > $i).
% 29.22/29.03  tff(decl_37952, type, fn_facilitated_diffusion_of_hydrated_ions_9: $i > $i).
% 29.22/29.03  tff(decl_37953, type, fn_facilitated_diffusion_of_hydrated_ions_10: $i > $i).
% 29.22/29.03  tff(decl_37954, type, fn_facilitated_diffusion_of_hydrated_ions_11: $i > $i).
% 29.22/29.03  tff(decl_37955, type, fn_facilitated_diffusion_of_hydrated_ions_12: $i > $i).
% 29.22/29.03  tff(decl_37956, type, fn_facilitated_diffusion_of_hydrated_ions_13: $i > $i).
% 29.22/29.03  tff(decl_37957, type, fn_facilitated_diffusion_of_hydrated_ions_14: $i > $i).
% 29.22/29.03  tff(decl_37958, type, fn_facilitated_diffusion_of_hydrated_ions_15: $i > $i).
% 29.22/29.03  tff(decl_37959, type, fn_facilitated_diffusion_of_hydrated_ions_16: $i > $i).
% 29.22/29.03  tff(decl_37960, type, fn_facilitated_diffusion_of_hydrated_ions_17: $i > $i).
% 29.22/29.03  tff(decl_37961, type, fn_facilitated_diffusion_of_hydrated_ions_19: $i > $i).
% 29.22/29.03  tff(decl_37962, type, fn_facilitated_diffusion_of_hydrated_ions_20: $i > $i).
% 29.22/29.03  tff(decl_37963, type, fn_facilitated_diffusion_of_hydrated_ions_21: $i > $i).
% 29.22/29.03  tff(decl_37964, type, fn_facilitated_diffusion_of_hydrated_ions_22: $i > $i).
% 29.22/29.03  tff(decl_37965, type, fn_facilitated_diffusion_of_hydrated_ions_23: $i > $i).
% 29.22/29.03  tff(decl_37966, type, fn_facilitated_diffusion_of_hydrated_ions_24: $i > $i).
% 29.22/29.03  tff(decl_37967, type, fn_facilitated_diffusion_of_hydrated_ions_25: $i > $i).
% 29.22/29.03  tff(decl_37968, type, fn_facilitated_diffusion_of_hydrated_ions_26: $i > $i).
% 29.22/29.03  tff(decl_37969, type, fn_facilitated_diffusion_of_hydrated_ions_27: $i > $i).
% 29.22/29.03  tff(decl_37970, type, fn_facilitated_diffusion_of_hydrated_ions_28: $i > $i).
% 29.22/29.03  tff(decl_37971, type, fn_facilitated_diffusion_of_hydrated_ions_29: $i > $i).
% 29.22/29.03  tff(decl_37972, type, fn_facilitated_diffusion_of_hydrated_ions_30: $i > $i).
% 29.22/29.03  tff(decl_37973, type, fn_facilitated_diffusion_of_hydrated_ions_31: $i > $i).
% 29.22/29.03  tff(decl_37974, type, fn_facilitated_diffusion_of_hydrated_ions_32: $i > $i).
% 29.22/29.03  tff(decl_37975, type, fn_facilitated_diffusion_of_hydrated_ions_33: $i > $i).
% 29.22/29.03  tff(decl_37976, type, fn_facilitated_diffusion_of_hydrated_ions_34: $i > $i).
% 29.22/29.03  tff(decl_37977, type, fn_facilitated_diffusion_of_hydrated_ions_35: $i > $i).
% 29.22/29.03  tff(decl_37978, type, fn_facilitated_diffusion_of_hydrated_ions_36: $i > $i).
% 29.22/29.03  tff(decl_37979, type, fn_facilitated_diffusion_of_hydrated_ions_41: $i > $i).
% 29.22/29.03  tff(decl_37980, type, hydrated_ion_1: $i > $o).
% 29.22/29.03  tff(decl_37981, type, fn_facilitated_diffusion_of_hydrated_ions_40: $i > $i).
% 29.22/29.03  tff(decl_37982, type, fn_facilitated_diffusion_of_hydrated_ions_2: $i > $i).
% 29.22/29.03  tff(decl_37983, type, fn_facilitated_diffusion_of_hydrated_ions_18: $i > $i).
% 29.22/29.03  tff(decl_37984, type, fn_facilitated_diffusion_of_hydrated_ions_39: $i > $i).
% 29.22/29.03  tff(decl_37985, type, fn_facilitated_diffusion_of_hydrated_ions_38: $i > $i).
% 29.22/29.03  tff(decl_37986, type, fn_facilitated_diffusion_of_hydrated_ions_37: $i > $i).
% 29.22/29.03  tff(decl_37987, type, 'Facilitated-Diffusion-Of-Ion': $i).
% 29.22/29.03  tff(decl_37988, type, 'The membrane potential acts like a battery, an energy source that affects the traffic of all charged substances across the membrane.': $i).
% 29.22/29.03  tff(decl_37989, type, 'facilitated diffusion of ion': $i).
% 29.22/29.03  tff(decl_37990, type, 'facilitated-diffusion-of-ion': $i).
% 29.22/29.03  tff(decl_37991, type, passive_transport_of_solute_1: $i > $o).
% 29.22/29.03  tff(decl_37992, type, fn_facilitated_diffusion_of_ion_11: $i > $i).
% 29.22/29.03  tff(decl_37993, type, fn_facilitated_diffusion_of_ion_16: $i > $i).
% 29.22/29.03  tff(decl_37994, type, fn_facilitated_diffusion_of_ion_17: $i > $i).
% 29.22/29.03  tff(decl_37995, type, fn_facilitated_diffusion_of_ion_18: $i > $i).
% 29.22/29.03  tff(decl_37996, type, fn_facilitated_diffusion_of_ion_19: $i > $i).
% 29.22/29.03  tff(decl_37997, type, fn_facilitated_diffusion_of_ion_20: $i > $i).
% 29.22/29.03  tff(decl_37998, type, fn_facilitated_diffusion_of_ion_21: $i > $i).
% 29.22/29.03  tff(decl_37999, type, fn_facilitated_diffusion_of_ion_22: $i > $i).
% 29.22/29.03  tff(decl_38000, type, fn_facilitated_diffusion_of_ion_24: $i > $i).
% 29.22/29.03  tff(decl_38001, type, fn_facilitated_diffusion_of_ion_30: $i > $i).
% 29.22/29.03  tff(decl_38002, type, fn_passive_transport_of_solute_1: $i > $i).
% 29.22/29.03  tff(decl_38003, type, fn_passive_transport_of_solute_2: $i > $i).
% 29.22/29.03  tff(decl_38004, type, 'Facilitated-Diffusion-Of-Polar-Molecule': $i).
% 29.22/29.03  tff(decl_38005, type, 'The proteins mediate the movement of molecules that are too polar or too large to move across a membrane.': $i).
% 29.22/29.03  tff(decl_38006, type, 'facilitated diffusion of polar molecule': $i).
% 29.22/29.03  tff(decl_38007, type, 'facilitated-diffusion-of-polar-molecule': $i).
% 29.22/29.03  tff(decl_38008, type, fn_facilitated_diffusion_of_polar_molecule_1: $i > $i).
% 29.22/29.03  tff(decl_38009, type, fn_facilitated_diffusion_of_polar_molecule_2: $i > $i).
% 29.22/29.03  tff(decl_38010, type, fn_facilitated_diffusion_of_polar_molecule_3: $i > $i).
% 29.22/29.03  tff(decl_38011, type, fn_facilitated_diffusion_of_polar_molecule_4: $i > $i).
% 29.22/29.03  tff(decl_38012, type, fn_facilitated_diffusion_of_polar_molecule_6: $i > $i).
% 29.22/29.03  tff(decl_38013, type, fn_facilitated_diffusion_of_polar_molecule_7: $i > $i).
% 29.22/29.03  tff(decl_38014, type, fn_facilitated_diffusion_of_polar_molecule_9: $i > $i).
% 29.22/29.03  tff(decl_38015, type, fn_facilitated_diffusion_of_polar_molecule_10: $i > $i).
% 29.22/29.03  tff(decl_38016, type, fn_facilitated_diffusion_of_polar_molecule_11: $i > $i).
% 29.22/29.03  tff(decl_38017, type, fn_facilitated_diffusion_of_polar_molecule_12: $i > $i).
% 29.22/29.03  tff(decl_38018, type, fn_facilitated_diffusion_of_polar_molecule_14: $i > $i).
% 29.22/29.03  tff(decl_38019, type, fn_facilitated_diffusion_of_polar_molecule_15: $i > $i).
% 29.22/29.03  tff(decl_38020, type, fn_facilitated_diffusion_of_polar_molecule_8: $i > $i).
% 29.22/29.03  tff(decl_38021, type, fn_facilitated_diffusion_of_polar_molecule_16: $i > $i).
% 29.22/29.03  tff(decl_38022, type, fn_facilitated_diffusion_of_polar_molecule_13: $i > $i).
% 29.22/29.03  tff(decl_38023, type, 'Facilitated-Diffusion-Of-Water-Using-Aquaporin': $i).
% 29.22/29.03  tff(decl_38024, type, 'The movement of water through biomembrane. Flow of water through water channels can occur as a result of diffusion or by filtration.': $i).
% 29.22/29.03  tff(decl_38025, type, 'perform osmosis': $i).
% 29.22/29.03  tff(decl_38026, type, 'facilitated diffusion of water using aquaporin': $i).
% 29.22/29.03  tff(decl_38027, type, 'facilitated-diffusion-of-water-using-aquaporin': $i).
% 29.22/29.03  tff(decl_38028, type, fn_facilitated_diffusion_of_water_using_aquaporin_1: $i > $i).
% 29.22/29.03  tff(decl_38029, type, fn_facilitated_diffusion_of_water_using_aquaporin_3: $i > $i).
% 29.22/29.03  tff(decl_38030, type, fn_facilitated_diffusion_of_water_using_aquaporin_5: $i > $i).
% 29.22/29.03  tff(decl_38031, type, fn_facilitated_diffusion_of_water_using_aquaporin_6: $i > $i).
% 29.22/29.03  tff(decl_38032, type, fn_facilitated_diffusion_of_water_using_aquaporin_7: $i > $i).
% 29.22/29.03  tff(decl_38033, type, fn_facilitated_diffusion_of_water_using_aquaporin_10: $i > $i).
% 29.22/29.03  tff(decl_38034, type, fn_facilitated_diffusion_of_water_using_aquaporin_11: $i > $i).
% 29.22/29.03  tff(decl_38035, type, fn_facilitated_diffusion_of_water_using_aquaporin_12: $i > $i).
% 29.22/29.03  tff(decl_38036, type, fn_facilitated_diffusion_using_channel_protein_4: $i > $i).
% 29.22/29.03  tff(decl_38037, type, fn_facilitated_diffusion_using_channel_protein_18: $i > $i).
% 29.22/29.03  tff(decl_38038, type, fn_facilitated_diffusion_of_water_using_aquaporin_8: $i > $i).
% 29.22/29.03  tff(decl_38039, type, 'Facilitated-Diffusion-Using-Carrier-Protein': $i).
% 29.22/29.03  tff(decl_38040, type, 'The transport proteins hold onto their passengers and physically move them across the membrane. The transport protein is specific for the substances it translocates.': $i).
% 29.22/29.03  tff(decl_38041, type, 'facilitated diffusion using carrier protein': $i).
% 29.22/29.03  tff(decl_38042, type, 'facilitated-diffusion-using-carrier-protein': $i).
% 29.22/29.03  tff(decl_38043, type, fn_facilitated_diffusion_using_carrier_protein_3: $i > $i).
% 29.22/29.03  tff(decl_38044, type, fn_facilitated_diffusion_using_carrier_protein_5: $i > $i).
% 29.22/29.03  tff(decl_38045, type, fn_facilitated_diffusion_using_carrier_protein_6: $i > $i).
% 29.22/29.03  tff(decl_38046, type, fn_facilitated_diffusion_using_carrier_protein_11: $i > $i).
% 29.22/29.03  tff(decl_38047, type, fn_facilitated_diffusion_using_carrier_protein_13: $i > $i).
% 29.22/29.03  tff(decl_38048, type, fn_facilitated_diffusion_using_carrier_protein_15: $i > $i).
% 29.22/29.03  tff(decl_38049, type, fn_facilitated_diffusion_using_carrier_protein_16: $i > $i).
% 29.22/29.03  tff(decl_38050, type, fn_facilitated_diffusion_using_carrier_protein_17: $i > $i).
% 29.22/29.03  tff(decl_38051, type, fn_facilitated_diffusion_using_carrier_protein_20: $i > $i).
% 29.22/29.03  tff(decl_38052, type, fn_facilitated_diffusion_using_carrier_protein_21: $i > $i).
% 29.22/29.03  tff(decl_38053, type, fn_facilitated_diffusion_using_carrier_protein_22: $i > $i).
% 29.22/29.03  tff(decl_38054, type, fn_facilitated_diffusion_using_carrier_protein_23: $i > $i).
% 29.22/29.03  tff(decl_38055, type, fn_facilitated_diffusion_using_carrier_protein_24: $i > $i).
% 29.22/29.03  tff(decl_38056, type, fn_facilitated_diffusion_using_carrier_protein_26: $i > $i).
% 29.22/29.03  tff(decl_38057, type, fn_facilitated_diffusion_using_carrier_protein_27: $i > $i).
% 29.22/29.03  tff(decl_38058, type, fn_facilitated_diffusion_using_carrier_protein_29: $i > $i).
% 29.22/29.03  tff(decl_38059, type, fn_facilitated_diffusion_using_carrier_protein_30: $i > $i).
% 29.22/29.03  tff(decl_38060, type, fn_facilitated_diffusion_using_carrier_protein_31: $i > $i).
% 29.22/29.03  tff(decl_38061, type, fn_facilitated_diffusion_using_carrier_protein_36: $i > $i).
% 29.22/29.03  tff(decl_38062, type, fn_facilitated_diffusion_using_carrier_protein_37: $i > $i).
% 29.22/29.03  tff(decl_38063, type, fn_facilitated_diffusion_using_carrier_protein_38: $i > $i).
% 29.22/29.03  tff(decl_38064, type, fn_facilitated_diffusion_using_carrier_protein_39: $i > $i).
% 29.22/29.03  tff(decl_38065, type, fn_facilitated_diffusion_using_carrier_protein_46: $i > $i).
% 29.22/29.03  tff(decl_38066, type, fn_facilitated_diffusion_using_carrier_protein_47: $i > $i).
% 29.22/29.03  tff(decl_38067, type, fn_facilitated_diffusion_using_carrier_protein_41: $i > $i).
% 29.22/29.03  tff(decl_38068, type, fn_facilitated_diffusion_using_carrier_protein_42: $i > $i).
% 29.22/29.03  tff(decl_38069, type, fn_facilitated_diffusion_using_carrier_protein_43: $i > $i).
% 29.22/29.03  tff(decl_38070, type, fn_facilitated_diffusion_using_carrier_protein_44: $i > $i).
% 29.22/29.03  tff(decl_38071, type, 'Facilitated-Diffusion-Using-Channel-Protein': $i).
% 29.22/29.03  tff(decl_38072, type, 'The molecules move with the help of channel protein across the biomembrane.': $i).
% 29.22/29.03  tff(decl_38073, type, 'facilitated diffusion using channel protein': $i).
% 29.22/29.03  tff(decl_38074, type, 'facilitated-diffusion-using-channel-protein': $i).
% 29.22/29.03  tff(decl_38075, type, fn_facilitated_diffusion_using_channel_protein_5: $i > $i).
% 29.22/29.03  tff(decl_38076, type, fn_facilitated_diffusion_using_channel_protein_9: $i > $i).
% 29.22/29.03  tff(decl_38077, type, fn_facilitated_diffusion_using_channel_protein_10: $i > $i).
% 29.22/29.03  tff(decl_38078, type, fn_facilitated_diffusion_using_channel_protein_11: $i > $i).
% 29.22/29.03  tff(decl_38079, type, fn_facilitated_diffusion_using_channel_protein_12: $i > $i).
% 29.22/29.03  tff(decl_38080, type, fn_facilitated_diffusion_using_channel_protein_15: $i > $i).
% 29.22/29.03  tff(decl_38081, type, fn_facilitated_diffusion_using_channel_protein_16: $i > $i).
% 29.22/29.03  tff(decl_38082, type, fn_facilitated_diffusion_using_channel_protein_17: $i > $i).
% 29.22/29.03  tff(decl_38083, type, fn_facilitated_diffusion_using_channel_protein_19: $i > $i).
% 29.22/29.03  tff(decl_38084, type, fn_facilitated_diffusion_using_channel_protein_20: $i > $i).
% 29.22/29.03  tff(decl_38085, type, fn_facilitated_diffusion_using_channel_protein_7: $i > $i).
% 29.22/29.03  tff(decl_38086, type, fn_facilitated_diffusion_using_channel_protein_6: $i > $i).
% 29.22/29.03  tff(decl_38087, type, fn_facilitated_diffusion_using_channel_protein_21: $i > $i).
% 29.22/29.03  tff(decl_38088, type, fn_facilitated_diffusion_using_channel_protein_3: $i > $i).
% 29.22/29.03  tff(decl_38089, type, facilitator_1: $i > $o).
% 29.22/29.03  tff(decl_38090, type, 'Facilitator': $i).
% 29.22/29.03  tff(decl_38091, type, 'A species that has a positive effect on the survival and reproduction of other species in a community and that influences community structure.': $i).
% 29.22/29.03  tff(decl_38092, type, facilitator: $i).
% 29.22/29.03  tff(decl_38093, type, 'Factory': $i).
% 29.22/29.03  tff(decl_38094, type, 'A building where a product is manufactured.': $i).
% 29.22/29.03  tff(decl_38095, type, factory: $i).
% 29.22/29.03  tff(decl_38096, type, facultative_anaerobe_1: $i > $o).
% 29.22/29.03  tff(decl_38097, type, 'Facultative-Anaerobe': $i).
% 29.22/29.03  tff(decl_38098, type, 'Cells or organisms with the ability to make ATP by aerobic respiration or by anaerobic respiration. Most facultative anaerobes preferentially utilize aerobic respiration.': $i).
% 29.22/29.03  tff(decl_38099, type, 'facultative anaerobe': $i).
% 29.22/29.03  tff(decl_38100, type, 'facultative-anaerobe': $i).
% 29.22/29.03  tff(decl_38101, type, 'FAD': $i).
% 29.22/29.03  tff(decl_38102, type, 'FAD (Flavin Adenine Dinucleotide) is a derivative of the B-vitamin riboflavin.': $i).
% 29.22/29.03  tff(decl_38103, type, 'flavin adenine dinucleotide': $i).
% 29.22/29.03  tff(decl_38104, type, fad: $i).
% 29.22/29.03  tff(decl_38105, type, fn_fad_1: $i > $i).
% 29.22/29.03  tff(decl_38106, type, fn_fad_2: $i > $i).
% 29.22/29.03  tff(decl_38107, type, fn_fad_4: $i > $i).
% 29.22/29.03  tff(decl_38108, type, fn_fad_5: $i > $i).
% 29.22/29.03  tff(decl_38109, type, 'The reduced form of FAD is FADH2. This acts as a reducing agent in most chemical reactions.': $i).
% 29.22/29.03  tff(decl_38110, type, 'flavin-adenine-dinucleotide': $i).
% 29.22/29.03  tff(decl_38111, type, fadh2: $i).
% 29.22/29.03  tff(decl_38112, type, fn_fadh2_11: $i > $i).
% 29.22/29.03  tff(decl_38113, type, 'Fall': $i).
% 29.22/29.03  tff(decl_38114, type, familial_hypercholesterolemia_1: $i > $o).
% 29.22/29.03  tff(decl_38115, type, 'Familial-Hypercholesterolemia': $i).
% 29.22/29.03  tff(decl_38116, type, 'In humans with familial hypercholesterolemia, an inherited disease characterized by a very high level of cholesterol in the blood, the LDL receptor proteins are defective, and the LDL particles cannot enter cells.': $i).
% 29.22/29.03  tff(decl_38117, type, 'familial hypercholesterolaemia': $i).
% 29.22/29.03  tff(decl_38118, type, 'familial-hypercholesterolaemia': $i).
% 29.22/29.03  tff(decl_38119, type, fh: $i).
% 29.22/29.03  tff(decl_38120, type, 'familial hypercholesterolemia': $i).
% 29.22/29.03  tff(decl_38121, type, 'familial-hypercholesterolemia': $i).
% 29.22/29.03  tff(decl_38122, type, family_1: $i > $o).
% 29.22/29.03  tff(decl_38123, type, 'Family': $i).
% 29.22/29.03  tff(decl_38124, type, house: $i).
% 29.22/29.03  tff(decl_38125, type, home: $i).
% 29.22/29.03  tff(decl_38126, type, family: $i).
% 29.22/29.03  tff(decl_38127, type, household: $i).
% 29.22/29.03  tff(decl_38128, type, menage: $i).
% 29.22/29.03  tff(decl_38129, type, 'family unit': $i).
% 29.22/29.03  tff(decl_38130, type, family_unit: $i).
% 29.22/29.03  tff(decl_38131, type, family_as_classification_1: $i > $o).
% 29.22/29.03  tff(decl_38132, type, 'Family-As-Classification': $i).
% 29.22/29.03  tff(decl_38133, type, 'In Linnean classification, the taxonomy category above genus and below order.': $i).
% 29.22/29.03  tff(decl_38134, type, 'family as classification': $i).
% 29.22/29.03  tff(decl_38135, type, 'family-as-classification': $i).
% 29.22/29.03  tff(decl_38136, type, fang_1: $i > $o).
% 29.22/29.03  tff(decl_38137, type, 'Fang': $i).
% 29.22/29.03  tff(decl_38138, type, 'Specialized elongated canine tooth which is sharply pointed. In some species, fangs are hollow for injecting venom into prey.': $i).
% 29.22/29.03  tff(decl_38139, type, fasciated_gene_1: $i > $o).
% 29.22/29.03  tff(decl_38140, type, 'Fasciated-Gene': $i).
% 29.22/29.03  tff(decl_38141, type, 'Gene associated with fasciation, or lengthening of structures at the apical meristem of plants.': $i).
% 29.22/29.03  tff(decl_38142, type, 'fasciated gene': $i).
% 29.22/29.03  tff(decl_38143, type, 'fasciated-gene': $i).
% 29.22/29.03  tff(decl_38144, type, plant_gene_1: $i > $o).
% 29.22/29.03  tff(decl_38145, type, fn_fasciated_gene_1: $i > $i).
% 29.22/29.03  tff(decl_38146, type, fn_fasciated_gene_2: $i > $i).
% 29.22/29.03  tff(decl_38147, type, fn_fasciated_gene_3: $i > $i).
% 29.22/29.03  tff(decl_38148, type, fn_fasciated_gene_6: $i > $i).
% 29.22/29.03  tff(decl_38149, type, fn_fasciated_gene_7: $i > $i).
% 29.22/29.03  tff(decl_38150, type, fn_fasciated_gene_8: $i > $i).
% 29.22/29.03  tff(decl_38151, type, fn_fasciated_gene_9: $i > $i).
% 29.22/29.03  tff(decl_38152, type, fn_fasciated_gene_10: $i > $i).
% 29.22/29.03  tff(decl_38153, type, fn_fasciated_gene_16: $i > $i).
% 29.22/29.03  tff(decl_38154, type, fn_fasciated_gene_17: $i > $i).
% 29.22/29.03  tff(decl_38155, type, fn_fasciated_gene_18: $i > $i).
% 29.22/29.03  tff(decl_38156, type, fn_fasciated_gene_19: $i > $i).
% 29.22/29.03  tff(decl_38157, type, fn_fasciated_gene_20: $i > $i).
% 29.22/29.03  tff(decl_38158, type, fn_fasciated_gene_22: $i > $i).
% 29.22/29.03  tff(decl_38159, type, fn_fasciated_gene_23: $i > $i).
% 29.22/29.03  tff(decl_38160, type, fn_fasciated_gene_24: $i > $i).
% 29.22/29.03  tff(decl_38161, type, fn_fasciated_gene_25: $i > $i).
% 29.22/29.03  tff(decl_38162, type, fn_fasciated_gene_26: $i > $i).
% 29.22/29.03  tff(decl_38163, type, fn_fasciated_gene_27: $i > $i).
% 29.22/29.03  tff(decl_38164, type, fn_fasciated_gene_28: $i > $i).
% 29.22/29.03  tff(decl_38165, type, fn_fasciated_gene_29: $i > $i).
% 29.22/29.03  tff(decl_38166, type, fn_fasciated_gene_30: $i > $i).
% 29.22/29.03  tff(decl_38167, type, fn_fasciated_gene_31: $i > $i).
% 29.22/29.03  tff(decl_38168, type, fn_fasciated_gene_32: $i > $i).
% 29.22/29.03  tff(decl_38169, type, fn_fasciated_gene_33: $i > $i).
% 29.22/29.03  tff(decl_38170, type, fn_fasciated_gene_34: $i > $i).
% 29.22/29.03  tff(decl_38171, type, fn_fasciated_gene_35: $i > $i).
% 29.22/29.03  tff(decl_38172, type, fn_fasciated_gene_36: $i > $i).
% 29.22/29.03  tff(decl_38173, type, fn_fasciated_gene_37: $i > $i).
% 29.22/29.03  tff(decl_38174, type, fn_fasciated_gene_38: $i > $i).
% 29.22/29.03  tff(decl_38175, type, fn_fasciated_gene_39: $i > $i).
% 29.22/29.03  tff(decl_38176, type, fn_fasciated_gene_40: $i > $i).
% 29.22/29.03  tff(decl_38177, type, fn_phosphodiester_bond_4: $i > $i).
% 29.22/29.03  tff(decl_38178, type, fn_fasciated_gene_13: $i > $i).
% 29.22/29.03  tff(decl_38179, type, fn_gene_8: $i > $i).
% 29.22/29.03  tff(decl_38180, type, fn_gene_3: $i > $i).
% 29.22/29.03  tff(decl_38181, type, fn_gene_5: $i > $i).
% 29.22/29.03  tff(decl_38182, type, fn_gene_4: $i > $i).
% 29.22/29.03  tff(decl_38183, type, fn_gene_10: $i > $i).
% 29.22/29.03  tff(decl_38184, type, fn_fasciated_gene_12: $i > $i).
% 29.22/29.03  tff(decl_38185, type, fn_gene_9: $i > $i).
% 29.22/29.03  tff(decl_38186, type, fn_gene_11: $i > $i).
% 29.22/29.03  tff(decl_38187, type, fn_gene_12: $i > $i).
% 29.22/29.03  tff(decl_38188, type, fn_fasciated_gene_11: $i > $i).
% 29.22/29.03  tff(decl_38189, type, fn_fasciated_gene_14: $i > $i).
% 29.22/29.03  tff(decl_38190, type, fn_fasciated_gene_15: $i > $i).
% 29.22/29.03  tff(decl_38191, type, fn_fasciated_gene_21: $i > $i).
% 29.22/29.03  tff(decl_38192, type, fast_block_1: $i > $o).
% 29.22/29.03  tff(decl_38193, type, 'Fast-Block': $i).
% 29.22/29.03  tff(decl_38194, type, 'A rapid depolarization of the egg membrane that is triggered when a sperm fuses to the egg membrane. The depolarization prevents other sperm from fusing with the same egg.': $i).
% 29.22/29.03  tff(decl_38195, type, 'block of fast': $i).
% 29.22/29.03  tff(decl_38196, type, 'fast block': $i).
% 29.22/29.03  tff(decl_38197, type, 'fast-block': $i).
% 29.22/29.03  tff(decl_38198, type, fast_muscle_fiber_1: $i > $o).
% 29.22/29.03  tff(decl_38199, type, 'Fast-Muscle-Fiber': $i).
% 29.22/29.03  tff(decl_38200, type, 'Skeletal muscle fiber that contracts quickly and strongly but fatigues rapidly.': $i).
% 29.22/29.03  tff(decl_38201, type, 'fast muscle fiber': $i).
% 29.22/29.03  tff(decl_38202, type, 'fast-muscle-fiber': $i).
% 29.22/29.03  tff(decl_38203, type, slow_twitch_fiber_1: $i > $o).
% 29.22/29.03  tff(decl_38204, type, 'Fat': $i).
% 29.22/29.03  tff(decl_38205, type, 'Fats consist of a wide group of compounds that are generally soluble in organic solvents and largely insoluble in water. Chemically, fats are generally triesters of glycerol and fatty acids. Fats may be either solid or liquid at room temperature, depending on their structure and composition': $i).
% 29.22/29.03  tff(decl_38206, type, triglyceride: $i).
% 29.22/29.03  tff(decl_38207, type, triacylglycerol: $i).
% 29.22/29.03  tff(decl_38208, type, tag: $i).
% 29.22/29.03  tff(decl_38209, type, tg: $i).
% 29.22/29.03  tff(decl_38210, type, fat: $i).
% 29.22/29.03  tff(decl_38211, type, fn_fat_1: $i > $i).
% 29.22/29.03  tff(decl_38212, type, fn_fat_2: $i > $i).
% 29.22/29.03  tff(decl_38213, type, fn_fat_3: $i > $i).
% 29.22/29.03  tff(decl_38214, type, fn_fat_5: $i > $i).
% 29.22/29.03  tff(decl_38215, type, glycerol_head_1: $i > $o).
% 29.22/29.03  tff(decl_38216, type, fn_fat_6: $i > $i).
% 29.22/29.03  tff(decl_38217, type, fn_fat_7: $i > $i).
% 29.22/29.03  tff(decl_38218, type, fn_fat_9: $i > $i).
% 29.22/29.03  tff(decl_38219, type, fn_fat_11: $i > $i).
% 29.22/29.03  tff(decl_38220, type, fn_fat_12: $i > $i).
% 29.22/29.03  tff(decl_38221, type, fn_fat_13: $i > $i).
% 29.22/29.03  tff(decl_38222, type, fn_fat_14: $i > $i).
% 29.22/29.03  tff(decl_38223, type, fatty_acid_0: $i).
% 29.22/29.03  tff(decl_38224, type, glycerol_0: $i).
% 29.22/29.03  tff(decl_38225, type, ester_linkage_0: $i).
% 29.22/29.03  tff(decl_38226, type, fatty_acid_tail_0: $i).
% 29.22/29.03  tff(decl_38227, type, fn_lipid_16: $i > $i).
% 29.22/29.03  tff(decl_38228, type, fat_soluble_vitamin_1: $i > $o).
% 29.22/29.03  tff(decl_38229, type, 'Fat-Soluble-Vitamin': $i).
% 29.22/29.03  tff(decl_38230, type, 'A fat-soluble organic molecule required in the diet in very small amounts.': $i).
% 29.22/29.03  tff(decl_38231, type, 'fat soluble vitamin': $i).
% 29.22/29.03  tff(decl_38232, type, 'fat-soluble-vitamin': $i).
% 29.22/29.03  tff(decl_38233, type, fn_fat_soluble_vitamin_2: $i > $i).
% 29.22/29.03  tff(decl_38234, type, vitamin_0: $i).
% 29.22/29.03  tff(decl_38235, type, fn_fat_soluble_vitamin_1: $i > $i).
% 29.22/29.03  tff(decl_38236, type, 'Fat-Substance': $i).
% 29.22/29.03  tff(decl_38237, type, 'Substance composed of fat molecules.': $i).
% 29.22/29.03  tff(decl_38238, type, 'substance of fat': $i).
% 29.22/29.03  tff(decl_38239, type, 'fat substance': $i).
% 29.22/29.03  tff(decl_38240, type, 'fat-substance': $i).
% 29.22/29.03  tff(decl_38241, type, 'Fate-Map': $i).
% 29.22/29.03  tff(decl_38242, type, 'A diagram of an embryo showing the resulting tissues and structures derived from each of the cells.': $i).
% 29.22/29.03  tff(decl_38243, type, 'map of fate': $i).
% 29.22/29.03  tff(decl_38244, type, 'fate map': $i).
% 29.22/29.03  tff(decl_38245, type, 'fate-map': $i).
% 29.22/29.03  tff(decl_38246, type, 'Fatty-Acid': $i).
% 29.22/29.03  tff(decl_38247, type, 'A fatty acid has a carboxylic acid on a long chain of carbon atoms. The carboxylic acid may also be called the carboxyl functional group. Fatty acids are a major source of energy for the cell. Compounds called phospholipids are created from fatty acids.': $i).
% 29.22/29.03  tff(decl_38248, type, 'acid of fatty': $i).
% 29.22/29.03  tff(decl_38249, type, 'fatty acid': $i).
% 29.22/29.03  tff(decl_38250, type, 'fatty-acid': $i).
% 29.22/29.03  tff(decl_38251, type, fn_fatty_acid_2: $i > $i).
% 29.22/29.03  tff(decl_38252, type, fn_fatty_acid_4: $i > $i).
% 29.22/29.03  tff(decl_38253, type, fn_fatty_acid_5: $i > $i).
% 29.22/29.03  tff(decl_38254, type, fn_fatty_acid_7: $i > $i).
% 29.22/29.03  tff(decl_38255, type, fn_fatty_acid_13: $i > $i).
% 29.22/29.03  tff(decl_38256, type, fn_fatty_acid_18: $i > $i).
% 29.22/29.03  tff(decl_38257, type, fn_fatty_acid_25: $i > $i).
% 29.22/29.03  tff(decl_38258, type, fn_fatty_acid_28: $i > $i).
% 29.22/29.03  tff(decl_38259, type, fn_fatty_acid_30: $i > $i).
% 29.22/29.03  tff(decl_38260, type, fn_fatty_acid_39: $i > $i).
% 29.22/29.03  tff(decl_38261, type, fn_fatty_acid_42: $i > $i).
% 29.22/29.03  tff(decl_38262, type, fn_fatty_acid_45: $i > $i).
% 29.22/29.03  tff(decl_38263, type, fn_fatty_acid_46: $i > $i).
% 29.22/29.03  tff(decl_38264, type, fn_fatty_acid_47: $i > $i).
% 29.22/29.03  tff(decl_38265, type, fn_fatty_acid_48: $i > $i).
% 29.22/29.03  tff(decl_38266, type, fn_fatty_acid_49: $i > $i).
% 29.22/29.03  tff(decl_38267, type, fn_fatty_acid_50: $i > $i).
% 29.22/29.03  tff(decl_38268, type, fn_fatty_acid_51: $i > $i).
% 29.22/29.03  tff(decl_38269, type, fn_fatty_acid_52: $i > $i).
% 29.22/29.03  tff(decl_38270, type, fn_fatty_acid_53: $i > $i).
% 29.22/29.03  tff(decl_38271, type, fn_fatty_acid_54: $i > $i).
% 29.22/29.03  tff(decl_38272, type, fn_fatty_acid_55: $i > $i).
% 29.22/29.03  tff(decl_38273, type, fn_fatty_acid_56: $i > $i).
% 29.22/29.03  tff(decl_38274, type, fn_fatty_acid_59: $i > $i).
% 29.22/29.03  tff(decl_38275, type, fn_fatty_acid_60: $i > $i).
% 29.22/29.03  tff(decl_38276, type, fn_fatty_acid_65: $i > $i).
% 29.22/29.03  tff(decl_38277, type, single_bond_0: $i).
% 29.22/29.03  tff(decl_38278, type, molecular_region_0: $i).
% 29.22/29.03  tff(decl_38279, type, fn_organic_acid_8: $i > $i).
% 29.22/29.03  tff(decl_38280, type, fn_organic_acid_5: $i > $i).
% 29.22/29.03  tff(decl_38281, type, fn_organic_acid_9: $i > $i).
% 29.22/29.03  tff(decl_38282, type, 'Fatty-Acid-Tail': $i).
% 29.22/29.03  tff(decl_38283, type, 'A fatty acid tail is a long tail-like region of a molecule which consists of fatty acids.': $i).
% 29.22/29.03  tff(decl_38284, type, 'hydrophobic tail': $i).
% 29.22/29.03  tff(decl_38285, type, 'hydrocarbon tail': $i).
% 29.22/29.03  tff(decl_38286, type, 'hydrocarbon-tail': $i).
% 29.22/29.03  tff(decl_38287, type, 'fatty acid tail': $i).
% 29.22/29.03  tff(decl_38288, type, 'fatty-acid-tail': $i).
% 29.22/29.03  tff(decl_38289, type, fn_fatty_acid_tail_2: $i > $i).
% 29.22/29.03  tff(decl_38290, type, fn_fatty_acid_tail_6: $i > $i).
% 29.22/29.03  tff(decl_38291, type, fn_fatty_acid_tail_7: $i > $i).
% 29.22/29.03  tff(decl_38292, type, fe_plus_3_1: $i > $o).
% 29.22/29.03  tff(decl_38293, type, 'Fe-Plus-3': $i).
% 29.22/29.03  tff(decl_38294, type, 'An ion of Iron with 3 positive charge.': $i).
% 29.22/29.03  tff(decl_38295, type, 'fe plus 3': $i).
% 29.22/29.03  tff(decl_38296, type, 'fe-plus-3': $i).
% 29.22/29.03  tff(decl_38297, type, fn_fe_plus_3_1: $i > $i).
% 29.22/29.03  tff(decl_38298, type, 'Feather': $i).
% 29.22/29.03  tff(decl_38299, type, 'An epidermal outgrowth that forms the outer covering of birds.': $i).
% 29.22/29.03  tff(decl_38300, type, feather: $i).
% 29.22/29.03  tff(decl_38301, type, specialised_organ_1: $i > $o).
% 29.22/29.03  tff(decl_38302, type, fn_feather_1: $i > $i).
% 29.22/29.03  tff(decl_38303, type, 'Feces': $i).
% 29.22/29.03  tff(decl_38304, type, 'The waste products of digestion.': $i).
% 29.22/29.03  tff(decl_38305, type, faeces: $i).
% 29.22/29.03  tff(decl_38306, type, 'fecal matter': $i).
% 29.22/29.03  tff(decl_38307, type, 'fecal-matter': $i).
% 29.22/29.03  tff(decl_38308, type, 'bowel movement': $i).
% 29.22/29.03  tff(decl_38309, type, 'bowel-movement': $i).
% 29.22/29.03  tff(decl_38310, type, poop: $i).
% 29.22/29.03  tff(decl_38311, type, feces: $i).
% 29.22/29.03  tff(decl_38312, type, fn_feces_2: $i > $i).
% 29.22/29.03  tff(decl_38313, type, fn_feces_3: $i > $i).
% 29.22/29.03  tff(decl_38314, type, fn_feces_4: $i > $i).
% 29.22/29.03  tff(decl_38315, type, fn_feces_5: $i > $i).
% 29.22/29.03  tff(decl_38316, type, fn_feces_6: $i > $i).
% 29.22/29.03  tff(decl_38317, type, fn_feces_7: $i > $i).
% 29.22/29.03  tff(decl_38318, type, fn_feces_8: $i > $i).
% 29.22/29.03  tff(decl_38319, type, fn_feces_9: $i > $i).
% 29.22/29.03  tff(decl_38320, type, fn_feces_11: $i > $i).
% 29.22/29.03  tff(decl_38321, type, fn_feces_12: $i > $i).
% 29.22/29.03  tff(decl_38322, type, fn_feces_13: $i > $i).
% 29.22/29.03  tff(decl_38323, type, fn_feces_14: $i > $i).
% 29.22/29.03  tff(decl_38324, type, fn_feces_15: $i > $i).
% 29.22/29.03  tff(decl_38325, type, fn_feces_16: $i > $i).
% 29.22/29.03  tff(decl_38326, type, 'Feed': $i).
% 29.22/29.03  tff(decl_38327, type, grub: $i).
% 29.22/29.03  tff(decl_38328, type, supply_1: $i > $o).
% 29.22/29.03  tff(decl_38329, type, fn_feed_1: $i > $i).
% 29.22/29.03  tff(decl_38330, type, fn_feed_2: $i > $i).
% 29.22/29.03  tff(decl_38331, type, fn_feed_3: $i > $i).
% 29.22/29.03  tff(decl_38332, type, fn_relinquish_1: $i > $i).
% 29.22/29.03  tff(decl_38333, type, 'Feedback-Inhibition': $i).
% 29.22/29.03  tff(decl_38334, type, 'A cellular control mechanism in which an enzyme that catalyzes the production of a particular substance in the cell is inhibited when that substance has accumulated to a certain level, thereby balancing the amount provided with the amount needed.': $i).
% 29.22/29.03  tff(decl_38335, type, 'negative feedback': $i).
% 29.22/29.03  tff(decl_38336, type, 'negative-feedback': $i).
% 29.22/29.03  tff(decl_38337, type, 'perform feedback inhibition': $i).
% 29.22/29.03  tff(decl_38338, type, 'inhibition of feedback': $i).
% 29.22/29.03  tff(decl_38339, type, 'feedback inhibition': $i).
% 29.22/29.03  tff(decl_38340, type, 'feedback-inhibition': $i).
% 29.22/29.03  tff(decl_38341, type, feedback_mechanism_1: $i > $o).
% 29.22/29.03  tff(decl_38342, type, induced_fit_1: $i > $o).
% 29.22/29.03  tff(decl_38343, type, fn_feedback_inhibition_1: $i > $i).
% 29.22/29.03  tff(decl_38344, type, fn_feedback_inhibition_2: $i > $i).
% 29.22/29.03  tff(decl_38345, type, fn_feedback_inhibition_3: $i > $i).
% 29.22/29.03  tff(decl_38346, type, feedback_inhibition_of_anabolic_pathway_1: $i > $o).
% 29.22/29.03  tff(decl_38347, type, fn_feedback_inhibition_of_anabolic_pathway_8: $i > $i).
% 29.22/29.03  tff(decl_38348, type, 'Feedback-Inhibition-Of-Anabolic-Pathway': $i).
% 29.22/29.03  tff(decl_38349, type, 'A cellular control mechanism in which teh anabolic pathway in the cell is inhibited thereby balancing the substance amount provided with the amount needed.': $i).
% 29.22/29.03  tff(decl_38350, type, 'perform feedback inhibition of an anabolic pathway': $i).
% 29.22/29.03  tff(decl_38351, type, 'feedback inhibition of anabolic pathway': $i).
% 29.22/29.03  tff(decl_38352, type, 'feedback-inhibition-of-anabolic-pathway': $i).
% 29.22/29.03  tff(decl_38353, type, fn_feedback_inhibition_of_anabolic_pathway_1: $i > $i).
% 29.22/29.03  tff(decl_38354, type, fn_feedback_inhibition_of_anabolic_pathway_2: $i > $i).
% 29.22/29.03  tff(decl_38355, type, fn_feedback_inhibition_of_anabolic_pathway_3: $i > $i).
% 29.22/29.03  tff(decl_38356, type, fn_feedback_inhibition_of_anabolic_pathway_4: $i > $i).
% 29.22/29.03  tff(decl_38357, type, fn_feedback_inhibition_of_anabolic_pathway_5: $i > $i).
% 29.22/29.03  tff(decl_38358, type, fn_feedback_inhibition_of_anabolic_pathway_7: $i > $i).
% 29.22/29.03  tff(decl_38359, type, fn_feedback_inhibition_of_glycolysis_3: $i > $i).
% 29.22/29.03  tff(decl_38360, type, 'Feedback-Inhibition-Of-Glycolysis': $i).
% 29.22/29.03  tff(decl_38361, type, 'A method of metabolic control of glycolysis where the end products of the pathway act as inhibitors of enzymes within the glycolytic pathway.': $i).
% 29.22/29.03  tff(decl_38362, type, 'perform feedback inhibition of glycolysis': $i).
% 29.22/29.03  tff(decl_38363, type, 'feedback inhibition of glycolysis': $i).
% 29.22/29.03  tff(decl_38364, type, 'feedback-inhibition-of-glycolysis': $i).
% 29.22/29.03  tff(decl_38365, type, 'Feedback-Inhibition-Of-Glycolysis-By-ATP': $i).
% 29.22/29.03  tff(decl_38366, type, 'A method of metabolic control of glycolysis in which excess ATP molecules produced during glycolysis act as an inhibitor of phosphofructokinase (PFK), an enzyme within the glycolytic pathway.': $i).
% 29.22/29.03  tff(decl_38367, type, 'feedback inhibition of glycolysis by atp': $i).
% 29.22/29.03  tff(decl_38368, type, 'feedback-inhibition-of-glycolysis-by-atp': $i).
% 29.22/29.03  tff(decl_38369, type, fn_feedback_inhibition_of_glycolysis_by_citrate_8: $i > $i).
% 29.22/29.03  tff(decl_38370, type, fn_feedback_inhibition_of_glycolysis_by_citrate_5: $i > $i).
% 29.22/29.03  tff(decl_38371, type, 'Feedback-Inhibition-Of-Glycolysis-By-Citrate': $i).
% 29.22/29.03  tff(decl_38372, type, 'High concentrations of ATP and citrate inhibit glycolysis by allosteric regulation of phosphofructokinase. This is referred to as feedback inhibition.': $i).
% 29.22/29.03  tff(decl_38373, type, 'feedback inhibition of glycolysis by citrate': $i).
% 29.22/29.03  tff(decl_38374, type, 'feedback-inhibition-of-glycolysis-by-citrate': $i).
% 29.22/29.03  tff(decl_38375, type, fn_feedback_inhibition_of_glycolysis_by_citrate_2: $i > $i).
% 29.22/29.03  tff(decl_38376, type, fn_feedback_inhibition_of_glycolysis_by_citrate_3: $i > $i).
% 29.22/29.03  tff(decl_38377, type, fn_feedback_inhibition_of_glycolysis_by_citrate_4: $i > $i).
% 29.22/29.03  tff(decl_38378, type, fn_feedback_inhibition_of_glycolysis_by_citrate_6: $i > $i).
% 29.22/29.03  tff(decl_38379, type, fn_feedback_inhibition_of_glycolysis_by_citrate_7: $i > $i).
% 29.22/29.03  tff(decl_38380, type, fn_mitochondrion_23: $i > $i).
% 29.22/29.03  tff(decl_38381, type, fn_mitochondrion_24: $i > $i).
% 29.22/29.03  tff(decl_38382, type, 'Feedback-Mechanism': $i).
% 29.22/29.03  tff(decl_38383, type, 'Mechanism by which the output or product of a process regulates that process.': $i).
% 29.22/29.03  tff(decl_38384, type, 'mechanism of feedback': $i).
% 29.22/29.03  tff(decl_38385, type, 'feedback mechanism': $i).
% 29.22/29.03  tff(decl_38386, type, 'feedback-mechanism': $i).
% 29.22/29.03  tff(decl_38387, type, 'Feeder': $i).
% 29.22/29.03  tff(decl_38388, type, 'Role assumed by an organism which refers to the way it obtains food.': $i).
% 29.22/29.03  tff(decl_38389, type, feeder: $i).
% 29.22/29.03  tff(decl_38390, type, 'Feeding': $i).
% 29.22/29.03  tff(decl_38391, type, 'The process of ingesting food to supply an animal\\s nutrient and energy needs.': $i).
% 29.22/29.03  tff(decl_38392, type, feeding: $i).
% 29.22/29.03  tff(decl_38393, type, feeding_behavior_1: $i > $o).
% 29.22/29.03  tff(decl_38394, type, 'Feeding-Behavior': $i).
% 29.22/29.03  tff(decl_38395, type, 'Behaviors relating to the obtaining of food by animals.': $i).
% 29.22/29.03  tff(decl_38396, type, 'behavior of feeding': $i).
% 29.22/29.03  tff(decl_38397, type, 'feeding behavior': $i).
% 29.22/29.03  tff(decl_38398, type, 'feeding-behavior': $i).
% 29.22/29.03  tff(decl_38399, type, female_calico_cat_expressing_fur_color_1: $i > $o).
% 29.22/29.03  tff(decl_38400, type, 'Female-Calico-Cat-Expressing-Fur-Color': $i).
% 29.22/29.03  tff(decl_38401, type, 'A cat with Oo and white spotting genes is commonly called a calico. The reason for the patchwork effect in female cats heterozygous for the O gene (Oo) is X-inactivation  one or the other X chromosome in every cell in the embryo is randomly inactivated (see Barr body), and the gene in the other X chromosome is expressed.': $i).
% 29.22/29.03  tff(decl_38402, type, 'female calico cat expressing fur color': $i).
% 29.22/29.03  tff(decl_38403, type, 'female-calico-cat-expressing-fur-color': $i).
% 29.22/29.03  tff(decl_38404, type, fn_female_calico_cat_expressing_fur_color_1: $i > $i).
% 29.22/29.03  tff(decl_38405, type, fn_female_calico_cat_expressing_fur_color_3: $i > $i).
% 29.22/29.03  tff(decl_38406, type, fur_1: $i > $o).
% 29.22/29.03  tff(decl_38407, type, fn_female_calico_cat_expressing_fur_color_4: $i > $i).
% 29.22/29.03  tff(decl_38408, type, fn_female_calico_cat_expressing_fur_color_5: $i > $i).
% 29.22/29.03  tff(decl_38409, type, fn_female_calico_cat_expressing_fur_color_6: $i > $i).
% 29.22/29.03  tff(decl_38410, type, 'Female-Reproductive-Cycle-Events': $i).
% 29.22/29.03  tff(decl_38411, type, 'Events related to the female sexual reproductive cycle in animals.': $i).
% 29.22/29.03  tff(decl_38412, type, 'female reproductive cycle event': $i).
% 29.22/29.03  tff(decl_38413, type, 'female-reproductive-cycle-event': $i).
% 29.22/29.03  tff(decl_38414, type, 'Female-Somatic-Cell': $i).
% 29.22/29.03  tff(decl_38415, type, 'Any cell in a female multicellular organism except a sperm or egg or their precursors.': $i).
% 29.22/29.03  tff(decl_38416, type, 'female somatic cell': $i).
% 29.22/29.03  tff(decl_38417, type, 'female-somatic-cell': $i).
% 29.22/29.03  tff(decl_38418, type, male_somatic_cell_1: $i > $o).
% 29.22/29.03  tff(decl_38419, type, fn_female_somatic_cell_1: $i > $i).
% 29.22/29.03  tff(decl_38420, type, fn_female_somatic_cell_2: $i > $i).
% 29.22/29.03  tff(decl_38421, type, barr_body_0: $i).
% 29.22/29.03  tff(decl_38422, type, 'Fermentation': $i).
% 29.22/29.03  tff(decl_38423, type, 'Fermentation in food processing typically is the conversion of carbohydrates to alcohols and carbon dioxide or organic acids using yeasts, bacteria, or a combination thereof, under anaerobic conditions.': $i).
% 29.22/29.03  tff(decl_38424, type, fermentation: $i).
% 29.22/29.03  tff(decl_38425, type, fn_fermentation_1: $i > $i).
% 29.22/29.03  tff(decl_38426, type, fn_fermentation_9: $i > $i).
% 29.22/29.03  tff(decl_38427, type, fn_fermentation_10: $i > $i).
% 29.22/29.03  tff(decl_38428, type, fn_fermentation_11: $i > $i).
% 29.22/29.03  tff(decl_38429, type, fn_fermentation_12: $i > $i).
% 29.22/29.03  tff(decl_38430, type, fn_fermentation_18: $i > $i).
% 29.22/29.03  tff(decl_38431, type, fn_fermentation_19: $i > $i).
% 29.22/29.03  tff(decl_38432, type, fn_fermentation_20: $i > $i).
% 29.22/29.03  tff(decl_38433, type, fn_fermentation_21: $i > $i).
% 29.22/29.03  tff(decl_38434, type, fn_fermentation_22: $i > $i).
% 29.22/29.03  tff(decl_38435, type, fn_fermentation_23: $i > $i).
% 29.22/29.03  tff(decl_38436, type, fn_fermentation_25: $i > $i).
% 29.22/29.03  tff(decl_38437, type, fn_fermentation_26: $i > $i).
% 29.22/29.03  tff(decl_38438, type, fn_fermentation_27: $i > $i).
% 29.22/29.03  tff(decl_38439, type, fn_fermentation_28: $i > $i).
% 29.22/29.03  tff(decl_38440, type, fn_fermentation_29: $i > $i).
% 29.22/29.03  tff(decl_38441, type, fn_fermentation_34: $i > $i).
% 29.22/29.03  tff(decl_38442, type, fn_fermentation_35: $i > $i).
% 29.22/29.03  tff(decl_38443, type, fn_fermentation_36: $i > $i).
% 29.22/29.03  tff(decl_38444, type, fn_fermentation_37: $i > $i).
% 29.22/29.03  tff(decl_38445, type, fn_fermentation_39: $i > $i).
% 29.22/29.03  tff(decl_38446, type, fn_fermentation_40: $i > $i).
% 29.22/29.03  tff(decl_38447, type, fn_fermentation_41: $i > $i).
% 29.22/29.03  tff(decl_38448, type, fn_fermentation_42: $i > $i).
% 29.22/29.03  tff(decl_38449, type, fn_fermentation_43: $i > $i).
% 29.22/29.03  tff(decl_38450, type, fn_fermentation_44: $i > $i).
% 29.22/29.03  tff(decl_38451, type, fn_fermentation_45: $i > $i).
% 29.22/29.03  tff(decl_38452, type, fn_fermentation_46: $i > $i).
% 29.22/29.03  tff(decl_38453, type, fn_fermentation_48: $i > $i).
% 29.22/29.03  tff(decl_38454, type, fn_fermentation_50: $i > $i).
% 29.22/29.03  tff(decl_38455, type, fn_fermentation_51: $i > $i).
% 29.22/29.03  tff(decl_38456, type, fn_fermentation_52: $i > $i).
% 29.22/29.03  tff(decl_38457, type, fn_fermentation_53: $i > $i).
% 29.22/29.03  tff(decl_38458, type, fn_fermentation_54: $i > $i).
% 29.22/29.03  tff(decl_38459, type, fn_fermentation_55: $i > $i).
% 29.22/29.03  tff(decl_38460, type, fn_fermentation_56: $i > $i).
% 29.22/29.03  tff(decl_38461, type, fn_fermentation_57: $i > $i).
% 29.22/29.03  tff(decl_38462, type, fn_fermentation_59: $i > $i).
% 29.22/29.03  tff(decl_38463, type, fn_glycolysis_1: $i > $i).
% 29.22/29.03  tff(decl_38464, type, fn_glycolysis_4: $i > $i).
% 29.22/29.03  tff(decl_38465, type, fn_glycolysis_2: $i > $i).
% 29.22/29.03  tff(decl_38466, type, fn_glycolysis_3: $i > $i).
% 29.22/29.03  tff(decl_38467, type, fn_glucose_6: $i > $i).
% 29.22/29.03  tff(decl_38468, type, fn_glucose_27: $i > $i).
% 29.22/29.03  tff(decl_38469, type, fn_glucose_24: $i > $i).
% 29.22/29.03  tff(decl_38470, type, fn_glucose_21: $i > $i).
% 29.22/29.03  tff(decl_38471, type, fn_glucose_22: $i > $i).
% 29.22/29.03  tff(decl_38472, type, fn_glucose_33: $i > $i).
% 29.22/29.03  tff(decl_38473, type, fn_glucose_15: $i > $i).
% 29.22/29.03  tff(decl_38474, type, fn_fermentation_13: $i > $i).
% 29.22/29.03  tff(decl_38475, type, fn_fermentation_61: $i > $i).
% 29.22/29.03  tff(decl_38476, type, fn_fermentation_8: $i > $i).
% 29.22/29.03  tff(decl_38477, type, fn_fermentation_7: $i > $i).
% 29.22/29.03  tff(decl_38478, type, fn_fermentation_14: $i > $i).
% 29.22/29.03  tff(decl_38479, type, fn_fermentation_64: $i > $i).
% 29.22/29.03  tff(decl_38480, type, fn_fermentation_63: $i > $i).
% 29.22/29.03  tff(decl_38481, type, fn_fermentation_16: $i > $i).
% 29.22/29.03  tff(decl_38482, type, fn_fermentation_15: $i > $i).
% 29.22/29.03  tff(decl_38483, type, fn_fermentation_60: $i > $i).
% 29.22/29.03  tff(decl_38484, type, fn_fermentation_62: $i > $i).
% 29.22/29.03  tff(decl_38485, type, fermenting_cell_1: $i > $o).
% 29.22/29.03  tff(decl_38486, type, 'Fermenting-Cell': $i).
% 29.22/29.03  tff(decl_38487, type, 'Fermentation in food processing typically is the conversion of carbohydrates to alcohols and carbon dioxide or organic acids using yeasts, bacteria, or a combination thereof, under anaerobic conditions. Some cells are involved in fermentation.': $i).
% 29.22/29.03  tff(decl_38488, type, 'cell involved in fermentation': $i).
% 29.22/29.03  tff(decl_38489, type, 'cell of fermenting': $i).
% 29.22/29.03  tff(decl_38490, type, 'fermenting cell': $i).
% 29.22/29.03  tff(decl_38491, type, 'fermenting-cell': $i).
% 29.22/29.03  tff(decl_38492, type, fermium_1: $i > $o).
% 29.22/29.03  tff(decl_38493, type, 'Fermium': $i).
% 29.22/29.03  tff(decl_38494, type, 'Fermium is a metal atom with atomic number 100. It is represented by the symbol Fm.': $i).
% 29.22/29.03  tff(decl_38495, type, fermium: $i).
% 29.22/29.03  tff(decl_38496, type, fm: $i).
% 29.22/29.03  tff(decl_38497, type, fn_fermium_3: $i > $i).
% 29.22/29.03  tff(decl_38498, type, fn_fermium_4: $i > $i).
% 29.22/29.03  tff(decl_38499, type, fn_fermium_5: $i > $i).
% 29.22/29.03  tff(decl_38500, type, fn_fermium_9: $i > $i).
% 29.22/29.03  tff(decl_38501, type, fn_fermium_10: $i > $i).
% 29.22/29.03  tff(decl_38502, type, fn_fermium_11: $i > $i).
% 29.22/29.03  tff(decl_38503, type, fn_fermium_12: $i > $i).
% 29.22/29.03  tff(decl_38504, type, "100": $i).
% 29.22/29.03  tff(decl_38505, type, "257": $i).
% 29.22/29.03  tff(decl_38506, type, fn_fermium_7: $i > $i).
% 29.22/29.03  tff(decl_38507, type, fn_fermium_8: $i > $i).
% 29.22/29.03  tff(decl_38508, type, fn_fermium_6: $i > $i).
% 29.22/29.03  tff(decl_38509, type, 'Ferredoxin': $i).
% 29.22/29.03  tff(decl_38510, type, 'Ferredoxins are iron-sulfur proteins that mediate electron transfer in a range of metabolic reactions.': $i).
% 29.22/29.03  tff(decl_38511, type, fd: $i).
% 29.22/29.03  tff(decl_38512, type, ferredoxin: $i).
% 29.22/29.03  tff(decl_38513, type, 'Fertility-Constant': $i).
% 29.22/29.03  tff(decl_38514, type, 'constant of fertility': $i).
% 29.22/29.03  tff(decl_38515, type, 'fertility constant': $i).
% 29.22/29.03  tff(decl_38516, type, 'fertility-constant': $i).
% 29.22/29.03  tff(decl_38517, type, 'Fertility-Scalar-Constant': $i).
% 29.22/29.03  tff(decl_38518, type, 'fertility scalar constant': $i).
% 29.22/29.03  tff(decl_38519, type, 'fertility-scalar-constant': $i).
% 29.22/29.03  tff(decl_38520, type, fertility_scale_1: $i > $o).
% 29.22/29.03  tff(decl_38521, type, 'Fertility-Scale': $i).
% 29.22/29.03  tff(decl_38522, type, 'scale of fertility': $i).
% 29.22/29.03  tff(decl_38523, type, 'fertility scale': $i).
% 29.22/29.03  tff(decl_38524, type, 'fertility-scale': $i).
% 29.22/29.03  tff(decl_38525, type, 'Fertility-Value': $i).
% 29.22/29.03  tff(decl_38526, type, fecundity: $i).
% 29.22/29.03  tff(decl_38527, type, fertility: $i).
% 29.22/29.03  tff(decl_38528, type, 'value of fertility': $i).
% 29.22/29.03  tff(decl_38529, type, 'fertility value': $i).
% 29.22/29.03  tff(decl_38530, type, 'fertility-value': $i).
% 29.22/29.03  tff(decl_38531, type, 'Fertilization': $i).
% 29.22/29.03  tff(decl_38532, type, '(1) The fusing of haploid gametes to form a diploid zygote. (2) The addition of nutrients to the soil, to promote plant growth.': $i).
% 29.22/29.03  tff(decl_38533, type, syngamy: $i).
% 29.22/29.03  tff(decl_38534, type, fertilization: $i).
% 29.22/29.03  tff(decl_38535, type, fn_fertilization_3: $i > $i).
% 29.22/29.03  tff(decl_38536, type, fn_fertilization_4: $i > $i).
% 29.22/29.03  tff(decl_38537, type, fn_fertilization_5: $i > $i).
% 29.22/29.03  tff(decl_38538, type, fn_fertilization_7: $i > $i).
% 29.22/29.03  tff(decl_38539, type, fn_fertilization_8: $i > $i).
% 29.22/29.03  tff(decl_38540, type, fn_fertilization_6: $i > $i).
% 29.22/29.03  tff(decl_38541, type, fn_fertilization_9: $i > $i).
% 29.22/29.03  tff(decl_38542, type, 'Fertilization-Envelope': $i).
% 29.22/29.03  tff(decl_38543, type, 'The protective layer formed when the vitelline layer of an egg is pushed away from the plasma membrane and hardened after fertilization by molecules exocytosed during the cortical reaction. The fertilization envelope is the slow block to polyspermy.': $i).
% 29.22/29.03  tff(decl_38544, type, 'envelope of fertilization': $i).
% 29.22/29.03  tff(decl_38545, type, 'fertilization envelope': $i).
% 29.22/29.03  tff(decl_38546, type, 'fertilization-envelope': $i).
% 29.22/29.03  tff(decl_38547, type, fertilizer_1: $i > $o).
% 29.22/29.03  tff(decl_38548, type, 'Fertilizer': $i).
% 29.22/29.03  tff(decl_38549, type, 'Any substance such as manure or a mixture of nitrates used to make soil more fertile.': $i).
% 29.22/29.03  tff(decl_38550, type, fertilizer: $i).
% 29.22/29.03  tff(decl_38551, type, 'agricultural fertilizer': $i).
% 29.22/29.03  tff(decl_38552, type, 'agricultural-fertilizer': $i).
% 29.22/29.03  tff(decl_38553, type, 'Fetal-Stage': $i).
% 29.22/29.03  tff(decl_38554, type, 'A developing mammal that has all the major structures of an adult. In humans, the fetal stage lasts from the 9th week of gestation until birth.': $i).
% 29.22/29.03  tff(decl_38555, type, 'fetal stage': $i).
% 29.22/29.03  tff(decl_38556, type, 'fetal-stage': $i).
% 29.22/29.03  tff(decl_38557, type, 'Fetal-Testing': $i).
% 29.22/29.03  tff(decl_38558, type, 'The process of determing genetic information from a fetus, such as genetic abnormalities.': $i).
% 29.22/29.03  tff(decl_38559, type, 'fetal testing': $i).
% 29.22/29.03  tff(decl_38560, type, 'fetal-testing': $i).
% 29.22/29.03  tff(decl_38561, type, fn_fetal_testing_1: $i > $i).
% 29.22/29.03  tff(decl_38562, type, fn_fetal_testing_2: $i > $i).
% 29.22/29.03  tff(decl_38563, type, fn_fetal_testing_3: $i > $i).
% 29.22/29.03  tff(decl_38564, type, fn_fetal_testing_4: $i > $i).
% 29.22/29.03  tff(decl_38565, type, fn_fetal_testing_5: $i > $i).
% 29.22/29.03  tff(decl_38566, type, fn_fetal_testing_6: $i > $i).
% 29.22/29.03  tff(decl_38567, type, fn_fetal_testing_7: $i > $i).
% 29.22/29.03  tff(decl_38568, type, fn_fetal_testing_8: $i > $i).
% 29.22/29.03  tff(decl_38569, type, fn_fetal_testing_9: $i > $i).
% 29.22/29.03  tff(decl_38570, type, fn_fetal_testing_10: $i > $i).
% 29.22/29.03  tff(decl_38571, type, fn_fetal_testing_11: $i > $i).
% 29.22/29.03  tff(decl_38572, type, fn_fetal_testing_12: $i > $i).
% 29.22/29.03  tff(decl_38573, type, genetic_disorder_1: $i > $o).
% 29.22/29.03  tff(decl_38574, type, fn_fetal_testing_13: $i > $i).
% 29.22/29.03  tff(decl_38575, type, 'Fetoscopy': $i).
% 29.22/29.03  tff(decl_38576, type, 'Technique for using fiber optics to examine a fetus in the uterus.': $i).
% 29.22/29.03  tff(decl_38577, type, fetoscopy: $i).
% 29.22/29.03  tff(decl_38578, type, 'Fetus': $i).
% 29.22/29.03  tff(decl_38579, type, fetus: $i).
% 29.22/29.03  tff(decl_38580, type, 'Fetus-Cell': $i).
% 29.22/29.03  tff(decl_38581, type, 'Cell of unborn offspring.': $i).
% 29.22/29.03  tff(decl_38582, type, 'cell of a fetus': $i).
% 29.22/29.03  tff(decl_38583, type, 'cell-of-a-fetus': $i).
% 29.22/29.03  tff(decl_38584, type, 'cell of fetus': $i).
% 29.22/29.03  tff(decl_38585, type, 'fetus cell': $i).
% 29.22/29.03  tff(decl_38586, type, 'fetus-cell': $i).
% 29.22/29.03  tff(decl_38587, type, fever_1: $i > $o).
% 29.22/29.03  tff(decl_38588, type, 'Fever': $i).
% 29.22/29.03  tff(decl_38589, type, 'A systemic response to infection in which the body\\s thermostat is set at a higher temperature.': $i).
% 29.22/29.03  tff(decl_38590, type, 'have fever': $i).
% 29.22/29.03  tff(decl_38591, type, fever: $i).
% 29.22/29.03  tff(decl_38592, type, 'Fiber': $i).
% 29.22/29.03  tff(decl_38593, type, 'Fiber is a class of materials that are continuous filaments or are in discrete elongated pieces, similar to lengths of thread. They are very important in the biology of both plants and animals, for holding tissues together.': $i).
% 29.22/29.03  tff(decl_38594, type, fibre: $i).
% 29.22/29.03  tff(decl_38595, type, fiber: $i).
% 29.22/29.03  tff(decl_38596, type, 'Fiber-Cell': $i).
% 29.22/29.03  tff(decl_38597, type, 'A type of long, slender sclerenchyma cell that typically occurs in bundles and provides mechanical support to the plant.': $i).
% 29.22/29.03  tff(decl_38598, type, 'cell of fiber': $i).
% 29.22/29.03  tff(decl_38599, type, 'fiber cell': $i).
% 29.22/29.03  tff(decl_38600, type, 'fiber-cell': $i).
% 29.22/29.03  tff(decl_38601, type, 'Fibrin': $i).
% 29.22/29.03  tff(decl_38602, type, 'The activated form of the blood-clotting protein fibrinogen. Fibrin aggregates into threads that form the fabric of the clot.': $i).
% 29.22/29.03  tff(decl_38603, type, fibrin: $i).
% 29.22/29.03  tff(decl_38604, type, filament_protein_1: $i > $o).
% 29.22/29.03  tff(decl_38605, type, 'Fibroblast': $i).
% 29.22/29.03  tff(decl_38606, type, 'A type of cell that synthesizes the extracellular matrix and collagen of loose connective tissue.': $i).
% 29.22/29.03  tff(decl_38607, type, fibroblast: $i).
% 29.22/29.03  tff(decl_38608, type, fn_fibroblast_1: $i > $i).
% 29.22/29.03  tff(decl_38609, type, fn_fibroblast_2: $i > $i).
% 29.22/29.03  tff(decl_38610, type, fn_fibroblast_3: $i > $i).
% 29.22/29.03  tff(decl_38611, type, pdgf_receptor_1: $i > $o).
% 29.22/29.03  tff(decl_38612, type, fn_fibroblast_4: $i > $i).
% 29.22/29.03  tff(decl_38613, type, fn_fibroblast_5: $i > $i).
% 29.22/29.03  tff(decl_38614, type, fn_fibroblast_6: $i > $i).
% 29.22/29.03  tff(decl_38615, type, fn_fibroblast_7: $i > $i).
% 29.22/29.03  tff(decl_38616, type, fn_fibroblast_8: $i > $i).
% 29.22/29.03  tff(decl_38617, type, fn_fibroblast_9: $i > $i).
% 29.22/29.03  tff(decl_38618, type, fn_fibroblast_10: $i > $i).
% 29.22/29.03  tff(decl_38619, type, fn_fibroblast_11: $i > $i).
% 29.22/29.03  tff(decl_38620, type, fn_fibroblast_12: $i > $i).
% 29.22/29.03  tff(decl_38621, type, fn_fibroblast_13: $i > $i).
% 29.22/29.03  tff(decl_38622, type, fn_fibroblast_14: $i > $i).
% 29.22/29.03  tff(decl_38623, type, fn_fibroblast_15: $i > $i).
% 29.22/29.03  tff(decl_38624, type, fn_fibroblast_16: $i > $i).
% 29.22/29.03  tff(decl_38625, type, fn_fibroblast_17: $i > $i).
% 29.22/29.03  tff(decl_38626, type, fn_fibroblast_18: $i > $i).
% 29.22/29.03  tff(decl_38627, type, fn_fibroblast_19: $i > $i).
% 29.22/29.03  tff(decl_38628, type, fn_fibroblast_20: $i > $i).
% 29.22/29.03  tff(decl_38629, type, fn_fibroblast_21: $i > $i).
% 29.22/29.03  tff(decl_38630, type, fn_fibroblast_22: $i > $i).
% 29.22/29.03  tff(decl_38631, type, fn_fibroblast_23: $i > $i).
% 29.22/29.03  tff(decl_38632, type, fn_fibroblast_24: $i > $i).
% 29.22/29.03  tff(decl_38633, type, fn_fibroblast_25: $i > $i).
% 29.22/29.03  tff(decl_38634, type, fn_fibroblast_26: $i > $i).
% 29.22/29.03  tff(decl_38635, type, fn_fibroblast_27: $i > $i).
% 29.22/29.03  tff(decl_38636, type, fn_fibroblast_28: $i > $i).
% 29.22/29.03  tff(decl_38637, type, fn_fibroblast_29: $i > $i).
% 29.22/29.03  tff(decl_38638, type, fn_fibroblast_30: $i > $i).
% 29.22/29.03  tff(decl_38639, type, fn_fibroblast_31: $i > $i).
% 29.22/29.03  tff(decl_38640, type, fn_fibroblast_32: $i > $i).
% 29.22/29.03  tff(decl_38641, type, fn_fibroblast_33: $i > $i).
% 29.22/29.03  tff(decl_38642, type, fn_fibroblast_34: $i > $i).
% 29.22/29.03  tff(decl_38643, type, fn_fibroblast_37: $i > $i).
% 29.22/29.03  tff(decl_38644, type, fn_fibroblast_38: $i > $i).
% 29.22/29.03  tff(decl_38645, type, fn_fibroblast_39: $i > $i).
% 29.22/29.03  tff(decl_38646, type, fn_fibroblast_40: $i > $i).
% 29.22/29.03  tff(decl_38647, type, fn_fibroblast_41: $i > $i).
% 29.22/29.03  tff(decl_38648, type, fn_fibroblast_42: $i > $i).
% 29.22/29.03  tff(decl_38649, type, fn_fibroblast_43: $i > $i).
% 29.22/29.03  tff(decl_38650, type, fn_fibroblast_44: $i > $i).
% 29.22/29.03  tff(decl_38651, type, fn_fibroblast_45: $i > $i).
% 29.22/29.03  tff(decl_38652, type, fn_phospholipid_bilayer_2: $i > $i).
% 29.22/29.03  tff(decl_38653, type, fn_phospholipid_bilayer_55: $i > $i).
% 29.22/29.03  tff(decl_38654, type, fn_phospholipid_bilayer_46: $i > $i).
% 29.22/29.03  tff(decl_38655, type, fn_phospholipid_bilayer_44: $i > $i).
% 29.22/29.03  tff(decl_38656, type, fn_phospholipid_bilayer_1: $i > $i).
% 29.22/29.03  tff(decl_38657, type, 'P3': $i).
% 29.22/29.03  tff(decl_38658, type, fn_fibroblast_35: $i > $i).
% 29.22/29.03  tff(decl_38659, type, fn_fibroblast_36: $i > $i).
% 29.22/29.03  tff(decl_38660, type, fibroblast_division_1: $i > $o).
% 29.22/29.03  tff(decl_38661, type, 'Fibroblast-Division': $i).
% 29.22/29.03  tff(decl_38662, type, 'Process of cell division in fibroblasts, specialized cells which produce collagen.': $i).
% 29.22/29.03  tff(decl_38663, type, 'division of fibroblast': $i).
% 29.22/29.03  tff(decl_38664, type, 'fibroblast division': $i).
% 29.22/29.03  tff(decl_38665, type, 'fibroblast-division': $i).
% 29.22/29.03  tff(decl_38666, type, fn_fibroblast_division_1: $i > $i).
% 29.22/29.03  tff(decl_38667, type, fn_fibroblast_division_2: $i > $i).
% 29.22/29.03  tff(decl_38668, type, fn_fibroblast_division_3: $i > $i).
% 29.22/29.03  tff(decl_38669, type, 'Fibronectin': $i).
% 29.22/29.03  tff(decl_38670, type, 'A glycoprotein that helps animal cells attach to the extracellular matrix.': $i).
% 29.22/29.03  tff(decl_38671, type, fibronectin: $i).
% 29.22/29.03  tff(decl_38672, type, fn_fibronectin_1: $i > $i).
% 29.22/29.03  tff(decl_38673, type, fn_fibronectin_2: $i > $i).
% 29.22/29.03  tff(decl_38674, type, fn_fibronectin_3: $i > $i).
% 29.22/29.03  tff(decl_38675, type, fn_fibronectin_4: $i > $i).
% 29.22/29.03  tff(decl_38676, type, fn_fibronectin_5: $i > $i).
% 29.22/29.03  tff(decl_38677, type, fn_fibronectin_6: $i > $i).
% 29.22/29.03  tff(decl_38678, type, fn_fibronectin_7: $i > $i).
% 29.22/29.03  tff(decl_38679, type, fn_fibronectin_8: $i > $i).
% 29.22/29.03  tff(decl_38680, type, fn_fibronectin_9: $i > $i).
% 29.22/29.03  tff(decl_38681, type, fn_fibronectin_10: $i > $i).
% 29.22/29.03  tff(decl_38682, type, fn_fibronectin_11: $i > $i).
% 29.22/29.03  tff(decl_38683, type, fn_fibronectin_12: $i > $i).
% 29.22/29.03  tff(decl_38684, type, fn_fibronectin_17: $i > $i).
% 29.22/29.03  tff(decl_38685, type, fn_fibronectin_18: $i > $i).
% 29.22/29.03  tff(decl_38686, type, fn_fibronectin_19: $i > $i).
% 29.22/29.03  tff(decl_38687, type, fn_fibronectin_20: $i > $i).
% 29.22/29.03  tff(decl_38688, type, fn_fibronectin_21: $i > $i).
% 29.22/29.03  tff(decl_38689, type, fn_fibronectin_22: $i > $i).
% 29.22/29.03  tff(decl_38690, type, fn_fibronectin_23: $i > $i).
% 29.22/29.03  tff(decl_38691, type, fn_fibronectin_24: $i > $i).
% 29.22/29.03  tff(decl_38692, type, fn_fibronectin_25: $i > $i).
% 29.22/29.03  tff(decl_38693, type, fn_fibronectin_26: $i > $i).
% 29.22/29.03  tff(decl_38694, type, fn_fibronectin_27: $i > $i).
% 29.22/29.03  tff(decl_38695, type, fn_fibronectin_28: $i > $i).
% 29.22/29.03  tff(decl_38696, type, fn_fibronectin_29: $i > $i).
% 29.22/29.03  tff(decl_38697, type, fn_fibronectin_30: $i > $i).
% 29.22/29.03  tff(decl_38698, type, fn_fibronectin_31: $i > $i).
% 29.22/29.03  tff(decl_38699, type, fn_fibronectin_32: $i > $i).
% 29.22/29.03  tff(decl_38700, type, fn_fibronectin_33: $i > $i).
% 29.22/29.03  tff(decl_38701, type, fn_fibronectin_34: $i > $i).
% 29.22/29.03  tff(decl_38702, type, fn_fibronectin_35: $i > $i).
% 29.22/29.03  tff(decl_38703, type, fn_fibronectin_36: $i > $i).
% 29.22/29.03  tff(decl_38704, type, fn_fibronectin_38: $i > $i).
% 29.22/29.03  tff(decl_38705, type, fn_fibronectin_39: $i > $i).
% 29.22/29.03  tff(decl_38706, type, fn_fibronectin_40: $i > $i).
% 29.22/29.03  tff(decl_38707, type, fn_fibronectin_41: $i > $i).
% 29.22/29.03  tff(decl_38708, type, fn_fibronectin_42: $i > $i).
% 29.22/29.03  tff(decl_38709, type, fn_fibronectin_43: $i > $i).
% 29.22/29.03  tff(decl_38710, type, fn_fibronectin_46: $i > $i).
% 29.22/29.03  tff(decl_38711, type, fn_fibronectin_48: $i > $i).
% 29.22/29.03  tff(decl_38712, type, fn_fibronectin_49: $i > $i).
% 29.22/29.03  tff(decl_38713, type, fn_fibronectin_50: $i > $i).
% 29.22/29.03  tff(decl_38714, type, fn_fibronectin_51: $i > $i).
% 29.22/29.03  tff(decl_38715, type, fn_fibronectin_52: $i > $i).
% 29.22/29.03  tff(decl_38716, type, fn_fibronectin_54: $i > $i).
% 29.22/29.03  tff(decl_38717, type, fn_fibronectin_55: $i > $i).
% 29.22/29.03  tff(decl_38718, type, fn_fibronectin_56: $i > $i).
% 29.22/29.03  tff(decl_38719, type, fn_integral_protein_11: $i > $i).
% 29.22/29.03  tff(decl_38720, type, fn_protein_11: $i > $i).
% 29.22/29.03  tff(decl_38721, type, fn_fibronectin_16: $i > $i).
% 29.22/29.03  tff(decl_38722, type, fn_fibronectin_15: $i > $i).
% 29.22/29.03  tff(decl_38723, type, fn_fibronectin_14: $i > $i).
% 29.22/29.03  tff(decl_38724, type, fn_fibronectin_13: $i > $i).
% 29.22/29.03  tff(decl_38725, type, 'Fibrous-Connective-Tissue': $i).
% 29.22/29.03  tff(decl_38726, type, 'Dense connective tissue with collagenous fibers organized into parallel bundles (e.g.,  tendons and ligaments). Dense connective tissue usually connects two tissues.': $i).
% 29.22/29.03  tff(decl_38727, type, 'fibrous connective tissue': $i).
% 29.22/29.03  tff(decl_38728, type, 'fibrous-connective-tissue': $i).
% 29.22/29.03  tff(decl_38729, type, 'Fibrous-Protein': $i).
% 29.22/29.03  tff(decl_38730, type, 'Proteins that tend to be insoluble and strong and so play a structural role in organisms for support or protection. Fibrous proteins can be subdivided into several different types: 1.keratins, found in hair, fingernails, and bird feathers 2. collagens the most abundant proteins in a vertebrate body  found in connective tissues such as cartilage 3. elastins, found in ligaments, around blood vessels.': $i).
% 29.22/29.03  tff(decl_38731, type, 'fibrous protein': $i).
% 29.22/29.03  tff(decl_38732, type, 'fibrous-protein': $i).
% 29.22/29.03  tff(decl_38733, type, 'Fibrous-Root': $i).
% 29.22/29.03  tff(decl_38734, type, 'Root system consisting of many small roots, often forming a mat which spreads out vertically and laterally in the soil.': $i).
% 29.22/29.03  tff(decl_38735, type, 'fibrous root': $i).
% 29.22/29.03  tff(decl_38736, type, 'fibrous-root': $i).
% 29.22/29.03  tff(decl_38737, type, fidget_1: $i > $o).
% 29.22/29.03  tff(decl_38738, type, 'Fidget': $i).
% 29.22/29.03  tff(decl_38739, type, fidget: $i).
% 29.22/29.03  tff(decl_38740, type, orient_1: $i > $o).
% 29.22/29.03  tff(decl_38741, type, stand_up_1: $i > $o).
% 29.22/29.03  tff(decl_38742, type, sit_down_1: $i > $o).
% 29.22/29.03  tff(decl_38743, type, gesticulate_1: $i > $o).
% 29.22/29.03  tff(decl_38744, type, fn_fidget_1: $i > $i).
% 29.22/29.03  tff(decl_38745, type, fight_or_flight_response_1: $i > $o).
% 29.22/29.03  tff(decl_38746, type, 'Fight-Or-Flight-Response': $i).
% 29.22/29.03  tff(decl_38747, type, 'Physiological response to stress in animals in which the body prepares for either aggressive action (fight) or avoidance action (flight) as a response to potential danger or conflict. The response is initiated by adrenaline signaling.': $i).
% 29.22/29.03  tff(decl_38748, type, 'fight or flight response': $i).
% 29.22/29.03  tff(decl_38749, type, 'fight-or-flight-response': $i).
% 29.22/29.03  tff(decl_38750, type, fn_fight_or_flight_response_1: $i > $i).
% 29.22/29.03  tff(decl_38751, type, stimulus_generation_1: $i > $o).
% 29.22/29.03  tff(decl_38752, type, fn_fight_or_flight_response_2: $i > $i).
% 29.22/29.03  tff(decl_38753, type, fn_fight_or_flight_response_3: $i > $i).
% 29.22/29.03  tff(decl_38754, type, fn_fight_or_flight_response_4: $i > $i).
% 29.22/29.03  tff(decl_38755, type, fn_fight_or_flight_response_5: $i > $i).
% 29.22/29.03  tff(decl_38756, type, fn_fight_or_flight_response_6: $i > $i).
% 29.22/29.03  tff(decl_38757, type, fn_fight_or_flight_response_7: $i > $i).
% 29.22/29.03  tff(decl_38758, type, fn_fight_or_flight_response_8: $i > $i).
% 29.22/29.03  tff(decl_38759, type, fn_fight_or_flight_response_9: $i > $i).
% 29.22/29.03  tff(decl_38760, type, fn_fight_or_flight_response_10: $i > $i).
% 29.22/29.03  tff(decl_38761, type, fn_fight_or_flight_response_11: $i > $i).
% 29.22/29.03  tff(decl_38762, type, fn_fight_or_flight_response_12: $i > $i).
% 29.22/29.03  tff(decl_38763, type, fn_fight_or_flight_response_13: $i > $i).
% 29.22/29.03  tff(decl_38764, type, fn_fight_or_flight_response_14: $i > $i).
% 29.22/29.03  tff(decl_38765, type, fn_fight_or_flight_response_15: $i > $i).
% 29.22/29.03  tff(decl_38766, type, fn_fight_or_flight_response_16: $i > $i).
% 29.22/29.03  tff(decl_38767, type, fn_fight_or_flight_response_17: $i > $i).
% 29.22/29.03  tff(decl_38768, type, fn_fight_or_flight_response_18: $i > $i).
% 29.22/29.03  tff(decl_38769, type, fn_fight_or_flight_response_19: $i > $i).
% 29.22/29.03  tff(decl_38770, type, fn_fight_or_flight_response_20: $i > $i).
% 29.22/29.03  tff(decl_38771, type, fn_fight_or_flight_response_21: $i > $i).
% 29.22/29.03  tff(decl_38772, type, fn_fight_or_flight_response_22: $i > $i).
% 29.22/29.03  tff(decl_38773, type, fn_fight_or_flight_response_23: $i > $i).
% 29.22/29.03  tff(decl_38774, type, fn_fight_or_flight_response_24: $i > $i).
% 29.22/29.03  tff(decl_38775, type, fn_fight_or_flight_response_25: $i > $i).
% 29.22/29.03  tff(decl_38776, type, fn_fight_or_flight_response_26: $i > $i).
% 29.22/29.03  tff(decl_38777, type, fn_fight_or_flight_response_28: $i > $i).
% 29.22/29.03  tff(decl_38778, type, fn_fight_or_flight_response_29: $i > $i).
% 29.22/29.03  tff(decl_38779, type, fn_fight_or_flight_response_30: $i > $i).
% 29.22/29.03  tff(decl_38780, type, fn_fight_or_flight_response_31: $i > $i).
% 29.22/29.03  tff(decl_38781, type, mobilization_of_fuel_reserve_1: $i > $o).
% 29.22/29.03  tff(decl_38782, type, fn_fight_or_flight_response_32: $i > $i).
% 29.22/29.03  tff(decl_38783, type, fn_fight_or_flight_response_33: $i > $i).
% 29.22/29.03  tff(decl_38784, type, fn_fight_or_flight_response_34: $i > $i).
% 29.22/29.03  tff(decl_38785, type, fn_fight_or_flight_response_35: $i > $i).
% 29.22/29.03  tff(decl_38786, type, fn_fight_or_flight_response_36: $i > $i).
% 29.22/29.03  tff(decl_38787, type, fn_fight_or_flight_response_37: $i > $i).
% 29.22/29.03  tff(decl_38788, type, fn_fight_or_flight_response_38: $i > $i).
% 29.22/29.03  tff(decl_38789, type, fn_fight_or_flight_response_39: $i > $i).
% 29.22/29.03  tff(decl_38790, type, fn_mobilization_of_fuel_reserve_3: $i > $i).
% 29.22/29.03  tff(decl_38791, type, fn_cell_communication_with_epinephrine_in_liver_cell_38: $i > $i).
% 29.22/29.03  tff(decl_38792, type, fn_cell_communication_with_epinephrine_in_liver_cell_37: $i > $i).
% 29.22/29.03  tff(decl_38793, type, fn_cell_communication_with_epinephrine_in_liver_cell_36: $i > $i).
% 29.22/29.03  tff(decl_38794, type, fn_mobilization_of_fuel_reserve_4: $i > $i).
% 29.22/29.03  tff(decl_38795, type, fn_fight_or_flight_response_40: $i > $i).
% 29.22/29.03  tff(decl_38796, type, fn_fight_or_flight_response_41: $i > $i).
% 29.22/29.03  tff(decl_38797, type, fn_fight_or_flight_response_27: $i > $i).
% 29.22/29.03  tff(decl_38798, type, fight_or_flight_response_leading_to_fight_1: $i > $o).
% 29.22/29.03  tff(decl_38799, type, 'Fight-Or-Flight-Response-Leading-To-Fight': $i).
% 29.22/29.03  tff(decl_38800, type, 'Physiological response to stress in animals resulting in aggresive action (fight) as a response to potential danger or conflict. The response is initiated by adrenaline signaling.': $i).
% 29.22/29.03  tff(decl_38801, type, 'fight or flight response leading to fight': $i).
% 29.22/29.03  tff(decl_38802, type, 'fight-or-flight-response-leading-to-fight': $i).
% 29.22/29.03  tff(decl_38803, type, fn_fight_or_flight_response_leading_to_fight_1: $i > $i).
% 29.22/29.03  tff(decl_38804, type, fn_fight_or_flight_response_leading_to_fight_2: $i > $i).
% 29.22/29.03  tff(decl_38805, type, fn_fight_or_flight_response_leading_to_fight_3: $i > $i).
% 29.22/29.03  tff(decl_38806, type, fn_fight_or_flight_response_leading_to_fight_4: $i > $i).
% 29.22/29.03  tff(decl_38807, type, fight_or_flight_response_leading_to_flight_1: $i > $o).
% 29.22/29.03  tff(decl_38808, type, 'Fight-Or-Flight-Response-Leading-To-Flight': $i).
% 29.22/29.03  tff(decl_38809, type, 'Physiological response to stress in animals resulting in avoidance action (flight) as a response to potential danger or conflict. The response is initiated by adrenaline signaling.': $i).
% 29.22/29.03  tff(decl_38810, type, 'fight or flight response leading to flight': $i).
% 29.22/29.03  tff(decl_38811, type, 'fight-or-flight-response-leading-to-flight': $i).
% 29.22/29.03  tff(decl_38812, type, fn_fight_or_flight_response_leading_to_flight_1: $i > $i).
% 29.22/29.03  tff(decl_38813, type, fn_fight_or_flight_response_leading_to_flight_2: $i > $i).
% 29.22/29.03  tff(decl_38814, type, fn_fight_or_flight_response_leading_to_flight_3: $i > $i).
% 29.22/29.03  tff(decl_38815, type, fn_fight_or_flight_response_leading_to_flight_4: $i > $i).
% 29.22/29.04  tff(decl_38816, type, fn_fight_or_flight_response_leading_to_flight_5: $i > $i).
% 29.22/29.04  tff(decl_38817, type, 'Filament-Protein': $i).
% 29.22/29.04  tff(decl_38818, type, 'A long chain of protein subunits.': $i).
% 29.22/29.04  tff(decl_38819, type, filament: $i).
% 29.22/29.04  tff(decl_38820, type, 'protein of filament': $i).
% 29.22/29.04  tff(decl_38821, type, 'filament protein': $i).
% 29.22/29.04  tff(decl_38822, type, 'filament-protein': $i).
% 29.22/29.04  tff(decl_38823, type, filter_1: $i > $o).
% 29.22/29.04  tff(decl_38824, type, 'Filter': $i).
% 29.22/29.04  tff(decl_38825, type, filter: $i).
% 29.22/29.04  tff(decl_38826, type, fn_filter_1: $i > $i).
% 29.22/29.04  tff(decl_38827, type, filter_feeder_1: $i > $o).
% 29.22/29.04  tff(decl_38828, type, 'Filter-Feeder': $i).
% 29.22/29.04  tff(decl_38829, type, 'Type of suspension feeder which actively filters food particles from water with specialized filtering structures.': $i).
% 29.22/29.04  tff(decl_38830, type, 'feeder of filter': $i).
% 29.22/29.04  tff(decl_38831, type, 'filter feeder': $i).
% 29.22/29.04  tff(decl_38832, type, 'filter-feeder': $i).
% 29.22/29.04  tff(decl_38833, type, suspension_feeder_1: $i > $o).
% 29.22/29.04  tff(decl_38834, type, fn_filter_feeder_1: $i > $i).
% 29.22/29.04  tff(decl_38835, type, fn_filter_feeder_2: $i > $i).
% 29.22/29.04  tff(decl_38836, type, fn_filter_feeder_3: $i > $i).
% 29.22/29.04  tff(decl_38837, type, fn_filter_feeder_4: $i > $i).
% 29.22/29.04  tff(decl_38838, type, fn_filter_feeder_5: $i > $i).
% 29.22/29.04  tff(decl_38839, type, fn_filter_feeder_6: $i > $i).
% 29.22/29.04  tff(decl_38840, type, fn_filter_feeder_7: $i > $i).
% 29.22/29.04  tff(decl_38841, type, fn_filter_feeder_8: $i > $i).
% 29.22/29.04  tff(decl_38842, type, fn_filter_feeder_9: $i > $i).
% 29.22/29.04  tff(decl_38843, type, fn_filter_feeder_10: $i > $i).
% 29.22/29.04  tff(decl_38844, type, fn_filter_feeder_11: $i > $i).
% 29.22/29.04  tff(decl_38845, type, fn_filter_feeder_12: $i > $i).
% 29.22/29.04  tff(decl_38846, type, fn_filter_feeder_13: $i > $i).
% 29.22/29.04  tff(decl_38847, type, fn_filter_feeder_14: $i > $i).
% 29.22/29.04  tff(decl_38848, type, fn_filter_feeder_15: $i > $i).
% 29.22/29.04  tff(decl_38849, type, fn_filter_feeder_16: $i > $i).
% 29.22/29.04  tff(decl_38850, type, fn_suspension_feeder_1: $i > $i).
% 29.22/29.04  tff(decl_38851, type, fn_suspension_feeder_3: $i > $i).
% 29.22/29.04  tff(decl_38852, type, fn_suspension_feeder_4: $i > $i).
% 29.22/29.04  tff(decl_38853, type, fn_suspension_feeder_5: $i > $i).
% 29.22/29.04  tff(decl_38854, type, fn_suspension_feeder_2: $i > $i).
% 29.22/29.04  tff(decl_38855, type, 'Filtrate': $i).
% 29.22/29.04  tff(decl_38856, type, 'Acellular liquid collected from body fluid and disposed of by the excretory system.': $i).
% 29.22/29.04  tff(decl_38857, type, filtrate: $i).
% 29.22/29.04  tff(decl_38858, type, filtration_1: $i > $o).
% 29.22/29.04  tff(decl_38859, type, 'Filtration': $i).
% 29.22/29.04  tff(decl_38860, type, 'In animals with excretory systems, the collection of water and small solute molecules, including metabolic wastes, from the fluids of the body.': $i).
% 29.22/29.04  tff(decl_38861, type, filtration: $i).
% 29.22/29.04  tff(decl_38862, type, 'Fimbria': $i).
% 29.22/29.04  tff(decl_38863, type, 'A short, hairlike appendage of a prokaryotic cell that helps it adhere to the substrate or to other cells; also known as an attachment pilus.': $i).
% 29.22/29.04  tff(decl_38864, type, fimbria: $i).
% 29.22/29.04  tff(decl_38865, type, prokaryotic_cell_structure_1: $i > $o).
% 29.22/29.04  tff(decl_38866, type, fn_fimbria_1: $i > $i).
% 29.22/29.04  tff(decl_38867, type, fn_fimbria_2: $i > $i).
% 29.22/29.04  tff(decl_38868, type, fn_fimbria_3: $i > $i).
% 29.22/29.04  tff(decl_38869, type, fn_fimbria_4: $i > $i).
% 29.22/29.04  tff(decl_38870, type, fn_fimbria_5: $i > $i).
% 29.22/29.04  tff(decl_38871, type, fn_fimbria_6: $i > $i).
% 29.22/29.04  tff(decl_38872, type, fn_fimbria_7: $i > $i).
% 29.22/29.04  tff(decl_38873, type, fn_fimbria_8: $i > $i).
% 29.22/29.04  tff(decl_38874, type, fin_1: $i > $o).
% 29.22/29.04  tff(decl_38875, type, 'Fin': $i).
% 29.22/29.04  tff(decl_38876, type, 'An organ of locomotion and balance in fishes and other aquatic animals.': $i).
% 29.22/29.04  tff(decl_38877, type, fin: $i).
% 29.22/29.04  tff(decl_38878, type, 'Final-Electron-Acceptor': $i).
% 29.22/29.04  tff(decl_38879, type, 'The molecule which accepts the electron at the end of an electron transport chain.': $i).
% 29.22/29.04  tff(decl_38880, type, 'final electron acceptor': $i).
% 29.22/29.04  tff(decl_38881, type, 'final-electron-acceptor': $i).
% 29.22/29.04  tff(decl_38882, type, financing_1: $i > $o).
% 29.22/29.04  tff(decl_38883, type, 'Financing': $i).
% 29.22/29.04  tff(decl_38884, type, funding: $i).
% 29.22/29.04  tff(decl_38885, type, financing: $i).
% 29.22/29.04  tff(decl_38886, type, finance: $i).
% 29.22/29.04  tff(decl_38887, type, finger_1: $i > $o).
% 29.22/29.04  tff(decl_38888, type, 'Finger': $i).
% 29.22/29.04  tff(decl_38889, type, 'A finger is a limb of the human body and a type of digit, an organ of manipulation and sensation found in the hands of humans and other primates.': $i).
% 29.22/29.04  tff(decl_38890, type, finger: $i).
% 29.22/29.04  tff(decl_38891, type, 'First-Electron-Shell': $i).
% 29.22/29.04  tff(decl_38892, type, 'The first energy shell of an atom, containing the valence electrons involved in the chemical reactions of that atom.': $i).
% 29.22/29.04  tff(decl_38893, type, 'first electron shell': $i).
% 29.22/29.04  tff(decl_38894, type, 'first electron-shell': $i).
% 29.22/29.04  tff(decl_38895, type, 'first-electron-shell': $i).
% 29.22/29.04  tff(decl_38896, type, third_electron_shell_1: $i > $o).
% 29.22/29.04  tff(decl_38897, type, first_law_thermodynamics_1: $i > $o).
% 29.22/29.04  tff(decl_38898, type, 'First-Law-Thermodynamics': $i).
% 29.22/29.04  tff(decl_38899, type, 'The law of conservation of energy, which states that the amount of energy in the universe is constant. Energy can be transferred from one form to another but can be neither created nor destroyed.': $i).
% 29.22/29.04  tff(decl_38900, type, 'principle of conservation of energy': $i).
% 29.22/29.04  tff(decl_38901, type, 'principle-of-conservation-of-energy': $i).
% 29.22/29.04  tff(decl_38902, type, 'first law of thermodynamics': $i).
% 29.22/29.04  tff(decl_38903, type, 'first-law-of-thermodynamics': $i).
% 29.22/29.04  tff(decl_38904, type, 'first law thermodynamics': $i).
% 29.22/29.04  tff(decl_38905, type, 'first-law-thermodynamic': $i).
% 29.22/29.04  tff(decl_38906, type, mendelian_law_1: $i > $o).
% 29.22/29.04  tff(decl_38907, type, rule_of_probability_1: $i > $o).
% 29.22/29.04  tff(decl_38908, type, second_law_thermodynamics_1: $i > $o).
% 29.22/29.04  tff(decl_38909, type, 'Fish': $i).
% 29.22/29.04  tff(decl_38910, type, 'A member of a paraphyletic group of aquatic animals that breathe with gills and have limbs that lack digits. Many have bodies covered with scales and most are ectothermic.': $i).
% 29.22/29.04  tff(decl_38911, type, fish: $i).
% 29.22/29.04  tff(decl_38912, type, fn_fish_1: $i > $i).
% 29.22/29.04  tff(decl_38913, type, fn_fish_3: $i > $i).
% 29.22/29.04  tff(decl_38914, type, fn_fish_4: $i > $i).
% 29.22/29.04  tff(decl_38915, type, omega_3_fatty_acid_1: $i > $o).
% 29.22/29.04  tff(decl_38916, type, fn_fish_5: $i > $i).
% 29.22/29.04  tff(decl_38917, type, fn_fish_6: $i > $i).
% 29.22/29.04  tff(decl_38918, type, fn_fish_7: $i > $i).
% 29.22/29.04  tff(decl_38919, type, fn_fish_8: $i > $i).
% 29.22/29.04  tff(decl_38920, type, fn_fish_9: $i > $i).
% 29.22/29.04  tff(decl_38921, type, fn_fish_10: $i > $i).
% 29.22/29.04  tff(decl_38922, type, fn_fish_11: $i > $i).
% 29.22/29.04  tff(decl_38923, type, fn_fish_12: $i > $i).
% 29.22/29.04  tff(decl_38924, type, fn_fish_13: $i > $i).
% 29.22/29.04  tff(decl_38925, type, fn_fish_14: $i > $i).
% 29.22/29.04  tff(decl_38926, type, fn_fish_15: $i > $i).
% 29.22/29.04  tff(decl_38927, type, fn_fish_16: $i > $i).
% 29.22/29.04  tff(decl_38928, type, fn_fish_17: $i > $i).
% 29.22/29.04  tff(decl_38929, type, fn_fish_18: $i > $i).
% 29.22/29.04  tff(decl_38930, type, fn_fish_19: $i > $i).
% 29.22/29.04  tff(decl_38931, type, fn_fish_20: $i > $i).
% 29.22/29.04  tff(decl_38932, type, fn_fish_21: $i > $i).
% 29.22/29.04  tff(decl_38933, type, fn_fish_22: $i > $i).
% 29.22/29.04  tff(decl_38934, type, fn_fish_23: $i > $i).
% 29.22/29.04  tff(decl_38935, type, fn_fish_24: $i > $i).
% 29.22/29.04  tff(decl_38936, type, fn_fish_25: $i > $i).
% 29.22/29.04  tff(decl_38937, type, fn_fish_26: $i > $i).
% 29.22/29.04  tff(decl_38938, type, fn_fish_27: $i > $i).
% 29.22/29.04  tff(decl_38939, type, fn_fish_28: $i > $i).
% 29.22/29.04  tff(decl_38940, type, esophagus_0: $i).
% 29.22/29.04  tff(decl_38941, type, fn_vertebrate_42: $i > $i).
% 29.22/29.04  tff(decl_38942, type, 'Fish-Fat': $i).
% 29.22/29.04  tff(decl_38943, type, 'The unsaturated fat obtained from fish is called fish fat.': $i).
% 29.22/29.04  tff(decl_38944, type, 'fat of fish': $i).
% 29.22/29.04  tff(decl_38945, type, 'fish fat': $i).
% 29.22/29.04  tff(decl_38946, type, 'fish-fat': $i).
% 29.22/29.04  tff(decl_38947, type, unsaturated_fat_1: $i > $o).
% 29.22/29.04  tff(decl_38948, type, trans_fat_1: $i > $o).
% 29.22/29.04  tff(decl_38949, type, fish_homeotic_gene_1: $i > $o).
% 29.22/29.04  tff(decl_38950, type, 'Fish-Homeotic-Gene': $i).
% 29.22/29.04  tff(decl_38951, type, 'Homeotic gene present in fish.': $i).
% 29.22/29.04  tff(decl_38952, type, 'fish homeotic gene': $i).
% 29.22/29.04  tff(decl_38953, type, 'fish-homeotic-gene': $i).
% 29.22/29.04  tff(decl_38954, type, fn_fish_homeotic_gene_1: $i > $i).
% 29.22/29.04  tff(decl_38955, type, fn_fish_homeotic_gene_2: $i > $i).
% 29.22/29.04  tff(decl_38956, type, fission_1: $i > $o).
% 29.22/29.04  tff(decl_38957, type, 'Fission': $i).
% 29.22/29.04  tff(decl_38958, type, 'A form of asexual reproduction in which an animal divides into two approximately equal-sized clonal offspring.': $i).
% 29.22/29.04  tff(decl_38959, type, fission: $i).
% 29.22/29.04  tff(decl_38960, type, 'Five-Kingdom-System': $i).
% 29.22/29.04  tff(decl_38961, type, 'A model that divides all life into five distinct kingdoms - Monera, Protisa, Fungi, Plantae, and Animalia.': $i).
% 29.22/29.04  tff(decl_38962, type, 'five kingdom system': $i).
% 29.22/29.04  tff(decl_38963, type, 'five-kingdom system': $i).
% 29.22/29.04  tff(decl_38964, type, 'five-kingdom-system': $i).
% 29.22/29.04  tff(decl_38965, type, 'Five-Prime-Cap': $i).
% 29.22/29.04  tff(decl_38966, type, 'A modified form of guanine added onto the nucleotide at the 5\\ end of a pre-mRNA molecule.': $i).
% 29.22/29.04  tff(decl_38967, type, '5 prime cap': $i).
% 29.22/29.04  tff(decl_38968, type, '5-prime-cap': $i).
% 29.22/29.04  tff(decl_38969, type, '5\\ cap': $i).
% 29.22/29.04  tff(decl_38970, type, '5\\-cap': $i).
% 29.22/29.04  tff(decl_38971, type, 'five prime cap': $i).
% 29.22/29.04  tff(decl_38972, type, 'five-prime-cap': $i).
% 29.22/29.04  tff(decl_38973, type, fn_five_prime_cap_2: $i > $i).
% 29.22/29.04  tff(decl_38974, type, fn_five_prime_cap_3: $i > $i).
% 29.22/29.04  tff(decl_38975, type, fn_five_prime_cap_4: $i > $i).
% 29.22/29.04  tff(decl_38976, type, fn_five_prime_cap_5: $i > $i).
% 29.22/29.04  tff(decl_38977, type, fn_five_prime_cap_7: $i > $i).
% 29.22/29.04  tff(decl_38978, type, fn_five_prime_cap_8: $i > $i).
% 29.22/29.04  tff(decl_38979, type, fn_five_prime_cap_9: $i > $i).
% 29.22/29.04  tff(decl_38980, type, fn_rna_5: $i > $i).
% 29.22/29.04  tff(decl_38981, type, fn_rna_8: $i > $i).
% 29.22/29.04  tff(decl_38982, type, fn_rna_3: $i > $i).
% 29.22/29.04  tff(decl_38983, type, fn_rna_10: $i > $i).
% 29.22/29.04  tff(decl_38984, type, fn_five_prime_cap_10: $i > $i).
% 29.22/29.04  tff(decl_38985, type, fn_five_prime_cap_11: $i > $i).
% 29.22/29.04  tff(decl_38986, type, fn_five_prime_cap_6: $i > $i).
% 29.22/29.04  tff(decl_38987, type, 'Five-Prime-End-of-mRNA': $i).
% 29.22/29.04  tff(decl_38988, type, 'The end of the RNA molecule which shows the fifth carbon on the ribose.': $i).
% 29.22/29.04  tff(decl_38989, type, 'five prime end of mrna': $i).
% 29.22/29.04  tff(decl_38990, type, 'five-prime-end-of-mrna': $i).
% 29.22/29.04  tff(decl_38991, type, 'Fixation': $i).
% 29.22/29.04  tff(decl_38992, type, 'Chemical process in which molecules are converted to a form which is more usable by organisms.': $i).
% 29.22/29.04  tff(decl_38993, type, fixate: $i).
% 29.22/29.04  tff(decl_38994, type, fixation: $i).
% 29.22/29.04  tff(decl_38995, type, fixed_action_pattern_1: $i > $o).
% 29.22/29.04  tff(decl_38996, type, 'Fixed-Action-Pattern': $i).
% 29.22/29.04  tff(decl_38997, type, 'In ethology, an instinctive behavioral pattern that cannot be broken down into smaller actions and that, once started, goes to completion.': $i).
% 29.22/29.04  tff(decl_38998, type, 'fixed action pattern': $i).
% 29.22/29.04  tff(decl_38999, type, 'fixed-action-pattern': $i).
% 29.22/29.04  tff(decl_39000, type, innate_behavior_1: $i > $o).
% 29.22/29.04  tff(decl_39001, type, flaccid_1: $i > $o).
% 29.22/29.04  tff(decl_39002, type, 'Flaccid': $i).
% 29.22/29.04  tff(decl_39003, type, 'Limp or lacking in stiffness. Said of a plant cell when there is no tendency for water to enter the cell.': $i).
% 29.22/29.04  tff(decl_39004, type, flaccid: $i).
% 29.22/29.04  tff(decl_39005, type, 'Flaccid-Cell': $i).
% 29.22/29.04  tff(decl_39006, type, 'A flaccid cell is a walled cell which has lost turgor pressure due to osmosis and is no longer rigid.': $i).
% 29.22/29.04  tff(decl_39007, type, 'shriveled cell': $i).
% 29.22/29.04  tff(decl_39008, type, 'shriveled-cell': $i).
% 29.22/29.04  tff(decl_39009, type, 'flaccid cell': $i).
% 29.22/29.04  tff(decl_39010, type, 'flaccid-cell': $i).
% 29.22/29.04  tff(decl_39011, type, fn_flaccid_cell_2: $i > $i).
% 29.22/29.04  tff(decl_39012, type, fn_flaccid_cell_3: $i > $i).
% 29.22/29.04  tff(decl_39013, type, fn_flaccid_cell_4: $i > $i).
% 29.22/29.04  tff(decl_39014, type, fn_flaccid_cell_6: $i > $i).
% 29.22/29.04  tff(decl_39015, type, fn_flaccid_cell_7: $i > $i).
% 29.22/29.04  tff(decl_39016, type, fn_flaccid_cell_8: $i > $i).
% 29.22/29.04  tff(decl_39017, type, fn_flaccid_cell_12: $i > $i).
% 29.22/29.04  tff(decl_39018, type, fn_flaccid_cell_13: $i > $i).
% 29.22/29.04  tff(decl_39019, type, fn_flaccid_cell_14: $i > $i).
% 29.22/29.04  tff(decl_39020, type, fn_flaccid_cell_15: $i > $i).
% 29.22/29.04  tff(decl_39021, type, fn_flaccid_cell_16: $i > $i).
% 29.22/29.04  tff(decl_39022, type, fn_flaccid_cell_17: $i > $i).
% 29.22/29.04  tff(decl_39023, type, fn_flaccid_cell_18: $i > $i).
% 29.22/29.04  tff(decl_39024, type, fn_flaccid_cell_19: $i > $i).
% 29.22/29.04  tff(decl_39025, type, fn_flaccid_cell_20: $i > $i).
% 29.22/29.04  tff(decl_39026, type, walled_cell_inside_isotonic_solution_1: $i > $o).
% 29.22/29.04  tff(decl_39027, type, fn_flaccid_cell_21: $i > $i).
% 29.22/29.04  tff(decl_39028, type, fn_flaccid_cell_22: $i > $i).
% 29.22/29.04  tff(decl_39029, type, fn_flaccid_cell_23: $i > $i).
% 29.22/29.04  tff(decl_39030, type, fn_flaccid_cell_24: $i > $i).
% 29.22/29.04  tff(decl_39031, type, fn_flaccid_cell_25: $i > $i).
% 29.22/29.04  tff(decl_39032, type, fn_flaccid_cell_26: $i > $i).
% 29.22/29.04  tff(decl_39033, type, fn_flaccid_cell_27: $i > $i).
% 29.22/29.04  tff(decl_39034, type, fn_flaccid_cell_28: $i > $i).
% 29.22/29.04  tff(decl_39035, type, fn_flaccid_cell_29: $i > $i).
% 29.22/29.04  tff(decl_39036, type, fn_flaccid_cell_30: $i > $i).
% 29.22/29.04  tff(decl_39037, type, fn_flaccid_cell_31: $i > $i).
% 29.22/29.04  tff(decl_39038, type, fn_flaccid_cell_32: $i > $i).
% 29.22/29.04  tff(decl_39039, type, fn_flaccid_cell_33: $i > $i).
% 29.22/29.04  tff(decl_39040, type, fn_flaccid_cell_34: $i > $i).
% 29.22/29.04  tff(decl_39041, type, fn_flaccid_cell_35: $i > $i).
% 29.22/29.04  tff(decl_39042, type, fn_walled_cell_inside_isotonic_solution_16: $i > $i).
% 29.22/29.04  tff(decl_39043, type, fn_flaccid_cell_11: $i > $i).
% 29.22/29.04  tff(decl_39044, type, fn_flaccid_cell_10: $i > $i).
% 29.22/29.04  tff(decl_39045, type, flagellated_cell_1: $i > $o).
% 29.22/29.04  tff(decl_39046, type, 'Flagellated-cell': $i).
% 29.22/29.04  tff(decl_39047, type, 'A cell or one-celled organism that has a flagellum, a long, cellular appendage specialized for locomotion.': $i).
% 29.22/29.04  tff(decl_39048, type, 'cell with a flagellum': $i).
% 29.22/29.04  tff(decl_39049, type, 'cell-with-a-flagellum': $i).
% 29.22/29.04  tff(decl_39050, type, 'flagellated cell': $i).
% 29.22/29.04  tff(decl_39051, type, 'flagellated-cell': $i).
% 29.22/29.04  tff(decl_39052, type, locomotor_cell_1: $i > $o).
% 29.22/29.04  tff(decl_39053, type, fn_flagellated_cell_1: $i > $i).
% 29.22/29.04  tff(decl_39054, type, fn_flagellated_cell_2: $i > $i).
% 29.22/29.04  tff(decl_39055, type, fn_flagellated_cell_3: $i > $i).
% 29.22/29.04  tff(decl_39056, type, fn_flagellated_cell_4: $i > $i).
% 29.22/29.04  tff(decl_39057, type, fn_flagellated_cell_5: $i > $i).
% 29.22/29.04  tff(decl_39058, type, fn_flagellated_cell_6: $i > $i).
% 29.22/29.04  tff(decl_39059, type, fn_flagellated_cell_7: $i > $i).
% 29.22/29.04  tff(decl_39060, type, fn_flagellated_cell_8: $i > $i).
% 29.22/29.04  tff(decl_39061, type, fn_flagellated_cell_9: $i > $i).
% 29.22/29.04  tff(decl_39062, type, fn_flagellated_cell_10: $i > $i).
% 29.22/29.04  tff(decl_39063, type, fn_flagellated_cell_11: $i > $i).
% 29.22/29.04  tff(decl_39064, type, fn_flagellated_cell_12: $i > $i).
% 29.22/29.04  tff(decl_39065, type, fn_flagellated_cell_13: $i > $i).
% 29.22/29.04  tff(decl_39066, type, fn_flagellated_cell_14: $i > $i).
% 29.22/29.04  tff(decl_39067, type, fn_flagellated_cell_15: $i > $i).
% 29.22/29.04  tff(decl_39068, type, fn_flagellated_cell_16: $i > $i).
% 29.22/29.04  tff(decl_39069, type, fn_flagellated_cell_17: $i > $i).
% 29.22/29.04  tff(decl_39070, type, 'Flagellum': $i).
% 29.22/29.04  tff(decl_39071, type, 'A long appendage that protrudes from the cell body of some eukaryotic and prokaryotic cells, specialized for locomotion. A eukaryotic flagellum consists of nine pairs of fused microtubules surrounding two unfused central microtubules.': $i).
% 29.22/29.04  tff(decl_39072, type, flagella: $i).
% 29.22/29.04  tff(decl_39073, type, flagellum: $i).
% 29.22/29.04  tff(decl_39074, type, fn_flagellum_1: $i > $i).
% 29.22/29.04  tff(decl_39075, type, fn_flagellum_4: $i > $i).
% 29.22/29.04  tff(decl_39076, type, fn_flagellum_5: $i > $i).
% 29.22/29.04  tff(decl_39077, type, fn_flagellum_7: $i > $i).
% 29.22/29.04  tff(decl_39078, type, fn_flagellum_8: $i > $i).
% 29.22/29.04  tff(decl_39079, type, fn_flagellum_9: $i > $i).
% 29.22/29.04  tff(decl_39080, type, fn_flagellum_11: $i > $i).
% 29.22/29.04  tff(decl_39081, type, fn_flagellum_13: $i > $i).
% 29.22/29.04  tff(decl_39082, type, fn_flagellum_15: $i > $i).
% 29.22/29.04  tff(decl_39083, type, fn_flagellum_16: $i > $i).
% 29.22/29.04  tff(decl_39084, type, fn_flagellum_17: $i > $i).
% 29.22/29.04  tff(decl_39085, type, fn_flagellum_18: $i > $i).
% 29.22/29.04  tff(decl_39086, type, fn_flagellum_21: $i > $i).
% 29.22/29.04  tff(decl_39087, type, fn_flagellum_28: $i > $i).
% 29.22/29.04  tff(decl_39088, type, fn_flagellum_29: $i > $i).
% 29.22/29.04  tff(decl_39089, type, fn_flagellum_30: $i > $i).
% 29.22/29.04  tff(decl_39090, type, fn_flagellum_31: $i > $i).
% 29.22/29.04  tff(decl_39091, type, fn_flagellum_32: $i > $i).
% 29.22/29.04  tff(decl_39092, type, fn_flagellum_33: $i > $i).
% 29.22/29.04  tff(decl_39093, type, fn_flagellum_34: $i > $i).
% 29.22/29.04  tff(decl_39094, type, fn_flagellum_36: $i > $i).
% 29.22/29.04  tff(decl_39095, type, fn_flagellum_37: $i > $i).
% 29.22/29.04  tff(decl_39096, type, fn_flagellum_38: $i > $i).
% 29.22/29.04  tff(decl_39097, type, fn_flagellum_39: $i > $i).
% 29.22/29.04  tff(decl_39098, type, fn_flagellum_40: $i > $i).
% 29.22/29.04  tff(decl_39099, type, fn_flagellum_41: $i > $i).
% 29.22/29.04  tff(decl_39100, type, fn_microtubule_doublet_2: $i > $i).
% 29.22/29.04  tff(decl_39101, type, fn_microtubule_doublet_1: $i > $i).
% 29.22/29.04  tff(decl_39102, type, microtubule_0: $i).
% 29.22/29.04  tff(decl_39103, type, cilium_0: $i).
% 29.22/29.04  tff(decl_39104, type, "0.25e0": $i).
% 29.22/29.04  tff(decl_39105, type, flask_1: $i > $o).
% 29.22/29.04  tff(decl_39106, type, 'Flask': $i).
% 29.22/29.04  tff(decl_39107, type, 'Container, usually made from glass, in which scientific experiments are conducted.': $i).
% 29.22/29.04  tff(decl_39108, type, flask: $i).
% 29.22/29.04  tff(decl_39109, type, flatworm_1: $i > $o).
% 29.22/29.04  tff(decl_39110, type, 'Flatworm': $i).
% 29.22/29.04  tff(decl_39111, type, 'A member of the Phylum Platyhelminthes. Includes the non-parasitic planarians and the parasitic flukes and tapeworms.': $i).
% 29.22/29.04  tff(decl_39112, type, flatworm: $i).
% 29.22/29.04  tff(decl_39113, type, fn_flatworm_1: $i > $i).
% 29.22/29.04  tff(decl_39114, type, fn_flatworm_2: $i > $i).
% 29.22/29.04  tff(decl_39115, type, fn_flatworm_3: $i > $i).
% 29.22/29.04  tff(decl_39116, type, fn_flatworm_5: $i > $i).
% 29.22/29.04  tff(decl_39117, type, fn_flatworm_6: $i > $i).
% 29.22/29.04  tff(decl_39118, type, fn_flatworm_7: $i > $i).
% 29.22/29.04  tff(decl_39119, type, fn_flatworm_8: $i > $i).
% 29.22/29.04  tff(decl_39120, type, fn_flatworm_11: $i > $i).
% 29.22/29.04  tff(decl_39121, type, fn_flatworm_12: $i > $i).
% 29.22/29.04  tff(decl_39122, type, fn_flatworm_13: $i > $i).
% 29.22/29.04  tff(decl_39123, type, fn_flatworm_14: $i > $i).
% 29.22/29.04  tff(decl_39124, type, fn_flatworm_15: $i > $i).
% 29.22/29.04  tff(decl_39125, type, fn_flatworm_16: $i > $i).
% 29.22/29.04  tff(decl_39126, type, fn_flatworm_17: $i > $i).
% 29.22/29.04  tff(decl_39127, type, fn_flatworm_18: $i > $i).
% 29.22/29.04  tff(decl_39128, type, fn_flatworm_19: $i > $i).
% 29.22/29.04  tff(decl_39129, type, fn_flatworm_20: $i > $i).
% 29.22/29.04  tff(decl_39130, type, fn_flatworm_21: $i > $i).
% 29.22/29.04  tff(decl_39131, type, fn_flatworm_22: $i > $i).
% 29.22/29.04  tff(decl_39132, type, fn_flatworm_23: $i > $i).
% 29.22/29.04  tff(decl_39133, type, fn_flatworm_24: $i > $i).
% 29.22/29.04  tff(decl_39134, type, fn_flatworm_25: $i > $i).
% 29.22/29.04  tff(decl_39135, type, fn_flatworm_26: $i > $i).
% 29.22/29.04  tff(decl_39136, type, fn_flatworm_27: $i > $i).
% 29.22/29.04  tff(decl_39137, type, fn_flatworm_28: $i > $i).
% 29.22/29.04  tff(decl_39138, type, fn_flatworm_29: $i > $i).
% 29.22/29.04  tff(decl_39139, type, fn_flatworm_30: $i > $i).
% 29.22/29.04  tff(decl_39140, type, fn_flatworm_31: $i > $i).
% 29.22/29.04  tff(decl_39141, type, fn_flatworm_32: $i > $i).
% 29.22/29.04  tff(decl_39142, type, fn_flatworm_33: $i > $i).
% 29.22/29.04  tff(decl_39143, type, fn_flatworm_34: $i > $i).
% 29.22/29.04  tff(decl_39144, type, fn_flatworm_35: $i > $i).
% 29.22/29.04  tff(decl_39145, type, fn_flatworm_36: $i > $i).
% 29.22/29.04  tff(decl_39146, type, fn_flatworm_37: $i > $i).
% 29.22/29.04  tff(decl_39147, type, fn_flatworm_38: $i > $i).
% 29.22/29.04  tff(decl_39148, type, fn_platyhelminthes_9: $i > $i).
% 29.22/29.04  tff(decl_39149, type, fn_platyhelminthes_2: $i > $i).
% 29.22/29.04  tff(decl_39150, type, fn_platyhelminthes_1: $i > $i).
% 29.22/29.04  tff(decl_39151, type, fn_platyhelminthes_10: $i > $i).
% 29.22/29.04  tff(decl_39152, type, fn_platyhelminthes_3: $i > $i).
% 29.22/29.04  tff(decl_39153, type, fn_platyhelminthes_4: $i > $i).
% 29.22/29.04  tff(decl_39154, type, fn_platyhelminthes_11: $i > $i).
% 29.22/29.04  tff(decl_39155, type, flavin_mononucleotide_1: $i > $o).
% 29.22/29.04  tff(decl_39156, type, 'Flavin-Mononucleotide': $i).
% 29.22/29.04  tff(decl_39157, type, 'A biological molecule derived from riboflavin (Vitamin B2); functions as a cofactor in various enzymes and photoreceptors.': $i).
% 29.22/29.04  tff(decl_39158, type, fmn: $i).
% 29.22/29.04  tff(decl_39159, type, 'riboflavin 5 phosphate': $i).
% 29.22/29.04  tff(decl_39160, type, 'riboflavin-5-phosphate': $i).
% 29.22/29.04  tff(decl_39161, type, 'fmn,': $i).
% 29.22/29.04  tff(decl_39162, type, 'riboflavin 5? phosphate': $i).
% 29.22/29.04  tff(decl_39163, type, 'riboflavin-5?-phosphate': $i).
% 29.22/29.04  tff(decl_39164, type, 'flavin mononucleotide': $i).
% 29.22/29.04  tff(decl_39165, type, 'flavin-mononucleotide': $i).
% 29.22/29.04  tff(decl_39166, type, 'Flavoprotein': $i).
% 29.22/29.04  tff(decl_39167, type, 'Flavoproteins are proteins that contain a nucleic acid derivative of riboflavin: the flavin adenine dinucleotide (FAD) or flavin mononucleotide (FMN).': $i).
% 29.22/29.04  tff(decl_39168, type, flavoprotein: $i).
% 29.22/29.04  tff(decl_39169, type, fn_flavoprotein_1: $i > $i).
% 29.22/29.04  tff(decl_39170, type, 'Flexibility-Constant': $i).
% 29.22/29.04  tff(decl_39171, type, 'constant of flexibility': $i).
% 29.22/29.04  tff(decl_39172, type, 'flexibility constant': $i).
% 29.22/29.04  tff(decl_39173, type, 'flexibility-constant': $i).
% 29.22/29.04  tff(decl_39174, type, 'Flexibility-Value': $i).
% 29.22/29.04  tff(decl_39175, type, flexibility: $i).
% 29.22/29.04  tff(decl_39176, type, 'value of flexibility': $i).
% 29.22/29.04  tff(decl_39177, type, 'flexibility value': $i).
% 29.22/29.04  tff(decl_39178, type, 'flexibility-value': $i).
% 29.22/29.04  tff(decl_39179, type, 'Flight': $i).
% 29.22/29.04  tff(decl_39180, type, 'A means of locomotion through the air.': $i).
% 29.22/29.04  tff(decl_39181, type, flight: $i).
% 29.22/29.04  tff(decl_39182, type, walk_1: $i > $o).
% 29.22/29.04  tff(decl_39183, type, fn_flight_1: $i > $i).
% 29.22/29.04  tff(decl_39184, type, 'Flightless-Birds': $i).
% 29.22/29.04  tff(decl_39185, type, 'Birds which evolved from flying ancestors but have lost the ability to fly.': $i).
% 29.22/29.04  tff(decl_39186, type, 'flightless birds': $i).
% 29.22/29.04  tff(decl_39187, type, 'flightless bird': $i).
% 29.22/29.04  tff(decl_39188, type, 'flightless-bird': $i).
% 29.22/29.04  tff(decl_39189, type, 'Float': $i).
% 29.22/29.04  tff(decl_39190, type, 'To stay on the surface of a liquid.': $i).
% 29.22/29.04  tff(decl_39191, type, float: $i).
% 29.22/29.04  tff(decl_39192, type, fn_float_1: $i > $i).
% 29.22/29.04  tff(decl_39193, type, fn_float_2: $i > $i).
% 29.22/29.04  tff(decl_39194, type, flooding_1: $i > $o).
% 29.22/29.04  tff(decl_39195, type, 'Flooding': $i).
% 29.22/29.04  tff(decl_39196, type, 'An overflow of an expanse of water that submerges land.': $i).
% 29.22/29.04  tff(decl_39197, type, flood: $i).
% 29.22/29.04  tff(decl_39198, type, flooding: $i).
% 29.22/29.04  tff(decl_39199, type, 'Floor': $i).
% 29.22/29.04  tff(decl_39200, type, 'a platform supporting the contents of a container': $i).
% 29.22/29.04  tff(decl_39201, type, floor: $i).
% 29.22/29.04  tff(decl_39202, type, 'Floral-Meristem': $i).
% 29.22/29.04  tff(decl_39203, type, 'The shoot apical meristem is transformed into an inflorescence meristem, which goes on to produce the floral meristem, which produces the familiar sepals, petals, stamens, and carpels of the flower during the developmental process of flowering.': $i).
% 29.22/29.04  tff(decl_39204, type, 'floral meristem': $i).
% 29.22/29.04  tff(decl_39205, type, 'floral-meristem': $i).
% 29.22/29.04  tff(decl_39206, type, fn_floral_meristem_1: $i > $i).
% 29.22/29.04  tff(decl_39207, type, fn_floral_meristem_2: $i > $i).
% 29.22/29.04  tff(decl_39208, type, fn_floral_meristem_3: $i > $i).
% 29.22/29.04  tff(decl_39209, type, fn_floral_meristem_4: $i > $i).
% 29.22/29.04  tff(decl_39210, type, shoot_apical_meristem_1: $i > $o).
% 29.22/29.04  tff(decl_39211, type, fn_floral_meristem_5: $i > $i).
% 29.22/29.04  tff(decl_39212, type, fn_floral_meristem_6: $i > $i).
% 29.22/29.04  tff(decl_39213, type, fn_floral_meristem_7: $i > $i).
% 29.22/29.04  tff(decl_39214, type, fn_floral_meristem_8: $i > $i).
% 29.22/29.04  tff(decl_39215, type, 'Layer I': $i).
% 29.22/29.04  tff(decl_39216, type, 'Layer III': $i).
% 29.22/29.04  tff(decl_39217, type, 'Layer II': $i).
% 29.22/29.04  tff(decl_39218, type, 'Florida-Scrub-Jay': $i).
% 29.22/29.04  tff(decl_39219, type, 'The only bird species that is endemic to the state of Florida.': $i).
% 29.22/29.04  tff(decl_39220, type, 'florida scrub jay': $i).
% 29.22/29.04  tff(decl_39221, type, 'florida-scrub-jay': $i).
% 29.22/29.04  tff(decl_39222, type, 'Florigen': $i).
% 29.22/29.04  tff(decl_39223, type, 'A flowering signal in angiosperms, not yet chemically identified, that may be a hormone or may be a change in relative concentrations of multiple hormones.': $i).
% 29.22/29.04  tff(decl_39224, type, florigen: $i).
% 29.22/29.04  tff(decl_39225, type, flow_1: $i > $o).
% 29.22/29.04  tff(decl_39226, type, 'Flow': $i).
% 29.22/29.04  tff(decl_39227, type, 'Fluid movement of a liquid or gas.': $i).
% 29.22/29.04  tff(decl_39228, type, flow: $i).
% 29.22/29.04  tff(decl_39229, type, 'Flower': $i).
% 29.22/29.04  tff(decl_39230, type, 'The reproductive structure of an angiosperm which is formed from a specially modified shoot.': $i).
% 29.22/29.04  tff(decl_39231, type, flower: $i).
% 29.22/29.04  tff(decl_39232, type, leaf_organ_1: $i > $o).
% 29.22/29.04  tff(decl_39233, type, fn_flower_3: $i > $i).
% 29.22/29.04  tff(decl_39234, type, fn_flower_4: $i > $i).
% 29.22/29.04  tff(decl_39235, type, fn_flower_5: $i > $i).
% 29.22/29.04  tff(decl_39236, type, fn_flower_6: $i > $i).
% 29.22/29.04  tff(decl_39237, type, fn_flower_7: $i > $i).
% 29.22/29.04  tff(decl_39238, type, stamen_1: $i > $o).
% 29.22/29.04  tff(decl_39239, type, fn_flower_8: $i > $i).
% 29.22/29.04  tff(decl_39240, type, fn_flower_9: $i > $i).
% 29.22/29.04  tff(decl_39241, type, petal_1: $i > $o).
% 29.22/29.04  tff(decl_39242, type, fn_flower_10: $i > $i).
% 29.22/29.04  tff(decl_39243, type, whorl_1: $i > $o).
% 29.22/29.04  tff(decl_39244, type, fn_flower_11: $i > $i).
% 29.22/29.04  tff(decl_39245, type, fn_flower_12: $i > $i).
% 29.22/29.04  tff(decl_39246, type, fn_flower_13: $i > $i).
% 29.22/29.04  tff(decl_39247, type, flower_color_1: $i > $o).
% 29.22/29.04  tff(decl_39248, type, 'Flower-Color': $i).
% 29.22/29.04  tff(decl_39249, type, 'The color of the flower.': $i).
% 29.22/29.04  tff(decl_39250, type, 'color of flower': $i).
% 29.22/29.04  tff(decl_39251, type, 'flower color': $i).
% 29.22/29.04  tff(decl_39252, type, 'flower-color': $i).
% 29.22/29.04  tff(decl_39253, type, fn_flower_color_1: $i > $i).
% 29.22/29.04  tff(decl_39254, type, purple_1: $i > $o).
% 29.22/29.04  tff(decl_39255, type, fn_flower_color_2: $i > $i).
% 29.22/29.04  tff(decl_39256, type, white_1: $i > $o).
% 29.22/29.04  tff(decl_39257, type, 'Flower-Development': $i).
% 29.22/29.04  tff(decl_39258, type, 'The process involved in the development of the flower during developmental process of a plant.': $i).
% 29.22/29.04  tff(decl_39259, type, 'development of flower': $i).
% 29.22/29.04  tff(decl_39260, type, 'flower development': $i).
% 29.22/29.04  tff(decl_39261, type, 'flower-development': $i).
% 29.22/29.04  tff(decl_39262, type, fn_flower_development_1: $i > $i).
% 29.22/29.04  tff(decl_39263, type, fn_flower_development_2: $i > $i).
% 29.22/29.04  tff(decl_39264, type, fn_flower_development_3: $i > $i).
% 29.22/29.04  tff(decl_39265, type, fn_flower_development_4: $i > $i).
% 29.22/29.04  tff(decl_39266, type, fn_flower_development_5: $i > $i).
% 29.22/29.04  tff(decl_39267, type, organ_identity_gene_1: $i > $o).
% 29.22/29.04  tff(decl_39268, type, fn_flower_development_6: $i > $i).
% 29.22/29.04  tff(decl_39269, type, fn_flower_development_7: $i > $i).
% 29.22/29.04  tff(decl_39270, type, fn_flower_development_8: $i > $i).
% 29.22/29.04  tff(decl_39271, type, fn_flower_development_9: $i > $i).
% 29.22/29.04  tff(decl_39272, type, fn_flower_development_10: $i > $i).
% 29.22/29.04  tff(decl_39273, type, fn_flower_development_11: $i > $i).
% 29.22/29.04  tff(decl_39274, type, fn_flower_development_12: $i > $i).
% 29.22/29.04  tff(decl_39275, type, fn_flower_development_13: $i > $i).
% 29.22/29.04  tff(decl_39276, type, fn_flower_development_14: $i > $i).
% 29.22/29.04  tff(decl_39277, type, fn_flower_development_15: $i > $i).
% 29.22/29.04  tff(decl_39278, type, fn_flower_development_16: $i > $i).
% 29.22/29.04  tff(decl_39279, type, fn_flower_development_17: $i > $i).
% 29.22/29.04  tff(decl_39280, type, fn_flower_development_18: $i > $i).
% 29.22/29.04  tff(decl_39281, type, fn_flower_development_19: $i > $i).
% 29.22/29.04  tff(decl_39282, type, fn_flower_development_20: $i > $i).
% 29.22/29.04  tff(decl_39283, type, fn_flower_development_21: $i > $i).
% 29.22/29.04  tff(decl_39284, type, fn_flower_development_22: $i > $i).
% 29.22/29.04  tff(decl_39285, type, fn_flower_development_23: $i > $i).
% 29.22/29.04  tff(decl_39286, type, fn_flower_development_24: $i > $i).
% 29.22/29.04  tff(decl_39287, type, 'Organ Identity Gene A': $i).
% 29.22/29.04  tff(decl_39288, type, 'Organ Identity Gene B': $i).
% 29.22/29.04  tff(decl_39289, type, 'Organ Identity C': $i).
% 29.22/29.04  tff(decl_39290, type, fn_organ_development_1: $i > $i).
% 29.22/29.04  tff(decl_39291, type, flower_filament_1: $i > $o).
% 29.22/29.04  tff(decl_39292, type, 'Flower-Filament': $i).
% 29.22/29.04  tff(decl_39293, type, 'In an angiosperm, the stalk portion of the stamen, the pollen-producing reproductive organ of a flower.': $i).
% 29.22/29.04  tff(decl_39294, type, 'filament of flower': $i).
% 29.22/29.04  tff(decl_39295, type, 'flower filament': $i).
% 29.22/29.04  tff(decl_39296, type, 'flower-filament': $i).
% 29.22/29.04  tff(decl_39297, type, 'Flower-Organ': $i).
% 29.22/29.04  tff(decl_39298, type, 'A specialized center of plant function composed of specialized leaf tissue, called flower tissue, and specific to plants.': $i).
% 29.22/29.04  tff(decl_39299, type, 'organ of flower': $i).
% 29.22/29.04  tff(decl_39300, type, 'flower organ': $i).
% 29.22/29.04  tff(decl_39301, type, 'flower-organ': $i).
% 29.22/29.04  tff(decl_39302, type, 'Flowering-Control-Plant': $i).
% 29.22/29.04  tff(decl_39303, type, 'Flowering control plants are plants which utilize mechanisms such as hours of daylight or level of maturity to determine when they flower.': $i).
% 29.22/29.04  tff(decl_39304, type, 'plant with flowering control': $i).
% 29.22/29.04  tff(decl_39305, type, 'plant-with-flowering-control': $i).
% 29.22/29.04  tff(decl_39306, type, 'flowering control plant': $i).
% 29.22/29.04  tff(decl_39307, type, 'flowering-control-plant': $i).
% 29.22/29.04  tff(decl_39308, type, fluent_status_1: $i > $o).
% 29.22/29.04  tff(decl_39309, type, 'Fluent-Status': $i).
% 29.22/29.04  tff(decl_39310, type, 'Fluid-Feeder': $i).
% 29.22/29.04  tff(decl_39311, type, 'An animal that feeds on fluids from another living organism.': $i).
% 29.22/29.04  tff(decl_39312, type, 'feeder of fluid': $i).
% 29.22/29.04  tff(decl_39313, type, 'fluid feeder': $i).
% 29.22/29.04  tff(decl_39314, type, 'fluid-feeder': $i).
% 29.22/29.04  tff(decl_39315, type, fn_fluid_feeder_1: $i > $i).
% 29.22/29.04  tff(decl_39316, type, fn_fluid_feeder_2: $i > $i).
% 29.22/29.04  tff(decl_39317, type, fn_fluid_feeder_3: $i > $i).
% 29.22/29.04  tff(decl_39318, type, fn_fluid_feeder_4: $i > $i).
% 29.22/29.04  tff(decl_39319, type, fn_fluid_feeder_5: $i > $i).
% 29.22/29.04  tff(decl_39320, type, fn_fluid_feeder_7: $i > $i).
% 29.22/29.04  tff(decl_39321, type, fn_fluid_feeder_8: $i > $i).
% 29.22/29.04  tff(decl_39322, type, fn_fluid_feeder_9: $i > $i).
% 29.22/29.04  tff(decl_39323, type, fn_fluid_feeder_10: $i > $i).
% 29.22/29.04  tff(decl_39324, type, fn_withdraw_1: $i > $i).
% 29.22/29.04  tff(decl_39325, type, 'Fluid-Feeding': $i).
% 29.22/29.04  tff(decl_39326, type, 'Obtaining food by sucking fluids from a live host.': $i).
% 29.22/29.04  tff(decl_39327, type, 'feeding of fluid': $i).
% 29.22/29.04  tff(decl_39328, type, 'fluid feeding': $i).
% 29.22/29.04  tff(decl_39329, type, 'fluid-feeding': $i).
% 29.22/29.04  tff(decl_39330, type, 'Fluid-Mosaic-Model': $i).
% 29.22/29.04  tff(decl_39331, type, 'The fluid mosaic model of S. J. Singer and Garth Nicolson 1972, the biological membranes can be considered as a two-dimensional liquid where all lipid and protein molecules diffuse more or less easily.': $i).
% 29.22/29.04  tff(decl_39332, type, 'fluid mosaic model': $i).
% 29.22/29.04  tff(decl_39333, type, 'fluid-mosaic-model': $i).
% 29.22/29.04  tff(decl_39334, type, fn_fluid_mosaic_model_1: $i > $i).
% 29.22/29.04  tff(decl_39335, type, fn_fluid_mosaic_model_2: $i > $i).
% 29.22/29.04  tff(decl_39336, type, fn_fluid_mosaic_model_3: $i > $i).
% 29.22/29.04  tff(decl_39337, type, fn_fluid_mosaic_model_4: $i > $i).
% 29.22/29.04  tff(decl_39338, type, s_j_singer_1: $i > $o).
% 29.22/29.04  tff(decl_39339, type, fn_fluid_mosaic_model_6: $i > $i).
% 29.22/29.04  tff(decl_39340, type, fn_fluid_mosaic_model_7: $i > $i).
% 29.22/29.04  tff(decl_39341, type, fn_fluid_mosaic_model_8: $i > $i).
% 29.22/29.04  tff(decl_39342, type, fn_fluid_mosaic_model_9: $i > $i).
% 29.22/29.04  tff(decl_39343, type, fn_fluid_mosaic_model_10: $i > $i).
% 29.22/29.04  tff(decl_39344, type, suggest_1: $i > $o).
% 29.22/29.04  tff(decl_39345, type, fn_fluid_mosaic_model_11: $i > $i).
% 29.22/29.04  tff(decl_39346, type, g_nicolson_1: $i > $o).
% 29.22/29.04  tff(decl_39347, type, fn_fluid_mosaic_model_12: $i > $i).
% 29.22/29.04  tff(decl_39348, type, fn_fluid_mosaic_model_13: $i > $i).
% 29.22/29.04  tff(decl_39349, type, fn_fluid_mosaic_model_14: $i > $i).
% 29.22/29.04  tff(decl_39350, type, peripheral_protein_1: $i > $o).
% 29.22/29.04  tff(decl_39351, type, fn_fluid_mosaic_model_15: $i > $i).
% 29.22/29.04  tff(decl_39352, type, fn_fluid_mosaic_model_16: $i > $i).
% 29.22/29.04  tff(decl_39353, type, fn_fluid_mosaic_model_17: $i > $i).
% 29.22/29.04  tff(decl_39354, type, fn_fluid_mosaic_model_18: $i > $i).
% 29.22/29.04  tff(decl_39355, type, fn_fluid_mosaic_model_19: $i > $i).
% 29.22/29.04  tff(decl_39356, type, fn_peripheral_protein_41: $i > $i).
% 29.22/29.04  tff(decl_39357, type, fn_peripheral_protein_46: $i > $i).
% 29.22/29.04  tff(decl_39358, type, fn_peripheral_protein_1: $i > $i).
% 29.22/29.04  tff(decl_39359, type, fn_peripheral_protein_45: $i > $i).
% 29.22/29.04  tff(decl_39360, type, fn_peripheral_protein_10: $i > $i).
% 29.22/29.04  tff(decl_39361, type, 'TP': $i).
% 29.22/29.04  tff(decl_39362, type, 'PP': $i).
% 29.22/29.04  tff(decl_39363, type, 'IP': $i).
% 29.22/29.04  tff(decl_39364, type, 'Fluid-Substance': $i).
% 29.22/29.04  tff(decl_39365, type, 'A substance, as a liquid or a gas, that is capable of flowing and which changes its shape at a steady rate when acted upon by a force. RHCD:508.': $i).
% 29.22/29.04  tff(decl_39366, type, fluid: $i).
% 29.22/29.04  tff(decl_39367, type, 'substance of fluid': $i).
% 29.22/29.04  tff(decl_39368, type, 'fluid substance': $i).
% 29.22/29.04  tff(decl_39369, type, 'fluid-substance': $i).
% 29.22/29.04  tff(decl_39370, type, 'Fluidity-Constant': $i).
% 29.22/29.04  tff(decl_39371, type, 'constant of fluidity': $i).
% 29.22/29.04  tff(decl_39372, type, 'fluidity constant': $i).
% 29.22/29.04  tff(decl_39373, type, 'fluidity-constant': $i).
% 29.22/29.04  tff(decl_39374, type, 'Fluidity-Value': $i).
% 29.22/29.04  tff(decl_39375, type, fluidity: $i).
% 29.22/29.04  tff(decl_39376, type, 'value of fluidity': $i).
% 29.22/29.04  tff(decl_39377, type, 'fluidity value': $i).
% 29.22/29.04  tff(decl_39378, type, 'fluidity-value': $i).
% 29.22/29.04  tff(decl_39379, type, fluorescence_1: $i > $o).
% 29.22/29.04  tff(decl_39380, type, 'Fluorescence': $i).
% 29.22/29.04  tff(decl_39381, type, 'Fluorescence is the emission of light by a substance that has absorbed light or other electromagnetic radiation of a different wavelength. In most cases, emitted light has a longer wavelength, and therefore lower energy, than the absorbed radiation.': $i).
% 29.22/29.04  tff(decl_39382, type, fluoresce: $i).
% 29.22/29.04  tff(decl_39383, type, fluorescence: $i).
% 29.22/29.04  tff(decl_39384, type, fn_fluorescence_2: $i > $i).
% 29.22/29.04  tff(decl_39385, type, fn_fluorescence_3: $i > $i).
% 29.22/29.04  tff(decl_39386, type, fn_fluorescence_4: $i > $i).
% 29.22/29.04  tff(decl_39387, type, fn_fluorescence_5: $i > $i).
% 29.22/29.04  tff(decl_39388, type, fn_fluorescence_6: $i > $i).
% 29.22/29.04  tff(decl_39389, type, fn_fluorescence_7: $i > $i).
% 29.22/29.04  tff(decl_39390, type, fn_fluorescence_8: $i > $i).
% 29.22/29.04  tff(decl_39391, type, fn_fluorescence_10: $i > $i).
% 29.22/29.04  tff(decl_39392, type, fn_fluorescence_11: $i > $i).
% 29.22/29.04  tff(decl_39393, type, fn_fluorescence_12: $i > $i).
% 29.22/29.04  tff(decl_39394, type, fn_fluorescence_9: $i > $i).
% 29.22/29.04  tff(decl_39395, type, fluorescent_specimen_1: $i > $o).
% 29.22/29.04  tff(decl_39396, type, 'Fluorescent-Specimen': $i).
% 29.22/29.04  tff(decl_39397, type, 'A fluorescent specimen has an inherent property of fluorescence. This property is due to presence of a fluorescent molecule as a part of their structure.': $i).
% 29.22/29.04  tff(decl_39398, type, 'fluorescent specimen': $i).
% 29.22/29.04  tff(decl_39399, type, 'fluorescent-specimen': $i).
% 29.22/29.04  tff(decl_39400, type, specimen_1: $i > $o).
% 29.22/29.04  tff(decl_39401, type, staining_1: $i > $o).
% 29.22/29.04  tff(decl_39402, type, fluorescent_substance_1: $i > $o).
% 29.22/29.04  tff(decl_39403, type, fluorescent_staining_1: $i > $o).
% 29.22/29.04  tff(decl_39404, type, fn_fluorescent_staining_2: $i > $i).
% 29.22/29.04  tff(decl_39405, type, 'Fluorescent-Staining': $i).
% 29.22/29.04  tff(decl_39406, type, 'A process of staining certain tissue components by combining it with a fluorescent dye or substance. This process is required to study a specimen with the fluorescent microscopy.': $i).
% 29.22/29.04  tff(decl_39407, type, stain: $i).
% 29.22/29.04  tff(decl_39408, type, 'fluorescent staining': $i).
% 29.22/29.04  tff(decl_39409, type, 'fluorescent-staining': $i).
% 29.22/29.04  tff(decl_39410, type, fn_fluorescent_staining_3: $i > $i).
% 29.22/29.04  tff(decl_39411, type, fn_fluorescent_staining_4: $i > $i).
% 29.22/29.04  tff(decl_39412, type, fn_fluorescent_staining_5: $i > $i).
% 29.22/29.04  tff(decl_39413, type, fn_specimen_stained_with_fluorescent_substance_1: $i > $i).
% 29.22/29.04  tff(decl_39414, type, 'Fluorescent-Substance': $i).
% 29.22/29.04  tff(decl_39415, type, 'A substance with the ability to emit light after absorbing light or other electromagnetic radiation.': $i).
% 29.22/29.04  tff(decl_39416, type, 'fluorescent material': $i).
% 29.22/29.04  tff(decl_39417, type, 'fluorescent-material': $i).
% 29.22/29.04  tff(decl_39418, type, 'fluorescent molecule': $i).
% 29.22/29.04  tff(decl_39419, type, 'fluorescent-molecule': $i).
% 29.22/29.04  tff(decl_39420, type, 'fluorescent dye': $i).
% 29.22/29.04  tff(decl_39421, type, 'fluorescent-dye': $i).
% 29.22/29.04  tff(decl_39422, type, fluorophore: $i).
% 29.22/29.04  tff(decl_39423, type, 'fluorescent substance': $i).
% 29.22/29.04  tff(decl_39424, type, 'fluorescent-substance': $i).
% 29.22/29.04  tff(decl_39425, type, fn_fluorescent_substance_1: $i > $i).
% 29.22/29.04  tff(decl_39426, type, fn_fluorescent_substance_2: $i > $i).
% 29.22/29.04  tff(decl_39427, type, fn_fluorescent_substance_3: $i > $i).
% 29.22/29.04  tff(decl_39428, type, fn_fluorescent_substance_4: $i > $i).
% 29.22/29.04  tff(decl_39429, type, fluorine_1: $i > $o).
% 29.22/29.04  tff(decl_39430, type, 'Fluorine': $i).
% 29.22/29.04  tff(decl_39431, type, 'Fluorine is a non metal atom with atomic number 9. It is represented by the symbol F.': $i).
% 29.22/29.04  tff(decl_39432, type, 'F': $i).
% 29.22/29.04  tff(decl_39433, type, fluorine: $i).
% 29.22/29.04  tff(decl_39434, type, fn_fluorine_4: $i > $i).
% 29.22/29.04  tff(decl_39435, type, fn_fluorine_5: $i > $i).
% 29.22/29.04  tff(decl_39436, type, fn_fluorine_6: $i > $i).
% 29.22/29.04  tff(decl_39437, type, fn_fluorine_7: $i > $i).
% 29.22/29.04  tff(decl_39438, type, fn_fluorine_11: $i > $i).
% 29.22/29.04  tff(decl_39439, type, fn_fluorine_12: $i > $i).
% 29.22/29.04  tff(decl_39440, type, fn_fluorine_13: $i > $i).
% 29.22/29.04  tff(decl_39441, type, fn_fluorine_14: $i > $i).
% 29.22/29.04  tff(decl_39442, type, "3.98": $i).
% 29.22/29.04  tff(decl_39443, type, "19": $i).
% 29.22/29.04  tff(decl_39444, type, fn_fluorine_9: $i > $i).
% 29.22/29.04  tff(decl_39445, type, fn_fluorine_10: $i > $i).
% 29.22/29.04  tff(decl_39446, type, fn_fluorine_8: $i > $i).
% 29.22/29.04  tff(decl_39447, type, fog_1: $i > $o).
% 29.22/29.04  tff(decl_39448, type, 'Fog': $i).
% 29.22/29.04  tff(decl_39449, type, 'A cloudlike mass or layer of minute water droplets near the surface of the earth.': $i).
% 29.22/29.04  tff(decl_39450, type, fog: $i).
% 29.22/29.04  tff(decl_39451, type, rain_1: $i > $o).
% 29.22/29.04  tff(decl_39452, type, snow_1: $i > $o).
% 29.22/29.04  tff(decl_39453, type, 'Fold': $i).
% 29.22/29.04  tff(decl_39454, type, 'The verb FOLD has 6 senses:1. bend or lay so that one part covers the other2. intertwine3. incorporate a food ingredient into a mixture by repeatedly turning it over without stirring or beating4. cease to operate or cause to cease operating5. confine in a fold, like sheep6. become folded or folded up': $i).
% 29.22/29.04  tff(decl_39455, type, bend: $i).
% 29.22/29.04  tff(decl_39456, type, loop: $i).
% 29.22/29.04  tff(decl_39457, type, fold: $i).
% 29.22/29.04  tff(decl_39458, type, folded_protein_1: $i > $o).
% 29.22/29.04  tff(decl_39459, type, 'Folded-Protein': $i).
% 29.22/29.04  tff(decl_39460, type, 'A protein that is properly folded.': $i).
% 29.22/29.04  tff(decl_39461, type, 'folded protein': $i).
% 29.22/29.04  tff(decl_39462, type, 'folded-protein': $i).
% 29.22/29.04  tff(decl_39463, type, 'Follicle-Cell': $i).
% 29.22/29.04  tff(decl_39464, type, 'Follicle cells of ovary are the basic units of female reproductive biology, each of which is composed of roughly spherical aggregations of cells found in the ovary.': $i).
% 29.22/29.04  tff(decl_39465, type, follicle: $i).
% 29.22/29.04  tff(decl_39466, type, 'ovarian follicle': $i).
% 29.22/29.04  tff(decl_39467, type, 'ovarian-follicle': $i).
% 29.22/29.04  tff(decl_39468, type, 'cell of follicle': $i).
% 29.22/29.04  tff(decl_39469, type, 'follicle cell': $i).
% 29.22/29.04  tff(decl_39470, type, 'follicle-cell': $i).
% 29.22/29.04  tff(decl_39471, type, ovarian_cell_1: $i > $o).
% 29.22/29.04  tff(decl_39472, type, 'Follicular-Phase': $i).
% 29.22/29.04  tff(decl_39473, type, 'Phase of the menstrual cycle in which blood levels of estrogen are increasing and follicles are maturing in the ovaries.': $i).
% 29.22/29.04  tff(decl_39474, type, 'proliferative phase': $i).
% 29.22/29.04  tff(decl_39475, type, 'proliferative-phase': $i).
% 29.22/29.04  tff(decl_39476, type, 'follicular phase': $i).
% 29.22/29.04  tff(decl_39477, type, 'follicular-phase': $i).
% 29.22/29.04  tff(decl_39478, type, follow_1: $i > $o).
% 29.22/29.04  tff(decl_39479, type, 'Follow': $i).
% 29.22/29.04  tff(decl_39480, type, follow: $i).
% 29.22/29.04  tff(decl_39481, type, fn_follow_1: $i > $i).
% 29.22/29.04  tff(decl_39482, type, fn_follow_2: $i > $i).
% 29.22/29.04  tff(decl_39483, type, 'Food': $i).
% 29.22/29.04  tff(decl_39484, type, 'Substance which provides nourishment to an organism.': $i).
% 29.22/29.04  tff(decl_39485, type, 'Food is a substance which when consumed provides energy and nutrition.': $i).
% 29.22/29.04  tff(decl_39486, type, food: $i).
% 29.22/29.04  tff(decl_39487, type, nutrient: $i).
% 29.22/29.04  tff(decl_39488, type, 'Food-Absorption': $i).
% 29.22/29.04  tff(decl_39489, type, 'The stage during food processing in which small nutrient molecules are absorbed by the cells of an organism.': $i).
% 29.22/29.04  tff(decl_39490, type, 'absorption of food': $i).
% 29.22/29.04  tff(decl_39491, type, 'food absorption': $i).
% 29.22/29.04  tff(decl_39492, type, 'food-absorption': $i).
% 29.22/29.04  tff(decl_39493, type, fn_food_absorption_1: $i > $i).
% 29.22/29.04  tff(decl_39494, type, fn_food_absorption_2: $i > $i).
% 29.22/29.04  tff(decl_39495, type, fn_food_absorption_3: $i > $i).
% 29.22/29.04  tff(decl_39496, type, food_chain_1: $i > $o).
% 29.22/29.04  tff(decl_39497, type, 'Food-Chain': $i).
% 29.22/29.04  tff(decl_39498, type, 'A linear series of species through which food energy flows in an ecosystem, beginning with primary producers and ending with top-level consumers.': $i).
% 29.22/29.04  tff(decl_39499, type, 'chain of food': $i).
% 29.22/29.04  tff(decl_39500, type, 'food chain': $i).
% 29.22/29.04  tff(decl_39501, type, 'food-chain': $i).
% 29.22/29.04  tff(decl_39502, type, 'Food-Plant': $i).
% 29.22/29.04  tff(decl_39503, type, 'A plant that is used for food.': $i).
% 29.22/29.04  tff(decl_39504, type, 'food plants': $i).
% 29.22/29.04  tff(decl_39505, type, 'food-plants': $i).
% 29.22/29.04  tff(decl_39506, type, 'host plant': $i).
% 29.22/29.04  tff(decl_39507, type, 'host-plant': $i).
% 29.22/29.04  tff(decl_39508, type, 'host plants': $i).
% 29.22/29.04  tff(decl_39509, type, 'host-plants': $i).
% 29.22/29.04  tff(decl_39510, type, 'plant of food': $i).
% 29.22/29.04  tff(decl_39511, type, 'food plant': $i).
% 29.22/29.04  tff(decl_39512, type, 'food-plant': $i).
% 29.22/29.04  tff(decl_39513, type, food_processing_1: $i > $o).
% 29.22/29.04  tff(decl_39514, type, 'Food-Processing': $i).
% 29.22/29.04  tff(decl_39515, type, 'A sequence of events that digest food into its usable forms and eliminate the wastes.': $i).
% 29.22/29.04  tff(decl_39516, type, 'processing of food': $i).
% 29.22/29.04  tff(decl_39517, type, 'food processing': $i).
% 29.22/29.04  tff(decl_39518, type, 'food-processing': $i).
% 29.22/29.04  tff(decl_39519, type, fn_food_processing_1: $i > $i).
% 29.22/29.04  tff(decl_39520, type, fn_food_processing_2: $i > $i).
% 29.22/29.04  tff(decl_39521, type, fn_food_processing_3: $i > $i).
% 29.22/29.04  tff(decl_39522, type, fn_food_processing_4: $i > $i).
% 29.22/29.04  tff(decl_39523, type, fn_food_processing_5: $i > $i).
% 29.22/29.04  tff(decl_39524, type, fn_food_processing_6: $i > $i).
% 29.22/29.04  tff(decl_39525, type, fn_food_processing_7: $i > $i).
% 29.22/29.04  tff(decl_39526, type, fn_food_processing_8: $i > $i).
% 29.22/29.04  tff(decl_39527, type, fn_food_processing_9: $i > $i).
% 29.22/29.04  tff(decl_39528, type, fn_food_processing_10: $i > $i).
% 29.22/29.04  tff(decl_39529, type, fn_food_processing_11: $i > $i).
% 29.22/29.04  tff(decl_39530, type, fn_food_processing_12: $i > $i).
% 29.22/29.04  tff(decl_39531, type, fn_food_processing_13: $i > $i).
% 29.22/29.04  tff(decl_39532, type, food_processing_in_bird_1: $i > $o).
% 29.22/29.04  tff(decl_39533, type, 'Food-Processing-In-Bird': $i).
% 29.22/29.04  tff(decl_39534, type, 'A sequence of events in birds that digest food into its usable forms and eliminate the wastes.': $i).
% 29.22/29.04  tff(decl_39535, type, 'food processing in bird': $i).
% 29.22/29.04  tff(decl_39536, type, 'food-processing-in-bird': $i).
% 29.22/29.04  tff(decl_39537, type, food_processing_in_cnidaria_1: $i > $o).
% 29.22/29.04  tff(decl_39538, type, 'Food-Processing-In-Cnidaria': $i).
% 29.22/29.04  tff(decl_39539, type, 'A sequence of events in cnidarians that digest food into its usable forms and eliminate the wastes.': $i).
% 29.22/29.04  tff(decl_39540, type, 'food processing in cnidaria': $i).
% 29.22/29.04  tff(decl_39541, type, 'food-processing-in-cnidaria': $i).
% 29.22/29.04  tff(decl_39542, type, fn_food_processing_in_cnidaria_1: $i > $i).
% 29.22/29.04  tff(decl_39543, type, fn_food_processing_in_cnidaria_2: $i > $i).
% 29.22/29.04  tff(decl_39544, type, fn_food_processing_in_cnidaria_3: $i > $i).
% 29.22/29.04  tff(decl_39545, type, prey_1: $i > $o).
% 29.22/29.04  tff(decl_39546, type, fn_food_processing_in_cnidaria_4: $i > $i).
% 29.22/29.04  tff(decl_39547, type, fn_food_processing_in_cnidaria_5: $i > $i).
% 29.22/29.04  tff(decl_39548, type, fn_food_processing_in_cnidaria_7: $i > $i).
% 29.22/29.04  tff(decl_39549, type, fn_food_processing_in_cnidaria_8: $i > $i).
% 29.22/29.04  tff(decl_39550, type, fn_food_processing_in_cnidaria_9: $i > $i).
% 29.22/29.04  tff(decl_39551, type, fn_food_processing_in_cnidaria_10: $i > $i).
% 29.22/29.04  tff(decl_39552, type, fn_food_processing_in_cnidaria_11: $i > $i).
% 29.22/29.04  tff(decl_39553, type, fn_food_processing_in_cnidaria_12: $i > $i).
% 29.22/29.04  tff(decl_39554, type, fn_food_processing_in_cnidaria_13: $i > $i).
% 29.22/29.04  tff(decl_39555, type, fn_food_processing_in_cnidaria_14: $i > $i).
% 29.22/29.04  tff(decl_39556, type, fn_food_processing_in_cnidaria_15: $i > $i).
% 29.22/29.04  tff(decl_39557, type, fn_food_processing_in_cnidaria_16: $i > $i).
% 29.22/29.04  tff(decl_39558, type, fn_food_processing_in_cnidaria_17: $i > $i).
% 29.22/29.04  tff(decl_39559, type, fn_food_processing_in_cnidaria_18: $i > $i).
% 29.22/29.04  tff(decl_39560, type, fn_food_processing_in_cnidaria_20: $i > $i).
% 29.22/29.04  tff(decl_39561, type, fn_food_processing_in_cnidaria_21: $i > $i).
% 29.22/29.04  tff(decl_39562, type, fn_food_processing_in_cnidaria_22: $i > $i).
% 29.22/29.04  tff(decl_39563, type, fn_food_processing_in_cnidaria_23: $i > $i).
% 29.22/29.04  tff(decl_39564, type, fn_food_processing_in_cnidaria_24: $i > $i).
% 29.22/29.04  tff(decl_39565, type, fn_food_processing_in_cnidaria_25: $i > $i).
% 29.22/29.04  tff(decl_39566, type, fn_food_processing_in_cnidaria_26: $i > $i).
% 29.22/29.04  tff(decl_39567, type, fn_food_processing_in_cnidaria_27: $i > $i).
% 29.22/29.04  tff(decl_39568, type, fn_food_processing_in_cnidaria_28: $i > $i).
% 29.22/29.04  tff(decl_39569, type, fn_food_processing_in_cnidaria_29: $i > $i).
% 29.22/29.04  tff(decl_39570, type, fn_food_processing_in_cnidaria_30: $i > $i).
% 29.22/29.04  tff(decl_39571, type, fn_food_processing_in_cnidaria_31: $i > $i).
% 29.22/29.04  tff(decl_39572, type, fn_food_processing_in_cnidaria_32: $i > $i).
% 29.22/29.04  tff(decl_39573, type, fn_food_processing_in_cnidaria_33: $i > $i).
% 29.22/29.04  tff(decl_39574, type, fn_food_processing_in_cnidaria_34: $i > $i).
% 29.22/29.04  tff(decl_39575, type, fn_food_processing_in_cnidaria_35: $i > $i).
% 29.22/29.04  tff(decl_39576, type, fn_food_processing_in_cnidaria_36: $i > $i).
% 29.22/29.04  tff(decl_39577, type, fn_food_processing_in_cnidaria_37: $i > $i).
% 29.22/29.04  tff(decl_39578, type, fn_food_processing_in_cnidaria_38: $i > $i).
% 29.22/29.04  tff(decl_39579, type, fn_food_processing_in_cnidaria_39: $i > $i).
% 29.22/29.04  tff(decl_39580, type, fn_food_processing_in_cnidaria_40: $i > $i).
% 29.22/29.04  tff(decl_39581, type, fn_food_processing_in_cnidaria_41: $i > $i).
% 29.22/29.04  tff(decl_39582, type, fn_food_processing_in_cnidaria_42: $i > $i).
% 29.22/29.04  tff(decl_39583, type, fn_food_processing_in_cnidaria_43: $i > $i).
% 29.22/29.04  tff(decl_39584, type, fn_food_processing_in_cnidaria_44: $i > $i).
% 29.22/29.04  tff(decl_39585, type, fn_food_processing_in_cnidaria_45: $i > $i).
% 29.22/29.04  tff(decl_39586, type, fn_food_processing_in_cnidaria_46: $i > $i).
% 29.22/29.04  tff(decl_39587, type, fn_food_processing_in_cnidaria_47: $i > $i).
% 29.22/29.04  tff(decl_39588, type, fn_food_processing_in_cnidaria_48: $i > $i).
% 29.22/29.04  tff(decl_39589, type, fn_food_processing_in_cnidaria_49: $i > $i).
% 29.22/29.04  tff(decl_39590, type, fn_food_processing_in_cnidaria_50: $i > $i).
% 29.22/29.04  tff(decl_39591, type, fn_food_processing_in_cnidaria_51: $i > $i).
% 29.22/29.04  tff(decl_39592, type, fn_lysosome_4: $i > $i).
% 29.22/29.04  tff(decl_39593, type, fn_food_processing_in_cnidaria_19: $i > $i).
% 29.22/29.04  tff(decl_39594, type, food_processing_in_earthworm_1: $i > $o).
% 29.22/29.04  tff(decl_39595, type, 'Food-Processing-In-Earthworm': $i).
% 29.22/29.04  tff(decl_39596, type, 'A sequence of events in earthworms that digest food into its usable forms and eliminate the wastes.': $i).
% 29.22/29.04  tff(decl_39597, type, 'food processing in earthworm': $i).
% 29.22/29.04  tff(decl_39598, type, 'food-processing-in-earthworm': $i).
% 29.22/29.04  tff(decl_39599, type, fn_food_processing_in_earthworm_1: $i > $i).
% 29.22/29.04  tff(decl_39600, type, fn_food_processing_in_earthworm_2: $i > $i).
% 29.22/29.04  tff(decl_39601, type, fn_food_processing_in_earthworm_3: $i > $i).
% 29.22/29.04  tff(decl_39602, type, fn_food_processing_in_earthworm_4: $i > $i).
% 29.22/29.04  tff(decl_39603, type, fn_food_processing_in_earthworm_5: $i > $i).
% 29.22/29.04  tff(decl_39604, type, fn_food_processing_in_earthworm_6: $i > $i).
% 29.22/29.04  tff(decl_39605, type, fn_food_processing_in_earthworm_7: $i > $i).
% 29.22/29.04  tff(decl_39606, type, fn_food_processing_in_earthworm_8: $i > $i).
% 29.22/29.04  tff(decl_39607, type, fn_food_processing_in_earthworm_9: $i > $i).
% 29.22/29.04  tff(decl_39608, type, fn_food_processing_in_earthworm_10: $i > $i).
% 29.22/29.04  tff(decl_39609, type, fn_food_processing_in_earthworm_11: $i > $i).
% 29.22/29.04  tff(decl_39610, type, fn_food_processing_in_earthworm_14: $i > $i).
% 29.22/29.04  tff(decl_39611, type, fn_food_processing_in_earthworm_15: $i > $i).
% 29.22/29.04  tff(decl_39612, type, fn_food_processing_in_earthworm_16: $i > $i).
% 29.22/29.04  tff(decl_39613, type, fn_food_processing_in_earthworm_17: $i > $i).
% 29.22/29.04  tff(decl_39614, type, fn_food_processing_in_earthworm_18: $i > $i).
% 29.22/29.04  tff(decl_39615, type, fn_food_processing_in_earthworm_19: $i > $i).
% 29.22/29.04  tff(decl_39616, type, fn_food_processing_in_earthworm_20: $i > $i).
% 29.22/29.04  tff(decl_39617, type, fn_food_processing_in_earthworm_21: $i > $i).
% 29.22/29.04  tff(decl_39618, type, fn_food_processing_in_earthworm_22: $i > $i).
% 29.22/29.04  tff(decl_39619, type, fn_food_processing_in_earthworm_23: $i > $i).
% 29.22/29.04  tff(decl_39620, type, fn_food_processing_in_earthworm_24: $i > $i).
% 29.22/29.04  tff(decl_39621, type, fn_food_processing_in_earthworm_25: $i > $i).
% 29.22/29.04  tff(decl_39622, type, fn_food_processing_in_earthworm_26: $i > $i).
% 29.22/29.04  tff(decl_39623, type, fn_food_processing_in_earthworm_27: $i > $i).
% 29.22/29.04  tff(decl_39624, type, fn_food_processing_in_earthworm_28: $i > $i).
% 29.22/29.04  tff(decl_39625, type, fn_food_processing_in_earthworm_29: $i > $i).
% 29.22/29.04  tff(decl_39626, type, fn_food_processing_in_earthworm_30: $i > $i).
% 29.22/29.04  tff(decl_39627, type, fn_food_processing_in_earthworm_31: $i > $i).
% 29.22/29.04  tff(decl_39628, type, fn_food_processing_in_earthworm_32: $i > $i).
% 29.22/29.04  tff(decl_39629, type, fn_food_processing_in_earthworm_33: $i > $i).
% 29.22/29.04  tff(decl_39630, type, fn_food_processing_in_earthworm_34: $i > $i).
% 29.22/29.04  tff(decl_39631, type, fn_food_processing_in_earthworm_35: $i > $i).
% 29.22/29.04  tff(decl_39632, type, fn_food_processing_in_earthworm_36: $i > $i).
% 29.22/29.04  tff(decl_39633, type, fn_food_processing_in_earthworm_37: $i > $i).
% 29.22/29.04  tff(decl_39634, type, fn_wet_3: $i > $i).
% 29.22/29.04  tff(decl_39635, type, fn_wet_2: $i > $i).
% 29.22/29.04  tff(decl_39636, type, fn_wet_4: $i > $i).
% 29.22/29.04  tff(decl_39637, type, fn_wet_5: $i > $i).
% 29.22/29.04  tff(decl_39638, type, fn_mechanical_digestion_7: $i > $i).
% 29.22/29.04  tff(decl_39639, type, fn_mechanical_digestion_1: $i > $i).
% 29.22/29.04  tff(decl_39640, type, fn_wet_1: $i > $i).
% 29.22/29.04  tff(decl_39641, type, 'S2': $i).
% 29.22/29.04  tff(decl_39642, type, 'S1': $i).
% 29.22/29.04  tff(decl_39643, type, fn_food_processing_in_earthworm_13: $i > $i).
% 29.22/29.04  tff(decl_39644, type, fn_food_processing_in_earthworm_12: $i > $i).
% 29.22/29.04  tff(decl_39645, type, food_processing_in_grasshopper_1: $i > $o).
% 29.22/29.04  tff(decl_39646, type, 'Food-Processing-In-Grasshopper': $i).
% 29.22/29.04  tff(decl_39647, type, 'A sequence of events in grasshoppers that digest food into its usable forms and eliminate the wastes.': $i).
% 29.22/29.04  tff(decl_39648, type, 'food processing in grasshopper': $i).
% 29.22/29.04  tff(decl_39649, type, 'food-processing-in-grasshopper': $i).
% 29.22/29.04  tff(decl_39650, type, fn_food_processing_in_grasshopper_1: $i > $i).
% 29.22/29.04  tff(decl_39651, type, fn_food_processing_in_grasshopper_2: $i > $i).
% 29.22/29.04  tff(decl_39652, type, fn_food_processing_in_grasshopper_3: $i > $i).
% 29.22/29.04  tff(decl_39653, type, fn_food_processing_in_grasshopper_4: $i > $i).
% 29.22/29.04  tff(decl_39654, type, fn_food_processing_in_grasshopper_5: $i > $i).
% 29.22/29.04  tff(decl_39655, type, fn_food_processing_in_grasshopper_6: $i > $i).
% 29.22/29.04  tff(decl_39656, type, fn_food_processing_in_grasshopper_7: $i > $i).
% 29.22/29.04  tff(decl_39657, type, fn_food_processing_in_grasshopper_8: $i > $i).
% 29.22/29.04  tff(decl_39658, type, fn_food_processing_in_grasshopper_9: $i > $i).
% 29.22/29.04  tff(decl_39659, type, fn_food_processing_in_grasshopper_10: $i > $i).
% 29.22/29.04  tff(decl_39660, type, fn_food_processing_in_grasshopper_11: $i > $i).
% 29.22/29.04  tff(decl_39661, type, fn_food_processing_in_grasshopper_12: $i > $i).
% 29.22/29.04  tff(decl_39662, type, fn_food_processing_in_grasshopper_13: $i > $i).
% 29.22/29.04  tff(decl_39663, type, fn_food_processing_in_grasshopper_14: $i > $i).
% 29.22/29.04  tff(decl_39664, type, fn_food_processing_in_grasshopper_15: $i > $i).
% 29.22/29.04  tff(decl_39665, type, fn_food_processing_in_grasshopper_16: $i > $i).
% 29.22/29.04  tff(decl_39666, type, fn_food_processing_in_grasshopper_17: $i > $i).
% 29.22/29.04  tff(decl_39667, type, fn_food_processing_in_grasshopper_18: $i > $i).
% 29.22/29.04  tff(decl_39668, type, fn_food_processing_in_grasshopper_19: $i > $i).
% 29.22/29.04  tff(decl_39669, type, grasshopper_digestive_system_1: $i > $o).
% 29.22/29.04  tff(decl_39670, type, fn_food_processing_in_grasshopper_20: $i > $i).
% 29.22/29.04  tff(decl_39671, type, fn_food_processing_in_grasshopper_21: $i > $i).
% 29.22/29.04  tff(decl_39672, type, fn_food_processing_in_grasshopper_22: $i > $i).
% 29.22/29.04  tff(decl_39673, type, fn_food_processing_in_grasshopper_23: $i > $i).
% 29.22/29.04  tff(decl_39674, type, fn_food_processing_in_grasshopper_24: $i > $i).
% 29.22/29.04  tff(decl_39675, type, fn_food_processing_in_grasshopper_27: $i > $i).
% 29.22/29.04  tff(decl_39676, type, fn_food_processing_in_grasshopper_28: $i > $i).
% 29.22/29.04  tff(decl_39677, type, fn_food_processing_in_grasshopper_29: $i > $i).
% 29.22/29.04  tff(decl_39678, type, fn_grasshopper_44: $i > $i).
% 29.22/29.04  tff(decl_39679, type, fn_grasshopper_46: $i > $i).
% 29.22/29.04  tff(decl_39680, type, fn_grasshopper_29: $i > $i).
% 29.22/29.04  tff(decl_39681, type, fn_grasshopper_31: $i > $i).
% 29.22/29.04  tff(decl_39682, type, fn_grasshopper_25: $i > $i).
% 29.22/29.04  tff(decl_39683, type, fn_grasshopper_26: $i > $i).
% 29.22/29.04  tff(decl_39684, type, fn_grasshopper_30: $i > $i).
% 29.22/29.04  tff(decl_39685, type, fn_grasshopper_22: $i > $i).
% 29.22/29.04  tff(decl_39686, type, fn_grasshopper_45: $i > $i).
% 29.22/29.04  tff(decl_39687, type, fn_grasshopper_27: $i > $i).
% 29.22/29.04  tff(decl_39688, type, fn_grasshopper_28: $i > $i).
% 29.22/29.04  tff(decl_39689, type, fn_gastric_cecum_2: $i > $i).
% 29.22/29.04  tff(decl_39690, type, fn_gastric_cecum_1: $i > $i).
% 29.22/29.04  tff(decl_39691, type, fn_grasshopper_47: $i > $i).
% 29.22/29.04  tff(decl_39692, type, fn_grasshopper_32: $i > $i).
% 29.22/29.04  tff(decl_39693, type, fn_food_processing_in_grasshopper_26: $i > $i).
% 29.22/29.04  tff(decl_39694, type, fn_food_processing_in_grasshopper_25: $i > $i).
% 29.22/29.04  tff(decl_39695, type, food_processing_in_mammal_1: $i > $o).
% 29.22/29.04  tff(decl_39696, type, 'Food-Processing-In-Mammal': $i).
% 29.22/29.04  tff(decl_39697, type, 'A sequence of events in mammals that digest food into its usable forms and eliminate the wastes.': $i).
% 29.22/29.04  tff(decl_39698, type, 'food processing in mammal': $i).
% 29.22/29.04  tff(decl_39699, type, 'food-processing-in-mammal': $i).
% 29.22/29.04  tff(decl_39700, type, fn_food_processing_in_mammal_1: $i > $i).
% 29.22/29.04  tff(decl_39701, type, food_processing_in_porifera_1: $i > $o).
% 29.22/29.04  tff(decl_39702, type, 'Food-Processing-In-Porifera': $i).
% 29.22/29.04  tff(decl_39703, type, 'A sequence of events in poriferans that digest food into its usable forms and eliminate the wastes.': $i).
% 29.22/29.04  tff(decl_39704, type, 'food processing in porifera': $i).
% 29.22/29.04  tff(decl_39705, type, 'food-processing-in-porifera': $i).
% 29.22/29.04  tff(decl_39706, type, fn_food_processing_in_porifera_1: $i > $i).
% 29.22/29.04  tff(decl_39707, type, fn_food_processing_in_porifera_2: $i > $i).
% 29.22/29.04  tff(decl_39708, type, fn_food_processing_in_porifera_3: $i > $i).
% 29.22/29.04  tff(decl_39709, type, fn_food_processing_in_porifera_4: $i > $i).
% 29.22/29.04  tff(decl_39710, type, fn_food_processing_in_porifera_5: $i > $i).
% 29.22/29.04  tff(decl_39711, type, fn_food_processing_in_porifera_6: $i > $i).
% 29.22/29.04  tff(decl_39712, type, fn_food_processing_in_porifera_7: $i > $i).
% 29.22/29.04  tff(decl_39713, type, fn_food_processing_in_porifera_8: $i > $i).
% 29.22/29.04  tff(decl_39714, type, fn_food_processing_in_porifera_9: $i > $i).
% 29.22/29.04  tff(decl_39715, type, fn_food_processing_in_porifera_10: $i > $i).
% 29.22/29.04  tff(decl_39716, type, fn_food_processing_in_porifera_11: $i > $i).
% 29.22/29.04  tff(decl_39717, type, fn_food_processing_in_porifera_12: $i > $i).
% 29.22/29.04  tff(decl_39718, type, fn_food_processing_in_porifera_13: $i > $i).
% 29.22/29.04  tff(decl_39719, type, fn_food_processing_in_porifera_14: $i > $i).
% 29.22/29.04  tff(decl_39720, type, fn_food_processing_in_porifera_15: $i > $i).
% 29.22/29.04  tff(decl_39721, type, fn_food_processing_in_porifera_16: $i > $i).
% 29.22/29.04  tff(decl_39722, type, fn_food_processing_in_porifera_17: $i > $i).
% 29.22/29.04  tff(decl_39723, type, fn_food_processing_in_porifera_18: $i > $i).
% 29.22/29.04  tff(decl_39724, type, fn_food_processing_in_porifera_19: $i > $i).
% 29.22/29.04  tff(decl_39725, type, fn_food_processing_in_porifera_20: $i > $i).
% 29.22/29.04  tff(decl_39726, type, fn_food_processing_in_porifera_21: $i > $i).
% 29.22/29.04  tff(decl_39727, type, fn_food_processing_in_porifera_22: $i > $i).
% 29.22/29.04  tff(decl_39728, type, fn_food_processing_in_porifera_23: $i > $i).
% 29.22/29.04  tff(decl_39729, type, fn_food_processing_in_porifera_24: $i > $i).
% 29.22/29.04  tff(decl_39730, type, fn_food_processing_in_porifera_25: $i > $i).
% 29.22/29.04  tff(decl_39731, type, fn_food_processing_in_porifera_26: $i > $i).
% 29.22/29.04  tff(decl_39732, type, fn_food_processing_in_porifera_27: $i > $i).
% 29.22/29.04  tff(decl_39733, type, fn_food_processing_in_porifera_28: $i > $i).
% 29.22/29.04  tff(decl_39734, type, fn_food_processing_in_porifera_29: $i > $i).
% 29.22/29.04  tff(decl_39735, type, fn_food_processing_in_porifera_30: $i > $i).
% 29.22/29.04  tff(decl_39736, type, fn_food_processing_in_porifera_31: $i > $i).
% 29.22/29.04  tff(decl_39737, type, fn_food_processing_in_porifera_32: $i > $i).
% 29.22/29.04  tff(decl_39738, type, fn_food_processing_in_porifera_33: $i > $i).
% 29.22/29.04  tff(decl_39739, type, fn_food_processing_in_porifera_34: $i > $i).
% 29.22/29.04  tff(decl_39740, type, fn_food_processing_in_porifera_35: $i > $i).
% 29.22/29.04  tff(decl_39741, type, fn_food_processing_in_porifera_36: $i > $i).
% 29.22/29.04  tff(decl_39742, type, fn_food_processing_in_porifera_37: $i > $i).
% 29.22/29.04  tff(decl_39743, type, fn_food_processing_in_porifera_38: $i > $i).
% 29.22/29.04  tff(decl_39744, type, fn_food_processing_in_porifera_39: $i > $i).
% 29.22/29.04  tff(decl_39745, type, fn_food_processing_in_porifera_40: $i > $i).
% 29.22/29.04  tff(decl_39746, type, fn_food_processing_in_porifera_41: $i > $i).
% 29.22/29.04  tff(decl_39747, type, fn_food_processing_in_porifera_42: $i > $i).
% 29.22/29.04  tff(decl_39748, type, fn_food_processing_in_porifera_43: $i > $i).
% 29.22/29.04  tff(decl_39749, type, fn_food_processing_in_porifera_44: $i > $i).
% 29.22/29.04  tff(decl_39750, type, fn_intracellular_digestion_8: $i > $i).
% 29.22/29.04  tff(decl_39751, type, fn_porifera_24: $i > $i).
% 29.22/29.04  tff(decl_39752, type, fn_porifera_34: $i > $i).
% 29.22/29.04  tff(decl_39753, type, fn_porifera_28: $i > $i).
% 29.22/29.04  tff(decl_39754, type, fn_porifera_12: $i > $i).
% 29.22/29.04  tff(decl_39755, type, fn_intracellular_digestion_3: $i > $i).
% 29.22/29.04  tff(decl_39756, type, fn_intracellular_digestion_30: $i > $i).
% 29.22/29.04  tff(decl_39757, type, fn_phagocytosis_46: $i > $i).
% 29.22/29.04  tff(decl_39758, type, fn_porifera_2: $i > $i).
% 29.22/29.04  tff(decl_39759, type, fn_intracellular_digestion_9: $i > $i).
% 29.22/29.04  tff(decl_39760, type, fn_porifera_11: $i > $i).
% 29.22/29.04  tff(decl_39761, type, fn_porifera_26: $i > $i).
% 29.22/29.04  tff(decl_39762, type, fn_porifera_32: $i > $i).
% 29.22/29.04  tff(decl_39763, type, 'ID1': $i).
% 29.22/29.04  tff(decl_39764, type, 'ID2': $i).
% 29.22/29.04  tff(decl_39765, type, fn_food_processing_in_porifera_46: $i > $i).
% 29.22/29.04  tff(decl_39766, type, fn_food_processing_in_porifera_45: $i > $i).
% 29.22/29.04  tff(decl_39767, type, food_processing_in_ruminant_1: $i > $o).
% 29.22/29.04  tff(decl_39768, type, 'Food-Processing-In-Ruminant': $i).
% 29.22/29.04  tff(decl_39769, type, 'A sequence of events in ruminants that digest food into its usable forms and eliminate the wastes.': $i).
% 29.22/29.04  tff(decl_39770, type, 'food processing in ruminant': $i).
% 29.22/29.04  tff(decl_39771, type, 'food-processing-in-ruminant': $i).
% 29.22/29.04  tff(decl_39772, type, 'Food-Vacuole': $i).
% 29.22/29.04  tff(decl_39773, type, 'Food vacoule is a food storing vacuole': $i).
% 29.22/29.04  tff(decl_39774, type, 'vacuole of food': $i).
% 29.22/29.04  tff(decl_39775, type, 'food vacuole': $i).
% 29.22/29.04  tff(decl_39776, type, 'food-vacuole': $i).
% 29.22/29.04  tff(decl_39777, type, fn_food_vacuole_2: $i > $i).
% 29.22/29.04  tff(decl_39778, type, fn_food_vacuole_3: $i > $i).
% 29.22/29.04  tff(decl_39779, type, fn_food_vacuole_7: $i > $i).
% 29.22/29.04  tff(decl_39780, type, fn_food_vacuole_8: $i > $i).
% 29.22/29.04  tff(decl_39781, type, fn_food_vacuole_9: $i > $i).
% 29.22/29.04  tff(decl_39782, type, fn_food_vacuole_10: $i > $i).
% 29.22/29.04  tff(decl_39783, type, fn_food_vacuole_11: $i > $i).
% 29.22/29.04  tff(decl_39784, type, fn_food_vacuole_12: $i > $i).
% 29.22/29.04  tff(decl_39785, type, fn_food_vacuole_13: $i > $i).
% 29.22/29.04  tff(decl_39786, type, fn_food_vacuole_14: $i > $i).
% 29.22/29.04  tff(decl_39787, type, fn_food_vacuole_15: $i > $i).
% 29.22/29.04  tff(decl_39788, type, fn_food_vacuole_16: $i > $i).
% 29.22/29.04  tff(decl_39789, type, fn_food_vacuole_18: $i > $i).
% 29.22/29.04  tff(decl_39790, type, fn_food_vacuole_19: $i > $i).
% 29.22/29.04  tff(decl_39791, type, fn_food_vacuole_20: $i > $i).
% 29.22/29.04  tff(decl_39792, type, fn_food_vacuole_21: $i > $i).
% 29.22/29.04  tff(decl_39793, type, fn_food_vacuole_23: $i > $i).
% 29.22/29.04  tff(decl_39794, type, fn_food_vacuole_25: $i > $i).
% 29.22/29.04  tff(decl_39795, type, fn_food_vacuole_26: $i > $i).
% 29.22/29.04  tff(decl_39796, type, fn_food_vacuole_27: $i > $i).
% 29.22/29.04  tff(decl_39797, type, fn_food_vacuole_28: $i > $i).
% 29.22/29.04  tff(decl_39798, type, fn_lipid_1: $i > $i).
% 29.22/29.04  tff(decl_39799, type, fn_lipid_2: $i > $i).
% 29.22/29.04  tff(decl_39800, type, fn_food_vacuole_5: $i > $i).
% 29.22/29.04  tff(decl_39801, type, fn_vacuole_8: $i > $i).
% 29.22/29.04  tff(decl_39802, type, fn_food_vacuole_6: $i > $i).
% 29.22/29.04  tff(decl_39803, type, food_web_1: $i > $o).
% 29.22/29.04  tff(decl_39804, type, 'Food-Web': $i).
% 29.22/29.04  tff(decl_39805, type, 'A diagram of trophic relationships in an ecosystem.': $i).
% 29.22/29.04  tff(decl_39806, type, 'web of food': $i).
% 29.22/29.04  tff(decl_39807, type, 'food web': $i).
% 29.22/29.04  tff(decl_39808, type, 'food-web': $i).
% 29.22/29.04  tff(decl_39809, type, fn_food_web_1: $i > $i).
% 29.22/29.04  tff(decl_39810, type, fn_food_web_2: $i > $i).
% 29.22/29.04  tff(decl_39811, type, foot_1: $i > $o).
% 29.22/29.04  tff(decl_39812, type, 'Foot': $i).
% 29.22/29.04  tff(decl_39813, type, '(1) In the sporophyte of a bryophyte, the structure that collects photosynthate, water, minerals, and amino acids from the parent gametophyte; (2) In molluscs, a muscular structure usually located ventrally and used for locomotion; (3) In vertebrates, the distal portion of a limb that bears the animal\\s weight and is used for locomotion.': $i).
% 29.22/29.04  tff(decl_39814, type, foot: $i).
% 29.22/29.04  tff(decl_39815, type, foraging_1: $i > $o).
% 29.22/29.04  tff(decl_39816, type, 'Foraging': $i).
% 29.22/29.04  tff(decl_39817, type, 'The search for and exploitation of food sources.': $i).
% 29.22/29.04  tff(decl_39818, type, forage: $i).
% 29.22/29.04  tff(decl_39819, type, foraging: $i).
% 29.22/29.04  tff(decl_39820, type, 'Foraminiferan': $i).
% 29.22/29.04  tff(decl_39821, type, 'Member of a group of amoeboid protists that secrete a shell of CaCO3 and extend pseudopodia through pores in the shell.': $i).
% 29.22/29.04  tff(decl_39822, type, foram: $i).
% 29.22/29.04  tff(decl_39823, type, foraminiferan: $i).
% 29.22/29.04  tff(decl_39824, type, 'Force': $i).
% 29.22/29.04  tff(decl_39825, type, 'In physics, a force is any influence that causes a free body to undergo a change in speed, a change in direction, or a change in shape.': $i).
% 29.22/29.04  tff(decl_39826, type, force: $i).
% 29.22/29.04  tff(decl_39827, type, 'Forebrain': $i).
% 29.22/29.04  tff(decl_39828, type, 'The ancestral and embryonic region of the vertebrate brain that develops into the thalamus, hypothalamus, and cerebrum.': $i).
% 29.22/29.04  tff(decl_39829, type, prosencephalon: $i).
% 29.22/29.04  tff(decl_39830, type, forebrain: $i).
% 29.22/29.04  tff(decl_39831, type, 'Foregut': $i).
% 29.22/29.04  tff(decl_39832, type, 'Anterior (frontmost) region of the alimentary canal in some animals which consists of the mouth, crop and esophagus.': $i).
% 29.22/29.04  tff(decl_39833, type, foregut: $i).
% 29.22/29.04  tff(decl_39834, type, foreign_1: $i > $o).
% 29.22/29.04  tff(decl_39835, type, 'Foreign': $i).
% 29.22/29.04  tff(decl_39836, type, 'Of non-native origin.': $i).
% 29.22/29.04  tff(decl_39837, type, foreign: $i).
% 29.22/29.04  tff(decl_39838, type, foreign_cell_1: $i > $o).
% 29.22/29.04  tff(decl_39839, type, 'Foreign-Cell': $i).
% 29.22/29.04  tff(decl_39840, type, 'A cell foreign to the body is foreign cell.': $i).
% 29.22/29.04  tff(decl_39841, type, 'invasive cell': $i).
% 29.22/29.04  tff(decl_39842, type, 'foreign cell': $i).
% 29.22/29.04  tff(decl_39843, type, 'foreign-cell': $i).
% 29.22/29.04  tff(decl_39844, type, 'Foreign-DNA': $i).
% 29.22/29.04  tff(decl_39845, type, 'DNA belonging to or extracted from another organism.': $i).
% 29.22/29.04  tff(decl_39846, type, 'foreign dna': $i).
% 29.22/29.04  tff(decl_39847, type, 'foreign-dna': $i).
% 29.22/29.04  tff(decl_39848, type, 'Foreign-Substance': $i).
% 29.22/29.04  tff(decl_39849, type, 'A substance foreign to the body is a foreign substance. Examples of foreign substances are allergens.': $i).
% 29.22/29.04  tff(decl_39850, type, 'foreign particle': $i).
% 29.22/29.04  tff(decl_39851, type, 'foreign substance': $i).
% 29.22/29.04  tff(decl_39852, type, 'foreign-substance': $i).
% 29.22/29.04  tff(decl_39853, type, forensic_detection_of_similarities_and_differences_in_dna_samples_1: $i > $o).
% 29.22/29.04  tff(decl_39854, type, 'Forensic-Detection-Of-Similarities-And-Differences-In-DNA-Samples': $i).
% 29.22/29.04  tff(decl_39855, type, 'A laboratory method using Southern blotting for detecting the similarities and differences in the DNA of two individuals.': $i).
% 29.22/29.04  tff(decl_39856, type, 'rflp in forensics': $i).
% 29.22/29.04  tff(decl_39857, type, 'dna analysis in forensics': $i).
% 29.22/29.04  tff(decl_39858, type, 'forensic detection of similarities and differences in dna sample': $i).
% 29.22/29.04  tff(decl_39859, type, 'forensic-detection-of-similarities-and-differences-in-dna-sample': $i).
% 29.22/29.04  tff(decl_39860, type, southern_blotting_1: $i > $o).
% 29.22/29.04  tff(decl_39861, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_1: $i > $i).
% 29.22/29.04  tff(decl_39862, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_3: $i > $i).
% 29.22/29.04  tff(decl_39863, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_4: $i > $i).
% 29.22/29.04  tff(decl_39864, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_5: $i > $i).
% 29.22/29.04  tff(decl_39865, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_6: $i > $i).
% 29.22/29.04  tff(decl_39866, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_7: $i > $i).
% 29.22/29.04  tff(decl_39867, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_8: $i > $i).
% 29.22/29.04  tff(decl_39868, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_9: $i > $i).
% 29.22/29.04  tff(decl_39869, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_10: $i > $i).
% 29.22/29.04  tff(decl_39870, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_11: $i > $i).
% 29.22/29.04  tff(decl_39871, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_12: $i > $i).
% 29.22/29.04  tff(decl_39872, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_13: $i > $i).
% 29.22/29.04  tff(decl_39873, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_14: $i > $i).
% 29.22/29.04  tff(decl_39874, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_15: $i > $i).
% 29.22/29.04  tff(decl_39875, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_16: $i > $i).
% 29.22/29.04  tff(decl_39876, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_17: $i > $i).
% 29.22/29.04  tff(decl_39877, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_18: $i > $i).
% 29.22/29.04  tff(decl_39878, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_19: $i > $i).
% 29.22/29.04  tff(decl_39879, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_20: $i > $i).
% 29.22/29.04  tff(decl_39880, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_21: $i > $i).
% 29.22/29.04  tff(decl_39881, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_22: $i > $i).
% 29.22/29.04  tff(decl_39882, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_23: $i > $i).
% 29.22/29.04  tff(decl_39883, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_24: $i > $i).
% 29.22/29.04  tff(decl_39884, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_25: $i > $i).
% 29.22/29.04  tff(decl_39885, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_26: $i > $i).
% 29.22/29.04  tff(decl_39886, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_27: $i > $i).
% 29.22/29.04  tff(decl_39887, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_28: $i > $i).
% 29.22/29.04  tff(decl_39888, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_29: $i > $i).
% 29.22/29.04  tff(decl_39889, type, fn_forensic_detection_of_similarities_and_differences_in_dna_samples_30: $i > $i).
% 29.22/29.04  tff(decl_39890, type, fn_human_cell_13: $i > $i).
% 29.22/29.04  tff(decl_39891, type, fn_restriction_fragment_length_polymorphism_19: $i > $i).
% 29.22/29.04  tff(decl_39892, type, restriction_fragment_length_polymorphism_0: $i).
% 29.22/29.04  tff(decl_39893, type, "1000": $i).
% 29.22/29.04  tff(decl_39894, type, fn_southern_blotting_14: $i > $i).
% 29.22/29.04  tff(decl_39895, type, fn_southern_blotting_15: $i > $i).
% 29.22/29.04  tff(decl_39896, type, fn_restriction_fragment_analysis_5: $i > $i).
% 29.22/29.04  tff(decl_39897, type, fn_restriction_fragment_analysis_6: $i > $i).
% 29.22/29.04  tff(decl_39898, type, fn_restriction_fragment_analysis_12: $i > $i).
% 29.22/29.04  tff(decl_39899, type, fn_restriction_fragment_analysis_8: $i > $i).
% 29.22/29.04  tff(decl_39900, type, fn_restriction_fragment_analysis_7: $i > $i).
% 29.22/29.04  tff(decl_39901, type, fn_restriction_fragment_analysis_11: $i > $i).
% 29.22/29.04  tff(decl_39902, type, forensic_science_1: $i > $o).
% 29.22/29.04  tff(decl_39903, type, 'Forensic-Science': $i).
% 29.22/29.04  tff(decl_39904, type, 'The use of a broad range of sciences to address questions of interest to a criminal or civil legal system.': $i).
% 29.22/29.04  tff(decl_39905, type, forensics: $i).
% 29.22/29.04  tff(decl_39906, type, 'forensic science': $i).
% 29.22/29.04  tff(decl_39907, type, 'forensic-science': $i).
% 29.22/29.04  tff(decl_39908, type, forest_1: $i > $o).
% 29.22/29.04  tff(decl_39909, type, 'Forest': $i).
% 29.22/29.04  tff(decl_39910, type, 'An area with a high density of trees.  More broadly, any area with tall, densely packed vegetation, such as a kelp forest.': $i).
% 29.22/29.04  tff(decl_39911, type, forest: $i).
% 29.22/29.04  tff(decl_39912, type, fn_forest_1: $i > $i).
% 29.22/29.04  tff(decl_39913, type, fn_forest_2: $i > $i).
% 29.22/29.04  tff(decl_39914, type, fn_forest_3: $i > $i).
% 29.22/29.04  tff(decl_39915, type, fn_forest_4: $i > $i).
% 29.22/29.04  tff(decl_39916, type, fn_forest_5: $i > $i).
% 29.22/29.04  tff(decl_39917, type, fn_forest_6: $i > $i).
% 29.22/29.04  tff(decl_39918, type, fn_forest_7: $i > $i).
% 29.22/29.04  tff(decl_39919, type, fn_forest_8: $i > $i).
% 29.22/29.04  tff(decl_39920, type, fn_forest_9: $i > $i).
% 29.22/29.04  tff(decl_39921, type, fn_forest_10: $i > $i).
% 29.22/29.04  tff(decl_39922, type, fn_forest_11: $i > $i).
% 29.22/29.04  tff(decl_39923, type, fn_forest_12: $i > $i).
% 29.22/29.04  tff(decl_39924, type, stone_1: $i > $o).
% 29.22/29.04  tff(decl_39925, type, fn_forest_13: $i > $i).
% 29.22/29.04  tff(decl_39926, type, fn_forest_14: $i > $i).
% 29.22/29.04  tff(decl_39927, type, fn_forest_15: $i > $i).
% 29.22/29.04  tff(decl_39928, type, fn_forest_16: $i > $i).
% 29.22/29.04  tff(decl_39929, type, leaching_1: $i > $o).
% 29.22/29.04  tff(decl_39930, type, fn_forest_17: $i > $i).
% 29.22/29.04  tff(decl_39931, type, fn_forest_18: $i > $i).
% 29.22/29.04  tff(decl_39932, type, fn_forest_19: $i > $i).
% 29.22/29.04  tff(decl_39933, type, fn_leaching_2: $i > $i).
% 29.22/29.04  tff(decl_39934, type, fn_leaching_3: $i > $i).
% 29.22/29.04  tff(decl_39935, type, fn_leaching_1: $i > $i).
% 29.22/29.04  tff(decl_39936, type, fn_ground_1: $i > $i).
% 29.22/29.04  tff(decl_39937, type, forget_1: $i > $o).
% 29.22/29.04  tff(decl_39938, type, 'Forget': $i).
% 29.22/29.04  tff(decl_39939, type, forget: $i).
% 29.22/29.04  tff(decl_39940, type, bury: $i).
% 29.22/29.04  tff(decl_39941, type, 'draw a blank': $i).
% 29.22/29.04  tff(decl_39942, type, draw_a_blank: $i).
% 29.22/29.04  tff(decl_39943, type, 'blank out': $i).
% 29.22/29.04  tff(decl_39944, type, blank_out: $i).
% 29.22/29.04  tff(decl_39945, type, fn_forget_1: $i > $i).
% 29.22/29.04  tff(decl_39946, type, fn_forget_2: $i > $i).
% 29.22/29.04  tff(decl_39947, type, formaldehyde_1: $i > $o).
% 29.22/29.04  tff(decl_39948, type, 'Formaldehyde': $i).
% 29.22/29.04  tff(decl_39949, type, 'A colorless gaseous compound (molecular formula CH2O), the simplest aldehyde': $i).
% 29.22/29.04  tff(decl_39950, type, ch2o: $i).
% 29.22/29.04  tff(decl_39951, type, formaldehyde: $i).
% 29.22/29.04  tff(decl_39952, type, fn_formaldehyde_1: $i > $i).
% 29.22/29.04  tff(decl_39953, type, fn_formaldehyde_2: $i > $i).
% 29.22/29.04  tff(decl_39954, type, fn_formaldehyde_3: $i > $i).
% 29.22/29.04  tff(decl_39955, type, fn_formaldehyde_4: $i > $i).
% 29.22/29.04  tff(decl_39956, type, fn_formaldehyde_5: $i > $i).
% 29.22/29.04  tff(decl_39957, type, fn_formaldehyde_6: $i > $i).
% 29.22/29.04  tff(decl_39958, type, fn_formaldehyde_7: $i > $i).
% 29.22/29.04  tff(decl_39959, type, fn_formaldehyde_8: $i > $i).
% 29.22/29.04  tff(decl_39960, type, fn_formaldehyde_9: $i > $i).
% 29.22/29.04  tff(decl_39961, type, fn_formaldehyde_10: $i > $i).
% 29.22/29.04  tff(decl_39962, type, fn_formaldehyde_11: $i > $i).
% 29.22/29.04  tff(decl_39963, type, fn_formaldehyde_12: $i > $i).
% 29.22/29.04  tff(decl_39964, type, fn_formaldehyde_13: $i > $i).
% 29.22/29.04  tff(decl_39965, type, fn_formaldehyde_14: $i > $i).
% 29.22/29.04  tff(decl_39966, type, fn_formaldehyde_15: $i > $i).
% 29.22/29.04  tff(decl_39967, type, fn_formaldehyde_16: $i > $i).
% 29.22/29.04  tff(decl_39968, type, format_equation_1: $i > $o).
% 29.22/29.04  tff(decl_39969, type, 'Format-Equation': $i).
% 29.22/29.04  tff(decl_39970, type, 'equation of format': $i).
% 29.22/29.04  tff(decl_39971, type, 'format equation': $i).
% 29.22/29.04  tff(decl_39972, type, 'format-equation': $i).
% 29.22/29.04  tff(decl_39973, type, 'Formation-Of-Cell-Plate': $i).
% 29.22/29.04  tff(decl_39974, type, 'During mitosis in plant cells, the process of forming a new cell wall, which results in separation of the two daughter cells.': $i).
% 29.22/29.04  tff(decl_39975, type, 'formation of cell plate': $i).
% 29.22/29.04  tff(decl_39976, type, 'formation-of-cell-plate': $i).
% 29.22/29.04  tff(decl_39977, type, fn_formation_of_cell_plate_1: $i > $i).
% 29.22/29.04  tff(decl_39978, type, fn_formation_of_cell_plate_3: $i > $i).
% 29.22/29.04  tff(decl_39979, type, fn_formation_of_cell_plate_4: $i > $i).
% 29.22/29.04  tff(decl_39980, type, fn_formation_of_cell_plate_6: $i > $i).
% 29.22/29.04  tff(decl_39981, type, fn_formation_of_cell_plate_7: $i > $i).
% 29.22/29.04  tff(decl_39982, type, fn_formation_of_cell_plate_8: $i > $i).
% 29.22/29.04  tff(decl_39983, type, fn_formation_of_cell_plate_9: $i > $i).
% 29.22/29.04  tff(decl_39984, type, fn_formation_of_cell_plate_11: $i > $i).
% 29.22/29.04  tff(decl_39985, type, fn_formation_of_cell_plate_12: $i > $i).
% 29.22/29.04  tff(decl_39986, type, fn_formation_of_cell_plate_13: $i > $i).
% 29.22/29.04  tff(decl_39987, type, 'Formation-Of-Cleavage-Furrow': $i).
% 29.22/29.04  tff(decl_39988, type, 'During mitosis in animal cells, the process of pinching together of the plasma membrane and cytoplasm which results in separation of the two daughter cells.': $i).
% 29.22/29.04  tff(decl_39989, type, 'formation of cleavage furrow': $i).
% 29.22/29.04  tff(decl_39990, type, 'formation-of-cleavage-furrow': $i).
% 29.22/29.04  tff(decl_39991, type, formation_of_water_molecule_1: $i > $o).
% 29.22/29.04  tff(decl_39992, type, fn_formation_of_water_molecule_8: $i > $i).
% 29.22/29.04  tff(decl_39993, type, fn_formation_of_water_molecule_6: $i > $i).
% 29.22/29.04  tff(decl_39994, type, fn_formation_of_water_molecule_7: $i > $i).
% 29.22/29.04  tff(decl_39995, type, fn_formation_of_water_molecule_5: $i > $i).
% 29.22/29.04  tff(decl_39996, type, 'Formation-Of-Water-Molecule': $i).
% 29.22/29.04  tff(decl_39997, type, 'Condensation of H+ and OH- to form water.': $i).
% 29.22/29.04  tff(decl_39998, type, 'synthesis of water': $i).
% 29.22/29.04  tff(decl_39999, type, 'formation of water': $i).
% 29.22/29.04  tff(decl_40000, type, 'condensation reaction of water': $i).
% 29.22/29.04  tff(decl_40001, type, 'water synthesis': $i).
% 29.22/29.04  tff(decl_40002, type, 'water formation': $i).
% 29.22/29.04  tff(decl_40003, type, 'form a water molecule': $i).
% 29.22/29.04  tff(decl_40004, type, 'formation of water molecule': $i).
% 29.22/29.04  tff(decl_40005, type, 'formation-of-water-molecule': $i).
% 29.22/29.04  tff(decl_40006, type, fn_formation_of_water_molecule_1: $i > $i).
% 29.22/29.04  tff(decl_40007, type, fn_formation_of_water_molecule_3: $i > $i).
% 29.22/29.04  tff(decl_40008, type, fn_formation_of_water_molecule_4: $i > $i).
% 29.22/29.04  tff(decl_40009, type, 'Formic-Acid': $i).
% 29.22/29.04  tff(decl_40010, type, 'Formic acid (also called methanoic acid) is the simplest carboxylic acid. Its formula is HCOOH or HCO2H. It is an important intermediate in chemical synthesis and occurs naturally, most notably in the venom of bee and ant stings.': $i).
% 29.22/29.04  tff(decl_40011, type, 'formic acid': $i).
% 29.22/29.04  tff(decl_40012, type, 'formic-acid': $i).
% 29.22/29.04  tff(decl_40013, type, fn_formic_acid_1: $i > $i).
% 29.22/29.04  tff(decl_40014, type, 'Formin': $i).
% 29.22/29.04  tff(decl_40015, type, 'Protein first identified in yeast cells which plays a role in the growth of cytoskeletal elements in cell division.': $i).
% 29.22/29.04  tff(decl_40016, type, formin: $i).
% 29.22/29.04  tff(decl_40017, type, 'Forward-Reaction': $i).
% 29.22/29.04  tff(decl_40018, type, 'A chemical reaction symbolized by a chemical equation in which the reactants and product are separated by an arrow that points to the right, toward the products.': $i).
% 29.22/29.04  tff(decl_40019, type, 'reaction of forward': $i).
% 29.22/29.04  tff(decl_40020, type, 'forward reaction': $i).
% 29.22/29.04  tff(decl_40021, type, 'forward-reaction': $i).
% 29.22/29.04  tff(decl_40022, type, fossil_1: $i > $o).
% 29.22/29.04  tff(decl_40023, type, 'Fossil': $i).
% 29.22/29.04  tff(decl_40024, type, 'Any remains, impression, or trace of a living thing of a former geologic age.': $i).
% 29.22/29.04  tff(decl_40025, type, fossil: $i).
% 29.22/29.04  tff(decl_40026, type, 'Fossil-Fuel': $i).
% 29.22/29.04  tff(decl_40027, type, 'Fossil fuel is the fuel produced from the dead remains of the ancient organisms. They comprises of coal, oil, gas etc.': $i).
% 29.22/29.04  tff(decl_40028, type, 'organic fuel': $i).
% 29.22/29.04  tff(decl_40029, type, 'organic-fuel': $i).
% 29.22/29.04  tff(decl_40030, type, 'fuel of fossil': $i).
% 29.22/29.04  tff(decl_40031, type, 'fossil fuel': $i).
% 29.22/29.04  tff(decl_40032, type, 'fossil-fuel': $i).
% 29.22/29.04  tff(decl_40033, type, fn_fossil_fuel_1: $i > $i).
% 29.22/29.04  tff(decl_40034, type, nonrenewable_resource_1: $i > $o).
% 29.22/29.04  tff(decl_40035, type, fn_fossil_fuel_3: $i > $i).
% 29.22/29.04  tff(decl_40036, type, fn_fossil_fuel_4: $i > $i).
% 29.22/29.04  tff(decl_40037, type, fn_fossil_fuel_5: $i > $i).
% 29.22/29.04  tff(decl_40038, type, fn_fossil_fuel_7: $i > $i).
% 29.22/29.04  tff(decl_40039, type, fn_fossil_fuel_8: $i > $i).
% 29.22/29.04  tff(decl_40040, type, fn_fossil_fuel_9: $i > $i).
% 29.22/29.04  tff(decl_40041, type, create_0: $i).
% 29.22/29.04  tff(decl_40042, type, hydrocarbon_molecule_0: $i).
% 29.22/29.04  tff(decl_40043, type, 'Fossil-Record': $i).
% 29.22/29.04  tff(decl_40044, type, 'The collection of fossils found that, although incomplete, is substantial and chronicles evolutionary history.': $i).
% 29.22/29.04  tff(decl_40045, type, 'record of fossil': $i).
% 29.22/29.04  tff(decl_40046, type, 'fossil record': $i).
% 29.22/29.04  tff(decl_40047, type, 'fossil-record': $i).
% 29.22/29.04  tff(decl_40048, type, founder_effect_1: $i > $o).
% 29.22/29.04  tff(decl_40049, type, 'Founder-Effect': $i).
% 29.22/29.04  tff(decl_40050, type, 'In population genetics, the founder effect is the loss of genetic diversity when a new population arises from a small number of members from a larger population. This form of genetic drift occurs because the alleles of the new population represent only a small fraction of the genetic diversity of the larger population.': $i).
% 29.22/29.04  tff(decl_40051, type, 'effect of founder': $i).
% 29.22/29.04  tff(decl_40052, type, 'founder effect': $i).
% 29.22/29.04  tff(decl_40053, type, 'founder-effect': $i).
% 29.22/29.04  tff(decl_40054, type, fovea_1: $i > $o).
% 29.22/29.04  tff(decl_40055, type, 'Fovea': $i).
% 29.22/29.04  tff(decl_40056, type, 'The area of the retina that contains the highest concentration of cones and is responsible for sharp central vision.': $i).
% 29.22/29.04  tff(decl_40057, type, fovea: $i).
% 29.22/29.04  tff(decl_40058, type, foxp2_gene_1: $i > $o).
% 29.22/29.04  tff(decl_40059, type, 'FOXP2-Gene': $i).
% 29.22/29.04  tff(decl_40060, type, 'Forkhead box protein P2 also known as FOXP2 is a protein that in humans is encoded by the FOXP2 gene.': $i).
% 29.22/29.04  tff(decl_40061, type, 'foxp2 gene': $i).
% 29.22/29.04  tff(decl_40062, type, 'foxp2-gene': $i).
% 29.22/29.04  tff(decl_40063, type, fn_foxp2_gene_2: $i > $i).
% 29.22/29.04  tff(decl_40064, type, fn_foxp2_gene_3: $i > $i).
% 29.22/29.04  tff(decl_40065, type, fn_foxp2_gene_4: $i > $i).
% 29.22/29.04  tff(decl_40066, type, fn_foxp2_gene_5: $i > $i).
% 29.22/29.04  tff(decl_40067, type, fn_foxp2_gene_6: $i > $i).
% 29.22/29.04  tff(decl_40068, type, fn_foxp2_gene_7: $i > $i).
% 29.22/29.04  tff(decl_40069, type, fn_foxp2_gene_8: $i > $i).
% 29.22/29.04  tff(decl_40070, type, fn_foxp2_gene_9: $i > $i).
% 29.22/29.04  tff(decl_40071, type, fn_foxp2_gene_10: $i > $i).
% 29.22/29.04  tff(decl_40072, type, fn_foxp2_gene_13: $i > $i).
% 29.22/29.04  tff(decl_40073, type, fn_foxp2_gene_14: $i > $i).
% 29.22/29.04  tff(decl_40074, type, fn_foxp2_gene_15: $i > $i).
% 29.22/29.04  tff(decl_40075, type, fn_foxp2_gene_16: $i > $i).
% 29.22/29.04  tff(decl_40076, type, fn_foxp2_gene_17: $i > $i).
% 29.22/29.04  tff(decl_40077, type, fn_foxp2_gene_18: $i > $i).
% 29.22/29.04  tff(decl_40078, type, fn_foxp2_gene_19: $i > $i).
% 29.22/29.04  tff(decl_40079, type, fn_foxp2_gene_20: $i > $i).
% 29.22/29.04  tff(decl_40080, type, fn_foxp2_gene_21: $i > $i).
% 29.22/29.04  tff(decl_40081, type, fn_foxp2_gene_22: $i > $i).
% 29.22/29.04  tff(decl_40082, type, fn_foxp2_gene_23: $i > $i).
% 29.22/29.04  tff(decl_40083, type, fn_foxp2_gene_24: $i > $i).
% 29.22/29.04  tff(decl_40084, type, fn_foxp2_gene_25: $i > $i).
% 29.22/29.04  tff(decl_40085, type, fn_foxp2_gene_26: $i > $i).
% 29.22/29.04  tff(decl_40086, type, fn_foxp2_gene_27: $i > $i).
% 29.22/29.04  tff(decl_40087, type, fn_foxp2_gene_28: $i > $i).
% 29.22/29.04  tff(decl_40088, type, fn_foxp2_gene_29: $i > $i).
% 29.22/29.04  tff(decl_40089, type, fn_foxp2_gene_30: $i > $i).
% 29.22/29.04  tff(decl_40090, type, fn_foxp2_gene_31: $i > $i).
% 29.22/29.04  tff(decl_40091, type, fn_foxp2_gene_32: $i > $i).
% 29.22/29.04  tff(decl_40092, type, fn_foxp2_gene_33: $i > $i).
% 29.22/29.04  tff(decl_40093, type, fn_foxp2_gene_34: $i > $i).
% 29.22/29.04  tff(decl_40094, type, fn_foxp2_gene_35: $i > $i).
% 29.22/29.04  tff(decl_40095, type, fn_foxp2_gene_38: $i > $i).
% 29.22/29.04  tff(decl_40096, type, fn_phosphodiester_bond_23: $i > $i).
% 29.22/29.04  tff(decl_40097, type, fn_phosphodiester_bond_38: $i > $i).
% 29.22/29.04  tff(decl_40098, type, fn_foxp2_gene_36: $i > $i).
% 29.22/29.04  tff(decl_40099, type, fn_regulatory_gene_12: $i > $i).
% 29.22/29.04  tff(decl_40100, type, fn_foxp2_gene_37: $i > $i).
% 29.22/29.04  tff(decl_40101, type, fn_regulatory_gene_13: $i > $i).
% 29.22/29.04  tff(decl_40102, type, fn_regulatory_gene_7: $i > $i).
% 29.22/29.04  tff(decl_40103, type, fn_regulatory_gene_9: $i > $i).
% 29.22/29.04  tff(decl_40104, type, fn_regulatory_gene_8: $i > $i).
% 29.22/29.04  tff(decl_40105, type, fn_regulatory_gene_6: $i > $i).
% 29.22/29.04  tff(decl_40106, type, fn_regulatory_gene_1: $i > $i).
% 29.22/29.04  tff(decl_40107, type, fn_regulatory_gene_10: $i > $i).
% 29.22/29.04  tff(decl_40108, type, fn_regulatory_gene_11: $i > $i).
% 29.22/29.04  tff(decl_40109, type, fn_regulatory_gene_4: $i > $i).
% 29.22/29.04  tff(decl_40110, type, fn_regulatory_gene_5: $i > $i).
% 29.22/29.04  tff(decl_40111, type, fragmentation_1: $i > $o).
% 29.22/29.04  tff(decl_40112, type, 'Fragmentation': $i).
% 29.22/29.04  tff(decl_40113, type, 'A method of asexual multiplication in which a single organism breaks into fragments that regenerate into new individuals.': $i).
% 29.22/29.04  tff(decl_40114, type, fragment: $i).
% 29.22/29.04  tff(decl_40115, type, fragmentation: $i).
% 29.22/29.04  tff(decl_40116, type, frameshift_mutation_1: $i > $o).
% 29.22/29.04  tff(decl_40117, type, 'Frameshift-Mutation': $i).
% 29.22/29.04  tff(decl_40118, type, 'A type of mutation that occurs when the number of nucleotides inserted into or deleted from a gene is not divisable by three. This results in a different translation from the original DNA transcript and a different amino acid sequence.': $i).
% 29.22/29.04  tff(decl_40119, type, 'frameshift mutation': $i).
% 29.22/29.04  tff(decl_40120, type, 'frameshift-mutation': $i).
% 29.22/29.04  tff(decl_40121, type, fn_frameshift_mutation_1: $i > $i).
% 29.22/29.04  tff(decl_40122, type, reading_frame_1: $i > $o).
% 29.22/29.04  tff(decl_40123, type, fn_frameshift_mutation_2: $i > $i).
% 29.22/29.04  tff(decl_40124, type, fn_frameshift_mutation_3: $i > $i).
% 29.22/29.04  tff(decl_40125, type, fn_frameshift_mutation_4: $i > $i).
% 29.22/29.04  tff(decl_40126, type, francium_1: $i > $o).
% 29.22/29.04  tff(decl_40127, type, 'Francium': $i).
% 29.22/29.04  tff(decl_40128, type, 'Francium is a metal atom with atomic number 87. It is represented by the symbol Fr.': $i).
% 29.22/29.04  tff(decl_40129, type, francium: $i).
% 29.22/29.04  tff(decl_40130, type, 'Fr': $i).
% 29.22/29.04  tff(decl_40131, type, fn_francium_3: $i > $i).
% 29.22/29.04  tff(decl_40132, type, fn_francium_4: $i > $i).
% 29.22/29.04  tff(decl_40133, type, fn_francium_5: $i > $i).
% 29.22/29.04  tff(decl_40134, type, fn_francium_9: $i > $i).
% 29.22/29.04  tff(decl_40135, type, fn_francium_10: $i > $i).
% 29.22/29.04  tff(decl_40136, type, fn_francium_11: $i > $i).
% 29.22/29.04  tff(decl_40137, type, fn_francium_12: $i > $i).
% 29.22/29.04  tff(decl_40138, type, "136": $i).
% 29.22/29.04  tff(decl_40139, type, "87": $i).
% 29.22/29.04  tff(decl_40140, type, "0.7": $i).
% 29.22/29.04  tff(decl_40141, type, "223": $i).
% 29.22/29.04  tff(decl_40142, type, fn_francium_7: $i > $i).
% 29.22/29.04  tff(decl_40143, type, fn_francium_8: $i > $i).
% 29.22/29.04  tff(decl_40144, type, fn_francium_6: $i > $i).
% 29.22/29.04  tff(decl_40145, type, franklin_x_ray_diffraction_experiment_1: $i > $o).
% 29.22/29.04  tff(decl_40146, type, 'Franklin-X-ray-Diffraction-Experiment': $i).
% 29.22/29.04  tff(decl_40147, type, 'X-ray diffraction was a method used by Rosalind Franklin to produce an image of the DNA molecule.  This image was the key in determining the structure of the molecule.': $i).
% 29.22/29.04  tff(decl_40148, type, 'franklin x ray crystallography': $i).
% 29.22/29.04  tff(decl_40149, type, 'franklin x-ray crystallography': $i).
% 29.22/29.04  tff(decl_40150, type, 'perform a franklin x ray diffraction experiment': $i).
% 29.22/29.04  tff(decl_40151, type, 'perform a franklin x-ray diffraction experiment': $i).
% 29.22/29.04  tff(decl_40152, type, 'franklin x ray diffraction experiment': $i).
% 29.22/29.04  tff(decl_40153, type, 'franklin-x-ray-diffraction-experiment': $i).
% 29.22/29.04  tff(decl_40154, type, fn_franklin_x_ray_diffraction_experiment_1: $i > $i).
% 29.22/29.04  tff(decl_40155, type, fn_franklin_x_ray_diffraction_experiment_2: $i > $i).
% 29.22/29.04  tff(decl_40156, type, 'Free-Energy': $i).
% 29.22/29.04  tff(decl_40157, type, 'The portion of the energy in a biological system that can be used to perform work under conditions of uniform temperature and pressure.': $i).
% 29.22/29.04  tff(decl_40158, type, g: $i).
% 29.22/29.04  tff(decl_40159, type, 'gibbs free energy': $i).
% 29.22/29.04  tff(decl_40160, type, 'gibbs-free-energy': $i).
% 29.22/29.04  tff(decl_40161, type, 'energy of free': $i).
% 29.22/29.04  tff(decl_40162, type, 'free energy': $i).
% 29.22/29.04  tff(decl_40163, type, 'free-energy': $i).
% 29.22/29.04  tff(decl_40164, type, 'Free-Energy-Change-Value': $i).
% 29.22/29.04  tff(decl_40165, type, 'free energy change': $i).
% 29.22/29.04  tff(decl_40166, type, 'free-energy-change': $i).
% 29.22/29.04  tff(decl_40167, type, 'free energy change value': $i).
% 29.22/29.04  tff(decl_40168, type, 'free-energy-change-value': $i).
% 29.22/29.04  tff(decl_40169, type, 'Free-Ribosome': $i).
% 29.22/29.04  tff(decl_40170, type, 'Ribosomes which are found in the cytosol of a cell, not attached to any organelle or membrane.': $i).
% 29.22/29.04  tff(decl_40171, type, 'ribosome of free': $i).
% 29.22/29.04  tff(decl_40172, type, 'free ribosome': $i).
% 29.22/29.04  tff(decl_40173, type, 'free-ribosome': $i).
% 29.22/29.04  tff(decl_40174, type, fn_free_ribosome_1: $i > $i).
% 29.22/29.04  tff(decl_40175, type, fn_free_ribosome_2: $i > $i).
% 29.22/29.04  tff(decl_40176, type, fn_free_ribosome_3: $i > $i).
% 29.22/29.04  tff(decl_40177, type, fn_free_ribosome_4: $i > $i).
% 29.22/29.04  tff(decl_40178, type, fn_free_ribosome_5: $i > $i).
% 29.22/29.04  tff(decl_40179, type, fn_free_ribosome_6: $i > $i).
% 29.22/29.04  tff(decl_40180, type, fn_free_ribosome_7: $i > $i).
% 29.22/29.04  tff(decl_40181, type, fn_free_ribosome_8: $i > $i).
% 29.22/29.04  tff(decl_40182, type, fn_free_ribosome_9: $i > $i).
% 29.22/29.04  tff(decl_40183, type, fn_free_ribosome_10: $i > $i).
% 29.22/29.04  tff(decl_40184, type, fn_free_ribosome_11: $i > $i).
% 29.22/29.04  tff(decl_40185, type, fn_free_ribosome_12: $i > $i).
% 29.22/29.04  tff(decl_40186, type, fn_p_site_6: $i > $i).
% 29.22/29.04  tff(decl_40187, type, fn_p_site_4: $i > $i).
% 29.22/29.04  tff(decl_40188, type, fn_ribosome_7: $i > $i).
% 29.22/29.04  tff(decl_40189, type, fn_ribosome_10: $i > $i).
% 29.22/29.04  tff(decl_40190, type, fn_ribosome_11: $i > $i).
% 29.22/29.04  tff(decl_40191, type, fn_ribosome_9: $i > $i).
% 29.22/29.04  tff(decl_40192, type, fn_ribosome_6: $i > $i).
% 29.22/29.04  tff(decl_40193, type, freeze_fracture_of_membrane_1: $i > $o).
% 29.22/29.04  tff(decl_40194, type, fn_freeze_fracture_of_membrane_1: $i > $i).
% 29.22/29.04  tff(decl_40195, type, 'Freeze-Fracture-Of-Membrane': $i).
% 29.22/29.04  tff(decl_40196, type, 'Freeze-fracture splits a membrane along the middle of the phospholipid bilayer.': $i).
% 29.22/29.04  tff(decl_40197, type, 'freeze fracture': $i).
% 29.22/29.04  tff(decl_40198, type, 'freeze-fracture': $i).
% 29.22/29.04  tff(decl_40199, type, 'freeze fracturing': $i).
% 29.22/29.04  tff(decl_40200, type, 'freeze-fracturing': $i).
% 29.22/29.04  tff(decl_40201, type, 'freeze fracture technique': $i).
% 29.22/29.04  tff(decl_40202, type, 'freeze-fracture-technique': $i).
% 29.22/29.04  tff(decl_40203, type, 'freeze fracture of membrane': $i).
% 29.22/29.04  tff(decl_40204, type, 'freeze-fracture-of-membrane': $i).
% 29.22/29.04  tff(decl_40205, type, fn_freeze_fracture_of_membrane_3: $i > $i).
% 29.22/29.04  tff(decl_40206, type, fn_freeze_fracture_of_membrane_4: $i > $i).
% 29.22/29.04  tff(decl_40207, type, fn_freeze_fracture_of_membrane_5: $i > $i).
% 29.22/29.04  tff(decl_40208, type, fn_freeze_fracture_of_membrane_6: $i > $i).
% 29.22/29.04  tff(decl_40209, type, fn_freeze_fracture_of_membrane_7: $i > $i).
% 29.22/29.04  tff(decl_40210, type, fn_freeze_fracture_of_membrane_8: $i > $i).
% 29.22/29.04  tff(decl_40211, type, fn_freeze_fracture_of_membrane_9: $i > $i).
% 29.22/29.04  tff(decl_40212, type, fn_freeze_fracture_of_membrane_10: $i > $i).
% 29.22/29.04  tff(decl_40213, type, fn_freeze_fracture_of_membrane_11: $i > $i).
% 29.22/29.04  tff(decl_40214, type, fn_freeze_fracture_of_membrane_12: $i > $i).
% 29.22/29.04  tff(decl_40215, type, fn_freezing_2: $i > $i).
% 29.22/29.04  tff(decl_40216, type, fn_freezing_1: $i > $i).
% 29.22/29.04  tff(decl_40217, type, 'Freezing': $i).
% 29.22/29.04  tff(decl_40218, type, 'The process of cooling a substance to the point in which it changes to its solid state.': $i).
% 29.22/29.04  tff(decl_40219, type, 'making ice': $i).
% 29.22/29.04  tff(decl_40220, type, freeze: $i).
% 29.22/29.04  tff(decl_40221, type, freezing: $i).
% 29.22/29.04  tff(decl_40222, type, freezing_of_water_1: $i > $o).
% 29.22/29.04  tff(decl_40223, type, 'Freezing-Of-Water': $i).
% 29.22/29.04  tff(decl_40224, type, 'The process of cooling water to the point in which it changes to ice, its solid state.  The freezing point of water is 32 degrees F or 0 degrees C.': $i).
% 29.22/29.04  tff(decl_40225, type, icing: $i).
% 29.22/29.04  tff(decl_40226, type, 'water solidification': $i).
% 29.22/29.04  tff(decl_40227, type, 'solidifying water': $i).
% 29.22/29.04  tff(decl_40228, type, 'water freezing': $i).
% 29.22/29.04  tff(decl_40229, type, 'water-freezing': $i).
% 29.22/29.04  tff(decl_40230, type, 'freezing of water': $i).
% 29.22/29.04  tff(decl_40231, type, 'freezing-of-water': $i).
% 29.22/29.04  tff(decl_40232, type, fn_freezing_of_water_2: $i > $i).
% 29.22/29.04  tff(decl_40233, type, fn_freezing_of_water_3: $i > $i).
% 29.22/29.04  tff(decl_40234, type, fn_freezing_of_water_6: $i > $i).
% 29.22/29.04  tff(decl_40235, type, fn_freezing_of_water_7: $i > $i).
% 29.22/29.04  tff(decl_40236, type, fn_freezing_of_water_8: $i > $i).
% 29.22/29.04  tff(decl_40237, type, fn_freezing_of_water_9: $i > $i).
% 29.22/29.04  tff(decl_40238, type, fn_freezing_of_water_10: $i > $i).
% 29.22/29.04  tff(decl_40239, type, fn_freezing_of_water_11: $i > $i).
% 29.22/29.04  tff(decl_40240, type, fn_freezing_of_water_12: $i > $i).
% 29.22/29.04  tff(decl_40241, type, fn_freezing_of_water_13: $i > $i).
% 29.22/29.04  tff(decl_40242, type, fn_freezing_of_water_14: $i > $i).
% 29.22/29.04  tff(decl_40243, type, fn_freezing_of_water_15: $i > $i).
% 29.22/29.04  tff(decl_40244, type, fn_freezing_of_water_16: $i > $i).
% 29.22/29.04  tff(decl_40245, type, fn_freezing_of_water_17: $i > $i).
% 29.22/29.04  tff(decl_40246, type, fn_freezing_of_water_18: $i > $i).
% 29.22/29.04  tff(decl_40247, type, fn_freezing_of_water_19: $i > $i).
% 29.22/29.04  tff(decl_40248, type, fn_freezing_of_water_20: $i > $i).
% 29.22/29.04  tff(decl_40249, type, fn_freezing_of_water_21: $i > $i).
% 29.22/29.04  tff(decl_40250, type, fn_freezing_of_water_22: $i > $i).
% 29.22/29.04  tff(decl_40251, type, fn_freezing_of_water_23: $i > $i).
% 29.22/29.04  tff(decl_40252, type, fn_freezing_of_water_24: $i > $i).
% 29.22/29.04  tff(decl_40253, type, fn_freezing_of_water_25: $i > $i).
% 29.22/29.04  tff(decl_40254, type, fn_freezing_of_water_26: $i > $i).
% 29.22/29.04  tff(decl_40255, type, fn_freezing_of_water_27: $i > $i).
% 29.22/29.04  tff(decl_40256, type, fn_freezing_of_water_28: $i > $i).
% 29.22/29.04  tff(decl_40257, type, fn_freezing_of_water_29: $i > $i).
% 29.22/29.04  tff(decl_40258, type, fn_freezing_of_water_30: $i > $i).
% 29.22/29.04  tff(decl_40259, type, fn_freezing_of_water_31: $i > $i).
% 29.22/29.04  tff(decl_40260, type, fn_ice_17: $i > $i).
% 29.22/29.04  tff(decl_40261, type, fn_hydrogen_bond_14: $i > $i).
% 29.22/29.04  tff(decl_40262, type, fn_hydrogen_bond_13: $i > $i).
% 29.22/29.04  tff(decl_40263, type, fn_hydrogen_bond_11: $i > $i).
% 29.22/29.04  tff(decl_40264, type, fn_hydrogen_bond_12: $i > $i).
% 29.22/29.04  tff(decl_40265, type, fn_water_43: $i > $i).
% 29.22/29.04  tff(decl_40266, type, fn_water_114: $i > $i).
% 29.22/29.04  tff(decl_40267, type, fn_ice_19: $i > $i).
% 29.22/29.04  tff(decl_40268, type, fn_ice_20: $i > $i).
% 29.22/29.04  tff(decl_40269, type, fn_ice_18: $i > $i).
% 29.22/29.04  tff(decl_40270, type, fn_water_33: $i > $i).
% 29.22/29.04  tff(decl_40271, type, fn_freezing_of_water_5: $i > $i).
% 29.22/29.04  tff(decl_40272, type, 'Frequency-Constant': $i).
% 29.22/29.04  tff(decl_40273, type, 'constant of frequency': $i).
% 29.22/29.04  tff(decl_40274, type, 'frequency constant': $i).
% 29.22/29.04  tff(decl_40275, type, 'frequency-constant': $i).
% 29.22/29.04  tff(decl_40276, type, frequency_dependent_selection_1: $i > $o).
% 29.22/29.04  tff(decl_40277, type, 'Frequency-Dependent-Selection': $i).
% 29.22/29.04  tff(decl_40278, type, 'A type of selection in which the survival and reproduction of any one phenotype depends on its relative frequency compared to other phenotypes in the population.': $i).
% 29.22/29.04  tff(decl_40279, type, 'frequency dependent selection': $i).
% 29.22/29.04  tff(decl_40280, type, 'frequency-dependent-selection': $i).
% 29.22/29.04  tff(decl_40281, type, frequency_scale_1: $i > $o).
% 29.22/29.04  tff(decl_40282, type, 'Frequency-Scale': $i).
% 29.22/29.04  tff(decl_40283, type, 'scale of frequency': $i).
% 29.22/29.04  tff(decl_40284, type, 'frequency scale': $i).
% 29.22/29.04  tff(decl_40285, type, 'frequency-scale': $i).
% 29.22/29.04  tff(decl_40286, type, 'Frequency-Value': $i).
% 29.22/29.04  tff(decl_40287, type, 'the rate of repetition of an Event': $i).
% 29.22/29.04  tff(decl_40288, type, frequence: $i).
% 29.22/29.04  tff(decl_40289, type, oftenness: $i).
% 29.22/29.04  tff(decl_40290, type, frequency: $i).
% 29.22/29.04  tff(decl_40291, type, 'value of frequency': $i).
% 29.22/29.04  tff(decl_40292, type, 'frequency value': $i).
% 29.22/29.04  tff(decl_40293, type, 'frequency-value': $i).
% 29.22/29.04  tff(decl_40294, type, freshwater_animal_1: $i > $o).
% 29.22/29.04  tff(decl_40295, type, 'Freshwater-Animal': $i).
% 29.22/29.04  tff(decl_40296, type, 'An animal that lives in low-saline bodies of water such as ponds, lakes, and rivers.': $i).
% 29.22/29.04  tff(decl_40297, type, 'freshwater animal': $i).
% 29.22/29.04  tff(decl_40298, type, 'freshwater-animal': $i).
% 29.22/29.04  tff(decl_40299, type, 'Freshwater-Biome': $i).
% 29.22/29.04  tff(decl_40300, type, 'A biome in a freshwater ecosystem.': $i).
% 29.22/29.04  tff(decl_40301, type, 'freshwater biome': $i).
% 29.22/29.04  tff(decl_40302, type, 'freshwater-biome': $i).
% 29.22/29.04  tff(decl_40303, type, 'Freshwater-Protist': $i).
% 29.22/29.04  tff(decl_40304, type, 'The protist that are known to occur in freshwater are called freshwater protists.': $i).
% 29.22/29.04  tff(decl_40305, type, 'freshwater protist': $i).
% 29.22/29.04  tff(decl_40306, type, 'freshwater-protist': $i).
% 29.22/29.04  tff(decl_40307, type, friction_1: $i > $o).
% 29.22/29.04  tff(decl_40308, type, 'Friction': $i).
% 29.22/29.04  tff(decl_40309, type, 'A force that opposes active movement.': $i).
% 29.22/29.04  tff(decl_40310, type, friction: $i).
% 29.22/29.04  tff(decl_40311, type, frog_1: $i > $o).
% 29.22/29.04  tff(decl_40312, type, 'Frog': $i).
% 29.22/29.04  tff(decl_40313, type, 'Frogs are amphibians falling in the order Anura': $i).
% 29.22/29.04  tff(decl_40314, type, frog_egg_1: $i > $o).
% 29.22/29.04  tff(decl_40315, type, 'Frog-Egg': $i).
% 29.22/29.04  tff(decl_40316, type, 'The female gamete of a frog.': $i).
% 29.22/29.04  tff(decl_40317, type, 'egg of frog': $i).
% 29.22/29.04  tff(decl_40318, type, 'frog egg': $i).
% 29.22/29.04  tff(decl_40319, type, 'frog-egg': $i).
% 29.22/29.04  tff(decl_40320, type, fn_frog_egg_1: $i > $i).
% 29.22/29.04  tff(decl_40321, type, fn_frog_egg_2: $i > $i).
% 29.22/29.04  tff(decl_40322, type, frog_homeotic_gene_1: $i > $o).
% 29.22/29.04  tff(decl_40323, type, 'Frog-Homeotic-Gene': $i).
% 29.22/29.04  tff(decl_40324, type, 'Homeotic gene present in frogs.': $i).
% 29.22/29.04  tff(decl_40325, type, 'frog homeotic gene': $i).
% 29.22/29.04  tff(decl_40326, type, 'frog-homeotic-gene': $i).
% 29.22/29.04  tff(decl_40327, type, fn_frog_homeotic_gene_1: $i > $i).
% 29.22/29.04  tff(decl_40328, type, fn_frog_homeotic_gene_2: $i > $i).
% 29.22/29.04  tff(decl_40329, type, frontal_lobe_1: $i > $o).
% 29.22/29.04  tff(decl_40330, type, 'Frontal-Lobe': $i).
% 29.22/29.04  tff(decl_40331, type, 'Anterior region of the cerebral cortex, respobsible for control of skeletal muscles, speech, and decision making.': $i).
% 29.22/29.04  tff(decl_40332, type, 'lobe of frontal': $i).
% 29.22/29.04  tff(decl_40333, type, 'frontal lobe': $i).
% 29.22/29.04  tff(decl_40334, type, 'frontal-lobe': $i).
% 29.22/29.04  tff(decl_40335, type, frozen_cell_1: $i > $o).
% 29.22/29.04  tff(decl_40336, type, 'Frozen-Cell': $i).
% 29.22/29.04  tff(decl_40337, type, 'Cell which has been affected by low temperature to the point where membrane fluidity is lost and cellular transport ceases.': $i).
% 29.22/29.04  tff(decl_40338, type, 'cell of frozen': $i).
% 29.22/29.04  tff(decl_40339, type, 'frozen cell': $i).
% 29.22/29.04  tff(decl_40340, type, 'frozen-cell': $i).
% 29.22/29.04  tff(decl_40341, type, fn_frozen_cell_1: $i > $i).
% 29.22/29.04  tff(decl_40342, type, fn_frozen_cell_2: $i > $i).
% 29.22/29.04  tff(decl_40343, type, fructose_1: $i > $o).
% 29.22/29.04  tff(decl_40344, type, 'Fructose': $i).
% 29.22/29.04  tff(decl_40345, type, 'Fructose, or fruit sugar, is a simple monosaccharide found in many foods. It is one of the three important dietary monosaccharides along with glucose and galactose.': $i).
% 29.22/29.04  tff(decl_40346, type, fructose: $i).
% 29.22/29.04  tff(decl_40347, type, hexose_1: $i > $o).
% 29.22/29.04  tff(decl_40348, type, fn_fructose_1: $i > $i).
% 29.22/29.04  tff(decl_40349, type, fn_glucose_3: $i > $i).
% 29.22/29.04  tff(decl_40350, type, 'Fructose-1,6-Bisphosphate': $i).
% 29.22/29.04  tff(decl_40351, type, 'An intermediate formed during the third step of glycolysis.': $i).
% 29.22/29.04  tff(decl_40352, type, 'harden young ester': $i).
% 29.22/29.04  tff(decl_40353, type, 'harden-young-ester': $i).
% 29.22/29.04  tff(decl_40354, type, 'fructose 1, 6 bisphosphate': $i).
% 29.22/29.04  tff(decl_40355, type, 'fructose 1,6 bisphosphate': $i).
% 29.22/29.04  tff(decl_40356, type, 'fructose-1,6-bisphosphate': $i).
% 29.22/29.04  tff(decl_40357, type, fn_fructose_1_comma_6_bisphosphate_1: $i > $i).
% 29.22/29.04  tff(decl_40358, type, fn_fructose_1_comma_6_bisphosphate_2: $i > $i).
% 29.22/29.04  tff(decl_40359, type, fn_fructose_1_comma_6_bisphosphate_3: $i > $i).
% 29.22/29.04  tff(decl_40360, type, fn_fructose_1_comma_6_bisphosphate_4: $i > $i).
% 29.22/29.04  tff(decl_40361, type, fn_fructose_1_comma_6_bisphosphate_5: $i > $i).
% 29.22/29.04  tff(decl_40362, type, fn_fructose_1_comma_6_bisphosphate_7: $i > $i).
% 29.22/29.04  tff(decl_40363, type, fn_fructose_1_comma_6_bisphosphate_8: $i > $i).
% 29.22/29.04  tff(decl_40364, type, fn_fructose_1_comma_6_bisphosphate_9: $i > $i).
% 29.22/29.04  tff(decl_40365, type, fn_fructose_1_comma_6_bisphosphate_10: $i > $i).
% 29.22/29.04  tff(decl_40366, type, fn_fructose_1_comma_6_bisphosphate_11: $i > $i).
% 29.22/29.04  tff(decl_40367, type, fn_fructose_1_comma_6_bisphosphate_12: $i > $i).
% 29.22/29.04  tff(decl_40368, type, fn_fructose_1_comma_6_bisphosphate_13: $i > $i).
% 29.22/29.04  tff(decl_40369, type, fn_fructose_1_comma_6_bisphosphate_14: $i > $i).
% 29.22/29.04  tff(decl_40370, type, fn_fructose_1_comma_6_bisphosphate_15: $i > $i).
% 29.22/29.04  tff(decl_40371, type, fn_fructose_1_comma_6_bisphosphate_17: $i > $i).
% 29.22/29.04  tff(decl_40372, type, fn_fructose_1_comma_6_bisphosphate_18: $i > $i).
% 29.22/29.04  tff(decl_40373, type, fn_fructose_1_comma_6_bisphosphate_19: $i > $i).
% 29.22/29.04  tff(decl_40374, type, fn_fructose_1_comma_6_bisphosphate_20: $i > $i).
% 29.22/29.04  tff(decl_40375, type, fn_fructose_1_comma_6_bisphosphate_21: $i > $i).
% 29.22/29.04  tff(decl_40376, type, fn_fructose_1_comma_6_bisphosphate_22: $i > $i).
% 29.22/29.04  tff(decl_40377, type, fn_fructose_1_comma_6_bisphosphate_23: $i > $i).
% 29.22/29.04  tff(decl_40378, type, fn_fructose_1_comma_6_bisphosphate_24: $i > $i).
% 29.22/29.04  tff(decl_40379, type, fn_fructose_1_comma_6_bisphosphate_25: $i > $i).
% 29.22/29.04  tff(decl_40380, type, fn_fructose_1_comma_6_bisphosphate_26: $i > $i).
% 29.22/29.04  tff(decl_40381, type, fn_fructose_1_comma_6_bisphosphate_27: $i > $i).
% 29.22/29.04  tff(decl_40382, type, fn_fructose_1_comma_6_bisphosphate_28: $i > $i).
% 29.22/29.04  tff(decl_40383, type, fn_fructose_1_comma_6_bisphosphate_29: $i > $i).
% 29.22/29.04  tff(decl_40384, type, fn_fructose_1_comma_6_bisphosphate_30: $i > $i).
% 29.22/29.04  tff(decl_40385, type, fn_fructose_1_comma_6_bisphosphate_31: $i > $i).
% 29.22/29.04  tff(decl_40386, type, fn_fructose_1_comma_6_bisphosphate_32: $i > $i).
% 29.22/29.04  tff(decl_40387, type, fn_fructose_1_comma_6_bisphosphate_33: $i > $i).
% 29.22/29.04  tff(decl_40388, type, fn_fructose_1_comma_6_bisphosphate_35: $i > $i).
% 29.22/29.04  tff(decl_40389, type, fn_fructose_1_comma_6_bisphosphate_36: $i > $i).
% 29.22/29.04  tff(decl_40390, type, fn_fructose_1_comma_6_bisphosphate_37: $i > $i).
% 29.22/29.04  tff(decl_40391, type, fn_fructose_1_comma_6_bisphosphate_38: $i > $i).
% 29.22/29.04  tff(decl_40392, type, fn_fructose_1_comma_6_bisphosphate_41: $i > $i).
% 29.22/29.04  tff(decl_40393, type, fn_fructose_1_comma_6_bisphosphate_42: $i > $i).
% 29.22/29.04  tff(decl_40394, type, fn_fructose_1_comma_6_bisphosphate_43: $i > $i).
% 29.22/29.04  tff(decl_40395, type, fn_fructose_1_comma_6_bisphosphate_44: $i > $i).
% 29.22/29.04  tff(decl_40396, type, fn_fructose_1_comma_6_bisphosphate_45: $i > $i).
% 29.22/29.04  tff(decl_40397, type, fn_fructose_1_comma_6_bisphosphate_46: $i > $i).
% 29.22/29.04  tff(decl_40398, type, fn_fructose_1_comma_6_bisphosphate_47: $i > $i).
% 29.22/29.04  tff(decl_40399, type, fn_fructose_1_comma_6_bisphosphate_48: $i > $i).
% 29.22/29.04  tff(decl_40400, type, fn_fructose_1_comma_6_bisphosphate_49: $i > $i).
% 29.22/29.04  tff(decl_40401, type, fn_fructose_1_comma_6_bisphosphate_50: $i > $i).
% 29.22/29.04  tff(decl_40402, type, fn_fructose_1_comma_6_bisphosphate_51: $i > $i).
% 29.22/29.04  tff(decl_40403, type, fn_fructose_1_comma_6_bisphosphate_52: $i > $i).
% 29.22/29.04  tff(decl_40404, type, fn_phosphate_group_26: $i > $i).
% 29.22/29.04  tff(decl_40405, type, fn_phosphate_group_25: $i > $i).
% 29.22/29.04  tff(decl_40406, type, fn_fructose_1_comma_6_bisphosphate_55: $i > $i).
% 29.22/29.04  tff(decl_40407, type, fn_fructose_1_comma_6_bisphosphate_16: $i > $i).
% 29.22/29.04  tff(decl_40408, type, fn_fructose_1_comma_6_bisphosphate_34: $i > $i).
% 29.22/29.04  tff(decl_40409, type, fn_fructose_1_comma_6_bisphosphate_40: $i > $i).
% 29.22/29.04  tff(decl_40410, type, fn_fructose_1_comma_6_bisphosphate_39: $i > $i).
% 29.22/29.04  tff(decl_40411, type, fn_fructose_1_comma_6_bisphosphate_53: $i > $i).
% 29.22/29.04  tff(decl_40412, type, fn_fructose_1_comma_6_bisphosphate_54: $i > $i).
% 29.22/29.04  tff(decl_40413, type, 'Fructose-6-Phosphate': $i).
% 29.22/29.04  tff(decl_40414, type, 'Fructose 6-phosphate (also known as the Neuberg ester) is fructose sugar phosphorylated on carbon 6 (i.e., is a fructosephosphate).': $i).
% 29.22/29.04  tff(decl_40415, type, 'neuberg  ester': $i).
% 29.22/29.04  tff(decl_40416, type, 'neuberg -ester': $i).
% 29.22/29.04  tff(decl_40417, type, 'fructose 6 phosphate': $i).
% 29.22/29.04  tff(decl_40418, type, 'fructose-6-phosphate': $i).
% 29.22/29.04  tff(decl_40419, type, fn_fructose_6_phosphate_1: $i > $i).
% 29.22/29.04  tff(decl_40420, type, fn_fructose_6_phosphate_5: $i > $i).
% 29.22/29.04  tff(decl_40421, type, fn_fructose_6_phosphate_6: $i > $i).
% 29.22/29.04  tff(decl_40422, type, fn_fructose_6_phosphate_7: $i > $i).
% 29.22/29.04  tff(decl_40423, type, fn_fructose_6_phosphate_8: $i > $i).
% 29.22/29.04  tff(decl_40424, type, fn_fructose_6_phosphate_9: $i > $i).
% 29.22/29.04  tff(decl_40425, type, fn_fructose_6_phosphate_10: $i > $i).
% 29.22/29.04  tff(decl_40426, type, fn_fructose_6_phosphate_11: $i > $i).
% 29.22/29.04  tff(decl_40427, type, fn_fructose_6_phosphate_12: $i > $i).
% 29.22/29.04  tff(decl_40428, type, fn_fructose_6_phosphate_13: $i > $i).
% 29.22/29.04  tff(decl_40429, type, fn_fructose_6_phosphate_16: $i > $i).
% 29.22/29.04  tff(decl_40430, type, fn_fructose_6_phosphate_17: $i > $i).
% 29.22/29.04  tff(decl_40431, type, fn_fructose_6_phosphate_18: $i > $i).
% 29.22/29.04  tff(decl_40432, type, fn_fructose_6_phosphate_22: $i > $i).
% 29.22/29.04  tff(decl_40433, type, fn_fructose_6_phosphate_23: $i > $i).
% 29.22/29.04  tff(decl_40434, type, fn_fructose_6_phosphate_24: $i > $i).
% 29.22/29.04  tff(decl_40435, type, fn_fructose_6_phosphate_25: $i > $i).
% 29.22/29.04  tff(decl_40436, type, fn_fructose_6_phosphate_26: $i > $i).
% 29.22/29.04  tff(decl_40437, type, fn_fructose_6_phosphate_27: $i > $i).
% 29.22/29.04  tff(decl_40438, type, fn_fructose_6_phosphate_28: $i > $i).
% 29.22/29.04  tff(decl_40439, type, fn_fructose_6_phosphate_29: $i > $i).
% 29.22/29.04  tff(decl_40440, type, fn_fructose_6_phosphate_30: $i > $i).
% 29.22/29.04  tff(decl_40441, type, fn_fructose_6_phosphate_31: $i > $i).
% 29.22/29.04  tff(decl_40442, type, fn_fructose_6_phosphate_32: $i > $i).
% 29.22/29.04  tff(decl_40443, type, fn_fructose_6_phosphate_33: $i > $i).
% 29.22/29.04  tff(decl_40444, type, fn_fructose_6_phosphate_34: $i > $i).
% 29.22/29.04  tff(decl_40445, type, fn_fructose_6_phosphate_35: $i > $i).
% 29.22/29.04  tff(decl_40446, type, fn_fructose_6_phosphate_36: $i > $i).
% 29.22/29.04  tff(decl_40447, type, fn_fructose_6_phosphate_37: $i > $i).
% 29.22/29.04  tff(decl_40448, type, fn_fructose_6_phosphate_38: $i > $i).
% 29.22/29.04  tff(decl_40449, type, fn_fructose_6_phosphate_39: $i > $i).
% 29.22/29.04  tff(decl_40450, type, fn_fructose_6_phosphate_40: $i > $i).
% 29.22/29.04  tff(decl_40451, type, fn_fructose_6_phosphate_42: $i > $i).
% 29.22/29.04  tff(decl_40452, type, fn_fructose_6_phosphate_43: $i > $i).
% 29.22/29.04  tff(decl_40453, type, fn_fructose_6_phosphate_44: $i > $i).
% 29.22/29.04  tff(decl_40454, type, fn_fructose_6_phosphate_45: $i > $i).
% 29.22/29.04  tff(decl_40455, type, fn_fructose_6_phosphate_46: $i > $i).
% 29.22/29.04  tff(decl_40456, type, fn_fructose_6_phosphate_4: $i > $i).
% 29.22/29.04  tff(decl_40457, type, fn_fructose_6_phosphate_3: $i > $i).
% 29.22/29.04  tff(decl_40458, type, fn_fructose_6_phosphate_41: $i > $i).
% 29.22/29.04  tff(decl_40459, type, fn_fructose_6_phosphate_15: $i > $i).
% 29.22/29.04  tff(decl_40460, type, fn_fructose_6_phosphate_14: $i > $i).
% 29.22/29.04  tff(decl_40461, type, fn_fructose_6_phosphate_19: $i > $i).
% 29.22/29.04  tff(decl_40462, type, fn_fructose_6_phosphate_20: $i > $i).
% 29.22/29.04  tff(decl_40463, type, fn_fructose_6_phosphate_21: $i > $i).
% 29.22/29.04  tff(decl_40464, type, 'Fruit': $i).
% 29.22/29.04  tff(decl_40465, type, 'Flowering plants produce fruits from one or more ovaries and sometimes other tissues as a means of seed dispersal.': $i).
% 29.22/29.04  tff(decl_40466, type, fruit: $i).
% 29.22/29.04  tff(decl_40467, type, fn_fruit_1: $i > $i).
% 29.22/29.04  tff(decl_40468, type, fn_fruit_2: $i > $i).
% 29.22/29.04  tff(decl_40469, type, fn_fruit_4: $i > $i).
% 29.22/29.04  tff(decl_40470, type, fn_fruit_5: $i > $i).
% 29.22/29.04  tff(decl_40471, type, fn_fruit_7: $i > $i).
% 29.22/29.04  tff(decl_40472, type, fn_fruit_8: $i > $i).
% 29.22/29.04  tff(decl_40473, type, fn_fruit_9: $i > $i).
% 29.22/29.04  tff(decl_40474, type, fn_fruit_11: $i > $i).
% 29.22/29.04  tff(decl_40475, type, fn_fruit_12: $i > $i).
% 29.22/29.04  tff(decl_40476, type, 'Fruit-Fly': $i).
% 29.22/29.04  tff(decl_40477, type, 'A group of flies belonging to the order Diptera.': $i).
% 29.22/29.04  tff(decl_40478, type, drosophila: $i).
% 29.22/29.04  tff(decl_40479, type, 'fruit flies': $i).
% 29.22/29.04  tff(decl_40480, type, 'fly of fruit': $i).
% 29.22/29.04  tff(decl_40481, type, 'fruit fly': $i).
% 29.22/29.04  tff(decl_40482, type, 'fruit-fly': $i).
% 29.22/29.04  tff(decl_40483, type, mosquito_1: $i > $o).
% 29.22/29.04  tff(decl_40484, type, fn_fruit_fly_3: $i > $i).
% 29.22/29.04  tff(decl_40485, type, fn_fruit_fly_4: $i > $i).
% 29.22/29.04  tff(decl_40486, type, fn_fruit_fly_7: $i > $i).
% 29.22/29.04  tff(decl_40487, type, fn_fruit_fly_8: $i > $i).
% 29.22/29.04  tff(decl_40488, type, fn_fruit_fly_9: $i > $i).
% 29.22/29.04  tff(decl_40489, type, fn_fruit_fly_12: $i > $i).
% 29.22/29.04  tff(decl_40490, type, fn_fruit_fly_14: $i > $i).
% 29.22/29.04  tff(decl_40491, type, fn_fruit_fly_15: $i > $i).
% 29.22/29.04  tff(decl_40492, type, fn_fruit_fly_16: $i > $i).
% 29.22/29.04  tff(decl_40493, type, fn_fruit_fly_19: $i > $i).
% 29.22/29.04  tff(decl_40494, type, fn_fruit_fly_20: $i > $i).
% 29.22/29.04  tff(decl_40495, type, fn_fruit_fly_22: $i > $i).
% 29.22/29.04  tff(decl_40496, type, fn_fruit_fly_32: $i > $i).
% 29.22/29.04  tff(decl_40497, type, fn_fruit_fly_33: $i > $i).
% 29.22/29.04  tff(decl_40498, type, fn_fruit_fly_34: $i > $i).
% 29.22/29.04  tff(decl_40499, type, fn_fruit_fly_35: $i > $i).
% 29.22/29.04  tff(decl_40500, type, sex_chromosome_0: $i).
% 29.22/29.04  tff(decl_40501, type, autosome_0: $i).
% 29.22/29.04  tff(decl_40502, type, fruit_fly_maternal_gene_1: $i > $o).
% 29.22/29.04  tff(decl_40503, type, 'Fruit-Fly-Maternal-Gene': $i).
% 29.22/29.04  tff(decl_40504, type, 'The genes of the fruit fly that code for mRNA are maternal effect genes.': $i).
% 29.22/29.04  tff(decl_40505, type, 'fruit fly maternal gene': $i).
% 29.22/29.04  tff(decl_40506, type, 'fruit-fly-maternal-gene': $i).
% 29.22/29.04  tff(decl_40507, type, fruit_fly_reproduction_1: $i > $o).
% 29.22/29.04  tff(decl_40508, type, 'Fruit-Fly-Reproduction': $i).
% 29.22/29.04  tff(decl_40509, type, 'Sexual reproduction in fruit fly species.': $i).
% 29.22/29.04  tff(decl_40510, type, 'fruit fly reproduction': $i).
% 29.22/29.04  tff(decl_40511, type, 'fruit-fly-reproduction': $i).
% 29.22/29.04  tff(decl_40512, type, fn_fruit_fly_reproduction_1: $i > $i).
% 29.22/29.04  tff(decl_40513, type, fn_fruit_fly_reproduction_3: $i > $i).
% 29.22/29.04  tff(decl_40514, type, fn_fruit_fly_reproduction_4: $i > $i).
% 29.22/29.04  tff(decl_40515, type, sexual_reproduction_0: $i).
% 29.22/29.04  tff(decl_40516, type, fn_sexual_reproduction_7: $i > $i).
% 29.22/29.04  tff(decl_40517, type, fn_sexual_reproduction_4: $i > $i).
% 29.22/29.04  tff(decl_40518, type, fruiting_body_1: $i > $o).
% 29.22/29.04  tff(decl_40519, type, 'Fruiting-Body': $i).
% 29.22/29.04  tff(decl_40520, type, 'Multicellular reproductive structure of fungi and some prokaryotes which produces spores.': $i).
% 29.22/29.04  tff(decl_40521, type, 'fruiting body': $i).
% 29.22/29.04  tff(decl_40522, type, 'fruiting-body': $i).
% 29.22/29.04  tff(decl_40523, type, fruiting_body_formation_in_myxobacterium_1: $i > $o).
% 29.22/29.04  tff(decl_40524, type, 'Fruiting-Body-Formation-In-Myxobacterium': $i).
% 29.22/29.04  tff(decl_40525, type, 'Multicellular reproductive structure of myxobacterium which produces spores. The fruiting body forms when individual cells aggregate together as a response to environmental stress.': $i).
% 29.22/29.04  tff(decl_40526, type, 'fruiting body formation in myxobacterium': $i).
% 29.22/29.04  tff(decl_40527, type, 'fruiting-body-formation-in-myxobacterium': $i).
% 29.22/29.04  tff(decl_40528, type, fruiting_body_formation_in_prokaryote_1: $i > $o).
% 29.22/29.04  tff(decl_40529, type, fn_fruiting_body_formation_in_myxobacterium_1: $i > $i).
% 29.22/29.04  tff(decl_40530, type, myxobacterium_1: $i > $o).
% 29.22/29.04  tff(decl_40531, type, fn_fruiting_body_formation_in_myxobacterium_2: $i > $i).
% 29.22/29.04  tff(decl_40532, type, fn_fruiting_body_formation_in_prokaryote_15: $i > $i).
% 29.22/29.04  tff(decl_40533, type, fn_fruiting_body_formation_in_prokaryote_16: $i > $i).
% 29.22/29.04  tff(decl_40534, type, 'Fruiting-Body-Formation-In-Prokaryote': $i).
% 29.22/29.04  tff(decl_40535, type, 'Multicellular reproductive structure of prokaryotes which produces spores. The fruiting body forms when individual cells aggregate together as a response to environmental stress.': $i).
% 29.22/29.04  tff(decl_40536, type, 'fruiting body formation in prokaryote': $i).
% 29.22/29.04  tff(decl_40537, type, 'fruiting-body-formation-in-prokaryote': $i).
% 29.22/29.04  tff(decl_40538, type, fn_fruiting_body_formation_in_prokaryote_1: $i > $i).
% 29.22/29.04  tff(decl_40539, type, spore_wall_1: $i > $o).
% 29.22/29.04  tff(decl_40540, type, fn_fruiting_body_formation_in_prokaryote_2: $i > $i).
% 29.22/29.04  tff(decl_40541, type, fn_fruiting_body_formation_in_prokaryote_3: $i > $i).
% 29.22/29.04  tff(decl_40542, type, fn_fruiting_body_formation_in_prokaryote_6: $i > $i).
% 29.22/29.04  tff(decl_40543, type, fn_fruiting_body_formation_in_prokaryote_7: $i > $i).
% 29.22/29.04  tff(decl_40544, type, fn_fruiting_body_formation_in_prokaryote_8: $i > $i).
% 29.22/29.04  tff(decl_40545, type, fn_fruiting_body_formation_in_prokaryote_9: $i > $i).
% 29.22/29.04  tff(decl_40546, type, fn_fruiting_body_formation_in_prokaryote_10: $i > $i).
% 29.22/29.04  tff(decl_40547, type, fn_fruiting_body_formation_in_prokaryote_11: $i > $i).
% 29.22/29.04  tff(decl_40548, type, fn_fruiting_body_formation_in_prokaryote_12: $i > $i).
% 29.22/29.04  tff(decl_40549, type, fn_fruiting_body_formation_in_prokaryote_13: $i > $i).
% 29.22/29.04  tff(decl_40550, type, fn_fruiting_body_formation_in_prokaryote_14: $i > $i).
% 29.22/29.04  tff(decl_40551, type, fn_quorum_sensing_in_prokaryote_11: $i > $i).
% 29.22/29.04  tff(decl_40552, type, spore_0: $i).
% 29.22/29.04  tff(decl_40553, type, experiencer_0: $i).
% 29.22/29.04  tff(decl_40554, type, fsh_1: $i > $o).
% 29.22/29.04  tff(decl_40555, type, 'FSH': $i).
% 29.22/29.04  tff(decl_40556, type, 'Follicle-stimulating hormone. A tropic hormone secreted from the anterior pituitary that stimulates follicle growth.': $i).
% 29.22/29.04  tff(decl_40557, type, 'follicle stimulating hormone': $i).
% 29.22/29.04  tff(decl_40558, type, 'follicle-stimulating-hormone': $i).
% 29.22/29.04  tff(decl_40559, type, fsh: $i).
% 29.22/29.04  tff(decl_40560, type, tropic_hormone_1: $i > $o).
% 29.22/29.04  tff(decl_40561, type, lh_1: $i > $o).
% 29.22/29.04  tff(decl_40562, type, hcg_1: $i > $o).
% 29.22/29.04  tff(decl_40563, type, 'Fuel': $i).
% 29.22/29.04  tff(decl_40564, type, 'Any material which is burned to supply power or heat.': $i).
% 29.22/29.04  tff(decl_40565, type, 'Fuel is a substance which when consumed provides energy.': $i).
% 29.22/29.04  tff(decl_40566, type, fuel: $i).
% 29.22/29.04  tff(decl_40567, type, fn_fuel_3: $i > $i).
% 29.22/29.04  tff(decl_40568, type, fn_fuel_4: $i > $i).
% 29.22/29.04  tff(decl_40569, type, fn_heat_3: $i > $i).
% 29.22/29.04  tff(decl_40570, type, fn_fuel_1: $i > $i).
% 29.22/29.04  tff(decl_40571, type, fn_fuel_2: $i > $i).
% 29.22/29.04  tff(decl_40572, type, 'Fumarate': $i).
% 29.22/29.04  tff(decl_40573, type, 'Fumarate is an intermediate compound formed in citric acid cycle.': $i).
% 29.22/29.04  tff(decl_40574, type, fumarate: $i).
% 29.22/29.04  tff(decl_40575, type, function_1: $i > $o).
% 29.22/29.04  tff(decl_40576, type, 'Function': $i).
% 29.22/29.04  tff(decl_40577, type, 'Functional-Group': $i).
% 29.22/29.04  tff(decl_40578, type, 'Functional groups are specific groups of atoms within organic molecules that are responsible for the characteristic chemical reactions of those organic  molecules.': $i).
% 29.22/29.04  tff(decl_40579, type, 'chemical group': $i).
% 29.22/29.04  tff(decl_40580, type, 'functional group': $i).
% 29.22/29.04  tff(decl_40581, type, 'functional-group': $i).
% 29.22/29.04  tff(decl_40582, type, functional_protein_1: $i > $o).
% 29.22/29.04  tff(decl_40583, type, 'Functional-Protein': $i).
% 29.22/29.04  tff(decl_40584, type, 'A protein in its functional (non-denatured), completely folded conformation.': $i).
% 29.22/29.04  tff(decl_40585, type, 'functional protein': $i).
% 29.22/29.04  tff(decl_40586, type, 'functional-protein': $i).
% 29.22/29.04  tff(decl_40587, type, fn_functional_protein_1: $i > $i).
% 29.22/29.04  tff(decl_40588, type, fn_functional_protein_2: $i > $i).
% 29.22/29.04  tff(decl_40589, type, fn_functional_protein_3: $i > $i).
% 29.22/29.04  tff(decl_40590, type, fn_functional_protein_4: $i > $i).
% 29.22/29.04  tff(decl_40591, type, fn_functional_protein_5: $i > $i).
% 29.22/29.04  tff(decl_40592, type, fn_functional_protein_6: $i > $i).
% 29.22/29.04  tff(decl_40593, type, fn_functional_protein_7: $i > $i).
% 29.22/29.04  tff(decl_40594, type, fn_functional_protein_8: $i > $i).
% 29.22/29.04  tff(decl_40595, type, fn_functional_protein_9: $i > $i).
% 29.22/29.04  tff(decl_40596, type, fn_functional_protein_10: $i > $i).
% 29.22/29.04  tff(decl_40597, type, fn_functional_protein_11: $i > $i).
% 29.22/29.04  tff(decl_40598, type, fn_functional_protein_12: $i > $i).
% 29.22/29.04  tff(decl_40599, type, fn_functional_protein_13: $i > $i).
% 29.22/29.04  tff(decl_40600, type, fn_functional_protein_14: $i > $i).
% 29.22/29.04  tff(decl_40601, type, fn_post_translational_modification_5: $i > $i).
% 29.22/29.04  tff(decl_40602, type, fn_post_translational_modification_10: $i > $i).
% 29.22/29.04  tff(decl_40603, type, fn_post_translational_modification_4: $i > $i).
% 29.22/29.04  tff(decl_40604, type, 'Functional-Region': $i).
% 29.22/29.04  tff(decl_40605, type, 'Functional region is a region present on a molecule which enables the function of the molecule.': $i).
% 29.22/29.04  tff(decl_40606, type, 'functional region': $i).
% 29.22/29.04  tff(decl_40607, type, 'functional-region': $i).
% 29.22/29.04  tff(decl_40608, type, 'Fungal-Appendage': $i).
% 29.22/29.04  tff(decl_40609, type, 'An external part, or natural prolongation, that protrudes from a fungus.': $i).
% 29.22/29.04  tff(decl_40610, type, 'fungal appendage': $i).
% 29.22/29.04  tff(decl_40611, type, 'fungal-appendage': $i).
% 29.22/29.04  tff(decl_40612, type, 'Fungal-Cell': $i).
% 29.22/29.04  tff(decl_40613, type, 'Fungal cell is a eukaryotic cell having a cell wall that is made up from chitin molecule.': $i).
% 29.22/29.04  tff(decl_40614, type, 'fungus cell': $i).
% 29.22/29.04  tff(decl_40615, type, 'fungus-cell': $i).
% 29.22/29.04  tff(decl_40616, type, 'fungi cells': $i).
% 29.22/29.04  tff(decl_40617, type, 'fungi-cells': $i).
% 29.22/29.04  tff(decl_40618, type, 'cell of a fungus': $i).
% 29.22/29.04  tff(decl_40619, type, 'cell-of-a-fungus': $i).
% 29.22/29.04  tff(decl_40620, type, 'fungal cell': $i).
% 29.22/29.04  tff(decl_40621, type, 'fungal-cell': $i).
% 29.22/29.04  tff(decl_40622, type, fn_fungal_cell_2: $i > $i).
% 29.22/29.04  tff(decl_40623, type, fn_fungal_cell_7: $i > $i).
% 29.22/29.04  tff(decl_40624, type, fn_fungal_cell_9: $i > $i).
% 29.22/29.04  tff(decl_40625, type, fn_fungal_cell_10: $i > $i).
% 29.22/29.04  tff(decl_40626, type, fn_fungal_cell_11: $i > $i).
% 29.22/29.04  tff(decl_40627, type, fn_fungal_cell_12: $i > $i).
% 29.22/29.04  tff(decl_40628, type, fn_fungal_cell_13: $i > $i).
% 29.22/29.04  tff(decl_40629, type, fn_fungal_cell_14: $i > $i).
% 29.22/29.04  tff(decl_40630, type, fn_fungal_cell_15: $i > $i).
% 29.22/29.04  tff(decl_40631, type, fn_fungal_cell_18: $i > $i).
% 29.22/29.04  tff(decl_40632, type, fungal_cell_wall_1: $i > $o).
% 29.22/29.04  tff(decl_40633, type, fn_fungal_cell_20: $i > $i).
% 29.22/29.04  tff(decl_40634, type, fn_fungal_cell_23: $i > $i).
% 29.22/29.04  tff(decl_40635, type, fn_fungal_cell_28: $i > $i).
% 29.22/29.04  tff(decl_40636, type, fn_fungal_cell_30: $i > $i).
% 29.22/29.04  tff(decl_40637, type, fn_fungal_cell_31: $i > $i).
% 29.22/29.04  tff(decl_40638, type, fn_fungal_cell_32: $i > $i).
% 29.22/29.04  tff(decl_40639, type, fn_fungal_cell_33: $i > $i).
% 29.22/29.04  tff(decl_40640, type, fn_smooth_endoplasmic_reticulum_30: $i > $i).
% 29.22/29.04  tff(decl_40641, type, 'Fungal-Cell-Inside-Hypertonic-Solution': $i).
% 29.22/29.04  tff(decl_40642, type, 'This is the situation in which fungal cell is placed inside hypertonic solution.': $i).
% 29.22/29.04  tff(decl_40643, type, 'fungal cell inside hypertonic solution': $i).
% 29.22/29.04  tff(decl_40644, type, 'fungal-cell-inside-hypertonic-solution': $i).
% 29.22/29.04  tff(decl_40645, type, 'Fungal-Cell-Wall': $i).
% 29.22/29.04  tff(decl_40646, type, 'A rigid barrier around the cells of fungi consisting largely of chitin and other polysaccharides, though not cellulose.': $i).
% 29.22/29.04  tff(decl_40647, type, 'fungal cell wall': $i).
% 29.22/29.04  tff(decl_40648, type, 'fungal cell-wall': $i).
% 29.22/29.04  tff(decl_40649, type, 'fungal-cell-wall': $i).
% 29.22/29.04  tff(decl_40650, type, fn_fungal_cell_wall_1: $i > $i).
% 29.22/29.04  tff(decl_40651, type, fn_fungal_life_cycle_3: $i > $i).
% 29.22/29.04  tff(decl_40652, type, 'Fungal-Life-Cycle': $i).
% 29.22/29.04  tff(decl_40653, type, 'The generation-to-generation sequence of stages in the reproductive history of a fungus.': $i).
% 29.22/29.04  tff(decl_40654, type, 'life cycle of fungus': $i).
% 29.22/29.04  tff(decl_40655, type, 'life-cycle-of-fungus': $i).
% 29.22/29.04  tff(decl_40656, type, 'undergo the fungal life cycle': $i).
% 29.22/29.04  tff(decl_40657, type, 'fungal life cycle': $i).
% 29.22/29.04  tff(decl_40658, type, 'fungal-life-cycle': $i).
% 29.22/29.04  tff(decl_40659, type, fn_fungal_life_cycle_2: $i > $i).
% 29.22/29.04  tff(decl_40660, type, fn_fungal_life_cycle_4: $i > $i).
% 29.22/29.04  tff(decl_40661, type, fn_fungal_life_cycle_5: $i > $i).
% 29.22/29.04  tff(decl_40662, type, haploid_cell_1: $i > $o).
% 29.22/29.04  tff(decl_40663, type, fn_fungal_life_cycle_6: $i > $i).
% 29.22/29.04  tff(decl_40664, type, fn_fungal_life_cycle_7: $i > $i).
% 29.22/29.04  tff(decl_40665, type, fn_fungal_life_cycle_8: $i > $i).
% 29.22/29.04  tff(decl_40666, type, fn_fungal_life_cycle_9: $i > $i).
% 29.22/29.04  tff(decl_40667, type, 'Fungal-Organ': $i).
% 29.22/29.04  tff(decl_40668, type, 'A specialized center of function composed of several different types of tissues specific to fungi.': $i).
% 29.22/29.04  tff(decl_40669, type, 'fungal organ': $i).
% 29.22/29.04  tff(decl_40670, type, 'fungal-organ': $i).
% 29.22/29.04  tff(decl_40671, type, 'Fungal-Tissue': $i).
% 29.22/29.04  tff(decl_40672, type, 'A tissue found in a fungus.': $i).
% 29.22/29.04  tff(decl_40673, type, 'fungal tissue': $i).
% 29.22/29.04  tff(decl_40674, type, 'fungal-tissue': $i).
% 29.22/29.04  tff(decl_40675, type, 'Fungus': $i).
% 29.22/29.04  tff(decl_40676, type, 'Plantlike organisms lacking chlorophyll. Include mushrooms, molds, yeasts, and mildews. Kingdom Fungi.': $i).
% 29.22/29.04  tff(decl_40677, type, 'Fungi comprise a kingdom of eukaryotes that acts decomposers and absorb nutrients from their surroundings .': $i).
% 29.22/29.04  tff(decl_40678, type, fungi: $i).
% 29.22/29.04  tff(decl_40679, type, mold: $i).
% 29.22/29.04  tff(decl_40680, type, yeast: $i).
% 29.22/29.04  tff(decl_40681, type, fungus: $i).
% 29.22/29.04  tff(decl_40682, type, 'Fur': $i).
% 29.22/29.04  tff(decl_40683, type, 'The soft, thick, hairy coat that covers the skin of some mammals.': $i).
% 29.22/29.04  tff(decl_40684, type, fur: $i).
% 29.22/29.04  tff(decl_40685, type, 'Furnishing': $i).
% 29.22/29.04  tff(decl_40686, type, 'furniture, fixtures, room accessories, etc.': $i).
% 29.22/29.04  tff(decl_40687, type, furnishings: $i).
% 29.22/29.04  tff(decl_40688, type, furnishing: $i).
% 29.22/29.04  tff(decl_40689, type, 'Furniture': $i).
% 29.22/29.04  tff(decl_40690, type, 'any artifact that helps make a room usable, though maybe not directly instrumental': $i).
% 29.22/29.04  tff(decl_40691, type, furniture: $i).
% 29.22/29.04  tff(decl_40692, type, 'Fus3': $i).
% 29.22/29.04  tff(decl_40693, type, 'FUs3 (mitogen activated protein kinase) is an enzyme which plays a role in cell signaling pathways leading to mating in yeast cells.': $i).
% 29.22/29.04  tff(decl_40694, type, fus3: $i).
% 29.22/29.04  tff(decl_40695, type, 'Fusiform-Initials': $i).
% 29.22/29.04  tff(decl_40696, type, 'Plant cambium cells with tapered ends that produce new vascular tissue in secondary growth.': $i).
% 29.22/29.04  tff(decl_40697, type, 'fusiform initials': $i).
% 29.22/29.04  tff(decl_40698, type, 'fusiform initial': $i).
% 29.22/29.04  tff(decl_40699, type, 'fusiform-initial': $i).
% 29.22/29.04  tff(decl_40700, type, 'Fusion': $i).
% 29.22/29.04  tff(decl_40701, type, 'An occurrence that involves the production of a union from different entities.': $i).
% 29.22/29.04  tff(decl_40702, type, merge: $i).
% 29.22/29.04  tff(decl_40703, type, fuse: $i).
% 29.22/29.04  tff(decl_40704, type, fusion: $i).
% 29.22/29.04  tff(decl_40705, type, 'G-Protein': $i).
% 29.22/29.04  tff(decl_40706, type, 'A protein that acts as a molecular switch, transmitting chemical signals from the outside of a cell to the inside.': $i).
% 29.22/29.04  tff(decl_40707, type, 'protein of g': $i).
% 29.22/29.04  tff(decl_40708, type, 'g protein': $i).
% 29.22/29.04  tff(decl_40709, type, 'g-protein': $i).
% 29.22/29.04  tff(decl_40710, type, 'G-Protein-Coupled-Receptor': $i).
% 29.22/29.04  tff(decl_40711, type, 'Member of a large group of transmembrane proteins that detect chemicals outside the cell and activate intracellular transduction pathways, thus triggering a cellular response to the external signal.': $i).
% 29.22/29.04  tff(decl_40712, type, 'g protein linked receptor': $i).
% 29.22/29.04  tff(decl_40713, type, 'g protein linked receptor protein': $i).
% 29.22/29.04  tff(decl_40714, type, 'g protein coupled receptor': $i).
% 29.22/29.04  tff(decl_40715, type, 'g-protein coupled receptor': $i).
% 29.22/29.04  tff(decl_40716, type, gpcr: $i).
% 29.22/29.04  tff(decl_40717, type, 'g-protein-coupled-receptor': $i).
% 29.22/29.04  tff(decl_40718, type, fn_g_protein_coupled_receptor_1: $i > $i).
% 29.22/29.04  tff(decl_40719, type, 'G.Nicolson': $i).
% 29.22/29.04  tff(decl_40720, type, 'Biologist that studied biomembranes and developed the Fluid Mosaic Model for placement of membrane proteins.': $i).
% 29.22/29.04  tff(decl_40721, type, nicolson: $i).
% 29.22/29.04  tff(decl_40722, type, 'g.nicolson': $i).
% 29.22/29.04  tff(decl_40723, type, 'G0-Phase': $i).
% 29.22/29.04  tff(decl_40724, type, 'A resting state in which cells have left the cell cycle and are not dividing.': $i).
% 29.22/29.04  tff(decl_40725, type, 'resting phase': $i).
% 29.22/29.04  tff(decl_40726, type, 'resting-phase': $i).
% 29.22/29.04  tff(decl_40727, type, 'undergo the g0 phase': $i).
% 29.22/29.04  tff(decl_40728, type, 'undergo the g0-phase': $i).
% 29.22/29.04  tff(decl_40729, type, 'g0 phase': $i).
% 29.22/29.04  tff(decl_40730, type, 'g0-phase': $i).
% 29.22/29.04  tff(decl_40731, type, fn_g0_phase_1: $i > $i).
% 29.22/29.04  tff(decl_40732, type, g1_checkpoint_1: $i > $o).
% 29.22/29.04  tff(decl_40733, type, 'G1-Checkpoint': $i).
% 29.22/29.04  tff(decl_40734, type, 'Checkpoint in the regulation of the cell cycle which occurs between the G1 and S phases of the cycle.': $i).
% 29.22/29.04  tff(decl_40735, type, 'restriction point': $i).
% 29.22/29.04  tff(decl_40736, type, 'g1 checkpoint': $i).
% 29.22/29.04  tff(decl_40737, type, 'g1-checkpoint': $i).
% 29.22/29.04  tff(decl_40738, type, fn_g1_checkpoint_2: $i > $i).
% 29.22/29.04  tff(decl_40739, type, checkpoint_0: $i).
% 29.22/29.04  tff(decl_40740, type, g1_checkpoint_in_animal_cell_1: $i > $o).
% 29.22/29.04  tff(decl_40741, type, 'G1-Checkpoint-In-Animal-Cell': $i).
% 29.22/29.04  tff(decl_40742, type, 'Checkpoint in the regulation of the animal cell cycle which occurs between the G1 and S phases of the cycle..': $i).
% 29.22/29.04  tff(decl_40743, type, 'g1 checkpoint in animal cell': $i).
% 29.22/29.04  tff(decl_40744, type, 'g1-checkpoint-in-animal-cell': $i).
% 29.22/29.04  tff(decl_40745, type, fn_g1_checkpoint_in_animal_cell_2: $i > $i).
% 29.22/29.04  tff(decl_40746, type, fn_g1_checkpoint_in_animal_cell_3: $i > $i).
% 29.22/29.04  tff(decl_40747, type, fn_g1_checkpoint_in_animal_cell_4: $i > $i).
% 29.22/29.04  tff(decl_40748, type, g1_phase_1: $i > $o).
% 29.22/29.04  tff(decl_40749, type, 'G1-Phase': $i).
% 29.22/29.04  tff(decl_40750, type, 'The first gap phase of the cell cycle. During the G1 phase the cell grows and produces the proteins and mRNA that are required for DNA synthesis.': $i).
% 29.22/29.04  tff(decl_40751, type, 'first gap': $i).
% 29.22/29.04  tff(decl_40752, type, 'initial interphase': $i).
% 29.22/29.04  tff(decl_40753, type, 'initial-interphase': $i).
% 29.22/29.04  tff(decl_40754, type, 'g1 phase': $i).
% 29.22/29.04  tff(decl_40755, type, 'g1-phase': $i).
% 29.22/29.04  tff(decl_40756, type, fn_g1_phase_1: $i > $i).
% 29.22/29.04  tff(decl_40757, type, fn_g1_phase_2: $i > $i).
% 29.22/29.04  tff(decl_40758, type, synthesis_of_organelle_1: $i > $o).
% 29.22/29.04  tff(decl_40759, type, fn_g1_phase_3: $i > $i).
% 29.22/29.04  tff(decl_40760, type, fn_g1_phase_4: $i > $i).
% 29.22/29.04  tff(decl_40761, type, fn_g1_phase_5: $i > $i).
% 29.22/29.04  tff(decl_40762, type, fn_g1_phase_6: $i > $i).
% 29.22/29.04  tff(decl_40763, type, fn_g1_phase_7: $i > $i).
% 29.22/29.04  tff(decl_40764, type, g2_checkpoint_1: $i > $o).
% 29.22/29.04  tff(decl_40765, type, 'G2-Checkpoint': $i).
% 29.22/29.04  tff(decl_40766, type, 'A control checkpoint at the end of the G2 phase of the cell cycle where the cell determines whether the cell can proceed to the M phase.': $i).
% 29.22/29.04  tff(decl_40767, type, 'g2 checkpoint': $i).
% 29.22/29.04  tff(decl_40768, type, 'g2-checkpoint': $i).
% 29.22/29.04  tff(decl_40769, type, fn_g2_checkpoint_1: $i > $i).
% 29.22/29.04  tff(decl_40770, type, fn_g2_checkpoint_2: $i > $i).
% 29.22/29.04  tff(decl_40771, type, g2_phase_1: $i > $o).
% 29.22/29.04  tff(decl_40772, type, fn_g2_checkpoint_3: $i > $i).
% 29.22/29.04  tff(decl_40773, type, fn_g2_checkpoint_4: $i > $i).
% 29.22/29.04  tff(decl_40774, type, fn_g2_checkpoint_5: $i > $i).
% 29.22/29.04  tff(decl_40775, type, 'G2-Phase': $i).
% 29.22/29.04  tff(decl_40776, type, 'The second gap phase of the cell cycle. The G2 phase is the last portion of interphase, following DNA synthesis.': $i).
% 29.22/29.04  tff(decl_40777, type, 'second gap': $i).
% 29.22/29.04  tff(decl_40778, type, 'late interphase': $i).
% 29.22/29.04  tff(decl_40779, type, 'late-interphase': $i).
% 29.22/29.04  tff(decl_40780, type, 'g2 phase': $i).
% 29.22/29.04  tff(decl_40781, type, 'g2-phase': $i).
% 29.22/29.04  tff(decl_40782, type, fn_g2_phase_1: $i > $i).
% 29.22/29.04  tff(decl_40783, type, fn_g2_phase_3: $i > $i).
% 29.22/29.04  tff(decl_40784, type, fn_g2_phase_4: $i > $i).
% 29.22/29.04  tff(decl_40785, type, fn_g2_phase_5: $i > $i).
% 29.22/29.04  tff(decl_40786, type, fn_g2_phase_6: $i > $i).
% 29.22/29.04  tff(decl_40787, type, fn_g2_phase_7: $i > $i).
% 29.22/29.04  tff(decl_40788, type, fn_g2_phase_8: $i > $i).
% 29.22/29.04  tff(decl_40789, type, fn_g2_phase_9: $i > $i).
% 29.22/29.04  tff(decl_40790, type, fn_g2_phase_10: $i > $i).
% 29.22/29.04  tff(decl_40791, type, fn_g2_phase_11: $i > $i).
% 29.22/29.04  tff(decl_40792, type, fn_g2_phase_12: $i > $i).
% 29.22/29.04  tff(decl_40793, type, fn_g2_phase_13: $i > $i).
% 29.22/29.04  tff(decl_40794, type, fn_g2_phase_14: $i > $i).
% 29.22/29.04  tff(decl_40795, type, fn_synthesis_of_organelle_1: $i > $i).
% 29.22/29.04  tff(decl_40796, type, gaba_1: $i > $o).
% 29.22/29.04  tff(decl_40797, type, 'GABA': $i).
% 29.22/29.04  tff(decl_40798, type, 'Gamma-aminobutyric acid, the primary inhibitory neurotransmitter in the central nervous system of mammals.': $i).
% 29.22/29.04  tff(decl_40799, type, 'gamma aminobutyric acid': $i).
% 29.22/29.04  tff(decl_40800, type, 'gamma-aminobutyric-acid': $i).
% 29.22/29.04  tff(decl_40801, type, gaba: $i).
% 29.22/29.04  tff(decl_40802, type, gadolinium_1: $i > $o).
% 29.22/29.04  tff(decl_40803, type, 'Gadolinium': $i).
% 29.22/29.04  tff(decl_40804, type, 'Gadolinium is a metal atom with atomic number 64. It is represented by the symbol Gd.': $i).
% 29.22/29.04  tff(decl_40805, type, gadolinium: $i).
% 29.22/29.04  tff(decl_40806, type, gd: $i).
% 29.22/29.04  tff(decl_40807, type, fn_gadolinium_4: $i > $i).
% 29.22/29.04  tff(decl_40808, type, fn_gadolinium_5: $i > $i).
% 29.22/29.04  tff(decl_40809, type, fn_gadolinium_6: $i > $i).
% 29.22/29.04  tff(decl_40810, type, fn_gadolinium_7: $i > $i).
% 29.22/29.04  tff(decl_40811, type, fn_gadolinium_11: $i > $i).
% 29.22/29.04  tff(decl_40812, type, fn_gadolinium_12: $i > $i).
% 29.22/29.04  tff(decl_40813, type, fn_gadolinium_13: $i > $i).
% 29.22/29.04  tff(decl_40814, type, fn_gadolinium_14: $i > $i).
% 29.22/29.04  tff(decl_40815, type, "93": $i).
% 29.22/29.04  tff(decl_40816, type, "157.3": $i).
% 29.22/29.04  tff(decl_40817, type, fn_gadolinium_9: $i > $i).
% 29.22/29.04  tff(decl_40818, type, fn_gadolinium_10: $i > $i).
% 29.22/29.04  tff(decl_40819, type, fn_gadolinium_8: $i > $i).
% 29.22/29.04  tff(decl_40820, type, 'Gain': $i).
% 29.22/29.04  tff(decl_40821, type, 'The result of making profit': $i).
% 29.22/29.04  tff(decl_40822, type, gain: $i).
% 29.22/29.04  tff(decl_40823, type, 'Galactose': $i).
% 29.22/29.04  tff(decl_40824, type, 'Galactose is a simple six carbon monosaccharide having an aldehyde group. It is a monomer of Lactose.': $i).
% 29.22/29.04  tff(decl_40825, type, galactose: $i).
% 29.22/29.04  tff(decl_40826, type, 'Galapagos-Finch': $i).
% 29.22/29.04  tff(decl_40827, type, 'A group of about 15 species of passerine birds, all but one of which are endemic to the Galapagos Islands. They were collected and studied by Charles Darwin.': $i).
% 29.22/29.04  tff(decl_40828, type, 'finch of galapagos': $i).
% 29.22/29.04  tff(decl_40829, type, 'galapagos finch': $i).
% 29.22/29.04  tff(decl_40830, type, 'galapagos-finch': $i).
% 29.22/29.04  tff(decl_40831, type, 'Gallbladder': $i).
% 29.22/29.04  tff(decl_40832, type, 'A small organ that aids in the digestion of fats. It stores and concentrates bile that is secreted by the liver and releases it into the small intestine as needed.': $i).
% 29.22/29.04  tff(decl_40833, type, gallbladder: $i).
% 29.22/29.04  tff(decl_40834, type, fn_gallbladder_1: $i > $i).
% 29.22/29.04  tff(decl_40835, type, fn_gallbladder_2: $i > $i).
% 29.22/29.04  tff(decl_40836, type, fn_gallbladder_3: $i > $i).
% 29.22/29.04  tff(decl_40837, type, gallium_1: $i > $o).
% 29.22/29.04  tff(decl_40838, type, 'Gallium': $i).
% 29.22/29.04  tff(decl_40839, type, 'Gallium is a metal atom with atomic number 31. It is represented by the symbol Ga.': $i).
% 29.22/29.04  tff(decl_40840, type, gallium: $i).
% 29.22/29.04  tff(decl_40841, type, fn_gallium_3: $i > $i).
% 29.22/29.04  tff(decl_40842, type, fn_gallium_4: $i > $i).
% 29.22/29.04  tff(decl_40843, type, fn_gallium_5: $i > $i).
% 29.22/29.04  tff(decl_40844, type, fn_gallium_9: $i > $i).
% 29.22/29.04  tff(decl_40845, type, fn_gallium_10: $i > $i).
% 29.22/29.04  tff(decl_40846, type, fn_gallium_11: $i > $i).
% 29.22/29.04  tff(decl_40847, type, fn_gallium_12: $i > $i).
% 29.22/29.04  tff(decl_40848, type, "39": $i).
% 29.22/29.04  tff(decl_40849, type, "31": $i).
% 29.22/29.04  tff(decl_40850, type, "1.81": $i).
% 29.22/29.04  tff(decl_40851, type, "70": $i).
% 29.22/29.04  tff(decl_40852, type, "69.72": $i).
% 29.22/29.04  tff(decl_40853, type, fn_gallium_7: $i > $i).
% 29.22/29.04  tff(decl_40854, type, fn_gallium_8: $i > $i).
% 29.22/29.04  tff(decl_40855, type, fn_gallium_6: $i > $i).
% 29.22/29.04  tff(decl_40856, type, 'Galvanometer': $i).
% 29.22/29.04  tff(decl_40857, type, 'An instrument which measures electrical current.': $i).
% 29.22/29.04  tff(decl_40858, type, galvanometer: $i).
% 29.22/29.04  tff(decl_40859, type, fn_galvanometer_1: $i > $i).
% 29.22/29.04  tff(decl_40860, type, fn_galvanometer_2: $i > $i).
% 29.22/29.04  tff(decl_40861, type, game_theory_1: $i > $o).
% 29.22/29.04  tff(decl_40862, type, 'Game-Theory': $i).
% 29.22/29.04  tff(decl_40863, type, 'An approach to the study of animal behavior in situations in which the outcome of one alternative strategy is dependent on the strategies used by other individuals in the population.': $i).
% 29.22/29.04  tff(decl_40864, type, 'theory of game': $i).
% 29.22/29.04  tff(decl_40865, type, 'game theory': $i).
% 29.22/29.04  tff(decl_40866, type, 'game-theory': $i).
% 29.22/29.04  tff(decl_40867, type, gametangium_1: $i > $o).
% 29.22/29.04  tff(decl_40868, type, 'Gametangium': $i).
% 29.22/29.04  tff(decl_40869, type, 'An organ in which gametes are produced. Found in algae, fungi, and the gametophytes of plants. Archegonia are female gametangia; antheridia are male gametangia.': $i).
% 29.22/29.04  tff(decl_40870, type, gametangia: $i).
% 29.22/29.04  tff(decl_40871, type, gametangium: $i).
% 29.22/29.04  tff(decl_40872, type, 'Gamete': $i).
% 29.22/29.04  tff(decl_40873, type, 'A haploid germ cell, such as an egg or sperm. During sexual fertilization, gametes fuse to produce a diploid zygote.': $i).
% 29.22/29.04  tff(decl_40874, type, 'sex cell': $i).
% 29.22/29.04  tff(decl_40875, type, 'germ cell': $i).
% 29.22/29.04  tff(decl_40876, type, 'reproductive cell': $i).
% 29.22/29.04  tff(decl_40877, type, 'human sex cell': $i).
% 29.22/29.04  tff(decl_40878, type, gamete: $i).
% 29.22/29.04  tff(decl_40879, type, gamete_production_1: $i > $o).
% 29.22/29.04  tff(decl_40880, type, 'Gamete-Production': $i).
% 29.22/29.04  tff(decl_40881, type, 'The formation of sex cells, egg cells in females and sperm cells in males, within the gonads, ovaries in females and testes in males, in a process known as gametogenesis.': $i).
% 29.22/29.04  tff(decl_40882, type, gametogenesis: $i).
% 29.22/29.04  tff(decl_40883, type, 'production of gamete': $i).
% 29.22/29.04  tff(decl_40884, type, 'gamete production': $i).
% 29.22/29.04  tff(decl_40885, type, 'gamete-production': $i).
% 29.22/29.04  tff(decl_40886, type, 'Gametogenesis': $i).
% 29.22/29.04  tff(decl_40887, type, 'The biological process by which haploid gametes are produced from diploid or haploid precursors.': $i).
% 29.22/29.04  tff(decl_40888, type, fn_gametogenesis_1: $i > $i).
% 29.22/29.04  tff(decl_40889, type, fn_gametogenesis_2: $i > $i).
% 29.22/29.04  tff(decl_40890, type, gametogenesis_in_animal_1: $i > $o).
% 29.22/29.04  tff(decl_40891, type, 'Gametogenesis-In-Animal': $i).
% 29.22/29.04  tff(decl_40892, type, 'The process in which gametes are produced in animals.': $i).
% 29.22/29.04  tff(decl_40893, type, 'gametogenesis in animal': $i).
% 29.22/29.04  tff(decl_40894, type, 'gametogenesis-in-animal': $i).
% 29.22/29.04  tff(decl_40895, type, fn_gametogenesis_in_animal_1: $i > $i).
% 29.22/29.04  tff(decl_40896, type, gonad_1: $i > $o).
% 29.22/29.04  tff(decl_40897, type, fn_gametogenesis_in_animal_2: $i > $i).
% 29.22/29.04  tff(decl_40898, type, fn_gametogenesis_in_animal_3: $i > $i).
% 29.22/29.04  tff(decl_40899, type, gametogenesis_in_human_1: $i > $o).
% 29.22/29.04  tff(decl_40900, type, 'Gametogenesis-In-Human': $i).
% 29.22/29.04  tff(decl_40901, type, 'The process in which gametes are produced in humans.': $i).
% 29.22/29.04  tff(decl_40902, type, 'gametogenesis in human': $i).
% 29.22/29.04  tff(decl_40903, type, 'gametogenesis-in-human': $i).
% 29.22/29.04  tff(decl_40904, type, fn_gametogenesis_in_human_1: $i > $i).
% 29.22/29.04  tff(decl_40905, type, fn_gametogenesis_in_human_2: $i > $i).
% 29.22/29.04  tff(decl_40906, type, fn_gametogenesis_in_human_3: $i > $i).
% 29.22/29.04  tff(decl_40907, type, fn_gametogenesis_in_human_4: $i > $i).
% 29.22/29.04  tff(decl_40908, type, fn_gametogenesis_in_human_5: $i > $i).
% 29.22/29.04  tff(decl_40909, type, fn_gametogenesis_in_human_6: $i > $i).
% 29.22/29.04  tff(decl_40910, type, "23": $i).
% 29.22/29.04  tff(decl_40911, type, "46": $i).
% 29.22/29.04  tff(decl_40912, type, gametophore_1: $i > $o).
% 29.22/29.04  tff(decl_40913, type, 'Gametophore': $i).
% 29.22/29.04  tff(decl_40914, type, 'The structure in mosses and ferns that bears the sexually mature gametangia.': $i).
% 29.22/29.04  tff(decl_40915, type, gametophore: $i).
% 29.22/29.04  tff(decl_40916, type, 'Gametophyte': $i).
% 29.22/29.04  tff(decl_40917, type, 'The haploid, multicellular stage of organisms (e.g., plants and some algae) that undergo alternation of generations. The gametophyte generation produces gametes via mitosis. Fertilization occurs between gametes from different individuals, resulting in a diploid zygote that develops into the sporophyte generation.': $i).
% 29.22/29.04  tff(decl_40918, type, gametophyte: $i).
% 29.22/29.04  tff(decl_40919, type, 'Gamma-Rays': $i).
% 29.22/29.04  tff(decl_40920, type, 'Gamma-rays are the radiation with wavelenth ranging from 0.00001 nm to 0.001 nm. Their wavelength is shortest of all the radiations.': $i).
% 29.22/29.04  tff(decl_40921, type, 'gamma ray': $i).
% 29.22/29.04  tff(decl_40922, type, 'gamma-ray': $i).
% 29.22/29.04  tff(decl_40923, type, fn_gamma_rays_4: $i > $i).
% 29.22/29.04  tff(decl_40924, type, fn_gamma_rays_5: $i > $i).
% 29.22/29.04  tff(decl_40925, type, fn_gamma_rays_6: $i > $i).
% 29.22/29.04  tff(decl_40926, type, "1.0e-5": $i).
% 29.22/29.04  tff(decl_40927, type, "0.001e0": $i).
% 29.22/29.04  tff(decl_40928, type, 'Ganglion': $i).
% 29.22/29.04  tff(decl_40929, type, 'A tissue of concentrated nerve cell bodies.': $i).
% 29.22/29.04  tff(decl_40930, type, ganglion: $i).
% 29.22/29.04  tff(decl_40931, type, 'Ganglion-Cell': $i).
% 29.22/29.04  tff(decl_40932, type, 'A type of neuron in the retina that receives visual information from the photoreceptors and relays that information via action potentials to the brain.': $i).
% 29.22/29.04  tff(decl_40933, type, 'cell of ganglion': $i).
% 29.22/29.04  tff(decl_40934, type, 'ganglion cell': $i).
% 29.22/29.04  tff(decl_40935, type, 'ganglion-cell': $i).
% 29.22/29.04  tff(decl_40936, type, 'Gap-Gene': $i).
% 29.22/29.04  tff(decl_40937, type, 'A type of gene that is involved in the development of segmented embryos in arthropods. Mutations in gap genes cause the loss of a series of adjacent segments, producing a': $i).
% 29.22/29.04  tff(decl_40938, type, 'gene of gap': $i).
% 29.22/29.04  tff(decl_40939, type, 'gap gene': $i).
% 29.22/29.04  tff(decl_40940, type, 'gap-gene': $i).
% 29.22/29.04  tff(decl_40941, type, laci_1: $i > $o).
% 29.22/29.04  tff(decl_40942, type, sonic_hedgehog_factor_1: $i > $o).
% 29.22/29.04  tff(decl_40943, type, trpr_1: $i > $o).
% 29.22/29.04  tff(decl_40944, type, gap_gene_mutation_1: $i > $o).
% 29.22/29.04  tff(decl_40945, type, 'Gap-Gene-Mutation': $i).
% 29.22/29.04  tff(decl_40946, type, 'Mutations in the gene encoding gap junction protein .': $i).
% 29.22/29.04  tff(decl_40947, type, 'gap gene mutation': $i).
% 29.22/29.04  tff(decl_40948, type, 'gap-gene-mutation': $i).
% 29.22/29.04  tff(decl_40949, type, fn_gap_gene_mutation_1: $i > $i).
% 29.22/29.04  tff(decl_40950, type, fn_gap_gene_mutation_2: $i > $i).
% 29.22/29.04  tff(decl_40951, type, fn_gap_gene_mutation_3: $i > $i).
% 29.22/29.04  tff(decl_40952, type, gap_in_segmentation_1: $i > $o).
% 29.22/29.04  tff(decl_40953, type, fn_gap_gene_mutation_4: $i > $i).
% 29.22/29.04  tff(decl_40954, type, fn_gap_in_segmentation_1: $i > $i).
% 29.22/29.04  tff(decl_40955, type, fn_mutation_2: $i > $i).
% 29.22/29.04  tff(decl_40956, type, 'Gap-In-Segmentation': $i).
% 29.22/29.04  tff(decl_40957, type, 'Mutations in the gap genes result in gaps in the segmentation pattern.': $i).
% 29.22/29.04  tff(decl_40958, type, 'gap in segmentation': $i).
% 29.22/29.04  tff(decl_40959, type, 'gap-in-segmentation': $i).
% 29.22/29.04  tff(decl_40960, type, fn_gap_in_segmentation_2: $i > $i).
% 29.22/29.04  tff(decl_40961, type, fn_gap_in_segmentation_3: $i > $i).
% 29.22/29.04  tff(decl_40962, type, fn_gap_in_segmentation_4: $i > $i).
% 29.22/29.04  tff(decl_40963, type, 'Gap-Junction': $i).
% 29.22/29.04  tff(decl_40964, type, 'Gap junctions, also called communicating junctions, provide cytoplasmic channels between animal cells.': $i).
% 29.22/29.04  tff(decl_40965, type, 'communicating junction': $i).
% 29.22/29.04  tff(decl_40966, type, 'junction of gap': $i).
% 29.22/29.04  tff(decl_40967, type, 'gap junction': $i).
% 29.22/29.04  tff(decl_40968, type, 'gap-junction': $i).
% 29.22/29.04  tff(decl_40969, type, fn_gap_junction_2: $i > $i).
% 29.22/29.04  tff(decl_40970, type, fn_gap_junction_3: $i > $i).
% 29.22/29.04  tff(decl_40971, type, fn_gap_junction_4: $i > $i).
% 29.22/29.04  tff(decl_40972, type, fn_gap_junction_5: $i > $i).
% 29.22/29.04  tff(decl_40973, type, fn_gap_junction_6: $i > $i).
% 29.22/29.04  tff(decl_40974, type, fn_gap_junction_7: $i > $i).
% 29.22/29.04  tff(decl_40975, type, fn_gap_junction_8: $i > $i).
% 29.22/29.04  tff(decl_40976, type, fn_gap_junction_11: $i > $i).
% 29.22/29.04  tff(decl_40977, type, fn_gap_junction_12: $i > $i).
% 29.22/29.04  tff(decl_40978, type, fn_gap_junction_13: $i > $i).
% 29.22/29.04  tff(decl_40979, type, fn_gap_junction_14: $i > $i).
% 29.22/29.04  tff(decl_40980, type, fn_gap_junction_15: $i > $i).
% 29.22/29.04  tff(decl_40981, type, 'Gary-Borisy': $i).
% 29.22/29.04  tff(decl_40982, type, 'Scientist at the University of Wisconsin who studied the shortening of microtubules during mitosis.': $i).
% 29.22/29.04  tff(decl_40983, type, 'gary borisy': $i).
% 29.22/29.04  tff(decl_40984, type, 'gary-borisy': $i).
% 29.22/29.04  tff(decl_40985, type, 'Gas-Exchange': $i).
% 29.22/29.04  tff(decl_40986, type, 'The exchange of gases between an organism and the environment. In animals, gas exchange refers to the uptake of oxygen from the environment and discharge of carbon dioxide to the environment.': $i).
% 29.22/29.04  tff(decl_40987, type, 'exchange of gas': $i).
% 29.22/29.04  tff(decl_40988, type, 'gas exchange': $i).
% 29.22/29.04  tff(decl_40989, type, 'gas-exchange': $i).
% 29.22/29.04  tff(decl_40990, type, 'Gas-Substance': $i).
% 29.22/29.04  tff(decl_40991, type, 'A substance in the gaseous state at room temperature': $i).
% 29.22/29.04  tff(decl_40992, type, gas: $i).
% 29.22/29.04  tff(decl_40993, type, 'substance of gas': $i).
% 29.22/29.04  tff(decl_40994, type, 'gas substance': $i).
% 29.22/29.04  tff(decl_40995, type, 'gas-substance': $i).
% 29.22/29.04  tff(decl_40996, type, gasoline_1: $i > $o).
% 29.22/29.04  tff(decl_40997, type, 'Gasoline': $i).
% 29.22/29.04  tff(decl_40998, type, 'A volatile mixture of flammable liquid hydrocarbons derived from crude petroleum and used principally as a fuel for internal-combustion engines.': $i).
% 29.22/29.04  tff(decl_40999, type, gasoline: $i).
% 29.22/29.04  tff(decl_41000, type, fn_gasoline_1: $i > $i).
% 29.22/29.04  tff(decl_41001, type, fn_gasoline_2: $i > $i).
% 29.22/29.04  tff(decl_41002, type, fn_gasoline_3: $i > $i).
% 29.22/29.04  tff(decl_41003, type, 'Gastric-Cecum': $i).
% 29.22/29.04  tff(decl_41004, type, 'Pouch in the midgut of the alimentary canal of insects which function in digestion and absorption.': $i).
% 29.22/29.04  tff(decl_41005, type, 'gastric cecum': $i).
% 29.22/29.04  tff(decl_41006, type, 'gastric-cecum': $i).
% 29.22/29.04  tff(decl_41007, type, 'Gastric-Gland': $i).
% 29.22/29.04  tff(decl_41008, type, 'Exocrine glands found in the lining of the stomach which secrete mucus, pepsinogen and hydrochloric acid into the stomack lumen.': $i).
% 29.22/29.04  tff(decl_41009, type, 'gastric gland': $i).
% 29.22/29.04  tff(decl_41010, type, 'gastric-gland': $i).
% 29.22/29.04  tff(decl_41011, type, fn_gastric_gland_1: $i > $i).
% 29.22/29.04  tff(decl_41012, type, parietal_cell_1: $i > $o).
% 29.22/29.04  tff(decl_41013, type, 'Gastric-Juice': $i).
% 29.22/29.04  tff(decl_41014, type, 'A digestive fluid secreted by the stomach which is acidic in nature.': $i).
% 29.22/29.04  tff(decl_41015, type, 'gastric juice': $i).
% 29.22/29.04  tff(decl_41016, type, 'gastric-juice': $i).
% 29.22/29.04  tff(decl_41017, type, fn_gastric_juice_2: $i > $i).
% 29.22/29.04  tff(decl_41018, type, fn_gastric_juice_3: $i > $i).
% 29.22/29.04  tff(decl_41019, type, pepsin_1: $i > $o).
% 29.22/29.04  tff(decl_41020, type, fn_gastric_juice_6: $i > $i).
% 29.22/29.04  tff(decl_41021, type, fn_gastric_juice_7: $i > $i).
% 29.22/29.04  tff(decl_41022, type, fn_gastric_juice_10: $i > $i).
% 29.22/29.04  tff(decl_41023, type, fn_gastric_juice_11: $i > $i).
% 29.22/29.04  tff(decl_41024, type, fn_gastric_juice_12: $i > $i).
% 29.22/29.04  tff(decl_41025, type, fn_gastric_juice_13: $i > $i).
% 29.22/29.04  tff(decl_41026, type, fn_gastric_juice_14: $i > $i).
% 29.22/29.04  tff(decl_41027, type, hydrochloric_acid_1: $i > $o).
% 29.22/29.04  tff(decl_41028, type, fn_gastric_juice_15: $i > $i).
% 29.22/29.04  tff(decl_41029, type, fn_gastric_juice_16: $i > $i).
% 29.22/29.04  tff(decl_41030, type, fn_gastric_juice_17: $i > $i).
% 29.22/29.04  tff(decl_41031, type, fn_gastric_juice_18: $i > $i).
% 29.22/29.04  tff(decl_41032, type, fn_gastric_juice_19: $i > $i).
% 29.22/29.04  tff(decl_41033, type, fn_gastric_juice_21: $i > $i).
% 29.22/29.04  tff(decl_41034, type, fn_gastric_juice_22: $i > $i).
% 29.22/29.04  tff(decl_41035, type, fn_gastric_juice_23: $i > $i).
% 29.22/29.04  tff(decl_41036, type, fn_gastric_juice_24: $i > $i).
% 29.22/29.04  tff(decl_41037, type, fn_gastric_juice_25: $i > $i).
% 29.22/29.04  tff(decl_41038, type, fn_gastric_juice_26: $i > $i).
% 29.22/29.04  tff(decl_41039, type, fn_gastric_juice_27: $i > $i).
% 29.22/29.04  tff(decl_41040, type, fn_gastric_juice_28: $i > $i).
% 29.22/29.04  tff(decl_41041, type, fn_gastric_juice_29: $i > $i).
% 29.22/29.04  tff(decl_41042, type, fn_water_100: $i > $i).
% 29.22/29.04  tff(decl_41043, type, fn_strong_acid_6: $i > $i).
% 29.22/29.04  tff(decl_41044, type, fn_strong_acid_3: $i > $i).
% 29.22/29.04  tff(decl_41045, type, fn_strong_acid_4: $i > $i).
% 29.22/29.04  tff(decl_41046, type, fn_strong_acid_5: $i > $i).
% 29.22/29.04  tff(decl_41047, type, strong_acid_0: $i).
% 29.22/29.04  tff(decl_41048, type, fn_gastric_juice_9: $i > $i).
% 29.22/29.04  tff(decl_41049, type, fn_acidic_solution_3: $i > $i).
% 29.22/29.04  tff(decl_41050, type, fn_gastric_juice_8: $i > $i).
% 29.22/29.04  tff(decl_41051, type, fn_acidic_solution_8: $i > $i).
% 29.22/29.04  tff(decl_41052, type, fn_gastric_juice_20: $i > $i).
% 29.22/29.04  tff(decl_41053, type, fn_biological_fluid_2: $i > $i).
% 29.22/29.04  tff(decl_41054, type, fn_acidic_solution_5: $i > $i).
% 29.22/29.04  tff(decl_41055, type, 'Gastric-Ulcer': $i).
% 29.22/29.04  tff(decl_41056, type, 'An erosion of the stomach lining, typically caused by the bacterium Helicobacter pylori.': $i).
% 29.22/29.04  tff(decl_41057, type, ulcer: $i).
% 29.22/29.04  tff(decl_41058, type, 'gastric ulcer': $i).
% 29.22/29.04  tff(decl_41059, type, 'gastric-ulcer': $i).
% 29.22/29.04  tff(decl_41060, type, 'Gastrin': $i).
% 29.22/29.04  tff(decl_41061, type, 'Peptide hormone secreted by the stomach which stimulates the production of gastric acid.': $i).
% 29.22/29.04  tff(decl_41062, type, gastrin: $i).
% 29.22/29.04  tff(decl_41063, type, fn_gastrin_1: $i > $i).
% 29.22/29.04  tff(decl_41064, type, 'Gastrodermal-Cell': $i).
% 29.22/29.04  tff(decl_41065, type, 'Cells specialized for nutrient absorption in some invertebrates.': $i).
% 29.22/29.04  tff(decl_41066, type, 'gastrodermal cell': $i).
% 29.22/29.04  tff(decl_41067, type, 'gastrodermal-cell': $i).
% 29.22/29.04  tff(decl_41068, type, 'Gastrodermis': $i).
% 29.22/29.04  tff(decl_41069, type, 'Inner layer of body plan of some invertebrates which lines the gastrovascular cavity and contains cells specialized for nutrient absorption.': $i).
% 29.22/29.04  tff(decl_41070, type, gastrodermis: $i).
% 29.22/29.04  tff(decl_41071, type, 'Gastropod': $i).
% 29.22/29.04  tff(decl_41072, type, 'Any member of the molluscan class Gastropoda, characterized by a distinct head, a single foot used for creeping, and the process of torsion during larval development. Examples of gastropods include snails, slugs, limpets, and abalones.': $i).
% 29.22/29.04  tff(decl_41073, type, gastropod: $i).
% 29.22/29.04  tff(decl_41074, type, 'Gastrovascular-Cavity': $i).
% 29.22/29.04  tff(decl_41075, type, 'A digestive cavity with a single opening that serves as both mouth and anus, found in cnidarians and ctenophores. The cavity is continually open to the surrounding environment and functions to distribute nutrients as well as digest food.': $i).
% 29.22/29.04  tff(decl_41076, type, 'gastrovascular cavity': $i).
% 29.22/29.04  tff(decl_41077, type, 'gastrovascular-cavity': $i).
% 29.22/29.04  tff(decl_41078, type, gastrula_1: $i > $o).
% 29.22/29.04  tff(decl_41079, type, 'Gastrula': $i).
% 29.22/29.04  tff(decl_41080, type, 'In early animal development, the embryonic stage that follows the blastula. A gastrula contains an invagination that becomes the animal\\s first digestive tract, called the archenteron, and the first two embryonic germ layers (ectoderm and endoderm).': $i).
% 29.22/29.04  tff(decl_41081, type, 'gastrula stage': $i).
% 29.22/29.04  tff(decl_41082, type, gastrula: $i).
% 29.22/29.04  tff(decl_41083, type, fn_gastrula_1: $i > $i).
% 29.22/29.04  tff(decl_41084, type, fn_gastrula_2: $i > $i).
% 29.22/29.04  tff(decl_41085, type, fn_gastrula_3: $i > $i).
% 29.22/29.04  tff(decl_41086, type, fn_gastrula_4: $i > $i).
% 29.22/29.04  tff(decl_41087, type, fn_gastrula_5: $i > $i).
% 29.22/29.04  tff(decl_41088, type, 'Gastrulation': $i).
% 29.22/29.04  tff(decl_41089, type, 'In early animal development, a process by which the single-layered blastula becomes a three-layered stage called a gastrula. Gastrulation involves the migration of cells inward, forming an invagination which becomes the archenteron. Gastrulation also establishes the three embryonic germ layers: ectoderm, mesoderm, and endoderm.': $i).
% 29.22/29.04  tff(decl_41090, type, 'undergo gastrulation': $i).
% 29.22/29.04  tff(decl_41091, type, gastrulation: $i).
% 29.22/29.04  tff(decl_41092, type, fn_gastrulation_1: $i > $i).
% 29.22/29.04  tff(decl_41093, type, fn_gastrulation_2: $i > $i).
% 29.22/29.04  tff(decl_41094, type, fn_gastrulation_3: $i > $i).
% 29.22/29.04  tff(decl_41095, type, fn_gastrulation_4: $i > $i).
% 29.22/29.04  tff(decl_41096, type, fn_gastrulation_5: $i > $i).
% 29.22/29.04  tff(decl_41097, type, fn_gastrulation_6: $i > $i).
% 29.22/29.04  tff(decl_41098, type, rudimentary_gut_cavity_1: $i > $o).
% 29.22/29.04  tff(decl_41099, type, fn_gastrulation_7: $i > $i).
% 29.22/29.04  tff(decl_41100, type, fn_gastrulation_8: $i > $i).
% 29.22/29.04  tff(decl_41101, type, 'Gated-Channel': $i).
% 29.22/29.04  tff(decl_41102, type, 'A transmembrane protein channel that opens or closes in response to a particular stimulus.': $i).
% 29.22/29.04  tff(decl_41103, type, 'gated channel': $i).
% 29.22/29.04  tff(decl_41104, type, 'gated-channel': $i).
% 29.22/29.04  tff(decl_41105, type, fn_gated_channel_1: $i > $i).
% 29.22/29.04  tff(decl_41106, type, fn_gated_channel_2: $i > $i).
% 29.22/29.04  tff(decl_41107, type, fn_gated_channel_5: $i > $i).
% 29.22/29.04  tff(decl_41108, type, fn_gated_channel_8: $i > $i).
% 29.22/29.04  tff(decl_41109, type, fn_gated_channel_9: $i > $i).
% 29.22/29.04  tff(decl_41110, type, fn_gated_channel_10: $i > $i).
% 29.22/29.04  tff(decl_41111, type, fn_gated_channel_11: $i > $i).
% 29.22/29.04  tff(decl_41112, type, fn_gated_channel_12: $i > $i).
% 29.22/29.04  tff(decl_41113, type, fn_gated_channel_14: $i > $i).
% 29.22/29.04  tff(decl_41114, type, fn_gated_channel_15: $i > $i).
% 29.22/29.04  tff(decl_41115, type, fn_gated_channel_18: $i > $i).
% 29.22/29.04  tff(decl_41116, type, fn_gated_channel_23: $i > $i).
% 29.22/29.04  tff(decl_41117, type, fn_gated_channel_27: $i > $i).
% 29.22/29.04  tff(decl_41118, type, fn_gated_channel_28: $i > $i).
% 29.22/29.04  tff(decl_41119, type, fn_gated_channel_31: $i > $i).
% 29.22/29.04  tff(decl_41120, type, fn_gated_channel_38: $i > $i).
% 29.22/29.04  tff(decl_41121, type, fn_open_1: $i > $i).
% 29.22/29.04  tff(decl_41122, type, fn_gated_channel_34: $i > $i).
% 29.22/29.04  tff(decl_41123, type, fn_gated_channel_35: $i > $i).
% 29.22/29.04  tff(decl_41124, type, fn_gated_channel_33: $i > $i).
% 29.22/29.04  tff(decl_41125, type, fn_channel_protein_1: $i > $i).
% 29.22/29.04  tff(decl_41126, type, fn_gated_channel_36: $i > $i).
% 29.22/29.04  tff(decl_41127, type, 'Gated-Ion-Channel': $i).
% 29.22/29.04  tff(decl_41128, type, 'A membrane channel that responds to a specific ion. Opening or closing of ion channels can change the membrane potential of a cell.': $i).
% 29.22/29.04  tff(decl_41129, type, 'gated ion channel': $i).
% 29.22/29.04  tff(decl_41130, type, 'gated-ion-channel': $i).
% 29.22/29.04  tff(decl_41131, type, fn_gated_ion_channel_1: $i > $i).
% 29.22/29.04  tff(decl_41132, type, fn_gated_ion_channel_2: $i > $i).
% 29.22/29.04  tff(decl_41133, type, fn_gated_ion_channel_3: $i > $i).
% 29.22/29.04  tff(decl_41134, type, 'GDP': $i).
% 29.22/29.04  tff(decl_41135, type, 'The dephosphorylated state of GTP.': $i).
% 29.22/29.04  tff(decl_41136, type, 'guanosine diphosphate': $i).
% 29.22/29.04  tff(decl_41137, type, 'guanosine-diphosphate': $i).
% 29.22/29.04  tff(decl_41138, type, gdp: $i).
% 29.22/29.04  tff(decl_41139, type, fn_gdp_1: $i > $i).
% 29.22/29.04  tff(decl_41140, type, fn_gdp_2: $i > $i).
% 29.22/29.04  tff(decl_41141, type, fn_gdp_3: $i > $i).
% 29.22/29.04  tff(decl_41142, type, fn_gdp_4: $i > $i).
% 29.22/29.04  tff(decl_41143, type, fn_gdp_5: $i > $i).
% 29.22/29.04  tff(decl_41144, type, fn_gdp_6: $i > $i).
% 29.22/29.04  tff(decl_41145, type, fn_gdp_7: $i > $i).
% 29.22/29.04  tff(decl_41146, type, fn_gdp_8: $i > $i).
% 29.22/29.04  tff(decl_41147, type, fn_gdp_9: $i > $i).
% 29.22/29.04  tff(decl_41148, type, fn_gdp_10: $i > $i).
% 29.22/29.04  tff(decl_41149, type, fn_gdp_11: $i > $i).
% 29.22/29.04  tff(decl_41150, type, fn_gdp_12: $i > $i).
% 29.22/29.04  tff(decl_41151, type, fn_gdp_13: $i > $i).
% 29.22/29.04  tff(decl_41152, type, fn_gdp_14: $i > $i).
% 29.22/29.04  tff(decl_41153, type, fn_gdp_15: $i > $i).
% 29.22/29.04  tff(decl_41154, type, fn_gdp_16: $i > $i).
% 29.22/29.04  tff(decl_41155, type, fn_gdp_17: $i > $i).
% 29.22/29.04  tff(decl_41156, type, fn_gdp_18: $i > $i).
% 29.22/29.04  tff(decl_41157, type, fn_gdp_19: $i > $i).
% 29.22/29.04  tff(decl_41158, type, fn_gdp_20: $i > $i).
% 29.22/29.04  tff(decl_41159, type, fn_gdp_21: $i > $i).
% 29.22/29.04  tff(decl_41160, type, fn_gdp_22: $i > $i).
% 29.22/29.04  tff(decl_41161, type, fn_gdp_23: $i > $i).
% 29.22/29.04  tff(decl_41162, type, fn_gdp_24: $i > $i).
% 29.22/29.04  tff(decl_41163, type, fn_gdp_25: $i > $i).
% 29.22/29.04  tff(decl_41164, type, fn_gdp_26: $i > $i).
% 29.22/29.04  tff(decl_41165, type, fn_gdp_27: $i > $i).
% 29.22/29.04  tff(decl_41166, type, fn_gdp_28: $i > $i).
% 29.22/29.04  tff(decl_41167, type, fn_gdp_29: $i > $i).
% 29.22/29.04  tff(decl_41168, type, fn_gdp_30: $i > $i).
% 29.22/29.04  tff(decl_41169, type, fn_gdp_31: $i > $i).
% 29.22/29.04  tff(decl_41170, type, fn_gdp_32: $i > $i).
% 29.22/29.04  tff(decl_41171, type, fn_gdp_33: $i > $i).
% 29.22/29.04  tff(decl_41172, type, fn_nucleoside_diphosphate_48: $i > $i).
% 29.22/29.04  tff(decl_41173, type, fn_nucleotide_25: $i > $i).
% 29.22/29.04  tff(decl_41174, type, fn_nucleoside_diphosphate_40: $i > $i).
% 29.22/29.04  tff(decl_41175, type, fn_nucleoside_diphosphate_39: $i > $i).
% 29.22/29.04  tff(decl_41176, type, gecko_lizard_1: $i > $o).
% 29.22/29.04  tff(decl_41177, type, 'Gecko-Lizard': $i).
% 29.22/29.04  tff(decl_41178, type, 'Order of tropical lizards with specialized toes for climbing.': $i).
% 29.22/29.04  tff(decl_41179, type, gecko: $i).
% 29.22/29.04  tff(decl_41180, type, 'lizard of gecko': $i).
% 29.22/29.04  tff(decl_41181, type, 'gecko lizard': $i).
% 29.22/29.04  tff(decl_41182, type, 'gecko-lizard': $i).
% 29.22/29.04  tff(decl_41183, type, squamata_1: $i > $o).
% 29.22/29.04  tff(decl_41184, type, fn_gecko_lizard_2: $i > $i).
% 29.22/29.04  tff(decl_41185, type, fn_gecko_lizard_3: $i > $i).
% 29.22/29.04  tff(decl_41186, type, fn_gecko_lizard_4: $i > $i).
% 29.22/29.04  tff(decl_41187, type, hair_1: $i > $o).
% 29.22/29.04  tff(decl_41188, type, fn_gecko_lizard_5: $i > $i).
% 29.22/29.04  tff(decl_41189, type, fn_gecko_lizard_6: $i > $i).
% 29.22/29.04  tff(decl_41190, type, fn_gecko_lizard_7: $i > $i).
% 29.22/29.04  tff(decl_41191, type, fn_gecko_lizard_8: $i > $i).
% 29.22/29.04  tff(decl_41192, type, fn_gecko_lizard_11: $i > $i).
% 29.22/29.04  tff(decl_41193, type, tip_1: $i > $o).
% 29.22/29.04  tff(decl_41194, type, fn_gecko_lizard_12: $i > $i).
% 29.22/29.04  tff(decl_41195, type, fn_gecko_lizard_14: $i > $i).
% 29.22/29.04  tff(decl_41196, type, fn_gecko_lizard_15: $i > $i).
% 29.22/29.04  tff(decl_41197, type, fn_gecko_lizard_18: $i > $i).
% 29.22/29.04  tff(decl_41198, type, fn_gecko_lizard_19: $i > $i).
% 29.22/29.04  tff(decl_41199, type, fn_gecko_lizard_20: $i > $i).
% 29.22/29.04  tff(decl_41200, type, fn_gecko_lizard_21: $i > $i).
% 29.22/29.04  tff(decl_41201, type, fn_gecko_lizard_22: $i > $i).
% 29.22/29.04  tff(decl_41202, type, fn_gecko_lizard_23: $i > $i).
% 29.22/29.04  tff(decl_41203, type, fn_gecko_lizard_24: $i > $i).
% 29.22/29.04  tff(decl_41204, type, fn_gecko_lizard_25: $i > $i).
% 29.22/29.04  tff(decl_41205, type, fn_gecko_lizard_26: $i > $i).
% 29.22/29.04  tff(decl_41206, type, fn_gecko_lizard_27: $i > $i).
% 29.22/29.04  tff(decl_41207, type, fn_gecko_lizard_28: $i > $i).
% 29.22/29.04  tff(decl_41208, type, fn_gecko_lizard_29: $i > $i).
% 29.22/29.04  tff(decl_41209, type, fn_gecko_lizard_30: $i > $i).
% 29.22/29.04  tff(decl_41210, type, fn_gecko_lizard_31: $i > $i).
% 29.22/29.04  tff(decl_41211, type, fn_gecko_lizard_32: $i > $i).
% 29.22/29.04  tff(decl_41212, type, fn_gecko_lizard_33: $i > $i).
% 29.22/29.04  tff(decl_41213, type, fn_gecko_lizard_34: $i > $i).
% 29.22/29.04  tff(decl_41214, type, fn_gecko_lizard_35: $i > $i).
% 29.22/29.04  tff(decl_41215, type, fn_gecko_lizard_36: $i > $i).
% 29.22/29.04  tff(decl_41216, type, fn_gecko_lizard_37: $i > $i).
% 29.22/29.04  tff(decl_41217, type, fn_gecko_lizard_38: $i > $i).
% 29.22/29.04  tff(decl_41218, type, fn_gecko_lizard_39: $i > $i).
% 29.22/29.04  tff(decl_41219, type, van_der_waal_interaction_1: $i > $o).
% 29.22/29.04  tff(decl_41220, type, fn_gecko_lizard_40: $i > $i).
% 29.22/29.04  tff(decl_41221, type, fn_gecko_lizard_41: $i > $i).
% 29.22/29.04  tff(decl_41222, type, organic_structure_1: $i > $o).
% 29.22/29.04  tff(decl_41223, type, fn_gecko_lizard_42: $i > $i).
% 29.22/29.04  tff(decl_41224, type, fn_gecko_lizard_43: $i > $i).
% 29.22/29.04  tff(decl_41225, type, fn_gecko_lizard_44: $i > $i).
% 29.22/29.04  tff(decl_41226, type, fn_gecko_lizard_45: $i > $i).
% 29.22/29.04  tff(decl_41227, type, fn_gecko_lizard_46: $i > $i).
% 29.22/29.04  tff(decl_41228, type, fn_organic_structure_1: $i > $i).
% 29.22/29.04  tff(decl_41229, type, fn_van_der_waal_interaction_2: $i > $i).
% 29.22/29.04  tff(decl_41230, type, fn_van_der_waal_interaction_1: $i > $i).
% 29.22/29.04  tff(decl_41231, type, leg_0: $i).
% 29.22/29.04  tff(decl_41232, type, hair_0: $i).
% 29.22/29.04  tff(decl_41233, type, fn_gecko_lizard_17: $i > $i).
% 29.22/29.04  tff(decl_41234, type, fn_gecko_lizard_16: $i > $i).
% 29.22/29.04  tff(decl_41235, type, fn_vertebrate_27: $i > $i).
% 29.22/29.04  tff(decl_41236, type, 'Gel': $i).
% 29.22/29.04  tff(decl_41237, type, 'A  matrix used to measure the size of nucleic acids via gel electrophoresis.': $i).
% 29.22/29.04  tff(decl_41238, type, 'agorose gel': $i).
% 29.22/29.04  tff(decl_41239, type, gel: $i).
% 29.22/29.04  tff(decl_41240, type, fn_gel_1: $i > $i).
% 29.22/29.04  tff(decl_41241, type, 'Gel-Electrophoresis': $i).
% 29.22/29.04  tff(decl_41242, type, 'A technique for separating nucleic acids or proteins on the basis of their size and electrical charge, both of which affect their rate of movement through an electric field in a gel.': $i).
% 29.22/29.04  tff(decl_41243, type, 'perform gel electrophoresis': $i).
% 29.22/29.04  tff(decl_41244, type, 'electrophoresis of gel': $i).
% 29.22/29.04  tff(decl_41245, type, 'gel electrophoresis': $i).
% 29.22/29.04  tff(decl_41246, type, 'gel-electrophoresis': $i).
% 29.22/29.04  tff(decl_41247, type, fn_gel_electrophoresis_3: $i > $i).
% 29.22/29.04  tff(decl_41248, type, fn_gel_electrophoresis_4: $i > $i).
% 29.22/29.04  tff(decl_41249, type, fn_gel_electrophoresis_5: $i > $i).
% 29.22/29.04  tff(decl_41250, type, gemmules_1: $i > $o).
% 29.22/29.04  tff(decl_41251, type, 'Gemmules': $i).
% 29.22/29.04  tff(decl_41252, type, 'Asexual dormant buds formed by some sponges in response to hostile environmental conditions. Gemmules can resist freezing, desiccation, and hypoxic conditions. When the environment becomes favorable, gemmules begin growing again.': $i).
% 29.22/29.04  tff(decl_41253, type, gemmules: $i).
% 29.22/29.04  tff(decl_41254, type, gemmule: $i).
% 29.22/29.04  tff(decl_41255, type, 'Gene': $i).
% 29.22/29.04  tff(decl_41256, type, 'A specific length of a DNA or RNA molecule (in some viruses) that functions as a discrete unit of inheritence.': $i).
% 29.22/29.04  tff(decl_41257, type, 'mendel\\s inheritable factor': $i).
% 29.22/29.04  tff(decl_41258, type, 'inheritable factor': $i).
% 29.22/29.04  tff(decl_41259, type, gene: $i).
% 29.22/29.04  tff(decl_41260, type, fn_gene_1: $i > $i).
% 29.22/29.04  tff(decl_41261, type, fn_gene_2: $i > $i).
% 29.22/29.04  tff(decl_41262, type, fn_gene_7: $i > $i).
% 29.22/29.04  tff(decl_41263, type, 'Gene-Activation': $i).
% 29.22/29.04  tff(decl_41264, type, 'The process of activation of a gene so that it is expressed at a particular time and location.': $i).
% 29.22/29.04  tff(decl_41265, type, 'activation of gene': $i).
% 29.22/29.04  tff(decl_41266, type, 'gene activation': $i).
% 29.22/29.04  tff(decl_41267, type, 'gene-activation': $i).
% 29.22/29.04  tff(decl_41268, type, fn_gene_activation_1: $i > $i).
% 29.22/29.04  tff(decl_41269, type, fn_gene_activation_2: $i > $i).
% 29.22/29.04  tff(decl_41270, type, fn_gene_activation_4: $i > $i).
% 29.22/29.04  tff(decl_41271, type, fn_gene_activation_5: $i > $i).
% 29.22/29.04  tff(decl_41272, type, fn_gene_activation_6: $i > $i).
% 29.22/29.04  tff(decl_41273, type, regulatory_gene_0: $i).
% 29.22/29.04  tff(decl_41274, type, 'Gene-Activation-Cascade': $i).
% 29.22/29.04  tff(decl_41275, type, 'Cascade of reactions that results in gene activation, or initiation of transcription.': $i).
% 29.22/29.04  tff(decl_41276, type, 'gene activation cascade': $i).
% 29.22/29.04  tff(decl_41277, type, 'gene-activation-cascade': $i).
% 29.22/29.04  tff(decl_41278, type, fn_gene_activation_cascade_1: $i > $i).
% 29.22/29.04  tff(decl_41279, type, fn_gene_activation_cascade_2: $i > $i).
% 29.22/29.04  tff(decl_41280, type, gene_allele_relationship_1: $i > $o).
% 29.22/29.04  tff(decl_41281, type, 'Gene-Allele-Relationship': $i).
% 29.22/29.04  tff(decl_41282, type, 'A particular gene on a chromosome has two or more versions, and each version of a gene is called an allele.': $i).
% 29.22/29.04  tff(decl_41283, type, 'have a gene allele relationship': $i).
% 29.22/29.04  tff(decl_41284, type, 'have a gene-allele relationship': $i).
% 29.22/29.04  tff(decl_41285, type, 'gene allele relationship': $i).
% 29.22/29.04  tff(decl_41286, type, 'gene-allele-relationship': $i).
% 29.22/29.04  tff(decl_41287, type, fn_gene_allele_relationship_1: $i > $i).
% 29.22/29.04  tff(decl_41288, type, fn_gene_allele_relationship_2: $i > $i).
% 29.22/29.04  tff(decl_41289, type, fn_gene_allele_relationship_3: $i > $i).
% 29.22/29.04  tff(decl_41290, type, fn_gene_allele_relationship_4: $i > $i).
% 29.22/29.04  tff(decl_41291, type, fn_gene_allele_relationship_5: $i > $i).
% 29.22/29.04  tff(decl_41292, type, fn_gene_allele_relationship_6: $i > $i).
% 29.22/29.04  tff(decl_41293, type, fn_gene_allele_relationship_7: $i > $i).
% 29.22/29.04  tff(decl_41294, type, fn_heterozygous_2: $i > $i).
% 29.22/29.04  tff(decl_41295, type, fn_heterozygous_1: $i > $i).
% 29.22/29.04  tff(decl_41296, type, 'Gene-Amplification': $i).
% 29.22/29.04  tff(decl_41297, type, 'In cells, the process of temporarily increasing the number of copies of a gene or gene family during a particular stage of development. In the laboratory, this term refers to the process of Polymerase Chain Reaction': $i).
% 29.22/29.04  tff(decl_41298, type, 'polymerase chain reaction': $i).
% 29.22/29.04  tff(decl_41299, type, 'polymerase-chain-reaction': $i).
% 29.22/29.04  tff(decl_41300, type, pcr: $i).
% 29.22/29.04  tff(decl_41301, type, 'amplification of gene': $i).
% 29.22/29.04  tff(decl_41302, type, 'gene amplification': $i).
% 29.22/29.04  tff(decl_41303, type, 'gene-amplification': $i).
% 29.22/29.04  tff(decl_41304, type, gene_loss_1: $i > $o).
% 29.22/29.04  tff(decl_41305, type, gene_rearrangement_1: $i > $o).
% 29.22/29.04  tff(decl_41306, type, fn_gene_amplification_1: $i > $i).
% 29.22/29.04  tff(decl_41307, type, fn_gene_amplification_3: $i > $i).
% 29.22/29.04  tff(decl_41308, type, fn_gene_amplification_5: $i > $i).
% 29.22/29.04  tff(decl_41309, type, 'Gene-Cloning': $i).
% 29.22/29.04  tff(decl_41310, type, 'The production of multiple copies of a gene.': $i).
% 29.22/29.04  tff(decl_41311, type, 'genetic cloning': $i).
% 29.22/29.04  tff(decl_41312, type, 'cloning of gene': $i).
% 29.22/29.04  tff(decl_41313, type, 'gene-cloning': $i).
% 29.22/29.04  tff(decl_41314, type, 'Gene-Expression': $i).
% 29.22/29.04  tff(decl_41315, type, 'The processes by which the information encoded in a gene is used to direct the synthesis of a polypeptide.': $i).
% 29.22/29.04  tff(decl_41316, type, 'expression of gene': $i).
% 29.22/29.04  tff(decl_41317, type, 'gene expression': $i).
% 29.22/29.04  tff(decl_41318, type, 'gene-expression': $i).
% 29.22/29.04  tff(decl_41319, type, fn_gene_expression_1: $i > $i).
% 29.22/29.04  tff(decl_41320, type, fn_gene_expression_5: $i > $i).
% 29.22/29.04  tff(decl_41321, type, 'Gene-Flow': $i).
% 29.22/29.04  tff(decl_41322, type, 'The movement of alleles between populations, resulting from the migration of fertile individuals or dispersal of gametes.': $i).
% 29.22/29.04  tff(decl_41323, type, 'gene migration': $i).
% 29.22/29.04  tff(decl_41324, type, 'gene-migration': $i).
% 29.22/29.04  tff(decl_41325, type, 'flow of gene': $i).
% 29.22/29.04  tff(decl_41326, type, 'gene flow': $i).
% 29.22/29.04  tff(decl_41327, type, 'gene-flow': $i).
% 29.22/29.04  tff(decl_41328, type, 'Gene-For-Gene-Recognition': $i).
% 29.22/29.04  tff(decl_41329, type, 'Specific resistance to a plant disease due to a precise match-up between an allele in the plant and an allele in the pathogen.': $i).
% 29.22/29.04  tff(decl_41330, type, 'gene for gene recognition': $i).
% 29.22/29.04  tff(decl_41331, type, 'gene-for-gene-recognition': $i).
% 29.22/29.04  tff(decl_41332, type, fn_gene_inactivation_2: $i > $i).
% 29.22/29.04  tff(decl_41333, type, fn_gene_inactivation_3: $i > $i).
% 29.22/29.04  tff(decl_41334, type, 'Gene-Inactivation': $i).
% 29.22/29.04  tff(decl_41335, type, 'Process of making a gene inaccessible for transcription.': $i).
% 29.22/29.04  tff(decl_41336, type, 'gene silencing': $i).
% 29.22/29.04  tff(decl_41337, type, 'gene-silencing': $i).
% 29.22/29.04  tff(decl_41338, type, 'inactivation of gene': $i).
% 29.22/29.04  tff(decl_41339, type, 'gene inactivation': $i).
% 29.22/29.04  tff(decl_41340, type, 'gene-inactivation': $i).
% 29.22/29.04  tff(decl_41341, type, 'Gene-Interactions': $i).
% 29.22/29.04  tff(decl_41342, type, 'The process in which two or more genes interact with and affect one another.': $i).
% 29.22/29.04  tff(decl_41343, type, 'gene interaction': $i).
% 29.22/29.04  tff(decl_41344, type, 'gene-interaction': $i).
% 29.22/29.04  tff(decl_41345, type, 'Gene-Loss': $i).
% 29.22/29.04  tff(decl_41346, type, 'A process in certain insects whereby genes are selectively lost in certain tissues.': $i).
% 29.22/29.04  tff(decl_41347, type, 'loss of gene': $i).
% 29.22/29.04  tff(decl_41348, type, 'gene loss': $i).
% 29.22/29.04  tff(decl_41349, type, 'gene-loss': $i).
% 29.22/29.04  tff(decl_41350, type, fn_gene_loss_1: $i > $i).
% 29.22/29.04  tff(decl_41351, type, fn_gene_loss_2: $i > $i).
% 29.22/29.04  tff(decl_41352, type, gene_pool_1: $i > $o).
% 29.22/29.04  tff(decl_41353, type, 'Gene-Pool': $i).
% 29.22/29.04  tff(decl_41354, type, 'The sum total of all alleles for all loci in a population. May also refer to the sum total of alleles for a single locus in a population.': $i).
% 29.22/29.04  tff(decl_41355, type, 'pool of gene': $i).
% 29.22/29.04  tff(decl_41356, type, 'gene pool': $i).
% 29.22/29.04  tff(decl_41357, type, 'gene-pool': $i).
% 29.22/29.04  tff(decl_41358, type, 'Gene-Rearrangement': $i).
% 29.22/29.04  tff(decl_41359, type, 'A somatic cell process whereby a gene\\s location in the DNA sequence is altered.': $i).
% 29.22/29.04  tff(decl_41360, type, 'rearrangement of gene': $i).
% 29.22/29.04  tff(decl_41361, type, 'gene rearrangement': $i).
% 29.22/29.04  tff(decl_41362, type, 'gene-rearrangement': $i).
% 29.22/29.04  tff(decl_41363, type, fn_gene_rearrangement_1: $i > $i).
% 29.22/29.04  tff(decl_41364, type, fn_gene_rearrangement_2: $i > $i).
% 29.22/29.04  tff(decl_41365, type, fn_gene_rearrangement_3: $i > $i).
% 29.22/29.04  tff(decl_41366, type, fn_gene_rearrangement_4: $i > $i).
% 29.22/29.04  tff(decl_41367, type, fn_gene_rearrangement_5: $i > $i).
% 29.22/29.04  tff(decl_41368, type, fn_gene_rearrangement_6: $i > $i).
% 29.22/29.04  tff(decl_41369, type, fn_gene_rearrangement_7: $i > $i).
% 29.22/29.04  tff(decl_41370, type, 'Gene-Regulation': $i).
% 29.22/29.04  tff(decl_41371, type, 'The processes used by cells to promote or inhibit the expression of genes.': $i).
% 29.22/29.04  tff(decl_41372, type, 'genetic control': $i).
% 29.22/29.04  tff(decl_41373, type, 'genetic-control': $i).
% 29.22/29.04  tff(decl_41374, type, 'regulation of gene expression': $i).
% 29.22/29.04  tff(decl_41375, type, 'regulation-of-gene-expression': $i).
% 29.22/29.04  tff(decl_41376, type, 'regulation of gene': $i).
% 29.22/29.04  tff(decl_41377, type, 'gene regulation': $i).
% 29.22/29.04  tff(decl_41378, type, 'gene-regulation': $i).
% 29.22/29.04  tff(decl_41379, type, fn_transcription_factor_1: $i > $i).
% 29.22/29.04  tff(decl_41380, type, gene_regulation_at_post_translational_level_1: $i > $o).
% 29.22/29.04  tff(decl_41381, type, 'Gene-Regulation-At-Post-Translational-Level': $i).
% 29.22/29.04  tff(decl_41382, type, 'Gene Regulation that inhibits gene expression by inhibiting post-translational modification.  This kind of gene regulation can be accomplished by cleaving the protein, attaching a sugar to the protein, phosphorylating the protein, or inhibiting a transport protein.': $i).
% 29.22/29.04  tff(decl_41383, type, 'gene regulation at post translational level': $i).
% 29.22/29.04  tff(decl_41384, type, 'gene-regulation-at-post-translational-level': $i).
% 29.22/29.04  tff(decl_41385, type, gene_regulation_at_translational_level_1: $i > $o).
% 29.22/29.04  tff(decl_41386, type, fn_gene_regulation_at_post_translational_level_1: $i > $i).
% 29.22/29.04  tff(decl_41387, type, inhibition_of_transport_protein_1: $i > $o).
% 29.22/29.04  tff(decl_41388, type, fn_gene_regulation_at_post_translational_level_2: $i > $i).
% 29.22/29.04  tff(decl_41389, type, fn_gene_regulation_at_post_translational_level_3: $i > $i).
% 29.22/29.04  tff(decl_41390, type, fn_gene_regulation_at_post_translational_level_4: $i > $i).
% 29.22/29.04  tff(decl_41391, type, fn_gene_regulation_at_post_translational_level_5: $i > $i).
% 29.22/29.04  tff(decl_41392, type, fn_gene_regulation_at_post_translational_level_6: $i > $i).
% 29.22/29.04  tff(decl_41393, type, fn_gene_regulation_at_post_translational_level_7: $i > $i).
% 29.22/29.04  tff(decl_41394, type, fn_gene_regulation_at_post_translational_level_8: $i > $i).
% 29.22/29.04  tff(decl_41395, type, fn_gene_regulation_at_post_translational_level_9: $i > $i).
% 29.22/29.04  tff(decl_41396, type, fn_gene_regulation_at_post_translational_level_10: $i > $i).
% 29.22/29.04  tff(decl_41397, type, fn_phosphorylation_of_protein_3: $i > $i).
% 29.22/29.04  tff(decl_41398, type, fn_gene_regulation_at_translational_level_1: $i > $i).
% 29.22/29.04  tff(decl_41399, type, 'Gene-Regulation-At-Translational-Level': $i).
% 29.22/29.04  tff(decl_41400, type, 'Inhibition of gene expression at the level of translation.  Attachment of a regulatory protein to the 5-prime end of mRNA blocks the ribosome, preventing translation initiation.': $i).
% 29.22/29.04  tff(decl_41401, type, 'gene regulation at translational level': $i).
% 29.22/29.04  tff(decl_41402, type, 'gene-regulation-at-translational-level': $i).
% 29.22/29.04  tff(decl_41403, type, fn_gene_regulation_at_translational_level_2: $i > $i).
% 29.22/29.04  tff(decl_41404, type, fn_gene_regulation_at_translational_level_3: $i > $i).
% 29.22/29.04  tff(decl_41405, type, fn_gene_regulation_at_translational_level_4: $i > $i).
% 29.22/29.04  tff(decl_41406, type, fn_gene_regulation_at_translational_level_6: $i > $i).
% 29.22/29.04  tff(decl_41407, type, fn_gene_regulation_at_translational_level_7: $i > $i).
% 29.22/29.04  tff(decl_41408, type, fn_gene_regulation_at_translational_level_8: $i > $i).
% 29.22/29.04  tff(decl_41409, type, fn_gene_regulation_at_translational_level_9: $i > $i).
% 29.22/29.04  tff(decl_41410, type, fn_gene_regulation_at_translational_level_10: $i > $i).
% 29.22/29.04  tff(decl_41411, type, fn_translation_initiation_10: $i > $i).
% 29.22/29.04  tff(decl_41412, type, fn_translation_initiation_8: $i > $i).
% 29.22/29.04  tff(decl_41413, type, 'Gene-Related-Aggregates': $i).
% 29.22/29.04  tff(decl_41414, type, 'An entity which is formed by the combination of many separate genetic-related units.': $i).
% 29.22/29.04  tff(decl_41415, type, 'gene related aggregate': $i).
% 29.22/29.04  tff(decl_41416, type, 'gene-related-aggregate': $i).
% 29.22/29.04  tff(decl_41417, type, 'Gene-Therapy': $i).
% 29.22/29.04  tff(decl_41418, type, 'The introduction of genes into an afflicted individual\\s somatic cells for therapeutic purposes.': $i).
% 29.22/29.04  tff(decl_41419, type, 'perform gene therapy': $i).
% 29.22/29.04  tff(decl_41420, type, 'therapy of gene': $i).
% 29.22/29.04  tff(decl_41421, type, 'gene therapy': $i).
% 29.22/29.04  tff(decl_41422, type, 'gene-therapy': $i).
% 29.22/29.04  tff(decl_41423, type, fn_gene_therapy_1: $i > $i).
% 29.22/29.04  tff(decl_41424, type, fn_gene_therapy_2: $i > $i).
% 29.22/29.04  tff(decl_41425, type, normal_1: $i > $o).
% 29.22/29.04  tff(decl_41426, type, fn_gene_therapy_3: $i > $i).
% 29.22/29.04  tff(decl_41427, type, fn_gene_therapy_4: $i > $i).
% 29.22/29.04  tff(decl_41428, type, fn_gene_therapy_5: $i > $i).
% 29.22/29.04  tff(decl_41429, type, fn_gene_therapy_6: $i > $i).
% 29.22/29.04  tff(decl_41430, type, fn_gene_therapy_7: $i > $i).
% 29.22/29.04  tff(decl_41431, type, fn_gene_therapy_8: $i > $i).
% 29.22/29.04  tff(decl_41432, type, fn_gene_therapy_9: $i > $i).
% 29.22/29.04  tff(decl_41433, type, fn_gene_therapy_10: $i > $i).
% 29.22/29.04  tff(decl_41434, type, fn_gene_therapy_11: $i > $i).
% 29.22/29.04  tff(decl_41435, type, fn_gene_therapy_12: $i > $i).
% 29.22/29.04  tff(decl_41436, type, fn_gene_therapy_13: $i > $i).
% 29.22/29.04  tff(decl_41437, type, 'Gene-with-Multiple-Alleles': $i).
% 29.22/29.04  tff(decl_41438, type, 'Alleles are forms of a gene, for example, a hair color gene with forms black, brown, and blond.  A gene with multiple alleles has more than one form, and each form encodes a different version of a trait.': $i).
% 29.22/29.04  tff(decl_41439, type, 'gene with multiple allele': $i).
% 29.22/29.04  tff(decl_41440, type, 'gene-with-multiple-allele': $i).
% 29.22/29.04  tff(decl_41441, type, genealogical_species_concept_1: $i > $o).
% 29.22/29.04  tff(decl_41442, type, 'Genealogical-Species-Concept': $i).
% 29.22/29.04  tff(decl_41443, type, 'Species identified as such based on the consensus of estimated genealogies of many different genes.': $i).
% 29.22/29.04  tff(decl_41444, type, 'genealogical species concept': $i).
% 29.22/29.04  tff(decl_41445, type, 'genealogical-species-concept': $i).
% 29.22/29.04  tff(decl_41446, type, 'General-Chemical-Process': $i).
% 29.22/29.04  tff(decl_41447, type, 'A process related to chemical interactions that may happen independent of biolological processes.': $i).
% 29.22/29.04  tff(decl_41448, type, 'general chemical process': $i).
% 29.22/29.04  tff(decl_41449, type, 'general-chemical-process': $i).
% 29.22/29.04  tff(decl_41450, type, generalized_transduction_1: $i > $o).
% 29.22/29.04  tff(decl_41451, type, 'Generalized-Transduction': $i).
% 29.22/29.04  tff(decl_41452, type, 'A type of viral transduction in which the phage transfers bacterial genes at random.': $i).
% 29.22/29.04  tff(decl_41453, type, 'generalized transduction': $i).
% 29.22/29.04  tff(decl_41454, type, 'generalized-transduction': $i).
% 29.22/29.04  tff(decl_41455, type, specialized_transduction_1: $i > $o).
% 29.22/29.04  tff(decl_41456, type, fn_generalized_transduction_1: $i > $i).
% 29.22/29.04  tff(decl_41457, type, fn_generalized_transduction_2: $i > $i).
% 29.22/29.04  tff(decl_41458, type, fn_generalized_transduction_3: $i > $i).
% 29.22/29.04  tff(decl_41459, type, fn_generalized_transduction_4: $i > $i).
% 29.22/29.04  tff(decl_41460, type, fn_generalized_transduction_5: $i > $i).
% 29.22/29.04  tff(decl_41461, type, fn_generalized_transduction_6: $i > $i).
% 29.22/29.04  tff(decl_41462, type, fn_generalized_transduction_7: $i > $i).
% 29.22/29.04  tff(decl_41463, type, fn_generalized_transduction_8: $i > $i).
% 29.22/29.04  tff(decl_41464, type, fn_generalized_transduction_9: $i > $i).
% 29.22/29.04  tff(decl_41465, type, fn_generalized_transduction_10: $i > $i).
% 29.22/29.04  tff(decl_41466, type, fn_generalized_transduction_11: $i > $i).
% 29.22/29.04  tff(decl_41467, type, fn_generalized_transduction_12: $i > $i).
% 29.22/29.04  tff(decl_41468, type, fn_virus_21: $i > $i).
% 29.22/29.04  tff(decl_41469, type, fn_transduction_gene_transfer_3: $i > $i).
% 29.22/29.04  tff(decl_41470, type, fn_transduction_gene_transfer_5: $i > $i).
% 29.22/29.04  tff(decl_41471, type, fn_transduction_gene_transfer_8: $i > $i).
% 29.22/29.04  tff(decl_41472, type, fn_transduction_gene_transfer_9: $i > $i).
% 29.22/29.04  tff(decl_41473, type, fn_transduction_gene_transfer_1: $i > $i).
% 29.22/29.04  tff(decl_41474, type, fn_transduction_gene_transfer_7: $i > $i).
% 29.22/29.04  tff(decl_41475, type, 'Generation': $i).
% 29.22/29.04  tff(decl_41476, type, 'The set of individuals born at the same time.': $i).
% 29.22/29.04  tff(decl_41477, type, generation: $i).
% 29.22/29.04  tff(decl_41478, type, fn_generation_3: $i > $i).
% 29.22/29.04  tff(decl_41479, type, fn_generation_4: $i > $i).
% 29.22/29.04  tff(decl_41480, type, fn_generation_7: $i > $i).
% 29.22/29.04  tff(decl_41481, type, fn_generation_8: $i > $i).
% 29.22/29.04  tff(decl_41482, type, generation_of_heat_energy_1: $i > $o).
% 29.22/29.04  tff(decl_41483, type, 'Generation-Of-Heat-Energy': $i).
% 29.22/29.04  tff(decl_41484, type, 'The process of genration of heat energy is generation of heat energy.': $i).
% 29.22/29.04  tff(decl_41485, type, generate: $i).
% 29.22/29.04  tff(decl_41486, type, 'generation of heat energy': $i).
% 29.22/29.04  tff(decl_41487, type, 'generation-of-heat-energy': $i).
% 29.22/29.04  tff(decl_41488, type, generation_of_kinetic_energy_1: $i > $o).
% 29.22/29.04  tff(decl_41489, type, fn_generation_of_heat_energy_1: $i > $i).
% 29.22/29.04  tff(decl_41490, type, fn_generation_of_heat_energy_2: $i > $i).
% 29.22/29.04  tff(decl_41491, type, fn_generation_of_heat_energy_3: $i > $i).
% 29.22/29.04  tff(decl_41492, type, fn_generation_of_kinetic_energy_3: $i > $i).
% 29.22/29.04  tff(decl_41493, type, 'Generation-Of-Hydrogen-Ion-Gradient-Across-Biomembrane': $i).
% 29.22/29.04  tff(decl_41494, type, 'Proton pump proteins within membranes generate a hydrogen ion gradient across the membrane, which can be used to produce energy for cellular work.': $i).
% 29.22/29.04  tff(decl_41495, type, 'generation of hydrogen ion gradient across biomembrane': $i).
% 29.22/29.04  tff(decl_41496, type, 'generation-of-hydrogen-ion-gradient-across-biomembrane': $i).
% 29.22/29.04  tff(decl_41497, type, 'Generation-of-Kinetic-Energy': $i).
% 29.22/29.04  tff(decl_41498, type, 'The process of genration of kinetic energy is generation of kinetic energy.': $i).
% 29.22/29.04  tff(decl_41499, type, 'generation of kinetic energy': $i).
% 29.22/29.04  tff(decl_41500, type, 'generation-of-kinetic-energy': $i).
% 29.22/29.04  tff(decl_41501, type, fn_generation_of_kinetic_energy_1: $i > $i).
% 29.22/29.04  tff(decl_41502, type, 'Genetic-Code': $i).
% 29.22/29.04  tff(decl_41503, type, 'The set of rules that govern the way that information in genetic material is translated into amino acid sequences.': $i).
% 29.22/29.04  tff(decl_41504, type, 'genetic information': $i).
% 29.22/29.04  tff(decl_41505, type, 'genetic-information': $i).
% 29.22/29.04  tff(decl_41506, type, 'genetic code': $i).
% 29.22/29.04  tff(decl_41507, type, 'genetic-code': $i).
% 29.22/29.04  tff(decl_41508, type, fn_genetic_code_3: $i > $i).
% 29.22/29.04  tff(decl_41509, type, fn_genetic_code_4: $i > $i).
% 29.22/29.04  tff(decl_41510, type, fn_genetic_code_5: $i > $i).
% 29.22/29.04  tff(decl_41511, type, fn_genetic_code_6: $i > $i).
% 29.22/29.04  tff(decl_41512, type, fn_genetic_code_7: $i > $i).
% 29.22/29.04  tff(decl_41513, type, fn_genetic_code_8: $i > $i).
% 29.22/29.04  tff(decl_41514, type, fn_genetic_code_9: $i > $i).
% 29.22/29.04  tff(decl_41515, type, fn_genetic_code_10: $i > $i).
% 29.22/29.04  tff(decl_41516, type, fn_genetic_code_11: $i > $i).
% 29.22/29.04  tff(decl_41517, type, fn_genetic_code_12: $i > $i).
% 29.22/29.04  tff(decl_41518, type, fn_genetic_code_13: $i > $i).
% 29.22/29.04  tff(decl_41519, type, fn_genetic_code_14: $i > $i).
% 29.22/29.04  tff(decl_41520, type, fn_genetic_code_15: $i > $i).
% 29.22/29.04  tff(decl_41521, type, 'Genetic-Disorder': $i).
% 29.22/29.04  tff(decl_41522, type, 'An illness caused by abnormalities in genes, usually hereditary.': $i).
% 29.22/29.04  tff(decl_41523, type, 'genetic disease': $i).
% 29.22/29.04  tff(decl_41524, type, 'genetic disorder': $i).
% 29.22/29.04  tff(decl_41525, type, 'genetic-disorder': $i).
% 29.22/29.04  tff(decl_41526, type, 'Genetic-Drift': $i).
% 29.22/29.04  tff(decl_41527, type, 'Changes in alelle frequencies between generations due to random sampling biases. Small populations are especially vulnerable to the effects of genetic drift.': $i).
% 29.22/29.04  tff(decl_41528, type, 'genetic drift': $i).
% 29.22/29.04  tff(decl_41529, type, 'genetic-drift': $i).
% 29.22/29.04  tff(decl_41530, type, fn_genetic_engineering_3: $i > $i).
% 29.22/29.04  tff(decl_41531, type, fn_genetic_engineering_4: $i > $i).
% 29.22/29.04  tff(decl_41532, type, fn_genetic_engineering_2: $i > $i).
% 29.22/29.04  tff(decl_41533, type, 'Genetic-Engineering': $i).
% 29.22/29.04  tff(decl_41534, type, 'The direct manipulation of genes for practical purposes.': $i).
% 29.22/29.04  tff(decl_41535, type, 'genetically engineer': $i).
% 29.22/29.04  tff(decl_41536, type, 'genetic engineering': $i).
% 29.22/29.04  tff(decl_41537, type, 'genetic-engineering': $i).
% 29.22/29.04  tff(decl_41538, type, 'Genetic-Linkage-Mapping': $i).
% 29.22/29.04  tff(decl_41539, type, 'The technique of mapping several thousand genetic markers spaced at equal distances throughout the chromosomes.': $i).
% 29.22/29.04  tff(decl_41540, type, 'genetic linkage mapping': $i).
% 29.22/29.04  tff(decl_41541, type, 'genetic-linkage-mapping': $i).
% 29.22/29.04  tff(decl_41542, type, 'Genetic-Map': $i).
% 29.22/29.04  tff(decl_41543, type, 'An ordered list of genetic loci (genes or other genetic markers) along a chromosome.': $i).
% 29.22/29.04  tff(decl_41544, type, 'genetic map': $i).
% 29.22/29.04  tff(decl_41545, type, 'genetic-map': $i).
% 29.22/29.04  tff(decl_41546, type, genetic_representation_1: $i > $o).
% 29.22/29.04  tff(decl_41547, type, fn_genetic_map_1: $i > $i).
% 29.22/29.04  tff(decl_41548, type, fn_genetic_map_2: $i > $i).
% 29.22/29.04  tff(decl_41549, type, sturtevant_1: $i > $o).
% 29.22/29.04  tff(decl_41550, type, fn_genetic_map_3: $i > $i).
% 29.22/29.04  tff(decl_41551, type, fn_genetic_map_4: $i > $i).
% 29.22/29.04  tff(decl_41552, type, fn_genetic_map_5: $i > $i).
% 29.22/29.04  tff(decl_41553, type, fn_genetic_map_6: $i > $i).
% 29.22/29.04  tff(decl_41554, type, fn_genetic_map_7: $i > $i).
% 29.22/29.04  tff(decl_41555, type, fn_genetic_map_8: $i > $i).
% 29.22/29.04  tff(decl_41556, type, fn_locus_1: $i > $i).
% 29.22/29.04  tff(decl_41557, type, 'Genetic-Marker': $i).
% 29.22/29.04  tff(decl_41558, type, 'A genetic marker is a gene or DNA sequence with a known location on a chromosome that can be used to identify cells, individual or species.': $i).
% 29.22/29.04  tff(decl_41559, type, 'genetic marker': $i).
% 29.22/29.04  tff(decl_41560, type, 'genetic-marker': $i).
% 29.22/29.04  tff(decl_41561, type, fn_genetic_marker_1: $i > $i).
% 29.22/29.04  tff(decl_41562, type, 'Genetic-Process': $i).
% 29.22/29.04  tff(decl_41563, type, 'A process involved in the transmission of genetic information from one organism to another.': $i).
% 29.22/29.04  tff(decl_41564, type, 'genetic process': $i).
% 29.22/29.04  tff(decl_41565, type, 'genetic-process': $i).
% 29.22/29.04  tff(decl_41566, type, genetic_profile_1: $i > $o).
% 29.22/29.04  tff(decl_41567, type, 'Genetic-Profile': $i).
% 29.22/29.04  tff(decl_41568, type, 'An individual\\s one-of-a-kind set of genetic markers. Genetic profiles can be used to determine familial relationships.': $i).
% 29.22/29.04  tff(decl_41569, type, 'genetic profile': $i).
% 29.22/29.04  tff(decl_41570, type, 'genetic-profile': $i).
% 29.22/29.04  tff(decl_41571, type, genetic_recombination_1: $i > $o).
% 29.22/29.04  tff(decl_41572, type, 'Genetic-recombination': $i).
% 29.22/29.04  tff(decl_41573, type, 'Genetic recombination is the exchange of DNA fragments between sister chromatids of a chromosome or non sister chromatids of homologous chromosomes. It is a common occurenence in meiosis and result in daughter cells with a different combination of genes than the parent cell': $i).
% 29.22/29.04  tff(decl_41574, type, recombine: $i).
% 29.22/29.04  tff(decl_41575, type, 'genetic recombination': $i).
% 29.22/29.04  tff(decl_41576, type, 'genetic-recombination': $i).
% 29.22/29.04  tff(decl_41577, type, fn_genetic_recombination_1: $i > $i).
% 29.22/29.04  tff(decl_41578, type, fn_genetic_recombination_2: $i > $i).
% 29.22/29.04  tff(decl_41579, type, fn_genetic_recombination_3: $i > $i).
% 29.22/29.04  tff(decl_41580, type, fn_genetic_recombination_4: $i > $i).
% 29.22/29.04  tff(decl_41581, type, genetic_recombination_in_lab_fragments_with_sticky_ends_1: $i > $o).
% 29.22/29.04  tff(decl_41582, type, fn_genetic_recombination_in_lab_fragments_with_sticky_ends_3: $i > $i).
% 29.22/29.04  tff(decl_41583, type, fn_genetic_recombination_in_lab_fragments_with_sticky_ends_2: $i > $i).
% 29.22/29.04  tff(decl_41584, type, 'Genetic-Recombination-In-Lab-Fragments-With-Sticky-Ends': $i).
% 29.22/29.04  tff(decl_41585, type, 'A process in which (1) restriction nuclease and two kinds of DNA are mixed, (2) the restriction nuclease applies a staggered cut to the two types of DNA to make sticky-end fragments, and (3) the restriction fragments attach with the help of ligase to make recombinant DNA.': $i).
% 29.22/29.04  tff(decl_41586, type, 'genetic recombination in lab fragments with sticky end': $i).
% 29.22/29.04  tff(decl_41587, type, 'genetic-recombination-in-lab-fragments-with-sticky-end': $i).
% 29.22/29.04  tff(decl_41588, type, genetic_recombination_in_lab_of_fragments_with_blunt_ends_1: $i > $o).
% 29.22/29.04  tff(decl_41589, type, fn_genetic_recombination_in_lab_fragments_with_sticky_ends_4: $i > $i).
% 29.22/29.04  tff(decl_41590, type, fn_genetic_recombination_in_lab_fragments_with_sticky_ends_5: $i > $i).
% 29.22/29.04  tff(decl_41591, type, fn_genetic_recombination_in_lab_of_fragments_3: $i > $i).
% 29.22/29.04  tff(decl_41592, type, fn_genetic_recombination_in_lab_of_fragments_14: $i > $i).
% 29.22/29.04  tff(decl_41593, type, fn_genetic_recombination_in_lab_of_fragments_15: $i > $i).
% 29.22/29.04  tff(decl_41594, type, 'Genetic-Recombination-In-Lab-Of-Fragments': $i).
% 29.22/29.04  tff(decl_41595, type, 'A process in which (1) restriction nuclease and two kinds of DNA are mixed, (2) the restriction nuclease lyses both types of DNA at restriction sites to make restriction fragments, and (3) the restriction fragments attach with the help of ligase to make recombinant DNA.': $i).
% 29.22/29.04  tff(decl_41596, type, 'genetic recombination in lab of fragment': $i).
% 29.22/29.04  tff(decl_41597, type, 'genetic-recombination-in-lab-of-fragment': $i).
% 29.22/29.04  tff(decl_41598, type, fn_genetic_recombination_in_lab_of_fragments_4: $i > $i).
% 29.22/29.04  tff(decl_41599, type, fn_genetic_recombination_in_lab_of_fragments_5: $i > $i).
% 29.22/29.04  tff(decl_41600, type, fn_genetic_recombination_in_lab_of_fragments_6: $i > $i).
% 29.22/29.04  tff(decl_41601, type, fn_genetic_recombination_in_lab_of_fragments_7: $i > $i).
% 29.22/29.04  tff(decl_41602, type, fn_genetic_recombination_in_lab_of_fragments_8: $i > $i).
% 29.22/29.04  tff(decl_41603, type, fn_genetic_recombination_in_lab_of_fragments_9: $i > $i).
% 29.22/29.04  tff(decl_41604, type, fn_genetic_recombination_in_lab_of_fragments_10: $i > $i).
% 29.22/29.04  tff(decl_41605, type, fn_restriction_fragment_6: $i > $i).
% 29.22/29.04  tff(decl_41606, type, restriction_fragment_0: $i).
% 29.22/29.04  tff(decl_41607, type, fn_genetic_recombination_in_lab_of_fragments_with_blunt_ends_3: $i > $i).
% 29.22/29.04  tff(decl_41608, type, fn_genetic_recombination_in_lab_of_fragments_with_blunt_ends_2: $i > $i).
% 29.22/29.04  tff(decl_41609, type, 'Genetic-Recombination-In-Lab-Of-Fragments-With-Blunt-Ends': $i).
% 29.22/29.04  tff(decl_41610, type, 'A process in which (1) restriction nuclease and two kinds of DNA are mixed, (2) the restriction nuclease applies a blunt cut to the two types of DNA to make blunt-end fragments, and (3) the restriction fragments attach with the help of ligase to make recombinant DNA.': $i).
% 29.22/29.04  tff(decl_41611, type, 'genetic recombination in lab of fragments with blunt end': $i).
% 29.22/29.04  tff(decl_41612, type, 'genetic-recombination-in-lab-of-fragments-with-blunt-end': $i).
% 29.22/29.04  tff(decl_41613, type, fn_genetic_recombination_in_lab_of_fragments_with_blunt_ends_4: $i > $i).
% 29.22/29.04  tff(decl_41614, type, 'Genetic-Representation': $i).
% 29.22/29.04  tff(decl_41615, type, 'A method of representing genetic data.': $i).
% 29.22/29.04  tff(decl_41616, type, 'genetic representation': $i).
% 29.22/29.04  tff(decl_41617, type, 'genetic-representation': $i).
% 29.22/29.04  tff(decl_41618, type, 'Genetic-Testing': $i).
% 29.22/29.04  tff(decl_41619, type, 'The process of determining an individual\\s genetic information, including genetic abnormalities and disorders.': $i).
% 29.22/29.04  tff(decl_41620, type, 'genetic screening': $i).
% 29.22/29.04  tff(decl_41621, type, 'genetic-screening': $i).
% 29.22/29.04  tff(decl_41622, type, 'dna based testing': $i).
% 29.22/29.04  tff(decl_41623, type, 'dna-based-testing': $i).
% 29.22/29.04  tff(decl_41624, type, 'genetic testing': $i).
% 29.22/29.04  tff(decl_41625, type, 'genetic-testing': $i).
% 29.22/29.04  tff(decl_41626, type, 'Genetic-Variation': $i).
% 29.22/29.04  tff(decl_41627, type, 'Genetic variation, variation in alleles of genes, occurs both within and among populations. Three mechanisms that contribute to the genetic variation arising from sexual reproduction are independent assortment of chromosomes, crossing over and random fertilization.': $i).
% 29.22/29.04  tff(decl_41628, type, 'genetic diversity': $i).
% 29.22/29.04  tff(decl_41629, type, 'genetic-diversity': $i).
% 29.22/29.04  tff(decl_41630, type, 'variation in offspring': $i).
% 29.22/29.04  tff(decl_41631, type, 'genetic variation': $i).
% 29.22/29.04  tff(decl_41632, type, 'genetic-variation': $i).
% 29.22/29.04  tff(decl_41633, type, genetically_modified_organism_1: $i > $o).
% 29.22/29.04  tff(decl_41634, type, 'Genetically-Modified-Organism': $i).
% 29.22/29.04  tff(decl_41635, type, 'An organism whose genetic material has been manipulated using the techniques of genetic engineering.': $i).
% 29.22/29.04  tff(decl_41636, type, 'genetically modified organism': $i).
% 29.22/29.04  tff(decl_41637, type, 'genetically-modified-organism': $i).
% 29.22/29.04  tff(decl_41638, type, geneticist_1: $i > $o).
% 29.22/29.04  tff(decl_41639, type, 'Geneticist': $i).
% 29.22/29.04  tff(decl_41640, type, 'A biologist who specializes in genetics.': $i).
% 29.22/29.04  tff(decl_41641, type, geneticist: $i).
% 29.22/29.04  tff(decl_41642, type, steward_1: $i > $o).
% 29.22/29.04  tff(decl_41643, type, 'Genetics': $i).
% 29.22/29.04  tff(decl_41644, type, 'The science of genes, heredity, and genetic variation.': $i).
% 29.22/29.04  tff(decl_41645, type, genetics: $i).
% 29.22/29.04  tff(decl_41646, type, 'Genome': $i).
% 29.22/29.04  tff(decl_41647, type, 'The genetic material of an organism or virus; the complete complement of an organism\\s or virus\\s genes along with its noncoding nucleic acid sequences.': $i).
% 29.22/29.04  tff(decl_41648, type, genome: $i).
% 29.22/29.04  tff(decl_41649, type, genome_mapping_1: $i > $o).
% 29.22/29.04  tff(decl_41650, type, 'Genome-Mapping': $i).
% 29.22/29.04  tff(decl_41651, type, 'The determination of the sequence of specific genes and their relative distances from each other on a given chromosome.': $i).
% 29.22/29.04  tff(decl_41652, type, 'mapping genome': $i).
% 29.22/29.04  tff(decl_41653, type, 'genome sequencing': $i).
% 29.22/29.04  tff(decl_41654, type, 'chromosome walking': $i).
% 29.22/29.04  tff(decl_41655, type, 'mapping of genome': $i).
% 29.22/29.04  tff(decl_41656, type, 'genome-mapping': $i).
% 29.22/29.04  tff(decl_41657, type, fn_genome_mapping_1: $i > $i).
% 29.22/29.04  tff(decl_41658, type, fn_genome_mapping_2: $i > $i).
% 29.22/29.04  tff(decl_41659, type, fn_genome_mapping_3: $i > $i).
% 29.22/29.04  tff(decl_41660, type, fn_genome_mapping_4: $i > $i).
% 29.22/29.04  tff(decl_41661, type, fn_genome_mapping_5: $i > $i).
% 29.22/29.04  tff(decl_41662, type, fn_genome_mapping_6: $i > $i).
% 29.22/29.04  tff(decl_41663, type, fn_genome_mapping_7: $i > $i).
% 29.22/29.04  tff(decl_41664, type, fn_genome_mapping_8: $i > $i).
% 29.22/29.04  tff(decl_41665, type, fn_genome_mapping_9: $i > $i).
% 29.22/29.04  tff(decl_41666, type, fn_genome_mapping_10: $i > $i).
% 29.22/29.04  tff(decl_41667, type, fn_genome_mapping_11: $i > $i).
% 29.22/29.04  tff(decl_41668, type, fn_genome_mapping_12: $i > $i).
% 29.22/29.04  tff(decl_41669, type, fn_genome_mapping_13: $i > $i).
% 29.22/29.04  tff(decl_41670, type, fn_genome_mapping_14: $i > $i).
% 29.22/29.04  tff(decl_41671, type, fn_genome_mapping_15: $i > $i).
% 29.22/29.04  tff(decl_41672, type, fn_genome_mapping_16: $i > $i).
% 29.22/29.04  tff(decl_41673, type, fn_genome_mapping_17: $i > $i).
% 29.22/29.04  tff(decl_41674, type, fn_genome_mapping_18: $i > $i).
% 29.22/29.04  tff(decl_41675, type, fn_genome_mapping_19: $i > $i).
% 29.22/29.04  tff(decl_41676, type, fn_genome_mapping_20: $i > $i).
% 29.22/29.04  tff(decl_41677, type, fn_genome_mapping_21: $i > $i).
% 29.22/29.04  tff(decl_41678, type, fn_genome_mapping_22: $i > $i).
% 29.22/29.04  tff(decl_41679, type, fn_genome_mapping_23: $i > $i).
% 29.22/29.04  tff(decl_41680, type, fn_genome_mapping_24: $i > $i).
% 29.22/29.04  tff(decl_41681, type, fn_genome_mapping_25: $i > $i).
% 29.22/29.04  tff(decl_41682, type, fn_genome_mapping_26: $i > $i).
% 29.22/29.04  tff(decl_41683, type, fn_genome_mapping_27: $i > $i).
% 29.22/29.04  tff(decl_41684, type, fn_genome_mapping_28: $i > $i).
% 29.22/29.04  tff(decl_41685, type, fn_genome_mapping_29: $i > $i).
% 29.22/29.04  tff(decl_41686, type, nucleic_acid_probe_1: $i > $o).
% 29.22/29.04  tff(decl_41687, type, fn_genome_mapping_30: $i > $i).
% 29.22/29.04  tff(decl_41688, type, fn_genome_mapping_31: $i > $i).
% 29.22/29.04  tff(decl_41689, type, fn_genome_mapping_32: $i > $i).
% 29.22/29.04  tff(decl_41690, type, fn_genome_mapping_33: $i > $i).
% 29.22/29.04  tff(decl_41691, type, fn_genome_mapping_34: $i > $i).
% 29.22/29.04  tff(decl_41692, type, fn_genome_mapping_35: $i > $i).
% 29.22/29.04  tff(decl_41693, type, fn_nucleic_acid_probe_3: $i > $i).
% 29.22/29.04  tff(decl_41694, type, fn_nucleic_acid_probe_4: $i > $i).
% 29.22/29.04  tff(decl_41695, type, cloned_dna_0: $i).
% 29.22/29.04  tff(decl_41696, type, genome_of_host_cell_1: $i > $o).
% 29.22/29.04  tff(decl_41697, type, 'Genome-Of-Host-Cell': $i).
% 29.22/29.04  tff(decl_41698, type, 'The complete complement of a host organism\\s genes along with its noncoding nucleic acid sequences.': $i).
% 29.22/29.04  tff(decl_41699, type, 'host cell gemome': $i).
% 29.22/29.04  tff(decl_41700, type, 'genome of host cell': $i).
% 29.22/29.04  tff(decl_41701, type, 'genome-of-host-cell': $i).
% 29.22/29.04  tff(decl_41702, type, fn_genome_of_host_cell_1: $i > $i).
% 29.22/29.04  tff(decl_41703, type, host_1: $i > $o).
% 29.22/29.04  tff(decl_41704, type, fn_genome_of_host_cell_2: $i > $i).
% 29.22/29.04  tff(decl_41705, type, fn_host_1: $i > $i).
% 29.22/29.04  tff(decl_41706, type, genome_of_virus_1: $i > $o).
% 29.22/29.04  tff(decl_41707, type, 'Genome-Of-Virus': $i).
% 29.22/29.04  tff(decl_41708, type, 'The complete complement of a virus\\s genes along with its noncoding nucleic acid sequences.': $i).
% 29.22/29.04  tff(decl_41709, type, 'viral genome': $i).
% 29.22/29.04  tff(decl_41710, type, 'virus genome': $i).
% 29.22/29.04  tff(decl_41711, type, 'virus-genome': $i).
% 29.22/29.04  tff(decl_41712, type, 'genome of virus': $i).
% 29.22/29.04  tff(decl_41713, type, 'genome-of-virus': $i).
% 29.22/29.04  tff(decl_41714, type, fn_genome_of_virus_1: $i > $i).
% 29.22/29.04  tff(decl_41715, type, 'Genomic-Imprinting': $i).
% 29.22/29.04  tff(decl_41716, type, 'A phenomenon in which expression of an allele in offspring depends on whether the allele is inherited from the male or female parent.': $i).
% 29.22/29.04  tff(decl_41717, type, 'perform genomic imprinting': $i).
% 29.22/29.04  tff(decl_41718, type, 'genomic imprinting': $i).
% 29.22/29.04  tff(decl_41719, type, 'genomic-imprinting': $i).
% 29.22/29.04  tff(decl_41720, type, fn_genomic_imprinting_1: $i > $i).
% 29.22/29.04  tff(decl_41721, type, fn_genomic_imprinting_2: $i > $i).
% 29.22/29.04  tff(decl_41722, type, fn_genomic_imprinting_3: $i > $i).
% 29.22/29.04  tff(decl_41723, type, fn_genomic_imprinting_4: $i > $i).
% 29.22/29.04  tff(decl_41724, type, fn_genomic_imprinting_5: $i > $i).
% 29.22/29.04  tff(decl_41725, type, fn_genomic_imprinting_6: $i > $i).
% 29.22/29.04  tff(decl_41726, type, fn_genomic_imprinting_7: $i > $i).
% 29.22/29.04  tff(decl_41727, type, 'Genomic-Library': $i).
% 29.22/29.04  tff(decl_41728, type, 'A set of cell clones containing all the DNA segments from a genome, each within a plasmid, phage, or other cloning vector.': $i).
% 29.22/29.04  tff(decl_41729, type, 'genomic library': $i).
% 29.22/29.04  tff(decl_41730, type, 'genomic-library': $i).
% 29.22/29.04  tff(decl_41731, type, fn_genomic_library_1: $i > $i).
% 29.22/29.04  tff(decl_41732, type, fn_genomic_library_2: $i > $i).
% 29.22/29.04  tff(decl_41733, type, fn_genomic_library_5: $i > $i).
% 29.22/29.04  tff(decl_41734, type, fn_genomic_library_6: $i > $i).
% 29.22/29.04  tff(decl_41735, type, fn_genomic_library_7: $i > $i).
% 29.22/29.04  tff(decl_41736, type, fn_genomic_library_8: $i > $i).
% 29.22/29.04  tff(decl_41737, type, "2000": $i).
% 29.22/29.04  tff(decl_41738, type, plasmid_0: $i).
% 29.22/29.04  tff(decl_41739, type, 'Genomic-Representation': $i).
% 29.22/29.04  tff(decl_41740, type, 'A way to represent the entire gneome of an individual organism.': $i).
% 29.22/29.04  tff(decl_41741, type, 'genomic representation': $i).
% 29.22/29.04  tff(decl_41742, type, 'genomic-representation': $i).
% 29.22/29.04  tff(decl_41743, type, genomics_1: $i > $o).
% 29.22/29.04  tff(decl_41744, type, 'Genomics': $i).
% 29.22/29.04  tff(decl_41745, type, 'A subset of the study of genetics that focuses on the study of entire genomes and the ways that genomes interact among individuals': $i).
% 29.22/29.04  tff(decl_41746, type, 'perform genomics': $i).
% 29.22/29.04  tff(decl_41747, type, genomics: $i).
% 29.22/29.04  tff(decl_41748, type, 'Genotype': $i).
% 29.22/29.04  tff(decl_41749, type, 'An individual\\s collection of alleles.': $i).
% 29.22/29.04  tff(decl_41750, type, genotype: $i).
% 29.22/29.04  tff(decl_41751, type, genotype_of_offspring_1: $i > $o).
% 29.22/29.04  tff(decl_41752, type, 'Genotype-Of-Offspring': $i).
% 29.22/29.04  tff(decl_41753, type, 'The genotype of the offspring of a genetic cross or mating.': $i).
% 29.22/29.04  tff(decl_41754, type, 'offspring phenotype': $i).
% 29.22/29.04  tff(decl_41755, type, 'offspring genotype': $i).
% 29.22/29.04  tff(decl_41756, type, 'offspring-genotype': $i).
% 29.22/29.04  tff(decl_41757, type, 'genotype of offspring': $i).
% 29.22/29.04  tff(decl_41758, type, 'genotype-of-offspring': $i).
% 29.22/29.04  tff(decl_41759, type, genotype_of_parent_1: $i > $o).
% 29.22/29.04  tff(decl_41760, type, 'Genotype-Of-Parent': $i).
% 29.22/29.04  tff(decl_41761, type, 'The genotype of the parent of a genetic cross or mating.': $i).
% 29.22/29.04  tff(decl_41762, type, 'parental genotype': $i).
% 29.22/29.04  tff(decl_41763, type, 'parental-genotype': $i).
% 29.22/29.04  tff(decl_41764, type, 'parent genotype': $i).
% 29.22/29.04  tff(decl_41765, type, 'parent-genotype': $i).
% 29.22/29.04  tff(decl_41766, type, 'genotype of parent': $i).
% 29.22/29.04  tff(decl_41767, type, 'genotype-of-parent': $i).
% 29.22/29.04  tff(decl_41768, type, fn_genotype_of_parent_1: $i > $i).
% 29.22/29.04  tff(decl_41769, type, fn_genotype_of_parent_2: $i > $i).
% 29.22/29.04  tff(decl_41770, type, 'Genotypic-Ratio': $i).
% 29.22/29.04  tff(decl_41771, type, 'The proportion of genotypes found in individuals after a cross. For example, consider a cross between two heterozygous individuals for trait A: Aa X Aa The result is a 1:2:1 ratio for the genotypes AA, Aa, and aa respectively. Put another way, if the parents had 100 offspring, 25 would be expected to have the genotype AA, 50 the genotype Aa and 25 the genotype aa.': $i).
% 29.22/29.04  tff(decl_41772, type, 'genotype ratio': $i).
% 29.22/29.04  tff(decl_41773, type, 'genotype-ratio': $i).
% 29.22/29.04  tff(decl_41774, type, 'genotypic ratio': $i).
% 29.22/29.04  tff(decl_41775, type, 'genotypic-ratio': $i).
% 29.22/29.04  tff(decl_41776, type, genus_1: $i > $o).
% 29.22/29.04  tff(decl_41777, type, 'Genus': $i).
% 29.22/29.04  tff(decl_41778, type, 'In Linnean taxonomy, the category above the species and below the family. The genus is the first part of a species\\ scientific name.': $i).
% 29.22/29.04  tff(decl_41779, type, genus: $i).
% 29.22/29.04  tff(decl_41780, type, geographic_barrier_1: $i > $o).
% 29.22/29.04  tff(decl_41781, type, 'Geographic-Barrier': $i).
% 29.22/29.04  tff(decl_41782, type, 'A geographic feature, such as a river or canyon, that separates populations and can thus lead to allopatric speciation.': $i).
% 29.22/29.04  tff(decl_41783, type, 'geographic barrier': $i).
% 29.22/29.04  tff(decl_41784, type, 'geographic-barrier': $i).
% 29.22/29.04  tff(decl_41785, type, 'Geographic-Region': $i).
% 29.22/29.04  tff(decl_41786, type, 'A location on the Earth.': $i).
% 29.22/29.04  tff(decl_41787, type, 'geographic region': $i).
% 29.22/29.04  tff(decl_41788, type, 'geographic-region': $i).
% 29.22/29.04  tff(decl_41789, type, 'Geologic-Entity': $i).
% 29.22/29.04  tff(decl_41790, type, 'An object created by geologic processes.': $i).
% 29.22/29.04  tff(decl_41791, type, 'geologic entity': $i).
% 29.22/29.04  tff(decl_41792, type, 'geologic-entity': $i).
% 29.22/29.04  tff(decl_41793, type, 'Geologic-Process': $i).
% 29.22/29.04  tff(decl_41794, type, 'Any of the processes that shapes the physical structure of the Earth.': $i).
% 29.22/29.04  tff(decl_41795, type, 'geologic process': $i).
% 29.22/29.04  tff(decl_41796, type, 'geologic-process': $i).
% 29.22/29.04  tff(decl_41797, type, geologic_uplift_1: $i > $o).
% 29.22/29.04  tff(decl_41798, type, 'Geologic-Uplift': $i).
% 29.22/29.04  tff(decl_41799, type, 'A geologic process that results in the elevation of rock layers.': $i).
% 29.22/29.04  tff(decl_41800, type, 'geologic uplift': $i).
% 29.22/29.04  tff(decl_41801, type, 'geologic-uplift': $i).
% 29.22/29.04  tff(decl_41802, type, geological_time_period_1: $i > $o).
% 29.22/29.04  tff(decl_41803, type, 'Geological-Time-Period': $i).
% 29.22/29.04  tff(decl_41804, type, 'A division of time related to the history of the earth.': $i).
% 29.22/29.04  tff(decl_41805, type, 'geological time period': $i).
% 29.22/29.04  tff(decl_41806, type, 'geological-time-period': $i).
% 29.22/29.04  tff(decl_41807, type, time_span_1: $i > $o).
% 29.22/29.04  tff(decl_41808, type, geology_1: $i > $o).
% 29.22/29.04  tff(decl_41809, type, 'Geology': $i).
% 29.22/29.04  tff(decl_41810, type, 'The study of the physical matter and energy that constitute the Earth.': $i).
% 29.22/29.04  tff(decl_41811, type, geology: $i).
% 29.22/29.04  tff(decl_41812, type, 'Germ-Layer': $i).
% 29.22/29.04  tff(decl_41813, type, 'In animal development, one of three layers of cells that will give rise to all of the tissues and organs of the body.': $i).
% 29.22/29.04  tff(decl_41814, type, 'layer of germ': $i).
% 29.22/29.04  tff(decl_41815, type, 'germ layer': $i).
% 29.22/29.04  tff(decl_41816, type, 'germ-layer': $i).
% 29.22/29.04  tff(decl_41817, type, germanium_1: $i > $o).
% 29.22/29.04  tff(decl_41818, type, 'Germanium': $i).
% 29.22/29.04  tff(decl_41819, type, 'Germanium is a metalloid atom with atomic number 32. It is represented by the symbol Ge.': $i).
% 29.22/29.04  tff(decl_41820, type, germanium: $i).
% 29.22/29.04  tff(decl_41821, type, 'Ge': $i).
% 29.22/29.04  tff(decl_41822, type, fn_germanium_3: $i > $i).
% 29.22/29.04  tff(decl_41823, type, fn_germanium_4: $i > $i).
% 29.22/29.04  tff(decl_41824, type, fn_germanium_5: $i > $i).
% 29.22/29.04  tff(decl_41825, type, fn_germanium_9: $i > $i).
% 29.22/29.04  tff(decl_41826, type, fn_germanium_10: $i > $i).
% 29.22/29.04  tff(decl_41827, type, fn_germanium_11: $i > $i).
% 29.22/29.04  tff(decl_41828, type, fn_germanium_12: $i > $i).
% 29.22/29.04  tff(decl_41829, type, "41": $i).
% 29.22/29.04  tff(decl_41830, type, "2.01": $i).
% 29.22/29.04  tff(decl_41831, type, "73": $i).
% 29.22/29.04  tff(decl_41832, type, "72.64": $i).
% 29.22/29.04  tff(decl_41833, type, fn_germanium_7: $i > $i).
% 29.22/29.04  tff(decl_41834, type, fn_germanium_8: $i > $i).
% 29.22/29.04  tff(decl_41835, type, fn_germanium_6: $i > $i).
% 29.22/29.04  tff(decl_41836, type, germination_1: $i > $o).
% 29.22/29.04  tff(decl_41837, type, 'Germination': $i).
% 29.22/29.04  tff(decl_41838, type, 'The process by which a seed or spore begins to grow.': $i).
% 29.22/29.04  tff(decl_41839, type, sprouting: $i).
% 29.22/29.04  tff(decl_41840, type, germinate: $i).
% 29.22/29.04  tff(decl_41841, type, germination: $i).
% 29.22/29.04  tff(decl_41842, type, fn_germination_1: $i > $i).
% 29.22/29.04  tff(decl_41843, type, seedling_1: $i > $o).
% 29.22/29.04  tff(decl_41844, type, germline_cell_1: $i > $o).
% 29.22/29.04  tff(decl_41845, type, 'Germline-Cell': $i).
% 29.22/29.04  tff(decl_41846, type, 'The germline cell of a mature or developing individual is the group of cells containing genetic material that may be passed to offspring.': $i).
% 29.22/29.04  tff(decl_41847, type, 'germ line cell': $i).
% 29.22/29.04  tff(decl_41848, type, 'germ-line cell': $i).
% 29.22/29.04  tff(decl_41849, type, 'germline cell': $i).
% 29.22/29.04  tff(decl_41850, type, 'germline-cell': $i).
% 29.22/29.04  tff(decl_41851, type, fn_germline_cell_1: $i > $i).
% 29.22/29.04  tff(decl_41852, type, 'Gestation': $i).
% 29.22/29.04  tff(decl_41853, type, 'The state of pregnancy, in which a female carries developing young in her reproductive tract.': $i).
% 29.22/29.04  tff(decl_41854, type, gestate: $i).
% 29.22/29.04  tff(decl_41855, type, gestation: $i).
% 29.22/29.04  tff(decl_41856, type, 'Gesticulate': $i).
% 29.22/29.04  tff(decl_41857, type, gesticulate: $i).
% 29.22/29.04  tff(decl_41858, type, gesture: $i).
% 29.22/29.04  tff(decl_41859, type, motion: $i).
% 29.22/29.04  tff(decl_41860, type, orient: $i).
% 29.22/29.04  tff(decl_41861, type, speak_1: $i > $o).
% 29.22/29.04  tff(decl_41862, type, fn_gesticulate_1: $i > $i).
% 29.22/29.04  tff(decl_41863, type, fn_gesticulate_2: $i > $i).
% 29.22/29.04  tff(decl_41864, type, get_free_dna_into_cell_1: $i > $o).
% 29.22/29.04  tff(decl_41865, type, 'Get-Free-DNA-Into-Cell': $i).
% 29.22/29.04  tff(decl_41866, type, 'Process of moving extant DNA inside a cell.': $i).
% 29.22/29.04  tff(decl_41867, type, insert: $i).
% 29.22/29.04  tff(decl_41868, type, 'get free dna into cell': $i).
% 29.22/29.04  tff(decl_41869, type, 'get-free-dna-into-cell': $i).
% 29.22/29.04  tff(decl_41870, type, fn_get_free_dna_into_cell_1: $i > $i).
% 29.22/29.04  tff(decl_41871, type, fn_get_free_dna_into_cell_3: $i > $i).
% 29.22/29.04  tff(decl_41872, type, fn_get_free_dna_into_cell_4: $i > $i).
% 29.22/29.04  tff(decl_41873, type, giant_tubeworm_1: $i > $o).
% 29.22/29.04  tff(decl_41874, type, 'Giant-Tubeworm': $i).
% 29.22/29.04  tff(decl_41875, type, 'Large polychaete worm, lacking a mouth or digestive system, which lives under deep pressure around hydrothermal vents in the ocean. Giant tube worms rely on mutualistic bacteria for their nutrition and survival. Scientific name Riftia pachyptila.': $i).
% 29.22/29.04  tff(decl_41876, type, 'giant tubeworm': $i).
% 29.22/29.04  tff(decl_41877, type, 'giant-tubeworm': $i).
% 29.22/29.04  tff(decl_41878, type, polychaete_1: $i > $o).
% 29.22/29.04  tff(decl_41879, type, fn_giant_tubeworm_1: $i > $i).
% 29.22/29.04  tff(decl_41880, type, fn_giant_tubeworm_3: $i > $i).
% 29.22/29.04  tff(decl_41881, type, fn_giant_tubeworm_4: $i > $i).
% 29.22/29.04  tff(decl_41882, type, fn_giant_tubeworm_5: $i > $i).
% 29.22/29.04  tff(decl_41883, type, fn_giant_tubeworm_6: $i > $i).
% 29.22/29.04  tff(decl_41884, type, fn_giant_tubeworm_7: $i > $i).
% 29.22/29.04  tff(decl_41885, type, fn_giant_tubeworm_8: $i > $i).
% 29.22/29.04  tff(decl_41886, type, fn_giant_tubeworm_9: $i > $i).
% 29.22/29.04  tff(decl_41887, type, fn_giant_tubeworm_12: $i > $i).
% 29.22/29.04  tff(decl_41888, type, fn_giant_tubeworm_13: $i > $i).
% 29.22/29.04  tff(decl_41889, type, fn_giant_tubeworm_14: $i > $i).
% 29.22/29.04  tff(decl_41890, type, fn_giant_tubeworm_15: $i > $i).
% 29.22/29.04  tff(decl_41891, type, fn_giant_tubeworm_16: $i > $i).
% 29.22/29.04  tff(decl_41892, type, fn_giant_tubeworm_17: $i > $i).
% 29.22/29.04  tff(decl_41893, type, fn_giant_tubeworm_18: $i > $i).
% 29.22/29.04  tff(decl_41894, type, fn_giant_tubeworm_19: $i > $i).
% 29.22/29.04  tff(decl_41895, type, fn_giant_tubeworm_20: $i > $i).
% 29.22/29.04  tff(decl_41896, type, fn_giant_tubeworm_21: $i > $i).
% 29.22/29.04  tff(decl_41897, type, fn_giant_tubeworm_22: $i > $i).
% 29.22/29.04  tff(decl_41898, type, fn_giant_tubeworm_23: $i > $i).
% 29.22/29.04  tff(decl_41899, type, fn_mutualism_2: $i > $i).
% 29.22/29.04  tff(decl_41900, type, fn_mutualism_1: $i > $i).
% 29.22/29.04  tff(decl_41901, type, "3.0e0": $i).
% 29.22/29.04  tff(decl_41902, type, gibberellin_1: $i > $o).
% 29.22/29.04  tff(decl_41903, type, 'Gibberellin': $i).
% 29.22/29.04  tff(decl_41904, type, 'Any of a group of plant hormones that regulate growth and developmental processes such as stem elongation, germination, flowering, and senescence.': $i).
% 29.22/29.04  tff(decl_41905, type, gibberellin: $i).
% 29.22/29.04  tff(decl_41906, type, 'Gigantism': $i).
% 29.22/29.04  tff(decl_41907, type, 'A medical condition a person grows excessively and reaches a height significantly above average. In humans, gigantism is caused by an excessive production of growth hormone during childhood.': $i).
% 29.22/29.04  tff(decl_41908, type, gigantism: $i).
% 29.22/29.04  tff(decl_41909, type, gill_1: $i > $o).
% 29.22/29.04  tff(decl_41910, type, 'Gill': $i).
% 29.22/29.04  tff(decl_41911, type, 'The respiratory organ of aquatic animals.': $i).
% 29.22/29.04  tff(decl_41912, type, gill: $i).
% 29.22/29.04  tff(decl_41913, type, fn_gill_2: $i > $i).
% 29.22/29.04  tff(decl_41914, type, fn_gill_3: $i > $i).
% 29.22/29.04  tff(decl_41915, type, 'Give': $i).
% 29.22/29.04  tff(decl_41916, type, relinquish_1: $i > $o).
% 29.22/29.04  tff(decl_41917, type, fn_give_1: $i > $i).
% 29.22/29.04  tff(decl_41918, type, 'Gizzard': $i).
% 29.22/29.04  tff(decl_41919, type, 'Muscular, thick walled organ found in the digestive tract of birds and some reptiles, fish and invertebrates which serves to help grind up food.': $i).
% 29.22/29.04  tff(decl_41920, type, gizzard: $i).
% 29.22/29.04  tff(decl_41921, type, 'Glacier': $i).
% 29.22/29.04  tff(decl_41922, type, 'A large mass of ice that persists for many years and moves slowly over the land.': $i).
% 29.22/29.04  tff(decl_41923, type, glacier: $i).
% 29.22/29.04  tff(decl_41924, type, 'Gland': $i).
% 29.22/29.04  tff(decl_41925, type, 'Any of several organs in the body that produce a chemical substance needed by the body and release it for circulation either via ducts or directly into the bloodstream.': $i).
% 29.22/29.04  tff(decl_41926, type, gland: $i).
% 29.22/29.04  tff(decl_41927, type, 'Glandular-Epithelium': $i).
% 29.22/29.04  tff(decl_41928, type, 'Type of epithelial tissue which is specialized for secretory activity.': $i).
% 29.22/29.04  tff(decl_41929, type, 'secretory epithelium': $i).
% 29.22/29.04  tff(decl_41930, type, 'secretory-epithelium': $i).
% 29.22/29.04  tff(decl_41931, type, 'glandular epithelium': $i).
% 29.22/29.04  tff(decl_41932, type, 'glandular-epithelium': $i).
% 29.22/29.04  tff(decl_41933, type, 'Glans': $i).
% 29.22/29.04  tff(decl_41934, type, 'The rounded tip of the penis or clitoris that is extremely sensitive and plays a key role in sexual arousal.': $i).
% 29.22/29.04  tff(decl_41935, type, glans: $i).
% 29.22/29.04  tff(decl_41936, type, glans_penis_1: $i > $o).
% 29.22/29.04  tff(decl_41937, type, 'Glans-Penis': $i).
% 29.22/29.04  tff(decl_41938, type, 'The distal end of the human penis.': $i).
% 29.22/29.04  tff(decl_41939, type, 'head of penis': $i).
% 29.22/29.04  tff(decl_41940, type, 'penis head': $i).
% 29.22/29.04  tff(decl_41941, type, 'penis of glans': $i).
% 29.22/29.04  tff(decl_41942, type, 'glans penis': $i).
% 29.22/29.04  tff(decl_41943, type, 'glans-penis': $i).
% 29.22/29.04  tff(decl_41944, type, glass_1: $i > $o).
% 29.22/29.04  tff(decl_41945, type, 'Glass': $i).
% 29.22/29.04  tff(decl_41946, type, glass: $i).
% 29.22/29.04  tff(decl_41947, type, wood_1: $i > $o).
% 29.22/29.04  tff(decl_41948, type, rubber_1: $i > $o).
% 29.22/29.04  tff(decl_41949, type, plastic_1: $i > $o).
% 29.22/29.04  tff(decl_41950, type, paper_1: $i > $o).
% 29.22/29.04  tff(decl_41951, type, 'Glass-Lens': $i).
% 29.22/29.04  tff(decl_41952, type, 'A glass lens is a lens made of glass and is an optical device with perfect or approximate axial symmetry which transmits and refracts light, converging or diverging the beam.': $i).
% 29.22/29.04  tff(decl_41953, type, 'glass-lens': $i).
% 29.22/29.04  tff(decl_41954, type, 'lens of glass': $i).
% 29.22/29.04  tff(decl_41955, type, 'glass lens': $i).
% 29.22/29.04  tff(decl_41956, type, 'glass-len': $i).
% 29.22/29.04  tff(decl_41957, type, 'Glial-Cell': $i).
% 29.22/29.04  tff(decl_41958, type, 'Supporting cells that are essential for the structural integrity of the nervous system and for the normal functioning of neurons.': $i).
% 29.22/29.04  tff(decl_41959, type, 'glial cell': $i).
% 29.22/29.04  tff(decl_41960, type, 'glial-cell': $i).
% 29.22/29.04  tff(decl_41961, type, global_air_circulation_1: $i > $o).
% 29.22/29.04  tff(decl_41962, type, 'Global-Air-Circulation': $i).
% 29.22/29.04  tff(decl_41963, type, 'A pattern of air circulation over the surface of the Earth, driven by latitude and temperature. The driving force for global air circulation is heating of the atmosphere at the equator.': $i).
% 29.22/29.04  tff(decl_41964, type, 'global air circulation': $i).
% 29.22/29.04  tff(decl_41965, type, 'global-air-circulation': $i).
% 29.22/29.04  tff(decl_41966, type, water_cycle_1: $i > $o).
% 29.22/29.04  tff(decl_41967, type, 'Global-Biogeochemical-Cycle': $i).
% 29.22/29.04  tff(decl_41968, type, 'Biogeochemical cycle which cycles chemicals through biotic and abiotic components of ecosystems on a global scale. Chemicals which naturally exist in gaseous form (such as nitrogen and oxygen) cycle globally.': $i).
% 29.22/29.04  tff(decl_41969, type, 'undergo the global biogeochemical cycle': $i).
% 29.22/29.04  tff(decl_41970, type, 'global biogeochemical cycle': $i).
% 29.22/29.04  tff(decl_41971, type, 'global-biogeochemical-cycle': $i).
% 29.22/29.04  tff(decl_41972, type, fn_global_biogeochemical_cycle_1: $i > $i).
% 29.22/29.04  tff(decl_41973, type, global_ecology_1: $i > $o).
% 29.22/29.04  tff(decl_41974, type, 'Global-Ecology': $i).
% 29.22/29.04  tff(decl_41975, type, 'The study of how organisms function and interact with their environment over a global scale.': $i).
% 29.22/29.04  tff(decl_41976, type, 'global ecology': $i).
% 29.22/29.04  tff(decl_41977, type, 'global-ecology': $i).
% 29.22/29.04  tff(decl_41978, type, global_warming_1: $i > $o).
% 29.22/29.04  tff(decl_41979, type, 'Global-Warming': $i).
% 29.22/29.04  tff(decl_41980, type, 'A process involving buildup of atmospheric CO2 and other greenhouse gases that increases global average temperature.': $i).
% 29.22/29.04  tff(decl_41981, type, 'undergo global warming': $i).
% 29.22/29.04  tff(decl_41982, type, heat: $i).
% 29.22/29.04  tff(decl_41983, type, 'global warming': $i).
% 29.22/29.04  tff(decl_41984, type, 'global-warming': $i).
% 29.22/29.04  tff(decl_41985, type, fn_global_warming_1: $i > $i).
% 29.22/29.04  tff(decl_41986, type, fn_global_warming_2: $i > $i).
% 29.22/29.04  tff(decl_41987, type, 'Globin-Ancestral-Gene': $i).
% 29.22/29.04  tff(decl_41988, type, 'Common evolutionary gene for beta globin ancestral gene and alpha globin ancestral gene.': $i).
% 29.22/29.04  tff(decl_41989, type, 'globin ancestral gene': $i).
% 29.22/29.04  tff(decl_41990, type, 'globin-ancestral-gene': $i).
% 29.22/29.04  tff(decl_41991, type, 'Globins': $i).
% 29.22/29.04  tff(decl_41992, type, 'A group of proteins that contain a heme group and function in transporting oxygen.': $i).
% 29.22/29.04  tff(decl_41993, type, globins: $i).
% 29.22/29.04  tff(decl_41994, type, globin: $i).
% 29.22/29.04  tff(decl_41995, type, 'Globular-Protein': $i).
% 29.22/29.04  tff(decl_41996, type, 'A protein which has a roughly spherical shape in its functional conformation.': $i).
% 29.22/29.04  tff(decl_41997, type, 'protein of globular': $i).
% 29.22/29.04  tff(decl_41998, type, 'globular protein': $i).
% 29.22/29.04  tff(decl_41999, type, 'globular-protein': $i).
% 29.22/29.04  tff(decl_42000, type, water_soluble_protein_1: $i > $o).
% 29.22/29.04  tff(decl_42001, type, fn_globular_protein_1: $i > $i).
% 29.22/29.04  tff(decl_42002, type, 'Glomeromycete': $i).
% 29.22/29.04  tff(decl_42003, type, 'One of a group of several phyla of fungi that form mutualistic associations, called arbuscular mycorrhizae, with plant roots.': $i).
% 29.22/29.04  tff(decl_42004, type, glomeromycete: $i).
% 29.22/29.04  tff(decl_42005, type, glomerulus_1: $i > $o).
% 29.22/29.04  tff(decl_42006, type, 'Glomerulus': $i).
% 29.22/29.04  tff(decl_42007, type, 'In the nephron of a mammalian kidney, a ball of capillaries that is surrounded by the Bowman\\s capsule and is the site of filtration.': $i).
% 29.22/29.04  tff(decl_42008, type, glomerulus: $i).
% 29.22/29.04  tff(decl_42009, type, peritubular_capillary_1: $i > $o).
% 29.22/29.04  tff(decl_42010, type, vasa_recta_1: $i > $o).
% 29.22/29.04  tff(decl_42011, type, glottis_1: $i > $o).
% 29.22/29.04  tff(decl_42012, type, 'Glottis': $i).
% 29.22/29.04  tff(decl_42013, type, 'The region of the larnyx which contains the vocal chords and the space between them.': $i).
% 29.22/29.04  tff(decl_42014, type, glottis: $i).
% 29.22/29.04  tff(decl_42015, type, fn_glottis_1: $i > $i).
% 29.22/29.04  tff(decl_42016, type, fn_glottis_2: $i > $i).
% 29.22/29.04  tff(decl_42017, type, fn_glottis_3: $i > $i).
% 29.22/29.04  tff(decl_42018, type, 'Glucagon': $i).
% 29.22/29.04  tff(decl_42019, type, 'A hormone, secreted by alpha cells of the pancreas, that raises blood glucose levels. It acts by stimulating the liver to break down glycogen and release glucose into the blood.': $i).
% 29.22/29.04  tff(decl_42020, type, glucagon: $i).
% 29.22/29.04  tff(decl_42021, type, pancreatic_hormone_1: $i > $o).
% 29.22/29.04  tff(decl_42022, type, glucocorticoid_1: $i > $o).
% 29.22/29.04  tff(decl_42023, type, 'Glucocorticoid': $i).
% 29.22/29.04  tff(decl_42024, type, 'A class of steroid hormones that are secreted by the adrenal cortex. They play a role in regulating glucose metabolism and immune function.': $i).
% 29.22/29.04  tff(decl_42025, type, glucocorticoid: $i).
% 29.22/29.04  tff(decl_42026, type, mineralocorticoid_1: $i > $o).
% 29.22/29.04  tff(decl_42027, type, 'Glucose': $i).
% 29.22/29.04  tff(decl_42028, type, 'Glucose is the most common simple sugar and the most important to the chemistry of life, as it is the substrate for cellular respiration and a product of photosynthesis.': $i).
% 29.22/29.04  tff(decl_42029, type, c6h12o6: $i).
% 29.22/29.04  tff(decl_42030, type, glucose: $i).
% 29.22/29.04  tff(decl_42031, type, fn_glucose_4: $i > $i).
% 29.22/29.04  tff(decl_42032, type, fn_glucose_5: $i > $i).
% 29.22/29.04  tff(decl_42033, type, fn_glucose_8: $i > $i).
% 29.22/29.04  tff(decl_42034, type, fn_glucose_9: $i > $i).
% 29.22/29.04  tff(decl_42035, type, fn_glucose_10: $i > $i).
% 29.22/29.04  tff(decl_42036, type, fn_glucose_11: $i > $i).
% 29.22/29.04  tff(decl_42037, type, fn_glucose_12: $i > $i).
% 29.22/29.04  tff(decl_42038, type, fn_glucose_13: $i > $i).
% 29.22/29.04  tff(decl_42039, type, fn_glucose_14: $i > $i).
% 29.22/29.04  tff(decl_42040, type, fn_glucose_16: $i > $i).
% 29.22/29.04  tff(decl_42041, type, fn_glucose_17: $i > $i).
% 29.22/29.04  tff(decl_42042, type, fn_glucose_18: $i > $i).
% 29.22/29.04  tff(decl_42043, type, fn_glucose_19: $i > $i).
% 29.22/29.04  tff(decl_42044, type, fn_glucose_20: $i > $i).
% 29.22/29.04  tff(decl_42045, type, fn_glucose_23: $i > $i).
% 29.22/29.04  tff(decl_42046, type, fn_glucose_25: $i > $i).
% 29.22/29.04  tff(decl_42047, type, fn_glucose_26: $i > $i).
% 29.22/29.04  tff(decl_42048, type, fn_glucose_28: $i > $i).
% 29.22/29.04  tff(decl_42049, type, fn_glucose_29: $i > $i).
% 29.22/29.04  tff(decl_42050, type, fn_glucose_30: $i > $i).
% 29.22/29.04  tff(decl_42051, type, fn_glucose_31: $i > $i).
% 29.22/29.04  tff(decl_42052, type, fn_glucose_32: $i > $i).
% 29.22/29.04  tff(decl_42053, type, fn_glucose_34: $i > $i).
% 29.22/29.04  tff(decl_42054, type, fn_glucose_35: $i > $i).
% 29.22/29.04  tff(decl_42055, type, fn_glucose_7: $i > $i).
% 29.22/29.04  tff(decl_42056, type, fn_monosaccharide_19: $i > $i).
% 29.22/29.04  tff(decl_42057, type, fn_monosaccharide_3: $i > $i).
% 29.22/29.04  tff(decl_42058, type, fn_glucose_36: $i > $i).
% 29.22/29.04  tff(decl_42059, type, fn_monosaccharide_1: $i > $i).
% 29.22/29.04  tff(decl_42060, type, fn_monosaccharide_4: $i > $i).
% 29.22/29.04  tff(decl_42061, type, fn_monosaccharide_7: $i > $i).
% 29.22/29.04  tff(decl_42062, type, fn_monosaccharide_8: $i > $i).
% 29.22/29.04  tff(decl_42063, type, 'Glucose-1-Phosphate': $i).
% 29.22/29.04  tff(decl_42064, type, 'An ion constituting both glucose and phosphate.': $i).
% 29.22/29.04  tff(decl_42065, type, 'glucose 1 phosphate': $i).
% 29.22/29.04  tff(decl_42066, type, 'glucose-1-phosphate': $i).
% 29.22/29.04  tff(decl_42067, type, fn_glucose_1_phosphate_2: $i > $i).
% 29.22/29.04  tff(decl_42068, type, fn_glucose_1_phosphate_3: $i > $i).
% 29.22/29.04  tff(decl_42069, type, fn_glucose_1_phosphate_4: $i > $i).
% 29.22/29.04  tff(decl_42070, type, fn_glucose_1_phosphate_5: $i > $i).
% 29.22/29.04  tff(decl_42071, type, fn_glucose_1_phosphate_6: $i > $i).
% 29.22/29.04  tff(decl_42072, type, 'Glucose-6-Phosphate': $i).
% 29.22/29.04  tff(decl_42073, type, 'Glucose 6-phosphate is glucose sugar phosphorylated on carbon 6.': $i).
% 29.22/29.04  tff(decl_42074, type, 'robison ester': $i).
% 29.22/29.04  tff(decl_42075, type, 'robison-ester': $i).
% 29.22/29.04  tff(decl_42076, type, 'glucose 6 phosphate': $i).
% 29.22/29.04  tff(decl_42077, type, 'glucose-6-phosphate': $i).
% 29.22/29.04  tff(decl_42078, type, fn_glucose_6_phosphate_2: $i > $i).
% 29.22/29.04  tff(decl_42079, type, fn_glucose_6_phosphate_3: $i > $i).
% 29.22/29.04  tff(decl_42080, type, fn_glucose_6_phosphate_4: $i > $i).
% 29.22/29.04  tff(decl_42081, type, fn_glucose_6_phosphate_5: $i > $i).
% 29.22/29.04  tff(decl_42082, type, fn_glucose_6_phosphate_8: $i > $i).
% 29.22/29.04  tff(decl_42083, type, fn_glucose_6_phosphate_9: $i > $i).
% 29.22/29.04  tff(decl_42084, type, fn_glucose_6_phosphate_10: $i > $i).
% 29.22/29.04  tff(decl_42085, type, fn_glucose_6_phosphate_11: $i > $i).
% 29.22/29.04  tff(decl_42086, type, fn_glucose_6_phosphate_12: $i > $i).
% 29.22/29.04  tff(decl_42087, type, fn_glucose_6_phosphate_13: $i > $i).
% 29.22/29.04  tff(decl_42088, type, fn_glucose_6_phosphate_14: $i > $i).
% 29.22/29.04  tff(decl_42089, type, fn_glucose_6_phosphate_15: $i > $i).
% 29.22/29.04  tff(decl_42090, type, fn_glucose_6_phosphate_16: $i > $i).
% 29.22/29.04  tff(decl_42091, type, fn_glucose_6_phosphate_17: $i > $i).
% 29.22/29.04  tff(decl_42092, type, fn_glucose_6_phosphate_18: $i > $i).
% 29.22/29.04  tff(decl_42093, type, fn_glucose_6_phosphate_19: $i > $i).
% 29.22/29.04  tff(decl_42094, type, fn_glucose_6_phosphate_20: $i > $i).
% 29.22/29.04  tff(decl_42095, type, fn_glucose_6_phosphate_21: $i > $i).
% 29.22/29.04  tff(decl_42096, type, fn_glucose_6_phosphate_22: $i > $i).
% 29.22/29.04  tff(decl_42097, type, fn_glucose_6_phosphate_23: $i > $i).
% 29.22/29.04  tff(decl_42098, type, 'Glucose-Isomer': $i).
% 29.22/29.04  tff(decl_42099, type, 'One of the two forms of glucose, each with the same atomic parts, but different structure, shape and function.': $i).
% 29.22/29.04  tff(decl_42100, type, 'isomer of glucose': $i).
% 29.22/29.04  tff(decl_42101, type, 'glucose isomer': $i).
% 29.22/29.04  tff(decl_42102, type, 'glucose-isomer': $i).
% 29.22/29.04  tff(decl_42103, type, fn_glucose_isomer_3: $i > $i).
% 29.22/29.04  tff(decl_42104, type, fn_glucose_isomer_4: $i > $i).
% 29.22/29.04  tff(decl_42105, type, glucose_storage_by_animals_1: $i > $o).
% 29.22/29.04  tff(decl_42106, type, fn_glucose_storage_by_animals_4: $i > $i).
% 29.22/29.04  tff(decl_42107, type, fn_glucose_storage_by_animals_1: $i > $i).
% 29.22/29.04  tff(decl_42108, type, 'Glucose-Storage-By-Animals': $i).
% 29.22/29.04  tff(decl_42109, type, 'Animals cannot store much glucose. Surplus energy would be stored as glycogen and then fat.': $i).
% 29.22/29.04  tff(decl_42110, type, store: $i).
% 29.22/29.04  tff(decl_42111, type, 'glucose storage by animal': $i).
% 29.22/29.04  tff(decl_42112, type, 'glucose-storage-by-animal': $i).
% 29.22/29.04  tff(decl_42113, type, glycogen_storage_by_vertebrate_1: $i > $o).
% 29.22/29.04  tff(decl_42114, type, fn_glucose_storage_by_animals_3: $i > $i).
% 29.22/29.04  tff(decl_42115, type, fn_glycogen_8: $i > $i).
% 29.22/29.04  tff(decl_42116, type, glucose_transporter_1: $i > $o).
% 29.22/29.04  tff(decl_42117, type, 'Glucose-Transporter': $i).
% 29.22/29.04  tff(decl_42118, type, 'An entity performing transport of glucose molecule within cells.': $i).
% 29.22/29.04  tff(decl_42119, type, 'glucose transporter': $i).
% 29.22/29.04  tff(decl_42120, type, 'glucose-transporter': $i).
% 29.22/29.04  tff(decl_42121, type, 'Glutamate': $i).
% 29.22/29.04  tff(decl_42122, type, 'A neurotransmitter in the central nervous system. It is a salt form of the amino acid glutamic acid.': $i).
% 29.22/29.04  tff(decl_42123, type, glutamate: $i).
% 29.22/29.04  tff(decl_42124, type, fn_glutamate_1: $i > $i).
% 29.22/29.04  tff(decl_42125, type, fn_glutamate_2: $i > $i).
% 29.22/29.04  tff(decl_42126, type, glutamic_acid_1: $i > $o).
% 29.22/29.04  tff(decl_42127, type, 'Glutamic-Acid': $i).
% 29.22/29.04  tff(decl_42128, type, glu: $i).
% 29.22/29.04  tff(decl_42129, type, e: $i).
% 29.22/29.04  tff(decl_42130, type, 'glutamic acid': $i).
% 29.22/29.04  tff(decl_42131, type, 'glutamic-acid': $i).
% 29.22/29.04  tff(decl_42132, type, glutamine_1: $i > $o).
% 29.22/29.04  tff(decl_42133, type, 'Glutamine': $i).
% 29.22/29.04  tff(decl_42134, type, gln: $i).
% 29.22/29.04  tff(decl_42135, type, q: $i).
% 29.22/29.04  tff(decl_42136, type, glutamine: $i).
% 29.22/29.04  tff(decl_42137, type, 'Glyceraldehyde-3-Phosphate': $i).
% 29.22/29.04  tff(decl_42138, type, 'Glyceraldehyde 3-phosphate, also known as triose phosphate or 3-phosphoglyceraldehyde and abbreviated as G3P, GADP, GAP, TP, GALP or PGAL, is a chemical compound that occurs as an intermediate in several central metabolic pathways of all organisms.': $i).
% 29.22/29.04  tff(decl_42139, type, 'glyceraldehyde phosphate': $i).
% 29.22/29.04  tff(decl_42140, type, 'p gal': $i).
% 29.22/29.04  tff(decl_42141, type, 'p-gal': $i).
% 29.22/29.04  tff(decl_42142, type, pgal: $i).
% 29.22/29.04  tff(decl_42143, type, glyceraldehyde: $i).
% 29.22/29.04  tff(decl_42144, type, 'glyceraldehyde 3 phosphate': $i).
% 29.22/29.04  tff(decl_42145, type, 'glyceraldehyde-3-phosphate': $i).
% 29.22/29.04  tff(decl_42146, type, fn_glyceraldehyde_3_phosphate_1: $i > $i).
% 29.22/29.04  tff(decl_42147, type, fn_glyceraldehyde_3_phosphate_2: $i > $i).
% 29.22/29.04  tff(decl_42148, type, fn_glyceraldehyde_3_phosphate_5: $i > $i).
% 29.22/29.04  tff(decl_42149, type, 'Glycerol': $i).
% 29.22/29.04  tff(decl_42150, type, 'Simple alcohol which forms the base of a triglyceride.': $i).
% 29.22/29.04  tff(decl_42151, type, glycerol: $i).
% 29.22/29.04  tff(decl_42152, type, fn_glycerol_1: $i > $i).
% 29.22/29.04  tff(decl_42153, type, 'Glycerol-Head': $i).
% 29.22/29.04  tff(decl_42154, type, 'Portion of a lipid containing glycerol.': $i).
% 29.22/29.04  tff(decl_42155, type, 'head of glycerol': $i).
% 29.22/29.04  tff(decl_42156, type, 'glycerol head': $i).
% 29.22/29.04  tff(decl_42157, type, 'glycerol-head': $i).
% 29.22/29.04  tff(decl_42158, type, glycerol_substance_1: $i > $o).
% 29.22/29.04  tff(decl_42159, type, 'Glycerol-Substance': $i).
% 29.22/29.04  tff(decl_42160, type, 'Liquid glycerol which is composed of glycerol molecules.': $i).
% 29.22/29.04  tff(decl_42161, type, 'substance of glycerol': $i).
% 29.22/29.04  tff(decl_42162, type, 'glycerol substance': $i).
% 29.22/29.04  tff(decl_42163, type, 'glycerol-substance': $i).
% 29.22/29.04  tff(decl_42164, type, fn_glycerol_substance_1: $i > $i).
% 29.22/29.04  tff(decl_42165, type, fn_glycerol_substance_3: $i > $i).
% 29.22/29.04  tff(decl_42166, type, fn_glycerol_substance_2: $i > $i).
% 29.22/29.04  tff(decl_42167, type, glycine_1: $i > $o).
% 29.22/29.04  tff(decl_42168, type, 'Glycine': $i).
% 29.22/29.04  tff(decl_42169, type, 'One of the 20 most common amino acids that make up proteins. It is the smallest of all amino acids. On its own , it can function as a neurotransmitter.': $i).
% 29.22/29.04  tff(decl_42170, type, gly: $i).
% 29.22/29.04  tff(decl_42171, type, glycine: $i).
% 29.22/29.04  tff(decl_42172, type, fn_glycine_1: $i > $i).
% 29.22/29.04  tff(decl_42173, type, fn_glycine_2: $i > $i).
% 29.22/29.04  tff(decl_42174, type, fn_glycine_9: $i > $i).
% 29.22/29.04  tff(decl_42175, type, fn_glycine_10: $i > $i).
% 29.22/29.04  tff(decl_42176, type, fn_glycine_11: $i > $i).
% 29.22/29.04  tff(decl_42177, type, fn_glycine_12: $i > $i).
% 29.22/29.04  tff(decl_42178, type, fn_glycine_13: $i > $i).
% 29.22/29.04  tff(decl_42179, type, fn_glycine_14: $i > $i).
% 29.22/29.04  tff(decl_42180, type, fn_glycine_15: $i > $i).
% 29.22/29.04  tff(decl_42181, type, fn_glycine_16: $i > $i).
% 29.22/29.04  tff(decl_42182, type, fn_glycine_17: $i > $i).
% 29.22/29.04  tff(decl_42183, type, fn_glycine_18: $i > $i).
% 29.22/29.04  tff(decl_42184, type, fn_glycine_19: $i > $i).
% 29.22/29.04  tff(decl_42185, type, fn_glycine_20: $i > $i).
% 29.22/29.04  tff(decl_42186, type, fn_glycine_21: $i > $i).
% 29.22/29.04  tff(decl_42187, type, fn_glycine_22: $i > $i).
% 29.22/29.05  tff(decl_42188, type, fn_glycine_23: $i > $i).
% 29.22/29.05  tff(decl_42189, type, fn_glycine_24: $i > $i).
% 29.22/29.05  tff(decl_42190, type, fn_glycine_25: $i > $i).
% 29.22/29.05  tff(decl_42191, type, fn_glycine_26: $i > $i).
% 29.22/29.05  tff(decl_42192, type, fn_glycine_27: $i > $i).
% 29.22/29.05  tff(decl_42193, type, fn_glycine_28: $i > $i).
% 29.22/29.05  tff(decl_42194, type, fn_glycine_30: $i > $i).
% 29.22/29.05  tff(decl_42195, type, fn_glycine_31: $i > $i).
% 29.22/29.05  tff(decl_42196, type, fn_glycine_32: $i > $i).
% 29.22/29.05  tff(decl_42197, type, fn_glycine_33: $i > $i).
% 29.22/29.05  tff(decl_42198, type, fn_glycine_34: $i > $i).
% 29.22/29.05  tff(decl_42199, type, fn_glycine_35: $i > $i).
% 29.22/29.05  tff(decl_42200, type, fn_glycine_36: $i > $i).
% 29.22/29.05  tff(decl_42201, type, fn_glycine_37: $i > $i).
% 29.22/29.05  tff(decl_42202, type, fn_glycine_38: $i > $i).
% 29.22/29.05  tff(decl_42203, type, fn_glycine_39: $i > $i).
% 29.22/29.05  tff(decl_42204, type, fn_hydrogen_20: $i > $i).
% 29.22/29.05  tff(decl_42205, type, fn_hydrogen_18: $i > $i).
% 29.22/29.05  tff(decl_42206, type, fn_carboxyl_group_1: $i > $i).
% 29.22/29.05  tff(decl_42207, type, fn_carboxyl_group_3: $i > $i).
% 29.22/29.05  tff(decl_42208, type, fn_carboxyl_group_2: $i > $i).
% 29.22/29.05  tff(decl_42209, type, fn_glycine_8: $i > $i).
% 29.22/29.05  tff(decl_42210, type, fn_glycine_7: $i > $i).
% 29.22/29.05  tff(decl_42211, type, fn_glycine_4: $i > $i).
% 29.22/29.05  tff(decl_42212, type, fn_glycine_29: $i > $i).
% 29.22/29.05  tff(decl_42213, type, fn_glycine_6: $i > $i).
% 29.22/29.05  tff(decl_42214, type, fn_glycine_5: $i > $i).
% 29.22/29.05  tff(decl_42215, type, fn_glycine_3: $i > $i).
% 29.22/29.05  tff(decl_42216, type, 'Glycogen': $i).
% 29.22/29.05  tff(decl_42217, type, 'Glycogen is a polysaccharide. The presence of side chains affects the density of energy storage and function of stuctural starches, and is characteristic to the structure of glycogen.': $i).
% 29.22/29.05  tff(decl_42218, type, 'major storage carbohydrate in animals': $i).
% 29.22/29.05  tff(decl_42219, type, glycogen: $i).
% 29.22/29.05  tff(decl_42220, type, fn_glycogen_2: $i > $i).
% 29.22/29.05  tff(decl_42221, type, fn_glycogen_4: $i > $i).
% 29.22/29.05  tff(decl_42222, type, fn_glycogen_7: $i > $i).
% 29.22/29.05  tff(decl_42223, type, fn_glycogen_9: $i > $i).
% 29.22/29.05  tff(decl_42224, type, fn_glycogen_10: $i > $i).
% 29.22/29.05  tff(decl_42225, type, fn_glycogen_11: $i > $i).
% 29.22/29.05  tff(decl_42226, type, fn_glycogen_12: $i > $i).
% 29.22/29.05  tff(decl_42227, type, fn_glycogen_13: $i > $i).
% 29.22/29.05  tff(decl_42228, type, fn_glycogen_14: $i > $i).
% 29.22/29.05  tff(decl_42229, type, fn_glycogen_15: $i > $i).
% 29.22/29.05  tff(decl_42230, type, fn_glycogen_16: $i > $i).
% 29.22/29.05  tff(decl_42231, type, fn_glycogen_17: $i > $i).
% 29.22/29.05  tff(decl_42232, type, fn_glycogen_18: $i > $i).
% 29.22/29.05  tff(decl_42233, type, fn_glycogen_19: $i > $i).
% 29.22/29.05  tff(decl_42234, type, fn_glycogen_20: $i > $i).
% 29.22/29.05  tff(decl_42235, type, fn_glycogen_21: $i > $i).
% 29.22/29.05  tff(decl_42236, type, fn_glycogen_22: $i > $i).
% 29.22/29.05  tff(decl_42237, type, fn_glycogen_23: $i > $i).
% 29.22/29.05  tff(decl_42238, type, fn_glycogen_24: $i > $i).
% 29.22/29.05  tff(decl_42239, type, fn_glycogen_25: $i > $i).
% 29.22/29.05  tff(decl_42240, type, fn_glycogen_28: $i > $i).
% 29.22/29.05  tff(decl_42241, type, fn_storage_polysaccharide_38: $i > $i).
% 29.22/29.05  tff(decl_42242, type, fn_glycogen_26: $i > $i).
% 29.22/29.05  tff(decl_42243, type, fn_glycogen_5: $i > $i).
% 29.22/29.05  tff(decl_42244, type, fn_glycogen_27: $i > $i).
% 29.22/29.05  tff(decl_42245, type, fn_glycogen_6: $i > $i).
% 29.22/29.05  tff(decl_42246, type, fn_storage_polysaccharide_54: $i > $i).
% 29.22/29.05  tff(decl_42247, type, fn_storage_polysaccharide_56: $i > $i).
% 29.22/29.05  tff(decl_42248, type, 'Glycogen-Breakdown': $i).
% 29.22/29.05  tff(decl_42249, type, 'The enzymatic breakdown, through hydrolysis, of glycogen, resulting in glucose.': $i).
% 29.22/29.05  tff(decl_42250, type, hydrolyze: $i).
% 29.22/29.05  tff(decl_42251, type, 'glycogen hydrolysis': $i).
% 29.22/29.05  tff(decl_42252, type, 'glycogen breakdown': $i).
% 29.22/29.05  tff(decl_42253, type, 'breakdown of glycogen': $i).
% 29.22/29.05  tff(decl_42254, type, 'glycogen-breakdown': $i).
% 29.22/29.05  tff(decl_42255, type, storage_polysaccharide_breakdown_1: $i > $o).
% 29.22/29.05  tff(decl_42256, type, hydrolysis_of_sucrose_1: $i > $o).
% 29.22/29.05  tff(decl_42257, type, fn_glycogen_breakdown_1: $i > $i).
% 29.22/29.05  tff(decl_42258, type, fn_glycogen_breakdown_2: $i > $i).
% 29.22/29.05  tff(decl_42259, type, fn_glycogen_breakdown_3: $i > $i).
% 29.22/29.05  tff(decl_42260, type, fn_glycogen_breakdown_6: $i > $i).
% 29.22/29.05  tff(decl_42261, type, fn_glycogen_breakdown_7: $i > $i).
% 29.22/29.05  tff(decl_42262, type, fn_glycogen_breakdown_8: $i > $i).
% 29.22/29.05  tff(decl_42263, type, fn_glycogen_breakdown_9: $i > $i).
% 29.22/29.05  tff(decl_42264, type, fn_glycogen_breakdown_10: $i > $i).
% 29.22/29.05  tff(decl_42265, type, fn_glycogen_breakdown_11: $i > $i).
% 29.22/29.05  tff(decl_42266, type, fn_glycogen_breakdown_12: $i > $i).
% 29.22/29.05  tff(decl_42267, type, fn_glycogen_breakdown_13: $i > $i).
% 29.22/29.05  tff(decl_42268, type, fn_glycogen_breakdown_14: $i > $i).
% 29.22/29.05  tff(decl_42269, type, fn_glycogen_breakdown_15: $i > $i).
% 29.22/29.05  tff(decl_42270, type, fn_glycogen_breakdown_17: $i > $i).
% 29.22/29.05  tff(decl_42271, type, fn_glycogen_breakdown_19: $i > $i).
% 29.22/29.05  tff(decl_42272, type, fn_glycogen_breakdown_20: $i > $i).
% 29.22/29.05  tff(decl_42273, type, fn_glycogen_breakdown_21: $i > $i).
% 29.22/29.05  tff(decl_42274, type, fn_glycogen_breakdown_22: $i > $i).
% 29.22/29.05  tff(decl_42275, type, fn_glycogen_breakdown_23: $i > $i).
% 29.22/29.05  tff(decl_42276, type, fn_glycogen_breakdown_24: $i > $i).
% 29.22/29.05  tff(decl_42277, type, fn_glycogen_breakdown_25: $i > $i).
% 29.22/29.05  tff(decl_42278, type, fn_glycogen_breakdown_26: $i > $i).
% 29.22/29.05  tff(decl_42279, type, fn_glycogen_breakdown_27: $i > $i).
% 29.22/29.05  tff(decl_42280, type, fn_glycogen_phosphorylase_15: $i > $i).
% 29.22/29.05  tff(decl_42281, type, fn_glycogen_phosphorylase_12: $i > $i).
% 29.22/29.05  tff(decl_42282, type, fn_glycogen_phosphorylase_18: $i > $i).
% 29.22/29.05  tff(decl_42283, type, fn_glycogen_phosphorylase_19: $i > $i).
% 29.22/29.05  tff(decl_42284, type, fn_glycogen_phosphorylase_8: $i > $i).
% 29.22/29.05  tff(decl_42285, type, fn_glycogen_phosphorylase_9: $i > $i).
% 29.22/29.05  tff(decl_42286, type, fn_glycogen_phosphorylase_5: $i > $i).
% 29.22/29.05  tff(decl_42287, type, fn_glycogen_phosphorylase_17: $i > $i).
% 29.22/29.05  tff(decl_42288, type, fn_glycogen_breakdown_29: $i > $i).
% 29.22/29.05  tff(decl_42289, type, fn_glycogen_breakdown_28: $i > $i).
% 29.22/29.05  tff(decl_42290, type, glycogen_breakdown_in_vertebrates_1: $i > $o).
% 29.22/29.05  tff(decl_42291, type, 'Glycogen-Breakdown-In-Vertebrates': $i).
% 29.22/29.05  tff(decl_42292, type, 'The breakdown of the storage polysaccharide, glycogen, stimulated by epinephrine.  Glycogen breakdown can lead to the production of glucose 6-phosphate, an early intermediate in the process of glycolysis or an increase in the glucose concentration in the bloodstream.': $i).
% 29.22/29.05  tff(decl_42293, type, 'glycogen breakdown in vertebrate': $i).
% 29.22/29.05  tff(decl_42294, type, 'glycogen-breakdown-in-vertebrate': $i).
% 29.22/29.05  tff(decl_42295, type, fn_glycogen_breakdown_in_vertebrates_1: $i > $i).
% 29.22/29.05  tff(decl_42296, type, fn_glycogen_breakdown_in_vertebrates_2: $i > $i).
% 29.22/29.05  tff(decl_42297, type, fn_glycogen_breakdown_in_vertebrates_3: $i > $i).
% 29.22/29.05  tff(decl_42298, type, fn_glycogen_breakdown_in_vertebrates_4: $i > $i).
% 29.22/29.05  tff(decl_42299, type, fn_glycogen_breakdown_in_vertebrates_7: $i > $i).
% 29.22/29.05  tff(decl_42300, type, fn_glycogen_breakdown_in_vertebrates_8: $i > $i).
% 29.22/29.05  tff(decl_42301, type, fn_glycogen_breakdown_in_vertebrates_9: $i > $i).
% 29.22/29.05  tff(decl_42302, type, fn_glycogen_breakdown_in_vertebrates_18: $i > $i).
% 29.22/29.05  tff(decl_42303, type, fn_glycogen_breakdown_in_vertebrates_19: $i > $i).
% 29.22/29.05  tff(decl_42304, type, fn_glycogen_breakdown_in_vertebrates_20: $i > $i).
% 29.22/29.05  tff(decl_42305, type, fn_glycogen_breakdown_in_vertebrates_21: $i > $i).
% 29.22/29.05  tff(decl_42306, type, fn_glycogen_breakdown_in_vertebrates_22: $i > $i).
% 29.22/29.05  tff(decl_42307, type, fn_glycogen_breakdown_in_vertebrates_23: $i > $i).
% 29.22/29.05  tff(decl_42308, type, fn_glycogen_breakdown_in_vertebrates_24: $i > $i).
% 29.22/29.05  tff(decl_42309, type, fn_glycogen_breakdown_in_vertebrates_25: $i > $i).
% 29.22/29.05  tff(decl_42310, type, fn_glycogen_breakdown_in_vertebrates_26: $i > $i).
% 29.22/29.05  tff(decl_42311, type, fn_glycogen_breakdown_in_vertebrates_27: $i > $i).
% 29.22/29.05  tff(decl_42312, type, fn_glycogen_breakdown_in_vertebrates_28: $i > $i).
% 29.22/29.05  tff(decl_42313, type, fn_glycogen_breakdown_in_vertebrates_29: $i > $i).
% 29.22/29.05  tff(decl_42314, type, fn_glycogen_breakdown_in_vertebrates_30: $i > $i).
% 29.22/29.05  tff(decl_42315, type, fn_glycogen_breakdown_in_vertebrates_31: $i > $i).
% 29.22/29.05  tff(decl_42316, type, fn_glycogen_breakdown_in_vertebrates_32: $i > $i).
% 29.22/29.05  tff(decl_42317, type, fn_glycogen_breakdown_in_vertebrates_33: $i > $i).
% 29.22/29.05  tff(decl_42318, type, fn_glycogen_breakdown_in_vertebrates_34: $i > $i).
% 29.22/29.05  tff(decl_42319, type, fn_glycogen_breakdown_in_vertebrates_35: $i > $i).
% 29.22/29.05  tff(decl_42320, type, fn_glycogen_breakdown_in_vertebrates_36: $i > $i).
% 29.22/29.05  tff(decl_42321, type, fn_glycogen_breakdown_in_vertebrates_37: $i > $i).
% 29.22/29.05  tff(decl_42322, type, fn_glycogen_breakdown_in_vertebrates_38: $i > $i).
% 29.22/29.05  tff(decl_42323, type, fn_glycogen_breakdown_in_vertebrates_39: $i > $i).
% 29.22/29.05  tff(decl_42324, type, fn_glycogen_breakdown_in_vertebrates_40: $i > $i).
% 29.22/29.05  tff(decl_42325, type, fn_glycogen_breakdown_in_vertebrates_41: $i > $i).
% 29.22/29.05  tff(decl_42326, type, fn_glycogen_breakdown_in_vertebrates_42: $i > $i).
% 29.22/29.05  tff(decl_42327, type, fn_glycogen_breakdown_in_vertebrates_43: $i > $i).
% 29.22/29.05  tff(decl_42328, type, fn_glycogen_breakdown_in_vertebrates_44: $i > $i).
% 29.22/29.05  tff(decl_42329, type, fn_glycogen_breakdown_in_vertebrates_45: $i > $i).
% 29.22/29.05  tff(decl_42330, type, fn_glycogen_breakdown_in_vertebrates_46: $i > $i).
% 29.22/29.05  tff(decl_42331, type, fn_glycogen_breakdown_in_vertebrates_47: $i > $i).
% 29.22/29.05  tff(decl_42332, type, fn_glycogen_breakdown_in_vertebrates_48: $i > $i).
% 29.22/29.05  tff(decl_42333, type, fn_glycogen_breakdown_in_vertebrates_49: $i > $i).
% 29.22/29.05  tff(decl_42334, type, fn_glycogen_breakdown_in_vertebrates_50: $i > $i).
% 29.22/29.05  tff(decl_42335, type, fn_glycogen_breakdown_in_vertebrates_51: $i > $i).
% 29.22/29.05  tff(decl_42336, type, fn_glycogen_breakdown_in_vertebrates_52: $i > $i).
% 29.22/29.05  tff(decl_42337, type, fn_glycogen_breakdown_in_vertebrates_53: $i > $i).
% 29.22/29.05  tff(decl_42338, type, fn_glycogen_breakdown_in_vertebrates_54: $i > $i).
% 29.22/29.05  tff(decl_42339, type, fn_glycogen_breakdown_in_vertebrates_55: $i > $i).
% 29.22/29.05  tff(decl_42340, type, fn_glycogen_breakdown_in_vertebrates_56: $i > $i).
% 29.22/29.05  tff(decl_42341, type, fn_glycogen_breakdown_in_vertebrates_57: $i > $i).
% 29.22/29.05  tff(decl_42342, type, fn_glycogen_breakdown_in_vertebrates_58: $i > $i).
% 29.22/29.05  tff(decl_42343, type, fn_glycogen_breakdown_in_vertebrates_59: $i > $i).
% 29.22/29.05  tff(decl_42344, type, fn_glycogen_breakdown_in_vertebrates_60: $i > $i).
% 29.22/29.05  tff(decl_42345, type, fn_glycogen_breakdown_in_vertebrates_61: $i > $i).
% 29.22/29.05  tff(decl_42346, type, fn_glycogen_breakdown_in_vertebrates_62: $i > $i).
% 29.22/29.05  tff(decl_42347, type, fn_glycogen_breakdown_in_vertebrates_63: $i > $i).
% 29.22/29.05  tff(decl_42348, type, fn_glycogen_breakdown_in_vertebrates_64: $i > $i).
% 29.22/29.05  tff(decl_42349, type, fn_glycogen_breakdown_in_vertebrates_65: $i > $i).
% 29.22/29.05  tff(decl_42350, type, fn_glycogen_breakdown_in_vertebrates_66: $i > $i).
% 29.22/29.05  tff(decl_42351, type, fn_glycogen_breakdown_in_vertebrates_67: $i > $i).
% 29.22/29.05  tff(decl_42352, type, fn_glycogen_breakdown_in_vertebrates_68: $i > $i).
% 29.22/29.05  tff(decl_42353, type, fn_glycogen_breakdown_in_vertebrates_69: $i > $i).
% 29.22/29.05  tff(decl_42354, type, fn_glycogen_phosphorylase_1: $i > $i).
% 29.22/29.05  tff(decl_42355, type, fn_glucose_1_phosphate_1: $i > $i).
% 29.22/29.05  tff(decl_42356, type, glucose_1_phosphate_0: $i).
% 29.22/29.05  tff(decl_42357, type, fn_glycogen_breakdown_in_vertebrates_11: $i > $i).
% 29.22/29.05  tff(decl_42358, type, fn_glycogen_breakdown_4: $i > $i).
% 29.22/29.05  tff(decl_42359, type, fn_glycogen_breakdown_in_vertebrates_10: $i > $i).
% 29.22/29.05  tff(decl_42360, type, fn_glycogen_breakdown_5: $i > $i).
% 29.22/29.05  tff(decl_42361, type, fn_glycogen_breakdown_in_vertebrates_5: $i > $i).
% 29.22/29.05  tff(decl_42362, type, fn_glycogen_breakdown_in_vertebrates_6: $i > $i).
% 29.22/29.05  tff(decl_42363, type, fn_polymer_breakdown_1: $i > $i).
% 29.22/29.05  tff(decl_42364, type, fn_glycogen_breakdown_in_vertebrates_12: $i > $i).
% 29.22/29.05  tff(decl_42365, type, fn_glycogen_breakdown_in_vertebrates_14: $i > $i).
% 29.22/29.05  tff(decl_42366, type, fn_glycogen_breakdown_in_vertebrates_15: $i > $i).
% 29.22/29.05  tff(decl_42367, type, fn_glycogen_breakdown_in_vertebrates_13: $i > $i).
% 29.22/29.05  tff(decl_42368, type, fn_glycogen_breakdown_in_vertebrates_17: $i > $i).
% 29.22/29.05  tff(decl_42369, type, fn_glycogen_breakdown_in_vertebrates_16: $i > $i).
% 29.22/29.05  tff(decl_42370, type, 'Glycogen-Phosphorylase': $i).
% 29.22/29.05  tff(decl_42371, type, 'Enzyme which catalyzes the breakdown of glycogen into glucose.': $i).
% 29.22/29.05  tff(decl_42372, type, 'phosphorylase of glycogen': $i).
% 29.22/29.05  tff(decl_42373, type, 'glycogen phosphorylase': $i).
% 29.22/29.05  tff(decl_42374, type, 'glycogen-phosphorylase': $i).
% 29.22/29.05  tff(decl_42375, type, phosphorylase_1: $i > $o).
% 29.22/29.05  tff(decl_42376, type, fn_glycogen_phosphorylase_2: $i > $i).
% 29.22/29.05  tff(decl_42377, type, fn_glycogen_phosphorylase_3: $i > $i).
% 29.22/29.05  tff(decl_42378, type, fn_glycogen_phosphorylase_4: $i > $i).
% 29.22/29.05  tff(decl_42379, type, fn_glycogen_phosphorylase_6: $i > $i).
% 29.22/29.05  tff(decl_42380, type, fn_glycogen_phosphorylase_10: $i > $i).
% 29.22/29.05  tff(decl_42381, type, fn_glycogen_phosphorylase_11: $i > $i).
% 29.22/29.05  tff(decl_42382, type, fn_glycogen_phosphorylase_13: $i > $i).
% 29.22/29.05  tff(decl_42383, type, fn_glycogen_phosphorylase_14: $i > $i).
% 29.22/29.05  tff(decl_42384, type, fn_glycogen_storage_by_vertebrate_11: $i > $i).
% 29.22/29.05  tff(decl_42385, type, 'Glycogen-Storage-By-Vertebrate': $i).
% 29.22/29.05  tff(decl_42386, type, 'The process by which the liver converts glucose to the polysaccharide glycogen, which is susequently  stored in muscle and liver cells until needed.': $i).
% 29.22/29.05  tff(decl_42387, type, 'glycogen storage by vertebrate': $i).
% 29.22/29.05  tff(decl_42388, type, 'glycogen-storage-by-vertebrate': $i).
% 29.22/29.05  tff(decl_42389, type, fn_glycogen_storage_by_vertebrate_2: $i > $i).
% 29.22/29.05  tff(decl_42390, type, fn_glycogen_storage_by_vertebrate_3: $i > $i).
% 29.22/29.05  tff(decl_42391, type, fn_glycogen_storage_by_vertebrate_4: $i > $i).
% 29.22/29.05  tff(decl_42392, type, fn_glycogen_storage_by_vertebrate_5: $i > $i).
% 29.22/29.05  tff(decl_42393, type, fn_glycogen_storage_by_vertebrate_6: $i > $i).
% 29.22/29.05  tff(decl_42394, type, fn_glycogen_storage_by_vertebrate_8: $i > $i).
% 29.22/29.05  tff(decl_42395, type, fn_glycogen_storage_by_vertebrate_9: $i > $i).
% 29.22/29.05  tff(decl_42396, type, fn_glycogen_storage_by_vertebrate_10: $i > $i).
% 29.22/29.05  tff(decl_42397, type, fn_glycogen_storage_by_vertebrate_12: $i > $i).
% 29.22/29.05  tff(decl_42398, type, fn_glycogen_storage_by_vertebrate_13: $i > $i).
% 29.22/29.05  tff(decl_42399, type, fn_glycogen_storage_by_vertebrate_14: $i > $i).
% 29.22/29.05  tff(decl_42400, type, fn_muscle_cell_54: $i > $i).
% 29.22/29.05  tff(decl_42401, type, fn_liver_cell_50: $i > $i).
% 29.22/29.05  tff(decl_42402, type, fn_muscle_cell_55: $i > $i).
% 29.22/29.05  tff(decl_42403, type, fn_liver_cell_51: $i > $i).
% 29.22/29.05  tff(decl_42404, type, fn_glycogen_storage_by_vertebrate_7: $i > $i).
% 29.22/29.05  tff(decl_42405, type, 'Glycolipid': $i).
% 29.22/29.05  tff(decl_42406, type, 'Glycolipids are lipids with a carbohydrate attached. Their role is to provide energy and also serve as markers for cellular recognition.': $i).
% 29.22/29.05  tff(decl_42407, type, glycolipid: $i).
% 29.22/29.05  tff(decl_42408, type, fn_glycolipid_2: $i > $i).
% 29.22/29.05  tff(decl_42409, type, fn_glycolipid_5: $i > $i).
% 29.22/29.05  tff(decl_42410, type, fn_glycolipid_6: $i > $i).
% 29.22/29.05  tff(decl_42411, type, fn_glycolipid_8: $i > $i).
% 29.22/29.05  tff(decl_42412, type, fn_glycolipid_9: $i > $i).
% 29.22/29.05  tff(decl_42413, type, fn_glycolipid_10: $i > $i).
% 29.22/29.05  tff(decl_42414, type, fn_glycolipid_11: $i > $i).
% 29.22/29.05  tff(decl_42415, type, fn_glycolipid_12: $i > $i).
% 29.22/29.05  tff(decl_42416, type, fn_glycolipid_14: $i > $i).
% 29.22/29.05  tff(decl_42417, type, fn_glycolipid_15: $i > $i).
% 29.22/29.05  tff(decl_42418, type, fn_glycolipid_16: $i > $i).
% 29.22/29.05  tff(decl_42419, type, fn_glycolipid_17: $i > $i).
% 29.22/29.05  tff(decl_42420, type, fn_glycolipid_18: $i > $i).
% 29.22/29.05  tff(decl_42421, type, fn_lipid_15: $i > $i).
% 29.22/29.05  tff(decl_42422, type, 'Glycolysis': $i).
% 29.22/29.05  tff(decl_42423, type, 'A series of chemical reactions that breaks a glucose into two molecules of pyruvate and yields two molecules of ATP.': $i).
% 29.22/29.05  tff(decl_42424, type, 'splitting of sugar': $i).
% 29.22/29.05  tff(decl_42425, type, 'splitting-of-sugar': $i).
% 29.22/29.05  tff(decl_42426, type, 'glycolytic pathway': $i).
% 29.22/29.05  tff(decl_42427, type, 'sugar splitting': $i).
% 29.22/29.05  tff(decl_42428, type, 'sugar-splitting': $i).
% 29.22/29.05  tff(decl_42429, type, 'perform glycolysis': $i).
% 29.22/29.05  tff(decl_42430, type, glycolysis: $i).
% 29.22/29.05  tff(decl_42431, type, fn_glycolysis_12: $i > $i).
% 29.22/29.05  tff(decl_42432, type, fn_glycolysis_14: $i > $i).
% 29.22/29.05  tff(decl_42433, type, fn_glycolysis_18: $i > $i).
% 29.22/29.05  tff(decl_42434, type, fn_glycolysis_20: $i > $i).
% 29.22/29.05  tff(decl_42435, type, fn_glycolysis_23: $i > $i).
% 29.22/29.05  tff(decl_42436, type, fn_glycolysis_24: $i > $i).
% 29.22/29.05  tff(decl_42437, type, fn_glycolysis_25: $i > $i).
% 29.22/29.05  tff(decl_42438, type, fn_glycolysis_26: $i > $i).
% 29.22/29.05  tff(decl_42439, type, fn_glycolysis_29: $i > $i).
% 29.22/29.05  tff(decl_42440, type, fn_glycolysis_30: $i > $i).
% 29.22/29.05  tff(decl_42441, type, fn_glycolysis_31: $i > $i).
% 29.22/29.05  tff(decl_42442, type, fn_glycolysis_32: $i > $i).
% 29.22/29.05  tff(decl_42443, type, fn_glycolysis_36: $i > $i).
% 29.22/29.05  tff(decl_42444, type, fn_glycolysis_37: $i > $i).
% 29.22/29.05  tff(decl_42445, type, fn_glycolysis_38: $i > $i).
% 29.22/29.05  tff(decl_42446, type, fn_glycolysis_39: $i > $i).
% 29.22/29.05  tff(decl_42447, type, fn_glycolysis_40: $i > $i).
% 29.22/29.05  tff(decl_42448, type, fn_glycolysis_41: $i > $i).
% 29.22/29.05  tff(decl_42449, type, fn_glycolysis_42: $i > $i).
% 29.22/29.05  tff(decl_42450, type, fn_glycolysis_43: $i > $i).
% 29.22/29.05  tff(decl_42451, type, fn_glycolysis_44: $i > $i).
% 29.22/29.05  tff(decl_42452, type, fn_glycolysis_45: $i > $i).
% 29.22/29.05  tff(decl_42453, type, fn_glycolysis_46: $i > $i).
% 29.22/29.05  tff(decl_42454, type, fn_glycolysis_49: $i > $i).
% 29.22/29.05  tff(decl_42455, type, fn_glycolysis_50: $i > $i).
% 29.22/29.05  tff(decl_42456, type, fn_glycolysis_51: $i > $i).
% 29.22/29.05  tff(decl_42457, type, fn_glycolysis_52: $i > $i).
% 29.22/29.05  tff(decl_42458, type, fn_glycolysis_54: $i > $i).
% 29.22/29.05  tff(decl_42459, type, fn_glycolysis_57: $i > $i).
% 29.22/29.05  tff(decl_42460, type, fn_glycolysis_58: $i > $i).
% 29.22/29.05  tff(decl_42461, type, fn_glycolysis_59: $i > $i).
% 29.22/29.05  tff(decl_42462, type, fn_glycolysis_60: $i > $i).
% 29.22/29.05  tff(decl_42463, type, fn_glycolysis_61: $i > $i).
% 29.22/29.05  tff(decl_42464, type, fn_glycolysis_71: $i > $i).
% 29.22/29.05  tff(decl_42465, type, fn_glycolysis_72: $i > $i).
% 29.22/29.05  tff(decl_42466, type, fn_glycolysis_76: $i > $i).
% 29.22/29.05  tff(decl_42467, type, fn_glycolysis_85: $i > $i).
% 29.22/29.05  tff(decl_42468, type, fn_glycolysis_86: $i > $i).
% 29.22/29.05  tff(decl_42469, type, fn_glycolysis_87: $i > $i).
% 29.22/29.05  tff(decl_42470, type, fn_glycolysis_92: $i > $i).
% 29.22/29.05  tff(decl_42471, type, fn_glycolysis_93: $i > $i).
% 29.22/29.05  tff(decl_42472, type, fn_glycolysis_94: $i > $i).
% 29.22/29.05  tff(decl_42473, type, fn_glycolysis_95: $i > $i).
% 29.22/29.05  tff(decl_42474, type, fn_glycolysis_96: $i > $i).
% 29.22/29.05  tff(decl_42475, type, fn_glycolysis_101: $i > $i).
% 29.22/29.05  tff(decl_42476, type, fn_glycolysis_102: $i > $i).
% 29.22/29.05  tff(decl_42477, type, fn_glycolysis_103: $i > $i).
% 29.22/29.05  tff(decl_42478, type, fn_glycolysis_104: $i > $i).
% 29.22/29.05  tff(decl_42479, type, fn_glycolysis_105: $i > $i).
% 29.22/29.05  tff(decl_42480, type, fn_glycolysis_10: $i > $i).
% 29.22/29.05  tff(decl_42481, type, fn_glycolysis_98: $i > $i).
% 29.22/29.05  tff(decl_42482, type, fn_glycolysis_7: $i > $i).
% 29.22/29.05  tff(decl_42483, type, fn_glycolysis_99: $i > $i).
% 29.22/29.05  tff(decl_42484, type, fn_glycolysis_6: $i > $i).
% 29.22/29.05  tff(decl_42485, type, fn_glycolysis_11: $i > $i).
% 29.22/29.05  tff(decl_42486, type, fn_glycolysis_107: $i > $i).
% 29.22/29.05  tff(decl_42487, type, fn_glycolysis_106: $i > $i).
% 29.22/29.05  tff(decl_42488, type, 'Glycoprotein': $i).
% 29.22/29.05  tff(decl_42489, type, 'Glycoprotein are proteins containing oligosaccharide chains covalently attached to their polypeptide side chains': $i).
% 29.22/29.05  tff(decl_42490, type, 'glyco protein': $i).
% 29.22/29.05  tff(decl_42491, type, 'glyco-protein': $i).
% 29.22/29.05  tff(decl_42492, type, glycoprotein: $i).
% 29.22/29.05  tff(decl_42493, type, fn_glycoprotein_13: $i > $i).
% 29.22/29.05  tff(decl_42494, type, fn_glycoprotein_16: $i > $i).
% 29.22/29.05  tff(decl_42495, type, fn_glycoprotein_27: $i > $i).
% 29.22/29.05  tff(decl_42496, type, fn_glycoprotein_28: $i > $i).
% 29.22/29.05  tff(decl_42497, type, fn_glycoprotein_29: $i > $i).
% 29.22/29.05  tff(decl_42498, type, fn_glycoprotein_30: $i > $i).
% 29.22/29.05  tff(decl_42499, type, fn_glycoprotein_31: $i > $i).
% 29.22/29.05  tff(decl_42500, type, fn_glycoprotein_15: $i > $i).
% 29.22/29.05  tff(decl_42501, type, 'Glycoprotein-Hormone': $i).
% 29.22/29.05  tff(decl_42502, type, 'A molecule that functions as a hormone and consists of a protein with at least one carbohydrate covalently bonded to it.': $i).
% 29.22/29.05  tff(decl_42503, type, 'hormone of glycoprotein': $i).
% 29.22/29.05  tff(decl_42504, type, 'glycoprotein hormone': $i).
% 29.22/29.05  tff(decl_42505, type, 'glycoprotein-hormone': $i).
% 29.22/29.05  tff(decl_42506, type, 'Glycosidic-Linkage': $i).
% 29.22/29.05  tff(decl_42507, type, 'A covalent bond between two monosaccharides, or between a carbohydrate and another molecule, formed by a dehydration synthesis reaction.': $i).
% 29.22/29.05  tff(decl_42508, type, 'glycosidic linkage': $i).
% 29.22/29.05  tff(decl_42509, type, 'glycosidic-linkage': $i).
% 29.22/29.05  tff(decl_42510, type, fn_glycosidic_linkage_5: $i > $i).
% 29.22/29.05  tff(decl_42511, type, fn_glycosidic_linkage_12: $i > $i).
% 29.22/29.05  tff(decl_42512, type, fn_glycosidic_linkage_23: $i > $i).
% 29.22/29.05  tff(decl_42513, type, fn_glycosidic_linkage_24: $i > $i).
% 29.22/29.05  tff(decl_42514, type, fn_glycosidic_linkage_28: $i > $i).
% 29.22/29.05  tff(decl_42515, type, fn_glycosidic_linkage_29: $i > $i).
% 29.22/29.05  tff(decl_42516, type, fn_glycosidic_linkage_39: $i > $i).
% 29.22/29.05  tff(decl_42517, type, fn_glycosidic_linkage_40: $i > $i).
% 29.22/29.05  tff(decl_42518, type, fn_glycosidic_linkage_52: $i > $i).
% 29.22/29.05  tff(decl_42519, type, fn_glycosidic_linkage_53: $i > $i).
% 29.22/29.05  tff(decl_42520, type, fn_glycosidic_linkage_54: $i > $i).
% 29.22/29.05  tff(decl_42521, type, fn_glycosidic_linkage_55: $i > $i).
% 29.22/29.05  tff(decl_42522, type, fn_glycosidic_linkage_8: $i > $i).
% 29.22/29.05  tff(decl_42523, type, glyoxysome_1: $i > $o).
% 29.22/29.05  tff(decl_42524, type, 'Glyoxysome': $i).
% 29.22/29.05  tff(decl_42525, type, 'A specialized peroxisome that occurs in plants and some algae.  Glyoxysomes contain enzymes that initiate the catalysis of fats, as well as enzymes that convert stored lipids into carbohydrates which the young seedling can use until it is mature enough for photosynthesis.': $i).
% 29.22/29.05  tff(decl_42526, type, glyoxysome: $i).
% 29.22/29.05  tff(decl_42527, type, fn_glyoxysome_1: $i > $i).
% 29.22/29.05  tff(decl_42528, type, fn_glyoxysome_2: $i > $i).
% 29.22/29.05  tff(decl_42529, type, fn_glyoxysome_3: $i > $i).
% 29.22/29.05  tff(decl_42530, type, fn_glyoxysome_4: $i > $i).
% 29.22/29.05  tff(decl_42531, type, fn_glyoxysome_5: $i > $i).
% 29.22/29.05  tff(decl_42532, type, fn_glyoxysome_6: $i > $i).
% 29.22/29.05  tff(decl_42533, type, fn_glyoxysome_7: $i > $i).
% 29.22/29.05  tff(decl_42534, type, fn_glyoxysome_8: $i > $i).
% 29.22/29.05  tff(decl_42535, type, fn_glyoxysome_9: $i > $i).
% 29.22/29.05  tff(decl_42536, type, fn_glyoxysome_10: $i > $i).
% 29.22/29.05  tff(decl_42537, type, fn_glyoxysome_11: $i > $i).
% 29.22/29.05  tff(decl_42538, type, fn_glyoxysome_12: $i > $i).
% 29.22/29.05  tff(decl_42539, type, fn_glyoxysome_13: $i > $i).
% 29.22/29.05  tff(decl_42540, type, fn_glyoxysome_14: $i > $i).
% 29.22/29.05  tff(decl_42541, type, fn_glyoxysome_15: $i > $i).
% 29.22/29.05  tff(decl_42542, type, fn_glyoxysome_16: $i > $i).
% 29.22/29.05  tff(decl_42543, type, fn_glyoxysome_17: $i > $i).
% 29.22/29.05  tff(decl_42544, type, fn_glyoxysome_18: $i > $i).
% 29.22/29.05  tff(decl_42545, type, fn_glyoxysome_19: $i > $i).
% 29.22/29.05  tff(decl_42546, type, fn_glyoxysome_20: $i > $i).
% 29.22/29.05  tff(decl_42547, type, fn_glyoxysome_21: $i > $i).
% 29.22/29.05  tff(decl_42548, type, fn_glyoxysome_22: $i > $i).
% 29.22/29.05  tff(decl_42549, type, fn_glyoxysome_23: $i > $i).
% 29.22/29.05  tff(decl_42550, type, fn_glyoxysome_24: $i > $i).
% 29.22/29.05  tff(decl_42551, type, fn_glyoxysome_26: $i > $i).
% 29.22/29.05  tff(decl_42552, type, fn_glyoxysome_27: $i > $i).
% 29.22/29.05  tff(decl_42553, type, fn_seed_6: $i > $i).
% 29.22/29.05  tff(decl_42554, type, fn_seed_5: $i > $i).
% 29.22/29.05  tff(decl_42555, type, fn_seed_7: $i > $i).
% 29.22/29.05  tff(decl_42556, type, fn_peroxisome_2: $i > $i).
% 29.22/29.05  tff(decl_42557, type, fn_glyoxysome_25: $i > $i).
% 29.22/29.05  tff(decl_42558, type, fn_peroxisome_53: $i > $i).
% 29.22/29.05  tff(decl_42559, type, fn_peroxisome_11: $i > $i).
% 29.22/29.05  tff(decl_42560, type, fn_peroxisome_41: $i > $i).
% 29.22/29.05  tff(decl_42561, type, fn_peroxisome_28: $i > $i).
% 29.22/29.05  tff(decl_42562, type, fn_peroxisome_42: $i > $i).
% 29.22/29.05  tff(decl_42563, type, fn_peroxisome_25: $i > $i).
% 29.22/29.05  tff(decl_42564, type, fn_peroxisome_26: $i > $i).
% 29.22/29.05  tff(decl_42565, type, fn_peroxisome_7: $i > $i).
% 29.22/29.05  tff(decl_42566, type, fn_peroxisome_52: $i > $i).
% 29.22/29.05  tff(decl_42567, type, fn_peroxisome_49: $i > $i).
% 29.22/29.05  tff(decl_42568, type, fn_peroxisome_47: $i > $i).
% 29.22/29.05  tff(decl_42569, type, fn_peroxisome_30: $i > $i).
% 29.22/29.05  tff(decl_42570, type, 'GMP': $i).
% 29.22/29.05  tff(decl_42571, type, 'Molecule which functions as a second messenger in some cell signalling pathways.': $i).
% 29.22/29.05  tff(decl_42572, type, gmp: $i).
% 29.22/29.05  tff(decl_42573, type, gnathostome_1: $i > $o).
% 29.22/29.05  tff(decl_42574, type, 'Gnathostome': $i).
% 29.22/29.05  tff(decl_42575, type, 'Any vertebrate animal that possesses jaws.': $i).
% 29.22/29.05  tff(decl_42576, type, gnathostomata: $i).
% 29.22/29.05  tff(decl_42577, type, 'jawed vertebrates': $i).
% 29.22/29.05  tff(decl_42578, type, gnathostome: $i).
% 29.22/29.05  tff(decl_42579, type, gnetophyta_1: $i > $o).
% 29.22/29.05  tff(decl_42580, type, 'Gnetophyta': $i).
% 29.22/29.05  tff(decl_42581, type, 'Type of gymnosperm characterized by double fertilization and vessel elements in its vascular tissue.': $i).
% 29.22/29.05  tff(decl_42582, type, gnetophyta: $i).
% 29.22/29.05  tff(decl_42583, type, fn_gnetophyta_1: $i > $i).
% 29.22/29.05  tff(decl_42584, type, fn_gnetophyta_2: $i > $i).
% 29.22/29.05  tff(decl_42585, type, fn_gnetophyta_3: $i > $i).
% 29.22/29.05  tff(decl_42586, type, fn_gnetophyta_4: $i > $i).
% 29.22/29.05  tff(decl_42587, type, fn_gnetophyta_5: $i > $i).
% 29.22/29.05  tff(decl_42588, type, fn_gnetophyta_6: $i > $i).
% 29.22/29.05  tff(decl_42589, type, fn_gnetophyta_8: $i > $i).
% 29.22/29.05  tff(decl_42590, type, fn_gnetophyta_9: $i > $i).
% 29.22/29.05  tff(decl_42591, type, fn_gnetophyta_10: $i > $i).
% 29.22/29.05  tff(decl_42592, type, fn_gnetophyta_17: $i > $i).
% 29.22/29.05  tff(decl_42593, type, fn_gnetophyta_18: $i > $i).
% 29.22/29.05  tff(decl_42594, type, fn_gnetophyta_19: $i > $i).
% 29.22/29.05  tff(decl_42595, type, fn_gnetophyta_20: $i > $i).
% 29.22/29.05  tff(decl_42596, type, fn_gnetophyta_21: $i > $i).
% 29.22/29.05  tff(decl_42597, type, fn_gnetophyta_22: $i > $i).
% 29.22/29.05  tff(decl_42598, type, fn_gnetophyta_23: $i > $i).
% 29.22/29.05  tff(decl_42599, type, fn_gnetophyta_24: $i > $i).
% 29.22/29.05  tff(decl_42600, type, fn_gnetophyta_25: $i > $i).
% 29.22/29.05  tff(decl_42601, type, fn_gnetophyta_26: $i > $i).
% 29.22/29.05  tff(decl_42602, type, fn_gnetophyta_27: $i > $i).
% 29.22/29.05  tff(decl_42603, type, fn_gnetophyta_28: $i > $i).
% 29.22/29.05  tff(decl_42604, type, fn_gnetophyta_29: $i > $i).
% 29.22/29.05  tff(decl_42605, type, fn_gnetophyta_30: $i > $i).
% 29.22/29.05  tff(decl_42606, type, fn_gnetophyta_31: $i > $i).
% 29.22/29.05  tff(decl_42607, type, fn_gnetophyta_32: $i > $i).
% 29.22/29.05  tff(decl_42608, type, fn_gnetophyta_33: $i > $i).
% 29.22/29.05  tff(decl_42609, type, fn_gnetophyta_34: $i > $i).
% 29.22/29.05  tff(decl_42610, type, fn_gnetophyta_35: $i > $i).
% 29.22/29.05  tff(decl_42611, type, fn_gnetophyta_36: $i > $i).
% 29.22/29.05  tff(decl_42612, type, fn_gnetophyta_37: $i > $i).
% 29.22/29.05  tff(decl_42613, type, fn_gnetophyta_38: $i > $i).
% 29.22/29.05  tff(decl_42614, type, fn_gnetophyta_39: $i > $i).
% 29.22/29.05  tff(decl_42615, type, fn_gnetophyta_40: $i > $i).
% 29.22/29.05  tff(decl_42616, type, fn_gnetophyta_41: $i > $i).
% 29.22/29.05  tff(decl_42617, type, fn_gnetophyta_42: $i > $i).
% 29.22/29.05  tff(decl_42618, type, fn_gnetophyta_43: $i > $i).
% 29.22/29.05  tff(decl_42619, type, fn_gnetophyta_44: $i > $i).
% 29.22/29.05  tff(decl_42620, type, fn_gnetophyta_45: $i > $i).
% 29.22/29.05  tff(decl_42621, type, fn_gnetophyta_46: $i > $i).
% 29.22/29.05  tff(decl_42622, type, fn_gnetophyta_47: $i > $i).
% 29.22/29.05  tff(decl_42623, type, fn_gnetophyta_48: $i > $i).
% 29.22/29.05  tff(decl_42624, type, fn_gnetophyta_49: $i > $i).
% 29.22/29.05  tff(decl_42625, type, fn_gnetophyta_50: $i > $i).
% 29.22/29.05  tff(decl_42626, type, fn_gnetophyta_52: $i > $i).
% 29.22/29.05  tff(decl_42627, type, fn_gnetophyta_53: $i > $i).
% 29.22/29.05  tff(decl_42628, type, fn_gnetophyta_54: $i > $i).
% 29.22/29.05  tff(decl_42629, type, fn_gnetophyta_55: $i > $i).
% 29.22/29.05  tff(decl_42630, type, fn_gnetophyta_56: $i > $i).
% 29.22/29.05  tff(decl_42631, type, fn_gnetophyta_57: $i > $i).
% 29.22/29.05  tff(decl_42632, type, fn_gnetophyta_58: $i > $i).
% 29.22/29.05  tff(decl_42633, type, fn_gnetophyta_59: $i > $i).
% 29.22/29.05  tff(decl_42634, type, fn_gnetophyta_60: $i > $i).
% 29.22/29.05  tff(decl_42635, type, fn_gnetophyta_61: $i > $i).
% 29.22/29.05  tff(decl_42636, type, fn_gnetophyta_62: $i > $i).
% 29.22/29.05  tff(decl_42637, type, fn_gnetophyta_63: $i > $i).
% 29.22/29.05  tff(decl_42638, type, fn_gnetophyta_64: $i > $i).
% 29.22/29.05  tff(decl_42639, type, fn_gnetophyta_65: $i > $i).
% 29.22/29.05  tff(decl_42640, type, fn_root_25: $i > $i).
% 29.22/29.05  tff(decl_42641, type, fn_seed_2: $i > $i).
% 29.22/29.05  tff(decl_42642, type, fn_root_26: $i > $i).
% 29.22/29.05  tff(decl_42643, type, fn_seed_1: $i > $i).
% 29.22/29.05  tff(decl_42644, type, fn_gnetophyta_51: $i > $i).
% 29.22/29.05  tff(decl_42645, type, fn_gnetophyta_66: $i > $i).
% 29.22/29.05  tff(decl_42646, type, fn_gnetophyta_67: $i > $i).
% 29.22/29.05  tff(decl_42647, type, fn_gymnosperm_17: $i > $i).
% 29.22/29.05  tff(decl_42648, type, fn_gymnosperm_1: $i > $i).
% 29.22/29.05  tff(decl_42649, type, fn_gnetophyta_15: $i > $i).
% 29.22/29.05  tff(decl_42650, type, fn_gnetophyta_16: $i > $i).
% 29.22/29.05  tff(decl_42651, type, fn_gnetophyta_11: $i > $i).
% 29.22/29.05  tff(decl_42652, type, fn_gnetophyta_12: $i > $i).
% 29.22/29.05  tff(decl_42653, type, fn_gnetophyta_14: $i > $i).
% 29.22/29.05  tff(decl_42654, type, fn_gnetophyta_13: $i > $i).
% 29.22/29.05  tff(decl_42655, type, go_through_1: $i > $o).
% 29.22/29.05  tff(decl_42656, type, 'Go-Through': $i).
% 29.22/29.05  tff(decl_42657, type, 'go through': $i).
% 29.22/29.05  tff(decl_42658, type, go_through: $i).
% 29.22/29.05  tff(decl_42659, type, 'go-through': $i).
% 29.22/29.05  tff(decl_42660, type, 'Go-To': $i).
% 29.22/29.05  tff(decl_42661, type, travel: $i).
% 29.22/29.05  tff(decl_42662, type, locomote: $i).
% 29.22/29.05  tff(decl_42663, type, reach: $i).
% 29.22/29.05  tff(decl_42664, type, 'move to': $i).
% 29.22/29.05  tff(decl_42665, type, 'go to': $i).
% 29.22/29.05  tff(decl_42666, type, 'go-to': $i).
% 29.22/29.05  tff(decl_42667, type, goal_1: $i > $o).
% 29.22/29.05  tff(decl_42668, type, 'Goal': $i).
% 29.22/29.05  tff(decl_42669, type, goal: $i).
% 29.22/29.05  tff(decl_42670, type, finish: $i).
% 29.22/29.05  tff(decl_42671, type, destination: $i).
% 29.22/29.05  tff(decl_42672, type, goiter_1: $i > $o).
% 29.22/29.05  tff(decl_42673, type, 'Goiter': $i).
% 29.22/29.05  tff(decl_42674, type, 'Medical condition in which the thyroid gland becomes enlarged.': $i).
% 29.22/29.05  tff(decl_42675, type, goiter: $i).
% 29.22/29.05  tff(decl_42676, type, gold_1: $i > $o).
% 29.22/29.05  tff(decl_42677, type, 'Gold': $i).
% 29.22/29.05  tff(decl_42678, type, 'Gold is a metal atom with atomic number 79. It is represented by the symbol Au.': $i).
% 29.22/29.05  tff(decl_42679, type, gold: $i).
% 29.22/29.05  tff(decl_42680, type, 'Au': $i).
% 29.22/29.05  tff(decl_42681, type, fn_gold_3: $i > $i).
% 29.22/29.05  tff(decl_42682, type, fn_gold_4: $i > $i).
% 29.22/29.05  tff(decl_42683, type, fn_gold_5: $i > $i).
% 29.22/29.05  tff(decl_42684, type, fn_gold_9: $i > $i).
% 29.22/29.05  tff(decl_42685, type, fn_gold_10: $i > $i).
% 29.22/29.05  tff(decl_42686, type, fn_gold_11: $i > $i).
% 29.22/29.05  tff(decl_42687, type, fn_gold_12: $i > $i).
% 29.22/29.05  tff(decl_42688, type, "118": $i).
% 29.22/29.05  tff(decl_42689, type, "79": $i).
% 29.22/29.05  tff(decl_42690, type, "2.54": $i).
% 29.22/29.05  tff(decl_42691, type, "197": $i).
% 29.22/29.05  tff(decl_42692, type, fn_gold_7: $i > $i).
% 29.22/29.05  tff(decl_42693, type, fn_gold_8: $i > $i).
% 29.22/29.05  tff(decl_42694, type, fn_gold_6: $i > $i).
% 29.22/29.05  tff(decl_42695, type, 'Golden-Alga': $i).
% 29.22/29.05  tff(decl_42696, type, 'A biflagellated, photosynthetic protist named for its color, which results from its yellow and brown carotenoids.': $i).
% 29.22/29.05  tff(decl_42697, type, 'golden alga': $i).
% 29.22/29.05  tff(decl_42698, type, 'golden-alga': $i).
% 29.22/29.05  tff(decl_42699, type, 'Golgi-Apparatus': $i).
% 29.22/29.05  tff(decl_42700, type, 'The Golgi apparatus is an organelle found in most eukaryotic cells.The primary function of the Golgi apparatus is to synthesize, process, store and package macromolecules, such as proteins and lipids. It is a part of the cellular endomembrane system.. Golgi consists of cisternae arranged as stacks but physically unconnected': $i).
% 29.22/29.05  tff(decl_42701, type, golgi: $i).
% 29.22/29.05  tff(decl_42702, type, 'golgi complex': $i).
% 29.22/29.05  tff(decl_42703, type, 'golgi-complex': $i).
% 29.22/29.05  tff(decl_42704, type, 'golgi bodies': $i).
% 29.22/29.05  tff(decl_42705, type, 'golgi-bodies': $i).
% 29.22/29.05  tff(decl_42706, type, dictyosome: $i).
% 29.22/29.05  tff(decl_42707, type, 'apparatus of golgi': $i).
% 29.22/29.05  tff(decl_42708, type, 'golgi apparatus': $i).
% 29.22/29.05  tff(decl_42709, type, 'golgi-apparatus': $i).
% 29.22/29.05  tff(decl_42710, type, fn_golgi_apparatus_1: $i > $i).
% 29.22/29.05  tff(decl_42711, type, fn_golgi_apparatus_2: $i > $i).
% 29.22/29.05  tff(decl_42712, type, fn_golgi_apparatus_3: $i > $i).
% 29.22/29.05  tff(decl_42713, type, fn_golgi_apparatus_4: $i > $i).
% 29.22/29.05  tff(decl_42714, type, fn_golgi_apparatus_6: $i > $i).
% 29.22/29.05  tff(decl_42715, type, fn_golgi_apparatus_7: $i > $i).
% 29.22/29.05  tff(decl_42716, type, fn_golgi_apparatus_9: $i > $i).
% 29.22/29.05  tff(decl_42717, type, fn_golgi_apparatus_12: $i > $i).
% 29.22/29.05  tff(decl_42718, type, fn_golgi_apparatus_13: $i > $i).
% 29.22/29.05  tff(decl_42719, type, fn_golgi_apparatus_14: $i > $i).
% 29.22/29.05  tff(decl_42720, type, fn_golgi_apparatus_16: $i > $i).
% 29.22/29.05  tff(decl_42721, type, fn_golgi_apparatus_17: $i > $i).
% 29.22/29.05  tff(decl_42722, type, fn_golgi_apparatus_18: $i > $i).
% 29.22/29.05  tff(decl_42723, type, fn_golgi_apparatus_19: $i > $i).
% 29.22/29.05  tff(decl_42724, type, fn_golgi_apparatus_20: $i > $i).
% 29.22/29.05  tff(decl_42725, type, fn_golgi_apparatus_21: $i > $i).
% 29.22/29.05  tff(decl_42726, type, fn_golgi_apparatus_23: $i > $i).
% 29.22/29.05  tff(decl_42727, type, fn_golgi_apparatus_24: $i > $i).
% 29.22/29.05  tff(decl_42728, type, fn_golgi_apparatus_25: $i > $i).
% 29.22/29.05  tff(decl_42729, type, fn_golgi_apparatus_26: $i > $i).
% 29.22/29.05  tff(decl_42730, type, fn_golgi_apparatus_27: $i > $i).
% 29.22/29.05  tff(decl_42731, type, fn_golgi_apparatus_28: $i > $i).
% 29.22/29.05  tff(decl_42732, type, fn_golgi_apparatus_29: $i > $i).
% 29.22/29.05  tff(decl_42733, type, fn_golgi_apparatus_30: $i > $i).
% 29.22/29.05  tff(decl_42734, type, fn_golgi_apparatus_31: $i > $i).
% 29.22/29.05  tff(decl_42735, type, fn_golgi_apparatus_32: $i > $i).
% 29.22/29.05  tff(decl_42736, type, fn_golgi_apparatus_33: $i > $i).
% 29.22/29.05  tff(decl_42737, type, fn_golgi_apparatus_34: $i > $i).
% 29.22/29.05  tff(decl_42738, type, fn_golgi_apparatus_35: $i > $i).
% 29.22/29.05  tff(decl_42739, type, fn_golgi_apparatus_36: $i > $i).
% 29.22/29.05  tff(decl_42740, type, fn_golgi_apparatus_37: $i > $i).
% 29.22/29.05  tff(decl_42741, type, fn_golgi_apparatus_38: $i > $i).
% 29.22/29.05  tff(decl_42742, type, fn_golgi_apparatus_39: $i > $i).
% 29.22/29.05  tff(decl_42743, type, fn_golgi_apparatus_40: $i > $i).
% 29.22/29.05  tff(decl_42744, type, fn_golgi_apparatus_41: $i > $i).
% 29.22/29.05  tff(decl_42745, type, fn_golgi_apparatus_42: $i > $i).
% 29.22/29.05  tff(decl_42746, type, fn_golgi_apparatus_43: $i > $i).
% 29.22/29.05  tff(decl_42747, type, fn_golgi_apparatus_44: $i > $i).
% 29.22/29.05  tff(decl_42748, type, fn_golgi_apparatus_45: $i > $i).
% 29.22/29.05  tff(decl_42749, type, fn_golgi_apparatus_46: $i > $i).
% 29.22/29.05  tff(decl_42750, type, fn_golgi_apparatus_47: $i > $i).
% 29.22/29.05  tff(decl_42751, type, fn_golgi_apparatus_48: $i > $i).
% 29.22/29.05  tff(decl_42752, type, fn_golgi_apparatus_49: $i > $i).
% 29.22/29.05  tff(decl_42753, type, fn_golgi_apparatus_50: $i > $i).
% 29.22/29.05  tff(decl_42754, type, fn_golgi_apparatus_51: $i > $i).
% 29.22/29.05  tff(decl_42755, type, fn_golgi_apparatus_52: $i > $i).
% 29.22/29.05  tff(decl_42756, type, fn_golgi_apparatus_53: $i > $i).
% 29.22/29.05  tff(decl_42757, type, fn_golgi_apparatus_54: $i > $i).
% 29.22/29.05  tff(decl_42758, type, fn_golgi_apparatus_55: $i > $i).
% 29.22/29.05  tff(decl_42759, type, fn_golgi_apparatus_56: $i > $i).
% 29.22/29.05  tff(decl_42760, type, fn_golgi_apparatus_57: $i > $i).
% 29.22/29.05  tff(decl_42761, type, fn_golgi_apparatus_58: $i > $i).
% 29.22/29.05  tff(decl_42762, type, fn_golgi_apparatus_59: $i > $i).
% 29.22/29.05  tff(decl_42763, type, fn_golgi_apparatus_60: $i > $i).
% 29.22/29.05  tff(decl_42764, type, fn_golgi_apparatus_61: $i > $i).
% 29.22/29.05  tff(decl_42765, type, fn_golgi_apparatus_62: $i > $i).
% 29.22/29.05  tff(decl_42766, type, fn_golgi_apparatus_63: $i > $i).
% 29.22/29.05  tff(decl_42767, type, fn_golgi_apparatus_64: $i > $i).
% 29.22/29.05  tff(decl_42768, type, fn_golgi_apparatus_66: $i > $i).
% 29.22/29.05  tff(decl_42769, type, fn_golgi_apparatus_67: $i > $i).
% 29.22/29.05  tff(decl_42770, type, fn_golgi_apparatus_68: $i > $i).
% 29.22/29.05  tff(decl_42771, type, fn_golgi_apparatus_69: $i > $i).
% 29.22/29.05  tff(decl_42772, type, fn_golgi_apparatus_70: $i > $i).
% 29.22/29.05  tff(decl_42773, type, fn_golgi_apparatus_71: $i > $i).
% 29.22/29.05  tff(decl_42774, type, fn_golgi_apparatus_72: $i > $i).
% 29.22/29.05  tff(decl_42775, type, fn_golgi_apparatus_73: $i > $i).
% 29.22/29.05  tff(decl_42776, type, fn_golgi_apparatus_74: $i > $i).
% 29.22/29.05  tff(decl_42777, type, fn_golgi_apparatus_75: $i > $i).
% 29.22/29.05  tff(decl_42778, type, fn_golgi_apparatus_76: $i > $i).
% 29.22/29.05  tff(decl_42779, type, fn_golgi_apparatus_77: $i > $i).
% 29.22/29.05  tff(decl_42780, type, fn_golgi_apparatus_78: $i > $i).
% 29.22/29.05  tff(decl_42781, type, fn_golgi_apparatus_79: $i > $i).
% 29.22/29.05  tff(decl_42782, type, fn_golgi_apparatus_80: $i > $i).
% 29.22/29.05  tff(decl_42783, type, fn_golgi_apparatus_81: $i > $i).
% 29.22/29.05  tff(decl_42784, type, fn_golgi_apparatus_83: $i > $i).
% 29.22/29.05  tff(decl_42785, type, fn_golgi_apparatus_84: $i > $i).
% 29.22/29.05  tff(decl_42786, type, fn_golgi_apparatus_85: $i > $i).
% 29.22/29.05  tff(decl_42787, type, fn_golgi_apparatus_94: $i > $i).
% 29.22/29.05  tff(decl_42788, type, fn_golgi_apparatus_95: $i > $i).
% 29.22/29.05  tff(decl_42789, type, fn_golgi_apparatus_96: $i > $i).
% 29.22/29.05  tff(decl_42790, type, fn_golgi_apparatus_97: $i > $i).
% 29.22/29.05  tff(decl_42791, type, fn_golgi_apparatus_98: $i > $i).
% 29.22/29.05  tff(decl_42792, type, fn_golgi_apparatus_99: $i > $i).
% 29.22/29.05  tff(decl_42793, type, fn_golgi_apparatus_100: $i > $i).
% 29.22/29.05  tff(decl_42794, type, fn_golgi_apparatus_101: $i > $i).
% 29.22/29.05  tff(decl_42795, type, fn_golgi_apparatus_102: $i > $i).
% 29.22/29.05  tff(decl_42796, type, fn_golgi_apparatus_103: $i > $i).
% 29.22/29.05  tff(decl_42797, type, fn_golgi_apparatus_104: $i > $i).
% 29.22/29.05  tff(decl_42798, type, fn_golgi_apparatus_105: $i > $i).
% 29.22/29.05  tff(decl_42799, type, fn_golgi_apparatus_106: $i > $i).
% 29.22/29.05  tff(decl_42800, type, fn_golgi_apparatus_107: $i > $i).
% 29.22/29.05  tff(decl_42801, type, fn_trans_face_4: $i > $i).
% 29.22/29.05  tff(decl_42802, type, fn_product_2: $i > $i).
% 29.22/29.05  tff(decl_42803, type, cisterna_0: $i).
% 29.22/29.05  tff(decl_42804, type, 'Gonad': $i).
% 29.22/29.05  tff(decl_42805, type, 'In most animals, the organ that produces either eggs or sperm.': $i).
% 29.22/29.05  tff(decl_42806, type, 'sex organ': $i).
% 29.22/29.05  tff(decl_42807, type, 'sex-organ': $i).
% 29.22/29.05  tff(decl_42808, type, gonad: $i).
% 29.22/29.05  tff(decl_42809, type, 'Gonadotropin-Releasing-Hormone': $i).
% 29.22/29.05  tff(decl_42810, type, 'A tropic peptide hormone produced and released by the hypothalamus and responsible for the release of FSH and LH from the anterior pituitary.': $i).
% 29.22/29.05  tff(decl_42811, type, gnrh: $i).
% 29.22/29.05  tff(decl_42812, type, 'gonadotropin releasing hormone': $i).
% 29.22/29.05  tff(decl_42813, type, 'gonadotropin-releasing hormone': $i).
% 29.22/29.05  tff(decl_42814, type, 'gonadotropin-releasing-hormone': $i).
% 29.22/29.05  tff(decl_42815, type, gonadotropin_role_1: $i > $o).
% 29.22/29.05  tff(decl_42816, type, 'Gonadotropin-Role': $i).
% 29.22/29.05  tff(decl_42817, type, 'When a molecule functions as a hormone which causes gonadal growth.': $i).
% 29.22/29.05  tff(decl_42818, type, 'role of gonadotropin': $i).
% 29.22/29.05  tff(decl_42819, type, 'gonadotropin role': $i).
% 29.22/29.05  tff(decl_42820, type, 'gonadotropin-role': $i).
% 29.22/29.05  tff(decl_42821, type, 'Gonorrhea': $i).
% 29.22/29.05  tff(decl_42822, type, 'A sexually transmitted infection caused by the bacterium Neisseria gonorrhoeae.': $i).
% 29.22/29.05  tff(decl_42823, type, 'the clap': $i).
% 29.22/29.05  tff(decl_42824, type, 'the-clap': $i).
% 29.22/29.05  tff(decl_42825, type, gonorrhea: $i).
% 29.22/29.05  tff(decl_42826, type, grade_1: $i > $o).
% 29.22/29.05  tff(decl_42827, type, 'Grade': $i).
% 29.22/29.05  tff(decl_42828, type, 'A group of organisms that share a key adaptation or a similar level of organizational complexity.': $i).
% 29.22/29.05  tff(decl_42829, type, grade: $i).
% 29.22/29.05  tff(decl_42830, type, graded_potential_1: $i > $o).
% 29.22/29.05  tff(decl_42831, type, 'Graded-Potential': $i).
% 29.22/29.05  tff(decl_42832, type, 'A change in the voltage across the membrane that is proportional to the strength of the stimulus.': $i).
% 29.22/29.05  tff(decl_42833, type, 'graded potential': $i).
% 29.22/29.05  tff(decl_42834, type, 'graded-potential': $i).
% 29.22/29.05  tff(decl_42835, type, receptor_potential_1: $i > $o).
% 29.22/29.05  tff(decl_42836, type, 'Gradient': $i).
% 29.22/29.05  tff(decl_42837, type, 'A graded change in the magnitude of some physical quantity or dimension.': $i).
% 29.22/29.05  tff(decl_42838, type, gradient: $i).
% 29.22/29.05  tff(decl_42839, type, 'Gradualism-Theory': $i).
% 29.22/29.05  tff(decl_42840, type, 'The theory that changes in lineages occur due to slow but continuous processes.': $i).
% 29.22/29.05  tff(decl_42841, type, 'gradualism theory': $i).
% 29.22/29.05  tff(decl_42842, type, 'gradualism-theory': $i).
% 29.22/29.05  tff(decl_42843, type, 'Gram-Negative-Bacteria': $i).
% 29.22/29.05  tff(decl_42844, type, 'Bacteria that do not absorb the crystal violet dye of the Gram stain and thus appear reddish or pink after counterstaining step of the Gram staining protocol. Gram-negative bacteria have an outer membrane that prevents the dye from adhering to the cell wall.': $i).
% 29.22/29.05  tff(decl_42845, type, 'gram negative bacterium': $i).
% 29.22/29.05  tff(decl_42846, type, 'gram-negative bacterium': $i).
% 29.22/29.05  tff(decl_42847, type, 'Gram-Positive-Bacteria': $i).
% 29.22/29.05  tff(decl_42848, type, 'Bacteria whose cell walls absorb the crystal violet dye of the Gram stain and appear dark blue or violet after the Gram staining protocol. Gram-positive bacteria do not have an outer membrane that prevents the dye from adhering to the cell wall.': $i).
% 29.22/29.05  tff(decl_42849, type, 'gram positive bacterium': $i).
% 29.22/29.05  tff(decl_42850, type, 'gram-positive bacterium': $i).
% 29.22/29.05  tff(decl_42851, type, 'gram-positive-bacteria': $i).
% 29.22/29.05  tff(decl_42852, type, 'Gram-Stain': $i).
% 29.22/29.05  tff(decl_42853, type, 'A staining method that distinguishes between two different kinds of bacterial cell walls.  The Gram staining protocol has two steps:  (1) staining with crystal violet dye; and (2) destaining with safranin or carbol fuchsin. After the staining protocol, Gram-negative bacteria appear reddish or pink, while Gram-positive bacteria are dark blue or violet.': $i).
% 29.22/29.05  tff(decl_42854, type, 'stain of gram': $i).
% 29.22/29.05  tff(decl_42855, type, 'gram stain': $i).
% 29.22/29.05  tff(decl_42856, type, 'gram-stain': $i).
% 29.22/29.05  tff(decl_42857, type, 'Granum': $i).
% 29.22/29.05  tff(decl_42858, type, 'Granum is a part of a chloroplast containing a stack of thylakoids.': $i).
% 29.22/29.05  tff(decl_42859, type, 'chloroplast membranous system': $i).
% 29.22/29.05  tff(decl_42860, type, 'chloroplast-membranous-system': $i).
% 29.22/29.05  tff(decl_42861, type, grana: $i).
% 29.22/29.05  tff(decl_42862, type, granum: $i).
% 29.22/29.05  tff(decl_42863, type, thylakoid_0: $i).
% 29.22/29.05  tff(decl_42864, type, 'Graphical-Representation': $i).
% 29.22/29.05  tff(decl_42865, type, 'A method of representing data in a graph, chart or image.': $i).
% 29.22/29.05  tff(decl_42866, type, 'graphical representation': $i).
% 29.22/29.05  tff(decl_42867, type, 'graphical-representation': $i).
% 29.22/29.05  tff(decl_42868, type, grass_1: $i > $o).
% 29.22/29.05  tff(decl_42869, type, 'Grass': $i).
% 29.22/29.05  tff(decl_42870, type, 'Plants that are typically short with long narrow leaves, that grow wild or are cultivated on lawns and pasture, and as a fodder crop.': $i).
% 29.22/29.05  tff(decl_42871, type, grass: $i).
% 29.22/29.05  tff(decl_42872, type, monocot_1: $i > $o).
% 29.22/29.05  tff(decl_42873, type, fn_grass_2: $i > $i).
% 29.22/29.05  tff(decl_42874, type, fn_grass_4: $i > $i).
% 29.22/29.05  tff(decl_42875, type, fn_grass_5: $i > $i).
% 29.22/29.05  tff(decl_42876, type, fn_grass_6: $i > $i).
% 29.22/29.05  tff(decl_42877, type, fn_grass_7: $i > $i).
% 29.22/29.05  tff(decl_42878, type, fn_grass_8: $i > $i).
% 29.22/29.05  tff(decl_42879, type, fn_grass_9: $i > $i).
% 29.22/29.05  tff(decl_42880, type, fn_grass_10: $i > $i).
% 29.22/29.05  tff(decl_42881, type, fn_grass_11: $i > $i).
% 29.22/29.05  tff(decl_42882, type, fn_grass_12: $i > $i).
% 29.22/29.05  tff(decl_42883, type, fn_grass_13: $i > $i).
% 29.22/29.05  tff(decl_42884, type, fn_grass_14: $i > $i).
% 29.22/29.05  tff(decl_42885, type, fn_grass_15: $i > $i).
% 29.22/29.05  tff(decl_42886, type, fn_grass_16: $i > $i).
% 29.22/29.05  tff(decl_42887, type, fn_grass_17: $i > $i).
% 29.22/29.05  tff(decl_42888, type, fn_grass_18: $i > $i).
% 29.22/29.05  tff(decl_42889, type, fn_grass_19: $i > $i).
% 29.22/29.05  tff(decl_42890, type, fn_grass_20: $i > $i).
% 29.22/29.05  tff(decl_42891, type, fn_grass_21: $i > $i).
% 29.22/29.05  tff(decl_42892, type, fn_grass_22: $i > $i).
% 29.22/29.05  tff(decl_42893, type, plant_0: $i).
% 29.22/29.05  tff(decl_42894, type, fn_grass_23: $i > $i).
% 29.22/29.05  tff(decl_42895, type, fn_grass_24: $i > $i).
% 29.22/29.05  tff(decl_42896, type, 'Grasshopper': $i).
% 29.22/29.05  tff(decl_42897, type, 'An insect in the order Orthoptera, similar to crickets and katydids. Grasshoppers are herbivores and feed on a wide variety of plants.': $i).
% 29.22/29.05  tff(decl_42898, type, grasshopper: $i).
% 29.22/29.05  tff(decl_42899, type, fn_grasshopper_1: $i > $i).
% 29.22/29.05  tff(decl_42900, type, fn_grasshopper_2: $i > $i).
% 29.22/29.05  tff(decl_42901, type, mandible_1: $i > $o).
% 29.22/29.05  tff(decl_42902, type, fn_grasshopper_3: $i > $i).
% 29.22/29.05  tff(decl_42903, type, fn_grasshopper_4: $i > $i).
% 29.22/29.05  tff(decl_42904, type, fn_grasshopper_5: $i > $i).
% 29.22/29.05  tff(decl_42905, type, fn_grasshopper_6: $i > $i).
% 29.22/29.05  tff(decl_42906, type, fn_grasshopper_7: $i > $i).
% 29.22/29.05  tff(decl_42907, type, fn_grasshopper_8: $i > $i).
% 29.22/29.05  tff(decl_42908, type, fn_grasshopper_9: $i > $i).
% 29.22/29.05  tff(decl_42909, type, fn_grasshopper_10: $i > $i).
% 29.22/29.05  tff(decl_42910, type, fn_grasshopper_11: $i > $i).
% 29.22/29.05  tff(decl_42911, type, fn_grasshopper_12: $i > $i).
% 29.22/29.05  tff(decl_42912, type, fn_grasshopper_13: $i > $i).
% 29.22/29.05  tff(decl_42913, type, fn_grasshopper_14: $i > $i).
% 29.22/29.05  tff(decl_42914, type, fn_grasshopper_15: $i > $i).
% 29.22/29.05  tff(decl_42915, type, fn_grasshopper_16: $i > $i).
% 29.22/29.05  tff(decl_42916, type, fn_grasshopper_17: $i > $i).
% 29.22/29.05  tff(decl_42917, type, fn_grasshopper_18: $i > $i).
% 29.22/29.05  tff(decl_42918, type, fn_grasshopper_19: $i > $i).
% 29.22/29.05  tff(decl_42919, type, fn_grasshopper_20: $i > $i).
% 29.22/29.05  tff(decl_42920, type, fn_grasshopper_21: $i > $i).
% 29.22/29.05  tff(decl_42921, type, fn_grasshopper_23: $i > $i).
% 29.22/29.05  tff(decl_42922, type, fn_grasshopper_24: $i > $i).
% 29.22/29.05  tff(decl_42923, type, fn_grasshopper_33: $i > $i).
% 29.22/29.05  tff(decl_42924, type, fn_grasshopper_34: $i > $i).
% 29.22/29.05  tff(decl_42925, type, fn_grasshopper_35: $i > $i).
% 29.22/29.05  tff(decl_42926, type, fn_grasshopper_36: $i > $i).
% 29.22/29.05  tff(decl_42927, type, fn_grasshopper_37: $i > $i).
% 29.22/29.05  tff(decl_42928, type, fn_grasshopper_38: $i > $i).
% 29.22/29.05  tff(decl_42929, type, fn_grasshopper_39: $i > $i).
% 29.22/29.05  tff(decl_42930, type, fn_grasshopper_40: $i > $i).
% 29.22/29.05  tff(decl_42931, type, fn_grasshopper_41: $i > $i).
% 29.22/29.05  tff(decl_42932, type, fn_grasshopper_42: $i > $i).
% 29.22/29.05  tff(decl_42933, type, fn_grasshopper_43: $i > $i).
% 29.22/29.05  tff(decl_42934, type, fn_grasshopper_digestive_system_5: $i > $i).
% 29.22/29.05  tff(decl_42935, type, fn_grasshopper_digestive_system_9: $i > $i).
% 29.22/29.05  tff(decl_42936, type, fn_grasshopper_digestive_system_6: $i > $i).
% 29.22/29.05  tff(decl_42937, type, fn_grasshopper_digestive_system_7: $i > $i).
% 29.22/29.05  tff(decl_42938, type, fn_grasshopper_digestive_system_10: $i > $i).
% 29.22/29.05  tff(decl_42939, type, fn_grasshopper_digestive_system_8: $i > $i).
% 29.22/29.05  tff(decl_42940, type, fn_grasshopper_digestive_system_4: $i > $i).
% 29.22/29.05  tff(decl_42941, type, fn_grasshopper_digestive_system_12: $i > $i).
% 29.22/29.05  tff(decl_42942, type, fn_grasshopper_digestive_system_3: $i > $i).
% 29.22/29.05  tff(decl_42943, type, fn_grasshopper_digestive_system_11: $i > $i).
% 29.22/29.05  tff(decl_42944, type, mandible_0: $i).
% 29.22/29.05  tff(decl_42945, type, 'Grasshopper-Digestive-System': $i).
% 29.22/29.05  tff(decl_42946, type, 'A system of organs in a grasshopper\\s body which is responsible for the digestion and absorption of nutrients from food.': $i).
% 29.22/29.05  tff(decl_42947, type, 'grasshopper digestive system': $i).
% 29.22/29.05  tff(decl_42948, type, 'grasshopper-digestive-system': $i).
% 29.22/29.05  tff(decl_42949, type, fn_grasshopper_digestive_system_1: $i > $i).
% 29.22/29.05  tff(decl_42950, type, grasshopper_homeotic_gene_1: $i > $o).
% 29.22/29.05  tff(decl_42951, type, 'Grasshopper-Homeotic-Gene': $i).
% 29.22/29.05  tff(decl_42952, type, 'Homeotic gene present in grasshopper.': $i).
% 29.22/29.05  tff(decl_42953, type, 'grasshopper homeotic gene': $i).
% 29.22/29.05  tff(decl_42954, type, 'grasshopper-homeotic-gene': $i).
% 29.22/29.05  tff(decl_42955, type, grasshopper_homeotic_gene_mutation_1: $i > $o).
% 29.22/29.05  tff(decl_42956, type, 'Grasshopper-Homeotic-Gene-Mutation': $i).
% 29.22/29.05  tff(decl_42957, type, 'Mutation of homeotic gene of grasshopper.': $i).
% 29.22/29.05  tff(decl_42958, type, 'grasshopper homeotic gene mutation': $i).
% 29.22/29.05  tff(decl_42959, type, 'grasshopper-homeotic-gene-mutation': $i).
% 29.22/29.05  tff(decl_42960, type, fn_grasshopper_homeotic_gene_mutation_1: $i > $i).
% 29.22/29.05  tff(decl_42961, type, fn_grasshopper_homeotic_gene_mutation_2: $i > $i).
% 29.22/29.05  tff(decl_42962, type, fn_grasshopper_homeotic_gene_mutation_3: $i > $i).
% 29.22/29.05  tff(decl_42963, type, fn_grasshopper_homeotic_gene_mutation_4: $i > $i).
% 29.22/29.05  tff(decl_42964, type, fn_grasshopper_homeotic_gene_mutation_5: $i > $i).
% 29.22/29.05  tff(decl_42965, type, gravitropism_1: $i > $o).
% 29.22/29.05  tff(decl_42966, type, 'Gravitropism': $i).
% 29.22/29.05  tff(decl_42967, type, 'The response of an organism to gravity. Positive gravitropism is movement along the direction of the pull of gravity, and negative gravitropism is movement in the opposite direction.': $i).
% 29.22/29.05  tff(decl_42968, type, gravitropism: $i).
% 29.22/29.05  tff(decl_42969, type, tropism_1: $i > $o).
% 29.22/29.05  tff(decl_42970, type, phototropism_1: $i > $o).
% 29.22/29.05  tff(decl_42971, type, thigmotropism_1: $i > $o).
% 29.22/29.05  tff(decl_42972, type, fn_gravitropism_1: $i > $i).
% 29.22/29.05  tff(decl_42973, type, 'Gravity': $i).
% 29.22/29.05  tff(decl_42974, type, 'The force that attracts physical bodies toward the earth\\s center, or toward any other physical body that has mass.': $i).
% 29.22/29.05  tff(decl_42975, type, gravity: $i).
% 29.22/29.05  tff(decl_42976, type, gray_crescent_1: $i > $o).
% 29.22/29.05  tff(decl_42977, type, 'Gray-Crescent': $i).
% 29.22/29.05  tff(decl_42978, type, 'In animal development, a pale gray, crescent-shaped region of cytoplasm that becomes exposed after the cortical rotation, located near the equator of an egg on the side opposite sperm entry. It marks the future dorsal side of the embryo.': $i).
% 29.22/29.05  tff(decl_42979, type, 'crescent of gray': $i).
% 29.22/29.05  tff(decl_42980, type, 'gray crescent': $i).
% 29.22/29.05  tff(decl_42981, type, 'gray-crescent': $i).
% 29.22/29.05  tff(decl_42982, type, 'Gray-Matter': $i).
% 29.22/29.05  tff(decl_42983, type, 'A major component of the central nervous system, consisting of the cell bodies of neurons, capillaries, and glial cells.': $i).
% 29.22/29.05  tff(decl_42984, type, 'matter of gray': $i).
% 29.22/29.05  tff(decl_42985, type, 'gray matter': $i).
% 29.22/29.05  tff(decl_42986, type, 'gray-matter': $i).
% 29.22/29.05  tff(decl_42987, type, 'Great-Auk': $i).
% 29.22/29.05  tff(decl_42988, type, 'A large, flightless bird that was driven to extinction in the mid-19th century by human hunting. Its scientific name is Pinguinus impennis.': $i).
% 29.22/29.05  tff(decl_42989, type, auk: $i).
% 29.22/29.05  tff(decl_42990, type, 'great auk': $i).
% 29.22/29.05  tff(decl_42991, type, 'great-auk': $i).
% 29.22/29.05  tff(decl_42992, type, seabird_1: $i > $o).
% 29.22/29.05  tff(decl_42993, type, green_algae_1: $i > $o).
% 29.22/29.05  tff(decl_42994, type, 'Green-Algae': $i).
% 29.22/29.05  tff(decl_42995, type, 'A paraphyletic grouping of photosynthetic protists whose chloroplasts are similar to those of land plants. Some green algae are more closely related to land plants than to other green algae.': $i).
% 29.22/29.05  tff(decl_42996, type, 'algae of green': $i).
% 29.22/29.05  tff(decl_42997, type, fn_green_light_5: $i > $i).
% 29.22/29.05  tff(decl_42998, type, 'Green-Light': $i).
% 29.22/29.05  tff(decl_42999, type, 'The portion of the electromagnetic spectrum that can be detected as green by the human eye, ranging in wavelength from about 495 nm to 570 nm.': $i).
% 29.22/29.05  tff(decl_43000, type, 'light of green': $i).
% 29.22/29.05  tff(decl_43001, type, 'green light': $i).
% 29.22/29.05  tff(decl_43002, type, 'green-light': $i).
% 29.22/29.05  tff(decl_43003, type, fn_green_light_3: $i > $i).
% 29.22/29.05  tff(decl_43004, type, fn_green_light_4: $i > $i).
% 29.22/29.05  tff(decl_43005, type, fn_green_light_8: $i > $i).
% 29.22/29.05  tff(decl_43006, type, "560.0e0": $i).
% 29.22/29.05  tff(decl_43007, type, fn_green_light_9: $i > $i).
% 29.22/29.05  tff(decl_43008, type, greenhouse_effect_1: $i > $o).
% 29.22/29.05  tff(decl_43009, type, 'Greenhouse-Effect': $i).
% 29.22/29.05  tff(decl_43010, type, 'A process by which solar radiation is absorbed at atmospheric gases and reradiated back towards the Earth, resulting in warmer temperatures than would occur in the absence of such atmospheric gases.': $i).
% 29.22/29.05  tff(decl_43011, type, 'effect of greenhouse': $i).
% 29.22/29.05  tff(decl_43012, type, 'greenhouse effect': $i).
% 29.22/29.05  tff(decl_43013, type, 'greenhouse-effect': $i).
% 29.22/29.05  tff(decl_43014, type, fn_greenhouse_effect_1: $i > $i).
% 29.22/29.05  tff(decl_43015, type, fn_greenhouse_effect_2: $i > $i).
% 29.22/29.05  tff(decl_43016, type, retain_1: $i > $o).
% 29.22/29.05  tff(decl_43017, type, fn_greenhouse_effect_3: $i > $i).
% 29.22/29.05  tff(decl_43018, type, 'Greenhouse-Gas': $i).
% 29.22/29.05  tff(decl_43019, type, 'Atmospheric gas that traps infrared radiation and causes heating of the atmosphere, resulting in global warming.': $i).
% 29.22/29.05  tff(decl_43020, type, 'gas of greenhouse': $i).
% 29.22/29.05  tff(decl_43021, type, 'greenhouse gas': $i).
% 29.22/29.05  tff(decl_43022, type, 'greenhouse-gas': $i).
% 29.22/29.05  tff(decl_43023, type, 'Greylag-Geese': $i).
% 29.22/29.05  tff(decl_43024, type, 'Geese of the species Anser anser, notable as the birds used in studies of behavioral imprinting.': $i).
% 29.22/29.05  tff(decl_43025, type, 'greylag goose': $i).
% 29.22/29.05  tff(decl_43026, type, 'greylag-geese': $i).
% 29.22/29.05  tff(decl_43027, type, grind_1: $i > $o).
% 29.22/29.05  tff(decl_43028, type, 'Grind': $i).
% 29.22/29.05  tff(decl_43029, type, 'To crush a substance to very small particles or powder.': $i).
% 29.22/29.05  tff(decl_43030, type, grind: $i).
% 29.22/29.05  tff(decl_43031, type, 'Gross-Primary-Production': $i).
% 29.22/29.05  tff(decl_43032, type, 'Gross primary production is the total rate of biomass produced by primary producers in an ecosystem.': $i).
% 29.22/29.05  tff(decl_43033, type, 'gross primary production': $i).
% 29.22/29.05  tff(decl_43034, type, 'gross-primary-production': $i).
% 29.22/29.05  tff(decl_43035, type, 'Ground': $i).
% 29.22/29.05  tff(decl_43036, type, 'The solid surface of the earth is referred to as Ground.': $i).
% 29.22/29.05  tff(decl_43037, type, ground: $i).
% 29.22/29.05  tff(decl_43038, type, 'Ground-Tissue': $i).
% 29.22/29.05  tff(decl_43039, type, 'In plants, tissues that are not part of the vascular bundle or dermal system. Ground tissue has a variety of functions, including photosynthesis, support, and storage.': $i).
% 29.22/29.05  tff(decl_43040, type, 'tissue of ground': $i).
% 29.22/29.05  tff(decl_43041, type, 'ground tissue': $i).
% 29.22/29.05  tff(decl_43042, type, 'ground-tissue': $i).
% 29.22/29.05  tff(decl_43043, type, 'Ground-Tissue-System': $i).
% 29.22/29.05  tff(decl_43044, type, 'Ground tissue system is responsible for most of the plants metabolic functions, is located between the dermal tissue and the vascular tissue in each organ. Tissues that are neither dermal nor vascular are part of the ground tissue system.': $i).
% 29.22/29.05  tff(decl_43045, type, 'ground tissue system': $i).
% 29.22/29.05  tff(decl_43046, type, 'ground-tissue-system': $i).
% 29.22/29.05  tff(decl_43047, type, 'Groundwater': $i).
% 29.22/29.05  tff(decl_43048, type, 'Groundwater is water located beneath the surface of ground': $i).
% 29.22/29.05  tff(decl_43049, type, groundwater: $i).
% 29.22/29.05  tff(decl_43050, type, 'Group': $i).
% 29.22/29.05  tff(decl_43051, type, 'a relatively small organization of Roles': $i).
% 29.22/29.05  tff(decl_43052, type, 'working group': $i).
% 29.22/29.05  tff(decl_43053, type, working_group: $i).
% 29.22/29.05  tff(decl_43054, type, 'working party': $i).
% 29.22/29.05  tff(decl_43055, type, working_party: $i).
% 29.22/29.05  tff(decl_43056, type, 'Group-Node': $i).
% 29.22/29.05  tff(decl_43057, type, 'node of group': $i).
% 29.22/29.05  tff(decl_43058, type, 'group node': $i).
% 29.22/29.05  tff(decl_43059, type, 'group-node': $i).
% 29.22/29.05  tff(decl_43060, type, grouping_activity_1: $i > $o).
% 29.22/29.05  tff(decl_43061, type, 'Grouping-Activity': $i).
% 29.22/29.05  tff(decl_43062, type, 'An activity which relates to the grouping or arrangement of persons or things.': $i).
% 29.22/29.05  tff(decl_43063, type, 'activity of grouping': $i).
% 29.22/29.05  tff(decl_43064, type, 'grouping activity': $i).
% 29.22/29.05  tff(decl_43065, type, 'grouping-activity': $i).
% 29.22/29.05  tff(decl_43066, type, 'Grow': $i).
% 29.22/29.05  tff(decl_43067, type, 'Increase or become larger in size.': $i).
% 29.22/29.05  tff(decl_43068, type, 'Growth': $i).
% 29.22/29.05  tff(decl_43069, type, mature: $i).
% 29.22/29.05  tff(decl_43070, type, maturate: $i).
% 29.22/29.05  tff(decl_43071, type, growth: $i).
% 29.22/29.05  tff(decl_43072, type, growing: $i).
% 29.22/29.05  tff(decl_43073, type, maturation: $i).
% 29.22/29.05  tff(decl_43074, type, ontogeny: $i).
% 29.22/29.05  tff(decl_43075, type, ontogenesis: $i).
% 29.22/29.05  tff(decl_43076, type, increase: $i).
% 29.22/29.05  tff(decl_43077, type, increment: $i).
% 29.22/29.05  tff(decl_43078, type, 'Growth-Cone': $i).
% 29.22/29.05  tff(decl_43079, type, 'In a neuron, the responsive region at the leading edge of the growing axon.': $i).
% 29.22/29.05  tff(decl_43080, type, 'cone of growth': $i).
% 29.22/29.05  tff(decl_43081, type, 'growth cone': $i).
% 29.22/29.05  tff(decl_43082, type, 'growth-cone': $i).
% 29.22/29.05  tff(decl_43083, type, 'Growth-Factor': $i).
% 29.22/29.05  tff(decl_43084, type, 'A local regulator that acts on nearby cells to stimulate cell proliferation and differentiation.': $i).
% 29.22/29.05  tff(decl_43085, type, 'paracrine growth factor': $i).
% 29.22/29.05  tff(decl_43086, type, 'factor of growth': $i).
% 29.22/29.05  tff(decl_43087, type, 'growth factor': $i).
% 29.22/29.05  tff(decl_43088, type, 'growth-factor': $i).
% 29.22/29.05  tff(decl_43089, type, fn_growth_factor_1: $i > $i).
% 29.22/29.05  tff(decl_43090, type, 'Growth-Factor-Receptor': $i).
% 29.22/29.05  tff(decl_43091, type, 'A regulatory protein in the cell membrane or in the cell that binds to another molecule leading to a change in cell growth behavior.': $i).
% 29.22/29.05  tff(decl_43092, type, 'growth factor receptor': $i).
% 29.22/29.05  tff(decl_43093, type, 'growth-factor receptor': $i).
% 29.22/29.05  tff(decl_43094, type, 'growth-factor-receptor': $i).
% 29.22/29.05  tff(decl_43095, type, growth_factor_release_1: $i > $o).
% 29.22/29.05  tff(decl_43096, type, 'Growth-Factor-Release': $i).
% 29.22/29.05  tff(decl_43097, type, 'Process of cell releasing growth factor.': $i).
% 29.22/29.05  tff(decl_43098, type, 'growth factor release': $i).
% 29.22/29.05  tff(decl_43099, type, 'growth-factor-release': $i).
% 29.22/29.05  tff(decl_43100, type, fn_growth_factor_release_1: $i > $i).
% 29.22/29.05  tff(decl_43101, type, fn_growth_factor_release_2: $i > $i).
% 29.22/29.05  tff(decl_43102, type, fn_growth_factor_release_3: $i > $i).
% 29.22/29.05  tff(decl_43103, type, fn_growth_factor_release_4: $i > $i).
% 29.22/29.05  tff(decl_43104, type, fn_growth_factor_release_5: $i > $i).
% 29.22/29.05  tff(decl_43105, type, fn_growth_factor_release_6: $i > $i).
% 29.22/29.05  tff(decl_43106, type, 'Growth-Hormone': $i).
% 29.22/29.05  tff(decl_43107, type, 'A hormone of the anterior pituitary that causes body growth, cell growth, and cell regeneration in humans and some other animals.': $i).
% 29.22/29.05  tff(decl_43108, type, gh: $i).
% 29.22/29.05  tff(decl_43109, type, 'hormone of growth': $i).
% 29.22/29.05  tff(decl_43110, type, 'growth hormone': $i).
% 29.22/29.05  tff(decl_43111, type, 'growth-hormone': $i).
% 29.22/29.05  tff(decl_43112, type, 'GTP': $i).
% 29.22/29.05  tff(decl_43113, type, 'Major nucleoside triphosphate used in the synthesis of                 RNA and in some energy-transfer reactions.  Has a                 special role in microtubule assembly, protein                  synthesis, and cell signaling.': $i).
% 29.22/29.05  tff(decl_43114, type, 'A molecule which is structurally and functionally very similar to ATP. This molecule stores energy in the covalent bonds between phosphate groups, which when broken releases energy and can be used to make ATP or to directly power cell processes.': $i).
% 29.22/29.05  tff(decl_43115, type, 'guanosine triphosphate': $i).
% 29.22/29.05  tff(decl_43116, type, 'guanosine-triphosphate': $i).
% 29.22/29.05  tff(decl_43117, type, gtp: $i).
% 29.22/29.05  tff(decl_43118, type, fn_gtp_3: $i > $i).
% 29.22/29.05  tff(decl_43119, type, fn_gtp_4: $i > $i).
% 29.22/29.05  tff(decl_43120, type, fn_gtp_5: $i > $i).
% 29.22/29.05  tff(decl_43121, type, fn_gtp_6: $i > $i).
% 29.22/29.05  tff(decl_43122, type, fn_gtp_7: $i > $i).
% 29.22/29.05  tff(decl_43123, type, fn_gtp_8: $i > $i).
% 29.22/29.05  tff(decl_43124, type, fn_gtp_9: $i > $i).
% 29.22/29.05  tff(decl_43125, type, fn_gtp_10: $i > $i).
% 29.22/29.05  tff(decl_43126, type, fn_gtp_11: $i > $i).
% 29.22/29.05  tff(decl_43127, type, fn_gtp_12: $i > $i).
% 29.22/29.05  tff(decl_43128, type, fn_gtp_13: $i > $i).
% 29.22/29.05  tff(decl_43129, type, fn_gtp_14: $i > $i).
% 29.22/29.05  tff(decl_43130, type, fn_gtp_16: $i > $i).
% 29.22/29.05  tff(decl_43131, type, fn_gtp_22: $i > $i).
% 29.22/29.05  tff(decl_43132, type, fn_gtp_23: $i > $i).
% 29.22/29.05  tff(decl_43133, type, fn_gtp_24: $i > $i).
% 29.22/29.05  tff(decl_43134, type, fn_gtp_25: $i > $i).
% 29.22/29.05  tff(decl_43135, type, fn_gtp_26: $i > $i).
% 29.22/29.05  tff(decl_43136, type, fn_gtp_27: $i > $i).
% 29.22/29.05  tff(decl_43137, type, fn_gtp_28: $i > $i).
% 29.22/29.05  tff(decl_43138, type, fn_gtp_29: $i > $i).
% 29.22/29.05  tff(decl_43139, type, fn_gtp_30: $i > $i).
% 29.22/29.05  tff(decl_43140, type, fn_gtp_31: $i > $i).
% 29.22/29.05  tff(decl_43141, type, fn_gtp_32: $i > $i).
% 29.22/29.05  tff(decl_43142, type, fn_gtp_33: $i > $i).
% 29.22/29.05  tff(decl_43143, type, fn_gtp_34: $i > $i).
% 29.22/29.05  tff(decl_43144, type, fn_gtp_35: $i > $i).
% 29.22/29.05  tff(decl_43145, type, fn_gtp_36: $i > $i).
% 29.22/29.05  tff(decl_43146, type, fn_gtp_37: $i > $i).
% 29.22/29.05  tff(decl_43147, type, fn_gtp_38: $i > $i).
% 29.22/29.05  tff(decl_43148, type, fn_gtp_39: $i > $i).
% 29.22/29.05  tff(decl_43149, type, fn_gtp_40: $i > $i).
% 29.22/29.05  tff(decl_43150, type, fn_gtp_41: $i > $i).
% 29.22/29.05  tff(decl_43151, type, fn_gtp_2: $i > $i).
% 29.22/29.05  tff(decl_43152, type, fn_gtp_1: $i > $i).
% 29.22/29.05  tff(decl_43153, type, fn_nucleotide_12: $i > $i).
% 29.22/29.05  tff(decl_43154, type, fn_nucleoside_triphosphate_4: $i > $i).
% 29.22/29.05  tff(decl_43155, type, fn_nucleoside_triphosphate_2: $i > $i).
% 29.22/29.05  tff(decl_43156, type, fn_nucleoside_triphosphate_24: $i > $i).
% 29.22/29.05  tff(decl_43157, type, 'GTPase': $i).
% 29.22/29.05  tff(decl_43158, type, 'Enzymes which catalyze the hydrolysis of guanine triphosphate to guanine diphosphate.': $i).
% 29.22/29.05  tff(decl_43159, type, gtpase: $i).
% 29.22/29.05  tff(decl_43160, type, fn_gtpase_1: $i > $i).
% 29.22/29.05  tff(decl_43161, type, fn_gtpase_5: $i > $i).
% 29.22/29.05  tff(decl_43162, type, fn_gtpase_7: $i > $i).
% 29.22/29.05  tff(decl_43163, type, fn_phosphatase_6: $i > $i).
% 29.22/29.05  tff(decl_43164, type, 'Guanine': $i).
% 29.22/29.05  tff(decl_43165, type, 'One of the five most common nitrogenous bases which make up nucleotide monomers of nucleic acids. Guanine is present in both DNA and RNA.': $i).
% 29.22/29.05  tff(decl_43166, type, guanine: $i).
% 29.22/29.05  tff(decl_43167, type, 'Guanine-At-DNA-Strand': $i).
% 29.22/29.05  tff(decl_43168, type, 'Guanine(G) is a nucleobase (a purine derivative) which is present at DNA.': $i).
% 29.22/29.05  tff(decl_43169, type, 'guanine at dna strand': $i).
% 29.22/29.05  tff(decl_43170, type, 'guanine-at-dna-strand': $i).
% 29.22/29.05  tff(decl_43171, type, 'Guanine-At-DNA-Strand-Opposite-To-DNA-Strand': $i).
% 29.22/29.05  tff(decl_43172, type, 'Guanine is a nitrogenous base which is present at DNA strand and is present opposite to other DNA strand having Cytosine.': $i).
% 29.22/29.05  tff(decl_43173, type, 'guanine at dna strand opposite to dna strand': $i).
% 29.22/29.05  tff(decl_43174, type, 'guanine-at-dna-strand-opposite-to-dna-strand': $i).
% 29.22/29.05  tff(decl_43175, type, fn_guanine_at_dna_strand_opposite_to_rna_strand_3: $i > $i).
% 29.22/29.05  tff(decl_43176, type, fn_guanine_at_dna_strand_opposite_to_rna_strand_2: $i > $i).
% 29.22/29.05  tff(decl_43177, type, 'Guanine-At-DNA-Strand-Opposite-To-RNA-Strand': $i).
% 29.22/29.05  tff(decl_43178, type, 'Guanine is a nitrogenous base which is present at DNA strand and is present opposite to RNA strand having Cytosine.': $i).
% 29.22/29.05  tff(decl_43179, type, 'guanine at dna strand opposite to rna strand': $i).
% 29.22/29.05  tff(decl_43180, type, 'guanine-at-dna-strand-opposite-to-rna-strand': $i).
% 29.22/29.05  tff(decl_43181, type, fn_guanine_at_dna_strand_opposite_to_rna_strand_4: $i > $i).
% 29.22/29.05  tff(decl_43182, type, 'Guanine-At-RNA-Strand': $i).
% 29.22/29.05  tff(decl_43183, type, 'Guanine(G) is a nucleobase (a purine derivative) which is present at RNA.': $i).
% 29.22/29.05  tff(decl_43184, type, 'guanine at rna strand': $i).
% 29.22/29.05  tff(decl_43185, type, 'guanine-at-rna-strand': $i).
% 29.22/29.05  tff(decl_43186, type, 'Guanine-At-RNA-Strand-Opposite-To-DNA-Strand': $i).
% 29.22/29.05  tff(decl_43187, type, 'Guanine is a nitrogenous base which is present at RNA strand and is present opposite to other DNA strand having Cytosine.': $i).
% 29.22/29.05  tff(decl_43188, type, 'guanine at rna strand opposite to dna strand': $i).
% 29.22/29.05  tff(decl_43189, type, 'guanine-at-rna-strand-opposite-to-dna-strand': $i).
% 29.22/29.05  tff(decl_43190, type, fn_guanine_at_rna_strand_opposite_to_rna_strand_3: $i > $i).
% 29.22/29.05  tff(decl_43191, type, fn_guanine_at_rna_strand_opposite_to_rna_strand_4: $i > $i).
% 29.22/29.05  tff(decl_43192, type, 'Guanine-At-RNA-Strand-Opposite-To-RNA-Strand': $i).
% 29.22/29.05  tff(decl_43193, type, 'Guanine is a nitrogenous base which is present at RNA strand and is present opposite to other RNA strand having Cytosine.': $i).
% 29.22/29.05  tff(decl_43194, type, 'guanine at rna strand opposite to rna strand': $i).
% 29.22/29.05  tff(decl_43195, type, 'guanine-at-rna-strand-opposite-to-rna-strand': $i).
% 29.22/29.05  tff(decl_43196, type, fn_guanine_at_rna_strand_opposite_to_rna_strand_2: $i > $i).
% 29.22/29.05  tff(decl_43197, type, 'Guard-Cell': $i).
% 29.22/29.05  tff(decl_43198, type, 'In plants, one of two cells that surround a stoma and control the opening and closing of the stoma.': $i).
% 29.22/29.05  tff(decl_43199, type, 'guard cells': $i).
% 29.22/29.05  tff(decl_43200, type, 'guard-cells': $i).
% 29.22/29.05  tff(decl_43201, type, 'cell of guard': $i).
% 29.22/29.05  tff(decl_43202, type, 'guard cell': $i).
% 29.22/29.05  tff(decl_43203, type, 'guard-cell': $i).
% 29.22/29.05  tff(decl_43204, type, plant_transport_cell_1: $i > $o).
% 29.22/29.05  tff(decl_43205, type, fn_guard_cell_2: $i > $i).
% 29.22/29.05  tff(decl_43206, type, fn_guard_cell_3: $i > $i).
% 29.22/29.05  tff(decl_43207, type, fn_guard_cell_4: $i > $i).
% 29.22/29.05  tff(decl_43208, type, fn_guard_cell_5: $i > $i).
% 29.22/29.05  tff(decl_43209, type, fn_guard_cell_6: $i > $i).
% 29.22/29.05  tff(decl_43210, type, fn_guard_cell_7: $i > $i).
% 29.22/29.05  tff(decl_43211, type, fn_guard_cell_8: $i > $i).
% 29.22/29.05  tff(decl_43212, type, fn_guard_cell_9: $i > $i).
% 29.22/29.05  tff(decl_43213, type, fn_guard_cell_10: $i > $i).
% 29.22/29.05  tff(decl_43214, type, fn_guard_cell_12: $i > $i).
% 29.22/29.05  tff(decl_43215, type, fn_guard_cell_13: $i > $i).
% 29.22/29.05  tff(decl_43216, type, fn_guard_cell_14: $i > $i).
% 29.22/29.05  tff(decl_43217, type, fn_guard_cell_15: $i > $i).
% 29.22/29.05  tff(decl_43218, type, fn_guard_cell_16: $i > $i).
% 29.22/29.05  tff(decl_43219, type, fn_guard_cell_17: $i > $i).
% 29.22/29.05  tff(decl_43220, type, fn_guard_cell_18: $i > $i).
% 29.22/29.05  tff(decl_43221, type, fn_guard_cell_20: $i > $i).
% 29.22/29.05  tff(decl_43222, type, fn_guard_cell_21: $i > $i).
% 29.22/29.05  tff(decl_43223, type, fn_guard_cell_22: $i > $i).
% 29.22/29.05  tff(decl_43224, type, fn_guard_cell_24: $i > $i).
% 29.22/29.05  tff(decl_43225, type, fn_guard_cell_25: $i > $i).
% 29.22/29.05  tff(decl_43226, type, fn_guard_cell_26: $i > $i).
% 29.22/29.05  tff(decl_43227, type, fn_guard_cell_27: $i > $i).
% 29.22/29.05  tff(decl_43228, type, fn_guard_cell_28: $i > $i).
% 29.22/29.05  tff(decl_43229, type, fn_guard_cell_29: $i > $i).
% 29.22/29.05  tff(decl_43230, type, fn_guard_cell_30: $i > $i).
% 29.22/29.05  tff(decl_43231, type, fn_guard_cell_31: $i > $i).
% 29.22/29.05  tff(decl_43232, type, fn_guard_cell_32: $i > $i).
% 29.22/29.05  tff(decl_43233, type, fn_guard_cell_33: $i > $i).
% 29.22/29.05  tff(decl_43234, type, fn_guard_cell_34: $i > $i).
% 29.22/29.05  tff(decl_43235, type, fn_guard_cell_35: $i > $i).
% 29.22/29.05  tff(decl_43236, type, fn_guard_cell_38: $i > $i).
% 29.22/29.05  tff(decl_43237, type, fn_guard_cell_39: $i > $i).
% 29.22/29.05  tff(decl_43238, type, fn_guard_cell_40: $i > $i).
% 29.22/29.05  tff(decl_43239, type, fn_guard_cell_41: $i > $i).
% 29.22/29.05  tff(decl_43240, type, fn_guard_cell_42: $i > $i).
% 29.22/29.05  tff(decl_43241, type, fn_guard_cell_43: $i > $i).
% 29.22/29.05  tff(decl_43242, type, fn_guard_cell_44: $i > $i).
% 29.22/29.05  tff(decl_43243, type, fn_guard_cell_45: $i > $i).
% 29.22/29.05  tff(decl_43244, type, fn_guard_cell_46: $i > $i).
% 29.22/29.05  tff(decl_43245, type, fn_guard_cell_36: $i > $i).
% 29.22/29.05  tff(decl_43246, type, fn_guard_cell_37: $i > $i).
% 29.22/29.05  tff(decl_43247, type, fn_plant_cell_16: $i > $i).
% 29.22/29.05  tff(decl_43248, type, fn_plant_cell_17: $i > $i).
% 29.22/29.05  tff(decl_43249, type, fn_plant_cell_19: $i > $i).
% 29.22/29.05  tff(decl_43250, type, fn_plant_cell_18: $i > $i).
% 29.22/29.05  tff(decl_43251, type, 'Gustation': $i).
% 29.22/29.05  tff(decl_43252, type, 'The process of interpreting information from the effects of chemicals interacting with chemorecetpors in the tongue.': $i).
% 29.22/29.05  tff(decl_43253, type, taste: $i).
% 29.22/29.05  tff(decl_43254, type, gustation: $i).
% 29.22/29.05  tff(decl_43255, type, sensory_process_1: $i > $o).
% 29.22/29.05  tff(decl_43256, type, gustatory_receptor_1: $i > $o).
% 29.22/29.05  tff(decl_43257, type, 'Gustatory-Receptor': $i).
% 29.22/29.05  tff(decl_43258, type, 'A type of chemoreceptor that responds to categories of related chemicals.': $i).
% 29.22/29.05  tff(decl_43259, type, 'gustatory receptor': $i).
% 29.22/29.05  tff(decl_43260, type, 'gustatory-receptor': $i).
% 29.22/29.05  tff(decl_43261, type, guttation_1: $i > $o).
% 29.22/29.05  tff(decl_43262, type, 'Guttation': $i).
% 29.22/29.05  tff(decl_43263, type, 'The exudation of water droplets, caused by root pressure in certain plants.': $i).
% 29.22/29.05  tff(decl_43264, type, guttation: $i).
% 29.22/29.05  tff(decl_43265, type, fn_guttation_1: $i > $i).
% 29.22/29.05  tff(decl_43266, type, fn_guttation_2: $i > $i).
% 29.22/29.05  tff(decl_43267, type, fn_guttation_3: $i > $i).
% 29.22/29.05  tff(decl_43268, type, fn_guttation_4: $i > $i).
% 29.22/29.05  tff(decl_43269, type, fn_guttation_5: $i > $i).
% 29.22/29.05  tff(decl_43270, type, fn_guttation_6: $i > $i).
% 29.22/29.05  tff(decl_43271, type, gymnamoeba_1: $i > $o).
% 29.22/29.05  tff(decl_43272, type, 'Gymnamoeba': $i).
% 29.22/29.05  tff(decl_43273, type, 'A phylum of the kingdom Amoebozoa.': $i).
% 29.22/29.05  tff(decl_43274, type, gymnamoeba: $i).
% 29.22/29.05  tff(decl_43275, type, 'Gymnosperm': $i).
% 29.22/29.05  tff(decl_43276, type, 'A vascular plant whose seeds are not encased in an ovary.': $i).
% 29.22/29.05  tff(decl_43277, type, gymnosperm: $i).
% 29.22/29.05  tff(decl_43278, type, fn_gymnosperm_12: $i > $i).
% 29.22/29.05  tff(decl_43279, type, fn_gymnosperm_18: $i > $i).
% 29.22/29.05  tff(decl_43280, type, fn_seed_plant_5: $i > $i).
% 29.22/29.05  tff(decl_43281, type, 'H1': $i).
% 29.22/29.05  tff(decl_43282, type, 'Histone that keeps DNA in place as it wraps around the nucleosome.': $i).
% 29.22/29.05  tff(decl_43283, type, h1: $i).
% 29.22/29.05  tff(decl_43284, type, h2a_1: $i > $o).
% 29.22/29.05  tff(decl_43285, type, h2b_1: $i > $o).
% 29.22/29.05  tff(decl_43286, type, h3_1: $i > $o).
% 29.22/29.05  tff(decl_43287, type, h4_1: $i > $o).
% 29.22/29.05  tff(decl_43288, type, fn_h1_1: $i > $i).
% 29.22/29.05  tff(decl_43289, type, fn_h1_2: $i > $i).
% 29.22/29.05  tff(decl_43290, type, 'H2A': $i).
% 29.22/29.05  tff(decl_43291, type, 'A type of histone.': $i).
% 29.22/29.05  tff(decl_43292, type, 'h2a histone': $i).
% 29.22/29.05  tff(decl_43293, type, h2a: $i).
% 29.22/29.05  tff(decl_43294, type, 'H2B': $i).
% 29.22/29.05  tff(decl_43295, type, 'h2b histone': $i).
% 29.22/29.05  tff(decl_43296, type, h2b: $i).
% 29.22/29.05  tff(decl_43297, type, 'H3': $i).
% 29.22/29.05  tff(decl_43298, type, 'h3 histone': $i).
% 29.22/29.05  tff(decl_43299, type, h3: $i).
% 29.22/29.05  tff(decl_43300, type, 'H4': $i).
% 29.22/29.05  tff(decl_43301, type, 'h4 histone': $i).
% 29.22/29.05  tff(decl_43302, type, h4: $i).
% 29.22/29.05  tff(decl_43303, type, habitat_selection_1: $i > $o).
% 29.22/29.05  tff(decl_43304, type, 'Habitat-Selection': $i).
% 29.22/29.05  tff(decl_43305, type, 'The processes by which organisms select the type of habitat to occupy.': $i).
% 29.22/29.05  tff(decl_43306, type, 'selection of habitat': $i).
% 29.22/29.05  tff(decl_43307, type, 'habitat selection': $i).
% 29.22/29.05  tff(decl_43308, type, 'habitat-selection': $i).
% 29.22/29.05  tff(decl_43309, type, 'Habituation': $i).
% 29.22/29.05  tff(decl_43310, type, 'Diminished response to a stimulus after repeated exposure.': $i).
% 29.22/29.05  tff(decl_43311, type, habituation: $i).
% 29.22/29.05  tff(decl_43312, type, hafnium_1: $i > $o).
% 29.22/29.05  tff(decl_43313, type, 'Hafnium': $i).
% 29.22/29.05  tff(decl_43314, type, 'Hafnium is a metal atom with atomic number 72. It is represented by the symbol Hf.': $i).
% 29.22/29.05  tff(decl_43315, type, hafnium: $i).
% 29.22/29.05  tff(decl_43316, type, 'Hf': $i).
% 29.22/29.05  tff(decl_43317, type, fn_hafnium_4: $i > $i).
% 29.22/29.05  tff(decl_43318, type, fn_hafnium_5: $i > $i).
% 29.22/29.05  tff(decl_43319, type, fn_hafnium_6: $i > $i).
% 29.22/29.05  tff(decl_43320, type, fn_hafnium_7: $i > $i).
% 29.22/29.05  tff(decl_43321, type, fn_hafnium_11: $i > $i).
% 29.22/29.05  tff(decl_43322, type, fn_hafnium_12: $i > $i).
% 29.22/29.05  tff(decl_43323, type, fn_hafnium_13: $i > $i).
% 29.22/29.05  tff(decl_43324, type, fn_hafnium_14: $i > $i).
% 29.22/29.05  tff(decl_43325, type, "72": $i).
% 29.22/29.05  tff(decl_43326, type, "179": $i).
% 29.22/29.05  tff(decl_43327, type, "178.5": $i).
% 29.22/29.05  tff(decl_43328, type, fn_hafnium_9: $i > $i).
% 29.22/29.05  tff(decl_43329, type, fn_hafnium_10: $i > $i).
% 29.22/29.05  tff(decl_43330, type, fn_hafnium_8: $i > $i).
% 29.22/29.05  tff(decl_43331, type, hagfish_1: $i > $o).
% 29.22/29.05  tff(decl_43332, type, 'Hagfish': $i).
% 29.22/29.05  tff(decl_43333, type, 'Marine animal of the clade Myxini, considered by some researchers not to be vertebrates because they have a skull but lack a vertebral column.': $i).
% 29.22/29.05  tff(decl_43334, type, hagfish: $i).
% 29.22/29.05  tff(decl_43335, type, lamprey_1: $i > $o).
% 29.22/29.05  tff(decl_43336, type, 'Hair': $i).
% 29.22/29.05  tff(decl_43337, type, 'Hair is a body covering that grows from the skin of mammals.': $i).
% 29.22/29.05  tff(decl_43338, type, hair: $i).
% 29.22/29.05  tff(decl_43339, type, fn_hair_1: $i > $i).
% 29.22/29.05  tff(decl_43340, type, hair_cell_1: $i > $o).
% 29.22/29.05  tff(decl_43341, type, 'Hair-Cell': $i).
% 29.22/29.05  tff(decl_43342, type, 'A type of mechanoreceptor found in the vertebrate ear and in the lateral line organs of fishes and amphibians, where they detect movement relative to the environment.': $i).
% 29.22/29.05  tff(decl_43343, type, 'cell of hair': $i).
% 29.22/29.05  tff(decl_43344, type, 'hair cell': $i).
% 29.22/29.05  tff(decl_43345, type, 'hair-cell': $i).
% 29.22/29.05  tff(decl_43346, type, 'Hallway': $i).
% 29.22/29.05  tff(decl_43347, type, hallway: $i).
% 29.22/29.05  tff(decl_43348, type, hand_1: $i > $o).
% 29.22/29.05  tff(decl_43349, type, 'Hand': $i).
% 29.22/29.05  tff(decl_43350, type, 'A hand is a prehensile, multi-fingered extremity located at the end of an arm or forelimb of primates such as humans, chimpanzees, monkeys, and lemurs.': $i).
% 29.22/29.05  tff(decl_43351, type, hand: $i).
% 29.22/29.05  tff(decl_43352, type, 'Hantavirus': $i).
% 29.22/29.05  tff(decl_43353, type, 'A group of viruses carried by rodents but which can cause disease in humans.': $i).
% 29.22/29.05  tff(decl_43354, type, hantavirus: $i).
% 29.22/29.05  tff(decl_43355, type, 'Haploid-cell': $i).
% 29.22/29.05  tff(decl_43356, type, 'The haploid cell is the cell which have half number  of chromosomes as present in the normal somatic cells of an organism': $i).
% 29.22/29.05  tff(decl_43357, type, 'n cell': $i).
% 29.22/29.05  tff(decl_43358, type, 'n-cell': $i).
% 29.22/29.05  tff(decl_43359, type, 'cell of haploid': $i).
% 29.22/29.05  tff(decl_43360, type, 'haploid cell': $i).
% 29.22/29.05  tff(decl_43361, type, 'haploid-cell': $i).
% 29.22/29.05  tff(decl_43362, type, fn_haploid_cell_2: $i > $i).
% 29.22/29.05  tff(decl_43363, type, fn_haploid_cell_3: $i > $i).
% 29.22/29.05  tff(decl_43364, type, fn_haploid_cell_7: $i > $i).
% 29.22/29.05  tff(decl_43365, type, fn_haploid_cell_8: $i > $i).
% 29.22/29.05  tff(decl_43366, type, fn_haploid_cell_9: $i > $i).
% 29.22/29.05  tff(decl_43367, type, fn_haploid_cell_10: $i > $i).
% 29.22/29.05  tff(decl_43368, type, fn_haploid_cell_12: $i > $i).
% 29.22/29.05  tff(decl_43369, type, fn_haploid_cell_13: $i > $i).
% 29.22/29.05  tff(decl_43370, type, fn_haploid_cell_14: $i > $i).
% 29.22/29.05  tff(decl_43371, type, fn_haploid_cell_15: $i > $i).
% 29.22/29.05  tff(decl_43372, type, fn_haploid_cell_16: $i > $i).
% 29.22/29.05  tff(decl_43373, type, fn_haploid_cell_17: $i > $i).
% 29.22/29.05  tff(decl_43374, type, fn_haploid_cell_18: $i > $i).
% 29.22/29.05  tff(decl_43375, type, fn_haploid_cell_19: $i > $i).
% 29.22/29.05  tff(decl_43376, type, fn_haploid_cell_20: $i > $i).
% 29.22/29.05  tff(decl_43377, type, fn_haploid_cell_21: $i > $i).
% 29.22/29.05  tff(decl_43378, type, fn_haploid_cell_22: $i > $i).
% 29.22/29.05  tff(decl_43379, type, fn_haploid_cell_23: $i > $i).
% 29.22/29.05  tff(decl_43380, type, fn_haploid_cell_24: $i > $i).
% 29.22/29.05  tff(decl_43381, type, fn_haploid_cell_25: $i > $i).
% 29.22/29.05  tff(decl_43382, type, fn_haploid_cell_26: $i > $i).
% 29.22/29.05  tff(decl_43383, type, fn_haploid_cell_27: $i > $i).
% 29.22/29.05  tff(decl_43384, type, fn_haploid_cell_28: $i > $i).
% 29.22/29.05  tff(decl_43385, type, fn_haploid_cell_29: $i > $i).
% 29.22/29.05  tff(decl_43386, type, fn_haploid_cell_30: $i > $i).
% 29.22/29.05  tff(decl_43387, type, fn_haploid_cell_11: $i > $i).
% 29.22/29.05  tff(decl_43388, type, fn_haploid_cell_5: $i > $i).
% 29.22/29.05  tff(decl_43389, type, fn_haploid_cell_4: $i > $i).
% 29.22/29.05  tff(decl_43390, type, fn_haploid_cell_6: $i > $i).
% 29.22/29.05  tff(decl_43391, type, fn_haploid_cell_1: $i > $i).
% 29.22/29.05  tff(decl_43392, type, haploid_gamete_1: $i > $o).
% 29.22/29.05  tff(decl_43393, type, 'Haploid-Gamete': $i).
% 29.22/29.05  tff(decl_43394, type, 'A gamete is a sex cell, either egg cells or sperm cells.  A haploid gamete describes a sex cell with one full set of chromosomes.': $i).
% 29.22/29.05  tff(decl_43395, type, 'gamete of haploid': $i).
% 29.22/29.05  tff(decl_43396, type, 'haploid gamete': $i).
% 29.22/29.05  tff(decl_43397, type, 'haploid-gamete': $i).
% 29.22/29.05  tff(decl_43398, type, 'Haploid-Number': $i).
% 29.22/29.05  tff(decl_43399, type, 'For humans, the haploid number, abbreviated n, is 23 (n = 23).': $i).
% 29.22/29.05  tff(decl_43400, type, 'number of haploid': $i).
% 29.22/29.05  tff(decl_43401, type, 'haploid number': $i).
% 29.22/29.05  tff(decl_43402, type, 'haploid-number': $i).
% 29.22/29.05  tff(decl_43403, type, haploidization_1: $i > $o).
% 29.22/29.05  tff(decl_43404, type, 'Haploidization': $i).
% 29.22/29.05  tff(decl_43405, type, 'It is the process of reduction of number of chromosomes of a parent cell to half after cell division to result in daughter cells with their number of chromosomes half as compared to those in parent cells': $i).
% 29.22/29.05  tff(decl_43406, type, haploidisation: $i).
% 29.22/29.05  tff(decl_43407, type, haploidization: $i).
% 29.22/29.05  tff(decl_43408, type, fn_haploidization_1: $i > $i).
% 29.22/29.05  tff(decl_43409, type, fn_haploidization_2: $i > $i).
% 29.22/29.05  tff(decl_43410, type, hardy_weinberg_equilibrium_1: $i > $o).
% 29.22/29.05  tff(decl_43411, type, 'Hardy-Weinberg-Equilibrium': $i).
% 29.22/29.05  tff(decl_43412, type, 'A theoretical condition in which a population is not evolving (i.e., allele frequencies are not changing) at a particular locus or loci being studied.': $i).
% 29.22/29.05  tff(decl_43413, type, 'hardy weinberg equilibrium': $i).
% 29.22/29.05  tff(decl_43414, type, 'hardy-weinberg-equilibrium': $i).
% 29.22/29.05  tff(decl_43415, type, 'Harm': $i).
% 29.22/29.05  tff(decl_43416, type, harm: $i).
% 29.22/29.05  tff(decl_43417, type, 'Has-Condition': $i).
% 29.22/29.05  tff(decl_43418, type, 'This axiom is built to introduce conditions on edges and nodes.': $i).
% 29.22/29.05  tff(decl_43419, type, 'have condition': $i).
% 29.22/29.05  tff(decl_43420, type, 'has condition': $i).
% 29.22/29.05  tff(decl_43421, type, 'has-condition': $i).
% 29.22/29.05  tff(decl_43422, type, hassium_1: $i > $o).
% 29.22/29.05  tff(decl_43423, type, 'Hassium': $i).
% 29.22/29.05  tff(decl_43424, type, 'Hassium is a metal atom with atomic number 108. It is represented by the symbol Hs.': $i).
% 29.22/29.05  tff(decl_43425, type, hassium: $i).
% 29.22/29.05  tff(decl_43426, type, 'Hs': $i).
% 29.22/29.05  tff(decl_43427, type, fn_hassium_1: $i > $i).
% 29.22/29.05  tff(decl_43428, type, fn_hassium_2: $i > $i).
% 29.22/29.05  tff(decl_43429, type, fn_hassium_6: $i > $i).
% 29.22/29.05  tff(decl_43430, type, fn_hassium_7: $i > $i).
% 29.22/29.05  tff(decl_43431, type, "108": $i).
% 29.22/29.05  tff(decl_43432, type, "269": $i).
% 29.22/29.05  tff(decl_43433, type, fn_hassium_4: $i > $i).
% 29.22/29.05  tff(decl_43434, type, fn_hassium_5: $i > $i).
% 29.22/29.05  tff(decl_43435, type, haustorium_1: $i > $o).
% 29.22/29.05  tff(decl_43436, type, 'Haustorium': $i).
% 29.22/29.05  tff(decl_43437, type, 'The specialized hypha of some symbiotic fungi, which penetrates the tissue of host plants. In parasitic fungi, the haustorium withdraws nutrients from the host.': $i).
% 29.22/29.05  tff(decl_43438, type, haustorium: $i).
% 29.22/29.05  tff(decl_43439, type, hay_1: $i > $o).
% 29.22/29.05  tff(decl_43440, type, 'Hay': $i).
% 29.22/29.05  tff(decl_43441, type, 'Hay is grass, legumes or other herbaceous plants that have been cut, dried, and stored for use as animal fodder, particularly for grazing livestock such as cattle, horses, goats, and sheep.': $i).
% 29.22/29.05  tff(decl_43442, type, hay: $i).
% 29.22/29.05  tff(decl_43443, type, 'HCG': $i).
% 29.22/29.05  tff(decl_43444, type, 'Human chorionic gonadotropin; a tropic hormone secreted by the placenta during the first trimester of pregnancy. HCG maintains the post-ovulatory corpus luteum and causes it to secrete progesterone, which in turn thickens the endometrial lining of the uterus.': $i).
% 29.22/29.05  tff(decl_43445, type, 'human chorionic gonadotropin': $i).
% 29.22/29.05  tff(decl_43446, type, 'human-chorionic-gonadotropin': $i).
% 29.22/29.05  tff(decl_43447, type, hcg: $i).
% 29.22/29.05  tff(decl_43448, type, 'Head': $i).
% 29.22/29.05  tff(decl_43449, type, 'The upper part of the human body or the front part of the body in animals is called the head.': $i).
% 29.22/29.05  tff(decl_43450, type, head: $i).
% 29.22/29.05  tff(decl_43451, type, head_nod_1: $i > $o).
% 29.22/29.05  tff(decl_43452, type, 'Head-Nod': $i).
% 29.22/29.05  tff(decl_43453, type, nod: $i).
% 29.22/29.05  tff(decl_43454, type, 'nod of head': $i).
% 29.22/29.05  tff(decl_43455, type, 'head nod': $i).
% 29.22/29.05  tff(decl_43456, type, 'head-nod': $i).
% 29.22/29.05  tff(decl_43457, type, head_shake_1: $i > $o).
% 29.22/29.05  tff(decl_43458, type, fn_head_nod_1: $i > $i).
% 29.22/29.05  tff(decl_43459, type, 'Head-Shake': $i).
% 29.22/29.05  tff(decl_43460, type, headshake: $i).
% 29.22/29.05  tff(decl_43461, type, headshaking: $i).
% 29.22/29.05  tff(decl_43462, type, 'shake of head': $i).
% 29.22/29.05  tff(decl_43463, type, 'head shake': $i).
% 29.22/29.05  tff(decl_43464, type, 'head-shake': $i).
% 29.22/29.05  tff(decl_43465, type, fn_head_shake_1: $i > $i).
% 29.22/29.05  tff(decl_43466, type, healing_1: $i > $o).
% 29.22/29.05  tff(decl_43467, type, 'Healing': $i).
% 29.22/29.05  tff(decl_43468, type, heal: $i).
% 29.22/29.05  tff(decl_43469, type, healing: $i).
% 29.22/29.05  tff(decl_43470, type, improvement_1: $i > $o).
% 29.22/29.05  tff(decl_43471, type, fn_healing_1: $i > $i).
% 29.22/29.05  tff(decl_43472, type, fn_improvement_1: $i > $i).
% 29.22/29.05  tff(decl_43473, type, hear_1: $i > $o).
% 29.22/29.05  tff(decl_43474, type, 'Hear': $i).
% 29.22/29.05  tff(decl_43475, type, hear: $i).
% 29.22/29.05  tff(decl_43476, type, sense: $i).
% 29.22/29.05  tff(decl_43477, type, read_1: $i > $o).
% 29.22/29.05  tff(decl_43478, type, fn_hear_1: $i > $i).
% 29.22/29.05  tff(decl_43479, type, sound_1: $i > $o).
% 29.22/29.05  tff(decl_43480, type, fn_sense_2: $i > $i).
% 29.22/29.05  tff(decl_43481, type, 'Heart': $i).
% 29.22/29.05  tff(decl_43482, type, 'A hollow muscular pump that circulates blood through the circulatory system.': $i).
% 29.22/29.05  tff(decl_43483, type, heart: $i).
% 29.22/29.05  tff(decl_43484, type, fn_heart_1: $i > $i).
% 29.22/29.05  tff(decl_43485, type, fn_heart_2: $i > $i).
% 29.22/29.05  tff(decl_43486, type, fn_heart_3: $i > $i).
% 29.22/29.05  tff(decl_43487, type, 'Heart-Attack': $i).
% 29.22/29.05  tff(decl_43488, type, 'Damage or death of cardiac tissue due to an interruption of blood supply to the heart.': $i).
% 29.22/29.05  tff(decl_43489, type, 'attack of heart': $i).
% 29.22/29.05  tff(decl_43490, type, 'heart attack': $i).
% 29.22/29.05  tff(decl_43491, type, 'heart-attack': $i).
% 29.22/29.05  tff(decl_43492, type, 'Heart-Beat': $i).
% 29.22/29.05  tff(decl_43493, type, 'The sound or pulse generated by the pumping action and the closing of the valves of the heart.': $i).
% 29.22/29.05  tff(decl_43494, type, 'beat of heart': $i).
% 29.22/29.05  tff(decl_43495, type, 'heart beat': $i).
% 29.22/29.05  tff(decl_43496, type, 'heart-beat': $i).
% 29.22/29.05  tff(decl_43497, type, 'Heart-Cell': $i).
% 29.22/29.05  tff(decl_43498, type, 'A cell which makes up the heart, an organ of the animal circulatory system.': $i).
% 29.22/29.05  tff(decl_43499, type, 'cell of heart': $i).
% 29.22/29.05  tff(decl_43500, type, 'heart cell': $i).
% 29.22/29.05  tff(decl_43501, type, 'heart-cell': $i).
% 29.22/29.05  tff(decl_43502, type, 'Heart-Murmur': $i).
% 29.22/29.05  tff(decl_43503, type, 'Audible abnormal heart sounds that are usually due to blood leaking through faulty valves.': $i).
% 29.22/29.05  tff(decl_43504, type, 'murmur of heart': $i).
% 29.22/29.05  tff(decl_43505, type, 'heart murmur': $i).
% 29.22/29.05  tff(decl_43506, type, 'heart-murmur': $i).
% 29.22/29.05  tff(decl_43507, type, heartwood_1: $i > $o).
% 29.22/29.05  tff(decl_43508, type, 'Heartwood': $i).
% 29.22/29.05  tff(decl_43509, type, 'Plant tissue comprised of secondary xylem that no longer functions in transporting water.': $i).
% 29.22/29.05  tff(decl_43510, type, heartwood: $i).
% 29.22/29.05  tff(decl_43511, type, secondary_plant_tissue_1: $i > $o).
% 29.22/29.05  tff(decl_43512, type, sapwood_1: $i > $o).
% 29.22/29.05  tff(decl_43513, type, 'Heat': $i).
% 29.22/29.05  tff(decl_43514, type, 'heat up': $i).
% 29.22/29.05  tff(decl_43515, type, heat_up: $i).
% 29.22/29.05  tff(decl_43516, type, 'hot up': $i).
% 29.22/29.05  tff(decl_43517, type, hot_up: $i).
% 29.22/29.05  tff(decl_43518, type, heat_absorption_by_tropical_sea_1: $i > $o).
% 29.22/29.05  tff(decl_43519, type, 'Heat-Absorption-By-Tropical-Sea': $i).
% 29.22/29.05  tff(decl_43520, type, 'The absorption of heat by a sea near the equator.': $i).
% 29.22/29.05  tff(decl_43521, type, 'heat absorption by tropical sea': $i).
% 29.22/29.05  tff(decl_43522, type, 'heat-absorption-by-tropical-sea': $i).
% 29.22/29.05  tff(decl_43523, type, fn_heat_absorption_by_tropical_sea_1: $i > $i).
% 29.22/29.05  tff(decl_43524, type, fn_heat_absorption_by_tropical_sea_2: $i > $i).
% 29.22/29.05  tff(decl_43525, type, fn_heat_absorption_by_tropical_sea_3: $i > $i).
% 29.22/29.05  tff(decl_43526, type, fn_heat_absorption_by_tropical_sea_4: $i > $i).
% 29.22/29.05  tff(decl_43527, type, fn_heat_absorption_by_tropical_sea_5: $i > $i).
% 29.22/29.05  tff(decl_43528, type, fn_heat_absorption_by_tropical_sea_6: $i > $i).
% 29.22/29.05  tff(decl_43529, type, fn_heat_absorption_by_tropical_sea_7: $i > $i).
% 29.22/29.05  tff(decl_43530, type, fn_heat_absorption_by_tropical_sea_8: $i > $i).
% 29.22/29.05  tff(decl_43531, type, fn_heat_absorption_by_tropical_sea_9: $i > $i).
% 29.22/29.05  tff(decl_43532, type, fn_water_body_2: $i > $i).
% 29.22/29.05  tff(decl_43533, type, fn_water_evaporation_9: $i > $i).
% 29.22/29.05  tff(decl_43534, type, 'Heat-of-Vaporization-Constant': $i).
% 29.22/29.05  tff(decl_43535, type, 'heat of vaporization constant': $i).
% 29.22/29.05  tff(decl_43536, type, 'heat-of-vaporization-constant': $i).
% 29.22/29.05  tff(decl_43537, type, heat_of_vaporization_scale_1: $i > $o).
% 29.22/29.05  tff(decl_43538, type, 'Heat-of-Vaporization-Scale': $i).
% 29.22/29.05  tff(decl_43539, type, 'heat of vaporization scale': $i).
% 29.22/29.05  tff(decl_43540, type, 'heat-of-vaporization-scale': $i).
% 29.22/29.05  tff(decl_43541, type, 'Heat-of-Vaporization-Value': $i).
% 29.22/29.05  tff(decl_43542, type, 'vaporization heat': $i).
% 29.22/29.05  tff(decl_43543, type, 'vaporization-heat': $i).
% 29.22/29.05  tff(decl_43544, type, 'heat of vaporization': $i).
% 29.22/29.05  tff(decl_43545, type, 'heat-of-vaporization': $i).
% 29.22/29.05  tff(decl_43546, type, 'heat of vaporization value': $i).
% 29.22/29.05  tff(decl_43547, type, 'heat-of-vaporization-value': $i).
% 29.22/29.05  tff(decl_43548, type, heat_shock_protein_1: $i > $o).
% 29.22/29.05  tff(decl_43549, type, 'Heat-Shock-Protein': $i).
% 29.22/29.05  tff(decl_43550, type, 'A group of proteins whose expression increases when cells are exposed to high temperatures.': $i).
% 29.22/29.05  tff(decl_43551, type, 'heat shock protein': $i).
% 29.22/29.05  tff(decl_43552, type, 'heat-shock protein': $i).
% 29.22/29.05  tff(decl_43553, type, 'heat-shock-protein': $i).
% 29.22/29.05  tff(decl_43554, type, 'Heat-Transfer': $i).
% 29.22/29.05  tff(decl_43555, type, 'The movement of heat energy from one object to another.': $i).
% 29.22/29.05  tff(decl_43556, type, 'transfer of heat': $i).
% 29.22/29.05  tff(decl_43557, type, 'heat transfer': $i).
% 29.22/29.05  tff(decl_43558, type, 'heat-transfer': $i).
% 29.22/29.05  tff(decl_43559, type, fn_heat_transfer_2: $i > $i).
% 29.22/29.05  tff(decl_43560, type, fn_heat_transfer_3: $i > $i).
% 29.22/29.05  tff(decl_43561, type, fn_heat_transfer_8: $i > $i).
% 29.22/29.05  tff(decl_43562, type, fn_heat_transfer_9: $i > $i).
% 29.22/29.05  tff(decl_43563, type, fn_heat_transfer_10: $i > $i).
% 29.22/29.05  tff(decl_43564, type, fn_heat_transfer_11: $i > $i).
% 29.22/29.05  tff(decl_43565, type, fn_heat_transfer_12: $i > $i).
% 29.22/29.05  tff(decl_43566, type, fn_heat_transfer_13: $i > $i).
% 29.22/29.05  tff(decl_43567, type, heating_of_liquid_1: $i > $o).
% 29.22/29.05  tff(decl_43568, type, 'Heating-Of-Liquid': $i).
% 29.22/29.05  tff(decl_43569, type, 'The absorption of heat by a liquid causing an increase to the liquid\\s temperature.': $i).
% 29.22/29.05  tff(decl_43570, type, 'heating liquid': $i).
% 29.22/29.05  tff(decl_43571, type, 'liquid heating': $i).
% 29.22/29.05  tff(decl_43572, type, 'liquid-heating': $i).
% 29.22/29.05  tff(decl_43573, type, 'heating of liquid': $i).
% 29.22/29.05  tff(decl_43574, type, 'heating-of-liquid': $i).
% 29.22/29.05  tff(decl_43575, type, fn_heating_of_liquid_1: $i > $i).
% 29.22/29.05  tff(decl_43576, type, fn_heating_of_liquid_2: $i > $i).
% 29.22/29.05  tff(decl_43577, type, fn_heating_of_liquid_4: $i > $i).
% 29.22/29.05  tff(decl_43578, type, fn_heating_of_liquid_5: $i > $i).
% 29.22/29.05  tff(decl_43579, type, fn_heating_of_liquid_6: $i > $i).
% 29.22/29.05  tff(decl_43580, type, fn_heating_of_liquid_3: $i > $i).
% 29.22/29.05  tff(decl_43581, type, heating_of_water_body_1: $i > $o).
% 29.22/29.05  tff(decl_43582, type, fn_heating_of_water_body_2: $i > $i).
% 29.22/29.05  tff(decl_43583, type, 'Heating-Of-Water-Body': $i).
% 29.22/29.05  tff(decl_43584, type, 'The absorption of heat by water causing an increase to the water\\s temperature.  Water has a high specific heat and so a lot of heat is required to raise the temperature of water.': $i).
% 29.22/29.05  tff(decl_43585, type, 'heating of water': $i).
% 29.22/29.05  tff(decl_43586, type, 'heating of water body': $i).
% 29.22/29.05  tff(decl_43587, type, 'heating-of-water-body': $i).
% 29.22/29.05  tff(decl_43588, type, fn_heating_of_water_body_3: $i > $i).
% 29.22/29.05  tff(decl_43589, type, fn_heating_of_water_body_4: $i > $i).
% 29.22/29.05  tff(decl_43590, type, fn_heating_of_water_body_6: $i > $i).
% 29.22/29.05  tff(decl_43591, type, fn_heating_of_water_body_7: $i > $i).
% 29.22/29.05  tff(decl_43592, type, fn_heating_of_water_body_8: $i > $i).
% 29.22/29.05  tff(decl_43593, type, thermal_energy_0: $i).
% 29.22/29.05  tff(decl_43594, type, 'Heavy-Chain': $i).
% 29.22/29.05  tff(decl_43595, type, 'The larger of the two types of polypeptide chains making up an antibody molecule. It consists of a constant region, which confers lysis and phagocytosis of microbes, and a variable region, which binds to specific antigens.': $i).
% 29.22/29.05  tff(decl_43596, type, 'chain of heavy': $i).
% 29.22/29.05  tff(decl_43597, type, 'heavy chain': $i).
% 29.22/29.05  tff(decl_43598, type, 'heavy-chain': $i).
% 29.22/29.05  tff(decl_43599, type, hedgehog_1: $i > $o).
% 29.22/29.05  tff(decl_43600, type, 'Hedgehog': $i).
% 29.22/29.05  tff(decl_43601, type, 'Omniverous mammal found in parts of Asia, Europe and Africa, characterized by presence of protective spines and ability to roll into a tight ball when threatened.': $i).
% 29.22/29.05  tff(decl_43602, type, hedgehog: $i).
% 29.22/29.05  tff(decl_43603, type, fn_hedgehog_1: $i > $i).
% 29.22/29.05  tff(decl_43604, type, fn_hedgehog_2: $i > $i).
% 29.22/29.05  tff(decl_43605, type, "90": $i).
% 29.22/29.05  tff(decl_43606, type, 'Height-Constant': $i).
% 29.22/29.05  tff(decl_43607, type, 'constant of height': $i).
% 29.22/29.05  tff(decl_43608, type, 'height constant': $i).
% 29.22/29.05  tff(decl_43609, type, 'height-constant': $i).
% 29.22/29.05  tff(decl_43610, type, height_scale_1: $i > $o).
% 29.22/29.05  tff(decl_43611, type, 'Height-Scale': $i).
% 29.22/29.05  tff(decl_43612, type, 'scale of height': $i).
% 29.22/29.05  tff(decl_43613, type, 'height scale': $i).
% 29.22/29.05  tff(decl_43614, type, 'height-scale': $i).
% 29.22/29.05  tff(decl_43615, type, hela_cell_1: $i > $o).
% 29.22/29.05  tff(decl_43616, type, 'Hela-Cell': $i).
% 29.22/29.05  tff(decl_43617, type, 'Immortal cell line derived from a tumor removed from cancer patient Henrietta Lacks, which has been used extensively in cell biology and cancer research.': $i).
% 29.22/29.05  tff(decl_43618, type, 'cell of hela': $i).
% 29.22/29.05  tff(decl_43619, type, 'hela cell': $i).
% 29.22/29.05  tff(decl_43620, type, 'hela-cell': $i).
% 29.22/29.05  tff(decl_43621, type, fn_hela_cell_1: $i > $i).
% 29.22/29.05  tff(decl_43622, type, henrietta_lacks_1: $i > $o).
% 29.22/29.05  tff(decl_43623, type, fn_hela_cell_2: $i > $i).
% 29.22/29.05  tff(decl_43624, type, fn_hela_cell_3: $i > $i).
% 29.22/29.05  tff(decl_43625, type, fn_hela_cell_4: $i > $i).
% 29.22/29.05  tff(decl_43626, type, fn_hela_cell_5: $i > $i).
% 29.22/29.05  tff(decl_43627, type, fn_hela_cell_8: $i > $i).
% 29.22/29.05  tff(decl_43628, type, fn_hela_cell_9: $i > $i).
% 29.22/29.05  tff(decl_43629, type, fn_hela_cell_10: $i > $i).
% 29.22/29.05  tff(decl_43630, type, fn_hela_cell_11: $i > $i).
% 29.22/29.05  tff(decl_43631, type, fn_hela_cell_12: $i > $i).
% 29.22/29.05  tff(decl_43632, type, fn_hela_cell_13: $i > $i).
% 29.22/29.05  tff(decl_43633, type, fn_hela_cell_14: $i > $i).
% 29.22/29.05  tff(decl_43634, type, fn_hela_cell_15: $i > $i).
% 29.22/29.05  tff(decl_43635, type, fn_hela_cell_16: $i > $i).
% 29.22/29.05  tff(decl_43636, type, fn_hela_cell_17: $i > $i).
% 29.22/29.05  tff(decl_43637, type, fn_hela_cell_18: $i > $i).
% 29.22/29.05  tff(decl_43638, type, fn_hela_cell_19: $i > $i).
% 29.22/29.05  tff(decl_43639, type, fn_hela_cell_20: $i > $i).
% 29.22/29.05  tff(decl_43640, type, fn_hela_cell_21: $i > $i).
% 29.22/29.05  tff(decl_43641, type, fn_hela_cell_22: $i > $i).
% 29.22/29.05  tff(decl_43642, type, fn_hela_cell_23: $i > $i).
% 29.22/29.05  tff(decl_43643, type, fn_hela_cell_24: $i > $i).
% 29.22/29.05  tff(decl_43644, type, fn_hela_cell_25: $i > $i).
% 29.22/29.05  tff(decl_43645, type, fn_hela_cell_26: $i > $i).
% 29.22/29.05  tff(decl_43646, type, fn_hela_cell_27: $i > $i).
% 29.22/29.05  tff(decl_43647, type, fn_hela_cell_28: $i > $i).
% 29.22/29.05  tff(decl_43648, type, fn_hela_cell_29: $i > $i).
% 29.22/29.05  tff(decl_43649, type, fn_hela_cell_30: $i > $i).
% 29.22/29.05  tff(decl_43650, type, fn_hela_cell_31: $i > $i).
% 29.22/29.05  tff(decl_43651, type, fn_hela_cell_32: $i > $i).
% 29.22/29.05  tff(decl_43652, type, fn_hela_cell_33: $i > $i).
% 29.22/29.05  tff(decl_43653, type, fn_hela_cell_34: $i > $i).
% 29.22/29.05  tff(decl_43654, type, fn_hela_cell_35: $i > $i).
% 29.22/29.05  tff(decl_43655, type, fn_hela_cell_36: $i > $i).
% 29.22/29.05  tff(decl_43656, type, fn_hela_cell_37: $i > $i).
% 29.22/29.05  tff(decl_43657, type, fn_hela_cell_38: $i > $i).
% 29.22/29.05  tff(decl_43658, type, fn_hela_cell_39: $i > $i).
% 29.22/29.05  tff(decl_43659, type, fn_hela_cell_40: $i > $i).
% 29.22/29.05  tff(decl_43660, type, fn_hela_cell_41: $i > $i).
% 29.22/29.05  tff(decl_43661, type, fn_hela_cell_42: $i > $i).
% 29.22/29.05  tff(decl_43662, type, fn_hela_cell_43: $i > $i).
% 29.22/29.05  tff(decl_43663, type, fn_hela_cell_44: $i > $i).
% 29.22/29.05  tff(decl_43664, type, fn_hela_cell_7: $i > $i).
% 29.22/29.05  tff(decl_43665, type, fn_hela_cell_6: $i > $i).
% 29.22/29.05  tff(decl_43666, type, 'Helicase': $i).
% 29.22/29.05  tff(decl_43667, type, 'Helicases are enzymes which untwist double-stranded DNA during DNA replication.': $i).
% 29.22/29.05  tff(decl_43668, type, 'dna helicase': $i).
% 29.22/29.05  tff(decl_43669, type, 'dna-helicase': $i).
% 29.22/29.05  tff(decl_43670, type, helicase: $i).
% 29.22/29.05  tff(decl_43671, type, fn_helicase_1: $i > $i).
% 29.22/29.05  tff(decl_43672, type, fn_helicase_2: $i > $i).
% 29.22/29.05  tff(decl_43673, type, helium_1: $i > $o).
% 29.22/29.05  tff(decl_43674, type, 'Helium': $i).
% 29.22/29.05  tff(decl_43675, type, 'Helium is a non metal atom with atomic number 2. It is represented by the symbol He.': $i).
% 29.22/29.05  tff(decl_43676, type, helium: $i).
% 29.22/29.05  tff(decl_43677, type, fn_helium_1: $i > $i).
% 29.22/29.05  tff(decl_43678, type, fn_helium_2: $i > $i).
% 29.22/29.05  tff(decl_43679, type, fn_helium_3: $i > $i).
% 29.22/29.05  tff(decl_43680, type, fn_helium_4: $i > $i).
% 29.22/29.05  tff(decl_43681, type, fn_helium_11: $i > $i).
% 29.22/29.05  tff(decl_43682, type, fn_helium_13: $i > $i).
% 29.22/29.05  tff(decl_43683, type, fn_helium_14: $i > $i).
% 29.22/29.05  tff(decl_43684, type, fn_helium_18: $i > $i).
% 29.22/29.05  tff(decl_43685, type, fn_helium_19: $i > $i).
% 29.22/29.05  tff(decl_43686, type, fn_helium_20: $i > $i).
% 29.22/29.05  tff(decl_43687, type, fn_helium_21: $i > $i).
% 29.22/29.05  tff(decl_43688, type, "4.003": $i).
% 29.22/29.05  tff(decl_43689, type, fn_helium_16: $i > $i).
% 29.22/29.05  tff(decl_43690, type, fn_helium_9: $i > $i).
% 29.22/29.05  tff(decl_43691, type, fn_helium_15: $i > $i).
% 29.22/29.05  tff(decl_43692, type, fn_helium_17: $i > $i).
% 29.22/29.05  tff(decl_43693, type, fn_helium_10: $i > $i).
% 29.22/29.05  tff(decl_43694, type, fn_helium_12: $i > $i).
% 29.22/29.05  tff(decl_43695, type, 'Helper-T': $i).
% 29.22/29.05  tff(decl_43696, type, 'A type of white blood cell with a role in adaptive immunity. Activated helper T cells secrete chemicals that promote the response of B cells (the humoral response) and cytotoxic T cells (the cell-mediated response).': $i).
% 29.22/29.05  tff(decl_43697, type, 't of helper': $i).
% 29.22/29.05  tff(decl_43698, type, 'helper t': $i).
% 29.22/29.05  tff(decl_43699, type, 'helper-t': $i).
% 29.22/29.05  tff(decl_43700, type, 'Heme': $i).
% 29.22/29.05  tff(decl_43701, type, 'A heme is a porphyrin prosthetic group of hemoglobin that binds iron and is valuable for oxygen transport in the body.': $i).
% 29.22/29.05  tff(decl_43702, type, 'heme group': $i).
% 29.22/29.05  tff(decl_43703, type, 'heme-group': $i).
% 29.22/29.05  tff(decl_43704, type, heme: $i).
% 29.22/29.05  tff(decl_43705, type, fn_heme_1: $i > $i).
% 29.22/29.05  tff(decl_43706, type, 'Hemiptera': $i).
% 29.22/29.05  tff(decl_43707, type, 'Order of the class Insecta having sucking mouthparts.': $i).
% 29.22/29.05  tff(decl_43708, type, 'true bugs': $i).
% 29.22/29.05  tff(decl_43709, type, 'true-bugs': $i).
% 29.22/29.05  tff(decl_43710, type, hemiptera: $i).
% 29.22/29.05  tff(decl_43711, type, hemizygous_1: $i > $o).
% 29.22/29.05  tff(decl_43712, type, 'Hemizygous': $i).
% 29.22/29.05  tff(decl_43713, type, 'Having only a single copy of a gene instead of the customary two copies.': $i).
% 29.22/29.05  tff(decl_43714, type, hemizygous: $i).
% 29.22/29.05  tff(decl_43715, type, fn_hemizygous_1: $i > $i).
% 29.22/29.05  tff(decl_43716, type, homologous_chromosome_0: $i).
% 29.22/29.05  tff(decl_43717, type, hemizygous_for_x_1: $i > $o).
% 29.22/29.05  tff(decl_43718, type, 'Hemizygous-For-X': $i).
% 29.22/29.05  tff(decl_43719, type, 'Having only a single copy of a gene on one X chromsome instead of the customary two copies.  Given that normal human males have only one X chromosome, they are thus hemizygous for X.': $i).
% 29.22/29.05  tff(decl_43720, type, 'hemizygous for x': $i).
% 29.22/29.05  tff(decl_43721, type, 'hemizygous-for-x': $i).
% 29.22/29.05  tff(decl_43722, type, fn_hemizygous_for_x_1: $i > $i).
% 29.22/29.05  tff(decl_43723, type, fn_hemizygous_for_x_3: $i > $i).
% 29.22/29.05  tff(decl_43724, type, fn_hemizygous_for_x_4: $i > $i).
% 29.22/29.05  tff(decl_43725, type, hemocyanin_1: $i > $o).
% 29.22/29.05  tff(decl_43726, type, 'Hemocyanin': $i).
% 29.22/29.05  tff(decl_43727, type, 'A respiratory pigment found in the hemolymph of arthropods and many mollusks; it has copper, rather than iron, as its oxygen-binding component.': $i).
% 29.22/29.05  tff(decl_43728, type, hemocyanin: $i).
% 29.22/29.05  tff(decl_43729, type, respiratory_pigment_1: $i > $o).
% 29.22/29.05  tff(decl_43730, type, 'Hemoglobin': $i).
% 29.22/29.05  tff(decl_43731, type, 'Hemoglobin is a quaternary protein in the red blood cells of vertebrates which forms a loose bond with oxygen and allows the oxygen to be transported by the blood from a respiratory structure to working cells within the body.': $i).
% 29.22/29.05  tff(decl_43732, type, haemoglobin: $i).
% 29.22/29.05  tff(decl_43733, type, hemoglobin: $i).
% 29.22/29.05  tff(decl_43734, type, fn_hemoglobin_4: $i > $i).
% 29.22/29.05  tff(decl_43735, type, fn_hemoglobin_5: $i > $i).
% 29.22/29.05  tff(decl_43736, type, fn_hemoglobin_6: $i > $i).
% 29.22/29.05  tff(decl_43737, type, ionic_region_1: $i > $o).
% 29.22/29.05  tff(decl_43738, type, fn_hemoglobin_8: $i > $i).
% 29.22/29.05  tff(decl_43739, type, fn_hemoglobin_9: $i > $i).
% 29.22/29.05  tff(decl_43740, type, fn_water_soluble_protein_6: $i > $i).
% 29.22/29.05  tff(decl_43741, type, 'Hemolymph': $i).
% 29.22/29.05  tff(decl_43742, type, 'The fluid that permeates body tissues, in invertebrate animals with an open circulatory system.': $i).
% 29.22/29.05  tff(decl_43743, type, hemolymph: $i).
% 29.22/29.05  tff(decl_43744, type, 'Hemophilia': $i).
% 29.22/29.05  tff(decl_43745, type, 'A human genetic disease caused by a sex-linked recessive allele resulting in the absence of one or more blood-clotting proteins; characterized by excessive bleeding following injury.': $i).
% 29.22/29.05  tff(decl_43746, type, hemophilia: $i).
% 29.22/29.05  tff(decl_43747, type, fn_hemophilia_2: $i > $i).
% 29.22/29.05  tff(decl_43748, type, fn_hemophilia_3: $i > $i).
% 29.22/29.05  tff(decl_43749, type, fn_hemophilia_4: $i > $i).
% 29.22/29.05  tff(decl_43750, type, hemophiliac_1: $i > $o).
% 29.22/29.05  tff(decl_43751, type, fn_hemophilia_5: $i > $i).
% 29.22/29.05  tff(decl_43752, type, fn_hemophilia_6: $i > $i).
% 29.22/29.05  tff(decl_43753, type, 'Hemophiliac': $i).
% 29.22/29.05  tff(decl_43754, type, 'Someone who has hemophilia and is subject to uncontrollable bleeding.': $i).
% 29.22/29.05  tff(decl_43755, type, 'person with hemophilia': $i).
% 29.22/29.05  tff(decl_43756, type, 'human with hemophilia': $i).
% 29.22/29.05  tff(decl_43757, type, 'hemophilic man': $i).
% 29.22/29.05  tff(decl_43758, type, 'hemophilic-man': $i).
% 29.22/29.05  tff(decl_43759, type, hemophiliac: $i).
% 29.22/29.05  tff(decl_43760, type, fn_hemophiliac_1: $i > $i).
% 29.22/29.05  tff(decl_43761, type, fn_hemophiliac_2: $i > $i).
% 29.22/29.05  tff(decl_43762, type, 'Hemorrhagic-Fever': $i).
% 29.22/29.05  tff(decl_43763, type, 'Any of several diverse virally-caused animal or human disease. Symptoms include high fever, bleeding disorders, shock, and death. There are 5 families of virus known to cause hemorrhagic fevers; for example, the Ebola virus.': $i).
% 29.22/29.05  tff(decl_43764, type, ebola: $i).
% 29.22/29.05  tff(decl_43765, type, 'viral hemorrhagic fevers': $i).
% 29.22/29.05  tff(decl_43766, type, 'viral-hemorrhagic-fevers': $i).
% 29.22/29.05  tff(decl_43767, type, vhf: $i).
% 29.22/29.05  tff(decl_43768, type, 'hemorrhagic fever': $i).
% 29.22/29.05  tff(decl_43769, type, 'hemorrhagic-fever': $i).
% 29.22/29.05  tff(decl_43770, type, 'Henrietta-Lacks': $i).
% 29.22/29.05  tff(decl_43771, type, 'African-American woman from whom the immortal HeLa cell line was isolated and created, without her consent or any compensation.': $i).
% 29.22/29.05  tff(decl_43772, type, 'henrietta lack': $i).
% 29.22/29.05  tff(decl_43773, type, 'henrietta-lack': $i).
% 29.22/29.05  tff(decl_43774, type, hepatic_portal_vessel_1: $i > $o).
% 29.22/29.05  tff(decl_43775, type, 'Hepatic-Portal-Vessel': $i).
% 29.22/29.05  tff(decl_43776, type, 'The vascular supply from the intestine, which carries products from digested food to the liver.': $i).
% 29.22/29.05  tff(decl_43777, type, 'hepatic portal vessel': $i).
% 29.22/29.05  tff(decl_43778, type, 'hepatic-portal-vessel': $i).
% 29.22/29.05  tff(decl_43779, type, 'Hepatitis-B-Virus': $i).
% 29.22/29.05  tff(decl_43780, type, 'A DNA virus which is responsible for Hepatitis B.': $i).
% 29.22/29.05  tff(decl_43781, type, 'hepatitis b virus': $i).
% 29.22/29.05  tff(decl_43782, type, 'hepatitis-b-virus': $i).
% 29.22/29.05  tff(decl_43783, type, her2_1: $i > $o).
% 29.22/29.05  tff(decl_43784, type, 'HER2': $i).
% 29.22/29.05  tff(decl_43785, type, 'Human Epidermal Growth Factor Receptor 2, a receptor protein which functions in cell signalling events leading to cell growth and division. It is implicated in certain types of cancer.': $i).
% 29.22/29.05  tff(decl_43786, type, her2: $i).
% 29.22/29.05  tff(decl_43787, type, fn_her2_1: $i > $i).
% 29.22/29.05  tff(decl_43788, type, fn_her2_2: $i > $i).
% 29.22/29.05  tff(decl_43789, type, fn_her2_3: $i > $i).
% 29.22/29.05  tff(decl_43790, type, fn_her2_4: $i > $i).
% 29.22/29.05  tff(decl_43791, type, fn_her2_5: $i > $i).
% 29.22/29.05  tff(decl_43792, type, fn_her2_6: $i > $i).
% 29.22/29.05  tff(decl_43793, type, fn_her2_7: $i > $i).
% 29.22/29.05  tff(decl_43794, type, fn_her2_8: $i > $i).
% 29.22/29.05  tff(decl_43795, type, fn_her2_9: $i > $i).
% 29.22/29.05  tff(decl_43796, type, fn_her2_10: $i > $i).
% 29.22/29.05  tff(decl_43797, type, fn_tyrosine_kinase_9: $i > $i).
% 29.22/29.05  tff(decl_43798, type, fn_tyrosine_kinase_10: $i > $i).
% 29.22/29.05  tff(decl_43799, type, fn_receptor_tyrosine_kinase_19: $i > $i).
% 29.22/29.05  tff(decl_43800, type, fn_receptor_tyrosine_kinase_12: $i > $i).
% 29.22/29.05  tff(decl_43801, type, fn_tyrosine_kinase_11: $i > $i).
% 29.22/29.05  tff(decl_43802, type, fn_receptor_tyrosine_kinase_20: $i > $i).
% 29.22/29.05  tff(decl_43803, type, herbivore_1: $i > $o).
% 29.22/29.05  tff(decl_43804, type, 'Herbivore': $i).
% 29.22/29.05  tff(decl_43805, type, 'An animal which primarily consumes plants or algae as a source of energy and nutrients.': $i).
% 29.22/29.05  tff(decl_43806, type, herbivore: $i).
% 29.22/29.05  tff(decl_43807, type, fn_herbivore_2: $i > $i).
% 29.22/29.05  tff(decl_43808, type, fn_herbivore_5: $i > $i).
% 29.22/29.05  tff(decl_43809, type, fn_herbivore_6: $i > $i).
% 29.22/29.05  tff(decl_43810, type, fn_herbivore_7: $i > $i).
% 29.22/29.05  tff(decl_43811, type, fn_herbivore_8: $i > $i).
% 29.22/29.05  tff(decl_43812, type, fn_herbivore_9: $i > $i).
% 29.22/29.05  tff(decl_43813, type, fn_herbivore_10: $i > $i).
% 29.22/29.05  tff(decl_43814, type, fn_herbivore_12: $i > $i).
% 29.22/29.05  tff(decl_43815, type, fn_herbivore_13: $i > $i).
% 29.22/29.05  tff(decl_43816, type, fn_herbivore_14: $i > $i).
% 29.22/29.05  tff(decl_43817, type, fn_herbivore_15: $i > $i).
% 29.22/29.05  tff(decl_43818, type, fn_herbivore_16: $i > $i).
% 29.22/29.05  tff(decl_43819, type, fn_herbivore_17: $i > $i).
% 29.22/29.05  tff(decl_43820, type, fn_herbivore_18: $i > $i).
% 29.22/29.05  tff(decl_43821, type, fn_herbivore_19: $i > $i).
% 29.22/29.05  tff(decl_43822, type, fn_herbivore_20: $i > $i).
% 29.22/29.05  tff(decl_43823, type, fn_herbivore_21: $i > $i).
% 29.22/29.05  tff(decl_43824, type, fn_herbivore_22: $i > $i).
% 29.22/29.05  tff(decl_43825, type, fn_herbivore_23: $i > $i).
% 29.22/29.05  tff(decl_43826, type, fn_herbivore_24: $i > $i).
% 29.22/29.05  tff(decl_43827, type, fn_herbivore_25: $i > $i).
% 29.22/29.05  tff(decl_43828, type, fn_herbivore_26: $i > $i).
% 29.22/29.05  tff(decl_43829, type, fn_herbivore_27: $i > $i).
% 29.22/29.05  tff(decl_43830, type, fn_symbiosis_2: $i > $i).
% 29.22/29.05  tff(decl_43831, type, fn_symbiosis_1: $i > $i).
% 29.22/29.05  tff(decl_43832, type, digestive_tract_0: $i).
% 29.22/29.05  tff(decl_43833, type, 'Herbivory': $i).
% 29.22/29.05  tff(decl_43834, type, 'The consumption of all or part of a plant or alga for food.': $i).
% 29.22/29.05  tff(decl_43835, type, herbivory: $i).
% 29.22/29.05  tff(decl_43836, type, herceptin_1: $i > $o).
% 29.22/29.05  tff(decl_43837, type, 'Herceptin': $i).
% 29.22/29.05  tff(decl_43838, type, 'Treatment for breast cancer involving abnormal HER2 receptors.': $i).
% 29.22/29.05  tff(decl_43839, type, herceptin: $i).
% 29.22/29.05  tff(decl_43840, type, fn_herceptin_1: $i > $i).
% 29.22/29.05  tff(decl_43841, type, fn_herceptin_2: $i > $i).
% 29.22/29.05  tff(decl_43842, type, fn_herceptin_3: $i > $i).
% 29.22/29.05  tff(decl_43843, type, fn_herceptin_4: $i > $i).
% 29.22/29.05  tff(decl_43844, type, fn_herceptin_5: $i > $i).
% 29.22/29.05  tff(decl_43845, type, fn_herceptin_6: $i > $i).
% 29.22/29.05  tff(decl_43846, type, fn_herceptin_7: $i > $i).
% 29.22/29.05  tff(decl_43847, type, fn_herceptin_8: $i > $i).
% 29.22/29.05  tff(decl_43848, type, fn_herceptin_9: $i > $i).
% 29.22/29.05  tff(decl_43849, type, fn_herceptin_10: $i > $i).
% 29.22/29.05  tff(decl_43850, type, fn_herceptin_11: $i > $i).
% 29.22/29.05  tff(decl_43851, type, fn_herceptin_12: $i > $i).
% 29.22/29.05  tff(decl_43852, type, hermaphroditism_1: $i > $o).
% 29.22/29.05  tff(decl_43853, type, 'Hermaphroditism': $i).
% 29.22/29.05  tff(decl_43854, type, 'In animals, the condition of having both female and male sexual function, producing both eggs and sperm.': $i).
% 29.22/29.05  tff(decl_43855, type, hermaphroditism: $i).
% 29.22/29.05  tff(decl_43856, type, heroin_1: $i > $o).
% 29.22/29.05  tff(decl_43857, type, 'Heroin': $i).
% 29.22/29.05  tff(decl_43858, type, 'Heroin is an opiate which relieves pain and alters mood by weakly binding to specific receptor molecules on the surfaces of brain cells.': $i).
% 29.22/29.05  tff(decl_43859, type, heroin: $i).
% 29.22/29.05  tff(decl_43860, type, fn_heroin_1: $i > $i).
% 29.22/29.05  tff(decl_43861, type, fn_heroin_3: $i > $i).
% 29.22/29.05  tff(decl_43862, type, attach_0: $i).
% 29.22/29.05  tff(decl_43863, type, fn_opiate_7: $i > $i).
% 29.22/29.05  tff(decl_43864, type, 'Herpesvirus': $i).
% 29.22/29.05  tff(decl_43865, type, 'A class of DNA viruses that cause disease in humans and other animals.': $i).
% 29.22/29.05  tff(decl_43866, type, herpesvirus: $i).
% 29.22/29.05  tff(decl_43867, type, hershey_chase_experiment_1: $i > $o).
% 29.22/29.05  tff(decl_43868, type, 'Hershey-Chase-Experiment': $i).
% 29.22/29.05  tff(decl_43869, type, 'An experiment in which scientists used autoradiography to determine that DNA, not protein, was the genetic material in a bacteriophage.': $i).
% 29.22/29.05  tff(decl_43870, type, 'hershey and chase experiment': $i).
% 29.22/29.05  tff(decl_43871, type, 'hershey chase experiment': $i).
% 29.22/29.05  tff(decl_43872, type, 'hershey-chase-experiment': $i).
% 29.22/29.05  tff(decl_43873, type, fn_hershey_chase_experiment_1: $i > $i).
% 29.22/29.05  tff(decl_43874, type, t2_phage_1: $i > $o).
% 29.22/29.05  tff(decl_43875, type, fn_hershey_chase_experiment_2: $i > $i).
% 29.22/29.05  tff(decl_43876, type, fn_hershey_chase_experiment_3: $i > $i).
% 29.22/29.05  tff(decl_43877, type, isotopic_labeling_1: $i > $o).
% 29.22/29.05  tff(decl_43878, type, fn_hershey_chase_experiment_4: $i > $i).
% 29.22/29.05  tff(decl_43879, type, solution_containing_labeled_phage_1: $i > $o).
% 29.22/29.05  tff(decl_43880, type, fn_hershey_chase_experiment_5: $i > $i).
% 29.22/29.05  tff(decl_43881, type, fn_hershey_chase_experiment_6: $i > $i).
% 29.22/29.05  tff(decl_43882, type, fn_hershey_chase_experiment_7: $i > $i).
% 29.22/29.05  tff(decl_43883, type, fn_hershey_chase_experiment_8: $i > $i).
% 29.22/29.05  tff(decl_43884, type, sulfur_35_1: $i > $o).
% 29.22/29.05  tff(decl_43885, type, fn_hershey_chase_experiment_9: $i > $i).
% 29.22/29.05  tff(decl_43886, type, phosphorus_32_1: $i > $o).
% 29.22/29.05  tff(decl_43887, type, fn_hershey_chase_experiment_10: $i > $i).
% 29.22/29.05  tff(decl_43888, type, fn_hershey_chase_experiment_11: $i > $i).
% 29.22/29.05  tff(decl_43889, type, fn_hershey_chase_experiment_12: $i > $i).
% 29.22/29.05  tff(decl_43890, type, isolation_of_phage_1: $i > $o).
% 29.22/29.05  tff(decl_43891, type, fn_hershey_chase_experiment_13: $i > $i).
% 29.22/29.05  tff(decl_43892, type, fn_hershey_chase_experiment_14: $i > $i).
% 29.22/29.05  tff(decl_43893, type, fn_hershey_chase_experiment_15: $i > $i).
% 29.22/29.05  tff(decl_43894, type, 'Heterochromatin': $i).
% 29.22/29.05  tff(decl_43895, type, 'Eukaryotic chromatin that remains highly compacted during interphase and is generally not transcribed.': $i).
% 29.22/29.05  tff(decl_43896, type, heterochromatin: $i).
% 29.22/29.05  tff(decl_43897, type, fn_heterochromatin_2: $i > $i).
% 29.22/29.05  tff(decl_43898, type, fn_heterochromatin_3: $i > $i).
% 29.22/29.05  tff(decl_43899, type, fn_heterochromatin_4: $i > $i).
% 29.22/29.05  tff(decl_43900, type, fn_heterochromatin_5: $i > $i).
% 29.22/29.05  tff(decl_43901, type, fn_heterochromatin_6: $i > $i).
% 29.22/29.05  tff(decl_43902, type, fn_heterochromatin_7: $i > $i).
% 29.22/29.05  tff(decl_43903, type, fn_heterochromatin_8: $i > $i).
% 29.22/29.05  tff(decl_43904, type, fn_heterochromatin_9: $i > $i).
% 29.22/29.05  tff(decl_43905, type, fn_heterochromatin_10: $i > $i).
% 29.22/29.05  tff(decl_43906, type, fn_heterochromatin_11: $i > $i).
% 29.22/29.05  tff(decl_43907, type, fn_heterochromatin_12: $i > $i).
% 29.22/29.05  tff(decl_43908, type, fn_heterochromatin_13: $i > $i).
% 29.22/29.05  tff(decl_43909, type, fn_heterochromatin_14: $i > $i).
% 29.22/29.05  tff(decl_43910, type, fn_heterochromatin_15: $i > $i).
% 29.22/29.05  tff(decl_43911, type, fn_heterochromatin_16: $i > $i).
% 29.22/29.05  tff(decl_43912, type, fn_heterochromatin_17: $i > $i).
% 29.22/29.05  tff(decl_43913, type, fn_heterochromatin_18: $i > $i).
% 29.22/29.05  tff(decl_43914, type, fn_heterochromatin_19: $i > $i).
% 29.22/29.05  tff(decl_43915, type, fn_heterochromatin_22: $i > $i).
% 29.22/29.05  tff(decl_43916, type, fn_heterochromatin_23: $i > $i).
% 29.22/29.05  tff(decl_43917, type, fn_heterochromatin_24: $i > $i).
% 29.22/29.05  tff(decl_43918, type, fn_heterochromatin_25: $i > $i).
% 29.22/29.05  tff(decl_43919, type, fn_heterochromatin_26: $i > $i).
% 29.22/29.05  tff(decl_43920, type, fn_heterochromatin_27: $i > $i).
% 29.22/29.05  tff(decl_43921, type, fn_heterochromatin_28: $i > $i).
% 29.22/29.05  tff(decl_43922, type, fn_heterochromatin_29: $i > $i).
% 29.22/29.05  tff(decl_43923, type, fn_heterochromatin_30: $i > $i).
% 29.22/29.05  tff(decl_43924, type, fn_heterochromatin_31: $i > $i).
% 29.22/29.05  tff(decl_43925, type, fn_heterochromatin_21: $i > $i).
% 29.22/29.05  tff(decl_43926, type, fn_heterochromatin_20: $i > $i).
% 29.22/29.05  tff(decl_43927, type, 'Heterochrony': $i).
% 29.22/29.05  tff(decl_43928, type, 'A change in the timing of developmental events or rate of growth.': $i).
% 29.22/29.05  tff(decl_43929, type, heterochrony: $i).
% 29.22/29.05  tff(decl_43930, type, 'Heterocyte': $i).
% 29.22/29.05  tff(decl_43931, type, 'A specialized cell that engages in nitrogen fixationin a chain of cyanobacteria that form a filament; formerly called heterocyst.': $i).
% 29.22/29.05  tff(decl_43932, type, heterocyte: $i).
% 29.22/29.05  tff(decl_43933, type, 'Heterogeneous-Mixture': $i).
% 29.22/29.05  tff(decl_43934, type, 'A substance which is not uniform throughout its composition.': $i).
% 29.22/29.05  tff(decl_43935, type, 'heterogeneous mixture': $i).
% 29.22/29.05  tff(decl_43936, type, 'heterogeneous-mixture': $i).
% 29.22/29.05  tff(decl_43937, type, 'Heterokaryon': $i).
% 29.22/29.05  tff(decl_43938, type, 'In a fungal mycelium, a cell containing at least two haploid nuclei.': $i).
% 29.22/29.05  tff(decl_43939, type, heterokaryon: $i).
% 29.22/29.05  tff(decl_43940, type, heteromorphic_1: $i > $o).
% 29.22/29.05  tff(decl_43941, type, 'Heteromorphic': $i).
% 29.22/29.05  tff(decl_43942, type, 'Having different forms at various stages of the life cycle, such as the sporophyte and gametophyte generations of plants and algae, and the larval and adult stages of many animals.': $i).
% 29.22/29.05  tff(decl_43943, type, heteromorphic: $i).
% 29.22/29.05  tff(decl_43944, type, 'Heterotroph': $i).
% 29.22/29.05  tff(decl_43945, type, 'An organism which obtains energy and nutrients from organic matter.': $i).
% 29.22/29.05  tff(decl_43946, type, 'heterotrophic organism': $i).
% 29.22/29.05  tff(decl_43947, type, 'non autrotrophic organism': $i).
% 29.22/29.05  tff(decl_43948, type, heterotroph: $i).
% 29.22/29.05  tff(decl_43949, type, fn_heterotroph_1: $i > $i).
% 29.22/29.05  tff(decl_43950, type, fn_heterotroph_6: $i > $i).
% 29.22/29.05  tff(decl_43951, type, fn_heterotroph_7: $i > $i).
% 29.22/29.05  tff(decl_43952, type, fn_heterotroph_8: $i > $i).
% 29.22/29.05  tff(decl_43953, type, fn_heterotroph_9: $i > $i).
% 29.22/29.05  tff(decl_43954, type, fn_heterotroph_10: $i > $i).
% 29.22/29.05  tff(decl_43955, type, fn_heterotroph_11: $i > $i).
% 29.22/29.05  tff(decl_43956, type, fn_heterotroph_12: $i > $i).
% 29.22/29.05  tff(decl_43957, type, fn_heterotroph_13: $i > $i).
% 29.22/29.05  tff(decl_43958, type, fn_heterotroph_14: $i > $i).
% 29.22/29.05  tff(decl_43959, type, fn_heterotroph_15: $i > $i).
% 29.22/29.05  tff(decl_43960, type, fn_heterotroph_16: $i > $i).
% 29.22/29.05  tff(decl_43961, type, fn_heterotroph_17: $i > $i).
% 29.22/29.05  tff(decl_43962, type, 'Heterozygote': $i).
% 29.22/29.05  tff(decl_43963, type, 'A person possessing two different forms of a particular gene, one inherited from each parent. A heterozygote is also called a carrier. For example, a woman who is a heterozygote for cystic fibrosis (CF) carries the CF gene on one of her chromosomes number 7 and the normal paired (non-CF) gene at the same position on her other chromosome 7. She is a carrier for CF but has no signs or symptoms of the disease. A manifesting heterozygote is a person who manifests signs or symptoms of what is usually a recessive condition and ordinarily only is evident in someone who has two copies of the gene. A compound heterozygote has two different mutant forms of a particular gene.': $i).
% 29.22/29.05  tff(decl_43964, type, heterozygote: $i).
% 29.22/29.05  tff(decl_43965, type, fn_heterozygote_1: $i > $i).
% 29.22/29.05  tff(decl_43966, type, fn_heterozygote_2: $i > $i).
% 29.22/29.05  tff(decl_43967, type, fn_heterozygote_3: $i > $i).
% 29.22/29.05  tff(decl_43968, type, fn_heterozygote_4: $i > $i).
% 29.22/29.05  tff(decl_43969, type, allele_0: $i).
% 29.22/29.05  tff(decl_43970, type, character_0: $i).
% 29.22/29.05  tff(decl_43971, type, heterozygote_advantage_1: $i > $o).
% 29.22/29.05  tff(decl_43972, type, 'Heterozygote-Advantage': $i).
% 29.22/29.05  tff(decl_43973, type, 'The situation in which heterozygous individuals have greater reproductive success when compared to homozygous individuals. This tends to preserve multiple alleles in a population.': $i).
% 29.22/29.05  tff(decl_43974, type, 'heterozygous advantage': $i).
% 29.22/29.05  tff(decl_43975, type, 'heterozygous-advantage': $i).
% 29.22/29.05  tff(decl_43976, type, 'advantage of heterozygote': $i).
% 29.22/29.05  tff(decl_43977, type, 'heterozygote advantage': $i).
% 29.22/29.05  tff(decl_43978, type, 'heterozygote-advantage': $i).
% 29.22/29.05  tff(decl_43979, type, 'Heterozygous': $i).
% 29.22/29.05  tff(decl_43980, type, 'Possessing two different alleles for a particular gene.': $i).
% 29.22/29.05  tff(decl_43981, type, heterozygous: $i).
% 29.22/29.05  tff(decl_43982, type, heterozygous_complete_dominant_1: $i > $o).
% 29.22/29.05  tff(decl_43983, type, 'Heterozygous-Complete-Dominant': $i).
% 29.22/29.05  tff(decl_43984, type, 'An individual that has two different alleles for the same gene.  One allele is dominant, and one is recessive.': $i).
% 29.22/29.05  tff(decl_43985, type, 'heterozygote complete dominant': $i).
% 29.22/29.05  tff(decl_43986, type, 'heterozygote-complete-dominant': $i).
% 29.22/29.05  tff(decl_43987, type, 'heterozygous complete dominant': $i).
% 29.22/29.05  tff(decl_43988, type, 'heterozygous-complete-dominant': $i).
% 29.22/29.05  tff(decl_43989, type, 'Heterozygous-Female': $i).
% 29.22/29.05  tff(decl_43990, type, 'A female who is heterozygous for an X chromosome gene.': $i).
% 29.22/29.05  tff(decl_43991, type, 'female of heterozygous': $i).
% 29.22/29.05  tff(decl_43992, type, 'heterozygous female': $i).
% 29.22/29.05  tff(decl_43993, type, 'heterozygous-female': $i).
% 29.22/29.05  tff(decl_43994, type, fn_heterozygous_female_1: $i > $i).
% 29.22/29.05  tff(decl_43995, type, fn_heterozygous_female_2: $i > $i).
% 29.22/29.05  tff(decl_43996, type, fn_heterozygous_female_3: $i > $i).
% 29.22/29.05  tff(decl_43997, type, fn_heterozygous_female_4: $i > $i).
% 29.22/29.05  tff(decl_43998, type, fn_heterozygous_female_5: $i > $i).
% 29.22/29.05  tff(decl_43999, type, 'Heterozygous-Trait-Incomplete-Dominance': $i).
% 29.22/29.05  tff(decl_44000, type, 'The phenoype of a heterozygous individual intermediate between the phenotypes of individuals homozygous for either allele.': $i).
% 29.22/29.05  tff(decl_44001, type, 'heterozygous trait incomplete dominance': $i).
% 29.22/29.05  tff(decl_44002, type, 'heterozygous-trait-incomplete-dominance': $i).
% 29.22/29.05  tff(decl_44003, type, fn_heterozygous_trait_incomplete_dominance_1: $i > $i).
% 29.22/29.05  tff(decl_44004, type, incomplete_dominance_1: $i > $o).
% 29.22/29.05  tff(decl_44005, type, fn_heterozygous_trait_incomplete_dominance_2: $i > $i).
% 29.22/29.05  tff(decl_44006, type, fn_heterozygous_trait_incomplete_dominance_3: $i > $i).
% 29.22/29.05  tff(decl_44007, type, 'Hexapod': $i).
% 29.22/29.05  tff(decl_44008, type, 'A group of arthropods possessing six legs; includes the insects as well as three smaller groups of wingless six-legged animals.': $i).
% 29.22/29.05  tff(decl_44009, type, hexapod: $i).
% 29.22/29.05  tff(decl_44010, type, 'Hexokinase': $i).
% 29.22/29.05  tff(decl_44011, type, 'A hexokinase is an enzyme that phosphorylates a six-carbon sugar, a hexose, to a hexose phosphate.': $i).
% 29.22/29.05  tff(decl_44012, type, hexokinase: $i).
% 29.22/29.05  tff(decl_44013, type, fn_hexokinase_1: $i > $i).
% 29.22/29.05  tff(decl_44014, type, fn_hexokinase_2: $i > $i).
% 29.22/29.05  tff(decl_44015, type, fn_hexokinase_3: $i > $i).
% 29.22/29.05  tff(decl_44016, type, fn_hexokinase_4: $i > $i).
% 29.22/29.05  tff(decl_44017, type, fn_hexokinase_5: $i > $i).
% 29.22/29.05  tff(decl_44018, type, fn_hexokinase_7: $i > $i).
% 29.22/29.05  tff(decl_44019, type, fn_hexokinase_10: $i > $i).
% 29.22/29.05  tff(decl_44020, type, fn_hexokinase_11: $i > $i).
% 29.22/29.05  tff(decl_44021, type, fn_hexokinase_12: $i > $i).
% 29.22/29.05  tff(decl_44022, type, fn_hexokinase_13: $i > $i).
% 29.22/29.05  tff(decl_44023, type, fn_hexokinase_14: $i > $i).
% 29.22/29.05  tff(decl_44024, type, fn_hexokinase_15: $i > $i).
% 29.22/29.05  tff(decl_44025, type, fn_hexokinase_16: $i > $i).
% 29.22/29.05  tff(decl_44026, type, fn_hexokinase_17: $i > $i).
% 29.22/29.05  tff(decl_44027, type, fn_hexokinase_18: $i > $i).
% 29.22/29.05  tff(decl_44028, type, fn_hexokinase_19: $i > $i).
% 29.22/29.05  tff(decl_44029, type, fn_hexokinase_20: $i > $i).
% 29.22/29.05  tff(decl_44030, type, 'Hexose': $i).
% 29.22/29.05  tff(decl_44031, type, 'Hexose is a monosaccharide with six carbon atoms, having the chemical formula C6H12O6.': $i).
% 29.22/29.05  tff(decl_44032, type, hexose: $i).
% 29.22/29.05  tff(decl_44033, type, fn_hexose_3: $i > $i).
% 29.22/29.05  tff(decl_44034, type, fn_hexose_4: $i > $i).
% 29.22/29.05  tff(decl_44035, type, fn_hexose_5: $i > $i).
% 29.22/29.05  tff(decl_44036, type, fn_hexose_6: $i > $i).
% 29.22/29.05  tff(decl_44037, type, fn_hexose_7: $i > $i).
% 29.22/29.05  tff(decl_44038, type, fn_hexose_8: $i > $i).
% 29.22/29.05  tff(decl_44039, type, fn_hexose_9: $i > $i).
% 29.22/29.05  tff(decl_44040, type, fn_hexose_10: $i > $i).
% 29.22/29.05  tff(decl_44041, type, fn_hexose_11: $i > $i).
% 29.22/29.05  tff(decl_44042, type, fn_hexose_12: $i > $i).
% 29.22/29.05  tff(decl_44043, type, fn_hexose_13: $i > $i).
% 29.22/29.05  tff(decl_44044, type, fn_hexose_14: $i > $i).
% 29.22/29.05  tff(decl_44045, type, fn_hexose_15: $i > $i).
% 29.22/29.05  tff(decl_44046, type, fn_hexose_16: $i > $i).
% 29.22/29.05  tff(decl_44047, type, fn_hexose_17: $i > $i).
% 29.22/29.05  tff(decl_44048, type, fn_hexose_18: $i > $i).
% 29.22/29.05  tff(decl_44049, type, fn_hexose_19: $i > $i).
% 29.22/29.05  tff(decl_44050, type, fn_hexose_20: $i > $i).
% 29.22/29.05  tff(decl_44051, type, fn_hexose_21: $i > $i).
% 29.22/29.05  tff(decl_44052, type, fn_hexose_22: $i > $i).
% 29.22/29.05  tff(decl_44053, type, fn_hexose_23: $i > $i).
% 29.22/29.05  tff(decl_44054, type, fn_hexose_2: $i > $i).
% 29.22/29.05  tff(decl_44055, type, fn_hexose_1: $i > $i).
% 29.22/29.05  tff(decl_44056, type, 'Hibernation': $i).
% 29.22/29.05  tff(decl_44057, type, 'A state of decreased metabolic rate, body temperature, and activity in mammals. Hibernation occurs in the winter and conserves energy at a time when food is scarce.': $i).
% 29.22/29.05  tff(decl_44058, type, hibernate: $i).
% 29.22/29.05  tff(decl_44059, type, hibernation: $i).
% 29.22/29.05  tff(decl_44060, type, fn_hibernation_2: $i > $i).
% 29.22/29.05  tff(decl_44061, type, fn_hibernation_3: $i > $i).
% 29.22/29.05  tff(decl_44062, type, fn_hibernation_4: $i > $i).
% 29.22/29.05  tff(decl_44063, type, fn_hibernation_5: $i > $i).
% 29.22/29.05  tff(decl_44064, type, fn_hibernation_7: $i > $i).
% 29.22/29.05  tff(decl_44065, type, fn_hibernation_8: $i > $i).
% 29.22/29.05  tff(decl_44066, type, fn_hibernation_9: $i > $i).
% 29.22/29.05  tff(decl_44067, type, fn_hibernation_10: $i > $i).
% 29.22/29.05  tff(decl_44068, type, fn_hibernation_12: $i > $i).
% 29.22/29.05  tff(decl_44069, type, fn_hibernation_13: $i > $i).
% 29.22/29.05  tff(decl_44070, type, fn_hibernation_14: $i > $i).
% 29.22/29.05  tff(decl_44071, type, fn_hibernation_15: $i > $i).
% 29.22/29.05  tff(decl_44072, type, fn_mammal_100: $i > $i).
% 29.22/29.05  tff(decl_44073, type, fn_mammal_90: $i > $i).
% 29.22/29.05  tff(decl_44074, type, mammal_0: $i).
% 29.22/29.05  tff(decl_44075, type, fn_hibernation_11: $i > $i).
% 29.22/29.05  tff(decl_44076, type, high_density_lipoprotein_1: $i > $o).
% 29.22/29.05  tff(decl_44077, type, 'High-Density-Lipoprotein': $i).
% 29.22/29.05  tff(decl_44078, type, 'One of five groups of lipoproteins that allow lipids such as triglycerides and cholesterol to be transported in the aqueous environment of blood.': $i).
% 29.22/29.05  tff(decl_44079, type, hdl: $i).
% 29.22/29.05  tff(decl_44080, type, 'high density lipoprotein': $i).
% 29.22/29.05  tff(decl_44081, type, 'high-density-lipoprotein': $i).
% 29.22/29.05  tff(decl_44082, type, lipoprotein_1: $i > $o).
% 29.22/29.05  tff(decl_44083, type, low_density_lipoprotein_1: $i > $o).
% 29.22/29.05  tff(decl_44084, type, 'Hindbrain': $i).
% 29.22/29.05  tff(decl_44085, type, 'The most posterior of the three embryonic and ancestral regions of the vertebrate brain. It develops into the cerebellum, pons, and medulla oblongata.': $i).
% 29.22/29.05  tff(decl_44086, type, rhombencephalon: $i).
% 29.22/29.05  tff(decl_44087, type, hindbrain: $i).
% 29.22/29.05  tff(decl_44088, type, 'Hindgut': $i).
% 29.22/29.05  tff(decl_44089, type, 'Posterior (hindmost) region of the alimentary canal in some animals which consists of the rectum and anus.': $i).
% 29.22/29.05  tff(decl_44090, type, hindgut: $i).
% 29.22/29.05  tff(decl_44091, type, 'Hinge-Joint': $i).
% 29.22/29.05  tff(decl_44092, type, 'A joint between two bones in which the bones are articulated so as to allow freedom of movement in a single plane only.': $i).
% 29.22/29.05  tff(decl_44093, type, 'joint of hinge': $i).
% 29.22/29.05  tff(decl_44094, type, 'hinge joint': $i).
% 29.22/29.05  tff(decl_44095, type, 'hinge-joint': $i).
% 29.22/29.05  tff(decl_44096, type, hirudinea_1: $i > $o).
% 29.22/29.05  tff(decl_44097, type, 'Hirudinea': $i).
% 29.22/29.05  tff(decl_44098, type, 'Annelid taxon that includes the leeches.': $i).
% 29.22/29.05  tff(decl_44099, type, hirudinea: $i).
% 29.22/29.05  tff(decl_44100, type, histamine_1: $i > $o).
% 29.22/29.05  tff(decl_44101, type, 'Histamine': $i).
% 29.22/29.05  tff(decl_44102, type, 'A substance released by the degranulation of mast cells. Histamine causes the dilation of blood vessels and triggers inflammatory and allergic responses.': $i).
% 29.22/29.05  tff(decl_44103, type, histamine: $i).
% 29.22/29.05  tff(decl_44104, type, histidine_1: $i > $o).
% 29.22/29.05  tff(decl_44105, type, 'Histidine': $i).
% 29.22/29.05  tff(decl_44106, type, histidine: $i).
% 29.22/29.05  tff(decl_44107, type, fn_histidine_1: $i > $i).
% 29.22/29.05  tff(decl_44108, type, fn_histidine_2: $i > $i).
% 29.22/29.05  tff(decl_44109, type, fn_histidine_3: $i > $i).
% 29.22/29.05  tff(decl_44110, type, fn_histidine_4: $i > $i).
% 29.22/29.05  tff(decl_44111, type, fn_histidine_5: $i > $i).
% 29.22/29.05  tff(decl_44112, type, fn_histidine_6: $i > $i).
% 29.22/29.05  tff(decl_44113, type, fn_histidine_7: $i > $i).
% 29.22/29.05  tff(decl_44114, type, fn_histidine_8: $i > $i).
% 29.22/29.05  tff(decl_44115, type, fn_histidine_9: $i > $i).
% 29.22/29.05  tff(decl_44116, type, fn_histidine_10: $i > $i).
% 29.22/29.05  tff(decl_44117, type, fn_histidine_11: $i > $i).
% 29.22/29.05  tff(decl_44118, type, fn_histidine_12: $i > $i).
% 29.22/29.05  tff(decl_44119, type, fn_histidine_13: $i > $i).
% 29.22/29.05  tff(decl_44120, type, fn_histidine_14: $i > $i).
% 29.22/29.05  tff(decl_44121, type, fn_histidine_15: $i > $i).
% 29.22/29.05  tff(decl_44122, type, fn_histidine_16: $i > $i).
% 29.22/29.05  tff(decl_44123, type, fn_histidine_17: $i > $i).
% 29.22/29.05  tff(decl_44124, type, fn_histidine_18: $i > $i).
% 29.22/29.05  tff(decl_44125, type, fn_histidine_19: $i > $i).
% 29.22/29.05  tff(decl_44126, type, fn_histidine_20: $i > $i).
% 29.22/29.05  tff(decl_44127, type, fn_histidine_21: $i > $i).
% 29.22/29.05  tff(decl_44128, type, fn_histidine_22: $i > $i).
% 29.22/29.05  tff(decl_44129, type, fn_histidine_23: $i > $i).
% 29.22/29.05  tff(decl_44130, type, fn_histidine_24: $i > $i).
% 29.22/29.05  tff(decl_44131, type, fn_histidine_25: $i > $i).
% 29.22/29.05  tff(decl_44132, type, fn_histidine_26: $i > $i).
% 29.22/29.05  tff(decl_44133, type, fn_histidine_27: $i > $i).
% 29.22/29.05  tff(decl_44134, type, fn_histidine_28: $i > $i).
% 29.22/29.05  tff(decl_44135, type, fn_histidine_29: $i > $i).
% 29.22/29.05  tff(decl_44136, type, fn_histidine_30: $i > $i).
% 29.22/29.05  tff(decl_44137, type, fn_histidine_31: $i > $i).
% 29.22/29.05  tff(decl_44138, type, fn_histidine_32: $i > $i).
% 29.22/29.05  tff(decl_44139, type, fn_histidine_33: $i > $i).
% 29.22/29.05  tff(decl_44140, type, fn_histidine_34: $i > $i).
% 29.22/29.05  tff(decl_44141, type, fn_histidine_35: $i > $i).
% 29.22/29.05  tff(decl_44142, type, fn_histidine_36: $i > $i).
% 29.22/29.05  tff(decl_44143, type, fn_histidine_37: $i > $i).
% 29.22/29.05  tff(decl_44144, type, fn_histidine_38: $i > $i).
% 29.22/29.05  tff(decl_44145, type, fn_histidine_39: $i > $i).
% 29.22/29.05  tff(decl_44146, type, fn_histidine_40: $i > $i).
% 29.22/29.05  tff(decl_44147, type, fn_histidine_41: $i > $i).
% 29.22/29.05  tff(decl_44148, type, fn_histidine_42: $i > $i).
% 29.22/29.05  tff(decl_44149, type, fn_histidine_43: $i > $i).
% 29.22/29.05  tff(decl_44150, type, fn_histidine_44: $i > $i).
% 29.22/29.05  tff(decl_44151, type, 'Histone': $i).
% 29.22/29.05  tff(decl_44152, type, 'A small protein with a high proportion of positively charged amino acids that binds to the negatively charged DNA and plays a key role in chromatin structure.': $i).
% 29.22/29.05  tff(decl_44153, type, histone: $i).
% 29.22/29.05  tff(decl_44154, type, fn_histone_5: $i > $i).
% 29.22/29.05  tff(decl_44155, type, fn_histone_6: $i > $i).
% 29.22/29.05  tff(decl_44156, type, fn_histone_7: $i > $i).
% 29.22/29.05  tff(decl_44157, type, fn_histone_8: $i > $i).
% 29.22/29.05  tff(decl_44158, type, fn_histone_9: $i > $i).
% 29.22/29.05  tff(decl_44159, type, fn_histone_10: $i > $i).
% 29.22/29.05  tff(decl_44160, type, fn_histone_16: $i > $i).
% 29.22/29.05  tff(decl_44161, type, fn_histone_17: $i > $i).
% 29.22/29.05  tff(decl_44162, type, fn_histone_18: $i > $i).
% 29.22/29.05  tff(decl_44163, type, fn_histone_19: $i > $i).
% 29.22/29.05  tff(decl_44164, type, fn_histone_20: $i > $i).
% 29.22/29.05  tff(decl_44165, type, fn_histone_21: $i > $i).
% 29.22/29.05  tff(decl_44166, type, fn_histone_22: $i > $i).
% 29.22/29.05  tff(decl_44167, type, fn_histone_23: $i > $i).
% 29.22/29.05  tff(decl_44168, type, fn_histone_24: $i > $i).
% 29.22/29.05  tff(decl_44169, type, fn_histone_25: $i > $i).
% 29.22/29.05  tff(decl_44170, type, fn_histone_26: $i > $i).
% 29.22/29.05  tff(decl_44171, type, fn_histone_27: $i > $i).
% 29.22/29.05  tff(decl_44172, type, fn_histone_28: $i > $i).
% 29.22/29.05  tff(decl_44173, type, fn_histone_29: $i > $i).
% 29.22/29.05  tff(decl_44174, type, fn_histone_31: $i > $i).
% 29.22/29.05  tff(decl_44175, type, fn_histone_32: $i > $i).
% 29.22/29.05  tff(decl_44176, type, fn_histone_33: $i > $i).
% 29.22/29.05  tff(decl_44177, type, fn_histone_34: $i > $i).
% 29.22/29.05  tff(decl_44178, type, fn_histone_35: $i > $i).
% 29.22/29.05  tff(decl_44179, type, fn_histone_36: $i > $i).
% 29.22/29.05  tff(decl_44180, type, fn_histone_15: $i > $i).
% 29.22/29.05  tff(decl_44181, type, fn_histone_14: $i > $i).
% 29.22/29.05  tff(decl_44182, type, fn_histone_13: $i > $i).
% 29.22/29.05  tff(decl_44183, type, fn_histone_12: $i > $i).
% 29.22/29.05  tff(decl_44184, type, fn_histone_30: $i > $i).
% 29.22/29.05  tff(decl_44185, type, fn_histone_acetylation_11: $i > $i).
% 29.22/29.05  tff(decl_44186, type, fn_histone_acetylation_6: $i > $i).
% 29.22/29.05  tff(decl_44187, type, fn_histone_acetylation_12: $i > $i).
% 29.22/29.05  tff(decl_44188, type, 'Histone-Acetylation': $i).
% 29.22/29.05  tff(decl_44189, type, 'The attachment of acetyl groups to certain amino acids of histone proteins.': $i).
% 29.22/29.05  tff(decl_44190, type, 'acetylation of histone': $i).
% 29.22/29.05  tff(decl_44191, type, 'histone acetylation': $i).
% 29.22/29.05  tff(decl_44192, type, 'histone-acetylation': $i).
% 29.22/29.05  tff(decl_44193, type, fn_histone_acetylation_1: $i > $i).
% 29.22/29.05  tff(decl_44194, type, fn_histone_acetylation_2: $i > $i).
% 29.22/29.05  tff(decl_44195, type, fn_histone_acetylation_3: $i > $i).
% 29.22/29.05  tff(decl_44196, type, fn_histone_acetylation_5: $i > $i).
% 29.22/29.05  tff(decl_44197, type, fn_histone_acetylation_7: $i > $i).
% 29.22/29.05  tff(decl_44198, type, fn_histone_acetylation_8: $i > $i).
% 29.22/29.05  tff(decl_44199, type, fn_histone_acetylation_9: $i > $i).
% 29.22/29.05  tff(decl_44200, type, fn_histone_acetylation_10: $i > $i).
% 29.22/29.05  tff(decl_44201, type, 'HIV': $i).
% 29.22/29.05  tff(decl_44202, type, 'A retrovirus that has been identified as the causative agent of AIDS.': $i).
% 29.22/29.05  tff(decl_44203, type, 'human immunodeficiency virus': $i).
% 29.22/29.05  tff(decl_44204, type, hiv: $i).
% 29.22/29.05  tff(decl_44205, type, htlv_1: $i > $o).
% 29.22/29.05  tff(decl_44206, type, fn_hiv_1: $i > $i).
% 29.22/29.05  tff(decl_44207, type, fn_hiv_2: $i > $i).
% 29.22/29.05  tff(decl_44208, type, fn_hiv_3: $i > $i).
% 29.22/29.05  tff(decl_44209, type, fn_hiv_4: $i > $i).
% 29.22/29.05  tff(decl_44210, type, fn_hiv_5: $i > $i).
% 29.22/29.05  tff(decl_44211, type, fn_hiv_6: $i > $i).
% 29.22/29.05  tff(decl_44212, type, fn_hiv_7: $i > $i).
% 29.22/29.05  tff(decl_44213, type, fn_viral_infection_10: $i > $i).
% 29.22/29.05  tff(decl_44214, type, fn_viral_infection_16: $i > $i).
% 29.22/29.05  tff(decl_44215, type, fn_virus_1: $i > $i).
% 29.22/29.05  tff(decl_44216, type, fn_virus_23: $i > $i).
% 29.22/29.05  tff(decl_44217, type, 'Hold': $i).
% 29.22/29.05  tff(decl_44218, type, 'hold up': $i).
% 29.22/29.05  tff(decl_44219, type, hold_up: $i).
% 29.22/29.05  tff(decl_44220, type, sustain: $i).
% 29.22/29.05  tff(decl_44221, type, 'take hold': $i).
% 29.22/29.05  tff(decl_44222, type, take_hold: $i).
% 29.22/29.05  tff(decl_44223, type, grasp: $i).
% 29.22/29.05  tff(decl_44224, type, 'Hold-Together': $i).
% 29.22/29.05  tff(decl_44225, type, 'To be joined and not separate.': $i).
% 29.22/29.05  tff(decl_44226, type, bind: $i).
% 29.22/29.05  tff(decl_44227, type, 'hold together': $i).
% 29.22/29.05  tff(decl_44228, type, 'hold-together': $i).
% 29.22/29.05  tff(decl_44229, type, holdfast_1: $i > $o).
% 29.22/29.05  tff(decl_44230, type, 'Holdfast': $i).
% 29.22/29.05  tff(decl_44231, type, 'The part of a seaweed body that anchors to a hard surface.': $i).
% 29.22/29.05  tff(decl_44232, type, protist_structure_1: $i > $o).
% 29.22/29.05  tff(decl_44233, type, holmium_1: $i > $o).
% 29.22/29.05  tff(decl_44234, type, 'Holmium': $i).
% 29.22/29.05  tff(decl_44235, type, 'Holmium is a metal atom with atomic number 67. It is represented by the symbol Ho.': $i).
% 29.22/29.05  tff(decl_44236, type, holmium: $i).
% 29.22/29.05  tff(decl_44237, type, ho: $i).
% 29.22/29.05  tff(decl_44238, type, fn_holmium_4: $i > $i).
% 29.22/29.05  tff(decl_44239, type, fn_holmium_5: $i > $i).
% 29.22/29.05  tff(decl_44240, type, fn_holmium_6: $i > $i).
% 29.22/29.05  tff(decl_44241, type, fn_holmium_7: $i > $i).
% 29.22/29.05  tff(decl_44242, type, fn_holmium_11: $i > $i).
% 29.22/29.05  tff(decl_44243, type, fn_holmium_12: $i > $i).
% 29.22/29.05  tff(decl_44244, type, fn_holmium_13: $i > $i).
% 29.22/29.05  tff(decl_44245, type, fn_holmium_14: $i > $i).
% 29.22/29.05  tff(decl_44246, type, "67": $i).
% 29.22/29.05  tff(decl_44247, type, "1.23": $i).
% 29.22/29.05  tff(decl_44248, type, "165": $i).
% 29.22/29.05  tff(decl_44249, type, "164.9": $i).
% 29.22/29.05  tff(decl_44250, type, fn_holmium_9: $i > $i).
% 29.22/29.05  tff(decl_44251, type, fn_holmium_10: $i > $i).
% 29.22/29.05  tff(decl_44252, type, fn_holmium_8: $i > $i).
% 29.22/29.05  tff(decl_44253, type, 'Holoblastic-Cleavage': $i).
% 29.22/29.05  tff(decl_44254, type, 'A type of cleavage division in which cells divide completely; typically occurs in animals with small eggs, such as sea urchins, or with eggs containing only moderate amounts of yolk, such as frogs.': $i).
% 29.22/29.05  tff(decl_44255, type, 'undergo holoblastic cleavage': $i).
% 29.22/29.05  tff(decl_44256, type, 'holoblastic cleavage': $i).
% 29.22/29.05  tff(decl_44257, type, 'holoblastic-cleavage': $i).
% 29.22/29.05  tff(decl_44258, type, home_1: $i > $o).
% 29.22/29.05  tff(decl_44259, type, 'Home': $i).
% 29.22/29.05  tff(decl_44260, type, 'Location of residence': $i).
% 29.22/29.05  tff(decl_44261, type, homeobox_1: $i > $o).
% 29.22/29.05  tff(decl_44262, type, 'Homeobox': $i).
% 29.22/29.05  tff(decl_44263, type, 'A DNA sequence that occurs within genes that regulate  morphogenesis (establishment of body axes) in eukaryotic organisms.': $i).
% 29.22/29.05  tff(decl_44264, type, homeobox: $i).
% 29.22/29.05  tff(decl_44265, type, fn_homeobox_1: $i > $i).
% 29.22/29.05  tff(decl_44266, type, homeodomain_1: $i > $o).
% 29.22/29.05  tff(decl_44267, type, fn_homeobox_2: $i > $i).
% 29.22/29.05  tff(decl_44268, type, fn_homeobox_3: $i > $i).
% 29.22/29.05  tff(decl_44269, type, homeobox_containing_gene_1: $i > $o).
% 29.22/29.05  tff(decl_44270, type, fn_homeobox_containing_gene_1: $i > $i).
% 29.22/29.05  tff(decl_44271, type, 'Homeobox-Containing-Gene': $i).
% 29.22/29.05  tff(decl_44272, type, 'A gene with a homeobox as a part is a homeobox containing gene.': $i).
% 29.22/29.05  tff(decl_44273, type, hoxgene: $i).
% 29.22/29.05  tff(decl_44274, type, 'homeobox containing gene': $i).
% 29.22/29.05  tff(decl_44275, type, 'homeobox-containing-gene': $i).
% 29.22/29.05  tff(decl_44276, type, 'Homeodomain': $i).
% 29.22/29.05  tff(decl_44277, type, 'A highly conserved protein sequence motif. It comprises 60 amino acids and contains a DNA-binding helixturnhelix motif indicating that acts as a transcription factor. The homeodomain is encoded for by a homeobox.': $i).
% 29.22/29.05  tff(decl_44278, type, homeodomain: $i).
% 29.22/29.05  tff(decl_44279, type, fn_homeodomain_1: $i > $i).
% 29.22/29.05  tff(decl_44280, type, fn_homeodomain_2: $i > $i).
% 29.22/29.05  tff(decl_44281, type, fn_homeodomain_3: $i > $i).
% 29.22/29.05  tff(decl_44282, type, fn_homeodomain_4: $i > $i).
% 29.22/29.05  tff(decl_44283, type, fn_homeodomain_5: $i > $i).
% 29.22/29.05  tff(decl_44284, type, fn_homeodomain_6: $i > $i).
% 29.22/29.05  tff(decl_44285, type, fn_homeodomain_8: $i > $i).
% 29.22/29.05  tff(decl_44286, type, fn_homeodomain_9: $i > $i).
% 29.22/29.05  tff(decl_44287, type, 'Homeodomain-Protein': $i).
% 29.22/29.05  tff(decl_44288, type, 'A protein containing a homeoprotein domain.': $i).
% 29.22/29.05  tff(decl_44289, type, 'homeodomain containing protein': $i).
% 29.22/29.05  tff(decl_44290, type, 'protein of homeodomain': $i).
% 29.22/29.05  tff(decl_44291, type, 'homeodomain protein': $i).
% 29.22/29.05  tff(decl_44292, type, 'homeodomain-protein': $i).
% 29.22/29.05  tff(decl_44293, type, fn_homeodomain_protein_1: $i > $i).
% 29.22/29.05  tff(decl_44294, type, fn_homeodomain_protein_2: $i > $i).
% 29.22/29.05  tff(decl_44295, type, homeostasis_1: $i > $o).
% 29.22/29.05  tff(decl_44296, type, 'Homeostasis': $i).
% 29.22/29.05  tff(decl_44297, type, 'The maintenance of internal conditions within survivable parameters.': $i).
% 29.22/29.05  tff(decl_44298, type, homeostasis: $i).
% 29.22/29.05  tff(decl_44299, type, 'Homeostatic-Response': $i).
% 29.22/29.05  tff(decl_44300, type, 'A physiological response that returns a variable to its set point.': $i).
% 29.22/29.05  tff(decl_44301, type, 'homeostatic response': $i).
% 29.22/29.05  tff(decl_44302, type, 'homeostatic-response': $i).
% 29.22/29.05  tff(decl_44303, type, 'Homeotic-Gene': $i).
% 29.22/29.05  tff(decl_44304, type, 'Any of a set of regulatory genes involved in developmental patterns and sequence. Homeotic genes control the placement and arrangement of body parts in eukaryotic organisms.': $i).
% 29.22/29.05  tff(decl_44305, type, 'homeotic gene': $i).
% 29.22/29.05  tff(decl_44306, type, 'homeotic-gene': $i).
% 29.22/29.05  tff(decl_44307, type, myod_gene_1: $i > $o).
% 29.22/29.05  tff(decl_44308, type, fn_homeotic_gene_1: $i > $i).
% 29.22/29.05  tff(decl_44309, type, fn_homeotic_gene_2: $i > $i).
% 29.22/29.05  tff(decl_44310, type, fn_homeotic_gene_3: $i > $i).
% 29.22/29.05  tff(decl_44311, type, fn_homeotic_gene_4: $i > $i).
% 29.22/29.05  tff(decl_44312, type, fn_homeotic_gene_5: $i > $i).
% 29.22/29.05  tff(decl_44313, type, fn_homeotic_gene_6: $i > $i).
% 29.22/29.05  tff(decl_44314, type, fn_homeotic_gene_7: $i > $i).
% 29.22/29.05  tff(decl_44315, type, fn_master_control_gene_4: $i > $i).
% 29.22/29.05  tff(decl_44316, type, 'Hominid': $i).
% 29.22/29.05  tff(decl_44317, type, 'A species on the human branch of the evolutionary tree. Hominins include Homo sapiens and our ancestors, a group of extinct species that are more closely related to us than to chimpanzees.': $i).
% 29.22/29.05  tff(decl_44318, type, hominid: $i).
% 29.22/29.05  tff(decl_44319, type, 'Homo-Erectus': $i).
% 29.22/29.05  tff(decl_44320, type, 'The first hominid species to migrate out of Africa. H. erectus lived from about 1.8 million years ago to 500,000 years ago, and compared to H. habilis, was taller and had a larger brain.': $i).
% 29.22/29.05  tff(decl_44321, type, 'homo erectus': $i).
% 29.22/29.05  tff(decl_44322, type, 'homo-erectus': $i).
% 29.22/29.05  tff(decl_44323, type, 'Homo-Ergaster': $i).
% 29.22/29.05  tff(decl_44324, type, 'An extinct hominid that lived in eastern and southern Africa during the early Pleistocene, about 1.7 to 1.3 million years ago.': $i).
% 29.22/29.05  tff(decl_44325, type, 'homo ergaster': $i).
% 29.22/29.05  tff(decl_44326, type, 'homo-ergaster': $i).
% 29.22/29.05  tff(decl_44327, type, 'Homo-Habilis': $i).
% 29.22/29.05  tff(decl_44328, type, 'The earliest ancestor of the Homo genus. The fossils range in age from about 2.5 to 1.6 million years old and show an ape-like body with disproportionately long arms and a cranial capacity slightly less than that of modern humans. H. habilis remains are often found with stone tools.': $i).
% 29.22/29.05  tff(decl_44329, type, 'homo habilis': $i).
% 29.22/29.05  tff(decl_44330, type, 'homo-habilis': $i).
% 29.22/29.05  tff(decl_44331, type, 'Homo-Heidelbergensis': $i).
% 29.22/29.05  tff(decl_44332, type, 'aAn extinct species of the genus Homo which lived from 2.33 to 1.4 million years ago. This species may be the direct ancestor of both Homo neanderthalensis in Europe and Homo sapiens.': $i).
% 29.22/29.05  tff(decl_44333, type, 'homo heidelbergensis': $i).
% 29.22/29.05  tff(decl_44334, type, 'homo-heidelbergensis': $i).
% 29.22/29.05  tff(decl_44335, type, 'Homo-Sapiens': $i).
% 29.22/29.05  tff(decl_44336, type, 'Anatomically and behaviorally modern humans; the only extant species in the genus Homo.': $i).
% 29.22/29.05  tff(decl_44337, type, 'homo sapiens': $i).
% 29.22/29.05  tff(decl_44338, type, 'homo-sapiens': $i).
% 29.22/29.05  tff(decl_44339, type, 'homo sapiens sapiens': $i).
% 29.22/29.05  tff(decl_44340, type, 'homo-sapiens-sapiens': $i).
% 29.22/29.05  tff(decl_44341, type, 'homo sapien': $i).
% 29.22/29.05  tff(decl_44342, type, 'homo-sapien': $i).
% 29.22/29.05  tff(decl_44343, type, 'Homogenate': $i).
% 29.22/29.05  tff(decl_44344, type, 'A homogenate is a mixture of the remnants of a tissue after it has been broken down such as by a blender, prior to further processing such as accomplished by centrifuging.': $i).
% 29.22/29.05  tff(decl_44345, type, homogenate: $i).
% 29.22/29.05  tff(decl_44346, type, fn_homogenate_1: $i > $i).
% 29.22/29.05  tff(decl_44347, type, 'Homogeneous-Mixture': $i).
% 29.22/29.05  tff(decl_44348, type, 'A substance that is uniform throughout in properties and composition.': $i).
% 29.22/29.05  tff(decl_44349, type, 'homogeneous mixture': $i).
% 29.22/29.05  tff(decl_44350, type, 'homogeneous-mixture': $i).
% 29.22/29.05  tff(decl_44351, type, 'Homogenization': $i).
% 29.22/29.05  tff(decl_44352, type, 'Homogenization is the process of breaking apart of a cell. It produces a homogenate.': $i).
% 29.22/29.05  tff(decl_44353, type, homogenize: $i).
% 29.22/29.05  tff(decl_44354, type, homogenization: $i).
% 29.22/29.05  tff(decl_44355, type, fn_homogenization_1: $i > $i).
% 29.22/29.05  tff(decl_44356, type, fn_homogenization_2: $i > $i).
% 29.22/29.05  tff(decl_44357, type, 'Homologous-chromosome': $i).
% 29.22/29.05  tff(decl_44358, type, 'Homologous chromosome is one of the pair of chromosomes (termed as homologous chromosomes) which is genetically identical to its corresponding homologous chromosome by having same DNA sequence throughout their length': $i).
% 29.22/29.05  tff(decl_44359, type, 'homologous chromosome': $i).
% 29.22/29.05  tff(decl_44360, type, 'homologous-chromosome': $i).
% 29.22/29.05  tff(decl_44361, type, homologous_gene_1: $i > $o).
% 29.22/29.05  tff(decl_44362, type, 'Homologous-Gene': $i).
% 29.22/29.05  tff(decl_44363, type, 'Genes that are common among different species which indicate common ancestry.': $i).
% 29.22/29.05  tff(decl_44364, type, 'homologous gene': $i).
% 29.22/29.05  tff(decl_44365, type, 'homologous-gene': $i).
% 29.22/29.05  tff(decl_44366, type, 'Homology': $i).
% 29.22/29.05  tff(decl_44367, type, 'Similarity of structure and function due to shared evolutionary ancestry.': $i).
% 29.22/29.05  tff(decl_44368, type, homologize: $i).
% 29.22/29.05  tff(decl_44369, type, homology: $i).
% 29.22/29.05  tff(decl_44370, type, homozygote_1: $i > $o).
% 29.22/29.05  tff(decl_44371, type, 'Homozygote': $i).
% 29.22/29.05  tff(decl_44372, type, 'An individual that is homozygous.': $i).
% 29.22/29.05  tff(decl_44373, type, homozygote: $i).
% 29.22/29.05  tff(decl_44374, type, fn_homozygote_1: $i > $i).
% 29.22/29.05  tff(decl_44375, type, 'Homozygous': $i).
% 29.22/29.05  tff(decl_44376, type, 'Having two identical alleles for a given gene.': $i).
% 29.22/29.05  tff(decl_44377, type, homozygous: $i).
% 29.22/29.05  tff(decl_44378, type, fn_homozygous_1: $i > $i).
% 29.22/29.05  tff(decl_44379, type, fn_homozygous_2: $i > $i).
% 29.22/29.05  tff(decl_44380, type, true_breeding_1: $i > $o).
% 29.22/29.05  tff(decl_44381, type, fn_homozygous_3: $i > $i).
% 29.22/29.05  tff(decl_44382, type, 'Homozygous-Dominant': $i).
% 29.22/29.05  tff(decl_44383, type, 'An individual who carries two copies of the allele that code for the dominant trait.': $i).
% 29.22/29.05  tff(decl_44384, type, 'dominant homozygote': $i).
% 29.22/29.05  tff(decl_44385, type, 'dominant of homozygous': $i).
% 29.22/29.05  tff(decl_44386, type, 'homozygous dominant': $i).
% 29.22/29.05  tff(decl_44387, type, 'homozygous-dominant': $i).
% 29.22/29.05  tff(decl_44388, type, fn_homozygous_dominant_1: $i > $i).
% 29.22/29.05  tff(decl_44389, type, fn_homozygous_dominant_2: $i > $i).
% 29.22/29.05  tff(decl_44390, type, 'Homozygous-Dominant-Cross': $i).
% 29.22/29.05  tff(decl_44391, type, 'A cross breeding event in which homozygous dominant male is crossed with homozygous dominant female and resultant is homozygous dominant offspring.': $i).
% 29.22/29.05  tff(decl_44392, type, 'homozygous dominant cross': $i).
% 29.22/29.05  tff(decl_44393, type, 'homozygous-dominant-cross': $i).
% 29.22/29.05  tff(decl_44394, type, fn_homozygous_dominant_cross_1: $i > $i).
% 29.22/29.05  tff(decl_44395, type, fn_homozygous_dominant_cross_2: $i > $i).
% 29.22/29.05  tff(decl_44396, type, fn_homozygous_dominant_cross_3: $i > $i).
% 29.22/29.05  tff(decl_44397, type, fn_homozygous_dominant_cross_4: $i > $i).
% 29.22/29.05  tff(decl_44398, type, fn_homozygous_dominant_cross_5: $i > $i).
% 29.22/29.05  tff(decl_44399, type, fn_homozygous_dominant_cross_6: $i > $i).
% 29.22/29.05  tff(decl_44400, type, fn_homozygous_dominant_cross_7: $i > $i).
% 29.22/29.05  tff(decl_44401, type, fn_homozygous_dominant_cross_8: $i > $i).
% 29.22/29.05  tff(decl_44402, type, 'Homozygous-Dominant-Female': $i).
% 29.22/29.05  tff(decl_44403, type, 'A female who is homozygous dominant for an X chromosome gene.': $i).
% 29.22/29.05  tff(decl_44404, type, 'homozygous dominant female': $i).
% 29.22/29.05  tff(decl_44405, type, 'homozygous-dominant-female': $i).
% 29.22/29.05  tff(decl_44406, type, homozygous_recessive_female_1: $i > $o).
% 29.22/29.05  tff(decl_44407, type, fn_homozygous_dominant_female_1: $i > $i).
% 29.22/29.05  tff(decl_44408, type, fn_homozygous_dominant_female_2: $i > $i).
% 29.22/29.05  tff(decl_44409, type, 'Homozygous-Recessive': $i).
% 29.22/29.05  tff(decl_44410, type, 'An individual who carries two copies of the allele that code for the recessive trait.': $i).
% 29.22/29.05  tff(decl_44411, type, 'homozygous recessive': $i).
% 29.22/29.05  tff(decl_44412, type, 'homozygous-recessive': $i).
% 29.22/29.05  tff(decl_44413, type, 'recessive homozygote': $i).
% 29.22/29.05  tff(decl_44414, type, 'recessive of homozygous': $i).
% 29.22/29.05  tff(decl_44415, type, fn_homozygous_recessive_1: $i > $i).
% 29.22/29.05  tff(decl_44416, type, fn_homozygous_recessive_2: $i > $i).
% 29.22/29.05  tff(decl_44417, type, 'Homozygous-Recessive-Cross': $i).
% 29.22/29.05  tff(decl_44418, type, 'A cross breeding event in which homozygous recessive male is crossed with homozygous recessive female and resultant is homozygous recessive offspring.': $i).
% 29.22/29.05  tff(decl_44419, type, 'homozygous recessive cross': $i).
% 29.22/29.05  tff(decl_44420, type, 'homozygous-recessive-cross': $i).
% 29.22/29.05  tff(decl_44421, type, fn_homozygous_recessive_cross_1: $i > $i).
% 29.22/29.05  tff(decl_44422, type, fn_homozygous_recessive_cross_2: $i > $i).
% 29.22/29.05  tff(decl_44423, type, fn_homozygous_recessive_cross_3: $i > $i).
% 29.22/29.05  tff(decl_44424, type, fn_homozygous_recessive_cross_4: $i > $i).
% 29.22/29.05  tff(decl_44425, type, fn_homozygous_recessive_cross_5: $i > $i).
% 29.22/29.05  tff(decl_44426, type, fn_homozygous_recessive_cross_6: $i > $i).
% 29.22/29.05  tff(decl_44427, type, fn_homozygous_recessive_cross_7: $i > $i).
% 29.22/29.05  tff(decl_44428, type, fn_homozygous_recessive_cross_8: $i > $i).
% 29.22/29.05  tff(decl_44429, type, 'Homozygous-Recessive-Female': $i).
% 29.22/29.05  tff(decl_44430, type, 'Homozygous recessive female carries both sex chromosomes having recessive alleles.': $i).
% 29.22/29.05  tff(decl_44431, type, 'homozygous recessive female': $i).
% 29.22/29.05  tff(decl_44432, type, 'homozygous-recessive-female': $i).
% 29.22/29.05  tff(decl_44433, type, fn_homozygous_recessive_female_1: $i > $i).
% 29.22/29.05  tff(decl_44434, type, fn_homozygous_recessive_female_2: $i > $i).
% 29.22/29.05  tff(decl_44435, type, homunculus_1: $i > $o).
% 29.22/29.05  tff(decl_44436, type, 'Homunculus': $i).
% 29.22/29.05  tff(decl_44437, type, 'The distorted scale model of a human drawn or sculpted to reflect the relative space human body parts occupy on the somatosensory cortex (sensory homunculus) and the motor cortex (motor homunculus).': $i).
% 29.22/29.05  tff(decl_44438, type, homunculus: $i).
% 29.22/29.05  tff(decl_44439, type, honeybee_1: $i > $o).
% 29.22/29.05  tff(decl_44440, type, 'Honeybee': $i).
% 29.22/29.05  tff(decl_44441, type, 'Subset of bees in the order Hymenoptera, distinguished from other bees by a highly organized colonial lifestyle, the construction of perennial nests made of wax, and the production of honey from nectar.': $i).
% 29.22/29.05  tff(decl_44442, type, honeybee: $i).
% 29.22/29.05  tff(decl_44443, type, 'Horizontal-Cell': $i).
% 29.22/29.05  tff(decl_44444, type, 'Neuron of the mammalian retina that integrates information from the photoreceptors before it is sent to the brain.': $i).
% 29.22/29.05  tff(decl_44445, type, 'cell of horizontal': $i).
% 29.22/29.05  tff(decl_44446, type, 'horizontal cell': $i).
% 29.22/29.05  tff(decl_44447, type, 'horizontal-cell': $i).
% 29.22/29.05  tff(decl_44448, type, 'Horizontal-Gene-Transfer': $i).
% 29.22/29.05  tff(decl_44449, type, 'The transfer of genes from one genome to another through mechanisms such as transposable elements, plasmid exchange, viral activity, and perhaps fusions of different organisms.': $i).
% 29.22/29.05  tff(decl_44450, type, hgt: $i).
% 29.22/29.05  tff(decl_44451, type, 'lateral gene transfer': $i).
% 29.22/29.05  tff(decl_44452, type, 'lateral-gene-transfer': $i).
% 29.22/29.05  tff(decl_44453, type, lgt: $i).
% 29.22/29.05  tff(decl_44454, type, 'horizontal gene transfer': $i).
% 29.22/29.05  tff(decl_44455, type, 'horizontal-gene-transfer': $i).
% 29.22/29.05  tff(decl_44456, type, fn_horizontal_gene_transfer_1: $i > $i).
% 29.22/29.05  tff(decl_44457, type, horizontal_transmission_1: $i > $o).
% 29.22/29.05  tff(decl_44458, type, 'Horizontal-Transmission': $i).
% 29.22/29.05  tff(decl_44459, type, 'When a plant is infected from an external source of the virus.': $i).
% 29.22/29.05  tff(decl_44460, type, 'transmission of horizontal': $i).
% 29.22/29.05  tff(decl_44461, type, 'horizontal transmission': $i).
% 29.22/29.05  tff(decl_44462, type, 'horizontal-transmission': $i).
% 29.22/29.05  tff(decl_44463, type, vertical_transmission_1: $i > $o).
% 29.22/29.05  tff(decl_44464, type, fn_horizontal_transmission_1: $i > $i).
% 29.22/29.05  tff(decl_44465, type, fn_horizontal_transmission_2: $i > $i).
% 29.22/29.05  tff(decl_44466, type, fn_horizontal_transmission_3: $i > $i).
% 29.22/29.05  tff(decl_44467, type, fn_horizontal_transmission_4: $i > $i).
% 29.22/29.05  tff(decl_44468, type, fn_horizontal_transmission_5: $i > $i).
% 29.22/29.05  tff(decl_44469, type, fn_horizontal_transmission_6: $i > $i).
% 29.22/29.05  tff(decl_44470, type, plant_virus_1: $i > $o).
% 29.22/29.05  tff(decl_44471, type, 'Hormonal-Signaling-In-Plant': $i).
% 29.22/29.05  tff(decl_44472, type, 'A form of long-distance signaling where hormones, secreted chemicals formed in specialized cells, sometimes travel through vessels in the plant, but they often reach their target cells by moving through cells or through the air as a gas.': $i).
% 29.22/29.05  tff(decl_44473, type, 'hormonal signaling in plant': $i).
% 29.22/29.05  tff(decl_44474, type, 'hormonal-signaling-in-plant': $i).
% 29.22/29.05  tff(decl_44475, type, 'Hormone': $i).
% 29.22/29.05  tff(decl_44476, type, 'A chemical that is secreted by specialized cells within an organ, travels in the bloodstream, and acts on specific target cells in another part of the body or another part of the secreting organ.': $i).
% 29.22/29.05  tff(decl_44477, type, hormone: $i).
% 29.22/29.05  tff(decl_44478, type, hormone_receptor_1: $i > $o).
% 29.22/29.05  tff(decl_44479, type, 'Hormone-Receptor': $i).
% 29.22/29.05  tff(decl_44480, type, 'A receptor protein on the surface of a cell or in its interior that binds to a specific hormone which often triggers the start of a biophysical signal that can lead to further signal transduction pathways, or trigger the activation or inhibition of genes.': $i).
% 29.22/29.05  tff(decl_44481, type, 'receptor of hormone': $i).
% 29.22/29.05  tff(decl_44482, type, 'hormone receptor': $i).
% 29.22/29.05  tff(decl_44483, type, 'hormone-receptor': $i).
% 29.22/29.05  tff(decl_44484, type, fn_hormone_receptor_1: $i > $i).
% 29.22/29.05  tff(decl_44485, type, hornwort_1: $i > $o).
% 29.22/29.05  tff(decl_44486, type, 'Hornwort': $i).
% 29.22/29.05  tff(decl_44487, type, 'Member of the phylum Antherocerophyta, which are small herbaceous bryophytes (nonvascular plants).': $i).
% 29.22/29.05  tff(decl_44488, type, anthroceroyphyta: $i).
% 29.22/29.05  tff(decl_44489, type, anthrocerophyte: $i).
% 29.22/29.05  tff(decl_44490, type, hornwort: $i).
% 29.22/29.05  tff(decl_44491, type, 'Host': $i).
% 29.22/29.05  tff(decl_44492, type, 'The larger of two partcipants in a symbiotic relationship. The host may serve as habitable environment or food for the smaller partner and may in turn be either harmed by or benefit from the presence of the smaller participant.': $i).
% 29.22/29.05  tff(decl_44493, type, host: $i).
% 29.22/29.05  tff(decl_44494, type, fn_host_2: $i > $i).
% 29.22/29.05  tff(decl_44495, type, host_range_1: $i > $o).
% 29.22/29.05  tff(decl_44496, type, 'Host-Range': $i).
% 29.22/29.05  tff(decl_44497, type, 'The limited range of host cell types that can be infected by a parasite or pathogen.': $i).
% 29.22/29.05  tff(decl_44498, type, 'range of host': $i).
% 29.22/29.05  tff(decl_44499, type, 'host range': $i).
% 29.22/29.05  tff(decl_44500, type, 'host-range': $i).
% 29.22/29.05  tff(decl_44501, type, hox_gene_1: $i > $o).
% 29.22/29.05  tff(decl_44502, type, 'Hox-Gene': $i).
% 29.22/29.05  tff(decl_44503, type, 'One of a group of related genes that regulate the formation of body axes during development.': $i).
% 29.22/29.05  tff(decl_44504, type, 'hox gene': $i).
% 29.22/29.05  tff(decl_44505, type, 'hox-gene': $i).
% 29.22/29.05  tff(decl_44506, type, 'HTLV': $i).
% 29.22/29.05  tff(decl_44507, type, 'Human T-lymphotrophic virus; a human RNA retrovirus that causes a type of cancer in T cells.': $i).
% 29.22/29.05  tff(decl_44508, type, 'human t cell leukemia virus': $i).
% 29.22/29.05  tff(decl_44509, type, 'human-t-cell-leukemia-virus': $i).
% 29.22/29.05  tff(decl_44510, type, 'human t lymphotropic virus type i': $i).
% 29.22/29.05  tff(decl_44511, type, 'human-t-lymphotropic-virus-type-i': $i).
% 29.22/29.05  tff(decl_44512, type, 'htlv 1': $i).
% 29.22/29.05  tff(decl_44513, type, 'htlv-1': $i).
% 29.22/29.05  tff(decl_44514, type, 'human t lymphotropic virus': $i).
% 29.22/29.05  tff(decl_44515, type, 'human-t-lymphotropic-virus': $i).
% 29.22/29.05  tff(decl_44516, type, htlv: $i).
% 29.22/29.05  tff(decl_44517, type, hugh_davson_1: $i > $o).
% 29.22/29.05  tff(decl_44518, type, 'Hugh-Davson': $i).
% 29.22/29.05  tff(decl_44519, type, 'Biologist that studied biomembranes and developed the Sandwich Model for placement of membrane proteins.': $i).
% 29.22/29.05  tff(decl_44520, type, davson: $i).
% 29.22/29.05  tff(decl_44521, type, 'hugh davson': $i).
% 29.22/29.05  tff(decl_44522, type, 'hugh-davson': $i).
% 29.22/29.05  tff(decl_44523, type, 'Human-Behavior': $i).
% 29.22/29.05  tff(decl_44524, type, 'Range of behaviors unique to humans which are influenced by human biology and culture.': $i).
% 29.22/29.05  tff(decl_44525, type, 'behavior of human': $i).
% 29.22/29.05  tff(decl_44526, type, 'human behavior': $i).
% 29.22/29.05  tff(decl_44527, type, 'human-behavior': $i).
% 29.22/29.05  tff(decl_44528, type, 'Human-Cell': $i).
% 29.22/29.05  tff(decl_44529, type, 'Human cell is the basic structural unit of Human': $i).
% 29.22/29.05  tff(decl_44530, type, 'cell of human': $i).
% 29.22/29.05  tff(decl_44531, type, 'human cell': $i).
% 29.22/29.05  tff(decl_44532, type, 'human-cell': $i).
% 29.22/29.05  tff(decl_44533, type, fn_human_cell_2: $i > $i).
% 29.22/29.05  tff(decl_44534, type, fn_human_cell_4: $i > $i).
% 29.22/29.05  tff(decl_44535, type, fn_human_cell_5: $i > $i).
% 29.22/29.05  tff(decl_44536, type, fn_human_cell_6: $i > $i).
% 29.22/29.05  tff(decl_44537, type, fn_human_cell_7: $i > $i).
% 29.22/29.05  tff(decl_44538, type, fn_human_cell_8: $i > $i).
% 29.22/29.05  tff(decl_44539, type, fn_human_cell_11: $i > $i).
% 29.22/29.05  tff(decl_44540, type, fn_human_cell_12: $i > $i).
% 29.22/29.05  tff(decl_44541, type, fn_human_cell_14: $i > $i).
% 29.22/29.05  tff(decl_44542, type, fn_human_cell_15: $i > $i).
% 29.22/29.05  tff(decl_44543, type, fn_human_cell_16: $i > $i).
% 29.22/29.05  tff(decl_44544, type, fn_human_cell_17: $i > $i).
% 29.22/29.05  tff(decl_44545, type, fn_human_cell_18: $i > $i).
% 29.22/29.05  tff(decl_44546, type, fn_human_cell_19: $i > $i).
% 29.22/29.05  tff(decl_44547, type, fn_human_cell_20: $i > $i).
% 29.22/29.05  tff(decl_44548, type, fn_human_cell_21: $i > $i).
% 29.22/29.05  tff(decl_44549, type, fn_human_cell_22: $i > $i).
% 29.22/29.05  tff(decl_44550, type, fn_human_cell_23: $i > $i).
% 29.22/29.05  tff(decl_44551, type, fn_human_cell_24: $i > $i).
% 29.22/29.05  tff(decl_44552, type, fn_human_cell_25: $i > $i).
% 29.22/29.05  tff(decl_44553, type, fn_human_cell_26: $i > $i).
% 29.22/29.05  tff(decl_44554, type, fn_human_cell_28: $i > $i).
% 29.22/29.05  tff(decl_44555, type, fn_human_cell_29: $i > $i).
% 29.22/29.05  tff(decl_44556, type, fn_human_cell_30: $i > $i).
% 29.22/29.05  tff(decl_44557, type, fn_human_cell_31: $i > $i).
% 29.22/29.05  tff(decl_44558, type, fn_human_cell_32: $i > $i).
% 29.22/29.05  tff(decl_44559, type, fn_human_cell_33: $i > $i).
% 29.22/29.05  tff(decl_44560, type, fn_human_cell_34: $i > $i).
% 29.22/29.05  tff(decl_44561, type, fn_human_cell_35: $i > $i).
% 29.22/29.05  tff(decl_44562, type, fn_human_cell_36: $i > $i).
% 29.22/29.05  tff(decl_44563, type, fn_human_cell_37: $i > $i).
% 29.22/29.05  tff(decl_44564, type, fn_human_cell_38: $i > $i).
% 29.22/29.05  tff(decl_44565, type, fn_human_cell_39: $i > $i).
% 29.22/29.05  tff(decl_44566, type, fn_human_cell_40: $i > $i).
% 29.22/29.05  tff(decl_44567, type, fn_human_cell_41: $i > $i).
% 29.22/29.05  tff(decl_44568, type, fn_human_cell_42: $i > $i).
% 29.22/29.05  tff(decl_44569, type, fn_human_cell_43: $i > $i).
% 29.22/29.05  tff(decl_44570, type, fn_human_cell_44: $i > $i).
% 29.22/29.05  tff(decl_44571, type, fn_human_cell_45: $i > $i).
% 29.22/29.05  tff(decl_44572, type, fn_human_cell_46: $i > $i).
% 29.22/29.05  tff(decl_44573, type, 'Length_DNA': $i).
% 29.22/29.05  tff(decl_44574, type, fn_human_cell_27: $i > $i).
% 29.22/29.05  tff(decl_44575, type, fn_human_cell_10: $i > $i).
% 29.22/29.05  tff(decl_44576, type, fn_human_cell_9: $i > $i).
% 29.22/29.05  tff(decl_44577, type, fn_mammalian_cell_3: $i > $i).
% 29.22/29.05  tff(decl_44578, type, 'Human-Chromosome': $i).
% 29.22/29.05  tff(decl_44579, type, 'A chromosome in the nucleus of a human cell.': $i).
% 29.22/29.05  tff(decl_44580, type, 'chromosome of human': $i).
% 29.22/29.05  tff(decl_44581, type, 'human chromosome': $i).
% 29.22/29.05  tff(decl_44582, type, 'human-chromosome': $i).
% 29.22/29.05  tff(decl_44583, type, paternal_chromosome_1: $i > $o).
% 29.22/29.05  tff(decl_44584, type, human_culture_1: $i > $o).
% 29.22/29.05  tff(decl_44585, type, 'Human-Culture': $i).
% 29.22/29.05  tff(decl_44586, type, 'In humans, the systems by which information is transferred through teaching and social learning rather than by genetics or instinct.': $i).
% 29.22/29.05  tff(decl_44587, type, 'culture of human': $i).
% 29.22/29.05  tff(decl_44588, type, 'human culture': $i).
% 29.22/29.05  tff(decl_44589, type, 'human-culture': $i).
% 29.22/29.05  tff(decl_44590, type, human_dentition_1: $i > $o).
% 29.22/29.05  tff(decl_44591, type, 'Human-Dentition': $i).
% 29.22/29.05  tff(decl_44592, type, 'A human\\s assortment of teeth.': $i).
% 29.22/29.05  tff(decl_44593, type, 'dentition of human': $i).
% 29.22/29.05  tff(decl_44594, type, 'human dentition': $i).
% 29.22/29.05  tff(decl_44595, type, 'human-dentition': $i).
% 29.22/29.05  tff(decl_44596, type, fn_human_dentition_1: $i > $i).
% 29.22/29.05  tff(decl_44597, type, molar_tooth_1: $i > $o).
% 29.22/29.05  tff(decl_44598, type, fn_human_dentition_2: $i > $i).
% 29.22/29.05  tff(decl_44599, type, premolar_tooth_1: $i > $o).
% 29.22/29.05  tff(decl_44600, type, fn_human_dentition_3: $i > $i).
% 29.22/29.05  tff(decl_44601, type, fn_human_dentition_4: $i > $i).
% 29.22/29.05  tff(decl_44602, type, incisor_1: $i > $o).
% 29.22/29.05  tff(decl_44603, type, incisor_0: $i).
% 29.22/29.05  tff(decl_44604, type, canine_tooth_0: $i).
% 29.22/29.05  tff(decl_44605, type, premolar_tooth_0: $i).
% 29.22/29.05  tff(decl_44606, type, molar_tooth_0: $i).
% 29.22/29.05  tff(decl_44607, type, human_disease_1: $i > $o).
% 29.22/29.05  tff(decl_44608, type, 'Human-Disease': $i).
% 29.22/29.05  tff(decl_44609, type, 'A disease occurring in humans.': $i).
% 29.22/29.05  tff(decl_44610, type, 'disease of human': $i).
% 29.22/29.05  tff(decl_44611, type, 'human disease': $i).
% 29.22/29.05  tff(decl_44612, type, 'human-disease': $i).
% 29.22/29.05  tff(decl_44613, type, 'Human-Driven-Disturbance': $i).
% 29.22/29.05  tff(decl_44614, type, 'Ecological disturbance that is generally attributed to or caused by human activity.': $i).
% 29.22/29.05  tff(decl_44615, type, 'human driven disturbance': $i).
% 29.22/29.05  tff(decl_44616, type, 'human-driven-disturbance': $i).
% 29.22/29.05  tff(decl_44617, type, 'Human-Evolution': $i).
% 29.22/29.05  tff(decl_44618, type, 'The evolutionary processes that lead up to Homo sapiens, especially those that occurred since the first appearance of the genus Homo.': $i).
% 29.22/29.05  tff(decl_44619, type, 'evolution of human': $i).
% 29.22/29.05  tff(decl_44620, type, 'human evolution': $i).
% 29.22/29.05  tff(decl_44621, type, 'human-evolution': $i).
% 29.22/29.05  tff(decl_44622, type, human_female_somatic_cell_1: $i > $o).
% 29.22/29.05  tff(decl_44623, type, 'Human-Female-Somatic-Cell': $i).
% 29.22/29.05  tff(decl_44624, type, 'Every other diploid cell that carries XX chromosomes, in a multicellular organism apart from the sperm and ova, the gametocytes from which the gametes are made, and undifferentiated stem cells.  Internal organs, skin, bones, blood, and connective tissue are all made up of somatic cells.': $i).
% 29.22/29.05  tff(decl_44625, type, 'human female somatic cell': $i).
% 29.22/29.05  tff(decl_44626, type, 'human-female-somatic-cell': $i).
% 29.22/29.05  tff(decl_44627, type, human_somatic_cell_1: $i > $o).
% 29.22/29.05  tff(decl_44628, type, human_male_somatic_cell_1: $i > $o).
% 29.22/29.05  tff(decl_44629, type, fn_human_female_somatic_cell_1: $i > $i).
% 29.22/29.05  tff(decl_44630, type, human_fertilization_1: $i > $o).
% 29.22/29.05  tff(decl_44631, type, 'Human-Fertilization': $i).
% 29.22/29.05  tff(decl_44632, type, 'The process of the fusion of gametes (sperm and ova) in hum sexual reproduction.': $i).
% 29.22/29.05  tff(decl_44633, type, 'fertilization of human': $i).
% 29.22/29.05  tff(decl_44634, type, 'human fertilization': $i).
% 29.22/29.05  tff(decl_44635, type, 'human-fertilization': $i).
% 29.22/29.05  tff(decl_44636, type, fn_human_fertilization_1: $i > $i).
% 29.22/29.05  tff(decl_44637, type, fn_human_fertilization_2: $i > $i).
% 29.22/29.05  tff(decl_44638, type, fn_human_fertilization_3: $i > $i).
% 29.22/29.05  tff(decl_44639, type, fn_human_fertilization_4: $i > $i).
% 29.22/29.05  tff(decl_44640, type, fn_human_fertilization_5: $i > $i).
% 29.22/29.05  tff(decl_44641, type, fn_human_fertilization_6: $i > $i).
% 29.22/29.05  tff(decl_44642, type, fn_human_fertilization_7: $i > $i).
% 29.22/29.05  tff(decl_44643, type, human_gamete_1: $i > $o).
% 29.22/29.05  tff(decl_44644, type, 'Human-Gamete': $i).
% 29.22/29.05  tff(decl_44645, type, 'Human sex cell have 23 chromosome, the male human sex cell is sperm and the female human sex cell is ovum.': $i).
% 29.22/29.05  tff(decl_44646, type, 'gamete of human': $i).
% 29.22/29.05  tff(decl_44647, type, 'human gamete': $i).
% 29.22/29.05  tff(decl_44648, type, 'human-gamete': $i).
% 29.22/29.05  tff(decl_44649, type, fn_human_gamete_1: $i > $i).
% 29.22/29.05  tff(decl_44650, type, human_gene_1: $i > $o).
% 29.22/29.05  tff(decl_44651, type, 'Human-Gene': $i).
% 29.22/29.05  tff(decl_44652, type, 'A gene is the basic unit of heredity in a living organism. Genes are present on chromosomes. Gene found in Humans is called as Human gene.': $i).
% 29.22/29.05  tff(decl_44653, type, 'gene of homo sapiens': $i).
% 29.22/29.05  tff(decl_44654, type, 'gene-of-homo-sapiens': $i).
% 29.22/29.05  tff(decl_44655, type, 'gene of human': $i).
% 29.22/29.05  tff(decl_44656, type, 'human gene': $i).
% 29.22/29.05  tff(decl_44657, type, 'human-gene': $i).
% 29.22/29.05  tff(decl_44658, type, 'Human-Genetic-Disorder': $i).
% 29.22/29.05  tff(decl_44659, type, 'A disease in humans caused by an individual\\s genetic makeup.': $i).
% 29.22/29.05  tff(decl_44660, type, 'human genetic disorder': $i).
% 29.22/29.05  tff(decl_44661, type, 'human-genetic-disorder': $i).
% 29.22/29.05  tff(decl_44662, type, human_genome_1: $i > $o).
% 29.22/29.05  tff(decl_44663, type, 'Human-Genome': $i).
% 29.22/29.05  tff(decl_44664, type, 'The human genome is the genome of Homo sapiens, which is stored on 23 chromosome pairs.': $i).
% 29.22/29.05  tff(decl_44665, type, 'genome of human': $i).
% 29.22/29.05  tff(decl_44666, type, 'human genome': $i).
% 29.22/29.05  tff(decl_44667, type, 'human-genome': $i).
% 29.22/29.05  tff(decl_44668, type, fn_human_genome_1: $i > $i).
% 29.22/29.05  tff(decl_44669, type, human_genome_project_1: $i > $o).
% 29.22/29.05  tff(decl_44670, type, 'Human-Genome-Project': $i).
% 29.22/29.05  tff(decl_44671, type, 'An international science research project to map and sequence the entire human genome.': $i).
% 29.22/29.05  tff(decl_44672, type, 'human genome project': $i).
% 29.22/29.05  tff(decl_44673, type, 'human-genome-project': $i).
% 29.22/29.05  tff(decl_44674, type, human_leukocyte_1: $i > $o).
% 29.22/29.05  tff(decl_44675, type, 'Human-Leukocyte': $i).
% 29.22/29.05  tff(decl_44676, type, 'White blood cells (WBCs), or leukocytes, are cells of the human immune system involved in defending the body against both infectious disease and foreign materials.': $i).
% 29.22/29.05  tff(decl_44677, type, 'leukocyte of human': $i).
% 29.22/29.05  tff(decl_44678, type, 'human leukocyte': $i).
% 29.22/29.05  tff(decl_44679, type, 'human-leukocyte': $i).
% 29.22/29.05  tff(decl_44680, type, human_limb_development_1: $i > $o).
% 29.22/29.05  tff(decl_44681, type, 'Human-Limb-Development': $i).
% 29.22/29.05  tff(decl_44682, type, 'The processes which direct the formation of the limbs during the embryonic development of a human.': $i).
% 29.22/29.05  tff(decl_44683, type, 'human limb development': $i).
% 29.22/29.05  tff(decl_44684, type, 'human-limb-development': $i).
% 29.22/29.05  tff(decl_44685, type, mammalian_limb_development_1: $i > $o).
% 29.22/29.05  tff(decl_44686, type, fn_human_limb_development_1: $i > $i).
% 29.22/29.05  tff(decl_44687, type, fn_human_limb_development_2: $i > $i).
% 29.22/29.05  tff(decl_44688, type, fn_human_limb_development_3: $i > $i).
% 29.22/29.05  tff(decl_44689, type, fn_human_limb_development_4: $i > $i).
% 29.22/29.05  tff(decl_44690, type, fn_human_limb_development_5: $i > $i).
% 29.22/29.05  tff(decl_44691, type, fn_human_limb_development_6: $i > $i).
% 29.22/29.05  tff(decl_44692, type, fn_human_limb_development_7: $i > $i).
% 29.22/29.05  tff(decl_44693, type, fn_human_limb_development_12: $i > $i).
% 29.22/29.05  tff(decl_44694, type, fn_human_limb_development_13: $i > $i).
% 29.22/29.05  tff(decl_44695, type, fn_human_limb_development_14: $i > $i).
% 29.22/29.05  tff(decl_44696, type, fn_human_limb_development_15: $i > $i).
% 29.22/29.05  tff(decl_44697, type, fn_human_limb_development_16: $i > $i).
% 29.22/29.05  tff(decl_44698, type, fn_human_limb_development_17: $i > $i).
% 29.22/29.05  tff(decl_44699, type, fn_human_limb_development_18: $i > $i).
% 29.22/29.05  tff(decl_44700, type, fn_human_limb_development_19: $i > $i).
% 29.22/29.05  tff(decl_44701, type, fn_human_limb_development_22: $i > $i).
% 29.22/29.05  tff(decl_44702, type, fn_human_limb_development_23: $i > $i).
% 29.22/29.05  tff(decl_44703, type, fn_human_limb_development_24: $i > $i).
% 29.22/29.05  tff(decl_44704, type, fn_human_limb_development_25: $i > $i).
% 29.22/29.05  tff(decl_44705, type, fn_human_limb_development_26: $i > $i).
% 29.22/29.05  tff(decl_44706, type, fn_human_limb_development_27: $i > $i).
% 29.22/29.05  tff(decl_44707, type, fn_human_limb_development_28: $i > $i).
% 29.22/29.05  tff(decl_44708, type, fn_human_limb_development_29: $i > $i).
% 29.22/29.05  tff(decl_44709, type, fn_human_limb_development_30: $i > $i).
% 29.22/29.05  tff(decl_44710, type, fn_human_limb_development_31: $i > $i).
% 29.22/29.05  tff(decl_44711, type, fn_human_limb_development_32: $i > $i).
% 29.22/29.05  tff(decl_44712, type, fn_human_limb_development_33: $i > $i).
% 29.22/29.05  tff(decl_44713, type, fn_human_limb_development_34: $i > $i).
% 29.22/29.05  tff(decl_44714, type, fn_human_limb_development_35: $i > $i).
% 29.22/29.05  tff(decl_44715, type, fn_human_limb_development_36: $i > $i).
% 29.22/29.05  tff(decl_44716, type, fn_human_limb_development_37: $i > $i).
% 29.22/29.05  tff(decl_44717, type, fn_human_limb_development_38: $i > $i).
% 29.22/29.05  tff(decl_44718, type, fn_human_limb_development_39: $i > $i).
% 29.22/29.05  tff(decl_44719, type, fn_human_limb_development_40: $i > $i).
% 29.22/29.05  tff(decl_44720, type, fn_human_limb_development_41: $i > $i).
% 29.22/29.05  tff(decl_44721, type, fn_human_limb_development_42: $i > $i).
% 29.22/29.05  tff(decl_44722, type, limb_1: $i > $o).
% 29.22/29.05  tff(decl_44723, type, fn_human_limb_development_43: $i > $i).
% 29.22/29.05  tff(decl_44724, type, fn_human_limb_development_44: $i > $i).
% 29.22/29.05  tff(decl_44725, type, fn_human_limb_development_45: $i > $i).
% 29.22/29.05  tff(decl_44726, type, fn_human_limb_development_46: $i > $i).
% 29.22/29.05  tff(decl_44727, type, morphogenesis_of_human_hand_1: $i > $o).
% 29.22/29.05  tff(decl_44728, type, fn_human_limb_development_47: $i > $i).
% 29.22/29.05  tff(decl_44729, type, morphogenesis_of_human_feet_1: $i > $o).
% 29.22/29.05  tff(decl_44730, type, fn_human_limb_development_48: $i > $i).
% 29.22/29.05  tff(decl_44731, type, fn_human_limb_development_49: $i > $i).
% 29.22/29.05  tff(decl_44732, type, fn_human_limb_development_50: $i > $i).
% 29.22/29.05  tff(decl_44733, type, fn_human_limb_development_51: $i > $i).
% 29.22/29.05  tff(decl_44734, type, fn_human_limb_development_52: $i > $i).
% 29.22/29.05  tff(decl_44735, type, fn_human_limb_development_53: $i > $i).
% 29.22/29.05  tff(decl_44736, type, fn_human_limb_development_54: $i > $i).
% 29.22/29.05  tff(decl_44737, type, fn_human_limb_development_55: $i > $i).
% 29.22/29.05  tff(decl_44738, type, fn_human_limb_development_56: $i > $i).
% 29.22/29.05  tff(decl_44739, type, fn_human_limb_development_57: $i > $i).
% 29.22/29.05  tff(decl_44740, type, fn_morphogenesis_of_human_hand_2: $i > $i).
% 29.22/29.05  tff(decl_44741, type, fn_morphogenesis_of_human_feet_2: $i > $i).
% 29.22/29.05  tff(decl_44742, type, fn_morphogenesis_of_human_hand_1: $i > $i).
% 29.22/29.05  tff(decl_44743, type, fn_morphogenesis_of_human_feet_1: $i > $i).
% 29.22/29.05  tff(decl_44744, type, fn_protease_6: $i > $i).
% 29.22/29.05  tff(decl_44745, type, organ_development_0: $i).
% 29.22/29.05  tff(decl_44746, type, limb_0: $i).
% 29.22/29.05  tff(decl_44747, type, fn_limb_development_3: $i > $i).
% 29.22/29.05  tff(decl_44748, type, fn_human_limb_development_11: $i > $i).
% 29.22/29.05  tff(decl_44749, type, fn_limb_development_5: $i > $i).
% 29.22/29.05  tff(decl_44750, type, fn_human_limb_development_10: $i > $i).
% 29.22/29.05  tff(decl_44751, type, fn_limb_development_4: $i > $i).
% 29.22/29.05  tff(decl_44752, type, fn_limb_development_6: $i > $i).
% 29.22/29.05  tff(decl_44753, type, fn_limb_development_8: $i > $i).
% 29.22/29.05  tff(decl_44754, type, fn_limb_development_7: $i > $i).
% 29.22/29.05  tff(decl_44755, type, fn_limb_development_17: $i > $i).
% 29.22/29.05  tff(decl_44756, type, fn_limb_development_16: $i > $i).
% 29.22/29.05  tff(decl_44757, type, fn_human_limb_development_21: $i > $i).
% 29.22/29.05  tff(decl_44758, type, fn_human_limb_development_20: $i > $i).
% 29.22/29.05  tff(decl_44759, type, 'Human-Male-Somatic-Cell': $i).
% 29.22/29.05  tff(decl_44760, type, 'Every other diploid cell that carries XY chromosomes, in a multicellular organism apart from the sperm and ova, the gametocytes from which the gametes are made, and undifferentiated stem cells.  Internal organs, skin, bones, blood, and connective tissue are all made up of somatic cells.': $i).
% 29.22/29.05  tff(decl_44761, type, 'human male somatic cell': $i).
% 29.22/29.05  tff(decl_44762, type, 'human-male-somatic-cell': $i).
% 29.22/29.05  tff(decl_44763, type, fn_human_male_somatic_cell_1: $i > $i).
% 29.22/29.05  tff(decl_44764, type, y_chromosome_0: $i).
% 29.22/29.05  tff(decl_44765, type, human_mitotic_cycle_1: $i > $o).
% 29.22/29.05  tff(decl_44766, type, 'Human-Mitotic-Cycle': $i).
% 29.22/29.05  tff(decl_44767, type, 'Cell cycle followed by somatic cells in humans. It results in daughter cells identical in genetic composition to the parent cells.': $i).
% 29.22/29.05  tff(decl_44768, type, 'human mitotic cycle': $i).
% 29.22/29.05  tff(decl_44769, type, 'human-mitotic-cycle': $i).
% 29.22/29.05  tff(decl_44770, type, mammalian_mitotic_cycle_1: $i > $o).
% 29.22/29.05  tff(decl_44771, type, fn_human_mitotic_cycle_2: $i > $i).
% 29.22/29.05  tff(decl_44772, type, fn_human_mitotic_cycle_6: $i > $i).
% 29.22/29.05  tff(decl_44773, type, fn_human_mitotic_cycle_7: $i > $i).
% 29.22/29.05  tff(decl_44774, type, fn_human_mitotic_cycle_8: $i > $i).
% 29.22/29.05  tff(decl_44775, type, fn_human_mitotic_cycle_12: $i > $i).
% 29.22/29.05  tff(decl_44776, type, fn_human_mitotic_cycle_13: $i > $i).
% 29.22/29.05  tff(decl_44777, type, fn_human_mitotic_cycle_14: $i > $i).
% 29.22/29.05  tff(decl_44778, type, fn_human_mitotic_cycle_15: $i > $i).
% 29.22/29.05  tff(decl_44779, type, fn_human_mitotic_cycle_17: $i > $i).
% 29.22/29.05  tff(decl_44780, type, fn_human_mitotic_cycle_19: $i > $i).
% 29.22/29.05  tff(decl_44781, type, fn_human_mitotic_cycle_23: $i > $i).
% 29.22/29.05  tff(decl_44782, type, fn_human_mitotic_cycle_24: $i > $i).
% 29.22/29.05  tff(decl_44783, type, fn_human_mitotic_cycle_25: $i > $i).
% 29.22/29.05  tff(decl_44784, type, fn_human_mitotic_cycle_26: $i > $i).
% 29.22/29.05  tff(decl_44785, type, fn_human_mitotic_cycle_27: $i > $i).
% 29.22/29.05  tff(decl_44786, type, fn_human_mitotic_cycle_28: $i > $i).
% 29.22/29.05  tff(decl_44787, type, fn_human_mitotic_cycle_29: $i > $i).
% 29.22/29.05  tff(decl_44788, type, fn_human_mitotic_cycle_32: $i > $i).
% 29.22/29.05  tff(decl_44789, type, prometaphase_1: $i > $o).
% 29.22/29.05  tff(decl_44790, type, fn_human_mitotic_cycle_33: $i > $i).
% 29.22/29.05  tff(decl_44791, type, fn_human_mitotic_cycle_34: $i > $i).
% 29.22/29.05  tff(decl_44792, type, fn_human_mitotic_cycle_35: $i > $i).
% 29.22/29.05  tff(decl_44793, type, fn_human_mitotic_cycle_36: $i > $i).
% 29.22/29.05  tff(decl_44794, type, fn_human_mitotic_cycle_37: $i > $i).
% 29.22/29.05  tff(decl_44795, type, fn_human_mitotic_cycle_38: $i > $i).
% 29.22/29.05  tff(decl_44796, type, fn_human_mitotic_cycle_39: $i > $i).
% 29.22/29.05  tff(decl_44797, type, fn_human_mitotic_cycle_40: $i > $i).
% 29.22/29.05  tff(decl_44798, type, fn_human_mitotic_cycle_41: $i > $i).
% 29.22/29.05  tff(decl_44799, type, fn_human_mitotic_cycle_42: $i > $i).
% 29.22/29.05  tff(decl_44800, type, fn_human_mitotic_cycle_43: $i > $i).
% 29.22/29.05  tff(decl_44801, type, fn_human_mitotic_cycle_44: $i > $i).
% 29.22/29.05  tff(decl_44802, type, fn_human_mitotic_cycle_45: $i > $i).
% 29.22/29.05  tff(decl_44803, type, fn_human_mitotic_cycle_46: $i > $i).
% 29.22/29.05  tff(decl_44804, type, fn_human_mitotic_cycle_47: $i > $i).
% 29.22/29.05  tff(decl_44805, type, fn_human_mitotic_cycle_48: $i > $i).
% 29.22/29.05  tff(decl_44806, type, fn_human_mitotic_cycle_49: $i > $i).
% 29.22/29.05  tff(decl_44807, type, fn_human_mitotic_cycle_50: $i > $i).
% 29.22/29.05  tff(decl_44808, type, fn_human_mitotic_cycle_51: $i > $i).
% 29.22/29.05  tff(decl_44809, type, fn_human_mitotic_cycle_52: $i > $i).
% 29.22/29.05  tff(decl_44810, type, fn_human_mitotic_cycle_53: $i > $i).
% 29.22/29.05  tff(decl_44811, type, fn_human_mitotic_cycle_54: $i > $i).
% 29.22/29.05  tff(decl_44812, type, fn_human_mitotic_cycle_55: $i > $i).
% 29.22/29.05  tff(decl_44813, type, fn_human_mitotic_cycle_57: $i > $i).
% 29.22/29.05  tff(decl_44814, type, fn_human_mitotic_cycle_58: $i > $i).
% 29.22/29.05  tff(decl_44815, type, fn_human_mitotic_cycle_59: $i > $i).
% 29.22/29.05  tff(decl_44816, type, fn_human_mitotic_cycle_60: $i > $i).
% 29.22/29.05  tff(decl_44817, type, fn_human_mitotic_cycle_61: $i > $i).
% 29.22/29.05  tff(decl_44818, type, fn_human_mitotic_cycle_62: $i > $i).
% 29.22/29.05  tff(decl_44819, type, fn_human_mitotic_cycle_63: $i > $i).
% 29.22/29.05  tff(decl_44820, type, fn_human_mitotic_cycle_64: $i > $i).
% 29.22/29.05  tff(decl_44821, type, fn_human_mitotic_cycle_65: $i > $i).
% 29.22/29.05  tff(decl_44822, type, fn_human_mitotic_cycle_66: $i > $i).
% 29.22/29.05  tff(decl_44823, type, fn_human_mitotic_cycle_67: $i > $i).
% 29.22/29.05  tff(decl_44824, type, fn_human_mitotic_cycle_68: $i > $i).
% 29.22/29.05  tff(decl_44825, type, fn_human_mitotic_cycle_69: $i > $i).
% 29.22/29.05  tff(decl_44826, type, fn_human_mitotic_cycle_70: $i > $i).
% 29.22/29.05  tff(decl_44827, type, fn_human_mitotic_cycle_71: $i > $i).
% 29.22/29.05  tff(decl_44828, type, fn_human_mitotic_cycle_72: $i > $i).
% 29.22/29.05  tff(decl_44829, type, fn_human_mitotic_cycle_73: $i > $i).
% 29.22/29.05  tff(decl_44830, type, fn_human_mitotic_cycle_74: $i > $i).
% 29.22/29.05  tff(decl_44831, type, fn_human_mitotic_cycle_75: $i > $i).
% 29.22/29.05  tff(decl_44832, type, fn_human_mitotic_cycle_76: $i > $i).
% 29.22/29.05  tff(decl_44833, type, fn_human_mitotic_cycle_79: $i > $i).
% 29.22/29.05  tff(decl_44834, type, fn_human_mitotic_cycle_80: $i > $i).
% 29.22/29.05  tff(decl_44835, type, fn_human_mitotic_cycle_81: $i > $i).
% 29.22/29.05  tff(decl_44836, type, fn_human_mitotic_cycle_82: $i > $i).
% 29.22/29.05  tff(decl_44837, type, fn_human_mitotic_cycle_83: $i > $i).
% 29.22/29.05  tff(decl_44838, type, fn_human_mitotic_cycle_84: $i > $i).
% 29.22/29.05  tff(decl_44839, type, fn_human_mitotic_cycle_85: $i > $i).
% 29.22/29.05  tff(decl_44840, type, fn_m_phase_1: $i > $i).
% 29.22/29.05  tff(decl_44841, type, fn_m_phase_2: $i > $i).
% 29.22/29.05  tff(decl_44842, type, fn_interphase_12: $i > $i).
% 29.22/29.05  tff(decl_44843, type, fn_interphase_5: $i > $i).
% 29.22/29.05  tff(decl_44844, type, fn_mitosis_36: $i > $i).
% 29.22/29.05  tff(decl_44845, type, fn_interphase_9: $i > $i).
% 29.22/29.05  tff(decl_44846, type, fn_m_phase_11: $i > $i).
% 29.22/29.05  tff(decl_44847, type, fn_s_phase_3: $i > $i).
% 29.22/29.05  tff(decl_44848, type, fn_m_phase_6: $i > $i).
% 29.22/29.05  tff(decl_44849, type, fn_m_phase_21: $i > $i).
% 29.22/29.05  tff(decl_44850, type, fn_prometaphase_38: $i > $i).
% 29.22/29.05  tff(decl_44851, type, fn_prophase_18: $i > $i).
% 29.22/29.05  tff(decl_44852, type, fn_m_phase_26: $i > $i).
% 29.22/29.05  tff(decl_44853, type, fn_interphase_20: $i > $i).
% 29.22/29.05  tff(decl_44854, type, fn_s_phase_15: $i > $i).
% 29.22/29.05  tff(decl_44855, type, fn_interphase_17: $i > $i).
% 29.22/29.05  tff(decl_44856, type, fn_s_phase_9: $i > $i).
% 29.22/29.05  tff(decl_44857, type, fn_interphase_14: $i > $i).
% 29.22/29.05  tff(decl_44858, type, fn_interphase_16: $i > $i).
% 29.22/29.05  tff(decl_44859, type, fn_interphase_8: $i > $i).
% 29.22/29.05  tff(decl_44860, type, fn_interphase_19: $i > $i).
% 29.22/29.05  tff(decl_44861, type, fn_interphase_11: $i > $i).
% 29.22/29.05  tff(decl_44862, type, fn_m_phase_40: $i > $i).
% 29.22/29.05  tff(decl_44863, type, fn_interphase_6: $i > $i).
% 29.22/29.05  tff(decl_44864, type, fn_m_phase_18: $i > $i).
% 29.22/29.05  tff(decl_44865, type, fn_interphase_7: $i > $i).
% 29.22/29.05  tff(decl_44866, type, fn_interphase_15: $i > $i).
% 29.22/29.05  tff(decl_44867, type, fn_s_phase_14: $i > $i).
% 29.22/29.05  tff(decl_44868, type, fn_m_phase_22: $i > $i).
% 29.22/29.05  tff(decl_44869, type, fn_m_phase_19: $i > $i).
% 29.22/29.05  tff(decl_44870, type, fn_interphase_18: $i > $i).
% 29.22/29.05  tff(decl_44871, type, fn_m_phase_23: $i > $i).
% 29.22/29.05  tff(decl_44872, type, fn_interphase_4: $i > $i).
% 29.22/29.05  tff(decl_44873, type, fn_s_phase_11: $i > $i).
% 29.22/29.05  tff(decl_44874, type, fn_interphase_21: $i > $i).
% 29.22/29.05  tff(decl_44875, type, 'Duration_SPhase': $i).
% 29.22/29.05  tff(decl_44876, type, 'Duration_HumanMitoticCellCycle': $i).
% 29.22/29.05  tff(decl_44877, type, "2.5e0": $i).
% 29.22/29.05  tff(decl_44878, type, "6.0e0": $i).
% 29.22/29.05  tff(decl_44879, type, "5.0e0": $i).
% 29.22/29.05  tff(decl_44880, type, fn_mammalian_mitotic_cycle_13: $i > $i).
% 29.22/29.05  tff(decl_44881, type, fn_mitotic_cell_cycle_23: $i > $i).
% 29.22/29.05  tff(decl_44882, type, fn_human_mitotic_cycle_56: $i > $i).
% 29.22/29.05  tff(decl_44883, type, fn_human_mitotic_cycle_31: $i > $i).
% 29.22/29.05  tff(decl_44884, type, fn_human_mitotic_cycle_30: $i > $i).
% 29.22/29.05  tff(decl_44885, type, fn_mammalian_mitotic_cycle_2: $i > $i).
% 29.22/29.05  tff(decl_44886, type, fn_mammalian_mitotic_cycle_11: $i > $i).
% 29.22/29.05  tff(decl_44887, type, fn_mammalian_mitotic_cycle_3: $i > $i).
% 29.22/29.05  tff(decl_44888, type, fn_mammalian_mitotic_cycle_4: $i > $i).
% 29.22/29.05  tff(decl_44889, type, fn_mitotic_cell_cycle_21: $i > $i).
% 29.22/29.05  tff(decl_44890, type, fn_mitotic_cell_cycle_33: $i > $i).
% 29.22/29.05  tff(decl_44891, type, fn_mitotic_cell_cycle_19: $i > $i).
% 29.22/29.05  tff(decl_44892, type, fn_mitotic_cell_cycle_45: $i > $i).
% 29.22/29.05  tff(decl_44893, type, fn_mitotic_cell_cycle_52: $i > $i).
% 29.22/29.05  tff(decl_44894, type, fn_mitotic_cell_cycle_32: $i > $i).
% 29.22/29.05  tff(decl_44895, type, fn_human_mitotic_cycle_77: $i > $i).
% 29.22/29.05  tff(decl_44896, type, fn_human_mitotic_cycle_78: $i > $i).
% 29.22/29.05  tff(decl_44897, type, fn_mitotic_cell_cycle_27: $i > $i).
% 29.22/29.05  tff(decl_44898, type, fn_mitotic_cell_cycle_25: $i > $i).
% 29.22/29.05  tff(decl_44899, type, human_nutritional_requirement_1: $i > $o).
% 29.22/29.05  tff(decl_44900, type, 'Human-Nutritional-Requirement': $i).
% 29.22/29.05  tff(decl_44901, type, 'Chemicals and elements found in food that are needed by humans in order to sustain healthy life.': $i).
% 29.22/29.05  tff(decl_44902, type, 'human nutritional requirement': $i).
% 29.22/29.05  tff(decl_44903, type, 'human-nutritional-requirement': $i).
% 29.22/29.05  tff(decl_44904, type, fn_human_nutritional_requirement_15: $i > $i).
% 29.22/29.05  tff(decl_44905, type, fn_human_nutritional_requirement_16: $i > $i).
% 29.22/29.05  tff(decl_44906, type, fn_human_nutritional_requirement_17: $i > $i).
% 29.22/29.05  tff(decl_44907, type, fn_human_nutritional_requirement_18: $i > $i).
% 29.22/29.05  tff(decl_44908, type, fn_human_nutritional_requirement_19: $i > $i).
% 29.22/29.05  tff(decl_44909, type, fn_human_nutritional_requirement_20: $i > $i).
% 29.22/29.05  tff(decl_44910, type, fn_human_nutritional_requirement_21: $i > $i).
% 29.22/29.05  tff(decl_44911, type, fn_human_nutritional_requirement_22: $i > $i).
% 29.22/29.05  tff(decl_44912, type, fn_human_nutritional_requirement_23: $i > $i).
% 29.22/29.05  tff(decl_44913, type, fn_human_nutritional_requirement_24: $i > $i).
% 29.22/29.05  tff(decl_44914, type, fn_human_nutritional_requirement_25: $i > $i).
% 29.22/29.05  tff(decl_44915, type, zinc_1: $i > $o).
% 29.22/29.05  tff(decl_44916, type, fn_human_nutritional_requirement_26: $i > $i).
% 29.22/29.05  tff(decl_44917, type, vanadium_1: $i > $o).
% 29.22/29.05  tff(decl_44918, type, fn_human_nutritional_requirement_27: $i > $i).
% 29.22/29.05  tff(decl_44919, type, tin_1: $i > $o).
% 29.22/29.05  tff(decl_44920, type, fn_human_nutritional_requirement_28: $i > $i).
% 29.22/29.05  tff(decl_44921, type, selenium_1: $i > $o).
% 29.22/29.05  tff(decl_44922, type, fn_human_nutritional_requirement_29: $i > $i).
% 29.22/29.05  tff(decl_44923, type, molybdenum_1: $i > $o).
% 29.22/29.05  tff(decl_44924, type, fn_human_nutritional_requirement_30: $i > $i).
% 29.22/29.05  tff(decl_44925, type, fn_human_nutritional_requirement_31: $i > $i).
% 29.22/29.05  tff(decl_44926, type, fn_human_nutritional_requirement_32: $i > $i).
% 29.22/29.05  tff(decl_44927, type, fn_human_nutritional_requirement_33: $i > $i).
% 29.22/29.05  tff(decl_44928, type, fn_human_nutritional_requirement_34: $i > $i).
% 29.22/29.05  tff(decl_44929, type, manganese_1: $i > $o).
% 29.22/29.05  tff(decl_44930, type, fn_human_nutritional_requirement_35: $i > $i).
% 29.22/29.05  tff(decl_44931, type, fn_human_nutritional_requirement_36: $i > $i).
% 29.22/29.05  tff(decl_44932, type, silicon_1: $i > $o).
% 29.22/29.05  tff(decl_44933, type, fn_human_nutritional_requirement_37: $i > $i).
% 29.22/29.05  tff(decl_44934, type, fn_human_nutritional_requirement_38: $i > $i).
% 29.22/29.05  tff(decl_44935, type, fn_human_nutritional_requirement_39: $i > $i).
% 29.22/29.05  tff(decl_44936, type, fn_human_nutritional_requirement_40: $i > $i).
% 29.22/29.05  tff(decl_44937, type, fn_human_nutritional_requirement_41: $i > $i).
% 29.22/29.05  tff(decl_44938, type, fn_human_nutritional_requirement_42: $i > $i).
% 29.22/29.05  tff(decl_44939, type, fn_human_nutritional_requirement_43: $i > $i).
% 29.22/29.05  tff(decl_44940, type, fn_human_nutritional_requirement_44: $i > $i).
% 29.22/29.05  tff(decl_44941, type, fn_human_nutritional_requirement_45: $i > $i).
% 29.22/29.05  tff(decl_44942, type, fn_human_nutritional_requirement_46: $i > $i).
% 29.22/29.05  tff(decl_44943, type, fn_human_nutritional_requirement_47: $i > $i).
% 29.22/29.05  tff(decl_44944, type, fn_human_nutritional_requirement_48: $i > $i).
% 29.22/29.05  tff(decl_44945, type, fn_human_nutritional_requirement_49: $i > $i).
% 29.22/29.05  tff(decl_44946, type, fn_human_nutritional_requirement_50: $i > $i).
% 29.22/29.05  tff(decl_44947, type, fn_human_nutritional_requirement_51: $i > $i).
% 29.22/29.05  tff(decl_44948, type, fn_human_nutritional_requirement_53: $i > $i).
% 29.22/29.05  tff(decl_44949, type, vitamin_c_1: $i > $o).
% 29.22/29.05  tff(decl_44950, type, fn_human_nutritional_requirement_54: $i > $i).
% 29.22/29.05  tff(decl_44951, type, fn_human_nutritional_requirement_55: $i > $i).
% 29.22/29.05  tff(decl_44952, type, fn_human_nutritional_requirement_56: $i > $i).
% 29.22/29.05  tff(decl_44953, type, fn_human_nutritional_requirement_57: $i > $i).
% 29.22/29.05  tff(decl_44954, type, fn_human_nutritional_requirement_58: $i > $i).
% 29.22/29.05  tff(decl_44955, type, fn_human_nutritional_requirement_59: $i > $i).
% 29.22/29.05  tff(decl_44956, type, fn_human_nutritional_requirement_60: $i > $i).
% 29.22/29.05  tff(decl_44957, type, fn_human_nutritional_requirement_61: $i > $i).
% 29.22/29.05  tff(decl_44958, type, fn_human_nutritional_requirement_62: $i > $i).
% 29.22/29.05  tff(decl_44959, type, fn_human_nutritional_requirement_63: $i > $i).
% 29.22/29.05  tff(decl_44960, type, fn_human_nutritional_requirement_64: $i > $i).
% 29.22/29.05  tff(decl_44961, type, fn_human_nutritional_requirement_65: $i > $i).
% 29.22/29.05  tff(decl_44962, type, fn_human_nutritional_requirement_66: $i > $i).
% 29.22/29.05  tff(decl_44963, type, fn_human_nutritional_requirement_67: $i > $i).
% 29.22/29.05  tff(decl_44964, type, fn_human_nutritional_requirement_68: $i > $i).
% 29.22/29.05  tff(decl_44965, type, fn_human_nutritional_requirement_69: $i > $i).
% 29.22/29.05  tff(decl_44966, type, fn_human_nutritional_requirement_70: $i > $i).
% 29.22/29.05  tff(decl_44967, type, fn_human_nutritional_requirement_71: $i > $i).
% 29.22/29.05  tff(decl_44968, type, fn_human_nutritional_requirement_72: $i > $i).
% 29.22/29.05  tff(decl_44969, type, fn_human_nutritional_requirement_73: $i > $i).
% 29.22/29.05  tff(decl_44970, type, fn_human_nutritional_requirement_74: $i > $i).
% 29.22/29.05  tff(decl_44971, type, fn_human_nutritional_requirement_75: $i > $i).
% 29.22/29.05  tff(decl_44972, type, fn_human_nutritional_requirement_76: $i > $i).
% 29.22/29.05  tff(decl_44973, type, fn_human_nutritional_requirement_77: $i > $i).
% 29.22/29.05  tff(decl_44974, type, fn_human_nutritional_requirement_78: $i > $i).
% 29.22/29.05  tff(decl_44975, type, lysine_1: $i > $o).
% 29.22/29.05  tff(decl_44976, type, fn_human_nutritional_requirement_79: $i > $i).
% 29.22/29.05  tff(decl_44977, type, fn_human_nutritional_requirement_80: $i > $i).
% 29.22/29.05  tff(decl_44978, type, fn_human_nutritional_requirement_81: $i > $i).
% 29.22/29.05  tff(decl_44979, type, fn_human_nutritional_requirement_82: $i > $i).
% 29.22/29.05  tff(decl_44980, type, fn_human_nutritional_requirement_83: $i > $i).
% 29.22/29.05  tff(decl_44981, type, fn_human_nutritional_requirement_84: $i > $i).
% 29.22/29.05  tff(decl_44982, type, fn_human_nutritional_requirement_85: $i > $i).
% 29.22/29.05  tff(decl_44983, type, fn_human_nutritional_requirement_86: $i > $i).
% 29.22/29.05  tff(decl_44984, type, fn_human_nutritional_requirement_87: $i > $i).
% 29.22/29.05  tff(decl_44985, type, linoleic_acid_1: $i > $o).
% 29.22/29.05  tff(decl_44986, type, fn_human_nutritional_requirement_88: $i > $i).
% 29.22/29.05  tff(decl_44987, type, human_ovum_1: $i > $o).
% 29.22/29.05  tff(decl_44988, type, 'Human-Ovum': $i).
% 29.22/29.05  tff(decl_44989, type, 'The female gamete in Humans; the egg cell': $i).
% 29.22/29.05  tff(decl_44990, type, 'ovum of human': $i).
% 29.22/29.05  tff(decl_44991, type, 'human ovum': $i).
% 29.22/29.05  tff(decl_44992, type, 'human-ovum': $i).
% 29.22/29.05  tff(decl_44993, type, ovum_1: $i > $o).
% 29.22/29.05  tff(decl_44994, type, fn_human_ovum_1: $i > $i).
% 29.22/29.05  tff(decl_44995, type, fn_human_ovum_2: $i > $i).
% 29.22/29.05  tff(decl_44996, type, fn_person_11: $i > $i).
% 29.22/29.05  tff(decl_44997, type, human_protein_1: $i > $o).
% 29.22/29.05  tff(decl_44998, type, 'Human-Protein': $i).
% 29.22/29.05  tff(decl_44999, type, 'Protein is a macromolecule made up of amino acids. The protein found in humans is called as Human protein.': $i).
% 29.22/29.05  tff(decl_45000, type, 'protein of human': $i).
% 29.22/29.05  tff(decl_45001, type, 'human protein': $i).
% 29.22/29.05  tff(decl_45002, type, 'human-protein': $i).
% 29.22/29.05  tff(decl_45003, type, 'Human-Somatic-Cell': $i).
% 29.22/29.05  tff(decl_45004, type, 'Somatic cells (diploid) are any cells forming the body of Humans, as opposed to germline cells': $i).
% 29.22/29.05  tff(decl_45005, type, 'human somatic cell': $i).
% 29.22/29.05  tff(decl_45006, type, 'human-somatic-cell': $i).
% 29.22/29.05  tff(decl_45007, type, human_sperm_1: $i > $o).
% 29.22/29.05  tff(decl_45008, type, 'Human-Sperm': $i).
% 29.22/29.05  tff(decl_45009, type, 'Human Sperm is a male reproductive cell or a male gamete of the Humans.': $i).
% 29.22/29.05  tff(decl_45010, type, 'sperm of human': $i).
% 29.22/29.05  tff(decl_45011, type, 'human sperm': $i).
% 29.22/29.05  tff(decl_45012, type, 'human-sperm': $i).
% 29.22/29.05  tff(decl_45013, type, fn_human_sperm_1: $i > $i).
% 29.22/29.05  tff(decl_45014, type, fn_human_sperm_2: $i > $i).
% 29.22/29.05  tff(decl_45015, type, fn_human_sperm_3: $i > $i).
% 29.22/29.05  tff(decl_45016, type, fn_human_sperm_4: $i > $i).
% 29.22/29.05  tff(decl_45017, type, fn_human_sperm_5: $i > $i).
% 29.22/29.05  tff(decl_45018, type, fn_human_sperm_6: $i > $i).
% 29.22/29.05  tff(decl_45019, type, fn_human_sperm_7: $i > $i).
% 29.22/29.05  tff(decl_45020, type, fn_human_sperm_8: $i > $i).
% 29.22/29.05  tff(decl_45021, type, fn_human_sperm_9: $i > $i).
% 29.22/29.05  tff(decl_45022, type, fn_human_sperm_10: $i > $i).
% 29.22/29.05  tff(decl_45023, type, fn_human_sperm_11: $i > $i).
% 29.22/29.05  tff(decl_45024, type, fn_human_sperm_12: $i > $i).
% 29.22/29.05  tff(decl_45025, type, fn_human_sperm_13: $i > $i).
% 29.22/29.05  tff(decl_45026, type, fn_human_sperm_14: $i > $i).
% 29.22/29.05  tff(decl_45027, type, fn_human_sperm_15: $i > $i).
% 29.22/29.05  tff(decl_45028, type, fn_human_sperm_16: $i > $i).
% 29.22/29.05  tff(decl_45029, type, fn_human_sperm_17: $i > $i).
% 29.22/29.05  tff(decl_45030, type, fn_human_sperm_18: $i > $i).
% 29.22/29.05  tff(decl_45031, type, fn_human_sperm_19: $i > $i).
% 29.22/29.05  tff(decl_45032, type, fn_human_sperm_20: $i > $i).
% 29.22/29.05  tff(decl_45033, type, fn_human_sperm_21: $i > $i).
% 29.22/29.05  tff(decl_45034, type, fn_human_sperm_22: $i > $i).
% 29.22/29.05  tff(decl_45035, type, fn_human_sperm_25: $i > $i).
% 29.22/29.05  tff(decl_45036, type, fn_human_sperm_26: $i > $i).
% 29.22/29.05  tff(decl_45037, type, fn_human_sperm_27: $i > $i).
% 29.22/29.05  tff(decl_45038, type, fn_human_sperm_28: $i > $i).
% 29.22/29.05  tff(decl_45039, type, fn_human_sperm_29: $i > $i).
% 29.22/29.05  tff(decl_45040, type, fn_human_sperm_30: $i > $i).
% 29.22/29.05  tff(decl_45041, type, fn_human_sperm_31: $i > $i).
% 29.22/29.05  tff(decl_45042, type, fn_human_sperm_32: $i > $i).
% 29.22/29.05  tff(decl_45043, type, fn_human_sperm_33: $i > $i).
% 29.22/29.05  tff(decl_45044, type, fn_human_sperm_34: $i > $i).
% 29.22/29.05  tff(decl_45045, type, fn_human_sperm_35: $i > $i).
% 29.22/29.05  tff(decl_45046, type, fn_human_sperm_36: $i > $i).
% 29.22/29.05  tff(decl_45047, type, fn_human_sperm_37: $i > $i).
% 29.22/29.05  tff(decl_45048, type, fn_human_sperm_38: $i > $i).
% 29.22/29.05  tff(decl_45049, type, fn_human_sperm_39: $i > $i).
% 29.22/29.05  tff(decl_45050, type, fn_human_sperm_40: $i > $i).
% 29.22/29.05  tff(decl_45051, type, fn_human_sperm_41: $i > $i).
% 29.22/29.05  tff(decl_45052, type, fn_human_sperm_42: $i > $i).
% 29.22/29.05  tff(decl_45053, type, fn_human_sperm_43: $i > $i).
% 29.22/29.05  tff(decl_45054, type, fn_human_sperm_44: $i > $i).
% 29.22/29.05  tff(decl_45055, type, fn_human_sperm_45: $i > $i).
% 29.22/29.05  tff(decl_45056, type, fn_human_sperm_46: $i > $i).
% 29.22/29.05  tff(decl_45057, type, fn_human_sperm_47: $i > $i).
% 29.22/29.05  tff(decl_45058, type, fn_human_sperm_48: $i > $i).
% 29.22/29.05  tff(decl_45059, type, fn_human_sperm_49: $i > $i).
% 29.22/29.05  tff(decl_45060, type, fn_human_sperm_50: $i > $i).
% 29.22/29.05  tff(decl_45061, type, fn_human_sperm_51: $i > $i).
% 29.22/29.05  tff(decl_45062, type, fn_human_sperm_52: $i > $i).
% 29.22/29.05  tff(decl_45063, type, fn_human_sperm_53: $i > $i).
% 29.22/29.05  tff(decl_45064, type, fn_human_sperm_54: $i > $i).
% 29.22/29.05  tff(decl_45065, type, fn_human_sperm_55: $i > $i).
% 29.22/29.05  tff(decl_45066, type, fn_human_sperm_56: $i > $i).
% 29.22/29.05  tff(decl_45067, type, fn_human_sperm_57: $i > $i).
% 29.22/29.05  tff(decl_45068, type, fn_human_sperm_58: $i > $i).
% 29.22/29.05  tff(decl_45069, type, fn_sperm_cell_8: $i > $i).
% 29.22/29.05  tff(decl_45070, type, fn_sperm_cell_30: $i > $i).
% 29.22/29.05  tff(decl_45071, type, fn_sperm_cell_23: $i > $i).
% 29.22/29.05  tff(decl_45072, type, fn_human_sperm_24: $i > $i).
% 29.22/29.05  tff(decl_45073, type, fn_human_sperm_23: $i > $i).
% 29.22/29.05  tff(decl_45074, type, fn_sperm_cell_15: $i > $i).
% 29.22/29.05  tff(decl_45075, type, fn_sperm_cell_14: $i > $i).
% 29.22/29.05  tff(decl_45076, type, fn_sperm_cell_16: $i > $i).
% 29.22/29.05  tff(decl_45077, type, fn_sperm_cell_25: $i > $i).
% 29.22/29.05  tff(decl_45078, type, fn_sperm_cell_22: $i > $i).
% 29.22/29.05  tff(decl_45079, type, fn_sperm_cell_13: $i > $i).
% 29.22/29.05  tff(decl_45080, type, fn_sperm_cell_9: $i > $i).
% 29.22/29.05  tff(decl_45081, type, fn_sperm_cell_35: $i > $i).
% 29.22/29.05  tff(decl_45082, type, fn_sperm_cell_17: $i > $i).
% 29.22/29.05  tff(decl_45083, type, fn_sperm_cell_31: $i > $i).
% 29.22/29.05  tff(decl_45084, type, fn_sperm_cell_33: $i > $i).
% 29.22/29.05  tff(decl_45085, type, fn_sperm_cell_12: $i > $i).
% 29.22/29.05  tff(decl_45086, type, fn_sperm_cell_28: $i > $i).
% 29.22/29.05  tff(decl_45087, type, fn_sperm_cell_4: $i > $i).
% 29.22/29.05  tff(decl_45088, type, fn_sperm_cell_27: $i > $i).
% 29.22/29.05  tff(decl_45089, type, fn_sperm_cell_32: $i > $i).
% 29.22/29.05  tff(decl_45090, type, 'Humidity-Constant': $i).
% 29.22/29.05  tff(decl_45091, type, 'constant of humidity': $i).
% 29.22/29.05  tff(decl_45092, type, 'humidity constant': $i).
% 29.22/29.05  tff(decl_45093, type, 'humidity-constant': $i).
% 29.22/29.05  tff(decl_45094, type, humidity_scale_1: $i > $o).
% 29.22/29.05  tff(decl_45095, type, 'Humidity-Scale': $i).
% 29.22/29.05  tff(decl_45096, type, 'scale of humidity': $i).
% 29.22/29.05  tff(decl_45097, type, 'humidity scale': $i).
% 29.22/29.05  tff(decl_45098, type, 'humidity-scale': $i).
% 29.22/29.05  tff(decl_45099, type, 'Humidity-Value': $i).
% 29.22/29.05  tff(decl_45100, type, humidity: $i).
% 29.22/29.05  tff(decl_45101, type, 'value of humidity': $i).
% 29.22/29.05  tff(decl_45102, type, 'humidity value': $i).
% 29.22/29.05  tff(decl_45103, type, 'humidity-value': $i).
% 29.22/29.05  tff(decl_45104, type, humoral_immune_response_1: $i > $o).
% 29.22/29.05  tff(decl_45105, type, 'Humoral-Immune-Response': $i).
% 29.22/29.05  tff(decl_45106, type, 'The aspect of immunity that involves the mediation of molecules such as antibodies secreted by B cells and complement proteins.': $i).
% 29.22/29.05  tff(decl_45107, type, 'humoral immune response': $i).
% 29.22/29.05  tff(decl_45108, type, 'humoral-immune-response': $i).
% 29.22/29.05  tff(decl_45109, type, humus_1: $i > $o).
% 29.22/29.05  tff(decl_45110, type, 'Humus': $i).
% 29.22/29.05  tff(decl_45111, type, 'Decomposed organic matter that adds structural stability to soil and increases nutrient and moisture retention.': $i).
% 29.22/29.05  tff(decl_45112, type, humus: $i).
% 29.22/29.05  tff(decl_45113, type, fn_humus_1: $i > $i).
% 29.22/29.05  tff(decl_45114, type, 'Huntingtons-Disease': $i).
% 29.22/29.05  tff(decl_45115, type, 'A human genetic disease caused by a dominant allele; characterized by uncontrollable body movements and degeneration of the nervous system; usually fatal 10 to 20 years after the onset of symptoms.': $i).
% 29.22/29.05  tff(decl_45116, type, 'huntington\\s chorea': $i).
% 29.22/29.05  tff(decl_45117, type, 'huntington\\s-chorea': $i).
% 29.22/29.05  tff(decl_45118, type, 'huntingtons disease': $i).
% 29.22/29.05  tff(decl_45119, type, 'huntingtons-disease': $i).
% 29.22/29.05  tff(decl_45120, type, fn_huntingtons_disease_1: $i > $i).
% 29.22/29.05  tff(decl_45121, type, fn_huntingtons_disease_2: $i > $i).
% 29.22/29.05  tff(decl_45122, type, fn_huntingtons_disease_3: $i > $i).
% 29.22/29.05  tff(decl_45123, type, fn_huntingtons_disease_4: $i > $i).
% 29.22/29.05  tff(decl_45124, type, 'Hybrid': $i).
% 29.22/29.05  tff(decl_45125, type, 'Offspring that results from the mating of individuals from two different species or two true-breeding varieties of the same species.': $i).
% 29.22/29.05  tff(decl_45126, type, hybrid: $i).
% 29.22/29.05  tff(decl_45127, type, hybrid_breakdown_1: $i > $o).
% 29.22/29.05  tff(decl_45128, type, 'Hybrid-Breakdown': $i).
% 29.22/29.05  tff(decl_45129, type, 'When first generation hybrids are viable and fertile but the next generation is not.': $i).
% 29.22/29.05  tff(decl_45130, type, 'breakdown of hybrid': $i).
% 29.22/29.05  tff(decl_45131, type, 'hybrid breakdown': $i).
% 29.22/29.05  tff(decl_45132, type, 'hybrid-breakdown': $i).
% 29.22/29.05  tff(decl_45133, type, hybrid_reduced_fertility_1: $i > $o).
% 29.22/29.05  tff(decl_45134, type, hybrid_reduced_viability_1: $i > $o).
% 29.22/29.05  tff(decl_45135, type, temporal_isolation_1: $i > $o).
% 29.22/29.05  tff(decl_45136, type, hybrid_orbital_1: $i > $o).
% 29.22/29.05  tff(decl_45137, type, 'Hybrid-Orbital': $i).
% 29.22/29.05  tff(decl_45138, type, 'A type of orbital that forms as a result of mixing different kinds of atomic orbitals on the same atom.  For example, mixing one s orbital and 3 p orbitals to form an sp3 hybrid orbital.': $i).
% 29.22/29.05  tff(decl_45139, type, 'orbital of hybrid': $i).
% 29.22/29.05  tff(decl_45140, type, 'hybrid orbital': $i).
% 29.22/29.05  tff(decl_45141, type, 'hybrid-orbital': $i).
% 29.22/29.05  tff(decl_45142, type, fn_hybrid_orbital_1: $i > $i).
% 29.22/29.05  tff(decl_45143, type, fn_hybrid_orbital_2: $i > $i).
% 29.22/29.05  tff(decl_45144, type, fn_hybrid_orbital_3: $i > $i).
% 29.22/29.05  tff(decl_45145, type, fn_hybrid_orbital_4: $i > $i).
% 29.22/29.05  tff(decl_45146, type, orbital_0: $i).
% 29.22/29.05  tff(decl_45147, type, 'Hybrid-Reduced-Fertility': $i).
% 29.22/29.05  tff(decl_45148, type, 'A post-zygotic barrier in which two species mate and produce hybrid offspring that are viable but completely or largely sterile.': $i).
% 29.22/29.05  tff(decl_45149, type, 'hybrid reduced fertility': $i).
% 29.22/29.05  tff(decl_45150, type, 'hybrid-reduced-fertility': $i).
% 29.22/29.05  tff(decl_45151, type, 'Hybrid-Reduced-Viability': $i).
% 29.22/29.05  tff(decl_45152, type, 'A post-zygotic reproductive barrier due to genetic incompatibility between the two species, resulting in abortion of development or frail offspring.': $i).
% 29.22/29.05  tff(decl_45153, type, 'hybrid reduced viability': $i).
% 29.22/29.05  tff(decl_45154, type, 'hybrid-reduced-viability': $i).
% 29.22/29.05  tff(decl_45155, type, 'Hybridization': $i).
% 29.22/29.05  tff(decl_45156, type, 'In genetics, the mating, or crossing, of two true-breeding varieties.': $i).
% 29.22/29.05  tff(decl_45157, type, hybridize: $i).
% 29.22/29.05  tff(decl_45158, type, hybridization: $i).
% 29.22/29.05  tff(decl_45159, type, fn_hybridization_1: $i > $i).
% 29.22/29.05  tff(decl_45160, type, fn_hybridization_2: $i > $i).
% 29.22/29.05  tff(decl_45161, type, fn_hybridization_3: $i > $i).
% 29.22/29.05  tff(decl_45162, type, fn_monohybrid_4: $i > $i).
% 29.22/29.05  tff(decl_45163, type, 'Hydra': $i).
% 29.22/29.05  tff(decl_45164, type, 'A genus of polypoid freshwater cnidarians, studied by biologists because of their ability to regenerate and apparent lack of senescence.': $i).
% 29.22/29.05  tff(decl_45165, type, hydra: $i).
% 29.22/29.05  tff(decl_45166, type, polyp_1: $i > $o).
% 29.22/29.05  tff(decl_45167, type, fn_hydra_1: $i > $i).
% 29.22/29.05  tff(decl_45168, type, fn_hydra_2: $i > $i).
% 29.22/29.05  tff(decl_45169, type, fn_hydra_3: $i > $i).
% 29.22/29.05  tff(decl_45170, type, fn_hydra_4: $i > $i).
% 29.22/29.05  tff(decl_45171, type, fn_hydra_5: $i > $i).
% 29.22/29.05  tff(decl_45172, type, fn_hydra_6: $i > $i).
% 29.22/29.05  tff(decl_45173, type, fn_hydra_7: $i > $i).
% 29.22/29.05  tff(decl_45174, type, fn_hydra_8: $i > $i).
% 29.22/29.05  tff(decl_45175, type, fn_hydra_9: $i > $i).
% 29.22/29.05  tff(decl_45176, type, fn_hydra_10: $i > $i).
% 29.22/29.05  tff(decl_45177, type, fn_hydra_11: $i > $i).
% 29.22/29.05  tff(decl_45178, type, fn_hydra_12: $i > $i).
% 29.22/29.05  tff(decl_45179, type, fn_hydra_13: $i > $i).
% 29.22/29.05  tff(decl_45180, type, fn_hydra_14: $i > $i).
% 29.22/29.05  tff(decl_45181, type, fn_hydra_15: $i > $i).
% 29.22/29.05  tff(decl_45182, type, fn_hydra_16: $i > $i).
% 29.22/29.05  tff(decl_45183, type, fn_hydra_17: $i > $i).
% 29.22/29.05  tff(decl_45184, type, fn_hydra_18: $i > $i).
% 29.22/29.05  tff(decl_45185, type, fn_hydra_19: $i > $i).
% 29.22/29.05  tff(decl_45186, type, fn_hydra_20: $i > $i).
% 29.22/29.05  tff(decl_45187, type, fn_hydra_21: $i > $i).
% 29.22/29.05  tff(decl_45188, type, fn_hydra_22: $i > $i).
% 29.22/29.05  tff(decl_45189, type, fn_hydra_23: $i > $i).
% 29.22/29.05  tff(decl_45190, type, fn_hydra_24: $i > $i).
% 29.22/29.05  tff(decl_45191, type, fn_hydra_25: $i > $i).
% 29.22/29.05  tff(decl_45192, type, fn_hydra_26: $i > $i).
% 29.22/29.05  tff(decl_45193, type, fn_hydra_27: $i > $i).
% 29.22/29.05  tff(decl_45194, type, fn_hydra_28: $i > $i).
% 29.22/29.05  tff(decl_45195, type, fn_hydra_29: $i > $i).
% 29.22/29.05  tff(decl_45196, type, fn_hydra_30: $i > $i).
% 29.22/29.05  tff(decl_45197, type, fn_hydra_31: $i > $i).
% 29.22/29.05  tff(decl_45198, type, fn_hydra_32: $i > $i).
% 29.22/29.05  tff(decl_45199, type, fn_hydra_33: $i > $i).
% 29.22/29.05  tff(decl_45200, type, fn_hydra_34: $i > $i).
% 29.22/29.05  tff(decl_45201, type, fn_hydra_35: $i > $i).
% 29.22/29.05  tff(decl_45202, type, fn_hydra_36: $i > $i).
% 29.22/29.05  tff(decl_45203, type, fn_hydra_37: $i > $i).
% 29.22/29.05  tff(decl_45204, type, fn_hydra_38: $i > $i).
% 29.22/29.05  tff(decl_45205, type, fn_hydra_39: $i > $i).
% 29.22/29.05  tff(decl_45206, type, fn_hydra_40: $i > $i).
% 29.22/29.05  tff(decl_45207, type, fn_hydra_41: $i > $i).
% 29.22/29.05  tff(decl_45208, type, fn_hydra_44: $i > $i).
% 29.22/29.05  tff(decl_45209, type, fn_hydra_45: $i > $i).
% 29.22/29.05  tff(decl_45210, type, fn_hydra_42: $i > $i).
% 29.22/29.05  tff(decl_45211, type, fn_hydra_43: $i > $i).
% 29.22/29.05  tff(decl_45212, type, hydration_shell_1: $i > $o).
% 29.22/29.05  tff(decl_45213, type, fn_hydrated_ion_2: $i > $i).
% 29.22/29.05  tff(decl_45214, type, 'Hydrated-Ion': $i).
% 29.22/29.05  tff(decl_45215, type, 'An ion surrounded by a shell of water around it.': $i).
% 29.22/29.05  tff(decl_45216, type, 'hydrated ion': $i).
% 29.22/29.05  tff(decl_45217, type, 'hydrated-ion': $i).
% 29.22/29.05  tff(decl_45218, type, fn_hydration_shell_1: $i > $i).
% 29.22/29.05  tff(decl_45219, type, hydrated_molecule_1: $i > $o).
% 29.22/29.05  tff(decl_45220, type, 'Hydrated-Molecule': $i).
% 29.22/29.05  tff(decl_45221, type, 'A molecule with a shell of water surrounding it.': $i).
% 29.22/29.05  tff(decl_45222, type, 'hydrated molecule': $i).
% 29.22/29.05  tff(decl_45223, type, 'hydrated-molecule': $i).
% 29.22/29.05  tff(decl_45224, type, fn_hydrated_molecule_1: $i > $i).
% 29.22/29.05  tff(decl_45225, type, fn_hydrated_molecule_2: $i > $i).
% 29.22/29.05  tff(decl_45226, type, 'Hydration': $i).
% 29.22/29.05  tff(decl_45227, type, 'A chemical reaction in which a hydroxyl group (OH-) and a hydrogen cation are added to the two carbon atoms bonded together in the carbon-carbon double bond which makes up an alkene functional group.': $i).
% 29.22/29.05  tff(decl_45228, type, hydrate: $i).
% 29.22/29.05  tff(decl_45229, type, hydration: $i).
% 29.22/29.05  tff(decl_45230, type, fn_hydration_1: $i > $i).
% 29.22/29.05  tff(decl_45231, type, 'Hydration-Shell': $i).
% 29.22/29.05  tff(decl_45232, type, 'Water molecules which surround and accompany an ion dissolved in a solution.': $i).
% 29.22/29.05  tff(decl_45233, type, 'solvation shell': $i).
% 29.22/29.05  tff(decl_45234, type, 'shell of hydration': $i).
% 29.22/29.05  tff(decl_45235, type, 'hydration shell': $i).
% 29.22/29.05  tff(decl_45236, type, 'hydration-shell': $i).
% 29.22/29.05  tff(decl_45237, type, fn_hydration_shell_2: $i > $i).
% 29.22/29.05  tff(decl_45238, type, fn_hydration_shell_4: $i > $i).
% 29.22/29.05  tff(decl_45239, type, fn_hydration_shell_5: $i > $i).
% 29.22/29.05  tff(decl_45240, type, fn_hydration_shell_6: $i > $i).
% 29.22/29.05  tff(decl_45241, type, 'Hydrocarbon-Chain': $i).
% 29.22/29.05  tff(decl_45242, type, 'Hydrocarbons joined together in a chain form a hydrocarbon chain.': $i).
% 29.22/29.05  tff(decl_45243, type, 'chain of hydrocarbon': $i).
% 29.22/29.05  tff(decl_45244, type, 'hydrocarbon chain': $i).
% 29.22/29.05  tff(decl_45245, type, 'hydrocarbon-chain': $i).
% 29.22/29.05  tff(decl_45246, type, 'Hydrocarbon-Molecule': $i).
% 29.22/29.05  tff(decl_45247, type, 'A class of organic molecules consisting entirely of carbon and hydrogen and no other types of atoms.': $i).
% 29.22/29.05  tff(decl_45248, type, hydrocarbon: $i).
% 29.22/29.05  tff(decl_45249, type, 'molecule of hydrocarbon': $i).
% 29.22/29.05  tff(decl_45250, type, 'hydrocarbon molecule': $i).
% 29.22/29.05  tff(decl_45251, type, 'hydrocarbon-molecule': $i).
% 29.22/29.05  tff(decl_45252, type, fn_hydrocarbon_molecule_1: $i > $i).
% 29.22/29.05  tff(decl_45253, type, fn_hydrocarbon_molecule_7: $i > $i).
% 29.22/29.05  tff(decl_45254, type, fn_hydrocarbon_molecule_9: $i > $i).
% 29.22/29.05  tff(decl_45255, type, fn_hydrocarbon_molecule_10: $i > $i).
% 29.22/29.05  tff(decl_45256, type, fn_hydrocarbon_molecule_12: $i > $i).
% 29.22/29.05  tff(decl_45257, type, fn_hydrocarbon_molecule_13: $i > $i).
% 29.22/29.05  tff(decl_45258, type, fn_hydrocarbon_molecule_26: $i > $i).
% 29.22/29.05  tff(decl_45259, type, fn_hydrocarbon_molecule_31: $i > $i).
% 29.22/29.05  tff(decl_45260, type, fn_hydrocarbon_molecule_32: $i > $i).
% 29.22/29.05  tff(decl_45261, type, fn_hydrocarbon_molecule_4: $i > $i).
% 29.22/29.05  tff(decl_45262, type, fn_hydrocarbon_molecule_3: $i > $i).
% 29.22/29.05  tff(decl_45263, type, 'Hydrocarbon-Substance': $i).
% 29.22/29.05  tff(decl_45264, type, 'substance of hydrocarbon': $i).
% 29.22/29.05  tff(decl_45265, type, 'hydrocarbon substance': $i).
% 29.22/29.05  tff(decl_45266, type, 'hydrocarbon-substance': $i).
% 29.22/29.05  tff(decl_45267, type, organic_molecule_substance_1: $i > $o).
% 29.22/29.05  tff(decl_45268, type, fn_organic_molecule_substance_1: $i > $i).
% 29.22/29.05  tff(decl_45269, type, 'Hydrochloric-Acid': $i).
% 29.22/29.05  tff(decl_45270, type, 'A strong acid with the chemical formula HCl.': $i).
% 29.22/29.05  tff(decl_45271, type, 'hydrochloric acid': $i).
% 29.22/29.05  tff(decl_45272, type, 'hydrochloric-acid': $i).
% 29.22/29.05  tff(decl_45273, type, strong_acid_1: $i > $o).
% 29.22/29.05  tff(decl_45274, type, hydrochloric_acid_molecule_1: $i > $o).
% 29.22/29.05  tff(decl_45275, type, 'Hydrochloric-Acid-Molecule': $i).
% 29.22/29.05  tff(decl_45276, type, 'Molecule with molecular formula HCl which dissociates to form hydrochloric acid in solution.': $i).
% 29.22/29.05  tff(decl_45277, type, 'hydrochloric acid molecule': $i).
% 29.22/29.05  tff(decl_45278, type, 'hydrochloric-acid-molecule': $i).
% 29.22/29.05  tff(decl_45279, type, hydroelectric_system_1: $i > $o).
% 29.22/29.05  tff(decl_45280, type, 'Hydroelectric-System': $i).
% 29.22/29.05  tff(decl_45281, type, 'A system in which the movement of water is used to generate electricity.': $i).
% 29.22/29.05  tff(decl_45282, type, 'hydroelectric system': $i).
% 29.22/29.05  tff(decl_45283, type, 'hydroelectric-system': $i).
% 29.22/29.05  tff(decl_45284, type, 'Hydrogen': $i).
% 29.22/29.05  tff(decl_45285, type, 'Hydrogen is a non metal atom with atomic number 1. It is represented by the symbol H. Isotopes include H-1, H-2 and H-3.': $i).
% 29.22/29.05  tff(decl_45286, type, 'H': $i).
% 29.22/29.05  tff(decl_45287, type, hydrogen: $i).
% 29.22/29.05  tff(decl_45288, type, fn_hydrogen_4: $i > $i).
% 29.22/29.05  tff(decl_45289, type, fn_hydrogen_5: $i > $i).
% 29.22/29.05  tff(decl_45290, type, "1.008": $i).
% 29.22/29.05  tff(decl_45291, type, hydrogen_1_1: $i > $o).
% 29.22/29.05  tff(decl_45292, type, 'Hydrogen-1': $i).
% 29.22/29.05  tff(decl_45293, type, 'This is one of the hydrogen isotopes that possess zero neutrons.': $i).
% 29.22/29.05  tff(decl_45294, type, '1 of hydrogen': $i).
% 29.22/29.05  tff(decl_45295, type, 'hydrogen 1': $i).
% 29.22/29.05  tff(decl_45296, type, 'hydrogen-1': $i).
% 29.22/29.05  tff(decl_45297, type, hydrogen_isotope_1: $i > $o).
% 29.22/29.05  tff(decl_45298, type, fn_hydrogen_1_1: $i > $i).
% 29.22/29.05  tff(decl_45299, type, fn_hydrogen_1_4: $i > $i).
% 29.22/29.05  tff(decl_45300, type, fn_hydrogen_1_5: $i > $i).
% 29.22/29.05  tff(decl_45301, type, "1.007e0": $i).
% 29.22/29.05  tff(decl_45302, type, fn_hydrogen_1_3: $i > $i).
% 29.22/29.05  tff(decl_45303, type, hydrogen_2_1: $i > $o).
% 29.22/29.05  tff(decl_45304, type, 'Hydrogen-2': $i).
% 29.22/29.05  tff(decl_45305, type, 'This is one of the hydrogen isotopes that possess one neutrons.': $i).
% 29.22/29.05  tff(decl_45306, type, '2 of hydrogen': $i).
% 29.22/29.05  tff(decl_45307, type, 'hydrogen 2': $i).
% 29.22/29.05  tff(decl_45308, type, 'hydrogen-2': $i).
% 29.22/29.05  tff(decl_45309, type, fn_hydrogen_2_1: $i > $i).
% 29.22/29.05  tff(decl_45310, type, fn_hydrogen_2_2: $i > $i).
% 29.22/29.05  tff(decl_45311, type, fn_hydrogen_2_5: $i > $i).
% 29.22/29.05  tff(decl_45312, type, "2.014e0": $i).
% 29.22/29.05  tff(decl_45313, type, fn_hydrogen_2_4: $i > $i).
% 29.22/29.05  tff(decl_45314, type, hydrogen_3_1: $i > $o).
% 29.22/29.05  tff(decl_45315, type, 'Hydrogen-3': $i).
% 29.22/29.05  tff(decl_45316, type, 'This is one of the hydrogen isotopes that possess two neutrons.': $i).
% 29.22/29.05  tff(decl_45317, type, '3 of hydrogen': $i).
% 29.22/29.05  tff(decl_45318, type, 'hydrogen 3': $i).
% 29.22/29.05  tff(decl_45319, type, 'hydrogen-3': $i).
% 29.22/29.05  tff(decl_45320, type, fn_hydrogen_3_2: $i > $i).
% 29.22/29.05  tff(decl_45321, type, fn_hydrogen_3_3: $i > $i).
% 29.22/29.05  tff(decl_45322, type, fn_hydrogen_3_5: $i > $i).
% 29.22/29.05  tff(decl_45323, type, "3.016e0": $i).
% 29.22/29.05  tff(decl_45324, type, fn_hydrogen_3_4: $i > $i).
% 29.22/29.05  tff(decl_45325, type, 'Hydrogen-Bond': $i).
% 29.22/29.05  tff(decl_45326, type, 'Hydrogen bond is the attractive interaction of a hydrogen atom with an atom of high electronegativity.': $i).
% 29.22/29.05  tff(decl_45327, type, 'bond of hydrogen': $i).
% 29.22/29.05  tff(decl_45328, type, 'hydrogen bond': $i).
% 29.22/29.05  tff(decl_45329, type, 'hydrogen-bond': $i).
% 29.22/29.05  tff(decl_45330, type, fn_hydrogen_bond_2: $i > $i).
% 29.22/29.05  tff(decl_45331, type, fn_hydrogen_bond_6: $i > $i).
% 29.22/29.05  tff(decl_45332, type, fn_hydrogen_bond_7: $i > $i).
% 29.22/29.05  tff(decl_45333, type, fn_hydrogen_bond_8: $i > $i).
% 29.22/29.05  tff(decl_45334, type, fn_hydrogen_bond_9: $i > $i).
% 29.22/29.05  tff(decl_45335, type, fn_hydrogen_bond_10: $i > $i).
% 29.22/29.05  tff(decl_45336, type, fn_hydrogen_bond_16: $i > $i).
% 29.22/29.05  tff(decl_45337, type, fn_hydrogen_bond_17: $i > $i).
% 29.22/29.05  tff(decl_45338, type, fn_hydrogen_bond_18: $i > $i).
% 29.22/29.05  tff(decl_45339, type, fn_hydrogen_bond_19: $i > $i).
% 29.22/29.05  tff(decl_45340, type, fn_hydrogen_bond_20: $i > $i).
% 29.22/29.05  tff(decl_45341, type, fn_hydrogen_bond_21: $i > $i).
% 29.22/29.05  tff(decl_45342, type, fn_hydrogen_bond_22: $i > $i).
% 29.22/29.05  tff(decl_45343, type, fn_hydrogen_bond_23: $i > $i).
% 29.22/29.05  tff(decl_45344, type, fn_hydrogen_bond_24: $i > $i).
% 29.22/29.05  tff(decl_45345, type, fn_hydrogen_bond_25: $i > $i).
% 29.22/29.05  tff(decl_45346, type, fn_hydrogen_bond_3: $i > $i).
% 29.22/29.05  tff(decl_45347, type, fn_hydrogen_bond_15: $i > $i).
% 29.22/29.05  tff(decl_45348, type, fn_hydrogen_bond_4: $i > $i).
% 29.22/29.05  tff(decl_45349, type, fn_hydrogen_bond_5: $i > $i).
% 29.22/29.05  tff(decl_45350, type, hydrogen_cyanide_1: $i > $o).
% 29.22/29.05  tff(decl_45351, type, 'Hydrogen-Cyanide': $i).
% 29.22/29.05  tff(decl_45352, type, 'It is a chemical compound with chemical formula HCN. It is a colorless and extremely poisonous liquid.': $i).
% 29.22/29.05  tff(decl_45353, type, hcn: $i).
% 29.22/29.05  tff(decl_45354, type, 'cyanide of hydrogen': $i).
% 29.22/29.05  tff(decl_45355, type, 'hydrogen cyanide': $i).
% 29.22/29.05  tff(decl_45356, type, 'hydrogen-cyanide': $i).
% 29.22/29.05  tff(decl_45357, type, 'Hydrogen-Ion': $i).
% 29.22/29.05  tff(decl_45358, type, 'A hydrogen ion is formed by release of one electron from a hydrogen atom, resulting in an ion with a charge of +1.': $i).
% 29.22/29.05  tff(decl_45359, type, 'h+': $i).
% 29.22/29.05  tff(decl_45360, type, 'ion of hydrogen': $i).
% 29.22/29.05  tff(decl_45361, type, 'hydrogen ion': $i).
% 29.22/29.05  tff(decl_45362, type, 'hydrogen-ion': $i).
% 29.22/29.05  tff(decl_45363, type, fn_hydrogen_ion_1: $i > $i).
% 29.22/29.05  tff(decl_45364, type, fn_hydrogen_ion_2: $i > $i).
% 29.22/29.05  tff(decl_45365, type, fn_hydrogen_ion_4: $i > $i).
% 29.22/29.05  tff(decl_45366, type, fn_hydrogen_ion_6: $i > $i).
% 29.22/29.05  tff(decl_45367, type, fn_hydrogen_ion_7: $i > $i).
% 29.22/29.05  tff(decl_45368, type, fn_hydrogen_ion_8: $i > $i).
% 29.22/29.05  tff(decl_45369, type, 'Hydrogen-Ion-Gradient': $i).
% 29.22/29.05  tff(decl_45370, type, 'A hydrogen ion gradient is a measurement of how the concentration of hydrogen ions change from one place to another, across a membrane.': $i).
% 29.22/29.05  tff(decl_45371, type, 'proton gradient': $i).
% 29.22/29.05  tff(decl_45372, type, 'ph gradient': $i).
% 29.22/29.05  tff(decl_45373, type, 'hydrogen ion gradient': $i).
% 29.22/29.05  tff(decl_45374, type, 'hydrogen-ion-gradient': $i).
% 29.22/29.05  tff(decl_45375, type, fn_hydrogen_ion_gradient_1: $i > $i).
% 29.22/29.05  tff(decl_45376, type, 'Hydrogen-Isotope': $i).
% 29.22/29.05  tff(decl_45377, type, 'All the hydrogen isoptopes have 1 proton and 1 electron. They differ in their neutron number.': $i).
% 29.22/29.05  tff(decl_45378, type, 'isotope of hydrogen': $i).
% 29.22/29.05  tff(decl_45379, type, 'hydrogen isotope': $i).
% 29.22/29.05  tff(decl_45380, type, 'hydrogen-isotope': $i).
% 29.22/29.05  tff(decl_45381, type, fn_hydrogen_isotope_1: $i > $i).
% 29.22/29.05  tff(decl_45382, type, fn_hydrogen_isotope_2: $i > $i).
% 29.22/29.05  tff(decl_45383, type, fn_hydrogen_isotope_3: $i > $i).
% 29.22/29.05  tff(decl_45384, type, fn_hydrogen_isotope_6: $i > $i).
% 29.22/29.05  tff(decl_45385, type, fn_hydrogen_isotope_7: $i > $i).
% 29.22/29.05  tff(decl_45386, type, fn_hydrogen_isotope_8: $i > $i).
% 29.22/29.05  tff(decl_45387, type, hydrogen_molecule_1: $i > $o).
% 29.22/29.05  tff(decl_45388, type, 'Hydrogen-Molecule': $i).
% 29.22/29.05  tff(decl_45389, type, 'Two atoms of hydrogen constitute a hydrogen molecule.': $i).
% 29.22/29.05  tff(decl_45390, type, h2: $i).
% 29.22/29.05  tff(decl_45391, type, 'molecule of hydrogen': $i).
% 29.22/29.05  tff(decl_45392, type, 'hydrogen molecule': $i).
% 29.22/29.05  tff(decl_45393, type, 'hydrogen-molecule': $i).
% 29.22/29.05  tff(decl_45394, type, hydrogen_sulfide_1: $i > $o).
% 29.22/29.05  tff(decl_45395, type, inorganic_acid_1: $i > $o).
% 29.22/29.05  tff(decl_45396, type, fn_hydrogen_molecule_1: $i > $i).
% 29.22/29.05  tff(decl_45397, type, fn_hydrogen_molecule_2: $i > $i).
% 29.22/29.05  tff(decl_45398, type, fn_hydrogen_molecule_3: $i > $i).
% 29.22/29.05  tff(decl_45399, type, fn_hydrogen_molecule_4: $i > $i).
% 29.22/29.05  tff(decl_45400, type, fn_hydrogen_molecule_5: $i > $i).
% 29.22/29.05  tff(decl_45401, type, fn_hydrogen_molecule_6: $i > $i).
% 29.22/29.05  tff(decl_45402, type, fn_hydrogen_molecule_7: $i > $i).
% 29.22/29.05  tff(decl_45403, type, fn_hydrogen_molecule_8: $i > $i).
% 29.22/29.05  tff(decl_45404, type, fn_hydrogen_molecule_9: $i > $i).
% 29.22/29.05  tff(decl_45405, type, fn_hydrogen_molecule_10: $i > $i).
% 29.22/29.05  tff(decl_45406, type, fn_hydrogen_molecule_11: $i > $i).
% 29.22/29.05  tff(decl_45407, type, fn_hydrogen_molecule_12: $i > $i).
% 29.22/29.05  tff(decl_45408, type, fn_hydrogen_molecule_13: $i > $i).
% 29.22/29.05  tff(decl_45409, type, fn_hydrogen_molecule_14: $i > $i).
% 29.22/29.05  tff(decl_45410, type, fn_hydrogen_molecule_15: $i > $i).
% 29.22/29.05  tff(decl_45411, type, fn_hydrogen_molecule_16: $i > $i).
% 29.22/29.05  tff(decl_45412, type, hydrogen_peroxide_1: $i > $o).
% 29.22/29.05  tff(decl_45413, type, 'Hydrogen-Peroxide': $i).
% 29.22/29.05  tff(decl_45414, type, 'Hydrogen peroxide is a weak acid with strong oxidizing properties': $i).
% 29.22/29.05  tff(decl_45415, type, 'peroxide of hydrogen': $i).
% 29.22/29.05  tff(decl_45416, type, 'hydrogen peroxide': $i).
% 29.22/29.05  tff(decl_45417, type, 'hydrogen-peroxide': $i).
% 29.22/29.05  tff(decl_45418, type, fn_hydrogen_peroxide_1: $i > $i).
% 29.22/29.05  tff(decl_45419, type, fn_hydrogen_peroxide_3: $i > $i).
% 29.22/29.05  tff(decl_45420, type, fn_hydrogen_peroxide_4: $i > $i).
% 29.22/29.05  tff(decl_45421, type, hydrogen_peroxide_substance_1: $i > $o).
% 29.22/29.05  tff(decl_45422, type, 'Hydrogen-Peroxide-Substance': $i).
% 29.22/29.05  tff(decl_45423, type, 'A substance consisting of hydrogen peroxide molecules.': $i).
% 29.22/29.05  tff(decl_45424, type, 'hydrogen peroxide substance': $i).
% 29.22/29.05  tff(decl_45425, type, 'hydrogen-peroxide-substance': $i).
% 29.22/29.05  tff(decl_45426, type, 'Hydrogen-Sulfide': $i).
% 29.22/29.05  tff(decl_45427, type, 'A colorless, very poisonous, flammable gas with the characteristic foul odor of rotten eggs.  The formula for this compound is H2S.': $i).
% 29.22/29.05  tff(decl_45428, type, 'sulfide of hydrogen': $i).
% 29.22/29.05  tff(decl_45429, type, 'hydrogen sulfide': $i).
% 29.22/29.05  tff(decl_45430, type, 'hydrogen-sulfide': $i).
% 29.22/29.05  tff(decl_45431, type, fn_hydrogen_sulfide_1: $i > $i).
% 29.22/29.05  tff(decl_45432, type, fn_hydrogen_sulfide_2: $i > $i).
% 29.22/29.05  tff(decl_45433, type, fn_hydrogen_sulfide_4: $i > $i).
% 29.22/29.05  tff(decl_45434, type, hydrogenated_margarine_1: $i > $o).
% 29.22/29.05  tff(decl_45435, type, 'Hydrogenated-Margarine': $i).
% 29.22/29.05  tff(decl_45436, type, 'Vegetable oil which has been converted to solid form through the chemical process of hydrogenation. Hydrogenation increases the proportion of saturated fats in the oil, causing it to be solid at room temperature.': $i).
% 29.22/29.05  tff(decl_45437, type, 'hydrogenated margarine': $i).
% 29.22/29.05  tff(decl_45438, type, 'hydrogenated-margarine': $i).
% 29.22/29.05  tff(decl_45439, type, margarine_1: $i > $o).
% 29.22/29.05  tff(decl_45440, type, 'FA1': $i).
% 29.22/29.05  tff(decl_45441, type, hydrogenated_peanut_butter_1: $i > $o).
% 29.22/29.05  tff(decl_45442, type, 'Hydrogenated-Peanut-Butter': $i).
% 29.22/29.05  tff(decl_45443, type, 'Peanut butter in which the liquid fat has been converted to solid form through the chemical process of hydrogenation. Hydrogenation increases the proportion of saturated fats in the oil, causing it to be solid at room temperature.': $i).
% 29.22/29.05  tff(decl_45444, type, 'hydrogenated peanut butter': $i).
% 29.22/29.05  tff(decl_45445, type, 'hydrogenated-peanut-butter': $i).
% 29.22/29.05  tff(decl_45446, type, peanut_butter_1: $i > $o).
% 29.22/29.05  tff(decl_45447, type, fn_hydrogenated_peanut_butter_1: $i > $i).
% 29.22/29.05  tff(decl_45448, type, fn_hydrogenated_peanut_butter_2: $i > $i).
% 29.22/29.05  tff(decl_45449, type, fn_hydrogenated_peanut_butter_3: $i > $i).
% 29.22/29.05  tff(decl_45450, type, fn_hydrogenated_peanut_butter_4: $i > $i).
% 29.22/29.05  tff(decl_45451, type, fn_hydrogenated_peanut_butter_5: $i > $i).
% 29.22/29.05  tff(decl_45452, type, hydrogenation_1: $i > $o).
% 29.22/29.05  tff(decl_45453, type, fn_hydrogenated_peanut_butter_6: $i > $i).
% 29.22/29.05  tff(decl_45454, type, fn_hydrogenated_peanut_butter_7: $i > $i).
% 29.22/29.05  tff(decl_45455, type, fn_hydrogenated_peanut_butter_8: $i > $i).
% 29.22/29.05  tff(decl_45456, type, fn_hydrogenation_2: $i > $i).
% 29.22/29.05  tff(decl_45457, type, fn_peanut_butter_1: $i > $i).
% 29.22/29.05  tff(decl_45458, type, fn_peanut_butter_2: $i > $i).
% 29.22/29.05  tff(decl_45459, type, hydrogenated_vegetable_oil_1: $i > $o).
% 29.22/29.05  tff(decl_45460, type, 'Hydrogenated-Vegetable-Oil': $i).
% 29.22/29.05  tff(decl_45461, type, 'Vegetable oil which has been treated by the process of hydrogenation and as a result contains a greater quantity of saturated fatty acids.': $i).
% 29.22/29.05  tff(decl_45462, type, 'hydrogenated vegetable oil': $i).
% 29.22/29.05  tff(decl_45463, type, 'hydrogenated-vegetable-oil': $i).
% 29.22/29.05  tff(decl_45464, type, vegetable_oil_1: $i > $o).
% 29.22/29.05  tff(decl_45465, type, saturated_animal_fat_1: $i > $o).
% 29.22/29.05  tff(decl_45466, type, fn_hydrogenated_vegetable_oil_1: $i > $i).
% 29.22/29.05  tff(decl_45467, type, fn_hydrogenated_vegetable_oil_2: $i > $i).
% 29.22/29.05  tff(decl_45468, type, fn_hydrogenated_vegetable_oil_3: $i > $i).
% 29.22/29.05  tff(decl_45469, type, fn_hydrogenated_vegetable_oil_4: $i > $i).
% 29.22/29.05  tff(decl_45470, type, fn_vegetable_oil_1: $i > $i).
% 29.22/29.05  tff(decl_45471, type, 'Hydrogenation': $i).
% 29.22/29.05  tff(decl_45472, type, 'The addition of hydrogen to another molecule or element.': $i).
% 29.22/29.05  tff(decl_45473, type, hydrogenate: $i).
% 29.22/29.05  tff(decl_45474, type, hydrogenation: $i).
% 29.22/29.05  tff(decl_45475, type, fn_hydrogenation_1: $i > $i).
% 29.22/29.05  tff(decl_45476, type, hydrogentation_1: $i > $o).
% 29.22/29.05  tff(decl_45477, type, 'Hydrogentation': $i).
% 29.22/29.05  tff(decl_45478, type, 'A chemical process in which hydrogen is added to a molecule. It is most commonly used to convert unsaturated fatty acids to saturated fatty acids in the food industry.': $i).
% 29.22/29.05  tff(decl_45479, type, hydrogentation: $i).
% 29.22/29.05  tff(decl_45480, type, fn_hydrogentation_1: $i > $i).
% 29.22/29.05  tff(decl_45481, type, fn_hydrogentation_2: $i > $i).
% 29.22/29.05  tff(decl_45482, type, fn_hydrogentation_3: $i > $i).
% 29.22/29.05  tff(decl_45483, type, 'Hydrolase': $i).
% 29.22/29.05  tff(decl_45484, type, 'Enzymes which catalyze the hydrolysis of various bonds': $i).
% 29.22/29.05  tff(decl_45485, type, hydrolase: $i).
% 29.22/29.05  tff(decl_45486, type, 'Hydrolysis': $i).
% 29.22/29.05  tff(decl_45487, type, 'A chemical reaction that breaks a covalent bond between molecules by inserting water between them; often occurs in the catalysis of polymers to monomers.': $i).
% 29.22/29.05  tff(decl_45488, type, hydrolize: $i).
% 29.22/29.05  tff(decl_45489, type, hydrolysis: $i).
% 29.22/29.05  tff(decl_45490, type, fn_hydrolysis_12: $i > $i).
% 29.22/29.05  tff(decl_45491, type, hydrolysis_of_starch_1: $i > $o).
% 29.22/29.05  tff(decl_45492, type, 'Hydrolysis-Of-Starch': $i).
% 29.22/29.05  tff(decl_45493, type, 'The enzymatic digestion of starch in organisms. Amylase is the enzyme which catalyzes starch breakdown.': $i).
% 29.22/29.05  tff(decl_45494, type, 'starch hydrolysis': $i).
% 29.22/29.05  tff(decl_45495, type, 'starch-hydrolysis': $i).
% 29.22/29.05  tff(decl_45496, type, 'hydrolysis of starch': $i).
% 29.22/29.05  tff(decl_45497, type, 'hydrolysis-of-starch': $i).
% 29.22/29.05  tff(decl_45498, type, fn_hydrolysis_of_starch_5: $i > $i).
% 29.22/29.05  tff(decl_45499, type, fn_hydrolysis_of_starch_6: $i > $i).
% 29.22/29.05  tff(decl_45500, type, fn_hydrolysis_of_starch_7: $i > $i).
% 29.22/29.05  tff(decl_45501, type, fn_hydrolysis_of_starch_8: $i > $i).
% 29.22/29.05  tff(decl_45502, type, fn_hydrolysis_of_starch_9: $i > $i).
% 29.22/29.05  tff(decl_45503, type, fn_hydrolysis_of_starch_10: $i > $i).
% 29.22/29.05  tff(decl_45504, type, fn_hydrolysis_of_starch_11: $i > $i).
% 29.22/29.05  tff(decl_45505, type, fn_hydrolysis_of_starch_12: $i > $i).
% 29.22/29.05  tff(decl_45506, type, fn_hydrolysis_of_starch_13: $i > $i).
% 29.22/29.05  tff(decl_45507, type, fn_hydrolysis_of_starch_14: $i > $i).
% 29.22/29.05  tff(decl_45508, type, fn_hydrolysis_of_starch_15: $i > $i).
% 29.22/29.05  tff(decl_45509, type, fn_hydrolysis_of_starch_16: $i > $i).
% 29.22/29.05  tff(decl_45510, type, fn_hydrolysis_of_starch_17: $i > $i).
% 29.22/29.05  tff(decl_45511, type, fn_hydrolysis_of_starch_18: $i > $i).
% 29.22/29.05  tff(decl_45512, type, fn_hydrolysis_of_starch_19: $i > $i).
% 29.22/29.05  tff(decl_45513, type, fn_hydrolysis_of_starch_20: $i > $i).
% 29.22/29.05  tff(decl_45514, type, fn_hydrolysis_of_starch_21: $i > $i).
% 29.22/29.05  tff(decl_45515, type, fn_hydrolysis_of_starch_22: $i > $i).
% 29.22/29.05  tff(decl_45516, type, fn_hydrolysis_of_starch_23: $i > $i).
% 29.22/29.05  tff(decl_45517, type, fn_hydrolysis_of_starch_24: $i > $i).
% 29.22/29.05  tff(decl_45518, type, fn_hydrolysis_of_starch_25: $i > $i).
% 29.22/29.05  tff(decl_45519, type, fn_hydrolysis_of_starch_26: $i > $i).
% 29.22/29.05  tff(decl_45520, type, fn_hydrolysis_of_starch_27: $i > $i).
% 29.22/29.05  tff(decl_45521, type, fn_hydrolysis_of_starch_28: $i > $i).
% 29.22/29.05  tff(decl_45522, type, fn_glucose_isomer_2: $i > $i).
% 29.22/29.05  tff(decl_45523, type, alpha_glucose_0: $i).
% 29.22/29.05  tff(decl_45524, type, fn_hydrolysis_of_starch_2: $i > $i).
% 29.22/29.05  tff(decl_45525, type, fn_hydrolysis_of_starch_1: $i > $i).
% 29.22/29.05  tff(decl_45526, type, fn_hydrolysis_of_starch_3: $i > $i).
% 29.22/29.05  tff(decl_45527, type, fn_hydrolysis_of_starch_4: $i > $i).
% 29.22/29.05  tff(decl_45528, type, 'Hydrolysis-Of-Sucrose': $i).
% 29.22/29.05  tff(decl_45529, type, 'The process of breaking down a sucrose molecule by addition of water to yield glucose and fructose': $i).
% 29.22/29.05  tff(decl_45530, type, 'sucrose hydrolysis': $i).
% 29.22/29.05  tff(decl_45531, type, 'sucrose-hydrolysis': $i).
% 29.22/29.05  tff(decl_45532, type, 'hydrolysis of sucrose': $i).
% 29.22/29.05  tff(decl_45533, type, 'hydrolysis-of-sucrose': $i).
% 29.22/29.05  tff(decl_45534, type, fn_hydrolysis_of_sucrose_3: $i > $i).
% 29.22/29.05  tff(decl_45535, type, sucrase_1: $i > $o).
% 29.22/29.05  tff(decl_45536, type, fn_hydrolysis_of_sucrose_4: $i > $i).
% 29.22/29.05  tff(decl_45537, type, fn_hydrolysis_of_sucrose_5: $i > $i).
% 29.22/29.05  tff(decl_45538, type, fn_hydrolysis_of_sucrose_6: $i > $i).
% 29.22/29.05  tff(decl_45539, type, fn_hydrolysis_of_sucrose_7: $i > $i).
% 29.22/29.05  tff(decl_45540, type, fn_hydrolysis_of_sucrose_8: $i > $i).
% 29.22/29.05  tff(decl_45541, type, fn_hydrolysis_of_sucrose_9: $i > $i).
% 29.22/29.05  tff(decl_45542, type, fn_hydrolysis_of_sucrose_10: $i > $i).
% 29.22/29.05  tff(decl_45543, type, fn_hydrolysis_of_sucrose_11: $i > $i).
% 29.22/29.05  tff(decl_45544, type, fn_hydrolysis_of_sucrose_12: $i > $i).
% 29.22/29.05  tff(decl_45545, type, fn_hydrolysis_of_sucrose_13: $i > $i).
% 29.22/29.05  tff(decl_45546, type, fn_hydrolysis_of_sucrose_14: $i > $i).
% 29.22/29.05  tff(decl_45547, type, fn_hydrolysis_of_sucrose_15: $i > $i).
% 29.22/29.05  tff(decl_45548, type, fn_hydrolysis_of_sucrose_16: $i > $i).
% 29.22/29.05  tff(decl_45549, type, fn_hydrolysis_of_sucrose_17: $i > $i).
% 29.22/29.05  tff(decl_45550, type, fn_hydrolysis_of_sucrose_18: $i > $i).
% 29.22/29.05  tff(decl_45551, type, fn_hydrolysis_of_sucrose_19: $i > $i).
% 29.22/29.05  tff(decl_45552, type, fn_hydrolysis_of_sucrose_20: $i > $i).
% 29.22/29.05  tff(decl_45553, type, fn_hydrolysis_of_sucrose_21: $i > $i).
% 29.22/29.05  tff(decl_45554, type, fn_hydrolysis_of_sucrose_22: $i > $i).
% 29.22/29.05  tff(decl_45555, type, fn_hydrolysis_of_sucrose_23: $i > $i).
% 29.22/29.05  tff(decl_45556, type, fn_sucrose_29: $i > $i).
% 29.22/29.05  tff(decl_45557, type, fn_sucrose_49: $i > $i).
% 29.22/29.05  tff(decl_45558, type, fn_sucrose_51: $i > $i).
% 29.22/29.05  tff(decl_45559, type, fn_sucrose_30: $i > $i).
% 29.22/29.05  tff(decl_45560, type, fn_sucrose_50: $i > $i).
% 29.22/29.05  tff(decl_45561, type, fn_sucrose_31: $i > $i).
% 29.22/29.05  tff(decl_45562, type, fn_hydrolysis_of_sucrose_1: $i > $i).
% 29.22/29.05  tff(decl_45563, type, fn_hydrolysis_of_sucrose_2: $i > $i).
% 29.22/29.05  tff(decl_45564, type, 'Hydronium-Ion': $i).
% 29.22/29.05  tff(decl_45565, type, 'A water molecule with an  hydrogen ion bound to it; molecular formula H3O+.': $i).
% 29.22/29.05  tff(decl_45566, type, 'hydronium ion': $i).
% 29.22/29.05  tff(decl_45567, type, 'hydronium-ion': $i).
% 29.22/29.05  tff(decl_45568, type, fn_hydronium_ion_1: $i > $i).
% 29.22/29.05  tff(decl_45569, type, fn_hydronium_ion_2: $i > $i).
% 29.22/29.05  tff(decl_45570, type, fn_hydronium_ion_3: $i > $i).
% 29.22/29.05  tff(decl_45571, type, fn_hydronium_ion_4: $i > $i).
% 29.22/29.05  tff(decl_45572, type, fn_hydronium_ion_5: $i > $i).
% 29.22/29.05  tff(decl_45573, type, 'Hydrophilic-Amino-Acid': $i).
% 29.22/29.05  tff(decl_45574, type, 'Amino acid with hydrophillic properties due to the presence of either a polar or an electrically charged side chain.': $i).
% 29.22/29.05  tff(decl_45575, type, 'hydrophilic amino acid': $i).
% 29.22/29.05  tff(decl_45576, type, 'hydrophilic-amino-acid': $i).
% 29.22/29.05  tff(decl_45577, type, 'Hydrophilic-Channel': $i).
% 29.22/29.05  tff(decl_45578, type, 'Structural channel through a protein which is surrounded by hydrophilic amino acids and allows hydrophilic molecules to pass though.': $i).
% 29.22/29.05  tff(decl_45579, type, 'hydrophilic-channel': $i).
% 29.22/29.05  tff(decl_45580, type, 'Hydrophilic-Compound': $i).
% 29.22/29.05  tff(decl_45581, type, 'A molecule with affinity for water.': $i).
% 29.22/29.05  tff(decl_45582, type, 'hydrophilic compound': $i).
% 29.22/29.05  tff(decl_45583, type, 'hydrophilic-compound': $i).
% 29.22/29.05  tff(decl_45584, type, 'Hydrophilic-End': $i).
% 29.22/29.05  tff(decl_45585, type, 'End of an entity that attracts water due to polarity or charge.': $i).
% 29.22/29.05  tff(decl_45586, type, 'hydrophilic end': $i).
% 29.22/29.05  tff(decl_45587, type, 'hydrophilic-end': $i).
% 29.22/29.05  tff(decl_45588, type, 'Hydrophilic-Face': $i).
% 29.22/29.05  tff(decl_45589, type, 'The hydrophilic side of an entity.': $i).
% 29.22/29.05  tff(decl_45590, type, 'outside face of biomembrane': $i).
% 29.22/29.05  tff(decl_45591, type, 'hydrophilic face': $i).
% 29.22/29.05  tff(decl_45592, type, 'hydrophilic-face': $i).
% 29.22/29.05  tff(decl_45593, type, 'Hydrophilic-Head': $i).
% 29.22/29.05  tff(decl_45594, type, 'The head part of a molecule that is polar (having a partial charge due to electronegativity) and therefore does not resist interaction with water.': $i).
% 29.22/29.05  tff(decl_45595, type, 'hydrophilic head': $i).
% 29.22/29.05  tff(decl_45596, type, 'hydrophilic-head': $i).
% 29.22/29.05  tff(decl_45597, type, 'Hydrophilic-Region': $i).
% 29.22/29.05  tff(decl_45598, type, 'A region showing hydrophilicity is called a hydrophilic region.': $i).
% 29.22/29.05  tff(decl_45599, type, 'hydrophilic region': $i).
% 29.22/29.05  tff(decl_45600, type, 'hydrophilic-region': $i).
% 29.22/29.05  tff(decl_45601, type, fn_hydrophilic_region_1: $i > $i).
% 29.22/29.05  tff(decl_45602, type, hydrophilic_substance_1: $i > $o).
% 29.22/29.05  tff(decl_45603, type, 'Hydrophilic-Substance': $i).
% 29.22/29.05  tff(decl_45604, type, 'A substance with an affinity for water.': $i).
% 29.22/29.05  tff(decl_45605, type, 'hydrophilic substance': $i).
% 29.22/29.05  tff(decl_45606, type, 'hydrophilic-substance': $i).
% 29.22/29.05  tff(decl_45607, type, fn_hydrophilic_substance_2: $i > $i).
% 29.22/29.05  tff(decl_45608, type, fn_hydrophilic_substance_3: $i > $i).
% 29.22/29.05  tff(decl_45609, type, fn_hydrophilic_substance_4: $i > $i).
% 29.22/29.05  tff(decl_45610, type, fn_hydrophilic_substance_5: $i > $i).
% 29.22/29.05  tff(decl_45611, type, 'Hydrophobic-Amino-Acid': $i).
% 29.22/29.05  tff(decl_45612, type, 'An amino acid which has hydrophobic properties due to the non-polar nature of the side chain.': $i).
% 29.22/29.05  tff(decl_45613, type, 'non polar amino acid': $i).
% 29.22/29.05  tff(decl_45614, type, 'hydrophobic amino acid': $i).
% 29.22/29.05  tff(decl_45615, type, 'hydrophobic-amino-acid': $i).
% 29.22/29.05  tff(decl_45616, type, fn_hydrophobic_amino_acid_12: $i > $i).
% 29.22/29.05  tff(decl_45617, type, fn_hydrophobic_amino_acid_25: $i > $i).
% 29.22/29.05  tff(decl_45618, type, fn_hydrophobic_amino_acid_32: $i > $i).
% 29.22/29.05  tff(decl_45619, type, fn_hydrophobic_amino_acid_33: $i > $i).
% 29.22/29.05  tff(decl_45620, type, fn_hydrophobic_amino_acid_37: $i > $i).
% 29.22/29.05  tff(decl_45621, type, fn_hydrophobic_amino_acid_39: $i > $i).
% 29.22/29.05  tff(decl_45622, type, fn_hydrophobic_amino_acid_47: $i > $i).
% 29.22/29.05  tff(decl_45623, type, fn_hydrophobic_amino_acid_49: $i > $i).
% 29.22/29.05  tff(decl_45624, type, fn_hydrophobic_amino_acid_50: $i > $i).
% 29.22/29.05  tff(decl_45625, type, fn_hydrophobic_amino_acid_52: $i > $i).
% 29.22/29.05  tff(decl_45626, type, fn_hydrophobic_amino_acid_53: $i > $i).
% 29.22/29.05  tff(decl_45627, type, fn_hydrophobic_amino_acid_54: $i > $i).
% 29.22/29.05  tff(decl_45628, type, fn_hydrophobic_amino_acid_55: $i > $i).
% 29.22/29.05  tff(decl_45629, type, fn_hydrophobic_amino_acid_56: $i > $i).
% 29.22/29.05  tff(decl_45630, type, fn_hydrophobic_amino_acid_57: $i > $i).
% 29.22/29.05  tff(decl_45631, type, fn_hydrophobic_amino_acid_58: $i > $i).
% 29.22/29.05  tff(decl_45632, type, fn_hydrophobic_amino_acid_61: $i > $i).
% 29.22/29.05  tff(decl_45633, type, fn_hydrophobic_amino_acid_77: $i > $i).
% 29.22/29.05  tff(decl_45634, type, fn_hydrophobic_amino_acid_83: $i > $i).
% 29.22/29.05  tff(decl_45635, type, fn_nonpolar_covalent_bond_25: $i > $i).
% 29.22/29.05  tff(decl_45636, type, fn_nonpolar_covalent_bond_21: $i > $i).
% 29.22/29.05  tff(decl_45637, type, fn_hydrophobic_amino_acid_17: $i > $i).
% 29.22/29.05  tff(decl_45638, type, fn_hydrophobic_amino_acid_71: $i > $i).
% 29.22/29.05  tff(decl_45639, type, fn_hydrophobic_amino_acid_72: $i > $i).
% 29.22/29.05  tff(decl_45640, type, fn_hydrophobic_amino_acid_75: $i > $i).
% 29.22/29.05  tff(decl_45641, type, fn_hydrophobic_amino_acid_76: $i > $i).
% 29.22/29.05  tff(decl_45642, type, fn_hydrophobic_amino_acid_46: $i > $i).
% 29.22/29.05  tff(decl_45643, type, fn_hydrophobic_amino_acid_70: $i > $i).
% 29.22/29.05  tff(decl_45644, type, fn_hydrophobic_amino_acid_73: $i > $i).
% 29.22/29.05  tff(decl_45645, type, fn_hydrophobic_amino_acid_74: $i > $i).
% 29.22/29.05  tff(decl_45646, type, fn_hydrophobic_amino_acid_48: $i > $i).
% 29.22/29.05  tff(decl_45647, type, fn_hydrophobic_compound_4: $i > $i).
% 29.22/29.05  tff(decl_45648, type, 'Hydrophobic-Compound': $i).
% 29.22/29.05  tff(decl_45649, type, 'A molecule with no affinity for water.': $i).
% 29.22/29.05  tff(decl_45650, type, 'hydrophobic molecule': $i).
% 29.22/29.05  tff(decl_45651, type, 'hydrophobic compound': $i).
% 29.22/29.05  tff(decl_45652, type, 'hydrophobic-compound': $i).
% 29.22/29.05  tff(decl_45653, type, fn_hydrophobic_region_4: $i > $i).
% 29.22/29.05  tff(decl_45654, type, 'Hydrophobic-Core': $i).
% 29.22/29.05  tff(decl_45655, type, 'The central (not surface) region of an entity. Generally a compact, non-dynamic region that is not solvent accessible is the hydrophobic core.': $i).
% 29.22/29.05  tff(decl_45656, type, 'hydrophobic interior': $i).
% 29.22/29.05  tff(decl_45657, type, 'hydrophobic-interior': $i).
% 29.22/29.05  tff(decl_45658, type, 'hydrophobic center': $i).
% 29.22/29.05  tff(decl_45659, type, 'hydrophobic-center': $i).
% 29.22/29.05  tff(decl_45660, type, 'hydrophobic core': $i).
% 29.22/29.05  tff(decl_45661, type, 'hydrophobic-core': $i).
% 29.22/29.05  tff(decl_45662, type, 'Hydrophobic-End': $i).
% 29.22/29.05  tff(decl_45663, type, 'The end of the molecule which is water repellent': $i).
% 29.22/29.05  tff(decl_45664, type, 'hydrophobic end': $i).
% 29.22/29.05  tff(decl_45665, type, 'hydrophobic-end': $i).
% 29.22/29.05  tff(decl_45666, type, 'Hydrophobic-Face': $i).
% 29.22/29.05  tff(decl_45667, type, 'The hydrophobic side of an entity.': $i).
% 29.22/29.05  tff(decl_45668, type, 'hydrophobic face': $i).
% 29.22/29.05  tff(decl_45669, type, 'hydrophobic-face': $i).
% 29.22/29.05  tff(decl_45670, type, 'Hydrophobic-Interaction': $i).
% 29.22/29.05  tff(decl_45671, type, 'The tendency of nonpolar molecules to aggregate together and exclude water molecules.': $i).
% 29.22/29.05  tff(decl_45672, type, 'hydrophobic interaction': $i).
% 29.22/29.05  tff(decl_45673, type, 'hydrophobic-interaction': $i).
% 29.22/29.05  tff(decl_45674, type, fn_hydrophobic_interaction_1: $i > $i).
% 29.22/29.05  tff(decl_45675, type, fn_hydrophobic_interaction_2: $i > $i).
% 29.22/29.05  tff(decl_45676, type, 'Hydrophobic-Region': $i).
% 29.22/29.05  tff(decl_45677, type, 'A region showing hydrophobicity is called a hydrophobic region.': $i).
% 29.22/29.05  tff(decl_45678, type, 'hydrophobic region': $i).
% 29.22/29.05  tff(decl_45679, type, 'hydrophobic-region': $i).
% 29.22/29.05  tff(decl_45680, type, fn_hydrophobic_region_1: $i > $i).
% 29.22/29.05  tff(decl_45681, type, fn_hydrophobic_region_3: $i > $i).
% 29.22/29.05  tff(decl_45682, type, hydrophobic_substance_1: $i > $o).
% 29.22/29.05  tff(decl_45683, type, 'Hydrophobic-Substance': $i).
% 29.22/29.06  tff(decl_45684, type, 'A substance with no affinity for water.  These substances tend to coalesce and form droplets in water.': $i).
% 29.22/29.06  tff(decl_45685, type, 'hydrophobic substance': $i).
% 29.22/29.06  tff(decl_45686, type, 'hydrophobic-substance': $i).
% 29.22/29.06  tff(decl_45687, type, fn_hydrophobic_substance_1: $i > $i).
% 29.22/29.06  tff(decl_45688, type, fn_hydrophobic_substance_2: $i > $i).
% 29.22/29.06  tff(decl_45689, type, fn_hydrophobic_substance_3: $i > $i).
% 29.22/29.06  tff(decl_45690, type, fn_hydrophobic_substance_4: $i > $i).
% 29.22/29.06  tff(decl_45691, type, fn_hydrophobic_substance_7: $i > $i).
% 29.22/29.06  tff(decl_45692, type, fn_hydrophobic_substance_8: $i > $i).
% 29.22/29.06  tff(decl_45693, type, fn_hydrophobic_substance_9: $i > $i).
% 29.22/29.06  tff(decl_45694, type, 'Hydroponic-Culture': $i).
% 29.22/29.06  tff(decl_45695, type, 'A method of growing plants in water with mineral solutions rather than in soil.': $i).
% 29.22/29.06  tff(decl_45696, type, hydroponic: $i).
% 29.22/29.06  tff(decl_45697, type, 'hydroponic agriculture': $i).
% 29.22/29.06  tff(decl_45698, type, 'hydroponic-agriculture': $i).
% 29.22/29.06  tff(decl_45699, type, 'hydroponic culture': $i).
% 29.22/29.06  tff(decl_45700, type, 'hydroponic-culture': $i).
% 29.22/29.06  tff(decl_45701, type, 'Hydrostatic-Skeleton': $i).
% 29.22/29.06  tff(decl_45702, type, 'An internal closed fluid-filled cavity that provides a rigidity against which muscles can contract. This type of skeleton is found in soft-bodied invertebrates such as cnidarians, annelids, and nematodes.': $i).
% 29.22/29.06  tff(decl_45703, type, 'hydrostatic skeleton': $i).
% 29.22/29.06  tff(decl_45704, type, 'hydrostatic-skeleton': $i).
% 29.22/29.06  tff(decl_45705, type, 'Hydroxide-Ion': $i).
% 29.22/29.06  tff(decl_45706, type, 'A hydroxide ion consists of an atom of oxygen bound to an atom of hydrogen, with a charge of -1 (OH-)': $i).
% 29.22/29.06  tff(decl_45707, type, 'hydroxyl ion': $i).
% 29.22/29.06  tff(decl_45708, type, 'hydroxyl-ion': $i).
% 29.22/29.06  tff(decl_45709, type, 'ion of hydroxide': $i).
% 29.22/29.06  tff(decl_45710, type, 'hydroxide ion': $i).
% 29.22/29.06  tff(decl_45711, type, 'hydroxide-ion': $i).
% 29.22/29.06  tff(decl_45712, type, fn_hydroxide_ion_2: $i > $i).
% 29.22/29.06  tff(decl_45713, type, fn_hydroxide_ion_3: $i > $i).
% 29.22/29.06  tff(decl_45714, type, fn_hydroxide_ion_4: $i > $i).
% 29.22/29.06  tff(decl_45715, type, fn_hydroxide_ion_5: $i > $i).
% 29.22/29.06  tff(decl_45716, type, fn_hydroxide_ion_6: $i > $i).
% 29.22/29.06  tff(decl_45717, type, fn_hydroxide_ion_7: $i > $i).
% 29.22/29.06  tff(decl_45718, type, fn_hydroxide_ion_8: $i > $i).
% 29.22/29.06  tff(decl_45719, type, fn_hydroxide_ion_9: $i > $i).
% 29.22/29.06  tff(decl_45720, type, fn_hydroxide_ion_10: $i > $i).
% 29.22/29.06  tff(decl_45721, type, fn_hydroxide_ion_11: $i > $i).
% 29.22/29.06  tff(decl_45722, type, fn_hydroxide_ion_12: $i > $i).
% 29.22/29.06  tff(decl_45723, type, fn_hydroxide_ion_13: $i > $i).
% 29.22/29.06  tff(decl_45724, type, fn_hydroxide_ion_14: $i > $i).
% 29.22/29.06  tff(decl_45725, type, fn_hydroxide_ion_15: $i > $i).
% 29.22/29.06  tff(decl_45726, type, fn_hydroxide_ion_16: $i > $i).
% 29.22/29.06  tff(decl_45727, type, fn_hydroxide_ion_17: $i > $i).
% 29.22/29.06  tff(decl_45728, type, fn_hydroxide_ion_18: $i > $i).
% 29.22/29.06  tff(decl_45729, type, fn_hydroxide_ion_19: $i > $i).
% 29.22/29.06  tff(decl_45730, type, fn_hydroxide_ion_1: $i > $i).
% 29.22/29.06  tff(decl_45731, type, 'Hydroxyl-Group': $i).
% 29.22/29.06  tff(decl_45732, type, 'Hydroxyl group is a functional group containing an oxygen atom bound covalently with a hydrogen atom. The molecular formula of hydroxyl group is -OH.': $i).
% 29.22/29.06  tff(decl_45733, type, 'oh group': $i).
% 29.22/29.06  tff(decl_45734, type, 'oh-group': $i).
% 29.22/29.06  tff(decl_45735, type, 'group of hydroxyl': $i).
% 29.22/29.06  tff(decl_45736, type, 'hydroxyl group': $i).
% 29.22/29.06  tff(decl_45737, type, 'hydroxyl-group': $i).
% 29.22/29.06  tff(decl_45738, type, fn_hydroxyl_group_3: $i > $i).
% 29.22/29.06  tff(decl_45739, type, 'Hydrozoan': $i).
% 29.22/29.06  tff(decl_45740, type, 'A member of the class Hydrozoa within the phylum Cnidaria. The life cycle of most hydrozoans contains an asexual polyp and a sexual medusa.': $i).
% 29.22/29.06  tff(decl_45741, type, hydrozoan: $i).
% 29.22/29.06  tff(decl_45742, type, 'Hymen': $i).
% 29.22/29.06  tff(decl_45743, type, 'A thin membrane that partially covers the vaginal opening in human females.': $i).
% 29.22/29.06  tff(decl_45744, type, hymen: $i).
% 29.22/29.06  tff(decl_45745, type, 'Hymenoptera': $i).
% 29.22/29.06  tff(decl_45746, type, 'A large order of insects, consisting of bees, wasps, ants, and sawflies.': $i).
% 29.22/29.06  tff(decl_45747, type, hymenoptera: $i).
% 29.22/29.06  tff(decl_45748, type, hyperactive_ras_protein_1: $i > $o).
% 29.22/29.06  tff(decl_45749, type, 'Hyperactive-Ras-Protein': $i).
% 29.22/29.06  tff(decl_45750, type, 'Hyperactive version of a Ras protein tha can increase cell division even in the absence of growth factor.': $i).
% 29.22/29.06  tff(decl_45751, type, 'cancer causing ras protein': $i).
% 29.22/29.06  tff(decl_45752, type, 'hyperactive ras protein': $i).
% 29.22/29.06  tff(decl_45753, type, 'hyperactive-ras-protein': $i).
% 29.22/29.06  tff(decl_45754, type, ras_protein_1: $i > $o).
% 29.22/29.06  tff(decl_45755, type, fn_hyperactive_ras_protein_2: $i > $i).
% 29.22/29.06  tff(decl_45756, type, fn_hyperactive_ras_protein_3: $i > $i).
% 29.22/29.06  tff(decl_45757, type, fn_hyperactive_ras_protein_4: $i > $i).
% 29.22/29.06  tff(decl_45758, type, fn_hyperactive_ras_protein_5: $i > $i).
% 29.22/29.06  tff(decl_45759, type, hyperpolarization_1: $i > $o).
% 29.22/29.06  tff(decl_45760, type, 'Hyperpolarization': $i).
% 29.22/29.06  tff(decl_45761, type, 'An alteration of a cell\\s membrane potential further away from the threshold, so that the inside of the cell becomes more negative relative to the outside. Hyperpolarization makes a cell less likely that a neuron will produce or transmit an action potential.': $i).
% 29.22/29.06  tff(decl_45762, type, hyperpolarization: $i).
% 29.22/29.06  tff(decl_45763, type, hypersensitivity_response_1: $i > $o).
% 29.22/29.06  tff(decl_45764, type, 'Hypersensitivity-Response': $i).
% 29.22/29.06  tff(decl_45765, type, 'In plants, a vigorous local plant defense in response to an avirulent pathogen.': $i).
% 29.22/29.06  tff(decl_45766, type, 'response of hypersensitivity': $i).
% 29.22/29.06  tff(decl_45767, type, 'hypersensitivity response': $i).
% 29.22/29.06  tff(decl_45768, type, 'hypersensitivity-response': $i).
% 29.22/29.06  tff(decl_45769, type, plant_process_1: $i > $o).
% 29.22/29.06  tff(decl_45770, type, 'Hypertension': $i).
% 29.22/29.06  tff(decl_45771, type, 'Chronic abnormally high pressure in the arteries.': $i).
% 29.22/29.06  tff(decl_45772, type, hypertension: $i).
% 29.22/29.06  tff(decl_45773, type, 'Hyperthyroidism': $i).
% 29.22/29.06  tff(decl_45774, type, 'A metabolic disease in which overactive tissue within the thyroid gland cause an overproduction of thyroid hormones (thyroxine or T4 and/or triiodothyronine or T3).': $i).
% 29.22/29.06  tff(decl_45775, type, hyperthyroidism: $i).
% 29.22/29.06  tff(decl_45776, type, hypertonic_1: $i > $o).
% 29.22/29.06  tff(decl_45777, type, 'Hypertonic': $i).
% 29.22/29.06  tff(decl_45778, type, 'Refers to a solution that has a higher salt solution than a cell, and will thus cause a cell to lose water.': $i).
% 29.22/29.06  tff(decl_45779, type, hypertonic: $i).
% 29.22/29.06  tff(decl_45780, type, tonicity_1: $i > $o).
% 29.22/29.06  tff(decl_45781, type, hypotonic_1: $i > $o).
% 29.22/29.06  tff(decl_45782, type, isotonic_1: $i > $o).
% 29.22/29.06  tff(decl_45783, type, 'Hypertonic-Solution': $i).
% 29.22/29.06  tff(decl_45784, type, 'A hypertonic solution is one with a high concentration of solutes when compared to another solution which is separated from it by a semipermeable membrane. As opposed to an isotonic solution or a hypotonic solution.': $i).
% 29.22/29.06  tff(decl_45785, type, 'hypertonic solution': $i).
% 29.22/29.06  tff(decl_45786, type, 'hypertonic-solution': $i).
% 29.22/29.06  tff(decl_45787, type, fn_hypertonic_solution_3: $i > $i).
% 29.22/29.06  tff(decl_45788, type, fn_hypertonic_solution_4: $i > $i).
% 29.22/29.06  tff(decl_45789, type, 'Hypha': $i).
% 29.22/29.06  tff(decl_45790, type, 'A long filamentous structure found in most fungi. The collective hyphae of a particular fungus make up its mycelium.': $i).
% 29.22/29.06  tff(decl_45791, type, hypha: $i).
% 29.22/29.06  tff(decl_45792, type, hypoblast_1: $i > $o).
% 29.22/29.06  tff(decl_45793, type, 'Hypoblast': $i).
% 29.22/29.06  tff(decl_45794, type, 'In animal development, the hypoblast is the embryonic precursor to endoderm and (potentially) mesoderm.': $i).
% 29.22/29.06  tff(decl_45795, type, hypoblast: $i).
% 29.22/29.06  tff(decl_45796, type, hypocotyl_1: $i > $o).
% 29.22/29.06  tff(decl_45797, type, 'Hypocotyl': $i).
% 29.22/29.06  tff(decl_45798, type, 'The young stem of a germinating angiosperm, below the cotyledons and above the root.': $i).
% 29.22/29.06  tff(decl_45799, type, hypocotyl: $i).
% 29.22/29.06  tff(decl_45800, type, hypodermis_1: $i > $o).
% 29.22/29.06  tff(decl_45801, type, 'Hypodermis': $i).
% 29.22/29.06  tff(decl_45802, type, 'A layer of tissue present beneath the dermis of vertebrate skin.': $i).
% 29.22/29.06  tff(decl_45803, type, 'subcutaneous layer': $i).
% 29.22/29.06  tff(decl_45804, type, 'subcutaneous-layer': $i).
% 29.22/29.06  tff(decl_45805, type, hypodermis: $i).
% 29.22/29.06  tff(decl_45806, type, 'Hypopituitarism': $i).
% 29.22/29.06  tff(decl_45807, type, 'Decreased hormone production by the pituitary gland. The decrease can be in any or all of the pituitary hormones.': $i).
% 29.22/29.06  tff(decl_45808, type, hypopituitarism: $i).
% 29.22/29.06  tff(decl_45809, type, 'Hypothalamus': $i).
% 29.22/29.06  tff(decl_45810, type, 'Portion of the vertebrate brain that functions in maintaining homeostasis and secretes a number of hormones, including tropic hormones that act on other endocrine organs. The hypothalamus has a neural connection to the posterior pituitary and thus links the endocrine and nervous systems.': $i).
% 29.22/29.06  tff(decl_45811, type, hypothalamus: $i).
% 29.22/29.06  tff(decl_45812, type, 'Hypothesis': $i).
% 29.22/29.06  tff(decl_45813, type, 'A tentative answer to a well-framed question, narrower in scope than a theory and subject to testing.': $i).
% 29.22/29.06  tff(decl_45814, type, hypotheses: $i).
% 29.22/29.06  tff(decl_45815, type, hypothesis: $i).
% 29.22/29.06  tff(decl_45816, type, 'Hypotonic': $i).
% 29.22/29.06  tff(decl_45817, type, 'Refers to a solution that has a lower salt concentration than a cell, and will thus cause a cell to take in water and swell.': $i).
% 29.22/29.06  tff(decl_45818, type, hypotonic: $i).
% 29.22/29.06  tff(decl_45819, type, 'Hypotonic-Solution': $i).
% 29.22/29.06  tff(decl_45820, type, 'A hypotonic solution is one with a low concentration of solutes when compared to another solution which is separated from it by a semipermeable membrane. As opposed to an isotonic solution or a hypertonic solution.': $i).
% 29.22/29.06  tff(decl_45821, type, 'hypotonic solution': $i).
% 29.22/29.06  tff(decl_45822, type, 'hypotonic-solution': $i).
% 29.22/29.06  tff(decl_45823, type, fn_hypertonic_solution_1: $i > $i).
% 29.22/29.06  tff(decl_45824, type, fn_hypertonic_solution_2: $i > $i).
% 29.22/29.06  tff(decl_45825, type, 'I-Band-Filament': $i).
% 29.22/29.06  tff(decl_45826, type, 'An area of the sarcomere that consists of thin filaments': $i).
% 29.22/29.06  tff(decl_45827, type, 'i band': $i).
% 29.22/29.06  tff(decl_45828, type, 'i-band': $i).
% 29.22/29.06  tff(decl_45829, type, 'i filament': $i).
% 29.22/29.06  tff(decl_45830, type, 'i-filament': $i).
% 29.22/29.06  tff(decl_45831, type, 'i band filament': $i).
% 29.22/29.06  tff(decl_45832, type, 'i-band-filament': $i).
% 29.22/29.06  tff(decl_45833, type, i_minus_1: $i > $o).
% 29.22/29.06  tff(decl_45834, type, 'I-Minus': $i).
% 29.22/29.06  tff(decl_45835, type, 'Iodide ion': $i).
% 29.22/29.06  tff(decl_45836, type, iodide: $i).
% 29.22/29.06  tff(decl_45837, type, 'minus of i': $i).
% 29.22/29.06  tff(decl_45838, type, 'i minus': $i).
% 29.22/29.06  tff(decl_45839, type, 'i-minus': $i).
% 29.22/29.06  tff(decl_45840, type, fn_i_minus_1: $i > $i).
% 29.22/29.06  tff(decl_45841, type, fn_i_minus_2: $i > $i).
% 29.22/29.06  tff(decl_45842, type, fn_i_minus_3: $i > $i).
% 29.22/29.06  tff(decl_45843, type, fn_i_minus_5: $i > $i).
% 29.22/29.06  tff(decl_45844, type, fn_i_minus_6: $i > $i).
% 29.22/29.06  tff(decl_45845, type, fn_i_minus_7: $i > $i).
% 29.22/29.06  tff(decl_45846, type, fn_i_minus_4: $i > $i).
% 29.22/29.06  tff(decl_45847, type, 'IA': $i).
% 29.22/29.06  tff(decl_45848, type, 'The allele coding for blood carbohydrate A.': $i).
% 29.22/29.06  tff(decl_45849, type, ia: $i).
% 29.22/29.06  tff(decl_45850, type, ia_alkali_metal_element_1: $i > $o).
% 29.22/29.06  tff(decl_45851, type, 'IA-Alkali-Metal-Element': $i).
% 29.22/29.06  tff(decl_45852, type, 'Elements in group 1A of the periodic table are called the alkali metals. They are H, Li, Na, K, Rb, Cs and Fr.': $i).
% 29.22/29.06  tff(decl_45853, type, 'group ia element': $i).
% 29.22/29.06  tff(decl_45854, type, 'group-ia-element': $i).
% 29.22/29.06  tff(decl_45855, type, 'alkali metal': $i).
% 29.22/29.06  tff(decl_45856, type, 'alkali-metal': $i).
% 29.22/29.06  tff(decl_45857, type, 'group 1 element': $i).
% 29.22/29.06  tff(decl_45858, type, 'group-1-element': $i).
% 29.22/29.06  tff(decl_45859, type, 'ia alkali metal element': $i).
% 29.22/29.06  tff(decl_45860, type, 'ia-alkali-metal-element': $i).
% 29.22/29.06  tff(decl_45861, type, 'IB': $i).
% 29.22/29.06  tff(decl_45862, type, 'The allele coding for blood carbohydrate B.': $i).
% 29.22/29.06  tff(decl_45863, type, ib: $i).
% 29.22/29.06  tff(decl_45864, type, ibuprofen_1: $i > $o).
% 29.22/29.06  tff(decl_45865, type, 'Ibuprofen': $i).
% 29.22/29.06  tff(decl_45866, type, 'Ibuprofen is a nonsteroidal anti-inflammatory drug': $i).
% 29.22/29.06  tff(decl_45867, type, ibuprofen: $i).
% 29.22/29.06  tff(decl_45868, type, ibuprofen_isomer_1: $i > $o).
% 29.22/29.06  tff(decl_45869, type, 'Ibuprofen-Isomer': $i).
% 29.22/29.06  tff(decl_45870, type, 'One of the two forms of Ibuprofen, each with the same atomic parts, but different structure, shape and function.': $i).
% 29.22/29.06  tff(decl_45871, type, 'isomer of ibuprofen': $i).
% 29.22/29.06  tff(decl_45872, type, 'ibuprofen isomer': $i).
% 29.22/29.06  tff(decl_45873, type, 'ibuprofen-isomer': $i).
% 29.22/29.06  tff(decl_45874, type, fn_ibuprofen_isomer_1: $i > $i).
% 29.22/29.06  tff(decl_45875, type, 'Ice': $i).
% 29.22/29.06  tff(decl_45876, type, 'The solid form of water. Because water molecules are farther apart in the solid form of water compared to the liquid form, ice floats on liquid water.': $i).
% 29.22/29.06  tff(decl_45877, type, 'solid water': $i).
% 29.22/29.06  tff(decl_45878, type, 'floating water': $i).
% 29.22/29.06  tff(decl_45879, type, 'floating ice': $i).
% 29.22/29.06  tff(decl_45880, type, 'frozen water': $i).
% 29.22/29.06  tff(decl_45881, type, ice: $i).
% 29.22/29.06  tff(decl_45882, type, fn_ice_2: $i > $i).
% 29.22/29.06  tff(decl_45883, type, fn_ice_4: $i > $i).
% 29.22/29.06  tff(decl_45884, type, fn_ice_6: $i > $i).
% 29.22/29.06  tff(decl_45885, type, fn_ice_8: $i > $i).
% 29.22/29.06  tff(decl_45886, type, fn_ice_9: $i > $i).
% 29.22/29.06  tff(decl_45887, type, fn_ice_10: $i > $i).
% 29.22/29.06  tff(decl_45888, type, fn_ice_11: $i > $i).
% 29.22/29.06  tff(decl_45889, type, fn_ice_13: $i > $i).
% 29.22/29.06  tff(decl_45890, type, fn_ice_14: $i > $i).
% 29.22/29.06  tff(decl_45891, type, fn_ice_15: $i > $i).
% 29.22/29.06  tff(decl_45892, type, fn_ice_21: $i > $i).
% 29.22/29.06  tff(decl_45893, type, fn_ice_22: $i > $i).
% 29.22/29.06  tff(decl_45894, type, fn_ice_23: $i > $i).
% 29.22/29.06  tff(decl_45895, type, fn_ice_24: $i > $i).
% 29.22/29.06  tff(decl_45896, type, fn_ice_25: $i > $i).
% 29.22/29.06  tff(decl_45897, type, fn_water_42: $i > $i).
% 29.22/29.06  tff(decl_45898, type, fn_water_32: $i > $i).
% 29.22/29.06  tff(decl_45899, type, fn_melting_3: $i > $i).
% 29.22/29.06  tff(decl_45900, type, fn_water_31: $i > $i).
% 29.22/29.06  tff(decl_45901, type, fn_melting_2: $i > $i).
% 29.22/29.06  tff(decl_45902, type, 'Ice_Density': $i).
% 29.22/29.06  tff(decl_45903, type, 'Water_Density': $i).
% 29.22/29.06  tff(decl_45904, type, fn_ice_26: $i > $i).
% 29.22/29.06  tff(decl_45905, type, fn_ice_12: $i > $i).
% 29.22/29.06  tff(decl_45906, type, fn_ice_16: $i > $i).
% 29.22/29.06  tff(decl_45907, type, identify_1: $i > $o).
% 29.22/29.06  tff(decl_45908, type, 'Identify': $i).
% 29.22/29.06  tff(decl_45909, type, 'To establish the identity of a particular thing or person.': $i).
% 29.22/29.06  tff(decl_45910, type, 'Identify-Cell-By-Protein-Expression': $i).
% 29.22/29.06  tff(decl_45911, type, 'Distinguishing cell and its corresponding gene and protein product by measuring protein.': $i).
% 29.22/29.06  tff(decl_45912, type, 'identify cell by protein expression': $i).
% 29.22/29.06  tff(decl_45913, type, 'identify-cell-by-protein-expression': $i).
% 29.22/29.06  tff(decl_45914, type, fn_identify_cell_by_protein_expression_1: $i > $i).
% 29.22/29.06  tff(decl_45915, type, fn_identify_cell_by_protein_expression_2: $i > $i).
% 29.22/29.06  tff(decl_45916, type, fn_identify_cell_by_protein_expression_3: $i > $i).
% 29.22/29.06  tff(decl_45917, type, fn_identify_cell_by_protein_expression_4: $i > $i).
% 29.22/29.06  tff(decl_45918, type, 'Identify-Cell-Clones-With-Gene-Of-Interest': $i).
% 29.22/29.06  tff(decl_45919, type, 'Identify Cell Clones With Gene Of Interest: Distinguishing cells with genes based on their genetic material and protein products by way of Nucleic Acid Hybridization and detecting protein expression, respectively.': $i).
% 29.22/29.06  tff(decl_45920, type, 'identify cell clones with gene of interest': $i).
% 29.22/29.06  tff(decl_45921, type, 'identify-cell-clones-with-gene-of-interest': $i).
% 29.22/29.06  tff(decl_45922, type, fn_identify_cell_clones_with_gene_of_interest_1: $i > $i).
% 29.22/29.06  tff(decl_45923, type, fn_identify_cell_clones_with_gene_of_interest_2: $i > $i).
% 29.22/29.06  tff(decl_45924, type, fn_identify_cell_clones_with_gene_of_interest_3: $i > $i).
% 29.22/29.06  tff(decl_45925, type, fn_identify_cell_clones_with_gene_of_interest_4: $i > $i).
% 29.22/29.06  tff(decl_45926, type, fn_identify_cell_clones_with_gene_of_interest_5: $i > $i).
% 29.22/29.06  tff(decl_45927, type, fn_identify_cell_clones_with_gene_of_interest_6: $i > $i).
% 29.22/29.06  tff(decl_45928, type, fn_identify_cell_clones_with_gene_of_interest_7: $i > $i).
% 29.22/29.06  tff(decl_45929, type, if_then_logic_1: $i > $o).
% 29.22/29.06  tff(decl_45930, type, 'If-Then-Logic': $i).
% 29.22/29.06  tff(decl_45931, type, 'A type of logic used in deductive reasoning in which general premises are used to predict a specific result we should expect if the premises are true.': $i).
% 29.22/29.06  tff(decl_45932, type, 'if then logic': $i).
% 29.22/29.06  tff(decl_45933, type, 'if-then-logic': $i).
% 29.22/29.06  tff(decl_45934, type, ige_antibodies_1: $i > $o).
% 29.22/29.06  tff(decl_45935, type, 'IgE-Antibodies': $i).
% 29.22/29.06  tff(decl_45936, type, 'A class of antibodies associated with common allergies such as hay fever, hives, and asthma.': $i).
% 29.22/29.06  tff(decl_45937, type, 'ige antibodyes': $i).
% 29.22/29.06  tff(decl_45938, type, 'ige antibody': $i).
% 29.22/29.06  tff(decl_45939, type, 'ige-antibody': $i).
% 29.22/29.06  tff(decl_45940, type, monoclonal_antibody_1: $i > $o).
% 29.22/29.06  tff(decl_45941, type, iia_alkaline_earth_metal_element_1: $i > $o).
% 29.22/29.06  tff(decl_45942, type, 'IIA-Alkaline-Earth-Metal-Element': $i).
% 29.22/29.06  tff(decl_45943, type, 'Elements in group 2A of the periodic table are called the alkaline earth metals. They are Be, Mg, Ca, Sr, Ba and Ra.': $i).
% 29.22/29.06  tff(decl_45944, type, iia: $i).
% 29.22/29.06  tff(decl_45945, type, 'group iia element': $i).
% 29.22/29.06  tff(decl_45946, type, 'group-iia-element': $i).
% 29.22/29.06  tff(decl_45947, type, 'group 2 element': $i).
% 29.22/29.06  tff(decl_45948, type, 'group-2-element': $i).
% 29.22/29.06  tff(decl_45949, type, 'alkaline earth metal': $i).
% 29.22/29.06  tff(decl_45950, type, 'alkaline-earth-metal': $i).
% 29.22/29.06  tff(decl_45951, type, 'iia alkaline earth metal element': $i).
% 29.22/29.06  tff(decl_45952, type, 'iia-alkaline-earth-metal-element': $i).
% 29.22/29.06  tff(decl_45953, type, iiia_element_1: $i > $o).
% 29.22/29.06  tff(decl_45954, type, 'IIIA-Element': $i).
% 29.22/29.06  tff(decl_45955, type, 'Elements in group 3A of the periodic table are B, Al, Ga, In and Tl.': $i).
% 29.22/29.06  tff(decl_45956, type, iiia: $i).
% 29.22/29.06  tff(decl_45957, type, 'group iiia elements': $i).
% 29.22/29.06  tff(decl_45958, type, 'group-iiia-elements': $i).
% 29.22/29.06  tff(decl_45959, type, 'group 3 elements': $i).
% 29.22/29.06  tff(decl_45960, type, 'group-3-elements': $i).
% 29.22/29.06  tff(decl_45961, type, 'iiia element': $i).
% 29.22/29.06  tff(decl_45962, type, 'iiia-element': $i).
% 29.22/29.06  tff(decl_45963, type, ileum_1: $i > $o).
% 29.22/29.06  tff(decl_45964, type, 'Ileum': $i).
% 29.22/29.06  tff(decl_45965, type, 'The distal region of the small intestine in most higher vertebrates. It is lined with villi and microvilli and functions in nutrient and water absorption.': $i).
% 29.22/29.06  tff(decl_45966, type, ileum: $i).
% 29.22/29.06  tff(decl_45967, type, 'Image': $i).
% 29.22/29.06  tff(decl_45968, type, 'A visual representation (of an object or scene or person or abstraction) produced on a surface.': $i).
% 29.22/29.06  tff(decl_45969, type, image: $i).
% 29.22/29.06  tff(decl_45970, type, imbibition_1: $i > $o).
% 29.22/29.06  tff(decl_45971, type, 'Imbibition': $i).
% 29.22/29.06  tff(decl_45972, type, 'Uptake of water at a surface.': $i).
% 29.22/29.06  tff(decl_45973, type, imbibe: $i).
% 29.22/29.06  tff(decl_45974, type, imbibition: $i).
% 29.22/29.06  tff(decl_45975, type, 'Immigration': $i).
% 29.22/29.06  tff(decl_45976, type, 'The movement into a population of individuals that came from another area.': $i).
% 29.22/29.06  tff(decl_45977, type, immigrate: $i).
% 29.22/29.06  tff(decl_45978, type, immigration: $i).
% 29.22/29.06  tff(decl_45979, type, 'Immune-Cell': $i).
% 29.22/29.06  tff(decl_45980, type, 'Immune cells are cells of the immune system involved in defending the body against both infectious diseases and foreign materials.': $i).
% 29.22/29.06  tff(decl_45981, type, 'cell of immune': $i).
% 29.22/29.06  tff(decl_45982, type, 'immune cell': $i).
% 29.22/29.06  tff(decl_45983, type, 'immune-cell': $i).
% 29.22/29.06  tff(decl_45984, type, fn_immune_cell_1: $i > $i).
% 29.22/29.06  tff(decl_45985, type, fn_immune_cell_2: $i > $i).
% 29.22/29.06  tff(decl_45986, type, fn_immune_cell_3: $i > $i).
% 29.22/29.06  tff(decl_45987, type, fn_immune_cell_4: $i > $i).
% 29.22/29.06  tff(decl_45988, type, fn_immune_cell_5: $i > $i).
% 29.22/29.06  tff(decl_45989, type, fn_immune_cell_6: $i > $i).
% 29.22/29.06  tff(decl_45990, type, fn_immune_cell_7: $i > $i).
% 29.22/29.06  tff(decl_45991, type, fn_immune_cell_8: $i > $i).
% 29.22/29.06  tff(decl_45992, type, immune_system_1: $i > $o).
% 29.22/29.06  tff(decl_45993, type, fn_immune_cell_9: $i > $i).
% 29.22/29.06  tff(decl_45994, type, fn_immune_response_2: $i > $i).
% 29.22/29.06  tff(decl_45995, type, 'Immune-Disorders': $i).
% 29.22/29.06  tff(decl_45996, type, 'Disorders caused by abnormal function of the immune system.': $i).
% 29.22/29.06  tff(decl_45997, type, 'immune disorders': $i).
% 29.22/29.06  tff(decl_45998, type, 'immune disorder': $i).
% 29.22/29.06  tff(decl_45999, type, 'immune-disorder': $i).
% 29.22/29.06  tff(decl_46000, type, 'Immune-Organ': $i).
% 29.22/29.06  tff(decl_46001, type, 'Organ which is part of the immune system of animals.': $i).
% 29.22/29.06  tff(decl_46002, type, 'organ of immune': $i).
% 29.22/29.06  tff(decl_46003, type, 'immune organ': $i).
% 29.22/29.06  tff(decl_46004, type, 'immune-organ': $i).
% 29.22/29.06  tff(decl_46005, type, 'Immune-Related-Intercellular-Process': $i).
% 29.22/29.06  tff(decl_46006, type, 'Intercellular process related to the immune system of animals.': $i).
% 29.22/29.06  tff(decl_46007, type, 'immune related intercellular process': $i).
% 29.22/29.06  tff(decl_46008, type, 'immune-related-intercellular-process': $i).
% 29.22/29.06  tff(decl_46009, type, 'Immune-Response': $i).
% 29.22/29.06  tff(decl_46010, type, 'Any process by which an organism recognizes and defends itself against microbial pathogens and substances that may be harmful.': $i).
% 29.22/29.06  tff(decl_46011, type, 'response of immune': $i).
% 29.22/29.06  tff(decl_46012, type, 'immune response': $i).
% 29.22/29.06  tff(decl_46013, type, 'immune-response': $i).
% 29.22/29.06  tff(decl_46014, type, fn_immune_response_1: $i > $i).
% 29.22/29.06  tff(decl_46015, type, immune_response_for_transformed_cell_1: $i > $o).
% 29.22/29.06  tff(decl_46016, type, 'Immune-Response-For-Transformed-Cell': $i).
% 29.22/29.06  tff(decl_46017, type, 'The process of how an organism recognizes and defends itself against cells which have transformed to cancer cells.': $i).
% 29.22/29.06  tff(decl_46018, type, 'immune response for transformed cell': $i).
% 29.22/29.06  tff(decl_46019, type, 'immune-response-for-transformed-cell': $i).
% 29.22/29.06  tff(decl_46020, type, fn_immune_response_for_transformed_cell_1: $i > $i).
% 29.22/29.06  tff(decl_46021, type, fn_immune_response_for_transformed_cell_2: $i > $i).
% 29.22/29.06  tff(decl_46022, type, fn_immune_response_for_transformed_cell_3: $i > $i).
% 29.22/29.06  tff(decl_46023, type, fn_immune_response_for_transformed_cell_4: $i > $i).
% 29.22/29.06  tff(decl_46024, type, 'Immune-System': $i).
% 29.22/29.06  tff(decl_46025, type, 'The set of biological processes and structures that protect an organism from disease.': $i).
% 29.22/29.06  tff(decl_46026, type, 'system of immune': $i).
% 29.22/29.06  tff(decl_46027, type, 'immune system': $i).
% 29.22/29.06  tff(decl_46028, type, 'immune-system': $i).
% 29.22/29.06  tff(decl_46029, type, fn_immune_system_1: $i > $i).
% 29.22/29.06  tff(decl_46030, type, fn_immune_system_2: $i > $i).
% 29.22/29.06  tff(decl_46031, type, fn_immune_system_3: $i > $i).
% 29.22/29.06  tff(decl_46032, type, fn_immune_system_4: $i > $i).
% 29.22/29.06  tff(decl_46033, type, fn_immune_system_5: $i > $i).
% 29.22/29.06  tff(decl_46034, type, fn_immune_system_6: $i > $i).
% 29.22/29.06  tff(decl_46035, type, fn_immune_system_7: $i > $i).
% 29.22/29.06  tff(decl_46036, type, fn_immune_system_8: $i > $i).
% 29.22/29.06  tff(decl_46037, type, fn_immune_system_9: $i > $i).
% 29.22/29.06  tff(decl_46038, type, fn_immune_system_10: $i > $i).
% 29.22/29.06  tff(decl_46039, type, rejection_of_foreign_cell_1: $i > $o).
% 29.22/29.06  tff(decl_46040, type, fn_immune_system_11: $i > $i).
% 29.22/29.06  tff(decl_46041, type, fn_immune_system_12: $i > $i).
% 29.22/29.06  tff(decl_46042, type, fn_immune_system_13: $i > $i).
% 29.22/29.06  tff(decl_46043, type, fn_rejection_of_foreign_cell_4: $i > $i).
% 29.22/29.06  tff(decl_46044, type, fn_rejection_of_foreign_cell_5: $i > $i).
% 29.22/29.06  tff(decl_46045, type, "1000000": $i).
% 29.22/29.06  tff(decl_46046, type, b_cell_0: $i).
% 29.22/29.06  tff(decl_46047, type, 'Immunization': $i).
% 29.22/29.06  tff(decl_46048, type, 'The process by which an inactive or weakened form of a pathogen is introduced into the body, triggering the production of memory cells.  Upon second contact with the pathogen, the immune system responds much more quickly and rapidly produces antibodies that can fight off the pathogen.': $i).
% 29.22/29.06  tff(decl_46049, type, vaccination: $i).
% 29.22/29.06  tff(decl_46050, type, immunize: $i).
% 29.22/29.06  tff(decl_46051, type, immunization: $i).
% 29.22/29.06  tff(decl_46052, type, immunodeficiency_1: $i > $o).
% 29.22/29.06  tff(decl_46053, type, 'Immunodeficiency': $i).
% 29.22/29.06  tff(decl_46054, type, 'A condition in which the immune system is not able to adequately protect against pathogens.': $i).
% 29.22/29.06  tff(decl_46055, type, immunodeficiency: $i).
% 29.22/29.06  tff(decl_46056, type, lupus_1: $i > $o).
% 29.22/29.06  tff(decl_46057, type, rheumatoid_arthritis_1: $i > $o).
% 29.22/29.06  tff(decl_46058, type, type_1_diabetes_mellitus_1: $i > $o).
% 29.22/29.06  tff(decl_46059, type, 'Immunoglobulin-Gene': $i).
% 29.22/29.06  tff(decl_46060, type, 'A gene encoding for an immunoglobulin (e.g., an antibody).': $i).
% 29.22/29.06  tff(decl_46061, type, 'antibody gene': $i).
% 29.22/29.06  tff(decl_46062, type, 'gene of immunoglobulin': $i).
% 29.22/29.06  tff(decl_46063, type, 'immunoglobulin gene': $i).
% 29.22/29.06  tff(decl_46064, type, 'immunoglobulin-gene': $i).
% 29.22/29.06  tff(decl_46065, type, fn_immunoglobulin_gene_3: $i > $i).
% 29.22/29.06  tff(decl_46066, type, fn_immunoglobulin_gene_4: $i > $i).
% 29.22/29.06  tff(decl_46067, type, fn_immunoglobulin_gene_5: $i > $i).
% 29.22/29.06  tff(decl_46068, type, fn_immunoglobulin_gene_6: $i > $i).
% 29.22/29.06  tff(decl_46069, type, fn_immunoglobulin_gene_7: $i > $i).
% 29.22/29.06  tff(decl_46070, type, fn_immunoglobulin_gene_8: $i > $i).
% 29.22/29.06  tff(decl_46071, type, fn_immunoglobulin_gene_10: $i > $i).
% 29.22/29.06  tff(decl_46072, type, fn_immunoglobulin_gene_11: $i > $i).
% 29.22/29.06  tff(decl_46073, type, fn_immunoglobulin_gene_12: $i > $i).
% 29.22/29.06  tff(decl_46074, type, fn_immunoglobulin_gene_13: $i > $i).
% 29.22/29.06  tff(decl_46075, type, fn_immunoglobulin_gene_14: $i > $i).
% 29.22/29.06  tff(decl_46076, type, fn_immunoglobulin_gene_15: $i > $i).
% 29.22/29.06  tff(decl_46077, type, fn_immunoglobulin_gene_16: $i > $i).
% 29.22/29.06  tff(decl_46078, type, fn_immunoglobulin_gene_17: $i > $i).
% 29.22/29.06  tff(decl_46079, type, fn_immunoglobulin_gene_18: $i > $i).
% 29.22/29.06  tff(decl_46080, type, fn_immunoglobulin_gene_19: $i > $i).
% 29.22/29.06  tff(decl_46081, type, fn_immunoglobulin_gene_20: $i > $i).
% 29.22/29.06  tff(decl_46082, type, fn_immunoglobulin_gene_21: $i > $i).
% 29.22/29.06  tff(decl_46083, type, fn_immunoglobulin_gene_22: $i > $i).
% 29.22/29.06  tff(decl_46084, type, fn_immunoglobulin_gene_23: $i > $i).
% 29.22/29.06  tff(decl_46085, type, fn_immunoglobulin_gene_24: $i > $i).
% 29.22/29.06  tff(decl_46086, type, fn_immunoglobulin_gene_25: $i > $i).
% 29.22/29.06  tff(decl_46087, type, fn_immunoglobulin_gene_26: $i > $i).
% 29.22/29.06  tff(decl_46088, type, fn_immunoglobulin_gene_27: $i > $i).
% 29.22/29.06  tff(decl_46089, type, fn_immunoglobulin_gene_29: $i > $i).
% 29.22/29.06  tff(decl_46090, type, fn_immunoglobulin_gene_30: $i > $i).
% 29.22/29.06  tff(decl_46091, type, fn_immunoglobulin_gene_31: $i > $i).
% 29.22/29.06  tff(decl_46092, type, fn_immunoglobulin_gene_32: $i > $i).
% 29.22/29.06  tff(decl_46093, type, fn_immunoglobulin_gene_33: $i > $i).
% 29.22/29.06  tff(decl_46094, type, 'Immunoglobulin-Protein': $i).
% 29.22/29.06  tff(decl_46095, type, 'Proteins that specifically recognize and help combat viruses, bacteria, and other invaders of the body.': $i).
% 29.22/29.06  tff(decl_46096, type, antibodies: $i).
% 29.22/29.06  tff(decl_46097, type, 'protein of immunoglobulin': $i).
% 29.22/29.06  tff(decl_46098, type, 'immunoglobulin protein': $i).
% 29.22/29.06  tff(decl_46099, type, 'immunoglobulin-protein': $i).
% 29.22/29.06  tff(decl_46100, type, 'Impair': $i).
% 29.22/29.06  tff(decl_46101, type, impair: $i).
% 29.22/29.06  tff(decl_46102, type, 'Implant': $i).
% 29.22/29.06  tff(decl_46103, type, 'To insert securely.': $i).
% 29.22/29.06  tff(decl_46104, type, implant: $i).
% 29.22/29.06  tff(decl_46105, type, 'Importance-Constant': $i).
% 29.22/29.06  tff(decl_46106, type, 'constant of importance': $i).
% 29.22/29.06  tff(decl_46107, type, 'importance constant': $i).
% 29.22/29.06  tff(decl_46108, type, 'importance-constant': $i).
% 29.22/29.06  tff(decl_46109, type, importance_scale_1: $i > $o).
% 29.22/29.06  tff(decl_46110, type, 'Importance-Scale': $i).
% 29.22/29.06  tff(decl_46111, type, 'scale of importance': $i).
% 29.22/29.06  tff(decl_46112, type, 'importance scale': $i).
% 29.22/29.06  tff(decl_46113, type, 'importance-scale': $i).
% 29.22/29.06  tff(decl_46114, type, imprinting_1: $i > $o).
% 29.22/29.06  tff(decl_46115, type, 'Imprinting': $i).
% 29.22/29.06  tff(decl_46116, type, 'In animal behavior, learning that occurs during a specific age or life history stage and generates a long-lasting behavioral response to a particular object or individual.': $i).
% 29.22/29.06  tff(decl_46117, type, imprint: $i).
% 29.22/29.06  tff(decl_46118, type, imprinting: $i).
% 29.22/29.06  tff(decl_46119, type, improperly_methylated_dna_1: $i > $o).
% 29.22/29.06  tff(decl_46120, type, 'Improperly-Methylated-DNA': $i).
% 29.22/29.06  tff(decl_46121, type, 'A portion of a DNA molecule with one or more methyl groups attached. The improperly methylated DNA have extra methyl groups.': $i).
% 29.22/29.06  tff(decl_46122, type, 'improperly methylated dna': $i).
% 29.22/29.06  tff(decl_46123, type, 'improperly-methylated-dna': $i).
% 29.22/29.06  tff(decl_46124, type, modified_dna_1: $i > $o).
% 29.22/29.06  tff(decl_46125, type, 'Improvement': $i).
% 29.22/29.06  tff(decl_46126, type, improve: $i).
% 29.22/29.06  tff(decl_46127, type, better: $i).
% 29.22/29.06  tff(decl_46128, type, amend: $i).
% 29.22/29.06  tff(decl_46129, type, ameliorate: $i).
% 29.22/29.06  tff(decl_46130, type, meliorate: $i).
% 29.22/29.06  tff(decl_46131, type, betterment: $i).
% 29.22/29.06  tff(decl_46132, type, advance: $i).
% 29.22/29.06  tff(decl_46133, type, 'In-Situ': $i).
% 29.22/29.06  tff(decl_46134, type, 'Technique in which biological events are examined where they occur, within the organism or cell.': $i).
% 29.22/29.06  tff(decl_46135, type, 'in situ': $i).
% 29.22/29.06  tff(decl_46136, type, 'in-situ': $i).
% 29.22/29.06  tff(decl_46137, type, in_vitro_1: $i > $o).
% 29.22/29.06  tff(decl_46138, type, 'In-Vitro': $i).
% 29.22/29.06  tff(decl_46139, type, 'Technique in which biological events are examined in the laboratory, outside and isolated from the organism or cell.': $i).
% 29.22/29.06  tff(decl_46140, type, 'in vitro': $i).
% 29.22/29.06  tff(decl_46141, type, 'in-vitro': $i).
% 29.22/29.06  tff(decl_46142, type, in_vitro_fertilization_1: $i > $o).
% 29.22/29.06  tff(decl_46143, type, 'In-Vitro-Fertilization': $i).
% 29.22/29.06  tff(decl_46144, type, 'The fertilization of eggs outside the body--i.e., in laboratory dishes--and concomitant implantation of early embryos into the mother\\s uterus.': $i).
% 29.22/29.06  tff(decl_46145, type, 'in vitro fertilization': $i).
% 29.22/29.06  tff(decl_46146, type, 'in-vitro-fertilization': $i).
% 29.22/29.06  tff(decl_46147, type, 'In-Vitro-Hybridization': $i).
% 29.22/29.06  tff(decl_46148, type, 'A technique used to discover the function of a gene. The gene is cloned, then specific changes are made in the sequence. The mutated gene is then reinserted into a living cell and its expressed phenotype is studied.': $i).
% 29.22/29.06  tff(decl_46149, type, 'undergo in vitro hybridization': $i).
% 29.22/29.06  tff(decl_46150, type, 'undergo in-vitro hybridization': $i).
% 29.22/29.06  tff(decl_46151, type, 'in vitro hybridization': $i).
% 29.22/29.06  tff(decl_46152, type, 'in-vitro-hybridization': $i).
% 29.22/29.06  tff(decl_46153, type, in_vitro_mutagenesis_1: $i > $o).
% 29.22/29.06  tff(decl_46154, type, 'In-Vitro-Mutagenesis': $i).
% 29.22/29.06  tff(decl_46155, type, 'A way of determining the function of a gene by: (1) cloning the gene; (2) creating specific or random mutations in the DNA sequence; (3) reinserting the mutated gene into a cell; and (4) observing the resulting phenotype.': $i).
% 29.22/29.06  tff(decl_46156, type, 'undergo in vitro mutagenesis': $i).
% 29.22/29.06  tff(decl_46157, type, 'undergo in-vitro mutagenesis': $i).
% 29.22/29.06  tff(decl_46158, type, 'in vitro mutagenesis': $i).
% 29.22/29.06  tff(decl_46159, type, 'in-vitro-mutagenesis': $i).
% 29.22/29.06  tff(decl_46160, type, 'Inactivation-Of-cAMP': $i).
% 29.22/29.06  tff(decl_46161, type, 'The process of converting active form of cAMP to inactive form by the enzymatic removal of a phosphate group.': $i).
% 29.22/29.06  tff(decl_46162, type, 'camp inactivation': $i).
% 29.22/29.06  tff(decl_46163, type, 'camp-inactivation': $i).
% 29.22/29.06  tff(decl_46164, type, 'inactivation of camp': $i).
% 29.22/29.06  tff(decl_46165, type, 'inactivation-of-camp': $i).
% 29.22/29.06  tff(decl_46166, type, inactivation_of_phosphorylated_kinase_1: $i > $o).
% 29.22/29.06  tff(decl_46167, type, inactivation_of_relay_molecule_1: $i > $o).
% 29.22/29.06  tff(decl_46168, type, fn_inactivation_of_camp_3: $i > $i).
% 29.22/29.06  tff(decl_46169, type, fn_inactivation_of_camp_4: $i > $i).
% 29.22/29.06  tff(decl_46170, type, fn_inactivation_of_camp_5: $i > $i).
% 29.22/29.06  tff(decl_46171, type, fn_inactivation_of_camp_6: $i > $i).
% 29.22/29.06  tff(decl_46172, type, fn_inactivation_of_camp_7: $i > $i).
% 29.22/29.06  tff(decl_46173, type, fn_inactivation_of_camp_8: $i > $i).
% 29.22/29.06  tff(decl_46174, type, fn_inactivation_of_camp_9: $i > $i).
% 29.22/29.06  tff(decl_46175, type, fn_inactivation_of_camp_10: $i > $i).
% 29.22/29.06  tff(decl_46176, type, fn_inactivation_of_camp_12: $i > $i).
% 29.22/29.06  tff(decl_46177, type, fn_inactivation_of_camp_13: $i > $i).
% 29.22/29.06  tff(decl_46178, type, fn_inactivation_of_camp_18: $i > $i).
% 29.22/29.06  tff(decl_46179, type, 'Inactivation-Of-Phosphorylated-Kinase': $i).
% 29.22/29.06  tff(decl_46180, type, 'Protein phosphatases are enzymes that remove phosphate groups from proteins to inactivate them.  Dephosphorylation of kinases inactivates them.': $i).
% 29.22/29.06  tff(decl_46181, type, 'inactivation of phosphorylated kinase': $i).
% 29.22/29.06  tff(decl_46182, type, 'inactivation-of-phosphorylated-kinase': $i).
% 29.22/29.06  tff(decl_46183, type, fn_inactivation_of_phosphorylated_kinase_1: $i > $i).
% 29.22/29.06  tff(decl_46184, type, fn_inactivation_of_phosphorylated_kinase_2: $i > $i).
% 29.22/29.06  tff(decl_46185, type, fn_inactivation_of_phosphorylated_kinase_3: $i > $i).
% 29.22/29.06  tff(decl_46186, type, fn_inactivation_of_phosphorylated_kinase_4: $i > $i).
% 29.22/29.06  tff(decl_46187, type, fn_inactivation_of_phosphorylated_kinase_5: $i > $i).
% 29.22/29.06  tff(decl_46188, type, fn_inactivation_of_phosphorylated_kinase_6: $i > $i).
% 29.22/29.06  tff(decl_46189, type, fn_inactivation_of_phosphorylated_kinase_7: $i > $i).
% 29.22/29.06  tff(decl_46190, type, fn_inactivation_of_phosphorylated_kinase_8: $i > $i).
% 29.22/29.06  tff(decl_46191, type, fn_inactivation_of_phosphorylated_kinase_9: $i > $i).
% 29.22/29.06  tff(decl_46192, type, fn_inactivation_of_phosphorylated_kinase_10: $i > $i).
% 29.22/29.06  tff(decl_46193, type, fn_inactivation_of_phosphorylated_kinase_11: $i > $i).
% 29.22/29.06  tff(decl_46194, type, phosphorylated_kinase_1: $i > $o).
% 29.22/29.06  tff(decl_46195, type, fn_inactivation_of_phosphorylated_kinase_12: $i > $i).
% 29.22/29.06  tff(decl_46196, type, fn_inactivation_of_phosphorylated_kinase_13: $i > $i).
% 29.22/29.06  tff(decl_46197, type, fn_inactivation_of_phosphorylated_kinase_14: $i > $i).
% 29.22/29.06  tff(decl_46198, type, fn_inactivation_of_phosphorylated_kinase_15: $i > $i).
% 29.22/29.06  tff(decl_46199, type, fn_inactivation_of_phosphorylated_kinase_16: $i > $i).
% 29.22/29.06  tff(decl_46200, type, fn_inactivation_of_phosphorylated_kinase_17: $i > $i).
% 29.22/29.06  tff(decl_46201, type, fn_inactivation_of_phosphorylated_kinase_18: $i > $i).
% 29.22/29.06  tff(decl_46202, type, fn_inactivation_of_phosphorylated_kinase_19: $i > $i).
% 29.22/29.06  tff(decl_46203, type, fn_inactivation_of_phosphorylated_kinase_20: $i > $i).
% 29.22/29.06  tff(decl_46204, type, fn_inactivation_of_phosphorylated_kinase_21: $i > $i).
% 29.22/29.06  tff(decl_46205, type, fn_inactivation_of_phosphorylated_kinase_22: $i > $i).
% 29.22/29.06  tff(decl_46206, type, fn_inactivation_of_phosphorylated_kinase_23: $i > $i).
% 29.22/29.06  tff(decl_46207, type, fn_inactivation_of_phosphorylated_kinase_24: $i > $i).
% 29.22/29.06  tff(decl_46208, type, fn_phosphorylated_kinase_2: $i > $i).
% 29.22/29.06  tff(decl_46209, type, fn_phosphorylated_kinase_1: $i > $i).
% 29.22/29.06  tff(decl_46210, type, fn_inactivation_of_phosphorylated_kinase_26: $i > $i).
% 29.22/29.06  tff(decl_46211, type, fn_inactivation_of_phosphorylated_kinase_25: $i > $i).
% 29.22/29.06  tff(decl_46212, type, 'Inactivation-Of-Relay-Molecule': $i).
% 29.22/29.06  tff(decl_46213, type, 'A relay molecules, often proteins, relay a signal from receptor to response.  Protein phosphatases dephosphorylate the relay molecule, deactivating it.': $i).
% 29.22/29.06  tff(decl_46214, type, 'inactivation of relay molecule': $i).
% 29.22/29.06  tff(decl_46215, type, 'inactivation-of-relay-molecule': $i).
% 29.22/29.06  tff(decl_46216, type, fn_inactivation_of_relay_molecule_1: $i > $i).
% 29.22/29.06  tff(decl_46217, type, fn_inactivation_of_relay_molecule_2: $i > $i).
% 29.22/29.06  tff(decl_46218, type, fn_inactivation_of_relay_molecule_3: $i > $i).
% 29.22/29.06  tff(decl_46219, type, fn_inactivation_of_relay_molecule_4: $i > $i).
% 29.22/29.06  tff(decl_46220, type, fn_inactivation_of_relay_molecule_5: $i > $i).
% 29.22/29.06  tff(decl_46221, type, fn_inactivation_of_relay_molecule_6: $i > $i).
% 29.22/29.06  tff(decl_46222, type, fn_inactivation_of_relay_molecule_7: $i > $i).
% 29.22/29.06  tff(decl_46223, type, fn_inactivation_of_relay_molecule_8: $i > $i).
% 29.22/29.06  tff(decl_46224, type, fn_inactivation_of_relay_molecule_9: $i > $i).
% 29.22/29.06  tff(decl_46225, type, fn_inactivation_of_relay_molecule_10: $i > $i).
% 29.22/29.06  tff(decl_46226, type, fn_inactivation_of_relay_molecule_11: $i > $i).
% 29.22/29.06  tff(decl_46227, type, fn_inactivation_of_relay_molecule_12: $i > $i).
% 29.22/29.06  tff(decl_46228, type, fn_inactivation_of_relay_molecule_13: $i > $i).
% 29.22/29.06  tff(decl_46229, type, fn_inactivation_of_relay_molecule_14: $i > $i).
% 29.22/29.06  tff(decl_46230, type, fn_inactivation_of_relay_molecule_15: $i > $i).
% 29.22/29.06  tff(decl_46231, type, fn_inactivation_of_relay_molecule_16: $i > $i).
% 29.22/29.06  tff(decl_46232, type, inactivation_of_transport_protein_1: $i > $o).
% 29.22/29.06  tff(decl_46233, type, 'Inactivation-Of-Transport-Protein': $i).
% 29.22/29.06  tff(decl_46234, type, 'Transport proteins are activated by phosphorylation, gaining a phosphate group from an ATP molecule.  Removal of the phosphate group would inactivate the transport protein.': $i).
% 29.22/29.06  tff(decl_46235, type, 'inactivation of transport protein': $i).
% 29.22/29.06  tff(decl_46236, type, 'inactivation-of-transport-protein': $i).
% 29.22/29.06  tff(decl_46237, type, fn_inactivation_of_transport_protein_1: $i > $i).
% 29.22/29.06  tff(decl_46238, type, fn_inactivation_of_transport_protein_2: $i > $i).
% 29.22/29.06  tff(decl_46239, type, fn_inactivation_of_transport_protein_3: $i > $i).
% 29.22/29.06  tff(decl_46240, type, fn_inactivation_of_transport_protein_4: $i > $i).
% 29.22/29.06  tff(decl_46241, type, fn_inactivation_of_transport_protein_5: $i > $i).
% 29.22/29.06  tff(decl_46242, type, fn_inactivation_of_transport_protein_6: $i > $i).
% 29.22/29.06  tff(decl_46243, type, fn_inactivation_of_transport_protein_7: $i > $i).
% 29.22/29.06  tff(decl_46244, type, fn_inactivation_of_transport_protein_8: $i > $i).
% 29.22/29.06  tff(decl_46245, type, fn_inactivation_of_transport_protein_9: $i > $i).
% 29.22/29.06  tff(decl_46246, type, fn_inactivation_of_transport_protein_10: $i > $i).
% 29.22/29.06  tff(decl_46247, type, fn_inactivation_of_transport_protein_11: $i > $i).
% 29.22/29.06  tff(decl_46248, type, fn_inactivation_of_transport_protein_12: $i > $i).
% 29.22/29.06  tff(decl_46249, type, fn_inactivation_of_transport_protein_13: $i > $i).
% 29.22/29.06  tff(decl_46250, type, fn_inactivation_of_transport_protein_14: $i > $i).
% 29.22/29.06  tff(decl_46251, type, fn_inactivation_of_transport_protein_15: $i > $i).
% 29.22/29.06  tff(decl_46252, type, fn_inactivation_of_transport_protein_16: $i > $i).
% 29.22/29.06  tff(decl_46253, type, fn_inactivation_of_transport_protein_17: $i > $i).
% 29.22/29.06  tff(decl_46254, type, fn_inactivation_of_transport_protein_18: $i > $i).
% 29.22/29.06  tff(decl_46255, type, fn_inactivation_of_transport_protein_19: $i > $i).
% 29.22/29.06  tff(decl_46256, type, fn_inactivation_of_transport_protein_20: $i > $i).
% 29.22/29.06  tff(decl_46257, type, fn_inactivation_of_transport_protein_21: $i > $i).
% 29.22/29.06  tff(decl_46258, type, fn_inactivation_of_transport_protein_22: $i > $i).
% 29.22/29.06  tff(decl_46259, type, 'Inactive-Repressor': $i).
% 29.22/29.06  tff(decl_46260, type, 'A protein that inhibits gene transcription.  In prokaryotes, repressors bind to the DNA in or near the promotor.  In eukaryotes, repressors may bind to control elements within enhancers, to activators, or to other proteins in a way that blocks activators from binding to DNA.': $i).
% 29.22/29.06  tff(decl_46261, type, 'inactive repressor': $i).
% 29.22/29.06  tff(decl_46262, type, 'inactive-repressor': $i).
% 29.22/29.06  tff(decl_46263, type, fn_inactive_repressor_1: $i > $i).
% 29.22/29.06  tff(decl_46264, type, fn_inactive_repressor_6: $i > $i).
% 29.22/29.06  tff(decl_46265, type, fn_inactive_repressor_7: $i > $i).
% 29.22/29.06  tff(decl_46266, type, fn_inactive_repressor_8: $i > $i).
% 29.22/29.06  tff(decl_46267, type, fn_inactive_repressor_9: $i > $i).
% 29.22/29.06  tff(decl_46268, type, fn_inactive_repressor_10: $i > $i).
% 29.22/29.06  tff(decl_46269, type, fn_inactive_repressor_11: $i > $i).
% 29.22/29.06  tff(decl_46270, type, fn_inactive_repressor_12: $i > $i).
% 29.22/29.06  tff(decl_46271, type, fn_inactive_repressor_13: $i > $i).
% 29.22/29.06  tff(decl_46272, type, fn_inactive_repressor_14: $i > $i).
% 29.22/29.06  tff(decl_46273, type, fn_inactive_repressor_15: $i > $i).
% 29.22/29.06  tff(decl_46274, type, fn_inactive_repressor_16: $i > $i).
% 29.22/29.06  tff(decl_46275, type, fn_inactive_repressor_17: $i > $i).
% 29.22/29.06  tff(decl_46276, type, fn_inactive_repressor_18: $i > $i).
% 29.22/29.06  tff(decl_46277, type, fn_inactive_repressor_19: $i > $i).
% 29.22/29.06  tff(decl_46278, type, fn_inactive_repressor_20: $i > $i).
% 29.22/29.06  tff(decl_46279, type, fn_inactive_repressor_21: $i > $i).
% 29.22/29.06  tff(decl_46280, type, fn_inactive_repressor_22: $i > $i).
% 29.22/29.06  tff(decl_46281, type, fn_inactive_repressor_23: $i > $i).
% 29.22/29.06  tff(decl_46282, type, fn_inactive_repressor_24: $i > $i).
% 29.22/29.06  tff(decl_46283, type, fn_inactive_repressor_25: $i > $i).
% 29.22/29.06  tff(decl_46284, type, fn_inactive_repressor_4: $i > $i).
% 29.22/29.06  tff(decl_46285, type, fn_inactive_repressor_3: $i > $i).
% 29.22/29.06  tff(decl_46286, type, fn_inactive_repressor_5: $i > $i).
% 29.22/29.06  tff(decl_46287, type, fn_inactive_repressor_2: $i > $i).
% 29.22/29.06  tff(decl_46288, type, 'Inanimate-Object': $i).
% 29.22/29.06  tff(decl_46289, type, 'A non-living thing': $i).
% 29.22/29.06  tff(decl_46290, type, 'inanimate object': $i).
% 29.22/29.06  tff(decl_46291, type, 'inanimate-object': $i).
% 29.22/29.06  tff(decl_46292, type, 'Inborn-Error-Of-Metabolism': $i).
% 29.22/29.06  tff(decl_46293, type, 'Class of genetic diseases which result in  hereditory metabolic disorders.': $i).
% 29.22/29.06  tff(decl_46294, type, 'inborn error of metabolism': $i).
% 29.22/29.06  tff(decl_46295, type, 'inborn-error-of-metabolism': $i).
% 29.22/29.06  tff(decl_46296, type, 'Incisor': $i).
% 29.22/29.06  tff(decl_46297, type, 'Relatively flat, blade-like tooth, located near the front of the mouth, specialized for holding and tearing food.': $i).
% 29.22/29.06  tff(decl_46298, type, incisor: $i).
% 29.22/29.06  tff(decl_46299, type, fn_incisor_1: $i > $i).
% 29.22/29.06  tff(decl_46300, type, fn_incisor_2: $i > $i).
% 29.22/29.06  tff(decl_46301, type, fn_incisor_3: $i > $i).
% 29.22/29.06  tff(decl_46302, type, 'Incomplete-Dominance': $i).
% 29.22/29.06  tff(decl_46303, type, 'The situation in which the phenotype of heterozygotes is intermediate between the phenotypes of individuals homozygous for either allele.': $i).
% 29.22/29.06  tff(decl_46304, type, 'incomplete dominance': $i).
% 29.22/29.06  tff(decl_46305, type, 'incomplete-dominance': $i).
% 29.22/29.06  tff(decl_46306, type, fn_incomplete_dominance_1: $i > $i).
% 29.22/29.06  tff(decl_46307, type, fn_incomplete_dominance_2: $i > $i).
% 29.22/29.06  tff(decl_46308, type, fn_incomplete_dominance_3: $i > $i).
% 29.22/29.06  tff(decl_46309, type, fn_incomplete_dominance_4: $i > $i).
% 29.22/29.06  tff(decl_46310, type, trait_on_one_end_of_a_range_1: $i > $o).
% 29.22/29.06  tff(decl_46311, type, 'Incomplete-Dominance-Cross-Breeding-Event': $i).
% 29.22/29.06  tff(decl_46312, type, 'Mating of two individuals, with expression of incomplete dominant alleles being investigated.': $i).
% 29.22/29.06  tff(decl_46313, type, 'incomplete dominance cross breeding event': $i).
% 29.22/29.06  tff(decl_46314, type, 'incomplete-dominance-cross-breeding-event': $i).
% 29.22/29.06  tff(decl_46315, type, fn_incomplete_dominance_cross_breeding_event_1: $i > $i).
% 29.22/29.06  tff(decl_46316, type, 'Incomplete-Flower': $i).
% 29.22/29.06  tff(decl_46317, type, 'A flower in which one or more of the four basic floral organs (sepals, petals, stamens, or carpels) are either absent or nonfunctional.': $i).
% 29.22/29.06  tff(decl_46318, type, 'incomplete flower': $i).
% 29.22/29.06  tff(decl_46319, type, 'incomplete-flower': $i).
% 29.22/29.06  tff(decl_46320, type, 'Incomplete-Metamorphosis': $i).
% 29.22/29.06  tff(decl_46321, type, 'A type of development in some insects, suchh as dragonflies and grasshoppers, in which there is no distinct larval stage and the young resemble small versions of the adult form. There is no radical metamorphosis; instead, the young undergo a series of molts, each time looking more like the adult form, until the full size is attained.': $i).
% 29.22/29.06  tff(decl_46322, type, 'incomplete metamorphosis': $i).
% 29.22/29.06  tff(decl_46323, type, 'incomplete-metamorphosis': $i).
% 29.22/29.06  tff(decl_46324, type, 'Incomplete-Valence-Shell': $i).
% 29.22/29.06  tff(decl_46325, type, 'The outermost energy shell of an atom holding less than the maximum number of possible valence electrons.': $i).
% 29.22/29.06  tff(decl_46326, type, 'incomplete outer shell': $i).
% 29.22/29.06  tff(decl_46327, type, 'incomplete valence shell': $i).
% 29.22/29.06  tff(decl_46328, type, 'incomplete-valence-shell': $i).
% 29.22/29.06  tff(decl_46329, type, 'Increase': $i).
% 29.22/29.06  tff(decl_46330, type, 'Increase-In-Accuracy-Of-DNA-Replication': $i).
% 29.22/29.06  tff(decl_46331, type, 'Process of increasing accuracy of DNA Replication.': $i).
% 29.22/29.06  tff(decl_46332, type, 'increase in accuracy of dna replication': $i).
% 29.22/29.06  tff(decl_46333, type, 'increase-in-accuracy-of-dna-replication': $i).
% 29.22/29.06  tff(decl_46334, type, fn_increase_in_accuracy_of_dna_replication_1: $i > $i).
% 29.22/29.06  tff(decl_46335, type, specificity_of_base_pairing_1: $i > $o).
% 29.22/29.06  tff(decl_46336, type, 'Increase-In-Cell-Size': $i).
% 29.22/29.06  tff(decl_46337, type, 'The growth in the size of the cell limited by the ratio of surface area to volume.': $i).
% 29.22/29.06  tff(decl_46338, type, 'increase in cell size': $i).
% 29.22/29.06  tff(decl_46339, type, 'increase-in-cell-size': $i).
% 29.22/29.06  tff(decl_46340, type, fn_increase_in_cell_size_1: $i > $i).
% 29.22/29.06  tff(decl_46341, type, fn_increase_in_cell_size_2: $i > $i).
% 29.22/29.06  tff(decl_46342, type, fn_increase_in_cell_size_3: $i > $i).
% 29.22/29.06  tff(decl_46343, type, fn_increase_in_cell_size_4: $i > $i).
% 29.22/29.06  tff(decl_46344, type, increase_in_stability_1: $i > $o).
% 29.22/29.06  tff(decl_46345, type, 'Increase-in-Stability': $i).
% 29.22/29.06  tff(decl_46346, type, 'Process of increasing stability.': $i).
% 29.22/29.06  tff(decl_46347, type, 'increase in stability': $i).
% 29.22/29.06  tff(decl_46348, type, 'increase-in-stability': $i).
% 29.22/29.06  tff(decl_46349, type, fn_increase_of_activation_energy_4: $i > $i).
% 29.22/29.06  tff(decl_46350, type, 'Increase-of-Activation-Energy': $i).
% 29.22/29.06  tff(decl_46351, type, 'It is the process of increase of activation energy.': $i).
% 29.22/29.06  tff(decl_46352, type, 'increase of activation energy': $i).
% 29.22/29.06  tff(decl_46353, type, 'increase-of-activation-energy': $i).
% 29.22/29.06  tff(decl_46354, type, fn_increase_of_activation_energy_1: $i > $i).
% 29.22/29.06  tff(decl_46355, type, fn_increase_of_activation_energy_3: $i > $i).
% 29.22/29.06  tff(decl_46356, type, fn_increase_of_activation_energy_5: $i > $i).
% 29.22/29.06  tff(decl_46357, type, fn_increase_of_activation_energy_9: $i > $i).
% 29.22/29.06  tff(decl_46358, type, threshold_potential_1: $i > $o).
% 29.22/29.06  tff(decl_46359, type, fn_increase_of_activation_energy_10: $i > $i).
% 29.22/29.06  tff(decl_46360, type, fn_voltage_8: $i > $i).
% 29.22/29.06  tff(decl_46361, type, fn_voltage_9: $i > $i).
% 29.22/29.06  tff(decl_46362, type, 'Q_ae': $i).
% 29.22/29.06  tff(decl_46363, type, 'Q_tp': $i).
% 29.22/29.06  tff(decl_46364, type, fn_increase_of_activation_energy_11: $i > $i).
% 29.22/29.06  tff(decl_46365, type, 'Incubation': $i).
% 29.22/29.06  tff(decl_46366, type, 'In birds and some reptiles, sitting on or huddling around a clutch of eggs to maintain them at the temperature required for embryo development.': $i).
% 29.22/29.06  tff(decl_46367, type, incubate: $i).
% 29.22/29.06  tff(decl_46368, type, incubation: $i).
% 29.22/29.06  tff(decl_46369, type, incus_1: $i > $o).
% 29.22/29.06  tff(decl_46370, type, 'Incus': $i).
% 29.22/29.06  tff(decl_46371, type, 'The second of three bones in the middle ear of mammals; also called the anvil.': $i).
% 29.22/29.06  tff(decl_46372, type, incus: $i).
% 29.22/29.06  tff(decl_46373, type, jaw_1: $i > $o).
% 29.22/29.06  tff(decl_46374, type, malleus_1: $i > $o).
% 29.22/29.06  tff(decl_46375, type, stapes_1: $i > $o).
% 29.22/29.06  tff(decl_46376, type, independent_assortment_1: $i > $o).
% 29.22/29.06  tff(decl_46377, type, 'Independent-Assortment': $i).
% 29.22/29.06  tff(decl_46378, type, 'The random orientation of pairs of homologous chromosomes at metaphase of meiosis I resulting in the random sorting of chromosomes, independent of every other pair of chromosomes, into the daughter cells formed during meiosis.': $i).
% 29.22/29.06  tff(decl_46379, type, 'assortment of independent': $i).
% 29.22/29.06  tff(decl_46380, type, 'independent assortment': $i).
% 29.22/29.06  tff(decl_46381, type, 'independent-assortment': $i).
% 29.22/29.06  tff(decl_46382, type, fn_independent_assortment_1: $i > $i).
% 29.22/29.06  tff(decl_46383, type, fn_independent_assortment_2: $i > $i).
% 29.22/29.06  tff(decl_46384, type, fn_independent_assortment_3: $i > $i).
% 29.22/29.06  tff(decl_46385, type, fn_independent_assortment_4: $i > $i).
% 29.22/29.06  tff(decl_46386, type, fn_independent_assortment_5: $i > $i).
% 29.22/29.06  tff(decl_46387, type, fn_independent_assortment_6: $i > $i).
% 29.22/29.06  tff(decl_46388, type, fn_independent_assortment_7: $i > $i).
% 29.22/29.06  tff(decl_46389, type, fn_independent_assortment_8: $i > $i).
% 29.22/29.06  tff(decl_46390, type, fn_independent_assortment_9: $i > $i).
% 29.22/29.06  tff(decl_46391, type, fn_independent_assortment_10: $i > $i).
% 29.22/29.06  tff(decl_46392, type, fn_independent_assortment_11: $i > $i).
% 29.22/29.06  tff(decl_46393, type, fn_independent_assortment_12: $i > $i).
% 29.22/29.06  tff(decl_46394, type, fn_independent_assortment_13: $i > $i).
% 29.22/29.06  tff(decl_46395, type, fn_independent_assortment_14: $i > $i).
% 29.22/29.06  tff(decl_46396, type, fn_independent_assortment_15: $i > $i).
% 29.22/29.06  tff(decl_46397, type, fn_independent_assortment_16: $i > $i).
% 29.22/29.06  tff(decl_46398, type, fn_independent_assortment_17: $i > $i).
% 29.22/29.06  tff(decl_46399, type, fn_independent_assortment_18: $i > $i).
% 29.22/29.06  tff(decl_46400, type, fn_independent_assortment_19: $i > $i).
% 29.22/29.06  tff(decl_46401, type, fn_independent_assortment_20: $i > $i).
% 29.22/29.06  tff(decl_46402, type, fn_independent_assortment_21: $i > $i).
% 29.22/29.06  tff(decl_46403, type, fn_independent_assortment_22: $i > $i).
% 29.22/29.06  tff(decl_46404, type, fn_independent_assortment_23: $i > $i).
% 29.22/29.06  tff(decl_46405, type, fn_independent_assortment_24: $i > $i).
% 29.22/29.06  tff(decl_46406, type, fn_independent_assortment_25: $i > $i).
% 29.22/29.06  tff(decl_46407, type, fn_independent_assortment_26: $i > $i).
% 29.22/29.06  tff(decl_46408, type, fn_independent_assortment_27: $i > $i).
% 29.22/29.06  tff(decl_46409, type, fn_independent_assortment_28: $i > $i).
% 29.22/29.06  tff(decl_46410, type, fn_independent_assortment_29: $i > $i).
% 29.22/29.06  tff(decl_46411, type, fn_tetrad_1: $i > $i).
% 29.22/29.06  tff(decl_46412, type, fn_tetrad_2: $i > $i).
% 29.22/29.06  tff(decl_46413, type, independently_inherited_1: $i > $o).
% 29.22/29.06  tff(decl_46414, type, 'Independently-Inherited': $i).
% 29.22/29.06  tff(decl_46415, type, 'Referring to genes that are randomly distributed into the gametes resulting from meiosis (unless they are physically linked on the same chromosome).': $i).
% 29.22/29.06  tff(decl_46416, type, 'inherit independently': $i).
% 29.22/29.06  tff(decl_46417, type, 'independently inherited': $i).
% 29.22/29.06  tff(decl_46418, type, 'independently-inherited': $i).
% 29.22/29.06  tff(decl_46419, type, 'Indeterminate-Cleavage': $i).
% 29.22/29.06  tff(decl_46420, type, 'In early animal development, a type of cleavage in which cell fates are determined relatively late, and each cell retains the ability to develop into a complete embryo.  Occurs in deuterostomes.': $i).
% 29.22/29.06  tff(decl_46421, type, 'undergo indeterminate cleavage': $i).
% 29.22/29.06  tff(decl_46422, type, 'indeterminate cleavage': $i).
% 29.22/29.06  tff(decl_46423, type, 'indeterminate-cleavage': $i).
% 29.22/29.06  tff(decl_46424, type, 'Indeterminate-Growth': $i).
% 29.22/29.06  tff(decl_46425, type, 'Growth that continues throughout an organism\\s lifetime.': $i).
% 29.22/29.06  tff(decl_46426, type, 'indeterminate growth': $i).
% 29.22/29.06  tff(decl_46427, type, 'indeterminate-growth': $i).
% 29.22/29.06  tff(decl_46428, type, 'Indium': $i).
% 29.22/29.06  tff(decl_46429, type, 'Indium is a metal atom with atomic number 49. It is represented by the symbol In.': $i).
% 29.22/29.06  tff(decl_46430, type, indium: $i).
% 29.22/29.06  tff(decl_46431, type, fn_indium_3: $i > $i).
% 29.22/29.06  tff(decl_46432, type, fn_indium_4: $i > $i).
% 29.22/29.06  tff(decl_46433, type, fn_indium_5: $i > $i).
% 29.22/29.06  tff(decl_46434, type, fn_indium_8: $i > $i).
% 29.22/29.06  tff(decl_46435, type, fn_indium_9: $i > $i).
% 29.22/29.06  tff(decl_46436, type, fn_indium_10: $i > $i).
% 29.22/29.06  tff(decl_46437, type, fn_indium_11: $i > $i).
% 29.22/29.06  tff(decl_46438, type, "49": $i).
% 29.22/29.06  tff(decl_46439, type, "1.78": $i).
% 29.22/29.06  tff(decl_46440, type, "115": $i).
% 29.22/29.06  tff(decl_46441, type, "114.8": $i).
% 29.22/29.06  tff(decl_46442, type, fn_indium_7: $i > $i).
% 29.22/29.06  tff(decl_46443, type, fn_indium_12: $i > $i).
% 29.22/29.06  tff(decl_46444, type, fn_indium_6: $i > $i).
% 29.22/29.06  tff(decl_46445, type, 'Individualistic-Hypothesis': $i).
% 29.22/29.06  tff(decl_46446, type, 'The hypothesis that species found together are members of a community simply because they happen to have similar abiotic requirements.': $i).
% 29.22/29.06  tff(decl_46447, type, 'individualistic hypothesis': $i).
% 29.22/29.06  tff(decl_46448, type, 'individualistic-hypothesis': $i).
% 29.22/29.06  tff(decl_46449, type, 'Induced-Fit': $i).
% 29.22/29.06  tff(decl_46450, type, 'A modification of the shape of the active site of an enzyme so that it holds substrate molecules tightly. The shape change is induced when the substrate enters the enzyme\\s binding site.': $i).
% 29.22/29.06  tff(decl_46451, type, 'induced fit': $i).
% 29.22/29.06  tff(decl_46452, type, 'induced-fit': $i).
% 29.22/29.06  tff(decl_46453, type, fn_induced_fit_4: $i > $i).
% 29.22/29.06  tff(decl_46454, type, fn_induced_fit_5: $i > $i).
% 29.22/29.06  tff(decl_46455, type, fn_induced_fit_6: $i > $i).
% 29.22/29.06  tff(decl_46456, type, fn_induced_fit_7: $i > $i).
% 29.22/29.06  tff(decl_46457, type, fn_induced_fit_8: $i > $i).
% 29.22/29.06  tff(decl_46458, type, fn_induced_fit_9: $i > $i).
% 29.22/29.06  tff(decl_46459, type, fn_induced_fit_10: $i > $i).
% 29.22/29.06  tff(decl_46460, type, fn_induced_fit_11: $i > $i).
% 29.22/29.06  tff(decl_46461, type, fn_induced_fit_12: $i > $i).
% 29.22/29.06  tff(decl_46462, type, fn_induced_fit_13: $i > $i).
% 29.22/29.06  tff(decl_46463, type, fn_induced_fit_14: $i > $i).
% 29.22/29.06  tff(decl_46464, type, 'Inducer': $i).
% 29.22/29.06  tff(decl_46465, type, 'A specific small molecule that binds to a bacterial repressor protein and changes the repressor\\s shape so that it cannot bind to an operator, thus switching an operon on.': $i).
% 29.22/29.06  tff(decl_46466, type, 'inducible enzyme': $i).
% 29.22/29.06  tff(decl_46467, type, 'inducible protein': $i).
% 29.22/29.06  tff(decl_46468, type, 'inducer enzyme': $i).
% 29.22/29.06  tff(decl_46469, type, 'inducer protein': $i).
% 29.22/29.06  tff(decl_46470, type, inducer: $i).
% 29.22/29.06  tff(decl_46471, type, fn_inducer_1: $i > $i).
% 29.22/29.06  tff(decl_46472, type, fn_inducer_2: $i > $i).
% 29.22/29.06  tff(decl_46473, type, fn_inducer_3: $i > $i).
% 29.22/29.06  tff(decl_46474, type, fn_inducer_4: $i > $i).
% 29.22/29.06  tff(decl_46475, type, fn_inducer_5: $i > $i).
% 29.22/29.06  tff(decl_46476, type, fn_repressor_4: $i > $i).
% 29.22/29.06  tff(decl_46477, type, inducible_operon_1: $i > $o).
% 29.22/29.06  tff(decl_46478, type, 'Inducible-Operon': $i).
% 29.22/29.06  tff(decl_46479, type, 'A functioning unit of genomic material containing a cluster of genes under the control of a single regulatory signal or promoter.  The operon is usually turned off but can be stimulated when a specific, small molecule interacts with a regulatory protein.': $i).
% 29.22/29.06  tff(decl_46480, type, 'inducible operon': $i).
% 29.22/29.06  tff(decl_46481, type, 'inducible-operon': $i).
% 29.22/29.06  tff(decl_46482, type, repressible_operon_1: $i > $o).
% 29.22/29.06  tff(decl_46483, type, fn_inducible_operon_1: $i > $i).
% 29.22/29.06  tff(decl_46484, type, fn_inducible_operon_2: $i > $i).
% 29.22/29.06  tff(decl_46485, type, fn_inducible_operon_3: $i > $i).
% 29.22/29.06  tff(decl_46486, type, induction_1: $i > $o).
% 29.22/29.06  tff(decl_46487, type, 'Induction': $i).
% 29.22/29.06  tff(decl_46488, type, 'In early development, the process by which one group of cells influences the development of another nearby cell or group of cells, typically by influencing gene expression.': $i).
% 29.22/29.06  tff(decl_46489, type, induce: $i).
% 29.22/29.06  tff(decl_46490, type, induction: $i).
% 29.22/29.06  tff(decl_46491, type, inductive_reasoning_1: $i > $o).
% 29.22/29.06  tff(decl_46492, type, 'Inductive-Reasoning': $i).
% 29.22/29.06  tff(decl_46493, type, 'A type of logic in which generalizations are based on a large number of specific observations.': $i).
% 29.22/29.06  tff(decl_46494, type, 'inductive reasoning': $i).
% 29.22/29.06  tff(decl_46495, type, 'inductive-reasoning': $i).
% 29.22/29.06  tff(decl_46496, type, 'Inert-Atom': $i).
% 29.22/29.06  tff(decl_46497, type, 'Unreactive, stable atom with a full valence shell.': $i).
% 29.22/29.06  tff(decl_46498, type, 'noble gas': $i).
% 29.22/29.06  tff(decl_46499, type, 'inert atom': $i).
% 29.22/29.06  tff(decl_46500, type, 'inert-atom': $i).
% 29.22/29.06  tff(decl_46501, type, fn_inert_atom_1: $i > $i).
% 29.22/29.06  tff(decl_46502, type, infant_1: $i > $o).
% 29.22/29.06  tff(decl_46503, type, 'Infant': $i).
% 29.22/29.06  tff(decl_46504, type, 'Young offspring of a human or other mammal.': $i).
% 29.22/29.06  tff(decl_46505, type, infant: $i).
% 29.22/29.06  tff(decl_46506, type, fn_infant_1: $i > $i).
% 29.22/29.06  tff(decl_46507, type, 'Infected-Cell': $i).
% 29.22/29.06  tff(decl_46508, type, 'A cell that has been infected by a virus.': $i).
% 29.22/29.06  tff(decl_46509, type, 'infected cell': $i).
% 29.22/29.06  tff(decl_46510, type, 'infected-cell': $i).
% 29.22/29.06  tff(decl_46511, type, 'Infection': $i).
% 29.22/29.06  tff(decl_46512, type, 'The invasion of a host\\s body by pathogens or parasites.': $i).
% 29.22/29.06  tff(decl_46513, type, infection: $i).
% 29.22/29.06  tff(decl_46514, type, 'Infectious-Disease': $i).
% 29.22/29.06  tff(decl_46515, type, 'A disease caused by infectious agents (e.g., bacteria) that can be transmissible from one host to another.': $i).
% 29.22/29.06  tff(decl_46516, type, 'communicable disease': $i).
% 29.22/29.06  tff(decl_46517, type, 'communicable-disease': $i).
% 29.22/29.06  tff(decl_46518, type, 'contagious disease': $i).
% 29.22/29.06  tff(decl_46519, type, 'contagious-disease': $i).
% 29.22/29.06  tff(decl_46520, type, 'transmissible disease': $i).
% 29.22/29.06  tff(decl_46521, type, 'transmissible-disease': $i).
% 29.22/29.06  tff(decl_46522, type, 'infectious disease': $i).
% 29.22/29.06  tff(decl_46523, type, 'infectious-disease': $i).
% 29.22/29.06  tff(decl_46524, type, infectious_particle_1: $i > $o).
% 29.22/29.06  tff(decl_46525, type, 'Infectious-Particle': $i).
% 29.22/29.06  tff(decl_46526, type, 'A non-living entity, such as a virus, a prion, or a viroid, that is capable of causing infection.': $i).
% 29.22/29.06  tff(decl_46527, type, pathogen: $i).
% 29.22/29.06  tff(decl_46528, type, 'infectious particle': $i).
% 29.22/29.06  tff(decl_46529, type, 'infectious-particle': $i).
% 29.22/29.06  tff(decl_46530, type, fn_infectious_particle_1: $i > $i).
% 29.22/29.06  tff(decl_46531, type, fn_infectious_particle_2: $i > $i).
% 29.22/29.06  tff(decl_46532, type, fn_infectious_particle_3: $i > $i).
% 29.22/29.06  tff(decl_46533, type, inflammatory_response_1: $i > $o).
% 29.22/29.06  tff(decl_46534, type, 'Inflammatory-Response': $i).
% 29.22/29.06  tff(decl_46535, type, 'The innate immune response of the body to harmful stimuli such as physical injury or infection. The inflammatory response involves dilation of blood vessels in the affected area, the release of histamines, and mobilization of white blood cells to the site of injury.': $i).
% 29.22/29.06  tff(decl_46536, type, 'inflammatory response': $i).
% 29.22/29.06  tff(decl_46537, type, 'inflammatory-response': $i).
% 29.22/29.06  tff(decl_46538, type, inflorescence_1: $i > $o).
% 29.22/29.06  tff(decl_46539, type, 'Inflorescence': $i).
% 29.22/29.06  tff(decl_46540, type, 'A cluster of flowers on a shared stem.': $i).
% 29.22/29.06  tff(decl_46541, type, inflorescence: $i).
% 29.22/29.06  tff(decl_46542, type, influence_1: $i > $o).
% 29.22/29.06  tff(decl_46543, type, 'Influence': $i).
% 29.22/29.06  tff(decl_46544, type, 'Effect of one thing on another.': $i).
% 29.22/29.06  tff(decl_46545, type, influence: $i).
% 29.22/29.06  tff(decl_46546, type, 'Influenza': $i).
% 29.22/29.06  tff(decl_46547, type, 'An infectious respiratory disease caused by the influenza virus.': $i).
% 29.22/29.06  tff(decl_46548, type, flu: $i).
% 29.22/29.06  tff(decl_46549, type, influenza: $i).
% 29.22/29.06  tff(decl_46550, type, 'Influenza-virus': $i).
% 29.22/29.06  tff(decl_46551, type, 'An RNA virus that infects epithelial cells of the respiratory tract abd causes influenza.': $i).
% 29.22/29.06  tff(decl_46552, type, 'flu virus': $i).
% 29.22/29.06  tff(decl_46553, type, 'flu-virus': $i).
% 29.22/29.06  tff(decl_46554, type, 'virus of influenza': $i).
% 29.22/29.06  tff(decl_46555, type, 'influenza virus': $i).
% 29.22/29.06  tff(decl_46556, type, 'influenza-virus': $i).
% 29.22/29.06  tff(decl_46557, type, fn_influenza_virus_1: $i > $i).
% 29.22/29.06  tff(decl_46558, type, 'Information': $i).
% 29.22/29.06  tff(decl_46559, type, 'Knowledge communicated or received concerning a particular fact or circumstance. RHCD:1st Revised: 684.': $i).
% 29.22/29.06  tff(decl_46560, type, information: $i).
% 29.22/29.06  tff(decl_46561, type, info: $i).
% 29.22/29.06  tff(decl_46562, type, 'Information-Sequence': $i).
% 29.22/29.06  tff(decl_46563, type, 'A sequence which encodes information.  Biological examples are DNA, RNA, and the amino acid sequence of proteins (which determines folding).': $i).
% 29.22/29.06  tff(decl_46564, type, string: $i).
% 29.22/29.06  tff(decl_46565, type, 'sequence of information': $i).
% 29.22/29.06  tff(decl_46566, type, 'information sequence': $i).
% 29.22/29.06  tff(decl_46567, type, 'information-sequence': $i).
% 29.22/29.06  tff(decl_46568, type, 'Infrared-Rays': $i).
% 29.22/29.06  tff(decl_46569, type, 'Infrared-rays are the electromagnetic radiation with wavelenth ranging from 1000 nm to 1000000 nm. Their wavelength is shorter than that of Microwaves, but longer than Ultraviolet-rays': $i).
% 29.22/29.06  tff(decl_46570, type, 'infrared ray': $i).
% 29.22/29.06  tff(decl_46571, type, 'infrared-ray': $i).
% 29.22/29.06  tff(decl_46572, type, fn_infrared_rays_3: $i > $i).
% 29.22/29.06  tff(decl_46573, type, fn_infrared_rays_4: $i > $i).
% 29.22/29.06  tff(decl_46574, type, fn_infrared_rays_7: $i > $i).
% 29.22/29.06  tff(decl_46575, type, "750.0e0": $i).
% 29.22/29.06  tff(decl_46576, type, fn_infrared_rays_6: $i > $i).
% 29.22/29.06  tff(decl_46577, type, 'Ingestion': $i).
% 29.22/29.06  tff(decl_46578, type, 'The act of eating food; the first step in food processing.': $i).
% 29.22/29.06  tff(decl_46579, type, ingest: $i).
% 29.22/29.06  tff(decl_46580, type, ingestion: $i).
% 29.22/29.06  tff(decl_46581, type, fn_ingestion_2: $i > $i).
% 29.22/29.06  tff(decl_46582, type, 'Ingroup': $i).
% 29.22/29.06  tff(decl_46583, type, 'In phylogenetic studies, the group of taxa being analysed.': $i).
% 29.22/29.06  tff(decl_46584, type, ingroup: $i).
% 29.22/29.06  tff(decl_46585, type, 'Inheritance': $i).
% 29.22/29.06  tff(decl_46586, type, 'The process by which offspring acquire or become predisposed to characteristics of their parent(s).': $i).
% 29.22/29.06  tff(decl_46587, type, heredity: $i).
% 29.22/29.06  tff(decl_46588, type, inheritance: $i).
% 29.22/29.06  tff(decl_46589, type, fn_inheritance_2: $i > $i).
% 29.22/29.06  tff(decl_46590, type, fn_inheritance_5: $i > $i).
% 29.22/29.06  tff(decl_46591, type, inheritance_of_extranuclear_genes_1: $i > $o).
% 29.22/29.06  tff(decl_46592, type, fn_inheritance_of_extranuclear_genes_4: $i > $i).
% 29.22/29.06  tff(decl_46593, type, 'Inheritance-Of-Extranuclear-Genes': $i).
% 29.22/29.06  tff(decl_46594, type, 'Inheritance for extranuclear genes, such as those in mitochondria or a plant\\s plastids.': $i).
% 29.22/29.06  tff(decl_46595, type, 'inheritance of extranuclear gene': $i).
% 29.22/29.06  tff(decl_46596, type, 'inheritance-of-extranuclear-gene': $i).
% 29.22/29.06  tff(decl_46597, type, fn_inheritance_of_extranuclear_genes_2: $i > $i).
% 29.22/29.06  tff(decl_46598, type, fn_inheritance_of_extranuclear_genes_3: $i > $i).
% 29.22/29.06  tff(decl_46599, type, 'Inhibin': $i).
% 29.22/29.06  tff(decl_46600, type, 'A peptide hormone secreted by the ovaries and testis that inhibits production of follicle stimulating hormone (FSH) by the anterior pituitary.': $i).
% 29.22/29.06  tff(decl_46601, type, inhibin: $i).
% 29.22/29.06  tff(decl_46602, type, 'Inhibition': $i).
% 29.22/29.06  tff(decl_46603, type, 'The process in which a chemical or entity decreases the activity of a reaction or organism.': $i).
% 29.22/29.06  tff(decl_46604, type, inhibition: $i).
% 29.22/29.06  tff(decl_46605, type, 'Inhibition-Of-Transport-Protein': $i).
% 29.22/29.06  tff(decl_46606, type, 'The transport proteins can be inhibited by molecules that resemble the normal substrate. This occurs when the imposter competes with the normally transported solute by binding to the transport protein.': $i).
% 29.22/29.06  tff(decl_46607, type, 'inhibition of transport protein': $i).
% 29.22/29.06  tff(decl_46608, type, 'inhibition-of-transport-protein': $i).
% 29.22/29.06  tff(decl_46609, type, fn_inhibition_of_transport_protein_1: $i > $i).
% 29.22/29.06  tff(decl_46610, type, fn_inhibition_of_transport_protein_2: $i > $i).
% 29.22/29.06  tff(decl_46611, type, fn_inhibition_of_transport_protein_3: $i > $i).
% 29.22/29.06  tff(decl_46612, type, fn_inhibition_of_transport_protein_4: $i > $i).
% 29.22/29.06  tff(decl_46613, type, fn_inhibition_of_transport_protein_5: $i > $i).
% 29.22/29.06  tff(decl_46614, type, fn_inhibition_of_transport_protein_6: $i > $i).
% 29.22/29.06  tff(decl_46615, type, fn_inhibition_of_transport_protein_7: $i > $i).
% 29.22/29.06  tff(decl_46616, type, fn_inhibition_of_transport_protein_8: $i > $i).
% 29.22/29.06  tff(decl_46617, type, fn_inhibition_of_transport_protein_9: $i > $i).
% 29.22/29.06  tff(decl_46618, type, fn_inhibitor_1: $i > $i).
% 29.22/29.06  tff(decl_46619, type, 'Inhibitor': $i).
% 29.22/29.06  tff(decl_46620, type, 'A substance that reduces or suppresses the activity of another substance.': $i).
% 29.22/29.06  tff(decl_46621, type, inhibitor: $i).
% 29.22/29.06  tff(decl_46622, type, 'Initial-Meristem': $i).
% 29.22/29.06  tff(decl_46623, type, 'A type of cell in the meristem of plants that is continually dividing, producing new cells for plant growth.': $i).
% 29.22/29.06  tff(decl_46624, type, 'meristem of initial': $i).
% 29.22/29.06  tff(decl_46625, type, 'initial meristem': $i).
% 29.22/29.06  tff(decl_46626, type, 'initial-meristem': $i).
% 29.22/29.06  tff(decl_46627, type, initiate_1: $i > $o).
% 29.22/29.06  tff(decl_46628, type, 'Initiate': $i).
% 29.22/29.06  tff(decl_46629, type, 'Cause a process or action to begin.': $i).
% 29.22/29.06  tff(decl_46630, type, initiation_1: $i > $o).
% 29.22/29.06  tff(decl_46631, type, 'Initiation': $i).
% 29.22/29.06  tff(decl_46632, type, 'The starting phase of a cellular process.': $i).
% 29.22/29.06  tff(decl_46633, type, initiation: $i).
% 29.22/29.06  tff(decl_46634, type, initiation_factor_1: $i > $o).
% 29.22/29.06  tff(decl_46635, type, 'Initiation-Factor': $i).
% 29.22/29.06  tff(decl_46636, type, 'Initiation-factors are the proteins involved in the initiation phase of a translation process (Synthesis of polypeptide). Initiation-factors are required to form the translation-initiation-complex': $i).
% 29.22/29.06  tff(decl_46637, type, if: $i).
% 29.22/29.06  tff(decl_46638, type, 'factor of initiation': $i).
% 29.22/29.06  tff(decl_46639, type, 'initiation factor': $i).
% 29.22/29.06  tff(decl_46640, type, 'initiation-factor': $i).
% 29.22/29.06  tff(decl_46641, type, fn_initiation_factor_1: $i > $i).
% 29.22/29.06  tff(decl_46642, type, 'Initiator-tRNA': $i).
% 29.22/29.06  tff(decl_46643, type, 'Initiator-tRNA is a tRNA which carries the first amino acid \\Methionine\\ to the Initiation (Start) codon for attachment': $i).
% 29.22/29.06  tff(decl_46644, type, 'initiator trna': $i).
% 29.22/29.06  tff(decl_46645, type, 'initiator-trna': $i).
% 29.22/29.06  tff(decl_46646, type, 'trna of initiator': $i).
% 29.22/29.06  tff(decl_46647, type, 'Inject': $i).
% 29.22/29.06  tff(decl_46648, type, 'To introduce a substance, usually a fluid, into a cell or organism through the use of a sharp pointed object, such as a syringe or insect mouth part adapted for this purpose.': $i).
% 29.22/29.06  tff(decl_46649, type, 'shoot in': $i).
% 29.22/29.06  tff(decl_46650, type, 'shoot-in': $i).
% 29.22/29.06  tff(decl_46651, type, inject: $i).
% 29.22/29.06  tff(decl_46652, type, penetrate_1: $i > $o).
% 29.22/29.06  tff(decl_46653, type, fn_inject_dna_with_needle_2: $i > $i).
% 29.22/29.06  tff(decl_46654, type, fn_inject_dna_with_needle_5: $i > $i).
% 29.22/29.06  tff(decl_46655, type, 'Inject-DNA-With-Needle': $i).
% 29.22/29.06  tff(decl_46656, type, 'Introducing DNA into a cell with a syringe.': $i).
% 29.22/29.06  tff(decl_46657, type, 'nuclear transplantation': $i).
% 29.22/29.06  tff(decl_46658, type, 'inject dna with needle': $i).
% 29.22/29.06  tff(decl_46659, type, 'inject-dna-with-needle': $i).
% 29.22/29.06  tff(decl_46660, type, fn_inject_dna_with_needle_3: $i > $i).
% 29.22/29.06  tff(decl_46661, type, needle_0: $i).
% 29.22/29.06  tff(decl_46662, type, 'Innate-Behavior': $i).
% 29.22/29.06  tff(decl_46663, type, 'In animals, behavior that is developmentally fixed and strongly controlled by genetics. Innate behaviors occur the same way in all individuals in a population, despite differences in environment and upbringing.': $i).
% 29.22/29.06  tff(decl_46664, type, instinct: $i).
% 29.22/29.06  tff(decl_46665, type, 'instinctive behavior': $i).
% 29.22/29.06  tff(decl_46666, type, 'instinctive-behavior': $i).
% 29.22/29.06  tff(decl_46667, type, 'innate behavior': $i).
% 29.22/29.06  tff(decl_46668, type, 'innate-behavior': $i).
% 29.22/29.06  tff(decl_46669, type, inner_cell_mass_1: $i > $o).
% 29.22/29.06  tff(decl_46670, type, 'Inner-Cell-Mass': $i).
% 29.22/29.06  tff(decl_46671, type, 'Mass of cells inside the early embryo of mammals, that will eventually develop into the tissues of the embryo itself and some of the extraembryonic membranes.': $i).
% 29.22/29.06  tff(decl_46672, type, 'inner cell mass': $i).
% 29.22/29.06  tff(decl_46673, type, 'inner-cell-mass': $i).
% 29.22/29.06  tff(decl_46674, type, 'Inner-Ear': $i).
% 29.22/29.06  tff(decl_46675, type, 'The innermost part of the vertebrate ear, responsible mainly for balance and sound detection. It contains the cochlea and the semicircular canals.': $i).
% 29.22/29.06  tff(decl_46676, type, 'inner ear': $i).
% 29.22/29.06  tff(decl_46677, type, 'inner-ear': $i).
% 29.22/29.06  tff(decl_46678, type, 'Inner-Membrane': $i).
% 29.22/29.06  tff(decl_46679, type, 'The inner enclosing layer of a double phospholipid-bilayer membrane. The inner membrane is comprised of a phospholipid bilayer.': $i).
% 29.22/29.06  tff(decl_46680, type, 'inner membrane': $i).
% 29.22/29.06  tff(decl_46681, type, 'inner-membrane': $i).
% 29.22/29.06  tff(decl_46682, type, 'Inner-Vulva': $i).
% 29.22/29.06  tff(decl_46683, type, 'Inner vulva is part of a vulva.': $i).
% 29.22/29.06  tff(decl_46684, type, 'inner vulva': $i).
% 29.22/29.06  tff(decl_46685, type, 'inner-vulva': $i).
% 29.22/29.06  tff(decl_46686, type, innovation_1: $i > $o).
% 29.22/29.06  tff(decl_46687, type, 'Innovation': $i).
% 29.22/29.06  tff(decl_46688, type, invention: $i).
% 29.22/29.06  tff(decl_46689, type, creation: $i).
% 29.22/29.06  tff(decl_46690, type, innovation: $i).
% 29.22/29.06  tff(decl_46691, type, innovate: $i).
% 29.22/29.06  tff(decl_46692, type, 'Inorganic-Acid': $i).
% 29.22/29.06  tff(decl_46693, type, 'A mineral acid derived from one or more inorganic compounds.': $i).
% 29.22/29.06  tff(decl_46694, type, 'mineral acid': $i).
% 29.22/29.06  tff(decl_46695, type, 'mineral-acid': $i).
% 29.22/29.06  tff(decl_46696, type, 'inorganic acid': $i).
% 29.22/29.06  tff(decl_46697, type, 'inorganic-acid': $i).
% 29.22/29.06  tff(decl_46698, type, 'Inorganic-Ion': $i).
% 29.22/29.06  tff(decl_46699, type, 'Inorganic ions are ions necessary for vital cellular activity in animals and plants': $i).
% 29.22/29.06  tff(decl_46700, type, 'inorganic ion': $i).
% 29.22/29.06  tff(decl_46701, type, 'inorganic-ion': $i).
% 29.22/29.06  tff(decl_46702, type, 'Inorganic-Molecule': $i).
% 29.22/29.06  tff(decl_46703, type, 'Molecule that is not organic': $i).
% 29.22/29.06  tff(decl_46704, type, 'A molecule which does not contain carbon.': $i).
% 29.22/29.06  tff(decl_46705, type, 'inorganic molecule': $i).
% 29.22/29.06  tff(decl_46706, type, 'inorganic-molecule': $i).
% 29.22/29.06  tff(decl_46707, type, inorganic_molecule_substance_1: $i > $o).
% 29.22/29.06  tff(decl_46708, type, 'Inorganic-Molecule-Substance': $i).
% 29.22/29.06  tff(decl_46709, type, 'inorganic molecule substance': $i).
% 29.22/29.06  tff(decl_46710, type, 'inorganic-molecule-substance': $i).
% 29.22/29.06  tff(decl_46711, type, molecule_substance_1: $i > $o).
% 29.22/29.06  tff(decl_46712, type, fn_inorganic_molecule_substance_1: $i > $i).
% 29.22/29.06  tff(decl_46713, type, fn_molecule_substance_1: $i > $i).
% 29.22/29.06  tff(decl_46714, type, 'Inorganic-Phosphate': $i).
% 29.22/29.06  tff(decl_46715, type, 'Inorganic phosphate is an ionic ester of phoshoric acid which contains no carbon atoms. It plays many important roles in cellular biology.': $i).
% 29.22/29.06  tff(decl_46716, type, 'inorganic phosphate': $i).
% 29.22/29.06  tff(decl_46717, type, 'inorganic-phosphate': $i).
% 29.22/29.06  tff(decl_46718, type, 'inorganic phosphate ion': $i).
% 29.22/29.06  tff(decl_46719, type, 'hopo32-': $i).
% 29.22/29.06  tff(decl_46720, type, fn_inorganic_phosphate_1: $i > $i).
% 29.22/29.06  tff(decl_46721, type, fn_inorganic_phosphate_2: $i > $i).
% 29.22/29.06  tff(decl_46722, type, fn_inorganic_phosphate_3: $i > $i).
% 29.22/29.06  tff(decl_46723, type, fn_inorganic_phosphate_5: $i > $i).
% 29.22/29.06  tff(decl_46724, type, "-2.0e0": $i).
% 29.22/29.06  tff(decl_46725, type, fn_inorganic_phosphate_4: $i > $i).
% 29.22/29.06  tff(decl_46726, type, inosine_1: $i > $o).
% 29.22/29.06  tff(decl_46727, type, 'Inosine': $i).
% 29.22/29.06  tff(decl_46728, type, 'Inosine is a nucleoside that is formed when hypoxanthine is attached to a ribose ring (also known as a ribofuranose) via a ?-N9-glycosidic bond.': $i).
% 29.22/29.06  tff(decl_46729, type, inosine: $i).
% 29.22/29.06  tff(decl_46730, type, fn_inosine_1: $i > $i).
% 29.22/29.06  tff(decl_46731, type, 'Inositol-Trisphosphate': $i).
% 29.22/29.06  tff(decl_46732, type, 'Abbreviated IP3; functions as a second messenger in signal transduction. IP3 binds to receptors in the endoplasmic reticulum (ER) and opens channels, allowing calcium ions to flow into the cytoplasm.': $i).
% 29.22/29.06  tff(decl_46733, type, 'inositol triphosphate': $i).
% 29.22/29.06  tff(decl_46734, type, ip3: $i).
% 29.22/29.06  tff(decl_46735, type, 'inositol 145 trisphosphate,': $i).
% 29.22/29.06  tff(decl_46736, type, 'inositol-145-trisphosphate,': $i).
% 29.22/29.06  tff(decl_46737, type, 'triphosphoinositol,': $i).
% 29.22/29.06  tff(decl_46738, type, 'insp3,': $i).
% 29.22/29.06  tff(decl_46739, type, 'inositol 145 trisphosphate': $i).
% 29.22/29.06  tff(decl_46740, type, 'inositol-145-trisphosphate': $i).
% 29.22/29.06  tff(decl_46741, type, triphosphoinositol: $i).
% 29.22/29.06  tff(decl_46742, type, insp3: $i).
% 29.22/29.06  tff(decl_46743, type, 'inositol trisphosphate': $i).
% 29.22/29.06  tff(decl_46744, type, 'inositol-trisphosphate': $i).
% 29.22/29.06  tff(decl_46745, type, fn_inositol_trisphosphate_1: $i > $i).
% 29.22/29.06  tff(decl_46746, type, fn_inositol_trisphosphate_2: $i > $i).
% 29.22/29.06  tff(decl_46747, type, fn_inositol_trisphosphate_3: $i > $i).
% 29.22/29.06  tff(decl_46748, type, fn_inositol_trisphosphate_4: $i > $i).
% 29.22/29.06  tff(decl_46749, type, fn_inositol_trisphosphate_5: $i > $i).
% 29.22/29.06  tff(decl_46750, type, fn_inositol_trisphosphate_6: $i > $i).
% 29.22/29.06  tff(decl_46751, type, fn_inositol_trisphosphate_7: $i > $i).
% 29.22/29.06  tff(decl_46752, type, fn_inositol_trisphosphate_8: $i > $i).
% 29.22/29.06  tff(decl_46753, type, fn_inositol_trisphosphate_9: $i > $i).
% 29.22/29.06  tff(decl_46754, type, fn_inositol_trisphosphate_10: $i > $i).
% 29.22/29.06  tff(decl_46755, type, fn_inositol_trisphosphate_11: $i > $i).
% 29.22/29.06  tff(decl_46756, type, fn_inositol_trisphosphate_12: $i > $i).
% 29.22/29.06  tff(decl_46757, type, fn_inositol_trisphosphate_13: $i > $i).
% 29.22/29.06  tff(decl_46758, type, fn_inositol_trisphosphate_14: $i > $i).
% 29.22/29.06  tff(decl_46759, type, fn_inositol_trisphosphate_15: $i > $i).
% 29.22/29.06  tff(decl_46760, type, inquire_1: $i > $o).
% 29.22/29.06  tff(decl_46761, type, 'Inquire': $i).
% 29.22/29.06  tff(decl_46762, type, ask: $i).
% 29.22/29.06  tff(decl_46763, type, enquire: $i).
% 29.22/29.06  tff(decl_46764, type, fn_inquire_1: $i > $i).
% 29.22/29.06  tff(decl_46765, type, question_1: $i > $o).
% 29.22/29.06  tff(decl_46766, type, fn_inquire_2: $i > $i).
% 29.22/29.06  tff(decl_46767, type, fn_inquire_3: $i > $i).
% 29.22/29.06  tff(decl_46768, type, 'Inquiry': $i).
% 29.22/29.06  tff(decl_46769, type, 'The search for information and explanation, often focused by specific questions.': $i).
% 29.22/29.06  tff(decl_46770, type, inquiry: $i).
% 29.22/29.06  tff(decl_46771, type, 'Insect': $i).
% 29.22/29.06  tff(decl_46772, type, 'One of a subset of primarily terrestrial arthropods characterized by three body segments (head, thorax, and abdomen) and wings for flight.': $i).
% 29.22/29.06  tff(decl_46773, type, insect: $i).
% 29.22/29.06  tff(decl_46774, type, fn_insect_2: $i > $i).
% 29.22/29.06  tff(decl_46775, type, fn_insect_8: $i > $i).
% 29.22/29.06  tff(decl_46776, type, fn_insect_10: $i > $i).
% 29.22/29.06  tff(decl_46777, type, fn_insect_24: $i > $i).
% 29.22/29.06  tff(decl_46778, type, anatomical_appendage_0: $i).
% 29.22/29.06  tff(decl_46779, type, 'Insect-Homeotic-Gene': $i).
% 29.22/29.06  tff(decl_46780, type, 'Homeotic gene present in insects.': $i).
% 29.22/29.06  tff(decl_46781, type, 'insect homeotic gene': $i).
% 29.22/29.06  tff(decl_46782, type, 'insect-homeotic-gene': $i).
% 29.22/29.06  tff(decl_46783, type, fn_insect_homeotic_gene_1: $i > $i).
% 29.22/29.06  tff(decl_46784, type, fn_insect_homeotic_gene_2: $i > $i).
% 29.22/29.06  tff(decl_46785, type, fn_insect_homeotic_gene_3: $i > $i).
% 29.22/29.06  tff(decl_46786, type, fn_insect_homeotic_gene_4: $i > $i).
% 29.22/29.06  tff(decl_46787, type, fn_insect_homeotic_gene_5: $i > $i).
% 29.22/29.06  tff(decl_46788, type, fn_insect_homeotic_gene_6: $i > $i).
% 29.22/29.06  tff(decl_46789, type, fn_insect_homeotic_gene_7: $i > $i).
% 29.22/29.06  tff(decl_46790, type, fn_insect_homeotic_gene_8: $i > $i).
% 29.22/29.06  tff(decl_46791, type, fn_insect_homeotic_gene_9: $i > $i).
% 29.22/29.06  tff(decl_46792, type, fn_insect_homeotic_gene_10: $i > $i).
% 29.22/29.06  tff(decl_46793, type, fn_insect_homeotic_gene_11: $i > $i).
% 29.22/29.06  tff(decl_46794, type, fn_insect_homeotic_gene_12: $i > $i).
% 29.22/29.06  tff(decl_46795, type, fn_insect_homeotic_gene_13: $i > $i).
% 29.22/29.06  tff(decl_46796, type, fn_insect_homeotic_gene_14: $i > $i).
% 29.22/29.06  tff(decl_46797, type, fn_insect_homeotic_gene_15: $i > $i).
% 29.22/29.06  tff(decl_46798, type, fn_insect_homeotic_gene_16: $i > $i).
% 29.22/29.06  tff(decl_46799, type, fn_insect_homeotic_gene_17: $i > $i).
% 29.22/29.06  tff(decl_46800, type, fn_insect_homeotic_gene_18: $i > $i).
% 29.22/29.06  tff(decl_46801, type, fn_insect_homeotic_gene_19: $i > $i).
% 29.22/29.06  tff(decl_46802, type, fn_insect_homeotic_gene_20: $i > $i).
% 29.22/29.06  tff(decl_46803, type, fn_insect_homeotic_gene_21: $i > $i).
% 29.22/29.06  tff(decl_46804, type, fn_insect_homeotic_gene_22: $i > $i).
% 29.22/29.06  tff(decl_46805, type, fn_insect_homeotic_gene_23: $i > $i).
% 29.22/29.06  tff(decl_46806, type, fn_insect_homeotic_gene_24: $i > $i).
% 29.22/29.06  tff(decl_46807, type, fn_insect_homeotic_gene_25: $i > $i).
% 29.22/29.06  tff(decl_46808, type, fn_insect_homeotic_gene_26: $i > $i).
% 29.22/29.06  tff(decl_46809, type, fn_insect_homeotic_gene_31: $i > $i).
% 29.22/29.06  tff(decl_46810, type, fn_insect_homeotic_gene_32: $i > $i).
% 29.22/29.06  tff(decl_46811, type, fn_insect_homeotic_gene_28: $i > $i).
% 29.22/29.06  tff(decl_46812, type, fn_master_control_gene_1: $i > $i).
% 29.22/29.06  tff(decl_46813, type, fn_insect_homeotic_gene_27: $i > $i).
% 29.22/29.06  tff(decl_46814, type, fn_master_control_gene_22: $i > $i).
% 29.22/29.06  tff(decl_46815, type, fn_insect_homeotic_gene_29: $i > $i).
% 29.22/29.06  tff(decl_46816, type, fn_master_control_gene_2: $i > $i).
% 29.22/29.06  tff(decl_46817, type, fn_insect_homeotic_gene_30: $i > $i).
% 29.22/29.06  tff(decl_46818, type, fn_master_control_gene_23: $i > $i).
% 29.22/29.06  tff(decl_46819, type, fn_master_control_gene_18: $i > $i).
% 29.22/29.06  tff(decl_46820, type, fn_master_control_gene_20: $i > $i).
% 29.22/29.06  tff(decl_46821, type, fn_master_control_gene_19: $i > $i).
% 29.22/29.06  tff(decl_46822, type, fn_master_control_gene_16: $i > $i).
% 29.22/29.06  tff(decl_46823, type, fn_master_control_gene_15: $i > $i).
% 29.22/29.06  tff(decl_46824, type, fn_master_control_gene_12: $i > $i).
% 29.22/29.06  tff(decl_46825, type, fn_master_control_gene_6: $i > $i).
% 29.22/29.06  tff(decl_46826, type, fn_master_control_gene_5: $i > $i).
% 29.22/29.06  tff(decl_46827, type, fn_master_control_gene_13: $i > $i).
% 29.22/29.06  tff(decl_46828, type, fn_master_control_gene_17: $i > $i).
% 29.22/29.06  tff(decl_46829, type, fn_master_control_gene_21: $i > $i).
% 29.22/29.06  tff(decl_46830, type, fn_master_control_gene_14: $i > $i).
% 29.22/29.06  tff(decl_46831, type, fn_master_control_gene_8: $i > $i).
% 29.22/29.06  tff(decl_46832, type, 'Insecticide': $i).
% 29.22/29.06  tff(decl_46833, type, 'A chemical used to kill insects.': $i).
% 29.22/29.06  tff(decl_46834, type, insecticide: $i).
% 29.22/29.06  tff(decl_46835, type, pesticide_1: $i > $o).
% 29.22/29.06  tff(decl_46836, type, 'Insectivora': $i).
% 29.22/29.06  tff(decl_46837, type, 'A polyphyletic grouping of mammals that eat primarily insects. Includes hedgehogs, shrews, and moles.': $i).
% 29.22/29.06  tff(decl_46838, type, insectivora: $i).
% 29.22/29.06  tff(decl_46839, type, insertion_1: $i > $o).
% 29.22/29.06  tff(decl_46840, type, 'Insertion': $i).
% 29.22/29.06  tff(decl_46841, type, 'A type of mutation involving the addition of at least one nucleotide base pair into a DNA sequence.': $i).
% 29.22/29.06  tff(decl_46842, type, insertion: $i).
% 29.22/29.06  tff(decl_46843, type, 'Insertion-Sequences': $i).
% 29.22/29.06  tff(decl_46844, type, 'The simplest kind of transposon, consisting of inverted repeats of DNA flanking a gene for transposase, the enzyme that catalyzes transposition.': $i).
% 29.22/29.06  tff(decl_46845, type, 'insertion sequence': $i).
% 29.22/29.06  tff(decl_46846, type, 'insertion-sequence': $i).
% 29.22/29.06  tff(decl_46847, type, 'insertion sequences': $i).
% 29.22/29.06  tff(decl_46848, type, fn_insertion_sequences_1: $i > $i).
% 29.22/29.06  tff(decl_46849, type, mutagen_1: $i > $o).
% 29.22/29.06  tff(decl_46850, type, fn_insertion_sequences_2: $i > $i).
% 29.22/29.06  tff(decl_46851, type, fn_insertion_sequences_3: $i > $i).
% 29.22/29.06  tff(decl_46852, type, 'Inside-Face': $i).
% 29.22/29.06  tff(decl_46853, type, 'The region inside an entity is called as its inside face.': $i).
% 29.22/29.06  tff(decl_46854, type, 'interior side': $i).
% 29.22/29.06  tff(decl_46855, type, 'interior-side': $i).
% 29.22/29.06  tff(decl_46856, type, 'face of inside': $i).
% 29.22/29.06  tff(decl_46857, type, 'inside face': $i).
% 29.22/29.06  tff(decl_46858, type, 'inside-face': $i).
% 29.22/29.06  tff(decl_46859, type, 'Institution': $i).
% 29.22/29.06  tff(decl_46860, type, 'a work organization': $i).
% 29.22/29.06  tff(decl_46861, type, establishment: $i).
% 29.22/29.06  tff(decl_46862, type, institution: $i).
% 29.22/29.06  tff(decl_46863, type, instruction_1: $i > $o).
% 29.22/29.06  tff(decl_46864, type, 'Instruction': $i).
% 29.22/29.06  tff(decl_46865, type, statement: $i).
% 29.22/29.06  tff(decl_46866, type, 'program line': $i).
% 29.22/29.06  tff(decl_46867, type, program_line: $i).
% 29.22/29.06  tff(decl_46868, type, instruction: $i).
% 29.22/29.06  tff(decl_46869, type, fn_instruction_1: $i > $i).
% 29.22/29.06  tff(decl_46870, type, 'Instrument-Role': $i).
% 29.22/29.06  tff(decl_46871, type, pawn: $i).
% 29.22/29.06  tff(decl_46872, type, 'role of instrument': $i).
% 29.22/29.06  tff(decl_46873, type, 'instrument role': $i).
% 29.22/29.06  tff(decl_46874, type, 'instrument-role': $i).
% 29.22/29.06  tff(decl_46875, type, 'Insulator': $i).
% 29.22/29.06  tff(decl_46876, type, 'An insulator resists the flow of heat.': $i).
% 29.22/29.06  tff(decl_46877, type, insulator: $i).
% 29.22/29.06  tff(decl_46878, type, fn_insulator_2: $i > $i).
% 29.22/29.06  tff(decl_46879, type, 'Insulin': $i).
% 29.22/29.06  tff(decl_46880, type, 'A peptide hormone produced and secreted by beta cells in the pancreas. Insulin promotes the uptake of glucose by cells and thus lowers blood glucose levels. It also stimulates the production of glycogen in the liver.': $i).
% 29.22/29.06  tff(decl_46881, type, insulin: $i).
% 29.22/29.06  tff(decl_46882, type, 'Intangible-Entity': $i).
% 29.22/29.06  tff(decl_46883, type, 'entity of intangible': $i).
% 29.22/29.06  tff(decl_46884, type, 'intangible entity': $i).
% 29.22/29.06  tff(decl_46885, type, 'intangible-entity': $i).
% 29.22/29.06  tff(decl_46886, type, integer_1: $i > $o).
% 29.22/29.06  tff(decl_46887, type, 'Integer': $i).
% 29.22/29.06  tff(decl_46888, type, number_1: $i > $o).
% 29.22/29.06  tff(decl_46889, type, 'Integral-Protein': $i).
% 29.22/29.06  tff(decl_46890, type, 'An integral membrane protein (IMP) is a protein molecule (or assembly of proteins) that is attached to the biological membrane. Such proteins can be separated from the biological membranes only using detergents, nonpolar solvents, or sometimes denaturing agents.': $i).
% 29.22/29.06  tff(decl_46891, type, 'protein of integral': $i).
% 29.22/29.06  tff(decl_46892, type, 'integral protein': $i).
% 29.22/29.06  tff(decl_46893, type, 'integral-protein': $i).
% 29.22/29.06  tff(decl_46894, type, fn_integral_protein_2: $i > $i).
% 29.22/29.06  tff(decl_46895, type, fn_integral_protein_3: $i > $i).
% 29.22/29.06  tff(decl_46896, type, fn_integral_protein_4: $i > $i).
% 29.22/29.06  tff(decl_46897, type, fn_integral_protein_22: $i > $i).
% 29.22/29.06  tff(decl_46898, type, fn_integral_protein_26: $i > $i).
% 29.22/29.06  tff(decl_46899, type, 'Integrin': $i).
% 29.22/29.06  tff(decl_46900, type, 'A transmembrane receptor protein that connects a cell\\s cytoskeleton with the extracellular matrix.': $i).
% 29.22/29.06  tff(decl_46901, type, integrin: $i).
% 29.22/29.06  tff(decl_46902, type, fn_integrin_1: $i > $i).
% 29.22/29.06  tff(decl_46903, type, fn_integrin_3: $i > $i).
% 29.22/29.06  tff(decl_46904, type, fn_integrin_4: $i > $i).
% 29.22/29.06  tff(decl_46905, type, fn_integrin_15: $i > $i).
% 29.22/29.06  tff(decl_46906, type, fn_integrin_16: $i > $i).
% 29.22/29.06  tff(decl_46907, type, fn_integrin_17: $i > $i).
% 29.22/29.06  tff(decl_46908, type, fn_integrin_18: $i > $i).
% 29.22/29.06  tff(decl_46909, type, fn_integrin_19: $i > $i).
% 29.22/29.06  tff(decl_46910, type, fn_integrin_20: $i > $i).
% 29.22/29.06  tff(decl_46911, type, fn_integrin_21: $i > $i).
% 29.22/29.06  tff(decl_46912, type, fn_integrin_22: $i > $i).
% 29.22/29.06  tff(decl_46913, type, fn_integrin_23: $i > $i).
% 29.22/29.06  tff(decl_46914, type, fn_integrin_24: $i > $i).
% 29.22/29.06  tff(decl_46915, type, fn_integrin_25: $i > $i).
% 29.22/29.06  tff(decl_46916, type, fn_integrin_26: $i > $i).
% 29.22/29.06  tff(decl_46917, type, fn_integrin_27: $i > $i).
% 29.22/29.06  tff(decl_46918, type, fn_integrin_28: $i > $i).
% 29.22/29.06  tff(decl_46919, type, fn_integrin_31: $i > $i).
% 29.22/29.06  tff(decl_46920, type, fn_integrin_32: $i > $i).
% 29.22/29.06  tff(decl_46921, type, fn_integrin_33: $i > $i).
% 29.22/29.06  tff(decl_46922, type, fn_integrin_34: $i > $i).
% 29.22/29.06  tff(decl_46923, type, fn_integrin_35: $i > $i).
% 29.22/29.06  tff(decl_46924, type, fn_integrin_37: $i > $i).
% 29.22/29.06  tff(decl_46925, type, fn_integrin_38: $i > $i).
% 29.22/29.06  tff(decl_46926, type, fn_integrin_40: $i > $i).
% 29.22/29.06  tff(decl_46927, type, fn_integrin_41: $i > $i).
% 29.22/29.06  tff(decl_46928, type, fn_plasma_membrane_53: $i > $i).
% 29.22/29.06  tff(decl_46929, type, fn_integrin_14: $i > $i).
% 29.22/29.06  tff(decl_46930, type, fn_integrin_13: $i > $i).
% 29.22/29.06  tff(decl_46931, type, fn_integrin_12: $i > $i).
% 29.22/29.06  tff(decl_46932, type, fn_integrin_11: $i > $i).
% 29.22/29.06  tff(decl_46933, type, 'Integrity-Constant': $i).
% 29.22/29.06  tff(decl_46934, type, 'constant of integrity': $i).
% 29.22/29.06  tff(decl_46935, type, 'integrity constant': $i).
% 29.22/29.06  tff(decl_46936, type, 'integrity-constant': $i).
% 29.22/29.06  tff(decl_46937, type, integrity_scale_1: $i > $o).
% 29.22/29.06  tff(decl_46938, type, 'Integrity-Scale': $i).
% 29.22/29.06  tff(decl_46939, type, 'scale of integrity': $i).
% 29.22/29.06  tff(decl_46940, type, 'integrity scale': $i).
% 29.22/29.06  tff(decl_46941, type, 'integrity-scale': $i).
% 29.22/29.06  tff(decl_46942, type, 'Integrity-Value': $i).
% 29.22/29.06  tff(decl_46943, type, 'an undivided or unbroken completeness or totality with nothing wanting': $i).
% 29.22/29.06  tff(decl_46944, type, unity: $i).
% 29.22/29.06  tff(decl_46945, type, wholeness: $i).
% 29.22/29.06  tff(decl_46946, type, integrity: $i).
% 29.22/29.06  tff(decl_46947, type, 'value of integrity': $i).
% 29.22/29.06  tff(decl_46948, type, 'integrity value': $i).
% 29.22/29.06  tff(decl_46949, type, 'integrity-value': $i).
% 29.22/29.06  tff(decl_46950, type, 'Integument': $i).
% 29.22/29.06  tff(decl_46951, type, 'One or more layers of tissue that form a covering over the ovule of an angiosperm.': $i).
% 29.22/29.06  tff(decl_46952, type, integument: $i).
% 29.22/29.06  tff(decl_46953, type, integumentary_system_1: $i > $o).
% 29.22/29.06  tff(decl_46954, type, 'Integumentary-System': $i).
% 29.22/29.06  tff(decl_46955, type, 'The organ system that protects a mammal\\s body from external damage; comprised of the skin, hair or fur, and nails or claws.': $i).
% 29.22/29.06  tff(decl_46956, type, 'integumentary system': $i).
% 29.22/29.06  tff(decl_46957, type, 'integumentary-system': $i).
% 29.22/29.06  tff(decl_46958, type, 'Intensity-Constant': $i).
% 29.22/29.06  tff(decl_46959, type, 'constant of intensity': $i).
% 29.22/29.06  tff(decl_46960, type, 'intensity constant': $i).
% 29.22/29.06  tff(decl_46961, type, 'intensity-constant': $i).
% 29.22/29.06  tff(decl_46962, type, intensity_scale_1: $i > $o).
% 29.22/29.06  tff(decl_46963, type, 'Intensity-Scale': $i).
% 29.22/29.06  tff(decl_46964, type, 'scale of intensity': $i).
% 29.22/29.06  tff(decl_46965, type, 'intensity scale': $i).
% 29.22/29.06  tff(decl_46966, type, 'intensity-scale': $i).
% 29.22/29.06  tff(decl_46967, type, 'Intensity-Value': $i).
% 29.22/29.06  tff(decl_46968, type, 'the intensity of a Thing': $i).
% 29.22/29.06  tff(decl_46969, type, volume: $i).
% 29.22/29.06  tff(decl_46970, type, strength: $i).
% 29.22/29.06  tff(decl_46971, type, 'intensity level': $i).
% 29.22/29.06  tff(decl_46972, type, loudness: $i).
% 29.22/29.06  tff(decl_46973, type, saturation: $i).
% 29.22/29.06  tff(decl_46974, type, chroma: $i).
% 29.22/29.06  tff(decl_46975, type, intensity: $i).
% 29.22/29.06  tff(decl_46976, type, 'value of intensity': $i).
% 29.22/29.06  tff(decl_46977, type, 'intensity value': $i).
% 29.22/29.06  tff(decl_46978, type, 'intensity-value': $i).
% 29.22/29.06  tff(decl_46979, type, intentional_1: $i > $o).
% 29.22/29.06  tff(decl_46980, type, 'Intentional': $i).
% 29.22/29.06  tff(decl_46981, type, intentional: $i).
% 29.22/29.06  tff(decl_46982, type, 'Interact': $i).
% 29.22/29.06  tff(decl_46983, type, 'Act in such a way as to have an effect on another': $i).
% 29.22/29.06  tff(decl_46984, type, interaction_of_light_with_matter_1: $i > $o).
% 29.22/29.06  tff(decl_46985, type, 'Interaction-Of-Light-With-Matter': $i).
% 29.22/29.06  tff(decl_46986, type, 'When light interacts with matter, some of the light is transmitted, some is reflected, and some is absorbed.': $i).
% 29.22/29.06  tff(decl_46987, type, 'interaction of light with matter': $i).
% 29.22/29.06  tff(decl_46988, type, 'interaction-of-light-with-matter': $i).
% 29.22/29.06  tff(decl_46989, type, fn_interaction_of_light_with_matter_1: $i > $i).
% 29.22/29.06  tff(decl_46990, type, fn_interaction_of_light_with_matter_2: $i > $i).
% 29.22/29.06  tff(decl_46991, type, fn_interaction_of_light_with_matter_3: $i > $i).
% 29.22/29.06  tff(decl_46992, type, fn_interaction_of_light_with_matter_4: $i > $i).
% 29.22/29.06  tff(decl_46993, type, fn_interaction_of_light_with_matter_5: $i > $i).
% 29.22/29.06  tff(decl_46994, type, fn_interaction_of_light_with_matter_6: $i > $i).
% 29.22/29.06  tff(decl_46995, type, fn_interaction_of_light_with_matter_7: $i > $i).
% 29.22/29.06  tff(decl_46996, type, 'Interactive-Hypothesis': $i).
% 29.22/29.06  tff(decl_46997, type, 'The hypothesis that species occur together because they are part of the same community, which is an assemblage of organisms closely linked due to biological interactions. This hypothesis treats the biological community as an integrated unit; i.e., a superorganism.': $i).
% 29.22/29.06  tff(decl_46998, type, 'interactive hypothesis': $i).
% 29.22/29.06  tff(decl_46999, type, 'interactive-hypothesis': $i).
% 29.22/29.06  tff(decl_47000, type, 'Intercalated-Disc': $i).
% 29.22/29.06  tff(decl_47001, type, 'The connection between cardiac muscle cells that allows the heart to beat as a single unit.': $i).
% 29.22/29.06  tff(decl_47002, type, 'intercalated disc': $i).
% 29.22/29.06  tff(decl_47003, type, 'intercalated-disc': $i).
% 29.22/29.06  tff(decl_47004, type, 'Intercellular-Joining': $i).
% 29.22/29.06  tff(decl_47005, type, '(1) (being located) Between or among cells. (2) Of or pertaining to that (e.g. substance, space, region) between the cells.': $i).
% 29.22/29.06  tff(decl_47006, type, 'intercellularly join': $i).
% 29.22/29.06  tff(decl_47007, type, 'intercellular joining': $i).
% 29.22/29.06  tff(decl_47008, type, 'intercellular-joining': $i).
% 29.22/29.06  tff(decl_47009, type, fn_intercellular_joining_1: $i > $i).
% 29.22/29.06  tff(decl_47010, type, fn_intercellular_joining_2: $i > $i).
% 29.22/29.06  tff(decl_47011, type, fn_intercellular_joining_3: $i > $i).
% 29.22/29.06  tff(decl_47012, type, 'Intercellular-Junction': $i).
% 29.22/29.06  tff(decl_47013, type, 'A membrane protein that is attached to 2 adjacent cells.': $i).
% 29.22/29.06  tff(decl_47014, type, 'cell junction': $i).
% 29.22/29.06  tff(decl_47015, type, 'cell-junction': $i).
% 29.22/29.06  tff(decl_47016, type, 'intercellular junction': $i).
% 29.22/29.06  tff(decl_47017, type, 'intercellular-junction': $i).
% 29.22/29.06  tff(decl_47018, type, 'Intercellular-Process': $i).
% 29.22/29.06  tff(decl_47019, type, 'A process that occurs between cells.': $i).
% 29.22/29.06  tff(decl_47020, type, 'intercellular process': $i).
% 29.22/29.06  tff(decl_47021, type, 'intercellular-process': $i).
% 29.22/29.06  tff(decl_47022, type, 'Interdigital-Tissue': $i).
% 29.22/29.06  tff(decl_47023, type, 'Tissue located between the toes or fingers 9digits) of an animal. Webbing between the toes of a duck or frog is an example of interdigital tissue.': $i).
% 29.22/29.06  tff(decl_47024, type, 'interdigital tissue': $i).
% 29.22/29.06  tff(decl_47025, type, 'interdigital-tissue': $i).
% 29.22/29.06  tff(decl_47026, type, interface_slot_1: $i > $o).
% 29.22/29.06  tff(decl_47027, type, 'Interface-Slot': $i).
% 29.22/29.06  tff(decl_47028, type, 'slot of interface': $i).
% 29.22/29.06  tff(decl_47029, type, 'interface slot': $i).
% 29.22/29.06  tff(decl_47030, type, 'interface-slot': $i).
% 29.22/29.06  tff(decl_47031, type, slot_1: $i > $o).
% 29.22/29.06  tff(decl_47032, type, 'Interferon': $i).
% 29.22/29.06  tff(decl_47033, type, 'Type of protein released by cells responding to infection by viruses and other pathogens. Alpha- and beta-interferons are released by virus-infected cells and help neighboring cells resist infection. Gamma-interferon is released by T cells and activates macrophages.': $i).
% 29.22/29.06  tff(decl_47034, type, interferon: $i).
% 29.22/29.06  tff(decl_47035, type, 'Intermediate-Filament': $i).
% 29.22/29.06  tff(decl_47036, type, 'Intermediate filament is a fibrous protein that helps in maintaining cell shape and hold organelles to a fixed position.': $i).
% 29.22/29.06  tff(decl_47037, type, 'filament of intermediate': $i).
% 29.22/29.06  tff(decl_47038, type, 'intermediate filament': $i).
% 29.22/29.06  tff(decl_47039, type, 'intermediate-filament': $i).
% 29.22/29.06  tff(decl_47040, type, fn_intermediate_filament_1: $i > $i).
% 29.22/29.06  tff(decl_47041, type, fn_intermediate_filament_2: $i > $i).
% 29.22/29.06  tff(decl_47042, type, fn_intermediate_filament_3: $i > $i).
% 29.22/29.06  tff(decl_47043, type, fn_intermediate_filament_7: $i > $i).
% 29.22/29.06  tff(decl_47044, type, fn_intermediate_filament_8: $i > $i).
% 29.22/29.06  tff(decl_47045, type, fn_intermediate_filament_13: $i > $i).
% 29.22/29.06  tff(decl_47046, type, fn_intermediate_filament_14: $i > $i).
% 29.22/29.06  tff(decl_47047, type, fn_intermediate_filament_15: $i > $i).
% 29.22/29.06  tff(decl_47048, type, fn_intermediate_filament_16: $i > $i).
% 29.22/29.06  tff(decl_47049, type, fn_intermediate_filament_17: $i > $i).
% 29.22/29.06  tff(decl_47050, type, fn_intermediate_filament_18: $i > $i).
% 29.22/29.06  tff(decl_47051, type, fn_intermediate_filament_19: $i > $i).
% 29.22/29.06  tff(decl_47052, type, fn_intermediate_filament_20: $i > $i).
% 29.22/29.06  tff(decl_47053, type, fn_intermediate_filament_21: $i > $i).
% 29.22/29.06  tff(decl_47054, type, fn_intermediate_filament_22: $i > $i).
% 29.22/29.06  tff(decl_47055, type, fn_intermediate_filament_23: $i > $i).
% 29.22/29.06  tff(decl_47056, type, fn_intermediate_filament_24: $i > $i).
% 29.22/29.06  tff(decl_47057, type, fn_intermediate_filament_25: $i > $i).
% 29.22/29.06  tff(decl_47058, type, fn_intermediate_filament_26: $i > $i).
% 29.22/29.06  tff(decl_47059, type, fn_intermediate_filament_27: $i > $i).
% 29.22/29.06  tff(decl_47060, type, fn_intermediate_filament_28: $i > $i).
% 29.22/29.06  tff(decl_47061, type, fn_intermediate_filament_29: $i > $i).
% 29.22/29.06  tff(decl_47062, type, fn_intermediate_filament_30: $i > $i).
% 29.22/29.06  tff(decl_47063, type, "8.0e0": $i).
% 29.22/29.06  tff(decl_47064, type, fn_intermediate_filament_9: $i > $i).
% 29.22/29.06  tff(decl_47065, type, fn_intermediate_filament_11: $i > $i).
% 29.22/29.06  tff(decl_47066, type, fn_intermediate_filament_10: $i > $i).
% 29.22/29.06  tff(decl_47067, type, fn_intermediate_filament_12: $i > $i).
% 29.22/29.06  tff(decl_47068, type, 'Intermembrane-Space': $i).
% 29.22/29.06  tff(decl_47069, type, 'The intermembrane space is present between the outer membrane and the inner membrane.': $i).
% 29.22/29.06  tff(decl_47070, type, 'intermembrane space': $i).
% 29.22/29.06  tff(decl_47071, type, 'intermembrane-space': $i).
% 29.22/29.06  tff(decl_47072, type, internal_fertilization_1: $i > $o).
% 29.22/29.06  tff(decl_47073, type, 'Internal-Fertilization': $i).
% 29.22/29.06  tff(decl_47074, type, 'Fertilization that takes place inside the female\\s reproductive tract. Sperm are usually deposited within or near the female\\s reproductive tract.': $i).
% 29.22/29.06  tff(decl_47075, type, 'internal fertilization': $i).
% 29.22/29.06  tff(decl_47076, type, 'internal-fertilization': $i).
% 29.22/29.06  tff(decl_47077, type, interneuron_1: $i > $o).
% 29.22/29.06  tff(decl_47078, type, 'Interneuron': $i).
% 29.22/29.06  tff(decl_47079, type, 'A neuron that forms connections between other neurons. In the vertebrate central nervous system, interneurons synapse with sensory and/or motor neurons and integrate either sensory input or motor output.': $i).
% 29.22/29.06  tff(decl_47080, type, interneuron: $i).
% 29.22/29.06  tff(decl_47081, type, motor_neuron_1: $i > $o).
% 29.22/29.06  tff(decl_47082, type, post_synaptic_cell_1: $i > $o).
% 29.22/29.06  tff(decl_47083, type, presynaptic_cell_1: $i > $o).
% 29.22/29.06  tff(decl_47084, type, fn_interneuron_1: $i > $i).
% 29.22/29.06  tff(decl_47085, type, fn_interneuron_2: $i > $i).
% 29.22/29.06  tff(decl_47086, type, fn_interneuron_3: $i > $i).
% 29.22/29.06  tff(decl_47087, type, internode_1: $i > $o).
% 29.22/29.06  tff(decl_47088, type, 'Internode': $i).
% 29.22/29.06  tff(decl_47089, type, 'A section of a plant stem between leaf nodes.': $i).
% 29.22/29.06  tff(decl_47090, type, internode: $i).
% 29.22/29.06  tff(decl_47091, type, 'Interphase': $i).
% 29.22/29.06  tff(decl_47092, type, 'Interphase is the growth phase of cell which prepares it for the subsequent cell division. During this phase, the chromosomes replicate. Also, here the nuclear membrane is still intact maintaining the nucleus. Interphase is about 90% of the whole cell cycle': $i).
% 29.22/29.06  tff(decl_47093, type, 'interphase i': $i).
% 29.22/29.06  tff(decl_47094, type, 'resting stage': $i).
% 29.22/29.06  tff(decl_47095, type, 'resting-stage': $i).
% 29.22/29.06  tff(decl_47096, type, 'undergo interphase': $i).
% 29.22/29.06  tff(decl_47097, type, interphase: $i).
% 29.22/29.06  tff(decl_47098, type, fn_interphase_1: $i > $i).
% 29.22/29.06  tff(decl_47099, type, fn_interphase_3: $i > $i).
% 29.22/29.06  tff(decl_47100, type, fn_interphase_10: $i > $i).
% 29.22/29.06  tff(decl_47101, type, fn_interphase_13: $i > $i).
% 29.22/29.06  tff(decl_47102, type, fn_s_phase_12: $i > $i).
% 29.22/29.06  tff(decl_47103, type, fn_s_phase_10: $i > $i).
% 29.22/29.06  tff(decl_47104, type, 'Interpret': $i).
% 29.22/29.06  tff(decl_47105, type, interpret: $i).
% 29.22/29.06  tff(decl_47106, type, understand: $i).
% 29.22/29.06  tff(decl_47107, type, intersexual_selection_1: $i > $o).
% 29.22/29.06  tff(decl_47108, type, 'Intersexual-Selection': $i).
% 29.22/29.06  tff(decl_47109, type, 'Type of selection in which members of one sex (usually females) are choosy when selecting mates. Also referred to as mate choice.': $i).
% 29.22/29.06  tff(decl_47110, type, 'intersexual selection': $i).
% 29.22/29.06  tff(decl_47111, type, 'intersexual-selection': $i).
% 29.22/29.06  tff(decl_47112, type, sexual_selection_1: $i > $o).
% 29.22/29.06  tff(decl_47113, type, intrasexual_selection_1: $i > $o).
% 29.22/29.06  tff(decl_47114, type, interspecific_competition_1: $i > $o).
% 29.22/29.06  tff(decl_47115, type, 'Interspecific-Competition': $i).
% 29.22/29.06  tff(decl_47116, type, 'A competitive interaction for a scarce resource that occurs between individuals of two or more species.': $i).
% 29.22/29.06  tff(decl_47117, type, 'interspecific competition': $i).
% 29.22/29.06  tff(decl_47118, type, 'interspecific-competition': $i).
% 29.22/29.06  tff(decl_47119, type, interspecific_interaction_1: $i > $o).
% 29.22/29.06  tff(decl_47120, type, 'Interspecific-Interaction': $i).
% 29.22/29.06  tff(decl_47121, type, 'An interaction between members of two or more species within a biological community.': $i).
% 29.22/29.06  tff(decl_47122, type, 'interspecific interaction': $i).
% 29.22/29.06  tff(decl_47123, type, 'interspecific-interaction': $i).
% 29.22/29.06  tff(decl_47124, type, interspersed_repetitive_dna_1: $i > $o).
% 29.22/29.06  tff(decl_47125, type, 'Interspersed-Repetitive-DNA': $i).
% 29.22/29.06  tff(decl_47126, type, 'Nucleotide sequences, usually noncoding, that are present in many copies in a eukaryotic genome. The repeated units may be short and arranged tandemly (in series) or long and dispersed in the genome.': $i).
% 29.22/29.06  tff(decl_47127, type, 'interspersed repetitive dna': $i).
% 29.22/29.06  tff(decl_47128, type, 'interspersed-repetitive-dna': $i).
% 29.22/29.06  tff(decl_47129, type, repetitive_dna_1: $i > $o).
% 29.22/29.06  tff(decl_47130, type, 'Interstitial-Fluid': $i).
% 29.22/29.06  tff(decl_47131, type, 'The aqueous solution that surrounds and bathes the cells of multicellular organisms.': $i).
% 29.22/29.06  tff(decl_47132, type, 'interstitial fluid': $i).
% 29.22/29.06  tff(decl_47133, type, 'interstitial-fluid': $i).
% 29.22/29.06  tff(decl_47134, type, 'Intertidal-Zone': $i).
% 29.22/29.06  tff(decl_47135, type, 'The narrow zone of the marine ecosystem that is adjacent to land. It is covered at high tide and exposed at low tide.': $i).
% 29.22/29.06  tff(decl_47136, type, 'intertidal zone': $i).
% 29.22/29.06  tff(decl_47137, type, 'intertidal-zone': $i).
% 29.22/29.06  tff(decl_47138, type, intestinal_cell_nucleus_transplantation_to_frog_egg_1: $i > $o).
% 29.22/29.06  tff(decl_47139, type, 'Intestinal-Cell-Nucleus-Transplantation-To-Frog-Egg': $i).
% 29.22/29.06  tff(decl_47140, type, 'The technique of placing a intestinal cell nucleus from differentiated cell into an enucleated cell of a frog egg.': $i).
% 29.22/29.06  tff(decl_47141, type, 'intestinal cell nucleus transplantation to frog egg': $i).
% 29.22/29.06  tff(decl_47142, type, 'intestinal-cell-nucleus-transplantation-to-frog-egg': $i).
% 29.22/29.06  tff(decl_47143, type, fn_intestinal_cell_nucleus_transplantation_to_frog_egg_4: $i > $i).
% 29.22/29.06  tff(decl_47144, type, fn_intestinal_cell_nucleus_transplantation_to_frog_egg_6: $i > $i).
% 29.22/29.06  tff(decl_47145, type, fn_intestinal_cell_nucleus_transplantation_to_frog_egg_7: $i > $i).
% 29.22/29.06  tff(decl_47146, type, fn_intestinal_cell_nucleus_transplantation_to_frog_egg_8: $i > $i).
% 29.22/29.06  tff(decl_47147, type, fn_intestinal_cell_nucleus_transplantation_to_frog_egg_9: $i > $i).
% 29.22/29.06  tff(decl_47148, type, tadpole_1: $i > $o).
% 29.22/29.06  tff(decl_47149, type, 'Quantity_Tadpole': $i).
% 29.22/29.06  tff(decl_47150, type, 'Quantity_FrogEgg': $i).
% 29.22/29.06  tff(decl_47151, type, 'Intestine': $i).
% 29.22/29.06  tff(decl_47152, type, 'Segment of the alimentary canal which participates in the absorption of nutrients from food. The intestine can be subdivided into two main segments, the small intestine and the large intestine.': $i).
% 29.22/29.06  tff(decl_47153, type, intestine: $i).
% 29.22/29.06  tff(decl_47154, type, 'Intracellular-Digestion': $i).
% 29.22/29.06  tff(decl_47155, type, 'A form of digestion in which food is taken into cells by phagocytosis. This type of digestion is found in sponges and most protozoa and coelenterates.': $i).
% 29.22/29.06  tff(decl_47156, type, 'intracellular digestion': $i).
% 29.22/29.06  tff(decl_47157, type, 'intracellular-digestion': $i).
% 29.22/29.06  tff(decl_47158, type, fn_intracellular_digestion_1: $i > $i).
% 29.22/29.06  tff(decl_47159, type, fn_intracellular_digestion_2: $i > $i).
% 29.22/29.06  tff(decl_47160, type, fn_intracellular_digestion_4: $i > $i).
% 29.22/29.06  tff(decl_47161, type, fn_intracellular_digestion_5: $i > $i).
% 29.22/29.06  tff(decl_47162, type, fn_intracellular_digestion_6: $i > $i).
% 29.22/29.06  tff(decl_47163, type, fn_intracellular_digestion_7: $i > $i).
% 29.22/29.06  tff(decl_47164, type, fn_intracellular_digestion_10: $i > $i).
% 29.22/29.06  tff(decl_47165, type, fn_intracellular_digestion_14: $i > $i).
% 29.22/29.06  tff(decl_47166, type, fn_intracellular_digestion_15: $i > $i).
% 29.22/29.06  tff(decl_47167, type, fn_intracellular_digestion_16: $i > $i).
% 29.22/29.06  tff(decl_47168, type, fn_intracellular_digestion_17: $i > $i).
% 29.22/29.06  tff(decl_47169, type, fn_intracellular_digestion_18: $i > $i).
% 29.22/29.06  tff(decl_47170, type, fn_intracellular_digestion_19: $i > $i).
% 29.22/29.06  tff(decl_47171, type, fn_intracellular_digestion_20: $i > $i).
% 29.22/29.06  tff(decl_47172, type, fn_intracellular_digestion_21: $i > $i).
% 29.22/29.06  tff(decl_47173, type, fn_intracellular_digestion_22: $i > $i).
% 29.22/29.06  tff(decl_47174, type, fn_intracellular_digestion_23: $i > $i).
% 29.22/29.06  tff(decl_47175, type, fn_intracellular_digestion_24: $i > $i).
% 29.22/29.06  tff(decl_47176, type, fn_intracellular_digestion_25: $i > $i).
% 29.22/29.06  tff(decl_47177, type, fn_intracellular_digestion_26: $i > $i).
% 29.22/29.06  tff(decl_47178, type, fn_intracellular_digestion_27: $i > $i).
% 29.22/29.06  tff(decl_47179, type, fn_intracellular_digestion_28: $i > $i).
% 29.22/29.06  tff(decl_47180, type, fn_intracellular_digestion_29: $i > $i).
% 29.22/29.06  tff(decl_47181, type, fn_lysosomal_enzyme_18: $i > $i).
% 29.22/29.06  tff(decl_47182, type, fn_intracellular_digestion_32: $i > $i).
% 29.22/29.06  tff(decl_47183, type, fn_intracellular_digestion_31: $i > $i).
% 29.22/29.06  tff(decl_47184, type, 'Intracellular-Material': $i).
% 29.22/29.06  tff(decl_47185, type, 'The substances within the cell.': $i).
% 29.22/29.06  tff(decl_47186, type, 'intracellular material': $i).
% 29.22/29.06  tff(decl_47187, type, 'intracellular-material': $i).
% 29.22/29.06  tff(decl_47188, type, 'Intracellular-Process': $i).
% 29.22/29.06  tff(decl_47189, type, 'A process that occurs within a living cell.': $i).
% 29.22/29.06  tff(decl_47190, type, 'intracellular process': $i).
% 29.22/29.06  tff(decl_47191, type, 'intracellular-process': $i).
% 29.22/29.06  tff(decl_47192, type, 'Intracellular-Receptor': $i).
% 29.22/29.06  tff(decl_47193, type, 'Receptor proteins that are located inside the cell rather than on the outer cell surface. They are receptors for thyroid hormones, steroid hormones, and local regulatory molecules such as inositol-triphosphate (IP3), whose regulatory functions are carried out largely within individual cells.': $i).
% 29.22/29.06  tff(decl_47194, type, 'intracellular receptor protein': $i).
% 29.22/29.06  tff(decl_47195, type, 'intracellular receptor': $i).
% 29.22/29.06  tff(decl_47196, type, 'intracellular-receptor': $i).
% 29.22/29.06  tff(decl_47197, type, intracytoplasmic_sperm_injection_1: $i > $o).
% 29.22/29.06  tff(decl_47198, type, 'Intracytoplasmic-Sperm-Injection': $i).
% 29.22/29.06  tff(decl_47199, type, 'An in vitro fertilization procedure in which a single sperm is injected directly into an egg.': $i).
% 29.22/29.06  tff(decl_47200, type, 'intracytoplasmic sperm injection': $i).
% 29.22/29.06  tff(decl_47201, type, 'intracytoplasmic-sperm-injection': $i).
% 29.22/29.06  tff(decl_47202, type, 'Intrasexual-Selection': $i).
% 29.22/29.06  tff(decl_47203, type, 'Direct competition between members of one sex (usually males) for access to mates of the opposite sex.': $i).
% 29.22/29.06  tff(decl_47204, type, 'intrasexual selection': $i).
% 29.22/29.06  tff(decl_47205, type, 'intrasexual-selection': $i).
% 29.22/29.06  tff(decl_47206, type, intrauterine_device_1: $i > $o).
% 29.22/29.06  tff(decl_47207, type, 'Intrauterine-Device': $i).
% 29.22/29.06  tff(decl_47208, type, 'A contraceptive device that is placed directly into the uterus. It acts by preventing fertilization, inhibiting transport of a fertilized egg, or preventing implantation of the early embryo into the endometrium.': $i).
% 29.22/29.06  tff(decl_47209, type, iud: $i).
% 29.22/29.06  tff(decl_47210, type, 'intrauterine device': $i).
% 29.22/29.06  tff(decl_47211, type, 'intrauterine-device': $i).
% 29.22/29.06  tff(decl_47212, type, natural_family_planning_1: $i > $o).
% 29.22/29.06  tff(decl_47213, type, rhythm_method_1: $i > $o).
% 29.22/29.06  tff(decl_47214, type, introduced_species_1: $i > $o).
% 29.22/29.06  tff(decl_47215, type, 'Introduced-Species': $i).
% 29.22/29.06  tff(decl_47216, type, 'A species transported by humans, either deliberately or accidentally, from its native range to a new geographic area. May also be referred to as exotic or non-native species.': $i).
% 29.22/29.06  tff(decl_47217, type, 'introduced species': $i).
% 29.22/29.06  tff(decl_47218, type, 'introduced-specy': $i).
% 29.22/29.06  tff(decl_47219, type, invasive_species_1: $i > $o).
% 29.22/29.06  tff(decl_47220, type, threatened_species_1: $i > $o).
% 29.22/29.06  tff(decl_47221, type, non_coding_dna_sequence_1: $i > $o).
% 29.22/29.06  tff(decl_47222, type, fn_intron_15: $i > $i).
% 29.22/29.06  tff(decl_47223, type, 'Intron': $i).
% 29.22/29.06  tff(decl_47224, type, '(1) Any sequence of nucleotides that is excised from a primary RNA transcript during mRNA processing. (2) The region of DNA from which this sequence was transcribed.': $i).
% 29.22/29.06  tff(decl_47225, type, 'intervening sequence': $i).
% 29.22/29.06  tff(decl_47226, type, 'intervening-sequence': $i).
% 29.22/29.06  tff(decl_47227, type, 'non coding segment': $i).
% 29.22/29.06  tff(decl_47228, type, 'non-coding-segment': $i).
% 29.22/29.06  tff(decl_47229, type, intron: $i).
% 29.22/29.06  tff(decl_47230, type, fn_intron_1: $i > $i).
% 29.22/29.06  tff(decl_47231, type, fn_intron_2: $i > $i).
% 29.22/29.06  tff(decl_47232, type, fn_intron_3: $i > $i).
% 29.22/29.06  tff(decl_47233, type, spliceosome_1: $i > $o).
% 29.22/29.06  tff(decl_47234, type, fn_intron_5: $i > $i).
% 29.22/29.06  tff(decl_47235, type, fn_intron_9: $i > $i).
% 29.22/29.06  tff(decl_47236, type, fn_intron_10: $i > $i).
% 29.22/29.06  tff(decl_47237, type, fn_intron_11: $i > $i).
% 29.22/29.06  tff(decl_47238, type, fn_intron_12: $i > $i).
% 29.22/29.06  tff(decl_47239, type, fn_intron_13: $i > $i).
% 29.22/29.06  tff(decl_47240, type, fn_intron_14: $i > $i).
% 29.22/29.06  tff(decl_47241, type, fn_intron_16: $i > $i).
% 29.22/29.06  tff(decl_47242, type, fn_intron_17: $i > $i).
% 29.22/29.06  tff(decl_47243, type, invade_1: $i > $o).
% 29.22/29.06  tff(decl_47244, type, 'Invade': $i).
% 29.22/29.06  tff(decl_47245, type, invade: $i).
% 29.22/29.06  tff(decl_47246, type, occupy: $i).
% 29.22/29.06  tff(decl_47247, type, penetrate: $i).
% 29.22/29.06  tff(decl_47248, type, perforate: $i).
% 29.22/29.06  tff(decl_47249, type, trespass_1: $i > $o).
% 29.22/29.06  tff(decl_47250, type, invagination_1: $i > $o).
% 29.22/29.06  tff(decl_47251, type, 'Invagination': $i).
% 29.22/29.06  tff(decl_47252, type, 'The infolding of one part of a structure within another part of the same structure.': $i).
% 29.22/29.06  tff(decl_47253, type, invaginate: $i).
% 29.22/29.06  tff(decl_47254, type, invagination: $i).
% 29.22/29.06  tff(decl_47255, type, 'Invasive-Species': $i).
% 29.22/29.06  tff(decl_47256, type, 'A species that becomes established outside its native range, often at the expense of native species in the new range. Many invasive species are introduced, deliberately or inadvertently, by humans.': $i).
% 29.22/29.06  tff(decl_47257, type, 'invasive species': $i).
% 29.22/29.06  tff(decl_47258, type, 'invasive-specy': $i).
% 29.22/29.06  tff(decl_47259, type, 'Inversion-Of-Chromosome-Fragment': $i).
% 29.22/29.06  tff(decl_47260, type, 'An aberration in chromosome structure resulting from reattachment of a chromosomal fragment in a reverse orientation to the chromosome from which it originated.': $i).
% 29.22/29.06  tff(decl_47261, type, invert: $i).
% 29.22/29.06  tff(decl_47262, type, 'inversion of chromosome fragment': $i).
% 29.22/29.06  tff(decl_47263, type, 'inversion-of-chromosome-fragment': $i).
% 29.22/29.06  tff(decl_47264, type, fn_inversion_of_chromosome_fragment_1: $i > $i).
% 29.22/29.06  tff(decl_47265, type, fn_inversion_of_chromosome_fragment_2: $i > $i).
% 29.22/29.06  tff(decl_47266, type, 'Invertebrate': $i).
% 29.22/29.06  tff(decl_47267, type, 'An animal without a backbone, or vertebral column. About 95% of all animal species are invertebrates.': $i).
% 29.22/29.06  tff(decl_47268, type, invertebrate: $i).
% 29.22/29.06  tff(decl_47269, type, fn_invertebrate_2: $i > $i).
% 29.22/29.06  tff(decl_47270, type, 'Invertebrate-Appendage': $i).
% 29.22/29.06  tff(decl_47271, type, 'An external body part, or natural prolongation, that protrudes from an invertebrate\\s body.': $i).
% 29.22/29.06  tff(decl_47272, type, 'appendage of invertebrate': $i).
% 29.22/29.06  tff(decl_47273, type, 'invertebrate appendage': $i).
% 29.22/29.06  tff(decl_47274, type, 'invertebrate-appendage': $i).
% 29.22/29.06  tff(decl_47275, type, 'Invertebrate-Cell': $i).
% 29.22/29.06  tff(decl_47276, type, 'Cell which makes up the body or tissues of an invertebrate.': $i).
% 29.22/29.06  tff(decl_47277, type, 'cell of invertebrate': $i).
% 29.22/29.06  tff(decl_47278, type, 'invertebrate cell': $i).
% 29.22/29.06  tff(decl_47279, type, 'invertebrate-cell': $i).
% 29.22/29.06  tff(decl_47280, type, involution_1: $i > $o).
% 29.22/29.06  tff(decl_47281, type, 'Involution': $i).
% 29.22/29.06  tff(decl_47282, type, 'In gastrulation of animal embryos, the process in which the surface layer of cells of a blastocyst rolls over the edge of the blastopore and into the interior of the embryo.': $i).
% 29.22/29.06  tff(decl_47283, type, involution: $i).
% 29.22/29.06  tff(decl_47284, type, 'Iodine': $i).
% 29.22/29.06  tff(decl_47285, type, 'Iodine is a non metal atom with atomic number 53. It is represented by the symbol I.': $i).
% 29.22/29.06  tff(decl_47286, type, 'I': $i).
% 29.22/29.06  tff(decl_47287, type, iodine: $i).
% 29.22/29.06  tff(decl_47288, type, fn_iodine_1: $i > $i).
% 29.22/29.06  tff(decl_47289, type, fn_iodine_2: $i > $i).
% 29.22/29.06  tff(decl_47290, type, fn_iodine_3: $i > $i).
% 29.22/29.06  tff(decl_47291, type, fn_iodine_8: $i > $i).
% 29.22/29.06  tff(decl_47292, type, fn_iodine_9: $i > $i).
% 29.22/29.06  tff(decl_47293, type, fn_iodine_10: $i > $i).
% 29.22/29.06  tff(decl_47294, type, fn_iodine_11: $i > $i).
% 29.22/29.06  tff(decl_47295, type, fn_iodine_12: $i > $i).
% 29.22/29.06  tff(decl_47296, type, "53": $i).
% 29.22/29.06  tff(decl_47297, type, "74": $i).
% 29.22/29.06  tff(decl_47298, type, "2.66": $i).
% 29.22/29.06  tff(decl_47299, type, "127": $i).
% 29.22/29.06  tff(decl_47300, type, "126.9": $i).
% 29.22/29.06  tff(decl_47301, type, fn_iodine_13: $i > $i).
% 29.22/29.06  tff(decl_47302, type, fn_iodine_7: $i > $i).
% 29.22/29.06  tff(decl_47303, type, fn_iodine_6: $i > $i).
% 29.22/29.06  tff(decl_47304, type, 'Ion': $i).
% 29.22/29.06  tff(decl_47305, type, 'An ion is an electrically charged atom or group of atoms (polyatomic ion); ions can be positively or negatively charged, depending on whether electrons are lost (positive) or gained (negative) by the atoms.': $i).
% 29.22/29.06  tff(decl_47306, type, 'has ion': $i).
% 29.22/29.06  tff(decl_47307, type, 'has-ion': $i).
% 29.22/29.06  tff(decl_47308, type, ion: $i).
% 29.22/29.06  tff(decl_47309, type, 'Ion-Channel': $i).
% 29.22/29.06  tff(decl_47310, type, 'A transmembrane protein which functions as a channel that allows ions to cross the cell membrane.': $i).
% 29.22/29.06  tff(decl_47311, type, 'channel of ion': $i).
% 29.22/29.06  tff(decl_47312, type, 'ion channel': $i).
% 29.22/29.06  tff(decl_47313, type, 'ion-channel': $i).
% 29.22/29.06  tff(decl_47314, type, 'Ionic-Bond': $i).
% 29.22/29.06  tff(decl_47315, type, 'A type of chemical bond where two oppositely-charged ions are held together due to electrical attraction.': $i).
% 29.22/29.06  tff(decl_47316, type, 'bond of ionic': $i).
% 29.22/29.06  tff(decl_47317, type, 'ionic bond': $i).
% 29.22/29.06  tff(decl_47318, type, 'ionic-bond': $i).
% 29.22/29.06  tff(decl_47319, type, 'Ionic-Compound': $i).
% 29.22/29.06  tff(decl_47320, type, 'An ionic compound is a compound composed of cations and anions.': $i).
% 29.22/29.06  tff(decl_47321, type, 'compound of ionic': $i).
% 29.22/29.06  tff(decl_47322, type, 'ionic compound': $i).
% 29.22/29.06  tff(decl_47323, type, 'ionic-compound': $i).
% 29.22/29.06  tff(decl_47324, type, ionic_compound_substance_1: $i > $o).
% 29.22/29.06  tff(decl_47325, type, 'Ionic-Compound-Substance': $i).
% 29.22/29.06  tff(decl_47326, type, 'ionic compound substance': $i).
% 29.22/29.06  tff(decl_47327, type, 'ionic-compound-substance': $i).
% 29.22/29.06  tff(decl_47328, type, strong_electrolyte_1: $i > $o).
% 29.22/29.06  tff(decl_47329, type, fn_ionic_compound_substance_1: $i > $i).
% 29.22/29.06  tff(decl_47330, type, fn_ionic_compound_substance_2: $i > $i).
% 29.22/29.06  tff(decl_47331, type, fn_ionic_compound_substance_3: $i > $i).
% 29.22/29.06  tff(decl_47332, type, 'Ionic-Region': $i).
% 29.22/29.06  tff(decl_47333, type, 'A section of a large molecule that is charged.': $i).
% 29.22/29.06  tff(decl_47334, type, 'region of ionic': $i).
% 29.22/29.06  tff(decl_47335, type, 'ionic region': $i).
% 29.22/29.06  tff(decl_47336, type, 'ionic-region': $i).
% 29.22/29.06  tff(decl_47337, type, nonpolar_region_1: $i > $o).
% 29.22/29.06  tff(decl_47338, type, 'Ionic-Substance': $i).
% 29.22/29.06  tff(decl_47339, type, 'A substance of an ionic compound.': $i).
% 29.22/29.06  tff(decl_47340, type, 'substance of ionic': $i).
% 29.22/29.06  tff(decl_47341, type, 'ionic substance': $i).
% 29.22/29.06  tff(decl_47342, type, 'ionic-substance': $i).
% 29.22/29.06  tff(decl_47343, type, fn_ionic_substance_1: $i > $i).
% 29.22/29.06  tff(decl_47344, type, fn_ionic_substance_2: $i > $i).
% 29.22/29.06  tff(decl_47345, type, 'IP3-Gated-Calcium-Ion-Channel': $i).
% 29.22/29.06  tff(decl_47346, type, 'Ion channel which controls the movement of calcium ions and is regulated buy the binding of IP3.': $i).
% 29.22/29.06  tff(decl_47347, type, 'ip3 gated calcium ion channel': $i).
% 29.22/29.06  tff(decl_47348, type, 'ip3-gated-calcium-ion-channel': $i).
% 29.22/29.06  tff(decl_47349, type, iridium_1: $i > $o).
% 29.22/29.06  tff(decl_47350, type, 'Iridium': $i).
% 29.22/29.06  tff(decl_47351, type, 'Iridium is a metal atom with atomic number 77. It is represented by the symbol Ir.': $i).
% 29.22/29.06  tff(decl_47352, type, iridium: $i).
% 29.22/29.06  tff(decl_47353, type, 'Ir': $i).
% 29.22/29.06  tff(decl_47354, type, fn_iridium_3: $i > $i).
% 29.22/29.06  tff(decl_47355, type, fn_iridium_4: $i > $i).
% 29.22/29.06  tff(decl_47356, type, fn_iridium_5: $i > $i).
% 29.22/29.06  tff(decl_47357, type, fn_iridium_9: $i > $i).
% 29.22/29.06  tff(decl_47358, type, fn_iridium_10: $i > $i).
% 29.22/29.06  tff(decl_47359, type, fn_iridium_11: $i > $i).
% 29.22/29.06  tff(decl_47360, type, fn_iridium_12: $i > $i).
% 29.22/29.06  tff(decl_47361, type, "77": $i).
% 29.22/29.06  tff(decl_47362, type, "192": $i).
% 29.22/29.06  tff(decl_47363, type, "192.2": $i).
% 29.22/29.06  tff(decl_47364, type, fn_iridium_7: $i > $i).
% 29.22/29.06  tff(decl_47365, type, fn_iridium_8: $i > $i).
% 29.22/29.06  tff(decl_47366, type, fn_iridium_6: $i > $i).
% 29.22/29.06  tff(decl_47367, type, 'Iris': $i).
% 29.22/29.06  tff(decl_47368, type, 'The colored part of the vertebrate eye, surrounding the pupil. The iris controls the size of the pupil and thus the amount of light entering the eye.': $i).
% 29.22/29.06  tff(decl_47369, type, iris: $i).
% 29.22/29.06  tff(decl_47370, type, 'Iron': $i).
% 29.22/29.06  tff(decl_47371, type, 'Iron is a metal atom with atomic number 26. It is represented by the symbol Fe.': $i).
% 29.22/29.06  tff(decl_47372, type, 'Fe': $i).
% 29.22/29.06  tff(decl_47373, type, iron: $i).
% 29.22/29.06  tff(decl_47374, type, fn_iron_3: $i > $i).
% 29.22/29.06  tff(decl_47375, type, fn_iron_4: $i > $i).
% 29.22/29.06  tff(decl_47376, type, fn_iron_5: $i > $i).
% 29.22/29.06  tff(decl_47377, type, fn_iron_9: $i > $i).
% 29.22/29.06  tff(decl_47378, type, fn_iron_10: $i > $i).
% 29.22/29.06  tff(decl_47379, type, fn_iron_11: $i > $i).
% 29.22/29.06  tff(decl_47380, type, fn_iron_12: $i > $i).
% 29.22/29.06  tff(decl_47381, type, "30": $i).
% 29.22/29.06  tff(decl_47382, type, "26": $i).
% 29.22/29.06  tff(decl_47383, type, "1.83": $i).
% 29.22/29.06  tff(decl_47384, type, "55.85": $i).
% 29.22/29.06  tff(decl_47385, type, fn_iron_7: $i > $i).
% 29.22/29.06  tff(decl_47386, type, fn_iron_8: $i > $i).
% 29.22/29.06  tff(decl_47387, type, fn_iron_6: $i > $i).
% 29.22/29.06  tff(decl_47388, type, 'Iron-Sulfur-Protein': $i).
% 29.22/29.06  tff(decl_47389, type, 'Proteins with clusters of non-heme iron, cysteine sulfur, and usually inorganic sulfur that function as electron-transfer groups in most iron-sulfur proteins, but in other proteins they have functions, such as catalysis of hydratase and dehydratase reactions, maintaining protein structure, or regulating activity.': $i).
% 29.22/29.06  tff(decl_47390, type, 'fe s protein': $i).
% 29.22/29.06  tff(decl_47391, type, 'fe-s-protein': $i).
% 29.22/29.06  tff(decl_47392, type, 'fe.s': $i).
% 29.22/29.06  tff(decl_47393, type, 'iron sulphur protein': $i).
% 29.22/29.06  tff(decl_47394, type, 'iron-sulphur-protein': $i).
% 29.22/29.06  tff(decl_47395, type, 'iron sulfur protein': $i).
% 29.22/29.06  tff(decl_47396, type, 'iron-sulfur protein': $i).
% 29.22/29.06  tff(decl_47397, type, 'iron-sulfur-protein': $i).
% 29.22/29.06  tff(decl_47398, type, fn_iron_sulfur_protein_1: $i > $i).
% 29.22/29.06  tff(decl_47399, type, fn_iron_sulfur_protein_2: $i > $i).
% 29.22/29.06  tff(decl_47400, type, fn_iron_sulfur_protein_3: $i > $i).
% 29.22/29.06  tff(decl_47401, type, fn_iron_sulfur_protein_6: $i > $i).
% 29.22/29.06  tff(decl_47402, type, fn_iron_sulfur_protein_7: $i > $i).
% 29.22/29.06  tff(decl_47403, type, fn_iron_sulfur_protein_8: $i > $i).
% 29.22/29.06  tff(decl_47404, type, fn_iron_sulfur_protein_9: $i > $i).
% 29.22/29.06  tff(decl_47405, type, fn_iron_sulfur_protein_10: $i > $i).
% 29.22/29.06  tff(decl_47406, type, fn_iron_sulfur_protein_11: $i > $i).
% 29.22/29.06  tff(decl_47407, type, 'Irreparable-DNA-Damage': $i).
% 29.22/29.06  tff(decl_47408, type, 'DNA damage that is too extensive for the cell to repair.': $i).
% 29.22/29.06  tff(decl_47409, type, 'damage irreparably': $i).
% 29.22/29.06  tff(decl_47410, type, 'irreparable dna damage': $i).
% 29.22/29.06  tff(decl_47411, type, 'irreparable-dna-damage': $i).
% 29.22/29.06  tff(decl_47412, type, irreversible_non_competitive_inhibition_1: $i > $o).
% 29.22/29.06  tff(decl_47413, type, 'Irreversible-Non-Competitive-Inhibition': $i).
% 29.22/29.06  tff(decl_47414, type, 'Non-competitive inhibition is a type of enzyme inhibition where the inhibitor reversibly binds to an allosteric site, a site different than the active site, on the enzyme, preventing the substrate from being able to bind to the active site. If the inhibitor attaches to the enzyme by covalent bonds, inhibition is usually irreversible.': $i).
% 29.22/29.06  tff(decl_47415, type, 'irreversible non competitive inhibition': $i).
% 29.22/29.06  tff(decl_47416, type, 'irreversible-non-competitive-inhibition': $i).
% 29.22/29.06  tff(decl_47417, type, reversible_non_competitive_inhibition_1: $i > $o).
% 29.22/29.06  tff(decl_47418, type, fn_irreversible_non_competitive_inhibition_1: $i > $i).
% 29.22/29.06  tff(decl_47419, type, fn_irreversible_non_competitive_inhibition_2: $i > $i).
% 29.22/29.06  tff(decl_47420, type, fn_non_competitive_inhibition_7: $i > $i).
% 29.22/29.06  tff(decl_47421, type, 'Irrigation': $i).
% 29.22/29.06  tff(decl_47422, type, 'The act of applying water to soil.': $i).
% 29.22/29.06  tff(decl_47423, type, irrigate: $i).
% 29.22/29.06  tff(decl_47424, type, irrigation: $i).
% 29.22/29.06  tff(decl_47425, type, 'Islets-Of-Langerhans': $i).
% 29.22/29.06  tff(decl_47426, type, 'Clusters of endocrine cells within the pancreas that produce and secrete the hormones glucagon (from alpha cells) and insulin (from beta cells).': $i).
% 29.22/29.06  tff(decl_47427, type, 'islet of langerhan': $i).
% 29.22/29.06  tff(decl_47428, type, 'islets of langerhan': $i).
% 29.22/29.06  tff(decl_47429, type, 'islets-of-langerhan': $i).
% 29.22/29.06  tff(decl_47430, type, 'Isocitrate': $i).
% 29.22/29.06  tff(decl_47431, type, 'Isocitrate is an intermediate compound formed in citric acid cycle.': $i).
% 29.22/29.06  tff(decl_47432, type, isocitrate: $i).
% 29.22/29.06  tff(decl_47433, type, isolated_chlorophyll_solution_1: $i > $o).
% 29.22/29.06  tff(decl_47434, type, 'Isolated-Chlorophyll-Solution': $i).
% 29.22/29.06  tff(decl_47435, type, 'A solution which contains chlorophyll isolated from photosynthetic cells. This solution is used to study the nature of light absorption in photosynthetic pigments.': $i).
% 29.22/29.06  tff(decl_47436, type, 'isolated chlorophyll solution': $i).
% 29.22/29.06  tff(decl_47437, type, 'isolated-chlorophyll-solution': $i).
% 29.22/29.06  tff(decl_47438, type, fn_isolated_chlorophyll_solution_1: $i > $i).
% 29.22/29.06  tff(decl_47439, type, fn_isolated_chlorophyll_solution_2: $i > $i).
% 29.22/29.06  tff(decl_47440, type, fn_isolated_chlorophyll_solution_3: $i > $i).
% 29.22/29.06  tff(decl_47441, type, fn_isolated_chlorophyll_solution_4: $i > $i).
% 29.22/29.06  tff(decl_47442, type, fn_isolated_chlorophyll_solution_5: $i > $i).
% 29.22/29.06  tff(decl_47443, type, fn_isolated_chlorophyll_solution_6: $i > $i).
% 29.22/29.06  tff(decl_47444, type, fn_isolated_chlorophyll_solution_7: $i > $i).
% 29.22/29.06  tff(decl_47445, type, fn_isolated_chlorophyll_solution_9: $i > $i).
% 29.22/29.06  tff(decl_47446, type, fn_isolated_chlorophyll_solution_10: $i > $i).
% 29.22/29.06  tff(decl_47447, type, fn_isolated_chlorophyll_solution_11: $i > $i).
% 29.22/29.06  tff(decl_47448, type, fn_isolated_chlorophyll_solution_12: $i > $i).
% 29.22/29.06  tff(decl_47449, type, isolation_of_chlorophyll_1: $i > $o).
% 29.22/29.06  tff(decl_47450, type, fn_isolated_chlorophyll_solution_13: $i > $i).
% 29.22/29.06  tff(decl_47451, type, fn_isolated_chlorophyll_solution_14: $i > $i).
% 29.22/29.06  tff(decl_47452, type, fn_isolated_chlorophyll_solution_15: $i > $i).
% 29.22/29.06  tff(decl_47453, type, fn_isolated_chlorophyll_solution_16: $i > $i).
% 29.22/29.06  tff(decl_47454, type, fn_isolated_chlorophyll_solution_17: $i > $i).
% 29.22/29.06  tff(decl_47455, type, fn_isolated_chlorophyll_solution_18: $i > $i).
% 29.22/29.06  tff(decl_47456, type, fn_isolated_chlorophyll_solution_19: $i > $i).
% 29.22/29.06  tff(decl_47457, type, fn_isolated_chlorophyll_solution_20: $i > $i).
% 29.22/29.06  tff(decl_47458, type, fn_isolated_chlorophyll_solution_21: $i > $i).
% 29.22/29.06  tff(decl_47459, type, fn_isolated_chlorophyll_solution_22: $i > $i).
% 29.22/29.06  tff(decl_47460, type, photon_1: $i > $o).
% 29.22/29.06  tff(decl_47461, type, fn_isolated_chlorophyll_solution_23: $i > $i).
% 29.22/29.06  tff(decl_47462, type, fn_isolated_chlorophyll_solution_24: $i > $i).
% 29.22/29.06  tff(decl_47463, type, fn_isolated_chlorophyll_solution_25: $i > $i).
% 29.22/29.06  tff(decl_47464, type, fn_isolated_chlorophyll_solution_26: $i > $i).
% 29.22/29.06  tff(decl_47465, type, fn_isolated_chlorophyll_solution_27: $i > $i).
% 29.22/29.06  tff(decl_47466, type, fn_isolation_of_chlorophyll_2: $i > $i).
% 29.22/29.06  tff(decl_47467, type, fn_light_1: $i > $i).
% 29.22/29.06  tff(decl_47468, type, fall_0: $i).
% 29.22/29.06  tff(decl_47469, type, isolated_system_1: $i > $o).
% 29.22/29.06  tff(decl_47470, type, 'Isolated-System': $i).
% 29.22/29.06  tff(decl_47471, type, 'Isolated system is a system that is unable to exchange either energy or matter with its surroundings.': $i).
% 29.22/29.06  tff(decl_47472, type, 'isolated system': $i).
% 29.22/29.06  tff(decl_47473, type, 'isolated-system': $i).
% 29.22/29.06  tff(decl_47474, type, 'Isolation': $i).
% 29.22/29.06  tff(decl_47475, type, 'The process of setting something apart from others.': $i).
% 29.22/29.06  tff(decl_47476, type, isolation: $i).
% 29.22/29.06  tff(decl_47477, type, 'Isolation-Of-Chlorophyll': $i).
% 29.22/29.06  tff(decl_47478, type, 'The process of extracting chlorophyll from photosynthetic cells or chloroplasts.': $i).
% 29.22/29.06  tff(decl_47479, type, isolate: $i).
% 29.22/29.06  tff(decl_47480, type, 'chlorophyll isolation': $i).
% 29.22/29.06  tff(decl_47481, type, 'chlorophyll-isolation': $i).
% 29.22/29.06  tff(decl_47482, type, 'isolation of chlorophyll': $i).
% 29.22/29.06  tff(decl_47483, type, 'isolation-of-chlorophyll': $i).
% 29.22/29.06  tff(decl_47484, type, fn_isolation_of_chlorophyll_1: $i > $i).
% 29.22/29.06  tff(decl_47485, type, isolation_of_dna_1: $i > $o).
% 29.22/29.06  tff(decl_47486, type, fn_isolation_of_dna_3: $i > $i).
% 29.22/29.06  tff(decl_47487, type, 'Isolation-Of-DNA': $i).
% 29.22/29.06  tff(decl_47488, type, 'A procedure used to collect DNA for analysis.': $i).
% 29.22/29.06  tff(decl_47489, type, 'dna isolation': $i).
% 29.22/29.06  tff(decl_47490, type, 'dna-isolation': $i).
% 29.22/29.06  tff(decl_47491, type, 'isolation of dna': $i).
% 29.22/29.06  tff(decl_47492, type, 'isolation-of-dna': $i).
% 29.22/29.06  tff(decl_47493, type, fn_isolation_of_dna_1: $i > $i).
% 29.22/29.06  tff(decl_47494, type, 'Isolation-Of-Gene-Source-DNA': $i).
% 29.22/29.06  tff(decl_47495, type, 'Collecting DNA that contains genes.': $i).
% 29.22/29.06  tff(decl_47496, type, 'isolation of gene': $i).
% 29.22/29.06  tff(decl_47497, type, 'isolation of gene source dna': $i).
% 29.22/29.06  tff(decl_47498, type, 'isolation-of-gene-source-dna': $i).
% 29.22/29.06  tff(decl_47499, type, 'Isolation-of-Phage': $i).
% 29.22/29.06  tff(decl_47500, type, 'Collecting phages for analysis and study.': $i).
% 29.22/29.06  tff(decl_47501, type, 'phage isolation': $i).
% 29.22/29.06  tff(decl_47502, type, 'phage-isolation': $i).
% 29.22/29.06  tff(decl_47503, type, 'isolation of phage': $i).
% 29.22/29.06  tff(decl_47504, type, 'isolation-of-phage': $i).
% 29.22/29.06  tff(decl_47505, type, fn_isolation_of_vector_2: $i > $i).
% 29.22/29.06  tff(decl_47506, type, 'Isolation-Of-Vector': $i).
% 29.22/29.06  tff(decl_47507, type, 'Collecting DNA in the form of a cloning vector.': $i).
% 29.22/29.06  tff(decl_47508, type, 'vector isolation': $i).
% 29.22/29.06  tff(decl_47509, type, 'vector-isolation': $i).
% 29.22/29.06  tff(decl_47510, type, 'isolation of vector': $i).
% 29.22/29.06  tff(decl_47511, type, 'isolation-of-vector': $i).
% 29.22/29.06  tff(decl_47512, type, isolation_of_vector_phage_1: $i > $o).
% 29.22/29.06  tff(decl_47513, type, fn_isolation_of_vector_phage_2: $i > $i).
% 29.22/29.06  tff(decl_47514, type, 'Isolation-Of-Vector-Phage': $i).
% 29.22/29.06  tff(decl_47515, type, 'Collecting DNA in the form of a phage cloning vector.': $i).
% 29.22/29.06  tff(decl_47516, type, 'isolation of vector phage': $i).
% 29.22/29.06  tff(decl_47517, type, 'isolation-of-vector-phage': $i).
% 29.22/29.06  tff(decl_47518, type, fn_isolation_of_vector_plasmid_2: $i > $i).
% 29.22/29.06  tff(decl_47519, type, 'Isolation-Of-Vector-Plasmid': $i).
% 29.22/29.06  tff(decl_47520, type, 'Collecting DNA in the form of a plasmid cloning vector.': $i).
% 29.22/29.06  tff(decl_47521, type, 'isolation of vector plasmid': $i).
% 29.22/29.06  tff(decl_47522, type, 'isolation-of-vector-plasmid': $i).
% 29.22/29.06  tff(decl_47523, type, 'Isoleucine': $i).
% 29.22/29.06  tff(decl_47524, type, isoleucine: $i).
% 29.22/29.06  tff(decl_47525, type, 'Isomer': $i).
% 29.22/29.06  tff(decl_47526, type, 'Molecules that have same atomic parts, but different structures. These include structural isomers that differe in covalent arrangement, geometric or cis-trans isomers that differe in the placement of atom pairs on the same sides of molecule with a double bond, and enantiomers which are isomers that are mirror images of each other.': $i).
% 29.22/29.06  tff(decl_47527, type, enantiomer: $i).
% 29.22/29.06  tff(decl_47528, type, 'structural isomer': $i).
% 29.22/29.06  tff(decl_47529, type, 'cis trans isomer': $i).
% 29.22/29.06  tff(decl_47530, type, 'cis-trans isomer': $i).
% 29.22/29.06  tff(decl_47531, type, 'cis isomer': $i).
% 29.22/29.06  tff(decl_47532, type, 'trans isomer': $i).
% 29.22/29.06  tff(decl_47533, type, 'l isomer': $i).
% 29.22/29.06  tff(decl_47534, type, 'd isomer': $i).
% 29.22/29.06  tff(decl_47535, type, 'geometric isomer': $i).
% 29.22/29.06  tff(decl_47536, type, 's isomer': $i).
% 29.22/29.06  tff(decl_47537, type, 'r isomer': $i).
% 29.22/29.06  tff(decl_47538, type, isomer: $i).
% 29.22/29.06  tff(decl_47539, type, 'Isomerase': $i).
% 29.22/29.06  tff(decl_47540, type, 'In biochemistry, an isomerase is an enzyme that catalyzes the structural rearrangement of isomers.': $i).
% 29.22/29.06  tff(decl_47541, type, isomerase: $i).
% 29.22/29.06  tff(decl_47542, type, 'Isomerization-Reaction': $i).
% 29.22/29.06  tff(decl_47543, type, 'Reaction in which a molecule changes from one geometric arrangement to another, without changing its molecular formula.': $i).
% 29.22/29.06  tff(decl_47544, type, 'reaction of isomerization': $i).
% 29.22/29.06  tff(decl_47545, type, 'isomerization reaction': $i).
% 29.22/29.06  tff(decl_47546, type, 'isomerization-reaction': $i).
% 29.22/29.06  tff(decl_47547, type, isomorphic_1: $i > $o).
% 29.22/29.06  tff(decl_47548, type, 'Isomorphic': $i).
% 29.22/29.06  tff(decl_47549, type, 'Having the same form in different life history stages, such as the sporophyte and gametophyte stages of plants and algae, and the larval and adult stages of animals.': $i).
% 29.22/29.06  tff(decl_47550, type, isomorphic: $i).
% 29.22/29.06  tff(decl_47551, type, life_cycle_of_fern_1: $i > $o).
% 29.22/29.06  tff(decl_47552, type, 'Isopod': $i).
% 29.22/29.06  tff(decl_47553, type, 'Member of a large, diverse group of crustaceans. Includes marine, freshwater, and terrestrial forms. Pill bugs and wood lice are examples of terrestrial isopods.': $i).
% 29.22/29.06  tff(decl_47554, type, isopod: $i).
% 29.22/29.06  tff(decl_47555, type, 'Isoptera': $i).
% 29.22/29.06  tff(decl_47556, type, 'Order of insects characterized by similar structure in all four wings.': $i).
% 29.22/29.06  tff(decl_47557, type, isoptera: $i).
% 29.22/29.06  tff(decl_47558, type, 'Isotonic': $i).
% 29.22/29.06  tff(decl_47559, type, 'Refers to a solution that has the same salt concentration as a cell, and thus has no effect on the movement water into or out of the cell.': $i).
% 29.22/29.06  tff(decl_47560, type, isotonic: $i).
% 29.22/29.06  tff(decl_47561, type, 'Isotonic-Solution': $i).
% 29.22/29.06  tff(decl_47562, type, 'A solution that has the same salt concentration as the normal cells of the body and the blood.': $i).
% 29.22/29.06  tff(decl_47563, type, 'isotonic solution': $i).
% 29.22/29.06  tff(decl_47564, type, 'isotonic-solution': $i).
% 29.22/29.06  tff(decl_47565, type, fn_isotonic_solution_1: $i > $i).
% 29.22/29.06  tff(decl_47566, type, fn_isotonic_solution_3: $i > $i).
% 29.22/29.06  tff(decl_47567, type, fn_isotonic_solution_4: $i > $i).
% 29.22/29.06  tff(decl_47568, type, fn_isotonic_solution_7: $i > $i).
% 29.22/29.06  tff(decl_47569, type, fn_isotonic_solution_13: $i > $i).
% 29.22/29.06  tff(decl_47570, type, fn_isotonic_solution_14: $i > $i).
% 29.22/29.06  tff(decl_47571, type, fn_isotonic_solution_15: $i > $i).
% 29.22/29.06  tff(decl_47572, type, fn_isotonic_solution_16: $i > $i).
% 29.22/29.06  tff(decl_47573, type, fn_isotonic_solution_19: $i > $i).
% 29.22/29.06  tff(decl_47574, type, fn_isotonic_solution_20: $i > $i).
% 29.22/29.06  tff(decl_47575, type, fn_isotonic_solution_22: $i > $i).
% 29.22/29.06  tff(decl_47576, type, fn_isotonic_solution_24: $i > $i).
% 29.22/29.06  tff(decl_47577, type, fn_isotonic_solution_25: $i > $i).
% 29.22/29.06  tff(decl_47578, type, fn_isotonic_solution_26: $i > $i).
% 29.22/29.06  tff(decl_47579, type, fn_isotonic_solution_10: $i > $i).
% 29.22/29.06  tff(decl_47580, type, fn_aqueous_solution_4: $i > $i).
% 29.22/29.06  tff(decl_47581, type, fn_isotonic_solution_9: $i > $i).
% 29.22/29.06  tff(decl_47582, type, fn_aqueous_solution_3: $i > $i).
% 29.22/29.06  tff(decl_47583, type, fn_isotonic_solution_12: $i > $i).
% 29.22/29.06  tff(decl_47584, type, fn_aqueous_solution_5: $i > $i).
% 29.22/29.06  tff(decl_47585, type, fn_isotonic_solution_23: $i > $i).
% 29.22/29.06  tff(decl_47586, type, fn_aqueous_solution_2: $i > $i).
% 29.22/29.06  tff(decl_47587, type, fn_isotonic_solution_11: $i > $i).
% 29.22/29.06  tff(decl_47588, type, fn_aqueous_solution_6: $i > $i).
% 29.22/29.06  tff(decl_47589, type, fn_isotonic_solution_21: $i > $i).
% 29.22/29.06  tff(decl_47590, type, fn_aqueous_solution_8: $i > $i).
% 29.22/29.06  tff(decl_47591, type, fn_isotonic_solution_17: $i > $i).
% 29.22/29.06  tff(decl_47592, type, fn_isotonic_solution_18: $i > $i).
% 29.22/29.06  tff(decl_47593, type, 'Isotope': $i).
% 29.22/29.06  tff(decl_47594, type, 'Isotopes are different types of atoms of the same chemical element, each having a different number of neutrons. In a corresponding manner, isotopes differ in mass number (or number of nucleons) but never in atomic number. The number of protons (the atomic number) is the same because that is what characterizes a chemical element.': $i).
% 29.22/29.06  tff(decl_47595, type, isotope: $i).
% 29.22/29.06  tff(decl_47596, type, isotope_conversion_1: $i > $o).
% 29.22/29.06  tff(decl_47597, type, 'Isotope-Conversion': $i).
% 29.22/29.06  tff(decl_47598, type, 'The process in which an isotope of an element is converted to a lighter isotope of the same element through the loss of one or more neutrons.': $i).
% 29.22/29.06  tff(decl_47599, type, 'conversion of isotope': $i).
% 29.22/29.06  tff(decl_47600, type, 'isotope conversion': $i).
% 29.22/29.06  tff(decl_47601, type, 'isotope-conversion': $i).
% 29.22/29.06  tff(decl_47602, type, fn_isotope_conversion_1: $i > $i).
% 29.22/29.06  tff(decl_47603, type, fn_isotope_conversion_2: $i > $i).
% 29.22/29.06  tff(decl_47604, type, fn_isotope_conversion_3: $i > $i).
% 29.22/29.06  tff(decl_47605, type, fn_isotope_conversion_4: $i > $i).
% 29.22/29.06  tff(decl_47606, type, fn_isotope_conversion_5: $i > $i).
% 29.22/29.06  tff(decl_47607, type, fn_isotope_conversion_6: $i > $i).
% 29.22/29.06  tff(decl_47608, type, fn_isotope_conversion_11: $i > $i).
% 29.22/29.06  tff(decl_47609, type, fn_isotope_conversion_12: $i > $i).
% 29.22/29.06  tff(decl_47610, type, fn_isotope_conversion_13: $i > $i).
% 29.22/29.06  tff(decl_47611, type, fn_isotope_conversion_14: $i > $i).
% 29.22/29.06  tff(decl_47612, type, fn_isotope_conversion_15: $i > $i).
% 29.22/29.06  tff(decl_47613, type, fn_isotope_conversion_16: $i > $i).
% 29.22/29.06  tff(decl_47614, type, fn_isotope_conversion_17: $i > $i).
% 29.22/29.06  tff(decl_47615, type, fn_radioactive_isotope_2: $i > $i).
% 29.22/29.06  tff(decl_47616, type, fn_radioactive_isotope_1: $i > $i).
% 29.22/29.06  tff(decl_47617, type, 'Isotopic-Labeling': $i).
% 29.22/29.06  tff(decl_47618, type, 'A technique for tracking the passage of a sample of a substance through a system by incorporating an unusual isotopes in its chemical composition allowing the substance to be detected.': $i).
% 29.22/29.06  tff(decl_47619, type, 'radioactive labeling': $i).
% 29.22/29.06  tff(decl_47620, type, 'radioactive-labeling': $i).
% 29.22/29.06  tff(decl_47621, type, 'radioisotope labeling': $i).
% 29.22/29.06  tff(decl_47622, type, 'radioisotope-labeling': $i).
% 29.22/29.06  tff(decl_47623, type, 'isotopic labeling': $i).
% 29.22/29.06  tff(decl_47624, type, 'isotopic-labeling': $i).
% 29.22/29.06  tff(decl_47625, type, fn_isotopic_labeling_1: $i > $i).
% 29.22/29.06  tff(decl_47626, type, fn_isotopic_labeling_2: $i > $i).
% 29.22/29.06  tff(decl_47627, type, fn_isotopic_labeling_3: $i > $i).
% 29.22/29.06  tff(decl_47628, type, 'Iteroparity': $i).
% 29.22/29.06  tff(decl_47629, type, 'The ability to produce offspring over several years.': $i).
% 29.22/29.06  tff(decl_47630, type, 'repeated reproduction': $i).
% 29.22/29.06  tff(decl_47631, type, 'repeated-reproduction': $i).
% 29.22/29.06  tff(decl_47632, type, iteroparity: $i).
% 29.22/29.06  tff(decl_47633, type, iva_element_1: $i > $o).
% 29.22/29.06  tff(decl_47634, type, 'IVA-Element': $i).
% 29.22/29.06  tff(decl_47635, type, 'Elements in group 4A of the periodic table are C, Si, Ge, Sn, Pb and the unnamed element 114.': $i).
% 29.22/29.06  tff(decl_47636, type, iva: $i).
% 29.22/29.06  tff(decl_47637, type, 'group iva elements': $i).
% 29.22/29.06  tff(decl_47638, type, 'group-iva-elements': $i).
% 29.22/29.06  tff(decl_47639, type, 'group 14 elements': $i).
% 29.22/29.06  tff(decl_47640, type, 'group-14-elements': $i).
% 29.22/29.06  tff(decl_47641, type, 'element of iva': $i).
% 29.22/29.06  tff(decl_47642, type, 'iva element': $i).
% 29.22/29.06  tff(decl_47643, type, 'iva-element': $i).
% 29.22/29.06  tff(decl_47644, type, jackbean_plant_1: $i > $o).
% 29.22/29.06  tff(decl_47645, type, 'Jackbean-Plant': $i).
% 29.22/29.06  tff(decl_47646, type, 'Vining legume with toxic leaves, important commercially as a source for several proteins used in biochemistry research.': $i).
% 29.22/29.06  tff(decl_47647, type, 'jackbean plant': $i).
% 29.22/29.06  tff(decl_47648, type, 'jackbean-plant': $i).
% 29.22/29.06  tff(decl_47649, type, james_danielli_1: $i > $o).
% 29.22/29.06  tff(decl_47650, type, 'James-Danielli': $i).
% 29.22/29.06  tff(decl_47651, type, 'james danielle': $i).
% 29.22/29.06  tff(decl_47652, type, 'james-danielle': $i).
% 29.22/29.06  tff(decl_47653, type, 'james danielli': $i).
% 29.22/29.06  tff(decl_47654, type, 'james-danielli': $i).
% 29.22/29.06  tff(decl_47655, type, jasmonic_acid_1: $i > $o).
% 29.22/29.06  tff(decl_47656, type, 'Jasmonic-Acid': $i).
% 29.22/29.06  tff(decl_47657, type, 'A chemical produced by plants that regulates various aspects of growth, development, and responses to abiotic or biotic stresses.': $i).
% 29.22/29.06  tff(decl_47658, type, 'jasmonic acid': $i).
% 29.22/29.06  tff(decl_47659, type, 'jasmonic-acid': $i).
% 29.22/29.06  tff(decl_47660, type, 'Jaw': $i).
% 29.22/29.06  tff(decl_47661, type, 'Any articulated, opposable structure located near the mouth, used for manipulating or grasping food.': $i).
% 29.22/29.06  tff(decl_47662, type, mandible: $i).
% 29.22/29.06  tff(decl_47663, type, maxilla: $i).
% 29.22/29.06  tff(decl_47664, type, jaw: $i).
% 29.22/29.06  tff(decl_47665, type, jejunum_1: $i > $o).
% 29.22/29.06  tff(decl_47666, type, 'Jejunum': $i).
% 29.22/29.06  tff(decl_47667, type, 'The middle section of the small intestine in most higher vertebrates, situated between the duodenum and the ileum. It is lined with villi and microvilli and functions in nutrient and water absorption.': $i).
% 29.22/29.06  tff(decl_47668, type, jejunum: $i).
% 29.22/29.06  tff(decl_47669, type, 'Joint': $i).
% 29.22/29.06  tff(decl_47670, type, 'The articulated junction where two bones meet.': $i).
% 29.22/29.06  tff(decl_47671, type, joint: $i).
% 29.22/29.06  tff(decl_47672, type, skeletal_organ_1: $i > $o).
% 29.22/29.06  tff(decl_47673, type, juvenile_hormone_1: $i > $o).
% 29.22/29.06  tff(decl_47674, type, 'Juvenile-Hormone': $i).
% 29.22/29.06  tff(decl_47675, type, 'An arthropod hormone that promotes the retention of larval characteristics and retards the onset of metamorphosis.': $i).
% 29.22/29.06  tff(decl_47676, type, 'hormone of juvenile': $i).
% 29.22/29.06  tff(decl_47677, type, 'juvenile hormone': $i).
% 29.22/29.06  tff(decl_47678, type, 'juvenile-hormone': $i).
% 29.22/29.06  tff(decl_47679, type, releasing_hormone_1: $i > $o).
% 29.22/29.06  tff(decl_47680, type, 'Juvenile-Stage': $i).
% 29.22/29.06  tff(decl_47681, type, 'A juvenile stage is a stage in the development when an individual organism has not reached its adult form, sexual maturity or size.': $i).
% 29.22/29.06  tff(decl_47682, type, 'stage of juvenile': $i).
% 29.22/29.06  tff(decl_47683, type, 'juvenile stage': $i).
% 29.22/29.06  tff(decl_47684, type, 'juvenile-stage': $i).
% 29.22/29.06  tff(decl_47685, type, juxtaglomerular_apparatus_1: $i > $o).
% 29.22/29.06  tff(decl_47686, type, 'Juxtaglomerular-Apparatus': $i).
% 29.22/29.06  tff(decl_47687, type, 'Specialized tissues located near the afferent arteriole that supplies blood to the glomerulus; the apparatus is involved in regulating kindey function.': $i).
% 29.22/29.06  tff(decl_47688, type, jga: $i).
% 29.22/29.06  tff(decl_47689, type, 'juxtaglomerular apparatus': $i).
% 29.22/29.06  tff(decl_47690, type, 'juxtaglomerular-apparatus': $i).
% 29.22/29.06  tff(decl_47691, type, mixed_tissue_1: $i > $o).
% 29.22/29.06  tff(decl_47692, type, 'Juxtamedullary-Nephron': $i).
% 29.22/29.06  tff(decl_47693, type, 'Type of nephron found only in mammals and birds. Juxtamedullary nephrons have a loop of Henle that is located deep in the medulla of the kidney.': $i).
% 29.22/29.06  tff(decl_47694, type, 'juxtamedullary nephron': $i).
% 29.22/29.06  tff(decl_47695, type, 'juxtamedullary-nephron': $i).
% 29.22/29.06  tff(decl_47696, type, k_selection_1: $i > $o).
% 29.22/29.06  tff(decl_47697, type, 'K-selection': $i).
% 29.22/29.06  tff(decl_47698, type, 'Selection for life history traits that are sensitive to population density': $i).
% 29.22/29.06  tff(decl_47699, type, 'density dependent selection': $i).
% 29.22/29.06  tff(decl_47700, type, 'density-dependent selection': $i).
% 29.22/29.06  tff(decl_47701, type, 'selection of k': $i).
% 29.22/29.06  tff(decl_47702, type, 'k selection': $i).
% 29.22/29.06  tff(decl_47703, type, 'k-selection': $i).
% 29.22/29.06  tff(decl_47704, type, r_selection_1: $i > $o).
% 29.22/29.06  tff(decl_47705, type, reinforcement_1: $i > $o).
% 29.22/29.06  tff(decl_47706, type, stabilizing_selection_1: $i > $o).
% 29.22/29.06  tff(decl_47707, type, 'Kangaroo': $i).
% 29.22/29.06  tff(decl_47708, type, 'Australian marsupial of the family Macropodidae.': $i).
% 29.22/29.06  tff(decl_47709, type, kangaroo: $i).
% 29.22/29.06  tff(decl_47710, type, karyogamy_1: $i > $o).
% 29.22/29.06  tff(decl_47711, type, 'Karyogamy': $i).
% 29.22/29.06  tff(decl_47712, type, 'The union and fusion of two pronuclei, as in fertilization.': $i).
% 29.22/29.06  tff(decl_47713, type, 'perform karyogamy': $i).
% 29.22/29.06  tff(decl_47714, type, karyogamy: $i).
% 29.22/29.06  tff(decl_47715, type, karyotype_1: $i > $o).
% 29.22/29.06  tff(decl_47716, type, 'Karyotype': $i).
% 29.22/29.06  tff(decl_47717, type, 'A karyotype is a visual arrangement of the chromosomes from a cell where the chromosomes are displayed to inspect for potential abnormalities.': $i).
% 29.22/29.06  tff(decl_47718, type, 'chromosome map': $i).
% 29.22/29.06  tff(decl_47719, type, karyotype: $i).
% 29.22/29.06  tff(decl_47720, type, fn_karyotype_1: $i > $i).
% 29.22/29.06  tff(decl_47721, type, fn_karyotype_3: $i > $i).
% 29.22/29.06  tff(decl_47722, type, fn_karyotype_4: $i > $i).
% 29.22/29.06  tff(decl_47723, type, fn_karyotype_5: $i > $i).
% 29.22/29.06  tff(decl_47724, type, fn_karyotype_6: $i > $i).
% 29.22/29.06  tff(decl_47725, type, fn_karyotype_7: $i > $i).
% 29.22/29.06  tff(decl_47726, type, fn_karyotype_8: $i > $i).
% 29.22/29.06  tff(decl_47727, type, fn_karyotype_9: $i > $i).
% 29.22/29.06  tff(decl_47728, type, fn_karyotype_10: $i > $i).
% 29.22/29.06  tff(decl_47729, type, fn_karyotype_11: $i > $i).
% 29.22/29.06  tff(decl_47730, type, perceive_1: $i > $o).
% 29.22/29.06  tff(decl_47731, type, 'Karyotyping': $i).
% 29.22/29.06  tff(decl_47732, type, 'A laboratory procedure which involves displaying a cell\\s chromosomes. The number and appearance of a cell\\s chromosome can be useful in helping to diagnose some congenital disorders such as Down syndrome.': $i).
% 29.22/29.06  tff(decl_47733, type, karyotyping: $i).
% 29.22/29.06  tff(decl_47734, type, fn_karyotyping_1: $i > $i).
% 29.22/29.06  tff(decl_47735, type, fn_karyotyping_2: $i > $i).
% 29.22/29.06  tff(decl_47736, type, fn_karyotyping_3: $i > $i).
% 29.22/29.06  tff(decl_47737, type, fn_karyotyping_4: $i > $i).
% 29.22/29.06  tff(decl_47738, type, fn_karyotyping_5: $i > $i).
% 29.22/29.06  tff(decl_47739, type, fn_karyotyping_6: $i > $i).
% 29.22/29.06  tff(decl_47740, type, fn_karyotyping_7: $i > $i).
% 29.22/29.06  tff(decl_47741, type, fn_karyotyping_8: $i > $i).
% 29.22/29.06  tff(decl_47742, type, fn_karyotyping_9: $i > $i).
% 29.22/29.06  tff(decl_47743, type, fn_karyotyping_10: $i > $i).
% 29.22/29.06  tff(decl_47744, type, kelp_1: $i > $o).
% 29.22/29.06  tff(decl_47745, type, 'Kelp': $i).
% 29.22/29.06  tff(decl_47746, type, 'Giant seaweeds that live in deeper waters beyond the marine intertidal zone.': $i).
% 29.22/29.06  tff(decl_47747, type, kelp: $i).
% 29.22/29.06  tff(decl_47748, type, 'Keratin': $i).
% 29.22/29.06  tff(decl_47749, type, 'Keratins are a family of proteins that are components of skin, hair, nails and claws.  Keratins also form the intermediate filaments of the cytoskeleton.': $i).
% 29.22/29.06  tff(decl_47750, type, keratin: $i).
% 29.22/29.06  tff(decl_47751, type, fn_keratin_1: $i > $i).
% 29.22/29.06  tff(decl_47752, type, fn_keratin_6: $i > $i).
% 29.22/29.06  tff(decl_47753, type, fn_keratin_7: $i > $i).
% 29.22/29.06  tff(decl_47754, type, fn_keratin_8: $i > $i).
% 29.22/29.06  tff(decl_47755, type, fn_keratin_9: $i > $i).
% 29.22/29.06  tff(decl_47756, type, fn_keratin_10: $i > $i).
% 29.22/29.06  tff(decl_47757, type, fn_keratin_11: $i > $i).
% 29.22/29.06  tff(decl_47758, type, fn_keratin_12: $i > $i).
% 29.22/29.06  tff(decl_47759, type, fn_keratin_13: $i > $i).
% 29.22/29.06  tff(decl_47760, type, fn_keratin_14: $i > $i).
% 29.22/29.06  tff(decl_47761, type, fn_keratin_15: $i > $i).
% 29.22/29.06  tff(decl_47762, type, fn_keratin_16: $i > $i).
% 29.22/29.06  tff(decl_47763, type, fn_keratin_17: $i > $i).
% 29.22/29.06  tff(decl_47764, type, fn_keratin_18: $i > $i).
% 29.22/29.06  tff(decl_47765, type, fn_keratin_19: $i > $i).
% 29.22/29.06  tff(decl_47766, type, fn_keratin_20: $i > $i).
% 29.22/29.06  tff(decl_47767, type, fn_keratin_21: $i > $i).
% 29.22/29.06  tff(decl_47768, type, fn_keratin_22: $i > $i).
% 29.22/29.06  tff(decl_47769, type, fn_keratin_23: $i > $i).
% 29.22/29.06  tff(decl_47770, type, fn_keratin_24: $i > $i).
% 29.22/29.06  tff(decl_47771, type, fn_keratin_25: $i > $i).
% 29.22/29.06  tff(decl_47772, type, fn_keratin_26: $i > $i).
% 29.22/29.06  tff(decl_47773, type, fn_keratin_27: $i > $i).
% 29.22/29.06  tff(decl_47774, type, fn_keratin_28: $i > $i).
% 29.22/29.06  tff(decl_47775, type, fn_keratin_29: $i > $i).
% 29.22/29.06  tff(decl_47776, type, fn_keratin_30: $i > $i).
% 29.22/29.06  tff(decl_47777, type, fn_keratin_31: $i > $i).
% 29.22/29.06  tff(decl_47778, type, fn_keratin_32: $i > $i).
% 29.22/29.06  tff(decl_47779, type, fn_keratin_33: $i > $i).
% 29.22/29.06  tff(decl_47780, type, fn_keratin_34: $i > $i).
% 29.22/29.06  tff(decl_47781, type, fn_keratin_35: $i > $i).
% 29.22/29.06  tff(decl_47782, type, fn_keratin_36: $i > $i).
% 29.22/29.06  tff(decl_47783, type, fn_keratin_37: $i > $i).
% 29.22/29.06  tff(decl_47784, type, fn_keratin_38: $i > $i).
% 29.22/29.06  tff(decl_47785, type, fn_keratin_39: $i > $i).
% 29.22/29.06  tff(decl_47786, type, fn_keratin_40: $i > $i).
% 29.22/29.06  tff(decl_47787, type, fn_keratin_41: $i > $i).
% 29.22/29.06  tff(decl_47788, type, fn_keratin_42: $i > $i).
% 29.22/29.06  tff(decl_47789, type, fn_keratin_5: $i > $i).
% 29.22/29.06  tff(decl_47790, type, fn_keratin_3: $i > $i).
% 29.22/29.06  tff(decl_47791, type, fn_keratin_2: $i > $i).
% 29.22/29.06  tff(decl_47792, type, fn_keratin_4: $i > $i).
% 29.22/29.06  tff(decl_47793, type, 'Ketone': $i).
% 29.22/29.06  tff(decl_47794, type, 'Ketone  is a compound with the structure RC(=O)R\\, where R and R\\ can be a variety of atoms and groups of atoms.': $i).
% 29.22/29.06  tff(decl_47795, type, ketone: $i).
% 29.22/29.06  tff(decl_47796, type, 'Ketose': $i).
% 29.22/29.06  tff(decl_47797, type, 'A ketose is a sugar containing one ketone group per molecule.': $i).
% 29.22/29.06  tff(decl_47798, type, 'ketose sugar': $i).
% 29.22/29.06  tff(decl_47799, type, 'ketose-sugar': $i).
% 29.22/29.06  tff(decl_47800, type, ketose: $i).
% 29.22/29.06  tff(decl_47801, type, 'Keystone-Species': $i).
% 29.22/29.06  tff(decl_47802, type, 'A species whose effect on community structure is disproportionately larger than its abundance within the community.': $i).
% 29.22/29.06  tff(decl_47803, type, 'keystone-species': $i).
% 29.22/29.06  tff(decl_47804, type, 'species of keystone': $i).
% 29.22/29.06  tff(decl_47805, type, 'keystone species': $i).
% 29.22/29.06  tff(decl_47806, type, 'keystone-specy': $i).
% 29.22/29.06  tff(decl_47807, type, ki_constant_1: $i > $o).
% 29.22/29.06  tff(decl_47808, type, 'KI-Constant': $i).
% 29.22/29.06  tff(decl_47809, type, 'constant of ki': $i).
% 29.22/29.06  tff(decl_47810, type, 'ki constant': $i).
% 29.22/29.06  tff(decl_47811, type, 'ki-constant': $i).
% 29.22/29.06  tff(decl_47812, type, ki_scale_1: $i > $o).
% 29.22/29.06  tff(decl_47813, type, 'KI-Scale': $i).
% 29.22/29.06  tff(decl_47814, type, 'scale of ki': $i).
% 29.22/29.06  tff(decl_47815, type, 'ki scale': $i).
% 29.22/29.06  tff(decl_47816, type, 'ki-scale': $i).
% 29.22/29.06  tff(decl_47817, type, kidney_1: $i > $o).
% 29.22/29.06  tff(decl_47818, type, 'Kidney': $i).
% 29.22/29.06  tff(decl_47819, type, 'An excretory and osmoregularity organ in animals.': $i).
% 29.22/29.06  tff(decl_47820, type, kidney: $i).
% 29.22/29.06  tff(decl_47821, type, fn_kidney_2: $i > $i).
% 29.22/29.06  tff(decl_47822, type, fn_kidney_3: $i > $i).
% 29.22/29.06  tff(decl_47823, type, fn_kidney_4: $i > $i).
% 29.22/29.06  tff(decl_47824, type, fn_kidney_5: $i > $i).
% 29.22/29.06  tff(decl_47825, type, fn_kidney_6: $i > $i).
% 29.22/29.06  tff(decl_47826, type, 'Killdeer': $i).
% 29.22/29.06  tff(decl_47827, type, 'A medium-sized bird of the plover family, known for its': $i).
% 29.22/29.06  tff(decl_47828, type, killdeer: $i).
% 29.22/29.06  tff(decl_47829, type, kin_selection_1: $i > $o).
% 29.22/29.06  tff(decl_47830, type, 'Kin-Selection': $i).
% 29.22/29.06  tff(decl_47831, type, 'An evolutionary strategy that benefits the reproductive fitness of one\\s kin at the expense of one\\s own fitness. Often results in the evolution of altruistic behavior.': $i).
% 29.22/29.06  tff(decl_47832, type, 'selection of kin': $i).
% 29.22/29.06  tff(decl_47833, type, 'kin selection': $i).
% 29.22/29.06  tff(decl_47834, type, 'kin-selection': $i).
% 29.22/29.06  tff(decl_47835, type, 'Kinase': $i).
% 29.22/29.06  tff(decl_47836, type, 'General name for an enzyme that transfers phosphate groups from ATP to a protein, thus phosphorylating the protein.': $i).
% 29.22/29.06  tff(decl_47837, type, 'protein kinase': $i).
% 29.22/29.06  tff(decl_47838, type, 'protein-kinase': $i).
% 29.22/29.06  tff(decl_47839, type, kinase: $i).
% 29.22/29.06  tff(decl_47840, type, fn_kinase_2: $i > $i).
% 29.22/29.06  tff(decl_47841, type, fn_kinase_3: $i > $i).
% 29.22/29.06  tff(decl_47842, type, kinesis_1: $i > $o).
% 29.22/29.06  tff(decl_47843, type, 'Kinesis': $i).
% 29.22/29.06  tff(decl_47844, type, 'Movement or activity of a cell or organism in response to a nondirectional stimulus.': $i).
% 29.22/29.06  tff(decl_47845, type, kinesis: $i).
% 29.22/29.06  tff(decl_47846, type, 'Kinetic-Energy': $i).
% 29.22/29.06  tff(decl_47847, type, 'The energy that an object possesses due to its motion relative to other objects.': $i).
% 29.22/29.06  tff(decl_47848, type, 'kinetic energy': $i).
% 29.22/29.06  tff(decl_47849, type, 'kinetic-energy': $i).
% 29.22/29.06  tff(decl_47850, type, 'Kinetochore': $i).
% 29.22/29.06  tff(decl_47851, type, 'A complex of proteins on the centromere of a chromatid, where the mitotic spindle attaches during mitosis or meiosis.': $i).
% 29.22/29.06  tff(decl_47852, type, kinetochore: $i).
% 29.22/29.06  tff(decl_47853, type, fn_kinetochore_8: $i > $i).
% 29.22/29.06  tff(decl_47854, type, fn_kinetochore_9: $i > $i).
% 29.22/29.06  tff(decl_47855, type, fn_kinetochore_10: $i > $i).
% 29.22/29.06  tff(decl_47856, type, fn_kinetochore_11: $i > $i).
% 29.22/29.06  tff(decl_47857, type, fn_kinetochore_12: $i > $i).
% 29.22/29.06  tff(decl_47858, type, fn_kinetochore_13: $i > $i).
% 29.22/29.06  tff(decl_47859, type, fn_kinetochore_14: $i > $i).
% 29.22/29.06  tff(decl_47860, type, fn_kinetochore_15: $i > $i).
% 29.22/29.06  tff(decl_47861, type, fn_kinetochore_16: $i > $i).
% 29.22/29.06  tff(decl_47862, type, fn_kinetochore_17: $i > $i).
% 29.22/29.06  tff(decl_47863, type, fn_kinetochore_18: $i > $i).
% 29.22/29.06  tff(decl_47864, type, fn_kinetochore_19: $i > $i).
% 29.22/29.06  tff(decl_47865, type, fn_kinetochore_20: $i > $i).
% 29.22/29.06  tff(decl_47866, type, fn_kinetochore_21: $i > $i).
% 29.22/29.06  tff(decl_47867, type, fn_kinetochore_22: $i > $i).
% 29.22/29.06  tff(decl_47868, type, fn_kinetochore_23: $i > $i).
% 29.22/29.06  tff(decl_47869, type, fn_kinetochore_26: $i > $i).
% 29.22/29.06  tff(decl_47870, type, "0.5e0": $i).
% 29.22/29.06  tff(decl_47871, type, fn_kinetochore_7: $i > $i).
% 29.22/29.06  tff(decl_47872, type, fn_kinetochore_6: $i > $i).
% 29.22/29.06  tff(decl_47873, type, fn_kinetochore_4: $i > $i).
% 29.22/29.06  tff(decl_47874, type, fn_kinetochore_5: $i > $i).
% 29.22/29.06  tff(decl_47875, type, fn_kinetochore_3: $i > $i).
% 29.22/29.06  tff(decl_47876, type, 'Kinetochore-Microtubule': $i).
% 29.22/29.06  tff(decl_47877, type, 'Kinetochore microtubule is a microtubule which attach to kinetochore during cell division and helps in segregation of chromosomes and chromatids in their respective daughter cells': $i).
% 29.22/29.06  tff(decl_47878, type, 'microtubule of kinetochore': $i).
% 29.22/29.06  tff(decl_47879, type, 'kinetochore microtubule': $i).
% 29.22/29.06  tff(decl_47880, type, 'kinetochore-microtubule': $i).
% 29.22/29.06  tff(decl_47881, type, fn_kinetochore_microtubule_1: $i > $i).
% 29.22/29.06  tff(decl_47882, type, fn_kinetochore_microtubule_2: $i > $i).
% 29.22/29.06  tff(decl_47883, type, 'Kinetoplastid': $i).
% 29.22/29.06  tff(decl_47884, type, 'One of a group of flagellated protozoans, distinguished by the presence of a DNA-containing granule located inside the single large mitochondrion. Many kinetoplastids, such as trypanosomes, cause disease in humans and other animals.': $i).
% 29.22/29.06  tff(decl_47885, type, kinetoplastid: $i).
% 29.22/29.06  tff(decl_47886, type, kingdom_1: $i > $o).
% 29.22/29.06  tff(decl_47887, type, 'Kingdom': $i).
% 29.22/29.06  tff(decl_47888, type, 'In Linnean taxonomy, the category above phylum and below domain.': $i).
% 29.22/29.06  tff(decl_47889, type, kingdom: $i).
% 29.22/29.06  tff(decl_47890, type, 'Klinefelter-Syndrome': $i).
% 29.22/29.06  tff(decl_47891, type, 'a condition in which human males have an extra (an aneuploidy) X sex chromosome.': $i).
% 29.22/29.06  tff(decl_47892, type, xxy: $i).
% 29.22/29.06  tff(decl_47893, type, 'syndrome of klinefelter': $i).
% 29.22/29.06  tff(decl_47894, type, 'klinefelter syndrome': $i).
% 29.22/29.06  tff(decl_47895, type, 'klinefelter-syndrome': $i).
% 29.22/29.06  tff(decl_47896, type, fn_klinefelter_syndrome_2: $i > $i).
% 29.22/29.06  tff(decl_47897, type, fn_klinefelter_syndrome_3: $i > $i).
% 29.22/29.06  tff(decl_47898, type, fn_klinefelter_syndrome_5: $i > $i).
% 29.22/29.06  tff(decl_47899, type, fn_klinefelter_syndrome_6: $i > $i).
% 29.22/29.06  tff(decl_47900, type, fn_klinefelter_syndrome_7: $i > $i).
% 29.22/29.06  tff(decl_47901, type, y_chromosome_1: $i > $o).
% 29.22/29.06  tff(decl_47902, type, fn_klinefelter_syndrome_8: $i > $i).
% 29.22/29.06  tff(decl_47903, type, fn_klinefelter_syndrome_10: $i > $i).
% 29.22/29.06  tff(decl_47904, type, fn_klinefelter_syndrome_11: $i > $i).
% 29.22/29.06  tff(decl_47905, type, fn_klinefelter_syndrome_12: $i > $i).
% 29.22/29.06  tff(decl_47906, type, testes_0: $i).
% 29.22/29.06  tff(decl_47907, type, 'KM-Class': $i).
% 29.22/29.06  tff(decl_47908, type, 'class of km': $i).
% 29.22/29.06  tff(decl_47909, type, 'km class': $i).
% 29.22/29.06  tff(decl_47910, type, 'km-class': $i).
% 29.22/29.06  tff(decl_47911, type, 'KM-Slot-Group': $i).
% 29.22/29.06  tff(decl_47912, type, 'km slot group': $i).
% 29.22/29.06  tff(decl_47913, type, 'km-slot-group': $i).
% 29.22/29.06  tff(decl_47914, type, knee_jerk_reflex_1: $i > $o).
% 29.22/29.06  tff(decl_47915, type, 'Knee-Jerk-Reflex': $i).
% 29.22/29.06  tff(decl_47916, type, 'Also called the patellar reflex.  Occurs when the patellar tendon is suddenly and unexpectedly stretched. The sensory neuron detecting the stretch signals a motor neuron to rapidly counteract the stretch by commanding the quadriceps to contract, causing the lower leg to jerk forward.': $i).
% 29.22/29.06  tff(decl_47917, type, 'knee jerk reflex': $i).
% 29.22/29.06  tff(decl_47918, type, 'knee-jerk-reflex': $i).
% 29.22/29.06  tff(decl_47919, type, reflex_1: $i > $o).
% 29.22/29.06  tff(decl_47920, type, swallowing_reflex_1: $i > $o).
% 29.22/29.06  tff(decl_47921, type, 'Knob': $i).
% 29.22/29.06  tff(decl_47922, type, 'Knob is a part of ATP Synthase': $i).
% 29.22/29.06  tff(decl_47923, type, 'catalytic knob': $i).
% 29.22/29.06  tff(decl_47924, type, 'catalytic-knob': $i).
% 29.22/29.06  tff(decl_47925, type, knob: $i).
% 29.22/29.06  tff(decl_47926, type, fn_knob_2: $i > $i).
% 29.22/29.06  tff(decl_47927, type, fn_knob_3: $i > $i).
% 29.22/29.06  tff(decl_47928, type, fn_knob_4: $i > $i).
% 29.22/29.06  tff(decl_47929, type, active_site_0: $i).
% 29.22/29.06  tff(decl_47930, type, 'Krill': $i).
% 29.22/29.06  tff(decl_47931, type, 'Members of the order Euphausiacea. These shrimp-like marine crustaceans are found in all oceans and are an important component of pelagic food webs.': $i).
% 29.22/29.06  tff(decl_47932, type, krill: $i).
% 29.22/29.06  tff(decl_47933, type, krypton_1: $i > $o).
% 29.22/29.06  tff(decl_47934, type, 'Krypton': $i).
% 29.22/29.06  tff(decl_47935, type, 'Krypton is a non metal atom with atomic number 36. It is represented by the symbol Kr.': $i).
% 29.22/29.06  tff(decl_47936, type, 'Kr': $i).
% 29.22/29.06  tff(decl_47937, type, krypton: $i).
% 29.22/29.06  tff(decl_47938, type, fn_krypton_4: $i > $i).
% 29.22/29.06  tff(decl_47939, type, fn_krypton_5: $i > $i).
% 29.22/29.06  tff(decl_47940, type, fn_krypton_6: $i > $i).
% 29.22/29.06  tff(decl_47941, type, fn_krypton_7: $i > $i).
% 29.22/29.06  tff(decl_47942, type, fn_krypton_11: $i > $i).
% 29.22/29.06  tff(decl_47943, type, fn_krypton_12: $i > $i).
% 29.22/29.06  tff(decl_47944, type, fn_krypton_13: $i > $i).
% 29.22/29.06  tff(decl_47945, type, fn_krypton_14: $i > $i).
% 29.22/29.06  tff(decl_47946, type, "36": $i).
% 29.22/29.06  tff(decl_47947, type, "84": $i).
% 29.22/29.06  tff(decl_47948, type, "83.8": $i).
% 29.22/29.06  tff(decl_47949, type, fn_krypton_9: $i > $i).
% 29.22/29.06  tff(decl_47950, type, fn_krypton_8: $i > $i).
% 29.22/29.06  tff(decl_47951, type, fn_krypton_10: $i > $i).
% 29.22/29.06  tff(decl_47952, type, kudzu_1: $i > $o).
% 29.22/29.06  tff(decl_47953, type, 'Kudzu': $i).
% 29.22/29.06  tff(decl_47954, type, 'The common name for one of five species of legumes in the genus  Pueraria which are native to southern Japan and southeastern China. Inregions such as the souther United States, kudzu has been introduced intentionally and has become a noxious weed.': $i).
% 29.22/29.06  tff(decl_47955, type, 'kudzu vine': $i).
% 29.22/29.06  tff(decl_47956, type, 'kudzu-vine': $i).
% 29.22/29.06  tff(decl_47957, type, kudzu: $i).
% 29.22/29.06  tff(decl_47958, type, fn_kudzu_1: $i > $i).
% 29.22/29.06  tff(decl_47959, type, fn_kudzu_2: $i > $i).
% 29.22/29.06  tff(decl_47960, type, fn_kudzu_3: $i > $i).
% 29.22/29.06  tff(decl_47961, type, l1_sequence_1: $i > $o).
% 29.22/29.06  tff(decl_47962, type, 'L1-Sequence': $i).
% 29.22/29.06  tff(decl_47963, type, 'A type of mobile DNA which can amplify itself and move within the genome.': $i).
% 29.22/29.06  tff(decl_47964, type, 'l1 gene sequence': $i).
% 29.22/29.06  tff(decl_47965, type, 'l1 gene': $i).
% 29.22/29.06  tff(decl_47966, type, 'line 1 sequence': $i).
% 29.22/29.06  tff(decl_47967, type, 'line-1-sequence': $i).
% 29.22/29.06  tff(decl_47968, type, 'line one sequence': $i).
% 29.22/29.06  tff(decl_47969, type, 'line-one-sequence': $i).
% 29.22/29.06  tff(decl_47970, type, 'l1 retrotransposon': $i).
% 29.22/29.06  tff(decl_47971, type, 'l1-retrotransposon': $i).
% 29.22/29.06  tff(decl_47972, type, 'line one retrotransposon': $i).
% 29.22/29.06  tff(decl_47973, type, 'line-one-retrotransposon': $i).
% 29.22/29.06  tff(decl_47974, type, 'long interspersed nuclear element': $i).
% 29.22/29.06  tff(decl_47975, type, 'long-interspersed-nuclear-element': $i).
% 29.22/29.06  tff(decl_47976, type, 'l1 sequence': $i).
% 29.22/29.06  tff(decl_47977, type, 'l1-sequence': $i).
% 29.22/29.06  tff(decl_47978, type, 'Labia-Majora': $i).
% 29.22/29.06  tff(decl_47979, type, 'A pair of thick, cutaneous folds that extend from the mons pubis to the perineum.': $i).
% 29.22/29.06  tff(decl_47980, type, 'labia majora': $i).
% 29.22/29.06  tff(decl_47981, type, 'labia-majora': $i).
% 29.22/29.06  tff(decl_47982, type, 'Labia-Minora': $i).
% 29.22/29.06  tff(decl_47983, type, 'A pair of flaps of skin surrounding the vaginal and urethral openings.': $i).
% 29.22/29.06  tff(decl_47984, type, 'labia minusa': $i).
% 29.22/29.06  tff(decl_47985, type, 'labia minora': $i).
% 29.22/29.06  tff(decl_47986, type, 'labia-minora': $i).
% 29.22/29.06  tff(decl_47987, type, labor_1: $i > $o).
% 29.22/29.06  tff(decl_47988, type, 'Labor': $i).
% 29.22/29.06  tff(decl_47989, type, 'A series of strong, repeated contractions that push a baby from the uterus.': $i).
% 29.22/29.06  tff(decl_47990, type, labor: $i).
% 29.22/29.06  tff(decl_47991, type, labor_and_delivery_1: $i > $o).
% 29.22/29.06  tff(decl_47992, type, 'Labor-And-Delivery': $i).
% 29.22/29.06  tff(decl_47993, type, 'The process of giving birth to offspring.': $i).
% 29.22/29.06  tff(decl_47994, type, 'labor and delivery': $i).
% 29.22/29.06  tff(decl_47995, type, 'labor-and-delivery': $i).
% 29.22/29.06  tff(decl_47996, type, 'Laboratory': $i).
% 29.22/29.06  tff(decl_47997, type, 'A workplace for conducting scientificresearch.': $i).
% 29.22/29.06  tff(decl_47998, type, laboratory: $i).
% 29.22/29.06  tff(decl_47999, type, 'Lac-Operon': $i).
% 29.22/29.06  tff(decl_48000, type, 'A group of genes that regulates the synthesis of enzymes that take up and metabolize lactose.': $i).
% 29.22/29.06  tff(decl_48001, type, 'operon of lac': $i).
% 29.22/29.06  tff(decl_48002, type, 'lac operon': $i).
% 29.22/29.06  tff(decl_48003, type, 'lac-operon': $i).
% 29.22/29.06  tff(decl_48004, type, fn_lac_operon_1: $i > $i).
% 29.22/29.06  tff(decl_48005, type, fn_lac_operon_2: $i > $i).
% 29.22/29.06  tff(decl_48006, type, fn_lac_operon_3: $i > $i).
% 29.22/29.06  tff(decl_48007, type, negative_gene_regulation_1: $i > $o).
% 29.22/29.06  tff(decl_48008, type, fn_lac_operon_4: $i > $i).
% 29.22/29.06  tff(decl_48009, type, fn_lac_operon_5: $i > $i).
% 29.22/29.06  tff(decl_48010, type, fn_lac_operon_6: $i > $i).
% 29.22/29.06  tff(decl_48011, type, fn_lac_operon_7: $i > $i).
% 29.22/29.06  tff(decl_48012, type, fn_lac_operon_8: $i > $i).
% 29.22/29.06  tff(decl_48013, type, fn_lac_operon_9: $i > $i).
% 29.22/29.06  tff(decl_48014, type, fn_lac_operon_11: $i > $i).
% 29.22/29.06  tff(decl_48015, type, fn_lac_operon_12: $i > $i).
% 29.22/29.06  tff(decl_48016, type, fn_lac_operon_13: $i > $i).
% 29.22/29.06  tff(decl_48017, type, fn_lac_operon_14: $i > $i).
% 29.22/29.06  tff(decl_48018, type, fn_lac_operon_15: $i > $i).
% 29.22/29.06  tff(decl_48019, type, fn_lac_operon_16: $i > $i).
% 29.22/29.06  tff(decl_48020, type, fn_lac_operon_17: $i > $i).
% 29.22/29.06  tff(decl_48021, type, fn_lac_operon_18: $i > $i).
% 29.22/29.06  tff(decl_48022, type, fn_lac_operon_19: $i > $i).
% 29.22/29.06  tff(decl_48023, type, fn_lac_operon_20: $i > $i).
% 29.22/29.06  tff(decl_48024, type, fn_lac_operon_21: $i > $i).
% 29.22/29.06  tff(decl_48025, type, fn_lac_operon_22: $i > $i).
% 29.22/29.06  tff(decl_48026, type, fn_operon_10: $i > $i).
% 29.22/29.06  tff(decl_48027, type, fn_operon_19: $i > $i).
% 29.22/29.06  tff(decl_48028, type, fn_operon_6: $i > $i).
% 29.22/29.06  tff(decl_48029, type, fn_operon_14: $i > $i).
% 29.22/29.06  tff(decl_48030, type, lac_operon_regulation_1: $i > $o).
% 29.22/29.06  tff(decl_48031, type, fn_lac_operon_regulation_2: $i > $i).
% 29.22/29.06  tff(decl_48032, type, 'Lac-Operon-Regulation': $i).
% 29.22/29.06  tff(decl_48033, type, 'Regulation of the lac operon mediated by the LacI gene.': $i).
% 29.22/29.06  tff(decl_48034, type, 'regulation of the lac operon': $i).
% 29.22/29.06  tff(decl_48035, type, 'negative regulation of lac operon': $i).
% 29.22/29.06  tff(decl_48036, type, 'lac operon regulation': $i).
% 29.22/29.06  tff(decl_48037, type, 'lac-operon-regulation': $i).
% 29.22/29.06  tff(decl_48038, type, trp_operon_regulation_1: $i > $o).
% 29.22/29.06  tff(decl_48039, type, 'LacI': $i).
% 29.22/29.06  tff(decl_48040, type, 'A regulatory gene coding for proteins involved in the metabolism of lactose in bacteria.': $i).
% 29.22/29.06  tff(decl_48041, type, 'regulatory gene for lac operon': $i).
% 29.22/29.06  tff(decl_48042, type, 'laci regulatory gene': $i).
% 29.22/29.06  tff(decl_48043, type, 'lac regulatory gene': $i).
% 29.22/29.06  tff(decl_48044, type, laci: $i).
% 29.22/29.06  tff(decl_48045, type, fn_laci_1: $i > $i).
% 29.22/29.06  tff(decl_48046, type, fn_laci_2: $i > $i).
% 29.22/29.06  tff(decl_48047, type, fn_laci_3: $i > $i).
% 29.22/29.06  tff(decl_48048, type, fn_laci_4: $i > $i).
% 29.22/29.06  tff(decl_48049, type, fn_laci_5: $i > $i).
% 29.22/29.06  tff(decl_48050, type, fn_laci_6: $i > $i).
% 29.22/29.06  tff(decl_48051, type, fn_laci_7: $i > $i).
% 29.22/29.06  tff(decl_48052, type, fn_laci_8: $i > $i).
% 29.22/29.06  tff(decl_48053, type, fn_laci_9: $i > $i).
% 29.22/29.06  tff(decl_48054, type, fn_laci_10: $i > $i).
% 29.22/29.06  tff(decl_48055, type, fn_repressor_7: $i > $i).
% 29.22/29.06  tff(decl_48056, type, fn_laci_11: $i > $i).
% 29.22/29.06  tff(decl_48057, type, fn_laci_12: $i > $i).
% 29.22/29.06  tff(decl_48058, type, 'Lactate': $i).
% 29.22/29.06  tff(decl_48059, type, 'Lactate is a salt or ester of lactic acid.': $i).
% 29.22/29.06  tff(decl_48060, type, lactate: $i).
% 29.22/29.06  tff(decl_48061, type, fn_lactate_1: $i > $i).
% 29.22/29.06  tff(decl_48062, type, fn_lactate_2: $i > $i).
% 29.22/29.06  tff(decl_48063, type, fn_lactate_3: $i > $i).
% 29.22/29.06  tff(decl_48064, type, fn_lactate_5: $i > $i).
% 29.22/29.06  tff(decl_48065, type, fn_lactate_6: $i > $i).
% 29.22/29.06  tff(decl_48066, type, fn_lactate_7: $i > $i).
% 29.22/29.06  tff(decl_48067, type, fn_lactate_9: $i > $i).
% 29.22/29.06  tff(decl_48068, type, fn_lactate_10: $i > $i).
% 29.22/29.06  tff(decl_48069, type, lactic_acid_1: $i > $o).
% 29.22/29.06  tff(decl_48070, type, fn_lactate_11: $i > $i).
% 29.22/29.06  tff(decl_48071, type, fn_lactic_acid_1: $i > $i).
% 29.22/29.06  tff(decl_48072, type, fn_lactate_4: $i > $i).
% 29.22/29.06  tff(decl_48073, type, fn_lactate_8: $i > $i).
% 29.22/29.06  tff(decl_48074, type, lactation_1: $i > $o).
% 29.22/29.06  tff(decl_48075, type, 'Lactation': $i).
% 29.22/29.06  tff(decl_48076, type, 'The production and secretion of milk from mammary glands to feed offspring.': $i).
% 29.22/29.06  tff(decl_48077, type, lactation: $i).
% 29.22/29.06  tff(decl_48078, type, 'Lacteal': $i).
% 29.22/29.06  tff(decl_48079, type, 'A lymphatic capillary that extends into the center of an intestinal villus and absorbs dietary fats.': $i).
% 29.22/29.06  tff(decl_48080, type, lacteal: $i).
% 29.22/29.06  tff(decl_48081, type, 'Lactic-Acid': $i).
% 29.22/29.06  tff(decl_48082, type, 'Lactic acid is produced as a result of lactic acid fermentation in cells.': $i).
% 29.22/29.06  tff(decl_48083, type, 'lactic acid': $i).
% 29.22/29.06  tff(decl_48084, type, 'lactic-acid': $i).
% 29.22/29.06  tff(decl_48085, type, fn_lactic_acid_2: $i > $i).
% 29.22/29.06  tff(decl_48086, type, fn_lactic_acid_3: $i > $i).
% 29.22/29.06  tff(decl_48087, type, fn_lactic_acid_4: $i > $i).
% 29.22/29.06  tff(decl_48088, type, fn_lactic_acid_5: $i > $i).
% 29.22/29.06  tff(decl_48089, type, fn_lactic_acid_6: $i > $i).
% 29.22/29.06  tff(decl_48090, type, fn_lactic_acid_7: $i > $i).
% 29.22/29.06  tff(decl_48091, type, fn_lactic_acid_8: $i > $i).
% 29.22/29.06  tff(decl_48092, type, fn_lactic_acid_9: $i > $i).
% 29.22/29.06  tff(decl_48093, type, fn_lactic_acid_10: $i > $i).
% 29.22/29.06  tff(decl_48094, type, fn_lactic_acid_11: $i > $i).
% 29.22/29.06  tff(decl_48095, type, fn_lactic_acid_12: $i > $i).
% 29.22/29.06  tff(decl_48096, type, fn_lactic_acid_13: $i > $i).
% 29.22/29.06  tff(decl_48097, type, fn_lactic_acid_14: $i > $i).
% 29.22/29.06  tff(decl_48098, type, 'Lactic-Acid-Fermentation': $i).
% 29.22/29.06  tff(decl_48099, type, 'A form of anaerobic fermentation in which glycolysis is followed by the reducation of pyruvate to form lactate.': $i).
% 29.22/29.06  tff(decl_48100, type, 'lactic acid fermentation': $i).
% 29.22/29.06  tff(decl_48101, type, 'lactic-acid-fermentation': $i).
% 29.22/29.06  tff(decl_48102, type, fn_lactic_acid_fermentation_1: $i > $i).
% 29.22/29.06  tff(decl_48103, type, fn_lactic_acid_fermentation_2: $i > $i).
% 29.22/29.06  tff(decl_48104, type, fn_lactic_acid_fermentation_3: $i > $i).
% 29.22/29.06  tff(decl_48105, type, fn_lactic_acid_fermentation_4: $i > $i).
% 29.22/29.06  tff(decl_48106, type, fn_lactic_acid_fermentation_5: $i > $i).
% 29.22/29.06  tff(decl_48107, type, fn_lactic_acid_fermentation_6: $i > $i).
% 29.22/29.06  tff(decl_48108, type, fn_lactic_acid_fermentation_7: $i > $i).
% 29.22/29.06  tff(decl_48109, type, fn_lactic_acid_fermentation_8: $i > $i).
% 29.22/29.06  tff(decl_48110, type, fn_lactic_acid_fermentation_9: $i > $i).
% 29.22/29.06  tff(decl_48111, type, fn_lactic_acid_fermentation_11: $i > $i).
% 29.22/29.06  tff(decl_48112, type, fn_lactic_acid_fermentation_12: $i > $i).
% 29.22/29.06  tff(decl_48113, type, fn_lactic_acid_fermentation_13: $i > $i).
% 29.22/29.06  tff(decl_48114, type, fn_lactic_acid_fermentation_14: $i > $i).
% 29.22/29.06  tff(decl_48115, type, fn_lactic_acid_fermentation_15: $i > $i).
% 29.22/29.06  tff(decl_48116, type, fn_lactic_acid_fermentation_18: $i > $i).
% 29.22/29.06  tff(decl_48117, type, fn_lactic_acid_fermentation_19: $i > $i).
% 29.22/29.06  tff(decl_48118, type, fn_lactic_acid_fermentation_20: $i > $i).
% 29.22/29.06  tff(decl_48119, type, fn_lactic_acid_fermentation_21: $i > $i).
% 29.22/29.06  tff(decl_48120, type, fn_lactic_acid_fermentation_22: $i > $i).
% 29.22/29.06  tff(decl_48121, type, fn_lactic_acid_fermentation_23: $i > $i).
% 29.22/29.06  tff(decl_48122, type, fn_lactic_acid_fermentation_24: $i > $i).
% 29.22/29.06  tff(decl_48123, type, fn_lactic_acid_fermentation_25: $i > $i).
% 29.22/29.06  tff(decl_48124, type, fn_lactic_acid_fermentation_26: $i > $i).
% 29.22/29.06  tff(decl_48125, type, fn_lactic_acid_fermentation_27: $i > $i).
% 29.22/29.06  tff(decl_48126, type, fn_lactic_acid_fermentation_28: $i > $i).
% 29.22/29.06  tff(decl_48127, type, fn_lactic_acid_fermentation_29: $i > $i).
% 29.22/29.06  tff(decl_48128, type, fn_lactic_acid_fermentation_30: $i > $i).
% 29.22/29.06  tff(decl_48129, type, fn_lactic_acid_fermentation_31: $i > $i).
% 29.22/29.06  tff(decl_48130, type, fn_lactic_acid_fermentation_32: $i > $i).
% 29.22/29.06  tff(decl_48131, type, fn_lactic_acid_fermentation_33: $i > $i).
% 29.22/29.06  tff(decl_48132, type, fn_lactic_acid_fermentation_34: $i > $i).
% 29.22/29.06  tff(decl_48133, type, fn_lactic_acid_fermentation_35: $i > $i).
% 29.22/29.06  tff(decl_48134, type, fn_lactic_acid_fermentation_36: $i > $i).
% 29.22/29.06  tff(decl_48135, type, fn_lactic_acid_fermentation_37: $i > $i).
% 29.22/29.06  tff(decl_48136, type, fn_lactic_acid_fermentation_38: $i > $i).
% 29.22/29.06  tff(decl_48137, type, fn_lactic_acid_fermentation_39: $i > $i).
% 29.22/29.06  tff(decl_48138, type, fn_lactic_acid_fermentation_40: $i > $i).
% 29.22/29.06  tff(decl_48139, type, fn_lactic_acid_fermentation_41: $i > $i).
% 29.22/29.06  tff(decl_48140, type, fn_lactic_acid_fermentation_42: $i > $i).
% 29.22/29.06  tff(decl_48141, type, fn_lactic_acid_fermentation_43: $i > $i).
% 29.22/29.06  tff(decl_48142, type, fn_lactic_acid_fermentation_44: $i > $i).
% 29.22/29.06  tff(decl_48143, type, fn_lactic_acid_fermentation_45: $i > $i).
% 29.22/29.06  tff(decl_48144, type, fn_lactic_acid_fermentation_46: $i > $i).
% 29.22/29.06  tff(decl_48145, type, fn_lactic_acid_fermentation_47: $i > $i).
% 29.22/29.06  tff(decl_48146, type, fn_lactic_acid_fermentation_48: $i > $i).
% 29.22/29.06  tff(decl_48147, type, fn_lactic_acid_fermentation_49: $i > $i).
% 29.22/29.06  tff(decl_48148, type, fn_lactic_acid_fermentation_50: $i > $i).
% 29.22/29.06  tff(decl_48149, type, fn_lactic_acid_fermentation_51: $i > $i).
% 29.22/29.06  tff(decl_48150, type, fn_lactic_acid_fermentation_56: $i > $i).
% 29.22/29.06  tff(decl_48151, type, fn_lactic_acid_fermentation_57: $i > $i).
% 29.22/29.06  tff(decl_48152, type, fn_lactic_acid_fermentation_58: $i > $i).
% 29.22/29.06  tff(decl_48153, type, fn_lactic_acid_fermentation_59: $i > $i).
% 29.22/29.06  tff(decl_48154, type, fn_lactic_acid_fermentation_60: $i > $i).
% 29.22/29.06  tff(decl_48155, type, fn_lactic_acid_fermentation_61: $i > $i).
% 29.22/29.06  tff(decl_48156, type, fn_lactic_acid_fermentation_62: $i > $i).
% 29.22/29.06  tff(decl_48157, type, fn_lactic_acid_fermentation_63: $i > $i).
% 29.22/29.06  tff(decl_48158, type, fn_lactic_acid_fermentation_64: $i > $i).
% 29.22/29.06  tff(decl_48159, type, fn_lactic_acid_fermentation_65: $i > $i).
% 29.22/29.06  tff(decl_48160, type, fn_lactic_acid_fermentation_66: $i > $i).
% 29.22/29.06  tff(decl_48161, type, fn_lactic_acid_fermentation_67: $i > $i).
% 29.22/29.06  tff(decl_48162, type, fn_lactic_acid_fermentation_68: $i > $i).
% 29.22/29.06  tff(decl_48163, type, fn_lactic_acid_fermentation_69: $i > $i).
% 29.22/29.06  tff(decl_48164, type, fn_lactic_acid_fermentation_70: $i > $i).
% 29.22/29.06  tff(decl_48165, type, fn_lactic_acid_fermentation_71: $i > $i).
% 29.22/29.06  tff(decl_48166, type, fn_lactic_acid_fermentation_72: $i > $i).
% 29.22/29.06  tff(decl_48167, type, fn_lactic_acid_fermentation_73: $i > $i).
% 29.22/29.06  tff(decl_48168, type, fn_lactic_acid_fermentation_74: $i > $i).
% 29.22/29.06  tff(decl_48169, type, fn_lactic_acid_fermentation_76: $i > $i).
% 29.22/29.06  tff(decl_48170, type, fn_lactic_acid_fermentation_77: $i > $i).
% 29.22/29.06  tff(decl_48171, type, fn_lactic_acid_fermentation_78: $i > $i).
% 29.22/29.06  tff(decl_48172, type, fn_lactic_acid_fermentation_79: $i > $i).
% 29.22/29.06  tff(decl_48173, type, fn_lactic_acid_fermentation_52: $i > $i).
% 29.22/29.06  tff(decl_48174, type, fn_lactic_acid_fermentation_53: $i > $i).
% 29.22/29.06  tff(decl_48175, type, fn_lactic_acid_fermentation_16: $i > $i).
% 29.22/29.06  tff(decl_48176, type, fn_lactic_acid_fermentation_17: $i > $i).
% 29.22/29.06  tff(decl_48177, type, fn_lactic_acid_fermentation_75: $i > $i).
% 29.22/29.06  tff(decl_48178, type, fn_lactic_acid_fermentation_10: $i > $i).
% 29.22/29.06  tff(decl_48179, type, fn_lactic_acid_fermentation_54: $i > $i).
% 29.22/29.06  tff(decl_48180, type, fn_lactic_acid_fermentation_55: $i > $i).
% 29.22/29.06  tff(decl_48181, type, lactic_acid_fermentation_by_bacteria_1: $i > $o).
% 29.22/29.06  tff(decl_48182, type, 'Lactic-Acid-Fermentation-By-Bacteria': $i).
% 29.22/29.06  tff(decl_48183, type, 'Lactic acid fermentation by bacteria is the process of fermentation of sugars by bacteria which results in byproduct Lactate.': $i).
% 29.22/29.06  tff(decl_48184, type, 'lactic acid fermentation by bacterium': $i).
% 29.22/29.06  tff(decl_48185, type, 'lactic-acid-fermentation-by-bacteria': $i).
% 29.22/29.06  tff(decl_48186, type, fn_lactic_acid_fermentation_by_bacteria_1: $i > $i).
% 29.22/29.06  tff(decl_48187, type, fn_lactic_acid_fermentation_by_bacteria_2: $i > $i).
% 29.22/29.06  tff(decl_48188, type, fn_lactic_acid_fermentation_by_bacteria_3: $i > $i).
% 29.22/29.06  tff(decl_48189, type, fn_lactic_acid_fermentation_by_bacteria_4: $i > $i).
% 29.22/29.06  tff(decl_48190, type, fn_lactic_acid_fermentation_by_bacteria_5: $i > $i).
% 29.22/29.06  tff(decl_48191, type, fn_lactic_acid_fermentation_by_bacteria_6: $i > $i).
% 29.22/29.06  tff(decl_48192, type, fn_lactic_acid_fermentation_by_bacteria_7: $i > $i).
% 29.22/29.06  tff(decl_48193, type, fn_lactic_acid_fermentation_by_bacteria_8: $i > $i).
% 29.22/29.06  tff(decl_48194, type, fn_lactic_acid_fermentation_by_bacteria_9: $i > $i).
% 29.22/29.06  tff(decl_48195, type, fn_lactic_acid_fermentation_by_bacteria_10: $i > $i).
% 29.22/29.06  tff(decl_48196, type, fn_lactic_acid_fermentation_by_bacteria_11: $i > $i).
% 29.22/29.06  tff(decl_48197, type, fn_lactic_acid_fermentation_by_bacteria_12: $i > $i).
% 29.22/29.06  tff(decl_48198, type, fn_lactic_acid_fermentation_by_bacteria_13: $i > $i).
% 29.22/29.06  tff(decl_48199, type, fn_lactic_acid_fermentation_by_bacteria_14: $i > $i).
% 29.22/29.06  tff(decl_48200, type, fn_lactic_acid_fermentation_by_bacteria_15: $i > $i).
% 29.22/29.06  tff(decl_48201, type, fn_lactic_acid_fermentation_by_bacteria_16: $i > $i).
% 29.22/29.06  tff(decl_48202, type, fn_lactic_acid_fermentation_by_bacteria_17: $i > $i).
% 29.22/29.06  tff(decl_48203, type, fn_lactic_acid_fermentation_by_bacteria_18: $i > $i).
% 29.22/29.06  tff(decl_48204, type, fn_lactic_acid_fermentation_by_bacteria_19: $i > $i).
% 29.22/29.06  tff(decl_48205, type, fn_lactic_acid_fermentation_by_bacteria_20: $i > $i).
% 29.22/29.06  tff(decl_48206, type, fn_lactic_acid_fermentation_by_bacteria_21: $i > $i).
% 29.22/29.06  tff(decl_48207, type, fn_lactic_acid_fermentation_by_bacteria_22: $i > $i).
% 29.22/29.06  tff(decl_48208, type, fn_lactic_acid_fermentation_by_bacteria_23: $i > $i).
% 29.22/29.06  tff(decl_48209, type, fn_lactic_acid_fermentation_by_bacteria_24: $i > $i).
% 29.22/29.06  tff(decl_48210, type, fn_lactic_acid_fermentation_by_bacteria_25: $i > $i).
% 29.22/29.06  tff(decl_48211, type, fn_lactic_acid_fermentation_by_bacteria_26: $i > $i).
% 29.22/29.06  tff(decl_48212, type, fn_lactic_acid_fermentation_by_bacteria_27: $i > $i).
% 29.22/29.06  tff(decl_48213, type, fn_lactic_acid_fermentation_by_bacteria_28: $i > $i).
% 29.22/29.06  tff(decl_48214, type, fn_lactic_acid_fermentation_by_bacteria_29: $i > $i).
% 29.22/29.06  tff(decl_48215, type, fn_lactic_acid_fermentation_by_bacteria_30: $i > $i).
% 29.22/29.06  tff(decl_48216, type, fn_lactic_acid_fermentation_by_bacteria_31: $i > $i).
% 29.22/29.06  tff(decl_48217, type, fn_lactic_acid_fermentation_by_bacteria_32: $i > $i).
% 29.22/29.06  tff(decl_48218, type, fn_lactic_acid_fermentation_by_bacteria_33: $i > $i).
% 29.22/29.06  tff(decl_48219, type, fn_lactic_acid_fermentation_by_bacteria_34: $i > $i).
% 29.22/29.06  tff(decl_48220, type, fn_lactic_acid_fermentation_by_bacteria_35: $i > $i).
% 29.22/29.06  tff(decl_48221, type, fn_lactic_acid_fermentation_by_bacteria_36: $i > $i).
% 29.22/29.06  tff(decl_48222, type, fn_lactic_acid_fermentation_by_bacteria_37: $i > $i).
% 29.22/29.06  tff(decl_48223, type, fn_lactic_acid_fermentation_by_bacteria_38: $i > $i).
% 29.22/29.06  tff(decl_48224, type, fn_lactic_acid_fermentation_by_bacteria_39: $i > $i).
% 29.22/29.06  tff(decl_48225, type, fn_lactic_acid_fermentation_by_bacteria_40: $i > $i).
% 29.22/29.06  tff(decl_48226, type, fn_lactic_acid_fermentation_by_bacteria_41: $i > $i).
% 29.22/29.06  tff(decl_48227, type, fn_lactic_acid_fermentation_by_bacteria_42: $i > $i).
% 29.22/29.06  tff(decl_48228, type, fn_lactic_acid_fermentation_by_bacteria_43: $i > $i).
% 29.22/29.06  tff(decl_48229, type, fn_lactic_acid_fermentation_by_bacteria_44: $i > $i).
% 29.22/29.06  tff(decl_48230, type, fn_lactic_acid_fermentation_by_bacteria_45: $i > $i).
% 29.22/29.06  tff(decl_48231, type, fn_lactic_acid_fermentation_by_bacteria_46: $i > $i).
% 29.22/29.06  tff(decl_48232, type, fn_lactic_acid_fermentation_by_bacteria_47: $i > $i).
% 29.22/29.06  tff(decl_48233, type, fn_lactic_acid_fermentation_by_bacteria_48: $i > $i).
% 29.22/29.06  tff(decl_48234, type, fn_lactic_acid_fermentation_by_bacteria_50: $i > $i).
% 29.22/29.06  tff(decl_48235, type, fn_lactic_acid_fermentation_by_bacteria_51: $i > $i).
% 29.22/29.06  tff(decl_48236, type, fn_lactic_acid_fermentation_by_bacteria_52: $i > $i).
% 29.22/29.06  tff(decl_48237, type, fn_lactic_acid_fermentation_by_bacteria_53: $i > $i).
% 29.22/29.06  tff(decl_48238, type, fn_lactic_acid_fermentation_by_bacteria_54: $i > $i).
% 29.22/29.06  tff(decl_48239, type, fn_lactic_acid_fermentation_by_bacteria_55: $i > $i).
% 29.22/29.06  tff(decl_48240, type, fn_lactic_acid_fermentation_by_bacteria_56: $i > $i).
% 29.22/29.06  tff(decl_48241, type, fn_lactic_acid_fermentation_by_bacteria_57: $i > $i).
% 29.22/29.06  tff(decl_48242, type, fn_lactic_acid_fermentation_by_bacteria_58: $i > $i).
% 29.22/29.06  tff(decl_48243, type, fn_lactic_acid_fermentation_by_bacteria_59: $i > $i).
% 29.22/29.06  tff(decl_48244, type, fn_lactic_acid_fermentation_by_bacteria_60: $i > $i).
% 29.22/29.06  tff(decl_48245, type, fn_lactic_acid_fermentation_by_bacteria_61: $i > $i).
% 29.22/29.06  tff(decl_48246, type, fn_lactic_acid_fermentation_by_bacteria_62: $i > $i).
% 29.22/29.06  tff(decl_48247, type, fn_lactic_acid_fermentation_by_bacteria_63: $i > $i).
% 29.22/29.06  tff(decl_48248, type, fn_lactic_acid_fermentation_by_bacteria_64: $i > $i).
% 29.22/29.06  tff(decl_48249, type, fn_lactic_acid_fermentation_by_bacteria_65: $i > $i).
% 29.22/29.06  tff(decl_48250, type, fn_lactic_acid_fermentation_by_bacteria_66: $i > $i).
% 29.22/29.06  tff(decl_48251, type, fn_lactic_acid_fermentation_by_bacteria_67: $i > $i).
% 29.22/29.06  tff(decl_48252, type, fn_lactic_acid_fermentation_by_bacteria_68: $i > $i).
% 29.22/29.06  tff(decl_48253, type, fn_lactic_acid_fermentation_by_bacteria_69: $i > $i).
% 29.22/29.06  tff(decl_48254, type, fn_lactic_acid_fermentation_by_bacteria_70: $i > $i).
% 29.22/29.06  tff(decl_48255, type, fn_lactic_acid_fermentation_by_bacteria_71: $i > $i).
% 29.22/29.06  tff(decl_48256, type, fn_lactic_acid_fermentation_by_bacteria_72: $i > $i).
% 29.22/29.06  tff(decl_48257, type, yogurt_1: $i > $o).
% 29.22/29.06  tff(decl_48258, type, fn_lactic_acid_fermentation_by_bacteria_73: $i > $i).
% 29.22/29.06  tff(decl_48259, type, fn_lactic_acid_fermentation_by_bacteria_74: $i > $i).
% 29.22/29.06  tff(decl_48260, type, fn_lactic_acid_fermentation_by_bacteria_75: $i > $i).
% 29.22/29.06  tff(decl_48261, type, fn_lactic_acid_fermentation_by_bacteria_76: $i > $i).
% 29.22/29.06  tff(decl_48262, type, fn_lactic_acid_fermentation_by_bacteria_77: $i > $i).
% 29.22/29.06  tff(decl_48263, type, fn_lactic_acid_fermentation_by_bacteria_78: $i > $i).
% 29.22/29.06  tff(decl_48264, type, fn_lactic_acid_fermentation_by_bacteria_79: $i > $i).
% 29.22/29.06  tff(decl_48265, type, fn_lactic_acid_fermentation_by_bacteria_80: $i > $i).
% 29.22/29.06  tff(decl_48266, type, fn_lactic_acid_fermentation_by_bacteria_81: $i > $i).
% 29.22/29.06  tff(decl_48267, type, fn_lactic_acid_fermentation_by_bacteria_82: $i > $i).
% 29.22/29.06  tff(decl_48268, type, fn_lactic_acid_fermentation_by_bacteria_83: $i > $i).
% 29.22/29.06  tff(decl_48269, type, fn_lactic_acid_fermentation_by_bacteria_86: $i > $i).
% 29.22/29.06  tff(decl_48270, type, fn_lactic_acid_fermentation_by_bacteria_87: $i > $i).
% 29.22/29.06  tff(decl_48271, type, fn_lactic_acid_fermentation_by_bacteria_88: $i > $i).
% 29.22/29.06  tff(decl_48272, type, fn_lactic_acid_fermentation_by_bacteria_89: $i > $i).
% 29.22/29.06  tff(decl_48273, type, fn_lactic_acid_fermentation_by_bacteria_90: $i > $i).
% 29.22/29.06  tff(decl_48274, type, fn_lactic_acid_fermentation_by_bacteria_91: $i > $i).
% 29.22/29.06  tff(decl_48275, type, fn_lactic_acid_fermentation_by_bacteria_92: $i > $i).
% 29.22/29.06  tff(decl_48276, type, fn_lactic_acid_fermentation_by_bacteria_93: $i > $i).
% 29.22/29.06  tff(decl_48277, type, fn_lactic_acid_fermentation_by_bacteria_94: $i > $i).
% 29.22/29.06  tff(decl_48278, type, fn_lactic_acid_fermentation_by_bacteria_95: $i > $i).
% 29.22/29.06  tff(decl_48279, type, fn_lactic_acid_fermentation_by_bacteria_96: $i > $i).
% 29.22/29.06  tff(decl_48280, type, fn_lactic_acid_fermentation_by_bacteria_97: $i > $i).
% 29.22/29.06  tff(decl_48281, type, fn_lactic_acid_fermentation_by_bacteria_98: $i > $i).
% 29.22/29.06  tff(decl_48282, type, fn_lactic_acid_fermentation_by_bacteria_99: $i > $i).
% 29.22/29.06  tff(decl_48283, type, fn_lactic_acid_fermentation_by_bacteria_102: $i > $i).
% 29.22/29.06  tff(decl_48284, type, fn_lactic_acid_fermentation_by_bacteria_103: $i > $i).
% 29.22/29.06  tff(decl_48285, type, fn_lactic_acid_fermentation_by_bacteria_104: $i > $i).
% 29.22/29.06  tff(decl_48286, type, fn_lactic_acid_fermentation_by_bacteria_105: $i > $i).
% 29.22/29.06  tff(decl_48287, type, fn_lactic_acid_fermentation_by_bacteria_106: $i > $i).
% 29.22/29.06  tff(decl_48288, type, fn_lactic_acid_fermentation_by_bacteria_107: $i > $i).
% 29.22/29.06  tff(decl_48289, type, fn_lactic_acid_fermentation_by_bacteria_108: $i > $i).
% 29.22/29.06  tff(decl_48290, type, fn_lactic_acid_fermentation_by_bacteria_109: $i > $i).
% 29.22/29.06  tff(decl_48291, type, fn_lactic_acid_fermentation_by_bacteria_111: $i > $i).
% 29.22/29.06  tff(decl_48292, type, fn_lactic_acid_fermentation_by_bacteria_112: $i > $i).
% 29.22/29.06  tff(decl_48293, type, fn_lactic_acid_fermentation_by_bacteria_113: $i > $i).
% 29.22/29.06  tff(decl_48294, type, fn_lactic_acid_fermentation_by_bacteria_114: $i > $i).
% 29.22/29.06  tff(decl_48295, type, fn_lactic_acid_fermentation_by_bacteria_115: $i > $i).
% 29.22/29.06  tff(decl_48296, type, fn_lactic_acid_fermentation_by_bacteria_116: $i > $i).
% 29.22/29.06  tff(decl_48297, type, fn_lactic_acid_fermentation_by_bacteria_117: $i > $i).
% 29.22/29.06  tff(decl_48298, type, fn_lactic_acid_fermentation_by_bacteria_118: $i > $i).
% 29.22/29.06  tff(decl_48299, type, fn_lactic_acid_fermentation_by_bacteria_119: $i > $i).
% 29.22/29.06  tff(decl_48300, type, fn_lactic_acid_fermentation_by_bacteria_124: $i > $i).
% 29.22/29.06  tff(decl_48301, type, fn_lactic_acid_fermentation_by_bacteria_125: $i > $i).
% 29.22/29.06  tff(decl_48302, type, fn_lactic_acid_fermentation_by_bacteria_126: $i > $i).
% 29.22/29.06  tff(decl_48303, type, fn_lactic_acid_fermentation_by_bacteria_127: $i > $i).
% 29.22/29.06  tff(decl_48304, type, fn_lactic_acid_fermentation_by_bacteria_129: $i > $i).
% 29.22/29.06  tff(decl_48305, type, fn_lactic_acid_fermentation_by_bacteria_130: $i > $i).
% 29.22/29.06  tff(decl_48306, type, fn_lactic_acid_fermentation_by_bacteria_131: $i > $i).
% 29.22/29.06  tff(decl_48307, type, fn_lactic_acid_fermentation_by_bacteria_132: $i > $i).
% 29.22/29.06  tff(decl_48308, type, fn_yogurt_8: $i > $i).
% 29.22/29.06  tff(decl_48309, type, fn_yogurt_7: $i > $i).
% 29.22/29.06  tff(decl_48310, type, fn_lactic_acid_fermentation_by_bacteria_110: $i > $i).
% 29.22/29.06  tff(decl_48311, type, fn_lactic_acid_fermentation_by_bacteria_120: $i > $i).
% 29.22/29.06  tff(decl_48312, type, fn_lactic_acid_fermentation_by_bacteria_121: $i > $i).
% 29.22/29.06  tff(decl_48313, type, fn_lactic_acid_fermentation_by_bacteria_84: $i > $i).
% 29.22/29.06  tff(decl_48314, type, fn_lactic_acid_fermentation_by_bacteria_85: $i > $i).
% 29.22/29.06  tff(decl_48315, type, fn_lactic_acid_fermentation_by_bacteria_49: $i > $i).
% 29.22/29.06  tff(decl_48316, type, fn_lactic_acid_fermentation_by_bacteria_128: $i > $i).
% 29.22/29.06  tff(decl_48317, type, fn_lactic_acid_fermentation_by_bacteria_123: $i > $i).
% 29.22/29.06  tff(decl_48318, type, fn_lactic_acid_fermentation_by_bacteria_122: $i > $i).
% 29.22/29.06  tff(decl_48319, type, fn_lactic_acid_fermentation_by_bacteria_101: $i > $i).
% 29.22/29.06  tff(decl_48320, type, fn_lactic_acid_fermentation_by_bacteria_100: $i > $i).
% 29.22/29.06  tff(decl_48321, type, lactic_acid_fermentation_by_fungi_1: $i > $o).
% 29.22/29.06  tff(decl_48322, type, 'Lactic-Acid-Fermentation-By-Fungi': $i).
% 29.22/29.06  tff(decl_48323, type, 'Lactic acid fermentation by fungi is the process of fermentation of sugars by fungi which results in byproduct Lactate.': $i).
% 29.22/29.06  tff(decl_48324, type, 'lactic acid fermentation by fungus': $i).
% 29.22/29.06  tff(decl_48325, type, 'lactic-acid-fermentation-by-fungi': $i).
% 29.22/29.06  tff(decl_48326, type, fn_lactic_acid_fermentation_by_fungi_1: $i > $i).
% 29.22/29.06  tff(decl_48327, type, fn_lactic_acid_fermentation_by_fungi_2: $i > $i).
% 29.22/29.06  tff(decl_48328, type, fn_lactic_acid_fermentation_by_fungi_3: $i > $i).
% 29.22/29.06  tff(decl_48329, type, fn_lactic_acid_fermentation_by_fungi_4: $i > $i).
% 29.22/29.06  tff(decl_48330, type, fn_lactic_acid_fermentation_by_fungi_5: $i > $i).
% 29.22/29.06  tff(decl_48331, type, fn_lactic_acid_fermentation_by_fungi_6: $i > $i).
% 29.22/29.06  tff(decl_48332, type, fn_lactic_acid_fermentation_by_fungi_7: $i > $i).
% 29.22/29.06  tff(decl_48333, type, fn_lactic_acid_fermentation_by_fungi_8: $i > $i).
% 29.22/29.06  tff(decl_48334, type, fn_lactic_acid_fermentation_by_fungi_10: $i > $i).
% 29.22/29.06  tff(decl_48335, type, fn_lactic_acid_fermentation_by_fungi_11: $i > $i).
% 29.22/29.06  tff(decl_48336, type, fn_lactic_acid_fermentation_by_fungi_13: $i > $i).
% 29.22/29.06  tff(decl_48337, type, fn_lactic_acid_fermentation_by_fungi_14: $i > $i).
% 29.22/29.06  tff(decl_48338, type, fn_lactic_acid_fermentation_by_fungi_15: $i > $i).
% 29.22/29.06  tff(decl_48339, type, fn_lactic_acid_fermentation_by_fungi_16: $i > $i).
% 29.22/29.06  tff(decl_48340, type, fn_lactic_acid_fermentation_by_fungi_17: $i > $i).
% 29.22/29.06  tff(decl_48341, type, fn_lactic_acid_fermentation_by_fungi_18: $i > $i).
% 29.22/29.06  tff(decl_48342, type, fn_lactic_acid_fermentation_by_fungi_19: $i > $i).
% 29.22/29.06  tff(decl_48343, type, fn_lactic_acid_fermentation_by_fungi_20: $i > $i).
% 29.22/29.06  tff(decl_48344, type, fn_lactic_acid_fermentation_by_fungi_21: $i > $i).
% 29.22/29.06  tff(decl_48345, type, fn_lactic_acid_fermentation_by_fungi_22: $i > $i).
% 29.22/29.06  tff(decl_48346, type, fn_lactic_acid_fermentation_by_fungi_23: $i > $i).
% 29.22/29.06  tff(decl_48347, type, fn_lactic_acid_fermentation_by_fungi_24: $i > $i).
% 29.22/29.06  tff(decl_48348, type, fn_lactic_acid_fermentation_by_fungi_25: $i > $i).
% 29.22/29.06  tff(decl_48349, type, fn_lactic_acid_fermentation_by_fungi_26: $i > $i).
% 29.22/29.06  tff(decl_48350, type, fn_lactic_acid_fermentation_by_fungi_27: $i > $i).
% 29.22/29.06  tff(decl_48351, type, fn_lactic_acid_fermentation_by_fungi_28: $i > $i).
% 29.22/29.06  tff(decl_48352, type, fn_lactic_acid_fermentation_by_fungi_29: $i > $i).
% 29.22/29.06  tff(decl_48353, type, fn_lactic_acid_fermentation_by_fungi_30: $i > $i).
% 29.22/29.06  tff(decl_48354, type, fn_lactic_acid_fermentation_by_fungi_31: $i > $i).
% 29.22/29.06  tff(decl_48355, type, fn_lactic_acid_fermentation_by_fungi_32: $i > $i).
% 29.22/29.06  tff(decl_48356, type, fn_lactic_acid_fermentation_by_fungi_33: $i > $i).
% 29.22/29.06  tff(decl_48357, type, fn_lactic_acid_fermentation_by_fungi_34: $i > $i).
% 29.22/29.06  tff(decl_48358, type, fn_lactic_acid_fermentation_by_fungi_35: $i > $i).
% 29.22/29.06  tff(decl_48359, type, fn_lactic_acid_fermentation_by_fungi_36: $i > $i).
% 29.22/29.06  tff(decl_48360, type, fn_lactic_acid_fermentation_by_fungi_37: $i > $i).
% 29.22/29.06  tff(decl_48361, type, fn_lactic_acid_fermentation_by_fungi_38: $i > $i).
% 29.22/29.06  tff(decl_48362, type, fn_lactic_acid_fermentation_by_fungi_39: $i > $i).
% 29.22/29.06  tff(decl_48363, type, fn_lactic_acid_fermentation_by_fungi_40: $i > $i).
% 29.22/29.06  tff(decl_48364, type, fn_lactic_acid_fermentation_by_fungi_41: $i > $i).
% 29.22/29.06  tff(decl_48365, type, fn_lactic_acid_fermentation_by_fungi_42: $i > $i).
% 29.22/29.06  tff(decl_48366, type, fn_lactic_acid_fermentation_by_fungi_43: $i > $i).
% 29.22/29.06  tff(decl_48367, type, fn_lactic_acid_fermentation_by_fungi_46: $i > $i).
% 29.22/29.06  tff(decl_48368, type, fn_lactic_acid_fermentation_by_fungi_47: $i > $i).
% 29.22/29.06  tff(decl_48369, type, fn_lactic_acid_fermentation_by_fungi_48: $i > $i).
% 29.22/29.06  tff(decl_48370, type, fn_lactic_acid_fermentation_by_fungi_49: $i > $i).
% 29.22/29.06  tff(decl_48371, type, fn_lactic_acid_fermentation_by_fungi_50: $i > $i).
% 29.22/29.06  tff(decl_48372, type, fn_yogurt_5: $i > $i).
% 29.22/29.06  tff(decl_48373, type, fn_lactic_acid_fermentation_by_fungi_51: $i > $i).
% 29.22/29.06  tff(decl_48374, type, fn_lactic_acid_fermentation_by_fungi_44: $i > $i).
% 29.22/29.06  tff(decl_48375, type, fn_lactic_acid_fermentation_by_fungi_45: $i > $i).
% 29.22/29.06  tff(decl_48376, type, fn_lactic_acid_fermentation_by_fungi_9: $i > $i).
% 29.22/29.06  tff(decl_48377, type, fn_lactic_acid_fermentation_by_fungi_12: $i > $i).
% 29.22/29.06  tff(decl_48378, type, 'Lactic-Acid-Fermentation-In-Muscle-Cell': $i).
% 29.22/29.06  tff(decl_48379, type, 'Lactic Acid fermentation occur in muscle cells during later stage of sternuous exercise because high rate of cellular respiration causes scarcity of oxygen.': $i).
% 29.22/29.06  tff(decl_48380, type, 'lactic acid fermentation in muscle cell': $i).
% 29.22/29.06  tff(decl_48381, type, 'lactic-acid-fermentation-in-muscle-cell': $i).
% 29.22/29.06  tff(decl_48382, type, fn_lactic_acid_fermentation_in_muscle_cell_1: $i > $i).
% 29.22/29.06  tff(decl_48383, type, fn_lactic_acid_fermentation_in_muscle_cell_2: $i > $i).
% 29.22/29.06  tff(decl_48384, type, fn_lactic_acid_fermentation_in_muscle_cell_3: $i > $i).
% 29.22/29.06  tff(decl_48385, type, fn_lactic_acid_fermentation_in_muscle_cell_4: $i > $i).
% 29.22/29.06  tff(decl_48386, type, fn_lactic_acid_fermentation_in_muscle_cell_5: $i > $i).
% 29.22/29.06  tff(decl_48387, type, fn_lactic_acid_fermentation_in_muscle_cell_6: $i > $i).
% 29.22/29.06  tff(decl_48388, type, fn_lactic_acid_fermentation_in_muscle_cell_7: $i > $i).
% 29.22/29.06  tff(decl_48389, type, fn_lactic_acid_fermentation_in_muscle_cell_8: $i > $i).
% 29.22/29.06  tff(decl_48390, type, fn_lactic_acid_fermentation_in_muscle_cell_9: $i > $i).
% 29.22/29.06  tff(decl_48391, type, fn_lactic_acid_fermentation_in_muscle_cell_10: $i > $i).
% 29.22/29.06  tff(decl_48392, type, fn_lactic_acid_fermentation_in_muscle_cell_11: $i > $i).
% 29.22/29.06  tff(decl_48393, type, fn_lactic_acid_fermentation_in_muscle_cell_12: $i > $i).
% 29.22/29.06  tff(decl_48394, type, fn_lactic_acid_fermentation_in_muscle_cell_13: $i > $i).
% 29.22/29.06  tff(decl_48395, type, fn_lactic_acid_fermentation_in_muscle_cell_14: $i > $i).
% 29.22/29.06  tff(decl_48396, type, fn_lactic_acid_fermentation_in_muscle_cell_15: $i > $i).
% 29.22/29.06  tff(decl_48397, type, fn_lactic_acid_fermentation_in_muscle_cell_16: $i > $i).
% 29.22/29.06  tff(decl_48398, type, fn_lactic_acid_fermentation_in_muscle_cell_17: $i > $i).
% 29.22/29.06  tff(decl_48399, type, fn_lactic_acid_fermentation_in_muscle_cell_18: $i > $i).
% 29.22/29.06  tff(decl_48400, type, fn_lactic_acid_fermentation_in_muscle_cell_19: $i > $i).
% 29.22/29.06  tff(decl_48401, type, fn_lactic_acid_fermentation_in_muscle_cell_20: $i > $i).
% 29.22/29.06  tff(decl_48402, type, fn_lactic_acid_fermentation_in_muscle_cell_22: $i > $i).
% 29.22/29.06  tff(decl_48403, type, fn_lactic_acid_fermentation_in_muscle_cell_23: $i > $i).
% 29.22/29.06  tff(decl_48404, type, fn_lactic_acid_fermentation_in_muscle_cell_25: $i > $i).
% 29.22/29.06  tff(decl_48405, type, fn_lactic_acid_fermentation_in_muscle_cell_27: $i > $i).
% 29.22/29.06  tff(decl_48406, type, fn_lactic_acid_fermentation_in_muscle_cell_28: $i > $i).
% 29.22/29.06  tff(decl_48407, type, fn_lactic_acid_fermentation_in_muscle_cell_30: $i > $i).
% 29.22/29.06  tff(decl_48408, type, fn_lactic_acid_fermentation_in_muscle_cell_31: $i > $i).
% 29.22/29.06  tff(decl_48409, type, fn_lactic_acid_fermentation_in_muscle_cell_32: $i > $i).
% 29.22/29.06  tff(decl_48410, type, fn_lactic_acid_fermentation_in_muscle_cell_33: $i > $i).
% 29.22/29.06  tff(decl_48411, type, fn_lactic_acid_fermentation_in_muscle_cell_34: $i > $i).
% 29.22/29.06  tff(decl_48412, type, fn_lactic_acid_fermentation_in_muscle_cell_35: $i > $i).
% 29.22/29.06  tff(decl_48413, type, fn_lactic_acid_fermentation_in_muscle_cell_36: $i > $i).
% 29.22/29.06  tff(decl_48414, type, fn_lactic_acid_fermentation_in_muscle_cell_37: $i > $i).
% 29.22/29.06  tff(decl_48415, type, fn_lactic_acid_fermentation_in_muscle_cell_38: $i > $i).
% 29.22/29.06  tff(decl_48416, type, fn_lactic_acid_fermentation_in_muscle_cell_39: $i > $i).
% 29.22/29.06  tff(decl_48417, type, fn_lactic_acid_fermentation_in_muscle_cell_40: $i > $i).
% 29.22/29.06  tff(decl_48418, type, fn_lactic_acid_fermentation_in_muscle_cell_41: $i > $i).
% 29.22/29.06  tff(decl_48419, type, fn_lactic_acid_fermentation_in_muscle_cell_42: $i > $i).
% 29.22/29.06  tff(decl_48420, type, fn_lactic_acid_fermentation_in_muscle_cell_43: $i > $i).
% 29.22/29.06  tff(decl_48421, type, fn_lactic_acid_fermentation_in_muscle_cell_44: $i > $i).
% 29.22/29.06  tff(decl_48422, type, fn_lactic_acid_fermentation_in_muscle_cell_45: $i > $i).
% 29.22/29.06  tff(decl_48423, type, fn_lactic_acid_fermentation_in_muscle_cell_46: $i > $i).
% 29.22/29.06  tff(decl_48424, type, fn_lactic_acid_fermentation_in_muscle_cell_47: $i > $i).
% 29.22/29.06  tff(decl_48425, type, fn_lactic_acid_fermentation_in_muscle_cell_48: $i > $i).
% 29.22/29.06  tff(decl_48426, type, fn_lactic_acid_fermentation_in_muscle_cell_52: $i > $i).
% 29.22/29.06  tff(decl_48427, type, fn_lactic_acid_fermentation_in_muscle_cell_53: $i > $i).
% 29.22/29.06  tff(decl_48428, type, fn_muscle_cell_17: $i > $i).
% 29.22/29.06  tff(decl_48429, type, fn_lactic_acid_fermentation_in_muscle_cell_51: $i > $i).
% 29.22/29.06  tff(decl_48430, type, fn_lactic_acid_fermentation_in_muscle_cell_50: $i > $i).
% 29.22/29.06  tff(decl_48431, type, fn_lactic_acid_fermentation_in_muscle_cell_49: $i > $i).
% 29.22/29.06  tff(decl_48432, type, 'Lactose': $i).
% 29.22/29.06  tff(decl_48433, type, 'A disaccharide consisting of glucose bonded to galactose via a glycosidic linkage. Lacotse is the most abundant sugar in milk.': $i).
% 29.22/29.06  tff(decl_48434, type, lactose: $i).
% 29.22/29.06  tff(decl_48435, type, fn_lactose_1: $i > $i).
% 29.22/29.06  tff(decl_48436, type, fn_lactose_2: $i > $i).
% 29.22/29.06  tff(decl_48437, type, fn_lactose_3: $i > $i).
% 29.22/29.06  tff(decl_48438, type, fn_lactose_4: $i > $i).
% 29.22/29.06  tff(decl_48439, type, fn_lactose_5: $i > $i).
% 29.22/29.06  tff(decl_48440, type, fn_lactose_6: $i > $i).
% 29.22/29.06  tff(decl_48441, type, fn_lactose_7: $i > $i).
% 29.22/29.06  tff(decl_48442, type, fn_lactose_8: $i > $i).
% 29.22/29.06  tff(decl_48443, type, fn_lactose_9: $i > $i).
% 29.22/29.06  tff(decl_48444, type, fn_lactose_10: $i > $i).
% 29.22/29.06  tff(decl_48445, type, fn_lactose_11: $i > $i).
% 29.22/29.06  tff(decl_48446, type, fn_lactose_12: $i > $i).
% 29.22/29.06  tff(decl_48447, type, fn_lactose_13: $i > $i).
% 29.22/29.06  tff(decl_48448, type, fn_lactose_14: $i > $i).
% 29.22/29.06  tff(decl_48449, type, fn_lactose_15: $i > $i).
% 29.22/29.06  tff(decl_48450, type, fn_lactose_16: $i > $i).
% 29.22/29.06  tff(decl_48451, type, fn_lactose_17: $i > $i).
% 29.22/29.06  tff(decl_48452, type, fn_lactose_18: $i > $i).
% 29.22/29.06  tff(decl_48453, type, fn_lactose_19: $i > $i).
% 29.22/29.06  tff(decl_48454, type, fn_lactose_20: $i > $i).
% 29.22/29.06  tff(decl_48455, type, fn_lactose_21: $i > $i).
% 29.22/29.06  tff(decl_48456, type, fn_lactose_22: $i > $i).
% 29.22/29.06  tff(decl_48457, type, fn_lactose_23: $i > $i).
% 29.22/29.06  tff(decl_48458, type, fn_lactose_25: $i > $i).
% 29.22/29.06  tff(decl_48459, type, fn_lactose_29: $i > $i).
% 29.22/29.06  tff(decl_48460, type, fn_lactose_30: $i > $i).
% 29.22/29.06  tff(decl_48461, type, fn_lactose_31: $i > $i).
% 29.22/29.06  tff(decl_48462, type, fn_lactose_32: $i > $i).
% 29.22/29.06  tff(decl_48463, type, fn_lactose_33: $i > $i).
% 29.22/29.06  tff(decl_48464, type, fn_lactose_39: $i > $i).
% 29.22/29.06  tff(decl_48465, type, fn_lactose_40: $i > $i).
% 29.22/29.06  tff(decl_48466, type, fn_lactose_41: $i > $i).
% 29.22/29.06  tff(decl_48467, type, fn_lactose_42: $i > $i).
% 29.22/29.06  tff(decl_48468, type, fn_lactose_43: $i > $i).
% 29.22/29.06  tff(decl_48469, type, fn_lactose_44: $i > $i).
% 29.22/29.06  tff(decl_48470, type, fn_lactose_45: $i > $i).
% 29.22/29.06  tff(decl_48471, type, fn_lactose_46: $i > $i).
% 29.22/29.06  tff(decl_48472, type, fn_lactose_50: $i > $i).
% 29.22/29.06  tff(decl_48473, type, fn_lactose_51: $i > $i).
% 29.22/29.06  tff(decl_48474, type, fn_lactose_56: $i > $i).
% 29.22/29.06  tff(decl_48475, type, fn_lactose_57: $i > $i).
% 29.22/29.06  tff(decl_48476, type, fn_lactose_58: $i > $i).
% 29.22/29.06  tff(decl_48477, type, fn_lactose_59: $i > $i).
% 29.22/29.06  tff(decl_48478, type, fn_lactose_66: $i > $i).
% 29.22/29.06  tff(decl_48479, type, fn_lactose_67: $i > $i).
% 29.22/29.06  tff(decl_48480, type, fn_lactose_68: $i > $i).
% 29.22/29.06  tff(decl_48481, type, fn_lactose_69: $i > $i).
% 29.22/29.06  tff(decl_48482, type, fn_lactose_70: $i > $i).
% 29.22/29.06  tff(decl_48483, type, fn_lactose_71: $i > $i).
% 29.22/29.06  tff(decl_48484, type, fn_lactose_72: $i > $i).
% 29.22/29.06  tff(decl_48485, type, fn_lactose_73: $i > $i).
% 29.22/29.06  tff(decl_48486, type, fn_lactose_74: $i > $i).
% 29.22/29.06  tff(decl_48487, type, fn_lactose_75: $i > $i).
% 29.22/29.06  tff(decl_48488, type, fn_lactose_76: $i > $i).
% 29.22/29.06  tff(decl_48489, type, fn_lactose_77: $i > $i).
% 29.22/29.06  tff(decl_48490, type, fn_lactose_65: $i > $i).
% 29.22/29.06  tff(decl_48491, type, fn_lactose_84: $i > $i).
% 29.22/29.06  tff(decl_48492, type, fn_lactose_54: $i > $i).
% 29.22/29.06  tff(decl_48493, type, fn_lactose_55: $i > $i).
% 29.22/29.06  tff(decl_48494, type, 'Lagging-strand': $i).
% 29.22/29.06  tff(decl_48495, type, 'The lagging strand is that strand of the DNA double helix that is orientated in a 3\\ to 5\\ manner. Because of its orientation, opposite to the working orientation of DNA polymerase III which is in a 5\\ to 3\\ manner, replication of the lagging strand is more complicated than of the leading strand.On the lagging strand, primase reads the DNA and adds RNA to it in short, separated segments. In eukaryotes, primase is intrinsic to Pol ?. DNA polymerase III or Pol ? lengthens the primed segments, forming Okazaki fragments. Primer removal in eukaryotes is also performed by Pol ?. In prokaryotes, DNA polymerase I reads the fragments, removes the RNA using its flap endonuclease domain, and replaces the RNA nucleotides with DNA nucleotides (this is necessary because RNA and DNA use slightly different kinds of nucleotides). DNA ligase joins the fragments together': $i).
% 29.22/29.06  tff(decl_48496, type, 'strand of lagging': $i).
% 29.22/29.06  tff(decl_48497, type, 'lagging strand': $i).
% 29.22/29.06  tff(decl_48498, type, 'lagging-strand': $i).
% 29.22/29.06  tff(decl_48499, type, 'Lagomorpha': $i).
% 29.22/29.06  tff(decl_48500, type, 'Mammalian order that includes rabbits, hares, and pikas.': $i).
% 29.22/29.06  tff(decl_48501, type, lagomorpha: $i).
% 29.22/29.06  tff(decl_48502, type, fn_lagomorpha_3: $i > $i).
% 29.22/29.06  tff(decl_48503, type, fn_lagomorpha_4: $i > $i).
% 29.22/29.06  tff(decl_48504, type, fn_lagomorpha_5: $i > $i).
% 29.22/29.06  tff(decl_48505, type, fn_lagomorpha_6: $i > $i).
% 29.22/29.06  tff(decl_48506, type, fn_lagomorpha_7: $i > $i).
% 29.22/29.06  tff(decl_48507, type, fn_lagomorpha_8: $i > $i).
% 29.22/29.06  tff(decl_48508, type, fn_lagomorpha_9: $i > $i).
% 29.22/29.06  tff(decl_48509, type, fn_lagomorpha_10: $i > $i).
% 29.22/29.06  tff(decl_48510, type, fn_lagomorpha_11: $i > $i).
% 29.22/29.06  tff(decl_48511, type, fn_lagomorpha_12: $i > $i).
% 29.22/29.06  tff(decl_48512, type, fn_lagomorpha_13: $i > $i).
% 29.22/29.06  tff(decl_48513, type, fn_lagomorpha_14: $i > $i).
% 29.22/29.06  tff(decl_48514, type, fn_lagomorpha_15: $i > $i).
% 29.22/29.06  tff(decl_48515, type, fn_lagomorpha_16: $i > $i).
% 29.22/29.06  tff(decl_48516, type, fn_lagomorpha_17: $i > $i).
% 29.22/29.06  tff(decl_48517, type, fn_lagomorpha_18: $i > $i).
% 29.22/29.06  tff(decl_48518, type, fn_lagomorpha_19: $i > $i).
% 29.22/29.06  tff(decl_48519, type, fn_lagomorpha_20: $i > $i).
% 29.22/29.06  tff(decl_48520, type, fn_lagomorpha_21: $i > $i).
% 29.22/29.06  tff(decl_48521, type, fn_lagomorpha_22: $i > $i).
% 29.22/29.06  tff(decl_48522, type, fn_lagomorpha_23: $i > $i).
% 29.22/29.06  tff(decl_48523, type, fn_lagomorpha_24: $i > $i).
% 29.22/29.06  tff(decl_48524, type, fn_lagomorpha_25: $i > $i).
% 29.22/29.06  tff(decl_48525, type, fn_lagomorpha_26: $i > $i).
% 29.22/29.06  tff(decl_48526, type, fn_lagomorpha_27: $i > $i).
% 29.22/29.06  tff(decl_48527, type, fn_lagomorpha_28: $i > $i).
% 29.22/29.06  tff(decl_48528, type, fn_lagomorpha_29: $i > $i).
% 29.22/29.06  tff(decl_48529, type, fn_lagomorpha_30: $i > $i).
% 29.22/29.06  tff(decl_48530, type, fn_lagomorpha_31: $i > $i).
% 29.22/29.06  tff(decl_48531, type, fn_lagomorpha_32: $i > $i).
% 29.22/29.06  tff(decl_48532, type, fn_lagomorpha_33: $i > $i).
% 29.22/29.06  tff(decl_48533, type, fn_lagomorpha_1: $i > $i).
% 29.22/29.06  tff(decl_48534, type, fn_mammal_77: $i > $i).
% 29.22/29.06  tff(decl_48535, type, fn_lagomorpha_2: $i > $i).
% 29.22/29.06  tff(decl_48536, type, fn_mammal_99: $i > $i).
% 29.22/29.06  tff(decl_48537, type, fn_mammal_91: $i > $i).
% 29.22/29.06  tff(decl_48538, type, fn_mammal_93: $i > $i).
% 29.22/29.06  tff(decl_48539, type, fn_mammal_3: $i > $i).
% 29.22/29.06  tff(decl_48540, type, fn_mammal_94: $i > $i).
% 29.22/29.06  tff(decl_48541, type, fn_mammal_95: $i > $i).
% 29.22/29.06  tff(decl_48542, type, fn_mammal_6: $i > $i).
% 29.22/29.06  tff(decl_48543, type, fn_mammal_2: $i > $i).
% 29.22/29.06  tff(decl_48544, type, fn_mammal_60: $i > $i).
% 29.22/29.06  tff(decl_48545, type, fn_mammal_78: $i > $i).
% 29.22/29.06  tff(decl_48546, type, fn_mammal_61: $i > $i).
% 29.22/29.06  tff(decl_48547, type, fn_mammal_65: $i > $i).
% 29.22/29.06  tff(decl_48548, type, fn_mammal_18: $i > $i).
% 29.22/29.06  tff(decl_48549, type, fn_mammal_97: $i > $i).
% 29.22/29.06  tff(decl_48550, type, fn_mammal_92: $i > $i).
% 29.22/29.06  tff(decl_48551, type, fn_mammal_79: $i > $i).
% 29.22/29.06  tff(decl_48552, type, fn_mammal_84: $i > $i).
% 29.22/29.06  tff(decl_48553, type, fn_mammal_83: $i > $i).
% 29.22/29.06  tff(decl_48554, type, fn_mammal_85: $i > $i).
% 29.22/29.06  tff(decl_48555, type, fn_mammal_98: $i > $i).
% 29.22/29.06  tff(decl_48556, type, fn_mammal_88: $i > $i).
% 29.22/29.06  tff(decl_48557, type, fn_mammal_80: $i > $i).
% 29.22/29.06  tff(decl_48558, type, fn_mammal_39: $i > $i).
% 29.22/29.06  tff(decl_48559, type, fn_mammal_89: $i > $i).
% 29.22/29.06  tff(decl_48560, type, fn_mammal_76: $i > $i).
% 29.22/29.06  tff(decl_48561, type, fn_mammal_81: $i > $i).
% 29.22/29.06  tff(decl_48562, type, 'Lake': $i).
% 29.22/29.06  tff(decl_48563, type, 'A large body of water, often (but not always) freshwater, located within a land mass.': $i).
% 29.22/29.06  tff(decl_48564, type, lake: $i).
% 29.22/29.06  tff(decl_48565, type, ocean_1: $i > $o).
% 29.22/29.06  tff(decl_48566, type, fn_lake_1: $i > $i).
% 29.22/29.06  tff(decl_48567, type, pelagic_zone_1: $i > $o).
% 29.22/29.06  tff(decl_48568, type, fn_lake_2: $i > $i).
% 29.22/29.06  tff(decl_48569, type, fn_lake_3: $i > $i).
% 29.22/29.06  tff(decl_48570, type, fn_lake_4: $i > $i).
% 29.22/29.06  tff(decl_48571, type, fn_lake_5: $i > $i).
% 29.22/29.06  tff(decl_48572, type, shore_1: $i > $o).
% 29.22/29.06  tff(decl_48573, type, fn_lake_6: $i > $i).
% 29.22/29.06  tff(decl_48574, type, fn_lake_7: $i > $i).
% 29.22/29.06  tff(decl_48575, type, fn_lake_10: $i > $i).
% 29.22/29.06  tff(decl_48576, type, fn_lake_11: $i > $i).
% 29.22/29.06  tff(decl_48577, type, fn_lake_12: $i > $i).
% 29.22/29.06  tff(decl_48578, type, fn_lake_13: $i > $i).
% 29.22/29.06  tff(decl_48579, type, fn_lake_14: $i > $i).
% 29.22/29.06  tff(decl_48580, type, fn_lake_15: $i > $i).
% 29.22/29.06  tff(decl_48581, type, fn_lake_16: $i > $i).
% 29.22/29.06  tff(decl_48582, type, fn_lake_17: $i > $i).
% 29.22/29.06  tff(decl_48583, type, fn_lake_18: $i > $i).
% 29.22/29.06  tff(decl_48584, type, fn_lake_19: $i > $i).
% 29.22/29.06  tff(decl_48585, type, fn_lake_20: $i > $i).
% 29.22/29.06  tff(decl_48586, type, fn_lake_21: $i > $i).
% 29.22/29.06  tff(decl_48587, type, fn_lake_22: $i > $i).
% 29.22/29.06  tff(decl_48588, type, fn_lake_23: $i > $i).
% 29.22/29.06  tff(decl_48589, type, fn_lake_24: $i > $i).
% 29.22/29.06  tff(decl_48590, type, fn_lake_25: $i > $i).
% 29.22/29.06  tff(decl_48591, type, fn_lake_26: $i > $i).
% 29.22/29.06  tff(decl_48592, type, fn_lake_27: $i > $i).
% 29.22/29.06  tff(decl_48593, type, fn_lake_28: $i > $i).
% 29.22/29.06  tff(decl_48594, type, fn_lake_29: $i > $i).
% 29.22/29.06  tff(decl_48595, type, fn_lake_30: $i > $i).
% 29.22/29.06  tff(decl_48596, type, fn_lake_31: $i > $i).
% 29.22/29.06  tff(decl_48597, type, fn_lake_32: $i > $i).
% 29.22/29.06  tff(decl_48598, type, fn_lake_33: $i > $i).
% 29.22/29.06  tff(decl_48599, type, fn_lake_34: $i > $i).
% 29.22/29.06  tff(decl_48600, type, fn_lake_35: $i > $i).
% 29.22/29.06  tff(decl_48601, type, fn_lake_36: $i > $i).
% 29.22/29.06  tff(decl_48602, type, fn_lake_37: $i > $i).
% 29.22/29.06  tff(decl_48603, type, fn_lake_38: $i > $i).
% 29.22/29.06  tff(decl_48604, type, fn_lake_39: $i > $i).
% 29.22/29.06  tff(decl_48605, type, fn_lake_40: $i > $i).
% 29.22/29.06  tff(decl_48606, type, fn_lake_41: $i > $i).
% 29.22/29.06  tff(decl_48607, type, fn_lake_42: $i > $i).
% 29.22/29.06  tff(decl_48608, type, fn_lake_43: $i > $i).
% 29.22/29.06  tff(decl_48609, type, fn_lake_44: $i > $i).
% 29.22/29.06  tff(decl_48610, type, fn_lake_45: $i > $i).
% 29.22/29.06  tff(decl_48611, type, fn_lake_46: $i > $i).
% 29.22/29.06  tff(decl_48612, type, fn_lake_47: $i > $i).
% 29.22/29.06  tff(decl_48613, type, fn_lake_48: $i > $i).
% 29.22/29.06  tff(decl_48614, type, fn_lake_49: $i > $i).
% 29.22/29.06  tff(decl_48615, type, fn_lake_50: $i > $i).
% 29.22/29.06  tff(decl_48616, type, fn_lake_51: $i > $i).
% 29.22/29.06  tff(decl_48617, type, fn_lake_9: $i > $i).
% 29.22/29.06  tff(decl_48618, type, fn_lake_8: $i > $i).
% 29.22/29.06  tff(decl_48619, type, fn_lake_53: $i > $i).
% 29.22/29.06  tff(decl_48620, type, fn_lake_54: $i > $i).
% 29.22/29.06  tff(decl_48621, type, fn_lake_52: $i > $i).
% 29.22/29.06  tff(decl_48622, type, fn_lake_55: $i > $i).
% 29.22/29.06  tff(decl_48623, type, fn_lake_56: $i > $i).
% 29.22/29.06  tff(decl_48624, type, 'Lamarcks-Theory-Of-Evolution': $i).
% 29.22/29.06  tff(decl_48625, type, 'The theory that organisms can pass to the offspring traits that are acquired during a lifetime.': $i).
% 29.22/29.06  tff(decl_48626, type, 'lamarcks theory of evolution': $i).
% 29.22/29.06  tff(decl_48627, type, 'lamarcks-theory-of-evolution': $i).
% 29.22/29.06  tff(decl_48628, type, lambda_phage_1: $i > $o).
% 29.22/29.06  tff(decl_48629, type, 'Lambda-Phage': $i).
% 29.22/29.06  tff(decl_48630, type, 'A bacteriophage that infects the bacterium E. coli.': $i).
% 29.22/29.06  tff(decl_48631, type, 'phage of lambda': $i).
% 29.22/29.06  tff(decl_48632, type, 'lambda phage': $i).
% 29.22/29.06  tff(decl_48633, type, 'lambda-phage': $i).
% 29.22/29.06  tff(decl_48634, type, 'Lamprey': $i).
% 29.22/29.06  tff(decl_48635, type, 'An aquatic craniate that lacks jaws but has a toothed, rasping mouth. Some are parasites of fishes, but most are free-living predators.': $i).
% 29.22/29.06  tff(decl_48636, type, lamprey: $i).
% 29.22/29.06  tff(decl_48637, type, lancelet_1: $i > $o).
% 29.22/29.06  tff(decl_48638, type, 'Lancelet': $i).
% 29.22/29.06  tff(decl_48639, type, 'A small, bladelike marine chordate; member of the subphylum Cephalochordata, which lack backbones and thus are not considered vertebrates.': $i).
% 29.22/29.06  tff(decl_48640, type, landmark_1: $i > $o).
% 29.22/29.06  tff(decl_48641, type, 'Landmark': $i).
% 29.22/29.06  tff(decl_48642, type, 'A location indicatora point of reference for orientation during navigation.': $i).
% 29.22/29.06  tff(decl_48643, type, landmark: $i).
% 29.22/29.06  tff(decl_48644, type, 'Landscape': $i).
% 29.22/29.06  tff(decl_48645, type, 'A large area that contains few to several different ecosystems that exchange organisms, materials, and energy.': $i).
% 29.22/29.06  tff(decl_48646, type, landscape: $i).
% 29.22/29.06  tff(decl_48647, type, landscape_ecology_1: $i > $o).
% 29.22/29.06  tff(decl_48648, type, 'Landscape-Ecology': $i).
% 29.22/29.06  tff(decl_48649, type, 'The scientific study of the effect of the spatial arrangement of different habitats on the abundance and distribution of organisms and ecosystem processes.': $i).
% 29.22/29.06  tff(decl_48650, type, 'ecology of landscape': $i).
% 29.22/29.06  tff(decl_48651, type, 'landscape ecology': $i).
% 29.22/29.06  tff(decl_48652, type, 'landscape-ecology': $i).
% 29.22/29.06  tff(decl_48653, type, 'Language': $i).
% 29.22/29.06  tff(decl_48654, type, language: $i).
% 29.22/29.06  tff(decl_48655, type, lanthanum_1: $i > $o).
% 29.22/29.06  tff(decl_48656, type, 'Lanthanum': $i).
% 29.22/29.06  tff(decl_48657, type, 'Lanthanum is a metal atom with atomic number 57. It is represented by the symbol La.': $i).
% 29.22/29.06  tff(decl_48658, type, lanthanum: $i).
% 29.22/29.06  tff(decl_48659, type, la: $i).
% 29.22/29.06  tff(decl_48660, type, fn_lanthanum_4: $i > $i).
% 29.22/29.06  tff(decl_48661, type, fn_lanthanum_5: $i > $i).
% 29.22/29.06  tff(decl_48662, type, fn_lanthanum_6: $i > $i).
% 29.22/29.06  tff(decl_48663, type, fn_lanthanum_7: $i > $i).
% 29.22/29.06  tff(decl_48664, type, fn_lanthanum_11: $i > $i).
% 29.22/29.06  tff(decl_48665, type, fn_lanthanum_12: $i > $i).
% 29.22/29.06  tff(decl_48666, type, fn_lanthanum_13: $i > $i).
% 29.22/29.06  tff(decl_48667, type, fn_lanthanum_14: $i > $i).
% 29.22/29.06  tff(decl_48668, type, "57": $i).
% 29.22/29.06  tff(decl_48669, type, "139": $i).
% 29.22/29.06  tff(decl_48670, type, "138.9": $i).
% 29.22/29.06  tff(decl_48671, type, fn_lanthanum_9: $i > $i).
% 29.22/29.06  tff(decl_48672, type, fn_lanthanum_10: $i > $i).
% 29.22/29.06  tff(decl_48673, type, fn_lanthanum_8: $i > $i).
% 29.22/29.06  tff(decl_48674, type, 'Lard': $i).
% 29.22/29.06  tff(decl_48675, type, 'Saturated fat, derived from pig fat, which is used in cooking.': $i).
% 29.22/29.06  tff(decl_48676, type, lard: $i).
% 29.22/29.06  tff(decl_48677, type, 'Large-Intestine': $i).
% 29.22/29.06  tff(decl_48678, type, 'The portion of the vertebrate digestive tract between the small intestine and the anus. The large intestine functions primarily in water reabsorption and feces formation.': $i).
% 29.22/29.06  tff(decl_48679, type, 'intestine of large': $i).
% 29.22/29.06  tff(decl_48680, type, 'large intestine': $i).
% 29.22/29.06  tff(decl_48681, type, 'large-intestine': $i).
% 29.22/29.06  tff(decl_48682, type, fn_large_intestine_1: $i > $i).
% 29.22/29.06  tff(decl_48683, type, reabsorption_1: $i > $o).
% 29.22/29.06  tff(decl_48684, type, fn_large_intestine_3: $i > $i).
% 29.22/29.06  tff(decl_48685, type, fn_large_intestine_4: $i > $i).
% 29.22/29.06  tff(decl_48686, type, fn_large_intestine_5: $i > $i).
% 29.22/29.06  tff(decl_48687, type, proximal_1: $i > $o).
% 29.22/29.06  tff(decl_48688, type, fn_large_intestine_6: $i > $i).
% 29.22/29.06  tff(decl_48689, type, fn_large_intestine_8: $i > $i).
% 29.22/29.06  tff(decl_48690, type, fn_large_intestine_9: $i > $i).
% 29.22/29.06  tff(decl_48691, type, fn_large_intestine_10: $i > $i).
% 29.22/29.06  tff(decl_48692, type, small_intestine_0: $i).
% 29.22/29.06  tff(decl_48693, type, 'Large-Ribosomal-Subunit': $i).
% 29.22/29.06  tff(decl_48694, type, 'A large ribosomal subunit is a presursor part of a  ribosome. It forms ribosomes along with the small ribosomal subunit.': $i).
% 29.22/29.06  tff(decl_48695, type, 'large ribosomal subunit': $i).
% 29.22/29.06  tff(decl_48696, type, 'large-ribosomal-subunit': $i).
% 29.22/29.06  tff(decl_48697, type, small_ribosomal_subunit_1: $i > $o).
% 29.22/29.06  tff(decl_48698, type, translation_initiation_complex_1: $i > $o).
% 29.22/29.06  tff(decl_48699, type, fn_large_ribosomal_subunit_1: $i > $i).
% 29.22/29.06  tff(decl_48700, type, ribosomal_rna_1: $i > $o).
% 29.22/29.06  tff(decl_48701, type, fn_large_ribosomal_subunit_2: $i > $i).
% 29.22/29.06  tff(decl_48702, type, 'Larva': $i).
% 29.22/29.06  tff(decl_48703, type, 'A larva is an immature life stage of many animal species. Larvae are sexually immature and may differ in many aspects from the mature adult form, including appearance, habitat, and feeding habits.': $i).
% 29.22/29.06  tff(decl_48704, type, larva: $i).
% 29.22/29.06  tff(decl_48705, type, fn_larva_1: $i > $i).
% 29.22/29.06  tff(decl_48706, type, 'Larva-Hatching': $i).
% 29.22/29.06  tff(decl_48707, type, 'The hatching of larvae from the egg is called as larva hatching.': $i).
% 29.22/29.06  tff(decl_48708, type, hatch: $i).
% 29.22/29.06  tff(decl_48709, type, 'hatching of larva': $i).
% 29.22/29.06  tff(decl_48710, type, 'larva hatching': $i).
% 29.22/29.06  tff(decl_48711, type, 'larva-hatching': $i).
% 29.22/29.06  tff(decl_48712, type, fn_larva_hatching_2: $i > $i).
% 29.22/29.06  tff(decl_48713, type, 'Larval-Stage': $i).
% 29.22/29.06  tff(decl_48714, type, 'The larval stage is actually the growth stage of the metamorphosis of an organism.': $i).
% 29.22/29.06  tff(decl_48715, type, 'larval stage': $i).
% 29.22/29.06  tff(decl_48716, type, 'larval-stage': $i).
% 29.22/29.06  tff(decl_48717, type, larynx_1: $i > $o).
% 29.22/29.06  tff(decl_48718, type, 'Larynx': $i).
% 29.22/29.06  tff(decl_48719, type, 'An organ in the neck of air-breathing vertebrates that contains the vocal folds necessary for phonation.': $i).
% 29.22/29.06  tff(decl_48720, type, 'voice box': $i).
% 29.22/29.06  tff(decl_48721, type, 'voice-box': $i).
% 29.22/29.06  tff(decl_48722, type, larynx: $i).
% 29.22/29.06  tff(decl_48723, type, 'Laser-Light': $i).
% 29.22/29.06  tff(decl_48724, type, 'Monochromatic, coherent (wavelengths are synchronized), and collimated (waves are all exactly parallel to each other)  light emitted from a laser.  These characteristics enable the light beam to be narrow and all the energy to be focused precisely on a small spot.': $i).
% 29.22/29.06  tff(decl_48725, type, 'laser beam': $i).
% 29.22/29.06  tff(decl_48726, type, 'laser-beam': $i).
% 29.22/29.06  tff(decl_48727, type, 'light of laser': $i).
% 29.22/29.06  tff(decl_48728, type, 'laser light': $i).
% 29.22/29.06  tff(decl_48729, type, 'laser-light': $i).
% 29.22/29.06  tff(decl_48730, type, lateral_1: $i > $o).
% 29.22/29.06  tff(decl_48731, type, 'Lateral': $i).
% 29.22/29.06  tff(decl_48732, type, 'Region at the sides of the body.  Opposite of medial.': $i).
% 29.22/29.06  tff(decl_48733, type, lateral: $i).
% 29.22/29.06  tff(decl_48734, type, 'Lateral-Geniculate': $i).
% 29.22/29.06  tff(decl_48735, type, 'One of a pair of structures in the brain that are the destination for most of the ganglion cell axons that form the optic nerves.': $i).
% 29.22/29.06  tff(decl_48736, type, 'lateral geniculate': $i).
% 29.22/29.06  tff(decl_48737, type, 'lateral-geniculate': $i).
% 29.22/29.06  tff(decl_48738, type, lateral_inhibition_1: $i > $o).
% 29.22/29.06  tff(decl_48739, type, 'Lateral-Inhibition': $i).
% 29.22/29.06  tff(decl_48740, type, 'The ability of a stimulated neuron to inhibit the activity of neighboring neurons. This results in a sharpened response to a local stimulus.': $i).
% 29.22/29.06  tff(decl_48741, type, 'inhibition of lateral': $i).
% 29.22/29.06  tff(decl_48742, type, 'lateral inhibition': $i).
% 29.22/29.06  tff(decl_48743, type, 'lateral-inhibition': $i).
% 29.22/29.06  tff(decl_48744, type, 'Lateral-Line': $i).
% 29.22/29.06  tff(decl_48745, type, 'A sensory organ found in fishes and aquatic amphibians. The lateral line consists of a series of pores running along the sides of the body. It detects motion and vibration in the water.': $i).
% 29.22/29.06  tff(decl_48746, type, 'line of lateral': $i).
% 29.22/29.06  tff(decl_48747, type, 'lateral line': $i).
% 29.22/29.06  tff(decl_48748, type, 'lateral-line': $i).
% 29.22/29.06  tff(decl_48749, type, 'Lateral-Line-System': $i).
% 29.22/29.06  tff(decl_48750, type, 'A sensory system found in fishes and aquatic amphibians. The lateral line consists of a series of pores running along the sides of the body. It detects motion and vibration in the water.': $i).
% 29.22/29.06  tff(decl_48751, type, 'lateral line system': $i).
% 29.22/29.06  tff(decl_48752, type, 'lateral-line-system': $i).
% 29.22/29.06  tff(decl_48753, type, 'Lateral-Meristem': $i).
% 29.22/29.06  tff(decl_48754, type, 'In plants, an area of growth that increases the diameter of a root or shoot. Examples include cork cambium and the vascular cambium.': $i).
% 29.22/29.06  tff(decl_48755, type, 'meristem of lateral': $i).
% 29.22/29.06  tff(decl_48756, type, 'lateral meristem': $i).
% 29.22/29.06  tff(decl_48757, type, 'lateral-meristem': $i).
% 29.22/29.06  tff(decl_48758, type, 'Lateral-Root': $i).
% 29.22/29.06  tff(decl_48759, type, 'A root that extends horizontally from the primary root and serves to anchor the plant in soil. Lateral roots also absorb water and nutrients from the soil.': $i).
% 29.22/29.06  tff(decl_48760, type, 'root of lateral': $i).
% 29.22/29.06  tff(decl_48761, type, 'lateral root': $i).
% 29.22/29.06  tff(decl_48762, type, 'lateral-root': $i).
% 29.22/29.06  tff(decl_48763, type, lateralization_1: $i > $o).
% 29.22/29.06  tff(decl_48764, type, 'Lateralization': $i).
% 29.22/29.06  tff(decl_48765, type, 'The segregation of function in the cerebral cortex into the left and right hemispheres of the brain.': $i).
% 29.22/29.06  tff(decl_48766, type, lateralization: $i).
% 29.22/29.06  tff(decl_48767, type, latitude_constant_1: $i > $o).
% 29.22/29.06  tff(decl_48768, type, 'Latitude-Constant': $i).
% 29.22/29.06  tff(decl_48769, type, 'constant of latitude': $i).
% 29.22/29.06  tff(decl_48770, type, 'latitude constant': $i).
% 29.22/29.06  tff(decl_48771, type, 'latitude-constant': $i).
% 29.22/29.06  tff(decl_48772, type, law_of_independent_assortment_1: $i > $o).
% 29.22/29.06  tff(decl_48773, type, 'Law-Of-Independent-Assortment': $i).
% 29.22/29.06  tff(decl_48774, type, 'Mendel\\s second law, stating that each allele pair segregates independently during gamete formation; applies when genes for two characteristics are located on different pairs of homologous chromosomes.': $i).
% 29.22/29.06  tff(decl_48775, type, 'law of independent assortment': $i).
% 29.22/29.06  tff(decl_48776, type, 'law-of-independent-assortment': $i).
% 29.22/29.06  tff(decl_48777, type, law_of_segregation_1: $i > $o).
% 29.22/29.06  tff(decl_48778, type, 'Law-of-Segregation': $i).
% 29.22/29.06  tff(decl_48779, type, 'Mendel\\s first law, stating that allele pairs separate during gamete formation, and then randomly re-form as pairs during the fusion of gametes at fertilization.': $i).
% 29.22/29.06  tff(decl_48780, type, 'segregation law': $i).
% 29.22/29.06  tff(decl_48781, type, 'segregation-law': $i).
% 29.22/29.06  tff(decl_48782, type, 'law of segregation': $i).
% 29.22/29.06  tff(decl_48783, type, 'law-of-segregation': $i).
% 29.22/29.06  tff(decl_48784, type, fn_law_of_segregation_1: $i > $i).
% 29.22/29.06  tff(decl_48785, type, fn_law_of_segregation_3: $i > $i).
% 29.22/29.06  tff(decl_48786, type, fn_law_of_segregation_4: $i > $i).
% 29.22/29.06  tff(decl_48787, type, fn_law_of_segregation_5: $i > $i).
% 29.22/29.06  tff(decl_48788, type, fn_law_of_segregation_6: $i > $i).
% 29.22/29.06  tff(decl_48789, type, fn_law_of_segregation_7: $i > $i).
% 29.22/29.06  tff(decl_48790, type, fn_law_of_segregation_8: $i > $i).
% 29.22/29.06  tff(decl_48791, type, fn_law_of_segregation_9: $i > $i).
% 29.22/29.06  tff(decl_48792, type, fn_law_of_segregation_10: $i > $i).
% 29.22/29.06  tff(decl_48793, type, fn_law_of_segregation_11: $i > $i).
% 29.22/29.06  tff(decl_48794, type, fn_law_of_segregation_12: $i > $i).
% 29.22/29.06  tff(decl_48795, type, fn_law_of_segregation_13: $i > $i).
% 29.22/29.06  tff(decl_48796, type, fn_law_of_segregation_14: $i > $i).
% 29.22/29.06  tff(decl_48797, type, fn_law_of_segregation_15: $i > $i).
% 29.22/29.06  tff(decl_48798, type, fn_law_of_segregation_16: $i > $i).
% 29.22/29.06  tff(decl_48799, type, fn_law_of_segregation_17: $i > $i).
% 29.22/29.06  tff(decl_48800, type, fn_law_of_segregation_18: $i > $i).
% 29.22/29.06  tff(decl_48801, type, fn_law_of_segregation_19: $i > $i).
% 29.22/29.06  tff(decl_48802, type, fn_law_of_segregation_20: $i > $i).
% 29.22/29.06  tff(decl_48803, type, fn_law_of_segregation_21: $i > $i).
% 29.22/29.06  tff(decl_48804, type, fn_law_of_segregation_22: $i > $i).
% 29.22/29.06  tff(decl_48805, type, fn_law_of_segregation_23: $i > $i).
% 29.22/29.06  tff(decl_48806, type, fn_law_of_segregation_24: $i > $i).
% 29.22/29.06  tff(decl_48807, type, fn_law_of_segregation_25: $i > $i).
% 29.22/29.06  tff(decl_48808, type, lawrencium_1: $i > $o).
% 29.22/29.06  tff(decl_48809, type, 'Lawrencium': $i).
% 29.22/29.06  tff(decl_48810, type, 'Lawrencium is a metal atom with atomic number 103. It is represented by the symbol Lr.': $i).
% 29.22/29.06  tff(decl_48811, type, lawrencium: $i).
% 29.22/29.06  tff(decl_48812, type, 'Lr': $i).
% 29.22/29.06  tff(decl_48813, type, fn_lawrencium_2: $i > $i).
% 29.22/29.06  tff(decl_48814, type, fn_lawrencium_3: $i > $i).
% 29.22/29.06  tff(decl_48815, type, fn_lawrencium_7: $i > $i).
% 29.22/29.06  tff(decl_48816, type, fn_lawrencium_8: $i > $i).
% 29.22/29.06  tff(decl_48817, type, fn_lawrencium_9: $i > $i).
% 29.22/29.06  tff(decl_48818, type, fn_lawrencium_10: $i > $i).
% 29.22/29.06  tff(decl_48819, type, "103": $i).
% 29.22/29.06  tff(decl_48820, type, "260": $i).
% 29.22/29.06  tff(decl_48821, type, fn_lawrencium_5: $i > $i).
% 29.22/29.06  tff(decl_48822, type, fn_lawrencium_6: $i > $i).
% 29.22/29.06  tff(decl_48823, type, fn_lawrencium_4: $i > $i).
% 29.22/29.06  tff(decl_48824, type, 'Layer': $i).
% 29.22/29.06  tff(decl_48825, type, 'A relatively thin sheetlike expanse or region lying over or under another.': $i).
% 29.22/29.07  tff(decl_48826, type, layer: $i).
% 29.22/29.07  tff(decl_48827, type, 'Leaching': $i).
% 29.22/29.07  tff(decl_48828, type, 'The dissolving and carrying of minerals and other compounds in a carrier liquid, usually water.': $i).
% 29.22/29.07  tff(decl_48829, type, leaching: $i).
% 29.22/29.07  tff(decl_48830, type, 'Lead': $i).
% 29.22/29.07  tff(decl_48831, type, 'Lead is a metal atom with atomic number 82. It is represented by the symbol Pb.': $i).
% 29.22/29.07  tff(decl_48832, type, 'Pb': $i).
% 29.22/29.07  tff(decl_48833, type, lead: $i).
% 29.22/29.07  tff(decl_48834, type, fn_lead_1: $i > $i).
% 29.22/29.07  tff(decl_48835, type, fn_lead_2: $i > $i).
% 29.22/29.07  tff(decl_48836, type, fn_lead_3: $i > $i).
% 29.22/29.07  tff(decl_48837, type, fn_lead_8: $i > $i).
% 29.22/29.07  tff(decl_48838, type, fn_lead_9: $i > $i).
% 29.22/29.07  tff(decl_48839, type, fn_lead_10: $i > $i).
% 29.22/29.07  tff(decl_48840, type, fn_lead_11: $i > $i).
% 29.22/29.07  tff(decl_48841, type, fn_lead_12: $i > $i).
% 29.22/29.07  tff(decl_48842, type, fn_lead_13: $i > $i).
% 29.22/29.07  tff(decl_48843, type, fn_pb_plus_2_1: $i > $i).
% 29.22/29.07  tff(decl_48844, type, "207.2": $i).
% 29.22/29.07  tff(decl_48845, type, "207": $i).
% 29.22/29.07  tff(decl_48846, type, "2.33": $i).
% 29.22/29.07  tff(decl_48847, type, fn_lead_14: $i > $i).
% 29.22/29.07  tff(decl_48848, type, fn_lead_7: $i > $i).
% 29.22/29.07  tff(decl_48849, type, fn_lead_6: $i > $i).
% 29.22/29.07  tff(decl_48850, type, 'Leader-Segment': $i).
% 29.22/29.07  tff(decl_48851, type, 'Leader segment is a sequence present at 5\\ end of the mRNA wich help in initiation of translation by allowing the assembly of translation initiation complex': $i).
% 29.22/29.07  tff(decl_48852, type, 'leader segment': $i).
% 29.22/29.07  tff(decl_48853, type, 'leader-segment': $i).
% 29.22/29.07  tff(decl_48854, type, 'segment of leader': $i).
% 29.22/29.07  tff(decl_48855, type, 'Leading-strand': $i).
% 29.22/29.07  tff(decl_48856, type, 'The leading strand is that strand of the DNA double helix that is orientated in a 5\\ to 3\\ manner. On the leading strand, a polymerase reads the DNA and adds nucleotides to it continuously. This polymerase is DNA polymerase III (DNA Pol III) in prokaryotes and presumably Pol ?[10][11] in eukaryotes.': $i).
% 29.22/29.07  tff(decl_48857, type, 'strand of leading': $i).
% 29.22/29.07  tff(decl_48858, type, 'leading strand': $i).
% 29.22/29.07  tff(decl_48859, type, 'leading-strand': $i).
% 29.22/29.07  tff(decl_48860, type, 'Leaf': $i).
% 29.22/29.07  tff(decl_48861, type, 'Leaf is an above-ground plant organ specialized for photosynthesis.': $i).
% 29.22/29.07  tff(decl_48862, type, leaves: $i).
% 29.22/29.07  tff(decl_48863, type, leaf: $i).
% 29.22/29.07  tff(decl_48864, type, fn_leaf_2: $i > $i).
% 29.22/29.07  tff(decl_48865, type, fn_leaf_4: $i > $i).
% 29.22/29.07  tff(decl_48866, type, fn_leaf_11: $i > $i).
% 29.22/29.07  tff(decl_48867, type, fn_leaf_15: $i > $i).
% 29.22/29.07  tff(decl_48868, type, fn_leaf_18: $i > $i).
% 29.22/29.07  tff(decl_48869, type, fn_leaf_19: $i > $i).
% 29.22/29.07  tff(decl_48870, type, fn_leaf_20: $i > $i).
% 29.22/29.07  tff(decl_48871, type, fn_leaf_22: $i > $i).
% 29.22/29.07  tff(decl_48872, type, fn_leaf_23: $i > $i).
% 29.22/29.07  tff(decl_48873, type, fn_leaf_24: $i > $i).
% 29.22/29.07  tff(decl_48874, type, fn_leaf_25: $i > $i).
% 29.22/29.07  tff(decl_48875, type, fn_leaf_28: $i > $i).
% 29.22/29.07  tff(decl_48876, type, fn_leaf_29: $i > $i).
% 29.22/29.07  tff(decl_48877, type, fn_leaf_30: $i > $i).
% 29.22/29.07  tff(decl_48878, type, fn_leaf_31: $i > $i).
% 29.22/29.07  tff(decl_48879, type, fn_leaf_32: $i > $i).
% 29.22/29.07  tff(decl_48880, type, fn_leaf_33: $i > $i).
% 29.22/29.07  tff(decl_48881, type, fn_leaf_34: $i > $i).
% 29.22/29.07  tff(decl_48882, type, fn_leaf_36: $i > $i).
% 29.22/29.07  tff(decl_48883, type, fn_leaf_37: $i > $i).
% 29.22/29.07  tff(decl_48884, type, fn_leaf_39: $i > $i).
% 29.22/29.07  tff(decl_48885, type, fn_leaf_40: $i > $i).
% 29.22/29.07  tff(decl_48886, type, fn_leaf_42: $i > $i).
% 29.22/29.07  tff(decl_48887, type, fn_leaf_49: $i > $i).
% 29.22/29.07  tff(decl_48888, type, fn_leaf_54: $i > $i).
% 29.22/29.07  tff(decl_48889, type, fn_leaf_55: $i > $i).
% 29.22/29.07  tff(decl_48890, type, fn_plant_vein_2: $i > $i).
% 29.22/29.07  tff(decl_48891, type, fn_stoma_6: $i > $i).
% 29.22/29.07  tff(decl_48892, type, fn_stoma_12: $i > $i).
% 29.22/29.07  tff(decl_48893, type, 'Leaf-Organ': $i).
% 29.22/29.07  tff(decl_48894, type, 'A specialized center of plant function composed of leaf tissue and specific to plants.': $i).
% 29.22/29.07  tff(decl_48895, type, 'organ of leaf': $i).
% 29.22/29.07  tff(decl_48896, type, 'leaf organ': $i).
% 29.22/29.07  tff(decl_48897, type, 'leaf-organ': $i).
% 29.22/29.07  tff(decl_48898, type, 'Leaf-Primordium': $i).
% 29.22/29.07  tff(decl_48899, type, 'Group of cells that will form a new leaf. Often seen as a small projection on the side of a shoot apical meristem.': $i).
% 29.22/29.07  tff(decl_48900, type, 'primordium of leaf': $i).
% 29.22/29.07  tff(decl_48901, type, 'leaf primordium': $i).
% 29.22/29.07  tff(decl_48902, type, 'leaf-primordium': $i).
% 29.22/29.07  tff(decl_48903, type, learn_1: $i > $o).
% 29.22/29.07  tff(decl_48904, type, 'Learn': $i).
% 29.22/29.07  tff(decl_48905, type, learn: $i).
% 29.22/29.07  tff(decl_48906, type, 'pick up': $i).
% 29.22/29.07  tff(decl_48907, type, pick_up: $i).
% 29.22/29.07  tff(decl_48908, type, out: $i).
% 29.22/29.07  tff(decl_48909, type, see: $i).
% 29.22/29.07  tff(decl_48910, type, memorize: $i).
% 29.22/29.07  tff(decl_48911, type, study: $i).
% 29.22/29.07  tff(decl_48912, type, 'Learned-Behavior': $i).
% 29.22/29.07  tff(decl_48913, type, 'Using specific experiences to modify behavior.': $i).
% 29.22/29.07  tff(decl_48914, type, 'learned behavior': $i).
% 29.22/29.07  tff(decl_48915, type, 'learned-behavior': $i).
% 29.22/29.07  tff(decl_48916, type, 'Learning': $i).
% 29.22/29.07  tff(decl_48917, type, acquisition: $i).
% 29.22/29.07  tff(decl_48918, type, learning: $i).
% 29.22/29.07  tff(decl_48919, type, 'basic cognitive process': $i).
% 29.22/29.07  tff(decl_48920, type, basic_cognitive_process: $i).
% 29.22/29.07  tff(decl_48921, type, 'Leave': $i).
% 29.22/29.07  tff(decl_48922, type, 'go away': $i).
% 29.22/29.07  tff(decl_48923, type, go_away: $i).
% 29.22/29.07  tff(decl_48924, type, 'go forth': $i).
% 29.22/29.07  tff(decl_48925, type, go_forth: $i).
% 29.22/29.07  tff(decl_48926, type, leech_1: $i > $o).
% 29.22/29.07  tff(decl_48927, type, 'Leech': $i).
% 29.22/29.07  tff(decl_48928, type, 'Type of annelid worm that has a sucker on the anterior and posterior ends. Many leeches are blood-sucking parasites and some have medicinal uses in limb reattachment and plastic surgery.': $i).
% 29.22/29.07  tff(decl_48929, type, leech: $i).
% 29.22/29.07  tff(decl_48930, type, 'Leg': $i).
% 29.22/29.07  tff(decl_48931, type, 'A leg is an anatomical animal structure used for locomotion. The distal end is often modified to distribute force (such as a foot). Most animals have an even number of legs.': $i).
% 29.22/29.07  tff(decl_48932, type, leg: $i).
% 29.22/29.07  tff(decl_48933, type, 'Legume': $i).
% 29.22/29.07  tff(decl_48934, type, 'A plant in the family Fabaceae (or Leguminosae), notable because most have root nodules that contain symbiotic nitrogen-fixing bacteria.': $i).
% 29.22/29.07  tff(decl_48935, type, pulse: $i).
% 29.22/29.07  tff(decl_48936, type, 'leguminous crop': $i).
% 29.22/29.07  tff(decl_48937, type, legume: $i).
% 29.22/29.07  tff(decl_48938, type, fn_legume_1: $i > $i).
% 29.22/29.07  tff(decl_48939, type, nodule_1: $i > $o).
% 29.22/29.07  tff(decl_48940, type, fn_legume_2: $i > $i).
% 29.22/29.07  tff(decl_48941, type, fn_legume_3: $i > $i).
% 29.22/29.07  tff(decl_48942, type, fn_legume_4: $i > $i).
% 29.22/29.07  tff(decl_48943, type, fn_legume_5: $i > $i).
% 29.22/29.07  tff(decl_48944, type, fn_legume_6: $i > $i).
% 29.22/29.07  tff(decl_48945, type, fn_legume_7: $i > $i).
% 29.22/29.07  tff(decl_48946, type, fn_legume_8: $i > $i).
% 29.22/29.07  tff(decl_48947, type, fn_legume_9: $i > $i).
% 29.22/29.07  tff(decl_48948, type, fn_legume_10: $i > $i).
% 29.22/29.07  tff(decl_48949, type, fn_legume_11: $i > $i).
% 29.22/29.07  tff(decl_48950, type, fn_legume_12: $i > $i).
% 29.22/29.07  tff(decl_48951, type, fn_legume_13: $i > $i).
% 29.22/29.07  tff(decl_48952, type, fn_legume_14: $i > $i).
% 29.22/29.07  tff(decl_48953, type, fn_legume_15: $i > $i).
% 29.22/29.07  tff(decl_48954, type, fn_legume_16: $i > $i).
% 29.22/29.07  tff(decl_48955, type, fn_legume_17: $i > $i).
% 29.22/29.07  tff(decl_48956, type, fn_legume_18: $i > $i).
% 29.22/29.07  tff(decl_48957, type, 'Length-Constant': $i).
% 29.22/29.07  tff(decl_48958, type, 'constant of length': $i).
% 29.22/29.07  tff(decl_48959, type, 'length constant': $i).
% 29.22/29.07  tff(decl_48960, type, 'length-constant': $i).
% 29.22/29.07  tff(decl_48961, type, length_scale_1: $i > $o).
% 29.22/29.07  tff(decl_48962, type, 'Length-Scale': $i).
% 29.22/29.07  tff(decl_48963, type, 'scale of length': $i).
% 29.22/29.07  tff(decl_48964, type, 'length scale': $i).
% 29.22/29.07  tff(decl_48965, type, 'length-scale': $i).
% 29.22/29.07  tff(decl_48966, type, 'Length-Value': $i).
% 29.22/29.07  tff(decl_48967, type, 'length is a property for describing how big the one-dimensional extent of a Spatial-Entity is': $i).
% 29.22/29.07  tff(decl_48968, type, breadth: $i).
% 29.22/29.07  tff(decl_48969, type, width: $i).
% 29.22/29.07  tff(decl_48970, type, wavelength: $i).
% 29.22/29.07  tff(decl_48971, type, thickness: $i).
% 29.22/29.07  tff(decl_48972, type, r: $i).
% 29.22/29.07  tff(decl_48973, type, radius: $i).
% 29.22/29.07  tff(decl_48974, type, perimeter: $i).
% 29.22/29.07  tff(decl_48975, type, 'resolving power': $i).
% 29.22/29.07  tff(decl_48976, type, resolution: $i).
% 29.22/29.07  tff(decl_48977, type, 'optical resolution': $i).
% 29.22/29.07  tff(decl_48978, type, 'optical-resolution': $i).
% 29.22/29.07  tff(decl_48979, type, tallness: $i).
% 29.22/29.07  tff(decl_48980, type, altitude: $i).
% 29.22/29.07  tff(decl_48981, type, height: $i).
% 29.22/29.07  tff(decl_48982, type, displacement: $i).
% 29.22/29.07  tff(decl_48983, type, distance: $i).
% 29.22/29.07  tff(decl_48984, type, diam: $i).
% 29.22/29.07  tff(decl_48985, type, diameter: $i).
% 29.22/29.07  tff(decl_48986, type, depth: $i).
% 29.22/29.07  tff(decl_48987, type, circumference: $i).
% 29.22/29.07  tff(decl_48988, type, 'total distance': $i).
% 29.22/29.07  tff(decl_48989, type, 'value of length': $i).
% 29.22/29.07  tff(decl_48990, type, 'length value': $i).
% 29.22/29.07  tff(decl_48991, type, 'length-value': $i).
% 29.22/29.07  tff(decl_48992, type, 'Lens': $i).
% 29.22/29.07  tff(decl_48993, type, 'A lens is any object which helps to focus light in a defined area. Biological lenses can be found in the eyes of animals where they focus light on photoreceptors and mechanical lenses can be found in optical devices including microscopes.': $i).
% 29.22/29.07  tff(decl_48994, type, lens: $i).
% 29.22/29.07  tff(decl_48995, type, lenticel_1: $i > $o).
% 29.22/29.07  tff(decl_48996, type, 'Lenticel': $i).
% 29.22/29.07  tff(decl_48997, type, 'In gymnosperms and some angiosperms, a small lens-shaped raised area in the bark of stems and shoots. Lenticels provide sites for gas exchange between living tissues and the air outside the tree.': $i).
% 29.22/29.07  tff(decl_48998, type, lenticel: $i).
% 29.22/29.07  tff(decl_48999, type, 'Lepidoptera': $i).
% 29.22/29.07  tff(decl_49000, type, 'A large order of insects that includes butterflies and moths.': $i).
% 29.22/29.07  tff(decl_49001, type, lepidoptera: $i).
% 29.22/29.07  tff(decl_49002, type, 'Lepidosaur': $i).
% 29.22/29.07  tff(decl_49003, type, 'A member of the group of reptiles whose living members include snakes, lizards, and tuataras.': $i).
% 29.22/29.07  tff(decl_49004, type, lepidosaur: $i).
% 29.22/29.07  tff(decl_49005, type, 'Leptin': $i).
% 29.22/29.07  tff(decl_49006, type, 'A protein hormone produced by adipose cells that plays a role in complex feedback mechanisms that regulate fat storage and use.': $i).
% 29.22/29.07  tff(decl_49007, type, leptin: $i).
% 29.22/29.07  tff(decl_49008, type, fn_leptin_1: $i > $i).
% 29.22/29.07  tff(decl_49009, type, fn_leptin_2: $i > $i).
% 29.22/29.07  tff(decl_49010, type, fn_leptin_3: $i > $i).
% 29.22/29.07  tff(decl_49011, type, fn_leptin_4: $i > $i).
% 29.22/29.07  tff(decl_49012, type, fn_leptin_5: $i > $i).
% 29.22/29.07  tff(decl_49013, type, fn_leptin_6: $i > $i).
% 29.22/29.07  tff(decl_49014, type, fn_leptin_7: $i > $i).
% 29.22/29.07  tff(decl_49015, type, fn_leptin_8: $i > $i).
% 29.22/29.07  tff(decl_49016, type, fn_leptin_9: $i > $i).
% 29.22/29.07  tff(decl_49017, type, fn_leptin_10: $i > $i).
% 29.22/29.07  tff(decl_49018, type, fn_leptin_11: $i > $i).
% 29.22/29.07  tff(decl_49019, type, fn_leptin_12: $i > $i).
% 29.22/29.07  tff(decl_49020, type, fn_leptin_13: $i > $i).
% 29.22/29.07  tff(decl_49021, type, fn_leptin_14: $i > $i).
% 29.22/29.07  tff(decl_49022, type, fn_leptin_15: $i > $i).
% 29.22/29.07  tff(decl_49023, type, fn_leptin_16: $i > $i).
% 29.22/29.07  tff(decl_49024, type, fn_leptin_17: $i > $i).
% 29.22/29.07  tff(decl_49025, type, fn_leptin_18: $i > $i).
% 29.22/29.07  tff(decl_49026, type, 'Let-Fall': $i).
% 29.22/29.07  tff(decl_49027, type, drop: $i).
% 29.22/29.07  tff(decl_49028, type, let: $i).
% 29.22/29.07  tff(decl_49029, type, 'fall of let': $i).
% 29.22/29.07  tff(decl_49030, type, 'let fall': $i).
% 29.22/29.07  tff(decl_49031, type, 'let-fall': $i).
% 29.22/29.07  tff(decl_49032, type, fn_let_fall_2: $i > $i).
% 29.22/29.07  tff(decl_49033, type, let_go_of_1: $i > $o).
% 29.22/29.07  tff(decl_49034, type, 'Let-Go-Of': $i).
% 29.22/29.07  tff(decl_49035, type, 'let go of': $i).
% 29.22/29.07  tff(decl_49036, type, let_go_of: $i).
% 29.22/29.07  tff(decl_49037, type, 'let-go-of': $i).
% 29.22/29.07  tff(decl_49038, type, fn_let_go_of_1: $i > $i).
% 29.22/29.07  tff(decl_49039, type, fn_let_go_of_2: $i > $i).
% 29.22/29.07  tff(decl_49040, type, 'Leucine': $i).
% 29.22/29.07  tff(decl_49041, type, leucine: $i).
% 29.22/29.07  tff(decl_49042, type, 'Leukemia': $i).
% 29.22/29.07  tff(decl_49043, type, 'A cancer of the blood or bone marrow characterized by an abnormal increase of blood cells, usually leukocytes.': $i).
% 29.22/29.07  tff(decl_49044, type, leukemia: $i).
% 29.22/29.07  tff(decl_49045, type, 'Leukocyte': $i).
% 29.22/29.07  tff(decl_49046, type, 'A leukocyte is a type of white blood cell whose primary role is to fight infection and often serves as phagocytes.': $i).
% 29.22/29.07  tff(decl_49047, type, 'white blood cell': $i).
% 29.22/29.07  tff(decl_49048, type, 'white-blood-cell': $i).
% 29.22/29.07  tff(decl_49049, type, wbc: $i).
% 29.22/29.07  tff(decl_49050, type, leukocyte: $i).
% 29.22/29.07  tff(decl_49051, type, lexical_relation_1: $i > $o).
% 29.22/29.07  tff(decl_49052, type, 'Lexical-Relation': $i).
% 29.22/29.07  tff(decl_49053, type, 'lexical relation': $i).
% 29.22/29.07  tff(decl_49054, type, 'lexical-relation': $i).
% 29.22/29.07  tff(decl_49055, type, leydig_cell_1: $i > $o).
% 29.22/29.07  tff(decl_49056, type, 'Leydig-Cell': $i).
% 29.22/29.07  tff(decl_49057, type, 'A type of cell that is adjacent to the seminiferous tubules of the testes; it secretes testosterone in response to luteinizing hormone.': $i).
% 29.22/29.07  tff(decl_49058, type, 'leydig cell': $i).
% 29.22/29.07  tff(decl_49059, type, 'leydig-cell': $i).
% 29.22/29.07  tff(decl_49060, type, 'LH': $i).
% 29.22/29.07  tff(decl_49061, type, 'Luteinizing hormone, a tropic hormone secreted by the anterior pituitary. In females, an LH surge in the first half of the menstrual cycle triggers ovulation and formation of the corpus luteum. In males, LH stimulates the Leydig cells to produce testosterone.': $i).
% 29.22/29.07  tff(decl_49062, type, 'luteinizing hormone': $i).
% 29.22/29.07  tff(decl_49063, type, 'luteinizing-hormone': $i).
% 29.22/29.07  tff(decl_49064, type, lh: $i).
% 29.22/29.07  tff(decl_49065, type, lichen_1: $i > $o).
% 29.22/29.07  tff(decl_49066, type, 'Lichen': $i).
% 29.22/29.07  tff(decl_49067, type, 'A composite organism resulting from the mutualistic association between a fungus and a photosynthetic partner, usually an alga or a cyanobacterium.': $i).
% 29.22/29.07  tff(decl_49068, type, lichen: $i).
% 29.22/29.07  tff(decl_49069, type, soredium_1: $i > $o).
% 29.22/29.07  tff(decl_49070, type, 'Lie': $i).
% 29.22/29.07  tff(decl_49071, type, misinform: $i).
% 29.22/29.07  tff(decl_49072, type, mislead: $i).
% 29.22/29.07  tff(decl_49073, type, fn_lie_1: $i > $i).
% 29.22/29.07  tff(decl_49074, type, fn_lie_3: $i > $i).
% 29.22/29.07  tff(decl_49075, type, 'Life-Cycle': $i).
% 29.22/29.07  tff(decl_49076, type, 'The events that occur in an organism\\s lifetime, from formation of the zygote to death.': $i).
% 29.22/29.07  tff(decl_49077, type, 'cycle of life': $i).
% 29.22/29.07  tff(decl_49078, type, 'life cycle': $i).
% 29.22/29.07  tff(decl_49079, type, 'life-cycle': $i).
% 29.22/29.07  tff(decl_49080, type, fn_life_cycle_1: $i > $i).
% 29.22/29.07  tff(decl_49081, type, 'Life-Cycle-Of-Drosophila': $i).
% 29.22/29.07  tff(decl_49082, type, 'The sequence of stages in the life cycle of Drosophila.': $i).
% 29.22/29.07  tff(decl_49083, type, 'life cycle of fruit fly': $i).
% 29.22/29.07  tff(decl_49084, type, 'life-cycle-of-fruit-fly': $i).
% 29.22/29.07  tff(decl_49085, type, 'undergo the life cycle of drosophila': $i).
% 29.22/29.07  tff(decl_49086, type, 'life cycle of drosophila': $i).
% 29.22/29.07  tff(decl_49087, type, 'life-cycle-of-drosophila': $i).
% 29.22/29.07  tff(decl_49088, type, 'Life-Cycle-Of-Fern': $i).
% 29.22/29.07  tff(decl_49089, type, 'The generation-to-generation sequence of stages in the lifespan of a fern.': $i).
% 29.22/29.07  tff(decl_49090, type, 'undergo the life cycle of fern': $i).
% 29.22/29.07  tff(decl_49091, type, 'life cycle of fern': $i).
% 29.22/29.07  tff(decl_49092, type, 'life-cycle-of-fern': $i).
% 29.22/29.07  tff(decl_49093, type, 'Life-Cycle-Process': $i).
% 29.22/29.07  tff(decl_49094, type, 'A life cycle is a period involving all different generations of a species succeeding each other through means of reproduction, whether through asexual reproduction or sexual reproduction (a period from one generation of organisms to the same identical).': $i).
% 29.22/29.07  tff(decl_49095, type, 'life cycle activity': $i).
% 29.22/29.07  tff(decl_49096, type, 'life activity': $i).
% 29.22/29.07  tff(decl_49097, type, 'biological activity': $i).
% 29.22/29.07  tff(decl_49098, type, 'life cycle process': $i).
% 29.22/29.07  tff(decl_49099, type, 'life-cycle-process': $i).
% 29.22/29.07  tff(decl_49100, type, 'Life-History': $i).
% 29.22/29.07  tff(decl_49101, type, 'The collection of traits that determine the schedule of key events, such as reproduction, in an organism\\s lifetime.': $i).
% 29.22/29.07  tff(decl_49102, type, 'history of life': $i).
% 29.22/29.07  tff(decl_49103, type, 'life history': $i).
% 29.22/29.07  tff(decl_49104, type, 'life-history': $i).
% 29.22/29.07  tff(decl_49105, type, 'Life-Stage': $i).
% 29.22/29.07  tff(decl_49106, type, 'Stages in the life cycle of an organism.': $i).
% 29.22/29.07  tff(decl_49107, type, 'stage of life': $i).
% 29.22/29.07  tff(decl_49108, type, 'life stage': $i).
% 29.22/29.07  tff(decl_49109, type, 'life-stage': $i).
% 29.22/29.07  tff(decl_49110, type, 'Life-Table': $i).
% 29.22/29.07  tff(decl_49111, type, 'A table of data summarizing probability of mortality among different age groups in a population.': $i).
% 29.22/29.07  tff(decl_49112, type, 'table of life': $i).
% 29.22/29.07  tff(decl_49113, type, 'life table': $i).
% 29.22/29.07  tff(decl_49114, type, 'life-table': $i).
% 29.22/29.07  tff(decl_49115, type, ligament_1: $i > $o).
% 29.22/29.07  tff(decl_49116, type, 'Ligament': $i).
% 29.22/29.07  tff(decl_49117, type, 'A fibrous connective tissue that connects bones to other bones at joints.': $i).
% 29.22/29.07  tff(decl_49118, type, ligament: $i).
% 29.22/29.07  tff(decl_49119, type, tendon_1: $i > $o).
% 29.22/29.07  tff(decl_49120, type, fn_ligament_1: $i > $i).
% 29.22/29.07  tff(decl_49121, type, fn_ligament_2: $i > $i).
% 29.22/29.07  tff(decl_49122, type, 'Ligand': $i).
% 29.22/29.07  tff(decl_49123, type, 'A ligand is a molecule that binds to something else, often a receptor to trigger a response': $i).
% 29.22/29.07  tff(decl_49124, type, ligand: $i).
% 29.22/29.07  tff(decl_49125, type, fn_ligand_2: $i > $i).
% 29.22/29.07  tff(decl_49126, type, fn_ligand_binding_1: $i > $i).
% 29.22/29.07  tff(decl_49127, type, 'Ligand-Binding': $i).
% 29.22/29.07  tff(decl_49128, type, 'The attachment of a molecule, the ligand, usually to a larger molecule which causes a receptor protein to undergo a change in shape often activating a cellular response.': $i).
% 29.22/29.07  tff(decl_49129, type, 'binding of ligand': $i).
% 29.22/29.07  tff(decl_49130, type, 'ligand binding': $i).
% 29.22/29.07  tff(decl_49131, type, 'ligand-binding': $i).
% 29.22/29.07  tff(decl_49132, type, ligand_gated_calcium_channel_1: $i > $o).
% 29.22/29.07  tff(decl_49133, type, 'Ligand-Gated-Calcium-Channel': $i).
% 29.22/29.07  tff(decl_49134, type, 'A receptor with a channel specific for Ca2+ ions that allows Ca2+ ions through when the receptor changes shape upon the binding of a signaling molecule.': $i).
% 29.22/29.07  tff(decl_49135, type, 'ligand gated calcium channel': $i).
% 29.22/29.07  tff(decl_49136, type, 'ligand-gated-calcium-channel': $i).
% 29.22/29.07  tff(decl_49137, type, 'Ligand-Gated-Ion-Channel': $i).
% 29.22/29.07  tff(decl_49138, type, 'A transmembrane protein that allows a particular ion to flow into the cell when a specific signal binds to the extracellular end of the protein.': $i).
% 29.22/29.07  tff(decl_49139, type, 'ligand gated ion channel': $i).
% 29.22/29.07  tff(decl_49140, type, 'ligand-gated ion-channel': $i).
% 29.22/29.07  tff(decl_49141, type, 'ligand-gated-ion-channel': $i).
% 29.22/29.07  tff(decl_49142, type, fn_ligand_gated_ion_channel_5: $i > $i).
% 29.22/29.07  tff(decl_49143, type, fn_ligand_gated_ion_channel_6: $i > $i).
% 29.22/29.07  tff(decl_49144, type, fn_ligand_gated_ion_channel_8: $i > $i).
% 29.22/29.07  tff(decl_49145, type, fn_ligand_gated_ion_channel_11: $i > $i).
% 29.22/29.07  tff(decl_49146, type, fn_ligand_gated_ion_channel_12: $i > $i).
% 29.22/29.07  tff(decl_49147, type, fn_ligand_gated_ion_channel_14: $i > $i).
% 29.22/29.07  tff(decl_49148, type, fn_ligand_gated_ion_channel_15: $i > $i).
% 29.22/29.07  tff(decl_49149, type, fn_ligand_gated_ion_channel_2: $i > $i).
% 29.22/29.07  tff(decl_49150, type, fn_ligand_gated_ion_channel_1: $i > $i).
% 29.22/29.07  tff(decl_49151, type, fn_ligand_gated_ion_channel_3: $i > $i).
% 29.22/29.07  tff(decl_49152, type, fn_ligand_gated_ion_channel_4: $i > $i).
% 29.22/29.07  tff(decl_49153, type, 'Ligase': $i).
% 29.22/29.07  tff(decl_49154, type, 'Enzymes which join two molecules with covalent bonds.': $i).
% 29.22/29.07  tff(decl_49155, type, ligase: $i).
% 29.22/29.07  tff(decl_49156, type, fn_ligase_2: $i > $i).
% 29.22/29.07  tff(decl_49157, type, 'Light': $i).
% 29.22/29.07  tff(decl_49158, type, 'Electromagnetic energy vibrations in the visible frequency range that propagate through a region.': $i).
% 29.22/29.07  tff(decl_49159, type, 'Light is a form of energy.': $i).
% 29.22/29.07  tff(decl_49160, type, 'visible light': $i).
% 29.22/29.07  tff(decl_49161, type, visible_light: $i).
% 29.22/29.07  tff(decl_49162, type, 'visible radiation': $i).
% 29.22/29.07  tff(decl_49163, type, visible_radiation: $i).
% 29.22/29.07  tff(decl_49164, type, 'light energy': $i).
% 29.22/29.07  tff(decl_49165, type, photo: $i).
% 29.22/29.07  tff(decl_49166, type, fn_photon_1: $i > $i).
% 29.22/29.07  tff(decl_49167, type, light_absorption_by_chlorophyll_followed_by_fluorescence_1: $i > $o).
% 29.22/29.07  tff(decl_49168, type, 'Light-Absorption-By-Chlorophyll-Followed-By-Fluorescence': $i).
% 29.22/29.07  tff(decl_49169, type, 'The trapping of light energy is the key to photosynthesis. The first event is the absorption of light by a photoreceptor molecule. The principal photoreceptor in the chloroplasts of most green plants is chlorophyll a, a substituted tetrapyrrole. The four nitrogen atoms of the pyrroles are coordinated to a magnesium ion. Unlike a porphyrin such as heme, chlorophyll has a reduced pyrrole ring. Another distinctive feature of chlorophyll is the presence of phytol, a highly hydrophobic 20-carbon alcohol, esterified to an acid side chain.': $i).
% 29.22/29.07  tff(decl_49170, type, 'light absorption by chlorophyll followed by fluorescence': $i).
% 29.22/29.07  tff(decl_49171, type, 'light-absorption-by-chlorophyll-followed-by-fluorescence': $i).
% 29.22/29.07  tff(decl_49172, type, phosphorescence_1: $i > $o).
% 29.22/29.07  tff(decl_49173, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_1: $i > $i).
% 29.22/29.07  tff(decl_49174, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_2: $i > $i).
% 29.22/29.07  tff(decl_49175, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_3: $i > $i).
% 29.22/29.07  tff(decl_49176, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_5: $i > $i).
% 29.22/29.07  tff(decl_49177, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_7: $i > $i).
% 29.22/29.07  tff(decl_49178, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_8: $i > $i).
% 29.22/29.07  tff(decl_49179, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_11: $i > $i).
% 29.22/29.07  tff(decl_49180, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_12: $i > $i).
% 29.22/29.07  tff(decl_49181, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_13: $i > $i).
% 29.22/29.07  tff(decl_49182, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_14: $i > $i).
% 29.22/29.07  tff(decl_49183, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_16: $i > $i).
% 29.22/29.07  tff(decl_49184, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_17: $i > $i).
% 29.22/29.07  tff(decl_49185, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_18: $i > $i).
% 29.22/29.07  tff(decl_49186, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_20: $i > $i).
% 29.22/29.07  tff(decl_49187, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_21: $i > $i).
% 29.22/29.07  tff(decl_49188, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_22: $i > $i).
% 29.22/29.07  tff(decl_49189, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_23: $i > $i).
% 29.22/29.07  tff(decl_49190, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_24: $i > $i).
% 29.22/29.07  tff(decl_49191, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_25: $i > $i).
% 29.22/29.07  tff(decl_49192, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_26: $i > $i).
% 29.22/29.07  tff(decl_49193, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_27: $i > $i).
% 29.22/29.07  tff(decl_49194, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_28: $i > $i).
% 29.22/29.07  tff(decl_49195, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_29: $i > $i).
% 29.22/29.07  tff(decl_49196, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_30: $i > $i).
% 29.22/29.07  tff(decl_49197, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_31: $i > $i).
% 29.22/29.07  tff(decl_49198, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_32: $i > $i).
% 29.22/29.07  tff(decl_49199, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_33: $i > $i).
% 29.22/29.07  tff(decl_49200, type, fn_phosphorescence_7: $i > $i).
% 29.22/29.07  tff(decl_49201, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_19: $i > $i).
% 29.22/29.07  tff(decl_49202, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_15: $i > $i).
% 29.22/29.07  tff(decl_49203, type, fn_phosphorescence_6: $i > $i).
% 29.22/29.07  tff(decl_49204, type, fn_phosphorescence_4: $i > $i).
% 29.22/29.07  tff(decl_49205, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_9: $i > $i).
% 29.22/29.07  tff(decl_49206, type, fn_light_absorption_by_chlorophyll_followed_by_fluorescence_10: $i > $i).
% 29.22/29.07  tff(decl_49207, type, 'Light-Chain': $i).
% 29.22/29.07  tff(decl_49208, type, 'The shorter of the two types of polypeptide chains making up an antibody molecule. It consists of a constant region, which confers lysis and phagocytosis of microbes, and a variable region, which binds to specific antigens.': $i).
% 29.22/29.07  tff(decl_49209, type, 'chain of light': $i).
% 29.22/29.07  tff(decl_49210, type, 'light chain': $i).
% 29.22/29.07  tff(decl_49211, type, 'light-chain': $i).
% 29.22/29.07  tff(decl_49212, type, 'Light-Harvesting-Complex': $i).
% 29.22/29.07  tff(decl_49213, type, 'Light-Harvesting-Complexes have parts including electron transport assemblies, antenna pigments, and accessory pigments.': $i).
% 29.22/29.07  tff(decl_49214, type, 'light harvesting complex': $i).
% 29.22/29.07  tff(decl_49215, type, 'light-harvesting complex': $i).
% 29.22/29.07  tff(decl_49216, type, 'light-harvesting-complex': $i).
% 29.22/29.07  tff(decl_49217, type, fn_light_harvesting_complex_1: $i > $i).
% 29.22/29.07  tff(decl_49218, type, fn_light_harvesting_complex_2: $i > $i).
% 29.22/29.07  tff(decl_49219, type, fn_light_harvesting_complex_3: $i > $i).
% 29.22/29.07  tff(decl_49220, type, fn_light_harvesting_complex_6: $i > $i).
% 29.22/29.07  tff(decl_49221, type, fn_light_harvesting_complex_7: $i > $i).
% 29.22/29.07  tff(decl_49222, type, fn_light_harvesting_complex_8: $i > $i).
% 29.22/29.07  tff(decl_49223, type, fn_light_harvesting_complex_9: $i > $i).
% 29.22/29.07  tff(decl_49224, type, fn_light_harvesting_complex_10: $i > $i).
% 29.22/29.07  tff(decl_49225, type, fn_light_harvesting_complex_11: $i > $i).
% 29.22/29.07  tff(decl_49226, type, fn_light_harvesting_complex_12: $i > $i).
% 29.22/29.07  tff(decl_49227, type, fn_light_harvesting_complex_21: $i > $i).
% 29.22/29.07  tff(decl_49228, type, fn_methyl_group_14: $i > $i).
% 29.22/29.07  tff(decl_49229, type, fn_methyl_group_10: $i > $i).
% 29.22/29.07  tff(decl_49230, type, 'Light-Microscope': $i).
% 29.22/29.07  tff(decl_49231, type, 'A light microscope is a tool for observation which passes light through a specimen and then through a set of lenses to produce an image.': $i).
% 29.22/29.07  tff(decl_49232, type, 'optical microscope': $i).
% 29.22/29.07  tff(decl_49233, type, 'optical-microscope': $i).
% 29.22/29.07  tff(decl_49234, type, 'microscope of light': $i).
% 29.22/29.07  tff(decl_49235, type, 'light microscope': $i).
% 29.22/29.07  tff(decl_49236, type, 'light-microscope': $i).
% 29.22/29.07  tff(decl_49237, type, fn_light_microscope_1: $i > $i).
% 29.22/29.07  tff(decl_49238, type, fn_light_microscope_2: $i > $i).
% 29.22/29.07  tff(decl_49239, type, "0.2e0": $i).
% 29.22/29.07  tff(decl_49240, type, glass_lens_0: $i).
% 29.22/29.07  tff(decl_49241, type, 'Light-Microscopy': $i).
% 29.22/29.07  tff(decl_49242, type, 'Visible light is passed through a specimen and then through glass lenses of the microscope magnifying the specimen up to 1000 times the actual size.': $i).
% 29.22/29.07  tff(decl_49243, type, 'optical microscopy': $i).
% 29.22/29.07  tff(decl_49244, type, 'optical-microscopy': $i).
% 29.22/29.07  tff(decl_49245, type, 'microscopy of light': $i).
% 29.22/29.07  tff(decl_49246, type, 'light microscopy': $i).
% 29.22/29.07  tff(decl_49247, type, 'light-microscopy': $i).
% 29.22/29.07  tff(decl_49248, type, fn_light_microscopy_1: $i > $i).
% 29.22/29.07  tff(decl_49249, type, fn_light_microscopy_2: $i > $i).
% 29.22/29.07  tff(decl_49250, type, fn_light_microscopy_3: $i > $i).
% 29.22/29.07  tff(decl_49251, type, fn_light_microscopy_5: $i > $i).
% 29.22/29.07  tff(decl_49252, type, fn_light_microscopy_6: $i > $i).
% 29.22/29.07  tff(decl_49253, type, fn_light_microscopy_7: $i > $i).
% 29.22/29.07  tff(decl_49254, type, fn_light_microscopy_8: $i > $i).
% 29.22/29.07  tff(decl_49255, type, fn_light_microscopy_9: $i > $i).
% 29.22/29.07  tff(decl_49256, type, fn_light_microscopy_10: $i > $i).
% 29.22/29.07  tff(decl_49257, type, fn_light_microscopy_11: $i > $i).
% 29.22/29.07  tff(decl_49258, type, fn_light_microscopy_12: $i > $i).
% 29.22/29.07  tff(decl_49259, type, fn_light_microscopy_13: $i > $i).
% 29.22/29.07  tff(decl_49260, type, fn_light_microscopy_14: $i > $i).
% 29.22/29.07  tff(decl_49261, type, fn_see_1: $i > $i).
% 29.22/29.07  tff(decl_49262, type, 'Light-Reaction': $i).
% 29.22/29.07  tff(decl_49263, type, 'The first major stage of photosynthesis, in which photons of light are used to split water molecules, producing oxygen as a byproduct. Light energy is converted to chemical energy and stored in ATP and NADPH.': $i).
% 29.22/29.07  tff(decl_49264, type, 'photo part of photosynthesis': $i).
% 29.22/29.07  tff(decl_49265, type, photophosphorylation: $i).
% 29.22/29.07  tff(decl_49266, type, 'reaction of light': $i).
% 29.22/29.07  tff(decl_49267, type, 'light reaction': $i).
% 29.22/29.07  tff(decl_49268, type, 'light-reaction': $i).
% 29.22/29.07  tff(decl_49269, type, fn_light_reaction_2: $i > $i).
% 29.22/29.07  tff(decl_49270, type, fn_light_reaction_11: $i > $i).
% 29.22/29.07  tff(decl_49271, type, fn_light_reaction_14: $i > $i).
% 29.22/29.07  tff(decl_49272, type, fn_light_reaction_15: $i > $i).
% 29.22/29.07  tff(decl_49273, type, fn_light_reaction_16: $i > $i).
% 29.22/29.07  tff(decl_49274, type, fn_light_reaction_17: $i > $i).
% 29.22/29.07  tff(decl_49275, type, fn_light_reaction_18: $i > $i).
% 29.22/29.07  tff(decl_49276, type, fn_light_reaction_20: $i > $i).
% 29.22/29.07  tff(decl_49277, type, fn_light_reaction_21: $i > $i).
% 29.22/29.07  tff(decl_49278, type, fn_light_reaction_22: $i > $i).
% 29.22/29.07  tff(decl_49279, type, fn_light_reaction_23: $i > $i).
% 29.22/29.07  tff(decl_49280, type, fn_light_reaction_24: $i > $i).
% 29.22/29.07  tff(decl_49281, type, fn_light_reaction_25: $i > $i).
% 29.22/29.07  tff(decl_49282, type, fn_light_reaction_26: $i > $i).
% 29.22/29.07  tff(decl_49283, type, fn_light_reaction_27: $i > $i).
% 29.22/29.07  tff(decl_49284, type, fn_light_reaction_28: $i > $i).
% 29.22/29.07  tff(decl_49285, type, fn_light_reaction_30: $i > $i).
% 29.22/29.07  tff(decl_49286, type, fn_light_reaction_32: $i > $i).
% 29.22/29.07  tff(decl_49287, type, fn_light_reaction_34: $i > $i).
% 29.22/29.07  tff(decl_49288, type, fn_light_reaction_35: $i > $i).
% 29.22/29.07  tff(decl_49289, type, fn_light_reaction_37: $i > $i).
% 29.22/29.07  tff(decl_49290, type, fn_light_reaction_38: $i > $i).
% 29.22/29.07  tff(decl_49291, type, fn_light_reaction_39: $i > $i).
% 29.22/29.07  tff(decl_49292, type, fn_light_reaction_40: $i > $i).
% 29.22/29.07  tff(decl_49293, type, fn_light_reaction_41: $i > $i).
% 29.22/29.07  tff(decl_49294, type, fn_light_reaction_42: $i > $i).
% 29.22/29.07  tff(decl_49295, type, fn_light_reaction_43: $i > $i).
% 29.22/29.07  tff(decl_49296, type, fn_light_reaction_44: $i > $i).
% 29.22/29.07  tff(decl_49297, type, fn_light_reaction_46: $i > $i).
% 29.22/29.07  tff(decl_49298, type, fn_light_reaction_55: $i > $i).
% 29.22/29.07  tff(decl_49299, type, fn_light_reaction_56: $i > $i).
% 29.22/29.07  tff(decl_49300, type, fn_light_reaction_60: $i > $i).
% 29.22/29.07  tff(decl_49301, type, fn_light_reaction_61: $i > $i).
% 29.22/29.07  tff(decl_49302, type, fn_proton_pump_29: $i > $i).
% 29.22/29.07  tff(decl_49303, type, fn_proton_pump_18: $i > $i).
% 29.22/29.07  tff(decl_49304, type, fn_proton_pump_56: $i > $i).
% 29.22/29.07  tff(decl_49305, type, fn_proton_pump_26: $i > $i).
% 29.22/29.07  tff(decl_49306, type, fn_proton_pump_43: $i > $i).
% 29.22/29.07  tff(decl_49307, type, fn_light_reaction_6: $i > $i).
% 29.22/29.07  tff(decl_49308, type, fn_light_reaction_5: $i > $i).
% 29.22/29.07  tff(decl_49309, type, fn_light_reaction_10: $i > $i).
% 29.22/29.07  tff(decl_49310, type, fn_light_reaction_9: $i > $i).
% 29.22/29.07  tff(decl_49311, type, fn_light_reaction_8: $i > $i).
% 29.22/29.07  tff(decl_49312, type, fn_light_reaction_7: $i > $i).
% 29.22/29.07  tff(decl_49313, type, 'Light-Reflection': $i).
% 29.22/29.07  tff(decl_49314, type, 'Reflection is defined as the bouncing back of a ray of light into the same medium, when it strikes a surface.': $i).
% 29.22/29.07  tff(decl_49315, type, reflect: $i).
% 29.22/29.07  tff(decl_49316, type, 'reflection of light': $i).
% 29.22/29.07  tff(decl_49317, type, 'light reflection': $i).
% 29.22/29.07  tff(decl_49318, type, 'light-reflection': $i).
% 29.22/29.07  tff(decl_49319, type, fn_light_reflection_2: $i > $i).
% 29.22/29.07  tff(decl_49320, type, 'Light-Transmission': $i).
% 29.22/29.07  tff(decl_49321, type, 'Light transmission is the percentage of incident light that passes through a film.': $i).
% 29.22/29.07  tff(decl_49322, type, transmittance: $i).
% 29.22/29.07  tff(decl_49323, type, 'transmission of light': $i).
% 29.22/29.07  tff(decl_49324, type, 'light transmission': $i).
% 29.22/29.07  tff(decl_49325, type, 'light-transmission': $i).
% 29.22/29.07  tff(decl_49326, type, fn_light_transmission_1: $i > $i).
% 29.22/29.07  tff(decl_49327, type, fn_light_transmission_2: $i > $i).
% 29.22/29.07  tff(decl_49328, type, lightning_1: $i > $o).
% 29.22/29.07  tff(decl_49329, type, 'Lightning': $i).
% 29.22/29.07  tff(decl_49330, type, 'A massive electrostatic discharge resulting from an imbalance of electrical charges in the atmosphere.': $i).
% 29.22/29.07  tff(decl_49331, type, lightning: $i).
% 29.22/29.07  tff(decl_49332, type, lignin_1: $i > $o).
% 29.22/29.07  tff(decl_49333, type, 'Lignin': $i).
% 29.22/29.07  tff(decl_49334, type, 'A complex chemical compound embedded within the cellulose matrix of plant cell walls. Lignin is a hard substance that provides structural support for terrestrial plants.': $i).
% 29.22/29.07  tff(decl_49335, type, lignin: $i).
% 29.22/29.07  tff(decl_49336, type, uric_acid_1: $i > $o).
% 29.22/29.07  tff(decl_49337, type, 'Limb': $i).
% 29.22/29.07  tff(decl_49338, type, 'In animals, a jointed or prehensile appendage used for locomotion, grasping, or carrying. In plants, a large or major branch of a tree.': $i).
% 29.22/29.07  tff(decl_49339, type, limb: $i).
% 29.22/29.07  tff(decl_49340, type, 'Limb-Development': $i).
% 29.22/29.07  tff(decl_49341, type, 'The processes which direct the formation of the limbs during the embryonic development of an animal.': $i).
% 29.22/29.07  tff(decl_49342, type, 'development of limb': $i).
% 29.22/29.07  tff(decl_49343, type, 'limb development': $i).
% 29.22/29.07  tff(decl_49344, type, 'limb-development': $i).
% 29.22/29.07  tff(decl_49345, type, fn_limb_development_2: $i > $i).
% 29.22/29.07  tff(decl_49346, type, fn_limb_development_12: $i > $i).
% 29.22/29.07  tff(decl_49347, type, fn_limb_development_15: $i > $i).
% 29.22/29.07  tff(decl_49348, type, fn_limb_development_18: $i > $i).
% 29.22/29.07  tff(decl_49349, type, fn_limb_development_19: $i > $i).
% 29.22/29.07  tff(decl_49350, type, fn_limb_development_20: $i > $i).
% 29.22/29.07  tff(decl_49351, type, fn_limb_development_21: $i > $i).
% 29.22/29.07  tff(decl_49352, type, fn_limb_development_22: $i > $i).
% 29.22/29.07  tff(decl_49353, type, digit_0: $i).
% 29.22/29.07  tff(decl_49354, type, 'Limiting-Nutrient': $i).
% 29.22/29.07  tff(decl_49355, type, 'The nutrient that is in most short supply compared to other nutrients. Addition of the limiting nutrient will increase productivity in an ecosystem.': $i).
% 29.22/29.07  tff(decl_49356, type, 'nutrient of limiting': $i).
% 29.22/29.07  tff(decl_49357, type, 'limiting nutrient': $i).
% 29.22/29.07  tff(decl_49358, type, 'limiting-nutrient': $i).
% 29.22/29.07  tff(decl_49359, type, macronutrient_1: $i > $o).
% 29.22/29.07  tff(decl_49360, type, micronutrient_1: $i > $o).
% 29.22/29.07  tff(decl_49361, type, 'Limnetic-Zone': $i).
% 29.22/29.07  tff(decl_49362, type, 'The well-lit surface waters of a lake far from shore.': $i).
% 29.22/29.07  tff(decl_49363, type, 'limnetic zone': $i).
% 29.22/29.07  tff(decl_49364, type, 'limnetic-zone': $i).
% 29.22/29.07  tff(decl_49365, type, 'Linear-Electron-Flow': $i).
% 29.22/29.07  tff(decl_49366, type, 'A route of electron flow during the light reactions of photosynthesis that involves both photosystems (I and II) and produces ATP, NADPH, and O2. The net electron flow is from H2O to NADP+.': $i).
% 29.22/29.07  tff(decl_49367, type, 'linear electron flow': $i).
% 29.22/29.07  tff(decl_49368, type, 'linear-electron-flow': $i).
% 29.22/29.07  tff(decl_49369, type, fn_linear_electron_flow_1: $i > $i).
% 29.22/29.07  tff(decl_49370, type, fn_linear_electron_flow_2: $i > $i).
% 29.22/29.07  tff(decl_49371, type, fn_linear_electron_flow_6: $i > $i).
% 29.22/29.07  tff(decl_49372, type, fn_linear_electron_flow_7: $i > $i).
% 29.22/29.07  tff(decl_49373, type, fn_linear_electron_flow_10: $i > $i).
% 29.22/29.07  tff(decl_49374, type, fn_linear_electron_flow_11: $i > $i).
% 29.22/29.07  tff(decl_49375, type, fn_linear_electron_flow_12: $i > $i).
% 29.22/29.07  tff(decl_49376, type, fn_linear_electron_flow_18: $i > $i).
% 29.22/29.07  tff(decl_49377, type, fn_linear_electron_flow_19: $i > $i).
% 29.22/29.07  tff(decl_49378, type, fn_linear_electron_flow_20: $i > $i).
% 29.22/29.07  tff(decl_49379, type, fn_linear_electron_flow_21: $i > $i).
% 29.22/29.07  tff(decl_49380, type, fn_linear_electron_flow_22: $i > $i).
% 29.22/29.07  tff(decl_49381, type, fn_linear_electron_flow_23: $i > $i).
% 29.22/29.07  tff(decl_49382, type, fn_linear_electron_flow_24: $i > $i).
% 29.22/29.07  tff(decl_49383, type, fn_linear_electron_flow_25: $i > $i).
% 29.22/29.07  tff(decl_49384, type, fn_linear_electron_flow_26: $i > $i).
% 29.22/29.07  tff(decl_49385, type, fn_linear_electron_flow_27: $i > $i).
% 29.22/29.07  tff(decl_49386, type, fn_linear_electron_flow_28: $i > $i).
% 29.22/29.07  tff(decl_49387, type, fn_linear_electron_flow_29: $i > $i).
% 29.22/29.07  tff(decl_49388, type, fn_linear_electron_flow_30: $i > $i).
% 29.22/29.07  tff(decl_49389, type, fn_linear_electron_flow_35: $i > $i).
% 29.22/29.07  tff(decl_49390, type, fn_linear_electron_flow_36: $i > $i).
% 29.22/29.07  tff(decl_49391, type, fn_linear_electron_flow_37: $i > $i).
% 29.22/29.07  tff(decl_49392, type, fn_linear_electron_flow_38: $i > $i).
% 29.22/29.07  tff(decl_49393, type, fn_linear_electron_flow_39: $i > $i).
% 29.22/29.07  tff(decl_49394, type, fn_linear_electron_flow_40: $i > $i).
% 29.22/29.07  tff(decl_49395, type, fn_linear_electron_flow_42: $i > $i).
% 29.22/29.07  tff(decl_49396, type, fn_linear_electron_flow_43: $i > $i).
% 29.22/29.07  tff(decl_49397, type, fn_linear_electron_flow_44: $i > $i).
% 29.22/29.07  tff(decl_49398, type, fn_linear_electron_flow_45: $i > $i).
% 29.22/29.07  tff(decl_49399, type, fn_linear_electron_flow_46: $i > $i).
% 29.22/29.07  tff(decl_49400, type, fn_linear_electron_flow_47: $i > $i).
% 29.22/29.07  tff(decl_49401, type, fn_linear_electron_flow_51: $i > $i).
% 29.22/29.07  tff(decl_49402, type, fn_linear_electron_flow_52: $i > $i).
% 29.22/29.07  tff(decl_49403, type, fn_linear_electron_flow_53: $i > $i).
% 29.22/29.07  tff(decl_49404, type, fn_linear_electron_flow_54: $i > $i).
% 29.22/29.07  tff(decl_49405, type, fn_linear_electron_flow_59: $i > $i).
% 29.22/29.07  tff(decl_49406, type, fn_linear_electron_flow_60: $i > $i).
% 29.22/29.07  tff(decl_49407, type, fn_linear_electron_flow_62: $i > $i).
% 29.22/29.07  tff(decl_49408, type, fn_linear_electron_flow_63: $i > $i).
% 29.22/29.07  tff(decl_49409, type, fn_linear_electron_flow_64: $i > $i).
% 29.22/29.07  tff(decl_49410, type, fn_linear_electron_flow_65: $i > $i).
% 29.22/29.07  tff(decl_49411, type, fn_linear_electron_flow_66: $i > $i).
% 29.22/29.07  tff(decl_49412, type, fn_linear_electron_flow_67: $i > $i).
% 29.22/29.07  tff(decl_49413, type, fn_linear_electron_flow_68: $i > $i).
% 29.22/29.07  tff(decl_49414, type, fn_linear_electron_flow_69: $i > $i).
% 29.22/29.07  tff(decl_49415, type, fn_linear_electron_flow_70: $i > $i).
% 29.22/29.07  tff(decl_49416, type, fn_linear_electron_flow_73: $i > $i).
% 29.22/29.07  tff(decl_49417, type, p680_1: $i > $o).
% 29.22/29.07  tff(decl_49418, type, fn_linear_electron_flow_74: $i > $i).
% 29.22/29.07  tff(decl_49419, type, fn_linear_electron_flow_75: $i > $i).
% 29.22/29.07  tff(decl_49420, type, fn_linear_electron_flow_76: $i > $i).
% 29.22/29.07  tff(decl_49421, type, fn_linear_electron_flow_77: $i > $i).
% 29.22/29.07  tff(decl_49422, type, fn_linear_electron_flow_78: $i > $i).
% 29.22/29.07  tff(decl_49423, type, fn_linear_electron_flow_79: $i > $i).
% 29.22/29.07  tff(decl_49424, type, fn_linear_electron_flow_80: $i > $i).
% 29.22/29.07  tff(decl_49425, type, fn_linear_electron_flow_81: $i > $i).
% 29.22/29.07  tff(decl_49426, type, fn_linear_electron_flow_82: $i > $i).
% 29.22/29.07  tff(decl_49427, type, fn_linear_electron_flow_83: $i > $i).
% 29.22/29.07  tff(decl_49428, type, fn_linear_electron_flow_88: $i > $i).
% 29.22/29.07  tff(decl_49429, type, fn_linear_electron_flow_89: $i > $i).
% 29.22/29.07  tff(decl_49430, type, fn_linear_electron_flow_90: $i > $i).
% 29.22/29.07  tff(decl_49431, type, fn_linear_electron_flow_91: $i > $i).
% 29.22/29.07  tff(decl_49432, type, fn_linear_electron_flow_92: $i > $i).
% 29.22/29.07  tff(decl_49433, type, fn_linear_electron_flow_93: $i > $i).
% 29.22/29.07  tff(decl_49434, type, fn_linear_electron_flow_94: $i > $i).
% 29.22/29.07  tff(decl_49435, type, fn_linear_electron_flow_95: $i > $i).
% 29.22/29.07  tff(decl_49436, type, fn_linear_electron_flow_96: $i > $i).
% 29.22/29.07  tff(decl_49437, type, fn_linear_electron_flow_97: $i > $i).
% 29.22/29.07  tff(decl_49438, type, fn_linear_electron_flow_98: $i > $i).
% 29.22/29.07  tff(decl_49439, type, fn_linear_electron_flow_100: $i > $i).
% 29.22/29.07  tff(decl_49440, type, nadp_plus_reductase_1: $i > $o).
% 29.22/29.07  tff(decl_49441, type, fn_linear_electron_flow_101: $i > $i).
% 29.22/29.07  tff(decl_49442, type, fn_linear_electron_flow_102: $i > $i).
% 29.22/29.07  tff(decl_49443, type, fn_linear_electron_flow_103: $i > $i).
% 29.22/29.07  tff(decl_49444, type, fn_linear_electron_flow_104: $i > $i).
% 29.22/29.07  tff(decl_49445, type, fn_linear_electron_flow_105: $i > $i).
% 29.22/29.07  tff(decl_49446, type, fn_linear_electron_flow_106: $i > $i).
% 29.22/29.07  tff(decl_49447, type, fn_linear_electron_flow_109: $i > $i).
% 29.22/29.07  tff(decl_49448, type, fn_linear_electron_flow_110: $i > $i).
% 29.22/29.07  tff(decl_49449, type, fn_linear_electron_flow_111: $i > $i).
% 29.22/29.07  tff(decl_49450, type, fn_linear_electron_flow_112: $i > $i).
% 29.22/29.07  tff(decl_49451, type, fn_linear_electron_flow_113: $i > $i).
% 29.22/29.07  tff(decl_49452, type, fn_linear_electron_flow_114: $i > $i).
% 29.22/29.07  tff(decl_49453, type, fn_linear_electron_flow_115: $i > $i).
% 29.22/29.07  tff(decl_49454, type, fn_linear_electron_flow_116: $i > $i).
% 29.22/29.07  tff(decl_49455, type, fn_linear_electron_flow_117: $i > $i).
% 29.22/29.07  tff(decl_49456, type, fn_linear_electron_flow_118: $i > $i).
% 29.22/29.07  tff(decl_49457, type, fn_linear_electron_flow_120: $i > $i).
% 29.22/29.07  tff(decl_49458, type, fn_linear_electron_flow_121: $i > $i).
% 29.22/29.07  tff(decl_49459, type, fn_linear_electron_flow_122: $i > $i).
% 29.22/29.07  tff(decl_49460, type, fn_linear_electron_flow_123: $i > $i).
% 29.22/29.07  tff(decl_49461, type, fn_linear_electron_flow_124: $i > $i).
% 29.22/29.07  tff(decl_49462, type, fn_linear_electron_flow_125: $i > $i).
% 29.22/29.07  tff(decl_49463, type, fn_linear_electron_flow_126: $i > $i).
% 29.22/29.07  tff(decl_49464, type, fn_linear_electron_flow_127: $i > $i).
% 29.22/29.07  tff(decl_49465, type, fn_linear_electron_flow_128: $i > $i).
% 29.22/29.07  tff(decl_49466, type, fn_linear_electron_flow_129: $i > $i).
% 29.22/29.07  tff(decl_49467, type, fn_linear_electron_flow_130: $i > $i).
% 29.22/29.07  tff(decl_49468, type, fn_linear_electron_flow_131: $i > $i).
% 29.22/29.07  tff(decl_49469, type, fn_linear_electron_flow_132: $i > $i).
% 29.22/29.07  tff(decl_49470, type, fn_linear_electron_flow_135: $i > $i).
% 29.22/29.07  tff(decl_49471, type, fn_linear_electron_flow_136: $i > $i).
% 29.22/29.07  tff(decl_49472, type, fn_linear_electron_flow_137: $i > $i).
% 29.22/29.07  tff(decl_49473, type, fn_linear_electron_flow_138: $i > $i).
% 29.22/29.07  tff(decl_49474, type, fn_linear_electron_flow_139: $i > $i).
% 29.22/29.07  tff(decl_49475, type, fn_linear_electron_flow_140: $i > $i).
% 29.22/29.07  tff(decl_49476, type, fn_linear_electron_flow_141: $i > $i).
% 29.22/29.07  tff(decl_49477, type, fn_linear_electron_flow_142: $i > $i).
% 29.22/29.07  tff(decl_49478, type, fn_linear_electron_flow_143: $i > $i).
% 29.22/29.07  tff(decl_49479, type, fn_linear_electron_flow_146: $i > $i).
% 29.22/29.07  tff(decl_49480, type, fn_linear_electron_flow_147: $i > $i).
% 29.22/29.07  tff(decl_49481, type, plastoquinone_1: $i > $o).
% 29.22/29.07  tff(decl_49482, type, fn_linear_electron_flow_148: $i > $i).
% 29.22/29.07  tff(decl_49483, type, fn_linear_electron_flow_149: $i > $i).
% 29.22/29.07  tff(decl_49484, type, fn_linear_electron_flow_150: $i > $i).
% 29.22/29.07  tff(decl_49485, type, fn_linear_electron_flow_151: $i > $i).
% 29.22/29.07  tff(decl_49486, type, fn_linear_electron_flow_152: $i > $i).
% 29.22/29.07  tff(decl_49487, type, fn_linear_electron_flow_153: $i > $i).
% 29.22/29.07  tff(decl_49488, type, fn_linear_electron_flow_154: $i > $i).
% 29.22/29.07  tff(decl_49489, type, fn_linear_electron_flow_155: $i > $i).
% 29.22/29.07  tff(decl_49490, type, fn_linear_electron_flow_157: $i > $i).
% 29.22/29.07  tff(decl_49491, type, fn_linear_electron_flow_158: $i > $i).
% 29.22/29.07  tff(decl_49492, type, fn_linear_electron_flow_159: $i > $i).
% 29.22/29.07  tff(decl_49493, type, fn_linear_electron_flow_160: $i > $i).
% 29.22/29.07  tff(decl_49494, type, fn_linear_electron_flow_161: $i > $i).
% 29.22/29.07  tff(decl_49495, type, fn_linear_electron_flow_162: $i > $i).
% 29.22/29.07  tff(decl_49496, type, fn_linear_electron_flow_163: $i > $i).
% 29.22/29.07  tff(decl_49497, type, fn_linear_electron_flow_164: $i > $i).
% 29.22/29.07  tff(decl_49498, type, fn_linear_electron_flow_165: $i > $i).
% 29.22/29.07  tff(decl_49499, type, fn_linear_electron_flow_166: $i > $i).
% 29.22/29.07  tff(decl_49500, type, fn_linear_electron_flow_167: $i > $i).
% 29.22/29.07  tff(decl_49501, type, fn_linear_electron_flow_172: $i > $i).
% 29.22/29.07  tff(decl_49502, type, fn_linear_electron_flow_173: $i > $i).
% 29.22/29.07  tff(decl_49503, type, fn_linear_electron_flow_174: $i > $i).
% 29.22/29.07  tff(decl_49504, type, fn_linear_electron_flow_175: $i > $i).
% 29.22/29.07  tff(decl_49505, type, fn_linear_electron_flow_176: $i > $i).
% 29.22/29.07  tff(decl_49506, type, fn_linear_electron_flow_177: $i > $i).
% 29.22/29.07  tff(decl_49507, type, fn_linear_electron_flow_178: $i > $i).
% 29.22/29.07  tff(decl_49508, type, fn_linear_electron_flow_179: $i > $i).
% 29.22/29.07  tff(decl_49509, type, fn_linear_electron_flow_180: $i > $i).
% 29.22/29.07  tff(decl_49510, type, fn_linear_electron_flow_181: $i > $i).
% 29.22/29.07  tff(decl_49511, type, fn_linear_electron_flow_182: $i > $i).
% 29.22/29.07  tff(decl_49512, type, fn_linear_electron_flow_183: $i > $i).
% 29.22/29.07  tff(decl_49513, type, fn_linear_electron_flow_184: $i > $i).
% 29.22/29.07  tff(decl_49514, type, fn_linear_electron_flow_185: $i > $i).
% 29.22/29.07  tff(decl_49515, type, fn_linear_electron_flow_186: $i > $i).
% 29.22/29.07  tff(decl_49516, type, fn_linear_electron_flow_187: $i > $i).
% 29.22/29.07  tff(decl_49517, type, fn_linear_electron_flow_188: $i > $i).
% 29.22/29.07  tff(decl_49518, type, fn_linear_electron_flow_189: $i > $i).
% 29.22/29.07  tff(decl_49519, type, fn_linear_electron_flow_191: $i > $i).
% 29.22/29.07  tff(decl_49520, type, fn_linear_electron_flow_192: $i > $i).
% 29.22/29.07  tff(decl_49521, type, fn_linear_electron_flow_193: $i > $i).
% 29.22/29.07  tff(decl_49522, type, fn_linear_electron_flow_194: $i > $i).
% 29.22/29.07  tff(decl_49523, type, fn_linear_electron_flow_195: $i > $i).
% 29.22/29.07  tff(decl_49524, type, fn_linear_electron_flow_196: $i > $i).
% 29.22/29.07  tff(decl_49525, type, fn_linear_electron_flow_197: $i > $i).
% 29.22/29.07  tff(decl_49526, type, fn_linear_electron_flow_198: $i > $i).
% 29.22/29.07  tff(decl_49527, type, fn_linear_electron_flow_199: $i > $i).
% 29.22/29.07  tff(decl_49528, type, fn_linear_electron_flow_200: $i > $i).
% 29.22/29.07  tff(decl_49529, type, fn_linear_electron_flow_201: $i > $i).
% 29.22/29.07  tff(decl_49530, type, fn_linear_electron_flow_202: $i > $i).
% 29.22/29.07  tff(decl_49531, type, fn_linear_electron_flow_203: $i > $i).
% 29.22/29.07  tff(decl_49532, type, fn_linear_electron_flow_204: $i > $i).
% 29.22/29.07  tff(decl_49533, type, fn_linear_electron_flow_205: $i > $i).
% 29.22/29.07  tff(decl_49534, type, fn_linear_electron_flow_206: $i > $i).
% 29.22/29.07  tff(decl_49535, type, fn_linear_electron_flow_207: $i > $i).
% 29.22/29.07  tff(decl_49536, type, fn_linear_electron_flow_208: $i > $i).
% 29.22/29.07  tff(decl_49537, type, fn_linear_electron_flow_209: $i > $i).
% 29.22/29.07  tff(decl_49538, type, fn_linear_electron_flow_210: $i > $i).
% 29.22/29.07  tff(decl_49539, type, fn_linear_electron_flow_211: $i > $i).
% 29.22/29.07  tff(decl_49540, type, fn_linear_electron_flow_212: $i > $i).
% 29.22/29.07  tff(decl_49541, type, fn_linear_electron_flow_213: $i > $i).
% 29.22/29.07  tff(decl_49542, type, fn_linear_electron_flow_214: $i > $i).
% 29.22/29.07  tff(decl_49543, type, fn_linear_electron_flow_216: $i > $i).
% 29.22/29.07  tff(decl_49544, type, fn_linear_electron_flow_217: $i > $i).
% 29.22/29.07  tff(decl_49545, type, fn_linear_electron_flow_218: $i > $i).
% 29.22/29.07  tff(decl_49546, type, fn_linear_electron_flow_219: $i > $i).
% 29.22/29.07  tff(decl_49547, type, fn_linear_electron_flow_220: $i > $i).
% 29.22/29.07  tff(decl_49548, type, fn_linear_electron_flow_221: $i > $i).
% 29.22/29.07  tff(decl_49549, type, p680_plus__1: $i > $o).
% 29.22/29.07  tff(decl_49550, type, fn_linear_electron_flow_222: $i > $i).
% 29.22/29.07  tff(decl_49551, type, fn_linear_electron_flow_223: $i > $i).
% 29.22/29.07  tff(decl_49552, type, fn_linear_electron_flow_224: $i > $i).
% 29.22/29.07  tff(decl_49553, type, fn_linear_electron_flow_225: $i > $i).
% 29.22/29.07  tff(decl_49554, type, fn_linear_electron_flow_226: $i > $i).
% 29.22/29.07  tff(decl_49555, type, fn_linear_electron_flow_227: $i > $i).
% 29.22/29.07  tff(decl_49556, type, fn_linear_electron_flow_228: $i > $i).
% 29.22/29.07  tff(decl_49557, type, fn_linear_electron_flow_229: $i > $i).
% 29.22/29.07  tff(decl_49558, type, fn_linear_electron_flow_230: $i > $i).
% 29.22/29.07  tff(decl_49559, type, fn_linear_electron_flow_231: $i > $i).
% 29.22/29.07  tff(decl_49560, type, fn_linear_electron_flow_232: $i > $i).
% 29.22/29.07  tff(decl_49561, type, fn_linear_electron_flow_233: $i > $i).
% 29.22/29.07  tff(decl_49562, type, fn_linear_electron_flow_234: $i > $i).
% 29.22/29.07  tff(decl_49563, type, fn_linear_electron_flow_235: $i > $i).
% 29.22/29.07  tff(decl_49564, type, fn_linear_electron_flow_236: $i > $i).
% 29.22/29.07  tff(decl_49565, type, fn_linear_electron_flow_237: $i > $i).
% 29.22/29.07  tff(decl_49566, type, fn_linear_electron_flow_238: $i > $i).
% 29.22/29.07  tff(decl_49567, type, fn_linear_electron_flow_239: $i > $i).
% 29.22/29.07  tff(decl_49568, type, fn_linear_electron_flow_240: $i > $i).
% 29.22/29.07  tff(decl_49569, type, fn_linear_electron_flow_241: $i > $i).
% 29.22/29.07  tff(decl_49570, type, fn_linear_electron_flow_242: $i > $i).
% 29.22/29.07  tff(decl_49571, type, fn_linear_electron_flow_245: $i > $i).
% 29.22/29.07  tff(decl_49572, type, fn_linear_electron_flow_246: $i > $i).
% 29.22/29.07  tff(decl_49573, type, fn_linear_electron_flow_247: $i > $i).
% 29.22/29.07  tff(decl_49574, type, fn_linear_electron_flow_248: $i > $i).
% 29.22/29.07  tff(decl_49575, type, fn_linear_electron_flow_249: $i > $i).
% 29.22/29.07  tff(decl_49576, type, fn_linear_electron_flow_250: $i > $i).
% 29.22/29.07  tff(decl_49577, type, fn_linear_electron_flow_251: $i > $i).
% 29.22/29.07  tff(decl_49578, type, fn_linear_electron_flow_252: $i > $i).
% 29.22/29.07  tff(decl_49579, type, fn_linear_electron_flow_253: $i > $i).
% 29.22/29.07  tff(decl_49580, type, fn_linear_electron_flow_254: $i > $i).
% 29.22/29.07  tff(decl_49581, type, fn_linear_electron_flow_255: $i > $i).
% 29.22/29.07  tff(decl_49582, type, fn_linear_electron_flow_256: $i > $i).
% 29.22/29.07  tff(decl_49583, type, fn_linear_electron_flow_257: $i > $i).
% 29.22/29.07  tff(decl_49584, type, fn_linear_electron_flow_258: $i > $i).
% 29.22/29.07  tff(decl_49585, type, fn_linear_electron_flow_259: $i > $i).
% 29.22/29.07  tff(decl_49586, type, fn_linear_electron_flow_260: $i > $i).
% 29.22/29.07  tff(decl_49587, type, fn_linear_electron_flow_261: $i > $i).
% 29.22/29.07  tff(decl_49588, type, fn_linear_electron_flow_262: $i > $i).
% 29.22/29.07  tff(decl_49589, type, fn_linear_electron_flow_263: $i > $i).
% 29.22/29.07  tff(decl_49590, type, fn_linear_electron_flow_264: $i > $i).
% 29.22/29.07  tff(decl_49591, type, fn_linear_electron_flow_265: $i > $i).
% 29.22/29.07  tff(decl_49592, type, fn_linear_electron_flow_266: $i > $i).
% 29.22/29.07  tff(decl_49593, type, fn_linear_electron_flow_267: $i > $i).
% 29.22/29.07  tff(decl_49594, type, fn_linear_electron_flow_268: $i > $i).
% 29.22/29.07  tff(decl_49595, type, fn_linear_electron_flow_269: $i > $i).
% 29.22/29.07  tff(decl_49596, type, fn_linear_electron_flow_270: $i > $i).
% 29.22/29.07  tff(decl_49597, type, fn_linear_electron_flow_271: $i > $i).
% 29.22/29.07  tff(decl_49598, type, fn_linear_electron_flow_272: $i > $i).
% 29.22/29.07  tff(decl_49599, type, fn_linear_electron_flow_273: $i > $i).
% 29.22/29.07  tff(decl_49600, type, fn_linear_electron_flow_274: $i > $i).
% 29.22/29.07  tff(decl_49601, type, fn_linear_electron_flow_275: $i > $i).
% 29.22/29.07  tff(decl_49602, type, fn_linear_electron_flow_276: $i > $i).
% 29.22/29.07  tff(decl_49603, type, fn_linear_electron_flow_277: $i > $i).
% 29.22/29.07  tff(decl_49604, type, fn_linear_electron_flow_278: $i > $i).
% 29.22/29.07  tff(decl_49605, type, fn_linear_electron_flow_279: $i > $i).
% 29.22/29.07  tff(decl_49606, type, fn_linear_electron_flow_280: $i > $i).
% 29.22/29.07  tff(decl_49607, type, fn_linear_electron_flow_281: $i > $i).
% 29.22/29.07  tff(decl_49608, type, fn_linear_electron_flow_282: $i > $i).
% 29.22/29.07  tff(decl_49609, type, fn_linear_electron_flow_283: $i > $i).
% 29.22/29.07  tff(decl_49610, type, fn_linear_electron_flow_284: $i > $i).
% 29.22/29.07  tff(decl_49611, type, fn_linear_electron_flow_285: $i > $i).
% 29.22/29.07  tff(decl_49612, type, fn_linear_electron_flow_286: $i > $i).
% 29.22/29.07  tff(decl_49613, type, fn_linear_electron_flow_287: $i > $i).
% 29.22/29.07  tff(decl_49614, type, fn_linear_electron_flow_288: $i > $i).
% 29.22/29.07  tff(decl_49615, type, fn_linear_electron_flow_289: $i > $i).
% 29.22/29.07  tff(decl_49616, type, fn_linear_electron_flow_290: $i > $i).
% 29.22/29.07  tff(decl_49617, type, fn_linear_electron_flow_291: $i > $i).
% 29.22/29.07  tff(decl_49618, type, fn_linear_electron_flow_292: $i > $i).
% 29.22/29.07  tff(decl_49619, type, fn_linear_electron_flow_293: $i > $i).
% 29.22/29.07  tff(decl_49620, type, fn_linear_electron_flow_294: $i > $i).
% 29.22/29.07  tff(decl_49621, type, fn_linear_electron_flow_295: $i > $i).
% 29.22/29.07  tff(decl_49622, type, fn_linear_electron_flow_296: $i > $i).
% 29.22/29.07  tff(decl_49623, type, fn_linear_electron_flow_297: $i > $i).
% 29.22/29.07  tff(decl_49624, type, fn_linear_electron_flow_298: $i > $i).
% 29.22/29.07  tff(decl_49625, type, fn_linear_electron_flow_299: $i > $i).
% 29.22/29.07  tff(decl_49626, type, fn_linear_electron_flow_300: $i > $i).
% 29.22/29.07  tff(decl_49627, type, fn_linear_electron_flow_301: $i > $i).
% 29.22/29.07  tff(decl_49628, type, fn_linear_electron_flow_302: $i > $i).
% 29.22/29.07  tff(decl_49629, type, fn_linear_electron_flow_303: $i > $i).
% 29.22/29.07  tff(decl_49630, type, fn_linear_electron_flow_304: $i > $i).
% 29.22/29.07  tff(decl_49631, type, fn_linear_electron_flow_305: $i > $i).
% 29.22/29.07  tff(decl_49632, type, fn_linear_electron_flow_308: $i > $i).
% 29.22/29.07  tff(decl_49633, type, fn_linear_electron_flow_309: $i > $i).
% 29.22/29.07  tff(decl_49634, type, fn_linear_electron_flow_310: $i > $i).
% 29.22/29.07  tff(decl_49635, type, fn_linear_electron_flow_311: $i > $i).
% 29.22/29.07  tff(decl_49636, type, fn_linear_electron_flow_312: $i > $i).
% 29.22/29.07  tff(decl_49637, type, fn_linear_electron_flow_313: $i > $i).
% 29.22/29.07  tff(decl_49638, type, fn_linear_electron_flow_314: $i > $i).
% 29.22/29.07  tff(decl_49639, type, fn_linear_electron_flow_315: $i > $i).
% 29.22/29.07  tff(decl_49640, type, fn_linear_electron_flow_316: $i > $i).
% 29.22/29.07  tff(decl_49641, type, fn_linear_electron_flow_317: $i > $i).
% 29.22/29.07  tff(decl_49642, type, fn_linear_electron_flow_318: $i > $i).
% 29.22/29.07  tff(decl_49643, type, fn_linear_electron_flow_319: $i > $i).
% 29.22/29.07  tff(decl_49644, type, fn_linear_electron_flow_320: $i > $i).
% 29.22/29.07  tff(decl_49645, type, fn_linear_electron_flow_321: $i > $i).
% 29.22/29.07  tff(decl_49646, type, fn_linear_electron_flow_322: $i > $i).
% 29.22/29.07  tff(decl_49647, type, fn_linear_electron_flow_323: $i > $i).
% 29.22/29.07  tff(decl_49648, type, fn_linear_electron_flow_324: $i > $i).
% 29.22/29.07  tff(decl_49649, type, fn_linear_electron_flow_325: $i > $i).
% 29.22/29.07  tff(decl_49650, type, fn_reaction_center_complex_12: $i > $i).
% 29.22/29.07  tff(decl_49651, type, fn_reaction_center_complex_3: $i > $i).
% 29.22/29.07  tff(decl_49652, type, fn_reaction_center_complex_1: $i > $i).
% 29.22/29.07  tff(decl_49653, type, fn_reaction_center_complex_4: $i > $i).
% 29.22/29.07  tff(decl_49654, type, fn_reaction_center_complex_2: $i > $i).
% 29.22/29.07  tff(decl_49655, type, fn_reaction_center_complex_10: $i > $i).
% 29.22/29.07  tff(decl_49656, type, fn_photosystem_ii_20: $i > $i).
% 29.22/29.07  tff(decl_49657, type, fn_photosystem_ii_21: $i > $i).
% 29.22/29.07  tff(decl_49658, type, fn_photosystem_ii_4: $i > $i).
% 29.22/29.07  tff(decl_49659, type, fn_photosystem_ii_5: $i > $i).
% 29.22/29.07  tff(decl_49660, type, fn_photosystem_ii_18: $i > $i).
% 29.22/29.07  tff(decl_49661, type, fn_photosystem_ii_9: $i > $i).
% 29.22/29.07  tff(decl_49662, type, fn_phospholipid_layer_16: $i > $i).
% 29.22/29.07  tff(decl_49663, type, fn_biomembrane_5: $i > $i).
% 29.22/29.07  tff(decl_49664, type, fn_biomembrane_7: $i > $i).
% 29.22/29.07  tff(decl_49665, type, fn_thylakoid_membrane_11: $i > $i).
% 29.22/29.07  tff(decl_49666, type, fn_thylakoid_membrane_10: $i > $i).
% 29.22/29.07  tff(decl_49667, type, fn_reaction_center_complex_14: $i > $i).
% 29.22/29.07  tff(decl_49668, type, fn_thylakoid_electron_transport_chain_15: $i > $i).
% 29.22/29.07  tff(decl_49669, type, fn_thylakoid_electron_transport_chain_13: $i > $i).
% 29.22/29.07  tff(decl_49670, type, fn_thylakoid_electron_transport_chain_17: $i > $i).
% 29.22/29.07  tff(decl_49671, type, fn_thylakoid_electron_transport_chain_14: $i > $i).
% 29.22/29.07  tff(decl_49672, type, fn_thylakoid_electron_transport_chain_16: $i > $i).
% 29.22/29.07  tff(decl_49673, type, fn_thylakoid_electron_transport_chain_12: $i > $i).
% 29.22/29.07  tff(decl_49674, type, fn_thylakoid_electron_transport_chain_18: $i > $i).
% 29.22/29.07  tff(decl_49675, type, fn_thylakoid_electron_transport_chain_28: $i > $i).
% 29.22/29.07  tff(decl_49676, type, fn_thylakoid_electron_transport_chain_29: $i > $i).
% 29.22/29.07  tff(decl_49677, type, fn_thylakoid_electron_transport_chain_30: $i > $i).
% 29.22/29.07  tff(decl_49678, type, fn_thylakoid_electron_transport_chain_26: $i > $i).
% 29.22/29.07  tff(decl_49679, type, fn_p680_18: $i > $i).
% 29.22/29.07  tff(decl_49680, type, fn_reaction_center_complex_6: $i > $i).
% 29.22/29.07  tff(decl_49681, type, fn_reaction_center_complex_13: $i > $i).
% 29.22/29.07  tff(decl_49682, type, fn_reaction_center_complex_9: $i > $i).
% 29.22/29.07  tff(decl_49683, type, fn_reaction_center_complex_7: $i > $i).
% 29.22/29.07  tff(decl_49684, type, fn_p680_19: $i > $i).
% 29.22/29.07  tff(decl_49685, type, fn_reaction_center_complex_11: $i > $i).
% 29.22/29.07  tff(decl_49686, type, fn_redox_reaction_6: $i > $i).
% 29.22/29.07  tff(decl_49687, type, fn_photosystem_ii_10: $i > $i).
% 29.22/29.07  tff(decl_49688, type, fn_photosystem_ii_17: $i > $i).
% 29.22/29.07  tff(decl_49689, type, fn_nadph_1: $i > $i).
% 29.22/29.07  tff(decl_49690, type, fn_thylakoid_membrane_15: $i > $i).
% 29.22/29.07  tff(decl_49691, type, fn_thylakoid_membrane_4: $i > $i).
% 29.22/29.07  tff(decl_49692, type, fn_reaction_center_complex_5: $i > $i).
% 29.22/29.07  tff(decl_49693, type, fn_reaction_center_complex_8: $i > $i).
% 29.22/29.07  tff(decl_49694, type, fn_thylakoid_electron_transport_chain_8: $i > $i).
% 29.22/29.07  tff(decl_49695, type, fn_thylakoid_electron_transport_chain_21: $i > $i).
% 29.22/29.07  tff(decl_49696, type, fn_thylakoid_electron_transport_chain_22: $i > $i).
% 29.22/29.07  tff(decl_49697, type, fn_thylakoid_membrane_7: $i > $i).
% 29.22/29.07  tff(decl_49698, type, fn_thylakoid_electron_transport_chain_11: $i > $i).
% 29.22/29.07  tff(decl_49699, type, fn_thylakoid_electron_transport_chain_1: $i > $i).
% 29.22/29.07  tff(decl_49700, type, fn_thylakoid_electron_transport_chain_4: $i > $i).
% 29.22/29.07  tff(decl_49701, type, fn_thylakoid_electron_transport_chain_19: $i > $i).
% 29.22/29.07  tff(decl_49702, type, fn_thylakoid_electron_transport_chain_2: $i > $i).
% 29.22/29.07  tff(decl_49703, type, fn_thylakoid_electron_transport_chain_6: $i > $i).
% 29.22/29.07  tff(decl_49704, type, fn_thylakoid_electron_transport_chain_7: $i > $i).
% 29.22/29.07  tff(decl_49705, type, fn_thylakoid_electron_transport_chain_9: $i > $i).
% 29.22/29.07  tff(decl_49706, type, fn_thylakoid_electron_transport_chain_10: $i > $i).
% 29.22/29.07  tff(decl_49707, type, fn_thylakoid_membrane_6: $i > $i).
% 29.22/29.07  tff(decl_49708, type, fn_photosystem_ii_3: $i > $i).
% 29.22/29.07  tff(decl_49709, type, fn_thylakoid_electron_transport_chain_25: $i > $i).
% 29.22/29.07  tff(decl_49710, type, fn_thylakoid_electron_transport_chain_23: $i > $i).
% 29.22/29.07  tff(decl_49711, type, fn_thylakoid_electron_transport_chain_27: $i > $i).
% 29.22/29.07  tff(decl_49712, type, fn_thylakoid_electron_transport_chain_3: $i > $i).
% 29.22/29.07  tff(decl_49713, type, fn_thylakoid_electron_transport_chain_20: $i > $i).
% 29.22/29.07  tff(decl_49714, type, fn_thylakoid_membrane_2: $i > $i).
% 29.22/29.07  tff(decl_49715, type, fn_thylakoid_electron_transport_chain_5: $i > $i).
% 29.22/29.07  tff(decl_49716, type, fn_p680_36: $i > $i).
% 29.22/29.07  tff(decl_49717, type, fn_p680_17: $i > $i).
% 29.22/29.07  tff(decl_49718, type, fn_photosystem_ii_11: $i > $i).
% 29.22/29.07  tff(decl_49719, type, '2-Water-to-p680+': $i).
% 29.22/29.07  tff(decl_49720, type, 'Quantity_ATP': $i).
% 29.22/29.07  tff(decl_49721, type, 'Quantity_NADPH': $i).
% 29.22/29.07  tff(decl_49722, type, fn_linear_electron_flow_171: $i > $i).
% 29.22/29.07  tff(decl_49723, type, fn_linear_electron_flow_170: $i > $i).
% 29.22/29.07  tff(decl_49724, type, fn_linear_electron_flow_169: $i > $i).
% 29.22/29.07  tff(decl_49725, type, fn_linear_electron_flow_134: $i > $i).
% 29.22/29.07  tff(decl_49726, type, fn_linear_electron_flow_133: $i > $i).
% 29.22/29.07  tff(decl_49727, type, fn_linear_electron_flow_108: $i > $i).
% 29.22/29.07  tff(decl_49728, type, fn_linear_electron_flow_107: $i > $i).
% 29.22/29.07  tff(decl_49729, type, fn_linear_electron_flow_306: $i > $i).
% 29.22/29.07  tff(decl_49730, type, fn_linear_electron_flow_307: $i > $i).
% 29.22/29.07  tff(decl_49731, type, fn_linear_electron_flow_145: $i > $i).
% 29.22/29.07  tff(decl_49732, type, fn_linear_electron_flow_144: $i > $i).
% 29.22/29.07  tff(decl_49733, type, fn_linear_electron_flow_72: $i > $i).
% 29.22/29.07  tff(decl_49734, type, fn_linear_electron_flow_71: $i > $i).
% 29.22/29.07  tff(decl_49735, type, fn_linear_electron_flow_119: $i > $i).
% 29.22/29.07  tff(decl_49736, type, fn_linear_electron_flow_87: $i > $i).
% 29.22/29.07  tff(decl_49737, type, fn_linear_electron_flow_86: $i > $i).
% 29.22/29.07  tff(decl_49738, type, fn_linear_electron_flow_61: $i > $i).
% 29.22/29.07  tff(decl_49739, type, fn_linear_electron_flow_156: $i > $i).
% 29.22/29.07  tff(decl_49740, type, fn_linear_electron_flow_168: $i > $i).
% 29.22/29.07  tff(decl_49741, type, fn_linear_electron_flow_85: $i > $i).
% 29.22/29.07  tff(decl_49742, type, fn_linear_electron_flow_84: $i > $i).
% 29.22/29.07  tff(decl_49743, type, fn_linear_electron_flow_243: $i > $i).
% 29.22/29.07  tff(decl_49744, type, fn_linear_electron_flow_244: $i > $i).
% 29.22/29.07  tff(decl_49745, type, 'Lining': $i).
% 29.22/29.07  tff(decl_49746, type, 'Layer on the inside of something.': $i).
% 29.22/29.07  tff(decl_49747, type, lining: $i).
% 29.22/29.07  tff(decl_49748, type, 'Linkage-Map': $i).
% 29.22/29.07  tff(decl_49749, type, 'A genetic map based on the frequencies of recombination between markers during crossing over of homologous chromosomes.': $i).
% 29.22/29.07  tff(decl_49750, type, 'map of linkage': $i).
% 29.22/29.07  tff(decl_49751, type, 'linkage map': $i).
% 29.22/29.07  tff(decl_49752, type, 'linkage-map': $i).
% 29.22/29.07  tff(decl_49753, type, physical_map_1: $i > $o).
% 29.22/29.07  tff(decl_49754, type, fn_linkage_map_1: $i > $i).
% 29.22/29.07  tff(decl_49755, type, recombination_frequency_1: $i > $o).
% 29.22/29.07  tff(decl_49756, type, fn_linkage_map_2: $i > $i).
% 29.22/29.07  tff(decl_49757, type, fn_linkage_map_3: $i > $i).
% 29.22/29.07  tff(decl_49758, type, fn_linkage_map_4: $i > $i).
% 29.22/29.07  tff(decl_49759, type, fn_linkage_map_5: $i > $i).
% 29.22/29.07  tff(decl_49760, type, fn_linkage_map_6: $i > $i).
% 29.22/29.07  tff(decl_49761, type, linked_genes_1: $i > $o).
% 29.22/29.07  tff(decl_49762, type, 'Linked-Genes': $i).
% 29.22/29.07  tff(decl_49763, type, 'Genes located close enough together on a chromosome that they tend to be inherited together.': $i).
% 29.22/29.07  tff(decl_49764, type, 'genetic linkage': $i).
% 29.22/29.07  tff(decl_49765, type, 'genetic-linkage': $i).
% 29.22/29.07  tff(decl_49766, type, 'linked genes': $i).
% 29.22/29.07  tff(decl_49767, type, 'linked gene': $i).
% 29.22/29.07  tff(decl_49768, type, 'linked-gene': $i).
% 29.22/29.07  tff(decl_49769, type, fn_linked_genes_1: $i > $i).
% 29.22/29.07  tff(decl_49770, type, fn_linked_genes_2: $i > $i).
% 29.22/29.07  tff(decl_49771, type, fn_map_unit_1: $i > $i).
% 29.22/29.07  tff(decl_49772, type, fn_map_unit_12: $i > $i).
% 29.22/29.07  tff(decl_49773, type, 'Linoleic-Acid': $i).
% 29.22/29.07  tff(decl_49774, type, 'Unsaturated fatty acid which is found in some lipids of cell membranes.': $i).
% 29.22/29.07  tff(decl_49775, type, 'linoleic acid': $i).
% 29.22/29.07  tff(decl_49776, type, 'linoleic-acid': $i).
% 29.22/29.07  tff(decl_49777, type, fn_linoleic_acid_1: $i > $i).
% 29.22/29.07  tff(decl_49778, type, fn_linoleic_acid_2: $i > $i).
% 29.22/29.07  tff(decl_49779, type, fn_linoleic_acid_3: $i > $i).
% 29.22/29.07  tff(decl_49780, type, fn_linoleic_acid_4: $i > $i).
% 29.22/29.07  tff(decl_49781, type, fn_linoleic_acid_5: $i > $i).
% 29.22/29.07  tff(decl_49782, type, fn_linoleic_acid_6: $i > $i).
% 29.22/29.07  tff(decl_49783, type, fn_linoleic_acid_7: $i > $i).
% 29.22/29.07  tff(decl_49784, type, fn_linoleic_acid_8: $i > $i).
% 29.22/29.07  tff(decl_49785, type, fn_linoleic_acid_9: $i > $i).
% 29.22/29.07  tff(decl_49786, type, fn_linoleic_acid_10: $i > $i).
% 29.22/29.07  tff(decl_49787, type, fn_linoleic_acid_11: $i > $i).
% 29.22/29.07  tff(decl_49788, type, fn_linoleic_acid_12: $i > $i).
% 29.22/29.07  tff(decl_49789, type, fn_linoleic_acid_13: $i > $i).
% 29.22/29.07  tff(decl_49790, type, fn_linoleic_acid_14: $i > $i).
% 29.22/29.07  tff(decl_49791, type, fn_linoleic_acid_15: $i > $i).
% 29.22/29.07  tff(decl_49792, type, fn_linoleic_acid_16: $i > $i).
% 29.22/29.07  tff(decl_49793, type, fn_linoleic_acid_17: $i > $i).
% 29.22/29.07  tff(decl_49794, type, fn_linoleic_acid_18: $i > $i).
% 29.22/29.07  tff(decl_49795, type, fn_linoleic_acid_19: $i > $i).
% 29.22/29.07  tff(decl_49796, type, fn_linoleic_acid_20: $i > $i).
% 29.22/29.07  tff(decl_49797, type, fn_linoleic_acid_21: $i > $i).
% 29.22/29.07  tff(decl_49798, type, fn_linoleic_acid_22: $i > $i).
% 29.22/29.07  tff(decl_49799, type, fn_linoleic_acid_23: $i > $i).
% 29.22/29.07  tff(decl_49800, type, fn_linoleic_acid_24: $i > $i).
% 29.22/29.07  tff(decl_49801, type, fn_linoleic_acid_25: $i > $i).
% 29.22/29.07  tff(decl_49802, type, fn_linoleic_acid_26: $i > $i).
% 29.22/29.07  tff(decl_49803, type, fn_linoleic_acid_27: $i > $i).
% 29.22/29.07  tff(decl_49804, type, fn_linoleic_acid_28: $i > $i).
% 29.22/29.07  tff(decl_49805, type, fn_linoleic_acid_29: $i > $i).
% 29.22/29.07  tff(decl_49806, type, fn_linoleic_acid_30: $i > $i).
% 29.22/29.07  tff(decl_49807, type, fn_linoleic_acid_31: $i > $i).
% 29.22/29.07  tff(decl_49808, type, fn_linoleic_acid_32: $i > $i).
% 29.22/29.07  tff(decl_49809, type, fn_linoleic_acid_33: $i > $i).
% 29.22/29.07  tff(decl_49810, type, fn_linoleic_acid_34: $i > $i).
% 29.22/29.07  tff(decl_49811, type, fn_linoleic_acid_35: $i > $i).
% 29.22/29.07  tff(decl_49812, type, fn_linoleic_acid_36: $i > $i).
% 29.22/29.07  tff(decl_49813, type, fn_linoleic_acid_37: $i > $i).
% 29.22/29.07  tff(decl_49814, type, fn_linoleic_acid_38: $i > $i).
% 29.22/29.07  tff(decl_49815, type, fn_linoleic_acid_39: $i > $i).
% 29.22/29.07  tff(decl_49816, type, fn_linoleic_acid_40: $i > $i).
% 29.22/29.07  tff(decl_49817, type, fn_linoleic_acid_41: $i > $i).
% 29.22/29.07  tff(decl_49818, type, fn_linoleic_acid_42: $i > $i).
% 29.22/29.07  tff(decl_49819, type, fn_linoleic_acid_43: $i > $i).
% 29.22/29.07  tff(decl_49820, type, fn_linoleic_acid_44: $i > $i).
% 29.22/29.07  tff(decl_49821, type, fn_linoleic_acid_45: $i > $i).
% 29.22/29.07  tff(decl_49822, type, fn_linoleic_acid_46: $i > $i).
% 29.22/29.07  tff(decl_49823, type, fn_linoleic_acid_47: $i > $i).
% 29.22/29.07  tff(decl_49824, type, fn_linoleic_acid_48: $i > $i).
% 29.22/29.07  tff(decl_49825, type, fn_linoleic_acid_49: $i > $i).
% 29.22/29.07  tff(decl_49826, type, fn_linoleic_acid_50: $i > $i).
% 29.22/29.07  tff(decl_49827, type, fn_linoleic_acid_51: $i > $i).
% 29.22/29.07  tff(decl_49828, type, fn_linoleic_acid_52: $i > $i).
% 29.22/29.07  tff(decl_49829, type, fn_linoleic_acid_53: $i > $i).
% 29.22/29.07  tff(decl_49830, type, fn_linoleic_acid_54: $i > $i).
% 29.22/29.07  tff(decl_49831, type, fn_linoleic_acid_55: $i > $i).
% 29.22/29.07  tff(decl_49832, type, fn_linoleic_acid_56: $i > $i).
% 29.22/29.07  tff(decl_49833, type, fn_linoleic_acid_57: $i > $i).
% 29.22/29.07  tff(decl_49834, type, fn_linoleic_acid_58: $i > $i).
% 29.22/29.07  tff(decl_49835, type, fn_linoleic_acid_59: $i > $i).
% 29.22/29.07  tff(decl_49836, type, fn_linoleic_acid_60: $i > $i).
% 29.22/29.07  tff(decl_49837, type, fn_linoleic_acid_61: $i > $i).
% 29.22/29.07  tff(decl_49838, type, fn_linoleic_acid_62: $i > $i).
% 29.22/29.07  tff(decl_49839, type, fn_linoleic_acid_63: $i > $i).
% 29.22/29.07  tff(decl_49840, type, fn_linoleic_acid_64: $i > $i).
% 29.22/29.07  tff(decl_49841, type, fn_linoleic_acid_65: $i > $i).
% 29.22/29.07  tff(decl_49842, type, fn_linoleic_acid_66: $i > $i).
% 29.22/29.07  tff(decl_49843, type, fn_linoleic_acid_67: $i > $i).
% 29.22/29.07  tff(decl_49844, type, fn_linoleic_acid_68: $i > $i).
% 29.22/29.07  tff(decl_49845, type, fn_linoleic_acid_69: $i > $i).
% 29.22/29.07  tff(decl_49846, type, fn_linoleic_acid_70: $i > $i).
% 29.22/29.07  tff(decl_49847, type, fn_linoleic_acid_71: $i > $i).
% 29.22/29.07  tff(decl_49848, type, fn_linoleic_acid_72: $i > $i).
% 29.22/29.07  tff(decl_49849, type, fn_linoleic_acid_73: $i > $i).
% 29.22/29.07  tff(decl_49850, type, fn_linoleic_acid_74: $i > $i).
% 29.22/29.07  tff(decl_49851, type, fn_linoleic_acid_75: $i > $i).
% 29.22/29.07  tff(decl_49852, type, fn_linoleic_acid_76: $i > $i).
% 29.22/29.07  tff(decl_49853, type, fn_linoleic_acid_77: $i > $i).
% 29.22/29.07  tff(decl_49854, type, fn_linoleic_acid_78: $i > $i).
% 29.22/29.07  tff(decl_49855, type, fn_linoleic_acid_79: $i > $i).
% 29.22/29.07  tff(decl_49856, type, fn_linoleic_acid_80: $i > $i).
% 29.22/29.07  tff(decl_49857, type, fn_linoleic_acid_81: $i > $i).
% 29.22/29.07  tff(decl_49858, type, fn_linoleic_acid_82: $i > $i).
% 29.22/29.07  tff(decl_49859, type, fn_linoleic_acid_83: $i > $i).
% 29.22/29.07  tff(decl_49860, type, fn_linoleic_acid_84: $i > $i).
% 29.22/29.07  tff(decl_49861, type, fn_linoleic_acid_85: $i > $i).
% 29.22/29.07  tff(decl_49862, type, fn_linoleic_acid_86: $i > $i).
% 29.22/29.07  tff(decl_49863, type, fn_linoleic_acid_87: $i > $i).
% 29.22/29.07  tff(decl_49864, type, fn_linoleic_acid_88: $i > $i).
% 29.22/29.07  tff(decl_49865, type, fn_linoleic_acid_89: $i > $i).
% 29.22/29.07  tff(decl_49866, type, fn_linoleic_acid_90: $i > $i).
% 29.22/29.07  tff(decl_49867, type, fn_linoleic_acid_91: $i > $i).
% 29.22/29.07  tff(decl_49868, type, fn_linoleic_acid_92: $i > $i).
% 29.22/29.07  tff(decl_49869, type, fn_linoleic_acid_93: $i > $i).
% 29.22/29.07  tff(decl_49870, type, fn_linoleic_acid_94: $i > $i).
% 29.22/29.07  tff(decl_49871, type, fn_linoleic_acid_95: $i > $i).
% 29.22/29.07  tff(decl_49872, type, fn_linoleic_acid_96: $i > $i).
% 29.22/29.07  tff(decl_49873, type, fn_linoleic_acid_97: $i > $i).
% 29.22/29.07  tff(decl_49874, type, fn_linoleic_acid_98: $i > $i).
% 29.22/29.07  tff(decl_49875, type, fn_linoleic_acid_99: $i > $i).
% 29.22/29.07  tff(decl_49876, type, fn_linoleic_acid_100: $i > $i).
% 29.22/29.07  tff(decl_49877, type, fn_linoleic_acid_101: $i > $i).
% 29.22/29.07  tff(decl_49878, type, fn_linoleic_acid_102: $i > $i).
% 29.22/29.07  tff(decl_49879, type, fn_linoleic_acid_103: $i > $i).
% 29.22/29.07  tff(decl_49880, type, fn_second_electron_shell_10: $i > $i).
% 29.22/29.07  tff(decl_49881, type, 'C2': $i).
% 29.22/29.07  tff(decl_49882, type, 'C3': $i).
% 29.22/29.07  tff(decl_49883, type, 'C1': $i).
% 29.22/29.07  tff(decl_49884, type, fn_unsaturated_fatty_acid_22: $i > $i).
% 29.22/29.07  tff(decl_49885, type, fn_unsaturated_fatty_acid_4: $i > $i).
% 29.22/29.07  tff(decl_49886, type, fn_unsaturated_fatty_acid_18: $i > $i).
% 29.22/29.07  tff(decl_49887, type, fn_unsaturated_fatty_acid_44: $i > $i).
% 29.22/29.07  tff(decl_49888, type, fn_unsaturated_fatty_acid_5: $i > $i).
% 29.22/29.07  tff(decl_49889, type, fn_unsaturated_fatty_acid_74: $i > $i).
% 29.22/29.07  tff(decl_49890, type, fn_unsaturated_fatty_acid_23: $i > $i).
% 29.22/29.07  tff(decl_49891, type, fn_unsaturated_fatty_acid_8: $i > $i).
% 29.22/29.07  tff(decl_49892, type, fn_unsaturated_fatty_acid_7: $i > $i).
% 29.22/29.07  tff(decl_49893, type, fn_unsaturated_fatty_acid_16: $i > $i).
% 29.22/29.07  tff(decl_49894, type, fn_unsaturated_fatty_acid_15: $i > $i).
% 29.22/29.07  tff(decl_49895, type, fn_unsaturated_fatty_acid_66: $i > $i).
% 29.22/29.07  tff(decl_49896, type, fn_unsaturated_fatty_acid_61: $i > $i).
% 29.22/29.07  tff(decl_49897, type, fn_unsaturated_fatty_acid_11: $i > $i).
% 29.22/29.07  tff(decl_49898, type, fn_unsaturated_fatty_acid_43: $i > $i).
% 29.22/29.07  tff(decl_49899, type, fn_unsaturated_fatty_acid_9: $i > $i).
% 29.22/29.07  tff(decl_49900, type, fn_unsaturated_fatty_acid_47: $i > $i).
% 29.22/29.07  tff(decl_49901, type, fn_unsaturated_fatty_acid_33: $i > $i).
% 29.22/29.07  tff(decl_49902, type, fn_unsaturated_fatty_acid_35: $i > $i).
% 29.22/29.07  tff(decl_49903, type, fn_unsaturated_fatty_acid_36: $i > $i).
% 29.22/29.07  tff(decl_49904, type, fn_unsaturated_fatty_acid_30: $i > $i).
% 29.22/29.07  tff(decl_49905, type, fn_unsaturated_fatty_acid_38: $i > $i).
% 29.22/29.07  tff(decl_49906, type, fn_unsaturated_fatty_acid_69: $i > $i).
% 29.22/29.07  tff(decl_49907, type, fn_unsaturated_fatty_acid_41: $i > $i).
% 29.22/29.07  tff(decl_49908, type, fn_unsaturated_fatty_acid_40: $i > $i).
% 29.22/29.07  tff(decl_49909, type, fn_unsaturated_fatty_acid_39: $i > $i).
% 29.22/29.07  tff(decl_49910, type, fn_unsaturated_fatty_acid_31: $i > $i).
% 29.22/29.07  tff(decl_49911, type, fn_unsaturated_fatty_acid_37: $i > $i).
% 29.22/29.07  tff(decl_49912, type, fn_unsaturated_fatty_acid_32: $i > $i).
% 29.22/29.07  tff(decl_49913, type, fn_unsaturated_fatty_acid_34: $i > $i).
% 29.22/29.07  tff(decl_49914, type, fn_unsaturated_fatty_acid_53: $i > $i).
% 29.22/29.07  tff(decl_49915, type, fn_unsaturated_fatty_acid_10: $i > $i).
% 29.22/29.07  tff(decl_49916, type, fn_unsaturated_fatty_acid_58: $i > $i).
% 29.22/29.07  tff(decl_49917, type, fn_unsaturated_fatty_acid_75: $i > $i).
% 29.22/29.07  tff(decl_49918, type, fn_unsaturated_fatty_acid_63: $i > $i).
% 29.22/29.07  tff(decl_49919, type, fn_unsaturated_fatty_acid_45: $i > $i).
% 29.22/29.07  tff(decl_49920, type, fn_unsaturated_fatty_acid_28: $i > $i).
% 29.22/29.07  tff(decl_49921, type, fn_unsaturated_fatty_acid_6: $i > $i).
% 29.22/29.07  tff(decl_49922, type, fn_unsaturated_fatty_acid_46: $i > $i).
% 29.22/29.07  tff(decl_49923, type, fn_unsaturated_fatty_acid_20: $i > $i).
% 29.22/29.07  tff(decl_49924, type, fn_unsaturated_fatty_acid_70: $i > $i).
% 29.22/29.07  tff(decl_49925, type, fn_unsaturated_fatty_acid_68: $i > $i).
% 29.22/29.07  tff(decl_49926, type, fn_unsaturated_fatty_acid_25: $i > $i).
% 29.22/29.07  tff(decl_49927, type, fn_unsaturated_fatty_acid_57: $i > $i).
% 29.22/29.07  tff(decl_49928, type, fn_unsaturated_fatty_acid_14: $i > $i).
% 29.22/29.07  tff(decl_49929, type, fn_unsaturated_fatty_acid_71: $i > $i).
% 29.22/29.07  tff(decl_49930, type, fn_unsaturated_fatty_acid_13: $i > $i).
% 29.22/29.07  tff(decl_49931, type, fn_unsaturated_fatty_acid_77: $i > $i).
% 29.22/29.07  tff(decl_49932, type, fn_unsaturated_fatty_acid_64: $i > $i).
% 29.22/29.07  tff(decl_49933, type, fn_unsaturated_fatty_acid_72: $i > $i).
% 29.22/29.07  tff(decl_49934, type, fn_unsaturated_fatty_acid_55: $i > $i).
% 29.22/29.07  tff(decl_49935, type, fn_unsaturated_fatty_acid_21: $i > $i).
% 29.22/29.07  tff(decl_49936, type, fn_unsaturated_fatty_acid_59: $i > $i).
% 29.22/29.07  tff(decl_49937, type, fn_unsaturated_fatty_acid_12: $i > $i).
% 29.22/29.07  tff(decl_49938, type, fn_unsaturated_fatty_acid_76: $i > $i).
% 29.22/29.07  tff(decl_49939, type, fn_unsaturated_fatty_acid_19: $i > $i).
% 29.22/29.07  tff(decl_49940, type, fn_unsaturated_fatty_acid_50: $i > $i).
% 29.22/29.07  tff(decl_49941, type, fn_unsaturated_fatty_acid_56: $i > $i).
% 29.22/29.07  tff(decl_49942, type, fn_unsaturated_fatty_acid_52: $i > $i).
% 29.22/29.07  tff(decl_49943, type, fn_unsaturated_fatty_acid_51: $i > $i).
% 29.22/29.07  tff(decl_49944, type, fn_unsaturated_fatty_acid_60: $i > $i).
% 29.22/29.07  tff(decl_49945, type, fn_unsaturated_fatty_acid_73: $i > $i).
% 29.22/29.07  tff(decl_49946, type, fn_unsaturated_fatty_acid_29: $i > $i).
% 29.22/29.07  tff(decl_49947, type, fn_unsaturated_fatty_acid_26: $i > $i).
% 29.22/29.07  tff(decl_49948, type, fn_unsaturated_fatty_acid_49: $i > $i).
% 29.22/29.07  tff(decl_49949, type, fn_unsaturated_fatty_acid_27: $i > $i).
% 29.22/29.07  tff(decl_49950, type, fn_unsaturated_fatty_acid_48: $i > $i).
% 29.22/29.07  tff(decl_49951, type, 'Lipase': $i).
% 29.22/29.07  tff(decl_49952, type, 'Lipase is an enzyme which hydrolysis the fat to glycerol and fatty acids.': $i).
% 29.22/29.07  tff(decl_49953, type, lipase: $i).
% 29.22/29.07  tff(decl_49954, type, fn_lipase_3: $i > $i).
% 29.22/29.07  tff(decl_49955, type, 'Lipid': $i).
% 29.22/29.07  tff(decl_49956, type, 'One of a family of compounds, including fats, phospholipids, and steroids, that are insoluble in water. Organic molecule, generally containing hydrocarbon': $i).
% 29.22/29.07  tff(decl_49957, type, 'Lipids are a broad group of naturally occurring molecules which includes fats, waxes, steroids, fat-soluble vitamins, phospholipids, and others.': $i).
% 29.22/29.07  tff(decl_49958, type, lipid: $i).
% 29.22/29.07  tff(decl_49959, type, fn_lipid_3: $i > $i).
% 29.22/29.07  tff(decl_49960, type, fn_lipid_4: $i > $i).
% 29.22/29.07  tff(decl_49961, type, fn_lipid_6: $i > $i).
% 29.22/29.07  tff(decl_49962, type, fn_lipid_10: $i > $i).
% 29.22/29.07  tff(decl_49963, type, fn_lipid_11: $i > $i).
% 29.22/29.07  tff(decl_49964, type, fn_lipid_13: $i > $i).
% 29.22/29.07  tff(decl_49965, type, 'Q_hydrogen': $i).
% 29.22/29.07  tff(decl_49966, type, 'Q_carbon': $i).
% 29.22/29.07  tff(decl_49967, type, fn_lipid_12: $i > $i).
% 29.22/29.07  tff(decl_49968, type, 'Lipoprotein': $i).
% 29.22/29.07  tff(decl_49969, type, 'Any of a group of biological molecules consisting of a lipid bound to a protein. Examples include high-density lipoprotein (HDL) and low-density lipoprotein (LDL), which transport fats in the bloodstream.': $i).
% 29.22/29.07  tff(decl_49970, type, lipoprotein: $i).
% 29.22/29.07  tff(decl_49971, type, liquid_ammonia_1: $i > $o).
% 29.22/29.07  tff(decl_49972, type, 'Liquid-Ammonia': $i).
% 29.22/29.07  tff(decl_49973, type, 'It is liquid form of ammonia.': $i).
% 29.22/29.07  tff(decl_49974, type, 'ammonia of liquid': $i).
% 29.22/29.07  tff(decl_49975, type, 'liquid ammonia': $i).
% 29.22/29.07  tff(decl_49976, type, 'liquid-ammonia': $i).
% 29.22/29.07  tff(decl_49977, type, fn_liquid_ammonia_1: $i > $i).
% 29.22/29.07  tff(decl_49978, type, fn_liquid_ammonia_3: $i > $i).
% 29.22/29.07  tff(decl_49979, type, "300.0e0": $i).
% 29.22/29.07  tff(decl_49980, type, 'Liquid-Substance': $i).
% 29.22/29.07  tff(decl_49981, type, 'A substance in the liquid state at room temperature': $i).
% 29.22/29.07  tff(decl_49982, type, liquid: $i).
% 29.22/29.07  tff(decl_49983, type, 'substance of liquid': $i).
% 29.22/29.07  tff(decl_49984, type, 'liquid substance': $i).
% 29.22/29.07  tff(decl_49985, type, 'liquid-substance': $i).
% 29.22/29.07  tff(decl_49986, type, lithium_1: $i > $o).
% 29.22/29.07  tff(decl_49987, type, 'Lithium': $i).
% 29.22/29.07  tff(decl_49988, type, 'Lithium is a metal atom with atomic number 3. It is represented by the symbol Li.': $i).
% 29.22/29.07  tff(decl_49989, type, 'Li': $i).
% 29.22/29.07  tff(decl_49990, type, lithium: $i).
% 29.22/29.07  tff(decl_49991, type, fn_lithium_4: $i > $i).
% 29.22/29.07  tff(decl_49992, type, fn_lithium_5: $i > $i).
% 29.22/29.07  tff(decl_49993, type, fn_lithium_6: $i > $i).
% 29.22/29.07  tff(decl_49994, type, fn_lithium_7: $i > $i).
% 29.22/29.07  tff(decl_49995, type, fn_lithium_8: $i > $i).
% 29.22/29.07  tff(decl_49996, type, fn_lithium_9: $i > $i).
% 29.22/29.07  tff(decl_49997, type, fn_lithium_10: $i > $i).
% 29.22/29.07  tff(decl_49998, type, fn_lithium_11: $i > $i).
% 29.22/29.07  tff(decl_49999, type, fn_lithium_12: $i > $i).
% 29.22/29.07  tff(decl_50000, type, fn_lithium_13: $i > $i).
% 29.22/29.07  tff(decl_50001, type, fn_lithium_17: $i > $i).
% 29.22/29.07  tff(decl_50002, type, fn_lithium_19: $i > $i).
% 29.22/29.07  tff(decl_50003, type, "0.98": $i).
% 29.22/29.07  tff(decl_50004, type, "6.941": $i).
% 29.22/29.07  tff(decl_50005, type, fn_lithium_16: $i > $i).
% 29.22/29.07  tff(decl_50006, type, fn_lithium_14: $i > $i).
% 29.22/29.07  tff(decl_50007, type, fn_lithium_18: $i > $i).
% 29.22/29.07  tff(decl_50008, type, fn_lithium_15: $i > $i).
% 29.22/29.07  tff(decl_50009, type, lithops_1: $i > $o).
% 29.22/29.07  tff(decl_50010, type, 'Lithops': $i).
% 29.22/29.07  tff(decl_50011, type, 'Lithops is a genus of perennial plants, also called stone plants.': $i).
% 29.22/29.07  tff(decl_50012, type, lithop: $i).
% 29.22/29.07  tff(decl_50013, type, perennial_1: $i > $o).
% 29.22/29.07  tff(decl_50014, type, fn_lithops_1: $i > $i).
% 29.22/29.07  tff(decl_50015, type, fn_lithops_2: $i > $i).
% 29.22/29.07  tff(decl_50016, type, fn_lithops_3: $i > $i).
% 29.22/29.07  tff(decl_50017, type, fn_lithops_5: $i > $i).
% 29.22/29.07  tff(decl_50018, type, fn_lithops_6: $i > $i).
% 29.22/29.07  tff(decl_50019, type, fn_lithops_7: $i > $i).
% 29.22/29.07  tff(decl_50020, type, fn_lithops_8: $i > $i).
% 29.22/29.07  tff(decl_50021, type, fn_lithops_9: $i > $i).
% 29.22/29.07  tff(decl_50022, type, fn_lithops_10: $i > $i).
% 29.22/29.07  tff(decl_50023, type, fn_lithops_11: $i > $i).
% 29.22/29.07  tff(decl_50024, type, fn_lithops_12: $i > $i).
% 29.22/29.07  tff(decl_50025, type, fn_lithops_13: $i > $i).
% 29.22/29.07  tff(decl_50026, type, fn_lithops_14: $i > $i).
% 29.22/29.07  tff(decl_50027, type, fn_lithops_21: $i > $i).
% 29.22/29.07  tff(decl_50028, type, fn_lithops_22: $i > $i).
% 29.22/29.07  tff(decl_50029, type, fn_lithops_23: $i > $i).
% 29.22/29.07  tff(decl_50030, type, fn_lithops_24: $i > $i).
% 29.22/29.07  tff(decl_50031, type, fn_lithops_25: $i > $i).
% 29.22/29.07  tff(decl_50032, type, fn_lithops_26: $i > $i).
% 29.22/29.07  tff(decl_50033, type, fn_lithops_27: $i > $i).
% 29.22/29.07  tff(decl_50034, type, fn_lithops_28: $i > $i).
% 29.22/29.07  tff(decl_50035, type, fn_lithops_29: $i > $i).
% 29.22/29.07  tff(decl_50036, type, fn_lithops_30: $i > $i).
% 29.22/29.07  tff(decl_50037, type, fn_lithops_31: $i > $i).
% 29.22/29.07  tff(decl_50038, type, fn_lithops_32: $i > $i).
% 29.22/29.07  tff(decl_50039, type, fn_lithops_33: $i > $i).
% 29.22/29.07  tff(decl_50040, type, fn_lithops_34: $i > $i).
% 29.22/29.07  tff(decl_50041, type, fn_lithops_35: $i > $i).
% 29.22/29.07  tff(decl_50042, type, fn_lithops_36: $i > $i).
% 29.22/29.07  tff(decl_50043, type, fn_lithops_37: $i > $i).
% 29.22/29.07  tff(decl_50044, type, fn_lithops_40: $i > $i).
% 29.22/29.07  tff(decl_50045, type, fn_lithops_41: $i > $i).
% 29.22/29.07  tff(decl_50046, type, fn_lithops_42: $i > $i).
% 29.22/29.07  tff(decl_50047, type, fn_lithops_43: $i > $i).
% 29.22/29.07  tff(decl_50048, type, fn_lithops_44: $i > $i).
% 29.22/29.07  tff(decl_50049, type, fn_lithops_45: $i > $i).
% 29.22/29.07  tff(decl_50050, type, fn_lithops_46: $i > $i).
% 29.22/29.07  tff(decl_50051, type, fn_lithops_47: $i > $i).
% 29.22/29.07  tff(decl_50052, type, fn_lithops_48: $i > $i).
% 29.22/29.07  tff(decl_50053, type, fn_lithops_49: $i > $i).
% 29.22/29.07  tff(decl_50054, type, fn_lithops_50: $i > $i).
% 29.22/29.07  tff(decl_50055, type, fn_lithops_51: $i > $i).
% 29.22/29.07  tff(decl_50056, type, fn_lithops_52: $i > $i).
% 29.22/29.07  tff(decl_50057, type, fn_lithops_53: $i > $i).
% 29.22/29.07  tff(decl_50058, type, fn_lithops_54: $i > $i).
% 29.22/29.07  tff(decl_50059, type, fn_lithops_55: $i > $i).
% 29.22/29.07  tff(decl_50060, type, fn_lithops_56: $i > $i).
% 29.22/29.07  tff(decl_50061, type, fn_lithops_57: $i > $i).
% 29.22/29.07  tff(decl_50062, type, fn_lithops_58: $i > $i).
% 29.22/29.07  tff(decl_50063, type, fn_lithops_59: $i > $i).
% 29.22/29.07  tff(decl_50064, type, fn_lithops_60: $i > $i).
% 29.22/29.07  tff(decl_50065, type, fn_lithops_61: $i > $i).
% 29.22/29.07  tff(decl_50066, type, fn_lithops_62: $i > $i).
% 29.22/29.07  tff(decl_50067, type, fn_lithops_63: $i > $i).
% 29.22/29.07  tff(decl_50068, type, fn_lithops_64: $i > $i).
% 29.22/29.07  tff(decl_50069, type, fn_lithops_65: $i > $i).
% 29.22/29.07  tff(decl_50070, type, fn_lithops_66: $i > $i).
% 29.22/29.07  tff(decl_50071, type, fn_lithops_67: $i > $i).
% 29.22/29.07  tff(decl_50072, type, fn_lithops_68: $i > $i).
% 29.22/29.07  tff(decl_50073, type, fn_lithops_69: $i > $i).
% 29.22/29.07  tff(decl_50074, type, fn_root_16: $i > $i).
% 29.22/29.07  tff(decl_50075, type, fn_root_1: $i > $i).
% 29.22/29.07  tff(decl_50076, type, fn_root_15: $i > $i).
% 29.22/29.07  tff(decl_50077, type, fn_root_2: $i > $i).
% 29.22/29.07  tff(decl_50078, type, fn_root_11: $i > $i).
% 29.22/29.07  tff(decl_50079, type, fn_photosynthesis_28: $i > $i).
% 29.22/29.07  tff(decl_50080, type, activity_0: $i).
% 29.22/29.07  tff(decl_50081, type, eukaryotic_cell_structure_0: $i).
% 29.22/29.07  tff(decl_50082, type, fn_succulent_plant_52: $i > $i).
% 29.22/29.07  tff(decl_50083, type, fn_succulent_plant_51: $i > $i).
% 29.22/29.07  tff(decl_50084, type, fn_lithops_39: $i > $i).
% 29.22/29.07  tff(decl_50085, type, fn_lithops_38: $i > $i).
% 29.22/29.07  tff(decl_50086, type, fn_succulent_plant_33: $i > $i).
% 29.22/29.07  tff(decl_50087, type, fn_succulent_plant_32: $i > $i).
% 29.22/29.07  tff(decl_50088, type, fn_succulent_plant_3: $i > $i).
% 29.22/29.07  tff(decl_50089, type, fn_succulent_plant_31: $i > $i).
% 29.22/29.07  tff(decl_50090, type, fn_succulent_plant_4: $i > $i).
% 29.22/29.07  tff(decl_50091, type, fn_succulent_plant_42: $i > $i).
% 29.22/29.07  tff(decl_50092, type, fn_succulent_plant_58: $i > $i).
% 29.22/29.07  tff(decl_50093, type, fn_succulent_plant_1: $i > $i).
% 29.22/29.07  tff(decl_50094, type, fn_succulent_plant_36: $i > $i).
% 29.22/29.07  tff(decl_50095, type, fn_succulent_plant_10: $i > $i).
% 29.22/29.07  tff(decl_50096, type, fn_succulent_plant_24: $i > $i).
% 29.22/29.07  tff(decl_50097, type, fn_succulent_plant_41: $i > $i).
% 29.22/29.07  tff(decl_50098, type, fn_lithops_20: $i > $i).
% 29.22/29.07  tff(decl_50099, type, fn_lithops_19: $i > $i).
% 29.22/29.07  tff(decl_50100, type, fn_lithops_16: $i > $i).
% 29.22/29.07  tff(decl_50101, type, fn_lithops_15: $i > $i).
% 29.22/29.07  tff(decl_50102, type, fn_lithops_18: $i > $i).
% 29.22/29.07  tff(decl_50103, type, fn_lithops_17: $i > $i).
% 29.22/29.07  tff(decl_50104, type, fn_succulent_plant_46: $i > $i).
% 29.22/29.07  tff(decl_50105, type, fn_succulent_plant_44: $i > $i).
% 29.22/29.07  tff(decl_50106, type, fn_succulent_plant_9: $i > $i).
% 29.22/29.07  tff(decl_50107, type, fn_vascular_plant_6: $i > $i).
% 29.22/29.07  tff(decl_50108, type, fn_succulent_plant_43: $i > $i).
% 29.22/29.07  tff(decl_50109, type, fn_succulent_plant_49: $i > $i).
% 29.22/29.07  tff(decl_50110, type, fn_succulent_plant_64: $i > $i).
% 29.22/29.07  tff(decl_50111, type, fn_succulent_plant_50: $i > $i).
% 29.22/29.07  tff(decl_50112, type, fn_succulent_plant_38: $i > $i).
% 29.22/29.07  tff(decl_50113, type, fn_succulent_plant_71: $i > $i).
% 29.22/29.07  tff(decl_50114, type, 'Littoral-Zone': $i).
% 29.22/29.07  tff(decl_50115, type, 'The shallow, well-lit, nearshore waters of a lake.': $i).
% 29.22/29.07  tff(decl_50116, type, 'zone of littoral': $i).
% 29.22/29.07  tff(decl_50117, type, 'littoral zone': $i).
% 29.22/29.07  tff(decl_50118, type, 'littoral-zone': $i).
% 29.22/29.07  tff(decl_50119, type, 'Liver': $i).
% 29.22/29.07  tff(decl_50120, type, 'Large and complicated reddish-brown glandular organ located in the upper right portion of the abdominal cavity; secretes bile and functions in metabolism of protein and carbohydrate and fat; synthesizes substances involved in the clotting of the blood; synthesizes vitamin A; detoxifies poisonous substances and breaks down worn-out erythrocytes': $i).
% 29.22/29.07  tff(decl_50121, type, liver: $i).
% 29.22/29.07  tff(decl_50122, type, fn_liver_1: $i > $i).
% 29.22/29.07  tff(decl_50123, type, fn_liver_2: $i > $i).
% 29.22/29.07  tff(decl_50124, type, fn_liver_3: $i > $i).
% 29.22/29.07  tff(decl_50125, type, fn_liver_4: $i > $i).
% 29.22/29.07  tff(decl_50126, type, fn_liver_5: $i > $i).
% 29.22/29.07  tff(decl_50127, type, fn_liver_6: $i > $i).
% 29.22/29.07  tff(decl_50128, type, fn_liver_7: $i > $i).
% 29.22/29.07  tff(decl_50129, type, fn_liver_8: $i > $i).
% 29.22/29.07  tff(decl_50130, type, fn_liver_9: $i > $i).
% 29.22/29.07  tff(decl_50131, type, fn_liver_10: $i > $i).
% 29.22/29.07  tff(decl_50132, type, fn_liver_11: $i > $i).
% 29.22/29.07  tff(decl_50133, type, fn_liver_12: $i > $i).
% 29.22/29.07  tff(decl_50134, type, 'Liver-Cell': $i).
% 29.22/29.07  tff(decl_50135, type, 'The cells of the liver which is largest gland in the body, and is situated slightly below the diaphragm and to the right of to the stomach.': $i).
% 29.22/29.07  tff(decl_50136, type, 'cell of liver': $i).
% 29.22/29.07  tff(decl_50137, type, 'liver cell': $i).
% 29.22/29.07  tff(decl_50138, type, 'liver-cell': $i).
% 29.22/29.07  tff(decl_50139, type, fn_liver_cell_1: $i > $i).
% 29.22/29.07  tff(decl_50140, type, fn_liver_cell_2: $i > $i).
% 29.22/29.07  tff(decl_50141, type, fn_liver_cell_4: $i > $i).
% 29.22/29.07  tff(decl_50142, type, fn_liver_cell_5: $i > $i).
% 29.22/29.07  tff(decl_50143, type, fn_liver_cell_6: $i > $i).
% 29.22/29.07  tff(decl_50144, type, fn_liver_cell_7: $i > $i).
% 29.22/29.07  tff(decl_50145, type, fn_liver_cell_8: $i > $i).
% 29.22/29.07  tff(decl_50146, type, fn_liver_cell_9: $i > $i).
% 29.22/29.07  tff(decl_50147, type, fn_liver_cell_10: $i > $i).
% 29.22/29.07  tff(decl_50148, type, fn_liver_cell_11: $i > $i).
% 29.22/29.07  tff(decl_50149, type, fn_liver_cell_12: $i > $i).
% 29.22/29.07  tff(decl_50150, type, fn_liver_cell_13: $i > $i).
% 29.22/29.07  tff(decl_50151, type, fn_liver_cell_14: $i > $i).
% 29.22/29.07  tff(decl_50152, type, fn_liver_cell_15: $i > $i).
% 29.22/29.07  tff(decl_50153, type, fn_liver_cell_16: $i > $i).
% 29.22/29.07  tff(decl_50154, type, fn_liver_cell_17: $i > $i).
% 29.22/29.07  tff(decl_50155, type, fn_liver_cell_18: $i > $i).
% 29.22/29.07  tff(decl_50156, type, fn_liver_cell_19: $i > $i).
% 29.22/29.07  tff(decl_50157, type, fn_liver_cell_20: $i > $i).
% 29.22/29.07  tff(decl_50158, type, fn_liver_cell_21: $i > $i).
% 29.22/29.07  tff(decl_50159, type, fn_liver_cell_22: $i > $i).
% 29.22/29.07  tff(decl_50160, type, fn_liver_cell_23: $i > $i).
% 29.22/29.07  tff(decl_50161, type, fn_liver_cell_24: $i > $i).
% 29.22/29.07  tff(decl_50162, type, fn_liver_cell_25: $i > $i).
% 29.22/29.07  tff(decl_50163, type, fn_liver_cell_26: $i > $i).
% 29.22/29.07  tff(decl_50164, type, fn_liver_cell_27: $i > $i).
% 29.22/29.07  tff(decl_50165, type, fn_liver_cell_28: $i > $i).
% 29.22/29.07  tff(decl_50166, type, fn_liver_cell_29: $i > $i).
% 29.22/29.07  tff(decl_50167, type, fn_liver_cell_30: $i > $i).
% 29.22/29.07  tff(decl_50168, type, fn_liver_cell_31: $i > $i).
% 29.22/29.07  tff(decl_50169, type, fn_liver_cell_32: $i > $i).
% 29.22/29.07  tff(decl_50170, type, fn_liver_cell_33: $i > $i).
% 29.22/29.07  tff(decl_50171, type, fn_liver_cell_34: $i > $i).
% 29.22/29.07  tff(decl_50172, type, fn_liver_cell_35: $i > $i).
% 29.22/29.07  tff(decl_50173, type, fn_liver_cell_36: $i > $i).
% 29.22/29.07  tff(decl_50174, type, fn_liver_cell_37: $i > $i).
% 29.22/29.07  tff(decl_50175, type, fn_liver_cell_38: $i > $i).
% 29.22/29.07  tff(decl_50176, type, fn_liver_cell_39: $i > $i).
% 29.22/29.07  tff(decl_50177, type, fn_liver_cell_40: $i > $i).
% 29.22/29.07  tff(decl_50178, type, fn_liver_cell_42: $i > $i).
% 29.22/29.07  tff(decl_50179, type, fn_liver_cell_43: $i > $i).
% 29.22/29.07  tff(decl_50180, type, fn_liver_cell_44: $i > $i).
% 29.22/29.07  tff(decl_50181, type, fn_liver_cell_45: $i > $i).
% 29.22/29.07  tff(decl_50182, type, fn_liver_cell_46: $i > $i).
% 29.22/29.07  tff(decl_50183, type, fn_liver_cell_47: $i > $i).
% 29.22/29.07  tff(decl_50184, type, fn_liver_cell_48: $i > $i).
% 29.22/29.07  tff(decl_50185, type, fn_liver_cell_49: $i > $i).
% 29.22/29.07  tff(decl_50186, type, fn_liver_cell_52: $i > $i).
% 29.22/29.07  tff(decl_50187, type, fn_liver_cell_53: $i > $i).
% 29.22/29.07  tff(decl_50188, type, fn_liver_cell_54: $i > $i).
% 29.22/29.07  tff(decl_50189, type, fn_liver_cell_55: $i > $i).
% 29.22/29.07  tff(decl_50190, type, fn_liver_cell_57: $i > $i).
% 29.22/29.07  tff(decl_50191, type, fn_liver_cell_59: $i > $i).
% 29.22/29.07  tff(decl_50192, type, fn_liver_cell_60: $i > $i).
% 29.22/29.07  tff(decl_50193, type, fn_liver_cell_61: $i > $i).
% 29.22/29.07  tff(decl_50194, type, fn_liver_cell_63: $i > $i).
% 29.22/29.07  tff(decl_50195, type, fn_liver_cell_64: $i > $i).
% 29.22/29.07  tff(decl_50196, type, fn_liver_cell_66: $i > $i).
% 29.22/29.07  tff(decl_50197, type, fn_liver_cell_67: $i > $i).
% 29.22/29.07  tff(decl_50198, type, fn_liver_cell_70: $i > $i).
% 29.22/29.07  tff(decl_50199, type, fn_liver_cell_71: $i > $i).
% 29.22/29.07  tff(decl_50200, type, fn_liver_cell_72: $i > $i).
% 29.22/29.07  tff(decl_50201, type, fn_liver_cell_73: $i > $i).
% 29.22/29.07  tff(decl_50202, type, fn_liver_cell_75: $i > $i).
% 29.22/29.07  tff(decl_50203, type, fn_liver_cell_76: $i > $i).
% 29.22/29.07  tff(decl_50204, type, fn_liver_cell_81: $i > $i).
% 29.22/29.07  tff(decl_50205, type, fn_liver_cell_82: $i > $i).
% 29.22/29.07  tff(decl_50206, type, fn_liver_cell_83: $i > $i).
% 29.22/29.07  tff(decl_50207, type, fn_liver_cell_84: $i > $i).
% 29.22/29.07  tff(decl_50208, type, fn_liver_cell_85: $i > $i).
% 29.22/29.07  tff(decl_50209, type, fn_liver_cell_86: $i > $i).
% 29.22/29.07  tff(decl_50210, type, fn_liver_cell_87: $i > $i).
% 29.22/29.07  tff(decl_50211, type, fn_liver_cell_88: $i > $i).
% 29.22/29.07  tff(decl_50212, type, fn_liver_cell_89: $i > $i).
% 29.22/29.07  tff(decl_50213, type, fn_liver_cell_90: $i > $i).
% 29.22/29.07  tff(decl_50214, type, fn_liver_cell_91: $i > $i).
% 29.22/29.07  tff(decl_50215, type, fn_liver_cell_92: $i > $i).
% 29.22/29.07  tff(decl_50216, type, fn_liver_cell_94: $i > $i).
% 29.22/29.07  tff(decl_50217, type, fn_liver_cell_95: $i > $i).
% 29.22/29.07  tff(decl_50218, type, fn_liver_cell_96: $i > $i).
% 29.22/29.07  tff(decl_50219, type, fn_liver_cell_97: $i > $i).
% 29.22/29.07  tff(decl_50220, type, fn_liver_cell_98: $i > $i).
% 29.22/29.07  tff(decl_50221, type, fn_liver_cell_99: $i > $i).
% 29.22/29.07  tff(decl_50222, type, fn_liver_cell_100: $i > $i).
% 29.22/29.07  tff(decl_50223, type, fn_liver_cell_101: $i > $i).
% 29.22/29.07  tff(decl_50224, type, fn_liver_cell_102: $i > $i).
% 29.22/29.07  tff(decl_50225, type, fn_liver_cell_103: $i > $i).
% 29.22/29.07  tff(decl_50226, type, fn_liver_cell_105: $i > $i).
% 29.22/29.07  tff(decl_50227, type, fn_liver_cell_106: $i > $i).
% 29.22/29.07  tff(decl_50228, type, fn_liver_cell_107: $i > $i).
% 29.22/29.07  tff(decl_50229, type, fn_liver_cell_108: $i > $i).
% 29.22/29.07  tff(decl_50230, type, fn_liver_cell_109: $i > $i).
% 29.22/29.07  tff(decl_50231, type, fn_liver_cell_110: $i > $i).
% 29.22/29.07  tff(decl_50232, type, fn_liver_cell_111: $i > $i).
% 29.22/29.07  tff(decl_50233, type, fn_liver_cell_112: $i > $i).
% 29.22/29.07  tff(decl_50234, type, fn_liver_cell_113: $i > $i).
% 29.22/29.07  tff(decl_50235, type, fn_liver_cell_114: $i > $i).
% 29.22/29.07  tff(decl_50236, type, fn_liver_cell_115: $i > $i).
% 29.22/29.07  tff(decl_50237, type, fn_liver_cell_116: $i > $i).
% 29.22/29.07  tff(decl_50238, type, fn_liver_cell_117: $i > $i).
% 29.22/29.07  tff(decl_50239, type, fn_liver_cell_118: $i > $i).
% 29.22/29.07  tff(decl_50240, type, fn_liver_cell_119: $i > $i).
% 29.22/29.07  tff(decl_50241, type, fn_liver_cell_121: $i > $i).
% 29.22/29.07  tff(decl_50242, type, fn_liver_cell_122: $i > $i).
% 29.22/29.07  tff(decl_50243, type, fn_smooth_endoplasmic_reticulum_4: $i > $i).
% 29.22/29.07  tff(decl_50244, type, fn_smooth_endoplasmic_reticulum_19: $i > $i).
% 29.22/29.07  tff(decl_50245, type, fn_smooth_endoplasmic_reticulum_20: $i > $i).
% 29.22/29.07  tff(decl_50246, type, fn_smooth_endoplasmic_reticulum_21: $i > $i).
% 29.22/29.07  tff(decl_50247, type, fn_smooth_endoplasmic_reticulum_9: $i > $i).
% 29.22/29.07  tff(decl_50248, type, fn_smooth_endoplasmic_reticulum_38: $i > $i).
% 29.22/29.07  tff(decl_50249, type, fn_smooth_endoplasmic_reticulum_6: $i > $i).
% 29.22/29.07  tff(decl_50250, type, fn_peroxisome_29: $i > $i).
% 29.22/29.07  tff(decl_50251, type, fn_rough_endoplasmic_reticulum_17: $i > $i).
% 29.22/29.07  tff(decl_50252, type, fn_storage_polysaccharide_breakdown_2: $i > $i).
% 29.22/29.07  tff(decl_50253, type, fn_smooth_endoplasmic_reticulum_31: $i > $i).
% 29.22/29.07  tff(decl_50254, type, fn_smooth_endoplasmic_reticulum_25: $i > $i).
% 29.22/29.07  tff(decl_50255, type, fn_smooth_endoplasmic_reticulum_29: $i > $i).
% 29.22/29.07  tff(decl_50256, type, fn_rough_endoplasmic_reticulum_24: $i > $i).
% 29.22/29.07  tff(decl_50257, type, fn_rough_endoplasmic_reticulum_20: $i > $i).
% 29.22/29.07  tff(decl_50258, type, fn_rough_endoplasmic_reticulum_87: $i > $i).
% 29.22/29.07  tff(decl_50259, type, fn_rough_endoplasmic_reticulum_19: $i > $i).
% 29.22/29.07  tff(decl_50260, type, fn_liver_cell_120: $i > $i).
% 29.22/29.07  tff(decl_50261, type, liverwort_1: $i > $o).
% 29.22/29.07  tff(decl_50262, type, 'Liverwort': $i).
% 29.22/29.07  tff(decl_50263, type, 'One of a group of small, nonvascular land plants of the phylum Hepatophyta.': $i).
% 29.22/29.07  tff(decl_50264, type, hepatophyta: $i).
% 29.22/29.07  tff(decl_50265, type, hepatophyte: $i).
% 29.22/29.07  tff(decl_50266, type, liverwort: $i).
% 29.22/29.07  tff(decl_50267, type, 'Living-Entity': $i).
% 29.22/29.07  tff(decl_50268, type, 'Any living organism': $i).
% 29.22/29.07  tff(decl_50269, type, benefactive_role: $i).
% 29.22/29.07  tff(decl_50270, type, 'benefactive role': $i).
% 29.22/29.07  tff(decl_50271, type, beneficiary: $i).
% 29.22/29.07  tff(decl_50272, type, 'living thing': $i).
% 29.22/29.07  tff(decl_50273, type, living_thing: $i).
% 29.22/29.07  tff(decl_50274, type, 'animate thing': $i).
% 29.22/29.07  tff(decl_50275, type, animate_thing: $i).
% 29.22/29.07  tff(decl_50276, type, 'entity of living': $i).
% 29.22/29.07  tff(decl_50277, type, 'living entity': $i).
% 29.22/29.07  tff(decl_50278, type, 'living-entity': $i).
% 29.22/29.07  tff(decl_50279, type, lizard_1: $i > $o).
% 29.22/29.07  tff(decl_50280, type, 'Lizard': $i).
% 29.22/29.07  tff(decl_50281, type, 'A large group of squamate reptiles, inhabiting all continents except Antarctica. Unlike the other major group of squamates, snakes, reptiles have feet and external ears.': $i).
% 29.22/29.07  tff(decl_50282, type, lizard: $i).
% 29.22/29.07  tff(decl_50283, type, 'Load': $i).
% 29.22/29.07  tff(decl_50284, type, load: $i).
% 29.22/29.07  tff(decl_50285, type, lade: $i).
% 29.22/29.07  tff(decl_50286, type, laden: $i).
% 29.22/29.07  tff(decl_50287, type, 'load up': $i).
% 29.22/29.07  tff(decl_50288, type, load_up: $i).
% 29.22/29.07  tff(decl_50289, type, stow: $i).
% 29.22/29.07  tff(decl_50290, type, fn_load_1: $i > $i).
% 29.22/29.07  tff(decl_50291, type, loading_of_sugar_into_sieve_tube_element_1: $i > $o).
% 29.22/29.07  tff(decl_50292, type, 'Loading-Of-Sugar-Into-Sieve-Tube-Element': $i).
% 29.22/29.07  tff(decl_50293, type, 'It involves the loading of sugar into sieve tube elements of phloem in leaf during the process of translocation of phloem sap.': $i).
% 29.22/29.07  tff(decl_50294, type, 'loading of sugar into sieve tube element': $i).
% 29.22/29.07  tff(decl_50295, type, 'loading-of-sugar-into-sieve-tube-element': $i).
% 29.22/29.07  tff(decl_50296, type, fn_loading_of_sugar_into_sieve_tube_element_3: $i > $i).
% 29.22/29.07  tff(decl_50297, type, fn_loading_of_sugar_into_sieve_tube_element_4: $i > $i).
% 29.22/29.07  tff(decl_50298, type, fn_loading_of_sugar_into_sieve_tube_element_5: $i > $i).
% 29.22/29.07  tff(decl_50299, type, fn_loading_of_sugar_into_sieve_tube_element_6: $i > $i).
% 29.22/29.07  tff(decl_50300, type, fn_loading_of_sugar_into_sieve_tube_element_7: $i > $i).
% 29.22/29.07  tff(decl_50301, type, fn_loading_of_sugar_into_sieve_tube_element_8: $i > $i).
% 29.22/29.07  tff(decl_50302, type, fn_loading_of_sugar_into_sieve_tube_element_9: $i > $i).
% 29.22/29.07  tff(decl_50303, type, fn_loading_of_sugar_into_sieve_tube_element_10: $i > $i).
% 29.22/29.07  tff(decl_50304, type, fn_loading_of_sugar_into_sieve_tube_element_11: $i > $i).
% 29.22/29.07  tff(decl_50305, type, symplastic_transport_1: $i > $o).
% 29.22/29.07  tff(decl_50306, type, fn_loading_of_sugar_into_sieve_tube_element_12: $i > $i).
% 29.22/29.07  tff(decl_50307, type, fn_loading_of_sugar_into_sieve_tube_element_13: $i > $i).
% 29.22/29.07  tff(decl_50308, type, fn_loading_of_sugar_into_sieve_tube_element_14: $i > $i).
% 29.22/29.07  tff(decl_50309, type, fn_loading_of_sugar_into_sieve_tube_element_15: $i > $i).
% 29.22/29.07  tff(decl_50310, type, fn_loading_of_sugar_into_sieve_tube_element_16: $i > $i).
% 29.22/29.07  tff(decl_50311, type, fn_symplastic_transport_2: $i > $i).
% 29.22/29.07  tff(decl_50312, type, cotransport_0: $i).
% 29.22/29.07  tff(decl_50313, type, 'Loam': $i).
% 29.22/29.07  tff(decl_50314, type, 'The most fertile type of soil, consisting of approximately equal proportions of clay, sand, and silt.': $i).
% 29.22/29.07  tff(decl_50315, type, loam: $i).
% 29.22/29.07  tff(decl_50316, type, 'Lobe': $i).
% 29.22/29.07  tff(decl_50317, type, 'Rounded, projecting section of an organ.': $i).
% 29.22/29.07  tff(decl_50318, type, lobe: $i).
% 29.22/29.07  tff(decl_50319, type, 'Lobe-Fin-Fish': $i).
% 29.22/29.07  tff(decl_50320, type, 'Fish of the clade Sarcopterygii, whose pectoral and pelvic fins are muscular and supported by bony extensions of the skeleton.': $i).
% 29.22/29.07  tff(decl_50321, type, actinistia: $i).
% 29.22/29.07  tff(decl_50322, type, 'lobe fin fish': $i).
% 29.22/29.07  tff(decl_50323, type, 'lobe-fin-fish': $i).
% 29.22/29.07  tff(decl_50324, type, 'Local-Biogeochemical-Cycle': $i).
% 29.22/29.07  tff(decl_50325, type, 'Biogeochemical cycle which cycles chemicals through biotic and abiotic components of ecosystems on a local scale. Chemicals which naturally exist in solid form (such as phosphorus and calcium) cycle locally.': $i).
% 29.22/29.07  tff(decl_50326, type, 'undergo the local biogeochemical cycle': $i).
% 29.22/29.07  tff(decl_50327, type, 'local biogeochemical cycle': $i).
% 29.22/29.07  tff(decl_50328, type, 'local-biogeochemical-cycle': $i).
% 29.22/29.07  tff(decl_50329, type, fn_local_biogeochemical_cycle_1: $i > $i).
% 29.22/29.07  tff(decl_50330, type, 'Local-Cell-Communication': $i).
% 29.22/29.07  tff(decl_50331, type, 'Occurs when local regulators, messenger molecules that travel only short distances, target cells within the immediate vicinity of the signaling cell.': $i).
% 29.22/29.07  tff(decl_50332, type, 'communicate over a short distance': $i).
% 29.22/29.07  tff(decl_50333, type, 'local cell communication': $i).
% 29.22/29.07  tff(decl_50334, type, 'local-cell-communication': $i).
% 29.22/29.07  tff(decl_50335, type, fn_local_cell_communication_2: $i > $i).
% 29.22/29.07  tff(decl_50336, type, long_distance_cell_communication_0: $i).
% 29.22/29.07  tff(decl_50337, type, 'Local-Regulator': $i).
% 29.22/29.07  tff(decl_50338, type, 'A chemical signal that influences only neighboring cells.': $i).
% 29.22/29.07  tff(decl_50339, type, 'regulator of local': $i).
% 29.22/29.07  tff(decl_50340, type, 'local regulator': $i).
% 29.22/29.07  tff(decl_50341, type, 'local-regulator': $i).
% 29.22/29.07  tff(decl_50342, type, fn_local_regulator_1: $i > $i).
% 29.22/29.07  tff(decl_50343, type, 'Locomotion': $i).
% 29.22/29.07  tff(decl_50344, type, locomotion: $i).
% 29.22/29.07  tff(decl_50345, type, locomotion_as_macrophysiological_process_1: $i > $o).
% 29.22/29.07  tff(decl_50346, type, 'Locomotion-As-Macrophysiological-Process': $i).
% 29.22/29.07  tff(decl_50347, type, 'Active motion from one place to another.': $i).
% 29.22/29.07  tff(decl_50348, type, 'locomotion as macrophysiological process': $i).
% 29.22/29.07  tff(decl_50349, type, 'locomotion-as-macrophysiological-process': $i).
% 29.22/29.07  tff(decl_50350, type, locomotion_of_eukaryotic_cell_by_flagellum_1: $i > $o).
% 29.22/29.07  tff(decl_50351, type, 'Locomotion-Of-Eukaryotic-Cell-By-Flagellum': $i).
% 29.22/29.07  tff(decl_50352, type, 'Locomotion, usually swimming, of a eukaryotic cell by means of a beating flagellum.  Most animals have sperm that use flagella for locomotion.': $i).
% 29.22/29.07  tff(decl_50353, type, 'locomotion of eukaryotic cell by flagellum': $i).
% 29.22/29.07  tff(decl_50354, type, 'locomotion-of-eukaryotic-cell-by-flagellum': $i).
% 29.22/29.07  tff(decl_50355, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_1: $i > $i).
% 29.22/29.07  tff(decl_50356, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_2: $i > $i).
% 29.22/29.07  tff(decl_50357, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_3: $i > $i).
% 29.22/29.07  tff(decl_50358, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_4: $i > $i).
% 29.22/29.07  tff(decl_50359, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_5: $i > $i).
% 29.22/29.07  tff(decl_50360, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_6: $i > $i).
% 29.22/29.07  tff(decl_50361, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_7: $i > $i).
% 29.22/29.07  tff(decl_50362, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_8: $i > $i).
% 29.22/29.07  tff(decl_50363, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_9: $i > $i).
% 29.22/29.07  tff(decl_50364, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_10: $i > $i).
% 29.22/29.07  tff(decl_50365, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_11: $i > $i).
% 29.22/29.07  tff(decl_50366, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_12: $i > $i).
% 29.22/29.07  tff(decl_50367, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_13: $i > $i).
% 29.22/29.07  tff(decl_50368, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_14: $i > $i).
% 29.22/29.07  tff(decl_50369, type, fn_locomotion_of_eukaryotic_cell_by_flagellum_15: $i > $i).
% 29.22/29.07  tff(decl_50370, type, locomotion_of_eukaryotic_cell_by_motile_cilium_1: $i > $o).
% 29.22/29.07  tff(decl_50371, type, 'Locomotion-Of-Eukaryotic-Cell-By-Motile-Cilium': $i).
% 29.22/29.07  tff(decl_50372, type, 'Locomotion, usually swimming, of a eukaryotic cell by means of motile cilia. A protozoan ciliate is an example of a eukaryotic cell that uses cilia for locomotion.': $i).
% 29.22/29.07  tff(decl_50373, type, 'locomotion of eukaryotic cell by motile cilium': $i).
% 29.22/29.07  tff(decl_50374, type, 'locomotion-of-eukaryotic-cell-by-motile-cilium': $i).
% 29.22/29.07  tff(decl_50375, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_1: $i > $i).
% 29.22/29.07  tff(decl_50376, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_2: $i > $i).
% 29.22/29.07  tff(decl_50377, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_3: $i > $i).
% 29.22/29.07  tff(decl_50378, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_4: $i > $i).
% 29.22/29.07  tff(decl_50379, type, motile_cilium_1: $i > $o).
% 29.22/29.07  tff(decl_50380, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_5: $i > $i).
% 29.22/29.07  tff(decl_50381, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_6: $i > $i).
% 29.22/29.07  tff(decl_50382, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_7: $i > $i).
% 29.22/29.07  tff(decl_50383, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_8: $i > $i).
% 29.22/29.07  tff(decl_50384, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_9: $i > $i).
% 29.22/29.07  tff(decl_50385, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_10: $i > $i).
% 29.22/29.07  tff(decl_50386, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_11: $i > $i).
% 29.22/29.07  tff(decl_50387, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_12: $i > $i).
% 29.22/29.07  tff(decl_50388, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_13: $i > $i).
% 29.22/29.07  tff(decl_50389, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_14: $i > $i).
% 29.22/29.07  tff(decl_50390, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_15: $i > $i).
% 29.22/29.07  tff(decl_50391, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_16: $i > $i).
% 29.22/29.07  tff(decl_50392, type, fn_locomotion_of_eukaryotic_cell_by_motile_cilium_17: $i > $i).
% 29.22/29.07  tff(decl_50393, type, fn_motile_cilium_14: $i > $i).
% 29.22/29.07  tff(decl_50394, type, fn_motile_cilium_7: $i > $i).
% 29.22/29.07  tff(decl_50395, type, fn_motile_cilium_15: $i > $i).
% 29.22/29.07  tff(decl_50396, type, fn_motile_cilium_13: $i > $i).
% 29.22/29.07  tff(decl_50397, type, fn_motile_cilium_8: $i > $i).
% 29.22/29.07  tff(decl_50398, type, fn_motile_cilium_17: $i > $i).
% 29.22/29.07  tff(decl_50399, type, fn_motile_cilium_16: $i > $i).
% 29.22/29.07  tff(decl_50400, type, fn_motile_cilium_19: $i > $i).
% 29.22/29.07  tff(decl_50401, type, fn_motile_cilium_18: $i > $i).
% 29.22/29.07  tff(decl_50402, type, fn_motile_cilium_10: $i > $i).
% 29.22/29.07  tff(decl_50403, type, 'Locomotor-Cell': $i).
% 29.22/29.07  tff(decl_50404, type, 'Cells with motile cilia or flagella that act as appendages that move the cell from one place to another or when attached to cells that are held in place, motile cilia and flagella can move fluid over the surface of the tissue.': $i).
% 29.22/29.07  tff(decl_50405, type, 'locomotor cell': $i).
% 29.22/29.07  tff(decl_50406, type, 'locomotor-cell': $i).
% 29.22/29.07  tff(decl_50407, type, 'Locus': $i).
% 29.22/29.07  tff(decl_50408, type, 'A specific place along the length of a chromosome where a given gene is located.': $i).
% 29.22/29.07  tff(decl_50409, type, loci: $i).
% 29.22/29.07  tff(decl_50410, type, locus: $i).
% 29.22/29.07  tff(decl_50411, type, 'Logging': $i).
% 29.22/29.07  tff(decl_50412, type, 'Any process in which selected trees are removed from a forested or wooded area. Also refers to the act of removing such trees.': $i).
% 29.22/29.07  tff(decl_50413, type, log: $i).
% 29.22/29.07  tff(decl_50414, type, logging: $i).
% 29.22/29.07  tff(decl_50415, type, 'Logistic-Population-Growth': $i).
% 29.22/29.07  tff(decl_50416, type, 'A model of population growth in which the rate of growth is slow at low population size, increases as population size increases, then decreases again as the population size approaches carrying capacity.': $i).
% 29.22/29.07  tff(decl_50417, type, 'logistic population growth': $i).
% 29.22/29.07  tff(decl_50418, type, 'logistic-population-growth': $i).
% 29.22/29.07  tff(decl_50419, type, long_day_plant_1: $i > $o).
% 29.22/29.07  tff(decl_50420, type, 'Long-Day-Plant': $i).
% 29.22/29.07  tff(decl_50421, type, 'A plant that flowers (usually in late spring or early summer) only when the light period is longer than a critical length.': $i).
% 29.22/29.07  tff(decl_50422, type, 'long day plant': $i).
% 29.22/29.07  tff(decl_50423, type, 'long-day-plant': $i).
% 29.22/29.07  tff(decl_50424, type, long_distance_between_genes_1: $i > $o).
% 29.22/29.07  tff(decl_50425, type, 'Long-Distance-Between-Genes': $i).
% 29.22/29.07  tff(decl_50426, type, 'In genetic mapping, a long distance between genes implies that they are unlinked or on separate chromosomes.': $i).
% 29.22/29.07  tff(decl_50427, type, 'long distance between gene': $i).
% 29.22/29.07  tff(decl_50428, type, 'long-distance-between-gene': $i).
% 29.22/29.07  tff(decl_50429, type, fn_long_distance_between_genes_1: $i > $i).
% 29.22/29.07  tff(decl_50430, type, 'Long-Distance-Cell-Communication': $i).
% 29.22/29.07  tff(decl_50431, type, 'Transmission of a chemical stimulus, a hormone, from one cell to another cell in a distant part of the organism.': $i).
% 29.22/29.07  tff(decl_50432, type, 'communicate over a long distance': $i).
% 29.22/29.07  tff(decl_50433, type, 'long distance cell communication': $i).
% 29.22/29.07  tff(decl_50434, type, 'long-distance-cell-communication': $i).
% 29.22/29.07  tff(decl_50435, type, fn_long_distance_cell_communication_2: $i > $i).
% 29.22/29.07  tff(decl_50436, type, local_cell_communication_0: $i).
% 29.22/29.07  tff(decl_50437, type, long_term_memory_1: $i > $o).
% 29.22/29.07  tff(decl_50438, type, 'Long-Term-Memory': $i).
% 29.22/29.07  tff(decl_50439, type, 'The ability to retain and recall information over a lifetime.': $i).
% 29.22/29.07  tff(decl_50440, type, 'long term memory': $i).
% 29.22/29.07  tff(decl_50441, type, 'long-term-memory': $i).
% 29.22/29.07  tff(decl_50442, type, memory_1: $i > $o).
% 29.22/29.07  tff(decl_50443, type, short_term_memory_1: $i > $o).
% 29.22/29.07  tff(decl_50444, type, long_term_potentiation_1: $i > $o).
% 29.22/29.07  tff(decl_50445, type, 'Long-Term-Potentiation': $i).
% 29.22/29.07  tff(decl_50446, type, 'An enhanced responsiveness to action potentials by a postsynaptic cell.': $i).
% 29.22/29.07  tff(decl_50447, type, ltp: $i).
% 29.22/29.07  tff(decl_50448, type, 'long term potentiation': $i).
% 29.22/29.07  tff(decl_50449, type, 'long-term-potentiation': $i).
% 29.22/29.07  tff(decl_50450, type, longitude_constant_1: $i > $o).
% 29.22/29.07  tff(decl_50451, type, 'Longitude-Constant': $i).
% 29.22/29.07  tff(decl_50452, type, 'constant of longitude': $i).
% 29.22/29.07  tff(decl_50453, type, 'longitude constant': $i).
% 29.22/29.07  tff(decl_50454, type, 'longitude-constant': $i).
% 29.22/29.07  tff(decl_50455, type, 'Loop-Of-Henle': $i).
% 29.22/29.07  tff(decl_50456, type, 'The portion of a nephron between the proximal and distal tubules. The loop of Henle extends into the medulla of the kidney, makes a hairpin turn, and returns to the cortex. It resorbs water and salts from the forming urine.': $i).
% 29.22/29.07  tff(decl_50457, type, 'loop of henle': $i).
% 29.22/29.07  tff(decl_50458, type, 'loop-of-henle': $i).
% 29.22/29.07  tff(decl_50459, type, 'Looped-Domains': $i).
% 29.22/29.07  tff(decl_50460, type, 'A looped domain is one level DNA coiling and packing which occurs in a condensed eukaryotic chromosome. Looped domains can be observed at the scale of 300nm where the DNA molecule attaches to a protein scaffold composed in part of  topoisomerase and H1 molecules': $i).
% 29.22/29.07  tff(decl_50461, type, 'looped domains': $i).
% 29.22/29.07  tff(decl_50462, type, 'looped domain': $i).
% 29.22/29.07  tff(decl_50463, type, 'looped-domain': $i).
% 29.22/29.07  tff(decl_50464, type, fn_looped_domains_2: $i > $i).
% 29.22/29.07  tff(decl_50465, type, fn_looped_domains_3: $i > $i).
% 29.22/29.07  tff(decl_50466, type, fn_looped_domains_4: $i > $i).
% 29.22/29.07  tff(decl_50467, type, fn_looped_domains_6: $i > $i).
% 29.22/29.07  tff(decl_50468, type, fn_looped_domains_7: $i > $i).
% 29.22/29.07  tff(decl_50469, type, fn_looped_domains_8: $i > $i).
% 29.22/29.07  tff(decl_50470, type, fn_looped_domains_12: $i > $i).
% 29.22/29.07  tff(decl_50471, type, fn_looped_domains_13: $i > $i).
% 29.22/29.07  tff(decl_50472, type, fn_looped_domains_14: $i > $i).
% 29.22/29.07  tff(decl_50473, type, fn_looped_domains_15: $i > $i).
% 29.22/29.07  tff(decl_50474, type, 'Loose-Connective-Tissue': $i).
% 29.22/29.07  tff(decl_50475, type, 'The most common type of connective tissue in vertebrates. Loose connective tissue holds organs in place and surrounds blood vessels and neurons.': $i).
% 29.22/29.07  tff(decl_50476, type, 'loose connective tissue': $i).
% 29.22/29.07  tff(decl_50477, type, 'loose-connective-tissue': $i).
% 29.22/29.07  tff(decl_50478, type, lophophore_1: $i > $o).
% 29.22/29.07  tff(decl_50479, type, 'Lophophore': $i).
% 29.22/29.07  tff(decl_50480, type, 'In some animals of the clade Lophotrochozoa, a ring of ciliated, coelomate tentacles surrounding the mouth and used for filter feeding.': $i).
% 29.22/29.07  tff(decl_50481, type, 'crown of ciliated tentacles': $i).
% 29.22/29.07  tff(decl_50482, type, lophophore: $i).
% 29.22/29.07  tff(decl_50483, type, 'Lophotrochozoan': $i).
% 29.22/29.07  tff(decl_50484, type, 'Member of the clade Lophotrochozoa, which consists of several animal phyla grouped together by shared molecular characteristics. Lophotrochozoans include animals with a lophophore or a trochophore larva.': $i).
% 29.22/29.07  tff(decl_50485, type, lophotrochozoa: $i).
% 29.22/29.07  tff(decl_50486, type, lophotrochozoan: $i).
% 29.22/29.07  tff(decl_50487, type, 'Lose': $i).
% 29.22/29.07  tff(decl_50488, type, 'Loser': $i).
% 29.22/29.07  tff(decl_50489, type, loser: $i).
% 29.22/29.07  tff(decl_50490, type, 'also ran': $i).
% 29.22/29.07  tff(decl_50491, type, 'also-ran': $i).
% 29.22/29.07  tff(decl_50492, type, loss_of_energy_by_electron_1: $i > $o).
% 29.22/29.07  tff(decl_50493, type, 'Loss-Of-Energy-By-Electron': $i).
% 29.22/29.07  tff(decl_50494, type, 'loss of energy by electron': $i).
% 29.22/29.07  tff(decl_50495, type, 'loss-of-energy-by-electron': $i).
% 29.22/29.07  tff(decl_50496, type, fn_loss_of_energy_by_electron_1: $i > $i).
% 29.22/29.07  tff(decl_50497, type, fn_loss_of_energy_by_electron_2: $i > $i).
% 29.22/29.07  tff(decl_50498, type, fn_loss_of_energy_by_electron_3: $i > $i).
% 29.22/29.07  tff(decl_50499, type, fn_loss_of_energy_by_electron_5: $i > $i).
% 29.22/29.07  tff(decl_50500, type, fn_loss_of_energy_by_electron_6: $i > $i).
% 29.22/29.07  tff(decl_50501, type, fn_loss_of_energy_by_electron_12: $i > $i).
% 29.22/29.07  tff(decl_50502, type, fn_loss_of_energy_by_electron_13: $i > $i).
% 29.22/29.07  tff(decl_50503, type, fn_loss_of_energy_by_electron_14: $i > $i).
% 29.22/29.07  tff(decl_50504, type, fn_loss_of_energy_by_electron_15: $i > $i).
% 29.22/29.07  tff(decl_50505, type, fn_loss_of_energy_by_electron_16: $i > $i).
% 29.22/29.07  tff(decl_50506, type, 'EnergyLost': $i).
% 29.22/29.07  tff(decl_50507, type, fn_loss_of_energy_by_electron_11: $i > $i).
% 29.22/29.07  tff(decl_50508, type, louis_pasteur_1: $i > $o).
% 29.22/29.07  tff(decl_50509, type, 'Louis-Pasteur': $i).
% 29.22/29.07  tff(decl_50510, type, 'Scientist who developed the process of pasteurization, after studying microbes and the impact of temperature and pressure on their populations.': $i).
% 29.22/29.07  tff(decl_50511, type, 'pasteur of louis': $i).
% 29.22/29.07  tff(decl_50512, type, 'louis pasteur': $i).
% 29.22/29.07  tff(decl_50513, type, 'louis-pasteur': $i).
% 29.22/29.07  tff(decl_50514, type, fn_louis_pasteur_1: $i > $i).
% 29.22/29.07  tff(decl_50515, type, fn_louis_pasteur_2: $i > $i).
% 29.22/29.07  tff(decl_50516, type, fn_louis_pasteur_3: $i > $i).
% 29.22/29.07  tff(decl_50517, type, 'Low-Density-Lipoprotein': $i).
% 29.22/29.07  tff(decl_50518, type, 'One of five groups of lipoproteins that allow lipids such as triglycerides and cholesterol to be transported in the aqueous environment of blood. High levels of LDL are associated with cardiovascular disease.': $i).
% 29.22/29.07  tff(decl_50519, type, ldl: $i).
% 29.22/29.07  tff(decl_50520, type, 'low density lipoprotein': $i).
% 29.22/29.07  tff(decl_50521, type, 'low-density-lipoprotein': $i).
% 29.22/29.07  tff(decl_50522, type, 'Lumen': $i).
% 29.22/29.07  tff(decl_50523, type, 'A space within a tubular organ or organelle.': $i).
% 29.22/29.07  tff(decl_50524, type, lumen: $i).
% 29.22/29.07  tff(decl_50525, type, luminance_constant_1: $i > $o).
% 29.22/29.07  tff(decl_50526, type, 'Luminance-Constant': $i).
% 29.22/29.07  tff(decl_50527, type, 'constant of luminance': $i).
% 29.22/29.07  tff(decl_50528, type, 'luminance constant': $i).
% 29.22/29.07  tff(decl_50529, type, 'luminance-constant': $i).
% 29.22/29.07  tff(decl_50530, type, 'Luminance-Value': $i).
% 29.22/29.07  tff(decl_50531, type, 'the quality of being luminous, emitting or reflecting light': $i).
% 29.22/29.07  tff(decl_50532, type, 'value of luminance': $i).
% 29.22/29.07  tff(decl_50533, type, 'luminance value': $i).
% 29.22/29.07  tff(decl_50534, type, 'luminance-value': $i).
% 29.22/29.07  tff(decl_50535, type, luminous_flux_constant_1: $i > $o).
% 29.22/29.07  tff(decl_50536, type, 'Luminous-Flux-Constant': $i).
% 29.22/29.07  tff(decl_50537, type, 'luminous flux constant': $i).
% 29.22/29.07  tff(decl_50538, type, 'luminous-flux-constant': $i).
% 29.22/29.07  tff(decl_50539, type, 'Luminous-Flux-Value': $i).
% 29.22/29.07  tff(decl_50540, type, 'the rate of flow of light energy': $i).
% 29.22/29.07  tff(decl_50541, type, 'luminous flux': $i).
% 29.22/29.07  tff(decl_50542, type, 'luminous-flux': $i).
% 29.22/29.07  tff(decl_50543, type, 'luminous flux value': $i).
% 29.22/29.07  tff(decl_50544, type, 'luminous-flux-value': $i).
% 29.22/29.07  tff(decl_50545, type, luminous_intensity_constant_1: $i > $o).
% 29.22/29.07  tff(decl_50546, type, 'Luminous-Intensity-Constant': $i).
% 29.22/29.07  tff(decl_50547, type, 'luminous intensity constant': $i).
% 29.22/29.07  tff(decl_50548, type, 'luminous-intensity-constant': $i).
% 29.22/29.07  tff(decl_50549, type, 'Luminous-Intensity-Value': $i).
% 29.22/29.07  tff(decl_50550, type, 'a measure of luminous intensity': $i).
% 29.22/29.07  tff(decl_50551, type, 'luminous intensity unit': $i).
% 29.22/29.07  tff(decl_50552, type, 'candlepower unit': $i).
% 29.22/29.07  tff(decl_50553, type, 'luminous intensity': $i).
% 29.22/29.07  tff(decl_50554, type, 'luminous-intensity': $i).
% 29.22/29.07  tff(decl_50555, type, 'luminous intensity value': $i).
% 29.22/29.07  tff(decl_50556, type, 'luminous-intensity-value': $i).
% 29.22/29.07  tff(decl_50557, type, 'Lunch': $i).
% 29.22/29.07  tff(decl_50558, type, lunch: $i).
% 29.22/29.07  tff(decl_50559, type, luncheon: $i).
% 29.22/29.07  tff(decl_50560, type, tiffin: $i).
% 29.22/29.07  tff(decl_50561, type, dejeuner: $i).
% 29.22/29.07  tff(decl_50562, type, 'Lung': $i).
% 29.22/29.07  tff(decl_50563, type, 'An infolded respiratory surface found in animals that breathe air, such as terrestrial vertebrates, pulmonate gastropods, and spiders. The internalized structure is connected to the outside by tubes through which air passes.': $i).
% 29.22/29.07  tff(decl_50564, type, lung: $i).
% 29.22/29.07  tff(decl_50565, type, fn_lung_2: $i > $i).
% 29.22/29.07  tff(decl_50566, type, fn_lung_3: $i > $i).
% 29.22/29.07  tff(decl_50567, type, lungfish_1: $i > $o).
% 29.22/29.07  tff(decl_50568, type, 'Lungfish': $i).
% 29.22/29.07  tff(decl_50569, type, 'A freshwater fish that has lungs and can breathe air.': $i).
% 29.22/29.07  tff(decl_50570, type, salamanderfish: $i).
% 29.22/29.07  tff(decl_50571, type, 'salamander fish': $i).
% 29.22/29.07  tff(decl_50572, type, 'salamander-fish': $i).
% 29.22/29.07  tff(decl_50573, type, lungfish: $i).
% 29.22/29.07  tff(decl_50574, type, 'Lupus': $i).
% 29.22/29.07  tff(decl_50575, type, 'A systemic autoimmune disease in which the immune system attacks the body\\s own tissue, resulting in chronic inflammation and tissue damage. Symptoms can occur in many body organs and tissues, including joints, skin, heart, and lungs.': $i).
% 29.22/29.07  tff(decl_50576, type, 'systemic lupus erythematosus': $i).
% 29.22/29.07  tff(decl_50577, type, 'systemic-lupus-erythematosus': $i).
% 29.22/29.07  tff(decl_50578, type, lupus: $i).
% 29.22/29.07  tff(decl_50579, type, luteal_phase_1: $i > $o).
% 29.22/29.07  tff(decl_50580, type, 'Luteal-Phase': $i).
% 29.22/29.07  tff(decl_50581, type, 'The latter part of the ovarian cycle when the corpus luteum secretes progesterone.': $i).
% 29.22/29.07  tff(decl_50582, type, 'luteal phase': $i).
% 29.22/29.07  tff(decl_50583, type, 'luteal-phase': $i).
% 29.22/29.07  tff(decl_50584, type, proliferative_phase_1: $i > $o).
% 29.22/29.07  tff(decl_50585, type, lutetium_1: $i > $o).
% 29.22/29.07  tff(decl_50586, type, 'Lutetium': $i).
% 29.22/29.07  tff(decl_50587, type, 'Lutetium is a metal atom with atomic number 71. It is represented by the symbol Lu.': $i).
% 29.22/29.07  tff(decl_50588, type, lutetium: $i).
% 29.22/29.07  tff(decl_50589, type, 'Lu': $i).
% 29.22/29.07  tff(decl_50590, type, fn_lutetium_4: $i > $i).
% 29.22/29.07  tff(decl_50591, type, fn_lutetium_5: $i > $i).
% 29.22/29.07  tff(decl_50592, type, fn_lutetium_6: $i > $i).
% 29.22/29.07  tff(decl_50593, type, fn_lutetium_7: $i > $i).
% 29.22/29.07  tff(decl_50594, type, fn_lutetium_11: $i > $i).
% 29.22/29.07  tff(decl_50595, type, fn_lutetium_12: $i > $i).
% 29.22/29.07  tff(decl_50596, type, fn_lutetium_13: $i > $i).
% 29.22/29.07  tff(decl_50597, type, fn_lutetium_14: $i > $i).
% 29.22/29.07  tff(decl_50598, type, "104": $i).
% 29.22/29.07  tff(decl_50599, type, "1.27": $i).
% 29.22/29.07  tff(decl_50600, type, "175": $i).
% 29.22/29.07  tff(decl_50601, type, fn_lutetium_9: $i > $i).
% 29.22/29.07  tff(decl_50602, type, fn_lutetium_10: $i > $i).
% 29.22/29.07  tff(decl_50603, type, fn_lutetium_8: $i > $i).
% 29.22/29.07  tff(decl_50604, type, 'Lyase': $i).
% 29.22/29.07  tff(decl_50605, type, 'Enzymes which  cleave various bonds by means other than hydrolysis and oxidation': $i).
% 29.22/29.07  tff(decl_50606, type, lyase: $i).
% 29.22/29.07  tff(decl_50607, type, lycophyta_1: $i > $o).
% 29.22/29.07  tff(decl_50608, type, 'Lycophyta': $i).
% 29.22/29.07  tff(decl_50609, type, 'The oldest extant lineage of vascular plants, going back to about 410 million years.': $i).
% 29.22/29.07  tff(decl_50610, type, lycophyta: $i).
% 29.22/29.07  tff(decl_50611, type, progymnosperm_1: $i > $o).
% 29.22/29.07  tff(decl_50612, type, pterophyte_1: $i > $o).
% 29.22/29.07  tff(decl_50613, type, lycophyte_1: $i > $o).
% 29.22/29.07  tff(decl_50614, type, 'Lycophyte': $i).
% 29.22/29.07  tff(decl_50615, type, 'Member of the phylum Lycophyta, including quillworts and club mosses.': $i).
% 29.22/29.07  tff(decl_50616, type, 'club moss': $i).
% 29.22/29.07  tff(decl_50617, type, 'club-moss': $i).
% 29.22/29.07  tff(decl_50618, type, 'spike moss': $i).
% 29.22/29.07  tff(decl_50619, type, 'spike-moss': $i).
% 29.22/29.07  tff(decl_50620, type, lycopodiphyta: $i).
% 29.22/29.07  tff(decl_50621, type, lycopods: $i).
% 29.22/29.07  tff(decl_50622, type, lycophyte: $i).
% 29.22/29.07  tff(decl_50623, type, 'Lyme-Disease': $i).
% 29.22/29.07  tff(decl_50624, type, 'An infectious disease caused by  the bacterial genus Borrelia and trasmitted to humans through tick bites.': $i).
% 29.22/29.07  tff(decl_50625, type, 'lyme borreliosis': $i).
% 29.22/29.07  tff(decl_50626, type, 'lyme-borreliosis': $i).
% 29.22/29.07  tff(decl_50627, type, 'lyme disease': $i).
% 29.22/29.07  tff(decl_50628, type, 'lyme-disease': $i).
% 29.22/29.07  tff(decl_50629, type, 'Lymph': $i).
% 29.22/29.07  tff(decl_50630, type, 'The fluid circulated by the lymphatic system. It is derived from interstitial fluid.': $i).
% 29.22/29.07  tff(decl_50631, type, lymph: $i).
% 29.22/29.07  tff(decl_50632, type, lymph_node_1: $i > $o).
% 29.22/29.07  tff(decl_50633, type, 'Lymph-Node': $i).
% 29.22/29.07  tff(decl_50634, type, 'An organ of the immune system, located in various parts of the body and connected by the lymphatic vessels. Lymph nodes filter and trap pathogens from lymph and, when swollen and hard, indicate an infection.': $i).
% 29.22/29.07  tff(decl_50635, type, 'node of lymph': $i).
% 29.22/29.07  tff(decl_50636, type, 'lymph node': $i).
% 29.22/29.07  tff(decl_50637, type, 'lymph-node': $i).
% 29.22/29.07  tff(decl_50638, type, lymph_vessel_1: $i > $o).
% 29.22/29.07  tff(decl_50639, type, 'Lymph-Vessel': $i).
% 29.22/29.07  tff(decl_50640, type, 'The part of the circulatory that carries lymph through out the body.': $i).
% 29.22/29.07  tff(decl_50641, type, 'vessel of lymph': $i).
% 29.22/29.07  tff(decl_50642, type, 'lymph vessel': $i).
% 29.22/29.07  tff(decl_50643, type, 'lymph-vessel': $i).
% 29.22/29.07  tff(decl_50644, type, fn_lymph_vessel_3: $i > $i).
% 29.22/29.07  tff(decl_50645, type, fn_lymph_vessel_4: $i > $i).
% 29.22/29.07  tff(decl_50646, type, fn_lymph_vessel_5: $i > $i).
% 29.22/29.07  tff(decl_50647, type, fn_lymph_vessel_6: $i > $i).
% 29.22/29.07  tff(decl_50648, type, fn_lymph_vessel_7: $i > $i).
% 29.22/29.07  tff(decl_50649, type, fn_lymph_vessel_8: $i > $i).
% 29.22/29.07  tff(decl_50650, type, secondary_cell_wall_1: $i > $o).
% 29.22/29.07  tff(decl_50651, type, lymphatic_system_1: $i > $o).
% 29.22/29.07  tff(decl_50652, type, 'Lymphatic-System': $i).
% 29.22/29.07  tff(decl_50653, type, 'A system of vessels and notes that runs parallel to the circulatory system. The lymphatic system functions in immunity and returns lost fluid to blood.': $i).
% 29.22/29.07  tff(decl_50654, type, 'lymphatic system': $i).
% 29.22/29.07  tff(decl_50655, type, 'lymphatic-system': $i).
% 29.22/29.07  tff(decl_50656, type, fn_lymphatic_system_1: $i > $i).
% 29.22/29.07  tff(decl_50657, type, 'Lymphatic-Tissue': $i).
% 29.22/29.07  tff(decl_50658, type, 'Tissues of the lymphatic system.': $i).
% 29.22/29.07  tff(decl_50659, type, 'lymphatic tissue': $i).
% 29.22/29.07  tff(decl_50660, type, 'lymphatic-tissue': $i).
% 29.22/29.07  tff(decl_50661, type, 'Lymphocyte': $i).
% 29.22/29.07  tff(decl_50662, type, 'A type of white blood cell in the vertebrate immune system. The three major types of lymphocytes (T cells, B cells, and natural killer cells) are involved in the acquired immune response.': $i).
% 29.22/29.07  tff(decl_50663, type, lymphocyte: $i).
% 29.22/29.07  tff(decl_50664, type, 'Lyse': $i).
% 29.22/29.07  tff(decl_50665, type, 'To cause or produce disintegration of a compound, substance or cell plasma membrane.': $i).
% 29.22/29.07  tff(decl_50666, type, lysis: $i).
% 29.22/29.07  tff(decl_50667, type, lyse: $i).
% 29.22/29.07  tff(decl_50668, type, 'Lysine': $i).
% 29.22/29.07  tff(decl_50669, type, lysine: $i).
% 29.22/29.07  tff(decl_50670, type, fn_lysine_1: $i > $i).
% 29.22/29.07  tff(decl_50671, type, fn_lysine_2: $i > $i).
% 29.22/29.07  tff(decl_50672, type, fn_lysine_3: $i > $i).
% 29.22/29.07  tff(decl_50673, type, fn_lysine_4: $i > $i).
% 29.22/29.07  tff(decl_50674, type, fn_lysine_5: $i > $i).
% 29.22/29.07  tff(decl_50675, type, fn_lysine_6: $i > $i).
% 29.22/29.07  tff(decl_50676, type, fn_lysine_7: $i > $i).
% 29.22/29.07  tff(decl_50677, type, fn_lysine_8: $i > $i).
% 29.22/29.07  tff(decl_50678, type, fn_lysine_9: $i > $i).
% 29.22/29.07  tff(decl_50679, type, fn_lysine_10: $i > $i).
% 29.22/29.07  tff(decl_50680, type, fn_lysine_11: $i > $i).
% 29.22/29.07  tff(decl_50681, type, fn_lysine_12: $i > $i).
% 29.22/29.07  tff(decl_50682, type, fn_lysine_13: $i > $i).
% 29.22/29.07  tff(decl_50683, type, fn_lysine_14: $i > $i).
% 29.22/29.07  tff(decl_50684, type, fn_lysine_15: $i > $i).
% 29.22/29.07  tff(decl_50685, type, fn_lysine_16: $i > $i).
% 29.22/29.07  tff(decl_50686, type, fn_lysine_17: $i > $i).
% 29.22/29.07  tff(decl_50687, type, fn_lysine_18: $i > $i).
% 29.22/29.07  tff(decl_50688, type, fn_lysine_19: $i > $i).
% 29.22/29.07  tff(decl_50689, type, fn_lysine_20: $i > $i).
% 29.22/29.07  tff(decl_50690, type, fn_lysine_21: $i > $i).
% 29.22/29.07  tff(decl_50691, type, fn_lysine_22: $i > $i).
% 29.22/29.07  tff(decl_50692, type, fn_lysine_23: $i > $i).
% 29.22/29.07  tff(decl_50693, type, fn_lysine_24: $i > $i).
% 29.22/29.07  tff(decl_50694, type, fn_lysine_25: $i > $i).
% 29.22/29.07  tff(decl_50695, type, fn_lysine_26: $i > $i).
% 29.22/29.07  tff(decl_50696, type, fn_lysine_27: $i > $i).
% 29.22/29.07  tff(decl_50697, type, fn_lysine_28: $i > $i).
% 29.22/29.07  tff(decl_50698, type, fn_lysine_29: $i > $i).
% 29.22/29.07  tff(decl_50699, type, fn_lysine_30: $i > $i).
% 29.22/29.07  tff(decl_50700, type, fn_lysine_31: $i > $i).
% 29.22/29.07  tff(decl_50701, type, fn_lysine_32: $i > $i).
% 29.22/29.07  tff(decl_50702, type, fn_lysine_33: $i > $i).
% 29.22/29.07  tff(decl_50703, type, fn_lysine_34: $i > $i).
% 29.22/29.07  tff(decl_50704, type, fn_lysine_35: $i > $i).
% 29.22/29.07  tff(decl_50705, type, fn_lysine_36: $i > $i).
% 29.22/29.07  tff(decl_50706, type, fn_lysine_37: $i > $i).
% 29.22/29.07  tff(decl_50707, type, fn_lysine_38: $i > $i).
% 29.22/29.07  tff(decl_50708, type, fn_lysine_39: $i > $i).
% 29.22/29.07  tff(decl_50709, type, fn_lysine_40: $i > $i).
% 29.22/29.07  tff(decl_50710, type, fn_lysine_41: $i > $i).
% 29.22/29.07  tff(decl_50711, type, fn_lysine_42: $i > $i).
% 29.22/29.07  tff(decl_50712, type, fn_lysine_43: $i > $i).
% 29.22/29.07  tff(decl_50713, type, fn_lysine_44: $i > $i).
% 29.22/29.07  tff(decl_50714, type, lysogenic_cycle_1: $i > $o).
% 29.22/29.07  tff(decl_50715, type, 'Lysogenic-Cycle': $i).
% 29.22/29.07  tff(decl_50716, type, 'A type of phage reproductive cycle in which the viral genome becomes incorporated into the bacterial host chromosome as a prophage and does not kill the host.': $i).
% 29.22/29.07  tff(decl_50717, type, 'undergo the lysogenic cycle': $i).
% 29.22/29.07  tff(decl_50718, type, 'lysogenic cycle': $i).
% 29.22/29.07  tff(decl_50719, type, 'lysogenic-cycle': $i).
% 29.22/29.07  tff(decl_50720, type, lytic_cycle_1: $i > $o).
% 29.22/29.07  tff(decl_50721, type, fn_lysogenic_cycle_1: $i > $i).
% 29.22/29.07  tff(decl_50722, type, fn_lysogenic_cycle_2: $i > $i).
% 29.22/29.07  tff(decl_50723, type, synthesis_of_dna_strand_1: $i > $o).
% 29.22/29.07  tff(decl_50724, type, fn_lysogenic_cycle_3: $i > $i).
% 29.22/29.07  tff(decl_50725, type, fn_lysogenic_cycle_4: $i > $i).
% 29.22/29.07  tff(decl_50726, type, fn_lysogenic_cycle_5: $i > $i).
% 29.22/29.07  tff(decl_50727, type, temperate_phage_1: $i > $o).
% 29.22/29.07  tff(decl_50728, type, fn_lysogenic_cycle_6: $i > $i).
% 29.22/29.07  tff(decl_50729, type, fn_lysogenic_cycle_7: $i > $i).
% 29.22/29.07  tff(decl_50730, type, fn_lysogenic_cycle_8: $i > $i).
% 29.22/29.07  tff(decl_50731, type, prophage_1: $i > $o).
% 29.22/29.07  tff(decl_50732, type, fn_lysogenic_cycle_9: $i > $i).
% 29.22/29.07  tff(decl_50733, type, fn_lysogenic_cycle_10: $i > $i).
% 29.22/29.07  tff(decl_50734, type, fn_lysogenic_cycle_11: $i > $i).
% 29.22/29.07  tff(decl_50735, type, fn_lysogenic_cycle_12: $i > $i).
% 29.22/29.07  tff(decl_50736, type, fn_lysogenic_cycle_13: $i > $i).
% 29.22/29.07  tff(decl_50737, type, fn_lysogenic_cycle_14: $i > $i).
% 29.22/29.07  tff(decl_50738, type, fn_lysogenic_cycle_15: $i > $i).
% 29.22/29.07  tff(decl_50739, type, fn_lysogenic_cycle_16: $i > $i).
% 29.22/29.07  tff(decl_50740, type, fn_lysogenic_cycle_17: $i > $i).
% 29.22/29.07  tff(decl_50741, type, fn_lysogenic_cycle_18: $i > $i).
% 29.22/29.07  tff(decl_50742, type, fn_lysogenic_cycle_19: $i > $i).
% 29.22/29.07  tff(decl_50743, type, fn_lysogenic_cycle_20: $i > $i).
% 29.22/29.07  tff(decl_50744, type, lysosomal_disorder_1: $i > $o).
% 29.22/29.07  tff(decl_50745, type, 'Lysosomal-Disorder': $i).
% 29.22/29.07  tff(decl_50746, type, 'Lysosomal disorder is a group of approximately 40 rare inherited metabolic disorders that result from defects in lysosomal function': $i).
% 29.22/29.07  tff(decl_50747, type, 'lysosomal disorder': $i).
% 29.22/29.07  tff(decl_50748, type, 'lysosomal-disorder': $i).
% 29.22/29.07  tff(decl_50749, type, 'Lysosomal-Enzyme': $i).
% 29.22/29.07  tff(decl_50750, type, 'Lysosomal enzymes are synthesized in the cytosol and the endoplasmic reticulum. Some important lysosomal enzymes include lipase, carbohydrase, proteases, nucleases and phosphoric acid': $i).
% 29.22/29.07  tff(decl_50751, type, 'enzyme in lysosome': $i).
% 29.22/29.07  tff(decl_50752, type, 'lysosomal enzyme': $i).
% 29.22/29.07  tff(decl_50753, type, 'lysosomal-enzyme': $i).
% 29.22/29.07  tff(decl_50754, type, fn_lysosomal_enzyme_5: $i > $i).
% 29.22/29.07  tff(decl_50755, type, fn_lysosomal_enzyme_6: $i > $i).
% 29.22/29.07  tff(decl_50756, type, fn_lysosomal_enzyme_7: $i > $i).
% 29.22/29.07  tff(decl_50757, type, fn_lysosomal_enzyme_8: $i > $i).
% 29.22/29.07  tff(decl_50758, type, fn_lysosomal_enzyme_9: $i > $i).
% 29.22/29.07  tff(decl_50759, type, fn_lysosomal_enzyme_10: $i > $i).
% 29.22/29.07  tff(decl_50760, type, fn_lysosomal_enzyme_11: $i > $i).
% 29.22/29.07  tff(decl_50761, type, fn_lysosomal_enzyme_12: $i > $i).
% 29.22/29.07  tff(decl_50762, type, fn_lysosomal_enzyme_13: $i > $i).
% 29.22/29.07  tff(decl_50763, type, fn_lysosomal_enzyme_14: $i > $i).
% 29.22/29.07  tff(decl_50764, type, fn_lysosomal_enzyme_15: $i > $i).
% 29.22/29.07  tff(decl_50765, type, fn_lysosomal_enzyme_16: $i > $i).
% 29.22/29.07  tff(decl_50766, type, fn_lysosomal_enzyme_19: $i > $i).
% 29.22/29.07  tff(decl_50767, type, fn_lysosomal_enzyme_20: $i > $i).
% 29.22/29.07  tff(decl_50768, type, fn_lysosomal_enzyme_21: $i > $i).
% 29.22/29.07  tff(decl_50769, type, fn_lysosomal_enzyme_22: $i > $i).
% 29.22/29.07  tff(decl_50770, type, fn_lysosomal_enzyme_23: $i > $i).
% 29.22/29.07  tff(decl_50771, type, fn_lysosomal_enzyme_24: $i > $i).
% 29.22/29.07  tff(decl_50772, type, fn_lysosomal_enzyme_2: $i > $i).
% 29.22/29.07  tff(decl_50773, type, fn_lysosomal_enzyme_3: $i > $i).
% 29.22/29.07  tff(decl_50774, type, fn_lysosomal_enzyme_4: $i > $i).
% 29.22/29.07  tff(decl_50775, type, 'Lysosomal-membrane': $i).
% 29.22/29.07  tff(decl_50776, type, 'The lysosomal membrane maintains low internal pH by pumping hydrogen ions from the cytosol into the lumen of the lysosome': $i).
% 29.22/29.07  tff(decl_50777, type, 'lysosomal envelope': $i).
% 29.22/29.07  tff(decl_50778, type, 'lysosomal membrane': $i).
% 29.22/29.07  tff(decl_50779, type, 'lysosomal-membrane': $i).
% 29.22/29.07  tff(decl_50780, type, fn_lysosomal_membrane_1: $i > $i).
% 29.22/29.07  tff(decl_50781, type, fn_lysosomal_membrane_4: $i > $i).
% 29.22/29.07  tff(decl_50782, type, fn_lysosomal_membrane_5: $i > $i).
% 29.22/29.07  tff(decl_50783, type, fn_lysosomal_membrane_8: $i > $i).
% 29.22/29.07  tff(decl_50784, type, fn_lysosomal_membrane_9: $i > $i).
% 29.22/29.07  tff(decl_50785, type, fn_lysosomal_membrane_10: $i > $i).
% 29.22/29.07  tff(decl_50786, type, fn_lysosomal_membrane_11: $i > $i).
% 29.22/29.07  tff(decl_50787, type, fn_lysosomal_membrane_12: $i > $i).
% 29.22/29.07  tff(decl_50788, type, fn_lysosomal_membrane_13: $i > $i).
% 29.22/29.07  tff(decl_50789, type, fn_lysosomal_membrane_14: $i > $i).
% 29.22/29.07  tff(decl_50790, type, fn_lysosomal_membrane_15: $i > $i).
% 29.22/29.07  tff(decl_50791, type, fn_lysosomal_membrane_16: $i > $i).
% 29.22/29.07  tff(decl_50792, type, fn_lysosomal_membrane_17: $i > $i).
% 29.22/29.07  tff(decl_50793, type, fn_lysosomal_membrane_18: $i > $i).
% 29.22/29.07  tff(decl_50794, type, fn_lysosomal_membrane_19: $i > $i).
% 29.22/29.07  tff(decl_50795, type, fn_lysosomal_membrane_20: $i > $i).
% 29.22/29.07  tff(decl_50796, type, fn_lysosomal_membrane_21: $i > $i).
% 29.22/29.07  tff(decl_50797, type, fn_lysosomal_membrane_22: $i > $i).
% 29.22/29.07  tff(decl_50798, type, fn_lysosomal_membrane_23: $i > $i).
% 29.22/29.07  tff(decl_50799, type, fn_lysosomal_membrane_24: $i > $i).
% 29.22/29.07  tff(decl_50800, type, fn_lysosomal_membrane_25: $i > $i).
% 29.22/29.07  tff(decl_50801, type, fn_lysosomal_membrane_26: $i > $i).
% 29.22/29.07  tff(decl_50802, type, fn_lysosomal_membrane_27: $i > $i).
% 29.22/29.07  tff(decl_50803, type, fn_lysosomal_membrane_28: $i > $i).
% 29.22/29.07  tff(decl_50804, type, fn_lysosomal_membrane_29: $i > $i).
% 29.22/29.07  tff(decl_50805, type, fn_lysosomal_membrane_30: $i > $i).
% 29.22/29.07  tff(decl_50806, type, fn_lysosomal_membrane_31: $i > $i).
% 29.22/29.07  tff(decl_50807, type, fn_lysosomal_membrane_32: $i > $i).
% 29.22/29.07  tff(decl_50808, type, fn_lysosomal_membrane_33: $i > $i).
% 29.22/29.07  tff(decl_50809, type, fn_lysosomal_membrane_34: $i > $i).
% 29.22/29.07  tff(decl_50810, type, fn_lysosomal_membrane_35: $i > $i).
% 29.22/29.07  tff(decl_50811, type, fn_lysosomal_membrane_36: $i > $i).
% 29.22/29.07  tff(decl_50812, type, fn_lysosomal_membrane_37: $i > $i).
% 29.22/29.07  tff(decl_50813, type, fn_lysosomal_membrane_38: $i > $i).
% 29.22/29.07  tff(decl_50814, type, fn_lysosomal_membrane_39: $i > $i).
% 29.22/29.07  tff(decl_50815, type, fn_lysosomal_membrane_40: $i > $i).
% 29.22/29.07  tff(decl_50816, type, fn_lysosomal_membrane_41: $i > $i).
% 29.22/29.07  tff(decl_50817, type, fn_lysosomal_membrane_42: $i > $i).
% 29.22/29.07  tff(decl_50818, type, fn_lysosomal_membrane_43: $i > $i).
% 29.22/29.07  tff(decl_50819, type, fn_lysosomal_membrane_44: $i > $i).
% 29.22/29.07  tff(decl_50820, type, fn_lysosomal_membrane_45: $i > $i).
% 29.22/29.07  tff(decl_50821, type, fn_lysosomal_membrane_46: $i > $i).
% 29.22/29.07  tff(decl_50822, type, fn_lysosomal_membrane_47: $i > $i).
% 29.22/29.07  tff(decl_50823, type, fn_lysosomal_membrane_48: $i > $i).
% 29.22/29.07  tff(decl_50824, type, fn_lysosomal_membrane_51: $i > $i).
% 29.22/29.07  tff(decl_50825, type, fn_lysosomal_membrane_52: $i > $i).
% 29.22/29.07  tff(decl_50826, type, fn_lysosomal_membrane_53: $i > $i).
% 29.22/29.07  tff(decl_50827, type, fn_lysosomal_membrane_54: $i > $i).
% 29.22/29.07  tff(decl_50828, type, fn_lysosomal_membrane_55: $i > $i).
% 29.22/29.07  tff(decl_50829, type, fn_lysosomal_membrane_56: $i > $i).
% 29.22/29.07  tff(decl_50830, type, fn_lysosomal_membrane_57: $i > $i).
% 29.22/29.07  tff(decl_50831, type, fn_lysosomal_membrane_58: $i > $i).
% 29.22/29.07  tff(decl_50832, type, fn_lysosomal_membrane_59: $i > $i).
% 29.22/29.07  tff(decl_50833, type, fn_lysosomal_membrane_60: $i > $i).
% 29.22/29.07  tff(decl_50834, type, fn_lysosomal_membrane_61: $i > $i).
% 29.22/29.07  tff(decl_50835, type, fn_lysosomal_membrane_62: $i > $i).
% 29.22/29.07  tff(decl_50836, type, fn_lysosomal_membrane_63: $i > $i).
% 29.22/29.07  tff(decl_50837, type, fn_lysosomal_membrane_64: $i > $i).
% 29.22/29.07  tff(decl_50838, type, fn_lysosomal_membrane_65: $i > $i).
% 29.22/29.07  tff(decl_50839, type, fn_lysosomal_membrane_66: $i > $i).
% 29.22/29.07  tff(decl_50840, type, fn_lysosomal_membrane_67: $i > $i).
% 29.22/29.07  tff(decl_50841, type, fn_rough_endoplasmic_reticulum_29: $i > $i).
% 29.22/29.07  tff(decl_50842, type, fn_synthesis_of_membrane_protein_20: $i > $i).
% 29.22/29.07  tff(decl_50843, type, fn_synthesis_of_membrane_protein_17: $i > $i).
% 29.22/29.07  tff(decl_50844, type, fn_rough_endoplasmic_reticulum_57: $i > $i).
% 29.22/29.07  tff(decl_50845, type, fn_rough_endoplasmic_reticulum_40: $i > $i).
% 29.22/29.07  tff(decl_50846, type, fn_rough_endoplasmic_reticulum_8: $i > $i).
% 29.22/29.07  tff(decl_50847, type, fn_synthesis_of_membrane_protein_19: $i > $i).
% 29.22/29.07  tff(decl_50848, type, fn_phospholipid_bilayer_25: $i > $i).
% 29.22/29.07  tff(decl_50849, type, fn_lysosomal_membrane_3: $i > $i).
% 29.22/29.07  tff(decl_50850, type, fn_biomembrane_38: $i > $i).
% 29.22/29.07  tff(decl_50851, type, fn_lysosomal_membrane_7: $i > $i).
% 29.22/29.07  tff(decl_50852, type, fn_lysosomal_membrane_68: $i > $i).
% 29.22/29.07  tff(decl_50853, type, fn_lysosomal_membrane_2: $i > $i).
% 29.22/29.07  tff(decl_50854, type, fn_biomembrane_37: $i > $i).
% 29.22/29.07  tff(decl_50855, type, fn_lysosomal_membrane_50: $i > $i).
% 29.22/29.07  tff(decl_50856, type, fn_lysosomal_membrane_49: $i > $i).
% 29.22/29.07  tff(decl_50857, type, fn_lysosomal_membrane_69: $i > $i).
% 29.22/29.07  tff(decl_50858, type, 'Lysosome': $i).
% 29.22/29.07  tff(decl_50859, type, 'Lysosomes are organelles containing digestive enzymes.They break down the food so it is easier to digest. They are found in animal cells, while in plant cells the same roles are performed by the vacuole. Lysosome has an acidic pH of about 5, which is the optimum pH for hydrolytic (lysosomal) enzymes': $i).
% 29.22/29.07  tff(decl_50860, type, lysosome: $i).
% 29.22/29.07  tff(decl_50861, type, fn_lysosome_1: $i > $i).
% 29.22/29.07  tff(decl_50862, type, fn_lysosome_2: $i > $i).
% 29.22/29.07  tff(decl_50863, type, fn_lysosome_3: $i > $i).
% 29.22/29.07  tff(decl_50864, type, fn_lysosome_5: $i > $i).
% 29.22/29.07  tff(decl_50865, type, fn_lysosome_6: $i > $i).
% 29.22/29.07  tff(decl_50866, type, fn_lysosome_7: $i > $i).
% 29.22/29.07  tff(decl_50867, type, fn_lysosome_8: $i > $i).
% 29.22/29.07  tff(decl_50868, type, fn_lysosome_9: $i > $i).
% 29.22/29.07  tff(decl_50869, type, fn_lysosome_10: $i > $i).
% 29.22/29.07  tff(decl_50870, type, fn_lysosome_11: $i > $i).
% 29.22/29.07  tff(decl_50871, type, fn_lysosome_12: $i > $i).
% 29.22/29.07  tff(decl_50872, type, fn_lysosome_13: $i > $i).
% 29.22/29.07  tff(decl_50873, type, fn_lysosome_14: $i > $i).
% 29.22/29.07  tff(decl_50874, type, fn_lysosome_15: $i > $i).
% 29.22/29.07  tff(decl_50875, type, fn_lysosome_16: $i > $i).
% 29.22/29.07  tff(decl_50876, type, fn_lysosome_17: $i > $i).
% 29.22/29.07  tff(decl_50877, type, fn_lysosome_18: $i > $i).
% 29.22/29.07  tff(decl_50878, type, fn_send_1: $i > $i).
% 29.22/29.07  tff(decl_50879, type, fn_send_3: $i > $i).
% 29.22/29.07  tff(decl_50880, type, lysozyme_1: $i > $o).
% 29.22/29.07  tff(decl_50881, type, 'Lysozyme': $i).
% 29.22/29.07  tff(decl_50882, type, 'An enzyme found in various body fluids (sweat, tears, blood) that attacks the peptidoglycan cell walls of bacteria. Lysozyme is a component of innate immunity.': $i).
% 29.22/29.07  tff(decl_50883, type, muramidase: $i).
% 29.22/29.07  tff(decl_50884, type, 'n acetylmuramide glycanhydrolase': $i).
% 29.22/29.07  tff(decl_50885, type, 'n-acetylmuramide-glycanhydrolase': $i).
% 29.22/29.07  tff(decl_50886, type, lysozyme: $i).
% 29.22/29.07  tff(decl_50887, type, fn_lysozyme_1: $i > $i).
% 29.22/29.07  tff(decl_50888, type, fn_lysozyme_2: $i > $i).
% 29.22/29.07  tff(decl_50889, type, fn_lysozyme_3: $i > $i).
% 29.22/29.07  tff(decl_50890, type, fn_lysozyme_4: $i > $i).
% 29.22/29.07  tff(decl_50891, type, fn_lysozyme_5: $i > $i).
% 29.22/29.07  tff(decl_50892, type, fn_lysozyme_6: $i > $i).
% 29.22/29.07  tff(decl_50893, type, fn_lysozyme_7: $i > $i).
% 29.22/29.07  tff(decl_50894, type, fn_lysozyme_8: $i > $i).
% 29.22/29.07  tff(decl_50895, type, fn_lysozyme_9: $i > $i).
% 29.22/29.07  tff(decl_50896, type, fn_lysozyme_10: $i > $i).
% 29.22/29.07  tff(decl_50897, type, fn_lysozyme_11: $i > $i).
% 29.22/29.07  tff(decl_50898, type, fn_lysozyme_12: $i > $i).
% 29.22/29.07  tff(decl_50899, type, fn_lysozyme_13: $i > $i).
% 29.22/29.07  tff(decl_50900, type, fn_lysozyme_14: $i > $i).
% 29.22/29.07  tff(decl_50901, type, fn_lysozyme_15: $i > $i).
% 29.22/29.07  tff(decl_50902, type, fn_lysozyme_16: $i > $i).
% 29.22/29.07  tff(decl_50903, type, fn_lysozyme_17: $i > $i).
% 29.22/29.07  tff(decl_50904, type, fn_lysozyme_18: $i > $i).
% 29.22/29.07  tff(decl_50905, type, fn_lysozyme_19: $i > $i).
% 29.22/29.07  tff(decl_50906, type, fn_lysozyme_20: $i > $i).
% 29.22/29.07  tff(decl_50907, type, fn_lysozyme_21: $i > $i).
% 29.22/29.07  tff(decl_50908, type, fn_lysozyme_22: $i > $i).
% 29.22/29.07  tff(decl_50909, type, fn_lysozyme_23: $i > $i).
% 29.22/29.07  tff(decl_50910, type, fn_lysozyme_24: $i > $i).
% 29.22/29.07  tff(decl_50911, type, fn_lysozyme_25: $i > $i).
% 29.22/29.07  tff(decl_50912, type, fn_lysozyme_26: $i > $i).
% 29.22/29.07  tff(decl_50913, type, 'Lytic-Cycle': $i).
% 29.22/29.07  tff(decl_50914, type, 'A type of phage reproductive cycle resulting in the release of new phages by lysis (and death) of the host cell.': $i).
% 29.22/29.07  tff(decl_50915, type, 'undergo the lytic cycle': $i).
% 29.22/29.07  tff(decl_50916, type, 'lytic cycle': $i).
% 29.22/29.07  tff(decl_50917, type, 'lytic-cycle': $i).
% 29.22/29.07  tff(decl_50918, type, fn_lytic_cycle_1: $i > $i).
% 29.22/29.07  tff(decl_50919, type, fn_lytic_cycle_2: $i > $i).
% 29.22/29.07  tff(decl_50920, type, fn_lytic_cycle_3: $i > $i).
% 29.22/29.07  tff(decl_50921, type, fn_lytic_cycle_4: $i > $i).
% 29.22/29.07  tff(decl_50922, type, fn_lytic_cycle_5: $i > $i).
% 29.22/29.07  tff(decl_50923, type, fn_lytic_cycle_6: $i > $i).
% 29.22/29.07  tff(decl_50924, type, fn_lytic_cycle_7: $i > $i).
% 29.22/29.07  tff(decl_50925, type, fn_lytic_cycle_8: $i > $i).
% 29.22/29.07  tff(decl_50926, type, fn_lytic_cycle_9: $i > $i).
% 29.22/29.07  tff(decl_50927, type, fn_lytic_cycle_10: $i > $i).
% 29.22/29.07  tff(decl_50928, type, fn_lytic_cycle_11: $i > $i).
% 29.22/29.07  tff(decl_50929, type, fn_lytic_cycle_12: $i > $i).
% 29.22/29.07  tff(decl_50930, type, fn_lytic_cycle_13: $i > $i).
% 29.22/29.07  tff(decl_50931, type, fn_lytic_cycle_14: $i > $i).
% 29.22/29.07  tff(decl_50932, type, fn_lytic_cycle_15: $i > $i).
% 29.22/29.07  tff(decl_50933, type, fn_lytic_cycle_16: $i > $i).
% 29.22/29.07  tff(decl_50934, type, fn_lytic_cycle_17: $i > $i).
% 29.22/29.07  tff(decl_50935, type, fn_lytic_cycle_18: $i > $i).
% 29.22/29.07  tff(decl_50936, type, phage_0: $i).
% 29.22/29.07  tff(decl_50937, type, 'M-Phase': $i).
% 29.22/29.07  tff(decl_50938, type, 'Mitotic phase is the cell division phase. It comprises of Mitosis and cytokinesis (separation of cytoplasm to form two daughter cells)': $i).
% 29.22/29.07  tff(decl_50939, type, 'm phase': $i).
% 29.22/29.07  tff(decl_50940, type, 'm-phase': $i).
% 29.22/29.07  tff(decl_50941, type, 'undergo mitotic phase': $i).
% 29.22/29.07  tff(decl_50942, type, 'mitotic phase': $i).
% 29.22/29.07  tff(decl_50943, type, 'mitotic-phase': $i).
% 29.22/29.07  tff(decl_50944, type, 'phase of m': $i).
% 29.22/29.07  tff(decl_50945, type, fn_m_phase_3: $i > $i).
% 29.22/29.07  tff(decl_50946, type, fn_m_phase_4: $i > $i).
% 29.22/29.07  tff(decl_50947, type, fn_m_phase_5: $i > $i).
% 29.22/29.07  tff(decl_50948, type, fn_m_phase_7: $i > $i).
% 29.22/29.07  tff(decl_50949, type, fn_m_phase_8: $i > $i).
% 29.22/29.07  tff(decl_50950, type, fn_m_phase_9: $i > $i).
% 29.22/29.07  tff(decl_50951, type, fn_m_phase_10: $i > $i).
% 29.22/29.07  tff(decl_50952, type, fn_m_phase_12: $i > $i).
% 29.22/29.07  tff(decl_50953, type, fn_m_phase_13: $i > $i).
% 29.22/29.07  tff(decl_50954, type, fn_m_phase_14: $i > $i).
% 29.22/29.07  tff(decl_50955, type, fn_m_phase_15: $i > $i).
% 29.22/29.07  tff(decl_50956, type, fn_m_phase_16: $i > $i).
% 29.22/29.07  tff(decl_50957, type, fn_m_phase_17: $i > $i).
% 29.22/29.07  tff(decl_50958, type, fn_m_phase_24: $i > $i).
% 29.22/29.07  tff(decl_50959, type, fn_m_phase_25: $i > $i).
% 29.22/29.07  tff(decl_50960, type, fn_m_phase_27: $i > $i).
% 29.22/29.07  tff(decl_50961, type, fn_m_phase_28: $i > $i).
% 29.22/29.07  tff(decl_50962, type, fn_m_phase_29: $i > $i).
% 29.22/29.07  tff(decl_50963, type, fn_m_phase_30: $i > $i).
% 29.22/29.07  tff(decl_50964, type, fn_m_phase_31: $i > $i).
% 29.22/29.07  tff(decl_50965, type, fn_m_phase_32: $i > $i).
% 29.22/29.07  tff(decl_50966, type, fn_m_phase_33: $i > $i).
% 29.22/29.07  tff(decl_50967, type, fn_m_phase_34: $i > $i).
% 29.22/29.07  tff(decl_50968, type, fn_m_phase_35: $i > $i).
% 29.22/29.07  tff(decl_50969, type, fn_m_phase_36: $i > $i).
% 29.22/29.07  tff(decl_50970, type, fn_m_phase_37: $i > $i).
% 29.22/29.07  tff(decl_50971, type, fn_m_phase_41: $i > $i).
% 29.22/29.07  tff(decl_50972, type, fn_mitosis_40: $i > $i).
% 29.22/29.07  tff(decl_50973, type, fn_mitosis_54: $i > $i).
% 29.22/29.07  tff(decl_50974, type, fn_m_phase_39: $i > $i).
% 29.22/29.07  tff(decl_50975, type, fn_m_phase_38: $i > $i).
% 29.22/29.07  tff(decl_50976, type, m_phase_checkpoint_1: $i > $o).
% 29.22/29.07  tff(decl_50977, type, 'M-Phase-Checkpoint': $i).
% 29.22/29.07  tff(decl_50978, type, 'Checkpoint in the regulation of the cell cycle which occurs between the G2 and M phases of the cycle.': $i).
% 29.22/29.07  tff(decl_50979, type, 'm phase checkpoint': $i).
% 29.22/29.07  tff(decl_50980, type, 'm-phase-checkpoint': $i).
% 29.22/29.07  tff(decl_50981, type, macroclimate_1: $i > $o).
% 29.22/29.07  tff(decl_50982, type, 'Macroclimate': $i).
% 29.22/29.07  tff(decl_50983, type, 'The climate of a relatively large geographic area.': $i).
% 29.22/29.07  tff(decl_50984, type, macroclimate: $i).
% 29.22/29.07  tff(decl_50985, type, microclimate_1: $i > $o).
% 29.22/29.07  tff(decl_50986, type, 'Macroevolution': $i).
% 29.22/29.07  tff(decl_50987, type, 'Evolutionary processes that occur above the level of species. Macroevolution includes the origin of new major groups of organisms and changes in large-scale patterns of evolution that occur over very long periods of time. Examples include mass extinctions and the appearance of major novel characteristics of organisms.': $i).
% 29.22/29.07  tff(decl_50988, type, macroevolution: $i).
% 29.22/29.07  tff(decl_50989, type, 'Macronutrient': $i).
% 29.22/29.07  tff(decl_50990, type, 'A compound that must be obtained in comparatively large amounts. The three primary macronutrients are carbohydrates, fats, and proteins.': $i).
% 29.22/29.07  tff(decl_50991, type, macronutrient: $i).
% 29.22/29.07  tff(decl_50992, type, macrophage_1: $i > $o).
% 29.22/29.07  tff(decl_50993, type, 'Macrophage': $i).
% 29.22/29.07  tff(decl_50994, type, 'Macrophages are white blood cells within tissues, produced by the division of monocytes. They help to defend the body by destroying bacteria and other invaders.': $i).
% 29.22/29.07  tff(decl_50995, type, monocyte: $i).
% 29.22/29.07  tff(decl_50996, type, macrophage: $i).
% 29.22/29.07  tff(decl_50997, type, fn_macrophage_1: $i > $i).
% 29.22/29.07  tff(decl_50998, type, fn_macrophage_2: $i > $i).
% 29.22/29.07  tff(decl_50999, type, fn_macrophage_3: $i > $i).
% 29.22/29.07  tff(decl_51000, type, fn_macrophage_4: $i > $i).
% 29.22/29.07  tff(decl_51001, type, fn_macrophage_5: $i > $i).
% 29.22/29.07  tff(decl_51002, type, fn_macrophage_6: $i > $i).
% 29.22/29.07  tff(decl_51003, type, fn_macrophage_7: $i > $i).
% 29.22/29.07  tff(decl_51004, type, fn_macrophage_8: $i > $i).
% 29.22/29.07  tff(decl_51005, type, fn_macrophage_9: $i > $i).
% 29.22/29.07  tff(decl_51006, type, fn_macrophage_10: $i > $i).
% 29.22/29.07  tff(decl_51007, type, fn_macrophage_11: $i > $i).
% 29.22/29.07  tff(decl_51008, type, fn_macrophage_12: $i > $i).
% 29.22/29.07  tff(decl_51009, type, fn_macrophage_13: $i > $i).
% 29.22/29.07  tff(decl_51010, type, fn_macrophage_14: $i > $i).
% 29.22/29.07  tff(decl_51011, type, fn_macrophage_15: $i > $i).
% 29.22/29.07  tff(decl_51012, type, fn_macrophage_16: $i > $i).
% 29.22/29.07  tff(decl_51013, type, fn_macrophage_17: $i > $i).
% 29.22/29.07  tff(decl_51014, type, fn_macrophage_18: $i > $i).
% 29.22/29.07  tff(decl_51015, type, fn_macrophage_21: $i > $i).
% 29.22/29.07  tff(decl_51016, type, fn_macrophage_22: $i > $i).
% 29.22/29.07  tff(decl_51017, type, fn_macrophage_23: $i > $i).
% 29.22/29.07  tff(decl_51018, type, fn_macrophage_24: $i > $i).
% 29.22/29.07  tff(decl_51019, type, fn_macrophage_25: $i > $i).
% 29.22/29.07  tff(decl_51020, type, fn_macrophage_26: $i > $i).
% 29.22/29.07  tff(decl_51021, type, fn_macrophage_27: $i > $i).
% 29.22/29.07  tff(decl_51022, type, fn_macrophage_28: $i > $i).
% 29.22/29.07  tff(decl_51023, type, fn_macrophage_29: $i > $i).
% 29.22/29.07  tff(decl_51024, type, fn_macrophage_30: $i > $i).
% 29.22/29.07  tff(decl_51025, type, fn_macrophage_31: $i > $i).
% 29.22/29.07  tff(decl_51026, type, fn_macrophage_32: $i > $i).
% 29.22/29.07  tff(decl_51027, type, fn_macrophage_33: $i > $i).
% 29.22/29.07  tff(decl_51028, type, fn_macrophage_34: $i > $i).
% 29.22/29.07  tff(decl_51029, type, fn_macrophage_35: $i > $i).
% 29.22/29.07  tff(decl_51030, type, fn_macrophage_36: $i > $i).
% 29.22/29.07  tff(decl_51031, type, fn_macrophage_37: $i > $i).
% 29.22/29.07  tff(decl_51032, type, fn_macrophage_38: $i > $i).
% 29.22/29.07  tff(decl_51033, type, fn_macrophage_39: $i > $i).
% 29.22/29.07  tff(decl_51034, type, fn_macrophage_40: $i > $i).
% 29.22/29.07  tff(decl_51035, type, fn_macrophage_41: $i > $i).
% 29.22/29.07  tff(decl_51036, type, fn_macrophage_42: $i > $i).
% 29.22/29.07  tff(decl_51037, type, fn_macrophage_43: $i > $i).
% 29.22/29.07  tff(decl_51038, type, fn_macrophage_44: $i > $i).
% 29.22/29.07  tff(decl_51039, type, fn_macrophage_45: $i > $i).
% 29.22/29.07  tff(decl_51040, type, fn_macrophage_46: $i > $i).
% 29.22/29.07  tff(decl_51041, type, fn_macrophage_47: $i > $i).
% 29.22/29.07  tff(decl_51042, type, fn_macrophage_48: $i > $i).
% 29.22/29.07  tff(decl_51043, type, fn_macrophage_49: $i > $i).
% 29.22/29.07  tff(decl_51044, type, fn_macrophage_50: $i > $i).
% 29.22/29.07  tff(decl_51045, type, fn_macrophage_51: $i > $i).
% 29.22/29.07  tff(decl_51046, type, fn_macrophage_52: $i > $i).
% 29.22/29.07  tff(decl_51047, type, fn_macrophage_53: $i > $i).
% 29.22/29.07  tff(decl_51048, type, fn_macrophage_54: $i > $i).
% 29.22/29.07  tff(decl_51049, type, fn_macrophage_55: $i > $i).
% 29.22/29.07  tff(decl_51050, type, fn_macrophage_56: $i > $i).
% 29.22/29.07  tff(decl_51051, type, fn_macrophage_57: $i > $i).
% 29.22/29.07  tff(decl_51052, type, fn_macrophage_58: $i > $i).
% 29.22/29.07  tff(decl_51053, type, fn_macrophage_59: $i > $i).
% 29.22/29.07  tff(decl_51054, type, fn_macrophage_60: $i > $i).
% 29.22/29.07  tff(decl_51055, type, fn_macrophage_61: $i > $i).
% 29.22/29.07  tff(decl_51056, type, fn_macrophage_62: $i > $i).
% 29.22/29.07  tff(decl_51057, type, fn_macrophage_63: $i > $i).
% 29.22/29.07  tff(decl_51058, type, fn_macrophage_64: $i > $i).
% 29.22/29.07  tff(decl_51059, type, fn_macrophage_65: $i > $i).
% 29.22/29.07  tff(decl_51060, type, fn_macrophage_66: $i > $i).
% 29.22/29.07  tff(decl_51061, type, fn_phagocytosis_80: $i > $i).
% 29.22/29.07  tff(decl_51062, type, fn_macrophage_20: $i > $i).
% 29.22/29.07  tff(decl_51063, type, fn_macrophage_19: $i > $i).
% 29.22/29.07  tff(decl_51064, type, 'Macrophysiological-Process': $i).
% 29.22/29.07  tff(decl_51065, type, 'A process that involves multiple types of cells and possibily organs.': $i).
% 29.22/29.07  tff(decl_51066, type, 'macrophysiological process': $i).
% 29.22/29.07  tff(decl_51067, type, 'macrophysiological-process': $i).
% 29.22/29.07  tff(decl_51068, type, maggot_1: $i > $o).
% 29.22/29.07  tff(decl_51069, type, 'Maggot': $i).
% 29.22/29.07  tff(decl_51070, type, 'Larval form of insect from the order Diptera (flies)': $i).
% 29.22/29.07  tff(decl_51071, type, maggot: $i).
% 29.22/29.07  tff(decl_51072, type, fn_maggot_3: $i > $i).
% 29.22/29.07  tff(decl_51073, type, fn_maggot_4: $i > $i).
% 29.22/29.07  tff(decl_51074, type, fn_maggot_5: $i > $i).
% 29.22/29.07  tff(decl_51075, type, fn_maggot_6: $i > $i).
% 29.22/29.07  tff(decl_51076, type, fn_maggot_7: $i > $i).
% 29.22/29.07  tff(decl_51077, type, fn_maggot_8: $i > $i).
% 29.22/29.07  tff(decl_51078, type, fn_maggot_9: $i > $i).
% 29.22/29.07  tff(decl_51079, type, fn_maggot_10: $i > $i).
% 29.22/29.07  tff(decl_51080, type, fn_maggot_11: $i > $i).
% 29.22/29.07  tff(decl_51081, type, fn_maggot_12: $i > $i).
% 29.22/29.07  tff(decl_51082, type, fn_maggot_13: $i > $i).
% 29.22/29.07  tff(decl_51083, type, fn_maggot_14: $i > $i).
% 29.22/29.07  tff(decl_51084, type, fn_maggot_15: $i > $i).
% 29.22/29.07  tff(decl_51085, type, fn_maggot_16: $i > $i).
% 29.22/29.07  tff(decl_51086, type, fn_maggot_17: $i > $i).
% 29.22/29.07  tff(decl_51087, type, fn_maggot_18: $i > $i).
% 29.22/29.07  tff(decl_51088, type, fn_maggot_19: $i > $i).
% 29.22/29.07  tff(decl_51089, type, fn_maggot_20: $i > $i).
% 29.22/29.07  tff(decl_51090, type, fn_maggot_21: $i > $i).
% 29.22/29.07  tff(decl_51091, type, fn_maggot_22: $i > $i).
% 29.22/29.07  tff(decl_51092, type, fn_maggot_23: $i > $i).
% 29.22/29.07  tff(decl_51093, type, fn_maggot_24: $i > $i).
% 29.22/29.07  tff(decl_51094, type, fn_maggot_25: $i > $i).
% 29.22/29.07  tff(decl_51095, type, fn_maggot_26: $i > $i).
% 29.22/29.07  tff(decl_51096, type, fn_maggot_27: $i > $i).
% 29.22/29.07  tff(decl_51097, type, fn_maggot_28: $i > $i).
% 29.22/29.07  tff(decl_51098, type, fn_maggot_29: $i > $i).
% 29.22/29.07  tff(decl_51099, type, fn_maggot_30: $i > $i).
% 29.22/29.07  tff(decl_51100, type, fn_maggot_31: $i > $i).
% 29.22/29.07  tff(decl_51101, type, fn_maggot_32: $i > $i).
% 29.22/29.07  tff(decl_51102, type, fn_maggot_33: $i > $i).
% 29.22/29.07  tff(decl_51103, type, fn_maggot_34: $i > $i).
% 29.22/29.07  tff(decl_51104, type, fn_maggot_35: $i > $i).
% 29.22/29.07  tff(decl_51105, type, fn_maggot_36: $i > $i).
% 29.22/29.07  tff(decl_51106, type, fn_maggot_37: $i > $i).
% 29.22/29.07  tff(decl_51107, type, fn_maggot_38: $i > $i).
% 29.22/29.07  tff(decl_51108, type, fn_maggot_39: $i > $i).
% 29.22/29.07  tff(decl_51109, type, 'Magnesium': $i).
% 29.22/29.07  tff(decl_51110, type, 'Magnesium is a metal atom with atomic number 12. It is represented by the symbol Mg.': $i).
% 29.22/29.07  tff(decl_51111, type, 'Mg': $i).
% 29.22/29.07  tff(decl_51112, type, magnesium: $i).
% 29.22/29.07  tff(decl_51113, type, fn_magnesium_4: $i > $i).
% 29.22/29.07  tff(decl_51114, type, fn_magnesium_5: $i > $i).
% 29.22/29.07  tff(decl_51115, type, fn_magnesium_6: $i > $i).
% 29.22/29.07  tff(decl_51116, type, fn_magnesium_7: $i > $i).
% 29.22/29.07  tff(decl_51117, type, fn_magnesium_11: $i > $i).
% 29.22/29.07  tff(decl_51118, type, fn_magnesium_12: $i > $i).
% 29.22/29.07  tff(decl_51119, type, fn_magnesium_13: $i > $i).
% 29.22/29.07  tff(decl_51120, type, fn_magnesium_14: $i > $i).
% 29.22/29.07  tff(decl_51121, type, "1.31": $i).
% 29.22/29.07  tff(decl_51122, type, "24.31": $i).
% 29.22/29.07  tff(decl_51123, type, fn_magnesium_9: $i > $i).
% 29.22/29.07  tff(decl_51124, type, fn_magnesium_10: $i > $i).
% 29.22/29.07  tff(decl_51125, type, fn_magnesium_8: $i > $i).
% 29.22/29.07  tff(decl_51126, type, 'Magnesium-Ion': $i).
% 29.22/29.07  tff(decl_51127, type, 'Ion of magnesium.': $i).
% 29.22/29.07  tff(decl_51128, type, 'ion of magnesium': $i).
% 29.22/29.07  tff(decl_51129, type, 'magnesium ion': $i).
% 29.22/29.07  tff(decl_51130, type, 'magnesium-ion': $i).
% 29.22/29.07  tff(decl_51131, type, fn_magnesium_ion_1: $i > $i).
% 29.22/29.07  tff(decl_51132, type, fn_magnesium_ion_2: $i > $i).
% 29.22/29.07  tff(decl_51133, type, fn_magnesium_ion_3: $i > $i).
% 29.22/29.07  tff(decl_51134, type, fn_magnesium_ion_4: $i > $i).
% 29.22/29.07  tff(decl_51135, type, fn_magnesium_ion_6: $i > $i).
% 29.22/29.07  tff(decl_51136, type, fn_magnesium_ion_7: $i > $i).
% 29.22/29.07  tff(decl_51137, type, fn_magnesium_ion_5: $i > $i).
% 29.22/29.07  tff(decl_51138, type, magnetic_reversal_1: $i > $o).
% 29.22/29.07  tff(decl_51139, type, 'Magnetic-Reversal': $i).
% 29.22/29.07  tff(decl_51140, type, 'A periodic change in the polarization of Earth\\s magnetic field so that the positions of magnetic north and magnetic south become interchanged.': $i).
% 29.22/29.07  tff(decl_51141, type, 'geomagnetic reversal': $i).
% 29.22/29.07  tff(decl_51142, type, 'geomagnetic-reversal': $i).
% 29.22/29.07  tff(decl_51143, type, 'magnetic reversal': $i).
% 29.22/29.07  tff(decl_51144, type, 'magnetic-reversal': $i).
% 29.22/29.07  tff(decl_51145, type, photoexcitation_1: $i > $o).
% 29.22/29.07  tff(decl_51146, type, magnification_constant_1: $i > $o).
% 29.22/29.07  tff(decl_51147, type, 'Magnification-Constant': $i).
% 29.22/29.07  tff(decl_51148, type, 'constant of magnification': $i).
% 29.22/29.07  tff(decl_51149, type, 'magnification constant': $i).
% 29.22/29.07  tff(decl_51150, type, 'magnification-constant': $i).
% 29.22/29.07  tff(decl_51151, type, magnification_scale_1: $i > $o).
% 29.22/29.07  tff(decl_51152, type, 'Magnification-Scale': $i).
% 29.22/29.07  tff(decl_51153, type, 'scale of magnification': $i).
% 29.22/29.07  tff(decl_51154, type, 'magnification scale': $i).
% 29.22/29.07  tff(decl_51155, type, 'magnification-scale': $i).
% 29.22/29.07  tff(decl_51156, type, 'Magnitude-Value': $i).
% 29.22/29.07  tff(decl_51157, type, size: $i).
% 29.22/29.07  tff(decl_51158, type, magnitude: $i).
% 29.22/29.07  tff(decl_51159, type, 'value of magnitude': $i).
% 29.22/29.07  tff(decl_51160, type, 'magnitude value': $i).
% 29.22/29.07  tff(decl_51161, type, 'magnitude-value': $i).
% 29.22/29.07  tff(decl_51162, type, magnoliid_1: $i > $o).
% 29.22/29.07  tff(decl_51163, type, 'Magnoliid': $i).
% 29.22/29.07  tff(decl_51164, type, 'Member of the angiosperm clade that includes the Magnoliaceae. Extant examples include cinnamon, avocado, magnolia, nutmeg, and bay laurel.': $i).
% 29.22/29.07  tff(decl_51165, type, magnoliid: $i).
% 29.22/29.07  tff(decl_51166, type, 'Maintenance': $i).
% 29.22/29.07  tff(decl_51167, type, care: $i).
% 29.22/29.07  tff(decl_51168, type, upkeep: $i).
% 29.22/29.07  tff(decl_51169, type, maintenance: $i).
% 29.22/29.07  tff(decl_51170, type, maintenance_of_concentration_of_calcium_ion_in_animal_cell_1: $i > $o).
% 29.22/29.07  tff(decl_51171, type, 'Maintenance-Of-Concentration-Of-Calcium-Ion-In-Animal-Cell': $i).
% 29.22/29.07  tff(decl_51172, type, 'Keeping a lower concentration of Ca2+ ions in the cytosol than the extracellular fluid via protein pumps that transfer Ca2+ ions into the extracellular fluid, the ER, and the mitochondria.': $i).
% 29.22/29.07  tff(decl_51173, type, 'maintenance of concentration of calcium ion in animal cell': $i).
% 29.22/29.07  tff(decl_51174, type, 'maintenance-of-concentration-of-calcium-ion-in-animal-cell': $i).
% 29.22/29.07  tff(decl_51175, type, maintenance_of_concentration_of_calcium_ion_in_eukaryotic_cell_1: $i > $o).
% 29.22/29.07  tff(decl_51176, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_3: $i > $i).
% 29.22/29.07  tff(decl_51177, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_4: $i > $i).
% 29.22/29.07  tff(decl_51178, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_5: $i > $i).
% 29.22/29.07  tff(decl_51179, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_6: $i > $i).
% 29.22/29.07  tff(decl_51180, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_7: $i > $i).
% 29.22/29.07  tff(decl_51181, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_10: $i > $i).
% 29.22/29.07  tff(decl_51182, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_11: $i > $i).
% 29.22/29.07  tff(decl_51183, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_12: $i > $i).
% 29.22/29.07  tff(decl_51184, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_13: $i > $i).
% 29.22/29.07  tff(decl_51185, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_14: $i > $i).
% 29.22/29.07  tff(decl_51186, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_15: $i > $i).
% 29.22/29.07  tff(decl_51187, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_16: $i > $i).
% 29.22/29.07  tff(decl_51188, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_17: $i > $i).
% 29.22/29.07  tff(decl_51189, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_18: $i > $i).
% 29.22/29.07  tff(decl_51190, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_19: $i > $i).
% 29.22/29.07  tff(decl_51191, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_20: $i > $i).
% 29.22/29.07  tff(decl_51192, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_21: $i > $i).
% 29.22/29.07  tff(decl_51193, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_22: $i > $i).
% 29.22/29.07  tff(decl_51194, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_23: $i > $i).
% 29.22/29.07  tff(decl_51195, type, uptake_of_calcium_ion_by_endoplasmic_reticulum_1: $i > $o).
% 29.22/29.07  tff(decl_51196, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_24: $i > $i).
% 29.22/29.07  tff(decl_51197, type, release_of_calcium_ion_by_cell_1: $i > $o).
% 29.22/29.07  tff(decl_51198, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_25: $i > $i).
% 29.22/29.07  tff(decl_51199, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_26: $i > $i).
% 29.22/29.07  tff(decl_51200, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_27: $i > $i).
% 29.22/29.07  tff(decl_51201, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_28: $i > $i).
% 29.22/29.07  tff(decl_51202, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_29: $i > $i).
% 29.22/29.07  tff(decl_51203, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_30: $i > $i).
% 29.22/29.07  tff(decl_51204, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_31: $i > $i).
% 29.22/29.07  tff(decl_51205, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_32: $i > $i).
% 29.22/29.07  tff(decl_51206, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_33: $i > $i).
% 29.22/29.07  tff(decl_51207, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_34: $i > $i).
% 29.22/29.07  tff(decl_51208, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_35: $i > $i).
% 29.22/29.07  tff(decl_51209, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_36: $i > $i).
% 29.22/29.07  tff(decl_51210, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_37: $i > $i).
% 29.22/29.07  tff(decl_51211, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_38: $i > $i).
% 29.22/29.07  tff(decl_51212, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_39: $i > $i).
% 29.22/29.07  tff(decl_51213, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_40: $i > $i).
% 29.22/29.07  tff(decl_51214, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_41: $i > $i).
% 29.22/29.07  tff(decl_51215, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_42: $i > $i).
% 29.22/29.07  tff(decl_51216, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_43: $i > $i).
% 29.22/29.07  tff(decl_51217, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_44: $i > $i).
% 29.22/29.07  tff(decl_51218, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_45: $i > $i).
% 29.22/29.07  tff(decl_51219, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_46: $i > $i).
% 29.22/29.07  tff(decl_51220, type, fn_maintenance_of_concentration_of_calcium_ion_in_animal_cell_47: $i > $i).
% 29.22/29.07  tff(decl_51221, type, fn_release_of_calcium_ion_by_cell_47: $i > $i).
% 29.22/29.07  tff(decl_51222, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_4: $i > $i).
% 29.22/29.07  tff(decl_51223, type, fn_release_of_calcium_ion_by_cell_81: $i > $i).
% 29.22/29.07  tff(decl_51224, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_55: $i > $i).
% 29.22/29.07  tff(decl_51225, type, fn_release_of_calcium_ion_by_cell_82: $i > $i).
% 29.22/29.07  tff(decl_51226, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_56: $i > $i).
% 29.22/29.07  tff(decl_51227, type, fn_release_of_calcium_ion_by_cell_80: $i > $i).
% 29.22/29.07  tff(decl_51228, type, fn_release_of_calcium_ion_by_cell_58: $i > $i).
% 29.22/29.07  tff(decl_51229, type, fn_release_of_calcium_ion_by_cell_48: $i > $i).
% 29.22/29.07  tff(decl_51230, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_57: $i > $i).
% 29.22/29.07  tff(decl_51231, type, fn_release_of_calcium_ion_by_cell_79: $i > $i).
% 29.22/29.07  tff(decl_51232, type, fn_release_of_calcium_ion_by_cell_126: $i > $i).
% 29.22/29.07  tff(decl_51233, type, fn_release_of_calcium_ion_by_cell_52: $i > $i).
% 29.22/29.07  tff(decl_51234, type, fn_release_of_calcium_ion_by_cell_53: $i > $i).
% 29.22/29.07  tff(decl_51235, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_33: $i > $i).
% 29.22/29.07  tff(decl_51236, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_27: $i > $i).
% 29.22/29.07  tff(decl_51237, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_12: $i > $i).
% 29.22/29.07  tff(decl_51238, type, fn_release_of_calcium_ion_by_cell_125: $i > $i).
% 29.22/29.07  tff(decl_51239, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_10: $i > $i).
% 29.22/29.07  tff(decl_51240, type, fn_release_of_calcium_ion_by_cell_54: $i > $i).
% 29.22/29.07  tff(decl_51241, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_11: $i > $i).
% 29.22/29.07  tff(decl_51242, type, fn_release_of_calcium_ion_by_cell_124: $i > $i).
% 29.22/29.07  tff(decl_51243, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_67: $i > $i).
% 29.22/29.07  tff(decl_51244, type, fn_release_of_calcium_ion_by_cell_51: $i > $i).
% 29.22/29.07  tff(decl_51245, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_34: $i > $i).
% 29.22/29.07  tff(decl_51246, type, fn_maintenance_of_concentration_of_calcium_ion_in_eukaryotic_cell_3: $i > $i).
% 29.22/29.07  tff(decl_51247, type, fn_maintenance_of_concentration_of_calcium_ion_in_eukaryotic_cell_1: $i > $i).
% 29.22/29.07  tff(decl_51248, type, fn_maintenance_of_concentration_of_calcium_ion_in_eukaryotic_cell_2: $i > $i).
% 29.22/29.07  tff(decl_51249, type, 'Maintenance-Of-Concentration-Of-Calcium-Ion-In-Eukaryotic-Cell': $i).
% 29.22/29.07  tff(decl_51250, type, 'Keeping a steady concentrations of Ca2+ ions in the cytosol of a nucleated cell.': $i).
% 29.22/29.07  tff(decl_51251, type, 'maintenance of concentration of calcium ion in eukaryotic cell': $i).
% 29.22/29.07  tff(decl_51252, type, 'maintenance-of-concentration-of-calcium-ion-in-eukaryotic-cell': $i).
% 29.22/29.07  tff(decl_51253, type, maintenance_of_ph_in_lysosome_1: $i > $o).
% 29.22/29.07  tff(decl_51254, type, fn_maintenance_of_concentration_of_calcium_ion_in_eukaryotic_cell_4: $i > $i).
% 29.22/29.07  tff(decl_51255, type, fn_maintenance_of_concentration_of_calcium_ion_in_eukaryotic_cell_5: $i > $i).
% 29.22/29.07  tff(decl_51256, type, 'Maintenance-of-pH-in-Lysosome': $i).
% 29.22/29.07  tff(decl_51257, type, 'This involves maintaining the pH inside a lysosome at about 5. This is the optimum pH for the functioning of hydrolytic lysosomal enzymes': $i).
% 29.22/29.07  tff(decl_51258, type, 'ph maintenance in lysosome': $i).
% 29.22/29.07  tff(decl_51259, type, 'lysosomal ph maintenance': $i).
% 29.22/29.07  tff(decl_51260, type, 'maintenance of lysosomal ph': $i).
% 29.22/29.07  tff(decl_51261, type, 'maintenance of ph': $i).
% 29.22/29.07  tff(decl_51262, type, 'maintenance of ph in lysosome': $i).
% 29.22/29.07  tff(decl_51263, type, 'maintenance-of-ph-in-lysosome': $i).
% 29.22/29.07  tff(decl_51264, type, fn_maintenance_of_ph_in_lysosome_1: $i > $i).
% 29.22/29.07  tff(decl_51265, type, fn_maintenance_of_ph_in_lysosome_2: $i > $i).
% 29.22/29.07  tff(decl_51266, type, fn_maintenance_of_ph_in_lysosome_3: $i > $i).
% 29.22/29.07  tff(decl_51267, type, fn_maintenance_of_ph_in_lysosome_4: $i > $i).
% 29.22/29.07  tff(decl_51268, type, fn_maintenance_of_ph_in_lysosome_5: $i > $i).
% 29.22/29.07  tff(decl_51269, type, 'Major-Depression': $i).
% 29.22/29.07  tff(decl_51270, type, 'A mental disorder characterized by periods of deep sadness, low self-esteem, and a loss of interest or pleasure in normally enjoyable activities.': $i).
% 29.22/29.07  tff(decl_51271, type, 'depression of major': $i).
% 29.22/29.07  tff(decl_51272, type, 'major depression': $i).
% 29.22/29.07  tff(decl_51273, type, 'major-depression': $i).
% 29.22/29.07  tff(decl_51274, type, major_histocompatibility_complex_gene_1: $i > $o).
% 29.22/29.07  tff(decl_51275, type, 'Major-Histocompatibility-Complex-Gene': $i).
% 29.22/29.07  tff(decl_51276, type, 'The major histocompatibility complex (MHC) is a large genomic region or gene family found in most vertebrates that encodes MHC molecules. MHC molecules play an important role in the immune system and autoimmunity.': $i).
% 29.22/29.07  tff(decl_51277, type, 'major histocompatibility complex gene': $i).
% 29.22/29.07  tff(decl_51278, type, 'major-histocompatibility-complex-gene': $i).
% 29.22/29.07  tff(decl_51279, type, multigene_family_1: $i > $o).
% 29.22/29.07  tff(decl_51280, type, multigene_family_of_identical_genes_1: $i > $o).
% 29.22/29.07  tff(decl_51281, type, multigene_family_of_nonidentical_genes_1: $i > $o).
% 29.22/29.07  tff(decl_51282, type, 'Major-Histocompatibility-Complex-Protein': $i).
% 29.22/29.07  tff(decl_51283, type, 'A cell-surface protein that presents antigens to T cells.': $i).
% 29.22/29.07  tff(decl_51284, type, mhc: $i).
% 29.22/29.07  tff(decl_51285, type, mchp: $i).
% 29.22/29.07  tff(decl_51286, type, 'major histocompatibility complex protein': $i).
% 29.22/29.07  tff(decl_51287, type, 'major-histocompatibility-complex-protein': $i).
% 29.22/29.07  tff(decl_51288, type, fn_major_histocompatibility_complex_protein_1: $i > $i).
% 29.22/29.07  tff(decl_51289, type, fn_major_histocompatibility_complex_protein_2: $i > $i).
% 29.22/29.07  tff(decl_51290, type, fn_major_histocompatibility_complex_protein_3: $i > $i).
% 29.22/29.07  tff(decl_51291, type, fn_major_histocompatibility_complex_protein_4: $i > $i).
% 29.22/29.07  tff(decl_51292, type, unequal_sharing_of_electrons_1: $i > $o).
% 29.22/29.07  tff(decl_51293, type, fn_major_histocompatibility_complex_protein_5: $i > $i).
% 29.22/29.07  tff(decl_51294, type, make_1: $i > $o).
% 29.22/29.07  tff(decl_51295, type, 'Make': $i).
% 29.22/29.07  tff(decl_51296, type, 'Form something by putting parts together or combining substances': $i).
% 29.22/29.07  tff(decl_51297, type, 'Make-Accessible': $i).
% 29.22/29.07  tff(decl_51298, type, 'make accessible': $i).
% 29.22/29.07  tff(decl_51299, type, 'make-accessible': $i).
% 29.22/29.07  tff(decl_51300, type, 'Make-Contact': $i).
% 29.22/29.07  tff(decl_51301, type, 'criss-cross': $i).
% 29.22/29.07  tff(decl_51302, type, 'criss cross': $i).
% 29.22/29.07  tff(decl_51303, type, 'make contact': $i).
% 29.22/29.07  tff(decl_51304, type, 'contact of make': $i).
% 29.22/29.07  tff(decl_51305, type, 'make-contact': $i).
% 29.22/29.07  tff(decl_51306, type, 'Make-Error': $i).
% 29.22/29.07  tff(decl_51307, type, 'In biology, a cellular action which produces an unexpected outcome.': $i).
% 29.22/29.07  tff(decl_51308, type, 'error of make': $i).
% 29.22/29.07  tff(decl_51309, type, 'make error': $i).
% 29.22/29.07  tff(decl_51310, type, 'make-error': $i).
% 29.22/29.07  tff(decl_51311, type, 'Make-Inaccessible': $i).
% 29.22/29.07  tff(decl_51312, type, 'make inaccessible': $i).
% 29.22/29.07  tff(decl_51313, type, 'make-inaccessible': $i).
% 29.22/29.07  tff(decl_51314, type, make_request_1: $i > $o).
% 29.22/29.07  tff(decl_51315, type, 'Make-Request': $i).
% 29.22/29.07  tff(decl_51316, type, request: $i).
% 29.22/29.07  tff(decl_51317, type, bespeak: $i).
% 29.22/29.07  tff(decl_51318, type, 'call for': $i).
% 29.22/29.07  tff(decl_51319, type, call_for: $i).
% 29.22/29.07  tff(decl_51320, type, quest: $i).
% 29.22/29.07  tff(decl_51321, type, 'request of make': $i).
% 29.22/29.07  tff(decl_51322, type, 'make request': $i).
% 29.22/29.07  tff(decl_51323, type, 'make-request': $i).
% 29.22/29.07  tff(decl_51324, type, teach_1: $i > $o).
% 29.22/29.07  tff(decl_51325, type, fn_make_request_1: $i > $i).
% 29.22/29.07  tff(decl_51326, type, fn_make_request_3: $i > $i).
% 29.22/29.07  tff(decl_51327, type, 'Malaria': $i).
% 29.22/29.07  tff(decl_51328, type, 'A mosquito-borne infectious disease of humans and other mammals caused by protozoans of the genus Plasmodium.': $i).
% 29.22/29.07  tff(decl_51329, type, 'malarial fever': $i).
% 29.22/29.07  tff(decl_51330, type, 'malarial-fever': $i).
% 29.22/29.07  tff(decl_51331, type, malaria: $i).
% 29.22/29.07  tff(decl_51332, type, 'Malate': $i).
% 29.22/29.07  tff(decl_51333, type, 'Malate is a salt or ester of malic acid.': $i).
% 29.22/29.07  tff(decl_51334, type, malate: $i).
% 29.22/29.07  tff(decl_51335, type, male_fruit_fly_1: $i > $o).
% 29.22/29.07  tff(decl_51336, type, 'Male-Fruit-Fly': $i).
% 29.22/29.07  tff(decl_51337, type, 'Drosophila melanogaster is a species of Diptera, or the order of flies, in the family Drosophilidae. The species is commonly known as the common fruit fly or vinegar fly. It has 2 sex chromosomes and 6 autosomes.': $i).
% 29.22/29.07  tff(decl_51338, type, 'male fruit fly': $i).
% 29.22/29.07  tff(decl_51339, type, 'male fruit-fly': $i).
% 29.22/29.07  tff(decl_51340, type, 'male-fruit-fly': $i).
% 29.22/29.07  tff(decl_51341, type, 'Male-Somatic-Cell': $i).
% 29.22/29.07  tff(decl_51342, type, 'A male somatic cell contains 23 pair of chromosomes including XY.': $i).
% 29.22/29.07  tff(decl_51343, type, 'male somatic cell': $i).
% 29.22/29.07  tff(decl_51344, type, 'male-somatic-cell': $i).
% 29.22/29.07  tff(decl_51345, type, fn_male_somatic_cell_1: $i > $i).
% 29.22/29.07  tff(decl_51346, type, fn_male_somatic_cell_2: $i > $i).
% 29.22/29.07  tff(decl_51347, type, malignant_tumor_1: $i > $o).
% 29.22/29.07  tff(decl_51348, type, 'Malignant-Tumor': $i).
% 29.22/29.07  tff(decl_51349, type, 'A cancerous tumor that is invasive enough to impair the functions of one or more organs.': $i).
% 29.22/29.07  tff(decl_51350, type, 'cancerous tumor': $i).
% 29.22/29.07  tff(decl_51351, type, 'metastatic tumor': $i).
% 29.22/29.07  tff(decl_51352, type, 'malignant tumor': $i).
% 29.22/29.07  tff(decl_51353, type, 'malignant-tumor': $i).
% 29.22/29.07  tff(decl_51354, type, fn_malignant_tumor_1: $i > $i).
% 29.22/29.07  tff(decl_51355, type, fn_malignant_tumor_2: $i > $i).
% 29.22/29.07  tff(decl_51356, type, cancer_cell_0: $i).
% 29.22/29.07  tff(decl_51357, type, malignant_tumor_growth_1: $i > $o).
% 29.22/29.07  tff(decl_51358, type, 'Malignant-Tumor-Growth': $i).
% 29.22/29.07  tff(decl_51359, type, 'Uncontrolled cell division of malignant cancerous cells, resulting in the growth of a malignant tumor. Tumor growth often also includes growth of supporting tissues, such as blood vessels.': $i).
% 29.22/29.07  tff(decl_51360, type, 'malignant tumor growth': $i).
% 29.22/29.07  tff(decl_51361, type, 'malignant-tumor-growth': $i).
% 29.22/29.07  tff(decl_51362, type, tumor_growth_1: $i > $o).
% 29.22/29.07  tff(decl_51363, type, fn_malignant_tumor_growth_1: $i > $i).
% 29.22/29.07  tff(decl_51364, type, fn_malignant_tumor_growth_3: $i > $i).
% 29.22/29.07  tff(decl_51365, type, fn_malignant_tumor_growth_4: $i > $i).
% 29.22/29.07  tff(decl_51366, type, fn_malignant_tumor_growth_5: $i > $i).
% 29.22/29.07  tff(decl_51367, type, fn_malignant_tumor_growth_6: $i > $i).
% 29.22/29.07  tff(decl_51368, type, fn_malignant_tumor_growth_7: $i > $i).
% 29.22/29.07  tff(decl_51369, type, fn_malignant_tumor_growth_8: $i > $i).
% 29.22/29.07  tff(decl_51370, type, fn_malignant_tumor_growth_9: $i > $i).
% 29.22/29.07  tff(decl_51371, type, fn_malignant_tumor_growth_10: $i > $i).
% 29.22/29.07  tff(decl_51372, type, fn_malignant_tumor_growth_11: $i > $i).
% 29.22/29.07  tff(decl_51373, type, fn_malignant_tumor_growth_12: $i > $i).
% 29.22/29.07  tff(decl_51374, type, fn_malignant_tumor_growth_13: $i > $i).
% 29.22/29.07  tff(decl_51375, type, fn_tumor_growth_2: $i > $i).
% 29.22/29.07  tff(decl_51376, type, fn_tumor_growth_3: $i > $i).
% 29.22/29.07  tff(decl_51377, type, fn_tumor_growth_8: $i > $i).
% 29.22/29.07  tff(decl_51378, type, fn_tumor_growth_7: $i > $i).
% 29.22/29.07  tff(decl_51379, type, fn_tumor_growth_1: $i > $i).
% 29.22/29.07  tff(decl_51380, type, fn_tumor_growth_10: $i > $i).
% 29.22/29.07  tff(decl_51381, type, fn_tumor_growth_5: $i > $i).
% 29.22/29.07  tff(decl_51382, type, fn_tumor_growth_6: $i > $i).
% 29.22/29.07  tff(decl_51383, type, 'Malleus': $i).
% 29.22/29.07  tff(decl_51384, type, 'The first of three bones in the middle ear of mammals; also called the hammer.': $i).
% 29.22/29.07  tff(decl_51385, type, malleus: $i).
% 29.22/29.07  tff(decl_51386, type, malnourishment_1: $i > $o).
% 29.22/29.07  tff(decl_51387, type, 'Malnourishment': $i).
% 29.22/29.07  tff(decl_51388, type, 'Long-term lack of one or more essential nutrients.': $i).
% 29.22/29.07  tff(decl_51389, type, malnourishment: $i).
% 29.22/29.07  tff(decl_51390, type, overnourishment_1: $i > $o).
% 29.22/29.07  tff(decl_51391, type, undernourishment_1: $i > $o).
% 29.22/29.07  tff(decl_51392, type, 'Malonate': $i).
% 29.22/29.07  tff(decl_51393, type, malonate: $i).
% 29.22/29.07  tff(decl_51394, type, fn_malonate_1: $i > $i).
% 29.22/29.07  tff(decl_51395, type, fn_malonate_2: $i > $i).
% 29.22/29.07  tff(decl_51396, type, malpighian_tubule_1: $i > $o).
% 29.22/29.07  tff(decl_51397, type, 'Malpighian-Tubule': $i).
% 29.22/29.07  tff(decl_51398, type, 'Unique excretory and osmoregulatory organ of terrestrial arthropods such as insects and spiders. Malpighian tubules collect nitrogenous wastes and excrete them into the intestine to be voided with feces.': $i).
% 29.22/29.07  tff(decl_51399, type, 'malpighian tubule': $i).
% 29.22/29.07  tff(decl_51400, type, 'malpighian-tubule': $i).
% 29.22/29.07  tff(decl_51401, type, 'Maltose': $i).
% 29.22/29.07  tff(decl_51402, type, 'A disaccharide formed by linking two glucose molecules together via a dehydration synthesis reaction.': $i).
% 29.22/29.07  tff(decl_51403, type, 'malt sugar': $i).
% 29.22/29.07  tff(decl_51404, type, 'malt-sugar': $i).
% 29.22/29.07  tff(decl_51405, type, maltose: $i).
% 29.22/29.07  tff(decl_51406, type, fn_maltose_1: $i > $i).
% 29.22/29.07  tff(decl_51407, type, fn_maltose_2: $i > $i).
% 29.22/29.07  tff(decl_51408, type, fn_maltose_5: $i > $i).
% 29.22/29.07  tff(decl_51409, type, fn_maltose_6: $i > $i).
% 29.22/29.07  tff(decl_51410, type, fn_maltose_7: $i > $i).
% 29.22/29.07  tff(decl_51411, type, fn_maltose_8: $i > $i).
% 29.22/29.07  tff(decl_51412, type, fn_maltose_9: $i > $i).
% 29.22/29.07  tff(decl_51413, type, fn_maltose_10: $i > $i).
% 29.22/29.07  tff(decl_51414, type, fn_maltose_11: $i > $i).
% 29.22/29.07  tff(decl_51415, type, fn_maltose_12: $i > $i).
% 29.22/29.07  tff(decl_51416, type, fn_maltose_13: $i > $i).
% 29.22/29.07  tff(decl_51417, type, fn_maltose_14: $i > $i).
% 29.22/29.07  tff(decl_51418, type, fn_maltose_15: $i > $i).
% 29.22/29.07  tff(decl_51419, type, fn_maltose_16: $i > $i).
% 29.22/29.07  tff(decl_51420, type, fn_maltose_17: $i > $i).
% 29.22/29.07  tff(decl_51421, type, fn_maltose_18: $i > $i).
% 29.22/29.07  tff(decl_51422, type, fn_maltose_19: $i > $i).
% 29.22/29.07  tff(decl_51423, type, fn_maltose_20: $i > $i).
% 29.22/29.07  tff(decl_51424, type, fn_maltose_21: $i > $i).
% 29.22/29.07  tff(decl_51425, type, fn_maltose_22: $i > $i).
% 29.22/29.07  tff(decl_51426, type, fn_maltose_23: $i > $i).
% 29.22/29.07  tff(decl_51427, type, fn_maltose_24: $i > $i).
% 29.22/29.07  tff(decl_51428, type, fn_maltose_25: $i > $i).
% 29.22/29.07  tff(decl_51429, type, fn_maltose_26: $i > $i).
% 29.22/29.07  tff(decl_51430, type, fn_maltose_27: $i > $i).
% 29.22/29.07  tff(decl_51431, type, fn_maltose_28: $i > $i).
% 29.22/29.07  tff(decl_51432, type, fn_maltose_30: $i > $i).
% 29.22/29.07  tff(decl_51433, type, fn_maltose_31: $i > $i).
% 29.22/29.07  tff(decl_51434, type, fn_maltose_32: $i > $i).
% 29.22/29.07  tff(decl_51435, type, fn_maltose_33: $i > $i).
% 29.22/29.07  tff(decl_51436, type, fn_maltose_34: $i > $i).
% 29.22/29.07  tff(decl_51437, type, fn_maltose_35: $i > $i).
% 29.22/29.07  tff(decl_51438, type, fn_maltose_36: $i > $i).
% 29.22/29.07  tff(decl_51439, type, fn_maltose_37: $i > $i).
% 29.22/29.07  tff(decl_51440, type, fn_maltose_38: $i > $i).
% 29.22/29.07  tff(decl_51441, type, fn_maltose_39: $i > $i).
% 29.22/29.07  tff(decl_51442, type, fn_maltose_40: $i > $i).
% 29.22/29.07  tff(decl_51443, type, fn_maltose_41: $i > $i).
% 29.22/29.07  tff(decl_51444, type, fn_maltose_42: $i > $i).
% 29.22/29.07  tff(decl_51445, type, fn_maltose_43: $i > $i).
% 29.22/29.07  tff(decl_51446, type, fn_maltose_44: $i > $i).
% 29.22/29.07  tff(decl_51447, type, fn_maltose_45: $i > $i).
% 29.22/29.07  tff(decl_51448, type, fn_maltose_46: $i > $i).
% 29.22/29.07  tff(decl_51449, type, fn_maltose_47: $i > $i).
% 29.22/29.07  tff(decl_51450, type, fn_maltose_48: $i > $i).
% 29.22/29.07  tff(decl_51451, type, fn_maltose_49: $i > $i).
% 29.22/29.07  tff(decl_51452, type, fn_maltose_50: $i > $i).
% 29.22/29.07  tff(decl_51453, type, fn_maltose_51: $i > $i).
% 29.22/29.07  tff(decl_51454, type, fn_maltose_52: $i > $i).
% 29.22/29.07  tff(decl_51455, type, fn_maltose_53: $i > $i).
% 29.22/29.07  tff(decl_51456, type, fn_maltose_54: $i > $i).
% 29.22/29.07  tff(decl_51457, type, fn_maltose_55: $i > $i).
% 29.22/29.07  tff(decl_51458, type, fn_maltose_56: $i > $i).
% 29.22/29.07  tff(decl_51459, type, fn_maltose_57: $i > $i).
% 29.22/29.07  tff(decl_51460, type, fn_maltose_58: $i > $i).
% 29.22/29.07  tff(decl_51461, type, fn_maltose_59: $i > $i).
% 29.22/29.07  tff(decl_51462, type, fn_maltose_60: $i > $i).
% 29.22/29.07  tff(decl_51463, type, fn_maltose_61: $i > $i).
% 29.22/29.07  tff(decl_51464, type, fn_maltose_62: $i > $i).
% 29.22/29.07  tff(decl_51465, type, fn_maltose_63: $i > $i).
% 29.22/29.07  tff(decl_51466, type, fn_maltose_64: $i > $i).
% 29.22/29.07  tff(decl_51467, type, fn_maltose_65: $i > $i).
% 29.22/29.07  tff(decl_51468, type, fn_maltose_66: $i > $i).
% 29.22/29.07  tff(decl_51469, type, fn_maltose_67: $i > $i).
% 29.22/29.07  tff(decl_51470, type, fn_maltose_68: $i > $i).
% 29.22/29.07  tff(decl_51471, type, fn_maltose_69: $i > $i).
% 29.22/29.07  tff(decl_51472, type, fn_maltose_70: $i > $i).
% 29.22/29.07  tff(decl_51473, type, fn_maltose_71: $i > $i).
% 29.22/29.07  tff(decl_51474, type, fn_maltose_72: $i > $i).
% 29.22/29.07  tff(decl_51475, type, fn_maltose_73: $i > $i).
% 29.22/29.07  tff(decl_51476, type, fn_maltose_74: $i > $i).
% 29.22/29.07  tff(decl_51477, type, fn_maltose_75: $i > $i).
% 29.22/29.07  tff(decl_51478, type, fn_maltose_76: $i > $i).
% 29.22/29.07  tff(decl_51479, type, fn_maltose_77: $i > $i).
% 29.22/29.07  tff(decl_51480, type, fn_maltose_78: $i > $i).
% 29.22/29.07  tff(decl_51481, type, fn_maltose_79: $i > $i).
% 29.22/29.07  tff(decl_51482, type, fn_maltose_80: $i > $i).
% 29.22/29.07  tff(decl_51483, type, fn_maltose_81: $i > $i).
% 29.22/29.07  tff(decl_51484, type, fn_maltose_82: $i > $i).
% 29.22/29.07  tff(decl_51485, type, fn_maltose_83: $i > $i).
% 29.22/29.07  tff(decl_51486, type, fn_maltose_84: $i > $i).
% 29.22/29.07  tff(decl_51487, type, fn_maltose_85: $i > $i).
% 29.22/29.07  tff(decl_51488, type, fn_maltose_86: $i > $i).
% 29.22/29.07  tff(decl_51489, type, fn_maltose_87: $i > $i).
% 29.22/29.07  tff(decl_51490, type, fn_maltose_88: $i > $i).
% 29.22/29.07  tff(decl_51491, type, fn_maltose_89: $i > $i).
% 29.22/29.07  tff(decl_51492, type, fn_maltose_90: $i > $i).
% 29.22/29.07  tff(decl_51493, type, fn_maltose_91: $i > $i).
% 29.22/29.07  tff(decl_51494, type, fn_maltose_92: $i > $i).
% 29.22/29.07  tff(decl_51495, type, fn_maltose_93: $i > $i).
% 29.22/29.07  tff(decl_51496, type, fn_maltose_94: $i > $i).
% 29.22/29.07  tff(decl_51497, type, fn_maltose_95: $i > $i).
% 29.22/29.07  tff(decl_51498, type, fn_maltose_96: $i > $i).
% 29.22/29.07  tff(decl_51499, type, fn_maltose_99: $i > $i).
% 29.22/29.07  tff(decl_51500, type, fn_maltose_100: $i > $i).
% 29.22/29.07  tff(decl_51501, type, fn_maltose_101: $i > $i).
% 29.22/29.07  tff(decl_51502, type, fn_maltose_102: $i > $i).
% 29.22/29.07  tff(decl_51503, type, fn_maltose_103: $i > $i).
% 29.22/29.07  tff(decl_51504, type, fn_maltose_104: $i > $i).
% 29.22/29.07  tff(decl_51505, type, fn_maltose_97: $i > $i).
% 29.22/29.07  tff(decl_51506, type, fn_maltose_98: $i > $i).
% 29.22/29.07  tff(decl_51507, type, fn_maltose_29: $i > $i).
% 29.22/29.07  tff(decl_51508, type, 'Mammal': $i).
% 29.22/29.07  tff(decl_51509, type, 'Member of a clade of endothermic amniotes. Mammals have hair and feed their young with milk produced by mammary glands.': $i).
% 29.22/29.07  tff(decl_51510, type, mammal: $i).
% 29.22/29.07  tff(decl_51511, type, fn_mammal_1: $i > $i).
% 29.22/29.07  tff(decl_51512, type, fn_mammal_4: $i > $i).
% 29.22/29.07  tff(decl_51513, type, fn_mammal_5: $i > $i).
% 29.22/29.07  tff(decl_51514, type, fn_mammal_7: $i > $i).
% 29.22/29.07  tff(decl_51515, type, fn_mammal_8: $i > $i).
% 29.22/29.07  tff(decl_51516, type, fn_mammal_9: $i > $i).
% 29.22/29.07  tff(decl_51517, type, tear_1: $i > $o).
% 29.22/29.07  tff(decl_51518, type, fn_mammal_10: $i > $i).
% 29.22/29.07  tff(decl_51519, type, fn_mammal_11: $i > $i).
% 29.22/29.07  tff(decl_51520, type, fn_mammal_12: $i > $i).
% 29.22/29.07  tff(decl_51521, type, fn_mammal_13: $i > $i).
% 29.22/29.07  tff(decl_51522, type, fn_mammal_14: $i > $i).
% 29.22/29.07  tff(decl_51523, type, fn_mammal_15: $i > $i).
% 29.22/29.07  tff(decl_51524, type, fn_mammal_16: $i > $i).
% 29.22/29.07  tff(decl_51525, type, fn_mammal_17: $i > $i).
% 29.22/29.07  tff(decl_51526, type, fn_mammal_19: $i > $i).
% 29.22/29.07  tff(decl_51527, type, fn_mammal_20: $i > $i).
% 29.22/29.07  tff(decl_51528, type, fn_mammal_21: $i > $i).
% 29.22/29.07  tff(decl_51529, type, fn_mammal_22: $i > $i).
% 29.22/29.07  tff(decl_51530, type, fn_mammal_23: $i > $i).
% 29.22/29.07  tff(decl_51531, type, fn_mammal_24: $i > $i).
% 29.22/29.07  tff(decl_51532, type, fn_mammal_25: $i > $i).
% 29.22/29.07  tff(decl_51533, type, fn_mammal_26: $i > $i).
% 29.22/29.07  tff(decl_51534, type, fn_mammal_28: $i > $i).
% 29.22/29.07  tff(decl_51535, type, fn_mammal_29: $i > $i).
% 29.22/29.07  tff(decl_51536, type, fn_mammal_30: $i > $i).
% 29.22/29.07  tff(decl_51537, type, fn_mammal_31: $i > $i).
% 29.22/29.07  tff(decl_51538, type, fn_mammal_32: $i > $i).
% 29.22/29.07  tff(decl_51539, type, fn_mammal_33: $i > $i).
% 29.22/29.07  tff(decl_51540, type, fn_mammal_34: $i > $i).
% 29.22/29.07  tff(decl_51541, type, fn_mammal_35: $i > $i).
% 29.22/29.07  tff(decl_51542, type, fn_mammal_36: $i > $i).
% 29.22/29.07  tff(decl_51543, type, fn_mammal_37: $i > $i).
% 29.22/29.07  tff(decl_51544, type, fn_mammal_38: $i > $i).
% 29.22/29.07  tff(decl_51545, type, fn_mammal_40: $i > $i).
% 29.22/29.07  tff(decl_51546, type, fn_mammal_41: $i > $i).
% 29.22/29.07  tff(decl_51547, type, fn_mammal_42: $i > $i).
% 29.22/29.07  tff(decl_51548, type, fn_mammal_43: $i > $i).
% 29.22/29.07  tff(decl_51549, type, fn_mammal_44: $i > $i).
% 29.22/29.07  tff(decl_51550, type, fn_mammal_45: $i > $i).
% 29.22/29.07  tff(decl_51551, type, fn_mammal_46: $i > $i).
% 29.22/29.07  tff(decl_51552, type, fn_mammal_47: $i > $i).
% 29.22/29.07  tff(decl_51553, type, fn_mammal_48: $i > $i).
% 29.22/29.07  tff(decl_51554, type, fn_mammal_49: $i > $i).
% 29.22/29.07  tff(decl_51555, type, fn_mammal_51: $i > $i).
% 29.22/29.07  tff(decl_51556, type, fn_mammal_52: $i > $i).
% 29.22/29.07  tff(decl_51557, type, fn_mammal_53: $i > $i).
% 29.22/29.07  tff(decl_51558, type, fn_mammal_54: $i > $i).
% 29.22/29.07  tff(decl_51559, type, fn_mammal_55: $i > $i).
% 29.22/29.07  tff(decl_51560, type, fn_mammal_56: $i > $i).
% 29.22/29.07  tff(decl_51561, type, fn_mammal_57: $i > $i).
% 29.22/29.07  tff(decl_51562, type, fn_mammal_58: $i > $i).
% 29.22/29.07  tff(decl_51563, type, fn_mammal_59: $i > $i).
% 29.22/29.07  tff(decl_51564, type, fn_mammal_62: $i > $i).
% 29.22/29.07  tff(decl_51565, type, fn_mammal_63: $i > $i).
% 29.22/29.07  tff(decl_51566, type, fn_mammal_64: $i > $i).
% 29.22/29.07  tff(decl_51567, type, fn_mammal_66: $i > $i).
% 29.22/29.07  tff(decl_51568, type, fn_mammal_67: $i > $i).
% 29.22/29.07  tff(decl_51569, type, fn_mammal_68: $i > $i).
% 29.22/29.07  tff(decl_51570, type, fn_mammal_69: $i > $i).
% 29.22/29.07  tff(decl_51571, type, fn_mammal_70: $i > $i).
% 29.22/29.07  tff(decl_51572, type, vitamin_b7_1: $i > $o).
% 29.22/29.07  tff(decl_51573, type, fn_mammal_71: $i > $i).
% 29.22/29.07  tff(decl_51574, type, vitamin_b9_1: $i > $o).
% 29.22/29.07  tff(decl_51575, type, fn_mammal_72: $i > $i).
% 29.22/29.07  tff(decl_51576, type, vitamin_k_1: $i > $o).
% 29.22/29.07  tff(decl_51577, type, fn_mammal_73: $i > $i).
% 29.22/29.07  tff(decl_51578, type, fn_mammal_74: $i > $i).
% 29.22/29.07  tff(decl_51579, type, fn_mammal_86: $i > $i).
% 29.22/29.07  tff(decl_51580, type, fn_mammal_87: $i > $i).
% 29.22/29.07  tff(decl_51581, type, fn_mammal_96: $i > $i).
% 29.22/29.07  tff(decl_51582, type, fn_pancreas_1: $i > $i).
% 29.22/29.07  tff(decl_51583, type, fn_pancreas_2: $i > $i).
% 29.22/29.07  tff(decl_51584, type, fn_pancreas_cell_5: $i > $i).
% 29.22/29.07  tff(decl_51585, type, fn_pancreas_cell_79: $i > $i).
% 29.22/29.07  tff(decl_51586, type, 'M1': $i).
% 29.22/29.07  tff(decl_51587, type, 'M2': $i).
% 29.22/29.07  tff(decl_51588, type, fn_vertebrate_1: $i > $i).
% 29.22/29.07  tff(decl_51589, type, fn_vertebrate_46: $i > $i).
% 29.22/29.07  tff(decl_51590, type, fn_vertebrate_50: $i > $i).
% 29.22/29.07  tff(decl_51591, type, fn_vertebrate_49: $i > $i).
% 29.22/29.07  tff(decl_51592, type, fn_vertebrate_45: $i > $i).
% 29.22/29.07  tff(decl_51593, type, fn_vertebrate_51: $i > $i).
% 29.22/29.07  tff(decl_51594, type, 'Mammal-Cloning': $i).
% 29.22/29.07  tff(decl_51595, type, 'Mammal cloning is to reproduce a mammal with genetic materials identical to its single parent.': $i).
% 29.22/29.07  tff(decl_51596, type, 'cloning of mammal': $i).
% 29.22/29.07  tff(decl_51597, type, 'mammal cloning': $i).
% 29.22/29.07  tff(decl_51598, type, 'mammal-cloning': $i).
% 29.22/29.07  tff(decl_51599, type, reproductive_cloning_1: $i > $o).
% 29.22/29.07  tff(decl_51600, type, fn_mammal_cloning_1: $i > $i).
% 29.22/29.07  tff(decl_51601, type, fn_mammal_cloning_2: $i > $i).
% 29.22/29.07  tff(decl_51602, type, fn_mammal_cloning_3: $i > $i).
% 29.22/29.07  tff(decl_51603, type, fn_mammal_cloning_4: $i > $i).
% 29.22/29.07  tff(decl_51604, type, uterus_1: $i > $o).
% 29.22/29.07  tff(decl_51605, type, fn_mammal_cloning_5: $i > $i).
% 29.22/29.07  tff(decl_51606, type, fn_mammal_cloning_6: $i > $i).
% 29.22/29.07  tff(decl_51607, type, fn_mammal_cloning_10: $i > $i).
% 29.22/29.07  tff(decl_51608, type, fn_mammal_cloning_12: $i > $i).
% 29.22/29.07  tff(decl_51609, type, fn_mammal_cloning_20: $i > $i).
% 29.22/29.07  tff(decl_51610, type, fn_mammal_cloning_21: $i > $i).
% 29.22/29.07  tff(decl_51611, type, fn_mammal_cloning_22: $i > $i).
% 29.22/29.07  tff(decl_51612, type, fn_mammal_cloning_23: $i > $i).
% 29.22/29.07  tff(decl_51613, type, fn_mammal_cloning_26: $i > $i).
% 29.22/29.07  tff(decl_51614, type, fn_mammal_cloning_27: $i > $i).
% 29.22/29.07  tff(decl_51615, type, fn_mammal_cloning_28: $i > $i).
% 29.22/29.07  tff(decl_51616, type, fn_mammal_cloning_29: $i > $i).
% 29.22/29.07  tff(decl_51617, type, fn_mammal_cloning_30: $i > $i).
% 29.22/29.07  tff(decl_51618, type, fn_mammal_cloning_31: $i > $i).
% 29.22/29.07  tff(decl_51619, type, fn_mammal_cloning_32: $i > $i).
% 29.22/29.07  tff(decl_51620, type, udder_1: $i > $o).
% 29.22/29.07  tff(decl_51621, type, fn_mammal_cloning_33: $i > $i).
% 29.22/29.07  tff(decl_51622, type, fn_mammal_cloning_34: $i > $i).
% 29.22/29.07  tff(decl_51623, type, 'Mammal II': $i).
% 29.22/29.07  tff(decl_51624, type, fn_reproductive_cloning_7: $i > $i).
% 29.22/29.07  tff(decl_51625, type, mammal_homeotic_gene_1: $i > $o).
% 29.22/29.07  tff(decl_51626, type, 'Mammal-Homeotic-Gene': $i).
% 29.22/29.07  tff(decl_51627, type, 'Homeotic gene present in mammals.': $i).
% 29.22/29.07  tff(decl_51628, type, 'mammal homeotic gene': $i).
% 29.22/29.07  tff(decl_51629, type, 'mammal-homeotic-gene': $i).
% 29.22/29.07  tff(decl_51630, type, fn_mammal_homeotic_gene_1: $i > $i).
% 29.22/29.07  tff(decl_51631, type, fn_mammal_homeotic_gene_2: $i > $i).
% 29.22/29.07  tff(decl_51632, type, mammalian_blood_1: $i > $o).
% 29.22/29.07  tff(decl_51633, type, 'Mammalian-Blood': $i).
% 29.22/29.07  tff(decl_51634, type, 'A connective tissue in mammals with a fluid matrix called plasma.': $i).
% 29.22/29.07  tff(decl_51635, type, 'mammalian blood': $i).
% 29.22/29.07  tff(decl_51636, type, 'mammalian-blood': $i).
% 29.22/29.07  tff(decl_51637, type, 'Mammalian-Cell': $i).
% 29.22/29.07  tff(decl_51638, type, 'Mammals including human are made up of very small cells called mammalian cells .These differ from plant cells by not having cell wall These are bounded by only plasma membrane so sensitive to osmotic lysis.': $i).
% 29.22/29.07  tff(decl_51639, type, 'mammalian cell': $i).
% 29.22/29.07  tff(decl_51640, type, 'mammalian-cell': $i).
% 29.22/29.07  tff(decl_51641, type, fn_mammalian_cell_1: $i > $i).
% 29.22/29.07  tff(decl_51642, type, fn_mammalian_cell_2: $i > $i).
% 29.22/29.07  tff(decl_51643, type, mammalian_digestive_system_1: $i > $o).
% 29.22/29.07  tff(decl_51644, type, 'Mammalian-Digestive-System': $i).
% 29.22/29.07  tff(decl_51645, type, 'A system of organs in a mammal\\s body which is responsible for the digestion and absorption of nutrients from food.': $i).
% 29.22/29.07  tff(decl_51646, type, 'mammalian digestive system': $i).
% 29.22/29.07  tff(decl_51647, type, 'mammalian-digestive-system': $i).
% 29.22/29.07  tff(decl_51648, type, fn_mammalian_digestive_system_1: $i > $i).
% 29.22/29.07  tff(decl_51649, type, fn_mammalian_digestive_system_2: $i > $i).
% 29.22/29.07  tff(decl_51650, type, fn_mammalian_digestive_system_3: $i > $i).
% 29.22/29.07  tff(decl_51651, type, fn_mammalian_digestive_system_4: $i > $i).
% 29.22/29.07  tff(decl_51652, type, fn_mammalian_digestive_system_5: $i > $i).
% 29.22/29.07  tff(decl_51653, type, fn_mammalian_digestive_system_6: $i > $i).
% 29.22/29.07  tff(decl_51654, type, fn_mammalian_digestive_system_7: $i > $i).
% 29.22/29.07  tff(decl_51655, type, fn_mammalian_digestive_system_8: $i > $i).
% 29.22/29.07  tff(decl_51656, type, tongue_1: $i > $o).
% 29.22/29.07  tff(decl_51657, type, fn_mammalian_digestive_system_9: $i > $i).
% 29.22/29.07  tff(decl_51658, type, fn_mammalian_digestive_system_10: $i > $i).
% 29.22/29.07  tff(decl_51659, type, fn_mammalian_digestive_system_11: $i > $i).
% 29.22/29.07  tff(decl_51660, type, fn_mammalian_digestive_system_12: $i > $i).
% 29.22/29.07  tff(decl_51661, type, fn_mammalian_digestive_system_13: $i > $i).
% 29.22/29.07  tff(decl_51662, type, fn_mammalian_digestive_system_14: $i > $i).
% 29.22/29.07  tff(decl_51663, type, fn_mammalian_digestive_system_15: $i > $i).
% 29.22/29.07  tff(decl_51664, type, fn_mammalian_digestive_system_16: $i > $i).
% 29.22/29.07  tff(decl_51665, type, fn_mammalian_digestive_system_17: $i > $i).
% 29.22/29.07  tff(decl_51666, type, fn_mouth_1: $i > $i).
% 29.22/29.07  tff(decl_51667, type, salivary_gland_0: $i).
% 29.22/29.07  tff(decl_51668, type, 'Mammalian-Limb-Development': $i).
% 29.22/29.07  tff(decl_51669, type, 'The processes which direct the formation of the limbs during the embryonic development of a mammal.': $i).
% 29.22/29.07  tff(decl_51670, type, 'mammalian limb development': $i).
% 29.22/29.07  tff(decl_51671, type, 'mammalian-limb-development': $i).
% 29.22/29.07  tff(decl_51672, type, fn_mammalian_limb_development_1: $i > $i).
% 29.22/29.07  tff(decl_51673, type, fn_mammalian_limb_development_3: $i > $i).
% 29.22/29.07  tff(decl_51674, type, fn_mammalian_limb_development_4: $i > $i).
% 29.22/29.07  tff(decl_51675, type, fn_mammalian_limb_development_5: $i > $i).
% 29.22/29.07  tff(decl_51676, type, fn_mammalian_limb_development_6: $i > $i).
% 29.22/29.07  tff(decl_51677, type, fn_mammalian_limb_development_7: $i > $i).
% 29.22/29.07  tff(decl_51678, type, fn_mammalian_limb_development_8: $i > $i).
% 29.22/29.07  tff(decl_51679, type, fn_mammalian_limb_development_9: $i > $i).
% 29.22/29.07  tff(decl_51680, type, fn_mammalian_limb_development_10: $i > $i).
% 29.22/29.07  tff(decl_51681, type, fn_mammalian_limb_development_11: $i > $i).
% 29.22/29.07  tff(decl_51682, type, fn_mammalian_limb_development_12: $i > $i).
% 29.22/29.07  tff(decl_51683, type, fn_mammalian_limb_development_13: $i > $i).
% 29.22/29.07  tff(decl_51684, type, fn_mammalian_limb_development_16: $i > $i).
% 29.22/29.07  tff(decl_51685, type, fn_mammalian_limb_development_15: $i > $i).
% 29.22/29.07  tff(decl_51686, type, fn_mammalian_limb_development_14: $i > $i).
% 29.22/29.07  tff(decl_51687, type, 'Mammalian-Mitotic-Cycle': $i).
% 29.22/29.07  tff(decl_51688, type, 'Cell cycle followed by somatic cells in mammals. It results in daughter cells identical in genetic composition to the parent cells.': $i).
% 29.22/29.07  tff(decl_51689, type, 'mammalian mitotic cycle': $i).
% 29.22/29.07  tff(decl_51690, type, 'mammalian-mitotic-cycle': $i).
% 29.22/29.07  tff(decl_51691, type, fn_mammalian_mitotic_cycle_1: $i > $i).
% 29.22/29.07  tff(decl_51692, type, fn_mammalian_mitotic_cycle_5: $i > $i).
% 29.22/29.07  tff(decl_51693, type, fn_mammalian_mitotic_cycle_6: $i > $i).
% 29.22/29.07  tff(decl_51694, type, fn_mammalian_mitotic_cycle_7: $i > $i).
% 29.22/29.07  tff(decl_51695, type, fn_mammalian_mitotic_cycle_8: $i > $i).
% 29.22/29.07  tff(decl_51696, type, telophase_1: $i > $o).
% 29.22/29.07  tff(decl_51697, type, fn_mammalian_mitotic_cycle_9: $i > $i).
% 29.22/29.07  tff(decl_51698, type, fn_mammalian_mitotic_cycle_10: $i > $i).
% 29.22/29.07  tff(decl_51699, type, fn_mammalian_mitotic_cycle_12: $i > $i).
% 29.22/29.07  tff(decl_51700, type, fn_mitosis_39: $i > $i).
% 29.22/29.07  tff(decl_51701, type, fn_telophase_18: $i > $i).
% 29.22/29.07  tff(decl_51702, type, fn_mitotic_cell_cycle_37: $i > $i).
% 29.22/29.07  tff(decl_51703, type, fn_mitotic_cell_cycle_36: $i > $i).
% 29.22/29.07  tff(decl_51704, type, 'Mammary-Cell': $i).
% 29.22/29.07  tff(decl_51705, type, 'The mammary cells are differentiated cells.': $i).
% 29.22/29.07  tff(decl_51706, type, 'mammary cell': $i).
% 29.22/29.07  tff(decl_51707, type, 'mammary-cell': $i).
% 29.22/29.07  tff(decl_51708, type, 'Mammary-Glands': $i).
% 29.22/29.07  tff(decl_51709, type, 'Exocrine glands in female mammals that produce milk to feed offspring.': $i).
% 29.22/29.07  tff(decl_51710, type, 'mammary glands': $i).
% 29.22/29.07  tff(decl_51711, type, 'mammary gland': $i).
% 29.22/29.07  tff(decl_51712, type, 'mammary-gland': $i).
% 29.22/29.07  tff(decl_51713, type, 'Mandible': $i).
% 29.22/29.07  tff(decl_51714, type, 'Either of the paired jaw-like feeding appendages surrounding the mouth in crustaceans, hexapods, and myriapods. Also refers to the lower jaw of many vertebrates.': $i).
% 29.22/29.07  tff(decl_51715, type, 'Manganese': $i).
% 29.22/29.07  tff(decl_51716, type, 'Manganese is a metal atom with atomic number 25. It is represented by the symbol Mn.': $i).
% 29.22/29.07  tff(decl_51717, type, manganese: $i).
% 29.22/29.07  tff(decl_51718, type, 'Mn': $i).
% 29.22/29.07  tff(decl_51719, type, fn_manganese_3: $i > $i).
% 29.22/29.07  tff(decl_51720, type, fn_manganese_4: $i > $i).
% 29.22/29.07  tff(decl_51721, type, fn_manganese_5: $i > $i).
% 29.22/29.07  tff(decl_51722, type, fn_manganese_9: $i > $i).
% 29.22/29.07  tff(decl_51723, type, fn_manganese_10: $i > $i).
% 29.22/29.07  tff(decl_51724, type, fn_manganese_11: $i > $i).
% 29.22/29.07  tff(decl_51725, type, fn_manganese_12: $i > $i).
% 29.22/29.07  tff(decl_51726, type, "1.55": $i).
% 29.22/29.07  tff(decl_51727, type, "54.94": $i).
% 29.22/29.07  tff(decl_51728, type, fn_manganese_7: $i > $i).
% 29.22/29.07  tff(decl_51729, type, fn_manganese_8: $i > $i).
% 29.22/29.07  tff(decl_51730, type, fn_manganese_6: $i > $i).
% 29.22/29.07  tff(decl_51731, type, 'Manner-Constant': $i).
% 29.22/29.07  tff(decl_51732, type, 'constant of manner': $i).
% 29.22/29.07  tff(decl_51733, type, 'manner constant': $i).
% 29.22/29.07  tff(decl_51734, type, 'manner-constant': $i).
% 29.22/29.07  tff(decl_51735, type, 'Manner-Value': $i).
% 29.22/29.07  tff(decl_51736, type, 'the manner in which an Event happens': $i).
% 29.22/29.07  tff(decl_51737, type, mode: $i).
% 29.22/29.07  tff(decl_51738, type, style: $i).
% 29.22/29.07  tff(decl_51739, type, fashion: $i).
% 29.22/29.07  tff(decl_51740, type, 'personal manner': $i).
% 29.22/29.07  tff(decl_51741, type, manner: $i).
% 29.22/29.07  tff(decl_51742, type, 'value of manner': $i).
% 29.22/29.07  tff(decl_51743, type, 'manner value': $i).
% 29.22/29.07  tff(decl_51744, type, 'manner-value': $i).
% 29.22/29.07  tff(decl_51745, type, mantle_1: $i > $o).
% 29.22/29.07  tff(decl_51746, type, 'Mantle': $i).
% 29.22/29.07  tff(decl_51747, type, 'A fold of tissue that covers a mollusc\\s visceral mass and secretes the shell.': $i).
% 29.22/29.07  tff(decl_51748, type, mantle: $i).
% 29.22/29.07  tff(decl_51749, type, 'Mantle-Cavity': $i).
% 29.22/29.08  tff(decl_51750, type, 'A water-filled space between the visceral mass and mantle of a mollusc. Certain organs, including gills and anus, are located in the mantle cavity.': $i).
% 29.22/29.08  tff(decl_51751, type, 'cavity of mantle': $i).
% 29.22/29.08  tff(decl_51752, type, 'mantle cavity': $i).
% 29.22/29.08  tff(decl_51753, type, 'mantle-cavity': $i).
% 29.22/29.08  tff(decl_51754, type, 'Map': $i).
% 29.22/29.08  tff(decl_51755, type, 'A map is a visual representation of an area or a method of presenting data in a visual way for clarification.': $i).
% 29.22/29.08  tff(decl_51756, type, 'Map-Unit': $i).
% 29.22/29.08  tff(decl_51757, type, 'Relative distance between genes on a chromosome.': $i).
% 29.22/29.08  tff(decl_51758, type, centimorgan: $i).
% 29.22/29.08  tff(decl_51759, type, 'unit of map': $i).
% 29.22/29.08  tff(decl_51760, type, 'map unit': $i).
% 29.22/29.08  tff(decl_51761, type, 'map-unit': $i).
% 29.22/29.08  tff(decl_51762, type, fn_map_unit_4: $i > $i).
% 29.22/29.08  tff(decl_51763, type, fn_map_unit_6: $i > $i).
% 29.22/29.08  tff(decl_51764, type, fn_map_unit_7: $i > $i).
% 29.22/29.08  tff(decl_51765, type, fn_map_unit_8: $i > $i).
% 29.22/29.08  tff(decl_51766, type, fn_map_unit_10: $i > $i).
% 29.22/29.08  tff(decl_51767, type, fn_map_unit_11: $i > $i).
% 29.22/29.08  tff(decl_51768, type, fn_recombination_frequency_1: $i > $i).
% 29.22/29.08  tff(decl_51769, type, fn_recombination_frequency_2: $i > $i).
% 29.22/29.08  tff(decl_51770, type, 'FrequencyOfRecombination': $i).
% 29.22/29.08  tff(decl_51771, type, is_between_0: $i).
% 29.22/29.08  tff(decl_51772, type, 'LengthOfMapUnit': $i).
% 29.22/29.08  tff(decl_51773, type, 'Margarine': $i).
% 29.22/29.08  tff(decl_51774, type, 'A butter substitute produced mainly from vegetable oil.': $i).
% 29.22/29.08  tff(decl_51775, type, margarine: $i).
% 29.22/29.08  tff(decl_51776, type, 'Marine-Benthic-Zone': $i).
% 29.22/29.08  tff(decl_51777, type, 'The bottom surface of a marine ecosystem. The ocean floor.': $i).
% 29.22/29.08  tff(decl_51778, type, 'marine benthic zone': $i).
% 29.22/29.08  tff(decl_51779, type, 'marine-benthic-zone': $i).
% 29.22/29.08  tff(decl_51780, type, 'Marine-Biome': $i).
% 29.22/29.08  tff(decl_51781, type, 'An aquatic biome distinguished on the basis of physical and chemical characteristics, most notably the presence of salt concentrations which average 3% or higher. Marine biomes include the oceans which cover approximately 75% of the Earth\\s surface.': $i).
% 29.22/29.08  tff(decl_51782, type, 'biome of marine': $i).
% 29.22/29.08  tff(decl_51783, type, 'marine biome': $i).
% 29.22/29.08  tff(decl_51784, type, 'marine-biome': $i).
% 29.22/29.08  tff(decl_51785, type, marine_invertebrate_1: $i > $o).
% 29.22/29.08  tff(decl_51786, type, 'Marine-Invertebrate': $i).
% 29.22/29.08  tff(decl_51787, type, 'Invertebrates found in marine environment are marine invertebrates.': $i).
% 29.22/29.08  tff(decl_51788, type, 'invertebrate of marine': $i).
% 29.22/29.08  tff(decl_51789, type, 'marine invertebrate': $i).
% 29.22/29.08  tff(decl_51790, type, 'marine-invertebrate': $i).
% 29.22/29.08  tff(decl_51791, type, 'Marine-Mammal': $i).
% 29.22/29.08  tff(decl_51792, type, 'Specialized group of mammals adapted for life in the ocean.': $i).
% 29.22/29.08  tff(decl_51793, type, 'mammal of marine': $i).
% 29.22/29.08  tff(decl_51794, type, 'marine mammal': $i).
% 29.22/29.08  tff(decl_51795, type, 'marine-mammal': $i).
% 29.22/29.08  tff(decl_51796, type, 'Mark': $i).
% 29.22/29.08  tff(decl_51797, type, write: $i).
% 29.22/29.08  tff(decl_51798, type, fn_mark_1: $i > $i).
% 29.22/29.08  tff(decl_51799, type, fn_mark_2: $i > $i).
% 29.22/29.08  tff(decl_51800, type, physical_mark_1: $i > $o).
% 29.22/29.08  tff(decl_51801, type, 'Mark-Recapture-Method': $i).
% 29.22/29.08  tff(decl_51802, type, 'A sampling technique often used to estimate fish and wildlife populations.': $i).
% 29.22/29.08  tff(decl_51803, type, 'mark recapture method': $i).
% 29.22/29.08  tff(decl_51804, type, 'mark-recapture-method': $i).
% 29.22/29.08  tff(decl_51805, type, population_biology_technique_1: $i > $o).
% 29.22/29.08  tff(decl_51806, type, 'Marsupial': $i).
% 29.22/29.08  tff(decl_51807, type, 'A group of mammals whose young are born precociously and complete their fetal development inside a pouch on their mother\\s belly. Examples include koalas, opossums, and kangaroos.': $i).
% 29.22/29.08  tff(decl_51808, type, marsupial: $i).
% 29.22/29.08  tff(decl_51809, type, 'Mass-Constant': $i).
% 29.22/29.08  tff(decl_51810, type, 'constant of mass': $i).
% 29.22/29.08  tff(decl_51811, type, 'mass constant': $i).
% 29.22/29.08  tff(decl_51812, type, 'mass-constant': $i).
% 29.22/29.08  tff(decl_51813, type, mass_extinction_1: $i > $o).
% 29.22/29.08  tff(decl_51814, type, 'Mass-Extinction': $i).
% 29.22/29.08  tff(decl_51815, type, 'A widespread and rapid decrease in the diversity of life on Earth, in which species across many taxa go extinct. Mass extinction occurs when the extinction rate increases more rapidly than the rate of speciation.': $i).
% 29.22/29.08  tff(decl_51816, type, 'extinction of mass': $i).
% 29.22/29.08  tff(decl_51817, type, 'mass extinction': $i).
% 29.22/29.08  tff(decl_51818, type, 'mass-extinction': $i).
% 29.22/29.08  tff(decl_51819, type, mass_scale_1: $i > $o).
% 29.22/29.08  tff(decl_51820, type, 'Mass-Scale': $i).
% 29.22/29.08  tff(decl_51821, type, 'scale of mass': $i).
% 29.22/29.08  tff(decl_51822, type, 'mass scale': $i).
% 29.22/29.08  tff(decl_51823, type, 'mass-scale': $i).
% 29.22/29.08  tff(decl_51824, type, 'Mass-Value': $i).
% 29.22/29.08  tff(decl_51825, type, 'the property of a body that causes it to have weight in a gravitational field': $i).
% 29.22/29.08  tff(decl_51826, type, mass: $i).
% 29.22/29.08  tff(decl_51827, type, 'atomic-mass': $i).
% 29.22/29.08  tff(decl_51828, type, 'value of mass': $i).
% 29.22/29.08  tff(decl_51829, type, 'mass value': $i).
% 29.22/29.08  tff(decl_51830, type, 'mass-value': $i).
% 29.22/29.08  tff(decl_51831, type, 'Mast-Cell': $i).
% 29.22/29.08  tff(decl_51832, type, 'A type of cell found in various vertebrate tissues. Mast cells contain granules of histamine and heparin, which, when released, trigger an inflammatory response to pathogens and allergens.': $i).
% 29.22/29.08  tff(decl_51833, type, 'cell of mast': $i).
% 29.22/29.08  tff(decl_51834, type, 'mast cell': $i).
% 29.22/29.08  tff(decl_51835, type, 'mast-cell': $i).
% 29.22/29.08  tff(decl_51836, type, 'Master-Control-Gene': $i).
% 29.22/29.08  tff(decl_51837, type, 'A single gene that, when expressed, initiates the development of a specific tissue or organ by activating many other genes.': $i).
% 29.22/29.08  tff(decl_51838, type, 'master regulatory gene': $i).
% 29.22/29.08  tff(decl_51839, type, 'master control gene': $i).
% 29.22/29.08  tff(decl_51840, type, 'master-control-gene': $i).
% 29.22/29.08  tff(decl_51841, type, fn_master_control_gene_3: $i > $i).
% 29.22/29.08  tff(decl_51842, type, fn_master_control_gene_7: $i > $i).
% 29.22/29.08  tff(decl_51843, type, fn_master_control_gene_9: $i > $i).
% 29.22/29.08  tff(decl_51844, type, fn_master_control_gene_10: $i > $i).
% 29.22/29.08  tff(decl_51845, type, fn_master_control_gene_11: $i > $i).
% 29.22/29.08  tff(decl_51846, type, match_result_viewpoint_1: $i > $o).
% 29.22/29.08  tff(decl_51847, type, 'Match-Result-Viewpoint': $i).
% 29.22/29.08  tff(decl_51848, type, 'match result viewpoint': $i).
% 29.22/29.08  tff(decl_51849, type, 'match-result-viewpoint': $i).
% 29.22/29.08  tff(decl_51850, type, mate_choice_copying_1: $i > $o).
% 29.22/29.08  tff(decl_51851, type, 'Mate-Choice-Copying': $i).
% 29.22/29.08  tff(decl_51852, type, 'Behavior in which individual mate choice is based on mate choices of other individuals in the population.': $i).
% 29.22/29.08  tff(decl_51853, type, 'mate choice copying': $i).
% 29.22/29.08  tff(decl_51854, type, 'mate-choice-copying': $i).
% 29.22/29.08  tff(decl_51855, type, maternal_chromosome_1: $i > $o).
% 29.22/29.08  tff(decl_51856, type, 'Maternal-Chromosome': $i).
% 29.22/29.08  tff(decl_51857, type, 'One of a pair of homologous chromosomes originating from the female gamete.': $i).
% 29.22/29.08  tff(decl_51858, type, 'maternal chromosome': $i).
% 29.22/29.08  tff(decl_51859, type, 'maternal-chromosome': $i).
% 29.22/29.08  tff(decl_51860, type, fn_maternal_chromosome_1: $i > $i).
% 29.22/29.08  tff(decl_51861, type, fn_maternal_chromosome_2: $i > $i).
% 29.22/29.08  tff(decl_51862, type, maternal_effect_1: $i > $o).
% 29.22/29.08  tff(decl_51863, type, 'Maternal-Effect': $i).
% 29.22/29.08  tff(decl_51864, type, 'A situation in which the phenotype of an organism is influenced by the environment and genotype of the mother despite the organism\\s own genotype.': $i).
% 29.22/29.08  tff(decl_51865, type, 'maternal effect': $i).
% 29.22/29.08  tff(decl_51866, type, 'maternal-effect': $i).
% 29.22/29.08  tff(decl_51867, type, 'Maternal-Effect-Gene': $i).
% 29.22/29.08  tff(decl_51868, type, 'A gene whose condition (i.e., mutant or not) in the mother determines the phenotype of the offspring, regardless of the offspring\\s genotype.': $i).
% 29.22/29.08  tff(decl_51869, type, 'egg polarity gene': $i).
% 29.22/29.08  tff(decl_51870, type, 'egg-polarity-gene': $i).
% 29.22/29.08  tff(decl_51871, type, 'maternal effect gene': $i).
% 29.22/29.08  tff(decl_51872, type, 'maternal-effect-gene': $i).
% 29.22/29.08  tff(decl_51873, type, fn_maternal_effect_gene_1: $i > $i).
% 29.22/29.08  tff(decl_51874, type, fn_maternal_effect_gene_2: $i > $i).
% 29.22/29.08  tff(decl_51875, type, fn_maternal_effect_gene_3: $i > $i).
% 29.22/29.08  tff(decl_51876, type, fn_maternal_effect_gene_4: $i > $i).
% 29.22/29.08  tff(decl_51877, type, fn_maternal_effect_gene_5: $i > $i).
% 29.22/29.08  tff(decl_51878, type, fn_maternal_effect_gene_6: $i > $i).
% 29.22/29.08  tff(decl_51879, type, fn_maternal_effect_gene_7: $i > $i).
% 29.22/29.08  tff(decl_51880, type, fn_maternal_effect_gene_8: $i > $i).
% 29.22/29.08  tff(decl_51881, type, fn_maternal_effect_gene_9: $i > $i).
% 29.22/29.08  tff(decl_51882, type, fn_maternal_effect_gene_10: $i > $i).
% 29.22/29.08  tff(decl_51883, type, fn_maternal_effect_gene_11: $i > $i).
% 29.22/29.08  tff(decl_51884, type, fn_maternal_effect_gene_12: $i > $i).
% 29.22/29.08  tff(decl_51885, type, fn_maternal_effect_gene_13: $i > $i).
% 29.22/29.08  tff(decl_51886, type, fn_maternal_effect_gene_14: $i > $i).
% 29.22/29.08  tff(decl_51887, type, fn_maternal_effect_gene_15: $i > $i).
% 29.22/29.08  tff(decl_51888, type, fn_maternal_effect_gene_16: $i > $i).
% 29.22/29.08  tff(decl_51889, type, fn_maternal_effect_gene_17: $i > $i).
% 29.22/29.08  tff(decl_51890, type, fn_maternal_effect_gene_18: $i > $i).
% 29.22/29.08  tff(decl_51891, type, fn_maternal_effect_gene_19: $i > $i).
% 29.22/29.08  tff(decl_51892, type, fn_maternal_effect_gene_22: $i > $i).
% 29.22/29.08  tff(decl_51893, type, fn_maternal_effect_gene_23: $i > $i).
% 29.22/29.08  tff(decl_51894, type, fn_maternal_effect_gene_24: $i > $i).
% 29.22/29.08  tff(decl_51895, type, fn_maternal_effect_gene_25: $i > $i).
% 29.22/29.08  tff(decl_51896, type, fn_maternal_effect_gene_26: $i > $i).
% 29.22/29.08  tff(decl_51897, type, fn_maternal_effect_gene_20: $i > $i).
% 29.22/29.08  tff(decl_51898, type, fn_sex_linked_gene_1: $i > $i).
% 29.22/29.08  tff(decl_51899, type, fn_maternal_effect_gene_21: $i > $i).
% 29.22/29.08  tff(decl_51900, type, fn_sex_linked_gene_2: $i > $i).
% 29.22/29.08  tff(decl_51901, type, fn_sex_linked_gene_10: $i > $i).
% 29.22/29.08  tff(decl_51902, type, fn_maternal_effect_gene_27: $i > $i).
% 29.22/29.08  tff(decl_51903, type, fn_sex_linked_gene_6: $i > $i).
% 29.22/29.08  tff(decl_51904, type, fn_maternal_effect_gene_28: $i > $i).
% 29.22/29.08  tff(decl_51905, type, fn_sex_linked_gene_5: $i > $i).
% 29.22/29.08  tff(decl_51906, type, fn_sex_linked_gene_9: $i > $i).
% 29.22/29.08  tff(decl_51907, type, fn_sex_linked_gene_8: $i > $i).
% 29.22/29.08  tff(decl_51908, type, fn_sex_linked_gene_15: $i > $i).
% 29.22/29.08  tff(decl_51909, type, fn_sex_linked_gene_7: $i > $i).
% 29.22/29.08  tff(decl_51910, type, fn_sex_linked_gene_14: $i > $i).
% 29.22/29.08  tff(decl_51911, type, fn_sex_linked_gene_3: $i > $i).
% 29.22/29.08  tff(decl_51912, type, fn_sex_linked_gene_4: $i > $i).
% 29.22/29.08  tff(decl_51913, type, fn_sex_linked_gene_13: $i > $i).
% 29.22/29.08  tff(decl_51914, type, fn_sex_linked_gene_11: $i > $i).
% 29.22/29.08  tff(decl_51915, type, fn_sex_linked_gene_12: $i > $i).
% 29.22/29.08  tff(decl_51916, type, fn_sex_linked_gene_17: $i > $i).
% 29.22/29.08  tff(decl_51917, type, fn_sex_linked_gene_16: $i > $i).
% 29.22/29.08  tff(decl_51918, type, 'Maternal-Effect-Gene-Mutation': $i).
% 29.22/29.08  tff(decl_51919, type, 'A gene mutation, that when mutant in the mother, results in a mutant phenotype in the offspring, regardless of the offspring\\s genotype.': $i).
% 29.22/29.08  tff(decl_51920, type, 'maternal effect gene mutation': $i).
% 29.22/29.08  tff(decl_51921, type, 'maternal-effect-gene-mutation': $i).
% 29.22/29.08  tff(decl_51922, type, fn_maternal_effect_gene_mutation_1: $i > $i).
% 29.22/29.08  tff(decl_51923, type, fn_maternal_effect_gene_mutation_2: $i > $i).
% 29.22/29.08  tff(decl_51924, type, fn_maternal_effect_gene_mutation_4: $i > $i).
% 29.22/29.08  tff(decl_51925, type, maternal_substance_1: $i > $o).
% 29.22/29.08  tff(decl_51926, type, 'Maternal-Substance': $i).
% 29.22/29.08  tff(decl_51927, type, 'The maternal substances in the egg that influence the course of early development, called cytoplasmic determinants,regulate the expression of genes that affect the developmental fate of the cells.': $i).
% 29.22/29.08  tff(decl_51928, type, 'maternal substance': $i).
% 29.22/29.08  tff(decl_51929, type, 'maternal-substance': $i).
% 29.22/29.08  tff(decl_51930, type, fn_maternal_substance_1: $i > $i).
% 29.22/29.08  tff(decl_51931, type, mathematical_model_1: $i > $o).
% 29.22/29.08  tff(decl_51932, type, 'Mathematical-Model': $i).
% 29.22/29.08  tff(decl_51933, type, 'A method of representing data or information based on mathematical formulas.': $i).
% 29.22/29.08  tff(decl_51934, type, 'mathematical model': $i).
% 29.22/29.08  tff(decl_51935, type, 'mathematical-model': $i).
% 29.22/29.08  tff(decl_51936, type, matheos_experiment_1: $i > $o).
% 29.22/29.08  tff(decl_51937, type, 'Matheos-Experiment': $i).
% 29.22/29.08  tff(decl_51938, type, 'Experiment conducted by D. Matheos and colleagues at Princeton University which studied the communication pathways used by mating yeast.': $i).
% 29.22/29.08  tff(decl_51939, type, 'matheos experiment': $i).
% 29.22/29.08  tff(decl_51940, type, 'matheos-experiment': $i).
% 29.22/29.08  tff(decl_51941, type, fn_matheos_experiment_1: $i > $i).
% 29.22/29.08  tff(decl_51942, type, fn_matheos_experiment_2: $i > $i).
% 29.22/29.08  tff(decl_51943, type, fn_matheos_experiment_5: $i > $i).
% 29.22/29.08  tff(decl_51944, type, fn_matheos_experiment_6: $i > $i).
% 29.22/29.08  tff(decl_51945, type, fn_matheos_experiment_7: $i > $i).
% 29.22/29.08  tff(decl_51946, type, fn_matheos_experiment_8: $i > $i).
% 29.22/29.08  tff(decl_51947, type, fn_matheos_experiment_11: $i > $i).
% 29.22/29.08  tff(decl_51948, type, fn_matheos_experiment_12: $i > $i).
% 29.22/29.08  tff(decl_51949, type, fn_matheos_experiment_13: $i > $i).
% 29.22/29.08  tff(decl_51950, type, fn_matheos_experiment_15: $i > $i).
% 29.22/29.08  tff(decl_51951, type, fn_matheos_experiment_17: $i > $i).
% 29.22/29.08  tff(decl_51952, type, fn_matheos_experiment_18: $i > $i).
% 29.22/29.08  tff(decl_51953, type, fn_matheos_experiment_19: $i > $i).
% 29.22/29.08  tff(decl_51954, type, fn_matheos_experiment_23: $i > $i).
% 29.22/29.08  tff(decl_51955, type, fn_matheos_experiment_24: $i > $i).
% 29.22/29.08  tff(decl_51956, type, fn_matheos_experiment_27: $i > $i).
% 29.22/29.08  tff(decl_51957, type, fn_matheos_experiment_28: $i > $i).
% 29.22/29.08  tff(decl_51958, type, fn_matheos_experiment_29: $i > $i).
% 29.22/29.08  tff(decl_51959, type, fn_matheos_experiment_30: $i > $i).
% 29.22/29.08  tff(decl_51960, type, fn_matheos_experiment_31: $i > $i).
% 29.22/29.08  tff(decl_51961, type, fn_matheos_experiment_32: $i > $i).
% 29.22/29.08  tff(decl_51962, type, fn_matheos_experiment_33: $i > $i).
% 29.22/29.08  tff(decl_51963, type, fn_matheos_experiment_34: $i > $i).
% 29.22/29.08  tff(decl_51964, type, fn_matheos_experiment_35: $i > $i).
% 29.22/29.08  tff(decl_51965, type, fn_matheos_experiment_36: $i > $i).
% 29.22/29.08  tff(decl_51966, type, fn_matheos_experiment_37: $i > $i).
% 29.22/29.08  tff(decl_51967, type, shmoo_1: $i > $o).
% 29.22/29.08  tff(decl_51968, type, fn_matheos_experiment_38: $i > $i).
% 29.22/29.08  tff(decl_51969, type, fn_matheos_experiment_39: $i > $i).
% 29.22/29.08  tff(decl_51970, type, fn_matheos_experiment_40: $i > $i).
% 29.22/29.08  tff(decl_51971, type, fn_matheos_experiment_41: $i > $i).
% 29.22/29.08  tff(decl_51972, type, fn_matheos_experiment_42: $i > $i).
% 29.22/29.08  tff(decl_51973, type, fn_matheos_experiment_43: $i > $i).
% 29.22/29.08  tff(decl_51974, type, fn_matheos_experiment_44: $i > $i).
% 29.22/29.08  tff(decl_51975, type, fn_matheos_experiment_45: $i > $i).
% 29.22/29.08  tff(decl_51976, type, fn_matheos_experiment_46: $i > $i).
% 29.22/29.08  tff(decl_51977, type, fn_matheos_experiment_47: $i > $i).
% 29.22/29.08  tff(decl_51978, type, fn_matheos_experiment_48: $i > $i).
% 29.22/29.08  tff(decl_51979, type, fn_matheos_experiment_49: $i > $i).
% 29.22/29.08  tff(decl_51980, type, fn_matheos_experiment_50: $i > $i).
% 29.22/29.08  tff(decl_51981, type, fn_matheos_experiment_51: $i > $i).
% 29.22/29.08  tff(decl_51982, type, fn_matheos_experiment_52: $i > $i).
% 29.22/29.08  tff(decl_51983, type, fn_matheos_experiment_53: $i > $i).
% 29.22/29.08  tff(decl_51984, type, fn_matheos_experiment_54: $i > $i).
% 29.22/29.08  tff(decl_51985, type, fn_matheos_experiment_55: $i > $i).
% 29.22/29.08  tff(decl_51986, type, fn_matheos_experiment_56: $i > $i).
% 29.22/29.08  tff(decl_51987, type, fn_matheos_experiment_57: $i > $i).
% 29.22/29.08  tff(decl_51988, type, fn_matheos_experiment_58: $i > $i).
% 29.22/29.08  tff(decl_51989, type, fn_matheos_experiment_59: $i > $i).
% 29.22/29.08  tff(decl_51990, type, fn_matheos_experiment_60: $i > $i).
% 29.22/29.08  tff(decl_51991, type, fn_matheos_experiment_61: $i > $i).
% 29.22/29.08  tff(decl_51992, type, fn_matheos_experiment_62: $i > $i).
% 29.22/29.08  tff(decl_51993, type, fn_matheos_experiment_63: $i > $i).
% 29.22/29.08  tff(decl_51994, type, fn_matheos_experiment_64: $i > $i).
% 29.22/29.08  tff(decl_51995, type, fn_matheos_experiment_65: $i > $i).
% 29.22/29.08  tff(decl_51996, type, fn_matheos_experiment_66: $i > $i).
% 29.22/29.08  tff(decl_51997, type, fn_matheos_experiment_67: $i > $i).
% 29.22/29.08  tff(decl_51998, type, fn_matheos_experiment_68: $i > $i).
% 29.22/29.08  tff(decl_51999, type, fn_matheos_experiment_69: $i > $i).
% 29.22/29.08  tff(decl_52000, type, fn_matheos_experiment_70: $i > $i).
% 29.22/29.08  tff(decl_52001, type, fn_matheos_experiment_71: $i > $i).
% 29.22/29.08  tff(decl_52002, type, fn_matheos_experiment_72: $i > $i).
% 29.22/29.08  tff(decl_52003, type, fn_matheos_experiment_73: $i > $i).
% 29.22/29.08  tff(decl_52004, type, fn_matheos_experiment_74: $i > $i).
% 29.22/29.08  tff(decl_52005, type, fn_matheos_experiment_75: $i > $i).
% 29.22/29.08  tff(decl_52006, type, fn_matheos_experiment_76: $i > $i).
% 29.22/29.08  tff(decl_52007, type, fn_matheos_experiment_77: $i > $i).
% 29.22/29.08  tff(decl_52008, type, fn_matheos_experiment_78: $i > $i).
% 29.22/29.08  tff(decl_52009, type, fn_matheos_experiment_79: $i > $i).
% 29.22/29.08  tff(decl_52010, type, fn_yeast_21: $i > $i).
% 29.22/29.08  tff(decl_52011, type, fn_yeast_18: $i > $i).
% 29.22/29.08  tff(decl_52012, type, 'Mating': $i).
% 29.22/29.08  tff(decl_52013, type, 'The pairing of opposite-sex or hermaphroditic organisms for copulation or sperm transfer.': $i).
% 29.22/29.08  tff(decl_52014, type, mate: $i).
% 29.22/29.08  tff(decl_52015, type, 'Mating-Factor': $i).
% 29.22/29.08  tff(decl_52016, type, 'Signaling molecule which induces the mating response in yeast cells. There are two yeast mating factors, produced by two mating types, alpha and a. Mating type \\alpha\\ produces alpha mating factor, and  mating type \\a\\ produces a mating factor.': $i).
% 29.22/29.08  tff(decl_52017, type, 'factor of mating': $i).
% 29.22/29.08  tff(decl_52018, type, 'mating factor': $i).
% 29.22/29.08  tff(decl_52019, type, 'mating-factor': $i).
% 29.22/29.08  tff(decl_52020, type, pheromone_1: $i > $o).
% 29.22/29.08  tff(decl_52021, type, 'Mating-Factor-A': $i).
% 29.22/29.08  tff(decl_52022, type, 'Signaling molecule produced by mating type a yeast cells, which communicates the presence of the mating type a cell to nearby mating type alpha cells.': $i).
% 29.22/29.08  tff(decl_52023, type, 'mating factor a': $i).
% 29.22/29.08  tff(decl_52024, type, 'mating-factor-a': $i).
% 29.22/29.08  tff(decl_52025, type, fn_mating_factor_a_3: $i > $i).
% 29.22/29.08  tff(decl_52026, type, fn_mating_factor_a_4: $i > $i).
% 29.22/29.08  tff(decl_52027, type, fn_mating_factor_a_5: $i > $i).
% 29.22/29.08  tff(decl_52028, type, fn_mating_factor_a_6: $i > $i).
% 29.22/29.08  tff(decl_52029, type, fn_mating_factor_a_7: $i > $i).
% 29.22/29.08  tff(decl_52030, type, fn_mating_factor_a_8: $i > $i).
% 29.22/29.08  tff(decl_52031, type, fn_mating_factor_a_9: $i > $i).
% 29.22/29.08  tff(decl_52032, type, fn_mating_factor_a_10: $i > $i).
% 29.22/29.08  tff(decl_52033, type, yeast_mating_factor_1: $i > $o).
% 29.22/29.08  tff(decl_52034, type, fn_mating_factor_a_2: $i > $i).
% 29.22/29.08  tff(decl_52035, type, fn_mating_factor_a_1: $i > $i).
% 29.22/29.08  tff(decl_52036, type, 'Mating-Factor-Alpha': $i).
% 29.22/29.08  tff(decl_52037, type, 'Signaling molecule produced by mating type alpha yeast cells, which communicates the presence of the mating type alpha cell to nearby mating type a cells.': $i).
% 29.22/29.08  tff(decl_52038, type, 'mating factor alpha': $i).
% 29.22/29.08  tff(decl_52039, type, 'mating-factor-alpha': $i).
% 29.22/29.08  tff(decl_52040, type, fn_mating_factor_alpha_3: $i > $i).
% 29.22/29.08  tff(decl_52041, type, fn_mating_factor_alpha_4: $i > $i).
% 29.22/29.08  tff(decl_52042, type, fn_mating_factor_alpha_5: $i > $i).
% 29.22/29.08  tff(decl_52043, type, fn_mating_factor_alpha_6: $i > $i).
% 29.22/29.08  tff(decl_52044, type, fn_mating_factor_alpha_7: $i > $i).
% 29.22/29.08  tff(decl_52045, type, fn_mating_factor_alpha_8: $i > $i).
% 29.22/29.08  tff(decl_52046, type, fn_mating_factor_alpha_9: $i > $i).
% 29.22/29.08  tff(decl_52047, type, fn_mating_factor_alpha_10: $i > $i).
% 29.22/29.08  tff(decl_52048, type, fn_mating_factor_alpha_2: $i > $i).
% 29.22/29.08  tff(decl_52049, type, fn_mating_factor_alpha_1: $i > $i).
% 29.22/29.08  tff(decl_52050, type, mating_of_saccharomyces_cerevisiae_1: $i > $o).
% 29.22/29.08  tff(decl_52051, type, 'Mating-of-Saccharomyces-Cerevisiae': $i).
% 29.22/29.08  tff(decl_52052, type, 'Process of genetic exchange between different mating types, alpha and a , of haploid yeast cells, resulting in the formation of diploid yeast cells.': $i).
% 29.22/29.08  tff(decl_52053, type, 'mating of saccharomyces cerevisiae': $i).
% 29.22/29.08  tff(decl_52054, type, 'mating-of-saccharomyces-cerevisiae': $i).
% 29.22/29.08  tff(decl_52055, type, fn_mating_of_saccharomyces_cerevisiae_1: $i > $i).
% 29.22/29.08  tff(decl_52056, type, fn_mating_of_saccharomyces_cerevisiae_2: $i > $i).
% 29.22/29.08  tff(decl_52057, type, fn_mating_of_saccharomyces_cerevisiae_3: $i > $i).
% 29.22/29.08  tff(decl_52058, type, fn_mating_of_saccharomyces_cerevisiae_4: $i > $i).
% 29.22/29.08  tff(decl_52059, type, fn_mating_of_saccharomyces_cerevisiae_5: $i > $i).
% 29.22/29.08  tff(decl_52060, type, fn_mating_of_saccharomyces_cerevisiae_6: $i > $i).
% 29.22/29.08  tff(decl_52061, type, fn_mating_of_saccharomyces_cerevisiae_7: $i > $i).
% 29.22/29.08  tff(decl_52062, type, fn_mating_of_saccharomyces_cerevisiae_8: $i > $i).
% 29.22/29.08  tff(decl_52063, type, fn_mating_of_saccharomyces_cerevisiae_9: $i > $i).
% 29.22/29.08  tff(decl_52064, type, fn_mating_of_saccharomyces_cerevisiae_10: $i > $i).
% 29.22/29.08  tff(decl_52065, type, fn_mating_of_saccharomyces_cerevisiae_11: $i > $i).
% 29.22/29.08  tff(decl_52066, type, fn_mating_of_saccharomyces_cerevisiae_12: $i > $i).
% 29.22/29.08  tff(decl_52067, type, fn_mating_of_saccharomyces_cerevisiae_13: $i > $i).
% 29.22/29.08  tff(decl_52068, type, fn_mating_of_saccharomyces_cerevisiae_14: $i > $i).
% 29.22/29.08  tff(decl_52069, type, fn_mating_of_saccharomyces_cerevisiae_15: $i > $i).
% 29.22/29.08  tff(decl_52070, type, fn_mating_of_saccharomyces_cerevisiae_16: $i > $i).
% 29.22/29.08  tff(decl_52071, type, fn_mating_of_saccharomyces_cerevisiae_17: $i > $i).
% 29.22/29.08  tff(decl_52072, type, fn_mating_of_saccharomyces_cerevisiae_18: $i > $i).
% 29.22/29.08  tff(decl_52073, type, shmoo_fusion_1: $i > $o).
% 29.22/29.08  tff(decl_52074, type, fn_mating_of_saccharomyces_cerevisiae_19: $i > $i).
% 29.22/29.08  tff(decl_52075, type, fn_mating_of_saccharomyces_cerevisiae_20: $i > $i).
% 29.22/29.08  tff(decl_52076, type, fn_mating_of_saccharomyces_cerevisiae_21: $i > $i).
% 29.22/29.08  tff(decl_52077, type, fn_shmoo_3: $i > $i).
% 29.22/29.08  tff(decl_52078, type, fn_shmoo_4: $i > $i).
% 29.22/29.08  tff(decl_52079, type, fn_shmoo_2: $i > $i).
% 29.22/29.08  tff(decl_52080, type, fn_shmoo_fusion_2: $i > $i).
% 29.22/29.08  tff(decl_52081, type, fn_shmoo_formation_4: $i > $i).
% 29.22/29.08  tff(decl_52082, type, fn_shmoo_fusion_1: $i > $i).
% 29.22/29.08  tff(decl_52083, type, 'Mating-Type-A': $i).
% 29.22/29.08  tff(decl_52084, type, 'Strain of haploid yeast which deomstrates simple, genetically based sexual differentiation that distinguishes them from the other mating type, mating type alpha. Mating type a can only mate with mating type alpha.': $i).
% 29.22/29.08  tff(decl_52085, type, 'mating type a': $i).
% 29.22/29.08  tff(decl_52086, type, 'mating-type-a': $i).
% 29.22/29.08  tff(decl_52087, type, fn_mating_type_a_1: $i > $i).
% 29.22/29.08  tff(decl_52088, type, fn_mating_type_a_2: $i > $i).
% 29.22/29.08  tff(decl_52089, type, fn_mating_type_a_3: $i > $i).
% 29.22/29.08  tff(decl_52090, type, fn_mating_type_a_4: $i > $i).
% 29.22/29.08  tff(decl_52091, type, fn_mating_type_a_5: $i > $i).
% 29.22/29.08  tff(decl_52092, type, fn_mating_type_a_6: $i > $i).
% 29.22/29.08  tff(decl_52093, type, fn_mating_type_a_7: $i > $i).
% 29.22/29.08  tff(decl_52094, type, fn_mating_type_a_8: $i > $i).
% 29.22/29.08  tff(decl_52095, type, fn_mating_type_a_9: $i > $i).
% 29.22/29.08  tff(decl_52096, type, fn_mating_type_a_10: $i > $i).
% 29.22/29.08  tff(decl_52097, type, fn_mating_type_a_11: $i > $i).
% 29.22/29.08  tff(decl_52098, type, fn_mating_type_a_12: $i > $i).
% 29.22/29.08  tff(decl_52099, type, fn_mating_type_a_13: $i > $i).
% 29.22/29.08  tff(decl_52100, type, fn_mating_type_a_14: $i > $i).
% 29.22/29.08  tff(decl_52101, type, fn_mating_type_a_15: $i > $i).
% 29.22/29.08  tff(decl_52102, type, fn_mating_type_a_16: $i > $i).
% 29.22/29.08  tff(decl_52103, type, fn_mating_type_a_17: $i > $i).
% 29.22/29.08  tff(decl_52104, type, fn_mating_type_a_18: $i > $i).
% 29.22/29.08  tff(decl_52105, type, fn_mating_type_a_19: $i > $i).
% 29.22/29.08  tff(decl_52106, type, fn_mating_type_a_20: $i > $i).
% 29.22/29.08  tff(decl_52107, type, fn_mating_type_a_21: $i > $i).
% 29.22/29.08  tff(decl_52108, type, fn_yeast_19: $i > $i).
% 29.22/29.08  tff(decl_52109, type, fn_yeast_4: $i > $i).
% 29.22/29.08  tff(decl_52110, type, fn_yeast_2: $i > $i).
% 29.22/29.08  tff(decl_52111, type, 'Mating-Type-Alpha': $i).
% 29.22/29.08  tff(decl_52112, type, 'Strain of haploid yeast which deomstrates simple, genetically based sexual differentiation that distinguishes them from the other mating type, mating type a. Mating type alpha can only mate with mating type a.': $i).
% 29.22/29.08  tff(decl_52113, type, 'mating type alpha': $i).
% 29.22/29.08  tff(decl_52114, type, 'mating-type-alpha': $i).
% 29.22/29.08  tff(decl_52115, type, fn_mating_type_alpha_1: $i > $i).
% 29.22/29.08  tff(decl_52116, type, fn_mating_type_alpha_2: $i > $i).
% 29.22/29.08  tff(decl_52117, type, fn_mating_type_alpha_3: $i > $i).
% 29.22/29.08  tff(decl_52118, type, fn_mating_type_alpha_4: $i > $i).
% 29.22/29.08  tff(decl_52119, type, fn_mating_type_alpha_5: $i > $i).
% 29.22/29.08  tff(decl_52120, type, fn_mating_type_alpha_6: $i > $i).
% 29.22/29.08  tff(decl_52121, type, fn_mating_type_alpha_7: $i > $i).
% 29.22/29.08  tff(decl_52122, type, fn_mating_type_alpha_8: $i > $i).
% 29.22/29.08  tff(decl_52123, type, fn_mating_type_alpha_9: $i > $i).
% 29.22/29.08  tff(decl_52124, type, fn_mating_type_alpha_10: $i > $i).
% 29.22/29.08  tff(decl_52125, type, fn_mating_type_alpha_11: $i > $i).
% 29.22/29.08  tff(decl_52126, type, fn_mating_type_alpha_12: $i > $i).
% 29.22/29.08  tff(decl_52127, type, fn_mating_type_alpha_13: $i > $i).
% 29.22/29.08  tff(decl_52128, type, fn_mating_type_alpha_14: $i > $i).
% 29.22/29.08  tff(decl_52129, type, fn_mating_type_alpha_15: $i > $i).
% 29.22/29.08  tff(decl_52130, type, fn_mating_type_alpha_16: $i > $i).
% 29.22/29.08  tff(decl_52131, type, fn_mating_type_alpha_17: $i > $i).
% 29.22/29.08  tff(decl_52132, type, fn_mating_type_alpha_18: $i > $i).
% 29.22/29.08  tff(decl_52133, type, fn_mating_type_alpha_19: $i > $i).
% 29.22/29.08  tff(decl_52134, type, fn_mating_type_alpha_20: $i > $i).
% 29.22/29.08  tff(decl_52135, type, fn_mating_type_alpha_21: $i > $i).
% 29.22/29.08  tff(decl_52136, type, 'Maturation': $i).
% 29.22/29.08  tff(decl_52137, type, 'The act of comingto full development; becoming mature is called as maturation.': $i).
% 29.22/29.08  tff(decl_52138, type, mature_muscle_cell_1: $i > $o).
% 29.22/29.08  tff(decl_52139, type, 'Mature-Muscle-Cell': $i).
% 29.22/29.08  tff(decl_52140, type, 'Muscle cell in a mature vertebrate which is no longer growing or dividing.': $i).
% 29.22/29.08  tff(decl_52141, type, 'mature muscle cell': $i).
% 29.22/29.08  tff(decl_52142, type, 'mature-muscle-cell': $i).
% 29.22/29.08  tff(decl_52143, type, nondividing_cell_1: $i > $o).
% 29.22/29.08  tff(decl_52144, type, fn_mature_muscle_cell_1: $i > $i).
% 29.22/29.08  tff(decl_52145, type, mature_nerve_cell_1: $i > $o).
% 29.22/29.08  tff(decl_52146, type, 'Mature-Nerve-Cell': $i).
% 29.22/29.08  tff(decl_52147, type, 'Nerve cell in a mature vertebrate which is no longer growing or dividing.': $i).
% 29.22/29.08  tff(decl_52148, type, 'mature nerve cell': $i).
% 29.22/29.08  tff(decl_52149, type, 'mature-nerve-cell': $i).
% 29.22/29.08  tff(decl_52150, type, fn_mature_nerve_cell_1: $i > $i).
% 29.22/29.08  tff(decl_52151, type, 'Mayfly': $i).
% 29.22/29.08  tff(decl_52152, type, 'An insect belonging to the order Ephemeroptera, which have aquatic larvae and a short-lived adult stage.': $i).
% 29.22/29.08  tff(decl_52153, type, dayfly: $i).
% 29.22/29.08  tff(decl_52154, type, shadfly: $i).
% 29.22/29.08  tff(decl_52155, type, mayfly: $i).
% 29.22/29.08  tff(decl_52156, type, 'Meal': $i).
% 29.22/29.08  tff(decl_52157, type, meal: $i).
% 29.22/29.08  tff(decl_52158, type, fn_meal_1: $i > $i).
% 29.22/29.08  tff(decl_52159, type, 'Measure': $i).
% 29.22/29.08  tff(decl_52160, type, 'The act of knowing the value of an entity.': $i).
% 29.22/29.08  tff(decl_52161, type, 'Mechanical-Digestion': $i).
% 29.22/29.08  tff(decl_52162, type, 'The breaking of food into smaller pieces by mechanical means, such as chewing or ginding, which increases the surface area for chemical processing.': $i).
% 29.22/29.08  tff(decl_52163, type, 'mechanical digestion': $i).
% 29.22/29.08  tff(decl_52164, type, 'mechanical-digestion': $i).
% 29.22/29.08  tff(decl_52165, type, fn_mechanical_digestion_2: $i > $i).
% 29.22/29.08  tff(decl_52166, type, fn_mechanical_digestion_3: $i > $i).
% 29.22/29.08  tff(decl_52167, type, fn_mechanical_digestion_4: $i > $i).
% 29.22/29.08  tff(decl_52168, type, mechanical_energy_1: $i > $o).
% 29.22/29.08  tff(decl_52169, type, 'Mechanical-Energy': $i).
% 29.22/29.08  tff(decl_52170, type, 'The energy that is possessed by an object due to its motion or due to its position. Mechanical energy can be either kinetic energy (energy of motion) or potential energy (stored energy of position).': $i).
% 29.22/29.08  tff(decl_52171, type, 'mechanical energy': $i).
% 29.22/29.08  tff(decl_52172, type, 'mechanical-energy': $i).
% 29.22/29.08  tff(decl_52173, type, 'Mechanical-Isolation': $i).
% 29.22/29.08  tff(decl_52174, type, 'A prezygotic barrier to reproduction. In animals, mechanical isolation occurs when the genitals of mating individuals are not compatible. In angiosperms, mechanical isolation occurs when a pollinator can transfer pollen effectively only to flowers of the same species.': $i).
% 29.22/29.08  tff(decl_52175, type, 'mechanical isolation': $i).
% 29.22/29.08  tff(decl_52176, type, 'mechanical-isolation': $i).
% 29.22/29.08  tff(decl_52177, type, species_isolation_1: $i > $o).
% 29.22/29.08  tff(decl_52178, type, mechanical_work_1: $i > $o).
% 29.22/29.08  tff(decl_52179, type, 'Mechanical-Work': $i).
% 29.22/29.08  tff(decl_52180, type, 'In cells and organisms, mechanical work is the process of using energy to move or change the shape of molecules or objects.': $i).
% 29.22/29.08  tff(decl_52181, type, 'mechanical work': $i).
% 29.22/29.08  tff(decl_52182, type, 'mechanical-work': $i).
% 29.22/29.08  tff(decl_52183, type, fn_mechanical_work_1: $i > $i).
% 29.22/29.08  tff(decl_52184, type, fn_mechanical_work_2: $i > $i).
% 29.22/29.08  tff(decl_52185, type, fn_mechanical_work_3: $i > $i).
% 29.22/29.08  tff(decl_52186, type, fn_mechanical_work_4: $i > $i).
% 29.22/29.08  tff(decl_52187, type, fn_mechanical_work_5: $i > $i).
% 29.22/29.08  tff(decl_52188, type, fn_mechanical_work_6: $i > $i).
% 29.22/29.08  tff(decl_52189, type, fn_mechanical_work_7: $i > $i).
% 29.22/29.08  tff(decl_52190, type, fn_mechanical_work_8: $i > $i).
% 29.22/29.08  tff(decl_52191, type, fn_mechanical_work_9: $i > $i).
% 29.22/29.08  tff(decl_52192, type, fn_mechanical_work_10: $i > $i).
% 29.22/29.08  tff(decl_52193, type, 'Mechanoreceptor': $i).
% 29.22/29.08  tff(decl_52194, type, 'A sensory receptor that responds to deformation or mechanical pressure. Mechanoreceptors detect pressure, stretch, and touch, sound, and motion.': $i).
% 29.22/29.08  tff(decl_52195, type, mechanoreceptor: $i).
% 29.22/29.08  tff(decl_52196, type, medial_1: $i > $o).
% 29.22/29.08  tff(decl_52197, type, 'Medial': $i).
% 29.22/29.08  tff(decl_52198, type, 'Region at the midline of the body.  Opposite of lateral.': $i).
% 29.22/29.08  tff(decl_52199, type, 'midline,': $i).
% 29.22/29.08  tff(decl_52200, type, 'sagittal,': $i).
% 29.22/29.08  tff(decl_52201, type, axial: $i).
% 29.22/29.08  tff(decl_52202, type, sagittal: $i).
% 29.22/29.08  tff(decl_52203, type, midline: $i).
% 29.22/29.08  tff(decl_52204, type, medial: $i).
% 29.22/29.08  tff(decl_52205, type, 'Medical-Procedure': $i).
% 29.22/29.08  tff(decl_52206, type, 'Intervention by trained personnel intended to alleviate a health problem.': $i).
% 29.22/29.08  tff(decl_52207, type, 'procedure of medical': $i).
% 29.22/29.08  tff(decl_52208, type, 'medical procedure': $i).
% 29.22/29.08  tff(decl_52209, type, 'medical-procedure': $i).
% 29.22/29.08  tff(decl_52210, type, 'Medical-Treatment-Of-Cancer': $i).
% 29.22/29.08  tff(decl_52211, type, 'A series of medical steps designed to reduce or eliminate the presence of tumors.': $i).
% 29.22/29.08  tff(decl_52212, type, 'medical treatment of cancer': $i).
% 29.22/29.08  tff(decl_52213, type, 'medical-treatment-of-cancer': $i).
% 29.22/29.08  tff(decl_52214, type, 'Medicine': $i).
% 29.22/29.08  tff(decl_52215, type, 'The science and practice of healing.  Also, chemicals used to treat or cure disorders and disease and promote healing.': $i).
% 29.22/29.08  tff(decl_52216, type, medicine: $i).
% 29.22/29.08  tff(decl_52217, type, 'Medium': $i).
% 29.22/29.08  tff(decl_52218, type, medium: $i).
% 29.22/29.08  tff(decl_52219, type, communicating: $i).
% 29.22/29.08  tff(decl_52220, type, 'Medulla-Oblongata': $i).
% 29.22/29.08  tff(decl_52221, type, 'The lower part of the vertebrate brain, visible as a swelling of the hindbrain anterior to the spinal cord. The medulla oblongata controls autonomic functions such as breathing, heart rate, blood pressure, swallowing, and vomiting.': $i).
% 29.22/29.08  tff(decl_52222, type, 'medulla oblongata': $i).
% 29.22/29.08  tff(decl_52223, type, 'medulla-oblongata': $i).
% 29.22/29.08  tff(decl_52224, type, medusa_1: $i > $o).
% 29.22/29.08  tff(decl_52225, type, 'Medusa': $i).
% 29.22/29.08  tff(decl_52226, type, 'The pelagic, flattened stage of the cnidarian body plan. The alternate body plan is the polyp, which is benthic and vaguely tubular.': $i).
% 29.22/29.08  tff(decl_52227, type, medusa: $i).
% 29.22/29.08  tff(decl_52228, type, 'Megaphyll': $i).
% 29.22/29.08  tff(decl_52229, type, 'A leaf that is not necessarily large but has a very branched vascular system. Most vascular plants have megaphylls.': $i).
% 29.22/29.08  tff(decl_52230, type, megaphyll: $i).
% 29.22/29.08  tff(decl_52231, type, megasporangium_1: $i > $o).
% 29.22/29.08  tff(decl_52232, type, 'Megasporangium': $i).
% 29.22/29.08  tff(decl_52233, type, 'An enclosure on a plant or fungus where megaspores are produced.': $i).
% 29.22/29.08  tff(decl_52234, type, megasporangia: $i).
% 29.22/29.08  tff(decl_52235, type, megasporangium: $i).
% 29.22/29.08  tff(decl_52236, type, 'Megaspore': $i).
% 29.22/29.08  tff(decl_52237, type, 'A spore that gives rise to a male gametophyte.': $i).
% 29.22/29.08  tff(decl_52238, type, megaspore: $i).
% 29.22/29.08  tff(decl_52239, type, 'Meiosis': $i).
% 29.22/29.08  tff(decl_52240, type, 'Meiosis includes two nuclear division and production of four haploid cells genetically different (has half the number of chromosomes as do their parent cell) to their parent cell.The meiotic cell cycle has two cell divisions and one duplication of DNA. The Gametes (Sex cell) are also the result of meiosis as the haploid cells formed as result of meiosis further undergo changes to form gametes.': $i).
% 29.22/29.08  tff(decl_52241, type, 'meiotic cell division': $i).
% 29.22/29.08  tff(decl_52242, type, 'undergo meiosis': $i).
% 29.22/29.08  tff(decl_52243, type, meiosis: $i).
% 29.22/29.08  tff(decl_52244, type, fn_meiosis_3: $i > $i).
% 29.22/29.08  tff(decl_52245, type, fn_meiosis_5: $i > $i).
% 29.22/29.08  tff(decl_52246, type, fn_meiosis_6: $i > $i).
% 29.22/29.08  tff(decl_52247, type, meiosis_i_1: $i > $o).
% 29.22/29.08  tff(decl_52248, type, fn_meiosis_7: $i > $i).
% 29.22/29.08  tff(decl_52249, type, fn_meiosis_8: $i > $i).
% 29.22/29.08  tff(decl_52250, type, fn_meiosis_9: $i > $i).
% 29.22/29.08  tff(decl_52251, type, meiosis_ii_1: $i > $o).
% 29.22/29.08  tff(decl_52252, type, fn_meiosis_10: $i > $i).
% 29.22/29.08  tff(decl_52253, type, fn_meiosis_12: $i > $i).
% 29.22/29.08  tff(decl_52254, type, fn_meiosis_13: $i > $i).
% 29.22/29.08  tff(decl_52255, type, fn_meiosis_14: $i > $i).
% 29.22/29.08  tff(decl_52256, type, fn_meiosis_15: $i > $i).
% 29.22/29.08  tff(decl_52257, type, fn_meiosis_16: $i > $i).
% 29.22/29.08  tff(decl_52258, type, fn_meiosis_18: $i > $i).
% 29.22/29.08  tff(decl_52259, type, fn_meiosis_19: $i > $i).
% 29.22/29.08  tff(decl_52260, type, causes_0: $i).
% 29.22/29.08  tff(decl_52261, type, nuclear_division_0: $i).
% 29.22/29.08  tff(decl_52262, type, cell_division_0: $i).
% 29.22/29.08  tff(decl_52263, type, 'HaploidNumber_EukaryoticChromosome1': $i).
% 29.22/29.08  tff(decl_52264, type, 'Quantity_EukaryoticChromosome2': $i).
% 29.22/29.08  tff(decl_52265, type, fn_meiosis_11: $i > $i).
% 29.22/29.08  tff(decl_52266, type, 'Meiosis-I': $i).
% 29.22/29.08  tff(decl_52267, type, 'In organisms that reproduce sexually, the first of two stages of cell division, which results in daughter cells containing half the number of chromsome sets as the parent cell. Meiosis I starts with a diploid cell and produces two haploid daughter cells.': $i).
% 29.22/29.08  tff(decl_52268, type, 'meiosis i': $i).
% 29.22/29.08  tff(decl_52269, type, 'meiosis-i': $i).
% 29.22/29.08  tff(decl_52270, type, fn_meiosis_i_1: $i > $i).
% 29.22/29.08  tff(decl_52271, type, prophase_i_1: $i > $o).
% 29.22/29.08  tff(decl_52272, type, fn_meiosis_i_2: $i > $i).
% 29.22/29.08  tff(decl_52273, type, fn_meiosis_i_3: $i > $i).
% 29.22/29.08  tff(decl_52274, type, fn_meiosis_i_4: $i > $i).
% 29.22/29.08  tff(decl_52275, type, fn_meiosis_i_5: $i > $i).
% 29.22/29.08  tff(decl_52276, type, fn_meiosis_i_6: $i > $i).
% 29.22/29.08  tff(decl_52277, type, fn_meiosis_i_7: $i > $i).
% 29.22/29.08  tff(decl_52278, type, fn_meiosis_i_8: $i > $i).
% 29.22/29.08  tff(decl_52279, type, fn_meiosis_i_9: $i > $i).
% 29.22/29.08  tff(decl_52280, type, fn_meiosis_i_10: $i > $i).
% 29.22/29.08  tff(decl_52281, type, fn_meiosis_i_11: $i > $i).
% 29.22/29.08  tff(decl_52282, type, fn_meiosis_i_12: $i > $i).
% 29.22/29.08  tff(decl_52283, type, fn_meiosis_i_13: $i > $i).
% 29.22/29.08  tff(decl_52284, type, fn_meiosis_i_14: $i > $i).
% 29.22/29.08  tff(decl_52285, type, fn_meiosis_i_16: $i > $i).
% 29.22/29.08  tff(decl_52286, type, fn_meiosis_i_17: $i > $i).
% 29.22/29.08  tff(decl_52287, type, fn_meiosis_i_18: $i > $i).
% 29.22/29.08  tff(decl_52288, type, fn_meiosis_i_19: $i > $i).
% 29.22/29.08  tff(decl_52289, type, fn_meiosis_i_20: $i > $i).
% 29.22/29.08  tff(decl_52290, type, fn_meiosis_i_21: $i > $i).
% 29.22/29.08  tff(decl_52291, type, fn_meiosis_i_22: $i > $i).
% 29.22/29.08  tff(decl_52292, type, fn_meiosis_i_23: $i > $i).
% 29.22/29.08  tff(decl_52293, type, fn_meiosis_i_24: $i > $i).
% 29.22/29.08  tff(decl_52294, type, fn_meiosis_i_25: $i > $i).
% 29.22/29.08  tff(decl_52295, type, fn_meiosis_i_26: $i > $i).
% 29.22/29.08  tff(decl_52296, type, fn_meiosis_i_27: $i > $i).
% 29.22/29.08  tff(decl_52297, type, fn_diploid_number_1: $i > $i).
% 29.22/29.08  tff(decl_52298, type, fn_prophase_i_6: $i > $i).
% 29.22/29.08  tff(decl_52299, type, '2n chromosomes': $i).
% 29.22/29.08  tff(decl_52300, type, fn_meiosis_i_15: $i > $i).
% 29.22/29.08  tff(decl_52301, type, fn_meiosis_i_29: $i > $i).
% 29.22/29.08  tff(decl_52302, type, fn_meiosis_i_28: $i > $i).
% 29.22/29.08  tff(decl_52303, type, 'Meiosis-II': $i).
% 29.22/29.08  tff(decl_52304, type, 'In organisms that reproduce sexually, the second of two stages of cell division, which separates and segregates the sister chromatids, producing four haploid daughter cells.': $i).
% 29.22/29.08  tff(decl_52305, type, 'meiosis ii': $i).
% 29.22/29.08  tff(decl_52306, type, 'meiosis-ii': $i).
% 29.22/29.08  tff(decl_52307, type, fn_meiosis_ii_1: $i > $i).
% 29.22/29.08  tff(decl_52308, type, fn_meiosis_ii_2: $i > $i).
% 29.22/29.08  tff(decl_52309, type, fn_meiosis_ii_3: $i > $i).
% 29.22/29.08  tff(decl_52310, type, fn_meiosis_ii_4: $i > $i).
% 29.22/29.08  tff(decl_52311, type, fn_meiosis_ii_5: $i > $i).
% 29.22/29.08  tff(decl_52312, type, fn_meiosis_ii_6: $i > $i).
% 29.22/29.08  tff(decl_52313, type, fn_meiosis_ii_7: $i > $i).
% 29.22/29.08  tff(decl_52314, type, fn_meiosis_ii_8: $i > $i).
% 29.22/29.08  tff(decl_52315, type, fn_meiosis_ii_9: $i > $i).
% 29.22/29.08  tff(decl_52316, type, prophase_ii_1: $i > $o).
% 29.22/29.08  tff(decl_52317, type, fn_meiosis_ii_10: $i > $i).
% 29.22/29.08  tff(decl_52318, type, metaphase_ii_1: $i > $o).
% 29.22/29.08  tff(decl_52319, type, fn_meiosis_ii_11: $i > $i).
% 29.22/29.08  tff(decl_52320, type, telophase_ii_1: $i > $o).
% 29.22/29.08  tff(decl_52321, type, fn_meiosis_ii_12: $i > $i).
% 29.22/29.08  tff(decl_52322, type, fn_meiosis_ii_13: $i > $i).
% 29.22/29.08  tff(decl_52323, type, fn_meiosis_ii_14: $i > $i).
% 29.22/29.08  tff(decl_52324, type, fn_meiosis_ii_15: $i > $i).
% 29.22/29.08  tff(decl_52325, type, fn_meiosis_ii_16: $i > $i).
% 29.22/29.08  tff(decl_52326, type, fn_meiosis_ii_17: $i > $i).
% 29.22/29.08  tff(decl_52327, type, fn_meiosis_ii_18: $i > $i).
% 29.22/29.08  tff(decl_52328, type, fn_meiosis_ii_19: $i > $i).
% 29.22/29.08  tff(decl_52329, type, fn_meiosis_ii_20: $i > $i).
% 29.22/29.08  tff(decl_52330, type, fn_meiosis_ii_21: $i > $i).
% 29.22/29.08  tff(decl_52331, type, fn_meiosis_ii_22: $i > $i).
% 29.22/29.08  tff(decl_52332, type, fn_meiosis_ii_23: $i > $i).
% 29.22/29.08  tff(decl_52333, type, fn_meiosis_ii_24: $i > $i).
% 29.22/29.08  tff(decl_52334, type, fn_meiosis_ii_25: $i > $i).
% 29.22/29.08  tff(decl_52335, type, fn_meiosis_ii_26: $i > $i).
% 29.22/29.08  tff(decl_52336, type, fn_meiosis_ii_27: $i > $i).
% 29.22/29.08  tff(decl_52337, type, fn_meiotic_event_1: $i > $i).
% 29.22/29.08  tff(decl_52338, type, gamete_0: $i).
% 29.22/29.08  tff(decl_52339, type, haploid_cell_0: $i).
% 29.22/29.08  tff(decl_52340, type, fn_meiosis_ii_29: $i > $i).
% 29.22/29.08  tff(decl_52341, type, fn_meiosis_ii_28: $i > $i).
% 29.22/29.08  tff(decl_52342, type, meiosis_in_female_1: $i > $o).
% 29.22/29.08  tff(decl_52343, type, 'Meiosis-in-Female': $i).
% 29.22/29.08  tff(decl_52344, type, 'A modified type of cell division in sexually reproducing organisms consisting of two rounds of cell division but only one round of DNA replication. It results in one egg cells with half the number of chromosome sets as the original cell and three polar bodies.': $i).
% 29.22/29.08  tff(decl_52345, type, 'meiosis in female': $i).
% 29.22/29.08  tff(decl_52346, type, 'meiosis-in-female': $i).
% 29.22/29.08  tff(decl_52347, type, fn_meiosis_in_female_1: $i > $i).
% 29.22/29.08  tff(decl_52348, type, fn_meiosis_in_female_2: $i > $i).
% 29.22/29.08  tff(decl_52349, type, polar_body_1: $i > $o).
% 29.22/29.08  tff(decl_52350, type, polar_body_0: $i).
% 29.22/29.08  tff(decl_52351, type, egg_cell_0: $i).
% 29.22/29.08  tff(decl_52352, type, meiosis_in_male_1: $i > $o).
% 29.22/29.08  tff(decl_52353, type, 'Meiosis-in-Male': $i).
% 29.22/29.08  tff(decl_52354, type, 'A modified type of cell division in sexually reproducing organisms consisting of two rounds of cell division but only one round of DNA replication. It results in four sperm cells with half the number of chromosome sets as the original cell.': $i).
% 29.22/29.08  tff(decl_52355, type, 'meiosis in male': $i).
% 29.22/29.08  tff(decl_52356, type, 'meiosis-in-male': $i).
% 29.22/29.08  tff(decl_52357, type, fn_meiosis_in_male_1: $i > $i).
% 29.22/29.08  tff(decl_52358, type, sperm_cell_0: $i).
% 29.22/29.08  tff(decl_52359, type, fn_meiotic_cell_cycle_3: $i > $i).
% 29.22/29.08  tff(decl_52360, type, 'Meiotic-cell-cycle': $i).
% 29.22/29.08  tff(decl_52361, type, 'Meiotic cell cycle is the cell cycle followed by gonadic cells. It results in daughter cells identical in genetic composition to the parent cells': $i).
% 29.22/29.08  tff(decl_52362, type, 'meiotic cell cycle': $i).
% 29.22/29.08  tff(decl_52363, type, 'meiotic cycle': $i).
% 29.22/29.08  tff(decl_52364, type, 'meiotic-cycle': $i).
% 29.22/29.08  tff(decl_52365, type, 'meiotic-cell-cycle': $i).
% 29.22/29.08  tff(decl_52366, type, fn_meiotic_cell_cycle_1: $i > $i).
% 29.22/29.08  tff(decl_52367, type, 'Meiotic-Event': $i).
% 29.22/29.08  tff(decl_52368, type, 'Events of cellular division which include Meiosis I and Meiosis II': $i).
% 29.22/29.08  tff(decl_52369, type, 'phases of meiosis': $i).
% 29.22/29.08  tff(decl_52370, type, 'phases-of-meiosis': $i).
% 29.22/29.08  tff(decl_52371, type, 'meiotic event': $i).
% 29.22/29.08  tff(decl_52372, type, 'meiotic-event': $i).
% 29.22/29.08  tff(decl_52373, type, meitnerium_1: $i > $o).
% 29.22/29.08  tff(decl_52374, type, 'Meitnerium': $i).
% 29.22/29.08  tff(decl_52375, type, 'Meitnerium is a metal atom with atomic number 109. It is represented by the symbol Mt.': $i).
% 29.22/29.08  tff(decl_52376, type, meitnerium: $i).
% 29.22/29.08  tff(decl_52377, type, 'Mt': $i).
% 29.22/29.08  tff(decl_52378, type, fn_meitnerium_1: $i > $i).
% 29.22/29.08  tff(decl_52379, type, fn_meitnerium_2: $i > $i).
% 29.22/29.08  tff(decl_52380, type, fn_meitnerium_6: $i > $i).
% 29.22/29.08  tff(decl_52381, type, fn_meitnerium_7: $i > $i).
% 29.22/29.08  tff(decl_52382, type, "159": $i).
% 29.22/29.08  tff(decl_52383, type, "109": $i).
% 29.22/29.08  tff(decl_52384, type, "268": $i).
% 29.22/29.08  tff(decl_52385, type, fn_meitnerium_4: $i > $i).
% 29.22/29.08  tff(decl_52386, type, fn_meitnerium_5: $i > $i).
% 29.22/29.08  tff(decl_52387, type, 'Melanocyte-Stimulating-Hormone': $i).
% 29.22/29.08  tff(decl_52388, type, 'A pituitary hormone that stimulates the production and release of the pigment melanin by melanocytes in hair and skin.': $i).
% 29.22/29.08  tff(decl_52389, type, msh: $i).
% 29.22/29.08  tff(decl_52390, type, intermedins: $i).
% 29.22/29.08  tff(decl_52391, type, 'melanocyte stimulating hormone': $i).
% 29.22/29.08  tff(decl_52392, type, 'melanocyte-stimulating-hormone': $i).
% 29.22/29.08  tff(decl_52393, type, fn_melanocyte_stimulating_hormone_1: $i > $i).
% 29.22/29.08  tff(decl_52394, type, 'Melatonin': $i).
% 29.22/29.08  tff(decl_52395, type, 'A naturally occuring hormone found in animals and plants. In animals, melatonin is secreted by the pineal gland and regulates circadian rhythms.': $i).
% 29.22/29.08  tff(decl_52396, type, melatonin: $i).
% 29.22/29.08  tff(decl_52397, type, 'Melting': $i).
% 29.22/29.08  tff(decl_52398, type, 'Applying heat to change a substance from a solid state to a liquid state.': $i).
% 29.22/29.08  tff(decl_52399, type, melt: $i).
% 29.22/29.08  tff(decl_52400, type, melting: $i).
% 29.22/29.08  tff(decl_52401, type, 'Membrane': $i).
% 29.22/29.08  tff(decl_52402, type, 'A thin, soft, pliable sheet or layer made of organic substance.': $i).
% 29.22/29.08  tff(decl_52403, type, 'A membrane is a layer of material which serves as a selective barrier between two phases and remains impermeable to specific particles, molecules, or substances .It acts as a pliable sheet of tissue that covers or lines or connects organs or cells of animals.': $i).
% 29.22/29.08  tff(decl_52404, type, semipermeable_entity_1: $i > $o).
% 29.22/29.08  tff(decl_52405, type, fn_semipermeable_entity_2: $i > $i).
% 29.22/29.08  tff(decl_52406, type, 'Membrane-Attack-Complex': $i).
% 29.22/29.08  tff(decl_52407, type, 'A group of complement proteins that forms a pore in the bacterial membrane, causing it to swell and lyse.': $i).
% 29.22/29.08  tff(decl_52408, type, 'membrane attack complex': $i).
% 29.22/29.08  tff(decl_52409, type, 'membrane-attack-complex': $i).
% 29.22/29.08  tff(decl_52410, type, membrane_bound_enzyme_1: $i > $o).
% 29.22/29.08  tff(decl_52411, type, 'Membrane-Bound-Enzyme': $i).
% 29.22/29.08  tff(decl_52412, type, 'A protein built into the membrane may be an enzyme with its active site exposed to substances in the adjacent solution.': $i).
% 29.22/29.08  tff(decl_52413, type, 'membrane enclosed enzyme': $i).
% 29.22/29.08  tff(decl_52414, type, 'membrane-enclosed-enzyme': $i).
% 29.22/29.08  tff(decl_52415, type, 'membrane bound enzyme': $i).
% 29.22/29.08  tff(decl_52416, type, 'membrane-bound enzyme': $i).
% 29.22/29.08  tff(decl_52417, type, 'membrane-bound-enzyme': $i).
% 29.22/29.08  tff(decl_52418, type, fn_membrane_bound_enzyme_1: $i > $i).
% 29.22/29.08  tff(decl_52419, type, fn_membrane_bound_enzyme_2: $i > $i).
% 29.22/29.08  tff(decl_52420, type, fn_membrane_bound_enzyme_3: $i > $i).
% 29.22/29.08  tff(decl_52421, type, membrane_carbohydrate_1: $i > $o).
% 29.22/29.08  tff(decl_52422, type, fn_membrane_carbohydrate_3: $i > $i).
% 29.22/29.08  tff(decl_52423, type, 'Membrane-carbohydrate': $i).
% 29.22/29.08  tff(decl_52424, type, 'Carbohydrates found within and on plasma membranes': $i).
% 29.22/29.08  tff(decl_52425, type, 'carbohydrate of membrane': $i).
% 29.22/29.08  tff(decl_52426, type, 'membrane carbohydrate': $i).
% 29.22/29.08  tff(decl_52427, type, 'membrane-carbohydrate': $i).
% 29.22/29.08  tff(decl_52428, type, fn_membrane_carbohydrate_1: $i > $i).
% 29.22/29.08  tff(decl_52429, type, membrane_enclosure_1: $i > $o).
% 29.22/29.08  tff(decl_52430, type, 'Membrane-Enclosure': $i).
% 29.22/29.08  tff(decl_52431, type, 'A membrane that serves as an enclosure or container': $i).
% 29.22/29.08  tff(decl_52432, type, 'A type of enclosure made of membrane': $i).
% 29.22/29.08  tff(decl_52433, type, 'enclosure of membrane': $i).
% 29.22/29.08  tff(decl_52434, type, 'membrane enclosure': $i).
% 29.22/29.08  tff(decl_52435, type, 'membrane-enclosure': $i).
% 29.22/29.08  tff(decl_52436, type, fn_membrane_enclosure_1: $i > $i).
% 29.22/29.08  tff(decl_52437, type, fn_membrane_enclosure_2: $i > $i).
% 29.22/29.08  tff(decl_52438, type, fn_membrane_enclosure_3: $i > $i).
% 29.22/29.08  tff(decl_52439, type, 'Membrane-Potential': $i).
% 29.22/29.08  tff(decl_52440, type, 'The difference in voltage across a membrane due to the unequal distribution of ions across the membrane.': $i).
% 29.22/29.08  tff(decl_52441, type, 'potential of membrane': $i).
% 29.22/29.08  tff(decl_52442, type, 'membrane potential': $i).
% 29.22/29.08  tff(decl_52443, type, 'membrane-potential': $i).
% 29.22/29.08  tff(decl_52444, type, voltage_1: $i > $o).
% 29.22/29.08  tff(decl_52445, type, fn_membrane_potential_1: $i > $i).
% 29.22/29.08  tff(decl_52446, type, fn_membrane_potential_3: $i > $i).
% 29.22/29.08  tff(decl_52447, type, fn_membrane_potential_4: $i > $i).
% 29.22/29.08  tff(decl_52448, type, 'Membrane-Protein': $i).
% 29.22/29.08  tff(decl_52449, type, 'A protein attached to or embedded within a cell membrane.': $i).
% 29.22/29.08  tff(decl_52450, type, 'protein of membrane': $i).
% 29.22/29.08  tff(decl_52451, type, 'membrane protein': $i).
% 29.22/29.08  tff(decl_52452, type, 'membrane-protein': $i).
% 29.22/29.08  tff(decl_52453, type, fn_membrane_protein_4: $i > $i).
% 29.22/29.08  tff(decl_52454, type, fn_membrane_protein_3: $i > $i).
% 29.22/29.08  tff(decl_52455, type, 'Memory': $i).
% 29.22/29.08  tff(decl_52456, type, 'The ability to store and later recover information about previous experiences or events.': $i).
% 29.22/29.08  tff(decl_52457, type, memory: $i).
% 29.22/29.08  tff(decl_52458, type, 'Memory-Cell': $i).
% 29.22/29.08  tff(decl_52459, type, 'One of a clone of long-lived T or B cells that is formed during a primary immune response. Upon subsequent exposure to the same antigen, memory cells are reactivated and begin to mount the second immune response.': $i).
% 29.22/29.08  tff(decl_52460, type, 'cell of memory': $i).
% 29.22/29.08  tff(decl_52461, type, 'memory cell': $i).
% 29.22/29.08  tff(decl_52462, type, 'memory-cell': $i).
% 29.22/29.08  tff(decl_52463, type, mendel_1: $i > $o).
% 29.22/29.08  tff(decl_52464, type, 'Mendel': $i).
% 29.22/29.08  tff(decl_52465, type, 'Mendel brought an experimental and quantitative approach to genetics.  Mendel discovered the basic principles of heridity by breeding garden peas in carefully planned experiments.': $i).
% 29.22/29.08  tff(decl_52466, type, 'gregor mendel': $i).
% 29.22/29.08  tff(decl_52467, type, 'gregor-mendel': $i).
% 29.22/29.08  tff(decl_52468, type, mendel: $i).
% 29.22/29.08  tff(decl_52469, type, fn_mendel_1: $i > $i).
% 29.22/29.08  tff(decl_52470, type, fn_mendel_2: $i > $i).
% 29.22/29.08  tff(decl_52471, type, fn_mendel_3: $i > $i).
% 29.22/29.08  tff(decl_52472, type, pea_1: $i > $o).
% 29.22/29.08  tff(decl_52473, type, fn_mendel_4: $i > $i).
% 29.22/29.08  tff(decl_52474, type, fn_mendel_5: $i > $i).
% 29.22/29.08  tff(decl_52475, type, fn_mendel_6: $i > $i).
% 29.22/29.08  tff(decl_52476, type, fn_mendel_7: $i > $i).
% 29.22/29.08  tff(decl_52477, type, fn_mendel_8: $i > $i).
% 29.22/29.08  tff(decl_52478, type, mendel_pollination_1: $i > $o).
% 29.22/29.08  tff(decl_52479, type, fn_mendel_9: $i > $i).
% 29.22/29.08  tff(decl_52480, type, 'Mendel-Pollination': $i).
% 29.22/29.08  tff(decl_52481, type, 'Mendel used a paintbrush to transfer sperm-bearing pollen from one plant to the egg-bearing carpel of another plant.': $i).
% 29.22/29.08  tff(decl_52482, type, 'pollination of mendel': $i).
% 29.22/29.08  tff(decl_52483, type, 'mendel pollination': $i).
% 29.22/29.08  tff(decl_52484, type, 'mendel-pollination': $i).
% 29.22/29.08  tff(decl_52485, type, pollination_1: $i > $o).
% 29.22/29.08  tff(decl_52486, type, fn_mendel_pollination_1: $i > $i).
% 29.22/29.08  tff(decl_52487, type, fn_mendel_pollination_2: $i > $i).
% 29.22/29.08  tff(decl_52488, type, fn_mendel_pollination_3: $i > $i).
% 29.22/29.08  tff(decl_52489, type, paintbrush_1: $i > $o).
% 29.22/29.08  tff(decl_52490, type, fn_mendel_pollination_4: $i > $i).
% 29.22/29.08  tff(decl_52491, type, fn_mendel_pollination_5: $i > $i).
% 29.22/29.08  tff(decl_52492, type, fn_mendel_pollination_6: $i > $i).
% 29.22/29.08  tff(decl_52493, type, mendelevium_1: $i > $o).
% 29.22/29.08  tff(decl_52494, type, 'Mendelevium': $i).
% 29.22/29.08  tff(decl_52495, type, 'Mendelevium is a metal atom with atomic number 101. It is represented by the symbol Md.': $i).
% 29.22/29.08  tff(decl_52496, type, mendelevium: $i).
% 29.22/29.08  tff(decl_52497, type, md: $i).
% 29.22/29.08  tff(decl_52498, type, fn_mendelevium_3: $i > $i).
% 29.22/29.08  tff(decl_52499, type, fn_mendelevium_4: $i > $i).
% 29.22/29.08  tff(decl_52500, type, fn_mendelevium_5: $i > $i).
% 29.22/29.08  tff(decl_52501, type, fn_mendelevium_9: $i > $i).
% 29.22/29.08  tff(decl_52502, type, fn_mendelevium_10: $i > $i).
% 29.22/29.08  tff(decl_52503, type, fn_mendelevium_11: $i > $i).
% 29.22/29.08  tff(decl_52504, type, fn_mendelevium_12: $i > $i).
% 29.22/29.08  tff(decl_52505, type, "101": $i).
% 29.22/29.08  tff(decl_52506, type, "15": $i).
% 29.22/29.08  tff(decl_52507, type, "258": $i).
% 29.22/29.08  tff(decl_52508, type, fn_mendelevium_7: $i > $i).
% 29.22/29.08  tff(decl_52509, type, fn_mendelevium_8: $i > $i).
% 29.22/29.08  tff(decl_52510, type, fn_mendelevium_6: $i > $i).
% 29.22/29.08  tff(decl_52511, type, 'Mendelian-Genetics': $i).
% 29.22/29.08  tff(decl_52512, type, 'The study of how heritable traits are passed from parents to offspring.': $i).
% 29.22/29.08  tff(decl_52513, type, 'mendelian genetics': $i).
% 29.22/29.08  tff(decl_52514, type, 'mendelian-genetic': $i).
% 29.22/29.08  tff(decl_52515, type, 'Mendelian-Law': $i).
% 29.22/29.08  tff(decl_52516, type, 'The laws of Allele Segregation and Independent Assortment which describe the behavior of Mendelian Inheritance.': $i).
% 29.22/29.08  tff(decl_52517, type, 'mendel law': $i).
% 29.22/29.08  tff(decl_52518, type, 'mendel-law': $i).
% 29.22/29.08  tff(decl_52519, type, 'mendelian law of random separation of genes across generations': $i).
% 29.22/29.08  tff(decl_52520, type, 'mendelian-law-of-random-separation-of-genes-across-generations': $i).
% 29.22/29.08  tff(decl_52521, type, 'mendels laws': $i).
% 29.22/29.08  tff(decl_52522, type, 'mendels-laws': $i).
% 29.22/29.08  tff(decl_52523, type, mendelism: $i).
% 29.22/29.08  tff(decl_52524, type, 'mendelian inheritance': $i).
% 29.22/29.08  tff(decl_52525, type, 'mendelian-inheritance': $i).
% 29.22/29.08  tff(decl_52526, type, 'mendelian law': $i).
% 29.22/29.08  tff(decl_52527, type, 'mendelian-law': $i).
% 29.22/29.08  tff(decl_52528, type, fn_mendelian_law_1: $i > $i).
% 29.22/29.08  tff(decl_52529, type, fn_mendelian_law_2: $i > $i).
% 29.22/29.08  tff(decl_52530, type, fn_mendelian_law_3: $i > $i).
% 29.22/29.08  tff(decl_52531, type, meniscus_1: $i > $o).
% 29.22/29.08  tff(decl_52532, type, 'Meniscus': $i).
% 29.22/29.08  tff(decl_52533, type, 'Cartilage found in the knee that functions as a shock absorbing system.': $i).
% 29.22/29.08  tff(decl_52534, type, meniscus: $i).
% 29.22/29.08  tff(decl_52535, type, 'Menopause': $i).
% 29.22/29.08  tff(decl_52536, type, 'The end of a human female\\s reproductive years, marked by the cessation of ovulation and menstruation.': $i).
% 29.22/29.08  tff(decl_52537, type, menopause: $i).
% 29.22/29.08  tff(decl_52538, type, menstrual_cycle_1: $i > $o).
% 29.22/29.08  tff(decl_52539, type, 'Menstrual-Cycle': $i).
% 29.22/29.08  tff(decl_52540, type, 'Also called the uterine cycle. In humans and some other primates, a cycle during which the endometrial lining is shed from the uterus if an egg is not fertilized.': $i).
% 29.22/29.08  tff(decl_52541, type, 'uterine cycle': $i).
% 29.22/29.08  tff(decl_52542, type, 'uterine-cycle': $i).
% 29.22/29.08  tff(decl_52543, type, menses: $i).
% 29.22/29.08  tff(decl_52544, type, period: $i).
% 29.22/29.08  tff(decl_52545, type, 'menstrual cycle': $i).
% 29.22/29.08  tff(decl_52546, type, 'menstrual-cycle': $i).
% 29.22/29.08  tff(decl_52547, type, menstrual_flow_1: $i > $o).
% 29.22/29.08  tff(decl_52548, type, 'Menstrual-Flow': $i).
% 29.22/29.08  tff(decl_52549, type, 'The part of the menstrual cycle when menstrual fluid is shed.': $i).
% 29.22/29.08  tff(decl_52550, type, 'menstrual flow': $i).
% 29.22/29.08  tff(decl_52551, type, 'menstrual-flow': $i).
% 29.22/29.08  tff(decl_52552, type, menstruation_1: $i > $o).
% 29.22/29.08  tff(decl_52553, type, 'Menstruation': $i).
% 29.22/29.08  tff(decl_52554, type, 'The shedding of part of the endometrial lining when an egg is not fertilized during a menstrual (uterine) cycle.': $i).
% 29.22/29.08  tff(decl_52555, type, menstruate: $i).
% 29.22/29.08  tff(decl_52556, type, menstruation: $i).
% 29.22/29.08  tff(decl_52557, type, 'Mental-Or-Brain-Disorder': $i).
% 29.22/29.08  tff(decl_52558, type, 'A disorder affecting one\\s brain or mental health.': $i).
% 29.22/29.08  tff(decl_52559, type, 'mental or brain disorder': $i).
% 29.22/29.08  tff(decl_52560, type, 'mental-or-brain-disorder': $i).
% 29.22/29.08  tff(decl_52561, type, mercury_1: $i > $o).
% 29.22/29.08  tff(decl_52562, type, 'Mercury': $i).
% 29.22/29.08  tff(decl_52563, type, 'Mercury is a metal atom with atomic number 80. It is represented by the symbol Hg.': $i).
% 29.22/29.08  tff(decl_52564, type, mercury: $i).
% 29.22/29.08  tff(decl_52565, type, 'Hg': $i).
% 29.22/29.08  tff(decl_52566, type, fn_mercury_3: $i > $i).
% 29.22/29.08  tff(decl_52567, type, fn_mercury_4: $i > $i).
% 29.22/29.08  tff(decl_52568, type, fn_mercury_5: $i > $i).
% 29.22/29.08  tff(decl_52569, type, fn_mercury_9: $i > $i).
% 29.22/29.08  tff(decl_52570, type, fn_mercury_10: $i > $i).
% 29.22/29.08  tff(decl_52571, type, fn_mercury_11: $i > $i).
% 29.22/29.08  tff(decl_52572, type, fn_mercury_12: $i > $i).
% 29.22/29.08  tff(decl_52573, type, "121": $i).
% 29.22/29.08  tff(decl_52574, type, "201": $i).
% 29.22/29.08  tff(decl_52575, type, "200.6": $i).
% 29.22/29.08  tff(decl_52576, type, fn_mercury_7: $i > $i).
% 29.22/29.08  tff(decl_52577, type, fn_mercury_8: $i > $i).
% 29.22/29.08  tff(decl_52578, type, fn_mercury_6: $i > $i).
% 29.22/29.08  tff(decl_52579, type, 'Meristem': $i).
% 29.22/29.08  tff(decl_52580, type, 'Plant tissue consisting of undifferentiated cells, found in regions where growth can occur.': $i).
% 29.22/29.08  tff(decl_52581, type, meristem: $i).
% 29.22/29.08  tff(decl_52582, type, meristem_identity_gene_1: $i > $o).
% 29.22/29.08  tff(decl_52583, type, 'Meristem-Identity-Gene': $i).
% 29.22/29.08  tff(decl_52584, type, 'A plant gene that facilitates the change from vegetative growth to flower production.': $i).
% 29.22/29.08  tff(decl_52585, type, 'meristem identity gene': $i).
% 29.22/29.08  tff(decl_52586, type, 'meristem-identity gene': $i).
% 29.22/29.08  tff(decl_52587, type, 'meristem-identity-gene': $i).
% 29.22/29.08  tff(decl_52588, type, 'Meroblastic-Cleavage': $i).
% 29.22/29.08  tff(decl_52589, type, 'A type of cleavage that occurs in yolk-rich eggs. Instead of the egg dividing completely, in meroblastic cleavage the cleavage furrows do not penetrate into the yolk, resulting in an embryo with one large cell and many smaller cells.': $i).
% 29.22/29.08  tff(decl_52590, type, 'undergo meroblastic cleavage': $i).
% 29.22/29.08  tff(decl_52591, type, 'meroblastic cleavage': $i).
% 29.22/29.08  tff(decl_52592, type, 'meroblastic-cleavage': $i).
% 29.22/29.08  tff(decl_52593, type, meronymic_relation_1: $i > $o).
% 29.22/29.08  tff(decl_52594, type, 'Meronymic-Relation': $i).
% 29.22/29.08  tff(decl_52595, type, 'A meronymic relation is a relation between parts and wholes. The parts of an entity are other entities, and the parts or steps of an event are other events. If a relation is a meronymic relation, then its inverse is also a meronymic relation.': $i).
% 29.22/29.08  tff(decl_52596, type, 'meronymic relation': $i).
% 29.22/29.08  tff(decl_52597, type, 'meronymic-relation': $i).
% 29.22/29.08  tff(decl_52598, type, 'Meselson-and-Stahl-Experiment': $i).
% 29.22/29.08  tff(decl_52599, type, 'An experiment that showed that DNA replicates by a semiconservative mechanism, resulting in two DNA molecules, with each containing one new strand and one old strand.': $i).
% 29.22/29.08  tff(decl_52600, type, 'meselson and stahl experiment': $i).
% 29.22/29.08  tff(decl_52601, type, 'meselson-and-stahl-experiment': $i).
% 29.22/29.08  tff(decl_52602, type, fn_meselson_and_stahl_experiment_1: $i > $i).
% 29.22/29.08  tff(decl_52603, type, fn_meselson_and_stahl_experiment_2: $i > $i).
% 29.22/29.08  tff(decl_52604, type, fn_meselson_and_stahl_experiment_3: $i > $i).
% 29.22/29.08  tff(decl_52605, type, fn_meselson_and_stahl_experiment_4: $i > $i).
% 29.22/29.08  tff(decl_52606, type, fn_meselson_and_stahl_experiment_7: $i > $i).
% 29.22/29.08  tff(decl_52607, type, fn_meselson_and_stahl_experiment_8: $i > $i).
% 29.22/29.08  tff(decl_52608, type, fn_meselson_and_stahl_experiment_9: $i > $i).
% 29.22/29.08  tff(decl_52609, type, fn_meselson_and_stahl_experiment_10: $i > $i).
% 29.22/29.08  tff(decl_52610, type, fn_meselson_and_stahl_experiment_11: $i > $i).
% 29.22/29.08  tff(decl_52611, type, fn_meselson_and_stahl_experiment_12: $i > $i).
% 29.22/29.08  tff(decl_52612, type, fn_meselson_and_stahl_experiment_13: $i > $i).
% 29.22/29.08  tff(decl_52613, type, fn_meselson_and_stahl_experiment_14: $i > $i).
% 29.22/29.08  tff(decl_52614, type, fn_meselson_and_stahl_experiment_15: $i > $i).
% 29.22/29.08  tff(decl_52615, type, fn_meselson_and_stahl_experiment_16: $i > $i).
% 29.22/29.08  tff(decl_52616, type, fn_meselson_and_stahl_experiment_17: $i > $i).
% 29.22/29.08  tff(decl_52617, type, fn_meselson_and_stahl_experiment_18: $i > $i).
% 29.22/29.08  tff(decl_52618, type, fn_meselson_and_stahl_experiment_19: $i > $i).
% 29.22/29.08  tff(decl_52619, type, fn_meselson_and_stahl_experiment_20: $i > $i).
% 29.22/29.08  tff(decl_52620, type, fn_meselson_and_stahl_experiment_21: $i > $i).
% 29.22/29.08  tff(decl_52621, type, nitrogen_15_1: $i > $o).
% 29.22/29.08  tff(decl_52622, type, fn_meselson_and_stahl_experiment_22: $i > $i).
% 29.22/29.08  tff(decl_52623, type, nitrogen_isotope_0: $i).
% 29.22/29.08  tff(decl_52624, type, mesenchyme_cell_1: $i > $o).
% 29.22/29.08  tff(decl_52625, type, 'Mesenchyme-Cell': $i).
% 29.22/29.08  tff(decl_52626, type, 'A cell that forms undifferentiated loose connective tissue. Mesenchyme cells derive from mesoderm during embryonic development.': $i).
% 29.22/29.08  tff(decl_52627, type, 'cell of mesenchyme': $i).
% 29.22/29.08  tff(decl_52628, type, 'mesenchyme cell': $i).
% 29.22/29.08  tff(decl_52629, type, 'mesenchyme-cell': $i).
% 29.22/29.08  tff(decl_52630, type, fn_mesenchyme_cell_1: $i > $i).
% 29.22/29.08  tff(decl_52631, type, fn_mesenchyme_cell_2: $i > $i).
% 29.22/29.08  tff(decl_52632, type, fn_mesenchyme_cell_3: $i > $i).
% 29.22/29.08  tff(decl_52633, type, mesentery_1: $i > $o).
% 29.22/29.08  tff(decl_52634, type, 'Mesentery': $i).
% 29.22/29.08  tff(decl_52635, type, 'The layers of peritoneum that attach the gut system and its associated organs, for example, the spleen, to the dorsal surface of the peritoneal cavity.': $i).
% 29.22/29.08  tff(decl_52636, type, mesentery: $i).
% 29.22/29.08  tff(decl_52637, type, 'Mesoderm': $i).
% 29.22/29.08  tff(decl_52638, type, 'In bilateral animals, the middle of the three embryonic germ layers. Mesoderm develops into the coelom, muscles, endoskeletal system, kidneys, gonads, vascular system, and notochord (in chordates only).': $i).
% 29.22/29.08  tff(decl_52639, type, mesoderm: $i).
% 29.22/29.08  tff(decl_52640, type, 'Mesohyl': $i).
% 29.22/29.08  tff(decl_52641, type, 'In sponges, the gelatinous matrix that fills the space between the external pinacoderm layer and the inner choanoderm layer.': $i).
% 29.22/29.08  tff(decl_52642, type, mesenchyme: $i).
% 29.22/29.08  tff(decl_52643, type, mesohyl: $i).
% 29.22/29.08  tff(decl_52644, type, 'Mesophyll': $i).
% 29.22/29.08  tff(decl_52645, type, 'Most of the interior of the leaf between the upper and lower layers of epidermis is a parenchyma (ground tissue) or chlorenchyma tissue called the mesophyll.': $i).
% 29.22/29.08  tff(decl_52646, type, mesophyll: $i).
% 29.22/29.08  tff(decl_52647, type, fn_mesophyll_3: $i > $i).
% 29.22/29.08  tff(decl_52648, type, fn_mesophyll_4: $i > $i).
% 29.22/29.08  tff(decl_52649, type, fn_mesophyll_7: $i > $i).
% 29.22/29.08  tff(decl_52650, type, fn_mesophyll_8: $i > $i).
% 29.22/29.08  tff(decl_52651, type, fn_mesophyll_9: $i > $i).
% 29.22/29.08  tff(decl_52652, type, 'Mesophyll-Cell': $i).
% 29.22/29.08  tff(decl_52653, type, 'Mesophyll cells are the objects inside a cross-section of a leaf which are loosley packed cells that give the leaf a spongy appearence.': $i).
% 29.22/29.08  tff(decl_52654, type, 'cell of mesophyll': $i).
% 29.22/29.08  tff(decl_52655, type, 'mesophyll cell': $i).
% 29.22/29.08  tff(decl_52656, type, 'mesophyll-cell': $i).
% 29.22/29.08  tff(decl_52657, type, mesquite_1: $i > $o).
% 29.22/29.08  tff(decl_52658, type, 'Mesquite': $i).
% 29.22/29.08  tff(decl_52659, type, 'Tree-like legume which is adapted for life in desert climates.': $i).
% 29.22/29.08  tff(decl_52660, type, mesquite: $i).
% 29.22/29.08  tff(decl_52661, type, fn_mesquite_1: $i > $i).
% 29.22/29.08  tff(decl_52662, type, fn_mesquite_2: $i > $i).
% 29.22/29.08  tff(decl_52663, type, fn_mesquite_5: $i > $i).
% 29.22/29.08  tff(decl_52664, type, "20.0e0": $i).
% 29.22/29.08  tff(decl_52665, type, 'Message': $i).
% 29.22/29.08  tff(decl_52666, type, 'an encoding of information in a language': $i).
% 29.22/29.08  tff(decl_52667, type, message: $i).
% 29.22/29.08  tff(decl_52668, type, fn_message_1: $i > $i).
% 29.22/29.08  tff(decl_52669, type, 'Message-Field': $i).
% 29.22/29.08  tff(decl_52670, type, 'a message whose content is a single constant': $i).
% 29.22/29.08  tff(decl_52671, type, 'field of message': $i).
% 29.22/29.08  tff(decl_52672, type, 'message field': $i).
% 29.22/29.08  tff(decl_52673, type, 'message-field': $i).
% 29.22/29.08  tff(decl_52674, type, 'Messenger': $i).
% 29.22/29.08  tff(decl_52675, type, 'A molecule that relays a message.': $i).
% 29.22/29.08  tff(decl_52676, type, messenger: $i).
% 29.22/29.08  tff(decl_52677, type, metabolic_disequilibrium_1: $i > $o).
% 29.22/29.08  tff(decl_52678, type, 'Metabolic-Disequilibrium': $i).
% 29.22/29.08  tff(decl_52679, type, 'metabolic disequilibrium': $i).
% 29.22/29.08  tff(decl_52680, type, 'metabolic-disequilibrium': $i).
% 29.22/29.08  tff(decl_52681, type, 'Metabolic-Disorder': $i).
% 29.22/29.08  tff(decl_52682, type, 'Any disease or disorder that disrupts normal metabolic processes.': $i).
% 29.22/29.08  tff(decl_52683, type, 'metabolic disorder': $i).
% 29.22/29.08  tff(decl_52684, type, 'metabolic-disorder': $i).
% 29.22/29.08  tff(decl_52685, type, 'Metabolic-Pathway': $i).
% 29.22/29.08  tff(decl_52686, type, 'Metabolic pathways are series of chemical reactions occurring within a cell.': $i).
% 29.22/29.08  tff(decl_52687, type, 'metabolic pathway': $i).
% 29.22/29.08  tff(decl_52688, type, 'metabolic-pathway': $i).
% 29.22/29.08  tff(decl_52689, type, metabolically_active_cell_1: $i > $o).
% 29.22/29.08  tff(decl_52690, type, 'Metabolically-Active-Cell': $i).
% 29.22/29.08  tff(decl_52691, type, 'Metabolic activity refers to the set of chemical reactions that maintain life in any organism. The state of high metabolism is a cell is calle as Cell-with-high-metabolic-activity.': $i).
% 29.22/29.08  tff(decl_52692, type, 'cell with high metabolic activity': $i).
% 29.22/29.08  tff(decl_52693, type, 'metabolically active cell': $i).
% 29.22/29.08  tff(decl_52694, type, 'metabolically-active-cell': $i).
% 29.22/29.08  tff(decl_52695, type, fn_metabolically_active_cell_2: $i > $i).
% 29.22/29.08  tff(decl_52696, type, fn_metabolically_active_cell_3: $i > $i).
% 29.22/29.08  tff(decl_52697, type, fn_metabolically_active_cell_4: $i > $i).
% 29.22/29.08  tff(decl_52698, type, fn_metabolically_active_cell_5: $i > $i).
% 29.22/29.08  tff(decl_52699, type, fn_metabolically_active_cell_6: $i > $i).
% 29.22/29.08  tff(decl_52700, type, fn_metabolically_active_cell_7: $i > $i).
% 29.22/29.08  tff(decl_52701, type, fn_metabolically_active_cell_10: $i > $i).
% 29.22/29.08  tff(decl_52702, type, fn_metabolically_active_cell_11: $i > $i).
% 29.22/29.08  tff(decl_52703, type, fn_metabolically_active_cell_12: $i > $i).
% 29.22/29.08  tff(decl_52704, type, fn_metabolically_active_cell_13: $i > $i).
% 29.22/29.08  tff(decl_52705, type, fn_metabolically_active_cell_14: $i > $i).
% 29.22/29.08  tff(decl_52706, type, fn_metabolically_active_cell_15: $i > $i).
% 29.22/29.08  tff(decl_52707, type, fn_metabolically_active_cell_16: $i > $i).
% 29.22/29.08  tff(decl_52708, type, fn_metabolically_active_cell_17: $i > $i).
% 29.22/29.08  tff(decl_52709, type, fn_metabolically_active_cell_18: $i > $i).
% 29.22/29.08  tff(decl_52710, type, fn_metabolically_active_cell_19: $i > $i).
% 29.22/29.08  tff(decl_52711, type, fn_metabolically_active_cell_20: $i > $i).
% 29.22/29.08  tff(decl_52712, type, fn_metabolically_active_cell_21: $i > $i).
% 29.22/29.08  tff(decl_52713, type, fn_metabolically_active_cell_22: $i > $i).
% 29.22/29.08  tff(decl_52714, type, fn_metabolically_active_cell_23: $i > $i).
% 29.22/29.08  tff(decl_52715, type, fn_metabolically_active_cell_24: $i > $i).
% 29.22/29.08  tff(decl_52716, type, fn_metabolically_active_cell_25: $i > $i).
% 29.22/29.08  tff(decl_52717, type, fn_metabolically_active_cell_26: $i > $i).
% 29.22/29.08  tff(decl_52718, type, fn_metabolically_active_cell_27: $i > $i).
% 29.22/29.08  tff(decl_52719, type, fn_metabolically_active_cell_28: $i > $i).
% 29.22/29.08  tff(decl_52720, type, fn_metabolically_active_cell_29: $i > $i).
% 29.22/29.08  tff(decl_52721, type, fn_metabolically_active_cell_30: $i > $i).
% 29.22/29.08  tff(decl_52722, type, fn_metabolically_active_cell_31: $i > $i).
% 29.22/29.08  tff(decl_52723, type, fn_metabolically_active_cell_32: $i > $i).
% 29.22/29.08  tff(decl_52724, type, fn_metabolically_active_cell_33: $i > $i).
% 29.22/29.08  tff(decl_52725, type, fn_nuclear_membrane_27: $i > $i).
% 29.22/29.08  tff(decl_52726, type, fn_synthesis_of_endomembranous_system_membrane_83: $i > $i).
% 29.22/29.08  tff(decl_52727, type, fn_rough_endoplasmic_reticulum_66: $i > $i).
% 29.22/29.08  tff(decl_52728, type, fn_synthesis_of_endomembranous_system_membrane_55: $i > $i).
% 29.22/29.08  tff(decl_52729, type, fn_nuclear_membrane_9: $i > $i).
% 29.22/29.08  tff(decl_52730, type, fn_metabolically_active_cell_9: $i > $i).
% 29.22/29.08  tff(decl_52731, type, fn_metabolically_active_cell_8: $i > $i).
% 29.22/29.08  tff(decl_52732, type, 'Metabolism': $i).
% 29.22/29.08  tff(decl_52733, type, 'Metabolism is the set of chemical reactions that occur in living organisms to maintain life. These processes allow organisms to grow and reproduce, maintain their structures, and respond to their environments. Metabolism is usually divided into two categories. Catabolism breaks down organic matter, for example to harvest energy in cellular respiration. Anabolism, on the other hand, uses energy to construct components of cells such as proteins and nucleic acids': $i).
% 29.22/29.08  tff(decl_52734, type, 'metabolic process': $i).
% 29.22/29.08  tff(decl_52735, type, 'cellular metabolism': $i).
% 29.22/29.08  tff(decl_52736, type, 'cellular-metabolism': $i).
% 29.22/29.08  tff(decl_52737, type, metabolize: $i).
% 29.22/29.08  tff(decl_52738, type, metabolism: $i).
% 29.22/29.08  tff(decl_52739, type, metal_1: $i > $o).
% 29.22/29.08  tff(decl_52740, type, 'Metal': $i).
% 29.22/29.08  tff(decl_52741, type, metal: $i).
% 29.22/29.08  tff(decl_52742, type, 'metallic element': $i).
% 29.22/29.08  tff(decl_52743, type, metallic_element: $i).
% 29.22/29.08  tff(decl_52744, type, alloy: $i).
% 29.22/29.08  tff(decl_52745, type, fn_metal_1: $i > $i).
% 29.22/29.08  tff(decl_52746, type, 'Metal-Atom': $i).
% 29.22/29.08  tff(decl_52747, type, 'Metals are elements that are usually solids at room temperature, exhibit high electrical and heat conductivity, and appear lustrous. Most of the elements in the periodic table are metals.': $i).
% 29.22/29.08  tff(decl_52748, type, 'atom of metal': $i).
% 29.22/29.08  tff(decl_52749, type, 'metal atom': $i).
% 29.22/29.08  tff(decl_52750, type, 'metal-atom': $i).
% 29.22/29.08  tff(decl_52751, type, 'Metal-Cation': $i).
% 29.22/29.08  tff(decl_52752, type, 'A metal cation is a positively charged metal ion.': $i).
% 29.22/29.08  tff(decl_52753, type, 'cation of metal': $i).
% 29.22/29.08  tff(decl_52754, type, 'metal cation': $i).
% 29.22/29.08  tff(decl_52755, type, 'metal-cation': $i).
% 29.22/29.08  tff(decl_52756, type, 'Metalloid-Atom': $i).
% 29.22/29.08  tff(decl_52757, type, 'Metalloids are elements that lie along the diagonal line separating the metals from the nonmetals in the periodic table; the properties of metalloids are intermediate between those of metals and nonmetals.': $i).
% 29.22/29.08  tff(decl_52758, type, 'metalloid atom': $i).
% 29.22/29.08  tff(decl_52759, type, 'metalloid-atom': $i).
% 29.22/29.08  tff(decl_52760, type, 'Metamorphosis': $i).
% 29.22/29.08  tff(decl_52761, type, 'Metamorphosis is a developmental process which occurs in some animals during which an animal in an immature larval stage transforms into a sexually-immature juvenile.': $i).
% 29.22/29.08  tff(decl_52762, type, transformation: $i).
% 29.22/29.08  tff(decl_52763, type, metamorphosis: $i).
% 29.22/29.08  tff(decl_52764, type, fn_metamorphosis_2: $i > $i).
% 29.22/29.08  tff(decl_52765, type, metamorphosis_in_frog_1: $i > $o).
% 29.22/29.08  tff(decl_52766, type, 'Metamorphosis-In-Frog': $i).
% 29.22/29.08  tff(decl_52767, type, 'The process of metamorphosis from tadpole to frog.': $i).
% 29.22/29.08  tff(decl_52768, type, 'metamorphosis in frog': $i).
% 29.22/29.08  tff(decl_52769, type, 'metamorphosis-in-frog': $i).
% 29.22/29.08  tff(decl_52770, type, fn_metamorphosis_in_frog_1: $i > $i).
% 29.22/29.08  tff(decl_52771, type, fn_metamorphosis_in_frog_2: $i > $i).
% 29.22/29.08  tff(decl_52772, type, fn_metamorphosis_in_frog_3: $i > $i).
% 29.22/29.08  tff(decl_52773, type, fn_metamorphosis_in_frog_4: $i > $i).
% 29.22/29.08  tff(decl_52774, type, fn_metamorphosis_in_frog_5: $i > $i).
% 29.22/29.08  tff(decl_52775, type, metanephridium_1: $i > $o).
% 29.22/29.08  tff(decl_52776, type, 'Metanephridium': $i).
% 29.22/29.08  tff(decl_52777, type, 'An excretory organ found in many aquatic invertebrates. A metanephridium typically consist of a ciliated funnel attached to a long tubules that opens to the outside.': $i).
% 29.22/29.08  tff(decl_52778, type, metanephridia: $i).
% 29.22/29.08  tff(decl_52779, type, metanephridium: $i).
% 29.22/29.08  tff(decl_52780, type, metaphase_1: $i > $o).
% 29.22/29.08  tff(decl_52781, type, 'Metaphase': $i).
% 29.22/29.08  tff(decl_52782, type, 'The stage of mitosis in which chromosomes are lined up at the metaphase plate, the spindle complex is completely formed, and the kinetochore of each chromatid is attached to its microtubule.': $i).
% 29.22/29.08  tff(decl_52783, type, 'undergo metaphase': $i).
% 29.22/29.08  tff(decl_52784, type, metaphase: $i).
% 29.22/29.08  tff(decl_52785, type, fn_metaphase_1: $i > $i).
% 29.22/29.08  tff(decl_52786, type, fn_metaphase_2: $i > $i).
% 29.22/29.08  tff(decl_52787, type, fn_metaphase_3: $i > $i).
% 29.22/29.08  tff(decl_52788, type, fn_metaphase_4: $i > $i).
% 29.22/29.08  tff(decl_52789, type, fn_metaphase_5: $i > $i).
% 29.22/29.08  tff(decl_52790, type, fn_metaphase_6: $i > $i).
% 29.22/29.08  tff(decl_52791, type, fn_metaphase_7: $i > $i).
% 29.22/29.08  tff(decl_52792, type, fn_metaphase_8: $i > $i).
% 29.22/29.08  tff(decl_52793, type, fn_metaphase_9: $i > $i).
% 29.22/29.08  tff(decl_52794, type, fn_metaphase_10: $i > $i).
% 29.22/29.08  tff(decl_52795, type, fn_metaphase_11: $i > $i).
% 29.22/29.08  tff(decl_52796, type, fn_metaphase_12: $i > $i).
% 29.22/29.08  tff(decl_52797, type, fn_metaphase_13: $i > $i).
% 29.22/29.08  tff(decl_52798, type, fn_metaphase_14: $i > $i).
% 29.22/29.08  tff(decl_52799, type, fn_metaphase_15: $i > $i).
% 29.22/29.08  tff(decl_52800, type, fn_metaphase_16: $i > $i).
% 29.22/29.08  tff(decl_52801, type, fn_metaphase_17: $i > $i).
% 29.22/29.08  tff(decl_52802, type, fn_metaphase_18: $i > $i).
% 29.22/29.08  tff(decl_52803, type, fn_metaphase_19: $i > $i).
% 29.22/29.08  tff(decl_52804, type, fn_metaphase_20: $i > $i).
% 29.22/29.08  tff(decl_52805, type, fn_metaphase_21: $i > $i).
% 29.22/29.08  tff(decl_52806, type, fn_metaphase_22: $i > $i).
% 29.22/29.08  tff(decl_52807, type, fn_metaphase_23: $i > $i).
% 29.22/29.08  tff(decl_52808, type, fn_metaphase_24: $i > $i).
% 29.22/29.08  tff(decl_52809, type, fn_metaphase_25: $i > $i).
% 29.22/29.08  tff(decl_52810, type, fn_metaphase_26: $i > $i).
% 29.22/29.08  tff(decl_52811, type, fn_metaphase_27: $i > $i).
% 29.22/29.08  tff(decl_52812, type, fn_metaphase_28: $i > $i).
% 29.22/29.08  tff(decl_52813, type, fn_metaphase_29: $i > $i).
% 29.22/29.08  tff(decl_52814, type, fn_metaphase_30: $i > $i).
% 29.22/29.08  tff(decl_52815, type, fn_metaphase_31: $i > $i).
% 29.22/29.08  tff(decl_52816, type, fn_metaphase_plate_1: $i > $i).
% 29.22/29.08  tff(decl_52817, type, fn_metaphase_plate_2: $i > $i).
% 29.22/29.08  tff(decl_52818, type, fn_mitotic_spindle_1: $i > $i).
% 29.22/29.08  tff(decl_52819, type, fn_metaphase_plate_7: $i > $i).
% 29.22/29.08  tff(decl_52820, type, fn_metaphase_plate_5: $i > $i).
% 29.22/29.08  tff(decl_52821, type, is_at_0: $i).
% 29.22/29.08  tff(decl_52822, type, cell_opposite_pole_0: $i).
% 29.22/29.08  tff(decl_52823, type, metaphase_chromatin_1: $i > $o).
% 29.22/29.08  tff(decl_52824, type, 'Metaphase-Chromatin': $i).
% 29.22/29.08  tff(decl_52825, type, 'The metaphase structure of chromatin differs vastly to that of interphase. It is optimised for physical strength and manageability, forming the classic chromosome structure seen in karyotypes. The structure of the condensed chromosome is thought to be loops of 30 nm fibre to a central scaffold of proteins. It is, however, not well characterised.The physical strength of chromatin is vital for this stage of division to prevent shear damage to the DNA as the daughter chromosomes are separated. To maximise strength the composition of the chromatin changes as it approaches the centromere, primarily through alternative histone H1 anologues.': $i).
% 29.22/29.08  tff(decl_52826, type, 'chromatin of metaphase': $i).
% 29.22/29.08  tff(decl_52827, type, 'metaphase chromatin': $i).
% 29.22/29.08  tff(decl_52828, type, 'metaphase-chromatin': $i).
% 29.22/29.08  tff(decl_52829, type, metaphase_i_1: $i > $o).
% 29.22/29.08  tff(decl_52830, type, fn_metaphase_i_2: $i > $i).
% 29.22/29.08  tff(decl_52831, type, fn_metaphase_i_7: $i > $i).
% 29.22/29.08  tff(decl_52832, type, fn_metaphase_i_8: $i > $i).
% 29.22/29.08  tff(decl_52833, type, fn_metaphase_i_4: $i > $i).
% 29.22/29.08  tff(decl_52834, type, 'Metaphase-I': $i).
% 29.22/29.08  tff(decl_52835, type, 'The chromosomes are arranged on the metaphase plate. Kinetochore microtubules are attached to one chromosome of each pair. The microtubules from the opposite pole are attached to the homologous.': $i).
% 29.22/29.08  tff(decl_52836, type, 'undergo metaphase i': $i).
% 29.22/29.08  tff(decl_52837, type, 'undergo metaphase-i': $i).
% 29.22/29.08  tff(decl_52838, type, 'metaphase i': $i).
% 29.22/29.08  tff(decl_52839, type, 'metaphase-i': $i).
% 29.22/29.08  tff(decl_52840, type, fn_metaphase_i_3: $i > $i).
% 29.22/29.08  tff(decl_52841, type, fn_metaphase_i_5: $i > $i).
% 29.22/29.08  tff(decl_52842, type, fn_metaphase_i_6: $i > $i).
% 29.22/29.08  tff(decl_52843, type, 'Metaphase-II': $i).
% 29.22/29.08  tff(decl_52844, type, 'The chromosomes are arranged on the metaphase plate. The kinetochore of the sister-chromatids of each chromosome pointing toward the opposite poles.': $i).
% 29.22/29.08  tff(decl_52845, type, 'undergo metaphase ii': $i).
% 29.22/29.08  tff(decl_52846, type, 'undergo metaphase-ii': $i).
% 29.22/29.08  tff(decl_52847, type, 'metaphase ii': $i).
% 29.22/29.08  tff(decl_52848, type, 'metaphase-ii': $i).
% 29.22/29.08  tff(decl_52849, type, fn_metaphase_ii_1: $i > $i).
% 29.22/29.08  tff(decl_52850, type, fn_metaphase_ii_2: $i > $i).
% 29.22/29.08  tff(decl_52851, type, fn_metaphase_ii_3: $i > $i).
% 29.22/29.08  tff(decl_52852, type, fn_metaphase_ii_4: $i > $i).
% 29.22/29.08  tff(decl_52853, type, fn_metaphase_ii_5: $i > $i).
% 29.22/29.08  tff(decl_52854, type, 'Metaphase-Plate': $i).
% 29.22/29.08  tff(decl_52855, type, 'An imaginary plane along the equator of a cell in metaphase. As duplicated chromosomes line up during the metaphase, their centromeres align on the metaphase plate.': $i).
% 29.22/29.08  tff(decl_52856, type, 'equatorial plate': $i).
% 29.22/29.08  tff(decl_52857, type, 'equatorial-plate': $i).
% 29.22/29.08  tff(decl_52858, type, 'plate of metaphase': $i).
% 29.22/29.08  tff(decl_52859, type, 'metaphase plate': $i).
% 29.22/29.08  tff(decl_52860, type, 'metaphase-plate': $i).
% 29.22/29.08  tff(decl_52861, type, fn_metaphase_plate_3: $i > $i).
% 29.22/29.08  tff(decl_52862, type, fn_metaphase_plate_4: $i > $i).
% 29.22/29.08  tff(decl_52863, type, fn_metaphase_plate_6: $i > $i).
% 29.22/29.08  tff(decl_52864, type, metapopulation_1: $i > $o).
% 29.22/29.08  tff(decl_52865, type, 'Metapopulation': $i).
% 29.22/29.08  tff(decl_52866, type, 'A group of populations of one species that are spatially separated but interact to some degree, including by immigration and emigration.': $i).
% 29.22/29.08  tff(decl_52867, type, metapopulation: $i).
% 29.22/29.08  tff(decl_52868, type, metastasis_1: $i > $o).
% 29.22/29.08  tff(decl_52869, type, 'Metastasis': $i).
% 29.22/29.08  tff(decl_52870, type, 'The dispersal of cancer cells from their original site to other parts of the body.': $i).
% 29.22/29.08  tff(decl_52871, type, metastasize: $i).
% 29.22/29.08  tff(decl_52872, type, metastasis: $i).
% 29.22/29.08  tff(decl_52873, type, fn_metastasis_1: $i > $i).
% 29.22/29.08  tff(decl_52874, type, fn_metastasis_2: $i > $i).
% 29.22/29.08  tff(decl_52875, type, fn_metastasis_3: $i > $i).
% 29.22/29.08  tff(decl_52876, type, fn_metastasis_4: $i > $i).
% 29.22/29.08  tff(decl_52877, type, fn_metastasis_5: $i > $i).
% 29.22/29.08  tff(decl_52878, type, fn_metastasis_6: $i > $i).
% 29.22/29.08  tff(decl_52879, type, surface_protein_1: $i > $o).
% 29.22/29.08  tff(decl_52880, type, fn_metastasis_7: $i > $i).
% 29.22/29.08  tff(decl_52881, type, fn_metastasis_8: $i > $i).
% 29.22/29.08  tff(decl_52882, type, fn_metastasis_9: $i > $i).
% 29.22/29.08  tff(decl_52883, type, fn_metastasis_10: $i > $i).
% 29.22/29.08  tff(decl_52884, type, fn_metastasis_11: $i > $i).
% 29.22/29.08  tff(decl_52885, type, fn_metastasis_12: $i > $i).
% 29.22/29.08  tff(decl_52886, type, fn_metastasis_13: $i > $i).
% 29.22/29.08  tff(decl_52887, type, fn_metastasis_14: $i > $i).
% 29.22/29.08  tff(decl_52888, type, fn_metastasis_15: $i > $i).
% 29.22/29.08  tff(decl_52889, type, fn_metastasis_16: $i > $i).
% 29.22/29.08  tff(decl_52890, type, fn_metastasis_17: $i > $i).
% 29.22/29.08  tff(decl_52891, type, fn_metastasis_18: $i > $i).
% 29.22/29.08  tff(decl_52892, type, fn_metastasis_19: $i > $i).
% 29.22/29.08  tff(decl_52893, type, fn_metastasis_20: $i > $i).
% 29.22/29.08  tff(decl_52894, type, fn_metastasis_21: $i > $i).
% 29.22/29.08  tff(decl_52895, type, fn_metastasis_22: $i > $i).
% 29.22/29.08  tff(decl_52896, type, fn_metastasis_23: $i > $i).
% 29.22/29.08  tff(decl_52897, type, fn_metastasis_24: $i > $i).
% 29.22/29.08  tff(decl_52898, type, fn_metastasis_25: $i > $i).
% 29.22/29.08  tff(decl_52899, type, fn_metastasis_26: $i > $i).
% 29.22/29.08  tff(decl_52900, type, fn_metastasis_27: $i > $i).
% 29.22/29.08  tff(decl_52901, type, fn_metastasis_28: $i > $i).
% 29.22/29.08  tff(decl_52902, type, fn_metastasis_29: $i > $i).
% 29.22/29.08  tff(decl_52903, type, fn_metastasis_30: $i > $i).
% 29.22/29.08  tff(decl_52904, type, fn_metastasis_31: $i > $i).
% 29.22/29.08  tff(decl_52905, type, fn_metastasis_32: $i > $i).
% 29.22/29.08  tff(decl_52906, type, prevents_0: $i).
% 29.22/29.08  tff(decl_52907, type, animal_process_0: $i).
% 29.22/29.08  tff(decl_52908, type, methamphetamine_1: $i > $o).
% 29.22/29.08  tff(decl_52909, type, 'Methamphetamine': $i).
% 29.22/29.08  tff(decl_52910, type, 'Methamphetamine is a central nervous system stimulant drug that is similar in structure to amphetamine.': $i).
% 29.22/29.08  tff(decl_52911, type, crank: $i).
% 29.22/29.08  tff(decl_52912, type, methamphetamine: $i).
% 29.22/29.08  tff(decl_52913, type, 'Methane': $i).
% 29.22/29.08  tff(decl_52914, type, 'Methane is a chemical compound with the chemical formula CH4. It is the simplest alkane, and the principal component of natural gas.': $i).
% 29.22/29.08  tff(decl_52915, type, ch4: $i).
% 29.22/29.08  tff(decl_52916, type, methane: $i).
% 29.22/29.08  tff(decl_52917, type, fn_methane_1: $i > $i).
% 29.22/29.08  tff(decl_52918, type, fn_methane_2: $i > $i).
% 29.22/29.08  tff(decl_52919, type, fn_methane_4: $i > $i).
% 29.22/29.08  tff(decl_52920, type, fn_methane_8: $i > $i).
% 29.22/29.08  tff(decl_52921, type, fn_methane_9: $i > $i).
% 29.22/29.08  tff(decl_52922, type, fn_methane_10: $i > $i).
% 29.22/29.08  tff(decl_52923, type, fn_methane_11: $i > $i).
% 29.22/29.08  tff(decl_52924, type, fn_methane_12: $i > $i).
% 29.22/29.08  tff(decl_52925, type, methane_gas_1: $i > $o).
% 29.22/29.08  tff(decl_52926, type, 'Methane-Gas': $i).
% 29.22/29.08  tff(decl_52927, type, 'The gaseous form of methane, chemical formula CH4.': $i).
% 29.22/29.08  tff(decl_52928, type, 'gas of methane': $i).
% 29.22/29.08  tff(decl_52929, type, 'methane gas': $i).
% 29.22/29.08  tff(decl_52930, type, 'methane-gas': $i).
% 29.22/29.08  tff(decl_52931, type, fn_methane_gas_1: $i > $i).
% 29.22/29.08  tff(decl_52932, type, methanogen_1: $i > $o).
% 29.22/29.08  tff(decl_52933, type, 'Methanogen': $i).
% 29.22/29.08  tff(decl_52934, type, 'An archaean microbe that produces methane as a byproduct of metabolism in anoxic conditions.': $i).
% 29.22/29.08  tff(decl_52935, type, methanogen: $i).
% 29.22/29.08  tff(decl_52936, type, methanol_substance_1: $i > $o).
% 29.22/29.08  tff(decl_52937, type, 'Methanol-Substance': $i).
% 29.22/29.08  tff(decl_52938, type, 'A liquid substance with molecular formula CH3OH.': $i).
% 29.22/29.08  tff(decl_52939, type, 'substance of methanol': $i).
% 29.22/29.08  tff(decl_52940, type, 'methanol substance': $i).
% 29.22/29.08  tff(decl_52941, type, 'methanol-substance': $i).
% 29.22/29.08  tff(decl_52942, type, fn_methanol_substance_1: $i > $i).
% 29.22/29.08  tff(decl_52943, type, methyl_alcohol_1: $i > $o).
% 29.22/29.08  tff(decl_52944, type, fn_methanol_substance_2: $i > $i).
% 29.22/29.08  tff(decl_52945, type, "263.0e0": $i).
% 29.22/29.08  tff(decl_52946, type, 'Methionine': $i).
% 29.22/29.08  tff(decl_52947, type, 'One of the 20 most common amino acids that make up proteins.  It is usually the first amino acid to be brought to the Translation Initiation Complex by tRNA.': $i).
% 29.22/29.08  tff(decl_52948, type, met: $i).
% 29.22/29.08  tff(decl_52949, type, methionine: $i).
% 29.22/29.08  tff(decl_52950, type, m: $i).
% 29.22/29.08  tff(decl_52951, type, fn_methionine_1: $i > $i).
% 29.22/29.08  tff(decl_52952, type, fn_methionine_2: $i > $i).
% 29.22/29.08  tff(decl_52953, type, fn_methionine_3: $i > $i).
% 29.22/29.08  tff(decl_52954, type, fn_methionine_4: $i > $i).
% 29.22/29.08  tff(decl_52955, type, fn_methionine_5: $i > $i).
% 29.22/29.08  tff(decl_52956, type, fn_methionine_6: $i > $i).
% 29.22/29.08  tff(decl_52957, type, fn_methionine_7: $i > $i).
% 29.22/29.08  tff(decl_52958, type, fn_methionine_8: $i > $i).
% 29.22/29.08  tff(decl_52959, type, fn_methionine_9: $i > $i).
% 29.22/29.08  tff(decl_52960, type, fn_methionine_10: $i > $i).
% 29.22/29.08  tff(decl_52961, type, fn_methionine_11: $i > $i).
% 29.22/29.08  tff(decl_52962, type, fn_methionine_12: $i > $i).
% 29.22/29.08  tff(decl_52963, type, fn_methionine_13: $i > $i).
% 29.22/29.08  tff(decl_52964, type, fn_methionine_14: $i > $i).
% 29.22/29.08  tff(decl_52965, type, fn_methionine_15: $i > $i).
% 29.22/29.08  tff(decl_52966, type, fn_methionine_16: $i > $i).
% 29.22/29.08  tff(decl_52967, type, fn_methionine_17: $i > $i).
% 29.22/29.08  tff(decl_52968, type, fn_methionine_18: $i > $i).
% 29.22/29.08  tff(decl_52969, type, fn_methionine_19: $i > $i).
% 29.22/29.08  tff(decl_52970, type, fn_methionine_20: $i > $i).
% 29.22/29.08  tff(decl_52971, type, fn_methionine_21: $i > $i).
% 29.22/29.08  tff(decl_52972, type, fn_methionine_22: $i > $i).
% 29.22/29.08  tff(decl_52973, type, fn_methionine_23: $i > $i).
% 29.22/29.08  tff(decl_52974, type, fn_methionine_24: $i > $i).
% 29.22/29.08  tff(decl_52975, type, fn_methionine_25: $i > $i).
% 29.22/29.08  tff(decl_52976, type, 'Method': $i).
% 29.22/29.08  tff(decl_52977, type, method: $i).
% 29.22/29.08  tff(decl_52978, type, 'Methyl-Alcohol': $i).
% 29.22/29.08  tff(decl_52979, type, 'It is a organic molecule with molecular formula CH3OH.': $i).
% 29.22/29.08  tff(decl_52980, type, 'alcohol of methyl': $i).
% 29.22/29.08  tff(decl_52981, type, 'methyl alcohol': $i).
% 29.22/29.08  tff(decl_52982, type, 'methyl-alcohol': $i).
% 29.22/29.08  tff(decl_52983, type, 'Methyl-Group': $i).
% 29.22/29.08  tff(decl_52984, type, 'A chemical group consisting of a carbon bonded to three hydrogen atoms. The methyl group may be attached to a carbon or to a different atom.': $i).
% 29.22/29.08  tff(decl_52985, type, 'ch3 group': $i).
% 29.22/29.08  tff(decl_52986, type, 'ch3-group': $i).
% 29.22/29.08  tff(decl_52987, type, 'group of methyl': $i).
% 29.22/29.08  tff(decl_52988, type, 'methyl group': $i).
% 29.22/29.08  tff(decl_52989, type, 'methyl-group': $i).
% 29.22/29.08  tff(decl_52990, type, fn_methyl_group_1: $i > $i).
% 29.22/29.08  tff(decl_52991, type, fn_methyl_group_2: $i > $i).
% 29.22/29.08  tff(decl_52992, type, fn_methyl_group_4: $i > $i).
% 29.22/29.08  tff(decl_52993, type, fn_methyl_group_8: $i > $i).
% 29.22/29.08  tff(decl_52994, type, fn_methyl_group_9: $i > $i).
% 29.22/29.08  tff(decl_52995, type, fn_methyl_group_13: $i > $i).
% 29.22/29.08  tff(decl_52996, type, fn_methyl_group_15: $i > $i).
% 29.22/29.08  tff(decl_52997, type, fn_methyl_group_16: $i > $i).
% 29.22/29.08  tff(decl_52998, type, fn_methyl_group_17: $i > $i).
% 29.22/29.08  tff(decl_52999, type, fn_methyl_group_18: $i > $i).
% 29.22/29.08  tff(decl_53000, type, fn_methyl_group_19: $i > $i).
% 29.22/29.08  tff(decl_53001, type, fn_methyl_group_21: $i > $i).
% 29.22/29.08  tff(decl_53002, type, fn_methyl_group_22: $i > $i).
% 29.22/29.08  tff(decl_53003, type, fn_methyl_group_23: $i > $i).
% 29.22/29.08  tff(decl_53004, type, fn_methyl_group_24: $i > $i).
% 29.22/29.08  tff(decl_53005, type, fn_methyl_group_25: $i > $i).
% 29.22/29.08  tff(decl_53006, type, fn_methyl_group_26: $i > $i).
% 29.22/29.08  tff(decl_53007, type, fn_methyl_group_27: $i > $i).
% 29.22/29.08  tff(decl_53008, type, fn_methyl_group_28: $i > $i).
% 29.22/29.08  tff(decl_53009, type, 'Methyl-Ion': $i).
% 29.22/29.08  tff(decl_53010, type, 'Methyl cation.': $i).
% 29.22/29.08  tff(decl_53011, type, 'ion of methyl': $i).
% 29.22/29.08  tff(decl_53012, type, 'methyl ion': $i).
% 29.22/29.08  tff(decl_53013, type, 'methyl-ion': $i).
% 29.22/29.08  tff(decl_53014, type, methylated_compound_1: $i > $o).
% 29.22/29.08  tff(decl_53015, type, 'Methylated-Compound': $i).
% 29.22/29.08  tff(decl_53016, type, 'A compound with a methyl group is called a methylated compound': $i).
% 29.22/29.08  tff(decl_53017, type, 'methylated compound': $i).
% 29.22/29.08  tff(decl_53018, type, 'methylated-compound': $i).
% 29.22/29.08  tff(decl_53019, type, fn_methylated_compound_3: $i > $i).
% 29.22/29.08  tff(decl_53020, type, fn_methylated_compound_4: $i > $i).
% 29.22/29.08  tff(decl_53021, type, fn_methylated_compound_5: $i > $i).
% 29.22/29.08  tff(decl_53022, type, fn_methylated_compound_6: $i > $i).
% 29.22/29.08  tff(decl_53023, type, fn_methylated_compound_7: $i > $i).
% 29.22/29.08  tff(decl_53024, type, fn_methylated_compound_2: $i > $i).
% 29.22/29.08  tff(decl_53025, type, fn_methylated_compound_1: $i > $i).
% 29.22/29.08  tff(decl_53026, type, 'Methylated-DNA': $i).
% 29.22/29.08  tff(decl_53027, type, 'A portion of a DNA molecule with one or more methyl groups attached.': $i).
% 29.22/29.08  tff(decl_53028, type, 'methylated dna': $i).
% 29.22/29.08  tff(decl_53029, type, 'methylated-dna': $i).
% 29.22/29.08  tff(decl_53030, type, fn_methylated_dna_2: $i > $i).
% 29.22/29.08  tff(decl_53031, type, fn_methylated_dna_3: $i > $i).
% 29.22/29.08  tff(decl_53032, type, fn_methylated_dna_4: $i > $i).
% 29.22/29.08  tff(decl_53033, type, 'Methylation': $i).
% 29.22/29.08  tff(decl_53034, type, 'The addition of a methyl group (-CH3) to a molecule.': $i).
% 29.22/29.08  tff(decl_53035, type, methylation: $i).
% 29.22/29.08  tff(decl_53036, type, methylation_enzyme_1: $i > $o).
% 29.22/29.08  tff(decl_53037, type, 'Methylation-Enzyme': $i).
% 29.22/29.08  tff(decl_53038, type, 'Enzyme that acts to catayze the addition of methyl groups to a chemical entity.': $i).
% 29.22/29.08  tff(decl_53039, type, 'enzyme of methylation': $i).
% 29.22/29.08  tff(decl_53040, type, 'methylation enzyme': $i).
% 29.22/29.08  tff(decl_53041, type, 'methylation-enzyme': $i).
% 29.22/29.08  tff(decl_53042, type, fn_methylation_enzyme_1: $i > $i).
% 29.22/29.08  tff(decl_53043, type, 'Microbial-Cell-To-Cell-Communication': $i).
% 29.22/29.08  tff(decl_53044, type, 'The secretion of small molecules whose increase in concentration, when detected by other bacterial cells allows them to monitor the local density of cells allowing bacterial populations to coordinate their behaviors so they can carry out activities that are only productive when performed by a given number of cells in synchrony.': $i).
% 29.22/29.08  tff(decl_53045, type, 'microbial cell to cell communication': $i).
% 29.22/29.08  tff(decl_53046, type, 'microbial-cell-to-cell-communication': $i).
% 29.22/29.08  tff(decl_53047, type, 'Microclimate': $i).
% 29.22/29.08  tff(decl_53048, type, 'Climatic conditions on a very small spatial scale, as under a log or on the surface of a rock in the intertidal.': $i).
% 29.22/29.08  tff(decl_53049, type, microclimate: $i).
% 29.22/29.08  tff(decl_53050, type, 'Microevolution': $i).
% 29.22/29.08  tff(decl_53051, type, 'Evolutionary processes that occur below the level of species; changes in population allele frequences over generations.': $i).
% 29.22/29.08  tff(decl_53052, type, microevolution: $i).
% 29.22/29.08  tff(decl_53053, type, 'Microfibril': $i).
% 29.22/29.08  tff(decl_53054, type, 'Parallel cellulose molecules hydrogen bond with each other, producing microfibrils. Microfibrils are produced by an enzyme called cellulose synthase and become embedded in a matrix of polysaccharides and protein in the extracellular matrix.': $i).
% 29.22/29.08  tff(decl_53055, type, microfibril: $i).
% 29.22/29.08  tff(decl_53056, type, fn_microfibril_2: $i > $i).
% 29.22/29.08  tff(decl_53057, type, fn_microfibril_4: $i > $i).
% 29.22/29.08  tff(decl_53058, type, fn_microfibril_7: $i > $i).
% 29.22/29.08  tff(decl_53059, type, fn_microfibril_9: $i > $i).
% 29.22/29.08  tff(decl_53060, type, fn_microfibril_10: $i > $i).
% 29.22/29.08  tff(decl_53061, type, fn_microfibril_11: $i > $i).
% 29.22/29.08  tff(decl_53062, type, fn_microfibril_12: $i > $i).
% 29.22/29.08  tff(decl_53063, type, fn_microfibril_14: $i > $i).
% 29.22/29.08  tff(decl_53064, type, fn_microfibril_15: $i > $i).
% 29.22/29.08  tff(decl_53065, type, fn_microfibril_16: $i > $i).
% 29.22/29.08  tff(decl_53066, type, fn_microfibril_17: $i > $i).
% 29.22/29.08  tff(decl_53067, type, fn_microfibril_18: $i > $i).
% 29.22/29.08  tff(decl_53068, type, fn_microfibril_19: $i > $i).
% 29.22/29.08  tff(decl_53069, type, fn_microfibril_20: $i > $i).
% 29.22/29.08  tff(decl_53070, type, fn_microfibril_21: $i > $i).
% 29.22/29.08  tff(decl_53071, type, fn_microfibril_23: $i > $i).
% 29.22/29.08  tff(decl_53072, type, fn_microfibril_22: $i > $i).
% 29.22/29.08  tff(decl_53073, type, 'Microfilament': $i).
% 29.22/29.08  tff(decl_53074, type, 'Microfilaments (or actin filaments or actin microfilaments) are the thinnest filaments of the cytoskeleton found in the cytoplasm of all eukaryotic cells.': $i).
% 29.22/29.08  tff(decl_53075, type, 'actin filament': $i).
% 29.22/29.08  tff(decl_53076, type, 'actin microfilament': $i).
% 29.22/29.08  tff(decl_53077, type, 'actin-microfilament': $i).
% 29.22/29.08  tff(decl_53078, type, microfilament: $i).
% 29.22/29.08  tff(decl_53079, type, fn_microfilament_1: $i > $i).
% 29.22/29.08  tff(decl_53080, type, fn_microfilament_2: $i > $i).
% 29.22/29.08  tff(decl_53081, type, fn_microfilament_4: $i > $i).
% 29.22/29.08  tff(decl_53082, type, fn_microfilament_6: $i > $i).
% 29.22/29.08  tff(decl_53083, type, fn_microfilament_11: $i > $i).
% 29.22/29.08  tff(decl_53084, type, fn_microfilament_12: $i > $i).
% 29.22/29.08  tff(decl_53085, type, fn_microfilament_13: $i > $i).
% 29.22/29.08  tff(decl_53086, type, fn_microfilament_14: $i > $i).
% 29.22/29.08  tff(decl_53087, type, fn_microfilament_15: $i > $i).
% 29.22/29.08  tff(decl_53088, type, fn_microfilament_16: $i > $i).
% 29.22/29.08  tff(decl_53089, type, fn_microfilament_17: $i > $i).
% 29.22/29.08  tff(decl_53090, type, fn_microfilament_18: $i > $i).
% 29.22/29.08  tff(decl_53091, type, fn_microfilament_19: $i > $i).
% 29.22/29.08  tff(decl_53092, type, fn_microfilament_20: $i > $i).
% 29.22/29.08  tff(decl_53093, type, fn_microfilament_21: $i > $i).
% 29.22/29.08  tff(decl_53094, type, fn_microfilament_22: $i > $i).
% 29.22/29.08  tff(decl_53095, type, fn_microfilament_25: $i > $i).
% 29.22/29.08  tff(decl_53096, type, fn_microfilament_26: $i > $i).
% 29.22/29.08  tff(decl_53097, type, actin_0: $i).
% 29.22/29.08  tff(decl_53098, type, fn_microfilament_10: $i > $i).
% 29.22/29.08  tff(decl_53099, type, fn_microfilament_8: $i > $i).
% 29.22/29.08  tff(decl_53100, type, fn_microfilament_7: $i > $i).
% 29.22/29.08  tff(decl_53101, type, fn_microfilament_9: $i > $i).
% 29.22/29.08  tff(decl_53102, type, 'Microfilament-Elongation': $i).
% 29.22/29.08  tff(decl_53103, type, 'The process in which the microfilaments are elongated by the enzymatic addition of actin monomers.': $i).
% 29.22/29.08  tff(decl_53104, type, 'elongation of microfilament': $i).
% 29.22/29.08  tff(decl_53105, type, 'microfilament elongation': $i).
% 29.22/29.08  tff(decl_53106, type, 'microfilament-elongation': $i).
% 29.22/29.08  tff(decl_53107, type, fn_microfilament_elongation_1: $i > $i).
% 29.22/29.08  tff(decl_53108, type, fn_microfilament_elongation_2: $i > $i).
% 29.22/29.08  tff(decl_53109, type, fn_microfilament_elongation_3: $i > $i).
% 29.22/29.08  tff(decl_53110, type, micrograph_1: $i > $o).
% 29.22/29.08  tff(decl_53111, type, 'Micrograph': $i).
% 29.22/29.08  tff(decl_53112, type, 'An image produced by a microscope.': $i).
% 29.22/29.08  tff(decl_53113, type, photomicrograph: $i).
% 29.22/29.08  tff(decl_53114, type, micrograph: $i).
% 29.22/29.08  tff(decl_53115, type, 'Micronutrient': $i).
% 29.22/29.08  tff(decl_53116, type, 'Chemicals that are required only in small amounts.': $i).
% 29.22/29.08  tff(decl_53117, type, micronutrient: $i).
% 29.22/29.08  tff(decl_53118, type, 'Microphyll': $i).
% 29.22/29.08  tff(decl_53119, type, 'A leaf that has a single, unbranched vein.': $i).
% 29.22/29.08  tff(decl_53120, type, microphyll: $i).
% 29.22/29.08  tff(decl_53121, type, 'Micropyle': $i).
% 29.22/29.08  tff(decl_53122, type, 'A small pore in the surface of an ovule, through which the pollen tube penetrates.': $i).
% 29.22/29.08  tff(decl_53123, type, micropyle: $i).
% 29.22/29.08  tff(decl_53124, type, microrna_1: $i > $o).
% 29.22/29.08  tff(decl_53125, type, 'MicroRNA': $i).
% 29.22/29.08  tff(decl_53126, type, 'A short (~22 base pair) sequence of RNA that binds to the complementary sequence of a messenger RNA transcript and suppresses translation of that part of the transcript.': $i).
% 29.22/29.08  tff(decl_53127, type, microrna: $i).
% 29.22/29.08  tff(decl_53128, type, regulatory_rna_1: $i > $o).
% 29.22/29.08  tff(decl_53129, type, microsatellite_dna_1: $i > $o).
% 29.22/29.08  tff(decl_53130, type, 'Microsatellite-DNA': $i).
% 29.22/29.08  tff(decl_53131, type, 'A type of tandemly repetitive DNA with 10-100 base pairs of repetitive DNA per site.': $i).
% 29.22/29.08  tff(decl_53132, type, 'microsatellite dna': $i).
% 29.22/29.08  tff(decl_53133, type, 'microsatellite-dna': $i).
% 29.22/29.08  tff(decl_53134, type, tandemly_repeated_dna_1: $i > $o).
% 29.22/29.08  tff(decl_53135, type, minisatellite_dna_1: $i > $o).
% 29.22/29.08  tff(decl_53136, type, regular_satellite_dna_1: $i > $o).
% 29.22/29.08  tff(decl_53137, type, short_tandem_repeat_1: $i > $o).
% 29.22/29.08  tff(decl_53138, type, fn_microsatellite_dna_1: $i > $i).
% 29.22/29.08  tff(decl_53139, type, fn_microsatellite_dna_2: $i > $i).
% 29.22/29.08  tff(decl_53140, type, fn_microsatellite_dna_3: $i > $i).
% 29.22/29.08  tff(decl_53141, type, fn_microsatellite_dna_4: $i > $i).
% 29.22/29.08  tff(decl_53142, type, fn_microsatellite_dna_5: $i > $i).
% 29.22/29.08  tff(decl_53143, type, fn_microsatellite_dna_6: $i > $i).
% 29.22/29.08  tff(decl_53144, type, fn_microsatellite_dna_7: $i > $i).
% 29.22/29.08  tff(decl_53145, type, fn_microsatellite_dna_8: $i > $i).
% 29.22/29.08  tff(decl_53146, type, fn_microsatellite_dna_9: $i > $i).
% 29.22/29.08  tff(decl_53147, type, fn_microsatellite_dna_10: $i > $i).
% 29.22/29.08  tff(decl_53148, type, fn_microsatellite_dna_11: $i > $i).
% 29.22/29.08  tff(decl_53149, type, dna_sequence_0: $i).
% 29.22/29.08  tff(decl_53150, type, nucleotide_0: $i).
% 29.22/29.08  tff(decl_53151, type, fn_tandemly_repeated_dna_2: $i > $i).
% 29.22/29.08  tff(decl_53152, type, 'Microscope': $i).
% 29.22/29.08  tff(decl_53153, type, 'A microscope is a tool for increasing the magnification of a visual image for the purpose of observation.': $i).
% 29.22/29.08  tff(decl_53154, type, microscope: $i).
% 29.22/29.08  tff(decl_53155, type, 'Microscopy': $i).
% 29.22/29.08  tff(decl_53156, type, 'Microscopy is the technical field of using microscope to view samples or objects that cannot be seen with the unaided eyes.': $i).
% 29.22/29.08  tff(decl_53157, type, microscopy: $i).
% 29.22/29.08  tff(decl_53158, type, fn_microscopy_2: $i > $i).
% 29.22/29.08  tff(decl_53159, type, fn_microscopy_4: $i > $i).
% 29.22/29.08  tff(decl_53160, type, microsporangium_1: $i > $o).
% 29.22/29.08  tff(decl_53161, type, 'Microsporangium': $i).
% 29.22/29.08  tff(decl_53162, type, 'An enclosure on a plant or fungus where microspores are produced.': $i).
% 29.22/29.08  tff(decl_53163, type, microsporangia: $i).
% 29.22/29.08  tff(decl_53164, type, microsporangium: $i).
% 29.22/29.08  tff(decl_53165, type, 'Microspore': $i).
% 29.22/29.08  tff(decl_53166, type, microspore: $i).
% 29.22/29.08  tff(decl_53167, type, 'Microtubule': $i).
% 29.22/29.08  tff(decl_53168, type, 'Microtubules are one of the components of the cytoskeleton. They are made-up of two subunits- alpha-tubulin and beta-tubulin. Microtubules serve as structural components within cells and are involved in many cellular processes including mitosis, cytokinesis, and vesicular transport. They form part of mitotic spindle': $i).
% 29.22/29.08  tff(decl_53169, type, microtubule: $i).
% 29.22/29.08  tff(decl_53170, type, fn_microtubule_1: $i > $i).
% 29.22/29.08  tff(decl_53171, type, fn_microtubule_3: $i > $i).
% 29.22/29.08  tff(decl_53172, type, fn_microtubule_5: $i > $i).
% 29.22/29.08  tff(decl_53173, type, fn_microtubule_6: $i > $i).
% 29.22/29.08  tff(decl_53174, type, fn_microtubule_8: $i > $i).
% 29.22/29.08  tff(decl_53175, type, fn_microtubule_13: $i > $i).
% 29.22/29.08  tff(decl_53176, type, fn_microtubule_14: $i > $i).
% 29.22/29.08  tff(decl_53177, type, tubulin_0: $i).
% 29.22/29.08  tff(decl_53178, type, "25.0e0": $i).
% 29.22/29.08  tff(decl_53179, type, "15.0e0": $i).
% 29.22/29.08  tff(decl_53180, type, 'Microtubule-Doublet': $i).
% 29.22/29.08  tff(decl_53181, type, 'Structure formed by two microtubules.': $i).
% 29.22/29.08  tff(decl_53182, type, 'doublet of microtubule': $i).
% 29.22/29.08  tff(decl_53183, type, 'microtubule doublet': $i).
% 29.22/29.08  tff(decl_53184, type, 'microtubule-doublet': $i).
% 29.22/29.08  tff(decl_53185, type, 'Microtubule-Elongation': $i).
% 29.22/29.08  tff(decl_53186, type, 'Microtubule-elongation is a process by which the microtuble fibers elongate. Microtubule elongation is important in vesicular transport and cell elongation during cytokinesis to provide for the formation of two daughter cells.': $i).
% 29.22/29.08  tff(decl_53187, type, 'microtubule elongation': $i).
% 29.22/29.08  tff(decl_53188, type, 'microtubule lengthening': $i).
% 29.22/29.08  tff(decl_53189, type, 'microtubule increase in length': $i).
% 29.22/29.08  tff(decl_53190, type, 'microtubule elongates': $i).
% 29.22/29.08  tff(decl_53191, type, 'elongation of microtubule': $i).
% 29.22/29.08  tff(decl_53192, type, 'microtubule-elongation': $i).
% 29.22/29.08  tff(decl_53193, type, fn_microtubule_elongation_3: $i > $i).
% 29.22/29.08  tff(decl_53194, type, 'Microtubule-Organizing-Center': $i).
% 29.22/29.08  tff(decl_53195, type, 'Eukaryotic cellular structure that produces and organizes microtubules.': $i).
% 29.22/29.08  tff(decl_53196, type, fn_microtubule_organizing_center_2: $i > $i).
% 29.22/29.08  tff(decl_53197, type, fn_microtubule_organizing_center_3: $i > $i).
% 29.22/29.08  tff(decl_53198, type, fn_microtubule_organizing_center_4: $i > $i).
% 29.22/29.08  tff(decl_53199, type, fn_microtubule_organizing_center_6: $i > $i).
% 29.22/29.08  tff(decl_53200, type, fn_microtubule_organizing_center_7: $i > $i).
% 29.22/29.08  tff(decl_53201, type, fn_microtubule_organizing_center_8: $i > $i).
% 29.22/29.08  tff(decl_53202, type, fn_microtubule_organizing_center_9: $i > $i).
% 29.22/29.08  tff(decl_53203, type, 'Microtubule-Shortening': $i).
% 29.22/29.08  tff(decl_53204, type, 'During mitosis, the process in which the spindle fibers shorten, separating the chromosomes to opposite poles of the cell.': $i).
% 29.22/29.08  tff(decl_53205, type, 'microtubule contraction': $i).
% 29.22/29.08  tff(decl_53206, type, 'microtubule depolymerisation': $i).
% 29.22/29.08  tff(decl_53207, type, 'microtubule depolymerization': $i).
% 29.22/29.08  tff(decl_53208, type, 'microtubule shortening': $i).
% 29.22/29.08  tff(decl_53209, type, 'microtubule shorten': $i).
% 29.22/29.08  tff(decl_53210, type, 'shortening of microtubule': $i).
% 29.22/29.08  tff(decl_53211, type, 'microtubule-shortening': $i).
% 29.22/29.08  tff(decl_53212, type, 'Microtubule-Triplet': $i).
% 29.22/29.08  tff(decl_53213, type, 'A group of three microtubules that anchors a cilium or flagellum into a basal body.': $i).
% 29.22/29.08  tff(decl_53214, type, 'triplet of microtubule': $i).
% 29.22/29.08  tff(decl_53215, type, 'microtubule triplet': $i).
% 29.22/29.08  tff(decl_53216, type, 'microtubule-triplet': $i).
% 29.22/29.08  tff(decl_53217, type, fn_microtubule_triplet_1: $i > $i).
% 29.22/29.08  tff(decl_53218, type, fn_microtubule_triplet_2: $i > $i).
% 29.22/29.08  tff(decl_53219, type, fn_microtubule_triplet_3: $i > $i).
% 29.22/29.08  tff(decl_53220, type, microvillus_1: $i > $o).
% 29.22/29.08  tff(decl_53221, type, 'Microvillus': $i).
% 29.22/29.08  tff(decl_53222, type, 'Thin, fingerlike extensions of the plasma membrane of epithelial cells that increase the surface are of absorptive surfaces such as the lumen of the small intestine.': $i).
% 29.22/29.08  tff(decl_53223, type, microvilli: $i).
% 29.22/29.08  tff(decl_53224, type, microvillus: $i).
% 29.22/29.08  tff(decl_53225, type, fn_microvillus_1: $i > $i).
% 29.22/29.08  tff(decl_53226, type, fn_microvillus_3: $i > $i).
% 29.22/29.08  tff(decl_53227, type, fn_microvillus_6: $i > $i).
% 29.22/29.08  tff(decl_53228, type, fn_microvillus_7: $i > $i).
% 29.22/29.08  tff(decl_53229, type, fn_microvillus_8: $i > $i).
% 29.22/29.08  tff(decl_53230, type, microfilament_0: $i).
% 29.22/29.08  tff(decl_53231, type, 'Microwaves': $i).
% 29.22/29.08  tff(decl_53232, type, 'Microwaves are the radiation with wavelenth ranging from 1 mm to 1 m. Their wavelength is shorter than that of infrared-rays, but longer than Radiowaves.': $i).
% 29.22/29.08  tff(decl_53233, type, microwave: $i).
% 29.22/29.08  tff(decl_53234, type, fn_microwaves_2: $i > $i).
% 29.22/29.08  tff(decl_53235, type, fn_microwaves_3: $i > $i).
% 29.22/29.08  tff(decl_53236, type, fn_microwaves_4: $i > $i).
% 29.22/29.08  tff(decl_53237, type, 'Midbrain': $i).
% 29.22/29.08  tff(decl_53238, type, 'A region of the vertebrate brain involved with sensory integration, motor control, sleep/wake cycles, and temperature regulation.': $i).
% 29.22/29.08  tff(decl_53239, type, mesencephalon: $i).
% 29.22/29.08  tff(decl_53240, type, midbrain: $i).
% 29.22/29.08  tff(decl_53241, type, 'Middle-Ear': $i).
% 29.22/29.08  tff(decl_53242, type, 'In vertebrates, the region of the ear between the tympanic membrane and the oval window. In mammals, the middle ear contains three bones (incus, malleus, and stapes) that are involved in sound perception.': $i).
% 29.22/29.08  tff(decl_53243, type, 'ear of middle': $i).
% 29.22/29.08  tff(decl_53244, type, 'middle ear': $i).
% 29.22/29.08  tff(decl_53245, type, 'middle-ear': $i).
% 29.22/29.08  tff(decl_53246, type, 'Middle-Lamella': $i).
% 29.22/29.08  tff(decl_53247, type, 'In plants, a thin layer of extracellular pectin that cements the cell walls of adjacent cells together.': $i).
% 29.22/29.08  tff(decl_53248, type, 'lamella of middle': $i).
% 29.22/29.08  tff(decl_53249, type, 'middle lamella': $i).
% 29.22/29.08  tff(decl_53250, type, 'middle-lamella': $i).
% 29.22/29.08  tff(decl_53251, type, 'Midgut': $i).
% 29.22/29.08  tff(decl_53252, type, 'Middle region of the alimentary canal in some animals in which most of the digestion takes place. Contains pouches called gstric cecae.': $i).
% 29.22/29.08  tff(decl_53253, type, midgut: $i).
% 29.22/29.08  tff(decl_53254, type, 'Migration': $i).
% 29.22/29.08  tff(decl_53255, type, 'Physical movement from one location to another.': $i).
% 29.22/29.08  tff(decl_53256, type, migrate: $i).
% 29.22/29.08  tff(decl_53257, type, migration: $i).
% 29.22/29.08  tff(decl_53258, type, 'Milk': $i).
% 29.22/29.08  tff(decl_53259, type, 'An  opaque  white  or  bluish-white  liquid  secreted  by  the mammary  glands  of  female mammals,  serving  for  the  nourishment  of  their  young.': $i).
% 29.22/29.08  tff(decl_53260, type, milk: $i).
% 29.22/29.08  tff(decl_53261, type, fn_milk_1: $i > $i).
% 29.22/29.08  tff(decl_53262, type, fn_milk_2: $i > $i).
% 29.22/29.08  tff(decl_53263, type, fn_milk_3: $i > $i).
% 29.22/29.08  tff(decl_53264, type, miller_urey_experiment_1: $i > $o).
% 29.22/29.08  tff(decl_53265, type, 'Miller-Urey-Experiment': $i).
% 29.22/29.08  tff(decl_53266, type, 'Experimental closed system created by Stanley Miller and Harold Urey, used to mimic the conditions present on early Earth. The Miller-Urey experiment provided evidence in support of the theory of abiotic synthesis of organic materials important to life.': $i).
% 29.22/29.08  tff(decl_53267, type, 'miller urey hypothesis': $i).
% 29.22/29.08  tff(decl_53268, type, 'miller-urey hypothesis': $i).
% 29.22/29.08  tff(decl_53269, type, 'miller urey experiment': $i).
% 29.22/29.08  tff(decl_53270, type, 'miller-urey-experiment': $i).
% 29.22/29.08  tff(decl_53271, type, fn_miller_urey_experiment_1: $i > $i).
% 29.22/29.08  tff(decl_53272, type, fn_miller_urey_experiment_2: $i > $i).
% 29.22/29.08  tff(decl_53273, type, fn_miller_urey_experiment_3: $i > $i).
% 29.22/29.08  tff(decl_53274, type, fn_miller_urey_experiment_4: $i > $i).
% 29.22/29.08  tff(decl_53275, type, fn_miller_urey_experiment_5: $i > $i).
% 29.22/29.08  tff(decl_53276, type, fn_miller_urey_experiment_6: $i > $i).
% 29.22/29.08  tff(decl_53277, type, fn_miller_urey_experiment_7: $i > $i).
% 29.22/29.08  tff(decl_53278, type, fn_miller_urey_experiment_8: $i > $i).
% 29.22/29.08  tff(decl_53279, type, fn_miller_urey_experiment_9: $i > $i).
% 29.22/29.08  tff(decl_53280, type, fn_miller_urey_experiment_10: $i > $i).
% 29.22/29.08  tff(decl_53281, type, fn_miller_urey_experiment_11: $i > $i).
% 29.22/29.08  tff(decl_53282, type, fn_miller_urey_experiment_12: $i > $i).
% 29.22/29.08  tff(decl_53283, type, fn_miller_urey_experiment_13: $i > $i).
% 29.22/29.08  tff(decl_53284, type, fn_miller_urey_experiment_14: $i > $i).
% 29.22/29.08  tff(decl_53285, type, fn_miller_urey_experiment_15: $i > $i).
% 29.22/29.08  tff(decl_53286, type, fn_miller_urey_experiment_16: $i > $i).
% 29.22/29.08  tff(decl_53287, type, fn_miller_urey_experiment_17: $i > $i).
% 29.22/29.08  tff(decl_53288, type, fn_miller_urey_experiment_18: $i > $i).
% 29.22/29.08  tff(decl_53289, type, fn_miller_urey_experiment_19: $i > $i).
% 29.22/29.08  tff(decl_53290, type, fn_miller_urey_experiment_20: $i > $i).
% 29.22/29.08  tff(decl_53291, type, fn_miller_urey_experiment_21: $i > $i).
% 29.22/29.08  tff(decl_53292, type, fn_miller_urey_experiment_22: $i > $i).
% 29.22/29.08  tff(decl_53293, type, fn_miller_urey_experiment_23: $i > $i).
% 29.22/29.08  tff(decl_53294, type, fn_miller_urey_experiment_24: $i > $i).
% 29.22/29.08  tff(decl_53295, type, fn_miller_urey_experiment_25: $i > $i).
% 29.22/29.08  tff(decl_53296, type, fn_miller_urey_experiment_26: $i > $i).
% 29.22/29.08  tff(decl_53297, type, fn_miller_urey_experiment_27: $i > $i).
% 29.22/29.08  tff(decl_53298, type, fn_miller_urey_experiment_28: $i > $i).
% 29.22/29.08  tff(decl_53299, type, fn_miller_urey_experiment_29: $i > $i).
% 29.22/29.08  tff(decl_53300, type, fn_miller_urey_experiment_30: $i > $i).
% 29.22/29.08  tff(decl_53301, type, fn_miller_urey_experiment_31: $i > $i).
% 29.22/29.08  tff(decl_53302, type, fn_miller_urey_experiment_32: $i > $i).
% 29.22/29.08  tff(decl_53303, type, fn_miller_urey_experiment_33: $i > $i).
% 29.22/29.08  tff(decl_53304, type, fn_miller_urey_experiment_34: $i > $i).
% 29.22/29.08  tff(decl_53305, type, fn_miller_urey_experiment_35: $i > $i).
% 29.22/29.08  tff(decl_53306, type, 'F1': $i).
% 29.22/29.08  tff(decl_53307, type, 'F2': $i).
% 29.22/29.08  tff(decl_53308, type, 'F3': $i).
% 29.22/29.08  tff(decl_53309, type, 'F4': $i).
% 29.22/29.08  tff(decl_53310, type, 'Millipede': $i).
% 29.22/29.08  tff(decl_53311, type, 'Member of a class of terrestrial arthropods that appear to have two pairs of walking legs per body segment.': $i).
% 29.22/29.08  tff(decl_53312, type, 'Mimicry': $i).
% 29.22/29.08  tff(decl_53313, type, 'An adaptation resulting in two species that have the same or similar appearance, in which at least one species benefits from the similarity.': $i).
% 29.22/29.08  tff(decl_53314, type, mimicry: $i).
% 29.22/29.08  tff(decl_53315, type, mimosa_pudica_1: $i > $o).
% 29.22/29.08  tff(decl_53316, type, 'Mimosa-Pudica': $i).
% 29.22/29.08  tff(decl_53317, type, 'A bushy legume which demonstrates rapid, visible leaf movement when touched. Also called Sensitive or Touch-Me-Not plant.': $i).
% 29.22/29.08  tff(decl_53318, type, 'mimosa pudica': $i).
% 29.22/29.08  tff(decl_53319, type, 'mimosa-pudica': $i).
% 29.22/29.08  tff(decl_53320, type, 'Mineral': $i).
% 29.22/29.08  tff(decl_53321, type, 'In nutrition, a compound that is required in the diet but is inorganic and cannot be synthesized biologically.': $i).
% 29.22/29.08  tff(decl_53322, type, mineral: $i).
% 29.22/29.08  tff(decl_53323, type, 'Mineralocorticoid': $i).
% 29.22/29.08  tff(decl_53324, type, 'One of a group of adrenal steroid hormones that regulate water and salt balance within the body.': $i).
% 29.22/29.08  tff(decl_53325, type, mineralocorticoid: $i).
% 29.22/29.08  tff(decl_53326, type, minimum_viable_population_1: $i > $o).
% 29.22/29.08  tff(decl_53327, type, 'Minimum-Viable-Population': $i).
% 29.22/29.08  tff(decl_53328, type, 'The smallest population size of a species that can be sustained in the wild.': $i).
% 29.22/29.08  tff(decl_53329, type, 'minimum viable population': $i).
% 29.22/29.08  tff(decl_53330, type, 'minimum-viable-population': $i).
% 29.22/29.08  tff(decl_53331, type, minipill_1: $i > $o).
% 29.22/29.08  tff(decl_53332, type, 'Minipill': $i).
% 29.22/29.08  tff(decl_53333, type, 'A form of oral contraception that contains only progestins, and no estrogen.': $i).
% 29.22/29.08  tff(decl_53334, type, minipill: $i).
% 29.22/29.08  tff(decl_53335, type, 'Minisatellite-DNA': $i).
% 29.22/29.08  tff(decl_53336, type, 'A type of tandemly repeated DNA with 100-100,000 base pairs of repetitive DNA per site.': $i).
% 29.22/29.08  tff(decl_53337, type, 'minisatellite dna': $i).
% 29.22/29.08  tff(decl_53338, type, 'minisatellite-dna': $i).
% 29.22/29.08  tff(decl_53339, type, fn_minisatellite_dna_1: $i > $i).
% 29.22/29.08  tff(decl_53340, type, fn_minisatellite_dna_2: $i > $i).
% 29.22/29.08  tff(decl_53341, type, fn_tandemly_repeated_dna_1: $i > $i).
% 29.22/29.08  tff(decl_53342, type, "100000": $i).
% 29.22/29.08  tff(decl_53343, type, 'Misfolded-Protein': $i).
% 29.22/29.08  tff(decl_53344, type, 'A misfolded form of a protein.': $i).
% 29.22/29.08  tff(decl_53345, type, 'misfolded protein': $i).
% 29.22/29.08  tff(decl_53346, type, 'misfolded-protein': $i).
% 29.22/29.08  tff(decl_53347, type, 'Mismatch-Repair': $i).
% 29.22/29.08  tff(decl_53348, type, 'A DNA repair mechanism that employs specific enzymes to detect, remove, and replace wrongly paired nucleotides.': $i).
% 29.22/29.08  tff(decl_53349, type, 'mismatch repair': $i).
% 29.22/29.08  tff(decl_53350, type, 'mismatch-repair': $i).
% 29.22/29.08  tff(decl_53351, type, nucleotide_excision_repair_1: $i > $o).
% 29.22/29.08  tff(decl_53352, type, fn_mismatch_repair_1: $i > $i).
% 29.22/29.08  tff(decl_53353, type, mismatched_nucleotide_1: $i > $o).
% 29.22/29.08  tff(decl_53354, type, fn_mismatch_repair_2: $i > $i).
% 29.22/29.08  tff(decl_53355, type, fn_mismatch_repair_3: $i > $i).
% 29.22/29.08  tff(decl_53356, type, fn_mismatch_repair_4: $i > $i).
% 29.22/29.08  tff(decl_53357, type, fn_mismatched_nucleotide_1: $i > $i).
% 29.22/29.08  tff(decl_53358, type, 'Mismatched-Nucleotide': $i).
% 29.22/29.08  tff(decl_53359, type, 'The pairing of an incorrect nucleotide to the template during synthesis of DNA or RNA.  Examples of mismatched bases are G paired with T and A paired with C.': $i).
% 29.22/29.08  tff(decl_53360, type, 'incorrectly paired nucelotide': $i).
% 29.22/29.08  tff(decl_53361, type, 'incorrectly-paired-nucelotide': $i).
% 29.22/29.08  tff(decl_53362, type, 'mismatched nucleotide': $i).
% 29.22/29.08  tff(decl_53363, type, 'mismatched-nucleotide': $i).
% 29.22/29.08  tff(decl_53364, type, misplaced_methyl_group_1: $i > $o).
% 29.22/29.08  tff(decl_53365, type, 'Misplaced-Methyl-Group': $i).
% 29.22/29.08  tff(decl_53366, type, 'Misplaced methyl groups could interefere with the development of an organism.': $i).
% 29.22/29.08  tff(decl_53367, type, 'misplaced methyl group': $i).
% 29.22/29.08  tff(decl_53368, type, 'misplaced-methyl-group': $i).
% 29.22/29.08  tff(decl_53369, type, fn_misplaced_methyl_group_1: $i > $i).
% 29.22/29.08  tff(decl_53370, type, fn_misplaced_methyl_group_2: $i > $i).
% 29.22/29.08  tff(decl_53371, type, fn_misplaced_methyl_group_3: $i > $i).
% 29.22/29.08  tff(decl_53372, type, fn_misplaced_methyl_group_4: $i > $i).
% 29.22/29.08  tff(decl_53373, type, fn_misplaced_methyl_group_5: $i > $i).
% 29.22/29.08  tff(decl_53374, type, fn_misplaced_methyl_group_6: $i > $i).
% 29.22/29.08  tff(decl_53375, type, fn_misplaced_methyl_group_7: $i > $i).
% 29.22/29.08  tff(decl_53376, type, fn_misplaced_methyl_group_8: $i > $i).
% 29.22/29.08  tff(decl_53377, type, fn_misplaced_methyl_group_9: $i > $i).
% 29.22/29.08  tff(decl_53378, type, fn_misplaced_methyl_group_10: $i > $i).
% 29.22/29.08  tff(decl_53379, type, fn_misplaced_methyl_group_11: $i > $i).
% 29.22/29.08  tff(decl_53380, type, fn_misplaced_methyl_group_12: $i > $i).
% 29.22/29.08  tff(decl_53381, type, fn_misplaced_methyl_group_13: $i > $i).
% 29.22/29.08  tff(decl_53382, type, fn_misplaced_methyl_group_14: $i > $i).
% 29.22/29.08  tff(decl_53383, type, fn_misplaced_methyl_group_15: $i > $i).
% 29.22/29.08  tff(decl_53384, type, fn_misplaced_methyl_group_16: $i > $i).
% 29.22/29.08  tff(decl_53385, type, fn_misplaced_methyl_group_17: $i > $i).
% 29.22/29.08  tff(decl_53386, type, fn_misplaced_methyl_group_18: $i > $i).
% 29.22/29.08  tff(decl_53387, type, missense_mutation_1: $i > $o).
% 29.22/29.08  tff(decl_53388, type, 'Missense-Mutation': $i).
% 29.22/29.08  tff(decl_53389, type, 'A point mutation that changes a codon so that it codes for a different amino acid.': $i).
% 29.22/29.08  tff(decl_53390, type, 'missense mutation': $i).
% 29.22/29.08  tff(decl_53391, type, 'missense-mutation': $i).
% 29.22/29.08  tff(decl_53392, type, mite_1: $i > $o).
% 29.22/29.08  tff(decl_53393, type, 'Mite': $i).
% 29.22/29.08  tff(decl_53394, type, 'One of a group of mostly microscopic arachnid arthropods of the subclass Acari.': $i).
% 29.22/29.08  tff(decl_53395, type, mite: $i).
% 29.22/29.08  tff(decl_53396, type, scorpion_1: $i > $o).
% 29.22/29.08  tff(decl_53397, type, spider_1: $i > $o).
% 29.22/29.08  tff(decl_53398, type, tick_1: $i > $o).
% 29.22/29.08  tff(decl_53399, type, 'Mitochondrial-DNA': $i).
% 29.22/29.08  tff(decl_53400, type, 'DNA in the mitochondrial of eukaryotic cells. Unlike nuclear DNA, which is inherited from both parents, mitochondrial DNA is inherited from the mother only.': $i).
% 29.22/29.08  tff(decl_53401, type, 'mitochondrial dna': $i).
% 29.22/29.08  tff(decl_53402, type, 'mitochondrial-dna': $i).
% 29.22/29.08  tff(decl_53403, type, fn_mitochondrial_dna_1: $i > $i).
% 29.22/29.08  tff(decl_53404, type, fn_mitochondrial_dna_2: $i > $i).
% 29.22/29.08  tff(decl_53405, type, fn_mitochondrial_dna_3: $i > $i).
% 29.22/29.08  tff(decl_53406, type, fn_mitochondrial_dna_4: $i > $i).
% 29.22/29.08  tff(decl_53407, type, fn_mitochondrial_dna_5: $i > $i).
% 29.22/29.08  tff(decl_53408, type, fn_mitochondrial_dna_6: $i > $i).
% 29.22/29.08  tff(decl_53409, type, fn_mitochondrial_dna_7: $i > $i).
% 29.22/29.08  tff(decl_53410, type, fn_mitochondrial_dna_8: $i > $i).
% 29.22/29.08  tff(decl_53411, type, fn_mitochondrial_dna_9: $i > $i).
% 29.22/29.08  tff(decl_53412, type, fn_mitochondrial_dna_10: $i > $i).
% 29.22/29.08  tff(decl_53413, type, fn_mitochondrial_dna_11: $i > $i).
% 29.22/29.08  tff(decl_53414, type, fn_mitochondrial_dna_12: $i > $i).
% 29.22/29.08  tff(decl_53415, type, fn_mitochondrial_dna_13: $i > $i).
% 29.22/29.08  tff(decl_53416, type, fn_mitochondrial_dna_14: $i > $i).
% 29.22/29.08  tff(decl_53417, type, fn_mitochondrial_dna_15: $i > $i).
% 29.22/29.08  tff(decl_53418, type, fn_mitochondrial_dna_16: $i > $i).
% 29.22/29.08  tff(decl_53419, type, fn_mitochondrial_dna_17: $i > $i).
% 29.22/29.08  tff(decl_53420, type, fn_mitochondrial_dna_18: $i > $i).
% 29.22/29.08  tff(decl_53421, type, fn_mitochondrial_dna_19: $i > $i).
% 29.22/29.08  tff(decl_53422, type, fn_mitochondrial_dna_20: $i > $i).
% 29.22/29.08  tff(decl_53423, type, fn_mitochondrial_dna_21: $i > $i).
% 29.22/29.08  tff(decl_53424, type, fn_mitochondrial_dna_22: $i > $i).
% 29.22/29.08  tff(decl_53425, type, fn_mitochondrial_dna_23: $i > $i).
% 29.22/29.08  tff(decl_53426, type, fn_mitochondrial_dna_24: $i > $i).
% 29.22/29.08  tff(decl_53427, type, fn_mitochondrial_dna_25: $i > $i).
% 29.22/29.08  tff(decl_53428, type, fn_mitochondrial_dna_27: $i > $i).
% 29.22/29.08  tff(decl_53429, type, fn_mitochondrial_dna_28: $i > $i).
% 29.22/29.08  tff(decl_53430, type, fn_mitochondrial_dna_31: $i > $i).
% 29.22/29.08  tff(decl_53431, type, fn_mitochondrial_dna_32: $i > $i).
% 29.22/29.08  tff(decl_53432, type, fn_mitochondrial_dna_33: $i > $i).
% 29.22/29.08  tff(decl_53433, type, fn_mitochondrial_dna_34: $i > $i).
% 29.22/29.08  tff(decl_53434, type, fn_mitochondrial_dna_35: $i > $i).
% 29.22/29.08  tff(decl_53435, type, fn_mitochondrial_dna_36: $i > $i).
% 29.22/29.08  tff(decl_53436, type, fn_mitochondrial_dna_37: $i > $i).
% 29.22/29.08  tff(decl_53437, type, fn_mitochondrial_dna_38: $i > $i).
% 29.22/29.08  tff(decl_53438, type, fn_mitochondrial_dna_39: $i > $i).
% 29.22/29.08  tff(decl_53439, type, fn_mitochondrial_dna_40: $i > $i).
% 29.22/29.08  tff(decl_53440, type, fn_mitochondrial_dna_41: $i > $i).
% 29.22/29.08  tff(decl_53441, type, fn_mitochondrial_dna_42: $i > $i).
% 29.22/29.08  tff(decl_53442, type, fn_mitochondrial_dna_43: $i > $i).
% 29.22/29.08  tff(decl_53443, type, fn_mitochondrial_dna_44: $i > $i).
% 29.22/29.08  tff(decl_53444, type, fn_mitochondrial_dna_45: $i > $i).
% 29.22/29.08  tff(decl_53445, type, fn_mitochondrial_dna_46: $i > $i).
% 29.22/29.08  tff(decl_53446, type, fn_mitochondrial_dna_47: $i > $i).
% 29.22/29.08  tff(decl_53447, type, fn_mitochondrial_dna_48: $i > $i).
% 29.22/29.08  tff(decl_53448, type, fn_mitochondrial_dna_49: $i > $i).
% 29.22/29.08  tff(decl_53449, type, fn_mitochondrial_dna_50: $i > $i).
% 29.22/29.08  tff(decl_53450, type, fn_mitochondrial_dna_51: $i > $i).
% 29.22/29.08  tff(decl_53451, type, fn_mitochondrial_dna_52: $i > $i).
% 29.22/29.08  tff(decl_53452, type, fn_mitochondrial_dna_53: $i > $i).
% 29.22/29.08  tff(decl_53453, type, fn_mitochondrial_dna_64: $i > $i).
% 29.22/29.08  tff(decl_53454, type, fn_mitochondrial_dna_65: $i > $i).
% 29.22/29.08  tff(decl_53455, type, fn_mitochondrial_dna_66: $i > $i).
% 29.22/29.08  tff(decl_53456, type, fn_mitochondrial_dna_67: $i > $i).
% 29.22/29.08  tff(decl_53457, type, fn_mitochondrial_dna_68: $i > $i).
% 29.22/29.08  tff(decl_53458, type, fn_mitochondrial_dna_69: $i > $i).
% 29.22/29.08  tff(decl_53459, type, fn_phosphodiester_bond_37: $i > $i).
% 29.22/29.08  tff(decl_53460, type, fn_phosphodiester_bond_12: $i > $i).
% 29.22/29.08  tff(decl_53461, type, fn_phosphodiester_bond_11: $i > $i).
% 29.22/29.08  tff(decl_53462, type, fn_phosphodiester_bond_7: $i > $i).
% 29.22/29.08  tff(decl_53463, type, fn_phosphodiester_bond_40: $i > $i).
% 29.22/29.08  tff(decl_53464, type, fn_phosphodiester_bond_39: $i > $i).
% 29.22/29.08  tff(decl_53465, type, fn_phosphodiester_bond_36: $i > $i).
% 29.22/29.08  tff(decl_53466, type, fn_phosphodiester_bond_32: $i > $i).
% 29.22/29.08  tff(decl_53467, type, fn_mitochondrial_dna_57: $i > $i).
% 29.22/29.08  tff(decl_53468, type, fn_mitochondrial_dna_56: $i > $i).
% 29.22/29.08  tff(decl_53469, type, fn_mitochondrial_dna_54: $i > $i).
% 29.22/29.08  tff(decl_53470, type, fn_mitochondrial_dna_55: $i > $i).
% 29.22/29.08  tff(decl_53471, type, fn_mitochondrial_dna_60: $i > $i).
% 29.22/29.08  tff(decl_53472, type, fn_mitochondrial_dna_58: $i > $i).
% 29.22/29.08  tff(decl_53473, type, fn_mitochondrial_dna_29: $i > $i).
% 29.22/29.08  tff(decl_53474, type, fn_mitochondrial_dna_63: $i > $i).
% 29.22/29.08  tff(decl_53475, type, fn_mitochondrial_dna_62: $i > $i).
% 29.22/29.08  tff(decl_53476, type, fn_mitochondrial_dna_70: $i > $i).
% 29.22/29.08  tff(decl_53477, type, fn_mitochondrial_dna_61: $i > $i).
% 29.22/29.08  tff(decl_53478, type, fn_mitochondrial_dna_30: $i > $i).
% 29.22/29.08  tff(decl_53479, type, fn_mitochondrial_dna_59: $i > $i).
% 29.22/29.08  tff(decl_53480, type, 'Mitochondrial-Electron-Transport-Chain': $i).
% 29.22/29.08  tff(decl_53481, type, 'A sequence of electron carrier molecules (membrane proteins) that shuttle electrons during the redox reactions that release energy used to make ATP. The electron transport chain assembly is present in the inner membrane of mitochondria of eukaryotes.': $i).
% 29.22/29.08  tff(decl_53482, type, 'electron transport chain in mitochondria': $i).
% 29.22/29.08  tff(decl_53483, type, 'mitochondrial electron transport chain': $i).
% 29.22/29.08  tff(decl_53484, type, 'mitochondrial-electron-transport-chain': $i).
% 29.22/29.08  tff(decl_53485, type, fn_mitochondrial_electron_transport_chain_1: $i > $i).
% 29.22/29.08  tff(decl_53486, type, fn_mitochondrial_electron_transport_chain_6: $i > $i).
% 29.22/29.08  tff(decl_53487, type, fn_mitochondrial_electron_transport_chain_12: $i > $i).
% 29.22/29.08  tff(decl_53488, type, fn_mitochondrial_electron_transport_chain_15: $i > $i).
% 29.22/29.08  tff(decl_53489, type, fn_mitochondrial_electron_transport_chain_16: $i > $i).
% 29.22/29.08  tff(decl_53490, type, fn_mitochondrial_electron_transport_chain_17: $i > $i).
% 29.22/29.08  tff(decl_53491, type, fn_mitochondrial_electron_transport_chain_14: $i > $i).
% 29.22/29.08  tff(decl_53492, type, 'Mitochondrial-Gene': $i).
% 29.22/29.08  tff(decl_53493, type, 'A gene located in the chromosome of a mitochondrion.': $i).
% 29.22/29.08  tff(decl_53494, type, 'mitochondrial gene': $i).
% 29.22/29.08  tff(decl_53495, type, 'mitochondrial-gene': $i).
% 29.22/29.08  tff(decl_53496, type, 'Mitochondrial-Matrix': $i).
% 29.22/29.08  tff(decl_53497, type, 'The mitochondrial matrix contains soluble enzymes that catalyze the oxidation of pyruvate and other small organic molecules. It also contains mitochondrial DNA and ribosomes': $i).
% 29.22/29.08  tff(decl_53498, type, 'mitochondrial matrix': $i).
% 29.22/29.08  tff(decl_53499, type, 'mitochondrial-matrix': $i).
% 29.22/29.08  tff(decl_53500, type, fn_mitochondrial_matrix_2: $i > $i).
% 29.22/29.08  tff(decl_53501, type, fn_mitochondrial_matrix_3: $i > $i).
% 29.22/29.08  tff(decl_53502, type, fn_mitochondrial_matrix_7: $i > $i).
% 29.22/29.08  tff(decl_53503, type, fn_semiautonomous_organelle_4: $i > $i).
% 29.22/29.08  tff(decl_53504, type, 'Mitochondrial-Membrane': $i).
% 29.22/29.08  tff(decl_53505, type, 'Double lipid bilayer which surrounds the mitochondrion and forms the infolds, called cristae, which function in the reactions of cellular respiration.': $i).
% 29.22/29.08  tff(decl_53506, type, 'mitochondrial membrane': $i).
% 29.22/29.08  tff(decl_53507, type, 'mitochondrial-membrane': $i).
% 29.22/29.08  tff(decl_53508, type, fn_mitochondrial_membrane_2: $i > $i).
% 29.22/29.08  tff(decl_53509, type, fn_mitochondrial_membrane_8: $i > $i).
% 29.22/29.08  tff(decl_53510, type, fn_mitochondrial_membrane_11: $i > $i).
% 29.22/29.08  tff(decl_53511, type, fn_mitochondrial_membrane_12: $i > $i).
% 29.22/29.08  tff(decl_53512, type, fn_mitochondrial_membrane_15: $i > $i).
% 29.22/29.08  tff(decl_53513, type, fn_mitochondrial_membrane_17: $i > $i).
% 29.22/29.08  tff(decl_53514, type, fn_mitochondrial_membrane_23: $i > $i).
% 29.22/29.08  tff(decl_53515, type, fn_mitochondrial_membrane_24: $i > $i).
% 29.22/29.08  tff(decl_53516, type, fn_mitochondrial_membrane_25: $i > $i).
% 29.22/29.08  tff(decl_53517, type, fn_mitochondrial_membrane_26: $i > $i).
% 29.22/29.08  tff(decl_53518, type, fn_mitochondrial_membrane_27: $i > $i).
% 29.22/29.08  tff(decl_53519, type, fn_mitochondrial_membrane_28: $i > $i).
% 29.22/29.08  tff(decl_53520, type, fn_mitochondrial_membrane_29: $i > $i).
% 29.22/29.08  tff(decl_53521, type, fn_mitochondrial_membrane_34: $i > $i).
% 29.22/29.08  tff(decl_53522, type, fn_mitochondrial_membrane_39: $i > $i).
% 29.22/29.08  tff(decl_53523, type, fn_mitochondrial_membrane_44: $i > $i).
% 29.22/29.08  tff(decl_53524, type, fn_mitochondrial_membrane_45: $i > $i).
% 29.22/29.08  tff(decl_53525, type, fn_mitochondrial_membrane_46: $i > $i).
% 29.22/29.08  tff(decl_53526, type, fn_mitochondrial_membrane_47: $i > $i).
% 29.22/29.08  tff(decl_53527, type, fn_mitochondrial_membrane_48: $i > $i).
% 29.22/29.08  tff(decl_53528, type, fn_mitochondrial_membrane_49: $i > $i).
% 29.22/29.08  tff(decl_53529, type, fn_mitochondrial_membrane_50: $i > $i).
% 29.22/29.08  tff(decl_53530, type, fn_mitochondrial_membrane_51: $i > $i).
% 29.22/29.08  tff(decl_53531, type, fn_mitochondrial_membrane_53: $i > $i).
% 29.22/29.08  tff(decl_53532, type, fn_mitochondrial_membrane_54: $i > $i).
% 29.22/29.08  tff(decl_53533, type, fn_mitochondrial_membrane_55: $i > $i).
% 29.22/29.08  tff(decl_53534, type, fn_mitochondrial_membrane_58: $i > $i).
% 29.22/29.08  tff(decl_53535, type, fn_mitochondrial_membrane_59: $i > $i).
% 29.22/29.08  tff(decl_53536, type, fn_mitochondrial_membrane_61: $i > $i).
% 29.22/29.08  tff(decl_53537, type, fn_mitochondrial_membrane_62: $i > $i).
% 29.22/29.08  tff(decl_53538, type, fn_mitochondrial_membrane_65: $i > $i).
% 29.22/29.08  tff(decl_53539, type, fn_mitochondrial_membrane_66: $i > $i).
% 29.22/29.08  tff(decl_53540, type, fn_mitochondrial_membrane_71: $i > $i).
% 29.22/29.08  tff(decl_53541, type, fn_mitochondrial_membrane_73: $i > $i).
% 29.22/29.08  tff(decl_53542, type, fn_mitochondrial_membrane_80: $i > $i).
% 29.22/29.08  tff(decl_53543, type, fn_mitochondrial_membrane_81: $i > $i).
% 29.22/29.08  tff(decl_53544, type, fn_mitochondrial_membrane_82: $i > $i).
% 29.22/29.08  tff(decl_53545, type, fn_mitochondrial_membrane_83: $i > $i).
% 29.22/29.08  tff(decl_53546, type, fn_mitochondrial_membrane_85: $i > $i).
% 29.22/29.08  tff(decl_53547, type, fn_mitochondrial_membrane_87: $i > $i).
% 29.22/29.08  tff(decl_53548, type, fn_atp_synthase_7: $i > $i).
% 29.22/29.08  tff(decl_53549, type, channel_protein_0: $i).
% 29.22/29.08  tff(decl_53550, type, fn_mitochondrial_membrane_40: $i > $i).
% 29.22/29.08  tff(decl_53551, type, fn_mitochondrial_membrane_22: $i > $i).
% 29.22/29.08  tff(decl_53552, type, fn_mitochondrial_membrane_56: $i > $i).
% 29.22/29.08  tff(decl_53553, type, fn_mitochondrial_membrane_21: $i > $i).
% 29.22/29.08  tff(decl_53554, type, fn_mitochondrial_membrane_57: $i > $i).
% 29.22/29.08  tff(decl_53555, type, fn_mitochondrial_membrane_77: $i > $i).
% 29.22/29.08  tff(decl_53556, type, fn_mitochondrial_membrane_79: $i > $i).
% 29.22/29.08  tff(decl_53557, type, fn_mitochondrial_membrane_76: $i > $i).
% 29.22/29.08  tff(decl_53558, type, fn_mitochondrial_membrane_78: $i > $i).
% 29.22/29.08  tff(decl_53559, type, 'Mitochondrial-Myopathy': $i).
% 29.22/29.08  tff(decl_53560, type, 'A disorder that causes problems with muscle growth and/or function due to problems with the muscle cells\\ mitochondria.': $i).
% 29.22/29.08  tff(decl_53561, type, 'mitochondrial myopathy': $i).
% 29.22/29.08  tff(decl_53562, type, 'mitochondrial-myopathy': $i).
% 29.22/29.08  tff(decl_53563, type, 'Mitochondrion': $i).
% 29.22/29.08  tff(decl_53564, type, 'A membrane-bound organelle found in eukaryotic cells that is the site for the citric acid cycle and oxidative phosphorylation.': $i).
% 29.22/29.08  tff(decl_53565, type, 'mitochondrion,': $i).
% 29.22/29.08  tff(decl_53566, type, mitochondria: $i).
% 29.22/29.08  tff(decl_53567, type, mitochondrion: $i).
% 29.22/29.08  tff(decl_53568, type, fn_mitochondrion_5: $i > $i).
% 29.22/29.08  tff(decl_53569, type, fn_mitochondrion_6: $i > $i).
% 29.22/29.08  tff(decl_53570, type, fn_mitochondrion_7: $i > $i).
% 29.22/29.08  tff(decl_53571, type, fn_mitochondrion_9: $i > $i).
% 29.22/29.08  tff(decl_53572, type, fn_mitochondrion_13: $i > $i).
% 29.22/29.08  tff(decl_53573, type, fn_mitochondrion_14: $i > $i).
% 29.22/29.08  tff(decl_53574, type, fn_mitochondrion_15: $i > $i).
% 29.22/29.08  tff(decl_53575, type, fn_mitochondrion_16: $i > $i).
% 29.22/29.08  tff(decl_53576, type, fn_mitochondrion_19: $i > $i).
% 29.22/29.08  tff(decl_53577, type, fn_mitochondrion_20: $i > $i).
% 29.22/29.08  tff(decl_53578, type, fn_mitochondrion_21: $i > $i).
% 29.22/29.08  tff(decl_53579, type, fn_mitochondrion_22: $i > $i).
% 29.22/29.08  tff(decl_53580, type, fn_mitochondrion_25: $i > $i).
% 29.22/29.08  tff(decl_53581, type, fn_mitochondrion_26: $i > $i).
% 29.22/29.08  tff(decl_53582, type, fn_mitochondrion_27: $i > $i).
% 29.22/29.08  tff(decl_53583, type, fn_mitochondrion_28: $i > $i).
% 29.22/29.08  tff(decl_53584, type, fn_mitochondrion_29: $i > $i).
% 29.22/29.08  tff(decl_53585, type, fn_mitochondrion_30: $i > $i).
% 29.22/29.08  tff(decl_53586, type, fn_mitochondrion_31: $i > $i).
% 29.22/29.08  tff(decl_53587, type, fn_mitochondrion_32: $i > $i).
% 29.22/29.08  tff(decl_53588, type, fn_mitochondrion_33: $i > $i).
% 29.22/29.08  tff(decl_53589, type, fn_mitochondrion_34: $i > $i).
% 29.22/29.08  tff(decl_53590, type, fn_mitochondrion_35: $i > $i).
% 29.22/29.08  tff(decl_53591, type, fn_mitochondrion_36: $i > $i).
% 29.22/29.08  tff(decl_53592, type, fn_mitochondrion_45: $i > $i).
% 29.22/29.08  tff(decl_53593, type, fn_mitochondrion_46: $i > $i).
% 29.22/29.08  tff(decl_53594, type, fn_mitochondrion_49: $i > $i).
% 29.22/29.08  tff(decl_53595, type, fn_mitochondrion_50: $i > $i).
% 29.22/29.08  tff(decl_53596, type, fn_mitochondrion_56: $i > $i).
% 29.22/29.08  tff(decl_53597, type, fn_mitochondrion_60: $i > $i).
% 29.22/29.08  tff(decl_53598, type, fn_mitochondrion_65: $i > $i).
% 29.22/29.08  tff(decl_53599, type, fn_mitochondrion_66: $i > $i).
% 29.22/29.08  tff(decl_53600, type, fn_mitochondrion_68: $i > $i).
% 29.22/29.08  tff(decl_53601, type, fn_mitochondrion_69: $i > $i).
% 29.22/29.08  tff(decl_53602, type, fn_mitochondrion_73: $i > $i).
% 29.22/29.08  tff(decl_53603, type, fn_mitochondrion_75: $i > $i).
% 29.22/29.08  tff(decl_53604, type, fn_mitochondrion_76: $i > $i).
% 29.22/29.08  tff(decl_53605, type, fn_mitochondrion_80: $i > $i).
% 29.22/29.08  tff(decl_53606, type, fn_mitochondrion_81: $i > $i).
% 29.22/29.08  tff(decl_53607, type, fn_mitochondrion_82: $i > $i).
% 29.22/29.08  tff(decl_53608, type, fn_mitochondrion_83: $i > $i).
% 29.22/29.08  tff(decl_53609, type, fn_mitochondrion_84: $i > $i).
% 29.22/29.08  tff(decl_53610, type, fn_mitochondrion_85: $i > $i).
% 29.22/29.08  tff(decl_53611, type, fn_mitochondrion_86: $i > $i).
% 29.22/29.08  tff(decl_53612, type, fn_mitochondrion_87: $i > $i).
% 29.22/29.08  tff(decl_53613, type, fn_mitochondrion_91: $i > $i).
% 29.22/29.08  tff(decl_53614, type, fn_mitochondrion_92: $i > $i).
% 29.22/29.08  tff(decl_53615, type, fn_mitochondrion_93: $i > $i).
% 29.22/29.08  tff(decl_53616, type, fn_mitochondrion_94: $i > $i).
% 29.22/29.08  tff(decl_53617, type, fn_mitochondrion_95: $i > $i).
% 29.22/29.08  tff(decl_53618, type, fn_mitochondrion_96: $i > $i).
% 29.22/29.08  tff(decl_53619, type, fn_mitochondrion_97: $i > $i).
% 29.22/29.08  tff(decl_53620, type, fn_mitochondrion_98: $i > $i).
% 29.22/29.08  tff(decl_53621, type, fn_mitochondrion_99: $i > $i).
% 29.22/29.08  tff(decl_53622, type, fn_mitochondrion_100: $i > $i).
% 29.22/29.08  tff(decl_53623, type, fn_mitochondrion_101: $i > $i).
% 29.22/29.08  tff(decl_53624, type, fn_mitochondrion_102: $i > $i).
% 29.22/29.08  tff(decl_53625, type, fn_mitochondrion_103: $i > $i).
% 29.22/29.08  tff(decl_53626, type, fn_mitochondrion_104: $i > $i).
% 29.22/29.08  tff(decl_53627, type, fn_mitochondrion_105: $i > $i).
% 29.22/29.08  tff(decl_53628, type, fn_mitochondrion_106: $i > $i).
% 29.22/29.08  tff(decl_53629, type, fn_mitochondrion_107: $i > $i).
% 29.22/29.08  tff(decl_53630, type, fn_mitochondrion_108: $i > $i).
% 29.22/29.08  tff(decl_53631, type, fn_mitochondrion_109: $i > $i).
% 29.22/29.08  tff(decl_53632, type, fn_mitochondrion_111: $i > $i).
% 29.22/29.08  tff(decl_53633, type, fn_mitochondrion_112: $i > $i).
% 29.22/29.08  tff(decl_53634, type, fn_mitochondrion_113: $i > $i).
% 29.22/29.08  tff(decl_53635, type, fn_mitochondrion_114: $i > $i).
% 29.22/29.08  tff(decl_53636, type, fn_mitochondrion_115: $i > $i).
% 29.22/29.08  tff(decl_53637, type, fn_mitochondrion_116: $i > $i).
% 29.22/29.08  tff(decl_53638, type, fn_mitochondrion_117: $i > $i).
% 29.22/29.08  tff(decl_53639, type, fn_mitochondrion_119: $i > $i).
% 29.22/29.08  tff(decl_53640, type, fn_mitochondrion_122: $i > $i).
% 29.22/29.08  tff(decl_53641, type, fn_mitochondrion_131: $i > $i).
% 29.22/29.08  tff(decl_53642, type, fn_mitochondrion_132: $i > $i).
% 29.22/29.08  tff(decl_53643, type, fn_mitochondrion_133: $i > $i).
% 29.22/29.08  tff(decl_53644, type, fn_mitochondrion_134: $i > $i).
% 29.22/29.08  tff(decl_53645, type, fn_mitochondrion_135: $i > $i).
% 29.22/29.08  tff(decl_53646, type, fn_mitochondrion_136: $i > $i).
% 29.22/29.08  tff(decl_53647, type, fn_mitochondrion_139: $i > $i).
% 29.22/29.08  tff(decl_53648, type, fn_mitochondrion_140: $i > $i).
% 29.22/29.08  tff(decl_53649, type, fn_mitochondrion_141: $i > $i).
% 29.22/29.08  tff(decl_53650, type, fn_mitochondrion_142: $i > $i).
% 29.22/29.08  tff(decl_53651, type, fn_mitochondrion_143: $i > $i).
% 29.22/29.08  tff(decl_53652, type, fn_mitochondrion_144: $i > $i).
% 29.22/29.08  tff(decl_53653, type, fn_mitochondrion_145: $i > $i).
% 29.22/29.08  tff(decl_53654, type, fn_mitochondrion_147: $i > $i).
% 29.22/29.08  tff(decl_53655, type, fn_mitochondrion_148: $i > $i).
% 29.22/29.08  tff(decl_53656, type, fn_mitochondrion_149: $i > $i).
% 29.22/29.08  tff(decl_53657, type, fn_mitochondrion_150: $i > $i).
% 29.22/29.08  tff(decl_53658, type, fn_mitochondrion_151: $i > $i).
% 29.22/29.08  tff(decl_53659, type, fn_mitochondrion_152: $i > $i).
% 29.22/29.08  tff(decl_53660, type, fn_mitochondrion_155: $i > $i).
% 29.22/29.08  tff(decl_53661, type, fn_mitochondrion_157: $i > $i).
% 29.22/29.08  tff(decl_53662, type, fn_mitochondrion_158: $i > $i).
% 29.22/29.08  tff(decl_53663, type, fn_mitochondrion_161: $i > $i).
% 29.22/29.08  tff(decl_53664, type, fn_mitochondrion_162: $i > $i).
% 29.22/29.08  tff(decl_53665, type, fn_mitochondrion_163: $i > $i).
% 29.22/29.08  tff(decl_53666, type, fn_mitochondrion_164: $i > $i).
% 29.22/29.08  tff(decl_53667, type, fn_mitochondrion_165: $i > $i).
% 29.22/29.08  tff(decl_53668, type, fn_mitochondrion_166: $i > $i).
% 29.22/29.08  tff(decl_53669, type, fn_mitochondrion_167: $i > $i).
% 29.22/29.08  tff(decl_53670, type, fn_mitochondrion_168: $i > $i).
% 29.22/29.08  tff(decl_53671, type, fn_mitochondrion_169: $i > $i).
% 29.22/29.08  tff(decl_53672, type, fn_mitochondrion_170: $i > $i).
% 29.22/29.08  tff(decl_53673, type, fn_mitochondrion_171: $i > $i).
% 29.22/29.08  tff(decl_53674, type, fn_mitochondrion_172: $i > $i).
% 29.22/29.08  tff(decl_53675, type, fn_mitochondrion_173: $i > $i).
% 29.22/29.08  tff(decl_53676, type, fn_mitochondrion_174: $i > $i).
% 29.22/29.08  tff(decl_53677, type, fn_mitochondrion_175: $i > $i).
% 29.22/29.08  tff(decl_53678, type, fn_mitochondrion_176: $i > $i).
% 29.22/29.08  tff(decl_53679, type, fn_mitochondrion_177: $i > $i).
% 29.22/29.08  tff(decl_53680, type, fn_mitochondrion_178: $i > $i).
% 29.22/29.08  tff(decl_53681, type, fn_mitochondrion_179: $i > $i).
% 29.22/29.08  tff(decl_53682, type, fn_mitochondrion_180: $i > $i).
% 29.22/29.08  tff(decl_53683, type, fn_mitochondrion_181: $i > $i).
% 29.22/29.08  tff(decl_53684, type, fn_mitochondrion_182: $i > $i).
% 29.22/29.08  tff(decl_53685, type, fn_mitochondrion_185: $i > $i).
% 29.22/29.08  tff(decl_53686, type, fn_mitochondrion_186: $i > $i).
% 29.22/29.08  tff(decl_53687, type, fn_mitochondrion_187: $i > $i).
% 29.22/29.08  tff(decl_53688, type, fn_mitochondrion_188: $i > $i).
% 29.22/29.08  tff(decl_53689, type, fn_citric_acid_cycle_24: $i > $i).
% 29.22/29.08  tff(decl_53690, type, fn_atp_synthase_10: $i > $i).
% 29.22/29.08  tff(decl_53691, type, fn_atp_synthase_9: $i > $i).
% 29.22/29.08  tff(decl_53692, type, fn_electrochemical_gradient_3: $i > $i).
% 29.22/29.08  tff(decl_53693, type, fn_electrochemical_gradient_5: $i > $i).
% 29.22/29.08  tff(decl_53694, type, fn_electrochemical_gradient_1: $i > $i).
% 29.22/29.08  tff(decl_53695, type, fn_electrochemical_gradient_4: $i > $i).
% 29.22/29.08  tff(decl_53696, type, fn_semiautonomous_organelle_9: $i > $i).
% 29.22/29.08  tff(decl_53697, type, fn_mitochondrion_183: $i > $i).
% 29.22/29.08  tff(decl_53698, type, fn_mitochondrion_184: $i > $i).
% 29.22/29.08  tff(decl_53699, type, fn_mitochondrion_129: $i > $i).
% 29.22/29.08  tff(decl_53700, type, fn_mitochondrion_130: $i > $i).
% 29.22/29.08  tff(decl_53701, type, fn_mitochondrion_125: $i > $i).
% 29.22/29.08  tff(decl_53702, type, fn_mitochondrion_126: $i > $i).
% 29.22/29.08  tff(decl_53703, type, fn_mitochondrion_124: $i > $i).
% 29.22/29.08  tff(decl_53704, type, fn_mitochondrion_123: $i > $i).
% 29.22/29.08  tff(decl_53705, type, fn_mitochondrion_127: $i > $i).
% 29.22/29.08  tff(decl_53706, type, fn_mitochondrion_128: $i > $i).
% 29.22/29.08  tff(decl_53707, type, fn_mitochondrion_43: $i > $i).
% 29.22/29.08  tff(decl_53708, type, fn_mitochondrion_42: $i > $i).
% 29.22/29.08  tff(decl_53709, type, fn_mitochondrion_40: $i > $i).
% 29.22/29.08  tff(decl_53710, type, fn_mitochondrion_41: $i > $i).
% 29.22/29.08  tff(decl_53711, type, fn_mitochondrion_44: $i > $i).
% 29.22/29.08  tff(decl_53712, type, fn_mitochondrion_48: $i > $i).
% 29.22/29.08  tff(decl_53713, type, fn_mitochondrion_47: $i > $i).
% 29.22/29.08  tff(decl_53714, type, 'Mitosis': $i).
% 29.22/29.08  tff(decl_53715, type, 'In eukaryotic cells, the process of nuclear division that results in the distribution of identical sets of chromosomes into two daughter nuclei. Mitosis can be subdivided into five stage: prophase, prometaphase, metaphase, anaphase, and telophase.': $i).
% 29.22/29.08  tff(decl_53716, type, 'undergo mitosis': $i).
% 29.22/29.08  tff(decl_53717, type, mitosis: $i).
% 29.22/29.08  tff(decl_53718, type, fn_mitosis_1: $i > $i).
% 29.22/29.08  tff(decl_53719, type, fn_mitosis_2: $i > $i).
% 29.22/29.08  tff(decl_53720, type, fn_mitosis_5: $i > $i).
% 29.22/29.08  tff(decl_53721, type, fn_mitosis_6: $i > $i).
% 29.22/29.08  tff(decl_53722, type, fn_mitosis_7: $i > $i).
% 29.22/29.08  tff(decl_53723, type, fn_mitosis_8: $i > $i).
% 29.22/29.08  tff(decl_53724, type, fn_mitosis_9: $i > $i).
% 29.22/29.08  tff(decl_53725, type, mitotic_spindle_formation_1: $i > $o).
% 29.22/29.08  tff(decl_53726, type, fn_mitosis_10: $i > $i).
% 29.22/29.08  tff(decl_53727, type, fn_mitosis_11: $i > $i).
% 29.22/29.08  tff(decl_53728, type, fn_mitosis_12: $i > $i).
% 29.22/29.08  tff(decl_53729, type, fn_mitosis_13: $i > $i).
% 29.22/29.08  tff(decl_53730, type, fn_mitosis_14: $i > $i).
% 29.22/29.08  tff(decl_53731, type, fn_mitosis_15: $i > $i).
% 29.22/29.08  tff(decl_53732, type, fn_mitosis_16: $i > $i).
% 29.22/29.08  tff(decl_53733, type, fn_mitosis_17: $i > $i).
% 29.22/29.08  tff(decl_53734, type, fn_mitosis_18: $i > $i).
% 29.22/29.08  tff(decl_53735, type, fn_mitosis_19: $i > $i).
% 29.22/29.08  tff(decl_53736, type, fn_mitosis_20: $i > $i).
% 29.22/29.08  tff(decl_53737, type, fn_mitosis_21: $i > $i).
% 29.22/29.08  tff(decl_53738, type, fn_mitosis_22: $i > $i).
% 29.22/29.08  tff(decl_53739, type, fn_mitosis_23: $i > $i).
% 29.22/29.08  tff(decl_53740, type, fn_mitosis_24: $i > $i).
% 29.22/29.08  tff(decl_53741, type, fn_mitosis_25: $i > $i).
% 29.22/29.08  tff(decl_53742, type, fn_mitosis_26: $i > $i).
% 29.22/29.08  tff(decl_53743, type, fn_mitosis_27: $i > $i).
% 29.22/29.08  tff(decl_53744, type, fn_mitosis_28: $i > $i).
% 29.22/29.08  tff(decl_53745, type, fn_mitosis_29: $i > $i).
% 29.22/29.08  tff(decl_53746, type, fn_mitosis_30: $i > $i).
% 29.22/29.08  tff(decl_53747, type, fn_mitosis_37: $i > $i).
% 29.22/29.08  tff(decl_53748, type, fn_mitosis_38: $i > $i).
% 29.22/29.08  tff(decl_53749, type, fn_mitosis_41: $i > $i).
% 29.22/29.08  tff(decl_53750, type, fn_mitosis_42: $i > $i).
% 29.22/29.08  tff(decl_53751, type, fn_mitosis_43: $i > $i).
% 29.22/29.08  tff(decl_53752, type, fn_mitosis_44: $i > $i).
% 29.22/29.08  tff(decl_53753, type, fn_mitosis_46: $i > $i).
% 29.22/29.08  tff(decl_53754, type, fn_mitosis_47: $i > $i).
% 29.22/29.08  tff(decl_53755, type, fn_mitosis_48: $i > $i).
% 29.22/29.08  tff(decl_53756, type, fn_mitosis_49: $i > $i).
% 29.22/29.08  tff(decl_53757, type, fn_mitosis_50: $i > $i).
% 29.22/29.08  tff(decl_53758, type, fn_mitosis_51: $i > $i).
% 29.22/29.08  tff(decl_53759, type, fn_mitosis_52: $i > $i).
% 29.22/29.08  tff(decl_53760, type, fn_mitosis_53: $i > $i).
% 29.22/29.08  tff(decl_53761, type, fn_telophase_10: $i > $i).
% 29.22/29.08  tff(decl_53762, type, fn_prometaphase_37: $i > $i).
% 29.22/29.08  tff(decl_53763, type, fn_prometaphase_39: $i > $i).
% 29.22/29.08  tff(decl_53764, type, fn_prometaphase_21: $i > $i).
% 29.22/29.08  tff(decl_53765, type, fn_prometaphase_41: $i > $i).
% 29.22/29.08  tff(decl_53766, type, fn_prometaphase_42: $i > $i).
% 29.22/29.08  tff(decl_53767, type, fn_prometaphase_44: $i > $i).
% 29.22/29.08  tff(decl_53768, type, fn_prometaphase_34: $i > $i).
% 29.22/29.08  tff(decl_53769, type, fn_prometaphase_35: $i > $i).
% 29.22/29.08  tff(decl_53770, type, fn_prometaphase_17: $i > $i).
% 29.22/29.08  tff(decl_53771, type, fn_prometaphase_33: $i > $i).
% 29.22/29.08  tff(decl_53772, type, fn_prometaphase_45: $i > $i).
% 29.22/29.08  tff(decl_53773, type, fn_prophase_28: $i > $i).
% 29.22/29.08  tff(decl_53774, type, fn_prophase_21: $i > $i).
% 29.22/29.08  tff(decl_53775, type, fn_prophase_30: $i > $i).
% 29.22/29.08  tff(decl_53776, type, fn_prophase_35: $i > $i).
% 29.22/29.08  tff(decl_53777, type, fn_prometaphase_36: $i > $i).
% 29.22/29.08  tff(decl_53778, type, fn_prometaphase_46: $i > $i).
% 29.22/29.08  tff(decl_53779, type, fn_prophase_47: $i > $i).
% 29.22/29.08  tff(decl_53780, type, fn_prometaphase_43: $i > $i).
% 29.22/29.08  tff(decl_53781, type, fn_prophase_49: $i > $i).
% 29.22/29.08  tff(decl_53782, type, fn_telophase_15: $i > $i).
% 29.22/29.08  tff(decl_53783, type, fn_prophase_46: $i > $i).
% 29.22/29.08  tff(decl_53784, type, fn_prometaphase_1: $i > $i).
% 29.22/29.08  tff(decl_53785, type, nucleus_0: $i).
% 29.22/29.08  tff(decl_53786, type, fn_mitosis_4: $i > $i).
% 29.22/29.08  tff(decl_53787, type, 'Mitotic-Cell-Cycle': $i).
% 29.22/29.08  tff(decl_53788, type, 'Cell cycle which contains the process of mitosis.  It results in daughter cells identical in genetic composition to the parent cells': $i).
% 29.22/29.08  tff(decl_53789, type, 'mitotic cell cycle': $i).
% 29.22/29.08  tff(decl_53790, type, 'mitotic-cell-cycle': $i).
% 29.22/29.08  tff(decl_53791, type, fn_mitotic_cell_cycle_6: $i > $i).
% 29.22/29.08  tff(decl_53792, type, fn_mitotic_cell_cycle_7: $i > $i).
% 29.22/29.08  tff(decl_53793, type, fn_mitotic_cell_cycle_8: $i > $i).
% 29.22/29.08  tff(decl_53794, type, fn_mitotic_cell_cycle_9: $i > $i).
% 29.22/29.08  tff(decl_53795, type, fn_mitotic_cell_cycle_10: $i > $i).
% 29.22/29.08  tff(decl_53796, type, fn_mitotic_cell_cycle_12: $i > $i).
% 29.22/29.08  tff(decl_53797, type, fn_mitotic_cell_cycle_13: $i > $i).
% 29.22/29.08  tff(decl_53798, type, fn_mitotic_cell_cycle_14: $i > $i).
% 29.22/29.08  tff(decl_53799, type, fn_mitotic_cell_cycle_15: $i > $i).
% 29.22/29.08  tff(decl_53800, type, fn_mitotic_cell_cycle_16: $i > $i).
% 29.22/29.08  tff(decl_53801, type, fn_mitotic_cell_cycle_17: $i > $i).
% 29.22/29.08  tff(decl_53802, type, fn_mitotic_cell_cycle_20: $i > $i).
% 29.22/29.08  tff(decl_53803, type, fn_mitotic_cell_cycle_22: $i > $i).
% 29.22/29.08  tff(decl_53804, type, fn_mitotic_cell_cycle_24: $i > $i).
% 29.22/29.08  tff(decl_53805, type, fn_mitotic_cell_cycle_29: $i > $i).
% 29.22/29.08  tff(decl_53806, type, fn_mitotic_cell_cycle_30: $i > $i).
% 29.22/29.08  tff(decl_53807, type, fn_mitotic_cell_cycle_38: $i > $i).
% 29.22/29.08  tff(decl_53808, type, fn_mitotic_cell_cycle_39: $i > $i).
% 29.22/29.08  tff(decl_53809, type, fn_mitotic_cell_cycle_40: $i > $i).
% 29.22/29.08  tff(decl_53810, type, fn_mitotic_cell_cycle_41: $i > $i).
% 29.22/29.08  tff(decl_53811, type, fn_mitotic_cell_cycle_42: $i > $i).
% 29.22/29.08  tff(decl_53812, type, fn_mitotic_cell_cycle_43: $i > $i).
% 29.22/29.08  tff(decl_53813, type, fn_mitotic_cell_cycle_44: $i > $i).
% 29.22/29.08  tff(decl_53814, type, fn_mitotic_cell_cycle_46: $i > $i).
% 29.22/29.08  tff(decl_53815, type, fn_mitotic_cell_cycle_47: $i > $i).
% 29.22/29.08  tff(decl_53816, type, fn_mitotic_cell_cycle_48: $i > $i).
% 29.22/29.08  tff(decl_53817, type, fn_mitotic_cell_cycle_49: $i > $i).
% 29.22/29.08  tff(decl_53818, type, fn_mitotic_cell_cycle_54: $i > $i).
% 29.22/29.08  tff(decl_53819, type, fn_mitotic_cell_cycle_55: $i > $i).
% 29.22/29.08  tff(decl_53820, type, fn_mitotic_cell_cycle_56: $i > $i).
% 29.22/29.08  tff(decl_53821, type, fn_mitotic_cell_cycle_57: $i > $i).
% 29.22/29.08  tff(decl_53822, type, fn_mitotic_cell_cycle_58: $i > $i).
% 29.22/29.08  tff(decl_53823, type, fn_mitotic_cell_cycle_59: $i > $i).
% 29.22/29.08  tff(decl_53824, type, fn_mitotic_cell_cycle_35: $i > $i).
% 29.22/29.08  tff(decl_53825, type, fn_mitotic_cell_cycle_34: $i > $i).
% 29.22/29.08  tff(decl_53826, type, 'Mitotic-Event': $i).
% 29.22/29.08  tff(decl_53827, type, 'Event that occurs during the process of mitosis.': $i).
% 29.22/29.08  tff(decl_53828, type, 'mitotic event': $i).
% 29.22/29.08  tff(decl_53829, type, 'mitotic-event': $i).
% 29.22/29.08  tff(decl_53830, type, 'Mitotic-Spindle': $i).
% 29.22/29.08  tff(decl_53831, type, 'The subcellular apparatus of microtubules and proteins that attach to chromatids and separate chromsomes during mitosis.': $i).
% 29.22/29.08  tff(decl_53832, type, 'spindle apparatus': $i).
% 29.22/29.08  tff(decl_53833, type, 'cellular spindle apparatus': $i).
% 29.22/29.08  tff(decl_53834, type, 'spindle fiber': $i).
% 29.22/29.08  tff(decl_53835, type, 'spindle fibre': $i).
% 29.22/29.08  tff(decl_53836, type, 'mitotic apparatus': $i).
% 29.22/29.08  tff(decl_53837, type, spindle: $i).
% 29.22/29.08  tff(decl_53838, type, 'mitotic spindle': $i).
% 29.22/29.08  tff(decl_53839, type, 'mitotic-spindle': $i).
% 29.22/29.08  tff(decl_53840, type, 'Mitotic-Spindle-Formation': $i).
% 29.22/29.08  tff(decl_53841, type, 'Formation of the mitotic spindle, consisting of microtubules, which attaches to and separates the chromosomes during mitosis.': $i).
% 29.22/29.08  tff(decl_53842, type, 'mitotic spindle formation': $i).
% 29.22/29.08  tff(decl_53843, type, 'mitotic-spindle-formation': $i).
% 29.22/29.08  tff(decl_53844, type, fn_mitotic_spindle_formation_1: $i > $i).
% 29.22/29.08  tff(decl_53845, type, fn_mitotic_spindle_formation_2: $i > $i).
% 29.22/29.08  tff(decl_53846, type, fn_mitotic_spindle_formation_3: $i > $i).
% 29.22/29.08  tff(decl_53847, type, fn_mitotic_spindle_formation_4: $i > $i).
% 29.22/29.08  tff(decl_53848, type, fn_mitotic_spindle_formation_5: $i > $i).
% 29.22/29.08  tff(decl_53849, type, fn_mitotic_spindle_formation_6: $i > $i).
% 29.22/29.08  tff(decl_53850, type, fn_mitotic_spindle_formation_7: $i > $i).
% 29.22/29.08  tff(decl_53851, type, fn_mitotic_spindle_formation_8: $i > $i).
% 29.22/29.08  tff(decl_53852, type, fn_mitotic_spindle_formation_9: $i > $i).
% 29.22/29.08  tff(decl_53853, type, fn_mitotic_spindle_formation_10: $i > $i).
% 29.22/29.08  tff(decl_53854, type, fn_mitotic_spindle_formation_11: $i > $i).
% 29.22/29.08  tff(decl_53855, type, fn_mitotic_spindle_formation_12: $i > $i).
% 29.22/29.08  tff(decl_53856, type, fn_mitotic_spindle_formation_13: $i > $i).
% 29.22/29.08  tff(decl_53857, type, 'Mitotic-Stage': $i).
% 29.22/29.08  tff(decl_53858, type, 'One of the steps of mitosis, such as anaphase.': $i).
% 29.22/29.08  tff(decl_53859, type, 'mitotic stage': $i).
% 29.22/29.08  tff(decl_53860, type, 'mitotic-stage': $i).
% 29.22/29.08  tff(decl_53861, type, 'Mix': $i).
% 29.22/29.08  tff(decl_53862, type, mix: $i).
% 29.22/29.08  tff(decl_53863, type, fn_mix_2: $i > $i).
% 29.22/29.08  tff(decl_53864, type, fn_mix_3: $i > $i).
% 29.22/29.08  tff(decl_53865, type, fn_mix_4: $i > $i).
% 29.22/29.08  tff(decl_53866, type, 'Mixed-Epithelial-Tissue': $i).
% 29.22/29.08  tff(decl_53867, type, 'Tissues or parts of organs that consist of more than one type of epithelial tissue.': $i).
% 29.22/29.08  tff(decl_53868, type, 'mixed epithelial tissue': $i).
% 29.22/29.08  tff(decl_53869, type, 'mixed-epithelial-tissue': $i).
% 29.22/29.08  tff(decl_53870, type, 'Mixed-Tissue': $i).
% 29.22/29.08  tff(decl_53871, type, 'Specialized tissues that are made up of a mixture of different tissues.': $i).
% 29.22/29.08  tff(decl_53872, type, 'mixed tissue': $i).
% 29.22/29.08  tff(decl_53873, type, 'mixed-tissue': $i).
% 29.22/29.08  tff(decl_53874, type, mixotroph_1: $i > $o).
% 29.22/29.08  tff(decl_53875, type, 'Mixotroph': $i).
% 29.22/29.08  tff(decl_53876, type, 'An organism that can function as either a heterotroph or an autotroph.': $i).
% 29.22/29.08  tff(decl_53877, type, mixotroph: $i).
% 29.22/29.08  tff(decl_53878, type, fn_mixotroph_1: $i > $i).
% 29.22/29.08  tff(decl_53879, type, fn_mixotroph_2: $i > $i).
% 29.22/29.08  tff(decl_53880, type, 'Mixture': $i).
% 29.22/29.08  tff(decl_53881, type, mixture: $i).
% 29.22/29.08  tff(decl_53882, type, 'Mobilization-Of-Fuel-Reserve': $i).
% 29.22/29.08  tff(decl_53883, type, 'The process in animals in which stored chemical energy, such as that in glycogen or fat, is utilized. This process is usually associated with the fight or flight response.': $i).
% 29.22/29.08  tff(decl_53884, type, 'mobilization of fuel reserve': $i).
% 29.22/29.08  tff(decl_53885, type, 'mobilization-of-fuel-reserve': $i).
% 29.22/29.08  tff(decl_53886, type, fn_mobilization_of_fuel_reserve_1: $i > $i).
% 29.22/29.08  tff(decl_53887, type, fn_mobilization_of_fuel_reserve_2: $i > $i).
% 29.22/29.08  tff(decl_53888, type, fn_mobilization_of_fuel_reserve_5: $i > $i).
% 29.22/29.08  tff(decl_53889, type, 'Model': $i).
% 29.22/29.08  tff(decl_53890, type, 'A representation of a theory or process.': $i).
% 29.22/29.08  tff(decl_53891, type, model: $i).
% 29.22/29.08  tff(decl_53892, type, 'Model-Organism': $i).
% 29.22/29.08  tff(decl_53893, type, 'A particular species chosen for research into broad biological principles because it is representative of a larger group and usually easy to grow in a lab.': $i).
% 29.22/29.08  tff(decl_53894, type, 'organism of model': $i).
% 29.22/29.08  tff(decl_53895, type, 'model organism': $i).
% 29.22/29.08  tff(decl_53896, type, 'model-organism': $i).
% 29.22/29.08  tff(decl_53897, type, fn_model_organism_1: $i > $i).
% 29.22/29.08  tff(decl_53898, type, fn_model_organism_2: $i > $i).
% 29.22/29.08  tff(decl_53899, type, fn_model_organism_3: $i > $i).
% 29.22/29.08  tff(decl_53900, type, fn_model_organism_4: $i > $i).
% 29.22/29.08  tff(decl_53901, type, fn_model_organism_5: $i > $i).
% 29.22/29.08  tff(decl_53902, type, fn_model_organism_7: $i > $i).
% 29.22/29.08  tff(decl_53903, type, fn_model_organism_8: $i > $i).
% 29.22/29.08  tff(decl_53904, type, fn_model_organism_9: $i > $i).
% 29.22/29.08  tff(decl_53905, type, models_of_dna_replication_1: $i > $o).
% 29.22/29.08  tff(decl_53906, type, 'Models-Of-DNA-Replication': $i).
% 29.22/29.08  tff(decl_53907, type, 'Theories of the possible ways that DNA can replicate.  There are three models of DNA replication - Conservative model, Semiconservative model and Dispersive model': $i).
% 29.22/29.08  tff(decl_53908, type, 'models of dna replication': $i).
% 29.22/29.08  tff(decl_53909, type, 'models-of-dna-replication': $i).
% 29.22/29.08  tff(decl_53910, type, 'Modified-DNA': $i).
% 29.22/29.08  tff(decl_53911, type, 'DNA that has been chemically altered, by either natural or scientific means.': $i).
% 29.22/29.08  tff(decl_53912, type, 'modified dna': $i).
% 29.22/29.08  tff(decl_53913, type, 'modified-dna': $i).
% 29.22/29.08  tff(decl_53914, type, 'Molar-Tooth': $i).
% 29.22/29.08  tff(decl_53915, type, 'Relatively short, strong tooth specialized for crushing and grinding  food.  Molars are the teeth which are found furthest back in the mouth.': $i).
% 29.22/29.08  tff(decl_53916, type, 'tooth of molar': $i).
% 29.22/29.08  tff(decl_53917, type, 'molar tooth': $i).
% 29.22/29.08  tff(decl_53918, type, 'molar-tooth': $i).
% 29.22/29.08  tff(decl_53919, type, fn_molar_tooth_1: $i > $i).
% 29.22/29.08  tff(decl_53920, type, fn_molar_tooth_2: $i > $i).
% 29.22/29.08  tff(decl_53921, type, fn_molar_tooth_3: $i > $i).
% 29.22/29.08  tff(decl_53922, type, fn_molar_tooth_4: $i > $i).
% 29.22/29.08  tff(decl_53923, type, fn_molar_tooth_5: $i > $i).
% 29.22/29.08  tff(decl_53924, type, fn_molar_tooth_6: $i > $i).
% 29.22/29.08  tff(decl_53925, type, 'Mold': $i).
% 29.22/29.08  tff(decl_53926, type, 'One of a diverse group of fungi that grow as a mass of filamentous hyphae, forming a visible mycelium. Molds reproduce by releasing haploid spores.': $i).
% 29.22/29.08  tff(decl_53927, type, 'Molecular-Assembly': $i).
% 29.22/29.08  tff(decl_53928, type, 'A group of molecules that assemble together to perform some biological function.': $i).
% 29.22/29.08  tff(decl_53929, type, supramolecular: $i).
% 29.22/29.08  tff(decl_53930, type, 'supramolecular assembly': $i).
% 29.22/29.08  tff(decl_53931, type, 'molecular assembly': $i).
% 29.22/29.08  tff(decl_53932, type, 'molecular-assembly': $i).
% 29.22/29.08  tff(decl_53933, type, molecular_biology_1: $i > $o).
% 29.22/29.08  tff(decl_53934, type, 'Molecular-Biology': $i).
% 29.22/29.08  tff(decl_53935, type, 'The study of biology at the molecular level.': $i).
% 29.22/29.08  tff(decl_53936, type, 'molecular biology': $i).
% 29.22/29.08  tff(decl_53937, type, 'molecular-biology': $i).
% 29.22/29.08  tff(decl_53938, type, molecular_biology_technique_1: $i > $o).
% 29.22/29.08  tff(decl_53939, type, 'Molecular-Biology-Technique': $i).
% 29.22/29.08  tff(decl_53940, type, 'Laboratory technique related to the study of biological molecules, such as DNA or protein.': $i).
% 29.22/29.08  tff(decl_53941, type, 'molecular biology technique': $i).
% 29.22/29.08  tff(decl_53942, type, 'molecular-biology-technique': $i).
% 29.22/29.08  tff(decl_53943, type, fn_molecular_biology_technique_1: $i > $i).
% 29.22/29.08  tff(decl_53944, type, 'Molecular-Clock': $i).
% 29.22/29.08  tff(decl_53945, type, 'A technique for estimating the length of time required for a given amount of molecular evolutionary change. Assumes that the molecules being studied mutate at a constant rate over time.': $i).
% 29.22/29.08  tff(decl_53946, type, 'molecular clock': $i).
% 29.22/29.08  tff(decl_53947, type, 'molecular-clock': $i).
% 29.22/29.08  tff(decl_53948, type, 'Molecular-Formula': $i).
% 29.22/29.08  tff(decl_53949, type, 'A type of notation that tells what and how many atoms there are in a molecule.': $i).
% 29.22/29.08  tff(decl_53950, type, 'molecular formula': $i).
% 29.22/29.08  tff(decl_53951, type, 'molecular-formula': $i).
% 29.22/29.08  tff(decl_53952, type, 'Molecular-Genetics': $i).
% 29.22/29.08  tff(decl_53953, type, 'Molecular genetics is the field of biology and genetics that studies the structure and function of genes at a molecular level.': $i).
% 29.22/29.08  tff(decl_53954, type, 'molecular genetics': $i).
% 29.22/29.08  tff(decl_53955, type, 'molecular-genetic': $i).
% 29.22/29.08  tff(decl_53956, type, 'Molecular-Motor': $i).
% 29.22/29.08  tff(decl_53957, type, 'A protein that uses energy in the form of ATP to do work.': $i).
% 29.22/29.08  tff(decl_53958, type, 'molecular machine': $i).
% 29.22/29.08  tff(decl_53959, type, 'molecular-machine': $i).
% 29.22/29.08  tff(decl_53960, type, 'molecular motor': $i).
% 29.22/29.08  tff(decl_53961, type, 'molecular-motor': $i).
% 29.22/29.08  tff(decl_53962, type, molecular_orbital_1: $i > $o).
% 29.22/29.08  tff(decl_53963, type, 'Molecular-Orbital': $i).
% 29.22/29.08  tff(decl_53964, type, 'In chemistry, a molecular orbital (or MO) is a mathematical function describing the wave-like behavior of an electron in a molecule.': $i).
% 29.22/29.08  tff(decl_53965, type, 'molecular orbital': $i).
% 29.22/29.08  tff(decl_53966, type, 'molecular-orbital': $i).
% 29.22/29.08  tff(decl_53967, type, 'Molecular-Region': $i).
% 29.22/29.08  tff(decl_53968, type, 'Region of a molecule.': $i).
% 29.22/29.08  tff(decl_53969, type, 'molecular region': $i).
% 29.22/29.08  tff(decl_53970, type, 'molecular-region': $i).
% 29.22/29.08  tff(decl_53971, type, 'Molecular-Systematics': $i).
% 29.22/29.08  tff(decl_53972, type, 'An aspect of biology that uses comparisons of nucleic acids and other molecules to infer evolutionary relationships among different taxa.': $i).
% 29.22/29.08  tff(decl_53973, type, 'molecular systematics': $i).
% 29.22/29.08  tff(decl_53974, type, 'molecular-systematic': $i).
% 29.22/29.08  tff(decl_53975, type, 'Molecule': $i).
% 29.22/29.08  tff(decl_53976, type, 'A molecule is a chemical combination of two or more atoms.': $i).
% 29.22/29.08  tff(decl_53977, type, molecule: $i).
% 29.22/29.08  tff(decl_53978, type, 'Molecule-Substance': $i).
% 29.22/29.08  tff(decl_53979, type, 'A Chemical composed of Molecules': $i).
% 29.22/29.08  tff(decl_53980, type, 'substance of molecule': $i).
% 29.22/29.08  tff(decl_53981, type, 'molecule substance': $i).
% 29.22/29.08  tff(decl_53982, type, 'molecule-substance': $i).
% 29.22/29.08  tff(decl_53983, type, 'Mollusc': $i).
% 29.22/29.08  tff(decl_53984, type, 'An animal of the phylum Mollusca, which includes snails, slugs, clams, squids, and octopuses.': $i).
% 29.22/29.08  tff(decl_53985, type, mollusk: $i).
% 29.22/29.08  tff(decl_53986, type, mollusca: $i).
% 29.22/29.08  tff(decl_53987, type, mollusc: $i).
% 29.22/29.08  tff(decl_53988, type, mollusc_homeotic_gene_1: $i > $o).
% 29.22/29.08  tff(decl_53989, type, 'Mollusc-Homeotic-Gene': $i).
% 29.22/29.08  tff(decl_53990, type, 'Homeotic gene present in molluscs.': $i).
% 29.22/29.08  tff(decl_53991, type, 'mollusc homeotic gene': $i).
% 29.22/29.08  tff(decl_53992, type, 'mollusc-homeotic-gene': $i).
% 29.22/29.08  tff(decl_53993, type, 'Molting': $i).
% 29.22/29.08  tff(decl_53994, type, 'In the ecdysozoan invertebrates, the process of shedding a chitinous exoskeleton at regular intervals. Since the rigid exoskeleton is of a fixed size, molting allows the animal to grow. Molting also occurs in reptiles, birds, and some marine mammals.': $i).
% 29.22/29.08  tff(decl_53995, type, molt: $i).
% 29.22/29.08  tff(decl_53996, type, molting: $i).
% 29.22/29.08  tff(decl_53997, type, 'Molybdenum': $i).
% 29.22/29.08  tff(decl_53998, type, 'Molybdenum is a metal atom with atomic number 42. It is represented by the symbol Mo.': $i).
% 29.22/29.08  tff(decl_53999, type, molybdenum: $i).
% 29.22/29.08  tff(decl_54000, type, 'Mo': $i).
% 29.22/29.08  tff(decl_54001, type, fn_molybdenum_3: $i > $i).
% 29.22/29.08  tff(decl_54002, type, fn_molybdenum_4: $i > $i).
% 29.22/29.08  tff(decl_54003, type, fn_molybdenum_5: $i > $i).
% 29.22/29.08  tff(decl_54004, type, fn_molybdenum_9: $i > $i).
% 29.22/29.08  tff(decl_54005, type, fn_molybdenum_10: $i > $i).
% 29.22/29.08  tff(decl_54006, type, fn_molybdenum_11: $i > $i).
% 29.22/29.08  tff(decl_54007, type, fn_molybdenum_12: $i > $i).
% 29.22/29.08  tff(decl_54008, type, "2.16": $i).
% 29.22/29.08  tff(decl_54009, type, "95.94": $i).
% 29.22/29.08  tff(decl_54010, type, fn_molybdenum_7: $i > $i).
% 29.22/29.08  tff(decl_54011, type, fn_molybdenum_8: $i > $i).
% 29.22/29.08  tff(decl_54012, type, fn_molybdenum_6: $i > $i).
% 29.22/29.08  tff(decl_54013, type, 'Moment-of-Inertia-Value': $i).
% 29.22/29.08  tff(decl_54014, type, 'the tendency of a body to resist angular acceleration': $i).
% 29.22/29.08  tff(decl_54015, type, inactiveness: $i).
% 29.22/29.08  tff(decl_54016, type, inactivity: $i).
% 29.22/29.08  tff(decl_54017, type, 'inertia moment': $i).
% 29.22/29.08  tff(decl_54018, type, 'inertia-moment': $i).
% 29.22/29.08  tff(decl_54019, type, 'moment of inertia': $i).
% 29.22/29.08  tff(decl_54020, type, 'moment-of-inertia': $i).
% 29.22/29.08  tff(decl_54021, type, inertia: $i).
% 29.22/29.08  tff(decl_54022, type, 'moment of inertia value': $i).
% 29.22/29.08  tff(decl_54023, type, 'moment-of-inertia-value': $i).
% 29.22/29.08  tff(decl_54024, type, 'Momentum-Value': $i).
% 29.22/29.08  tff(decl_54025, type, 'the product of a body\\s mass and its velocity': $i).
% 29.22/29.08  tff(decl_54026, type, momentum: $i).
% 29.22/29.08  tff(decl_54027, type, 'value of momentum': $i).
% 29.22/29.08  tff(decl_54028, type, 'momentum value': $i).
% 29.22/29.08  tff(decl_54029, type, 'momentum-value': $i).
% 29.22/29.08  tff(decl_54030, type, monera_1: $i > $o).
% 29.22/29.08  tff(decl_54031, type, 'Monera': $i).
% 29.22/29.08  tff(decl_54032, type, 'Under the outdated 5-kingdom classification system, Monera was the name for the kingdom of prokaryotic organisms.': $i).
% 29.22/29.08  tff(decl_54033, type, monera: $i).
% 29.22/29.08  tff(decl_54034, type, 'Money': $i).
% 29.22/29.08  tff(decl_54035, type, money: $i).
% 29.22/29.08  tff(decl_54036, type, fn_money_1: $i > $i).
% 29.22/29.08  tff(decl_54037, type, fn_money_2: $i > $i).
% 29.22/29.08  tff(decl_54038, type, fn_money_3: $i > $i).
% 29.22/29.08  tff(decl_54039, type, fn_money_5: $i > $i).
% 29.22/29.08  tff(decl_54040, type, sell_1: $i > $o).
% 29.22/29.08  tff(decl_54041, type, fn_money_6: $i > $i).
% 29.22/29.08  tff(decl_54042, type, fn_sell_2: $i > $i).
% 29.22/29.08  tff(decl_54043, type, 'Monkey': $i).
% 29.22/29.08  tff(decl_54044, type, 'A primate of the infraorder Simiiformes, excluding humans and other apes.': $i).
% 29.22/29.08  tff(decl_54045, type, monkey: $i).
% 29.22/29.08  tff(decl_54046, type, 'Monoatomic-Ion': $i).
% 29.22/29.08  tff(decl_54047, type, 'Ion which consists of a single atom': $i).
% 29.22/29.08  tff(decl_54048, type, 'atomic ion': $i).
% 29.22/29.08  tff(decl_54049, type, 'atomic-ion': $i).
% 29.22/29.08  tff(decl_54050, type, 'monoatomic ion': $i).
% 29.22/29.08  tff(decl_54051, type, 'monoatomic-ion': $i).
% 29.22/29.08  tff(decl_54052, type, 'Monoclonal-Antibody': $i).
% 29.22/29.08  tff(decl_54053, type, 'An antibody that is antigen-specific and produced from a single clonal lineage of cultured cells.': $i).
% 29.22/29.08  tff(decl_54054, type, 'monoclonal antibody': $i).
% 29.22/29.08  tff(decl_54055, type, 'monoclonal-antibody': $i).
% 29.22/29.08  tff(decl_54056, type, 'Monocot': $i).
% 29.22/29.08  tff(decl_54057, type, 'Member of a clade consisting of flowering plants that have one embryonic seed leaf, or cotyledon.': $i).
% 29.22/29.08  tff(decl_54058, type, monocot: $i).
% 29.22/29.08  tff(decl_54059, type, fn_monocot_1: $i > $i).
% 29.22/29.08  tff(decl_54060, type, fn_monocot_2: $i > $i).
% 29.22/29.08  tff(decl_54061, type, fn_monocot_3: $i > $i).
% 29.22/29.08  tff(decl_54062, type, fn_monocot_4: $i > $i).
% 29.22/29.08  tff(decl_54063, type, stele_1: $i > $o).
% 29.22/29.08  tff(decl_54064, type, fn_root_14: $i > $i).
% 29.22/29.08  tff(decl_54065, type, 'Monoculture': $i).
% 29.22/29.08  tff(decl_54066, type, 'The agricultural practice of farming a single crop over large areas and for several years in a row.': $i).
% 29.22/29.08  tff(decl_54067, type, monoculture: $i).
% 29.22/29.08  tff(decl_54068, type, monogamous_mating_1: $i > $o).
% 29.22/29.08  tff(decl_54069, type, 'Monogamous-Mating': $i).
% 29.22/29.08  tff(decl_54070, type, 'The practice of a single male mating with a single female.': $i).
% 29.22/29.08  tff(decl_54071, type, 'monogamous mating': $i).
% 29.22/29.08  tff(decl_54072, type, 'monogamous-mating': $i).
% 29.22/29.08  tff(decl_54073, type, polyandry_1: $i > $o).
% 29.22/29.08  tff(decl_54074, type, polygamous_mating_1: $i > $o).
% 29.22/29.08  tff(decl_54075, type, polygyny_1: $i > $o).
% 29.22/29.08  tff(decl_54076, type, promiscuous_mating_1: $i > $o).
% 29.22/29.08  tff(decl_54077, type, stickleback_fish_mating_behavior_1: $i > $o).
% 29.22/29.08  tff(decl_54078, type, 'Monoglyceride': $i).
% 29.22/29.08  tff(decl_54079, type, 'Molecule resulting from hydrolysis of fats which consists of a single glycerol bound to a single fatty acid.': $i).
% 29.22/29.08  tff(decl_54080, type, monoglyceride: $i).
% 29.22/29.08  tff(decl_54081, type, fn_monoglyceride_1: $i > $i).
% 29.22/29.08  tff(decl_54082, type, fn_monoglyceride_2: $i > $i).
% 29.22/29.08  tff(decl_54083, type, fn_monoglyceride_3: $i > $i).
% 29.22/29.08  tff(decl_54084, type, fn_monoglyceride_4: $i > $i).
% 29.22/29.08  tff(decl_54085, type, fn_monoglyceride_5: $i > $i).
% 29.22/29.08  tff(decl_54086, type, fn_monoglyceride_6: $i > $i).
% 29.22/29.08  tff(decl_54087, type, fn_monoglyceride_7: $i > $i).
% 29.22/29.08  tff(decl_54088, type, fn_monoglyceride_8: $i > $i).
% 29.22/29.08  tff(decl_54089, type, fn_monoglyceride_9: $i > $i).
% 29.22/29.08  tff(decl_54090, type, fn_monoglyceride_10: $i > $i).
% 29.22/29.08  tff(decl_54091, type, fn_monoglyceride_11: $i > $i).
% 29.22/29.08  tff(decl_54092, type, fn_monoglyceride_12: $i > $i).
% 29.22/29.08  tff(decl_54093, type, fn_monoglyceride_13: $i > $i).
% 29.22/29.08  tff(decl_54094, type, fn_monoglyceride_14: $i > $i).
% 29.22/29.08  tff(decl_54095, type, fn_monoglyceride_15: $i > $i).
% 29.22/29.08  tff(decl_54096, type, fn_monoglyceride_16: $i > $i).
% 29.22/29.08  tff(decl_54097, type, fn_monoglyceride_17: $i > $i).
% 29.22/29.08  tff(decl_54098, type, fn_monoglyceride_18: $i > $i).
% 29.22/29.08  tff(decl_54099, type, fn_monoglyceride_19: $i > $i).
% 29.22/29.08  tff(decl_54100, type, fn_monoglyceride_20: $i > $i).
% 29.22/29.08  tff(decl_54101, type, fn_monoglyceride_21: $i > $i).
% 29.22/29.08  tff(decl_54102, type, fn_monoglyceride_22: $i > $i).
% 29.22/29.08  tff(decl_54103, type, fn_monoglyceride_23: $i > $i).
% 29.22/29.08  tff(decl_54104, type, fn_monoglyceride_24: $i > $i).
% 29.22/29.08  tff(decl_54105, type, fn_monoglyceride_25: $i > $i).
% 29.22/29.08  tff(decl_54106, type, 'Monohybrid': $i).
% 29.22/29.08  tff(decl_54107, type, 'An organism that is heterozygous with respect to a single gene of interest. All the offspring from a cross between parents homozygous for different alleles are monohybrids. For example, parents of genotypes AA and aa produce a monohybrid of genotype Aa.': $i).
% 29.22/29.08  tff(decl_54108, type, monohybrid: $i).
% 29.22/29.08  tff(decl_54109, type, fn_monohybrid_1: $i > $i).
% 29.22/29.08  tff(decl_54110, type, fn_monohybrid_2: $i > $i).
% 29.22/29.08  tff(decl_54111, type, fn_monohybrid_3: $i > $i).
% 29.22/29.08  tff(decl_54112, type, 'Monomer': $i).
% 29.22/29.08  tff(decl_54113, type, 'A monomer is a small, repeated component of a much larger organic molecule known as the polymer.': $i).
% 29.22/29.08  tff(decl_54114, type, monomer: $i).
% 29.22/29.08  tff(decl_54115, type, monophyletic_1: $i > $o).
% 29.22/29.08  tff(decl_54116, type, 'Monophyletic': $i).
% 29.22/29.08  tff(decl_54117, type, 'Descriptive of a group of taxa that includes a recent common ancestor and all of its descendants. In cladistics, a monophyletic group is called a clade.': $i).
% 29.22/29.08  tff(decl_54118, type, 'Monosaccharide': $i).
% 29.22/29.08  tff(decl_54119, type, 'The monomer of a carbohydrate. Also known as a simple sugar.': $i).
% 29.22/29.08  tff(decl_54120, type, 'mono saccharide': $i).
% 29.22/29.08  tff(decl_54121, type, 'mono-saccharide': $i).
% 29.22/29.08  tff(decl_54122, type, monosaccharide: $i).
% 29.22/29.08  tff(decl_54123, type, fn_monosaccharide_2: $i > $i).
% 29.22/29.08  tff(decl_54124, type, fn_monosaccharide_11: $i > $i).
% 29.22/29.08  tff(decl_54125, type, fn_monosaccharide_14: $i > $i).
% 29.22/29.08  tff(decl_54126, type, fn_monosaccharide_15: $i > $i).
% 29.22/29.08  tff(decl_54127, type, 'Monosomic': $i).
% 29.22/29.08  tff(decl_54128, type, 'Describes a normally diploid cell that is missing one copy of a particular chromosome.': $i).
% 29.22/29.08  tff(decl_54129, type, monosomic: $i).
% 29.22/29.08  tff(decl_54130, type, 'Monotreme': $i).
% 29.22/29.08  tff(decl_54131, type, 'An egg-laying mammal, such as a platypus or echidna.': $i).
% 29.22/29.08  tff(decl_54132, type, monotreme: $i).
% 29.22/29.08  tff(decl_54133, type, morgan_1: $i > $o).
% 29.22/29.08  tff(decl_54134, type, 'Morgan': $i).
% 29.22/29.08  tff(decl_54135, type, 'Thomas Hunt Morgan, an embyologist at Columbia University, was the first to associate a specific gene with a specific chromosome.': $i).
% 29.22/29.08  tff(decl_54136, type, 'thomas hunt morgan': $i).
% 29.22/29.08  tff(decl_54137, type, 't h morgan': $i).
% 29.22/29.08  tff(decl_54138, type, morgan: $i).
% 29.22/29.08  tff(decl_54139, type, fn_morgan_1: $i > $i).
% 29.22/29.08  tff(decl_54140, type, fn_morgan_2: $i > $i).
% 29.22/29.08  tff(decl_54141, type, fn_morgan_3: $i > $i).
% 29.22/29.08  tff(decl_54142, type, fn_morgan_4: $i > $i).
% 29.22/29.08  tff(decl_54143, type, fn_morgan_5: $i > $i).
% 29.22/29.08  tff(decl_54144, type, fn_morgan_6: $i > $i).
% 29.22/29.08  tff(decl_54145, type, fn_morgan_7: $i > $i).
% 29.22/29.08  tff(decl_54146, type, fn_morgan_8: $i > $i).
% 29.22/29.08  tff(decl_54147, type, fn_morgan_9: $i > $i).
% 29.22/29.08  tff(decl_54148, type, fn_morgan_10: $i > $i).
% 29.22/29.08  tff(decl_54149, type, 'Morning-After-Pill': $i).
% 29.22/29.08  tff(decl_54150, type, 'Drugs that act both to prevent ovulation or fertilization and possibly post-fertilization implantation of a blastocyst.': $i).
% 29.22/29.08  tff(decl_54151, type, ru486: $i).
% 29.22/29.08  tff(decl_54152, type, 'morning after pill': $i).
% 29.22/29.08  tff(decl_54153, type, 'morning-after-pill': $i).
% 29.22/29.08  tff(decl_54154, type, morphine_1: $i > $o).
% 29.22/29.08  tff(decl_54155, type, 'Morphine': $i).
% 29.22/29.08  tff(decl_54156, type, 'Morphine  is an opiate which relieves pain and alters mood by weakly binding to specific receptor molecules on the surfaces of brain cells.': $i).
% 29.22/29.08  tff(decl_54157, type, morphine: $i).
% 29.22/29.08  tff(decl_54158, type, fn_morphine_4: $i > $i).
% 29.22/29.08  tff(decl_54159, type, fn_morphine_5: $i > $i).
% 29.22/29.08  tff(decl_54160, type, fn_morphine_6: $i > $i).
% 29.22/29.08  tff(decl_54161, type, fn_morphine_7: $i > $i).
% 29.22/29.08  tff(decl_54162, type, fn_morphine_8: $i > $i).
% 29.22/29.08  tff(decl_54163, type, fn_morphine_9: $i > $i).
% 29.22/29.08  tff(decl_54164, type, fn_morphine_10: $i > $i).
% 29.22/29.08  tff(decl_54165, type, fn_morphine_11: $i > $i).
% 29.22/29.08  tff(decl_54166, type, fn_morphine_12: $i > $i).
% 29.22/29.08  tff(decl_54167, type, fn_morphine_13: $i > $i).
% 29.22/29.08  tff(decl_54168, type, fn_morphine_14: $i > $i).
% 29.22/29.08  tff(decl_54169, type, fn_morphine_15: $i > $i).
% 29.22/29.08  tff(decl_54170, type, fn_morphine_16: $i > $i).
% 29.22/29.08  tff(decl_54171, type, fn_morphine_17: $i > $i).
% 29.22/29.08  tff(decl_54172, type, fn_morphine_18: $i > $i).
% 29.22/29.08  tff(decl_54173, type, fn_morphine_19: $i > $i).
% 29.22/29.08  tff(decl_54174, type, fn_morphine_20: $i > $i).
% 29.22/29.08  tff(decl_54175, type, fn_morphine_21: $i > $i).
% 29.22/29.08  tff(decl_54176, type, fn_morphine_22: $i > $i).
% 29.22/29.08  tff(decl_54177, type, fn_morphine_23: $i > $i).
% 29.22/29.08  tff(decl_54178, type, fn_morphine_24: $i > $i).
% 29.22/29.08  tff(decl_54179, type, fn_morphine_25: $i > $i).
% 29.22/29.08  tff(decl_54180, type, fn_nerve_cell_37: $i > $i).
% 29.22/29.08  tff(decl_54181, type, fn_nerve_cell_32: $i > $i).
% 29.22/29.08  tff(decl_54182, type, fn_nerve_cell_41: $i > $i).
% 29.22/29.08  tff(decl_54183, type, fn_nerve_cell_11: $i > $i).
% 29.22/29.08  tff(decl_54184, type, fn_nerve_cell_42: $i > $i).
% 29.22/29.08  tff(decl_54185, type, fn_nerve_cell_36: $i > $i).
% 29.22/29.08  tff(decl_54186, type, fn_nerve_cell_30: $i > $i).
% 29.22/29.08  tff(decl_54187, type, fn_nerve_cell_39: $i > $i).
% 29.22/29.08  tff(decl_54188, type, fn_nerve_cell_15: $i > $i).
% 29.22/29.08  tff(decl_54189, type, fn_opiate_1: $i > $i).
% 29.22/29.08  tff(decl_54190, type, fn_opiate_8: $i > $i).
% 29.22/29.08  tff(decl_54191, type, 'Morphogen': $i).
% 29.22/29.08  tff(decl_54192, type, 'A substance present in an animal embryo which occurs along a developmental axis and whase gradient influences major developmental patterns .': $i).
% 29.22/29.08  tff(decl_54193, type, morphogen: $i).
% 29.22/29.08  tff(decl_54194, type, fn_morphogen_2: $i > $i).
% 29.22/29.08  tff(decl_54195, type, 'Morphogenesis': $i).
% 29.22/29.08  tff(decl_54196, type, 'The process of developing a body\\s shape.': $i).
% 29.22/29.08  tff(decl_54197, type, 'creation of form': $i).
% 29.22/29.08  tff(decl_54198, type, morphogenesis: $i).
% 29.22/29.08  tff(decl_54199, type, fn_morphogenesis_2: $i > $i).
% 29.22/29.08  tff(decl_54200, type, fn_morphogenesis_3: $i > $i).
% 29.22/29.08  tff(decl_54201, type, fn_morphogenesis_5: $i > $i).
% 29.22/29.08  tff(decl_54202, type, fn_morphogenesis_6: $i > $i).
% 29.22/29.08  tff(decl_54203, type, fn_morphogenesis_7: $i > $i).
% 29.22/29.08  tff(decl_54204, type, fn_morphogenesis_8: $i > $i).
% 29.22/29.08  tff(decl_54205, type, fn_morphogenesis_9: $i > $i).
% 29.22/29.08  tff(decl_54206, type, morphogenesis_in_animal_1: $i > $o).
% 29.22/29.08  tff(decl_54207, type, 'Morphogenesis-In-Animal': $i).
% 29.22/29.08  tff(decl_54208, type, 'Morphogenesis is the biological process that causes an animal to develop its shape. It is one of three fundamental aspects of developmental biology along with the control of cell growth and cellular differentiation.': $i).
% 29.22/29.08  tff(decl_54209, type, 'morphogenesis in animal': $i).
% 29.22/29.08  tff(decl_54210, type, 'morphogenesis-in-animal': $i).
% 29.22/29.08  tff(decl_54211, type, fn_morphogenesis_in_animal_1: $i > $i).
% 29.22/29.08  tff(decl_54212, type, tissue_movement_1: $i > $o).
% 29.22/29.08  tff(decl_54213, type, fn_morphogenesis_in_animal_2: $i > $i).
% 29.22/29.08  tff(decl_54214, type, morphogenesis_in_plant_1: $i > $o).
% 29.22/29.08  tff(decl_54215, type, 'Morphogenesis-in-Plant': $i).
% 29.22/29.08  tff(decl_54216, type, 'Morphogenesis is the biological process that causes a plant to develop its shape. It is one of three fundamental aspects of developmental biology along with the control of cell growth and cellular differentiation.': $i).
% 29.22/29.08  tff(decl_54217, type, 'morphogenesis in plant': $i).
% 29.22/29.08  tff(decl_54218, type, 'morphogenesis-in-plant': $i).
% 29.22/29.08  tff(decl_54219, type, 'Morphogenesis-Of-Human-Feet': $i).
% 29.22/29.08  tff(decl_54220, type, 'Morphogenesis of feet is the biological process that causes development of feet in human.': $i).
% 29.22/29.08  tff(decl_54221, type, 'morphogenesis of human foot': $i).
% 29.22/29.08  tff(decl_54222, type, 'morphogenesis-of-human-foot': $i).
% 29.22/29.08  tff(decl_54223, type, 'morphogenesis-of-human-feet': $i).
% 29.22/29.08  tff(decl_54224, type, 'Morphogenesis-Of-Human-Hand': $i).
% 29.22/29.08  tff(decl_54225, type, 'The biological process that causes development of hands in humans.': $i).
% 29.22/29.08  tff(decl_54226, type, 'morphogenesis of human hand': $i).
% 29.22/29.08  tff(decl_54227, type, 'morphogenesis-of-human-hand': $i).
% 29.22/29.08  tff(decl_54228, type, 'Morphogenetic-Movement': $i).
% 29.22/29.08  tff(decl_54229, type, 'Movements of cells or of groups of cells or tissues in the course of development is called as morphogenetic movement.': $i).
% 29.22/29.08  tff(decl_54230, type, 'morphogenetic movement': $i).
% 29.22/29.08  tff(decl_54231, type, 'morphogenetic-movement': $i).
% 29.22/29.08  tff(decl_54232, type, fn_morphogenetic_movement_1: $i > $i).
% 29.22/29.08  tff(decl_54233, type, fn_morphogenetic_movement_2: $i > $i).
% 29.22/29.08  tff(decl_54234, type, 'Morphological-Species-Concept': $i).
% 29.22/29.08  tff(decl_54235, type, 'A definition of species based on aspects of anatomy.': $i).
% 29.22/29.08  tff(decl_54236, type, 'morphological species concept': $i).
% 29.22/29.08  tff(decl_54237, type, 'morphological-species-concept': $i).
% 29.22/29.08  tff(decl_54238, type, 'Morphology': $i).
% 29.22/29.08  tff(decl_54239, type, 'The external form of an organism.': $i).
% 29.22/29.08  tff(decl_54240, type, morphology: $i).
% 29.22/29.08  tff(decl_54241, type, 'Mosquito': $i).
% 29.22/29.08  tff(decl_54242, type, 'Small flies of the family Culicidae.  Many feed on the blood of humans and other vertebrates and are vectors for diseases such as malaria.': $i).
% 29.22/29.08  tff(decl_54243, type, mosquito: $i).
% 29.22/29.08  tff(decl_54244, type, fn_mosquito_1: $i > $i).
% 29.22/29.08  tff(decl_54245, type, moss_1: $i > $o).
% 29.22/29.08  tff(decl_54246, type, 'Moss': $i).
% 29.22/29.08  tff(decl_54247, type, 'Member of the division Bryophyta, a group of small, herbaceous nonvascular plants.': $i).
% 29.22/29.08  tff(decl_54248, type, bryophyta: $i).
% 29.22/29.08  tff(decl_54249, type, moss: $i).
% 29.22/29.08  tff(decl_54250, type, 'Moth': $i).
% 29.22/29.08  tff(decl_54251, type, 'Member of the insect order Lepidoptera, which also includes butterflies.': $i).
% 29.22/29.08  tff(decl_54252, type, moth: $i).
% 29.22/29.08  tff(decl_54253, type, 'Motile-Cilium': $i).
% 29.22/29.08  tff(decl_54254, type, 'In unicellular eukaryotes, motile cilium functions in locomotion, to move the cell. In multicellular eukaryotes, motile cilium also moves materials along a passageway, such as in the throat or fallopian tube of mammals.': $i).
% 29.22/29.08  tff(decl_54255, type, 'motile cilia': $i).
% 29.22/29.08  tff(decl_54256, type, 'cilium of motile': $i).
% 29.22/29.08  tff(decl_54257, type, 'motile cilium': $i).
% 29.22/29.08  tff(decl_54258, type, 'motile-cilium': $i).
% 29.22/29.08  tff(decl_54259, type, fn_motile_cilium_3: $i > $i).
% 29.22/29.08  tff(decl_54260, type, fn_motile_cilium_4: $i > $i).
% 29.22/29.08  tff(decl_54261, type, fn_motile_cilium_6: $i > $i).
% 29.22/29.08  tff(decl_54262, type, fn_motile_cilium_9: $i > $i).
% 29.22/29.08  tff(decl_54263, type, fn_motile_cilium_12: $i > $i).
% 29.22/29.08  tff(decl_54264, type, fn_motile_cilium_20: $i > $i).
% 29.22/29.08  tff(decl_54265, type, fn_motile_cilium_11: $i > $i).
% 29.22/29.08  tff(decl_54266, type, fn_cilium_3: $i > $i).
% 29.22/29.08  tff(decl_54267, type, 'Motor-Neuron': $i).
% 29.22/29.08  tff(decl_54268, type, 'A neruon whose soma is located within the central nervous system; motor neurons transmit signals from the central nervous system to a muscle or gland cell.': $i).
% 29.22/29.08  tff(decl_54269, type, 'neuron of motor': $i).
% 29.22/29.08  tff(decl_54270, type, 'motor neuron': $i).
% 29.22/29.08  tff(decl_54271, type, 'motor-neuron': $i).
% 29.22/29.08  tff(decl_54272, type, fn_motor_neuron_1: $i > $i).
% 29.22/29.08  tff(decl_54273, type, fn_motor_neuron_2: $i > $i).
% 29.22/29.08  tff(decl_54274, type, fn_motor_neuron_3: $i > $i).
% 29.22/29.08  tff(decl_54275, type, 'Motor-Protein': $i).
% 29.22/29.08  tff(decl_54276, type, 'Motor proteins are a class of molecular motors that are able to move along the surface of a suitable substrate. They are powered by the hydrolysis of ATP and convert chemical energy into mechanical work.': $i).
% 29.22/29.08  tff(decl_54277, type, 'protein of motor': $i).
% 29.22/29.08  tff(decl_54278, type, 'motor protein': $i).
% 29.22/29.08  tff(decl_54279, type, 'motor-protein': $i).
% 29.22/29.08  tff(decl_54280, type, fn_motor_protein_4: $i > $i).
% 29.22/29.08  tff(decl_54281, type, fn_motor_protein_5: $i > $i).
% 29.22/29.08  tff(decl_54282, type, fn_motor_protein_7: $i > $i).
% 29.22/29.08  tff(decl_54283, type, fn_motor_protein_15: $i > $i).
% 29.22/29.08  tff(decl_54284, type, 'Motor-System': $i).
% 29.22/29.08  tff(decl_54285, type, 'A branch of the peripheral nervous system that consists of motor neurons that respond to external stimuli by sending signals to skeletal muscles.': $i).
% 29.22/29.08  tff(decl_54286, type, 'system of motor': $i).
% 29.22/29.08  tff(decl_54287, type, 'motor system': $i).
% 29.22/29.08  tff(decl_54288, type, 'motor-system': $i).
% 29.22/29.08  tff(decl_54289, type, motor_unit_1: $i > $o).
% 29.22/29.08  tff(decl_54290, type, 'Motor-Unit': $i).
% 29.22/29.08  tff(decl_54291, type, 'An individual motor neuron and the skeletal muscles innervated by its axon.': $i).
% 29.22/29.08  tff(decl_54292, type, 'unit of motor': $i).
% 29.22/29.08  tff(decl_54293, type, 'motor unit': $i).
% 29.22/29.08  tff(decl_54294, type, 'motor-unit': $i).
% 29.22/29.08  tff(decl_54295, type, mountain_1: $i > $o).
% 29.22/29.08  tff(decl_54296, type, 'Mountain': $i).
% 29.22/29.08  tff(decl_54297, type, 'A landform that rises above the surrounding landscape, usually in the form of a peak. Mountains are generally steeper than hills and are formed by plate tectonics.': $i).
% 29.22/29.08  tff(decl_54298, type, mountain: $i).
% 29.22/29.08  tff(decl_54299, type, mouse_1: $i > $o).
% 29.22/29.08  tff(decl_54300, type, 'Mouse': $i).
% 29.22/29.08  tff(decl_54301, type, 'Common name for a small mammal member of the class rodentia, characterized by elongated front teeth adapted for gnawing and a long, hairless tail.': $i).
% 29.22/29.08  tff(decl_54302, type, mouse: $i).
% 29.22/29.08  tff(decl_54303, type, mouse_developmental_genetics_1: $i > $o).
% 29.22/29.08  tff(decl_54304, type, 'Mouse-Developmental-Genetics': $i).
% 29.22/29.08  tff(decl_54305, type, 'Developmental genetics of mouse studies the effect that genes have in a phenotype, given normal or abnormal epigenetic parameters.': $i).
% 29.22/29.08  tff(decl_54306, type, 'mouse developmental genetics': $i).
% 29.22/29.08  tff(decl_54307, type, 'mouse-developmental-genetic': $i).
% 29.22/29.08  tff(decl_54308, type, zebrafish_developmental_genetics_1: $i > $o).
% 29.22/29.08  tff(decl_54309, type, mouse_limb_development_1: $i > $o).
% 29.22/29.08  tff(decl_54310, type, 'Mouse-Limb-Development': $i).
% 29.22/29.08  tff(decl_54311, type, 'The processes which direct the formation of the limbs during the embryonic development of a mouse.': $i).
% 29.22/29.08  tff(decl_54312, type, 'mouse limb development': $i).
% 29.22/29.08  tff(decl_54313, type, 'mouse-limb-development': $i).
% 29.22/29.08  tff(decl_54314, type, fn_mouse_limb_development_1: $i > $i).
% 29.22/29.08  tff(decl_54315, type, fn_mouse_limb_development_2: $i > $i).
% 29.22/29.08  tff(decl_54316, type, fn_mouse_limb_development_3: $i > $i).
% 29.22/29.08  tff(decl_54317, type, fn_mouse_limb_development_4: $i > $i).
% 29.22/29.08  tff(decl_54318, type, fn_mouse_limb_development_5: $i > $i).
% 29.22/29.08  tff(decl_54319, type, fn_mouse_limb_development_6: $i > $i).
% 29.22/29.08  tff(decl_54320, type, fn_mouse_limb_development_7: $i > $i).
% 29.22/29.08  tff(decl_54321, type, fn_mouse_limb_development_8: $i > $i).
% 29.22/29.08  tff(decl_54322, type, fn_mouse_limb_development_9: $i > $i).
% 29.22/29.08  tff(decl_54323, type, fn_mouse_limb_development_10: $i > $i).
% 29.22/29.08  tff(decl_54324, type, fn_mouse_limb_development_11: $i > $i).
% 29.22/29.08  tff(decl_54325, type, fn_mouse_limb_development_12: $i > $i).
% 29.22/29.08  tff(decl_54326, type, fn_mouse_limb_development_13: $i > $i).
% 29.22/29.08  tff(decl_54327, type, fn_mouse_limb_development_14: $i > $i).
% 29.22/29.08  tff(decl_54328, type, fn_mouse_limb_development_15: $i > $i).
% 29.22/29.08  tff(decl_54329, type, fn_mouse_limb_development_16: $i > $i).
% 29.22/29.08  tff(decl_54330, type, fn_mouse_limb_development_17: $i > $i).
% 29.22/29.08  tff(decl_54331, type, fn_mouse_limb_development_18: $i > $i).
% 29.22/29.08  tff(decl_54332, type, fn_mouse_limb_development_19: $i > $i).
% 29.22/29.08  tff(decl_54333, type, fn_mouse_limb_development_20: $i > $i).
% 29.22/29.08  tff(decl_54334, type, fn_mouse_limb_development_21: $i > $i).
% 29.22/29.08  tff(decl_54335, type, fn_mouse_limb_development_22: $i > $i).
% 29.22/29.08  tff(decl_54336, type, fn_mouse_limb_development_23: $i > $i).
% 29.22/29.08  tff(decl_54337, type, fn_mouse_limb_development_24: $i > $i).
% 29.22/29.08  tff(decl_54338, type, fn_mouse_limb_development_25: $i > $i).
% 29.22/29.08  tff(decl_54339, type, fn_mouse_limb_development_26: $i > $i).
% 29.22/29.08  tff(decl_54340, type, fn_mouse_limb_development_27: $i > $i).
% 29.22/29.08  tff(decl_54341, type, fn_mouse_limb_development_28: $i > $i).
% 29.22/29.08  tff(decl_54342, type, fn_mouse_limb_development_31: $i > $i).
% 29.22/29.08  tff(decl_54343, type, fn_mouse_limb_development_30: $i > $i).
% 29.22/29.08  tff(decl_54344, type, fn_mouse_limb_development_29: $i > $i).
% 29.22/29.08  tff(decl_54345, type, 'Mouth': $i).
% 29.22/29.08  tff(decl_54346, type, 'The mouth is the part of the alimentary canal in an animal that receives food and produces saliva.': $i).
% 29.22/29.08  tff(decl_54347, type, mouth: $i).
% 29.22/29.08  tff(decl_54348, type, fn_mouth_3: $i > $i).
% 29.22/29.08  tff(decl_54349, type, 'Move': $i).
% 29.22/29.08  tff(decl_54350, type, displace: $i).
% 29.22/29.08  tff(decl_54351, type, movement: $i).
% 29.22/29.08  tff(decl_54352, type, drive: $i).
% 29.22/29.08  tff(decl_54353, type, accelerate: $i).
% 29.22/29.08  tff(decl_54354, type, roll: $i).
% 29.22/29.08  tff(decl_54355, type, 'Move-Apart': $i).
% 29.22/29.08  tff(decl_54356, type, disunite: $i).
% 29.22/29.08  tff(decl_54357, type, 'cause to move apart': $i).
% 29.22/29.08  tff(decl_54358, type, 'move apart': $i).
% 29.22/29.08  tff(decl_54359, type, 'move-apart': $i).
% 29.22/29.08  tff(decl_54360, type, 'Move-Into': $i).
% 29.22/29.08  tff(decl_54361, type, 'move-into': $i).
% 29.22/29.08  tff(decl_54362, type, 'Move-Out-Of': $i).
% 29.22/29.08  tff(decl_54363, type, 'move out of': $i).
% 29.22/29.08  tff(decl_54364, type, 'move-out-of': $i).
% 29.22/29.08  tff(decl_54365, type, 'Move-Through': $i).
% 29.22/29.08  tff(decl_54366, type, 'travel along': $i).
% 29.22/29.08  tff(decl_54367, type, travel_along: $i).
% 29.22/29.08  tff(decl_54368, type, 'move through': $i).
% 29.22/29.08  tff(decl_54369, type, 'move-through': $i).
% 29.22/29.08  tff(decl_54370, type, 'Move-Together': $i).
% 29.22/29.08  tff(decl_54371, type, 'get together': $i).
% 29.22/29.08  tff(decl_54372, type, get_together: $i).
% 29.22/29.08  tff(decl_54373, type, 'cause to move together': $i).
% 29.22/29.08  tff(decl_54374, type, 'bring together': $i).
% 29.22/29.08  tff(decl_54375, type, 'move together': $i).
% 29.22/29.08  tff(decl_54376, type, 'move-together': $i).
% 29.22/29.08  tff(decl_54377, type, movement_corridor_1: $i > $o).
% 29.22/29.08  tff(decl_54378, type, 'Movement-Corridor': $i).
% 29.22/29.08  tff(decl_54379, type, 'Also called a habitat corridor, a movement corridor is a strip habitable space that connects larger, otherwise disjointed habitable areas.': $i).
% 29.22/29.08  tff(decl_54380, type, 'corridor of movement': $i).
% 29.22/29.08  tff(decl_54381, type, 'movement corridor': $i).
% 29.22/29.08  tff(decl_54382, type, 'movement-corridor': $i).
% 29.22/29.08  tff(decl_54383, type, movement_of_endocrine_hormone_1: $i > $o).
% 29.22/29.08  tff(decl_54384, type, 'Movement-Of-Endocrine-Hormone': $i).
% 29.22/29.08  tff(decl_54385, type, 'The circulation of a hormone through the blood vascular system, from the organ that secreted it to the target cells or organ.': $i).
% 29.22/29.08  tff(decl_54386, type, 'movement of endocrine hormone': $i).
% 29.22/29.08  tff(decl_54387, type, 'movement-of-endocrine-hormone': $i).
% 29.22/29.08  tff(decl_54388, type, fn_movement_of_endocrine_hormone_1: $i > $i).
% 29.22/29.08  tff(decl_54389, type, fn_movement_of_endocrine_hormone_2: $i > $i).
% 29.22/29.08  tff(decl_54390, type, fn_movement_of_endocrine_hormone_3: $i > $i).
% 29.22/29.08  tff(decl_54391, type, fn_movement_of_endocrine_hormone_4: $i > $i).
% 29.22/29.08  tff(decl_54392, type, 'Movement-Of-Endomembranous-System-Membrane': $i).
% 29.22/29.08  tff(decl_54393, type, 'The act of movement of cellular membrane from one region to another.': $i).
% 29.22/29.08  tff(decl_54394, type, 'movement of cellular membrane': $i).
% 29.22/29.08  tff(decl_54395, type, 'movement-of-cellular-membrane': $i).
% 29.22/29.08  tff(decl_54396, type, 'movement of endomembranous system membrane': $i).
% 29.22/29.08  tff(decl_54397, type, 'movement-of-endomembranous-system-membrane': $i).
% 29.22/29.08  tff(decl_54398, type, fn_movement_of_endomembranous_system_membrane_7: $i > $i).
% 29.22/29.08  tff(decl_54399, type, fn_movement_of_endomembranous_system_membrane_12: $i > $i).
% 29.22/29.08  tff(decl_54400, type, fn_movement_of_endomembranous_system_membrane_17: $i > $i).
% 29.22/29.08  tff(decl_54401, type, fn_movement_of_endomembranous_system_membrane_18: $i > $i).
% 29.22/29.08  tff(decl_54402, type, fn_movement_of_endomembranous_system_membrane_19: $i > $i).
% 29.22/29.08  tff(decl_54403, type, movement_of_hydrated_molecule_across_biomembrane_1: $i > $o).
% 29.22/29.08  tff(decl_54404, type, 'Movement-Of-Hydrated-Molecule-Across-Biomembrane': $i).
% 29.22/29.08  tff(decl_54405, type, 'The process of moving of a hydrated molecule across a biomembrane.': $i).
% 29.22/29.08  tff(decl_54406, type, 'movement of hydrated molecule across biomembrane': $i).
% 29.22/29.08  tff(decl_54407, type, 'movement-of-hydrated-molecule-across-biomembrane': $i).
% 29.22/29.08  tff(decl_54408, type, fn_movement_of_hydrated_molecule_across_biomembrane_1: $i > $i).
% 29.22/29.08  tff(decl_54409, type, fn_movement_of_hydrated_molecule_across_biomembrane_2: $i > $i).
% 29.22/29.08  tff(decl_54410, type, fn_movement_of_hydrated_molecule_across_biomembrane_3: $i > $i).
% 29.22/29.08  tff(decl_54411, type, fn_movement_of_hydrated_molecule_across_biomembrane_4: $i > $i).
% 29.22/29.08  tff(decl_54412, type, fn_movement_of_hydrated_molecule_across_biomembrane_5: $i > $i).
% 29.22/29.08  tff(decl_54413, type, fn_movement_of_hydrated_molecule_across_biomembrane_6: $i > $i).
% 29.22/29.08  tff(decl_54414, type, fn_movement_of_hydrated_molecule_across_biomembrane_7: $i > $i).
% 29.22/29.08  tff(decl_54415, type, fn_movement_of_hydrated_molecule_across_biomembrane_8: $i > $i).
% 29.22/29.08  tff(decl_54416, type, fn_movement_of_hydrated_molecule_across_biomembrane_9: $i > $i).
% 29.22/29.08  tff(decl_54417, type, fn_movement_of_hydrated_molecule_across_biomembrane_14: $i > $i).
% 29.22/29.08  tff(decl_54418, type, fn_movement_of_hydrated_molecule_across_biomembrane_15: $i > $i).
% 29.22/29.08  tff(decl_54419, type, fn_movement_of_hydrated_molecule_across_biomembrane_16: $i > $i).
% 29.22/29.08  tff(decl_54420, type, fn_movement_of_hydrated_molecule_across_biomembrane_17: $i > $i).
% 29.22/29.08  tff(decl_54421, type, fn_movement_of_hydrated_molecule_across_biomembrane_18: $i > $i).
% 29.22/29.08  tff(decl_54422, type, fn_movement_of_hydrated_molecule_across_biomembrane_19: $i > $i).
% 29.22/29.08  tff(decl_54423, type, fn_movement_of_hydrated_molecule_across_biomembrane_20: $i > $i).
% 29.22/29.08  tff(decl_54424, type, fn_movement_of_hydrated_molecule_across_biomembrane_21: $i > $i).
% 29.22/29.08  tff(decl_54425, type, fn_movement_of_hydrated_molecule_across_biomembrane_22: $i > $i).
% 29.22/29.08  tff(decl_54426, type, fn_movement_of_hydrated_molecule_across_biomembrane_23: $i > $i).
% 29.22/29.08  tff(decl_54427, type, fn_movement_of_hydrated_molecule_across_biomembrane_24: $i > $i).
% 29.22/29.08  tff(decl_54428, type, fn_movement_of_hydrated_molecule_across_biomembrane_25: $i > $i).
% 29.22/29.08  tff(decl_54429, type, fn_movement_of_hydrated_molecule_across_biomembrane_26: $i > $i).
% 29.22/29.08  tff(decl_54430, type, fn_movement_of_hydrated_molecule_across_biomembrane_27: $i > $i).
% 29.22/29.08  tff(decl_54431, type, fn_movement_of_hydrated_molecule_across_biomembrane_28: $i > $i).
% 29.22/29.08  tff(decl_54432, type, fn_movement_of_hydrated_molecule_across_biomembrane_29: $i > $i).
% 29.22/29.08  tff(decl_54433, type, fn_movement_of_hydrated_molecule_across_biomembrane_30: $i > $i).
% 29.22/29.08  tff(decl_54434, type, fn_movement_of_hydrated_molecule_across_biomembrane_31: $i > $i).
% 29.22/29.08  tff(decl_54435, type, fn_movement_of_hydrated_molecule_across_biomembrane_33: $i > $i).
% 29.22/29.08  tff(decl_54436, type, fn_movement_of_hydrated_molecule_across_biomembrane_34: $i > $i).
% 29.22/29.08  tff(decl_54437, type, fn_movement_of_hydrated_molecule_across_biomembrane_35: $i > $i).
% 29.22/29.08  tff(decl_54438, type, fn_movement_of_hydrated_molecule_across_biomembrane_36: $i > $i).
% 29.22/29.08  tff(decl_54439, type, fn_movement_of_hydrated_molecule_across_biomembrane_37: $i > $i).
% 29.22/29.08  tff(decl_54440, type, fn_movement_of_hydrated_molecule_across_biomembrane_38: $i > $i).
% 29.22/29.08  tff(decl_54441, type, fn_movement_of_hydrated_molecule_across_biomembrane_39: $i > $i).
% 29.22/29.08  tff(decl_54442, type, fn_movement_of_hydrated_molecule_across_biomembrane_40: $i > $i).
% 29.22/29.08  tff(decl_54443, type, fn_movement_of_hydrated_molecule_across_biomembrane_41: $i > $i).
% 29.22/29.08  tff(decl_54444, type, fn_movement_of_hydrated_molecule_across_biomembrane_42: $i > $i).
% 29.22/29.08  tff(decl_54445, type, fn_movement_of_hydrated_molecule_across_biomembrane_43: $i > $i).
% 29.22/29.08  tff(decl_54446, type, fn_movement_of_hydrated_molecule_across_biomembrane_44: $i > $i).
% 29.22/29.08  tff(decl_54447, type, fn_movement_of_hydrated_molecule_across_biomembrane_45: $i > $i).
% 29.22/29.08  tff(decl_54448, type, fn_movement_of_hydrated_molecule_across_biomembrane_46: $i > $i).
% 29.22/29.08  tff(decl_54449, type, fn_movement_of_hydrated_molecule_across_biomembrane_47: $i > $i).
% 29.22/29.08  tff(decl_54450, type, fn_movement_of_hydrated_molecule_across_biomembrane_48: $i > $i).
% 29.22/29.08  tff(decl_54451, type, fn_movement_of_hydrated_molecule_across_biomembrane_49: $i > $i).
% 29.22/29.08  tff(decl_54452, type, fn_movement_of_hydrated_molecule_across_biomembrane_50: $i > $i).
% 29.22/29.08  tff(decl_54453, type, fn_movement_of_hydrated_molecule_across_biomembrane_51: $i > $i).
% 29.22/29.08  tff(decl_54454, type, fn_movement_of_hydrated_molecule_across_biomembrane_52: $i > $i).
% 29.22/29.08  tff(decl_54455, type, fn_movement_of_hydrated_molecule_across_biomembrane_53: $i > $i).
% 29.22/29.08  tff(decl_54456, type, fn_movement_of_hydrated_molecule_across_biomembrane_56: $i > $i).
% 29.22/29.08  tff(decl_54457, type, fn_movement_of_hydrated_molecule_across_biomembrane_57: $i > $i).
% 29.22/29.08  tff(decl_54458, type, fn_movement_of_hydrated_molecule_across_biomembrane_58: $i > $i).
% 29.22/29.08  tff(decl_54459, type, fn_movement_of_hydrated_molecule_across_biomembrane_59: $i > $i).
% 29.22/29.08  tff(decl_54460, type, fn_movement_of_hydrated_molecule_across_biomembrane_54: $i > $i).
% 29.22/29.08  tff(decl_54461, type, fn_movement_of_hydrated_molecule_across_biomembrane_55: $i > $i).
% 29.22/29.08  tff(decl_54462, type, fn_movement_of_hydrated_molecule_across_biomembrane_32: $i > $i).
% 29.22/29.08  tff(decl_54463, type, fn_movement_of_hydrated_molecule_across_biomembrane_10: $i > $i).
% 29.22/29.08  tff(decl_54464, type, fn_movement_of_hydrated_molecule_across_biomembrane_13: $i > $i).
% 29.22/29.08  tff(decl_54465, type, fn_movement_of_hydrated_molecule_across_biomembrane_12: $i > $i).
% 29.22/29.08  tff(decl_54466, type, fn_movement_of_hydrated_molecule_across_biomembrane_11: $i > $i).
% 29.22/29.08  tff(decl_54467, type, movement_of_hydrogen_ion_to_mitochondrial_matrix_1: $i > $o).
% 29.22/29.08  tff(decl_54468, type, 'Movement-Of-Hydrogen-Ion-To-Mitochondrial-Matrix': $i).
% 29.22/29.08  tff(decl_54469, type, 'The passive transfer of hydrogen ions, driven by the proton-motive force, from the intermembrane space to the mitochondrial matrix via ATP synthase, a protein embedded in the inner mitochondrial membrane.  The diffusion of H+ ions through ATP synthase drives the synthesis of ATP in the mitochondria.': $i).
% 29.22/29.08  tff(decl_54470, type, 'movement of hydrogen ion to mitochondrial matrix': $i).
% 29.22/29.08  tff(decl_54471, type, 'movement-of-hydrogen-ion-to-mitochondrial-matrix': $i).
% 29.22/29.08  tff(decl_54472, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_3: $i > $i).
% 29.22/29.08  tff(decl_54473, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_4: $i > $i).
% 29.22/29.08  tff(decl_54474, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_5: $i > $i).
% 29.22/29.08  tff(decl_54475, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_6: $i > $i).
% 29.22/29.08  tff(decl_54476, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_7: $i > $i).
% 29.22/29.08  tff(decl_54477, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_8: $i > $i).
% 29.22/29.08  tff(decl_54478, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_9: $i > $i).
% 29.22/29.08  tff(decl_54479, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_10: $i > $i).
% 29.22/29.08  tff(decl_54480, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_11: $i > $i).
% 29.22/29.08  tff(decl_54481, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_12: $i > $i).
% 29.22/29.08  tff(decl_54482, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_13: $i > $i).
% 29.22/29.08  tff(decl_54483, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_14: $i > $i).
% 29.22/29.08  tff(decl_54484, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_15: $i > $i).
% 29.22/29.08  tff(decl_54485, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_16: $i > $i).
% 29.22/29.08  tff(decl_54486, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_19: $i > $i).
% 29.22/29.08  tff(decl_54487, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_20: $i > $i).
% 29.22/29.08  tff(decl_54488, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_21: $i > $i).
% 29.22/29.08  tff(decl_54489, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_22: $i > $i).
% 29.22/29.08  tff(decl_54490, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_23: $i > $i).
% 29.22/29.08  tff(decl_54491, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_24: $i > $i).
% 29.22/29.08  tff(decl_54492, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_25: $i > $i).
% 29.22/29.08  tff(decl_54493, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_26: $i > $i).
% 29.22/29.08  tff(decl_54494, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_27: $i > $i).
% 29.22/29.08  tff(decl_54495, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_28: $i > $i).
% 29.22/29.08  tff(decl_54496, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_29: $i > $i).
% 29.22/29.08  tff(decl_54497, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_30: $i > $i).
% 29.22/29.08  tff(decl_54498, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_31: $i > $i).
% 29.22/29.08  tff(decl_54499, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_32: $i > $i).
% 29.22/29.08  tff(decl_54500, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_33: $i > $i).
% 29.22/29.08  tff(decl_54501, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_34: $i > $i).
% 29.22/29.08  tff(decl_54502, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_35: $i > $i).
% 29.22/29.08  tff(decl_54503, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_36: $i > $i).
% 29.22/29.08  tff(decl_54504, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_37: $i > $i).
% 29.22/29.08  tff(decl_54505, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_38: $i > $i).
% 29.22/29.08  tff(decl_54506, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_39: $i > $i).
% 29.22/29.08  tff(decl_54507, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_40: $i > $i).
% 29.22/29.08  tff(decl_54508, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_41: $i > $i).
% 29.22/29.08  tff(decl_54509, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_42: $i > $i).
% 29.22/29.08  tff(decl_54510, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_43: $i > $i).
% 29.22/29.08  tff(decl_54511, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_44: $i > $i).
% 29.22/29.08  tff(decl_54512, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_45: $i > $i).
% 29.22/29.08  tff(decl_54513, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_46: $i > $i).
% 29.22/29.08  tff(decl_54514, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_47: $i > $i).
% 29.22/29.08  tff(decl_54515, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_48: $i > $i).
% 29.22/29.08  tff(decl_54516, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_49: $i > $i).
% 29.22/29.08  tff(decl_54517, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_50: $i > $i).
% 29.22/29.08  tff(decl_54518, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_51: $i > $i).
% 29.22/29.08  tff(decl_54519, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_52: $i > $i).
% 29.22/29.08  tff(decl_54520, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_53: $i > $i).
% 29.22/29.08  tff(decl_54521, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_54: $i > $i).
% 29.22/29.08  tff(decl_54522, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_55: $i > $i).
% 29.22/29.08  tff(decl_54523, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_56: $i > $i).
% 29.22/29.08  tff(decl_54524, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_57: $i > $i).
% 29.22/29.08  tff(decl_54525, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_58: $i > $i).
% 29.22/29.08  tff(decl_54526, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_59: $i > $i).
% 29.22/29.08  tff(decl_54527, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_60: $i > $i).
% 29.22/29.08  tff(decl_54528, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_61: $i > $i).
% 29.22/29.08  tff(decl_54529, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_62: $i > $i).
% 29.22/29.08  tff(decl_54530, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_63: $i > $i).
% 29.22/29.08  tff(decl_54531, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_64: $i > $i).
% 29.22/29.08  tff(decl_54532, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_65: $i > $i).
% 29.22/29.08  tff(decl_54533, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_66: $i > $i).
% 29.22/29.08  tff(decl_54534, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_67: $i > $i).
% 29.22/29.08  tff(decl_54535, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_68: $i > $i).
% 29.22/29.08  tff(decl_54536, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_69: $i > $i).
% 29.22/29.08  tff(decl_54537, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_70: $i > $i).
% 29.22/29.08  tff(decl_54538, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_71: $i > $i).
% 29.22/29.08  tff(decl_54539, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_72: $i > $i).
% 29.22/29.08  tff(decl_54540, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_73: $i > $i).
% 29.22/29.08  tff(decl_54541, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_74: $i > $i).
% 29.22/29.08  tff(decl_54542, type, fn_atp_synthase_3: $i > $i).
% 29.22/29.08  tff(decl_54543, type, fn_transmembrane_protein_1: $i > $i).
% 29.22/29.08  tff(decl_54544, type, fn_atp_synthase_2: $i > $i).
% 29.22/29.08  tff(decl_54545, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_17: $i > $i).
% 29.22/29.08  tff(decl_54546, type, fn_movement_of_hydrogen_ion_to_mitochondrial_matrix_18: $i > $i).
% 29.22/29.08  tff(decl_54547, type, 'Movement-Of-Hydrophobic-Molecule-Across-Biomembrane': $i).
% 29.22/29.08  tff(decl_54548, type, 'Hydrophobic molecules, such as hydrocarbons, carbon dioxide, and oxygen, can dissolve in the lipid bilayer of the membrane and cross it with ease.': $i).
% 29.22/29.08  tff(decl_54549, type, 'movement of hydrophobic molecule across biomembrane': $i).
% 29.22/29.08  tff(decl_54550, type, 'movement-of-hydrophobic-molecule-across-biomembrane': $i).
% 29.22/29.08  tff(decl_54551, type, fn_movement_of_hydrophobic_molecule_across_biomembrane_1: $i > $i).
% 29.22/29.08  tff(decl_54552, type, moving_object_1: $i > $o).
% 29.22/29.08  tff(decl_54553, type, 'Moving-Object': $i).
% 29.22/29.08  tff(decl_54554, type, 'A state of the object in motion and hence has kinetic energy': $i).
% 29.22/29.08  tff(decl_54555, type, 'moving object': $i).
% 29.22/29.08  tff(decl_54556, type, 'moving-object': $i).
% 29.22/29.08  tff(decl_54557, type, fn_moving_object_1: $i > $i).
% 29.22/29.08  tff(decl_54558, type, fn_moving_object_2: $i > $i).
% 29.22/29.08  tff(decl_54559, type, 'MPF': $i).
% 29.22/29.08  tff(decl_54560, type, 'Maturation-promoting factor; a protein complex that stimulates the mitotic phase of the cell cycle.': $i).
% 29.22/29.08  tff(decl_54561, type, 'maturation promoting factor': $i).
% 29.22/29.08  tff(decl_54562, type, 'maturation-promoting-factor': $i).
% 29.22/29.08  tff(decl_54563, type, 'm phase promoting factor': $i).
% 29.22/29.08  tff(decl_54564, type, mpf: $i).
% 29.22/29.08  tff(decl_54565, type, fn_mpf_1: $i > $i).
% 29.22/29.08  tff(decl_54566, type, fn_mpf_2: $i > $i).
% 29.22/29.08  tff(decl_54567, type, fn_mpf_3: $i > $i).
% 29.22/29.08  tff(decl_54568, type, 'MRNA': $i).
% 29.22/29.08  tff(decl_54569, type, 'mRNA is a nucleic acid which serve as template for Protein synthesis. it is synthesized in nuclear region using DNA as template and comes in cytoplasm to direct translation (protein synthesis)': $i).
% 29.22/29.08  tff(decl_54570, type, 'messenger rna': $i).
% 29.22/29.08  tff(decl_54571, type, 'messenger ribonucleic acid': $i).
% 29.22/29.08  tff(decl_54572, type, 'messenger ribo nucleic acid': $i).
% 29.22/29.08  tff(decl_54573, type, 'messenger ribo-nucleic acid': $i).
% 29.22/29.08  tff(decl_54574, type, mrna: $i).
% 29.22/29.08  tff(decl_54575, type, 'messenger-rna': $i).
% 29.22/29.08  tff(decl_54576, type, fn_mrna_1: $i > $i).
% 29.22/29.08  tff(decl_54577, type, fn_mrna_2: $i > $i).
% 29.22/29.08  tff(decl_54578, type, fn_mrna_3: $i > $i).
% 29.22/29.08  tff(decl_54579, type, fn_mrna_4: $i > $i).
% 29.22/29.08  tff(decl_54580, type, fn_mrna_5: $i > $i).
% 29.22/29.08  tff(decl_54581, type, fn_mrna_6: $i > $i).
% 29.22/29.08  tff(decl_54582, type, fn_mrna_7: $i > $i).
% 29.22/29.08  tff(decl_54583, type, stop_codon_1: $i > $o).
% 29.22/29.08  tff(decl_54584, type, fn_mrna_8: $i > $i).
% 29.22/29.08  tff(decl_54585, type, trailer_segment_1: $i > $o).
% 29.22/29.08  tff(decl_54586, type, fn_mrna_9: $i > $i).
% 29.22/29.08  tff(decl_54587, type, fn_mrna_10: $i > $i).
% 29.22/29.08  tff(decl_54588, type, fn_mrna_11: $i > $i).
% 29.22/29.08  tff(decl_54589, type, fn_mrna_12: $i > $i).
% 29.22/29.08  tff(decl_54590, type, fn_mrna_13: $i > $i).
% 29.22/29.08  tff(decl_54591, type, fn_mrna_14: $i > $i).
% 29.22/29.08  tff(decl_54592, type, fn_mrna_15: $i > $i).
% 29.22/29.08  tff(decl_54593, type, fn_mrna_16: $i > $i).
% 29.22/29.08  tff(decl_54594, type, fn_mrna_17: $i > $i).
% 29.22/29.08  tff(decl_54595, type, fn_mrna_18: $i > $i).
% 29.22/29.08  tff(decl_54596, type, fn_mrna_19: $i > $i).
% 29.22/29.08  tff(decl_54597, type, fn_mrna_24: $i > $i).
% 29.22/29.08  tff(decl_54598, type, fn_mrna_25: $i > $i).
% 29.22/29.08  tff(decl_54599, type, fn_mrna_26: $i > $i).
% 29.22/29.08  tff(decl_54600, type, fn_mrna_27: $i > $i).
% 29.22/29.08  tff(decl_54601, type, fn_mrna_28: $i > $i).
% 29.22/29.08  tff(decl_54602, type, fn_mrna_29: $i > $i).
% 29.22/29.08  tff(decl_54603, type, fn_mrna_30: $i > $i).
% 29.22/29.08  tff(decl_54604, type, fn_mrna_31: $i > $i).
% 29.22/29.08  tff(decl_54605, type, fn_mrna_32: $i > $i).
% 29.22/29.08  tff(decl_54606, type, fn_mrna_33: $i > $i).
% 29.22/29.08  tff(decl_54607, type, fn_mrna_35: $i > $i).
% 29.22/29.08  tff(decl_54608, type, fn_mrna_36: $i > $i).
% 29.22/29.08  tff(decl_54609, type, fn_mrna_37: $i > $i).
% 29.22/29.08  tff(decl_54610, type, fn_mrna_38: $i > $i).
% 29.22/29.08  tff(decl_54611, type, fn_mrna_39: $i > $i).
% 29.22/29.08  tff(decl_54612, type, fn_mrna_40: $i > $i).
% 29.22/29.08  tff(decl_54613, type, fn_mrna_41: $i > $i).
% 29.22/29.08  tff(decl_54614, type, fn_mrna_42: $i > $i).
% 29.22/29.08  tff(decl_54615, type, fn_mrna_43: $i > $i).
% 29.22/29.08  tff(decl_54616, type, fn_mrna_44: $i > $i).
% 29.22/29.08  tff(decl_54617, type, fn_mrna_45: $i > $i).
% 29.22/29.08  tff(decl_54618, type, fn_mrna_46: $i > $i).
% 29.22/29.08  tff(decl_54619, type, fn_mrna_47: $i > $i).
% 29.22/29.08  tff(decl_54620, type, fn_ribonucleoside_monophosphate_51: $i > $i).
% 29.22/29.08  tff(decl_54621, type, fn_rna_2: $i > $i).
% 29.22/29.08  tff(decl_54622, type, fn_rna_9: $i > $i).
% 29.22/29.08  tff(decl_54623, type, fn_mrna_23: $i > $i).
% 29.22/29.08  tff(decl_54624, type, fn_mrna_22: $i > $i).
% 29.22/29.08  tff(decl_54625, type, fn_mrna_20: $i > $i).
% 29.22/29.08  tff(decl_54626, type, fn_mrna_21: $i > $i).
% 29.22/29.08  tff(decl_54627, type, mrna_degradation_1: $i > $o).
% 29.22/29.08  tff(decl_54628, type, fn_mrna_degradation_15: $i > $i).
% 29.22/29.08  tff(decl_54629, type, 'MRNA-Degradation': $i).
% 29.22/29.08  tff(decl_54630, type, 'The process of degrading MRNA to RNA fragments.': $i).
% 29.22/29.08  tff(decl_54631, type, 'degradation of mrna': $i).
% 29.22/29.08  tff(decl_54632, type, 'mrna degradation': $i).
% 29.22/29.08  tff(decl_54633, type, 'mrna-degradation': $i).
% 29.22/29.08  tff(decl_54634, type, fn_mrna_degradation_1: $i > $i).
% 29.22/29.08  tff(decl_54635, type, fn_mrna_degradation_2: $i > $i).
% 29.22/29.08  tff(decl_54636, type, fn_mrna_degradation_3: $i > $i).
% 29.22/29.08  tff(decl_54637, type, fn_mrna_degradation_4: $i > $i).
% 29.22/29.08  tff(decl_54638, type, fn_mrna_degradation_5: $i > $i).
% 29.22/29.08  tff(decl_54639, type, fn_mrna_degradation_6: $i > $i).
% 29.22/29.08  tff(decl_54640, type, rna_fragment_1: $i > $o).
% 29.22/29.08  tff(decl_54641, type, fn_mrna_degradation_8: $i > $i).
% 29.22/29.08  tff(decl_54642, type, fn_mrna_degradation_9: $i > $i).
% 29.22/29.08  tff(decl_54643, type, fn_mrna_degradation_10: $i > $i).
% 29.22/29.08  tff(decl_54644, type, fn_mrna_degradation_11: $i > $i).
% 29.22/29.08  tff(decl_54645, type, fn_mrna_degradation_12: $i > $i).
% 29.22/29.08  tff(decl_54646, type, fn_mrna_degradation_13: $i > $i).
% 29.22/29.08  tff(decl_54647, type, fn_mrna_degradation_14: $i > $i).
% 29.22/29.08  tff(decl_54648, type, mucin_1: $i > $o).
% 29.22/29.08  tff(decl_54649, type, 'Mucin': $i).
% 29.22/29.08  tff(decl_54650, type, 'Slippery glycoprotein found in mucus.': $i).
% 29.22/29.08  tff(decl_54651, type, mucin: $i).
% 29.22/29.08  tff(decl_54652, type, fn_mucin_1: $i > $i).
% 29.22/29.08  tff(decl_54653, type, 'Mucus': $i).
% 29.22/29.08  tff(decl_54654, type, 'A slippery secretion produced by mucous cells. Mucus is a mixture of glycoproteins, salts, cells, and water. It forms a protective coating for membranes that are exposed to the outer environment.': $i).
% 29.22/29.08  tff(decl_54655, type, mucus: $i).
% 29.22/29.08  tff(decl_54656, type, fn_mucus_2: $i > $i).
% 29.22/29.08  tff(decl_54657, type, fn_mucus_3: $i > $i).
% 29.22/29.08  tff(decl_54658, type, fn_mucus_4: $i > $i).
% 29.22/29.08  tff(decl_54659, type, fn_mucus_5: $i > $i).
% 29.22/29.08  tff(decl_54660, type, biological_fluid_0: $i).
% 29.22/29.08  tff(decl_54661, type, mucus_cell_1: $i > $o).
% 29.22/29.08  tff(decl_54662, type, 'Mucus-Cell': $i).
% 29.22/29.08  tff(decl_54663, type, 'Cells of mucous glands that secrete mucus.': $i).
% 29.22/29.08  tff(decl_54664, type, 'cell of mucus': $i).
% 29.22/29.08  tff(decl_54665, type, 'mucus cell': $i).
% 29.22/29.08  tff(decl_54666, type, 'mucus-cell': $i).
% 29.22/29.08  tff(decl_54667, type, fn_mucus_cell_2: $i > $i).
% 29.22/29.08  tff(decl_54668, type, fn_mucus_cell_3: $i > $i).
% 29.22/29.08  tff(decl_54669, type, fn_mucus_cell_4: $i > $i).
% 29.22/29.08  tff(decl_54670, type, fn_mucus_cell_5: $i > $i).
% 29.22/29.08  tff(decl_54671, type, fn_mucus_cell_6: $i > $i).
% 29.22/29.08  tff(decl_54672, type, fn_mucus_cell_7: $i > $i).
% 29.22/29.08  tff(decl_54673, type, fn_mucus_cell_8: $i > $i).
% 29.22/29.08  tff(decl_54674, type, fn_mucus_cell_9: $i > $i).
% 29.22/29.08  tff(decl_54675, type, fn_mucus_cell_10: $i > $i).
% 29.22/29.08  tff(decl_54676, type, fn_mucus_cell_11: $i > $i).
% 29.22/29.08  tff(decl_54677, type, fn_mucus_cell_12: $i > $i).
% 29.22/29.08  tff(decl_54678, type, fn_mucus_cell_13: $i > $i).
% 29.22/29.08  tff(decl_54679, type, fn_mucus_cell_14: $i > $i).
% 29.22/29.08  tff(decl_54680, type, fn_mucus_cell_15: $i > $i).
% 29.22/29.08  tff(decl_54681, type, fn_mucus_cell_16: $i > $i).
% 29.22/29.08  tff(decl_54682, type, fn_mucus_cell_17: $i > $i).
% 29.22/29.08  tff(decl_54683, type, fn_mucus_cell_18: $i > $i).
% 29.22/29.08  tff(decl_54684, type, fn_mucus_cell_19: $i > $i).
% 29.22/29.08  tff(decl_54685, type, fn_mucus_cell_20: $i > $i).
% 29.22/29.08  tff(decl_54686, type, fn_mucus_cell_21: $i > $i).
% 29.22/29.08  tff(decl_54687, type, fn_mucus_cell_22: $i > $i).
% 29.22/29.08  tff(decl_54688, type, fn_mucus_cell_23: $i > $i).
% 29.22/29.08  tff(decl_54689, type, fn_mucus_cell_24: $i > $i).
% 29.22/29.08  tff(decl_54690, type, fn_mucus_cell_25: $i > $i).
% 29.22/29.08  tff(decl_54691, type, fn_mucus_cell_26: $i > $i).
% 29.22/29.08  tff(decl_54692, type, fn_mucus_cell_27: $i > $i).
% 29.22/29.08  tff(decl_54693, type, fn_mucus_cell_28: $i > $i).
% 29.22/29.08  tff(decl_54694, type, fn_mucus_cell_29: $i > $i).
% 29.22/29.08  tff(decl_54695, type, fn_mucus_cell_30: $i > $i).
% 29.22/29.08  tff(decl_54696, type, fn_mucus_cell_31: $i > $i).
% 29.22/29.08  tff(decl_54697, type, fn_mucus_cell_32: $i > $i).
% 29.22/29.08  tff(decl_54698, type, fn_mucus_cell_33: $i > $i).
% 29.22/29.08  tff(decl_54699, type, fn_mucus_cell_34: $i > $i).
% 29.22/29.08  tff(decl_54700, type, fn_mucus_cell_35: $i > $i).
% 29.22/29.08  tff(decl_54701, type, fn_mucus_cell_36: $i > $i).
% 29.22/29.08  tff(decl_54702, type, fn_mucus_cell_37: $i > $i).
% 29.22/29.08  tff(decl_54703, type, fn_mucus_cell_38: $i > $i).
% 29.22/29.08  tff(decl_54704, type, fn_mucus_cell_39: $i > $i).
% 29.22/29.08  tff(decl_54705, type, fn_mucus_cell_40: $i > $i).
% 29.22/29.08  tff(decl_54706, type, fn_mucus_cell_41: $i > $i).
% 29.22/29.08  tff(decl_54707, type, fn_mucus_cell_42: $i > $i).
% 29.22/29.08  tff(decl_54708, type, fn_mucus_cell_43: $i > $i).
% 29.22/29.08  tff(decl_54709, type, fn_mucus_cell_44: $i > $i).
% 29.22/29.08  tff(decl_54710, type, fn_mucus_cell_45: $i > $i).
% 29.22/29.08  tff(decl_54711, type, fn_mucus_cell_46: $i > $i).
% 29.22/29.08  tff(decl_54712, type, fn_mucus_cell_47: $i > $i).
% 29.22/29.08  tff(decl_54713, type, fn_mucus_cell_48: $i > $i).
% 29.22/29.08  tff(decl_54714, type, fn_mucus_cell_49: $i > $i).
% 29.22/29.08  tff(decl_54715, type, fn_mucus_cell_50: $i > $i).
% 29.22/29.08  tff(decl_54716, type, fn_mucus_cell_51: $i > $i).
% 29.22/29.08  tff(decl_54717, type, fn_mucus_cell_52: $i > $i).
% 29.22/29.08  tff(decl_54718, type, fn_mucus_cell_53: $i > $i).
% 29.22/29.08  tff(decl_54719, type, fn_mucus_cell_54: $i > $i).
% 29.22/29.08  tff(decl_54720, type, fn_mucus_cell_55: $i > $i).
% 29.22/29.08  tff(decl_54721, type, fn_mucus_cell_56: $i > $i).
% 29.22/29.08  tff(decl_54722, type, fn_mucus_cell_57: $i > $i).
% 29.22/29.08  tff(decl_54723, type, fn_mucus_cell_58: $i > $i).
% 29.22/29.08  tff(decl_54724, type, fn_mucus_cell_59: $i > $i).
% 29.22/29.08  tff(decl_54725, type, fn_mucus_cell_60: $i > $i).
% 29.22/29.08  tff(decl_54726, type, fn_mucus_cell_62: $i > $i).
% 29.22/29.08  tff(decl_54727, type, fn_mucus_cell_63: $i > $i).
% 29.22/29.08  tff(decl_54728, type, fn_mucus_cell_64: $i > $i).
% 29.22/29.08  tff(decl_54729, type, fn_mucus_cell_66: $i > $i).
% 29.22/29.08  tff(decl_54730, type, fn_mucus_cell_67: $i > $i).
% 29.22/29.08  tff(decl_54731, type, fn_mucus_cell_68: $i > $i).
% 29.22/29.08  tff(decl_54732, type, fn_synthesis_of_membrane_protein_16: $i > $i).
% 29.22/29.08  tff(decl_54733, type, fn_synthesis_of_glycoprotein_24: $i > $i).
% 29.22/29.08  tff(decl_54734, type, fn_synthesis_of_glycoprotein_64: $i > $i).
% 29.22/29.08  tff(decl_54735, type, fn_synthesis_of_glycoprotein_25: $i > $i).
% 29.22/29.08  tff(decl_54736, type, fn_synthesis_of_glycoprotein_2: $i > $i).
% 29.22/29.08  tff(decl_54737, type, fn_synthesis_of_glycoprotein_58: $i > $i).
% 29.22/29.08  tff(decl_54738, type, fn_synthesis_of_glycoprotein_59: $i > $i).
% 29.22/29.08  tff(decl_54739, type, fn_synthesis_of_glycoprotein_77: $i > $i).
% 29.22/29.08  tff(decl_54740, type, fn_synthesis_of_glycoprotein_88: $i > $i).
% 29.22/29.08  tff(decl_54741, type, fn_synthesis_of_glycoprotein_18: $i > $i).
% 29.22/29.08  tff(decl_54742, type, fn_synthesis_of_glycoprotein_28: $i > $i).
% 29.22/29.08  tff(decl_54743, type, fn_synthesis_of_glycoprotein_13: $i > $i).
% 29.22/29.08  tff(decl_54744, type, fn_synthesis_of_glycoprotein_42: $i > $i).
% 29.22/29.08  tff(decl_54745, type, fn_synthesis_of_protein_7: $i > $i).
% 29.22/29.08  tff(decl_54746, type, fn_synthesis_of_glycoprotein_66: $i > $i).
% 29.22/29.08  tff(decl_54747, type, fn_polymer_synthesis_8: $i > $i).
% 29.22/29.08  tff(decl_54748, type, fn_synthesis_of_protein_8: $i > $i).
% 29.22/29.08  tff(decl_54749, type, fn_synthesis_of_glycoprotein_65: $i > $i).
% 29.22/29.08  tff(decl_54750, type, fn_synthesis_of_protein_1: $i > $i).
% 29.22/29.08  tff(decl_54751, type, fn_synthesis_of_glycoprotein_29: $i > $i).
% 29.22/29.08  tff(decl_54752, type, fn_synthesis_of_protein_3: $i > $i).
% 29.22/29.08  tff(decl_54753, type, fn_synthesis_of_glycoprotein_31: $i > $i).
% 29.22/29.08  tff(decl_54754, type, fn_synthesis_of_glycoprotein_60: $i > $i).
% 29.22/29.08  tff(decl_54755, type, fn_synthesis_of_glycoprotein_55: $i > $i).
% 29.22/29.08  tff(decl_54756, type, fn_synthesis_of_glycoprotein_6: $i > $i).
% 29.22/29.08  tff(decl_54757, type, fn_synthesis_of_glycoprotein_52: $i > $i).
% 29.22/29.08  tff(decl_54758, type, fn_synthesis_of_glycoprotein_70: $i > $i).
% 29.22/29.08  tff(decl_54759, type, fn_synthesis_of_protein_12: $i > $i).
% 29.22/29.08  tff(decl_54760, type, fn_synthesis_of_glycoprotein_57: $i > $i).
% 29.22/29.08  tff(decl_54761, type, fn_synthesis_of_glycoprotein_67: $i > $i).
% 29.22/29.08  tff(decl_54762, type, fn_synthesis_of_glycoprotein_30: $i > $i).
% 29.22/29.08  tff(decl_54763, type, fn_secretory_cell_9: $i > $i).
% 29.22/29.08  tff(decl_54764, type, fn_secretory_cell_20: $i > $i).
% 29.22/29.08  tff(decl_54765, type, fn_secretory_cell_10: $i > $i).
% 29.22/29.08  tff(decl_54766, type, fn_secretory_cell_6: $i > $i).
% 29.22/29.08  tff(decl_54767, type, fn_secretory_cell_5: $i > $i).
% 29.22/29.08  tff(decl_54768, type, fn_secretory_cell_13: $i > $i).
% 29.22/29.08  tff(decl_54769, type, fn_mucus_cell_61: $i > $i).
% 29.22/29.08  tff(decl_54770, type, fn_mucus_cell_65: $i > $i).
% 29.22/29.08  tff(decl_54771, type, 'Mullerian-Mimicry': $i).
% 29.22/29.08  tff(decl_54772, type, 'A type of mimicry in which two or more unpalatable species, which may or not be closely related and may or may not have common predators, mimic each other\\s warning signals.': $i).
% 29.22/29.08  tff(decl_54773, type, 'mullerian mimicry': $i).
% 29.22/29.08  tff(decl_54774, type, 'mullerian-mimicry': $i).
% 29.22/29.08  tff(decl_54775, type, 'Multi-Step-Reaction': $i).
% 29.22/29.08  tff(decl_54776, type, 'A chemical reaction that involves more than one discreet step.': $i).
% 29.22/29.08  tff(decl_54777, type, 'multi step reaction': $i).
% 29.22/29.08  tff(decl_54778, type, 'multi-step-reaction': $i).
% 29.22/29.08  tff(decl_54779, type, 'Multicellular-Organism': $i).
% 29.22/29.08  tff(decl_54780, type, 'An organism composed of more than one cell.                          Souther.': $i).
% 29.22/29.08  tff(decl_54781, type, 'Multicellular organisms are organisms that consist of more than one cell, in contrast to single-celled organisms.': $i).
% 29.22/29.08  tff(decl_54782, type, 'multicellular organism': $i).
% 29.22/29.08  tff(decl_54783, type, 'multicellular-organism': $i).
% 29.22/29.08  tff(decl_54784, type, 'Multienzyme-Complex': $i).
% 29.22/29.08  tff(decl_54785, type, 'Cluster of distinct enzymes catalyzing consecutive reactions of a metabolic pathway.': $i).
% 29.22/29.08  tff(decl_54786, type, 'multienzyme complex': $i).
% 29.22/29.08  tff(decl_54787, type, 'multienzyme-complex': $i).
% 29.22/29.08  tff(decl_54788, type, fn_multienzyme_complex_1: $i > $i).
% 29.22/29.08  tff(decl_54789, type, fn_multienzyme_complex_2: $i > $i).
% 29.22/29.08  tff(decl_54790, type, 'Multifactorial-Genetic-Disorder': $i).
% 29.22/29.08  tff(decl_54791, type, 'A disorder caused by multiple genes and a combination of environmental and lifestyle factors.': $i).
% 29.22/29.08  tff(decl_54792, type, 'multifactorial genetic disorder': $i).
% 29.22/29.08  tff(decl_54793, type, 'multifactorial-genetic-disorder': $i).
% 29.22/29.08  tff(decl_54794, type, 'Multifactorial-Phenotype': $i).
% 29.22/29.08  tff(decl_54795, type, 'A type of phenotype influenced by genetic and environmental factors.': $i).
% 29.22/29.08  tff(decl_54796, type, 'multifactorial character': $i).
% 29.22/29.08  tff(decl_54797, type, 'multifactorial phenotype': $i).
% 29.22/29.08  tff(decl_54798, type, 'multifactorial-phenotype': $i).
% 29.22/29.08  tff(decl_54799, type, fn_multifactorial_phenotype_1: $i > $i).
% 29.22/29.08  tff(decl_54800, type, fn_multifactorial_phenotype_2: $i > $i).
% 29.22/29.08  tff(decl_54801, type, fn_multifactorial_phenotype_3: $i > $i).
% 29.22/29.08  tff(decl_54802, type, 'Multigene-Family': $i).
% 29.22/29.08  tff(decl_54803, type, 'A collection of genes with similar or identical sequences, presumably of common origin.': $i).
% 29.22/29.08  tff(decl_54804, type, 'multigene family': $i).
% 29.22/29.08  tff(decl_54805, type, 'multigene-family': $i).
% 29.22/29.08  tff(decl_54806, type, fn_multigene_family_1: $i > $i).
% 29.22/29.08  tff(decl_54807, type, fn_multigene_family_2: $i > $i).
% 29.22/29.08  tff(decl_54808, type, fn_multigene_family_3: $i > $i).
% 29.22/29.08  tff(decl_54809, type, fn_multigene_family_4: $i > $i).
% 29.22/29.08  tff(decl_54810, type, fn_multigene_family_5: $i > $i).
% 29.22/29.08  tff(decl_54811, type, fn_multigene_family_6: $i > $i).
% 29.22/29.08  tff(decl_54812, type, fn_multigene_family_7: $i > $i).
% 29.22/29.08  tff(decl_54813, type, fn_multigene_family_8: $i > $i).
% 29.22/29.08  tff(decl_54814, type, fn_multigene_family_9: $i > $i).
% 29.22/29.08  tff(decl_54815, type, fn_multigene_family_10: $i > $i).
% 29.22/29.08  tff(decl_54816, type, fn_multigene_family_11: $i > $i).
% 29.22/29.08  tff(decl_54817, type, fn_multigene_family_12: $i > $i).
% 29.22/29.08  tff(decl_54818, type, fn_repeated_gene_duplication_6: $i > $i).
% 29.22/29.08  tff(decl_54819, type, ancestral_gene_0: $i).
% 29.22/29.08  tff(decl_54820, type, multigene_family_alpha_globin_1: $i > $o).
% 29.22/29.08  tff(decl_54821, type, 'Multigene-Family-Alpha-Globin': $i).
% 29.22/29.08  tff(decl_54822, type, 'A collection of genes with identical sequences, presumably of common origin, used by a cell to rapidly make large quantities of alpha globin.': $i).
% 29.22/29.08  tff(decl_54823, type, 'multigene family alpha globin': $i).
% 29.22/29.08  tff(decl_54824, type, 'multigene-family-alpha-globin': $i).
% 29.22/29.08  tff(decl_54825, type, multigene_family_beta_globin_1: $i > $o).
% 29.22/29.08  tff(decl_54826, type, fn_multigene_family_alpha_globin_1: $i > $i).
% 29.22/29.08  tff(decl_54827, type, fn_multigene_family_alpha_globin_2: $i > $i).
% 29.22/29.08  tff(decl_54828, type, 'Multigene-Family-Beta-Globin': $i).
% 29.22/29.08  tff(decl_54829, type, 'A collection of genes with identical sequences, presumably of common origin, used by a cell to rapidly make large quantities of beta globin.': $i).
% 29.22/29.08  tff(decl_54830, type, 'multi gene family beta globin': $i).
% 29.22/29.08  tff(decl_54831, type, 'multigene family beta globin': $i).
% 29.22/29.08  tff(decl_54832, type, 'multigene-family-beta-globin': $i).
% 29.22/29.08  tff(decl_54833, type, fn_multigene_family_beta_globin_1: $i > $i).
% 29.22/29.08  tff(decl_54834, type, fn_multigene_family_beta_globin_2: $i > $i).
% 29.22/29.08  tff(decl_54835, type, fn_multigene_family_beta_globin_3: $i > $i).
% 29.22/29.08  tff(decl_54836, type, fn_multigene_family_beta_globin_4: $i > $i).
% 29.22/29.08  tff(decl_54837, type, fn_multigene_family_beta_globin_5: $i > $i).
% 29.22/29.08  tff(decl_54838, type, fn_multigene_family_beta_globin_6: $i > $i).
% 29.22/29.08  tff(decl_54839, type, multigene_family_for_rrna_1: $i > $o).
% 29.22/29.08  tff(decl_54840, type, 'Multigene-Family-For-RRNA': $i).
% 29.22/29.08  tff(decl_54841, type, 'A multigene family is a cluster of related genes, but the individual genes have identical or similar nucleotide sequences and hence contain identical pieces of information.': $i).
% 29.22/29.08  tff(decl_54842, type, 'multigene family for ribosomal rna': $i).
% 29.22/29.08  tff(decl_54843, type, 'multigene family for rrna': $i).
% 29.22/29.08  tff(decl_54844, type, 'multigene-family-for-rrna': $i).
% 29.22/29.08  tff(decl_54845, type, fn_multigene_family_for_rrna_1: $i > $i).
% 29.22/29.08  tff(decl_54846, type, fn_multigene_family_for_rrna_2: $i > $i).
% 29.22/29.08  tff(decl_54847, type, fn_multigene_family_for_rrna_3: $i > $i).
% 29.22/29.08  tff(decl_54848, type, fn_multigene_family_for_rrna_4: $i > $i).
% 29.22/29.08  tff(decl_54849, type, fn_multigene_family_for_rrna_5: $i > $i).
% 29.22/29.08  tff(decl_54850, type, fn_multigene_family_for_rrna_6: $i > $i).
% 29.22/29.08  tff(decl_54851, type, fn_multigene_family_for_rrna_7: $i > $i).
% 29.22/29.08  tff(decl_54852, type, fn_multigene_family_for_rrna_10: $i > $i).
% 29.22/29.08  tff(decl_54853, type, fn_multigene_family_for_rrna_11: $i > $i).
% 29.22/29.08  tff(decl_54854, type, fn_multigene_family_for_rrna_12: $i > $i).
% 29.22/29.08  tff(decl_54855, type, fn_multigene_family_for_rrna_13: $i > $i).
% 29.22/29.08  tff(decl_54856, type, fn_multigene_family_for_rrna_14: $i > $i).
% 29.22/29.08  tff(decl_54857, type, fn_multigene_family_for_rrna_15: $i > $i).
% 29.22/29.08  tff(decl_54858, type, fn_multigene_family_for_rrna_16: $i > $i).
% 29.22/29.08  tff(decl_54859, type, fn_multigene_family_for_rrna_17: $i > $i).
% 29.22/29.08  tff(decl_54860, type, fn_multigene_family_for_rrna_18: $i > $i).
% 29.22/29.08  tff(decl_54861, type, fn_multigene_family_for_rrna_19: $i > $i).
% 29.22/29.08  tff(decl_54862, type, fn_multigene_family_for_rrna_20: $i > $i).
% 29.22/29.08  tff(decl_54863, type, fn_multigene_family_for_rrna_21: $i > $i).
% 29.22/29.08  tff(decl_54864, type, fn_multigene_family_for_rrna_22: $i > $i).
% 29.22/29.08  tff(decl_54865, type, fn_multigene_family_for_rrna_23: $i > $i).
% 29.22/29.08  tff(decl_54866, type, fn_multigene_family_for_rrna_24: $i > $i).
% 29.22/29.08  tff(decl_54867, type, fn_multigene_family_of_identical_genes_4: $i > $i).
% 29.22/29.08  tff(decl_54868, type, fn_multigene_family_of_identical_genes_2: $i > $i).
% 29.22/29.08  tff(decl_54869, type, fn_multigene_family_of_identical_genes_3: $i > $i).
% 29.22/29.08  tff(decl_54870, type, fn_multigene_family_for_rrna_8: $i > $i).
% 29.22/29.08  tff(decl_54871, type, fn_multigene_family_for_rrna_9: $i > $i).
% 29.22/29.08  tff(decl_54872, type, 'Multigene-Family-Of-Identical-Genes': $i).
% 29.22/29.08  tff(decl_54873, type, 'A collection of genes with identical sequences, presumably of common origin, used by a cell to rapidly make large quantities of identical products.': $i).
% 29.22/29.08  tff(decl_54874, type, 'multigene family of identical gene': $i).
% 29.22/29.08  tff(decl_54875, type, 'multigene-family-of-identical-gene': $i).
% 29.22/29.08  tff(decl_54876, type, fn_multigene_family_of_identical_genes_1: $i > $i).
% 29.22/29.08  tff(decl_54877, type, fn_multigene_family_of_identical_genes_5: $i > $i).
% 29.22/29.08  tff(decl_54878, type, 'Multigene-Family-Of-Nonidentical-Genes': $i).
% 29.22/29.08  tff(decl_54879, type, 'A collection of genes, presumably of common origin, used by a cell to make closely related products.': $i).
% 29.22/29.08  tff(decl_54880, type, 'multigene family of nonidentical gene': $i).
% 29.22/29.08  tff(decl_54881, type, 'multigene-family-of-nonidentical-gene': $i).
% 29.22/29.08  tff(decl_54882, type, 'Multinucleated-Cell': $i).
% 29.22/29.09  tff(decl_54883, type, 'Cells which have more than one nucleus.': $i).
% 29.22/29.09  tff(decl_54884, type, 'multinucleate cell': $i).
% 29.22/29.09  tff(decl_54885, type, 'coenocytic cell': $i).
% 29.22/29.09  tff(decl_54886, type, 'multinucleated cell': $i).
% 29.22/29.09  tff(decl_54887, type, 'multinucleated-cell': $i).
% 29.22/29.09  tff(decl_54888, type, fn_multinucleated_cell_1: $i > $i).
% 29.22/29.09  tff(decl_54889, type, 'Multinucleated-Stage': $i).
% 29.22/29.09  tff(decl_54890, type, 'A stage where the cell of the organism is multinucleated.': $i).
% 29.22/29.09  tff(decl_54891, type, 'multinucleated stage': $i).
% 29.22/29.09  tff(decl_54892, type, 'multinucleated-stage': $i).
% 29.22/29.09  tff(decl_54893, type, fn_multinucleated_stage_1: $i > $i).
% 29.22/29.09  tff(decl_54894, type, multiple_fruit_1: $i > $o).
% 29.22/29.09  tff(decl_54895, type, 'Multiple-Fruit': $i).
% 29.22/29.09  tff(decl_54896, type, 'A fruit that is formed from a cluster of flowers, or an inflorescence.': $i).
% 29.22/29.09  tff(decl_54897, type, 'fruit of multiple': $i).
% 29.22/29.09  tff(decl_54898, type, 'multiple fruit': $i).
% 29.22/29.09  tff(decl_54899, type, 'multiple-fruit': $i).
% 29.22/29.09  tff(decl_54900, type, simple_fruit_1: $i > $o).
% 29.22/29.09  tff(decl_54901, type, 'Multiple-Sclerosis': $i).
% 29.22/29.09  tff(decl_54902, type, 'An auto-immune inflammatory disease of the nervous sytem, in which the myelin sheath covering the axons of the brain and spinal cord are damaged or dysfunctional. A broad spectrum of temporary, treatable neurological symptoms may occur, as well as permanent neurological disorder.': $i).
% 29.22/29.09  tff(decl_54903, type, 'sclerosis of multiple': $i).
% 29.22/29.09  tff(decl_54904, type, 'multiple sclerosis': $i).
% 29.22/29.09  tff(decl_54905, type, 'multiple-sclerosis': $i).
% 29.22/29.09  tff(decl_54906, type, multipotent_stem_cell_1: $i > $o).
% 29.22/29.09  tff(decl_54907, type, 'Multipotent-Stem-Cell': $i).
% 29.22/29.09  tff(decl_54908, type, 'Multipotent stem cells are a specialized cell type that is produced from pluripotent stem cells.': $i).
% 29.22/29.09  tff(decl_54909, type, 'multipotent stem cell': $i).
% 29.22/29.09  tff(decl_54910, type, 'multipotent-stem-cell': $i).
% 29.22/29.09  tff(decl_54911, type, fn_multipotent_stem_cell_1: $i > $i).
% 29.22/29.09  tff(decl_54912, type, fn_multipotent_stem_cell_2: $i > $i).
% 29.22/29.09  tff(decl_54913, type, fn_multipotent_stem_cell_3: $i > $i).
% 29.22/29.09  tff(decl_54914, type, fn_multipotent_stem_cell_4: $i > $i).
% 29.22/29.09  tff(decl_54915, type, fn_multipotent_stem_cell_5: $i > $i).
% 29.22/29.09  tff(decl_54916, type, fn_multipotent_stem_cell_6: $i > $i).
% 29.22/29.09  tff(decl_54917, type, fn_multipotent_stem_cell_7: $i > $i).
% 29.22/29.09  tff(decl_54918, type, fn_multipotent_stem_cell_8: $i > $i).
% 29.22/29.09  tff(decl_54919, type, fn_multipotent_stem_cell_9: $i > $i).
% 29.22/29.09  tff(decl_54920, type, fn_multipotent_stem_cell_10: $i > $i).
% 29.22/29.09  tff(decl_54921, type, fn_multipotent_stem_cell_11: $i > $i).
% 29.22/29.09  tff(decl_54922, type, fn_multipotent_stem_cell_12: $i > $i).
% 29.22/29.09  tff(decl_54923, type, fn_multipotent_stem_cell_13: $i > $i).
% 29.22/29.09  tff(decl_54924, type, fn_multipotent_stem_cell_14: $i > $i).
% 29.22/29.09  tff(decl_54925, type, fn_multipotent_stem_cell_15: $i > $i).
% 29.22/29.09  tff(decl_54926, type, fn_multipotent_stem_cell_16: $i > $i).
% 29.22/29.09  tff(decl_54927, type, fn_multipotent_stem_cell_17: $i > $i).
% 29.22/29.09  tff(decl_54928, type, fn_multipotent_stem_cell_18: $i > $i).
% 29.22/29.09  tff(decl_54929, type, fn_multipotent_stem_cell_19: $i > $i).
% 29.22/29.09  tff(decl_54930, type, fn_multipotent_stem_cell_20: $i > $i).
% 29.22/29.09  tff(decl_54931, type, fn_multipotent_stem_cell_21: $i > $i).
% 29.22/29.09  tff(decl_54932, type, 'Multiprotein-Complex-I': $i).
% 29.22/29.09  tff(decl_54933, type, 'Multiprotein complex I is the first component in the electron transport chain in the mitochondria.': $i).
% 29.22/29.09  tff(decl_54934, type, 'multiprotein complex i': $i).
% 29.22/29.09  tff(decl_54935, type, 'multiprotein-complex-i': $i).
% 29.22/29.09  tff(decl_54936, type, 'Multiprotein-Complex-II': $i).
% 29.22/29.09  tff(decl_54937, type, 'Multiprotein complex II is the second multiprotein complex in the electron transport chain in the mitochondria.': $i).
% 29.22/29.09  tff(decl_54938, type, 'multiprotein complex ii': $i).
% 29.22/29.09  tff(decl_54939, type, 'multiprotein-complex-ii': $i).
% 29.22/29.09  tff(decl_54940, type, fn_multiprotein_complex_ii_1: $i > $i).
% 29.22/29.09  tff(decl_54941, type, 'Multiprotein-Complex-III': $i).
% 29.22/29.09  tff(decl_54942, type, 'Multiprotein complex III is the third multiprotein complex in the electron transport chain in the mitochondria.': $i).
% 29.22/29.09  tff(decl_54943, type, 'multiprotein complex iii': $i).
% 29.22/29.09  tff(decl_54944, type, 'multiprotein-complex-iii': $i).
% 29.22/29.09  tff(decl_54945, type, 'Multiprotein-Complex-IV': $i).
% 29.22/29.09  tff(decl_54946, type, 'Multiprotein complex IV is the fourth multiprotein complex in the electron transport chain in the mitochondria.': $i).
% 29.22/29.09  tff(decl_54947, type, 'multiprotein complex iv': $i).
% 29.22/29.09  tff(decl_54948, type, 'multiprotein-complex-iv': $i).
% 29.22/29.09  tff(decl_54949, type, fn_multiprotein_complex_iv_2: $i > $i).
% 29.22/29.09  tff(decl_54950, type, multislot_value_viewpoint_1: $i > $o).
% 29.22/29.09  tff(decl_54951, type, 'Multislot-Value-Viewpoint': $i).
% 29.22/29.09  tff(decl_54952, type, 'multislot value viewpoint': $i).
% 29.22/29.09  tff(decl_54953, type, 'multislot-value-viewpoint': $i).
% 29.22/29.09  tff(decl_54954, type, 'Muscle': $i).
% 29.22/29.09  tff(decl_54955, type, 'A single organ that is part of the muscular system and composed of contractile muscular tissue.': $i).
% 29.22/29.09  tff(decl_54956, type, muscle: $i).
% 29.22/29.09  tff(decl_54957, type, fn_muscle_1: $i > $i).
% 29.22/29.09  tff(decl_54958, type, fn_muscle_2: $i > $i).
% 29.22/29.09  tff(decl_54959, type, fn_muscle_3: $i > $i).
% 29.22/29.09  tff(decl_54960, type, fn_muscle_4: $i > $i).
% 29.22/29.09  tff(decl_54961, type, 'Muscle-Cell': $i).
% 29.22/29.09  tff(decl_54962, type, 'Cells that are elongated and contractile that form the muscles of the body': $i).
% 29.22/29.09  tff(decl_54963, type, 'cell of muscle': $i).
% 29.22/29.09  tff(decl_54964, type, 'muscle cell': $i).
% 29.22/29.09  tff(decl_54965, type, 'muscle-cell': $i).
% 29.22/29.09  tff(decl_54966, type, fn_muscle_cell_1: $i > $i).
% 29.22/29.09  tff(decl_54967, type, fn_muscle_cell_2: $i > $i).
% 29.22/29.09  tff(decl_54968, type, fn_muscle_cell_3: $i > $i).
% 29.22/29.09  tff(decl_54969, type, fn_muscle_cell_5: $i > $i).
% 29.22/29.09  tff(decl_54970, type, fn_muscle_cell_6: $i > $i).
% 29.22/29.09  tff(decl_54971, type, fn_muscle_cell_7: $i > $i).
% 29.22/29.09  tff(decl_54972, type, fn_muscle_cell_8: $i > $i).
% 29.22/29.09  tff(decl_54973, type, fn_muscle_cell_9: $i > $i).
% 29.22/29.09  tff(decl_54974, type, fn_muscle_cell_10: $i > $i).
% 29.22/29.09  tff(decl_54975, type, fn_muscle_cell_11: $i > $i).
% 29.22/29.09  tff(decl_54976, type, fn_muscle_cell_12: $i > $i).
% 29.22/29.09  tff(decl_54977, type, fn_muscle_cell_13: $i > $i).
% 29.22/29.09  tff(decl_54978, type, fn_muscle_cell_16: $i > $i).
% 29.22/29.09  tff(decl_54979, type, fn_muscle_cell_18: $i > $i).
% 29.22/29.09  tff(decl_54980, type, fn_muscle_cell_19: $i > $i).
% 29.22/29.09  tff(decl_54981, type, fn_muscle_cell_20: $i > $i).
% 29.22/29.09  tff(decl_54982, type, fn_muscle_cell_21: $i > $i).
% 29.22/29.09  tff(decl_54983, type, fn_muscle_cell_22: $i > $i).
% 29.22/29.09  tff(decl_54984, type, fn_muscle_cell_23: $i > $i).
% 29.22/29.09  tff(decl_54985, type, fn_muscle_cell_24: $i > $i).
% 29.22/29.09  tff(decl_54986, type, fn_muscle_cell_25: $i > $i).
% 29.22/29.09  tff(decl_54987, type, fn_muscle_cell_26: $i > $i).
% 29.22/29.09  tff(decl_54988, type, fn_muscle_cell_27: $i > $i).
% 29.22/29.09  tff(decl_54989, type, fn_muscle_cell_28: $i > $i).
% 29.22/29.09  tff(decl_54990, type, fn_muscle_cell_29: $i > $i).
% 29.22/29.09  tff(decl_54991, type, fn_muscle_cell_30: $i > $i).
% 29.22/29.09  tff(decl_54992, type, fn_muscle_cell_31: $i > $i).
% 29.22/29.09  tff(decl_54993, type, fn_muscle_cell_32: $i > $i).
% 29.22/29.09  tff(decl_54994, type, fn_muscle_cell_33: $i > $i).
% 29.22/29.09  tff(decl_54995, type, fn_muscle_cell_34: $i > $i).
% 29.22/29.09  tff(decl_54996, type, fn_muscle_cell_35: $i > $i).
% 29.22/29.09  tff(decl_54997, type, fn_muscle_cell_36: $i > $i).
% 29.22/29.09  tff(decl_54998, type, fn_muscle_cell_37: $i > $i).
% 29.22/29.09  tff(decl_54999, type, fn_muscle_cell_38: $i > $i).
% 29.22/29.09  tff(decl_55000, type, fn_muscle_cell_39: $i > $i).
% 29.22/29.09  tff(decl_55001, type, fn_muscle_cell_40: $i > $i).
% 29.22/29.09  tff(decl_55002, type, fn_muscle_cell_41: $i > $i).
% 29.22/29.09  tff(decl_55003, type, fn_muscle_cell_42: $i > $i).
% 29.22/29.09  tff(decl_55004, type, fn_muscle_cell_43: $i > $i).
% 29.22/29.09  tff(decl_55005, type, fn_muscle_cell_44: $i > $i).
% 29.22/29.09  tff(decl_55006, type, fn_muscle_cell_45: $i > $i).
% 29.22/29.09  tff(decl_55007, type, fn_muscle_cell_46: $i > $i).
% 29.22/29.09  tff(decl_55008, type, fn_muscle_cell_47: $i > $i).
% 29.22/29.09  tff(decl_55009, type, fn_muscle_cell_48: $i > $i).
% 29.22/29.09  tff(decl_55010, type, fn_muscle_cell_49: $i > $i).
% 29.22/29.09  tff(decl_55011, type, fn_muscle_cell_50: $i > $i).
% 29.22/29.09  tff(decl_55012, type, fn_muscle_cell_51: $i > $i).
% 29.22/29.09  tff(decl_55013, type, fn_muscle_cell_52: $i > $i).
% 29.22/29.09  tff(decl_55014, type, myosin_filament_1: $i > $o).
% 29.22/29.09  tff(decl_55015, type, fn_muscle_cell_53: $i > $i).
% 29.22/29.09  tff(decl_55016, type, fn_muscle_cell_56: $i > $i).
% 29.22/29.09  tff(decl_55017, type, fn_muscle_cell_57: $i > $i).
% 29.22/29.09  tff(decl_55018, type, fn_muscle_cell_58: $i > $i).
% 29.22/29.09  tff(decl_55019, type, fn_muscle_cell_59: $i > $i).
% 29.22/29.09  tff(decl_55020, type, fn_muscle_cell_60: $i > $i).
% 29.22/29.09  tff(decl_55021, type, fn_muscle_cell_61: $i > $i).
% 29.22/29.09  tff(decl_55022, type, fn_muscle_cell_62: $i > $i).
% 29.22/29.09  tff(decl_55023, type, fn_muscle_cell_63: $i > $i).
% 29.22/29.09  tff(decl_55024, type, fn_muscle_cell_64: $i > $i).
% 29.22/29.09  tff(decl_55025, type, fn_muscle_cell_65: $i > $i).
% 29.22/29.09  tff(decl_55026, type, fn_muscle_cell_66: $i > $i).
% 29.22/29.09  tff(decl_55027, type, fn_muscle_cell_67: $i > $i).
% 29.22/29.09  tff(decl_55028, type, fn_muscle_cell_68: $i > $i).
% 29.22/29.09  tff(decl_55029, type, fn_muscle_cell_69: $i > $i).
% 29.22/29.09  tff(decl_55030, type, fn_muscle_cell_70: $i > $i).
% 29.22/29.09  tff(decl_55031, type, fn_muscle_cell_71: $i > $i).
% 29.22/29.09  tff(decl_55032, type, fn_muscle_cell_72: $i > $i).
% 29.22/29.09  tff(decl_55033, type, fn_muscle_cell_73: $i > $i).
% 29.22/29.09  tff(decl_55034, type, fn_muscle_cell_74: $i > $i).
% 29.22/29.09  tff(decl_55035, type, fn_muscle_cell_75: $i > $i).
% 29.22/29.09  tff(decl_55036, type, fn_muscle_cell_76: $i > $i).
% 29.22/29.09  tff(decl_55037, type, fn_muscle_cell_77: $i > $i).
% 29.22/29.09  tff(decl_55038, type, fn_muscle_cell_78: $i > $i).
% 29.22/29.09  tff(decl_55039, type, fn_muscle_cell_79: $i > $i).
% 29.22/29.09  tff(decl_55040, type, fn_myosin_filament_3: $i > $i).
% 29.22/29.09  tff(decl_55041, type, fn_myosin_filament_2: $i > $i).
% 29.22/29.09  tff(decl_55042, type, fn_myosin_filament_4: $i > $i).
% 29.22/29.09  tff(decl_55043, type, fn_muscle_cell_15: $i > $i).
% 29.22/29.09  tff(decl_55044, type, fn_muscle_cell_14: $i > $i).
% 29.22/29.09  tff(decl_55045, type, 'Muscle-Cell-Determination': $i).
% 29.22/29.09  tff(decl_55046, type, 'The progressive restriction of developmental potential in which the possible fate of muscle cell becomes more limited. At the end of determination, a cell is committed to its fate.': $i).
% 29.22/29.09  tff(decl_55047, type, 'muscle cell determination': $i).
% 29.22/29.09  tff(decl_55048, type, 'muscle-cell-determination': $i).
% 29.22/29.09  tff(decl_55049, type, fn_muscle_cell_determination_1: $i > $i).
% 29.22/29.09  tff(decl_55050, type, fn_muscle_cell_determination_2: $i > $i).
% 29.22/29.09  tff(decl_55051, type, fn_muscle_cell_determination_3: $i > $i).
% 29.22/29.09  tff(decl_55052, type, fn_muscle_cell_determination_4: $i > $i).
% 29.22/29.09  tff(decl_55053, type, fn_muscle_cell_determination_5: $i > $i).
% 29.22/29.09  tff(decl_55054, type, fn_muscle_cell_determination_6: $i > $i).
% 29.22/29.09  tff(decl_55055, type, fn_muscle_cell_determination_7: $i > $i).
% 29.22/29.09  tff(decl_55056, type, fn_muscle_cell_determination_8: $i > $i).
% 29.22/29.09  tff(decl_55057, type, fn_muscle_cell_determination_9: $i > $i).
% 29.22/29.09  tff(decl_55058, type, fn_muscle_cell_determination_10: $i > $i).
% 29.22/29.09  tff(decl_55059, type, myod_protein_1: $i > $o).
% 29.22/29.09  tff(decl_55060, type, fn_muscle_cell_determination_11: $i > $i).
% 29.22/29.09  tff(decl_55061, type, fn_muscle_cell_determination_12: $i > $i).
% 29.22/29.09  tff(decl_55062, type, fn_muscle_cell_determination_13: $i > $i).
% 29.22/29.09  tff(decl_55063, type, 'Muscle-Cell-Differentiation': $i).
% 29.22/29.09  tff(decl_55064, type, 'Muscle cell differentiation is a process in which a muscle cell develops into a specific type of cell in response to specific triggers from the body or the cell itself.': $i).
% 29.22/29.09  tff(decl_55065, type, 'muscle cell differentiation': $i).
% 29.22/29.09  tff(decl_55066, type, 'muscle-cell-differentiation': $i).
% 29.22/29.09  tff(decl_55067, type, fn_muscle_cell_differentiation_1: $i > $i).
% 29.22/29.09  tff(decl_55068, type, fn_muscle_cell_differentiation_2: $i > $i).
% 29.22/29.09  tff(decl_55069, type, fn_muscle_cell_differentiation_7: $i > $i).
% 29.22/29.09  tff(decl_55070, type, fn_muscle_cell_differentiation_8: $i > $i).
% 29.22/29.09  tff(decl_55071, type, fn_muscle_cell_differentiation_9: $i > $i).
% 29.22/29.09  tff(decl_55072, type, fn_muscle_cell_differentiation_10: $i > $i).
% 29.22/29.09  tff(decl_55073, type, fn_muscle_cell_differentiation_11: $i > $i).
% 29.22/29.09  tff(decl_55074, type, fn_muscle_cell_differentiation_12: $i > $i).
% 29.22/29.09  tff(decl_55075, type, fn_muscle_cell_differentiation_13: $i > $i).
% 29.22/29.09  tff(decl_55076, type, fn_muscle_cell_differentiation_14: $i > $i).
% 29.22/29.09  tff(decl_55077, type, fn_cell_12: $i > $i).
% 29.22/29.09  tff(decl_55078, type, fn_muscle_cell_differentiation_4: $i > $i).
% 29.22/29.09  tff(decl_55079, type, fn_muscle_cell_differentiation_3: $i > $i).
% 29.22/29.09  tff(decl_55080, type, fn_muscle_cell_differentiation_6: $i > $i).
% 29.22/29.09  tff(decl_55081, type, fn_muscle_cell_differentiation_5: $i > $i).
% 29.22/29.09  tff(decl_55082, type, 'Muscle-Contraction': $i).
% 29.22/29.09  tff(decl_55083, type, 'An act of contraction, shortening or tensing of a muscle part or muscle fiber.': $i).
% 29.22/29.09  tff(decl_55084, type, 'muscle cell contraction': $i).
% 29.22/29.09  tff(decl_55085, type, 'contraction of muscle': $i).
% 29.22/29.09  tff(decl_55086, type, 'muscle contraction': $i).
% 29.22/29.09  tff(decl_55087, type, 'muscle-contraction': $i).
% 29.22/29.09  tff(decl_55088, type, fn_muscle_contraction_1: $i > $i).
% 29.22/29.09  tff(decl_55089, type, fn_muscle_contraction_2: $i > $i).
% 29.22/29.09  tff(decl_55090, type, fn_muscle_contraction_3: $i > $i).
% 29.22/29.09  tff(decl_55091, type, fn_muscle_contraction_4: $i > $i).
% 29.22/29.09  tff(decl_55092, type, fn_muscle_contraction_5: $i > $i).
% 29.22/29.09  tff(decl_55093, type, fn_muscle_contraction_6: $i > $i).
% 29.22/29.09  tff(decl_55094, type, fn_muscle_contraction_7: $i > $i).
% 29.22/29.09  tff(decl_55095, type, fn_muscle_contraction_8: $i > $i).
% 29.22/29.09  tff(decl_55096, type, fn_muscle_contraction_9: $i > $i).
% 29.22/29.09  tff(decl_55097, type, fn_muscle_contraction_10: $i > $i).
% 29.22/29.09  tff(decl_55098, type, fn_muscle_contraction_11: $i > $i).
% 29.22/29.09  tff(decl_55099, type, fn_muscle_contraction_12: $i > $i).
% 29.22/29.09  tff(decl_55100, type, fn_muscle_contraction_13: $i > $i).
% 29.22/29.09  tff(decl_55101, type, fn_muscle_contraction_14: $i > $i).
% 29.22/29.09  tff(decl_55102, type, fn_muscle_contraction_16: $i > $i).
% 29.22/29.09  tff(decl_55103, type, fn_muscle_contraction_15: $i > $i).
% 29.22/29.09  tff(decl_55104, type, 'Muscle-Relaxation': $i).
% 29.22/29.09  tff(decl_55105, type, 'The elongation and decontraction of muscle tissue.': $i).
% 29.22/29.09  tff(decl_55106, type, relax: $i).
% 29.22/29.09  tff(decl_55107, type, 'relaxation of muscle': $i).
% 29.22/29.09  tff(decl_55108, type, 'muscle relaxation': $i).
% 29.22/29.09  tff(decl_55109, type, 'muscle-relaxation': $i).
% 29.22/29.09  tff(decl_55110, type, fn_muscle_relaxation_1: $i > $i).
% 29.22/29.09  tff(decl_55111, type, fn_muscle_relaxation_2: $i > $i).
% 29.22/29.09  tff(decl_55112, type, 'Muscle-Specific-Transcription-Factor': $i).
% 29.22/29.09  tff(decl_55113, type, 'A regulatory protein that binds to specific DNA sequences and thereby controls the transfer (or transcription) of genetic information from DNA to mRNA in muscle cells.': $i).
% 29.22/29.09  tff(decl_55114, type, 'muscle specific transcription factor': $i).
% 29.22/29.09  tff(decl_55115, type, 'muscle-specific-transcription-factor': $i).
% 29.22/29.09  tff(decl_55116, type, 'Muscle-Tissue': $i).
% 29.22/29.09  tff(decl_55117, type, 'Tissue consisting of contractile muscle cells.': $i).
% 29.22/29.09  tff(decl_55118, type, 'tissue of muscle': $i).
% 29.22/29.09  tff(decl_55119, type, 'muscle tissue': $i).
% 29.22/29.09  tff(decl_55120, type, 'muscle-tissue': $i).
% 29.22/29.09  tff(decl_55121, type, mushroom_1: $i > $o).
% 29.22/29.09  tff(decl_55122, type, 'Mushroom': $i).
% 29.22/29.09  tff(decl_55123, type, 'The spore-producing fruiting body of some fungi.': $i).
% 29.22/29.09  tff(decl_55124, type, mushroom: $i).
% 29.22/29.09  tff(decl_55125, type, mussel_1: $i > $o).
% 29.22/29.09  tff(decl_55126, type, 'Mussel': $i).
% 29.22/29.09  tff(decl_55127, type, 'The common name for marine or freshwater animals from the molluscan class Bivalvia. Mussels can generally be distinguished from other bivalves by their shape:  one end is tapered to a point while the other is rounded.': $i).
% 29.22/29.09  tff(decl_55128, type, mussel: $i).
% 29.22/29.09  tff(decl_55129, type, oyster_1: $i > $o).
% 29.22/29.09  tff(decl_55130, type, 'Mutagen': $i).
% 29.22/29.09  tff(decl_55131, type, 'A chemical or physical agent that causes a change in the genetic material of an organism.': $i).
% 29.22/29.09  tff(decl_55132, type, mutagen: $i).
% 29.22/29.09  tff(decl_55133, type, 'Mutant-Phenotype': $i).
% 29.22/29.09  tff(decl_55134, type, 'An individual bearing an allele that has undergone mutation and is expressed in the phenotype.': $i).
% 29.22/29.09  tff(decl_55135, type, 'phenotype of mutant': $i).
% 29.22/29.09  tff(decl_55136, type, 'mutant phenotype': $i).
% 29.22/29.09  tff(decl_55137, type, 'mutant-phenotype': $i).
% 29.22/29.09  tff(decl_55138, type, 'Mutant-Type': $i).
% 29.22/29.09  tff(decl_55139, type, 'Traits that are alternatives to the wild type.': $i).
% 29.22/29.09  tff(decl_55140, type, 'type of mutant': $i).
% 29.22/29.09  tff(decl_55141, type, 'mutant type': $i).
% 29.22/29.09  tff(decl_55142, type, 'mutant-type': $i).
% 29.22/29.09  tff(decl_55143, type, fn_mutant_type_1: $i > $i).
% 29.22/29.09  tff(decl_55144, type, fn_mutant_type_2: $i > $i).
% 29.22/29.09  tff(decl_55145, type, fn_mutant_type_3: $i > $i).
% 29.22/29.09  tff(decl_55146, type, fn_mutant_type_4: $i > $i).
% 29.22/29.09  tff(decl_55147, type, 'Mutation': $i).
% 29.22/29.09  tff(decl_55148, type, 'A change in the nucleotide sequence of an organism\\s genetic material.': $i).
% 29.22/29.09  tff(decl_55149, type, mutation: $i).
% 29.22/29.09  tff(decl_55150, type, fn_mutation_1: $i > $i).
% 29.22/29.09  tff(decl_55151, type, 'Mutualism': $i).
% 29.22/29.09  tff(decl_55152, type, 'A symbiotic relationship in which both partners benefit from the association.': $i).
% 29.22/29.09  tff(decl_55153, type, 'mutually benefit': $i).
% 29.22/29.09  tff(decl_55154, type, 'undergo mutualism': $i).
% 29.22/29.09  tff(decl_55155, type, mutualism: $i).
% 29.22/29.09  tff(decl_55156, type, 'Mycelium': $i).
% 29.22/29.09  tff(decl_55157, type, 'The vegetative part of a fungus, consisting of a densely branched network of hyphae.': $i).
% 29.22/29.09  tff(decl_55158, type, mycelium: $i).
% 29.22/29.09  tff(decl_55159, type, 'Mycetozoa': $i).
% 29.22/29.09  tff(decl_55160, type, 'A phylum within the kingdom Amoebozoa.': $i).
% 29.22/29.09  tff(decl_55161, type, mycetozoa: $i).
% 29.22/29.09  tff(decl_55162, type, 'Mycoplasma': $i).
% 29.22/29.09  tff(decl_55163, type, 'Mycoplasma is a genus of bacteria that lack a cell wall.': $i).
% 29.22/29.09  tff(decl_55164, type, mycoplasma: $i).
% 29.22/29.09  tff(decl_55165, type, fn_mycoplasma_1: $i > $i).
% 29.22/29.09  tff(decl_55166, type, fn_mycoplasma_2: $i > $i).
% 29.22/29.09  tff(decl_55167, type, fn_mycoplasma_3: $i > $i).
% 29.22/29.09  tff(decl_55168, type, fn_mycoplasma_4: $i > $i).
% 29.22/29.09  tff(decl_55169, type, fn_mycoplasma_5: $i > $i).
% 29.22/29.09  tff(decl_55170, type, fn_mycoplasma_6: $i > $i).
% 29.22/29.09  tff(decl_55171, type, fn_mycoplasma_7: $i > $i).
% 29.22/29.09  tff(decl_55172, type, fn_mycoplasma_8: $i > $i).
% 29.22/29.09  tff(decl_55173, type, fn_mycoplasma_9: $i > $i).
% 29.22/29.09  tff(decl_55174, type, fn_mycoplasma_10: $i > $i).
% 29.22/29.09  tff(decl_55175, type, fn_mycoplasma_11: $i > $i).
% 29.22/29.09  tff(decl_55176, type, fn_mycoplasma_12: $i > $i).
% 29.22/29.09  tff(decl_55177, type, fn_mycoplasma_13: $i > $i).
% 29.22/29.09  tff(decl_55178, type, fn_mycoplasma_14: $i > $i).
% 29.22/29.09  tff(decl_55179, type, fn_mycoplasma_15: $i > $i).
% 29.22/29.09  tff(decl_55180, type, fn_mycoplasma_16: $i > $i).
% 29.22/29.09  tff(decl_55181, type, fn_mycoplasma_17: $i > $i).
% 29.22/29.09  tff(decl_55182, type, fn_mycoplasma_18: $i > $i).
% 29.22/29.09  tff(decl_55183, type, fn_mycoplasma_19: $i > $i).
% 29.22/29.09  tff(decl_55184, type, fn_mycoplasma_20: $i > $i).
% 29.22/29.09  tff(decl_55185, type, fn_mycoplasma_21: $i > $i).
% 29.22/29.09  tff(decl_55186, type, 'Mycorrhiza': $i).
% 29.22/29.09  tff(decl_55187, type, 'A mutualistic relationship between a fungus and the roots of a plant.': $i).
% 29.22/29.09  tff(decl_55188, type, mycorrhiza: $i).
% 29.22/29.09  tff(decl_55189, type, fn_mycorrhiza_2: $i > $i).
% 29.22/29.09  tff(decl_55190, type, fn_mycorrhiza_3: $i > $i).
% 29.22/29.09  tff(decl_55191, type, fn_mycorrhiza_4: $i > $i).
% 29.22/29.09  tff(decl_55192, type, fn_mycorrhiza_6: $i > $i).
% 29.22/29.09  tff(decl_55193, type, fn_mycorrhiza_7: $i > $i).
% 29.22/29.09  tff(decl_55194, type, fn_mycorrhiza_8: $i > $i).
% 29.22/29.09  tff(decl_55195, type, fn_mycorrhiza_9: $i > $i).
% 29.22/29.09  tff(decl_55196, type, fn_mycorrhiza_10: $i > $i).
% 29.22/29.09  tff(decl_55197, type, fn_mycorrhiza_11: $i > $i).
% 29.22/29.09  tff(decl_55198, type, fn_mycorrhiza_12: $i > $i).
% 29.22/29.09  tff(decl_55199, type, fn_mycorrhiza_13: $i > $i).
% 29.22/29.09  tff(decl_55200, type, fn_mycorrhiza_14: $i > $i).
% 29.22/29.09  tff(decl_55201, type, fn_mycorrhiza_15: $i > $i).
% 29.22/29.09  tff(decl_55202, type, fn_mycorrhiza_16: $i > $i).
% 29.22/29.09  tff(decl_55203, type, fn_mycorrhiza_17: $i > $i).
% 29.22/29.09  tff(decl_55204, type, fn_mycorrhiza_18: $i > $i).
% 29.22/29.09  tff(decl_55205, type, fn_mycorrhiza_19: $i > $i).
% 29.22/29.09  tff(decl_55206, type, fn_mycorrhiza_20: $i > $i).
% 29.22/29.09  tff(decl_55207, type, hypha_0: $i).
% 29.22/29.09  tff(decl_55208, type, 'Mycosis': $i).
% 29.22/29.09  tff(decl_55209, type, 'A fungal infection of animals, including humans.': $i).
% 29.22/29.09  tff(decl_55210, type, 'fungal disease': $i).
% 29.22/29.09  tff(decl_55211, type, 'fungal-disease': $i).
% 29.22/29.09  tff(decl_55212, type, mycosis: $i).
% 29.22/29.09  tff(decl_55213, type, 'Myelin-Sheath': $i).
% 29.22/29.09  tff(decl_55214, type, 'An electrically insulating layer along the axons of vertebrate neurons. The myelin sheath is formed from the cell membranes of multiple Schwann cells and is interrupted at regular intervals called the nodes of Ranvier.': $i).
% 29.22/29.09  tff(decl_55215, type, 'sheath of myelin': $i).
% 29.22/29.09  tff(decl_55216, type, 'myelin sheath': $i).
% 29.22/29.09  tff(decl_55217, type, 'myelin-sheath': $i).
% 29.22/29.09  tff(decl_55218, type, 'Myoblast': $i).
% 29.22/29.09  tff(decl_55219, type, 'An undifferentiated cell in a vertebrate embryo that will eventually become a muscle cell.': $i).
% 29.22/29.09  tff(decl_55220, type, myoblast: $i).
% 29.22/29.09  tff(decl_55221, type, fn_myoblast_1: $i > $i).
% 29.22/29.09  tff(decl_55222, type, fn_myoblast_2: $i > $i).
% 29.22/29.09  tff(decl_55223, type, 'MyoD-Gene': $i).
% 29.22/29.09  tff(decl_55224, type, 'The myoD gene converts many differentiated cell types into muscle.': $i).
% 29.22/29.09  tff(decl_55225, type, 'myod gene': $i).
% 29.22/29.09  tff(decl_55226, type, 'myod-gene': $i).
% 29.22/29.09  tff(decl_55227, type, fn_myod_gene_1: $i > $i).
% 29.22/29.09  tff(decl_55228, type, 'MyoD-Protein': $i).
% 29.22/29.09  tff(decl_55229, type, 'MyoD is a protein with a key role in regulating muscle differentiation. MyoD belongs to a family of proteins known as myogenic regulatory factors.': $i).
% 29.22/29.09  tff(decl_55230, type, 'myod protein': $i).
% 29.22/29.09  tff(decl_55231, type, 'myod-protein': $i).
% 29.22/29.09  tff(decl_55232, type, fn_myod_protein_1: $i > $i).
% 29.22/29.09  tff(decl_55233, type, fn_myod_protein_2: $i > $i).
% 29.22/29.09  tff(decl_55234, type, fn_myod_protein_3: $i > $i).
% 29.22/29.09  tff(decl_55235, type, fn_myod_protein_4: $i > $i).
% 29.22/29.09  tff(decl_55236, type, fn_myod_protein_5: $i > $i).
% 29.22/29.09  tff(decl_55237, type, fn_myod_protein_6: $i > $i).
% 29.22/29.09  tff(decl_55238, type, 'MSTF1': $i).
% 29.22/29.09  tff(decl_55239, type, 'MSFT2': $i).
% 29.22/29.09  tff(decl_55240, type, 'Myofibril': $i).
% 29.22/29.09  tff(decl_55241, type, 'The basic unit of a muscle. Myofibrils are composed of thin filaments of actin, thick filaments of myosin, and other proteins that hold them together.': $i).
% 29.22/29.09  tff(decl_55242, type, myofibril: $i).
% 29.22/29.09  tff(decl_55243, type, myoglobin_1: $i > $o).
% 29.22/29.09  tff(decl_55244, type, 'Myoglobin': $i).
% 29.22/29.09  tff(decl_55245, type, 'An oxygen-binding molecule found in the muscle cells of vertebrates.': $i).
% 29.22/29.09  tff(decl_55246, type, myoglobin: $i).
% 29.22/29.09  tff(decl_55247, type, 'Myosin': $i).
% 29.22/29.09  tff(decl_55248, type, 'Myosin is a large family of motor proteins which bring about actin-based motility. It is present in all eukaryotic cells': $i).
% 29.22/29.09  tff(decl_55249, type, myosin: $i).
% 29.22/29.09  tff(decl_55250, type, fn_myosin_5: $i > $i).
% 29.22/29.09  tff(decl_55251, type, fn_myosin_6: $i > $i).
% 29.22/29.09  tff(decl_55252, type, fn_myosin_7: $i > $i).
% 29.22/29.09  tff(decl_55253, type, fn_myosin_8: $i > $i).
% 29.22/29.09  tff(decl_55254, type, fn_myosin_9: $i > $i).
% 29.22/29.09  tff(decl_55255, type, fn_myosin_10: $i > $i).
% 29.22/29.09  tff(decl_55256, type, fn_myosin_11: $i > $i).
% 29.22/29.09  tff(decl_55257, type, fn_myosin_12: $i > $i).
% 29.22/29.09  tff(decl_55258, type, fn_myosin_13: $i > $i).
% 29.22/29.09  tff(decl_55259, type, fn_myosin_14: $i > $i).
% 29.22/29.09  tff(decl_55260, type, fn_myosin_15: $i > $i).
% 29.22/29.09  tff(decl_55261, type, fn_myosin_16: $i > $i).
% 29.22/29.09  tff(decl_55262, type, fn_myosin_17: $i > $i).
% 29.22/29.09  tff(decl_55263, type, fn_myosin_18: $i > $i).
% 29.22/29.09  tff(decl_55264, type, fn_myosin_19: $i > $i).
% 29.22/29.09  tff(decl_55265, type, fn_myosin_20: $i > $i).
% 29.22/29.09  tff(decl_55266, type, fn_myosin_21: $i > $i).
% 29.22/29.09  tff(decl_55267, type, fn_myosin_22: $i > $i).
% 29.22/29.09  tff(decl_55268, type, fn_myosin_23: $i > $i).
% 29.22/29.09  tff(decl_55269, type, fn_myosin_4: $i > $i).
% 29.22/29.09  tff(decl_55270, type, fn_myosin_3: $i > $i).
% 29.22/29.09  tff(decl_55271, type, fn_myosin_2: $i > $i).
% 29.22/29.09  tff(decl_55272, type, fn_myosin_1: $i > $i).
% 29.22/29.09  tff(decl_55273, type, 'Myosin-Filament': $i).
% 29.22/29.09  tff(decl_55274, type, 'Myosin filament are made up of Myosin protein. They are present in muscle cells.': $i).
% 29.22/29.09  tff(decl_55275, type, 'filament of myosin': $i).
% 29.22/29.09  tff(decl_55276, type, 'myosin filament': $i).
% 29.22/29.09  tff(decl_55277, type, 'myosin-filament': $i).
% 29.22/29.09  tff(decl_55278, type, fn_myosin_filament_1: $i > $i).
% 29.22/29.09  tff(decl_55279, type, fn_myosin_filament_5: $i > $i).
% 29.22/29.09  tff(decl_55280, type, fn_myosin_filament_6: $i > $i).
% 29.22/29.09  tff(decl_55281, type, fn_myosin_filament_7: $i > $i).
% 29.22/29.09  tff(decl_55282, type, myosin_0: $i).
% 29.22/29.09  tff(decl_55283, type, myotonia_1: $i > $o).
% 29.22/29.09  tff(decl_55284, type, 'Myotonia': $i).
% 29.22/29.09  tff(decl_55285, type, 'A state of increased muscle tension or rigidity. During sexual arousal in humans, some tissues exhibit myotonia.': $i).
% 29.22/29.09  tff(decl_55286, type, myotonia: $i).
% 29.22/29.09  tff(decl_55287, type, 'Myriapod': $i).
% 29.22/29.09  tff(decl_55288, type, 'A terrestrial arthropod with many similar-looking body segments and either one or two pairs of legs per segment. Examples include centipedes and millipedes.': $i).
% 29.22/29.09  tff(decl_55289, type, myriapod: $i).
% 29.22/29.09  tff(decl_55290, type, 'Myxobacterium': $i).
% 29.22/29.09  tff(decl_55291, type, 'Group of soil dwelling, decomposing bacteria.': $i).
% 29.22/29.09  tff(decl_55292, type, 'slime bacteria': $i).
% 29.22/29.09  tff(decl_55293, type, myxobacterium: $i).
% 29.22/29.09  tff(decl_55294, type, fn_myxobacterium_1: $i > $i).
% 29.22/29.09  tff(decl_55295, type, n_minus_3_1: $i > $o).
% 29.22/29.09  tff(decl_55296, type, 'N-Minus-3': $i).
% 29.22/29.09  tff(decl_55297, type, 'The nitride ion of nitrogen.': $i).
% 29.22/29.09  tff(decl_55298, type, nitride: $i).
% 29.22/29.09  tff(decl_55299, type, 'n minus 3': $i).
% 29.22/29.09  tff(decl_55300, type, 'n-minus-3': $i).
% 29.22/29.09  tff(decl_55301, type, fn_n_minus_3_1: $i > $i).
% 29.22/29.09  tff(decl_55302, type, fn_n_minus_3_2: $i > $i).
% 29.22/29.09  tff(decl_55303, type, fn_n_minus_3_3: $i > $i).
% 29.22/29.09  tff(decl_55304, type, fn_n_minus_3_4: $i > $i).
% 29.22/29.09  tff(decl_55305, type, fn_n_minus_3_5: $i > $i).
% 29.22/29.09  tff(decl_55306, type, fn_n_minus_3_6: $i > $i).
% 29.22/29.09  tff(decl_55307, type, 'N2-Gas': $i).
% 29.22/29.09  tff(decl_55308, type, 'Diatomic nitrogen gas, which is the elemental form of nitrogen that makes up most of the Earth\\s atmosphere.': $i).
% 29.22/29.09  tff(decl_55309, type, 'n2 gas': $i).
% 29.22/29.09  tff(decl_55310, type, 'n2-gas': $i).
% 29.22/29.09  tff(decl_55311, type, na_substance_1: $i > $o).
% 29.22/29.09  tff(decl_55312, type, 'Na-Substance': $i).
% 29.22/29.09  tff(decl_55313, type, 'substance of na': $i).
% 29.22/29.09  tff(decl_55314, type, 'na substance': $i).
% 29.22/29.09  tff(decl_55315, type, 'na-substance': $i).
% 29.22/29.09  tff(decl_55316, type, fn_na_substance_1: $i > $i).
% 29.22/29.09  tff(decl_55317, type, 'NAD-Plus': $i).
% 29.22/29.09  tff(decl_55318, type, 'Nicotinamide adenine dinucleotide, abbreviated NAD+, is a coenzyme found in all living cells. The compound is a dinucleotide, since it consists of two nucleotides joined through their phosphate groups, with one nucleotide containing an adenine base and the other containing nicotinamide.': $i).
% 29.22/29.09  tff(decl_55319, type, nad: $i).
% 29.22/29.09  tff(decl_55320, type, 'nad molecule': $i).
% 29.22/29.09  tff(decl_55321, type, 'nicotinamide adenine dinucleotide': $i).
% 29.22/29.09  tff(decl_55322, type, 'nad+': $i).
% 29.22/29.09  tff(decl_55323, type, 'plus of nad': $i).
% 29.22/29.09  tff(decl_55324, type, 'nad plus': $i).
% 29.22/29.09  tff(decl_55325, type, 'nad-plus': $i).
% 29.22/29.09  tff(decl_55326, type, fn_nad_plus_13: $i > $i).
% 29.22/29.09  tff(decl_55327, type, fn_nad_plus_12: $i > $i).
% 29.22/29.09  tff(decl_55328, type, 'The reduced form of NAD+ is NADH. NADH acts as a reducing agent in most of the chemical reactions.': $i).
% 29.22/29.09  tff(decl_55329, type, 'nicotinamide-adenine-dinucleotide': $i).
% 29.22/29.09  tff(decl_55330, type, nadh: $i).
% 29.22/29.09  tff(decl_55331, type, fn_nadh_3: $i > $i).
% 29.22/29.09  tff(decl_55332, type, fn_nadh_4: $i > $i).
% 29.22/29.09  tff(decl_55333, type, 'NADP-Plus': $i).
% 29.22/29.09  tff(decl_55334, type, 'A coenzyme that accepts and temporarily stores energized electrons from the light reactions.': $i).
% 29.22/29.09  tff(decl_55335, type, 'nicotinamide adenine dinucleotide phosphate': $i).
% 29.22/29.09  tff(decl_55336, type, 'nicotinamide-adenine-dinucleotide-phosphate': $i).
% 29.22/29.09  tff(decl_55337, type, 'plus of nadp': $i).
% 29.22/29.09  tff(decl_55338, type, 'nadp plus': $i).
% 29.22/29.09  tff(decl_55339, type, 'nadp-plus': $i).
% 29.22/29.09  tff(decl_55340, type, fn_nadp_plus_1: $i > $i).
% 29.22/29.09  tff(decl_55341, type, fn_nadp_plus_4: $i > $i).
% 29.22/29.09  tff(decl_55342, type, fn_nadp_plus_5: $i > $i).
% 29.22/29.09  tff(decl_55343, type, fn_nadp_plus_6: $i > $i).
% 29.22/29.09  tff(decl_55344, type, fn_nadp_plus_7: $i > $i).
% 29.22/29.09  tff(decl_55345, type, fn_nadp_plus_8: $i > $i).
% 29.22/29.09  tff(decl_55346, type, fn_nadp_plus_9: $i > $i).
% 29.22/29.09  tff(decl_55347, type, fn_nadp_plus_10: $i > $i).
% 29.22/29.09  tff(decl_55348, type, fn_nadp_plus_11: $i > $i).
% 29.22/29.09  tff(decl_55349, type, fn_nadp_plus_12: $i > $i).
% 29.22/29.09  tff(decl_55350, type, fn_nadp_plus_13: $i > $i).
% 29.22/29.09  tff(decl_55351, type, fn_nadp_plus_3: $i > $i).
% 29.22/29.09  tff(decl_55352, type, fn_nadp_plus_2: $i > $i).
% 29.22/29.09  tff(decl_55353, type, 'NADP-Plus-Reductase': $i).
% 29.22/29.09  tff(decl_55354, type, 'An enzyme used during photosynthesis that adds high energy electrons to NADP+ to reduce it to NADPH.': $i).
% 29.22/29.09  tff(decl_55355, type, 'nadp plus reductase': $i).
% 29.22/29.09  tff(decl_55356, type, 'nadp-plus-reductase': $i).
% 29.22/29.09  tff(decl_55357, type, fn_nadp_plus_reductase_3: $i > $i).
% 29.22/29.09  tff(decl_55358, type, fn_nadp_plus_reductase_4: $i > $i).
% 29.22/29.09  tff(decl_55359, type, fn_nadp_plus_reductase_5: $i > $i).
% 29.22/29.09  tff(decl_55360, type, fn_nadp_plus_reductase_6: $i > $i).
% 29.22/29.09  tff(decl_55361, type, fn_nadp_plus_reductase_7: $i > $i).
% 29.22/29.09  tff(decl_55362, type, fn_nadp_plus_reductase_8: $i > $i).
% 29.22/29.09  tff(decl_55363, type, fn_nadp_plus_reductase_9: $i > $i).
% 29.22/29.09  tff(decl_55364, type, fn_nadp_plus_reductase_10: $i > $i).
% 29.22/29.09  tff(decl_55365, type, fn_nadp_plus_reductase_11: $i > $i).
% 29.22/29.09  tff(decl_55366, type, fn_nadp_plus_reductase_12: $i > $i).
% 29.22/29.09  tff(decl_55367, type, fn_nadp_plus_reductase_13: $i > $i).
% 29.22/29.09  tff(decl_55368, type, fn_nadp_plus_reductase_14: $i > $i).
% 29.22/29.09  tff(decl_55369, type, fn_nadp_plus_reductase_15: $i > $i).
% 29.22/29.09  tff(decl_55370, type, fn_nadp_plus_reductase_2: $i > $i).
% 29.22/29.09  tff(decl_55371, type, fn_nadp_plus_reductase_1: $i > $i).
% 29.22/29.09  tff(decl_55372, type, 'NADPH': $i).
% 29.22/29.09  tff(decl_55373, type, 'A coenzyme that is used to carry high energy electrons during photosynthesis.': $i).
% 29.22/29.09  tff(decl_55374, type, 'nadph molecule': $i).
% 29.22/29.09  tff(decl_55375, type, fn_nadph_4: $i > $i).
% 29.22/29.09  tff(decl_55376, type, fn_nadph_5: $i > $i).
% 29.22/29.09  tff(decl_55377, type, fn_nadph_6: $i > $i).
% 29.22/29.09  tff(decl_55378, type, fn_nadph_7: $i > $i).
% 29.22/29.09  tff(decl_55379, type, fn_nadph_8: $i > $i).
% 29.22/29.09  tff(decl_55380, type, fn_nadph_9: $i > $i).
% 29.22/29.09  tff(decl_55381, type, fn_nadph_10: $i > $i).
% 29.22/29.09  tff(decl_55382, type, fn_nadph_11: $i > $i).
% 29.22/29.09  tff(decl_55383, type, fn_nadph_12: $i > $i).
% 29.22/29.09  tff(decl_55384, type, fn_nadph_13: $i > $i).
% 29.22/29.09  tff(decl_55385, type, fn_nadph_2: $i > $i).
% 29.22/29.09  tff(decl_55386, type, fn_nadph_3: $i > $i).
% 29.22/29.09  tff(decl_55387, type, national_park_1: $i > $o).
% 29.22/29.09  tff(decl_55388, type, 'National-Park': $i).
% 29.22/29.09  tff(decl_55389, type, 'A reserve of natural or semi-natural land, declared or owned by a government, set aside for human recreation and enjoyment, animal and environmental protection and restricted from most development.': $i).
% 29.22/29.09  tff(decl_55390, type, 'park of national': $i).
% 29.22/29.09  tff(decl_55391, type, 'national park': $i).
% 29.22/29.09  tff(decl_55392, type, 'national-park': $i).
% 29.22/29.09  tff(decl_55393, type, reserve_1: $i > $o).
% 29.22/29.09  tff(decl_55394, type, nature_reserve_1: $i > $o).
% 29.22/29.09  tff(decl_55395, type, zoned_reserve_1: $i > $o).
% 29.22/29.09  tff(decl_55396, type, native_american_1: $i > $o).
% 29.22/29.09  tff(decl_55397, type, 'Native-American': $i).
% 29.22/29.09  tff(decl_55398, type, 'Any of the indigenous peoples of North and South America.': $i).
% 29.22/29.09  tff(decl_55399, type, 'american of native': $i).
% 29.22/29.09  tff(decl_55400, type, 'native american': $i).
% 29.22/29.09  tff(decl_55401, type, 'native-american': $i).
% 29.22/29.09  tff(decl_55402, type, 'Natural-Family-Planning': $i).
% 29.22/29.09  tff(decl_55403, type, 'A method of contraception that involves avoiding sexual intercourse at times that conception is most likely to occur.': $i).
% 29.22/29.09  tff(decl_55404, type, 'natural family planning': $i).
% 29.22/29.09  tff(decl_55405, type, 'natural-family-planning': $i).
% 29.22/29.09  tff(decl_55406, type, natural_gas_1: $i > $o).
% 29.22/29.09  tff(decl_55407, type, 'Natural-Gas': $i).
% 29.22/29.09  tff(decl_55408, type, 'Gaseous hydrocarbon which occurs naturally in the ground, consisting primarily of methane.': $i).
% 29.22/29.09  tff(decl_55409, type, 'gas of natural': $i).
% 29.22/29.09  tff(decl_55410, type, 'natural gas': $i).
% 29.22/29.09  tff(decl_55411, type, 'natural-gas': $i).
% 29.22/29.09  tff(decl_55412, type, fn_natural_gas_1: $i > $i).
% 29.22/29.09  tff(decl_55413, type, 'Natural-Killer-Cell': $i).
% 29.22/29.09  tff(decl_55414, type, 'A type of leukocyte that kills early tumor cells and cells that are infected with viruses. Natural killer cells are an important component of innate immunity.': $i).
% 29.22/29.09  tff(decl_55415, type, 'natural killer cell': $i).
% 29.22/29.09  tff(decl_55416, type, 'natural-killer-cell': $i).
% 29.22/29.09  tff(decl_55417, type, 'Natural-Language': $i).
% 29.22/29.09  tff(decl_55418, type, 'natural language': $i).
% 29.22/29.09  tff(decl_55419, type, natural_language: $i).
% 29.22/29.09  tff(decl_55420, type, tongue: $i).
% 29.22/29.09  tff(decl_55421, type, 'language of natural': $i).
% 29.22/29.09  tff(decl_55422, type, 'natural-language': $i).
% 29.22/29.09  tff(decl_55423, type, 'Natural-Selection': $i).
% 29.22/29.09  tff(decl_55424, type, 'The gradual, non-random process by which certain inherited characteristics are passed to future generations based on the fitness of their bearers compared to the bearers of other characteristics.': $i).
% 29.22/29.09  tff(decl_55425, type, 'selection of natural': $i).
% 29.22/29.09  tff(decl_55426, type, 'natural selection': $i).
% 29.22/29.09  tff(decl_55427, type, 'natural-selection': $i).
% 29.22/29.09  tff(decl_55428, type, nature_1: $i > $o).
% 29.22/29.09  tff(decl_55429, type, 'Nature': $i).
% 29.22/29.09  tff(decl_55430, type, 'The external world in its entirety.': $i).
% 29.22/29.09  tff(decl_55431, type, nature: $i).
% 29.22/29.09  tff(decl_55432, type, 'Nature-Reserve': $i).
% 29.22/29.09  tff(decl_55433, type, 'A region set aside for wildlife in order to help perserve endangered organisms and ecosystems, and to maintain biodiversity.': $i).
% 29.22/29.09  tff(decl_55434, type, 'natural preserves': $i).
% 29.22/29.09  tff(decl_55435, type, 'natural-preserves': $i).
% 29.22/29.09  tff(decl_55436, type, 'reserve of nature': $i).
% 29.22/29.09  tff(decl_55437, type, 'nature reserve': $i).
% 29.22/29.09  tff(decl_55438, type, 'nature-reserve': $i).
% 29.22/29.09  tff(decl_55439, type, 'Navigation': $i).
% 29.22/29.09  tff(decl_55440, type, 'A complex behavior in which an animal determines its present location relative to other locations in addition to detecting compass direction (orientation).': $i).
% 29.22/29.09  tff(decl_55441, type, navigate: $i).
% 29.22/29.09  tff(decl_55442, type, navigation: $i).
% 29.22/29.09  tff(decl_55443, type, 'Neanderthal': $i).
% 29.22/29.09  tff(decl_55444, type, 'Hominids who lived throughout Europe from about 200,000 to 40,000 years ago. Fossilized skulls indicate that Neanderthals had brains as large as ours, though somewhat different in shape.': $i).
% 29.22/29.09  tff(decl_55445, type, neanderthal: $i).
% 29.22/29.09  tff(decl_55446, type, 'Needle': $i).
% 29.22/29.09  tff(decl_55447, type, 'Long linear instrument with a pointy end.': $i).
% 29.22/29.09  tff(decl_55448, type, negation_node_1: $i > $o).
% 29.22/29.09  tff(decl_55449, type, 'Negation-Node': $i).
% 29.22/29.09  tff(decl_55450, type, 'node of negation': $i).
% 29.22/29.09  tff(decl_55451, type, 'negation node': $i).
% 29.22/29.09  tff(decl_55452, type, 'negation-node': $i).
% 29.22/29.09  tff(decl_55453, type, 'Negative-Feedback': $i).
% 29.22/29.09  tff(decl_55454, type, 'One of the primary mechanisms of homeostasis, in which a change in a variable causes a response that counteracts the initial change.': $i).
% 29.22/29.09  tff(decl_55455, type, 'feedback of negative': $i).
% 29.22/29.09  tff(decl_55456, type, 'Negative-Gene-Regulation': $i).
% 29.22/29.09  tff(decl_55457, type, 'Gene regulation mediated by factors that block, turn down or turn off transcription.': $i).
% 29.22/29.09  tff(decl_55458, type, 'negative gene regulation': $i).
% 29.22/29.09  tff(decl_55459, type, 'negative-gene-regulation': $i).
% 29.22/29.09  tff(decl_55460, type, fn_negative_gene_regulation_1: $i > $i).
% 29.22/29.09  tff(decl_55461, type, fn_negative_gene_regulation_2: $i > $i).
% 29.22/29.09  tff(decl_55462, type, fn_negative_gene_regulation_3: $i > $i).
% 29.22/29.09  tff(decl_55463, type, negative_pressure_breathing_1: $i > $o).
% 29.22/29.09  tff(decl_55464, type, 'Negative-Pressure-Breathing': $i).
% 29.22/29.09  tff(decl_55465, type, 'In mammals, a type of breathing in which contraction of the diaphragm increases the volume of the thoracic cavity and pulls air into the lungs.': $i).
% 29.22/29.09  tff(decl_55466, type, 'negative pressure breathing': $i).
% 29.22/29.09  tff(decl_55467, type, 'negative-pressure-breathing': $i).
% 29.22/29.09  tff(decl_55468, type, positive_pressure_breathing_1: $i > $o).
% 29.22/29.09  tff(decl_55469, type, 'Negatively-Charged-Region': $i).
% 29.22/29.09  tff(decl_55470, type, 'The region is concentrated with negative charges.': $i).
% 29.22/29.09  tff(decl_55471, type, 'negatively charged region': $i).
% 29.22/29.09  tff(decl_55472, type, 'negatively-charged-region': $i).
% 29.22/29.09  tff(decl_55473, type, fn_negatively_charged_region_3: $i > $i).
% 29.22/29.09  tff(decl_55474, type, fn_negatively_charged_region_4: $i > $i).
% 29.22/29.09  tff(decl_55475, type, fn_negatively_charged_region_5: $i > $i).
% 29.22/29.09  tff(decl_55476, type, fn_negatively_charged_region_6: $i > $i).
% 29.22/29.09  tff(decl_55477, type, nematocyst_1: $i > $o).
% 29.22/29.09  tff(decl_55478, type, 'Nematocyst': $i).
% 29.22/29.09  tff(decl_55479, type, 'In some cnidarian cells, a coiled harpoon-like thread inside a capsule called a cnida. When discharged, a nematocyst penetrates the flesh of predators or prey and injects toxins.': $i).
% 29.22/29.09  tff(decl_55480, type, nematocyst: $i).
% 29.22/29.09  tff(decl_55481, type, fn_nematocyst_1: $i > $i).
% 29.22/29.09  tff(decl_55482, type, fn_nematocyst_2: $i > $i).
% 29.22/29.09  tff(decl_55483, type, fn_nematocyst_3: $i > $i).
% 29.22/29.09  tff(decl_55484, type, 'Nematode': $i).
% 29.22/29.09  tff(decl_55485, type, 'Also called roundworms. Nematodes are small unsegmented worms with a rounded body tapered at both ends. Most nematodes are free-living but some are parasitic.': $i).
% 29.22/29.09  tff(decl_55486, type, roundworms: $i).
% 29.22/29.09  tff(decl_55487, type, nematoda: $i).
% 29.22/29.09  tff(decl_55488, type, nematode: $i).
% 29.22/29.09  tff(decl_55489, type, fn_nematode_2: $i > $i).
% 29.22/29.09  tff(decl_55490, type, nematode_homeotic_gene_1: $i > $o).
% 29.22/29.09  tff(decl_55491, type, 'Nematode-Homeotic-Gene': $i).
% 29.22/29.09  tff(decl_55492, type, 'Homeotic gene present in nematodes.': $i).
% 29.22/29.09  tff(decl_55493, type, 'nematode homeotic gene': $i).
% 29.22/29.09  tff(decl_55494, type, 'nematode-homeotic-gene': $i).
% 29.22/29.09  tff(decl_55495, type, 'Nemertea': $i).
% 29.22/29.09  tff(decl_55496, type, 'A phylum of triploblastic, non-segmented, invertebrate animals also known as ribbon worms or proboscis worms.': $i).
% 29.22/29.09  tff(decl_55497, type, 'ribbon worms': $i).
% 29.22/29.09  tff(decl_55498, type, 'ribbon-worms': $i).
% 29.22/29.09  tff(decl_55499, type, ribbonworms: $i).
% 29.22/29.09  tff(decl_55500, type, ribbonworm: $i).
% 29.22/29.09  tff(decl_55501, type, 'proboscis worm': $i).
% 29.22/29.09  tff(decl_55502, type, 'proboscis-worm': $i).
% 29.22/29.09  tff(decl_55503, type, 'ribbon worm': $i).
% 29.22/29.09  tff(decl_55504, type, 'ribbon-worm': $i).
% 29.22/29.09  tff(decl_55505, type, nemertean: $i).
% 29.22/29.09  tff(decl_55506, type, nemertea: $i).
% 29.22/29.09  tff(decl_55507, type, neodymium_1: $i > $o).
% 29.22/29.09  tff(decl_55508, type, 'Neodymium': $i).
% 29.22/29.09  tff(decl_55509, type, 'Neodymium is a metal atom with atomic number 60. It is represented by the symbol Nd.': $i).
% 29.22/29.09  tff(decl_55510, type, neodymium: $i).
% 29.22/29.09  tff(decl_55511, type, nd: $i).
% 29.22/29.09  tff(decl_55512, type, fn_neodymium_3: $i > $i).
% 29.22/29.09  tff(decl_55513, type, fn_neodymium_4: $i > $i).
% 29.22/29.09  tff(decl_55514, type, fn_neodymium_5: $i > $i).
% 29.22/29.09  tff(decl_55515, type, fn_neodymium_9: $i > $i).
% 29.22/29.09  tff(decl_55516, type, fn_neodymium_10: $i > $i).
% 29.22/29.09  tff(decl_55517, type, fn_neodymium_11: $i > $i).
% 29.22/29.09  tff(decl_55518, type, fn_neodymium_12: $i > $i).
% 29.22/29.09  tff(decl_55519, type, "60": $i).
% 29.22/29.09  tff(decl_55520, type, "1.14": $i).
% 29.22/29.09  tff(decl_55521, type, "144": $i).
% 29.22/29.09  tff(decl_55522, type, "144.2": $i).
% 29.22/29.09  tff(decl_55523, type, fn_neodymium_7: $i > $i).
% 29.22/29.09  tff(decl_55524, type, fn_neodymium_8: $i > $i).
% 29.22/29.09  tff(decl_55525, type, fn_neodymium_6: $i > $i).
% 29.22/29.09  tff(decl_55526, type, 'Neon': $i).
% 29.22/29.09  tff(decl_55527, type, 'Neon is a non metal atom with atomic number 10. It is represented by the symbol Ne.': $i).
% 29.22/29.09  tff(decl_55528, type, 'Ne': $i).
% 29.22/29.09  tff(decl_55529, type, neon: $i).
% 29.22/29.09  tff(decl_55530, type, fn_neon_4: $i > $i).
% 29.22/29.09  tff(decl_55531, type, fn_neon_5: $i > $i).
% 29.22/29.09  tff(decl_55532, type, fn_neon_6: $i > $i).
% 29.22/29.09  tff(decl_55533, type, fn_neon_7: $i > $i).
% 29.22/29.09  tff(decl_55534, type, fn_neon_11: $i > $i).
% 29.22/29.09  tff(decl_55535, type, fn_neon_12: $i > $i).
% 29.22/29.09  tff(decl_55536, type, fn_neon_13: $i > $i).
% 29.22/29.09  tff(decl_55537, type, fn_neon_14: $i > $i).
% 29.22/29.09  tff(decl_55538, type, "20.18": $i).
% 29.22/29.09  tff(decl_55539, type, fn_neon_9: $i > $i).
% 29.22/29.09  tff(decl_55540, type, fn_neon_8: $i > $i).
% 29.22/29.09  tff(decl_55541, type, fn_neon_10: $i > $i).
% 29.22/29.09  tff(decl_55542, type, 'Nephron': $i).
% 29.22/29.09  tff(decl_55543, type, 'The functional unit of the vertebrate kidney.': $i).
% 29.22/29.09  tff(decl_55544, type, nephron: $i).
% 29.22/29.09  tff(decl_55545, type, neptunium_1: $i > $o).
% 29.22/29.09  tff(decl_55546, type, 'Neptunium': $i).
% 29.22/29.09  tff(decl_55547, type, 'Neptunium is a metal atom with atomic number 93. It is represented by the symbol Np.': $i).
% 29.22/29.09  tff(decl_55548, type, neptunium: $i).
% 29.22/29.09  tff(decl_55549, type, np: $i).
% 29.22/29.09  tff(decl_55550, type, fn_neptunium_3: $i > $i).
% 29.22/29.09  tff(decl_55551, type, fn_neptunium_4: $i > $i).
% 29.22/29.09  tff(decl_55552, type, fn_neptunium_5: $i > $i).
% 29.22/29.09  tff(decl_55553, type, fn_neptunium_9: $i > $i).
% 29.22/29.09  tff(decl_55554, type, fn_neptunium_10: $i > $i).
% 29.22/29.09  tff(decl_55555, type, fn_neptunium_11: $i > $i).
% 29.22/29.09  tff(decl_55556, type, fn_neptunium_12: $i > $i).
% 29.22/29.09  tff(decl_55557, type, "1.36": $i).
% 29.22/29.09  tff(decl_55558, type, "237": $i).
% 29.22/29.09  tff(decl_55559, type, fn_neptunium_7: $i > $i).
% 29.22/29.09  tff(decl_55560, type, fn_neptunium_8: $i > $i).
% 29.22/29.09  tff(decl_55561, type, fn_neptunium_6: $i > $i).
% 29.22/29.09  tff(decl_55562, type, 'Neritic-Zone': $i).
% 29.22/29.09  tff(decl_55563, type, 'The relatively shallow waters of the ocean lying over the continental shelf.': $i).
% 29.22/29.09  tff(decl_55564, type, 'neritic zone': $i).
% 29.22/29.09  tff(decl_55565, type, 'neritic-zone': $i).
% 29.22/29.09  tff(decl_55566, type, 'Nerve': $i).
% 29.22/29.09  tff(decl_55567, type, 'A cable-like bundle of axons wrapped in connective tissue.': $i).
% 29.22/29.09  tff(decl_55568, type, 'neuron bundle': $i).
% 29.22/29.09  tff(decl_55569, type, nerve: $i).
% 29.22/29.09  tff(decl_55570, type, 'Nerve-Cell': $i).
% 29.22/29.09  tff(decl_55571, type, 'A neuron also known as a neurone or nerve cell  is an electrically excitable cell that processes and transmits information by electrical and chemical signaling.': $i).
% 29.22/29.09  tff(decl_55572, type, neuron: $i).
% 29.22/29.09  tff(decl_55573, type, neurone: $i).
% 29.22/29.09  tff(decl_55574, type, 'cell of nerve': $i).
% 29.22/29.09  tff(decl_55575, type, 'nerve cell': $i).
% 29.22/29.09  tff(decl_55576, type, 'nerve-cell': $i).
% 29.22/29.09  tff(decl_55577, type, fn_nerve_cell_1: $i > $i).
% 29.22/29.09  tff(decl_55578, type, fn_nerve_cell_2: $i > $i).
% 29.22/29.09  tff(decl_55579, type, fn_nerve_cell_3: $i > $i).
% 29.22/29.09  tff(decl_55580, type, fn_nerve_cell_4: $i > $i).
% 29.22/29.09  tff(decl_55581, type, fn_nerve_cell_5: $i > $i).
% 29.22/29.09  tff(decl_55582, type, fn_nerve_cell_6: $i > $i).
% 29.22/29.09  tff(decl_55583, type, fn_nerve_cell_7: $i > $i).
% 29.22/29.09  tff(decl_55584, type, fn_nerve_cell_8: $i > $i).
% 29.22/29.09  tff(decl_55585, type, fn_nerve_cell_9: $i > $i).
% 29.22/29.09  tff(decl_55586, type, fn_nerve_cell_10: $i > $i).
% 29.22/29.09  tff(decl_55587, type, fn_nerve_cell_12: $i > $i).
% 29.22/29.09  tff(decl_55588, type, fn_nerve_cell_13: $i > $i).
% 29.22/29.09  tff(decl_55589, type, fn_nerve_cell_14: $i > $i).
% 29.22/29.09  tff(decl_55590, type, fn_nerve_cell_16: $i > $i).
% 29.22/29.09  tff(decl_55591, type, fn_nerve_cell_17: $i > $i).
% 29.22/29.09  tff(decl_55592, type, fn_nerve_cell_18: $i > $i).
% 29.22/29.09  tff(decl_55593, type, fn_nerve_cell_19: $i > $i).
% 29.22/29.09  tff(decl_55594, type, fn_nerve_cell_20: $i > $i).
% 29.22/29.09  tff(decl_55595, type, fn_nerve_cell_23: $i > $i).
% 29.22/29.09  tff(decl_55596, type, fn_nerve_cell_25: $i > $i).
% 29.22/29.09  tff(decl_55597, type, fn_nerve_cell_26: $i > $i).
% 29.22/29.09  tff(decl_55598, type, fn_nerve_cell_27: $i > $i).
% 29.22/29.09  tff(decl_55599, type, fn_nerve_cell_28: $i > $i).
% 29.22/29.09  tff(decl_55600, type, fn_nerve_cell_29: $i > $i).
% 29.22/29.09  tff(decl_55601, type, fn_nerve_cell_33: $i > $i).
% 29.22/29.09  tff(decl_55602, type, fn_nerve_cell_34: $i > $i).
% 29.22/29.09  tff(decl_55603, type, fn_nerve_cell_38: $i > $i).
% 29.22/29.09  tff(decl_55604, type, fn_nerve_cell_40: $i > $i).
% 29.22/29.09  tff(decl_55605, type, fn_nerve_cell_45: $i > $i).
% 29.22/29.09  tff(decl_55606, type, fn_nerve_cell_46: $i > $i).
% 29.22/29.09  tff(decl_55607, type, fn_nerve_cell_47: $i > $i).
% 29.22/29.09  tff(decl_55608, type, fn_nerve_cell_48: $i > $i).
% 29.22/29.09  tff(decl_55609, type, fn_nerve_cell_49: $i > $i).
% 29.22/29.09  tff(decl_55610, type, fn_nerve_cell_52: $i > $i).
% 29.22/29.09  tff(decl_55611, type, fn_nerve_cell_53: $i > $i).
% 29.22/29.09  tff(decl_55612, type, fn_nerve_cell_56: $i > $i).
% 29.22/29.09  tff(decl_55613, type, fn_nerve_cell_57: $i > $i).
% 29.22/29.09  tff(decl_55614, type, fn_nerve_cell_58: $i > $i).
% 29.22/29.09  tff(decl_55615, type, fn_nerve_cell_59: $i > $i).
% 29.22/29.09  tff(decl_55616, type, fn_nerve_cell_60: $i > $i).
% 29.22/29.09  tff(decl_55617, type, fn_sodium_potassium_pump_1: $i > $i).
% 29.22/29.09  tff(decl_55618, type, fn_sodium_potassium_pump_40: $i > $i).
% 29.22/29.09  tff(decl_55619, type, fn_nerve_cell_54: $i > $i).
% 29.22/29.09  tff(decl_55620, type, fn_nerve_cell_55: $i > $i).
% 29.22/29.09  tff(decl_55621, type, 'Nerve-Circuit': $i).
% 29.22/29.09  tff(decl_55622, type, 'A series of nerve cells that pass signals from one to the next.': $i).
% 29.22/29.09  tff(decl_55623, type, 'circuit of nerve': $i).
% 29.22/29.09  tff(decl_55624, type, 'nerve circuit': $i).
% 29.22/29.09  tff(decl_55625, type, 'nerve-circuit': $i).
% 29.22/29.09  tff(decl_55626, type, nerve_cord_1: $i > $o).
% 29.22/29.09  tff(decl_55627, type, 'Nerve-Cord': $i).
% 29.22/29.09  tff(decl_55628, type, 'A large collection of nerve cell bodies and fibers typically running along the long axis of an organism.': $i).
% 29.22/29.09  tff(decl_55629, type, 'cord of nerve': $i).
% 29.22/29.09  tff(decl_55630, type, 'nerve cord': $i).
% 29.22/29.09  tff(decl_55631, type, 'nerve-cord': $i).
% 29.22/29.09  tff(decl_55632, type, nerve_growth_factor_1: $i > $o).
% 29.22/29.09  tff(decl_55633, type, 'Nerve-Growth-Factor': $i).
% 29.22/29.09  tff(decl_55634, type, 'A local regulator involved in development of embryonic nerve cells, white blood cells, and many other kinds of cells.': $i).
% 29.22/29.09  tff(decl_55635, type, ngf: $i).
% 29.22/29.09  tff(decl_55636, type, 'nerve growth factor': $i).
% 29.22/29.09  tff(decl_55637, type, 'nerve growth-factor': $i).
% 29.22/29.09  tff(decl_55638, type, 'nerve-growth-factor': $i).
% 29.22/29.09  tff(decl_55639, type, fn_nerve_growth_factor_1: $i > $i).
% 29.22/29.09  tff(decl_55640, type, fn_nerve_growth_factor_2: $i > $i).
% 29.22/29.09  tff(decl_55641, type, fn_nerve_growth_factor_3: $i > $i).
% 29.22/29.09  tff(decl_55642, type, nerve_impulse_1: $i > $o).
% 29.22/29.09  tff(decl_55643, type, 'Nerve-Impulse': $i).
% 29.22/29.09  tff(decl_55644, type, 'The electrochemical signal sent by a neuron.': $i).
% 29.22/29.09  tff(decl_55645, type, 'impulse of nerve': $i).
% 29.22/29.09  tff(decl_55646, type, 'nerve impulse': $i).
% 29.22/29.09  tff(decl_55647, type, 'nerve-impulse': $i).
% 29.22/29.09  tff(decl_55648, type, 'Nerve-Net': $i).
% 29.22/29.09  tff(decl_55649, type, 'A diffuse network of nerves covering the surface of the body; characteristic of animals with radial symmetry, such as cnidarians.': $i).
% 29.22/29.09  tff(decl_55650, type, 'net of nerve': $i).
% 29.22/29.09  tff(decl_55651, type, 'nerve net': $i).
% 29.22/29.09  tff(decl_55652, type, 'nerve-net': $i).
% 29.22/29.09  tff(decl_55653, type, 'Nerve-Related-Intercellular-Process': $i).
% 29.22/29.09  tff(decl_55654, type, 'Intercellular process related to the functioning of the nervous system.': $i).
% 29.22/29.09  tff(decl_55655, type, 'nerve related intercellular process': $i).
% 29.22/29.09  tff(decl_55656, type, 'nerve-related-intercellular-process': $i).
% 29.22/29.09  tff(decl_55657, type, 'Nervous-Organ': $i).
% 29.22/29.09  tff(decl_55658, type, 'Organ which is part of the nervous system of animals.': $i).
% 29.22/29.09  tff(decl_55659, type, 'nervous organ': $i).
% 29.22/29.09  tff(decl_55660, type, 'nervous-organ': $i).
% 29.22/29.09  tff(decl_55661, type, 'Nervous-System': $i).
% 29.22/29.09  tff(decl_55662, type, 'In animals, the system of communication involving neurons that receive information from sensory receptors and relay electrochemical signals to muscles, glands, and other organs. The nervous system works with the endocrine system to maintain homeostasis within the body.': $i).
% 29.22/29.09  tff(decl_55663, type, 'nervous system': $i).
% 29.22/29.09  tff(decl_55664, type, 'nervous-system': $i).
% 29.22/29.09  tff(decl_55665, type, nervous_system_development_1: $i > $o).
% 29.22/29.09  tff(decl_55666, type, 'Nervous-System-Development': $i).
% 29.22/29.09  tff(decl_55667, type, 'The process of development of the nervous system in animals. This process is usually complete by birth or hatching of the organism.': $i).
% 29.22/29.09  tff(decl_55668, type, 'nervous system development': $i).
% 29.22/29.09  tff(decl_55669, type, 'nervous-system-development': $i).
% 29.22/29.09  tff(decl_55670, type, fn_nervous_system_development_1: $i > $i).
% 29.22/29.09  tff(decl_55671, type, fn_nervous_system_development_2: $i > $i).
% 29.22/29.09  tff(decl_55672, type, fn_nervous_system_development_3: $i > $i).
% 29.22/29.09  tff(decl_55673, type, nervous_system_development_in_vertebrate_1: $i > $o).
% 29.22/29.09  tff(decl_55674, type, 'Nervous-System-Development-In-Vertebrate': $i).
% 29.22/29.09  tff(decl_55675, type, 'The formation of the nervous system is essentially complete by birth or hatching of the vertebrate organism.': $i).
% 29.22/29.09  tff(decl_55676, type, 'nervous system development in vertebrate': $i).
% 29.22/29.09  tff(decl_55677, type, 'nervous-system-development-in-vertebrate': $i).
% 29.22/29.09  tff(decl_55678, type, fn_nervous_system_development_in_vertebrate_1: $i > $i).
% 29.22/29.09  tff(decl_55679, type, fn_nervous_system_development_in_vertebrate_2: $i > $i).
% 29.22/29.09  tff(decl_55680, type, 'Nervous-Tissue': $i).
% 29.22/29.09  tff(decl_55681, type, 'Tissue that makes up the cells and organs of the nervous system. Neurons and glial cells are made of nervous tissue.': $i).
% 29.22/29.09  tff(decl_55682, type, 'nervous tissue': $i).
% 29.22/29.09  tff(decl_55683, type, 'nervous-tissue': $i).
% 29.22/29.09  tff(decl_55684, type, nest_1: $i > $o).
% 29.22/29.09  tff(decl_55685, type, 'Nest': $i).
% 29.22/29.09  tff(decl_55686, type, 'A site in which an animal deposits eggs and raises offspring. A nest can also be a place for an animal to live.': $i).
% 29.22/29.09  tff(decl_55687, type, nest: $i).
% 29.22/29.09  tff(decl_55688, type, 'Neural-Crest': $i).
% 29.22/29.09  tff(decl_55689, type, 'In the early development of vertebrates, a group of cells located adjacent to the neural tube. The cells give rise to a variety of body structures, including skeletal elements of the head and face, smooth muscle, the adrenal glands, and the peripheral nervous system.': $i).
% 29.22/29.09  tff(decl_55690, type, 'neural crest': $i).
% 29.22/29.09  tff(decl_55691, type, 'neural-crest': $i).
% 29.22/29.09  tff(decl_55692, type, neural_progenitor_cell_1: $i > $o).
% 29.22/29.09  tff(decl_55693, type, 'Neural-Progenitor-Cell': $i).
% 29.22/29.09  tff(decl_55694, type, 'Stem cells committed to becoming nerve cells.': $i).
% 29.22/29.09  tff(decl_55695, type, 'neural progenitor cell': $i).
% 29.22/29.09  tff(decl_55696, type, 'neural-progenitor-cell': $i).
% 29.22/29.09  tff(decl_55697, type, 'Neural-Signaling': $i).
% 29.22/29.09  tff(decl_55698, type, 'Delivering messages through a neural pathway.': $i).
% 29.22/29.09  tff(decl_55699, type, 'neural communication': $i).
% 29.22/29.09  tff(decl_55700, type, 'nerve cell signaling': $i).
% 29.22/29.09  tff(decl_55701, type, 'neural-signaling': $i).
% 29.22/29.09  tff(decl_55702, type, fn_neural_signaling_2: $i > $i).
% 29.22/29.09  tff(decl_55703, type, fn_neural_signaling_3: $i > $i).
% 29.22/29.09  tff(decl_55704, type, fn_neural_signaling_4: $i > $i).
% 29.22/29.09  tff(decl_55705, type, fn_neural_signaling_5: $i > $i).
% 29.22/29.09  tff(decl_55706, type, fn_neural_signaling_6: $i > $i).
% 29.22/29.09  tff(decl_55707, type, fn_neural_signaling_7: $i > $i).
% 29.22/29.09  tff(decl_55708, type, fn_neural_signaling_8: $i > $i).
% 29.22/29.09  tff(decl_55709, type, fn_neural_signaling_9: $i > $i).
% 29.22/29.09  tff(decl_55710, type, fn_neural_signaling_10: $i > $i).
% 29.22/29.09  tff(decl_55711, type, fn_neural_signaling_11: $i > $i).
% 29.22/29.09  tff(decl_55712, type, fn_neural_signaling_12: $i > $i).
% 29.22/29.09  tff(decl_55713, type, fn_neural_signaling_13: $i > $i).
% 29.22/29.09  tff(decl_55714, type, fn_neural_signaling_14: $i > $i).
% 29.22/29.09  tff(decl_55715, type, fn_neural_signaling_15: $i > $i).
% 29.22/29.09  tff(decl_55716, type, fn_neural_signaling_20: $i > $i).
% 29.22/29.09  tff(decl_55717, type, fn_neural_signaling_22: $i > $i).
% 29.22/29.09  tff(decl_55718, type, fn_neural_signaling_23: $i > $i).
% 29.22/29.09  tff(decl_55719, type, fn_neural_signaling_24: $i > $i).
% 29.22/29.09  tff(decl_55720, type, fn_neural_signaling_25: $i > $i).
% 29.22/29.09  tff(decl_55721, type, fn_neural_signaling_26: $i > $i).
% 29.22/29.09  tff(decl_55722, type, fn_neural_signaling_27: $i > $i).
% 29.22/29.09  tff(decl_55723, type, fn_neural_signaling_28: $i > $i).
% 29.22/29.09  tff(decl_55724, type, fn_neural_signaling_29: $i > $i).
% 29.22/29.09  tff(decl_55725, type, fn_neural_signaling_30: $i > $i).
% 29.22/29.09  tff(decl_55726, type, fn_neural_signaling_31: $i > $i).
% 29.22/29.09  tff(decl_55727, type, fn_neural_signaling_32: $i > $i).
% 29.22/29.09  tff(decl_55728, type, fn_neural_signaling_33: $i > $i).
% 29.22/29.09  tff(decl_55729, type, fn_neural_signaling_34: $i > $i).
% 29.22/29.09  tff(decl_55730, type, fn_neural_signaling_35: $i > $i).
% 29.22/29.09  tff(decl_55731, type, fn_neural_signaling_36: $i > $i).
% 29.22/29.09  tff(decl_55732, type, fn_neural_signaling_37: $i > $i).
% 29.22/29.09  tff(decl_55733, type, fn_neural_signaling_38: $i > $i).
% 29.22/29.09  tff(decl_55734, type, fn_neural_signaling_39: $i > $i).
% 29.22/29.09  tff(decl_55735, type, fn_neural_signaling_40: $i > $i).
% 29.22/29.09  tff(decl_55736, type, fn_neural_signaling_41: $i > $i).
% 29.22/29.09  tff(decl_55737, type, fn_neural_signaling_42: $i > $i).
% 29.22/29.09  tff(decl_55738, type, fn_neural_signaling_43: $i > $i).
% 29.22/29.09  tff(decl_55739, type, fn_neural_signaling_44: $i > $i).
% 29.22/29.09  tff(decl_55740, type, fn_concentration_gradient_1: $i > $i).
% 29.22/29.09  tff(decl_55741, type, fn_neural_signaling_21: $i > $i).
% 29.22/29.09  tff(decl_55742, type, fn_neural_signaling_45: $i > $i).
% 29.22/29.09  tff(decl_55743, type, fn_neural_signaling_46: $i > $i).
% 29.22/29.09  tff(decl_55744, type, neural_tube_1: $i > $o).
% 29.22/29.09  tff(decl_55745, type, 'Neural-Tube': $i).
% 29.22/29.09  tff(decl_55746, type, 'Just dorsal to the notochord in developing embryo of a vertebrate animal, a longitudinal tube of infolded ectodermal cells that will give rise to the central nervous system.': $i).
% 29.22/29.09  tff(decl_55747, type, 'neural tube': $i).
% 29.22/29.09  tff(decl_55748, type, 'neural-tube': $i).
% 29.22/29.09  tff(decl_55749, type, neurohormone_1: $i > $o).
% 29.22/29.09  tff(decl_55750, type, 'Neurohormone': $i).
% 29.22/29.09  tff(decl_55751, type, 'A hormone that is secreted by a neuron.': $i).
% 29.22/29.09  tff(decl_55752, type, neurohormone: $i).
% 29.22/29.09  tff(decl_55753, type, 'Neuromast': $i).
% 29.22/29.09  tff(decl_55754, type, 'A cluster of hair cells and a receptor cap that is part of the lateral line system in fish.': $i).
% 29.22/29.09  tff(decl_55755, type, neuromast: $i).
% 29.22/29.09  tff(decl_55756, type, sensory_nervous_tissue_1: $i > $o).
% 29.22/29.09  tff(decl_55757, type, 'Neuron-Structure': $i).
% 29.22/29.09  tff(decl_55758, type, 'A structure found in neurons (nerve cells.)': $i).
% 29.22/29.09  tff(decl_55759, type, 'structure of neuron': $i).
% 29.22/29.09  tff(decl_55760, type, 'structure-of-neuron': $i).
% 29.22/29.09  tff(decl_55761, type, 'neuron structure': $i).
% 29.22/29.09  tff(decl_55762, type, 'neuron-structure': $i).
% 29.22/29.09  tff(decl_55763, type, 'Neuropeptide': $i).
% 29.22/29.09  tff(decl_55764, type, 'A short chain of amino acids that functions as a neurotransmitter.': $i).
% 29.22/29.09  tff(decl_55765, type, neuropeptide: $i).
% 29.22/29.09  tff(decl_55766, type, neurospora_1: $i > $o).
% 29.22/29.09  tff(decl_55767, type, 'Neurospora': $i).
% 29.22/29.09  tff(decl_55768, type, 'A genus of ascomycete fungi. It includes the bread mold Neurospora crassa.': $i).
% 29.22/29.09  tff(decl_55769, type, neurospora: $i).
% 29.22/29.09  tff(decl_55770, type, penicillium_1: $i > $o).
% 29.22/29.09  tff(decl_55771, type, 'Neurotransmitter': $i).
% 29.22/29.09  tff(decl_55772, type, 'A molecule which is released by neurons to communicate with other neurons, muscle cells, or glands.': $i).
% 29.22/29.09  tff(decl_55773, type, neurotransmitter: $i).
% 29.22/29.09  tff(decl_55774, type, neutral_solution_1: $i > $o).
% 29.22/29.09  tff(decl_55775, type, 'Neutral-Solution': $i).
% 29.22/29.09  tff(decl_55776, type, 'An aqueous solution with a pH 7.': $i).
% 29.22/29.09  tff(decl_55777, type, 'neutral solution': $i).
% 29.22/29.09  tff(decl_55778, type, 'solution of neutral': $i).
% 29.22/29.09  tff(decl_55779, type, 'neutral-solution': $i).
% 29.22/29.09  tff(decl_55780, type, fn_neutral_solution_1: $i > $i).
% 29.22/29.09  tff(decl_55781, type, fn_neutral_solution_2: $i > $i).
% 29.22/29.09  tff(decl_55782, type, fn_neutral_solution_3: $i > $i).
% 29.22/29.09  tff(decl_55783, type, 'Neutron': $i).
% 29.22/29.09  tff(decl_55784, type, 'An electrically neutral particle found in the nucleus of atoms.': $i).
% 29.22/29.09  tff(decl_55785, type, neutron: $i).
% 29.22/29.09  tff(decl_55786, type, fn_neutron_2: $i > $i).
% 29.22/29.09  tff(decl_55787, type, fn_neutron_3: $i > $i).
% 29.22/29.09  tff(decl_55788, type, 'Neutrophil': $i).
% 29.22/29.09  tff(decl_55789, type, 'Phagocytic white blood cells that consume microbial pathogens and then tend to self-destruct. Neutrophils are the most abundant white blood cells and recruit very quickly to a site of injury or trauma.': $i).
% 29.22/29.09  tff(decl_55790, type, neutrophil: $i).
% 29.22/29.09  tff(decl_55791, type, newborn_1: $i > $o).
% 29.22/29.09  tff(decl_55792, type, 'Newborn': $i).
% 29.22/29.09  tff(decl_55793, type, 'In humans, an infant who is hours, days, or up to a few weeks old.': $i).
% 29.22/29.09  tff(decl_55794, type, newborn: $i).
% 29.22/29.09  tff(decl_55795, type, fn_newborn_1: $i > $i).
% 29.22/29.09  tff(decl_55796, type, 'Newborn-Screening': $i).
% 29.22/29.09  tff(decl_55797, type, 'The process of testing newborn babies for conditions that may affect their short-term or long-term health.': $i).
% 29.22/29.09  tff(decl_55798, type, 'screening of newborn': $i).
% 29.22/29.09  tff(decl_55799, type, 'newborn screening': $i).
% 29.22/29.09  tff(decl_55800, type, 'newborn-screening': $i).
% 29.22/29.09  tff(decl_55801, type, nh2_minus_1: $i > $o).
% 29.22/29.09  tff(decl_55802, type, 'NH2-Minus': $i).
% 29.22/29.09  tff(decl_55803, type, 'Amido ion': $i).
% 29.22/29.09  tff(decl_55804, type, 'amido group': $i).
% 29.22/29.09  tff(decl_55805, type, 'nh2 minus': $i).
% 29.22/29.09  tff(decl_55806, type, 'nh2-minus': $i).
% 29.22/29.09  tff(decl_55807, type, fn_nh2_minus_2: $i > $i).
% 29.22/29.09  tff(decl_55808, type, fn_nh2_minus_1: $i > $i).
% 29.22/29.09  tff(decl_55809, type, 'NH4-Plus': $i).
% 29.22/29.09  tff(decl_55810, type, 'Ammonium cation': $i).
% 29.22/29.09  tff(decl_55811, type, 'ammonium ion': $i).
% 29.22/29.09  tff(decl_55812, type, 'nh4 plus': $i).
% 29.22/29.09  tff(decl_55813, type, 'nh4-plus': $i).
% 29.22/29.09  tff(decl_55814, type, fn_nh4_plus_2: $i > $i).
% 29.22/29.09  tff(decl_55815, type, fn_nh4_plus_1: $i > $i).
% 29.22/29.09  tff(decl_55816, type, nh4_plus_substance_1: $i > $o).
% 29.22/29.09  tff(decl_55817, type, 'NH4-Plus-Substance': $i).
% 29.22/29.09  tff(decl_55818, type, 'nh4 plus substance': $i).
% 29.22/29.09  tff(decl_55819, type, 'nh4-plus-substance': $i).
% 29.22/29.09  tff(decl_55820, type, fn_nh4_plus_substance_1: $i > $i).
% 29.22/29.09  tff(decl_55821, type, fn_nh4_plus_substance_2: $i > $i).
% 29.22/29.09  tff(decl_55822, type, fn_nh4_plus_substance_3: $i > $i).
% 29.22/29.09  tff(decl_55823, type, fn_nh4_plus_substance_6: $i > $i).
% 29.22/29.09  tff(decl_55824, type, "5.6e-10": $i).
% 29.22/29.09  tff(decl_55825, type, acid_0: $i).
% 29.22/29.09  tff(decl_55826, type, 'NH4Cl': $i).
% 29.22/29.09  tff(decl_55827, type, 'Ammonium chloride': $i).
% 29.22/29.09  tff(decl_55828, type, 'ammonium chloride': $i).
% 29.22/29.09  tff(decl_55829, type, nh4cl: $i).
% 29.22/29.09  tff(decl_55830, type, fn_nh4cl_1: $i > $i).
% 29.22/29.09  tff(decl_55831, type, fn_nh4cl_2: $i > $i).
% 29.22/29.09  tff(decl_55832, type, nickel_1: $i > $o).
% 29.22/29.09  tff(decl_55833, type, 'Nickel': $i).
% 29.22/29.09  tff(decl_55834, type, 'Nickel is a metal atom with atomic number 28. It is represented by the symbol Ni.': $i).
% 29.22/29.09  tff(decl_55835, type, nickel: $i).
% 29.22/29.09  tff(decl_55836, type, 'Ni': $i).
% 29.22/29.09  tff(decl_55837, type, fn_nickel_3: $i > $i).
% 29.22/29.09  tff(decl_55838, type, fn_nickel_4: $i > $i).
% 29.22/29.09  tff(decl_55839, type, fn_nickel_5: $i > $i).
% 29.22/29.09  tff(decl_55840, type, fn_nickel_9: $i > $i).
% 29.22/29.09  tff(decl_55841, type, fn_nickel_10: $i > $i).
% 29.22/29.09  tff(decl_55842, type, fn_nickel_11: $i > $i).
% 29.22/29.09  tff(decl_55843, type, fn_nickel_12: $i > $i).
% 29.22/29.09  tff(decl_55844, type, "1.91": $i).
% 29.22/29.09  tff(decl_55845, type, "58.69": $i).
% 29.22/29.09  tff(decl_55846, type, fn_nickel_7: $i > $i).
% 29.22/29.09  tff(decl_55847, type, fn_nickel_8: $i > $i).
% 29.22/29.09  tff(decl_55848, type, fn_nickel_6: $i > $i).
% 29.22/29.09  tff(decl_55849, type, 'Nicks-in-damaged-DNA': $i).
% 29.22/29.09  tff(decl_55850, type, 'These are openings present in DNA strand as a result of damage inflicted in the strand by various harmful chemicals or radiations': $i).
% 29.22/29.09  tff(decl_55851, type, 'nicks in damaged dna': $i).
% 29.22/29.09  tff(decl_55852, type, 'nicks-in-damaged-dna': $i).
% 29.22/29.09  tff(decl_55853, type, nicotinamide_1: $i > $o).
% 29.22/29.09  tff(decl_55854, type, 'Nicotinamide': $i).
% 29.22/29.09  tff(decl_55855, type, 'Nicotinamide is a nitrogenous base': $i).
% 29.22/29.09  tff(decl_55856, type, nicotinamide: $i).
% 29.22/29.09  tff(decl_55857, type, niobium_1: $i > $o).
% 29.22/29.09  tff(decl_55858, type, 'Niobium': $i).
% 29.22/29.09  tff(decl_55859, type, 'Niobium is a metal atom with atomic number 41. It is represented by the symbol Nb.': $i).
% 29.22/29.09  tff(decl_55860, type, niobium: $i).
% 29.22/29.09  tff(decl_55861, type, 'Nb': $i).
% 29.22/29.09  tff(decl_55862, type, fn_niobium_3: $i > $i).
% 29.22/29.09  tff(decl_55863, type, fn_niobium_4: $i > $i).
% 29.22/29.09  tff(decl_55864, type, fn_niobium_5: $i > $i).
% 29.22/29.09  tff(decl_55865, type, fn_niobium_9: $i > $i).
% 29.22/29.09  tff(decl_55866, type, fn_niobium_10: $i > $i).
% 29.22/29.09  tff(decl_55867, type, fn_niobium_11: $i > $i).
% 29.22/29.09  tff(decl_55868, type, fn_niobium_12: $i > $i).
% 29.22/29.09  tff(decl_55869, type, "1.6": $i).
% 29.22/29.09  tff(decl_55870, type, "92.91": $i).
% 29.22/29.09  tff(decl_55871, type, fn_niobium_7: $i > $i).
% 29.22/29.09  tff(decl_55872, type, fn_niobium_8: $i > $i).
% 29.22/29.09  tff(decl_55873, type, fn_niobium_6: $i > $i).
% 29.22/29.09  tff(decl_55874, type, 'Nipah-Virus': $i).
% 29.22/29.09  tff(decl_55875, type, 'A virus that causes encephalitis (inflammation of the brain).': $i).
% 29.22/29.09  tff(decl_55876, type, 'nipah virus': $i).
% 29.22/29.09  tff(decl_55877, type, 'nipah-virus': $i).
% 29.22/29.09  tff(decl_55878, type, 'Nitrate-Ion': $i).
% 29.22/29.09  tff(decl_55879, type, 'Polyatomic ion of nitrogen and oxygen with the formula NO3-': $i).
% 29.22/29.09  tff(decl_55880, type, 'ion of nitrate': $i).
% 29.22/29.09  tff(decl_55881, type, 'nitrate ion': $i).
% 29.22/29.09  tff(decl_55882, type, 'nitrate-ion': $i).
% 29.22/29.09  tff(decl_55883, type, fn_nitrate_ion_1: $i > $i).
% 29.22/29.09  tff(decl_55884, type, fn_nitrate_ion_2: $i > $i).
% 29.22/29.09  tff(decl_55885, type, 'Nitric-Acid': $i).
% 29.22/29.09  tff(decl_55886, type, 'Strong acid made from the dissociation of nitrogen dioxide in water.': $i).
% 29.22/29.09  tff(decl_55887, type, 'nitric acid': $i).
% 29.22/29.09  tff(decl_55888, type, 'nitric-acid': $i).
% 29.22/29.09  tff(decl_55889, type, fn_nitric_acid_1: $i > $i).
% 29.22/29.09  tff(decl_55890, type, 'Nitric-Acid-Compound': $i).
% 29.22/29.09  tff(decl_55891, type, 'An acidic compound with molecular formula HNO3.': $i).
% 29.22/29.09  tff(decl_55892, type, 'nitric acid compound': $i).
% 29.22/29.09  tff(decl_55893, type, 'nitric-acid-compound': $i).
% 29.22/29.09  tff(decl_55894, type, fn_nitric_acid_compound_1: $i > $i).
% 29.22/29.09  tff(decl_55895, type, fn_nitric_acid_compound_2: $i > $i).
% 29.22/29.09  tff(decl_55896, type, fn_nitric_acid_compound_3: $i > $i).
% 29.22/29.09  tff(decl_55897, type, nitrogen_0: $i).
% 29.22/29.09  tff(decl_55898, type, 'Nitric-Oxide': $i).
% 29.22/29.09  tff(decl_55899, type, 'A gas with the molecular formula NO that functions as a neurotransmitter and a local regulator.': $i).
% 29.22/29.09  tff(decl_55900, type, 'nitric oxide': $i).
% 29.22/29.09  tff(decl_55901, type, 'nitric-oxide': $i).
% 29.22/29.09  tff(decl_55902, type, fn_nitric_oxide_1: $i > $i).
% 29.22/29.09  tff(decl_55903, type, fn_nitric_oxide_4: $i > $i).
% 29.22/29.09  tff(decl_55904, type, inorganic_molecule_0: $i).
% 29.22/29.09  tff(decl_55905, type, 'Nitric-Oxide-Gas': $i).
% 29.22/29.09  tff(decl_55906, type, 'chemical symbol - NO; A gaseous, chemical signaling molecule with an intracellular receptor.  NO molecules are able to pass through the cell membrane because they are small enough to pass readily between the membrane phospholipids.': $i).
% 29.22/29.09  tff(decl_55907, type, 'nitric oxide gas': $i).
% 29.22/29.09  tff(decl_55908, type, 'nitric-oxide-gas': $i).
% 29.22/29.09  tff(decl_55909, type, fn_nitric_oxide_gas_1: $i > $i).
% 29.22/29.09  tff(decl_55910, type, 'Nitrification': $i).
% 29.22/29.09  tff(decl_55911, type, 'Nitrification is an important series of steps in the nitrogen cycle in which ammonia is converted into nitrates, which are an important class of plant nutrients.': $i).
% 29.22/29.09  tff(decl_55912, type, nitrify: $i).
% 29.22/29.09  tff(decl_55913, type, nitrification: $i).
% 29.22/29.09  tff(decl_55914, type, fn_nitrification_1: $i > $i).
% 29.22/29.09  tff(decl_55915, type, nitrifying_bacterium_1: $i > $o).
% 29.22/29.09  tff(decl_55916, type, fn_nitrification_4: $i > $i).
% 29.22/29.09  tff(decl_55917, type, fn_nitrification_5: $i > $i).
% 29.22/29.09  tff(decl_55918, type, 'Nitrifying-Bacterium': $i).
% 29.22/29.09  tff(decl_55919, type, 'A bacterium that is able to oxidize nitrite to nitrate, an important step in the nitrogen cycle.': $i).
% 29.22/29.09  tff(decl_55920, type, 'nitrifying bacterium': $i).
% 29.22/29.09  tff(decl_55921, type, 'nitrifying-bacterium': $i).
% 29.22/29.09  tff(decl_55922, type, fn_nitrifying_bacterium_1: $i > $i).
% 29.22/29.09  tff(decl_55923, type, fn_nitrifying_bacterium_2: $i > $i).
% 29.22/29.09  tff(decl_55924, type, fn_nitrifying_bacterium_3: $i > $i).
% 29.22/29.09  tff(decl_55925, type, fn_nitrifying_bacterium_4: $i > $i).
% 29.22/29.09  tff(decl_55926, type, fn_nitrifying_bacterium_5: $i > $i).
% 29.22/29.09  tff(decl_55927, type, fn_nitrifying_bacterium_6: $i > $i).
% 29.22/29.09  tff(decl_55928, type, fn_nitrifying_bacterium_7: $i > $i).
% 29.22/29.09  tff(decl_55929, type, fn_nitrifying_bacterium_8: $i > $i).
% 29.22/29.09  tff(decl_55930, type, fn_nitrifying_bacterium_9: $i > $i).
% 29.22/29.09  tff(decl_55931, type, fn_nitrifying_bacterium_10: $i > $i).
% 29.22/29.09  tff(decl_55932, type, fn_nitrifying_bacterium_11: $i > $i).
% 29.22/29.09  tff(decl_55933, type, fn_nitrifying_bacterium_12: $i > $i).
% 29.22/29.09  tff(decl_55934, type, fn_nitrifying_bacterium_13: $i > $i).
% 29.22/29.09  tff(decl_55935, type, fn_nitrifying_bacterium_14: $i > $i).
% 29.22/29.09  tff(decl_55936, type, fn_nitrifying_bacterium_15: $i > $i).
% 29.22/29.09  tff(decl_55937, type, fn_nitrifying_bacterium_16: $i > $i).
% 29.22/29.09  tff(decl_55938, type, fn_nitrifying_bacterium_17: $i > $i).
% 29.22/29.09  tff(decl_55939, type, fn_nitrifying_bacterium_18: $i > $i).
% 29.22/29.09  tff(decl_55940, type, fn_nitrifying_bacterium_19: $i > $i).
% 29.22/29.09  tff(decl_55941, type, fn_nitrifying_bacterium_20: $i > $i).
% 29.22/29.09  tff(decl_55942, type, fn_nitrifying_bacterium_21: $i > $i).
% 29.22/29.09  tff(decl_55943, type, fn_nitrifying_bacterium_22: $i > $i).
% 29.22/29.09  tff(decl_55944, type, fn_nitrifying_bacterium_23: $i > $i).
% 29.22/29.09  tff(decl_55945, type, 'Nitrogen': $i).
% 29.22/29.09  tff(decl_55946, type, 'Nitrogen is a non metal atom with atomic number 7. It is represented by the symbol N.': $i).
% 29.22/29.09  tff(decl_55947, type, 'N': $i).
% 29.22/29.09  tff(decl_55948, type, nitrogen: $i).
% 29.22/29.09  tff(decl_55949, type, fn_nitrogen_2: $i > $i).
% 29.22/29.09  tff(decl_55950, type, fn_nitrogen_3: $i > $i).
% 29.22/29.09  tff(decl_55951, type, fn_nitrogen_4: $i > $i).
% 29.22/29.09  tff(decl_55952, type, fn_nitrogen_6: $i > $i).
% 29.22/29.09  tff(decl_55953, type, fn_nitrogen_8: $i > $i).
% 29.22/29.09  tff(decl_55954, type, fn_nitrogen_15: $i > $i).
% 29.22/29.09  tff(decl_55955, type, fn_nitrogen_17: $i > $i).
% 29.22/29.09  tff(decl_55956, type, "14.01": $i).
% 29.22/29.09  tff(decl_55957, type, "3.04": $i).
% 29.22/29.09  tff(decl_55958, type, fn_nitrogen_21: $i > $i).
% 29.22/29.09  tff(decl_55959, type, fn_nitrogen_20: $i > $i).
% 29.22/29.09  tff(decl_55960, type, fn_nitrogen_19: $i > $i).
% 29.22/29.09  tff(decl_55961, type, fn_nitrogen_7: $i > $i).
% 29.22/29.09  tff(decl_55962, type, nitrogen_14_1: $i > $o).
% 29.22/29.09  tff(decl_55963, type, 'Nitrogen-14': $i).
% 29.22/29.09  tff(decl_55964, type, 'This is one of the Nitrogen isotopes that possess seven neutrons.': $i).
% 29.22/29.09  tff(decl_55965, type, '14 of nitrogen': $i).
% 29.22/29.09  tff(decl_55966, type, 'nitrogen 14': $i).
% 29.22/29.09  tff(decl_55967, type, 'nitrogen-14': $i).
% 29.22/29.09  tff(decl_55968, type, nitrogen_isotope_1: $i > $o).
% 29.22/29.09  tff(decl_55969, type, fn_nitrogen_14_2: $i > $i).
% 29.22/29.09  tff(decl_55970, type, fn_nitrogen_14_4: $i > $i).
% 29.22/29.09  tff(decl_55971, type, fn_nitrogen_14_5: $i > $i).
% 29.22/29.09  tff(decl_55972, type, fn_nitrogen_isotope_3: $i > $i).
% 29.22/29.09  tff(decl_55973, type, fn_nitrogen_14_3: $i > $i).
% 29.22/29.09  tff(decl_55974, type, 'Nitrogen-15': $i).
% 29.22/29.09  tff(decl_55975, type, 'This is one of the Nitrogen isotopes that possess eight neutrons.': $i).
% 29.22/29.09  tff(decl_55976, type, '15 of nitrogen': $i).
% 29.22/29.09  tff(decl_55977, type, 'nitrogen 15': $i).
% 29.22/29.09  tff(decl_55978, type, 'nitrogen-15': $i).
% 29.22/29.09  tff(decl_55979, type, fn_nitrogen_15_2: $i > $i).
% 29.22/29.09  tff(decl_55980, type, fn_nitrogen_15_4: $i > $i).
% 29.22/29.09  tff(decl_55981, type, fn_nitrogen_15_5: $i > $i).
% 29.22/29.09  tff(decl_55982, type, fn_nitrogen_15_3: $i > $i).
% 29.22/29.09  tff(decl_55983, type, 'Nitrogen-Cycle': $i).
% 29.22/29.09  tff(decl_55984, type, 'The natural processes by which nitrogen is converted among its various forms in the environment. Atmospheric nitrogen is converted by bacteria into forms that are assimilated by primary producers and subsequently incorporated into higher trophic levels. The processes of decomposition and excretion return nitrogen to the abiotic environment.': $i).
% 29.22/29.09  tff(decl_55985, type, 'undergo the nitrogen cycle': $i).
% 29.22/29.09  tff(decl_55986, type, 'cycle of nitrogen': $i).
% 29.22/29.09  tff(decl_55987, type, 'nitrogen cycle': $i).
% 29.22/29.09  tff(decl_55988, type, 'nitrogen-cycle': $i).
% 29.22/29.09  tff(decl_55989, type, fn_nitrogen_cycle_1: $i > $i).
% 29.22/29.09  tff(decl_55990, type, fn_nitrogen_cycle_2: $i > $i).
% 29.22/29.09  tff(decl_55991, type, fn_nitrogen_cycle_3: $i > $i).
% 29.22/29.09  tff(decl_55992, type, runoff_1: $i > $o).
% 29.22/29.09  tff(decl_55993, type, fn_nitrogen_cycle_4: $i > $i).
% 29.22/29.09  tff(decl_55994, type, fn_nitrogen_cycle_5: $i > $i).
% 29.22/29.09  tff(decl_55995, type, fn_nitrogen_cycle_6: $i > $i).
% 29.22/29.09  tff(decl_55996, type, fn_nitrogen_cycle_7: $i > $i).
% 29.22/29.09  tff(decl_55997, type, terrestrial_nitrogen_cycle_1: $i > $o).
% 29.22/29.09  tff(decl_55998, type, fn_nitrogen_cycle_8: $i > $i).
% 29.22/29.09  tff(decl_55999, type, fn_nitrogen_cycle_9: $i > $i).
% 29.22/29.09  tff(decl_56000, type, fn_nitrogen_cycle_10: $i > $i).
% 29.22/29.09  tff(decl_56001, type, fn_nitrogen_cycle_11: $i > $i).
% 29.22/29.09  tff(decl_56002, type, fn_nitrogen_cycle_12: $i > $i).
% 29.22/29.09  tff(decl_56003, type, fn_nitrogen_cycle_13: $i > $i).
% 29.22/29.09  tff(decl_56004, type, fn_nitrogen_cycle_14: $i > $i).
% 29.22/29.09  tff(decl_56005, type, fn_nitrogen_cycle_15: $i > $i).
% 29.22/29.09  tff(decl_56006, type, fn_nitrogen_cycle_16: $i > $i).
% 29.22/29.09  tff(decl_56007, type, fn_nitrogen_cycle_17: $i > $i).
% 29.22/29.09  tff(decl_56008, type, fn_nitrogen_cycle_18: $i > $i).
% 29.22/29.09  tff(decl_56009, type, fn_nitrogen_cycle_19: $i > $i).
% 29.22/29.09  tff(decl_56010, type, fn_nitrogen_cycle_20: $i > $i).
% 29.22/29.09  tff(decl_56011, type, fn_nitrogen_cycle_21: $i > $i).
% 29.22/29.09  tff(decl_56012, type, fn_nitrogen_cycle_22: $i > $i).
% 29.22/29.09  tff(decl_56013, type, fn_terrestrial_nitrogen_cycle_34: $i > $i).
% 29.22/29.09  tff(decl_56014, type, fn_terrestrial_nitrogen_cycle_24: $i > $i).
% 29.22/29.09  tff(decl_56015, type, fn_terrestrial_nitrogen_cycle_36: $i > $i).
% 29.22/29.09  tff(decl_56016, type, fn_terrestrial_nitrogen_cycle_37: $i > $i).
% 29.22/29.09  tff(decl_56017, type, fn_terrestrial_nitrogen_cycle_43: $i > $i).
% 29.22/29.09  tff(decl_56018, type, fn_terrestrial_nitrogen_cycle_23: $i > $i).
% 29.22/29.09  tff(decl_56019, type, fn_terrestrial_nitrogen_cycle_2: $i > $i).
% 29.22/29.09  tff(decl_56020, type, fn_terrestrial_nitrogen_cycle_3: $i > $i).
% 29.22/29.09  tff(decl_56021, type, fn_terrestrial_nitrogen_cycle_16: $i > $i).
% 29.22/29.09  tff(decl_56022, type, fn_terrestrial_nitrogen_cycle_42: $i > $i).
% 29.22/29.09  tff(decl_56023, type, fn_terrestrial_nitrogen_cycle_20: $i > $i).
% 29.22/29.09  tff(decl_56024, type, fn_terrestrial_nitrogen_cycle_48: $i > $i).
% 29.22/29.09  tff(decl_56025, type, fn_terrestrial_nitrogen_cycle_28: $i > $i).
% 29.22/29.09  tff(decl_56026, type, fn_terrestrial_nitrogen_cycle_53: $i > $i).
% 29.22/29.09  tff(decl_56027, type, 'Nitrogen-Fixation': $i).
% 29.22/29.09  tff(decl_56028, type, 'The process by which atmospheric nitrogen (N2 gas) is converted to ammonia (NH3). The only organisms that can fix nitrogen are certain groups of prokaryotes.': $i).
% 29.22/29.09  tff(decl_56029, type, 'fixation of nitrogen': $i).
% 29.22/29.09  tff(decl_56030, type, 'nitrogen fixation': $i).
% 29.22/29.09  tff(decl_56031, type, 'nitrogen-fixation': $i).
% 29.22/29.09  tff(decl_56032, type, fn_nitrogen_fixation_2: $i > $i).
% 29.22/29.09  tff(decl_56033, type, fn_nitrogen_fixation_3: $i > $i).
% 29.22/29.09  tff(decl_56034, type, fn_nitrogen_fixation_6: $i > $i).
% 29.22/29.09  tff(decl_56035, type, 'Nitrogen-Fixing-Bacterium': $i).
% 29.22/29.09  tff(decl_56036, type, 'A bacterium that converts atmospheric N2 into a form that can be assimilated by primary producers.': $i).
% 29.22/29.09  tff(decl_56037, type, 'nitrogen fixing bacterium': $i).
% 29.22/29.09  tff(decl_56038, type, 'nitrogen-fixing-bacterium': $i).
% 29.22/29.09  tff(decl_56039, type, 'Nitrogen-Isotope': $i).
% 29.22/29.09  tff(decl_56040, type, 'All the nitrogen isoptopes have 7 protons and 7 electrons. They differ in their neutron number.': $i).
% 29.22/29.09  tff(decl_56041, type, 'isotope of nitrogen': $i).
% 29.22/29.09  tff(decl_56042, type, 'nitrogen isotope': $i).
% 29.22/29.09  tff(decl_56043, type, 'nitrogen-isotope': $i).
% 29.22/29.09  tff(decl_56044, type, fn_nitrogen_isotope_4: $i > $i).
% 29.22/29.09  tff(decl_56045, type, fn_nitrogen_isotope_5: $i > $i).
% 29.22/29.09  tff(decl_56046, type, fn_nitrogen_isotope_6: $i > $i).
% 29.22/29.09  tff(decl_56047, type, fn_nitrogen_isotope_7: $i > $i).
% 29.22/29.09  tff(decl_56048, type, fn_nitrogen_isotope_9: $i > $i).
% 29.22/29.09  tff(decl_56049, type, fn_nitrogen_isotope_10: $i > $i).
% 29.22/29.09  tff(decl_56050, type, fn_nitrogen_isotope_8: $i > $i).
% 29.22/29.09  tff(decl_56051, type, 'Nitrogen-Molecule': $i).
% 29.22/29.09  tff(decl_56052, type, 'Molecule of nitrogen, in which two or more nitrogen atoms are bound together with covalent bonds.': $i).
% 29.22/29.09  tff(decl_56053, type, 'molecule of nitrogen': $i).
% 29.22/29.09  tff(decl_56054, type, 'nitrogen molecule': $i).
% 29.22/29.09  tff(decl_56055, type, 'nitrogen-molecule': $i).
% 29.22/29.09  tff(decl_56056, type, fn_nitrogen_molecule_1: $i > $i).
% 29.22/29.09  tff(decl_56057, type, fn_nitrogen_molecule_3: $i > $i).
% 29.22/29.09  tff(decl_56058, type, fn_nitrogen_molecule_4: $i > $i).
% 29.22/29.09  tff(decl_56059, type, fn_nitrogen_molecule_5: $i > $i).
% 29.22/29.09  tff(decl_56060, type, fn_nitrogen_molecule_6: $i > $i).
% 29.22/29.09  tff(decl_56061, type, fn_nitrogen_molecule_7: $i > $i).
% 29.22/29.09  tff(decl_56062, type, fn_nitrogen_molecule_8: $i > $i).
% 29.22/29.09  tff(decl_56063, type, fn_nitrogen_molecule_9: $i > $i).
% 29.22/29.09  tff(decl_56064, type, fn_nitrogen_molecule_10: $i > $i).
% 29.22/29.09  tff(decl_56065, type, fn_nitrogen_molecule_11: $i > $i).
% 29.22/29.09  tff(decl_56066, type, fn_nitrogen_molecule_12: $i > $i).
% 29.22/29.09  tff(decl_56067, type, fn_nitrogen_molecule_13: $i > $i).
% 29.22/29.09  tff(decl_56068, type, fn_nitrogen_molecule_14: $i > $i).
% 29.22/29.09  tff(decl_56069, type, fn_nitrogen_molecule_15: $i > $i).
% 29.22/29.09  tff(decl_56070, type, fn_nitrogen_molecule_16: $i > $i).
% 29.22/29.09  tff(decl_56071, type, fn_nitrogen_molecule_2: $i > $i).
% 29.22/29.09  tff(decl_56072, type, 'Nitrogenous-Base': $i).
% 29.22/29.09  tff(decl_56073, type, 'Nitrogenous bases (nucleobase) are parts of DNA and RNA. They are involved in hydrogen bonding with corresponding nucleobase present on complementary strand for base paring between the two strands. Adenine, Guanine, Cytosine (all three present in DNA and RNA), Thymine (present in DNA only), Uracil (present in RNA only) are the nitrogenous bases': $i).
% 29.22/29.09  tff(decl_56074, type, 'nitrogen containing base': $i).
% 29.22/29.09  tff(decl_56075, type, 'nitrogen-containing base': $i).
% 29.22/29.09  tff(decl_56076, type, 'nitrogenous base': $i).
% 29.22/29.09  tff(decl_56077, type, 'nitrogenous-base': $i).
% 29.22/29.09  tff(decl_56078, type, fn_nitrogenous_base_1: $i > $i).
% 29.22/29.09  tff(decl_56079, type, fn_nitrogenous_base_2: $i > $i).
% 29.22/29.09  tff(decl_56080, type, 'Nitrogenous-Base-Present-In-DNA': $i).
% 29.22/29.09  tff(decl_56081, type, 'This Nitrogenous base is present in DNA.': $i).
% 29.22/29.09  tff(decl_56082, type, 'nitrogenous bases present in dna': $i).
% 29.22/29.09  tff(decl_56083, type, 'nitrogenous base present in dna': $i).
% 29.22/29.09  tff(decl_56084, type, 'nitrogenous-base-present-in-dna': $i).
% 29.22/29.09  tff(decl_56085, type, 'Nitrogenous-Base-Present-In-RNA': $i).
% 29.22/29.09  tff(decl_56086, type, 'The nitrogenous base present in RNA strand.': $i).
% 29.22/29.09  tff(decl_56087, type, 'nitrogenous bases present in rna': $i).
% 29.22/29.09  tff(decl_56088, type, 'nitrogenous base present in rna': $i).
% 29.22/29.09  tff(decl_56089, type, 'nitrogenous-base-present-in-rna': $i).
% 29.22/29.09  tff(decl_56090, type, 'Nitrogenous-Compound': $i).
% 29.22/29.09  tff(decl_56091, type, 'A chemical compound containing nitrogen.': $i).
% 29.22/29.09  tff(decl_56092, type, 'compound containing nitrogen': $i).
% 29.22/29.09  tff(decl_56093, type, 'compound-containing-nitrogen': $i).
% 29.22/29.09  tff(decl_56094, type, 'nitrogenous compound': $i).
% 29.22/29.09  tff(decl_56095, type, 'nitrogenous-compound': $i).
% 29.22/29.09  tff(decl_56096, type, fn_nitrogenous_compound_1: $i > $i).
% 29.22/29.09  tff(decl_56097, type, 'Nitrogenous-Waste': $i).
% 29.22/29.09  tff(decl_56098, type, 'The waste products resulting from the digestion of proteins and other nitrogenous molecules.': $i).
% 29.22/29.09  tff(decl_56099, type, 'nitrogenous waste': $i).
% 29.22/29.09  tff(decl_56100, type, 'nitrogenous-waste': $i).
% 29.22/29.09  tff(decl_56101, type, 'Nitroglycerine': $i).
% 29.22/29.09  tff(decl_56102, type, 'A heavy, oily, colorless, explosive liquid used medically as a vasodilator to treat heart conditions.': $i).
% 29.22/29.09  tff(decl_56103, type, nitroglycerine: $i).
% 29.22/29.09  tff(decl_56104, type, nl_slot_group_1: $i > $o).
% 29.22/29.09  tff(decl_56105, type, 'NL-Slot-Group': $i).
% 29.22/29.09  tff(decl_56106, type, 'nl slot group': $i).
% 29.22/29.09  tff(decl_56107, type, 'nl-slot-group': $i).
% 29.22/29.09  tff(decl_56108, type, nmr_spectroscopy_1: $i > $o).
% 29.22/29.09  tff(decl_56109, type, 'NMR-Spectroscopy': $i).
% 29.22/29.09  tff(decl_56110, type, 'Nuclear Magnetic Resonance (NMR) spectroscopy is an analytical chemistry technique used in quality control and reserach for determining the molecular structure.': $i).
% 29.22/29.09  tff(decl_56111, type, 'nuclear magnetic resonance spectroscopy': $i).
% 29.22/29.09  tff(decl_56112, type, 'spectroscopy of nmr': $i).
% 29.22/29.09  tff(decl_56113, type, 'nmr spectroscopy': $i).
% 29.22/29.09  tff(decl_56114, type, 'nmr-spectroscopy': $i).
% 29.22/29.09  tff(decl_56115, type, 'No-Till-Agriculture': $i).
% 29.22/29.09  tff(decl_56116, type, 'An agricultural practice that grows crops without tilling, or turning over, the soil.': $i).
% 29.22/29.09  tff(decl_56117, type, 'no till agriculture': $i).
% 29.22/29.09  tff(decl_56118, type, 'no-till-agriculture': $i).
% 29.22/29.09  tff(decl_56119, type, 'NO2-Minus': $i).
% 29.22/29.09  tff(decl_56120, type, 'The nitrite ion of nitrogen.': $i).
% 29.22/29.09  tff(decl_56121, type, nitrite: $i).
% 29.22/29.09  tff(decl_56122, type, 'no2 minus': $i).
% 29.22/29.09  tff(decl_56123, type, 'no2-minus': $i).
% 29.22/29.09  tff(decl_56124, type, fn_no2_minus_2: $i > $i).
% 29.22/29.09  tff(decl_56125, type, fn_no2_minus_1: $i > $i).
% 29.22/29.09  tff(decl_56126, type, no2_minus_substance_1: $i > $o).
% 29.22/29.09  tff(decl_56127, type, 'NO2-Minus-Substance': $i).
% 29.22/29.09  tff(decl_56128, type, 'no2 minus substance': $i).
% 29.22/29.09  tff(decl_56129, type, 'no2-minus-substance': $i).
% 29.22/29.09  tff(decl_56130, type, fn_no2_minus_substance_3: $i > $i).
% 29.22/29.09  tff(decl_56131, type, fn_no2_minus_substance_4: $i > $i).
% 29.22/29.09  tff(decl_56132, type, fn_no2_minus_substance_5: $i > $i).
% 29.22/29.09  tff(decl_56133, type, fn_no2_minus_substance_6: $i > $i).
% 29.22/29.09  tff(decl_56134, type, "2.22e-11": $i).
% 29.22/29.09  tff(decl_56135, type, nobelium_1: $i > $o).
% 29.22/29.09  tff(decl_56136, type, 'Nobelium': $i).
% 29.22/29.09  tff(decl_56137, type, 'Nobelium is a metal atom with atomic number 102. It is represented by the symbol No.': $i).
% 29.22/29.09  tff(decl_56138, type, nobelium: $i).
% 29.22/29.09  tff(decl_56139, type, no: $i).
% 29.22/29.09  tff(decl_56140, type, fn_nobelium_3: $i > $i).
% 29.22/29.09  tff(decl_56141, type, fn_nobelium_4: $i > $i).
% 29.22/29.09  tff(decl_56142, type, fn_nobelium_5: $i > $i).
% 29.22/29.09  tff(decl_56143, type, fn_nobelium_9: $i > $i).
% 29.22/29.09  tff(decl_56144, type, fn_nobelium_10: $i > $i).
% 29.22/29.09  tff(decl_56145, type, fn_nobelium_11: $i > $i).
% 29.22/29.09  tff(decl_56146, type, fn_nobelium_12: $i > $i).
% 29.22/29.09  tff(decl_56147, type, "102": $i).
% 29.22/29.09  tff(decl_56148, type, "16": $i).
% 29.22/29.09  tff(decl_56149, type, "259": $i).
% 29.22/29.09  tff(decl_56150, type, fn_nobelium_7: $i > $i).
% 29.22/29.09  tff(decl_56151, type, fn_nobelium_8: $i > $i).
% 29.22/29.09  tff(decl_56152, type, fn_nobelium_6: $i > $i).
% 29.22/29.09  tff(decl_56153, type, 'Nociceptor': $i).
% 29.22/29.09  tff(decl_56154, type, 'A sensory receptor that responds to potentially damaging stimuli, which are usually perceived as pain.': $i).
% 29.22/29.09  tff(decl_56155, type, nociceptor: $i).
% 29.22/29.09  tff(decl_56156, type, nod_gene_1: $i > $o).
% 29.22/29.09  tff(decl_56157, type, 'Nod-Gene': $i).
% 29.22/29.09  tff(decl_56158, type, 'A bacterial gene that causes roots of certain plants to form openings for symbiotic fungus to enter.': $i).
% 29.22/29.09  tff(decl_56159, type, 'gene of nod': $i).
% 29.22/29.09  tff(decl_56160, type, 'nod gene': $i).
% 29.22/29.09  tff(decl_56161, type, 'nod-gene': $i).
% 29.22/29.09  tff(decl_56162, type, node_1: $i > $o).
% 29.22/29.09  tff(decl_56163, type, 'Node': $i).
% 29.22/29.09  tff(decl_56164, type, 'Location on a plant stem where a leaf arises.': $i).
% 29.22/29.09  tff(decl_56165, type, node: $i).
% 29.22/29.09  tff(decl_56166, type, 'Node-Of-Ranvier': $i).
% 29.22/29.09  tff(decl_56167, type, 'A gap in the coating of myelin along certain axons, where an action potential can be generated. The gaps allow for saltatory conduction, in which a new action potential is generated at each node and appears to jump from node to node.': $i).
% 29.22/29.09  tff(decl_56168, type, 'node of ranvier': $i).
% 29.22/29.09  tff(decl_56169, type, 'node-of-ranvier': $i).
% 29.22/29.09  tff(decl_56170, type, 'Nodule': $i).
% 29.22/29.09  tff(decl_56171, type, 'A group of cells forming a swelling on the root of a legume. Nodules contain symbiotic nitrogen-fixing bacteria.': $i).
% 29.22/29.09  tff(decl_56172, type, nodule: $i).
% 29.22/29.09  tff(decl_56173, type, 'Non-Coding-DNA-Sequence': $i).
% 29.22/29.09  tff(decl_56174, type, 'A sequence of DNA that does not code for a polypeptide.': $i).
% 29.22/29.09  tff(decl_56175, type, 'non coding dna sequence': $i).
% 29.22/29.09  tff(decl_56176, type, 'non-coding-dna-sequence': $i).
% 29.22/29.09  tff(decl_56177, type, 'Non-Competitive-Inhibition': $i).
% 29.22/29.09  tff(decl_56178, type, 'Non-competitive inhibition is a type of enzyme inhibition where the inhibitor reversibly binds to an allosteric site, a site different than the active site, on the enzyme, preventing the substrate from being able to bind to the active site.': $i).
% 29.22/29.09  tff(decl_56179, type, 'non competitive inhibition': $i).
% 29.22/29.09  tff(decl_56180, type, 'non-competitive-inhibition': $i).
% 29.22/29.09  tff(decl_56181, type, fn_non_competitive_inhibition_1: $i > $i).
% 29.22/29.09  tff(decl_56182, type, fn_non_competitive_inhibition_3: $i > $i).
% 29.22/29.09  tff(decl_56183, type, fn_non_competitive_inhibition_4: $i > $i).
% 29.22/29.09  tff(decl_56184, type, fn_non_competitive_inhibition_6: $i > $i).
% 29.22/29.09  tff(decl_56185, type, fn_non_competitive_inhibition_8: $i > $i).
% 29.22/29.09  tff(decl_56186, type, noncompetitive_inhibitor_1: $i > $o).
% 29.22/29.09  tff(decl_56187, type, fn_non_competitive_inhibition_9: $i > $i).
% 29.22/29.09  tff(decl_56188, type, fn_non_competitive_inhibition_10: $i > $i).
% 29.22/29.09  tff(decl_56189, type, non_disjunction_1: $i > $o).
% 29.22/29.09  tff(decl_56190, type, 'Non-Disjunction': $i).
% 29.22/29.09  tff(decl_56191, type, 'An error in meiosis or mitosis in which members of a pair of homologous chromosomes or a pair of sister chromatids fail to separate properly from each other.': $i).
% 29.22/29.09  tff(decl_56192, type, nondisjunction: $i).
% 29.22/29.09  tff(decl_56193, type, 'non disjunction': $i).
% 29.22/29.09  tff(decl_56194, type, 'non-disjunction': $i).
% 29.22/29.09  tff(decl_56195, type, fn_non_disjunction_1: $i > $i).
% 29.22/29.09  tff(decl_56196, type, non_dissolution_of_oil_in_water_1: $i > $o).
% 29.22/29.09  tff(decl_56197, type, 'Non-Dissolution-of-Oil-in-Water': $i).
% 29.22/29.09  tff(decl_56198, type, 'Oil is a lipid, and lipid molecules are composed of long, nonpolar hydrocarbon chains.  Water molecules are polar and so nonpolar oil molecules will not dissolve in water.': $i).
% 29.22/29.09  tff(decl_56199, type, 'non dissolution of oil in water': $i).
% 29.22/29.09  tff(decl_56200, type, 'non-dissolution-of-oil-in-water': $i).
% 29.22/29.09  tff(decl_56201, type, fn_non_dissolution_of_oil_in_water_1: $i > $i).
% 29.22/29.09  tff(decl_56202, type, presence_of_nonpolar_fatty_acid_polymers_1: $i > $o).
% 29.22/29.09  tff(decl_56203, type, fn_non_dissolution_of_oil_in_water_2: $i > $i).
% 29.22/29.09  tff(decl_56204, type, fn_non_dissolution_of_oil_in_water_3: $i > $i).
% 29.22/29.09  tff(decl_56205, type, non_essential_amino_acid_1: $i > $o).
% 29.22/29.09  tff(decl_56206, type, 'Non-Essential-Amino-Acid': $i).
% 29.22/29.09  tff(decl_56207, type, 'An amino acid that can be synthesized by the human body and thus is not a required element of the human diet.': $i).
% 29.22/29.09  tff(decl_56208, type, 'non essential amino acid': $i).
% 29.22/29.09  tff(decl_56209, type, 'non-essential-amino-acid': $i).
% 29.22/29.09  tff(decl_56210, type, 'Non-Homologous-Chromosome': $i).
% 29.22/29.09  tff(decl_56211, type, 'One of a pair of chromosomes that is not homologous to another chromosome.': $i).
% 29.22/29.09  tff(decl_56212, type, 'non homologous chromosome': $i).
% 29.22/29.09  tff(decl_56213, type, 'non-homologous-chromosome': $i).
% 29.22/29.09  tff(decl_56214, type, 'Non-Living-Entity': $i).
% 29.22/29.09  tff(decl_56215, type, 'An entity which does not have life.': $i).
% 29.22/29.09  tff(decl_56216, type, dead: $i).
% 29.22/29.09  tff(decl_56217, type, 'non living': $i).
% 29.22/29.09  tff(decl_56218, type, 'non-living': $i).
% 29.22/29.09  tff(decl_56219, type, nonliving: $i).
% 29.22/29.09  tff(decl_56220, type, 'non living entity': $i).
% 29.22/29.09  tff(decl_56221, type, 'non-living-entity': $i).
% 29.22/29.09  tff(decl_56222, type, non_living_structure_1: $i > $o).
% 29.22/29.09  tff(decl_56223, type, 'Non-Living-Structure': $i).
% 29.22/29.09  tff(decl_56224, type, 'A structural component of a non-living entity.': $i).
% 29.22/29.09  tff(decl_56225, type, 'non living structure': $i).
% 29.22/29.09  tff(decl_56226, type, 'non-living-structure': $i).
% 29.22/29.09  tff(decl_56227, type, 'Non-Mendelian-Genetics': $i).
% 29.22/29.09  tff(decl_56228, type, 'A general term that refers to any pattern of inheritance in which traits do not segregate in accordance with Mendels laws.': $i).
% 29.22/29.09  tff(decl_56229, type, 'non mendelian genetics': $i).
% 29.22/29.09  tff(decl_56230, type, 'non-mendelian-genetic': $i).
% 29.22/29.09  tff(decl_56231, type, non_metal_1: $i > $o).
% 29.22/29.09  tff(decl_56232, type, 'Non-Metal': $i).
% 29.22/29.09  tff(decl_56233, type, nonmetal: $i).
% 29.22/29.09  tff(decl_56234, type, 'non metal': $i).
% 29.22/29.09  tff(decl_56235, type, 'non-metal': $i).
% 29.22/29.09  tff(decl_56236, type, fn_non_metal_1: $i > $i).
% 29.22/29.09  tff(decl_56237, type, 'Non-Metal-Atom': $i).
% 29.22/29.09  tff(decl_56238, type, 'Nonmetals are elements in the upper right corner of the periodic table; nonmetals differ from metals in their physical and chemical properties.': $i).
% 29.22/29.09  tff(decl_56239, type, 'non metal atom': $i).
% 29.22/29.09  tff(decl_56240, type, 'non-metal-atom': $i).
% 29.22/29.09  tff(decl_56241, type, 'Non-Motile-Cilium': $i).
% 29.22/29.09  tff(decl_56242, type, 'This is the cilium present on eukaryotic cell which work in the sensory activities of the cell.': $i).
% 29.22/29.09  tff(decl_56243, type, 'primary cilium': $i).
% 29.22/29.09  tff(decl_56244, type, 'primary-cilium': $i).
% 29.22/29.09  tff(decl_56245, type, 'signal receiving cilium': $i).
% 29.22/29.09  tff(decl_56246, type, 'antennae cilium': $i).
% 29.22/29.09  tff(decl_56247, type, 'immotile cilium': $i).
% 29.22/29.09  tff(decl_56248, type, 'non motile cilium': $i).
% 29.22/29.09  tff(decl_56249, type, 'non-motile-cilium': $i).
% 29.22/29.09  tff(decl_56250, type, fn_non_motile_cilium_1: $i > $i).
% 29.22/29.09  tff(decl_56251, type, fn_non_motile_cilium_2: $i > $i).
% 29.22/29.09  tff(decl_56252, type, fn_non_motile_cilium_3: $i > $i).
% 29.22/29.09  tff(decl_56253, type, fn_non_motile_cilium_4: $i > $i).
% 29.22/29.09  tff(decl_56254, type, fn_non_motile_cilium_5: $i > $i).
% 29.22/29.09  tff(decl_56255, type, fn_non_motile_cilium_6: $i > $i).
% 29.22/29.09  tff(decl_56256, type, fn_non_motile_cilium_7: $i > $i).
% 29.22/29.09  tff(decl_56257, type, 'Non-Polar-Side-Chain': $i).
% 29.22/29.09  tff(decl_56258, type, 'Polar side chain are hydrophobic regions in a amino acid.': $i).
% 29.22/29.09  tff(decl_56259, type, 'non polar side chain': $i).
% 29.22/29.09  tff(decl_56260, type, 'non-polar-side-chain': $i).
% 29.22/29.09  tff(decl_56261, type, non_spontaneous_change_1: $i > $o).
% 29.22/29.09  tff(decl_56262, type, 'Non-Spontaneous-Change': $i).
% 29.22/29.09  tff(decl_56263, type, 'A non-spontaneous change is an unfavourable reaction or process which requires expenditure of energy for it to occur.': $i).
% 29.22/29.09  tff(decl_56264, type, 'non spontaneous change': $i).
% 29.22/29.09  tff(decl_56265, type, 'non-spontaneous-change': $i).
% 29.22/29.09  tff(decl_56266, type, fn_non_spontaneous_change_1: $i > $i).
% 29.22/29.09  tff(decl_56267, type, 'Noncellulose-Polysaccharide': $i).
% 29.22/29.09  tff(decl_56268, type, 'Food substances such as hemicellulose, pectins, gums, mucilages, and algal products that absorb water and swell to a larger bulk. They slow emptying of food from the stomach, bind bile acids, provide fermentation material for the colon, and prevent spastic colon pressure and are non-cellulose polysaccharides.': $i).
% 29.22/29.09  tff(decl_56269, type, 'noncellulose polysaccharide': $i).
% 29.22/29.09  tff(decl_56270, type, 'noncellulose-polysaccharide': $i).
% 29.22/29.09  tff(decl_56271, type, 'Noncompetitive-Inhibitor': $i).
% 29.22/29.09  tff(decl_56272, type, 'A noncompetitive inhibitor is a substance that interacts with the enyzme, but usually not at the active site.  The noncompetitive inhibitor reacts either remote from or very close to the active site.  The net effect of a non competitive inhibitor is to change the shape of the enzyme and thus the active site, so that the substrate can no longer interact with the enzyme to give a reaction. Non competitive inhibitors are usually reversible, but are not influenced by concentrations of the substrate as is the case for a reversible competive inhibitor.': $i).
% 29.22/29.09  tff(decl_56273, type, 'non competitive inhibitor': $i).
% 29.22/29.09  tff(decl_56274, type, 'non-competitive-inhibitor': $i).
% 29.22/29.09  tff(decl_56275, type, 'noncompetitive inhibitor': $i).
% 29.22/29.09  tff(decl_56276, type, 'noncompetitive-inhibitor': $i).
% 29.22/29.09  tff(decl_56277, type, fn_noncompetitive_inhibitor_1: $i > $i).
% 29.22/29.09  tff(decl_56278, type, fn_noncompetitive_inhibitor_2: $i > $i).
% 29.22/29.09  tff(decl_56279, type, fn_noncompetitive_inhibitor_3: $i > $i).
% 29.22/29.09  tff(decl_56280, type, fn_noncompetitive_inhibitor_4: $i > $i).
% 29.22/29.09  tff(decl_56281, type, fn_noncompetitive_inhibitor_5: $i > $i).
% 29.22/29.09  tff(decl_56282, type, fn_noncompetitive_inhibitor_6: $i > $i).
% 29.22/29.09  tff(decl_56283, type, fn_noncompetitive_inhibitor_7: $i > $i).
% 29.22/29.09  tff(decl_56284, type, fn_noncompetitive_inhibitor_8: $i > $i).
% 29.22/29.09  tff(decl_56285, type, fn_non_competitive_inhibition_5: $i > $i).
% 29.22/29.09  tff(decl_56286, type, fn_non_competitive_inhibition_2: $i > $i).
% 29.22/29.09  tff(decl_56287, type, fn_noncompetitive_inhibitor_10: $i > $i).
% 29.22/29.09  tff(decl_56288, type, fn_noncompetitive_inhibitor_9: $i > $i).
% 29.22/29.09  tff(decl_56289, type, 'Nondividing-Cell': $i).
% 29.22/29.09  tff(decl_56290, type, 'Cell which is in a nondividing stage of the cell cycle, such as G1 or G0, and is not actively undergoing diviision. This could be either a temporary or a permanent state, depending on the cell type and age.': $i).
% 29.22/29.09  tff(decl_56291, type, 'nondividing cell': $i).
% 29.22/29.09  tff(decl_56292, type, 'nondividing-cell': $i).
% 29.22/29.09  tff(decl_56293, type, nonelectrolyte_1: $i > $o).
% 29.22/29.09  tff(decl_56294, type, 'Nonelectrolyte': $i).
% 29.22/29.09  tff(decl_56295, type, 'A nonelectrolyte is a substance that does not ionise in water and consequently gives a nonconducting solution.': $i).
% 29.22/29.09  tff(decl_56296, type, 'non electrolyte': $i).
% 29.22/29.09  tff(decl_56297, type, 'non-electrolyte': $i).
% 29.22/29.09  tff(decl_56298, type, nonelectrolyte: $i).
% 29.22/29.09  tff(decl_56299, type, fn_nonelectrolyte_2: $i > $i).
% 29.22/29.09  tff(decl_56300, type, 'Nonequilibrium-Model': $i).
% 29.22/29.09  tff(decl_56301, type, 'A model that states that community structure changes constantly after being disturbed.': $i).
% 29.22/29.09  tff(decl_56302, type, 'nonequilibrium model': $i).
% 29.22/29.09  tff(decl_56303, type, 'nonequilibrium-model': $i).
% 29.22/29.09  tff(decl_56304, type, 'Nonkinetochore-Microtubule': $i).
% 29.22/29.09  tff(decl_56305, type, 'Nonkinetochore microtubule is a microtubule which does not attach to kinetochore during cell division. It rather find and interact with corresponding nonkinetochore microtubules from the opposite centrosome to form the mitotic spindle': $i).
% 29.22/29.09  tff(decl_56306, type, 'non kinetochore microtubule': $i).
% 29.22/29.09  tff(decl_56307, type, 'non-kinetochore microtubule': $i).
% 29.22/29.09  tff(decl_56308, type, 'polar microtubule': $i).
% 29.22/29.09  tff(decl_56309, type, 'nonkinetochore microtubule': $i).
% 29.22/29.09  tff(decl_56310, type, 'nonkinetochore-microtubule': $i).
% 29.22/29.09  tff(decl_56311, type, fn_nonkinetochore_microtubule_3: $i > $i).
% 29.22/29.09  tff(decl_56312, type, 'Nonpolar-Covalent-Bond': $i).
% 29.22/29.09  tff(decl_56313, type, 'A covalent bond between two atoms with the same or similar electronegativity. The electrons in the bond are shared equally between the atoms.': $i).
% 29.22/29.09  tff(decl_56314, type, 'nonpolar covalent bond': $i).
% 29.22/29.09  tff(decl_56315, type, 'nonpolar-covalent-bond': $i).
% 29.22/29.09  tff(decl_56316, type, fn_nonpolar_covalent_bond_6: $i > $i).
% 29.22/29.09  tff(decl_56317, type, fn_nonpolar_covalent_bond_7: $i > $i).
% 29.22/29.09  tff(decl_56318, type, fn_nonpolar_covalent_bond_8: $i > $i).
% 29.22/29.09  tff(decl_56319, type, fn_nonpolar_covalent_bond_10: $i > $i).
% 29.22/29.09  tff(decl_56320, type, fn_nonpolar_covalent_bond_11: $i > $i).
% 29.22/29.09  tff(decl_56321, type, fn_nonpolar_covalent_bond_12: $i > $i).
% 29.22/29.09  tff(decl_56322, type, fn_nonpolar_covalent_bond_13: $i > $i).
% 29.22/29.09  tff(decl_56323, type, fn_nonpolar_covalent_bond_14: $i > $i).
% 29.22/29.09  tff(decl_56324, type, fn_nonpolar_covalent_bond_15: $i > $i).
% 29.22/29.09  tff(decl_56325, type, fn_nonpolar_covalent_bond_16: $i > $i).
% 29.22/29.09  tff(decl_56326, type, fn_nonpolar_covalent_bond_18: $i > $i).
% 29.22/29.09  tff(decl_56327, type, fn_nonpolar_covalent_bond_17: $i > $i).
% 29.22/29.09  tff(decl_56328, type, fn_nonpolar_covalent_bond_9: $i > $i).
% 29.22/29.09  tff(decl_56329, type, 'Nonpolar-Molecule': $i).
% 29.22/29.09  tff(decl_56330, type, 'A molecule where all bonds share charges equally or where polar covalent bonds in a molecule nullify each other.  These molecules are hydrophobic.': $i).
% 29.22/29.09  tff(decl_56331, type, 'nonpolar molecule': $i).
% 29.22/29.09  tff(decl_56332, type, 'nonpolar-molecule': $i).
% 29.22/29.09  tff(decl_56333, type, fn_nonpolar_molecule_2: $i > $i).
% 29.22/29.09  tff(decl_56334, type, fn_nonpolar_molecule_1: $i > $i).
% 29.22/29.09  tff(decl_56335, type, 'Nonpolar-Region': $i).
% 29.22/29.09  tff(decl_56336, type, 'A part of a molecule that is nonpolar.': $i).
% 29.22/29.09  tff(decl_56337, type, 'nonpolar region': $i).
% 29.22/29.09  tff(decl_56338, type, 'nonpolar-region': $i).
% 29.22/29.09  tff(decl_56339, type, 'Nonpolar-Substance': $i).
% 29.22/29.09  tff(decl_56340, type, 'A substance whose individual molecules are nonpolar.': $i).
% 29.22/29.09  tff(decl_56341, type, 'nonpolar substance': $i).
% 29.22/29.09  tff(decl_56342, type, 'nonpolar-substance': $i).
% 29.22/29.09  tff(decl_56343, type, 'Nonrenewable-Resource': $i).
% 29.22/29.09  tff(decl_56344, type, 'nonrenewable resource': $i).
% 29.22/29.09  tff(decl_56345, type, 'nonrenewable-resource': $i).
% 29.22/29.09  tff(decl_56346, type, nonsense_mutation_1: $i > $o).
% 29.22/29.09  tff(decl_56347, type, 'Nonsense-Mutation': $i).
% 29.22/29.09  tff(decl_56348, type, 'A point mutation that results in a stop codon, leading to a prematurely shortened polypeptide chain.': $i).
% 29.22/29.09  tff(decl_56349, type, 'mutation of nonsense': $i).
% 29.22/29.09  tff(decl_56350, type, 'nonsense mutation': $i).
% 29.22/29.09  tff(decl_56351, type, 'nonsense-mutation': $i).
% 29.22/29.09  tff(decl_56352, type, nonsister_chromatid_1: $i > $o).
% 29.22/29.09  tff(decl_56353, type, 'Nonsister-chromatid': $i).
% 29.22/29.09  tff(decl_56354, type, 'Nonsister chromatids are the two chromatids belonging to separate but homologous chromosomes': $i).
% 29.22/29.09  tff(decl_56355, type, 'non sister chromatid': $i).
% 29.22/29.09  tff(decl_56356, type, 'non-sister chromatid': $i).
% 29.22/29.09  tff(decl_56357, type, 'nonsister chromatid': $i).
% 29.22/29.09  tff(decl_56358, type, 'nonsister-chromatid': $i).
% 29.22/29.09  tff(decl_56359, type, nonspecific_defense_mechanism_1: $i > $o).
% 29.22/29.09  tff(decl_56360, type, 'Nonspecific-Defense-Mechanism': $i).
% 29.22/29.09  tff(decl_56361, type, 'Mechanisms of the immune system that work against a wide range of pathogens.': $i).
% 29.22/29.09  tff(decl_56362, type, 'nonspecific defense mechanism': $i).
% 29.22/29.09  tff(decl_56363, type, 'nonspecific-defense-mechanism': $i).
% 29.22/29.09  tff(decl_56364, type, 'Norepinephrine': $i).
% 29.22/29.09  tff(decl_56365, type, 'Also known as noradrenaline; a molecule that is similar to epinephrine and functions as both a hormone and a neurotransmitter.': $i).
% 29.22/29.09  tff(decl_56366, type, norepinephrine: $i).
% 29.22/29.09  tff(decl_56367, type, norm_of_reaction_1: $i > $o).
% 29.22/29.09  tff(decl_56368, type, 'Norm-Of-Reaction': $i).
% 29.22/29.09  tff(decl_56369, type, 'The range of phenotypes produced by a single genotype, due to environmental influences.': $i).
% 29.22/29.09  tff(decl_56370, type, 'phenotypic range': $i).
% 29.22/29.09  tff(decl_56371, type, 'reaction norm': $i).
% 29.22/29.09  tff(decl_56372, type, 'reaction-norm': $i).
% 29.22/29.09  tff(decl_56373, type, 'norm of reaction': $i).
% 29.22/29.09  tff(decl_56374, type, 'norm-of-reaction': $i).
% 29.22/29.09  tff(decl_56375, type, fn_norm_of_reaction_1: $i > $i).
% 29.22/29.09  tff(decl_56376, type, fn_norm_of_reaction_2: $i > $i).
% 29.22/29.09  tff(decl_56377, type, fn_norm_of_reaction_3: $i > $i).
% 29.22/29.09  tff(decl_56378, type, 'Normal': $i).
% 29.22/29.09  tff(decl_56379, type, 'Behaves as expected; standard.': $i).
% 29.22/29.09  tff(decl_56380, type, normal: $i).
% 29.22/29.09  tff(decl_56381, type, normal_person_1: $i > $o).
% 29.22/29.09  tff(decl_56382, type, 'Normal-Person': $i).
% 29.22/29.09  tff(decl_56383, type, 'A person who is normal with reference to a certain condition.': $i).
% 29.22/29.09  tff(decl_56384, type, 'normal human': $i).
% 29.22/29.09  tff(decl_56385, type, 'wild type person': $i).
% 29.22/29.09  tff(decl_56386, type, 'wild-type person': $i).
% 29.22/29.09  tff(decl_56387, type, 'person of normal': $i).
% 29.22/29.09  tff(decl_56388, type, 'normal person': $i).
% 29.22/29.09  tff(decl_56389, type, 'normal-person': $i).
% 29.22/29.09  tff(decl_56390, type, northern_blotting_1: $i > $o).
% 29.22/29.09  tff(decl_56391, type, 'Northern-Blotting': $i).
% 29.22/29.09  tff(decl_56392, type, 'A technique for detecting specific nucleotide sequences in a sample of mRNA. It involves the use of gel electrophoresis to separate RNA pieces by size and hybridization with labeled probes.': $i).
% 29.22/29.09  tff(decl_56393, type, 'blotting of northern': $i).
% 29.22/29.09  tff(decl_56394, type, 'northern blotting': $i).
% 29.22/29.09  tff(decl_56395, type, 'northern-blotting': $i).
% 29.22/29.09  tff(decl_56396, type, 'Northern-Coniferous': $i).
% 29.22/29.09  tff(decl_56397, type, 'A terrestrial biome of the northern hemisphere, dominated by coniferous trees and long, cold winters.': $i).
% 29.22/29.09  tff(decl_56398, type, 'northern coniferous': $i).
% 29.22/29.09  tff(decl_56399, type, 'northern-coniferous': $i).
% 29.22/29.09  tff(decl_56400, type, 'Notochord': $i).
% 29.22/29.09  tff(decl_56401, type, 'A flexible, mesodermally derived rod that runs longitudinally along the embryo of all vertebrate embryos.': $i).
% 29.22/29.09  tff(decl_56402, type, notochord: $i).
% 29.22/29.09  tff(decl_56403, type, 'Novel-DNA-Sequence': $i).
% 29.22/29.09  tff(decl_56404, type, 'A new DNA sequence created through genetic modification.': $i).
% 29.22/29.09  tff(decl_56405, type, 'novel dna sequence': $i).
% 29.22/29.09  tff(decl_56406, type, 'novel-dna-sequence': $i).
% 29.22/29.09  tff(decl_56407, type, 'Nuclear-Division': $i).
% 29.22/29.09  tff(decl_56408, type, 'The process of the division of the nucleus in eukaryotic cells.': $i).
% 29.22/29.09  tff(decl_56409, type, 'nuclear division': $i).
% 29.22/29.09  tff(decl_56410, type, 'nuclear-division': $i).
% 29.22/29.09  tff(decl_56411, type, fn_nuclear_division_1: $i > $i).
% 29.22/29.09  tff(decl_56412, type, 'Nuclear-Lamina': $i).
% 29.22/29.09  tff(decl_56413, type, 'Nuclear-lamina is an array of protein filaments which lines the nuclear side of the nuclear membrane. It maintains the shape of the nucleus': $i).
% 29.22/29.09  tff(decl_56414, type, 'nuclear lamina': $i).
% 29.22/29.09  tff(decl_56415, type, 'nuclear-lamina': $i).
% 29.22/29.09  tff(decl_56416, type, fn_nuclear_lamina_2: $i > $i).
% 29.22/29.09  tff(decl_56417, type, fn_nuclear_lamina_3: $i > $i).
% 29.22/29.09  tff(decl_56418, type, fn_nuclear_lamina_4: $i > $i).
% 29.22/29.09  tff(decl_56419, type, fn_nuclear_lamina_5: $i > $i).
% 29.22/29.09  tff(decl_56420, type, fn_nuclear_lamina_6: $i > $i).
% 29.22/29.09  tff(decl_56421, type, 'Nuclear-Matrix': $i).
% 29.22/29.09  tff(decl_56422, type, 'Nuclear-matrix is a framework of fibers extending throughout the nuclear interior': $i).
% 29.22/29.09  tff(decl_56423, type, 'nuclear matrix': $i).
% 29.22/29.09  tff(decl_56424, type, 'nuclear-matrix': $i).
% 29.22/29.09  tff(decl_56425, type, 'Nuclear-Membrane': $i).
% 29.22/29.09  tff(decl_56426, type, 'Nuclear-Membrane is a double lipid bilayer that acts as a barrier enclosing the genetic material in eukaryotic cells': $i).
% 29.22/29.09  tff(decl_56427, type, 'nuclear envelope': $i).
% 29.22/29.09  tff(decl_56428, type, 'nuclear-envelope': $i).
% 29.22/29.09  tff(decl_56429, type, 'perinuclear envelope': $i).
% 29.22/29.09  tff(decl_56430, type, 'perinuclear-envelope': $i).
% 29.22/29.09  tff(decl_56431, type, nucleolemma: $i).
% 29.22/29.09  tff(decl_56432, type, karyotheca: $i).
% 29.22/29.09  tff(decl_56433, type, 'nuclear membrane': $i).
% 29.22/29.09  tff(decl_56434, type, 'nuclear-membrane': $i).
% 29.22/29.09  tff(decl_56435, type, fn_nuclear_membrane_6: $i > $i).
% 29.22/29.09  tff(decl_56436, type, fn_nuclear_membrane_7: $i > $i).
% 29.22/29.09  tff(decl_56437, type, fn_nuclear_membrane_8: $i > $i).
% 29.22/29.09  tff(decl_56438, type, fn_nuclear_membrane_10: $i > $i).
% 29.22/29.09  tff(decl_56439, type, fn_nuclear_membrane_11: $i > $i).
% 29.22/29.09  tff(decl_56440, type, fn_nuclear_membrane_12: $i > $i).
% 29.22/29.09  tff(decl_56441, type, fn_nuclear_membrane_20: $i > $i).
% 29.22/29.09  tff(decl_56442, type, fn_nuclear_membrane_22: $i > $i).
% 29.22/29.09  tff(decl_56443, type, fn_nuclear_membrane_23: $i > $i).
% 29.22/29.09  tff(decl_56444, type, fn_nuclear_membrane_24: $i > $i).
% 29.22/29.09  tff(decl_56445, type, fn_nuclear_membrane_25: $i > $i).
% 29.22/29.09  tff(decl_56446, type, fn_nuclear_membrane_26: $i > $i).
% 29.22/29.09  tff(decl_56447, type, "90.0": $i).
% 29.22/29.09  tff(decl_56448, type, "110.0": $i).
% 29.22/29.09  tff(decl_56449, type, membrane_0: $i).
% 29.22/29.09  tff(decl_56450, type, "40.0e0": $i).
% 29.22/29.09  tff(decl_56451, type, 'Nuclear-Pore': $i).
% 29.22/29.09  tff(decl_56452, type, 'Channel through the nuclear envelope that allows selected molecules to move between the nucleus and cytoplasm.': $i).
% 29.22/29.09  tff(decl_56453, type, 'nuclear pore': $i).
% 29.22/29.09  tff(decl_56454, type, 'nuclear-pore': $i).
% 29.22/29.09  tff(decl_56455, type, 'Nuclear-Receptor': $i).
% 29.22/29.09  tff(decl_56456, type, 'Receptor proteins found in the nuclear membrane responsible for regulation of gene expression.': $i).
% 29.22/29.09  tff(decl_56457, type, 'nuclear receptor': $i).
% 29.22/29.09  tff(decl_56458, type, 'nuclear-receptor': $i).
% 29.22/29.09  tff(decl_56459, type, nuclear_response_1: $i > $o).
% 29.22/29.09  tff(decl_56460, type, 'Nuclear-Response': $i).
% 29.22/29.09  tff(decl_56461, type, 'During a cell signalling event, a cellular response which occurs in the nucleus of the cell.': $i).
% 29.22/29.09  tff(decl_56462, type, 'nuclear response': $i).
% 29.22/29.09  tff(decl_56463, type, 'nuclear-response': $i).
% 29.22/29.09  tff(decl_56464, type, nuclear_transmutation_1: $i > $o).
% 29.22/29.09  tff(decl_56465, type, 'Nuclear-Transmutation': $i).
% 29.22/29.09  tff(decl_56466, type, 'The process in which radioactive decay results in an atom of one element transforming into an atom of another element, through the loss of one or more protons.': $i).
% 29.22/29.09  tff(decl_56467, type, 'undergo nuclear transmutation': $i).
% 29.22/29.09  tff(decl_56468, type, 'nuclear transmutation': $i).
% 29.22/29.09  tff(decl_56469, type, 'nuclear-transmutation': $i).
% 29.22/29.09  tff(decl_56470, type, fn_nuclear_transmutation_1: $i > $i).
% 29.22/29.09  tff(decl_56471, type, fn_nuclear_transmutation_3: $i > $i).
% 29.22/29.09  tff(decl_56472, type, fn_nuclear_transmutation_4: $i > $i).
% 29.22/29.09  tff(decl_56473, type, fn_nuclear_transmutation_5: $i > $i).
% 29.22/29.09  tff(decl_56474, type, fn_nuclear_transmutation_6: $i > $i).
% 29.22/29.09  tff(decl_56475, type, fn_nuclear_transmutation_9: $i > $i).
% 29.22/29.09  tff(decl_56476, type, fn_nuclear_transmutation_10: $i > $i).
% 29.22/29.09  tff(decl_56477, type, fn_nuclear_transmutation_11: $i > $i).
% 29.22/29.09  tff(decl_56478, type, fn_nuclear_transmutation_12: $i > $i).
% 29.22/29.09  tff(decl_56479, type, fn_nuclear_transmutation_13: $i > $i).
% 29.22/29.09  tff(decl_56480, type, fn_nuclear_transmutation_14: $i > $i).
% 29.22/29.09  tff(decl_56481, type, fn_nuclear_transmutation_15: $i > $i).
% 29.22/29.09  tff(decl_56482, type, fn_nuclear_transmutation_16: $i > $i).
% 29.22/29.09  tff(decl_56483, type, fn_radioactivity_4: $i > $i).
% 29.22/29.09  tff(decl_56484, type, fn_nuclear_transmutation_8: $i > $i).
% 29.22/29.09  tff(decl_56485, type, fn_nuclear_transmutation_7: $i > $i).
% 29.22/29.09  tff(decl_56486, type, fn_radioactivity_2: $i > $i).
% 29.22/29.09  tff(decl_56487, type, fn_radioactivity_5: $i > $i).
% 29.22/29.09  tff(decl_56488, type, fn_radioactivity_7: $i > $i).
% 29.22/29.09  tff(decl_56489, type, fn_radioactivity_3: $i > $i).
% 29.22/29.09  tff(decl_56490, type, 'Nuclear-Transplantation': $i).
% 29.22/29.09  tff(decl_56491, type, 'A process in which the nucleus from one cell is transplanted to a cell from which the original nucleus has been removed.': $i).
% 29.22/29.09  tff(decl_56492, type, 'nuclear-transplantation': $i).
% 29.22/29.09  tff(decl_56493, type, fn_nuclear_transplantation_4: $i > $i).
% 29.22/29.09  tff(decl_56494, type, fn_nuclear_transplantation_5: $i > $i).
% 29.22/29.09  tff(decl_56495, type, nuclear_transplantation_in_animal_1: $i > $o).
% 29.22/29.09  tff(decl_56496, type, fn_nuclear_transplantation_in_animal_3: $i > $i).
% 29.22/29.09  tff(decl_56497, type, fn_nuclear_transplantation_in_animal_2: $i > $i).
% 29.22/29.09  tff(decl_56498, type, 'Nuclear-Transplantation-In-Animal': $i).
% 29.22/29.09  tff(decl_56499, type, 'The technique of placing a nucleus from another source into an enucleated animal cell is called nuclear transplantation in animal.': $i).
% 29.22/29.09  tff(decl_56500, type, 'nuclear transplantation in animal': $i).
% 29.22/29.09  tff(decl_56501, type, 'nuclear-transplantation-in-animal': $i).
% 29.22/29.09  tff(decl_56502, type, nuclear_transplantation_in_animal_zygote_1: $i > $o).
% 29.22/29.09  tff(decl_56503, type, fn_nuclear_transplantation_in_animal_zygote_3: $i > $i).
% 29.22/29.09  tff(decl_56504, type, fn_nuclear_transplantation_in_animal_zygote_2: $i > $i).
% 29.22/29.09  tff(decl_56505, type, 'Nuclear-Transplantation-In-Animal-Zygote': $i).
% 29.22/29.09  tff(decl_56506, type, 'The technique of placing a nucleus from another source into an enucleated animal zygote.': $i).
% 29.22/29.09  tff(decl_56507, type, 'nuclear transplantation in animal zygote': $i).
% 29.22/29.09  tff(decl_56508, type, 'nuclear-transplantation-in-animal-zygote': $i).
% 29.22/29.09  tff(decl_56509, type, nuclear_transplantation_in_unfertilized_animal_egg_cell_1: $i > $o).
% 29.22/29.09  tff(decl_56510, type, fn_nuclear_transplantation_in_unfertilized_animal_egg_cell_4: $i > $i).
% 29.22/29.09  tff(decl_56511, type, fn_nuclear_transplantation_in_unfertilized_animal_egg_cell_3: $i > $i).
% 29.22/29.09  tff(decl_56512, type, 'Nuclear-Transplantation-In-Unfertilized-Animal-Egg-Cell': $i).
% 29.22/29.09  tff(decl_56513, type, 'The technique of placing a nucleus from another source into an enucleated unfertilized animal egg cell.': $i).
% 29.22/29.09  tff(decl_56514, type, 'nuclear transplantation in unfertilized animal egg cell': $i).
% 29.22/29.09  tff(decl_56515, type, 'nuclear-transplantation-in-unfertilized-animal-egg-cell': $i).
% 29.22/29.09  tff(decl_56516, type, fn_nuclear_transplantation_in_unfertilized_animal_egg_cell_2: $i > $i).
% 29.22/29.09  tff(decl_56517, type, nucleariid_1: $i > $o).
% 29.22/29.09  tff(decl_56518, type, 'Nucleariid': $i).
% 29.22/29.09  tff(decl_56519, type, 'A type of amoeboid protist that is more closely related to fungi than to other protists': $i).
% 29.22/29.09  tff(decl_56520, type, nucleariid: $i).
% 29.22/29.09  tff(decl_56521, type, 'Nuclease': $i).
% 29.22/29.09  tff(decl_56522, type, 'A nuclease is a type of enzyme specialized for hydrolysis of nucleic acids resulting in the removal of single nucleotides or complete dissassociation of the entire molecule.': $i).
% 29.22/29.09  tff(decl_56523, type, 'dna cutting enzyme': $i).
% 29.22/29.09  tff(decl_56524, type, 'dna-cutting-enzyme': $i).
% 29.22/29.09  tff(decl_56525, type, nuclease: $i).
% 29.22/29.09  tff(decl_56526, type, fn_nuclease_6: $i > $i).
% 29.22/29.09  tff(decl_56527, type, 'Nucleic-Acid': $i).
% 29.22/29.09  tff(decl_56528, type, 'Nucleic-acid is a macromolecule made up of nucleotides. It is one of the structural components of the cell. In an organism, it serves as a carrier of genetic information': $i).
% 29.22/29.09  tff(decl_56529, type, 'heredity material': $i).
% 29.22/29.09  tff(decl_56530, type, 'heredity-material': $i).
% 29.22/29.09  tff(decl_56531, type, 'hereditary material': $i).
% 29.22/29.09  tff(decl_56532, type, 'hereditary-material': $i).
% 29.22/29.09  tff(decl_56533, type, 'nucleic acid': $i).
% 29.22/29.09  tff(decl_56534, type, 'nucleic-acid': $i).
% 29.22/29.09  tff(decl_56535, type, fn_nucleic_acid_2: $i > $i).
% 29.22/29.09  tff(decl_56536, type, fn_nucleic_acid_3: $i > $i).
% 29.22/29.09  tff(decl_56537, type, fn_nucleic_acid_4: $i > $i).
% 29.22/29.09  tff(decl_56538, type, fn_nucleic_acid_13: $i > $i).
% 29.22/29.09  tff(decl_56539, type, fn_nucleic_acid_14: $i > $i).
% 29.22/29.09  tff(decl_56540, type, fn_nucleic_acid_17: $i > $i).
% 29.22/29.09  tff(decl_56541, type, fn_nucleic_acid_18: $i > $i).
% 29.22/29.09  tff(decl_56542, type, fn_nucleic_acid_21: $i > $i).
% 29.22/29.09  tff(decl_56543, type, fn_phosphodiester_bond_3: $i > $i).
% 29.22/29.09  tff(decl_56544, type, fn_phosphodiester_bond_2: $i > $i).
% 29.22/29.09  tff(decl_56545, type, fn_phosphodiester_bond_28: $i > $i).
% 29.22/29.09  tff(decl_56546, type, fn_phosphodiester_bond_34: $i > $i).
% 29.22/29.09  tff(decl_56547, type, fn_phosphodiester_bond_22: $i > $i).
% 29.22/29.09  tff(decl_56548, type, fn_nucleic_acid_5: $i > $i).
% 29.22/29.09  tff(decl_56549, type, fn_nucleic_acid_hybridization_3: $i > $i).
% 29.22/29.09  tff(decl_56550, type, 'Nucleic-Acid-Hybridization': $i).
% 29.22/29.09  tff(decl_56551, type, 'Process of hydrogen bonding a nucleic acid probe marked with a radioactive isotope to a gene, to mark that gene and make it visible in an autoradiograph.': $i).
% 29.22/29.09  tff(decl_56552, type, 'nucleic acid hybridization': $i).
% 29.22/29.09  tff(decl_56553, type, 'nucleic-acid-hybridization': $i).
% 29.22/29.09  tff(decl_56554, type, fn_nucleic_acid_hybridization_1: $i > $i).
% 29.22/29.09  tff(decl_56555, type, fn_nucleic_acid_hybridization_4: $i > $i).
% 29.22/29.09  tff(decl_56556, type, fn_nucleic_acid_hybridization_5: $i > $i).
% 29.22/29.09  tff(decl_56557, type, fn_nucleic_acid_hybridization_6: $i > $i).
% 29.22/29.09  tff(decl_56558, type, fn_nucleic_acid_hybridization_7: $i > $i).
% 29.22/29.09  tff(decl_56559, type, fn_nucleic_acid_hybridization_8: $i > $i).
% 29.22/29.09  tff(decl_56560, type, fn_nucleic_acid_hybridization_9: $i > $i).
% 29.22/29.09  tff(decl_56561, type, fn_nucleic_acid_hybridization_10: $i > $i).
% 29.22/29.09  tff(decl_56562, type, fn_nucleic_acid_hybridization_11: $i > $i).
% 29.22/29.09  tff(decl_56563, type, fn_nucleic_acid_hybridization_12: $i > $i).
% 29.22/29.09  tff(decl_56564, type, fn_nucleic_acid_hybridization_13: $i > $i).
% 29.22/29.09  tff(decl_56565, type, fn_nucleic_acid_probe_6: $i > $i).
% 29.22/29.09  tff(decl_56566, type, fn_nucleic_acid_probe_5: $i > $i).
% 29.22/29.09  tff(decl_56567, type, 'Nucleic-Acid-Probe': $i).
% 29.22/29.09  tff(decl_56568, type, 'Nucleic acid sequence made up of a single nucleic acid strand and a radioactive isotope marker.': $i).
% 29.22/29.09  tff(decl_56569, type, 'radioactive isotope tag': $i).
% 29.22/29.09  tff(decl_56570, type, 'radioactive tag': $i).
% 29.22/29.09  tff(decl_56571, type, 'radioactive nucleic acid': $i).
% 29.22/29.09  tff(decl_56572, type, 'radioactive nucleotide': $i).
% 29.22/29.09  tff(decl_56573, type, 'nucleic acid probe': $i).
% 29.22/29.09  tff(decl_56574, type, 'nucleic-acid-probe': $i).
% 29.22/29.09  tff(decl_56575, type, fn_nucleic_acid_probe_2: $i > $i).
% 29.22/29.09  tff(decl_56576, type, nucleic_acid_strand_0: $i).
% 29.22/29.09  tff(decl_56577, type, 'Nucleic-Acid-Process': $i).
% 29.22/29.09  tff(decl_56578, type, 'A cellular process related to DNA, RNA and other nucleic acids.': $i).
% 29.22/29.09  tff(decl_56579, type, 'nucleic acid process': $i).
% 29.22/29.09  tff(decl_56580, type, 'nucleic-acid-process': $i).
% 29.22/29.09  tff(decl_56581, type, 'Nucleic-Acid-Region': $i).
% 29.22/29.09  tff(decl_56582, type, 'A region of a nucleic acid.': $i).
% 29.22/29.09  tff(decl_56583, type, 'nucleic acid region': $i).
% 29.22/29.09  tff(decl_56584, type, 'nucleic-acid-region': $i).
% 29.22/29.09  tff(decl_56585, type, 'Nucleic-Acid-Sequence': $i).
% 29.22/29.09  tff(decl_56586, type, 'A sequence of nucleotides in a strand of DNA or RNA.': $i).
% 29.22/29.09  tff(decl_56587, type, 'nucleotide sequence': $i).
% 29.22/29.09  tff(decl_56588, type, 'nucleotide-sequence': $i).
% 29.22/29.09  tff(decl_56589, type, polynucleotide: $i).
% 29.22/29.09  tff(decl_56590, type, 'nucleic acid sequence': $i).
% 29.22/29.09  tff(decl_56591, type, 'nucleic-acid-sequence': $i).
% 29.22/29.09  tff(decl_56592, type, fn_nucleic_acid_sequence_7: $i > $i).
% 29.22/29.09  tff(decl_56593, type, fn_nucleic_acid_sequence_8: $i > $i).
% 29.22/29.09  tff(decl_56594, type, 'Nucleic-Acid-Strand': $i).
% 29.22/29.09  tff(decl_56595, type, 'Nucleic acid in a strand form.': $i).
% 29.22/29.09  tff(decl_56596, type, 'nucleic acid strand': $i).
% 29.22/29.09  tff(decl_56597, type, 'nucleic-acid-strand': $i).
% 29.22/29.09  tff(decl_56598, type, 'Nucleoid': $i).
% 29.22/29.09  tff(decl_56599, type, 'The nucleoid is an irregularly-shaped dense region of chromosomal DNA  (genetic material) within the prokaryotic cell. Further, it lacks a nuclear membrane.': $i).
% 29.22/29.09  tff(decl_56600, type, nucleoid: $i).
% 29.22/29.09  tff(decl_56601, type, fn_nucleoid_1: $i > $i).
% 29.22/29.09  tff(decl_56602, type, 'Nucleolus': $i).
% 29.22/29.09  tff(decl_56603, type, 'Nucleolus is a dense non-membranous region inside nucleus which is the site of synthesis of ribosomal subunits by joining of rRNA and proteins. They are present single or more than one in a nucleus': $i).
% 29.22/29.09  tff(decl_56604, type, nucleoli: $i).
% 29.22/29.09  tff(decl_56605, type, nucleolus: $i).
% 29.22/29.09  tff(decl_56606, type, fn_nucleolus_1: $i > $i).
% 29.22/29.09  tff(decl_56607, type, fn_nucleolus_2: $i > $i).
% 29.22/29.09  tff(decl_56608, type, synthesis_of_rrna_1: $i > $o).
% 29.22/29.09  tff(decl_56609, type, fn_nucleolus_3: $i > $i).
% 29.22/29.09  tff(decl_56610, type, fn_nucleolus_4: $i > $i).
% 29.22/29.09  tff(decl_56611, type, synthesis_of_ribosomal_subunit_1: $i > $o).
% 29.22/29.09  tff(decl_56612, type, fn_nucleolus_5: $i > $i).
% 29.22/29.09  tff(decl_56613, type, fn_nucleolus_6: $i > $i).
% 29.22/29.09  tff(decl_56614, type, fn_synthesis_of_ribosomal_subunit_10: $i > $i).
% 29.22/29.09  tff(decl_56615, type, fn_synthesis_of_ribosomal_subunit_2: $i > $i).
% 29.22/29.09  tff(decl_56616, type, fn_synthesis_of_ribosomal_subunit_9: $i > $i).
% 29.22/29.09  tff(decl_56617, type, fn_synthesis_of_ribosomal_subunit_8: $i > $i).
% 29.22/29.09  tff(decl_56618, type, fn_synthesis_of_rrna_4: $i > $i).
% 29.22/29.09  tff(decl_56619, type, nucleosidase_1: $i > $o).
% 29.22/29.09  tff(decl_56620, type, 'Nucleosidase': $i).
% 29.22/29.09  tff(decl_56621, type, 'Enzyme which catalyzes the hydrolyis of nucleosides.': $i).
% 29.22/29.09  tff(decl_56622, type, nucleosidase: $i).
% 29.22/29.09  tff(decl_56623, type, 'Nucleoside': $i).
% 29.22/29.09  tff(decl_56624, type, 'Nucleosides consist of nitrogenous bases (purine or pyrimidine) bound to a five carbon sugar (ribose or deoxyribose.) Also refers to the portion of a nucelotide without the phosphate group.': $i).
% 29.22/29.09  tff(decl_56625, type, nucleoside: $i).
% 29.22/29.09  tff(decl_56626, type, fn_nucleoside_1: $i > $i).
% 29.22/29.09  tff(decl_56627, type, fn_nucleoside_2: $i > $i).
% 29.22/29.09  tff(decl_56628, type, fn_nucleoside_3: $i > $i).
% 29.22/29.09  tff(decl_56629, type, fn_nucleoside_4: $i > $i).
% 29.22/29.09  tff(decl_56630, type, fn_nucleoside_13: $i > $i).
% 29.22/29.09  tff(decl_56631, type, fn_nucleoside_14: $i > $i).
% 29.22/29.09  tff(decl_56632, type, fn_nucleoside_15: $i > $i).
% 29.22/29.09  tff(decl_56633, type, fn_nucleoside_16: $i > $i).
% 29.22/29.09  tff(decl_56634, type, fn_nucleoside_17: $i > $i).
% 29.22/29.09  tff(decl_56635, type, fn_nucleoside_18: $i > $i).
% 29.22/29.09  tff(decl_56636, type, fn_nucleoside_19: $i > $i).
% 29.22/29.09  tff(decl_56637, type, fn_pentose_20: $i > $i).
% 29.22/29.09  tff(decl_56638, type, fn_pentose_9: $i > $i).
% 29.22/29.09  tff(decl_56639, type, fn_pentose_14: $i > $i).
% 29.22/29.09  tff(decl_56640, type, 'Nucleoside-Diphosphate': $i).
% 29.22/29.09  tff(decl_56641, type, 'The nucleoside diphosphate has a nitrogen base and two phosphate groups.': $i).
% 29.22/29.09  tff(decl_56642, type, 'nucleoside diphosphate': $i).
% 29.22/29.09  tff(decl_56643, type, 'nucleoside-diphosphate': $i).
% 29.22/29.09  tff(decl_56644, type, fn_nucleoside_diphosphate_2: $i > $i).
% 29.22/29.09  tff(decl_56645, type, fn_nucleoside_diphosphate_5: $i > $i).
% 29.22/29.09  tff(decl_56646, type, fn_nucleoside_diphosphate_6: $i > $i).
% 29.22/29.09  tff(decl_56647, type, fn_nucleoside_diphosphate_7: $i > $i).
% 29.22/29.09  tff(decl_56648, type, fn_nucleoside_diphosphate_9: $i > $i).
% 29.22/29.09  tff(decl_56649, type, fn_nucleoside_diphosphate_10: $i > $i).
% 29.22/29.09  tff(decl_56650, type, fn_nucleoside_diphosphate_11: $i > $i).
% 29.22/29.09  tff(decl_56651, type, fn_nucleoside_diphosphate_12: $i > $i).
% 29.22/29.09  tff(decl_56652, type, fn_nucleoside_diphosphate_13: $i > $i).
% 29.22/29.09  tff(decl_56653, type, fn_nucleoside_diphosphate_14: $i > $i).
% 29.22/29.09  tff(decl_56654, type, fn_nucleoside_diphosphate_15: $i > $i).
% 29.22/29.09  tff(decl_56655, type, fn_nucleoside_diphosphate_16: $i > $i).
% 29.22/29.09  tff(decl_56656, type, fn_nucleoside_diphosphate_17: $i > $i).
% 29.22/29.09  tff(decl_56657, type, fn_nucleoside_diphosphate_18: $i > $i).
% 29.22/29.09  tff(decl_56658, type, fn_nucleoside_diphosphate_19: $i > $i).
% 29.22/29.09  tff(decl_56659, type, fn_nucleoside_diphosphate_20: $i > $i).
% 29.22/29.09  tff(decl_56660, type, fn_nucleoside_diphosphate_22: $i > $i).
% 29.22/29.09  tff(decl_56661, type, fn_nucleoside_diphosphate_23: $i > $i).
% 29.22/29.09  tff(decl_56662, type, fn_nucleoside_diphosphate_24: $i > $i).
% 29.22/29.09  tff(decl_56663, type, fn_nucleoside_diphosphate_31: $i > $i).
% 29.22/29.09  tff(decl_56664, type, fn_nucleoside_diphosphate_42: $i > $i).
% 29.22/29.09  tff(decl_56665, type, fn_nucleoside_diphosphate_46: $i > $i).
% 29.22/29.09  tff(decl_56666, type, fn_pentose_19: $i > $i).
% 29.22/29.09  tff(decl_56667, type, fn_nucleotide_32: $i > $i).
% 29.22/29.09  tff(decl_56668, type, fn_nucleotide_21: $i > $i).
% 29.22/29.09  tff(decl_56669, type, fn_nucleotide_22: $i > $i).
% 29.22/29.09  tff(decl_56670, type, fn_nucleotide_28: $i > $i).
% 29.22/29.09  tff(decl_56671, type, fn_nucleotide_8: $i > $i).
% 29.22/29.09  tff(decl_56672, type, fn_nucleotide_7: $i > $i).
% 29.22/29.09  tff(decl_56673, type, 'Nucleoside-Monophosphate': $i).
% 29.22/29.09  tff(decl_56674, type, 'Nucleoside Monophosphate has a nitrogenous base and a phosphate group': $i).
% 29.22/29.09  tff(decl_56675, type, 'nucleoside monophosphate': $i).
% 29.22/29.09  tff(decl_56676, type, 'nucleoside-monophosphate': $i).
% 29.22/29.09  tff(decl_56677, type, fn_nucleoside_monophosphate_2: $i > $i).
% 29.22/29.09  tff(decl_56678, type, fn_nucleoside_monophosphate_31: $i > $i).
% 29.22/29.09  tff(decl_56679, type, fn_nucleoside_monophosphate_37: $i > $i).
% 29.22/29.09  tff(decl_56680, type, fn_nucleoside_monophosphate_38: $i > $i).
% 29.22/29.09  tff(decl_56681, type, fn_nucleoside_monophosphate_41: $i > $i).
% 29.22/29.09  tff(decl_56682, type, fn_nucleoside_monophosphate_46: $i > $i).
% 29.22/29.09  tff(decl_56683, type, fn_nucleoside_monophosphate_47: $i > $i).
% 29.22/29.09  tff(decl_56684, type, fn_nucleoside_monophosphate_48: $i > $i).
% 29.22/29.09  tff(decl_56685, type, fn_nucleoside_monophosphate_49: $i > $i).
% 29.22/29.09  tff(decl_56686, type, fn_nucleoside_monophosphate_50: $i > $i).
% 29.22/29.09  tff(decl_56687, type, fn_nucleoside_monophosphate_51: $i > $i).
% 29.22/29.09  tff(decl_56688, type, fn_nucleoside_monophosphate_53: $i > $i).
% 29.22/29.09  tff(decl_56689, type, fn_nucleoside_monophosphate_58: $i > $i).
% 29.22/29.09  tff(decl_56690, type, fn_nucleoside_monophosphate_59: $i > $i).
% 29.22/29.09  tff(decl_56691, type, fn_nucleoside_monophosphate_68: $i > $i).
% 29.22/29.09  tff(decl_56692, type, fn_nucleoside_monophosphate_69: $i > $i).
% 29.22/29.09  tff(decl_56693, type, fn_nucleoside_monophosphate_70: $i > $i).
% 29.22/29.09  tff(decl_56694, type, fn_nucleotide_19: $i > $i).
% 29.22/29.09  tff(decl_56695, type, fn_nucleotide_27: $i > $i).
% 29.22/29.09  tff(decl_56696, type, fn_nucleoside_monophosphate_66: $i > $i).
% 29.22/29.09  tff(decl_56697, type, fn_nucleoside_monophosphate_67: $i > $i).
% 29.22/29.09  tff(decl_56698, type, 'Nucleoside-Triphosphate': $i).
% 29.22/29.09  tff(decl_56699, type, 'The nucleoside diphosphate has a nitrogen base and three phosphate groups.': $i).
% 29.22/29.09  tff(decl_56700, type, 'nucleoside triphosphate': $i).
% 29.22/29.09  tff(decl_56701, type, 'nucleoside-triphosphate': $i).
% 29.22/29.09  tff(decl_56702, type, fn_nucleoside_triphosphate_26: $i > $i).
% 29.22/29.09  tff(decl_56703, type, fn_nucleoside_triphosphate_9: $i > $i).
% 29.22/29.09  tff(decl_56704, type, fn_nucleotide_31: $i > $i).
% 29.22/29.09  tff(decl_56705, type, fn_nucleotide_18: $i > $i).
% 29.22/29.09  tff(decl_56706, type, 'Nucleosome': $i).
% 29.22/29.09  tff(decl_56707, type, 'The basic, bead-like unit of DNA packing in eukaryotes, consisting of a segment of DNA wound around a protein core composed of two copies of each of four types of histone.': $i).
% 29.22/29.09  tff(decl_56708, type, nucleosome: $i).
% 29.22/29.09  tff(decl_56709, type, fn_nucleosome_1: $i > $i).
% 29.22/29.09  tff(decl_56710, type, fn_nucleosome_5: $i > $i).
% 29.22/29.09  tff(decl_56711, type, fn_nucleosome_6: $i > $i).
% 29.22/29.09  tff(decl_56712, type, fn_nucleosome_7: $i > $i).
% 29.22/29.09  tff(decl_56713, type, fn_nucleosome_8: $i > $i).
% 29.22/29.09  tff(decl_56714, type, fn_nucleosome_9: $i > $i).
% 29.22/29.09  tff(decl_56715, type, fn_nucleosome_10: $i > $i).
% 29.22/29.09  tff(decl_56716, type, fn_nucleosome_11: $i > $i).
% 29.22/29.09  tff(decl_56717, type, fn_nucleosome_12: $i > $i).
% 29.22/29.09  tff(decl_56718, type, fn_nucleosome_13: $i > $i).
% 29.22/29.09  tff(decl_56719, type, fn_rna_polymerase_29: $i > $i).
% 29.22/29.09  tff(decl_56720, type, 'Enzyme which catalyzes the hydrolyis of nucleotides.': $i).
% 29.22/29.09  tff(decl_56721, type, nucleotidase: $i).
% 29.22/29.09  tff(decl_56722, type, 'Nucleotide': $i).
% 29.22/29.09  tff(decl_56723, type, 'Nucleotides are molecules that, when joined together, make up the structural units of RNA and DNA.': $i).
% 29.22/29.09  tff(decl_56724, type, nucleotide: $i).
% 29.22/29.09  tff(decl_56725, type, fn_nucleotide_1: $i > $i).
% 29.22/29.09  tff(decl_56726, type, fn_nucleotide_11: $i > $i).
% 29.22/29.09  tff(decl_56727, type, fn_nucleotide_14: $i > $i).
% 29.22/29.09  tff(decl_56728, type, fn_nucleotide_17: $i > $i).
% 29.22/29.09  tff(decl_56729, type, fn_nucleotide_37: $i > $i).
% 29.22/29.09  tff(decl_56730, type, fn_nucleotide_38: $i > $i).
% 29.22/29.09  tff(decl_56731, type, fn_nucleotide_39: $i > $i).
% 29.22/29.09  tff(decl_56732, type, fn_nucleotide_40: $i > $i).
% 29.22/29.09  tff(decl_56733, type, fn_nucleotide_41: $i > $i).
% 29.22/29.09  tff(decl_56734, type, fn_nucleotide_42: $i > $i).
% 29.22/29.09  tff(decl_56735, type, fn_nucleotide_43: $i > $i).
% 29.22/29.09  tff(decl_56736, type, fn_nucleotide_44: $i > $i).
% 29.22/29.09  tff(decl_56737, type, fn_nucleotide_45: $i > $i).
% 29.22/29.09  tff(decl_56738, type, fn_nucleotide_46: $i > $i).
% 29.22/29.09  tff(decl_56739, type, fn_nucleotide_47: $i > $i).
% 29.22/29.09  tff(decl_56740, type, fn_nucleotide_48: $i > $i).
% 29.22/29.09  tff(decl_56741, type, fn_nucleotide_49: $i > $i).
% 29.22/29.09  tff(decl_56742, type, fn_nucleotide_50: $i > $i).
% 29.22/29.09  tff(decl_56743, type, fn_nucleotide_51: $i > $i).
% 29.22/29.09  tff(decl_56744, type, fn_phosphate_group_23: $i > $i).
% 29.22/29.09  tff(decl_56745, type, fn_phosphate_group_7: $i > $i).
% 29.22/29.09  tff(decl_56746, type, fn_nucleotide_excision_repair_12: $i > $i).
% 29.22/29.09  tff(decl_56747, type, 'Nucleotide-Excision-Repair': $i).
% 29.22/29.09  tff(decl_56748, type, 'A DNA repair mechanism in which a damaged segment of DNA is removed and the the complementary strand is used as a template to construct the correct sequence.': $i).
% 29.22/29.09  tff(decl_56749, type, 'nucleotide excision repair': $i).
% 29.22/29.09  tff(decl_56750, type, 'nucleotide-excision-repair': $i).
% 29.22/29.09  tff(decl_56751, type, fn_nucleotide_excision_repair_2: $i > $i).
% 29.22/29.09  tff(decl_56752, type, fn_nucleotide_excision_repair_3: $i > $i).
% 29.22/29.09  tff(decl_56753, type, fn_nucleotide_excision_repair_4: $i > $i).
% 29.22/29.09  tff(decl_56754, type, fn_nucleotide_excision_repair_5: $i > $i).
% 29.22/29.09  tff(decl_56755, type, fn_nucleotide_excision_repair_6: $i > $i).
% 29.22/29.09  tff(decl_56756, type, fn_nucleotide_excision_repair_7: $i > $i).
% 29.22/29.09  tff(decl_56757, type, fn_nucleotide_excision_repair_8: $i > $i).
% 29.22/29.09  tff(decl_56758, type, fn_nucleotide_excision_repair_9: $i > $i).
% 29.22/29.09  tff(decl_56759, type, fn_nucleotide_excision_repair_10: $i > $i).
% 29.22/29.09  tff(decl_56760, type, fn_nucleotide_excision_repair_11: $i > $i).
% 29.22/29.09  tff(decl_56761, type, fn_repair_enzyme_1: $i > $i).
% 29.22/29.09  tff(decl_56762, type, 'Nucleus': $i).
% 29.22/29.09  tff(decl_56763, type, 'A membrane bound organelle found in eukaryotic cells which contains most of the  genetic material of the cell.': $i).
% 29.22/29.09  tff(decl_56764, type, nuclei: $i).
% 29.22/29.09  tff(decl_56765, type, 'control center': $i).
% 29.22/29.09  tff(decl_56766, type, nucleus: $i).
% 29.22/29.09  tff(decl_56767, type, fn_nucleus_2: $i > $i).
% 29.22/29.09  tff(decl_56768, type, fn_nucleus_4: $i > $i).
% 29.22/29.09  tff(decl_56769, type, fn_nucleus_7: $i > $i).
% 29.22/29.09  tff(decl_56770, type, fn_nucleus_10: $i > $i).
% 29.22/29.09  tff(decl_56771, type, fn_nucleus_12: $i > $i).
% 29.22/29.09  tff(decl_56772, type, snrnp_1: $i > $o).
% 29.22/29.09  tff(decl_56773, type, fn_snrnp_3: $i > $i).
% 29.22/29.09  tff(decl_56774, type, nucleolus_0: $i).
% 29.22/29.09  tff(decl_56775, type, 'Number': $i).
% 29.22/29.09  tff(decl_56776, type, number: $i).
% 29.22/29.09  tff(decl_56777, type, number_field_1: $i > $o).
% 29.22/29.09  tff(decl_56778, type, 'Number-Field': $i).
% 29.22/29.09  tff(decl_56779, type, 'a message field whose content is a numeric constant': $i).
% 29.22/29.09  tff(decl_56780, type, 'field of number': $i).
% 29.22/29.09  tff(decl_56781, type, 'number field': $i).
% 29.22/29.09  tff(decl_56782, type, 'number-field': $i).
% 29.22/29.09  tff(decl_56783, type, text_field_1: $i > $o).
% 29.22/29.09  tff(decl_56784, type, 'Nurse-cell': $i).
% 29.22/29.09  tff(decl_56785, type, 'Specialized macrophages residing in the bone marrow that assist in the development of red blood cells. They absorb the nuclei of immature red blood cells and may provide growth factors to help the red blood cells mature.': $i).
% 29.22/29.09  tff(decl_56786, type, 'cell of nurse': $i).
% 29.22/29.09  tff(decl_56787, type, 'nurse cell': $i).
% 29.22/29.09  tff(decl_56788, type, 'nurse-cell': $i).
% 29.22/29.09  tff(decl_56789, type, fn_nurse_cell_1: $i > $i).
% 29.22/29.09  tff(decl_56790, type, nut_1: $i > $o).
% 29.22/29.09  tff(decl_56791, type, 'Nut': $i).
% 29.22/29.09  tff(decl_56792, type, 'Nut is the fruit of some plants and has a hard, dry outer shell.': $i).
% 29.22/29.09  tff(decl_56793, type, nut: $i).
% 29.22/29.09  tff(decl_56794, type, fn_nut_1: $i > $i).
% 29.22/29.09  tff(decl_56795, type, 'Nutrient': $i).
% 29.22/29.09  tff(decl_56796, type, 'A nutritive substance or ingredient.': $i).
% 29.22/29.09  tff(decl_56797, type, 'A chemical that is used in an organism\\s metabolism and is obtained from the environment. Different organisms have different nutrient requirements.': $i).
% 29.22/29.09  tff(decl_56798, type, 'Nutrition': $i).
% 29.22/29.09  tff(decl_56799, type, 'The processes by which an organism ingests and obtains nutrients from food.': $i).
% 29.22/29.09  tff(decl_56800, type, 'obtain nutrition': $i).
% 29.22/29.09  tff(decl_56801, type, nutrify: $i).
% 29.22/29.09  tff(decl_56802, type, nutrition: $i).
% 29.22/29.09  tff(decl_56803, type, 'Nutritional-Requirement': $i).
% 29.22/29.09  tff(decl_56804, type, 'Chemicals and elements that are needed by an organism in order to sustain healthy life.': $i).
% 29.22/29.09  tff(decl_56805, type, 'nutritional requirement': $i).
% 29.22/29.09  tff(decl_56806, type, 'nutritional-requirement': $i).
% 29.22/29.09  tff(decl_56807, type, fn_nutritional_requirement_1: $i > $i).
% 29.22/29.09  tff(decl_56808, type, 'O-Minus-2': $i).
% 29.22/29.09  tff(decl_56809, type, 'Ion of oxygen atom with a 2- charge.': $i).
% 29.22/29.09  tff(decl_56810, type, 'oxygen minus': $i).
% 29.22/29.09  tff(decl_56811, type, 'o minus 2': $i).
% 29.22/29.09  tff(decl_56812, type, 'o-minus-2': $i).
% 29.22/29.09  tff(decl_56813, type, fn_o_minus_2_1: $i > $i).
% 29.22/29.09  tff(decl_56814, type, fn_o_minus_2_3: $i > $i).
% 29.22/29.09  tff(decl_56815, type, fn_o_minus_2_2: $i > $i).
% 29.22/29.09  tff(decl_56816, type, 'O2-Gas': $i).
% 29.22/29.09  tff(decl_56817, type, 'Diatomic oxygen gas, which is the elemental form of oxygen most commonly found on Earth.': $i).
% 29.22/29.09  tff(decl_56818, type, 'o2 gas': $i).
% 29.22/29.09  tff(decl_56819, type, 'o2-gas': $i).
% 29.22/29.09  tff(decl_56820, type, fn_o2_gas_1: $i > $i).
% 29.22/29.09  tff(decl_56821, type, ob_gene_1: $i > $o).
% 29.22/29.09  tff(decl_56822, type, 'Ob-Gene': $i).
% 29.22/29.09  tff(decl_56823, type, 'Gene which codes for the leptin. This gene and its product, originally discovered in mice, plays an important role in the regulation of appetitie in mammals.': $i).
% 29.22/29.09  tff(decl_56824, type, 'gene of ob': $i).
% 29.22/29.09  tff(decl_56825, type, 'ob gene': $i).
% 29.22/29.09  tff(decl_56826, type, 'ob-gene': $i).
% 29.22/29.09  tff(decl_56827, type, fn_ob_gene_1: $i > $i).
% 29.22/29.09  tff(decl_56828, type, fn_ob_gene_2: $i > $i).
% 29.22/29.09  tff(decl_56829, type, fn_ob_gene_3: $i > $i).
% 29.22/29.09  tff(decl_56830, type, obesity_1: $i > $o).
% 29.22/29.09  tff(decl_56831, type, 'Obesity': $i).
% 29.22/29.09  tff(decl_56832, type, 'A medical condition in which excess body fat can have have an adverse effect on health, including reduced life expectancy.': $i).
% 29.22/29.09  tff(decl_56833, type, obesity: $i).
% 29.22/29.09  tff(decl_56834, type, 'Obligate-Aerobe': $i).
% 29.22/29.09  tff(decl_56835, type, 'An organism that requires oxygen and cannot live without it.': $i).
% 29.22/29.09  tff(decl_56836, type, 'obligate aerobe': $i).
% 29.22/29.09  tff(decl_56837, type, 'obligate-aerobe': $i).
% 29.22/29.09  tff(decl_56838, type, 'Obligate-Anaerobe': $i).
% 29.22/29.09  tff(decl_56839, type, 'A cell or organism only capable of anaerobic respiration.': $i).
% 29.22/29.09  tff(decl_56840, type, 'obligate anaerobe': $i).
% 29.22/29.09  tff(decl_56841, type, 'obligate-anaerobe': $i).
% 29.22/29.09  tff(decl_56842, type, observations_1: $i > $o).
% 29.22/29.09  tff(decl_56843, type, 'Observations': $i).
% 29.22/29.09  tff(decl_56844, type, 'The result of recording data by study, use of the senses, or use of scientific instruments.': $i).
% 29.22/29.09  tff(decl_56845, type, 'scientific observation': $i).
% 29.22/29.09  tff(decl_56846, type, observation: $i).
% 29.22/29.09  tff(decl_56847, type, 'Obstruct': $i).
% 29.22/29.09  tff(decl_56848, type, 'Obtain': $i).
% 29.22/29.09  tff(decl_56849, type, obtain: $i).
% 29.22/29.09  tff(decl_56850, type, occipital_lobe_1: $i > $o).
% 29.22/29.09  tff(decl_56851, type, 'Occipital-Lobe': $i).
% 29.22/29.09  tff(decl_56852, type, 'Posterior region of the cerebral cortex responsible for vision processing.': $i).
% 29.22/29.09  tff(decl_56853, type, 'occipital lobe': $i).
% 29.22/29.09  tff(decl_56854, type, 'occipital-lobe': $i).
% 29.22/29.09  tff(decl_56855, type, 'Ocean': $i).
% 29.22/29.09  tff(decl_56856, type, 'A major body of salt water and the largest marine environment on Earth.': $i).
% 29.22/29.09  tff(decl_56857, type, ocean: $i).
% 29.22/29.09  tff(decl_56858, type, fn_ocean_2: $i > $i).
% 29.22/29.09  tff(decl_56859, type, fn_ocean_3: $i > $i).
% 29.22/29.09  tff(decl_56860, type, fn_ocean_4: $i > $i).
% 29.22/29.09  tff(decl_56861, type, fn_ocean_5: $i > $i).
% 29.22/29.09  tff(decl_56862, type, fn_ocean_6: $i > $i).
% 29.22/29.09  tff(decl_56863, type, fn_ocean_7: $i > $i).
% 29.22/29.09  tff(decl_56864, type, fn_ocean_8: $i > $i).
% 29.22/29.09  tff(decl_56865, type, fn_ocean_9: $i > $i).
% 29.22/29.09  tff(decl_56866, type, fn_ocean_10: $i > $i).
% 29.22/29.09  tff(decl_56867, type, fn_ocean_11: $i > $i).
% 29.22/29.09  tff(decl_56868, type, fn_ocean_12: $i > $i).
% 29.22/29.09  tff(decl_56869, type, oceanic_zone_1: $i > $o).
% 29.22/29.09  tff(decl_56870, type, fn_ocean_13: $i > $i).
% 29.22/29.09  tff(decl_56871, type, fn_ocean_14: $i > $i).
% 29.22/29.09  tff(decl_56872, type, aquatic_zone_0: $i).
% 29.22/29.09  tff(decl_56873, type, ocean_acidification_1: $i > $o).
% 29.22/29.09  tff(decl_56874, type, 'Ocean-Acidification': $i).
% 29.22/29.09  tff(decl_56875, type, 'A decrease in the pH of the ocean due to accumulation of anthropogenic CO2 in the atmosphere. CO2 dissolves from the atmosphere into the ocean and reacts with water to form carbonic acid, which then dissociates into bicarbonate (HCO3-) and a hydrogen ion (H+). It is the increase in the concentration of H+ that lowers pH.': $i).
% 29.22/29.09  tff(decl_56876, type, acidify: $i).
% 29.22/29.09  tff(decl_56877, type, 'acidification of ocean': $i).
% 29.22/29.09  tff(decl_56878, type, 'ocean acidification': $i).
% 29.22/29.09  tff(decl_56879, type, 'ocean-acidification': $i).
% 29.22/29.09  tff(decl_56880, type, fn_ocean_acidification_1: $i > $i).
% 29.22/29.09  tff(decl_56881, type, fn_ocean_acidification_5: $i > $i).
% 29.22/29.09  tff(decl_56882, type, fn_ocean_acidification_6: $i > $i).
% 29.22/29.09  tff(decl_56883, type, fn_ocean_acidification_7: $i > $i).
% 29.22/29.09  tff(decl_56884, type, fn_ocean_acidification_11: $i > $i).
% 29.22/29.09  tff(decl_56885, type, fn_ocean_acidification_13: $i > $i).
% 29.22/29.09  tff(decl_56886, type, fn_ocean_acidification_14: $i > $i).
% 29.22/29.09  tff(decl_56887, type, fn_ocean_acidification_15: $i > $i).
% 29.22/29.09  tff(decl_56888, type, fn_ocean_acidification_19: $i > $i).
% 29.22/29.09  tff(decl_56889, type, fn_ocean_acidification_20: $i > $i).
% 29.22/29.09  tff(decl_56890, type, fn_ocean_acidification_21: $i > $i).
% 29.22/29.09  tff(decl_56891, type, fn_ocean_acidification_22: $i > $i).
% 29.22/29.09  tff(decl_56892, type, fn_ocean_acidification_23: $i > $i).
% 29.22/29.09  tff(decl_56893, type, fn_ocean_acidification_24: $i > $i).
% 29.22/29.09  tff(decl_56894, type, fn_ocean_acidification_25: $i > $i).
% 29.22/29.09  tff(decl_56895, type, fn_ocean_acidification_26: $i > $i).
% 29.22/29.09  tff(decl_56896, type, fn_ocean_acidification_27: $i > $i).
% 29.22/29.09  tff(decl_56897, type, fn_ocean_acidification_29: $i > $i).
% 29.22/29.09  tff(decl_56898, type, fn_ocean_acidification_30: $i > $i).
% 29.22/29.09  tff(decl_56899, type, fn_ocean_acidification_31: $i > $i).
% 29.22/29.09  tff(decl_56900, type, fn_ocean_acidification_32: $i > $i).
% 29.22/29.09  tff(decl_56901, type, fn_ocean_acidification_33: $i > $i).
% 29.22/29.09  tff(decl_56902, type, fn_ocean_acidification_34: $i > $i).
% 29.22/29.09  tff(decl_56903, type, fn_ocean_acidification_35: $i > $i).
% 29.22/29.09  tff(decl_56904, type, fn_ocean_acidification_36: $i > $i).
% 29.22/29.09  tff(decl_56905, type, fn_ocean_acidification_37: $i > $i).
% 29.22/29.09  tff(decl_56906, type, fn_ocean_acidification_38: $i > $i).
% 29.22/29.09  tff(decl_56907, type, fn_ocean_acidification_39: $i > $i).
% 29.22/29.09  tff(decl_56908, type, fn_ocean_acidification_40: $i > $i).
% 29.22/29.09  tff(decl_56909, type, fn_ocean_acidification_41: $i > $i).
% 29.22/29.09  tff(decl_56910, type, fn_ocean_acidification_42: $i > $i).
% 29.22/29.09  tff(decl_56911, type, fn_ocean_acidification_44: $i > $i).
% 29.22/29.09  tff(decl_56912, type, fn_ocean_acidification_45: $i > $i).
% 29.22/29.09  tff(decl_56913, type, shell_calcification_1: $i > $o).
% 29.22/29.09  tff(decl_56914, type, fn_ocean_acidification_46: $i > $i).
% 29.22/29.09  tff(decl_56915, type, fn_ocean_acidification_47: $i > $i).
% 29.22/29.09  tff(decl_56916, type, fn_ocean_acidification_48: $i > $i).
% 29.22/29.09  tff(decl_56917, type, fn_ocean_acidification_49: $i > $i).
% 29.22/29.09  tff(decl_56918, type, fn_ocean_acidification_50: $i > $i).
% 29.22/29.09  tff(decl_56919, type, fn_ocean_acidification_51: $i > $i).
% 29.22/29.09  tff(decl_56920, type, fn_ocean_acidification_52: $i > $i).
% 29.22/29.09  tff(decl_56921, type, fn_ocean_acidification_53: $i > $i).
% 29.22/29.09  tff(decl_56922, type, fn_ocean_acidification_54: $i > $i).
% 29.22/29.09  tff(decl_56923, type, fn_ocean_acidification_55: $i > $i).
% 29.22/29.09  tff(decl_56924, type, fn_ocean_acidification_56: $i > $i).
% 29.22/29.09  tff(decl_56925, type, fn_ocean_acidification_57: $i > $i).
% 29.22/29.09  tff(decl_56926, type, fn_ocean_acidification_58: $i > $i).
% 29.22/29.09  tff(decl_56927, type, fn_ocean_acidification_59: $i > $i).
% 29.22/29.09  tff(decl_56928, type, fn_ocean_acidification_60: $i > $i).
% 29.22/29.09  tff(decl_56929, type, fn_ocean_acidification_61: $i > $i).
% 29.22/29.09  tff(decl_56930, type, fn_aquatic_ecosystem_1: $i > $i).
% 29.22/29.09  tff(decl_56931, type, fn_aquatic_ecosystem_2: $i > $i).
% 29.22/29.09  tff(decl_56932, type, 'Carbonate_Ion': $i).
% 29.22/29.09  tff(decl_56933, type, 'Bicarbonate_Ion': $i).
% 29.22/29.09  tff(decl_56934, type, 'Hydrgen_Ion': $i).
% 29.22/29.09  tff(decl_56935, type, solution_0: $i).
% 29.22/29.09  tff(decl_56936, type, fn_ocean_acidification_28: $i > $i).
% 29.22/29.09  tff(decl_56937, type, fn_ocean_acidification_43: $i > $i).
% 29.22/29.09  tff(decl_56938, type, fn_ocean_acidification_62: $i > $i).
% 29.22/29.09  tff(decl_56939, type, fn_ocean_acidification_18: $i > $i).
% 29.22/29.09  tff(decl_56940, type, fn_ocean_acidification_17: $i > $i).
% 29.22/29.09  tff(decl_56941, type, 'Oceanic-Pelagic-Zone': $i).
% 29.22/29.09  tff(decl_56942, type, 'The waters of the ocean beyond the continental shelf, far from shore and mixed by currents.': $i).
% 29.22/29.09  tff(decl_56943, type, 'oceanic pelagic zone': $i).
% 29.22/29.09  tff(decl_56944, type, 'oceanic-pelagic-zone': $i).
% 29.22/29.09  tff(decl_56945, type, 'Oceanic-Zone': $i).
% 29.22/29.09  tff(decl_56946, type, 'Most of the ocean\\s waters far from shore, constantly mixed by ocean currents.': $i).
% 29.22/29.09  tff(decl_56947, type, 'zone of oceanic': $i).
% 29.22/29.09  tff(decl_56948, type, 'oceanic zone': $i).
% 29.22/29.09  tff(decl_56949, type, 'oceanic-zone': $i).
% 29.22/29.09  tff(decl_56950, type, ocotillo_1: $i > $o).
% 29.22/29.09  tff(decl_56951, type, 'Ocotillo': $i).
% 29.22/29.09  tff(decl_56952, type, 'Ocotillo is a desert plant common in the southwestern region of the United States and northern Mexico.': $i).
% 29.22/29.09  tff(decl_56953, type, ocotillo: $i).
% 29.22/29.09  tff(decl_56954, type, octopus_1: $i > $o).
% 29.22/29.09  tff(decl_56955, type, 'Octopus': $i).
% 29.22/29.09  tff(decl_56956, type, 'A cephalopod mollusc that has four pairs of suckered arms arranged around a central mouth. Octopuses are highly cephalized.': $i).
% 29.22/29.09  tff(decl_56957, type, octopus: $i).
% 29.22/29.09  tff(decl_56958, type, 'Odonata': $i).
% 29.22/29.09  tff(decl_56959, type, 'An order of insects that includes dragonflies and damselflies.': $i).
% 29.22/29.09  tff(decl_56960, type, odonata: $i).
% 29.22/29.09  tff(decl_56961, type, odorant_1: $i > $o).
% 29.22/29.09  tff(decl_56962, type, 'Odorant': $i).
% 29.22/29.09  tff(decl_56963, type, 'Any molecule in the air that can be detected by the olfactory system\\s sensory receptors.': $i).
% 29.22/29.09  tff(decl_56964, type, 'aroma compound': $i).
% 29.22/29.09  tff(decl_56965, type, 'aroma-compound': $i).
% 29.22/29.09  tff(decl_56966, type, fn_odorant_1: $i > $i).
% 29.22/29.09  tff(decl_56967, type, fn_odorant_2: $i > $i).
% 29.22/29.09  tff(decl_56968, type, fn_odorant_3: $i > $i).
% 29.22/29.09  tff(decl_56969, type, fn_odorant_4: $i > $i).
% 29.22/29.09  tff(decl_56970, type, 'Offspring': $i).
% 29.22/29.09  tff(decl_56971, type, 'An offspring is the descendent or progeny of an organism.': $i).
% 29.22/29.09  tff(decl_56972, type, baby: $i).
% 29.22/29.09  tff(decl_56973, type, child: $i).
% 29.22/29.09  tff(decl_56974, type, progeny: $i).
% 29.22/29.09  tff(decl_56975, type, descendant: $i).
% 29.22/29.09  tff(decl_56976, type, offspring: $i).
% 29.22/29.09  tff(decl_56977, type, 'Oil': $i).
% 29.22/29.09  tff(decl_56978, type, 'It is a form of Lipid': $i).
% 29.22/29.09  tff(decl_56979, type, oil: $i).
% 29.22/29.09  tff(decl_56980, type, oil_substance_1: $i > $o).
% 29.22/29.09  tff(decl_56981, type, fn_oil_substance_2: $i > $i).
% 29.22/29.09  tff(decl_56982, type, 'Oil-Substance': $i).
% 29.22/29.09  tff(decl_56983, type, 'An oil is any substance that is liquid at ambient temperatures and is hydrophobic but soluble in organic solvents.': $i).
% 29.22/29.09  tff(decl_56984, type, 'substance of oil': $i).
% 29.22/29.09  tff(decl_56985, type, 'oil substance': $i).
% 29.22/29.09  tff(decl_56986, type, 'oil-substance': $i).
% 29.22/29.09  tff(decl_56987, type, 'Okazaki-fragments': $i).
% 29.22/29.09  tff(decl_56988, type, 'Short pieces of DNA created on the lagging strand during DNA replication.': $i).
% 29.22/29.09  tff(decl_56989, type, 'okazaki fragment': $i).
% 29.22/29.09  tff(decl_56990, type, 'okazaki-fragment': $i).
% 29.22/29.09  tff(decl_56991, type, 'okazaki fragments': $i).
% 29.22/29.09  tff(decl_56992, type, fn_okazaki_fragments_1: $i > $i).
% 29.22/29.09  tff(decl_56993, type, fn_okazaki_fragments_2: $i > $i).
% 29.22/29.09  tff(decl_56994, type, fn_synthesis_of_dna_strand_1: $i > $i).
% 29.22/29.09  tff(decl_56995, type, oleander_1: $i > $o).
% 29.22/29.09  tff(decl_56996, type, 'Oleander': $i).
% 29.22/29.09  tff(decl_56997, type, 'A poisonous Eurasian evergreen shrub (Nerium oleander) having fragrant white, rose, or purple flowers, whorled leaves, and long follicles containing numerous comose seeds.': $i).
% 29.22/29.09  tff(decl_56998, type, oleander: $i).
% 29.22/29.09  tff(decl_56999, type, 'Olfaction': $i).
% 29.22/29.09  tff(decl_57000, type, 'Olfaction is the special sense which is otherwise known as the sense of smell.': $i).
% 29.22/29.09  tff(decl_57001, type, smelling: $i).
% 29.22/29.09  tff(decl_57002, type, smell: $i).
% 29.22/29.09  tff(decl_57003, type, 'olfactory use': $i).
% 29.22/29.09  tff(decl_57004, type, olfaction: $i).
% 29.22/29.09  tff(decl_57005, type, 'Oligochaete': $i).
% 29.22/29.09  tff(decl_57006, type, 'Subclass of the phylum Annelida characterized by the presence of few hairs (setae) on each of their body segments.': $i).
% 29.22/29.09  tff(decl_57007, type, oligochaete: $i).
% 29.22/29.09  tff(decl_57008, type, 'Oligodendrocyte': $i).
% 29.22/29.09  tff(decl_57009, type, 'A type of glial cell found in the central nervous sytem of some vertebrates. Oligodendrocytes form the insulating myelin sheath that covers the axons of neurons.': $i).
% 29.22/29.09  tff(decl_57010, type, oligodendrocyte: $i).
% 29.22/29.09  tff(decl_57011, type, 'Oligosaccharide': $i).
% 29.22/29.09  tff(decl_57012, type, 'Oligosaccharides are polymers containing a small number (typically three to ten) of component sugars (monosaccharides)': $i).
% 29.22/29.09  tff(decl_57013, type, 'oligo saccharide': $i).
% 29.22/29.09  tff(decl_57014, type, 'oligo-saccharide': $i).
% 29.22/29.09  tff(decl_57015, type, oligosaccharide: $i).
% 29.22/29.09  tff(decl_57016, type, fn_oligosaccharide_1: $i > $i).
% 29.22/29.09  tff(decl_57017, type, 'Oligosaccharin': $i).
% 29.22/29.09  tff(decl_57018, type, 'Any of a group of regulatory polysaccharides derived from plant cell walls that induces a physiological response in nearby cells. Oligosaccharins control functions such as growth, defense against disease, development, and reproduction.': $i).
% 29.22/29.09  tff(decl_57019, type, oligosaccharin: $i).
% 29.22/29.09  tff(decl_57020, type, 'Oligotrophic-Lake': $i).
% 29.22/29.09  tff(decl_57021, type, 'A lake that is nutrient-poor and thus has low productivity. The waters of an oligotrophic lake are clear, with very few phytoplankton.': $i).
% 29.22/29.09  tff(decl_57022, type, 'oligotrophic lake': $i).
% 29.22/29.09  tff(decl_57023, type, 'oligotrophic-lake': $i).
% 29.22/29.09  tff(decl_57024, type, olive_oil_1: $i > $o).
% 29.22/29.09  tff(decl_57025, type, 'Olive-Oil': $i).
% 29.22/29.09  tff(decl_57026, type, 'The fat obtained from olive fruit of the olive plant is called olive oil.': $i).
% 29.22/29.09  tff(decl_57027, type, 'oil of olive': $i).
% 29.22/29.09  tff(decl_57028, type, 'olive oil': $i).
% 29.22/29.09  tff(decl_57029, type, 'olive-oil': $i).
% 29.22/29.09  tff(decl_57030, type, omasum_1: $i > $o).
% 29.22/29.09  tff(decl_57031, type, 'Omasum': $i).
% 29.22/29.09  tff(decl_57032, type, 'The third chamber in a ruminant\\s digestive system in which water is removed from the cud.': $i).
% 29.22/29.09  tff(decl_57033, type, omasum: $i).
% 29.22/29.09  tff(decl_57034, type, 'Omega-3-Fatty-Acid': $i).
% 29.22/29.09  tff(decl_57035, type, 'Omega 3 fatty acids are essential fatty acid required for normal growth in children and protect adults against cardiovascular disease. Omega 3 fatty acid are found in Fatty fish, certain nuts and vegetable oils.': $i).
% 29.22/29.09  tff(decl_57036, type, 'omega 3 fatty acid': $i).
% 29.22/29.09  tff(decl_57037, type, 'omega-3-fatty-acid': $i).
% 29.22/29.09  tff(decl_57038, type, 'Ommatidium': $i).
% 29.22/29.09  tff(decl_57039, type, 'The functional unit of the compound eye found in arthropods and some polychaete worms.': $i).
% 29.22/29.09  tff(decl_57040, type, ommatidia: $i).
% 29.22/29.09  tff(decl_57041, type, ommatidium: $i).
% 29.22/29.09  tff(decl_57042, type, omnivore_1: $i > $o).
% 29.22/29.09  tff(decl_57043, type, 'Omnivore': $i).
% 29.22/29.09  tff(decl_57044, type, 'An animal which obtains energy and nutrients by consuming both heterotrophs and autotrophs.': $i).
% 29.22/29.09  tff(decl_57045, type, omnivore: $i).
% 29.22/29.09  tff(decl_57046, type, fn_omnivore_1: $i > $i).
% 29.22/29.09  tff(decl_57047, type, fn_omnivore_2: $i > $i).
% 29.22/29.09  tff(decl_57048, type, fn_omnivore_3: $i > $i).
% 29.22/29.09  tff(decl_57049, type, fn_omnivore_4: $i > $i).
% 29.22/29.09  tff(decl_57050, type, fn_omnivore_5: $i > $i).
% 29.22/29.09  tff(decl_57051, type, fn_omnivore_8: $i > $i).
% 29.22/29.09  tff(decl_57052, type, fn_omnivore_9: $i > $i).
% 29.22/29.09  tff(decl_57053, type, fn_omnivore_10: $i > $i).
% 29.22/29.09  tff(decl_57054, type, fn_omnivore_11: $i > $i).
% 29.22/29.09  tff(decl_57055, type, fn_omnivore_12: $i > $i).
% 29.22/29.09  tff(decl_57056, type, 'Oncogene': $i).
% 29.22/29.09  tff(decl_57057, type, 'A gene found in viral or cellular genomes that is involved in triggering molecular events that can lead to cancer.': $i).
% 29.22/29.09  tff(decl_57058, type, 'cancer causing gene': $i).
% 29.22/29.09  tff(decl_57059, type, oncogene: $i).
% 29.22/29.09  tff(decl_57060, type, fn_oncogene_2: $i > $i).
% 29.22/29.09  tff(decl_57061, type, fn_oncogene_3: $i > $i).
% 29.22/29.09  tff(decl_57062, type, fn_oncogene_4: $i > $i).
% 29.22/29.09  tff(decl_57063, type, fn_oncogene_5: $i > $i).
% 29.22/29.09  tff(decl_57064, type, fn_oncogene_6: $i > $i).
% 29.22/29.09  tff(decl_57065, type, fn_oncogene_7: $i > $i).
% 29.22/29.09  tff(decl_57066, type, fn_oncogene_11: $i > $i).
% 29.22/29.09  tff(decl_57067, type, fn_oncogene_12: $i > $i).
% 29.22/29.09  tff(decl_57068, type, fn_oncogene_13: $i > $i).
% 29.22/29.09  tff(decl_57069, type, fn_oncogene_14: $i > $i).
% 29.22/29.09  tff(decl_57070, type, fn_oncogene_15: $i > $i).
% 29.22/29.09  tff(decl_57071, type, fn_oncogene_16: $i > $i).
% 29.22/29.09  tff(decl_57072, type, proto_oncogene_1: $i > $o).
% 29.22/29.09  tff(decl_57073, type, fn_oncogene_17: $i > $i).
% 29.22/29.09  tff(decl_57074, type, fn_oncogene_19: $i > $i).
% 29.22/29.09  tff(decl_57075, type, fn_oncogene_20: $i > $i).
% 29.22/29.09  tff(decl_57076, type, fn_oncogene_21: $i > $i).
% 29.22/29.09  tff(decl_57077, type, fn_oncogene_22: $i > $i).
% 29.22/29.09  tff(decl_57078, type, fn_oncogene_23: $i > $i).
% 29.22/29.09  tff(decl_57079, type, fn_proto_oncogene_14: $i > $i).
% 29.22/29.09  tff(decl_57080, type, fn_proto_oncogene_5: $i > $i).
% 29.22/29.09  tff(decl_57081, type, one_gene_one_enzyme_hypothesis_1: $i > $o).
% 29.22/29.09  tff(decl_57082, type, 'One-Gene-One-Enzyme-Hypothesis': $i).
% 29.22/29.09  tff(decl_57083, type, 'One Gene One Enzyme hypothesis is concerned with the hypothesis that a gene has a function of dictating the synthesis of a specific enzyme. This hypothesis was given by Beadle and tatum': $i).
% 29.22/29.09  tff(decl_57084, type, 'one gene one enzyme': $i).
% 29.22/29.09  tff(decl_57085, type, 'one-gene-one-enzyme': $i).
% 29.22/29.09  tff(decl_57086, type, 'one gene one enzyme hypothesis': $i).
% 29.22/29.09  tff(decl_57087, type, 'one gene-one enzyme hypothesis': $i).
% 29.22/29.09  tff(decl_57088, type, 'one-gene-one-enzyme-hypothesis': $i).
% 29.22/29.09  tff(decl_57089, type, one_gene_one_polypeptide_1: $i > $o).
% 29.22/29.09  tff(decl_57090, type, 'One-Gene-One-Polypeptide': $i).
% 29.22/29.09  tff(decl_57091, type, 'One Gene One Polypeptide hypothesis is concerned with the hypothesis that a gene has a function of dictating the synthesis of a specific Polypeptide. This hypothesis was a restatement of Beadle and Tatum\\s one gene one enzyme hypothesis. This hypothesis was based on the fact that many enzymes being protein are constructed from two or more different polypeptide chains': $i).
% 29.22/29.09  tff(decl_57092, type, 'one gene one polypeptide': $i).
% 29.22/29.09  tff(decl_57093, type, 'one-gene-one-polypeptide': $i).
% 29.22/29.09  tff(decl_57094, type, 'one gene-one polypeptide': $i).
% 29.22/29.09  tff(decl_57095, type, oocyte_1: $i > $o).
% 29.22/29.09  tff(decl_57096, type, 'Oocyte': $i).
% 29.22/29.09  tff(decl_57097, type, 'In animals, a female germ cell; an immature egg.': $i).
% 29.22/29.09  tff(decl_57098, type, oocyte: $i).
% 29.22/29.09  tff(decl_57099, type, 'Oogenesis': $i).
% 29.22/29.09  tff(decl_57100, type, 'The production of an ovum, or female gamete.': $i).
% 29.22/29.09  tff(decl_57101, type, 'female process of gametogenesis': $i).
% 29.22/29.09  tff(decl_57102, type, 'gametogenesis in females': $i).
% 29.22/29.09  tff(decl_57103, type, oogenesis: $i).
% 29.22/29.09  tff(decl_57104, type, fn_oogenesis_1: $i > $i).
% 29.22/29.09  tff(decl_57105, type, fn_oogenesis_2: $i > $i).
% 29.22/29.09  tff(decl_57106, type, fn_oogenesis_3: $i > $i).
% 29.22/29.09  tff(decl_57107, type, primary_oocyte_1: $i > $o).
% 29.22/29.09  tff(decl_57108, type, fn_oogenesis_4: $i > $i).
% 29.22/29.09  tff(decl_57109, type, secondary_oocyte_1: $i > $o).
% 29.22/29.09  tff(decl_57110, type, fn_oogenesis_5: $i > $i).
% 29.22/29.09  tff(decl_57111, type, fn_oogenesis_6: $i > $i).
% 29.22/29.09  tff(decl_57112, type, fn_oogenesis_7: $i > $i).
% 29.22/29.09  tff(decl_57113, type, fn_oogenesis_8: $i > $i).
% 29.22/29.09  tff(decl_57114, type, fn_oogenesis_9: $i > $i).
% 29.22/29.09  tff(decl_57115, type, fn_oogenesis_10: $i > $i).
% 29.22/29.09  tff(decl_57116, type, secondary_oocyte_0: $i).
% 29.22/29.09  tff(decl_57117, type, oogenesis_in_human_1: $i > $o).
% 29.22/29.09  tff(decl_57118, type, 'Oogenesis-In-Human': $i).
% 29.22/29.09  tff(decl_57119, type, 'The process in which ova, the female gamete, are produced in humans.': $i).
% 29.22/29.09  tff(decl_57120, type, 'oogenesis in human': $i).
% 29.22/29.09  tff(decl_57121, type, 'oogenesis-in-human': $i).
% 29.22/29.09  tff(decl_57122, type, fn_oogenesis_in_human_1: $i > $i).
% 29.22/29.09  tff(decl_57123, type, oogonium_1: $i > $o).
% 29.22/29.09  tff(decl_57124, type, 'Oogonium': $i).
% 29.22/29.09  tff(decl_57125, type, 'A cell that gives rise to oocytes via mitotic division.': $i).
% 29.22/29.09  tff(decl_57126, type, oogonia: $i).
% 29.22/29.09  tff(decl_57127, type, oogonium: $i).
% 29.22/29.09  tff(decl_57128, type, 'Oomycete': $i).
% 29.22/29.09  tff(decl_57129, type, 'One of a lineage of fungus-like microbes, often called water molds, that are filamentous in form and have an absorptive lifestyle. Many are plant pathogens but most are saprobes.': $i).
% 29.22/29.09  tff(decl_57130, type, oomycete: $i).
% 29.22/29.09  tff(decl_57131, type, oomycota_1: $i > $o).
% 29.22/29.09  tff(decl_57132, type, 'Oomycota': $i).
% 29.22/29.09  tff(decl_57133, type, 'The taxonomic class that includes the oomycetes.': $i).
% 29.22/29.09  tff(decl_57134, type, 'Open': $i).
% 29.22/29.09  tff(decl_57135, type, 'open up': $i).
% 29.22/29.09  tff(decl_57136, type, open_up: $i).
% 29.22/29.09  tff(decl_57137, type, afford: $i).
% 29.22/29.09  tff(decl_57138, type, unfasten: $i).
% 29.22/29.09  tff(decl_57139, type, fn_unblock_1: $i > $i).
% 29.22/29.09  tff(decl_57140, type, open_circulatory_system_1: $i > $o).
% 29.22/29.09  tff(decl_57141, type, 'Open-Circulatory-System': $i).
% 29.22/29.09  tff(decl_57142, type, 'A circulatory system in which the blood and the interstitial fluid are essentially the same, and the blood leaves vessels to flow directly over body tissues.': $i).
% 29.22/29.09  tff(decl_57143, type, 'open circulatory system': $i).
% 29.22/29.09  tff(decl_57144, type, 'open-circulatory-system': $i).
% 29.22/29.09  tff(decl_57145, type, 'Open-System': $i).
% 29.22/29.09  tff(decl_57146, type, 'A system in which energy (and often matter) can be transferred between the system and its surroundings.': $i).
% 29.22/29.09  tff(decl_57147, type, 'system of open': $i).
% 29.22/29.09  tff(decl_57148, type, 'open system': $i).
% 29.22/29.09  tff(decl_57149, type, 'open-system': $i).
% 29.22/29.09  tff(decl_57150, type, fn_open_system_1: $i > $i).
% 29.22/29.09  tff(decl_57151, type, fn_open_system_2: $i > $i).
% 29.22/29.09  tff(decl_57152, type, fn_open_system_3: $i > $i).
% 29.22/29.09  tff(decl_57153, type, opening_of_stoma_1: $i > $o).
% 29.22/29.09  tff(decl_57154, type, 'Opening-Of-Stoma': $i).
% 29.22/29.09  tff(decl_57155, type, 'Opening of the pores found in the leaf and stem epidermis of plants through which gas exchange and transpiration occurs.': $i).
% 29.22/29.09  tff(decl_57156, type, 'stoma opening': $i).
% 29.22/29.09  tff(decl_57157, type, 'stoma-opening': $i).
% 29.22/29.09  tff(decl_57158, type, 'opening of stoma': $i).
% 29.22/29.09  tff(decl_57159, type, 'opening-of-stoma': $i).
% 29.22/29.09  tff(decl_57160, type, fn_opening_of_stoma_1: $i > $i).
% 29.22/29.09  tff(decl_57161, type, fn_opening_of_stoma_2: $i > $i).
% 29.22/29.09  tff(decl_57162, type, fn_opening_of_stoma_3: $i > $i).
% 29.22/29.09  tff(decl_57163, type, fn_opening_of_stoma_4: $i > $i).
% 29.22/29.09  tff(decl_57164, type, fn_opening_of_stoma_5: $i > $i).
% 29.22/29.09  tff(decl_57165, type, fn_opening_of_stoma_6: $i > $i).
% 29.22/29.09  tff(decl_57166, type, fn_opening_of_stoma_7: $i > $i).
% 29.22/29.09  tff(decl_57167, type, fn_opening_of_stoma_8: $i > $i).
% 29.22/29.09  tff(decl_57168, type, fn_opening_of_stoma_9: $i > $i).
% 29.22/29.09  tff(decl_57169, type, fn_opening_of_stoma_10: $i > $i).
% 29.22/29.09  tff(decl_57170, type, fn_opening_of_stoma_11: $i > $i).
% 29.22/29.09  tff(decl_57171, type, fn_opening_of_stoma_12: $i > $i).
% 29.22/29.09  tff(decl_57172, type, fn_opening_of_stoma_15: $i > $i).
% 29.22/29.09  tff(decl_57173, type, fn_opening_of_stoma_16: $i > $i).
% 29.22/29.09  tff(decl_57174, type, fn_opening_of_stoma_17: $i > $i).
% 29.22/29.09  tff(decl_57175, type, fn_opening_of_stoma_18: $i > $i).
% 29.22/29.09  tff(decl_57176, type, fn_opening_of_stoma_19: $i > $i).
% 29.22/29.09  tff(decl_57177, type, fn_opening_of_stoma_20: $i > $i).
% 29.22/29.09  tff(decl_57178, type, fn_opening_of_stoma_21: $i > $i).
% 29.22/29.09  tff(decl_57179, type, fn_opening_of_stoma_22: $i > $i).
% 29.22/29.09  tff(decl_57180, type, fn_opening_of_stoma_23: $i > $i).
% 29.22/29.09  tff(decl_57181, type, fn_opening_of_stoma_24: $i > $i).
% 29.22/29.09  tff(decl_57182, type, fn_opening_of_stoma_25: $i > $i).
% 29.22/29.09  tff(decl_57183, type, turgid_cell_1: $i > $o).
% 29.22/29.09  tff(decl_57184, type, fn_opening_of_stoma_26: $i > $i).
% 29.22/29.09  tff(decl_57185, type, fn_opening_of_stoma_27: $i > $i).
% 29.22/29.09  tff(decl_57186, type, fn_opening_of_stoma_28: $i > $i).
% 29.22/29.09  tff(decl_57187, type, fn_opening_of_stoma_29: $i > $i).
% 29.22/29.09  tff(decl_57188, type, fn_opening_of_stoma_30: $i > $i).
% 29.22/29.09  tff(decl_57189, type, fn_opening_of_stoma_31: $i > $i).
% 29.22/29.09  tff(decl_57190, type, fn_opening_of_stoma_32: $i > $i).
% 29.22/29.09  tff(decl_57191, type, fn_opening_of_stoma_33: $i > $i).
% 29.22/29.09  tff(decl_57192, type, fn_opening_of_stoma_34: $i > $i).
% 29.22/29.09  tff(decl_57193, type, fn_opening_of_stoma_35: $i > $i).
% 29.22/29.09  tff(decl_57194, type, fn_opening_of_stoma_36: $i > $i).
% 29.22/29.09  tff(decl_57195, type, fn_opening_of_stoma_37: $i > $i).
% 29.22/29.09  tff(decl_57196, type, fn_opening_of_stoma_38: $i > $i).
% 29.22/29.09  tff(decl_57197, type, fn_opening_of_stoma_39: $i > $i).
% 29.22/29.09  tff(decl_57198, type, fn_opening_of_stoma_40: $i > $i).
% 29.22/29.09  tff(decl_57199, type, fn_opening_of_stoma_41: $i > $i).
% 29.22/29.09  tff(decl_57200, type, fn_opening_of_stoma_42: $i > $i).
% 29.22/29.09  tff(decl_57201, type, fn_opening_of_stoma_43: $i > $i).
% 29.22/29.09  tff(decl_57202, type, fn_opening_of_stoma_44: $i > $i).
% 29.22/29.09  tff(decl_57203, type, fn_opening_of_stoma_45: $i > $i).
% 29.22/29.09  tff(decl_57204, type, fn_opening_of_stoma_46: $i > $i).
% 29.22/29.09  tff(decl_57205, type, fn_opening_of_stoma_47: $i > $i).
% 29.22/29.09  tff(decl_57206, type, fn_opening_of_stoma_48: $i > $i).
% 29.22/29.09  tff(decl_57207, type, fn_opening_of_stoma_49: $i > $i).
% 29.22/29.09  tff(decl_57208, type, fn_opening_of_stoma_50: $i > $i).
% 29.22/29.09  tff(decl_57209, type, fn_opening_of_stoma_51: $i > $i).
% 29.22/29.09  tff(decl_57210, type, fn_opening_of_stoma_52: $i > $i).
% 29.22/29.09  tff(decl_57211, type, fn_opening_of_stoma_53: $i > $i).
% 29.22/29.09  tff(decl_57212, type, fn_opening_of_stoma_54: $i > $i).
% 29.22/29.09  tff(decl_57213, type, fn_opening_of_stoma_55: $i > $i).
% 29.22/29.09  tff(decl_57214, type, fn_opening_of_stoma_56: $i > $i).
% 29.22/29.09  tff(decl_57215, type, fn_opening_of_stoma_57: $i > $i).
% 29.22/29.09  tff(decl_57216, type, fn_turgid_cell_75: $i > $i).
% 29.22/29.09  tff(decl_57217, type, fn_turgid_cell_67: $i > $i).
% 29.22/29.09  tff(decl_57218, type, fn_turgid_cell_74: $i > $i).
% 29.22/29.09  tff(decl_57219, type, fn_opening_of_stoma_58: $i > $i).
% 29.22/29.09  tff(decl_57220, type, fn_opening_of_stoma_59: $i > $i).
% 29.22/29.09  tff(decl_57221, type, 'Operant-Conditioning': $i).
% 29.22/29.09  tff(decl_57222, type, 'A type of learning in which an animal learns to associate one of its own behaviors with either a reward or a punishment and thus modifies its behavior to seek the award or avoid the punishment.': $i).
% 29.22/29.09  tff(decl_57223, type, 'operant conditioning': $i).
% 29.22/29.09  tff(decl_57224, type, 'operant-conditioning': $i).
% 29.22/29.09  tff(decl_57225, type, operations_1: $i > $o).
% 29.22/29.09  tff(decl_57226, type, 'Operations': $i).
% 29.22/29.09  tff(decl_57227, type, operation: $i).
% 29.22/29.09  tff(decl_57228, type, 'business activity': $i).
% 29.22/29.09  tff(decl_57229, type, business_activity: $i).
% 29.22/29.09  tff(decl_57230, type, 'commercial activity': $i).
% 29.22/29.09  tff(decl_57231, type, commercial_activity: $i).
% 29.22/29.09  tff(decl_57232, type, operate: $i).
% 29.22/29.09  tff(decl_57233, type, 'Operator': $i).
% 29.22/29.09  tff(decl_57234, type, 'In bacterial and phage DNA, a sequence of nucleotides near the start of an operon to which an active repressor can attach which prevents RNA polymerase from attaching to the promter and transcribing the genes of the operon.': $i).
% 29.22/29.09  tff(decl_57235, type, 'on off switch': $i).
% 29.22/29.09  tff(decl_57236, type, 'on-off switch': $i).
% 29.22/29.09  tff(decl_57237, type, operator: $i).
% 29.22/29.09  tff(decl_57238, type, fn_operator_1: $i > $i).
% 29.22/29.09  tff(decl_57239, type, fn_operator_2: $i > $i).
% 29.22/29.09  tff(decl_57240, type, fn_operator_5: $i > $i).
% 29.22/29.09  tff(decl_57241, type, fn_operator_6: $i > $i).
% 29.22/29.09  tff(decl_57242, type, fn_operator_7: $i > $i).
% 29.22/29.09  tff(decl_57243, type, fn_operator_8: $i > $i).
% 29.22/29.09  tff(decl_57244, type, fn_operator_9: $i > $i).
% 29.22/29.09  tff(decl_57245, type, fn_operator_10: $i > $i).
% 29.22/29.09  tff(decl_57246, type, fn_operator_11: $i > $i).
% 29.22/29.09  tff(decl_57247, type, fn_operator_12: $i > $i).
% 29.22/29.09  tff(decl_57248, type, fn_operator_4: $i > $i).
% 29.22/29.09  tff(decl_57249, type, fn_operator_3: $i > $i).
% 29.22/29.09  tff(decl_57250, type, operator_is_off_1: $i > $o).
% 29.22/29.09  tff(decl_57251, type, 'Operator-Is-Off': $i).
% 29.22/29.09  tff(decl_57252, type, 'An operator whose state inhibits RNA polymerases\\ action.': $i).
% 29.22/29.09  tff(decl_57253, type, 'closed operator': $i).
% 29.22/29.09  tff(decl_57254, type, 'bound operator': $i).
% 29.22/29.09  tff(decl_57255, type, 'blocked operator': $i).
% 29.22/29.09  tff(decl_57256, type, 'operator is off': $i).
% 29.22/29.09  tff(decl_57257, type, 'operator-is-off': $i).
% 29.22/29.09  tff(decl_57258, type, operator_is_on_1: $i > $o).
% 29.22/29.09  tff(decl_57259, type, fn_operator_is_off_1: $i > $i).
% 29.22/29.09  tff(decl_57260, type, fn_operator_is_off_2: $i > $i).
% 29.22/29.09  tff(decl_57261, type, 'Operator-Is-On': $i).
% 29.22/29.09  tff(decl_57262, type, 'An operator whose state enables RNA polymerases\\ action.': $i).
% 29.22/29.09  tff(decl_57263, type, 'open operator': $i).
% 29.22/29.09  tff(decl_57264, type, 'unbound operator': $i).
% 29.22/29.09  tff(decl_57265, type, 'unblocked operator': $i).
% 29.22/29.09  tff(decl_57266, type, 'operator is on': $i).
% 29.22/29.09  tff(decl_57267, type, 'operator-is-on': $i).
% 29.22/29.09  tff(decl_57268, type, fn_operator_is_on_1: $i > $i).
% 29.22/29.09  tff(decl_57269, type, fn_operator_is_on_2: $i > $i).
% 29.22/29.09  tff(decl_57270, type, operculum_1: $i > $o).
% 29.22/29.09  tff(decl_57271, type, 'Operculum': $i).
% 29.22/29.09  tff(decl_57272, type, 'In bony fishes, a bony covering that protects the gills. Also, the structure that closes the shells of snails and some tubeworms.': $i).
% 29.22/29.09  tff(decl_57273, type, opercula: $i).
% 29.22/29.09  tff(decl_57274, type, operculum: $i).
% 29.22/29.09  tff(decl_57275, type, vertebrate_appendage_1: $i > $o).
% 29.22/29.09  tff(decl_57276, type, 'Operon': $i).
% 29.22/29.09  tff(decl_57277, type, 'A group of genes controlled by a single promotor, or regulator.': $i).
% 29.22/29.09  tff(decl_57278, type, operon: $i).
% 29.22/29.09  tff(decl_57279, type, fn_operon_7: $i > $i).
% 29.22/29.09  tff(decl_57280, type, fn_operon_8: $i > $i).
% 29.22/29.09  tff(decl_57281, type, fn_operon_9: $i > $i).
% 29.22/29.09  tff(decl_57282, type, fn_operon_11: $i > $i).
% 29.22/29.09  tff(decl_57283, type, fn_operon_12: $i > $i).
% 29.22/29.09  tff(decl_57284, type, fn_operon_13: $i > $i).
% 29.22/29.09  tff(decl_57285, type, fn_operon_15: $i > $i).
% 29.22/29.09  tff(decl_57286, type, fn_operon_16: $i > $i).
% 29.22/29.09  tff(decl_57287, type, fn_operon_17: $i > $i).
% 29.22/29.09  tff(decl_57288, type, fn_operon_18: $i > $i).
% 29.22/29.09  tff(decl_57289, type, fn_operon_20: $i > $i).
% 29.22/29.09  tff(decl_57290, type, fn_operon_21: $i > $i).
% 29.22/29.09  tff(decl_57291, type, 'Opiate': $i).
% 29.22/29.09  tff(decl_57292, type, 'A drug derived from opium.': $i).
% 29.22/29.09  tff(decl_57293, type, opiate: $i).
% 29.22/29.09  tff(decl_57294, type, fn_opiate_2: $i > $i).
% 29.22/29.09  tff(decl_57295, type, fn_opiate_3: $i > $i).
% 29.22/29.09  tff(decl_57296, type, fn_opiate_4: $i > $i).
% 29.22/29.09  tff(decl_57297, type, opisthokont_1: $i > $o).
% 29.22/29.09  tff(decl_57298, type, 'Opisthokont': $i).
% 29.22/29.09  tff(decl_57299, type, 'Member of the clade Opisthokonta, which are organisms whose common ancestor had a posterior flagellum used for locomotion. Animals, fungi, and some protists are all opisthokonts.': $i).
% 29.22/29.09  tff(decl_57300, type, opisthokont: $i).
% 29.22/29.09  tff(decl_57301, type, 'Opportunistic-Feeding': $i).
% 29.22/29.09  tff(decl_57302, type, 'The ability to feed on a variety of foods as they become available.': $i).
% 29.22/29.09  tff(decl_57303, type, 'opportunistic feeding': $i).
% 29.22/29.09  tff(decl_57304, type, 'opportunistic-feeding': $i).
% 29.22/29.09  tff(decl_57305, type, 'Opportunistic-Pathogen': $i).
% 29.22/29.09  tff(decl_57306, type, 'A pathogen that typically does not cause a disease within a host unless the host\\s immune system is compromised.': $i).
% 29.22/29.09  tff(decl_57307, type, 'opportunistic pathogen': $i).
% 29.22/29.09  tff(decl_57308, type, 'opportunistic-pathogen': $i).
% 29.22/29.09  tff(decl_57309, type, opposable_thumb_1: $i > $o).
% 29.22/29.09  tff(decl_57310, type, 'Opposable-Thumb': $i).
% 29.22/29.09  tff(decl_57311, type, 'A thumb that can bend in such a way that it can touch all of the remaining four fingers.': $i).
% 29.22/29.09  tff(decl_57312, type, thumb: $i).
% 29.22/29.09  tff(decl_57313, type, 'opposable thumb': $i).
% 29.22/29.09  tff(decl_57314, type, 'opposable-thumb': $i).
% 29.22/29.09  tff(decl_57315, type, opsin_1: $i > $o).
% 29.22/29.09  tff(decl_57316, type, 'Opsin': $i).
% 29.22/29.09  tff(decl_57317, type, 'One of a group of light-sensitive membrane proteins found in the photoreceptor cells of the retina.': $i).
% 29.22/29.09  tff(decl_57318, type, opsin: $i).
% 29.22/29.09  tff(decl_57319, type, fn_opsin_1: $i > $i).
% 29.22/29.09  tff(decl_57320, type, fn_opsin_2: $i > $i).
% 29.22/29.09  tff(decl_57321, type, fn_opsin_3: $i > $i).
% 29.22/29.09  tff(decl_57322, type, fn_opsin_4: $i > $i).
% 29.22/29.09  tff(decl_57323, type, fn_opsin_5: $i > $i).
% 29.22/29.09  tff(decl_57324, type, fn_opsin_6: $i > $i).
% 29.22/29.09  tff(decl_57325, type, fn_opsin_7: $i > $i).
% 29.22/29.09  tff(decl_57326, type, fn_opsin_8: $i > $i).
% 29.22/29.09  tff(decl_57327, type, fn_opsin_9: $i > $i).
% 29.22/29.09  tff(decl_57328, type, fn_opsin_10: $i > $i).
% 29.22/29.09  tff(decl_57329, type, fn_opsin_11: $i > $i).
% 29.22/29.09  tff(decl_57330, type, fn_opsin_12: $i > $i).
% 29.22/29.09  tff(decl_57331, type, fn_opsin_13: $i > $i).
% 29.22/29.09  tff(decl_57332, type, fn_opsin_14: $i > $i).
% 29.22/29.09  tff(decl_57333, type, fn_opsin_15: $i > $i).
% 29.22/29.09  tff(decl_57334, type, fn_opsin_16: $i > $i).
% 29.22/29.09  tff(decl_57335, type, fn_opsin_17: $i > $i).
% 29.22/29.09  tff(decl_57336, type, 'Optic-Chiasm': $i).
% 29.22/29.09  tff(decl_57337, type, 'The part of the brain where the left and right optic nerves partially cross. The right side of the brain receives information transmitted from the left visual feed of each eye, while the left side of the brain receives information from the right visual field of each eye.': $i).
% 29.22/29.09  tff(decl_57338, type, 'chiasm of optic': $i).
% 29.22/29.09  tff(decl_57339, type, 'optic chiasm': $i).
% 29.22/29.09  tff(decl_57340, type, 'optic-chiasm': $i).
% 29.22/29.09  tff(decl_57341, type, 'Optic-Nerve': $i).
% 29.22/29.09  tff(decl_57342, type, 'A bundle of neurons that carries sensory information from the retina to the brain.': $i).
% 29.22/29.09  tff(decl_57343, type, 'cranial nerve ii': $i).
% 29.22/29.09  tff(decl_57344, type, 'cranial-nerve-ii': $i).
% 29.22/29.09  tff(decl_57345, type, 'nerve of optic': $i).
% 29.22/29.09  tff(decl_57346, type, 'optic nerve': $i).
% 29.22/29.09  tff(decl_57347, type, 'optic-nerve': $i).
% 29.22/29.09  tff(decl_57348, type, 'Optical-Device': $i).
% 29.22/29.09  tff(decl_57349, type, 'An optical instrument either processes light waves to enhance an image for viewing, or analyzes light waves (or photons) to determine one of a number of characteristic properties.': $i).
% 29.22/29.09  tff(decl_57350, type, 'optical device': $i).
% 29.22/29.09  tff(decl_57351, type, 'optical-device': $i).
% 29.22/29.09  tff(decl_57352, type, optical_resolution_constant_1: $i > $o).
% 29.22/29.09  tff(decl_57353, type, 'Optical-Resolution-Constant': $i).
% 29.22/29.09  tff(decl_57354, type, 'optical resolution constant': $i).
% 29.22/29.09  tff(decl_57355, type, 'optical-resolution-constant': $i).
% 29.22/29.09  tff(decl_57356, type, optical_resolution_scale_1: $i > $o).
% 29.22/29.09  tff(decl_57357, type, 'Optical-Resolution-Scale': $i).
% 29.22/29.09  tff(decl_57358, type, 'optical resolution scale': $i).
% 29.22/29.09  tff(decl_57359, type, 'optical-resolution-scale': $i).
% 29.22/29.09  tff(decl_57360, type, 'Optical-Sectioning': $i).
% 29.22/29.09  tff(decl_57361, type, 'The process by which a suitably designed microscope can produce clear images of focal planes deep within a thick sample. This is used to reduce the need for thin sectioning using instruments such as the microtome.': $i).
% 29.22/29.09  tff(decl_57362, type, 'optical sectioning': $i).
% 29.22/29.09  tff(decl_57363, type, 'optical-sectioning': $i).
% 29.22/29.09  tff(decl_57364, type, fn_optical_sectioning_1: $i > $i).
% 29.22/29.09  tff(decl_57365, type, optimal_foraging_1: $i > $o).
% 29.22/29.09  tff(decl_57366, type, 'Optimal-Foraging': $i).
% 29.22/29.09  tff(decl_57367, type, 'The theory that foraging behavior is based on a compromise between the costs and benefits of feeding.': $i).
% 29.22/29.09  tff(decl_57368, type, 'optimal foraging': $i).
% 29.22/29.09  tff(decl_57369, type, 'optimal-foraging': $i).
% 29.22/29.09  tff(decl_57370, type, 'Oral-Cavity': $i).
% 29.22/29.09  tff(decl_57371, type, 'An animal\\s mouth.': $i).
% 29.22/29.09  tff(decl_57372, type, 'cavity of oral': $i).
% 29.22/29.09  tff(decl_57373, type, 'oral cavity': $i).
% 29.22/29.09  tff(decl_57374, type, 'oral-cavity': $i).
% 29.22/29.09  tff(decl_57375, type, 'Orange-Light': $i).
% 29.22/29.09  tff(decl_57376, type, 'The portion of the electromagnetic spectrum that can be detected as orange by the human eye, ranging in wavelength from about 590 nm to 620 nm.': $i).
% 29.22/29.09  tff(decl_57377, type, 'light of orange': $i).
% 29.22/29.09  tff(decl_57378, type, 'orange light': $i).
% 29.22/29.09  tff(decl_57379, type, 'orange-light': $i).
% 29.22/29.09  tff(decl_57380, type, fn_orange_light_4: $i > $i).
% 29.22/29.09  tff(decl_57381, type, fn_orange_light_5: $i > $i).
% 29.22/29.09  tff(decl_57382, type, fn_orange_light_7: $i > $i).
% 29.22/29.09  tff(decl_57383, type, fn_orange_light_10: $i > $i).
% 29.22/29.09  tff(decl_57384, type, "590.0e0": $i).
% 29.22/29.09  tff(decl_57385, type, "640.0e0": $i).
% 29.22/29.09  tff(decl_57386, type, fn_orange_light_9: $i > $i).
% 29.22/29.09  tff(decl_57387, type, fn_orange_light_6: $i > $i).
% 29.22/29.09  tff(decl_57388, type, 'Orbital': $i).
% 29.22/29.09  tff(decl_57389, type, 'The volume of space where an electron can be found 90% of the time.': $i).
% 29.22/29.09  tff(decl_57390, type, orbital: $i).
% 29.22/29.09  tff(decl_57391, type, fn_orbital_1: $i > $i).
% 29.22/29.09  tff(decl_57392, type, fn_orbital_2: $i > $i).
% 29.22/29.09  tff(decl_57393, type, fn_orbital_3: $i > $i).
% 29.22/29.09  tff(decl_57394, type, order_1: $i > $o).
% 29.22/29.09  tff(decl_57395, type, 'Order': $i).
% 29.22/29.09  tff(decl_57396, type, 'In Linnean classification, the taxonomic category below Class and above Family.': $i).
% 29.22/29.09  tff(decl_57397, type, 'Organ': $i).
% 29.22/29.09  tff(decl_57398, type, 'A collection of tissues organized into a functional unit within the body.': $i).
% 29.22/29.09  tff(decl_57399, type, organ: $i).
% 29.22/29.09  tff(decl_57400, type, suborganismal_entity_1: $i > $o).
% 29.22/29.09  tff(decl_57401, type, 'Organ-Development': $i).
% 29.22/29.09  tff(decl_57402, type, 'The process involved in the development of the organs during developmental process of an organism.': $i).
% 29.22/29.09  tff(decl_57403, type, 'organ formation': $i).
% 29.22/29.09  tff(decl_57404, type, 'development of organ': $i).
% 29.22/29.09  tff(decl_57405, type, 'organ development': $i).
% 29.22/29.09  tff(decl_57406, type, 'organ-development': $i).
% 29.22/29.09  tff(decl_57407, type, 'Organ-Identity-Gene': $i).
% 29.22/29.09  tff(decl_57408, type, 'A family of genes found in flowering plants which encode transcription factors that regulate the development of floral pattern. The expression of floral identity genes in particular floral organ primordia is related to the position of the floral organ primordia .': $i).
% 29.22/29.09  tff(decl_57409, type, 'plant homeotic gene': $i).
% 29.22/29.09  tff(decl_57410, type, 'organ identity gene': $i).
% 29.22/29.09  tff(decl_57411, type, 'organ-identity gene': $i).
% 29.22/29.09  tff(decl_57412, type, 'organ-identity-gene': $i).
% 29.22/29.09  tff(decl_57413, type, fn_organ_identity_gene_1: $i > $i).
% 29.22/29.09  tff(decl_57414, type, fn_organ_identity_gene_2: $i > $i).
% 29.22/29.09  tff(decl_57415, type, fn_organ_identity_gene_3: $i > $i).
% 29.22/29.09  tff(decl_57416, type, fn_organ_identity_gene_4: $i > $i).
% 29.22/29.09  tff(decl_57417, type, fn_organ_identity_gene_5: $i > $i).
% 29.22/29.09  tff(decl_57418, type, fn_organ_identity_gene_10: $i > $i).
% 29.22/29.09  tff(decl_57419, type, fn_organ_identity_gene_11: $i > $i).
% 29.22/29.09  tff(decl_57420, type, fn_organ_identity_gene_12: $i > $i).
% 29.22/29.09  tff(decl_57421, type, fn_organ_identity_gene_13: $i > $i).
% 29.22/29.09  tff(decl_57422, type, fn_organ_identity_gene_14: $i > $i).
% 29.22/29.09  tff(decl_57423, type, fn_organ_identity_gene_15: $i > $i).
% 29.22/29.09  tff(decl_57424, type, fn_organ_identity_gene_16: $i > $i).
% 29.22/29.09  tff(decl_57425, type, fn_organ_identity_gene_17: $i > $i).
% 29.22/29.09  tff(decl_57426, type, fn_organ_identity_gene_18: $i > $i).
% 29.22/29.09  tff(decl_57427, type, fn_organ_identity_gene_19: $i > $i).
% 29.22/29.09  tff(decl_57428, type, fn_organ_identity_gene_20: $i > $i).
% 29.22/29.09  tff(decl_57429, type, fn_organ_identity_gene_21: $i > $i).
% 29.22/29.09  tff(decl_57430, type, fn_organ_identity_gene_22: $i > $i).
% 29.22/29.09  tff(decl_57431, type, fn_organ_identity_gene_23: $i > $i).
% 29.22/29.09  tff(decl_57432, type, fn_organ_identity_gene_24: $i > $i).
% 29.22/29.09  tff(decl_57433, type, fn_organ_identity_gene_25: $i > $i).
% 29.22/29.09  tff(decl_57434, type, fn_organ_identity_gene_26: $i > $i).
% 29.22/29.09  tff(decl_57435, type, fn_organ_identity_gene_27: $i > $i).
% 29.22/29.09  tff(decl_57436, type, fn_organ_identity_gene_28: $i > $i).
% 29.22/29.09  tff(decl_57437, type, fn_organ_identity_gene_29: $i > $i).
% 29.22/29.09  tff(decl_57438, type, fn_organ_identity_gene_30: $i > $i).
% 29.22/29.09  tff(decl_57439, type, fn_organ_identity_gene_31: $i > $i).
% 29.22/29.09  tff(decl_57440, type, fn_organ_identity_gene_9: $i > $i).
% 29.22/29.09  tff(decl_57441, type, fn_organ_identity_gene_8: $i > $i).
% 29.22/29.09  tff(decl_57442, type, fn_organ_identity_gene_7: $i > $i).
% 29.22/29.09  tff(decl_57443, type, fn_organ_identity_gene_6: $i > $i).
% 29.22/29.09  tff(decl_57444, type, 'Organ-Of-Corti': $i).
% 29.22/29.09  tff(decl_57445, type, 'In mammals, the organ of the inner ear that contains the receptor cells for hearing.': $i).
% 29.22/29.09  tff(decl_57446, type, 'organ of corti': $i).
% 29.22/29.09  tff(decl_57447, type, 'organ-of-corti': $i).
% 29.22/29.09  tff(decl_57448, type, 'Organ-Of-Equilibrium': $i).
% 29.22/29.09  tff(decl_57449, type, 'An organ specialized in maintaining equilibrium.': $i).
% 29.22/29.09  tff(decl_57450, type, 'equilibrium organ': $i).
% 29.22/29.09  tff(decl_57451, type, 'equilibrium-organ': $i).
% 29.22/29.09  tff(decl_57452, type, 'organ of equilibrium': $i).
% 29.22/29.09  tff(decl_57453, type, 'organ-of-equilibrium': $i).
% 29.22/29.09  tff(decl_57454, type, 'Organ-Region': $i).
% 29.22/29.09  tff(decl_57455, type, 'A region of an organ': $i).
% 29.22/29.09  tff(decl_57456, type, 'region of organ': $i).
% 29.22/29.09  tff(decl_57457, type, 'organ region': $i).
% 29.22/29.09  tff(decl_57458, type, 'organ-region': $i).
% 29.22/29.09  tff(decl_57459, type, 'Organ-Space': $i).
% 29.22/29.09  tff(decl_57460, type, 'A space in an organ which is surrounded by anatomical structures.': $i).
% 29.22/29.09  tff(decl_57461, type, 'space of organ': $i).
% 29.22/29.09  tff(decl_57462, type, 'organ space': $i).
% 29.22/29.09  tff(decl_57463, type, 'organ-space': $i).
% 29.22/29.09  tff(decl_57464, type, 'Organ-System': $i).
% 29.22/29.09  tff(decl_57465, type, 'A group of organs working as a unit to perform some vital function in the body.': $i).
% 29.22/29.09  tff(decl_57466, type, 'system of organ': $i).
% 29.22/29.09  tff(decl_57467, type, 'organ system': $i).
% 29.22/29.09  tff(decl_57468, type, 'organ-system': $i).
% 29.22/29.09  tff(decl_57469, type, 'Organelle': $i).
% 29.22/29.09  tff(decl_57470, type, 'An organelle is a specialized component of a cell. Every organelle has a specific function essential for survival of the cell. In prokaryotes, nucleoid,  ribosome, plasma membrane, ribosome, pili, flagella are examples of an organelle while in eukaryotes organelles are nucleus, Endoplasmic reticulum etc': $i).
% 29.22/29.09  tff(decl_57471, type, 'membrane bound organelle': $i).
% 29.22/29.09  tff(decl_57472, type, 'membrane-bound-organelle': $i).
% 29.22/29.09  tff(decl_57473, type, organelle: $i).
% 29.22/29.09  tff(decl_57474, type, 'Organic-Acid': $i).
% 29.22/29.09  tff(decl_57475, type, 'An organic acid is an organic compound with acidic properties. The most common organic acids are the carboxylic acids, whose acidity is associated with their carboxyl group -COOH.': $i).
% 29.22/29.09  tff(decl_57476, type, 'organic acid': $i).
% 29.22/29.09  tff(decl_57477, type, 'organic-acid': $i).
% 29.22/29.09  tff(decl_57478, type, fn_organic_acid_3: $i > $i).
% 29.22/29.09  tff(decl_57479, type, fn_organic_acid_4: $i > $i).
% 29.22/29.09  tff(decl_57480, type, fn_organic_acid_6: $i > $i).
% 29.22/29.09  tff(decl_57481, type, fn_organic_acid_7: $i > $i).
% 29.22/29.09  tff(decl_57482, type, 'Organic-Anion': $i).
% 29.22/29.09  tff(decl_57483, type, 'A negatively charged organic ion is organic anion.': $i).
% 29.22/29.09  tff(decl_57484, type, 'organic anion': $i).
% 29.22/29.09  tff(decl_57485, type, 'organic-anion': $i).
% 29.22/29.09  tff(decl_57486, type, organic_chemistry_1: $i > $o).
% 29.22/29.09  tff(decl_57487, type, 'Organic-Chemistry': $i).
% 29.22/29.09  tff(decl_57488, type, 'The study of carbon-based compounds.': $i).
% 29.22/29.09  tff(decl_57489, type, 'organic chemistry': $i).
% 29.22/29.09  tff(decl_57490, type, 'organic-chemistry': $i).
% 29.22/29.09  tff(decl_57491, type, fn_organic_chemistry_1: $i > $i).
% 29.22/29.09  tff(decl_57492, type, 'Organic-Entity': $i).
% 29.22/29.09  tff(decl_57493, type, 'Substances or objects which are parts of, related to, or derived from living organisms.': $i).
% 29.22/29.09  tff(decl_57494, type, 'organic entity': $i).
% 29.22/29.09  tff(decl_57495, type, 'organic-entity': $i).
% 29.22/29.09  tff(decl_57496, type, 'Organic-Molecule': $i).
% 29.22/29.09  tff(decl_57497, type, 'Molecule containing carbon.': $i).
% 29.22/29.09  tff(decl_57498, type, 'Molecules containing carbon and possessing carbon-hydrogen and carbon-carbon bonds.': $i).
% 29.22/29.09  tff(decl_57499, type, 'organic compound': $i).
% 29.22/29.09  tff(decl_57500, type, 'organic molecule': $i).
% 29.22/29.09  tff(decl_57501, type, 'organic-molecule': $i).
% 29.22/29.09  tff(decl_57502, type, 'Organic-Molecule-Substance': $i).
% 29.22/29.09  tff(decl_57503, type, 'organic molecule substance': $i).
% 29.22/29.09  tff(decl_57504, type, 'organic-molecule-substance': $i).
% 29.22/29.09  tff(decl_57505, type, organic_phosphate_1: $i > $o).
% 29.22/29.09  tff(decl_57506, type, 'Organic-Phosphate': $i).
% 29.22/29.09  tff(decl_57507, type, 'An organic compound which contains phosphate functional groups.': $i).
% 29.22/29.09  tff(decl_57508, type, 'organic compound containing phosphate group': $i).
% 29.22/29.09  tff(decl_57509, type, 'organic-compound-containing-phosphate-group': $i).
% 29.22/29.09  tff(decl_57510, type, 'organic phosphate': $i).
% 29.22/29.09  tff(decl_57511, type, 'organic-phosphate': $i).
% 29.22/29.09  tff(decl_57512, type, fn_organic_phosphate_3: $i > $i).
% 29.22/29.09  tff(decl_57513, type, fn_organic_phosphate_4: $i > $i).
% 29.22/29.09  tff(decl_57514, type, fn_organic_phosphate_5: $i > $i).
% 29.22/29.09  tff(decl_57515, type, fn_organic_phosphate_6: $i > $i).
% 29.22/29.09  tff(decl_57516, type, fn_organic_phosphate_7: $i > $i).
% 29.22/29.09  tff(decl_57517, type, fn_organic_phosphate_8: $i > $i).
% 29.22/29.09  tff(decl_57518, type, fn_organic_phosphate_9: $i > $i).
% 29.22/29.09  tff(decl_57519, type, fn_organic_phosphate_10: $i > $i).
% 29.22/29.09  tff(decl_57520, type, fn_organic_phosphate_11: $i > $i).
% 29.22/29.09  tff(decl_57521, type, fn_organic_phosphate_12: $i > $i).
% 29.22/29.09  tff(decl_57522, type, fn_organic_phosphate_13: $i > $i).
% 29.22/29.09  tff(decl_57523, type, fn_organic_phosphate_14: $i > $i).
% 29.22/29.09  tff(decl_57524, type, fn_organic_phosphate_2: $i > $i).
% 29.22/29.09  tff(decl_57525, type, fn_organic_phosphate_1: $i > $i).
% 29.22/29.09  tff(decl_57526, type, 'Organic-Structure': $i).
% 29.22/29.09  tff(decl_57527, type, 'A structure made up of organic molecules, such as                         the plasma membrane, organelles, etc.': $i).
% 29.22/29.09  tff(decl_57528, type, 'Physical structure composed of organic molecules and produced by organisms.': $i).
% 29.22/29.09  tff(decl_57529, type, 'organic structure': $i).
% 29.22/29.09  tff(decl_57530, type, 'organic-structure': $i).
% 29.22/29.09  tff(decl_57531, type, 'Organism': $i).
% 29.22/29.09  tff(decl_57532, type, 'Single or multicellular entities which are free living and capable of reproduction.': $i).
% 29.22/29.09  tff(decl_57533, type, 'Organism is a living entity made up of cell(s)': $i).
% 29.22/29.09  tff(decl_57534, type, organism: $i).
% 29.22/29.09  tff(decl_57535, type, organism_group_1: $i > $o).
% 29.22/29.09  tff(decl_57536, type, 'Organism-Group': $i).
% 29.22/29.09  tff(decl_57537, type, 'Groupings which relate to sets of organisms, either of the same or different species.': $i).
% 29.22/29.09  tff(decl_57538, type, 'group of organism': $i).
% 29.22/29.09  tff(decl_57539, type, 'organism group': $i).
% 29.22/29.09  tff(decl_57540, type, 'organism-group': $i).
% 29.22/29.09  tff(decl_57541, type, fn_organism_maturation_2: $i > $i).
% 29.22/29.09  tff(decl_57542, type, 'Organism-Maturation': $i).
% 29.22/29.09  tff(decl_57543, type, 'The process of an individual organism growing organically; a purely biological unfolding of events involved in an organism changing gradually from a simple to a more complex level is called as organism maturation.': $i).
% 29.22/29.09  tff(decl_57544, type, 'maturation of organism': $i).
% 29.22/29.09  tff(decl_57545, type, 'organism maturation': $i).
% 29.22/29.09  tff(decl_57546, type, 'organism-maturation': $i).
% 29.22/29.09  tff(decl_57547, type, 'Organism-Role': $i).
% 29.22/29.09  tff(decl_57548, type, 'Specific roles that organisms play.': $i).
% 29.22/29.09  tff(decl_57549, type, 'role of organism': $i).
% 29.22/29.09  tff(decl_57550, type, 'organism role': $i).
% 29.22/29.09  tff(decl_57551, type, 'organism-role': $i).
% 29.22/29.09  tff(decl_57552, type, 'Organismal-Development': $i).
% 29.22/29.09  tff(decl_57553, type, 'The macrophysiological process that involves the development of organism is organismal development.': $i).
% 29.22/29.09  tff(decl_57554, type, 'multicellular organism development': $i).
% 29.22/29.09  tff(decl_57555, type, 'organismal development': $i).
% 29.22/29.09  tff(decl_57556, type, 'organismal-development': $i).
% 29.22/29.09  tff(decl_57557, type, fn_organismal_development_2: $i > $i).
% 29.22/29.09  tff(decl_57558, type, organismal_ecology_1: $i > $o).
% 29.22/29.09  tff(decl_57559, type, 'Organismal-Ecology': $i).
% 29.22/29.09  tff(decl_57560, type, 'The level of ecology that focuses on the physiological, behavioral, and morphological ways that individual organisms interact with their biotic and abiotic environment.': $i).
% 29.22/29.09  tff(decl_57561, type, 'organismal ecology': $i).
% 29.22/29.09  tff(decl_57562, type, 'organismal-ecology': $i).
% 29.22/29.09  tff(decl_57563, type, 'Organismal-Region': $i).
% 29.22/29.09  tff(decl_57564, type, 'A region of an organism.': $i).
% 29.22/29.09  tff(decl_57565, type, 'body region,': $i).
% 29.22/29.09  tff(decl_57566, type, 'region on the body,': $i).
% 29.22/29.09  tff(decl_57567, type, 'region on the body': $i).
% 29.22/29.09  tff(decl_57568, type, 'body region': $i).
% 29.22/29.09  tff(decl_57569, type, 'organismal region': $i).
% 29.22/29.09  tff(decl_57570, type, 'organismal-region': $i).
% 29.22/29.09  tff(decl_57571, type, 'Organization': $i).
% 29.22/29.09  tff(decl_57572, type, 'an aggregate of roles': $i).
% 29.22/29.09  tff(decl_57573, type, 'organization of in': $i).
% 29.22/29.09  tff(decl_57574, type, 'in organization': $i).
% 29.22/29.09  tff(decl_57575, type, 'in-organization': $i).
% 29.22/29.09  tff(decl_57576, type, administration: $i).
% 29.22/29.09  tff(decl_57577, type, governance: $i).
% 29.22/29.09  tff(decl_57578, type, 'governing body': $i).
% 29.22/29.09  tff(decl_57579, type, governing_body: $i).
% 29.22/29.09  tff(decl_57580, type, brass: $i).
% 29.22/29.09  tff(decl_57581, type, organization: $i).
% 29.22/29.09  tff(decl_57582, type, organisation: $i).
% 29.22/29.09  tff(decl_57583, type, 'Organizing': $i).
% 29.22/29.09  tff(decl_57584, type, organize: $i).
% 29.22/29.09  tff(decl_57585, type, organizing: $i).
% 29.22/29.09  tff(decl_57586, type, 'Organogenesis': $i).
% 29.22/29.09  tff(decl_57587, type, 'In animals, the processes by which the three embryonic germ layers (endoderm, ectoderm, and mesoderm) develop into the internal organs.': $i).
% 29.22/29.09  tff(decl_57588, type, organogenesis: $i).
% 29.22/29.09  tff(decl_57589, type, orgasm_1: $i > $o).
% 29.22/29.09  tff(decl_57590, type, 'Orgasm': $i).
% 29.22/29.09  tff(decl_57591, type, 'The sudden release of accumulated sexual tension accompanied by rhythmic, involuntary contractions of in the pelvic region and a sensation of intense pleasure.': $i).
% 29.22/29.09  tff(decl_57592, type, orgasm: $i).
% 29.22/29.09  tff(decl_57593, type, 'Orient': $i).
% 29.22/29.09  tff(decl_57594, type, 'Orientation-Constant': $i).
% 29.22/29.09  tff(decl_57595, type, 'constant of orientation': $i).
% 29.22/29.09  tff(decl_57596, type, 'orientation constant': $i).
% 29.22/29.09  tff(decl_57597, type, 'orientation-constant': $i).
% 29.22/29.09  tff(decl_57598, type, 'Origin-Of-Replication': $i).
% 29.22/29.09  tff(decl_57599, type, 'A particular sequence of nucleotides that indicates where DNA replication begins.': $i).
% 29.22/29.09  tff(decl_57600, type, 'origin of dna replication': $i).
% 29.22/29.09  tff(decl_57601, type, 'replication origin': $i).
% 29.22/29.09  tff(decl_57602, type, 'replication-origin': $i).
% 29.22/29.09  tff(decl_57603, type, 'origin of replication': $i).
% 29.22/29.09  tff(decl_57604, type, 'origin-of-replication': $i).
% 29.22/29.09  tff(decl_57605, type, orthologous_gene_1: $i > $o).
% 29.22/29.09  tff(decl_57606, type, 'Orthologous-Gene': $i).
% 29.22/29.09  tff(decl_57607, type, 'One of a set genes that occur in different species and are descended from the same gene in the last common ancestor.': $i).
% 29.22/29.09  tff(decl_57608, type, 'orthologous gene': $i).
% 29.22/29.09  tff(decl_57609, type, 'orthologous-gene': $i).
% 29.22/29.09  tff(decl_57610, type, 'Orthoptera': $i).
% 29.22/29.09  tff(decl_57611, type, 'An insect order that includes crickets and grasshoppers.': $i).
% 29.22/29.09  tff(decl_57612, type, orthoptera: $i).
% 29.22/29.09  tff(decl_57613, type, 'Osculum': $i).
% 29.22/29.09  tff(decl_57614, type, 'The excurrent opening of a sponge, through which water is expelled from the spongocoel.': $i).
% 29.22/29.09  tff(decl_57615, type, osculum: $i).
% 29.22/29.09  tff(decl_57616, type, osmium_1: $i > $o).
% 29.22/29.09  tff(decl_57617, type, 'Osmium': $i).
% 29.22/29.09  tff(decl_57618, type, 'Osmium is a metal atom with atomic number 76. It is represented by the symbol Os.': $i).
% 29.22/29.09  tff(decl_57619, type, osmium: $i).
% 29.22/29.09  tff(decl_57620, type, 'Os': $i).
% 29.22/29.09  tff(decl_57621, type, fn_osmium_3: $i > $i).
% 29.22/29.09  tff(decl_57622, type, fn_osmium_4: $i > $i).
% 29.22/29.09  tff(decl_57623, type, fn_osmium_5: $i > $i).
% 29.22/29.09  tff(decl_57624, type, fn_osmium_9: $i > $i).
% 29.22/29.09  tff(decl_57625, type, fn_osmium_10: $i > $i).
% 29.22/29.09  tff(decl_57626, type, fn_osmium_11: $i > $i).
% 29.22/29.09  tff(decl_57627, type, fn_osmium_12: $i > $i).
% 29.22/29.09  tff(decl_57628, type, "114": $i).
% 29.22/29.09  tff(decl_57629, type, "76": $i).
% 29.22/29.09  tff(decl_57630, type, "190": $i).
% 29.22/29.09  tff(decl_57631, type, "190.2": $i).
% 29.22/29.09  tff(decl_57632, type, fn_osmium_7: $i > $i).
% 29.22/29.09  tff(decl_57633, type, fn_osmium_8: $i > $i).
% 29.22/29.09  tff(decl_57634, type, fn_osmium_6: $i > $i).
% 29.22/29.09  tff(decl_57635, type, osmoconformer_1: $i > $o).
% 29.22/29.09  tff(decl_57636, type, 'Osmoconformer': $i).
% 29.22/29.09  tff(decl_57637, type, 'An animal whose body osmolarity is the same as its environment.': $i).
% 29.22/29.09  tff(decl_57638, type, osmoconformer: $i).
% 29.22/29.09  tff(decl_57639, type, 'Osmoregulation': $i).
% 29.22/29.09  tff(decl_57640, type, 'Osmoregulation is the process of regulation of osmotic pressure. Cell has to maintain their osmotic pressure at optimum level in order to survive. There are many mechanisms of osmoregulation': $i).
% 29.22/29.09  tff(decl_57641, type, 'regulation of osmotic pressure': $i).
% 29.22/29.09  tff(decl_57642, type, 'osmotic pressure regulation': $i).
% 29.22/29.09  tff(decl_57643, type, osmoregulate: $i).
% 29.22/29.09  tff(decl_57644, type, osmoregulation: $i).
% 29.22/29.09  tff(decl_57645, type, fn_osmoregulation_1: $i > $i).
% 29.22/29.09  tff(decl_57646, type, fn_osmoregulation_5: $i > $i).
% 29.22/29.09  tff(decl_57647, type, fn_osmoregulation_6: $i > $i).
% 29.22/29.09  tff(decl_57648, type, fn_osmoregulation_7: $i > $i).
% 29.22/29.09  tff(decl_57649, type, fn_osmoregulation_8: $i > $i).
% 29.22/29.09  tff(decl_57650, type, fn_osmoregulation_9: $i > $i).
% 29.22/29.09  tff(decl_57651, type, fn_osmoregulation_10: $i > $i).
% 29.22/29.09  tff(decl_57652, type, fn_osmoregulation_11: $i > $i).
% 29.22/29.09  tff(decl_57653, type, fn_osmoregulation_12: $i > $i).
% 29.22/29.09  tff(decl_57654, type, fn_osmoregulation_13: $i > $i).
% 29.22/29.09  tff(decl_57655, type, fn_osmoregulation_14: $i > $i).
% 29.22/29.09  tff(decl_57656, type, fn_osmoregulation_15: $i > $i).
% 29.22/29.09  tff(decl_57657, type, fn_osmoregulation_16: $i > $i).
% 29.22/29.09  tff(decl_57658, type, fn_osmoregulation_17: $i > $i).
% 29.22/29.09  tff(decl_57659, type, fn_osmoregulation_18: $i > $i).
% 29.22/29.09  tff(decl_57660, type, fn_osmoregulation_20: $i > $i).
% 29.22/29.09  tff(decl_57661, type, fn_passive_transport_2: $i > $i).
% 29.22/29.09  tff(decl_57662, type, fn_passive_transport_3: $i > $i).
% 29.22/29.09  tff(decl_57663, type, osmoregulation_in_organism_with_cell_with_cell_wall_in_hypotonic_solution_1: $i > $o).
% 29.22/29.09  tff(decl_57664, type, 'Osmoregulation-In-Organism-With-Cell-With-Cell-Wall-In-Hypotonic-Solution': $i).
% 29.22/29.09  tff(decl_57665, type, 'Regulation of solute concentrations and water balance by an organism with a protective later external to the plasma membrane around each cell in a solution that will cause the cell to take up water.  The cell, however, will not burst due to the presence of the cell wall.': $i).
% 29.22/29.09  tff(decl_57666, type, 'osmoregulation in organism with cell with cell wall in hypotonic solution': $i).
% 29.22/29.09  tff(decl_57667, type, 'osmoregulation-in-organism-with-cell-with-cell-wall-in-hypotonic-solution': $i).
% 29.22/29.09  tff(decl_57668, type, osmoregulation_in_organism_with_cell_without_cell_wall_in_hypertonic_solution_1: $i > $o).
% 29.22/29.09  tff(decl_57669, type, osmoregulation_in_organism_with_cell_without_cell_wall_in_hypotonic_solution_1: $i > $o).
% 29.22/29.09  tff(decl_57670, type, osmoregulation_in_paramecium_in_hypotonic_solution_1: $i > $o).
% 29.22/29.09  tff(decl_57671, type, fn_osmoregulation_in_organism_with_cell_with_cell_wall_in_hypotonic_solution_1: $i > $i).
% 29.22/29.09  tff(decl_57672, type, water_balance_1: $i > $o).
% 29.22/29.09  tff(decl_57673, type, fn_osmoregulation_in_organism_with_cell_with_cell_wall_in_hypotonic_solution_2: $i > $i).
% 29.22/29.09  tff(decl_57674, type, fn_osmoregulation_in_organism_with_cell_with_cell_wall_in_hypotonic_solution_3: $i > $i).
% 29.22/29.09  tff(decl_57675, type, fn_osmoregulation_in_organism_with_cell_with_cell_wall_in_hypotonic_solution_4: $i > $i).
% 29.22/29.09  tff(decl_57676, type, 'Osmoregulation-In-Organism-With-Cell-Without-Cell-Wall-In-Hypertonic-Solution': $i).
% 29.22/29.09  tff(decl_57677, type, 'An organism with a cell without cell wall when placed in a hypertonic solution will lose water to its environment, shrivel, and probably die.': $i).
% 29.22/29.09  tff(decl_57678, type, 'osmoregulation in organism with cell without cell wall in hypertonic solution': $i).
% 29.22/29.09  tff(decl_57679, type, 'osmoregulation-in-organism-with-cell-without-cell-wall-in-hypertonic-solution': $i).
% 29.22/29.09  tff(decl_57680, type, fn_osmoregulation_in_organism_with_cell_without_cell_wall_in_hypertonic_solution_1: $i > $i).
% 29.22/29.09  tff(decl_57681, type, fn_osmoregulation_in_organism_with_cell_without_cell_wall_in_hypertonic_solution_2: $i > $i).
% 29.22/29.09  tff(decl_57682, type, 'Osmoregulation-In-Organism-With-Cell-Without-Cell-Wall-In-Hypotonic-Solution': $i).
% 29.22/29.09  tff(decl_57683, type, 'Organism with cells without cell wall when kept in a hypotonic solution, water will enter faster than it leaves, and the cell will swell and lyse (burst) like an overfilled water balloon.': $i).
% 29.22/29.09  tff(decl_57684, type, 'osmoregulation in organism with cell without cell wall in hypotonic solution': $i).
% 29.22/29.09  tff(decl_57685, type, 'osmoregulation-in-organism-with-cell-without-cell-wall-in-hypotonic-solution': $i).
% 29.22/29.09  tff(decl_57686, type, fn_osmoregulation_in_organism_with_cell_without_cell_wall_in_hypotonic_solution_1: $i > $i).
% 29.22/29.09  tff(decl_57687, type, fn_osmoregulation_in_organism_with_cell_without_cell_wall_in_hypotonic_solution_2: $i > $i).
% 29.22/29.09  tff(decl_57688, type, 'Osmoregulation-In-Paramecium-In-Hypotonic-Solution': $i).
% 29.22/29.09  tff(decl_57689, type, 'The osmoregulation in paramecium when it is placed inside hypotonic solution.': $i).
% 29.22/29.09  tff(decl_57690, type, 'osmoregulation in paramecium in hypotonic solution': $i).
% 29.22/29.09  tff(decl_57691, type, 'osmoregulation-in-paramecium-in-hypotonic-solution': $i).
% 29.22/29.09  tff(decl_57692, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_1: $i > $i).
% 29.22/29.09  tff(decl_57693, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_2: $i > $i).
% 29.22/29.09  tff(decl_57694, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_3: $i > $i).
% 29.22/29.09  tff(decl_57695, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_4: $i > $i).
% 29.22/29.09  tff(decl_57696, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_6: $i > $i).
% 29.22/29.09  tff(decl_57697, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_10: $i > $i).
% 29.22/29.09  tff(decl_57698, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_11: $i > $i).
% 29.22/29.09  tff(decl_57699, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_12: $i > $i).
% 29.22/29.09  tff(decl_57700, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_13: $i > $i).
% 29.22/29.09  tff(decl_57701, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_14: $i > $i).
% 29.22/29.09  tff(decl_57702, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_15: $i > $i).
% 29.22/29.09  tff(decl_57703, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_16: $i > $i).
% 29.22/29.09  tff(decl_57704, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_17: $i > $i).
% 29.22/29.09  tff(decl_57705, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_18: $i > $i).
% 29.22/29.09  tff(decl_57706, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_19: $i > $i).
% 29.22/29.09  tff(decl_57707, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_20: $i > $i).
% 29.22/29.09  tff(decl_57708, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_21: $i > $i).
% 29.22/29.09  tff(decl_57709, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_22: $i > $i).
% 29.22/29.09  tff(decl_57710, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_23: $i > $i).
% 29.22/29.09  tff(decl_57711, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_24: $i > $i).
% 29.22/29.09  tff(decl_57712, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_25: $i > $i).
% 29.22/29.09  tff(decl_57713, type, paramecium_1: $i > $o).
% 29.22/29.09  tff(decl_57714, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_26: $i > $i).
% 29.22/29.09  tff(decl_57715, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_27: $i > $i).
% 29.22/29.09  tff(decl_57716, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_28: $i > $i).
% 29.22/29.09  tff(decl_57717, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_29: $i > $i).
% 29.22/29.09  tff(decl_57718, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_30: $i > $i).
% 29.22/29.09  tff(decl_57719, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_31: $i > $i).
% 29.22/29.09  tff(decl_57720, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_32: $i > $i).
% 29.22/29.09  tff(decl_57721, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_33: $i > $i).
% 29.22/29.09  tff(decl_57722, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_34: $i > $i).
% 29.22/29.09  tff(decl_57723, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_35: $i > $i).
% 29.22/29.09  tff(decl_57724, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_36: $i > $i).
% 29.22/29.09  tff(decl_57725, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_37: $i > $i).
% 29.22/29.09  tff(decl_57726, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_38: $i > $i).
% 29.22/29.09  tff(decl_57727, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_39: $i > $i).
% 29.22/29.09  tff(decl_57728, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_40: $i > $i).
% 29.22/29.09  tff(decl_57729, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_41: $i > $i).
% 29.22/29.09  tff(decl_57730, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_42: $i > $i).
% 29.22/29.09  tff(decl_57731, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_43: $i > $i).
% 29.22/29.09  tff(decl_57732, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_44: $i > $i).
% 29.22/29.09  tff(decl_57733, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_45: $i > $i).
% 29.22/29.09  tff(decl_57734, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_46: $i > $i).
% 29.22/29.09  tff(decl_57735, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_47: $i > $i).
% 29.22/29.09  tff(decl_57736, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_48: $i > $i).
% 29.22/29.09  tff(decl_57737, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_53: $i > $i).
% 29.22/29.09  tff(decl_57738, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_54: $i > $i).
% 29.22/29.09  tff(decl_57739, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_55: $i > $i).
% 29.22/29.09  tff(decl_57740, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_56: $i > $i).
% 29.22/29.09  tff(decl_57741, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_57: $i > $i).
% 29.22/29.09  tff(decl_57742, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_58: $i > $i).
% 29.22/29.09  tff(decl_57743, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_59: $i > $i).
% 29.22/29.09  tff(decl_57744, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_60: $i > $i).
% 29.22/29.09  tff(decl_57745, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_61: $i > $i).
% 29.22/29.09  tff(decl_57746, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_62: $i > $i).
% 29.22/29.09  tff(decl_57747, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_63: $i > $i).
% 29.22/29.09  tff(decl_57748, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_64: $i > $i).
% 29.22/29.09  tff(decl_57749, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_65: $i > $i).
% 29.22/29.09  tff(decl_57750, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_66: $i > $i).
% 29.22/29.09  tff(decl_57751, type, 'Rate_TakeInWater': $i).
% 29.22/29.09  tff(decl_57752, type, 'Rate_MoveOutOfWater': $i).
% 29.22/29.09  tff(decl_57753, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_52: $i > $i).
% 29.22/29.09  tff(decl_57754, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_51: $i > $i).
% 29.22/29.09  tff(decl_57755, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_50: $i > $i).
% 29.22/29.09  tff(decl_57756, type, fn_osmoregulation_in_paramecium_in_hypotonic_solution_49: $i > $i).
% 29.22/29.09  tff(decl_57757, type, 'Osmoregulator': $i).
% 29.22/29.09  tff(decl_57758, type, 'An animal that maintains a constant internal osmolarity independent of the external environment.': $i).
% 29.22/29.09  tff(decl_57759, type, osmoregulator: $i).
% 29.22/29.09  tff(decl_57760, type, fn_osmoregulator_1: $i > $i).
% 29.22/29.09  tff(decl_57761, type, fn_osmoregulator_2: $i > $i).
% 29.22/29.09  tff(decl_57762, type, 'Osmosis': $i).
% 29.22/29.09  tff(decl_57763, type, 'Osmosis is the movement of water molecules through a selectively-permeable membrane down a water potential gradient': $i).
% 29.22/29.09  tff(decl_57764, type, 'diffusion of water': $i).
% 29.22/29.09  tff(decl_57765, type, osmosis: $i).
% 29.22/29.09  tff(decl_57766, type, fn_osmosis_9: $i > $i).
% 29.22/29.09  tff(decl_57767, type, fn_osmosis_10: $i > $i).
% 29.22/29.09  tff(decl_57768, type, fn_osmosis_11: $i > $i).
% 29.22/29.09  tff(decl_57769, type, fn_osmosis_12: $i > $i).
% 29.22/29.09  tff(decl_57770, type, fn_osmosis_13: $i > $i).
% 29.22/29.09  tff(decl_57771, type, fn_osmosis_14: $i > $i).
% 29.22/29.09  tff(decl_57772, type, fn_osmosis_23: $i > $i).
% 29.22/29.09  tff(decl_57773, type, 'Solutepotential': $i).
% 29.22/29.09  tff(decl_57774, type, 'Pressurepotential': $i).
% 29.22/29.09  tff(decl_57775, type, osmosis_of_plant_cell_in_distilled_water_1: $i > $o).
% 29.22/29.09  tff(decl_57776, type, 'Osmosis-of-Plant-Cell-in-Distilled-Water': $i).
% 29.22/29.09  tff(decl_57777, type, 'Movement of water for a plant cell placed in pure water devoid of solutes.  Water would move into the cell causing the cell to swell.': $i).
% 29.22/29.09  tff(decl_57778, type, 'osmosis of plant cell in distilled water': $i).
% 29.22/29.09  tff(decl_57779, type, 'osmosis-of-plant-cell-in-distilled-water': $i).
% 29.22/29.09  tff(decl_57780, type, fn_osmosis_of_plant_cell_in_distilled_water_1: $i > $i).
% 29.22/29.09  tff(decl_57781, type, fn_osmosis_of_plant_cell_in_distilled_water_2: $i > $i).
% 29.22/29.09  tff(decl_57782, type, fn_osmosis_of_plant_cell_in_distilled_water_3: $i > $i).
% 29.22/29.09  tff(decl_57783, type, fn_osmosis_of_plant_cell_in_distilled_water_5: $i > $i).
% 29.22/29.09  tff(decl_57784, type, fn_osmosis_of_plant_cell_in_distilled_water_6: $i > $i).
% 29.22/29.09  tff(decl_57785, type, fn_osmosis_of_plant_cell_in_distilled_water_7: $i > $i).
% 29.22/29.09  tff(decl_57786, type, fn_osmosis_of_plant_cell_in_distilled_water_10: $i > $i).
% 29.22/29.09  tff(decl_57787, type, fn_osmosis_of_plant_cell_in_distilled_water_11: $i > $i).
% 29.22/29.09  tff(decl_57788, type, fn_osmosis_of_plant_cell_in_distilled_water_12: $i > $i).
% 29.22/29.09  tff(decl_57789, type, fn_osmosis_of_plant_cell_in_distilled_water_13: $i > $i).
% 29.22/29.09  tff(decl_57790, type, fn_osmosis_of_plant_cell_in_distilled_water_14: $i > $i).
% 29.22/29.09  tff(decl_57791, type, fn_osmosis_of_plant_cell_in_distilled_water_15: $i > $i).
% 29.22/29.09  tff(decl_57792, type, fn_osmosis_of_plant_cell_in_distilled_water_16: $i > $i).
% 29.22/29.09  tff(decl_57793, type, fn_osmosis_of_plant_cell_in_distilled_water_17: $i > $i).
% 29.22/29.09  tff(decl_57794, type, fn_osmosis_of_plant_cell_in_distilled_water_18: $i > $i).
% 29.22/29.09  tff(decl_57795, type, fn_osmosis_of_plant_cell_in_distilled_water_19: $i > $i).
% 29.22/29.09  tff(decl_57796, type, fn_osmosis_of_plant_cell_in_distilled_water_20: $i > $i).
% 29.22/29.09  tff(decl_57797, type, fn_osmosis_of_plant_cell_in_distilled_water_21: $i > $i).
% 29.22/29.09  tff(decl_57798, type, fn_osmosis_of_plant_cell_in_distilled_water_22: $i > $i).
% 29.22/29.09  tff(decl_57799, type, fn_osmosis_of_plant_cell_in_distilled_water_23: $i > $i).
% 29.22/29.09  tff(decl_57800, type, fn_osmosis_of_plant_cell_in_distilled_water_24: $i > $i).
% 29.22/29.09  tff(decl_57801, type, fn_osmosis_of_plant_cell_in_distilled_water_25: $i > $i).
% 29.22/29.09  tff(decl_57802, type, fn_osmosis_of_plant_cell_in_distilled_water_26: $i > $i).
% 29.22/29.09  tff(decl_57803, type, fn_osmosis_of_plant_cell_in_distilled_water_27: $i > $i).
% 29.22/29.09  tff(decl_57804, type, fn_osmosis_of_plant_cell_in_distilled_water_28: $i > $i).
% 29.22/29.09  tff(decl_57805, type, fn_osmosis_of_plant_cell_in_distilled_water_29: $i > $i).
% 29.22/29.09  tff(decl_57806, type, fn_osmosis_of_plant_cell_in_distilled_water_30: $i > $i).
% 29.22/29.09  tff(decl_57807, type, fn_osmosis_of_plant_cell_in_distilled_water_31: $i > $i).
% 29.22/29.09  tff(decl_57808, type, fn_osmosis_of_plant_cell_in_distilled_water_32: $i > $i).
% 29.22/29.09  tff(decl_57809, type, fn_osmosis_of_plant_cell_in_distilled_water_33: $i > $i).
% 29.22/29.09  tff(decl_57810, type, fn_osmosis_of_plant_cell_in_distilled_water_34: $i > $i).
% 29.22/29.09  tff(decl_57811, type, fn_osmosis_of_plant_cell_in_distilled_water_35: $i > $i).
% 29.22/29.09  tff(decl_57812, type, fn_osmosis_of_plant_cell_in_distilled_water_36: $i > $i).
% 29.22/29.09  tff(decl_57813, type, fn_osmosis_of_plant_cell_in_distilled_water_37: $i > $i).
% 29.22/29.09  tff(decl_57814, type, fn_osmosis_of_plant_cell_in_distilled_water_38: $i > $i).
% 29.22/29.09  tff(decl_57815, type, fn_osmosis_of_plant_cell_in_distilled_water_39: $i > $i).
% 29.22/29.09  tff(decl_57816, type, fn_osmosis_of_plant_cell_in_distilled_water_40: $i > $i).
% 29.22/29.09  tff(decl_57817, type, fn_osmosis_of_plant_cell_in_distilled_water_41: $i > $i).
% 29.22/29.09  tff(decl_57818, type, fn_osmosis_of_plant_cell_in_distilled_water_42: $i > $i).
% 29.22/29.09  tff(decl_57819, type, fn_osmosis_of_plant_cell_in_distilled_water_43: $i > $i).
% 29.22/29.09  tff(decl_57820, type, fn_osmosis_of_plant_cell_in_distilled_water_44: $i > $i).
% 29.22/29.09  tff(decl_57821, type, fn_osmosis_of_plant_cell_in_distilled_water_45: $i > $i).
% 29.22/29.09  tff(decl_57822, type, fn_osmosis_of_plant_cell_in_distilled_water_46: $i > $i).
% 29.22/29.09  tff(decl_57823, type, fn_osmosis_of_plant_cell_in_distilled_water_47: $i > $i).
% 29.22/29.09  tff(decl_57824, type, fn_osmosis_of_plant_cell_in_distilled_water_48: $i > $i).
% 29.22/29.09  tff(decl_57825, type, fn_osmosis_of_plant_cell_in_distilled_water_49: $i > $i).
% 29.22/29.09  tff(decl_57826, type, fn_osmosis_of_plant_cell_in_distilled_water_50: $i > $i).
% 29.22/29.09  tff(decl_57827, type, fn_osmosis_of_plant_cell_in_distilled_water_51: $i > $i).
% 29.22/29.09  tff(decl_57828, type, fn_osmosis_of_plant_cell_in_distilled_water_52: $i > $i).
% 29.22/29.09  tff(decl_57829, type, fn_osmosis_of_plant_cell_in_distilled_water_53: $i > $i).
% 29.22/29.09  tff(decl_57830, type, fn_osmosis_of_plant_cell_in_distilled_water_54: $i > $i).
% 29.22/29.09  tff(decl_57831, type, fn_osmosis_of_plant_cell_in_distilled_water_55: $i > $i).
% 29.22/29.09  tff(decl_57832, type, fn_osmosis_of_plant_cell_in_distilled_water_60: $i > $i).
% 29.22/29.09  tff(decl_57833, type, fn_osmosis_of_plant_cell_in_distilled_water_61: $i > $i).
% 29.22/29.09  tff(decl_57834, type, fn_osmosis_of_plant_cell_in_distilled_water_62: $i > $i).
% 29.22/29.09  tff(decl_57835, type, fn_osmosis_of_plant_cell_in_distilled_water_57: $i > $i).
% 29.22/29.09  tff(decl_57836, type, fn_passive_transport_9: $i > $i).
% 29.22/29.09  tff(decl_57837, type, fn_osmosis_of_plant_cell_in_distilled_water_58: $i > $i).
% 29.22/29.09  tff(decl_57838, type, fn_osmosis_of_plant_cell_in_distilled_water_9: $i > $i).
% 29.22/29.09  tff(decl_57839, type, fn_osmosis_of_plant_cell_in_distilled_water_59: $i > $i).
% 29.22/29.09  tff(decl_57840, type, fn_osmosis_of_plant_cell_in_distilled_water_8: $i > $i).
% 29.22/29.09  tff(decl_57841, type, fn_passive_transport_8: $i > $i).
% 29.22/29.09  tff(decl_57842, type, fn_osmosis_of_plant_cell_in_distilled_water_4: $i > $i).
% 29.22/29.09  tff(decl_57843, type, fn_osmosis_of_plant_cell_in_distilled_water_56: $i > $i).
% 29.22/29.09  tff(decl_57844, type, fn_osmosis_of_plant_cell_in_distilled_water_64: $i > $i).
% 29.22/29.09  tff(decl_57845, type, fn_osmosis_of_plant_cell_in_distilled_water_63: $i > $i).
% 29.22/29.09  tff(decl_57846, type, 'Outer-Ear': $i).
% 29.22/29.09  tff(decl_57847, type, 'The outermost region of the ear in reptiles, birds, and mammals; includes the pinna and the ear canal.': $i).
% 29.22/29.09  tff(decl_57848, type, 'outer ear': $i).
% 29.22/29.09  tff(decl_57849, type, 'outer-ear': $i).
% 29.22/29.09  tff(decl_57850, type, 'Outer-membrane': $i).
% 29.22/29.09  tff(decl_57851, type, 'It is outer enclosing layer of a double lipid bilayer membrane. It comprises of phospholipid bilayer': $i).
% 29.22/29.09  tff(decl_57852, type, 'outer envelope': $i).
% 29.22/29.09  tff(decl_57853, type, 'outer-envelope': $i).
% 29.22/29.09  tff(decl_57854, type, 'outer covering': $i).
% 29.22/29.09  tff(decl_57855, type, 'outer-covering': $i).
% 29.22/29.09  tff(decl_57856, type, 'outer membrane': $i).
% 29.22/29.09  tff(decl_57857, type, 'outer-membrane': $i).
% 29.22/29.09  tff(decl_57858, type, 'Outer-Vulva': $i).
% 29.22/29.09  tff(decl_57859, type, 'Outer vulva is part of a vulva.': $i).
% 29.22/29.09  tff(decl_57860, type, 'outer vulva': $i).
% 29.22/29.09  tff(decl_57861, type, 'outer-vulva': $i).
% 29.22/29.09  tff(decl_57862, type, 'Outgroup': $i).
% 29.22/29.09  tff(decl_57863, type, 'In cladistic analyses, the monophyletic group that is chosen to serve as a reference point in determining the evolutionary relationships among other groups. The outgroup is chosen so that its members are more distantly related to the groups in question than the groups in question are to each other.': $i).
% 29.22/29.09  tff(decl_57864, type, outgroup: $i).
% 29.22/29.09  tff(decl_57865, type, 'Outlet': $i).
% 29.22/29.09  tff(decl_57866, type, issue: $i).
% 29.22/29.09  tff(decl_57867, type, outlet: $i).
% 29.22/29.09  tff(decl_57868, type, 'way out': $i).
% 29.22/29.09  tff(decl_57869, type, way_out: $i).
% 29.22/29.09  tff(decl_57870, type, 'Outside-Face': $i).
% 29.22/29.09  tff(decl_57871, type, 'The region outside an entity is called as its outside face.': $i).
% 29.22/29.09  tff(decl_57872, type, 'exterior side': $i).
% 29.22/29.09  tff(decl_57873, type, 'exterior-side': $i).
% 29.22/29.09  tff(decl_57874, type, 'face of outside': $i).
% 29.22/29.09  tff(decl_57875, type, 'outside face': $i).
% 29.22/29.09  tff(decl_57876, type, 'outside-face': $i).
% 29.22/29.09  tff(decl_57877, type, 'Oval-Window': $i).
% 29.22/29.09  tff(decl_57878, type, 'A membrane-covered opening between the middle ear and the inner ear. Sound passes through the oval window between the middle ear and the inner ear.': $i).
% 29.22/29.09  tff(decl_57879, type, 'window of oval': $i).
% 29.22/29.09  tff(decl_57880, type, 'oval window': $i).
% 29.22/29.09  tff(decl_57881, type, 'oval-window': $i).
% 29.22/29.09  tff(decl_57882, type, 'Ovarian-Cell': $i).
% 29.22/29.09  tff(decl_57883, type, 'A cell from the ovary, the structure that produces female gametes and reproductive hormones.': $i).
% 29.22/29.09  tff(decl_57884, type, 'cell of ovary': $i).
% 29.22/29.09  tff(decl_57885, type, 'cell-of-ovary': $i).
% 29.22/29.09  tff(decl_57886, type, 'ovarian cell': $i).
% 29.22/29.09  tff(decl_57887, type, 'ovarian-cell': $i).
% 29.22/29.09  tff(decl_57888, type, fn_ovarian_cell_1: $i > $i).
% 29.22/29.09  tff(decl_57889, type, fn_ovarian_cell_4: $i > $i).
% 29.22/29.09  tff(decl_57890, type, fn_ovarian_cell_5: $i > $i).
% 29.22/29.09  tff(decl_57891, type, fn_ovarian_cell_6: $i > $i).
% 29.22/29.09  tff(decl_57892, type, fn_ovarian_cell_7: $i > $i).
% 29.22/29.09  tff(decl_57893, type, fn_ovarian_cell_8: $i > $i).
% 29.22/29.09  tff(decl_57894, type, fn_ovarian_cell_9: $i > $i).
% 29.22/29.09  tff(decl_57895, type, fn_ovarian_cell_10: $i > $i).
% 29.22/29.09  tff(decl_57896, type, fn_ovarian_cell_11: $i > $i).
% 29.22/29.09  tff(decl_57897, type, fn_ovarian_cell_12: $i > $i).
% 29.22/29.09  tff(decl_57898, type, fn_ovarian_cell_13: $i > $i).
% 29.22/29.09  tff(decl_57899, type, fn_ovarian_cell_14: $i > $i).
% 29.22/29.09  tff(decl_57900, type, fn_ovarian_cell_15: $i > $i).
% 29.22/29.09  tff(decl_57901, type, fn_ovarian_cell_16: $i > $i).
% 29.22/29.09  tff(decl_57902, type, fn_ovarian_cell_17: $i > $i).
% 29.22/29.09  tff(decl_57903, type, fn_ovarian_cell_18: $i > $i).
% 29.22/29.09  tff(decl_57904, type, fn_ovarian_cell_19: $i > $i).
% 29.22/29.09  tff(decl_57905, type, fn_ovarian_cell_20: $i > $i).
% 29.22/29.09  tff(decl_57906, type, fn_ovarian_cell_3: $i > $i).
% 29.22/29.09  tff(decl_57907, type, fn_ovarian_cell_2: $i > $i).
% 29.22/29.09  tff(decl_57908, type, ovarian_cycle_1: $i > $o).
% 29.22/29.09  tff(decl_57909, type, 'Ovarian-Cycle': $i).
% 29.22/29.09  tff(decl_57910, type, 'In the mammalian ovary, the regular progression through the follicular phase, ovulation, and the luteal phase. The ovarian cycle is regulated by hormones.': $i).
% 29.22/29.09  tff(decl_57911, type, 'ovarian cycle': $i).
% 29.22/29.09  tff(decl_57912, type, 'ovarian-cycle': $i).
% 29.22/29.09  tff(decl_57913, type, 'Ovary': $i).
% 29.22/29.09  tff(decl_57914, type, 'Ovaries are reproductive organs which produce female gametes in animals. In plants, ovaries house one or more ovules.': $i).
% 29.22/29.09  tff(decl_57915, type, ovary: $i).
% 29.22/29.09  tff(decl_57916, type, fn_ovary_2: $i > $i).
% 29.22/29.09  tff(decl_57917, type, fn_ovary_3: $i > $i).
% 29.22/29.09  tff(decl_57918, type, fn_ovary_4: $i > $i).
% 29.22/29.09  tff(decl_57919, type, fn_ovary_5: $i > $i).
% 29.22/29.09  tff(decl_57920, type, overexploitation_1: $i > $o).
% 29.22/29.09  tff(decl_57921, type, 'Overexploitation': $i).
% 29.22/29.09  tff(decl_57922, type, 'The human harvest of a renewable resource beyond the point at which the populations can recover.': $i).
% 29.22/29.09  tff(decl_57923, type, overexploit: $i).
% 29.22/29.09  tff(decl_57924, type, overexploitation: $i).
% 29.22/29.09  tff(decl_57925, type, overfishing_1: $i > $o).
% 29.22/29.09  tff(decl_57926, type, 'Overfishing': $i).
% 29.22/29.09  tff(decl_57927, type, 'A type of overexploitation in which a fishery species are harvested at rates that exceed the ability of the population\\s ability to rebound.': $i).
% 29.22/29.09  tff(decl_57928, type, overfishing: $i).
% 29.22/29.09  tff(decl_57929, type, 'Overnourishment': $i).
% 29.22/29.09  tff(decl_57930, type, 'The consumption of more calories than the body needs for normal metabolic activities.': $i).
% 29.22/29.09  tff(decl_57931, type, overnourishment: $i).
% 29.22/29.09  tff(decl_57932, type, oviduct_1: $i > $o).
% 29.22/29.09  tff(decl_57933, type, 'Oviduct': $i).
% 29.22/29.09  tff(decl_57934, type, 'A tube whose role is to deliver eggs to the vagina (invertebrates) or uterus (vertebrates).': $i).
% 29.22/29.09  tff(decl_57935, type, oviduct: $i).
% 29.22/29.09  tff(decl_57936, type, fn_oviduct_1: $i > $i).
% 29.22/29.09  tff(decl_57937, type, fn_oviduct_2: $i > $i).
% 29.22/29.09  tff(decl_57938, type, fn_oviduct_3: $i > $i).
% 29.22/29.09  tff(decl_57939, type, fn_oviduct_4: $i > $i).
% 29.22/29.09  tff(decl_57940, type, fn_oviduct_5: $i > $i).
% 29.22/29.09  tff(decl_57941, type, fn_oviduct_6: $i > $i).
% 29.22/29.09  tff(decl_57942, type, fn_oviduct_7: $i > $i).
% 29.22/29.09  tff(decl_57943, type, fn_oviduct_8: $i > $i).
% 29.22/29.09  tff(decl_57944, type, fn_oviduct_9: $i > $i).
% 29.22/29.09  tff(decl_57945, type, fn_oviduct_10: $i > $i).
% 29.22/29.09  tff(decl_57946, type, 'Oviparous': $i).
% 29.22/29.09  tff(decl_57947, type, 'Describes an animal that develops from eggs deposited outside the mother\\s body.': $i).
% 29.22/29.09  tff(decl_57948, type, oviparous: $i).
% 29.22/29.09  tff(decl_57949, type, 'Ovoviviparous': $i).
% 29.22/29.09  tff(decl_57950, type, 'Describes an animal that develops from eggs that hatch inside the mother\\s body.': $i).
% 29.22/29.09  tff(decl_57951, type, ovoviviparous: $i).
% 29.22/29.09  tff(decl_57952, type, 'Ovulation': $i).
% 29.22/29.09  tff(decl_57953, type, 'The release of an egg from an ovary. In humans, ovulation occurs approximately midway through the uterine (menstrual) cycle.': $i).
% 29.22/29.09  tff(decl_57954, type, ovulate: $i).
% 29.22/29.09  tff(decl_57955, type, ovulation: $i).
% 29.22/29.09  tff(decl_57956, type, 'Ovule': $i).
% 29.22/29.09  tff(decl_57957, type, 'A structure that develops within the ovary of a seed plant and contains the female gametophyte.': $i).
% 29.22/29.09  tff(decl_57958, type, ovule: $i).
% 29.22/29.09  tff(decl_57959, type, fn_ovule_1: $i > $i).
% 29.22/29.09  tff(decl_57960, type, fn_ovule_2: $i > $i).
% 29.22/29.09  tff(decl_57961, type, 'Ovum': $i).
% 29.22/29.09  tff(decl_57962, type, 'The human female reproductive cell; the female gamete': $i).
% 29.22/29.09  tff(decl_57963, type, ova: $i).
% 29.22/29.09  tff(decl_57964, type, 'Oxaloacetate': $i).
% 29.22/29.09  tff(decl_57965, type, 'Oxaloacetate is a metabolic intermediate that couples with acetyl coA to form citrate in Kreb\\s cycle.': $i).
% 29.22/29.09  tff(decl_57966, type, oxaloacetate: $i).
% 29.22/29.09  tff(decl_57967, type, 'Oxidation': $i).
% 29.22/29.09  tff(decl_57968, type, 'A reaction in which the atoms in an element lose electrons and the valence of the element is correspondingly increased.': $i).
% 29.22/29.09  tff(decl_57969, type, 'lose electron': $i).
% 29.22/29.09  tff(decl_57970, type, oxidise: $i).
% 29.22/29.09  tff(decl_57971, type, oxidize: $i).
% 29.22/29.09  tff(decl_57972, type, oxidation: $i).
% 29.22/29.09  tff(decl_57973, type, fn_oxidizing_agent_2: $i > $i).
% 29.22/29.09  tff(decl_57974, type, 'Oxidation-State-Constant': $i).
% 29.22/29.09  tff(decl_57975, type, 'oxidation state constant': $i).
% 29.22/29.09  tff(decl_57976, type, 'oxidation-state-constant': $i).
% 29.22/29.09  tff(decl_57977, type, 'Oxidation-State-Value': $i).
% 29.22/29.09  tff(decl_57978, type, 'state of oxidation': $i).
% 29.22/29.09  tff(decl_57979, type, 'oxidation state': $i).
% 29.22/29.09  tff(decl_57980, type, 'oxidation-state': $i).
% 29.22/29.09  tff(decl_57981, type, 'oxidation state value': $i).
% 29.22/29.09  tff(decl_57982, type, 'oxidation-state-value': $i).
% 29.22/29.09  tff(decl_57983, type, 'Oxidative-Phosphorylation': $i).
% 29.22/29.09  tff(decl_57984, type, 'Oxidative phosphorylation is a metabolic pathway that uses energy released by the oxidation of nutrients to produce adenosine triphosphate (ATP).': $i).
% 29.22/29.09  tff(decl_57985, type, 'oxidative phosphorylation': $i).
% 29.22/29.09  tff(decl_57986, type, 'oxidative-phosphorylation': $i).
% 29.22/29.09  tff(decl_57987, type, synthesis_of_amino_acid_1: $i > $o).
% 29.22/29.09  tff(decl_57988, type, fn_oxidative_phosphorylation_1: $i > $i).
% 29.22/29.09  tff(decl_57989, type, fn_oxidative_phosphorylation_3: $i > $i).
% 29.22/29.09  tff(decl_57990, type, fn_oxidative_phosphorylation_4: $i > $i).
% 29.22/29.09  tff(decl_57991, type, fn_oxidative_phosphorylation_7: $i > $i).
% 29.22/29.09  tff(decl_57992, type, fn_oxidative_phosphorylation_25: $i > $i).
% 29.22/29.09  tff(decl_57993, type, fn_oxidative_phosphorylation_26: $i > $i).
% 29.22/29.09  tff(decl_57994, type, fn_oxidative_phosphorylation_29: $i > $i).
% 29.22/29.09  tff(decl_57995, type, fn_oxidative_phosphorylation_30: $i > $i).
% 29.22/29.09  tff(decl_57996, type, fn_oxidative_phosphorylation_34: $i > $i).
% 29.22/29.09  tff(decl_57997, type, fn_oxidative_phosphorylation_35: $i > $i).
% 29.22/29.09  tff(decl_57998, type, fn_oxidative_phosphorylation_36: $i > $i).
% 29.22/29.09  tff(decl_57999, type, fn_oxidative_phosphorylation_37: $i > $i).
% 29.22/29.09  tff(decl_58000, type, fn_oxidative_phosphorylation_38: $i > $i).
% 29.22/29.09  tff(decl_58001, type, fn_oxidative_phosphorylation_39: $i > $i).
% 29.22/29.09  tff(decl_58002, type, fn_oxidative_phosphorylation_49: $i > $i).
% 29.22/29.09  tff(decl_58003, type, fn_oxidative_phosphorylation_52: $i > $i).
% 29.22/29.09  tff(decl_58004, type, fn_oxidative_phosphorylation_53: $i > $i).
% 29.22/29.09  tff(decl_58005, type, fn_oxidative_phosphorylation_54: $i > $i).
% 29.22/29.09  tff(decl_58006, type, fn_oxidative_phosphorylation_55: $i > $i).
% 29.22/29.09  tff(decl_58007, type, fn_oxidative_phosphorylation_57: $i > $i).
% 29.22/29.09  tff(decl_58008, type, fn_oxidative_phosphorylation_58: $i > $i).
% 29.22/29.09  tff(decl_58009, type, fn_oxidative_phosphorylation_65: $i > $i).
% 29.22/29.09  tff(decl_58010, type, fn_oxidative_phosphorylation_66: $i > $i).
% 29.22/29.09  tff(decl_58011, type, fn_oxidative_phosphorylation_67: $i > $i).
% 29.22/29.09  tff(decl_58012, type, fn_oxidative_phosphorylation_68: $i > $i).
% 29.22/29.09  tff(decl_58013, type, fn_oxidative_phosphorylation_69: $i > $i).
% 29.22/29.09  tff(decl_58014, type, fn_oxidative_phosphorylation_70: $i > $i).
% 29.22/29.09  tff(decl_58015, type, "-53.0e0": $i).
% 29.22/29.09  tff(decl_58016, type, fn_oxidative_phosphorylation_59: $i > $i).
% 29.22/29.09  tff(decl_58017, type, fn_oxidative_phosphorylation_61: $i > $i).
% 29.22/29.09  tff(decl_58018, type, fn_oxidative_phosphorylation_62: $i > $i).
% 29.22/29.09  tff(decl_58019, type, fn_oxidative_phosphorylation_60: $i > $i).
% 29.22/29.09  tff(decl_58020, type, fn_oxidative_phosphorylation_63: $i > $i).
% 29.22/29.09  tff(decl_58021, type, fn_oxidative_phosphorylation_64: $i > $i).
% 29.22/29.09  tff(decl_58022, type, 'Oxidizing-Agent': $i).
% 29.22/29.09  tff(decl_58023, type, 'The molecule that accepts electrons in a redox reaction.': $i).
% 29.22/29.09  tff(decl_58024, type, 'oxidizing agent': $i).
% 29.22/29.09  tff(decl_58025, type, 'oxidising agent': $i).
% 29.22/29.09  tff(decl_58026, type, 'oxidising-agent': $i).
% 29.22/29.09  tff(decl_58027, type, 'oxidizing-agent': $i).
% 29.22/29.09  tff(decl_58028, type, 'Oxidoreductase': $i).
% 29.22/29.09  tff(decl_58029, type, 'Enzymes which catalyze oxidation/reduction reactions.': $i).
% 29.22/29.10  tff(decl_58030, type, oxidoreductase: $i).
% 29.22/29.10  tff(decl_58031, type, fn_oxidoreductase_7: $i > $i).
% 29.22/29.10  tff(decl_58032, type, fn_oxidoreductase_9: $i > $i).
% 29.22/29.10  tff(decl_58033, type, fn_oxidoreductase_10: $i > $i).
% 29.22/29.10  tff(decl_58034, type, 'Oxygen': $i).
% 29.22/29.10  tff(decl_58035, type, 'Oxygen is a non metal atom with atomic number 8. It is represented by the symbol O.': $i).
% 29.22/29.10  tff(decl_58036, type, 'O': $i).
% 29.22/29.10  tff(decl_58037, type, oxygen: $i).
% 29.22/29.10  tff(decl_58038, type, fn_oxygen_2: $i > $i).
% 29.22/29.10  tff(decl_58039, type, fn_oxygen_3: $i > $i).
% 29.22/29.10  tff(decl_58040, type, fn_oxygen_16: $i > $i).
% 29.22/29.10  tff(decl_58041, type, fn_oxygen_15: $i > $i).
% 29.22/29.10  tff(decl_58042, type, oxygen_16_1: $i > $o).
% 29.22/29.10  tff(decl_58043, type, 'Oxygen-16': $i).
% 29.22/29.10  tff(decl_58044, type, 'This is one of the Oxygen isotopes that possess eight neutrons.': $i).
% 29.22/29.10  tff(decl_58045, type, '16 of oxygen': $i).
% 29.22/29.10  tff(decl_58046, type, 'oxygen 16': $i).
% 29.22/29.10  tff(decl_58047, type, 'oxygen-16': $i).
% 29.22/29.10  tff(decl_58048, type, oxygen_isotope_1: $i > $o).
% 29.22/29.10  tff(decl_58049, type, fn_oxygen_16_1: $i > $i).
% 29.22/29.10  tff(decl_58050, type, fn_oxygen_16_2: $i > $i).
% 29.22/29.10  tff(decl_58051, type, fn_oxygen_16_5: $i > $i).
% 29.22/29.10  tff(decl_58052, type, "15.995e0": $i).
% 29.22/29.10  tff(decl_58053, type, "16.0e0": $i).
% 29.22/29.10  tff(decl_58054, type, fn_oxygen_16_4: $i > $i).
% 29.22/29.10  tff(decl_58055, type, oxygen_18_1: $i > $o).
% 29.22/29.10  tff(decl_58056, type, 'Oxygen-18': $i).
% 29.22/29.10  tff(decl_58057, type, 'This is one of the Oxygenn isotopes that possess ten neutrons.': $i).
% 29.22/29.10  tff(decl_58058, type, '18 of oxygen': $i).
% 29.22/29.10  tff(decl_58059, type, 'oxygen 18': $i).
% 29.22/29.10  tff(decl_58060, type, 'oxygen-18': $i).
% 29.22/29.10  tff(decl_58061, type, fn_oxygen_18_2: $i > $i).
% 29.22/29.10  tff(decl_58062, type, fn_oxygen_18_3: $i > $i).
% 29.22/29.10  tff(decl_58063, type, fn_oxygen_18_5: $i > $i).
% 29.22/29.10  tff(decl_58064, type, "17.999e0": $i).
% 29.22/29.10  tff(decl_58065, type, "18.0e0": $i).
% 29.22/29.10  tff(decl_58066, type, fn_oxygen_18_4: $i > $i).
% 29.22/29.10  tff(decl_58067, type, oxygen_cycle_1: $i > $o).
% 29.22/29.10  tff(decl_58068, type, 'Oxygen-Cycle': $i).
% 29.22/29.10  tff(decl_58069, type, 'The cycling of oxygen through the biotic and abiotic components of ecosystems.': $i).
% 29.22/29.10  tff(decl_58070, type, 'undergo the oxygen cycle': $i).
% 29.22/29.10  tff(decl_58071, type, 'cycle of oxygen': $i).
% 29.22/29.10  tff(decl_58072, type, 'oxygen cycle': $i).
% 29.22/29.10  tff(decl_58073, type, 'oxygen-cycle': $i).
% 29.22/29.10  tff(decl_58074, type, fn_oxygen_cycle_1: $i > $i).
% 29.22/29.10  tff(decl_58075, type, 'Oxygen-Isotope': $i).
% 29.22/29.10  tff(decl_58076, type, 'Different types of atoms of the same oxygen, each having a different number of neutrons.': $i).
% 29.22/29.10  tff(decl_58077, type, 'isotope of oxygen': $i).
% 29.22/29.10  tff(decl_58078, type, 'oxygen isotope': $i).
% 29.22/29.10  tff(decl_58079, type, 'oxygen-isotope': $i).
% 29.22/29.10  tff(decl_58080, type, fn_oxygen_isotope_1: $i > $i).
% 29.22/29.10  tff(decl_58081, type, fn_oxygen_isotope_2: $i > $i).
% 29.22/29.10  tff(decl_58082, type, fn_oxygen_isotope_3: $i > $i).
% 29.22/29.10  tff(decl_58083, type, fn_oxygen_isotope_6: $i > $i).
% 29.22/29.10  tff(decl_58084, type, fn_oxygen_isotope_7: $i > $i).
% 29.22/29.10  tff(decl_58085, type, fn_oxygen_isotope_5: $i > $i).
% 29.22/29.10  tff(decl_58086, type, 'Oxygen-Molecule': $i).
% 29.22/29.10  tff(decl_58087, type, 'There are two atoms of oxygen in an oxygen molecule.': $i).
% 29.22/29.10  tff(decl_58088, type, 'molecular oxygen': $i).
% 29.22/29.10  tff(decl_58089, type, 'oxygen gas': $i).
% 29.22/29.10  tff(decl_58090, type, o2: $i).
% 29.22/29.10  tff(decl_58091, type, 'molecule of oxygen': $i).
% 29.22/29.10  tff(decl_58092, type, 'oxygen molecule': $i).
% 29.22/29.10  tff(decl_58093, type, 'oxygen-molecule': $i).
% 29.22/29.10  tff(decl_58094, type, fn_oxygen_molecule_1: $i > $i).
% 29.22/29.10  tff(decl_58095, type, fn_oxygen_molecule_2: $i > $i).
% 29.22/29.10  tff(decl_58096, type, fn_oxygen_molecule_3: $i > $i).
% 29.22/29.10  tff(decl_58097, type, fn_oxygen_molecule_4: $i > $i).
% 29.22/29.10  tff(decl_58098, type, fn_oxygen_molecule_5: $i > $i).
% 29.22/29.10  tff(decl_58099, type, fn_oxygen_molecule_7: $i > $i).
% 29.22/29.10  tff(decl_58100, type, fn_oxygen_molecule_8: $i > $i).
% 29.22/29.10  tff(decl_58101, type, fn_oxygen_molecule_9: $i > $i).
% 29.22/29.10  tff(decl_58102, type, fn_oxygen_molecule_11: $i > $i).
% 29.22/29.10  tff(decl_58103, type, fn_oxygen_molecule_12: $i > $i).
% 29.22/29.10  tff(decl_58104, type, fn_oxygen_molecule_13: $i > $i).
% 29.22/29.10  tff(decl_58105, type, fn_oxygen_molecule_14: $i > $i).
% 29.22/29.10  tff(decl_58106, type, fn_oxygen_molecule_15: $i > $i).
% 29.22/29.10  tff(decl_58107, type, fn_oxygen_molecule_16: $i > $i).
% 29.22/29.10  tff(decl_58108, type, fn_oxygen_molecule_17: $i > $i).
% 29.22/29.10  tff(decl_58109, type, fn_nonpolar_covalent_bond_4: $i > $i).
% 29.22/29.10  tff(decl_58110, type, fn_oxygen_molecule_10: $i > $i).
% 29.22/29.10  tff(decl_58111, type, fn_oxygen_molecule_6: $i > $i).
% 29.22/29.10  tff(decl_58112, type, 'Oxytocin': $i).
% 29.22/29.10  tff(decl_58113, type, 'A hypothalamic hormone that is released from the posterior pituitary gland. Oxytocin stimulates uterine contractions during labor and causes the ejection of milk from mammary glands during nursing.': $i).
% 29.22/29.10  tff(decl_58114, type, oxytocin: $i).
% 29.22/29.10  tff(decl_58115, type, fn_oxytocin_1: $i > $i).
% 29.22/29.10  tff(decl_58116, type, 'Oyster': $i).
% 29.22/29.10  tff(decl_58117, type, 'Any of a variety of bivalve mollusks living in marine or brackish water. Oysters typically live with one of their shells adhered to a rock or other hard surface. Humans oysters for food and as a source of pearls.': $i).
% 29.22/29.10  tff(decl_58118, type, oyster: $i).
% 29.22/29.10  tff(decl_58119, type, ozone_1: $i > $o).
% 29.22/29.10  tff(decl_58120, type, 'Ozone': $i).
% 29.22/29.10  tff(decl_58121, type, 'A triatomic molecule, consisting of three oxygen atoms.': $i).
% 29.22/29.10  tff(decl_58122, type, ozone: $i).
% 29.22/29.10  tff(decl_58123, type, ozone_depletion_1: $i > $o).
% 29.22/29.10  tff(decl_58124, type, 'Ozone-Depletion': $i).
% 29.22/29.10  tff(decl_58125, type, 'The decrease of ozone molecules in the lower stratosphere due to human activity.': $i).
% 29.22/29.10  tff(decl_58126, type, 'depletion of ozone': $i).
% 29.22/29.10  tff(decl_58127, type, 'ozone depletion': $i).
% 29.22/29.10  tff(decl_58128, type, 'ozone-depletion': $i).
% 29.22/29.10  tff(decl_58129, type, ozone_gas_1: $i > $o).
% 29.22/29.10  tff(decl_58130, type, 'Ozone-Gas': $i).
% 29.22/29.10  tff(decl_58131, type, 'Ozone gas is gaseous form of ozone.': $i).
% 29.22/29.10  tff(decl_58132, type, 'gas of ozone': $i).
% 29.22/29.10  tff(decl_58133, type, 'ozone gas': $i).
% 29.22/29.10  tff(decl_58134, type, 'ozone-gas': $i).
% 29.22/29.10  tff(decl_58135, type, fn_ozone_gas_1: $i > $i).
% 29.22/29.10  tff(decl_58136, type, 'P-Generation': $i).
% 29.22/29.10  tff(decl_58137, type, 'The parent individuals from which offspring are derived in studies of inheritance; P stands for parental.': $i).
% 29.22/29.10  tff(decl_58138, type, 'generation of p': $i).
% 29.22/29.10  tff(decl_58139, type, 'p generation': $i).
% 29.22/29.10  tff(decl_58140, type, 'p-generation': $i).
% 29.22/29.10  tff(decl_58141, type, fn_p_generation_1: $i > $i).
% 29.22/29.10  tff(decl_58142, type, fn_p_generation_2: $i > $i).
% 29.22/29.10  tff(decl_58143, type, fn_p_generation_3: $i > $i).
% 29.22/29.10  tff(decl_58144, type, 'P-Orbital': $i).
% 29.22/29.10  tff(decl_58145, type, 'The p orbital is a dumbbell-shaped region describing where an electron can be found, within a certain degree of probability. The shape of the orbital depends on the quantum numbers associated with an energy state.': $i).
% 29.22/29.10  tff(decl_58146, type, 'orbital of p': $i).
% 29.22/29.10  tff(decl_58147, type, 'p orbital': $i).
% 29.22/29.10  tff(decl_58148, type, 'p-orbital': $i).
% 29.22/29.10  tff(decl_58149, type, 'P-Site': $i).
% 29.22/29.10  tff(decl_58150, type, 'The site on the ribosome where the the tRNA holding the                        growing polypeptide chain binds.': $i).
% 29.22/29.10  tff(decl_58151, type, 'One of a ribosome\\s three binding sites for tRNA during translation.  The P site holds the tRNA carrying the growing polypeptide chain.  (P stands for peptidyl tRNA.)': $i).
% 29.22/29.10  tff(decl_58152, type, 'site of p': $i).
% 29.22/29.10  tff(decl_58153, type, 'p site': $i).
% 29.22/29.10  tff(decl_58154, type, 'p-site': $i).
% 29.22/29.10  tff(decl_58155, type, fn_p_site_1: $i > $i).
% 29.22/29.10  tff(decl_58156, type, fn_p_site_2: $i > $i).
% 29.22/29.10  tff(decl_58157, type, fn_p_site_3: $i > $i).
% 29.22/29.10  tff(decl_58158, type, fn_p_site_5: $i > $i).
% 29.22/29.10  tff(decl_58159, type, fn_p_site_7: $i > $i).
% 29.22/29.10  tff(decl_58160, type, peptidyl_trna_1: $i > $o).
% 29.22/29.10  tff(decl_58161, type, p21_gene_1: $i > $o).
% 29.22/29.10  tff(decl_58162, type, 'P21-Gene': $i).
% 29.22/29.10  tff(decl_58163, type, 'The p21 gene codes for a cyclin-dependent kinase inhibitor, which helps to regulate the cell cycle.': $i).
% 29.22/29.10  tff(decl_58164, type, 'p21 gene': $i).
% 29.22/29.10  tff(decl_58165, type, 'p21-gene': $i).
% 29.22/29.10  tff(decl_58166, type, p21_protein_1: $i > $o).
% 29.22/29.10  tff(decl_58167, type, 'P21-Protein': $i).
% 29.22/29.10  tff(decl_58168, type, 'p21 or WAF1 also known as cyclin-dependent kinase inhibitor 1 or CDK-interacting protein 1 is a protein that in humans is encoded by the CDKN1A gene located on chromosome 6.': $i).
% 29.22/29.10  tff(decl_58169, type, 'ras p21': $i).
% 29.22/29.10  tff(decl_58170, type, 'ras-p21': $i).
% 29.22/29.10  tff(decl_58171, type, 'ras p21 protein activator 1': $i).
% 29.22/29.10  tff(decl_58172, type, 'ras-p21-protein-activator-1': $i).
% 29.22/29.10  tff(decl_58173, type, rasgap: $i).
% 29.22/29.10  tff(decl_58174, type, 'p21 protein': $i).
% 29.22/29.10  tff(decl_58175, type, 'p21-protein': $i).
% 29.22/29.10  tff(decl_58176, type, fn_p21_protein_1: $i > $i).
% 29.22/29.10  tff(decl_58177, type, p53_gene_1: $i > $o).
% 29.22/29.10  tff(decl_58178, type, 'P53-Gene': $i).
% 29.22/29.10  tff(decl_58179, type, 'Acts as a tumor suppressor gene through the synthesis of the cell growth inhibitor p53 protein.': $i).
% 29.22/29.10  tff(decl_58180, type, 'protein 53 gene': $i).
% 29.22/29.10  tff(decl_58181, type, 'protein-53-gene': $i).
% 29.22/29.10  tff(decl_58182, type, 'tumor protein 53 gene': $i).
% 29.22/29.10  tff(decl_58183, type, 'tumor-protein-53-gene': $i).
% 29.22/29.10  tff(decl_58184, type, 'p53 gene': $i).
% 29.22/29.10  tff(decl_58185, type, 'p53-gene': $i).
% 29.22/29.10  tff(decl_58186, type, fn_p53_gene_1: $i > $i).
% 29.22/29.10  tff(decl_58187, type, fn_p53_gene_2: $i > $i).
% 29.22/29.10  tff(decl_58188, type, tumor_suppression_1: $i > $o).
% 29.22/29.10  tff(decl_58189, type, fn_p53_gene_3: $i > $i).
% 29.22/29.10  tff(decl_58190, type, fn_p53_gene_4: $i > $i).
% 29.22/29.10  tff(decl_58191, type, fn_p53_gene_5: $i > $i).
% 29.22/29.10  tff(decl_58192, type, fn_p53_gene_6: $i > $i).
% 29.22/29.10  tff(decl_58193, type, fn_p53_gene_7: $i > $i).
% 29.22/29.10  tff(decl_58194, type, fn_p53_gene_8: $i > $i).
% 29.22/29.10  tff(decl_58195, type, fn_p53_gene_9: $i > $i).
% 29.22/29.10  tff(decl_58196, type, fn_p53_gene_10: $i > $i).
% 29.22/29.10  tff(decl_58197, type, fn_p53_gene_11: $i > $i).
% 29.22/29.10  tff(decl_58198, type, fn_p53_gene_12: $i > $i).
% 29.22/29.10  tff(decl_58199, type, fn_p53_gene_13: $i > $i).
% 29.22/29.10  tff(decl_58200, type, fn_p53_gene_14: $i > $i).
% 29.22/29.10  tff(decl_58201, type, fn_p53_gene_15: $i > $i).
% 29.22/29.10  tff(decl_58202, type, fn_p53_gene_16: $i > $i).
% 29.22/29.10  tff(decl_58203, type, fn_p53_gene_17: $i > $i).
% 29.22/29.10  tff(decl_58204, type, fn_p53_gene_18: $i > $i).
% 29.22/29.10  tff(decl_58205, type, fn_p53_gene_19: $i > $i).
% 29.22/29.10  tff(decl_58206, type, fn_p53_gene_20: $i > $i).
% 29.22/29.10  tff(decl_58207, type, fn_p53_gene_21: $i > $i).
% 29.22/29.10  tff(decl_58208, type, fn_p53_gene_22: $i > $i).
% 29.22/29.10  tff(decl_58209, type, fn_p53_gene_23: $i > $i).
% 29.22/29.10  tff(decl_58210, type, fn_p53_gene_24: $i > $i).
% 29.22/29.10  tff(decl_58211, type, fn_p53_gene_25: $i > $i).
% 29.22/29.10  tff(decl_58212, type, fn_p53_gene_26: $i > $i).
% 29.22/29.10  tff(decl_58213, type, fn_p53_gene_27: $i > $i).
% 29.22/29.10  tff(decl_58214, type, fn_p53_gene_28: $i > $i).
% 29.22/29.10  tff(decl_58215, type, fn_p53_gene_29: $i > $i).
% 29.22/29.10  tff(decl_58216, type, fn_p53_gene_30: $i > $i).
% 29.22/29.10  tff(decl_58217, type, fn_p53_gene_31: $i > $i).
% 29.22/29.10  tff(decl_58218, type, fn_p53_gene_32: $i > $i).
% 29.22/29.10  tff(decl_58219, type, fn_p53_gene_33: $i > $i).
% 29.22/29.10  tff(decl_58220, type, fn_tumor_suppressor_gene_18: $i > $i).
% 29.22/29.10  tff(decl_58221, type, fn_tumor_suppressor_gene_17: $i > $i).
% 29.22/29.10  tff(decl_58222, type, fn_p53_gene_36: $i > $i).
% 29.22/29.10  tff(decl_58223, type, fn_tumor_suppressor_gene_13: $i > $i).
% 29.22/29.10  tff(decl_58224, type, fn_p53_gene_37: $i > $i).
% 29.22/29.10  tff(decl_58225, type, fn_tumor_suppressor_gene_14: $i > $i).
% 29.22/29.10  tff(decl_58226, type, fn_p53_gene_34: $i > $i).
% 29.22/29.10  tff(decl_58227, type, fn_tumor_suppressor_gene_16: $i > $i).
% 29.22/29.10  tff(decl_58228, type, fn_p53_gene_35: $i > $i).
% 29.22/29.10  tff(decl_58229, type, fn_tumor_suppressor_gene_15: $i > $i).
% 29.22/29.10  tff(decl_58230, type, fn_tumor_suppressor_gene_20: $i > $i).
% 29.22/29.10  tff(decl_58231, type, fn_tumor_suppressor_gene_19: $i > $i).
% 29.22/29.10  tff(decl_58232, type, fn_tumor_suppressor_gene_21: $i > $i).
% 29.22/29.10  tff(decl_58233, type, fn_tumor_suppressor_gene_23: $i > $i).
% 29.22/29.10  tff(decl_58234, type, fn_tumor_suppressor_gene_22: $i > $i).
% 29.22/29.10  tff(decl_58235, type, fn_tumor_suppressor_gene_24: $i > $i).
% 29.22/29.10  tff(decl_58236, type, fn_tumor_suppressor_gene_27: $i > $i).
% 29.22/29.10  tff(decl_58237, type, fn_tumor_suppressor_gene_28: $i > $i).
% 29.22/29.10  tff(decl_58238, type, fn_tumor_suppressor_gene_29: $i > $i).
% 29.22/29.10  tff(decl_58239, type, fn_tumor_suppressor_gene_32: $i > $i).
% 29.22/29.10  tff(decl_58240, type, fn_tumor_suppressor_gene_12: $i > $i).
% 29.22/29.10  tff(decl_58241, type, fn_tumor_suppressor_gene_11: $i > $i).
% 29.22/29.10  tff(decl_58242, type, fn_tumor_suppressor_gene_33: $i > $i).
% 29.22/29.10  tff(decl_58243, type, 'P53-Protein': $i).
% 29.22/29.10  tff(decl_58244, type, 'A protein that acts as a transcription factor to inhibit cell growth, promote cell repair, and initiate the cell death of damaged cells.': $i).
% 29.22/29.10  tff(decl_58245, type, 'p53 protein': $i).
% 29.22/29.10  tff(decl_58246, type, 'p53-protein': $i).
% 29.22/29.10  tff(decl_58247, type, fn_p53_protein_1: $i > $i).
% 29.22/29.10  tff(decl_58248, type, fn_p53_protein_2: $i > $i).
% 29.22/29.10  tff(decl_58249, type, fn_p53_protein_3: $i > $i).
% 29.22/29.10  tff(decl_58250, type, fn_p53_protein_4: $i > $i).
% 29.22/29.10  tff(decl_58251, type, 'P680': $i).
% 29.22/29.10  tff(decl_58252, type, 'A unique type of chlorophyll molecule which plays an important role in photosynthesis and is located in the reaction center of photosystem II.': $i).
% 29.22/29.10  tff(decl_58253, type, 'p680 chlorophyll': $i).
% 29.22/29.10  tff(decl_58254, type, p680: $i).
% 29.22/29.10  tff(decl_58255, type, fn_p680_1: $i > $i).
% 29.22/29.10  tff(decl_58256, type, fn_p680_4: $i > $i).
% 29.22/29.10  tff(decl_58257, type, fn_p680_5: $i > $i).
% 29.22/29.10  tff(decl_58258, type, fn_p680_6: $i > $i).
% 29.22/29.10  tff(decl_58259, type, fn_p680_7: $i > $i).
% 29.22/29.10  tff(decl_58260, type, fn_p680_8: $i > $i).
% 29.22/29.10  tff(decl_58261, type, fn_p680_9: $i > $i).
% 29.22/29.10  tff(decl_58262, type, fn_p680_10: $i > $i).
% 29.22/29.10  tff(decl_58263, type, fn_p680_11: $i > $i).
% 29.22/29.10  tff(decl_58264, type, fn_p680_12: $i > $i).
% 29.22/29.10  tff(decl_58265, type, fn_p680_13: $i > $i).
% 29.22/29.10  tff(decl_58266, type, fn_p680_16: $i > $i).
% 29.22/29.10  tff(decl_58267, type, fn_p680_20: $i > $i).
% 29.22/29.10  tff(decl_58268, type, fn_p680_21: $i > $i).
% 29.22/29.10  tff(decl_58269, type, fn_p680_22: $i > $i).
% 29.22/29.10  tff(decl_58270, type, fn_p680_23: $i > $i).
% 29.22/29.10  tff(decl_58271, type, fn_p680_24: $i > $i).
% 29.22/29.10  tff(decl_58272, type, fn_p680_25: $i > $i).
% 29.22/29.10  tff(decl_58273, type, fn_p680_26: $i > $i).
% 29.22/29.10  tff(decl_58274, type, fn_p680_27: $i > $i).
% 29.22/29.10  tff(decl_58275, type, fn_p680_28: $i > $i).
% 29.22/29.10  tff(decl_58276, type, fn_p680_29: $i > $i).
% 29.22/29.10  tff(decl_58277, type, fn_p680_30: $i > $i).
% 29.22/29.10  tff(decl_58278, type, fn_p680_31: $i > $i).
% 29.22/29.10  tff(decl_58279, type, fn_p680_32: $i > $i).
% 29.22/29.10  tff(decl_58280, type, fn_p680_33: $i > $i).
% 29.22/29.10  tff(decl_58281, type, fn_p680_34: $i > $i).
% 29.22/29.10  tff(decl_58282, type, fn_p680_35: $i > $i).
% 29.22/29.10  tff(decl_58283, type, fn_p680_37: $i > $i).
% 29.22/29.10  tff(decl_58284, type, fn_p680_38: $i > $i).
% 29.22/29.10  tff(decl_58285, type, fn_p680_14: $i > $i).
% 29.22/29.10  tff(decl_58286, type, fn_p680_15: $i > $i).
% 29.22/29.10  tff(decl_58287, type, fn_p680_3: $i > $i).
% 29.22/29.10  tff(decl_58288, type, fn_p680_2: $i > $i).
% 29.22/29.10  tff(decl_58289, type, 'P680+': $i).
% 29.22/29.10  tff(decl_58290, type, 'p680 missing an electron, typically after an electron is removed to a primary electron acceptor in the electron transport chain of photosynthesis.': $i).
% 29.22/29.10  tff(decl_58291, type, 'p680+': $i).
% 29.22/29.10  tff(decl_58292, type, 'P700': $i).
% 29.22/29.10  tff(decl_58293, type, 'P700, or Photosystem I primary donor, (where P stands for pigment) is the reaction-center chlorophyll a molecule in association with photosystem I. Its absorption spectrum peaks at 700 nm.': $i).
% 29.22/29.10  tff(decl_58294, type, 'oxidised chlorophyll': $i).
% 29.22/29.10  tff(decl_58295, type, 'oxidized chlorophyll': $i).
% 29.22/29.10  tff(decl_58296, type, p700: $i).
% 29.22/29.10  tff(decl_58297, type, fn_p700_1: $i > $i).
% 29.22/29.10  tff(decl_58298, type, fn_p700_2: $i > $i).
% 29.22/29.10  tff(decl_58299, type, fn_p700_3: $i > $i).
% 29.22/29.10  tff(decl_58300, type, fn_p700_4: $i > $i).
% 29.22/29.10  tff(decl_58301, type, fn_p700_5: $i > $i).
% 29.22/29.10  tff(decl_58302, type, fn_p700_6: $i > $i).
% 29.22/29.10  tff(decl_58303, type, fn_p700_7: $i > $i).
% 29.22/29.10  tff(decl_58304, type, fn_p700_8: $i > $i).
% 29.22/29.10  tff(decl_58305, type, fn_p700_9: $i > $i).
% 29.22/29.10  tff(decl_58306, type, fn_p700_10: $i > $i).
% 29.22/29.10  tff(decl_58307, type, fn_p700_11: $i > $i).
% 29.22/29.10  tff(decl_58308, type, fn_p700_16: $i > $i).
% 29.22/29.10  tff(decl_58309, type, fn_p700_17: $i > $i).
% 29.22/29.10  tff(decl_58310, type, fn_p700_18: $i > $i).
% 29.22/29.10  tff(decl_58311, type, fn_p700_19: $i > $i).
% 29.22/29.10  tff(decl_58312, type, fn_p700_20: $i > $i).
% 29.22/29.10  tff(decl_58313, type, fn_p700_21: $i > $i).
% 29.22/29.10  tff(decl_58314, type, fn_p700_22: $i > $i).
% 29.22/29.10  tff(decl_58315, type, fn_p700_23: $i > $i).
% 29.22/29.10  tff(decl_58316, type, fn_p700_24: $i > $i).
% 29.22/29.10  tff(decl_58317, type, fn_p700_31: $i > $i).
% 29.22/29.10  tff(decl_58318, type, fn_p700_32: $i > $i).
% 29.22/29.10  tff(decl_58319, type, fn_p700_33: $i > $i).
% 29.22/29.10  tff(decl_58320, type, fn_p700_34: $i > $i).
% 29.22/29.10  tff(decl_58321, type, fn_p700_35: $i > $i).
% 29.22/29.10  tff(decl_58322, type, fn_p700_36: $i > $i).
% 29.22/29.10  tff(decl_58323, type, fn_p700_29: $i > $i).
% 29.22/29.10  tff(decl_58324, type, fn_p700_30: $i > $i).
% 29.22/29.10  tff(decl_58325, type, fn_p700_37: $i > $i).
% 29.22/29.10  tff(decl_58326, type, fn_p700_38: $i > $i).
% 29.22/29.10  tff(decl_58327, type, 'P700+': $i).
% 29.22/29.10  tff(decl_58328, type, 'p700 missing an electron, typically after an electron is removed to a primary electron acceptor in the electron transport chain of photosynthesis.': $i).
% 29.22/29.10  tff(decl_58329, type, 'p700+': $i).
% 29.22/29.10  tff(decl_58330, type, fn_package_recombinants_in_capsid_5: $i > $i).
% 29.22/29.10  tff(decl_58331, type, fn_package_recombinants_in_capsid_4: $i > $i).
% 29.22/29.10  tff(decl_58332, type, 'Package-Recombinants-In-Capsid': $i).
% 29.22/29.10  tff(decl_58333, type, 'Moving recombinants (from a genetic recombination event) into capsid container, resulting in phage.': $i).
% 29.22/29.10  tff(decl_58334, type, 'package recombinants in capsid': $i).
% 29.22/29.10  tff(decl_58335, type, 'package-recombinants-in-capsid': $i).
% 29.22/29.10  tff(decl_58336, type, fn_package_recombinants_in_capsid_2: $i > $i).
% 29.22/29.10  tff(decl_58337, type, fn_package_recombinants_in_capsid_3: $i > $i).
% 29.22/29.10  tff(decl_58338, type, 'Pacman-Mechanism': $i).
% 29.22/29.10  tff(decl_58339, type, 'Mechanism for the movement of chromosomes during anaphase in which an enzyme depolymerizes the kinetochore microtubules as motor proteins move the chromosomes in a walking motion along the kinetochores.': $i).
% 29.22/29.10  tff(decl_58340, type, 'pacman mechanism': $i).
% 29.22/29.10  tff(decl_58341, type, 'pacman-mechanism': $i).
% 29.22/29.10  tff(decl_58342, type, 'Paedomorphosis': $i).
% 29.22/29.10  tff(decl_58343, type, 'The retention of larval features in an adult organism.': $i).
% 29.22/29.10  tff(decl_58344, type, paedomorphosis: $i).
% 29.22/29.10  tff(decl_58345, type, pain_1: $i > $o).
% 29.22/29.10  tff(decl_58346, type, 'Pain': $i).
% 29.22/29.10  tff(decl_58347, type, 'An unpleasant sensory and/or emotional experience associated with actual or anticipated tissue damage.': $i).
% 29.22/29.10  tff(decl_58348, type, pain: $i).
% 29.22/29.10  tff(decl_58349, type, 'Pain-Receptor': $i).
% 29.22/29.10  tff(decl_58350, type, 'A type of sensory receptor that responds to painful stimuli; also known as a nociceptor.': $i).
% 29.22/29.10  tff(decl_58351, type, 'receptor of pain': $i).
% 29.22/29.10  tff(decl_58352, type, 'pain receptor': $i).
% 29.22/29.10  tff(decl_58353, type, 'pain-receptor': $i).
% 29.22/29.10  tff(decl_58354, type, 'Paintbrush': $i).
% 29.22/29.10  tff(decl_58355, type, 'A brush which is used to paint': $i).
% 29.22/29.10  tff(decl_58356, type, paintbrush: $i).
% 29.22/29.10  tff(decl_58357, type, 'Pair-Rule-Gene': $i).
% 29.22/29.10  tff(decl_58358, type, 'A type of gene involved in the development of the segmented embryos of insects. Pair-rule genes are defined by the effect of a mutation in that gene, which causes the loss of the normal developmental pattern in alternating segments.': $i).
% 29.22/29.10  tff(decl_58359, type, 'pair rule gene': $i).
% 29.22/29.10  tff(decl_58360, type, 'pair-rule-gene': $i).
% 29.22/29.10  tff(decl_58361, type, pair_rule_gene_mutation_1: $i > $o).
% 29.22/29.10  tff(decl_58362, type, 'Pair-Rule-Gene-Mutation': $i).
% 29.22/29.10  tff(decl_58363, type, 'Pair-rule genes mutations in these cause a series of deletions affecting alternate segments, leaving the embryo with only half as many segments as usual.': $i).
% 29.22/29.10  tff(decl_58364, type, 'pair rule gene mutation': $i).
% 29.22/29.10  tff(decl_58365, type, 'pair-rule-gene-mutation': $i).
% 29.22/29.10  tff(decl_58366, type, fn_pair_rule_gene_mutation_1: $i > $i).
% 29.22/29.10  tff(decl_58367, type, fn_pair_rule_gene_mutation_2: $i > $i).
% 29.22/29.10  tff(decl_58368, type, fn_pair_rule_gene_mutation_3: $i > $i).
% 29.22/29.10  tff(decl_58369, type, fn_pair_rule_gene_mutation_5: $i > $i).
% 29.22/29.10  tff(decl_58370, type, fn_pair_rule_gene_mutation_8: $i > $i).
% 29.22/29.10  tff(decl_58371, type, fn_pair_rule_gene_mutation_9: $i > $i).
% 29.22/29.10  tff(decl_58372, type, fn_pair_rule_gene_mutation_10: $i > $i).
% 29.22/29.10  tff(decl_58373, type, fn_pair_rule_gene_mutation_11: $i > $i).
% 29.22/29.10  tff(decl_58374, type, fn_pair_rule_gene_mutation_12: $i > $i).
% 29.22/29.10  tff(decl_58375, type, fn_pair_rule_gene_mutation_13: $i > $i).
% 29.22/29.10  tff(decl_58376, type, fn_pair_rule_gene_mutation_14: $i > $i).
% 29.22/29.10  tff(decl_58377, type, 'Quantity_BodySegment1': $i).
% 29.22/29.10  tff(decl_58378, type, 'Quantity_BodySegment2': $i).
% 29.22/29.10  tff(decl_58379, type, fn_pair_rule_gene_mutation_15: $i > $i).
% 29.22/29.10  tff(decl_58380, type, paired_electron_1: $i > $o).
% 29.22/29.10  tff(decl_58381, type, 'Paired-Electron': $i).
% 29.22/29.10  tff(decl_58382, type, 'One of two electrons that form a valence bond between two atoms.': $i).
% 29.22/29.10  tff(decl_58383, type, 'paired electron': $i).
% 29.22/29.10  tff(decl_58384, type, 'paired-electron': $i).
% 29.22/29.10  tff(decl_58385, type, unpaired_electron_1: $i > $o).
% 29.22/29.10  tff(decl_58386, type, pairing_of_homologous_chromosome_1: $i > $o).
% 29.22/29.10  tff(decl_58387, type, 'Pairing-Of-Homologous-Chromosome': $i).
% 29.22/29.10  tff(decl_58388, type, 'An event where corresponding chromosomes, one from each parent, pair together during metaphase I of meiosis.': $i).
% 29.22/29.10  tff(decl_58389, type, 'pairing of homologous chromosomes': $i).
% 29.22/29.10  tff(decl_58390, type, 'pairing of homologous chromosome': $i).
% 29.22/29.10  tff(decl_58391, type, 'pairing-of-homologous-chromosome': $i).
% 29.22/29.10  tff(decl_58392, type, fn_pairing_of_homologous_chromosome_1: $i > $i).
% 29.22/29.10  tff(decl_58393, type, fn_pairing_of_homologous_chromosome_2: $i > $i).
% 29.22/29.10  tff(decl_58394, type, fn_pairing_of_homologous_chromosome_3: $i > $i).
% 29.22/29.10  tff(decl_58395, type, fn_pairing_of_homologous_chromosome_4: $i > $i).
% 29.22/29.10  tff(decl_58396, type, fn_pairing_of_homologous_chromosome_5: $i > $i).
% 29.22/29.10  tff(decl_58397, type, paleoanthropology_1: $i > $o).
% 29.22/29.10  tff(decl_58398, type, 'Paleoanthropology': $i).
% 29.22/29.10  tff(decl_58399, type, 'The study of ancient humans and human evolution, relying heavily on the fossil record.': $i).
% 29.22/29.10  tff(decl_58400, type, paleoanthropology: $i).
% 29.22/29.10  tff(decl_58401, type, 'Paleontological-Species-Concept': $i).
% 29.22/29.10  tff(decl_58402, type, 'The definition of a species based morphological features known only from the fossil record.': $i).
% 29.22/29.10  tff(decl_58403, type, 'paleontological species concept': $i).
% 29.22/29.10  tff(decl_58404, type, 'paleontological-species-concept': $i).
% 29.22/29.10  tff(decl_58405, type, paleontology_1: $i > $o).
% 29.22/29.10  tff(decl_58406, type, 'Paleontology': $i).
% 29.22/29.10  tff(decl_58407, type, 'The scientific study of prehistoric life. Paleontology uses the fossil record to determine organisms\\ evolutionary history and ecological interactions.': $i).
% 29.22/29.10  tff(decl_58408, type, paleontology: $i).
% 29.22/29.10  tff(decl_58409, type, 'Palisade-Mesophyll': $i).
% 29.22/29.10  tff(decl_58410, type, 'It is one of the layers of mesophylls of many eudicots.': $i).
% 29.22/29.10  tff(decl_58411, type, 'mesophyll of palisade': $i).
% 29.22/29.10  tff(decl_58412, type, 'palisade mesophyll': $i).
% 29.22/29.10  tff(decl_58413, type, 'palisade-mesophyll': $i).
% 29.22/29.10  tff(decl_58414, type, fn_palisade_mesophyll_1: $i > $i).
% 29.22/29.10  tff(decl_58415, type, sclerenchyma_fiber_1: $i > $o).
% 29.22/29.10  tff(decl_58416, type, palladium_1: $i > $o).
% 29.22/29.10  tff(decl_58417, type, 'Palladium': $i).
% 29.22/29.10  tff(decl_58418, type, 'Palladium is a metal atom with atomic number 46. It is represented by the symbol Pd.': $i).
% 29.22/29.10  tff(decl_58419, type, palladium: $i).
% 29.22/29.10  tff(decl_58420, type, 'Pd': $i).
% 29.22/29.10  tff(decl_58421, type, fn_palladium_3: $i > $i).
% 29.22/29.10  tff(decl_58422, type, fn_palladium_4: $i > $i).
% 29.22/29.10  tff(decl_58423, type, fn_palladium_5: $i > $i).
% 29.22/29.10  tff(decl_58424, type, fn_palladium_9: $i > $i).
% 29.22/29.10  tff(decl_58425, type, fn_palladium_10: $i > $i).
% 29.22/29.10  tff(decl_58426, type, fn_palladium_11: $i > $i).
% 29.22/29.10  tff(decl_58427, type, fn_palladium_12: $i > $i).
% 29.22/29.10  tff(decl_58428, type, "106": $i).
% 29.22/29.10  tff(decl_58429, type, "106.4": $i).
% 29.22/29.10  tff(decl_58430, type, fn_palladium_7: $i > $i).
% 29.22/29.10  tff(decl_58431, type, fn_palladium_8: $i > $i).
% 29.22/29.10  tff(decl_58432, type, fn_palladium_6: $i > $i).
% 29.22/29.10  tff(decl_58433, type, 'Pancreas': $i).
% 29.22/29.10  tff(decl_58434, type, 'The pancreas is an important organ which serves both endocrine and exocrine functions. The primary endocrine function of the pancreas is to secrete the hormone insulin and the pancreas functions as an exocrine gland for the digestive system by secreteing digestive enzymes.': $i).
% 29.22/29.10  tff(decl_58435, type, pancreas: $i).
% 29.22/29.10  tff(decl_58436, type, 'Pancreas-Cell': $i).
% 29.22/29.10  tff(decl_58437, type, 'The cells of the pancreas, an organ which is both an endocrine and exocrine gland. The pancreas has two cells, beta and islet of lagerhans.': $i).
% 29.22/29.10  tff(decl_58438, type, 'cell of pancreas': $i).
% 29.22/29.10  tff(decl_58439, type, 'pancreas cell': $i).
% 29.22/29.10  tff(decl_58440, type, 'pancreas-cell': $i).
% 29.22/29.10  tff(decl_58441, type, fn_pancreas_cell_2: $i > $i).
% 29.22/29.10  tff(decl_58442, type, fn_pancreas_cell_3: $i > $i).
% 29.22/29.10  tff(decl_58443, type, fn_pancreas_cell_4: $i > $i).
% 29.22/29.10  tff(decl_58444, type, fn_pancreas_cell_6: $i > $i).
% 29.22/29.10  tff(decl_58445, type, fn_pancreas_cell_7: $i > $i).
% 29.22/29.10  tff(decl_58446, type, fn_pancreas_cell_8: $i > $i).
% 29.22/29.10  tff(decl_58447, type, fn_pancreas_cell_9: $i > $i).
% 29.22/29.10  tff(decl_58448, type, fn_pancreas_cell_10: $i > $i).
% 29.22/29.10  tff(decl_58449, type, fn_pancreas_cell_11: $i > $i).
% 29.22/29.10  tff(decl_58450, type, fn_pancreas_cell_12: $i > $i).
% 29.22/29.10  tff(decl_58451, type, fn_pancreas_cell_13: $i > $i).
% 29.22/29.10  tff(decl_58452, type, fn_pancreas_cell_14: $i > $i).
% 29.22/29.10  tff(decl_58453, type, fn_pancreas_cell_15: $i > $i).
% 29.22/29.10  tff(decl_58454, type, fn_pancreas_cell_17: $i > $i).
% 29.22/29.10  tff(decl_58455, type, fn_pancreas_cell_18: $i > $i).
% 29.22/29.10  tff(decl_58456, type, fn_pancreas_cell_19: $i > $i).
% 29.22/29.10  tff(decl_58457, type, fn_pancreas_cell_21: $i > $i).
% 29.22/29.10  tff(decl_58458, type, fn_pancreas_cell_22: $i > $i).
% 29.22/29.10  tff(decl_58459, type, fn_pancreas_cell_23: $i > $i).
% 29.22/29.10  tff(decl_58460, type, fn_pancreas_cell_24: $i > $i).
% 29.22/29.10  tff(decl_58461, type, fn_pancreas_cell_27: $i > $i).
% 29.22/29.10  tff(decl_58462, type, fn_pancreas_cell_34: $i > $i).
% 29.22/29.10  tff(decl_58463, type, fn_pancreas_cell_35: $i > $i).
% 29.22/29.10  tff(decl_58464, type, fn_pancreas_cell_36: $i > $i).
% 29.22/29.10  tff(decl_58465, type, fn_pancreas_cell_37: $i > $i).
% 29.22/29.10  tff(decl_58466, type, fn_pancreas_cell_38: $i > $i).
% 29.22/29.10  tff(decl_58467, type, fn_pancreas_cell_39: $i > $i).
% 29.22/29.10  tff(decl_58468, type, fn_pancreas_cell_40: $i > $i).
% 29.22/29.10  tff(decl_58469, type, fn_pancreas_cell_41: $i > $i).
% 29.22/29.10  tff(decl_58470, type, fn_pancreas_cell_42: $i > $i).
% 29.22/29.10  tff(decl_58471, type, fn_pancreas_cell_43: $i > $i).
% 29.22/29.10  tff(decl_58472, type, fn_pancreas_cell_46: $i > $i).
% 29.22/29.10  tff(decl_58473, type, fn_pancreas_cell_47: $i > $i).
% 29.22/29.10  tff(decl_58474, type, fn_pancreas_cell_48: $i > $i).
% 29.22/29.10  tff(decl_58475, type, fn_pancreas_cell_49: $i > $i).
% 29.22/29.10  tff(decl_58476, type, fn_pancreas_cell_50: $i > $i).
% 29.22/29.10  tff(decl_58477, type, fn_pancreas_cell_51: $i > $i).
% 29.22/29.10  tff(decl_58478, type, fn_pancreas_cell_52: $i > $i).
% 29.22/29.10  tff(decl_58479, type, fn_pancreas_cell_53: $i > $i).
% 29.22/29.10  tff(decl_58480, type, fn_pancreas_cell_54: $i > $i).
% 29.22/29.10  tff(decl_58481, type, fn_pancreas_cell_55: $i > $i).
% 29.22/29.10  tff(decl_58482, type, fn_pancreas_cell_56: $i > $i).
% 29.22/29.10  tff(decl_58483, type, fn_pancreas_cell_57: $i > $i).
% 29.22/29.10  tff(decl_58484, type, fn_pancreas_cell_58: $i > $i).
% 29.22/29.10  tff(decl_58485, type, fn_pancreas_cell_59: $i > $i).
% 29.22/29.10  tff(decl_58486, type, fn_pancreas_cell_60: $i > $i).
% 29.22/29.10  tff(decl_58487, type, fn_pancreas_cell_61: $i > $i).
% 29.22/29.10  tff(decl_58488, type, fn_pancreas_cell_62: $i > $i).
% 29.22/29.10  tff(decl_58489, type, fn_pancreas_cell_63: $i > $i).
% 29.22/29.10  tff(decl_58490, type, fn_pancreas_cell_64: $i > $i).
% 29.22/29.10  tff(decl_58491, type, fn_pancreas_cell_65: $i > $i).
% 29.22/29.10  tff(decl_58492, type, fn_pancreas_cell_66: $i > $i).
% 29.22/29.10  tff(decl_58493, type, fn_pancreas_cell_67: $i > $i).
% 29.22/29.10  tff(decl_58494, type, fn_pancreas_cell_68: $i > $i).
% 29.22/29.10  tff(decl_58495, type, fn_pancreas_cell_69: $i > $i).
% 29.22/29.10  tff(decl_58496, type, fn_pancreas_cell_70: $i > $i).
% 29.22/29.10  tff(decl_58497, type, fn_pancreas_cell_71: $i > $i).
% 29.22/29.10  tff(decl_58498, type, fn_pancreas_cell_72: $i > $i).
% 29.22/29.10  tff(decl_58499, type, fn_pancreas_cell_73: $i > $i).
% 29.22/29.10  tff(decl_58500, type, fn_pancreas_cell_74: $i > $i).
% 29.22/29.10  tff(decl_58501, type, fn_pancreas_cell_75: $i > $i).
% 29.22/29.10  tff(decl_58502, type, fn_pancreas_cell_76: $i > $i).
% 29.22/29.10  tff(decl_58503, type, fn_pancreas_cell_77: $i > $i).
% 29.22/29.10  tff(decl_58504, type, fn_pancreas_cell_78: $i > $i).
% 29.22/29.10  tff(decl_58505, type, fn_pancreas_cell_80: $i > $i).
% 29.22/29.10  tff(decl_58506, type, fn_pancreas_cell_81: $i > $i).
% 29.22/29.10  tff(decl_58507, type, fn_pancreas_cell_82: $i > $i).
% 29.22/29.10  tff(decl_58508, type, fn_pancreas_cell_83: $i > $i).
% 29.22/29.10  tff(decl_58509, type, fn_pancreas_cell_84: $i > $i).
% 29.22/29.10  tff(decl_58510, type, fn_pancreas_cell_85: $i > $i).
% 29.22/29.10  tff(decl_58511, type, fn_pancreas_cell_86: $i > $i).
% 29.22/29.10  tff(decl_58512, type, fn_pancreas_cell_87: $i > $i).
% 29.22/29.10  tff(decl_58513, type, fn_pancreas_cell_88: $i > $i).
% 29.22/29.10  tff(decl_58514, type, fn_pancreas_cell_89: $i > $i).
% 29.22/29.10  tff(decl_58515, type, fn_pancreas_cell_90: $i > $i).
% 29.22/29.10  tff(decl_58516, type, fn_pancreas_cell_91: $i > $i).
% 29.22/29.10  tff(decl_58517, type, fn_pancreas_cell_92: $i > $i).
% 29.22/29.10  tff(decl_58518, type, fn_pancreas_cell_93: $i > $i).
% 29.22/29.10  tff(decl_58519, type, fn_pancreas_cell_94: $i > $i).
% 29.22/29.10  tff(decl_58520, type, fn_pancreas_cell_95: $i > $i).
% 29.22/29.10  tff(decl_58521, type, fn_pancreas_cell_96: $i > $i).
% 29.22/29.10  tff(decl_58522, type, fn_pancreas_cell_97: $i > $i).
% 29.22/29.10  tff(decl_58523, type, fn_pancreas_cell_98: $i > $i).
% 29.22/29.10  tff(decl_58524, type, fn_pancreas_cell_99: $i > $i).
% 29.22/29.10  tff(decl_58525, type, fn_pancreas_cell_100: $i > $i).
% 29.22/29.10  tff(decl_58526, type, fn_pancreas_cell_101: $i > $i).
% 29.22/29.10  tff(decl_58527, type, fn_pancreas_cell_102: $i > $i).
% 29.22/29.10  tff(decl_58528, type, fn_pancreas_cell_103: $i > $i).
% 29.22/29.10  tff(decl_58529, type, fn_pancreas_cell_104: $i > $i).
% 29.22/29.10  tff(decl_58530, type, fn_pancreas_cell_105: $i > $i).
% 29.22/29.10  tff(decl_58531, type, fn_pancreas_cell_106: $i > $i).
% 29.22/29.10  tff(decl_58532, type, fn_pancreas_cell_107: $i > $i).
% 29.22/29.10  tff(decl_58533, type, fn_pancreas_cell_108: $i > $i).
% 29.22/29.10  tff(decl_58534, type, fn_pancreas_cell_109: $i > $i).
% 29.22/29.10  tff(decl_58535, type, fn_pancreas_cell_110: $i > $i).
% 29.22/29.10  tff(decl_58536, type, fn_pancreas_cell_111: $i > $i).
% 29.22/29.10  tff(decl_58537, type, fn_pancreas_cell_112: $i > $i).
% 29.22/29.10  tff(decl_58538, type, fn_pancreas_cell_113: $i > $i).
% 29.22/29.10  tff(decl_58539, type, fn_pancreas_cell_114: $i > $i).
% 29.22/29.10  tff(decl_58540, type, fn_pancreas_cell_115: $i > $i).
% 29.22/29.10  tff(decl_58541, type, fn_pancreas_cell_116: $i > $i).
% 29.22/29.10  tff(decl_58542, type, fn_pancreas_cell_117: $i > $i).
% 29.22/29.10  tff(decl_58543, type, fn_pancreas_cell_118: $i > $i).
% 29.22/29.10  tff(decl_58544, type, fn_pancreas_cell_119: $i > $i).
% 29.22/29.10  tff(decl_58545, type, fn_pancreas_cell_120: $i > $i).
% 29.22/29.10  tff(decl_58546, type, fn_pancreas_cell_121: $i > $i).
% 29.22/29.10  tff(decl_58547, type, fn_pancreas_cell_122: $i > $i).
% 29.22/29.10  tff(decl_58548, type, fn_pancreas_cell_123: $i > $i).
% 29.22/29.10  tff(decl_58549, type, fn_pancreas_cell_124: $i > $i).
% 29.22/29.10  tff(decl_58550, type, fn_pancreas_cell_125: $i > $i).
% 29.22/29.10  tff(decl_58551, type, fn_pancreas_cell_126: $i > $i).
% 29.22/29.10  tff(decl_58552, type, fn_pancreas_cell_127: $i > $i).
% 29.22/29.10  tff(decl_58553, type, fn_pancreas_cell_128: $i > $i).
% 29.22/29.10  tff(decl_58554, type, fn_synthesis_of_endomembranous_system_membrane_72: $i > $i).
% 29.22/29.10  tff(decl_58555, type, free_ribosome_0: $i).
% 29.22/29.10  tff(decl_58556, type, fn_secretory_cell_22: $i > $i).
% 29.22/29.10  tff(decl_58557, type, fn_secretory_cell_19: $i > $i).
% 29.22/29.10  tff(decl_58558, type, fn_secretory_cell_21: $i > $i).
% 29.22/29.10  tff(decl_58559, type, fn_secretory_cell_18: $i > $i).
% 29.22/29.10  tff(decl_58560, type, fn_secretory_cell_17: $i > $i).
% 29.22/29.10  tff(decl_58561, type, fn_secretory_cell_49: $i > $i).
% 29.22/29.10  tff(decl_58562, type, fn_secretory_cell_23: $i > $i).
% 29.22/29.10  tff(decl_58563, type, fn_secretory_cell_80: $i > $i).
% 29.22/29.10  tff(decl_58564, type, fn_secretory_cell_26: $i > $i).
% 29.22/29.10  tff(decl_58565, type, fn_secretory_cell_48: $i > $i).
% 29.22/29.10  tff(decl_58566, type, fn_secretory_cell_47: $i > $i).
% 29.22/29.10  tff(decl_58567, type, fn_pancreas_cell_45: $i > $i).
% 29.22/29.10  tff(decl_58568, type, fn_pancreas_cell_44: $i > $i).
% 29.22/29.10  tff(decl_58569, type, 'Pancreatic-Amylase': $i).
% 29.22/29.10  tff(decl_58570, type, 'Enzyme secreted by the pancreas which hydrolyzes starch and glycogen during the process of digestion.': $i).
% 29.22/29.10  tff(decl_58571, type, 'pancreatic amylase': $i).
% 29.22/29.10  tff(decl_58572, type, 'pancreatic-amylase': $i).
% 29.22/29.10  tff(decl_58573, type, 'Pancreatic-Carboxypeptidase': $i).
% 29.22/29.10  tff(decl_58574, type, 'Enzyme produced by the pancreas which catalyzes the chemical digestion of proteins.': $i).
% 29.22/29.10  tff(decl_58575, type, 'pancreatic carboxypeptidase': $i).
% 29.22/29.10  tff(decl_58576, type, 'pancreatic-carboxypeptidase': $i).
% 29.22/29.10  tff(decl_58577, type, 'Pancreatic-Hormone': $i).
% 29.22/29.10  tff(decl_58578, type, 'One of the hormones produced by the pancreas that function in the maintenance of blood glucose levels.': $i).
% 29.22/29.10  tff(decl_58579, type, 'pancreatic hormone': $i).
% 29.22/29.10  tff(decl_58580, type, 'pancreatic-hormone': $i).
% 29.22/29.10  tff(decl_58581, type, 'Pancreatic-Lipase': $i).
% 29.22/29.10  tff(decl_58582, type, 'Lipase enzyme produced by the pancreas which functions in the digestion of lipids.': $i).
% 29.22/29.10  tff(decl_58583, type, 'pancreatic lipase': $i).
% 29.22/29.10  tff(decl_58584, type, 'pancreatic-lipase': $i).
% 29.22/29.10  tff(decl_58585, type, 'Pancreatic-Nuclease': $i).
% 29.22/29.10  tff(decl_58586, type, 'Nuclease enzyme produced by the pancreas which functions in the digestion of nucleic acids.': $i).
% 29.22/29.10  tff(decl_58587, type, 'pancreatic nuclease': $i).
% 29.22/29.10  tff(decl_58588, type, 'pancreatic-nuclease': $i).
% 29.22/29.10  tff(decl_58589, type, pandemic_1: $i > $o).
% 29.22/29.10  tff(decl_58590, type, 'Pandemic': $i).
% 29.22/29.10  tff(decl_58591, type, 'An epidemic of infectious disease that spreads across the globe.': $i).
% 29.22/29.10  tff(decl_58592, type, pandemic: $i).
% 29.22/29.10  tff(decl_58593, type, 'Paper': $i).
% 29.22/29.10  tff(decl_58594, type, paper: $i).
% 29.22/29.10  tff(decl_58595, type, fn_paper_1: $i > $i).
% 29.22/29.10  tff(decl_58596, type, papilloma_virus_1: $i > $o).
% 29.22/29.10  tff(decl_58597, type, 'Papilloma-Virus': $i).
% 29.22/29.10  tff(decl_58598, type, 'One of an ancient family of viruses that infect humans and other aminote vertebrates. In humans, the human papilloma virus (HPV) causes genital warts and cervical cancer.': $i).
% 29.22/29.10  tff(decl_58599, type, 'virus of papilloma': $i).
% 29.22/29.10  tff(decl_58600, type, 'papilloma virus': $i).
% 29.22/29.10  tff(decl_58601, type, 'papilloma-virus': $i).
% 29.22/29.10  tff(decl_58602, type, 'Papovavirus': $i).
% 29.22/29.10  tff(decl_58603, type, 'A class of viruses with double stranded DNA.': $i).
% 29.22/29.10  tff(decl_58604, type, papovavirus: $i).
% 29.22/29.10  tff(decl_58605, type, 'Parabasalid': $i).
% 29.22/29.10  tff(decl_58606, type, 'One of a group of anaerobic flagellated protists that form symbiotic or parasitic relationships with animals. Parabasalids have flagella arranged in one or more clusters in the anterior region of the cell, and also display a secondary lack of mitochondria.': $i).
% 29.22/29.10  tff(decl_58607, type, parabasalid: $i).
% 29.22/29.10  tff(decl_58608, type, paracrine_molecule_1: $i > $o).
% 29.22/29.10  tff(decl_58609, type, 'Paracrine-Molecule': $i).
% 29.22/29.10  tff(decl_58610, type, 'A secreted signalling molecule whose target is a neighboring cell.': $i).
% 29.22/29.10  tff(decl_58611, type, 'paracrine molecule': $i).
% 29.22/29.10  tff(decl_58612, type, 'paracrine-molecule': $i).
% 29.22/29.10  tff(decl_58613, type, 'Parallel-DNA-strand': $i).
% 29.22/29.10  tff(decl_58614, type, 'A parallel DNA strand is one of the two DNA strands present in a chromosome. The sugar-phosphate backbone of parallel DNA strands run in opposite direction of that of Anti-parallel DNA strands. In parallel DNA strands, the 3\\ and 5\\ ends of both strands match.': $i).
% 29.22/29.10  tff(decl_58615, type, 'parallel dna strand': $i).
% 29.22/29.10  tff(decl_58616, type, 'parallel-dna-strand': $i).
% 29.22/29.10  tff(decl_58617, type, paralogous_gene_1: $i > $o).
% 29.22/29.10  tff(decl_58618, type, 'Paralogous-Gene': $i).
% 29.22/29.10  tff(decl_58619, type, 'Paralogous genes are genes that arise from a gene duplication event within the genome of an individual.': $i).
% 29.22/29.10  tff(decl_58620, type, 'paralogous gene': $i).
% 29.22/29.10  tff(decl_58621, type, 'paralogous-gene': $i).
% 29.22/29.10  tff(decl_58622, type, 'Paramecium': $i).
% 29.22/29.10  tff(decl_58623, type, 'A genus of freshwater unicellular ciliate protozoans. Paramecium are used in observational studies of ciliary locomotion and osmoregulation, as they can be seen to remove excess water that enters the cell via osmosis. They are heterotrophic.': $i).
% 29.22/29.10  tff(decl_58624, type, paramecium: $i).
% 29.22/29.10  tff(decl_58625, type, stylonychia_1: $i > $o).
% 29.22/29.10  tff(decl_58626, type, 'Paranthropus-Boisei': $i).
% 29.22/29.10  tff(decl_58627, type, 'A species of early hominid that lived from 2.6 to 1.2 million years ago in eastern Africa.': $i).
% 29.22/29.10  tff(decl_58628, type, 'paranthropus boisei': $i).
% 29.22/29.10  tff(decl_58629, type, 'paranthropus-boisei': $i).
% 29.22/29.10  tff(decl_58630, type, 'Paraphyletic': $i).
% 29.22/29.10  tff(decl_58631, type, 'In cladistics, a term used to describe a group of taxa that consists of a common ancestor and some, but not all, of its descendants.': $i).
% 29.22/29.10  tff(decl_58632, type, paraphyletic: $i).
% 29.22/29.10  tff(decl_58633, type, paraphyly: $i).
% 29.22/29.10  tff(decl_58634, type, 'Parareptile': $i).
% 29.22/29.10  tff(decl_58635, type, 'The first major group of reptiles to emerge. Most were large-bodied herbivores. The parareptiles went extinct in the Triassic.': $i).
% 29.22/29.10  tff(decl_58636, type, parareptile: $i).
% 29.22/29.10  tff(decl_58637, type, 'Parasite': $i).
% 29.22/29.10  tff(decl_58638, type, 'An organism that feeds on an individual of another species (the host) while living on or within the host\\s body. A single parasite generally causes only minor damage to the host.': $i).
% 29.22/29.10  tff(decl_58639, type, parasite: $i).
% 29.22/29.10  tff(decl_58640, type, parasitism_1: $i > $o).
% 29.22/29.10  tff(decl_58641, type, 'Parasitism': $i).
% 29.22/29.10  tff(decl_58642, type, 'A symbiotic relationship in which one organism (called the parasite) feeds on or in some other way benefits from the association, at the expense of the other organism (called the host). Hosts are generally not killed directly by their parasites.': $i).
% 29.22/29.10  tff(decl_58643, type, parasitism: $i).
% 29.22/29.10  tff(decl_58644, type, 'Parasitoid': $i).
% 29.22/29.10  tff(decl_58645, type, 'An organism that spends part of its life as a parasite, especially one that eventually kills or sterilizes the host.': $i).
% 29.22/29.10  tff(decl_58646, type, parasitoid: $i).
% 29.22/29.10  tff(decl_58647, type, 'Parasitoid-Wasp': $i).
% 29.22/29.10  tff(decl_58648, type, 'A large group of hymenopteran wasps that primarily parasitize other insects. Adult female wasps lay eggs in the bodies of the host, which is then consumed from the inside by the developing wasp larva. The mature larva eats its way out of or bursts through the body of the dying host and then pupates.': $i).
% 29.22/29.10  tff(decl_58649, type, 'wasp of parasitoid': $i).
% 29.22/29.10  tff(decl_58650, type, 'parasitoid wasp': $i).
% 29.22/29.10  tff(decl_58651, type, 'parasitoid-wasp': $i).
% 29.22/29.10  tff(decl_58652, type, parasympathetic_division_1: $i > $o).
% 29.22/29.10  tff(decl_58653, type, 'Parasympathetic-Division': $i).
% 29.22/29.10  tff(decl_58654, type, 'One of three divisions of the autonomic nervous system, along with the sympathetic and enteric divisions. The parasympathetic division regulates body functions that occur at rest, such as sexual arousal, salivation, and digestion.': $i).
% 29.22/29.10  tff(decl_58655, type, 'division of parasympathetic': $i).
% 29.22/29.10  tff(decl_58656, type, 'parasympathetic division': $i).
% 29.22/29.10  tff(decl_58657, type, 'parasympathetic-division': $i).
% 29.22/29.10  tff(decl_58658, type, sympathetic_division_1: $i > $o).
% 29.22/29.10  tff(decl_58659, type, parathion_1: $i > $o).
% 29.22/29.10  tff(decl_58660, type, 'Parathion': $i).
% 29.22/29.10  tff(decl_58661, type, 'It is an organophosphate compound used as an insecticide.': $i).
% 29.22/29.10  tff(decl_58662, type, parathion: $i).
% 29.22/29.10  tff(decl_58663, type, fn_parathion_1: $i > $i).
% 29.22/29.10  tff(decl_58664, type, 'Parathyroid-Gland': $i).
% 29.22/29.10  tff(decl_58665, type, 'Any of the four small endocrine glands in the neck that secrete parathyroid hormone.': $i).
% 29.22/29.10  tff(decl_58666, type, 'gland of parathyroid': $i).
% 29.22/29.10  tff(decl_58667, type, 'parathyroid gland': $i).
% 29.22/29.10  tff(decl_58668, type, 'parathyroid-gland': $i).
% 29.22/29.10  tff(decl_58669, type, 'Parathyroid-Hormone': $i).
% 29.22/29.10  tff(decl_58670, type, 'A hormone secreted by the parathyroid glands. It increases blood calcium levels by stimulating calcium release from bones and reabsorption of calcium by the kidneys.': $i).
% 29.22/29.10  tff(decl_58671, type, 'hormone of parathyroid': $i).
% 29.22/29.10  tff(decl_58672, type, 'parathyroid hormone': $i).
% 29.22/29.10  tff(decl_58673, type, 'parathyroid-hormone': $i).
% 29.22/29.10  tff(decl_58674, type, parazoa_1: $i > $o).
% 29.22/29.10  tff(decl_58675, type, 'Parazoa': $i).
% 29.22/29.10  tff(decl_58676, type, 'Morphologically simple animals, including sponges, that lack true tissues.': $i).
% 29.22/29.10  tff(decl_58677, type, parazoa: $i).
% 29.22/29.10  tff(decl_58678, type, fn_parazoa_1: $i > $i).
% 29.22/29.10  tff(decl_58679, type, fn_parazoa_2: $i > $i).
% 29.22/29.10  tff(decl_58680, type, fn_parazoa_3: $i > $i).
% 29.22/29.10  tff(decl_58681, type, fn_parazoa_4: $i > $i).
% 29.22/29.10  tff(decl_58682, type, fn_parazoa_5: $i > $i).
% 29.22/29.10  tff(decl_58683, type, fn_parazoa_6: $i > $i).
% 29.22/29.10  tff(decl_58684, type, 'Parenchyma-Cell': $i).
% 29.22/29.10  tff(decl_58685, type, 'In plants, a type of thin-walled cell that performs a variety of metabolic functions.': $i).
% 29.22/29.10  tff(decl_58686, type, 'cell of parenchyma': $i).
% 29.22/29.10  tff(decl_58687, type, 'parenchyma cell': $i).
% 29.22/29.10  tff(decl_58688, type, 'parenchyma-cell': $i).
% 29.22/29.10  tff(decl_58689, type, fn_parenchyma_cell_1: $i > $i).
% 29.22/29.10  tff(decl_58690, type, fn_parenchyma_cell_2: $i > $i).
% 29.22/29.10  tff(decl_58691, type, fn_parenchyma_cell_3: $i > $i).
% 29.22/29.10  tff(decl_58692, type, fn_parenchyma_cell_4: $i > $i).
% 29.22/29.10  tff(decl_58693, type, fn_parenchyma_cell_5: $i > $i).
% 29.22/29.10  tff(decl_58694, type, fn_parenchyma_cell_6: $i > $i).
% 29.22/29.10  tff(decl_58695, type, fn_parenchyma_cell_7: $i > $i).
% 29.22/29.10  tff(decl_58696, type, fn_parenchyma_cell_8: $i > $i).
% 29.22/29.10  tff(decl_58697, type, fn_parenchyma_cell_10: $i > $i).
% 29.22/29.10  tff(decl_58698, type, fn_plasmodesmata_5: $i > $i).
% 29.22/29.10  tff(decl_58699, type, fn_plasmodesmata_6: $i > $i).
% 29.22/29.10  tff(decl_58700, type, fn_plasmodesmata_17: $i > $i).
% 29.22/29.10  tff(decl_58701, type, fn_plasmodesmata_13: $i > $i).
% 29.22/29.10  tff(decl_58702, type, fn_plasmodesmata_18: $i > $i).
% 29.22/29.10  tff(decl_58703, type, fn_plasmodesmata_19: $i > $i).
% 29.22/29.10  tff(decl_58704, type, fn_plant_cell_104: $i > $i).
% 29.22/29.10  tff(decl_58705, type, fn_plant_metabolic_cell_8: $i > $i).
% 29.22/29.10  tff(decl_58706, type, fn_plant_metabolic_cell_10: $i > $i).
% 29.22/29.10  tff(decl_58707, type, fn_plant_metabolic_cell_20: $i > $i).
% 29.22/29.10  tff(decl_58708, type, fn_plant_metabolic_cell_16: $i > $i).
% 29.22/29.10  tff(decl_58709, type, fn_plant_metabolic_cell_43: $i > $i).
% 29.22/29.10  tff(decl_58710, type, fn_plant_metabolic_cell_12: $i > $i).
% 29.22/29.10  tff(decl_58711, type, fn_plant_metabolic_cell_38: $i > $i).
% 29.22/29.10  tff(decl_58712, type, 'Parent': $i).
% 29.22/29.10  tff(decl_58713, type, 'In biology, an organism that gives rise to another.': $i).
% 29.22/29.10  tff(decl_58714, type, parent: $i).
% 29.22/29.10  tff(decl_58715, type, fn_parent_1: $i > $i).
% 29.22/29.10  tff(decl_58716, type, fn_parent_2: $i > $i).
% 29.22/29.10  tff(decl_58717, type, 'Parent-Cell': $i).
% 29.22/29.10  tff(decl_58718, type, 'During cell division, the parent cell is the initial cell that will divide, resulting in daughter cells.': $i).
% 29.22/29.10  tff(decl_58719, type, 'cell of parent': $i).
% 29.22/29.10  tff(decl_58720, type, 'parent cell': $i).
% 29.22/29.10  tff(decl_58721, type, 'parent-cell': $i).
% 29.22/29.10  tff(decl_58722, type, 'Parental-strands': $i).
% 29.22/29.10  tff(decl_58723, type, 'Parental strands are the original DNA strands to be replicated': $i).
% 29.22/29.10  tff(decl_58724, type, 'parent strand': $i).
% 29.22/29.10  tff(decl_58725, type, 'parental dna strand': $i).
% 29.22/29.10  tff(decl_58726, type, 'parental strands': $i).
% 29.22/29.10  tff(decl_58727, type, 'parental strand': $i).
% 29.22/29.10  tff(decl_58728, type, 'parental-strand': $i).
% 29.22/29.10  tff(decl_58729, type, 'Parental-Type': $i).
% 29.22/29.10  tff(decl_58730, type, 'Offspring with a phenotype that matches one of the parental phenotypes.': $i).
% 29.22/29.10  tff(decl_58731, type, 'parental type': $i).
% 29.22/29.10  tff(decl_58732, type, 'parental-type': $i).
% 29.22/29.10  tff(decl_58733, type, fn_parental_type_3: $i > $i).
% 29.22/29.10  tff(decl_58734, type, fn_parental_type_4: $i > $i).
% 29.22/29.10  tff(decl_58735, type, fn_parental_type_5: $i > $i).
% 29.22/29.10  tff(decl_58736, type, fn_parental_type_6: $i > $i).
% 29.22/29.10  tff(decl_58737, type, fn_parental_type_7: $i > $i).
% 29.22/29.10  tff(decl_58738, type, fn_parental_type_8: $i > $i).
% 29.22/29.10  tff(decl_58739, type, fn_parental_type_9: $i > $i).
% 29.22/29.10  tff(decl_58740, type, fn_parental_type_10: $i > $i).
% 29.22/29.10  tff(decl_58741, type, fn_parental_type_11: $i > $i).
% 29.22/29.10  tff(decl_58742, type, fn_parental_type_12: $i > $i).
% 29.22/29.10  tff(decl_58743, type, fn_parental_type_13: $i > $i).
% 29.22/29.10  tff(decl_58744, type, fn_reproduction_1: $i > $i).
% 29.22/29.10  tff(decl_58745, type, 'Parietal-Cell': $i).
% 29.22/29.10  tff(decl_58746, type, 'Secretory cell found in the lining of the stomach which produces and secretes hydrochloric acid into the lumen of the stomach.': $i).
% 29.22/29.10  tff(decl_58747, type, 'parietal cell': $i).
% 29.22/29.10  tff(decl_58748, type, 'parietal-cell': $i).
% 29.22/29.10  tff(decl_58749, type, fn_parietal_cell_1: $i > $i).
% 29.22/29.10  tff(decl_58750, type, fn_parietal_cell_2: $i > $i).
% 29.22/29.10  tff(decl_58751, type, fn_parietal_cell_3: $i > $i).
% 29.22/29.10  tff(decl_58752, type, fn_parietal_cell_4: $i > $i).
% 29.22/29.10  tff(decl_58753, type, fn_parietal_cell_5: $i > $i).
% 29.22/29.10  tff(decl_58754, type, fn_parietal_cell_6: $i > $i).
% 29.22/29.10  tff(decl_58755, type, fn_parietal_cell_7: $i > $i).
% 29.22/29.10  tff(decl_58756, type, fn_parietal_cell_8: $i > $i).
% 29.22/29.10  tff(decl_58757, type, fn_parietal_cell_9: $i > $i).
% 29.22/29.10  tff(decl_58758, type, fn_parietal_cell_10: $i > $i).
% 29.22/29.10  tff(decl_58759, type, fn_parietal_cell_11: $i > $i).
% 29.22/29.10  tff(decl_58760, type, fn_parietal_cell_12: $i > $i).
% 29.22/29.10  tff(decl_58761, type, fn_parietal_cell_15: $i > $i).
% 29.22/29.10  tff(decl_58762, type, fn_parietal_cell_16: $i > $i).
% 29.22/29.10  tff(decl_58763, type, fn_parietal_cell_17: $i > $i).
% 29.22/29.10  tff(decl_58764, type, fn_parietal_cell_18: $i > $i).
% 29.22/29.10  tff(decl_58765, type, fn_parietal_cell_19: $i > $i).
% 29.22/29.10  tff(decl_58766, type, fn_parietal_cell_20: $i > $i).
% 29.22/29.10  tff(decl_58767, type, fn_parietal_cell_21: $i > $i).
% 29.22/29.10  tff(decl_58768, type, fn_parietal_cell_22: $i > $i).
% 29.22/29.10  tff(decl_58769, type, fn_parietal_cell_23: $i > $i).
% 29.22/29.10  tff(decl_58770, type, fn_parietal_cell_24: $i > $i).
% 29.22/29.10  tff(decl_58771, type, fn_parietal_cell_25: $i > $i).
% 29.22/29.10  tff(decl_58772, type, fn_parietal_cell_26: $i > $i).
% 29.22/29.10  tff(decl_58773, type, fn_parietal_cell_27: $i > $i).
% 29.22/29.10  tff(decl_58774, type, fn_parietal_cell_28: $i > $i).
% 29.22/29.10  tff(decl_58775, type, fn_parietal_cell_29: $i > $i).
% 29.22/29.10  tff(decl_58776, type, fn_parietal_cell_30: $i > $i).
% 29.22/29.10  tff(decl_58777, type, fn_parietal_cell_31: $i > $i).
% 29.22/29.10  tff(decl_58778, type, fn_parietal_cell_32: $i > $i).
% 29.22/29.10  tff(decl_58779, type, fn_parietal_cell_33: $i > $i).
% 29.22/29.10  tff(decl_58780, type, fn_parietal_cell_34: $i > $i).
% 29.22/29.10  tff(decl_58781, type, fn_parietal_cell_35: $i > $i).
% 29.22/29.10  tff(decl_58782, type, fn_parietal_cell_36: $i > $i).
% 29.22/29.10  tff(decl_58783, type, fn_parietal_cell_37: $i > $i).
% 29.22/29.10  tff(decl_58784, type, fn_parietal_cell_38: $i > $i).
% 29.22/29.10  tff(decl_58785, type, fn_parietal_cell_39: $i > $i).
% 29.22/29.10  tff(decl_58786, type, fn_parietal_cell_40: $i > $i).
% 29.22/29.10  tff(decl_58787, type, fn_parietal_cell_41: $i > $i).
% 29.22/29.10  tff(decl_58788, type, fn_parietal_cell_42: $i > $i).
% 29.22/29.10  tff(decl_58789, type, fn_parietal_cell_43: $i > $i).
% 29.22/29.10  tff(decl_58790, type, fn_parietal_cell_44: $i > $i).
% 29.22/29.10  tff(decl_58791, type, fn_parietal_cell_45: $i > $i).
% 29.22/29.10  tff(decl_58792, type, fn_parietal_cell_46: $i > $i).
% 29.22/29.10  tff(decl_58793, type, fn_parietal_cell_47: $i > $i).
% 29.22/29.10  tff(decl_58794, type, fn_parietal_cell_48: $i > $i).
% 29.22/29.10  tff(decl_58795, type, fn_parietal_cell_49: $i > $i).
% 29.22/29.10  tff(decl_58796, type, fn_parietal_cell_50: $i > $i).
% 29.22/29.10  tff(decl_58797, type, fn_parietal_cell_51: $i > $i).
% 29.22/29.10  tff(decl_58798, type, fn_parietal_cell_52: $i > $i).
% 29.22/29.10  tff(decl_58799, type, fn_parietal_cell_53: $i > $i).
% 29.22/29.10  tff(decl_58800, type, fn_parietal_cell_54: $i > $i).
% 29.22/29.10  tff(decl_58801, type, fn_parietal_cell_55: $i > $i).
% 29.22/29.10  tff(decl_58802, type, fn_parietal_cell_56: $i > $i).
% 29.22/29.10  tff(decl_58803, type, fn_parietal_cell_57: $i > $i).
% 29.22/29.10  tff(decl_58804, type, fn_parietal_cell_58: $i > $i).
% 29.22/29.10  tff(decl_58805, type, fn_parietal_cell_59: $i > $i).
% 29.22/29.10  tff(decl_58806, type, fn_parietal_cell_60: $i > $i).
% 29.22/29.10  tff(decl_58807, type, fn_parietal_cell_14: $i > $i).
% 29.22/29.10  tff(decl_58808, type, fn_parietal_cell_13: $i > $i).
% 29.22/29.10  tff(decl_58809, type, fn_secretory_cell_56: $i > $i).
% 29.22/29.10  tff(decl_58810, type, parietal_lobe_1: $i > $o).
% 29.22/29.10  tff(decl_58811, type, 'Parietal-Lobe': $i).
% 29.22/29.10  tff(decl_58812, type, 'Region of cerebral cortex responsible for processing sensory information and touch.': $i).
% 29.22/29.10  tff(decl_58813, type, 'parietal lobe': $i).
% 29.22/29.10  tff(decl_58814, type, 'parietal-lobe': $i).
% 29.22/29.10  tff(decl_58815, type, 'ParkingLot': $i).
% 29.22/29.10  tff(decl_58816, type, 'parking lot': $i).
% 29.22/29.10  tff(decl_58817, type, parking_lot: $i).
% 29.22/29.10  tff(decl_58818, type, lot: $i).
% 29.22/29.10  tff(decl_58819, type, 'car park': $i).
% 29.22/29.10  tff(decl_58820, type, car_park: $i).
% 29.22/29.10  tff(decl_58821, type, park: $i).
% 29.22/29.10  tff(decl_58822, type, 'parking area': $i).
% 29.22/29.10  tff(decl_58823, type, parking_area: $i).
% 29.22/29.10  tff(decl_58824, type, parkinglot: $i).
% 29.22/29.10  tff(decl_58825, type, 'Parkinsons-Disease': $i).
% 29.22/29.10  tff(decl_58826, type, 'A progressive disorder of the brain characterized by tremors and difficulty with walking, movement, and coordination.': $i).
% 29.22/29.10  tff(decl_58827, type, 'parkinsons disease': $i).
% 29.22/29.10  tff(decl_58828, type, 'parkinsons-disease': $i).
% 29.22/29.10  tff(decl_58829, type, parkinsons_disease_process_1: $i > $o).
% 29.22/29.10  tff(decl_58830, type, 'Parkinsons-Disease-Process': $i).
% 29.22/29.10  tff(decl_58831, type, 'Process related to the progression of Parkinson\\s disease.': $i).
% 29.22/29.10  tff(decl_58832, type, 'parkinsons disease process': $i).
% 29.22/29.10  tff(decl_58833, type, 'parkinsons-disease-process': $i).
% 29.22/29.10  tff(decl_58834, type, fn_parkinsons_disease_process_1: $i > $i).
% 29.22/29.10  tff(decl_58835, type, 'Parthenogenesis': $i).
% 29.22/29.10  tff(decl_58836, type, 'A type of asexual reproduction in which females produce unfertilized eggs that develop into female offspring.': $i).
% 29.22/29.10  tff(decl_58837, type, 'undergo parthenogenesis': $i).
% 29.22/29.10  tff(decl_58838, type, parthenogenesis: $i).
% 29.22/29.10  tff(decl_58839, type, fn_parthenogenesis_1: $i > $i).
% 29.22/29.10  tff(decl_58840, type, unfertilized_egg_1: $i > $o).
% 29.22/29.10  tff(decl_58841, type, 'Partial-Closing-Of-Stoma': $i).
% 29.22/29.10  tff(decl_58842, type, 'The incomplete closure of pores in the epidermis of the leaves and stems of plants determined by conditions such as CO2 concentration in the leaves, drought, and high temperature.': $i).
% 29.22/29.10  tff(decl_58843, type, 'close partially': $i).
% 29.22/29.10  tff(decl_58844, type, 'partial closing of stoma': $i).
% 29.22/29.10  tff(decl_58845, type, 'partial-closing-of-stoma': $i).
% 29.22/29.10  tff(decl_58846, type, fn_partial_closing_of_stoma_2: $i > $i).
% 29.22/29.10  tff(decl_58847, type, fn_partial_closing_of_stoma_3: $i > $i).
% 29.22/29.10  tff(decl_58848, type, fn_partial_closing_of_stoma_4: $i > $i).
% 29.22/29.10  tff(decl_58849, type, fn_partial_closing_of_stoma_10: $i > $i).
% 29.22/29.10  tff(decl_58850, type, fn_partial_closing_of_stoma_11: $i > $i).
% 29.22/29.10  tff(decl_58851, type, fn_partial_closing_of_stoma_12: $i > $i).
% 29.22/29.10  tff(decl_58852, type, fn_partial_closing_of_stoma_13: $i > $i).
% 29.22/29.10  tff(decl_58853, type, fn_partial_closing_of_stoma_14: $i > $i).
% 29.22/29.10  tff(decl_58854, type, fn_partial_closing_of_stoma_15: $i > $i).
% 29.22/29.10  tff(decl_58855, type, fn_partial_closing_of_stoma_16: $i > $i).
% 29.22/29.10  tff(decl_58856, type, fn_partial_closing_of_stoma_17: $i > $i).
% 29.22/29.10  tff(decl_58857, type, fn_partial_closing_of_stoma_18: $i > $i).
% 29.22/29.10  tff(decl_58858, type, fn_partial_closing_of_stoma_19: $i > $i).
% 29.22/29.10  tff(decl_58859, type, fn_partial_closing_of_stoma_20: $i > $i).
% 29.22/29.10  tff(decl_58860, type, fn_partial_closing_of_stoma_21: $i > $i).
% 29.22/29.10  tff(decl_58861, type, fn_partial_closing_of_stoma_22: $i > $i).
% 29.22/29.10  tff(decl_58862, type, fn_partial_closing_of_stoma_23: $i > $i).
% 29.22/29.10  tff(decl_58863, type, fn_partial_closing_of_stoma_24: $i > $i).
% 29.22/29.10  tff(decl_58864, type, fn_partial_closing_of_stoma_25: $i > $i).
% 29.22/29.10  tff(decl_58865, type, fn_partial_closing_of_stoma_26: $i > $i).
% 29.22/29.10  tff(decl_58866, type, fn_partial_closing_of_stoma_27: $i > $i).
% 29.22/29.10  tff(decl_58867, type, fn_partial_closing_of_stoma_28: $i > $i).
% 29.22/29.10  tff(decl_58868, type, fn_partial_closing_of_stoma_8: $i > $i).
% 29.22/29.10  tff(decl_58869, type, fn_partial_closing_of_stoma_7: $i > $i).
% 29.22/29.10  tff(decl_58870, type, 'Participant': $i).
% 29.22/29.10  tff(decl_58871, type, participant_relation_1: $i > $o).
% 29.22/29.10  tff(decl_58872, type, 'Participant-Relation': $i).
% 29.22/29.10  tff(decl_58873, type, 'A participant relation is a relation between an entity and an event, in which the entity is directly involved in the event. If a relation is a Participant-Relation, then its inverse is also an instance of Participant-Relation. The one exception is in-event, which relates an event to a role. In this case, the role player is understood as being directly involved in the event. There may or may not be another participant relation connecting the role player to the event': $i).
% 29.22/29.10  tff(decl_58874, type, 'relation of participant': $i).
% 29.22/29.10  tff(decl_58875, type, 'participant relation': $i).
% 29.22/29.10  tff(decl_58876, type, 'participant-relation': $i).
% 29.22/29.10  tff(decl_58877, type, particle_1: $i > $o).
% 29.22/29.10  tff(decl_58878, type, 'Particle': $i).
% 29.22/29.10  tff(decl_58879, type, 'In the physical sciences, a particle is a small localized object to which can be ascribed several physical properties such as volume or mass.': $i).
% 29.22/29.10  tff(decl_58880, type, particle: $i).
% 29.22/29.10  tff(decl_58881, type, particle_in_motion_1: $i > $o).
% 29.22/29.10  tff(decl_58882, type, 'Particle-In-Motion': $i).
% 29.22/29.10  tff(decl_58883, type, 'Molecules have intrinsic kinetic energy called thermal motion.': $i).
% 29.22/29.10  tff(decl_58884, type, 'molecule in motion': $i).
% 29.22/29.10  tff(decl_58885, type, 'particle in motion': $i).
% 29.22/29.10  tff(decl_58886, type, 'particle-in-motion': $i).
% 29.22/29.10  tff(decl_58887, type, fn_particle_in_motion_1: $i > $i).
% 29.22/29.10  tff(decl_58888, type, fn_particle_in_motion_2: $i > $i).
% 29.22/29.10  tff(decl_58889, type, partition_1: $i > $o).
% 29.22/29.10  tff(decl_58890, type, 'Partition': $i).
% 29.22/29.10  tff(decl_58891, type, partition: $i).
% 29.22/29.10  tff(decl_58892, type, 'Passive-Transport': $i).
% 29.22/29.10  tff(decl_58893, type, 'Passive transport means moving biochemicals and other atomic or molecular substances across membranes.': $i).
% 29.22/29.10  tff(decl_58894, type, 'diffusion of molecule across membrane': $i).
% 29.22/29.10  tff(decl_58895, type, 'diffusion-of-molecule-across-membrane': $i).
% 29.22/29.10  tff(decl_58896, type, 'transport of passive': $i).
% 29.22/29.10  tff(decl_58897, type, 'passive transport': $i).
% 29.22/29.10  tff(decl_58898, type, 'passive-transport': $i).
% 29.22/29.10  tff(decl_58899, type, fn_passive_transport_4: $i > $i).
% 29.22/29.10  tff(decl_58900, type, fn_spontaneous_change_5: $i > $i).
% 29.22/29.10  tff(decl_58901, type, fn_spontaneous_change_10: $i > $i).
% 29.22/29.10  tff(decl_58902, type, fn_spontaneous_change_6: $i > $i).
% 29.22/29.10  tff(decl_58903, type, fn_spontaneous_change_4: $i > $i).
% 29.22/29.10  tff(decl_58904, type, 'Passive-Transport-Of-Solute': $i).
% 29.22/29.10  tff(decl_58905, type, 'Transport of a dissolved solute without the input of chemical energy.': $i).
% 29.22/29.10  tff(decl_58906, type, 'passive transport of solute': $i).
% 29.22/29.10  tff(decl_58907, type, 'passive-transport-of-solute': $i).
% 29.22/29.10  tff(decl_58908, type, 'Passive-Transport-Of-Water': $i).
% 29.22/29.10  tff(decl_58909, type, 'Transport of water without the input of chemical energy; for example, osmosis.': $i).
% 29.22/29.10  tff(decl_58910, type, 'passive transport of water': $i).
% 29.22/29.10  tff(decl_58911, type, 'passive-transport-of-water': $i).
% 29.22/29.10  tff(decl_58912, type, 'Paternal-Chromosome': $i).
% 29.22/29.10  tff(decl_58913, type, 'One of a pair of homologous chromosomes originating from the male gamete.': $i).
% 29.22/29.10  tff(decl_58914, type, 'paternal chromosome': $i).
% 29.22/29.10  tff(decl_58915, type, 'paternal-chromosome': $i).
% 29.22/29.10  tff(decl_58916, type, 'Paternity-Testing': $i).
% 29.22/29.10  tff(decl_58917, type, 'A test to determine the male parent of an offspring.': $i).
% 29.22/29.10  tff(decl_58918, type, 'parental testing': $i).
% 29.22/29.10  tff(decl_58919, type, 'parental-testing': $i).
% 29.22/29.10  tff(decl_58920, type, 'testing of paternity': $i).
% 29.22/29.10  tff(decl_58921, type, 'paternity testing': $i).
% 29.22/29.10  tff(decl_58922, type, 'paternity-testing': $i).
% 29.22/29.10  tff(decl_58923, type, 'Pathogen': $i).
% 29.22/29.10  tff(decl_58924, type, 'An organism or virus that causes disease.': $i).
% 29.22/29.10  tff(decl_58925, type, patient_1: $i > $o).
% 29.22/29.10  tff(decl_58926, type, 'Patient': $i).
% 29.22/29.10  tff(decl_58927, type, 'A patient is any recipient of medical attention, care, or treatment.': $i).
% 29.22/29.10  tff(decl_58928, type, patient: $i).
% 29.22/29.10  tff(decl_58929, type, 'Pattern-Formation': $i).
% 29.22/29.10  tff(decl_58930, type, 'Pattern formation is the development of a spatial organization in which the tissues and organs of an organism end up in their characteristic spatial organization.': $i).
% 29.22/29.10  tff(decl_58931, type, 'formation of pattern': $i).
% 29.22/29.10  tff(decl_58932, type, 'pattern formation': $i).
% 29.22/29.10  tff(decl_58933, type, 'pattern-formation': $i).
% 29.22/29.10  tff(decl_58934, type, fn_pattern_formation_1: $i > $i).
% 29.22/29.10  tff(decl_58935, type, fn_pattern_formation_2: $i > $i).
% 29.22/29.10  tff(decl_58936, type, fn_pattern_formation_3: $i > $i).
% 29.22/29.10  tff(decl_58937, type, fn_pattern_formation_4: $i > $i).
% 29.22/29.10  tff(decl_58938, type, fn_pattern_formation_5: $i > $i).
% 29.22/29.10  tff(decl_58939, type, fn_pattern_formation_7: $i > $i).
% 29.22/29.10  tff(decl_58940, type, fn_pattern_formation_8: $i > $i).
% 29.22/29.10  tff(decl_58941, type, paw_development_1: $i > $o).
% 29.22/29.10  tff(decl_58942, type, 'Paw-Development': $i).
% 29.22/29.10  tff(decl_58943, type, 'The processes which direct the formation of the paws during the embryonic development of a mammal.': $i).
% 29.22/29.10  tff(decl_58944, type, 'development of paw': $i).
% 29.22/29.10  tff(decl_58945, type, 'paw development': $i).
% 29.22/29.10  tff(decl_58946, type, 'paw-development': $i).
% 29.22/29.10  tff(decl_58947, type, fn_paw_development_1: $i > $i).
% 29.22/29.10  tff(decl_58948, type, fn_paw_development_3: $i > $i).
% 29.22/29.10  tff(decl_58949, type, fn_paw_development_4: $i > $i).
% 29.22/29.10  tff(decl_58950, type, fn_paw_development_5: $i > $i).
% 29.22/29.10  tff(decl_58951, type, fn_paw_development_6: $i > $i).
% 29.22/29.10  tff(decl_58952, type, fn_paw_development_7: $i > $i).
% 29.22/29.10  tff(decl_58953, type, fn_paw_development_8: $i > $i).
% 29.22/29.10  tff(decl_58954, type, fn_paw_development_9: $i > $i).
% 29.22/29.10  tff(decl_58955, type, fn_paw_development_10: $i > $i).
% 29.22/29.10  tff(decl_58956, type, fn_paw_development_11: $i > $i).
% 29.22/29.10  tff(decl_58957, type, fn_paw_development_12: $i > $i).
% 29.22/29.10  tff(decl_58958, type, fn_paw_development_13: $i > $i).
% 29.22/29.10  tff(decl_58959, type, fn_paw_development_14: $i > $i).
% 29.22/29.10  tff(decl_58960, type, fn_paw_development_15: $i > $i).
% 29.22/29.10  tff(decl_58961, type, fn_paw_development_16: $i > $i).
% 29.22/29.10  tff(decl_58962, type, fn_paw_development_17: $i > $i).
% 29.22/29.10  tff(decl_58963, type, fn_paw_development_18: $i > $i).
% 29.22/29.10  tff(decl_58964, type, fn_paw_development_19: $i > $i).
% 29.22/29.10  tff(decl_58965, type, fn_paw_development_20: $i > $i).
% 29.22/29.10  tff(decl_58966, type, fn_paw_development_21: $i > $i).
% 29.22/29.10  tff(decl_58967, type, fn_paw_development_22: $i > $i).
% 29.22/29.10  tff(decl_58968, type, fn_paw_development_23: $i > $i).
% 29.22/29.10  tff(decl_58969, type, fn_paw_development_24: $i > $i).
% 29.22/29.10  tff(decl_58970, type, fn_paw_development_25: $i > $i).
% 29.22/29.10  tff(decl_58971, type, fn_paw_development_26: $i > $i).
% 29.22/29.10  tff(decl_58972, type, fn_paw_development_27: $i > $i).
% 29.22/29.10  tff(decl_58973, type, fn_paw_development_28: $i > $i).
% 29.22/29.10  tff(decl_58974, type, fn_paw_development_29: $i > $i).
% 29.22/29.10  tff(decl_58975, type, fn_paw_development_30: $i > $i).
% 29.22/29.10  tff(decl_58976, type, fn_paw_development_31: $i > $i).
% 29.22/29.10  tff(decl_58977, type, fn_paw_development_32: $i > $i).
% 29.22/29.10  tff(decl_58978, type, fn_paw_development_33: $i > $i).
% 29.22/29.10  tff(decl_58979, type, fn_paw_development_34: $i > $i).
% 29.22/29.10  tff(decl_58980, type, fn_paw_development_35: $i > $i).
% 29.22/29.10  tff(decl_58981, type, fn_paw_development_36: $i > $i).
% 29.22/29.10  tff(decl_58982, type, 'Pb-Plus-2': $i).
% 29.22/29.10  tff(decl_58983, type, 'An Ion of Lead with 2 positive charge.': $i).
% 29.22/29.10  tff(decl_58984, type, 'pb plus 2': $i).
% 29.22/29.10  tff(decl_58985, type, 'pb-plus-2': $i).
% 29.22/29.10  tff(decl_58986, type, fn_pb_plus_2_2: $i > $i).
% 29.22/29.10  tff(decl_58987, type, fn_pb_plus_2_3: $i > $i).
% 29.22/29.10  tff(decl_58988, type, fn_pb_plus_2_4: $i > $i).
% 29.22/29.10  tff(decl_58989, type, 'PDGF-Receptor': $i).
% 29.22/29.10  tff(decl_58990, type, 'Receptor found on the surface of cells which receives the signal carried by platelet derived growth factor (PDGF).': $i).
% 29.22/29.10  tff(decl_58991, type, 'pdgf receptor': $i).
% 29.22/29.10  tff(decl_58992, type, 'pdgf-receptor': $i).
% 29.22/29.10  tff(decl_58993, type, 'Pea': $i).
% 29.22/29.10  tff(decl_58994, type, 'The plant used by Gregor Mendel to study inheritance of traits.': $i).
% 29.22/29.10  tff(decl_58995, type, pea: $i).
% 29.22/29.10  tff(decl_58996, type, 'Peanut-Butter': $i).
% 29.22/29.10  tff(decl_58997, type, 'Peanut butter is a food paste made primarily from ground dry roasted peanuts, popular in North America, the Netherlands and the United Kingdom.': $i).
% 29.22/29.10  tff(decl_58998, type, 'butter of peanut': $i).
% 29.22/29.10  tff(decl_58999, type, 'peanut butter': $i).
% 29.22/29.10  tff(decl_59000, type, 'peanut-butter': $i).
% 29.22/29.10  tff(decl_59001, type, 'Peat': $i).
% 29.22/29.10  tff(decl_59002, type, 'An accumulation of partially decayed vegetation, the major component of which is wetland moss from the genus Sphagnum.': $i).
% 29.22/29.10  tff(decl_59003, type, turf: $i).
% 29.22/29.10  tff(decl_59004, type, peat: $i).
% 29.22/29.10  tff(decl_59005, type, pectin_1: $i > $o).
% 29.22/29.10  tff(decl_59006, type, 'Pectin': $i).
% 29.22/29.10  tff(decl_59007, type, 'In plant cells, pectin consists of a complex set of polysaccharides that are present in most primary cell walls and particularly abundant in the non-woody parts of terrestrial plants. Pectin is present not only throughout primary cell walls but also in the middle lamella between plant cells where it helps to bind cells together.': $i).
% 29.22/29.10  tff(decl_59008, type, 'gelling agent': $i).
% 29.22/29.10  tff(decl_59009, type, 'gelling-agent': $i).
% 29.22/29.10  tff(decl_59010, type, pectin: $i).
% 29.22/29.10  tff(decl_59011, type, fn_pectin_4: $i > $i).
% 29.22/29.10  tff(decl_59012, type, fn_pectin_5: $i > $i).
% 29.22/29.10  tff(decl_59013, type, fn_pectin_6: $i > $i).
% 29.22/29.10  tff(decl_59014, type, fn_pectin_7: $i > $i).
% 29.22/29.10  tff(decl_59015, type, fn_pectin_8: $i > $i).
% 29.22/29.10  tff(decl_59016, type, fn_pectin_11: $i > $i).
% 29.22/29.10  tff(decl_59017, type, fn_pectin_12: $i > $i).
% 29.22/29.10  tff(decl_59018, type, fn_pectin_13: $i > $i).
% 29.22/29.10  tff(decl_59019, type, fn_pectin_14: $i > $i).
% 29.22/29.10  tff(decl_59020, type, fn_pectin_15: $i > $i).
% 29.22/29.10  tff(decl_59021, type, fn_pectin_16: $i > $i).
% 29.22/29.10  tff(decl_59022, type, fn_pectin_17: $i > $i).
% 29.22/29.10  tff(decl_59023, type, fn_pectin_18: $i > $i).
% 29.22/29.10  tff(decl_59024, type, fn_pectin_19: $i > $i).
% 29.22/29.10  tff(decl_59025, type, fn_pectin_20: $i > $i).
% 29.22/29.10  tff(decl_59026, type, fn_pectin_21: $i > $i).
% 29.22/29.10  tff(decl_59027, type, fn_pectin_22: $i > $i).
% 29.22/29.10  tff(decl_59028, type, fn_pectin_23: $i > $i).
% 29.22/29.10  tff(decl_59029, type, fn_pectin_24: $i > $i).
% 29.22/29.10  tff(decl_59030, type, fn_pectin_25: $i > $i).
% 29.22/29.10  tff(decl_59031, type, fn_pectin_26: $i > $i).
% 29.22/29.10  tff(decl_59032, type, fn_pectin_27: $i > $i).
% 29.22/29.10  tff(decl_59033, type, fn_pectin_28: $i > $i).
% 29.22/29.10  tff(decl_59034, type, fn_pectin_29: $i > $i).
% 29.22/29.10  tff(decl_59035, type, fn_pectin_30: $i > $i).
% 29.22/29.10  tff(decl_59036, type, fn_pectin_1: $i > $i).
% 29.22/29.10  tff(decl_59037, type, fn_pectin_10: $i > $i).
% 29.22/29.10  tff(decl_59038, type, fn_pectin_9: $i > $i).
% 29.22/29.10  tff(decl_59039, type, fn_pectin_3: $i > $i).
% 29.22/29.10  tff(decl_59040, type, fn_pectin_31: $i > $i).
% 29.22/29.10  tff(decl_59041, type, fn_pectin_2: $i > $i).
% 29.22/29.10  tff(decl_59042, type, fn_pectin_32: $i > $i).
% 29.22/29.10  tff(decl_59043, type, 'Pedigree': $i).
% 29.22/29.10  tff(decl_59044, type, 'A family tree diagram used to show the occurrence of inherited traits over multiple generations.': $i).
% 29.22/29.10  tff(decl_59045, type, pedigree: $i).
% 29.22/29.10  tff(decl_59046, type, fn_pedigree_1: $i > $i).
% 29.22/29.10  tff(decl_59047, type, fn_pedigree_2: $i > $i).
% 29.22/29.10  tff(decl_59048, type, fn_pedigree_3: $i > $i).
% 29.22/29.10  tff(decl_59049, type, fn_pedigree_4: $i > $i).
% 29.22/29.10  tff(decl_59050, type, fn_pedigree_5: $i > $i).
% 29.22/29.10  tff(decl_59051, type, fn_pedigree_6: $i > $i).
% 29.22/29.10  tff(decl_59052, type, 'Pelagic-Zone': $i).
% 29.22/29.10  tff(decl_59053, type, 'The open-water component of aquatic biomes.': $i).
% 29.22/29.10  tff(decl_59054, type, 'pelagic zone': $i).
% 29.22/29.10  tff(decl_59055, type, 'pelagic-zone': $i).
% 29.22/29.10  tff(decl_59056, type, fn_pelagic_zone_1: $i > $i).
% 29.22/29.10  tff(decl_59057, type, fn_pelagic_zone_2: $i > $i).
% 29.22/29.10  tff(decl_59058, type, 'Pellet': $i).
% 29.22/29.10  tff(decl_59059, type, 'Pellet is a solid material which settles at the bottom of a solution.': $i).
% 29.22/29.10  tff(decl_59060, type, precipitate: $i).
% 29.22/29.10  tff(decl_59061, type, pellet: $i).
% 29.22/29.10  tff(decl_59062, type, 'Penetrate': $i).
% 29.22/29.10  tff(decl_59063, type, fn_penetrate_1: $i > $i).
% 29.22/29.10  tff(decl_59064, type, fn_penetrate_2: $i > $i).
% 29.22/29.10  tff(decl_59065, type, fn_penetrate_3: $i > $i).
% 29.22/29.10  tff(decl_59066, type, 'Penicillin': $i).
% 29.22/29.10  tff(decl_59067, type, 'The first antibiotic discovered. It is produced by the ascomycete mold Penicillium, a fungus.': $i).
% 29.22/29.10  tff(decl_59068, type, penicillin: $i).
% 29.22/29.10  tff(decl_59069, type, fn_penicillin_1: $i > $i).
% 29.22/29.10  tff(decl_59070, type, fn_penicillin_2: $i > $i).
% 29.22/29.10  tff(decl_59071, type, fn_penicillin_3: $i > $i).
% 29.22/29.10  tff(decl_59072, type, fn_penicillin_4: $i > $i).
% 29.22/29.10  tff(decl_59073, type, fn_penicillin_5: $i > $i).
% 29.22/29.10  tff(decl_59074, type, fn_penicillin_6: $i > $i).
% 29.22/29.10  tff(decl_59075, type, fn_penicillin_7: $i > $i).
% 29.22/29.10  tff(decl_59076, type, fn_penicillin_8: $i > $i).
% 29.22/29.10  tff(decl_59077, type, fn_penicillin_9: $i > $i).
% 29.22/29.10  tff(decl_59078, type, fn_penicillin_10: $i > $i).
% 29.22/29.10  tff(decl_59079, type, fn_penicillin_11: $i > $i).
% 29.22/29.10  tff(decl_59080, type, 'Penicillium': $i).
% 29.22/29.10  tff(decl_59081, type, 'A genus of ascomycete fungi, some members of which produce the antibiotic penicillin.': $i).
% 29.22/29.10  tff(decl_59082, type, penicillium: $i).
% 29.22/29.10  tff(decl_59083, type, penis_1: $i > $o).
% 29.22/29.10  tff(decl_59084, type, 'Penis': $i).
% 29.22/29.10  tff(decl_59085, type, 'The male copulatory organ in animals.': $i).
% 29.22/29.10  tff(decl_59086, type, penis: $i).
% 29.22/29.10  tff(decl_59087, type, 'Pentose': $i).
% 29.22/29.10  tff(decl_59088, type, 'A pentose is a monosaccharide with five carbon atoms. Pentoses are organized into two groups. Aldopentoses have an aldehyde functional group at position. Ketopentoses have a ketone functional group in position 2 or 3.': $i).
% 29.22/29.10  tff(decl_59089, type, 'pentose sugar': $i).
% 29.22/29.10  tff(decl_59090, type, 'pentose-sugar': $i).
% 29.22/29.10  tff(decl_59091, type, 'five carbon sugar': $i).
% 29.22/29.10  tff(decl_59092, type, 'five-carbon-sugar': $i).
% 29.22/29.10  tff(decl_59093, type, pentose: $i).
% 29.22/29.10  tff(decl_59094, type, fn_pentose_8: $i > $i).
% 29.22/29.10  tff(decl_59095, type, fn_pentose_13: $i > $i).
% 29.22/29.10  tff(decl_59096, type, fn_pentose_17: $i > $i).
% 29.22/29.10  tff(decl_59097, type, fn_pentose_18: $i > $i).
% 29.22/29.10  tff(decl_59098, type, fn_pentose_3: $i > $i).
% 29.22/29.10  tff(decl_59099, type, fn_pentose_2: $i > $i).
% 29.22/29.10  tff(decl_59100, type, fn_pentose_22: $i > $i).
% 29.22/29.10  tff(decl_59101, type, fn_pentose_23: $i > $i).
% 29.22/29.10  tff(decl_59102, type, fn_pentose_1: $i > $i).
% 29.22/29.10  tff(decl_59103, type, 'PEP-Carboxylase': $i).
% 29.22/29.10  tff(decl_59104, type, 'In C4 photosynthesis, PEP-Carboxylase is the first enzyme in the carbon-fixation pathway that occurs in mesophyll cells. PEP-Carboxylase adds CO2 to phosphoenolpyruvate (PEP) forming oxaloacetate.': $i).
% 29.22/29.10  tff(decl_59105, type, 'phosphoenolpyruvate carboxylase': $i).
% 29.22/29.10  tff(decl_59106, type, 'phosphoenolpyruvate-carboxylase': $i).
% 29.22/29.10  tff(decl_59107, type, pepcase: $i).
% 29.22/29.10  tff(decl_59108, type, pepc: $i).
% 29.22/29.10  tff(decl_59109, type, 'pep carboxylase': $i).
% 29.22/29.10  tff(decl_59110, type, 'pep-carboxylase': $i).
% 29.22/29.10  tff(decl_59111, type, fn_pep_carboxylase_3: $i > $i).
% 29.22/29.10  tff(decl_59112, type, fn_pep_carboxylase_4: $i > $i).
% 29.22/29.10  tff(decl_59113, type, fn_pep_carboxylase_5: $i > $i).
% 29.22/29.10  tff(decl_59114, type, fn_pep_carboxylase_7: $i > $i).
% 29.22/29.10  tff(decl_59115, type, fn_pep_carboxylase_11: $i > $i).
% 29.22/29.10  tff(decl_59116, type, fn_pep_carboxylase_12: $i > $i).
% 29.22/29.10  tff(decl_59117, type, fn_pep_carboxylase_13: $i > $i).
% 29.22/29.10  tff(decl_59118, type, fn_pep_carboxylase_14: $i > $i).
% 29.22/29.10  tff(decl_59119, type, fn_pep_carboxylase_15: $i > $i).
% 29.22/29.10  tff(decl_59120, type, fn_pep_carboxylase_16: $i > $i).
% 29.22/29.10  tff(decl_59121, type, fn_pep_carboxylase_17: $i > $i).
% 29.22/29.10  tff(decl_59122, type, fn_pep_carboxylase_18: $i > $i).
% 29.22/29.10  tff(decl_59123, type, fn_pep_carboxylase_19: $i > $i).
% 29.22/29.10  tff(decl_59124, type, fn_pep_carboxylase_20: $i > $i).
% 29.22/29.10  tff(decl_59125, type, fn_pep_carboxylase_21: $i > $i).
% 29.22/29.10  tff(decl_59126, type, fn_pep_carboxylase_22: $i > $i).
% 29.22/29.10  tff(decl_59127, type, fn_pep_carboxylase_27: $i > $i).
% 29.22/29.10  tff(decl_59128, type, fn_pep_carboxylase_28: $i > $i).
% 29.22/29.10  tff(decl_59129, type, fn_pep_carboxylase_29: $i > $i).
% 29.22/29.10  tff(decl_59130, type, fn_pep_carboxylase_30: $i > $i).
% 29.22/29.10  tff(decl_59131, type, fn_pep_carboxylase_31: $i > $i).
% 29.22/29.10  tff(decl_59132, type, fn_pep_carboxylase_32: $i > $i).
% 29.22/29.10  tff(decl_59133, type, fn_pep_carboxylase_33: $i > $i).
% 29.22/29.10  tff(decl_59134, type, fn_pep_carboxylase_34: $i > $i).
% 29.22/29.10  tff(decl_59135, type, fn_pep_carboxylase_35: $i > $i).
% 29.22/29.10  tff(decl_59136, type, fn_pep_carboxylase_36: $i > $i).
% 29.22/29.10  tff(decl_59137, type, fn_pep_carboxylase_37: $i > $i).
% 29.22/29.10  tff(decl_59138, type, fn_pep_carboxylase_38: $i > $i).
% 29.22/29.10  tff(decl_59139, type, fn_pep_carboxylase_40: $i > $i).
% 29.22/29.10  tff(decl_59140, type, fn_pep_carboxylase_43: $i > $i).
% 29.22/29.10  tff(decl_59141, type, fn_pep_carboxylase_45: $i > $i).
% 29.22/29.10  tff(decl_59142, type, rubisco_1: $i > $o).
% 29.22/29.10  tff(decl_59143, type, fn_pep_carboxylase_46: $i > $i).
% 29.22/29.10  tff(decl_59144, type, fn_pep_carboxylase_49: $i > $i).
% 29.22/29.10  tff(decl_59145, type, fn_pep_carboxylase_50: $i > $i).
% 29.22/29.10  tff(decl_59146, type, fn_pep_carboxylase_51: $i > $i).
% 29.22/29.10  tff(decl_59147, type, fn_pep_carboxylase_52: $i > $i).
% 29.22/29.10  tff(decl_59148, type, fn_pep_carboxylase_54: $i > $i).
% 29.22/29.10  tff(decl_59149, type, fn_pep_carboxylase_55: $i > $i).
% 29.22/29.10  tff(decl_59150, type, fn_pep_carboxylase_56: $i > $i).
% 29.22/29.10  tff(decl_59151, type, fn_pep_carboxylase_57: $i > $i).
% 29.22/29.10  tff(decl_59152, type, fn_pep_carboxylase_58: $i > $i).
% 29.22/29.10  tff(decl_59153, type, fn_pep_carboxylase_59: $i > $i).
% 29.22/29.10  tff(decl_59154, type, fn_pep_carboxylase_60: $i > $i).
% 29.22/29.10  tff(decl_59155, type, fn_pep_carboxylase_61: $i > $i).
% 29.22/29.10  tff(decl_59156, type, fn_rubisco_18: $i > $i).
% 29.22/29.10  tff(decl_59157, type, fn_pep_carboxylase_24: $i > $i).
% 29.22/29.10  tff(decl_59158, type, fn_pep_carboxylase_25: $i > $i).
% 29.22/29.10  tff(decl_59159, type, fn_pep_carboxylase_26: $i > $i).
% 29.22/29.10  tff(decl_59160, type, fn_pep_carboxylase_23: $i > $i).
% 29.22/29.10  tff(decl_59161, type, fn_pep_carboxylase_9: $i > $i).
% 29.22/29.10  tff(decl_59162, type, fn_pep_carboxylase_10: $i > $i).
% 29.22/29.10  tff(decl_59163, type, 'Pepsin': $i).
% 29.22/29.10  tff(decl_59164, type, 'Pepsin is an enzyme whose precursor form (pepsinogen) is released by the chief cells in the stomach and that degrades food proteins into peptides. It was discovered in 1836 by Theodor Schwann who also coined its name from the Greek word pepsis, meaning digestion (peptein: to digest).': $i).
% 29.22/29.10  tff(decl_59165, type, pepsin: $i).
% 29.22/29.10  tff(decl_59166, type, fn_pepsin_1: $i > $i).
% 29.22/29.10  tff(decl_59167, type, fn_pepsin_2: $i > $i).
% 29.22/29.10  tff(decl_59168, type, fn_pepsin_3: $i > $i).
% 29.22/29.10  tff(decl_59169, type, fn_pepsin_5: $i > $i).
% 29.22/29.10  tff(decl_59170, type, fn_pepsin_6: $i > $i).
% 29.22/29.10  tff(decl_59171, type, fn_pepsin_7: $i > $i).
% 29.22/29.10  tff(decl_59172, type, fn_pepsin_8: $i > $i).
% 29.22/29.10  tff(decl_59173, type, fn_pepsin_9: $i > $i).
% 29.22/29.10  tff(decl_59174, type, fn_pepsin_10: $i > $i).
% 29.22/29.10  tff(decl_59175, type, fn_pepsin_11: $i > $i).
% 29.22/29.10  tff(decl_59176, type, fn_pepsin_12: $i > $i).
% 29.22/29.10  tff(decl_59177, type, fn_pepsin_13: $i > $i).
% 29.22/29.10  tff(decl_59178, type, fn_pepsin_14: $i > $i).
% 29.22/29.10  tff(decl_59179, type, fn_pepsin_15: $i > $i).
% 29.22/29.10  tff(decl_59180, type, fn_pepsin_16: $i > $i).
% 29.22/29.10  tff(decl_59181, type, fn_pepsin_17: $i > $i).
% 29.22/29.10  tff(decl_59182, type, fn_pepsin_18: $i > $i).
% 29.22/29.10  tff(decl_59183, type, fn_pepsin_19: $i > $i).
% 29.22/29.10  tff(decl_59184, type, fn_pepsin_20: $i > $i).
% 29.22/29.10  tff(decl_59185, type, fn_pepsin_21: $i > $i).
% 29.22/29.10  tff(decl_59186, type, fn_pepsin_22: $i > $i).
% 29.22/29.10  tff(decl_59187, type, fn_pepsin_23: $i > $i).
% 29.22/29.10  tff(decl_59188, type, fn_pepsin_24: $i > $i).
% 29.22/29.10  tff(decl_59189, type, fn_pepsin_25: $i > $i).
% 29.22/29.10  tff(decl_59190, type, fn_pepsin_26: $i > $i).
% 29.22/29.10  tff(decl_59191, type, 'Pepsinogen': $i).
% 29.22/29.10  tff(decl_59192, type, 'The precursor molecule to the digestive enzyme pepsin. Pepsinogen is secreted by chief cells in the stomach and in the acidic environment of the stomach unfolds and cleaves itself to generate pepsin.': $i).
% 29.22/29.10  tff(decl_59193, type, pepsinogen: $i).
% 29.22/29.10  tff(decl_59194, type, fn_pepsinogen_1: $i > $i).
% 29.22/29.10  tff(decl_59195, type, fn_pepsinogen_2: $i > $i).
% 29.22/29.10  tff(decl_59196, type, fn_pepsinogen_3: $i > $i).
% 29.22/29.10  tff(decl_59197, type, fn_pepsinogen_5: $i > $i).
% 29.22/29.10  tff(decl_59198, type, fn_pepsinogen_6: $i > $i).
% 29.22/29.10  tff(decl_59199, type, fn_pepsinogen_7: $i > $i).
% 29.22/29.10  tff(decl_59200, type, fn_pepsinogen_8: $i > $i).
% 29.22/29.10  tff(decl_59201, type, fn_pepsinogen_9: $i > $i).
% 29.22/29.10  tff(decl_59202, type, fn_pepsinogen_10: $i > $i).
% 29.22/29.10  tff(decl_59203, type, 'Peptide-Bond': $i).
% 29.22/29.10  tff(decl_59204, type, 'Peptide bond is the bond formed between two amino acids': $i).
% 29.22/29.10  tff(decl_59205, type, 'peptide bond': $i).
% 29.22/29.10  tff(decl_59206, type, 'peptide-bond': $i).
% 29.22/29.10  tff(decl_59207, type, 'bond of peptide': $i).
% 29.22/29.10  tff(decl_59208, type, fn_peptide_bond_2: $i > $i).
% 29.22/29.10  tff(decl_59209, type, fn_peptide_bond_19: $i > $i).
% 29.22/29.10  tff(decl_59210, type, fn_peptide_bond_20: $i > $i).
% 29.22/29.10  tff(decl_59211, type, fn_peptide_bond_25: $i > $i).
% 29.22/29.10  tff(decl_59212, type, fn_peptide_bond_26: $i > $i).
% 29.22/29.10  tff(decl_59213, type, fn_peptide_bond_36: $i > $i).
% 29.22/29.10  tff(decl_59214, type, fn_peptide_bond_38: $i > $i).
% 29.22/29.10  tff(decl_59215, type, fn_peptide_bond_54: $i > $i).
% 29.22/29.10  tff(decl_59216, type, fn_nitrogen_5: $i > $i).
% 29.22/29.10  tff(decl_59217, type, fn_peptide_bond_8: $i > $i).
% 29.22/29.10  tff(decl_59218, type, fn_peptide_bond_6: $i > $i).
% 29.22/29.10  tff(decl_59219, type, fn_peptide_bond_5: $i > $i).
% 29.22/29.10  tff(decl_59220, type, fn_peptide_bond_7: $i > $i).
% 29.22/29.10  tff(decl_59221, type, peptide_bond_formation_1: $i > $o).
% 29.22/29.10  tff(decl_59222, type, fn_peptide_bond_formation_19: $i > $i).
% 29.22/29.10  tff(decl_59223, type, 'Peptide-Bond-Formation': $i).
% 29.22/29.10  tff(decl_59224, type, 'Peptide bond formation is the process of the formation of peptide bond between two amino acids': $i).
% 29.22/29.10  tff(decl_59225, type, 'peptide bond formation': $i).
% 29.22/29.10  tff(decl_59226, type, 'peptide-bond-formation': $i).
% 29.22/29.10  tff(decl_59227, type, fn_peptide_bond_formation_2: $i > $i).
% 29.22/29.10  tff(decl_59228, type, fn_peptide_bond_formation_3: $i > $i).
% 29.22/29.10  tff(decl_59229, type, fn_peptide_bond_formation_4: $i > $i).
% 29.22/29.10  tff(decl_59230, type, fn_peptide_bond_formation_5: $i > $i).
% 29.22/29.10  tff(decl_59231, type, fn_peptide_bond_formation_6: $i > $i).
% 29.22/29.10  tff(decl_59232, type, fn_peptide_bond_formation_7: $i > $i).
% 29.22/29.10  tff(decl_59233, type, fn_peptide_bond_formation_8: $i > $i).
% 29.22/29.10  tff(decl_59234, type, fn_peptide_bond_formation_9: $i > $i).
% 29.22/29.10  tff(decl_59235, type, fn_peptide_bond_formation_10: $i > $i).
% 29.22/29.10  tff(decl_59236, type, fn_peptide_bond_formation_11: $i > $i).
% 29.22/29.10  tff(decl_59237, type, fn_peptide_bond_formation_12: $i > $i).
% 29.22/29.10  tff(decl_59238, type, fn_peptide_bond_formation_13: $i > $i).
% 29.22/29.10  tff(decl_59239, type, fn_peptide_bond_formation_14: $i > $i).
% 29.22/29.10  tff(decl_59240, type, fn_peptide_bond_formation_15: $i > $i).
% 29.22/29.10  tff(decl_59241, type, fn_peptide_bond_formation_16: $i > $i).
% 29.22/29.10  tff(decl_59242, type, fn_peptide_bond_formation_17: $i > $i).
% 29.22/29.10  tff(decl_59243, type, fn_peptide_bond_formation_18: $i > $i).
% 29.22/29.10  tff(decl_59244, type, fn_translation_elongation_10: $i > $i).
% 29.22/29.10  tff(decl_59245, type, fn_translation_elongation_15: $i > $i).
% 29.22/29.10  tff(decl_59246, type, fn_translation_elongation_11: $i > $i).
% 29.22/29.10  tff(decl_59247, type, fn_translation_elongation_21: $i > $i).
% 29.22/29.10  tff(decl_59248, type, fn_translation_elongation_9: $i > $i).
% 29.22/29.10  tff(decl_59249, type, fn_translation_elongation_2: $i > $i).
% 29.22/29.10  tff(decl_59250, type, peptide_bond_0: $i).
% 29.22/29.10  tff(decl_59251, type, 'Peptide-Hormone': $i).
% 29.22/29.10  tff(decl_59252, type, 'A polypeptide chain that functions as a hormone.': $i).
% 29.22/29.10  tff(decl_59253, type, 'protein hormone': $i).
% 29.22/29.10  tff(decl_59254, type, 'protein-hormone': $i).
% 29.22/29.10  tff(decl_59255, type, 'hormone of peptide': $i).
% 29.22/29.10  tff(decl_59256, type, 'peptide hormone': $i).
% 29.22/29.10  tff(decl_59257, type, 'peptide-hormone': $i).
% 29.22/29.10  tff(decl_59258, type, 'Peptidoglycan': $i).
% 29.22/29.10  tff(decl_59259, type, 'A polymer that provides structure to the cell wall of bacteria. It consists of chains of amino sugars cross-linked by short polypeptides.': $i).
% 29.22/29.10  tff(decl_59260, type, peptidoglycan: $i).
% 29.22/29.10  tff(decl_59261, type, fn_peptidoglycan_1: $i > $i).
% 29.22/29.10  tff(decl_59262, type, fn_peptidoglycan_2: $i > $i).
% 29.22/29.10  tff(decl_59263, type, fn_peptidoglycan_3: $i > $i).
% 29.22/29.10  tff(decl_59264, type, fn_peptidoglycan_4: $i > $i).
% 29.22/29.10  tff(decl_59265, type, fn_peptidoglycan_5: $i > $i).
% 29.22/29.10  tff(decl_59266, type, fn_peptidoglycan_6: $i > $i).
% 29.22/29.10  tff(decl_59267, type, fn_peptidoglycan_7: $i > $i).
% 29.22/29.10  tff(decl_59268, type, fn_peptidoglycan_8: $i > $i).
% 29.22/29.10  tff(decl_59269, type, fn_peptidoglycan_9: $i > $i).
% 29.22/29.10  tff(decl_59270, type, fn_peptidoglycan_10: $i > $i).
% 29.22/29.10  tff(decl_59271, type, fn_peptidoglycan_11: $i > $i).
% 29.22/29.10  tff(decl_59272, type, fn_peptidoglycan_12: $i > $i).
% 29.22/29.10  tff(decl_59273, type, fn_peptidoglycan_13: $i > $i).
% 29.22/29.10  tff(decl_59274, type, fn_peptidoglycan_14: $i > $i).
% 29.22/29.10  tff(decl_59275, type, fn_peptidoglycan_15: $i > $i).
% 29.22/29.10  tff(decl_59276, type, fn_peptidoglycan_16: $i > $i).
% 29.22/29.10  tff(decl_59277, type, fn_peptidoglycan_21: $i > $i).
% 29.22/29.10  tff(decl_59278, type, fn_peptidoglycan_22: $i > $i).
% 29.22/29.10  tff(decl_59279, type, fn_peptidoglycan_23: $i > $i).
% 29.22/29.10  tff(decl_59280, type, fn_peptidoglycan_17: $i > $i).
% 29.22/29.10  tff(decl_59281, type, fn_peptidoglycan_18: $i > $i).
% 29.22/29.10  tff(decl_59282, type, fn_peptidoglycan_19: $i > $i).
% 29.22/29.10  tff(decl_59283, type, fn_peptidoglycan_20: $i > $i).
% 29.22/29.10  tff(decl_59284, type, 'Peptidyl-tRNA': $i).
% 29.22/29.10  tff(decl_59285, type, 'The tRNA molecule that is in the P site and holds the growing polypeptide chain.': $i).
% 29.22/29.10  tff(decl_59286, type, 'peptidyl trna': $i).
% 29.22/29.10  tff(decl_59287, type, 'peptidyl-trna': $i).
% 29.22/29.10  tff(decl_59288, type, 'Perceive': $i).
% 29.22/29.10  tff(decl_59289, type, perceive: $i).
% 29.22/29.10  tff(decl_59290, type, comprehend: $i).
% 29.22/29.10  tff(decl_59291, type, 'Perception': $i).
% 29.22/29.10  tff(decl_59292, type, 'The organization and interpretation of sensory information to understand and represent the environment.': $i).
% 29.22/29.10  tff(decl_59293, type, perception: $i).
% 29.22/29.10  tff(decl_59294, type, 'Perennial': $i).
% 29.22/29.10  tff(decl_59295, type, 'A flowering plant that lives for many years.': $i).
% 29.22/29.10  tff(decl_59296, type, 'perennial plant': $i).
% 29.22/29.10  tff(decl_59297, type, perennial: $i).
% 29.22/29.10  tff(decl_59298, type, perforation_plate_1: $i > $o).
% 29.22/29.10  tff(decl_59299, type, 'Perforation-Plate': $i).
% 29.22/29.10  tff(decl_59300, type, 'Perforation plates are present at the end walls of vessel elements and  enable water to flow freely through the vessels.': $i).
% 29.22/29.10  tff(decl_59301, type, 'plate of perforation': $i).
% 29.22/29.10  tff(decl_59302, type, 'perforation plate': $i).
% 29.22/29.10  tff(decl_59303, type, 'perforation-plate': $i).
% 29.22/29.10  tff(decl_59304, type, pericycle_1: $i > $o).
% 29.22/29.10  tff(decl_59305, type, 'Pericycle': $i).
% 29.22/29.10  tff(decl_59306, type, 'In plants, the outermost layer of cells in the vascular cylinder; lateral roots arise from the pericycle.': $i).
% 29.22/29.10  tff(decl_59307, type, pericycle: $i).
% 29.22/29.10  tff(decl_59308, type, scion_1: $i > $o).
% 29.22/29.10  tff(decl_59309, type, sieve_plate_1: $i > $o).
% 29.22/29.10  tff(decl_59310, type, vascular_cambium_1: $i > $o).
% 29.22/29.10  tff(decl_59311, type, water_vascular_system_1: $i > $o).
% 29.22/29.10  tff(decl_59312, type, 'Periderm': $i).
% 29.22/29.10  tff(decl_59313, type, 'A secondary covering that forms on small woody stems and consists of the cork and cork cambium.': $i).
% 29.22/29.10  tff(decl_59314, type, periderm: $i).
% 29.22/29.10  tff(decl_59315, type, perimeter_constant_1: $i > $o).
% 29.22/29.10  tff(decl_59316, type, 'Perimeter-Constant': $i).
% 29.22/29.10  tff(decl_59317, type, 'constant of perimeter': $i).
% 29.22/29.10  tff(decl_59318, type, 'perimeter constant': $i).
% 29.22/29.10  tff(decl_59319, type, 'perimeter-constant': $i).
% 29.22/29.10  tff(decl_59320, type, perimeter_scale_1: $i > $o).
% 29.22/29.10  tff(decl_59321, type, 'Perimeter-Scale': $i).
% 29.22/29.10  tff(decl_59322, type, 'scale of perimeter': $i).
% 29.22/29.10  tff(decl_59323, type, 'perimeter scale': $i).
% 29.22/29.10  tff(decl_59324, type, 'perimeter-scale': $i).
% 29.22/29.10  tff(decl_59325, type, 'Periodic-Table': $i).
% 29.22/29.10  tff(decl_59326, type, 'A tabular display of the chemical elements arranged by chemical properties such as atomic number and number of valence electrons.': $i).
% 29.22/29.10  tff(decl_59327, type, 'periodic table': $i).
% 29.22/29.10  tff(decl_59328, type, 'periodic-table': $i).
% 29.22/29.10  tff(decl_59329, type, 'Peripheral-Nervous-System': $i).
% 29.22/29.10  tff(decl_59330, type, 'The neurons and ganglia outside the brain and spinal cord.': $i).
% 29.22/29.10  tff(decl_59331, type, 'peripheral nervous system': $i).
% 29.22/29.10  tff(decl_59332, type, 'peripheral nervous-system': $i).
% 29.22/29.10  tff(decl_59333, type, 'peripheral-nervous-system': $i).
% 29.22/29.10  tff(decl_59334, type, 'Peripheral-Protein': $i).
% 29.22/29.10  tff(decl_59335, type, 'Peripheral proteins are cell membrane proteins that are not embedded in the cell membrane but instead attached to the surface of the membrane, often connected to integral proteins which are embedded in the cell membrane.': $i).
% 29.22/29.10  tff(decl_59336, type, 'protein of peripheral': $i).
% 29.22/29.10  tff(decl_59337, type, 'peripheral protein': $i).
% 29.22/29.10  tff(decl_59338, type, 'peripheral-protein': $i).
% 29.22/29.10  tff(decl_59339, type, fn_peripheral_protein_2: $i > $i).
% 29.22/29.10  tff(decl_59340, type, fn_peripheral_protein_3: $i > $i).
% 29.22/29.10  tff(decl_59341, type, fn_peripheral_protein_4: $i > $i).
% 29.22/29.10  tff(decl_59342, type, fn_peripheral_protein_7: $i > $i).
% 29.22/29.10  tff(decl_59343, type, fn_peripheral_protein_8: $i > $i).
% 29.22/29.10  tff(decl_59344, type, fn_peripheral_protein_9: $i > $i).
% 29.22/29.10  tff(decl_59345, type, fn_peripheral_protein_11: $i > $i).
% 29.22/29.10  tff(decl_59346, type, fn_peripheral_protein_12: $i > $i).
% 29.22/29.10  tff(decl_59347, type, fn_peripheral_protein_13: $i > $i).
% 29.22/29.10  tff(decl_59348, type, fn_peripheral_protein_14: $i > $i).
% 29.22/29.10  tff(decl_59349, type, fn_peripheral_protein_15: $i > $i).
% 29.22/29.10  tff(decl_59350, type, fn_peripheral_protein_16: $i > $i).
% 29.22/29.10  tff(decl_59351, type, fn_peripheral_protein_17: $i > $i).
% 29.22/29.10  tff(decl_59352, type, fn_peripheral_protein_18: $i > $i).
% 29.22/29.10  tff(decl_59353, type, fn_peripheral_protein_19: $i > $i).
% 29.22/29.10  tff(decl_59354, type, fn_peripheral_protein_20: $i > $i).
% 29.22/29.10  tff(decl_59355, type, fn_peripheral_protein_21: $i > $i).
% 29.22/29.10  tff(decl_59356, type, fn_peripheral_protein_22: $i > $i).
% 29.22/29.10  tff(decl_59357, type, fn_peripheral_protein_23: $i > $i).
% 29.22/29.10  tff(decl_59358, type, fn_peripheral_protein_24: $i > $i).
% 29.22/29.10  tff(decl_59359, type, fn_peripheral_protein_25: $i > $i).
% 29.22/29.10  tff(decl_59360, type, fn_peripheral_protein_26: $i > $i).
% 29.22/29.10  tff(decl_59361, type, fn_peripheral_protein_27: $i > $i).
% 29.22/29.10  tff(decl_59362, type, fn_peripheral_protein_28: $i > $i).
% 29.22/29.10  tff(decl_59363, type, fn_peripheral_protein_29: $i > $i).
% 29.22/29.10  tff(decl_59364, type, fn_peripheral_protein_30: $i > $i).
% 29.22/29.10  tff(decl_59365, type, fn_peripheral_protein_31: $i > $i).
% 29.22/29.10  tff(decl_59366, type, fn_peripheral_protein_32: $i > $i).
% 29.22/29.10  tff(decl_59367, type, fn_peripheral_protein_33: $i > $i).
% 29.22/29.10  tff(decl_59368, type, fn_peripheral_protein_34: $i > $i).
% 29.22/29.10  tff(decl_59369, type, fn_peripheral_protein_35: $i > $i).
% 29.22/29.10  tff(decl_59370, type, fn_peripheral_protein_36: $i > $i).
% 29.22/29.10  tff(decl_59371, type, fn_peripheral_protein_37: $i > $i).
% 29.22/29.10  tff(decl_59372, type, fn_peripheral_protein_38: $i > $i).
% 29.22/29.10  tff(decl_59373, type, fn_peripheral_protein_39: $i > $i).
% 29.22/29.10  tff(decl_59374, type, fn_peripheral_protein_40: $i > $i).
% 29.22/29.10  tff(decl_59375, type, fn_peripheral_protein_42: $i > $i).
% 29.22/29.10  tff(decl_59376, type, fn_peripheral_protein_43: $i > $i).
% 29.22/29.10  tff(decl_59377, type, fn_peripheral_protein_44: $i > $i).
% 29.22/29.10  tff(decl_59378, type, fn_peripheral_protein_6: $i > $i).
% 29.22/29.10  tff(decl_59379, type, fn_peripheral_protein_47: $i > $i).
% 29.22/29.10  tff(decl_59380, type, fn_peripheral_protein_48: $i > $i).
% 29.22/29.10  tff(decl_59381, type, fn_peripheral_protein_49: $i > $i).
% 29.22/29.10  tff(decl_59382, type, fn_peripheral_protein_50: $i > $i).
% 29.22/29.10  tff(decl_59383, type, fn_peripheral_protein_51: $i > $i).
% 29.22/29.10  tff(decl_59384, type, fn_peripheral_protein_52: $i > $i).
% 29.22/29.10  tff(decl_59385, type, fn_peripheral_protein_5: $i > $i).
% 29.22/29.10  tff(decl_59386, type, 'Periphery': $i).
% 29.22/29.10  tff(decl_59387, type, 'The outside boundary or surface of something is called as periphery.': $i).
% 29.22/29.10  tff(decl_59388, type, 'peripheral region': $i).
% 29.22/29.10  tff(decl_59389, type, 'peripheral-region': $i).
% 29.22/29.10  tff(decl_59390, type, periphery: $i).
% 29.22/29.10  tff(decl_59391, type, 'Perissodactyla': $i).
% 29.22/29.10  tff(decl_59392, type, 'Ungulates with an odd number of toes. Species include horse, zebra and rhinoceros.': $i).
% 29.22/29.10  tff(decl_59393, type, perissodactyla: $i).
% 29.22/29.10  tff(decl_59394, type, 'Peristalsis': $i).
% 29.22/29.10  tff(decl_59395, type, '(1) A series of alternating contraction and relaxation of muscles lining the alimentary canal that move food through the digestive tract; (2) A type of movement seen in some terrestrial animals, in which rhythmic waves of muscle contraction move from the anterior to the posterior regions and propel the animal forward, as in earthworms.': $i).
% 29.22/29.10  tff(decl_59396, type, peristalsis: $i).
% 29.22/29.10  tff(decl_59397, type, fn_peristalsis_3: $i > $i).
% 29.22/29.10  tff(decl_59398, type, fn_peristalsis_4: $i > $i).
% 29.22/29.10  tff(decl_59399, type, fn_peristalsis_5: $i > $i).
% 29.22/29.10  tff(decl_59400, type, fn_peristalsis_7: $i > $i).
% 29.22/29.10  tff(decl_59401, type, fn_peristalsis_9: $i > $i).
% 29.22/29.10  tff(decl_59402, type, 'Peristome': $i).
% 29.22/29.10  tff(decl_59403, type, 'An anatomical structure that surrounds an opening. In mosses, the peristome is a specialized structure of a sporangium that allows spores to be released gradually rather than explosively.': $i).
% 29.22/29.10  tff(decl_59404, type, peristome: $i).
% 29.22/29.10  tff(decl_59405, type, 'Peritubular-Capillary': $i).
% 29.22/29.10  tff(decl_59406, type, 'One of the tiny capillaries that runs alongside the proximal and distal tubules of the kidney .': $i).
% 29.22/29.10  tff(decl_59407, type, 'peritubular capillary': $i).
% 29.22/29.10  tff(decl_59408, type, 'peritubular-capillary': $i).
% 29.22/29.10  tff(decl_59409, type, permafrost_1: $i > $o).
% 29.22/29.10  tff(decl_59410, type, 'Permafrost': $i).
% 29.22/29.10  tff(decl_59411, type, 'Any permanently frozen soil, sediment, or rock layer.': $i).
% 29.22/29.10  tff(decl_59412, type, permafrost: $i).
% 29.22/29.10  tff(decl_59413, type, 'Peroxisome': $i).
% 29.22/29.10  tff(decl_59414, type, 'Peroxisomes are organelles from the microbody family and are present in almost all eukaryotic cells. They participate in the metabolism of fatty acids and many other metabolites.': $i).
% 29.22/29.10  tff(decl_59415, type, peroxisome: $i).
% 29.22/29.10  tff(decl_59416, type, fn_peroxisome_1: $i > $i).
% 29.22/29.10  tff(decl_59417, type, fn_peroxisome_4: $i > $i).
% 29.22/29.10  tff(decl_59418, type, fn_peroxisome_6: $i > $i).
% 29.22/29.10  tff(decl_59419, type, fn_peroxisome_8: $i > $i).
% 29.22/29.10  tff(decl_59420, type, fn_peroxisome_9: $i > $i).
% 29.22/29.10  tff(decl_59421, type, fn_peroxisome_10: $i > $i).
% 29.22/29.10  tff(decl_59422, type, fn_peroxisome_16: $i > $i).
% 29.22/29.10  tff(decl_59423, type, fn_peroxisome_19: $i > $i).
% 29.22/29.10  tff(decl_59424, type, fn_peroxisome_20: $i > $i).
% 29.22/29.10  tff(decl_59425, type, fn_peroxisome_21: $i > $i).
% 29.22/29.10  tff(decl_59426, type, fn_peroxisome_22: $i > $i).
% 29.22/29.10  tff(decl_59427, type, fn_peroxisome_23: $i > $i).
% 29.22/29.10  tff(decl_59428, type, fn_peroxisome_24: $i > $i).
% 29.22/29.10  tff(decl_59429, type, fn_peroxisome_27: $i > $i).
% 29.22/29.10  tff(decl_59430, type, fn_peroxisome_31: $i > $i).
% 29.22/29.10  tff(decl_59431, type, fn_peroxisome_33: $i > $i).
% 29.22/29.10  tff(decl_59432, type, fn_peroxisome_34: $i > $i).
% 29.22/29.10  tff(decl_59433, type, fn_peroxisome_35: $i > $i).
% 29.22/29.10  tff(decl_59434, type, fn_peroxisome_36: $i > $i).
% 29.22/29.10  tff(decl_59435, type, fn_peroxisome_37: $i > $i).
% 29.22/29.10  tff(decl_59436, type, fn_peroxisome_38: $i > $i).
% 29.22/29.10  tff(decl_59437, type, fn_peroxisome_39: $i > $i).
% 29.22/29.10  tff(decl_59438, type, fn_peroxisome_44: $i > $i).
% 29.22/29.10  tff(decl_59439, type, fn_peroxisome_45: $i > $i).
% 29.22/29.10  tff(decl_59440, type, fn_peroxisome_46: $i > $i).
% 29.22/29.10  tff(decl_59441, type, fn_peroxisome_48: $i > $i).
% 29.22/29.10  tff(decl_59442, type, fn_peroxisome_50: $i > $i).
% 29.22/29.10  tff(decl_59443, type, fn_peroxisome_51: $i > $i).
% 29.22/29.10  tff(decl_59444, type, fn_peroxisome_54: $i > $i).
% 29.22/29.10  tff(decl_59445, type, fn_peroxisome_55: $i > $i).
% 29.22/29.10  tff(decl_59446, type, fn_peroxisome_56: $i > $i).
% 29.22/29.10  tff(decl_59447, type, fn_smooth_endoplasmic_reticulum_45: $i > $i).
% 29.22/29.10  tff(decl_59448, type, fn_peroxisome_18: $i > $i).
% 29.32/29.10  tff(decl_59449, type, fn_peroxisome_17: $i > $i).
% 29.32/29.10  tff(decl_59450, type, peroxisome_division_1: $i > $o).
% 29.32/29.10  tff(decl_59451, type, 'Peroxisome-Division': $i).
% 29.32/29.10  tff(decl_59452, type, 'The process of the division of the peroxisome in eukaryotic cells.': $i).
% 29.32/29.10  tff(decl_59453, type, 'division of peroxisome': $i).
% 29.32/29.10  tff(decl_59454, type, 'peroxisome division': $i).
% 29.32/29.10  tff(decl_59455, type, 'peroxisome-division': $i).
% 29.32/29.10  tff(decl_59456, type, fn_peroxisome_division_1: $i > $i).
% 29.32/29.10  tff(decl_59457, type, fn_peroxisome_division_3: $i > $i).
% 29.32/29.10  tff(decl_59458, type, fn_peroxisome_division_4: $i > $i).
% 29.32/29.10  tff(decl_59459, type, fn_peroxisome_division_5: $i > $i).
% 29.32/29.10  tff(decl_59460, type, fn_peroxisome_division_2: $i > $i).
% 29.32/29.10  tff(decl_59461, type, 'Person': $i).
% 29.32/29.10  tff(decl_59462, type, 'human being; a sentient animal': $i).
% 29.32/29.10  tff(decl_59463, type, 'A person (plural: persons or people; from Latin: persona, meaning mask)is a human being, or an entity with attributes that, depending on the context, are recognized as consisting in personhood.': $i).
% 29.32/29.10  tff(decl_59464, type, person: $i).
% 29.32/29.10  tff(decl_59465, type, individual: $i).
% 29.32/29.10  tff(decl_59466, type, someone: $i).
% 29.32/29.10  tff(decl_59467, type, somebody: $i).
% 29.32/29.10  tff(decl_59468, type, mortal: $i).
% 29.32/29.10  tff(decl_59469, type, human: $i).
% 29.32/29.10  tff(decl_59470, type, soul: $i).
% 29.32/29.10  tff(decl_59471, type, fn_person_1: $i > $i).
% 29.32/29.10  tff(decl_59472, type, fn_person_2: $i > $i).
% 29.32/29.10  tff(decl_59473, type, fn_person_3: $i > $i).
% 29.32/29.10  tff(decl_59474, type, fn_person_4: $i > $i).
% 29.32/29.10  tff(decl_59475, type, fn_person_5: $i > $i).
% 29.32/29.10  tff(decl_59476, type, fn_person_6: $i > $i).
% 29.32/29.10  tff(decl_59477, type, fn_person_7: $i > $i).
% 29.32/29.10  tff(decl_59478, type, fn_person_10: $i > $i).
% 29.32/29.10  tff(decl_59479, type, fn_person_12: $i > $i).
% 29.32/29.10  tff(decl_59480, type, fn_person_13: $i > $i).
% 29.32/29.10  tff(decl_59481, type, fn_person_14: $i > $i).
% 29.32/29.10  tff(decl_59482, type, fn_person_17: $i > $i).
% 29.32/29.10  tff(decl_59483, type, fn_person_42: $i > $i).
% 29.32/29.10  tff(decl_59484, type, fn_person_43: $i > $i).
% 29.32/29.10  tff(decl_59485, type, fn_person_45: $i > $i).
% 29.32/29.10  tff(decl_59486, type, fn_person_48: $i > $i).
% 29.32/29.10  tff(decl_59487, type, fn_person_51: $i > $i).
% 29.32/29.10  tff(decl_59488, type, fn_person_52: $i > $i).
% 29.32/29.10  tff(decl_59489, type, fn_person_53: $i > $i).
% 29.32/29.10  tff(decl_59490, type, fn_person_54: $i > $i).
% 29.32/29.10  tff(decl_59491, type, fn_person_55: $i > $i).
% 29.32/29.10  tff(decl_59492, type, fn_person_56: $i > $i).
% 29.32/29.10  tff(decl_59493, type, fn_person_57: $i > $i).
% 29.32/29.10  tff(decl_59494, type, fn_person_58: $i > $i).
% 29.32/29.10  tff(decl_59495, type, fn_person_59: $i > $i).
% 29.32/29.10  tff(decl_59496, type, fn_person_66: $i > $i).
% 29.32/29.10  tff(decl_59497, type, fn_person_70: $i > $i).
% 29.32/29.10  tff(decl_59498, type, fn_salivary_gland_5: $i > $i).
% 29.32/29.10  tff(decl_59499, type, fn_salivary_gland_4: $i > $i).
% 29.32/29.10  tff(decl_59500, type, fn_salivary_gland_2: $i > $i).
% 29.32/29.10  tff(decl_59501, type, fn_vertebrate_43: $i > $i).
% 29.32/29.10  tff(decl_59502, type, 'Pesticide': $i).
% 29.32/29.10  tff(decl_59503, type, 'Any chemical used to kill or repel pest animals.': $i).
% 29.32/29.10  tff(decl_59504, type, pesticide: $i).
% 29.32/29.10  tff(decl_59505, type, pesticide_resistance_1: $i > $o).
% 29.32/29.10  tff(decl_59506, type, 'Pesticide-Resistance': $i).
% 29.32/29.10  tff(decl_59507, type, 'The evolved ability of a pest population to resist the effects of a pesticide.': $i).
% 29.32/29.10  tff(decl_59508, type, 'resistance of pesticide': $i).
% 29.32/29.10  tff(decl_59509, type, 'pesticide resistance': $i).
% 29.32/29.10  tff(decl_59510, type, 'pesticide-resistance': $i).
% 29.32/29.10  tff(decl_59511, type, pesticide_resistance_process_1: $i > $o).
% 29.32/29.10  tff(decl_59512, type, 'Pesticide-Resistance-Process': $i).
% 29.32/29.10  tff(decl_59513, type, 'The process by which a cell resists harm by a pesticide.': $i).
% 29.32/29.10  tff(decl_59514, type, 'pesticide resistance process': $i).
% 29.32/29.10  tff(decl_59515, type, 'pesticide-resistance-process': $i).
% 29.32/29.10  tff(decl_59516, type, 'PET-Scanner': $i).
% 29.32/29.10  tff(decl_59517, type, 'Positron-emission tomography scanner. A medical imaging device that produces a 3-dimensional representation of the body.': $i).
% 29.32/29.10  tff(decl_59518, type, 'scanner of pet': $i).
% 29.32/29.10  tff(decl_59519, type, 'pet scanner': $i).
% 29.32/29.10  tff(decl_59520, type, 'pet-scanner': $i).
% 29.32/29.10  tff(decl_59521, type, fn_pet_scanner_1: $i > $i).
% 29.32/29.10  tff(decl_59522, type, fn_pet_scanner_2: $i > $i).
% 29.32/29.10  tff(decl_59523, type, 'Petal': $i).
% 29.32/29.10  tff(decl_59524, type, 'A modified leaf of a flowering plant. Petals are the often colorful parts of a flower that advertise it to insects and other pollinators.': $i).
% 29.32/29.10  tff(decl_59525, type, petal: $i).
% 29.32/29.10  tff(decl_59526, type, fn_petal_1: $i > $i).
% 29.32/29.10  tff(decl_59527, type, fn_petal_2: $i > $i).
% 29.32/29.10  tff(decl_59528, type, fn_petal_3: $i > $i).
% 29.32/29.10  tff(decl_59529, type, fn_petal_4: $i > $i).
% 29.32/29.10  tff(decl_59530, type, fn_petal_5: $i > $i).
% 29.32/29.10  tff(decl_59531, type, fn_petal_6: $i > $i).
% 29.32/29.10  tff(decl_59532, type, fn_petal_7: $i > $i).
% 29.32/29.10  tff(decl_59533, type, fn_petal_8: $i > $i).
% 29.32/29.10  tff(decl_59534, type, fn_petal_9: $i > $i).
% 29.32/29.10  tff(decl_59535, type, fn_petal_10: $i > $i).
% 29.32/29.10  tff(decl_59536, type, fn_petal_11: $i > $i).
% 29.32/29.10  tff(decl_59537, type, fn_petal_12: $i > $i).
% 29.32/29.10  tff(decl_59538, type, fn_petal_13: $i > $i).
% 29.32/29.10  tff(decl_59539, type, 'Petiole': $i).
% 29.32/29.10  tff(decl_59540, type, 'In plants, the stalk that attaches a leaf to a node on the stem.': $i).
% 29.32/29.10  tff(decl_59541, type, petiole: $i).
% 29.32/29.10  tff(decl_59542, type, 'Petri-Dish': $i).
% 29.32/29.10  tff(decl_59543, type, 'A shallow dish usedto culture bacteria.': $i).
% 29.32/29.10  tff(decl_59544, type, 'culture dish': $i).
% 29.32/29.10  tff(decl_59545, type, 'culture-dish': $i).
% 29.32/29.10  tff(decl_59546, type, 'petri dish': $i).
% 29.32/29.10  tff(decl_59547, type, 'petri-dish': $i).
% 29.32/29.10  tff(decl_59548, type, petroleum_1: $i > $o).
% 29.32/29.10  tff(decl_59549, type, 'Petroleum': $i).
% 29.32/29.10  tff(decl_59550, type, 'A naturally occuring flammable liquid made of a complex mixture of hydrocarbons. Petroleum is found in various geologic formations beneath the surface of the earth. It is mined and extracted from the earth and distilled into gasoline, kerosene, and a variety of solvents.': $i).
% 29.32/29.10  tff(decl_59551, type, petroleum: $i).
% 29.32/29.10  tff(decl_59552, type, fn_petroleum_2: $i > $i).
% 29.32/29.10  tff(decl_59553, type, fn_petroleum_1: $i > $i).
% 29.32/29.10  tff(decl_59554, type, 'PH-Constant': $i).
% 29.32/29.10  tff(decl_59555, type, 'ph constant': $i).
% 29.32/29.10  tff(decl_59556, type, 'ph-constant': $i).
% 29.32/29.10  tff(decl_59557, type, 'PH-Maintenance': $i).
% 29.32/29.10  tff(decl_59558, type, 'Process which keeps the pH of a solution, cell or organ within normal limits.': $i).
% 29.32/29.10  tff(decl_59559, type, 'maintain ph': $i).
% 29.32/29.10  tff(decl_59560, type, 'ph maintenance': $i).
% 29.32/29.10  tff(decl_59561, type, 'ph-maintenance': $i).
% 29.32/29.10  tff(decl_59562, type, ph_scale_1: $i > $o).
% 29.32/29.10  tff(decl_59563, type, 'PH-Scale': $i).
% 29.32/29.10  tff(decl_59564, type, 'ph scale': $i).
% 29.32/29.10  tff(decl_59565, type, 'ph-scale': $i).
% 29.32/29.10  tff(decl_59566, type, 'PH-Value': $i).
% 29.32/29.10  tff(decl_59567, type, ph: $i).
% 29.32/29.10  tff(decl_59568, type, 'ph value': $i).
% 29.32/29.10  tff(decl_59569, type, 'ph-value': $i).
% 29.32/29.10  tff(decl_59570, type, 'Phage': $i).
% 29.32/29.10  tff(decl_59571, type, 'A bacteriophage, or a virus that infects and replicates inside bacterial cells.': $i).
% 29.32/29.10  tff(decl_59572, type, bacteriophage: $i).
% 29.32/29.10  tff(decl_59573, type, 'bacteria virus': $i).
% 29.32/29.10  tff(decl_59574, type, 'virus infecting bacterial host': $i).
% 29.32/29.10  tff(decl_59575, type, phage: $i).
% 29.32/29.10  tff(decl_59576, type, fn_phage_1: $i > $i).
% 29.32/29.10  tff(decl_59577, type, fn_phage_2: $i > $i).
% 29.32/29.10  tff(decl_59578, type, phage_dna_1: $i > $o).
% 29.32/29.10  tff(decl_59579, type, 'Phage-DNA': $i).
% 29.32/29.10  tff(decl_59580, type, 'The genomic material of a phage.': $i).
% 29.32/29.10  tff(decl_59581, type, 'dna of phage': $i).
% 29.32/29.10  tff(decl_59582, type, 'phage dna': $i).
% 29.32/29.10  tff(decl_59583, type, 'phage-dna': $i).
% 29.32/29.10  tff(decl_59584, type, phage_lambda_1: $i > $o).
% 29.32/29.10  tff(decl_59585, type, 'Phage-Lambda': $i).
% 29.32/29.10  tff(decl_59586, type, 'One species of temperate bacteriophage.': $i).
% 29.32/29.10  tff(decl_59587, type, lambda: $i).
% 29.32/29.10  tff(decl_59588, type, 'lambda of phage': $i).
% 29.32/29.10  tff(decl_59589, type, 'phage lambda': $i).
% 29.32/29.10  tff(decl_59590, type, 'phage-lambda': $i).
% 29.32/29.10  tff(decl_59591, type, 'Phage-Reproduction-Cycle': $i).
% 29.32/29.10  tff(decl_59592, type, 'The mechanisms by which phages replicate.  The two alternative mechanisms are the lytic cycle which results in the death of the host cell or the lysogenic cycle where the viral genome is incorporated into the host cell\\s chromosome as a prophage and is replicated along with the chromosome and does not kill the host cell.': $i).
% 29.32/29.10  tff(decl_59593, type, 'phage reproduction cycle': $i).
% 29.32/29.10  tff(decl_59594, type, 'phage-reproduction-cycle': $i).
% 29.32/29.10  tff(decl_59595, type, reproductive_cycle_1: $i > $o).
% 29.32/29.10  tff(decl_59596, type, 'Phagocyte': $i).
% 29.32/29.10  tff(decl_59597, type, 'Gneral name given to the types of white blood cells, such as macrophages and monocytes, which destroy antigenic invaders such as viruses and bacteria or damaged cell parts through phagocytosis.': $i).
% 29.32/29.10  tff(decl_59598, type, phagocyte: $i).
% 29.32/29.10  tff(decl_59599, type, 'Phagocytosis': $i).
% 29.32/29.10  tff(decl_59600, type, 'Phagocytosis is the cellular process of phagocytes and protists of engulfing solid particles by the cell membrane to form an internal phagosome. Some human cells also carry out phagocytosis.': $i).
% 29.32/29.10  tff(decl_59601, type, 'cellular eating': $i).
% 29.32/29.10  tff(decl_59602, type, 'cellular-eating': $i).
% 29.32/29.10  tff(decl_59603, type, 'perform phagocytosis': $i).
% 29.32/29.10  tff(decl_59604, type, phagocytosis: $i).
% 29.32/29.10  tff(decl_59605, type, pinocytosis_1: $i > $o).
% 29.32/29.10  tff(decl_59606, type, fn_phagocytosis_2: $i > $i).
% 29.32/29.10  tff(decl_59607, type, fn_phagocytosis_3: $i > $i).
% 29.32/29.10  tff(decl_59608, type, fn_phagocytosis_4: $i > $i).
% 29.32/29.10  tff(decl_59609, type, fn_phagocytosis_6: $i > $i).
% 29.32/29.10  tff(decl_59610, type, fn_phagocytosis_9: $i > $i).
% 29.32/29.10  tff(decl_59611, type, fn_phagocytosis_10: $i > $i).
% 29.32/29.10  tff(decl_59612, type, fn_phagocytosis_11: $i > $i).
% 29.32/29.10  tff(decl_59613, type, fn_phagocytosis_13: $i > $i).
% 29.32/29.10  tff(decl_59614, type, fn_phagocytosis_14: $i > $i).
% 29.32/29.10  tff(decl_59615, type, fn_phagocytosis_15: $i > $i).
% 29.32/29.10  tff(decl_59616, type, fn_phagocytosis_16: $i > $i).
% 29.32/29.10  tff(decl_59617, type, fn_phagocytosis_20: $i > $i).
% 29.32/29.10  tff(decl_59618, type, fn_phagocytosis_25: $i > $i).
% 29.32/29.10  tff(decl_59619, type, fn_phagocytosis_26: $i > $i).
% 29.32/29.10  tff(decl_59620, type, fn_phagocytosis_27: $i > $i).
% 29.32/29.10  tff(decl_59621, type, fn_phagocytosis_28: $i > $i).
% 29.32/29.10  tff(decl_59622, type, fn_phagocytosis_29: $i > $i).
% 29.32/29.10  tff(decl_59623, type, fn_phagocytosis_30: $i > $i).
% 29.32/29.10  tff(decl_59624, type, fn_phagocytosis_31: $i > $i).
% 29.32/29.10  tff(decl_59625, type, fn_phagocytosis_32: $i > $i).
% 29.32/29.10  tff(decl_59626, type, fn_phagocytosis_33: $i > $i).
% 29.32/29.10  tff(decl_59627, type, fn_phagocytosis_34: $i > $i).
% 29.32/29.10  tff(decl_59628, type, fn_phagocytosis_35: $i > $i).
% 29.32/29.10  tff(decl_59629, type, fn_phagocytosis_36: $i > $i).
% 29.32/29.10  tff(decl_59630, type, fn_phagocytosis_37: $i > $i).
% 29.32/29.10  tff(decl_59631, type, fn_phagocytosis_38: $i > $i).
% 29.32/29.10  tff(decl_59632, type, fn_phagocytosis_39: $i > $i).
% 29.32/29.10  tff(decl_59633, type, fn_phagocytosis_40: $i > $i).
% 29.32/29.10  tff(decl_59634, type, fn_phagocytosis_41: $i > $i).
% 29.32/29.10  tff(decl_59635, type, fn_phagocytosis_47: $i > $i).
% 29.32/29.10  tff(decl_59636, type, fn_phagocytosis_48: $i > $i).
% 29.32/29.10  tff(decl_59637, type, fn_phagocytosis_50: $i > $i).
% 29.32/29.10  tff(decl_59638, type, fn_phagocytosis_51: $i > $i).
% 29.32/29.10  tff(decl_59639, type, fn_phagocytosis_52: $i > $i).
% 29.32/29.10  tff(decl_59640, type, fn_phagocytosis_53: $i > $i).
% 29.32/29.10  tff(decl_59641, type, fn_phagocytosis_54: $i > $i).
% 29.32/29.10  tff(decl_59642, type, fn_phagocytosis_55: $i > $i).
% 29.32/29.10  tff(decl_59643, type, fn_phagocytosis_56: $i > $i).
% 29.32/29.10  tff(decl_59644, type, fn_phagocytosis_57: $i > $i).
% 29.32/29.10  tff(decl_59645, type, fn_phagocytosis_58: $i > $i).
% 29.32/29.10  tff(decl_59646, type, fn_phagocytosis_59: $i > $i).
% 29.32/29.10  tff(decl_59647, type, fn_phagocytosis_60: $i > $i).
% 29.32/29.10  tff(decl_59648, type, fn_phagocytosis_61: $i > $i).
% 29.32/29.10  tff(decl_59649, type, fn_phagocytosis_62: $i > $i).
% 29.32/29.10  tff(decl_59650, type, fn_phagocytosis_63: $i > $i).
% 29.32/29.10  tff(decl_59651, type, fn_phagocytosis_64: $i > $i).
% 29.32/29.10  tff(decl_59652, type, fn_phagocytosis_65: $i > $i).
% 29.32/29.10  tff(decl_59653, type, fn_phagocytosis_67: $i > $i).
% 29.32/29.10  tff(decl_59654, type, fn_phagocytosis_68: $i > $i).
% 29.32/29.10  tff(decl_59655, type, fn_phagocytosis_69: $i > $i).
% 29.32/29.10  tff(decl_59656, type, fn_phagocytosis_72: $i > $i).
% 29.32/29.10  tff(decl_59657, type, fn_phagocytosis_73: $i > $i).
% 29.32/29.10  tff(decl_59658, type, fn_phagocytosis_74: $i > $i).
% 29.32/29.10  tff(decl_59659, type, fn_phagocytosis_75: $i > $i).
% 29.32/29.10  tff(decl_59660, type, fn_phagocytosis_78: $i > $i).
% 29.32/29.10  tff(decl_59661, type, fn_phagocytosis_83: $i > $i).
% 29.32/29.10  tff(decl_59662, type, fn_phagocytosis_84: $i > $i).
% 29.32/29.10  tff(decl_59663, type, fn_phagocytosis_85: $i > $i).
% 29.32/29.10  tff(decl_59664, type, fn_phagocytosis_86: $i > $i).
% 29.32/29.10  tff(decl_59665, type, fn_phagocytosis_87: $i > $i).
% 29.32/29.10  tff(decl_59666, type, fn_phagocytosis_89: $i > $i).
% 29.32/29.10  tff(decl_59667, type, fn_phagocytosis_90: $i > $i).
% 29.32/29.10  tff(decl_59668, type, fn_phagocytosis_93: $i > $i).
% 29.32/29.10  tff(decl_59669, type, fn_phagocytosis_95: $i > $i).
% 29.32/29.10  tff(decl_59670, type, fn_phagocytosis_96: $i > $i).
% 29.32/29.10  tff(decl_59671, type, fn_phagocytosis_99: $i > $i).
% 29.32/29.10  tff(decl_59672, type, fn_phagocytosis_100: $i > $i).
% 29.32/29.10  tff(decl_59673, type, fn_phagocytosis_101: $i > $i).
% 29.32/29.10  tff(decl_59674, type, fn_phagocytosis_102: $i > $i).
% 29.32/29.10  tff(decl_59675, type, fn_phagocytosis_103: $i > $i).
% 29.32/29.10  tff(decl_59676, type, fn_phagocytosis_104: $i > $i).
% 29.32/29.10  tff(decl_59677, type, fn_phagocytosis_105: $i > $i).
% 29.32/29.10  tff(decl_59678, type, fn_phagocytosis_106: $i > $i).
% 29.32/29.10  tff(decl_59679, type, fn_phagocytosis_107: $i > $i).
% 29.32/29.10  tff(decl_59680, type, fn_phagocytosis_108: $i > $i).
% 29.32/29.10  tff(decl_59681, type, fn_phagocytosis_109: $i > $i).
% 29.32/29.10  tff(decl_59682, type, fn_phagocytosis_110: $i > $i).
% 29.32/29.10  tff(decl_59683, type, fn_phagocytosis_111: $i > $i).
% 29.32/29.10  tff(decl_59684, type, fn_phagocytosis_112: $i > $i).
% 29.32/29.10  tff(decl_59685, type, fn_phagocytosis_113: $i > $i).
% 29.32/29.10  tff(decl_59686, type, fn_phagocytosis_114: $i > $i).
% 29.32/29.10  tff(decl_59687, type, fn_phagocytosis_115: $i > $i).
% 29.32/29.10  tff(decl_59688, type, fn_phagocytosis_116: $i > $i).
% 29.32/29.10  tff(decl_59689, type, fn_phagocytosis_117: $i > $i).
% 29.32/29.10  tff(decl_59690, type, fn_phagocytosis_118: $i > $i).
% 29.32/29.10  tff(decl_59691, type, fn_phagocytosis_119: $i > $i).
% 29.32/29.10  tff(decl_59692, type, fn_lysosomal_enzyme_1: $i > $i).
% 29.32/29.10  tff(decl_59693, type, fn_plasma_membrane_32: $i > $i).
% 29.32/29.10  tff(decl_59694, type, fn_pseudopodium_1: $i > $i).
% 29.32/29.10  tff(decl_59695, type, fn_phagocytosis_22: $i > $i).
% 29.32/29.10  tff(decl_59696, type, fn_phagocytosis_23: $i > $i).
% 29.32/29.10  tff(decl_59697, type, fn_phagocytosis_24: $i > $i).
% 29.32/29.10  tff(decl_59698, type, fn_phagocytosis_21: $i > $i).
% 29.32/29.10  tff(decl_59699, type, fn_phagocytosis_44: $i > $i).
% 29.32/29.10  tff(decl_59700, type, fn_phagocytosis_45: $i > $i).
% 29.32/29.10  tff(decl_59701, type, fn_phagocytosis_43: $i > $i).
% 29.32/29.10  tff(decl_59702, type, fn_phagocytosis_42: $i > $i).
% 29.32/29.10  tff(decl_59703, type, fn_phagocytosis_17: $i > $i).
% 29.32/29.10  tff(decl_59704, type, fn_phagocytosis_18: $i > $i).
% 29.32/29.10  tff(decl_59705, type, 'Pharmaceutical-Product': $i).
% 29.32/29.10  tff(decl_59706, type, 'A chemical substance used in medical diagnosis, treatment, or prevention of disease.': $i).
% 29.32/29.10  tff(decl_59707, type, 'product of pharmaceutical': $i).
% 29.32/29.10  tff(decl_59708, type, 'pharmaceutical product': $i).
% 29.32/29.10  tff(decl_59709, type, 'pharmaceutical-product': $i).
% 29.32/29.10  tff(decl_59710, type, 'Pharyngeal-Cleft': $i).
% 29.32/29.10  tff(decl_59711, type, 'One of a series of grooves separating the branchial pouches in the pharynx of chordate embryos. In some chordates, the pharyngeal clefts develop into gill slits.': $i).
% 29.32/29.10  tff(decl_59712, type, 'pharyngeal cleft': $i).
% 29.32/29.10  tff(decl_59713, type, 'pharyngeal-cleft': $i).
% 29.32/29.10  tff(decl_59714, type, 'Pharyngeal-Slit': $i).
% 29.32/29.10  tff(decl_59715, type, 'A slit in the pharyngeal region of a chordate embryo. Pharyngeal slits are used for filter feeding in many of the invertebrate chordates. In tetrapod vertebrates, pharyngeal slits are present only in the embryonic stage.': $i).
% 29.32/29.10  tff(decl_59716, type, 'pharyngeal slit': $i).
% 29.32/29.10  tff(decl_59717, type, 'pharyngeal-slit': $i).
% 29.32/29.10  tff(decl_59718, type, 'Pharynx': $i).
% 29.32/29.10  tff(decl_59719, type, '(1) In vertebrate animals, the region of the throat where the passages for air and food occur. (2) In some invertebrate animals, such as flatworms and roundworms, a muscular portion of the anterior alimentary canal that may or may not be eversible.': $i).
% 29.32/29.10  tff(decl_59720, type, pharynx: $i).
% 29.32/29.10  tff(decl_59721, type, 'Phase-Change': $i).
% 29.32/29.10  tff(decl_59722, type, 'A transition from one developmental stage to another.': $i).
% 29.32/29.10  tff(decl_59723, type, 'change of phase': $i).
% 29.32/29.10  tff(decl_59724, type, 'phase change': $i).
% 29.32/29.10  tff(decl_59725, type, 'phase-change': $i).
% 29.32/29.10  tff(decl_59726, type, 'Phase-Contrast-Microscope': $i).
% 29.32/29.10  tff(decl_59727, type, 'A type of light microscope that increases contrast in unstained cells or transparent organisms by amplifying variations in density within the specimen.': $i).
% 29.32/29.10  tff(decl_59728, type, 'phase contrast microscope': $i).
% 29.32/29.10  tff(decl_59729, type, 'phase-contrast-microscope': $i).
% 29.32/29.10  tff(decl_59730, type, phenobarbital_1: $i > $o).
% 29.32/29.10  tff(decl_59731, type, 'Phenobarbital': $i).
% 29.32/29.10  tff(decl_59732, type, 'A long-acting barbiturate used as a sedative': $i).
% 29.32/29.10  tff(decl_59733, type, phenobarbital: $i).
% 29.32/29.10  tff(decl_59734, type, 'Phenotype': $i).
% 29.32/29.10  tff(decl_59735, type, 'The physical and physiological traits of an organism.': $i).
% 29.32/29.10  tff(decl_59736, type, trait: $i).
% 29.32/29.10  tff(decl_59737, type, 'physical trait': $i).
% 29.32/29.10  tff(decl_59738, type, 'physical character': $i).
% 29.32/29.10  tff(decl_59739, type, appearance: $i).
% 29.32/29.10  tff(decl_59740, type, 'physiological trait': $i).
% 29.32/29.10  tff(decl_59741, type, phenotype: $i).
% 29.32/29.10  tff(decl_59742, type, trait_0: $i).
% 29.32/29.10  tff(decl_59743, type, 'Phenotype-Of-Offspring': $i).
% 29.32/29.10  tff(decl_59744, type, 'Phenotype of offspring.': $i).
% 29.32/29.10  tff(decl_59745, type, 'offspring-phenotype': $i).
% 29.32/29.10  tff(decl_59746, type, 'phenotype of offspring': $i).
% 29.32/29.10  tff(decl_59747, type, 'phenotype-of-offspring': $i).
% 29.32/29.10  tff(decl_59748, type, 'Phenotype-Of-Parent': $i).
% 29.32/29.10  tff(decl_59749, type, 'Phenotype of parent.': $i).
% 29.32/29.10  tff(decl_59750, type, 'parental phenotype': $i).
% 29.32/29.10  tff(decl_59751, type, 'parent phenotype': $i).
% 29.32/29.10  tff(decl_59752, type, 'parent-phenotype': $i).
% 29.32/29.10  tff(decl_59753, type, 'phenotype of parent': $i).
% 29.32/29.10  tff(decl_59754, type, 'phenotype-of-parent': $i).
% 29.32/29.10  tff(decl_59755, type, 'Phenotypic-Ratio': $i).
% 29.32/29.10  tff(decl_59756, type, 'A ratio indicating the expected numbers of individuals with each observable trait possible from a genetic cross.': $i).
% 29.32/29.10  tff(decl_59757, type, 'phenotype ratio': $i).
% 29.32/29.10  tff(decl_59758, type, 'phenotype-ratio': $i).
% 29.32/29.10  tff(decl_59759, type, 'phenotypic ratio': $i).
% 29.32/29.10  tff(decl_59760, type, 'phenotypic-ratio': $i).
% 29.32/29.10  tff(decl_59761, type, 'Phenylalanine': $i).
% 29.32/29.10  tff(decl_59762, type, phenylalanine: $i).
% 29.32/29.10  tff(decl_59763, type, 'Phenylketonuria': $i).
% 29.32/29.10  tff(decl_59764, type, 'an autosomal recessive metabolic genetic disorder characterized by a deficiency in an enzyme needed to metabolize the amino acid phenylalanine': $i).
% 29.32/29.10  tff(decl_59765, type, pku: $i).
% 29.32/29.10  tff(decl_59766, type, phenylketonuria: $i).
% 29.32/29.10  tff(decl_59767, type, fn_phenylketonuria_1: $i > $i).
% 29.32/29.10  tff(decl_59768, type, fn_phenylketonuria_2: $i > $i).
% 29.32/29.10  tff(decl_59769, type, 'Pheromone': $i).
% 29.32/29.10  tff(decl_59770, type, 'A biologically produced chemical that is released into the environment and functions in communication between individuals of the same species.': $i).
% 29.32/29.10  tff(decl_59771, type, pheromone: $i).
% 29.32/29.10  tff(decl_59772, type, 'Phloem': $i).
% 29.32/29.10  tff(decl_59773, type, 'In vascular plants, the living tissue that transports nutrients and photosynthetic products throughout the plant.': $i).
% 29.32/29.10  tff(decl_59774, type, phloem: $i).
% 29.32/29.10  tff(decl_59775, type, fn_phloem_1: $i > $i).
% 29.32/29.10  tff(decl_59776, type, sieve_tube_1: $i > $o).
% 29.32/29.10  tff(decl_59777, type, fn_phloem_2: $i > $i).
% 29.32/29.10  tff(decl_59778, type, translocation_of_phloem_sap_1: $i > $o).
% 29.32/29.10  tff(decl_59779, type, phloem_sap_1: $i > $o).
% 29.32/29.10  tff(decl_59780, type, 'Phloem-Sap': $i).
% 29.32/29.10  tff(decl_59781, type, 'A sugar solution that is transported by phloem throughout a plant.': $i).
% 29.32/29.10  tff(decl_59782, type, 'sap of phloem': $i).
% 29.32/29.10  tff(decl_59783, type, 'phloem sap': $i).
% 29.32/29.10  tff(decl_59784, type, 'phloem-sap': $i).
% 29.32/29.10  tff(decl_59785, type, fn_phloem_sap_1: $i > $i).
% 29.32/29.10  tff(decl_59786, type, fn_phloem_sap_2: $i > $i).
% 29.32/29.10  tff(decl_59787, type, fn_phloem_sap_3: $i > $i).
% 29.32/29.10  tff(decl_59788, type, fn_phloem_sap_5: $i > $i).
% 29.32/29.10  tff(decl_59789, type, fn_phloem_sap_6: $i > $i).
% 29.32/29.10  tff(decl_59790, type, fn_phloem_sap_7: $i > $i).
% 29.32/29.10  tff(decl_59791, type, fn_phloem_sap_8: $i > $i).
% 29.32/29.10  tff(decl_59792, type, fn_phloem_sap_9: $i > $i).
% 29.32/29.10  tff(decl_59793, type, fn_phloem_sap_10: $i > $i).
% 29.32/29.10  tff(decl_59794, type, fn_phloem_sap_11: $i > $i).
% 29.32/29.10  tff(decl_59795, type, fn_phloem_sap_12: $i > $i).
% 29.32/29.10  tff(decl_59796, type, fn_phloem_sap_13: $i > $i).
% 29.32/29.10  tff(decl_59797, type, fn_phloem_sap_18: $i > $i).
% 29.32/29.10  tff(decl_59798, type, fn_phloem_sap_19: $i > $i).
% 29.32/29.10  tff(decl_59799, type, fn_phloem_sap_20: $i > $i).
% 29.32/29.10  tff(decl_59800, type, fn_phloem_sap_21: $i > $i).
% 29.32/29.10  tff(decl_59801, type, fn_phloem_sap_22: $i > $i).
% 29.32/29.10  tff(decl_59802, type, fn_phloem_sap_23: $i > $i).
% 29.32/29.10  tff(decl_59803, type, fn_phloem_sap_24: $i > $i).
% 29.32/29.10  tff(decl_59804, type, fn_phloem_sap_25: $i > $i).
% 29.32/29.10  tff(decl_59805, type, fn_phloem_sap_26: $i > $i).
% 29.32/29.10  tff(decl_59806, type, fn_phloem_sap_27: $i > $i).
% 29.32/29.10  tff(decl_59807, type, fn_phloem_sap_28: $i > $i).
% 29.32/29.10  tff(decl_59808, type, fn_phloem_sap_29: $i > $i).
% 29.32/29.10  tff(decl_59809, type, fn_phloem_sap_30: $i > $i).
% 29.32/29.10  tff(decl_59810, type, fn_phloem_sap_31: $i > $i).
% 29.32/29.10  tff(decl_59811, type, fn_phloem_sap_32: $i > $i).
% 29.32/29.10  tff(decl_59812, type, fn_phloem_sap_33: $i > $i).
% 29.32/29.10  tff(decl_59813, type, fn_phloem_sap_35: $i > $i).
% 29.32/29.10  tff(decl_59814, type, fn_phloem_sap_34: $i > $i).
% 29.32/29.10  tff(decl_59815, type, fn_solution_1: $i > $i).
% 29.32/29.10  tff(decl_59816, type, fn_solution_2: $i > $i).
% 29.32/29.10  tff(decl_59817, type, fn_phloem_sap_17: $i > $i).
% 29.32/29.10  tff(decl_59818, type, 'Phoronid': $i).
% 29.32/29.10  tff(decl_59819, type, 'A member of the phylum Phoronida, commonly called horseshoe worms. Phoronids are vermiform in shape, but have a U-shaped gut so that the mouth and anus are located on the same end of the body. Phoronids use a lophophore for filter-feeding.': $i).
% 29.32/29.10  tff(decl_59820, type, 'horseshoe worms': $i).
% 29.32/29.10  tff(decl_59821, type, 'horseshoe-worms': $i).
% 29.32/29.10  tff(decl_59822, type, phoronid: $i).
% 29.32/29.10  tff(decl_59823, type, 'Phosphatase': $i).
% 29.32/29.10  tff(decl_59824, type, 'Enzymes which catalyze removal of a phosphate group from its substrate.': $i).
% 29.32/29.10  tff(decl_59825, type, phosphatase: $i).
% 29.32/29.10  tff(decl_59826, type, fn_phosphatase_3: $i > $i).
% 29.32/29.10  tff(decl_59827, type, fn_phosphatase_4: $i > $i).
% 29.32/29.10  tff(decl_59828, type, fn_phosphatase_5: $i > $i).
% 29.32/29.10  tff(decl_59829, type, fn_phosphatase_7: $i > $i).
% 29.32/29.10  tff(decl_59830, type, fn_phosphatase_2: $i > $i).
% 29.32/29.10  tff(decl_59831, type, phosphate_bond_1: $i > $o).
% 29.32/29.10  tff(decl_59832, type, 'Phosphate-Bond': $i).
% 29.32/29.10  tff(decl_59833, type, 'The phosphate bonds are formed when compounds such as adenosine diphosphate and adenosine triphosphate are created.': $i).
% 29.32/29.10  tff(decl_59834, type, 'bond of phosphate': $i).
% 29.32/29.10  tff(decl_59835, type, 'phosphate bond': $i).
% 29.32/29.10  tff(decl_59836, type, 'phosphate-bond': $i).
% 29.32/29.10  tff(decl_59837, type, fn_phosphate_bond_5: $i > $i).
% 29.32/29.10  tff(decl_59838, type, fn_phosphate_bond_6: $i > $i).
% 29.32/29.10  tff(decl_59839, type, fn_phosphate_bond_7: $i > $i).
% 29.32/29.10  tff(decl_59840, type, fn_phosphate_bond_8: $i > $i).
% 29.32/29.10  tff(decl_59841, type, fn_phosphate_bond_9: $i > $i).
% 29.32/29.10  tff(decl_59842, type, fn_phosphate_bond_10: $i > $i).
% 29.32/29.10  tff(decl_59843, type, fn_phosphate_bond_11: $i > $i).
% 29.32/29.10  tff(decl_59844, type, fn_phosphate_bond_12: $i > $i).
% 29.32/29.10  tff(decl_59845, type, fn_phosphate_bond_13: $i > $i).
% 29.32/29.10  tff(decl_59846, type, fn_phosphate_bond_14: $i > $i).
% 29.32/29.10  tff(decl_59847, type, fn_phosphate_bond_15: $i > $i).
% 29.32/29.10  tff(decl_59848, type, fn_phosphate_bond_16: $i > $i).
% 29.32/29.10  tff(decl_59849, type, fn_phosphate_bond_17: $i > $i).
% 29.32/29.10  tff(decl_59850, type, fn_phosphate_bond_18: $i > $i).
% 29.32/29.10  tff(decl_59851, type, fn_phosphate_bond_19: $i > $i).
% 29.32/29.10  tff(decl_59852, type, fn_phosphate_bond_20: $i > $i).
% 29.32/29.10  tff(decl_59853, type, fn_phosphate_bond_21: $i > $i).
% 29.32/29.10  tff(decl_59854, type, fn_phosphate_bond_22: $i > $i).
% 29.32/29.10  tff(decl_59855, type, fn_phosphate_bond_23: $i > $i).
% 29.32/29.10  tff(decl_59856, type, fn_phosphate_bond_24: $i > $i).
% 29.32/29.10  tff(decl_59857, type, fn_phosphate_bond_25: $i > $i).
% 29.32/29.10  tff(decl_59858, type, fn_phosphate_bond_26: $i > $i).
% 29.32/29.10  tff(decl_59859, type, fn_phosphate_bond_27: $i > $i).
% 29.32/29.10  tff(decl_59860, type, fn_phosphate_bond_29: $i > $i).
% 29.32/29.10  tff(decl_59861, type, fn_phosphate_bond_30: $i > $i).
% 29.32/29.10  tff(decl_59862, type, fn_phosphate_bond_31: $i > $i).
% 29.32/29.10  tff(decl_59863, type, fn_phosphate_group_46: $i > $i).
% 29.32/29.10  tff(decl_59864, type, fn_phosphate_group_30: $i > $i).
% 29.32/29.10  tff(decl_59865, type, fn_phosphate_group_29: $i > $i).
% 29.32/29.10  tff(decl_59866, type, fn_phosphate_group_2: $i > $i).
% 29.32/29.10  tff(decl_59867, type, fn_phosphate_group_4: $i > $i).
% 29.32/29.10  tff(decl_59868, type, fn_phosphate_bond_28: $i > $i).
% 29.32/29.10  tff(decl_59869, type, fn_phosphate_bond_3: $i > $i).
% 29.32/29.10  tff(decl_59870, type, fn_phosphate_bond_4: $i > $i).
% 29.32/29.10  tff(decl_59871, type, phosphate_detergent_1: $i > $o).
% 29.32/29.10  tff(decl_59872, type, 'Phosphate-Detergent': $i).
% 29.32/29.10  tff(decl_59873, type, 'An organic compound containing phosphates, which has both polar and non-polar characteristics and used to soften hard water and help suspend dirt in water.': $i).
% 29.32/29.10  tff(decl_59874, type, tsp: $i).
% 29.32/29.10  tff(decl_59875, type, 'detergent of phosphate': $i).
% 29.32/29.10  tff(decl_59876, type, 'phosphate detergent': $i).
% 29.32/29.10  tff(decl_59877, type, 'phosphate-detergent': $i).
% 29.32/29.10  tff(decl_59878, type, 'Phosphate-Group': $i).
% 29.32/29.10  tff(decl_59879, type, 'Phosphate group is an inorganic molecule which is made up of phosphorous and oxygen, It has two negative charge. It plays many important roles in biological reactions': $i).
% 29.32/29.10  tff(decl_59880, type, phosphate: $i).
% 29.32/29.10  tff(decl_59881, type, 'group of phosphate': $i).
% 29.32/29.10  tff(decl_59882, type, 'phosphate group': $i).
% 29.32/29.10  tff(decl_59883, type, 'phosphate-group': $i).
% 29.32/29.10  tff(decl_59884, type, fn_phosphate_group_1: $i > $i).
% 29.32/29.10  tff(decl_59885, type, fn_phosphate_group_15: $i > $i).
% 29.32/29.10  tff(decl_59886, type, fn_phosphate_group_27: $i > $i).
% 29.32/29.10  tff(decl_59887, type, fn_phosphate_group_28: $i > $i).
% 29.32/29.10  tff(decl_59888, type, fn_phosphate_group_31: $i > $i).
% 29.32/29.10  tff(decl_59889, type, fn_phosphate_group_32: $i > $i).
% 29.32/29.10  tff(decl_59890, type, fn_phosphate_group_33: $i > $i).
% 29.32/29.10  tff(decl_59891, type, fn_phosphate_group_34: $i > $i).
% 29.32/29.10  tff(decl_59892, type, fn_phosphate_group_24: $i > $i).
% 29.32/29.10  tff(decl_59893, type, fn_phosphate_group_43: $i > $i).
% 29.32/29.10  tff(decl_59894, type, fn_phosphate_group_44: $i > $i).
% 29.32/29.10  tff(decl_59895, type, fn_phosphate_group_45: $i > $i).
% 29.32/29.10  tff(decl_59896, type, fn_phosphate_group_42: $i > $i).
% 29.32/29.10  tff(decl_59897, type, 'Phosphate-Ion': $i).
% 29.32/29.10  tff(decl_59898, type, 'Polyatomic ion of phosphorus with a charge of minus 3': $i).
% 29.32/29.10  tff(decl_59899, type, '(hopo3)2-': $i).
% 29.32/29.10  tff(decl_59900, type, pi: $i).
% 29.32/29.10  tff(decl_59901, type, 'ion of phosphate': $i).
% 29.32/29.10  tff(decl_59902, type, 'phosphate ion': $i).
% 29.32/29.10  tff(decl_59903, type, 'phosphate-ion': $i).
% 29.32/29.10  tff(decl_59904, type, fn_phosphate_ion_2: $i > $i).
% 29.32/29.10  tff(decl_59905, type, fn_phosphate_ion_3: $i > $i).
% 29.32/29.10  tff(decl_59906, type, fn_phosphate_ion_4: $i > $i).
% 29.32/29.10  tff(decl_59907, type, "-3.0e0": $i).
% 29.32/29.10  tff(decl_59908, type, fn_phosphate_ion_1: $i > $i).
% 29.32/29.10  tff(decl_59909, type, phosphatidylcholine_1: $i > $o).
% 29.32/29.10  tff(decl_59910, type, 'Phosphatidylcholine': $i).
% 29.32/29.10  tff(decl_59911, type, 'A phospholipid that is a major component of cellular membranes and functions in the transport of lipoproteins in tissues. It contains a choline group.': $i).
% 29.32/29.10  tff(decl_59912, type, phosphatidylcholine: $i).
% 29.32/29.10  tff(decl_59913, type, fn_phosphatidylcholine_2: $i > $i).
% 29.32/29.10  tff(decl_59914, type, fn_phosphatidylcholine_3: $i > $i).
% 29.32/29.10  tff(decl_59915, type, fn_phosphatidylcholine_4: $i > $i).
% 29.32/29.10  tff(decl_59916, type, fn_phosphatidylcholine_5: $i > $i).
% 29.32/29.10  tff(decl_59917, type, fn_phosphatidylcholine_6: $i > $i).
% 29.32/29.10  tff(decl_59918, type, fn_phosphatidylcholine_7: $i > $i).
% 29.32/29.10  tff(decl_59919, type, fn_phosphatidylcholine_8: $i > $i).
% 29.32/29.10  tff(decl_59920, type, fn_phosphatidylcholine_9: $i > $i).
% 29.32/29.10  tff(decl_59921, type, fn_phosphatidylcholine_10: $i > $i).
% 29.32/29.10  tff(decl_59922, type, fn_phosphatidylcholine_11: $i > $i).
% 29.32/29.10  tff(decl_59923, type, fn_phosphatidylcholine_12: $i > $i).
% 29.32/29.10  tff(decl_59924, type, fn_phosphatidylcholine_13: $i > $i).
% 29.32/29.10  tff(decl_59925, type, fn_phosphatidylcholine_14: $i > $i).
% 29.32/29.10  tff(decl_59926, type, fn_phosphatidylcholine_15: $i > $i).
% 29.32/29.10  tff(decl_59927, type, fn_phosphatidylcholine_16: $i > $i).
% 29.32/29.10  tff(decl_59928, type, fn_phosphatidylcholine_17: $i > $i).
% 29.32/29.10  tff(decl_59929, type, fn_phosphatidylcholine_18: $i > $i).
% 29.32/29.10  tff(decl_59930, type, fn_phosphatidylcholine_19: $i > $i).
% 29.32/29.10  tff(decl_59931, type, fn_phosphatidylcholine_20: $i > $i).
% 29.32/29.10  tff(decl_59932, type, fn_phosphatidylcholine_21: $i > $i).
% 29.32/29.10  tff(decl_59933, type, fn_phosphatidylcholine_22: $i > $i).
% 29.32/29.10  tff(decl_59934, type, fn_phosphatidylcholine_23: $i > $i).
% 29.32/29.10  tff(decl_59935, type, fn_phosphatidylcholine_24: $i > $i).
% 29.32/29.10  tff(decl_59936, type, fn_phospholipid_78: $i > $i).
% 29.32/29.10  tff(decl_59937, type, fn_phospholipid_76: $i > $i).
% 29.32/29.10  tff(decl_59938, type, fn_phospholipid_72: $i > $i).
% 29.32/29.10  tff(decl_59939, type, fn_phospholipid_15: $i > $i).
% 29.32/29.10  tff(decl_59940, type, fn_phospholipid_74: $i > $i).
% 29.32/29.10  tff(decl_59941, type, 'Phosphatidylinositol-Bisphosphate': $i).
% 29.32/29.10  tff(decl_59942, type, 'Type of phospholipid which is a component of certain biomembranes.': $i).
% 29.32/29.10  tff(decl_59943, type, 'phosphatidylinositol bisphosphate': $i).
% 29.32/29.10  tff(decl_59944, type, 'phosphatidylinositol-bisphosphate': $i).
% 29.32/29.10  tff(decl_59945, type, 'Phosphodiester-Bond': $i).
% 29.32/29.10  tff(decl_59946, type, 'A bond between two pentose sugars and a phosphate group.  These bonds link nucleotides together in RNA and DNA.': $i).
% 29.32/29.10  tff(decl_59947, type, 'phosphodiester bonds': $i).
% 29.32/29.10  tff(decl_59948, type, 'phosphodiester-bonds': $i).
% 29.32/29.10  tff(decl_59949, type, 'phosphodiester bond': $i).
% 29.32/29.10  tff(decl_59950, type, 'phosphodiester-bond': $i).
% 29.32/29.10  tff(decl_59951, type, fn_phosphodiester_bond_5: $i > $i).
% 29.32/29.10  tff(decl_59952, type, fn_phosphodiester_bond_8: $i > $i).
% 29.32/29.10  tff(decl_59953, type, fn_phosphodiester_bond_9: $i > $i).
% 29.32/29.10  tff(decl_59954, type, fn_phosphodiester_bond_10: $i > $i).
% 29.32/29.10  tff(decl_59955, type, fn_phosphodiester_bond_13: $i > $i).
% 29.32/29.10  tff(decl_59956, type, fn_phosphodiester_bond_19: $i > $i).
% 29.32/29.10  tff(decl_59957, type, fn_phosphodiester_bond_21: $i > $i).
% 29.32/29.10  tff(decl_59958, type, fn_phosphodiester_bond_24: $i > $i).
% 29.32/29.10  tff(decl_59959, type, fn_phosphodiester_bond_25: $i > $i).
% 29.32/29.10  tff(decl_59960, type, fn_phosphodiester_bond_35: $i > $i).
% 29.32/29.10  tff(decl_59961, type, fn_phosphodiester_bond_41: $i > $i).
% 29.32/29.10  tff(decl_59962, type, fn_phosphodiester_bond_45: $i > $i).
% 29.32/29.10  tff(decl_59963, type, fn_phosphodiester_bond_42: $i > $i).
% 29.32/29.10  tff(decl_59964, type, fn_phosphodiester_bond_43: $i > $i).
% 29.32/29.10  tff(decl_59965, type, 'Phosphodiesterase': $i).
% 29.32/29.10  tff(decl_59966, type, 'An enzyme that catalyzes the hydrolysis of a phosphodiester bond.': $i).
% 29.32/29.10  tff(decl_59967, type, 'Phosphoenolpyruvate': $i).
% 29.32/29.10  tff(decl_59968, type, 'In glycolysis, during energy payoff phase phosphoenolpyruvate is formed from 2-phosphoglycerate.': $i).
% 29.32/29.10  tff(decl_59969, type, pep: $i).
% 29.32/29.10  tff(decl_59970, type, phosphoenolpyruvate: $i).
% 29.32/29.10  tff(decl_59971, type, 'Phosphofructokinase': $i).
% 29.32/29.10  tff(decl_59972, type, 'Phosphofructokinase is a kinase enzyme that phosphorylates fructose 6-phosphate in glycolysis.': $i).
% 29.32/29.10  tff(decl_59973, type, phosphofructokinase: $i).
% 29.32/29.10  tff(decl_59974, type, fn_phosphofructokinase_1: $i > $i).
% 29.32/29.10  tff(decl_59975, type, fn_phosphofructokinase_2: $i > $i).
% 29.32/29.10  tff(decl_59976, type, fn_phosphofructokinase_3: $i > $i).
% 29.32/29.10  tff(decl_59977, type, fn_phosphofructokinase_5: $i > $i).
% 29.32/29.10  tff(decl_59978, type, fn_phosphofructokinase_12: $i > $i).
% 29.32/29.10  tff(decl_59979, type, fn_phosphofructokinase_13: $i > $i).
% 29.32/29.10  tff(decl_59980, type, fn_phosphofructokinase_14: $i > $i).
% 29.32/29.10  tff(decl_59981, type, fn_phosphofructokinase_15: $i > $i).
% 29.32/29.10  tff(decl_59982, type, fn_phosphofructokinase_16: $i > $i).
% 29.32/29.10  tff(decl_59983, type, fn_phosphofructokinase_20: $i > $i).
% 29.32/29.10  tff(decl_59984, type, fn_phosphofructokinase_21: $i > $i).
% 29.32/29.10  tff(decl_59985, type, fn_phosphofructokinase_22: $i > $i).
% 29.32/29.10  tff(decl_59986, type, fn_phosphofructokinase_23: $i > $i).
% 29.32/29.10  tff(decl_59987, type, fn_phosphofructokinase_25: $i > $i).
% 29.32/29.10  tff(decl_59988, type, fn_phosphofructokinase_26: $i > $i).
% 29.32/29.10  tff(decl_59989, type, fn_phosphofructokinase_29: $i > $i).
% 29.32/29.10  tff(decl_59990, type, fn_phosphofructokinase_30: $i > $i).
% 29.32/29.10  tff(decl_59991, type, fn_phosphofructokinase_31: $i > $i).
% 29.32/29.10  tff(decl_59992, type, fn_phosphofructokinase_32: $i > $i).
% 29.32/29.10  tff(decl_59993, type, fn_phosphofructokinase_33: $i > $i).
% 29.32/29.10  tff(decl_59994, type, fn_phosphofructokinase_34: $i > $i).
% 29.32/29.10  tff(decl_59995, type, fn_phosphofructokinase_35: $i > $i).
% 29.32/29.10  tff(decl_59996, type, fn_phosphofructokinase_36: $i > $i).
% 29.32/29.10  tff(decl_59997, type, fn_phosphofructokinase_37: $i > $i).
% 29.32/29.10  tff(decl_59998, type, fn_phosphofructokinase_38: $i > $i).
% 29.32/29.10  tff(decl_59999, type, fn_phosphofructokinase_39: $i > $i).
% 29.32/29.10  tff(decl_60000, type, fn_phosphofructokinase_40: $i > $i).
% 29.32/29.10  tff(decl_60001, type, fn_phosphofructokinase_41: $i > $i).
% 29.32/29.10  tff(decl_60002, type, fn_phosphofructokinase_42: $i > $i).
% 29.32/29.10  tff(decl_60003, type, fn_phosphofructokinase_43: $i > $i).
% 29.32/29.10  tff(decl_60004, type, fn_phosphofructokinase_44: $i > $i).
% 29.32/29.10  tff(decl_60005, type, fn_phosphofructokinase_45: $i > $i).
% 29.32/29.10  tff(decl_60006, type, fn_phosphofructokinase_46: $i > $i).
% 29.32/29.10  tff(decl_60007, type, fn_phosphofructokinase_47: $i > $i).
% 29.32/29.10  tff(decl_60008, type, fn_phosphofructokinase_48: $i > $i).
% 29.32/29.10  tff(decl_60009, type, fn_phosphofructokinase_49: $i > $i).
% 29.32/29.10  tff(decl_60010, type, fn_phosphofructokinase_50: $i > $i).
% 29.32/29.10  tff(decl_60011, type, fn_phosphofructokinase_9: $i > $i).
% 29.32/29.10  tff(decl_60012, type, fn_phosphofructokinase_8: $i > $i).
% 29.32/29.10  tff(decl_60013, type, fn_phosphofructokinase_11: $i > $i).
% 29.32/29.10  tff(decl_60014, type, fn_allosteric_enzyme_1: $i > $i).
% 29.32/29.10  tff(decl_60015, type, fn_phosphofructokinase_10: $i > $i).
% 29.32/29.10  tff(decl_60016, type, fn_allosteric_enzyme_2: $i > $i).
% 29.32/29.10  tff(decl_60017, type, fn_phosphofructokinase_7: $i > $i).
% 29.32/29.10  tff(decl_60018, type, fn_allosteric_enzyme_12: $i > $i).
% 29.32/29.10  tff(decl_60019, type, fn_phosphofructokinase_6: $i > $i).
% 29.32/29.10  tff(decl_60020, type, 'Phosphoglucoisomerase': $i).
% 29.32/29.10  tff(decl_60021, type, 'An enzyme which catalyzes the conversion of glucose-6-phosphate into fructose 6-phosphate in the second step of glycolysis.': $i).
% 29.32/29.10  tff(decl_60022, type, 'glucose 6 phosphate isomerase': $i).
% 29.32/29.10  tff(decl_60023, type, 'glucose-6-phosphate-isomerase': $i).
% 29.32/29.10  tff(decl_60024, type, 'phosphoglucose isomerase': $i).
% 29.32/29.10  tff(decl_60025, type, 'phosphoglucose-isomerase': $i).
% 29.32/29.10  tff(decl_60026, type, 'phosphohexose isomerase': $i).
% 29.32/29.10  tff(decl_60027, type, 'phosphohexose-isomerase': $i).
% 29.32/29.10  tff(decl_60028, type, phosphoglucoisomerase: $i).
% 29.32/29.10  tff(decl_60029, type, fn_phosphoglucoisomerase_1: $i > $i).
% 29.32/29.10  tff(decl_60030, type, fn_phosphoglucoisomerase_2: $i > $i).
% 29.32/29.10  tff(decl_60031, type, fn_phosphoglucoisomerase_3: $i > $i).
% 29.32/29.10  tff(decl_60032, type, fn_phosphoglucoisomerase_4: $i > $i).
% 29.32/29.10  tff(decl_60033, type, fn_phosphoglucoisomerase_5: $i > $i).
% 29.32/29.10  tff(decl_60034, type, fn_phosphoglucoisomerase_6: $i > $i).
% 29.32/29.10  tff(decl_60035, type, fn_phosphoglucoisomerase_7: $i > $i).
% 29.32/29.10  tff(decl_60036, type, fn_phosphoglucoisomerase_8: $i > $i).
% 29.32/29.10  tff(decl_60037, type, fn_phosphoglucoisomerase_9: $i > $i).
% 29.32/29.10  tff(decl_60038, type, fn_phosphoglucoisomerase_10: $i > $i).
% 29.32/29.10  tff(decl_60039, type, fn_phosphoglucoisomerase_11: $i > $i).
% 29.32/29.10  tff(decl_60040, type, fn_phosphoglucoisomerase_12: $i > $i).
% 29.32/29.10  tff(decl_60041, type, fn_phosphoglucoisomerase_13: $i > $i).
% 29.32/29.10  tff(decl_60042, type, fn_phosphoglucoisomerase_14: $i > $i).
% 29.32/29.10  tff(decl_60043, type, fn_phosphoglucoisomerase_15: $i > $i).
% 29.32/29.10  tff(decl_60044, type, fn_phosphoglucoisomerase_16: $i > $i).
% 29.32/29.10  tff(decl_60045, type, fn_phosphoglucoisomerase_17: $i > $i).
% 29.32/29.10  tff(decl_60046, type, fn_phosphoglucoisomerase_18: $i > $i).
% 29.32/29.10  tff(decl_60047, type, fn_phosphoglucoisomerase_19: $i > $i).
% 29.32/29.10  tff(decl_60048, type, fn_phosphoglucoisomerase_20: $i > $i).
% 29.32/29.10  tff(decl_60049, type, 'Phosphoglycerokinase': $i).
% 29.32/29.10  tff(decl_60050, type, 'The enzyme phosphoglycerokinase transfers a P from 1,3-diphoshoglyceric acid to a molecule of ADP to form ATP. This happens for each molecule of 1,3-diphoshoglyceric acid. The process yields two 3-phosphoglyceric acid molecules and two ATP': $i).
% 29.32/29.10  tff(decl_60051, type, 'phosphoglycerate kinase': $i).
% 29.32/29.10  tff(decl_60052, type, phosphoglycerokinase: $i).
% 29.32/29.10  tff(decl_60053, type, fn_phosphoglycerokinase_1: $i > $i).
% 29.32/29.10  tff(decl_60054, type, fn_phosphoglycerokinase_2: $i > $i).
% 29.32/29.10  tff(decl_60055, type, fn_phosphoglycerokinase_3: $i > $i).
% 29.32/29.10  tff(decl_60056, type, fn_phosphoglycerokinase_4: $i > $i).
% 29.32/29.10  tff(decl_60057, type, fn_phosphoglycerokinase_5: $i > $i).
% 29.32/29.10  tff(decl_60058, type, fn_phosphoglycerokinase_6: $i > $i).
% 29.32/29.10  tff(decl_60059, type, fn_phosphoglycerokinase_7: $i > $i).
% 29.32/29.10  tff(decl_60060, type, fn_phosphoglycerokinase_8: $i > $i).
% 29.32/29.10  tff(decl_60061, type, fn_phosphoglycerokinase_9: $i > $i).
% 29.32/29.10  tff(decl_60062, type, fn_phosphoglycerokinase_10: $i > $i).
% 29.32/29.10  tff(decl_60063, type, fn_phosphoglycerokinase_11: $i > $i).
% 29.32/29.10  tff(decl_60064, type, fn_phosphoglycerokinase_12: $i > $i).
% 29.32/29.10  tff(decl_60065, type, fn_phosphoglycerokinase_13: $i > $i).
% 29.32/29.10  tff(decl_60066, type, fn_phosphoglycerokinase_14: $i > $i).
% 29.32/29.10  tff(decl_60067, type, fn_phosphoglycerokinase_15: $i > $i).
% 29.32/29.10  tff(decl_60068, type, fn_phosphoglycerokinase_16: $i > $i).
% 29.32/29.10  tff(decl_60069, type, fn_phosphoglycerokinase_17: $i > $i).
% 29.32/29.10  tff(decl_60070, type, fn_phosphoglycerokinase_18: $i > $i).
% 29.32/29.10  tff(decl_60071, type, fn_phosphoglycerokinase_19: $i > $i).
% 29.32/29.10  tff(decl_60072, type, fn_phosphoglycerokinase_20: $i > $i).
% 29.32/29.10  tff(decl_60073, type, 'Phosphoglyceromutase': $i).
% 29.32/29.10  tff(decl_60074, type, 'The enzyme phosphoglyceromutase relocates the Phosphate group of 3-phosphoglyceric acid from the third carbon to the second carbon to form 2-phosphoglyceric acid.': $i).
% 29.32/29.10  tff(decl_60075, type, 'phosphoglycerate mutase': $i).
% 29.32/29.10  tff(decl_60076, type, phosphoglyceromutase: $i).
% 29.32/29.10  tff(decl_60077, type, 'Phospholipase-C': $i).
% 29.32/29.10  tff(decl_60078, type, 'An enzyme that cleaves lipid molecules just ahead of the phosphate group.': $i).
% 29.32/29.10  tff(decl_60079, type, plc: $i).
% 29.32/29.10  tff(decl_60080, type, 'phospholipase c': $i).
% 29.32/29.10  tff(decl_60081, type, 'phospholipase-c': $i).
% 29.32/29.10  tff(decl_60082, type, fn_phospholipase_c_1: $i > $i).
% 29.32/29.10  tff(decl_60083, type, fn_phospholipase_c_2: $i > $i).
% 29.32/29.10  tff(decl_60084, type, fn_phospholipase_c_3: $i > $i).
% 29.32/29.10  tff(decl_60085, type, fn_phospholipase_c_4: $i > $i).
% 29.32/29.10  tff(decl_60086, type, fn_phospholipase_c_6: $i > $i).
% 29.32/29.10  tff(decl_60087, type, fn_phospholipase_c_7: $i > $i).
% 29.32/29.10  tff(decl_60088, type, fn_phospholipase_c_10: $i > $i).
% 29.32/29.10  tff(decl_60089, type, fn_phospholipase_c_11: $i > $i).
% 29.32/29.10  tff(decl_60090, type, fn_phospholipase_c_12: $i > $i).
% 29.32/29.10  tff(decl_60091, type, fn_phospholipase_c_13: $i > $i).
% 29.32/29.10  tff(decl_60092, type, fn_phospholipase_c_14: $i > $i).
% 29.32/29.10  tff(decl_60093, type, fn_phospholipase_c_16: $i > $i).
% 29.32/29.10  tff(decl_60094, type, fn_phospholipase_c_17: $i > $i).
% 29.32/29.10  tff(decl_60095, type, fn_phospholipase_c_18: $i > $i).
% 29.32/29.10  tff(decl_60096, type, fn_phospholipase_c_20: $i > $i).
% 29.32/29.10  tff(decl_60097, type, 'Phospholipid': $i).
% 29.32/29.10  tff(decl_60098, type, 'Phospholipid is a class of lipid which has its primary function as a structural component of cell membranes': $i).
% 29.32/29.10  tff(decl_60099, type, phospholipid: $i).
% 29.32/29.10  tff(decl_60100, type, fn_phospholipid_1: $i > $i).
% 29.32/29.10  tff(decl_60101, type, fn_phospholipid_2: $i > $i).
% 29.32/29.10  tff(decl_60102, type, fn_phospholipid_4: $i > $i).
% 29.32/29.10  tff(decl_60103, type, fn_phospholipid_6: $i > $i).
% 29.32/29.10  tff(decl_60104, type, fn_phospholipid_14: $i > $i).
% 29.32/29.10  tff(decl_60105, type, fn_phospholipid_16: $i > $i).
% 29.32/29.10  tff(decl_60106, type, fn_phospholipid_17: $i > $i).
% 29.32/29.10  tff(decl_60107, type, fn_phospholipid_18: $i > $i).
% 29.32/29.10  tff(decl_60108, type, fn_phospholipid_19: $i > $i).
% 29.32/29.10  tff(decl_60109, type, fn_phospholipid_20: $i > $i).
% 29.32/29.10  tff(decl_60110, type, fn_phospholipid_22: $i > $i).
% 29.32/29.10  tff(decl_60111, type, fn_phospholipid_23: $i > $i).
% 29.32/29.10  tff(decl_60112, type, fn_phospholipid_24: $i > $i).
% 29.32/29.10  tff(decl_60113, type, fn_phospholipid_25: $i > $i).
% 29.32/29.10  tff(decl_60114, type, fn_phospholipid_26: $i > $i).
% 29.32/29.10  tff(decl_60115, type, fn_phospholipid_27: $i > $i).
% 29.32/29.10  tff(decl_60116, type, fn_phospholipid_28: $i > $i).
% 29.32/29.10  tff(decl_60117, type, fn_phospholipid_29: $i > $i).
% 29.32/29.10  tff(decl_60118, type, fn_phospholipid_30: $i > $i).
% 29.32/29.10  tff(decl_60119, type, fn_phospholipid_31: $i > $i).
% 29.32/29.10  tff(decl_60120, type, fn_phospholipid_32: $i > $i).
% 29.32/29.10  tff(decl_60121, type, fn_phospholipid_33: $i > $i).
% 29.32/29.10  tff(decl_60122, type, fn_phospholipid_34: $i > $i).
% 29.32/29.10  tff(decl_60123, type, fn_phospholipid_35: $i > $i).
% 29.32/29.10  tff(decl_60124, type, fn_phospholipid_36: $i > $i).
% 29.32/29.10  tff(decl_60125, type, fn_phospholipid_37: $i > $i).
% 29.32/29.10  tff(decl_60126, type, fn_phospholipid_38: $i > $i).
% 29.32/29.10  tff(decl_60127, type, fn_phospholipid_39: $i > $i).
% 29.32/29.10  tff(decl_60128, type, fn_phospholipid_40: $i > $i).
% 29.32/29.10  tff(decl_60129, type, fn_phospholipid_41: $i > $i).
% 29.32/29.10  tff(decl_60130, type, fn_phospholipid_42: $i > $i).
% 29.32/29.10  tff(decl_60131, type, fn_phospholipid_45: $i > $i).
% 29.32/29.10  tff(decl_60132, type, fn_phospholipid_46: $i > $i).
% 29.32/29.10  tff(decl_60133, type, fn_phospholipid_47: $i > $i).
% 29.32/29.10  tff(decl_60134, type, fn_phospholipid_48: $i > $i).
% 29.32/29.10  tff(decl_60135, type, fn_phospholipid_49: $i > $i).
% 29.32/29.10  tff(decl_60136, type, fn_phospholipid_50: $i > $i).
% 29.32/29.10  tff(decl_60137, type, fn_phospholipid_53: $i > $i).
% 29.32/29.10  tff(decl_60138, type, fn_phospholipid_54: $i > $i).
% 29.32/29.10  tff(decl_60139, type, fn_phospholipid_55: $i > $i).
% 29.32/29.10  tff(decl_60140, type, fn_phospholipid_56: $i > $i).
% 29.32/29.10  tff(decl_60141, type, fn_phospholipid_57: $i > $i).
% 29.32/29.10  tff(decl_60142, type, fn_phospholipid_58: $i > $i).
% 29.32/29.10  tff(decl_60143, type, fn_phospholipid_61: $i > $i).
% 29.32/29.10  tff(decl_60144, type, fn_phospholipid_62: $i > $i).
% 29.32/29.10  tff(decl_60145, type, fn_phospholipid_63: $i > $i).
% 29.32/29.10  tff(decl_60146, type, fn_phospholipid_64: $i > $i).
% 29.32/29.10  tff(decl_60147, type, fn_phospholipid_65: $i > $i).
% 29.32/29.10  tff(decl_60148, type, fn_phospholipid_66: $i > $i).
% 29.32/29.10  tff(decl_60149, type, fn_phospholipid_67: $i > $i).
% 29.32/29.10  tff(decl_60150, type, fn_phospholipid_68: $i > $i).
% 29.32/29.10  tff(decl_60151, type, fn_phospholipid_69: $i > $i).
% 29.32/29.10  tff(decl_60152, type, fn_phospholipid_73: $i > $i).
% 29.32/29.10  tff(decl_60153, type, fn_phospholipid_75: $i > $i).
% 29.32/29.10  tff(decl_60154, type, fn_phospholipid_77: $i > $i).
% 29.32/29.10  tff(decl_60155, type, fn_phospholipid_79: $i > $i).
% 29.32/29.10  tff(decl_60156, type, fn_phospholipid_82: $i > $i).
% 29.32/29.10  tff(decl_60157, type, fn_phospholipid_85: $i > $i).
% 29.32/29.10  tff(decl_60158, type, fn_phospholipid_86: $i > $i).
% 29.32/29.10  tff(decl_60159, type, fn_phospholipid_93: $i > $i).
% 29.32/29.10  tff(decl_60160, type, fn_phospholipid_95: $i > $i).
% 29.32/29.10  tff(decl_60161, type, fn_phospholipid_96: $i > $i).
% 29.32/29.10  tff(decl_60162, type, fn_phospholipid_100: $i > $i).
% 29.32/29.10  tff(decl_60163, type, fn_phospholipid_106: $i > $i).
% 29.32/29.10  tff(decl_60164, type, fn_phospholipid_107: $i > $i).
% 29.32/29.10  tff(decl_60165, type, fn_phospholipid_108: $i > $i).
% 29.32/29.10  tff(decl_60166, type, fn_phospholipid_109: $i > $i).
% 29.32/29.10  tff(decl_60167, type, fn_phospholipid_110: $i > $i).
% 29.32/29.10  tff(decl_60168, type, fn_phospholipid_111: $i > $i).
% 29.32/29.10  tff(decl_60169, type, fn_phospholipid_112: $i > $i).
% 29.32/29.10  tff(decl_60170, type, fn_phospholipid_113: $i > $i).
% 29.32/29.10  tff(decl_60171, type, fn_phospholipid_114: $i > $i).
% 29.32/29.10  tff(decl_60172, type, fn_phospholipid_115: $i > $i).
% 29.32/29.10  tff(decl_60173, type, fn_phospholipid_117: $i > $i).
% 29.32/29.10  tff(decl_60174, type, fn_phospholipid_118: $i > $i).
% 29.32/29.10  tff(decl_60175, type, fn_phospholipid_119: $i > $i).
% 29.32/29.10  tff(decl_60176, type, fn_phospholipid_120: $i > $i).
% 29.32/29.10  tff(decl_60177, type, fn_phospholipid_121: $i > $i).
% 29.32/29.10  tff(decl_60178, type, fn_phospholipid_122: $i > $i).
% 29.32/29.10  tff(decl_60179, type, fn_phospholipid_123: $i > $i).
% 29.32/29.10  tff(decl_60180, type, fn_phospholipid_124: $i > $i).
% 29.32/29.10  tff(decl_60181, type, fn_phospholipid_125: $i > $i).
% 29.32/29.10  tff(decl_60182, type, fn_phospholipid_126: $i > $i).
% 29.32/29.10  tff(decl_60183, type, fn_phospholipid_127: $i > $i).
% 29.32/29.10  tff(decl_60184, type, fn_phospholipid_128: $i > $i).
% 29.32/29.10  tff(decl_60185, type, fn_phospholipid_129: $i > $i).
% 29.32/29.10  tff(decl_60186, type, fn_phospholipid_130: $i > $i).
% 29.32/29.10  tff(decl_60187, type, fn_phospholipid_131: $i > $i).
% 29.32/29.10  tff(decl_60188, type, fn_phospholipid_132: $i > $i).
% 29.32/29.10  tff(decl_60189, type, fn_phospholipid_133: $i > $i).
% 29.32/29.10  tff(decl_60190, type, fn_phospholipid_134: $i > $i).
% 29.32/29.10  tff(decl_60191, type, 'HG3': $i).
% 29.32/29.10  tff(decl_60192, type, fn_phospholipid_12: $i > $i).
% 29.32/29.10  tff(decl_60193, type, fn_phospholipid_11: $i > $i).
% 29.32/29.10  tff(decl_60194, type, fn_phospholipid_10: $i > $i).
% 29.32/29.10  tff(decl_60195, type, fn_phospholipid_8: $i > $i).
% 29.32/29.10  tff(decl_60196, type, fn_phospholipid_51: $i > $i).
% 29.32/29.10  tff(decl_60197, type, fn_phospholipid_9: $i > $i).
% 29.32/29.10  tff(decl_60198, type, fn_phospholipid_21: $i > $i).
% 29.32/29.10  tff(decl_60199, type, 'Phospholipid-Bilayer': $i).
% 29.32/29.10  tff(decl_60200, type, 'The lipid bilayer is a thin membrane made of two layers of lipid molecules. These membranes are flat sheets that form a continuous barrier around cells. Phospholipid bilayer is the main component of biological membranes.': $i).
% 29.32/29.10  tff(decl_60201, type, 'lipid bilayer': $i).
% 29.32/29.10  tff(decl_60202, type, 'lipid-bilayer': $i).
% 29.32/29.10  tff(decl_60203, type, 'bilayer of phospholipids': $i).
% 29.32/29.10  tff(decl_60204, type, 'bilayer-of-phospholipids': $i).
% 29.32/29.10  tff(decl_60205, type, 'phospholipid bilayer': $i).
% 29.32/29.10  tff(decl_60206, type, 'phospholipid-bilayer': $i).
% 29.32/29.10  tff(decl_60207, type, fn_phospholipid_bilayer_4: $i > $i).
% 29.32/29.10  tff(decl_60208, type, fn_phospholipid_bilayer_5: $i > $i).
% 29.32/29.10  tff(decl_60209, type, fn_phospholipid_bilayer_8: $i > $i).
% 29.32/29.10  tff(decl_60210, type, fn_phospholipid_bilayer_9: $i > $i).
% 29.32/29.10  tff(decl_60211, type, fn_phospholipid_bilayer_12: $i > $i).
% 29.32/29.10  tff(decl_60212, type, fn_phospholipid_bilayer_13: $i > $i).
% 29.32/29.10  tff(decl_60213, type, fn_phospholipid_bilayer_16: $i > $i).
% 29.32/29.10  tff(decl_60214, type, fn_phospholipid_bilayer_17: $i > $i).
% 29.32/29.10  tff(decl_60215, type, fn_phospholipid_bilayer_18: $i > $i).
% 29.32/29.10  tff(decl_60216, type, fn_phospholipid_bilayer_20: $i > $i).
% 29.32/29.10  tff(decl_60217, type, fn_phospholipid_bilayer_21: $i > $i).
% 29.32/29.10  tff(decl_60218, type, fn_phospholipid_bilayer_22: $i > $i).
% 29.32/29.10  tff(decl_60219, type, fn_phospholipid_bilayer_27: $i > $i).
% 29.32/29.10  tff(decl_60220, type, fn_phospholipid_bilayer_28: $i > $i).
% 29.32/29.10  tff(decl_60221, type, fn_phospholipid_bilayer_29: $i > $i).
% 29.32/29.10  tff(decl_60222, type, fn_phospholipid_bilayer_30: $i > $i).
% 29.32/29.10  tff(decl_60223, type, fn_phospholipid_bilayer_31: $i > $i).
% 29.32/29.10  tff(decl_60224, type, fn_phospholipid_bilayer_40: $i > $i).
% 29.32/29.10  tff(decl_60225, type, fn_phospholipid_bilayer_41: $i > $i).
% 29.32/29.10  tff(decl_60226, type, fn_phospholipid_bilayer_42: $i > $i).
% 29.32/29.10  tff(decl_60227, type, fn_phospholipid_bilayer_43: $i > $i).
% 29.32/29.10  tff(decl_60228, type, fn_phospholipid_bilayer_45: $i > $i).
% 29.32/29.10  tff(decl_60229, type, fn_phospholipid_bilayer_47: $i > $i).
% 29.32/29.10  tff(decl_60230, type, fn_phospholipid_bilayer_48: $i > $i).
% 29.32/29.10  tff(decl_60231, type, fn_phospholipid_bilayer_49: $i > $i).
% 29.32/29.10  tff(decl_60232, type, fn_phospholipid_bilayer_50: $i > $i).
% 29.32/29.10  tff(decl_60233, type, fn_phospholipid_bilayer_51: $i > $i).
% 29.32/29.10  tff(decl_60234, type, fn_phospholipid_bilayer_52: $i > $i).
% 29.32/29.10  tff(decl_60235, type, fn_phospholipid_bilayer_53: $i > $i).
% 29.32/29.10  tff(decl_60236, type, fn_phospholipid_bilayer_54: $i > $i).
% 29.32/29.10  tff(decl_60237, type, fn_phospholipid_layer_13: $i > $i).
% 29.32/29.10  tff(decl_60238, type, fn_phospholipid_layer_10: $i > $i).
% 29.32/29.10  tff(decl_60239, type, phospholipid_layer_0: $i).
% 29.32/29.10  tff(decl_60240, type, fn_phospholipid_bilayer_11: $i > $i).
% 29.32/29.10  tff(decl_60241, type, fn_phospholipid_bilayer_10: $i > $i).
% 29.32/29.10  tff(decl_60242, type, fn_phospholipid_bilayer_15: $i > $i).
% 29.32/29.10  tff(decl_60243, type, fn_phospholipid_bilayer_14: $i > $i).
% 29.32/29.10  tff(decl_60244, type, 'Phospholipid-Layer': $i).
% 29.32/29.10  tff(decl_60245, type, 'A phospholipid layer that covers the surface of a cell and acts as a barrier between the inside of a cell and its environment is made up of phospholipids.': $i).
% 29.32/29.10  tff(decl_60246, type, 'layer of phospholipid': $i).
% 29.32/29.10  tff(decl_60247, type, 'phospholipid layer': $i).
% 29.32/29.10  tff(decl_60248, type, 'phospholipid-layer': $i).
% 29.32/29.10  tff(decl_60249, type, fn_phospholipid_layer_3: $i > $i).
% 29.32/29.10  tff(decl_60250, type, fn_phospholipid_layer_4: $i > $i).
% 29.32/29.10  tff(decl_60251, type, fn_phospholipid_layer_8: $i > $i).
% 29.32/29.10  tff(decl_60252, type, phospholipid_0: $i).
% 29.32/29.10  tff(decl_60253, type, 'Phosphorescence': $i).
% 29.32/29.10  tff(decl_60254, type, 'Light that continues to be emitted from atoms or molecules that absorbed energy from light after the light has been removed.': $i).
% 29.32/29.10  tff(decl_60255, type, phosphoresce: $i).
% 29.32/29.10  tff(decl_60256, type, phosphorescence: $i).
% 29.32/29.10  tff(decl_60257, type, fn_phosphorescence_1: $i > $i).
% 29.32/29.10  tff(decl_60258, type, fn_phosphorescence_2: $i > $i).
% 29.32/29.10  tff(decl_60259, type, fn_phosphorescence_3: $i > $i).
% 29.32/29.10  tff(decl_60260, type, fn_phosphorescence_5: $i > $i).
% 29.32/29.10  tff(decl_60261, type, fn_phosphorescence_8: $i > $i).
% 29.32/29.10  tff(decl_60262, type, phosphoric_acid_1: $i > $o).
% 29.32/29.10  tff(decl_60263, type, 'Phosphoric-Acid': $i).
% 29.32/29.10  tff(decl_60264, type, 'A mineral (inorganic) acid having the chemical formula H3PO4. Phosphoric acid molecules can combine with themselves to form a variety of compounds which are also referred to as phosphoric acids, but in a more general way.': $i).
% 29.32/29.10  tff(decl_60265, type, 'orthophosphoric acid': $i).
% 29.32/29.10  tff(decl_60266, type, 'orthophosphoric-acid': $i).
% 29.32/29.10  tff(decl_60267, type, 'phosphoric(v) acid': $i).
% 29.32/29.10  tff(decl_60268, type, 'phosphoric(v)-acid': $i).
% 29.32/29.10  tff(decl_60269, type, 'phosphoric acid': $i).
% 29.32/29.10  tff(decl_60270, type, 'phosphoric-acid': $i).
% 29.32/29.10  tff(decl_60271, type, fn_phosphoric_acid_1: $i > $i).
% 29.32/29.10  tff(decl_60272, type, fn_phosphoric_acid_4: $i > $i).
% 29.32/29.10  tff(decl_60273, type, fn_phosphoric_acid_5: $i > $i).
% 29.32/29.10  tff(decl_60274, type, fn_phosphoric_acid_6: $i > $i).
% 29.32/29.10  tff(decl_60275, type, fn_phosphoric_acid_7: $i > $i).
% 29.32/29.10  tff(decl_60276, type, fn_phosphoric_acid_8: $i > $i).
% 29.32/29.10  tff(decl_60277, type, fn_phosphoric_acid_9: $i > $i).
% 29.32/29.10  tff(decl_60278, type, fn_phosphoric_acid_10: $i > $i).
% 29.32/29.10  tff(decl_60279, type, fn_phosphoric_acid_11: $i > $i).
% 29.32/29.10  tff(decl_60280, type, fn_phosphoric_acid_2: $i > $i).
% 29.32/29.10  tff(decl_60281, type, fn_phosphoric_acid_3: $i > $i).
% 29.32/29.10  tff(decl_60282, type, 'Phosphorus': $i).
% 29.32/29.10  tff(decl_60283, type, 'An element with an atomic number of 15. Isotopes include P-31 and P-32.': $i).
% 29.32/29.10  tff(decl_60284, type, 'P': $i).
% 29.32/29.10  tff(decl_60285, type, phosphorus: $i).
% 29.32/29.10  tff(decl_60286, type, fn_phosphorus_1: $i > $i).
% 29.32/29.10  tff(decl_60287, type, fn_phosphorus_2: $i > $i).
% 29.32/29.10  tff(decl_60288, type, fn_phosphorus_3: $i > $i).
% 29.32/29.10  tff(decl_60289, type, fn_phosphorus_5: $i > $i).
% 29.32/29.10  tff(decl_60290, type, fn_phosphorus_6: $i > $i).
% 29.32/29.10  tff(decl_60291, type, fn_phosphorus_7: $i > $i).
% 29.32/29.10  tff(decl_60292, type, fn_phosphorus_8: $i > $i).
% 29.32/29.10  tff(decl_60293, type, "2.19": $i).
% 29.32/29.10  tff(decl_60294, type, "30.97": $i).
% 29.32/29.10  tff(decl_60295, type, fn_phosphorus_10: $i > $i).
% 29.32/29.10  tff(decl_60296, type, fn_phosphorus_9: $i > $i).
% 29.32/29.10  tff(decl_60297, type, fn_phosphorus_11: $i > $i).
% 29.32/29.10  tff(decl_60298, type, phosphorus_31_1: $i > $o).
% 29.32/29.10  tff(decl_60299, type, 'Phosphorus-31': $i).
% 29.32/29.10  tff(decl_60300, type, 'This is one of the Phosphorous isotopes that possess sixteen neutrons.': $i).
% 29.32/29.10  tff(decl_60301, type, 'phosphorus 31': $i).
% 29.32/29.10  tff(decl_60302, type, 'phosphorus-31': $i).
% 29.32/29.10  tff(decl_60303, type, phosphorus_isotope_1: $i > $o).
% 29.32/29.10  tff(decl_60304, type, fn_phosphorus_31_1: $i > $i).
% 29.32/29.10  tff(decl_60305, type, fn_phosphorus_31_3: $i > $i).
% 29.32/29.10  tff(decl_60306, type, fn_phosphorus_31_4: $i > $i).
% 29.32/29.10  tff(decl_60307, type, "30.974e0": $i).
% 29.32/29.10  tff(decl_60308, type, "31.0e0": $i).
% 29.32/29.10  tff(decl_60309, type, fn_phosphorus_isotope_2: $i > $i).
% 29.32/29.10  tff(decl_60310, type, fn_phosphorus_31_5: $i > $i).
% 29.32/29.10  tff(decl_60311, type, 'Phosphorus-32': $i).
% 29.32/29.10  tff(decl_60312, type, 'This is one of the Phosphorous isotopes that possess seventeen neutrons.': $i).
% 29.32/29.10  tff(decl_60313, type, 'phosphorus 32': $i).
% 29.32/29.10  tff(decl_60314, type, 'phosphorus-32': $i).
% 29.32/29.10  tff(decl_60315, type, fn_phosphorus_32_2: $i > $i).
% 29.32/29.10  tff(decl_60316, type, fn_phosphorus_32_4: $i > $i).
% 29.32/29.10  tff(decl_60317, type, fn_phosphorus_32_5: $i > $i).
% 29.32/29.10  tff(decl_60318, type, "32.0e0": $i).
% 29.32/29.10  tff(decl_60319, type, "31.974e0": $i).
% 29.32/29.10  tff(decl_60320, type, fn_phosphorus_32_3: $i > $i).
% 29.32/29.10  tff(decl_60321, type, phosphorus_cycle_1: $i > $o).
% 29.32/29.10  tff(decl_60322, type, 'Phosphorus-Cycle': $i).
% 29.32/29.10  tff(decl_60323, type, 'Local biogeochemical cycle which cycles phosphorus through the biotic and abiotic components of ecosystems.': $i).
% 29.32/29.10  tff(decl_60324, type, 'undergo the phosphorus cycle': $i).
% 29.32/29.10  tff(decl_60325, type, 'cycle of phosphorus': $i).
% 29.32/29.10  tff(decl_60326, type, 'phosphorus cycle': $i).
% 29.32/29.10  tff(decl_60327, type, 'phosphorus-cycle': $i).
% 29.32/29.10  tff(decl_60328, type, fn_phosphorus_cycle_1: $i > $i).
% 29.32/29.10  tff(decl_60329, type, fn_phosphorus_cycle_2: $i > $i).
% 29.32/29.10  tff(decl_60330, type, fn_phosphorus_cycle_3: $i > $i).
% 29.32/29.10  tff(decl_60331, type, fn_phosphorus_cycle_4: $i > $i).
% 29.32/29.10  tff(decl_60332, type, fn_phosphorus_cycle_5: $i > $i).
% 29.32/29.10  tff(decl_60333, type, weathering_1: $i > $o).
% 29.32/29.10  tff(decl_60334, type, fn_phosphorus_cycle_6: $i > $i).
% 29.32/29.10  tff(decl_60335, type, rock_1: $i > $o).
% 29.32/29.10  tff(decl_60336, type, fn_phosphorus_cycle_7: $i > $i).
% 29.32/29.10  tff(decl_60337, type, fn_phosphorus_cycle_8: $i > $i).
% 29.32/29.10  tff(decl_60338, type, fn_phosphorus_cycle_9: $i > $i).
% 29.32/29.10  tff(decl_60339, type, sedimentary_rock_1: $i > $o).
% 29.32/29.10  tff(decl_60340, type, fn_phosphorus_cycle_10: $i > $i).
% 29.32/29.10  tff(decl_60341, type, fn_phosphorus_cycle_11: $i > $i).
% 29.32/29.10  tff(decl_60342, type, fn_phosphorus_cycle_12: $i > $i).
% 29.32/29.10  tff(decl_60343, type, fn_phosphorus_cycle_17: $i > $i).
% 29.32/29.10  tff(decl_60344, type, fn_phosphorus_cycle_18: $i > $i).
% 29.32/29.10  tff(decl_60345, type, fn_phosphorus_cycle_19: $i > $i).
% 29.32/29.10  tff(decl_60346, type, fn_phosphorus_cycle_20: $i > $i).
% 29.32/29.10  tff(decl_60347, type, fn_phosphorus_cycle_21: $i > $i).
% 29.32/29.10  tff(decl_60348, type, fn_phosphorus_cycle_22: $i > $i).
% 29.32/29.10  tff(decl_60349, type, fn_phosphorus_cycle_23: $i > $i).
% 29.32/29.10  tff(decl_60350, type, fn_phosphorus_cycle_24: $i > $i).
% 29.32/29.10  tff(decl_60351, type, fn_phosphorus_cycle_25: $i > $i).
% 29.32/29.10  tff(decl_60352, type, fn_phosphorus_cycle_26: $i > $i).
% 29.32/29.10  tff(decl_60353, type, fn_phosphorus_cycle_27: $i > $i).
% 29.32/29.10  tff(decl_60354, type, fn_phosphorus_cycle_28: $i > $i).
% 29.32/29.10  tff(decl_60355, type, fn_phosphorus_cycle_29: $i > $i).
% 29.32/29.10  tff(decl_60356, type, fn_phosphorus_cycle_30: $i > $i).
% 29.32/29.10  tff(decl_60357, type, fn_phosphorus_cycle_31: $i > $i).
% 29.32/29.10  tff(decl_60358, type, fn_phosphorus_cycle_32: $i > $i).
% 29.32/29.10  tff(decl_60359, type, fn_phosphorus_cycle_33: $i > $i).
% 29.32/29.10  tff(decl_60360, type, fn_phosphorus_cycle_34: $i > $i).
% 29.32/29.10  tff(decl_60361, type, fn_phosphorus_cycle_35: $i > $i).
% 29.32/29.10  tff(decl_60362, type, fn_phosphorus_cycle_36: $i > $i).
% 29.32/29.10  tff(decl_60363, type, fn_phosphorus_cycle_37: $i > $i).
% 29.32/29.10  tff(decl_60364, type, fn_phosphorus_cycle_38: $i > $i).
% 29.32/29.10  tff(decl_60365, type, fn_phosphorus_cycle_39: $i > $i).
% 29.32/29.10  tff(decl_60366, type, fn_phosphorus_cycle_40: $i > $i).
% 29.32/29.10  tff(decl_60367, type, fn_phosphorus_cycle_41: $i > $i).
% 29.32/29.10  tff(decl_60368, type, fn_phosphorus_cycle_42: $i > $i).
% 29.32/29.10  tff(decl_60369, type, fn_phosphorus_cycle_43: $i > $i).
% 29.32/29.10  tff(decl_60370, type, fn_phosphorus_cycle_44: $i > $i).
% 29.32/29.10  tff(decl_60371, type, fn_phosphorus_cycle_45: $i > $i).
% 29.32/29.10  tff(decl_60372, type, fn_phosphorus_cycle_46: $i > $i).
% 29.32/29.10  tff(decl_60373, type, fn_phosphorus_cycle_47: $i > $i).
% 29.32/29.10  tff(decl_60374, type, fn_phosphorus_cycle_48: $i > $i).
% 29.32/29.10  tff(decl_60375, type, fn_phosphorus_cycle_49: $i > $i).
% 29.32/29.10  tff(decl_60376, type, fn_phosphorus_cycle_50: $i > $i).
% 29.32/29.10  tff(decl_60377, type, fn_phosphorus_cycle_51: $i > $i).
% 29.32/29.10  tff(decl_60378, type, fn_phosphorus_cycle_52: $i > $i).
% 29.32/29.10  tff(decl_60379, type, fn_phosphorus_cycle_53: $i > $i).
% 29.32/29.10  tff(decl_60380, type, fn_phosphorus_cycle_54: $i > $i).
% 29.32/29.10  tff(decl_60381, type, fn_phosphorus_cycle_55: $i > $i).
% 29.32/29.10  tff(decl_60382, type, fn_phosphorus_cycle_56: $i > $i).
% 29.32/29.10  tff(decl_60383, type, fn_phosphorus_cycle_57: $i > $i).
% 29.32/29.10  tff(decl_60384, type, fn_phosphorus_cycle_58: $i > $i).
% 29.32/29.10  tff(decl_60385, type, fn_phosphorus_cycle_59: $i > $i).
% 29.32/29.10  tff(decl_60386, type, fn_phosphorus_cycle_60: $i > $i).
% 29.32/29.10  tff(decl_60387, type, fn_phosphorus_cycle_61: $i > $i).
% 29.32/29.10  tff(decl_60388, type, fn_phosphorus_cycle_62: $i > $i).
% 29.32/29.10  tff(decl_60389, type, fn_phosphorus_cycle_63: $i > $i).
% 29.32/29.10  tff(decl_60390, type, fn_phosphorus_cycle_64: $i > $i).
% 29.32/29.10  tff(decl_60391, type, fn_phosphorus_cycle_65: $i > $i).
% 29.32/29.10  tff(decl_60392, type, fn_phosphorus_cycle_66: $i > $i).
% 29.32/29.10  tff(decl_60393, type, fn_phosphorus_cycle_67: $i > $i).
% 29.32/29.10  tff(decl_60394, type, sedimentation_1: $i > $o).
% 29.32/29.10  tff(decl_60395, type, fn_sedimentation_2: $i > $i).
% 29.32/29.10  tff(decl_60396, type, fn_precipitation_form_1: $i > $i).
% 29.32/29.10  tff(decl_60397, type, fn_sedimentation_1: $i > $i).
% 29.32/29.10  tff(decl_60398, type, fn_phosphorus_cycle_16: $i > $i).
% 29.32/29.10  tff(decl_60399, type, fn_phosphorus_cycle_15: $i > $i).
% 29.32/29.10  tff(decl_60400, type, fn_phosphorus_cycle_13: $i > $i).
% 29.32/29.10  tff(decl_60401, type, fn_phosphorus_cycle_14: $i > $i).
% 29.32/29.10  tff(decl_60402, type, 'Phosphorus-Isotope': $i).
% 29.32/29.10  tff(decl_60403, type, 'All the phosphorous isoptopes have 15 protons and 15 electrons. They differ in their neutron number.': $i).
% 29.32/29.10  tff(decl_60404, type, 'isotope of phosphorus': $i).
% 29.32/29.10  tff(decl_60405, type, 'phosphorus isotope': $i).
% 29.32/29.10  tff(decl_60406, type, 'phosphorus-isotope': $i).
% 29.32/29.10  tff(decl_60407, type, fn_phosphorus_isotope_3: $i > $i).
% 29.32/29.10  tff(decl_60408, type, fn_phosphorus_isotope_4: $i > $i).
% 29.32/29.10  tff(decl_60409, type, fn_phosphorus_isotope_5: $i > $i).
% 29.32/29.10  tff(decl_60410, type, fn_phosphorus_isotope_7: $i > $i).
% 29.32/29.10  tff(decl_60411, type, fn_phosphorus_isotope_8: $i > $i).
% 29.32/29.10  tff(decl_60412, type, fn_phosphorus_isotope_6: $i > $i).
% 29.32/29.10  tff(decl_60413, type, 'Phosphorylase': $i).
% 29.32/29.10  tff(decl_60414, type, 'Enzyme which catalyzes the addition of a phosphate group from inorganic phosphate to a protein or other molecule.': $i).
% 29.32/29.10  tff(decl_60415, type, phosphorylase: $i).
% 29.32/29.10  tff(decl_60416, type, 'Phosphorylase-Kinase': $i).
% 29.32/29.10  tff(decl_60417, type, 'Serine/Threonine kinase enzyme which phosphorylates and activates glycogen phosphorylase, initiating the process of glycogen breakdown.': $i).
% 29.32/29.10  tff(decl_60418, type, 'kinase of phosphorylase': $i).
% 29.32/29.10  tff(decl_60419, type, 'phosphorylase kinase': $i).
% 29.32/29.10  tff(decl_60420, type, 'phosphorylase-kinase': $i).
% 29.32/29.10  tff(decl_60421, type, phosphorylated_1: $i > $o).
% 29.32/29.10  tff(decl_60422, type, 'Phosphorylated': $i).
% 29.32/29.10  tff(decl_60423, type, 'Refers to a molecule that contains a covalently bonded phosphate group.': $i).
% 29.32/29.10  tff(decl_60424, type, phosphorylated: $i).
% 29.32/29.10  tff(decl_60425, type, phosphorylated_glutamic_acid_1: $i > $o).
% 29.32/29.10  tff(decl_60426, type, 'Phosphorylated-Glutamic-Acid': $i).
% 29.32/29.10  tff(decl_60427, type, 'A glutamic acid molecule possessing a phosphate group (added) is a phosphorylated glutamic acid.': $i).
% 29.32/29.10  tff(decl_60428, type, 'phosphorylated glutamic acid': $i).
% 29.32/29.10  tff(decl_60429, type, 'phosphorylated-glutamic-acid': $i).
% 29.32/29.10  tff(decl_60430, type, fn_phosphorylated_glutamic_acid_1: $i > $i).
% 29.32/29.10  tff(decl_60431, type, fn_phosphorylated_glutamic_acid_2: $i > $i).
% 29.32/29.10  tff(decl_60432, type, fn_phosphorylated_glutamic_acid_3: $i > $i).
% 29.32/29.10  tff(decl_60433, type, 'Phosphorylated-Intermediate': $i).
% 29.32/29.10  tff(decl_60434, type, 'A reaction intermediate formed by addition of a phosphate group is called a phosphorylated intermediate.': $i).
% 29.32/29.10  tff(decl_60435, type, 'phosphorylated molecule': $i).
% 29.32/29.10  tff(decl_60436, type, 'phosphorylated-molecule': $i).
% 29.32/29.10  tff(decl_60437, type, 'intermediate of phosphorylated': $i).
% 29.32/29.10  tff(decl_60438, type, 'phosphorylated intermediate': $i).
% 29.32/29.10  tff(decl_60439, type, 'phosphorylated-intermediate': $i).
% 29.32/29.10  tff(decl_60440, type, 'Phosphorylated-Kinase': $i).
% 29.32/29.10  tff(decl_60441, type, 'A kinase is an enzyme that transfers phosphate groups from ATP to a protein.   Often, these proteins are other kinases in a pathway.  A phosphorylated kinase is an activated kinase.': $i).
% 29.32/29.10  tff(decl_60442, type, 'kinase of phosphorylated': $i).
% 29.32/29.10  tff(decl_60443, type, 'phosphorylated kinase': $i).
% 29.32/29.10  tff(decl_60444, type, 'phosphorylated-kinase': $i).
% 29.32/29.10  tff(decl_60445, type, fn_phosphorylated_kinase_3: $i > $i).
% 29.32/29.10  tff(decl_60446, type, fn_phosphorylated_kinase_4: $i > $i).
% 29.32/29.10  tff(decl_60447, type, fn_phosphorylated_kinase_5: $i > $i).
% 29.32/29.10  tff(decl_60448, type, 'Phosphorylation': $i).
% 29.32/29.10  tff(decl_60449, type, 'Phosphorylation is the addition of a phosphate (PO4) group to a protein or other organic molecule. Phosphorylation activates or deactivates many protein enzymes, causing or preventing the mechanisms of diseases such as cancer and diabetes.': $i).
% 29.32/29.10  tff(decl_60450, type, phosphorylate: $i).
% 29.32/29.10  tff(decl_60451, type, phosphorylation: $i).
% 29.32/29.10  tff(decl_60452, type, 'Phosphorylation-Cascade': $i).
% 29.32/29.10  tff(decl_60453, type, 'A series of phosphorylation reactions is called a phosphorylation cascade.': $i).
% 29.32/29.10  tff(decl_60454, type, 'cascade of phosphorylation': $i).
% 29.32/29.10  tff(decl_60455, type, 'phosphorylation cascade': $i).
% 29.32/29.10  tff(decl_60456, type, 'phosphorylation-cascade': $i).
% 29.32/29.10  tff(decl_60457, type, phosphorylation_of_glutamic_acid_1: $i > $o).
% 29.32/29.10  tff(decl_60458, type, 'Phosphorylation-Of-Glutamic-Acid': $i).
% 29.32/29.10  tff(decl_60459, type, 'Phosphorylation of glutamic acid is the addition of a phosphate (PO4) group to glutamic acid.': $i).
% 29.32/29.10  tff(decl_60460, type, 'phosphorylation of glutamic acid': $i).
% 29.32/29.10  tff(decl_60461, type, 'phosphorylation-of-glutamic-acid': $i).
% 29.32/29.10  tff(decl_60462, type, fn_phosphorylation_of_glutamic_acid_2: $i > $i).
% 29.32/29.10  tff(decl_60463, type, fn_phosphorylation_of_glutamic_acid_3: $i > $i).
% 29.32/29.10  tff(decl_60464, type, fn_phosphorylation_of_glutamic_acid_4: $i > $i).
% 29.32/29.10  tff(decl_60465, type, fn_phosphorylation_of_glutamic_acid_5: $i > $i).
% 29.32/29.10  tff(decl_60466, type, fn_phosphorylation_of_glutamic_acid_1: $i > $i).
% 29.32/29.10  tff(decl_60467, type, 'Phosphorylation-Of-Protein': $i).
% 29.32/29.10  tff(decl_60468, type, 'A widespread cellular mechanism for activating proteins involved in signal transduction pathways.': $i).
% 29.32/29.10  tff(decl_60469, type, 'protein phosphorylation': $i).
% 29.32/29.10  tff(decl_60470, type, 'protein-phosphorylation': $i).
% 29.32/29.10  tff(decl_60471, type, 'phosphorylation of protein': $i).
% 29.32/29.10  tff(decl_60472, type, 'phosphorylation-of-protein': $i).
% 29.32/29.10  tff(decl_60473, type, fn_phosphorylation_of_protein_1: $i > $i).
% 29.32/29.10  tff(decl_60474, type, fn_phosphorylation_of_protein_2: $i > $i).
% 29.32/29.10  tff(decl_60475, type, phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_1: $i > $o).
% 29.32/29.10  tff(decl_60476, type, 'Phosphorylation-Of-Tyrosine-Kinase-Receptor-At-Tyrosine': $i).
% 29.32/29.10  tff(decl_60477, type, 'On receptor tyrosine kinase proteins, the tyrosine kinase adds a phosphate from an ATP molecule to a tyrosine on the receptor tyrosine kinase proteins activating the receptor and triggering the signal transduction pathway.': $i).
% 29.32/29.10  tff(decl_60478, type, 'phosphorylation of tyrosine kinase receptor at tyrosine': $i).
% 29.32/29.10  tff(decl_60479, type, 'phosphorylation-of-tyrosine-kinase-receptor-at-tyrosine': $i).
% 29.32/29.10  tff(decl_60480, type, fn_phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_1: $i > $i).
% 29.32/29.10  tff(decl_60481, type, fn_phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_2: $i > $i).
% 29.32/29.10  tff(decl_60482, type, fn_phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_3: $i > $i).
% 29.32/29.10  tff(decl_60483, type, fn_phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_4: $i > $i).
% 29.32/29.10  tff(decl_60484, type, fn_phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_5: $i > $i).
% 29.32/29.10  tff(decl_60485, type, fn_phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_6: $i > $i).
% 29.32/29.10  tff(decl_60486, type, fn_phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_7: $i > $i).
% 29.32/29.10  tff(decl_60487, type, fn_phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_8: $i > $i).
% 29.32/29.10  tff(decl_60488, type, fn_phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_9: $i > $i).
% 29.32/29.10  tff(decl_60489, type, fn_phosphorylation_of_tyrosine_kinase_receptor_at_tyrosine_10: $i > $i).
% 29.32/29.10  tff(decl_60490, type, fn_receptor_tyrosine_kinase_21: $i > $i).
% 29.32/29.10  tff(decl_60491, type, 'Photic-Zone': $i).
% 29.32/29.10  tff(decl_60492, type, 'The surface waters of an ocean or lake, where sufficient light penetrates for photsynthesis to occur.': $i).
% 29.32/29.10  tff(decl_60493, type, 'photic zone': $i).
% 29.32/29.10  tff(decl_60494, type, 'photic-zone': $i).
% 29.32/29.10  tff(decl_60495, type, 'Photoautotroph': $i).
% 29.32/29.10  tff(decl_60496, type, 'Phototrophs are the organisms (usually plants) that carry out photosynthesis to acquire energy. They use the energy from sunlight to convert carbon dioxide and water into organic materials to be utilized in cellular functions such as biosynthesis and respiration.': $i).
% 29.32/29.10  tff(decl_60497, type, 'photo autotroph': $i).
% 29.32/29.10  tff(decl_60498, type, phototroph: $i).
% 29.32/29.10  tff(decl_60499, type, 'photosynthetic cell': $i).
% 29.32/29.10  tff(decl_60500, type, photoautotroph: $i).
% 29.32/29.10  tff(decl_60501, type, fn_photoautotroph_3: $i > $i).
% 29.32/29.10  tff(decl_60502, type, fn_photoautotroph_4: $i > $i).
% 29.32/29.10  tff(decl_60503, type, fn_photoautotroph_6: $i > $i).
% 29.32/29.10  tff(decl_60504, type, fn_photoautotroph_7: $i > $i).
% 29.32/29.10  tff(decl_60505, type, fn_photoautotroph_8: $i > $i).
% 29.32/29.10  tff(decl_60506, type, fn_photoautotroph_9: $i > $i).
% 29.32/29.10  tff(decl_60507, type, fn_photoautotroph_10: $i > $i).
% 29.32/29.10  tff(decl_60508, type, fn_photoautotroph_11: $i > $i).
% 29.32/29.10  tff(decl_60509, type, fn_photoautotroph_12: $i > $i).
% 29.32/29.10  tff(decl_60510, type, fn_photoautotroph_13: $i > $i).
% 29.32/29.10  tff(decl_60511, type, fn_photoautotroph_14: $i > $i).
% 29.32/29.10  tff(decl_60512, type, fn_photoautotroph_15: $i > $i).
% 29.32/29.10  tff(decl_60513, type, fn_photoautotroph_16: $i > $i).
% 29.32/29.10  tff(decl_60514, type, fn_photoautotroph_20: $i > $i).
% 29.32/29.10  tff(decl_60515, type, fn_photoautotroph_21: $i > $i).
% 29.32/29.10  tff(decl_60516, type, fn_photoautotroph_22: $i > $i).
% 29.32/29.10  tff(decl_60517, type, fn_photoautotroph_23: $i > $i).
% 29.32/29.10  tff(decl_60518, type, fn_photoautotroph_24: $i > $i).
% 29.32/29.10  tff(decl_60519, type, fn_photoautotroph_26: $i > $i).
% 29.32/29.10  tff(decl_60520, type, fn_photoautotroph_27: $i > $i).
% 29.32/29.10  tff(decl_60521, type, fn_photoautotroph_28: $i > $i).
% 29.32/29.10  tff(decl_60522, type, fn_photoautotroph_29: $i > $i).
% 29.32/29.10  tff(decl_60523, type, fn_photoautotroph_30: $i > $i).
% 29.32/29.10  tff(decl_60524, type, fn_photoautotroph_31: $i > $i).
% 29.32/29.10  tff(decl_60525, type, fn_photoautotroph_32: $i > $i).
% 29.32/29.10  tff(decl_60526, type, fn_photoautotroph_33: $i > $i).
% 29.32/29.10  tff(decl_60527, type, fn_photoautotroph_34: $i > $i).
% 29.32/29.10  tff(decl_60528, type, fn_photoautotroph_39: $i > $i).
% 29.32/29.10  tff(decl_60529, type, fn_photoautotroph_35: $i > $i).
% 29.32/29.10  tff(decl_60530, type, fn_photoautotroph_36: $i > $i).
% 29.32/29.10  tff(decl_60531, type, fn_photoautotroph_38: $i > $i).
% 29.32/29.10  tff(decl_60532, type, fn_photoautotroph_1: $i > $i).
% 29.32/29.10  tff(decl_60533, type, fn_photoautotroph_37: $i > $i).
% 29.32/29.10  tff(decl_60534, type, fn_photoautotroph_2: $i > $i).
% 29.32/29.10  tff(decl_60535, type, photoelectric_tube_1: $i > $o).
% 29.32/29.10  tff(decl_60536, type, 'Photoelectric-Tube': $i).
% 29.32/29.10  tff(decl_60537, type, 'A photoelectric tube is a device which converts light to electricity.': $i).
% 29.32/29.10  tff(decl_60538, type, 'photoelectric tube': $i).
% 29.32/29.10  tff(decl_60539, type, 'photoelectric-tube': $i).
% 29.32/29.10  tff(decl_60540, type, 'Photoexcitation': $i).
% 29.32/29.10  tff(decl_60541, type, 'The process of electron excitation by photon absorption.': $i).
% 29.32/29.10  tff(decl_60542, type, photoexcitation: $i).
% 29.32/29.10  tff(decl_60543, type, 'Photographic-Film': $i).
% 29.32/29.10  tff(decl_60544, type, 'Photographic material consisting of a base of celluloid covered with a photographic emulsion; used to make negatives or transparencies that can be developed.': $i).
% 29.32/29.10  tff(decl_60545, type, 'photographic film': $i).
% 29.32/29.10  tff(decl_60546, type, 'photographic-film': $i).
% 29.32/29.10  tff(decl_60547, type, 'Photoheterotroph': $i).
% 29.32/29.10  tff(decl_60548, type, 'An organism that uses the energy from light to produce ATP but is unable to fix carbon and must obtain it from an organic source.': $i).
% 29.32/29.10  tff(decl_60549, type, fn_photoheterotroph_1: $i > $i).
% 29.32/29.10  tff(decl_60550, type, fn_photoheterotroph_2: $i > $i).
% 29.32/29.10  tff(decl_60551, type, photomorphogenesis_1: $i > $o).
% 29.32/29.10  tff(decl_60552, type, 'Photomorphogenesis': $i).
% 29.32/29.10  tff(decl_60553, type, 'In plants, the effects of light on development and morphology.': $i).
% 29.32/29.10  tff(decl_60554, type, photomorphogenesis: $i).
% 29.32/29.10  tff(decl_60555, type, 'Photon': $i).
% 29.32/29.10  tff(decl_60556, type, 'The elementary particle of electromagnetic radiation.': $i).
% 29.32/29.10  tff(decl_60557, type, 'particle of light': $i).
% 29.32/29.10  tff(decl_60558, type, 'discrete particle of light': $i).
% 29.32/29.10  tff(decl_60559, type, photon: $i).
% 29.32/29.10  tff(decl_60560, type, fn_photon_2: $i > $i).
% 29.32/29.10  tff(decl_60561, type, fn_photon_3: $i > $i).
% 29.32/29.10  tff(decl_60562, type, fn_photon_5: $i > $i).
% 29.32/29.10  tff(decl_60563, type, fn_photon_4: $i > $i).
% 29.32/29.10  tff(decl_60564, type, photoperiodic_control_of_flowering_1: $i > $o).
% 29.32/29.10  tff(decl_60565, type, 'Photoperiodic-Control-Of-Flowering': $i).
% 29.32/29.10  tff(decl_60566, type, 'A physiological response to photoperiod that determines when a plant flowers.': $i).
% 29.32/29.10  tff(decl_60567, type, 'photoperiodic control of flowering': $i).
% 29.32/29.10  tff(decl_60568, type, 'photoperiodic-control-of-flowering': $i).
% 29.32/29.10  tff(decl_60569, type, photoperiodism_1: $i > $o).
% 29.32/29.10  tff(decl_60570, type, 'Photoperiodism': $i).
% 29.32/29.10  tff(decl_60571, type, 'A physiological response to the relative lengths of night and day. Most organisms demonstrate some degree of photoperiodism.': $i).
% 29.32/29.10  tff(decl_60572, type, photoperiodism: $i).
% 29.32/29.10  tff(decl_60573, type, positive_feedback_1: $i > $o).
% 29.32/29.10  tff(decl_60574, type, thigmomorphogenesis_1: $i > $o).
% 29.32/29.10  tff(decl_60575, type, triple_response_1: $i > $o).
% 29.32/29.10  tff(decl_60576, type, fn_photoperiodism_1: $i > $i).
% 29.32/29.10  tff(decl_60577, type, 'Photoprotection': $i).
% 29.32/29.10  tff(decl_60578, type, 'Photoprotection is a group of mechanisms that nature has developed to minimize the damage that the human body suffers when exposed to UV radiation. This damage mostly occurs in the skin, but the rest of the body (especially the testicles) can be affected by the oxidative stress caused by UV light.': $i).
% 29.32/29.10  tff(decl_60579, type, photoprotection: $i).
% 29.32/29.10  tff(decl_60580, type, fn_photoprotection_1: $i > $i).
% 29.32/29.10  tff(decl_60581, type, fn_photoprotection_2: $i > $i).
% 29.32/29.10  tff(decl_60582, type, fn_photoprotection_3: $i > $i).
% 29.32/29.10  tff(decl_60583, type, photoprotection_in_eye_1: $i > $o).
% 29.32/29.10  tff(decl_60584, type, 'Photoprotection-In-Eye': $i).
% 29.32/29.10  tff(decl_60585, type, 'Photoprotection is a group of mechanisms that nature has developed to minimize the damage that the human body suffers when exposed to UV radiation.': $i).
% 29.32/29.10  tff(decl_60586, type, 'photoprotection in eye': $i).
% 29.32/29.10  tff(decl_60587, type, 'photoprotection-in-eye': $i).
% 29.32/29.10  tff(decl_60588, type, fn_photoprotection_in_eye_1: $i > $i).
% 29.32/29.10  tff(decl_60589, type, fn_photoprotection_in_eye_2: $i > $i).
% 29.32/29.10  tff(decl_60590, type, 'Photoprotection-In-Plant': $i).
% 29.32/29.10  tff(decl_60591, type, 'Plants are able to turn unwanted absorbed light into heat by altering the structure of one of the proteins in the membranes. This prevents the damage by dissipating the lethal excess radiation. This process is aided by special carotenoid molecule called zeaxanthin.': $i).
% 29.32/29.10  tff(decl_60592, type, photoprotect: $i).
% 29.32/29.10  tff(decl_60593, type, 'photoprotection in plant': $i).
% 29.32/29.10  tff(decl_60594, type, 'photoprotection-in-plant': $i).
% 29.32/29.10  tff(decl_60595, type, fn_photoprotection_in_plant_2: $i > $i).
% 29.32/29.10  tff(decl_60596, type, fn_photoprotection_in_plant_3: $i > $i).
% 29.32/29.10  tff(decl_60597, type, fn_photoprotection_in_plant_4: $i > $i).
% 29.32/29.10  tff(decl_60598, type, fn_photoprotection_in_plant_5: $i > $i).
% 29.32/29.10  tff(decl_60599, type, fn_photoprotection_in_plant_6: $i > $i).
% 29.32/29.10  tff(decl_60600, type, fn_photoprotection_in_plant_7: $i > $i).
% 29.32/29.10  tff(decl_60601, type, fn_photoprotection_in_plant_8: $i > $i).
% 29.32/29.10  tff(decl_60602, type, fn_photoprotection_in_plant_9: $i > $i).
% 29.32/29.10  tff(decl_60603, type, fn_photoprotection_in_plant_10: $i > $i).
% 29.32/29.10  tff(decl_60604, type, fn_photoprotection_in_plant_11: $i > $i).
% 29.32/29.10  tff(decl_60605, type, 'Photoreceptor': $i).
% 29.32/29.10  tff(decl_60606, type, 'A sensory receptor that detects visible light.': $i).
% 29.32/29.10  tff(decl_60607, type, photoreceptor: $i).
% 29.32/29.10  tff(decl_60608, type, 'Photorespiration': $i).
% 29.32/29.10  tff(decl_60609, type, 'When CO2 concentration become low in C3 plants, the enzyme rubisco adds O2 as a ligand instead of CO2. The result of photorespiration includes a two-carbon compound that leaves the chloroplast and is recycled by a peroxisome and a mitochondrion, which requires energy. Photorespiration reduces the efficiency of photosynthesis since it uses ATP and does not generate any sugars.': $i).
% 29.32/29.10  tff(decl_60610, type, photorespiration: $i).
% 29.32/29.10  tff(decl_60611, type, fn_photorespiration_1: $i > $i).
% 29.32/29.10  tff(decl_60612, type, fn_photorespiration_5: $i > $i).
% 29.32/29.10  tff(decl_60613, type, fn_photorespiration_6: $i > $i).
% 29.32/29.10  tff(decl_60614, type, fn_photorespiration_7: $i > $i).
% 29.32/29.10  tff(decl_60615, type, fn_photorespiration_8: $i > $i).
% 29.32/29.10  tff(decl_60616, type, fn_photorespiration_10: $i > $i).
% 29.32/29.10  tff(decl_60617, type, fn_photorespiration_11: $i > $i).
% 29.32/29.10  tff(decl_60618, type, fn_photorespiration_12: $i > $i).
% 29.32/29.10  tff(decl_60619, type, fn_photorespiration_13: $i > $i).
% 29.32/29.10  tff(decl_60620, type, fn_photorespiration_14: $i > $i).
% 29.32/29.10  tff(decl_60621, type, fn_photorespiration_15: $i > $i).
% 29.32/29.10  tff(decl_60622, type, serine_1: $i > $o).
% 29.32/29.10  tff(decl_60623, type, fn_photorespiration_16: $i > $i).
% 29.32/29.10  tff(decl_60624, type, fn_photorespiration_17: $i > $i).
% 29.32/29.10  tff(decl_60625, type, fn_photorespiration_18: $i > $i).
% 29.32/29.10  tff(decl_60626, type, fn_photorespiration_19: $i > $i).
% 29.32/29.10  tff(decl_60627, type, fn_photorespiration_22: $i > $i).
% 29.32/29.10  tff(decl_60628, type, fn_photorespiration_24: $i > $i).
% 29.32/29.10  tff(decl_60629, type, fn_photorespiration_25: $i > $i).
% 29.32/29.10  tff(decl_60630, type, fn_photorespiration_26: $i > $i).
% 29.32/29.10  tff(decl_60631, type, fn_photorespiration_27: $i > $i).
% 29.32/29.10  tff(decl_60632, type, fn_photorespiration_28: $i > $i).
% 29.32/29.10  tff(decl_60633, type, fn_photorespiration_29: $i > $i).
% 29.32/29.10  tff(decl_60634, type, fn_photorespiration_30: $i > $i).
% 29.32/29.10  tff(decl_60635, type, fn_photorespiration_31: $i > $i).
% 29.32/29.10  tff(decl_60636, type, fn_photorespiration_32: $i > $i).
% 29.32/29.10  tff(decl_60637, type, fn_photorespiration_33: $i > $i).
% 29.32/29.10  tff(decl_60638, type, fn_photorespiration_34: $i > $i).
% 29.32/29.10  tff(decl_60639, type, fn_photorespiration_35: $i > $i).
% 29.32/29.10  tff(decl_60640, type, fn_photorespiration_36: $i > $i).
% 29.32/29.10  tff(decl_60641, type, fn_photorespiration_37: $i > $i).
% 29.32/29.10  tff(decl_60642, type, fn_photorespiration_38: $i > $i).
% 29.32/29.10  tff(decl_60643, type, fn_photorespiration_39: $i > $i).
% 29.32/29.10  tff(decl_60644, type, fn_photorespiration_41: $i > $i).
% 29.32/29.10  tff(decl_60645, type, fn_photorespiration_42: $i > $i).
% 29.32/29.10  tff(decl_60646, type, fn_photorespiration_43: $i > $i).
% 29.32/29.10  tff(decl_60647, type, fn_photorespiration_44: $i > $i).
% 29.32/29.10  tff(decl_60648, type, fn_photorespiration_45: $i > $i).
% 29.32/29.10  tff(decl_60649, type, fn_photorespiration_46: $i > $i).
% 29.32/29.10  tff(decl_60650, type, fn_photorespiration_47: $i > $i).
% 29.32/29.10  tff(decl_60651, type, fn_photorespiration_48: $i > $i).
% 29.32/29.10  tff(decl_60652, type, fn_photorespiration_49: $i > $i).
% 29.32/29.10  tff(decl_60653, type, fn_photorespiration_50: $i > $i).
% 29.32/29.10  tff(decl_60654, type, fn_photorespiration_51: $i > $i).
% 29.32/29.10  tff(decl_60655, type, fn_photorespiration_52: $i > $i).
% 29.32/29.10  tff(decl_60656, type, fn_photorespiration_53: $i > $i).
% 29.32/29.10  tff(decl_60657, type, fn_photorespiration_54: $i > $i).
% 29.32/29.10  tff(decl_60658, type, fn_photorespiration_55: $i > $i).
% 29.32/29.10  tff(decl_60659, type, fn_photorespiration_56: $i > $i).
% 29.32/29.10  tff(decl_60660, type, fn_photorespiration_58: $i > $i).
% 29.32/29.10  tff(decl_60661, type, fn_photorespiration_59: $i > $i).
% 29.32/29.10  tff(decl_60662, type, fn_photorespiration_60: $i > $i).
% 29.32/29.10  tff(decl_60663, type, fn_photorespiration_61: $i > $i).
% 29.32/29.10  tff(decl_60664, type, fn_photorespiration_62: $i > $i).
% 29.32/29.10  tff(decl_60665, type, fn_photorespiration_63: $i > $i).
% 29.32/29.10  tff(decl_60666, type, fn_photorespiration_64: $i > $i).
% 29.32/29.10  tff(decl_60667, type, fn_photorespiration_65: $i > $i).
% 29.32/29.10  tff(decl_60668, type, fn_photorespiration_66: $i > $i).
% 29.32/29.10  tff(decl_60669, type, fn_photorespiration_67: $i > $i).
% 29.32/29.10  tff(decl_60670, type, fn_photorespiration_68: $i > $i).
% 29.32/29.10  tff(decl_60671, type, fn_photorespiration_69: $i > $i).
% 29.32/29.10  tff(decl_60672, type, fn_photorespiration_70: $i > $i).
% 29.32/29.10  tff(decl_60673, type, fn_photorespiration_71: $i > $i).
% 29.32/29.10  tff(decl_60674, type, fn_photorespiration_72: $i > $i).
% 29.32/29.10  tff(decl_60675, type, fn_photorespiration_73: $i > $i).
% 29.32/29.10  tff(decl_60676, type, fn_photorespiration_74: $i > $i).
% 29.32/29.10  tff(decl_60677, type, fn_photorespiration_75: $i > $i).
% 29.32/29.10  tff(decl_60678, type, fn_photorespiration_76: $i > $i).
% 29.32/29.10  tff(decl_60679, type, fn_photorespiration_77: $i > $i).
% 29.32/29.10  tff(decl_60680, type, fn_photorespiration_78: $i > $i).
% 29.32/29.10  tff(decl_60681, type, fn_mitochondrion_17: $i > $i).
% 29.32/29.10  tff(decl_60682, type, fn_peroxisome_5: $i > $i).
% 29.32/29.10  tff(decl_60683, type, fn_stroma_2: $i > $i).
% 29.32/29.10  tff(decl_60684, type, fn_photorespiration_23: $i > $i).
% 29.32/29.10  tff(decl_60685, type, fn_photorespiration_21: $i > $i).
% 29.32/29.10  tff(decl_60686, type, fn_photorespiration_20: $i > $i).
% 29.32/29.10  tff(decl_60687, type, 'Photosynthesis': $i).
% 29.32/29.10  tff(decl_60688, type, 'The conversion of light energy to chemical energy; occurs in plants, algae, and certain prokaryotes.': $i).
% 29.32/29.10  tff(decl_60689, type, 'Photosynthesis is a process where solar energy is converted to chemical energy by absorbing sunlight and using it to drive the synthesis of organic compounds from carbon dioxide and water.': $i).
% 29.32/29.10  tff(decl_60690, type, photosynthesize: $i).
% 29.32/29.10  tff(decl_60691, type, photosynthesis: $i).
% 29.32/29.10  tff(decl_60692, type, fn_photosynthesis_2: $i > $i).
% 29.32/29.10  tff(decl_60693, type, fn_photosynthesis_7: $i > $i).
% 29.32/29.10  tff(decl_60694, type, fn_photosynthesis_8: $i > $i).
% 29.32/29.10  tff(decl_60695, type, fn_photosynthesis_9: $i > $i).
% 29.32/29.10  tff(decl_60696, type, fn_photosynthesis_10: $i > $i).
% 29.32/29.10  tff(decl_60697, type, fn_photosynthesis_20: $i > $i).
% 29.32/29.10  tff(decl_60698, type, fn_photosynthesis_21: $i > $i).
% 29.32/29.10  tff(decl_60699, type, fn_photosynthesis_22: $i > $i).
% 29.32/29.10  tff(decl_60700, type, fn_photosynthesis_23: $i > $i).
% 29.32/29.10  tff(decl_60701, type, fn_photosynthesis_26: $i > $i).
% 29.32/29.10  tff(decl_60702, type, fn_photosynthesis_39: $i > $i).
% 29.32/29.10  tff(decl_60703, type, fn_photosynthesis_45: $i > $i).
% 29.32/29.10  tff(decl_60704, type, fn_photosynthesis_48: $i > $i).
% 29.32/29.10  tff(decl_60705, type, fn_photosynthesis_63: $i > $i).
% 29.32/29.10  tff(decl_60706, type, fn_photosynthesis_76: $i > $i).
% 29.32/29.10  tff(decl_60707, type, fn_photosynthesis_77: $i > $i).
% 29.32/29.10  tff(decl_60708, type, fn_photosynthesis_78: $i > $i).
% 29.32/29.10  tff(decl_60709, type, fn_photosynthesis_79: $i > $i).
% 29.32/29.10  tff(decl_60710, type, fn_photosynthesis_80: $i > $i).
% 29.32/29.10  tff(decl_60711, type, fn_photosynthesis_81: $i > $i).
% 29.32/29.10  tff(decl_60712, type, fn_photosynthesis_82: $i > $i).
% 29.32/29.10  tff(decl_60713, type, fn_photosynthesis_83: $i > $i).
% 29.32/29.10  tff(decl_60714, type, fn_photosynthesis_84: $i > $i).
% 29.32/29.10  tff(decl_60715, type, fn_photosynthesis_85: $i > $i).
% 29.32/29.10  tff(decl_60716, type, fn_photosynthesis_86: $i > $i).
% 29.32/29.10  tff(decl_60717, type, fn_photosynthesis_87: $i > $i).
% 29.32/29.10  tff(decl_60718, type, fn_photosynthesis_88: $i > $i).
% 29.32/29.10  tff(decl_60719, type, fn_photosynthesis_89: $i > $i).
% 29.32/29.10  tff(decl_60720, type, fn_photosynthesis_106: $i > $i).
% 29.32/29.10  tff(decl_60721, type, fn_photosystem_i_4: $i > $i).
% 29.32/29.10  tff(decl_60722, type, fn_photosystem_i_3: $i > $i).
% 29.32/29.10  tff(decl_60723, type, fn_photosystem_i_12: $i > $i).
% 29.32/29.10  tff(decl_60724, type, fn_photosystem_i_5: $i > $i).
% 29.32/29.10  tff(decl_60725, type, fn_photosystem_i_2: $i > $i).
% 29.32/29.10  tff(decl_60726, type, fn_photosystem_i_1: $i > $i).
% 29.32/29.10  tff(decl_60727, type, fn_photosystem_i_15: $i > $i).
% 29.32/29.10  tff(decl_60728, type, fn_photosystem_i_13: $i > $i).
% 29.32/29.10  tff(decl_60729, type, fn_photosystem_i_19: $i > $i).
% 29.32/29.10  tff(decl_60730, type, fn_photosystem_i_14: $i > $i).
% 29.32/29.10  tff(decl_60731, type, fn_photosystem_i_20: $i > $i).
% 29.32/29.10  tff(decl_60732, type, fn_photosystem_i_11: $i > $i).
% 29.32/29.10  tff(decl_60733, type, fn_photosystem_i_16: $i > $i).
% 29.32/29.10  tff(decl_60734, type, "686.0e0": $i).
% 29.32/29.10  tff(decl_60735, type, fn_photosynthesis_49: $i > $i).
% 29.32/29.10  tff(decl_60736, type, fn_photosynthesis_13: $i > $i).
% 29.32/29.10  tff(decl_60737, type, fn_photosynthesis_12: $i > $i).
% 29.32/29.10  tff(decl_60738, type, fn_photosynthesis_15: $i > $i).
% 29.32/29.10  tff(decl_60739, type, fn_photosynthesis_14: $i > $i).
% 29.32/29.10  tff(decl_60740, type, fn_photosynthesis_109: $i > $i).
% 29.32/29.10  tff(decl_60741, type, fn_photosynthesis_110: $i > $i).
% 29.32/29.10  tff(decl_60742, type, 'Photosynthetic-Pigment': $i).
% 29.32/29.10  tff(decl_60743, type, 'A molecule that absorbs certain wavelengths of light and reflects others. The energy from the absorbed light is used in the light-dependent reactions of photosynthesis.': $i).
% 29.32/29.10  tff(decl_60744, type, 'Photosynthetic-Prokaryote': $i).
% 29.32/29.10  tff(decl_60745, type, 'A prokaryote which undergoes photosynthesis.': $i).
% 29.32/29.10  tff(decl_60746, type, 'photosynthetic bacterium': $i).
% 29.32/29.10  tff(decl_60747, type, 'photosynthetic-bacterium': $i).
% 29.32/29.10  tff(decl_60748, type, 'photosynthetic bacteria': $i).
% 29.32/29.10  tff(decl_60749, type, 'photosynthetic-bacteria': $i).
% 29.32/29.10  tff(decl_60750, type, 'photosynthetic prokaryote': $i).
% 29.32/29.10  tff(decl_60751, type, 'photosynthetic-prokaryote': $i).
% 29.32/29.10  tff(decl_60752, type, fn_photosynthetic_prokaryote_7: $i > $i).
% 29.32/29.10  tff(decl_60753, type, fn_photosynthetic_prokaryote_13: $i > $i).
% 29.32/29.10  tff(decl_60754, type, fn_photosynthetic_prokaryote_15: $i > $i).
% 29.32/29.10  tff(decl_60755, type, fn_photosynthetic_prokaryote_16: $i > $i).
% 29.32/29.10  tff(decl_60756, type, fn_photosynthetic_prokaryote_17: $i > $i).
% 29.32/29.10  tff(decl_60757, type, fn_photosynthetic_prokaryote_18: $i > $i).
% 29.32/29.10  tff(decl_60758, type, fn_photosynthetic_prokaryote_19: $i > $i).
% 29.32/29.10  tff(decl_60759, type, fn_photosynthetic_prokaryote_20: $i > $i).
% 29.32/29.10  tff(decl_60760, type, fn_photosynthetic_prokaryote_21: $i > $i).
% 29.32/29.10  tff(decl_60761, type, fn_photosynthetic_prokaryote_22: $i > $i).
% 29.32/29.10  tff(decl_60762, type, fn_photosynthetic_prokaryote_23: $i > $i).
% 29.32/29.10  tff(decl_60763, type, fn_prokaryote_4: $i > $i).
% 29.32/29.10  tff(decl_60764, type, fn_prokaryote_5: $i > $i).
% 29.32/29.10  tff(decl_60765, type, fn_prokaryote_11: $i > $i).
% 29.32/29.10  tff(decl_60766, type, 'Photosystem': $i).
% 29.32/29.10  tff(decl_60767, type, 'Photosystems are functional and structural units of protein complexes involved in photosynthesis that together carry out the primary photochemistry of photosynthesis: the absorption of light and the transfer of energy and electrons. They are found in the thylakoid membranes of plants, algae and cyanobacteria (in plants and algae these are located in the chloroplasts), or in the cytoplasmic membrane of photosynthetic bacteria.': $i).
% 29.32/29.10  tff(decl_60768, type, 'group of photosynthetic pigments at thylakoid membrane of chloroplast': $i).
% 29.32/29.10  tff(decl_60769, type, photosystem: $i).
% 29.32/29.10  tff(decl_60770, type, fn_photosystem_1: $i > $i).
% 29.32/29.10  tff(decl_60771, type, light_harvesting_complex_0: $i).
% 29.32/29.10  tff(decl_60772, type, 'Photosystem-I': $i).
% 29.32/29.10  tff(decl_60773, type, 'An organization of chlorophyll and other small organic molecules and proteins located in the thylakoid membrane of a chloroplast. Photosystem-I is the second of two photosystems which participate in the light reactions of photosynthesis. At the center of each photosystem is a special molecule of chlorophyll a surrounded by several light-harvesting complexes. The form of chlorophyll a location in photosystem-I is called P700 because it most efficiently absorbs light energy with a wavelength of 700nm.': $i).
% 29.32/29.10  tff(decl_60774, type, 'plastocyanin ferredoxin oxidoreductase': $i).
% 29.32/29.10  tff(decl_60775, type, 'plastocyanin-ferredoxin-oxidoreductase': $i).
% 29.32/29.10  tff(decl_60776, type, 'ps i': $i).
% 29.32/29.10  tff(decl_60777, type, 'photosystem i': $i).
% 29.32/29.10  tff(decl_60778, type, 'photosystem-i': $i).
% 29.32/29.10  tff(decl_60779, type, fn_photosystem_i_6: $i > $i).
% 29.32/29.10  tff(decl_60780, type, fn_photosystem_i_7: $i > $i).
% 29.32/29.10  tff(decl_60781, type, fn_photosystem_i_8: $i > $i).
% 29.32/29.10  tff(decl_60782, type, fn_photosystem_i_9: $i > $i).
% 29.32/29.10  tff(decl_60783, type, fn_photosystem_i_17: $i > $i).
% 29.32/29.10  tff(decl_60784, type, fn_photosystem_i_18: $i > $i).
% 29.32/29.10  tff(decl_60785, type, 'Photosystem-II': $i).
% 29.32/29.10  tff(decl_60786, type, 'Photosystem II (or water-plastoquinone oxidoreductase) is the first protein complex in the light-dependent reactions. It is located in the thylakoid membrane of plants, algae, and cyanobacteria.': $i).
% 29.32/29.10  tff(decl_60787, type, 'water plastoquinone oxidoreductase': $i).
% 29.32/29.10  tff(decl_60788, type, 'water-plastoquinone-oxidoreductase': $i).
% 29.32/29.10  tff(decl_60789, type, 'ps ii': $i).
% 29.32/29.10  tff(decl_60790, type, 'photosystem ii': $i).
% 29.32/29.10  tff(decl_60791, type, 'photosystem-ii': $i).
% 29.32/29.10  tff(decl_60792, type, fn_photosystem_ii_1: $i > $i).
% 29.32/29.10  tff(decl_60793, type, fn_photosystem_ii_2: $i > $i).
% 29.32/29.10  tff(decl_60794, type, fn_photosystem_ii_6: $i > $i).
% 29.32/29.10  tff(decl_60795, type, fn_photosystem_ii_7: $i > $i).
% 29.32/29.10  tff(decl_60796, type, fn_photosystem_ii_8: $i > $i).
% 29.32/29.10  tff(decl_60797, type, fn_photosystem_ii_12: $i > $i).
% 29.32/29.10  tff(decl_60798, type, fn_photosystem_ii_13: $i > $i).
% 29.32/29.10  tff(decl_60799, type, fn_photosystem_ii_14: $i > $i).
% 29.32/29.10  tff(decl_60800, type, fn_photosystem_ii_15: $i > $i).
% 29.32/29.10  tff(decl_60801, type, fn_photosystem_ii_16: $i > $i).
% 29.32/29.10  tff(decl_60802, type, fn_photosystem_ii_19: $i > $i).
% 29.32/29.10  tff(decl_60803, type, phototropin_1: $i > $o).
% 29.32/29.10  tff(decl_60804, type, 'Phototropin': $i).
% 29.32/29.10  tff(decl_60805, type, 'Proteins that regulate the phototropism responses in plants.': $i).
% 29.32/29.10  tff(decl_60806, type, phototropin: $i).
% 29.32/29.10  tff(decl_60807, type, 'Phototropism': $i).
% 29.32/29.10  tff(decl_60808, type, 'Growth of a plant shoot toward or away from light.': $i).
% 29.32/29.10  tff(decl_60809, type, phototropism: $i).
% 29.32/29.10  tff(decl_60810, type, 'Phragmoplast': $i).
% 29.32/29.10  tff(decl_60811, type, 'In plants, an arrangement of microtubules, microfilaments, and Golgi-derived vesicles that align along the midline during cytokinesis of a dividing cell.': $i).
% 29.32/29.10  tff(decl_60812, type, phragmoplast: $i).
% 29.32/29.10  tff(decl_60813, type, plant_cell_structure_1: $i > $o).
% 29.32/29.10  tff(decl_60814, type, phycobilin_1: $i > $o).
% 29.32/29.10  tff(decl_60815, type, 'Phycobilin': $i).
% 29.32/29.10  tff(decl_60816, type, 'Any of several water-soluble pigment molecules found in cyanobacteria and the chloroplasts of red algae.': $i).
% 29.32/29.10  tff(decl_60817, type, phycobilin: $i).
% 29.32/29.10  tff(decl_60818, type, 'PhyloCode': $i).
% 29.32/29.10  tff(decl_60819, type, 'A system of biological classification in which only monophyletic groups are named.': $i).
% 29.32/29.10  tff(decl_60820, type, 'international code of phylogenetic nomenclature': $i).
% 29.32/29.10  tff(decl_60821, type, 'international-code-of-phylogenetic-nomenclature': $i).
% 29.32/29.10  tff(decl_60822, type, 'phylogenetic code': $i).
% 29.32/29.10  tff(decl_60823, type, 'phylogenetic-code': $i).
% 29.32/29.10  tff(decl_60824, type, 'phylogenetic nomenclature': $i).
% 29.32/29.10  tff(decl_60825, type, 'phylogenetic-nomenclature': $i).
% 29.32/29.10  tff(decl_60826, type, phylocode: $i).
% 29.32/29.10  tff(decl_60827, type, 'Phylogenetic-Bracketing': $i).
% 29.32/29.10  tff(decl_60828, type, 'An approach to phylogenetic analysis in which features that are shared by two groups of organisms can be predicted to occur in their common ancestor and all of its descendants.': $i).
% 29.32/29.10  tff(decl_60829, type, 'phylogenetic bracketing': $i).
% 29.32/29.10  tff(decl_60830, type, 'phylogenetic-bracketing': $i).
% 29.32/29.10  tff(decl_60831, type, 'Phylogenetic-Species-Concept': $i).
% 29.32/29.10  tff(decl_60832, type, 'Defines a species as all the descendants of a single parental population.': $i).
% 29.32/29.10  tff(decl_60833, type, 'phylogenetic species concept': $i).
% 29.32/29.10  tff(decl_60834, type, 'phylogenetic-species-concept': $i).
% 29.32/29.10  tff(decl_60835, type, 'Phylogenetic-Tree': $i).
% 29.32/29.10  tff(decl_60836, type, 'A branching diagram representing the inferred evolutionary relationships among a group of organisms.': $i).
% 29.32/29.10  tff(decl_60837, type, 'evolutionary tree': $i).
% 29.32/29.10  tff(decl_60838, type, 'evolutionary-tree': $i).
% 29.32/29.10  tff(decl_60839, type, 'phylogenetic tree': $i).
% 29.32/29.10  tff(decl_60840, type, 'phylogenetic-tree': $i).
% 29.32/29.10  tff(decl_60841, type, 'Phylogeny': $i).
% 29.32/29.10  tff(decl_60842, type, 'The evolutionary history of a group of related organisms.': $i).
% 29.32/29.10  tff(decl_60843, type, phylogeny: $i).
% 29.32/29.10  tff(decl_60844, type, phylogram_1: $i > $o).
% 29.32/29.10  tff(decl_60845, type, 'Phylogram': $i).
% 29.32/29.10  tff(decl_60846, type, 'A phylogenetic tree in which the length of a particular branch is proportional to the amount of genetic change that has occurred.': $i).
% 29.32/29.10  tff(decl_60847, type, phylogram: $i).
% 29.32/29.10  tff(decl_60848, type, ultrametric_tree_1: $i > $o).
% 29.32/29.10  tff(decl_60849, type, rooted_1: $i > $o).
% 29.32/29.10  tff(decl_60850, type, phylum_1: $i > $o).
% 29.32/29.10  tff(decl_60851, type, 'Phylum': $i).
% 29.32/29.10  tff(decl_60852, type, 'In Linnean taxonomy, the taxonomic level below Kingdom and above Class.': $i).
% 29.32/29.10  tff(decl_60853, type, phylum: $i).
% 29.32/29.10  tff(decl_60854, type, physical_change_1: $i > $o).
% 29.32/29.10  tff(decl_60855, type, 'Physical-Change': $i).
% 29.32/29.10  tff(decl_60856, type, 'A change in the physical state of a molecule, object, wave or system.': $i).
% 29.32/29.10  tff(decl_60857, type, 'physical change': $i).
% 29.32/29.10  tff(decl_60858, type, 'physical-change': $i).
% 29.32/29.10  tff(decl_60859, type, 'Physical-Document': $i).
% 29.32/29.10  tff(decl_60860, type, 'a physically rendered written message': $i).
% 29.32/29.10  tff(decl_60861, type, 'physical document': $i).
% 29.32/29.10  tff(decl_60862, type, 'physical-document': $i).
% 29.32/29.10  tff(decl_60863, type, fn_physical_document_1: $i > $i).
% 29.32/29.10  tff(decl_60864, type, fn_physical_document_2: $i > $i).
% 29.32/29.10  tff(decl_60865, type, print_1: $i > $o).
% 29.32/29.10  tff(decl_60866, type, 'Physical-Map': $i).
% 29.32/29.10  tff(decl_60867, type, 'A map of genes in which the actual physical distances between genes are expressed, typically as the number of base pairs along the DNA.': $i).
% 29.32/29.10  tff(decl_60868, type, 'physical map': $i).
% 29.32/29.10  tff(decl_60869, type, 'physical-map': $i).
% 29.32/29.10  tff(decl_60870, type, 'Physical-Mark': $i).
% 29.32/29.10  tff(decl_60871, type, 'Any mark created as the result of writing, sketching, printing, drawing etc (i.e. the result of Mark).  Any persistant physical mark or set of marks created by depositing or applying something acting in the role of a writing substance (e.g. ink, paint, sand, blood) to some kind of writable medium using something acting in the role of writing implement (e.g. pencil, marker, finger, paintbrush, spray paint can, printer).': $i).
% 29.32/29.10  tff(decl_60872, type, print: $i).
% 29.32/29.10  tff(decl_60873, type, 'physical mark': $i).
% 29.32/29.10  tff(decl_60874, type, 'physical-mark': $i).
% 29.32/29.10  tff(decl_60875, type, fn_physical_mark_1: $i > $i).
% 29.32/29.10  tff(decl_60876, type, 'Physical-Object': $i).
% 29.32/29.10  tff(decl_60877, type, projectile: $i).
% 29.32/29.10  tff(decl_60878, type, 'physical object': $i).
% 29.32/29.10  tff(decl_60879, type, 'physical-object': $i).
% 29.32/29.10  tff(decl_60880, type, 'Physical-Object-State': $i).
% 29.32/29.10  tff(decl_60881, type, 'Particular condition of a physical object.': $i).
% 29.32/29.10  tff(decl_60882, type, 'physical object state': $i).
% 29.32/29.10  tff(decl_60883, type, 'physical-object-state': $i).
% 29.32/29.10  tff(decl_60884, type, 'Physical-Process': $i).
% 29.32/29.10  tff(decl_60885, type, 'Process which relates to the physical, non-living world.': $i).
% 29.32/29.10  tff(decl_60886, type, 'physical process': $i).
% 29.32/29.10  tff(decl_60887, type, 'physical-process': $i).
% 29.32/29.10  tff(decl_60888, type, physician_1: $i > $o).
% 29.32/29.10  tff(decl_60889, type, 'Physician': $i).
% 29.32/29.10  tff(decl_60890, type, 'Physicians (doctors) are professionals which practice medicine and possess medical degrees and a medical license.': $i).
% 29.32/29.10  tff(decl_60891, type, physician: $i).
% 29.32/29.10  tff(decl_60892, type, fn_physician_1: $i > $i).
% 29.32/29.10  tff(decl_60893, type, fn_physician_2: $i > $i).
% 29.32/29.10  tff(decl_60894, type, physiology_1: $i > $o).
% 29.32/29.10  tff(decl_60895, type, 'Physiology': $i).
% 29.32/29.10  tff(decl_60896, type, 'The study of how organisms function.': $i).
% 29.32/29.10  tff(decl_60897, type, physiology: $i).
% 29.32/29.10  tff(decl_60898, type, 'Phytochemical': $i).
% 29.32/29.10  tff(decl_60899, type, phytochemical: $i).
% 29.32/29.10  tff(decl_60900, type, fn_phytochemical_8: $i > $i).
% 29.32/29.10  tff(decl_60901, type, 'Phytochrome': $i).
% 29.32/29.10  tff(decl_60902, type, 'In plants, a type of photoreceptor that absorbs red light. Phytochromes regulate a plant\\s responses to photoperiod and other physiological processes such as seed germination and flowering.': $i).
% 29.32/29.10  tff(decl_60903, type, phytochrome: $i).
% 29.32/29.10  tff(decl_60904, type, 'Phytoplankton': $i).
% 29.32/29.10  tff(decl_60905, type, 'Portion of plankton which is photosynthetic. Phytoplanton are a group of small, free floating autotrophic organisms, including algae and bacteria, that float freely in water and perform photosynthesis.': $i).
% 29.32/29.10  tff(decl_60906, type, phytoplankton: $i).
% 29.32/29.10  tff(decl_60907, type, 'Phytoremediation': $i).
% 29.32/29.10  tff(decl_60908, type, 'The practice of using plants to remediate environmental problems. Some plants have the ability to extract heavy metals and other toxins from soil and sequester them in parts of the plant that can be easily removed. This ability provides a mechanism by which polluted areas can be treated without having to remove and store large amounts of soil.': $i).
% 29.32/29.10  tff(decl_60909, type, phytoremediation: $i).
% 29.32/29.10  tff(decl_60910, type, piece_of_glass_1: $i > $o).
% 29.32/29.10  tff(decl_60911, type, 'Piece-of-Glass': $i).
% 29.32/29.10  tff(decl_60912, type, 'glass piece': $i).
% 29.32/29.10  tff(decl_60913, type, 'glass-piece': $i).
% 29.32/29.10  tff(decl_60914, type, 'piece of glass': $i).
% 29.32/29.10  tff(decl_60915, type, 'piece-of-glass': $i).
% 29.32/29.10  tff(decl_60916, type, fn_piece_of_glass_1: $i > $i).
% 29.32/29.10  tff(decl_60917, type, fn_piece_of_substance_1: $i > $i).
% 29.32/29.10  tff(decl_60918, type, piece_of_metal_1: $i > $o).
% 29.32/29.10  tff(decl_60919, type, 'Piece-of-Metal': $i).
% 29.32/29.10  tff(decl_60920, type, 'metal piece': $i).
% 29.32/29.10  tff(decl_60921, type, 'metal-piece': $i).
% 29.32/29.10  tff(decl_60922, type, 'piece of metal': $i).
% 29.32/29.10  tff(decl_60923, type, 'piece-of-metal': $i).
% 29.32/29.10  tff(decl_60924, type, fn_piece_of_metal_1: $i > $i).
% 29.32/29.10  tff(decl_60925, type, piece_of_paper_1: $i > $o).
% 29.32/29.10  tff(decl_60926, type, 'Piece-of-Paper': $i).
% 29.32/29.10  tff(decl_60927, type, 'paper piece': $i).
% 29.32/29.10  tff(decl_60928, type, 'paper-piece': $i).
% 29.32/29.10  tff(decl_60929, type, 'piece of paper': $i).
% 29.32/29.10  tff(decl_60930, type, 'piece-of-paper': $i).
% 29.32/29.10  tff(decl_60931, type, fn_piece_of_paper_1: $i > $i).
% 29.32/29.10  tff(decl_60932, type, piece_of_plastic_1: $i > $o).
% 29.32/29.10  tff(decl_60933, type, 'Piece-of-Plastic': $i).
% 29.32/29.10  tff(decl_60934, type, 'plastic piece': $i).
% 29.32/29.10  tff(decl_60935, type, 'plastic-piece': $i).
% 29.32/29.10  tff(decl_60936, type, 'piece of plastic': $i).
% 29.32/29.10  tff(decl_60937, type, 'piece-of-plastic': $i).
% 29.32/29.10  tff(decl_60938, type, fn_piece_of_plastic_1: $i > $i).
% 29.32/29.10  tff(decl_60939, type, piece_of_rubber_1: $i > $o).
% 29.32/29.10  tff(decl_60940, type, 'Piece-of-Rubber': $i).
% 29.32/29.10  tff(decl_60941, type, 'rubber piece': $i).
% 29.32/29.10  tff(decl_60942, type, 'rubber-piece': $i).
% 29.32/29.10  tff(decl_60943, type, 'piece of rubber': $i).
% 29.32/29.10  tff(decl_60944, type, 'piece-of-rubber': $i).
% 29.32/29.10  tff(decl_60945, type, fn_piece_of_rubber_1: $i > $i).
% 29.32/29.10  tff(decl_60946, type, piece_of_stone_1: $i > $o).
% 29.32/29.10  tff(decl_60947, type, 'Piece-of-Stone': $i).
% 29.32/29.10  tff(decl_60948, type, stone: $i).
% 29.32/29.10  tff(decl_60949, type, rock: $i).
% 29.32/29.10  tff(decl_60950, type, 'stone piece': $i).
% 29.32/29.10  tff(decl_60951, type, 'stone-piece': $i).
% 29.32/29.10  tff(decl_60952, type, 'piece of stone': $i).
% 29.32/29.10  tff(decl_60953, type, 'piece-of-stone': $i).
% 29.32/29.10  tff(decl_60954, type, fn_piece_of_stone_1: $i > $i).
% 29.32/29.10  tff(decl_60955, type, 'Piece-of-Substance': $i).
% 29.32/29.10  tff(decl_60956, type, 'substance piece': $i).
% 29.32/29.10  tff(decl_60957, type, 'substance-piece': $i).
% 29.32/29.10  tff(decl_60958, type, 'piece of substance': $i).
% 29.32/29.10  tff(decl_60959, type, 'piece-of-substance': $i).
% 29.32/29.10  tff(decl_60960, type, 'Piece-of-Tissue': $i).
% 29.32/29.10  tff(decl_60961, type, 'tissue piece': $i).
% 29.32/29.10  tff(decl_60962, type, 'tissue-piece': $i).
% 29.32/29.10  tff(decl_60963, type, 'piece of tissue': $i).
% 29.32/29.10  tff(decl_60964, type, 'piece-of-tissue': $i).
% 29.32/29.10  tff(decl_60965, type, piece_of_wood_1: $i > $o).
% 29.32/29.10  tff(decl_60966, type, 'Piece-of-Wood': $i).
% 29.32/29.10  tff(decl_60967, type, 'wood piece': $i).
% 29.32/29.10  tff(decl_60968, type, 'wood-piece': $i).
% 29.32/29.10  tff(decl_60969, type, 'piece of wood': $i).
% 29.32/29.10  tff(decl_60970, type, 'piece-of-wood': $i).
% 29.32/29.10  tff(decl_60971, type, fn_piece_of_wood_1: $i > $i).
% 29.32/29.10  tff(decl_60972, type, 'Pigment': $i).
% 29.32/29.10  tff(decl_60973, type, 'Any substance which absorbs visible light.': $i).
% 29.32/29.10  tff(decl_60974, type, pigment: $i).
% 29.32/29.10  tff(decl_60975, type, pili_1: $i > $o).
% 29.32/29.10  tff(decl_60976, type, 'Pili': $i).
% 29.32/29.10  tff(decl_60977, type, 'Pili are hairlike structures found on the surface of many bacteria which have primary role in attachment of a bacterial cell to another cell': $i).
% 29.32/29.10  tff(decl_60978, type, pilus: $i).
% 29.32/29.10  tff(decl_60979, type, pillus: $i).
% 29.32/29.10  tff(decl_60980, type, fn_pili_1: $i > $i).
% 29.32/29.10  tff(decl_60981, type, fn_pili_2: $i > $i).
% 29.32/29.10  tff(decl_60982, type, fn_pili_3: $i > $i).
% 29.32/29.10  tff(decl_60983, type, 'Piloting': $i).
% 29.32/29.10  tff(decl_60984, type, 'Use of a series of recognizable landmarks to navigate to a final destination.': $i).
% 29.32/29.10  tff(decl_60985, type, pilot: $i).
% 29.32/29.10  tff(decl_60986, type, piloting: $i).
% 29.32/29.10  tff(decl_60987, type, pine_1: $i > $o).
% 29.32/29.10  tff(decl_60988, type, 'Pine': $i).
% 29.32/29.10  tff(decl_60989, type, 'Any of several coniferous trees in the genus Pinus.': $i).
% 29.32/29.10  tff(decl_60990, type, pine: $i).
% 29.32/29.10  tff(decl_60991, type, 'Pineal-Gland': $i).
% 29.32/29.10  tff(decl_60992, type, 'A small endocrine gland in the vertebrate brain; secretes the hormone melatonin, which modulates sleep/wake cycles.': $i).
% 29.32/29.10  tff(decl_60993, type, 'pineal gland': $i).
% 29.32/29.10  tff(decl_60994, type, 'pineal-gland': $i).
% 29.32/29.10  tff(decl_60995, type, 'Pineapple-Plant': $i).
% 29.32/29.10  tff(decl_60996, type, 'Pineapple (Ananas comosus) is the common name for a tropical plant and its edible fruit which are coalesced berries.': $i).
% 29.32/29.10  tff(decl_60997, type, 'ananas comosus': $i).
% 29.32/29.10  tff(decl_60998, type, 'plant of pineapple': $i).
% 29.32/29.10  tff(decl_60999, type, 'pineapple plant': $i).
% 29.32/29.10  tff(decl_61000, type, 'pineapple-plant': $i).
% 29.32/29.10  tff(decl_61001, type, pink_1: $i > $o).
% 29.32/29.10  tff(decl_61002, type, 'Pink': $i).
% 29.32/29.10  tff(decl_61003, type, 'Pink is a mixture of red and white': $i).
% 29.32/29.10  tff(decl_61004, type, pink: $i).
% 29.32/29.10  tff(decl_61005, type, pinnipedia_1: $i > $o).
% 29.32/29.10  tff(decl_61006, type, 'Pinnipedia': $i).
% 29.32/29.10  tff(decl_61007, type, 'Semi-aquatic fin-footed mammals. The group includes seals, otters, walruses, and sea lions.': $i).
% 29.32/29.10  tff(decl_61008, type, pinnipedia: $i).
% 29.32/29.10  tff(decl_61009, type, 'Pinocytosis': $i).
% 29.32/29.10  tff(decl_61010, type, 'In cellular biology, pinocytosis (cell-drinking, bulk-phase pinocytosis, non-specific, non-adsorptive pinocytosis, fluid endocytosis) is a form of endocytosis in which small particles are brought into the cell suspended within small vesicles which subsequently fuse with lysosomes to hydrolyze, or to break down, the particles.': $i).
% 29.32/29.10  tff(decl_61011, type, 'cellular drinking': $i).
% 29.32/29.10  tff(decl_61012, type, 'cellular-drinking': $i).
% 29.32/29.10  tff(decl_61013, type, 'perform pinocytosis': $i).
% 29.32/29.10  tff(decl_61014, type, pinocytosis: $i).
% 29.32/29.10  tff(decl_61015, type, fn_pinocytosis_1: $i > $i).
% 29.32/29.10  tff(decl_61016, type, fn_pinocytosis_2: $i > $i).
% 29.32/29.10  tff(decl_61017, type, fn_pinocytosis_3: $i > $i).
% 29.32/29.10  tff(decl_61018, type, fn_pinocytosis_4: $i > $i).
% 29.32/29.10  tff(decl_61019, type, fn_pinocytosis_5: $i > $i).
% 29.32/29.10  tff(decl_61020, type, fn_pinocytosis_7: $i > $i).
% 29.32/29.10  tff(decl_61021, type, fn_pinocytosis_8: $i > $i).
% 29.32/29.10  tff(decl_61022, type, fn_pinocytosis_9: $i > $i).
% 29.32/29.10  tff(decl_61023, type, fn_pinocytosis_10: $i > $i).
% 29.32/29.10  tff(decl_61024, type, fn_pinocytosis_11: $i > $i).
% 29.32/29.10  tff(decl_61025, type, fn_pinocytosis_12: $i > $i).
% 29.32/29.10  tff(decl_61026, type, fn_pinocytosis_13: $i > $i).
% 29.32/29.10  tff(decl_61027, type, fn_pinocytosis_14: $i > $i).
% 29.32/29.10  tff(decl_61028, type, fn_pinocytosis_15: $i > $i).
% 29.32/29.10  tff(decl_61029, type, fn_pinocytosis_16: $i > $i).
% 29.32/29.10  tff(decl_61030, type, fn_pinocytosis_17: $i > $i).
% 29.32/29.10  tff(decl_61031, type, fn_pinocytosis_18: $i > $i).
% 29.32/29.10  tff(decl_61032, type, fn_pinocytosis_19: $i > $i).
% 29.32/29.10  tff(decl_61033, type, fn_pinocytosis_20: $i > $i).
% 29.32/29.10  tff(decl_61034, type, fn_pinocytosis_21: $i > $i).
% 29.32/29.10  tff(decl_61035, type, fn_pinocytosis_22: $i > $i).
% 29.32/29.10  tff(decl_61036, type, fn_pinocytosis_23: $i > $i).
% 29.32/29.10  tff(decl_61037, type, fn_pinocytosis_24: $i > $i).
% 29.32/29.10  tff(decl_61038, type, fn_pinocytosis_25: $i > $i).
% 29.32/29.10  tff(decl_61039, type, fn_pinocytosis_26: $i > $i).
% 29.32/29.10  tff(decl_61040, type, fn_pinocytosis_27: $i > $i).
% 29.32/29.10  tff(decl_61041, type, fn_pinocytosis_28: $i > $i).
% 29.32/29.11  tff(decl_61042, type, fn_pinocytosis_29: $i > $i).
% 29.32/29.11  tff(decl_61043, type, fn_pinocytosis_30: $i > $i).
% 29.32/29.11  tff(decl_61044, type, fn_pinocytosis_31: $i > $i).
% 29.32/29.11  tff(decl_61045, type, fn_pinocytosis_33: $i > $i).
% 29.32/29.11  tff(decl_61046, type, fn_pinocytosis_34: $i > $i).
% 29.32/29.11  tff(decl_61047, type, fn_pinocytosis_35: $i > $i).
% 29.32/29.11  tff(decl_61048, type, fn_pinocytosis_36: $i > $i).
% 29.32/29.11  tff(decl_61049, type, fn_pinocytosis_37: $i > $i).
% 29.32/29.11  tff(decl_61050, type, fn_pinocytosis_38: $i > $i).
% 29.32/29.11  tff(decl_61051, type, fn_pinocytosis_39: $i > $i).
% 29.32/29.11  tff(decl_61052, type, fn_pinocytosis_40: $i > $i).
% 29.32/29.11  tff(decl_61053, type, fn_pinocytosis_41: $i > $i).
% 29.32/29.11  tff(decl_61054, type, fn_pinocytosis_42: $i > $i).
% 29.32/29.11  tff(decl_61055, type, fn_pinocytosis_43: $i > $i).
% 29.32/29.11  tff(decl_61056, type, fn_pinocytosis_44: $i > $i).
% 29.32/29.11  tff(decl_61057, type, fn_pinocytosis_45: $i > $i).
% 29.32/29.11  tff(decl_61058, type, fn_pinocytosis_46: $i > $i).
% 29.32/29.11  tff(decl_61059, type, fn_pinocytosis_47: $i > $i).
% 29.32/29.11  tff(decl_61060, type, fn_pinocytosis_48: $i > $i).
% 29.32/29.11  tff(decl_61061, type, fn_pinocytosis_51: $i > $i).
% 29.32/29.11  tff(decl_61062, type, fn_pinocytosis_52: $i > $i).
% 29.32/29.11  tff(decl_61063, type, fn_pinocytosis_53: $i > $i).
% 29.32/29.11  tff(decl_61064, type, fn_pinocytosis_54: $i > $i).
% 29.32/29.11  tff(decl_61065, type, fn_pinocytosis_55: $i > $i).
% 29.32/29.11  tff(decl_61066, type, fn_pinocytosis_56: $i > $i).
% 29.32/29.11  tff(decl_61067, type, fn_pinocytosis_59: $i > $i).
% 29.32/29.11  tff(decl_61068, type, fn_pinocytosis_60: $i > $i).
% 29.32/29.11  tff(decl_61069, type, fn_pinocytosis_32: $i > $i).
% 29.32/29.11  tff(decl_61070, type, fn_endocytosis_1: $i > $i).
% 29.32/29.11  tff(decl_61071, type, fn_pinocytosis_57: $i > $i).
% 29.32/29.11  tff(decl_61072, type, fn_pinocytosis_58: $i > $i).
% 29.32/29.11  tff(decl_61073, type, fn_pinocytosis_50: $i > $i).
% 29.32/29.11  tff(decl_61074, type, fn_pinocytosis_49: $i > $i).
% 29.32/29.11  tff(decl_61075, type, pistil_1: $i > $o).
% 29.32/29.11  tff(decl_61076, type, 'Pistil': $i).
% 29.32/29.11  tff(decl_61077, type, 'A single carpel or a group of fused carpels.': $i).
% 29.32/29.11  tff(decl_61078, type, pistil: $i).
% 29.32/29.11  tff(decl_61079, type, 'Pith': $i).
% 29.32/29.11  tff(decl_61080, type, 'Ground tissue of soft, spongy parenchyma cells in the stem of vascular plants. Pith is surrounded by a ring of xylem and a ring of phloem.': $i).
% 29.32/29.11  tff(decl_61081, type, pith: $i).
% 29.32/29.11  tff(decl_61082, type, 'Pituitary-Gland': $i).
% 29.32/29.11  tff(decl_61083, type, 'An endocrine gland situated at the base of the hypothalamus. It has an anterior lobe, which secretes several hormones that regulate a variety of bodily functions; and a posterior lobe that has neural connections to the hypothalamus and stores and releases hypothalamic hormones.': $i).
% 29.32/29.11  tff(decl_61084, type, 'gland of pituitary': $i).
% 29.32/29.11  tff(decl_61085, type, 'pituitary gland': $i).
% 29.32/29.11  tff(decl_61086, type, 'pituitary-gland': $i).
% 29.32/29.11  tff(decl_61087, type, 'Pituitary-Peptide-Hormone': $i).
% 29.32/29.11  tff(decl_61088, type, 'Peptide hormones secreted by the pituitary gland.': $i).
% 29.32/29.11  tff(decl_61089, type, 'pituitary peptide hormone': $i).
% 29.32/29.11  tff(decl_61090, type, 'pituitary-peptide-hormone': $i).
% 29.32/29.11  tff(decl_61091, type, 'Pivot-Joint': $i).
% 29.32/29.11  tff(decl_61092, type, 'A freely moving joint in which movement is limited to rotation around a central axis.': $i).
% 29.32/29.11  tff(decl_61093, type, 'joint of pivot': $i).
% 29.32/29.11  tff(decl_61094, type, 'pivot joint': $i).
% 29.32/29.11  tff(decl_61095, type, 'pivot-joint': $i).
% 29.32/29.11  tff(decl_61096, type, 'PKa-Value': $i).
% 29.32/29.11  tff(decl_61097, type, 'the negative log to base 10 of the acidity constant, ka.': $i).
% 29.32/29.11  tff(decl_61098, type, pka: $i).
% 29.32/29.11  tff(decl_61099, type, 'pka value': $i).
% 29.32/29.11  tff(decl_61100, type, 'pka-value': $i).
% 29.32/29.11  tff(decl_61101, type, 'PKb-Value': $i).
% 29.32/29.11  tff(decl_61102, type, 'the negative log to base 10 of the alkalinity constant, kb.': $i).
% 29.32/29.11  tff(decl_61103, type, pkb: $i).
% 29.32/29.11  tff(decl_61104, type, 'pkb value': $i).
% 29.32/29.11  tff(decl_61105, type, 'pkb-value': $i).
% 29.32/29.11  tff(decl_61106, type, place_1: $i > $o).
% 29.32/29.11  tff(decl_61107, type, 'Place': $i).
% 29.32/29.11  tff(decl_61108, type, place_order_1: $i > $o).
% 29.32/29.11  tff(decl_61109, type, 'Place-Order': $i).
% 29.32/29.11  tff(decl_61110, type, 'order of place': $i).
% 29.32/29.11  tff(decl_61111, type, 'place order': $i).
% 29.32/29.11  tff(decl_61112, type, 'place-order': $i).
% 29.32/29.11  tff(decl_61113, type, fn_place_order_1: $i > $i).
% 29.32/29.11  tff(decl_61114, type, fn_place_order_2: $i > $i).
% 29.32/29.11  tff(decl_61115, type, 'Placenta': $i).
% 29.32/29.11  tff(decl_61116, type, 'A structure in the pregnant uterus for nourishing a viviparous fetus with the mother\\s blood supply; formed from the uterine lining and embryonic membranes.': $i).
% 29.32/29.11  tff(decl_61117, type, placenta: $i).
% 29.32/29.11  tff(decl_61118, type, fn_placenta_1: $i > $i).
% 29.32/29.11  tff(decl_61119, type, pregnant_uterus_1: $i > $o).
% 29.32/29.11  tff(decl_61120, type, 'Placental-Mammal': $i).
% 29.32/29.11  tff(decl_61121, type, 'Eutherian mammals with a more complex placenta and a longer-lasting association between a mother and her developing young.': $i).
% 29.32/29.11  tff(decl_61122, type, 'mammal of placental': $i).
% 29.32/29.11  tff(decl_61123, type, 'placental mammal': $i).
% 29.32/29.11  tff(decl_61124, type, 'placental-mammal': $i).
% 29.32/29.11  tff(decl_61125, type, 'Placental-Transfer-Cell': $i).
% 29.32/29.11  tff(decl_61126, type, 'In plants, a cell that facilitates the transfer of nutrients from the plant to the developing embryo.': $i).
% 29.32/29.11  tff(decl_61127, type, 'placental transfer cell': $i).
% 29.32/29.11  tff(decl_61128, type, 'placental-transfer-cell': $i).
% 29.32/29.11  tff(decl_61129, type, 'Placoderm': $i).
% 29.32/29.11  tff(decl_61130, type, 'Member of a group of extinct armoured fishes that lived from the late Silurian to the end of the Devonian.': $i).
% 29.32/29.11  tff(decl_61131, type, placoderm: $i).
% 29.32/29.11  tff(decl_61132, type, placozoa_1: $i > $o).
% 29.32/29.11  tff(decl_61133, type, 'Placozoa': $i).
% 29.32/29.11  tff(decl_61134, type, 'Phylum of invertebrates consisting of a single bilayer of a few thousand cells. There is only one known existing species (Tricoplax adhaerans).': $i).
% 29.32/29.11  tff(decl_61135, type, placozoa: $i).
% 29.32/29.11  tff(decl_61136, type, fn_placozoa_2: $i > $i).
% 29.32/29.11  tff(decl_61137, type, fn_placozoa_3: $i > $i).
% 29.32/29.11  tff(decl_61138, type, fn_placozoa_4: $i > $i).
% 29.32/29.11  tff(decl_61139, type, fn_placozoa_5: $i > $i).
% 29.32/29.11  tff(decl_61140, type, fn_placozoa_6: $i > $i).
% 29.32/29.11  tff(decl_61141, type, fn_placozoa_7: $i > $i).
% 29.32/29.11  tff(decl_61142, type, fn_placozoa_8: $i > $i).
% 29.32/29.11  tff(decl_61143, type, planarian_1: $i > $o).
% 29.32/29.11  tff(decl_61144, type, 'Planarian': $i).
% 29.32/29.11  tff(decl_61145, type, 'A freshwater non-parasitic flatworm found in ponds and streams.': $i).
% 29.32/29.11  tff(decl_61146, type, planarian: $i).
% 29.32/29.11  tff(decl_61147, type, tapeworm_1: $i > $o).
% 29.32/29.11  tff(decl_61148, type, trematode_1: $i > $o).
% 29.32/29.11  tff(decl_61149, type, turbellarian_1: $i > $o).
% 29.32/29.11  tff(decl_61150, type, planet_1: $i > $o).
% 29.32/29.11  tff(decl_61151, type, 'Planet': $i).
% 29.32/29.11  tff(decl_61152, type, 'A celestial body larger than an asteroid or comet that orbits a star.': $i).
% 29.32/29.11  tff(decl_61153, type, planet: $i).
% 29.32/29.11  tff(decl_61154, type, 'Plankton': $i).
% 29.32/29.11  tff(decl_61155, type, 'Group of small, free floating organisms, including algae, bacteria and animals, that float freely in water.': $i).
% 29.32/29.11  tff(decl_61156, type, plankton: $i).
% 29.32/29.11  tff(decl_61157, type, planning_1: $i > $o).
% 29.32/29.11  tff(decl_61158, type, 'Planning': $i).
% 29.32/29.11  tff(decl_61159, type, plan: $i).
% 29.32/29.11  tff(decl_61160, type, preparation: $i).
% 29.32/29.11  tff(decl_61161, type, planning: $i).
% 29.32/29.11  tff(decl_61162, type, readying: $i).
% 29.32/29.11  tff(decl_61163, type, 'Plant': $i).
% 29.32/29.11  tff(decl_61164, type, 'a living entity incapable of locomotion': $i).
% 29.32/29.11  tff(decl_61165, type, 'Plant are the living organisms belonging to the kingdom Plantae. They include familiar organisms such as tree, herbs, bushes, grasses, vines, ferns, mosses and green algae.': $i).
% 29.32/29.11  tff(decl_61166, type, plant: $i).
% 29.32/29.11  tff(decl_61167, type, 'plant life': $i).
% 29.32/29.11  tff(decl_61168, type, plant_life: $i).
% 29.32/29.11  tff(decl_61169, type, flora: $i).
% 29.32/29.11  tff(decl_61170, type, fn_plant_1: $i > $i).
% 29.32/29.11  tff(decl_61171, type, fn_plant_2: $i > $i).
% 29.32/29.11  tff(decl_61172, type, fn_plant_3: $i > $i).
% 29.32/29.11  tff(decl_61173, type, fn_plant_5: $i > $i).
% 29.32/29.11  tff(decl_61174, type, fn_plant_6: $i > $i).
% 29.32/29.11  tff(decl_61175, type, fn_plant_8: $i > $i).
% 29.32/29.11  tff(decl_61176, type, fn_plant_9: $i > $i).
% 29.32/29.11  tff(decl_61177, type, fn_plant_26: $i > $i).
% 29.32/29.11  tff(decl_61178, type, fn_plant_27: $i > $i).
% 29.32/29.11  tff(decl_61179, type, fn_plant_33: $i > $i).
% 29.32/29.11  tff(decl_61180, type, fn_starch_storage_by_plant_1: $i > $i).
% 29.32/29.11  tff(decl_61181, type, fn_tuber_4: $i > $i).
% 29.32/29.11  tff(decl_61182, type, fn_plant_40: $i > $i).
% 29.32/29.11  tff(decl_61183, type, fn_plant_39: $i > $i).
% 29.32/29.11  tff(decl_61184, type, fn_plant_42: $i > $i).
% 29.32/29.11  tff(decl_61185, type, fn_plant_43: $i > $i).
% 29.32/29.11  tff(decl_61186, type, fn_plant_44: $i > $i).
% 29.32/29.11  tff(decl_61187, type, 'Plant-Appendage': $i).
% 29.32/29.11  tff(decl_61188, type, 'An external part, or natural prolongation, that protrudes from a plant.': $i).
% 29.32/29.11  tff(decl_61189, type, 'appendage of plant': $i).
% 29.32/29.11  tff(decl_61190, type, 'plant appendage': $i).
% 29.32/29.11  tff(decl_61191, type, 'plant-appendage': $i).
% 29.32/29.11  tff(decl_61192, type, 'Plant-Cell': $i).
% 29.32/29.11  tff(decl_61193, type, 'Plant cell is the basic structural entity of the Plants': $i).
% 29.32/29.11  tff(decl_61194, type, 'cell of plant': $i).
% 29.32/29.11  tff(decl_61195, type, 'plant cell': $i).
% 29.32/29.11  tff(decl_61196, type, 'plant-cell': $i).
% 29.32/29.11  tff(decl_61197, type, fn_plant_cell_2: $i > $i).
% 29.32/29.11  tff(decl_61198, type, fn_plant_cell_3: $i > $i).
% 29.32/29.11  tff(decl_61199, type, fn_plant_cell_4: $i > $i).
% 29.32/29.11  tff(decl_61200, type, fn_plant_cell_5: $i > $i).
% 29.32/29.11  tff(decl_61201, type, fn_plant_cell_7: $i > $i).
% 29.32/29.11  tff(decl_61202, type, fn_plant_cell_10: $i > $i).
% 29.32/29.11  tff(decl_61203, type, fn_plant_cell_12: $i > $i).
% 29.32/29.11  tff(decl_61204, type, fn_plant_cell_13: $i > $i).
% 29.32/29.11  tff(decl_61205, type, fn_plant_cell_26: $i > $i).
% 29.32/29.11  tff(decl_61206, type, fn_plant_cell_28: $i > $i).
% 29.32/29.11  tff(decl_61207, type, fn_plant_cell_30: $i > $i).
% 29.32/29.11  tff(decl_61208, type, fn_plant_cell_38: $i > $i).
% 29.32/29.11  tff(decl_61209, type, fn_plant_cell_39: $i > $i).
% 29.32/29.11  tff(decl_61210, type, fn_plant_cell_40: $i > $i).
% 29.32/29.11  tff(decl_61211, type, fn_plant_cell_41: $i > $i).
% 29.32/29.11  tff(decl_61212, type, fn_plant_cell_45: $i > $i).
% 29.32/29.11  tff(decl_61213, type, fn_plant_cell_46: $i > $i).
% 29.32/29.11  tff(decl_61214, type, fn_plant_cell_47: $i > $i).
% 29.32/29.11  tff(decl_61215, type, fn_plant_cell_48: $i > $i).
% 29.32/29.11  tff(decl_61216, type, fn_plant_cell_49: $i > $i).
% 29.32/29.11  tff(decl_61217, type, fn_plant_cell_50: $i > $i).
% 29.32/29.11  tff(decl_61218, type, fn_plant_cell_51: $i > $i).
% 29.32/29.11  tff(decl_61219, type, fn_plant_cell_52: $i > $i).
% 29.32/29.11  tff(decl_61220, type, fn_plant_cell_53: $i > $i).
% 29.32/29.11  tff(decl_61221, type, fn_plant_cell_54: $i > $i).
% 29.32/29.11  tff(decl_61222, type, fn_plant_cell_55: $i > $i).
% 29.32/29.11  tff(decl_61223, type, fn_plant_cell_69: $i > $i).
% 29.32/29.11  tff(decl_61224, type, fn_plant_cell_70: $i > $i).
% 29.32/29.11  tff(decl_61225, type, fn_plant_cell_85: $i > $i).
% 29.32/29.11  tff(decl_61226, type, fn_plant_cell_86: $i > $i).
% 29.32/29.11  tff(decl_61227, type, fn_plant_cell_88: $i > $i).
% 29.32/29.11  tff(decl_61228, type, fn_plant_cell_101: $i > $i).
% 29.32/29.11  tff(decl_61229, type, fn_plant_cell_102: $i > $i).
% 29.32/29.11  tff(decl_61230, type, fn_plant_cell_103: $i > $i).
% 29.32/29.11  tff(decl_61231, type, fn_plant_cell_107: $i > $i).
% 29.32/29.11  tff(decl_61232, type, fn_plant_cell_108: $i > $i).
% 29.32/29.11  tff(decl_61233, type, fn_plant_cell_109: $i > $i).
% 29.32/29.11  tff(decl_61234, type, fn_plant_cell_113: $i > $i).
% 29.32/29.11  tff(decl_61235, type, fn_plant_cell_114: $i > $i).
% 29.32/29.11  tff(decl_61236, type, fn_plant_cell_117: $i > $i).
% 29.32/29.11  tff(decl_61237, type, fn_plant_cell_118: $i > $i).
% 29.32/29.11  tff(decl_61238, type, fn_plant_cell_119: $i > $i).
% 29.32/29.11  tff(decl_61239, type, fn_phospholipid_layer_5: $i > $i).
% 29.32/29.11  tff(decl_61240, type, fn_proton_pump_20: $i > $i).
% 29.32/29.11  tff(decl_61241, type, fn_proton_pump_64: $i > $i).
% 29.32/29.11  tff(decl_61242, type, fn_proton_pump_66: $i > $i).
% 29.32/29.11  tff(decl_61243, type, fn_proton_pump_21: $i > $i).
% 29.32/29.11  tff(decl_61244, type, electrogenic_pump_0: $i).
% 29.32/29.11  tff(decl_61245, type, fn_plant_cell_106: $i > $i).
% 29.32/29.11  tff(decl_61246, type, fn_plant_cell_105: $i > $i).
% 29.32/29.11  tff(decl_61247, type, fn_plant_cell_34: $i > $i).
% 29.32/29.11  tff(decl_61248, type, fn_plant_cell_33: $i > $i).
% 29.32/29.11  tff(decl_61249, type, fn_plant_cell_36: $i > $i).
% 29.32/29.11  tff(decl_61250, type, fn_plant_cell_32: $i > $i).
% 29.32/29.11  tff(decl_61251, type, fn_plant_cell_31: $i > $i).
% 29.32/29.11  tff(decl_61252, type, fn_plant_cell_111: $i > $i).
% 29.32/29.11  tff(decl_61253, type, fn_plant_cell_112: $i > $i).
% 29.32/29.11  tff(decl_61254, type, fn_plant_cell_35: $i > $i).
% 29.32/29.11  tff(decl_61255, type, fn_plant_cell_37: $i > $i).
% 29.32/29.11  tff(decl_61256, type, 'Plant-Cell-Inside-Hypertonic-Solution': $i).
% 29.32/29.11  tff(decl_61257, type, 'A plant cell within a solution that contains more solute than the interior of the cell which will result in water diffusing out of and shrinking the cell.': $i).
% 29.32/29.11  tff(decl_61258, type, 'plant cell inside hypertonic solution': $i).
% 29.32/29.11  tff(decl_61259, type, 'plant-cell-inside-hypertonic-solution': $i).
% 29.32/29.11  tff(decl_61260, type, 'Plant-Cell-Inside-Hypotonic-Solution': $i).
% 29.32/29.11  tff(decl_61261, type, 'This is the condition in which plant cell is placed inside hypotonic solution': $i).
% 29.32/29.11  tff(decl_61262, type, 'plant cell inside hypotonic solution': $i).
% 29.32/29.11  tff(decl_61263, type, 'plant-cell-inside-hypotonic-solution': $i).
% 29.32/29.11  tff(decl_61264, type, walled_cell_inside_hypotonic_solution_1: $i > $o).
% 29.32/29.11  tff(decl_61265, type, 'Plant-Cell-Inside-Isotonic-Solution': $i).
% 29.32/29.11  tff(decl_61266, type, 'Because both the cell and the outside are isotonic (equally balanced in concentration) the water will contue to move equally in both directions.': $i).
% 29.32/29.11  tff(decl_61267, type, 'plant cell inside isotonic solution': $i).
% 29.32/29.11  tff(decl_61268, type, 'plant-cell-inside-isotonic-solution': $i).
% 29.32/29.11  tff(decl_61269, type, fn_plant_cell_inside_isotonic_solution_1: $i > $i).
% 29.32/29.11  tff(decl_61270, type, fn_plant_cell_inside_isotonic_solution_6: $i > $i).
% 29.32/29.11  tff(decl_61271, type, fn_plant_cell_inside_isotonic_solution_7: $i > $i).
% 29.32/29.11  tff(decl_61272, type, fn_plant_cell_inside_isotonic_solution_8: $i > $i).
% 29.32/29.11  tff(decl_61273, type, fn_plant_cell_inside_isotonic_solution_9: $i > $i).
% 29.32/29.11  tff(decl_61274, type, fn_plant_cell_inside_isotonic_solution_10: $i > $i).
% 29.32/29.11  tff(decl_61275, type, fn_plant_cell_inside_isotonic_solution_11: $i > $i).
% 29.32/29.11  tff(decl_61276, type, fn_plant_cell_inside_isotonic_solution_12: $i > $i).
% 29.32/29.11  tff(decl_61277, type, fn_plant_cell_inside_isotonic_solution_13: $i > $i).
% 29.32/29.11  tff(decl_61278, type, fn_plant_cell_inside_isotonic_solution_14: $i > $i).
% 29.32/29.11  tff(decl_61279, type, fn_plant_cell_inside_isotonic_solution_15: $i > $i).
% 29.32/29.11  tff(decl_61280, type, fn_plant_cell_inside_isotonic_solution_16: $i > $i).
% 29.32/29.11  tff(decl_61281, type, fn_plant_cell_inside_isotonic_solution_17: $i > $i).
% 29.32/29.11  tff(decl_61282, type, fn_plant_cell_inside_isotonic_solution_19: $i > $i).
% 29.32/29.11  tff(decl_61283, type, fn_plant_cell_inside_isotonic_solution_20: $i > $i).
% 29.32/29.11  tff(decl_61284, type, fn_plant_cell_inside_isotonic_solution_21: $i > $i).
% 29.32/29.11  tff(decl_61285, type, fn_plant_cell_inside_isotonic_solution_22: $i > $i).
% 29.32/29.11  tff(decl_61286, type, fn_plant_cell_inside_isotonic_solution_23: $i > $i).
% 29.32/29.11  tff(decl_61287, type, fn_plant_cell_inside_isotonic_solution_24: $i > $i).
% 29.32/29.11  tff(decl_61288, type, fn_plant_cell_inside_isotonic_solution_25: $i > $i).
% 29.32/29.11  tff(decl_61289, type, fn_plant_cell_inside_isotonic_solution_26: $i > $i).
% 29.32/29.11  tff(decl_61290, type, fn_plant_cell_inside_isotonic_solution_27: $i > $i).
% 29.32/29.11  tff(decl_61291, type, fn_plant_cell_inside_isotonic_solution_28: $i > $i).
% 29.32/29.11  tff(decl_61292, type, fn_plant_cell_inside_isotonic_solution_29: $i > $i).
% 29.32/29.11  tff(decl_61293, type, fn_plant_cell_inside_isotonic_solution_30: $i > $i).
% 29.32/29.11  tff(decl_61294, type, fn_plant_cell_inside_isotonic_solution_31: $i > $i).
% 29.32/29.11  tff(decl_61295, type, fn_plant_cell_inside_isotonic_solution_32: $i > $i).
% 29.32/29.11  tff(decl_61296, type, fn_plant_cell_inside_isotonic_solution_33: $i > $i).
% 29.32/29.11  tff(decl_61297, type, fn_plant_cell_inside_isotonic_solution_34: $i > $i).
% 29.32/29.11  tff(decl_61298, type, fn_plant_cell_inside_isotonic_solution_35: $i > $i).
% 29.32/29.11  tff(decl_61299, type, fn_plant_cell_inside_isotonic_solution_36: $i > $i).
% 29.32/29.11  tff(decl_61300, type, fn_plant_cell_inside_isotonic_solution_37: $i > $i).
% 29.32/29.11  tff(decl_61301, type, fn_plant_cell_inside_isotonic_solution_38: $i > $i).
% 29.32/29.11  tff(decl_61302, type, fn_plant_cell_inside_isotonic_solution_39: $i > $i).
% 29.32/29.11  tff(decl_61303, type, fn_plant_cell_inside_isotonic_solution_40: $i > $i).
% 29.32/29.11  tff(decl_61304, type, fn_plant_cell_inside_isotonic_solution_41: $i > $i).
% 29.32/29.11  tff(decl_61305, type, fn_plant_cell_inside_isotonic_solution_42: $i > $i).
% 29.32/29.11  tff(decl_61306, type, fn_plant_cell_inside_isotonic_solution_43: $i > $i).
% 29.32/29.11  tff(decl_61307, type, fn_plant_cell_inside_isotonic_solution_44: $i > $i).
% 29.32/29.11  tff(decl_61308, type, fn_plant_cell_inside_isotonic_solution_45: $i > $i).
% 29.32/29.11  tff(decl_61309, type, fn_plant_cell_inside_isotonic_solution_46: $i > $i).
% 29.32/29.11  tff(decl_61310, type, fn_plant_cell_inside_isotonic_solution_47: $i > $i).
% 29.32/29.11  tff(decl_61311, type, fn_plant_cell_inside_isotonic_solution_48: $i > $i).
% 29.32/29.11  tff(decl_61312, type, fn_plant_cell_inside_isotonic_solution_49: $i > $i).
% 29.32/29.11  tff(decl_61313, type, fn_plant_cell_inside_isotonic_solution_50: $i > $i).
% 29.32/29.11  tff(decl_61314, type, fn_plant_cell_inside_isotonic_solution_51: $i > $i).
% 29.32/29.11  tff(decl_61315, type, fn_plant_cell_inside_isotonic_solution_52: $i > $i).
% 29.32/29.11  tff(decl_61316, type, fn_plant_cell_inside_isotonic_solution_53: $i > $i).
% 29.32/29.11  tff(decl_61317, type, fn_plant_cell_inside_isotonic_solution_54: $i > $i).
% 29.32/29.11  tff(decl_61318, type, fn_plant_cell_inside_isotonic_solution_55: $i > $i).
% 29.32/29.11  tff(decl_61319, type, fn_plant_cell_inside_isotonic_solution_56: $i > $i).
% 29.32/29.11  tff(decl_61320, type, fn_plant_cell_inside_isotonic_solution_57: $i > $i).
% 29.32/29.11  tff(decl_61321, type, fn_plant_cell_inside_isotonic_solution_58: $i > $i).
% 29.32/29.11  tff(decl_61322, type, fn_plant_cell_inside_isotonic_solution_59: $i > $i).
% 29.32/29.11  tff(decl_61323, type, fn_plant_cell_inside_isotonic_solution_60: $i > $i).
% 29.32/29.11  tff(decl_61324, type, fn_plant_cell_inside_isotonic_solution_61: $i > $i).
% 29.32/29.11  tff(decl_61325, type, fn_plant_cell_inside_isotonic_solution_62: $i > $i).
% 29.32/29.11  tff(decl_61326, type, fn_plant_cell_inside_isotonic_solution_63: $i > $i).
% 29.32/29.11  tff(decl_61327, type, fn_plant_cell_inside_isotonic_solution_64: $i > $i).
% 29.32/29.11  tff(decl_61328, type, fn_plant_cell_inside_isotonic_solution_65: $i > $i).
% 29.32/29.11  tff(decl_61329, type, fn_plant_cell_inside_isotonic_solution_68: $i > $i).
% 29.32/29.11  tff(decl_61330, type, fn_proton_pump_13: $i > $i).
% 29.32/29.11  tff(decl_61331, type, fn_proton_pump_12: $i > $i).
% 29.32/29.11  tff(decl_61332, type, fn_carrier_protein_1: $i > $i).
% 29.32/29.11  tff(decl_61333, type, fn_proton_pump_53: $i > $i).
% 29.32/29.11  tff(decl_61334, type, fn_walled_cell_inside_isotonic_solution_10: $i > $i).
% 29.32/29.11  tff(decl_61335, type, fn_walled_cell_inside_isotonic_solution_11: $i > $i).
% 29.32/29.11  tff(decl_61336, type, fn_walled_cell_inside_isotonic_solution_13: $i > $i).
% 29.32/29.11  tff(decl_61337, type, fn_walled_cell_inside_isotonic_solution_12: $i > $i).
% 29.32/29.11  tff(decl_61338, type, fn_walled_cell_inside_isotonic_solution_3: $i > $i).
% 29.32/29.11  tff(decl_61339, type, fn_walled_cell_inside_isotonic_solution_4: $i > $i).
% 29.32/29.11  tff(decl_61340, type, fn_plant_cell_inside_isotonic_solution_66: $i > $i).
% 29.32/29.11  tff(decl_61341, type, fn_plant_cell_inside_isotonic_solution_3: $i > $i).
% 29.32/29.11  tff(decl_61342, type, fn_plant_cell_inside_isotonic_solution_67: $i > $i).
% 29.32/29.11  tff(decl_61343, type, fn_plant_cell_inside_isotonic_solution_2: $i > $i).
% 29.32/29.11  tff(decl_61344, type, fn_walled_cell_inside_isotonic_solution_7: $i > $i).
% 29.32/29.11  tff(decl_61345, type, fn_walled_cell_inside_isotonic_solution_15: $i > $i).
% 29.32/29.11  tff(decl_61346, type, fn_walled_cell_inside_isotonic_solution_14: $i > $i).
% 29.32/29.11  tff(decl_61347, type, fn_plant_cell_inside_isotonic_solution_18: $i > $i).
% 29.32/29.11  tff(decl_61348, type, fn_walled_cell_inside_isotonic_solution_8: $i > $i).
% 29.32/29.11  tff(decl_61349, type, fn_walled_cell_inside_isotonic_solution_17: $i > $i).
% 29.32/29.11  tff(decl_61350, type, fn_walled_cell_inside_isotonic_solution_6: $i > $i).
% 29.32/29.11  tff(decl_61351, type, fn_walled_cell_inside_isotonic_solution_9: $i > $i).
% 29.32/29.11  tff(decl_61352, type, fn_plant_cell_inside_isotonic_solution_5: $i > $i).
% 29.32/29.11  tff(decl_61353, type, fn_plant_cell_inside_isotonic_solution_4: $i > $i).
% 29.32/29.11  tff(decl_61354, type, 'Plant-Cell-Structure': $i).
% 29.32/29.11  tff(decl_61355, type, 'A structure at the cellular level found in plant cells': $i).
% 29.32/29.11  tff(decl_61356, type, 'structure of plant cell': $i).
% 29.32/29.11  tff(decl_61357, type, 'structure-of-plant-cell': $i).
% 29.32/29.11  tff(decl_61358, type, 'plant cell structure': $i).
% 29.32/29.11  tff(decl_61359, type, 'plant-cell-structure': $i).
% 29.32/29.11  tff(decl_61360, type, 'Plant-Cell-Wall': $i).
% 29.32/29.11  tff(decl_61361, type, 'A protective layer external to the plasma membrane in the cells of plants.  Cellulose is the primary component in plant cell walls.': $i).
% 29.32/29.11  tff(decl_61362, type, 'plant cell wall': $i).
% 29.32/29.11  tff(decl_61363, type, 'plant cell-wall': $i).
% 29.32/29.11  tff(decl_61364, type, 'plant-cell-wall': $i).
% 29.32/29.11  tff(decl_61365, type, fn_plant_cell_wall_1: $i > $i).
% 29.32/29.11  tff(decl_61366, type, fn_plant_cell_wall_3: $i > $i).
% 29.32/29.11  tff(decl_61367, type, fn_plant_cell_wall_4: $i > $i).
% 29.32/29.11  tff(decl_61368, type, fn_plant_cell_wall_5: $i > $i).
% 29.32/29.11  tff(decl_61369, type, fn_plant_cell_wall_7: $i > $i).
% 29.32/29.11  tff(decl_61370, type, fn_plant_cell_wall_9: $i > $i).
% 29.32/29.11  tff(decl_61371, type, fn_plant_cell_wall_11: $i > $i).
% 29.32/29.11  tff(decl_61372, type, fn_plant_cell_wall_12: $i > $i).
% 29.32/29.11  tff(decl_61373, type, fn_plant_cell_wall_13: $i > $i).
% 29.32/29.11  tff(decl_61374, type, fn_plant_cell_wall_14: $i > $i).
% 29.32/29.11  tff(decl_61375, type, fn_plant_cell_wall_15: $i > $i).
% 29.32/29.11  tff(decl_61376, type, fn_plant_cell_wall_16: $i > $i).
% 29.32/29.11  tff(decl_61377, type, fn_plant_cell_wall_18: $i > $i).
% 29.32/29.11  tff(decl_61378, type, fn_plant_cell_wall_19: $i > $i).
% 29.32/29.11  tff(decl_61379, type, fn_plant_cell_wall_20: $i > $i).
% 29.32/29.11  tff(decl_61380, type, fn_plant_cell_wall_29: $i > $i).
% 29.32/29.11  tff(decl_61381, type, fn_plant_cell_wall_30: $i > $i).
% 29.32/29.11  tff(decl_61382, type, fn_plant_cell_wall_31: $i > $i).
% 29.32/29.11  tff(decl_61383, type, fn_plant_cell_wall_32: $i > $i).
% 29.32/29.11  tff(decl_61384, type, fn_plant_cell_wall_33: $i > $i).
% 29.32/29.11  tff(decl_61385, type, fn_plant_cell_wall_34: $i > $i).
% 29.32/29.11  tff(decl_61386, type, fn_plant_cell_wall_35: $i > $i).
% 29.32/29.11  tff(decl_61387, type, fn_plant_cell_wall_36: $i > $i).
% 29.32/29.11  tff(decl_61388, type, fn_plant_cell_wall_37: $i > $i).
% 29.32/29.11  tff(decl_61389, type, fn_plant_cell_wall_38: $i > $i).
% 29.32/29.11  tff(decl_61390, type, fn_plant_cell_wall_39: $i > $i).
% 29.32/29.11  tff(decl_61391, type, fn_plant_cell_wall_40: $i > $i).
% 29.32/29.11  tff(decl_61392, type, fn_plant_cell_wall_41: $i > $i).
% 29.32/29.11  tff(decl_61393, type, fn_plant_cell_wall_42: $i > $i).
% 29.32/29.11  tff(decl_61394, type, fn_plant_cell_wall_43: $i > $i).
% 29.32/29.11  tff(decl_61395, type, fn_plant_cell_wall_44: $i > $i).
% 29.32/29.11  tff(decl_61396, type, fn_plant_cell_wall_45: $i > $i).
% 29.32/29.11  tff(decl_61397, type, fn_plant_cell_wall_46: $i > $i).
% 29.32/29.11  tff(decl_61398, type, fn_plant_cell_wall_47: $i > $i).
% 29.32/29.11  tff(decl_61399, type, fn_plant_cell_wall_48: $i > $i).
% 29.32/29.11  tff(decl_61400, type, fn_plant_cell_wall_49: $i > $i).
% 29.32/29.11  tff(decl_61401, type, fn_plant_cell_wall_50: $i > $i).
% 29.32/29.11  tff(decl_61402, type, polymer_0: $i).
% 29.32/29.11  tff(decl_61403, type, fn_plant_cell_wall_54: $i > $i).
% 29.32/29.11  tff(decl_61404, type, fn_plant_cell_wall_53: $i > $i).
% 29.32/29.11  tff(decl_61405, type, fn_plant_cell_wall_52: $i > $i).
% 29.32/29.11  tff(decl_61406, type, fn_plant_cell_wall_51: $i > $i).
% 29.32/29.11  tff(decl_61407, type, plant_cloning_1: $i > $o).
% 29.32/29.11  tff(decl_61408, type, 'Plant-Cloning': $i).
% 29.32/29.11  tff(decl_61409, type, 'Producing genetically identical copies of a plant.  For plants, this includes vegetative reproduction.': $i).
% 29.32/29.11  tff(decl_61410, type, 'cloning of plant': $i).
% 29.32/29.11  tff(decl_61411, type, 'plant cloning': $i).
% 29.32/29.11  tff(decl_61412, type, 'plant-cloning': $i).
% 29.32/29.11  tff(decl_61413, type, fn_plant_cloning_1: $i > $i).
% 29.32/29.11  tff(decl_61414, type, fn_plant_cloning_2: $i > $i).
% 29.32/29.11  tff(decl_61415, type, fn_plant_cloning_3: $i > $i).
% 29.32/29.11  tff(decl_61416, type, fn_plant_cloning_4: $i > $i).
% 29.32/29.11  tff(decl_61417, type, fn_plant_cloning_5: $i > $i).
% 29.32/29.11  tff(decl_61418, type, fn_plant_cloning_6: $i > $i).
% 29.32/29.11  tff(decl_61419, type, fn_plant_cloning_7: $i > $i).
% 29.32/29.11  tff(decl_61420, type, fn_plant_cloning_8: $i > $i).
% 29.32/29.11  tff(decl_61421, type, 'Plant-Development': $i).
% 29.32/29.11  tff(decl_61422, type, 'The developmental processes that occur during the life of a plant.': $i).
% 29.32/29.11  tff(decl_61423, type, 'development of plant': $i).
% 29.32/29.11  tff(decl_61424, type, 'plant development': $i).
% 29.32/29.11  tff(decl_61425, type, 'plant-development': $i).
% 29.32/29.11  tff(decl_61426, type, fn_plant_development_1: $i > $i).
% 29.32/29.11  tff(decl_61427, type, fn_plant_development_2: $i > $i).
% 29.32/29.11  tff(decl_61428, type, fn_plant_development_3: $i > $i).
% 29.32/29.11  tff(decl_61429, type, fn_plant_development_4: $i > $i).
% 29.32/29.11  tff(decl_61430, type, fn_plant_development_5: $i > $i).
% 29.32/29.11  tff(decl_61431, type, fn_plant_development_6: $i > $i).
% 29.32/29.11  tff(decl_61432, type, fn_plant_development_7: $i > $i).
% 29.32/29.11  tff(decl_61433, type, fn_plant_development_8: $i > $i).
% 29.32/29.11  tff(decl_61434, type, fn_plant_development_9: $i > $i).
% 29.32/29.11  tff(decl_61435, type, fn_plant_development_10: $i > $i).
% 29.32/29.11  tff(decl_61436, type, fn_plant_development_11: $i > $i).
% 29.32/29.11  tff(decl_61437, type, fn_plant_development_12: $i > $i).
% 29.32/29.11  tff(decl_61438, type, fn_plant_development_13: $i > $i).
% 29.32/29.11  tff(decl_61439, type, fn_plant_development_14: $i > $i).
% 29.32/29.11  tff(decl_61440, type, fn_plant_development_15: $i > $i).
% 29.32/29.11  tff(decl_61441, type, fn_plant_development_16: $i > $i).
% 29.32/29.11  tff(decl_61442, type, fn_plant_development_17: $i > $i).
% 29.32/29.11  tff(decl_61443, type, fn_plant_development_18: $i > $i).
% 29.32/29.11  tff(decl_61444, type, fn_plant_development_19: $i > $i).
% 29.32/29.11  tff(decl_61445, type, fn_plant_development_20: $i > $i).
% 29.32/29.11  tff(decl_61446, type, fn_plant_development_21: $i > $i).
% 29.32/29.11  tff(decl_61447, type, fn_plant_development_22: $i > $i).
% 29.32/29.11  tff(decl_61448, type, fn_plant_development_23: $i > $i).
% 29.32/29.11  tff(decl_61449, type, fn_plant_development_24: $i > $i).
% 29.32/29.11  tff(decl_61450, type, fn_plant_development_25: $i > $i).
% 29.32/29.11  tff(decl_61451, type, fn_plant_development_26: $i > $i).
% 29.32/29.11  tff(decl_61452, type, root_apical_meristem_1: $i > $o).
% 29.32/29.11  tff(decl_61453, type, fn_plant_development_27: $i > $i).
% 29.32/29.11  tff(decl_61454, type, fn_plant_development_28: $i > $i).
% 29.32/29.11  tff(decl_61455, type, fn_plant_development_29: $i > $i).
% 29.32/29.11  tff(decl_61456, type, fn_plant_development_30: $i > $i).
% 29.32/29.11  tff(decl_61457, type, fn_plant_development_31: $i > $i).
% 29.32/29.11  tff(decl_61458, type, fn_plant_development_32: $i > $i).
% 29.32/29.11  tff(decl_61459, type, fn_plant_development_33: $i > $i).
% 29.32/29.11  tff(decl_61460, type, fn_plant_development_34: $i > $i).
% 29.32/29.11  tff(decl_61461, type, fn_plant_development_35: $i > $i).
% 29.32/29.11  tff(decl_61462, type, fn_plant_development_36: $i > $i).
% 29.32/29.11  tff(decl_61463, type, fn_plant_development_37: $i > $i).
% 29.32/29.11  tff(decl_61464, type, fn_plant_development_38: $i > $i).
% 29.32/29.11  tff(decl_61465, type, fn_shoot_apical_meristem_2: $i > $i).
% 29.32/29.11  tff(decl_61466, type, fn_root_apical_meristem_2: $i > $i).
% 29.32/29.11  tff(decl_61467, type, fn_root_apical_meristem_3: $i > $i).
% 29.32/29.11  tff(decl_61468, type, plant_disease_1: $i > $o).
% 29.32/29.11  tff(decl_61469, type, 'Plant-Disease': $i).
% 29.32/29.11  tff(decl_61470, type, 'Plant diseases are usually caused by fungi, bacteria and viruses. Also there are other diseases which are caused by adverse environmental conditions.': $i).
% 29.32/29.11  tff(decl_61471, type, 'plant disease': $i).
% 29.32/29.11  tff(decl_61472, type, 'disease of plant': $i).
% 29.32/29.11  tff(decl_61473, type, 'plant-disease': $i).
% 29.32/29.11  tff(decl_61474, type, 'Plant-Embryo': $i).
% 29.32/29.11  tff(decl_61475, type, 'A plant embryo is an undeveloped plant inside a seed.': $i).
% 29.32/29.11  tff(decl_61476, type, 'embryo of plant': $i).
% 29.32/29.11  tff(decl_61477, type, 'plant embryo': $i).
% 29.32/29.11  tff(decl_61478, type, 'plant-embryo': $i).
% 29.32/29.11  tff(decl_61479, type, 'Plant-Fat': $i).
% 29.32/29.11  tff(decl_61480, type, 'The unsaturated fat obtained from plants is called plant fat.': $i).
% 29.32/29.11  tff(decl_61481, type, 'fat of plant': $i).
% 29.32/29.11  tff(decl_61482, type, 'plant fat': $i).
% 29.32/29.11  tff(decl_61483, type, 'plant-fat': $i).
% 29.32/29.11  tff(decl_61484, type, 'Plant-Fertilization': $i).
% 29.32/29.11  tff(decl_61485, type, 'In plants, the union of haploid gametes to produce a diploid zygote.': $i).
% 29.32/29.11  tff(decl_61486, type, 'fertilization of plant': $i).
% 29.32/29.11  tff(decl_61487, type, 'plant fertilization': $i).
% 29.32/29.11  tff(decl_61488, type, 'plant-fertilization': $i).
% 29.32/29.11  tff(decl_61489, type, 'Plant-Gene': $i).
% 29.32/29.11  tff(decl_61490, type, 'A gene of a plant.': $i).
% 29.32/29.11  tff(decl_61491, type, 'gene of plant': $i).
% 29.32/29.11  tff(decl_61492, type, 'plant gene': $i).
% 29.32/29.11  tff(decl_61493, type, 'plant-gene': $i).
% 29.32/29.11  tff(decl_61494, type, 'Plant-Growth': $i).
% 29.32/29.11  tff(decl_61495, type, 'A process related to the growth of plants.': $i).
% 29.32/29.11  tff(decl_61496, type, 'growth of plant': $i).
% 29.32/29.11  tff(decl_61497, type, 'plant growth': $i).
% 29.32/29.11  tff(decl_61498, type, 'plant-growth': $i).
% 29.32/29.11  tff(decl_61499, type, fn_plant_growth_3: $i > $i).
% 29.32/29.11  tff(decl_61500, type, fn_plant_growth_4: $i > $i).
% 29.32/29.11  tff(decl_61501, type, fn_plant_growth_5: $i > $i).
% 29.32/29.11  tff(decl_61502, type, fn_plant_growth_6: $i > $i).
% 29.32/29.11  tff(decl_61503, type, fn_plant_growth_7: $i > $i).
% 29.32/29.11  tff(decl_61504, type, 'Plant-Hormone': $i).
% 29.32/29.11  tff(decl_61505, type, 'Any of several chemicals produced by plants that control or regulate physiological processes such as growth, development, metabolism, and responses to the environment.': $i).
% 29.32/29.11  tff(decl_61506, type, 'hormone of plant': $i).
% 29.32/29.11  tff(decl_61507, type, 'plant hormone': $i).
% 29.32/29.11  tff(decl_61508, type, 'plant-hormone': $i).
% 29.32/29.11  tff(decl_61509, type, 'Plant-Intercellular-Process': $i).
% 29.32/29.11  tff(decl_61510, type, 'Intercellular process that occurs in plants.': $i).
% 29.32/29.11  tff(decl_61511, type, 'plant intercellular process': $i).
% 29.32/29.11  tff(decl_61512, type, 'plant-intercellular-process': $i).
% 29.32/29.11  tff(decl_61513, type, 'Plant-Life-Cycle': $i).
% 29.32/29.11  tff(decl_61514, type, 'The plant life cycle starts with a seed, which germinates and grows into a plant.': $i).
% 29.32/29.11  tff(decl_61515, type, 'plant life cycle': $i).
% 29.32/29.11  tff(decl_61516, type, 'plant-life-cycle': $i).
% 29.32/29.11  tff(decl_61517, type, 'Plant-Metabolic-Cell': $i).
% 29.32/29.11  tff(decl_61518, type, 'Plant cell which participates in metabolic reactions.': $i).
% 29.32/29.11  tff(decl_61519, type, 'plant metabolic cell': $i).
% 29.32/29.11  tff(decl_61520, type, 'plant-metabolic-cell': $i).
% 29.32/29.11  tff(decl_61521, type, fn_plant_metabolic_cell_1: $i > $i).
% 29.32/29.11  tff(decl_61522, type, fn_plant_metabolic_cell_2: $i > $i).
% 29.32/29.11  tff(decl_61523, type, fn_plant_metabolic_cell_3: $i > $i).
% 29.32/29.11  tff(decl_61524, type, fn_plant_metabolic_cell_9: $i > $i).
% 29.32/29.11  tff(decl_61525, type, fn_plant_metabolic_cell_11: $i > $i).
% 29.32/29.11  tff(decl_61526, type, fn_plant_metabolic_cell_13: $i > $i).
% 29.32/29.11  tff(decl_61527, type, fn_plant_metabolic_cell_14: $i > $i).
% 29.32/29.11  tff(decl_61528, type, fn_plant_metabolic_cell_15: $i > $i).
% 29.32/29.11  tff(decl_61529, type, fn_plant_metabolic_cell_23: $i > $i).
% 29.32/29.11  tff(decl_61530, type, fn_plant_metabolic_cell_24: $i > $i).
% 29.32/29.11  tff(decl_61531, type, fn_plant_metabolic_cell_26: $i > $i).
% 29.32/29.11  tff(decl_61532, type, fn_plant_metabolic_cell_27: $i > $i).
% 29.32/29.11  tff(decl_61533, type, fn_plant_metabolic_cell_29: $i > $i).
% 29.32/29.11  tff(decl_61534, type, fn_plant_metabolic_cell_30: $i > $i).
% 29.32/29.11  tff(decl_61535, type, fn_plant_metabolic_cell_31: $i > $i).
% 29.32/29.11  tff(decl_61536, type, fn_plant_metabolic_cell_32: $i > $i).
% 29.32/29.11  tff(decl_61537, type, fn_plant_metabolic_cell_33: $i > $i).
% 29.32/29.11  tff(decl_61538, type, fn_plant_metabolic_cell_34: $i > $i).
% 29.32/29.11  tff(decl_61539, type, fn_plant_metabolic_cell_40: $i > $i).
% 29.32/29.11  tff(decl_61540, type, fn_plant_metabolic_cell_41: $i > $i).
% 29.32/29.11  tff(decl_61541, type, fn_plant_metabolic_cell_42: $i > $i).
% 29.32/29.11  tff(decl_61542, type, fn_plant_metabolic_cell_4: $i > $i).
% 29.32/29.11  tff(decl_61543, type, plant_mitotic_cycle_1: $i > $o).
% 29.32/29.11  tff(decl_61544, type, 'Plant-Mitotic-Cycle': $i).
% 29.32/29.11  tff(decl_61545, type, 'Cell cycle which involves mitosis in plant cells.': $i).
% 29.32/29.11  tff(decl_61546, type, 'plant mitotic cycle': $i).
% 29.32/29.11  tff(decl_61547, type, 'plant-mitotic-cycle': $i).
% 29.32/29.11  tff(decl_61548, type, fn_plant_mitotic_cycle_1: $i > $i).
% 29.32/29.11  tff(decl_61549, type, fn_plant_mitotic_cycle_2: $i > $i).
% 29.32/29.11  tff(decl_61550, type, fn_plant_mitotic_cycle_3: $i > $i).
% 29.32/29.11  tff(decl_61551, type, fn_plant_mitotic_cycle_4: $i > $i).
% 29.32/29.11  tff(decl_61552, type, fn_plant_mitotic_cycle_5: $i > $i).
% 29.32/29.11  tff(decl_61553, type, fn_plant_mitotic_cycle_6: $i > $i).
% 29.32/29.11  tff(decl_61554, type, fn_plant_mitotic_cycle_7: $i > $i).
% 29.32/29.11  tff(decl_61555, type, fn_plant_mitotic_cycle_10: $i > $i).
% 29.32/29.11  tff(decl_61556, type, fn_plant_mitotic_cycle_11: $i > $i).
% 29.32/29.11  tff(decl_61557, type, fn_plant_mitotic_cycle_12: $i > $i).
% 29.32/29.11  tff(decl_61558, type, fn_plant_mitotic_cycle_13: $i > $i).
% 29.32/29.11  tff(decl_61559, type, fn_plant_mitotic_cycle_14: $i > $i).
% 29.32/29.11  tff(decl_61560, type, fn_plant_mitotic_cycle_15: $i > $i).
% 29.32/29.11  tff(decl_61561, type, fn_plant_mitotic_cycle_16: $i > $i).
% 29.32/29.11  tff(decl_61562, type, fn_plant_mitotic_cycle_17: $i > $i).
% 29.32/29.11  tff(decl_61563, type, fn_plant_mitotic_cycle_18: $i > $i).
% 29.32/29.11  tff(decl_61564, type, fn_plant_mitotic_cycle_19: $i > $i).
% 29.32/29.11  tff(decl_61565, type, fn_plant_mitotic_cycle_20: $i > $i).
% 29.32/29.11  tff(decl_61566, type, fn_plant_mitotic_cycle_21: $i > $i).
% 29.32/29.11  tff(decl_61567, type, fn_plant_mitotic_cycle_22: $i > $i).
% 29.32/29.11  tff(decl_61568, type, fn_plant_mitotic_cycle_23: $i > $i).
% 29.32/29.11  tff(decl_61569, type, fn_plant_mitotic_cycle_24: $i > $i).
% 29.32/29.11  tff(decl_61570, type, fn_plant_mitotic_cycle_25: $i > $i).
% 29.32/29.11  tff(decl_61571, type, fn_plant_mitotic_cycle_26: $i > $i).
% 29.32/29.11  tff(decl_61572, type, fn_plant_mitotic_cycle_27: $i > $i).
% 29.32/29.11  tff(decl_61573, type, fn_plant_mitotic_cycle_28: $i > $i).
% 29.32/29.11  tff(decl_61574, type, fn_plant_mitotic_cycle_29: $i > $i).
% 29.32/29.11  tff(decl_61575, type, fn_plant_mitotic_cycle_30: $i > $i).
% 29.32/29.11  tff(decl_61576, type, fn_plant_mitotic_cycle_31: $i > $i).
% 29.32/29.11  tff(decl_61577, type, fn_plant_mitotic_cycle_32: $i > $i).
% 29.32/29.11  tff(decl_61578, type, fn_plant_mitotic_cycle_33: $i > $i).
% 29.32/29.11  tff(decl_61579, type, fn_plant_mitotic_cycle_34: $i > $i).
% 29.32/29.11  tff(decl_61580, type, fn_plant_mitotic_cycle_35: $i > $i).
% 29.32/29.11  tff(decl_61581, type, fn_plant_mitotic_cycle_36: $i > $i).
% 29.32/29.11  tff(decl_61582, type, fn_plant_mitotic_cycle_37: $i > $i).
% 29.32/29.11  tff(decl_61583, type, fn_plant_mitotic_cycle_38: $i > $i).
% 29.32/29.11  tff(decl_61584, type, fn_prophase_3: $i > $i).
% 29.32/29.11  tff(decl_61585, type, fn_prophase_13: $i > $i).
% 29.32/29.11  tff(decl_61586, type, fn_prophase_24: $i > $i).
% 29.32/29.11  tff(decl_61587, type, fn_plant_mitotic_cycle_9: $i > $i).
% 29.32/29.11  tff(decl_61588, type, fn_plant_mitotic_cycle_8: $i > $i).
% 29.32/29.11  tff(decl_61589, type, plant_nutritional_requirement_1: $i > $o).
% 29.32/29.11  tff(decl_61590, type, 'Plant-Nutritional-Requirement': $i).
% 29.32/29.11  tff(decl_61591, type, 'Chemicals and elements that are needed by plants in order to sustain healthy life.': $i).
% 29.32/29.11  tff(decl_61592, type, 'plant nutritional requirement': $i).
% 29.32/29.11  tff(decl_61593, type, 'plant-nutritional-requirement': $i).
% 29.32/29.11  tff(decl_61594, type, fn_plant_nutritional_requirement_2: $i > $i).
% 29.32/29.11  tff(decl_61595, type, fn_plant_nutritional_requirement_3: $i > $i).
% 29.32/29.11  tff(decl_61596, type, fn_plant_nutritional_requirement_4: $i > $i).
% 29.32/29.11  tff(decl_61597, type, fn_plant_nutritional_requirement_5: $i > $i).
% 29.32/29.11  tff(decl_61598, type, fn_plant_nutritional_requirement_6: $i > $i).
% 29.32/29.11  tff(decl_61599, type, fn_plant_nutritional_requirement_7: $i > $i).
% 29.32/29.11  tff(decl_61600, type, fn_plant_nutritional_requirement_8: $i > $i).
% 29.32/29.11  tff(decl_61601, type, fn_plant_nutritional_requirement_9: $i > $i).
% 29.32/29.11  tff(decl_61602, type, fn_plant_nutritional_requirement_10: $i > $i).
% 29.32/29.11  tff(decl_61603, type, fn_plant_nutritional_requirement_11: $i > $i).
% 29.32/29.11  tff(decl_61604, type, fn_plant_nutritional_requirement_12: $i > $i).
% 29.32/29.11  tff(decl_61605, type, fn_plant_nutritional_requirement_13: $i > $i).
% 29.32/29.11  tff(decl_61606, type, fn_plant_nutritional_requirement_14: $i > $i).
% 29.32/29.11  tff(decl_61607, type, fn_plant_nutritional_requirement_15: $i > $i).
% 29.32/29.11  tff(decl_61608, type, 'Plant-Organ': $i).
% 29.32/29.11  tff(decl_61609, type, 'In plants, a specialized center consisting of several tissues working together to perform a specific function.': $i).
% 29.32/29.11  tff(decl_61610, type, 'organ of plant': $i).
% 29.32/29.11  tff(decl_61611, type, 'plant organ': $i).
% 29.32/29.11  tff(decl_61612, type, 'plant-organ': $i).
% 29.32/29.11  tff(decl_61613, type, 'Plant-Process': $i).
% 29.32/29.11  tff(decl_61614, type, 'A process unique to plants.': $i).
% 29.32/29.11  tff(decl_61615, type, 'process of plant': $i).
% 29.32/29.11  tff(decl_61616, type, 'plant process': $i).
% 29.32/29.11  tff(decl_61617, type, 'plant-process': $i).
% 29.32/29.11  tff(decl_61618, type, 'Plant-Region': $i).
% 29.32/29.11  tff(decl_61619, type, 'A region of a plant.': $i).
% 29.32/29.11  tff(decl_61620, type, 'region of plant': $i).
% 29.32/29.11  tff(decl_61621, type, 'plant region': $i).
% 29.32/29.11  tff(decl_61622, type, 'plant-region': $i).
% 29.32/29.11  tff(decl_61623, type, 'Plant-Reproduction': $i).
% 29.32/29.11  tff(decl_61624, type, 'The production of new individuals, in plants.': $i).
% 29.32/29.11  tff(decl_61625, type, 'reproduction of plant': $i).
% 29.32/29.11  tff(decl_61626, type, 'plant reproduction': $i).
% 29.32/29.11  tff(decl_61627, type, 'plant-reproduction': $i).
% 29.32/29.11  tff(decl_61628, type, 'Plant-Response': $i).
% 29.32/29.11  tff(decl_61629, type, 'Any of the ways that a plant responds to its environment.': $i).
% 29.32/29.11  tff(decl_61630, type, 'response of plant': $i).
% 29.32/29.11  tff(decl_61631, type, 'plant response': $i).
% 29.32/29.11  tff(decl_61632, type, 'plant-response': $i).
% 29.32/29.11  tff(decl_61633, type, 'Plant-Space': $i).
% 29.32/29.11  tff(decl_61634, type, 'A space in plants which is surrounded by anatomical structures.': $i).
% 29.32/29.11  tff(decl_61635, type, 'space of plant': $i).
% 29.32/29.11  tff(decl_61636, type, 'plant space': $i).
% 29.32/29.11  tff(decl_61637, type, 'plant-space': $i).
% 29.32/29.11  tff(decl_61638, type, 'Plant-Specific-Tissue': $i).
% 29.32/29.11  tff(decl_61639, type, 'Tissue specific to plants.': $i).
% 29.32/29.11  tff(decl_61640, type, 'plant tissue': $i).
% 29.32/29.11  tff(decl_61641, type, 'plant specific tissue': $i).
% 29.32/29.11  tff(decl_61642, type, 'plant-specific-tissue': $i).
% 29.32/29.11  tff(decl_61643, type, fn_plant_specific_tissue_1: $i > $i).
% 29.32/29.11  tff(decl_61644, type, fn_plant_specific_tissue_2: $i > $i).
% 29.32/29.11  tff(decl_61645, type, 'Plant-Spore': $i).
% 29.32/29.11  tff(decl_61646, type, 'A plant spore is a small usually single-celled asexual reproductive body produced by many nonflowering plants. Vascular plant spores are always haploid.': $i).
% 29.32/29.11  tff(decl_61647, type, 'spore of plant': $i).
% 29.32/29.11  tff(decl_61648, type, 'plant spore': $i).
% 29.32/29.11  tff(decl_61649, type, 'plant-spore': $i).
% 29.32/29.11  tff(decl_61650, type, 'Plant-Statolith': $i).
% 29.32/29.11  tff(decl_61651, type, 'In plants, a specialized plastid containing dense starch grains; the entire structure may function in detecting gravity.': $i).
% 29.32/29.11  tff(decl_61652, type, 'plant statolith': $i).
% 29.32/29.11  tff(decl_61653, type, 'plant-statolith': $i).
% 29.32/29.11  tff(decl_61654, type, fn_plant_statolith_1: $i > $i).
% 29.32/29.11  tff(decl_61655, type, fn_plant_statolith_2: $i > $i).
% 29.32/29.11  tff(decl_61656, type, fn_plant_statolith_3: $i > $i).
% 29.32/29.11  tff(decl_61657, type, fn_plant_statolith_5: $i > $i).
% 29.32/29.11  tff(decl_61658, type, fn_plant_statolith_6: $i > $i).
% 29.32/29.11  tff(decl_61659, type, fn_plant_statolith_7: $i > $i).
% 29.32/29.11  tff(decl_61660, type, fn_plant_statolith_8: $i > $i).
% 29.32/29.11  tff(decl_61661, type, fn_plant_statolith_9: $i > $i).
% 29.32/29.11  tff(decl_61662, type, plant_storage_polysaccharide_1: $i > $o).
% 29.32/29.11  tff(decl_61663, type, 'Plant-Storage-Polysaccharide': $i).
% 29.32/29.11  tff(decl_61664, type, 'A polysaccharide which is used for energy storage in plants.': $i).
% 29.32/29.11  tff(decl_61665, type, 'plant storage polysaccharide': $i).
% 29.32/29.11  tff(decl_61666, type, 'plant-storage-polysaccharide': $i).
% 29.32/29.11  tff(decl_61667, type, 'Plant-Structure': $i).
% 29.32/29.11  tff(decl_61668, type, 'The way a plant is constructed and the arrangement of its parts.': $i).
% 29.32/29.11  tff(decl_61669, type, 'plant morphology': $i).
% 29.32/29.11  tff(decl_61670, type, 'plant-morphology': $i).
% 29.32/29.11  tff(decl_61671, type, 'structure of plant': $i).
% 29.32/29.11  tff(decl_61672, type, 'plant structure': $i).
% 29.32/29.11  tff(decl_61673, type, 'plant-structure': $i).
% 29.32/29.11  tff(decl_61674, type, 'Plant-Support-Cell': $i).
% 29.32/29.11  tff(decl_61675, type, 'Plant cell which provides structural support.': $i).
% 29.32/29.11  tff(decl_61676, type, 'plant support cell': $i).
% 29.32/29.11  tff(decl_61677, type, 'plant-support-cell': $i).
% 29.32/29.11  tff(decl_61678, type, plant_system_1: $i > $o).
% 29.32/29.11  tff(decl_61679, type, 'Plant-System': $i).
% 29.32/29.11  tff(decl_61680, type, 'A group of organs in that work together in performing vital functions in plants.': $i).
% 29.32/29.11  tff(decl_61681, type, 'system of plant': $i).
% 29.32/29.11  tff(decl_61682, type, 'plant system': $i).
% 29.32/29.11  tff(decl_61683, type, 'plant-system': $i).
% 29.32/29.11  tff(decl_61684, type, 'Plant-Transport': $i).
% 29.32/29.11  tff(decl_61685, type, 'Process related to the transport of water and nutrients in plants.': $i).
% 29.32/29.11  tff(decl_61686, type, 'transport of plant': $i).
% 29.32/29.11  tff(decl_61687, type, 'plant transport': $i).
% 29.32/29.11  tff(decl_61688, type, 'plant-transport': $i).
% 29.32/29.11  tff(decl_61689, type, 'Plant-Transport-Cell': $i).
% 29.32/29.11  tff(decl_61690, type, 'Plant cell which transports water and other substances within the plant.': $i).
% 29.32/29.11  tff(decl_61691, type, 'plant transport cell': $i).
% 29.32/29.11  tff(decl_61692, type, 'plant-transport-cell': $i).
% 29.32/29.11  tff(decl_61693, type, 'Plant-Vein': $i).
% 29.32/29.11  tff(decl_61694, type, 'A vascular bundle in the leaf of a plant.': $i).
% 29.32/29.11  tff(decl_61695, type, 'vein of plant': $i).
% 29.32/29.11  tff(decl_61696, type, 'plant vein': $i).
% 29.32/29.11  tff(decl_61697, type, 'plant-vein': $i).
% 29.32/29.11  tff(decl_61698, type, 'Plant-Virus': $i).
% 29.32/29.11  tff(decl_61699, type, 'A virus affecting plants, which like all viruses must infect a host to use the cell\\s machinery to replicate.': $i).
% 29.32/29.11  tff(decl_61700, type, 'virus of plant': $i).
% 29.32/29.11  tff(decl_61701, type, 'plant virus': $i).
% 29.32/29.11  tff(decl_61702, type, 'plant-virus': $i).
% 29.32/29.11  tff(decl_61703, type, fn_plant_virus_1: $i > $i).
% 29.32/29.11  tff(decl_61704, type, fn_plant_virus_2: $i > $i).
% 29.32/29.11  tff(decl_61705, type, fn_plant_virus_3: $i > $i).
% 29.32/29.11  tff(decl_61706, type, fn_plant_virus_4: $i > $i).
% 29.32/29.11  tff(decl_61707, type, fn_plant_virus_5: $i > $i).
% 29.32/29.11  tff(decl_61708, type, fn_plant_virus_6: $i > $i).
% 29.32/29.11  tff(decl_61709, type, fn_plant_virus_7: $i > $i).
% 29.32/29.11  tff(decl_61710, type, 'Plasma': $i).
% 29.32/29.11  tff(decl_61711, type, 'The yellowish liquid component of blood, in which the various blood cells are suspended.': $i).
% 29.32/29.11  tff(decl_61712, type, plasma: $i).
% 29.32/29.11  tff(decl_61713, type, 'Plasma-Cell': $i).
% 29.32/29.11  tff(decl_61714, type, 'An antibody-secreting B cell, the major component of humoral immunity.': $i).
% 29.32/29.11  tff(decl_61715, type, 'cell of plasma': $i).
% 29.32/29.11  tff(decl_61716, type, 'plasma cell': $i).
% 29.32/29.11  tff(decl_61717, type, 'plasma-cell': $i).
% 29.32/29.11  tff(decl_61718, type, 'Plasma-membrane': $i).
% 29.32/29.11  tff(decl_61719, type, 'Plasma-membrane is a lipid bilayer that acts as a barrier enclosing cell. It is a selective membrane controlling movement of nutrients, waste material and other particles in and out of the cell': $i).
% 29.32/29.11  tff(decl_61720, type, plasmalemma: $i).
% 29.32/29.11  tff(decl_61721, type, 'cell membrane': $i).
% 29.32/29.11  tff(decl_61722, type, 'cell-membrane': $i).
% 29.32/29.11  tff(decl_61723, type, 'membrane of plasma': $i).
% 29.32/29.11  tff(decl_61724, type, 'plasma membrane': $i).
% 29.32/29.11  tff(decl_61725, type, 'plasma-membrane': $i).
% 29.32/29.11  tff(decl_61726, type, fn_plasma_membrane_2: $i > $i).
% 29.32/29.11  tff(decl_61727, type, fn_plasma_membrane_7: $i > $i).
% 29.32/29.11  tff(decl_61728, type, fn_plasma_membrane_9: $i > $i).
% 29.32/29.11  tff(decl_61729, type, fn_plasma_membrane_10: $i > $i).
% 29.32/29.11  tff(decl_61730, type, fn_plasma_membrane_13: $i > $i).
% 29.32/29.11  tff(decl_61731, type, fn_plasma_membrane_21: $i > $i).
% 29.32/29.11  tff(decl_61732, type, fn_plasma_membrane_23: $i > $i).
% 29.32/29.11  tff(decl_61733, type, fn_plasma_membrane_24: $i > $i).
% 29.32/29.11  tff(decl_61734, type, fn_plasma_membrane_25: $i > $i).
% 29.32/29.11  tff(decl_61735, type, fn_plasma_membrane_26: $i > $i).
% 29.32/29.11  tff(decl_61736, type, fn_plasma_membrane_39: $i > $i).
% 29.32/29.11  tff(decl_61737, type, fn_plasma_membrane_41: $i > $i).
% 29.32/29.11  tff(decl_61738, type, fn_plasma_membrane_42: $i > $i).
% 29.32/29.11  tff(decl_61739, type, fn_plasma_membrane_43: $i > $i).
% 29.32/29.11  tff(decl_61740, type, fn_plasma_membrane_44: $i > $i).
% 29.32/29.11  tff(decl_61741, type, fn_plasma_membrane_45: $i > $i).
% 29.32/29.11  tff(decl_61742, type, fn_plasma_membrane_46: $i > $i).
% 29.32/29.11  tff(decl_61743, type, fn_plasma_membrane_47: $i > $i).
% 29.32/29.11  tff(decl_61744, type, fn_plasma_membrane_48: $i > $i).
% 29.32/29.11  tff(decl_61745, type, fn_plasma_membrane_49: $i > $i).
% 29.32/29.11  tff(decl_61746, type, fn_plasma_membrane_56: $i > $i).
% 29.32/29.11  tff(decl_61747, type, fn_plasma_membrane_58: $i > $i).
% 29.32/29.11  tff(decl_61748, type, fn_plasma_membrane_59: $i > $i).
% 29.32/29.11  tff(decl_61749, type, fn_plasma_membrane_60: $i > $i).
% 29.32/29.11  tff(decl_61750, type, fn_plasma_membrane_75: $i > $i).
% 29.32/29.11  tff(decl_61751, type, fn_plasma_membrane_76: $i > $i).
% 29.32/29.11  tff(decl_61752, type, fn_plasma_membrane_79: $i > $i).
% 29.32/29.11  tff(decl_61753, type, 'Hydrophobic end 1': $i).
% 29.32/29.11  tff(decl_61754, type, transport_protein_0: $i).
% 29.32/29.11  tff(decl_61755, type, 'Plasmid': $i).
% 29.32/29.11  tff(decl_61756, type, fn_plasmid_2: $i > $i).
% 29.32/29.11  tff(decl_61757, type, fn_plasmid_3: $i > $i).
% 29.32/29.11  tff(decl_61758, type, fn_plasmid_4: $i > $i).
% 29.32/29.11  tff(decl_61759, type, fn_plasmid_6: $i > $i).
% 29.32/29.11  tff(decl_61760, type, 'Plasmodesmata': $i).
% 29.32/29.11  tff(decl_61761, type, 'Plasmodesmata are microscopic channels which traverse the cell walls of plant cells enabling transport and communication between them': $i).
% 29.32/29.11  tff(decl_61762, type, plasmodesma: $i).
% 29.32/29.11  tff(decl_61763, type, plasmodesmata: $i).
% 29.32/29.11  tff(decl_61764, type, fn_plasmodesmata_2: $i > $i).
% 29.32/29.11  tff(decl_61765, type, fn_plasmodesmata_4: $i > $i).
% 29.32/29.11  tff(decl_61766, type, fn_plasmodesmata_7: $i > $i).
% 29.32/29.11  tff(decl_61767, type, fn_plasmodesmata_8: $i > $i).
% 29.32/29.11  tff(decl_61768, type, fn_plasmodesmata_12: $i > $i).
% 29.32/29.11  tff(decl_61769, type, fn_plasmodesmata_14: $i > $i).
% 29.32/29.11  tff(decl_61770, type, fn_plasmodesmata_15: $i > $i).
% 29.32/29.11  tff(decl_61771, type, fn_plasmodesmata_16: $i > $i).
% 29.32/29.11  tff(decl_61772, type, 'Plasmodial-Slime-Mold': $i).
% 29.32/29.11  tff(decl_61773, type, 'Any of a group of organisms of uncertain affinity, characterized by a life cycle with several morphologic phases, amoeboid cells, flagellated cells, and a multinucleate phase.': $i).
% 29.32/29.11  tff(decl_61774, type, 'plasmodial slime mold': $i).
% 29.32/29.11  tff(decl_61775, type, 'plasmodial-slime-mold': $i).
% 29.32/29.11  tff(decl_61776, type, 'Plasmodium': $i).
% 29.32/29.11  tff(decl_61777, type, 'The multinucleate phase in the life cycle of some slime molds.': $i).
% 29.32/29.11  tff(decl_61778, type, plasmodium: $i).
% 29.32/29.11  tff(decl_61779, type, plasmogamy_1: $i > $o).
% 29.32/29.11  tff(decl_61780, type, 'Plasmogamy': $i).
% 29.32/29.11  tff(decl_61781, type, 'In fungi, the fusion of cytoplasms from two parent mycelia; occurs as one stage of fertilization.': $i).
% 29.32/29.11  tff(decl_61782, type, plasmogamy: $i).
% 29.32/29.11  tff(decl_61783, type, 'Plasmolysis': $i).
% 29.32/29.11  tff(decl_61784, type, 'Plasmolysis is the process in plant cells where the plasma membrane pulls away from the cell wall due to the loss of water through osmosis. The reverse process, cytolysis, can occur if the cell is in a hypotonic solution resulting in a higher external osmotic pressure and a net flow of water into the cell. Through observation of plasmolysis and deplasmolysis it is possible to determine the tonicity of the cell\\s environment as well as the rate solute molecules cross the cellular membrane.': $i).
% 29.32/29.11  tff(decl_61785, type, plasmolyze: $i).
% 29.32/29.11  tff(decl_61786, type, 'undergo plasmolysis': $i).
% 29.32/29.11  tff(decl_61787, type, plasmolysis: $i).
% 29.32/29.11  tff(decl_61788, type, fn_plasmolysis_3: $i > $i).
% 29.32/29.11  tff(decl_61789, type, fn_plasmolysis_4: $i > $i).
% 29.32/29.11  tff(decl_61790, type, fn_plasmolysis_11: $i > $i).
% 29.32/29.11  tff(decl_61791, type, fn_plasmolysis_12: $i > $i).
% 29.32/29.11  tff(decl_61792, type, fn_plasmolysis_13: $i > $i).
% 29.32/29.11  tff(decl_61793, type, fn_plasmolysis_14: $i > $i).
% 29.32/29.11  tff(decl_61794, type, fn_plasmolysis_15: $i > $i).
% 29.32/29.11  tff(decl_61795, type, fn_plasmolysis_17: $i > $i).
% 29.32/29.11  tff(decl_61796, type, fn_plasmolysis_18: $i > $i).
% 29.32/29.11  tff(decl_61797, type, fn_plasmolysis_20: $i > $i).
% 29.32/29.11  tff(decl_61798, type, fn_plasmolysis_21: $i > $i).
% 29.32/29.11  tff(decl_61799, type, fn_plasmolysis_26: $i > $i).
% 29.32/29.11  tff(decl_61800, type, 'Plastic': $i).
% 29.32/29.11  tff(decl_61801, type, plastic: $i).
% 29.32/29.11  tff(decl_61802, type, 'Plastid': $i).
% 29.32/29.11  tff(decl_61803, type, 'Plastids are major organelles found in the cells of plants and algae. Plastids are the site of manufacture and storage of important chemical compounds used by the cell. Plastids often contain pigments used in photosynthesis.': $i).
% 29.32/29.11  tff(decl_61804, type, plastids: $i).
% 29.32/29.11  tff(decl_61805, type, plastid: $i).
% 29.32/29.11  tff(decl_61806, type, fn_plastid_2: $i > $i).
% 29.32/29.11  tff(decl_61807, type, fn_plastid_4: $i > $i).
% 29.32/29.11  tff(decl_61808, type, fn_plastid_6: $i > $i).
% 29.32/29.11  tff(decl_61809, type, fn_plastid_7: $i > $i).
% 29.32/29.11  tff(decl_61810, type, fn_plastid_8: $i > $i).
% 29.32/29.11  tff(decl_61811, type, fn_plastid_11: $i > $i).
% 29.32/29.11  tff(decl_61812, type, fn_plastid_12: $i > $i).
% 29.32/29.11  tff(decl_61813, type, fn_plastid_13: $i > $i).
% 29.32/29.11  tff(decl_61814, type, 'Plastocyanin': $i).
% 29.32/29.11  tff(decl_61815, type, 'Plastocyanin is an important copper-containing protein involved in electron-transfer. The protein is monomeric, with a molecular weight around 10,500 Daltons, and 99 amino acids in most vascular plants. It is a member of the plastocyanin family of copper binding proteins.': $i).
% 29.32/29.11  tff(decl_61816, type, pc: $i).
% 29.32/29.11  tff(decl_61817, type, plastocyanin: $i).
% 29.32/29.11  tff(decl_61818, type, fn_plastocyanin_1: $i > $i).
% 29.32/29.11  tff(decl_61819, type, fn_plastocyanin_3: $i > $i).
% 29.32/29.11  tff(decl_61820, type, fn_plastocyanin_4: $i > $i).
% 29.32/29.11  tff(decl_61821, type, fn_plastocyanin_5: $i > $i).
% 29.32/29.11  tff(decl_61822, type, fn_plastocyanin_6: $i > $i).
% 29.32/29.11  tff(decl_61823, type, fn_plastocyanin_7: $i > $i).
% 29.32/29.11  tff(decl_61824, type, "10500.0e0": $i).
% 29.32/29.11  tff(decl_61825, type, 'Plastoquinone': $i).
% 29.32/29.11  tff(decl_61826, type, 'A mobile electron carrier that transfers electrons between photosystem-I and cytochrome during photosynthesis.': $i).
% 29.32/29.11  tff(decl_61827, type, pq: $i).
% 29.32/29.11  tff(decl_61828, type, plastoquinone: $i).
% 29.32/29.11  tff(decl_61829, type, fn_plastoquinone_1: $i > $i).
% 29.32/29.11  tff(decl_61830, type, fn_plastoquinone_2: $i > $i).
% 29.32/29.11  tff(decl_61831, type, fn_plastoquinone_5: $i > $i).
% 29.32/29.11  tff(decl_61832, type, fn_plastoquinone_6: $i > $i).
% 29.32/29.11  tff(decl_61833, type, fn_plastoquinone_7: $i > $i).
% 29.32/29.11  tff(decl_61834, type, fn_plastoquinone_8: $i > $i).
% 29.32/29.11  tff(decl_61835, type, fn_plastoquinone_9: $i > $i).
% 29.32/29.11  tff(decl_61836, type, fn_plastoquinone_10: $i > $i).
% 29.32/29.11  tff(decl_61837, type, fn_plastoquinone_11: $i > $i).
% 29.32/29.11  tff(decl_61838, type, fn_plastoquinone_12: $i > $i).
% 29.32/29.11  tff(decl_61839, type, fn_plastoquinone_13: $i > $i).
% 29.32/29.11  tff(decl_61840, type, fn_plastoquinone_14: $i > $i).
% 29.32/29.11  tff(decl_61841, type, fn_plastoquinone_15: $i > $i).
% 29.32/29.11  tff(decl_61842, type, fn_plastoquinone_16: $i > $i).
% 29.32/29.11  tff(decl_61843, type, fn_plastoquinone_4: $i > $i).
% 29.32/29.11  tff(decl_61844, type, 'Plate-Tectonics': $i).
% 29.32/29.11  tff(decl_61845, type, 'Theory describing large-scale movements of lithospheric plates of the earth. Seafloor spreading, subduction, and transform faults are the ways that two plates can interact. All are associated with geologic activity and earthquakes.': $i).
% 29.32/29.11  tff(decl_61846, type, 'plate-tectonics': $i).
% 29.32/29.11  tff(decl_61847, type, 'tectonics of plate': $i).
% 29.32/29.11  tff(decl_61848, type, 'plate tectonics': $i).
% 29.32/29.11  tff(decl_61849, type, 'plate-tectonic': $i).
% 29.32/29.11  tff(decl_61850, type, 'Platelet': $i).
% 29.32/29.11  tff(decl_61851, type, 'A small, irregularly shaped cell fragment that circulates in the blood and is involved in the formation of blood clots.': $i).
% 29.32/29.11  tff(decl_61852, type, thrombocyte: $i).
% 29.32/29.11  tff(decl_61853, type, platelet: $i).
% 29.32/29.11  tff(decl_61854, type, 'Platelet-Derived-Growth-Factor': $i).
% 29.32/29.11  tff(decl_61855, type, 'A protein made by platelets that stimulates blood vessel formation.': $i).
% 29.32/29.11  tff(decl_61856, type, 'platelet derived growth factor': $i).
% 29.32/29.11  tff(decl_61857, type, 'platelet-derived growth factor': $i).
% 29.32/29.11  tff(decl_61858, type, 'platelet-derived growth-factor': $i).
% 29.32/29.11  tff(decl_61859, type, 'platelet-derived-growth-factor': $i).
% 29.32/29.11  tff(decl_61860, type, platelet_formation_1: $i > $o).
% 29.32/29.11  tff(decl_61861, type, 'Platelet-Formation': $i).
% 29.32/29.11  tff(decl_61862, type, 'The process in which a megakaryocyte precurser cell fragments into thrombocytes (platelets).': $i).
% 29.32/29.11  tff(decl_61863, type, 'formation of platelet': $i).
% 29.32/29.11  tff(decl_61864, type, 'platelet formation': $i).
% 29.32/29.11  tff(decl_61865, type, 'platelet-formation': $i).
% 29.32/29.11  tff(decl_61866, type, fn_platelet_formation_1: $i > $i).
% 29.32/29.11  tff(decl_61867, type, fn_platelet_formation_2: $i > $i).
% 29.32/29.11  tff(decl_61868, type, fn_platelet_formation_3: $i > $i).
% 29.32/29.11  tff(decl_61869, type, 'Platform': $i).
% 29.32/29.11  tff(decl_61870, type, 'a horizontal architectural structure supporting everything on it': $i).
% 29.32/29.11  tff(decl_61871, type, 'supporting structure': $i).
% 29.32/29.11  tff(decl_61872, type, supporting_structure: $i).
% 29.32/29.11  tff(decl_61873, type, platform: $i).
% 29.32/29.11  tff(decl_61874, type, fn_platform_2: $i > $i).
% 29.32/29.11  tff(decl_61875, type, platinum_1: $i > $o).
% 29.32/29.11  tff(decl_61876, type, 'Platinum': $i).
% 29.32/29.11  tff(decl_61877, type, 'Platinum is a metal atom with atomic number 78. It is represented by the symbol Pt.': $i).
% 29.32/29.11  tff(decl_61878, type, platinum: $i).
% 29.32/29.11  tff(decl_61879, type, 'Pt': $i).
% 29.32/29.11  tff(decl_61880, type, fn_platinum_3: $i > $i).
% 29.32/29.11  tff(decl_61881, type, fn_platinum_4: $i > $i).
% 29.32/29.11  tff(decl_61882, type, fn_platinum_5: $i > $i).
% 29.32/29.11  tff(decl_61883, type, fn_platinum_9: $i > $i).
% 29.32/29.11  tff(decl_61884, type, fn_platinum_10: $i > $i).
% 29.32/29.11  tff(decl_61885, type, fn_platinum_11: $i > $i).
% 29.32/29.11  tff(decl_61886, type, fn_platinum_12: $i > $i).
% 29.32/29.11  tff(decl_61887, type, "117": $i).
% 29.32/29.11  tff(decl_61888, type, "2.28": $i).
% 29.32/29.11  tff(decl_61889, type, "195": $i).
% 29.32/29.11  tff(decl_61890, type, "195.1": $i).
% 29.32/29.11  tff(decl_61891, type, fn_platinum_7: $i > $i).
% 29.32/29.11  tff(decl_61892, type, fn_platinum_8: $i > $i).
% 29.32/29.11  tff(decl_61893, type, fn_platinum_6: $i > $i).
% 29.32/29.11  tff(decl_61894, type, 'Platyhelminthes': $i).
% 29.32/29.11  tff(decl_61895, type, 'A phylum of comparatively simple, unsegmented, wormlike animals with flattened bodies. They have bilateral symmetry but no specialized organs for respiration or circulation. Many are free-living (non-parasitic) but most are endoparasites or ectoparasites of vertebrates.': $i).
% 29.32/29.11  tff(decl_61896, type, 'flat worm': $i).
% 29.32/29.11  tff(decl_61897, type, 'flat-worm': $i).
% 29.32/29.11  tff(decl_61898, type, platyhelminth: $i).
% 29.32/29.11  tff(decl_61899, type, platyhelminthes: $i).
% 29.32/29.11  tff(decl_61900, type, fn_platyhelminthes_5: $i > $i).
% 29.32/29.11  tff(decl_61901, type, fn_platyhelminthes_6: $i > $i).
% 29.32/29.11  tff(decl_61902, type, fn_platyhelminthes_7: $i > $i).
% 29.32/29.11  tff(decl_61903, type, fn_platyhelminthes_8: $i > $i).
% 29.32/29.11  tff(decl_61904, type, fn_platyhelminthes_12: $i > $i).
% 29.32/29.11  tff(decl_61905, type, fn_platyhelminthes_13: $i > $i).
% 29.32/29.11  tff(decl_61906, type, fn_platyhelminthes_14: $i > $i).
% 29.32/29.11  tff(decl_61907, type, fn_platyhelminthes_15: $i > $i).
% 29.32/29.11  tff(decl_61908, type, fn_platyhelminthes_16: $i > $i).
% 29.32/29.11  tff(decl_61909, type, fn_platyhelminthes_17: $i > $i).
% 29.32/29.11  tff(decl_61910, type, fn_platyhelminthes_18: $i > $i).
% 29.32/29.11  tff(decl_61911, type, fn_platyhelminthes_19: $i > $i).
% 29.32/29.11  tff(decl_61912, type, fn_platyhelminthes_20: $i > $i).
% 29.32/29.11  tff(decl_61913, type, pleiotropy_1: $i > $o).
% 29.32/29.11  tff(decl_61914, type, 'Pleiotropy': $i).
% 29.32/29.11  tff(decl_61915, type, 'The ability of a single gene to have multiple effects.': $i).
% 29.32/29.11  tff(decl_61916, type, pleiotropy: $i).
% 29.32/29.11  tff(decl_61917, type, fn_pleiotropy_1: $i > $i).
% 29.32/29.11  tff(decl_61918, type, fn_pleiotropy_2: $i > $i).
% 29.32/29.11  tff(decl_61919, type, fn_pleiotropy_3: $i > $i).
% 29.32/29.11  tff(decl_61920, type, pluripotent_stem_cell_1: $i > $o).
% 29.32/29.11  tff(decl_61921, type, 'Pluripotent-Stem-Cell': $i).
% 29.32/29.11  tff(decl_61922, type, 'Pluripotent stem cells have the potential to differentiate into specialized cells in the body but they can\\t develop into a complete organism. A cell that can give rise to many, but not all, parts of an organism.': $i).
% 29.32/29.11  tff(decl_61923, type, 'pluripotent stem cell': $i).
% 29.32/29.11  tff(decl_61924, type, 'pluripotent-stem-cell': $i).
% 29.32/29.11  tff(decl_61925, type, fn_pluripotent_stem_cell_1: $i > $i).
% 29.32/29.11  tff(decl_61926, type, fn_pluripotent_stem_cell_2: $i > $i).
% 29.32/29.11  tff(decl_61927, type, fn_pluripotent_stem_cell_3: $i > $i).
% 29.32/29.11  tff(decl_61928, type, fn_pluripotent_stem_cell_4: $i > $i).
% 29.32/29.11  tff(decl_61929, type, fn_pluripotent_stem_cell_5: $i > $i).
% 29.32/29.11  tff(decl_61930, type, fn_pluripotent_stem_cell_6: $i > $i).
% 29.32/29.11  tff(decl_61931, type, fn_pluripotent_stem_cell_7: $i > $i).
% 29.32/29.11  tff(decl_61932, type, fn_pluripotent_stem_cell_8: $i > $i).
% 29.32/29.11  tff(decl_61933, type, fn_pluripotent_stem_cell_9: $i > $i).
% 29.32/29.11  tff(decl_61934, type, fn_pluripotent_stem_cell_10: $i > $i).
% 29.32/29.11  tff(decl_61935, type, fn_pluripotent_stem_cell_13: $i > $i).
% 29.32/29.11  tff(decl_61936, type, fn_pluripotent_stem_cell_14: $i > $i).
% 29.32/29.11  tff(decl_61937, type, fn_pluripotent_stem_cell_15: $i > $i).
% 29.32/29.11  tff(decl_61938, type, fn_pluripotent_stem_cell_16: $i > $i).
% 29.32/29.11  tff(decl_61939, type, fn_pluripotent_stem_cell_17: $i > $i).
% 29.32/29.11  tff(decl_61940, type, fn_pluripotent_stem_cell_18: $i > $i).
% 29.32/29.11  tff(decl_61941, type, fn_pluripotent_stem_cell_19: $i > $i).
% 29.32/29.11  tff(decl_61942, type, fn_pluripotent_stem_cell_20: $i > $i).
% 29.32/29.11  tff(decl_61943, type, fn_pluripotent_stem_cell_21: $i > $i).
% 29.32/29.11  tff(decl_61944, type, fn_pluripotent_stem_cell_22: $i > $i).
% 29.32/29.11  tff(decl_61945, type, fn_pluripotent_stem_cell_23: $i > $i).
% 29.32/29.11  tff(decl_61946, type, fn_pluripotent_stem_cell_24: $i > $i).
% 29.32/29.11  tff(decl_61947, type, fn_pluripotent_stem_cell_25: $i > $i).
% 29.32/29.11  tff(decl_61948, type, fn_pluripotent_stem_cell_26: $i > $i).
% 29.32/29.11  tff(decl_61949, type, fn_pluripotent_stem_cell_27: $i > $i).
% 29.32/29.11  tff(decl_61950, type, fn_pluripotent_stem_cell_28: $i > $i).
% 29.32/29.11  tff(decl_61951, type, fn_pluripotent_stem_cell_29: $i > $i).
% 29.32/29.11  tff(decl_61952, type, fn_pluripotent_stem_cell_30: $i > $i).
% 29.32/29.11  tff(decl_61953, type, fn_pluripotent_stem_cell_31: $i > $i).
% 29.32/29.11  tff(decl_61954, type, fn_pluripotent_stem_cell_32: $i > $i).
% 29.32/29.11  tff(decl_61955, type, fn_pluripotent_stem_cell_33: $i > $i).
% 29.32/29.11  tff(decl_61956, type, fn_pluripotent_stem_cell_34: $i > $i).
% 29.32/29.11  tff(decl_61957, type, fn_pluripotent_stem_cell_35: $i > $i).
% 29.32/29.11  tff(decl_61958, type, fn_pluripotent_stem_cell_36: $i > $i).
% 29.32/29.11  tff(decl_61959, type, fn_pluripotent_stem_cell_37: $i > $i).
% 29.32/29.11  tff(decl_61960, type, fn_pluripotent_stem_cell_38: $i > $i).
% 29.32/29.11  tff(decl_61961, type, fn_pluripotent_stem_cell_39: $i > $i).
% 29.32/29.11  tff(decl_61962, type, fn_pluripotent_stem_cell_40: $i > $i).
% 29.32/29.11  tff(decl_61963, type, fn_pluripotent_stem_cell_41: $i > $i).
% 29.32/29.11  tff(decl_61964, type, fn_pluripotent_stem_cell_42: $i > $i).
% 29.32/29.11  tff(decl_61965, type, fn_pluripotent_stem_cell_43: $i > $i).
% 29.32/29.11  tff(decl_61966, type, fn_pluripotent_stem_cell_44: $i > $i).
% 29.32/29.11  tff(decl_61967, type, fn_pluripotent_stem_cell_45: $i > $i).
% 29.32/29.11  tff(decl_61968, type, fn_pluripotent_stem_cell_46: $i > $i).
% 29.32/29.11  tff(decl_61969, type, fn_pluripotent_stem_cell_47: $i > $i).
% 29.32/29.11  tff(decl_61970, type, fn_pluripotent_stem_cell_48: $i > $i).
% 29.32/29.11  tff(decl_61971, type, fn_pluripotent_stem_cell_49: $i > $i).
% 29.32/29.11  tff(decl_61972, type, fn_pluripotent_stem_cell_50: $i > $i).
% 29.32/29.11  tff(decl_61973, type, fn_stem_cell_differentiation_1: $i > $i).
% 29.32/29.11  tff(decl_61974, type, fn_pluripotent_stem_cell_11: $i > $i).
% 29.32/29.11  tff(decl_61975, type, fn_pluripotent_stem_cell_12: $i > $i).
% 29.32/29.11  tff(decl_61976, type, plutonium_1: $i > $o).
% 29.32/29.11  tff(decl_61977, type, 'Plutonium': $i).
% 29.32/29.11  tff(decl_61978, type, 'Plutonium is a metal atom with atomic number 94. It is represented by the symbol Pu.': $i).
% 29.32/29.11  tff(decl_61979, type, plutonium: $i).
% 29.32/29.11  tff(decl_61980, type, pu: $i).
% 29.32/29.11  tff(decl_61981, type, fn_plutonium_3: $i > $i).
% 29.32/29.11  tff(decl_61982, type, fn_plutonium_4: $i > $i).
% 29.32/29.11  tff(decl_61983, type, fn_plutonium_5: $i > $i).
% 29.32/29.11  tff(decl_61984, type, fn_plutonium_9: $i > $i).
% 29.32/29.11  tff(decl_61985, type, fn_plutonium_10: $i > $i).
% 29.32/29.11  tff(decl_61986, type, fn_plutonium_11: $i > $i).
% 29.32/29.11  tff(decl_61987, type, fn_plutonium_12: $i > $i).
% 29.32/29.11  tff(decl_61988, type, "94": $i).
% 29.32/29.11  tff(decl_61989, type, "1.28": $i).
% 29.32/29.11  tff(decl_61990, type, "244": $i).
% 29.32/29.11  tff(decl_61991, type, fn_plutonium_7: $i > $i).
% 29.32/29.11  tff(decl_61992, type, fn_plutonium_8: $i > $i).
% 29.32/29.11  tff(decl_61993, type, fn_plutonium_6: $i > $i).
% 29.32/29.11  tff(decl_61994, type, 'Point-Mutation': $i).
% 29.32/29.11  tff(decl_61995, type, 'A point mutation is a change in a single nucleotide pair in a gene sequence.': $i).
% 29.32/29.11  tff(decl_61996, type, 'mutation of point': $i).
% 29.32/29.11  tff(decl_61997, type, 'point mutation': $i).
% 29.32/29.11  tff(decl_61998, type, 'point-mutation': $i).
% 29.32/29.11  tff(decl_61999, type, fn_point_mutation_1: $i > $i).
% 29.32/29.11  tff(decl_62000, type, fn_point_mutation_2: $i > $i).
% 29.32/29.11  tff(decl_62001, type, fn_point_mutation_3: $i > $i).
% 29.32/29.11  tff(decl_62002, type, fn_point_mutation_4: $i > $i).
% 29.32/29.11  tff(decl_62003, type, fn_point_mutation_5: $i > $i).
% 29.32/29.11  tff(decl_62004, type, fn_point_mutation_6: $i > $i).
% 29.32/29.11  tff(decl_62005, type, fn_point_mutation_7: $i > $i).
% 29.32/29.11  tff(decl_62006, type, fn_point_mutation_8: $i > $i).
% 29.32/29.11  tff(decl_62007, type, fn_point_mutation_9: $i > $i).
% 29.32/29.11  tff(decl_62008, type, fn_point_mutation_10: $i > $i).
% 29.32/29.11  tff(decl_62009, type, fn_point_mutation_11: $i > $i).
% 29.32/29.11  tff(decl_62010, type, fn_point_mutation_12: $i > $i).
% 29.32/29.11  tff(decl_62011, type, fn_point_mutation_13: $i > $i).
% 29.32/29.11  tff(decl_62012, type, fn_point_mutation_14: $i > $i).
% 29.32/29.11  tff(decl_62013, type, fn_point_mutation_15: $i > $i).
% 29.32/29.11  tff(decl_62014, type, fn_point_mutation_16: $i > $i).
% 29.32/29.11  tff(decl_62015, type, 'Polar-Amino-Acid': $i).
% 29.32/29.11  tff(decl_62016, type, 'An amino acid which has hydrophillic properties due to the presence of a polar side chain.': $i).
% 29.32/29.11  tff(decl_62017, type, 'polar amino acid': $i).
% 29.32/29.11  tff(decl_62018, type, 'polar-amino-acid': $i).
% 29.32/29.11  tff(decl_62019, type, 'Polar-Body': $i).
% 29.32/29.11  tff(decl_62020, type, 'A polar body is a cell structure found inside an ovum is a small cell containing little cytoplasm that is produced along with the oocyte and later discarded. Both animal and plant ova possess it. It is also known as a polar cell.': $i).
% 29.32/29.11  tff(decl_62021, type, 'polar body': $i).
% 29.32/29.11  tff(decl_62022, type, 'polar-body': $i).
% 29.32/29.11  tff(decl_62023, type, 'Polar-Covalent-Bond': $i).
% 29.32/29.11  tff(decl_62024, type, 'A covalent bond between two atoms with different electronegativities. The electrons in the bond are not shared equally and are pulled towards the atom with the stronger electronegativity, resulting in that atom having a slight negative charge relative to the other atom.': $i).
% 29.32/29.11  tff(decl_62025, type, 'polar covalent bond': $i).
% 29.32/29.11  tff(decl_62026, type, 'polar-covalent-bond': $i).
% 29.32/29.11  tff(decl_62027, type, 'Polar-Molecule': $i).
% 29.32/29.11  tff(decl_62028, type, 'A molecule (such as water) that has opposite charges in different regions.': $i).
% 29.32/29.11  tff(decl_62029, type, 'polar molecule': $i).
% 29.32/29.11  tff(decl_62030, type, 'polar-molecule': $i).
% 29.32/29.11  tff(decl_62031, type, polar_molecule_solution_1: $i > $o).
% 29.32/29.11  tff(decl_62032, type, 'Polar-Molecule-Solution': $i).
% 29.32/29.11  tff(decl_62033, type, 'A solution where the solute molecules are polar.': $i).
% 29.32/29.11  tff(decl_62034, type, 'polar molecule solution': $i).
% 29.32/29.11  tff(decl_62035, type, 'polar-molecule-solution': $i).
% 29.32/29.11  tff(decl_62036, type, protein_solution_1: $i > $o).
% 29.32/29.11  tff(decl_62037, type, fn_polar_molecule_solution_2: $i > $i).
% 29.32/29.11  tff(decl_62038, type, fn_polar_molecule_solution_3: $i > $i).
% 29.32/29.11  tff(decl_62039, type, 'Polar-Region': $i).
% 29.32/29.11  tff(decl_62040, type, 'A part of a large molecule that is polar.': $i).
% 29.32/29.11  tff(decl_62041, type, 'polar region': $i).
% 29.32/29.11  tff(decl_62042, type, 'polar-region': $i).
% 29.32/29.11  tff(decl_62043, type, 'Polar-Side-Chain': $i).
% 29.32/29.11  tff(decl_62044, type, 'Polar side chain are hydrophillic regions in a amino acid.': $i).
% 29.32/29.11  tff(decl_62045, type, 'polar side chain': $i).
% 29.32/29.11  tff(decl_62046, type, 'polar-side-chain': $i).
% 29.32/29.11  tff(decl_62047, type, 'Polar-Substance': $i).
% 29.32/29.11  tff(decl_62048, type, 'A substance whose individual molecules have an uneven distribution of charges across covalent bonds between atoms of the molecule.': $i).
% 29.32/29.11  tff(decl_62049, type, 'polar substance': $i).
% 29.32/29.11  tff(decl_62050, type, 'polar-substance': $i).
% 29.32/29.11  tff(decl_62051, type, polar_molecule_0: $i).
% 29.32/29.11  tff(decl_62052, type, polar_transport_1: $i > $o).
% 29.32/29.11  tff(decl_62053, type, 'Polar-Transport': $i).
% 29.32/29.11  tff(decl_62054, type, 'A process of unidirectional transport of auxin in plants from shoot to base.': $i).
% 29.32/29.11  tff(decl_62055, type, 'polar transport': $i).
% 29.32/29.11  tff(decl_62056, type, 'polar-transport': $i).
% 29.32/29.11  tff(decl_62057, type, 'Polarity-Constant': $i).
% 29.32/29.11  tff(decl_62058, type, 'constant of polarity': $i).
% 29.32/29.11  tff(decl_62059, type, 'polarity constant': $i).
% 29.32/29.11  tff(decl_62060, type, 'polarity-constant': $i).
% 29.32/29.11  tff(decl_62061, type, 'Polarity-Value': $i).
% 29.32/29.11  tff(decl_62062, type, 'the electrical polarity of a Chemical-Objects': $i).
% 29.32/29.11  tff(decl_62063, type, 'value of polarity': $i).
% 29.32/29.11  tff(decl_62064, type, 'polarity value': $i).
% 29.32/29.11  tff(decl_62065, type, 'polarity-value': $i).
% 29.32/29.11  tff(decl_62066, type, polarization_1: $i > $o).
% 29.32/29.11  tff(decl_62067, type, 'Polarization': $i).
% 29.32/29.11  tff(decl_62068, type, 'A change in potential across a cellular membrane.': $i).
% 29.32/29.11  tff(decl_62069, type, polarize: $i).
% 29.32/29.11  tff(decl_62070, type, polarization: $i).
% 29.32/29.11  tff(decl_62071, type, 'Pole': $i).
% 29.32/29.11  tff(decl_62072, type, 'A fixed point by which other locations are defined.': $i).
% 29.32/29.11  tff(decl_62073, type, pole: $i).
% 29.32/29.11  tff(decl_62074, type, 'Political-State': $i).
% 29.32/29.11  tff(decl_62075, type, 'a state (such as Texas) within a country': $i).
% 29.32/29.11  tff(decl_62076, type, province: $i).
% 29.32/29.11  tff(decl_62077, type, 'political state': $i).
% 29.32/29.11  tff(decl_62078, type, 'political-state': $i).
% 29.32/29.11  tff(decl_62079, type, 'Pollen-Grain': $i).
% 29.32/29.11  tff(decl_62080, type, 'In seed plants, a structure consisting of the male gametophyte enclosed within a pollen wall. Pollen produces male gametes.': $i).
% 29.32/29.11  tff(decl_62081, type, pollen: $i).
% 29.32/29.11  tff(decl_62082, type, 'grain of pollen': $i).
% 29.32/29.11  tff(decl_62083, type, 'pollen grain': $i).
% 29.32/29.11  tff(decl_62084, type, 'pollen-grain': $i).
% 29.32/29.11  tff(decl_62085, type, fn_pollen_grain_1: $i > $i).
% 29.32/29.11  tff(decl_62086, type, fn_pollen_grain_2: $i > $i).
% 29.32/29.11  tff(decl_62087, type, 'Pollen-Tube': $i).
% 29.32/29.11  tff(decl_62088, type, 'Part of the male gametophyte in seed plants. The pollen tube transports male gametes from the pollen grain to the ovules of a flower.': $i).
% 29.32/29.11  tff(decl_62089, type, 'tube of pollen': $i).
% 29.32/29.11  tff(decl_62090, type, 'pollen tube': $i).
% 29.32/29.11  tff(decl_62091, type, 'pollen-tube': $i).
% 29.32/29.11  tff(decl_62092, type, 'Pollination': $i).
% 29.32/29.11  tff(decl_62093, type, 'The transfer of pollen to the part of a seed plant containing the ovules, a process required for fertilization.': $i).
% 29.32/29.11  tff(decl_62094, type, pollinate: $i).
% 29.32/29.11  tff(decl_62095, type, pollination: $i).
% 29.32/29.11  tff(decl_62096, type, fn_pollination_1: $i > $i).
% 29.32/29.11  tff(decl_62097, type, fn_pollination_2: $i > $i).
% 29.32/29.11  tff(decl_62098, type, 'Pollinator': $i).
% 29.32/29.11  tff(decl_62099, type, 'A biotic agent, such as an insect or bird, that transfers pollen from the anthers of one flower to the stigma of another flower.': $i).
% 29.32/29.11  tff(decl_62100, type, pollinator: $i).
% 29.32/29.11  tff(decl_62101, type, 'Polonium': $i).
% 29.32/29.11  tff(decl_62102, type, 'Polonium is a metal atom with atomic number 84. It is represented by the symbol Po.': $i).
% 29.32/29.11  tff(decl_62103, type, 'Po': $i).
% 29.32/29.11  tff(decl_62104, type, polonium: $i).
% 29.32/29.11  tff(decl_62105, type, fn_polonium_3: $i > $i).
% 29.32/29.11  tff(decl_62106, type, fn_polonium_4: $i > $i).
% 29.32/29.11  tff(decl_62107, type, fn_polonium_5: $i > $i).
% 29.32/29.11  tff(decl_62108, type, fn_polonium_8: $i > $i).
% 29.32/29.11  tff(decl_62109, type, fn_polonium_9: $i > $i).
% 29.32/29.11  tff(decl_62110, type, fn_polonium_10: $i > $i).
% 29.32/29.11  tff(decl_62111, type, fn_polonium_11: $i > $i).
% 29.32/29.11  tff(decl_62112, type, fn_polonium_7: $i > $i).
% 29.32/29.11  tff(decl_62113, type, fn_polonium_12: $i > $i).
% 29.32/29.11  tff(decl_62114, type, fn_polonium_6: $i > $i).
% 29.32/29.11  tff(decl_62115, type, 'Poly(A)-Tail': $i).
% 29.32/29.11  tff(decl_62116, type, 'After transcription, pre-MRNA is processed to faciltate export and prevent degradation. To the 3\\ end of the pre-MRAN, a series of 50-250 adenine molecules are added to male the poly(A) tail as part of this process..': $i).
% 29.32/29.11  tff(decl_62117, type, 'poly a': $i).
% 29.32/29.11  tff(decl_62118, type, 'poly-a': $i).
% 29.32/29.11  tff(decl_62119, type, 'poly a tail': $i).
% 29.32/29.11  tff(decl_62120, type, 'poly-a-tail': $i).
% 29.32/29.11  tff(decl_62121, type, 'a tail': $i).
% 29.32/29.11  tff(decl_62122, type, 'a-tail': $i).
% 29.32/29.11  tff(decl_62123, type, 'poly(a) tail': $i).
% 29.32/29.11  tff(decl_62124, type, 'poly(a)-tail': $i).
% 29.32/29.11  tff(decl_62125, type, fn_poly_a__tail_1: $i > $i).
% 29.32/29.11  tff(decl_62126, type, fn_poly_a__tail_2: $i > $i).
% 29.32/29.11  tff(decl_62127, type, fn_poly_a__tail_3: $i > $i).
% 29.32/29.11  tff(decl_62128, type, fn_poly_a__tail_4: $i > $i).
% 29.32/29.11  tff(decl_62129, type, fn_poly_a__tail_5: $i > $i).
% 29.32/29.11  tff(decl_62130, type, poly_u_1: $i > $o).
% 29.32/29.11  tff(decl_62131, type, 'Poly-U': $i).
% 29.32/29.11  tff(decl_62132, type, 'A strand of RNA containing only the nucleotide uracil.': $i).
% 29.32/29.11  tff(decl_62133, type, 'poly u': $i).
% 29.32/29.11  tff(decl_62134, type, 'poly-u': $i).
% 29.32/29.11  tff(decl_62135, type, fn_poly_u_1: $i > $i).
% 29.32/29.11  tff(decl_62136, type, 'Polyadenylation': $i).
% 29.32/29.11  tff(decl_62137, type, 'The addition of adenine nucleotides to mRNA.  The poly-A tail (along with the 5\\cap) functions to facilitate the export of the mature mRNA from the nucleus.': $i).
% 29.32/29.11  tff(decl_62138, type, 'addition of poly a tail in transcription': $i).
% 29.32/29.11  tff(decl_62139, type, polyadenylation: $i).
% 29.32/29.11  tff(decl_62140, type, fn_polyadenylation_1: $i > $i).
% 29.32/29.11  tff(decl_62141, type, prevention_of_mrna_degradation_1: $i > $o).
% 29.32/29.11  tff(decl_62142, type, fn_polyadenylation_2: $i > $i).
% 29.32/29.11  tff(decl_62143, type, fn_polyadenylation_3: $i > $i).
% 29.32/29.11  tff(decl_62144, type, fn_polyadenylation_4: $i > $i).
% 29.32/29.11  tff(decl_62145, type, fn_polyadenylation_5: $i > $i).
% 29.32/29.11  tff(decl_62146, type, fn_polyadenylation_6: $i > $i).
% 29.32/29.11  tff(decl_62147, type, fn_polyadenylation_7: $i > $i).
% 29.32/29.11  tff(decl_62148, type, fn_polyadenylation_8: $i > $i).
% 29.32/29.11  tff(decl_62149, type, fn_polyadenylation_9: $i > $i).
% 29.32/29.11  tff(decl_62150, type, fn_polyadenylation_10: $i > $i).
% 29.32/29.11  tff(decl_62151, type, fn_polyadenylation_11: $i > $i).
% 29.32/29.11  tff(decl_62152, type, fn_polyadenylation_12: $i > $i).
% 29.32/29.11  tff(decl_62153, type, fn_polyadenylation_13: $i > $i).
% 29.32/29.11  tff(decl_62154, type, 'Polyandry': $i).
% 29.32/29.11  tff(decl_62155, type, 'A polygamous mating system involving one female and many males.': $i).
% 29.32/29.11  tff(decl_62156, type, polyandry: $i).
% 29.32/29.11  tff(decl_62157, type, 'Polyatomic-Ion': $i).
% 29.32/29.11  tff(decl_62158, type, 'Ion which consists of more than one atom': $i).
% 29.32/29.11  tff(decl_62159, type, 'molecular ion': $i).
% 29.32/29.11  tff(decl_62160, type, 'molecular-ion': $i).
% 29.32/29.11  tff(decl_62161, type, 'ionic molecule': $i).
% 29.32/29.11  tff(decl_62162, type, 'polyatomic ion': $i).
% 29.32/29.11  tff(decl_62163, type, 'polyatomic-ion': $i).
% 29.32/29.11  tff(decl_62164, type, 'Polychaete': $i).
% 29.32/29.11  tff(decl_62165, type, 'A segmented marine worm of the class Polychaeta in the phylum Annelida.': $i).
% 29.32/29.11  tff(decl_62166, type, polychaete: $i).
% 29.32/29.11  tff(decl_62167, type, 'Polydactyly': $i).
% 29.32/29.11  tff(decl_62168, type, 'The condition of having supernumerary fingers or toes.': $i).
% 29.32/29.11  tff(decl_62169, type, polydactyly: $i).
% 29.32/29.11  tff(decl_62170, type, fn_polydactyly_1: $i > $i).
% 29.32/29.11  tff(decl_62171, type, fn_polydactyly_2: $i > $i).
% 29.32/29.11  tff(decl_62172, type, 'Polygamous-Mating': $i).
% 29.32/29.11  tff(decl_62173, type, 'A mating system in which a member of one sex mates with several members of the opposite sex.': $i).
% 29.32/29.11  tff(decl_62174, type, 'polygamous mating': $i).
% 29.32/29.11  tff(decl_62175, type, 'polygamous-mating': $i).
% 29.32/29.11  tff(decl_62176, type, 'Polygenic-Inheritance': $i).
% 29.32/29.11  tff(decl_62177, type, 'An additive effect of two or more genes on a single phenotypic character.': $i).
% 29.32/29.11  tff(decl_62178, type, 'multifactorial inheritance': $i).
% 29.32/29.11  tff(decl_62179, type, 'polygenic inheritance': $i).
% 29.32/29.11  tff(decl_62180, type, 'polygenic-inheritance': $i).
% 29.32/29.11  tff(decl_62181, type, fn_polygenic_inheritance_1: $i > $i).
% 29.32/29.11  tff(decl_62182, type, fn_polygenic_inheritance_2: $i > $i).
% 29.32/29.11  tff(decl_62183, type, fn_polygenic_inheritance_3: $i > $i).
% 29.32/29.11  tff(decl_62184, type, 'Polygyny': $i).
% 29.32/29.11  tff(decl_62185, type, 'A polygamous mating system involving one male and many females.': $i).
% 29.32/29.11  tff(decl_62186, type, polygyny: $i).
% 29.32/29.11  tff(decl_62187, type, monomer_0: $i).
% 29.32/29.11  tff(decl_62188, type, 'Polymer': $i).
% 29.32/29.11  tff(decl_62189, type, 'A polymer is a large molecule (macromolecule) composed of repeating structural units typically connected by covalent chemical bonds.': $i).
% 29.32/29.11  tff(decl_62190, type, chain: $i).
% 29.32/29.11  tff(decl_62191, type, 'large biological molecule': $i).
% 29.32/29.11  tff(decl_62192, type, 'large-biological-molecule': $i).
% 29.32/29.11  tff(decl_62193, type, 'large biomolecule': $i).
% 29.32/29.11  tff(decl_62194, type, 'large-biomolecule': $i).
% 29.32/29.11  tff(decl_62195, type, macromolecule: $i).
% 29.32/29.11  tff(decl_62196, type, polymer: $i).
% 29.32/29.11  tff(decl_62197, type, 'Polymer-Breakdown': $i).
% 29.32/29.11  tff(decl_62198, type, 'The process of breakdown of a polymer is called polymer breakdown.': $i).
% 29.32/29.11  tff(decl_62199, type, 'polymer hydrolysis': $i).
% 29.32/29.11  tff(decl_62200, type, 'polymer-hydrolysis': $i).
% 29.32/29.11  tff(decl_62201, type, 'breakdown of polymer': $i).
% 29.32/29.11  tff(decl_62202, type, 'polymer breakdown': $i).
% 29.32/29.11  tff(decl_62203, type, 'polymer-breakdown': $i).
% 29.32/29.11  tff(decl_62204, type, fn_polymer_breakdown_3: $i > $i).
% 29.32/29.11  tff(decl_62205, type, 'Polymer-Synthesis': $i).
% 29.32/29.11  tff(decl_62206, type, 'The process of synthesis of a polymer is called polymer synthesis.': $i).
% 29.32/29.11  tff(decl_62207, type, polymerization: $i).
% 29.32/29.11  tff(decl_62208, type, polymerisation: $i).
% 29.32/29.11  tff(decl_62209, type, 'synthesis of polymer': $i).
% 29.32/29.11  tff(decl_62210, type, 'polymer synthesis': $i).
% 29.32/29.11  tff(decl_62211, type, 'polymer-synthesis': $i).
% 29.32/29.11  tff(decl_62212, type, fn_polymer_synthesis_2: $i > $i).
% 29.32/29.11  tff(decl_62213, type, fn_polymer_synthesis_3: $i > $i).
% 29.32/29.11  tff(decl_62214, type, fn_polymer_synthesis_4: $i > $i).
% 29.32/29.11  tff(decl_62215, type, fn_polymer_synthesis_13: $i > $i).
% 29.32/29.11  tff(decl_62216, type, fn_polymer_synthesis_14: $i > $i).
% 29.32/29.11  tff(decl_62217, type, fn_polymer_synthesis_16: $i > $i).
% 29.32/29.11  tff(decl_62218, type, fn_polymer_synthesis_17: $i > $i).
% 29.32/29.11  tff(decl_62219, type, fn_polymer_synthesis_21: $i > $i).
% 29.32/29.11  tff(decl_62220, type, fn_polymer_synthesis_25: $i > $i).
% 29.32/29.11  tff(decl_62221, type, condensation_reaction_0: $i).
% 29.32/29.11  tff(decl_62222, type, 'Polymerase': $i).
% 29.32/29.11  tff(decl_62223, type, 'Polymerases are a class of enzymes which build DNA or RNA molecules by using a template.': $i).
% 29.32/29.11  tff(decl_62224, type, polymerase: $i).
% 29.32/29.11  tff(decl_62225, type, 'Polymerase-Chain-Reaction': $i).
% 29.32/29.11  tff(decl_62226, type, 'A technique for amplifying DNA in vitro by incubating it with specific primers, a heat-resistant DNA polymerase, and nucleotides.': $i).
% 29.32/29.11  tff(decl_62227, type, 'dna amplification in lab': $i).
% 29.32/29.11  tff(decl_62228, type, 'dna replication in lab': $i).
% 29.32/29.11  tff(decl_62229, type, 'undergo polymerase chain reaction': $i).
% 29.32/29.11  tff(decl_62230, type, fn_polymerase_chain_reaction_1: $i > $i).
% 29.32/29.11  tff(decl_62231, type, fn_polymerase_chain_reaction_6: $i > $i).
% 29.32/29.11  tff(decl_62232, type, fn_polymerase_chain_reaction_7: $i > $i).
% 29.32/29.11  tff(decl_62233, type, fn_polymerase_chain_reaction_8: $i > $i).
% 29.32/29.11  tff(decl_62234, type, fn_polymerase_chain_reaction_9: $i > $i).
% 29.32/29.11  tff(decl_62235, type, fn_polymerase_chain_reaction_10: $i > $i).
% 29.32/29.11  tff(decl_62236, type, fn_polymerase_chain_reaction_11: $i > $i).
% 29.32/29.11  tff(decl_62237, type, fn_polymerase_chain_reaction_12: $i > $i).
% 29.32/29.11  tff(decl_62238, type, fn_polymerase_chain_reaction_13: $i > $i).
% 29.32/29.11  tff(decl_62239, type, fn_polymerase_chain_reaction_14: $i > $i).
% 29.32/29.11  tff(decl_62240, type, fn_polymerase_chain_reaction_15: $i > $i).
% 29.32/29.11  tff(decl_62241, type, fn_polymerase_chain_reaction_16: $i > $i).
% 29.32/29.11  tff(decl_62242, type, fn_polymerase_chain_reaction_17: $i > $i).
% 29.32/29.11  tff(decl_62243, type, fn_polymerase_chain_reaction_18: $i > $i).
% 29.32/29.11  tff(decl_62244, type, fn_polymerase_chain_reaction_19: $i > $i).
% 29.32/29.11  tff(decl_62245, type, fn_polymerase_chain_reaction_20: $i > $i).
% 29.32/29.11  tff(decl_62246, type, fn_polymerase_chain_reaction_21: $i > $i).
% 29.32/29.11  tff(decl_62247, type, fn_polymerase_chain_reaction_22: $i > $i).
% 29.32/29.11  tff(decl_62248, type, fn_polymerase_chain_reaction_23: $i > $i).
% 29.32/29.11  tff(decl_62249, type, fn_polymerase_chain_reaction_3: $i > $i).
% 29.32/29.11  tff(decl_62250, type, fn_polymerase_chain_reaction_2: $i > $i).
% 29.32/29.11  tff(decl_62251, type, fn_polymerase_chain_reaction_5: $i > $i).
% 29.32/29.11  tff(decl_62252, type, fn_synthesis_of_dna_strand_7: $i > $i).
% 29.32/29.11  tff(decl_62253, type, fn_polymerase_chain_reaction_4: $i > $i).
% 29.32/29.11  tff(decl_62254, type, fn_synthesis_of_dna_strand_8: $i > $i).
% 29.32/29.11  tff(decl_62255, type, fn_synthesis_of_dna_strand_11: $i > $i).
% 29.32/29.11  tff(decl_62256, type, fn_synthesis_of_dna_strand_12: $i > $i).
% 29.32/29.11  tff(decl_62257, type, fn_synthesis_of_dna_strand_13: $i > $i).
% 29.32/29.11  tff(decl_62258, type, fn_synthesis_of_dna_strand_23: $i > $i).
% 29.32/29.11  tff(decl_62259, type, fn_synthesis_of_dna_strand_25: $i > $i).
% 29.32/29.11  tff(decl_62260, type, fn_synthesis_of_dna_strand_24: $i > $i).
% 29.32/29.11  tff(decl_62261, type, fn_synthesis_of_dna_strand_14: $i > $i).
% 29.32/29.11  tff(decl_62262, type, fn_synthesis_of_dna_strand_15: $i > $i).
% 29.32/29.11  tff(decl_62263, type, fn_synthesis_of_dna_strand_16: $i > $i).
% 29.32/29.11  tff(decl_62264, type, fn_synthesis_of_dna_strand_10: $i > $i).
% 29.32/29.11  tff(decl_62265, type, 'Polyp': $i).
% 29.32/29.11  tff(decl_62266, type, 'The benthic, vaguely tubular body plan of the generalized cnidarian life cycle. The other body variant is the medusa, which is flattened and pelagic.': $i).
% 29.32/29.11  tff(decl_62267, type, polyp: $i).
% 29.32/29.11  tff(decl_62268, type, 'Polypeptide': $i).
% 29.32/29.11  tff(decl_62269, type, 'Polypeptides are chains of amino acids connected to each other by peptide bond.': $i).
% 29.32/29.11  tff(decl_62270, type, polypeptide: $i).
% 29.32/29.11  tff(decl_62271, type, fn_polypeptide_1: $i > $i).
% 29.32/29.11  tff(decl_62272, type, fn_polypeptide_20: $i > $i).
% 29.32/29.11  tff(decl_62273, type, fn_polypeptide_21: $i > $i).
% 29.32/29.11  tff(decl_62274, type, fn_polypeptide_26: $i > $i).
% 29.32/29.11  tff(decl_62275, type, fn_polypeptide_27: $i > $i).
% 29.32/29.11  tff(decl_62276, type, fn_polypeptide_28: $i > $i).
% 29.32/29.11  tff(decl_62277, type, fn_polypeptide_29: $i > $i).
% 29.32/29.11  tff(decl_62278, type, fn_polypeptide_32: $i > $i).
% 29.32/29.11  tff(decl_62279, type, fn_polypeptide_33: $i > $i).
% 29.32/29.11  tff(decl_62280, type, fn_polypeptide_34: $i > $i).
% 29.32/29.11  tff(decl_62281, type, fn_polypeptide_35: $i > $i).
% 29.32/29.11  tff(decl_62282, type, fn_polypeptide_36: $i > $i).
% 29.32/29.11  tff(decl_62283, type, fn_polypeptide_45: $i > $i).
% 29.32/29.11  tff(decl_62284, type, fn_polypeptide_46: $i > $i).
% 29.32/29.11  tff(decl_62285, type, fn_polypeptide_47: $i > $i).
% 29.32/29.11  tff(decl_62286, type, fn_polypeptide_57: $i > $i).
% 29.32/29.11  tff(decl_62287, type, fn_polypeptide_58: $i > $i).
% 29.32/29.11  tff(decl_62288, type, fn_polypeptide_59: $i > $i).
% 29.32/29.11  tff(decl_62289, type, fn_polypeptide_60: $i > $i).
% 29.32/29.11  tff(decl_62290, type, fn_polypeptide_62: $i > $i).
% 29.32/29.11  tff(decl_62291, type, fn_polypeptide_64: $i > $i).
% 29.32/29.11  tff(decl_62292, type, fn_polypeptide_65: $i > $i).
% 29.32/29.11  tff(decl_62293, type, fn_polypeptide_66: $i > $i).
% 29.32/29.11  tff(decl_62294, type, fn_polypeptide_67: $i > $i).
% 29.32/29.11  tff(decl_62295, type, fn_polypeptide_68: $i > $i).
% 29.32/29.11  tff(decl_62296, type, fn_polypeptide_70: $i > $i).
% 29.32/29.11  tff(decl_62297, type, fn_polypeptide_71: $i > $i).
% 29.32/29.11  tff(decl_62298, type, fn_polypeptide_72: $i > $i).
% 29.32/29.11  tff(decl_62299, type, fn_polypeptide_73: $i > $i).
% 29.32/29.11  tff(decl_62300, type, fn_polypeptide_74: $i > $i).
% 29.32/29.11  tff(decl_62301, type, fn_polypeptide_75: $i > $i).
% 29.32/29.11  tff(decl_62302, type, fn_polypeptide_76: $i > $i).
% 29.32/29.11  tff(decl_62303, type, fn_polypeptide_79: $i > $i).
% 29.32/29.11  tff(decl_62304, type, fn_polypeptide_86: $i > $i).
% 29.32/29.11  tff(decl_62305, type, fn_polypeptide_88: $i > $i).
% 29.32/29.11  tff(decl_62306, type, fn_polypeptide_92: $i > $i).
% 29.32/29.11  tff(decl_62307, type, fn_polypeptide_93: $i > $i).
% 29.32/29.11  tff(decl_62308, type, fn_polypeptide_95: $i > $i).
% 29.32/29.11  tff(decl_62309, type, fn_polypeptide_114: $i > $i).
% 29.32/29.11  tff(decl_62310, type, fn_polypeptide_116: $i > $i).
% 29.32/29.11  tff(decl_62311, type, fn_polypeptide_117: $i > $i).
% 29.32/29.11  tff(decl_62312, type, fn_polypeptide_124: $i > $i).
% 29.32/29.11  tff(decl_62313, type, fn_valence_electron_3: $i > $i).
% 29.32/29.11  tff(decl_62314, type, fn_polypeptide_13: $i > $i).
% 29.32/29.11  tff(decl_62315, type, fn_polypeptide_12: $i > $i).
% 29.32/29.11  tff(decl_62316, type, fn_polypeptide_11: $i > $i).
% 29.32/29.11  tff(decl_62317, type, fn_polypeptide_10: $i > $i).
% 29.32/29.11  tff(decl_62318, type, fn_polypeptide_8: $i > $i).
% 29.32/29.11  tff(decl_62319, type, fn_polypeptide_5: $i > $i).
% 29.32/29.11  tff(decl_62320, type, fn_polypeptide_6: $i > $i).
% 29.32/29.11  tff(decl_62321, type, fn_polypeptide_7: $i > $i).
% 29.32/29.11  tff(decl_62322, type, fn_polypeptide_77: $i > $i).
% 29.32/29.11  tff(decl_62323, type, fn_polypeptide_14: $i > $i).
% 29.32/29.11  tff(decl_62324, type, fn_polypeptide_9: $i > $i).
% 29.32/29.11  tff(decl_62325, type, fn_polypeptide_4: $i > $i).
% 29.32/29.11  tff(decl_62326, type, fn_polypeptide_3: $i > $i).
% 29.32/29.11  tff(decl_62327, type, 'Polypeptide-Segment': $i).
% 29.32/29.11  tff(decl_62328, type, 'A polymer of many amino acids linked together by peptide bonds.': $i).
% 29.32/29.11  tff(decl_62329, type, 'segment of polypeptide': $i).
% 29.32/29.11  tff(decl_62330, type, 'polypeptide segment': $i).
% 29.32/29.11  tff(decl_62331, type, 'polypeptide-segment': $i).
% 29.32/29.11  tff(decl_62332, type, 'Polyphyletic': $i).
% 29.32/29.11  tff(decl_62333, type, 'Describes a grouping of taxa that are descended from more than one different ancestors.': $i).
% 29.32/29.11  tff(decl_62334, type, polyphyly: $i).
% 29.32/29.11  tff(decl_62335, type, polyphyletic: $i).
% 29.32/29.11  tff(decl_62336, type, 'Polyploidy': $i).
% 29.32/29.11  tff(decl_62337, type, 'The state of possessing more than two complete sets of chromosomes. Polyploidy results from an accident of cell division.': $i).
% 29.32/29.11  tff(decl_62338, type, polyploidy: $i).
% 29.32/29.11  tff(decl_62339, type, polyprotic_acid_1: $i > $o).
% 29.32/29.11  tff(decl_62340, type, 'Polyprotic-Acid': $i).
% 29.32/29.11  tff(decl_62341, type, 'An acid that yields two or more H+ ion per molecule of acid.': $i).
% 29.32/29.11  tff(decl_62342, type, 'polyprotic acid': $i).
% 29.32/29.11  tff(decl_62343, type, 'polyprotic-acid': $i).
% 29.32/29.11  tff(decl_62344, type, c6h5cooh_substance_1: $i > $o).
% 29.32/29.11  tff(decl_62345, type, ch2_cooh_2_substance_1: $i > $o).
% 29.32/29.11  tff(decl_62346, type, polyprotic_acid_compound_1: $i > $o).
% 29.32/29.11  tff(decl_62347, type, 'Polyprotic-Acid-Compound': $i).
% 29.32/29.11  tff(decl_62348, type, 'polyprotic acid compound': $i).
% 29.32/29.11  tff(decl_62349, type, 'polyprotic-acid-compound': $i).
% 29.32/29.11  tff(decl_62350, type, polyribosome_1: $i > $o).
% 29.32/29.11  tff(decl_62351, type, 'Polyribosome': $i).
% 29.32/29.11  tff(decl_62352, type, 'A polyribosome is a series of ribosomes simultaneously translating a single mRNA strand into multiple polypeptide copies.': $i).
% 29.32/29.11  tff(decl_62353, type, polysome: $i).
% 29.32/29.11  tff(decl_62354, type, polyribosome: $i).
% 29.32/29.11  tff(decl_62355, type, fn_polyribosome_1: $i > $i).
% 29.32/29.11  tff(decl_62356, type, fn_polyribosome_2: $i > $i).
% 29.32/29.11  tff(decl_62357, type, fn_polyribosome_3: $i > $i).
% 29.32/29.11  tff(decl_62358, type, fn_polyribosome_4: $i > $i).
% 29.32/29.11  tff(decl_62359, type, fn_polyribosome_5: $i > $i).
% 29.32/29.11  tff(decl_62360, type, fn_polyribosome_6: $i > $i).
% 29.32/29.11  tff(decl_62361, type, fn_polyribosome_7: $i > $i).
% 29.32/29.11  tff(decl_62362, type, fn_polyribosome_8: $i > $i).
% 29.32/29.11  tff(decl_62363, type, fn_polyribosome_9: $i > $i).
% 29.32/29.11  tff(decl_62364, type, fn_polyribosome_10: $i > $i).
% 29.32/29.11  tff(decl_62365, type, mrna_0: $i).
% 29.32/29.11  tff(decl_62366, type, ribosome_0: $i).
% 29.32/29.11  tff(decl_62367, type, 'Polysaccharide': $i).
% 29.32/29.11  tff(decl_62368, type, 'Carbohydrate molecules formed by the polymerization of monosaccharides by dehydration synthesis.': $i).
% 29.32/29.11  tff(decl_62369, type, 'poly saccharide': $i).
% 29.32/29.11  tff(decl_62370, type, 'poly-saccharide': $i).
% 29.32/29.11  tff(decl_62371, type, polysaccharide: $i).
% 29.32/29.11  tff(decl_62372, type, polyspermy_1: $i > $o).
% 29.32/29.11  tff(decl_62373, type, 'Polyspermy': $i).
% 29.32/29.11  tff(decl_62374, type, 'The fertilization of an egg by more than one sperm cell.': $i).
% 29.32/29.11  tff(decl_62375, type, polyspermy: $i).
% 29.32/29.11  tff(decl_62376, type, polysporangiophyte_1: $i > $o).
% 29.32/29.11  tff(decl_62377, type, 'Polysporangiophyte': $i).
% 29.32/29.11  tff(decl_62378, type, 'A group of land plants which features sporangia with several branches.': $i).
% 29.32/29.11  tff(decl_62379, type, polysporangiophyte: $i).
% 29.32/29.11  tff(decl_62380, type, polytomy_1: $i > $o).
% 29.32/29.11  tff(decl_62381, type, 'Polytomy': $i).
% 29.32/29.11  tff(decl_62382, type, 'In a phylogenetic tree, a branch point that gives rise to more than two descendent taxa, which occurs when the evolutionary relationships among the descendent taxa have not been determined.': $i).
% 29.32/29.11  tff(decl_62383, type, polytomy: $i).
% 29.32/29.11  tff(decl_62384, type, pompes_disease_1: $i > $o).
% 29.32/29.11  tff(decl_62385, type, 'Pompes-Disease': $i).
% 29.32/29.11  tff(decl_62386, type, 'Pompe disease is a neuromuscular, autosomal recessive metabolic disorder in the family of lysosomal storage diseases caused by a deficiency in the enzyme Acid alpha-glucosidase which is needed to break down glycogen for energy. The lysosomes become engorged with indigestible substrates, that interfere in cellular activities': $i).
% 29.32/29.11  tff(decl_62387, type, 'glycogen storage disease type ii': $i).
% 29.32/29.11  tff(decl_62388, type, 'acid maltase deficiency': $i).
% 29.32/29.11  tff(decl_62389, type, 'glycogen-storage-disease-type-ii': $i).
% 29.32/29.11  tff(decl_62390, type, 'acid-maltase-deficiency': $i).
% 29.32/29.11  tff(decl_62391, type, 'pompe\\s disease': $i).
% 29.32/29.11  tff(decl_62392, type, 'pompe\\s-disease': $i).
% 29.32/29.11  tff(decl_62393, type, 'pompes disease': $i).
% 29.32/29.11  tff(decl_62394, type, 'pompes-disease': $i).
% 29.32/29.11  tff(decl_62395, type, 'Pond': $i).
% 29.32/29.11  tff(decl_62396, type, 'A small body of water, usually smaller than a lake.': $i).
% 29.32/29.11  tff(decl_62397, type, pond: $i).
% 29.32/29.11  tff(decl_62398, type, river_1: $i > $o).
% 29.32/29.11  tff(decl_62399, type, stream_1: $i > $o).
% 29.32/29.11  tff(decl_62400, type, fn_pond_1: $i > $i).
% 29.32/29.11  tff(decl_62401, type, 'Pons': $i).
% 29.32/29.11  tff(decl_62402, type, 'Structure located in the vertebrate brainstem. The pons has autonomic homeostatic functions such as the regulation of breathing and sleep.': $i).
% 29.32/29.11  tff(decl_62403, type, pons: $i).
% 29.32/29.11  tff(decl_62404, type, 'Population': $i).
% 29.32/29.11  tff(decl_62405, type, 'A group of individuals of the same species in a specified area. These individuals interact and can interbreed to produce fertile offspring.': $i).
% 29.32/29.11  tff(decl_62406, type, population: $i).
% 29.32/29.11  tff(decl_62407, type, 'Population-Biology-Technique': $i).
% 29.32/29.11  tff(decl_62408, type, 'Techniques used in the study of populations of organisms.': $i).
% 29.32/29.11  tff(decl_62409, type, 'population biology technique': $i).
% 29.32/29.11  tff(decl_62410, type, 'population-biology-technique': $i).
% 29.32/29.11  tff(decl_62411, type, population_dynamics_1: $i > $o).
% 29.32/29.11  tff(decl_62412, type, 'Population-Dynamics': $i).
% 29.32/29.11  tff(decl_62413, type, 'Demographic characteristics of populations such as abundance, reproduction and survival, in addition to those factors which influence demographic characteristics of poulations.': $i).
% 29.32/29.11  tff(decl_62414, type, 'population-dynamics': $i).
% 29.32/29.11  tff(decl_62415, type, 'dynamics of population': $i).
% 29.32/29.11  tff(decl_62416, type, 'population dynamics': $i).
% 29.32/29.11  tff(decl_62417, type, 'population-dynamic': $i).
% 29.32/29.11  tff(decl_62418, type, 'Population-Ecology': $i).
% 29.32/29.11  tff(decl_62419, type, 'The study of how populations interact with the environment. Includes the study of how the environment affects population density and distribution, age structure, and size.': $i).
% 29.32/29.11  tff(decl_62420, type, 'ecology of population': $i).
% 29.32/29.11  tff(decl_62421, type, 'population ecology': $i).
% 29.32/29.11  tff(decl_62422, type, 'population-ecology': $i).
% 29.32/29.11  tff(decl_62423, type, 'Population-Process': $i).
% 29.32/29.11  tff(decl_62424, type, 'An ecological process that occurs at the level of populations.': $i).
% 29.32/29.11  tff(decl_62425, type, 'process of population': $i).
% 29.32/29.11  tff(decl_62426, type, 'population process': $i).
% 29.32/29.11  tff(decl_62427, type, 'population-process': $i).
% 29.32/29.11  tff(decl_62428, type, 'Population-Representation': $i).
% 29.32/29.11  tff(decl_62429, type, 'A method of representing population data.': $i).
% 29.32/29.11  tff(decl_62430, type, 'representation of population': $i).
% 29.32/29.11  tff(decl_62431, type, 'population representation': $i).
% 29.32/29.11  tff(decl_62432, type, 'population-representation': $i).
% 29.32/29.11  tff(decl_62433, type, 'Population-Viability-Analysis': $i).
% 29.32/29.11  tff(decl_62434, type, 'An analysis whose objective is to make a reasonable prediction of a populations chances for survival, usually expressed as a certain probability of survival over a particular time.': $i).
% 29.32/29.11  tff(decl_62435, type, 'population viability analysis': $i).
% 29.32/29.11  tff(decl_62436, type, 'population-viability-analysis': $i).
% 29.32/29.11  tff(decl_62437, type, 'Pore': $i).
% 29.32/29.11  tff(decl_62438, type, 'Channel through the nuclear envelope that allows                         selected molecules to move between the nucleus and                         cytoplasm.': $i).
% 29.32/29.11  tff(decl_62439, type, 'A small opening in a surface.': $i).
% 29.32/29.11  tff(decl_62440, type, pore: $i).
% 29.32/29.11  tff(decl_62441, type, 'Pore-complex': $i).
% 29.32/29.11  tff(decl_62442, type, 'It is an intricate protein structure which lines pores in the nuclear membrane': $i).
% 29.32/29.11  tff(decl_62443, type, 'complex of pore': $i).
% 29.32/29.11  tff(decl_62444, type, 'pore complex': $i).
% 29.32/29.11  tff(decl_62445, type, 'pore-complex': $i).
% 29.32/29.11  tff(decl_62446, type, fn_pore_complex_1: $i > $i).
% 29.32/29.11  tff(decl_62447, type, fn_pore_complex_3: $i > $i).
% 29.32/29.11  tff(decl_62448, type, fn_pore_complex_4: $i > $i).
% 29.32/29.11  tff(decl_62449, type, fn_pore_complex_6: $i > $i).
% 29.32/29.11  tff(decl_62450, type, fn_pore_complex_8: $i > $i).
% 29.32/29.11  tff(decl_62451, type, 'Porifera': $i).
% 29.32/29.11  tff(decl_62452, type, 'A phylum of multicellular animals, such as sponges, that have different cell types but lack true tissues.': $i).
% 29.32/29.11  tff(decl_62453, type, poriferan: $i).
% 29.32/29.11  tff(decl_62454, type, sponges: $i).
% 29.32/29.11  tff(decl_62455, type, porifera: $i).
% 29.32/29.11  tff(decl_62456, type, fn_porifera_1: $i > $i).
% 29.32/29.11  tff(decl_62457, type, fn_porifera_3: $i > $i).
% 29.32/29.11  tff(decl_62458, type, fn_porifera_4: $i > $i).
% 29.32/29.11  tff(decl_62459, type, fn_porifera_5: $i > $i).
% 29.32/29.11  tff(decl_62460, type, fn_porifera_6: $i > $i).
% 29.32/29.11  tff(decl_62461, type, fn_porifera_7: $i > $i).
% 29.32/29.11  tff(decl_62462, type, fn_porifera_10: $i > $i).
% 29.32/29.11  tff(decl_62463, type, fn_porifera_13: $i > $i).
% 29.32/29.11  tff(decl_62464, type, fn_porifera_14: $i > $i).
% 29.32/29.11  tff(decl_62465, type, fn_porifera_15: $i > $i).
% 29.32/29.11  tff(decl_62466, type, fn_porifera_16: $i > $i).
% 29.32/29.11  tff(decl_62467, type, fn_porifera_17: $i > $i).
% 29.32/29.11  tff(decl_62468, type, fn_porifera_18: $i > $i).
% 29.32/29.11  tff(decl_62469, type, fn_porifera_19: $i > $i).
% 29.32/29.11  tff(decl_62470, type, fn_porifera_20: $i > $i).
% 29.32/29.11  tff(decl_62471, type, fn_porifera_21: $i > $i).
% 29.32/29.11  tff(decl_62472, type, fn_porifera_22: $i > $i).
% 29.32/29.11  tff(decl_62473, type, fn_porifera_23: $i > $i).
% 29.32/29.11  tff(decl_62474, type, fn_porifera_25: $i > $i).
% 29.32/29.11  tff(decl_62475, type, fn_porifera_27: $i > $i).
% 29.32/29.11  tff(decl_62476, type, fn_porifera_29: $i > $i).
% 29.32/29.11  tff(decl_62477, type, fn_porifera_30: $i > $i).
% 29.32/29.11  tff(decl_62478, type, fn_porifera_31: $i > $i).
% 29.32/29.11  tff(decl_62479, type, fn_porifera_33: $i > $i).
% 29.32/29.11  tff(decl_62480, type, fn_porifera_35: $i > $i).
% 29.32/29.11  tff(decl_62481, type, fn_porifera_36: $i > $i).
% 29.32/29.11  tff(decl_62482, type, fn_porifera_37: $i > $i).
% 29.32/29.11  tff(decl_62483, type, fn_porifera_38: $i > $i).
% 29.32/29.11  tff(decl_62484, type, fn_porifera_39: $i > $i).
% 29.32/29.11  tff(decl_62485, type, fn_porifera_40: $i > $i).
% 29.32/29.11  tff(decl_62486, type, fn_porifera_41: $i > $i).
% 29.32/29.11  tff(decl_62487, type, fn_porifera_42: $i > $i).
% 29.32/29.11  tff(decl_62488, type, fn_porifera_43: $i > $i).
% 29.32/29.11  tff(decl_62489, type, fn_porifera_44: $i > $i).
% 29.32/29.11  tff(decl_62490, type, fn_porifera_45: $i > $i).
% 29.32/29.11  tff(decl_62491, type, 'Porphyrin': $i).
% 29.32/29.11  tff(decl_62492, type, 'Porphyrins are a group of organic compounds of which many occur in nature. One of the best-known porphyrins is heme, the pigment in red blood cells; heme is a cofactor of the protein hemoglobin.': $i).
% 29.32/29.11  tff(decl_62493, type, 'porphyrin ring': $i).
% 29.32/29.11  tff(decl_62494, type, 'porphyrin-ring': $i).
% 29.32/29.11  tff(decl_62495, type, porphyrin: $i).
% 29.32/29.11  tff(decl_62496, type, fn_porphyrin_4: $i > $i).
% 29.32/29.11  tff(decl_62497, type, aromatic_hydrocarbon_0: $i).
% 29.32/29.11  tff(decl_62498, type, 'Portal': $i).
% 29.32/29.11  tff(decl_62499, type, portal: $i).
% 29.32/29.11  tff(decl_62500, type, 'Portal-Covering': $i).
% 29.32/29.11  tff(decl_62501, type, 'movable barrier': $i).
% 29.32/29.11  tff(decl_62502, type, movable_barrier: $i).
% 29.32/29.11  tff(decl_62503, type, 'covering of portal': $i).
% 29.32/29.11  tff(decl_62504, type, 'portal covering': $i).
% 29.32/29.11  tff(decl_62505, type, 'portal-covering': $i).
% 29.32/29.11  tff(decl_62506, type, 'Positional-Information': $i).
% 29.32/29.11  tff(decl_62507, type, 'The instructions that are interpreted by cells to determine their differentiation in respect of their position relative to other parts of the organism, for example digit formation in the limb bud of vertebrates.': $i).
% 29.32/29.11  tff(decl_62508, type, 'positional information': $i).
% 29.32/29.11  tff(decl_62509, type, 'positional-information': $i).
% 29.32/29.11  tff(decl_62510, type, fn_positional_information_1: $i > $i).
% 29.32/29.11  tff(decl_62511, type, fn_positional_information_3: $i > $i).
% 29.32/29.11  tff(decl_62512, type, 'Positive-Feedback': $i).
% 29.32/29.11  tff(decl_62513, type, 'One of the primary mechanisms of homeostasis, in which a change in a variable causes a response that amplifies the initial change.': $i).
% 29.32/29.11  tff(decl_62514, type, 'feedback of positive': $i).
% 29.32/29.11  tff(decl_62515, type, 'positive feedback': $i).
% 29.32/29.11  tff(decl_62516, type, 'positive-feedback': $i).
% 29.32/29.11  tff(decl_62517, type, fn_positive_gene_regulation_2: $i > $i).
% 29.32/29.11  tff(decl_62518, type, 'Positive-Gene-Regulation': $i).
% 29.32/29.11  tff(decl_62519, type, 'Gene regulation that promotes transcription.': $i).
% 29.32/29.11  tff(decl_62520, type, 'positive gene regulation': $i).
% 29.32/29.11  tff(decl_62521, type, 'positive-gene-regulation': $i).
% 29.32/29.11  tff(decl_62522, type, fn_positive_gene_regulation_4: $i > $i).
% 29.32/29.11  tff(decl_62523, type, fn_positive_gene_regulation_5: $i > $i).
% 29.32/29.11  tff(decl_62524, type, 'Positive-Pressure-Breathing': $i).
% 29.32/29.11  tff(decl_62525, type, 'A type of breathing in which air is pushed into the lungs.': $i).
% 29.32/29.11  tff(decl_62526, type, 'positive pressure breathing': $i).
% 29.32/29.11  tff(decl_62527, type, 'positive-pressure-breathing': $i).
% 29.32/29.11  tff(decl_62528, type, 'Positively-Charged-Region': $i).
% 29.32/29.11  tff(decl_62529, type, 'The region is concentrated with positive charge.': $i).
% 29.32/29.11  tff(decl_62530, type, 'positively charged region': $i).
% 29.32/29.11  tff(decl_62531, type, 'positively-charged-region': $i).
% 29.32/29.11  tff(decl_62532, type, fn_positively_charged_region_1: $i > $i).
% 29.32/29.11  tff(decl_62533, type, fn_positively_charged_region_2: $i > $i).
% 29.32/29.11  tff(decl_62534, type, fn_positively_charged_region_3: $i > $i).
% 29.32/29.11  tff(decl_62535, type, fn_positively_charged_region_4: $i > $i).
% 29.32/29.11  tff(decl_62536, type, positron_1: $i > $o).
% 29.32/29.11  tff(decl_62537, type, 'Positron': $i).
% 29.32/29.11  tff(decl_62538, type, 'The positron or antielectron is the antiparticle or the antimatter counterpart of the electron.': $i).
% 29.32/29.11  tff(decl_62539, type, antielectron: $i).
% 29.32/29.11  tff(decl_62540, type, positron: $i).
% 29.32/29.11  tff(decl_62541, type, 'Positron-Emission-Tomography': $i).
% 29.32/29.11  tff(decl_62542, type, 'A nuclear medical imaging technique which produces a 3D image or picture of functional processes in the body. The system detects pairs of gamma rays emitted indirectly by a positron-emitting radionuclide (tracer), which is introduced into the body on a biologically active molecule. Images of tracer concentration in 3-dimensional or 4-dimensional space (the 4th dimension being time) within the body are then reconstructed by computer analysis.': $i).
% 29.32/29.11  tff(decl_62543, type, pet: $i).
% 29.32/29.11  tff(decl_62544, type, 'pet scan': $i).
% 29.32/29.11  tff(decl_62545, type, 'pet scanning': $i).
% 29.32/29.11  tff(decl_62546, type, 'pet-scan': $i).
% 29.32/29.11  tff(decl_62547, type, 'positron emission tomography': $i).
% 29.32/29.11  tff(decl_62548, type, 'positron-emission-tomography': $i).
% 29.32/29.11  tff(decl_62549, type, fn_positron_emission_tomography_2: $i > $i).
% 29.32/29.11  tff(decl_62550, type, fn_positron_emission_tomography_3: $i > $i).
% 29.32/29.11  tff(decl_62551, type, fn_positron_emission_tomography_4: $i > $i).
% 29.32/29.11  tff(decl_62552, type, fn_positron_emission_tomography_5: $i > $i).
% 29.32/29.11  tff(decl_62553, type, fn_positron_emission_tomography_6: $i > $i).
% 29.32/29.11  tff(decl_62554, type, fn_positron_emission_tomography_7: $i > $i).
% 29.32/29.11  tff(decl_62555, type, fn_positron_emission_tomography_8: $i > $i).
% 29.32/29.11  tff(decl_62556, type, fn_positron_emission_tomography_9: $i > $i).
% 29.32/29.11  tff(decl_62557, type, fn_positron_emission_tomography_10: $i > $i).
% 29.32/29.11  tff(decl_62558, type, fn_positron_emission_tomography_11: $i > $i).
% 29.32/29.11  tff(decl_62559, type, fn_positron_emission_tomography_12: $i > $i).
% 29.32/29.11  tff(decl_62560, type, fn_positron_emission_tomography_14: $i > $i).
% 29.32/29.11  tff(decl_62561, type, fn_positron_emission_tomography_15: $i > $i).
% 29.32/29.11  tff(decl_62562, type, fn_positron_emission_tomography_18: $i > $i).
% 29.32/29.11  tff(decl_62563, type, fn_positron_emission_tomography_19: $i > $i).
% 29.32/29.11  tff(decl_62564, type, fn_positron_emission_tomography_20: $i > $i).
% 29.32/29.11  tff(decl_62565, type, fn_positron_emission_tomography_21: $i > $i).
% 29.32/29.11  tff(decl_62566, type, fn_positron_emission_tomography_22: $i > $i).
% 29.32/29.11  tff(decl_62567, type, fn_positron_emission_tomography_23: $i > $i).
% 29.32/29.11  tff(decl_62568, type, fn_positron_emission_tomography_24: $i > $i).
% 29.32/29.11  tff(decl_62569, type, fn_positron_emission_tomography_25: $i > $i).
% 29.32/29.11  tff(decl_62570, type, fn_positron_emission_tomography_26: $i > $i).
% 29.32/29.11  tff(decl_62571, type, fn_positron_emission_tomography_27: $i > $i).
% 29.32/29.11  tff(decl_62572, type, fn_positron_emission_tomography_28: $i > $i).
% 29.32/29.11  tff(decl_62573, type, fn_positron_emission_tomography_29: $i > $i).
% 29.32/29.11  tff(decl_62574, type, fn_positron_emission_tomography_30: $i > $i).
% 29.32/29.11  tff(decl_62575, type, fn_positron_emission_tomography_31: $i > $i).
% 29.32/29.11  tff(decl_62576, type, fn_positron_emission_tomography_32: $i > $i).
% 29.32/29.11  tff(decl_62577, type, fn_positron_emission_tomography_33: $i > $i).
% 29.32/29.11  tff(decl_62578, type, fn_positron_emission_tomography_34: $i > $i).
% 29.32/29.11  tff(decl_62579, type, fn_positron_emission_tomography_35: $i > $i).
% 29.32/29.11  tff(decl_62580, type, fn_radioactive_tracer_6: $i > $i).
% 29.32/29.11  tff(decl_62581, type, fn_positron_emission_tomography_17: $i > $i).
% 29.32/29.11  tff(decl_62582, type, 'Post-Synaptic-Cell': $i).
% 29.32/29.11  tff(decl_62583, type, 'The target cell at a synapse.': $i).
% 29.32/29.11  tff(decl_62584, type, 'post synaptic cell': $i).
% 29.32/29.11  tff(decl_62585, type, 'post-synaptic-cell': $i).
% 29.32/29.11  tff(decl_62586, type, fn_post_synaptic_cell_1: $i > $i).
% 29.32/29.11  tff(decl_62587, type, fn_post_synaptic_cell_2: $i > $i).
% 29.32/29.11  tff(decl_62588, type, fn_post_synaptic_cell_3: $i > $i).
% 29.32/29.11  tff(decl_62589, type, 'Post-Transcriptional-Modification-Of-RNA': $i).
% 29.32/29.11  tff(decl_62590, type, 'Processing within the nucleus of a euakryotic cell, in which introns of pre-mRNA are removed, resulting in mRNA.': $i).
% 29.32/29.11  tff(decl_62591, type, 'post transcriptional modification of rna': $i).
% 29.32/29.11  tff(decl_62592, type, 'post-transcriptional-modification-of-rna': $i).
% 29.32/29.11  tff(decl_62593, type, rna_processing_1: $i > $o).
% 29.32/29.11  tff(decl_62594, type, fn_post_transcriptional_modification_of_rna_1: $i > $i).
% 29.32/29.11  tff(decl_62595, type, fn_post_transcriptional_modification_of_rna_2: $i > $i).
% 29.32/29.11  tff(decl_62596, type, fn_post_transcriptional_modification_of_rna_3: $i > $i).
% 29.32/29.11  tff(decl_62597, type, fn_rna_processing_1: $i > $i).
% 29.32/29.11  tff(decl_62598, type, 'Post-Translational-Modification': $i).
% 29.32/29.11  tff(decl_62599, type, 'Post-Translational modification is the process by which a newly formed polypeptide changes to a functional protein by folding and modifying the polypeptide chain by cleaving or adding functional groups.': $i).
% 29.32/29.11  tff(decl_62600, type, 'modification after translation': $i).
% 29.32/29.11  tff(decl_62601, type, 'post translational modification': $i).
% 29.32/29.11  tff(decl_62602, type, 'post-translational-modification': $i).
% 29.32/29.11  tff(decl_62603, type, 'posttranslational modification': $i).
% 29.32/29.11  tff(decl_62604, type, 'post-translational modification': $i).
% 29.32/29.11  tff(decl_62605, type, 'post translation modification': $i).
% 29.32/29.11  tff(decl_62606, type, 'post-translation modification': $i).
% 29.32/29.11  tff(decl_62607, type, 'protein processing': $i).
% 29.32/29.11  tff(decl_62608, type, 'polypeptide processing': $i).
% 29.32/29.11  tff(decl_62609, type, 'protein modification': $i).
% 29.32/29.11  tff(decl_62610, type, 'polypeptide modification': $i).
% 29.32/29.11  tff(decl_62611, type, fn_post_translational_modification_2: $i > $i).
% 29.32/29.11  tff(decl_62612, type, fn_post_translational_modification_3: $i > $i).
% 29.32/29.11  tff(decl_62613, type, fn_post_translational_modification_6: $i > $i).
% 29.32/29.11  tff(decl_62614, type, fn_post_translational_modification_7: $i > $i).
% 29.32/29.11  tff(decl_62615, type, fn_post_translational_modification_8: $i > $i).
% 29.32/29.11  tff(decl_62616, type, fn_post_translational_modification_9: $i > $i).
% 29.32/29.11  tff(decl_62617, type, fn_post_translational_modification_11: $i > $i).
% 29.32/29.11  tff(decl_62618, type, posterior_1: $i > $o).
% 29.32/29.11  tff(decl_62619, type, 'Posterior': $i).
% 29.32/29.11  tff(decl_62620, type, 'Region of the body at the bottom or hind end, opposite of the anterior region.': $i).
% 29.32/29.11  tff(decl_62621, type, caudal: $i).
% 29.32/29.11  tff(decl_62622, type, posterior: $i).
% 29.32/29.11  tff(decl_62623, type, 'Posterior-End': $i).
% 29.32/29.11  tff(decl_62624, type, 'The rear end region.': $i).
% 29.32/29.11  tff(decl_62625, type, 'end of posterior': $i).
% 29.32/29.11  tff(decl_62626, type, 'posterior end': $i).
% 29.32/29.11  tff(decl_62627, type, 'posterior-end': $i).
% 29.32/29.11  tff(decl_62628, type, 'Posterior-Pituitary': $i).
% 29.32/29.11  tff(decl_62629, type, 'An extension of the hypothalamus, composed of neurons. Stores and secretes hypothalamic hormones such as oxytocin and antidiuretic hormone. Also called the neurohypophysis.': $i).
% 29.32/29.11  tff(decl_62630, type, 'pituitary of posterior': $i).
% 29.32/29.11  tff(decl_62631, type, 'posterior pituitary': $i).
% 29.32/29.11  tff(decl_62632, type, 'posterior-pituitary': $i).
% 29.32/29.11  tff(decl_62633, type, 'Posterior-Structure': $i).
% 29.32/29.11  tff(decl_62634, type, 'The structure situated behind or at the rear end.': $i).
% 29.32/29.11  tff(decl_62635, type, 'structure of posterior': $i).
% 29.32/29.11  tff(decl_62636, type, 'posterior structure': $i).
% 29.32/29.11  tff(decl_62637, type, 'posterior-structure': $i).
% 29.32/29.11  tff(decl_62638, type, fn_posterior_structure_1: $i > $i).
% 29.32/29.11  tff(decl_62639, type, 'Postzygotic-Barrier': $i).
% 29.32/29.11  tff(decl_62640, type, 'A barrier to reproduction between two different species. Postzygotic barriers allow fertilization to occur but the resulting zygote does not develop into a viable, fertile hybrid.': $i).
% 29.32/29.11  tff(decl_62641, type, 'postzygotic barrier': $i).
% 29.32/29.11  tff(decl_62642, type, 'postzygotic-barrier': $i).
% 29.32/29.11  tff(decl_62643, type, 'Potassium': $i).
% 29.32/29.11  tff(decl_62644, type, 'Potassium is a metal atom with atomic number 19. It is represented by the symbol K.': $i).
% 29.32/29.11  tff(decl_62645, type, 'K': $i).
% 29.32/29.11  tff(decl_62646, type, potassium: $i).
% 29.32/29.11  tff(decl_62647, type, fn_potassium_4: $i > $i).
% 29.32/29.11  tff(decl_62648, type, fn_potassium_5: $i > $i).
% 29.32/29.11  tff(decl_62649, type, fn_potassium_6: $i > $i).
% 29.32/29.11  tff(decl_62650, type, fn_potassium_7: $i > $i).
% 29.32/29.11  tff(decl_62651, type, fn_potassium_11: $i > $i).
% 29.32/29.11  tff(decl_62652, type, fn_potassium_12: $i > $i).
% 29.32/29.11  tff(decl_62653, type, fn_potassium_13: $i > $i).
% 29.32/29.11  tff(decl_62654, type, fn_potassium_14: $i > $i).
% 29.32/29.11  tff(decl_62655, type, fn_potassium_15: $i > $i).
% 29.32/29.11  tff(decl_62656, type, fn_potassium_16: $i > $i).
% 29.32/29.11  tff(decl_62657, type, fn_potassium_17: $i > $i).
% 29.32/29.11  tff(decl_62658, type, fn_potassium_18: $i > $i).
% 29.32/29.11  tff(decl_62659, type, fn_potassium_19: $i > $i).
% 29.32/29.11  tff(decl_62660, type, fn_potassium_20: $i > $i).
% 29.32/29.11  tff(decl_62661, type, "39.1": $i).
% 29.32/29.11  tff(decl_62662, type, "0.82": $i).
% 29.32/29.11  tff(decl_62663, type, fn_potassium_8: $i > $i).
% 29.32/29.11  tff(decl_62664, type, fn_potassium_10: $i > $i).
% 29.32/29.11  tff(decl_62665, type, fn_potassium_9: $i > $i).
% 29.32/29.11  tff(decl_62666, type, potassium_cycle_1: $i > $o).
% 29.32/29.11  tff(decl_62667, type, 'Potassium-Cycle': $i).
% 29.32/29.11  tff(decl_62668, type, 'Local biogeochemical cycle which cycles potassium through the biotic and abiotic components of ecosystems.': $i).
% 29.32/29.11  tff(decl_62669, type, 'undergo the potassium cycle': $i).
% 29.32/29.11  tff(decl_62670, type, 'cycle of potassium': $i).
% 29.32/29.11  tff(decl_62671, type, 'potassium cycle': $i).
% 29.32/29.11  tff(decl_62672, type, 'potassium-cycle': $i).
% 29.32/29.11  tff(decl_62673, type, fn_potassium_cycle_1: $i > $i).
% 29.32/29.11  tff(decl_62674, type, fn_potassium_cycle_2: $i > $i).
% 29.32/29.11  tff(decl_62675, type, fn_potassium_cycle_3: $i > $i).
% 29.32/29.11  tff(decl_62676, type, fn_potassium_cycle_4: $i > $i).
% 29.32/29.11  tff(decl_62677, type, fn_potassium_cycle_5: $i > $i).
% 29.32/29.11  tff(decl_62678, type, fn_potassium_cycle_6: $i > $i).
% 29.32/29.11  tff(decl_62679, type, fn_potassium_cycle_7: $i > $i).
% 29.32/29.11  tff(decl_62680, type, fn_potassium_cycle_8: $i > $i).
% 29.32/29.11  tff(decl_62681, type, fn_potassium_cycle_9: $i > $i).
% 29.32/29.11  tff(decl_62682, type, fn_potassium_cycle_10: $i > $i).
% 29.32/29.11  tff(decl_62683, type, fn_potassium_cycle_11: $i > $i).
% 29.32/29.11  tff(decl_62684, type, fn_potassium_cycle_12: $i > $i).
% 29.32/29.11  tff(decl_62685, type, fn_potassium_cycle_13: $i > $i).
% 29.32/29.11  tff(decl_62686, type, fn_potassium_cycle_14: $i > $i).
% 29.32/29.11  tff(decl_62687, type, fn_potassium_cycle_15: $i > $i).
% 29.32/29.11  tff(decl_62688, type, fn_potassium_cycle_16: $i > $i).
% 29.32/29.11  tff(decl_62689, type, fn_potassium_cycle_17: $i > $i).
% 29.32/29.11  tff(decl_62690, type, 'Potassium-Gated-Channel': $i).
% 29.32/29.11  tff(decl_62691, type, 'A transmembrane protein that responds to voltage changes across the membrane by allowing potassium ions to flow out of the cell, returning the membrane potential to its resting state.': $i).
% 29.32/29.11  tff(decl_62692, type, 'potassium gated channel': $i).
% 29.32/29.11  tff(decl_62693, type, 'potassium-gated-channel': $i).
% 29.32/29.11  tff(decl_62694, type, voltage_gated_ion_channel_1: $i > $o).
% 29.32/29.11  tff(decl_62695, type, 'Potassium-Ion': $i).
% 29.32/29.11  tff(decl_62696, type, 'An atom of potassium with a charge of 1+; plays an essential role int eh formation of the resting potential in nerve cells.': $i).
% 29.32/29.11  tff(decl_62697, type, 'k+': $i).
% 29.32/29.11  tff(decl_62698, type, 'ion of potassium': $i).
% 29.32/29.11  tff(decl_62699, type, 'potassium ion': $i).
% 29.32/29.11  tff(decl_62700, type, 'potassium-ion': $i).
% 29.32/29.11  tff(decl_62701, type, fn_potassium_ion_1: $i > $i).
% 29.32/29.11  tff(decl_62702, type, fn_potassium_ion_2: $i > $i).
% 29.32/29.11  tff(decl_62703, type, fn_potassium_ion_3: $i > $i).
% 29.32/29.11  tff(decl_62704, type, fn_potassium_ion_4: $i > $i).
% 29.32/29.11  tff(decl_62705, type, fn_potassium_ion_6: $i > $i).
% 29.32/29.11  tff(decl_62706, type, fn_potassium_ion_7: $i > $i).
% 29.32/29.11  tff(decl_62707, type, fn_potassium_ion_5: $i > $i).
% 29.32/29.11  tff(decl_62708, type, potato_plant_1: $i > $o).
% 29.32/29.11  tff(decl_62709, type, 'Potato-Plant': $i).
% 29.32/29.11  tff(decl_62710, type, 'Potato is a starchy, tuberous crop.': $i).
% 29.32/29.11  tff(decl_62711, type, 'plant of potato': $i).
% 29.32/29.11  tff(decl_62712, type, 'potato plant': $i).
% 29.32/29.11  tff(decl_62713, type, 'potato-plant': $i).
% 29.32/29.11  tff(decl_62714, type, fn_potato_plant_1: $i > $i).
% 29.32/29.11  tff(decl_62715, type, fn_potato_plant_2: $i > $i).
% 29.32/29.11  tff(decl_62716, type, fn_potato_plant_3: $i > $i).
% 29.32/29.11  tff(decl_62717, type, fn_potato_plant_4: $i > $i).
% 29.32/29.11  tff(decl_62718, type, fn_potato_plant_5: $i > $i).
% 29.32/29.11  tff(decl_62719, type, 'Potential-Energy': $i).
% 29.32/29.11  tff(decl_62720, type, 'The energy that an object or matter has due to its position or location.': $i).
% 29.32/29.11  tff(decl_62721, type, 'energy of potential': $i).
% 29.32/29.11  tff(decl_62722, type, 'potential energy': $i).
% 29.32/29.11  tff(decl_62723, type, 'potential-energy': $i).
% 29.32/29.11  tff(decl_62724, type, 'Potential-Value': $i).
% 29.32/29.11  tff(decl_62725, type, potential: $i).
% 29.32/29.11  tff(decl_62726, type, 'potential of water': $i).
% 29.32/29.11  tff(decl_62727, type, 'water potential': $i).
% 29.32/29.11  tff(decl_62728, type, 'water-potential': $i).
% 29.32/29.11  tff(decl_62729, type, 'osmotic potential': $i).
% 29.32/29.11  tff(decl_62730, type, 'potential of solute': $i).
% 29.32/29.11  tff(decl_62731, type, 'solute potential': $i).
% 29.32/29.11  tff(decl_62732, type, 'solute-potential': $i).
% 29.32/29.11  tff(decl_62733, type, 'potential of pressure': $i).
% 29.32/29.11  tff(decl_62734, type, 'pressure potential': $i).
% 29.32/29.11  tff(decl_62735, type, 'pressure-potential': $i).
% 29.32/29.11  tff(decl_62736, type, 'value of potential': $i).
% 29.32/29.11  tff(decl_62737, type, 'potential value': $i).
% 29.32/29.11  tff(decl_62738, type, 'potential-value': $i).
% 29.32/29.11  tff(decl_62739, type, power_constant_1: $i > $o).
% 29.32/29.11  tff(decl_62740, type, 'Power-Constant': $i).
% 29.32/29.11  tff(decl_62741, type, 'constant of power': $i).
% 29.32/29.11  tff(decl_62742, type, 'power constant': $i).
% 29.32/29.11  tff(decl_62743, type, 'power-constant': $i).
% 29.32/29.11  tff(decl_62744, type, 'Power-Value': $i).
% 29.32/29.11  tff(decl_62745, type, 'the rate of doing work': $i).
% 29.32/29.11  tff(decl_62746, type, power: $i).
% 29.32/29.11  tff(decl_62747, type, 'value of power': $i).
% 29.32/29.11  tff(decl_62748, type, 'power value': $i).
% 29.32/29.11  tff(decl_62749, type, 'power-value': $i).
% 29.32/29.11  tff(decl_62750, type, 'Practice-Hypothesis-Of-Play': $i).
% 29.32/29.11  tff(decl_62751, type, 'The hypothesis that play is a type of learning that allows young animals to perfect behaviors that they will need as adults. As an example, kittens stalking and pouncing on each other could be practicing their hunting skills.': $i).
% 29.32/29.11  tff(decl_62752, type, 'practice hypothesis of play': $i).
% 29.32/29.11  tff(decl_62753, type, 'practice-hypothesis-of-play': $i).
% 29.32/29.11  tff(decl_62754, type, 'Prader-Willi-Syndrome': $i).
% 29.32/29.11  tff(decl_62755, type, 'A rare congenital disease in which some genes are missing on chromosome 15.': $i).
% 29.32/29.11  tff(decl_62756, type, 'prader willi syndrome': $i).
% 29.32/29.11  tff(decl_62757, type, 'prader-willi-syndrome': $i).
% 29.32/29.11  tff(decl_62758, type, praseodymium_1: $i > $o).
% 29.32/29.11  tff(decl_62759, type, 'Praseodymium': $i).
% 29.32/29.11  tff(decl_62760, type, 'Praseodymium is a metal atom with atomic number 59. It is represented by the symbol Pr.': $i).
% 29.32/29.11  tff(decl_62761, type, praseodymium: $i).
% 29.32/29.11  tff(decl_62762, type, pr: $i).
% 29.32/29.11  tff(decl_62763, type, fn_praseodymium_4: $i > $i).
% 29.32/29.11  tff(decl_62764, type, fn_praseodymium_5: $i > $i).
% 29.32/29.11  tff(decl_62765, type, fn_praseodymium_6: $i > $i).
% 29.32/29.11  tff(decl_62766, type, fn_praseodymium_7: $i > $i).
% 29.32/29.11  tff(decl_62767, type, fn_praseodymium_11: $i > $i).
% 29.32/29.11  tff(decl_62768, type, fn_praseodymium_12: $i > $i).
% 29.32/29.11  tff(decl_62769, type, fn_praseodymium_13: $i > $i).
% 29.32/29.11  tff(decl_62770, type, fn_praseodymium_14: $i > $i).
% 29.32/29.11  tff(decl_62771, type, "1.13": $i).
% 29.32/29.11  tff(decl_62772, type, "141": $i).
% 29.32/29.11  tff(decl_62773, type, "140.9": $i).
% 29.32/29.11  tff(decl_62774, type, fn_praseodymium_9: $i > $i).
% 29.32/29.11  tff(decl_62775, type, fn_praseodymium_10: $i > $i).
% 29.32/29.11  tff(decl_62776, type, fn_praseodymium_8: $i > $i).
% 29.32/29.11  tff(decl_62777, type, 'Pre-mRNA': $i).
% 29.32/29.11  tff(decl_62778, type, 'Messenger RNA before it has been modified after transcription.': $i).
% 29.32/29.11  tff(decl_62779, type, 'primary transcript': $i).
% 29.32/29.11  tff(decl_62780, type, 'primary-transcript': $i).
% 29.32/29.11  tff(decl_62781, type, 'precursor mrna': $i).
% 29.32/29.11  tff(decl_62782, type, 'precursor-mrna': $i).
% 29.32/29.11  tff(decl_62783, type, 'precursor messenger rna': $i).
% 29.32/29.11  tff(decl_62784, type, 'precursor-messenger-rna': $i).
% 29.32/29.11  tff(decl_62785, type, 'rna transcript': $i).
% 29.32/29.11  tff(decl_62786, type, 'rna-transcript': $i).
% 29.32/29.11  tff(decl_62787, type, 'initial rna transcript': $i).
% 29.32/29.11  tff(decl_62788, type, 'initial-rna-transcript': $i).
% 29.32/29.11  tff(decl_62789, type, 'pre mrna': $i).
% 29.32/29.11  tff(decl_62790, type, 'pre-mrna': $i).
% 29.32/29.11  tff(decl_62791, type, fn_pre_mrna_1: $i > $i).
% 29.32/29.11  tff(decl_62792, type, fn_pre_mrna_2: $i > $i).
% 29.32/29.11  tff(decl_62793, type, fn_pre_mrna_5: $i > $i).
% 29.32/29.11  tff(decl_62794, type, fn_pre_mrna_7: $i > $i).
% 29.32/29.11  tff(decl_62795, type, fn_pre_mrna_8: $i > $i).
% 29.32/29.11  tff(decl_62796, type, fn_pre_mrna_9: $i > $i).
% 29.32/29.11  tff(decl_62797, type, fn_pre_mrna_10: $i > $i).
% 29.32/29.11  tff(decl_62798, type, fn_pre_mrna_11: $i > $i).
% 29.32/29.11  tff(decl_62799, type, fn_pre_mrna_12: $i > $i).
% 29.32/29.11  tff(decl_62800, type, fn_pre_mrna_13: $i > $i).
% 29.32/29.11  tff(decl_62801, type, fn_pre_mrna_14: $i > $i).
% 29.32/29.11  tff(decl_62802, type, fn_pre_mrna_15: $i > $i).
% 29.32/29.11  tff(decl_62803, type, fn_pre_mrna_16: $i > $i).
% 29.32/29.11  tff(decl_62804, type, fn_pre_mrna_18: $i > $i).
% 29.32/29.11  tff(decl_62805, type, fn_rna_15: $i > $i).
% 29.32/29.11  tff(decl_62806, type, fn_rna_7: $i > $i).
% 29.32/29.11  tff(decl_62807, type, fn_rna_16: $i > $i).
% 29.32/29.11  tff(decl_62808, type, fn_rna_6: $i > $i).
% 29.32/29.11  tff(decl_62809, type, fn_rna_4: $i > $i).
% 29.32/29.11  tff(decl_62810, type, 'Precipitation': $i).
% 29.32/29.11  tff(decl_62811, type, 'Any product of the condensation of atmospheric water vapor that falls to the Earth\\s surface (e.g., rain, snow, ice pellets).': $i).
% 29.32/29.11  tff(decl_62812, type, precipitation: $i).
% 29.32/29.11  tff(decl_62813, type, fn_precipitation_1: $i > $i).
% 29.32/29.11  tff(decl_62814, type, fn_precipitation_2: $i > $i).
% 29.32/29.11  tff(decl_62815, type, 'Precipitation-Form': $i).
% 29.32/29.11  tff(decl_62816, type, 'Water that falls to the earth in various forms, including rain, snow, and fog.': $i).
% 29.32/29.11  tff(decl_62817, type, 'form of precipitation': $i).
% 29.32/29.11  tff(decl_62818, type, 'precipitation form': $i).
% 29.32/29.11  tff(decl_62819, type, 'precipitation-form': $i).
% 29.32/29.11  tff(decl_62820, type, precursor_1: $i > $o).
% 29.32/29.11  tff(decl_62821, type, 'Precursor': $i).
% 29.32/29.11  tff(decl_62822, type, 'Entity that participates in an event and precedes another entity, like a result of that event.': $i).
% 29.32/29.11  tff(decl_62823, type, precursor: $i).
% 29.32/29.11  tff(decl_62824, type, fn_precursor_1: $i > $i).
% 29.32/29.11  tff(decl_62825, type, fn_precursor_2: $i > $i).
% 29.32/29.11  tff(decl_62826, type, fn_precursor_3: $i > $i).
% 29.32/29.11  tff(decl_62827, type, 'Predation': $i).
% 29.32/29.11  tff(decl_62828, type, 'An interspecific interaction in which one species eats the other.': $i).
% 29.32/29.11  tff(decl_62829, type, predate: $i).
% 29.32/29.11  tff(decl_62830, type, predation: $i).
% 29.32/29.11  tff(decl_62831, type, predator_1: $i > $o).
% 29.32/29.11  tff(decl_62832, type, 'Predator': $i).
% 29.32/29.11  tff(decl_62833, type, 'An animal that preys upon other animals.': $i).
% 29.32/29.11  tff(decl_62834, type, predator: $i).
% 29.32/29.11  tff(decl_62835, type, 'Predict': $i).
% 29.32/29.11  tff(decl_62836, type, 'to declare or indicate in advance; to foretell on the basis of observation, experience, or scientific reason.': $i).
% 29.32/29.11  tff(decl_62837, type, predict: $i).
% 29.32/29.11  tff(decl_62838, type, pregnancy_1: $i > $o).
% 29.32/29.11  tff(decl_62839, type, 'Pregnancy': $i).
% 29.32/29.11  tff(decl_62840, type, 'The development of one or more offspring in the uterus.': $i).
% 29.32/29.11  tff(decl_62841, type, pregnancy: $i).
% 29.32/29.11  tff(decl_62842, type, pregnant_female_1: $i > $o).
% 29.32/29.11  tff(decl_62843, type, 'Pregnant-Female': $i).
% 29.32/29.11  tff(decl_62844, type, 'A female carrying one or more unborn offspring.': $i).
% 29.32/29.11  tff(decl_62845, type, 'pregnant female': $i).
% 29.32/29.11  tff(decl_62846, type, 'pregnant-female': $i).
% 29.32/29.11  tff(decl_62847, type, fn_pregnant_female_1: $i > $i).
% 29.32/29.11  tff(decl_62848, type, 'Pregnant-Uterus': $i).
% 29.32/29.11  tff(decl_62849, type, 'Uterus of a pregant viviparous mother.': $i).
% 29.32/29.11  tff(decl_62850, type, 'pregnant uterus': $i).
% 29.32/29.11  tff(decl_62851, type, 'pregnant-uterus': $i).
% 29.32/29.11  tff(decl_62852, type, 'Premolar-Tooth': $i).
% 29.32/29.11  tff(decl_62853, type, 'Relatively short, strong tooth specialized for crushing and grinding  food.  Premolars are the teeth which are found between the canines and the molars.': $i).
% 29.32/29.11  tff(decl_62854, type, 'tooth of premolar': $i).
% 29.32/29.11  tff(decl_62855, type, 'premolar tooth': $i).
% 29.32/29.11  tff(decl_62856, type, 'premolar-tooth': $i).
% 29.32/29.11  tff(decl_62857, type, fn_premolar_tooth_1: $i > $i).
% 29.32/29.11  tff(decl_62858, type, fn_premolar_tooth_2: $i > $i).
% 29.32/29.11  tff(decl_62859, type, fn_premolar_tooth_3: $i > $i).
% 29.32/29.11  tff(decl_62860, type, fn_premolar_tooth_4: $i > $i).
% 29.32/29.11  tff(decl_62861, type, fn_premolar_tooth_5: $i > $i).
% 29.32/29.11  tff(decl_62862, type, fn_premolar_tooth_6: $i > $i).
% 29.32/29.11  tff(decl_62863, type, preparatory_event_1: $i > $o).
% 29.32/29.11  tff(decl_62864, type, 'Preparatory-Event': $i).
% 29.32/29.11  tff(decl_62865, type, 'preparatory event': $i).
% 29.32/29.11  tff(decl_62866, type, 'preparatory-event': $i).
% 29.32/29.11  tff(decl_62867, type, 'Preprophase-Band': $i).
% 29.32/29.11  tff(decl_62868, type, 'A ring-shaped microtubular array in the cortex of a plant cell that is about to begin mitosis.': $i).
% 29.32/29.11  tff(decl_62869, type, 'preprophase band': $i).
% 29.32/29.11  tff(decl_62870, type, 'preprophase-band': $i).
% 29.32/29.11  tff(decl_62871, type, 'Prepuce': $i).
% 29.32/29.11  tff(decl_62872, type, 'A fold of skin that covers and protects the head of the penis or clitoris.': $i).
% 29.32/29.11  tff(decl_62873, type, prepuce: $i).
% 29.32/29.11  tff(decl_62874, type, 'Presence-of-nonpolar-fatty-acid-polymers': $i).
% 29.32/29.11  tff(decl_62875, type, 'The presence of nonpolar fatty acid polymers in a lipid.': $i).
% 29.32/29.11  tff(decl_62876, type, 'presence of nonpolar fatty acid polymer': $i).
% 29.32/29.11  tff(decl_62877, type, 'presence-of-nonpolar-fatty-acid-polymer': $i).
% 29.32/29.11  tff(decl_62878, type, 'Pressure-Constant': $i).
% 29.32/29.11  tff(decl_62879, type, 'constant of pressure': $i).
% 29.32/29.11  tff(decl_62880, type, 'pressure constant': $i).
% 29.32/29.11  tff(decl_62881, type, 'pressure-constant': $i).
% 29.32/29.11  tff(decl_62882, type, pressure_flow_1: $i > $o).
% 29.32/29.11  tff(decl_62883, type, 'Pressure-Flow': $i).
% 29.32/29.11  tff(decl_62884, type, 'In angiosperms, the mechanism of translocation of phloem sap from source to sink.': $i).
% 29.32/29.11  tff(decl_62885, type, 'flow of pressure': $i).
% 29.32/29.11  tff(decl_62886, type, 'pressure flow': $i).
% 29.32/29.11  tff(decl_62887, type, 'pressure-flow': $i).
% 29.32/29.11  tff(decl_62888, type, 'Pressure-Gradient': $i).
% 29.32/29.11  tff(decl_62889, type, 'A region along which the pressure increases or decreases.': $i).
% 29.32/29.11  tff(decl_62890, type, 'gradient of pressure': $i).
% 29.32/29.11  tff(decl_62891, type, 'pressure gradient': $i).
% 29.32/29.11  tff(decl_62892, type, 'pressure-gradient': $i).
% 29.32/29.11  tff(decl_62893, type, fn_pressure_gradient_3: $i > $i).
% 29.32/29.11  tff(decl_62894, type, fn_pressure_gradient_4: $i > $i).
% 29.32/29.11  tff(decl_62895, type, fn_pressure_gradient_5: $i > $i).
% 29.32/29.11  tff(decl_62896, type, fn_pressure_gradient_6: $i > $i).
% 29.32/29.11  tff(decl_62897, type, pressure_scale_1: $i > $o).
% 29.32/29.11  tff(decl_62898, type, 'Pressure-Scale': $i).
% 29.32/29.11  tff(decl_62899, type, 'scale of pressure': $i).
% 29.32/29.11  tff(decl_62900, type, 'pressure scale': $i).
% 29.32/29.11  tff(decl_62901, type, 'pressure-scale': $i).
% 29.32/29.11  tff(decl_62902, type, 'Pressure-Value': $i).
% 29.32/29.11  tff(decl_62903, type, 'pressure level': $i).
% 29.32/29.11  tff(decl_62904, type, 'force per unit area': $i).
% 29.32/29.11  tff(decl_62905, type, pressure: $i).
% 29.32/29.11  tff(decl_62906, type, 'value of pressure': $i).
% 29.32/29.11  tff(decl_62907, type, 'pressure value': $i).
% 29.32/29.11  tff(decl_62908, type, 'pressure-value': $i).
% 29.32/29.11  tff(decl_62909, type, 'Presynaptic-Cell': $i).
% 29.32/29.11  tff(decl_62910, type, 'The transmitting cell at a synapse.': $i).
% 29.32/29.11  tff(decl_62911, type, 'presynaptic cell': $i).
% 29.32/29.11  tff(decl_62912, type, 'presynaptic-cell': $i).
% 29.32/29.11  tff(decl_62913, type, fn_presynaptic_cell_1: $i > $i).
% 29.32/29.11  tff(decl_62914, type, fn_presynaptic_cell_2: $i > $i).
% 29.32/29.11  tff(decl_62915, type, fn_presynaptic_cell_3: $i > $i).
% 29.32/29.11  tff(decl_62916, type, 'Prevention-of-mRNA-Degradation': $i).
% 29.32/29.11  tff(decl_62917, type, 'The 5\\ cap and a poly-A tail added to mRNA after transcription serve to protect mRNA from degradation. The 5\\ end receives a 5\\cap, a modified form of a guanine nucleotide added onto the 5\\ end after transcription of the first 20-40 nucleotides.  At the 3\\ end, an enzyme adds 50-250 more adenine nucleotides forming a poly-A tail.': $i).
% 29.32/29.11  tff(decl_62918, type, 'prevention of mrna degradation': $i).
% 29.32/29.11  tff(decl_62919, type, 'prevention-of-mrna-degradation': $i).
% 29.32/29.11  tff(decl_62920, type, prevention_of_water_loss_1: $i > $o).
% 29.32/29.11  tff(decl_62921, type, 'Prevention-of-Water-Loss': $i).
% 29.32/29.11  tff(decl_62922, type, 'A macrophysiological process in which an organism maintains water balance through a variety of mechanisms.': $i).
% 29.32/29.11  tff(decl_62923, type, 'prevention of water loss': $i).
% 29.32/29.11  tff(decl_62924, type, 'prevention-of-water-loss': $i).
% 29.32/29.11  tff(decl_62925, type, fn_prevention_of_water_loss_1: $i > $i).
% 29.32/29.11  tff(decl_62926, type, 'Prey': $i).
% 29.32/29.11  tff(decl_62927, type, 'An organism that is hunted or caught for food.': $i).
% 29.32/29.11  tff(decl_62928, type, prey: $i).
% 29.32/29.11  tff(decl_62929, type, 'Prezygotic-Barrier': $i).
% 29.32/29.11  tff(decl_62930, type, 'A barrier to hybridization that prevents the sperm of one species from fertilizing the egg of another species.': $i).
% 29.32/29.11  tff(decl_62931, type, 'prezygotic barrier': $i).
% 29.32/29.11  tff(decl_62932, type, 'prezygotic-barrier': $i).
% 29.32/29.11  tff(decl_62933, type, primary_amino_acid_sequence_1: $i > $o).
% 29.32/29.11  tff(decl_62934, type, 'Primary-Amino-Acid-Sequence': $i).
% 29.32/29.11  tff(decl_62935, type, 'The level of protein structure referring to the specific linear sequence of amino acids.  The sequence of amino acids determines the protein\\s identity.': $i).
% 29.32/29.11  tff(decl_62936, type, 'first stage of protein folding': $i).
% 29.32/29.11  tff(decl_62937, type, 'primary structure': $i).
% 29.32/29.11  tff(decl_62938, type, 'primary amino acid sequence': $i).
% 29.32/29.11  tff(decl_62939, type, 'primary-amino-acid-sequence': $i).
% 29.32/29.11  tff(decl_62940, type, 'Primary-Cell-Wall': $i).
% 29.32/29.11  tff(decl_62941, type, 'In plants, a thin, semi-permeable layer that is secreted outside the plasma membrane in young cells.': $i).
% 29.32/29.11  tff(decl_62942, type, 'primary cell wall': $i).
% 29.32/29.11  tff(decl_62943, type, 'primary cell-wall': $i).
% 29.32/29.11  tff(decl_62944, type, 'primary-cell-wall': $i).
% 29.32/29.11  tff(decl_62945, type, 'Primary-Constant': $i).
% 29.32/29.11  tff(decl_62946, type, 'constant of primary': $i).
% 29.32/29.11  tff(decl_62947, type, 'primary constant': $i).
% 29.32/29.11  tff(decl_62948, type, 'primary-constant': $i).
% 29.32/29.11  tff(decl_62949, type, 'Primary-Consumer': $i).
% 29.32/29.11  tff(decl_62950, type, 'An organism that eats primary producers (autotrophs).': $i).
% 29.32/29.11  tff(decl_62951, type, 'consumer of primary': $i).
% 29.32/29.11  tff(decl_62952, type, 'primary consumer': $i).
% 29.32/29.11  tff(decl_62953, type, 'primary-consumer': $i).
% 29.32/29.11  tff(decl_62954, type, fn_primary_consumer_1: $i > $i).
% 29.32/29.11  tff(decl_62955, type, fn_primary_consumer_2: $i > $i).
% 29.32/29.11  tff(decl_62956, type, fn_primary_consumer_4: $i > $i).
% 29.32/29.11  tff(decl_62957, type, fn_primary_consumer_5: $i > $i).
% 29.32/29.11  tff(decl_62958, type, fn_primary_consumer_6: $i > $i).
% 29.32/29.11  tff(decl_62959, type, fn_primary_consumer_7: $i > $i).
% 29.32/29.11  tff(decl_62960, type, fn_primary_consumer_8: $i > $i).
% 29.32/29.11  tff(decl_62961, type, primary_consumers_1: $i > $o).
% 29.32/29.11  tff(decl_62962, type, 'Primary-Consumers': $i).
% 29.32/29.11  tff(decl_62963, type, 'Group of organisms in an ecosystem which feeds directly on producers.': $i).
% 29.32/29.11  tff(decl_62964, type, 'Primary-Electron-Acceptor': $i).
% 29.32/29.11  tff(decl_62965, type, 'Found in the chloroplast thylakoid membrane or in the photosynthetic membrane of some prokaryotes, the primary electron acceptor is a specialized molecule that sits in the reaction center with chlorophyll a molecules. The primary electron acceptor accepts electrons from the chlorophyll a molecules after the reaction center has been': $i).
% 29.32/29.11  tff(decl_62966, type, 'primary electron acceptor': $i).
% 29.32/29.11  tff(decl_62967, type, 'primary-electron-acceptor': $i).
% 29.32/29.11  tff(decl_62968, type, 'Primary-Growth': $i).
% 29.32/29.11  tff(decl_62969, type, 'In plants, growth along an apical meristem that lengthens stems and roots.': $i).
% 29.32/29.11  tff(decl_62970, type, 'growth of primary': $i).
% 29.32/29.11  tff(decl_62971, type, 'primary growth': $i).
% 29.32/29.11  tff(decl_62972, type, 'primary-growth': $i).
% 29.32/29.11  tff(decl_62973, type, primary_immune_response_1: $i > $o).
% 29.32/29.11  tff(decl_62974, type, 'Primary-Immune-Response': $i).
% 29.32/29.11  tff(decl_62975, type, 'The immune system\\s first response on exposure to a novel antigen. It appears 10-17 days after the initial exposure.': $i).
% 29.32/29.11  tff(decl_62976, type, 'primary immune response': $i).
% 29.32/29.11  tff(decl_62977, type, 'primary-immune-response': $i).
% 29.32/29.11  tff(decl_62978, type, 'Primary-Motor-Cortex': $i).
% 29.32/29.11  tff(decl_62979, type, 'A region of the brain that in humans is located in the posterior region of the frontal lobe. It is responsible for sending the first signals that control the actions of skeletal muscles.': $i).
% 29.32/29.11  tff(decl_62980, type, 'motor cortex': $i).
% 29.32/29.11  tff(decl_62981, type, 'motor-cortex': $i).
% 29.32/29.11  tff(decl_62982, type, 'primary motor cortex': $i).
% 29.32/29.11  tff(decl_62983, type, 'primary-motor-cortex': $i).
% 29.32/29.11  tff(decl_62984, type, 'Primary-Oocyte': $i).
% 29.32/29.11  tff(decl_62985, type, 'A primary oocyte is a developmentally-arrested precursor cell which may eventually develop into a mature egg or oocyte.': $i).
% 29.32/29.11  tff(decl_62986, type, 'oocyte of primary': $i).
% 29.32/29.11  tff(decl_62987, type, 'primary oocyte': $i).
% 29.32/29.11  tff(decl_62988, type, 'primary-oocyte': $i).
% 29.32/29.11  tff(decl_62989, type, 'Primary-Plant': $i).
% 29.32/29.11  tff(decl_62990, type, 'The tissues produced by apical meristems, which lengthen stems and roots.': $i).
% 29.32/29.11  tff(decl_62991, type, 'plant of primary': $i).
% 29.32/29.11  tff(decl_62992, type, 'primary plant': $i).
% 29.32/29.11  tff(decl_62993, type, 'primary-plant': $i).
% 29.32/29.11  tff(decl_62994, type, 'Primary-Plant-Body': $i).
% 29.32/29.11  tff(decl_62995, type, 'Plant body tissues that are produced by growth from apical meristems.': $i).
% 29.32/29.11  tff(decl_62996, type, 'primary plant body': $i).
% 29.32/29.11  tff(decl_62997, type, 'primary-plant-body': $i).
% 29.32/29.11  tff(decl_62998, type, primary_rna_transcript_1: $i > $o).
% 29.32/29.11  tff(decl_62999, type, 'Primary-RNA-Transcript': $i).
% 29.32/29.11  tff(decl_63000, type, 'The initial RNA transcript, before any post-transcriptional modification has occurred.': $i).
% 29.32/29.11  tff(decl_63001, type, 'primary rna transcript': $i).
% 29.32/29.11  tff(decl_63002, type, 'primary-rna-transcript': $i).
% 29.32/29.11  tff(decl_63003, type, 'Primary-Somatosensory-Cortex': $i).
% 29.32/29.11  tff(decl_63004, type, 'A region of the brain located in the postcentral gyrus of the parietal lobe. It is responsible for the perception of touch and tactile stimuli.': $i).
% 29.32/29.11  tff(decl_63005, type, 'somatosensory cortex': $i).
% 29.32/29.11  tff(decl_63006, type, 'somatosensory-cortex': $i).
% 29.32/29.11  tff(decl_63007, type, 'primary somatosensory cortex': $i).
% 29.32/29.11  tff(decl_63008, type, 'primary-somatosensory-cortex': $i).
% 29.32/29.11  tff(decl_63009, type, primary_spermatocyte_1: $i > $o).
% 29.32/29.11  tff(decl_63010, type, 'Primary-spermatocyte': $i).
% 29.32/29.11  tff(decl_63011, type, 'The male sex cell which undergoes meiosis to produce sperm cells.': $i).
% 29.32/29.11  tff(decl_63012, type, 'spermatocyte of primary': $i).
% 29.32/29.11  tff(decl_63013, type, 'primary spermatocyte': $i).
% 29.32/29.11  tff(decl_63014, type, 'primary-spermatocyte': $i).
% 29.32/29.11  tff(decl_63015, type, spermatocyte_1: $i > $o).
% 29.32/29.11  tff(decl_63016, type, fn_primary_spermatocyte_1: $i > $i).
% 29.32/29.11  tff(decl_63017, type, fn_primary_spermatocyte_2: $i > $i).
% 29.32/29.11  tff(decl_63018, type, fn_primary_spermatocyte_5: $i > $i).
% 29.32/29.11  tff(decl_63019, type, fn_primary_spermatocyte_6: $i > $i).
% 29.32/29.11  tff(decl_63020, type, fn_primary_spermatocyte_7: $i > $i).
% 29.32/29.11  tff(decl_63021, type, fn_primary_spermatocyte_8: $i > $i).
% 29.32/29.11  tff(decl_63022, type, fn_primary_spermatocyte_9: $i > $i).
% 29.32/29.11  tff(decl_63023, type, fn_primary_spermatocyte_10: $i > $i).
% 29.32/29.11  tff(decl_63024, type, fn_primary_spermatocyte_11: $i > $i).
% 29.32/29.11  tff(decl_63025, type, fn_primary_spermatocyte_12: $i > $i).
% 29.32/29.11  tff(decl_63026, type, fn_primary_spermatocyte_13: $i > $i).
% 29.32/29.11  tff(decl_63027, type, fn_primary_spermatocyte_14: $i > $i).
% 29.32/29.11  tff(decl_63028, type, fn_primary_spermatocyte_15: $i > $i).
% 29.32/29.11  tff(decl_63029, type, fn_primary_spermatocyte_16: $i > $i).
% 29.32/29.11  tff(decl_63030, type, fn_primary_spermatocyte_17: $i > $i).
% 29.32/29.11  tff(decl_63031, type, fn_primary_spermatocyte_18: $i > $i).
% 29.32/29.11  tff(decl_63032, type, fn_primary_spermatocyte_19: $i > $i).
% 29.32/29.11  tff(decl_63033, type, fn_primary_spermatocyte_20: $i > $i).
% 29.32/29.11  tff(decl_63034, type, fn_primary_spermatocyte_21: $i > $i).
% 29.32/29.11  tff(decl_63035, type, fn_primary_spermatocyte_22: $i > $i).
% 29.32/29.11  tff(decl_63036, type, fn_primary_spermatocyte_23: $i > $i).
% 29.32/29.11  tff(decl_63037, type, fn_primary_spermatocyte_24: $i > $i).
% 29.32/29.11  tff(decl_63038, type, fn_primary_spermatocyte_25: $i > $i).
% 29.32/29.11  tff(decl_63039, type, fn_primary_spermatocyte_26: $i > $i).
% 29.32/29.11  tff(decl_63040, type, fn_primary_spermatocyte_4: $i > $i).
% 29.32/29.11  tff(decl_63041, type, fn_primary_spermatocyte_3: $i > $i).
% 29.32/29.11  tff(decl_63042, type, primary_succession_1: $i > $o).
% 29.32/29.11  tff(decl_63043, type, 'Primary-Succession': $i).
% 29.32/29.11  tff(decl_63044, type, 'Ecological succession that occurs in an area that previously had no living organisms and generally has very little soil, such as a recent lava flow or the area where a glacier has retreated.': $i).
% 29.32/29.11  tff(decl_63045, type, 'succession of primary': $i).
% 29.32/29.11  tff(decl_63046, type, 'primary succession': $i).
% 29.32/29.11  tff(decl_63047, type, 'primary-succession': $i).
% 29.32/29.11  tff(decl_63048, type, secondary_succession_1: $i > $o).
% 29.32/29.11  tff(decl_63049, type, 'Primary-Visual-Cortex': $i).
% 29.32/29.11  tff(decl_63050, type, 'A region of the brain in the posterior area of the occipital lobe, specialized for processing information about stationary and moving objects and pattern formation.': $i).
% 29.32/29.11  tff(decl_63051, type, 'visual cortex': $i).
% 29.32/29.11  tff(decl_63052, type, 'visual-cortex': $i).
% 29.32/29.11  tff(decl_63053, type, 'primary visual cortex': $i).
% 29.32/29.11  tff(decl_63054, type, 'primary-visual-cortex': $i).
% 29.32/29.11  tff(decl_63055, type, 'Primate': $i).
% 29.32/29.11  tff(decl_63056, type, 'A member of the biological order Primates, the group that contains simians (apes and monkeys) and prosimians (lemurs, lorises, galagos and tarsiers ).': $i).
% 29.32/29.11  tff(decl_63057, type, primate: $i).
% 29.32/29.11  tff(decl_63058, type, 'Primer': $i).
% 29.32/29.11  tff(decl_63059, type, 'A primer is a short strand of RNA that binds to unwound DNA segments and serves as a starting point for DNA synthesis.': $i).
% 29.32/29.11  tff(decl_63060, type, primer: $i).
% 29.32/29.11  tff(decl_63061, type, fn_primer_1: $i > $i).
% 29.32/29.11  tff(decl_63062, type, fn_primer_4: $i > $i).
% 29.32/29.11  tff(decl_63063, type, primer_0: $i).
% 29.32/29.11  tff(decl_63064, type, fn_primer_5: $i > $i).
% 29.32/29.11  tff(decl_63065, type, primitive_streak_1: $i > $o).
% 29.32/29.11  tff(decl_63066, type, 'Primitive-Streak': $i).
% 29.32/29.11  tff(decl_63067, type, 'A structure that occurs in the very early embryonic development of reptiles, birds, and mammals. It establishes the eventual anterior-posterior axis of the embryo.': $i).
% 29.32/29.11  tff(decl_63068, type, 'streak of primitive': $i).
% 29.32/29.11  tff(decl_63069, type, 'primitive streak': $i).
% 29.32/29.11  tff(decl_63070, type, 'primitive-streak': $i).
% 29.32/29.11  tff(decl_63071, type, 'Print': $i).
% 29.32/29.11  tff(decl_63072, type, publish: $i).
% 29.32/29.11  tff(decl_63073, type, fn_print_1: $i > $i).
% 29.32/29.11  tff(decl_63074, type, fn_print_2: $i > $i).
% 29.32/29.11  tff(decl_63075, type, prion_1: $i > $o).
% 29.32/29.11  tff(decl_63076, type, 'Prion': $i).
% 29.32/29.11  tff(decl_63077, type, 'An infectious agent that is a misfolded version of a normal cellular protein. Prions appear to increase in number by converting correctly folded versions of the protein to more prions.': $i).
% 29.32/29.11  tff(decl_63078, type, prion: $i).
% 29.32/29.11  tff(decl_63079, type, viroid_1: $i > $o).
% 29.32/29.11  tff(decl_63080, type, fn_prion_1: $i > $i).
% 29.32/29.11  tff(decl_63081, type, fn_prion_2: $i > $i).
% 29.32/29.11  tff(decl_63082, type, fn_prion_3: $i > $i).
% 29.32/29.11  tff(decl_63083, type, fn_prion_4: $i > $i).
% 29.32/29.11  tff(decl_63084, type, fn_prion_5: $i > $i).
% 29.32/29.11  tff(decl_63085, type, fn_prion_6: $i > $i).
% 29.32/29.11  tff(decl_63086, type, fn_prion_7: $i > $i).
% 29.32/29.11  tff(decl_63087, type, fn_prion_8: $i > $i).
% 29.32/29.11  tff(decl_63088, type, 'Priority-Constant': $i).
% 29.32/29.11  tff(decl_63089, type, 'constant of priority': $i).
% 29.32/29.11  tff(decl_63090, type, 'priority constant': $i).
% 29.32/29.11  tff(decl_63091, type, 'priority-constant': $i).
% 29.32/29.11  tff(decl_63092, type, priority_scale_1: $i > $o).
% 29.32/29.11  tff(decl_63093, type, 'Priority-Scale': $i).
% 29.32/29.11  tff(decl_63094, type, 'scale of priority': $i).
% 29.32/29.11  tff(decl_63095, type, 'priority scale': $i).
% 29.32/29.11  tff(decl_63096, type, 'priority-scale': $i).
% 29.32/29.11  tff(decl_63097, type, 'Prism': $i).
% 29.32/29.11  tff(decl_63098, type, 'A prism can sort white light into its component colors.': $i).
% 29.32/29.11  tff(decl_63099, type, prism: $i).
% 29.32/29.11  tff(decl_63100, type, fn_prism_1: $i > $i).
% 29.32/29.11  tff(decl_63101, type, fn_prism_2: $i > $i).
% 29.32/29.11  tff(decl_63102, type, fn_prism_3: $i > $i).
% 29.32/29.11  tff(decl_63103, type, fn_prism_4: $i > $i).
% 29.32/29.11  tff(decl_63104, type, fn_prism_5: $i > $i).
% 29.32/29.11  tff(decl_63105, type, fn_prism_6: $i > $i).
% 29.32/29.11  tff(decl_63106, type, fn_prism_7: $i > $i).
% 29.32/29.11  tff(decl_63107, type, fn_prism_8: $i > $i).
% 29.32/29.11  tff(decl_63108, type, problem_solving_1: $i > $o).
% 29.32/29.11  tff(decl_63109, type, 'Problem-Solving': $i).
% 29.32/29.11  tff(decl_63110, type, 'The cognitive activity of finding solutions to problems.': $i).
% 29.32/29.11  tff(decl_63111, type, 'solving of problem': $i).
% 29.32/29.11  tff(decl_63112, type, 'problem solving': $i).
% 29.32/29.11  tff(decl_63113, type, 'problem-solving': $i).
% 29.32/29.11  tff(decl_63114, type, 'Produce': $i).
% 29.32/29.11  tff(decl_63115, type, 'bring forth': $i).
% 29.32/29.11  tff(decl_63116, type, bring_forth: $i).
% 29.32/29.11  tff(decl_63117, type, 'Producers': $i).
% 29.32/29.11  tff(decl_63118, type, 'Group of organisms in an ecosystem which obtains energy and nutrients from abiotic sources.': $i).
% 29.32/29.11  tff(decl_63119, type, 'Product': $i).
% 29.32/29.11  tff(decl_63120, type, 'The noun product is defined as a thing produced by labor or effort or the result of an act or a process .': $i).
% 29.32/29.11  tff(decl_63121, type, production: $i).
% 29.32/29.11  tff(decl_63122, type, production_of_bile_1: $i > $o).
% 29.32/29.11  tff(decl_63123, type, 'Production-Of-Bile': $i).
% 29.32/29.11  tff(decl_63124, type, 'The process in which bile, a fluid which aids in the digestion of lipids, is produced by the liver and stored in the gall bladder.': $i).
% 29.32/29.11  tff(decl_63125, type, 'bile production': $i).
% 29.32/29.11  tff(decl_63126, type, 'bile-production': $i).
% 29.32/29.11  tff(decl_63127, type, 'production of bile': $i).
% 29.32/29.11  tff(decl_63128, type, 'production-of-bile': $i).
% 29.32/29.11  tff(decl_63129, type, production_of_herceptin_1: $i > $o).
% 29.32/29.11  tff(decl_63130, type, 'Production-Of-Herceptin': $i).
% 29.32/29.11  tff(decl_63131, type, 'The pharmaceutical production of herceptin, a drug used in the treatment for breast cancer involving abnormal HER2 receptors.': $i).
% 29.32/29.11  tff(decl_63132, type, 'herceptin production': $i).
% 29.32/29.11  tff(decl_63133, type, 'herceptin-production': $i).
% 29.32/29.11  tff(decl_63134, type, 'production of herceptin': $i).
% 29.32/29.11  tff(decl_63135, type, 'production-of-herceptin': $i).
% 29.32/29.11  tff(decl_63136, type, fn_production_of_herceptin_1: $i > $i).
% 29.32/29.11  tff(decl_63137, type, fn_production_of_herceptin_2: $i > $i).
% 29.32/29.11  tff(decl_63138, type, fn_production_of_herceptin_3: $i > $i).
% 29.32/29.11  tff(decl_63139, type, 'Progesterone': $i).
% 29.32/29.11  tff(decl_63140, type, 'A steroid hormone involved in the female menstrual cycle. It prepares the uterus for pregnancy and supports the pregnancy itself.': $i).
% 29.32/29.11  tff(decl_63141, type, progesterone: $i).
% 29.32/29.11  tff(decl_63142, type, 'Progestin': $i).
% 29.32/29.11  tff(decl_63143, type, 'A synthetic steroid hormone with effects similar to progesterone. Commonly used for contraception or hormone replacement therapy.': $i).
% 29.32/29.11  tff(decl_63144, type, progestin: $i).
% 29.32/29.11  tff(decl_63145, type, 'Progymnosperm': $i).
% 29.32/29.11  tff(decl_63146, type, 'One of an extinct group of woody, spore-bearing plant that may be an ancestor to seed plants.': $i).
% 29.32/29.11  tff(decl_63147, type, progymnosperm: $i).
% 29.32/29.11  tff(decl_63148, type, 'Prokaryote': $i).
% 29.32/29.11  tff(decl_63149, type, 'Single-celled organism distinguished by the absence of a distinct nucleus.': $i).
% 29.32/29.11  tff(decl_63150, type, 'Prokaryote is a unicellular organism that does not have nucleus.': $i).
% 29.32/29.11  tff(decl_63151, type, prokaryote: $i).
% 29.32/29.11  tff(decl_63152, type, 'prokaryotic cell': $i).
% 29.32/29.11  tff(decl_63153, type, 'prokaryotic-cell': $i).
% 29.32/29.11  tff(decl_63154, type, fn_prokaryote_2: $i > $i).
% 29.32/29.11  tff(decl_63155, type, 'Prokaryote-DNA-Sequence': $i).
% 29.32/29.11  tff(decl_63156, type, 'A DNA sequence found only in prokaryotes.': $i).
% 29.32/29.11  tff(decl_63157, type, 'prokaryote dna sequence': $i).
% 29.32/29.11  tff(decl_63158, type, 'prokaryote-dna-sequence': $i).
% 29.32/29.11  tff(decl_63159, type, fn_prokaryotic_cell_cycle_2: $i > $i).
% 29.32/29.11  tff(decl_63160, type, 'Prokaryotic-Cell-Cycle': $i).
% 29.32/29.11  tff(decl_63161, type, 'The prokaryotic cell cycle is simpler than the eukaryotic cell cycle. The unicellular prokaryotes grow until reaching a critical size, they can replicate DNA and segregate copies of the chromosome.': $i).
% 29.32/29.11  tff(decl_63162, type, 'undergo the prokaryotic cell cycle': $i).
% 29.32/29.11  tff(decl_63163, type, 'prokaryotic cell cycle': $i).
% 29.32/29.11  tff(decl_63164, type, 'prokaryotic-cell-cycle': $i).
% 29.32/29.11  tff(decl_63165, type, fn_prokaryotic_cell_cycle_3: $i > $i).
% 29.32/29.11  tff(decl_63166, type, fn_prokaryotic_cell_cycle_4: $i > $i).
% 29.32/29.11  tff(decl_63167, type, 'Prokaryotic-Cell-Structure': $i).
% 29.32/29.11  tff(decl_63168, type, 'A structure at the cellular level found in prokaryotes.': $i).
% 29.32/29.11  tff(decl_63169, type, 'structure of prokaryote': $i).
% 29.32/29.11  tff(decl_63170, type, 'structure-of-prokaryote': $i).
% 29.32/29.11  tff(decl_63171, type, 'prokaryote structure': $i).
% 29.32/29.11  tff(decl_63172, type, 'prokaryote-structure': $i).
% 29.32/29.11  tff(decl_63173, type, 'prokaryotic cell structure': $i).
% 29.32/29.11  tff(decl_63174, type, 'prokaryotic-cell-structure': $i).
% 29.32/29.11  tff(decl_63175, type, prokaryotic_cellular_respiration_1: $i > $o).
% 29.32/29.11  tff(decl_63176, type, 'Prokaryotic-Cellular-Respiration': $i).
% 29.32/29.11  tff(decl_63177, type, 'Prokaryotic cellular respiration is a set of catabolic pathways which break down glucose in cytosol and use an electron transport chain for the production of 32 ATP molecules.': $i).
% 29.32/29.11  tff(decl_63178, type, 'prokaryotic cellular respiration': $i).
% 29.32/29.11  tff(decl_63179, type, 'prokaryotic-cellular-respiration': $i).
% 29.32/29.11  tff(decl_63180, type, fn_prokaryotic_cellular_respiration_1: $i > $i).
% 29.32/29.11  tff(decl_63181, type, fn_prokaryotic_cellular_respiration_2: $i > $i).
% 29.32/29.11  tff(decl_63182, type, fn_prokaryotic_cellular_respiration_3: $i > $i).
% 29.32/29.11  tff(decl_63183, type, fn_prokaryotic_cellular_respiration_4: $i > $i).
% 29.32/29.11  tff(decl_63184, type, fn_prokaryotic_cellular_respiration_5: $i > $i).
% 29.32/29.11  tff(decl_63185, type, fn_prokaryotic_cellular_respiration_6: $i > $i).
% 29.32/29.11  tff(decl_63186, type, fn_prokaryotic_cellular_respiration_7: $i > $i).
% 29.32/29.11  tff(decl_63187, type, fn_prokaryotic_cellular_respiration_8: $i > $i).
% 29.32/29.11  tff(decl_63188, type, fn_prokaryotic_cellular_respiration_9: $i > $i).
% 29.32/29.11  tff(decl_63189, type, fn_prokaryotic_cellular_respiration_10: $i > $i).
% 29.32/29.11  tff(decl_63190, type, fn_prokaryotic_cellular_respiration_11: $i > $i).
% 29.32/29.11  tff(decl_63191, type, fn_prokaryotic_cellular_respiration_12: $i > $i).
% 29.32/29.11  tff(decl_63192, type, fn_prokaryotic_cellular_respiration_13: $i > $i).
% 29.32/29.11  tff(decl_63193, type, fn_prokaryotic_cellular_respiration_14: $i > $i).
% 29.32/29.11  tff(decl_63194, type, fn_prokaryotic_cellular_respiration_15: $i > $i).
% 29.32/29.11  tff(decl_63195, type, fn_prokaryotic_cellular_respiration_16: $i > $i).
% 29.32/29.11  tff(decl_63196, type, fn_prokaryotic_cellular_respiration_17: $i > $i).
% 29.32/29.11  tff(decl_63197, type, fn_prokaryotic_cellular_respiration_18: $i > $i).
% 29.32/29.11  tff(decl_63198, type, fn_prokaryotic_cellular_respiration_19: $i > $i).
% 29.32/29.11  tff(decl_63199, type, fn_prokaryotic_cellular_respiration_20: $i > $i).
% 29.32/29.11  tff(decl_63200, type, fn_prokaryotic_cellular_respiration_21: $i > $i).
% 29.32/29.11  tff(decl_63201, type, fn_prokaryotic_cellular_respiration_22: $i > $i).
% 29.32/29.11  tff(decl_63202, type, fn_prokaryotic_cellular_respiration_23: $i > $i).
% 29.32/29.11  tff(decl_63203, type, fn_prokaryotic_cellular_respiration_24: $i > $i).
% 29.32/29.11  tff(decl_63204, type, fn_prokaryotic_cellular_respiration_25: $i > $i).
% 29.32/29.11  tff(decl_63205, type, fn_prokaryotic_cellular_respiration_30: $i > $i).
% 29.32/29.11  tff(decl_63206, type, fn_prokaryotic_cellular_respiration_31: $i > $i).
% 29.32/29.11  tff(decl_63207, type, fn_prokaryotic_cellular_respiration_32: $i > $i).
% 29.32/29.11  tff(decl_63208, type, fn_prokaryotic_cellular_respiration_33: $i > $i).
% 29.32/29.11  tff(decl_63209, type, fn_prokaryotic_cellular_respiration_34: $i > $i).
% 29.32/29.11  tff(decl_63210, type, fn_prokaryotic_cellular_respiration_35: $i > $i).
% 29.32/29.11  tff(decl_63211, type, fn_prokaryotic_cellular_respiration_36: $i > $i).
% 29.32/29.11  tff(decl_63212, type, fn_prokaryotic_cellular_respiration_37: $i > $i).
% 29.32/29.11  tff(decl_63213, type, fn_prokaryotic_cellular_respiration_38: $i > $i).
% 29.32/29.11  tff(decl_63214, type, fn_prokaryotic_cellular_respiration_39: $i > $i).
% 29.32/29.11  tff(decl_63215, type, fn_prokaryotic_cellular_respiration_40: $i > $i).
% 29.32/29.11  tff(decl_63216, type, fn_prokaryotic_cellular_respiration_41: $i > $i).
% 29.32/29.11  tff(decl_63217, type, fn_prokaryotic_cellular_respiration_42: $i > $i).
% 29.32/29.11  tff(decl_63218, type, fn_prokaryotic_cellular_respiration_43: $i > $i).
% 29.32/29.11  tff(decl_63219, type, fn_prokaryotic_cellular_respiration_44: $i > $i).
% 29.32/29.11  tff(decl_63220, type, fn_prokaryotic_cellular_respiration_45: $i > $i).
% 29.32/29.11  tff(decl_63221, type, fn_prokaryotic_cellular_respiration_46: $i > $i).
% 29.32/29.11  tff(decl_63222, type, fn_prokaryotic_cellular_respiration_47: $i > $i).
% 29.32/29.11  tff(decl_63223, type, fn_prokaryotic_cellular_respiration_48: $i > $i).
% 29.32/29.11  tff(decl_63224, type, fn_prokaryotic_cellular_respiration_49: $i > $i).
% 29.32/29.11  tff(decl_63225, type, fn_prokaryotic_cellular_respiration_50: $i > $i).
% 29.32/29.11  tff(decl_63226, type, fn_prokaryotic_cellular_respiration_51: $i > $i).
% 29.32/29.11  tff(decl_63227, type, fn_prokaryotic_cellular_respiration_52: $i > $i).
% 29.32/29.11  tff(decl_63228, type, fn_prokaryotic_cellular_respiration_53: $i > $i).
% 29.32/29.11  tff(decl_63229, type, fn_prokaryotic_cellular_respiration_54: $i > $i).
% 29.32/29.11  tff(decl_63230, type, fn_prokaryotic_cellular_respiration_55: $i > $i).
% 29.32/29.11  tff(decl_63231, type, fn_prokaryotic_cellular_respiration_56: $i > $i).
% 29.32/29.11  tff(decl_63232, type, fn_prokaryotic_cellular_respiration_57: $i > $i).
% 29.32/29.11  tff(decl_63233, type, fn_prokaryotic_cellular_respiration_58: $i > $i).
% 29.32/29.11  tff(decl_63234, type, fn_prokaryotic_cellular_respiration_61: $i > $i).
% 29.32/29.11  tff(decl_63235, type, fn_prokaryotic_cellular_respiration_62: $i > $i).
% 29.32/29.11  tff(decl_63236, type, fn_prokaryotic_cellular_respiration_63: $i > $i).
% 29.32/29.11  tff(decl_63237, type, fn_prokaryotic_cellular_respiration_64: $i > $i).
% 29.32/29.11  tff(decl_63238, type, fn_prokaryotic_cellular_respiration_65: $i > $i).
% 29.32/29.11  tff(decl_63239, type, fn_prokaryotic_cellular_respiration_70: $i > $i).
% 29.32/29.11  tff(decl_63240, type, fn_prokaryotic_cellular_respiration_71: $i > $i).
% 29.32/29.11  tff(decl_63241, type, fn_prokaryotic_cellular_respiration_72: $i > $i).
% 29.32/29.11  tff(decl_63242, type, fn_prokaryotic_cellular_respiration_73: $i > $i).
% 29.32/29.11  tff(decl_63243, type, fn_prokaryotic_cellular_respiration_74: $i > $i).
% 29.32/29.11  tff(decl_63244, type, fn_prokaryotic_cellular_respiration_75: $i > $i).
% 29.32/29.11  tff(decl_63245, type, fn_prokaryotic_cellular_respiration_76: $i > $i).
% 29.32/29.11  tff(decl_63246, type, fn_prokaryotic_cellular_respiration_77: $i > $i).
% 29.32/29.11  tff(decl_63247, type, fn_prokaryotic_cellular_respiration_78: $i > $i).
% 29.32/29.11  tff(decl_63248, type, fn_prokaryotic_cellular_respiration_79: $i > $i).
% 29.32/29.11  tff(decl_63249, type, fn_prokaryotic_cellular_respiration_80: $i > $i).
% 29.32/29.11  tff(decl_63250, type, fn_prokaryotic_cellular_respiration_81: $i > $i).
% 29.32/29.11  tff(decl_63251, type, fn_prokaryotic_cellular_respiration_82: $i > $i).
% 29.32/29.11  tff(decl_63252, type, fn_prokaryotic_cellular_respiration_83: $i > $i).
% 29.32/29.11  tff(decl_63253, type, fn_prokaryotic_cellular_respiration_84: $i > $i).
% 29.32/29.11  tff(decl_63254, type, fn_prokaryotic_cellular_respiration_85: $i > $i).
% 29.32/29.11  tff(decl_63255, type, fn_prokaryotic_cellular_respiration_86: $i > $i).
% 29.32/29.11  tff(decl_63256, type, fn_prokaryotic_cellular_respiration_87: $i > $i).
% 29.32/29.11  tff(decl_63257, type, fn_prokaryotic_cellular_respiration_88: $i > $i).
% 29.32/29.11  tff(decl_63258, type, fn_prokaryotic_cellular_respiration_89: $i > $i).
% 29.32/29.11  tff(decl_63259, type, fn_prokaryotic_cellular_respiration_90: $i > $i).
% 29.32/29.11  tff(decl_63260, type, fn_prokaryotic_cellular_respiration_91: $i > $i).
% 29.32/29.11  tff(decl_63261, type, fn_prokaryotic_cellular_respiration_92: $i > $i).
% 29.32/29.11  tff(decl_63262, type, fn_prokaryotic_cellular_respiration_93: $i > $i).
% 29.32/29.11  tff(decl_63263, type, fn_prokaryotic_cellular_respiration_94: $i > $i).
% 29.32/29.11  tff(decl_63264, type, fn_prokaryotic_cellular_respiration_95: $i > $i).
% 29.32/29.11  tff(decl_63265, type, fn_prokaryotic_cellular_respiration_96: $i > $i).
% 29.32/29.11  tff(decl_63266, type, fn_prokaryotic_cellular_respiration_97: $i > $i).
% 29.32/29.11  tff(decl_63267, type, fn_prokaryotic_cellular_respiration_98: $i > $i).
% 29.32/29.11  tff(decl_63268, type, fn_prokaryotic_cellular_respiration_99: $i > $i).
% 29.32/29.11  tff(decl_63269, type, fn_prokaryotic_cellular_respiration_100: $i > $i).
% 29.32/29.11  tff(decl_63270, type, fn_prokaryotic_cellular_respiration_101: $i > $i).
% 29.32/29.11  tff(decl_63271, type, fn_prokaryotic_cellular_respiration_102: $i > $i).
% 29.32/29.11  tff(decl_63272, type, fn_prokaryotic_cellular_respiration_103: $i > $i).
% 29.32/29.11  tff(decl_63273, type, fn_prokaryotic_cellular_respiration_104: $i > $i).
% 29.32/29.11  tff(decl_63274, type, fn_prokaryotic_cellular_respiration_105: $i > $i).
% 29.32/29.11  tff(decl_63275, type, fn_prokaryotic_cellular_respiration_106: $i > $i).
% 29.32/29.11  tff(decl_63276, type, fn_prokaryotic_cellular_respiration_107: $i > $i).
% 29.32/29.11  tff(decl_63277, type, fn_prokaryotic_cellular_respiration_108: $i > $i).
% 29.32/29.11  tff(decl_63278, type, fn_prokaryotic_cellular_respiration_109: $i > $i).
% 29.32/29.11  tff(decl_63279, type, fn_prokaryotic_cellular_respiration_110: $i > $i).
% 29.32/29.11  tff(decl_63280, type, fn_prokaryotic_cellular_respiration_111: $i > $i).
% 29.32/29.11  tff(decl_63281, type, fn_prokaryotic_cellular_respiration_112: $i > $i).
% 29.32/29.11  tff(decl_63282, type, fn_prokaryotic_cellular_respiration_113: $i > $i).
% 29.32/29.11  tff(decl_63283, type, fn_prokaryotic_cellular_respiration_114: $i > $i).
% 29.32/29.11  tff(decl_63284, type, fn_prokaryotic_cellular_respiration_115: $i > $i).
% 29.32/29.11  tff(decl_63285, type, fn_prokaryotic_cellular_respiration_116: $i > $i).
% 29.32/29.11  tff(decl_63286, type, fn_prokaryotic_cellular_respiration_117: $i > $i).
% 29.32/29.11  tff(decl_63287, type, fn_prokaryotic_cellular_respiration_118: $i > $i).
% 29.32/29.11  tff(decl_63288, type, fn_prokaryotic_cellular_respiration_119: $i > $i).
% 29.32/29.11  tff(decl_63289, type, fn_prokaryotic_cellular_respiration_122: $i > $i).
% 29.32/29.11  tff(decl_63290, type, fn_prokaryotic_cellular_respiration_123: $i > $i).
% 29.32/29.11  tff(decl_63291, type, fn_prokaryotic_cellular_respiration_124: $i > $i).
% 29.32/29.11  tff(decl_63292, type, fn_prokaryotic_cellular_respiration_125: $i > $i).
% 29.32/29.11  tff(decl_63293, type, fn_prokaryotic_cellular_respiration_126: $i > $i).
% 29.32/29.11  tff(decl_63294, type, fn_prokaryotic_cellular_respiration_127: $i > $i).
% 29.32/29.11  tff(decl_63295, type, fn_prokaryotic_cellular_respiration_128: $i > $i).
% 29.32/29.11  tff(decl_63296, type, fn_prokaryotic_cellular_respiration_129: $i > $i).
% 29.32/29.11  tff(decl_63297, type, fn_prokaryotic_cellular_respiration_130: $i > $i).
% 29.32/29.11  tff(decl_63298, type, fn_prokaryotic_cellular_respiration_131: $i > $i).
% 29.32/29.11  tff(decl_63299, type, fn_prokaryotic_cellular_respiration_132: $i > $i).
% 29.32/29.11  tff(decl_63300, type, fn_prokaryotic_cellular_respiration_136: $i > $i).
% 29.32/29.11  tff(decl_63301, type, fn_prokaryotic_cellular_respiration_137: $i > $i).
% 29.32/29.11  tff(decl_63302, type, fn_prokaryotic_cellular_respiration_138: $i > $i).
% 29.32/29.11  tff(decl_63303, type, fn_prokaryotic_cellular_respiration_139: $i > $i).
% 29.32/29.11  tff(decl_63304, type, fn_prokaryotic_cellular_respiration_140: $i > $i).
% 29.32/29.11  tff(decl_63305, type, fn_prokaryotic_cellular_respiration_141: $i > $i).
% 29.32/29.11  tff(decl_63306, type, fn_prokaryotic_cellular_respiration_142: $i > $i).
% 29.32/29.11  tff(decl_63307, type, fn_prokaryotic_cellular_respiration_143: $i > $i).
% 29.32/29.11  tff(decl_63308, type, fn_prokaryotic_cellular_respiration_144: $i > $i).
% 29.32/29.11  tff(decl_63309, type, fn_prokaryotic_cellular_respiration_145: $i > $i).
% 29.32/29.11  tff(decl_63310, type, fn_prokaryotic_cellular_respiration_146: $i > $i).
% 29.32/29.11  tff(decl_63311, type, fn_prokaryotic_cellular_respiration_147: $i > $i).
% 29.32/29.11  tff(decl_63312, type, fn_prokaryotic_cellular_respiration_148: $i > $i).
% 29.32/29.11  tff(decl_63313, type, fn_prokaryotic_cellular_respiration_149: $i > $i).
% 29.32/29.11  tff(decl_63314, type, fn_citric_acid_cycle_25: $i > $i).
% 29.32/29.11  tff(decl_63315, type, fn_citric_acid_cycle_26: $i > $i).
% 29.32/29.11  tff(decl_63316, type, fn_prokaryotic_cellular_respiration_60: $i > $i).
% 29.32/29.11  tff(decl_63317, type, fn_prokaryotic_cellular_respiration_59: $i > $i).
% 29.32/29.11  tff(decl_63318, type, fn_prokaryotic_cellular_respiration_28: $i > $i).
% 29.32/29.11  tff(decl_63319, type, fn_prokaryotic_cellular_respiration_27: $i > $i).
% 29.32/29.11  tff(decl_63320, type, fn_prokaryotic_cellular_respiration_26: $i > $i).
% 29.32/29.11  tff(decl_63321, type, fn_prokaryotic_cellular_respiration_29: $i > $i).
% 29.32/29.11  tff(decl_63322, type, fn_prokaryotic_cellular_respiration_150: $i > $i).
% 29.32/29.11  tff(decl_63323, type, fn_prokaryotic_cellular_respiration_67: $i > $i).
% 29.32/29.11  tff(decl_63324, type, fn_prokaryotic_cellular_respiration_151: $i > $i).
% 29.32/29.11  tff(decl_63325, type, fn_prokaryotic_cellular_respiration_66: $i > $i).
% 29.32/29.11  tff(decl_63326, type, fn_prokaryotic_cellular_respiration_68: $i > $i).
% 29.32/29.11  tff(decl_63327, type, fn_prokaryotic_cellular_respiration_69: $i > $i).
% 29.32/29.11  tff(decl_63328, type, fn_prokaryotic_cellular_respiration_120: $i > $i).
% 29.32/29.11  tff(decl_63329, type, fn_prokaryotic_cellular_respiration_133: $i > $i).
% 29.32/29.11  tff(decl_63330, type, fn_prokaryotic_cellular_respiration_121: $i > $i).
% 29.32/29.11  tff(decl_63331, type, fn_prokaryotic_cellular_respiration_135: $i > $i).
% 29.32/29.11  tff(decl_63332, type, fn_prokaryotic_cellular_respiration_134: $i > $i).
% 29.32/29.11  tff(decl_63333, type, 'Prokaryotic-Chromatin': $i).
% 29.32/29.11  tff(decl_63334, type, 'Chromatin is the combination of DNA, histone, and other proteins that make up chromosomes. It is found inside the nuclear envelope of eukaryotic cells. It is divided between heterochromatin (condensed) and euchromatin (extended) forms.The functions of chromatin are to package DNA into a smaller volume to fit in the cell, to strengthen the DNA to allow mitosis and meiosis, and to control gene expression and DNA replication. Changes in chromatin structure are affected by chemical modifications of histone proteins, such as methylation and acetylation, and by other DNA-binding proteins.': $i).
% 29.32/29.11  tff(decl_63335, type, 'prokaryotic chromatin': $i).
% 29.32/29.11  tff(decl_63336, type, 'prokaryotic-chromatin': $i).
% 29.32/29.11  tff(decl_63337, type, fn_prokaryotic_chromatin_5: $i > $i).
% 29.32/29.11  tff(decl_63338, type, fn_prokaryotic_chromatin_6: $i > $i).
% 29.32/29.11  tff(decl_63339, type, fn_prokaryotic_chromatin_7: $i > $i).
% 29.32/29.11  tff(decl_63340, type, fn_prokaryotic_chromatin_8: $i > $i).
% 29.32/29.11  tff(decl_63341, type, fn_prokaryotic_chromatin_9: $i > $i).
% 29.32/29.11  tff(decl_63342, type, fn_prokaryotic_chromatin_10: $i > $i).
% 29.32/29.11  tff(decl_63343, type, circular_dna_0: $i).
% 29.32/29.11  tff(decl_63344, type, 'Prokaryotic-Chromosome': $i).
% 29.32/29.11  tff(decl_63345, type, 'The bacterial chromosome is circular in structure and has a single origin. It is a stretch of DNA having a specific sequence of nucleotides.': $i).
% 29.32/29.11  tff(decl_63346, type, 'prokaryotic chromosome': $i).
% 29.32/29.11  tff(decl_63347, type, 'prokaryotic-chromosome': $i).
% 29.32/29.11  tff(decl_63348, type, fn_prokaryotic_chromosome_2: $i > $i).
% 29.32/29.11  tff(decl_63349, type, fn_prokaryotic_chromosome_3: $i > $i).
% 29.32/29.11  tff(decl_63350, type, fn_prokaryotic_chromosome_5: $i > $i).
% 29.32/29.11  tff(decl_63351, type, prokaryotic_cilium_1: $i > $o).
% 29.32/29.11  tff(decl_63352, type, fn_prokaryotic_cilium_3: $i > $i).
% 29.32/29.11  tff(decl_63353, type, fn_prokaryotic_cilium_1: $i > $i).
% 29.32/29.11  tff(decl_63354, type, fn_prokaryotic_cilium_4: $i > $i).
% 29.32/29.11  tff(decl_63355, type, 'Prokaryotic-Cilium': $i).
% 29.32/29.11  tff(decl_63356, type, 'Cilium present on the prokaryotic cell.': $i).
% 29.32/29.11  tff(decl_63357, type, 'prokaryotic cilia': $i).
% 29.32/29.11  tff(decl_63358, type, 'prokaryotic cilium': $i).
% 29.32/29.11  tff(decl_63359, type, 'prokaryotic-cilium': $i).
% 29.32/29.11  tff(decl_63360, type, 'Prokaryotic-Electron-Transport-Chain': $i).
% 29.32/29.11  tff(decl_63361, type, 'A sequence of electron carrier molecules (membrane proteins) that shuttle electrons during the redox reactions that release energy used to make ATP. The electron transport chain assembly is present in the inner membrane of plasma membrane of prokaryotic cell.': $i).
% 29.32/29.11  tff(decl_63362, type, 'prokaryotic electron transport chain': $i).
% 29.32/29.11  tff(decl_63363, type, 'prokaryotic-electron-transport-chain': $i).
% 29.32/29.11  tff(decl_63364, type, fn_prokaryotic_electron_transport_chain_1: $i > $i).
% 29.32/29.11  tff(decl_63365, type, fn_prokaryotic_electron_transport_chain_2: $i > $i).
% 29.32/29.11  tff(decl_63366, type, prokaryotic_flagellum_1: $i > $o).
% 29.32/29.11  tff(decl_63367, type, 'Prokaryotic-Flagellum': $i).
% 29.32/29.11  tff(decl_63368, type, 'A long appendage that protrudes from the cell body of some  prokaryotic cells, specialized for locomotion.': $i).
% 29.32/29.11  tff(decl_63369, type, 'prokaryotic flagellum': $i).
% 29.32/29.11  tff(decl_63370, type, 'prokaryotic-flagellum': $i).
% 29.32/29.11  tff(decl_63371, type, 'Prokaryotic-Gene': $i).
% 29.32/29.11  tff(decl_63372, type, 'A gene of a prokaryotic organism.': $i).
% 29.32/29.11  tff(decl_63373, type, 'bacterial gene': $i).
% 29.32/29.11  tff(decl_63374, type, 'prokaryotic gene': $i).
% 29.32/29.11  tff(decl_63375, type, 'prokaryotic-gene': $i).
% 29.32/29.11  tff(decl_63376, type, prokaryotic_genome_1: $i > $o).
% 29.32/29.11  tff(decl_63377, type, 'Prokaryotic-Genome': $i).
% 29.32/29.11  tff(decl_63378, type, 'Genome of a prokaryotic cell.': $i).
% 29.32/29.11  tff(decl_63379, type, 'prokaryotic genome': $i).
% 29.32/29.11  tff(decl_63380, type, 'prokaryotic-genome': $i).
% 29.32/29.11  tff(decl_63381, type, fn_prokaryotic_genome_1: $i > $i).
% 29.32/29.11  tff(decl_63382, type, fn_prokaryotic_genome_2: $i > $i).
% 29.32/29.11  tff(decl_63383, type, prokaryotic_chromosome_0: $i).
% 29.32/29.11  tff(decl_63384, type, prokaryotic_light_reaction_1: $i > $o).
% 29.32/29.11  tff(decl_63385, type, 'Prokaryotic-Light-Reaction': $i).
% 29.32/29.11  tff(decl_63386, type, 'The light-dependent reactions of photosynthesis in a prokaryotic organism.': $i).
% 29.32/29.11  tff(decl_63387, type, 'prokaryotic light reaction': $i).
% 29.32/29.11  tff(decl_63388, type, 'prokaryotic-light-reaction': $i).
% 29.32/29.11  tff(decl_63389, type, fn_prokaryotic_light_reaction_1: $i > $i).
% 29.32/29.11  tff(decl_63390, type, fn_prokaryotic_light_reaction_2: $i > $i).
% 29.32/29.11  tff(decl_63391, type, fn_prokaryotic_light_reaction_3: $i > $i).
% 29.32/29.11  tff(decl_63392, type, fn_prokaryotic_light_reaction_4: $i > $i).
% 29.32/29.11  tff(decl_63393, type, fn_prokaryotic_light_reaction_5: $i > $i).
% 29.32/29.11  tff(decl_63394, type, fn_prokaryotic_light_reaction_6: $i > $i).
% 29.32/29.11  tff(decl_63395, type, fn_prokaryotic_light_reaction_7: $i > $i).
% 29.32/29.11  tff(decl_63396, type, fn_prokaryotic_light_reaction_8: $i > $i).
% 29.32/29.11  tff(decl_63397, type, fn_prokaryotic_light_reaction_9: $i > $i).
% 29.32/29.11  tff(decl_63398, type, fn_prokaryotic_light_reaction_10: $i > $i).
% 29.32/29.11  tff(decl_63399, type, fn_prokaryotic_light_reaction_11: $i > $i).
% 29.32/29.11  tff(decl_63400, type, fn_prokaryotic_light_reaction_12: $i > $i).
% 29.32/29.11  tff(decl_63401, type, fn_prokaryotic_light_reaction_13: $i > $i).
% 29.32/29.11  tff(decl_63402, type, fn_prokaryotic_light_reaction_14: $i > $i).
% 29.32/29.11  tff(decl_63403, type, fn_prokaryotic_light_reaction_15: $i > $i).
% 29.32/29.11  tff(decl_63404, type, fn_prokaryotic_light_reaction_16: $i > $i).
% 29.32/29.11  tff(decl_63405, type, fn_prokaryotic_light_reaction_17: $i > $i).
% 29.32/29.11  tff(decl_63406, type, fn_prokaryotic_light_reaction_18: $i > $i).
% 29.32/29.11  tff(decl_63407, type, fn_prokaryotic_light_reaction_19: $i > $i).
% 29.32/29.11  tff(decl_63408, type, fn_prokaryotic_light_reaction_20: $i > $i).
% 29.32/29.11  tff(decl_63409, type, fn_prokaryotic_light_reaction_21: $i > $i).
% 29.32/29.11  tff(decl_63410, type, fn_prokaryotic_light_reaction_22: $i > $i).
% 29.32/29.11  tff(decl_63411, type, fn_prokaryotic_light_reaction_23: $i > $i).
% 29.32/29.11  tff(decl_63412, type, fn_prokaryotic_light_reaction_24: $i > $i).
% 29.32/29.11  tff(decl_63413, type, fn_prokaryotic_light_reaction_25: $i > $i).
% 29.32/29.11  tff(decl_63414, type, fn_prokaryotic_light_reaction_26: $i > $i).
% 29.32/29.11  tff(decl_63415, type, fn_prokaryotic_light_reaction_27: $i > $i).
% 29.32/29.11  tff(decl_63416, type, fn_prokaryotic_light_reaction_28: $i > $i).
% 29.32/29.11  tff(decl_63417, type, fn_prokaryotic_light_reaction_29: $i > $i).
% 29.32/29.11  tff(decl_63418, type, fn_prokaryotic_light_reaction_30: $i > $i).
% 29.32/29.11  tff(decl_63419, type, fn_prokaryotic_light_reaction_31: $i > $i).
% 29.32/29.11  tff(decl_63420, type, fn_prokaryotic_light_reaction_32: $i > $i).
% 29.32/29.11  tff(decl_63421, type, fn_prokaryotic_light_reaction_33: $i > $i).
% 29.32/29.11  tff(decl_63422, type, prokaryotic_light_reaction_with_cyclic_electron_flow_1: $i > $o).
% 29.32/29.11  tff(decl_63423, type, 'Prokaryotic-Light-Reaction-With-Cyclic-Electron-Flow': $i).
% 29.32/29.11  tff(decl_63424, type, 'The linear electron flow that occurs during the light reaction in prokaryotic organisms.': $i).
% 29.32/29.11  tff(decl_63425, type, 'prokaryotic light reaction with cyclic electron flow': $i).
% 29.32/29.11  tff(decl_63426, type, 'prokaryotic-light-reaction-with-cyclic-electron-flow': $i).
% 29.32/29.11  tff(decl_63427, type, fn_prokaryotic_light_reaction_with_cyclic_electron_flow_1: $i > $i).
% 29.32/29.11  tff(decl_63428, type, prokaryotic_light_reaction_with_linear_electron_flow_1: $i > $o).
% 29.32/29.11  tff(decl_63429, type, 'Prokaryotic-Light-Reaction-With-Linear-Electron-Flow': $i).
% 29.32/29.11  tff(decl_63430, type, 'The light-dependent reactions of photosynthesis in a prokaryotic organism in which the electrons flow in a linear direction.': $i).
% 29.32/29.11  tff(decl_63431, type, 'prokaryotic light reaction with linear electron flow': $i).
% 29.32/29.11  tff(decl_63432, type, 'prokaryotic-light-reaction-with-linear-electron-flow': $i).
% 29.32/29.11  tff(decl_63433, type, fn_prokaryotic_light_reaction_with_linear_electron_flow_1: $i > $i).
% 29.32/29.11  tff(decl_63434, type, 'Prokaryotic-mRNA': $i).
% 29.32/29.11  tff(decl_63435, type, 'An RNA transcript, often of an operon, a cluster of genes, in the cytoplasm of a prokaryote, such as bacteria.  Prokaryotic mRNA is translated directly into protein without undergoing any post-transcriptional processing as in the eukaryotic cell.': $i).
% 29.32/29.11  tff(decl_63436, type, 'prokaryotic messenger rna': $i).
% 29.32/29.11  tff(decl_63437, type, 'prokaryotic mrna': $i).
% 29.32/29.11  tff(decl_63438, type, 'prokaryotic-mrna': $i).
% 29.32/29.11  tff(decl_63439, type, fn_prokaryotic_mrna_1: $i > $i).
% 29.32/29.11  tff(decl_63440, type, fn_prokaryotic_mrna_2: $i > $i).
% 29.32/29.11  tff(decl_63441, type, fn_prokaryotic_mrna_3: $i > $i).
% 29.32/29.11  tff(decl_63442, type, fn_prokaryotic_mrna_4: $i > $i).
% 29.32/29.11  tff(decl_63443, type, fn_prokaryotic_mrna_5: $i > $i).
% 29.32/29.11  tff(decl_63444, type, fn_prokaryotic_mrna_6: $i > $i).
% 29.32/29.11  tff(decl_63445, type, fn_prokaryotic_mrna_7: $i > $i).
% 29.32/29.11  tff(decl_63446, type, fn_prokaryotic_mrna_8: $i > $i).
% 29.32/29.11  tff(decl_63447, type, fn_prokaryotic_mrna_9: $i > $i).
% 29.32/29.11  tff(decl_63448, type, fn_prokaryotic_mrna_10: $i > $i).
% 29.32/29.11  tff(decl_63449, type, fn_prokaryotic_mrna_11: $i > $i).
% 29.32/29.11  tff(decl_63450, type, fn_prokaryotic_mrna_18: $i > $i).
% 29.32/29.11  tff(decl_63451, type, fn_prokaryotic_mrna_19: $i > $i).
% 29.32/29.11  tff(decl_63452, type, fn_prokaryotic_mrna_20: $i > $i).
% 29.32/29.11  tff(decl_63453, type, fn_prokaryotic_mrna_21: $i > $i).
% 29.32/29.11  tff(decl_63454, type, fn_prokaryotic_mrna_22: $i > $i).
% 29.32/29.11  tff(decl_63455, type, fn_prokaryotic_mrna_23: $i > $i).
% 29.32/29.11  tff(decl_63456, type, fn_prokaryotic_mrna_24: $i > $i).
% 29.32/29.11  tff(decl_63457, type, fn_prokaryotic_mrna_25: $i > $i).
% 29.32/29.11  tff(decl_63458, type, fn_prokaryotic_mrna_26: $i > $i).
% 29.32/29.11  tff(decl_63459, type, fn_prokaryotic_mrna_28: $i > $i).
% 29.32/29.11  tff(decl_63460, type, fn_prokaryotic_mrna_29: $i > $i).
% 29.32/29.11  tff(decl_63461, type, fn_prokaryotic_mrna_30: $i > $i).
% 29.32/29.11  tff(decl_63462, type, fn_prokaryotic_mrna_31: $i > $i).
% 29.32/29.11  tff(decl_63463, type, fn_prokaryotic_mrna_32: $i > $i).
% 29.32/29.11  tff(decl_63464, type, fn_prokaryotic_mrna_34: $i > $i).
% 29.32/29.11  tff(decl_63465, type, fn_prokaryotic_mrna_35: $i > $i).
% 29.32/29.11  tff(decl_63466, type, fn_prokaryotic_mrna_36: $i > $i).
% 29.32/29.11  tff(decl_63467, type, fn_prokaryotic_mrna_37: $i > $i).
% 29.32/29.11  tff(decl_63468, type, fn_prokaryotic_mrna_38: $i > $i).
% 29.32/29.11  tff(decl_63469, type, fn_prokaryotic_mrna_39: $i > $i).
% 29.32/29.11  tff(decl_63470, type, fn_prokaryotic_mrna_40: $i > $i).
% 29.32/29.11  tff(decl_63471, type, fn_prokaryotic_mrna_41: $i > $i).
% 29.32/29.11  tff(decl_63472, type, uga_1: $i > $o).
% 29.32/29.11  tff(decl_63473, type, fn_prokaryotic_mrna_42: $i > $i).
% 29.32/29.11  tff(decl_63474, type, fn_prokaryotic_mrna_43: $i > $i).
% 29.32/29.11  tff(decl_63475, type, fn_prokaryotic_mrna_44: $i > $i).
% 29.32/29.11  tff(decl_63476, type, fn_prokaryotic_mrna_45: $i > $i).
% 29.32/29.11  tff(decl_63477, type, fn_prokaryotic_mrna_46: $i > $i).
% 29.32/29.11  tff(decl_63478, type, fn_prokaryotic_mrna_47: $i > $i).
% 29.32/29.11  tff(decl_63479, type, fn_prokaryotic_mrna_48: $i > $i).
% 29.32/29.11  tff(decl_63480, type, fn_prokaryotic_mrna_49: $i > $i).
% 29.32/29.11  tff(decl_63481, type, fn_prokaryotic_mrna_50: $i > $i).
% 29.32/29.11  tff(decl_63482, type, fn_prokaryotic_mrna_51: $i > $i).
% 29.32/29.11  tff(decl_63483, type, fn_prokaryotic_mrna_52: $i > $i).
% 29.32/29.11  tff(decl_63484, type, fn_prokaryotic_mrna_53: $i > $i).
% 29.32/29.11  tff(decl_63485, type, fn_prokaryotic_mrna_54: $i > $i).
% 29.32/29.11  tff(decl_63486, type, fn_prokaryotic_mrna_55: $i > $i).
% 29.32/29.11  tff(decl_63487, type, fn_prokaryotic_mrna_56: $i > $i).
% 29.32/29.11  tff(decl_63488, type, fn_prokaryotic_mrna_57: $i > $i).
% 29.32/29.11  tff(decl_63489, type, fn_prokaryotic_mrna_27: $i > $i).
% 29.32/29.11  tff(decl_63490, type, fn_prokaryotic_mrna_17: $i > $i).
% 29.32/29.11  tff(decl_63491, type, fn_prokaryotic_mrna_16: $i > $i).
% 29.32/29.11  tff(decl_63492, type, fn_prokaryotic_mrna_14: $i > $i).
% 29.32/29.11  tff(decl_63493, type, fn_prokaryotic_mrna_15: $i > $i).
% 29.32/29.11  tff(decl_63494, type, fn_prokaryotic_mrna_13: $i > $i).
% 29.32/29.11  tff(decl_63495, type, fn_rna_18: $i > $i).
% 29.32/29.11  tff(decl_63496, type, fn_prokaryotic_mrna_12: $i > $i).
% 29.32/29.11  tff(decl_63497, type, fn_rna_19: $i > $i).
% 29.32/29.11  tff(decl_63498, type, fn_prokaryotic_mrna_33: $i > $i).
% 29.32/29.11  tff(decl_63499, type, fn_rna_11: $i > $i).
% 29.32/29.11  tff(decl_63500, type, fn_rna_17: $i > $i).
% 29.32/29.11  tff(decl_63501, type, fn_rna_12: $i > $i).
% 29.32/29.11  tff(decl_63502, type, fn_rna_13: $i > $i).
% 29.32/29.11  tff(decl_63503, type, fn_rna_14: $i > $i).
% 29.32/29.11  tff(decl_63504, type, 'Prokaryotic-Oxidative-Phosphorylation': $i).
% 29.32/29.11  tff(decl_63505, type, 'Oxidative phosphorylation in prokaryote is a metabolic pathway that uses energy released by the oxidation of nutrients to produce adenosine triphosphate (ATP) in prokaryote.': $i).
% 29.32/29.11  tff(decl_63506, type, 'prokaryotic oxidative phosphorylation': $i).
% 29.32/29.11  tff(decl_63507, type, 'prokaryotic-oxidative-phosphorylation': $i).
% 29.32/29.11  tff(decl_63508, type, fn_prokaryotic_oxidative_phosphorylation_1: $i > $i).
% 29.32/29.11  tff(decl_63509, type, fn_prokaryotic_oxidative_phosphorylation_2: $i > $i).
% 29.32/29.11  tff(decl_63510, type, fn_prokaryotic_oxidative_phosphorylation_3: $i > $i).
% 29.32/29.11  tff(decl_63511, type, fn_prokaryotic_oxidative_phosphorylation_4: $i > $i).
% 29.32/29.11  tff(decl_63512, type, fn_prokaryotic_oxidative_phosphorylation_5: $i > $i).
% 29.32/29.11  tff(decl_63513, type, fn_prokaryotic_oxidative_phosphorylation_6: $i > $i).
% 29.32/29.11  tff(decl_63514, type, fn_prokaryotic_oxidative_phosphorylation_7: $i > $i).
% 29.32/29.11  tff(decl_63515, type, fn_prokaryotic_oxidative_phosphorylation_8: $i > $i).
% 29.32/29.11  tff(decl_63516, type, fn_prokaryotic_oxidative_phosphorylation_11: $i > $i).
% 29.32/29.11  tff(decl_63517, type, fn_prokaryotic_oxidative_phosphorylation_12: $i > $i).
% 29.32/29.11  tff(decl_63518, type, fn_prokaryotic_oxidative_phosphorylation_13: $i > $i).
% 29.32/29.11  tff(decl_63519, type, fn_prokaryotic_oxidative_phosphorylation_14: $i > $i).
% 29.32/29.11  tff(decl_63520, type, fn_prokaryotic_oxidative_phosphorylation_15: $i > $i).
% 29.32/29.11  tff(decl_63521, type, fn_prokaryotic_oxidative_phosphorylation_16: $i > $i).
% 29.32/29.11  tff(decl_63522, type, fn_prokaryotic_oxidative_phosphorylation_17: $i > $i).
% 29.32/29.11  tff(decl_63523, type, fn_prokaryotic_oxidative_phosphorylation_18: $i > $i).
% 29.32/29.11  tff(decl_63524, type, fn_prokaryotic_oxidative_phosphorylation_19: $i > $i).
% 29.32/29.11  tff(decl_63525, type, fn_prokaryotic_oxidative_phosphorylation_20: $i > $i).
% 29.32/29.11  tff(decl_63526, type, fn_prokaryotic_oxidative_phosphorylation_21: $i > $i).
% 29.32/29.11  tff(decl_63527, type, fn_prokaryotic_oxidative_phosphorylation_22: $i > $i).
% 29.32/29.11  tff(decl_63528, type, fn_prokaryotic_oxidative_phosphorylation_23: $i > $i).
% 29.32/29.11  tff(decl_63529, type, fn_prokaryotic_oxidative_phosphorylation_24: $i > $i).
% 29.32/29.11  tff(decl_63530, type, fn_prokaryotic_oxidative_phosphorylation_25: $i > $i).
% 29.32/29.11  tff(decl_63531, type, fn_prokaryotic_oxidative_phosphorylation_26: $i > $i).
% 29.32/29.11  tff(decl_63532, type, fn_prokaryotic_oxidative_phosphorylation_27: $i > $i).
% 29.32/29.11  tff(decl_63533, type, fn_prokaryotic_oxidative_phosphorylation_28: $i > $i).
% 29.32/29.11  tff(decl_63534, type, fn_prokaryotic_oxidative_phosphorylation_29: $i > $i).
% 29.32/29.11  tff(decl_63535, type, fn_prokaryotic_oxidative_phosphorylation_30: $i > $i).
% 29.32/29.11  tff(decl_63536, type, fn_prokaryotic_oxidative_phosphorylation_31: $i > $i).
% 29.32/29.11  tff(decl_63537, type, fn_prokaryotic_oxidative_phosphorylation_32: $i > $i).
% 29.32/29.11  tff(decl_63538, type, fn_prokaryotic_oxidative_phosphorylation_33: $i > $i).
% 29.32/29.11  tff(decl_63539, type, fn_prokaryotic_oxidative_phosphorylation_34: $i > $i).
% 29.32/29.11  tff(decl_63540, type, fn_prokaryotic_oxidative_phosphorylation_35: $i > $i).
% 29.32/29.11  tff(decl_63541, type, fn_prokaryotic_oxidative_phosphorylation_36: $i > $i).
% 29.32/29.11  tff(decl_63542, type, fn_prokaryotic_oxidative_phosphorylation_37: $i > $i).
% 29.32/29.11  tff(decl_63543, type, fn_prokaryotic_oxidative_phosphorylation_38: $i > $i).
% 29.32/29.11  tff(decl_63544, type, fn_prokaryotic_oxidative_phosphorylation_39: $i > $i).
% 29.32/29.11  tff(decl_63545, type, fn_prokaryotic_oxidative_phosphorylation_40: $i > $i).
% 29.32/29.11  tff(decl_63546, type, fn_prokaryotic_oxidative_phosphorylation_41: $i > $i).
% 29.32/29.11  tff(decl_63547, type, fn_prokaryotic_oxidative_phosphorylation_42: $i > $i).
% 29.32/29.11  tff(decl_63548, type, fn_prokaryotic_oxidative_phosphorylation_43: $i > $i).
% 29.32/29.11  tff(decl_63549, type, fn_prokaryotic_oxidative_phosphorylation_44: $i > $i).
% 29.32/29.11  tff(decl_63550, type, fn_prokaryotic_oxidative_phosphorylation_45: $i > $i).
% 29.32/29.11  tff(decl_63551, type, fn_prokaryotic_oxidative_phosphorylation_46: $i > $i).
% 29.32/29.11  tff(decl_63552, type, fn_prokaryotic_oxidative_phosphorylation_47: $i > $i).
% 29.32/29.11  tff(decl_63553, type, fn_prokaryotic_oxidative_phosphorylation_48: $i > $i).
% 29.32/29.11  tff(decl_63554, type, fn_prokaryotic_oxidative_phosphorylation_49: $i > $i).
% 29.32/29.11  tff(decl_63555, type, fn_prokaryotic_oxidative_phosphorylation_50: $i > $i).
% 29.32/29.11  tff(decl_63556, type, fn_prokaryotic_oxidative_phosphorylation_51: $i > $i).
% 29.32/29.11  tff(decl_63557, type, fn_prokaryotic_oxidative_phosphorylation_52: $i > $i).
% 29.32/29.11  tff(decl_63558, type, fn_prokaryotic_oxidative_phosphorylation_53: $i > $i).
% 29.32/29.11  tff(decl_63559, type, fn_prokaryotic_oxidative_phosphorylation_54: $i > $i).
% 29.32/29.11  tff(decl_63560, type, fn_prokaryotic_oxidative_phosphorylation_55: $i > $i).
% 29.32/29.11  tff(decl_63561, type, fn_prokaryotic_oxidative_phosphorylation_56: $i > $i).
% 29.32/29.11  tff(decl_63562, type, fn_prokaryotic_oxidative_phosphorylation_57: $i > $i).
% 29.32/29.11  tff(decl_63563, type, fn_prokaryotic_oxidative_phosphorylation_58: $i > $i).
% 29.32/29.11  tff(decl_63564, type, fn_prokaryotic_oxidative_phosphorylation_59: $i > $i).
% 29.32/29.11  tff(decl_63565, type, fn_prokaryotic_oxidative_phosphorylation_60: $i > $i).
% 29.32/29.11  tff(decl_63566, type, fn_prokaryotic_oxidative_phosphorylation_61: $i > $i).
% 29.32/29.11  tff(decl_63567, type, fn_prokaryotic_oxidative_phosphorylation_62: $i > $i).
% 29.32/29.11  tff(decl_63568, type, fn_prokaryotic_oxidative_phosphorylation_63: $i > $i).
% 29.32/29.11  tff(decl_63569, type, fn_prokaryotic_oxidative_phosphorylation_64: $i > $i).
% 29.32/29.11  tff(decl_63570, type, fn_prokaryotic_oxidative_phosphorylation_65: $i > $i).
% 29.32/29.11  tff(decl_63571, type, fn_prokaryotic_oxidative_phosphorylation_66: $i > $i).
% 29.32/29.11  tff(decl_63572, type, fn_prokaryotic_oxidative_phosphorylation_67: $i > $i).
% 29.32/29.11  tff(decl_63573, type, fn_prokaryotic_oxidative_phosphorylation_68: $i > $i).
% 29.32/29.11  tff(decl_63574, type, fn_prokaryotic_oxidative_phosphorylation_69: $i > $i).
% 29.32/29.11  tff(decl_63575, type, fn_prokaryotic_oxidative_phosphorylation_10: $i > $i).
% 29.32/29.11  tff(decl_63576, type, fn_prokaryotic_oxidative_phosphorylation_9: $i > $i).
% 29.32/29.11  tff(decl_63577, type, prokaryotic_pyruvate_oxidation_1: $i > $o).
% 29.32/29.11  tff(decl_63578, type, 'Prokaryotic-Pyruvate-Oxidation': $i).
% 29.32/29.11  tff(decl_63579, type, 'The oxidative conversion of pyruvate into acetyl-CoA which occurs inside cytosol of a prokaryotic cell is referred to as the prokaryotic pyruvate oxidation. It is catalyzed by the pyruvate dehydrogenase complex.': $i).
% 29.32/29.11  tff(decl_63580, type, 'prokaryotic pyruvate oxidation': $i).
% 29.32/29.11  tff(decl_63581, type, 'prokaryotic-pyruvate-oxidation': $i).
% 29.32/29.11  tff(decl_63582, type, fn_prokaryotic_pyruvate_oxidation_1: $i > $i).
% 29.32/29.11  tff(decl_63583, type, fn_prokaryotic_pyruvate_oxidation_2: $i > $i).
% 29.32/29.11  tff(decl_63584, type, 'Prokaryotic-Ribosome': $i).
% 29.32/29.11  tff(decl_63585, type, 'A cell structure in prokaryotes that receives the mRNA and translates the genetic information into proteins during protein synthesis.  They are composed of three types of rRNA, the 16S rRNA, 23S rRNA, and 5S rRNA which combine with proteins to form a complete, functional ribosome.': $i).
% 29.32/29.11  tff(decl_63586, type, 'prokaryotic ribosome': $i).
% 29.32/29.11  tff(decl_63587, type, 'prokaryotic-ribosome': $i).
% 29.32/29.11  tff(decl_63588, type, fn_prokaryotic_ribosome_2: $i > $i).
% 29.32/29.11  tff(decl_63589, type, eukaryotic_ribosome_0: $i).
% 29.32/29.11  tff(decl_63590, type, fn_prokaryotic_ribosome_3: $i > $i).
% 29.32/29.11  tff(decl_63591, type, synthesis_of_mrna_in_prokaryote_1: $i > $o).
% 29.32/29.11  tff(decl_63592, type, prokaryotic_transcription_1: $i > $o).
% 29.32/29.11  tff(decl_63593, type, fn_prokaryotic_transcription_3: $i > $i).
% 29.32/29.11  tff(decl_63594, type, 'Prokaryotic-Transcription': $i).
% 29.32/29.11  tff(decl_63595, type, 'The process where mRNA transcripts of the prokaryotic DNA are produced, to be translated into proteins. Prokaryotic transcription simultaneously with translation in the cytoplasm, unlike in eukaryotes where the process is separated due to the presence of the nuclear envelope.': $i).
% 29.32/29.11  tff(decl_63596, type, 'transcription in prokaryotes': $i).
% 29.32/29.11  tff(decl_63597, type, 'prokaryotic transcription': $i).
% 29.32/29.11  tff(decl_63598, type, 'prokaryotic-transcription': $i).
% 29.32/29.11  tff(decl_63599, type, fn_prokaryotic_transcription_1: $i > $i).
% 29.32/29.11  tff(decl_63600, type, fn_prokaryotic_transcription_4: $i > $i).
% 29.32/29.11  tff(decl_63601, type, transcription_termination_in_prokaryotes_1: $i > $o).
% 29.32/29.11  tff(decl_63602, type, fn_synthesis_of_mrna_4: $i > $i).
% 29.32/29.11  tff(decl_63603, type, fn_synthesis_of_mrna_in_prokaryote_2: $i > $i).
% 29.32/29.11  tff(decl_63604, type, prokaryotic_transcription_initiation_1: $i > $o).
% 29.32/29.11  tff(decl_63605, type, 'Prokaryotic-Transcription-Initiation': $i).
% 29.32/29.11  tff(decl_63606, type, 'Prokaryotic transcription initiation is less complex than eukaryotic transcription initiation. The RNA polymerase binds to several specificity factors to form a holoenzyme.The specificity factor eventually dissociates from the holoenzyme and elongation proceeds.': $i).
% 29.32/29.11  tff(decl_63607, type, 'prokaryotic transcription initiation': $i).
% 29.32/29.11  tff(decl_63608, type, 'prokaryotic-transcription-initiation': $i).
% 29.32/29.11  tff(decl_63609, type, fn_prokaryotic_transcription_initiation_1: $i > $i).
% 29.32/29.11  tff(decl_63610, type, fn_prokaryotic_transcription_initiation_2: $i > $i).
% 29.32/29.11  tff(decl_63611, type, fn_prokaryotic_transcription_initiation_3: $i > $i).
% 29.32/29.11  tff(decl_63612, type, fn_prokaryotic_transcription_initiation_4: $i > $i).
% 29.32/29.11  tff(decl_63613, type, 'Prolactin': $i).
% 29.32/29.11  tff(decl_63614, type, 'A peptide hormone produced by and secreted from the anterior pituitary gland. It has different effects in different vertebrate groups. In mammals, it promotes lactation .': $i).
% 29.32/29.11  tff(decl_63615, type, prolactin: $i).
% 29.32/29.11  tff(decl_63616, type, prl: $i).
% 29.32/29.11  tff(decl_63617, type, 'Proliferative-Phase': $i).
% 29.32/29.11  tff(decl_63618, type, 'The first half of the menstrual cycle, when the endometrial layer thickens in preparation to receive a fertilized egg.': $i).
% 29.32/29.11  tff(decl_63619, type, proline_1: $i > $o).
% 29.32/29.11  tff(decl_63620, type, 'Proline': $i).
% 29.32/29.11  tff(decl_63621, type, proline: $i).
% 29.32/29.11  tff(decl_63622, type, fn_proline_1: $i > $i).
% 29.32/29.11  tff(decl_63623, type, fn_proline_2: $i > $i).
% 29.32/29.11  tff(decl_63624, type, fn_proline_3: $i > $i).
% 29.32/29.11  tff(decl_63625, type, fn_proline_4: $i > $i).
% 29.32/29.11  tff(decl_63626, type, fn_proline_5: $i > $i).
% 29.32/29.11  tff(decl_63627, type, 'Prometaphase': $i).
% 29.32/29.11  tff(decl_63628, type, 'The phase of the cell cycle after prophase and before metaphase. In prometaphase the nuclear envelope begins to fragment, kinetochores begin to appear on the chromosomes, and spindle fibers begin attaching to the kinetochores.': $i).
% 29.32/29.11  tff(decl_63629, type, 'undergo prometaphase': $i).
% 29.32/29.11  tff(decl_63630, type, prometaphase: $i).
% 29.32/29.11  tff(decl_63631, type, fn_prometaphase_2: $i > $i).
% 29.32/29.11  tff(decl_63632, type, fn_prometaphase_4: $i > $i).
% 29.32/29.11  tff(decl_63633, type, fn_prometaphase_7: $i > $i).
% 29.32/29.11  tff(decl_63634, type, fn_prometaphase_8: $i > $i).
% 29.32/29.11  tff(decl_63635, type, fn_prometaphase_9: $i > $i).
% 29.32/29.11  tff(decl_63636, type, fn_prometaphase_10: $i > $i).
% 29.32/29.11  tff(decl_63637, type, fn_prometaphase_11: $i > $i).
% 29.32/29.11  tff(decl_63638, type, fn_prometaphase_12: $i > $i).
% 29.32/29.11  tff(decl_63639, type, fn_prometaphase_13: $i > $i).
% 29.32/29.11  tff(decl_63640, type, fn_prometaphase_14: $i > $i).
% 29.32/29.11  tff(decl_63641, type, fn_prometaphase_15: $i > $i).
% 29.32/29.11  tff(decl_63642, type, fn_prometaphase_16: $i > $i).
% 29.32/29.11  tff(decl_63643, type, fn_prometaphase_18: $i > $i).
% 29.32/29.11  tff(decl_63644, type, fn_prometaphase_19: $i > $i).
% 29.32/29.11  tff(decl_63645, type, fn_prometaphase_20: $i > $i).
% 29.32/29.11  tff(decl_63646, type, fn_prometaphase_22: $i > $i).
% 29.32/29.11  tff(decl_63647, type, fn_prometaphase_23: $i > $i).
% 29.32/29.11  tff(decl_63648, type, fn_prometaphase_24: $i > $i).
% 29.32/29.11  tff(decl_63649, type, fn_prometaphase_25: $i > $i).
% 29.32/29.11  tff(decl_63650, type, fn_prometaphase_26: $i > $i).
% 29.32/29.11  tff(decl_63651, type, fn_prometaphase_27: $i > $i).
% 29.32/29.11  tff(decl_63652, type, fn_prometaphase_28: $i > $i).
% 29.32/29.11  tff(decl_63653, type, fn_prometaphase_29: $i > $i).
% 29.32/29.11  tff(decl_63654, type, fn_prometaphase_31: $i > $i).
% 29.32/29.11  tff(decl_63655, type, fn_prometaphase_32: $i > $i).
% 29.32/29.11  tff(decl_63656, type, fn_prometaphase_40: $i > $i).
% 29.32/29.11  tff(decl_63657, type, fn_prometaphase_47: $i > $i).
% 29.32/29.11  tff(decl_63658, type, fn_prometaphase_48: $i > $i).
% 29.32/29.11  tff(decl_63659, type, fn_prometaphase_49: $i > $i).
% 29.32/29.11  tff(decl_63660, type, fn_prometaphase_50: $i > $i).
% 29.32/29.11  tff(decl_63661, type, fn_prometaphase_51: $i > $i).
% 29.32/29.11  tff(decl_63662, type, fn_prometaphase_52: $i > $i).
% 29.32/29.11  tff(decl_63663, type, fn_prometaphase_30: $i > $i).
% 29.32/29.11  tff(decl_63664, type, promethium_1: $i > $o).
% 29.32/29.11  tff(decl_63665, type, 'Promethium': $i).
% 29.32/29.11  tff(decl_63666, type, 'Promethium is a metal atom with atomic number 61. It is represented by the symbol Pm.': $i).
% 29.32/29.11  tff(decl_63667, type, promethium: $i).
% 29.32/29.11  tff(decl_63668, type, pm: $i).
% 29.32/29.11  tff(decl_63669, type, fn_promethium_4: $i > $i).
% 29.32/29.11  tff(decl_63670, type, fn_promethium_5: $i > $i).
% 29.32/29.11  tff(decl_63671, type, fn_promethium_6: $i > $i).
% 29.32/29.11  tff(decl_63672, type, fn_promethium_7: $i > $i).
% 29.32/29.11  tff(decl_63673, type, fn_promethium_11: $i > $i).
% 29.32/29.11  tff(decl_63674, type, fn_promethium_12: $i > $i).
% 29.32/29.11  tff(decl_63675, type, fn_promethium_13: $i > $i).
% 29.32/29.11  tff(decl_63676, type, fn_promethium_14: $i > $i).
% 29.32/29.11  tff(decl_63677, type, "61": $i).
% 29.32/29.11  tff(decl_63678, type, "145": $i).
% 29.32/29.11  tff(decl_63679, type, fn_promethium_9: $i > $i).
% 29.32/29.11  tff(decl_63680, type, fn_promethium_10: $i > $i).
% 29.32/29.11  tff(decl_63681, type, fn_promethium_8: $i > $i).
% 29.32/29.11  tff(decl_63682, type, 'Promiscuous-Mating': $i).
% 29.32/29.11  tff(decl_63683, type, 'A type of mating system in which individuals mate without forming strong pair-bonds or lasting relationships.': $i).
% 29.32/29.11  tff(decl_63684, type, 'promiscuous mating': $i).
% 29.32/29.11  tff(decl_63685, type, 'promiscuous-mating': $i).
% 29.32/29.11  tff(decl_63686, type, 'Promoter': $i).
% 29.32/29.11  tff(decl_63687, type, 'A sequence of nucleotides in DNA to which RNA polymerase binds to begin transcription.': $i).
% 29.32/29.11  tff(decl_63688, type, promoter: $i).
% 29.32/29.11  tff(decl_63689, type, fn_promoter_1: $i > $i).
% 29.32/29.11  tff(decl_63690, type, fn_promoter_2: $i > $i).
% 29.32/29.11  tff(decl_63691, type, fn_tata_box_5: $i > $i).
% 29.32/29.11  tff(decl_63692, type, 'Proofreading-Of-DNA-Replication': $i).
% 29.32/29.11  tff(decl_63693, type, 'The process of checking and repairing errors that occur during DNA replication, carried out by enzymes, including DNA polymerase.': $i).
% 29.32/29.11  tff(decl_63694, type, 'proofreading of dna replication': $i).
% 29.32/29.11  tff(decl_63695, type, 'proofreading-of-dna-replication': $i).
% 29.32/29.11  tff(decl_63696, type, 'Propagation': $i).
% 29.32/29.11  tff(decl_63697, type, 'Production of new individuals, or the continuation of a lineage by sexual or asexual means.': $i).
% 29.32/29.11  tff(decl_63698, type, propagate: $i).
% 29.32/29.11  tff(decl_63699, type, propagation: $i).
% 29.32/29.11  tff(decl_63700, type, 'Propel': $i).
% 29.32/29.11  tff(decl_63701, type, propel: $i).
% 29.32/29.11  tff(decl_63702, type, impel: $i).
% 29.32/29.11  tff(decl_63703, type, fn_propel_1: $i > $i).
% 29.32/29.11  tff(decl_63704, type, fn_propel_2: $i > $i).
% 29.32/29.11  tff(decl_63705, type, target_1: $i > $o).
% 29.32/29.11  tff(decl_63706, type, fn_target_1: $i > $i).
% 29.32/29.11  tff(decl_63707, type, 'Property': $i).
% 29.32/29.11  tff(decl_63708, type, property: $i).
% 29.32/29.11  tff(decl_63709, type, property_class_order_1: $i > $o).
% 29.32/29.11  tff(decl_63710, type, 'Property-Class-Order': $i).
% 29.32/29.11  tff(decl_63711, type, 'property class order': $i).
% 29.32/29.11  tff(decl_63712, type, 'property-class-order': $i).
% 29.32/29.11  tff(decl_63713, type, 'Property-Group': $i).
% 29.32/29.11  tff(decl_63714, type, 'group of property': $i).
% 29.32/29.11  tff(decl_63715, type, 'property group': $i).
% 29.32/29.11  tff(decl_63716, type, 'property-group': $i).
% 29.32/29.11  tff(decl_63717, type, 'Property-Node': $i).
% 29.32/29.11  tff(decl_63718, type, 'node of property': $i).
% 29.32/29.11  tff(decl_63719, type, 'property node': $i).
% 29.32/29.11  tff(decl_63720, type, 'property-node': $i).
% 29.32/29.11  tff(decl_63721, type, property_relation_1: $i > $o).
% 29.32/29.11  tff(decl_63722, type, 'Property-Relation': $i).
% 29.32/29.11  tff(decl_63723, type, 'relation of property': $i).
% 29.32/29.11  tff(decl_63724, type, 'property relation': $i).
% 29.32/29.11  tff(decl_63725, type, 'property-relation': $i).
% 29.32/29.11  tff(decl_63726, type, 'Property-Value': $i).
% 29.32/29.11  tff(decl_63727, type, 'to value': $i).
% 29.32/29.11  tff(decl_63728, type, 'to-value': $i).
% 29.32/29.11  tff(decl_63729, type, 'same type': $i).
% 29.32/29.11  tff(decl_63730, type, 'influence of positive': $i).
% 29.32/29.11  tff(decl_63731, type, 'positive influence': $i).
% 29.32/29.11  tff(decl_63732, type, 'positive-influence': $i).
% 29.32/29.11  tff(decl_63733, type, 'influence of negative': $i).
% 29.32/29.11  tff(decl_63734, type, 'negative influence': $i).
% 29.32/29.11  tff(decl_63735, type, 'negative-influence': $i).
% 29.32/29.11  tff(decl_63736, type, 'inversely proportional': $i).
% 29.32/29.11  tff(decl_63737, type, 'inversely-proportional': $i).
% 29.32/29.11  tff(decl_63738, type, 'from value': $i).
% 29.32/29.11  tff(decl_63739, type, 'from-value': $i).
% 29.32/29.11  tff(decl_63740, type, 'directly proportional': $i).
% 29.32/29.11  tff(decl_63741, type, 'directly-proportional': $i).
% 29.32/29.11  tff(decl_63742, type, correspondence: $i).
% 29.32/29.11  tff(decl_63743, type, 'value of property': $i).
% 29.32/29.11  tff(decl_63744, type, 'property value': $i).
% 29.32/29.11  tff(decl_63745, type, 'property-value': $i).
% 29.32/29.11  tff(decl_63746, type, 'Prophage': $i).
% 29.32/29.11  tff(decl_63747, type, 'A phage genome that has been inserted into a specific site on a bacterial chromosome.': $i).
% 29.32/29.11  tff(decl_63748, type, prophage: $i).
% 29.32/29.11  tff(decl_63749, type, fn_prophage_1: $i > $i).
% 29.32/29.11  tff(decl_63750, type, fn_prophage_2: $i > $i).
% 29.32/29.11  tff(decl_63751, type, fn_prophage_3: $i > $i).
% 29.32/29.11  tff(decl_63752, type, fn_prophage_4: $i > $i).
% 29.32/29.11  tff(decl_63753, type, fn_prophage_5: $i > $i).
% 29.32/29.11  tff(decl_63754, type, fn_prophage_6: $i > $i).
% 29.32/29.11  tff(decl_63755, type, fn_prophage_7: $i > $i).
% 29.32/29.11  tff(decl_63756, type, fn_prophage_8: $i > $i).
% 29.32/29.11  tff(decl_63757, type, 'Prophase': $i).
% 29.32/29.11  tff(decl_63758, type, 'Prophase is the initial stage of cell division. Prophase can be identified by distinguishable events including dissolution of the nuclear membrane and condensation of chromatin': $i).
% 29.32/29.11  tff(decl_63759, type, 'undergo prophase': $i).
% 29.32/29.11  tff(decl_63760, type, prophase: $i).
% 29.32/29.11  tff(decl_63761, type, fn_prophase_1: $i > $i).
% 29.32/29.11  tff(decl_63762, type, fn_prophase_2: $i > $i).
% 29.32/29.11  tff(decl_63763, type, fn_prophase_4: $i > $i).
% 29.32/29.11  tff(decl_63764, type, sister_chromatid_cohesion_1: $i > $o).
% 29.32/29.11  tff(decl_63765, type, fn_prophase_5: $i > $i).
% 29.32/29.11  tff(decl_63766, type, fn_prophase_6: $i > $i).
% 29.32/29.11  tff(decl_63767, type, fn_prophase_7: $i > $i).
% 29.32/29.11  tff(decl_63768, type, fn_prophase_10: $i > $i).
% 29.32/29.11  tff(decl_63769, type, fn_prophase_11: $i > $i).
% 29.32/29.11  tff(decl_63770, type, fn_prophase_12: $i > $i).
% 29.32/29.11  tff(decl_63771, type, fn_prophase_14: $i > $i).
% 29.32/29.11  tff(decl_63772, type, fn_prophase_15: $i > $i).
% 29.32/29.11  tff(decl_63773, type, fn_prophase_16: $i > $i).
% 29.32/29.11  tff(decl_63774, type, fn_prophase_17: $i > $i).
% 29.32/29.11  tff(decl_63775, type, fn_prophase_19: $i > $i).
% 29.32/29.11  tff(decl_63776, type, fn_prophase_20: $i > $i).
% 29.32/29.11  tff(decl_63777, type, fn_prophase_22: $i > $i).
% 29.32/29.11  tff(decl_63778, type, fn_prophase_23: $i > $i).
% 29.32/29.11  tff(decl_63779, type, fn_prophase_25: $i > $i).
% 29.32/29.11  tff(decl_63780, type, fn_prophase_26: $i > $i).
% 29.32/29.11  tff(decl_63781, type, fn_prophase_27: $i > $i).
% 29.32/29.11  tff(decl_63782, type, fn_prophase_29: $i > $i).
% 29.32/29.11  tff(decl_63783, type, fn_prophase_31: $i > $i).
% 29.32/29.11  tff(decl_63784, type, fn_prophase_32: $i > $i).
% 29.32/29.11  tff(decl_63785, type, fn_prophase_33: $i > $i).
% 29.32/29.11  tff(decl_63786, type, fn_prophase_34: $i > $i).
% 29.32/29.11  tff(decl_63787, type, fn_prophase_36: $i > $i).
% 29.32/29.11  tff(decl_63788, type, fn_prophase_37: $i > $i).
% 29.32/29.11  tff(decl_63789, type, fn_prophase_38: $i > $i).
% 29.32/29.11  tff(decl_63790, type, fn_prophase_39: $i > $i).
% 29.32/29.11  tff(decl_63791, type, fn_prophase_40: $i > $i).
% 29.32/29.11  tff(decl_63792, type, fn_prophase_41: $i > $i).
% 29.32/29.11  tff(decl_63793, type, fn_prophase_42: $i > $i).
% 29.32/29.11  tff(decl_63794, type, fn_prophase_43: $i > $i).
% 29.32/29.11  tff(decl_63795, type, fn_prophase_44: $i > $i).
% 29.32/29.11  tff(decl_63796, type, fn_prophase_45: $i > $i).
% 29.32/29.11  tff(decl_63797, type, fn_prophase_48: $i > $i).
% 29.32/29.11  tff(decl_63798, type, fn_prophase_50: $i > $i).
% 29.32/29.11  tff(decl_63799, type, fn_prophase_51: $i > $i).
% 29.32/29.11  tff(decl_63800, type, fn_prophase_52: $i > $i).
% 29.32/29.11  tff(decl_63801, type, fn_sister_chromatid_4: $i > $i).
% 29.32/29.11  tff(decl_63802, type, fn_prophase_54: $i > $i).
% 29.32/29.11  tff(decl_63803, type, fn_prophase_55: $i > $i).
% 29.32/29.11  tff(decl_63804, type, fn_prophase_9: $i > $i).
% 29.32/29.11  tff(decl_63805, type, fn_prophase_8: $i > $i).
% 29.32/29.11  tff(decl_63806, type, fn_prophase_53: $i > $i).
% 29.32/29.11  tff(decl_63807, type, fn_prophase_i_28: $i > $i).
% 29.32/29.11  tff(decl_63808, type, fn_prophase_i_27: $i > $i).
% 29.32/29.11  tff(decl_63809, type, 'Prophase-I': $i).
% 29.32/29.11  tff(decl_63810, type, 'The first phase of meiosis where the chromosomes begin to condense and become organized for the rest of the meiotic process.  Crossing over also occurs during prophase I.': $i).
% 29.32/29.11  tff(decl_63811, type, 'meiotic prophase i': $i).
% 29.32/29.11  tff(decl_63812, type, 'meiotic prophase-i': $i).
% 29.32/29.11  tff(decl_63813, type, 'undergo prophase i': $i).
% 29.32/29.11  tff(decl_63814, type, 'undergo prophase-i': $i).
% 29.32/29.11  tff(decl_63815, type, 'prophase i': $i).
% 29.32/29.11  tff(decl_63816, type, 'prophase-i': $i).
% 29.32/29.11  tff(decl_63817, type, fn_prophase_i_1: $i > $i).
% 29.32/29.11  tff(decl_63818, type, fn_prophase_i_2: $i > $i).
% 29.32/29.11  tff(decl_63819, type, fn_prophase_i_3: $i > $i).
% 29.32/29.11  tff(decl_63820, type, fn_prophase_i_4: $i > $i).
% 29.32/29.11  tff(decl_63821, type, fn_prophase_i_5: $i > $i).
% 29.32/29.11  tff(decl_63822, type, fn_prophase_i_8: $i > $i).
% 29.32/29.11  tff(decl_63823, type, fn_prophase_i_9: $i > $i).
% 29.32/29.11  tff(decl_63824, type, fn_prophase_i_10: $i > $i).
% 29.32/29.11  tff(decl_63825, type, fn_prophase_i_11: $i > $i).
% 29.32/29.11  tff(decl_63826, type, fn_prophase_i_12: $i > $i).
% 29.32/29.11  tff(decl_63827, type, fn_prophase_i_13: $i > $i).
% 29.32/29.11  tff(decl_63828, type, fn_prophase_i_14: $i > $i).
% 29.32/29.11  tff(decl_63829, type, fn_prophase_i_15: $i > $i).
% 29.32/29.11  tff(decl_63830, type, fn_prophase_i_16: $i > $i).
% 29.32/29.11  tff(decl_63831, type, fn_prophase_i_17: $i > $i).
% 29.32/29.11  tff(decl_63832, type, fn_prophase_i_18: $i > $i).
% 29.32/29.11  tff(decl_63833, type, fn_prophase_i_19: $i > $i).
% 29.32/29.11  tff(decl_63834, type, fn_prophase_i_20: $i > $i).
% 29.32/29.11  tff(decl_63835, type, fn_prophase_i_21: $i > $i).
% 29.32/29.11  tff(decl_63836, type, fn_prophase_i_22: $i > $i).
% 29.32/29.11  tff(decl_63837, type, fn_prophase_i_23: $i > $i).
% 29.32/29.11  tff(decl_63838, type, fn_prophase_i_24: $i > $i).
% 29.32/29.11  tff(decl_63839, type, fn_prophase_i_25: $i > $i).
% 29.32/29.11  tff(decl_63840, type, fn_prophase_i_26: $i > $i).
% 29.32/29.11  tff(decl_63841, type, fn_prophase_i_29: $i > $i).
% 29.32/29.11  tff(decl_63842, type, fn_prophase_i_30: $i > $i).
% 29.32/29.11  tff(decl_63843, type, synapsis_1: $i > $o).
% 29.32/29.11  tff(decl_63844, type, fn_prophase_i_31: $i > $i).
% 29.32/29.11  tff(decl_63845, type, fn_synapsis_16: $i > $i).
% 29.32/29.11  tff(decl_63846, type, 'Prophase-II': $i).
% 29.32/29.11  tff(decl_63847, type, 'During Prophase II phase of Meiosis II, a spindle apparatus is formed and the chromosomes move toward the metaphase II plate': $i).
% 29.32/29.11  tff(decl_63848, type, 'undergo prophase ii': $i).
% 29.32/29.11  tff(decl_63849, type, 'undergo prophase-ii': $i).
% 29.32/29.11  tff(decl_63850, type, 'prophase ii': $i).
% 29.32/29.11  tff(decl_63851, type, 'prophase-ii': $i).
% 29.32/29.11  tff(decl_63852, type, fn_prophase_ii_1: $i > $i).
% 29.32/29.11  tff(decl_63853, type, fn_prophase_ii_2: $i > $i).
% 29.32/29.11  tff(decl_63854, type, fn_prophase_ii_3: $i > $i).
% 29.32/29.11  tff(decl_63855, type, fn_prophase_ii_4: $i > $i).
% 29.32/29.11  tff(decl_63856, type, fn_prophase_ii_5: $i > $i).
% 29.32/29.11  tff(decl_63857, type, fn_prophase_ii_6: $i > $i).
% 29.32/29.11  tff(decl_63858, type, fn_prophase_ii_7: $i > $i).
% 29.32/29.11  tff(decl_63859, type, fn_prophase_ii_8: $i > $i).
% 29.32/29.11  tff(decl_63860, type, prosecution_1: $i > $o).
% 29.32/29.11  tff(decl_63861, type, 'Prosecution': $i).
% 29.32/29.11  tff(decl_63862, type, prosecution: $i).
% 29.32/29.11  tff(decl_63863, type, 'criminal prosecution': $i).
% 29.32/29.11  tff(decl_63864, type, criminal_prosecution: $i).
% 29.32/29.11  tff(decl_63865, type, 'legal action': $i).
% 29.32/29.11  tff(decl_63866, type, legal_action: $i).
% 29.32/29.11  tff(decl_63867, type, prosecute: $i).
% 29.32/29.11  tff(decl_63868, type, prostaglandin_1: $i > $o).
% 29.32/29.11  tff(decl_63869, type, 'Prostaglandin': $i).
% 29.32/29.11  tff(decl_63870, type, 'A local regulator comprised of modified fatty acids, often derived from lipids to the plasma membrane.': $i).
% 29.32/29.11  tff(decl_63871, type, prostaglandin: $i).
% 29.32/29.11  tff(decl_63872, type, pg: $i).
% 29.32/29.11  tff(decl_63873, type, 'Prostate-Cancer': $i).
% 29.32/29.11  tff(decl_63874, type, 'Cancer of the prostate gland.': $i).
% 29.32/29.11  tff(decl_63875, type, 'cancer of prostate': $i).
% 29.32/29.11  tff(decl_63876, type, 'prostate cancer': $i).
% 29.32/29.11  tff(decl_63877, type, 'prostate-cancer': $i).
% 29.32/29.11  tff(decl_63878, type, 'Prostate-Gland': $i).
% 29.32/29.11  tff(decl_63879, type, 'A gland in the human male reproductive tract that secretes an alkaline component of semen.': $i).
% 29.32/29.11  tff(decl_63880, type, 'gland of prostate': $i).
% 29.32/29.11  tff(decl_63881, type, 'prostate gland': $i).
% 29.32/29.11  tff(decl_63882, type, 'prostate-gland': $i).
% 29.32/29.11  tff(decl_63883, type, 'Prosthetic-Group': $i).
% 29.32/29.11  tff(decl_63884, type, 'A non-protein segment of a functional protein that is essential for the function of the protein is considered a prosthetic group.': $i).
% 29.32/29.11  tff(decl_63885, type, 'prosthetic group': $i).
% 29.32/29.11  tff(decl_63886, type, 'prosthetic-group': $i).
% 29.32/29.11  tff(decl_63887, type, fn_prosthetic_group_1: $i > $i).
% 29.32/29.11  tff(decl_63888, type, protactinium_1: $i > $o).
% 29.32/29.11  tff(decl_63889, type, 'Protactinium': $i).
% 29.32/29.11  tff(decl_63890, type, 'Protactinium is a metal atom with atomic number 91. It is represented by the symbol Pa.': $i).
% 29.32/29.11  tff(decl_63891, type, protactinium: $i).
% 29.32/29.11  tff(decl_63892, type, pa: $i).
% 29.32/29.11  tff(decl_63893, type, fn_protactinium_4: $i > $i).
% 29.32/29.11  tff(decl_63894, type, fn_protactinium_5: $i > $i).
% 29.32/29.11  tff(decl_63895, type, fn_protactinium_6: $i > $i).
% 29.32/29.11  tff(decl_63896, type, fn_protactinium_7: $i > $i).
% 29.32/29.11  tff(decl_63897, type, fn_protactinium_11: $i > $i).
% 29.32/29.11  tff(decl_63898, type, fn_protactinium_12: $i > $i).
% 29.32/29.11  tff(decl_63899, type, fn_protactinium_13: $i > $i).
% 29.32/29.11  tff(decl_63900, type, fn_protactinium_14: $i > $i).
% 29.32/29.11  tff(decl_63901, type, "91": $i).
% 29.32/29.11  tff(decl_63902, type, "1.5": $i).
% 29.32/29.11  tff(decl_63903, type, "231": $i).
% 29.32/29.11  tff(decl_63904, type, fn_protactinium_9: $i > $i).
% 29.32/29.11  tff(decl_63905, type, fn_protactinium_10: $i > $i).
% 29.32/29.11  tff(decl_63906, type, fn_protactinium_8: $i > $i).
% 29.32/29.11  tff(decl_63907, type, 'Protease': $i).
% 29.32/29.11  tff(decl_63908, type, 'A protease (also termed peptidase or proteinase) breaks down proteins. A protease is any enzyme that conducts proteolysis, that is, begins protein catabolism by hydrolysis of the peptide bonds that link amino acids together in the polypeptide chain forming the protein.': $i).
% 29.32/29.11  tff(decl_63909, type, peptidase: $i).
% 29.32/29.11  tff(decl_63910, type, proteinase: $i).
% 29.32/29.11  tff(decl_63911, type, protease: $i).
% 29.32/29.11  tff(decl_63912, type, fn_protease_7: $i > $i).
% 29.32/29.11  tff(decl_63913, type, fn_protease_9: $i > $i).
% 29.32/29.11  tff(decl_63914, type, fn_protease_10: $i > $i).
% 29.32/29.11  tff(decl_63915, type, fn_protease_11: $i > $i).
% 29.32/29.11  tff(decl_63916, type, fn_protease_12: $i > $i).
% 29.32/29.11  tff(decl_63917, type, fn_protease_13: $i > $i).
% 29.32/29.11  tff(decl_63918, type, fn_protease_14: $i > $i).
% 29.32/29.11  tff(decl_63919, type, fn_protease_15: $i > $i).
% 29.32/29.11  tff(decl_63920, type, fn_protease_16: $i > $i).
% 29.32/29.11  tff(decl_63921, type, fn_protease_20: $i > $i).
% 29.32/29.11  tff(decl_63922, type, fn_protease_21: $i > $i).
% 29.32/29.11  tff(decl_63923, type, fn_protease_24: $i > $i).
% 29.32/29.11  tff(decl_63924, type, fn_protease_25: $i > $i).
% 29.32/29.11  tff(decl_63925, type, fn_protease_26: $i > $i).
% 29.32/29.11  tff(decl_63926, type, fn_protease_28: $i > $i).
% 29.32/29.11  tff(decl_63927, type, fn_protease_30: $i > $i).
% 29.32/29.11  tff(decl_63928, type, fn_protease_32: $i > $i).
% 29.32/29.11  tff(decl_63929, type, fn_protease_33: $i > $i).
% 29.32/29.11  tff(decl_63930, type, fn_protease_34: $i > $i).
% 29.32/29.11  tff(decl_63931, type, fn_protease_4: $i > $i).
% 29.32/29.11  tff(decl_63932, type, fn_protease_3: $i > $i).
% 29.32/29.11  tff(decl_63933, type, 'Proteasome': $i).
% 29.32/29.11  tff(decl_63934, type, 'A giant protein complex that recognizes and destroys proteins tagged for elimination by the small protein ubiquitin.': $i).
% 29.32/29.11  tff(decl_63935, type, proteasome: $i).
% 29.32/29.11  tff(decl_63936, type, fn_proteasome_1: $i > $i).
% 29.32/29.11  tff(decl_63937, type, fn_proteasome_2: $i > $i).
% 29.32/29.11  tff(decl_63938, type, fn_proteasome_3: $i > $i).
% 29.32/29.11  tff(decl_63939, type, fn_proteasome_4: $i > $i).
% 29.32/29.11  tff(decl_63940, type, fn_proteasome_5: $i > $i).
% 29.32/29.11  tff(decl_63941, type, fn_proteasome_10: $i > $i).
% 29.32/29.11  tff(decl_63942, type, fn_proteasome_11: $i > $i).
% 29.32/29.11  tff(decl_63943, type, fn_proteasome_12: $i > $i).
% 29.32/29.11  tff(decl_63944, type, fn_proteasome_13: $i > $i).
% 29.32/29.11  tff(decl_63945, type, fn_proteasome_14: $i > $i).
% 29.32/29.11  tff(decl_63946, type, fn_proteasome_15: $i > $i).
% 29.32/29.11  tff(decl_63947, type, fn_proteasome_16: $i > $i).
% 29.32/29.11  tff(decl_63948, type, fn_proteasome_17: $i > $i).
% 29.32/29.11  tff(decl_63949, type, fn_proteasome_18: $i > $i).
% 29.32/29.11  tff(decl_63950, type, fn_proteasome_19: $i > $i).
% 29.32/29.11  tff(decl_63951, type, fn_proteasome_20: $i > $i).
% 29.32/29.11  tff(decl_63952, type, fn_proteasome_21: $i > $i).
% 29.32/29.11  tff(decl_63953, type, fn_proteasome_22: $i > $i).
% 29.32/29.11  tff(decl_63954, type, fn_proteasome_23: $i > $i).
% 29.32/29.11  tff(decl_63955, type, fn_proteasome_24: $i > $i).
% 29.32/29.11  tff(decl_63956, type, fn_proteasome_6: $i > $i).
% 29.32/29.11  tff(decl_63957, type, fn_proteasome_8: $i > $i).
% 29.32/29.11  tff(decl_63958, type, fn_proteasome_7: $i > $i).
% 29.32/29.11  tff(decl_63959, type, fn_proteasome_9: $i > $i).
% 29.32/29.11  tff(decl_63960, type, 'Protein': $i).
% 29.32/29.11  tff(decl_63961, type, 'Proteins are macromolecules, consisting of polypeptide chains made from 20 different kinds of amino acids. Proteins serve many functions in organisms, including catalysis, defense, and transport.': $i).
% 29.32/29.11  tff(decl_63962, type, protein: $i).
% 29.32/29.11  tff(decl_63963, type, fn_protein_3: $i > $i).
% 29.32/29.11  tff(decl_63964, type, fn_protein_4: $i > $i).
% 29.32/29.11  tff(decl_63965, type, fn_protein_domain_1: $i > $i).
% 29.32/29.11  tff(decl_63966, type, protein_analysis_1: $i > $o).
% 29.32/29.11  tff(decl_63967, type, 'Protein-Analysis': $i).
% 29.32/29.11  tff(decl_63968, type, 'The process of determining the structure and function of a protein through laboratory techniques and bioinformatics.': $i).
% 29.32/29.11  tff(decl_63969, type, 'analysis of protein': $i).
% 29.32/29.11  tff(decl_63970, type, 'protein analysis': $i).
% 29.32/29.11  tff(decl_63971, type, 'protein-analysis': $i).
% 29.32/29.11  tff(decl_63972, type, fn_protein_analysis_1: $i > $i).
% 29.32/29.11  tff(decl_63973, type, fn_protein_analysis_2: $i > $i).
% 29.32/29.11  tff(decl_63974, type, fn_protein_analysis_3: $i > $i).
% 29.32/29.11  tff(decl_63975, type, protein_breakdown_1: $i > $o).
% 29.32/29.11  tff(decl_63976, type, 'Protein-Breakdown': $i).
% 29.32/29.11  tff(decl_63977, type, 'The process in which proteins breakdown into their simpler components.': $i).
% 29.32/29.11  tff(decl_63978, type, 'breakdown of protein': $i).
% 29.32/29.11  tff(decl_63979, type, 'protein breakdown': $i).
% 29.32/29.11  tff(decl_63980, type, 'protein-breakdown': $i).
% 29.32/29.11  tff(decl_63981, type, fn_protein_breakdown_1: $i > $i).
% 29.32/29.11  tff(decl_63982, type, fn_protein_breakdown_2: $i > $i).
% 29.32/29.11  tff(decl_63983, type, fn_protein_breakdown_3: $i > $i).
% 29.32/29.11  tff(decl_63984, type, fn_protein_breakdown_4: $i > $i).
% 29.32/29.11  tff(decl_63985, type, fn_protein_breakdown_5: $i > $i).
% 29.32/29.11  tff(decl_63986, type, fn_protein_breakdown_6: $i > $i).
% 29.32/29.11  tff(decl_63987, type, fn_protein_breakdown_7: $i > $i).
% 29.32/29.11  tff(decl_63988, type, fn_protein_breakdown_8: $i > $i).
% 29.32/29.11  tff(decl_63989, type, fn_protein_breakdown_9: $i > $i).
% 29.32/29.11  tff(decl_63990, type, fn_protein_breakdown_10: $i > $i).
% 29.32/29.11  tff(decl_63991, type, fn_protein_breakdown_11: $i > $i).
% 29.32/29.11  tff(decl_63992, type, 'Protein-Complex': $i).
% 29.32/29.11  tff(decl_63993, type, 'A group of proteins whose arrangement is organized to perform a particular function.': $i).
% 29.32/29.11  tff(decl_63994, type, 'complex of protein': $i).
% 29.32/29.11  tff(decl_63995, type, 'protein complex': $i).
% 29.32/29.11  tff(decl_63996, type, 'protein-complex': $i).
% 29.32/29.11  tff(decl_63997, type, 'Protein-Core': $i).
% 29.32/29.11  tff(decl_63998, type, 'A protein complex composed of two molecules each of four different types of histone: H2A, H2B, H3, and H4.': $i).
% 29.32/29.11  tff(decl_63999, type, 'core of protein': $i).
% 29.32/29.11  tff(decl_64000, type, 'protein core': $i).
% 29.32/29.11  tff(decl_64001, type, 'protein-core': $i).
% 29.32/29.11  tff(decl_64002, type, fn_protein_core_1: $i > $i).
% 29.32/29.11  tff(decl_64003, type, fn_protein_core_2: $i > $i).
% 29.32/29.11  tff(decl_64004, type, fn_protein_core_3: $i > $i).
% 29.32/29.11  tff(decl_64005, type, fn_protein_core_4: $i > $i).
% 29.32/29.11  tff(decl_64006, type, 'Protein-Denaturation': $i).
% 29.32/29.11  tff(decl_64007, type, 'A process in which a protein unravels and loses its native shape, thereby becoming biologically inactive.  Denaturation occurs under extreme (noncellular) conditions of pH, salt concentration, and temperature.': $i).
% 29.32/29.11  tff(decl_64008, type, 'denaturation of protein': $i).
% 29.32/29.11  tff(decl_64009, type, 'protein denaturation': $i).
% 29.32/29.11  tff(decl_64010, type, 'protein-denaturation': $i).
% 29.32/29.11  tff(decl_64011, type, fn_protein_denaturation_2: $i > $i).
% 29.32/29.11  tff(decl_64012, type, fn_protein_denaturation_3: $i > $i).
% 29.32/29.11  tff(decl_64013, type, fn_protein_denaturation_4: $i > $i).
% 29.32/29.11  tff(decl_64014, type, fn_protein_denaturation_5: $i > $i).
% 29.32/29.11  tff(decl_64015, type, fn_protein_denaturation_6: $i > $i).
% 29.32/29.11  tff(decl_64016, type, fn_protein_denaturation_8: $i > $i).
% 29.32/29.11  tff(decl_64017, type, protein_denaturation_by_denaturation_agent_1: $i > $o).
% 29.32/29.11  tff(decl_64018, type, 'Protein-Denaturation-By-Denaturation-Agent': $i).
% 29.32/29.11  tff(decl_64019, type, 'A process in which a protein loses its native shape due to the disruption of weak chemical bonds and interactions under extreme (noncellular) conditions of pH, salt concentration, or temperature, thereby becoming biologically inactive.': $i).
% 29.32/29.11  tff(decl_64020, type, 'protein denaturation by denaturation agent': $i).
% 29.32/29.11  tff(decl_64021, type, 'protein-denaturation-by-denaturation-agent': $i).
% 29.32/29.11  tff(decl_64022, type, fn_protein_denaturation_by_denaturation_agent_1: $i > $i).
% 29.32/29.11  tff(decl_64023, type, fn_protein_denaturation_by_denaturation_agent_2: $i > $i).
% 29.32/29.11  tff(decl_64024, type, fn_protein_denaturation_by_denaturation_agent_3: $i > $i).
% 29.32/29.11  tff(decl_64025, type, unfolded_protein_1: $i > $o).
% 29.32/29.11  tff(decl_64026, type, fn_protein_denaturation_by_denaturation_agent_4: $i > $i).
% 29.32/29.11  tff(decl_64027, type, fn_protein_denaturation_by_denaturation_agent_5: $i > $i).
% 29.32/29.11  tff(decl_64028, type, fn_protein_denaturation_by_denaturation_agent_8: $i > $i).
% 29.32/29.11  tff(decl_64029, type, fn_protein_denaturation_by_denaturation_agent_9: $i > $i).
% 29.32/29.11  tff(decl_64030, type, fn_protein_denaturation_by_denaturation_agent_10: $i > $i).
% 29.32/29.11  tff(decl_64031, type, fn_protein_denaturation_by_denaturation_agent_11: $i > $i).
% 29.32/29.11  tff(decl_64032, type, fn_protein_denaturation_by_denaturation_agent_12: $i > $i).
% 29.32/29.11  tff(decl_64033, type, fn_protein_denaturation_by_denaturation_agent_13: $i > $i).
% 29.32/29.11  tff(decl_64034, type, fn_protein_denaturation_by_denaturation_agent_14: $i > $i).
% 29.32/29.11  tff(decl_64035, type, fn_protein_denaturation_by_denaturation_agent_15: $i > $i).
% 29.32/29.11  tff(decl_64036, type, fn_protein_denaturation_by_denaturation_agent_16: $i > $i).
% 29.32/29.11  tff(decl_64037, type, fn_protein_denaturation_by_denaturation_agent_17: $i > $i).
% 29.32/29.11  tff(decl_64038, type, fn_protein_denaturation_by_denaturation_agent_18: $i > $i).
% 29.32/29.11  tff(decl_64039, type, fn_protein_denaturation_by_denaturation_agent_19: $i > $i).
% 29.32/29.11  tff(decl_64040, type, break_0: $i).
% 29.32/29.11  tff(decl_64041, type, fn_protein_denaturation_by_denaturation_agent_7: $i > $i).
% 29.32/29.11  tff(decl_64042, type, fn_protein_denaturation_7: $i > $i).
% 29.32/29.11  tff(decl_64043, type, fn_protein_denaturation_by_denaturation_agent_6: $i > $i).
% 29.32/29.11  tff(decl_64044, type, fn_protein_denaturation_1: $i > $i).
% 29.32/29.11  tff(decl_64045, type, protein_denaturation_by_heat_1: $i > $o).
% 29.32/29.11  tff(decl_64046, type, fn_protein_denaturation_by_heat_1: $i > $i).
% 29.32/29.11  tff(decl_64047, type, 'Protein-Denaturation-By-Heat': $i).
% 29.32/29.11  tff(decl_64048, type, 'If protein is exposed to excessive heat, it undergoes denaturation and loses it shape and function.': $i).
% 29.32/29.11  tff(decl_64049, type, 'protein denaturation by heat': $i).
% 29.32/29.11  tff(decl_64050, type, 'protein-denaturation-by-heat': $i).
% 29.32/29.11  tff(decl_64051, type, fn_protein_denaturation_by_heat_3: $i > $i).
% 29.32/29.11  tff(decl_64052, type, fn_protein_denaturation_by_heat_4: $i > $i).
% 29.32/29.11  tff(decl_64053, type, fn_protein_denaturation_by_heat_5: $i > $i).
% 29.32/29.11  tff(decl_64054, type, 'Protein-Denaturation-By-PH-Change': $i).
% 29.32/29.11  tff(decl_64055, type, 'A process in which a protein loses its native shape due to the disruption of the ionic bonds that maintain the protein\\s shape, thereby becoming biologically inactive.': $i).
% 29.32/29.11  tff(decl_64056, type, 'protein denaturation by ph change': $i).
% 29.32/29.11  tff(decl_64057, type, 'protein-denaturation-by-ph-change': $i).
% 29.32/29.11  tff(decl_64058, type, protein_denaturation_by_salt_concentration_change_1: $i > $o).
% 29.32/29.11  tff(decl_64059, type, fn_protein_denaturation_by_ph_change_2: $i > $i).
% 29.32/29.11  tff(decl_64060, type, fn_protein_denaturation_by_ph_change_3: $i > $i).
% 29.32/29.11  tff(decl_64061, type, fn_protein_denaturation_by_ph_change_5: $i > $i).
% 29.32/29.11  tff(decl_64062, type, fn_protein_denaturation_by_ph_change_6: $i > $i).
% 29.32/29.11  tff(decl_64063, type, fn_protein_denaturation_by_ph_change_7: $i > $i).
% 29.32/29.11  tff(decl_64064, type, fn_protein_denaturation_by_ph_change_9: $i > $i).
% 29.32/29.11  tff(decl_64065, type, fn_protein_denaturation_by_ph_change_10: $i > $i).
% 29.32/29.11  tff(decl_64066, type, 'Protein-Denaturation-By-Salt-Concentration-Change': $i).
% 29.32/29.11  tff(decl_64067, type, 'A process in which a protein loses its native shape due to the disruption of the ionic bonds that maintain the protein\\s shape, thereby becoming biologically inactive, in much the same way as with a change in pH.': $i).
% 29.32/29.11  tff(decl_64068, type, 'protein denaturation by salt concentration change': $i).
% 29.32/29.11  tff(decl_64069, type, 'protein-denaturation-by-salt-concentration-change': $i).
% 29.32/29.11  tff(decl_64070, type, fn_protein_denaturation_by_salt_concentration_change_1: $i > $i).
% 29.32/29.11  tff(decl_64071, type, fn_protein_denaturation_by_salt_concentration_change_2: $i > $i).
% 29.32/29.11  tff(decl_64072, type, fn_protein_denaturation_by_salt_concentration_change_3: $i > $i).
% 29.32/29.11  tff(decl_64073, type, fn_protein_denaturation_by_salt_concentration_change_4: $i > $i).
% 29.32/29.11  tff(decl_64074, type, fn_protein_dimer_3: $i > $i).
% 29.32/29.11  tff(decl_64075, type, 'Protein-Dimer': $i).
% 29.32/29.11  tff(decl_64076, type, 'Two proteins associating closely together to form a dimer': $i).
% 29.32/29.11  tff(decl_64077, type, 'dimer of protein': $i).
% 29.32/29.11  tff(decl_64078, type, 'protein dimer': $i).
% 29.32/29.11  tff(decl_64079, type, 'protein-dimer': $i).
% 29.32/29.11  tff(decl_64080, type, fn_protein_dimer_2: $i > $i).
% 29.32/29.11  tff(decl_64081, type, fn_protein_dimer_4: $i > $i).
% 29.32/29.11  tff(decl_64082, type, 'Protein-Domain': $i).
% 29.32/29.11  tff(decl_64083, type, 'A defined portion of a protein which has been identified as uniques according to its structure or its function.': $i).
% 29.32/29.11  tff(decl_64084, type, 'domain of protein': $i).
% 29.32/29.11  tff(decl_64085, type, 'protein domain': $i).
% 29.32/29.11  tff(decl_64086, type, 'protein-domain': $i).
% 29.32/29.11  tff(decl_64087, type, 'Protein-Enzyme': $i).
% 29.32/29.11  tff(decl_64088, type, 'A protein that functions as an enzyme.': $i).
% 29.32/29.11  tff(decl_64089, type, 'enzymatic protein': $i).
% 29.32/29.11  tff(decl_64090, type, 'enzyme of protein': $i).
% 29.32/29.11  tff(decl_64091, type, 'protein enzyme': $i).
% 29.32/29.11  tff(decl_64092, type, 'protein-enzyme': $i).
% 29.32/29.11  tff(decl_64093, type, fn_protein_enzyme_1: $i > $i).
% 29.32/29.11  tff(decl_64094, type, 'Protein-Folding': $i).
% 29.32/29.11  tff(decl_64095, type, 'The process of altering the shape of a polypeptide through interactions such as hydrogen bonds, hydrophobic interactions, and disulfide bridges to create a functional protein.': $i).
% 29.32/29.11  tff(decl_64096, type, 'folding of protein': $i).
% 29.32/29.11  tff(decl_64097, type, 'protein folding': $i).
% 29.32/29.11  tff(decl_64098, type, 'protein-folding': $i).
% 29.32/29.11  tff(decl_64099, type, fn_protein_folding_1: $i > $i).
% 29.32/29.11  tff(decl_64100, type, fn_protein_folding_2: $i > $i).
% 29.32/29.11  tff(decl_64101, type, fn_protein_folding_3: $i > $i).
% 29.32/29.11  tff(decl_64102, type, fn_protein_folding_4: $i > $i).
% 29.32/29.11  tff(decl_64103, type, fn_protein_folding_5: $i > $i).
% 29.32/29.11  tff(decl_64104, type, fn_protein_folding_6: $i > $i).
% 29.32/29.11  tff(decl_64105, type, fn_protein_folding_7: $i > $i).
% 29.32/29.11  tff(decl_64106, type, fn_protein_folding_8: $i > $i).
% 29.32/29.11  tff(decl_64107, type, fn_protein_folding_9: $i > $i).
% 29.32/29.11  tff(decl_64108, type, fn_protein_folding_10: $i > $i).
% 29.32/29.11  tff(decl_64109, type, tertiary_protein_structure_1: $i > $o).
% 29.32/29.11  tff(decl_64110, type, fn_tertiary_protein_structure_65: $i > $i).
% 29.32/29.11  tff(decl_64111, type, fn_secondary_protein_structure_22: $i > $i).
% 29.32/29.11  tff(decl_64112, type, fn_secondary_protein_structure_3: $i > $i).
% 29.32/29.11  tff(decl_64113, type, fn_secondary_protein_structure_52: $i > $i).
% 29.32/29.11  tff(decl_64114, type, 'Protein-Kinase': $i).
% 29.32/29.11  tff(decl_64115, type, 'Enzyme which phosphorylates proteins.': $i).
% 29.32/29.11  tff(decl_64116, type, 'kinase of protein': $i).
% 29.32/29.11  tff(decl_64117, type, 'Protein-Kinase-A': $i).
% 29.32/29.11  tff(decl_64118, type, 'A serine/threonine kinase that is activated by cAMP.': $i).
% 29.32/29.11  tff(decl_64119, type, 'serine threonine kinase': $i).
% 29.32/29.11  tff(decl_64120, type, 'serine-threonine-kinase': $i).
% 29.32/29.11  tff(decl_64121, type, 'protein kinase a': $i).
% 29.32/29.11  tff(decl_64122, type, 'protein-kinase-a': $i).
% 29.32/29.11  tff(decl_64123, type, 'Protein-Layer': $i).
% 29.32/29.11  tff(decl_64124, type, 'A protein layer that covers the surface of a cell and acts as a barrier between the inside of a cell and its environment.': $i).
% 29.32/29.11  tff(decl_64125, type, 'layer of protein': $i).
% 29.32/29.11  tff(decl_64126, type, 'protein layer': $i).
% 29.32/29.11  tff(decl_64127, type, 'protein-layer': $i).
% 29.32/29.11  tff(decl_64128, type, 'Protein-Phosphatase': $i).
% 29.32/29.11  tff(decl_64129, type, 'An enzyme that cleaves phosphate groups from other proteins. Protein phosphatases often work to reverse the activity of protein kinases.': $i).
% 29.32/29.11  tff(decl_64130, type, 'phosphatase of protein': $i).
% 29.32/29.11  tff(decl_64131, type, 'protein phosphatase': $i).
% 29.32/29.11  tff(decl_64132, type, 'protein-phosphatase': $i).
% 29.32/29.11  tff(decl_64133, type, 'Protein-Pump': $i).
% 29.32/29.11  tff(decl_64134, type, 'Protein pumps are proteins which engage in the active transport (pumping) of ions and other molecules across cell membranes.': $i).
% 29.32/29.11  tff(decl_64135, type, 'protein pump': $i).
% 29.32/29.11  tff(decl_64136, type, 'protein-pump': $i).
% 29.32/29.11  tff(decl_64137, type, 'Protein-Related-Aggregates': $i).
% 29.32/29.11  tff(decl_64138, type, 'An entity which is formed by the combination of separate protein-related units.': $i).
% 29.32/29.11  tff(decl_64139, type, 'protein related aggregate': $i).
% 29.32/29.11  tff(decl_64140, type, 'protein-related-aggregate': $i).
% 29.32/29.11  tff(decl_64141, type, fn_protein_solution_3: $i > $i).
% 29.32/29.11  tff(decl_64142, type, fn_protein_solution_2: $i > $i).
% 29.32/29.11  tff(decl_64143, type, 'Protein-Solution': $i).
% 29.32/29.11  tff(decl_64144, type, 'A solution in which water is the solvent and soluble proteins are the solute.': $i).
% 29.32/29.11  tff(decl_64145, type, 'solution of protein': $i).
% 29.32/29.11  tff(decl_64146, type, 'protein solution': $i).
% 29.32/29.11  tff(decl_64147, type, 'protein-solution': $i).
% 29.32/29.11  tff(decl_64148, type, 'Proteobacteria': $i).
% 29.32/29.11  tff(decl_64149, type, 'A major group of bacteria that includes several pathogenic genera such as Escherichia, Salmonella, Helicobacter, and Vibrio.': $i).
% 29.32/29.11  tff(decl_64150, type, proteobacteria: $i).
% 29.32/29.11  tff(decl_64151, type, 'Proteoglycan': $i).
% 29.32/29.11  tff(decl_64152, type, 'A large molecule composed of several carbohydrate chains attached to a core of protein, found in the connective tissues of animals.': $i).
% 29.32/29.11  tff(decl_64153, type, proteoglycan: $i).
% 29.32/29.11  tff(decl_64154, type, fn_proteoglycan_1: $i > $i).
% 29.32/29.11  tff(decl_64155, type, fn_proteoglycan_4: $i > $i).
% 29.32/29.11  tff(decl_64156, type, fn_proteoglycan_5: $i > $i).
% 29.32/29.11  tff(decl_64157, type, fn_proteoglycan_6: $i > $i).
% 29.32/29.11  tff(decl_64158, type, fn_proteoglycan_7: $i > $i).
% 29.32/29.11  tff(decl_64159, type, fn_proteoglycan_8: $i > $i).
% 29.32/29.11  tff(decl_64160, type, fn_proteoglycan_9: $i > $i).
% 29.32/29.11  tff(decl_64161, type, proteome_1: $i > $o).
% 29.32/29.11  tff(decl_64162, type, 'Proteome': $i).
% 29.32/29.11  tff(decl_64163, type, 'The proteome is the entire set of proteins expressed by a genome, cell, tissue or organism.': $i).
% 29.32/29.11  tff(decl_64164, type, 'protein set': $i).
% 29.32/29.11  tff(decl_64165, type, 'full protein set': $i).
% 29.32/29.11  tff(decl_64166, type, 'protein family': $i).
% 29.32/29.11  tff(decl_64167, type, proteome: $i).
% 29.32/29.11  tff(decl_64168, type, fn_proteome_1: $i > $i).
% 29.32/29.11  tff(decl_64169, type, fn_proteome_2: $i > $i).
% 29.32/29.11  tff(decl_64170, type, fn_proteome_3: $i > $i).
% 29.32/29.11  tff(decl_64171, type, fn_proteome_4: $i > $i).
% 29.32/29.11  tff(decl_64172, type, fn_proteome_5: $i > $i).
% 29.32/29.11  tff(decl_64173, type, fn_proteome_6: $i > $i).
% 29.32/29.11  tff(decl_64174, type, fn_proteome_7: $i > $i).
% 29.32/29.11  tff(decl_64175, type, fn_proteome_8: $i > $i).
% 29.32/29.11  tff(decl_64176, type, genome_0: $i).
% 29.32/29.11  tff(decl_64177, type, proteomics_1: $i > $o).
% 29.32/29.11  tff(decl_64178, type, 'Proteomics': $i).
% 29.32/29.11  tff(decl_64179, type, 'The systematic study of the full protein sets (proteomes) encoded by genomes.': $i).
% 29.32/29.11  tff(decl_64180, type, proteomics: $i).
% 29.32/29.11  tff(decl_64181, type, study_of_membrane_by_electron_microscopy_1: $i > $o).
% 29.32/29.11  tff(decl_64182, type, fn_proteomics_1: $i > $i).
% 29.32/29.11  tff(decl_64183, type, 'Eukaryotic, unicellular organism. Includes protozoans, slime molds, and certain algae. Kingdom Protoctista.': $i).
% 29.32/29.11  tff(decl_64184, type, 'Protists are a diverse group of eukaryotic microorganisms. They are either unicellular, or multicellular without specialized tissues. They differ from other Eukaryotes (Animal, Plant and Fungi) by having a comparatively simple cellular organization.': $i).
% 29.32/29.11  tff(decl_64185, type, protista: $i).
% 29.32/29.11  tff(decl_64186, type, protist: $i).
% 29.32/29.11  tff(decl_64187, type, 'Protist-Cell': $i).
% 29.32/29.11  tff(decl_64188, type, 'The cell of any eukaryote that is not a plant, animal, or fungus.  They are usually unicellular though some are colonial and others are multicellular.': $i).
% 29.32/29.11  tff(decl_64189, type, 'cell of protist': $i).
% 29.32/29.11  tff(decl_64190, type, 'cell-of-protist': $i).
% 29.32/29.11  tff(decl_64191, type, 'protist cell': $i).
% 29.32/29.11  tff(decl_64192, type, 'protist-cell': $i).
% 29.32/29.11  tff(decl_64193, type, fn_protist_cell_1: $i > $i).
% 29.32/29.11  tff(decl_64194, type, 'Protist-Structure': $i).
% 29.32/29.11  tff(decl_64195, type, 'Structures specifically related to protists': $i).
% 29.32/29.11  tff(decl_64196, type, 'structure of protist': $i).
% 29.32/29.11  tff(decl_64197, type, 'protist structure': $i).
% 29.32/29.12  tff(decl_64198, type, 'protist-structure': $i).
% 29.32/29.12  tff(decl_64199, type, 'Proto-Oncogene': $i).
% 29.32/29.12  tff(decl_64200, type, 'Normal cellular genes that code for proteins that stimulate normal cell growth and division.': $i).
% 29.32/29.12  tff(decl_64201, type, 'proto oncogene': $i).
% 29.32/29.12  tff(decl_64202, type, 'proto-oncogene': $i).
% 29.32/29.12  tff(decl_64203, type, fn_proto_oncogene_3: $i > $i).
% 29.32/29.12  tff(decl_64204, type, fn_proto_oncogene_4: $i > $i).
% 29.32/29.12  tff(decl_64205, type, fn_proto_oncogene_6: $i > $i).
% 29.32/29.12  tff(decl_64206, type, fn_proto_oncogene_7: $i > $i).
% 29.32/29.12  tff(decl_64207, type, fn_proto_oncogene_8: $i > $i).
% 29.32/29.12  tff(decl_64208, type, fn_proto_oncogene_9: $i > $i).
% 29.32/29.12  tff(decl_64209, type, fn_proto_oncogene_10: $i > $i).
% 29.32/29.12  tff(decl_64210, type, fn_proto_oncogene_11: $i > $i).
% 29.32/29.12  tff(decl_64211, type, fn_proto_oncogene_12: $i > $i).
% 29.32/29.12  tff(decl_64212, type, fn_proto_oncogene_13: $i > $i).
% 29.32/29.12  tff(decl_64213, type, 'Protobiont': $i).
% 29.32/29.12  tff(decl_64214, type, 'A collection of abiotically produced organic molecules separated from the surrounding environment by a membrane. Protobionts may have been the precursors to prokaryote cells.': $i).
% 29.32/29.12  tff(decl_64215, type, protobiont: $i).
% 29.32/29.12  tff(decl_64216, type, 'Proton': $i).
% 29.32/29.12  tff(decl_64217, type, 'An electrically positive particle found in the nucleus of atoms. Protons carry a charge of +1.': $i).
% 29.32/29.12  tff(decl_64218, type, proton: $i).
% 29.32/29.12  tff(decl_64219, type, fn_proton_2: $i > $i).
% 29.32/29.12  tff(decl_64220, type, fn_proton_3: $i > $i).
% 29.32/29.12  tff(decl_64221, type, 'Proton-Motive-Force': $i).
% 29.32/29.12  tff(decl_64222, type, 'Energy that is generated by the transfer of protons or electrons across an energy-transducing membrane and that can be used for chemical, osmotic, or mechanical work. Proton-motive force can be generated by a variety of phenomena including the operation of an electron transport chain, illumination of a purple membrane, and the hydrolysis of ATP by a proton atpase.': $i).
% 29.32/29.12  tff(decl_64223, type, pmf: $i).
% 29.32/29.12  tff(decl_64224, type, 'proton motive force': $i).
% 29.32/29.12  tff(decl_64225, type, 'proton-motive force': $i).
% 29.32/29.12  tff(decl_64226, type, 'proton-motive-force': $i).
% 29.32/29.12  tff(decl_64227, type, fn_proton_motive_force_1: $i > $i).
% 29.32/29.12  tff(decl_64228, type, 'Proton-Pump': $i).
% 29.32/29.12  tff(decl_64229, type, 'A proton pump is an integral membrane protein that is capable of moving protons across the membrane of a cell, mitochondrion, or other subcellular compartment.': $i).
% 29.32/29.12  tff(decl_64230, type, 'proton pump': $i).
% 29.32/29.12  tff(decl_64231, type, 'proton-pump': $i).
% 29.32/29.12  tff(decl_64232, type, fn_proton_pump_1: $i > $i).
% 29.32/29.12  tff(decl_64233, type, fn_proton_pump_2: $i > $i).
% 29.32/29.12  tff(decl_64234, type, fn_proton_pump_3: $i > $i).
% 29.32/29.12  tff(decl_64235, type, fn_proton_pump_4: $i > $i).
% 29.32/29.12  tff(decl_64236, type, fn_proton_pump_5: $i > $i).
% 29.32/29.12  tff(decl_64237, type, fn_proton_pump_6: $i > $i).
% 29.32/29.12  tff(decl_64238, type, fn_proton_pump_7: $i > $i).
% 29.32/29.12  tff(decl_64239, type, fn_proton_pump_8: $i > $i).
% 29.32/29.12  tff(decl_64240, type, fn_proton_pump_9: $i > $i).
% 29.32/29.12  tff(decl_64241, type, fn_proton_pump_10: $i > $i).
% 29.32/29.12  tff(decl_64242, type, fn_proton_pump_11: $i > $i).
% 29.32/29.12  tff(decl_64243, type, fn_proton_pump_14: $i > $i).
% 29.32/29.12  tff(decl_64244, type, fn_proton_pump_15: $i > $i).
% 29.32/29.12  tff(decl_64245, type, fn_proton_pump_16: $i > $i).
% 29.32/29.12  tff(decl_64246, type, fn_proton_pump_17: $i > $i).
% 29.32/29.12  tff(decl_64247, type, fn_proton_pump_19: $i > $i).
% 29.32/29.12  tff(decl_64248, type, fn_proton_pump_22: $i > $i).
% 29.32/29.12  tff(decl_64249, type, fn_proton_pump_23: $i > $i).
% 29.32/29.12  tff(decl_64250, type, fn_proton_pump_27: $i > $i).
% 29.32/29.12  tff(decl_64251, type, fn_proton_pump_28: $i > $i).
% 29.32/29.12  tff(decl_64252, type, fn_proton_pump_32: $i > $i).
% 29.32/29.12  tff(decl_64253, type, fn_proton_pump_33: $i > $i).
% 29.32/29.12  tff(decl_64254, type, fn_proton_pump_34: $i > $i).
% 29.32/29.12  tff(decl_64255, type, fn_proton_pump_35: $i > $i).
% 29.32/29.12  tff(decl_64256, type, fn_proton_pump_37: $i > $i).
% 29.32/29.12  tff(decl_64257, type, fn_proton_pump_38: $i > $i).
% 29.32/29.12  tff(decl_64258, type, fn_proton_pump_39: $i > $i).
% 29.32/29.12  tff(decl_64259, type, fn_proton_pump_40: $i > $i).
% 29.32/29.12  tff(decl_64260, type, fn_proton_pump_41: $i > $i).
% 29.32/29.12  tff(decl_64261, type, fn_proton_pump_44: $i > $i).
% 29.32/29.12  tff(decl_64262, type, fn_proton_pump_45: $i > $i).
% 29.32/29.12  tff(decl_64263, type, fn_proton_pump_46: $i > $i).
% 29.32/29.12  tff(decl_64264, type, fn_proton_pump_47: $i > $i).
% 29.32/29.12  tff(decl_64265, type, fn_proton_pump_48: $i > $i).
% 29.32/29.12  tff(decl_64266, type, fn_proton_pump_49: $i > $i).
% 29.32/29.12  tff(decl_64267, type, fn_proton_pump_50: $i > $i).
% 29.32/29.12  tff(decl_64268, type, fn_proton_pump_51: $i > $i).
% 29.32/29.12  tff(decl_64269, type, fn_proton_pump_52: $i > $i).
% 29.32/29.12  tff(decl_64270, type, fn_proton_pump_55: $i > $i).
% 29.32/29.12  tff(decl_64271, type, fn_proton_pump_57: $i > $i).
% 29.32/29.12  tff(decl_64272, type, fn_proton_pump_58: $i > $i).
% 29.32/29.12  tff(decl_64273, type, fn_proton_pump_60: $i > $i).
% 29.32/29.12  tff(decl_64274, type, fn_proton_pump_61: $i > $i).
% 29.32/29.12  tff(decl_64275, type, fn_proton_pump_62: $i > $i).
% 29.32/29.12  tff(decl_64276, type, fn_proton_pump_63: $i > $i).
% 29.32/29.12  tff(decl_64277, type, fn_proton_pump_65: $i > $i).
% 29.32/29.12  tff(decl_64278, type, fn_proton_pump_67: $i > $i).
% 29.32/29.12  tff(decl_64279, type, fn_proton_pump_69: $i > $i).
% 29.32/29.12  tff(decl_64280, type, fn_proton_pump_70: $i > $i).
% 29.32/29.12  tff(decl_64281, type, fn_proton_pump_71: $i > $i).
% 29.32/29.12  tff(decl_64282, type, fn_proton_pump_72: $i > $i).
% 29.32/29.12  tff(decl_64283, type, fn_proton_pump_73: $i > $i).
% 29.32/29.12  tff(decl_64284, type, fn_proton_pump_74: $i > $i).
% 29.32/29.12  tff(decl_64285, type, fn_proton_pump_75: $i > $i).
% 29.32/29.12  tff(decl_64286, type, fn_proton_pump_77: $i > $i).
% 29.32/29.12  tff(decl_64287, type, fn_proton_pump_78: $i > $i).
% 29.32/29.12  tff(decl_64288, type, fn_proton_pump_30: $i > $i).
% 29.32/29.12  tff(decl_64289, type, fn_proton_pump_31: $i > $i).
% 29.32/29.12  tff(decl_64290, type, 'Protonema': $i).
% 29.32/29.12  tff(decl_64291, type, 'In mosses, a filamentous mass of haploid cells produced by germinating spores.': $i).
% 29.32/29.12  tff(decl_64292, type, protonema: $i).
% 29.32/29.12  tff(decl_64293, type, protonephridium_1: $i > $o).
% 29.32/29.12  tff(decl_64294, type, 'Protonephridium': $i).
% 29.32/29.12  tff(decl_64295, type, 'An osmoregulatory organ found in the animal phyla Platyhelminthes and Rotifera, which consists of a network of blind-ended tubules and flame bulbs.': $i).
% 29.32/29.12  tff(decl_64296, type, 'flame bulb': $i).
% 29.32/29.12  tff(decl_64297, type, 'flame-bulb': $i).
% 29.32/29.12  tff(decl_64298, type, protonephridia: $i).
% 29.32/29.12  tff(decl_64299, type, protonephridium: $i).
% 29.32/29.12  tff(decl_64300, type, 'Protoplast': $i).
% 29.32/29.12  tff(decl_64301, type, 'The living part of a walled cell, which also includes the plasma membrane.': $i).
% 29.32/29.12  tff(decl_64302, type, protoplast: $i).
% 29.32/29.12  tff(decl_64303, type, protoplast_fusion_1: $i > $o).
% 29.32/29.12  tff(decl_64304, type, 'Protoplast-Fusion': $i).
% 29.32/29.12  tff(decl_64305, type, 'A method of hybridizing otherwise incompatible plants by fusing their protoplasts. The resulting hybrid offspring has the characteristics of both parent species.': $i).
% 29.32/29.12  tff(decl_64306, type, 'fusion of protoplast': $i).
% 29.32/29.12  tff(decl_64307, type, 'protoplast fusion': $i).
% 29.32/29.12  tff(decl_64308, type, 'protoplast-fusion': $i).
% 29.32/29.12  tff(decl_64309, type, 'Protostome-Development': $i).
% 29.32/29.12  tff(decl_64310, type, 'A developmental mode in animals in which the blastopore develops into the mouth; often associated with formation of the coelom by schizocoely, a process in which solid blocks of mesodermal tissue split to form hollow cavities. Annelids, molluscs, and arthropods have protostomous development.': $i).
% 29.32/29.12  tff(decl_64311, type, 'protostome development': $i).
% 29.32/29.12  tff(decl_64312, type, 'protostome-development': $i).
% 29.32/29.12  tff(decl_64313, type, 'Protozoan-Disease': $i).
% 29.32/29.12  tff(decl_64314, type, 'Abnormal condition in an organism, caused by infection with protozoa.': $i).
% 29.32/29.12  tff(decl_64315, type, 'disease of protozoan': $i).
% 29.32/29.12  tff(decl_64316, type, 'protozoan disease': $i).
% 29.32/29.12  tff(decl_64317, type, 'protozoan-disease': $i).
% 29.32/29.12  tff(decl_64318, type, 'Province': $i).
% 29.32/29.12  tff(decl_64319, type, provirus_1: $i > $o).
% 29.32/29.12  tff(decl_64320, type, 'Provirus': $i).
% 29.32/29.12  tff(decl_64321, type, 'A viral genome that is permanently inserted into a host genome.': $i).
% 29.32/29.12  tff(decl_64322, type, provirus: $i).
% 29.32/29.12  tff(decl_64323, type, fn_provirus_1: $i > $i).
% 29.32/29.12  tff(decl_64324, type, fn_provirus_2: $i > $i).
% 29.32/29.12  tff(decl_64325, type, fn_provirus_3: $i > $i).
% 29.32/29.12  tff(decl_64326, type, fn_provirus_4: $i > $i).
% 29.32/29.12  tff(decl_64327, type, fn_provirus_5: $i > $i).
% 29.32/29.12  tff(decl_64328, type, 'Proximal': $i).
% 29.32/29.12  tff(decl_64329, type, 'Region of appendages towards the trunk or core of the body.  Opposite of distal.': $i).
% 29.32/29.12  tff(decl_64330, type, proximal: $i).
% 29.32/29.12  tff(decl_64331, type, 'Proximal-Control-Element': $i).
% 29.32/29.12  tff(decl_64332, type, 'A control element on the DNA that is close to the promoter.': $i).
% 29.32/29.12  tff(decl_64333, type, 'proximal control element': $i).
% 29.32/29.12  tff(decl_64334, type, 'proximal-control-element': $i).
% 29.32/29.12  tff(decl_64335, type, fn_proximal_control_element_1: $i > $i).
% 29.32/29.12  tff(decl_64336, type, fn_proximal_control_element_2: $i > $i).
% 29.32/29.12  tff(decl_64337, type, 'Proximal-Tubule': $i).
% 29.32/29.12  tff(decl_64338, type, 'The part of a nephron that leads from the Bowman\\s capsule to the loop of Henle.': $i).
% 29.32/29.12  tff(decl_64339, type, 'tubule of proximal': $i).
% 29.32/29.12  tff(decl_64340, type, 'proximal tubule': $i).
% 29.32/29.12  tff(decl_64341, type, 'proximal-tubule': $i).
% 29.32/29.12  tff(decl_64342, type, 'Proximate-Causation': $i).
% 29.32/29.12  tff(decl_64343, type, 'Causes of behavior that are mechanistic in nature and concerned with environmental stimuli, as well as the underlying genetic and physiological mechanisms for a particular behavior.': $i).
% 29.32/29.12  tff(decl_64344, type, 'proximate causation': $i).
% 29.32/29.12  tff(decl_64345, type, 'proximate-causation': $i).
% 29.32/29.12  tff(decl_64346, type, pruning_1: $i > $o).
% 29.32/29.12  tff(decl_64347, type, 'Pruning': $i).
% 29.32/29.12  tff(decl_64348, type, 'The process of selectively removing parts of plants in order to control growth and increase fruit size.': $i).
% 29.32/29.12  tff(decl_64349, type, prune: $i).
% 29.32/29.12  tff(decl_64350, type, pruning: $i).
% 29.32/29.12  tff(decl_64351, type, 'Pseudogene': $i).
% 29.32/29.12  tff(decl_64352, type, 'A DNA segment very similar to a real gene but which does not yield a functional product; a DNA segment that formerly functioned as a gene but has become inactivated in a particular species because of mutation.': $i).
% 29.32/29.12  tff(decl_64353, type, pseudogene: $i).
% 29.32/29.12  tff(decl_64354, type, fn_pseudogene_1: $i > $i).
% 29.32/29.12  tff(decl_64355, type, fn_pseudogene_4: $i > $i).
% 29.32/29.12  tff(decl_64356, type, fn_pseudogene_5: $i > $i).
% 29.32/29.12  tff(decl_64357, type, fn_pseudogene_6: $i > $i).
% 29.32/29.12  tff(decl_64358, type, fn_pseudogene_7: $i > $i).
% 29.32/29.12  tff(decl_64359, type, fn_pseudogene_8: $i > $i).
% 29.32/29.12  tff(decl_64360, type, fn_pseudogene_9: $i > $i).
% 29.32/29.12  tff(decl_64361, type, fn_pseudogene_10: $i > $i).
% 29.32/29.12  tff(decl_64362, type, fn_pseudogene_11: $i > $i).
% 29.32/29.12  tff(decl_64363, type, fn_pseudogene_13: $i > $i).
% 29.32/29.12  tff(decl_64364, type, fn_pseudogene_14: $i > $i).
% 29.32/29.12  tff(decl_64365, type, fn_pseudogene_15: $i > $i).
% 29.32/29.12  tff(decl_64366, type, fn_pseudogene_16: $i > $i).
% 29.32/29.12  tff(decl_64367, type, fn_pseudogene_17: $i > $i).
% 29.32/29.12  tff(decl_64368, type, fn_pseudogene_18: $i > $i).
% 29.32/29.12  tff(decl_64369, type, fn_pseudogene_19: $i > $i).
% 29.32/29.12  tff(decl_64370, type, fn_pseudogene_20: $i > $i).
% 29.32/29.12  tff(decl_64371, type, fn_pseudogene_21: $i > $i).
% 29.32/29.12  tff(decl_64372, type, fn_pseudogene_22: $i > $i).
% 29.32/29.12  tff(decl_64373, type, fn_pseudogene_23: $i > $i).
% 29.32/29.12  tff(decl_64374, type, fn_pseudogene_24: $i > $i).
% 29.32/29.12  tff(decl_64375, type, fn_pseudogene_25: $i > $i).
% 29.32/29.12  tff(decl_64376, type, fn_pseudogene_26: $i > $i).
% 29.32/29.12  tff(decl_64377, type, fn_pseudogene_27: $i > $i).
% 29.32/29.12  tff(decl_64378, type, fn_pseudogene_28: $i > $i).
% 29.32/29.12  tff(decl_64379, type, fn_pseudogene_33: $i > $i).
% 29.32/29.12  tff(decl_64380, type, fn_pseudogene_34: $i > $i).
% 29.32/29.12  tff(decl_64381, type, fn_repeated_gene_duplication_1: $i > $i).
% 29.32/29.12  tff(decl_64382, type, fn_pseudogene_32: $i > $i).
% 29.32/29.12  tff(decl_64383, type, fn_pseudogene_31: $i > $i).
% 29.32/29.12  tff(decl_64384, type, fn_pseudogene_29: $i > $i).
% 29.32/29.12  tff(decl_64385, type, fn_pseudogene_30: $i > $i).
% 29.32/29.12  tff(decl_64386, type, fn_pseudogene_3: $i > $i).
% 29.32/29.12  tff(decl_64387, type, fn_pseudogene_2: $i > $i).
% 29.32/29.12  tff(decl_64388, type, fn_pseudogene_12: $i > $i).
% 29.32/29.12  tff(decl_64389, type, 'Pseudopodium': $i).
% 29.32/29.12  tff(decl_64390, type, 'A temporary extension of cytoplasm, used by amoebae and other amoeboid cells for feeding and locomotion.': $i).
% 29.32/29.12  tff(decl_64391, type, pseudopodia: $i).
% 29.32/29.12  tff(decl_64392, type, pseudopodium: $i).
% 29.32/29.12  tff(decl_64393, type, psychotic_1: $i > $o).
% 29.32/29.12  tff(decl_64394, type, 'Psychotic': $i).
% 29.32/29.12  tff(decl_64395, type, 'Characterized by abnormal thinking and a loss of reality; experiencing hallucinations, delusions, and distorted perceptions.': $i).
% 29.32/29.12  tff(decl_64396, type, psychotic: $i).
% 29.32/29.12  tff(decl_64397, type, 'Pterophyte': $i).
% 29.32/29.12  tff(decl_64398, type, 'A plant of the phylum Pterophyta, such as ferns, horsetails, and whisk ferns.': $i).
% 29.32/29.12  tff(decl_64399, type, pterophyte: $i).
% 29.32/29.12  tff(decl_64400, type, 'Pterosaur': $i).
% 29.32/29.12  tff(decl_64401, type, 'A flying reptile that lived from the late Triassic to the end of the Cretaceous.': $i).
% 29.32/29.12  tff(decl_64402, type, pterosaur: $i).
% 29.32/29.12  tff(decl_64403, type, pull_1: $i > $o).
% 29.32/29.12  tff(decl_64404, type, 'Pull': $i).
% 29.32/29.12  tff(decl_64405, type, 'The act of exerting force on an object towards the agent.': $i).
% 29.32/29.12  tff(decl_64406, type, pull: $i).
% 29.32/29.12  tff(decl_64407, type, fn_pull_1: $i > $i).
% 29.32/29.12  tff(decl_64408, type, fn_pull_2: $i > $i).
% 29.32/29.12  tff(decl_64409, type, fn_pull_3: $i > $i).
% 29.32/29.12  tff(decl_64410, type, pulmocutaneous_circuit_1: $i > $o).
% 29.32/29.12  tff(decl_64411, type, 'Pulmocutaneous-Circuit': $i).
% 29.32/29.12  tff(decl_64412, type, 'In amphibians, a branch of the circulatory system that directs blood to the lungs and skin.': $i).
% 29.32/29.12  tff(decl_64413, type, 'pulmocutaneous circuit': $i).
% 29.32/29.12  tff(decl_64414, type, 'pulmocutaneous-circuit': $i).
% 29.32/29.12  tff(decl_64415, type, pulmonary_artery_1: $i > $o).
% 29.32/29.12  tff(decl_64416, type, 'Pulmonary-Artery': $i).
% 29.32/29.12  tff(decl_64417, type, 'A blood vessel that carries deoxygenated blood away from the heart towards the lungs.': $i).
% 29.32/29.12  tff(decl_64418, type, 'pulmonary artery': $i).
% 29.32/29.12  tff(decl_64419, type, 'pulmonary-artery': $i).
% 29.32/29.12  tff(decl_64420, type, pulmonary_circuit_1: $i > $o).
% 29.32/29.12  tff(decl_64421, type, 'Pulmonary-Circuit': $i).
% 29.32/29.12  tff(decl_64422, type, 'The branch of the circulatory system that sends blood to the lungs to be oxygenated.': $i).
% 29.32/29.12  tff(decl_64423, type, 'pulmonary circuit': $i).
% 29.32/29.12  tff(decl_64424, type, 'pulmonary-circuit': $i).
% 29.32/29.12  tff(decl_64425, type, pulmonary_vein_1: $i > $o).
% 29.32/29.12  tff(decl_64426, type, 'Pulmonary-Vein': $i).
% 29.32/29.12  tff(decl_64427, type, 'A blood vessel that carries oxygenated blood from the lungs towards the heart.': $i).
% 29.32/29.12  tff(decl_64428, type, 'pulmonary vein': $i).
% 29.32/29.12  tff(decl_64429, type, 'pulmonary-vein': $i).
% 29.32/29.12  tff(decl_64430, type, vein_1: $i > $o).
% 29.32/29.12  tff(decl_64431, type, renal_vein_1: $i > $o).
% 29.32/29.12  tff(decl_64432, type, venule_1: $i > $o).
% 29.32/29.12  tff(decl_64433, type, 'Pulse': $i).
% 29.32/29.12  tff(decl_64434, type, 'A pressure wave produced when the heart contracts and sends blood through the arteries. It can be felt via palpation in several places on the body as an expansion of artery walls.': $i).
% 29.32/29.12  tff(decl_64435, type, pulvinus_1: $i > $o).
% 29.32/29.12  tff(decl_64436, type, 'Pulvinus': $i).
% 29.32/29.12  tff(decl_64437, type, 'In plants, a thickened area at the base of a leaf. It facilitates a plant\\s growth-independent movements.': $i).
% 29.32/29.12  tff(decl_64438, type, pulvina: $i).
% 29.32/29.12  tff(decl_64439, type, pulvinus: $i).
% 29.32/29.12  tff(decl_64440, type, 'Punctuated-Equilibria': $i).
% 29.32/29.12  tff(decl_64441, type, 'A phenomenon observed in the fossil record, in which there appear to be long periods of morphological stasis interrupted by comparatively brief periods of rapid morphological change.': $i).
% 29.32/29.12  tff(decl_64442, type, 'punctuated equilibrium': $i).
% 29.32/29.12  tff(decl_64443, type, 'punctuated-equilibrium': $i).
% 29.32/29.12  tff(decl_64444, type, 'punctuated-equilibria': $i).
% 29.32/29.12  tff(decl_64445, type, 'Punnett-Square': $i).
% 29.32/29.12  tff(decl_64446, type, 'A diagram used in the study of inheritance to show the predicted results of random fertilization in genetic crosses.': $i).
% 29.32/29.12  tff(decl_64447, type, 'punnett square': $i).
% 29.32/29.12  tff(decl_64448, type, 'punnett-square': $i).
% 29.32/29.12  tff(decl_64449, type, fn_punnett_square_1: $i > $i).
% 29.32/29.12  tff(decl_64450, type, fn_punnett_square_2: $i > $i).
% 29.32/29.12  tff(decl_64451, type, random_fertilization_1: $i > $o).
% 29.32/29.12  tff(decl_64452, type, fn_punnett_square_3: $i > $i).
% 29.32/29.12  tff(decl_64453, type, fn_punnett_square_4: $i > $i).
% 29.32/29.12  tff(decl_64454, type, fn_punnett_square_5: $i > $i).
% 29.32/29.12  tff(decl_64455, type, fn_punnett_square_6: $i > $i).
% 29.32/29.12  tff(decl_64456, type, fn_punnett_square_7: $i > $i).
% 29.32/29.12  tff(decl_64457, type, 'Pupa': $i).
% 29.32/29.12  tff(decl_64458, type, 'A pupa is the life stage of some insects undergoing transformation. The pupal stage is found only in holometabolous insects, those that undergo a complete metamorphosis, going through four life stages; embryo, larva, pupa and imago.': $i).
% 29.32/29.12  tff(decl_64459, type, pupae: $i).
% 29.32/29.12  tff(decl_64460, type, pupa: $i).
% 29.32/29.12  tff(decl_64461, type, 'Pupal-Case': $i).
% 29.32/29.12  tff(decl_64462, type, 'A covering of the Pupa of an organism is called as pupal case.': $i).
% 29.32/29.12  tff(decl_64463, type, 'pupal case': $i).
% 29.32/29.12  tff(decl_64464, type, 'pupal-case': $i).
% 29.32/29.12  tff(decl_64465, type, pupil_1: $i > $o).
% 29.32/29.12  tff(decl_64466, type, 'Pupil': $i).
% 29.32/29.12  tff(decl_64467, type, pupil: $i).
% 29.32/29.12  tff(decl_64468, type, student: $i).
% 29.32/29.12  tff(decl_64469, type, educatee: $i).
% 29.32/29.12  tff(decl_64470, type, schoolchild: $i).
% 29.32/29.12  tff(decl_64471, type, 'school age child': $i).
% 29.32/29.12  tff(decl_64472, type, 'school-age_child': $i).
% 29.32/29.12  tff(decl_64473, type, fn_pupil_1: $i > $i).
% 29.32/29.12  tff(decl_64474, type, 'Pupil-Of-An-Eye': $i).
% 29.32/29.12  tff(decl_64475, type, 'An opening in the iris of an eye, which allows light to enter the eye. The size of the pupil, and thus the amount of light that enters the eye, is controlled by the iris.': $i).
% 29.32/29.12  tff(decl_64476, type, 'pupil of an eye': $i).
% 29.32/29.12  tff(decl_64477, type, 'pupil-of-an-eye': $i).
% 29.32/29.12  tff(decl_64478, type, 'Purine': $i).
% 29.32/29.12  tff(decl_64479, type, 'Purine base is a heterocyclic aromatic organic compound, consisting of a pyrimidine ring fused to an imidazole ring. In DNA the purine bases present are Adenine and Guanine': $i).
% 29.32/29.12  tff(decl_64480, type, purine: $i).
% 29.32/29.12  tff(decl_64481, type, fn_purine_2: $i > $i).
% 29.32/29.12  tff(decl_64482, type, 'Purple': $i).
% 29.32/29.12  tff(decl_64483, type, 'Any color composed of some amount of red and blue.': $i).
% 29.32/29.12  tff(decl_64484, type, purple: $i).
% 29.32/29.12  tff(decl_64485, type, 'Push': $i).
% 29.32/29.12  tff(decl_64486, type, 'The act of exerting force on an object away from the agent.': $i).
% 29.32/29.12  tff(decl_64487, type, push: $i).
% 29.32/29.12  tff(decl_64488, type, fn_push_1: $i > $i).
% 29.32/29.12  tff(decl_64489, type, 'Pyloric-Sphincter': $i).
% 29.32/29.12  tff(decl_64490, type, 'A strong muscular opening at the distal end of the stomach that regulates the passage of food from the stomach into the duodenum.': $i).
% 29.32/29.12  tff(decl_64491, type, 'pyloric sphincter': $i).
% 29.32/29.12  tff(decl_64492, type, 'pyloric-sphincter': $i).
% 29.32/29.12  tff(decl_64493, type, 'Pyramid-Of-Numbers': $i).
% 29.32/29.12  tff(decl_64494, type, 'A diagram that shows the numbers of individual organisms in every trophic level in an ecosystem.': $i).
% 29.32/29.12  tff(decl_64495, type, 'numbers pyramid': $i).
% 29.32/29.12  tff(decl_64496, type, 'numbers-pyramid': $i).
% 29.32/29.12  tff(decl_64497, type, 'pyramid of numbers': $i).
% 29.32/29.12  tff(decl_64498, type, 'pyramid-of-number': $i).
% 29.32/29.12  tff(decl_64499, type, 'Pyramid-Of-Production': $i).
% 29.32/29.12  tff(decl_64500, type, 'A diagram that shows the magnitude of energy loss at every level in an ecosystem.': $i).
% 29.32/29.12  tff(decl_64501, type, 'production pyramid': $i).
% 29.32/29.12  tff(decl_64502, type, 'production-pyramid': $i).
% 29.32/29.12  tff(decl_64503, type, 'pyramid of production': $i).
% 29.32/29.12  tff(decl_64504, type, 'pyramid-of-production': $i).
% 29.32/29.12  tff(decl_64505, type, 'Pyrimidine': $i).
% 29.32/29.12  tff(decl_64506, type, 'Pyrimidine is a heterocyclic aromatic organic compound similar to benzene and pyridine, containing two nitrogen atoms at positions 1 and 3 of the six-member ring. Pyrimidines present in DNA are thymine and cytosine': $i).
% 29.32/29.12  tff(decl_64507, type, pyrimidine: $i).
% 29.32/29.12  tff(decl_64508, type, 'Pyrophosphate': $i).
% 29.32/29.12  tff(decl_64509, type, 'A salt or ester containing two phosphate groups is called a diphosphate. The anion, the salts, and the esters of pyrophosphoric acid are diphosphates that are known as pyrophosphates.': $i).
% 29.32/29.12  tff(decl_64510, type, pyrophosphate: $i).
% 29.32/29.12  tff(decl_64511, type, fn_pyrophosphate_3: $i > $i).
% 29.32/29.12  tff(decl_64512, type, fn_pyrophosphate_4: $i > $i).
% 29.32/29.12  tff(decl_64513, type, fn_pyrophosphate_5: $i > $i).
% 29.32/29.12  tff(decl_64514, type, fn_pyrophosphate_6: $i > $i).
% 29.32/29.12  tff(decl_64515, type, fn_pyrophosphate_7: $i > $i).
% 29.32/29.12  tff(decl_64516, type, fn_pyrophosphate_8: $i > $i).
% 29.32/29.12  tff(decl_64517, type, fn_pyrophosphate_2: $i > $i).
% 29.32/29.12  tff(decl_64518, type, fn_pyrophosphate_1: $i > $i).
% 29.32/29.12  tff(decl_64519, type, 'Pyruvate': $i).
% 29.32/29.12  tff(decl_64520, type, 'Pyruvate is the end product of glycolysis, which is converted into acetyl coA that enters the Krebs cycle when there is sufficient oxygen available. When the oxygen is insufficient, pyruvate is broken down anaerobically, creating lactate in animals (including humans) and ethanol in plants.': $i).
% 29.32/29.12  tff(decl_64521, type, pyruvate: $i).
% 29.32/29.12  tff(decl_64522, type, fn_pyruvate_1: $i > $i).
% 29.32/29.12  tff(decl_64523, type, fn_pyruvate_2: $i > $i).
% 29.32/29.12  tff(decl_64524, type, fn_pyruvate_3: $i > $i).
% 29.32/29.12  tff(decl_64525, type, fn_pyruvate_4: $i > $i).
% 29.32/29.12  tff(decl_64526, type, fn_pyruvate_5: $i > $i).
% 29.32/29.12  tff(decl_64527, type, fn_pyruvate_6: $i > $i).
% 29.32/29.12  tff(decl_64528, type, fn_pyruvate_7: $i > $i).
% 29.32/29.12  tff(decl_64529, type, fn_pyruvate_8: $i > $i).
% 29.32/29.12  tff(decl_64530, type, fn_pyruvate_9: $i > $i).
% 29.32/29.12  tff(decl_64531, type, fn_pyruvate_11: $i > $i).
% 29.32/29.12  tff(decl_64532, type, fn_pyruvate_12: $i > $i).
% 29.32/29.12  tff(decl_64533, type, fn_pyruvate_13: $i > $i).
% 29.32/29.12  tff(decl_64534, type, fn_pyruvate_14: $i > $i).
% 29.32/29.12  tff(decl_64535, type, fn_pyruvate_15: $i > $i).
% 29.32/29.12  tff(decl_64536, type, fn_pyruvate_17: $i > $i).
% 29.32/29.12  tff(decl_64537, type, fn_pyruvate_16: $i > $i).
% 29.32/29.12  tff(decl_64538, type, fn_pyruvate_10: $i > $i).
% 29.32/29.12  tff(decl_64539, type, 'Pyruvate-Kinase': $i).
% 29.32/29.12  tff(decl_64540, type, 'The enzyme pyruvate kinase transfers a P from PEP to ADP to form pyruvic acid and ATP. This happens for each molecule of PEP. This reaction yields 2 molecules of pyruvic acid and 2 ATP molecules.': $i).
% 29.32/29.12  tff(decl_64541, type, 'kinase of pyruvate': $i).
% 29.32/29.12  tff(decl_64542, type, 'pyruvate kinase': $i).
% 29.32/29.12  tff(decl_64543, type, 'pyruvate-kinase': $i).
% 29.32/29.12  tff(decl_64544, type, fn_pyruvate_kinase_1: $i > $i).
% 29.32/29.12  tff(decl_64545, type, fn_pyruvate_kinase_2: $i > $i).
% 29.32/29.12  tff(decl_64546, type, fn_pyruvate_kinase_3: $i > $i).
% 29.32/29.12  tff(decl_64547, type, fn_pyruvate_kinase_4: $i > $i).
% 29.32/29.12  tff(decl_64548, type, fn_pyruvate_kinase_5: $i > $i).
% 29.32/29.12  tff(decl_64549, type, fn_pyruvate_kinase_6: $i > $i).
% 29.32/29.12  tff(decl_64550, type, fn_pyruvate_kinase_7: $i > $i).
% 29.32/29.12  tff(decl_64551, type, fn_pyruvate_kinase_8: $i > $i).
% 29.32/29.12  tff(decl_64552, type, fn_pyruvate_kinase_10: $i > $i).
% 29.32/29.12  tff(decl_64553, type, fn_pyruvate_kinase_11: $i > $i).
% 29.32/29.12  tff(decl_64554, type, fn_pyruvate_kinase_12: $i > $i).
% 29.32/29.12  tff(decl_64555, type, fn_pyruvate_kinase_13: $i > $i).
% 29.32/29.12  tff(decl_64556, type, fn_pyruvate_kinase_14: $i > $i).
% 29.32/29.12  tff(decl_64557, type, fn_pyruvate_kinase_15: $i > $i).
% 29.32/29.12  tff(decl_64558, type, fn_pyruvate_kinase_16: $i > $i).
% 29.32/29.12  tff(decl_64559, type, fn_pyruvate_kinase_17: $i > $i).
% 29.32/29.12  tff(decl_64560, type, fn_pyruvate_kinase_18: $i > $i).
% 29.32/29.12  tff(decl_64561, type, fn_pyruvate_kinase_19: $i > $i).
% 29.32/29.12  tff(decl_64562, type, fn_pyruvate_kinase_20: $i > $i).
% 29.32/29.12  tff(decl_64563, type, 'Pyruvate-Oxidation': $i).
% 29.32/29.12  tff(decl_64564, type, 'A step in the process of cellular respiration where pyruvate, formed during glycolysis, enters the mitochondria and is oxidized to a compound called acetyl CoA which enters the citric acid cycle.': $i).
% 29.32/29.12  tff(decl_64565, type, 'conversion of pyruvate to acetyl coenzyme a': $i).
% 29.32/29.12  tff(decl_64566, type, 'conversion-of-pyruvate-to-acetyl-coenzyme-a': $i).
% 29.32/29.12  tff(decl_64567, type, 'oxidation of pyruvate': $i).
% 29.32/29.12  tff(decl_64568, type, 'pyruvate oxidation': $i).
% 29.32/29.12  tff(decl_64569, type, 'pyruvate-oxidation': $i).
% 29.32/29.12  tff(decl_64570, type, fn_pyruvate_oxidation_6: $i > $i).
% 29.32/29.12  tff(decl_64571, type, fn_pyruvate_oxidation_9: $i > $i).
% 29.32/29.12  tff(decl_64572, type, fn_pyruvate_oxidation_16: $i > $i).
% 29.32/29.12  tff(decl_64573, type, fn_pyruvate_oxidation_17: $i > $i).
% 29.32/29.12  tff(decl_64574, type, fn_pyruvate_oxidation_18: $i > $i).
% 29.32/29.12  tff(decl_64575, type, fn_pyruvate_oxidation_26: $i > $i).
% 29.32/29.12  tff(decl_64576, type, fn_pyruvate_oxidation_42: $i > $i).
% 29.32/29.12  tff(decl_64577, type, fn_pyruvate_oxidation_43: $i > $i).
% 29.32/29.12  tff(decl_64578, type, fn_pyruvate_oxidation_44: $i > $i).
% 29.32/29.12  tff(decl_64579, type, fn_pyruvate_oxidation_45: $i > $i).
% 29.32/29.12  tff(decl_64580, type, fn_pyruvate_oxidation_46: $i > $i).
% 29.32/29.12  tff(decl_64581, type, fn_pyruvate_oxidation_51: $i > $i).
% 29.32/29.12  tff(decl_64582, type, fn_pyruvate_oxidation_53: $i > $i).
% 29.32/29.12  tff(decl_64583, type, fn_pyruvate_oxidation_55: $i > $i).
% 29.32/29.12  tff(decl_64584, type, fn_pyruvate_oxidation_56: $i > $i).
% 29.32/29.12  tff(decl_64585, type, fn_pyruvate_oxidation_68: $i > $i).
% 29.32/29.12  tff(decl_64586, type, fn_pyruvate_oxidation_69: $i > $i).
% 29.32/29.12  tff(decl_64587, type, fn_pyruvate_oxidation_70: $i > $i).
% 29.32/29.12  tff(decl_64588, type, fn_pyruvate_oxidation_71: $i > $i).
% 29.32/29.12  tff(decl_64589, type, fn_pyruvate_oxidation_72: $i > $i).
% 29.32/29.12  tff(decl_64590, type, fn_pyruvate_oxidation_73: $i > $i).
% 29.32/29.12  tff(decl_64591, type, fn_pyruvate_oxidation_75: $i > $i).
% 29.32/29.12  tff(decl_64592, type, fn_pyruvate_oxidation_76: $i > $i).
% 29.32/29.12  tff(decl_64593, type, fn_pyruvate_oxidation_80: $i > $i).
% 29.32/29.12  tff(decl_64594, type, fn_pyruvate_oxidation_83: $i > $i).
% 29.32/29.12  tff(decl_64595, type, fn_pyruvate_oxidation_12: $i > $i).
% 29.32/29.12  tff(decl_64596, type, fn_pyruvate_oxidation_40: $i > $i).
% 29.32/29.12  tff(decl_64597, type, fn_pyruvate_oxidation_39: $i > $i).
% 29.32/29.12  tff(decl_64598, type, fn_pyruvate_oxidation_48: $i > $i).
% 29.32/29.12  tff(decl_64599, type, fn_pyruvate_oxidation_49: $i > $i).
% 29.32/29.12  tff(decl_64600, type, 'Pyruvic-Acid': $i).
% 29.32/29.12  tff(decl_64601, type, 'Pyruvic acid is an organic acid and a ketone.  The ion of pyruvic acid is known as pyruvate, and is a key intersection in several metabolic pathways.': $i).
% 29.32/29.12  tff(decl_64602, type, 'pyruvic acid': $i).
% 29.32/29.12  tff(decl_64603, type, 'pyruvic-acid': $i).
% 29.32/29.12  tff(decl_64604, type, pyy_1: $i > $o).
% 29.32/29.12  tff(decl_64605, type, 'PYY': $i).
% 29.32/29.12  tff(decl_64606, type, 'A short polypeptide chain hormone which is released by the small intestine after eating and functions in the regulation of appetite.': $i).
% 29.32/29.12  tff(decl_64607, type, pyy: $i).
% 29.32/29.12  tff(decl_64608, type, fn_pyy_1: $i > $i).
% 29.32/29.12  tff(decl_64609, type, fn_pyy_2: $i > $i).
% 29.32/29.12  tff(decl_64610, type, fn_pyy_3: $i > $i).
% 29.32/29.12  tff(decl_64611, type, 'Quantity-Constant': $i).
% 29.32/29.12  tff(decl_64612, type, 'constant of quantity': $i).
% 29.32/29.12  tff(decl_64613, type, 'quantity constant': $i).
% 29.32/29.12  tff(decl_64614, type, 'quantity-constant': $i).
% 29.32/29.12  tff(decl_64615, type, 'Quantity-Value': $i).
% 29.32/29.12  tff(decl_64616, type, 'quantity is a property describing the amount of a Chemical': $i).
% 29.32/29.12  tff(decl_64617, type, amount: $i).
% 29.32/29.12  tff(decl_64618, type, quantity: $i).
% 29.32/29.12  tff(decl_64619, type, 'value of quantity': $i).
% 29.32/29.12  tff(decl_64620, type, 'quantity value': $i).
% 29.32/29.12  tff(decl_64621, type, 'quantity-value': $i).
% 29.32/29.12  tff(decl_64622, type, quarternary_protein_structure_1: $i > $o).
% 29.32/29.12  tff(decl_64623, type, 'Quarternary-Protein-Structure': $i).
% 29.32/29.12  tff(decl_64624, type, 'The fourth level of protein structure which consists of two or more polypeptide chains aggregated into one functional molecule.': $i).
% 29.32/29.12  tff(decl_64625, type, 'fourth stage of protein folding': $i).
% 29.32/29.12  tff(decl_64626, type, 'functional protein structure': $i).
% 29.32/29.12  tff(decl_64627, type, 'quarternary protein structure': $i).
% 29.32/29.12  tff(decl_64628, type, 'quarternary-protein-structure': $i).
% 29.32/29.12  tff(decl_64629, type, fn_quarternary_protein_structure_1: $i > $i).
% 29.32/29.12  tff(decl_64630, type, fn_quarternary_protein_structure_2: $i > $i).
% 29.32/29.12  tff(decl_64631, type, fn_quarternary_protein_structure_3: $i > $i).
% 29.32/29.12  tff(decl_64632, type, 'Question': $i).
% 29.32/29.12  tff(decl_64633, type, enquiry: $i).
% 29.32/29.12  tff(decl_64634, type, query: $i).
% 29.32/29.12  tff(decl_64635, type, interrogation: $i).
% 29.32/29.12  tff(decl_64636, type, 'interrogative sentence': $i).
% 29.32/29.12  tff(decl_64637, type, interrogative_sentence: $i).
% 29.32/29.12  tff(decl_64638, type, question: $i).
% 29.32/29.12  tff(decl_64639, type, 'Quorum-Sensing-In-Prokaryote': $i).
% 29.32/29.12  tff(decl_64640, type, 'In prokaryotes, a series of events, including regulation of gene expression, which results from cellular signals sent as a result of population density and contact with other prokaryotes.': $i).
% 29.32/29.12  tff(decl_64641, type, 'quorum sensing in prokaryote': $i).
% 29.32/29.12  tff(decl_64642, type, 'quorum-sensing-in-prokaryote': $i).
% 29.32/29.12  tff(decl_64643, type, fn_quorum_sensing_in_prokaryote_1: $i > $i).
% 29.32/29.12  tff(decl_64644, type, starving_cell_1: $i > $o).
% 29.32/29.12  tff(decl_64645, type, fn_quorum_sensing_in_prokaryote_2: $i > $i).
% 29.32/29.12  tff(decl_64646, type, fn_quorum_sensing_in_prokaryote_6: $i > $i).
% 29.32/29.12  tff(decl_64647, type, cell_communication_0: $i).
% 29.32/29.12  tff(decl_64648, type, r_albuterol_1: $i > $o).
% 29.32/29.12  tff(decl_64649, type, 'R-Albuterol': $i).
% 29.32/29.12  tff(decl_64650, type, 'R-Albuterol is the R-enantiomer of Ibuprofen.': $i).
% 29.32/29.12  tff(decl_64651, type, 'albuterol of r': $i).
% 29.32/29.12  tff(decl_64652, type, 'r albuterol': $i).
% 29.32/29.12  tff(decl_64653, type, 'r-albuterol': $i).
% 29.32/29.12  tff(decl_64654, type, 'R-Group': $i).
% 29.32/29.12  tff(decl_64655, type, 'R-Group is a variable group attached to the alpha carbon of Amino Acid. R group can be single Hydrogen or it may be a carbon skeleton with various functional groups attached.': $i).
% 29.32/29.12  tff(decl_64656, type, 'side chain': $i).
% 29.32/29.12  tff(decl_64657, type, 'group of r': $i).
% 29.32/29.12  tff(decl_64658, type, 'r group': $i).
% 29.32/29.12  tff(decl_64659, type, 'r-group': $i).
% 29.32/29.12  tff(decl_64660, type, r_ibuprofen_1: $i > $o).
% 29.32/29.12  tff(decl_64661, type, 'R-Ibuprofen': $i).
% 29.32/29.12  tff(decl_64662, type, 'Ibuprofen-R is the R-enantiomer of Ibuprofen.': $i).
% 29.32/29.12  tff(decl_64663, type, 'ibuprofen of r': $i).
% 29.32/29.12  tff(decl_64664, type, 'r ibuprofen': $i).
% 29.32/29.12  tff(decl_64665, type, 'r-ibuprofen': $i).
% 29.32/29.12  tff(decl_64666, type, 'R-Plasmid': $i).
% 29.32/29.12  tff(decl_64667, type, 'A bacterial plasmid carrying genes that confer resistance to certain antibiotics.': $i).
% 29.32/29.12  tff(decl_64668, type, 'plasmid of r': $i).
% 29.32/29.12  tff(decl_64669, type, 'r plasmid': $i).
% 29.32/29.12  tff(decl_64670, type, 'r-plasmid': $i).
% 29.32/29.12  tff(decl_64671, type, fn_r_plasmid_1: $i > $i).
% 29.32/29.12  tff(decl_64672, type, fn_r_plasmid_2: $i > $i).
% 29.32/29.12  tff(decl_64673, type, fn_r_plasmid_3: $i > $i).
% 29.32/29.12  tff(decl_64674, type, 'R-Selection': $i).
% 29.32/29.12  tff(decl_64675, type, 'Selection for life history traits that are favorable in low-density environments, such as high fecundity and early reproduction.': $i).
% 29.32/29.12  tff(decl_64676, type, 'selection of r': $i).
% 29.32/29.12  tff(decl_64677, type, 'r selection': $i).
% 29.32/29.12  tff(decl_64678, type, 'r-selection': $i).
% 29.32/29.12  tff(decl_64679, type, 'Radial-Cleavage': $i).
% 29.32/29.12  tff(decl_64680, type, 'A pattern of embryonic development in deuterostomes in which cleavage produces tiers of cells that are situated directly one above the other.': $i).
% 29.32/29.12  tff(decl_64681, type, 'cleavage of radial': $i).
% 29.32/29.12  tff(decl_64682, type, 'radial cleavage': $i).
% 29.32/29.12  tff(decl_64683, type, 'radial-cleavage': $i).
% 29.32/29.12  tff(decl_64684, type, 'Radial-Glia': $i).
% 29.32/29.12  tff(decl_64685, type, 'In an embryo, supporting cells that form tracks along which newly formed neurons migrate from the neural tube; can also act as stem cells that give rise to other glia and neurons.': $i).
% 29.32/29.12  tff(decl_64686, type, 'glia of radial': $i).
% 29.32/29.12  tff(decl_64687, type, 'radial glia': $i).
% 29.32/29.12  tff(decl_64688, type, 'radial-glia': $i).
% 29.32/29.12  tff(decl_64689, type, 'Radiata': $i).
% 29.32/29.12  tff(decl_64690, type, 'An animal clade that includes the radially symmetric animals of the Eumetazoa subkingdom.  Examples include the Cnidaria and the Ctenophora.': $i).
% 29.32/29.12  tff(decl_64691, type, radiata: $i).
% 29.32/29.12  tff(decl_64692, type, 'Radiation': $i).
% 29.32/29.12  tff(decl_64693, type, 'Radiation is the production of electromagnetic radiation whose energy varies inversely with wavelength. The different wavelengths of radiation are classified into categories that include visible light.': $i).
% 29.32/29.12  tff(decl_64694, type, radiation: $i).
% 29.32/29.12  tff(decl_64695, type, radiation_treatment_for_cancer_1: $i > $o).
% 29.32/29.12  tff(decl_64696, type, 'Radiation-Treatment-For-Cancer': $i).
% 29.32/29.12  tff(decl_64697, type, 'Treament used in some forms of cancer and other conditions which involves application of radioactive materials.': $i).
% 29.32/29.12  tff(decl_64698, type, 'radiation treatment for cancer': $i).
% 29.32/29.12  tff(decl_64699, type, 'radiation-treatment-for-cancer': $i).
% 29.32/29.12  tff(decl_64700, type, fn_radiation_treatment_for_cancer_3: $i > $i).
% 29.32/29.12  tff(decl_64701, type, fn_radiation_treatment_for_cancer_4: $i > $i).
% 29.32/29.12  tff(decl_64702, type, fn_radiation_treatment_for_cancer_5: $i > $i).
% 29.32/29.12  tff(decl_64703, type, fn_radiation_treatment_for_cancer_6: $i > $i).
% 29.32/29.12  tff(decl_64704, type, fn_radiation_treatment_for_cancer_7: $i > $i).
% 29.32/29.12  tff(decl_64705, type, fn_radiation_treatment_for_cancer_8: $i > $i).
% 29.32/29.12  tff(decl_64706, type, radical_model_1: $i > $o).
% 29.32/29.12  tff(decl_64707, type, 'Radical-Model': $i).
% 29.32/29.12  tff(decl_64708, type, 'It refers to a basic model.': $i).
% 29.32/29.12  tff(decl_64709, type, 'model of radical': $i).
% 29.32/29.12  tff(decl_64710, type, 'radical model': $i).
% 29.32/29.12  tff(decl_64711, type, 'radical-model': $i).
% 29.32/29.12  tff(decl_64712, type, 'Radicle': $i).
% 29.32/29.12  tff(decl_64713, type, 'The embryonic root of a plant and the first part to emerge from a seed during germination.': $i).
% 29.32/29.12  tff(decl_64714, type, radicle: $i).
% 29.32/29.12  tff(decl_64715, type, 'Radio-Waves': $i).
% 29.32/29.12  tff(decl_64716, type, 'Electromagnetic radiation with wavelength greater than 1 mm. Radio waves have the longest wavelength of all electromagnetic radiation.': $i).
% 29.32/29.12  tff(decl_64717, type, 'radio wave': $i).
% 29.32/29.12  tff(decl_64718, type, 'radio-wave': $i).
% 29.32/29.12  tff(decl_64719, type, fn_radio_waves_4: $i > $i).
% 29.32/29.12  tff(decl_64720, type, fn_radio_waves_5: $i > $i).
% 29.32/29.12  tff(decl_64721, type, fn_radio_waves_6: $i > $i).
% 29.32/29.12  tff(decl_64722, type, 'Radioactive-emissions': $i).
% 29.32/29.12  tff(decl_64723, type, 'Radioactive emissions are high energy radiations produced by radioactive entities': $i).
% 29.32/29.12  tff(decl_64724, type, 'radioactive emissions': $i).
% 29.32/29.12  tff(decl_64725, type, 'radioactive emission': $i).
% 29.32/29.12  tff(decl_64726, type, 'radioactive-emission': $i).
% 29.32/29.12  tff(decl_64727, type, fn_radioactive_emissions_1: $i > $i).
% 29.32/29.12  tff(decl_64728, type, fn_radioactive_emissions_2: $i > $i).
% 29.32/29.12  tff(decl_64729, type, fn_radioactive_emissions_3: $i > $i).
% 29.32/29.12  tff(decl_64730, type, 'Radioactive-Isotope': $i).
% 29.32/29.12  tff(decl_64731, type, 'An unstable isotope whose nucleus spontaneously decays and emits sub-nuclear particles and energy.': $i).
% 29.32/29.12  tff(decl_64732, type, 'radioactive isotope': $i).
% 29.32/29.12  tff(decl_64733, type, 'radioactive-isotope': $i).
% 29.32/29.12  tff(decl_64734, type, radioactive_probe_1: $i > $o).
% 29.32/29.12  tff(decl_64735, type, 'Radioactive-Probe': $i).
% 29.32/29.12  tff(decl_64736, type, 'A segment of single-stranded DNA that is radioactively labeled and complementary to the gene of interest when studying a particular gene.': $i).
% 29.32/29.12  tff(decl_64737, type, 'radioactive probe': $i).
% 29.32/29.12  tff(decl_64738, type, 'radioactive-probe': $i).
% 29.32/29.12  tff(decl_64739, type, 'Radioactive-Tracer': $i).
% 29.32/29.12  tff(decl_64740, type, 'A substance containing a radioactive isotope that is used to measure the speed of chemical processes and to track the movement of a substance through a natural system such as a cell or tissue.  Radioactive forms of hydrogen, carbon, phosphorus, sulfur, and iodine are commonly used in applications including biochemical assays, metabolism studies, and medical diagnostics.': $i).
% 29.32/29.12  tff(decl_64741, type, 'radioactive label': $i).
% 29.32/29.12  tff(decl_64742, type, 'radioactive-label': $i).
% 29.32/29.12  tff(decl_64743, type, 'radioactive tracer': $i).
% 29.32/29.12  tff(decl_64744, type, 'radioactive-tracer': $i).
% 29.32/29.12  tff(decl_64745, type, fn_radioactive_tracer_2: $i > $i).
% 29.32/29.12  tff(decl_64746, type, fn_radioactive_tracer_3: $i > $i).
% 29.32/29.12  tff(decl_64747, type, fn_radioactive_tracer_4: $i > $i).
% 29.32/29.12  tff(decl_64748, type, fn_radioactive_tracer_5: $i > $i).
% 29.32/29.12  tff(decl_64749, type, detect_0: $i).
% 29.32/29.12  tff(decl_64750, type, radioactive_treatment_1: $i > $o).
% 29.32/29.12  tff(decl_64751, type, 'Radioactive-Treatment': $i).
% 29.32/29.12  tff(decl_64752, type, 'The use of radioactive isotopes to treat cancer.': $i).
% 29.32/29.12  tff(decl_64753, type, 'radiation treatment': $i).
% 29.32/29.12  tff(decl_64754, type, 'radiation-treatment': $i).
% 29.32/29.12  tff(decl_64755, type, 'radiation therapy': $i).
% 29.32/29.12  tff(decl_64756, type, treat: $i).
% 29.32/29.12  tff(decl_64757, type, 'radioactive treatment': $i).
% 29.32/29.12  tff(decl_64758, type, 'radioactive-treatment': $i).
% 29.32/29.12  tff(decl_64759, type, fn_radioactive_treatment_1: $i > $i).
% 29.32/29.12  tff(decl_64760, type, fn_radioactive_treatment_2: $i > $i).
% 29.32/29.12  tff(decl_64761, type, 'Radioactivity': $i).
% 29.32/29.12  tff(decl_64762, type, 'The emmission of radiation,  resulting from either a nuclear reaction or the spontaneous nuclear decay of radioactive substances.': $i).
% 29.32/29.12  tff(decl_64763, type, 'radioactive decay': $i).
% 29.32/29.12  tff(decl_64764, type, 'radioactive-decay': $i).
% 29.32/29.12  tff(decl_64765, type, radioactivity: $i).
% 29.32/29.12  tff(decl_64766, type, fn_radioactivity_1: $i > $i).
% 29.32/29.12  tff(decl_64767, type, fn_radioactivity_6: $i > $i).
% 29.32/29.12  tff(decl_64768, type, 'Radiolarian': $i).
% 29.32/29.12  tff(decl_64769, type, 'An aquatic protist, usually marine, that has a shell made of silica and pseudopodia that protrude radially along skeletal spines extending from the center of the body.': $i).
% 29.32/29.12  tff(decl_64770, type, radiolarian: $i).
% 29.32/29.12  tff(decl_64771, type, 'Radiometric-Dating': $i).
% 29.32/29.12  tff(decl_64772, type, 'A technique for determining the age of a rock or fossil by comparing the abundances of a naturally occurring radioactive substance and one or more of its decay products.': $i).
% 29.32/29.12  tff(decl_64773, type, 'radiometric dating': $i).
% 29.32/29.12  tff(decl_64774, type, 'radiometric-dating': $i).
% 29.32/29.12  tff(decl_64775, type, radium_1: $i > $o).
% 29.32/29.12  tff(decl_64776, type, 'Radium': $i).
% 29.32/29.12  tff(decl_64777, type, 'Radium is a metal atom with atomic number 88. It is represented by the symbol Ra.': $i).
% 29.32/29.12  tff(decl_64778, type, radium: $i).
% 29.32/29.12  tff(decl_64779, type, 'Ra': $i).
% 29.32/29.12  tff(decl_64780, type, fn_radium_4: $i > $i).
% 29.32/29.12  tff(decl_64781, type, fn_radium_5: $i > $i).
% 29.32/29.12  tff(decl_64782, type, fn_radium_6: $i > $i).
% 29.32/29.12  tff(decl_64783, type, fn_radium_7: $i > $i).
% 29.32/29.12  tff(decl_64784, type, fn_radium_11: $i > $i).
% 29.32/29.12  tff(decl_64785, type, fn_radium_12: $i > $i).
% 29.32/29.12  tff(decl_64786, type, fn_radium_13: $i > $i).
% 29.32/29.12  tff(decl_64787, type, fn_radium_14: $i > $i).
% 29.32/29.12  tff(decl_64788, type, "88": $i).
% 29.32/29.12  tff(decl_64789, type, "226": $i).
% 29.32/29.12  tff(decl_64790, type, fn_radium_9: $i > $i).
% 29.32/29.12  tff(decl_64791, type, fn_radium_10: $i > $i).
% 29.32/29.12  tff(decl_64792, type, fn_radium_8: $i > $i).
% 29.32/29.12  tff(decl_64793, type, radius_constant_1: $i > $o).
% 29.32/29.12  tff(decl_64794, type, 'Radius-Constant': $i).
% 29.32/29.12  tff(decl_64795, type, 'constant of radius': $i).
% 29.32/29.12  tff(decl_64796, type, 'radius constant': $i).
% 29.32/29.12  tff(decl_64797, type, 'radius-constant': $i).
% 29.32/29.12  tff(decl_64798, type, radius_scale_1: $i > $o).
% 29.32/29.12  tff(decl_64799, type, 'Radius-Scale': $i).
% 29.32/29.12  tff(decl_64800, type, 'scale of radius': $i).
% 29.32/29.12  tff(decl_64801, type, 'radius scale': $i).
% 29.32/29.12  tff(decl_64802, type, 'radius-scale': $i).
% 29.32/29.12  tff(decl_64803, type, radon_1: $i > $o).
% 29.32/29.12  tff(decl_64804, type, 'Radon': $i).
% 29.32/29.12  tff(decl_64805, type, 'Radon is a non metal atom with atomic number 86. It is represented by the symbol Rn.': $i).
% 29.32/29.12  tff(decl_64806, type, 'Rn': $i).
% 29.32/29.12  tff(decl_64807, type, radon: $i).
% 29.32/29.12  tff(decl_64808, type, fn_radon_4: $i > $i).
% 29.32/29.12  tff(decl_64809, type, fn_radon_5: $i > $i).
% 29.32/29.12  tff(decl_64810, type, fn_radon_6: $i > $i).
% 29.32/29.12  tff(decl_64811, type, fn_radon_7: $i > $i).
% 29.32/29.12  tff(decl_64812, type, fn_radon_11: $i > $i).
% 29.32/29.12  tff(decl_64813, type, fn_radon_12: $i > $i).
% 29.32/29.12  tff(decl_64814, type, fn_radon_13: $i > $i).
% 29.32/29.12  tff(decl_64815, type, fn_radon_14: $i > $i).
% 29.32/29.12  tff(decl_64816, type, "86": $i).
% 29.32/29.12  tff(decl_64817, type, "222": $i).
% 29.32/29.12  tff(decl_64818, type, fn_radon_9: $i > $i).
% 29.32/29.12  tff(decl_64819, type, fn_radon_8: $i > $i).
% 29.32/29.12  tff(decl_64820, type, fn_radon_10: $i > $i).
% 29.32/29.12  tff(decl_64821, type, radula_1: $i > $o).
% 29.32/29.12  tff(decl_64822, type, 'Radula': $i).
% 29.32/29.12  tff(decl_64823, type, 'A filelike rasping organ used by many molluscs to scrape films or bite algae while feeding.': $i).
% 29.32/29.12  tff(decl_64824, type, radula: $i).
% 29.32/29.12  tff(decl_64825, type, raft_spider_1: $i > $o).
% 29.32/29.12  tff(decl_64826, type, 'Raft-Spider': $i).
% 29.32/29.12  tff(decl_64827, type, 'A species of semi-aquatic arachnid which hunts on the surface of water in a pond or lake. It is able to walk upon the water surface due to the high surface tension of water.': $i).
% 29.32/29.12  tff(decl_64828, type, 'spider of raft': $i).
% 29.32/29.12  tff(decl_64829, type, 'raft spider': $i).
% 29.32/29.12  tff(decl_64830, type, 'raft-spider': $i).
% 29.32/29.12  tff(decl_64831, type, fn_raft_spider_1: $i > $i).
% 29.32/29.12  tff(decl_64832, type, fn_raft_spider_2: $i > $i).
% 29.32/29.12  tff(decl_64833, type, fn_raft_spider_3: $i > $i).
% 29.32/29.12  tff(decl_64834, type, fn_raft_spider_4: $i > $i).
% 29.32/29.12  tff(decl_64835, type, fn_raft_spider_5: $i > $i).
% 29.32/29.12  tff(decl_64836, type, fn_raft_spider_6: $i > $i).
% 29.32/29.12  tff(decl_64837, type, fn_raft_spider_7: $i > $i).
% 29.32/29.12  tff(decl_64838, type, fn_raft_spider_8: $i > $i).
% 29.32/29.12  tff(decl_64839, type, fn_raft_spider_9: $i > $i).
% 29.32/29.12  tff(decl_64840, type, fn_raft_spider_10: $i > $i).
% 29.32/29.12  tff(decl_64841, type, fn_raft_spider_11: $i > $i).
% 29.32/29.12  tff(decl_64842, type, fn_raft_spider_12: $i > $i).
% 29.32/29.12  tff(decl_64843, type, fn_raft_spider_13: $i > $i).
% 29.32/29.12  tff(decl_64844, type, fn_raft_spider_14: $i > $i).
% 29.32/29.12  tff(decl_64845, type, fn_raft_spider_15: $i > $i).
% 29.32/29.12  tff(decl_64846, type, fn_raft_spider_16: $i > $i).
% 29.32/29.12  tff(decl_64847, type, fn_raft_spider_17: $i > $i).
% 29.32/29.12  tff(decl_64848, type, fn_raft_spider_18: $i > $i).
% 29.32/29.12  tff(decl_64849, type, fn_walk_1: $i > $i).
% 29.32/29.12  tff(decl_64850, type, fn_raft_spider_20: $i > $i).
% 29.32/29.12  tff(decl_64851, type, fn_raft_spider_19: $i > $i).
% 29.32/29.12  tff(decl_64852, type, 'Rain': $i).
% 29.32/29.12  tff(decl_64853, type, 'Condensed water vapor that falls to the earth as water drops.': $i).
% 29.32/29.12  tff(decl_64854, type, rain: $i).
% 29.32/29.12  tff(decl_64855, type, fn_rain_2: $i > $i).
% 29.32/29.12  tff(decl_64856, type, "5.6e0": $i).
% 29.32/29.12  tff(decl_64857, type, 'Random-Fertilization': $i).
% 29.32/29.12  tff(decl_64858, type, 'The random nature of fertilization in which an ovum, representing one of a number of possible chromosome combinations, is fertilized by a single sperm cell, which represents one of a number of different possibilities.': $i).
% 29.32/29.12  tff(decl_64859, type, 'random fertilization': $i).
% 29.32/29.12  tff(decl_64860, type, 'random-fertilization': $i).
% 29.32/29.12  tff(decl_64861, type, fn_random_fertilization_1: $i > $i).
% 29.32/29.12  tff(decl_64862, type, fn_random_fertilization_2: $i > $i).
% 29.32/29.12  tff(decl_64863, type, fn_random_fertilization_3: $i > $i).
% 29.32/29.12  tff(decl_64864, type, fn_random_fertilization_4: $i > $i).
% 29.32/29.12  tff(decl_64865, type, fn_random_fertilization_5: $i > $i).
% 29.32/29.12  tff(decl_64866, type, 'Random-Motion': $i).
% 29.32/29.12  tff(decl_64867, type, 'This is the case where the movement is random.': $i).
% 29.32/29.12  tff(decl_64868, type, 'random motion': $i).
% 29.32/29.12  tff(decl_64869, type, 'random-motion': $i).
% 29.32/29.12  tff(decl_64870, type, 'Random-Recombination': $i).
% 29.32/29.12  tff(decl_64871, type, 'Recombinant constructed by digesting and randomly religating the DNA genome.': $i).
% 29.32/29.12  tff(decl_64872, type, 'random recombination': $i).
% 29.32/29.12  tff(decl_64873, type, 'random-recombination': $i).
% 29.32/29.12  tff(decl_64874, type, raphia_regalis_1: $i > $o).
% 29.32/29.12  tff(decl_64875, type, 'Raphia-Regalis': $i).
% 29.32/29.12  tff(decl_64876, type, 'Raphia regalis is a species of flowering plant in the family Arecaceae. It is a native of African rain forests.': $i).
% 29.32/29.12  tff(decl_64877, type, 'raphia regalis': $i).
% 29.32/29.12  tff(decl_64878, type, 'raphia-regalis': $i).
% 29.32/29.12  tff(decl_64879, type, ras_gene_1: $i > $o).
% 29.32/29.12  tff(decl_64880, type, 'Ras-Gene': $i).
% 29.32/29.12  tff(decl_64881, type, 'Gene that codes for Ras protein.': $i).
% 29.32/29.12  tff(decl_64882, type, 'rat sarcoma protein gene': $i).
% 29.32/29.12  tff(decl_64883, type, 'rat-sarcoma-protein-gene': $i).
% 29.32/29.12  tff(decl_64884, type, 'ras gene': $i).
% 29.32/29.12  tff(decl_64885, type, 'ras-gene': $i).
% 29.32/29.12  tff(decl_64886, type, fn_ras_gene_3: $i > $i).
% 29.32/29.12  tff(decl_64887, type, fn_ras_gene_4: $i > $i).
% 29.32/29.12  tff(decl_64888, type, fn_ras_gene_5: $i > $i).
% 29.32/29.12  tff(decl_64889, type, fn_ras_gene_6: $i > $i).
% 29.32/29.12  tff(decl_64890, type, fn_ras_gene_9: $i > $i).
% 29.32/29.12  tff(decl_64891, type, fn_ras_gene_10: $i > $i).
% 29.32/29.12  tff(decl_64892, type, fn_ras_gene_11: $i > $i).
% 29.32/29.12  tff(decl_64893, type, fn_ras_gene_12: $i > $i).
% 29.32/29.12  tff(decl_64894, type, fn_ras_gene_13: $i > $i).
% 29.32/29.12  tff(decl_64895, type, fn_ras_gene_14: $i > $i).
% 29.32/29.12  tff(decl_64896, type, fn_ras_gene_15: $i > $i).
% 29.32/29.12  tff(decl_64897, type, fn_ras_gene_16: $i > $i).
% 29.32/29.12  tff(decl_64898, type, fn_ras_gene_17: $i > $i).
% 29.32/29.12  tff(decl_64899, type, fn_ras_gene_18: $i > $i).
% 29.32/29.12  tff(decl_64900, type, fn_ras_gene_19: $i > $i).
% 29.32/29.12  tff(decl_64901, type, fn_ras_gene_20: $i > $i).
% 29.32/29.12  tff(decl_64902, type, fn_ras_gene_21: $i > $i).
% 29.32/29.12  tff(decl_64903, type, fn_ras_protein_13: $i > $i).
% 29.32/29.12  tff(decl_64904, type, fn_ras_gene_7: $i > $i).
% 29.32/29.12  tff(decl_64905, type, fn_ras_gene_8: $i > $i).
% 29.32/29.12  tff(decl_64906, type, ras_oncogene_1: $i > $o).
% 29.32/29.12  tff(decl_64907, type, 'Ras-Oncogene': $i).
% 29.32/29.12  tff(decl_64908, type, 'Ras coding oncogene.': $i).
% 29.32/29.12  tff(decl_64909, type, 'ras oncogene': $i).
% 29.32/29.12  tff(decl_64910, type, 'ras-oncogene': $i).
% 29.32/29.12  tff(decl_64911, type, fn_ras_oncogene_1: $i > $i).
% 29.32/29.12  tff(decl_64912, type, fn_ras_oncogene_2: $i > $i).
% 29.32/29.12  tff(decl_64913, type, fn_ras_oncogene_3: $i > $i).
% 29.32/29.12  tff(decl_64914, type, fn_ras_oncogene_4: $i > $i).
% 29.32/29.12  tff(decl_64915, type, fn_ras_oncogene_5: $i > $i).
% 29.32/29.12  tff(decl_64916, type, fn_ras_oncogene_6: $i > $i).
% 29.32/29.12  tff(decl_64917, type, 'Ras-Protein': $i).
% 29.32/29.12  tff(decl_64918, type, 'The Ras protein is a component of signal-transduction.  Activation of Ras signalling causes cell growth.': $i).
% 29.32/29.12  tff(decl_64919, type, 'ras protein': $i).
% 29.32/29.12  tff(decl_64920, type, 'ras-protein': $i).
% 29.32/29.12  tff(decl_64921, type, fn_ras_protein_1: $i > $i).
% 29.32/29.12  tff(decl_64922, type, fn_ras_protein_2: $i > $i).
% 29.32/29.12  tff(decl_64923, type, fn_ras_protein_4: $i > $i).
% 29.32/29.12  tff(decl_64924, type, fn_ras_protein_5: $i > $i).
% 29.32/29.12  tff(decl_64925, type, fn_ras_protein_6: $i > $i).
% 29.32/29.12  tff(decl_64926, type, fn_ras_protein_7: $i > $i).
% 29.32/29.12  tff(decl_64927, type, fn_ras_protein_8: $i > $i).
% 29.32/29.12  tff(decl_64928, type, fn_ras_protein_9: $i > $i).
% 29.32/29.12  tff(decl_64929, type, fn_ras_protein_10: $i > $i).
% 29.32/29.12  tff(decl_64930, type, fn_ras_protein_11: $i > $i).
% 29.32/29.12  tff(decl_64931, type, fn_ras_protein_12: $i > $i).
% 29.32/29.12  tff(decl_64932, type, fn_ras_protein_14: $i > $i).
% 29.32/29.12  tff(decl_64933, type, fn_ras_protein_15: $i > $i).
% 29.32/29.12  tff(decl_64934, type, fn_ras_protein_16: $i > $i).
% 29.32/29.12  tff(decl_64935, type, fn_ras_protein_17: $i > $i).
% 29.32/29.12  tff(decl_64936, type, fn_ras_protein_18: $i > $i).
% 29.32/29.12  tff(decl_64937, type, fn_ras_protein_19: $i > $i).
% 29.32/29.12  tff(decl_64938, type, fn_regulatory_gene_2: $i > $i).
% 29.32/29.12  tff(decl_64939, type, increase_0: $i).
% 29.32/29.12  tff(decl_64940, type, 'Rate-Constant': $i).
% 29.32/29.12  tff(decl_64941, type, 'constant of rate': $i).
% 29.32/29.12  tff(decl_64942, type, 'rate constant': $i).
% 29.32/29.12  tff(decl_64943, type, 'rate-constant': $i).
% 29.32/29.12  tff(decl_64944, type, rate_scale_1: $i > $o).
% 29.32/29.12  tff(decl_64945, type, 'Rate-Scale': $i).
% 29.32/29.12  tff(decl_64946, type, 'scale of rate': $i).
% 29.32/29.12  tff(decl_64947, type, 'rate scale': $i).
% 29.32/29.12  tff(decl_64948, type, 'rate-scale': $i).
% 29.32/29.12  tff(decl_64949, type, 'Rate-Value': $i).
% 29.32/29.12  tff(decl_64950, type, 'the rate at which an Event is happening': $i).
% 29.32/29.12  tff(decl_64951, type, rate: $i).
% 29.32/29.12  tff(decl_64952, type, 'value of rate': $i).
% 29.32/29.12  tff(decl_64953, type, 'rate value': $i).
% 29.32/29.12  tff(decl_64954, type, 'rate-value': $i).
% 29.32/29.12  tff(decl_64955, type, 'Ratite': $i).
% 29.32/29.12  tff(decl_64956, type, 'One of a diverse group of flightless birds.': $i).
% 29.32/29.12  tff(decl_64957, type, ratite: $i).
% 29.32/29.12  tff(decl_64958, type, 'Ray-Finned-Fish': $i).
% 29.32/29.12  tff(decl_64959, type, 'A fish in the class Actinopterygii, characterized by fins consisting of a thin web of skin supported by fin rays rather than bones.': $i).
% 29.32/29.12  tff(decl_64960, type, 'ray finned fish': $i).
% 29.32/29.12  tff(decl_64961, type, 'ray-finned fish': $i).
% 29.32/29.12  tff(decl_64962, type, 'ray-finned-fish': $i).
% 29.32/29.12  tff(decl_64963, type, 'Reabsorption': $i).
% 29.32/29.12  tff(decl_64964, type, 'In kidneys and other excretory systems, the recovery of water and solutes from the filtrate.': $i).
% 29.32/29.12  tff(decl_64965, type, reabsorb: $i).
% 29.32/29.12  tff(decl_64966, type, reabsorption: $i).
% 29.32/29.12  tff(decl_64967, type, 'Reactant': $i).
% 29.32/29.12  tff(decl_64968, type, 'One of the starting materials in a chemical reaction. Unlike a catalyst, a reactant participates directly in a chemical reaction and is changed in some way by the reaction.': $i).
% 29.32/29.12  tff(decl_64969, type, reactant: $i).
% 29.32/29.12  tff(decl_64970, type, 'Reaction-Center-Complex': $i).
% 29.32/29.12  tff(decl_64971, type, 'The region of a photosystem where the first light-driven chemical reaction of photosynthesis occurs.': $i).
% 29.32/29.12  tff(decl_64972, type, 'reaction center complex': $i).
% 29.32/29.12  tff(decl_64973, type, 'reaction-center complex': $i).
% 29.32/29.12  tff(decl_64974, type, 'reaction center': $i).
% 29.32/29.12  tff(decl_64975, type, 'reaction-center-complex': $i).
% 29.32/29.12  tff(decl_64976, type, chlorophyll_a_0: $i).
% 29.32/29.12  tff(decl_64977, type, 'Reaction-Direction-Constant': $i).
% 29.32/29.12  tff(decl_64978, type, 'reaction direction constant': $i).
% 29.32/29.12  tff(decl_64979, type, 'reaction-direction-constant': $i).
% 29.32/29.12  tff(decl_64980, type, 'Reaction-Direction-Value': $i).
% 29.32/29.12  tff(decl_64981, type, 'the direction of an equilibrium reaction, i.e. left or right.': $i).
% 29.32/29.12  tff(decl_64982, type, 'direction of reaction': $i).
% 29.32/29.12  tff(decl_64983, type, 'reaction direction': $i).
% 29.32/29.12  tff(decl_64984, type, 'reaction-direction': $i).
% 29.32/29.12  tff(decl_64985, type, 'reaction direction value': $i).
% 29.32/29.12  tff(decl_64986, type, 'reaction-direction-value': $i).
% 29.32/29.12  tff(decl_64987, type, reaction_material_1: $i > $o).
% 29.32/29.12  tff(decl_64988, type, 'Reaction-Material': $i).
% 29.32/29.12  tff(decl_64989, type, 'material of reaction': $i).
% 29.32/29.12  tff(decl_64990, type, 'reaction material': $i).
% 29.32/29.12  tff(decl_64991, type, 'reaction-material': $i).
% 29.32/29.12  tff(decl_64992, type, reaction_result_1: $i > $o).
% 29.32/29.12  tff(decl_64993, type, 'Reaction-Result': $i).
% 29.32/29.12  tff(decl_64994, type, 'result of reaction': $i).
% 29.32/29.12  tff(decl_64995, type, 'reaction result': $i).
% 29.32/29.12  tff(decl_64996, type, 'reaction-result': $i).
% 29.32/29.12  tff(decl_64997, type, reactive_chemical_1: $i > $o).
% 29.32/29.12  tff(decl_64998, type, 'Reactive-Chemical': $i).
% 29.32/29.12  tff(decl_64999, type, 'Reactive chemicals are highly active entities and react aggresively with other entities to make harmful changes to them': $i).
% 29.32/29.12  tff(decl_65000, type, 'reactive chemical': $i).
% 29.32/29.12  tff(decl_65001, type, 'reactive-chemical': $i).
% 29.32/29.12  tff(decl_65002, type, 'Read': $i).
% 29.32/29.12  tff(decl_65003, type, read: $i).
% 29.32/29.12  tff(decl_65004, type, fn_read_1: $i > $i).
% 29.32/29.12  tff(decl_65005, type, 'Reading-Frame': $i).
% 29.32/29.12  tff(decl_65006, type, 'On a strand of mRNA, the group of three nucleotides that read and translated during polypeptide synthesis.': $i).
% 29.32/29.12  tff(decl_65007, type, rf: $i).
% 29.32/29.12  tff(decl_65008, type, 'frame of reading': $i).
% 29.32/29.12  tff(decl_65009, type, 'reading frame': $i).
% 29.32/29.12  tff(decl_65010, type, 'reading-frame': $i).
% 29.32/29.12  tff(decl_65011, type, 'Rearrangement': $i).
% 29.32/29.12  tff(decl_65012, type, 'A rearrangement reaction is a broad class of organic reactions where the carbon skeleton of a molecule is rearranged to give a structural isomer of the original molecule. Often a substituent moves from one atom to another atom in the same molecule.': $i).
% 29.32/29.12  tff(decl_65013, type, rearrangement: $i).
% 29.32/29.12  tff(decl_65014, type, 'Receive': $i).
% 29.32/29.12  tff(decl_65015, type, receive: $i).
% 29.32/29.12  tff(decl_65016, type, have: $i).
% 29.32/29.12  tff(decl_65017, type, 'Receptacle': $i).
% 29.32/29.12  tff(decl_65018, type, 'The basal part of a flower; the thickened part of the stem from which the floral organs arise.': $i).
% 29.32/29.12  tff(decl_65019, type, receptacle: $i).
% 29.32/29.12  tff(decl_65020, type, 'Receptor': $i).
% 29.32/29.12  tff(decl_65021, type, 'A molecule or structure that responds to a stimulus and causes a specific effect on a cell or organism.': $i).
% 29.32/29.12  tff(decl_65022, type, 'signal receptor': $i).
% 29.32/29.12  tff(decl_65023, type, 'signal-receptor': $i).
% 29.32/29.12  tff(decl_65024, type, receptor: $i).
% 29.32/29.12  tff(decl_65025, type, 'Receptor-Mediated-Endocytosis': $i).
% 29.32/29.12  tff(decl_65026, type, 'Receptor-mediated endocytosis (RME), also called clathrin-dependent endocytosis, is a process by which cells internalize molecules (endocytosis) by the inward budding of plasma membrane vesicles containing proteins with receptor sites specific to the molecules being internalized.': $i).
% 29.32/29.12  tff(decl_65027, type, 'perform receptor mediated endocytosis': $i).
% 29.32/29.12  tff(decl_65028, type, 'receptor mediated endocytosis': $i).
% 29.32/29.12  tff(decl_65029, type, 'receptor-mediated-endocytosis': $i).
% 29.32/29.12  tff(decl_65030, type, fn_receptor_mediated_endocytosis_1: $i > $i).
% 29.32/29.12  tff(decl_65031, type, fn_receptor_mediated_endocytosis_2: $i > $i).
% 29.32/29.12  tff(decl_65032, type, fn_receptor_mediated_endocytosis_3: $i > $i).
% 29.32/29.12  tff(decl_65033, type, fn_receptor_mediated_endocytosis_4: $i > $i).
% 29.32/29.12  tff(decl_65034, type, fn_receptor_mediated_endocytosis_5: $i > $i).
% 29.32/29.12  tff(decl_65035, type, fn_receptor_mediated_endocytosis_6: $i > $i).
% 29.32/29.12  tff(decl_65036, type, fn_receptor_mediated_endocytosis_7: $i > $i).
% 29.32/29.12  tff(decl_65037, type, fn_receptor_mediated_endocytosis_8: $i > $i).
% 29.32/29.12  tff(decl_65038, type, fn_receptor_mediated_endocytosis_9: $i > $i).
% 29.32/29.12  tff(decl_65039, type, fn_receptor_mediated_endocytosis_11: $i > $i).
% 29.32/29.12  tff(decl_65040, type, fn_receptor_mediated_endocytosis_27: $i > $i).
% 29.32/29.12  tff(decl_65041, type, fn_receptor_mediated_endocytosis_28: $i > $i).
% 29.32/29.12  tff(decl_65042, type, fn_receptor_mediated_endocytosis_29: $i > $i).
% 29.32/29.12  tff(decl_65043, type, fn_receptor_mediated_endocytosis_30: $i > $i).
% 29.32/29.12  tff(decl_65044, type, fn_receptor_mediated_endocytosis_31: $i > $i).
% 29.32/29.12  tff(decl_65045, type, fn_receptor_mediated_endocytosis_32: $i > $i).
% 29.32/29.12  tff(decl_65046, type, fn_receptor_mediated_endocytosis_33: $i > $i).
% 29.32/29.12  tff(decl_65047, type, fn_receptor_mediated_endocytosis_34: $i > $i).
% 29.32/29.12  tff(decl_65048, type, fn_receptor_mediated_endocytosis_35: $i > $i).
% 29.32/29.12  tff(decl_65049, type, fn_receptor_mediated_endocytosis_36: $i > $i).
% 29.32/29.12  tff(decl_65050, type, fn_receptor_mediated_endocytosis_37: $i > $i).
% 29.32/29.12  tff(decl_65051, type, fn_receptor_mediated_endocytosis_38: $i > $i).
% 29.32/29.12  tff(decl_65052, type, fn_receptor_mediated_endocytosis_39: $i > $i).
% 29.32/29.12  tff(decl_65053, type, fn_receptor_mediated_endocytosis_40: $i > $i).
% 29.32/29.12  tff(decl_65054, type, fn_receptor_mediated_endocytosis_41: $i > $i).
% 29.32/29.12  tff(decl_65055, type, fn_receptor_mediated_endocytosis_42: $i > $i).
% 29.32/29.12  tff(decl_65056, type, fn_receptor_mediated_endocytosis_43: $i > $i).
% 29.32/29.12  tff(decl_65057, type, fn_receptor_mediated_endocytosis_44: $i > $i).
% 29.32/29.12  tff(decl_65058, type, fn_receptor_mediated_endocytosis_45: $i > $i).
% 29.32/29.12  tff(decl_65059, type, fn_receptor_mediated_endocytosis_46: $i > $i).
% 29.32/29.12  tff(decl_65060, type, fn_receptor_mediated_endocytosis_47: $i > $i).
% 29.32/29.12  tff(decl_65061, type, fn_receptor_mediated_endocytosis_48: $i > $i).
% 29.32/29.12  tff(decl_65062, type, fn_receptor_mediated_endocytosis_49: $i > $i).
% 29.32/29.12  tff(decl_65063, type, fn_receptor_mediated_endocytosis_50: $i > $i).
% 29.32/29.12  tff(decl_65064, type, fn_receptor_mediated_endocytosis_51: $i > $i).
% 29.32/29.12  tff(decl_65065, type, fn_receptor_mediated_endocytosis_52: $i > $i).
% 29.32/29.12  tff(decl_65066, type, fn_receptor_mediated_endocytosis_53: $i > $i).
% 29.32/29.12  tff(decl_65067, type, fn_receptor_mediated_endocytosis_54: $i > $i).
% 29.32/29.12  tff(decl_65068, type, fn_receptor_mediated_endocytosis_55: $i > $i).
% 29.32/29.12  tff(decl_65069, type, fn_receptor_mediated_endocytosis_56: $i > $i).
% 29.32/29.12  tff(decl_65070, type, fn_receptor_mediated_endocytosis_57: $i > $i).
% 29.32/29.12  tff(decl_65071, type, fn_receptor_mediated_endocytosis_58: $i > $i).
% 29.32/29.12  tff(decl_65072, type, fn_receptor_mediated_endocytosis_59: $i > $i).
% 29.32/29.12  tff(decl_65073, type, fn_receptor_mediated_endocytosis_60: $i > $i).
% 29.32/29.12  tff(decl_65074, type, fn_receptor_mediated_endocytosis_61: $i > $i).
% 29.32/29.12  tff(decl_65075, type, fn_receptor_mediated_endocytosis_62: $i > $i).
% 29.32/29.12  tff(decl_65076, type, fn_receptor_mediated_endocytosis_63: $i > $i).
% 29.32/29.12  tff(decl_65077, type, fn_receptor_mediated_endocytosis_64: $i > $i).
% 29.32/29.12  tff(decl_65078, type, fn_receptor_mediated_endocytosis_65: $i > $i).
% 29.32/29.12  tff(decl_65079, type, fn_receptor_mediated_endocytosis_66: $i > $i).
% 29.32/29.12  tff(decl_65080, type, fn_receptor_mediated_endocytosis_67: $i > $i).
% 29.32/29.12  tff(decl_65081, type, fn_receptor_mediated_endocytosis_68: $i > $i).
% 29.32/29.12  tff(decl_65082, type, fn_receptor_mediated_endocytosis_69: $i > $i).
% 29.32/29.12  tff(decl_65083, type, fn_receptor_mediated_endocytosis_70: $i > $i).
% 29.32/29.12  tff(decl_65084, type, fn_receptor_mediated_endocytosis_71: $i > $i).
% 29.32/29.12  tff(decl_65085, type, fn_receptor_mediated_endocytosis_72: $i > $i).
% 29.32/29.12  tff(decl_65086, type, fn_receptor_mediated_endocytosis_73: $i > $i).
% 29.32/29.12  tff(decl_65087, type, fn_receptor_mediated_endocytosis_74: $i > $i).
% 29.32/29.12  tff(decl_65088, type, fn_receptor_mediated_endocytosis_75: $i > $i).
% 29.32/29.12  tff(decl_65089, type, fn_receptor_mediated_endocytosis_76: $i > $i).
% 29.32/29.12  tff(decl_65090, type, fn_receptor_mediated_endocytosis_77: $i > $i).
% 29.32/29.12  tff(decl_65091, type, fn_receptor_mediated_endocytosis_78: $i > $i).
% 29.32/29.12  tff(decl_65092, type, fn_receptor_mediated_endocytosis_79: $i > $i).
% 29.32/29.12  tff(decl_65093, type, fn_receptor_mediated_endocytosis_80: $i > $i).
% 29.32/29.12  tff(decl_65094, type, fn_receptor_mediated_endocytosis_81: $i > $i).
% 29.32/29.12  tff(decl_65095, type, fn_receptor_mediated_endocytosis_82: $i > $i).
% 29.32/29.12  tff(decl_65096, type, fn_receptor_mediated_endocytosis_83: $i > $i).
% 29.32/29.12  tff(decl_65097, type, fn_receptor_mediated_endocytosis_84: $i > $i).
% 29.32/29.12  tff(decl_65098, type, fn_receptor_mediated_endocytosis_87: $i > $i).
% 29.32/29.12  tff(decl_65099, type, fn_receptor_mediated_endocytosis_88: $i > $i).
% 29.32/29.12  tff(decl_65100, type, fn_receptor_mediated_endocytosis_89: $i > $i).
% 29.32/29.12  tff(decl_65101, type, fn_receptor_mediated_endocytosis_90: $i > $i).
% 29.32/29.12  tff(decl_65102, type, fn_receptor_mediated_endocytosis_91: $i > $i).
% 29.32/29.12  tff(decl_65103, type, fn_receptor_mediated_endocytosis_92: $i > $i).
% 29.32/29.12  tff(decl_65104, type, fn_receptor_mediated_endocytosis_93: $i > $i).
% 29.32/29.12  tff(decl_65105, type, fn_receptor_mediated_endocytosis_94: $i > $i).
% 29.32/29.12  tff(decl_65106, type, fn_receptor_mediated_endocytosis_95: $i > $i).
% 29.32/29.12  tff(decl_65107, type, fn_receptor_mediated_endocytosis_97: $i > $i).
% 29.32/29.12  tff(decl_65108, type, fn_receptor_mediated_endocytosis_98: $i > $i).
% 29.32/29.12  tff(decl_65109, type, fn_receptor_mediated_endocytosis_99: $i > $i).
% 29.32/29.12  tff(decl_65110, type, fn_receptor_mediated_endocytosis_100: $i > $i).
% 29.32/29.12  tff(decl_65111, type, fn_receptor_mediated_endocytosis_101: $i > $i).
% 29.32/29.12  tff(decl_65112, type, fn_receptor_mediated_endocytosis_102: $i > $i).
% 29.32/29.12  tff(decl_65113, type, fn_receptor_mediated_endocytosis_103: $i > $i).
% 29.32/29.12  tff(decl_65114, type, fn_receptor_mediated_endocytosis_104: $i > $i).
% 29.32/29.12  tff(decl_65115, type, fn_receptor_mediated_endocytosis_105: $i > $i).
% 29.32/29.12  tff(decl_65116, type, fn_receptor_mediated_endocytosis_106: $i > $i).
% 29.32/29.12  tff(decl_65117, type, fn_receptor_mediated_endocytosis_107: $i > $i).
% 29.32/29.12  tff(decl_65118, type, fn_receptor_mediated_endocytosis_108: $i > $i).
% 29.32/29.12  tff(decl_65119, type, fn_receptor_mediated_endocytosis_109: $i > $i).
% 29.32/29.12  tff(decl_65120, type, fn_receptor_mediated_endocytosis_112: $i > $i).
% 29.32/29.12  tff(decl_65121, type, fn_receptor_mediated_endocytosis_113: $i > $i).
% 29.32/29.12  tff(decl_65122, type, fn_receptor_mediated_endocytosis_114: $i > $i).
% 29.32/29.12  tff(decl_65123, type, fn_receptor_mediated_endocytosis_115: $i > $i).
% 29.32/29.12  tff(decl_65124, type, fn_receptor_mediated_endocytosis_116: $i > $i).
% 29.32/29.12  tff(decl_65125, type, fn_receptor_mediated_endocytosis_18: $i > $i).
% 29.32/29.12  tff(decl_65126, type, fn_receptor_mediated_endocytosis_17: $i > $i).
% 29.32/29.12  tff(decl_65127, type, fn_receptor_mediated_endocytosis_16: $i > $i).
% 29.32/29.12  tff(decl_65128, type, fn_receptor_mediated_endocytosis_19: $i > $i).
% 29.32/29.12  tff(decl_65129, type, fn_receptor_mediated_endocytosis_20: $i > $i).
% 29.32/29.12  tff(decl_65130, type, fn_receptor_mediated_endocytosis_26: $i > $i).
% 29.32/29.12  tff(decl_65131, type, fn_receptor_mediated_endocytosis_25: $i > $i).
% 29.32/29.12  tff(decl_65132, type, fn_receptor_mediated_endocytosis_24: $i > $i).
% 29.32/29.12  tff(decl_65133, type, fn_receptor_mediated_endocytosis_23: $i > $i).
% 29.32/29.12  tff(decl_65134, type, fn_receptor_mediated_endocytosis_21: $i > $i).
% 29.32/29.12  tff(decl_65135, type, fn_receptor_mediated_endocytosis_15: $i > $i).
% 29.32/29.12  tff(decl_65136, type, fn_receptor_mediated_endocytosis_14: $i > $i).
% 29.32/29.12  tff(decl_65137, type, fn_receptor_mediated_endocytosis_13: $i > $i).
% 29.32/29.12  tff(decl_65138, type, fn_receptor_mediated_endocytosis_12: $i > $i).
% 29.32/29.12  tff(decl_65139, type, fn_receptor_mediated_endocytosis_22: $i > $i).
% 29.32/29.12  tff(decl_65140, type, fn_receptor_mediated_endocytosis_110: $i > $i).
% 29.32/29.12  tff(decl_65141, type, fn_receptor_mediated_endocytosis_111: $i > $i).
% 29.32/29.12  tff(decl_65142, type, 'Receptor-Potential': $i).
% 29.32/29.12  tff(decl_65143, type, 'A type of graded potential in a sensory response neuron.': $i).
% 29.32/29.12  tff(decl_65144, type, 'potential of receptor': $i).
% 29.32/29.12  tff(decl_65145, type, 'receptor potential': $i).
% 29.32/29.12  tff(decl_65146, type, 'receptor-potential': $i).
% 29.32/29.12  tff(decl_65147, type, 'Receptor-Protein': $i).
% 29.32/29.12  tff(decl_65148, type, 'Receptor proteins located in the cytoplasm, cell membrane, or nuclear membrane bind to another molecule leading to a change in cell behavior.': $i).
% 29.32/29.12  tff(decl_65149, type, 'protein of receptor': $i).
% 29.32/29.12  tff(decl_65150, type, 'receptor protein': $i).
% 29.32/29.12  tff(decl_65151, type, 'receptor-protein': $i).
% 29.32/29.12  tff(decl_65152, type, 'Receptor-Site': $i).
% 29.32/29.12  tff(decl_65153, type, 'A molecular site or the docking port on the surface of, or within, a cell, usually involving proteins that are capable of recognizing and binding with specific molecules.': $i).
% 29.32/29.12  tff(decl_65154, type, 'site of receptor': $i).
% 29.32/29.12  tff(decl_65155, type, 'receptor site': $i).
% 29.32/29.12  tff(decl_65156, type, 'receptor-site': $i).
% 29.32/29.12  tff(decl_65157, type, 'Receptor-Tyrosine-Kinase': $i).
% 29.32/29.12  tff(decl_65158, type, 'A transmembrane protein in the plasma membrane. The intracellular side of the protein catalyzes the phosphorylation of a tyrosine on another protein.': $i).
% 29.32/29.12  tff(decl_65159, type, 'tyrosine kinase receptor': $i).
% 29.32/29.12  tff(decl_65160, type, 'receptor tyrosine kinase': $i).
% 29.32/29.12  tff(decl_65161, type, 'receptor tyrosine-kinase': $i).
% 29.32/29.12  tff(decl_65162, type, 'receptor-tyrosine-kinase': $i).
% 29.32/29.12  tff(decl_65163, type, fn_receptor_tyrosine_kinase_2: $i > $i).
% 29.32/29.12  tff(decl_65164, type, fn_receptor_tyrosine_kinase_5: $i > $i).
% 29.32/29.12  tff(decl_65165, type, fn_receptor_tyrosine_kinase_6: $i > $i).
% 29.32/29.12  tff(decl_65166, type, fn_receptor_tyrosine_kinase_7: $i > $i).
% 29.32/29.12  tff(decl_65167, type, fn_receptor_tyrosine_kinase_8: $i > $i).
% 29.32/29.12  tff(decl_65168, type, fn_receptor_tyrosine_kinase_11: $i > $i).
% 29.32/29.12  tff(decl_65169, type, fn_receptor_tyrosine_kinase_13: $i > $i).
% 29.32/29.12  tff(decl_65170, type, fn_receptor_tyrosine_kinase_14: $i > $i).
% 29.32/29.12  tff(decl_65171, type, fn_receptor_tyrosine_kinase_15: $i > $i).
% 29.32/29.12  tff(decl_65172, type, fn_receptor_tyrosine_kinase_16: $i > $i).
% 29.32/29.12  tff(decl_65173, type, fn_receptor_tyrosine_kinase_17: $i > $i).
% 29.32/29.12  tff(decl_65174, type, fn_receptor_tyrosine_kinase_18: $i > $i).
% 29.32/29.12  tff(decl_65175, type, fn_receptor_tyrosine_kinase_22: $i > $i).
% 29.32/29.12  tff(decl_65176, type, fn_receptor_tyrosine_kinase_23: $i > $i).
% 29.32/29.12  tff(decl_65177, type, tyrosine_0: $i).
% 29.32/29.12  tff(decl_65178, type, 'Receptor-Tyrosine-Kinase-Dimer': $i).
% 29.32/29.12  tff(decl_65179, type, 'Tyrosine kinase receptors exist as individual units referred to as monomers.  Once a signal binds to the receptor, the monomers form a dimer when they associate closely together.': $i).
% 29.32/29.12  tff(decl_65180, type, 'receptor tyrosine kinase dimer': $i).
% 29.32/29.12  tff(decl_65181, type, 'receptor-tyrosine-kinase-dimer': $i).
% 29.32/29.12  tff(decl_65182, type, 'Recessive': $i).
% 29.32/29.12  tff(decl_65183, type, 'The recessive condition is said to be masked by the presence of the dominant gene when both are present; i.e., the recessive condition is seen only in the absence of the dominant gene.': $i).
% 29.32/29.12  tff(decl_65184, type, 'absence of the dominant gene': $i).
% 29.32/29.12  tff(decl_65185, type, recessive: $i).
% 29.32/29.12  tff(decl_65186, type, fn_recessive_1: $i > $i).
% 29.32/29.12  tff(decl_65187, type, 'Recessive-Allele': $i).
% 29.32/29.12  tff(decl_65188, type, 'An allele that does not contribute to the phenotype in heterozygotes.': $i).
% 29.32/29.12  tff(decl_65189, type, 'allele of recessive': $i).
% 29.32/29.12  tff(decl_65190, type, 'recessive allele': $i).
% 29.32/29.12  tff(decl_65191, type, 'recessive-allele': $i).
% 29.32/29.12  tff(decl_65192, type, 'Recessive-Male': $i).
% 29.32/29.12  tff(decl_65193, type, 'A male who has the recessive allele for an X chromosome gene.': $i).
% 29.32/29.12  tff(decl_65194, type, 'x recessive and y': $i).
% 29.32/29.12  tff(decl_65195, type, 'x-recessive-and-y': $i).
% 29.32/29.12  tff(decl_65196, type, 'male of recessive': $i).
% 29.32/29.12  tff(decl_65197, type, 'recessive male': $i).
% 29.32/29.12  tff(decl_65198, type, 'recessive-male': $i).
% 29.32/29.12  tff(decl_65199, type, fn_recessive_male_1: $i > $i).
% 29.32/29.12  tff(decl_65200, type, fn_recessive_male_2: $i > $i).
% 29.32/29.12  tff(decl_65201, type, fn_recessive_male_3: $i > $i).
% 29.32/29.12  tff(decl_65202, type, recessive_phenotype_1: $i > $o).
% 29.32/29.12  tff(decl_65203, type, 'Recessive-Phenotype': $i).
% 29.32/29.12  tff(decl_65204, type, 'The phenotype of a genotype containing two recessive alleles.': $i).
% 29.32/29.12  tff(decl_65205, type, 'phenotype of recessive': $i).
% 29.32/29.12  tff(decl_65206, type, 'recessive phenotype': $i).
% 29.32/29.12  tff(decl_65207, type, 'recessive-phenotype': $i).
% 29.32/29.12  tff(decl_65208, type, 'Recessive-Trait': $i).
% 29.32/29.12  tff(decl_65209, type, 'A genetic trait which is is seen only in the absence of the dominant gene.': $i).
% 29.32/29.12  tff(decl_65210, type, 'trait of recessive': $i).
% 29.32/29.12  tff(decl_65211, type, 'recessive trait': $i).
% 29.32/29.12  tff(decl_65212, type, 'recessive-trait': $i).
% 29.32/29.12  tff(decl_65213, type, fn_recessive_trait_1: $i > $i).
% 29.32/29.12  tff(decl_65214, type, fn_recessive_trait_2: $i > $i).
% 29.32/29.12  tff(decl_65215, type, recessive_allele_0: $i).
% 29.32/29.12  tff(decl_65216, type, 'Recipient-Role': $i).
% 29.32/29.12  tff(decl_65217, type, receiver: $i).
% 29.32/29.12  tff(decl_65218, type, 'role of recipient': $i).
% 29.32/29.12  tff(decl_65219, type, 'recipient-role': $i).
% 29.32/29.12  tff(decl_65220, type, reciprocal_altruism_1: $i > $o).
% 29.32/29.12  tff(decl_65221, type, 'Reciprocal-Altruism': $i).
% 29.32/29.12  tff(decl_65222, type, 'Behavior in which one organism temporarily benefits an unrelated individual at the expense of its own fitness, with the expectation that the recipient will behave in a similar way at a later time.': $i).
% 29.32/29.12  tff(decl_65223, type, 'altruism of reciprocal': $i).
% 29.32/29.12  tff(decl_65224, type, 'reciprocal altruism': $i).
% 29.32/29.12  tff(decl_65225, type, 'reciprocal-altruism': $i).
% 29.32/29.12  tff(decl_65226, type, 'Recognize': $i).
% 29.32/29.12  tff(decl_65227, type, acknowledge: $i).
% 29.32/29.12  tff(decl_65228, type, recognise: $i).
% 29.32/29.12  tff(decl_65229, type, discern: $i).
% 29.32/29.12  tff(decl_65230, type, 'pick out': $i).
% 29.32/29.12  tff(decl_65231, type, pick_out: $i).
% 29.32/29.12  tff(decl_65232, type, 'make out': $i).
% 29.32/29.12  tff(decl_65233, type, make_out: $i).
% 29.32/29.12  tff(decl_65234, type, 'tell apart': $i).
% 29.32/29.12  tff(decl_65235, type, tell_apart: $i).
% 29.32/29.12  tff(decl_65236, type, 'Recombinant': $i).
% 29.32/29.12  tff(decl_65237, type, 'An offspring whose phenotype differs from that of the parents.': $i).
% 29.32/29.12  tff(decl_65238, type, recombinants: $i).
% 29.32/29.12  tff(decl_65239, type, recombinant: $i).
% 29.32/29.12  tff(decl_65240, type, fn_recombinant_1: $i > $i).
% 29.32/29.12  tff(decl_65241, type, fn_recombinant_2: $i > $i).
% 29.32/29.12  tff(decl_65242, type, fn_recombinant_3: $i > $i).
% 29.32/29.12  tff(decl_65243, type, fn_recombinant_4: $i > $i).
% 29.32/29.12  tff(decl_65244, type, 'Recombinant-Chromosome': $i).
% 29.32/29.12  tff(decl_65245, type, 'A chromosome that combines the DNA from two parents, due to crossing over events in meiosis.': $i).
% 29.32/29.12  tff(decl_65246, type, 'chromosome of recombinant': $i).
% 29.32/29.12  tff(decl_65247, type, 'recombinant chromosome': $i).
% 29.32/29.12  tff(decl_65248, type, 'recombinant-chromosome': $i).
% 29.32/29.12  tff(decl_65249, type, fn_recombinant_chromosome_1: $i > $i).
% 29.32/29.12  tff(decl_65250, type, fn_recombinant_chromosome_2: $i > $i).
% 29.32/29.12  tff(decl_65251, type, 'Recombinant-DNA': $i).
% 29.32/29.12  tff(decl_65252, type, 'A DNA molecule made in vitro with segments from different sources.': $i).
% 29.32/29.12  tff(decl_65253, type, rdna: $i).
% 29.32/29.12  tff(decl_65254, type, 'chimeric dna': $i).
% 29.32/29.12  tff(decl_65255, type, 'chimeric-dna': $i).
% 29.32/29.12  tff(decl_65256, type, 'dna of recombinant': $i).
% 29.32/29.12  tff(decl_65257, type, 'recombinant dna': $i).
% 29.32/29.12  tff(decl_65258, type, 'recombinant-dna': $i).
% 29.32/29.12  tff(decl_65259, type, fn_recombinant_dna_5: $i > $i).
% 29.32/29.12  tff(decl_65260, type, fn_recombinant_dna_6: $i > $i).
% 29.32/29.12  tff(decl_65261, type, fn_recombinant_dna_7: $i > $i).
% 29.32/29.12  tff(decl_65262, type, fn_recombinant_dna_8: $i > $i).
% 29.32/29.12  tff(decl_65263, type, fn_recombinant_dna_9: $i > $i).
% 29.32/29.12  tff(decl_65264, type, fn_recombinant_dna_10: $i > $i).
% 29.32/29.12  tff(decl_65265, type, fn_recombinant_dna_11: $i > $i).
% 29.32/29.12  tff(decl_65266, type, fn_recombinant_dna_12: $i > $i).
% 29.32/29.12  tff(decl_65267, type, fn_recombinant_dna_13: $i > $i).
% 29.32/29.12  tff(decl_65268, type, fn_recombinant_dna_14: $i > $i).
% 29.32/29.12  tff(decl_65269, type, fn_recombinant_dna_15: $i > $i).
% 29.32/29.12  tff(decl_65270, type, fn_recombinant_dna_16: $i > $i).
% 29.32/29.12  tff(decl_65271, type, fn_recombinant_dna_17: $i > $i).
% 29.32/29.12  tff(decl_65272, type, fn_recombinant_dna_19: $i > $i).
% 29.32/29.12  tff(decl_65273, type, fn_recombinant_dna_4: $i > $i).
% 29.32/29.12  tff(decl_65274, type, fn_recombinant_dna_3: $i > $i).
% 29.32/29.12  tff(decl_65275, type, fn_recombinant_dna_2: $i > $i).
% 29.32/29.12  tff(decl_65276, type, fn_recombinant_dna_1: $i > $i).
% 29.32/29.12  tff(decl_65277, type, 'Recombinant-DNA-Technology': $i).
% 29.32/29.12  tff(decl_65278, type, 'Recombinant DNA is a DNA molecule made in vitro with segments from different sources.': $i).
% 29.32/29.12  tff(decl_65279, type, 'recombinant dna technology': $i).
% 29.32/29.12  tff(decl_65280, type, 'recombinant-dna-technology': $i).
% 29.32/29.12  tff(decl_65281, type, 'Recombinant-Immune-Cell': $i).
% 29.32/29.12  tff(decl_65282, type, 'An invertrbrate immune cell whose genome has undergone permanent rearrangement.': $i).
% 29.32/29.12  tff(decl_65283, type, 'recombinant immune cell': $i).
% 29.32/29.12  tff(decl_65284, type, 'recombinant-immune-cell': $i).
% 29.32/29.12  tff(decl_65285, type, 'Recombinant-Plasmid': $i).
% 29.32/29.12  tff(decl_65286, type, 'A recombinant plasmid is produced by inserting DNA into plasmids.': $i).
% 29.32/29.12  tff(decl_65287, type, 'plasmid of recombinant': $i).
% 29.32/29.12  tff(decl_65288, type, 'recombinant plasmid': $i).
% 29.32/29.12  tff(decl_65289, type, 'recombinant-plasmid': $i).
% 29.32/29.12  tff(decl_65290, type, fn_recombinant_plasmid_1: $i > $i).
% 29.32/29.12  tff(decl_65291, type, fn_recombinant_plasmid_2: $i > $i).
% 29.32/29.12  tff(decl_65292, type, 'Recombination': $i).
% 29.32/29.12  tff(decl_65293, type, 'Genetic recombination, the process by which genetic material is broken and joined to other genetic material.': $i).
% 29.32/29.12  tff(decl_65294, type, 'Recombination-Frequency': $i).
% 29.32/29.12  tff(decl_65295, type, 'Probability of recombination event.': $i).
% 29.32/29.12  tff(decl_65296, type, 'frequency of recombination': $i).
% 29.32/29.12  tff(decl_65297, type, 'recombination frequency': $i).
% 29.32/29.12  tff(decl_65298, type, 'recombination-frequency': $i).
% 29.32/29.12  tff(decl_65299, type, record_1: $i > $o).
% 29.32/29.12  tff(decl_65300, type, 'Record': $i).
% 29.32/29.12  tff(decl_65301, type, record: $i).
% 29.32/29.12  tff(decl_65302, type, tape: $i).
% 29.32/29.12  tff(decl_65303, type, recording: $i).
% 29.32/29.12  tff(decl_65304, type, transcription: $i).
% 29.32/29.12  tff(decl_65305, type, fn_record_1: $i > $i).
% 29.32/29.12  tff(decl_65306, type, 'Recording': $i).
% 29.32/29.12  tff(decl_65307, type, 'A kind of Message created by a Sensor as the result of a Record event.': $i).
% 29.32/29.12  tff(decl_65308, type, fn_recording_1: $i > $i).
% 29.32/29.12  tff(decl_65309, type, recreate_1: $i > $o).
% 29.32/29.12  tff(decl_65310, type, 'Recreate': $i).
% 29.32/29.12  tff(decl_65311, type, 'To make again or make anew.': $i).
% 29.32/29.12  tff(decl_65312, type, 're form': $i).
% 29.32/29.12  tff(decl_65313, type, reform: $i).
% 29.32/29.12  tff(decl_65314, type, recreate: $i).
% 29.32/29.12  tff(decl_65315, type, fn_recreate_1: $i > $i).
% 29.32/29.12  tff(decl_65316, type, fn_recreate_2: $i > $i).
% 29.32/29.12  tff(decl_65317, type, fn_recreate_3: $i > $i).
% 29.32/29.12  tff(decl_65318, type, recruitment_1: $i > $o).
% 29.32/29.12  tff(decl_65319, type, 'Recruitment': $i).
% 29.32/29.12  tff(decl_65320, type, 'The process of progressively increasing the tension of a muscle by activating more and more of the motor neurons controlling the muscle.': $i).
% 29.32/29.12  tff(decl_65321, type, recruit: $i).
% 29.32/29.12  tff(decl_65322, type, recruitment: $i).
% 29.32/29.12  tff(decl_65323, type, 'Rectum': $i).
% 29.32/29.12  tff(decl_65324, type, 'The distal part of the large intestine, where feces are stored until the animal defecates.': $i).
% 29.32/29.12  tff(decl_65325, type, rectum: $i).
% 29.32/29.12  tff(decl_65326, type, fn_rectum_1: $i > $i).
% 29.32/29.12  tff(decl_65327, type, fn_rectum_2: $i > $i).
% 29.32/29.12  tff(decl_65328, type, fn_rectum_3: $i > $i).
% 29.32/29.12  tff(decl_65329, type, fn_rectum_4: $i > $i).
% 29.32/29.12  tff(decl_65330, type, fn_rectum_5: $i > $i).
% 29.32/29.12  tff(decl_65331, type, fn_rectum_6: $i > $i).
% 29.32/29.12  tff(decl_65332, type, fn_recycling_of_amino_acid_5: $i > $i).
% 29.32/29.12  tff(decl_65333, type, 'Recycling-Of-Amino-Acid': $i).
% 29.32/29.12  tff(decl_65334, type, 'The break down of proteins via hydrolysis to form amino acids.  These amino acids will then be used for protein synthesis or metabolism as in glycolysis or the citric acid cycle.  Recycling of Amino Acids is an important process when the cell is starved of amino acids from an outside source.  It cannibalizes its own proteins to provide itself with amino acids.': $i).
% 29.32/29.12  tff(decl_65335, type, 'recycling of amino acid': $i).
% 29.32/29.12  tff(decl_65336, type, 'recycling-of-amino-acid': $i).
% 29.32/29.12  tff(decl_65337, type, fn_recycling_of_amino_acid_1: $i > $i).
% 29.32/29.12  tff(decl_65338, type, fn_recycling_of_amino_acid_3: $i > $i).
% 29.32/29.12  tff(decl_65339, type, fn_recycling_of_amino_acid_4: $i > $i).
% 29.32/29.12  tff(decl_65340, type, fn_recycling_of_amino_acid_6: $i > $i).
% 29.32/29.12  tff(decl_65341, type, recycling_of_oxygen_1: $i > $o).
% 29.32/29.12  tff(decl_65342, type, 'Recycling-Of-Oxygen': $i).
% 29.32/29.12  tff(decl_65343, type, 'The waste product of photosynthesis, O2, restores the atmospheric oxygen consumed during cellular respiration.': $i).
% 29.32/29.12  tff(decl_65344, type, 'oxygen recycling': $i).
% 29.32/29.12  tff(decl_65345, type, 'oxygen-recycling': $i).
% 29.32/29.12  tff(decl_65346, type, 'recycling of oxygen': $i).
% 29.32/29.12  tff(decl_65347, type, 'recycling-of-oxygen': $i).
% 29.32/29.12  tff(decl_65348, type, fn_recycling_of_oxygen_1: $i > $i).
% 29.32/29.12  tff(decl_65349, type, fn_recycling_of_oxygen_2: $i > $i).
% 29.32/29.12  tff(decl_65350, type, red_algae_1: $i > $o).
% 29.32/29.12  tff(decl_65351, type, 'Red-Algae': $i).
% 29.32/29.12  tff(decl_65352, type, 'Photosynthetic protists in the phylum Rhodophyta, whose red pigments cover the green of chlorophyll. Most are marine and multicellular.': $i).
% 29.32/29.12  tff(decl_65353, type, 'algae of red': $i).
% 29.32/29.12  tff(decl_65354, type, 'red algae': $i).
% 29.32/29.12  tff(decl_65355, type, 'red-algae': $i).
% 29.32/29.12  tff(decl_65356, type, 'Red-Cockaded-Woodpecker': $i).
% 29.32/29.12  tff(decl_65357, type, 'Picoides borealis, a woodpecker native to southeastern North America.': $i).
% 29.32/29.12  tff(decl_65358, type, 'red cockaded woodpecker': $i).
% 29.32/29.12  tff(decl_65359, type, 'red-cockaded woodpecker': $i).
% 29.32/29.12  tff(decl_65360, type, 'red-cockaded-woodpecker': $i).
% 29.32/29.12  tff(decl_65361, type, 'Red-Light': $i).
% 29.32/29.12  tff(decl_65362, type, 'The portion of the electromagnetic spectrum that can be detected as red by the human eye, ranging in wavelength from about 620 nm to 750 nm.': $i).
% 29.32/29.12  tff(decl_65363, type, 'light of red': $i).
% 29.32/29.12  tff(decl_65364, type, 'red light': $i).
% 29.32/29.12  tff(decl_65365, type, 'red-light': $i).
% 29.32/29.12  tff(decl_65366, type, fn_red_light_3: $i > $i).
% 29.32/29.12  tff(decl_65367, type, fn_red_light_5: $i > $i).
% 29.32/29.12  tff(decl_65368, type, fn_red_light_6: $i > $i).
% 29.32/29.12  tff(decl_65369, type, fn_red_light_9: $i > $i).
% 29.32/29.12  tff(decl_65370, type, fn_red_light_11: $i > $i).
% 29.32/29.12  tff(decl_65371, type, "620.0e0": $i).
% 29.32/29.12  tff(decl_65372, type, fn_red_light_12: $i > $i).
% 29.32/29.12  tff(decl_65373, type, fn_red_light_8: $i > $i).
% 29.32/29.12  tff(decl_65374, type, 'Red-Tide': $i).
% 29.32/29.12  tff(decl_65375, type, 'A rapid population explosion of phytoplankton in coastal areas, resulting in population densities high enough to color the water. Some red tide species produce toxins and a red tide of these organisms is referred to as a harmful algal bloom.': $i).
% 29.32/29.12  tff(decl_65376, type, 'tide of red': $i).
% 29.32/29.12  tff(decl_65377, type, 'Redox-Reaction': $i).
% 29.32/29.12  tff(decl_65378, type, 'Redox (shorthand for oxidation-reduction) reactions describe all chemical reactions in which atoms have their oxidation number (oxidation state) changed.': $i).
% 29.32/29.12  tff(decl_65379, type, 'redox process': $i).
% 29.32/29.12  tff(decl_65380, type, 'oxidation reduction': $i).
% 29.32/29.12  tff(decl_65381, type, 'oxidation-reduction': $i).
% 29.32/29.12  tff(decl_65382, type, 'reduction oxidation': $i).
% 29.32/29.12  tff(decl_65383, type, 'reduction-oxidation': $i).
% 29.32/29.12  tff(decl_65384, type, 'transfer of electron': $i).
% 29.32/29.12  tff(decl_65385, type, 'electron transfer': $i).
% 29.32/29.12  tff(decl_65386, type, 'reaction of redox': $i).
% 29.32/29.12  tff(decl_65387, type, 'redox reaction': $i).
% 29.32/29.12  tff(decl_65388, type, 'redox-reaction': $i).
% 29.32/29.12  tff(decl_65389, type, fn_redox_reaction_4: $i > $i).
% 29.32/29.12  tff(decl_65390, type, 'Reducing-Agent': $i).
% 29.32/29.12  tff(decl_65391, type, 'The electron donor in a redox reaction.': $i).
% 29.32/29.12  tff(decl_65392, type, 'reducing agent': $i).
% 29.32/29.12  tff(decl_65393, type, 'agent of reduction': $i).
% 29.32/29.12  tff(decl_65394, type, 'agent of reducing': $i).
% 29.32/29.12  tff(decl_65395, type, 'reducing-agent': $i).
% 29.32/29.12  tff(decl_65396, type, 'Reduction': $i).
% 29.32/29.12  tff(decl_65397, type, 'A reaction in which the atoms in an element accept electrons.': $i).
% 29.32/29.12  tff(decl_65398, type, reduce: $i).
% 29.32/29.12  tff(decl_65399, type, reduction: $i).
% 29.32/29.12  tff(decl_65400, type, 'Reduction-In-Calvin-Cycle': $i).
% 29.32/29.12  tff(decl_65401, type, 'The second phase of the calvin cycle often called Reduction which includes phosphorylation of 3-Phosphoglycerate and reduction of 1,3-bisphosphoglycerate to glyceraldehyde-3-phosphate.': $i).
% 29.32/29.12  tff(decl_65402, type, 'calvin cycle reduction': $i).
% 29.32/29.12  tff(decl_65403, type, 'calvin-cycle-reduction': $i).
% 29.32/29.12  tff(decl_65404, type, 'reduction in calvin cycle': $i).
% 29.32/29.12  tff(decl_65405, type, 'reduction-in-calvin-cycle': $i).
% 29.32/29.12  tff(decl_65406, type, fn_reduction_in_calvin_cycle_3: $i > $i).
% 29.32/29.12  tff(decl_65407, type, fn_reduction_in_calvin_cycle_7: $i > $i).
% 29.32/29.12  tff(decl_65408, type, fn_reduction_in_calvin_cycle_11: $i > $i).
% 29.32/29.12  tff(decl_65409, type, fn_reduction_in_calvin_cycle_12: $i > $i).
% 29.32/29.12  tff(decl_65410, type, fn_reduction_in_calvin_cycle_13: $i > $i).
% 29.32/29.12  tff(decl_65411, type, fn_reduction_in_calvin_cycle_14: $i > $i).
% 29.32/29.12  tff(decl_65412, type, fn_reduction_in_calvin_cycle_15: $i > $i).
% 29.32/29.12  tff(decl_65413, type, reductionism_1: $i > $o).
% 29.32/29.12  tff(decl_65414, type, 'Reductionism': $i).
% 29.32/29.12  tff(decl_65415, type, 'The practice of reducing complex systems to simpler components that are more manageable to study.': $i).
% 29.32/29.12  tff(decl_65416, type, reductionism: $i).
% 29.32/29.12  tff(decl_65417, type, 'Redundancy-Model': $i).
% 29.32/29.12  tff(decl_65418, type, 'A model of community structure which assumes that more than one species fills a given niche in an ecosystem; thus, the loss of one species does not create conditions from which the ecosystem cannot recover.': $i).
% 29.32/29.12  tff(decl_65419, type, 'model of redundancy': $i).
% 29.32/29.12  tff(decl_65420, type, 'redundancy model': $i).
% 29.32/29.12  tff(decl_65421, type, 'redundancy-model': $i).
% 29.32/29.12  tff(decl_65422, type, 'Reeling-Mechanism': $i).
% 29.32/29.12  tff(decl_65423, type, 'Mechanism for the movement of chromosomes during anaphase in which an enzyme depolymerizes the kinetochore microtubules as motor proteins wind up or reel in the kinetochores, resulting in movement of the chromosomes.': $i).
% 29.32/29.12  tff(decl_65424, type, 'reeling mechanism': $i).
% 29.32/29.12  tff(decl_65425, type, 'reeling-mechanism': $i).
% 29.32/29.12  tff(decl_65426, type, 'Reflex': $i).
% 29.32/29.12  tff(decl_65427, type, 'An involuntary and automatic reaction to a stimulus.': $i).
% 29.32/29.12  tff(decl_65428, type, reflex: $i).
% 29.32/29.12  tff(decl_65429, type, reflex_arc_1: $i > $o).
% 29.32/29.12  tff(decl_65430, type, 'Reflex-Arc': $i).
% 29.32/29.12  tff(decl_65431, type, 'The neural path that controls a reflex, which can generally be mapped as (sensory receptor)-->(spinal cord)-->(motor neuron).': $i).
% 29.32/29.12  tff(decl_65432, type, 'arc of reflex': $i).
% 29.32/29.12  tff(decl_65433, type, 'reflex arc': $i).
% 29.32/29.12  tff(decl_65434, type, 'reflex-arc': $i).
% 29.32/29.12  tff(decl_65435, type, reflexive_cliche_1: $i > $o).
% 29.32/29.12  tff(decl_65436, type, 'Reflexive-Cliche': $i).
% 29.32/29.12  tff(decl_65437, type, 'cliche of reflexive': $i).
% 29.32/29.12  tff(decl_65438, type, 'reflexive cliche': $i).
% 29.32/29.12  tff(decl_65439, type, 'reflexive-cliche': $i).
% 29.32/29.12  tff(decl_65440, type, 'Refract': $i).
% 29.32/29.12  tff(decl_65441, type, 'Refraction is the change of direction of a wave.': $i).
% 29.32/29.12  tff(decl_65442, type, refract: $i).
% 29.32/29.12  tff(decl_65443, type, refractory_period_1: $i > $o).
% 29.32/29.12  tff(decl_65444, type, 'Refractory-Period': $i).
% 29.32/29.12  tff(decl_65445, type, 'The period of time after an action potential when a neuron cannot respond to another stimulus.': $i).
% 29.32/29.12  tff(decl_65446, type, 'period of refractory': $i).
% 29.32/29.12  tff(decl_65447, type, 'refractory period': $i).
% 29.32/29.12  tff(decl_65448, type, 'refractory-period': $i).
% 29.32/29.12  tff(decl_65449, type, regeneration_1: $i > $o).
% 29.32/29.12  tff(decl_65450, type, 'Regeneration': $i).
% 29.32/29.12  tff(decl_65451, type, 'The act of forming again (especially with improvements or removal of defects).': $i).
% 29.32/29.12  tff(decl_65452, type, regenerate: $i).
% 29.32/29.12  tff(decl_65453, type, regeneration: $i).
% 29.32/29.12  tff(decl_65454, type, ribulose_bisphosphate_0: $i).
% 29.32/29.12  tff(decl_65455, type, 'Regeneration-Of-Ribulose-Bisphosphate': $i).
% 29.32/29.12  tff(decl_65456, type, 'In photosynthesis, PGA is reduced to form 3 carbon sugar, phosphoglyceraldehyde. Not all the 3 carbon sugar is converted to 6 carbon sugar. Some of it enters a series of reactions which results in regeneration of ribulose bisphosphate.': $i).
% 29.32/29.12  tff(decl_65457, type, 'regeneration of ribulose bisphosphate': $i).
% 29.32/29.12  tff(decl_65458, type, 'regeneration-of-ribulose-bisphosphate': $i).
% 29.32/29.12  tff(decl_65459, type, 'Region': $i).
% 29.32/29.12  tff(decl_65460, type, 'a Place with extent (not a point)': $i).
% 29.32/29.12  tff(decl_65461, type, region: $i).
% 29.32/29.12  tff(decl_65462, type, 'has region': $i).
% 29.32/29.12  tff(decl_65463, type, 'has-region': $i).
% 29.32/29.12  tff(decl_65464, type, 'Regular-Satellite-DNA': $i).
% 29.32/29.12  tff(decl_65465, type, 'A type of tandemly repetitive DNA with 100,000 to 10 million base pairs of repetitive DNA per site.': $i).
% 29.32/29.12  tff(decl_65466, type, 'satellite dna': $i).
% 29.32/29.12  tff(decl_65467, type, 'satellite-dna': $i).
% 29.32/29.12  tff(decl_65468, type, 'regular satellite dna': $i).
% 29.32/29.12  tff(decl_65469, type, 'regular-satellite-dna': $i).
% 29.32/29.12  tff(decl_65470, type, fn_regular_satellite_dna_1: $i > $i).
% 29.32/29.12  tff(decl_65471, type, fn_regular_satellite_dna_2: $i > $i).
% 29.32/29.12  tff(decl_65472, type, 'Regulation': $i).
% 29.32/29.12  tff(decl_65473, type, 'Regulation refers to the the control or maintenance of an entity or event.': $i).
% 29.32/29.12  tff(decl_65474, type, regulation: $i).
% 29.32/29.12  tff(decl_65475, type, 'Regulation-Of-Cell-Cycle': $i).
% 29.32/29.12  tff(decl_65476, type, 'The process of promoting or inhibiting cell division.': $i).
% 29.32/29.12  tff(decl_65477, type, 'regulation of cell cycle': $i).
% 29.32/29.12  tff(decl_65478, type, 'regulation-of-cell-cycle': $i).
% 29.32/29.12  tff(decl_65479, type, regulation_of_cell_cycle_experiment_1: $i > $o).
% 29.32/29.12  tff(decl_65480, type, 'Regulation-Of-Cell-Cycle-Experiment': $i).
% 29.32/29.12  tff(decl_65481, type, 'Experiment conducted by R.T. Johnson and colleagues at the University of Colorado in which the control of the cell cycle was studied.': $i).
% 29.32/29.12  tff(decl_65482, type, 'regulation of cell cycle experiment': $i).
% 29.32/29.12  tff(decl_65483, type, 'regulation-of-cell-cycle-experiment': $i).
% 29.32/29.12  tff(decl_65484, type, fn_regulation_of_cell_cycle_experiment_1: $i > $i).
% 29.32/29.12  tff(decl_65485, type, fn_regulation_of_cell_cycle_experiment_2: $i > $i).
% 29.32/29.12  tff(decl_65486, type, fn_regulation_of_cell_cycle_experiment_3: $i > $i).
% 29.32/29.12  tff(decl_65487, type, fn_regulation_of_cell_cycle_experiment_4: $i > $i).
% 29.32/29.12  tff(decl_65488, type, fn_regulation_of_cell_cycle_experiment_5: $i > $i).
% 29.32/29.12  tff(decl_65489, type, fn_regulation_of_cell_cycle_experiment_6: $i > $i).
% 29.32/29.12  tff(decl_65490, type, fn_regulation_of_cell_cycle_experiment_7: $i > $i).
% 29.32/29.12  tff(decl_65491, type, fn_regulation_of_cell_cycle_experiment_8: $i > $i).
% 29.32/29.12  tff(decl_65492, type, fn_regulation_of_cell_cycle_experiment_9: $i > $i).
% 29.32/29.12  tff(decl_65493, type, fn_regulation_of_cell_cycle_experiment_10: $i > $i).
% 29.32/29.12  tff(decl_65494, type, fn_regulation_of_cell_cycle_experiment_11: $i > $i).
% 29.32/29.12  tff(decl_65495, type, fn_regulation_of_cell_cycle_experiment_12: $i > $i).
% 29.32/29.12  tff(decl_65496, type, fn_regulation_of_cell_cycle_experiment_13: $i > $i).
% 29.32/29.12  tff(decl_65497, type, fn_regulation_of_cell_cycle_experiment_14: $i > $i).
% 29.32/29.12  tff(decl_65498, type, fn_regulation_of_cell_cycle_experiment_15: $i > $i).
% 29.32/29.12  tff(decl_65499, type, fn_regulation_of_cell_cycle_experiment_16: $i > $i).
% 29.32/29.12  tff(decl_65500, type, fn_regulation_of_cell_cycle_experiment_17: $i > $i).
% 29.32/29.12  tff(decl_65501, type, fn_regulation_of_cell_cycle_experiment_18: $i > $i).
% 29.32/29.12  tff(decl_65502, type, fn_regulation_of_cell_cycle_experiment_19: $i > $i).
% 29.32/29.12  tff(decl_65503, type, regulation_of_phosphatase_1: $i > $o).
% 29.32/29.12  tff(decl_65504, type, fn_regulation_of_phosphatase_3: $i > $i).
% 29.32/29.12  tff(decl_65505, type, 'Regulation-Of-Phosphatase': $i).
% 29.32/29.12  tff(decl_65506, type, 'The activation and deactivation of phosphatase by the signals in the cell.': $i).
% 29.32/29.12  tff(decl_65507, type, 'phosphatase regulation': $i).
% 29.32/29.12  tff(decl_65508, type, 'phosphatase-regulation': $i).
% 29.32/29.12  tff(decl_65509, type, 'regulation of phosphatase': $i).
% 29.32/29.12  tff(decl_65510, type, 'regulation-of-phosphatase': $i).
% 29.32/29.12  tff(decl_65511, type, fn_regulation_of_phosphatase_2: $i > $i).
% 29.32/29.12  tff(decl_65512, type, regulation_of_protein_kinase_1: $i > $o).
% 29.32/29.12  tff(decl_65513, type, 'Regulation-Of-Protein-Kinase': $i).
% 29.32/29.12  tff(decl_65514, type, 'Occurs via phosphorylation and dephosphorylation of the kinase.  Phosphorylation activates the kinase, and dephosphorylation deactivates the kinase.': $i).
% 29.32/29.12  tff(decl_65515, type, 'regulation of protein kinase': $i).
% 29.32/29.12  tff(decl_65516, type, 'regulation-of-protein-kinase': $i).
% 29.32/29.12  tff(decl_65517, type, fn_regulation_of_protein_kinase_1: $i > $i).
% 29.32/29.12  tff(decl_65518, type, 'Regulator-Animal': $i).
% 29.32/29.12  tff(decl_65519, type, 'An animal whose internal conditions remain constant due to mechanisms of homeostasis.': $i).
% 29.32/29.12  tff(decl_65520, type, 'animal of regulator': $i).
% 29.32/29.12  tff(decl_65521, type, 'regulator animal': $i).
% 29.32/29.12  tff(decl_65522, type, 'regulator-animal': $i).
% 29.32/29.12  tff(decl_65523, type, fn_regulator_animal_1: $i > $i).
% 29.32/29.12  tff(decl_65524, type, fn_regulator_animal_2: $i > $i).
% 29.32/29.12  tff(decl_65525, type, 'Regulator-Molecule': $i).
% 29.32/29.12  tff(decl_65526, type, 'Regulator molecules are molecules which control or regulate reactions and events within cells.': $i).
% 29.32/29.12  tff(decl_65527, type, regulator: $i).
% 29.32/29.12  tff(decl_65528, type, 'molecule of regulator': $i).
% 29.32/29.12  tff(decl_65529, type, 'regulator molecule': $i).
% 29.32/29.12  tff(decl_65530, type, 'regulator-molecule': $i).
% 29.32/29.12  tff(decl_65531, type, fn_regulator_molecule_1: $i > $i).
% 29.32/29.12  tff(decl_65532, type, 'Regulatory-Gene': $i).
% 29.32/29.12  tff(decl_65533, type, 'A gene whose protein product controls the transcription of a different gene or group of genes.': $i).
% 29.32/29.12  tff(decl_65534, type, 'regulatory gene': $i).
% 29.32/29.12  tff(decl_65535, type, 'regulatory-gene': $i).
% 29.32/29.12  tff(decl_65536, type, fn_regulatory_gene_3: $i > $i).
% 29.32/29.12  tff(decl_65537, type, 'Regulatory-Protein': $i).
% 29.32/29.12  tff(decl_65538, type, 'A protein that regulates activity within the cell.': $i).
% 29.32/29.12  tff(decl_65539, type, 'regulatory protein': $i).
% 29.32/29.12  tff(decl_65540, type, 'regulatory-protein': $i).
% 29.32/29.12  tff(decl_65541, type, 'Regulatory-RNA': $i).
% 29.32/29.12  tff(decl_65542, type, 'RNA which functions in the regulation and control of genes or cellular functions.': $i).
% 29.32/29.12  tff(decl_65543, type, 'regulatory rna': $i).
% 29.32/29.12  tff(decl_65544, type, 'regulatory-rna': $i).
% 29.32/29.12  tff(decl_65545, type, regulatory_sequence_of_rna_1: $i > $o).
% 29.32/29.12  tff(decl_65546, type, fn_regulatory_sequence_of_rna_4: $i > $i).
% 29.32/29.12  tff(decl_65547, type, fn_regulatory_sequence_of_rna_1: $i > $i).
% 29.32/29.12  tff(decl_65548, type, 'Regulatory-Sequence-Of-RNA': $i).
% 29.32/29.12  tff(decl_65549, type, 'A sequence of RNA that binds to regulatory proteins to control intron-exon choices.': $i).
% 29.32/29.12  tff(decl_65550, type, 'regulatory sequence of rna': $i).
% 29.32/29.12  tff(decl_65551, type, 'regulatory-sequence-of-rna': $i).
% 29.32/29.12  tff(decl_65552, type, transcribed_terminator_1: $i > $o).
% 29.32/29.12  tff(decl_65553, type, fn_regulatory_sequence_of_rna_3: $i > $i).
% 29.32/29.12  tff(decl_65554, type, regulatory_system_1: $i > $o).
% 29.32/29.12  tff(decl_65555, type, 'Regulatory-System': $i).
% 29.32/29.12  tff(decl_65556, type, 'A system of organs that control the activities of other organ systems in the body.': $i).
% 29.32/29.12  tff(decl_65557, type, 'regulatory system': $i).
% 29.32/29.12  tff(decl_65558, type, 'regulatory-system': $i).
% 29.32/29.12  tff(decl_65559, type, regurgitation_1: $i > $o).
% 29.32/29.12  tff(decl_65560, type, 'Regurgitation': $i).
% 29.32/29.12  tff(decl_65561, type, 'In animals, refers to the controlled vomiting of stomach materials for further chewing and digestion (as in ruminants) or feeding of young (as in some birds).': $i).
% 29.32/29.12  tff(decl_65562, type, regurgitate: $i).
% 29.32/29.12  tff(decl_65563, type, regurgitation: $i).
% 29.32/29.12  tff(decl_65564, type, 'Reinforcement': $i).
% 29.32/29.12  tff(decl_65565, type, 'A process in which natural selection strengthens reproductive isolation and reduces the chances that hybrids will form.': $i).
% 29.32/29.12  tff(decl_65566, type, reinforce: $i).
% 29.32/29.12  tff(decl_65567, type, reinforcement: $i).
% 29.32/29.12  tff(decl_65568, type, fn_rejection_of_foreign_cell_1: $i > $i).
% 29.32/29.12  tff(decl_65569, type, 'Rejection-Of-Foreign-Cell': $i).
% 29.32/29.12  tff(decl_65570, type, 'The situation where cells from another person (as in transplanted tissues and organs) can be recognized as foreign and attached by immune defenses.': $i).
% 29.32/29.12  tff(decl_65571, type, reject: $i).
% 29.32/29.12  tff(decl_65572, type, 'rejection of foreign cell': $i).
% 29.32/29.12  tff(decl_65573, type, 'rejection-of-foreign-cell': $i).
% 29.32/29.12  tff(decl_65574, type, fn_rejection_of_foreign_cell_3: $i > $i).
% 29.32/29.12  tff(decl_65575, type, fn_vertebrate_13: $i > $i).
% 29.32/29.12  tff(decl_65576, type, 'Relation': $i).
% 29.32/29.12  tff(decl_65577, type, 'Relative-Relationship': $i).
% 29.32/29.12  tff(decl_65578, type, 'A comparison between entities.': $i).
% 29.32/29.12  tff(decl_65579, type, 'relationship of relative': $i).
% 29.32/29.12  tff(decl_65580, type, 'relative relationship': $i).
% 29.32/29.12  tff(decl_65581, type, 'relative-relationship': $i).
% 29.32/29.12  tff(decl_65582, type, 'Relay-Molecule': $i).
% 29.32/29.12  tff(decl_65583, type, 'A molecule that transmits the initial signal to other proteins in the cell triggering a cellular response.': $i).
% 29.32/29.12  tff(decl_65584, type, 'molecule of relay': $i).
% 29.32/29.12  tff(decl_65585, type, 'relay molecule': $i).
% 29.32/29.12  tff(decl_65586, type, 'relay-molecule': $i).
% 29.32/29.12  tff(decl_65587, type, 'Relay-Protein': $i).
% 29.32/29.12  tff(decl_65588, type, 'A protein that transmits a signal the initial signal to other proteins in the cell triggering a cellular response.': $i).
% 29.32/29.12  tff(decl_65589, type, 'protein of relay': $i).
% 29.32/29.12  tff(decl_65590, type, 'relay protein': $i).
% 29.32/29.12  tff(decl_65591, type, 'relay-protein': $i).
% 29.32/29.12  tff(decl_65592, type, 'Release': $i).
% 29.32/29.12  tff(decl_65593, type, turn: $i).
% 29.32/29.12  tff(decl_65594, type, release_factor_1: $i > $o).
% 29.32/29.12  tff(decl_65595, type, 'Release-Factor': $i).
% 29.32/29.12  tff(decl_65596, type, 'Release factor is a protein which causes the termination of translation process (Synthesis of protein). The Release factor binds at A site of a Ribosome to release the finished polypeptide from the tRNA present in P site': $i).
% 29.32/29.12  tff(decl_65597, type, 'release factor': $i).
% 29.32/29.12  tff(decl_65598, type, 'release-factor': $i).
% 29.32/29.12  tff(decl_65599, type, 'factor of release': $i).
% 29.32/29.12  tff(decl_65600, type, fn_release_factor_1: $i > $i).
% 29.32/29.12  tff(decl_65601, type, 'Release-Of-Calcium-Ion-By-Cell': $i).
% 29.32/29.12  tff(decl_65602, type, 'Release of calcium ions across plasma membrane via active transport.': $i).
% 29.32/29.12  tff(decl_65603, type, 'release of calcium ion by cell': $i).
% 29.32/29.12  tff(decl_65604, type, 'release-of-calcium-ion-by-cell': $i).
% 29.32/29.12  tff(decl_65605, type, release_of_calcium_ion_by_endoplasmic_reticulum_1: $i > $o).
% 29.32/29.12  tff(decl_65606, type, fn_release_of_calcium_ion_by_cell_4: $i > $i).
% 29.32/29.12  tff(decl_65607, type, fn_release_of_calcium_ion_by_cell_5: $i > $i).
% 29.32/29.12  tff(decl_65608, type, fn_release_of_calcium_ion_by_cell_6: $i > $i).
% 29.32/29.12  tff(decl_65609, type, fn_release_of_calcium_ion_by_cell_7: $i > $i).
% 29.32/29.12  tff(decl_65610, type, fn_release_of_calcium_ion_by_cell_8: $i > $i).
% 29.32/29.12  tff(decl_65611, type, fn_release_of_calcium_ion_by_cell_9: $i > $i).
% 29.32/29.12  tff(decl_65612, type, fn_release_of_calcium_ion_by_cell_10: $i > $i).
% 29.32/29.12  tff(decl_65613, type, fn_release_of_calcium_ion_by_cell_11: $i > $i).
% 29.32/29.12  tff(decl_65614, type, fn_release_of_calcium_ion_by_cell_12: $i > $i).
% 29.32/29.12  tff(decl_65615, type, fn_release_of_calcium_ion_by_cell_13: $i > $i).
% 29.32/29.12  tff(decl_65616, type, fn_release_of_calcium_ion_by_cell_14: $i > $i).
% 29.32/29.12  tff(decl_65617, type, fn_release_of_calcium_ion_by_cell_15: $i > $i).
% 29.32/29.12  tff(decl_65618, type, fn_release_of_calcium_ion_by_cell_16: $i > $i).
% 29.32/29.12  tff(decl_65619, type, fn_release_of_calcium_ion_by_cell_17: $i > $i).
% 29.32/29.12  tff(decl_65620, type, fn_release_of_calcium_ion_by_cell_18: $i > $i).
% 29.32/29.12  tff(decl_65621, type, fn_release_of_calcium_ion_by_cell_19: $i > $i).
% 29.32/29.12  tff(decl_65622, type, fn_release_of_calcium_ion_by_cell_20: $i > $i).
% 29.32/29.12  tff(decl_65623, type, fn_release_of_calcium_ion_by_cell_21: $i > $i).
% 29.32/29.12  tff(decl_65624, type, fn_release_of_calcium_ion_by_cell_22: $i > $i).
% 29.32/29.12  tff(decl_65625, type, fn_release_of_calcium_ion_by_cell_23: $i > $i).
% 29.32/29.12  tff(decl_65626, type, fn_release_of_calcium_ion_by_cell_24: $i > $i).
% 29.32/29.12  tff(decl_65627, type, fn_release_of_calcium_ion_by_cell_25: $i > $i).
% 29.32/29.12  tff(decl_65628, type, fn_release_of_calcium_ion_by_cell_26: $i > $i).
% 29.32/29.12  tff(decl_65629, type, fn_release_of_calcium_ion_by_cell_27: $i > $i).
% 29.32/29.12  tff(decl_65630, type, fn_release_of_calcium_ion_by_cell_28: $i > $i).
% 29.32/29.12  tff(decl_65631, type, fn_release_of_calcium_ion_by_cell_29: $i > $i).
% 29.32/29.12  tff(decl_65632, type, fn_release_of_calcium_ion_by_cell_30: $i > $i).
% 29.32/29.12  tff(decl_65633, type, fn_release_of_calcium_ion_by_cell_33: $i > $i).
% 29.32/29.12  tff(decl_65634, type, fn_release_of_calcium_ion_by_cell_34: $i > $i).
% 29.32/29.12  tff(decl_65635, type, fn_release_of_calcium_ion_by_cell_39: $i > $i).
% 29.32/29.12  tff(decl_65636, type, fn_release_of_calcium_ion_by_cell_40: $i > $i).
% 29.32/29.12  tff(decl_65637, type, fn_release_of_calcium_ion_by_cell_41: $i > $i).
% 29.32/29.12  tff(decl_65638, type, fn_release_of_calcium_ion_by_cell_42: $i > $i).
% 29.32/29.12  tff(decl_65639, type, fn_release_of_calcium_ion_by_cell_43: $i > $i).
% 29.32/29.12  tff(decl_65640, type, fn_release_of_calcium_ion_by_cell_44: $i > $i).
% 29.32/29.12  tff(decl_65641, type, fn_release_of_calcium_ion_by_cell_45: $i > $i).
% 29.32/29.12  tff(decl_65642, type, fn_release_of_calcium_ion_by_cell_46: $i > $i).
% 29.32/29.12  tff(decl_65643, type, fn_release_of_calcium_ion_by_cell_49: $i > $i).
% 29.32/29.12  tff(decl_65644, type, fn_release_of_calcium_ion_by_cell_50: $i > $i).
% 29.32/29.12  tff(decl_65645, type, fn_release_of_calcium_ion_by_cell_55: $i > $i).
% 29.32/29.12  tff(decl_65646, type, fn_release_of_calcium_ion_by_cell_56: $i > $i).
% 29.32/29.12  tff(decl_65647, type, fn_release_of_calcium_ion_by_cell_57: $i > $i).
% 29.32/29.12  tff(decl_65648, type, fn_release_of_calcium_ion_by_cell_59: $i > $i).
% 29.32/29.12  tff(decl_65649, type, fn_release_of_calcium_ion_by_cell_61: $i > $i).
% 29.32/29.12  tff(decl_65650, type, fn_release_of_calcium_ion_by_cell_62: $i > $i).
% 29.32/29.12  tff(decl_65651, type, fn_release_of_calcium_ion_by_cell_63: $i > $i).
% 29.32/29.12  tff(decl_65652, type, fn_release_of_calcium_ion_by_cell_64: $i > $i).
% 29.32/29.12  tff(decl_65653, type, fn_release_of_calcium_ion_by_cell_65: $i > $i).
% 29.32/29.12  tff(decl_65654, type, fn_release_of_calcium_ion_by_cell_66: $i > $i).
% 29.32/29.12  tff(decl_65655, type, fn_release_of_calcium_ion_by_cell_67: $i > $i).
% 29.32/29.12  tff(decl_65656, type, fn_release_of_calcium_ion_by_cell_68: $i > $i).
% 29.32/29.12  tff(decl_65657, type, fn_release_of_calcium_ion_by_cell_69: $i > $i).
% 29.32/29.12  tff(decl_65658, type, fn_release_of_calcium_ion_by_cell_70: $i > $i).
% 29.32/29.12  tff(decl_65659, type, fn_release_of_calcium_ion_by_cell_71: $i > $i).
% 29.32/29.12  tff(decl_65660, type, fn_release_of_calcium_ion_by_cell_72: $i > $i).
% 29.32/29.12  tff(decl_65661, type, fn_release_of_calcium_ion_by_cell_73: $i > $i).
% 29.32/29.12  tff(decl_65662, type, fn_release_of_calcium_ion_by_cell_74: $i > $i).
% 29.32/29.12  tff(decl_65663, type, fn_release_of_calcium_ion_by_cell_75: $i > $i).
% 29.32/29.12  tff(decl_65664, type, fn_release_of_calcium_ion_by_cell_76: $i > $i).
% 29.32/29.12  tff(decl_65665, type, fn_release_of_calcium_ion_by_cell_77: $i > $i).
% 29.32/29.12  tff(decl_65666, type, fn_release_of_calcium_ion_by_cell_78: $i > $i).
% 29.32/29.12  tff(decl_65667, type, fn_release_of_calcium_ion_by_cell_83: $i > $i).
% 29.32/29.12  tff(decl_65668, type, fn_release_of_calcium_ion_by_cell_84: $i > $i).
% 29.32/29.12  tff(decl_65669, type, fn_release_of_calcium_ion_by_cell_85: $i > $i).
% 29.32/29.12  tff(decl_65670, type, fn_release_of_calcium_ion_by_cell_86: $i > $i).
% 29.32/29.12  tff(decl_65671, type, fn_release_of_calcium_ion_by_cell_87: $i > $i).
% 29.32/29.12  tff(decl_65672, type, fn_release_of_calcium_ion_by_cell_88: $i > $i).
% 29.32/29.12  tff(decl_65673, type, fn_release_of_calcium_ion_by_cell_89: $i > $i).
% 29.32/29.12  tff(decl_65674, type, fn_release_of_calcium_ion_by_cell_90: $i > $i).
% 29.32/29.12  tff(decl_65675, type, fn_release_of_calcium_ion_by_cell_91: $i > $i).
% 29.32/29.12  tff(decl_65676, type, fn_release_of_calcium_ion_by_cell_92: $i > $i).
% 29.32/29.12  tff(decl_65677, type, fn_release_of_calcium_ion_by_cell_93: $i > $i).
% 29.32/29.12  tff(decl_65678, type, fn_release_of_calcium_ion_by_cell_94: $i > $i).
% 29.32/29.12  tff(decl_65679, type, fn_release_of_calcium_ion_by_cell_95: $i > $i).
% 29.32/29.12  tff(decl_65680, type, fn_release_of_calcium_ion_by_cell_96: $i > $i).
% 29.32/29.12  tff(decl_65681, type, fn_release_of_calcium_ion_by_cell_97: $i > $i).
% 29.32/29.12  tff(decl_65682, type, fn_release_of_calcium_ion_by_cell_98: $i > $i).
% 29.32/29.12  tff(decl_65683, type, fn_release_of_calcium_ion_by_cell_99: $i > $i).
% 29.32/29.12  tff(decl_65684, type, fn_release_of_calcium_ion_by_cell_100: $i > $i).
% 29.32/29.12  tff(decl_65685, type, fn_release_of_calcium_ion_by_cell_101: $i > $i).
% 29.32/29.12  tff(decl_65686, type, fn_release_of_calcium_ion_by_cell_102: $i > $i).
% 29.32/29.12  tff(decl_65687, type, fn_release_of_calcium_ion_by_cell_103: $i > $i).
% 29.32/29.12  tff(decl_65688, type, fn_release_of_calcium_ion_by_cell_104: $i > $i).
% 29.32/29.12  tff(decl_65689, type, fn_release_of_calcium_ion_by_cell_109: $i > $i).
% 29.32/29.12  tff(decl_65690, type, fn_release_of_calcium_ion_by_cell_110: $i > $i).
% 29.32/29.12  tff(decl_65691, type, fn_release_of_calcium_ion_by_cell_111: $i > $i).
% 29.32/29.12  tff(decl_65692, type, fn_release_of_calcium_ion_by_cell_112: $i > $i).
% 29.32/29.12  tff(decl_65693, type, fn_release_of_calcium_ion_by_cell_113: $i > $i).
% 29.32/29.12  tff(decl_65694, type, fn_release_of_calcium_ion_by_cell_114: $i > $i).
% 29.32/29.12  tff(decl_65695, type, fn_release_of_calcium_ion_by_cell_115: $i > $i).
% 29.32/29.12  tff(decl_65696, type, fn_release_of_calcium_ion_by_cell_116: $i > $i).
% 29.32/29.12  tff(decl_65697, type, fn_release_of_calcium_ion_by_cell_117: $i > $i).
% 29.32/29.12  tff(decl_65698, type, fn_release_of_calcium_ion_by_cell_118: $i > $i).
% 29.32/29.12  tff(decl_65699, type, fn_release_of_calcium_ion_by_cell_119: $i > $i).
% 29.32/29.12  tff(decl_65700, type, fn_release_of_calcium_ion_by_cell_122: $i > $i).
% 29.32/29.12  tff(decl_65701, type, fn_release_of_calcium_ion_by_cell_123: $i > $i).
% 29.32/29.12  tff(decl_65702, type, fn_release_of_calcium_ion_by_cell_127: $i > $i).
% 29.32/29.12  tff(decl_65703, type, fn_release_of_calcium_ion_by_cell_128: $i > $i).
% 29.32/29.12  tff(decl_65704, type, fn_release_of_calcium_ion_by_cell_60: $i > $i).
% 29.32/29.12  tff(decl_65705, type, fn_release_of_calcium_ion_by_cell_38: $i > $i).
% 29.32/29.12  tff(decl_65706, type, fn_release_of_calcium_ion_by_cell_36: $i > $i).
% 29.32/29.12  tff(decl_65707, type, fn_release_of_calcium_ion_by_cell_35: $i > $i).
% 29.32/29.12  tff(decl_65708, type, fn_release_of_calcium_ion_by_cell_37: $i > $i).
% 29.32/29.12  tff(decl_65709, type, fn_release_of_calcium_ion_by_cell_32: $i > $i).
% 29.32/29.12  tff(decl_65710, type, fn_release_of_calcium_ion_by_cell_108: $i > $i).
% 29.32/29.12  tff(decl_65711, type, fn_release_of_calcium_ion_by_cell_107: $i > $i).
% 29.32/29.12  tff(decl_65712, type, fn_release_of_calcium_ion_by_cell_105: $i > $i).
% 29.32/29.12  tff(decl_65713, type, fn_release_of_calcium_ion_by_cell_106: $i > $i).
% 29.32/29.12  tff(decl_65714, type, fn_release_of_calcium_ion_by_cell_120: $i > $i).
% 29.32/29.12  tff(decl_65715, type, fn_release_of_calcium_ion_by_cell_31: $i > $i).
% 29.32/29.12  tff(decl_65716, type, fn_release_of_calcium_ion_by_cell_121: $i > $i).
% 29.32/29.12  tff(decl_65717, type, 'Release-Of-Calcium-Ion-By-Endoplasmic-Reticulum': $i).
% 29.32/29.12  tff(decl_65718, type, 'Ca2+ ions are actively transported and stored within the ER lumen. The release of the ions back into the cytosol is triggered by a signal, which in turn triggers various responses depending on what kind of cell it is.': $i).
% 29.32/29.12  tff(decl_65719, type, 'release of calcium ion by endoplasmic reticulum': $i).
% 29.32/29.12  tff(decl_65720, type, 'release-of-calcium-ion-by-endoplasmic-reticulum': $i).
% 29.32/29.12  tff(decl_65721, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_1: $i > $i).
% 29.32/29.12  tff(decl_65722, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_2: $i > $i).
% 29.32/29.12  tff(decl_65723, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_3: $i > $i).
% 29.32/29.12  tff(decl_65724, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_4: $i > $i).
% 29.32/29.12  tff(decl_65725, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_5: $i > $i).
% 29.32/29.12  tff(decl_65726, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_6: $i > $i).
% 29.32/29.12  tff(decl_65727, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_7: $i > $i).
% 29.32/29.12  tff(decl_65728, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_8: $i > $i).
% 29.32/29.12  tff(decl_65729, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_9: $i > $i).
% 29.32/29.12  tff(decl_65730, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_10: $i > $i).
% 29.32/29.12  tff(decl_65731, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_11: $i > $i).
% 29.32/29.12  tff(decl_65732, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_12: $i > $i).
% 29.32/29.12  tff(decl_65733, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_13: $i > $i).
% 29.32/29.12  tff(decl_65734, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_14: $i > $i).
% 29.32/29.12  tff(decl_65735, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_15: $i > $i).
% 29.32/29.12  tff(decl_65736, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_16: $i > $i).
% 29.32/29.12  tff(decl_65737, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_17: $i > $i).
% 29.32/29.12  tff(decl_65738, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_18: $i > $i).
% 29.32/29.12  tff(decl_65739, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_19: $i > $i).
% 29.32/29.12  tff(decl_65740, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_20: $i > $i).
% 29.32/29.12  tff(decl_65741, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_21: $i > $i).
% 29.32/29.12  tff(decl_65742, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_22: $i > $i).
% 29.32/29.12  tff(decl_65743, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_23: $i > $i).
% 29.32/29.12  tff(decl_65744, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_24: $i > $i).
% 29.32/29.12  tff(decl_65745, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_25: $i > $i).
% 29.32/29.12  tff(decl_65746, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_26: $i > $i).
% 29.32/29.12  tff(decl_65747, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_27: $i > $i).
% 29.32/29.12  tff(decl_65748, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_28: $i > $i).
% 29.32/29.12  tff(decl_65749, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_29: $i > $i).
% 29.32/29.12  tff(decl_65750, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_30: $i > $i).
% 29.32/29.12  tff(decl_65751, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_31: $i > $i).
% 29.32/29.12  tff(decl_65752, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_32: $i > $i).
% 29.32/29.12  tff(decl_65753, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_33: $i > $i).
% 29.32/29.12  tff(decl_65754, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_34: $i > $i).
% 29.32/29.12  tff(decl_65755, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_35: $i > $i).
% 29.32/29.12  tff(decl_65756, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_36: $i > $i).
% 29.32/29.12  tff(decl_65757, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_37: $i > $i).
% 29.32/29.12  tff(decl_65758, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_38: $i > $i).
% 29.32/29.12  tff(decl_65759, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_39: $i > $i).
% 29.32/29.12  tff(decl_65760, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_40: $i > $i).
% 29.32/29.12  tff(decl_65761, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_41: $i > $i).
% 29.32/29.12  tff(decl_65762, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_42: $i > $i).
% 29.32/29.12  tff(decl_65763, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_43: $i > $i).
% 29.32/29.12  tff(decl_65764, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_44: $i > $i).
% 29.32/29.12  tff(decl_65765, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_45: $i > $i).
% 29.32/29.12  tff(decl_65766, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_46: $i > $i).
% 29.32/29.12  tff(decl_65767, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_47: $i > $i).
% 29.32/29.12  tff(decl_65768, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_48: $i > $i).
% 29.32/29.12  tff(decl_65769, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_49: $i > $i).
% 29.32/29.12  tff(decl_65770, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_50: $i > $i).
% 29.32/29.12  tff(decl_65771, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_51: $i > $i).
% 29.32/29.12  tff(decl_65772, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_52: $i > $i).
% 29.32/29.12  tff(decl_65773, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_53: $i > $i).
% 29.32/29.12  tff(decl_65774, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_54: $i > $i).
% 29.32/29.12  tff(decl_65775, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_55: $i > $i).
% 29.32/29.12  tff(decl_65776, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_56: $i > $i).
% 29.32/29.12  tff(decl_65777, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_57: $i > $i).
% 29.32/29.12  tff(decl_65778, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_58: $i > $i).
% 29.32/29.12  tff(decl_65779, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_59: $i > $i).
% 29.32/29.12  tff(decl_65780, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_60: $i > $i).
% 29.32/29.12  tff(decl_65781, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_61: $i > $i).
% 29.32/29.12  tff(decl_65782, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_62: $i > $i).
% 29.32/29.12  tff(decl_65783, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_63: $i > $i).
% 29.32/29.12  tff(decl_65784, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_64: $i > $i).
% 29.32/29.12  tff(decl_65785, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_65: $i > $i).
% 29.32/29.12  tff(decl_65786, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_66: $i > $i).
% 29.32/29.12  tff(decl_65787, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_67: $i > $i).
% 29.32/29.12  tff(decl_65788, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_68: $i > $i).
% 29.32/29.12  tff(decl_65789, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_76: $i > $i).
% 29.32/29.12  tff(decl_65790, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_77: $i > $i).
% 29.32/29.12  tff(decl_65791, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_78: $i > $i).
% 29.32/29.12  tff(decl_65792, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_79: $i > $i).
% 29.32/29.12  tff(decl_65793, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_80: $i > $i).
% 29.32/29.12  tff(decl_65794, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_81: $i > $i).
% 29.32/29.12  tff(decl_65795, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_82: $i > $i).
% 29.32/29.12  tff(decl_65796, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_83: $i > $i).
% 29.32/29.12  tff(decl_65797, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_84: $i > $i).
% 29.32/29.12  tff(decl_65798, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_85: $i > $i).
% 29.32/29.12  tff(decl_65799, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_86: $i > $i).
% 29.32/29.12  tff(decl_65800, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_87: $i > $i).
% 29.32/29.12  tff(decl_65801, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_88: $i > $i).
% 29.32/29.12  tff(decl_65802, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_89: $i > $i).
% 29.32/29.12  tff(decl_65803, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_90: $i > $i).
% 29.32/29.12  tff(decl_65804, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_91: $i > $i).
% 29.32/29.12  tff(decl_65805, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_92: $i > $i).
% 29.32/29.12  tff(decl_65806, type, fn_smooth_endoplasmic_reticulum_35: $i > $i).
% 29.32/29.12  tff(decl_65807, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_69: $i > $i).
% 29.32/29.12  tff(decl_65808, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_70: $i > $i).
% 29.32/29.12  tff(decl_65809, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_72: $i > $i).
% 29.32/29.12  tff(decl_65810, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_73: $i > $i).
% 29.32/29.12  tff(decl_65811, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_74: $i > $i).
% 29.32/29.12  tff(decl_65812, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_75: $i > $i).
% 29.32/29.12  tff(decl_65813, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_71: $i > $i).
% 29.32/29.12  tff(decl_65814, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_93: $i > $i).
% 29.32/29.12  tff(decl_65815, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_94: $i > $i).
% 29.32/29.12  tff(decl_65816, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_95: $i > $i).
% 29.32/29.12  tff(decl_65817, type, fn_release_of_calcium_ion_by_endoplasmic_reticulum_96: $i > $i).
% 29.32/29.12  tff(decl_65818, type, release_resource_1: $i > $o).
% 29.32/29.12  tff(decl_65819, type, 'Release-Resource': $i).
% 29.32/29.12  tff(decl_65820, type, 'resource of release': $i).
% 29.32/29.12  tff(decl_65821, type, 'release resource': $i).
% 29.32/29.12  tff(decl_65822, type, 'release-resource': $i).
% 29.32/29.12  tff(decl_65823, type, fn_release_resource_1: $i > $i).
% 29.32/29.12  tff(decl_65824, type, fn_release_resource_2: $i > $i).
% 29.32/29.12  tff(decl_65825, type, 'Releasing-Hormone': $i).
% 29.32/29.12  tff(decl_65826, type, 'A hormone whose primary function is to control the release of another hormone.': $i).
% 29.32/29.12  tff(decl_65827, type, 'releasing hormone': $i).
% 29.32/29.12  tff(decl_65828, type, 'releasing-hormone': $i).
% 29.32/29.12  tff(decl_65829, type, 'Relinquish': $i).
% 29.32/29.12  tff(decl_65830, type, relinquish: $i).
% 29.32/29.12  tff(decl_65831, type, cede: $i).
% 29.32/29.12  tff(decl_65832, type, free: $i).
% 29.32/29.12  tff(decl_65833, type, 'give up': $i).
% 29.32/29.12  tff(decl_65834, type, give_up: $i).
% 29.32/29.12  tff(decl_65835, type, surrender: $i).
% 29.32/29.12  tff(decl_65836, type, removal_of_waste_product_by_prokaryote_using_proton_motive_force_1: $i > $o).
% 29.32/29.12  tff(decl_65837, type, 'Removal-Of-Waste-Product-By-Prokaryote-Using-Proton-Motive-Force': $i).
% 29.32/29.12  tff(decl_65838, type, 'The removal of a waste product by a prokaryote through cotransport with protons.': $i).
% 29.32/29.12  tff(decl_65839, type, remove: $i).
% 29.32/29.12  tff(decl_65840, type, 'removal of waste product by prokaryote using proton motive force': $i).
% 29.32/29.12  tff(decl_65841, type, 'removal-of-waste-product-by-prokaryote-using-proton-motive-force': $i).
% 29.32/29.12  tff(decl_65842, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_1: $i > $i).
% 29.32/29.12  tff(decl_65843, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_6: $i > $i).
% 29.32/29.12  tff(decl_65844, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_7: $i > $i).
% 29.32/29.12  tff(decl_65845, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_8: $i > $i).
% 29.32/29.12  tff(decl_65846, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_9: $i > $i).
% 29.32/29.12  tff(decl_65847, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_10: $i > $i).
% 29.32/29.12  tff(decl_65848, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_11: $i > $i).
% 29.32/29.12  tff(decl_65849, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_12: $i > $i).
% 29.32/29.12  tff(decl_65850, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_13: $i > $i).
% 29.32/29.12  tff(decl_65851, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_14: $i > $i).
% 29.32/29.12  tff(decl_65852, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_15: $i > $i).
% 29.32/29.12  tff(decl_65853, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_16: $i > $i).
% 29.32/29.12  tff(decl_65854, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_17: $i > $i).
% 29.32/29.12  tff(decl_65855, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_18: $i > $i).
% 29.32/29.12  tff(decl_65856, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_19: $i > $i).
% 29.32/29.12  tff(decl_65857, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_20: $i > $i).
% 29.32/29.12  tff(decl_65858, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_21: $i > $i).
% 29.32/29.12  tff(decl_65859, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_22: $i > $i).
% 29.32/29.12  tff(decl_65860, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_23: $i > $i).
% 29.32/29.12  tff(decl_65861, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_24: $i > $i).
% 29.32/29.12  tff(decl_65862, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_25: $i > $i).
% 29.32/29.12  tff(decl_65863, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_26: $i > $i).
% 29.32/29.12  tff(decl_65864, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_27: $i > $i).
% 29.32/29.12  tff(decl_65865, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_28: $i > $i).
% 29.32/29.12  tff(decl_65866, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_29: $i > $i).
% 29.32/29.12  tff(decl_65867, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_30: $i > $i).
% 29.32/29.12  tff(decl_65868, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_31: $i > $i).
% 29.32/29.12  tff(decl_65869, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_32: $i > $i).
% 29.32/29.12  tff(decl_65870, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_5: $i > $i).
% 29.32/29.12  tff(decl_65871, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_4: $i > $i).
% 29.32/29.12  tff(decl_65872, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_2: $i > $i).
% 29.32/29.12  tff(decl_65873, type, fn_removal_of_waste_product_by_prokaryote_using_proton_motive_force_3: $i > $i).
% 29.32/29.12  tff(decl_65874, type, 'Remove': $i).
% 29.32/29.12  tff(decl_65875, type, renal_artery_1: $i > $o).
% 29.32/29.12  tff(decl_65876, type, 'Renal-Artery': $i).
% 29.32/29.12  tff(decl_65877, type, 'The blood vessel bringing unfiltered blood to the kidney.': $i).
% 29.32/29.12  tff(decl_65878, type, 'renal artery': $i).
% 29.32/29.12  tff(decl_65879, type, 'renal-artery': $i).
% 29.32/29.12  tff(decl_65880, type, 'Renal-Cortex': $i).
% 29.32/29.12  tff(decl_65881, type, 'The outer portion of the kidney, situated between the renal medulla and the renal capsule.': $i).
% 29.32/29.12  tff(decl_65882, type, 'renal cortex': $i).
% 29.32/29.12  tff(decl_65883, type, 'renal-cortex': $i).
% 29.32/29.12  tff(decl_65884, type, 'Renal-Disease': $i).
% 29.32/29.12  tff(decl_65885, type, 'A medical condition in which the kidneys fail to adequately filter toxins and waste products from the blood. The two forms are acute (acute kidney injury) and chronic (chronic kidney disease).': $i).
% 29.32/29.12  tff(decl_65886, type, 'renal failure': $i).
% 29.32/29.12  tff(decl_65887, type, 'renal-failure': $i).
% 29.32/29.12  tff(decl_65888, type, 'kidney failure': $i).
% 29.32/29.12  tff(decl_65889, type, 'kidney-failure': $i).
% 29.32/29.12  tff(decl_65890, type, 'renal-insufficiency': $i).
% 29.32/29.12  tff(decl_65891, type, 'renal disease': $i).
% 29.32/29.12  tff(decl_65892, type, 'renal-disease': $i).
% 29.32/29.12  tff(decl_65893, type, 'Renal-Medulla': $i).
% 29.32/29.12  tff(decl_65894, type, 'The innermost part of the kidney, lying interior to the renal cortex.': $i).
% 29.32/29.12  tff(decl_65895, type, 'renal medulla': $i).
% 29.32/29.12  tff(decl_65896, type, 'renal-medulla': $i).
% 29.32/29.12  tff(decl_65897, type, 'Renal-Pelvis': $i).
% 29.32/29.12  tff(decl_65898, type, 'The funnel-shaped proximal portion of the ureter, which lies within the kidney. It collects processed filtrate from the collecting ducts and is drained by the tubule of the ureter.': $i).
% 29.32/29.12  tff(decl_65899, type, 'renal pelvis': $i).
% 29.32/29.12  tff(decl_65900, type, 'renal-pelvis': $i).
% 29.32/29.12  tff(decl_65901, type, 'Renal-Vein': $i).
% 29.32/29.12  tff(decl_65902, type, 'A blood vessel that carries filtered blood away from the kidney.': $i).
% 29.32/29.12  tff(decl_65903, type, 'renal vein': $i).
% 29.32/29.12  tff(decl_65904, type, 'renal-vein': $i).
% 29.32/29.12  tff(decl_65905, type, 'Renewable-Resource': $i).
% 29.32/29.12  tff(decl_65906, type, 'renewable resource': $i).
% 29.32/29.12  tff(decl_65907, type, renewable_resource: $i).
% 29.32/29.12  tff(decl_65908, type, 'renewable-resource': $i).
% 29.32/29.12  tff(decl_65909, type, 'Renin-Angiotensin-Aldosterone-System': $i).
% 29.32/29.12  tff(decl_65910, type, 'A negative-feedback circuit that hormonally regulates the movement of salt and water in and out of nephrons.': $i).
% 29.32/29.12  tff(decl_65911, type, raas: $i).
% 29.32/29.12  tff(decl_65912, type, 'renin angiotensin system': $i).
% 29.32/29.12  tff(decl_65913, type, 'renin-angiotensin-system': $i).
% 29.32/29.12  tff(decl_65914, type, ras: $i).
% 29.32/29.12  tff(decl_65915, type, 'renin angiotensin aldosterone system': $i).
% 29.32/29.12  tff(decl_65916, type, 'renin-angiotensin-aldosterone-system': $i).
% 29.32/29.12  tff(decl_65917, type, 'Repair': $i).
% 29.32/29.12  tff(decl_65918, type, bushel: $i).
% 29.32/29.12  tff(decl_65919, type, doctor: $i).
% 29.32/29.12  tff(decl_65920, type, 'furbish up': $i).
% 29.32/29.12  tff(decl_65921, type, furbish_up: $i).
% 29.32/29.12  tff(decl_65922, type, mend: $i).
% 29.32/29.12  tff(decl_65923, type, restore: $i).
% 29.32/29.12  tff(decl_65924, type, 'touch on': $i).
% 29.32/29.12  tff(decl_65925, type, touch_on: $i).
% 29.32/29.12  tff(decl_65926, type, 'Repair-enzyme': $i).
% 29.32/29.12  tff(decl_65927, type, 'Group of enzymes of several types which catalyze DNA repair.': $i).
% 29.32/29.12  tff(decl_65928, type, 'dna repair enzymes': $i).
% 29.32/29.12  tff(decl_65929, type, 'dna-repair-enzymes': $i).
% 29.32/29.12  tff(decl_65930, type, 'enzyme of repair': $i).
% 29.32/29.12  tff(decl_65931, type, 'repair enzyme': $i).
% 29.32/29.12  tff(decl_65932, type, 'repair-enzyme': $i).
% 29.32/29.12  tff(decl_65933, type, fn_repair_enzyme_2: $i > $i).
% 29.32/29.12  tff(decl_65934, type, skin_cell_1: $i > $o).
% 29.32/29.12  tff(decl_65935, type, 'Repeated-Gene-Duplication': $i).
% 29.32/29.12  tff(decl_65936, type, 'The repeated duplication of a gene.  It occurs when an error in DNA replication leads to the duplication of a region of DNA containing a (generally functional) gene.': $i).
% 29.32/29.12  tff(decl_65937, type, 'duplicate repeatedly': $i).
% 29.32/29.12  tff(decl_65938, type, 'repeated gene duplication': $i).
% 29.32/29.12  tff(decl_65939, type, 'repeated-gene-duplication': $i).
% 29.32/29.12  tff(decl_65940, type, fn_repeated_gene_duplication_2: $i > $i).
% 29.32/29.12  tff(decl_65941, type, fn_repeated_gene_duplication_3: $i > $i).
% 29.32/29.12  tff(decl_65942, type, fn_repeated_gene_duplication_4: $i > $i).
% 29.32/29.12  tff(decl_65943, type, fn_repeated_gene_duplication_5: $i > $i).
% 29.32/29.12  tff(decl_65944, type, fn_repeated_gene_duplication_7: $i > $i).
% 29.32/29.12  tff(decl_65945, type, repeating_units_1: $i > $o).
% 29.32/29.12  tff(decl_65946, type, 'Repeating-units': $i).
% 29.32/29.12  tff(decl_65947, type, 'Chains of linked monomers forming a macromolecule.': $i).
% 29.32/29.12  tff(decl_65948, type, 'repeating unit': $i).
% 29.32/29.12  tff(decl_65949, type, 'repeating-unit': $i).
% 29.32/29.12  tff(decl_65950, type, 'Repel': $i).
% 29.32/29.12  tff(decl_65951, type, 'To keep away or drive back.': $i).
% 29.32/29.12  tff(decl_65952, type, 'no affinity for': $i).
% 29.32/29.12  tff(decl_65953, type, 'has no affinity': $i).
% 29.32/29.12  tff(decl_65954, type, repel: $i).
% 29.32/29.12  tff(decl_65955, type, repertoire_1: $i > $o).
% 29.32/29.12  tff(decl_65956, type, 'Repertoire': $i).
% 29.32/29.12  tff(decl_65957, type, 'The suite of behaviors that an individual is capable of.': $i).
% 29.32/29.12  tff(decl_65958, type, repertoire: $i).
% 29.32/29.12  tff(decl_65959, type, 'Repetitive-DNA': $i).
% 29.32/29.12  tff(decl_65960, type, 'Nucleotide sequences that occur in many copies in a eukaryotic genome. The repeated sequences are usually noncoding and can be either long and dispersed throughout the genome, or short and repeated in tandem sequence.': $i).
% 29.32/29.12  tff(decl_65961, type, 'repetitive dna': $i).
% 29.32/29.12  tff(decl_65962, type, 'repetitive-dna': $i).
% 29.32/29.12  tff(decl_65963, type, 'Replace': $i).
% 29.32/29.12  tff(decl_65964, type, replace: $i).
% 29.32/29.12  tff(decl_65965, type, 'Replenish': $i).
% 29.32/29.12  tff(decl_65966, type, replenish: $i).
% 29.32/29.12  tff(decl_65967, type, refill: $i).
% 29.32/29.12  tff(decl_65968, type, 'fill again': $i).
% 29.32/29.12  tff(decl_65969, type, fill_again: $i).
% 29.32/29.12  tff(decl_65970, type, 'Replication': $i).
% 29.32/29.12  tff(decl_65971, type, replication: $i).
% 29.32/29.12  tff(decl_65972, type, 'Replication-bubble': $i).
% 29.32/29.12  tff(decl_65973, type, 'The part of the DNA, between the two replication forks, where the two strands have been separated for DNA synthesis to occur.': $i).
% 29.32/29.12  tff(decl_65974, type, 'bubble of replication': $i).
% 29.32/29.12  tff(decl_65975, type, 'replication bubble': $i).
% 29.32/29.12  tff(decl_65976, type, 'replication-bubble': $i).
% 29.32/29.12  tff(decl_65977, type, fn_replication_bubble_1: $i > $i).
% 29.32/29.12  tff(decl_65978, type, 'Replication-fork': $i).
% 29.32/29.12  tff(decl_65979, type, 'Replication fork is a Y-shaped structure formed at the end of replication bubble during DNA replication. It serves as the site of DNA synthesis.': $i).
% 29.32/29.12  tff(decl_65980, type, 'fork of replication': $i).
% 29.32/29.12  tff(decl_65981, type, 'replication fork': $i).
% 29.32/29.12  tff(decl_65982, type, 'replication-fork': $i).
% 29.32/29.12  tff(decl_65983, type, 'Replication-initiator-protein': $i).
% 29.32/29.12  tff(decl_65984, type, 'This is the protein which identifies the origin of replication and then binds to it. It opens up the DNA  at the origin of replication with help of other proteins': $i).
% 29.32/29.12  tff(decl_65985, type, 'origin recognition complex': $i).
% 29.32/29.12  tff(decl_65986, type, 'replication initiator protein': $i).
% 29.32/29.12  tff(decl_65987, type, 'replication-initiator-protein': $i).
% 29.32/29.12  tff(decl_65988, type, fn_replication_initiator_protein_1: $i > $i).
% 29.32/29.12  tff(decl_65989, type, reporting_1: $i > $o).
% 29.32/29.12  tff(decl_65990, type, 'Reporting': $i).
% 29.32/29.12  tff(decl_65991, type, coverage: $i).
% 29.32/29.12  tff(decl_65992, type, reportage: $i).
% 29.32/29.12  tff(decl_65993, type, news: $i).
% 29.32/29.12  tff(decl_65994, type, report: $i).
% 29.32/29.12  tff(decl_65995, type, reporting: $i).
% 29.32/29.12  tff(decl_65996, type, 'Representation': $i).
% 29.32/29.12  tff(decl_65997, type, 'A constructed presentation of some idea, object, or phenomenon.': $i).
% 29.32/29.12  tff(decl_65998, type, representation: $i).
% 29.32/29.12  tff(decl_65999, type, 'Representation-Of-Data': $i).
% 29.32/29.12  tff(decl_66000, type, 'The way in which recorded information is represented.': $i).
% 29.32/29.12  tff(decl_66001, type, 'data representation': $i).
% 29.32/29.12  tff(decl_66002, type, 'data-representation': $i).
% 29.32/29.12  tff(decl_66003, type, 'representation of data': $i).
% 29.32/29.12  tff(decl_66004, type, 'representation-of-data': $i).
% 29.32/29.12  tff(decl_66005, type, 'Repressible-Operon': $i).
% 29.32/29.12  tff(decl_66006, type, 'A string of genes in a prokaryote which is regulated by a repressor molecule.': $i).
% 29.32/29.12  tff(decl_66007, type, repressible: $i).
% 29.32/29.12  tff(decl_66008, type, 'repressible operon': $i).
% 29.32/29.12  tff(decl_66009, type, 'repressible-operon': $i).
% 29.32/29.12  tff(decl_66010, type, 'Repressor': $i).
% 29.32/29.12  tff(decl_66011, type, 'A protein that inhibits gene transcription. In prokaryotes, repressors bind to the DNA in or near the promoter. In eukaryotes, repressors may bind to control elements within enhancers, to activators, or to other proteins in a way that blocks activators from binding to DNA.': $i).
% 29.32/29.12  tff(decl_66012, type, 'repressor protein': $i).
% 29.32/29.12  tff(decl_66013, type, 'repressor enzyme': $i).
% 29.32/29.12  tff(decl_66014, type, 'repressible enzyme': $i).
% 29.32/29.12  tff(decl_66015, type, 'repressible protein': $i).
% 29.32/29.12  tff(decl_66016, type, repressor: $i).
% 29.32/29.12  tff(decl_66017, type, fn_repressor_1: $i > $i).
% 29.32/29.12  tff(decl_66018, type, fn_repressor_2: $i > $i).
% 29.32/29.12  tff(decl_66019, type, fn_repressor_3: $i > $i).
% 29.32/29.12  tff(decl_66020, type, fn_repressor_5: $i > $i).
% 29.32/29.12  tff(decl_66021, type, fn_repressor_6: $i > $i).
% 29.32/29.12  tff(decl_66022, type, 'Reproduce': $i).
% 29.32/29.12  tff(decl_66023, type, 'To produce a counterpart, image, or copy of itself is reproduce.': $i).
% 29.32/29.12  tff(decl_66024, type, 'Reproduction': $i).
% 29.32/29.12  tff(decl_66025, type, 'Any process by which new individuals are produced.': $i).
% 29.32/29.12  tff(decl_66026, type, reproduction: $i).
% 29.32/29.12  tff(decl_66027, type, fn_reproduction_4: $i > $i).
% 29.32/29.12  tff(decl_66028, type, reproductive_barrier_1: $i > $o).
% 29.32/29.12  tff(decl_66029, type, 'Reproductive-Barrier': $i).
% 29.32/29.12  tff(decl_66030, type, 'Any biological mechanism that prevents interbreeding between different species.': $i).
% 29.32/29.12  tff(decl_66031, type, 'reproductive barrier': $i).
% 29.32/29.12  tff(decl_66032, type, 'reproductive-barrier': $i).
% 29.32/29.12  tff(decl_66033, type, 'Reproductive-Barrier-Method': $i).
% 29.32/29.12  tff(decl_66034, type, 'Any method of contraception that physically blocks sperm from reaching an egg.  Examples include condoms and the diaphragm.': $i).
% 29.32/29.12  tff(decl_66035, type, 'reproductive barrier method': $i).
% 29.32/29.12  tff(decl_66036, type, 'reproductive-barrier-method': $i).
% 29.32/29.12  tff(decl_66037, type, 'Reproductive-Behavior': $i).
% 29.32/29.12  tff(decl_66038, type, 'Behaviors relating to mating and rearing of young in animals.': $i).
% 29.32/29.12  tff(decl_66039, type, 'reproductive behavior': $i).
% 29.32/29.12  tff(decl_66040, type, 'reproductive-behavior': $i).
% 29.32/29.12  tff(decl_66041, type, 'Reproductive-Cell': $i).
% 29.32/29.12  tff(decl_66042, type, 'A gamete, or a cell that gives rise to a gamete.': $i).
% 29.32/29.12  tff(decl_66043, type, 'reproductive-cell': $i).
% 29.32/29.12  tff(decl_66044, type, 'Reproductive-Cloning': $i).
% 29.32/29.12  tff(decl_66045, type, 'Reproductive cloning is a type of cloning which is performed for the purpose of creating a duplicate copy of another organism.': $i).
% 29.32/29.12  tff(decl_66046, type, 'organism cloning': $i).
% 29.32/29.12  tff(decl_66047, type, 'organism-cloning': $i).
% 29.32/29.12  tff(decl_66048, type, 'multicellular organism cloning': $i).
% 29.32/29.12  tff(decl_66049, type, 'reproductive cloning': $i).
% 29.32/29.12  tff(decl_66050, type, 'reproductive-cloning': $i).
% 29.32/29.12  tff(decl_66051, type, fn_reproductive_cloning_1: $i > $i).
% 29.32/29.12  tff(decl_66052, type, fn_reproductive_cloning_2: $i > $i).
% 29.32/29.12  tff(decl_66053, type, fn_reproductive_cloning_3: $i > $i).
% 29.32/29.12  tff(decl_66054, type, fn_reproductive_cloning_4: $i > $i).
% 29.32/29.12  tff(decl_66055, type, fn_reproductive_cloning_5: $i > $i).
% 29.32/29.12  tff(decl_66056, type, fn_reproductive_cloning_6: $i > $i).
% 29.32/29.12  tff(decl_66057, type, 'Reproductive-Cycle': $i).
% 29.32/29.12  tff(decl_66058, type, 'A cycle involving the reproduction of an organism.': $i).
% 29.32/29.12  tff(decl_66059, type, 'reproductive cycle': $i).
% 29.32/29.12  tff(decl_66060, type, 'reproductive-cycle': $i).
% 29.32/29.12  tff(decl_66061, type, reproductive_cycle_of_enveloped_virus_1: $i > $o).
% 29.32/29.12  tff(decl_66062, type, fn_reproductive_cycle_of_enveloped_virus_19: $i > $i).
% 29.32/29.12  tff(decl_66063, type, fn_reproductive_cycle_of_enveloped_virus_20: $i > $i).
% 29.32/29.12  tff(decl_66064, type, 'Reproductive-Cycle-Of-Enveloped-Virus': $i).
% 29.32/29.12  tff(decl_66065, type, 'Process of reproduction of a virus with a viral envelope, which animal viruses have.': $i).
% 29.32/29.12  tff(decl_66066, type, 'reproductive cycle of animal virus': $i).
% 29.32/29.12  tff(decl_66067, type, 'animal viral infection': $i).
% 29.32/29.12  tff(decl_66068, type, 'viral infection by animal virus': $i).
% 29.32/29.12  tff(decl_66069, type, 'viral infection by enveloped virus': $i).
% 29.32/29.12  tff(decl_66070, type, 'undergo the reproductive cycle': $i).
% 29.32/29.12  tff(decl_66071, type, 'reproductive cycle of enveloped virus': $i).
% 29.32/29.12  tff(decl_66072, type, 'reproductive-cycle-of-enveloped-virus': $i).
% 29.32/29.12  tff(decl_66073, type, fn_reproductive_cycle_of_enveloped_virus_1: $i > $i).
% 29.32/29.12  tff(decl_66074, type, fn_reproductive_cycle_of_enveloped_virus_2: $i > $i).
% 29.32/29.12  tff(decl_66075, type, fn_reproductive_cycle_of_enveloped_virus_4: $i > $i).
% 29.32/29.12  tff(decl_66076, type, fn_reproductive_cycle_of_enveloped_virus_5: $i > $i).
% 29.32/29.12  tff(decl_66077, type, fn_reproductive_cycle_of_enveloped_virus_6: $i > $i).
% 29.32/29.12  tff(decl_66078, type, fn_reproductive_cycle_of_enveloped_virus_7: $i > $i).
% 29.32/29.12  tff(decl_66079, type, fn_reproductive_cycle_of_enveloped_virus_8: $i > $i).
% 29.32/29.12  tff(decl_66080, type, fn_reproductive_cycle_of_enveloped_virus_9: $i > $i).
% 29.32/29.12  tff(decl_66081, type, fn_reproductive_cycle_of_enveloped_virus_10: $i > $i).
% 29.32/29.12  tff(decl_66082, type, fn_reproductive_cycle_of_enveloped_virus_11: $i > $i).
% 29.32/29.12  tff(decl_66083, type, fn_reproductive_cycle_of_enveloped_virus_12: $i > $i).
% 29.32/29.12  tff(decl_66084, type, take_control_1: $i > $o).
% 29.32/29.12  tff(decl_66085, type, fn_reproductive_cycle_of_enveloped_virus_13: $i > $i).
% 29.32/29.12  tff(decl_66086, type, fn_reproductive_cycle_of_enveloped_virus_14: $i > $i).
% 29.32/29.12  tff(decl_66087, type, fn_reproductive_cycle_of_enveloped_virus_15: $i > $i).
% 29.32/29.12  tff(decl_66088, type, fn_reproductive_cycle_of_enveloped_virus_16: $i > $i).
% 29.32/29.12  tff(decl_66089, type, fn_reproductive_cycle_of_enveloped_virus_17: $i > $i).
% 29.32/29.12  tff(decl_66090, type, fn_reproductive_cycle_of_enveloped_virus_18: $i > $i).
% 29.32/29.12  tff(decl_66091, type, fn_reproductive_cycle_of_enveloped_virus_21: $i > $i).
% 29.32/29.12  tff(decl_66092, type, fn_reproductive_cycle_of_enveloped_virus_22: $i > $i).
% 29.32/29.12  tff(decl_66093, type, fn_reproductive_cycle_of_enveloped_virus_23: $i > $i).
% 29.32/29.12  tff(decl_66094, type, fn_reproductive_cycle_of_enveloped_virus_24: $i > $i).
% 29.32/29.12  tff(decl_66095, type, fn_reproductive_cycle_of_enveloped_virus_25: $i > $i).
% 29.32/29.12  tff(decl_66096, type, fn_reproductive_cycle_of_enveloped_virus_26: $i > $i).
% 29.32/29.12  tff(decl_66097, type, fn_reproductive_cycle_of_enveloped_virus_27: $i > $i).
% 29.32/29.12  tff(decl_66098, type, fn_reproductive_cycle_of_enveloped_virus_28: $i > $i).
% 29.32/29.12  tff(decl_66099, type, fn_reproductive_cycle_of_enveloped_virus_29: $i > $i).
% 29.32/29.12  tff(decl_66100, type, fn_reproductive_cycle_of_enveloped_virus_30: $i > $i).
% 29.32/29.12  tff(decl_66101, type, fn_viral_envelope_11: $i > $i).
% 29.32/29.12  tff(decl_66102, type, fn_viral_infection_1: $i > $i).
% 29.32/29.12  tff(decl_66103, type, fn_viral_infection_23: $i > $i).
% 29.32/29.12  tff(decl_66104, type, fn_viral_infection_24: $i > $i).
% 29.32/29.12  tff(decl_66105, type, fn_viral_infection_14: $i > $i).
% 29.32/29.12  tff(decl_66106, type, fn_viral_infection_12: $i > $i).
% 29.32/29.12  tff(decl_66107, type, 'Reproductive-Isolation': $i).
% 29.32/29.12  tff(decl_66108, type, 'The presence of barriers to reproduction, which prevent individuals from different species from producing viable, fertile offspring.': $i).
% 29.32/29.12  tff(decl_66109, type, 'reproductive isolation': $i).
% 29.32/29.12  tff(decl_66110, type, 'reproductive-isolation': $i).
% 29.32/29.12  tff(decl_66111, type, 'Reproductive-Organ': $i).
% 29.32/29.12  tff(decl_66112, type, 'Organ which is part of the reproductive system of animals.': $i).
% 29.32/29.12  tff(decl_66113, type, 'reproductive organ': $i).
% 29.32/29.12  tff(decl_66114, type, 'reproductive-organ': $i).
% 29.32/29.12  tff(decl_66115, type, 'Reproductive-Process': $i).
% 29.32/29.12  tff(decl_66116, type, 'A process related to the reproduction of organisms.': $i).
% 29.32/29.12  tff(decl_66117, type, 'reproductive process': $i).
% 29.32/29.12  tff(decl_66118, type, 'reproductive-process': $i).
% 29.32/29.12  tff(decl_66119, type, reproductive_system_1: $i > $o).
% 29.32/29.12  tff(decl_66120, type, 'Reproductive-System': $i).
% 29.32/29.12  tff(decl_66121, type, 'System of organs and structures involved in the process of reproduction in animals or plants.': $i).
% 29.32/29.12  tff(decl_66122, type, 'reproductive system': $i).
% 29.32/29.12  tff(decl_66123, type, 'reproductive-system': $i).
% 29.32/29.12  tff(decl_66124, type, 'Reproductive-Table': $i).
% 29.32/29.12  tff(decl_66125, type, 'A summary of age-specific reproductive rates in a population, presented in tabular format.': $i).
% 29.32/29.12  tff(decl_66126, type, 'reproductive table': $i).
% 29.32/29.12  tff(decl_66127, type, 'reproductive-table': $i).
% 29.32/29.12  tff(decl_66128, type, 'Reptile': $i).
% 29.32/29.12  tff(decl_66129, type, 'Any member of the group of amniote vertebrates that includes turtles, snakes, lizards, crocodilians, tuataras, and birds.': $i).
% 29.32/29.12  tff(decl_66130, type, reptile: $i).
% 29.32/29.12  tff(decl_66131, type, 'Request': $i).
% 29.32/29.12  tff(decl_66132, type, 'Research': $i).
% 29.32/29.12  tff(decl_66133, type, research: $i).
% 29.32/29.12  tff(decl_66134, type, investigating: $i).
% 29.32/29.12  tff(decl_66135, type, 'Reserve': $i).
% 29.32/29.12  tff(decl_66136, type, 'An area set aside within a geographical region for the preservation of wildlife or natural formations.': $i).
% 29.32/29.12  tff(decl_66137, type, reserve: $i).
% 29.32/29.12  tff(decl_66138, type, 'Resource': $i).
% 29.32/29.12  tff(decl_66139, type, resource: $i).
% 29.32/29.12  tff(decl_66140, type, resource_partitioning_1: $i > $o).
% 29.32/29.12  tff(decl_66141, type, 'Resource-Partitioning': $i).
% 29.32/29.12  tff(decl_66142, type, 'The sharing of an environmental resource by two coexisting species, so that each species\\ niche differs from the niches of other species using the shared resource.': $i).
% 29.32/29.12  tff(decl_66143, type, 'partitioning of resource': $i).
% 29.32/29.12  tff(decl_66144, type, 'resource partitioning': $i).
% 29.32/29.12  tff(decl_66145, type, 'resource-partitioning': $i).
% 29.32/29.12  tff(decl_66146, type, 'Respiratory-Organ': $i).
% 29.32/29.12  tff(decl_66147, type, 'Organ which is part of the respiratory system of animals.': $i).
% 29.32/29.12  tff(decl_66148, type, 'respiratory organ': $i).
% 29.32/29.12  tff(decl_66149, type, 'respiratory-organ': $i).
% 29.32/29.12  tff(decl_66150, type, 'Respiratory-Pigment': $i).
% 29.32/29.12  tff(decl_66151, type, 'An oxygen-binding molecule that is transported in blood or hemolymph.': $i).
% 29.32/29.12  tff(decl_66152, type, 'respiratory pigment': $i).
% 29.32/29.12  tff(decl_66153, type, 'respiratory-pigment': $i).
% 29.32/29.12  tff(decl_66154, type, 'Respiratory-Process': $i).
% 29.32/29.12  tff(decl_66155, type, 'A process related to the exchange of gases in organisms.': $i).
% 29.32/29.12  tff(decl_66156, type, 'respiratory process': $i).
% 29.32/29.12  tff(decl_66157, type, 'respiratory-process': $i).
% 29.32/29.12  tff(decl_66158, type, 'Respiratory-System': $i).
% 29.32/29.12  tff(decl_66159, type, 'The organ system responsible for gas exchange.': $i).
% 29.32/29.12  tff(decl_66160, type, 'respiratory system': $i).
% 29.32/29.12  tff(decl_66161, type, 'respiratory-system': $i).
% 29.32/29.12  tff(decl_66162, type, respiratory_tract_1: $i > $o).
% 29.32/29.12  tff(decl_66163, type, 'Respiratory-Tract': $i).
% 29.32/29.12  tff(decl_66164, type, 'Region of the respiratory system which contains the airways, lungs, and respiratory passages.': $i).
% 29.32/29.12  tff(decl_66165, type, 'respiratory tract': $i).
% 29.32/29.12  tff(decl_66166, type, 'respiratory-tract': $i).
% 29.32/29.12  tff(decl_66167, type, fn_respiratory_tract_1: $i > $i).
% 29.32/29.12  tff(decl_66168, type, 'Resting-Nerve-Cell': $i).
% 29.32/29.12  tff(decl_66169, type, 'In a resting nerve cell membrane, all the sodium gates are closed and some of the potassium gates are open.': $i).
% 29.32/29.12  tff(decl_66170, type, 'resting nerve cell': $i).
% 29.32/29.12  tff(decl_66171, type, 'resting nerve-cell': $i).
% 29.32/29.12  tff(decl_66172, type, 'resting-nerve-cell': $i).
% 29.32/29.12  tff(decl_66173, type, fn_resting_nerve_cell_1: $i > $i).
% 29.32/29.12  tff(decl_66174, type, fn_resting_nerve_cell_2: $i > $i).
% 29.32/29.12  tff(decl_66175, type, fn_resting_nerve_cell_3: $i > $i).
% 29.32/29.12  tff(decl_66176, type, fn_resting_nerve_cell_5: $i > $i).
% 29.32/29.12  tff(decl_66177, type, fn_resting_nerve_cell_6: $i > $i).
% 29.32/29.12  tff(decl_66178, type, fn_resting_nerve_cell_7: $i > $i).
% 29.32/29.12  tff(decl_66179, type, fn_resting_nerve_cell_10: $i > $i).
% 29.32/29.12  tff(decl_66180, type, fn_resting_nerve_cell_11: $i > $i).
% 29.32/29.12  tff(decl_66181, type, fn_resting_nerve_cell_13: $i > $i).
% 29.32/29.12  tff(decl_66182, type, fn_resting_nerve_cell_14: $i > $i).
% 29.32/29.12  tff(decl_66183, type, fn_resting_nerve_cell_15: $i > $i).
% 29.32/29.12  tff(decl_66184, type, fn_resting_nerve_cell_17: $i > $i).
% 29.32/29.12  tff(decl_66185, type, fn_resting_nerve_cell_18: $i > $i).
% 29.32/29.12  tff(decl_66186, type, fn_resting_nerve_cell_20: $i > $i).
% 29.32/29.12  tff(decl_66187, type, fn_resting_nerve_cell_21: $i > $i).
% 29.32/29.12  tff(decl_66188, type, fn_resting_nerve_cell_22: $i > $i).
% 29.32/29.12  tff(decl_66189, type, fn_resting_nerve_cell_23: $i > $i).
% 29.32/29.12  tff(decl_66190, type, fn_resting_nerve_cell_24: $i > $i).
% 29.32/29.12  tff(decl_66191, type, fn_resting_nerve_cell_25: $i > $i).
% 29.32/29.12  tff(decl_66192, type, fn_resting_nerve_cell_26: $i > $i).
% 29.32/29.12  tff(decl_66193, type, fn_resting_nerve_cell_27: $i > $i).
% 29.32/29.12  tff(decl_66194, type, fn_resting_nerve_cell_28: $i > $i).
% 29.32/29.12  tff(decl_66195, type, fn_resting_nerve_cell_29: $i > $i).
% 29.32/29.12  tff(decl_66196, type, fn_resting_nerve_cell_30: $i > $i).
% 29.32/29.12  tff(decl_66197, type, fn_resting_nerve_cell_31: $i > $i).
% 29.32/29.12  tff(decl_66198, type, fn_resting_nerve_cell_32: $i > $i).
% 29.32/29.12  tff(decl_66199, type, fn_resting_nerve_cell_33: $i > $i).
% 29.32/29.12  tff(decl_66200, type, fn_resting_nerve_cell_34: $i > $i).
% 29.32/29.12  tff(decl_66201, type, fn_resting_nerve_cell_35: $i > $i).
% 29.32/29.12  tff(decl_66202, type, fn_resting_nerve_cell_36: $i > $i).
% 29.32/29.12  tff(decl_66203, type, fn_resting_nerve_cell_37: $i > $i).
% 29.32/29.12  tff(decl_66204, type, fn_resting_nerve_cell_39: $i > $i).
% 29.32/29.12  tff(decl_66205, type, fn_resting_nerve_cell_40: $i > $i).
% 29.32/29.12  tff(decl_66206, type, fn_resting_nerve_cell_41: $i > $i).
% 29.32/29.12  tff(decl_66207, type, fn_resting_nerve_cell_42: $i > $i).
% 29.32/29.12  tff(decl_66208, type, fn_resting_nerve_cell_43: $i > $i).
% 29.32/29.12  tff(decl_66209, type, fn_resting_nerve_cell_44: $i > $i).
% 29.32/29.12  tff(decl_66210, type, fn_resting_nerve_cell_45: $i > $i).
% 29.32/29.12  tff(decl_66211, type, fn_resting_nerve_cell_46: $i > $i).
% 29.32/29.12  tff(decl_66212, type, fn_resting_nerve_cell_47: $i > $i).
% 29.32/29.12  tff(decl_66213, type, fn_resting_nerve_cell_48: $i > $i).
% 29.32/29.12  tff(decl_66214, type, fn_resting_nerve_cell_49: $i > $i).
% 29.32/29.12  tff(decl_66215, type, fn_resting_nerve_cell_50: $i > $i).
% 29.32/29.12  tff(decl_66216, type, fn_resting_nerve_cell_51: $i > $i).
% 29.32/29.12  tff(decl_66217, type, fn_resting_nerve_cell_52: $i > $i).
% 29.32/29.12  tff(decl_66218, type, fn_resting_nerve_cell_53: $i > $i).
% 29.32/29.12  tff(decl_66219, type, fn_resting_nerve_cell_54: $i > $i).
% 29.32/29.12  tff(decl_66220, type, 'Con_SodiumIonInExtracellularMatrix': $i).
% 29.32/29.12  tff(decl_66221, type, 'Con_SodiumIonInCytoplasml': $i).
% 29.32/29.12  tff(decl_66222, type, fn_resting_nerve_cell_38: $i > $i).
% 29.32/29.12  tff(decl_66223, type, resting_potential_1: $i > $o).
% 29.32/29.12  tff(decl_66224, type, 'Resting-Potential': $i).
% 29.32/29.12  tff(decl_66225, type, 'The membrane potential of a nonconducting cell. The inside of the cell is negatively charged relative to the outside.': $i).
% 29.32/29.12  tff(decl_66226, type, 'resting potential': $i).
% 29.32/29.12  tff(decl_66227, type, 'resting-potential': $i).
% 29.32/29.12  tff(decl_66228, type, restoration_ecology_1: $i > $o).
% 29.32/29.12  tff(decl_66229, type, 'Restoration-Ecology': $i).
% 29.32/29.12  tff(decl_66230, type, 'The application of ecological principles, to return to natural conditions an ecosystem that has been disturbed by human activity.': $i).
% 29.32/29.12  tff(decl_66231, type, 'ecology of restoration': $i).
% 29.32/29.12  tff(decl_66232, type, 'restoration ecology': $i).
% 29.32/29.12  tff(decl_66233, type, 'restoration-ecology': $i).
% 29.32/29.12  tff(decl_66234, type, 'Restrain': $i).
% 29.32/29.12  tff(decl_66235, type, restrain: $i).
% 29.32/29.12  tff(decl_66236, type, 'hold back': $i).
% 29.32/29.12  tff(decl_66237, type, hold_back: $i).
% 29.32/29.12  tff(decl_66238, type, keep: $i).
% 29.32/29.12  tff(decl_66239, type, 'keep back': $i).
% 29.32/29.12  tff(decl_66240, type, keep_back: $i).
% 29.32/29.12  tff(decl_66241, type, 'Restriction-Fragment': $i).
% 29.32/29.12  tff(decl_66242, type, 'A DNA segment that results from the cutting of DNA by a restriction enzyme.': $i).
% 29.32/29.12  tff(decl_66243, type, 'fragment of restriction': $i).
% 29.32/29.12  tff(decl_66244, type, 'restriction fragment': $i).
% 29.32/29.12  tff(decl_66245, type, 'restriction-fragment': $i).
% 29.32/29.12  tff(decl_66246, type, fn_restriction_fragment_3: $i > $i).
% 29.32/29.12  tff(decl_66247, type, fn_restriction_fragment_4: $i > $i).
% 29.32/29.12  tff(decl_66248, type, fn_restriction_fragment_5: $i > $i).
% 29.32/29.12  tff(decl_66249, type, fn_restriction_fragment_7: $i > $i).
% 29.32/29.12  tff(decl_66250, type, fn_restriction_fragment_10: $i > $i).
% 29.32/29.12  tff(decl_66251, type, fn_restriction_fragment_11: $i > $i).
% 29.32/29.12  tff(decl_66252, type, fn_restriction_fragment_12: $i > $i).
% 29.32/29.12  tff(decl_66253, type, fn_restriction_fragment_13: $i > $i).
% 29.32/29.12  tff(decl_66254, type, fn_restriction_fragment_14: $i > $i).
% 29.32/29.12  tff(decl_66255, type, fn_restriction_fragment_15: $i > $i).
% 29.32/29.12  tff(decl_66256, type, fn_restriction_fragment_17: $i > $i).
% 29.32/29.12  tff(decl_66257, type, fn_restriction_fragment_9: $i > $i).
% 29.32/29.12  tff(decl_66258, type, fn_restriction_fragment_8: $i > $i).
% 29.32/29.12  tff(decl_66259, type, fn_restriction_fragment_analysis_13: $i > $i).
% 29.32/29.12  tff(decl_66260, type, 'Restriction-Fragment-Analysis': $i).
% 29.32/29.12  tff(decl_66261, type, 'A DNA analysis whereby the DNA sample is broken into pieces (digested) by restriction enzymes and the resulting restriction fragments are separated according to their lengths by gel electrophoresis.': $i).
% 29.32/29.12  tff(decl_66262, type, 'restriction fragment analysis': $i).
% 29.32/29.12  tff(decl_66263, type, 'restriction-fragment-analysis': $i).
% 29.32/29.12  tff(decl_66264, type, fn_restriction_fragment_analysis_2: $i > $i).
% 29.32/29.12  tff(decl_66265, type, fn_restriction_fragment_analysis_3: $i > $i).
% 29.32/29.12  tff(decl_66266, type, fn_restriction_fragment_analysis_4: $i > $i).
% 29.32/29.12  tff(decl_66267, type, fn_restriction_fragment_analysis_9: $i > $i).
% 29.32/29.12  tff(decl_66268, type, fn_restriction_fragment_analysis_10: $i > $i).
% 29.32/29.12  tff(decl_66269, type, fn_restriction_site_21: $i > $i).
% 29.32/29.12  tff(decl_66270, type, fn_restriction_site_17: $i > $i).
% 29.32/29.12  tff(decl_66271, type, 'Restriction-Fragment-Length-Polymorphism': $i).
% 29.32/29.12  tff(decl_66272, type, 'Differences in DNA sequence on homologous chromosomes that can result in different patterns of restriction fragment length; useful as genetic markers for making linkage maps.': $i).
% 29.32/29.12  tff(decl_66273, type, rflp: $i).
% 29.32/29.12  tff(decl_66274, type, 'rflp marker': $i).
% 29.32/29.12  tff(decl_66275, type, rflps: $i).
% 29.32/29.12  tff(decl_66276, type, 'restriction fragment length polymorphism': $i).
% 29.32/29.12  tff(decl_66277, type, 'restriction-fragment-length-polymorphism': $i).
% 29.32/29.12  tff(decl_66278, type, fn_restriction_fragment_length_polymorphism_1: $i > $i).
% 29.32/29.12  tff(decl_66279, type, fn_restriction_fragment_length_polymorphism_2: $i > $i).
% 29.32/29.12  tff(decl_66280, type, fn_restriction_fragment_length_polymorphism_3: $i > $i).
% 29.32/29.12  tff(decl_66281, type, fn_restriction_fragment_length_polymorphism_8: $i > $i).
% 29.32/29.12  tff(decl_66282, type, fn_restriction_fragment_length_polymorphism_9: $i > $i).
% 29.32/29.12  tff(decl_66283, type, fn_restriction_fragment_length_polymorphism_10: $i > $i).
% 29.32/29.12  tff(decl_66284, type, fn_restriction_fragment_length_polymorphism_11: $i > $i).
% 29.32/29.12  tff(decl_66285, type, fn_restriction_fragment_length_polymorphism_12: $i > $i).
% 29.32/29.12  tff(decl_66286, type, fn_restriction_fragment_length_polymorphism_13: $i > $i).
% 29.32/29.12  tff(decl_66287, type, fn_restriction_fragment_length_polymorphism_14: $i > $i).
% 29.32/29.12  tff(decl_66288, type, fn_restriction_fragment_length_polymorphism_15: $i > $i).
% 29.32/29.12  tff(decl_66289, type, fn_restriction_fragment_length_polymorphism_16: $i > $i).
% 29.32/29.12  tff(decl_66290, type, fn_restriction_fragment_length_polymorphism_17: $i > $i).
% 29.32/29.12  tff(decl_66291, type, fn_restriction_fragment_length_polymorphism_18: $i > $i).
% 29.32/29.12  tff(decl_66292, type, fn_restriction_fragment_length_polymorphism_20: $i > $i).
% 29.32/29.12  tff(decl_66293, type, fn_restriction_fragment_length_polymorphism_6: $i > $i).
% 29.32/29.12  tff(decl_66294, type, fn_restriction_fragment_length_polymorphism_5: $i > $i).
% 29.32/29.12  tff(decl_66295, type, fn_restriction_fragment_2: $i > $i).
% 29.32/29.12  tff(decl_66296, type, fn_restriction_fragment_length_polymorphism_7: $i > $i).
% 29.32/29.12  tff(decl_66297, type, fn_restriction_fragment_length_polymorphism_4: $i > $i).
% 29.32/29.12  tff(decl_66298, type, fn_restriction_fragment_1: $i > $i).
% 29.32/29.12  tff(decl_66299, type, 'Restriction-Nuclease': $i).
% 29.32/29.12  tff(decl_66300, type, 'Any of the enzymes that cut nucleic acid at specific restriction sites and produce restriction fragments.': $i).
% 29.32/29.12  tff(decl_66301, type, 'restriction enzyme': $i).
% 29.32/29.12  tff(decl_66302, type, 'restriction endonuclease': $i).
% 29.32/29.12  tff(decl_66303, type, 'restriction-endonuclease': $i).
% 29.32/29.12  tff(decl_66304, type, endonuclease: $i).
% 29.32/29.12  tff(decl_66305, type, 'nuclease of restriction': $i).
% 29.32/29.12  tff(decl_66306, type, 'restriction nuclease': $i).
% 29.32/29.12  tff(decl_66307, type, 'restriction-nuclease': $i).
% 29.32/29.12  tff(decl_66308, type, fn_restriction_nuclease_1: $i > $i).
% 29.32/29.12  tff(decl_66309, type, fn_restriction_nuclease_2: $i > $i).
% 29.32/29.12  tff(decl_66310, type, fn_restriction_nuclease_3: $i > $i).
% 29.32/29.12  tff(decl_66311, type, fn_restriction_nuclease_7: $i > $i).
% 29.32/29.12  tff(decl_66312, type, fn_restriction_nuclease_8: $i > $i).
% 29.32/29.12  tff(decl_66313, type, fn_restriction_nuclease_9: $i > $i).
% 29.32/29.12  tff(decl_66314, type, fn_restriction_nuclease_10: $i > $i).
% 29.32/29.12  tff(decl_66315, type, fn_restriction_nuclease_11: $i > $i).
% 29.32/29.12  tff(decl_66316, type, fn_restriction_nuclease_12: $i > $i).
% 29.32/29.12  tff(decl_66317, type, fn_restriction_nuclease_13: $i > $i).
% 29.32/29.12  tff(decl_66318, type, fn_restriction_nuclease_14: $i > $i).
% 29.32/29.12  tff(decl_66319, type, fn_restriction_nuclease_16: $i > $i).
% 29.32/29.12  tff(decl_66320, type, fn_restriction_nuclease_17: $i > $i).
% 29.32/29.12  tff(decl_66321, type, fn_restriction_nuclease_18: $i > $i).
% 29.32/29.12  tff(decl_66322, type, fn_restriction_nuclease_19: $i > $i).
% 29.32/29.12  tff(decl_66323, type, fn_restriction_nuclease_20: $i > $i).
% 29.32/29.12  tff(decl_66324, type, fn_restriction_nuclease_21: $i > $i).
% 29.32/29.12  tff(decl_66325, type, fn_restriction_nuclease_22: $i > $i).
% 29.32/29.12  tff(decl_66326, type, fn_restriction_nuclease_23: $i > $i).
% 29.32/29.12  tff(decl_66327, type, fn_restriction_nuclease_24: $i > $i).
% 29.32/29.12  tff(decl_66328, type, fn_restriction_nuclease_25: $i > $i).
% 29.32/29.12  tff(decl_66329, type, fn_restriction_nuclease_27: $i > $i).
% 29.32/29.12  tff(decl_66330, type, fn_restriction_nuclease_28: $i > $i).
% 29.32/29.12  tff(decl_66331, type, fn_restriction_nuclease_29: $i > $i).
% 29.32/29.12  tff(decl_66332, type, fn_restriction_nuclease_30: $i > $i).
% 29.32/29.12  tff(decl_66333, type, fn_restriction_nuclease_31: $i > $i).
% 29.32/29.12  tff(decl_66334, type, fn_restriction_nuclease_32: $i > $i).
% 29.32/29.12  tff(decl_66335, type, fn_restriction_nuclease_33: $i > $i).
% 29.32/29.12  tff(decl_66336, type, fn_restriction_nuclease_34: $i > $i).
% 29.32/29.12  tff(decl_66337, type, fn_restriction_nuclease_35: $i > $i).
% 29.32/29.12  tff(decl_66338, type, fn_restriction_nuclease_36: $i > $i).
% 29.32/29.12  tff(decl_66339, type, fn_restriction_nuclease_37: $i > $i).
% 29.32/29.12  tff(decl_66340, type, fn_restriction_nuclease_38: $i > $i).
% 29.32/29.12  tff(decl_66341, type, fn_restriction_nuclease_39: $i > $i).
% 29.32/29.12  tff(decl_66342, type, fn_restriction_site_19: $i > $i).
% 29.32/29.12  tff(decl_66343, type, fn_staggered_cut_5: $i > $i).
% 29.32/29.12  tff(decl_66344, type, fn_restriction_site_18: $i > $i).
% 29.32/29.12  tff(decl_66345, type, fn_staggered_cut_6: $i > $i).
% 29.32/29.12  tff(decl_66346, type, fn_restriction_site_20: $i > $i).
% 29.32/29.12  tff(decl_66347, type, covalent_bond_0: $i).
% 29.32/29.12  tff(decl_66348, type, fn_restriction_nuclease_15: $i > $i).
% 29.32/29.12  tff(decl_66349, type, fn_restriction_nuclease_6: $i > $i).
% 29.32/29.12  tff(decl_66350, type, fn_restriction_nuclease_5: $i > $i).
% 29.32/29.12  tff(decl_66351, type, 'Restriction-Site': $i).
% 29.32/29.12  tff(decl_66352, type, 'A specific sequence on a DNA strand that is recognized and cut by a restriction enzyme.': $i).
% 29.32/29.12  tff(decl_66353, type, 'recognition sequence': $i).
% 29.32/29.12  tff(decl_66354, type, 'restriction sequence': $i).
% 29.32/29.12  tff(decl_66355, type, 'restriction recognition site': $i).
% 29.32/29.12  tff(decl_66356, type, 'restriction-recognition-site': $i).
% 29.32/29.12  tff(decl_66357, type, 'site of restriction': $i).
% 29.32/29.12  tff(decl_66358, type, 'restriction site': $i).
% 29.32/29.12  tff(decl_66359, type, 'restriction-site': $i).
% 29.32/29.12  tff(decl_66360, type, fn_restriction_site_1: $i > $i).
% 29.32/29.12  tff(decl_66361, type, fn_restriction_site_2: $i > $i).
% 29.32/29.12  tff(decl_66362, type, fn_restriction_site_3: $i > $i).
% 29.32/29.12  tff(decl_66363, type, fn_restriction_site_4: $i > $i).
% 29.32/29.12  tff(decl_66364, type, fn_restriction_site_5: $i > $i).
% 29.32/29.12  tff(decl_66365, type, fn_restriction_site_6: $i > $i).
% 29.32/29.12  tff(decl_66366, type, fn_restriction_site_8: $i > $i).
% 29.32/29.12  tff(decl_66367, type, fn_restriction_site_9: $i > $i).
% 29.32/29.12  tff(decl_66368, type, fn_restriction_site_10: $i > $i).
% 29.32/29.12  tff(decl_66369, type, fn_restriction_site_11: $i > $i).
% 29.32/29.12  tff(decl_66370, type, fn_restriction_site_12: $i > $i).
% 29.32/29.12  tff(decl_66371, type, fn_restriction_site_13: $i > $i).
% 29.32/29.12  tff(decl_66372, type, fn_restriction_site_14: $i > $i).
% 29.32/29.12  tff(decl_66373, type, fn_restriction_site_15: $i > $i).
% 29.32/29.12  tff(decl_66374, type, fn_restriction_site_16: $i > $i).
% 29.32/29.12  tff(decl_66375, type, fn_restriction_site_22: $i > $i).
% 29.32/29.12  tff(decl_66376, type, fn_restriction_site_23: $i > $i).
% 29.32/29.12  tff(decl_66377, type, fn_restriction_site_24: $i > $i).
% 29.32/29.12  tff(decl_66378, type, fn_restriction_site_25: $i > $i).
% 29.32/29.12  tff(decl_66379, type, fn_restriction_site_26: $i > $i).
% 29.32/29.12  tff(decl_66380, type, 'Retain': $i).
% 29.32/29.12  tff(decl_66381, type, 'To keep or maintain possession.': $i).
% 29.32/29.12  tff(decl_66382, type, retain: $i).
% 29.32/29.12  tff(decl_66383, type, reticular_fiber_1: $i > $o).
% 29.32/29.12  tff(decl_66384, type, 'Reticular-Fiber': $i).
% 29.32/29.12  tff(decl_66385, type, 'A type of fiber in connective tissue that acts as a supportive mesh in soft tissues.': $i).
% 29.32/29.12  tff(decl_66386, type, 'reticular fiber': $i).
% 29.32/29.12  tff(decl_66387, type, 'reticular-fiber': $i).
% 29.32/29.12  tff(decl_66388, type, 'Reticular-Formation': $i).
% 29.32/29.12  tff(decl_66389, type, 'A region in the brainstem that is involved in filtering out extraneous stimuli and regulating the sleep-wake cycle.': $i).
% 29.32/29.12  tff(decl_66390, type, 'sleep center': $i).
% 29.32/29.12  tff(decl_66391, type, 'sleep-center': $i).
% 29.32/29.12  tff(decl_66392, type, 'reticular formation': $i).
% 29.32/29.12  tff(decl_66393, type, 'reticular-formation': $i).
% 29.32/29.12  tff(decl_66394, type, 'Reticular-System': $i).
% 29.32/29.12  tff(decl_66395, type, 'A system of mutlinucleated neurons passing through the core of the brain. The reticular activating system is responsible for arousal and the transition between sleep and wakefulness.': $i).
% 29.32/29.12  tff(decl_66396, type, 'reticular activating system': $i).
% 29.32/29.12  tff(decl_66397, type, 'reticular-activating-system': $i).
% 29.32/29.12  tff(decl_66398, type, 'reticular system': $i).
% 29.32/29.12  tff(decl_66399, type, 'reticular-system': $i).
% 29.32/29.12  tff(decl_66400, type, reticulum_1: $i > $o).
% 29.32/29.12  tff(decl_66401, type, 'Reticulum': $i).
% 29.32/29.12  tff(decl_66402, type, 'The second chamber in a ruminant\\s digestive system in which cud is digested by the action of mutualistic prokaryotes and protists.': $i).
% 29.32/29.12  tff(decl_66403, type, reticulum: $i).
% 29.32/29.12  tff(decl_66404, type, 'Retina': $i).
% 29.32/29.12  tff(decl_66405, type, 'The layer at the back of the eye that contains the photoreceptor cells (rods and cones).': $i).
% 29.32/29.12  tff(decl_66406, type, retina: $i).
% 29.32/29.12  tff(decl_66407, type, retinal_1: $i > $o).
% 29.32/29.12  tff(decl_66408, type, 'Retinal': $i).
% 29.32/29.12  tff(decl_66409, type, 'A form of Vitamin A that absorbs light in the photoreceptor cells of the vertebrate eye.': $i).
% 29.32/29.12  tff(decl_66410, type, retinal: $i).
% 29.32/29.12  tff(decl_66411, type, visual_pigment_1: $i > $o).
% 29.32/29.12  tff(decl_66412, type, fn_retinal_1: $i > $i).
% 29.32/29.12  tff(decl_66413, type, vitamin_a_1: $i > $o).
% 29.32/29.12  tff(decl_66414, type, 'Retrotransposon': $i).
% 29.32/29.12  tff(decl_66415, type, 'A transposable element that moves within a genome by means of an RNA intermediate, a transcript of the retrotransposon DNA.': $i).
% 29.32/29.12  tff(decl_66416, type, retrotransposon: $i).
% 29.32/29.12  tff(decl_66417, type, fn_retrotransposon_1: $i > $i).
% 29.32/29.12  tff(decl_66418, type, fn_retrotransposon_2: $i > $i).
% 29.32/29.12  tff(decl_66419, type, fn_retrotransposon_3: $i > $i).
% 29.32/29.12  tff(decl_66420, type, fn_retrotransposon_4: $i > $i).
% 29.32/29.12  tff(decl_66421, type, reverse_transcriptase_1: $i > $o).
% 29.32/29.12  tff(decl_66422, type, fn_retrotransposon_5: $i > $i).
% 29.32/29.12  tff(decl_66423, type, fn_retrotransposon_6: $i > $i).
% 29.32/29.12  tff(decl_66424, type, fn_retrotransposon_7: $i > $i).
% 29.32/29.12  tff(decl_66425, type, fn_retrotransposon_8: $i > $i).
% 29.32/29.12  tff(decl_66426, type, fn_retrotransposon_9: $i > $i).
% 29.32/29.12  tff(decl_66427, type, fn_retrotransposon_10: $i > $i).
% 29.32/29.12  tff(decl_66428, type, fn_retrotransposon_11: $i > $i).
% 29.32/29.12  tff(decl_66429, type, fn_retrotransposon_12: $i > $i).
% 29.32/29.12  tff(decl_66430, type, fn_retrotransposon_13: $i > $i).
% 29.32/29.12  tff(decl_66431, type, fn_retrotransposon_14: $i > $i).
% 29.32/29.12  tff(decl_66432, type, fn_retrotransposon_15: $i > $i).
% 29.32/29.12  tff(decl_66433, type, transposase_1: $i > $o).
% 29.32/29.12  tff(decl_66434, type, fn_retrotransposon_16: $i > $i).
% 29.32/29.12  tff(decl_66435, type, fn_retrotransposon_17: $i > $i).
% 29.32/29.12  tff(decl_66436, type, fn_retrotransposon_18: $i > $i).
% 29.32/29.12  tff(decl_66437, type, fn_retrotransposon_19: $i > $i).
% 29.32/29.12  tff(decl_66438, type, fn_retrotransposon_20: $i > $i).
% 29.32/29.12  tff(decl_66439, type, fn_retrotransposon_21: $i > $i).
% 29.32/29.12  tff(decl_66440, type, fn_retrotransposon_22: $i > $i).
% 29.32/29.12  tff(decl_66441, type, fn_retrotransposon_23: $i > $i).
% 29.32/29.12  tff(decl_66442, type, fn_retrotransposon_24: $i > $i).
% 29.32/29.12  tff(decl_66443, type, fn_retrotransposon_25: $i > $i).
% 29.32/29.12  tff(decl_66444, type, fn_retrotransposon_26: $i > $i).
% 29.32/29.12  tff(decl_66445, type, fn_retrotransposon_27: $i > $i).
% 29.32/29.12  tff(decl_66446, type, fn_retrotransposon_28: $i > $i).
% 29.32/29.12  tff(decl_66447, type, fn_retrotransposon_29: $i > $i).
% 29.32/29.12  tff(decl_66448, type, fn_retrotransposon_30: $i > $i).
% 29.32/29.12  tff(decl_66449, type, fn_retrotransposon_31: $i > $i).
% 29.32/29.12  tff(decl_66450, type, fn_retrotransposon_32: $i > $i).
% 29.32/29.12  tff(decl_66451, type, fn_retrotransposon_33: $i > $i).
% 29.32/29.12  tff(decl_66452, type, fn_retrotransposon_34: $i > $i).
% 29.32/29.12  tff(decl_66453, type, fn_retrotransposon_35: $i > $i).
% 29.32/29.12  tff(decl_66454, type, fn_retrotransposon_36: $i > $i).
% 29.32/29.12  tff(decl_66455, type, fn_retrotransposon_37: $i > $i).
% 29.32/29.12  tff(decl_66456, type, fn_retrotransposon_42: $i > $i).
% 29.32/29.12  tff(decl_66457, type, fn_retrotransposon_43: $i > $i).
% 29.32/29.12  tff(decl_66458, type, fn_retrotransposon_38: $i > $i).
% 29.32/29.12  tff(decl_66459, type, fn_transposon_34: $i > $i).
% 29.32/29.12  tff(decl_66460, type, fn_retrotransposon_39: $i > $i).
% 29.32/29.12  tff(decl_66461, type, fn_transposon_35: $i > $i).
% 29.32/29.12  tff(decl_66462, type, fn_retrotransposon_40: $i > $i).
% 29.32/29.12  tff(decl_66463, type, fn_transposon_1: $i > $i).
% 29.32/29.12  tff(decl_66464, type, fn_retrotransposon_41: $i > $i).
% 29.32/29.12  tff(decl_66465, type, fn_transposon_2: $i > $i).
% 29.32/29.12  tff(decl_66466, type, fn_transposon_22: $i > $i).
% 29.32/29.12  tff(decl_66467, type, fn_transposon_31: $i > $i).
% 29.32/29.12  tff(decl_66468, type, fn_transposon_32: $i > $i).
% 29.32/29.12  tff(decl_66469, type, fn_transposon_33: $i > $i).
% 29.32/29.12  tff(decl_66470, type, fn_transposon_36: $i > $i).
% 29.32/29.12  tff(decl_66471, type, fn_transposon_37: $i > $i).
% 29.32/29.12  tff(decl_66472, type, fn_transposon_10: $i > $i).
% 29.32/29.12  tff(decl_66473, type, fn_transposon_11: $i > $i).
% 29.32/29.12  tff(decl_66474, type, fn_transposon_26: $i > $i).
% 29.32/29.12  tff(decl_66475, type, fn_transposon_27: $i > $i).
% 29.32/29.12  tff(decl_66476, type, fn_transposon_15: $i > $i).
% 29.32/29.12  tff(decl_66477, type, fn_transposon_24: $i > $i).
% 29.32/29.12  tff(decl_66478, type, fn_transposon_29: $i > $i).
% 29.32/29.12  tff(decl_66479, type, fn_transposon_25: $i > $i).
% 29.32/29.12  tff(decl_66480, type, fn_transposon_3: $i > $i).
% 29.32/29.12  tff(decl_66481, type, fn_transposon_14: $i > $i).
% 29.32/29.12  tff(decl_66482, type, fn_transposon_18: $i > $i).
% 29.32/29.12  tff(decl_66483, type, fn_transposon_17: $i > $i).
% 29.32/29.12  tff(decl_66484, type, fn_transposon_28: $i > $i).
% 29.32/29.12  tff(decl_66485, type, fn_transposon_9: $i > $i).
% 29.32/29.12  tff(decl_66486, type, fn_transposon_8: $i > $i).
% 29.32/29.12  tff(decl_66487, type, fn_transposon_13: $i > $i).
% 29.32/29.12  tff(decl_66488, type, 'Retrovirus': $i).
% 29.32/29.12  tff(decl_66489, type, 'An RNA virus that reproduces by transcribing its RNA into DNA and then inserting the DNA into a cellular chromosome; an important class of cancer-causing viruses.': $i).
% 29.32/29.12  tff(decl_66490, type, 'class vi rna virus': $i).
% 29.32/29.12  tff(decl_66491, type, retrovirus: $i).
% 29.32/29.12  tff(decl_66492, type, 'Reverse-Reaction': $i).
% 29.32/29.12  tff(decl_66493, type, 'A chemical reaction symbolized by a chemical equation in which the products of a forward reaction have become the reactants, and the reactants of the forward reaction are now the products. This is indicated by an arrow that points toward the left.': $i).
% 29.32/29.12  tff(decl_66494, type, 'backward reaction': $i).
% 29.32/29.12  tff(decl_66495, type, 'reaction of reverse': $i).
% 29.32/29.12  tff(decl_66496, type, 'reverse reaction': $i).
% 29.32/29.12  tff(decl_66497, type, 'reverse-reaction': $i).
% 29.32/29.12  tff(decl_66498, type, fn_reverse_reaction_1: $i > $i).
% 29.32/29.12  tff(decl_66499, type, fn_reverse_reaction_2: $i > $i).
% 29.32/29.12  tff(decl_66500, type, fn_reverse_reaction_9: $i > $i).
% 29.32/29.12  tff(decl_66501, type, 'Reverse-Transcriptase': $i).
% 29.32/29.12  tff(decl_66502, type, 'An enzyme encoded by certain viruses (retroviruses) that uses RNA as a template for DNA synthesis.': $i).
% 29.32/29.12  tff(decl_66503, type, 'transcriptase of reverse': $i).
% 29.32/29.12  tff(decl_66504, type, 'reverse transcriptase': $i).
% 29.32/29.12  tff(decl_66505, type, 'reverse-transcriptase': $i).
% 29.32/29.12  tff(decl_66506, type, rna_polymerase_i_1: $i > $o).
% 29.32/29.12  tff(decl_66507, type, fn_reverse_transcriptase_1: $i > $i).
% 29.32/29.12  tff(decl_66508, type, fn_reverse_transcriptase_2: $i > $i).
% 29.32/29.12  tff(decl_66509, type, fn_reverse_transcriptase_7: $i > $i).
% 29.32/29.12  tff(decl_66510, type, fn_reverse_transcriptase_8: $i > $i).
% 29.32/29.12  tff(decl_66511, type, fn_reverse_transcriptase_9: $i > $i).
% 29.32/29.12  tff(decl_66512, type, fn_reverse_transcriptase_10: $i > $i).
% 29.32/29.12  tff(decl_66513, type, fn_reverse_transcriptase_11: $i > $i).
% 29.32/29.12  tff(decl_66514, type, fn_reverse_transcriptase_12: $i > $i).
% 29.32/29.12  tff(decl_66515, type, fn_reverse_transcriptase_13: $i > $i).
% 29.32/29.12  tff(decl_66516, type, fn_reverse_transcriptase_14: $i > $i).
% 29.32/29.12  tff(decl_66517, type, fn_reverse_transcriptase_15: $i > $i).
% 29.32/29.12  tff(decl_66518, type, fn_reverse_transcriptase_16: $i > $i).
% 29.32/29.12  tff(decl_66519, type, fn_reverse_transcriptase_17: $i > $i).
% 29.32/29.12  tff(decl_66520, type, fn_reverse_transcriptase_18: $i > $i).
% 29.32/29.12  tff(decl_66521, type, fn_reverse_transcriptase_19: $i > $i).
% 29.32/29.12  tff(decl_66522, type, fn_reverse_transcriptase_20: $i > $i).
% 29.32/29.12  tff(decl_66523, type, fn_reverse_transcriptase_21: $i > $i).
% 29.32/29.12  tff(decl_66524, type, fn_reverse_transcriptase_22: $i > $i).
% 29.32/29.12  tff(decl_66525, type, fn_reverse_transcriptase_23: $i > $i).
% 29.32/29.12  tff(decl_66526, type, fn_reverse_transcriptase_24: $i > $i).
% 29.32/29.12  tff(decl_66527, type, fn_reverse_transcriptase_25: $i > $i).
% 29.32/29.12  tff(decl_66528, type, fn_reverse_transcriptase_26: $i > $i).
% 29.32/29.12  tff(decl_66529, type, fn_reverse_transcriptase_27: $i > $i).
% 29.32/29.12  tff(decl_66530, type, fn_synthesis_of_rna_2: $i > $i).
% 29.32/29.12  tff(decl_66531, type, fn_reverse_transcription_21: $i > $i).
% 29.32/29.12  tff(decl_66532, type, fn_reverse_transcription_17: $i > $i).
% 29.32/29.12  tff(decl_66533, type, fn_reverse_transcriptase_6: $i > $i).
% 29.32/29.12  tff(decl_66534, type, fn_reverse_transcriptase_5: $i > $i).
% 29.32/29.12  tff(decl_66535, type, fn_reverse_transcriptase_4: $i > $i).
% 29.32/29.12  tff(decl_66536, type, fn_reverse_transcriptase_3: $i > $i).
% 29.32/29.12  tff(decl_66537, type, fn_dna_polymerase_23: $i > $i).
% 29.32/29.12  tff(decl_66538, type, 'Reverse-Transcription': $i).
% 29.32/29.12  tff(decl_66539, type, 'A genetic process whereby RNA is used as the template for producing DNA.': $i).
% 29.32/29.12  tff(decl_66540, type, 'reverse transcribe': $i).
% 29.32/29.12  tff(decl_66541, type, 'transcription of reverse': $i).
% 29.32/29.12  tff(decl_66542, type, 'reverse transcription': $i).
% 29.32/29.12  tff(decl_66543, type, 'reverse-transcription': $i).
% 29.32/29.12  tff(decl_66544, type, fn_reverse_transcription_4: $i > $i).
% 29.32/29.12  tff(decl_66545, type, fn_reverse_transcription_5: $i > $i).
% 29.32/29.12  tff(decl_66546, type, fn_reverse_transcription_6: $i > $i).
% 29.32/29.12  tff(decl_66547, type, fn_reverse_transcription_7: $i > $i).
% 29.32/29.12  tff(decl_66548, type, fn_reverse_transcription_8: $i > $i).
% 29.32/29.12  tff(decl_66549, type, fn_reverse_transcription_9: $i > $i).
% 29.32/29.12  tff(decl_66550, type, fn_reverse_transcription_10: $i > $i).
% 29.32/29.12  tff(decl_66551, type, fn_reverse_transcription_11: $i > $i).
% 29.32/29.12  tff(decl_66552, type, fn_reverse_transcription_12: $i > $i).
% 29.32/29.12  tff(decl_66553, type, fn_reverse_transcription_13: $i > $i).
% 29.32/29.12  tff(decl_66554, type, fn_reverse_transcription_14: $i > $i).
% 29.32/29.12  tff(decl_66555, type, fn_reverse_transcription_15: $i > $i).
% 29.32/29.12  tff(decl_66556, type, fn_reverse_transcription_16: $i > $i).
% 29.32/29.12  tff(decl_66557, type, fn_reverse_transcription_18: $i > $i).
% 29.32/29.12  tff(decl_66558, type, fn_reverse_transcription_19: $i > $i).
% 29.32/29.12  tff(decl_66559, type, fn_reverse_transcription_20: $i > $i).
% 29.32/29.12  tff(decl_66560, type, fn_reverse_transcription_22: $i > $i).
% 29.32/29.12  tff(decl_66561, type, fn_reverse_transcription_23: $i > $i).
% 29.32/29.12  tff(decl_66562, type, fn_reverse_transcription_24: $i > $i).
% 29.32/29.12  tff(decl_66563, type, fn_reverse_transcription_25: $i > $i).
% 29.32/29.12  tff(decl_66564, type, fn_reverse_transcription_26: $i > $i).
% 29.32/29.12  tff(decl_66565, type, fn_reverse_transcription_27: $i > $i).
% 29.32/29.12  tff(decl_66566, type, fn_reverse_transcription_28: $i > $i).
% 29.32/29.12  tff(decl_66567, type, fn_reverse_transcription_29: $i > $i).
% 29.32/29.12  tff(decl_66568, type, fn_reverse_transcription_2: $i > $i).
% 29.32/29.12  tff(decl_66569, type, fn_reverse_transcription_1: $i > $i).
% 29.32/29.12  tff(decl_66570, type, fn_synthesis_of_dna_strand_2: $i > $i).
% 29.32/29.12  tff(decl_66571, type, fn_reverse_transcription_30: $i > $i).
% 29.32/29.12  tff(decl_66572, type, fn_reverse_transcription_3: $i > $i).
% 29.32/29.12  tff(decl_66573, type, fn_synthesis_of_dna_strand_20: $i > $i).
% 29.32/29.12  tff(decl_66574, type, fn_synthesis_of_dna_strand_9: $i > $i).
% 29.32/29.12  tff(decl_66575, type, fn_synthesis_of_dna_strand_17: $i > $i).
% 29.32/29.12  tff(decl_66576, type, reversible_competitive_inhibition_1: $i > $o).
% 29.32/29.12  tff(decl_66577, type, 'Reversible-Competitive-Inhibition': $i).
% 29.32/29.12  tff(decl_66578, type, 'A competitive inhibition is usually reversible if sufficient substrate molecules are available to ultimately displace the inhibitor.': $i).
% 29.32/29.12  tff(decl_66579, type, 'reversible competitive inhibition': $i).
% 29.32/29.12  tff(decl_66580, type, 'reversible-competitive-inhibition': $i).
% 29.32/29.12  tff(decl_66581, type, 'Reversible-Non-Competitive-Inhibition': $i).
% 29.32/29.12  tff(decl_66582, type, 'A type of enzyme inhibition where the inhibitor reversibly binds to an allosteric site, a site different than the active site, on the enzyme, preventing the substrate from being able to bind to the active site.': $i).
% 29.32/29.12  tff(decl_66583, type, 'reversible non competitive inhibition': $i).
% 29.32/29.12  tff(decl_66584, type, 'reversible-non-competitive-inhibition': $i).
% 29.32/29.12  tff(decl_66585, type, fn_reversible_non_competitive_inhibition_1: $i > $i).
% 29.32/29.12  tff(decl_66586, type, fn_reversible_non_competitive_inhibition_2: $i > $i).
% 29.32/29.12  tff(decl_66587, type, 'Reversible-Reaction': $i).
% 29.32/29.12  tff(decl_66588, type, 'A reversible reaction is a chemical reaction that results in an equilibrium mixture of reactants and products.': $i).
% 29.32/29.12  tff(decl_66589, type, 'reaction of reversible': $i).
% 29.32/29.12  tff(decl_66590, type, 'reversible reaction': $i).
% 29.32/29.12  tff(decl_66591, type, 'reversible-reaction': $i).
% 29.32/29.12  tff(decl_66592, type, rh_factor_1: $i > $o).
% 29.32/29.12  tff(decl_66593, type, 'Rh-Factor': $i).
% 29.32/29.12  tff(decl_66594, type, 'A membrane protein found on red blood cells that is recgonized by IgG class antibodies.': $i).
% 29.32/29.12  tff(decl_66595, type, 'rhesus factor': $i).
% 29.32/29.12  tff(decl_66596, type, 'rhesus-factor': $i).
% 29.32/29.12  tff(decl_66597, type, 'factor of rh': $i).
% 29.32/29.12  tff(decl_66598, type, 'rh factor': $i).
% 29.32/29.12  tff(decl_66599, type, 'rh-factor': $i).
% 29.32/29.12  tff(decl_66600, type, fn_rh_factor_1: $i > $i).
% 29.32/29.12  tff(decl_66601, type, fn_rh_factor_2: $i > $i).
% 29.32/29.12  tff(decl_66602, type, rhenium_1: $i > $o).
% 29.32/29.12  tff(decl_66603, type, 'Rhenium': $i).
% 29.32/29.12  tff(decl_66604, type, 'Rhenium is a metal atom with atomic number 75. It is represented by the symbol Re.': $i).
% 29.32/29.12  tff(decl_66605, type, rhenium: $i).
% 29.32/29.12  tff(decl_66606, type, 'Re': $i).
% 29.32/29.12  tff(decl_66607, type, fn_rhenium_3: $i > $i).
% 29.32/29.12  tff(decl_66608, type, fn_rhenium_4: $i > $i).
% 29.32/29.12  tff(decl_66609, type, fn_rhenium_5: $i > $i).
% 29.32/29.12  tff(decl_66610, type, fn_rhenium_9: $i > $i).
% 29.32/29.12  tff(decl_66611, type, fn_rhenium_10: $i > $i).
% 29.32/29.12  tff(decl_66612, type, fn_rhenium_11: $i > $i).
% 29.32/29.12  tff(decl_66613, type, fn_rhenium_12: $i > $i).
% 29.32/29.12  tff(decl_66614, type, "111": $i).
% 29.32/29.12  tff(decl_66615, type, "186": $i).
% 29.32/29.12  tff(decl_66616, type, "186.2": $i).
% 29.32/29.12  tff(decl_66617, type, fn_rhenium_7: $i > $i).
% 29.32/29.12  tff(decl_66618, type, fn_rhenium_8: $i > $i).
% 29.32/29.12  tff(decl_66619, type, fn_rhenium_6: $i > $i).
% 29.32/29.12  tff(decl_66620, type, 'Rheumatoid-Arthritis': $i).
% 29.32/29.12  tff(decl_66621, type, 'A chronic, systemic inflammatory disease that primarily affects joints.': $i).
% 29.32/29.12  tff(decl_66622, type, 'rheumatoid arthritis': $i).
% 29.32/29.12  tff(decl_66623, type, 'rheumatoid-arthritis': $i).
% 29.32/29.12  tff(decl_66624, type, 'Rhizaria': $i).
% 29.32/29.12  tff(decl_66625, type, 'A large supergroup of mostly unicellular organisms, defined by shared DNA characteristics.': $i).
% 29.32/29.12  tff(decl_66626, type, rhizaria: $i).
% 29.32/29.12  tff(decl_66627, type, 'Rhizobacterium': $i).
% 29.32/29.12  tff(decl_66628, type, 'Bacteria that live in soil and form symbiotic relationships with the roots of plants.': $i).
% 29.32/29.12  tff(decl_66629, type, rhizobacterium: $i).
% 29.32/29.12  tff(decl_66630, type, fn_rhizobacterium_1: $i > $i).
% 29.32/29.12  tff(decl_66631, type, fn_rhizobacterium_2: $i > $i).
% 29.32/29.12  tff(decl_66632, type, fn_rhizobacterium_3: $i > $i).
% 29.32/29.12  tff(decl_66633, type, fn_rhizobacterium_4: $i > $i).
% 29.32/29.12  tff(decl_66634, type, fn_rhizobacterium_5: $i > $i).
% 29.32/29.12  tff(decl_66635, type, fn_rhizobacterium_6: $i > $i).
% 29.32/29.12  tff(decl_66636, type, fn_rhizobacterium_7: $i > $i).
% 29.32/29.12  tff(decl_66637, type, fn_rhizobacterium_8: $i > $i).
% 29.32/29.12  tff(decl_66638, type, fn_rhizobacterium_9: $i > $i).
% 29.32/29.12  tff(decl_66639, type, fn_rhizobacterium_10: $i > $i).
% 29.32/29.12  tff(decl_66640, type, fn_rhizobacterium_11: $i > $i).
% 29.32/29.12  tff(decl_66641, type, fn_rhizobacterium_12: $i > $i).
% 29.32/29.12  tff(decl_66642, type, fn_rhizobacterium_13: $i > $i).
% 29.32/29.12  tff(decl_66643, type, fn_rhizobacterium_14: $i > $i).
% 29.32/29.12  tff(decl_66644, type, fn_rhizobacterium_15: $i > $i).
% 29.32/29.12  tff(decl_66645, type, fn_rhizobacterium_16: $i > $i).
% 29.32/29.12  tff(decl_66646, type, fn_rhizobacterium_18: $i > $i).
% 29.32/29.12  tff(decl_66647, type, fn_rhizobacterium_17: $i > $i).
% 29.32/29.12  tff(decl_66648, type, fn_rhizobacterium_20: $i > $i).
% 29.32/29.12  tff(decl_66649, type, fn_rhizobacterium_19: $i > $i).
% 29.32/29.12  tff(decl_66650, type, 'Rhizoid': $i).
% 29.32/29.12  tff(decl_66651, type, 'A long, tubular structure that consists of a single cell or a filament of cells, that extends from the lower epidermal cells of bryophytes and anchors the plant into the soil.': $i).
% 29.32/29.12  tff(decl_66652, type, rhizoid: $i).
% 29.32/29.12  tff(decl_66653, type, rhizome_1: $i > $o).
% 29.32/29.12  tff(decl_66654, type, 'Rhizome': $i).
% 29.32/29.12  tff(decl_66655, type, 'A modified plant stem that extends horizontally along the surface of the soil or just below the surface, with roots growing down and shoots growing up.': $i).
% 29.32/29.12  tff(decl_66656, type, rhizome: $i).
% 29.32/29.12  tff(decl_66657, type, rhizosphere_1: $i > $o).
% 29.32/29.12  tff(decl_66658, type, 'Rhizosphere': $i).
% 29.32/29.12  tff(decl_66659, type, 'The narrow region of soil that is directly affected by plant roots and associated soil microbes.': $i).
% 29.32/29.12  tff(decl_66660, type, rhizosphere: $i).
% 29.32/29.12  tff(decl_66661, type, rhodium_1: $i > $o).
% 29.32/29.12  tff(decl_66662, type, 'Rhodium': $i).
% 29.32/29.12  tff(decl_66663, type, 'Rhodium is a metal atom with atomic number 45. It is represented by the symbol Rh.': $i).
% 29.32/29.12  tff(decl_66664, type, rhodium: $i).
% 29.32/29.12  tff(decl_66665, type, 'Rh': $i).
% 29.32/29.12  tff(decl_66666, type, fn_rhodium_3: $i > $i).
% 29.32/29.12  tff(decl_66667, type, fn_rhodium_4: $i > $i).
% 29.32/29.12  tff(decl_66668, type, fn_rhodium_5: $i > $i).
% 29.32/29.12  tff(decl_66669, type, fn_rhodium_9: $i > $i).
% 29.32/29.12  tff(decl_66670, type, fn_rhodium_10: $i > $i).
% 29.32/29.12  tff(decl_66671, type, fn_rhodium_11: $i > $i).
% 29.32/29.12  tff(decl_66672, type, fn_rhodium_12: $i > $i).
% 29.32/29.12  tff(decl_66673, type, "102.9": $i).
% 29.32/29.12  tff(decl_66674, type, fn_rhodium_7: $i > $i).
% 29.32/29.12  tff(decl_66675, type, fn_rhodium_8: $i > $i).
% 29.32/29.12  tff(decl_66676, type, fn_rhodium_6: $i > $i).
% 29.32/29.12  tff(decl_66677, type, rhodobacter_1: $i > $o).
% 29.32/29.12  tff(decl_66678, type, 'Rhodobacter': $i).
% 29.32/29.12  tff(decl_66679, type, 'Diverse group of photosynthetic bacteria found primarily in aquatic ecosystems.': $i).
% 29.32/29.12  tff(decl_66680, type, rhodobacter: $i).
% 29.32/29.12  tff(decl_66681, type, fn_rhodobacter_1: $i > $i).
% 29.32/29.12  tff(decl_66682, type, fn_rhodobacter_2: $i > $i).
% 29.32/29.12  tff(decl_66683, type, fn_rhodobacter_3: $i > $i).
% 29.32/29.12  tff(decl_66684, type, fn_rhodobacter_4: $i > $i).
% 29.32/29.12  tff(decl_66685, type, fn_rhodobacter_5: $i > $i).
% 29.32/29.12  tff(decl_66686, type, fn_rhodobacter_6: $i > $i).
% 29.32/29.12  tff(decl_66687, type, fn_rhodobacter_7: $i > $i).
% 29.32/29.12  tff(decl_66688, type, fn_rhodobacter_8: $i > $i).
% 29.32/29.12  tff(decl_66689, type, fn_rhodobacter_9: $i > $i).
% 29.32/29.12  tff(decl_66690, type, fn_rhodobacter_10: $i > $i).
% 29.32/29.12  tff(decl_66691, type, fn_rhodobacter_11: $i > $i).
% 29.32/29.12  tff(decl_66692, type, fn_rhodobacter_12: $i > $i).
% 29.32/29.12  tff(decl_66693, type, fn_rhodobacter_13: $i > $i).
% 29.32/29.12  tff(decl_66694, type, fn_rhodobacter_14: $i > $i).
% 29.32/29.12  tff(decl_66695, type, fn_rhodobacter_15: $i > $i).
% 29.32/29.12  tff(decl_66696, type, fn_rhodobacter_16: $i > $i).
% 29.32/29.12  tff(decl_66697, type, fn_rhodobacter_18: $i > $i).
% 29.32/29.12  tff(decl_66698, type, fn_rhodobacter_17: $i > $i).
% 29.32/29.12  tff(decl_66699, type, fn_rhodobacter_20: $i > $i).
% 29.32/29.12  tff(decl_66700, type, fn_rhodobacter_19: $i > $i).
% 29.32/29.12  tff(decl_66701, type, 'Rhodophyte': $i).
% 29.32/29.12  tff(decl_66702, type, 'Member of the phylum Rhodophyta, or red algae. Rhodophytes belong to a large and diverse group of algae, most of which are marine and multicellular. The rhodophytes are distinguished from other algae by the posession of red phycobilin photosynthetic pigments.': $i).
% 29.32/29.12  tff(decl_66703, type, rhodophyte: $i).
% 29.32/29.12  tff(decl_66704, type, rhodopsin_1: $i > $o).
% 29.32/29.12  tff(decl_66705, type, 'Rhodopsin': $i).
% 29.32/29.12  tff(decl_66706, type, 'A visual pigment that consists of retinal and the protein opsin. Absorption of light causes rhodopsin to dissociate into its retinal and opsin components; after a period of time the rhodopsin is reconstituted.': $i).
% 29.32/29.12  tff(decl_66707, type, 'visual purple': $i).
% 29.32/29.12  tff(decl_66708, type, 'visual-purple': $i).
% 29.32/29.12  tff(decl_66709, type, rhodopsin: $i).
% 29.32/29.12  tff(decl_66710, type, fn_rhodopsin_1: $i > $i).
% 29.32/29.12  tff(decl_66711, type, fn_rhodopsin_2: $i > $i).
% 29.32/29.12  tff(decl_66712, type, fn_rhodopsin_3: $i > $i).
% 29.32/29.12  tff(decl_66713, type, 'Rhythm-Method': $i).
% 29.32/29.12  tff(decl_66714, type, 'A contraceptive method that relies on abstention from sexual intercourse when conception is most likely. Also known as natural family planning because it does not rely on chemical or barrier methods to prevent pregnancy.': $i).
% 29.32/29.12  tff(decl_66715, type, 'method of rhythm': $i).
% 29.32/29.12  tff(decl_66716, type, 'rhythm method': $i).
% 29.32/29.12  tff(decl_66717, type, 'rhythm-method': $i).
% 29.32/29.12  tff(decl_66718, type, 'Ribonuclease': $i).
% 29.32/29.12  tff(decl_66719, type, 'Hydrolytic enzyme that takes apart ribonuclease.': $i).
% 29.32/29.12  tff(decl_66720, type, 'hydrolytic enzyme that digests mrna': $i).
% 29.32/29.12  tff(decl_66721, type, ribonuclease: $i).
% 29.32/29.12  tff(decl_66722, type, fn_ribonuclease_1: $i > $i).
% 29.32/29.12  tff(decl_66723, type, fn_ribonuclease_2: $i > $i).
% 29.32/29.12  tff(decl_66724, type, fn_ribonuclease_3: $i > $i).
% 29.32/29.12  tff(decl_66725, type, fn_ribonuclease_4: $i > $i).
% 29.32/29.12  tff(decl_66726, type, fn_ribonuclease_5: $i > $i).
% 29.32/29.12  tff(decl_66727, type, 'Ribonucleoside-Diphosphate': $i).
% 29.32/29.12  tff(decl_66728, type, 'The ribonucleoside diphosphate has nitrogen base, two phosphate groups and a ribose sugar.': $i).
% 29.32/29.12  tff(decl_66729, type, 'ribonucleoside diphosphate': $i).
% 29.32/29.12  tff(decl_66730, type, 'ribonucleoside-diphosphate': $i).
% 29.32/29.12  tff(decl_66731, type, 'Ribonucleoside-Monophosphate': $i).
% 29.32/29.12  tff(decl_66732, type, 'The ribonucleoside monophosphate has nitrogen base, one phosphate group and a ribose sugar.': $i).
% 29.32/29.12  tff(decl_66733, type, 'ribonucleoside monophosphate': $i).
% 29.32/29.12  tff(decl_66734, type, 'ribonucleoside-monophosphate': $i).
% 29.32/29.12  tff(decl_66735, type, fn_ribonucleoside_monophosphate_4: $i > $i).
% 29.32/29.12  tff(decl_66736, type, fn_ribonucleoside_monophosphate_5: $i > $i).
% 29.32/29.12  tff(decl_66737, type, fn_ribonucleoside_monophosphate_6: $i > $i).
% 29.32/29.12  tff(decl_66738, type, fn_ribonucleoside_monophosphate_7: $i > $i).
% 29.32/29.12  tff(decl_66739, type, fn_ribonucleoside_monophosphate_8: $i > $i).
% 29.32/29.12  tff(decl_66740, type, fn_ribonucleoside_monophosphate_9: $i > $i).
% 29.32/29.12  tff(decl_66741, type, fn_ribonucleoside_monophosphate_10: $i > $i).
% 29.32/29.12  tff(decl_66742, type, fn_ribonucleoside_monophosphate_11: $i > $i).
% 29.32/29.12  tff(decl_66743, type, fn_ribonucleoside_monophosphate_12: $i > $i).
% 29.32/29.12  tff(decl_66744, type, fn_ribonucleoside_monophosphate_13: $i > $i).
% 29.32/29.12  tff(decl_66745, type, fn_ribonucleoside_monophosphate_14: $i > $i).
% 29.32/29.12  tff(decl_66746, type, fn_ribonucleoside_monophosphate_15: $i > $i).
% 29.32/29.12  tff(decl_66747, type, fn_ribonucleoside_monophosphate_16: $i > $i).
% 29.32/29.12  tff(decl_66748, type, fn_ribonucleoside_monophosphate_17: $i > $i).
% 29.32/29.12  tff(decl_66749, type, fn_ribonucleoside_monophosphate_18: $i > $i).
% 29.32/29.12  tff(decl_66750, type, fn_ribonucleoside_monophosphate_19: $i > $i).
% 29.32/29.12  tff(decl_66751, type, fn_ribonucleoside_monophosphate_20: $i > $i).
% 29.32/29.12  tff(decl_66752, type, fn_ribonucleoside_monophosphate_21: $i > $i).
% 29.32/29.12  tff(decl_66753, type, fn_ribonucleoside_monophosphate_22: $i > $i).
% 29.32/29.12  tff(decl_66754, type, fn_ribonucleoside_monophosphate_23: $i > $i).
% 29.32/29.12  tff(decl_66755, type, fn_ribonucleoside_monophosphate_24: $i > $i).
% 29.32/29.12  tff(decl_66756, type, fn_ribonucleoside_monophosphate_25: $i > $i).
% 29.32/29.12  tff(decl_66757, type, fn_ribonucleoside_monophosphate_26: $i > $i).
% 29.32/29.12  tff(decl_66758, type, fn_ribonucleoside_monophosphate_27: $i > $i).
% 29.32/29.12  tff(decl_66759, type, fn_ribonucleoside_monophosphate_28: $i > $i).
% 29.32/29.12  tff(decl_66760, type, fn_ribonucleoside_monophosphate_29: $i > $i).
% 29.32/29.12  tff(decl_66761, type, fn_ribonucleoside_monophosphate_30: $i > $i).
% 29.32/29.12  tff(decl_66762, type, fn_ribonucleoside_monophosphate_31: $i > $i).
% 29.32/29.12  tff(decl_66763, type, fn_ribonucleoside_monophosphate_32: $i > $i).
% 29.32/29.12  tff(decl_66764, type, fn_ribonucleoside_monophosphate_33: $i > $i).
% 29.32/29.12  tff(decl_66765, type, fn_ribonucleoside_monophosphate_34: $i > $i).
% 29.32/29.12  tff(decl_66766, type, fn_ribonucleoside_monophosphate_35: $i > $i).
% 29.32/29.12  tff(decl_66767, type, fn_ribonucleoside_monophosphate_36: $i > $i).
% 29.32/29.12  tff(decl_66768, type, fn_ribonucleoside_monophosphate_37: $i > $i).
% 29.32/29.12  tff(decl_66769, type, fn_ribonucleoside_monophosphate_38: $i > $i).
% 29.32/29.12  tff(decl_66770, type, fn_ribonucleoside_monophosphate_39: $i > $i).
% 29.32/29.12  tff(decl_66771, type, fn_ribonucleoside_monophosphate_40: $i > $i).
% 29.32/29.12  tff(decl_66772, type, fn_ribonucleoside_monophosphate_41: $i > $i).
% 29.32/29.12  tff(decl_66773, type, fn_ribonucleoside_monophosphate_42: $i > $i).
% 29.32/29.12  tff(decl_66774, type, fn_ribonucleoside_monophosphate_43: $i > $i).
% 29.32/29.12  tff(decl_66775, type, fn_ribonucleoside_monophosphate_44: $i > $i).
% 29.32/29.12  tff(decl_66776, type, fn_ribonucleoside_monophosphate_45: $i > $i).
% 29.32/29.12  tff(decl_66777, type, fn_ribonucleoside_monophosphate_46: $i > $i).
% 29.32/29.12  tff(decl_66778, type, fn_ribonucleoside_monophosphate_47: $i > $i).
% 29.32/29.12  tff(decl_66779, type, fn_ribonucleoside_monophosphate_48: $i > $i).
% 29.32/29.12  tff(decl_66780, type, fn_ribonucleoside_monophosphate_49: $i > $i).
% 29.32/29.12  tff(decl_66781, type, fn_ribonucleoside_monophosphate_50: $i > $i).
% 29.32/29.12  tff(decl_66782, type, fn_ribonucleoside_monophosphate_52: $i > $i).
% 29.32/29.12  tff(decl_66783, type, fn_ribonucleoside_monophosphate_53: $i > $i).
% 29.32/29.12  tff(decl_66784, type, fn_ribonucleoside_monophosphate_54: $i > $i).
% 29.32/29.12  tff(decl_66785, type, fn_ribonucleoside_monophosphate_55: $i > $i).
% 29.32/29.12  tff(decl_66786, type, fn_ribonucleoside_monophosphate_56: $i > $i).
% 29.32/29.12  tff(decl_66787, type, fn_ribonucleoside_monophosphate_57: $i > $i).
% 29.32/29.12  tff(decl_66788, type, fn_ribonucleoside_monophosphate_58: $i > $i).
% 29.32/29.12  tff(decl_66789, type, fn_ribonucleoside_monophosphate_59: $i > $i).
% 29.32/29.12  tff(decl_66790, type, fn_ribonucleoside_monophosphate_60: $i > $i).
% 29.32/29.12  tff(decl_66791, type, fn_ribonucleoside_monophosphate_61: $i > $i).
% 29.32/29.12  tff(decl_66792, type, fn_ribonucleoside_monophosphate_62: $i > $i).
% 29.32/29.12  tff(decl_66793, type, fn_ribonucleoside_monophosphate_63: $i > $i).
% 29.32/29.12  tff(decl_66794, type, fn_ribonucleoside_monophosphate_64: $i > $i).
% 29.32/29.12  tff(decl_66795, type, fn_ribonucleoside_monophosphate_65: $i > $i).
% 29.32/29.12  tff(decl_66796, type, fn_ribonucleoside_monophosphate_66: $i > $i).
% 29.32/29.12  tff(decl_66797, type, fn_ribonucleoside_monophosphate_67: $i > $i).
% 29.32/29.12  tff(decl_66798, type, fn_ribonucleoside_monophosphate_68: $i > $i).
% 29.32/29.12  tff(decl_66799, type, fn_ribonucleoside_monophosphate_69: $i > $i).
% 29.32/29.12  tff(decl_66800, type, fn_ribonucleoside_monophosphate_70: $i > $i).
% 29.32/29.12  tff(decl_66801, type, fn_ribonucleoside_monophosphate_71: $i > $i).
% 29.32/29.12  tff(decl_66802, type, fn_ribonucleoside_monophosphate_72: $i > $i).
% 29.32/29.12  tff(decl_66803, type, fn_ribonucleoside_monophosphate_73: $i > $i).
% 29.32/29.12  tff(decl_66804, type, fn_ribonucleoside_monophosphate_74: $i > $i).
% 29.32/29.12  tff(decl_66805, type, fn_ribonucleoside_monophosphate_75: $i > $i).
% 29.32/29.12  tff(decl_66806, type, fn_ribonucleoside_monophosphate_76: $i > $i).
% 29.32/29.12  tff(decl_66807, type, fn_ribonucleoside_monophosphate_77: $i > $i).
% 29.32/29.12  tff(decl_66808, type, fn_ribonucleoside_monophosphate_78: $i > $i).
% 29.32/29.12  tff(decl_66809, type, fn_ribonucleoside_monophosphate_79: $i > $i).
% 29.32/29.12  tff(decl_66810, type, fn_ribonucleoside_monophosphate_80: $i > $i).
% 29.32/29.12  tff(decl_66811, type, fn_ribonucleoside_monophosphate_81: $i > $i).
% 29.32/29.12  tff(decl_66812, type, fn_ribonucleoside_monophosphate_82: $i > $i).
% 29.32/29.12  tff(decl_66813, type, fn_ribonucleoside_monophosphate_83: $i > $i).
% 29.32/29.12  tff(decl_66814, type, fn_ribonucleoside_monophosphate_84: $i > $i).
% 29.32/29.12  tff(decl_66815, type, fn_ribonucleoside_monophosphate_85: $i > $i).
% 29.32/29.12  tff(decl_66816, type, fn_ribonucleoside_monophosphate_86: $i > $i).
% 29.32/29.12  tff(decl_66817, type, fn_ribonucleoside_monophosphate_87: $i > $i).
% 29.32/29.12  tff(decl_66818, type, fn_ribonucleoside_monophosphate_88: $i > $i).
% 29.32/29.12  tff(decl_66819, type, fn_ribonucleoside_monophosphate_90: $i > $i).
% 29.32/29.12  tff(decl_66820, type, fn_ribonucleoside_monophosphate_89: $i > $i).
% 29.32/29.12  tff(decl_66821, type, 'Ribonucleoside-Triphosphate': $i).
% 29.32/29.12  tff(decl_66822, type, 'The ribonucleoside triphosphate has nitrogen base, three phosphate groups and a ribose sugar.': $i).
% 29.32/29.12  tff(decl_66823, type, 'ribonucleoside triphosphate': $i).
% 29.32/29.12  tff(decl_66824, type, 'ribonucleoside-triphosphate': $i).
% 29.32/29.12  tff(decl_66825, type, 'Ribonucleotide': $i).
% 29.32/29.12  tff(decl_66826, type, 'RNA monomers composed of a ribose sugar and the nitrogenous bases adenine (A), cytosine (C), guanine (G), and uracil (U).': $i).
% 29.32/29.12  tff(decl_66827, type, 'rna nucleotide': $i).
% 29.32/29.12  tff(decl_66828, type, 'rna-nucleotide': $i).
% 29.32/29.12  tff(decl_66829, type, ribonucleotide: $i).
% 29.32/29.12  tff(decl_66830, type, fn_ribonucleotide_1: $i > $i).
% 29.32/29.12  tff(decl_66831, type, fn_ribonucleotide_5: $i > $i).
% 29.32/29.12  tff(decl_66832, type, fn_ribonucleotide_21: $i > $i).
% 29.32/29.12  tff(decl_66833, type, 'Ribose': $i).
% 29.32/29.12  tff(decl_66834, type, 'Ribose is an aldopentose sugar. It is basic structural unit of RNA. Once phosphorylated it serve as subunit of ATP, NADH and several other compounds useful in metabolism': $i).
% 29.32/29.12  tff(decl_66835, type, 'd ribose': $i).
% 29.32/29.12  tff(decl_66836, type, ribose: $i).
% 29.32/29.12  tff(decl_66837, type, 'Ribosomal-RNA': $i).
% 29.32/29.12  tff(decl_66838, type, 'A type of RNA that combines with proteins to make up ribosomes; it is the most abundant type of RNA in a cell.': $i).
% 29.32/29.12  tff(decl_66839, type, rrna: $i).
% 29.32/29.12  tff(decl_66840, type, 'ribosomal rna': $i).
% 29.32/29.12  tff(decl_66841, type, 'ribosomal-rna': $i).
% 29.32/29.12  tff(decl_66842, type, fn_ribosomal_rna_1: $i > $i).
% 29.32/29.12  tff(decl_66843, type, fn_ribosomal_rna_2: $i > $i).
% 29.32/29.12  tff(decl_66844, type, fn_ribosomal_rna_3: $i > $i).
% 29.32/29.12  tff(decl_66845, type, fn_ribosomal_rna_4: $i > $i).
% 29.32/29.12  tff(decl_66846, type, ribosomal_subunit_1: $i > $o).
% 29.32/29.12  tff(decl_66847, type, 'Ribosomal-subunit': $i).
% 29.32/29.12  tff(decl_66848, type, 'Ribosomal subunit is the structural components of ribosome': $i).
% 29.32/29.12  tff(decl_66849, type, 'ribosome subunit': $i).
% 29.32/29.12  tff(decl_66850, type, 'ribosome-subunit': $i).
% 29.32/29.12  tff(decl_66851, type, 'subunit of ribosome': $i).
% 29.32/29.12  tff(decl_66852, type, 'precursor of ribosome': $i).
% 29.32/29.12  tff(decl_66853, type, 'ribosomal subunit': $i).
% 29.32/29.12  tff(decl_66854, type, 'ribosomal-subunit': $i).
% 29.32/29.12  tff(decl_66855, type, fn_ribosomal_subunit_1: $i > $i).
% 29.32/29.12  tff(decl_66856, type, fn_ribosomal_subunit_2: $i > $i).
% 29.32/29.12  tff(decl_66857, type, 'Ribosome': $i).
% 29.32/29.12  tff(decl_66858, type, 'Ribosome is a cellular component made up of rRNA and Proteins. It is primarily involved in protein synthesis.': $i).
% 29.32/29.12  tff(decl_66859, type, ribosome: $i).
% 29.32/29.12  tff(decl_66860, type, fn_ribosome_3: $i > $i).
% 29.32/29.12  tff(decl_66861, type, fn_ribosome_4: $i > $i).
% 29.32/29.12  tff(decl_66862, type, fn_ribosome_8: $i > $i).
% 29.32/29.12  tff(decl_66863, type, fn_translation_initiation_13: $i > $i).
% 29.32/29.12  tff(decl_66864, type, fn_translation_initiation_11: $i > $i).
% 29.32/29.12  tff(decl_66865, type, fn_translation_initiation_4: $i > $i).
% 29.32/29.12  tff(decl_66866, type, 'Ribosome-Region': $i).
% 29.32/29.12  tff(decl_66867, type, 'Region of a ribosome.': $i).
% 29.32/29.12  tff(decl_66868, type, 'ribosomal region': $i).
% 29.32/29.12  tff(decl_66869, type, 'region on ribosome': $i).
% 29.32/29.12  tff(decl_66870, type, 'site on ribosome': $i).
% 29.32/29.12  tff(decl_66871, type, 'ribosome site': $i).
% 29.32/29.12  tff(decl_66872, type, 'ribosomal site': $i).
% 29.32/29.12  tff(decl_66873, type, 'region of ribosome': $i).
% 29.32/29.12  tff(decl_66874, type, 'ribosome region': $i).
% 29.32/29.12  tff(decl_66875, type, 'ribosome-region': $i).
% 29.32/29.12  tff(decl_66876, type, ribozyme_1: $i > $o).
% 29.32/29.12  tff(decl_66877, type, 'Ribozyme': $i).
% 29.32/29.12  tff(decl_66878, type, 'Ribozymes are RNA molecules which catalyze a chemical reaction. Generally, they catalyze either the hydrolysis of one of their own phosphodiester bonds, or the hydrolysis of bonds in other RNAs, but they have also been found to catalyze the aminotransferase activity of the ribosome.': $i).
% 29.32/29.12  tff(decl_66879, type, 'rna enzyme': $i).
% 29.32/29.12  tff(decl_66880, type, 'rna-enzyme': $i).
% 29.32/29.12  tff(decl_66881, type, 'catalytic rna': $i).
% 29.32/29.12  tff(decl_66882, type, 'catalytic-rna': $i).
% 29.32/29.12  tff(decl_66883, type, 'rna enzymes': $i).
% 29.32/29.12  tff(decl_66884, type, 'rna-enzymes': $i).
% 29.32/29.12  tff(decl_66885, type, ribozyme: $i).
% 29.32/29.12  tff(decl_66886, type, fn_ribozyme_1: $i > $i).
% 29.32/29.12  tff(decl_66887, type, fn_ribozyme_2: $i > $i).
% 29.32/29.12  tff(decl_66888, type, fn_ribozyme_3: $i > $i).
% 29.32/29.12  tff(decl_66889, type, fn_ribozyme_4: $i > $i).
% 29.32/29.12  tff(decl_66890, type, fn_ribozyme_5: $i > $i).
% 29.32/29.12  tff(decl_66891, type, fn_ribozyme_6: $i > $i).
% 29.32/29.12  tff(decl_66892, type, 'Ribulose-Bisphosphate': $i).
% 29.32/29.12  tff(decl_66893, type, 'The molecule to which CO2 is bound during carbon fixation in C4 plants.  The reaction is catalyzed by RuBP carboxylase or rubisco.': $i).
% 29.32/29.12  tff(decl_66894, type, rubp: $i).
% 29.32/29.12  tff(decl_66895, type, 'ribulose bisphosphate': $i).
% 29.32/29.12  tff(decl_66896, type, 'ribulose-bisphosphate': $i).
% 29.32/29.12  tff(decl_66897, type, fn_ribulose_bisphosphate_4: $i > $i).
% 29.32/29.12  tff(decl_66898, type, fn_ribulose_bisphosphate_5: $i > $i).
% 29.32/29.12  tff(decl_66899, type, fn_ribulose_bisphosphate_6: $i > $i).
% 29.32/29.12  tff(decl_66900, type, fn_ribulose_bisphosphate_7: $i > $i).
% 29.32/29.12  tff(decl_66901, type, fn_ribulose_bisphosphate_8: $i > $i).
% 29.32/29.12  tff(decl_66902, type, fn_ribulose_bisphosphate_9: $i > $i).
% 29.32/29.12  tff(decl_66903, type, fn_ribulose_bisphosphate_10: $i > $i).
% 29.32/29.12  tff(decl_66904, type, fn_ribulose_bisphosphate_11: $i > $i).
% 29.32/29.12  tff(decl_66905, type, fn_ribulose_bisphosphate_12: $i > $i).
% 29.32/29.12  tff(decl_66906, type, fn_ribulose_bisphosphate_13: $i > $i).
% 29.32/29.12  tff(decl_66907, type, fn_ribulose_bisphosphate_14: $i > $i).
% 29.32/29.12  tff(decl_66908, type, fn_ribulose_bisphosphate_15: $i > $i).
% 29.32/29.12  tff(decl_66909, type, fn_ribulose_bisphosphate_16: $i > $i).
% 29.32/29.12  tff(decl_66910, type, fn_ribulose_bisphosphate_17: $i > $i).
% 29.32/29.12  tff(decl_66911, type, fn_ribulose_bisphosphate_28: $i > $i).
% 29.32/29.12  tff(decl_66912, type, fn_ribulose_bisphosphate_3: $i > $i).
% 29.32/29.12  tff(decl_66913, type, fn_ribulose_bisphosphate_2: $i > $i).
% 29.32/29.12  tff(decl_66914, type, fn_ribulose_bisphosphate_1: $i > $i).
% 29.32/29.12  tff(decl_66915, type, rice_plant_1: $i > $o).
% 29.32/29.12  tff(decl_66916, type, 'Rice-Plant': $i).
% 29.32/29.12  tff(decl_66917, type, 'Rice is the seed of the monocot plants Oryza sativa or Oryza glaberrima.': $i).
% 29.32/29.12  tff(decl_66918, type, rice: $i).
% 29.32/29.12  tff(decl_66919, type, 'plant of rice': $i).
% 29.32/29.12  tff(decl_66920, type, 'rice plant': $i).
% 29.32/29.12  tff(decl_66921, type, 'rice-plant': $i).
% 29.32/29.12  tff(decl_66922, type, soyabean_plant_1: $i > $o).
% 29.32/29.12  tff(decl_66923, type, wheat_plant_1: $i > $o).
% 29.32/29.12  tff(decl_66924, type, fn_rice_plant_1: $i > $i).
% 29.32/29.12  tff(decl_66925, type, fn_rice_plant_2: $i > $i).
% 29.32/29.12  tff(decl_66926, type, fn_rice_plant_3: $i > $i).
% 29.32/29.12  tff(decl_66927, type, fn_rice_plant_4: $i > $i).
% 29.32/29.12  tff(decl_66928, type, fn_rice_plant_5: $i > $i).
% 29.32/29.12  tff(decl_66929, type, fn_rice_plant_6: $i > $i).
% 29.32/29.12  tff(decl_66930, type, fn_rice_plant_7: $i > $i).
% 29.32/29.12  tff(decl_66931, type, fn_rice_plant_8: $i > $i).
% 29.32/29.12  tff(decl_66932, type, fn_rice_plant_9: $i > $i).
% 29.32/29.12  tff(decl_66933, type, fn_rice_plant_10: $i > $i).
% 29.32/29.12  tff(decl_66934, type, fn_rice_plant_11: $i > $i).
% 29.32/29.12  tff(decl_66935, type, fn_rice_plant_12: $i > $i).
% 29.32/29.12  tff(decl_66936, type, fn_rice_plant_13: $i > $i).
% 29.32/29.12  tff(decl_66937, type, fn_rice_plant_14: $i > $i).
% 29.32/29.12  tff(decl_66938, type, fn_rice_plant_15: $i > $i).
% 29.32/29.12  tff(decl_66939, type, fn_rice_plant_16: $i > $i).
% 29.32/29.12  tff(decl_66940, type, fn_rice_plant_17: $i > $i).
% 29.32/29.12  tff(decl_66941, type, fn_rice_plant_18: $i > $i).
% 29.32/29.12  tff(decl_66942, type, fn_rice_plant_19: $i > $i).
% 29.32/29.12  tff(decl_66943, type, fn_rice_plant_20: $i > $i).
% 29.32/29.12  tff(decl_66944, type, fn_rice_plant_21: $i > $i).
% 29.32/29.12  tff(decl_66945, type, fn_rice_plant_22: $i > $i).
% 29.32/29.12  tff(decl_66946, type, fn_rice_plant_23: $i > $i).
% 29.32/29.12  tff(decl_66947, type, fn_rice_plant_24: $i > $i).
% 29.32/29.12  tff(decl_66948, type, fn_rice_plant_25: $i > $i).
% 29.32/29.12  tff(decl_66949, type, fn_rice_plant_26: $i > $i).
% 29.32/29.12  tff(decl_66950, type, fn_rice_plant_27: $i > $i).
% 29.32/29.12  tff(decl_66951, type, fn_rice_plant_28: $i > $i).
% 29.32/29.12  tff(decl_66952, type, fn_rice_plant_29: $i > $i).
% 29.32/29.12  tff(decl_66953, type, fn_rice_plant_30: $i > $i).
% 29.32/29.12  tff(decl_66954, type, fn_rice_plant_31: $i > $i).
% 29.32/29.12  tff(decl_66955, type, fn_rice_plant_32: $i > $i).
% 29.32/29.12  tff(decl_66956, type, fn_rice_plant_33: $i > $i).
% 29.32/29.12  tff(decl_66957, type, fn_rice_plant_34: $i > $i).
% 29.32/29.12  tff(decl_66958, type, fn_rice_plant_35: $i > $i).
% 29.32/29.12  tff(decl_66959, type, fn_rice_plant_36: $i > $i).
% 29.32/29.12  tff(decl_66960, type, fn_rice_plant_37: $i > $i).
% 29.32/29.12  tff(decl_66961, type, fn_rice_plant_38: $i > $i).
% 29.32/29.12  tff(decl_66962, type, fn_rice_plant_39: $i > $i).
% 29.32/29.12  tff(decl_66963, type, fn_rice_plant_40: $i > $i).
% 29.32/29.12  tff(decl_66964, type, fn_rice_plant_41: $i > $i).
% 29.32/29.12  tff(decl_66965, type, fn_rice_plant_42: $i > $i).
% 29.32/29.12  tff(decl_66966, type, fn_rice_plant_43: $i > $i).
% 29.32/29.12  tff(decl_66967, type, fn_rice_plant_44: $i > $i).
% 29.32/29.12  tff(decl_66968, type, fn_rice_plant_45: $i > $i).
% 29.32/29.12  tff(decl_66969, type, fn_rice_plant_46: $i > $i).
% 29.32/29.12  tff(decl_66970, type, fn_rice_plant_47: $i > $i).
% 29.32/29.12  tff(decl_66971, type, fn_rice_plant_48: $i > $i).
% 29.32/29.12  tff(decl_66972, type, fn_rice_plant_49: $i > $i).
% 29.32/29.12  tff(decl_66973, type, fn_rice_plant_50: $i > $i).
% 29.32/29.12  tff(decl_66974, type, fn_rice_plant_51: $i > $i).
% 29.32/29.12  tff(decl_66975, type, fn_rice_plant_52: $i > $i).
% 29.32/29.12  tff(decl_66976, type, fn_rice_plant_55: $i > $i).
% 29.32/29.12  tff(decl_66977, type, fn_rice_plant_56: $i > $i).
% 29.32/29.12  tff(decl_66978, type, fn_rice_plant_57: $i > $i).
% 29.32/29.12  tff(decl_66979, type, fn_rice_plant_58: $i > $i).
% 29.32/29.12  tff(decl_66980, type, fn_rice_plant_59: $i > $i).
% 29.32/29.12  tff(decl_66981, type, fn_rice_plant_60: $i > $i).
% 29.32/29.12  tff(decl_66982, type, fn_rice_plant_61: $i > $i).
% 29.32/29.12  tff(decl_66983, type, fn_rice_plant_62: $i > $i).
% 29.32/29.12  tff(decl_66984, type, fn_rice_plant_63: $i > $i).
% 29.32/29.12  tff(decl_66985, type, fn_rice_plant_64: $i > $i).
% 29.32/29.12  tff(decl_66986, type, fn_rice_plant_65: $i > $i).
% 29.32/29.12  tff(decl_66987, type, fn_rice_plant_66: $i > $i).
% 29.32/29.12  tff(decl_66988, type, fn_rice_plant_67: $i > $i).
% 29.32/29.12  tff(decl_66989, type, fn_rice_plant_68: $i > $i).
% 29.32/29.12  tff(decl_66990, type, fn_rice_plant_69: $i > $i).
% 29.32/29.12  tff(decl_66991, type, fn_rice_plant_70: $i > $i).
% 29.32/29.12  tff(decl_66992, type, fn_rice_plant_71: $i > $i).
% 29.32/29.12  tff(decl_66993, type, fn_rice_plant_72: $i > $i).
% 29.32/29.12  tff(decl_66994, type, fn_rice_plant_73: $i > $i).
% 29.32/29.12  tff(decl_66995, type, fn_rice_plant_74: $i > $i).
% 29.32/29.12  tff(decl_66996, type, fn_rice_plant_75: $i > $i).
% 29.32/29.12  tff(decl_66997, type, fn_rice_plant_76: $i > $i).
% 29.32/29.12  tff(decl_66998, type, fn_rice_plant_77: $i > $i).
% 29.32/29.12  tff(decl_66999, type, fn_rice_plant_78: $i > $i).
% 29.32/29.12  tff(decl_67000, type, fn_rice_plant_79: $i > $i).
% 29.32/29.12  tff(decl_67001, type, fn_rice_plant_80: $i > $i).
% 29.32/29.12  tff(decl_67002, type, fn_rice_plant_81: $i > $i).
% 29.32/29.12  tff(decl_67003, type, fn_rice_plant_82: $i > $i).
% 29.32/29.12  tff(decl_67004, type, fn_rice_plant_83: $i > $i).
% 29.32/29.12  tff(decl_67005, type, fn_rice_plant_84: $i > $i).
% 29.32/29.12  tff(decl_67006, type, fn_rice_plant_85: $i > $i).
% 29.32/29.12  tff(decl_67007, type, fn_rice_plant_86: $i > $i).
% 29.32/29.12  tff(decl_67008, type, fn_rice_plant_87: $i > $i).
% 29.32/29.12  tff(decl_67009, type, fn_rice_plant_88: $i > $i).
% 29.32/29.12  tff(decl_67010, type, fn_rice_plant_89: $i > $i).
% 29.32/29.12  tff(decl_67011, type, fn_rice_plant_90: $i > $i).
% 29.32/29.12  tff(decl_67012, type, fn_rice_plant_91: $i > $i).
% 29.32/29.12  tff(decl_67013, type, fn_rice_plant_92: $i > $i).
% 29.32/29.12  tff(decl_67014, type, fn_rice_plant_93: $i > $i).
% 29.32/29.12  tff(decl_67015, type, fn_rice_plant_94: $i > $i).
% 29.32/29.12  tff(decl_67016, type, fn_rice_plant_95: $i > $i).
% 29.32/29.12  tff(decl_67017, type, fn_rice_plant_96: $i > $i).
% 29.32/29.12  tff(decl_67018, type, fn_rice_plant_97: $i > $i).
% 29.32/29.12  tff(decl_67019, type, fn_rice_plant_98: $i > $i).
% 29.32/29.12  tff(decl_67020, type, fn_rice_plant_99: $i > $i).
% 29.32/29.12  tff(decl_67021, type, fn_rice_plant_100: $i > $i).
% 29.32/29.12  tff(decl_67022, type, fn_rice_plant_101: $i > $i).
% 29.32/29.12  tff(decl_67023, type, fn_rice_plant_102: $i > $i).
% 29.32/29.12  tff(decl_67024, type, fn_rice_plant_103: $i > $i).
% 29.32/29.12  tff(decl_67025, type, fn_rice_plant_104: $i > $i).
% 29.32/29.12  tff(decl_67026, type, fn_rice_plant_105: $i > $i).
% 29.32/29.12  tff(decl_67027, type, fn_rice_plant_106: $i > $i).
% 29.32/29.12  tff(decl_67028, type, fn_rice_plant_107: $i > $i).
% 29.32/29.12  tff(decl_67029, type, fn_rice_plant_108: $i > $i).
% 29.32/29.12  tff(decl_67030, type, fn_rice_plant_109: $i > $i).
% 29.32/29.12  tff(decl_67031, type, fn_rice_plant_110: $i > $i).
% 29.32/29.12  tff(decl_67032, type, fn_rice_plant_111: $i > $i).
% 29.32/29.12  tff(decl_67033, type, fn_rice_plant_112: $i > $i).
% 29.32/29.12  tff(decl_67034, type, fn_rice_plant_113: $i > $i).
% 29.32/29.12  tff(decl_67035, type, fn_rice_plant_114: $i > $i).
% 29.32/29.12  tff(decl_67036, type, fn_rice_plant_115: $i > $i).
% 29.32/29.12  tff(decl_67037, type, fn_rice_plant_116: $i > $i).
% 29.32/29.12  tff(decl_67038, type, fn_rice_plant_117: $i > $i).
% 29.32/29.12  tff(decl_67039, type, fn_rice_plant_118: $i > $i).
% 29.32/29.12  tff(decl_67040, type, fn_rice_plant_119: $i > $i).
% 29.32/29.12  tff(decl_67041, type, fn_rice_plant_120: $i > $i).
% 29.32/29.12  tff(decl_67042, type, fn_rice_plant_121: $i > $i).
% 29.32/29.12  tff(decl_67043, type, fn_rice_plant_122: $i > $i).
% 29.32/29.12  tff(decl_67044, type, fn_rice_plant_123: $i > $i).
% 29.32/29.12  tff(decl_67045, type, fn_rice_plant_124: $i > $i).
% 29.32/29.12  tff(decl_67046, type, fn_rice_plant_125: $i > $i).
% 29.32/29.12  tff(decl_67047, type, fn_rice_plant_126: $i > $i).
% 29.32/29.12  tff(decl_67048, type, fn_rice_plant_127: $i > $i).
% 29.32/29.12  tff(decl_67049, type, fn_rice_plant_128: $i > $i).
% 29.32/29.12  tff(decl_67050, type, fn_rice_plant_129: $i > $i).
% 29.32/29.12  tff(decl_67051, type, fn_rice_plant_130: $i > $i).
% 29.32/29.12  tff(decl_67052, type, fn_rice_plant_131: $i > $i).
% 29.32/29.12  tff(decl_67053, type, fn_rice_plant_132: $i > $i).
% 29.32/29.12  tff(decl_67054, type, fn_rice_plant_133: $i > $i).
% 29.32/29.12  tff(decl_67055, type, fn_rice_plant_134: $i > $i).
% 29.32/29.12  tff(decl_67056, type, fn_rice_plant_135: $i > $i).
% 29.32/29.12  tff(decl_67057, type, fn_rice_plant_136: $i > $i).
% 29.32/29.12  tff(decl_67058, type, fn_rice_plant_137: $i > $i).
% 29.32/29.12  tff(decl_67059, type, fn_rice_plant_138: $i > $i).
% 29.32/29.12  tff(decl_67060, type, fn_rice_plant_139: $i > $i).
% 29.32/29.12  tff(decl_67061, type, fn_rice_plant_140: $i > $i).
% 29.32/29.12  tff(decl_67062, type, fn_rice_plant_141: $i > $i).
% 29.32/29.12  tff(decl_67063, type, fn_rice_plant_142: $i > $i).
% 29.32/29.12  tff(decl_67064, type, fn_rice_plant_143: $i > $i).
% 29.32/29.12  tff(decl_67065, type, fn_rice_plant_150: $i > $i).
% 29.32/29.12  tff(decl_67066, type, fn_rice_plant_151: $i > $i).
% 29.32/29.12  tff(decl_67067, type, fn_smooth_endoplasmic_reticulum_32: $i > $i).
% 29.32/29.12  tff(decl_67068, type, fn_rice_plant_148: $i > $i).
% 29.32/29.12  tff(decl_67069, type, fn_rice_plant_149: $i > $i).
% 29.32/29.12  tff(decl_67070, type, fn_rice_plant_144: $i > $i).
% 29.32/29.12  tff(decl_67071, type, fn_rice_plant_145: $i > $i).
% 29.32/29.12  tff(decl_67072, type, fn_rice_plant_146: $i > $i).
% 29.32/29.12  tff(decl_67073, type, fn_rice_plant_147: $i > $i).
% 29.32/29.12  tff(decl_67074, type, fn_rice_plant_53: $i > $i).
% 29.32/29.12  tff(decl_67075, type, fn_rice_plant_54: $i > $i).
% 29.32/29.12  tff(decl_67076, type, 'River': $i).
% 29.32/29.12  tff(decl_67077, type, 'A natural waterway, usually freshwater, that drains into an ocean, lake, or another river.': $i).
% 29.32/29.12  tff(decl_67078, type, river: $i).
% 29.32/29.12  tff(decl_67079, type, 'Rivet-Model': $i).
% 29.32/29.12  tff(decl_67080, type, 'A model of community structure that suggests that the majority of species in a community have close ecological ties to other members of the community.': $i).
% 29.32/29.12  tff(decl_67081, type, 'model of rivet': $i).
% 29.32/29.12  tff(decl_67082, type, 'rivet model': $i).
% 29.32/29.12  tff(decl_67083, type, 'rivet-model': $i).
% 29.32/29.12  tff(decl_67084, type, 'RNA': $i).
% 29.32/29.12  tff(decl_67085, type, 'RNA is a nucleic-acid made up of ribonucleotides.': $i).
% 29.32/29.12  tff(decl_67086, type, 'ribonucleic acid': $i).
% 29.32/29.12  tff(decl_67087, type, 'ribo nucleic acid': $i).
% 29.32/29.12  tff(decl_67088, type, 'ribo-nucleic acid': $i).
% 29.32/29.12  tff(decl_67089, type, 'ribonucleic-acid': $i).
% 29.32/29.12  tff(decl_67090, type, rna: $i).
% 29.32/29.12  tff(decl_67091, type, ribonucleotide_0: $i).
% 29.32/29.12  tff(decl_67092, type, 'RNA-Codon': $i).
% 29.32/29.12  tff(decl_67093, type, 'An RNA codon is  three nucleotides in a messenger RNA molecule whose sequence of nitrogenous bases codes for one specific amino acid.': $i).
% 29.32/29.12  tff(decl_67094, type, 'codon of rna': $i).
% 29.32/29.12  tff(decl_67095, type, 'rna codon': $i).
% 29.32/29.12  tff(decl_67096, type, 'rna-codon': $i).
% 29.32/29.12  tff(decl_67097, type, fn_rna_codon_1: $i > $i).
% 29.32/29.12  tff(decl_67098, type, fn_rna_codon_2: $i > $i).
% 29.32/29.12  tff(decl_67099, type, fn_rna_codon_3: $i > $i).
% 29.32/29.12  tff(decl_67100, type, fn_rna_codon_6: $i > $i).
% 29.32/29.12  tff(decl_67101, type, fn_rna_codon_7: $i > $i).
% 29.32/29.12  tff(decl_67102, type, fn_rna_codon_8: $i > $i).
% 29.32/29.12  tff(decl_67103, type, fn_rna_codon_9: $i > $i).
% 29.32/29.12  tff(decl_67104, type, fn_rna_codon_10: $i > $i).
% 29.32/29.12  tff(decl_67105, type, fn_rna_codon_11: $i > $i).
% 29.32/29.12  tff(decl_67106, type, fn_rna_codon_12: $i > $i).
% 29.32/29.12  tff(decl_67107, type, complement_0: $i).
% 29.32/29.12  tff(decl_67108, type, fn_rna_codon_5: $i > $i).
% 29.32/29.12  tff(decl_67109, type, fn_rna_codon_4: $i > $i).
% 29.32/29.12  tff(decl_67110, type, 'RNA-Fragment': $i).
% 29.32/29.12  tff(decl_67111, type, 'Resultant pieces of RNA from RNA degradation.': $i).
% 29.32/29.12  tff(decl_67112, type, 'fragment of rna': $i).
% 29.32/29.12  tff(decl_67113, type, 'rna fragment': $i).
% 29.32/29.12  tff(decl_67114, type, 'rna-fragment': $i).
% 29.32/29.12  tff(decl_67115, type, 'RNA-Interference': $i).
% 29.32/29.12  tff(decl_67116, type, 'A molecular biology technique used to inhibit the expression of selected genes. A synthesized strand of RNA binds to the selected gene and initiates the breakdown of the gene\\s mRNA so that it is not incorporated into the final transcript.': $i).
% 29.32/29.12  tff(decl_67117, type, 'stop gene expression': $i).
% 29.32/29.12  tff(decl_67118, type, 'silence gene expression': $i).
% 29.32/29.12  tff(decl_67119, type, 'rna i': $i).
% 29.32/29.12  tff(decl_67120, type, 'rna-i': $i).
% 29.32/29.12  tff(decl_67121, type, 'double stranded rna': $i).
% 29.32/29.12  tff(decl_67122, type, 'double-stranded-rna': $i).
% 29.32/29.12  tff(decl_67123, type, 'interference of rna': $i).
% 29.32/29.12  tff(decl_67124, type, 'rna interference': $i).
% 29.32/29.12  tff(decl_67125, type, 'rna-interference': $i).
% 29.32/29.12  tff(decl_67126, type, fn_rna_interference_1: $i > $i).
% 29.32/29.12  tff(decl_67127, type, fn_rna_interference_2: $i > $i).
% 29.32/29.12  tff(decl_67128, type, fn_rna_interference_3: $i > $i).
% 29.32/29.12  tff(decl_67129, type, fn_rna_interference_4: $i > $i).
% 29.32/29.12  tff(decl_67130, type, fn_rna_interference_5: $i > $i).
% 29.32/29.12  tff(decl_67131, type, fn_rna_interference_6: $i > $i).
% 29.32/29.12  tff(decl_67132, type, fn_rna_interference_7: $i > $i).
% 29.32/29.12  tff(decl_67133, type, fn_rna_interference_8: $i > $i).
% 29.32/29.12  tff(decl_67134, type, fn_rna_interference_9: $i > $i).
% 29.32/29.12  tff(decl_67135, type, fn_rna_interference_10: $i > $i).
% 29.32/29.12  tff(decl_67136, type, fn_rna_interference_11: $i > $i).
% 29.32/29.12  tff(decl_67137, type, fn_rna_interference_12: $i > $i).
% 29.32/29.12  tff(decl_67138, type, fn_rna_interference_13: $i > $i).
% 29.32/29.12  tff(decl_67139, type, fn_rna_interference_14: $i > $i).
% 29.32/29.12  tff(decl_67140, type, fn_rna_interference_15: $i > $i).
% 29.32/29.12  tff(decl_67141, type, 'RNA-Polymerase': $i).
% 29.32/29.12  tff(decl_67142, type, 'RNA-Polymerase is an enzyme that plays a primary role in DNA Transcription, the process of synthesizing mRNA.': $i).
% 29.32/29.12  tff(decl_67143, type, 'polymerase of rna': $i).
% 29.32/29.12  tff(decl_67144, type, 'rna polymerase': $i).
% 29.32/29.12  tff(decl_67145, type, 'rna-polymerase': $i).
% 29.32/29.12  tff(decl_67146, type, fn_rna_polymerase_1: $i > $i).
% 29.32/29.12  tff(decl_67147, type, fn_rna_polymerase_3: $i > $i).
% 29.32/29.12  tff(decl_67148, type, fn_rna_polymerase_4: $i > $i).
% 29.32/29.12  tff(decl_67149, type, fn_rna_polymerase_5: $i > $i).
% 29.32/29.12  tff(decl_67150, type, fn_rna_polymerase_6: $i > $i).
% 29.32/29.12  tff(decl_67151, type, fn_rna_polymerase_7: $i > $i).
% 29.32/29.12  tff(decl_67152, type, fn_rna_polymerase_8: $i > $i).
% 29.32/29.12  tff(decl_67153, type, fn_rna_polymerase_9: $i > $i).
% 29.32/29.12  tff(decl_67154, type, fn_rna_polymerase_10: $i > $i).
% 29.32/29.12  tff(decl_67155, type, fn_rna_polymerase_11: $i > $i).
% 29.32/29.12  tff(decl_67156, type, fn_rna_polymerase_12: $i > $i).
% 29.32/29.12  tff(decl_67157, type, fn_rna_polymerase_13: $i > $i).
% 29.32/29.12  tff(decl_67158, type, fn_rna_polymerase_14: $i > $i).
% 29.32/29.12  tff(decl_67159, type, fn_rna_polymerase_15: $i > $i).
% 29.32/29.12  tff(decl_67160, type, fn_rna_polymerase_16: $i > $i).
% 29.32/29.12  tff(decl_67161, type, fn_rna_polymerase_17: $i > $i).
% 29.32/29.12  tff(decl_67162, type, fn_rna_polymerase_18: $i > $i).
% 29.32/29.12  tff(decl_67163, type, fn_rna_polymerase_19: $i > $i).
% 29.32/29.12  tff(decl_67164, type, fn_rna_polymerase_20: $i > $i).
% 29.32/29.12  tff(decl_67165, type, fn_rna_polymerase_21: $i > $i).
% 29.32/29.12  tff(decl_67166, type, fn_rna_polymerase_22: $i > $i).
% 29.32/29.12  tff(decl_67167, type, fn_rna_polymerase_23: $i > $i).
% 29.32/29.12  tff(decl_67168, type, fn_rna_polymerase_24: $i > $i).
% 29.32/29.12  tff(decl_67169, type, fn_rna_polymerase_25: $i > $i).
% 29.32/29.12  tff(decl_67170, type, fn_synthesis_of_rna_4: $i > $i).
% 29.32/29.12  tff(decl_67171, type, fn_rna_polymerase_26: $i > $i).
% 29.32/29.12  tff(decl_67172, type, fn_rna_polymerase_27: $i > $i).
% 29.32/29.12  tff(decl_67173, type, fn_rna_polymerase_28: $i > $i).
% 29.32/29.12  tff(decl_67174, type, 'RNA-Polymerase-I': $i).
% 29.32/29.12  tff(decl_67175, type, 'An enzyme that links ribonucleotides into a growing RNA chain during transcription, based on complementary binding to nucleotides on a DNA template strand.': $i).
% 29.32/29.12  tff(decl_67176, type, 'pol i': $i).
% 29.32/29.12  tff(decl_67177, type, 'rna pol i': $i).
% 29.32/29.12  tff(decl_67178, type, 'rna-pol-i': $i).
% 29.32/29.12  tff(decl_67179, type, 'rna polymerase i': $i).
% 29.32/29.12  tff(decl_67180, type, 'rna-polymerase-i': $i).
% 29.32/29.12  tff(decl_67181, type, 'RNA-Primer': $i).
% 29.32/29.12  tff(decl_67182, type, 'Primer is a short stretch of RNA which is used to start synthesis of a new DNA strand using a parent DNA strand as template.': $i).
% 29.32/29.12  tff(decl_67183, type, 'primer of rna': $i).
% 29.32/29.12  tff(decl_67184, type, 'rna primer': $i).
% 29.32/29.12  tff(decl_67185, type, 'rna-primer': $i).
% 29.32/29.12  tff(decl_67186, type, fn_rna_primer_1: $i > $i).
% 29.32/29.12  tff(decl_67187, type, fn_rna_primer_2: $i > $i).
% 29.32/29.12  tff(decl_67188, type, fn_rna_primer_3: $i > $i).
% 29.32/29.12  tff(decl_67189, type, fn_rna_primer_4: $i > $i).
% 29.32/29.12  tff(decl_67190, type, fn_rna_primer_5: $i > $i).
% 29.32/29.12  tff(decl_67191, type, fn_rna_primer_6: $i > $i).
% 29.32/29.12  tff(decl_67192, type, fn_rna_primer_7: $i > $i).
% 29.32/29.12  tff(decl_67193, type, fn_rna_primer_8: $i > $i).
% 29.32/29.12  tff(decl_67194, type, 'RNA-priming': $i).
% 29.32/29.12  tff(decl_67195, type, 'The synthesis of a short RNA segment called a primer onto which DNA polymerase can add DNA nucleotides to begin DNA synthesis.': $i).
% 29.32/29.12  tff(decl_67196, type, 'priming of rna': $i).
% 29.32/29.12  tff(decl_67197, type, 'rna priming': $i).
% 29.32/29.12  tff(decl_67198, type, 'rna-priming': $i).
% 29.32/29.12  tff(decl_67199, type, fn_rna_priming_1: $i > $i).
% 29.32/29.12  tff(decl_67200, type, fn_rna_priming_2: $i > $i).
% 29.32/29.12  tff(decl_67201, type, fn_rna_priming_3: $i > $i).
% 29.32/29.13  tff(decl_67202, type, fn_rna_priming_4: $i > $i).
% 29.32/29.13  tff(decl_67203, type, fn_rna_priming_5: $i > $i).
% 29.32/29.13  tff(decl_67204, type, fn_rna_priming_6: $i > $i).
% 29.32/29.13  tff(decl_67205, type, fn_rna_priming_7: $i > $i).
% 29.32/29.13  tff(decl_67206, type, fn_rna_priming_8: $i > $i).
% 29.32/29.13  tff(decl_67207, type, fn_rna_priming_9: $i > $i).
% 29.32/29.13  tff(decl_67208, type, fn_rna_priming_10: $i > $i).
% 29.32/29.13  tff(decl_67209, type, fn_synthesis_of_rna_3: $i > $i).
% 29.32/29.13  tff(decl_67210, type, 'RNA-Processing': $i).
% 29.32/29.13  tff(decl_67211, type, 'During RNA-processing, enzymes in the nucleus of eukaryotic organisms modify pre-mRNA before the pre-mRNA is transported into the cytoplasm.': $i).
% 29.32/29.13  tff(decl_67212, type, 'processing of rna': $i).
% 29.32/29.13  tff(decl_67213, type, 'rna processing': $i).
% 29.32/29.13  tff(decl_67214, type, 'rna-processing': $i).
% 29.32/29.13  tff(decl_67215, type, fn_rna_processing_2: $i > $i).
% 29.32/29.13  tff(decl_67216, type, fn_rna_processing_3: $i > $i).
% 29.32/29.13  tff(decl_67217, type, fn_rna_processing_4: $i > $i).
% 29.32/29.13  tff(decl_67218, type, fn_rna_splicing_4: $i > $i).
% 29.32/29.13  tff(decl_67219, type, 'RNA-Sequence': $i).
% 29.32/29.13  tff(decl_67220, type, 'A sequence of RNA nucleotides.': $i).
% 29.32/29.13  tff(decl_67221, type, 'sequence of rna': $i).
% 29.32/29.13  tff(decl_67222, type, 'rna sequence': $i).
% 29.32/29.13  tff(decl_67223, type, 'rna-sequence': $i).
% 29.32/29.13  tff(decl_67224, type, fn_rna_sequence_1: $i > $i).
% 29.32/29.13  tff(decl_67225, type, fn_rna_sequence_2: $i > $i).
% 29.32/29.13  tff(decl_67226, type, 'RNA-Splicing': $i).
% 29.32/29.13  tff(decl_67227, type, 'Modification of an mRNA transcript to remove introns and join the remaining exons together.': $i).
% 29.32/29.13  tff(decl_67228, type, 'splicing of rna': $i).
% 29.32/29.13  tff(decl_67229, type, 'rna splicing': $i).
% 29.32/29.13  tff(decl_67230, type, 'rna-splicing': $i).
% 29.32/29.13  tff(decl_67231, type, fn_rna_splicing_1: $i > $i).
% 29.32/29.13  tff(decl_67232, type, fn_rna_splicing_2: $i > $i).
% 29.32/29.13  tff(decl_67233, type, fn_rna_splicing_3: $i > $i).
% 29.32/29.13  tff(decl_67234, type, fn_rna_splicing_5: $i > $i).
% 29.32/29.13  tff(decl_67235, type, fn_rna_splicing_6: $i > $i).
% 29.32/29.13  tff(decl_67236, type, fn_rna_splicing_7: $i > $i).
% 29.32/29.13  tff(decl_67237, type, fn_rna_splicing_8: $i > $i).
% 29.32/29.13  tff(decl_67238, type, fn_rna_splicing_9: $i > $i).
% 29.32/29.13  tff(decl_67239, type, fn_rna_splicing_10: $i > $i).
% 29.32/29.13  tff(decl_67240, type, fn_rna_splicing_11: $i > $i).
% 29.32/29.13  tff(decl_67241, type, fn_rna_splicing_12: $i > $i).
% 29.32/29.13  tff(decl_67242, type, fn_rna_splicing_13: $i > $i).
% 29.32/29.13  tff(decl_67243, type, fn_spliceosome_4: $i > $i).
% 29.32/29.13  tff(decl_67244, type, fn_spliceosome_5: $i > $i).
% 29.32/29.13  tff(decl_67245, type, fn_spliceosome_6: $i > $i).
% 29.32/29.13  tff(decl_67246, type, fn_spliceosome_1: $i > $i).
% 29.32/29.13  tff(decl_67247, type, 'RNA-strand': $i).
% 29.32/29.13  tff(decl_67248, type, 'A single-stranded RNA polymer composed of ribonucleotides.': $i).
% 29.32/29.13  tff(decl_67249, type, 'strand of rna': $i).
% 29.32/29.13  tff(decl_67250, type, 'rna strand': $i).
% 29.32/29.13  tff(decl_67251, type, 'rna-strand': $i).
% 29.32/29.13  tff(decl_67252, type, fn_rna_strand_1: $i > $i).
% 29.32/29.13  tff(decl_67253, type, fn_rna_strand_2: $i > $i).
% 29.32/29.13  tff(decl_67254, type, fn_rna_strand_3: $i > $i).
% 29.32/29.13  tff(decl_67255, type, fn_rna_strand_4: $i > $i).
% 29.32/29.13  tff(decl_67256, type, fn_rna_strand_5: $i > $i).
% 29.32/29.13  tff(decl_67257, type, fn_rna_strand_6: $i > $i).
% 29.32/29.13  tff(decl_67258, type, fn_rna_strand_7: $i > $i).
% 29.32/29.13  tff(decl_67259, type, fn_rna_strand_8: $i > $i).
% 29.32/29.13  tff(decl_67260, type, fn_rna_strand_9: $i > $i).
% 29.32/29.13  tff(decl_67261, type, fn_rna_strand_10: $i > $i).
% 29.32/29.13  tff(decl_67262, type, fn_rna_strand_11: $i > $i).
% 29.32/29.13  tff(decl_67263, type, fn_rna_strand_12: $i > $i).
% 29.32/29.13  tff(decl_67264, type, fn_rna_strand_17: $i > $i).
% 29.32/29.13  tff(decl_67265, type, fn_rna_strand_18: $i > $i).
% 29.32/29.13  tff(decl_67266, type, fn_rna_strand_19: $i > $i).
% 29.32/29.13  tff(decl_67267, type, fn_rna_strand_20: $i > $i).
% 29.32/29.13  tff(decl_67268, type, fn_rna_strand_21: $i > $i).
% 29.32/29.13  tff(decl_67269, type, fn_rna_strand_22: $i > $i).
% 29.32/29.13  tff(decl_67270, type, fn_rna_strand_23: $i > $i).
% 29.32/29.13  tff(decl_67271, type, fn_rna_strand_24: $i > $i).
% 29.32/29.13  tff(decl_67272, type, fn_rna_strand_25: $i > $i).
% 29.32/29.13  tff(decl_67273, type, fn_rna_strand_27: $i > $i).
% 29.32/29.13  tff(decl_67274, type, fn_rna_strand_29: $i > $i).
% 29.32/29.13  tff(decl_67275, type, fn_rna_strand_30: $i > $i).
% 29.32/29.13  tff(decl_67276, type, fn_rna_strand_31: $i > $i).
% 29.32/29.13  tff(decl_67277, type, fn_rna_strand_33: $i > $i).
% 29.32/29.13  tff(decl_67278, type, fn_rna_strand_34: $i > $i).
% 29.32/29.13  tff(decl_67279, type, fn_rna_strand_35: $i > $i).
% 29.32/29.13  tff(decl_67280, type, fn_rna_strand_36: $i > $i).
% 29.32/29.13  tff(decl_67281, type, fn_rna_strand_37: $i > $i).
% 29.32/29.13  tff(decl_67282, type, fn_rna_strand_41: $i > $i).
% 29.32/29.13  tff(decl_67283, type, fn_rna_strand_42: $i > $i).
% 29.32/29.13  tff(decl_67284, type, fn_rna_strand_43: $i > $i).
% 29.32/29.13  tff(decl_67285, type, fn_rna_strand_44: $i > $i).
% 29.32/29.13  tff(decl_67286, type, fn_rna_strand_45: $i > $i).
% 29.32/29.13  tff(decl_67287, type, fn_rna_strand_46: $i > $i).
% 29.32/29.13  tff(decl_67288, type, fn_rna_strand_47: $i > $i).
% 29.32/29.13  tff(decl_67289, type, fn_rna_strand_48: $i > $i).
% 29.32/29.13  tff(decl_67290, type, fn_rna_strand_49: $i > $i).
% 29.32/29.13  tff(decl_67291, type, fn_rna_strand_50: $i > $i).
% 29.32/29.13  tff(decl_67292, type, fn_rna_strand_51: $i > $i).
% 29.32/29.13  tff(decl_67293, type, fn_rna_strand_52: $i > $i).
% 29.32/29.13  tff(decl_67294, type, fn_rna_strand_53: $i > $i).
% 29.32/29.13  tff(decl_67295, type, fn_rna_strand_54: $i > $i).
% 29.32/29.13  tff(decl_67296, type, fn_rna_strand_55: $i > $i).
% 29.32/29.13  tff(decl_67297, type, fn_rna_strand_56: $i > $i).
% 29.32/29.13  tff(decl_67298, type, fn_rna_strand_57: $i > $i).
% 29.32/29.13  tff(decl_67299, type, fn_rna_strand_58: $i > $i).
% 29.32/29.13  tff(decl_67300, type, fn_rna_strand_59: $i > $i).
% 29.32/29.13  tff(decl_67301, type, fn_rna_strand_60: $i > $i).
% 29.32/29.13  tff(decl_67302, type, fn_rna_strand_61: $i > $i).
% 29.32/29.13  tff(decl_67303, type, fn_rna_strand_62: $i > $i).
% 29.32/29.13  tff(decl_67304, type, fn_rna_strand_63: $i > $i).
% 29.32/29.13  tff(decl_67305, type, fn_rna_strand_64: $i > $i).
% 29.32/29.13  tff(decl_67306, type, fn_rna_strand_65: $i > $i).
% 29.32/29.13  tff(decl_67307, type, fn_rna_strand_66: $i > $i).
% 29.32/29.13  tff(decl_67308, type, fn_rna_strand_67: $i > $i).
% 29.32/29.13  tff(decl_67309, type, fn_rna_strand_68: $i > $i).
% 29.32/29.13  tff(decl_67310, type, fn_rna_strand_69: $i > $i).
% 29.32/29.13  tff(decl_67311, type, fn_rna_strand_70: $i > $i).
% 29.32/29.13  tff(decl_67312, type, fn_rna_strand_71: $i > $i).
% 29.32/29.13  tff(decl_67313, type, fn_rna_strand_72: $i > $i).
% 29.32/29.13  tff(decl_67314, type, fn_rna_strand_73: $i > $i).
% 29.32/29.13  tff(decl_67315, type, fn_rna_strand_74: $i > $i).
% 29.32/29.13  tff(decl_67316, type, fn_rna_strand_75: $i > $i).
% 29.32/29.13  tff(decl_67317, type, fn_rna_strand_76: $i > $i).
% 29.32/29.13  tff(decl_67318, type, fn_rna_strand_77: $i > $i).
% 29.32/29.13  tff(decl_67319, type, fn_rna_strand_78: $i > $i).
% 29.32/29.13  tff(decl_67320, type, fn_rna_strand_79: $i > $i).
% 29.32/29.13  tff(decl_67321, type, fn_rna_strand_80: $i > $i).
% 29.32/29.13  tff(decl_67322, type, fn_rna_strand_81: $i > $i).
% 29.32/29.13  tff(decl_67323, type, fn_rna_strand_82: $i > $i).
% 29.32/29.13  tff(decl_67324, type, fn_rna_strand_83: $i > $i).
% 29.32/29.13  tff(decl_67325, type, fn_rna_strand_84: $i > $i).
% 29.32/29.13  tff(decl_67326, type, fn_rna_strand_85: $i > $i).
% 29.32/29.13  tff(decl_67327, type, fn_rna_strand_86: $i > $i).
% 29.32/29.13  tff(decl_67328, type, fn_rna_strand_87: $i > $i).
% 29.32/29.13  tff(decl_67329, type, fn_rna_strand_88: $i > $i).
% 29.32/29.13  tff(decl_67330, type, fn_rna_strand_89: $i > $i).
% 29.32/29.13  tff(decl_67331, type, fn_rna_strand_90: $i > $i).
% 29.32/29.13  tff(decl_67332, type, fn_rna_strand_91: $i > $i).
% 29.32/29.13  tff(decl_67333, type, fn_rna_strand_92: $i > $i).
% 29.32/29.13  tff(decl_67334, type, fn_rna_strand_93: $i > $i).
% 29.32/29.13  tff(decl_67335, type, fn_rna_strand_98: $i > $i).
% 29.32/29.13  tff(decl_67336, type, fn_rna_strand_99: $i > $i).
% 29.32/29.13  tff(decl_67337, type, fn_rna_strand_100: $i > $i).
% 29.32/29.13  tff(decl_67338, type, fn_rna_strand_95: $i > $i).
% 29.32/29.13  tff(decl_67339, type, fn_rna_strand_96: $i > $i).
% 29.32/29.13  tff(decl_67340, type, fn_rna_strand_94: $i > $i).
% 29.32/29.13  tff(decl_67341, type, fn_rna_strand_97: $i > $i).
% 29.32/29.13  tff(decl_67342, type, fn_rna_strand_32: $i > $i).
% 29.32/29.13  tff(decl_67343, type, fn_rna_strand_16: $i > $i).
% 29.32/29.13  tff(decl_67344, type, fn_rna_strand_15: $i > $i).
% 29.32/29.13  tff(decl_67345, type, fn_rna_strand_13: $i > $i).
% 29.32/29.13  tff(decl_67346, type, fn_rna_strand_101: $i > $i).
% 29.32/29.13  tff(decl_67347, type, fn_rna_strand_14: $i > $i).
% 29.32/29.13  tff(decl_67348, type, fn_rna_strand_28: $i > $i).
% 29.32/29.13  tff(decl_67349, type, fn_rna_strand_26: $i > $i).
% 29.32/29.13  tff(decl_67350, type, 'RNA-Virus': $i).
% 29.32/29.13  tff(decl_67351, type, 'A virus with RNA as its genetic material.': $i).
% 29.32/29.13  tff(decl_67352, type, 'virus of rna': $i).
% 29.32/29.13  tff(decl_67353, type, 'rna virus': $i).
% 29.32/29.13  tff(decl_67354, type, 'rna-virus': $i).
% 29.32/29.13  tff(decl_67355, type, fn_rna_virus_1: $i > $i).
% 29.32/29.13  tff(decl_67356, type, fn_rna_virus_2: $i > $i).
% 29.32/29.13  tff(decl_67357, type, fn_rna_virus_3: $i > $i).
% 29.32/29.13  tff(decl_67358, type, fn_rna_virus_4: $i > $i).
% 29.32/29.13  tff(decl_67359, type, fn_rna_virus_5: $i > $i).
% 29.32/29.13  tff(decl_67360, type, 'RNA-Virus-Class-IV': $i).
% 29.32/29.13  tff(decl_67361, type, 'Classes of animal virus that can serve as mRNA.  Includes classes picornavirus and togavirus.': $i).
% 29.32/29.13  tff(decl_67362, type, 'class iv rna virus': $i).
% 29.32/29.13  tff(decl_67363, type, 'rna virus class iv': $i).
% 29.32/29.13  tff(decl_67364, type, 'rna-virus-class-iv': $i).
% 29.32/29.13  tff(decl_67365, type, 'RNA-Virus-Class-V': $i).
% 29.32/29.13  tff(decl_67366, type, 'Classes of animal virus in which the viral RNA genome serves as a template for mRNA synthesis.  Includes classes rhabdovirus, paramyxovirus, orthomyxovirus.': $i).
% 29.32/29.13  tff(decl_67367, type, 'class v rna virus': $i).
% 29.32/29.13  tff(decl_67368, type, 'rna virus class v': $i).
% 29.32/29.13  tff(decl_67369, type, 'rna-virus-class-v': $i).
% 29.32/29.13  tff(decl_67370, type, fn_rna_virus_class_v_1: $i > $i).
% 29.32/29.13  tff(decl_67371, type, fn_rna_virus_class_v_2: $i > $i).
% 29.32/29.13  tff(decl_67372, type, fn_rna_virus_class_v_3: $i > $i).
% 29.32/29.13  tff(decl_67373, type, fn_rna_virus_class_v_4: $i > $i).
% 29.32/29.13  tff(decl_67374, type, 'RNA-World': $i).
% 29.32/29.13  tff(decl_67375, type, 'A model that suggests that RNA was the precursor genetic material to DNA.': $i).
% 29.32/29.13  tff(decl_67376, type, 'world of rna': $i).
% 29.32/29.13  tff(decl_67377, type, 'rna world': $i).
% 29.32/29.13  tff(decl_67378, type, 'rna-world': $i).
% 29.32/29.13  tff(decl_67379, type, 'Rock': $i).
% 29.32/29.13  tff(decl_67380, type, 'Solid minerals found on the surface of the earth.': $i).
% 29.32/29.13  tff(decl_67381, type, 'Rod': $i).
% 29.32/29.13  tff(decl_67382, type, 'Rod is a part of ATP Synthase': $i).
% 29.32/29.13  tff(decl_67383, type, rod: $i).
% 29.32/29.13  tff(decl_67384, type, rod_cell_1: $i > $o).
% 29.32/29.13  tff(decl_67385, type, 'Rod-cell': $i).
% 29.32/29.13  tff(decl_67386, type, 'Rod cell is a cell found in the retina that is sensitive to light/dark (black/white)': $i).
% 29.32/29.13  tff(decl_67387, type, 'cell of rod': $i).
% 29.32/29.13  tff(decl_67388, type, 'rod cell': $i).
% 29.32/29.13  tff(decl_67389, type, 'rod-cell': $i).
% 29.32/29.13  tff(decl_67390, type, rod_shaped_prokaryote_1: $i > $o).
% 29.32/29.13  tff(decl_67391, type, 'Rod-Shaped-Prokaryote': $i).
% 29.32/29.13  tff(decl_67392, type, 'Prokaryote that has a rod shape.': $i).
% 29.32/29.13  tff(decl_67393, type, 'rod shaped prokaryote': $i).
% 29.32/29.13  tff(decl_67394, type, 'rod-shaped prokaryote': $i).
% 29.32/29.13  tff(decl_67395, type, 'rod-shaped-prokaryote': $i).
% 29.32/29.13  tff(decl_67396, type, fn_rod_shaped_prokaryote_1: $i > $i).
% 29.32/29.13  tff(decl_67397, type, fn_rod_shaped_prokaryote_2: $i > $i).
% 29.32/29.13  tff(decl_67398, type, 'Rodent': $i).
% 29.32/29.13  tff(decl_67399, type, 'A member of the mammalian clade Rodentia, which have continuously growing incisors in the upper and lower jaws.': $i).
% 29.32/29.13  tff(decl_67400, type, rodent: $i).
% 29.32/29.13  tff(decl_67401, type, roentgenium_1: $i > $o).
% 29.32/29.13  tff(decl_67402, type, 'Roentgenium': $i).
% 29.32/29.13  tff(decl_67403, type, 'Roentgenium is a metal atom with atomic number 111. It is represented by the symbol Rg.': $i).
% 29.32/29.13  tff(decl_67404, type, roentgenium: $i).
% 29.32/29.13  tff(decl_67405, type, rg: $i).
% 29.32/29.13  tff(decl_67406, type, fn_roentgenium_1: $i > $i).
% 29.32/29.13  tff(decl_67407, type, fn_roentgenium_2: $i > $i).
% 29.32/29.13  tff(decl_67408, type, fn_roentgenium_6: $i > $i).
% 29.32/29.13  tff(decl_67409, type, fn_roentgenium_7: $i > $i).
% 29.32/29.13  tff(decl_67410, type, "272": $i).
% 29.32/29.13  tff(decl_67411, type, fn_roentgenium_4: $i > $i).
% 29.32/29.13  tff(decl_67412, type, fn_roentgenium_5: $i > $i).
% 29.32/29.13  tff(decl_67413, type, 'Role': $i).
% 29.32/29.13  tff(decl_67414, type, 'Roof': $i).
% 29.32/29.13  tff(decl_67415, type, 'an architectural structure covering another architectural structure': $i).
% 29.32/29.13  tff(decl_67416, type, roof: $i).
% 29.32/29.13  tff(decl_67417, type, fn_roof_2: $i > $i).
% 29.32/29.13  tff(decl_67418, type, 'Room': $i).
% 29.32/29.13  tff(decl_67419, type, 'an architectural structure playing a container within a building': $i).
% 29.32/29.13  tff(decl_67420, type, room: $i).
% 29.32/29.13  tff(decl_67421, type, fn_room_1: $i > $i).
% 29.32/29.13  tff(decl_67422, type, fn_room_2: $i > $i).
% 29.32/29.13  tff(decl_67423, type, fn_room_3: $i > $i).
% 29.32/29.13  tff(decl_67424, type, fn_room_4: $i > $i).
% 29.32/29.13  tff(decl_67425, type, fn_room_5: $i > $i).
% 29.32/29.13  tff(decl_67426, type, 'Root': $i).
% 29.32/29.13  tff(decl_67427, type, 'In vascular plants, an organ that anchors a plant in the soil and absorbs nutrients and water from the soil.': $i).
% 29.32/29.13  tff(decl_67428, type, root: $i).
% 29.32/29.13  tff(decl_67429, type, fn_root_3: $i > $i).
% 29.32/29.13  tff(decl_67430, type, fn_root_4: $i > $i).
% 29.32/29.13  tff(decl_67431, type, fn_root_6: $i > $i).
% 29.32/29.13  tff(decl_67432, type, fn_root_7: $i > $i).
% 29.32/29.13  tff(decl_67433, type, fn_root_8: $i > $i).
% 29.32/29.13  tff(decl_67434, type, fn_root_9: $i > $i).
% 29.32/29.13  tff(decl_67435, type, fn_root_10: $i > $i).
% 29.32/29.13  tff(decl_67436, type, fn_root_12: $i > $i).
% 29.32/29.13  tff(decl_67437, type, fn_root_17: $i > $i).
% 29.32/29.13  tff(decl_67438, type, fn_root_18: $i > $i).
% 29.32/29.13  tff(decl_67439, type, fn_root_19: $i > $i).
% 29.32/29.13  tff(decl_67440, type, fn_root_20: $i > $i).
% 29.32/29.13  tff(decl_67441, type, fn_root_21: $i > $i).
% 29.32/29.13  tff(decl_67442, type, fn_root_22: $i > $i).
% 29.32/29.13  tff(decl_67443, type, fn_root_23: $i > $i).
% 29.32/29.13  tff(decl_67444, type, fn_root_24: $i > $i).
% 29.32/29.13  tff(decl_67445, type, fn_root_29: $i > $i).
% 29.32/29.13  tff(decl_67446, type, fn_root_31: $i > $i).
% 29.32/29.13  tff(decl_67447, type, fn_root_32: $i > $i).
% 29.32/29.13  tff(decl_67448, type, fn_root_34: $i > $i).
% 29.32/29.13  tff(decl_67449, type, fn_root_35: $i > $i).
% 29.32/29.13  tff(decl_67450, type, fn_root_36: $i > $i).
% 29.32/29.13  tff(decl_67451, type, fn_uptake_of_nutrient_by_cell_using_proton_pump_1: $i > $i).
% 29.32/29.13  tff(decl_67452, type, fn_uptake_of_nutrient_by_cell_using_proton_pump_9: $i > $i).
% 29.32/29.13  tff(decl_67453, type, 'Root-Apical-Meristem': $i).
% 29.32/29.13  tff(decl_67454, type, 'Embryonic plant tissue in the tips of root is called as root apical meristem. The dividing cells of an apical meristem enable the plant to grow in length.': $i).
% 29.32/29.13  tff(decl_67455, type, 'root apical meristem': $i).
% 29.32/29.13  tff(decl_67456, type, 'root-apical-meristem': $i).
% 29.32/29.13  tff(decl_67457, type, fn_root_apical_meristem_1: $i > $i).
% 29.32/29.13  tff(decl_67458, type, fn_root_apical_meristem_4: $i > $i).
% 29.32/29.13  tff(decl_67459, type, 'Root-Cap': $i).
% 29.32/29.13  tff(decl_67460, type, 'A section of tissue at the growing tip of a plant root. It protects the root apical meristem.': $i).
% 29.32/29.13  tff(decl_67461, type, 'cap of root': $i).
% 29.32/29.13  tff(decl_67462, type, 'root cap': $i).
% 29.32/29.13  tff(decl_67463, type, 'root-cap': $i).
% 29.32/29.13  tff(decl_67464, type, 'Root-Hair': $i).
% 29.32/29.13  tff(decl_67465, type, 'A tiny extension of a root epidermal cell, growing just behind the root tip and increasing surface area for absorption of water and minerals.': $i).
% 29.32/29.13  tff(decl_67466, type, 'hair of root': $i).
% 29.32/29.13  tff(decl_67467, type, 'root hair': $i).
% 29.32/29.13  tff(decl_67468, type, 'root-hair': $i).
% 29.32/29.13  tff(decl_67469, type, 'Root-Organ': $i).
% 29.32/29.13  tff(decl_67470, type, 'A specialized center of plant function composed of root tissue and specific to plants.': $i).
% 29.32/29.13  tff(decl_67471, type, 'organ of root': $i).
% 29.32/29.13  tff(decl_67472, type, 'root organ': $i).
% 29.32/29.13  tff(decl_67473, type, 'root-organ': $i).
% 29.32/29.13  tff(decl_67474, type, 'Root-System': $i).
% 29.32/29.13  tff(decl_67475, type, 'All of a plants roots, which anchor it in the soil, absorb and transport minerals and water, and store food.': $i).
% 29.32/29.13  tff(decl_67476, type, 'system of root': $i).
% 29.32/29.13  tff(decl_67477, type, 'root system': $i).
% 29.32/29.13  tff(decl_67478, type, 'root-system': $i).
% 29.32/29.13  tff(decl_67479, type, 'Rooted': $i).
% 29.32/29.13  tff(decl_67480, type, 'A term used to describe a phylogenetic tree that includes a branch point that represents the last known common ancestor for all taxa in the analysis.': $i).
% 29.32/29.13  tff(decl_67481, type, rooted: $i).
% 29.32/29.13  tff(decl_67482, type, 'Rosette-Cellulose-Synthesizing-Complex': $i).
% 29.32/29.13  tff(decl_67483, type, 'In plant cells, a rosette-shaped array of proteins that floats in the plasma membrane and secretes the cellulose fibers that make up the cell wall.': $i).
% 29.32/29.13  tff(decl_67484, type, 'rosette cellulose synthesizing complex': $i).
% 29.32/29.13  tff(decl_67485, type, 'rosette cellulose-synthesizing complex': $i).
% 29.32/29.13  tff(decl_67486, type, 'rosette-cellulose-synthesizing-complex': $i).
% 29.32/29.13  tff(decl_67487, type, 'Rotate': $i).
% 29.32/29.13  tff(decl_67488, type, rotate: $i).
% 29.32/29.13  tff(decl_67489, type, circuvolve: $i).
% 29.32/29.13  tff(decl_67490, type, rotation_of_flagella_in_prokaryote_1: $i > $o).
% 29.32/29.13  tff(decl_67491, type, fn_rotation_of_flagella_in_prokaryote_5: $i > $i).
% 29.32/29.13  tff(decl_67492, type, 'Rotation-Of-Flagella-In-Prokaryote': $i).
% 29.32/29.13  tff(decl_67493, type, 'In prokaryotes, the flagella rotates, propelling the cell forward. This movement differs from the way a flagella works in a eukaryote.': $i).
% 29.32/29.13  tff(decl_67494, type, 'rotation of flagella in prokaryote': $i).
% 29.32/29.13  tff(decl_67495, type, 'rotation-of-flagella-in-prokaryote': $i).
% 29.32/29.13  tff(decl_67496, type, fn_rotation_of_flagella_in_prokaryote_1: $i > $i).
% 29.32/29.13  tff(decl_67497, type, fn_rotation_of_flagella_in_prokaryote_3: $i > $i).
% 29.32/29.13  tff(decl_67498, type, fn_rotation_of_flagella_in_prokaryote_4: $i > $i).
% 29.32/29.13  tff(decl_67499, type, rotational_rate_constant_1: $i > $o).
% 29.32/29.13  tff(decl_67500, type, 'Rotational-Rate-Constant': $i).
% 29.32/29.13  tff(decl_67501, type, 'rotational rate constant': $i).
% 29.32/29.13  tff(decl_67502, type, 'rotational-rate-constant': $i).
% 29.32/29.13  tff(decl_67503, type, 'Rotational-Rate-Value': $i).
% 29.32/29.13  tff(decl_67504, type, 'the rate of rotation': $i).
% 29.32/29.13  tff(decl_67505, type, 'rotational rate': $i).
% 29.32/29.13  tff(decl_67506, type, 'rotational-rate': $i).
% 29.32/29.13  tff(decl_67507, type, 'rotational rate value': $i).
% 29.32/29.13  tff(decl_67508, type, 'rotational-rate-value': $i).
% 29.32/29.13  tff(decl_67509, type, 'Rotifer': $i).
% 29.32/29.13  tff(decl_67510, type, 'A member of the phylum Rotifera, a group of small aquatic animals that use a crown of cilia for locomotion and filter-feeding.': $i).
% 29.32/29.13  tff(decl_67511, type, rotifera: $i).
% 29.32/29.13  tff(decl_67512, type, rotifer: $i).
% 29.32/29.13  tff(decl_67513, type, 'Rotor': $i).
% 29.32/29.13  tff(decl_67514, type, 'Protein component of ATP-synthase and molecular motors which changes shape in response to the binding of a ligand, typically a hydrogen ion.': $i).
% 29.32/29.13  tff(decl_67515, type, rotor: $i).
% 29.32/29.13  tff(decl_67516, type, fn_rotor_1: $i > $i).
% 29.32/29.13  tff(decl_67517, type, 'Rough-Endoplasmic-Reticulum': $i).
% 29.32/29.13  tff(decl_67518, type, 'Rough Endoplasmic Reticulum is an endoplasmic reticulum which has ribosomes attached on its surface. It is primarily involved in synthesis and transfer of proteins from one part of the cell to another.': $i).
% 29.32/29.13  tff(decl_67519, type, rer: $i).
% 29.32/29.13  tff(decl_67520, type, 'rough endoplasmic reticulum': $i).
% 29.32/29.13  tff(decl_67521, type, 'rough er': $i).
% 29.32/29.13  tff(decl_67522, type, 'rough-er': $i).
% 29.32/29.13  tff(decl_67523, type, 'rough-endoplasmic-reticulum': $i).
% 29.32/29.13  tff(decl_67524, type, fn_rough_endoplasmic_reticulum_4: $i > $i).
% 29.32/29.13  tff(decl_67525, type, fn_rough_endoplasmic_reticulum_6: $i > $i).
% 29.32/29.13  tff(decl_67526, type, fn_rough_endoplasmic_reticulum_7: $i > $i).
% 29.32/29.13  tff(decl_67527, type, fn_rough_endoplasmic_reticulum_9: $i > $i).
% 29.32/29.13  tff(decl_67528, type, fn_rough_endoplasmic_reticulum_10: $i > $i).
% 29.32/29.13  tff(decl_67529, type, fn_rough_endoplasmic_reticulum_12: $i > $i).
% 29.32/29.13  tff(decl_67530, type, fn_rough_endoplasmic_reticulum_14: $i > $i).
% 29.32/29.13  tff(decl_67531, type, fn_rough_endoplasmic_reticulum_15: $i > $i).
% 29.32/29.13  tff(decl_67532, type, fn_rough_endoplasmic_reticulum_16: $i > $i).
% 29.32/29.13  tff(decl_67533, type, fn_rough_endoplasmic_reticulum_18: $i > $i).
% 29.32/29.13  tff(decl_67534, type, fn_rough_endoplasmic_reticulum_25: $i > $i).
% 29.32/29.13  tff(decl_67535, type, fn_rough_endoplasmic_reticulum_26: $i > $i).
% 29.32/29.13  tff(decl_67536, type, fn_rough_endoplasmic_reticulum_31: $i > $i).
% 29.32/29.13  tff(decl_67537, type, fn_rough_endoplasmic_reticulum_33: $i > $i).
% 29.32/29.13  tff(decl_67538, type, fn_rough_endoplasmic_reticulum_34: $i > $i).
% 29.32/29.13  tff(decl_67539, type, fn_rough_endoplasmic_reticulum_35: $i > $i).
% 29.32/29.13  tff(decl_67540, type, fn_rough_endoplasmic_reticulum_36: $i > $i).
% 29.32/29.13  tff(decl_67541, type, fn_rough_endoplasmic_reticulum_37: $i > $i).
% 29.32/29.13  tff(decl_67542, type, fn_rough_endoplasmic_reticulum_38: $i > $i).
% 29.32/29.13  tff(decl_67543, type, fn_rough_endoplasmic_reticulum_41: $i > $i).
% 29.32/29.13  tff(decl_67544, type, fn_rough_endoplasmic_reticulum_42: $i > $i).
% 29.32/29.13  tff(decl_67545, type, fn_rough_endoplasmic_reticulum_43: $i > $i).
% 29.32/29.13  tff(decl_67546, type, fn_rough_endoplasmic_reticulum_44: $i > $i).
% 29.32/29.13  tff(decl_67547, type, fn_rough_endoplasmic_reticulum_45: $i > $i).
% 29.32/29.13  tff(decl_67548, type, fn_rough_endoplasmic_reticulum_46: $i > $i).
% 29.32/29.13  tff(decl_67549, type, fn_rough_endoplasmic_reticulum_48: $i > $i).
% 29.32/29.13  tff(decl_67550, type, fn_rough_endoplasmic_reticulum_49: $i > $i).
% 29.32/29.13  tff(decl_67551, type, fn_rough_endoplasmic_reticulum_50: $i > $i).
% 29.32/29.13  tff(decl_67552, type, fn_rough_endoplasmic_reticulum_53: $i > $i).
% 29.32/29.13  tff(decl_67553, type, fn_rough_endoplasmic_reticulum_54: $i > $i).
% 29.32/29.13  tff(decl_67554, type, fn_rough_endoplasmic_reticulum_59: $i > $i).
% 29.32/29.13  tff(decl_67555, type, transitional_endoplasmic_reticulum_1: $i > $o).
% 29.32/29.13  tff(decl_67556, type, fn_rough_endoplasmic_reticulum_60: $i > $i).
% 29.32/29.13  tff(decl_67557, type, fn_rough_endoplasmic_reticulum_61: $i > $i).
% 29.32/29.13  tff(decl_67558, type, fn_rough_endoplasmic_reticulum_63: $i > $i).
% 29.32/29.13  tff(decl_67559, type, fn_rough_endoplasmic_reticulum_64: $i > $i).
% 29.32/29.13  tff(decl_67560, type, fn_rough_endoplasmic_reticulum_65: $i > $i).
% 29.32/29.13  tff(decl_67561, type, fn_rough_endoplasmic_reticulum_67: $i > $i).
% 29.32/29.13  tff(decl_67562, type, fn_rough_endoplasmic_reticulum_69: $i > $i).
% 29.32/29.13  tff(decl_67563, type, fn_rough_endoplasmic_reticulum_70: $i > $i).
% 29.32/29.13  tff(decl_67564, type, fn_rough_endoplasmic_reticulum_71: $i > $i).
% 29.32/29.13  tff(decl_67565, type, fn_rough_endoplasmic_reticulum_72: $i > $i).
% 29.32/29.13  tff(decl_67566, type, fn_rough_endoplasmic_reticulum_73: $i > $i).
% 29.32/29.13  tff(decl_67567, type, fn_rough_endoplasmic_reticulum_74: $i > $i).
% 29.32/29.13  tff(decl_67568, type, fn_rough_endoplasmic_reticulum_75: $i > $i).
% 29.32/29.13  tff(decl_67569, type, fn_rough_endoplasmic_reticulum_77: $i > $i).
% 29.32/29.13  tff(decl_67570, type, fn_rough_endoplasmic_reticulum_78: $i > $i).
% 29.32/29.13  tff(decl_67571, type, fn_rough_endoplasmic_reticulum_79: $i > $i).
% 29.32/29.13  tff(decl_67572, type, fn_rough_endoplasmic_reticulum_80: $i > $i).
% 29.32/29.13  tff(decl_67573, type, fn_rough_endoplasmic_reticulum_81: $i > $i).
% 29.32/29.13  tff(decl_67574, type, fn_rough_endoplasmic_reticulum_82: $i > $i).
% 29.32/29.13  tff(decl_67575, type, fn_rough_endoplasmic_reticulum_86: $i > $i).
% 29.32/29.13  tff(decl_67576, type, fn_synthesis_of_glycoprotein_95: $i > $i).
% 29.32/29.13  tff(decl_67577, type, fn_synthesis_of_glycoprotein_3: $i > $i).
% 29.32/29.13  tff(decl_67578, type, fn_synthesis_of_glycoprotein_5: $i > $i).
% 29.32/29.13  tff(decl_67579, type, fn_translation_termination_36: $i > $i).
% 29.32/29.13  tff(decl_67580, type, fn_synthesis_of_glycoprotein_93: $i > $i).
% 29.32/29.13  tff(decl_67581, type, fn_transitional_endoplasmic_reticulum_2: $i > $i).
% 29.32/29.13  tff(decl_67582, type, fn_synthesis_of_glycoprotein_98: $i > $i).
% 29.32/29.13  tff(decl_67583, type, fn_synthesis_of_glycoprotein_83: $i > $i).
% 29.32/29.13  tff(decl_67584, type, fn_synthesis_of_glycoprotein_56: $i > $i).
% 29.32/29.13  tff(decl_67585, type, fn_translation_termination_6: $i > $i).
% 29.32/29.13  tff(decl_67586, type, fn_translation_21: $i > $i).
% 29.32/29.13  tff(decl_67587, type, fn_synthesis_of_glycoprotein_62: $i > $i).
% 29.32/29.13  tff(decl_67588, type, fn_synthesis_of_glycoprotein_61: $i > $i).
% 29.32/29.13  tff(decl_67589, type, fn_synthesis_of_glycoprotein_76: $i > $i).
% 29.32/29.13  tff(decl_67590, type, fn_synthesis_of_glycoprotein_46: $i > $i).
% 29.32/29.13  tff(decl_67591, type, fn_synthesis_of_protein_9: $i > $i).
% 29.32/29.13  tff(decl_67592, type, fn_synthesis_of_glycoprotein_43: $i > $i).
% 29.32/29.13  tff(decl_67593, type, fn_translation_termination_2: $i > $i).
% 29.32/29.13  tff(decl_67594, type, fn_synthesis_of_glycoprotein_63: $i > $i).
% 29.32/29.13  tff(decl_67595, type, fn_synthesis_of_membrane_protein_23: $i > $i).
% 29.32/29.13  tff(decl_67596, type, 'Round-Window': $i).
% 29.32/29.13  tff(decl_67597, type, 'One of two openings in the mammalian ear. The round window is where vibrations from the stapes are transferred to the cochlea.': $i).
% 29.32/29.13  tff(decl_67598, type, 'window of round': $i).
% 29.32/29.13  tff(decl_67599, type, 'round window': $i).
% 29.32/29.13  tff(decl_67600, type, 'round-window': $i).
% 29.32/29.13  tff(decl_67601, type, rrna_gene_1: $i > $o).
% 29.32/29.13  tff(decl_67602, type, 'RRNA-Gene': $i).
% 29.32/29.13  tff(decl_67603, type, 'Ribosomal RNA gene found within the nucleolus region.': $i).
% 29.32/29.13  tff(decl_67604, type, 'rrna gene': $i).
% 29.32/29.13  tff(decl_67605, type, 'rrna-gene': $i).
% 29.32/29.13  tff(decl_67606, type, fn_rrna_gene_1: $i > $i).
% 29.32/29.13  tff(decl_67607, type, fn_rrna_gene_4: $i > $i).
% 29.32/29.13  tff(decl_67608, type, fn_rrna_gene_5: $i > $i).
% 29.32/29.13  tff(decl_67609, type, fn_rrna_gene_6: $i > $i).
% 29.32/29.13  tff(decl_67610, type, fn_rrna_gene_7: $i > $i).
% 29.32/29.13  tff(decl_67611, type, fn_rrna_gene_8: $i > $i).
% 29.32/29.13  tff(decl_67612, type, fn_rrna_gene_9: $i > $i).
% 29.32/29.13  tff(decl_67613, type, fn_rrna_gene_10: $i > $i).
% 29.32/29.13  tff(decl_67614, type, fn_rrna_gene_11: $i > $i).
% 29.32/29.13  tff(decl_67615, type, fn_rrna_gene_12: $i > $i).
% 29.32/29.13  tff(decl_67616, type, fn_rrna_gene_13: $i > $i).
% 29.32/29.13  tff(decl_67617, type, fn_rrna_gene_3: $i > $i).
% 29.32/29.13  tff(decl_67618, type, fn_rrna_gene_2: $i > $i).
% 29.32/29.13  tff(decl_67619, type, 'RRNA-Gene-Amplification': $i).
% 29.32/29.13  tff(decl_67620, type, 'Amplification of ribosomal RNA gene.': $i).
% 29.32/29.13  tff(decl_67621, type, 'rrna gene amplification': $i).
% 29.32/29.13  tff(decl_67622, type, 'rrna-gene-amplification': $i).
% 29.32/29.13  tff(decl_67623, type, fn_rrna_gene_amplification_1: $i > $i).
% 29.32/29.13  tff(decl_67624, type, fn_rrna_gene_amplification_2: $i > $i).
% 29.32/29.13  tff(decl_67625, type, fn_rrna_gene_amplification_3: $i > $i).
% 29.32/29.13  tff(decl_67626, type, fn_rrna_gene_amplification_4: $i > $i).
% 29.32/29.13  tff(decl_67627, type, fn_rrna_gene_amplification_5: $i > $i).
% 29.32/29.13  tff(decl_67628, type, fn_rrna_gene_amplification_6: $i > $i).
% 29.32/29.13  tff(decl_67629, type, fn_rrna_gene_amplification_7: $i > $i).
% 29.32/29.13  tff(decl_67630, type, fn_rrna_gene_amplification_8: $i > $i).
% 29.32/29.13  tff(decl_67631, type, fn_rrna_gene_amplification_9: $i > $i).
% 29.32/29.13  tff(decl_67632, type, fn_rrna_gene_amplification_10: $i > $i).
% 29.32/29.13  tff(decl_67633, type, fn_rrna_gene_amplification_11: $i > $i).
% 29.32/29.13  tff(decl_67634, type, fn_rrna_gene_amplification_12: $i > $i).
% 29.32/29.13  tff(decl_67635, type, rrna_gene_0: $i).
% 29.32/29.13  tff(decl_67636, type, 'Rubber': $i).
% 29.32/29.13  tff(decl_67637, type, rubber: $i).
% 29.32/29.13  tff(decl_67638, type, 'india rubber': $i).
% 29.32/29.13  tff(decl_67639, type, india_rubber: $i).
% 29.32/29.13  tff(decl_67640, type, 'gum elastic': $i).
% 29.32/29.13  tff(decl_67641, type, gum_elastic: $i).
% 29.32/29.13  tff(decl_67642, type, caoutchouc: $i).
% 29.32/29.13  tff(decl_67643, type, rubidium_1: $i > $o).
% 29.32/29.13  tff(decl_67644, type, 'Rubidium': $i).
% 29.32/29.13  tff(decl_67645, type, 'Rubidium is a metal atom with atomic number 37. It is represented by the symbol Rb.': $i).
% 29.32/29.13  tff(decl_67646, type, rubidium: $i).
% 29.32/29.13  tff(decl_67647, type, 'Rb': $i).
% 29.32/29.13  tff(decl_67648, type, fn_rubidium_4: $i > $i).
% 29.32/29.13  tff(decl_67649, type, fn_rubidium_5: $i > $i).
% 29.32/29.13  tff(decl_67650, type, fn_rubidium_6: $i > $i).
% 29.32/29.13  tff(decl_67651, type, fn_rubidium_7: $i > $i).
% 29.32/29.13  tff(decl_67652, type, fn_rubidium_11: $i > $i).
% 29.32/29.13  tff(decl_67653, type, fn_rubidium_12: $i > $i).
% 29.32/29.13  tff(decl_67654, type, fn_rubidium_13: $i > $i).
% 29.32/29.13  tff(decl_67655, type, fn_rubidium_14: $i > $i).
% 29.32/29.13  tff(decl_67656, type, "37": $i).
% 29.32/29.13  tff(decl_67657, type, "85.47": $i).
% 29.32/29.13  tff(decl_67658, type, fn_rubidium_9: $i > $i).
% 29.32/29.13  tff(decl_67659, type, fn_rubidium_10: $i > $i).
% 29.32/29.13  tff(decl_67660, type, fn_rubidium_8: $i > $i).
% 29.32/29.13  tff(decl_67661, type, 'Rubisco': $i).
% 29.32/29.13  tff(decl_67662, type, 'The enzyme ribulose bisphosphate carboxylase catalyzes the addition of CO2 to ribulose bisphosphate in the first step of the Calvin Cycle.': $i).
% 29.32/29.13  tff(decl_67663, type, 'rubp carboxylase': $i).
% 29.32/29.13  tff(decl_67664, type, 'ribulose 1,5 bisphosphate carboxylase oxygenase': $i).
% 29.32/29.13  tff(decl_67665, type, 'ribulose-1,5-bisphosphate-carboxylase-oxygenase': $i).
% 29.32/29.13  tff(decl_67666, type, 'rubp-carboxylase': $i).
% 29.32/29.13  tff(decl_67667, type, 'ribulose 1,5 bisphosphate carboxylase': $i).
% 29.32/29.13  tff(decl_67668, type, 'ribulose-1,5-bisphosphate carboxylase': $i).
% 29.32/29.13  tff(decl_67669, type, rubisco: $i).
% 29.32/29.13  tff(decl_67670, type, fn_rubisco_2: $i > $i).
% 29.32/29.13  tff(decl_67671, type, fn_rubisco_6: $i > $i).
% 29.32/29.13  tff(decl_67672, type, fn_rubisco_7: $i > $i).
% 29.32/29.13  tff(decl_67673, type, fn_rubisco_8: $i > $i).
% 29.32/29.13  tff(decl_67674, type, fn_rubisco_9: $i > $i).
% 29.32/29.13  tff(decl_67675, type, fn_rubisco_10: $i > $i).
% 29.32/29.13  tff(decl_67676, type, fn_rubisco_11: $i > $i).
% 29.32/29.13  tff(decl_67677, type, fn_rubisco_12: $i > $i).
% 29.32/29.13  tff(decl_67678, type, fn_rubisco_13: $i > $i).
% 29.32/29.13  tff(decl_67679, type, fn_rubisco_14: $i > $i).
% 29.32/29.13  tff(decl_67680, type, fn_rubisco_15: $i > $i).
% 29.32/29.13  tff(decl_67681, type, fn_rubisco_16: $i > $i).
% 29.32/29.13  tff(decl_67682, type, fn_rubisco_17: $i > $i).
% 29.32/29.13  tff(decl_67683, type, fn_rubisco_19: $i > $i).
% 29.32/29.13  tff(decl_67684, type, fn_rubisco_20: $i > $i).
% 29.32/29.13  tff(decl_67685, type, fn_rubisco_21: $i > $i).
% 29.32/29.13  tff(decl_67686, type, fn_rubisco_22: $i > $i).
% 29.32/29.13  tff(decl_67687, type, fn_rubisco_23: $i > $i).
% 29.32/29.13  tff(decl_67688, type, fn_rubisco_24: $i > $i).
% 29.32/29.13  tff(decl_67689, type, fn_rubisco_25: $i > $i).
% 29.32/29.13  tff(decl_67690, type, fn_rubisco_26: $i > $i).
% 29.32/29.13  tff(decl_67691, type, fn_rubisco_27: $i > $i).
% 29.32/29.13  tff(decl_67692, type, fn_rubisco_28: $i > $i).
% 29.32/29.13  tff(decl_67693, type, 'Old': $i).
% 29.32/29.13  tff(decl_67694, type, fn_rubisco_3: $i > $i).
% 29.32/29.13  tff(decl_67695, type, fn_rubisco_4: $i > $i).
% 29.32/29.13  tff(decl_67696, type, fn_rubisco_5: $i > $i).
% 29.32/29.13  tff(decl_67697, type, 'Rudimentary-Gut-Cavity': $i).
% 29.32/29.13  tff(decl_67698, type, 'The cavity of the gut that is not fully developed is called as rudimentary gut cavity.': $i).
% 29.32/29.13  tff(decl_67699, type, 'rudimentary gut cavity': $i).
% 29.32/29.13  tff(decl_67700, type, 'rudimentary-gut-cavity': $i).
% 29.32/29.13  tff(decl_67701, type, rudolf_virchow_1: $i > $o).
% 29.32/29.13  tff(decl_67702, type, 'Rudolf-Virchow': $i).
% 29.32/29.13  tff(decl_67703, type, 'German physician who conducted experiments on the cell cycle and is credited with discovery of the Cell Theory.': $i).
% 29.32/29.13  tff(decl_67704, type, 'rudolf virchow': $i).
% 29.32/29.13  tff(decl_67705, type, 'rudolf-virchow': $i).
% 29.32/29.13  tff(decl_67706, type, ruin_1: $i > $o).
% 29.32/29.13  tff(decl_67707, type, 'Ruin': $i).
% 29.32/29.13  tff(decl_67708, type, 'Rule-Of-Addition': $i).
% 29.32/29.13  tff(decl_67709, type, 'A statistical rule that says the probability of an event that can happen in more tha one way is the sum of the individual probabilities. Used in determining heterozygote probabilities.': $i).
% 29.32/29.13  tff(decl_67710, type, 'addition rule': $i).
% 29.32/29.13  tff(decl_67711, type, 'addition-rule': $i).
% 29.32/29.13  tff(decl_67712, type, 'rule of addition': $i).
% 29.32/29.13  tff(decl_67713, type, 'rule-of-addition': $i).
% 29.32/29.13  tff(decl_67714, type, 'Rule-Of-Probability': $i).
% 29.32/29.13  tff(decl_67715, type, 'Rules that describe how likely it is that some event will occur.': $i).
% 29.32/29.13  tff(decl_67716, type, 'probability rule': $i).
% 29.32/29.13  tff(decl_67717, type, 'probability-rule': $i).
% 29.32/29.13  tff(decl_67718, type, 'rule of probability': $i).
% 29.32/29.13  tff(decl_67719, type, 'rule-of-probability': $i).
% 29.32/29.13  tff(decl_67720, type, fn_rule_of_probability_2: $i > $i).
% 29.32/29.13  tff(decl_67721, type, fn_rule_of_probability_3: $i > $i).
% 29.32/29.13  tff(decl_67722, type, fn_rule_of_probability_7: $i > $i).
% 29.32/29.13  tff(decl_67723, type, p: $i).
% 29.32/29.13  tff(decl_67724, type, 'Rumen': $i).
% 29.32/29.13  tff(decl_67725, type, 'The first stomach in the digestive system of a ruminant which serves as the primary site for microbial digestion before moving on to the reticulum.': $i).
% 29.32/29.13  tff(decl_67726, type, rumen: $i).
% 29.32/29.13  tff(decl_67727, type, ruminant_1: $i > $o).
% 29.32/29.13  tff(decl_67728, type, 'Ruminant': $i).
% 29.32/29.13  tff(decl_67729, type, 'An herbivorous mammal whose stomach has multiple chambers and is specialized for digesting plant material. Examples include cows and sheep.': $i).
% 29.32/29.13  tff(decl_67730, type, ruminant: $i).
% 29.32/29.13  tff(decl_67731, type, ruminant_digestive_system_1: $i > $o).
% 29.32/29.13  tff(decl_67732, type, 'Ruminant-Digestive-System': $i).
% 29.32/29.13  tff(decl_67733, type, 'The system of organs in a ruminant\\s body which is responsible for the digestion and absorption of nutrients from food.': $i).
% 29.32/29.13  tff(decl_67734, type, 'ruminant digestive system': $i).
% 29.32/29.13  tff(decl_67735, type, 'ruminant-digestive-system': $i).
% 29.32/29.13  tff(decl_67736, type, fn_ruminant_digestive_system_1: $i > $i).
% 29.32/29.13  tff(decl_67737, type, fn_ruminant_digestive_system_2: $i > $i).
% 29.32/29.13  tff(decl_67738, type, fn_ruminant_digestive_system_3: $i > $i).
% 29.32/29.13  tff(decl_67739, type, fn_ruminant_digestive_system_4: $i > $i).
% 29.32/29.13  tff(decl_67740, type, fn_ruminant_digestive_system_5: $i > $i).
% 29.32/29.13  tff(decl_67741, type, fn_ruminant_digestive_system_6: $i > $i).
% 29.32/29.13  tff(decl_67742, type, fn_ruminant_digestive_system_7: $i > $i).
% 29.32/29.13  tff(decl_67743, type, fn_ruminant_digestive_system_8: $i > $i).
% 29.32/29.13  tff(decl_67744, type, 'Runoff': $i).
% 29.32/29.13  tff(decl_67745, type, 'Draining of water from land surfaces.': $i).
% 29.32/29.13  tff(decl_67746, type, 'run off': $i).
% 29.32/29.13  tff(decl_67747, type, runoff: $i).
% 29.32/29.13  tff(decl_67748, type, ruthenium_1: $i > $o).
% 29.32/29.13  tff(decl_67749, type, 'Ruthenium': $i).
% 29.32/29.13  tff(decl_67750, type, 'Ruthenium is a metal atom with atomic number 44. It is represented by the symbol Ru.': $i).
% 29.32/29.13  tff(decl_67751, type, ruthenium: $i).
% 29.32/29.13  tff(decl_67752, type, 'Ru': $i).
% 29.32/29.13  tff(decl_67753, type, fn_ruthenium_3: $i > $i).
% 29.32/29.13  tff(decl_67754, type, fn_ruthenium_4: $i > $i).
% 29.32/29.13  tff(decl_67755, type, fn_ruthenium_5: $i > $i).
% 29.32/29.13  tff(decl_67756, type, fn_ruthenium_9: $i > $i).
% 29.32/29.13  tff(decl_67757, type, fn_ruthenium_10: $i > $i).
% 29.32/29.13  tff(decl_67758, type, fn_ruthenium_11: $i > $i).
% 29.32/29.13  tff(decl_67759, type, fn_ruthenium_12: $i > $i).
% 29.32/29.13  tff(decl_67760, type, "44": $i).
% 29.32/29.13  tff(decl_67761, type, "101.1": $i).
% 29.32/29.13  tff(decl_67762, type, fn_ruthenium_7: $i > $i).
% 29.32/29.13  tff(decl_67763, type, fn_ruthenium_8: $i > $i).
% 29.32/29.13  tff(decl_67764, type, fn_ruthenium_6: $i > $i).
% 29.32/29.13  tff(decl_67765, type, rutherfordium_1: $i > $o).
% 29.32/29.13  tff(decl_67766, type, 'Rutherfordium': $i).
% 29.32/29.13  tff(decl_67767, type, 'Rutherfordium is a metal atom with atomic number 104. It is represented by the symbol Rf.': $i).
% 29.32/29.13  tff(decl_67768, type, rutherfordium: $i).
% 29.32/29.13  tff(decl_67769, type, 'Rf': $i).
% 29.32/29.13  tff(decl_67770, type, fn_rutherfordium_2: $i > $i).
% 29.32/29.13  tff(decl_67771, type, fn_rutherfordium_3: $i > $i).
% 29.32/29.13  tff(decl_67772, type, fn_rutherfordium_7: $i > $i).
% 29.32/29.13  tff(decl_67773, type, fn_rutherfordium_8: $i > $i).
% 29.32/29.13  tff(decl_67774, type, fn_rutherfordium_9: $i > $i).
% 29.32/29.13  tff(decl_67775, type, fn_rutherfordium_10: $i > $i).
% 29.32/29.13  tff(decl_67776, type, "261": $i).
% 29.32/29.13  tff(decl_67777, type, fn_rutherfordium_5: $i > $i).
% 29.32/29.13  tff(decl_67778, type, fn_rutherfordium_6: $i > $i).
% 29.32/29.13  tff(decl_67779, type, fn_rutherfordium_4: $i > $i).
% 29.32/29.13  tff(decl_67780, type, s_albuterol_1: $i > $o).
% 29.32/29.13  tff(decl_67781, type, 'S-Albuterol': $i).
% 29.32/29.13  tff(decl_67782, type, 'S-Albuterol is the S-enantiomer of Albuterol.': $i).
% 29.32/29.13  tff(decl_67783, type, 'albuterol of s': $i).
% 29.32/29.13  tff(decl_67784, type, 's albuterol': $i).
% 29.32/29.13  tff(decl_67785, type, 's-albuterol': $i).
% 29.32/29.13  tff(decl_67786, type, s_gene_1: $i > $o).
% 29.32/29.13  tff(decl_67787, type, 'S-Gene': $i).
% 29.32/29.13  tff(decl_67788, type, 'A locus that codes for one of the mechanisms of self-incompatibility in plants.': $i).
% 29.32/29.13  tff(decl_67789, type, 'gene of s': $i).
% 29.32/29.13  tff(decl_67790, type, 's gene': $i).
% 29.32/29.13  tff(decl_67791, type, 's-gene': $i).
% 29.32/29.13  tff(decl_67792, type, s_ibuprofen_1: $i > $o).
% 29.32/29.13  tff(decl_67793, type, 'S-Ibuprofen': $i).
% 29.32/29.13  tff(decl_67794, type, 'Ibuprofen-S is the S-enantiomer of Ibuprofen.': $i).
% 29.32/29.13  tff(decl_67795, type, 'ibuprofen of s': $i).
% 29.32/29.13  tff(decl_67796, type, 's ibuprofen': $i).
% 29.32/29.13  tff(decl_67797, type, 's-ibuprofen': $i).
% 29.32/29.13  tff(decl_67798, type, s_minus_2_1: $i > $o).
% 29.32/29.13  tff(decl_67799, type, 'S-Minus-2': $i).
% 29.32/29.13  tff(decl_67800, type, 'The anion of sulfur. It is a strong base and a moderately strong reducing agent.': $i).
% 29.32/29.13  tff(decl_67801, type, sulfide: $i).
% 29.32/29.13  tff(decl_67802, type, 's minus 2': $i).
% 29.32/29.13  tff(decl_67803, type, 's-minus-2': $i).
% 29.32/29.13  tff(decl_67804, type, fn_s_minus_2_1: $i > $i).
% 29.32/29.13  tff(decl_67805, type, fn_s_minus_2_2: $i > $i).
% 29.32/29.13  tff(decl_67806, type, fn_s_minus_2_3: $i > $i).
% 29.32/29.13  tff(decl_67807, type, fn_s_minus_2_4: $i > $i).
% 29.32/29.13  tff(decl_67808, type, fn_s_minus_2_5: $i > $i).
% 29.32/29.13  tff(decl_67809, type, fn_s_minus_2_6: $i > $i).
% 29.32/29.13  tff(decl_67810, type, 'S-Orbital': $i).
% 29.32/29.13  tff(decl_67811, type, 'The s orbital is a spherically-shaped region describing where an electron can be found, within a certain degree of probability. The shape of the orbital depends on the quantum numbers associated with an energy state. All s orbitals have l = m = 0, but the value of n can vary.': $i).
% 29.32/29.13  tff(decl_67812, type, 'orbital of s': $i).
% 29.32/29.13  tff(decl_67813, type, 's orbital': $i).
% 29.32/29.13  tff(decl_67814, type, 's-orbital': $i).
% 29.32/29.13  tff(decl_67815, type, 'S-phase': $i).
% 29.32/29.13  tff(decl_67816, type, 'S phase is the phase between the G1 phase (initial interphase) and G2 phase (late interphase). This phase involves synthesis of copy of chromosomes i.e. DNA replication': $i).
% 29.32/29.13  tff(decl_67817, type, 'dna synthesis phase': $i).
% 29.32/29.13  tff(decl_67818, type, 'undergo s phase': $i).
% 29.32/29.13  tff(decl_67819, type, 'undergo s-phase': $i).
% 29.32/29.13  tff(decl_67820, type, 'phase of s': $i).
% 29.32/29.13  tff(decl_67821, type, 's phase': $i).
% 29.32/29.13  tff(decl_67822, type, 's-phase': $i).
% 29.32/29.13  tff(decl_67823, type, fn_s_phase_1: $i > $i).
% 29.32/29.13  tff(decl_67824, type, fn_s_phase_2: $i > $i).
% 29.32/29.13  tff(decl_67825, type, fn_s_phase_4: $i > $i).
% 29.32/29.13  tff(decl_67826, type, fn_s_phase_5: $i > $i).
% 29.32/29.13  tff(decl_67827, type, fn_s_phase_6: $i > $i).
% 29.32/29.13  tff(decl_67828, type, fn_s_phase_7: $i > $i).
% 29.32/29.13  tff(decl_67829, type, fn_s_phase_8: $i > $i).
% 29.32/29.13  tff(decl_67830, type, fn_s_phase_13: $i > $i).
% 29.32/29.13  tff(decl_67831, type, fn_s_phase_16: $i > $i).
% 29.32/29.13  tff(decl_67832, type, 'S.J.Singer': $i).
% 29.32/29.13  tff(decl_67833, type, singer: $i).
% 29.32/29.13  tff(decl_67834, type, 's. j. singer': $i).
% 29.32/29.13  tff(decl_67835, type, 's.j.singer': $i).
% 29.32/29.13  tff(decl_67836, type, sa_node_1: $i > $o).
% 29.32/29.13  tff(decl_67837, type, 'SA-Node': $i).
% 29.32/29.13  tff(decl_67838, type, 'The sinoatrial node, a cluster of cells in the upper wall of the right atrium of the heart, that act as a pacemaker. The electrical signals that stimulate contraction of cardiac muscle are generated at the SA node.': $i).
% 29.32/29.13  tff(decl_67839, type, 'sinoatrial node': $i).
% 29.32/29.13  tff(decl_67840, type, 'sinoatrial-node': $i).
% 29.32/29.13  tff(decl_67841, type, 'sino atrial node': $i).
% 29.32/29.13  tff(decl_67842, type, 'sino-atrial-node': $i).
% 29.32/29.13  tff(decl_67843, type, 'node of sa': $i).
% 29.32/29.13  tff(decl_67844, type, 'sa node': $i).
% 29.32/29.13  tff(decl_67845, type, 'sa-node': $i).
% 29.32/29.13  tff(decl_67846, type, 'Sac': $i).
% 29.32/29.13  tff(decl_67847, type, 'A pouch or pouchlike structure that may be filled with fluid.': $i).
% 29.32/29.13  tff(decl_67848, type, sac: $i).
% 29.32/29.13  tff(decl_67849, type, 'Saccharomyces-Cerevisiae': $i).
% 29.32/29.13  tff(decl_67850, type, 'A species  of budding  yeast.': $i).
% 29.32/29.13  tff(decl_67851, type, 'baker\\s yeast': $i).
% 29.32/29.13  tff(decl_67852, type, 'saccharomyces cerevisiae': $i).
% 29.32/29.13  tff(decl_67853, type, 's. cerevisiae': $i).
% 29.32/29.13  tff(decl_67854, type, 'bakers yeast': $i).
% 29.32/29.13  tff(decl_67855, type, 'saccharomyces-cerevisiae': $i).
% 29.32/29.13  tff(decl_67856, type, fn_saccharomyces_cerevisiae_1: $i > $i).
% 29.32/29.13  tff(decl_67857, type, 'Saccule': $i).
% 29.32/29.13  tff(decl_67858, type, 'In the vertebrate ear, a chamber containing sensory cells that translate movements of the head to neural impulses. The saccule is part of the vestibular system, which is important in maintaining the sense of balance, or equilibrium.': $i).
% 29.32/29.13  tff(decl_67859, type, saccule: $i).
% 29.32/29.13  tff(decl_67860, type, salicylic_acid_1: $i > $o).
% 29.32/29.13  tff(decl_67861, type, 'Salicylic-Acid': $i).
% 29.32/29.13  tff(decl_67862, type, 'A crystalline organic hormone that acts as a plant hormone. It is involved in growth, development, photosynthesis, and other aspects of plant physiology.': $i).
% 29.32/29.13  tff(decl_67863, type, 'aspirin, 2 hydroxybenzoic acid': $i).
% 29.32/29.13  tff(decl_67864, type, 'aspirin, 2-hydroxybenzoic-acid': $i).
% 29.32/29.13  tff(decl_67865, type, 'salicylic acid': $i).
% 29.32/29.13  tff(decl_67866, type, 'salicylic-acid': $i).
% 29.32/29.13  tff(decl_67867, type, salient_node_1: $i > $o).
% 29.32/29.13  tff(decl_67868, type, 'Salient-Node': $i).
% 29.32/29.13  tff(decl_67869, type, 'node of salient': $i).
% 29.32/29.13  tff(decl_67870, type, 'salient node': $i).
% 29.32/29.13  tff(decl_67871, type, 'salient-node': $i).
% 29.32/29.13  tff(decl_67872, type, salinization_of_soil_1: $i > $o).
% 29.32/29.13  tff(decl_67873, type, 'Salinization-Of-Soil': $i).
% 29.32/29.13  tff(decl_67874, type, 'The accumulation of salts in soil, due to natural processes such as mineral weathering or the withdrawal of an ocean, or artificial processes such as agricultural irrigation.': $i).
% 29.32/29.13  tff(decl_67875, type, 'salinization of soil': $i).
% 29.32/29.13  tff(decl_67876, type, 'salinization-of-soil': $i).
% 29.32/29.13  tff(decl_67877, type, 'Saliva': $i).
% 29.32/29.13  tff(decl_67878, type, 'A clear, water-based fluid secreted into the mouth by salivary glands. Human saliva contains enzymes and lubricants to begin digesting food and facilitate maceration and swallowing.': $i).
% 29.32/29.13  tff(decl_67879, type, spit: $i).
% 29.32/29.13  tff(decl_67880, type, spittle: $i).
% 29.32/29.13  tff(decl_67881, type, drivel: $i).
% 29.32/29.13  tff(decl_67882, type, drool: $i).
% 29.32/29.13  tff(decl_67883, type, slobber: $i).
% 29.32/29.13  tff(decl_67884, type, saliva: $i).
% 29.32/29.13  tff(decl_67885, type, fn_saliva_1: $i > $i).
% 29.32/29.13  tff(decl_67886, type, fn_saliva_2: $i > $i).
% 29.32/29.13  tff(decl_67887, type, fn_saliva_3: $i > $i).
% 29.32/29.13  tff(decl_67888, type, fn_saliva_4: $i > $i).
% 29.32/29.13  tff(decl_67889, type, fn_saliva_6: $i > $i).
% 29.32/29.13  tff(decl_67890, type, fn_saliva_7: $i > $i).
% 29.32/29.13  tff(decl_67891, type, fn_saliva_8: $i > $i).
% 29.32/29.13  tff(decl_67892, type, fn_saliva_9: $i > $i).
% 29.32/29.13  tff(decl_67893, type, fn_saliva_10: $i > $i).
% 29.32/29.13  tff(decl_67894, type, fn_saliva_11: $i > $i).
% 29.32/29.13  tff(decl_67895, type, fn_saliva_12: $i > $i).
% 29.32/29.13  tff(decl_67896, type, fn_saliva_13: $i > $i).
% 29.32/29.13  tff(decl_67897, type, fn_saliva_14: $i > $i).
% 29.32/29.13  tff(decl_67898, type, fn_saliva_15: $i > $i).
% 29.32/29.13  tff(decl_67899, type, fn_saliva_16: $i > $i).
% 29.32/29.13  tff(decl_67900, type, fn_saliva_17: $i > $i).
% 29.32/29.13  tff(decl_67901, type, fn_saliva_18: $i > $i).
% 29.32/29.13  tff(decl_67902, type, 'Salivary-Amylase': $i).
% 29.32/29.13  tff(decl_67903, type, 'An enzyme, secreted by the salivary glands, that breaks starch into sugars.': $i).
% 29.32/29.13  tff(decl_67904, type, 'salivary amylase': $i).
% 29.32/29.13  tff(decl_67905, type, 'salivary-amylase': $i).
% 29.32/29.13  tff(decl_67906, type, 'Salivary-Gland': $i).
% 29.32/29.13  tff(decl_67907, type, 'An exocrine gland that secretes saliva into the oral cavity.': $i).
% 29.32/29.13  tff(decl_67908, type, 'salivary gland': $i).
% 29.32/29.13  tff(decl_67909, type, 'salivary-gland': $i).
% 29.32/29.13  tff(decl_67910, type, fn_salivary_gland_1: $i > $i).
% 29.32/29.13  tff(decl_67911, type, 'Salmonella': $i).
% 29.32/29.13  tff(decl_67912, type, 'A genus of rod-shaped, Gram-negative enteric bacteria, found in the guts of many vertebrates. In humans, Salmonella causes diseases such as typhoid fever and foodborne illnesses.': $i).
% 29.32/29.13  tff(decl_67913, type, salmonella: $i).
% 29.32/29.13  tff(decl_67914, type, 'Salt': $i).
% 29.32/29.13  tff(decl_67915, type, 'A salt is an ionic compound formed by replacing one or more H+ of an acid by other cations.': $i).
% 29.32/29.13  tff(decl_67916, type, salt: $i).
% 29.32/29.13  tff(decl_67917, type, 'salt crystal': $i).
% 29.32/29.13  tff(decl_67918, type, fn_salt_2: $i > $i).
% 29.32/29.13  tff(decl_67919, type, 'Salt-Solution': $i).
% 29.32/29.13  tff(decl_67920, type, 'An ionic compound dissolved in a solvent.  Salt solution can refer specifically to a solution of sodium chloride or other ionic compounds.': $i).
% 29.32/29.13  tff(decl_67921, type, 'solution of salt': $i).
% 29.32/29.13  tff(decl_67922, type, 'salt solution': $i).
% 29.32/29.13  tff(decl_67923, type, 'salt-solution': $i).
% 29.32/29.13  tff(decl_67924, type, 'Salt-Status-Constant': $i).
% 29.32/29.13  tff(decl_67925, type, 'salt status constant': $i).
% 29.32/29.13  tff(decl_67926, type, 'salt-status-constant': $i).
% 29.32/29.13  tff(decl_67927, type, 'Salt-Status-Value': $i).
% 29.32/29.13  tff(decl_67928, type, 'whether an ionic compound is salt or not': $i).
% 29.32/29.13  tff(decl_67929, type, 'status of salt': $i).
% 29.32/29.13  tff(decl_67930, type, 'salt status': $i).
% 29.32/29.13  tff(decl_67931, type, 'salt-status': $i).
% 29.32/29.13  tff(decl_67932, type, 'salt status value': $i).
% 29.32/29.13  tff(decl_67933, type, 'salt-status-value': $i).
% 29.32/29.13  tff(decl_67934, type, 'Salt-Substance': $i).
% 29.32/29.13  tff(decl_67935, type, 'A Chemical whose basic structural unit is a Salt (an ionic compound formed by replacing one or more H+ of an acid by other cations).': $i).
% 29.32/29.13  tff(decl_67936, type, 'substance of salt': $i).
% 29.32/29.13  tff(decl_67937, type, 'salt substance': $i).
% 29.32/29.13  tff(decl_67938, type, 'salt-substance': $i).
% 29.32/29.13  tff(decl_67939, type, fn_salt_substance_2: $i > $i).
% 29.32/29.13  tff(decl_67940, type, fn_salt_substance_3: $i > $i).
% 29.32/29.13  tff(decl_67941, type, fn_salt_substance_1: $i > $i).
% 29.32/29.13  tff(decl_67942, type, saltatory_conduction_1: $i > $o).
% 29.32/29.13  tff(decl_67943, type, 'Saltatory-Conduction': $i).
% 29.32/29.13  tff(decl_67944, type, 'The rapid propagation of an action potential along the myelinated axon of a neuron, resulting from the action potential jumping from one node of Ranvier to the next and skipping over the myelinated sections of the axon.': $i).
% 29.32/29.13  tff(decl_67945, type, 'saltatory conduction': $i).
% 29.32/29.13  tff(decl_67946, type, 'saltatory-conduction': $i).
% 29.32/29.13  tff(decl_67947, type, samarium_1: $i > $o).
% 29.32/29.13  tff(decl_67948, type, 'Samarium': $i).
% 29.32/29.13  tff(decl_67949, type, 'Samarium is a metal atom with atomic number 62. It is represented by the symbol Sm.': $i).
% 29.32/29.13  tff(decl_67950, type, samarium: $i).
% 29.32/29.13  tff(decl_67951, type, sm: $i).
% 29.32/29.13  tff(decl_67952, type, fn_samarium_3: $i > $i).
% 29.32/29.13  tff(decl_67953, type, fn_samarium_4: $i > $i).
% 29.32/29.13  tff(decl_67954, type, fn_samarium_5: $i > $i).
% 29.32/29.13  tff(decl_67955, type, fn_samarium_9: $i > $i).
% 29.32/29.13  tff(decl_67956, type, fn_samarium_10: $i > $i).
% 29.32/29.13  tff(decl_67957, type, fn_samarium_11: $i > $i).
% 29.32/29.13  tff(decl_67958, type, fn_samarium_12: $i > $i).
% 29.32/29.13  tff(decl_67959, type, "62": $i).
% 29.32/29.13  tff(decl_67960, type, "1.17": $i).
% 29.32/29.13  tff(decl_67961, type, "150.4": $i).
% 29.32/29.13  tff(decl_67962, type, fn_samarium_7: $i > $i).
% 29.32/29.13  tff(decl_67963, type, fn_samarium_8: $i > $i).
% 29.32/29.13  tff(decl_67964, type, fn_samarium_6: $i > $i).
% 29.32/29.13  tff(decl_67965, type, sand_dollar_embryo_1: $i > $o).
% 29.32/29.13  tff(decl_67966, type, 'Sand-Dollar-Embryo': $i).
% 29.32/29.13  tff(decl_67967, type, 'The early, free swimming developmental stage of a sand dollar.': $i).
% 29.32/29.13  tff(decl_67968, type, 'sand dollar embryo': $i).
% 29.32/29.13  tff(decl_67969, type, 'sand-dollar-embryo': $i).
% 29.32/29.13  tff(decl_67970, type, fn_sand_dollar_embryo_2: $i > $i).
% 29.32/29.13  tff(decl_67971, type, 'Sandwich-Model': $i).
% 29.32/29.13  tff(decl_67972, type, 'In 1935, Hugh Davson and James Danielli modeled the cell membrane as a sandwich:  a phospholipid bilayer sandwiched between two layers of protein.': $i).
% 29.32/29.13  tff(decl_67973, type, 'davson danielli model': $i).
% 29.32/29.13  tff(decl_67974, type, 'davson-danielli-model': $i).
% 29.32/29.13  tff(decl_67975, type, 'davson-danielli model': $i).
% 29.32/29.13  tff(decl_67976, type, 'davson danielli': $i).
% 29.32/29.13  tff(decl_67977, type, 'davson-danielli': $i).
% 29.32/29.13  tff(decl_67978, type, 'model of sandwich': $i).
% 29.32/29.13  tff(decl_67979, type, 'sandwich model': $i).
% 29.32/29.13  tff(decl_67980, type, 'sandwich-model': $i).
% 29.32/29.13  tff(decl_67981, type, fn_sandwich_model_1: $i > $i).
% 29.32/29.13  tff(decl_67982, type, fn_sandwich_model_3: $i > $i).
% 29.32/29.13  tff(decl_67983, type, fn_sandwich_model_4: $i > $i).
% 29.32/29.13  tff(decl_67984, type, fn_sandwich_model_5: $i > $i).
% 29.32/29.13  tff(decl_67985, type, fn_sandwich_model_6: $i > $i).
% 29.32/29.13  tff(decl_67986, type, fn_sandwich_model_7: $i > $i).
% 29.32/29.13  tff(decl_67987, type, fn_sandwich_model_8: $i > $i).
% 29.32/29.13  tff(decl_67988, type, fn_sandwich_model_9: $i > $i).
% 29.32/29.13  tff(decl_67989, type, fn_sandwich_model_10: $i > $i).
% 29.32/29.13  tff(decl_67990, type, fn_sandwich_model_11: $i > $i).
% 29.32/29.13  tff(decl_67991, type, fn_sandwich_model_12: $i > $i).
% 29.32/29.13  tff(decl_67992, type, fn_sandwich_model_13: $i > $i).
% 29.32/29.13  tff(decl_67993, type, fn_sandwich_model_14: $i > $i).
% 29.32/29.13  tff(decl_67994, type, fn_sandwich_model_15: $i > $i).
% 29.32/29.13  tff(decl_67995, type, fn_sandwich_model_16: $i > $i).
% 29.32/29.13  tff(decl_67996, type, fn_sandwich_model_17: $i > $i).
% 29.32/29.13  tff(decl_67997, type, fn_sandwich_model_18: $i > $i).
% 29.32/29.13  tff(decl_67998, type, 'PL1': $i).
% 29.32/29.13  tff(decl_67999, type, 'PL2': $i).
% 29.32/29.13  tff(decl_68000, type, 'MP3': $i).
% 29.32/29.13  tff(decl_68001, type, 'MP4': $i).
% 29.32/29.13  tff(decl_68002, type, 'Sap': $i).
% 29.32/29.13  tff(decl_68003, type, 'A solution of salts, sugars, minerals and other dissolved substances.': $i).
% 29.32/29.13  tff(decl_68004, type, sap: $i).
% 29.32/29.13  tff(decl_68005, type, 'Sapwood': $i).
% 29.32/29.13  tff(decl_68006, type, 'Plant tissue comprised of secondary xylem that transports water and minerals up the plant.': $i).
% 29.32/29.13  tff(decl_68007, type, sapwood: $i).
% 29.32/29.13  tff(decl_68008, type, 'Sarcomere': $i).
% 29.32/29.13  tff(decl_68009, type, 'The functional, contractile unit of striated muscle, bounded on each end by the Z lines.': $i).
% 29.32/29.13  tff(decl_68010, type, sarcomere: $i).
% 29.32/29.13  tff(decl_68011, type, sarcoplasmic_reticulum_1: $i > $o).
% 29.32/29.13  tff(decl_68012, type, 'Sarcoplasmic-Reticulum': $i).
% 29.32/29.13  tff(decl_68013, type, 'Smooth endoplasmic reticulum that is found in smooth and striated muscle. Sarcoplasmic reticulum regulates the amount of calcium in the cytoplasm of muscle cells.': $i).
% 29.32/29.13  tff(decl_68014, type, 'sarcoplasmic reticulum': $i).
% 29.32/29.13  tff(decl_68015, type, 'sarcoplasmic-reticulum': $i).
% 29.32/29.13  tff(decl_68016, type, sarin_1: $i > $o).
% 29.32/29.13  tff(decl_68017, type, 'Sarin': $i).
% 29.32/29.13  tff(decl_68018, type, 'An organophosphorus nerve gas used as a chemical weapon.': $i).
% 29.32/29.13  tff(decl_68019, type, sarin: $i).
% 29.32/29.13  tff(decl_68020, type, fn_sarin_1: $i > $i).
% 29.32/29.13  tff(decl_68021, type, fn_sarin_7: $i > $i).
% 29.32/29.13  tff(decl_68022, type, fn_sarin_8: $i > $i).
% 29.32/29.13  tff(decl_68023, type, fn_sarin_9: $i > $i).
% 29.32/29.13  tff(decl_68024, type, fn_sarin_10: $i > $i).
% 29.32/29.13  tff(decl_68025, type, fn_sarin_11: $i > $i).
% 29.32/29.13  tff(decl_68026, type, fn_sarin_12: $i > $i).
% 29.32/29.13  tff(decl_68027, type, fn_sarin_13: $i > $i).
% 29.32/29.13  tff(decl_68028, type, fn_sarin_14: $i > $i).
% 29.32/29.13  tff(decl_68029, type, fn_sarin_15: $i > $i).
% 29.32/29.13  tff(decl_68030, type, fn_sarin_16: $i > $i).
% 29.32/29.13  tff(decl_68031, type, fn_sarin_17: $i > $i).
% 29.32/29.13  tff(decl_68032, type, fn_sarin_18: $i > $i).
% 29.32/29.13  tff(decl_68033, type, fn_sarin_19: $i > $i).
% 29.32/29.13  tff(decl_68034, type, fn_sarin_20: $i > $i).
% 29.32/29.13  tff(decl_68035, type, fn_sarin_21: $i > $i).
% 29.32/29.13  tff(decl_68036, type, fn_sarin_22: $i > $i).
% 29.32/29.13  tff(decl_68037, type, fn_sarin_23: $i > $i).
% 29.32/29.13  tff(decl_68038, type, fn_sarin_24: $i > $i).
% 29.32/29.13  tff(decl_68039, type, fn_sarin_25: $i > $i).
% 29.32/29.13  tff(decl_68040, type, fn_sarin_26: $i > $i).
% 29.32/29.13  tff(decl_68041, type, fn_sarin_27: $i > $i).
% 29.32/29.13  tff(decl_68042, type, fn_sarin_28: $i > $i).
% 29.32/29.13  tff(decl_68043, type, fn_sarin_29: $i > $i).
% 29.32/29.13  tff(decl_68044, type, fn_sarin_30: $i > $i).
% 29.32/29.13  tff(decl_68045, type, fn_sarin_31: $i > $i).
% 29.32/29.13  tff(decl_68046, type, fn_sarin_32: $i > $i).
% 29.32/29.13  tff(decl_68047, type, fn_sarin_33: $i > $i).
% 29.32/29.13  tff(decl_68048, type, fn_sarin_34: $i > $i).
% 29.32/29.13  tff(decl_68049, type, fn_sarin_35: $i > $i).
% 29.32/29.13  tff(decl_68050, type, fn_sarin_36: $i > $i).
% 29.32/29.13  tff(decl_68051, type, fn_sarin_37: $i > $i).
% 29.32/29.13  tff(decl_68052, type, fn_sarin_38: $i > $i).
% 29.32/29.13  tff(decl_68053, type, fn_sarin_39: $i > $i).
% 29.32/29.13  tff(decl_68054, type, fn_sarin_40: $i > $i).
% 29.32/29.13  tff(decl_68055, type, fn_sarin_41: $i > $i).
% 29.32/29.13  tff(decl_68056, type, fn_sarin_42: $i > $i).
% 29.32/29.13  tff(decl_68057, type, organic_phosphate_0: $i).
% 29.32/29.13  tff(decl_68058, type, fn_sarin_5: $i > $i).
% 29.32/29.13  tff(decl_68059, type, fn_sarin_6: $i > $i).
% 29.32/29.13  tff(decl_68060, type, fn_sarin_4: $i > $i).
% 29.32/29.13  tff(decl_68061, type, fn_sarin_3: $i > $i).
% 29.32/29.13  tff(decl_68062, type, satiety_center_1: $i > $o).
% 29.32/29.13  tff(decl_68063, type, 'Satiety-Center': $i).
% 29.32/29.13  tff(decl_68064, type, 'Region of the brain which functions in appetite regulation.': $i).
% 29.32/29.13  tff(decl_68065, type, 'center of satiety': $i).
% 29.32/29.13  tff(decl_68066, type, 'satiety center': $i).
% 29.32/29.13  tff(decl_68067, type, 'satiety-center': $i).
% 29.32/29.13  tff(decl_68068, type, fn_satiety_center_1: $i > $i).
% 29.32/29.13  tff(decl_68069, type, 'Saturated-Animal-Fat': $i).
% 29.32/29.13  tff(decl_68070, type, 'Any fat (such as butter, suet or lard) that comes from an animal. Because they are almost entirely saturated, animal fats are not recommended for people on lowfat or low-cholesterol diets': $i).
% 29.32/29.13  tff(decl_68071, type, 'saturated animal fat': $i).
% 29.32/29.13  tff(decl_68072, type, 'saturated-animal-fat': $i).
% 29.32/29.13  tff(decl_68073, type, fn_saturated_animal_fat_substance_2: $i > $i).
% 29.32/29.13  tff(decl_68074, type, 'Saturated-Animal-Fat-Substance': $i).
% 29.32/29.13  tff(decl_68075, type, 'A technique using a scanning electron microscope which uses an electron beam to scan the surface of a sample, coated with metal atoms, to study details of its topography.': $i).
% 29.32/29.13  tff(decl_68076, type, 'saturated animal fat substance': $i).
% 29.32/29.13  tff(decl_68077, type, 'saturated-animal-fat-substance': $i).
% 29.32/29.13  tff(decl_68078, type, fn_saturated_animal_fat_substance_3: $i > $i).
% 29.32/29.13  tff(decl_68079, type, fn_saturated_animal_fat_substance_4: $i > $i).
% 29.32/29.13  tff(decl_68080, type, 'Saturated-Fat': $i).
% 29.32/29.13  tff(decl_68081, type, 'Saturated fat is a fat that consists of one to three saturated fatty acids attached to a glycerol.': $i).
% 29.32/29.13  tff(decl_68082, type, 'saturated fat': $i).
% 29.32/29.13  tff(decl_68083, type, 'saturated-fat': $i).
% 29.32/29.13  tff(decl_68084, type, fn_saturated_fat_1: $i > $i).
% 29.32/29.13  tff(decl_68085, type, 'Saturated-Fatty-Acid': $i).
% 29.32/29.13  tff(decl_68086, type, 'Saturated fatty acids are long-chain carboxylic acids that usually have between 12 and 24 carbon atoms and have no double bonds.': $i).
% 29.32/29.13  tff(decl_68087, type, 'saturated fatty acid tail': $i).
% 29.32/29.13  tff(decl_68088, type, 'saturated-fatty-acid-tail': $i).
% 29.32/29.13  tff(decl_68089, type, 'saturated hydrocarbon tail': $i).
% 29.32/29.13  tff(decl_68090, type, 'saturated phospholipid': $i).
% 29.32/29.13  tff(decl_68091, type, 'saturated hydrocarbon': $i).
% 29.32/29.13  tff(decl_68092, type, 'saturated fatty acid': $i).
% 29.32/29.13  tff(decl_68093, type, 'saturated-fatty-acid': $i).
% 29.32/29.13  tff(decl_68094, type, fn_saturated_fatty_acid_2: $i > $i).
% 29.32/29.13  tff(decl_68095, type, fn_saturated_fatty_acid_3: $i > $i).
% 29.32/29.13  tff(decl_68096, type, fn_saturated_fatty_acid_7: $i > $i).
% 29.32/29.13  tff(decl_68097, type, fn_saturated_fatty_acid_8: $i > $i).
% 29.32/29.13  tff(decl_68098, type, fn_saturated_fatty_acid_9: $i > $i).
% 29.32/29.13  tff(decl_68099, type, fn_saturated_fatty_acid_10: $i > $i).
% 29.32/29.13  tff(decl_68100, type, fn_saturated_fatty_acid_11: $i > $i).
% 29.32/29.13  tff(decl_68101, type, fn_saturated_fatty_acid_12: $i > $i).
% 29.32/29.13  tff(decl_68102, type, fn_saturated_fatty_acid_13: $i > $i).
% 29.32/29.13  tff(decl_68103, type, fn_saturated_fatty_acid_14: $i > $i).
% 29.32/29.13  tff(decl_68104, type, fn_saturated_fatty_acid_15: $i > $i).
% 29.32/29.13  tff(decl_68105, type, fn_saturated_fatty_acid_16: $i > $i).
% 29.32/29.13  tff(decl_68106, type, fn_saturated_fatty_acid_17: $i > $i).
% 29.32/29.13  tff(decl_68107, type, fn_saturated_fatty_acid_18: $i > $i).
% 29.32/29.13  tff(decl_68108, type, fn_saturated_fatty_acid_19: $i > $i).
% 29.32/29.13  tff(decl_68109, type, fn_saturated_fatty_acid_20: $i > $i).
% 29.32/29.13  tff(decl_68110, type, fn_saturated_fatty_acid_21: $i > $i).
% 29.32/29.13  tff(decl_68111, type, fn_saturated_fatty_acid_22: $i > $i).
% 29.32/29.13  tff(decl_68112, type, fn_saturated_fatty_acid_23: $i > $i).
% 29.32/29.13  tff(decl_68113, type, fn_saturated_fatty_acid_24: $i > $i).
% 29.32/29.13  tff(decl_68114, type, fn_saturated_fatty_acid_25: $i > $i).
% 29.32/29.13  tff(decl_68115, type, fn_saturated_fatty_acid_26: $i > $i).
% 29.32/29.13  tff(decl_68116, type, fn_saturated_fatty_acid_27: $i > $i).
% 29.32/29.13  tff(decl_68117, type, fn_saturated_fatty_acid_28: $i > $i).
% 29.32/29.13  tff(decl_68118, type, fn_saturated_fatty_acid_29: $i > $i).
% 29.32/29.13  tff(decl_68119, type, fn_saturated_fatty_acid_30: $i > $i).
% 29.32/29.13  tff(decl_68120, type, fn_saturated_fatty_acid_31: $i > $i).
% 29.32/29.13  tff(decl_68121, type, fn_saturated_fatty_acid_32: $i > $i).
% 29.32/29.13  tff(decl_68122, type, fn_saturated_fatty_acid_33: $i > $i).
% 29.32/29.13  tff(decl_68123, type, fn_saturated_fatty_acid_34: $i > $i).
% 29.32/29.13  tff(decl_68124, type, fn_saturated_fatty_acid_35: $i > $i).
% 29.32/29.13  tff(decl_68125, type, fn_saturated_fatty_acid_36: $i > $i).
% 29.32/29.13  tff(decl_68126, type, fn_saturated_fatty_acid_37: $i > $i).
% 29.32/29.13  tff(decl_68127, type, fn_saturated_fatty_acid_38: $i > $i).
% 29.32/29.13  tff(decl_68128, type, fn_saturated_fatty_acid_39: $i > $i).
% 29.32/29.13  tff(decl_68129, type, fn_saturated_fatty_acid_40: $i > $i).
% 29.32/29.13  tff(decl_68130, type, fn_saturated_fatty_acid_41: $i > $i).
% 29.32/29.13  tff(decl_68131, type, fn_saturated_fatty_acid_42: $i > $i).
% 29.32/29.13  tff(decl_68132, type, fn_saturated_fatty_acid_43: $i > $i).
% 29.32/29.13  tff(decl_68133, type, fn_saturated_fatty_acid_44: $i > $i).
% 29.32/29.13  tff(decl_68134, type, fn_saturated_fatty_acid_45: $i > $i).
% 29.32/29.13  tff(decl_68135, type, fn_saturated_fatty_acid_46: $i > $i).
% 29.32/29.13  tff(decl_68136, type, fn_saturated_fatty_acid_47: $i > $i).
% 29.32/29.13  tff(decl_68137, type, fn_saturated_fatty_acid_48: $i > $i).
% 29.32/29.13  tff(decl_68138, type, fn_saturated_fatty_acid_49: $i > $i).
% 29.32/29.13  tff(decl_68139, type, fn_saturated_fatty_acid_50: $i > $i).
% 29.32/29.13  tff(decl_68140, type, fn_saturated_fatty_acid_51: $i > $i).
% 29.32/29.13  tff(decl_68141, type, fn_saturated_fatty_acid_52: $i > $i).
% 29.32/29.13  tff(decl_68142, type, fn_saturated_fatty_acid_53: $i > $i).
% 29.32/29.13  tff(decl_68143, type, fn_saturated_fatty_acid_54: $i > $i).
% 29.32/29.13  tff(decl_68144, type, fn_saturated_fatty_acid_55: $i > $i).
% 29.32/29.13  tff(decl_68145, type, fn_saturated_fatty_acid_56: $i > $i).
% 29.32/29.13  tff(decl_68146, type, fn_saturated_fatty_acid_57: $i > $i).
% 29.32/29.13  tff(decl_68147, type, fn_saturated_fatty_acid_58: $i > $i).
% 29.32/29.13  tff(decl_68148, type, fn_saturated_fatty_acid_59: $i > $i).
% 29.32/29.13  tff(decl_68149, type, fn_saturated_fatty_acid_60: $i > $i).
% 29.32/29.13  tff(decl_68150, type, fn_saturated_fatty_acid_61: $i > $i).
% 29.32/29.13  tff(decl_68151, type, fn_saturated_fatty_acid_62: $i > $i).
% 29.32/29.13  tff(decl_68152, type, fn_saturated_fatty_acid_63: $i > $i).
% 29.32/29.13  tff(decl_68153, type, fn_saturated_fatty_acid_64: $i > $i).
% 29.32/29.13  tff(decl_68154, type, fn_saturated_fatty_acid_65: $i > $i).
% 29.32/29.13  tff(decl_68155, type, fn_saturated_fatty_acid_66: $i > $i).
% 29.32/29.13  tff(decl_68156, type, fn_saturated_fatty_acid_67: $i > $i).
% 29.32/29.13  tff(decl_68157, type, fn_saturated_fatty_acid_68: $i > $i).
% 29.32/29.13  tff(decl_68158, type, fn_saturated_fatty_acid_69: $i > $i).
% 29.32/29.13  tff(decl_68159, type, fn_saturated_fatty_acid_70: $i > $i).
% 29.32/29.13  tff(decl_68160, type, fn_saturated_fatty_acid_71: $i > $i).
% 29.32/29.13  tff(decl_68161, type, fn_saturated_fatty_acid_72: $i > $i).
% 29.32/29.13  tff(decl_68162, type, fn_saturated_fatty_acid_73: $i > $i).
% 29.32/29.13  tff(decl_68163, type, unsaturated_fatty_acid_0: $i).
% 29.32/29.13  tff(decl_68164, type, fn_saturated_fatty_acid_5: $i > $i).
% 29.32/29.13  tff(decl_68165, type, fn_saturated_fatty_acid_6: $i > $i).
% 29.32/29.13  tff(decl_68166, type, 'Savanna': $i).
% 29.32/29.13  tff(decl_68167, type, 'A grassland biome in which trees are sparsely distributed so that the canopy does not close and enough sunlight penetrates to support the growth of grasses. Savannas are characterized by seasonal rain and occasional wildfire.': $i).
% 29.32/29.13  tff(decl_68168, type, savanna: $i).
% 29.32/29.13  tff(decl_68169, type, 'Scaffolding-Protein': $i).
% 29.32/29.13  tff(decl_68170, type, 'A type of protein that regulates signaling pathways; a large protein to which other relay proteins are attached, making signal transmission more efficient.': $i).
% 29.32/29.13  tff(decl_68171, type, 'protein of scaffolding': $i).
% 29.32/29.13  tff(decl_68172, type, 'scaffolding protein': $i).
% 29.32/29.13  tff(decl_68173, type, 'scaffolding-protein': $i).
% 29.32/29.13  tff(decl_68174, type, fn_scaffolding_protein_1: $i > $i).
% 29.32/29.13  tff(decl_68175, type, signal_transduction_with_scaffolding_protein_1: $i > $o).
% 29.32/29.13  tff(decl_68176, type, fn_scaffolding_protein_2: $i > $i).
% 29.32/29.13  tff(decl_68177, type, fn_scaffolding_protein_3: $i > $i).
% 29.32/29.13  tff(decl_68178, type, fn_scaffolding_protein_4: $i > $i).
% 29.32/29.13  tff(decl_68179, type, fn_scaffolding_protein_6: $i > $i).
% 29.32/29.13  tff(decl_68180, type, fn_scaffolding_protein_7: $i > $i).
% 29.32/29.13  tff(decl_68181, type, fn_scaffolding_protein_8: $i > $i).
% 29.32/29.13  tff(decl_68182, type, relay_protein_0: $i).
% 29.32/29.13  tff(decl_68183, type, fn_scaffolding_protein_5: $i > $i).
% 29.32/29.13  tff(decl_68184, type, scalar_1: $i > $o).
% 29.32/29.13  tff(decl_68185, type, 'Scalar': $i).
% 29.32/29.13  tff(decl_68186, type, scalar: $i).
% 29.32/29.13  tff(decl_68187, type, 'Scale': $i).
% 29.32/29.13  tff(decl_68188, type, scale: $i).
% 29.32/29.13  tff(decl_68189, type, scandium_1: $i > $o).
% 29.32/29.13  tff(decl_68190, type, 'Scandium': $i).
% 29.32/29.13  tff(decl_68191, type, 'Scandium is a metal atom with atomic number 21. It is represented by the symbol Sc.': $i).
% 29.32/29.13  tff(decl_68192, type, scandium: $i).
% 29.32/29.13  tff(decl_68193, type, 'Sc': $i).
% 29.32/29.13  tff(decl_68194, type, fn_scandium_4: $i > $i).
% 29.32/29.13  tff(decl_68195, type, fn_scandium_5: $i > $i).
% 29.32/29.13  tff(decl_68196, type, fn_scandium_6: $i > $i).
% 29.32/29.13  tff(decl_68197, type, fn_scandium_7: $i > $i).
% 29.32/29.13  tff(decl_68198, type, fn_scandium_11: $i > $i).
% 29.32/29.13  tff(decl_68199, type, fn_scandium_12: $i > $i).
% 29.32/29.13  tff(decl_68200, type, fn_scandium_13: $i > $i).
% 29.32/29.13  tff(decl_68201, type, fn_scandium_14: $i > $i).
% 29.32/29.13  tff(decl_68202, type, "21": $i).
% 29.32/29.13  tff(decl_68203, type, "44.96": $i).
% 29.32/29.13  tff(decl_68204, type, fn_scandium_9: $i > $i).
% 29.32/29.13  tff(decl_68205, type, fn_scandium_10: $i > $i).
% 29.32/29.13  tff(decl_68206, type, fn_scandium_8: $i > $i).
% 29.32/29.13  tff(decl_68207, type, scanning_electron_microscope_1: $i > $o).
% 29.32/29.13  tff(decl_68208, type, 'Scanning-Electron-Microscope': $i).
% 29.32/29.13  tff(decl_68209, type, 'A scanning electron microscope, a type of electron microscope that images the sample surface by scanning it with a high-energy beam of electrons in a raster scan pattern. The electrons interact with the atoms that make up the sample producing signals that contain information about the sample\\s surface topography, composition and other properties such as electrical conductivity.': $i).
% 29.32/29.13  tff(decl_68210, type, sem: $i).
% 29.32/29.13  tff(decl_68211, type, 'scanning electron microscope': $i).
% 29.32/29.13  tff(decl_68212, type, 'scanning-electron-microscope': $i).
% 29.32/29.13  tff(decl_68213, type, scanning_electron_microscopy_1: $i > $o).
% 29.32/29.13  tff(decl_68214, type, 'Scanning-Electron-Microscopy': $i).
% 29.32/29.13  tff(decl_68215, type, 'The scanning electron microscope (SEM) uses a focused beam of high-energy electrons to generate a variety of signals at the surface of solid specimens. The signals that derive from electron-sample interactions reveal information about the sample including external morphology (texture), chemical composition, and crystalline structure and orientation of materials making up the sample. This technique iused to view sample using a scanning electron microscope is called Scanning electron microscopy.': $i).
% 29.32/29.13  tff(decl_68216, type, 'scanning electron microscopy': $i).
% 29.32/29.13  tff(decl_68217, type, 'scanning-electron-microscopy': $i).
% 29.32/29.13  tff(decl_68218, type, transmission_electron_microscopy_1: $i > $o).
% 29.32/29.13  tff(decl_68219, type, fn_scanning_electron_microscopy_1: $i > $i).
% 29.32/29.13  tff(decl_68220, type, fn_scanning_electron_microscopy_2: $i > $i).
% 29.32/29.13  tff(decl_68221, type, 'Schizophrenia': $i).
% 29.32/29.13  tff(decl_68222, type, 'A chronic, severe, and often debilitating brain disorder characterized by periods in which patients suffer from delusions, hallucinations, and paranoia.': $i).
% 29.32/29.13  tff(decl_68223, type, schizophrenia: $i).
% 29.32/29.13  tff(decl_68224, type, 'Schwann-Cell': $i).
% 29.32/29.13  tff(decl_68225, type, 'The type of glial cell that wraps around the axons of neurons in the peripheral nervous system to form the myelin sheath.': $i).
% 29.32/29.13  tff(decl_68226, type, 'cell of schwann': $i).
% 29.32/29.13  tff(decl_68227, type, 'schwann cell': $i).
% 29.32/29.13  tff(decl_68228, type, 'schwann-cell': $i).
% 29.32/29.13  tff(decl_68229, type, science_as_a_social_process_1: $i > $o).
% 29.32/29.13  tff(decl_68230, type, 'Science-As-A-Social-Process': $i).
% 29.32/29.13  tff(decl_68231, type, 'The view that science is a process constructed and mediated by human interaction.': $i).
% 29.32/29.13  tff(decl_68232, type, 'science as a social process': $i).
% 29.32/29.13  tff(decl_68233, type, 'science-as-a-social-process': $i).
% 29.32/29.13  tff(decl_68234, type, 'Science-As-Process': $i).
% 29.32/29.13  tff(decl_68235, type, 'The view of science as a process of investigation that includes making repeatable observations and testing hypotheses.': $i).
% 29.32/29.13  tff(decl_68236, type, 'science as process': $i).
% 29.32/29.13  tff(decl_68237, type, 'science-as-process': $i).
% 29.32/29.13  tff(decl_68238, type, 'Scientific-Device': $i).
% 29.32/29.13  tff(decl_68239, type, 'Any item that is used to do research or make scientific observations.': $i).
% 29.32/29.13  tff(decl_68240, type, 'scientific device': $i).
% 29.32/29.13  tff(decl_68241, type, 'scientific-device': $i).
% 29.32/29.13  tff(decl_68242, type, 'Scientific-Laws': $i).
% 29.32/29.13  tff(decl_68243, type, 'A concise statement, based on repeated experimental observations, that expresses a fundamental scientific principle.': $i).
% 29.32/29.13  tff(decl_68244, type, 'scientific laws': $i).
% 29.32/29.13  tff(decl_68245, type, 'scientific law': $i).
% 29.32/29.13  tff(decl_68246, type, 'scientific-law': $i).
% 29.32/29.13  tff(decl_68247, type, 'Scientific-Method': $i).
% 29.32/29.13  tff(decl_68248, type, 'A formal process of inquiry consisting of a series of steps that ideally leads to explanations to sought questions.': $i).
% 29.32/29.13  tff(decl_68249, type, 'scientific method': $i).
% 29.32/29.13  tff(decl_68250, type, 'scientific-method': $i).
% 29.32/29.13  tff(decl_68251, type, 'Scientist': $i).
% 29.32/29.13  tff(decl_68252, type, 'A person who is engaged in scientific research or the understanding of science.': $i).
% 29.32/29.13  tff(decl_68253, type, researcher: $i).
% 29.32/29.13  tff(decl_68254, type, scientist: $i).
% 29.32/29.13  tff(decl_68255, type, 'Scion': $i).
% 29.32/29.13  tff(decl_68256, type, 'In botanic grafting, the shoot that is grafted onto the rootstock.': $i).
% 29.32/29.13  tff(decl_68257, type, scion: $i).
% 29.32/29.13  tff(decl_68258, type, 'Sclera': $i).
% 29.32/29.13  tff(decl_68259, type, 'The opaque, tough outer layer of the vertebrate eye.': $i).
% 29.32/29.13  tff(decl_68260, type, sclera: $i).
% 29.32/29.13  tff(decl_68261, type, 'Sclereid': $i).
% 29.32/29.13  tff(decl_68262, type, 'Irregularly sclerenchyma cells with thickened walls. Some plants have sclereids scattered throughout the parenchyma.': $i).
% 29.32/29.13  tff(decl_68263, type, sclereid: $i).
% 29.32/29.13  tff(decl_68264, type, 'Sclerenchyma-Cell': $i).
% 29.32/29.13  tff(decl_68265, type, 'A type of supportive plant cell with lignified secondary walls. Sclerenchyma cells are usually dead at maturity.': $i).
% 29.32/29.13  tff(decl_68266, type, 'sclerenchyma cell': $i).
% 29.32/29.13  tff(decl_68267, type, 'sclerenchyma-cell': $i).
% 29.32/29.13  tff(decl_68268, type, 'Sclerenchyma-Fiber': $i).
% 29.32/29.13  tff(decl_68269, type, 'Long, slender sclerenchyma cells, typically occurring in bundles. They provide support to the plant and are typically dead at maturity.': $i).
% 29.32/29.13  tff(decl_68270, type, 'sclerenchyma fiber': $i).
% 29.32/29.13  tff(decl_68271, type, 'sclerenchyma-fiber': $i).
% 29.32/29.13  tff(decl_68272, type, 'Scorpion': $i).
% 29.32/29.13  tff(decl_68273, type, 'A predatory arachnid with four pairs of walking legs, one pair of grasping claws, and a long segmented tail that ends with a venomous stinger. The tail is usually arced over the body, with the sting used to attack prey or predators.': $i).
% 29.32/29.13  tff(decl_68274, type, scorpion: $i).
% 29.32/29.13  tff(decl_68275, type, scrotum_1: $i > $o).
% 29.32/29.13  tff(decl_68276, type, 'Scrotum': $i).
% 29.32/29.13  tff(decl_68277, type, 'In some male mammals, a pouch of skin that lies outside the abdominal cavity and houses the testes. The external location allows the testes to remain at the lower temperature that is required for spermatogenesis.': $i).
% 29.32/29.13  tff(decl_68278, type, scrotum: $i).
% 29.32/29.13  tff(decl_68279, type, 'Scyphozoan': $i).
% 29.32/29.13  tff(decl_68280, type, 'An animal of the cnidarian class Scyphozoa, in which the dominant phase of the life cycle is the pelagic medusa form.': $i).
% 29.32/29.13  tff(decl_68281, type, scyphozoa: $i).
% 29.32/29.13  tff(decl_68282, type, scyphozoan: $i).
% 29.32/29.13  tff(decl_68283, type, 'Sea': $i).
% 29.32/29.13  tff(decl_68284, type, 'Large body of salt water partially or completely enclosed by land.': $i).
% 29.32/29.13  tff(decl_68285, type, sea: $i).
% 29.32/29.13  tff(decl_68286, type, fn_sea_1: $i > $i).
% 29.32/29.13  tff(decl_68287, type, fn_sea_2: $i > $i).
% 29.32/29.13  tff(decl_68288, type, fn_sea_3: $i > $i).
% 29.32/29.13  tff(decl_68289, type, fn_sea_4: $i > $i).
% 29.32/29.13  tff(decl_68290, type, fn_sea_5: $i > $i).
% 29.32/29.13  tff(decl_68291, type, fn_sea_6: $i > $i).
% 29.32/29.13  tff(decl_68292, type, fn_sea_7: $i > $i).
% 29.32/29.13  tff(decl_68293, type, sea_anemone_1: $i > $o).
% 29.32/29.13  tff(decl_68294, type, 'Sea-Anemone': $i).
% 29.32/29.13  tff(decl_68295, type, 'A large anthozoan polyp in the phylum Cnidaria. Sea anemones are related to corals but do not form colonies or build calcareous skeletons.': $i).
% 29.32/29.13  tff(decl_68296, type, 'anemone of sea': $i).
% 29.32/29.13  tff(decl_68297, type, 'sea anemone': $i).
% 29.32/29.13  tff(decl_68298, type, 'sea-anemone': $i).
% 29.32/29.13  tff(decl_68299, type, 'Sea-Cucumber': $i).
% 29.32/29.13  tff(decl_68300, type, 'A member of the echinoderm class Holothuroidea. Sea cucumbers have a long, flexible body with a mouth and tube feet at one end; most are deposit- or suspension-feeders.': $i).
% 29.32/29.13  tff(decl_68301, type, 'cucumber of sea': $i).
% 29.32/29.13  tff(decl_68302, type, 'sea cucumber': $i).
% 29.32/29.13  tff(decl_68303, type, 'sea-cucumber': $i).
% 29.32/29.13  tff(decl_68304, type, 'Sea-Daisy': $i).
% 29.32/29.13  tff(decl_68305, type, 'A group of unusual deep-sea animals of the phylum Echinodermata. Three species have been described, all in the genus Xyloplax.': $i).
% 29.32/29.13  tff(decl_68306, type, 'daisy of sea': $i).
% 29.32/29.13  tff(decl_68307, type, 'sea daisy': $i).
% 29.32/29.13  tff(decl_68308, type, 'sea-daisy': $i).
% 29.32/29.13  tff(decl_68309, type, 'Sea-Lily': $i).
% 29.32/29.13  tff(decl_68310, type, 'A stalked crinoid, with delicate arms surrounding a central mouth, attached to a hard surface.': $i).
% 29.32/29.13  tff(decl_68311, type, 'lily of sea': $i).
% 29.32/29.13  tff(decl_68312, type, 'sea lily': $i).
% 29.32/29.13  tff(decl_68313, type, 'sea-lily': $i).
% 29.32/29.13  tff(decl_68314, type, sea_slug_1: $i > $o).
% 29.32/29.13  tff(decl_68315, type, 'Sea-Slug': $i).
% 29.32/29.13  tff(decl_68316, type, 'Common name for a group of marine gastropods without shells.': $i).
% 29.32/29.13  tff(decl_68317, type, 'slug of sea': $i).
% 29.32/29.13  tff(decl_68318, type, 'sea slug': $i).
% 29.32/29.13  tff(decl_68319, type, 'sea-slug': $i).
% 29.32/29.13  tff(decl_68320, type, fn_sea_slug_1: $i > $i).
% 29.32/29.13  tff(decl_68321, type, fn_sea_slug_2: $i > $i).
% 29.32/29.13  tff(decl_68322, type, fn_sea_slug_3: $i > $i).
% 29.32/29.13  tff(decl_68323, type, fn_sea_slug_4: $i > $i).
% 29.32/29.13  tff(decl_68324, type, fn_sea_slug_5: $i > $i).
% 29.32/29.13  tff(decl_68325, type, fn_sea_slug_6: $i > $i).
% 29.32/29.13  tff(decl_68326, type, fn_sea_slug_7: $i > $i).
% 29.32/29.13  tff(decl_68327, type, fn_sea_slug_8: $i > $i).
% 29.32/29.13  tff(decl_68328, type, fn_sea_slug_9: $i > $i).
% 29.32/29.13  tff(decl_68329, type, fn_sea_slug_10: $i > $i).
% 29.32/29.13  tff(decl_68330, type, fn_sea_slug_11: $i > $i).
% 29.32/29.13  tff(decl_68331, type, fn_sea_slug_12: $i > $i).
% 29.32/29.13  tff(decl_68332, type, fn_sea_slug_13: $i > $i).
% 29.32/29.13  tff(decl_68333, type, fn_sea_slug_14: $i > $i).
% 29.32/29.13  tff(decl_68334, type, fn_sea_slug_15: $i > $i).
% 29.32/29.13  tff(decl_68335, type, fn_sea_slug_16: $i > $i).
% 29.32/29.13  tff(decl_68336, type, fn_sea_slug_17: $i > $i).
% 29.32/29.13  tff(decl_68337, type, fn_sea_slug_18: $i > $i).
% 29.32/29.13  tff(decl_68338, type, 'Sea-Star': $i).
% 29.32/29.13  tff(decl_68339, type, 'A member of the echinoderm class Asteroidea.': $i).
% 29.32/29.13  tff(decl_68340, type, 'star of sea': $i).
% 29.32/29.13  tff(decl_68341, type, 'sea star': $i).
% 29.32/29.13  tff(decl_68342, type, 'sea-star': $i).
% 29.32/29.13  tff(decl_68343, type, 'Sea-Urchin': $i).
% 29.32/29.13  tff(decl_68344, type, 'A small, globular animal with long spines, in the echinoderm class Echinoidea.': $i).
% 29.32/29.13  tff(decl_68345, type, 'urchin of sea': $i).
% 29.32/29.13  tff(decl_68346, type, 'sea urchin': $i).
% 29.32/29.13  tff(decl_68347, type, 'sea-urchin': $i).
% 29.32/29.13  tff(decl_68348, type, 'Seabird': $i).
% 29.32/29.13  tff(decl_68349, type, 'Type of bird which spends the major portion of its life in or around the sea or ocean. Seabirds include penguins, seagulls and cormorants.': $i).
% 29.32/29.13  tff(decl_68350, type, seabird: $i).
% 29.32/29.13  tff(decl_68351, type, seaborgium_1: $i > $o).
% 29.32/29.13  tff(decl_68352, type, 'Seaborgium': $i).
% 29.32/29.13  tff(decl_68353, type, 'Seaborgium is a metal atom with atomic number 106. It is represented by the symbol Sg.': $i).
% 29.32/29.13  tff(decl_68354, type, seaborgium: $i).
% 29.32/29.13  tff(decl_68355, type, 'Sg': $i).
% 29.32/29.13  tff(decl_68356, type, fn_seaborgium_1: $i > $i).
% 29.32/29.13  tff(decl_68357, type, fn_seaborgium_2: $i > $i).
% 29.32/29.13  tff(decl_68358, type, fn_seaborgium_6: $i > $i).
% 29.32/29.13  tff(decl_68359, type, fn_seaborgium_7: $i > $i).
% 29.32/29.13  tff(decl_68360, type, "160": $i).
% 29.32/29.13  tff(decl_68361, type, "266": $i).
% 29.32/29.13  tff(decl_68362, type, fn_seaborgium_4: $i > $i).
% 29.32/29.13  tff(decl_68363, type, fn_seaborgium_5: $i > $i).
% 29.32/29.13  tff(decl_68364, type, season_1: $i > $o).
% 29.32/29.13  tff(decl_68365, type, 'Season': $i).
% 29.32/29.13  tff(decl_68366, type, 'A subdivision of the year, marked by changes in biological activity, weather, and daylength.': $i).
% 29.32/29.13  tff(decl_68367, type, season: $i).
% 29.32/29.13  tff(decl_68368, type, seat_1: $i > $o).
% 29.32/29.13  tff(decl_68369, type, 'Seat': $i).
% 29.32/29.13  tff(decl_68370, type, seat: $i).
% 29.32/29.13  tff(decl_68371, type, 'Seaweed': $i).
% 29.32/29.13  tff(decl_68372, type, 'A colloquial term for macroscopic benthic marine algae.': $i).
% 29.32/29.13  tff(decl_68373, type, seaweed: $i).
% 29.32/29.13  tff(decl_68374, type, 'Second-Electron-Shell': $i).
% 29.32/29.13  tff(decl_68375, type, 'The second energy shell of an atom, containing the valence electrons involved in the chemical reactions of that atom.': $i).
% 29.32/29.13  tff(decl_68376, type, 'second electron shell': $i).
% 29.32/29.13  tff(decl_68377, type, 'second electron-shell': $i).
% 29.32/29.13  tff(decl_68378, type, 'second-electron-shell': $i).
% 29.32/29.13  tff(decl_68379, type, fn_second_electron_shell_2: $i > $i).
% 29.32/29.13  tff(decl_68380, type, fn_second_electron_shell_4: $i > $i).
% 29.32/29.13  tff(decl_68381, type, fn_second_electron_shell_6: $i > $i).
% 29.32/29.13  tff(decl_68382, type, fn_second_electron_shell_7: $i > $i).
% 29.32/29.13  tff(decl_68383, type, fn_second_electron_shell_15: $i > $i).
% 29.32/29.13  tff(decl_68384, type, fn_second_electron_shell_16: $i > $i).
% 29.32/29.13  tff(decl_68385, type, fn_second_electron_shell_17: $i > $i).
% 29.32/29.13  tff(decl_68386, type, fn_second_electron_shell_8: $i > $i).
% 29.32/29.13  tff(decl_68387, type, 'Second-Law-Thermodynamics': $i).
% 29.32/29.13  tff(decl_68388, type, 'The second law of thermodynamics states that the entropy of the universe is always increasing. A corallary of this statement is the fact that every transfer of energy contributes to the increase in entropy and at least some amount of usuable energy excapes in the form of heat': $i).
% 29.32/29.13  tff(decl_68389, type, 'second law of thermodynamics': $i).
% 29.32/29.13  tff(decl_68390, type, 'second-law-of-thermodynamics': $i).
% 29.32/29.13  tff(decl_68391, type, 'second law thermodynamics': $i).
% 29.32/29.13  tff(decl_68392, type, 'second-law-thermodynamic': $i).
% 29.32/29.13  tff(decl_68393, type, 'Second-Messenger': $i).
% 29.32/29.13  tff(decl_68394, type, 'A small molecule or ion, such as Ca2+ or cyclic AMP, that relays a signal sent to a cell\\s membrane to the appropriate target molecule in the nucleus or cytoplasm.': $i).
% 29.32/29.13  tff(decl_68395, type, 'secondary messenger': $i).
% 29.32/29.13  tff(decl_68396, type, 'messenger of second': $i).
% 29.32/29.13  tff(decl_68397, type, 'second messenger': $i).
% 29.32/29.13  tff(decl_68398, type, 'second-messenger': $i).
% 29.32/29.13  tff(decl_68399, type, fn_second_messenger_2: $i > $i).
% 29.32/29.13  tff(decl_68400, type, fn_second_messenger_4: $i > $i).
% 29.32/29.13  tff(decl_68401, type, fn_second_messenger_5: $i > $i).
% 29.32/29.13  tff(decl_68402, type, 'Second-Stage-Larva': $i).
% 29.32/29.13  tff(decl_68403, type, 'The immature, free-living form of most invertebrates, amphibians, and fish which at hatching from the egg is fundamentally unlike its parent and must metamorphose.  The larval stage is the second stage of development.': $i).
% 29.32/29.13  tff(decl_68404, type, 'second stage larva': $i).
% 29.32/29.13  tff(decl_68405, type, 'second-stage-larva': $i).
% 29.32/29.13  tff(decl_68406, type, fn_second_stage_larva_1: $i > $i).
% 29.32/29.13  tff(decl_68407, type, ventral_surface_1: $i > $o).
% 29.32/29.13  tff(decl_68408, type, fn_second_stage_larva_2: $i > $i).
% 29.32/29.13  tff(decl_68409, type, fn_second_stage_larva_5: $i > $i).
% 29.32/29.13  tff(decl_68410, type, fn_second_stage_larva_7: $i > $i).
% 29.32/29.13  tff(decl_68411, type, fn_second_stage_larva_8: $i > $i).
% 29.32/29.13  tff(decl_68412, type, 'VPC 6': $i).
% 29.32/29.13  tff(decl_68413, type, 'VPC 3': $i).
% 29.32/29.13  tff(decl_68414, type, 'VPC 1': $i).
% 29.32/29.13  tff(decl_68415, type, 'Secondary-Cell-Wall': $i).
% 29.32/29.13  tff(decl_68416, type, 'In plants, a strong, tough matrix deposited between the plasma membrane and the primary cell wall. It provides additional support to the individual cell, and strength and rigidity to the plant at large.': $i).
% 29.32/29.13  tff(decl_68417, type, 'secondary cell wall': $i).
% 29.32/29.13  tff(decl_68418, type, 'secondary cell-wall': $i).
% 29.32/29.13  tff(decl_68419, type, 'secondary-cell-wall': $i).
% 29.32/29.13  tff(decl_68420, type, 'Secondary-Consumer': $i).
% 29.32/29.13  tff(decl_68421, type, 'A carnivore that feeds primarily on herbivores.': $i).
% 29.32/29.13  tff(decl_68422, type, 'consumer of secondary': $i).
% 29.32/29.13  tff(decl_68423, type, 'secondary consumer': $i).
% 29.32/29.13  tff(decl_68424, type, 'secondary-consumer': $i).
% 29.32/29.13  tff(decl_68425, type, fn_secondary_consumer_1: $i > $i).
% 29.32/29.13  tff(decl_68426, type, fn_secondary_consumer_2: $i > $i).
% 29.32/29.13  tff(decl_68427, type, fn_secondary_consumer_3: $i > $i).
% 29.32/29.13  tff(decl_68428, type, fn_secondary_consumer_4: $i > $i).
% 29.32/29.13  tff(decl_68429, type, fn_secondary_consumer_5: $i > $i).
% 29.32/29.13  tff(decl_68430, type, fn_secondary_consumer_6: $i > $i).
% 29.32/29.13  tff(decl_68431, type, fn_secondary_consumer_7: $i > $i).
% 29.32/29.13  tff(decl_68432, type, fn_secondary_consumer_8: $i > $i).
% 29.32/29.13  tff(decl_68433, type, secondary_consumers_1: $i > $o).
% 29.32/29.13  tff(decl_68434, type, 'Secondary-Consumers': $i).
% 29.32/29.13  tff(decl_68435, type, 'Group of organisms in an ecosystem which feeds directly on primary consumers.': $i).
% 29.32/29.13  tff(decl_68436, type, secondary_endosymbiosis_1: $i > $o).
% 29.32/29.13  tff(decl_68437, type, 'Secondary-Endosymbiosis': $i).
% 29.32/29.13  tff(decl_68438, type, 'The process in eukaryotic evolution that occurred when one heterotrophic eukaryotic cell engulfed and retained a photosynthetic eukaryotic cell. The engulfed photosynthetic cell survived as a plastid within the formerly heterotrophic cell.': $i).
% 29.32/29.13  tff(decl_68439, type, 'endosymbiosis of secondary': $i).
% 29.32/29.13  tff(decl_68440, type, 'secondary endosymbiosis': $i).
% 29.32/29.13  tff(decl_68441, type, 'secondary-endosymbiosis': $i).
% 29.32/29.13  tff(decl_68442, type, secondary_growth_1: $i > $o).
% 29.32/29.13  tff(decl_68443, type, 'Secondary-Growth': $i).
% 29.32/29.13  tff(decl_68444, type, 'In plants, growth from the lateral meristems, which thickens roots and shoots.': $i).
% 29.32/29.13  tff(decl_68445, type, 'growth of secondary': $i).
% 29.32/29.13  tff(decl_68446, type, 'secondary growth': $i).
% 29.32/29.13  tff(decl_68447, type, 'secondary-growth': $i).
% 29.32/29.13  tff(decl_68448, type, secondary_immune_response_1: $i > $o).
% 29.32/29.13  tff(decl_68449, type, 'Secondary-Immune-Response': $i).
% 29.32/29.13  tff(decl_68450, type, 'The acquired immune response to a second or subsequent exposure to a particular antigen. The secondary response is faster, stronger, and of longer duration than the primary immune response.': $i).
% 29.32/29.13  tff(decl_68451, type, 'secondary immune response': $i).
% 29.32/29.13  tff(decl_68452, type, 'secondary-immune-response': $i).
% 29.32/29.13  tff(decl_68453, type, 'Secondary-Oocyte': $i).
% 29.32/29.13  tff(decl_68454, type, 'It is a haploid cell produced by meiotic division of primary oocyte (diploid cell). It further undergoes second meiotic division to produce ovum': $i).
% 29.32/29.13  tff(decl_68455, type, 'oocyte of secondary': $i).
% 29.32/29.13  tff(decl_68456, type, 'secondary oocyte': $i).
% 29.32/29.13  tff(decl_68457, type, 'secondary-oocyte': $i).
% 29.32/29.13  tff(decl_68458, type, 'Secondary-Plant-Tissue': $i).
% 29.32/29.13  tff(decl_68459, type, 'The tissues produced by the vascular cambium and cork cambium, which thicken the stems and roots of woody plants.': $i).
% 29.32/29.13  tff(decl_68460, type, 'secondary plant tissue': $i).
% 29.32/29.13  tff(decl_68461, type, 'secondary-plant-tissue': $i).
% 29.32/29.13  tff(decl_68462, type, 'Secondary-Protein-Structure': $i).
% 29.32/29.13  tff(decl_68463, type, 'Regions of repetitive coiling or folding of the polpeptide backbone of a protein due to hydrogen bonding between constituents of the backbone (not the side chains).': $i).
% 29.32/29.13  tff(decl_68464, type, 'second stage of protein folding': $i).
% 29.32/29.13  tff(decl_68465, type, 'secondary protein structure': $i).
% 29.32/29.13  tff(decl_68466, type, 'secondary-protein-structure': $i).
% 29.32/29.13  tff(decl_68467, type, fn_secondary_protein_structure_1: $i > $i).
% 29.32/29.13  tff(decl_68468, type, fn_secondary_protein_structure_2: $i > $i).
% 29.32/29.13  tff(decl_68469, type, fn_secondary_protein_structure_6: $i > $i).
% 29.32/29.13  tff(decl_68470, type, fn_secondary_protein_structure_7: $i > $i).
% 29.32/29.13  tff(decl_68471, type, fn_secondary_protein_structure_8: $i > $i).
% 29.32/29.13  tff(decl_68472, type, fn_secondary_protein_structure_9: $i > $i).
% 29.32/29.13  tff(decl_68473, type, fn_secondary_protein_structure_10: $i > $i).
% 29.32/29.13  tff(decl_68474, type, fn_secondary_protein_structure_11: $i > $i).
% 29.32/29.13  tff(decl_68475, type, fn_secondary_protein_structure_12: $i > $i).
% 29.32/29.13  tff(decl_68476, type, fn_secondary_protein_structure_13: $i > $i).
% 29.32/29.13  tff(decl_68477, type, fn_secondary_protein_structure_14: $i > $i).
% 29.32/29.13  tff(decl_68478, type, fn_secondary_protein_structure_15: $i > $i).
% 29.32/29.13  tff(decl_68479, type, fn_secondary_protein_structure_16: $i > $i).
% 29.32/29.13  tff(decl_68480, type, fn_secondary_protein_structure_17: $i > $i).
% 29.32/29.13  tff(decl_68481, type, fn_secondary_protein_structure_18: $i > $i).
% 29.32/29.13  tff(decl_68482, type, fn_secondary_protein_structure_19: $i > $i).
% 29.32/29.13  tff(decl_68483, type, fn_secondary_protein_structure_20: $i > $i).
% 29.32/29.13  tff(decl_68484, type, fn_secondary_protein_structure_21: $i > $i).
% 29.32/29.13  tff(decl_68485, type, fn_secondary_protein_structure_23: $i > $i).
% 29.32/29.13  tff(decl_68486, type, fn_secondary_protein_structure_24: $i > $i).
% 29.32/29.13  tff(decl_68487, type, fn_secondary_protein_structure_25: $i > $i).
% 29.32/29.13  tff(decl_68488, type, fn_secondary_protein_structure_26: $i > $i).
% 29.32/29.13  tff(decl_68489, type, fn_secondary_protein_structure_27: $i > $i).
% 29.32/29.13  tff(decl_68490, type, fn_secondary_protein_structure_28: $i > $i).
% 29.32/29.13  tff(decl_68491, type, fn_secondary_protein_structure_29: $i > $i).
% 29.32/29.13  tff(decl_68492, type, fn_secondary_protein_structure_30: $i > $i).
% 29.32/29.13  tff(decl_68493, type, fn_secondary_protein_structure_31: $i > $i).
% 29.32/29.13  tff(decl_68494, type, fn_secondary_protein_structure_32: $i > $i).
% 29.32/29.13  tff(decl_68495, type, fn_secondary_protein_structure_33: $i > $i).
% 29.32/29.13  tff(decl_68496, type, fn_secondary_protein_structure_34: $i > $i).
% 29.32/29.13  tff(decl_68497, type, fn_secondary_protein_structure_35: $i > $i).
% 29.32/29.13  tff(decl_68498, type, fn_secondary_protein_structure_36: $i > $i).
% 29.32/29.13  tff(decl_68499, type, fn_secondary_protein_structure_37: $i > $i).
% 29.32/29.13  tff(decl_68500, type, fn_secondary_protein_structure_38: $i > $i).
% 29.32/29.13  tff(decl_68501, type, fn_secondary_protein_structure_39: $i > $i).
% 29.32/29.13  tff(decl_68502, type, fn_secondary_protein_structure_40: $i > $i).
% 29.32/29.13  tff(decl_68503, type, fn_secondary_protein_structure_41: $i > $i).
% 29.32/29.13  tff(decl_68504, type, fn_secondary_protein_structure_42: $i > $i).
% 29.32/29.13  tff(decl_68505, type, fn_secondary_protein_structure_43: $i > $i).
% 29.32/29.13  tff(decl_68506, type, fn_secondary_protein_structure_44: $i > $i).
% 29.32/29.13  tff(decl_68507, type, fn_secondary_protein_structure_45: $i > $i).
% 29.32/29.13  tff(decl_68508, type, fn_secondary_protein_structure_46: $i > $i).
% 29.32/29.13  tff(decl_68509, type, fn_secondary_protein_structure_47: $i > $i).
% 29.32/29.13  tff(decl_68510, type, fn_secondary_protein_structure_48: $i > $i).
% 29.32/29.13  tff(decl_68511, type, fn_secondary_protein_structure_49: $i > $i).
% 29.32/29.13  tff(decl_68512, type, fn_secondary_protein_structure_50: $i > $i).
% 29.32/29.13  tff(decl_68513, type, fn_secondary_protein_structure_51: $i > $i).
% 29.32/29.13  tff(decl_68514, type, secondary_protein_structure_0: $i).
% 29.32/29.13  tff(decl_68515, type, fn_secondary_protein_structure_4: $i > $i).
% 29.32/29.13  tff(decl_68516, type, fn_secondary_protein_structure_5: $i > $i).
% 29.32/29.13  tff(decl_68517, type, secondary_spermatocyte_1: $i > $o).
% 29.32/29.13  tff(decl_68518, type, 'Secondary-spermatocyte': $i).
% 29.32/29.13  tff(decl_68519, type, 'Secondary spermatocyte is the cell produced as a result of first meiotic division of Primary spermatocyte. It has half the number of chromosomes as possessed by the primary spermatocyte': $i).
% 29.32/29.13  tff(decl_68520, type, 'spermatocyte of secondary': $i).
% 29.32/29.13  tff(decl_68521, type, 'secondary spermatocyte': $i).
% 29.32/29.13  tff(decl_68522, type, 'secondary-spermatocyte': $i).
% 29.32/29.13  tff(decl_68523, type, fn_secondary_spermatocyte_1: $i > $i).
% 29.32/29.13  tff(decl_68524, type, fn_secondary_spermatocyte_2: $i > $i).
% 29.32/29.13  tff(decl_68525, type, fn_secondary_spermatocyte_3: $i > $i).
% 29.32/29.13  tff(decl_68526, type, fn_secondary_spermatocyte_4: $i > $i).
% 29.32/29.13  tff(decl_68527, type, fn_secondary_spermatocyte_5: $i > $i).
% 29.32/29.13  tff(decl_68528, type, fn_secondary_spermatocyte_6: $i > $i).
% 29.32/29.13  tff(decl_68529, type, fn_secondary_spermatocyte_7: $i > $i).
% 29.32/29.13  tff(decl_68530, type, fn_secondary_spermatocyte_8: $i > $i).
% 29.32/29.13  tff(decl_68531, type, fn_secondary_spermatocyte_9: $i > $i).
% 29.32/29.13  tff(decl_68532, type, fn_secondary_spermatocyte_10: $i > $i).
% 29.32/29.13  tff(decl_68533, type, fn_secondary_spermatocyte_11: $i > $i).
% 29.32/29.13  tff(decl_68534, type, fn_secondary_spermatocyte_12: $i > $i).
% 29.32/29.13  tff(decl_68535, type, fn_secondary_spermatocyte_13: $i > $i).
% 29.32/29.13  tff(decl_68536, type, fn_secondary_spermatocyte_14: $i > $i).
% 29.32/29.13  tff(decl_68537, type, fn_secondary_spermatocyte_15: $i > $i).
% 29.32/29.13  tff(decl_68538, type, fn_secondary_spermatocyte_16: $i > $i).
% 29.32/29.13  tff(decl_68539, type, fn_secondary_spermatocyte_17: $i > $i).
% 29.32/29.13  tff(decl_68540, type, fn_secondary_spermatocyte_18: $i > $i).
% 29.32/29.13  tff(decl_68541, type, fn_secondary_spermatocyte_19: $i > $i).
% 29.32/29.13  tff(decl_68542, type, fn_secondary_spermatocyte_20: $i > $i).
% 29.32/29.13  tff(decl_68543, type, fn_secondary_spermatocyte_21: $i > $i).
% 29.32/29.13  tff(decl_68544, type, fn_secondary_spermatocyte_24: $i > $i).
% 29.32/29.13  tff(decl_68545, type, fn_secondary_spermatocyte_22: $i > $i).
% 29.32/29.13  tff(decl_68546, type, fn_secondary_spermatocyte_23: $i > $i).
% 29.32/29.13  tff(decl_68547, type, 'Secondary-Succession': $i).
% 29.32/29.13  tff(decl_68548, type, 'The community changes that occur in an area that had been previously colonized but recently disturbed or destroyed; for example, in an area that has been burned by wildfire.': $i).
% 29.32/29.13  tff(decl_68549, type, 'succession of secondary': $i).
% 29.32/29.13  tff(decl_68550, type, 'secondary succession': $i).
% 29.32/29.13  tff(decl_68551, type, 'secondary-succession': $i).
% 29.32/29.13  tff(decl_68552, type, 'Secreted-Fluid': $i).
% 29.32/29.13  tff(decl_68553, type, 'Fluids, that are normally produced and discharged from cells, which have a specific task after leaving the cell': $i).
% 29.32/29.13  tff(decl_68554, type, 'secreted fluid': $i).
% 29.32/29.13  tff(decl_68555, type, 'secreted-fluid': $i).
% 29.32/29.13  tff(decl_68556, type, 'Secretin': $i).
% 29.32/29.13  tff(decl_68557, type, 'A hormone secreted by the duodenum that regulates secretions of the stomach and pancreas. Secretin causes the pancreas to release bicarbonate ions into the duodenum when acidic chyme is passed from the stomach into the duodenum, thus bringing the chyme to a pH that digestive enzymes can tolerate. It also reduces acid secretion by the stomach.': $i).
% 29.32/29.13  tff(decl_68558, type, secretin: $i).
% 29.32/29.13  tff(decl_68559, type, fn_secretin_1: $i > $i).
% 29.32/29.13  tff(decl_68560, type, 'Secretion': $i).
% 29.32/29.13  tff(decl_68561, type, 'Secretion occurs when a ceullar product is exported from the cell .': $i).
% 29.32/29.13  tff(decl_68562, type, secrete: $i).
% 29.32/29.13  tff(decl_68563, type, secretion: $i).
% 29.32/29.13  tff(decl_68564, type, secretion_of_chemical_signal_by_neuron_1: $i > $o).
% 29.32/29.13  tff(decl_68565, type, 'Secretion-Of-Chemical-Signal-By-Neuron': $i).
% 29.32/29.13  tff(decl_68566, type, 'Neuron, or nerve cell, which uses exocytosis to release chemical signals that stimulate other neurons or muscle cells.': $i).
% 29.32/29.13  tff(decl_68567, type, 'neurotransmitter secretion': $i).
% 29.32/29.13  tff(decl_68568, type, 'neurotransmitter release': $i).
% 29.32/29.13  tff(decl_68569, type, 'secretion of chemical signal by neuron': $i).
% 29.32/29.13  tff(decl_68570, type, 'secretion-of-chemical-signal-by-neuron': $i).
% 29.32/29.13  tff(decl_68571, type, secretion_of_insulin_by_pancreas_cell_1: $i > $o).
% 29.32/29.13  tff(decl_68572, type, fn_secretion_of_chemical_signal_by_neuron_1: $i > $i).
% 29.32/29.13  tff(decl_68573, type, fn_secretion_of_chemical_signal_by_neuron_2: $i > $i).
% 29.32/29.13  tff(decl_68574, type, fn_secretion_of_chemical_signal_by_neuron_3: $i > $i).
% 29.32/29.13  tff(decl_68575, type, fn_secretion_of_chemical_signal_by_neuron_4: $i > $i).
% 29.32/29.13  tff(decl_68576, type, fn_secretion_of_chemical_signal_by_neuron_5: $i > $i).
% 29.32/29.13  tff(decl_68577, type, fn_secretion_of_chemical_signal_by_neuron_6: $i > $i).
% 29.32/29.13  tff(decl_68578, type, fn_secretion_of_chemical_signal_by_neuron_7: $i > $i).
% 29.32/29.13  tff(decl_68579, type, fn_secretion_of_chemical_signal_by_neuron_8: $i > $i).
% 29.32/29.13  tff(decl_68580, type, fn_secretion_of_chemical_signal_by_neuron_9: $i > $i).
% 29.32/29.13  tff(decl_68581, type, fn_secretion_of_chemical_signal_by_neuron_10: $i > $i).
% 29.32/29.13  tff(decl_68582, type, fn_secretion_of_chemical_signal_by_neuron_11: $i > $i).
% 29.32/29.13  tff(decl_68583, type, fn_secretion_of_chemical_signal_by_neuron_12: $i > $i).
% 29.32/29.13  tff(decl_68584, type, fn_secretion_of_chemical_signal_by_neuron_13: $i > $i).
% 29.32/29.13  tff(decl_68585, type, fn_secretion_of_chemical_signal_by_neuron_14: $i > $i).
% 29.32/29.13  tff(decl_68586, type, fn_secretion_of_chemical_signal_by_neuron_15: $i > $i).
% 29.32/29.13  tff(decl_68587, type, fn_secretion_of_chemical_signal_by_neuron_16: $i > $i).
% 29.32/29.13  tff(decl_68588, type, fn_secretion_of_chemical_signal_by_neuron_17: $i > $i).
% 29.32/29.13  tff(decl_68589, type, fn_secretion_of_chemical_signal_by_neuron_18: $i > $i).
% 29.32/29.13  tff(decl_68590, type, fn_secretion_of_chemical_signal_by_neuron_19: $i > $i).
% 29.32/29.13  tff(decl_68591, type, fn_secretion_of_chemical_signal_by_neuron_20: $i > $i).
% 29.32/29.13  tff(decl_68592, type, fn_secretion_of_chemical_signal_by_neuron_21: $i > $i).
% 29.32/29.13  tff(decl_68593, type, fn_secretion_of_chemical_signal_by_neuron_22: $i > $i).
% 29.32/29.13  tff(decl_68594, type, fn_secretion_of_chemical_signal_by_neuron_23: $i > $i).
% 29.32/29.13  tff(decl_68595, type, secretion_of_enzymes_by_small_intestine_1: $i > $o).
% 29.32/29.13  tff(decl_68596, type, 'Secretion-Of-Enzymes-By-Small-Intestine': $i).
% 29.32/29.13  tff(decl_68597, type, 'The process of producing and releasing digestive enzymes from the small intestine.': $i).
% 29.32/29.13  tff(decl_68598, type, 'secretion of enzymes by small intestine': $i).
% 29.32/29.13  tff(decl_68599, type, 'secretion-of-enzymes-by-small-intestine': $i).
% 29.32/29.13  tff(decl_68600, type, secretion_of_gastric_juice_1: $i > $o).
% 29.32/29.13  tff(decl_68601, type, 'Secretion-Of-Gastric-Juice': $i).
% 29.32/29.13  tff(decl_68602, type, 'The process in which gastric fluid, a fluid which aids in the digestion, is produced by the stomach.': $i).
% 29.32/29.13  tff(decl_68603, type, 'secretion of gastric juice': $i).
% 29.32/29.13  tff(decl_68604, type, 'secretion-of-gastric-juice': $i).
% 29.32/29.13  tff(decl_68605, type, fn_secretion_of_gastric_juice_1: $i > $i).
% 29.32/29.13  tff(decl_68606, type, fn_secretion_of_gastric_juice_4: $i > $i).
% 29.32/29.13  tff(decl_68607, type, fn_secretion_of_gastric_juice_5: $i > $i).
% 29.32/29.13  tff(decl_68608, type, fn_secretion_of_gastric_juice_6: $i > $i).
% 29.32/29.13  tff(decl_68609, type, fn_secretion_of_gastric_juice_7: $i > $i).
% 29.32/29.13  tff(decl_68610, type, fn_secretion_of_gastric_juice_8: $i > $i).
% 29.32/29.13  tff(decl_68611, type, fn_secretion_of_gastric_juice_9: $i > $i).
% 29.32/29.13  tff(decl_68612, type, fn_secretion_of_gastric_juice_10: $i > $i).
% 29.32/29.13  tff(decl_68613, type, fn_secretion_of_gastric_juice_11: $i > $i).
% 29.32/29.13  tff(decl_68614, type, fn_secretion_of_gastric_juice_12: $i > $i).
% 29.32/29.13  tff(decl_68615, type, fn_secretion_of_gastric_juice_13: $i > $i).
% 29.32/29.13  tff(decl_68616, type, fn_secretion_of_gastric_juice_14: $i > $i).
% 29.32/29.13  tff(decl_68617, type, fn_secretion_of_gastric_juice_15: $i > $i).
% 29.32/29.13  tff(decl_68618, type, fn_secretion_of_gastric_juice_16: $i > $i).
% 29.32/29.13  tff(decl_68619, type, fn_secretion_of_gastric_juice_17: $i > $i).
% 29.32/29.13  tff(decl_68620, type, fn_secretion_of_gastric_juice_18: $i > $i).
% 29.32/29.13  tff(decl_68621, type, fn_secretion_of_gastric_juice_19: $i > $i).
% 29.32/29.13  tff(decl_68622, type, fn_secretion_of_gastric_juice_20: $i > $i).
% 29.32/29.13  tff(decl_68623, type, fn_secretion_of_gastric_juice_21: $i > $i).
% 29.32/29.13  tff(decl_68624, type, fn_secretion_of_gastric_juice_22: $i > $i).
% 29.32/29.13  tff(decl_68625, type, fn_secretion_of_gastric_juice_23: $i > $i).
% 29.32/29.13  tff(decl_68626, type, fn_secretion_of_gastric_juice_24: $i > $i).
% 29.32/29.13  tff(decl_68627, type, fn_secretion_of_gastric_juice_25: $i > $i).
% 29.32/29.13  tff(decl_68628, type, fn_secretion_of_gastric_juice_26: $i > $i).
% 29.32/29.13  tff(decl_68629, type, fn_secretion_of_gastric_juice_27: $i > $i).
% 29.32/29.13  tff(decl_68630, type, fn_secretion_of_gastric_juice_28: $i > $i).
% 29.32/29.13  tff(decl_68631, type, fn_secretion_of_gastric_juice_29: $i > $i).
% 29.32/29.13  tff(decl_68632, type, fn_secretion_of_gastric_juice_2: $i > $i).
% 29.32/29.13  tff(decl_68633, type, fn_secretion_of_gastric_juice_3: $i > $i).
% 29.32/29.13  tff(decl_68634, type, secretion_of_hormones_by_small_intestine_1: $i > $o).
% 29.32/29.13  tff(decl_68635, type, 'Secretion-Of-Hormones-By-Small-Intestine': $i).
% 29.32/29.13  tff(decl_68636, type, 'The process of producing and releasing hormones from the small intestine.': $i).
% 29.32/29.13  tff(decl_68637, type, 'secretion of hormones by small intestine': $i).
% 29.32/29.13  tff(decl_68638, type, 'secretion-of-hormones-by-small-intestine': $i).
% 29.32/29.13  tff(decl_68639, type, 'Secretion-Of-Insulin-By-Pancreas-Cell': $i).
% 29.32/29.13  tff(decl_68640, type, 'The cells in the pancreas manufacture the hormone insulin and secrete it into the blood by exocytosis.': $i).
% 29.32/29.13  tff(decl_68641, type, 'secretion of insulin by pancreas cell': $i).
% 29.32/29.13  tff(decl_68642, type, 'secretion-of-insulin-by-pancreas-cell': $i).
% 29.32/29.13  tff(decl_68643, type, fn_secretion_of_insulin_by_pancreas_cell_3: $i > $i).
% 29.32/29.13  tff(decl_68644, type, fn_secretion_of_insulin_by_pancreas_cell_4: $i > $i).
% 29.32/29.13  tff(decl_68645, type, fn_secretion_of_insulin_by_pancreas_cell_5: $i > $i).
% 29.32/29.13  tff(decl_68646, type, fn_secretion_of_insulin_by_pancreas_cell_6: $i > $i).
% 29.32/29.13  tff(decl_68647, type, fn_secretion_of_insulin_by_pancreas_cell_7: $i > $i).
% 29.32/29.13  tff(decl_68648, type, fn_secretion_of_insulin_by_pancreas_cell_8: $i > $i).
% 29.32/29.13  tff(decl_68649, type, fn_secretion_of_insulin_by_pancreas_cell_9: $i > $i).
% 29.32/29.13  tff(decl_68650, type, fn_secretion_of_insulin_by_pancreas_cell_10: $i > $i).
% 29.32/29.13  tff(decl_68651, type, fn_secretion_of_insulin_by_pancreas_cell_11: $i > $i).
% 29.32/29.13  tff(decl_68652, type, fn_secretion_of_insulin_by_pancreas_cell_12: $i > $i).
% 29.32/29.13  tff(decl_68653, type, fn_secretion_of_insulin_by_pancreas_cell_13: $i > $i).
% 29.32/29.13  tff(decl_68654, type, fn_secretion_of_insulin_by_pancreas_cell_14: $i > $i).
% 29.32/29.13  tff(decl_68655, type, fn_secretion_of_insulin_by_pancreas_cell_15: $i > $i).
% 29.32/29.13  tff(decl_68656, type, fn_secretion_of_insulin_by_pancreas_cell_16: $i > $i).
% 29.32/29.13  tff(decl_68657, type, fn_secretion_of_insulin_by_pancreas_cell_17: $i > $i).
% 29.32/29.13  tff(decl_68658, type, fn_secretion_of_insulin_by_pancreas_cell_18: $i > $i).
% 29.32/29.13  tff(decl_68659, type, fn_secretion_of_insulin_by_pancreas_cell_19: $i > $i).
% 29.32/29.13  tff(decl_68660, type, fn_secretion_of_insulin_by_pancreas_cell_20: $i > $i).
% 29.32/29.13  tff(decl_68661, type, fn_secretion_of_insulin_by_pancreas_cell_21: $i > $i).
% 29.32/29.13  tff(decl_68662, type, fn_secretion_of_insulin_by_pancreas_cell_22: $i > $i).
% 29.32/29.13  tff(decl_68663, type, fn_secretion_of_insulin_by_pancreas_cell_23: $i > $i).
% 29.32/29.13  tff(decl_68664, type, fn_secretion_of_insulin_by_pancreas_cell_24: $i > $i).
% 29.32/29.13  tff(decl_68665, type, fn_secretion_of_insulin_by_pancreas_cell_25: $i > $i).
% 29.32/29.13  tff(decl_68666, type, fn_secretion_of_insulin_by_pancreas_cell_26: $i > $i).
% 29.32/29.13  tff(decl_68667, type, fn_secretion_of_insulin_by_pancreas_cell_27: $i > $i).
% 29.32/29.13  tff(decl_68668, type, fn_secretion_of_insulin_by_pancreas_cell_28: $i > $i).
% 29.32/29.13  tff(decl_68669, type, fn_secretion_of_insulin_by_pancreas_cell_29: $i > $i).
% 29.32/29.13  tff(decl_68670, type, fn_secretion_of_insulin_by_pancreas_cell_30: $i > $i).
% 29.32/29.13  tff(decl_68671, type, fn_secretion_of_insulin_by_pancreas_cell_31: $i > $i).
% 29.32/29.13  tff(decl_68672, type, fn_secretion_of_insulin_by_pancreas_cell_32: $i > $i).
% 29.32/29.13  tff(decl_68673, type, fn_secretion_of_insulin_by_pancreas_cell_33: $i > $i).
% 29.32/29.13  tff(decl_68674, type, fn_secretion_of_insulin_by_pancreas_cell_34: $i > $i).
% 29.32/29.13  tff(decl_68675, type, fn_secretion_of_insulin_by_pancreas_cell_35: $i > $i).
% 29.32/29.13  tff(decl_68676, type, fn_secretion_of_insulin_by_pancreas_cell_36: $i > $i).
% 29.32/29.13  tff(decl_68677, type, fn_secretion_of_insulin_by_pancreas_cell_37: $i > $i).
% 29.32/29.13  tff(decl_68678, type, fn_secretion_of_insulin_by_pancreas_cell_38: $i > $i).
% 29.32/29.13  tff(decl_68679, type, fn_secretion_of_insulin_by_pancreas_cell_39: $i > $i).
% 29.32/29.13  tff(decl_68680, type, fn_secretion_of_insulin_by_pancreas_cell_40: $i > $i).
% 29.32/29.13  tff(decl_68681, type, fn_secretion_of_insulin_by_pancreas_cell_41: $i > $i).
% 29.32/29.13  tff(decl_68682, type, fn_secretion_of_insulin_by_pancreas_cell_42: $i > $i).
% 29.32/29.13  tff(decl_68683, type, fn_secretion_of_insulin_by_pancreas_cell_43: $i > $i).
% 29.32/29.13  tff(decl_68684, type, fn_secretion_of_insulin_by_pancreas_cell_44: $i > $i).
% 29.32/29.13  tff(decl_68685, type, fn_secretion_of_insulin_by_pancreas_cell_45: $i > $i).
% 29.32/29.13  tff(decl_68686, type, fn_secretion_of_insulin_by_pancreas_cell_46: $i > $i).
% 29.32/29.13  tff(decl_68687, type, fn_secretion_of_insulin_by_pancreas_cell_47: $i > $i).
% 29.32/29.13  tff(decl_68688, type, fn_secretion_of_insulin_by_pancreas_cell_48: $i > $i).
% 29.32/29.13  tff(decl_68689, type, fn_secretion_of_insulin_by_pancreas_cell_49: $i > $i).
% 29.32/29.13  tff(decl_68690, type, fn_secretion_of_insulin_by_pancreas_cell_50: $i > $i).
% 29.32/29.13  tff(decl_68691, type, fn_secretion_of_insulin_by_pancreas_cell_51: $i > $i).
% 29.32/29.13  tff(decl_68692, type, fn_secretion_of_insulin_by_pancreas_cell_52: $i > $i).
% 29.32/29.13  tff(decl_68693, type, fn_secretion_of_insulin_by_pancreas_cell_53: $i > $i).
% 29.32/29.13  tff(decl_68694, type, fn_secretion_of_insulin_by_pancreas_cell_54: $i > $i).
% 29.32/29.13  tff(decl_68695, type, fn_secretion_of_insulin_by_pancreas_cell_55: $i > $i).
% 29.32/29.13  tff(decl_68696, type, fn_secretion_of_insulin_by_pancreas_cell_56: $i > $i).
% 29.32/29.13  tff(decl_68697, type, fn_secretion_of_insulin_by_pancreas_cell_57: $i > $i).
% 29.32/29.13  tff(decl_68698, type, fn_secretion_of_insulin_by_pancreas_cell_58: $i > $i).
% 29.32/29.13  tff(decl_68699, type, fn_secretion_of_insulin_by_pancreas_cell_59: $i > $i).
% 29.32/29.13  tff(decl_68700, type, fn_secretion_of_insulin_by_pancreas_cell_60: $i > $i).
% 29.32/29.13  tff(decl_68701, type, fn_secretion_of_insulin_by_pancreas_cell_61: $i > $i).
% 29.32/29.13  tff(decl_68702, type, fn_secretion_of_insulin_by_pancreas_cell_62: $i > $i).
% 29.32/29.13  tff(decl_68703, type, fn_synthesis_of_endomembranous_system_membrane_2: $i > $i).
% 29.32/29.13  tff(decl_68704, type, fn_synthesis_of_endomembranous_system_membrane_1: $i > $i).
% 29.32/29.13  tff(decl_68705, type, fn_synthesis_of_endomembranous_system_membrane_56: $i > $i).
% 29.32/29.13  tff(decl_68706, type, secretion_of_pancreatic_enzyme_1: $i > $o).
% 29.32/29.13  tff(decl_68707, type, 'Secretion-Of-Pancreatic-Enzyme': $i).
% 29.32/29.13  tff(decl_68708, type, 'The process of producing and releasing digestive enzymes from the pancreas.': $i).
% 29.32/29.13  tff(decl_68709, type, 'secretion of pancreatic enzyme': $i).
% 29.32/29.13  tff(decl_68710, type, 'secretion-of-pancreatic-enzyme': $i).
% 29.32/29.13  tff(decl_68711, type, fn_secretion_of_pancreatic_enzyme_1: $i > $i).
% 29.32/29.13  tff(decl_68712, type, fn_secretion_of_pancreatic_enzyme_2: $i > $i).
% 29.32/29.13  tff(decl_68713, type, fn_secretion_of_pancreatic_enzyme_3: $i > $i).
% 29.32/29.13  tff(decl_68714, type, secretion_of_pancreatic_hormone_1: $i > $o).
% 29.32/29.13  tff(decl_68715, type, 'Secretion-Of-Pancreatic-Hormone': $i).
% 29.32/29.13  tff(decl_68716, type, 'The process of producing and releasing hormones from the pancreas.': $i).
% 29.32/29.13  tff(decl_68717, type, 'secretion of pancreatic hormone': $i).
% 29.32/29.13  tff(decl_68718, type, 'secretion-of-pancreatic-hormone': $i).
% 29.32/29.13  tff(decl_68719, type, 'Secretor': $i).
% 29.32/29.13  tff(decl_68720, type, 'Cell, tissue, organ or organism that releases chemicals through the process of secretion.': $i).
% 29.32/29.13  tff(decl_68721, type, secretor: $i).
% 29.32/29.13  tff(decl_68722, type, fn_secretor_1: $i > $i).
% 29.32/29.13  tff(decl_68723, type, 'Secretory-Cell': $i).
% 29.32/29.13  tff(decl_68724, type, 'A cell that plays role in secretion.': $i).
% 29.32/29.13  tff(decl_68725, type, 'secreting cell': $i).
% 29.32/29.13  tff(decl_68726, type, 'secretory cell': $i).
% 29.32/29.13  tff(decl_68727, type, 'secretory-cell': $i).
% 29.32/29.13  tff(decl_68728, type, fn_secretory_cell_2: $i > $i).
% 29.32/29.13  tff(decl_68729, type, fn_secretory_cell_3: $i > $i).
% 29.32/29.13  tff(decl_68730, type, fn_secretory_cell_7: $i > $i).
% 29.32/29.13  tff(decl_68731, type, fn_secretory_cell_11: $i > $i).
% 29.32/29.13  tff(decl_68732, type, fn_secretory_cell_12: $i > $i).
% 29.32/29.13  tff(decl_68733, type, fn_secretory_cell_14: $i > $i).
% 29.32/29.13  tff(decl_68734, type, fn_secretory_cell_16: $i > $i).
% 29.32/29.13  tff(decl_68735, type, fn_secretory_cell_27: $i > $i).
% 29.32/29.13  tff(decl_68736, type, fn_secretory_cell_46: $i > $i).
% 29.32/29.13  tff(decl_68737, type, fn_secretory_cell_51: $i > $i).
% 29.32/29.13  tff(decl_68738, type, fn_secretory_cell_61: $i > $i).
% 29.32/29.13  tff(decl_68739, type, fn_secretory_cell_89: $i > $i).
% 29.32/29.13  tff(decl_68740, type, fn_secretory_cell_90: $i > $i).
% 29.32/29.13  tff(decl_68741, type, golgi_apparatus_0: $i).
% 29.32/29.13  tff(decl_68742, type, organelle_0: $i).
% 29.32/29.13  tff(decl_68743, type, fn_secretory_cell_45: $i > $i).
% 29.32/29.13  tff(decl_68744, type, fn_secretory_cell_50: $i > $i).
% 29.32/29.13  tff(decl_68745, type, 'Secretory-Organ': $i).
% 29.32/29.13  tff(decl_68746, type, 'An organ that plays a role in secretion.': $i).
% 29.32/29.13  tff(decl_68747, type, 'secretory organ': $i).
% 29.32/29.13  tff(decl_68748, type, 'secretory-organ': $i).
% 29.32/29.13  tff(decl_68749, type, secretory_phase_1: $i > $o).
% 29.32/29.13  tff(decl_68750, type, 'Secretory-Phase': $i).
% 29.32/29.13  tff(decl_68751, type, 'Also called the luteal phase; the latter phase of the uterine (menstrual) cycle when the endometrial lining continues to get thicker and more vascularized in preparation for a fertilized egg.': $i).
% 29.32/29.13  tff(decl_68752, type, 'secretory phase': $i).
% 29.32/29.13  tff(decl_68753, type, 'secretory-phase': $i).
% 29.32/29.13  tff(decl_68754, type, 'Secretory-Protein': $i).
% 29.32/29.13  tff(decl_68755, type, 'A protein produced by cells and secreted outside of the cell.': $i).
% 29.32/29.13  tff(decl_68756, type, 'secretory protein': $i).
% 29.32/29.13  tff(decl_68757, type, 'secretory-protein': $i).
% 29.32/29.13  tff(decl_68758, type, 'Sedimentary-Rock': $i).
% 29.32/29.13  tff(decl_68759, type, 'A type of rock that is formed by sedimentation of material in layers on the surface of the earth or in bodies of water.': $i).
% 29.32/29.13  tff(decl_68760, type, 'sedimentary rock': $i).
% 29.32/29.13  tff(decl_68761, type, 'sedimentary-rock': $i).
% 29.32/29.13  tff(decl_68762, type, 'Sedimentation': $i).
% 29.32/29.13  tff(decl_68763, type, 'The gradual accumulation of materials at the bottom of a body of water.': $i).
% 29.32/29.13  tff(decl_68764, type, sediment: $i).
% 29.32/29.13  tff(decl_68765, type, sedimentation: $i).
% 29.32/29.13  tff(decl_68766, type, 'See': $i).
% 29.32/29.13  tff(decl_68767, type, 'Seed': $i).
% 29.32/29.13  tff(decl_68768, type, 'An adaptation of some terrestrial plants consisting of an embryo packaged along with a store of food within a protective coat.': $i).
% 29.32/29.13  tff(decl_68769, type, seed: $i).
% 29.32/29.13  tff(decl_68770, type, fn_seed_3: $i > $i).
% 29.32/29.13  tff(decl_68771, type, fn_seed_4: $i > $i).
% 29.32/29.13  tff(decl_68772, type, 'Seed-Coat': $i).
% 29.32/29.13  tff(decl_68773, type, 'In plants, a protective covering of a seed, developed from tissue that surrounds the ovule.': $i).
% 29.32/29.13  tff(decl_68774, type, 'coat of seed': $i).
% 29.32/29.13  tff(decl_68775, type, 'seed coat': $i).
% 29.32/29.13  tff(decl_68776, type, 'seed-coat': $i).
% 29.32/29.13  tff(decl_68777, type, 'Seed-Plant': $i).
% 29.32/29.13  tff(decl_68778, type, 'A plant that produces seeds.': $i).
% 29.32/29.13  tff(decl_68779, type, spermatophyte: $i).
% 29.32/29.13  tff(decl_68780, type, 'plant of seed': $i).
% 29.32/29.13  tff(decl_68781, type, 'seed plant': $i).
% 29.32/29.13  tff(decl_68782, type, 'seed-plant': $i).
% 29.32/29.13  tff(decl_68783, type, 'Seedless-Vascular-Plant': $i).
% 29.32/29.13  tff(decl_68784, type, 'A paraphyletic grouping of plants that have vascular tissue but do not produces seeds. Examples include the lycophytes (club mosses and kin) and pterophytes (ferns and kin).': $i).
% 29.32/29.13  tff(decl_68785, type, 'seedless vascular plant': $i).
% 29.32/29.13  tff(decl_68786, type, 'seedless-vascular-plant': $i).
% 29.32/29.13  tff(decl_68787, type, 'Seedling': $i).
% 29.32/29.13  tff(decl_68788, type, 'The immature, multicellular stage of development of a seed plant. Seedlings develop from germination of the seed.': $i).
% 29.32/29.13  tff(decl_68789, type, seedling: $i).
% 29.32/29.13  tff(decl_68790, type, fn_seedling_1: $i > $i).
% 29.32/29.13  tff(decl_68791, type, fn_seedling_2: $i > $i).
% 29.32/29.13  tff(decl_68792, type, fn_seedling_3: $i > $i).
% 29.32/29.13  tff(decl_68793, type, fn_seedling_4: $i > $i).
% 29.32/29.13  tff(decl_68794, type, fn_seedling_5: $i > $i).
% 29.32/29.13  tff(decl_68795, type, fn_seedling_7: $i > $i).
% 29.32/29.13  tff(decl_68796, type, fn_seedling_8: $i > $i).
% 29.32/29.13  tff(decl_68797, type, fn_seedling_11: $i > $i).
% 29.32/29.13  tff(decl_68798, type, fn_seedling_12: $i > $i).
% 29.32/29.13  tff(decl_68799, type, fn_seedling_13: $i > $i).
% 29.32/29.13  tff(decl_68800, type, fn_seedling_14: $i > $i).
% 29.32/29.13  tff(decl_68801, type, fn_seedling_15: $i > $i).
% 29.32/29.13  tff(decl_68802, type, fn_seedling_16: $i > $i).
% 29.32/29.13  tff(decl_68803, type, fn_seedling_17: $i > $i).
% 29.32/29.13  tff(decl_68804, type, fn_seedling_18: $i > $i).
% 29.32/29.13  tff(decl_68805, type, fn_seedling_19: $i > $i).
% 29.32/29.13  tff(decl_68806, type, fn_seedling_22: $i > $i).
% 29.32/29.13  tff(decl_68807, type, fn_seedling_23: $i > $i).
% 29.32/29.13  tff(decl_68808, type, fn_seedling_24: $i > $i).
% 29.32/29.13  tff(decl_68809, type, fn_seedling_25: $i > $i).
% 29.32/29.13  tff(decl_68810, type, fn_seedling_21: $i > $i).
% 29.32/29.13  tff(decl_68811, type, fn_seedling_20: $i > $i).
% 29.32/29.13  tff(decl_68812, type, 'Segment-Formation': $i).
% 29.32/29.13  tff(decl_68813, type, 'A stage where the segment formation takes place in the development of the organism.': $i).
% 29.32/29.13  tff(decl_68814, type, 'formation of segment': $i).
% 29.32/29.13  tff(decl_68815, type, 'segment formation': $i).
% 29.32/29.13  tff(decl_68816, type, 'segment-formation': $i).
% 29.32/29.13  tff(decl_68817, type, fn_segment_formation_1: $i > $i).
% 29.32/29.13  tff(decl_68818, type, fn_segment_formation_3: $i > $i).
% 29.32/29.13  tff(decl_68819, type, 'Segment-Polarity-Gene': $i).
% 29.32/29.13  tff(decl_68820, type, 'A segmentation gene whose function is to define the anterior and posterior polarities within each embryonic parasegment.': $i).
% 29.32/29.13  tff(decl_68821, type, 'segment polarity gene': $i).
% 29.32/29.13  tff(decl_68822, type, 'segment-polarity-gene': $i).
% 29.32/29.13  tff(decl_68823, type, segment_polarity_gene_mutation_1: $i > $o).
% 29.32/29.13  tff(decl_68824, type, 'Segment-Polarity-Gene-Mutation': $i).
% 29.32/29.13  tff(decl_68825, type, 'A chromosomal mutation associated with segment polarity gene is a segment polarity gene mutation.': $i).
% 29.32/29.13  tff(decl_68826, type, 'segment polarity gene mutation': $i).
% 29.32/29.13  tff(decl_68827, type, 'segment-polarity-gene-mutation': $i).
% 29.32/29.13  tff(decl_68828, type, fn_segment_polarity_gene_mutation_1: $i > $i).
% 29.32/29.13  tff(decl_68829, type, fn_segment_polarity_gene_mutation_2: $i > $i).
% 29.32/29.13  tff(decl_68830, type, fn_segment_polarity_gene_mutation_3: $i > $i).
% 29.32/29.13  tff(decl_68831, type, fn_segment_polarity_gene_mutation_4: $i > $i).
% 29.32/29.13  tff(decl_68832, type, fn_segment_polarity_gene_mutation_5: $i > $i).
% 29.32/29.13  tff(decl_68833, type, fn_segment_polarity_gene_mutation_6: $i > $i).
% 29.32/29.13  tff(decl_68834, type, fn_segment_polarity_gene_mutation_7: $i > $i).
% 29.32/29.13  tff(decl_68835, type, 'Segmentation-Gene': $i).
% 29.32/29.13  tff(decl_68836, type, 'A zygotic gene responsible for the formation of body segments.': $i).
% 29.32/29.13  tff(decl_68837, type, 'gene of segmentation': $i).
% 29.32/29.13  tff(decl_68838, type, 'segmentation gene': $i).
% 29.32/29.13  tff(decl_68839, type, 'segmentation-gene': $i).
% 29.32/29.13  tff(decl_68840, type, fn_segmentation_gene_1: $i > $i).
% 29.32/29.13  tff(decl_68841, type, 'Segmented-Embryo': $i).
% 29.32/29.13  tff(decl_68842, type, 'An embryo that is segmented is called as segmented embryo.': $i).
% 29.32/29.13  tff(decl_68843, type, 'segmented embryo': $i).
% 29.32/29.13  tff(decl_68844, type, 'segmented-embryo': $i).
% 29.32/29.13  tff(decl_68845, type, fn_segmented_embryo_1: $i > $i).
% 29.32/29.13  tff(decl_68846, type, segmented_worm_1: $i > $o).
% 29.32/29.13  tff(decl_68847, type, 'Segmented-Worm': $i).
% 29.32/29.13  tff(decl_68848, type, 'A worm in the phylum Annelida; includes the Polychaeta (marine segmented worms), Oligochaeta (earthworms), and Hirudinea (leeches).': $i).
% 29.32/29.13  tff(decl_68849, type, 'Segregate': $i).
% 29.32/29.13  tff(decl_68850, type, 'Segregation is the process of separating or isolating one thing from another and placing it in a group apart from the others.': $i).
% 29.32/29.13  tff(decl_68851, type, sort: $i).
% 29.32/29.13  tff(decl_68852, type, segregate: $i).
% 29.32/29.13  tff(decl_68853, type, segregation_of_alleles_1: $i > $o).
% 29.32/29.13  tff(decl_68854, type, 'Segregation-Of-Alleles': $i).
% 29.32/29.13  tff(decl_68855, type, 'The separation of an individual\\s two alleles at a given locus into different gametes during meiosis.': $i).
% 29.32/29.13  tff(decl_68856, type, 'segregation of allele': $i).
% 29.32/29.13  tff(decl_68857, type, 'segregation-of-allele': $i).
% 29.32/29.13  tff(decl_68858, type, fn_segregation_of_alleles_1: $i > $i).
% 29.32/29.13  tff(decl_68859, type, 'Select': $i).
% 29.32/29.13  tff(decl_68860, type, choose: $i).
% 29.32/29.13  tff(decl_68861, type, selection_1: $i > $o).
% 29.32/29.13  tff(decl_68862, type, 'Selection': $i).
% 29.32/29.13  tff(decl_68863, type, selection: $i).
% 29.32/29.13  tff(decl_68864, type, choice: $i).
% 29.32/29.13  tff(decl_68865, type, pick: $i).
% 29.32/29.13  tff(decl_68866, type, 'Selection-Force': $i).
% 29.32/29.13  tff(decl_68867, type, 'A process in which the environment selects or favors some individuals over other individuals in the same population.': $i).
% 29.32/29.13  tff(decl_68868, type, 'force of selection': $i).
% 29.32/29.13  tff(decl_68869, type, 'selection force': $i).
% 29.32/29.13  tff(decl_68870, type, 'selection-force': $i).
% 29.32/29.13  tff(decl_68871, type, 'Selective-Degradation': $i).
% 29.32/29.13  tff(decl_68872, type, 'Degradation which is regulated and targeted to specific molecules or organelles.': $i).
% 29.32/29.13  tff(decl_68873, type, 'degrade selectively': $i).
% 29.32/29.13  tff(decl_68874, type, 'selective degradation': $i).
% 29.32/29.13  tff(decl_68875, type, 'selective-degradation': $i).
% 29.32/29.13  tff(decl_68876, type, fn_selective_degradation_1: $i > $i).
% 29.32/29.13  tff(decl_68877, type, fn_selective_degradation_2: $i > $i).
% 29.32/29.13  tff(decl_68878, type, fn_selective_degradation_3: $i > $i).
% 29.32/29.13  tff(decl_68879, type, fn_selective_degradation_5: $i > $i).
% 29.32/29.13  tff(decl_68880, type, fn_selective_degradation_6: $i > $i).
% 29.32/29.13  tff(decl_68881, type, fn_selective_degradation_7: $i > $i).
% 29.32/29.13  tff(decl_68882, type, fn_selective_degradation_8: $i > $i).
% 29.32/29.13  tff(decl_68883, type, fn_selective_degradation_9: $i > $i).
% 29.32/29.13  tff(decl_68884, type, fn_selective_degradation_10: $i > $i).
% 29.32/29.13  tff(decl_68885, type, fn_selective_degradation_12: $i > $i).
% 29.32/29.13  tff(decl_68886, type, fn_selective_degradation_13: $i > $i).
% 29.32/29.13  tff(decl_68887, type, fn_selective_degradation_14: $i > $i).
% 29.32/29.13  tff(decl_68888, type, fn_selective_degradation_15: $i > $i).
% 29.32/29.13  tff(decl_68889, type, fn_selective_degradation_16: $i > $i).
% 29.32/29.13  tff(decl_68890, type, fn_selective_degradation_17: $i > $i).
% 29.32/29.13  tff(decl_68891, type, fn_selective_degradation_18: $i > $i).
% 29.32/29.13  tff(decl_68892, type, fn_selective_degradation_19: $i > $i).
% 29.32/29.13  tff(decl_68893, type, fn_selective_degradation_20: $i > $i).
% 29.32/29.13  tff(decl_68894, type, fn_selective_degradation_21: $i > $i).
% 29.32/29.13  tff(decl_68895, type, fn_selective_degradation_22: $i > $i).
% 29.32/29.13  tff(decl_68896, type, fn_selective_degradation_23: $i > $i).
% 29.32/29.13  tff(decl_68897, type, fn_ubiquitin_6: $i > $i).
% 29.32/29.13  tff(decl_68898, type, fn_ubiquitin_5: $i > $i).
% 29.32/29.13  tff(decl_68899, type, fn_ubiquitin_7: $i > $i).
% 29.32/29.13  tff(decl_68900, type, fn_ubiquitin_3: $i > $i).
% 29.32/29.13  tff(decl_68901, type, fn_ubiquitin_2: $i > $i).
% 29.32/29.13  tff(decl_68902, type, fn_protein_2: $i > $i).
% 29.32/29.13  tff(decl_68903, type, fn_ubiquitin_4: $i > $i).
% 29.32/29.13  tff(decl_68904, type, fn_ubiquitin_1: $i > $i).
% 29.32/29.13  tff(decl_68905, type, fn_selective_degradation_11: $i > $i).
% 29.32/29.13  tff(decl_68906, type, 'Selenium': $i).
% 29.32/29.13  tff(decl_68907, type, 'Selenium is a non metal atom with atomic number 34. It is represented by the symbol Se.': $i).
% 29.32/29.13  tff(decl_68908, type, selenium: $i).
% 29.32/29.13  tff(decl_68909, type, 'Se': $i).
% 29.32/29.13  tff(decl_68910, type, fn_selenium_3: $i > $i).
% 29.32/29.13  tff(decl_68911, type, fn_selenium_4: $i > $i).
% 29.32/29.13  tff(decl_68912, type, fn_selenium_5: $i > $i).
% 29.32/29.13  tff(decl_68913, type, fn_selenium_9: $i > $i).
% 29.32/29.13  tff(decl_68914, type, fn_selenium_10: $i > $i).
% 29.32/29.13  tff(decl_68915, type, fn_selenium_11: $i > $i).
% 29.32/29.13  tff(decl_68916, type, fn_selenium_12: $i > $i).
% 29.32/29.13  tff(decl_68917, type, "34": $i).
% 29.32/29.13  tff(decl_68918, type, "78.96": $i).
% 29.32/29.13  tff(decl_68919, type, fn_selenium_7: $i > $i).
% 29.32/29.13  tff(decl_68920, type, fn_selenium_8: $i > $i).
% 29.32/29.13  tff(decl_68921, type, fn_selenium_6: $i > $i).
% 29.32/29.13  tff(decl_68922, type, self_awareness_1: $i > $o).
% 29.32/29.13  tff(decl_68923, type, 'Self-Awareness': $i).
% 29.32/29.13  tff(decl_68924, type, 'The ability of an organism to recognize itself as a distinct individual, usually determined experimentally by a mirror test.': $i).
% 29.32/29.13  tff(decl_68925, type, 'awareness of self': $i).
% 29.32/29.13  tff(decl_68926, type, 'self awareness': $i).
% 29.32/29.13  tff(decl_68927, type, 'self-awareness': $i).
% 29.32/29.13  tff(decl_68928, type, self_organization_of_phospholipids_1: $i > $o).
% 29.32/29.13  tff(decl_68929, type, 'Self-Organization-of-Phospholipids': $i).
% 29.32/29.13  tff(decl_68930, type, 'Self organization of phospholipids is the process in which phospholipids   orient themselves with respect to the water and with each other so that the hydrophilic (water loving) head groups are grouped together and face the water, and the hydrophobic (water fearing) tails turn away from the water and toward each other.': $i).
% 29.32/29.13  tff(decl_68931, type, 'self organization of phospholipid within biomembrane': $i).
% 29.32/29.13  tff(decl_68932, type, 'self organization of phospholipids in water': $i).
% 29.32/29.13  tff(decl_68933, type, 'self-organization of phospholipids in water': $i).
% 29.32/29.13  tff(decl_68934, type, 'self organization of phospholipid bilayer': $i).
% 29.32/29.13  tff(decl_68935, type, 'self-organization of phospholipid bilayer': $i).
% 29.32/29.13  tff(decl_68936, type, 'organization of phospholipids in water': $i).
% 29.32/29.13  tff(decl_68937, type, 'spontaneous formation of membrane in water': $i).
% 29.32/29.13  tff(decl_68938, type, 'spontaneous formation of membrane': $i).
% 29.32/29.13  tff(decl_68939, type, 'self organization of phospholipid': $i).
% 29.32/29.13  tff(decl_68940, type, 'self-organization-of-phospholipid': $i).
% 29.32/29.13  tff(decl_68941, type, self_organize_1: $i > $o).
% 29.32/29.13  tff(decl_68942, type, fn_self_organization_of_phospholipids_1: $i > $i).
% 29.32/29.13  tff(decl_68943, type, fn_self_organization_of_phospholipids_2: $i > $i).
% 29.32/29.13  tff(decl_68944, type, fn_self_organization_of_phospholipids_3: $i > $i).
% 29.32/29.13  tff(decl_68945, type, fn_self_organization_of_phospholipids_4: $i > $i).
% 29.32/29.13  tff(decl_68946, type, fn_self_organization_of_phospholipids_5: $i > $i).
% 29.32/29.13  tff(decl_68947, type, fn_self_organization_of_phospholipids_6: $i > $i).
% 29.32/29.13  tff(decl_68948, type, fn_self_organization_of_phospholipids_7: $i > $i).
% 29.32/29.13  tff(decl_68949, type, fn_self_organize_2: $i > $i).
% 29.32/29.13  tff(decl_68950, type, 'Self-organize': $i).
% 29.32/29.13  tff(decl_68951, type, 'Process in which molecules form an organized arrangement based on their chemical properties, such as polarity.': $i).
% 29.32/29.13  tff(decl_68952, type, 'self organize': $i).
% 29.32/29.13  tff(decl_68953, type, 'self-organize': $i).
% 29.32/29.13  tff(decl_68954, type, 'Self-Pollination': $i).
% 29.32/29.13  tff(decl_68955, type, 'The transfer of pollen to a flower of the same plant or to another plant with the same genetic make up.': $i).
% 29.32/29.13  tff(decl_68956, type, 'pollinate itself': $i).
% 29.32/29.13  tff(decl_68957, type, 'pollination of self': $i).
% 29.32/29.13  tff(decl_68958, type, 'self pollination': $i).
% 29.32/29.13  tff(decl_68959, type, 'self-pollination': $i).
% 29.32/29.13  tff(decl_68960, type, self_pruning_1: $i > $o).
% 29.32/29.13  tff(decl_68961, type, 'Self-Pruning': $i).
% 29.32/29.13  tff(decl_68962, type, 'The programmed death and shedding of plant parts such as leaves, flowers and fruits.': $i).
% 29.32/29.13  tff(decl_68963, type, 'self prune': $i).
% 29.32/29.13  tff(decl_68964, type, 'self-prune': $i).
% 29.32/29.13  tff(decl_68965, type, 'pruning of self': $i).
% 29.32/29.13  tff(decl_68966, type, 'self pruning': $i).
% 29.32/29.13  tff(decl_68967, type, 'self-pruning': $i).
% 29.32/29.13  tff(decl_68968, type, fn_self_pruning_1: $i > $i).
% 29.32/29.13  tff(decl_68969, type, fn_self_pruning_2: $i > $i).
% 29.32/29.13  tff(decl_68970, type, fn_self_pruning_3: $i > $i).
% 29.32/29.13  tff(decl_68971, type, fn_self_pruning_4: $i > $i).
% 29.32/29.13  tff(decl_68972, type, fn_self_pruning_5: $i > $i).
% 29.32/29.13  tff(decl_68973, type, fn_self_pruning_6: $i > $i).
% 29.32/29.13  tff(decl_68974, type, self_recognition_1: $i > $o).
% 29.32/29.13  tff(decl_68975, type, 'Self-Recognition': $i).
% 29.32/29.13  tff(decl_68976, type, 'An organism\\s ability to distinguish the cells of self from those of nonself.': $i).
% 29.32/29.13  tff(decl_68977, type, 'recognition of self': $i).
% 29.32/29.13  tff(decl_68978, type, 'self recognition': $i).
% 29.32/29.13  tff(decl_68979, type, 'self-recognition': $i).
% 29.32/29.13  tff(decl_68980, type, 'Sell': $i).
% 29.32/29.13  tff(decl_68981, type, sell: $i).
% 29.32/29.13  tff(decl_68982, type, fn_sell_1: $i > $i).
% 29.32/29.13  tff(decl_68983, type, selling_1: $i > $o).
% 29.32/29.13  tff(decl_68984, type, 'Selling': $i).
% 29.32/29.13  tff(decl_68985, type, merchandising: $i).
% 29.32/29.13  tff(decl_68986, type, marketing: $i).
% 29.32/29.13  tff(decl_68987, type, commerce: $i).
% 29.32/29.13  tff(decl_68988, type, selling: $i).
% 29.32/29.13  tff(decl_68989, type, 'Semelparity': $i).
% 29.32/29.13  tff(decl_68990, type, 'A reproductive strategy that involves producing all of one\\s offspring in a single event, usually shortly before death.': $i).
% 29.32/29.13  tff(decl_68991, type, 'big bang reproduction': $i).
% 29.32/29.13  tff(decl_68992, type, semelparity: $i).
% 29.32/29.13  tff(decl_68993, type, 'Semen': $i).
% 29.32/29.13  tff(decl_68994, type, 'The fluid that is ejaculated from the penis during orgasm, consisting of sperm, mucus, sugars, enzymes, prostaglandins, and ascorbic acid.': $i).
% 29.32/29.13  tff(decl_68995, type, semen: $i).
% 29.32/29.13  tff(decl_68996, type, semi_conservative_replication_1: $i > $o).
% 29.32/29.13  tff(decl_68997, type, 'Semi-Conservative-Replication': $i).
% 29.32/29.13  tff(decl_68998, type, 'Type of DNA replication in which the replicated double helix consists of one old strand, derived from the parental molecule, and one newly made strand.': $i).
% 29.32/29.13  tff(decl_68999, type, 'semiconservative model': $i).
% 29.32/29.13  tff(decl_69000, type, 'semiconservative-model': $i).
% 29.32/29.13  tff(decl_69001, type, 'semiconservative replication': $i).
% 29.32/29.13  tff(decl_69002, type, 'semiconservative-replication': $i).
% 29.32/29.13  tff(decl_69003, type, 'semi conservative model': $i).
% 29.32/29.13  tff(decl_69004, type, 'semi-conservative-model': $i).
% 29.32/29.13  tff(decl_69005, type, 'watson and crick model': $i).
% 29.32/29.13  tff(decl_69006, type, 'watson-and-crick-model': $i).
% 29.32/29.13  tff(decl_69007, type, 'watson & crick model': $i).
% 29.32/29.13  tff(decl_69008, type, 'watson-&-crick-model': $i).
% 29.32/29.13  tff(decl_69009, type, 'watson crick model': $i).
% 29.32/29.13  tff(decl_69010, type, 'watson-crick-model': $i).
% 29.32/29.13  tff(decl_69011, type, 'semi conservative replication': $i).
% 29.32/29.13  tff(decl_69012, type, 'semi-conservative-replication': $i).
% 29.32/29.13  tff(decl_69013, type, 'Semiautonomous-Organelle': $i).
% 29.32/29.13  tff(decl_69014, type, 'A semiautonomous organelle  have their own DNA, mRNA, tRNA, ribosomes and they replicate by binary fission so they are said to be self governing.': $i).
% 29.32/29.13  tff(decl_69015, type, 'semi autonomous organelle': $i).
% 29.32/29.13  tff(decl_69016, type, 'semi-autonomous organelle': $i).
% 29.32/29.13  tff(decl_69017, type, 'semiautonomous organelle': $i).
% 29.32/29.13  tff(decl_69018, type, 'semiautonomous-organelle': $i).
% 29.32/29.13  tff(decl_69019, type, fn_semiautonomous_organelle_3: $i > $i).
% 29.32/29.13  tff(decl_69020, type, 'Semicircular-Canal': $i).
% 29.32/29.13  tff(decl_69021, type, 'One of three fluid-filled, half-circular, interconnected tubes in the inner ear of mammals. They detect positional changes of the head and maintain equilibrium.': $i).
% 29.32/29.13  tff(decl_69022, type, 'semicircular canal': $i).
% 29.32/29.13  tff(decl_69023, type, 'semicircular-canal': $i).
% 29.32/29.13  tff(decl_69024, type, 'Semilunar-Valve': $i).
% 29.32/29.13  tff(decl_69025, type, 'Either of two valves located at the exits of the heart. The pulmonary valve leaves the right ventricle and the aortic valve leaves the left ventricle.': $i).
% 29.32/29.13  tff(decl_69026, type, 'semilunar valve': $i).
% 29.32/29.13  tff(decl_69027, type, 'semilunar-valve': $i).
% 29.32/29.13  tff(decl_69028, type, 'Seminal-Vesicle': $i).
% 29.32/29.13  tff(decl_69029, type, 'A paired gland in male mammals that secretes most of the fluid component of semen, including ions to raise the pH.': $i).
% 29.32/29.13  tff(decl_69030, type, 'seminal vesicle': $i).
% 29.32/29.13  tff(decl_69031, type, 'seminal-vesicle': $i).
% 29.32/29.13  tff(decl_69032, type, 'Seminiferous-Tubule': $i).
% 29.32/29.13  tff(decl_69033, type, 'A convoluted tube in the testis, where meiosis takes place and sperm are produced.': $i).
% 29.32/29.13  tff(decl_69034, type, 'seminiferous tubule': $i).
% 29.32/29.13  tff(decl_69035, type, 'seminiferous-tubule': $i).
% 29.32/29.13  tff(decl_69036, type, 'Semipermeable-Entity': $i).
% 29.32/29.13  tff(decl_69037, type, 'Semipermeable entity allows only certain things to pass through it.': $i).
% 29.32/29.13  tff(decl_69038, type, semipermeable: $i).
% 29.32/29.13  tff(decl_69039, type, 'semi permeable': $i).
% 29.32/29.13  tff(decl_69040, type, 'semi-permeable': $i).
% 29.32/29.13  tff(decl_69041, type, semipermeability: $i).
% 29.32/29.13  tff(decl_69042, type, permeability: $i).
% 29.32/29.13  tff(decl_69043, type, permeable: $i).
% 29.32/29.13  tff(decl_69044, type, 'semipermeable entity': $i).
% 29.32/29.13  tff(decl_69045, type, 'semipermeable-entity': $i).
% 29.32/29.13  tff(decl_69046, type, 'Semisolid-Substance': $i).
% 29.32/29.13  tff(decl_69047, type, 'Substances are partly solid; having a rigidity and viscosity intermediate between a solid and a liquid': $i).
% 29.32/29.13  tff(decl_69048, type, semifluid: $i).
% 29.32/29.13  tff(decl_69049, type, semisolid: $i).
% 29.32/29.13  tff(decl_69050, type, 'semi fluid': $i).
% 29.32/29.13  tff(decl_69051, type, 'semi-fluid': $i).
% 29.32/29.13  tff(decl_69052, type, 'semi solid': $i).
% 29.32/29.13  tff(decl_69053, type, 'semi-solid': $i).
% 29.32/29.13  tff(decl_69054, type, 'semi fluid substance': $i).
% 29.32/29.13  tff(decl_69055, type, 'semi-fluid substance': $i).
% 29.32/29.13  tff(decl_69056, type, 'semifluid substance': $i).
% 29.32/29.13  tff(decl_69057, type, 'semisolid substance': $i).
% 29.32/29.13  tff(decl_69058, type, 'semisolid-substance': $i).
% 29.32/29.13  tff(decl_69059, type, 'Send': $i).
% 29.32/29.13  tff(decl_69060, type, send: $i).
% 29.32/29.13  tff(decl_69061, type, mail: $i).
% 29.32/29.13  tff(decl_69062, type, post: $i).
% 29.32/29.13  tff(decl_69063, type, 'send out': $i).
% 29.32/29.13  tff(decl_69064, type, send_out: $i).
% 29.32/29.13  tff(decl_69065, type, 'Senescence': $i).
% 29.32/29.13  tff(decl_69066, type, 'The endogenous process of accumulative alterations to molecular and cellular structure, resulting in death.': $i).
% 29.32/29.13  tff(decl_69067, type, senescence: $i).
% 29.32/29.13  tff(decl_69068, type, 'Senescent-Cell': $i).
% 29.32/29.13  tff(decl_69069, type, 'A cell that is no longer dividing but is still metabolically active (i.e., not dead).': $i).
% 29.32/29.13  tff(decl_69070, type, 'senescent cell': $i).
% 29.32/29.13  tff(decl_69071, type, 'senescent-cell': $i).
% 29.32/29.13  tff(decl_69072, type, 'Sensation': $i).
% 29.32/29.13  tff(decl_69073, type, 'The transmission of nerve impulses in response to the detection of an internal or external stimulus.': $i).
% 29.32/29.13  tff(decl_69074, type, sensation: $i).
% 29.32/29.13  tff(decl_69075, type, 'Sense': $i).
% 29.32/29.13  tff(decl_69076, type, feel: $i).
% 29.32/29.13  tff(decl_69077, type, fn_sense_3: $i > $i).
% 29.32/29.13  tff(decl_69078, type, 'Sensitive-Period': $i).
% 29.32/29.13  tff(decl_69079, type, 'A limited period of time in an individual\\s development when it is easy to learn particular behaviors.': $i).
% 29.32/29.13  tff(decl_69080, type, 'sensitive period': $i).
% 29.32/29.13  tff(decl_69081, type, 'sensitive-period': $i).
% 29.32/29.13  tff(decl_69082, type, sensory_adaptation_1: $i > $o).
% 29.32/29.13  tff(decl_69083, type, 'Sensory-Adaptation': $i).
% 29.32/29.13  tff(decl_69084, type, 'A decrease in sensitivity to a particular stimulus when a sensory neuron has been stimulated repeatedly.': $i).
% 29.32/29.13  tff(decl_69085, type, 'sensory adaptation': $i).
% 29.32/29.13  tff(decl_69086, type, 'sensory-adaptation': $i).
% 29.32/29.13  tff(decl_69087, type, 'Sensory-Division': $i).
% 29.32/29.13  tff(decl_69088, type, 'The afferent neurons that convey information to the CNS from the sensory receptors that monitor the external and internal environment.': $i).
% 29.32/29.13  tff(decl_69089, type, 'sensory division': $i).
% 29.32/29.13  tff(decl_69090, type, 'sensory-division': $i).
% 29.32/29.13  tff(decl_69091, type, 'Sensory-Nervous-Tissue': $i).
% 29.32/29.13  tff(decl_69092, type, 'Tissue made up of neurons and supportive cells specifically related to the senses.': $i).
% 29.32/29.13  tff(decl_69093, type, 'sensory nervous tissue': $i).
% 29.32/29.13  tff(decl_69094, type, 'sensory-nervous-tissue': $i).
% 29.32/29.13  tff(decl_69095, type, 'Sensory-Neuron': $i).
% 29.32/29.13  tff(decl_69096, type, 'A neuron responsible for receiving information from the external or internal environment and conveying it in electrical form to the central nervous system.': $i).
% 29.32/29.13  tff(decl_69097, type, 'sensory neuron': $i).
% 29.32/29.13  tff(decl_69098, type, 'sensory-neuron': $i).
% 29.32/29.13  tff(decl_69099, type, fn_sensory_neuron_1: $i > $i).
% 29.32/29.13  tff(decl_69100, type, fn_sensory_neuron_2: $i > $i).
% 29.32/29.13  tff(decl_69101, type, fn_sensory_neuron_3: $i > $i).
% 29.32/29.13  tff(decl_69102, type, 'Sensory-Organ': $i).
% 29.32/29.13  tff(decl_69103, type, 'An organ that receives and relays information from the internal or external environment to the rest of the nervous system.': $i).
% 29.32/29.13  tff(decl_69104, type, 'sensory organ': $i).
% 29.32/29.13  tff(decl_69105, type, 'sensory-organ': $i).
% 29.32/29.13  tff(decl_69106, type, 'Sensory-Process': $i).
% 29.32/29.13  tff(decl_69107, type, 'Any process related to the detection of external or internal stimuli and the conversion of those stimuli to sensory perceptions.': $i).
% 29.32/29.13  tff(decl_69108, type, 'sensory process': $i).
% 29.32/29.13  tff(decl_69109, type, 'sensory-process': $i).
% 29.32/29.13  tff(decl_69110, type, 'Sensory-Reception': $i).
% 29.32/29.13  tff(decl_69111, type, 'The detection of an external or internal stimulus by a sensory neuron.': $i).
% 29.32/29.13  tff(decl_69112, type, 'sensory reception': $i).
% 29.32/29.13  tff(decl_69113, type, 'sensory-reception': $i).
% 29.32/29.13  tff(decl_69114, type, 'Sensory-Receptor': $i).
% 29.32/29.13  tff(decl_69115, type, 'Any part of a body (i.e, an organ, cell, or structure within a cell) that detects and responds to a specific stimulus from the internal or external environment.': $i).
% 29.32/29.13  tff(decl_69116, type, 'sensory receptor': $i).
% 29.32/29.13  tff(decl_69117, type, 'sensory-receptor': $i).
% 29.32/29.13  tff(decl_69118, type, 'Sensory-System': $i).
% 29.32/29.13  tff(decl_69119, type, 'A part of the nervous system, consisting of sensory receptors, neural pathways, and areas of the brain involved in sensory perception.': $i).
% 29.32/29.13  tff(decl_69120, type, 'sensory system': $i).
% 29.32/29.13  tff(decl_69121, type, 'sensory-system': $i).
% 29.32/29.13  tff(decl_69122, type, sensory_transduction_1: $i > $o).
% 29.32/29.13  tff(decl_69123, type, 'Sensory-Transduction': $i).
% 29.32/29.13  tff(decl_69124, type, 'The conversion of a sensory stimulus into an action potential in a receptor cell.': $i).
% 29.32/29.13  tff(decl_69125, type, 'sensory transduction': $i).
% 29.32/29.13  tff(decl_69126, type, 'sensory-transduction': $i).
% 29.32/29.13  tff(decl_69127, type, 'Sentience-Constant': $i).
% 29.32/29.13  tff(decl_69128, type, 'constant of sentience': $i).
% 29.32/29.13  tff(decl_69129, type, 'sentience constant': $i).
% 29.32/29.13  tff(decl_69130, type, 'sentience-constant': $i).
% 29.32/29.13  tff(decl_69131, type, 'Sentience-Value': $i).
% 29.32/29.13  tff(decl_69132, type, 'the readiness to perceive sensations': $i).
% 29.32/29.13  tff(decl_69133, type, sentience: $i).
% 29.32/29.13  tff(decl_69134, type, 'value of sentience': $i).
% 29.32/29.13  tff(decl_69135, type, 'sentience value': $i).
% 29.32/29.13  tff(decl_69136, type, 'sentience-value': $i).
% 29.32/29.13  tff(decl_69137, type, 'Sepal': $i).
% 29.32/29.13  tff(decl_69138, type, 'In angiosperms, a modified leaf that encloses and protects a developing flower bud before it blooms.': $i).
% 29.32/29.13  tff(decl_69139, type, sepal: $i).
% 29.32/29.13  tff(decl_69140, type, separase_1: $i > $o).
% 29.32/29.13  tff(decl_69141, type, 'Separase': $i).
% 29.32/29.13  tff(decl_69142, type, 'Enzyme which cleaves the cohesion proteins holding together sister chromatids during anaphase of the cell cycle.': $i).
% 29.32/29.13  tff(decl_69143, type, separase: $i).
% 29.32/29.13  tff(decl_69144, type, 'Separation-Of-Sister-Chromatids': $i).
% 29.32/29.13  tff(decl_69145, type, 'During mitosis, the sequence of events which results in the separation of the sister chromatids which make up a diploid chromosome into two separate and identical chromosomes.': $i).
% 29.32/29.13  tff(decl_69146, type, 'separation of sister chromatid': $i).
% 29.32/29.13  tff(decl_69147, type, 'separation-of-sister-chromatid': $i).
% 29.32/29.13  tff(decl_69148, type, fn_separation_of_sister_chromatids_1: $i > $i).
% 29.32/29.13  tff(decl_69149, type, fn_separation_of_sister_chromatids_2: $i > $i).
% 29.32/29.13  tff(decl_69150, type, fn_separation_of_sister_chromatids_3: $i > $i).
% 29.32/29.13  tff(decl_69151, type, fn_separation_of_sister_chromatids_4: $i > $i).
% 29.32/29.13  tff(decl_69152, type, fn_separation_of_sister_chromatids_5: $i > $i).
% 29.32/29.13  tff(decl_69153, type, fn_separation_of_sister_chromatids_6: $i > $i).
% 29.32/29.13  tff(decl_69154, type, fn_separation_of_sister_chromatids_7: $i > $i).
% 29.32/29.13  tff(decl_69155, type, fn_separation_of_sister_chromatids_8: $i > $i).
% 29.32/29.13  tff(decl_69156, type, fn_separation_of_sister_chromatids_9: $i > $i).
% 29.32/29.13  tff(decl_69157, type, fn_separation_of_sister_chromatids_10: $i > $i).
% 29.32/29.13  tff(decl_69158, type, fn_separation_of_sister_chromatids_11: $i > $i).
% 29.32/29.13  tff(decl_69159, type, fn_separation_of_sister_chromatids_12: $i > $i).
% 29.32/29.13  tff(decl_69160, type, fn_sister_chromatid_cohesion_6: $i > $i).
% 29.32/29.13  tff(decl_69161, type, fn_sister_chromatid_cohesion_7: $i > $i).
% 29.32/29.13  tff(decl_69162, type, fn_sister_chromatid_cohesion_8: $i > $i).
% 29.32/29.13  tff(decl_69163, type, fn_sister_chromatid_cohesion_1: $i > $i).
% 29.32/29.13  tff(decl_69164, type, fn_sister_chromatid_cohesion_9: $i > $i).
% 29.32/29.13  tff(decl_69165, type, septic_shock_1: $i > $o).
% 29.32/29.13  tff(decl_69166, type, 'Septic-Shock': $i).
% 29.32/29.13  tff(decl_69167, type, 'An extreme immune response to an infection that has spread throughout the body\\s organs and tissues, resulting in extremely low blood pressure and, possibly, death.': $i).
% 29.32/29.13  tff(decl_69168, type, 'septic shock': $i).
% 29.32/29.13  tff(decl_69169, type, 'septic-shock': $i).
% 29.32/29.13  tff(decl_69170, type, septum_1: $i > $o).
% 29.32/29.13  tff(decl_69171, type, 'Septum': $i).
% 29.32/29.13  tff(decl_69172, type, 'A wall or curtain of tissue that divides a space or cavity into smaller subunits.': $i).
% 29.32/29.13  tff(decl_69173, type, septum: $i).
% 29.32/29.13  tff(decl_69174, type, 'Sequence': $i).
% 29.32/29.13  tff(decl_69175, type, 'A succession of things, events, or movements.': $i).
% 29.32/29.13  tff(decl_69176, type, series: $i).
% 29.32/29.13  tff(decl_69177, type, 'Sequencing-Machine': $i).
% 29.32/29.13  tff(decl_69178, type, 'An automated instrument used to sequence DNA.': $i).
% 29.32/29.13  tff(decl_69179, type, 'sequencing machine': $i).
% 29.32/29.13  tff(decl_69180, type, 'sequencing-machine': $i).
% 29.32/29.13  tff(decl_69181, type, 'Serine': $i).
% 29.32/29.13  tff(decl_69182, type, 'S': $i).
% 29.32/29.13  tff(decl_69183, type, ser: $i).
% 29.32/29.13  tff(decl_69184, type, serine: $i).
% 29.32/29.13  tff(decl_69185, type, 'Serine-Threonine-Kinase': $i).
% 29.32/29.13  tff(decl_69186, type, 'Kinase enzyme that catalyzes the addition of a phosphate group to the OH group of seriene or threonine amino acids in a protein.': $i).
% 29.32/29.13  tff(decl_69187, type, 'Serotonin': $i).
% 29.32/29.13  tff(decl_69188, type, 'A tryptophan-derived neurotransmitter of the central nervous system.': $i).
% 29.32/29.13  tff(decl_69189, type, serotonin: $i).
% 29.32/29.13  tff(decl_69190, type, service_1: $i > $o).
% 29.32/29.13  tff(decl_69191, type, 'Service': $i).
% 29.32/29.13  tff(decl_69192, type, service: $i).
% 29.32/29.13  tff(decl_69193, type, fn_service_1: $i > $i).
% 29.32/29.13  tff(decl_69194, type, fn_service_2: $i > $i).
% 29.32/29.13  tff(decl_69195, type, 'Session': $i).
% 29.32/29.13  tff(decl_69196, type, session: $i).
% 29.32/29.13  tff(decl_69197, type, 'Seta': $i).
% 29.32/29.13  tff(decl_69198, type, '(1) In bryophytes, the elongated stalk of the sporophyte phase; (2) In invertebrates such as arthropods and segmented worms, a hair-like bristle that can have chemosensory, mechanosensory, or locomotory functions.': $i).
% 29.32/29.13  tff(decl_69199, type, seta: $i).
% 29.32/29.13  tff(decl_69200, type, 'Seven-Methyl-Guanosine': $i).
% 29.32/29.13  tff(decl_69201, type, 'It is a modified form of Guanosine triphosphate which is added to the 5-prime end of mRNA to provide a protective cap at the site': $i).
% 29.32/29.13  tff(decl_69202, type, 'seven methyl guanosine': $i).
% 29.32/29.13  tff(decl_69203, type, 'seven-methyl-guanosine': $i).
% 29.32/29.13  tff(decl_69204, type, 'Sex-Chromosome': $i).
% 29.32/29.13  tff(decl_69205, type, 'A chromosome responsible for determining the sex of an individual.': $i).
% 29.32/29.13  tff(decl_69206, type, 'chromosome of sex': $i).
% 29.32/29.13  tff(decl_69207, type, 'sex chromosome': $i).
% 29.32/29.13  tff(decl_69208, type, 'sex-chromosome': $i).
% 29.32/29.13  tff(decl_69209, type, 'Sex-Constant': $i).
% 29.32/29.13  tff(decl_69210, type, 'constant of sex': $i).
% 29.32/29.13  tff(decl_69211, type, 'sex constant': $i).
% 29.32/29.13  tff(decl_69212, type, 'sex-constant': $i).
% 29.32/29.13  tff(decl_69213, type, 'Sex-Hormone': $i).
% 29.32/29.13  tff(decl_69214, type, 'Sex hormones are the hormones formed by the gonadic organs i.e. testes and ovaries. They are primarily steroids in chemical nature': $i).
% 29.32/29.13  tff(decl_69215, type, 'hormone of sex': $i).
% 29.32/29.13  tff(decl_69216, type, 'sex hormone': $i).
% 29.32/29.13  tff(decl_69217, type, 'sex-hormone': $i).
% 29.32/29.13  tff(decl_69218, type, 'Sex-Linkage-Cross-Breeding-Event': $i).
% 29.32/29.13  tff(decl_69219, type, 'Mating of two individuals, with expression of sex-linked alleles being investigated.': $i).
% 29.32/29.13  tff(decl_69220, type, 'sex linkage cross breeding event': $i).
% 29.32/29.13  tff(decl_69221, type, 'sex-linkage-cross-breeding-event': $i).
% 29.32/29.13  tff(decl_69222, type, fn_sex_linkage_cross_breeding_event_1: $i > $i).
% 29.32/29.13  tff(decl_69223, type, x_linked_inheritance_1: $i > $o).
% 29.32/29.13  tff(decl_69224, type, 'Sex-Linked-Gene': $i).
% 29.32/29.13  tff(decl_69225, type, 'A gene located on a sex chromosome.': $i).
% 29.32/29.13  tff(decl_69226, type, 'sex linked gene': $i).
% 29.32/29.13  tff(decl_69227, type, 'sex-linked gene': $i).
% 29.32/29.13  tff(decl_69228, type, 'sex-linked-gene': $i).
% 29.32/29.13  tff(decl_69229, type, sex_linked_hemophilia_gene_1: $i > $o).
% 29.32/29.13  tff(decl_69230, type, 'Sex-linked-Hemophilia-Gene': $i).
% 29.32/29.13  tff(decl_69231, type, 'A gene for a human genetic disease caused by a recessive allele located on the X-chromosome resulting in the absence of one or more blood-clotting proteins.': $i).
% 29.32/29.13  tff(decl_69232, type, 'sex linked hemophilia gene': $i).
% 29.32/29.13  tff(decl_69233, type, 'sex-linked-hemophilia-gene': $i).
% 29.32/29.13  tff(decl_69234, type, 'Sex-Linked-Human-Genetic-Disorder': $i).
% 29.32/29.13  tff(decl_69235, type, 'A disease caused by a gene whose locus is on the X chromosome. Females must be homozygous for the disease-causing allele to have the disease but may carry the disease-causing allele in a heterozygous genotype, whereas males will have the disease any time they inherit the disease-causing allele from their mothers.': $i).
% 29.32/29.13  tff(decl_69236, type, 'sex linked': $i).
% 29.32/29.13  tff(decl_69237, type, 'sex-linked': $i).
% 29.32/29.13  tff(decl_69238, type, 'sex linked human genetic disorder': $i).
% 29.32/29.13  tff(decl_69239, type, 'sex-linked human genetic disorder': $i).
% 29.32/29.13  tff(decl_69240, type, 'sex-linked-human-genetic-disorder': $i).
% 29.32/29.13  tff(decl_69241, type, fn_sex_linked_human_genetic_disorder_1: $i > $i).
% 29.32/29.13  tff(decl_69242, type, sex_linked_inheritance_1: $i > $o).
% 29.32/29.13  tff(decl_69243, type, fn_sex_linked_inheritance_2: $i > $i).
% 29.32/29.13  tff(decl_69244, type, 'Sex-Linked-Inheritance': $i).
% 29.32/29.13  tff(decl_69245, type, 'Inheritance of characteristics that are determined by genes carried on the sex chromosomes.': $i).
% 29.32/29.13  tff(decl_69246, type, 'sex linked inheritance': $i).
% 29.32/29.13  tff(decl_69247, type, 'sex-linked inheritance': $i).
% 29.32/29.13  tff(decl_69248, type, 'sex-linked-inheritance': $i).
% 29.32/29.13  tff(decl_69249, type, 'Sex-Pili': $i).
% 29.32/29.13  tff(decl_69250, type, 'Sex-pili are hairlike appendages found on the surface of many bacteria that enable the transfer of plasmids between the bacteria.': $i).
% 29.32/29.13  tff(decl_69251, type, 'sex pili': $i).
% 29.32/29.13  tff(decl_69252, type, 'sex pilus': $i).
% 29.32/29.13  tff(decl_69253, type, 'sex-pili': $i).
% 29.32/29.13  tff(decl_69254, type, fn_sex_pili_1: $i > $i).
% 29.32/29.13  tff(decl_69255, type, fn_sex_pili_2: $i > $i).
% 29.32/29.13  tff(decl_69256, type, fn_sex_pili_3: $i > $i).
% 29.32/29.13  tff(decl_69257, type, fn_sex_pili_4: $i > $i).
% 29.32/29.13  tff(decl_69258, type, 'Sex-Pilus': $i).
% 29.32/29.13  tff(decl_69259, type, 'A hairlike appendage on the surface of some bacteria. A sex pilus connects two bacterial cells together to allow conjugation, or exchange of genetic material.': $i).
% 29.32/29.13  tff(decl_69260, type, 'conjugal pilus': $i).
% 29.32/29.13  tff(decl_69261, type, 'conjugal-pilus': $i).
% 29.32/29.13  tff(decl_69262, type, 'pilus of sex': $i).
% 29.32/29.13  tff(decl_69263, type, 'sex-pilus': $i).
% 29.32/29.13  tff(decl_69264, type, 'Sex-Value': $i).
% 29.32/29.13  tff(decl_69265, type, 'either of the two categories (male or female) into which most organisms are divided': $i).
% 29.32/29.13  tff(decl_69266, type, gender: $i).
% 29.32/29.13  tff(decl_69267, type, sexuality: $i).
% 29.32/29.13  tff(decl_69268, type, sex: $i).
% 29.32/29.13  tff(decl_69269, type, 'value of sex': $i).
% 29.32/29.13  tff(decl_69270, type, 'sex value': $i).
% 29.32/29.13  tff(decl_69271, type, 'sex-value': $i).
% 29.32/29.13  tff(decl_69272, type, sexual_dimorphism_1: $i > $o).
% 29.32/29.13  tff(decl_69273, type, 'Sexual-Dimorphism': $i).
% 29.32/29.13  tff(decl_69274, type, 'Noticeable morphological differences between males and females of the same species.': $i).
% 29.32/29.13  tff(decl_69275, type, 'sexual dimorphism': $i).
% 29.32/29.13  tff(decl_69276, type, 'sexual-dimorphism': $i).
% 29.32/29.13  tff(decl_69277, type, 'Sexual-Intercourse': $i).
% 29.32/29.13  tff(decl_69278, type, 'An act of contraction, shortening or tensing of a part muscle or muscle fiber.': $i).
% 29.32/29.13  tff(decl_69279, type, copulation: $i).
% 29.32/29.13  tff(decl_69280, type, 'sexual intercourse': $i).
% 29.32/29.13  tff(decl_69281, type, 'sexual-intercourse': $i).
% 29.32/29.13  tff(decl_69282, type, fn_sexual_life_cycle_5: $i > $i).
% 29.32/29.13  tff(decl_69283, type, 'Sexual-Life-Cycle': $i).
% 29.32/29.13  tff(decl_69284, type, 'The birth-to-death sequence of life history stages in a sexually reproducing organism.': $i).
% 29.32/29.13  tff(decl_69285, type, 'undergo the sexual life cycle': $i).
% 29.32/29.13  tff(decl_69286, type, 'sexual life cycle': $i).
% 29.32/29.13  tff(decl_69287, type, 'sexual-life-cycle': $i).
% 29.32/29.13  tff(decl_69288, type, fn_sexual_life_cycle_1: $i > $i).
% 29.32/29.13  tff(decl_69289, type, fn_sexual_life_cycle_2: $i > $i).
% 29.32/29.13  tff(decl_69290, type, fn_sexual_life_cycle_3: $i > $i).
% 29.32/29.13  tff(decl_69291, type, fn_sexual_life_cycle_4: $i > $i).
% 29.32/29.13  tff(decl_69292, type, fn_sexual_reproduction_3: $i > $i).
% 29.32/29.13  tff(decl_69293, type, fn_sexual_reproduction_2: $i > $i).
% 29.32/29.13  tff(decl_69294, type, 'Sexual-Reproduction': $i).
% 29.32/29.13  tff(decl_69295, type, 'It is the process by which a eukaryotic organism alongwith its complement organism functions as parent and creates its offspring and passes on its genetic material to the offspring. It mainly involves two processes \\Meiosis\\ and \\Fertilization\\.': $i).
% 29.32/29.13  tff(decl_69296, type, 'sexual reproduction': $i).
% 29.32/29.13  tff(decl_69297, type, 'sexual-reproduction': $i).
% 29.32/29.13  tff(decl_69298, type, fn_sexual_reproduction_5: $i > $i).
% 29.32/29.13  tff(decl_69299, type, fn_sexual_reproduction_6: $i > $i).
% 29.32/29.13  tff(decl_69300, type, 'Sexual-Selection': $i).
% 29.32/29.13  tff(decl_69301, type, 'A form of natural selection that acts differently on males and females within species in which males and females have different, sometimes conflicting, reproductive strategies.': $i).
% 29.32/29.13  tff(decl_69302, type, 'sexual selection': $i).
% 29.32/29.13  tff(decl_69303, type, 'sexual-selection': $i).
% 29.32/29.13  tff(decl_69304, type, shaken_attribute_group_1: $i > $o).
% 29.32/29.13  tff(decl_69305, type, 'SHAKEN-Attribute-Group': $i).
% 29.32/29.13  tff(decl_69306, type, 'shaken attribute group': $i).
% 29.32/29.13  tff(decl_69307, type, 'shaken-attribute-group': $i).
% 29.32/29.13  tff(decl_69308, type, shaken_slot_group_1: $i > $o).
% 29.32/29.13  tff(decl_69309, type, shaken_column_content_order_constant_1: $i > $o).
% 29.32/29.13  tff(decl_69310, type, 'SHAKEN-Column-Content-Order-Constant': $i).
% 29.32/29.13  tff(decl_69311, type, 'shaken column content order constant': $i).
% 29.32/29.13  tff(decl_69312, type, 'shaken-column-content-order-constant': $i).
% 29.32/29.13  tff(decl_69313, type, shaken_partition_1: $i > $o).
% 29.32/29.13  tff(decl_69314, type, 'SHAKEN-Partition': $i).
% 29.32/29.13  tff(decl_69315, type, 'shaken partition': $i).
% 29.32/29.13  tff(decl_69316, type, 'shaken-partition': $i).
% 29.32/29.13  tff(decl_69317, type, 'SHAKEN-Slot-Group': $i).
% 29.32/29.13  tff(decl_69318, type, 'shaken slot group': $i).
% 29.32/29.13  tff(decl_69319, type, 'shaken-slot-group': $i).
% 29.32/29.13  tff(decl_69320, type, 'Shaken-Slot-Group': $i).
% 29.32/29.13  tff(decl_69321, type, shaken_table_1: $i > $o).
% 29.32/29.13  tff(decl_69322, type, 'SHAKEN-Table': $i).
% 29.32/29.13  tff(decl_69323, type, 'shaken table': $i).
% 29.32/29.13  tff(decl_69324, type, 'shaken-table': $i).
% 29.32/29.13  tff(decl_69325, type, shaken_table_column_1: $i > $o).
% 29.32/29.13  tff(decl_69326, type, 'SHAKEN-Table-Column': $i).
% 29.32/29.13  tff(decl_69327, type, 'shaken table column': $i).
% 29.32/29.13  tff(decl_69328, type, 'shaken-table-column': $i).
% 29.32/29.13  tff(decl_69329, type, shaken_table_header_column_1: $i > $o).
% 29.32/29.13  tff(decl_69330, type, 'SHAKEN-Table-Header-Column': $i).
% 29.32/29.13  tff(decl_69331, type, 'shaken table header column': $i).
% 29.32/29.13  tff(decl_69332, type, 'shaken-table-header-column': $i).
% 29.32/29.13  tff(decl_69333, type, 'Shape-Changing-Cell': $i).
% 29.32/29.13  tff(decl_69334, type, 'A cell that changes shape is cell showing shape change.': $i).
% 29.32/29.13  tff(decl_69335, type, 'cell showing shape change': $i).
% 29.32/29.13  tff(decl_69336, type, 'cell showing shape-change': $i).
% 29.32/29.13  tff(decl_69337, type, 'shape changing cell': $i).
% 29.32/29.13  tff(decl_69338, type, 'shape-changing-cell': $i).
% 29.32/29.13  tff(decl_69339, type, fn_shape_changing_cell_2: $i > $i).
% 29.32/29.13  tff(decl_69340, type, fn_shape_changing_cell_3: $i > $i).
% 29.32/29.13  tff(decl_69341, type, fn_shape_changing_cell_5: $i > $i).
% 29.32/29.13  tff(decl_69342, type, fn_shape_changing_cell_4: $i > $i).
% 29.32/29.13  tff(decl_69343, type, 'Shape-Constant': $i).
% 29.32/29.13  tff(decl_69344, type, 'constant of shape': $i).
% 29.32/29.13  tff(decl_69345, type, 'shape constant': $i).
% 29.32/29.13  tff(decl_69346, type, 'shape-constant': $i).
% 29.32/29.13  tff(decl_69347, type, 'Shape-Value': $i).
% 29.32/29.13  tff(decl_69348, type, 'any spatial attributes (especially as defined by outline)': $i).
% 29.32/29.13  tff(decl_69349, type, configuration: $i).
% 29.32/29.13  tff(decl_69350, type, contour: $i).
% 29.32/29.13  tff(decl_69351, type, conformation: $i).
% 29.32/29.13  tff(decl_69352, type, shape: $i).
% 29.32/29.13  tff(decl_69353, type, 'value of shape': $i).
% 29.32/29.13  tff(decl_69354, type, 'shape value': $i).
% 29.32/29.13  tff(decl_69355, type, 'shape-value': $i).
% 29.32/29.13  tff(decl_69356, type, 'Share': $i).
% 29.32/29.13  tff(decl_69357, type, 'The act of utilization of resources by two entities.': $i).
% 29.32/29.13  tff(decl_69358, type, 'Shear': $i).
% 29.32/29.13  tff(decl_69359, type, 'The processes of removing sections from a larger object by cutting or clipping.': $i).
% 29.32/29.13  tff(decl_69360, type, shear: $i).
% 29.32/29.13  tff(decl_69361, type, 'Shelf': $i).
% 29.32/29.13  tff(decl_69362, type, shelf: $i).
% 29.32/29.13  tff(decl_69363, type, 'Shell': $i).
% 29.32/29.13  tff(decl_69364, type, 'A rigid covering that protects an organism, such as the exoskeleton of molluscs and arthropods, or an object, such as the shell of a bird\\s egg.': $i).
% 29.32/29.13  tff(decl_69365, type, shell: $i).
% 29.32/29.13  tff(decl_69366, type, 'Shell-Calcification': $i).
% 29.32/29.13  tff(decl_69367, type, 'The secretion of calcium carbonate which results in a hardened shell around certain aquatic animals.': $i).
% 29.32/29.13  tff(decl_69368, type, 'calcification of shell': $i).
% 29.32/29.13  tff(decl_69369, type, 'shell calcification': $i).
% 29.32/29.13  tff(decl_69370, type, 'shell-calcification': $i).
% 29.32/29.13  tff(decl_69371, type, fn_shell_calcification_1: $i > $i).
% 29.32/29.13  tff(decl_69372, type, fn_shell_calcification_2: $i > $i).
% 29.32/29.13  tff(decl_69373, type, fn_shell_calcification_3: $i > $i).
% 29.32/29.13  tff(decl_69374, type, 'Shelled-Egg': $i).
% 29.32/29.13  tff(decl_69375, type, 'An egg with an outer covering, shell around the zygote is a shelled egg.': $i).
% 29.32/29.13  tff(decl_69376, type, 'shelled egg': $i).
% 29.32/29.13  tff(decl_69377, type, 'shelled-egg': $i).
% 29.32/29.13  tff(decl_69378, type, fn_shelled_egg_1: $i > $i).
% 29.32/29.13  tff(decl_69379, type, fn_shelled_egg_2: $i > $i).
% 29.32/29.13  tff(decl_69380, type, fn_shelled_egg_3: $i > $i).
% 29.32/29.13  tff(decl_69381, type, fn_shelled_egg_4: $i > $i).
% 29.32/29.13  tff(decl_69382, type, fn_shelled_egg_5: $i > $i).
% 29.32/29.13  tff(decl_69383, type, fn_shelled_egg_6: $i > $i).
% 29.32/29.13  tff(decl_69384, type, shewanella_oneidensis_1: $i > $o).
% 29.32/29.13  tff(decl_69385, type, 'Shewanella-Oneidensis': $i).
% 29.32/29.13  tff(decl_69386, type, 'A species of bacteria that reduces heavy metals and is used in bioremediation projects.': $i).
% 29.32/29.13  tff(decl_69387, type, 'shewanella oneidensis': $i).
% 29.32/29.13  tff(decl_69388, type, 'shewanella-oneidensis': $i).
% 29.32/29.13  tff(decl_69389, type, fn_shewanella_oneidensis_1: $i > $i).
% 29.32/29.13  tff(decl_69390, type, uranium_1: $i > $o).
% 29.32/29.13  tff(decl_69391, type, fn_shewanella_oneidensis_2: $i > $i).
% 29.32/29.13  tff(decl_69392, type, fn_shewanella_oneidensis_3: $i > $i).
% 29.32/29.13  tff(decl_69393, type, fn_shewanella_oneidensis_4: $i > $i).
% 29.32/29.13  tff(decl_69394, type, fn_shewanella_oneidensis_5: $i > $i).
% 29.32/29.13  tff(decl_69395, type, fn_shewanella_oneidensis_6: $i > $i).
% 29.32/29.13  tff(decl_69396, type, fn_shewanella_oneidensis_7: $i > $i).
% 29.32/29.13  tff(decl_69397, type, fn_shewanella_oneidensis_12: $i > $i).
% 29.32/29.13  tff(decl_69398, type, fn_shewanella_oneidensis_13: $i > $i).
% 29.32/29.13  tff(decl_69399, type, fn_shewanella_oneidensis_14: $i > $i).
% 29.32/29.13  tff(decl_69400, type, fn_shewanella_oneidensis_15: $i > $i).
% 29.32/29.13  tff(decl_69401, type, fn_shewanella_oneidensis_16: $i > $i).
% 29.32/29.13  tff(decl_69402, type, fn_shewanella_oneidensis_17: $i > $i).
% 29.32/29.13  tff(decl_69403, type, fn_shewanella_oneidensis_18: $i > $i).
% 29.32/29.13  tff(decl_69404, type, fn_shewanella_oneidensis_19: $i > $i).
% 29.32/29.13  tff(decl_69405, type, fn_shewanella_oneidensis_25: $i > $i).
% 29.32/29.13  tff(decl_69406, type, fn_shewanella_oneidensis_26: $i > $i).
% 29.32/29.13  tff(decl_69407, type, fn_shewanella_oneidensis_27: $i > $i).
% 29.32/29.13  tff(decl_69408, type, fn_shewanella_oneidensis_28: $i > $i).
% 29.32/29.13  tff(decl_69409, type, fn_shewanella_oneidensis_29: $i > $i).
% 29.32/29.13  tff(decl_69410, type, fn_shewanella_oneidensis_31: $i > $i).
% 29.32/29.13  tff(decl_69411, type, fn_shewanella_oneidensis_32: $i > $i).
% 29.32/29.13  tff(decl_69412, type, fn_shewanella_oneidensis_33: $i > $i).
% 29.32/29.13  tff(decl_69413, type, fn_shewanella_oneidensis_34: $i > $i).
% 29.32/29.13  tff(decl_69414, type, fn_shewanella_oneidensis_35: $i > $i).
% 29.32/29.13  tff(decl_69415, type, fn_shewanella_oneidensis_36: $i > $i).
% 29.32/29.13  tff(decl_69416, type, fn_shewanella_oneidensis_37: $i > $i).
% 29.32/29.13  tff(decl_69417, type, fn_shewanella_oneidensis_38: $i > $i).
% 29.32/29.13  tff(decl_69418, type, fn_shewanella_oneidensis_39: $i > $i).
% 29.32/29.13  tff(decl_69419, type, fn_shewanella_oneidensis_40: $i > $i).
% 29.32/29.13  tff(decl_69420, type, metal_atom_0: $i).
% 29.32/29.13  tff(decl_69421, type, non_metal_atom_0: $i).
% 29.32/29.13  tff(decl_69422, type, fn_shewanella_oneidensis_23: $i > $i).
% 29.32/29.13  tff(decl_69423, type, fn_shewanella_oneidensis_22: $i > $i).
% 29.32/29.13  tff(decl_69424, type, fn_shewanella_oneidensis_24: $i > $i).
% 29.32/29.13  tff(decl_69425, type, fn_shewanella_oneidensis_21: $i > $i).
% 29.32/29.13  tff(decl_69426, type, fn_shewanella_oneidensis_30: $i > $i).
% 29.32/29.13  tff(decl_69427, type, fn_shewanella_oneidensis_20: $i > $i).
% 29.32/29.13  tff(decl_69428, type, fn_shewanella_oneidensis_11: $i > $i).
% 29.32/29.13  tff(decl_69429, type, fn_shewanella_oneidensis_10: $i > $i).
% 29.32/29.13  tff(decl_69430, type, fn_shewanella_oneidensis_9: $i > $i).
% 29.32/29.13  tff(decl_69431, type, fn_shewanella_oneidensis_8: $i > $i).
% 29.32/29.13  tff(decl_69432, type, shipping_1: $i > $o).
% 29.32/29.13  tff(decl_69433, type, 'Shipping': $i).
% 29.32/29.13  tff(decl_69434, type, transportation: $i).
% 29.32/29.13  tff(decl_69435, type, shipping: $i).
% 29.32/29.13  tff(decl_69436, type, ship: $i).
% 29.32/29.13  tff(decl_69437, type, shivering_1: $i > $o).
% 29.32/29.13  tff(decl_69438, type, 'Shivering': $i).
% 29.32/29.13  tff(decl_69439, type, 'Shivering is an involuntary shaking of the body in response to hypothermia.': $i).
% 29.32/29.13  tff(decl_69440, type, shiver: $i).
% 29.32/29.13  tff(decl_69441, type, shivering: $i).
% 29.32/29.13  tff(decl_69442, type, fn_shivering_1: $i > $i).
% 29.32/29.13  tff(decl_69443, type, fn_shivering_2: $i > $i).
% 29.32/29.13  tff(decl_69444, type, fn_shivering_3: $i > $i).
% 29.32/29.13  tff(decl_69445, type, fn_shivering_4: $i > $i).
% 29.32/29.13  tff(decl_69446, type, fn_shivering_5: $i > $i).
% 29.32/29.13  tff(decl_69447, type, muscle_contraction_0: $i).
% 29.32/29.13  tff(decl_69448, type, 'Shmoo': $i).
% 29.32/29.13  tff(decl_69449, type, 'Name given to the cellular bulge that results from the response to mating factor in mating yeast, after its resemblance to the cartoon character of the same name.': $i).
% 29.32/29.13  tff(decl_69450, type, shmoo: $i).
% 29.32/29.13  tff(decl_69451, type, fn_shmoo_1: $i > $i).
% 29.32/29.13  tff(decl_69452, type, 'Shmoo-Formation': $i).
% 29.32/29.13  tff(decl_69453, type, 'The process of formation of a cellular bulge (shmoo) in yeast as a response to the mating factor signals generated by the opposite mating type.': $i).
% 29.32/29.13  tff(decl_69454, type, 'formation of shmoo': $i).
% 29.32/29.13  tff(decl_69455, type, 'shmoo formation': $i).
% 29.32/29.13  tff(decl_69456, type, 'shmoo-formation': $i).
% 29.32/29.13  tff(decl_69457, type, fn_shmoo_formation_3: $i > $i).
% 29.32/29.13  tff(decl_69458, type, 'Shmoo-Fusion': $i).
% 29.32/29.13  tff(decl_69459, type, 'The fusion of the specialized form of yeast cells, called shmoos, which result from the formation of bulges in the yeast cell as a response to signaling with yeast mating factors.  Shmoo fusion occurs during the mating of yeast cells.': $i).
% 29.32/29.13  tff(decl_69460, type, 'yeast mating': $i).
% 29.32/29.13  tff(decl_69461, type, 'fusion of shmoo': $i).
% 29.32/29.13  tff(decl_69462, type, 'shmoo fusion': $i).
% 29.32/29.13  tff(decl_69463, type, 'shmoo-fusion': $i).
% 29.32/29.13  tff(decl_69464, type, 'Shoot': $i).
% 29.32/29.13  tff(decl_69465, type, 'Shoots are new plant growth, they can include stems, flowering stems with flower buds, and leaves.': $i).
% 29.32/29.13  tff(decl_69466, type, shoot: $i).
% 29.32/29.13  tff(decl_69467, type, 'Shoot-Apical-Meristem': $i).
% 29.32/29.13  tff(decl_69468, type, 'Embryonic plant tissue in the tips of shoot is called as shoot apical meristem. The dividing cells of an apical meristem enable the plant to grow in length.': $i).
% 29.32/29.13  tff(decl_69469, type, 'shoot apical meristem': $i).
% 29.32/29.13  tff(decl_69470, type, 'shoot-apical-meristem': $i).
% 29.32/29.13  tff(decl_69471, type, fn_shoot_apical_meristem_1: $i > $i).
% 29.32/29.13  tff(decl_69472, type, fn_shoot_apical_meristem_3: $i > $i).
% 29.32/29.13  tff(decl_69473, type, 'Shoot-System': $i).
% 29.32/29.13  tff(decl_69474, type, 'In plants, organs such as leaves, stems, and flowers, which usually occur above ground.': $i).
% 29.32/29.13  tff(decl_69475, type, 'system of shoot': $i).
% 29.32/29.13  tff(decl_69476, type, 'shoot system': $i).
% 29.32/29.13  tff(decl_69477, type, 'shoot-system': $i).
% 29.32/29.13  tff(decl_69478, type, 'Shore': $i).
% 29.32/29.13  tff(decl_69479, type, 'Region of land along the edge of an aquatic biome.': $i).
% 29.32/29.13  tff(decl_69480, type, shore: $i).
% 29.32/29.13  tff(decl_69481, type, short_day_plant_1: $i > $o).
% 29.32/29.13  tff(decl_69482, type, 'Short-Day-Plant': $i).
% 29.32/29.13  tff(decl_69483, type, 'A plant that requires a long period of darkness for flowering. Short day plants typically bloom in late summer, fall, or winter.': $i).
% 29.32/29.13  tff(decl_69484, type, 'short day plant': $i).
% 29.32/29.13  tff(decl_69485, type, 'short-day plant': $i).
% 29.32/29.13  tff(decl_69486, type, 'short-day-plant': $i).
% 29.32/29.13  tff(decl_69487, type, 'Short-Tandem-Repeat': $i).
% 29.32/29.13  tff(decl_69488, type, 'Repeating sequences of 2-6 nucleotides in DNA. Variation in the number of short tandem repeats (STRs) act as genetic markers and can be used to create genetic profiles of individuals.': $i).
% 29.32/29.13  tff(decl_69489, type, 'short tandem repeat': $i).
% 29.32/29.13  tff(decl_69490, type, 'short-tandem-repeat': $i).
% 29.32/29.13  tff(decl_69491, type, fn_short_tandem_repeat_1: $i > $i).
% 29.32/29.13  tff(decl_69492, type, fn_short_tandem_repeat_2: $i > $i).
% 29.32/29.13  tff(decl_69493, type, fn_short_tandem_repeat_3: $i > $i).
% 29.32/29.13  tff(decl_69494, type, fn_short_tandem_repeat_4: $i > $i).
% 29.32/29.13  tff(decl_69495, type, fn_short_tandem_repeat_5: $i > $i).
% 29.32/29.13  tff(decl_69496, type, 'Short-Term-Memory': $i).
% 29.32/29.13  tff(decl_69497, type, 'The ability to hold a small amount of information in one\\s mind in an active, readily accessible state for a short period of time, then release it when it becomes irrelevant.': $i).
% 29.32/29.13  tff(decl_69498, type, 'short term memory': $i).
% 29.32/29.13  tff(decl_69499, type, 'short-term-memory': $i).
% 29.32/29.13  tff(decl_69500, type, 'Shotgun-Sequencing': $i).
% 29.32/29.13  tff(decl_69501, type, 'A method for sequencing long strands of DNA.': $i).
% 29.32/29.13  tff(decl_69502, type, 'shotgun sequencing': $i).
% 29.32/29.13  tff(decl_69503, type, 'shotgun-sequencing': $i).
% 29.32/29.13  tff(decl_69504, type, shut_out_1: $i > $o).
% 29.32/29.13  tff(decl_69505, type, 'Shut-Out': $i).
% 29.32/29.13  tff(decl_69506, type, 'shut out': $i).
% 29.32/29.13  tff(decl_69507, type, shut_out: $i).
% 29.32/29.13  tff(decl_69508, type, exclude: $i).
% 29.32/29.13  tff(decl_69509, type, 'keep out': $i).
% 29.32/29.13  tff(decl_69510, type, keep_out: $i).
% 29.32/29.13  tff(decl_69511, type, 'shut-out': $i).
% 29.32/29.13  tff(decl_69512, type, fn_shut_out_1: $i > $i).
% 29.32/29.13  tff(decl_69513, type, fn_shut_out_2: $i > $i).
% 29.32/29.13  tff(decl_69514, type, fn_shut_out_3: $i > $i).
% 29.32/29.13  tff(decl_69515, type, sickle_cell_1: $i > $o).
% 29.32/29.13  tff(decl_69516, type, 'Sickle-Cell': $i).
% 29.32/29.13  tff(decl_69517, type, 'A red blood cell that has a sickle shape due to an abnormal form of hemoglobin (HbS).': $i).
% 29.32/29.13  tff(decl_69518, type, 'cell of sickle': $i).
% 29.32/29.13  tff(decl_69519, type, 'sickle cell': $i).
% 29.32/29.13  tff(decl_69520, type, 'sickle-cell': $i).
% 29.32/29.13  tff(decl_69521, type, fn_sickle_cell_1: $i > $i).
% 29.32/29.13  tff(decl_69522, type, fn_sickle_cell_2: $i > $i).
% 29.32/29.13  tff(decl_69523, type, fn_sickle_cell_3: $i > $i).
% 29.32/29.13  tff(decl_69524, type, fn_sickle_cell_4: $i > $i).
% 29.32/29.13  tff(decl_69525, type, fn_sickle_cell_5: $i > $i).
% 29.32/29.13  tff(decl_69526, type, fn_sickle_cell_6: $i > $i).
% 29.32/29.13  tff(decl_69527, type, fn_sickle_cell_7: $i > $i).
% 29.32/29.13  tff(decl_69528, type, fn_sickle_cell_8: $i > $i).
% 29.32/29.13  tff(decl_69529, type, fn_sickle_cell_9: $i > $i).
% 29.32/29.13  tff(decl_69530, type, fn_sickle_cell_10: $i > $i).
% 29.32/29.13  tff(decl_69531, type, fn_sickle_cell_11: $i > $i).
% 29.32/29.13  tff(decl_69532, type, fn_sickle_cell_12: $i > $i).
% 29.32/29.13  tff(decl_69533, type, fn_sickle_cell_13: $i > $i).
% 29.32/29.13  tff(decl_69534, type, fn_sickle_cell_14: $i > $i).
% 29.32/29.13  tff(decl_69535, type, fn_sickle_cell_15: $i > $i).
% 29.32/29.13  tff(decl_69536, type, fn_sickle_cell_16: $i > $i).
% 29.32/29.13  tff(decl_69537, type, fn_sickle_cell_17: $i > $i).
% 29.32/29.13  tff(decl_69538, type, fn_sickle_cell_18: $i > $i).
% 29.32/29.13  tff(decl_69539, type, fn_sickle_cell_19: $i > $i).
% 29.32/29.13  tff(decl_69540, type, fn_sickle_cell_20: $i > $i).
% 29.32/29.13  tff(decl_69541, type, fn_sickle_cell_21: $i > $i).
% 29.32/29.13  tff(decl_69542, type, fn_sickle_cell_22: $i > $i).
% 29.32/29.13  tff(decl_69543, type, fn_sickle_cell_23: $i > $i).
% 29.32/29.13  tff(decl_69544, type, fn_sickle_cell_24: $i > $i).
% 29.32/29.13  tff(decl_69545, type, fn_sickle_cell_25: $i > $i).
% 29.32/29.13  tff(decl_69546, type, fn_sickle_cell_26: $i > $i).
% 29.32/29.13  tff(decl_69547, type, fn_sickle_cell_27: $i > $i).
% 29.32/29.13  tff(decl_69548, type, fn_sickle_cell_28: $i > $i).
% 29.32/29.13  tff(decl_69549, type, fn_sickle_cell_29: $i > $i).
% 29.32/29.13  tff(decl_69550, type, fn_sickle_cell_30: $i > $i).
% 29.32/29.13  tff(decl_69551, type, fn_sickle_cell_31: $i > $i).
% 29.32/29.13  tff(decl_69552, type, fn_sickle_cell_32: $i > $i).
% 29.32/29.13  tff(decl_69553, type, fn_sickle_cell_33: $i > $i).
% 29.32/29.13  tff(decl_69554, type, fn_sickle_cell_34: $i > $i).
% 29.32/29.13  tff(decl_69555, type, fn_sickle_cell_37: $i > $i).
% 29.32/29.13  tff(decl_69556, type, fn_sickle_cell_38: $i > $i).
% 29.32/29.13  tff(decl_69557, type, fn_sickle_cell_35: $i > $i).
% 29.32/29.13  tff(decl_69558, type, fn_sickle_cell_36: $i > $i).
% 29.32/29.13  tff(decl_69559, type, 'Sickle-Cell-Anemia': $i).
% 29.32/29.13  tff(decl_69560, type, 'an autosomal recessive genetic blood disorder characterized by red blood cells that assume an abnormal, rigid, sickle shape.': $i).
% 29.32/29.13  tff(decl_69561, type, 'sickle cell anemia': $i).
% 29.32/29.13  tff(decl_69562, type, 'sickle-cell anemia': $i).
% 29.32/29.13  tff(decl_69563, type, 'sickle-cell-anemia': $i).
% 29.32/29.13  tff(decl_69564, type, fn_sickle_cell_anemia_1: $i > $i).
% 29.32/29.13  tff(decl_69565, type, fn_sickle_cell_anemia_2: $i > $i).
% 29.32/29.13  tff(decl_69566, type, fn_sickle_cell_anemia_3: $i > $i).
% 29.32/29.13  tff(decl_69567, type, fn_sickle_cell_anemia_4: $i > $i).
% 29.32/29.13  tff(decl_69568, type, fn_sickle_cell_anemia_5: $i > $i).
% 29.32/29.13  tff(decl_69569, type, fn_sickle_cell_anemia_6: $i > $i).
% 29.32/29.13  tff(decl_69570, type, fn_sickle_cell_anemia_7: $i > $i).
% 29.32/29.13  tff(decl_69571, type, fn_sickle_cell_anemia_8: $i > $i).
% 29.32/29.13  tff(decl_69572, type, fn_sickle_cell_anemia_9: $i > $i).
% 29.32/29.13  tff(decl_69573, type, fn_sickle_cell_anemia_10: $i > $i).
% 29.32/29.13  tff(decl_69574, type, fn_sickle_cell_anemia_11: $i > $i).
% 29.32/29.13  tff(decl_69575, type, 'Sieve-Plate': $i).
% 29.32/29.13  tff(decl_69576, type, 'An end wall in a sieve-tube element, which facilitates the flow of phloem sap in angiosperm sieve tubes.': $i).
% 29.32/29.13  tff(decl_69577, type, 'plate of sieve': $i).
% 29.32/29.13  tff(decl_69578, type, 'sieve plate': $i).
% 29.32/29.13  tff(decl_69579, type, 'sieve-plate': $i).
% 29.32/29.13  tff(decl_69580, type, fn_sieve_plate_1: $i > $i).
% 29.32/29.13  tff(decl_69581, type, 'Sieve-Tube': $i).
% 29.32/29.13  tff(decl_69582, type, 'Sieve tube is formed by chain of sieve tube element': $i).
% 29.32/29.13  tff(decl_69583, type, 'tube of sieve': $i).
% 29.32/29.13  tff(decl_69584, type, 'sieve tube': $i).
% 29.32/29.13  tff(decl_69585, type, 'sieve-tube': $i).
% 29.32/29.13  tff(decl_69586, type, fn_sieve_tube_1: $i > $i).
% 29.32/29.13  tff(decl_69587, type, fn_sieve_tube_2: $i > $i).
% 29.32/29.13  tff(decl_69588, type, fn_sieve_tube_3: $i > $i).
% 29.32/29.13  tff(decl_69589, type, fn_sieve_tube_4: $i > $i).
% 29.32/29.13  tff(decl_69590, type, fn_sieve_tube_5: $i > $i).
% 29.32/29.13  tff(decl_69591, type, fn_sieve_tube_6: $i > $i).
% 29.32/29.13  tff(decl_69592, type, fn_sieve_tube_8: $i > $i).
% 29.32/29.13  tff(decl_69593, type, fn_sieve_tube_9: $i > $i).
% 29.32/29.13  tff(decl_69594, type, fn_sieve_tube_10: $i > $i).
% 29.32/29.13  tff(decl_69595, type, fn_sieve_tube_11: $i > $i).
% 29.32/29.13  tff(decl_69596, type, fn_sieve_tube_12: $i > $i).
% 29.32/29.13  tff(decl_69597, type, fn_sieve_tube_13: $i > $i).
% 29.32/29.13  tff(decl_69598, type, fn_sieve_tube_14: $i > $i).
% 29.32/29.13  tff(decl_69599, type, 'Sieve-Tube-Element': $i).
% 29.32/29.13  tff(decl_69600, type, 'In plants, a living cell found in the phloem and functioning in the transport of sugars. The ends of sieve tube elements are connected to other sieve tube elements to make up the sieve tube.': $i).
% 29.32/29.13  tff(decl_69601, type, 'sugar conducting cell': $i).
% 29.32/29.13  tff(decl_69602, type, 'sieve cell': $i).
% 29.32/29.13  tff(decl_69603, type, 'sieve tube member': $i).
% 29.32/29.13  tff(decl_69604, type, 'sieve tube element': $i).
% 29.32/29.13  tff(decl_69605, type, 'sieve-tube element': $i).
% 29.32/29.13  tff(decl_69606, type, 'sieve-tube-element': $i).
% 29.32/29.13  tff(decl_69607, type, fn_sieve_tube_element_1: $i > $i).
% 29.32/29.13  tff(decl_69608, type, fn_sieve_tube_element_2: $i > $i).
% 29.32/29.13  tff(decl_69609, type, plant_transport_cell_0: $i).
% 29.32/29.13  tff(decl_69610, type, 'Sight': $i).
% 29.32/29.13  tff(decl_69611, type, 'The ability to receive and interpret the information contained in visible light.': $i).
% 29.32/29.13  tff(decl_69612, type, sight: $i).
% 29.32/29.13  tff(decl_69613, type, sign_stimulus_1: $i > $o).
% 29.32/29.13  tff(decl_69614, type, 'Sign-Stimulus': $i).
% 29.32/29.13  tff(decl_69615, type, 'An external sensory stimulus that causes a fixed action pattern in an animal.': $i).
% 29.32/29.13  tff(decl_69616, type, 'stimulus of sign': $i).
% 29.32/29.13  tff(decl_69617, type, 'sign stimulus': $i).
% 29.32/29.13  tff(decl_69618, type, 'sign-stimulus': $i).
% 29.32/29.13  tff(decl_69619, type, 'Signal': $i).
% 29.32/29.13  tff(decl_69620, type, 'Message or instructions carried by a molecule or electrical pulse.': $i).
% 29.32/29.13  tff(decl_69621, type, signaling: $i).
% 29.32/29.13  tff(decl_69622, type, 'Signal-Amplification': $i).
% 29.32/29.13  tff(decl_69623, type, 'The strengthening of stimulus energy during transduction.': $i).
% 29.32/29.13  tff(decl_69624, type, 'amplification of signal': $i).
% 29.32/29.13  tff(decl_69625, type, 'signal amplification': $i).
% 29.32/29.13  tff(decl_69626, type, 'signal-amplification': $i).
% 29.32/29.13  tff(decl_69627, type, fn_signal_amplification_1: $i > $i).
% 29.32/29.13  tff(decl_69628, type, fn_signal_amplification_2: $i > $i).
% 29.32/29.13  tff(decl_69629, type, fn_signal_amplification_3: $i > $i).
% 29.32/29.13  tff(decl_69630, type, fn_signal_amplification_6: $i > $i).
% 29.32/29.13  tff(decl_69631, type, 'Signal-Generation': $i).
% 29.32/29.13  tff(decl_69632, type, 'The production of a signal by a signaling cell during the process of cellular communication.': $i).
% 29.32/29.13  tff(decl_69633, type, transduction: $i).
% 29.32/29.13  tff(decl_69634, type, 'signal transduction': $i).
% 29.32/29.13  tff(decl_69635, type, 'generation of signal': $i).
% 29.32/29.13  tff(decl_69636, type, 'signal generation': $i).
% 29.32/29.13  tff(decl_69637, type, 'signal-generation': $i).
% 29.32/29.13  tff(decl_69638, type, fn_signal_generation_3: $i > $i).
% 29.32/29.13  tff(decl_69639, type, 'Signal-Peptide': $i).
% 29.32/29.13  tff(decl_69640, type, 'A short sequence of amino acids at the amino end of a newly synthesized polypeptide that directs it to the endoplasmic reticulum or another organelle.': $i).
% 29.32/29.13  tff(decl_69641, type, 'peptide of signal': $i).
% 29.32/29.13  tff(decl_69642, type, 'signal peptide': $i).
% 29.32/29.13  tff(decl_69643, type, 'signal-peptide': $i).
% 29.32/29.13  tff(decl_69644, type, 'Signal-Reception': $i).
% 29.32/29.13  tff(decl_69645, type, 'The target cell\\s detection of a signaling molecule coming from outside the cell.': $i).
% 29.32/29.13  tff(decl_69646, type, 'chemical signal reception': $i).
% 29.32/29.13  tff(decl_69647, type, 'signal detection': $i).
% 29.32/29.13  tff(decl_69648, type, 'carry a signal': $i).
% 29.32/29.13  tff(decl_69649, type, 'receive a signal': $i).
% 29.32/29.13  tff(decl_69650, type, 'reception of signal': $i).
% 29.32/29.13  tff(decl_69651, type, 'signal reception': $i).
% 29.32/29.13  tff(decl_69652, type, 'signal-reception': $i).
% 29.32/29.13  tff(decl_69653, type, fn_signal_reception_2: $i > $i).
% 29.32/29.13  tff(decl_69654, type, 'Signal-Reception-With-Testosterone': $i).
% 29.32/29.13  tff(decl_69655, type, 'The process of signal reception in which the signal molecule is testosterone.': $i).
% 29.32/29.13  tff(decl_69656, type, 'signal reception with testosterone': $i).
% 29.32/29.13  tff(decl_69657, type, 'signal-reception-with-testosterone': $i).
% 29.32/29.13  tff(decl_69658, type, fn_signal_reception_with_testosterone_2: $i > $i).
% 29.32/29.13  tff(decl_69659, type, fn_signal_reception_with_testosterone_14: $i > $i).
% 29.32/29.13  tff(decl_69660, type, fn_signal_reception_with_testosterone_15: $i > $i).
% 29.32/29.13  tff(decl_69661, type, fn_signal_reception_with_testosterone_16: $i > $i).
% 29.32/29.13  tff(decl_69662, type, fn_signal_reception_with_testosterone_17: $i > $i).
% 29.32/29.13  tff(decl_69663, type, fn_signal_reception_with_testosterone_18: $i > $i).
% 29.32/29.13  tff(decl_69664, type, fn_signal_reception_with_testosterone_19: $i > $i).
% 29.32/29.13  tff(decl_69665, type, fn_signal_reception_with_testosterone_20: $i > $i).
% 29.32/29.13  tff(decl_69666, type, fn_signal_reception_with_testosterone_21: $i > $i).
% 29.32/29.13  tff(decl_69667, type, fn_signal_reception_with_testosterone_22: $i > $i).
% 29.32/29.13  tff(decl_69668, type, fn_signal_reception_with_testosterone_24: $i > $i).
% 29.32/29.13  tff(decl_69669, type, fn_signal_reception_with_testosterone_25: $i > $i).
% 29.32/29.13  tff(decl_69670, type, fn_signal_reception_with_testosterone_26: $i > $i).
% 29.32/29.13  tff(decl_69671, type, fn_signal_reception_with_testosterone_6: $i > $i).
% 29.32/29.13  tff(decl_69672, type, fn_signal_reception_with_testosterone_5: $i > $i).
% 29.32/29.13  tff(decl_69673, type, fn_signal_reception_with_testosterone_4: $i > $i).
% 29.32/29.13  tff(decl_69674, type, 'Signal-Recognition-Particle': $i).
% 29.32/29.13  tff(decl_69675, type, 'A complex of protein and RNA that recognizes a signal peptide as it comes out of a ribosome and guides the ribosome to the endoplasmic reticulum by binding to a specific receptor on the ER.': $i).
% 29.32/29.13  tff(decl_69676, type, 'signal recognition particle': $i).
% 29.32/29.13  tff(decl_69677, type, 'signal-recognition particle': $i).
% 29.32/29.13  tff(decl_69678, type, 'signal-recognition-particle': $i).
% 29.32/29.13  tff(decl_69679, type, 'Signal-Transduction': $i).
% 29.32/29.13  tff(decl_69680, type, 'The process in which an extracellular signal activates a cell surface receptor, which then causes an intracellular response.': $i).
% 29.32/29.13  tff(decl_69681, type, 'signaling pathway': $i).
% 29.32/29.13  tff(decl_69682, type, 'signalling pathway': $i).
% 29.32/29.13  tff(decl_69683, type, 'transduction cell signalling': $i).
% 29.32/29.13  tff(decl_69684, type, 'relay a signal': $i).
% 29.32/29.13  tff(decl_69685, type, 'transduction of signal': $i).
% 29.32/29.13  tff(decl_69686, type, 'signal-transduction': $i).
% 29.32/29.13  tff(decl_69687, type, 'Signal-Transduction-With-Ca2-Plus': $i).
% 29.32/29.13  tff(decl_69688, type, 'A signal transduction pathway in which calcium ions act as second messengers.': $i).
% 29.32/29.13  tff(decl_69689, type, 'signal transduction with ca2 plus': $i).
% 29.32/29.13  tff(decl_69690, type, 'signal-transduction-with-ca2-plus': $i).
% 29.32/29.13  tff(decl_69691, type, signal_transduction_with_second_messenger_1: $i > $o).
% 29.32/29.13  tff(decl_69692, type, fn_signal_transduction_with_ca2_plus_1: $i > $i).
% 29.32/29.13  tff(decl_69693, type, fn_signal_transduction_with_second_messenger_2: $i > $i).
% 29.32/29.13  tff(decl_69694, type, 'Signal-Transduction-With-Calmodulin': $i).
% 29.32/29.13  tff(decl_69695, type, 'Pathway of signal transduction in which calcium ions bind to calmodulin protein, resulting in enzyme activation.': $i).
% 29.32/29.13  tff(decl_69696, type, 'signal transduction with calmodulin': $i).
% 29.32/29.13  tff(decl_69697, type, 'signal-transduction-with-calmodulin': $i).
% 29.32/29.13  tff(decl_69698, type, signal_transduction_with_ip3_1: $i > $o).
% 29.32/29.13  tff(decl_69699, type, 'Signal-Transduction-With-IP3': $i).
% 29.32/29.13  tff(decl_69700, type, 'Signal transduction event of cell signaling which involves IP3 as a second messenger.': $i).
% 29.32/29.13  tff(decl_69701, type, 'signal transduction with ip3': $i).
% 29.32/29.13  tff(decl_69702, type, 'signal-transduction-with-ip3': $i).
% 29.32/29.13  tff(decl_69703, type, fn_signal_transduction_with_ip3_1: $i > $i).
% 29.32/29.13  tff(decl_69704, type, fn_signal_transduction_with_ip3_2: $i > $i).
% 29.32/29.13  tff(decl_69705, type, fn_signal_transduction_with_ip3_3: $i > $i).
% 29.32/29.13  tff(decl_69706, type, fn_signal_transduction_with_ip3_4: $i > $i).
% 29.32/29.13  tff(decl_69707, type, fn_signal_transduction_with_ip3_5: $i > $i).
% 29.32/29.13  tff(decl_69708, type, fn_signal_transduction_with_ip3_8: $i > $i).
% 29.32/29.13  tff(decl_69709, type, fn_signal_transduction_with_ip3_9: $i > $i).
% 29.32/29.13  tff(decl_69710, type, fn_signal_transduction_with_ip3_10: $i > $i).
% 29.32/29.13  tff(decl_69711, type, fn_signal_transduction_with_ip3_11: $i > $i).
% 29.32/29.13  tff(decl_69712, type, fn_signal_transduction_with_ip3_12: $i > $i).
% 29.32/29.13  tff(decl_69713, type, fn_signal_transduction_with_ip3_13: $i > $i).
% 29.32/29.13  tff(decl_69714, type, fn_signal_transduction_with_ip3_14: $i > $i).
% 29.32/29.13  tff(decl_69715, type, fn_signal_transduction_with_ip3_15: $i > $i).
% 29.32/29.13  tff(decl_69716, type, fn_signal_transduction_with_ip3_16: $i > $i).
% 29.32/29.13  tff(decl_69717, type, fn_signal_transduction_with_ip3_17: $i > $i).
% 29.32/29.13  tff(decl_69718, type, fn_signal_transduction_with_ip3_18: $i > $i).
% 29.32/29.13  tff(decl_69719, type, fn_signal_transduction_with_ip3_19: $i > $i).
% 29.32/29.13  tff(decl_69720, type, 'Signal-Transduction-With-Phosphorylation-Cascade': $i).
% 29.32/29.13  tff(decl_69721, type, 'The process of signal transduction which involves a series of phosphorylation reactions.': $i).
% 29.32/29.13  tff(decl_69722, type, 'signal transduction with phosphorylation cascade': $i).
% 29.32/29.13  tff(decl_69723, type, 'signal-transduction-with-phosphorylation-cascade': $i).
% 29.32/29.13  tff(decl_69724, type, fn_signal_transduction_with_phosphorylation_cascade_8: $i > $i).
% 29.32/29.13  tff(decl_69725, type, fn_signal_transduction_with_phosphorylation_cascade_9: $i > $i).
% 29.32/29.13  tff(decl_69726, type, fn_signal_transduction_with_phosphorylation_cascade_10: $i > $i).
% 29.32/29.13  tff(decl_69727, type, fn_signal_transduction_with_phosphorylation_cascade_12: $i > $i).
% 29.32/29.13  tff(decl_69728, type, fn_signal_transduction_with_phosphorylation_cascade_13: $i > $i).
% 29.32/29.13  tff(decl_69729, type, fn_signal_transduction_with_phosphorylation_cascade_14: $i > $i).
% 29.32/29.13  tff(decl_69730, type, fn_signal_transduction_with_phosphorylation_cascade_15: $i > $i).
% 29.32/29.13  tff(decl_69731, type, fn_signal_transduction_with_phosphorylation_cascade_17: $i > $i).
% 29.32/29.13  tff(decl_69732, type, fn_signal_transduction_with_phosphorylation_cascade_18: $i > $i).
% 29.32/29.13  tff(decl_69733, type, fn_signal_transduction_with_phosphorylation_cascade_19: $i > $i).
% 29.32/29.13  tff(decl_69734, type, fn_signal_transduction_with_phosphorylation_cascade_20: $i > $i).
% 29.32/29.13  tff(decl_69735, type, fn_signal_transduction_with_phosphorylation_cascade_22: $i > $i).
% 29.32/29.13  tff(decl_69736, type, fn_signal_transduction_with_phosphorylation_cascade_23: $i > $i).
% 29.32/29.13  tff(decl_69737, type, fn_signal_transduction_with_phosphorylation_cascade_24: $i > $i).
% 29.32/29.13  tff(decl_69738, type, fn_signal_transduction_with_phosphorylation_cascade_25: $i > $i).
% 29.32/29.13  tff(decl_69739, type, fn_signal_transduction_with_phosphorylation_cascade_26: $i > $i).
% 29.32/29.13  tff(decl_69740, type, fn_signal_transduction_with_phosphorylation_cascade_27: $i > $i).
% 29.32/29.13  tff(decl_69741, type, fn_signal_transduction_with_phosphorylation_cascade_40: $i > $i).
% 29.32/29.13  tff(decl_69742, type, fn_signal_transduction_with_phosphorylation_cascade_41: $i > $i).
% 29.32/29.13  tff(decl_69743, type, fn_signal_transduction_with_phosphorylation_cascade_42: $i > $i).
% 29.32/29.13  tff(decl_69744, type, fn_signal_transduction_with_phosphorylation_cascade_45: $i > $i).
% 29.32/29.13  tff(decl_69745, type, fn_signal_transduction_with_phosphorylation_cascade_48: $i > $i).
% 29.32/29.13  tff(decl_69746, type, fn_signal_transduction_with_phosphorylation_cascade_50: $i > $i).
% 29.32/29.13  tff(decl_69747, type, fn_signal_transduction_with_phosphorylation_cascade_51: $i > $i).
% 29.32/29.13  tff(decl_69748, type, fn_signal_transduction_with_phosphorylation_cascade_56: $i > $i).
% 29.32/29.13  tff(decl_69749, type, fn_signal_transduction_with_phosphorylation_cascade_57: $i > $i).
% 29.32/29.13  tff(decl_69750, type, fn_signal_transduction_with_phosphorylation_cascade_58: $i > $i).
% 29.32/29.13  tff(decl_69751, type, fn_signal_transduction_with_phosphorylation_cascade_59: $i > $i).
% 29.32/29.13  tff(decl_69752, type, fn_signal_transduction_with_phosphorylation_cascade_60: $i > $i).
% 29.32/29.13  tff(decl_69753, type, fn_signal_transduction_with_phosphorylation_cascade_61: $i > $i).
% 29.32/29.13  tff(decl_69754, type, fn_signal_transduction_with_phosphorylation_cascade_65: $i > $i).
% 29.32/29.13  tff(decl_69755, type, fn_signal_transduction_with_phosphorylation_cascade_66: $i > $i).
% 29.32/29.13  tff(decl_69756, type, fn_signal_transduction_with_phosphorylation_cascade_71: $i > $i).
% 29.32/29.13  tff(decl_69757, type, fn_signal_transduction_with_phosphorylation_cascade_72: $i > $i).
% 29.32/29.13  tff(decl_69758, type, fn_signal_transduction_with_phosphorylation_cascade_73: $i > $i).
% 29.32/29.13  tff(decl_69759, type, fn_signal_transduction_with_phosphorylation_cascade_74: $i > $i).
% 29.32/29.13  tff(decl_69760, type, fn_signal_transduction_with_phosphorylation_cascade_75: $i > $i).
% 29.32/29.13  tff(decl_69761, type, fn_signal_transduction_with_phosphorylation_cascade_76: $i > $i).
% 29.32/29.13  tff(decl_69762, type, fn_signal_transduction_with_phosphorylation_cascade_78: $i > $i).
% 29.32/29.13  tff(decl_69763, type, fn_signal_transduction_with_phosphorylation_cascade_79: $i > $i).
% 29.32/29.13  tff(decl_69764, type, fn_signal_transduction_with_phosphorylation_cascade_80: $i > $i).
% 29.32/29.13  tff(decl_69765, type, fn_signal_transduction_with_phosphorylation_cascade_81: $i > $i).
% 29.32/29.13  tff(decl_69766, type, fn_signal_transduction_with_phosphorylation_cascade_82: $i > $i).
% 29.32/29.13  tff(decl_69767, type, fn_signal_transduction_with_phosphorylation_cascade_84: $i > $i).
% 29.32/29.13  tff(decl_69768, type, fn_signal_transduction_with_phosphorylation_cascade_85: $i > $i).
% 29.32/29.13  tff(decl_69769, type, fn_signal_transduction_with_phosphorylation_cascade_86: $i > $i).
% 29.32/29.13  tff(decl_69770, type, fn_signal_transduction_with_phosphorylation_cascade_87: $i > $i).
% 29.32/29.13  tff(decl_69771, type, fn_signal_transduction_with_phosphorylation_cascade_88: $i > $i).
% 29.32/29.13  tff(decl_69772, type, fn_signal_transduction_with_phosphorylation_cascade_89: $i > $i).
% 29.32/29.13  tff(decl_69773, type, fn_signal_transduction_with_phosphorylation_cascade_91: $i > $i).
% 29.32/29.13  tff(decl_69774, type, fn_signal_transduction_with_phosphorylation_cascade_92: $i > $i).
% 29.32/29.13  tff(decl_69775, type, fn_signal_transduction_with_phosphorylation_cascade_93: $i > $i).
% 29.32/29.13  tff(decl_69776, type, fn_signal_transduction_with_phosphorylation_cascade_94: $i > $i).
% 29.32/29.13  tff(decl_69777, type, fn_signal_transduction_with_phosphorylation_cascade_95: $i > $i).
% 29.32/29.13  tff(decl_69778, type, fn_signal_transduction_with_phosphorylation_cascade_99: $i > $i).
% 29.32/29.13  tff(decl_69779, type, fn_signal_transduction_with_phosphorylation_cascade_100: $i > $i).
% 29.32/29.13  tff(decl_69780, type, fn_signal_transduction_with_phosphorylation_cascade_101: $i > $i).
% 29.32/29.13  tff(decl_69781, type, fn_signal_transduction_with_phosphorylation_cascade_102: $i > $i).
% 29.32/29.13  tff(decl_69782, type, fn_signal_transduction_with_phosphorylation_cascade_109: $i > $i).
% 29.32/29.13  tff(decl_69783, type, fn_signal_transduction_with_phosphorylation_cascade_110: $i > $i).
% 29.32/29.13  tff(decl_69784, type, fn_signal_transduction_with_phosphorylation_cascade_111: $i > $i).
% 29.32/29.13  tff(decl_69785, type, fn_signal_transduction_with_phosphorylation_cascade_112: $i > $i).
% 29.32/29.13  tff(decl_69786, type, fn_signal_transduction_with_phosphorylation_cascade_113: $i > $i).
% 29.32/29.13  tff(decl_69787, type, fn_signal_transduction_with_phosphorylation_cascade_114: $i > $i).
% 29.32/29.13  tff(decl_69788, type, fn_signal_transduction_with_phosphorylation_cascade_116: $i > $i).
% 29.32/29.13  tff(decl_69789, type, fn_signal_transduction_with_phosphorylation_cascade_117: $i > $i).
% 29.32/29.13  tff(decl_69790, type, fn_signal_transduction_with_phosphorylation_cascade_118: $i > $i).
% 29.32/29.13  tff(decl_69791, type, fn_signal_transduction_with_phosphorylation_cascade_119: $i > $i).
% 29.32/29.13  tff(decl_69792, type, fn_signal_transduction_with_phosphorylation_cascade_122: $i > $i).
% 29.32/29.13  tff(decl_69793, type, fn_signal_transduction_with_phosphorylation_cascade_123: $i > $i).
% 29.32/29.13  tff(decl_69794, type, fn_signal_transduction_with_phosphorylation_cascade_124: $i > $i).
% 29.32/29.13  tff(decl_69795, type, fn_signal_transduction_with_phosphorylation_cascade_125: $i > $i).
% 29.32/29.13  tff(decl_69796, type, fn_signal_transduction_with_phosphorylation_cascade_126: $i > $i).
% 29.32/29.13  tff(decl_69797, type, fn_signal_transduction_with_phosphorylation_cascade_127: $i > $i).
% 29.32/29.13  tff(decl_69798, type, fn_signal_transduction_with_phosphorylation_cascade_128: $i > $i).
% 29.32/29.13  tff(decl_69799, type, fn_signal_transduction_with_phosphorylation_cascade_129: $i > $i).
% 29.32/29.13  tff(decl_69800, type, fn_signal_transduction_with_phosphorylation_cascade_130: $i > $i).
% 29.32/29.13  tff(decl_69801, type, fn_signal_transduction_with_phosphorylation_cascade_131: $i > $i).
% 29.32/29.13  tff(decl_69802, type, fn_signal_transduction_with_phosphorylation_cascade_132: $i > $i).
% 29.32/29.13  tff(decl_69803, type, fn_signal_transduction_with_phosphorylation_cascade_120: $i > $i).
% 29.32/29.13  tff(decl_69804, type, fn_signal_transduction_with_phosphorylation_cascade_133: $i > $i).
% 29.32/29.13  tff(decl_69805, type, fn_signal_transduction_with_phosphorylation_cascade_134: $i > $i).
% 29.32/29.13  tff(decl_69806, type, fn_signal_transduction_with_phosphorylation_cascade_54: $i > $i).
% 29.32/29.13  tff(decl_69807, type, 'Signal-Transduction-With-Scaffolding-Protein': $i).
% 29.32/29.13  tff(decl_69808, type, 'Signal transduction event in which a receptor is attached to a protein that scaffolds or provides structural integrity to the cell. These scaffolding proteins act as relay proteins during cell signaling to increase efficiency of signal transduction.': $i).
% 29.32/29.13  tff(decl_69809, type, 'signal transduction with receptor bound to scaffolding protein': $i).
% 29.32/29.13  tff(decl_69810, type, 'signal transduction with receptor bound to structural protein': $i).
% 29.32/29.13  tff(decl_69811, type, 'signal transduction with scaffolding protein': $i).
% 29.32/29.13  tff(decl_69812, type, 'signal-transduction-with-scaffolding-protein': $i).
% 29.32/29.13  tff(decl_69813, type, fn_signal_transduction_with_scaffolding_protein_1: $i > $i).
% 29.32/29.13  tff(decl_69814, type, fn_signal_transduction_with_scaffolding_protein_2: $i > $i).
% 29.32/29.13  tff(decl_69815, type, fn_signal_transduction_with_scaffolding_protein_4: $i > $i).
% 29.32/29.13  tff(decl_69816, type, fn_signal_transduction_with_scaffolding_protein_5: $i > $i).
% 29.32/29.13  tff(decl_69817, type, fn_signal_transduction_with_scaffolding_protein_6: $i > $i).
% 29.32/29.13  tff(decl_69818, type, fn_signal_transduction_with_scaffolding_protein_7: $i > $i).
% 29.32/29.13  tff(decl_69819, type, fn_signal_transduction_with_scaffolding_protein_10: $i > $i).
% 29.32/29.13  tff(decl_69820, type, fn_signal_transduction_with_scaffolding_protein_11: $i > $i).
% 29.32/29.13  tff(decl_69821, type, fn_signal_transduction_with_scaffolding_protein_14: $i > $i).
% 29.32/29.13  tff(decl_69822, type, fn_signal_transduction_with_scaffolding_protein_15: $i > $i).
% 29.32/29.13  tff(decl_69823, type, fn_signal_transduction_with_scaffolding_protein_16: $i > $i).
% 29.32/29.13  tff(decl_69824, type, fn_signal_transduction_with_scaffolding_protein_17: $i > $i).
% 29.32/29.13  tff(decl_69825, type, fn_signal_transduction_with_scaffolding_protein_18: $i > $i).
% 29.32/29.13  tff(decl_69826, type, fn_signal_transduction_with_scaffolding_protein_19: $i > $i).
% 29.32/29.13  tff(decl_69827, type, fn_signal_transduction_with_scaffolding_protein_20: $i > $i).
% 29.32/29.13  tff(decl_69828, type, fn_signal_transduction_with_scaffolding_protein_21: $i > $i).
% 29.32/29.13  tff(decl_69829, type, fn_signal_transduction_with_scaffolding_protein_22: $i > $i).
% 29.32/29.13  tff(decl_69830, type, fn_signal_transduction_with_scaffolding_protein_23: $i > $i).
% 29.32/29.13  tff(decl_69831, type, fn_signal_transduction_with_scaffolding_protein_24: $i > $i).
% 29.32/29.13  tff(decl_69832, type, fn_signal_transduction_with_scaffolding_protein_25: $i > $i).
% 29.32/29.13  tff(decl_69833, type, fn_signal_transduction_with_scaffolding_protein_26: $i > $i).
% 29.32/29.13  tff(decl_69834, type, protein_kinase_0: $i).
% 29.32/29.13  tff(decl_69835, type, fn_signal_transduction_with_scaffolding_protein_12: $i > $i).
% 29.32/29.13  tff(decl_69836, type, fn_signal_transduction_with_scaffolding_protein_13: $i > $i).
% 29.32/29.13  tff(decl_69837, type, 'Signal-Transduction-With-Second-Messenger': $i).
% 29.32/29.13  tff(decl_69838, type, 'The linkage of a mechanical, chemical, or electromagnetic stimulus to a specific cellular response through the use of a secondary signal molecule called a secondary messenger.': $i).
% 29.32/29.13  tff(decl_69839, type, 'signal transduction with second messenger': $i).
% 29.32/29.13  tff(decl_69840, type, 'signal-transduction-with-second-messenger': $i).
% 29.32/29.13  tff(decl_69841, type, 'Signal-Transduction-With-Testosterone': $i).
% 29.32/29.13  tff(decl_69842, type, 'The process of signal transduction in which the signal molecule is testosterone.': $i).
% 29.32/29.13  tff(decl_69843, type, 'signal transduction with testosterone': $i).
% 29.32/29.13  tff(decl_69844, type, 'signal-transduction-with-testosterone': $i).
% 29.32/29.13  tff(decl_69845, type, fn_signal_transduction_with_testosterone_1: $i > $i).
% 29.32/29.13  tff(decl_69846, type, fn_signal_transduction_with_testosterone_3: $i > $i).
% 29.32/29.13  tff(decl_69847, type, fn_signal_transduction_with_testosterone_4: $i > $i).
% 29.32/29.13  tff(decl_69848, type, fn_signal_transduction_with_testosterone_5: $i > $i).
% 29.32/29.13  tff(decl_69849, type, fn_signal_transduction_with_testosterone_6: $i > $i).
% 29.32/29.13  tff(decl_69850, type, fn_signal_transduction_with_testosterone_7: $i > $i).
% 29.32/29.13  tff(decl_69851, type, fn_signal_transduction_with_testosterone_9: $i > $i).
% 29.32/29.13  tff(decl_69852, type, fn_signal_transduction_with_testosterone_10: $i > $i).
% 29.32/29.13  tff(decl_69853, type, fn_signal_transduction_with_testosterone_13: $i > $i).
% 29.32/29.13  tff(decl_69854, type, fn_signal_transduction_with_testosterone_14: $i > $i).
% 29.32/29.13  tff(decl_69855, type, fn_signal_transduction_with_testosterone_15: $i > $i).
% 29.32/29.13  tff(decl_69856, type, fn_signal_transduction_with_testosterone_16: $i > $i).
% 29.32/29.13  tff(decl_69857, type, fn_signal_transduction_with_testosterone_17: $i > $i).
% 29.32/29.13  tff(decl_69858, type, fn_signal_transduction_with_testosterone_18: $i > $i).
% 29.32/29.13  tff(decl_69859, type, fn_signal_transduction_with_testosterone_19: $i > $i).
% 29.32/29.13  tff(decl_69860, type, fn_signal_transduction_with_testosterone_20: $i > $i).
% 29.32/29.13  tff(decl_69861, type, fn_signal_transduction_with_testosterone_8: $i > $i).
% 29.32/29.13  tff(decl_69862, type, 'Signal-Transmission': $i).
% 29.32/29.13  tff(decl_69863, type, 'The passing on of a signal from one place to another.': $i).
% 29.32/29.13  tff(decl_69864, type, 'transmission of signal': $i).
% 29.32/29.13  tff(decl_69865, type, 'signal transmission': $i).
% 29.32/29.13  tff(decl_69866, type, 'signal-transmission': $i).
% 29.32/29.13  tff(decl_69867, type, fn_signal_transmission_4: $i > $i).
% 29.32/29.13  tff(decl_69868, type, transmitting_cell_1: $i > $o).
% 29.32/29.13  tff(decl_69869, type, fn_signal_transmission_6: $i > $i).
% 29.32/29.13  tff(decl_69870, type, fn_transmitting_cell_2: $i > $i).
% 29.32/29.13  tff(decl_69871, type, 'Silent-Mutation': $i).
% 29.32/29.13  tff(decl_69872, type, 'A mutation that has no effect on the encoded protein.': $i).
% 29.32/29.13  tff(decl_69873, type, 'silent mutation': $i).
% 29.32/29.13  tff(decl_69874, type, 'silent-mutation': $i).
% 29.32/29.13  tff(decl_69875, type, 'Silicon': $i).
% 29.32/29.13  tff(decl_69876, type, 'Silicon is a metalloid atom with atomic number 14. It is represented by the symbol Si.': $i).
% 29.32/29.13  tff(decl_69877, type, silicon: $i).
% 29.32/29.13  tff(decl_69878, type, 'Si': $i).
% 29.32/29.13  tff(decl_69879, type, fn_silicon_3: $i > $i).
% 29.32/29.13  tff(decl_69880, type, fn_silicon_4: $i > $i).
% 29.32/29.13  tff(decl_69881, type, fn_silicon_5: $i > $i).
% 29.32/29.13  tff(decl_69882, type, fn_silicon_9: $i > $i).
% 29.32/29.13  tff(decl_69883, type, fn_silicon_10: $i > $i).
% 29.32/29.13  tff(decl_69884, type, fn_silicon_11: $i > $i).
% 29.32/29.13  tff(decl_69885, type, fn_silicon_12: $i > $i).
% 29.32/29.13  tff(decl_69886, type, "28.09": $i).
% 29.32/29.13  tff(decl_69887, type, fn_silicon_7: $i > $i).
% 29.32/29.13  tff(decl_69888, type, fn_silicon_8: $i > $i).
% 29.32/29.13  tff(decl_69889, type, fn_silicon_6: $i > $i).
% 29.32/29.13  tff(decl_69890, type, silk_1: $i > $o).
% 29.32/29.13  tff(decl_69891, type, 'Silk': $i).
% 29.32/29.13  tff(decl_69892, type, 'A strong, shimmering fiber produced by silkworms when making cocoons and harvested to produce fabric and thread.': $i).
% 29.32/29.13  tff(decl_69893, type, silk: $i).
% 29.32/29.13  tff(decl_69894, type, fn_silk_1: $i > $i).
% 29.32/29.13  tff(decl_69895, type, silver_1: $i > $o).
% 29.32/29.13  tff(decl_69896, type, 'Silver': $i).
% 29.32/29.13  tff(decl_69897, type, 'Silver is a metal atom with atomic number 47. It is represented by the symbol Ag.': $i).
% 29.32/29.13  tff(decl_69898, type, silver: $i).
% 29.32/29.13  tff(decl_69899, type, 'Ag': $i).
% 29.32/29.13  tff(decl_69900, type, fn_silver_3: $i > $i).
% 29.32/29.13  tff(decl_69901, type, fn_silver_4: $i > $i).
% 29.32/29.13  tff(decl_69902, type, fn_silver_5: $i > $i).
% 29.32/29.13  tff(decl_69903, type, fn_silver_9: $i > $i).
% 29.32/29.13  tff(decl_69904, type, fn_silver_10: $i > $i).
% 29.32/29.13  tff(decl_69905, type, fn_silver_11: $i > $i).
% 29.32/29.13  tff(decl_69906, type, fn_silver_12: $i > $i).
% 29.32/29.13  tff(decl_69907, type, "47": $i).
% 29.32/29.13  tff(decl_69908, type, "1.93": $i).
% 29.32/29.13  tff(decl_69909, type, "107.9": $i).
% 29.32/29.13  tff(decl_69910, type, fn_silver_7: $i > $i).
% 29.32/29.13  tff(decl_69911, type, fn_silver_8: $i > $i).
% 29.32/29.13  tff(decl_69912, type, fn_silver_6: $i > $i).
% 29.32/29.13  tff(decl_69913, type, 'Simple-Fruit': $i).
% 29.32/29.13  tff(decl_69914, type, 'A fruit that develops from either a single carpel or several carpels fused into a single unit.': $i).
% 29.32/29.13  tff(decl_69915, type, 'fruit of simple': $i).
% 29.32/29.13  tff(decl_69916, type, 'simple fruit': $i).
% 29.32/29.13  tff(decl_69917, type, 'simple-fruit': $i).
% 29.32/29.13  tff(decl_69918, type, simple_sequence_dna_1: $i > $o).
% 29.32/29.13  tff(decl_69919, type, 'Simple-Sequence-DNA': $i).
% 29.32/29.13  tff(decl_69920, type, 'DNA that contains several copies of repeated short nucleotide sequences.': $i).
% 29.32/29.13  tff(decl_69921, type, 'repeated sequence dna': $i).
% 29.32/29.13  tff(decl_69922, type, 'repeated-sequence-dna': $i).
% 29.32/29.13  tff(decl_69923, type, 'simple sequence dna': $i).
% 29.32/29.13  tff(decl_69924, type, 'simple-sequence-dna': $i).
% 29.32/29.13  tff(decl_69925, type, 'Simple-Squamous-Epithelium': $i).
% 29.32/29.13  tff(decl_69926, type, 'A single layer of flat cells lining an epithelium, specialized for material exchange by its thin and leaky structure.': $i).
% 29.32/29.13  tff(decl_69927, type, 'squamous epithelium': $i).
% 29.32/29.13  tff(decl_69928, type, 'squamous-epithelium': $i).
% 29.32/29.13  tff(decl_69929, type, 'simple squamous epithelium': $i).
% 29.32/29.13  tff(decl_69930, type, 'simple-squamous-epithelium': $i).
% 29.32/29.13  tff(decl_69931, type, 'Single-Bond': $i).
% 29.32/29.13  tff(decl_69932, type, 'The attractive force between two atoms sharing a single pair of electrons.': $i).
% 29.32/29.13  tff(decl_69933, type, 'bond of single': $i).
% 29.32/29.13  tff(decl_69934, type, 'single bond': $i).
% 29.32/29.13  tff(decl_69935, type, 'single-bond': $i).
% 29.32/29.13  tff(decl_69936, type, 'Single-Circulation': $i).
% 29.32/29.13  tff(decl_69937, type, 'A circulatory system that contains one pump and a single loop of vessels. Blood passes from the respiratory surfaces to the body tissues before returning to the heart.': $i).
% 29.32/29.13  tff(decl_69938, type, 'circulation of single': $i).
% 29.32/29.13  tff(decl_69939, type, 'single circulation': $i).
% 29.32/29.13  tff(decl_69940, type, 'single-circulation': $i).
% 29.32/29.13  tff(decl_69941, type, 'Single-Lens-Eye': $i).
% 29.32/29.13  tff(decl_69942, type, 'A type of eye that works on camera-like principles. Light enters the eye through a small opening (the pupil) and is focus by a single lens on to receptor cells at the back of the eye.': $i).
% 29.32/29.13  tff(decl_69943, type, 'single lens eye': $i).
% 29.32/29.13  tff(decl_69944, type, 'single-lens eye': $i).
% 29.32/29.13  tff(decl_69945, type, 'single-lens-eye': $i).
% 29.32/29.13  tff(decl_69946, type, 'Single-Strand-Binding-Protein': $i).
% 29.32/29.13  tff(decl_69947, type, 'Single strand binding proteins is useful in unwinding double helix': $i).
% 29.32/29.13  tff(decl_69948, type, 'single strand binding protein': $i).
% 29.32/29.13  tff(decl_69949, type, 'single-strand-binding-protein': $i).
% 29.32/29.13  tff(decl_69950, type, 'Sister-Chromatid': $i).
% 29.32/29.13  tff(decl_69951, type, 'Either of two identical copies of a replicated chromosome, attached to each other at the centromere. Sister chromatids are eventually separated during mitosis or meiosis.': $i).
% 29.32/29.13  tff(decl_69952, type, 'sister-chromatids': $i).
% 29.32/29.13  tff(decl_69953, type, 'sister chromatid i': $i).
% 29.32/29.13  tff(decl_69954, type, 'sister-chromatid-i': $i).
% 29.32/29.13  tff(decl_69955, type, 'sister chromatid ii': $i).
% 29.32/29.13  tff(decl_69956, type, 'sister-chromatid-ii': $i).
% 29.32/29.13  tff(decl_69957, type, 'chromatid of sister': $i).
% 29.32/29.13  tff(decl_69958, type, 'sister-chromatid': $i).
% 29.32/29.13  tff(decl_69959, type, fn_sister_chromatid_1: $i > $i).
% 29.32/29.13  tff(decl_69960, type, fn_sister_chromatid_2: $i > $i).
% 29.32/29.13  tff(decl_69961, type, fn_sister_chromatid_3: $i > $i).
% 29.32/29.13  tff(decl_69962, type, fn_sister_chromatid_5: $i > $i).
% 29.32/29.13  tff(decl_69963, type, fn_sister_chromatid_6: $i > $i).
% 29.32/29.13  tff(decl_69964, type, fn_sister_chromatid_7: $i > $i).
% 29.32/29.13  tff(decl_69965, type, fn_sister_chromatid_8: $i > $i).
% 29.32/29.13  tff(decl_69966, type, fn_sister_chromatid_9: $i > $i).
% 29.32/29.13  tff(decl_69967, type, fn_sister_chromatid_10: $i > $i).
% 29.32/29.13  tff(decl_69968, type, fn_sister_chromatid_11: $i > $i).
% 29.32/29.13  tff(decl_69969, type, 'Sister-Chromatid-Cohesion': $i).
% 29.32/29.13  tff(decl_69970, type, 'During mitosis, the process in which the duplicated chromosomes (called sister chromatids) are held together by cohesin proteins into a diploid chromosome.': $i).
% 29.32/29.13  tff(decl_69971, type, 'sister chromatid cohesion': $i).
% 29.32/29.13  tff(decl_69972, type, 'sister-chromatid-cohesion': $i).
% 29.32/29.13  tff(decl_69973, type, fn_sister_chromatid_cohesion_2: $i > $i).
% 29.32/29.13  tff(decl_69974, type, fn_sister_chromatid_cohesion_3: $i > $i).
% 29.32/29.13  tff(decl_69975, type, fn_sister_chromatid_cohesion_4: $i > $i).
% 29.32/29.13  tff(decl_69976, type, fn_sister_chromatid_cohesion_5: $i > $i).
% 29.32/29.13  tff(decl_69977, type, 'Sit-Down': $i).
% 29.32/29.13  tff(decl_69978, type, sit: $i).
% 29.32/29.13  tff(decl_69979, type, 'sit down': $i).
% 29.32/29.13  tff(decl_69980, type, sit_down: $i).
% 29.32/29.13  tff(decl_69981, type, 'sit-down': $i).
% 29.32/29.13  tff(decl_69982, type, fn_sit_down_1: $i > $i).
% 29.32/29.13  tff(decl_69983, type, 'Situation': $i).
% 29.32/29.13  tff(decl_69984, type, situation: $i).
% 29.32/29.13  tff(decl_69985, type, 'Size-Constant': $i).
% 29.32/29.13  tff(decl_69986, type, 'constant of size': $i).
% 29.32/29.13  tff(decl_69987, type, 'size constant': $i).
% 29.32/29.13  tff(decl_69988, type, 'size-constant': $i).
% 29.32/29.13  tff(decl_69989, type, size_scale_1: $i > $o).
% 29.32/29.13  tff(decl_69990, type, 'Size-Scale': $i).
% 29.32/29.13  tff(decl_69991, type, 'scale of size': $i).
% 29.32/29.13  tff(decl_69992, type, 'size scale': $i).
% 29.32/29.13  tff(decl_69993, type, 'size-scale': $i).
% 29.32/29.13  tff(decl_69994, type, 'Size-Value': $i).
% 29.32/29.13  tff(decl_69995, type, 'the size of the Tangible-Entity': $i).
% 29.32/29.13  tff(decl_69996, type, 'value of size': $i).
% 29.32/29.13  tff(decl_69997, type, 'size value': $i).
% 29.32/29.13  tff(decl_69998, type, 'size-value': $i).
% 29.32/29.13  tff(decl_69999, type, 'Skeletal-Muscle': $i).
% 29.32/29.13  tff(decl_70000, type, 'A type of striated muscle that is under control of the voluntary somatic nervous system.': $i).
% 29.32/29.13  tff(decl_70001, type, 'skeletal muscle': $i).
% 29.32/29.13  tff(decl_70002, type, 'skeletal-muscle': $i).
% 29.32/29.13  tff(decl_70003, type, skeletal_muscle_cell_1: $i > $o).
% 29.32/29.13  tff(decl_70004, type, 'Skeletal-Muscle-Cell': $i).
% 29.32/29.13  tff(decl_70005, type, 'A usually voluntary muscle made up of elongated, multinucleated, transversely striated muscle fibers, having principally bony attachments.': $i).
% 29.32/29.13  tff(decl_70006, type, 'skeletal muscle cell': $i).
% 29.32/29.13  tff(decl_70007, type, 'skeletal-muscle-cell': $i).
% 29.32/29.13  tff(decl_70008, type, 'Skeletal-Muscle-Cell-Differentiation': $i).
% 29.32/29.13  tff(decl_70009, type, 'Skeletal muscle cell differentiation is a process in which a muscle cell develops into a specific type of cell in response to specific triggers from the body or the cell itself.': $i).
% 29.32/29.13  tff(decl_70010, type, 'skeletal muscle cell differentiation': $i).
% 29.32/29.13  tff(decl_70011, type, 'skeletal-muscle-cell-differentiation': $i).
% 29.32/29.13  tff(decl_70012, type, fn_skeletal_muscle_cell_differentiation_1: $i > $i).
% 29.32/29.13  tff(decl_70013, type, fn_skeletal_muscle_cell_differentiation_2: $i > $i).
% 29.32/29.13  tff(decl_70014, type, fn_skeletal_muscle_cell_differentiation_3: $i > $i).
% 29.32/29.13  tff(decl_70015, type, fn_skeletal_muscle_cell_differentiation_4: $i > $i).
% 29.32/29.13  tff(decl_70016, type, fn_skeletal_muscle_cell_differentiation_5: $i > $i).
% 29.32/29.13  tff(decl_70017, type, fn_skeletal_muscle_cell_differentiation_6: $i > $i).
% 29.32/29.13  tff(decl_70018, type, fn_skeletal_muscle_cell_differentiation_7: $i > $i).
% 29.32/29.13  tff(decl_70019, type, fn_skeletal_muscle_cell_differentiation_8: $i > $i).
% 29.32/29.13  tff(decl_70020, type, fn_skeletal_muscle_cell_differentiation_9: $i > $i).
% 29.32/29.13  tff(decl_70021, type, fn_skeletal_muscle_cell_differentiation_10: $i > $i).
% 29.32/29.13  tff(decl_70022, type, fn_skeletal_muscle_cell_differentiation_11: $i > $i).
% 29.32/29.13  tff(decl_70023, type, fn_skeletal_muscle_cell_differentiation_12: $i > $i).
% 29.32/29.13  tff(decl_70024, type, fn_skeletal_muscle_cell_differentiation_13: $i > $i).
% 29.32/29.13  tff(decl_70025, type, fn_skeletal_muscle_cell_differentiation_14: $i > $i).
% 29.32/29.13  tff(decl_70026, type, fn_skeletal_muscle_cell_differentiation_15: $i > $i).
% 29.32/29.13  tff(decl_70027, type, fn_skeletal_muscle_cell_differentiation_16: $i > $i).
% 29.32/29.13  tff(decl_70028, type, fn_skeletal_muscle_cell_differentiation_17: $i > $i).
% 29.32/29.13  tff(decl_70029, type, fn_skeletal_muscle_cell_differentiation_18: $i > $i).
% 29.32/29.13  tff(decl_70030, type, fn_skeletal_muscle_cell_differentiation_19: $i > $i).
% 29.32/29.13  tff(decl_70031, type, fn_skeletal_muscle_cell_differentiation_20: $i > $i).
% 29.32/29.13  tff(decl_70032, type, fn_skeletal_muscle_cell_differentiation_21: $i > $i).
% 29.32/29.13  tff(decl_70033, type, fn_skeletal_muscle_cell_differentiation_22: $i > $i).
% 29.32/29.13  tff(decl_70034, type, fn_skeletal_muscle_cell_differentiation_23: $i > $i).
% 29.32/29.13  tff(decl_70035, type, fn_skeletal_muscle_cell_differentiation_24: $i > $i).
% 29.32/29.13  tff(decl_70036, type, fn_skeletal_muscle_cell_differentiation_25: $i > $i).
% 29.32/29.13  tff(decl_70037, type, fn_skeletal_muscle_cell_differentiation_26: $i > $i).
% 29.32/29.13  tff(decl_70038, type, fn_skeletal_muscle_cell_differentiation_27: $i > $i).
% 29.32/29.13  tff(decl_70039, type, fn_skeletal_muscle_cell_differentiation_28: $i > $i).
% 29.32/29.13  tff(decl_70040, type, fn_skeletal_muscle_cell_differentiation_29: $i > $i).
% 29.32/29.13  tff(decl_70041, type, fn_skeletal_muscle_cell_differentiation_30: $i > $i).
% 29.32/29.13  tff(decl_70042, type, fn_skeletal_muscle_cell_differentiation_31: $i > $i).
% 29.32/29.13  tff(decl_70043, type, fn_skeletal_muscle_cell_differentiation_32: $i > $i).
% 29.32/29.13  tff(decl_70044, type, fn_skeletal_muscle_cell_differentiation_33: $i > $i).
% 29.32/29.13  tff(decl_70045, type, fn_skeletal_muscle_cell_differentiation_34: $i > $i).
% 29.32/29.13  tff(decl_70046, type, fn_skeletal_muscle_cell_differentiation_35: $i > $i).
% 29.32/29.13  tff(decl_70047, type, fn_skeletal_muscle_cell_differentiation_40: $i > $i).
% 29.32/29.13  tff(decl_70048, type, fn_skeletal_muscle_cell_differentiation_41: $i > $i).
% 29.32/29.13  tff(decl_70049, type, fn_skeletal_muscle_cell_differentiation_42: $i > $i).
% 29.32/29.13  tff(decl_70050, type, 'MSTF2': $i).
% 29.32/29.13  tff(decl_70051, type, myoblast_0: $i).
% 29.32/29.13  tff(decl_70052, type, fn_skeletal_muscle_cell_differentiation_37: $i > $i).
% 29.32/29.13  tff(decl_70053, type, fn_skeletal_muscle_cell_differentiation_39: $i > $i).
% 29.32/29.13  tff(decl_70054, type, fn_skeletal_muscle_cell_differentiation_38: $i > $i).
% 29.32/29.13  tff(decl_70055, type, fn_skeletal_muscle_cell_differentiation_36: $i > $i).
% 29.32/29.13  tff(decl_70056, type, 'Skeletal-Organ': $i).
% 29.32/29.13  tff(decl_70057, type, 'An organ or part of the skeletal system.': $i).
% 29.32/29.13  tff(decl_70058, type, 'organ of skeletal system': $i).
% 29.32/29.13  tff(decl_70059, type, 'organ-of-skeletal-system': $i).
% 29.32/29.13  tff(decl_70060, type, 'skeletal organ': $i).
% 29.32/29.13  tff(decl_70061, type, 'skeletal-organ': $i).
% 29.32/29.13  tff(decl_70062, type, skeletal_system_1: $i > $o).
% 29.32/29.13  tff(decl_70063, type, 'Skeletal-System': $i).
% 29.32/29.13  tff(decl_70064, type, 'In animal bodies, the rigid structures that provide support and site for muscle attachment.': $i).
% 29.32/29.13  tff(decl_70065, type, 'skeletal system': $i).
% 29.32/29.13  tff(decl_70066, type, 'skeletal-system': $i).
% 29.32/29.13  tff(decl_70067, type, 'Skeleton': $i).
% 29.32/29.13  tff(decl_70068, type, 'A rigid framework that provides structure in an animal\\s body. Chordates and echinoderms have an endoskeleton, while arthropods and molluscs have an exoskeleton and many soft-bodied invertebrates have a hydrostatic skeleton.': $i).
% 29.32/29.13  tff(decl_70069, type, skeleton: $i).
% 29.32/29.13  tff(decl_70070, type, 'Skin': $i).
% 29.32/29.13  tff(decl_70071, type, 'The outer covering of an animal, particularly a vertebrate.': $i).
% 29.32/29.13  tff(decl_70072, type, fn_skin_1: $i > $i).
% 29.32/29.13  tff(decl_70073, type, fn_skin_2: $i > $i).
% 29.32/29.13  tff(decl_70074, type, fn_skin_3: $i > $i).
% 29.32/29.13  tff(decl_70075, type, 'Skin-cell': $i).
% 29.32/29.13  tff(decl_70076, type, 'The cells of the skin of an animal is called as a skin-cell.': $i).
% 29.32/29.13  tff(decl_70077, type, 'cell of skin': $i).
% 29.32/29.13  tff(decl_70078, type, 'skin cell': $i).
% 29.32/29.13  tff(decl_70079, type, 'skin-cell': $i).
% 29.32/29.13  tff(decl_70080, type, fn_skin_cell_1: $i > $i).
% 29.32/29.13  tff(decl_70081, type, fn_skin_cell_2: $i > $i).
% 29.32/29.13  tff(decl_70082, type, fn_skin_cell_3: $i > $i).
% 29.32/29.13  tff(decl_70083, type, skin_cell_division_1: $i > $o).
% 29.32/29.13  tff(decl_70084, type, 'Skin-Cell-Division': $i).
% 29.32/29.13  tff(decl_70085, type, 'A process in skin cells by which the parent cell divides into two or more daughter cells.': $i).
% 29.32/29.13  tff(decl_70086, type, 'skin cell division': $i).
% 29.32/29.13  tff(decl_70087, type, 'skin-cell-division': $i).
% 29.32/29.13  tff(decl_70088, type, fn_skin_cell_division_1: $i > $i).
% 29.32/29.13  tff(decl_70089, type, fn_skin_cell_division_3: $i > $i).
% 29.32/29.13  tff(decl_70090, type, fn_skin_cell_division_4: $i > $i).
% 29.32/29.13  tff(decl_70091, type, sleep_1: $i > $o).
% 29.32/29.13  tff(decl_70092, type, 'Sleep': $i).
% 29.32/29.13  tff(decl_70093, type, 'A naturally occuring period of rest characterized by reduced consciousness, reduced sensory activity, and inactivity. In humans, dreaming occurs during sleep.': $i).
% 29.32/29.13  tff(decl_70094, type, sleep: $i).
% 29.32/29.13  tff(decl_70095, type, 'Slide': $i).
% 29.32/29.13  tff(decl_70096, type, slide: $i).
% 29.32/29.13  tff(decl_70097, type, slight_decrease_of_water_temperature_1: $i > $o).
% 29.32/29.13  tff(decl_70098, type, 'Slight-Decrease-Of-Water-Temperature': $i).
% 29.32/29.13  tff(decl_70099, type, 'An incremental decline in the intensity of heat in water.': $i).
% 29.32/29.13  tff(decl_70100, type, 'slight decrease of water temperature': $i).
% 29.32/29.13  tff(decl_70101, type, 'slight-decrease-of-water-temperature': $i).
% 29.32/29.13  tff(decl_70102, type, fn_slight_decrease_of_water_temperature_2: $i > $i).
% 29.32/29.13  tff(decl_70103, type, fn_slight_decrease_of_water_temperature_3: $i > $i).
% 29.32/29.13  tff(decl_70104, type, fn_slight_decrease_of_water_temperature_5: $i > $i).
% 29.32/29.13  tff(decl_70105, type, fn_slight_decrease_of_water_temperature_6: $i > $i).
% 29.32/29.13  tff(decl_70106, type, fn_slight_decrease_of_water_temperature_7: $i > $i).
% 29.32/29.13  tff(decl_70107, type, fn_slight_decrease_of_water_temperature_8: $i > $i).
% 29.32/29.13  tff(decl_70108, type, fn_slight_decrease_of_water_temperature_9: $i > $i).
% 29.32/29.13  tff(decl_70109, type, fn_slight_decrease_of_water_temperature_4: $i > $i).
% 29.32/29.13  tff(decl_70110, type, 'Slope-Constant': $i).
% 29.32/29.13  tff(decl_70111, type, 'constant of slope': $i).
% 29.32/29.13  tff(decl_70112, type, 'slope constant': $i).
% 29.32/29.13  tff(decl_70113, type, 'slope-constant': $i).
% 29.32/29.13  tff(decl_70114, type, slope_scale_1: $i > $o).
% 29.32/29.13  tff(decl_70115, type, 'Slope-Scale': $i).
% 29.32/29.13  tff(decl_70116, type, 'scale of slope': $i).
% 29.32/29.13  tff(decl_70117, type, 'slope scale': $i).
% 29.32/29.13  tff(decl_70118, type, 'slope-scale': $i).
% 29.32/29.13  tff(decl_70119, type, 'Slot': $i).
% 29.32/29.13  tff(decl_70120, type, slot: $i).
% 29.32/29.13  tff(decl_70121, type, slot_query_viewpoint_1: $i > $o).
% 29.32/29.13  tff(decl_70122, type, 'Slot-Query-Viewpoint': $i).
% 29.32/29.13  tff(decl_70123, type, 'slot query viewpoint': $i).
% 29.32/29.13  tff(decl_70124, type, 'slot-query-viewpoint': $i).
% 29.32/29.13  tff(decl_70125, type, slot_value_viewpoint_1: $i > $o).
% 29.32/29.13  tff(decl_70126, type, 'Slot-Value-Viewpoint': $i).
% 29.32/29.13  tff(decl_70127, type, 'slot value viewpoint': $i).
% 29.32/29.13  tff(decl_70128, type, 'slot-value-viewpoint': $i).
% 29.32/29.13  tff(decl_70129, type, slow_block_1: $i > $o).
% 29.32/29.13  tff(decl_70130, type, 'Slow-Block': $i).
% 29.32/29.13  tff(decl_70131, type, 'The formation and hardening of the fertilization envelope after an egg has been penetrated by a sperm, which prevents additional sperm from penetrating the egg. In sea urchins, the fertilization envelope takes about 1 minute to form.': $i).
% 29.32/29.13  tff(decl_70132, type, 'slow block': $i).
% 29.32/29.13  tff(decl_70133, type, 'slow-block': $i).
% 29.32/29.13  tff(decl_70134, type, 'Slow-Twitch-Fiber': $i).
% 29.32/29.13  tff(decl_70135, type, 'A skeletal muscle fiber that contracts for a long time but with little force; slow twitch muscles can sustain long periods of aerobic activity.': $i).
% 29.32/29.13  tff(decl_70136, type, 'slow twitch fiber': $i).
% 29.32/29.13  tff(decl_70137, type, 'slow-twitch-fiber': $i).
% 29.32/29.13  tff(decl_70138, type, slug_1: $i > $o).
% 29.32/29.13  tff(decl_70139, type, 'Slug': $i).
% 29.32/29.13  tff(decl_70140, type, 'A gastropod mollusc that generally lacks a shell, although some marine species have a reduced shell or a small internal shell. Slugs can be either aquatic or terrestrial.': $i).
% 29.32/29.13  tff(decl_70141, type, slug: $i).
% 29.32/29.13  tff(decl_70142, type, small_interfering_rna_1: $i > $o).
% 29.32/29.13  tff(decl_70143, type, 'Small-Interfering-RNA': $i).
% 29.32/29.13  tff(decl_70144, type, 'Single-stranded RNA that interferes with the expression of certain genes by binding to and preventing the translation of its complementary sequence on an mRNA transcript.': $i).
% 29.32/29.13  tff(decl_70145, type, sirna: $i).
% 29.32/29.13  tff(decl_70146, type, 'small rnai': $i).
% 29.32/29.13  tff(decl_70147, type, 'small-rnai': $i).
% 29.32/29.13  tff(decl_70148, type, 'small interfering rna': $i).
% 29.32/29.13  tff(decl_70149, type, 'small-interfering-rna': $i).
% 29.32/29.13  tff(decl_70150, type, 'Small-Intestine': $i).
% 29.32/29.13  tff(decl_70151, type, 'The longest section of the mammalian alimentary canal, situated between the stomach and the large intestine. It is the primary site for the enzymatic digestion of food and the absorption of nutrients.': $i).
% 29.32/29.13  tff(decl_70152, type, 'intestine of small': $i).
% 29.32/29.13  tff(decl_70153, type, 'small intestine': $i).
% 29.32/29.13  tff(decl_70154, type, 'small-intestine': $i).
% 29.32/29.13  tff(decl_70155, type, fn_small_intestine_1: $i > $i).
% 29.32/29.13  tff(decl_70156, type, fn_small_intestine_2: $i > $i).
% 29.32/29.13  tff(decl_70157, type, fn_small_intestine_3: $i > $i).
% 29.32/29.13  tff(decl_70158, type, fn_small_intestine_5: $i > $i).
% 29.32/29.13  tff(decl_70159, type, fn_small_intestine_6: $i > $i).
% 29.32/29.13  tff(decl_70160, type, fn_small_intestine_7: $i > $i).
% 29.32/29.13  tff(decl_70161, type, fn_small_intestine_8: $i > $i).
% 29.32/29.13  tff(decl_70162, type, fn_small_intestine_9: $i > $i).
% 29.32/29.13  tff(decl_70163, type, fn_small_intestine_10: $i > $i).
% 29.32/29.13  tff(decl_70164, type, fn_small_intestine_12: $i > $i).
% 29.32/29.13  tff(decl_70165, type, trypsin_1: $i > $o).
% 29.32/29.13  tff(decl_70166, type, fn_small_intestine_13: $i > $i).
% 29.32/29.13  tff(decl_70167, type, fn_small_intestine_14: $i > $i).
% 29.32/29.13  tff(decl_70168, type, fn_small_intestine_16: $i > $i).
% 29.32/29.13  tff(decl_70169, type, fn_small_intestine_17: $i > $i).
% 29.32/29.13  tff(decl_70170, type, fn_small_intestine_18: $i > $i).
% 29.32/29.13  tff(decl_70171, type, fn_small_intestine_23: $i > $i).
% 29.32/29.13  tff(decl_70172, type, fn_small_intestine_24: $i > $i).
% 29.32/29.13  tff(decl_70173, type, fn_small_intestine_25: $i > $i).
% 29.32/29.13  tff(decl_70174, type, fn_small_intestine_26: $i > $i).
% 29.32/29.13  tff(decl_70175, type, fn_small_intestine_27: $i > $i).
% 29.32/29.13  tff(decl_70176, type, fn_small_intestine_28: $i > $i).
% 29.32/29.13  tff(decl_70177, type, fn_small_intestine_29: $i > $i).
% 29.32/29.13  tff(decl_70178, type, fn_small_intestine_30: $i > $i).
% 29.32/29.13  tff(decl_70179, type, fn_small_intestine_31: $i > $i).
% 29.32/29.13  tff(decl_70180, type, fn_small_intestine_33: $i > $i).
% 29.32/29.13  tff(decl_70181, type, fn_small_intestine_34: $i > $i).
% 29.32/29.13  tff(decl_70182, type, fn_small_intestine_35: $i > $i).
% 29.32/29.13  tff(decl_70183, type, fn_small_intestine_36: $i > $i).
% 29.32/29.13  tff(decl_70184, type, villus_1: $i > $o).
% 29.32/29.13  tff(decl_70185, type, fn_small_intestine_37: $i > $i).
% 29.32/29.13  tff(decl_70186, type, fn_small_intestine_38: $i > $i).
% 29.32/29.13  tff(decl_70187, type, fn_small_intestine_39: $i > $i).
% 29.32/29.13  tff(decl_70188, type, fn_small_intestine_40: $i > $i).
% 29.32/29.13  tff(decl_70189, type, fn_small_intestine_41: $i > $i).
% 29.32/29.13  tff(decl_70190, type, fn_villus_3: $i > $i).
% 29.32/29.13  tff(decl_70191, type, fn_villus_1: $i > $i).
% 29.32/29.13  tff(decl_70192, type, fn_villus_4: $i > $i).
% 29.32/29.13  tff(decl_70193, type, fn_villus_5: $i > $i).
% 29.32/29.13  tff(decl_70194, type, large_intestine_0: $i).
% 29.32/29.13  tff(decl_70195, type, fn_small_intestine_42: $i > $i).
% 29.32/29.13  tff(decl_70196, type, 'Small-Ribosomal-Subunit': $i).
% 29.32/29.13  tff(decl_70197, type, 'A small ribosomal subunit is a presursor part of a  ribosome. It forms ribosomes along with the large ribosomal subunit.': $i).
% 29.32/29.13  tff(decl_70198, type, 'small ribosomal subunit': $i).
% 29.32/29.13  tff(decl_70199, type, 'small-ribosomal-subunit': $i).
% 29.32/29.13  tff(decl_70200, type, fn_small_ribosomal_subunit_1: $i > $i).
% 29.32/29.13  tff(decl_70201, type, fn_small_ribosomal_subunit_2: $i > $i).
% 29.32/29.13  tff(decl_70202, type, 'Smallpox': $i).
% 29.32/29.13  tff(decl_70203, type, 'An infectious disease of humans caused by the Variola viruses. It has been eradicated from the human population since 1979.': $i).
% 29.32/29.13  tff(decl_70204, type, variola: $i).
% 29.32/29.13  tff(decl_70205, type, smallpox: $i).
% 29.32/29.13  tff(decl_70206, type, 'Smell-Constant': $i).
% 29.32/29.13  tff(decl_70207, type, 'constant of smell': $i).
% 29.32/29.13  tff(decl_70208, type, 'smell constant': $i).
% 29.32/29.13  tff(decl_70209, type, 'smell-constant': $i).
% 29.32/29.13  tff(decl_70210, type, 'Smell-Value': $i).
% 29.32/29.13  tff(decl_70211, type, 'any property detected by the olfactory system': $i).
% 29.32/29.13  tff(decl_70212, type, 'olfactory property': $i).
% 29.32/29.13  tff(decl_70213, type, aroma: $i).
% 29.32/29.13  tff(decl_70214, type, odor: $i).
% 29.32/29.13  tff(decl_70215, type, odour: $i).
% 29.32/29.13  tff(decl_70216, type, scent: $i).
% 29.32/29.13  tff(decl_70217, type, 'value of smell': $i).
% 29.32/29.13  tff(decl_70218, type, 'smell value': $i).
% 29.32/29.13  tff(decl_70219, type, 'smell-value': $i).
% 29.32/29.13  tff(decl_70220, type, 'Smooth-Endoplasmic-Reticulum': $i).
% 29.32/29.13  tff(decl_70221, type, 'Smooth Endoplasmic Reticulum (SER) is an endoplasmic reticulum which does not have ribosomes attached on its surface. It is primarily concerned with syntheis of lipids, metabolism of carbohydrates and detoxification of drugs and poisons. It is prevalent in liver cells': $i).
% 29.32/29.13  tff(decl_70222, type, 'smooth endoplasmic reticulum': $i).
% 29.32/29.13  tff(decl_70223, type, 'smooth-endoplasmic-reticulum': $i).
% 29.32/29.13  tff(decl_70224, type, 'smooth er': $i).
% 29.32/29.13  tff(decl_70225, type, 'smooth-er': $i).
% 29.32/29.13  tff(decl_70226, type, fn_smooth_endoplasmic_reticulum_2: $i > $i).
% 29.32/29.13  tff(decl_70227, type, fn_smooth_endoplasmic_reticulum_5: $i > $i).
% 29.32/29.13  tff(decl_70228, type, fn_smooth_endoplasmic_reticulum_14: $i > $i).
% 29.32/29.13  tff(decl_70229, type, fn_smooth_endoplasmic_reticulum_16: $i > $i).
% 29.32/29.13  tff(decl_70230, type, fn_smooth_endoplasmic_reticulum_17: $i > $i).
% 29.32/29.13  tff(decl_70231, type, fn_smooth_endoplasmic_reticulum_18: $i > $i).
% 29.32/29.13  tff(decl_70232, type, fn_smooth_endoplasmic_reticulum_26: $i > $i).
% 29.32/29.13  tff(decl_70233, type, fn_smooth_endoplasmic_reticulum_27: $i > $i).
% 29.32/29.13  tff(decl_70234, type, fn_smooth_endoplasmic_reticulum_40: $i > $i).
% 29.32/29.13  tff(decl_70235, type, fn_smooth_endoplasmic_reticulum_41: $i > $i).
% 29.32/29.13  tff(decl_70236, type, fn_smooth_endoplasmic_reticulum_43: $i > $i).
% 29.32/29.13  tff(decl_70237, type, fn_smooth_endoplasmic_reticulum_44: $i > $i).
% 29.32/29.13  tff(decl_70238, type, fn_smooth_endoplasmic_reticulum_52: $i > $i).
% 29.32/29.13  tff(decl_70239, type, fn_smooth_endoplasmic_reticulum_51: $i > $i).
% 29.32/29.13  tff(decl_70240, type, 'Smooth-Muscle': $i).
% 29.32/29.13  tff(decl_70241, type, 'A type of involuntary, non-striated muscle. It is found in the walls of blood vessels, the bladder, the gastrointestinal tract, the reproductive tracts, the respiratory tract, and the iris of the eye.': $i).
% 29.32/29.13  tff(decl_70242, type, 'visceral muscle': $i).
% 29.32/29.13  tff(decl_70243, type, 'visceral-muscle': $i).
% 29.32/29.13  tff(decl_70244, type, 'muscle of smooth': $i).
% 29.32/29.13  tff(decl_70245, type, 'smooth muscle': $i).
% 29.32/29.13  tff(decl_70246, type, 'smooth-muscle': $i).
% 29.32/29.13  tff(decl_70247, type, smooth_muscle_cell_1: $i > $o).
% 29.32/29.13  tff(decl_70248, type, 'Smooth-Muscle-Cell': $i).
% 29.32/29.13  tff(decl_70249, type, 'Muscle cells which appear unstriated in muscle tissue. The mammalian digestive system contains smooth muscle cells.': $i).
% 29.32/29.13  tff(decl_70250, type, 'smooth muscle cell': $i).
% 29.32/29.13  tff(decl_70251, type, 'smooth-muscle-cell': $i).
% 29.32/29.13  tff(decl_70252, type, smw_attribute_group_1: $i > $o).
% 29.32/29.13  tff(decl_70253, type, 'SMW-Attribute-Group': $i).
% 29.32/29.13  tff(decl_70254, type, 'smw attribute group': $i).
% 29.32/29.13  tff(decl_70255, type, 'smw-attribute-group': $i).
% 29.32/29.13  tff(decl_70256, type, snake_1: $i > $o).
% 29.32/29.13  tff(decl_70257, type, 'Snake': $i).
% 29.32/29.13  tff(decl_70258, type, 'Member of the reptile class with an elongated legless body, lidless eyes and lack of external ears. All snakes are carnivores.': $i).
% 29.32/29.13  tff(decl_70259, type, snake: $i).
% 29.32/29.13  tff(decl_70260, type, fn_snake_1: $i > $i).
% 29.32/29.13  tff(decl_70261, type, fn_snake_2: $i > $i).
% 29.32/29.13  tff(decl_70262, type, fn_snake_3: $i > $i).
% 29.32/29.13  tff(decl_70263, type, fn_snake_4: $i > $i).
% 29.32/29.13  tff(decl_70264, type, fn_snake_5: $i > $i).
% 29.32/29.13  tff(decl_70265, type, fn_snake_6: $i > $i).
% 29.32/29.13  tff(decl_70266, type, fn_snake_7: $i > $i).
% 29.32/29.13  tff(decl_70267, type, fn_snake_8: $i > $i).
% 29.32/29.13  tff(decl_70268, type, fn_snake_9: $i > $i).
% 29.32/29.13  tff(decl_70269, type, fn_snake_10: $i > $i).
% 29.32/29.13  tff(decl_70270, type, fn_snake_11: $i > $i).
% 29.32/29.13  tff(decl_70271, type, fn_snake_12: $i > $i).
% 29.32/29.13  tff(decl_70272, type, fn_snake_13: $i > $i).
% 29.32/29.13  tff(decl_70273, type, fn_snake_14: $i > $i).
% 29.32/29.13  tff(decl_70274, type, fn_snake_15: $i > $i).
% 29.32/29.13  tff(decl_70275, type, fn_snake_16: $i > $i).
% 29.32/29.13  tff(decl_70276, type, fn_snake_17: $i > $i).
% 29.32/29.13  tff(decl_70277, type, fn_snake_18: $i > $i).
% 29.32/29.13  tff(decl_70278, type, fn_snake_19: $i > $i).
% 29.32/29.13  tff(decl_70279, type, fn_snake_20: $i > $i).
% 29.32/29.13  tff(decl_70280, type, fn_snake_21: $i > $i).
% 29.32/29.13  tff(decl_70281, type, fn_snake_22: $i > $i).
% 29.32/29.13  tff(decl_70282, type, fn_snake_23: $i > $i).
% 29.32/29.13  tff(decl_70283, type, fn_snake_24: $i > $i).
% 29.32/29.13  tff(decl_70284, type, fn_snake_25: $i > $i).
% 29.32/29.13  tff(decl_70285, type, fn_snake_26: $i > $i).
% 29.32/29.13  tff(decl_70286, type, fn_snake_27: $i > $i).
% 29.32/29.13  tff(decl_70287, type, fn_snake_28: $i > $i).
% 29.32/29.13  tff(decl_70288, type, fn_snake_29: $i > $i).
% 29.32/29.13  tff(decl_70289, type, fn_snake_30: $i > $i).
% 29.32/29.13  tff(decl_70290, type, fn_snake_31: $i > $i).
% 29.32/29.13  tff(decl_70291, type, fn_snake_32: $i > $i).
% 29.32/29.13  tff(decl_70292, type, fn_snake_33: $i > $i).
% 29.32/29.13  tff(decl_70293, type, fn_snake_34: $i > $i).
% 29.32/29.13  tff(decl_70294, type, fn_snake_35: $i > $i).
% 29.32/29.13  tff(decl_70295, type, fn_snake_36: $i > $i).
% 29.32/29.13  tff(decl_70296, type, fn_snake_37: $i > $i).
% 29.32/29.13  tff(decl_70297, type, fn_snake_38: $i > $i).
% 29.32/29.13  tff(decl_70298, type, fn_snake_39: $i > $i).
% 29.32/29.13  tff(decl_70299, type, fn_vertebrate_44: $i > $i).
% 29.32/29.13  tff(decl_70300, type, 'Snow': $i).
% 29.32/29.13  tff(decl_70301, type, 'Ice crystals formed from frozen water vapor in the atmosphere that falls to the earth as a form of precipitation.': $i).
% 29.32/29.13  tff(decl_70302, type, snow: $i).
% 29.32/29.13  tff(decl_70303, type, snow_melting_1: $i > $o).
% 29.32/29.13  tff(decl_70304, type, 'Snow-Melting': $i).
% 29.32/29.13  tff(decl_70305, type, 'The conversion of snow to water as the temperature increases.': $i).
% 29.32/29.13  tff(decl_70306, type, 'melting of snow': $i).
% 29.32/29.13  tff(decl_70307, type, 'snow melting': $i).
% 29.32/29.13  tff(decl_70308, type, 'snow-melting': $i).
% 29.32/29.13  tff(decl_70309, type, fn_snow_melting_2: $i > $i).
% 29.32/29.13  tff(decl_70310, type, fn_snow_melting_3: $i > $i).
% 29.32/29.13  tff(decl_70311, type, fn_snow_melting_4: $i > $i).
% 29.32/29.13  tff(decl_70312, type, fn_snow_melting_5: $i > $i).
% 29.32/29.13  tff(decl_70313, type, fn_snow_melting_7: $i > $i).
% 29.32/29.13  tff(decl_70314, type, fn_snow_melting_8: $i > $i).
% 29.32/29.13  tff(decl_70315, type, fn_snow_melting_9: $i > $i).
% 29.32/29.13  tff(decl_70316, type, fn_snow_melting_10: $i > $i).
% 29.32/29.13  tff(decl_70317, type, fn_snow_melting_13: $i > $i).
% 29.32/29.13  tff(decl_70318, type, fn_snow_melting_14: $i > $i).
% 29.32/29.13  tff(decl_70319, type, fn_snow_melting_15: $i > $i).
% 29.32/29.13  tff(decl_70320, type, fn_snow_melting_16: $i > $i).
% 29.32/29.13  tff(decl_70321, type, fn_snow_melting_17: $i > $i).
% 29.32/29.13  tff(decl_70322, type, fn_snow_melting_18: $i > $i).
% 29.32/29.13  tff(decl_70323, type, fn_snow_melting_19: $i > $i).
% 29.32/29.13  tff(decl_70324, type, fn_snow_melting_20: $i > $i).
% 29.32/29.13  tff(decl_70325, type, fn_snow_melting_21: $i > $i).
% 29.32/29.13  tff(decl_70326, type, fn_snow_melting_22: $i > $i).
% 29.32/29.13  tff(decl_70327, type, fn_snow_melting_23: $i > $i).
% 29.32/29.13  tff(decl_70328, type, fn_snow_melting_24: $i > $i).
% 29.32/29.13  tff(decl_70329, type, fn_snow_melting_25: $i > $i).
% 29.32/29.13  tff(decl_70330, type, fn_snow_melting_26: $i > $i).
% 29.32/29.13  tff(decl_70331, type, fn_snow_melting_27: $i > $i).
% 29.32/29.13  tff(decl_70332, type, fn_snow_melting_28: $i > $i).
% 29.32/29.13  tff(decl_70333, type, fn_snow_melting_30: $i > $i).
% 29.32/29.13  tff(decl_70334, type, fn_snow_melting_31: $i > $i).
% 29.32/29.13  tff(decl_70335, type, fn_snow_melting_32: $i > $i).
% 29.32/29.13  tff(decl_70336, type, fn_snow_melting_33: $i > $i).
% 29.32/29.13  tff(decl_70337, type, fn_snow_melting_34: $i > $i).
% 29.32/29.13  tff(decl_70338, type, fn_snow_melting_35: $i > $i).
% 29.32/29.13  tff(decl_70339, type, fn_snow_melting_36: $i > $i).
% 29.32/29.13  tff(decl_70340, type, fn_snow_melting_37: $i > $i).
% 29.32/29.13  tff(decl_70341, type, fn_snow_melting_38: $i > $i).
% 29.32/29.13  tff(decl_70342, type, fn_snow_melting_29: $i > $i).
% 29.32/29.13  tff(decl_70343, type, fn_snow_melting_6: $i > $i).
% 29.32/29.13  tff(decl_70344, type, fn_snow_melting_11: $i > $i).
% 29.32/29.13  tff(decl_70345, type, fn_snow_melting_12: $i > $i).
% 29.32/29.13  tff(decl_70346, type, 'Snowball-Earth-Hypothesis': $i).
% 29.32/29.13  tff(decl_70347, type, 'The hypothesis suggesting that a severe ice age enduring from 750 to 570 million years ago may help to explain why multicellular eukaryotes were relatively limited in diversity and distribution until the very late Precambrian.': $i).
% 29.32/29.13  tff(decl_70348, type, 'snowball earth hypothesis': $i).
% 29.32/29.13  tff(decl_70349, type, 'snowball-earth-hypothesis': $i).
% 29.32/29.13  tff(decl_70350, type, snrna_1: $i > $o).
% 29.32/29.13  tff(decl_70351, type, 'SnRNA': $i).
% 29.32/29.13  tff(decl_70352, type, 'Small nuclear RNA; short pieces of RNA found in the nucleus. They are involved in recognizing pre-mRNA splice sites.': $i).
% 29.32/29.13  tff(decl_70353, type, 'small nuclear rna': $i).
% 29.32/29.13  tff(decl_70354, type, 'small-nuclear-rna': $i).
% 29.32/29.13  tff(decl_70355, type, snrna: $i).
% 29.32/29.13  tff(decl_70356, type, fn_snrna_1: $i > $i).
% 29.32/29.13  tff(decl_70357, type, fn_snrna_2: $i > $i).
% 29.32/29.13  tff(decl_70358, type, fn_snrna_5: $i > $i).
% 29.32/29.13  tff(decl_70359, type, fn_snrna_6: $i > $i).
% 29.32/29.13  tff(decl_70360, type, fn_snrna_7: $i > $i).
% 29.32/29.13  tff(decl_70361, type, fn_snrna_8: $i > $i).
% 29.32/29.13  tff(decl_70362, type, fn_snrna_14: $i > $i).
% 29.32/29.13  tff(decl_70363, type, fn_snrna_15: $i > $i).
% 29.32/29.13  tff(decl_70364, type, fn_snrna_16: $i > $i).
% 29.32/29.13  tff(decl_70365, type, fn_snrna_17: $i > $i).
% 29.32/29.13  tff(decl_70366, type, fn_snrna_18: $i > $i).
% 29.32/29.13  tff(decl_70367, type, fn_snrna_19: $i > $i).
% 29.32/29.13  tff(decl_70368, type, fn_snrna_20: $i > $i).
% 29.32/29.13  tff(decl_70369, type, fn_snrna_21: $i > $i).
% 29.32/29.13  tff(decl_70370, type, fn_snrna_22: $i > $i).
% 29.32/29.13  tff(decl_70371, type, fn_snrna_23: $i > $i).
% 29.32/29.13  tff(decl_70372, type, fn_snrna_24: $i > $i).
% 29.32/29.13  tff(decl_70373, type, fn_snrna_25: $i > $i).
% 29.32/29.13  tff(decl_70374, type, fn_snrna_26: $i > $i).
% 29.32/29.13  tff(decl_70375, type, fn_snrna_27: $i > $i).
% 29.32/29.13  tff(decl_70376, type, fn_snrna_28: $i > $i).
% 29.32/29.13  tff(decl_70377, type, fn_snrna_29: $i > $i).
% 29.32/29.13  tff(decl_70378, type, fn_snrna_30: $i > $i).
% 29.32/29.13  tff(decl_70379, type, fn_snrna_31: $i > $i).
% 29.32/29.13  tff(decl_70380, type, fn_snrna_32: $i > $i).
% 29.32/29.13  tff(decl_70381, type, fn_snrna_33: $i > $i).
% 29.32/29.13  tff(decl_70382, type, fn_snrna_34: $i > $i).
% 29.32/29.13  tff(decl_70383, type, fn_snrna_35: $i > $i).
% 29.32/29.13  tff(decl_70384, type, fn_snrna_36: $i > $i).
% 29.32/29.13  tff(decl_70385, type, fn_snrna_37: $i > $i).
% 29.32/29.13  tff(decl_70386, type, fn_snrna_38: $i > $i).
% 29.32/29.13  tff(decl_70387, type, fn_snrna_39: $i > $i).
% 29.32/29.13  tff(decl_70388, type, fn_snrna_40: $i > $i).
% 29.32/29.13  tff(decl_70389, type, fn_snrna_41: $i > $i).
% 29.32/29.14  tff(decl_70390, type, fn_snrna_42: $i > $i).
% 29.32/29.14  tff(decl_70391, type, fn_snrna_43: $i > $i).
% 29.32/29.14  tff(decl_70392, type, fn_ester_linkage_1: $i > $i).
% 29.32/29.14  tff(decl_70393, type, ribonucleoside_monophosphate_0: $i).
% 29.32/29.14  tff(decl_70394, type, fn_snrna_12: $i > $i).
% 29.32/29.14  tff(decl_70395, type, fn_snrna_13: $i > $i).
% 29.32/29.14  tff(decl_70396, type, fn_snrna_11: $i > $i).
% 29.32/29.14  tff(decl_70397, type, fn_snrna_10: $i > $i).
% 29.32/29.14  tff(decl_70398, type, fn_snrna_4: $i > $i).
% 29.32/29.14  tff(decl_70399, type, fn_snrna_9: $i > $i).
% 29.32/29.14  tff(decl_70400, type, fn_snrna_3: $i > $i).
% 29.32/29.14  tff(decl_70401, type, 'SnRNP': $i).
% 29.32/29.14  tff(decl_70402, type, 'Small nuclear ribonucleoproteins or snRNPs are RNA-protein complexes. They combine with unmodified pre-mRNA and various other proteins to form a spliceosome. They play role in the RNA-Splicing and help remove the introns.': $i).
% 29.32/29.14  tff(decl_70403, type, snurps: $i).
% 29.32/29.14  tff(decl_70404, type, 'small nuclear ribonucleoprotein': $i).
% 29.32/29.14  tff(decl_70405, type, 'small-nuclear-ribonucleoprotein': $i).
% 29.32/29.14  tff(decl_70406, type, snrnp: $i).
% 29.32/29.14  tff(decl_70407, type, fn_snrnp_1: $i > $i).
% 29.32/29.14  tff(decl_70408, type, fn_snrnp_2: $i > $i).
% 29.32/29.14  tff(decl_70409, type, so4_minus_2_1: $i > $o).
% 29.32/29.14  tff(decl_70410, type, 'SO4-Minus-2': $i).
% 29.32/29.14  tff(decl_70411, type, 'The sulfate ion.': $i).
% 29.32/29.14  tff(decl_70412, type, sulfate: $i).
% 29.32/29.14  tff(decl_70413, type, 'so4 minus 2': $i).
% 29.32/29.14  tff(decl_70414, type, 'so4-minus-2': $i).
% 29.32/29.14  tff(decl_70415, type, fn_so4_minus_2_2: $i > $i).
% 29.32/29.14  tff(decl_70416, type, fn_so4_minus_2_1: $i > $i).
% 29.32/29.14  tff(decl_70417, type, 'Social-Behavior': $i).
% 29.32/29.14  tff(decl_70418, type, 'Behaviors taking place between organisms of the same species.': $i).
% 29.32/29.14  tff(decl_70419, type, 'behavior of social': $i).
% 29.32/29.14  tff(decl_70420, type, 'social behavior': $i).
% 29.32/29.14  tff(decl_70421, type, 'social-behavior': $i).
% 29.32/29.14  tff(decl_70422, type, 'Social-Learning': $i).
% 29.32/29.14  tff(decl_70423, type, 'The modification of behavior based on observations of the behavior or other individuals.': $i).
% 29.32/29.14  tff(decl_70424, type, 'learning of social': $i).
% 29.32/29.14  tff(decl_70425, type, 'social learning': $i).
% 29.32/29.14  tff(decl_70426, type, 'social-learning': $i).
% 29.32/29.14  tff(decl_70427, type, sociobiology_1: $i > $o).
% 29.32/29.14  tff(decl_70428, type, 'Sociobiology': $i).
% 29.32/29.14  tff(decl_70429, type, 'The study of behavior based on the assumption that social behavior results from evolution.': $i).
% 29.32/29.14  tff(decl_70430, type, sociobiology: $i).
% 29.32/29.14  tff(decl_70431, type, 'Sodium': $i).
% 29.32/29.14  tff(decl_70432, type, 'Sodium is a metal atom with atomic number 11. It is represented by the symbol Na.': $i).
% 29.32/29.14  tff(decl_70433, type, 'Na': $i).
% 29.32/29.14  tff(decl_70434, type, sodium: $i).
% 29.32/29.14  tff(decl_70435, type, fn_sodium_4: $i > $i).
% 29.32/29.14  tff(decl_70436, type, fn_sodium_5: $i > $i).
% 29.32/29.14  tff(decl_70437, type, fn_sodium_6: $i > $i).
% 29.32/29.14  tff(decl_70438, type, fn_sodium_7: $i > $i).
% 29.32/29.14  tff(decl_70439, type, fn_sodium_10: $i > $i).
% 29.32/29.14  tff(decl_70440, type, fn_sodium_11: $i > $i).
% 29.32/29.14  tff(decl_70441, type, fn_sodium_12: $i > $i).
% 29.32/29.14  tff(decl_70442, type, fn_sodium_13: $i > $i).
% 29.32/29.14  tff(decl_70443, type, "0.93": $i).
% 29.32/29.14  tff(decl_70444, type, "22.99": $i).
% 29.32/29.14  tff(decl_70445, type, fn_sodium_9: $i > $i).
% 29.32/29.14  tff(decl_70446, type, fn_sodium_14: $i > $i).
% 29.32/29.14  tff(decl_70447, type, fn_sodium_8: $i > $i).
% 29.32/29.14  tff(decl_70448, type, 'Sodium-Channel': $i).
% 29.32/29.14  tff(decl_70449, type, 'An ion channel that conducts sodium ions through a cell\\s plasma membrane.': $i).
% 29.32/29.14  tff(decl_70450, type, 'sodium gated ion channel': $i).
% 29.32/29.14  tff(decl_70451, type, 'sodium-gated-ion-channel': $i).
% 29.32/29.14  tff(decl_70452, type, 'sodium gated ion-channel': $i).
% 29.32/29.14  tff(decl_70453, type, 'channel of sodium': $i).
% 29.32/29.14  tff(decl_70454, type, 'sodium channel': $i).
% 29.32/29.14  tff(decl_70455, type, 'sodium-channel': $i).
% 29.32/29.14  tff(decl_70456, type, fn_sodium_channel_1: $i > $i).
% 29.32/29.14  tff(decl_70457, type, fn_sodium_channel_2: $i > $i).
% 29.32/29.14  tff(decl_70458, type, 'Sodium-Chloride': $i).
% 29.32/29.14  tff(decl_70459, type, 'An ionic compound (i.e., salt) containing one sodium ion and one chloride ion.': $i).
% 29.32/29.14  tff(decl_70460, type, 'table salt': $i).
% 29.32/29.14  tff(decl_70461, type, 'table-salt': $i).
% 29.32/29.14  tff(decl_70462, type, 'common salt': $i).
% 29.32/29.14  tff(decl_70463, type, 'common-salt': $i).
% 29.32/29.14  tff(decl_70464, type, nacl: $i).
% 29.32/29.14  tff(decl_70465, type, 'chloride of sodium': $i).
% 29.32/29.14  tff(decl_70466, type, 'sodium chloride': $i).
% 29.32/29.14  tff(decl_70467, type, 'sodium-chloride': $i).
% 29.32/29.14  tff(decl_70468, type, fn_sodium_chloride_1: $i > $i).
% 29.32/29.14  tff(decl_70469, type, fn_sodium_chloride_2: $i > $i).
% 29.32/29.14  tff(decl_70470, type, fn_sodium_chloride_3: $i > $i).
% 29.32/29.14  tff(decl_70471, type, fn_sodium_chloride_4: $i > $i).
% 29.32/29.14  tff(decl_70472, type, 'Sodium-Chloride-Crystal': $i).
% 29.32/29.14  tff(decl_70473, type, 'The solid form of sodium chloride (table salt).': $i).
% 29.32/29.14  tff(decl_70474, type, 'sodium chloride crystal': $i).
% 29.32/29.14  tff(decl_70475, type, 'sodium-chloride-crystal': $i).
% 29.32/29.14  tff(decl_70476, type, fn_sodium_chloride_crystal_1: $i > $i).
% 29.32/29.14  tff(decl_70477, type, fn_sodium_chloride_crystal_2: $i > $i).
% 29.32/29.14  tff(decl_70478, type, fn_sodium_chloride_crystal_3: $i > $i).
% 29.32/29.14  tff(decl_70479, type, fn_sodium_chloride_crystal_4: $i > $i).
% 29.32/29.14  tff(decl_70480, type, fn_sodium_chloride_crystal_5: $i > $i).
% 29.32/29.14  tff(decl_70481, type, fn_sodium_chloride_crystal_6: $i > $i).
% 29.32/29.14  tff(decl_70482, type, 'Sodium-Chloride-Solution': $i).
% 29.32/29.14  tff(decl_70483, type, 'A solution in which sodium chloride (table salt) has been dissolved in water.': $i).
% 29.32/29.14  tff(decl_70484, type, 'sodium chloride solution': $i).
% 29.32/29.14  tff(decl_70485, type, 'sodium-chloride-solution': $i).
% 29.32/29.14  tff(decl_70486, type, fn_sodium_chloride_solution_1: $i > $i).
% 29.32/29.14  tff(decl_70487, type, fn_sodium_chloride_solution_2: $i > $i).
% 29.32/29.14  tff(decl_70488, type, fn_sodium_chloride_solution_3: $i > $i).
% 29.32/29.14  tff(decl_70489, type, fn_sodium_chloride_solution_4: $i > $i).
% 29.32/29.14  tff(decl_70490, type, fn_sodium_chloride_solution_5: $i > $i).
% 29.32/29.14  tff(decl_70491, type, fn_sodium_chloride_solution_6: $i > $i).
% 29.32/29.14  tff(decl_70492, type, fn_sodium_chloride_solution_7: $i > $i).
% 29.32/29.14  tff(decl_70493, type, fn_sodium_chloride_solution_8: $i > $i).
% 29.32/29.14  tff(decl_70494, type, fn_sodium_chloride_solution_9: $i > $i).
% 29.32/29.14  tff(decl_70495, type, fn_sodium_chloride_solution_10: $i > $i).
% 29.32/29.14  tff(decl_70496, type, fn_sodium_chloride_solution_11: $i > $i).
% 29.32/29.14  tff(decl_70497, type, fn_sodium_chloride_solution_12: $i > $i).
% 29.32/29.14  tff(decl_70498, type, fn_sodium_chloride_solution_13: $i > $i).
% 29.32/29.14  tff(decl_70499, type, sodium_hydroxide_1: $i > $o).
% 29.32/29.14  tff(decl_70500, type, 'Sodium-Hydroxide': $i).
% 29.32/29.14  tff(decl_70501, type, 'A very strong base.': $i).
% 29.32/29.14  tff(decl_70502, type, naoh: $i).
% 29.32/29.14  tff(decl_70503, type, 'hydroxide of sodium': $i).
% 29.32/29.14  tff(decl_70504, type, 'sodium hydroxide': $i).
% 29.32/29.14  tff(decl_70505, type, 'sodium-hydroxide': $i).
% 29.32/29.14  tff(decl_70506, type, strong_base_1: $i > $o).
% 29.32/29.14  tff(decl_70507, type, 'Sodium-Ion': $i).
% 29.32/29.14  tff(decl_70508, type, 'Sodium ion is soluble in water in nearly all of its compounds, and is thus present in great quantities in the Earth\\s oceans and other stagnant bodies of water.': $i).
% 29.32/29.14  tff(decl_70509, type, 'ion of sodium': $i).
% 29.32/29.14  tff(decl_70510, type, 'sodium ion': $i).
% 29.32/29.14  tff(decl_70511, type, 'sodium-ion': $i).
% 29.32/29.14  tff(decl_70512, type, fn_sodium_ion_1: $i > $i).
% 29.32/29.14  tff(decl_70513, type, fn_sodium_ion_2: $i > $i).
% 29.32/29.14  tff(decl_70514, type, fn_sodium_ion_3: $i > $i).
% 29.32/29.14  tff(decl_70515, type, fn_sodium_ion_5: $i > $i).
% 29.32/29.14  tff(decl_70516, type, fn_sodium_ion_6: $i > $i).
% 29.32/29.14  tff(decl_70517, type, fn_sodium_ion_7: $i > $i).
% 29.32/29.14  tff(decl_70518, type, fn_sodium_ion_4: $i > $i).
% 29.32/29.14  tff(decl_70519, type, sodium_ion_substance_1: $i > $o).
% 29.32/29.14  tff(decl_70520, type, 'Sodium-Ion-Substance': $i).
% 29.32/29.14  tff(decl_70521, type, 'Substance composed of sodium ions.': $i).
% 29.32/29.14  tff(decl_70522, type, 'sodium ion substance': $i).
% 29.32/29.14  tff(decl_70523, type, 'sodium-ion-substance': $i).
% 29.32/29.14  tff(decl_70524, type, fn_sodium_ion_substance_1: $i > $i).
% 29.32/29.14  tff(decl_70525, type, 'Sodium-Potassium-Pump': $i).
% 29.32/29.14  tff(decl_70526, type, 'The sodium potassium pump is a transmembrane protein that performs active transport and undergoes conformational changes to move sodium ion out of and potassium ion into a cell across a membrane': $i).
% 29.32/29.14  tff(decl_70527, type, 'sodium potassium carrier protein': $i).
% 29.32/29.14  tff(decl_70528, type, 'sodium-potassium carrier protein': $i).
% 29.32/29.14  tff(decl_70529, type, 'sodium potassium electrogenic pump': $i).
% 29.32/29.14  tff(decl_70530, type, 'sodium-potassium electrogenic pump': $i).
% 29.32/29.14  tff(decl_70531, type, 'sodium potassium transport protein': $i).
% 29.32/29.14  tff(decl_70532, type, 'sodium-potassium transport protein': $i).
% 29.32/29.14  tff(decl_70533, type, 'sodium potassium transmembrane protein': $i).
% 29.32/29.14  tff(decl_70534, type, 'sodium-potassium transmembrane protein': $i).
% 29.32/29.14  tff(decl_70535, type, 'sodium potassium protein': $i).
% 29.32/29.14  tff(decl_70536, type, 'sodium-potassium protein': $i).
% 29.32/29.14  tff(decl_70537, type, 'sodium potassium pump': $i).
% 29.32/29.14  tff(decl_70538, type, 'sodium-potassium pump': $i).
% 29.32/29.14  tff(decl_70539, type, 'sodium-potassium-pump': $i).
% 29.32/29.14  tff(decl_70540, type, fn_sodium_potassium_pump_2: $i > $i).
% 29.32/29.14  tff(decl_70541, type, fn_sodium_potassium_pump_4: $i > $i).
% 29.32/29.14  tff(decl_70542, type, fn_sodium_potassium_pump_5: $i > $i).
% 29.32/29.14  tff(decl_70543, type, fn_sodium_potassium_pump_6: $i > $i).
% 29.32/29.14  tff(decl_70544, type, fn_sodium_potassium_pump_7: $i > $i).
% 29.32/29.14  tff(decl_70545, type, fn_sodium_potassium_pump_8: $i > $i).
% 29.32/29.14  tff(decl_70546, type, fn_sodium_potassium_pump_9: $i > $i).
% 29.32/29.14  tff(decl_70547, type, fn_sodium_potassium_pump_11: $i > $i).
% 29.32/29.14  tff(decl_70548, type, fn_sodium_potassium_pump_13: $i > $i).
% 29.32/29.14  tff(decl_70549, type, fn_sodium_potassium_pump_14: $i > $i).
% 29.32/29.14  tff(decl_70550, type, fn_sodium_potassium_pump_15: $i > $i).
% 29.32/29.14  tff(decl_70551, type, fn_sodium_potassium_pump_18: $i > $i).
% 29.32/29.14  tff(decl_70552, type, fn_sodium_potassium_pump_20: $i > $i).
% 29.32/29.14  tff(decl_70553, type, fn_sodium_potassium_pump_27: $i > $i).
% 29.32/29.14  tff(decl_70554, type, fn_sodium_potassium_pump_34: $i > $i).
% 29.32/29.14  tff(decl_70555, type, fn_sodium_potassium_pump_47: $i > $i).
% 29.32/29.14  tff(decl_70556, type, fn_sodium_potassium_pump_48: $i > $i).
% 29.32/29.14  tff(decl_70557, type, fn_sodium_potassium_pump_49: $i > $i).
% 29.32/29.14  tff(decl_70558, type, fn_sodium_potassium_pump_53: $i > $i).
% 29.32/29.14  tff(decl_70559, type, fn_sodium_potassium_pump_54: $i > $i).
% 29.32/29.14  tff(decl_70560, type, protein_pump_0: $i).
% 29.32/29.14  tff(decl_70561, type, fn_sodium_potassium_pump_43: $i > $i).
% 29.32/29.14  tff(decl_70562, type, fn_sodium_potassium_pump_46: $i > $i).
% 29.32/29.14  tff(decl_70563, type, 'Soil': $i).
% 29.32/29.14  tff(decl_70564, type, 'The component of the earth\\s surface that consists of humus and disintegrated rock.': $i).
% 29.32/29.14  tff(decl_70565, type, dirt: $i).
% 29.32/29.14  tff(decl_70566, type, soil: $i).
% 29.32/29.14  tff(decl_70567, type, fn_soil_3: $i > $i).
% 29.32/29.14  tff(decl_70568, type, soil_depletion_1: $i > $o).
% 29.32/29.14  tff(decl_70569, type, 'Soil-Depletion': $i).
% 29.32/29.14  tff(decl_70570, type, 'The removal of essential nutrients from the soil, without replacing them.': $i).
% 29.32/29.14  tff(decl_70571, type, 'depletion of soil': $i).
% 29.32/29.14  tff(decl_70572, type, 'soil depletion': $i).
% 29.32/29.14  tff(decl_70573, type, 'soil-depletion': $i).
% 29.32/29.14  tff(decl_70574, type, soil_horizon_1: $i > $o).
% 29.32/29.14  tff(decl_70575, type, 'Soil-Horizon': $i).
% 29.32/29.14  tff(decl_70576, type, 'A more or less distinct horizontal layer in a soil, which differs physically from the layers above and below it.': $i).
% 29.32/29.14  tff(decl_70577, type, 'horizon of soil': $i).
% 29.32/29.14  tff(decl_70578, type, 'soil horizon': $i).
% 29.32/29.14  tff(decl_70579, type, 'soil-horizon': $i).
% 29.32/29.14  tff(decl_70580, type, 'Soil-Solution': $i).
% 29.32/29.14  tff(decl_70581, type, 'Soil Solution consists of water molecules and dissolved mineral ions that are not bound tightly to soil particles.': $i).
% 29.32/29.14  tff(decl_70582, type, 'solution of soil': $i).
% 29.32/29.14  tff(decl_70583, type, 'soil solution': $i).
% 29.32/29.14  tff(decl_70584, type, 'soil-solution': $i).
% 29.32/29.14  tff(decl_70585, type, soil_to_xylem_pathway_1: $i > $o).
% 29.32/29.14  tff(decl_70586, type, 'Soil-To-Xylem-Pathway': $i).
% 29.32/29.14  tff(decl_70587, type, 'Water and minerals pass from the soil into the root cortex using soil to xylem pathway.': $i).
% 29.32/29.14  tff(decl_70588, type, 'soil to xylem pathway': $i).
% 29.32/29.14  tff(decl_70589, type, 'soil-to-xylem-pathway': $i).
% 29.32/29.14  tff(decl_70590, type, fn_soil_to_xylem_pathway_1: $i > $i).
% 29.32/29.14  tff(decl_70591, type, fn_soil_to_xylem_pathway_2: $i > $i).
% 29.32/29.14  tff(decl_70592, type, fn_soil_to_xylem_pathway_3: $i > $i).
% 29.32/29.14  tff(decl_70593, type, fn_soil_to_xylem_pathway_4: $i > $i).
% 29.32/29.14  tff(decl_70594, type, fn_soil_to_xylem_pathway_5: $i > $i).
% 29.32/29.14  tff(decl_70595, type, fn_soil_to_xylem_pathway_6: $i > $i).
% 29.32/29.14  tff(decl_70596, type, fn_soil_to_xylem_pathway_7: $i > $i).
% 29.32/29.14  tff(decl_70597, type, fn_soil_to_xylem_pathway_8: $i > $i).
% 29.32/29.14  tff(decl_70598, type, fn_soil_to_xylem_pathway_9: $i > $i).
% 29.32/29.14  tff(decl_70599, type, fn_soil_to_xylem_pathway_10: $i > $i).
% 29.32/29.14  tff(decl_70600, type, fn_soil_to_xylem_pathway_11: $i > $i).
% 29.32/29.14  tff(decl_70601, type, fn_soil_to_xylem_pathway_12: $i > $i).
% 29.32/29.14  tff(decl_70602, type, fn_soil_to_xylem_pathway_13: $i > $i).
% 29.32/29.14  tff(decl_70603, type, fn_soil_to_xylem_pathway_14: $i > $i).
% 29.32/29.14  tff(decl_70604, type, fn_soil_to_xylem_pathway_15: $i > $i).
% 29.32/29.14  tff(decl_70605, type, fn_soil_to_xylem_pathway_16: $i > $i).
% 29.32/29.14  tff(decl_70606, type, fn_soil_to_xylem_pathway_17: $i > $i).
% 29.32/29.14  tff(decl_70607, type, fn_soil_to_xylem_pathway_18: $i > $i).
% 29.32/29.14  tff(decl_70608, type, fn_soil_to_xylem_pathway_19: $i > $i).
% 29.32/29.14  tff(decl_70609, type, fn_soil_to_xylem_pathway_20: $i > $i).
% 29.32/29.14  tff(decl_70610, type, fn_soil_to_xylem_pathway_21: $i > $i).
% 29.32/29.14  tff(decl_70611, type, fn_soil_to_xylem_pathway_22: $i > $i).
% 29.32/29.14  tff(decl_70612, type, fn_soil_to_xylem_pathway_23: $i > $i).
% 29.32/29.14  tff(decl_70613, type, fn_soil_to_xylem_pathway_24: $i > $i).
% 29.32/29.14  tff(decl_70614, type, fn_soil_to_xylem_pathway_25: $i > $i).
% 29.32/29.14  tff(decl_70615, type, fn_soil_to_xylem_pathway_26: $i > $i).
% 29.32/29.14  tff(decl_70616, type, fn_soil_to_xylem_pathway_27: $i > $i).
% 29.32/29.14  tff(decl_70617, type, fn_soil_to_xylem_pathway_28: $i > $i).
% 29.32/29.14  tff(decl_70618, type, fn_soil_to_xylem_pathway_29: $i > $i).
% 29.32/29.14  tff(decl_70619, type, fn_soil_to_xylem_pathway_30: $i > $i).
% 29.32/29.14  tff(decl_70620, type, transmembrane_transport_1: $i > $o).
% 29.32/29.14  tff(decl_70621, type, fn_soil_to_xylem_pathway_31: $i > $i).
% 29.32/29.14  tff(decl_70622, type, fn_soil_to_xylem_pathway_32: $i > $i).
% 29.32/29.14  tff(decl_70623, type, fn_soil_to_xylem_pathway_33: $i > $i).
% 29.32/29.14  tff(decl_70624, type, fn_soil_to_xylem_pathway_34: $i > $i).
% 29.32/29.14  tff(decl_70625, type, fn_soil_to_xylem_pathway_35: $i > $i).
% 29.32/29.14  tff(decl_70626, type, fn_soil_to_xylem_pathway_36: $i > $i).
% 29.32/29.14  tff(decl_70627, type, fn_soil_to_xylem_pathway_37: $i > $i).
% 29.32/29.14  tff(decl_70628, type, fn_soil_to_xylem_pathway_38: $i > $i).
% 29.32/29.14  tff(decl_70629, type, fn_soil_to_xylem_pathway_39: $i > $i).
% 29.32/29.14  tff(decl_70630, type, fn_soil_to_xylem_pathway_40: $i > $i).
% 29.32/29.14  tff(decl_70631, type, fn_soil_to_xylem_pathway_41: $i > $i).
% 29.32/29.14  tff(decl_70632, type, fn_soil_to_xylem_pathway_42: $i > $i).
% 29.32/29.14  tff(decl_70633, type, fn_soil_to_xylem_pathway_43: $i > $i).
% 29.32/29.14  tff(decl_70634, type, fn_soil_to_xylem_pathway_44: $i > $i).
% 29.32/29.14  tff(decl_70635, type, fn_soil_to_xylem_pathway_45: $i > $i).
% 29.32/29.14  tff(decl_70636, type, fn_soil_to_xylem_pathway_46: $i > $i).
% 29.32/29.14  tff(decl_70637, type, fn_soil_to_xylem_pathway_47: $i > $i).
% 29.32/29.14  tff(decl_70638, type, fn_soil_to_xylem_pathway_48: $i > $i).
% 29.32/29.14  tff(decl_70639, type, fn_soil_to_xylem_pathway_49: $i > $i).
% 29.32/29.14  tff(decl_70640, type, fn_soil_to_xylem_pathway_50: $i > $i).
% 29.32/29.14  tff(decl_70641, type, fn_xylem_32: $i > $i).
% 29.32/29.14  tff(decl_70642, type, fn_xylem_16: $i > $i).
% 29.32/29.14  tff(decl_70643, type, fn_transmembrane_transport_3: $i > $i).
% 29.32/29.14  tff(decl_70644, type, fn_transmembrane_transport_2: $i > $i).
% 29.32/29.14  tff(decl_70645, type, fn_symplastic_transport_1: $i > $i).
% 29.32/29.14  tff(decl_70646, type, 'Solid-Substance': $i).
% 29.32/29.14  tff(decl_70647, type, 'A substance in the solid state at room temperature': $i).
% 29.32/29.14  tff(decl_70648, type, solid: $i).
% 29.32/29.14  tff(decl_70649, type, 'substance of solid': $i).
% 29.32/29.14  tff(decl_70650, type, 'solid substance': $i).
% 29.32/29.14  tff(decl_70651, type, 'solid-substance': $i).
% 29.32/29.14  tff(decl_70652, type, fn_solid_substance_2: $i > $i).
% 29.32/29.14  tff(decl_70653, type, 'Solid-Support': $i).
% 29.32/29.14  tff(decl_70654, type, 'A carrier substance, such as nitrocellulose  PVDF or nylon membrane, used in a blotting process.': $i).
% 29.32/29.14  tff(decl_70655, type, 'nylon membrane': $i).
% 29.32/29.14  tff(decl_70656, type, 'nylon-membrane': $i).
% 29.32/29.14  tff(decl_70657, type, nitrocellose: $i).
% 29.32/29.14  tff(decl_70658, type, 'nylon paper': $i).
% 29.32/29.14  tff(decl_70659, type, 'nylon-paper': $i).
% 29.32/29.14  tff(decl_70660, type, 'support of solid': $i).
% 29.32/29.14  tff(decl_70661, type, 'solid support': $i).
% 29.32/29.14  tff(decl_70662, type, 'solid-support': $i).
% 29.32/29.14  tff(decl_70663, type, 'Solubility-Constant': $i).
% 29.32/29.14  tff(decl_70664, type, 'constant of solubility': $i).
% 29.32/29.14  tff(decl_70665, type, 'solubility constant': $i).
% 29.32/29.14  tff(decl_70666, type, 'solubility-constant': $i).
% 29.32/29.14  tff(decl_70667, type, 'Solubility-Value': $i).
% 29.32/29.14  tff(decl_70668, type, 'The solubility of a Chemical': $i).
% 29.32/29.14  tff(decl_70669, type, 'Solubility is commonly expressed as a concentration, either by mass (g of solute per kg of solvent, g per dL of solvent), mass concentration, molarity, molality, mole fraction or other similar descriptions of concentration. The maximum equilibrium amount of solute that can dissolve per amount of solvent is the solubility of that solute in that solvent under the specified conditions. Temperature has a positive impact on solubility.': $i).
% 29.32/29.14  tff(decl_70670, type, 'solubility in water': $i).
% 29.32/29.14  tff(decl_70671, type, 'solubility-in-water': $i).
% 29.32/29.14  tff(decl_70672, type, 'solubility in lipid': $i).
% 29.32/29.14  tff(decl_70673, type, 'solubility-in-lipid': $i).
% 29.32/29.14  tff(decl_70674, type, solubility: $i).
% 29.32/29.14  tff(decl_70675, type, 'value of solubility': $i).
% 29.32/29.14  tff(decl_70676, type, 'solubility value': $i).
% 29.32/29.14  tff(decl_70677, type, 'solubility-value': $i).
% 29.32/29.14  tff(decl_70678, type, soluble_substance_1: $i > $o).
% 29.32/29.14  tff(decl_70679, type, 'Soluble-Substance': $i).
% 29.32/29.14  tff(decl_70680, type, 'Substance which dissolves in a fluid.': $i).
% 29.32/29.14  tff(decl_70681, type, 'A substance capable of being dissolved.': $i).
% 29.32/29.14  tff(decl_70682, type, 'soluble substance': $i).
% 29.32/29.14  tff(decl_70683, type, 'soluble-substance': $i).
% 29.32/29.14  tff(decl_70684, type, 'Solute': $i).
% 29.32/29.14  tff(decl_70685, type, 'A solute is a substance dissolved in a solvent to make a homogenous mixture': $i).
% 29.32/29.14  tff(decl_70686, type, solute: $i).
% 29.32/29.14  tff(decl_70687, type, 'Solution': $i).
% 29.32/29.14  tff(decl_70688, type, 'A solution is a mixture of substances that has a uniform composition; a homogeneous mixture.': $i).
% 29.32/29.14  tff(decl_70689, type, solution: $i).
% 29.32/29.14  tff(decl_70690, type, fn_solution_3: $i > $i).
% 29.32/29.14  tff(decl_70691, type, 'Solution-containing-labeled-phage': $i).
% 29.32/29.14  tff(decl_70692, type, 'A mixture where viruses are radioactively labeled.  Used in the Hershey-Chase experiment to determine whether proteins or DNA carried genetic information.': $i).
% 29.32/29.14  tff(decl_70693, type, 'solution containing labeled phage': $i).
% 29.32/29.14  tff(decl_70694, type, 'solution-containing-labeled-phage': $i).
% 29.32/29.14  tff(decl_70695, type, 'Solvent': $i).
% 29.32/29.14  tff(decl_70696, type, 'The substance in which another substance is dissolved to produce a solution.': $i).
% 29.32/29.14  tff(decl_70697, type, solvent: $i).
% 29.32/29.14  tff(decl_70698, type, 'Somatic-Cell': $i).
% 29.32/29.14  tff(decl_70699, type, 'Somatic cells include all body cells in multicellular organisms except gametes or those cells which produce gametes.': $i).
% 29.32/29.14  tff(decl_70700, type, 'somatic cell': $i).
% 29.32/29.14  tff(decl_70701, type, 'somatic-cell': $i).
% 29.32/29.14  tff(decl_70702, type, somite_1: $i > $o).
% 29.32/29.14  tff(decl_70703, type, 'Somite': $i).
% 29.32/29.14  tff(decl_70704, type, 'In vertebrate embryos, one of a series of paired blocks of mesoderm lying on either side of the notochord.': $i).
% 29.32/29.14  tff(decl_70705, type, somite: $i).
% 29.32/29.14  tff(decl_70706, type, 'Sonic-Hedgehog-Factor': $i).
% 29.32/29.14  tff(decl_70707, type, 'A protein growth factor that is coded by the sonic hedgehog gene. It is secreted by cells of the zone of polarizing activity (ZPA) and involved in limb formation.': $i).
% 29.32/29.14  tff(decl_70708, type, 'sonic hedgehog factor': $i).
% 29.32/29.14  tff(decl_70709, type, 'sonic-hedgehog-factor': $i).
% 29.32/29.14  tff(decl_70710, type, 'Soredium': $i).
% 29.32/29.14  tff(decl_70711, type, 'In lichens, a reproductive structure consisting of a small group of fungal hyphae wrapped around algal cells.': $i).
% 29.32/29.14  tff(decl_70712, type, soredium: $i).
% 29.32/29.14  tff(decl_70713, type, sorus_1: $i > $o).
% 29.32/29.14  tff(decl_70714, type, 'Sorus': $i).
% 29.32/29.14  tff(decl_70715, type, 'A cluster of sporangia on the sporophyll of a fern. The arrangement of sori is a useful character in fern identification.': $i).
% 29.32/29.14  tff(decl_70716, type, sori: $i).
% 29.32/29.14  tff(decl_70717, type, sorus: $i).
% 29.32/29.14  tff(decl_70718, type, 'Sound': $i).
% 29.32/29.14  tff(decl_70719, type, 'Mechanical energy vibrations that propagate through a solid, liquid, or gas medium.': $i).
% 29.32/29.14  tff(decl_70720, type, sound: $i).
% 29.32/29.14  tff(decl_70721, type, fn_sound_1: $i > $i).
% 29.32/29.14  tff(decl_70722, type, 'Southern-Blotting': $i).
% 29.32/29.14  tff(decl_70723, type, 'A technique that enables specific nucleotide sequences to be detected in a sample of DNA. It involves gel electrophoresis of DNA molecules and their transfer to a membrane (blotting), followed by nucleic acid hybridization with a labeled probe.': $i).
% 29.32/29.14  tff(decl_70724, type, 'southern hybridization': $i).
% 29.32/29.14  tff(decl_70725, type, 'southern blotting': $i).
% 29.32/29.14  tff(decl_70726, type, 'southern-blotting': $i).
% 29.32/29.14  tff(decl_70727, type, fn_southern_blotting_1: $i > $i).
% 29.32/29.14  tff(decl_70728, type, fn_southern_blotting_2: $i > $i).
% 29.32/29.14  tff(decl_70729, type, fn_southern_blotting_3: $i > $i).
% 29.32/29.14  tff(decl_70730, type, fn_southern_blotting_4: $i > $i).
% 29.32/29.14  tff(decl_70731, type, fn_southern_blotting_5: $i > $i).
% 29.32/29.14  tff(decl_70732, type, fn_southern_blotting_7: $i > $i).
% 29.32/29.14  tff(decl_70733, type, fn_southern_blotting_8: $i > $i).
% 29.32/29.14  tff(decl_70734, type, fn_southern_blotting_9: $i > $i).
% 29.32/29.14  tff(decl_70735, type, fn_southern_blotting_10: $i > $i).
% 29.32/29.14  tff(decl_70736, type, fn_southern_blotting_11: $i > $i).
% 29.32/29.14  tff(decl_70737, type, fn_southern_blotting_12: $i > $i).
% 29.32/29.14  tff(decl_70738, type, fn_southern_blotting_13: $i > $i).
% 29.32/29.14  tff(decl_70739, type, fn_southern_blotting_16: $i > $i).
% 29.32/29.14  tff(decl_70740, type, 'Soyabean-Plant': $i).
% 29.32/29.14  tff(decl_70741, type, 'The soybean is a species of legume native to East Asia. The plant is classed as an oilseed rather than a pulse.': $i).
% 29.32/29.14  tff(decl_70742, type, 'soya bean': $i).
% 29.32/29.14  tff(decl_70743, type, soyabean: $i).
% 29.32/29.14  tff(decl_70744, type, soybean: $i).
% 29.32/29.14  tff(decl_70745, type, 'soybean plant': $i).
% 29.32/29.14  tff(decl_70746, type, 'soyabean plant': $i).
% 29.32/29.14  tff(decl_70747, type, 'soyabean-plant': $i).
% 29.32/29.14  tff(decl_70748, type, fn_soyabean_plant_1: $i > $i).
% 29.32/29.14  tff(decl_70749, type, fn_soyabean_plant_2: $i > $i).
% 29.32/29.14  tff(decl_70750, type, fn_soyabean_plant_3: $i > $i).
% 29.32/29.14  tff(decl_70751, type, fn_soyabean_plant_4: $i > $i).
% 29.32/29.14  tff(decl_70752, type, fn_soyabean_plant_5: $i > $i).
% 29.32/29.14  tff(decl_70753, type, fn_soyabean_plant_6: $i > $i).
% 29.32/29.14  tff(decl_70754, type, sp3_orbital_1: $i > $o).
% 29.32/29.14  tff(decl_70755, type, 'SP3-Orbital': $i).
% 29.32/29.14  tff(decl_70756, type, 'One of the four hybrid orbitals formed by hybridization of an s orbital and three p orbitals.': $i).
% 29.32/29.14  tff(decl_70757, type, 'sp3 orbital': $i).
% 29.32/29.14  tff(decl_70758, type, 'sp3-orbital': $i).
% 29.32/29.14  tff(decl_70759, type, fn_sp3_orbital_1: $i > $i).
% 29.32/29.14  tff(decl_70760, type, fn_sp3_orbital_2: $i > $i).
% 29.32/29.14  tff(decl_70761, type, fn_sp3_orbital_3: $i > $i).
% 29.32/29.14  tff(decl_70762, type, fn_sp3_orbital_4: $i > $i).
% 29.32/29.14  tff(decl_70763, type, fn_sp3_orbital_5: $i > $i).
% 29.32/29.14  tff(decl_70764, type, 'Space': $i).
% 29.32/29.14  tff(decl_70765, type, 'A blank or empty area.': $i).
% 29.32/29.14  tff(decl_70766, type, space: $i).
% 29.32/29.14  tff(decl_70767, type, 'Spatial-Entity': $i).
% 29.32/29.14  tff(decl_70768, type, toward: $i).
% 29.32/29.14  tff(decl_70769, type, 'text is southwest': $i).
% 29.32/29.14  tff(decl_70770, type, 'text-is-southwest': $i).
% 29.32/29.14  tff(decl_70771, type, site: $i).
% 29.32/29.14  tff(decl_70772, type, path: $i).
% 29.32/29.14  tff(decl_70773, type, source: $i).
% 29.32/29.14  tff(decl_70774, type, origin: $i).
% 29.32/29.14  tff(decl_70775, type, 'is facing': $i).
% 29.32/29.14  tff(decl_70776, type, 'is-facing': $i).
% 29.32/29.14  tff(decl_70777, type, 'has state': $i).
% 29.32/29.14  tff(decl_70778, type, 'has-state': $i).
% 29.32/29.14  tff(decl_70779, type, 'has habitat': $i).
% 29.32/29.14  tff(decl_70780, type, 'has-habitat': $i).
% 29.32/29.14  tff(decl_70781, type, content: $i).
% 29.32/29.14  tff(decl_70782, type, complement: $i).
% 29.32/29.14  tff(decl_70783, type, abut: $i).
% 29.32/29.14  tff(decl_70784, type, location: $i).
% 29.32/29.14  tff(decl_70785, type, 'spatial entity': $i).
% 29.32/29.14  tff(decl_70786, type, 'spatial-entity': $i).
% 29.32/29.14  tff(decl_70787, type, 'Spatial-Learning': $i).
% 29.32/29.14  tff(decl_70788, type, 'The part of memory that is responsible for recording information about the spatial structure of the environment.': $i).
% 29.32/29.14  tff(decl_70789, type, 'spatial learning': $i).
% 29.32/29.14  tff(decl_70790, type, 'spatial-learning': $i).
% 29.32/29.14  tff(decl_70791, type, spatial_relation_1: $i > $o).
% 29.32/29.14  tff(decl_70792, type, 'Spatial-Relation': $i).
% 29.32/29.14  tff(decl_70793, type, 'A spatial relation is a relation between an entity or event, and a spatial entity. In such relations, the entity or event is placed in absolute or relative position to the region denoted by the spatial entity. If a relation is a spatial relation, then its inverse is also a spatial relation.': $i).
% 29.32/29.14  tff(decl_70794, type, 'spatial relation': $i).
% 29.32/29.14  tff(decl_70795, type, 'spatial-relation': $i).
% 29.32/29.14  tff(decl_70796, type, spatial_summation_1: $i > $o).
% 29.32/29.14  tff(decl_70797, type, 'Spatial-Summation': $i).
% 29.32/29.14  tff(decl_70798, type, 'The result of neural integration, in which the sum of multiple EPSPs and IPSPs determine the membrane potential of a post-synaptic neuron.': $i).
% 29.32/29.14  tff(decl_70799, type, 'spatial summation': $i).
% 29.32/29.14  tff(decl_70800, type, 'spatial-summation': $i).
% 29.32/29.14  tff(decl_70801, type, 'Speak': $i).
% 29.32/29.14  tff(decl_70802, type, talk: $i).
% 29.32/29.14  tff(decl_70803, type, speak: $i).
% 29.32/29.14  tff(decl_70804, type, verbalize: $i).
% 29.32/29.14  tff(decl_70805, type, verbalise: $i).
% 29.32/29.14  tff(decl_70806, type, fn_speak_1: $i > $i).
% 29.32/29.14  tff(decl_70807, type, fn_speak_2: $i > $i).
% 29.32/29.14  tff(decl_70808, type, 'Specialised-Organ': $i).
% 29.32/29.14  tff(decl_70809, type, 'Organ which serves a specialized function in animals.': $i).
% 29.32/29.14  tff(decl_70810, type, 'specialised organ': $i).
% 29.32/29.14  tff(decl_70811, type, 'specialised-organ': $i).
% 29.32/29.14  tff(decl_70812, type, fn_specialized_transduction_5: $i > $i).
% 29.32/29.14  tff(decl_70813, type, 'Specialized-Transduction': $i).
% 29.32/29.14  tff(decl_70814, type, 'A type of viral transduction in which the phage transfers only those gene near the prophage site on the bacterial chromosome.': $i).
% 29.32/29.14  tff(decl_70815, type, 'specialized transduction': $i).
% 29.32/29.14  tff(decl_70816, type, 'specialized-transduction': $i).
% 29.32/29.14  tff(decl_70817, type, fn_specialized_transduction_2: $i > $i).
% 29.32/29.14  tff(decl_70818, type, fn_specialized_transduction_3: $i > $i).
% 29.32/29.14  tff(decl_70819, type, fn_specialized_transduction_4: $i > $i).
% 29.32/29.14  tff(decl_70820, type, fn_transduction_gene_transfer_4: $i > $i).
% 29.32/29.14  tff(decl_70821, type, 'Speciation': $i).
% 29.32/29.14  tff(decl_70822, type, 'The evolutionary process by which new species are formed.': $i).
% 29.32/29.14  tff(decl_70823, type, speciate: $i).
% 29.32/29.14  tff(decl_70824, type, speciation: $i).
% 29.32/29.14  tff(decl_70825, type, 'Species': $i).
% 29.32/29.14  tff(decl_70826, type, 'A population that is reproductively isolated from other populations. In other words, members of a species have the potential to mate with each other and produce viable, fertile offspring; however, they do not produce viable, fertile offspring if they mate with individuals from another species.': $i).
% 29.32/29.14  tff(decl_70827, type, species: $i).
% 29.32/29.14  tff(decl_70828, type, 'Species-Area-Curve': $i).
% 29.32/29.14  tff(decl_70829, type, 'A model that quantifies the relationship between geographic area of a community and the number of species in that community.': $i).
% 29.32/29.14  tff(decl_70830, type, 'species area curve': $i).
% 29.32/29.14  tff(decl_70831, type, 'species-area curve': $i).
% 29.32/29.14  tff(decl_70832, type, 'species-area-curve': $i).
% 29.32/29.14  tff(decl_70833, type, 'Species-Concept': $i).
% 29.32/29.14  tff(decl_70834, type, 'Attempts to explain the very existence of species as discrete units in the diversity of life.': $i).
% 29.32/29.14  tff(decl_70835, type, 'concept of species': $i).
% 29.32/29.14  tff(decl_70836, type, 'species concept': $i).
% 29.32/29.14  tff(decl_70837, type, 'species-concept': $i).
% 29.32/29.14  tff(decl_70838, type, 'Species-Interactions': $i).
% 29.32/29.14  tff(decl_70839, type, 'Behaviors involving specific types of interactions between or within species.': $i).
% 29.32/29.14  tff(decl_70840, type, 'species interaction': $i).
% 29.32/29.14  tff(decl_70841, type, 'species-interaction': $i).
% 29.32/29.14  tff(decl_70842, type, 'Species-Isolation': $i).
% 29.32/29.14  tff(decl_70843, type, 'An evolutionary process in which members of a species become isolated from one another and are unable to produce viable offspring.': $i).
% 29.32/29.14  tff(decl_70844, type, 'isolation of species': $i).
% 29.32/29.14  tff(decl_70845, type, 'species isolation': $i).
% 29.32/29.14  tff(decl_70846, type, 'species-isolation': $i).
% 29.32/29.14  tff(decl_70847, type, specific_heat_1: $i > $o).
% 29.32/29.14  tff(decl_70848, type, 'Specific-Heat': $i).
% 29.32/29.14  tff(decl_70849, type, 'The amount of heat that must be absorbed or lost for 1 g of a substance to change its temperature by 1 degree C.': $i).
% 29.32/29.14  tff(decl_70850, type, 'heat capacity': $i).
% 29.32/29.14  tff(decl_70851, type, 'heat-capacity': $i).
% 29.32/29.14  tff(decl_70852, type, 'specific heat capacity': $i).
% 29.32/29.14  tff(decl_70853, type, 'specific-heat-capacity': $i).
% 29.32/29.14  tff(decl_70854, type, sh: $i).
% 29.32/29.14  tff(decl_70855, type, 'heat of specific': $i).
% 29.32/29.14  tff(decl_70856, type, 'specific heat': $i).
% 29.32/29.14  tff(decl_70857, type, 'specific-heat': $i).
% 29.32/29.14  tff(decl_70858, type, 'Specific-Heat-Constant': $i).
% 29.32/29.14  tff(decl_70859, type, 'specific heat constant': $i).
% 29.32/29.14  tff(decl_70860, type, 'specific-heat-constant': $i).
% 29.32/29.14  tff(decl_70861, type, specific_heat_scale_1: $i > $o).
% 29.32/29.14  tff(decl_70862, type, 'Specific-Heat-Scale': $i).
% 29.32/29.14  tff(decl_70863, type, 'specific heat scale': $i).
% 29.32/29.14  tff(decl_70864, type, 'specific-heat-scale': $i).
% 29.32/29.14  tff(decl_70865, type, 'Specific-Heat-Value': $i).
% 29.32/29.14  tff(decl_70866, type, 'specific heat value': $i).
% 29.32/29.14  tff(decl_70867, type, 'specific-heat-value': $i).
% 29.32/29.14  tff(decl_70868, type, 'Specific-Surface-Area-Constant': $i).
% 29.32/29.14  tff(decl_70869, type, 'specific surface area constant': $i).
% 29.32/29.14  tff(decl_70870, type, 'specific-surface-area-constant': $i).
% 29.32/29.14  tff(decl_70871, type, specific_surface_area_scale_1: $i > $o).
% 29.32/29.14  tff(decl_70872, type, 'Specific-Surface-Area-Scale': $i).
% 29.32/29.14  tff(decl_70873, type, 'specific surface area scale': $i).
% 29.32/29.14  tff(decl_70874, type, 'specific-surface-area-scale': $i).
% 29.32/29.14  tff(decl_70875, type, 'Specific-Surface-Area-Value': $i).
% 29.32/29.14  tff(decl_70876, type, 'surface to volume ratio': $i).
% 29.32/29.14  tff(decl_70877, type, 'surface to mass ratio': $i).
% 29.32/29.14  tff(decl_70878, type, 'specific surface area': $i).
% 29.32/29.14  tff(decl_70879, type, 'specific-surface-area': $i).
% 29.32/29.14  tff(decl_70880, type, 'specific surface area value': $i).
% 29.32/29.14  tff(decl_70881, type, 'specific-surface-area-value': $i).
% 29.32/29.14  tff(decl_70882, type, specification_1: $i > $o).
% 29.32/29.14  tff(decl_70883, type, 'Specification': $i).
% 29.32/29.14  tff(decl_70884, type, 'A description of something in terms of specific values of its features': $i).
% 29.32/29.14  tff(decl_70885, type, specification: $i).
% 29.32/29.14  tff(decl_70886, type, spec: $i).
% 29.32/29.14  tff(decl_70887, type, fn_specification_1: $i > $i).
% 29.32/29.14  tff(decl_70888, type, specify_1: $i > $o).
% 29.32/29.14  tff(decl_70889, type, fn_specification_2: $i > $i).
% 29.32/29.14  tff(decl_70890, type, 'Specificity-of-Base-Pairing': $i).
% 29.32/29.14  tff(decl_70891, type, 'Each nucleotide pairs with only one other nucleotide, A with T and C with G.  Each pair is held together by hydrogen bonds between the nitrogenous bases of the nucleotide.': $i).
% 29.32/29.14  tff(decl_70892, type, 'specificity of base pairing': $i).
% 29.32/29.14  tff(decl_70893, type, 'specificity-of-base-pairing': $i).
% 29.32/29.14  tff(decl_70894, type, fn_specificity_of_base_pairing_1: $i > $i).
% 29.32/29.14  tff(decl_70895, type, fn_specificity_of_base_pairing_2: $i > $i).
% 29.32/29.14  tff(decl_70896, type, fn_specificity_of_base_pairing_3: $i > $i).
% 29.32/29.14  tff(decl_70897, type, 'Specify': $i).
% 29.32/29.14  tff(decl_70898, type, stipulate: $i).
% 29.32/29.14  tff(decl_70899, type, qualify: $i).
% 29.32/29.14  tff(decl_70900, type, specify: $i).
% 29.32/29.14  tff(decl_70901, type, define: $i).
% 29.32/29.14  tff(decl_70902, type, delineate: $i).
% 29.32/29.14  tff(decl_70903, type, delimit: $i).
% 29.32/29.14  tff(decl_70904, type, delimitate: $i).
% 29.32/29.14  tff(decl_70905, type, limit: $i).
% 29.32/29.14  tff(decl_70906, type, particularize: $i).
% 29.32/29.14  tff(decl_70907, type, particularise: $i).
% 29.32/29.14  tff(decl_70908, type, specialize: $i).
% 29.32/29.14  tff(decl_70909, type, specialise: $i).
% 29.32/29.14  tff(decl_70910, type, 'pin down': $i).
% 29.32/29.14  tff(decl_70911, type, pin_down: $i).
% 29.32/29.14  tff(decl_70912, type, 'peg down': $i).
% 29.32/29.14  tff(decl_70913, type, peg_down: $i).
% 29.32/29.14  tff(decl_70914, type, 'nail down': $i).
% 29.32/29.14  tff(decl_70915, type, nail_down: $i).
% 29.32/29.14  tff(decl_70916, type, 'narrow down': $i).
% 29.32/29.14  tff(decl_70917, type, narrow_down: $i).
% 29.32/29.14  tff(decl_70918, type, narrow: $i).
% 29.32/29.14  tff(decl_70919, type, fn_specify_1: $i > $i).
% 29.32/29.14  tff(decl_70920, type, fn_specify_2: $i > $i).
% 29.32/29.14  tff(decl_70921, type, 'Specimen': $i).
% 29.32/29.14  tff(decl_70922, type, 'A specimen is a portion or quantity of material for use in testing, examination, or study.': $i).
% 29.32/29.14  tff(decl_70923, type, specimen: $i).
% 29.32/29.14  tff(decl_70924, type, 'Specimen-Stained-With-Fluorescent-Substance': $i).
% 29.32/29.14  tff(decl_70925, type, 'These specimen does not possess fluorescence property of their own. For their study by fluorescent microscopy, these have to be stained with a fluorescent molecule or marker by the procedure of fluorescent staining.': $i).
% 29.32/29.14  tff(decl_70926, type, 'specimen stained with fluorescent substance': $i).
% 29.32/29.14  tff(decl_70927, type, 'specimen-stained-with-fluorescent-substance': $i).
% 29.32/29.14  tff(decl_70928, type, 'Spectrophotometer': $i).
% 29.32/29.14  tff(decl_70929, type, 'An instrument used to determine the intensity of various wavelengths in a spectrum of light.': $i).
% 29.32/29.14  tff(decl_70930, type, spectrophotometer: $i).
% 29.32/29.14  tff(decl_70931, type, fn_spectrophotometer_1: $i > $i).
% 29.32/29.14  tff(decl_70932, type, fn_spectrophotometer_2: $i > $i).
% 29.32/29.14  tff(decl_70933, type, fn_spectrophotometer_3: $i > $i).
% 29.32/29.14  tff(decl_70934, type, fn_spectrophotometer_4: $i > $i).
% 29.32/29.14  tff(decl_70935, type, fn_spectrophotometer_5: $i > $i).
% 29.32/29.14  tff(decl_70936, type, fn_spectrophotometer_6: $i > $i).
% 29.32/29.14  tff(decl_70937, type, fn_spectrophotometer_7: $i > $i).
% 29.32/29.14  tff(decl_70938, type, fn_spectrophotometer_8: $i > $i).
% 29.32/29.14  tff(decl_70939, type, fn_spectrophotometer_9: $i > $i).
% 29.32/29.14  tff(decl_70940, type, fn_spectrophotometer_10: $i > $i).
% 29.32/29.14  tff(decl_70941, type, fn_spectrophotometer_11: $i > $i).
% 29.32/29.14  tff(decl_70942, type, fn_spectrophotometer_12: $i > $i).
% 29.32/29.14  tff(decl_70943, type, fn_spectrophotometer_13: $i > $i).
% 29.32/29.14  tff(decl_70944, type, fn_spectrophotometer_14: $i > $i).
% 29.32/29.14  tff(decl_70945, type, 'Spectrophotometry': $i).
% 29.32/29.14  tff(decl_70946, type, 'The study of light absorption by using the instrument, spectrophotometer.  Absorption occurs when energy from the radiative source is absorbed by the material. Absorption is often determined by measuring the fraction of energy transmitted through the material; absorption will decrease the transmitted portion.': $i).
% 29.32/29.14  tff(decl_70947, type, 'measure absorption': $i).
% 29.32/29.14  tff(decl_70948, type, spectrophotometry: $i).
% 29.32/29.14  tff(decl_70949, type, fn_spectrophotometry_1: $i > $i).
% 29.32/29.14  tff(decl_70950, type, fn_spectrophotometry_2: $i > $i).
% 29.32/29.14  tff(decl_70951, type, fn_spectrophotometry_3: $i > $i).
% 29.32/29.14  tff(decl_70952, type, fn_spectrophotometry_4: $i > $i).
% 29.32/29.14  tff(decl_70953, type, fn_spectrophotometry_5: $i > $i).
% 29.32/29.14  tff(decl_70954, type, fn_spectrophotometry_6: $i > $i).
% 29.32/29.14  tff(decl_70955, type, fn_spectrophotometry_7: $i > $i).
% 29.32/29.14  tff(decl_70956, type, fn_spectrophotometry_8: $i > $i).
% 29.32/29.14  tff(decl_70957, type, fn_spectrophotometry_9: $i > $i).
% 29.32/29.14  tff(decl_70958, type, fn_spectrophotometry_10: $i > $i).
% 29.32/29.14  tff(decl_70959, type, fn_spectrophotometry_11: $i > $i).
% 29.32/29.14  tff(decl_70960, type, fn_spectrophotometry_12: $i > $i).
% 29.32/29.14  tff(decl_70961, type, fn_spectrophotometry_13: $i > $i).
% 29.32/29.14  tff(decl_70962, type, fn_spectrophotometry_14: $i > $i).
% 29.32/29.14  tff(decl_70963, type, fn_spectrophotometry_15: $i > $i).
% 29.32/29.14  tff(decl_70964, type, fn_spectrophotometry_16: $i > $i).
% 29.32/29.14  tff(decl_70965, type, fn_spectrophotometry_17: $i > $i).
% 29.32/29.14  tff(decl_70966, type, fn_spectrophotometry_18: $i > $i).
% 29.32/29.14  tff(decl_70967, type, fn_spectrophotometry_19: $i > $i).
% 29.32/29.14  tff(decl_70968, type, fn_spectrophotometry_20: $i > $i).
% 29.32/29.14  tff(decl_70969, type, fn_spectrophotometry_21: $i > $i).
% 29.32/29.14  tff(decl_70970, type, fn_spectrophotometry_22: $i > $i).
% 29.32/29.14  tff(decl_70971, type, fn_spectrophotometry_23: $i > $i).
% 29.32/29.14  tff(decl_70972, type, fn_spectrophotometry_24: $i > $i).
% 29.32/29.14  tff(decl_70973, type, fn_spectrophotometry_25: $i > $i).
% 29.32/29.14  tff(decl_70974, type, fn_spectrophotometry_26: $i > $i).
% 29.32/29.14  tff(decl_70975, type, fn_spectrophotometry_27: $i > $i).
% 29.32/29.14  tff(decl_70976, type, fn_spectrophotometry_28: $i > $i).
% 29.32/29.14  tff(decl_70977, type, fn_spectrophotometry_29: $i > $i).
% 29.32/29.14  tff(decl_70978, type, fn_spectrophotometry_30: $i > $i).
% 29.32/29.14  tff(decl_70979, type, fn_spectrophotometry_31: $i > $i).
% 29.32/29.14  tff(decl_70980, type, fn_spectrophotometry_32: $i > $i).
% 29.32/29.14  tff(decl_70981, type, fn_spectrophotometry_33: $i > $i).
% 29.32/29.14  tff(decl_70982, type, fn_spectrophotometry_34: $i > $i).
% 29.32/29.14  tff(decl_70983, type, fn_spectrophotometry_35: $i > $i).
% 29.32/29.14  tff(decl_70984, type, fn_spectrophotometry_36: $i > $i).
% 29.32/29.14  tff(decl_70985, type, fn_spectrophotometry_37: $i > $i).
% 29.32/29.14  tff(decl_70986, type, fn_spectrophotometry_38: $i > $i).
% 29.32/29.14  tff(decl_70987, type, fn_spectrophotometry_39: $i > $i).
% 29.32/29.14  tff(decl_70988, type, fn_spectrophotometry_40: $i > $i).
% 29.32/29.14  tff(decl_70989, type, fn_spectrophotometry_41: $i > $i).
% 29.32/29.14  tff(decl_70990, type, fn_spectrophotometry_42: $i > $i).
% 29.32/29.14  tff(decl_70991, type, fn_spectrophotometry_43: $i > $i).
% 29.32/29.14  tff(decl_70992, type, fn_spectrophotometry_44: $i > $i).
% 29.32/29.14  tff(decl_70993, type, fn_spectrophotometry_45: $i > $i).
% 29.32/29.14  tff(decl_70994, type, fn_spectrophotometry_46: $i > $i).
% 29.32/29.14  tff(decl_70995, type, fn_spectrophotometry_47: $i > $i).
% 29.32/29.14  tff(decl_70996, type, fn_spectrophotometry_48: $i > $i).
% 29.32/29.14  tff(decl_70997, type, fn_spectrophotometry_49: $i > $i).
% 29.32/29.14  tff(decl_70998, type, fn_spectrophotometry_50: $i > $i).
% 29.32/29.14  tff(decl_70999, type, fn_spectrophotometry_51: $i > $i).
% 29.32/29.14  tff(decl_71000, type, fn_spectrophotometry_52: $i > $i).
% 29.32/29.14  tff(decl_71001, type, fn_spectrophotometry_53: $i > $i).
% 29.32/29.14  tff(decl_71002, type, fn_spectrophotometry_54: $i > $i).
% 29.32/29.14  tff(decl_71003, type, fn_spectrophotometry_55: $i > $i).
% 29.32/29.14  tff(decl_71004, type, fn_spectrophotometry_56: $i > $i).
% 29.32/29.14  tff(decl_71005, type, fn_spectrophotometry_57: $i > $i).
% 29.32/29.14  tff(decl_71006, type, 'Spectrum': $i).
% 29.32/29.14  tff(decl_71007, type, 'A collection or sequence of related qualities, ideas, or activities.': $i).
% 29.32/29.14  tff(decl_71008, type, spectrum: $i).
% 29.32/29.14  tff(decl_71009, type, 'Speech': $i).
% 29.32/29.14  tff(decl_71010, type, 'In humans, a vocalized form of communication.': $i).
% 29.32/29.14  tff(decl_71011, type, speechify: $i).
% 29.32/29.14  tff(decl_71012, type, speech: $i).
% 29.32/29.14  tff(decl_71013, type, 'Speed-Constant': $i).
% 29.32/29.14  tff(decl_71014, type, 'constant of speed': $i).
% 29.32/29.14  tff(decl_71015, type, 'speed constant': $i).
% 29.32/29.14  tff(decl_71016, type, 'speed-constant': $i).
% 29.32/29.14  tff(decl_71017, type, 'Speed-Value': $i).
% 29.32/29.14  tff(decl_71018, type, 'Distance travelled per unit time': $i).
% 29.32/29.14  tff(decl_71019, type, velocity: $i).
% 29.32/29.14  tff(decl_71020, type, 'speed magnitude': $i).
% 29.32/29.14  tff(decl_71021, type, 'velocity magnitude': $i).
% 29.32/29.14  tff(decl_71022, type, speed: $i).
% 29.32/29.14  tff(decl_71023, type, 'value of speed': $i).
% 29.32/29.14  tff(decl_71024, type, 'speed value': $i).
% 29.32/29.14  tff(decl_71025, type, 'speed-value': $i).
% 29.32/29.14  tff(decl_71026, type, 'Sperm-Cell': $i).
% 29.32/29.14  tff(decl_71027, type, 'The male gamete.': $i).
% 29.32/29.14  tff(decl_71028, type, spermatozoan: $i).
% 29.32/29.14  tff(decl_71029, type, spermatozoa: $i).
% 29.32/29.14  tff(decl_71030, type, sperm: $i).
% 29.32/29.14  tff(decl_71031, type, 'cell of sperm': $i).
% 29.32/29.14  tff(decl_71032, type, 'sperm cell': $i).
% 29.32/29.14  tff(decl_71033, type, 'sperm-cell': $i).
% 29.32/29.14  tff(decl_71034, type, fn_sperm_cell_1: $i > $i).
% 29.32/29.14  tff(decl_71035, type, fn_sperm_cell_2: $i > $i).
% 29.32/29.14  tff(decl_71036, type, fn_sperm_cell_3: $i > $i).
% 29.32/29.14  tff(decl_71037, type, fn_sperm_cell_5: $i > $i).
% 29.32/29.14  tff(decl_71038, type, fn_sperm_cell_6: $i > $i).
% 29.32/29.14  tff(decl_71039, type, fn_sperm_cell_7: $i > $i).
% 29.32/29.14  tff(decl_71040, type, fn_sperm_cell_18: $i > $i).
% 29.32/29.14  tff(decl_71041, type, fn_sperm_cell_19: $i > $i).
% 29.32/29.14  tff(decl_71042, type, fn_sperm_cell_20: $i > $i).
% 29.32/29.14  tff(decl_71043, type, fn_sperm_cell_21: $i > $i).
% 29.32/29.14  tff(decl_71044, type, fn_sperm_cell_24: $i > $i).
% 29.32/29.14  tff(decl_71045, type, fn_sperm_cell_26: $i > $i).
% 29.32/29.14  tff(decl_71046, type, fn_sperm_cell_29: $i > $i).
% 29.32/29.14  tff(decl_71047, type, fn_sperm_cell_34: $i > $i).
% 29.32/29.14  tff(decl_71048, type, fn_sperm_cell_11: $i > $i).
% 29.32/29.14  tff(decl_71049, type, fn_sperm_cell_10: $i > $i).
% 29.32/29.14  tff(decl_71050, type, spermatheca_1: $i > $o).
% 29.32/29.14  tff(decl_71051, type, 'Spermatheca': $i).
% 29.32/29.14  tff(decl_71052, type, 'In some insects, molluscs, and other animals, a sac in the female reproductive system that stores sperm.': $i).
% 29.32/29.14  tff(decl_71053, type, spermatheca: $i).
% 29.32/29.14  tff(decl_71054, type, 'Spermatocyte': $i).
% 29.32/29.14  tff(decl_71055, type, 'The spermatocyte is an intermediate step in the process of spermatogenesis which leads to the development of mature sperm cells.': $i).
% 29.32/29.14  tff(decl_71056, type, spermatocyte: $i).
% 29.32/29.14  tff(decl_71057, type, spermatogenesis_1: $i > $o).
% 29.32/29.14  tff(decl_71058, type, 'Spermatogenesis': $i).
% 29.32/29.14  tff(decl_71059, type, 'Spermatogenesis is the formation and development of sperm.': $i).
% 29.32/29.14  tff(decl_71060, type, 'gametogenesis in males': $i).
% 29.32/29.14  tff(decl_71061, type, spermatogenesis: $i).
% 29.32/29.14  tff(decl_71062, type, fn_spermatogenesis_1: $i > $i).
% 29.32/29.14  tff(decl_71063, type, fn_spermatogenesis_2: $i > $i).
% 29.32/29.14  tff(decl_71064, type, fn_spermatogenesis_3: $i > $i).
% 29.32/29.14  tff(decl_71065, type, fn_spermatogenesis_4: $i > $i).
% 29.32/29.14  tff(decl_71066, type, fn_spermatogenesis_5: $i > $i).
% 29.32/29.14  tff(decl_71067, type, fn_spermatogenesis_6: $i > $i).
% 29.32/29.14  tff(decl_71068, type, fn_spermatogenesis_7: $i > $i).
% 29.32/29.14  tff(decl_71069, type, fn_spermatogenesis_8: $i > $i).
% 29.32/29.14  tff(decl_71070, type, secondary_spermatocyte_0: $i).
% 29.32/29.14  tff(decl_71071, type, chromatid_0: $i).
% 29.32/29.14  tff(decl_71072, type, spermatogenesis_in_human_1: $i > $o).
% 29.32/29.14  tff(decl_71073, type, 'Spermatogenesis-In-Human': $i).
% 29.32/29.14  tff(decl_71074, type, 'The process of production of mature sperm cells in the human testis.': $i).
% 29.32/29.14  tff(decl_71075, type, 'spermatogenesis in human': $i).
% 29.32/29.14  tff(decl_71076, type, 'spermatogenesis-in-human': $i).
% 29.32/29.14  tff(decl_71077, type, fn_spermatogenesis_in_human_1: $i > $i).
% 29.32/29.14  tff(decl_71078, type, spermatogonium_1: $i > $o).
% 29.32/29.14  tff(decl_71079, type, 'Spermatogonium': $i).
% 29.32/29.14  tff(decl_71080, type, 'A precursor cell that divides via mitosis to produce spermatocytes.': $i).
% 29.32/29.14  tff(decl_71081, type, spermatogonia: $i).
% 29.32/29.14  tff(decl_71082, type, spermatogonium: $i).
% 29.32/29.14  tff(decl_71083, type, spermatophyte_plant_development_1: $i > $o).
% 29.32/29.14  tff(decl_71084, type, 'Spermatophyte-Plant-Development': $i).
% 29.32/29.14  tff(decl_71085, type, 'Spermatophyte plant development involves formation of a complete embryo from a zygote ; seed germination; the elaboration of a mature vegetative plant from the embryo.': $i).
% 29.32/29.14  tff(decl_71086, type, 'spermatophyte plant development': $i).
% 29.32/29.14  tff(decl_71087, type, 'spermatophyte-plant-development': $i).
% 29.32/29.14  tff(decl_71088, type, fn_spermatophyte_plant_development_1: $i > $i).
% 29.32/29.14  tff(decl_71089, type, fn_spermatophyte_plant_development_2: $i > $i).
% 29.32/29.14  tff(decl_71090, type, fn_spermatophyte_plant_development_3: $i > $i).
% 29.32/29.14  tff(decl_71091, type, fn_spermatophyte_plant_development_4: $i > $i).
% 29.32/29.14  tff(decl_71092, type, fn_spermatophyte_plant_development_5: $i > $i).
% 29.32/29.14  tff(decl_71093, type, fn_spermatophyte_plant_development_6: $i > $i).
% 29.32/29.14  tff(decl_71094, type, 'Sphincter': $i).
% 29.32/29.14  tff(decl_71095, type, 'A ring of muscle that normally constricts the opening of a body passage or orifice, and relaxes to allow the passage of material.': $i).
% 29.32/29.14  tff(decl_71096, type, sphincter: $i).
% 29.32/29.14  tff(decl_71097, type, fn_sphincter_1: $i > $i).
% 29.32/29.14  tff(decl_71098, type, fn_sphincter_2: $i > $i).
% 29.32/29.14  tff(decl_71099, type, fn_sphincter_3: $i > $i).
% 29.32/29.14  tff(decl_71100, type, 'Spider': $i).
% 29.32/29.14  tff(decl_71101, type, 'Members of the order Araneae. They are air-breathing arthropods that have eight legs, and chelicerae with fangs that inject venom. They are the largest order of arachnids and rank seventh in total species diversity among all other groups of organisms.': $i).
% 29.32/29.14  tff(decl_71102, type, spider: $i).
% 29.32/29.14  tff(decl_71103, type, fn_spider_3: $i > $i).
% 29.32/29.14  tff(decl_71104, type, fn_spider_4: $i > $i).
% 29.32/29.14  tff(decl_71105, type, fn_spider_5: $i > $i).
% 29.32/29.14  tff(decl_71106, type, fn_spider_6: $i > $i).
% 29.32/29.14  tff(decl_71107, type, fn_spider_7: $i > $i).
% 29.32/29.14  tff(decl_71108, type, fn_spider_8: $i > $i).
% 29.32/29.14  tff(decl_71109, type, fn_spider_9: $i > $i).
% 29.32/29.14  tff(decl_71110, type, fn_spider_10: $i > $i).
% 29.32/29.14  tff(decl_71111, type, fn_spider_11: $i > $i).
% 29.32/29.14  tff(decl_71112, type, fn_spider_12: $i > $i).
% 29.32/29.14  tff(decl_71113, type, fn_spider_2: $i > $i).
% 29.32/29.14  tff(decl_71114, type, fn_spider_1: $i > $i).
% 29.32/29.14  tff(decl_71115, type, spider_silk_1: $i > $o).
% 29.32/29.14  tff(decl_71116, type, 'Spider-Silk': $i).
% 29.32/29.14  tff(decl_71117, type, 'Spider silk is a structure created by special glands in the spider\\s abdomen. It is used in synthesis of Spider Web.': $i).
% 29.32/29.14  tff(decl_71118, type, 'silk of spider': $i).
% 29.32/29.14  tff(decl_71119, type, 'spider silk': $i).
% 29.32/29.14  tff(decl_71120, type, 'spider-silk': $i).
% 29.32/29.14  tff(decl_71121, type, fn_spider_silk_1: $i > $i).
% 29.32/29.14  tff(decl_71122, type, fn_spider_silk_2: $i > $i).
% 29.32/29.14  tff(decl_71123, type, fn_spider_silk_3: $i > $i).
% 29.32/29.14  tff(decl_71124, type, fn_spider_silk_4: $i > $i).
% 29.32/29.14  tff(decl_71125, type, fn_spider_silk_5: $i > $i).
% 29.32/29.14  tff(decl_71126, type, fn_spider_silk_6: $i > $i).
% 29.32/29.14  tff(decl_71127, type, spider_web_1: $i > $o).
% 29.32/29.14  tff(decl_71128, type, 'Spider-Web': $i).
% 29.32/29.14  tff(decl_71129, type, 'A spider web is a structure composed of silk, made by special glands in the spider\\s abdomen, which is used to capture prey, escape predators, and protect eggs.': $i).
% 29.32/29.14  tff(decl_71130, type, 'web of spider': $i).
% 29.32/29.14  tff(decl_71131, type, 'spider web': $i).
% 29.32/29.14  tff(decl_71132, type, 'spider-web': $i).
% 29.32/29.14  tff(decl_71133, type, fn_spider_web_1: $i > $i).
% 29.32/29.14  tff(decl_71134, type, spinal_cord_1: $i > $o).
% 29.32/29.14  tff(decl_71135, type, 'Spinal-Cord': $i).
% 29.32/29.14  tff(decl_71136, type, 'A long, thin bundle of nervous tissue that passes through the vertebral column and carries messages between the brain and the rest of the body.': $i).
% 29.32/29.14  tff(decl_71137, type, 'cord of spinal': $i).
% 29.32/29.14  tff(decl_71138, type, 'spinal cord': $i).
% 29.32/29.14  tff(decl_71139, type, 'spinal-cord': $i).
% 29.32/29.14  tff(decl_71140, type, 'Spinal-Nerve': $i).
% 29.32/29.14  tff(decl_71141, type, 'In the vertebrate peripheral nervous system, a nerve that carries signals to or from the spinal cord.': $i).
% 29.32/29.14  tff(decl_71142, type, 'nerve of spinal': $i).
% 29.32/29.14  tff(decl_71143, type, 'spinal nerve': $i).
% 29.32/29.14  tff(decl_71144, type, 'spinal-nerve': $i).
% 29.32/29.14  tff(decl_71145, type, 'Spindle': $i).
% 29.32/29.14  tff(decl_71146, type, 'Cellular structure composed of cytoskeletal elements which functions to segregate chromosomes during cell division.': $i).
% 29.32/29.14  tff(decl_71147, type, 'Spiral-Cleavage': $i).
% 29.32/29.14  tff(decl_71148, type, 'A type of cleavage pattern in protostomous development in which the cells of each layer of the embryo sit in the grooves between cells of adjacent layers.': $i).
% 29.32/29.14  tff(decl_71149, type, 'undergo spiral cleavage': $i).
% 29.32/29.14  tff(decl_71150, type, 'cleavage of spiral': $i).
% 29.32/29.14  tff(decl_71151, type, 'spiral cleavage': $i).
% 29.32/29.14  tff(decl_71152, type, 'spiral-cleavage': $i).
% 29.32/29.14  tff(decl_71153, type, 'Spirochete': $i).
% 29.32/29.14  tff(decl_71154, type, 'Gram-negative bacteria, which have long, helically coiled (spiral-shaped) cells.': $i).
% 29.32/29.14  tff(decl_71155, type, spirochete: $i).
% 29.32/29.14  tff(decl_71156, type, 'Splice-Site': $i).
% 29.32/29.14  tff(decl_71157, type, 'These are the short nucleotide sequences present at end of intron which serve as a signal for removal of introns from the pre-mRNA and joining of the exons to form an mRNA': $i).
% 29.32/29.14  tff(decl_71158, type, 'site of splice': $i).
% 29.32/29.14  tff(decl_71159, type, 'splice site': $i).
% 29.32/29.14  tff(decl_71160, type, 'splice-site': $i).
% 29.32/29.14  tff(decl_71161, type, 'Spliceosome': $i).
% 29.32/29.14  tff(decl_71162, type, 'A large complex of protein and RNA that splices introns out of a strand of mRNA and joins together the adjacent exons to produce the final mRNA transcript.': $i).
% 29.32/29.14  tff(decl_71163, type, spliceosome: $i).
% 29.32/29.14  tff(decl_71164, type, fn_spliceosome_2: $i > $i).
% 29.32/29.14  tff(decl_71165, type, fn_spliceosome_3: $i > $i).
% 29.32/29.14  tff(decl_71166, type, split_gene_1: $i > $o).
% 29.32/29.14  tff(decl_71167, type, 'Split-Gene': $i).
% 29.32/29.14  tff(decl_71168, type, 'Genes that include noncoding regions (introns) and coding regions (exons).': $i).
% 29.32/29.14  tff(decl_71169, type, 'gene of split': $i).
% 29.32/29.14  tff(decl_71170, type, 'split gene': $i).
% 29.32/29.14  tff(decl_71171, type, 'split-gene': $i).
% 29.32/29.14  tff(decl_71172, type, 'Spongocoel': $i).
% 29.32/29.14  tff(decl_71173, type, 'The central cavity of a sponge\\s body.': $i).
% 29.32/29.14  tff(decl_71174, type, 'sponge central cavity': $i).
% 29.32/29.14  tff(decl_71175, type, 'central cavity of a sponge': $i).
% 29.32/29.14  tff(decl_71176, type, spongocoel: $i).
% 29.32/29.14  tff(decl_71177, type, 'Spongy-Mesophyll': $i).
% 29.32/29.14  tff(decl_71178, type, 'It is one of the layers of mesophylls of many eudicots': $i).
% 29.32/29.14  tff(decl_71179, type, 'spongy mesophyll': $i).
% 29.32/29.14  tff(decl_71180, type, 'spongy-mesophyll': $i).
% 29.32/29.14  tff(decl_71181, type, fn_spongy_mesophyll_2: $i > $i).
% 29.32/29.14  tff(decl_71182, type, 'Spontaneous-Change': $i).
% 29.32/29.14  tff(decl_71183, type, 'A spontaneous change is the time-evolution of a system in which it releases free energy (most often as heat) and moves to a lower, more thermodynamically stable, energy state.': $i).
% 29.32/29.14  tff(decl_71184, type, 'spontaneous change': $i).
% 29.32/29.14  tff(decl_71185, type, 'spontaneous-change': $i).
% 29.32/29.14  tff(decl_71186, type, fn_spontaneous_change_2: $i > $i).
% 29.32/29.14  tff(decl_71187, type, fn_spontaneous_change_3: $i > $i).
% 29.32/29.14  tff(decl_71188, type, non_spontaneous_change_0: $i).
% 29.32/29.14  tff(decl_71189, type, spontaneous_mutation_1: $i > $o).
% 29.32/29.14  tff(decl_71190, type, 'Spontaneous-Mutation': $i).
% 29.32/29.14  tff(decl_71191, type, 'An error that occurs during DNA replication, repair, or recombination.': $i).
% 29.32/29.14  tff(decl_71192, type, 'spontaneous mutation': $i).
% 29.32/29.14  tff(decl_71193, type, 'spontaneous-mutation': $i).
% 29.32/29.14  tff(decl_71194, type, 'Sporangium': $i).
% 29.32/29.14  tff(decl_71195, type, 'In fungi and plants, a structure in which spores are formed via meiosis.': $i).
% 29.32/29.14  tff(decl_71196, type, sporangium: $i).
% 29.32/29.14  tff(decl_71197, type, 'Spore': $i).
% 29.32/29.14  tff(decl_71198, type, 'A haploid cell produced in the sporophyte by meiosis in the life cycle of a plant or alga undergoing alternation of generations. A spore can divide by mitosis to develop into a multicellular haploid individual, the gametophyte, without fusing with another cell. (2) In fungi, a haploid cell, produced either sexually or asexually, that produces a mycelium after germination.': $i).
% 29.32/29.14  tff(decl_71199, type, spore: $i).
% 29.32/29.14  tff(decl_71200, type, 'Spore-Wall': $i).
% 29.32/29.14  tff(decl_71201, type, 'The external covering of a yeast spore.': $i).
% 29.32/29.14  tff(decl_71202, type, 'wall of spore': $i).
% 29.32/29.14  tff(decl_71203, type, 'spore wall': $i).
% 29.32/29.14  tff(decl_71204, type, 'spore-wall': $i).
% 29.32/29.14  tff(decl_71205, type, fn_spore_wall_1: $i > $i).
% 29.32/29.14  tff(decl_71206, type, organic_structure_0: $i).
% 29.32/29.14  tff(decl_71207, type, sporocyte_1: $i > $o).
% 29.32/29.14  tff(decl_71208, type, 'Sporocyte': $i).
% 29.32/29.14  tff(decl_71209, type, 'A diploid cell that undergoes meiosis and produces haploid spores.': $i).
% 29.32/29.14  tff(decl_71210, type, sporocyte: $i).
% 29.32/29.14  tff(decl_71211, type, 'Sporophyll': $i).
% 29.32/29.14  tff(decl_71212, type, 'In plants, a leaf that bears sporangia and is thus modified for reproduction.': $i).
% 29.32/29.14  tff(decl_71213, type, sporophyll: $i).
% 29.32/29.14  tff(decl_71214, type, 'Sporophyte': $i).
% 29.32/29.14  tff(decl_71215, type, 'The diploid multicellular stage of organisms (e.g., plants and some algae) that undergo alternation of generations. The sporophyte produces haploid spores via meiosis, which develop into gametophytes.': $i).
% 29.32/29.14  tff(decl_71216, type, sporophyte: $i).
% 29.32/29.14  tff(decl_71217, type, 'Sporopollenin': $i).
% 29.32/29.14  tff(decl_71218, type, 'A tough, chemically stable polymer that forms the outer wall of pollen grains and plant and algal spores, protting them from the external environment.': $i).
% 29.32/29.14  tff(decl_71219, type, sporopollenin: $i).
% 29.32/29.14  tff(decl_71220, type, 'Squamata': $i).
% 29.32/29.14  tff(decl_71221, type, 'The largest order of reptiles, including lizards and snakes.': $i).
% 29.32/29.14  tff(decl_71222, type, squamata: $i).
% 29.32/29.14  tff(decl_71223, type, tuatara_1: $i > $o).
% 29.32/29.14  tff(decl_71224, type, sry_1: $i > $o).
% 29.32/29.14  tff(decl_71225, type, 'SRY': $i).
% 29.32/29.14  tff(decl_71226, type, 'A gene on the Y chromosome that must be present for normal testes development.': $i).
% 29.32/29.14  tff(decl_71227, type, 'sex determining region': $i).
% 29.32/29.14  tff(decl_71228, type, 'sry gene': $i).
% 29.32/29.14  tff(decl_71229, type, 'sex determining region y': $i).
% 29.32/29.14  tff(decl_71230, type, 'sex-determining-region-y': $i).
% 29.32/29.14  tff(decl_71231, type, 'sex determining region y gene': $i).
% 29.32/29.14  tff(decl_71232, type, 'sex-determining-region-y-gene': $i).
% 29.32/29.14  tff(decl_71233, type, 'sry-gene': $i).
% 29.32/29.14  tff(decl_71234, type, sry: $i).
% 29.32/29.14  tff(decl_71235, type, fn_sry_1: $i > $i).
% 29.32/29.14  tff(decl_71236, type, fn_sry_2: $i > $i).
% 29.32/29.14  tff(decl_71237, type, fn_sry_3: $i > $i).
% 29.32/29.14  tff(decl_71238, type, fn_sry_4: $i > $i).
% 29.32/29.14  tff(decl_71239, type, ssu_rrna_sequence_1: $i > $o).
% 29.32/29.14  tff(decl_71240, type, 'SSU-rRNA-Sequence': $i).
% 29.32/29.14  tff(decl_71241, type, 'The gene that codes for the small ribosomal subunit RNA, which  is present in all organisms, making it a good choice for studying the deepest branching in evolutionary history.': $i).
% 29.32/29.14  tff(decl_71242, type, 'small ribosomal subunit rna': $i).
% 29.32/29.14  tff(decl_71243, type, 'small-ribosomal-subunit-rna': $i).
% 29.32/29.14  tff(decl_71244, type, 'gene for ssu rrna': $i).
% 29.32/29.14  tff(decl_71245, type, 'gene-for-ssu-rrna': $i).
% 29.32/29.14  tff(decl_71246, type, 'ssu rrna sequence': $i).
% 29.32/29.14  tff(decl_71247, type, 'ssu-rrna-sequence': $i).
% 29.32/29.14  tff(decl_71248, type, 'Stabilizing-Selection': $i).
% 29.32/29.14  tff(decl_71249, type, 'Natural selection that acts against extreme phenotypes, so that individuals with intermediate phenotypes have greater survival and reproductive success.': $i).
% 29.32/29.14  tff(decl_71250, type, 'stabilizing selection': $i).
% 29.32/29.14  tff(decl_71251, type, 'stabilizing-selection': $i).
% 29.32/29.14  tff(decl_71252, type, 'Stable-System': $i).
% 29.32/29.14  tff(decl_71253, type, 'A system which is stable is called stable-system.': $i).
% 29.32/29.14  tff(decl_71254, type, 'system of stable': $i).
% 29.32/29.14  tff(decl_71255, type, 'stable system': $i).
% 29.32/29.14  tff(decl_71256, type, 'stable-system': $i).
% 29.32/29.14  tff(decl_71257, type, stage_of_protein_folding_1: $i > $o).
% 29.32/29.14  tff(decl_71258, type, 'Stage-of-Protein-Folding': $i).
% 29.32/29.14  tff(decl_71259, type, 'Proteins have four stages of protein folding: primary, secondary, tertiary, and quaternary.': $i).
% 29.32/29.14  tff(decl_71260, type, 'stage of protein folding': $i).
% 29.32/29.14  tff(decl_71261, type, 'stage-of-protein-folding': $i).
% 29.32/29.14  tff(decl_71262, type, 'Staggered-Cut': $i).
% 29.32/29.14  tff(decl_71263, type, 'The result of a restriction enzyme\\s staggered breaking of the covalent phophodiester bonds of both DNA strands.': $i).
% 29.32/29.14  tff(decl_71264, type, 'staggered cut': $i).
% 29.32/29.14  tff(decl_71265, type, 'staggered-cut': $i).
% 29.32/29.14  tff(decl_71266, type, fn_staggered_cut_1: $i > $i).
% 29.32/29.14  tff(decl_71267, type, fn_staggered_cut_2: $i > $i).
% 29.32/29.14  tff(decl_71268, type, fn_staggered_cut_3: $i > $i).
% 29.32/29.14  tff(decl_71269, type, fn_staggered_cut_4: $i > $i).
% 29.32/29.14  tff(decl_71270, type, fn_staggered_cut_7: $i > $i).
% 29.32/29.14  tff(decl_71271, type, fn_staggered_cut_8: $i > $i).
% 29.32/29.14  tff(decl_71272, type, sticky_end_fragment_0: $i).
% 29.32/29.14  tff(decl_71273, type, stained_band_1: $i > $o).
% 29.32/29.14  tff(decl_71274, type, 'Stained-Band': $i).
% 29.32/29.14  tff(decl_71275, type, 'Chromosome marker created with a stain and used to locate chromosomal features.': $i).
% 29.32/29.14  tff(decl_71276, type, 'stained band': $i).
% 29.32/29.14  tff(decl_71277, type, 'stained-band': $i).
% 29.32/29.14  tff(decl_71278, type, fn_stained_band_1: $i > $i).
% 29.32/29.14  tff(decl_71279, type, fn_stained_band_2: $i > $i).
% 29.32/29.14  tff(decl_71280, type, fn_stained_band_3: $i > $i).
% 29.32/29.14  tff(decl_71281, type, fn_stained_band_4: $i > $i).
% 29.32/29.14  tff(decl_71282, type, 'Staining': $i).
% 29.32/29.14  tff(decl_71283, type, 'The act of spotting or staining something with the use of a dye to colour specimens for microscopic study': $i).
% 29.32/29.14  tff(decl_71284, type, staining: $i).
% 29.32/29.14  tff(decl_71285, type, 'Stamen': $i).
% 29.32/29.14  tff(decl_71286, type, 'The pollen-producing reproductive organ of a flower, consisting of an anther and a filament.': $i).
% 29.32/29.14  tff(decl_71287, type, stamen: $i).
% 29.32/29.14  tff(decl_71288, type, fn_stamen_1: $i > $i).
% 29.32/29.14  tff(decl_71289, type, fn_stamen_3: $i > $i).
% 29.32/29.14  tff(decl_71290, type, fn_stamen_4: $i > $i).
% 29.32/29.14  tff(decl_71291, type, 'Stand-Up': $i).
% 29.32/29.14  tff(decl_71292, type, stand: $i).
% 29.32/29.14  tff(decl_71293, type, 'stand up': $i).
% 29.32/29.14  tff(decl_71294, type, stand_up: $i).
% 29.32/29.14  tff(decl_71295, type, 'stand-up': $i).
% 29.32/29.14  tff(decl_71296, type, fn_stand_up_1: $i > $i).
% 29.32/29.14  tff(decl_71297, type, standing_crop_1: $i > $o).
% 29.32/29.14  tff(decl_71298, type, 'Standing-Crop': $i).
% 29.32/29.14  tff(decl_71299, type, 'The total biomass of organisms in an area at a specific time.': $i).
% 29.32/29.14  tff(decl_71300, type, 'crop of standing': $i).
% 29.32/29.14  tff(decl_71301, type, 'standing crop': $i).
% 29.32/29.14  tff(decl_71302, type, 'standing-crop': $i).
% 29.32/29.14  tff(decl_71303, type, 'Stapes': $i).
% 29.32/29.14  tff(decl_71304, type, 'The third of three bones in the middle ear of mammals; also called the stirrup.': $i).
% 29.32/29.14  tff(decl_71305, type, stapes: $i).
% 29.32/29.14  tff(decl_71306, type, stape: $i).
% 29.32/29.14  tff(decl_71307, type, star_1: $i > $o).
% 29.32/29.14  tff(decl_71308, type, 'Star': $i).
% 29.32/29.14  tff(decl_71309, type, 'A star is a massive, luminous ball of plasma held together by gravity. At the end of its lifetime, a star can also contain a proportion of degenerate matter. The nearest star to Earth is the Sun, which is the source of most of the energy on Earth.': $i).
% 29.32/29.14  tff(decl_71310, type, star: $i).
% 29.32/29.14  tff(decl_71311, type, 'Starch': $i).
% 29.32/29.14  tff(decl_71312, type, 'Starch is a polysachharide consisting of a large number of glucose units joined together by alpha-glycosidic linkages. It is produced by all green plants as an energy state.': $i).
% 29.32/29.14  tff(decl_71313, type, starch: $i).
% 29.32/29.14  tff(decl_71314, type, fn_starch_4: $i > $i).
% 29.32/29.14  tff(decl_71315, type, fn_starch_7: $i > $i).
% 29.32/29.14  tff(decl_71316, type, fn_starch_8: $i > $i).
% 29.32/29.14  tff(decl_71317, type, fn_starch_10: $i > $i).
% 29.32/29.14  tff(decl_71318, type, fn_starch_11: $i > $i).
% 29.32/29.14  tff(decl_71319, type, fn_starch_12: $i > $i).
% 29.32/29.14  tff(decl_71320, type, fn_starch_13: $i > $i).
% 29.32/29.14  tff(decl_71321, type, fn_starch_14: $i > $i).
% 29.32/29.14  tff(decl_71322, type, fn_starch_15: $i > $i).
% 29.32/29.14  tff(decl_71323, type, fn_starch_16: $i > $i).
% 29.32/29.14  tff(decl_71324, type, fn_starch_17: $i > $i).
% 29.32/29.14  tff(decl_71325, type, fn_starch_18: $i > $i).
% 29.32/29.14  tff(decl_71326, type, fn_starch_19: $i > $i).
% 29.32/29.14  tff(decl_71327, type, fn_starch_21: $i > $i).
% 29.32/29.14  tff(decl_71328, type, fn_starch_22: $i > $i).
% 29.32/29.14  tff(decl_71329, type, fn_starch_23: $i > $i).
% 29.32/29.14  tff(decl_71330, type, fn_starch_24: $i > $i).
% 29.32/29.14  tff(decl_71331, type, fn_starch_25: $i > $i).
% 29.32/29.14  tff(decl_71332, type, fn_starch_26: $i > $i).
% 29.32/29.14  tff(decl_71333, type, fn_starch_27: $i > $i).
% 29.32/29.14  tff(decl_71334, type, fn_starch_28: $i > $i).
% 29.32/29.14  tff(decl_71335, type, fn_starch_29: $i > $i).
% 29.32/29.14  tff(decl_71336, type, fn_starch_30: $i > $i).
% 29.32/29.14  tff(decl_71337, type, fn_starch_31: $i > $i).
% 29.32/29.14  tff(decl_71338, type, fn_starch_32: $i > $i).
% 29.32/29.14  tff(decl_71339, type, fn_starch_33: $i > $i).
% 29.32/29.14  tff(decl_71340, type, fn_starch_35: $i > $i).
% 29.32/29.14  tff(decl_71341, type, fn_starch_36: $i > $i).
% 29.32/29.14  tff(decl_71342, type, fn_starch_37: $i > $i).
% 29.32/29.14  tff(decl_71343, type, fn_starch_38: $i > $i).
% 29.32/29.14  tff(decl_71344, type, fn_starch_39: $i > $i).
% 29.32/29.14  tff(decl_71345, type, fn_starch_40: $i > $i).
% 29.32/29.14  tff(decl_71346, type, fn_starch_41: $i > $i).
% 29.32/29.14  tff(decl_71347, type, fn_starch_42: $i > $i).
% 29.32/29.14  tff(decl_71348, type, fn_starch_43: $i > $i).
% 29.32/29.14  tff(decl_71349, type, fn_starch_44: $i > $i).
% 29.32/29.14  tff(decl_71350, type, fn_starch_45: $i > $i).
% 29.32/29.14  tff(decl_71351, type, fn_starch_48: $i > $i).
% 29.32/29.14  tff(decl_71352, type, fn_starch_49: $i > $i).
% 29.32/29.14  tff(decl_71353, type, fn_starch_50: $i > $i).
% 29.32/29.14  tff(decl_71354, type, fn_starch_53: $i > $i).
% 29.32/29.14  tff(decl_71355, type, fn_starch_56: $i > $i).
% 29.32/29.14  tff(decl_71356, type, fn_starch_57: $i > $i).
% 29.32/29.14  tff(decl_71357, type, fn_starch_62: $i > $i).
% 29.32/29.14  tff(decl_71358, type, fn_starch_63: $i > $i).
% 29.32/29.14  tff(decl_71359, type, fn_starch_64: $i > $i).
% 29.32/29.14  tff(decl_71360, type, fn_starch_69: $i > $i).
% 29.32/29.14  tff(decl_71361, type, fn_starch_72: $i > $i).
% 29.32/29.14  tff(decl_71362, type, fn_starch_74: $i > $i).
% 29.32/29.14  tff(decl_71363, type, fn_starch_75: $i > $i).
% 29.32/29.14  tff(decl_71364, type, fn_starch_76: $i > $i).
% 29.32/29.14  tff(decl_71365, type, fn_starch_77: $i > $i).
% 29.32/29.14  tff(decl_71366, type, fn_starch_78: $i > $i).
% 29.32/29.14  tff(decl_71367, type, fn_starch_79: $i > $i).
% 29.32/29.14  tff(decl_71368, type, fn_starch_80: $i > $i).
% 29.32/29.14  tff(decl_71369, type, fn_starch_81: $i > $i).
% 29.32/29.14  tff(decl_71370, type, fn_starch_82: $i > $i).
% 29.32/29.14  tff(decl_71371, type, fn_starch_83: $i > $i).
% 29.32/29.14  tff(decl_71372, type, fn_starch_84: $i > $i).
% 29.32/29.14  tff(decl_71373, type, fn_starch_85: $i > $i).
% 29.32/29.14  tff(decl_71374, type, fn_starch_86: $i > $i).
% 29.32/29.14  tff(decl_71375, type, fn_starch_87: $i > $i).
% 29.32/29.14  tff(decl_71376, type, fn_starch_88: $i > $i).
% 29.32/29.14  tff(decl_71377, type, fn_starch_89: $i > $i).
% 29.32/29.14  tff(decl_71378, type, fn_starch_90: $i > $i).
% 29.32/29.14  tff(decl_71379, type, fn_starch_91: $i > $i).
% 29.32/29.14  tff(decl_71380, type, fn_starch_92: $i > $i).
% 29.32/29.14  tff(decl_71381, type, fn_starch_93: $i > $i).
% 29.32/29.14  tff(decl_71382, type, fn_starch_94: $i > $i).
% 29.32/29.14  tff(decl_71383, type, fn_starch_95: $i > $i).
% 29.32/29.14  tff(decl_71384, type, fn_starch_96: $i > $i).
% 29.32/29.14  tff(decl_71385, type, fn_starch_97: $i > $i).
% 29.32/29.14  tff(decl_71386, type, fn_starch_98: $i > $i).
% 29.32/29.14  tff(decl_71387, type, fn_starch_99: $i > $i).
% 29.32/29.14  tff(decl_71388, type, fn_starch_100: $i > $i).
% 29.32/29.14  tff(decl_71389, type, fn_starch_101: $i > $i).
% 29.32/29.14  tff(decl_71390, type, fn_starch_102: $i > $i).
% 29.32/29.14  tff(decl_71391, type, fn_starch_103: $i > $i).
% 29.32/29.14  tff(decl_71392, type, fn_storage_polysaccharide_78: $i > $i).
% 29.32/29.14  tff(decl_71393, type, fn_storage_polysaccharide_67: $i > $i).
% 29.32/29.14  tff(decl_71394, type, fn_storage_polysaccharide_60: $i > $i).
% 29.32/29.14  tff(decl_71395, type, fn_storage_polysaccharide_77: $i > $i).
% 29.32/29.14  tff(decl_71396, type, fn_storage_polysaccharide_35: $i > $i).
% 29.32/29.14  tff(decl_71397, type, fn_storage_polysaccharide_76: $i > $i).
% 29.32/29.14  tff(decl_71398, type, fn_storage_polysaccharide_15: $i > $i).
% 29.32/29.14  tff(decl_71399, type, fn_storage_polysaccharide_24: $i > $i).
% 29.32/29.14  tff(decl_71400, type, fn_storage_polysaccharide_32: $i > $i).
% 29.32/29.14  tff(decl_71401, type, fn_storage_polysaccharide_26: $i > $i).
% 29.32/29.14  tff(decl_71402, type, fn_storage_polysaccharide_25: $i > $i).
% 29.32/29.14  tff(decl_71403, type, fn_storage_polysaccharide_14: $i > $i).
% 29.32/29.14  tff(decl_71404, type, fn_storage_polysaccharide_13: $i > $i).
% 29.32/29.14  tff(decl_71405, type, fn_storage_polysaccharide_68: $i > $i).
% 29.32/29.14  tff(decl_71406, type, fn_storage_polysaccharide_64: $i > $i).
% 29.32/29.14  tff(decl_71407, type, fn_storage_polysaccharide_58: $i > $i).
% 29.32/29.14  tff(decl_71408, type, fn_storage_polysaccharide_11: $i > $i).
% 29.32/29.14  tff(decl_71409, type, fn_storage_polysaccharide_1: $i > $i).
% 29.32/29.14  tff(decl_71410, type, fn_storage_polysaccharide_75: $i > $i).
% 29.32/29.14  tff(decl_71411, type, fn_storage_polysaccharide_31: $i > $i).
% 29.32/29.14  tff(decl_71412, type, fn_storage_polysaccharide_5: $i > $i).
% 29.32/29.14  tff(decl_71413, type, fn_storage_polysaccharide_30: $i > $i).
% 29.32/29.14  tff(decl_71414, type, fn_storage_polysaccharide_20: $i > $i).
% 29.32/29.14  tff(decl_71415, type, fn_storage_polysaccharide_6: $i > $i).
% 29.32/29.14  tff(decl_71416, type, fn_storage_polysaccharide_57: $i > $i).
% 29.32/29.14  tff(decl_71417, type, fn_storage_polysaccharide_2: $i > $i).
% 29.32/29.14  tff(decl_71418, type, fn_storage_polysaccharide_53: $i > $i).
% 29.32/29.14  tff(decl_71419, type, fn_storage_polysaccharide_59: $i > $i).
% 29.32/29.14  tff(decl_71420, type, fn_storage_polysaccharide_28: $i > $i).
% 29.32/29.14  tff(decl_71421, type, fn_storage_polysaccharide_19: $i > $i).
% 29.32/29.14  tff(decl_71422, type, fn_storage_polysaccharide_66: $i > $i).
% 29.32/29.14  tff(decl_71423, type, 'Starch-Storage-By-Plant': $i).
% 29.32/29.14  tff(decl_71424, type, 'Plants store carbohydrates in the form of starch. Amyloplasts are specialized plastids (a type of organelle) for the storage of starch in plants.': $i).
% 29.32/29.14  tff(decl_71425, type, 'starch storage by plant': $i).
% 29.32/29.14  tff(decl_71426, type, 'starch-storage-by-plant': $i).
% 29.32/29.14  tff(decl_71427, type, fn_starch_storage_by_plant_4: $i > $i).
% 29.32/29.14  tff(decl_71428, type, fn_starch_storage_by_plant_7: $i > $i).
% 29.32/29.14  tff(decl_71429, type, fn_starch_storage_by_plant_8: $i > $i).
% 29.32/29.14  tff(decl_71430, type, 'Start-codon': $i).
% 29.32/29.14  tff(decl_71431, type, 'ATG and AUG denote sequences of DNA and RNA respectively that are the start codon or initiation codon encoding the amino acid methionine (Met) in eukaryotes and a modified Met (fMet) in prokaryotes.': $i).
% 29.32/29.14  tff(decl_71432, type, 'initiation codon': $i).
% 29.32/29.14  tff(decl_71433, type, 'initiation-codon': $i).
% 29.32/29.14  tff(decl_71434, type, 'codon of start': $i).
% 29.32/29.14  tff(decl_71435, type, 'start-codon': $i).
% 29.32/29.14  tff(decl_71436, type, start_signal_1: $i > $o).
% 29.32/29.14  tff(decl_71437, type, 'Start-Signal': $i).
% 29.32/29.14  tff(decl_71438, type, 'Message or instructions, carried by a molecule or electrical pulse, which initiates a biological process.': $i).
% 29.32/29.14  tff(decl_71439, type, 'signal of start': $i).
% 29.32/29.14  tff(decl_71440, type, 'start signal': $i).
% 29.32/29.14  tff(decl_71441, type, 'start-signal': $i).
% 29.32/29.14  tff(decl_71442, type, 'Starving-Cell': $i).
% 29.32/29.14  tff(decl_71443, type, 'A cell which lacks sufficient energy, nutrients or oxygen to maintain life process.': $i).
% 29.32/29.14  tff(decl_71444, type, 'cell of starving': $i).
% 29.32/29.14  tff(decl_71445, type, 'starving cell': $i).
% 29.32/29.14  tff(decl_71446, type, 'starving-cell': $i).
% 29.32/29.14  tff(decl_71447, type, 'State': $i).
% 29.32/29.14  tff(decl_71448, type, 'resulting state': $i).
% 29.32/29.14  tff(decl_71449, type, 'resulting-state': $i).
% 29.32/29.14  tff(decl_71450, type, be: $i).
% 29.32/29.14  tff(decl_71451, type, 'State-Constant': $i).
% 29.32/29.14  tff(decl_71452, type, 'constant of state': $i).
% 29.32/29.14  tff(decl_71453, type, 'state constant': $i).
% 29.32/29.14  tff(decl_71454, type, 'state-constant': $i).
% 29.32/29.14  tff(decl_71455, type, 'State-Value': $i).
% 29.32/29.14  tff(decl_71456, type, 'state of matter': $i).
% 29.32/29.14  tff(decl_71457, type, 'physical state': $i).
% 29.32/29.14  tff(decl_71458, type, 'physical-state': $i).
% 29.32/29.14  tff(decl_71459, type, 'value of state': $i).
% 29.32/29.14  tff(decl_71460, type, 'state value': $i).
% 29.32/29.14  tff(decl_71461, type, 'state-value': $i).
% 29.32/29.14  tff(decl_71462, type, 'Statocyst': $i).
% 29.32/29.14  tff(decl_71463, type, 'A type of gravity sensor that functions in equilibrium, found in many invertebrates. It consists of a mineralized concretion in a fluid-filled sac lined with hair cells. As the animal moves, different hair cells are stimulated, providing information about the animal\\s orientation with respect to gravity.': $i).
% 29.32/29.14  tff(decl_71464, type, statocyst: $i).
% 29.32/29.14  tff(decl_71465, type, 'Stator': $i).
% 29.32/29.14  tff(decl_71466, type, 'A component of ATP synthase that is anchored int he membrane and which contains a half channel through which H+ ions enter as they flow down their concentration gradient.': $i).
% 29.32/29.14  tff(decl_71467, type, stator: $i).
% 29.32/29.14  tff(decl_71468, type, fn_stator_1: $i > $i).
% 29.32/29.14  tff(decl_71469, type, hydrophilic_channel_0: $i).
% 29.32/29.14  tff(decl_71470, type, 'Stele': $i).
% 29.32/29.14  tff(decl_71471, type, 'In plants, the central portion of a root or shoot that contains the vascular tissue.': $i).
% 29.32/29.14  tff(decl_71472, type, 'vascular cylinder': $i).
% 29.32/29.14  tff(decl_71473, type, 'vascular-cylinder': $i).
% 29.32/29.14  tff(decl_71474, type, stele: $i).
% 29.32/29.14  tff(decl_71475, type, fn_stele_1: $i > $i).
% 29.32/29.14  tff(decl_71476, type, fn_stele_2: $i > $i).
% 29.32/29.14  tff(decl_71477, type, fn_stele_3: $i > $i).
% 29.32/29.14  tff(decl_71478, type, fn_stele_4: $i > $i).
% 29.32/29.14  tff(decl_71479, type, fn_stele_5: $i > $i).
% 29.32/29.14  tff(decl_71480, type, fn_stele_6: $i > $i).
% 29.32/29.14  tff(decl_71481, type, fn_stele_7: $i > $i).
% 29.32/29.14  tff(decl_71482, type, fn_stele_8: $i > $i).
% 29.32/29.14  tff(decl_71483, type, fn_stele_9: $i > $i).
% 29.32/29.14  tff(decl_71484, type, fn_stele_10: $i > $i).
% 29.32/29.14  tff(decl_71485, type, fn_stele_11: $i > $i).
% 29.32/29.14  tff(decl_71486, type, 'Stem': $i).
% 29.32/29.14  tff(decl_71487, type, 'The main upright shoot of a vascular plant, that bears the leaves and reproductive structures.': $i).
% 29.32/29.14  tff(decl_71488, type, stem: $i).
% 29.32/29.14  tff(decl_71489, type, fn_stem_4: $i > $i).
% 29.32/29.14  tff(decl_71490, type, fn_stem_5: $i > $i).
% 29.32/29.14  tff(decl_71491, type, fn_stem_7: $i > $i).
% 29.32/29.14  tff(decl_71492, type, fn_stem_9: $i > $i).
% 29.32/29.14  tff(decl_71493, type, fn_stem_10: $i > $i).
% 29.32/29.14  tff(decl_71494, type, fn_stem_12: $i > $i).
% 29.32/29.14  tff(decl_71495, type, 'Quantity_OrgaMolRespiration': $i).
% 29.32/29.14  tff(decl_71496, type, 'Quantity_OrgMolPhotosynthesis': $i).
% 29.32/29.14  tff(decl_71497, type, 'Stem-Cell': $i).
% 29.32/29.14  tff(decl_71498, type, 'A relatively unspecialized biological cell that can divide and produce daughter cells that can differentiate into specialized cells.': $i).
% 29.32/29.14  tff(decl_71499, type, 'cell of stem': $i).
% 29.32/29.14  tff(decl_71500, type, 'stem cell': $i).
% 29.32/29.14  tff(decl_71501, type, 'stem-cell': $i).
% 29.32/29.14  tff(decl_71502, type, fn_stem_cell_6: $i > $i).
% 29.32/29.14  tff(decl_71503, type, fn_stem_cell_7: $i > $i).
% 29.32/29.14  tff(decl_71504, type, fn_stem_cell_8: $i > $i).
% 29.32/29.14  tff(decl_71505, type, fn_stem_cell_9: $i > $i).
% 29.32/29.14  tff(decl_71506, type, fn_stem_cell_11: $i > $i).
% 29.32/29.14  tff(decl_71507, type, fn_stem_cell_22: $i > $i).
% 29.32/29.14  tff(decl_71508, type, 'Stem-Cell-Culturing': $i).
% 29.32/29.14  tff(decl_71509, type, 'The growing of the stem cells in laboratory is called stem cell culturing.': $i).
% 29.32/29.14  tff(decl_71510, type, 'stem cell culturing': $i).
% 29.32/29.14  tff(decl_71511, type, 'stem-cell-culturing': $i).
% 29.32/29.14  tff(decl_71512, type, 'Stem-Cell-Differentiation': $i).
% 29.32/29.14  tff(decl_71513, type, 'Stem cell develops into two differentiated daughter cells by differentiating.': $i).
% 29.32/29.14  tff(decl_71514, type, 'stem cell differentiation': $i).
% 29.32/29.14  tff(decl_71515, type, 'stem-cell-differentiation': $i).
% 29.32/29.14  tff(decl_71516, type, stem_cell_differentiation_in_bone_marrow_1: $i > $o).
% 29.32/29.14  tff(decl_71517, type, fn_stem_cell_differentiation_in_bone_marrow_1: $i > $i).
% 29.32/29.14  tff(decl_71518, type, 'Stem-Cell-Differentiation-In-Bone-Marrow': $i).
% 29.32/29.14  tff(decl_71519, type, 'The differentiation of the bone marrow stem cells.': $i).
% 29.32/29.14  tff(decl_71520, type, 'stem cell differentiation in bone marrow': $i).
% 29.32/29.14  tff(decl_71521, type, 'stem-cell-differentiation-in-bone-marrow': $i).
% 29.32/29.14  tff(decl_71522, type, stem_cell_differentiation_in_brain_1: $i > $o).
% 29.32/29.14  tff(decl_71523, type, 'Stem-Cell-Differentiation-In-Brain': $i).
% 29.32/29.14  tff(decl_71524, type, 'The differentiation of the brain stem cells.': $i).
% 29.32/29.14  tff(decl_71525, type, 'stem cell differentiation in brain': $i).
% 29.32/29.14  tff(decl_71526, type, 'stem-cell-differentiation-in-brain': $i).
% 29.32/29.14  tff(decl_71527, type, fn_stem_cell_differentiation_in_brain_1: $i > $i).
% 29.32/29.14  tff(decl_71528, type, fn_stem_cell_differentiation_in_brain_2: $i > $i).
% 29.32/29.14  tff(decl_71529, type, fn_stem_cell_differentiation_in_brain_3: $i > $i).
% 29.32/29.14  tff(decl_71530, type, fn_stem_cell_differentiation_in_brain_4: $i > $i).
% 29.32/29.14  tff(decl_71531, type, fn_stem_cell_differentiation_in_brain_5: $i > $i).
% 29.32/29.14  tff(decl_71532, type, fn_stem_cell_differentiation_in_brain_6: $i > $i).
% 29.32/29.14  tff(decl_71533, type, fn_stem_cell_differentiation_in_brain_7: $i > $i).
% 29.32/29.14  tff(decl_71534, type, fn_stem_cell_differentiation_in_brain_8: $i > $i).
% 29.32/29.14  tff(decl_71535, type, fn_stem_cell_differentiation_in_brain_9: $i > $i).
% 29.32/29.14  tff(decl_71536, type, fn_stem_cell_differentiation_in_brain_10: $i > $i).
% 29.32/29.14  tff(decl_71537, type, fn_stem_cell_differentiation_in_brain_11: $i > $i).
% 29.32/29.14  tff(decl_71538, type, 'Stem-Organ': $i).
% 29.32/29.14  tff(decl_71539, type, 'A specialized center of plant function composed of stem tissue and specific to plants.': $i).
% 29.32/29.14  tff(decl_71540, type, 'organ of stem': $i).
% 29.32/29.14  tff(decl_71541, type, 'stem organ': $i).
% 29.32/29.14  tff(decl_71542, type, 'stem-organ': $i).
% 29.32/29.14  tff(decl_71543, type, 'Steroid': $i).
% 29.32/29.14  tff(decl_71544, type, 'A class of lipid molecules having a characteristic skeleton of four rings joined together and various chemical groups attached to them.': $i).
% 29.32/29.14  tff(decl_71545, type, steroid: $i).
% 29.32/29.14  tff(decl_71546, type, fn_steroid_2: $i > $i).
% 29.32/29.14  tff(decl_71547, type, cyclohexane_0: $i).
% 29.32/29.14  tff(decl_71548, type, 'Steroid-Hormone': $i).
% 29.32/29.14  tff(decl_71549, type, 'A steroid molecule that acts as a hormone.': $i).
% 29.32/29.14  tff(decl_71550, type, 'hormone of steroid': $i).
% 29.32/29.14  tff(decl_71551, type, 'steroid hormone': $i).
% 29.32/29.14  tff(decl_71552, type, 'steroid-hormone': $i).
% 29.32/29.14  tff(decl_71553, type, 'Steward': $i).
% 29.32/29.14  tff(decl_71554, type, 'F. C. Steward and his students at Cornell University demonstrated that whole plants could be regenerated from somatic (nonreproductive) cells dissected from a carrot.': $i).
% 29.32/29.14  tff(decl_71555, type, 'fc steward': $i).
% 29.32/29.14  tff(decl_71556, type, 'f.c.steward': $i).
% 29.32/29.14  tff(decl_71557, type, 'frederic campion steward': $i).
% 29.32/29.14  tff(decl_71558, type, steward: $i).
% 29.32/29.14  tff(decl_71559, type, 'Steward-Experiment-On-Carrot': $i).
% 29.32/29.14  tff(decl_71560, type, 'In classic experiments conducted during the 1950s, F. C. Steward and his students at Cornell University demonstrated that whole plants could be regenerated from somatic (nonreproductive) cells dissected from a carrot.': $i).
% 29.32/29.14  tff(decl_71561, type, 'steward experiment on carrot': $i).
% 29.32/29.14  tff(decl_71562, type, 'steward-experiment-on-carrot': $i).
% 29.32/29.14  tff(decl_71563, type, fn_steward_experiment_on_carrot_1: $i > $i).
% 29.32/29.14  tff(decl_71564, type, fn_steward_experiment_on_carrot_2: $i > $i).
% 29.32/29.14  tff(decl_71565, type, fn_steward_experiment_on_carrot_3: $i > $i).
% 29.32/29.14  tff(decl_71566, type, fn_steward_experiment_on_carrot_4: $i > $i).
% 29.32/29.14  tff(decl_71567, type, fn_steward_experiment_on_carrot_5: $i > $i).
% 29.32/29.14  tff(decl_71568, type, fn_steward_experiment_on_carrot_6: $i > $i).
% 29.32/29.14  tff(decl_71569, type, test_tube_cloning_1: $i > $o).
% 29.32/29.14  tff(decl_71570, type, fn_steward_experiment_on_carrot_7: $i > $i).
% 29.32/29.14  tff(decl_71571, type, fn_steward_experiment_on_carrot_8: $i > $i).
% 29.32/29.14  tff(decl_71572, type, fn_steward_experiment_on_carrot_9: $i > $i).
% 29.32/29.14  tff(decl_71573, type, 'Stickleback': $i).
% 29.32/29.14  tff(decl_71574, type, 'A fish of the family Gasterosteidae, characterized by strong spines in the dorsal fin. Sticklebacks do not have scales but some are covered with bony plates.': $i).
% 29.32/29.14  tff(decl_71575, type, stickleback: $i).
% 29.32/29.14  tff(decl_71576, type, 'Stickleback-Fish-Mating-Behavior': $i).
% 29.32/29.14  tff(decl_71577, type, 'An example of an innate courting behavior in which courtship succeeds only if the female displays a swollen belly, which is full of eggs, and the male demonstrates that he has built a nest.': $i).
% 29.32/29.14  tff(decl_71578, type, 'stickleback fish mating behavior': $i).
% 29.32/29.14  tff(decl_71579, type, 'stickleback-fish-mating-behavior': $i).
% 29.32/29.14  tff(decl_71580, type, 'Sticky-End-Fragment': $i).
% 29.32/29.14  tff(decl_71581, type, 'A single-stranded end of a double-stranded staggered cut restriction fragment.': $i).
% 29.32/29.14  tff(decl_71582, type, 'sticky end': $i).
% 29.32/29.14  tff(decl_71583, type, 'sticky end fragment': $i).
% 29.32/29.14  tff(decl_71584, type, 'sticky-end-fragment': $i).
% 29.32/29.14  tff(decl_71585, type, fn_sticky_end_fragment_1: $i > $i).
% 29.32/29.14  tff(decl_71586, type, fn_sticky_end_fragment_2: $i > $i).
% 29.32/29.14  tff(decl_71587, type, fn_sticky_end_fragment_3: $i > $i).
% 29.32/29.14  tff(decl_71588, type, fn_sticky_end_fragment_4: $i > $i).
% 29.32/29.14  tff(decl_71589, type, fn_sticky_end_fragment_5: $i > $i).
% 29.32/29.14  tff(decl_71590, type, fn_sticky_end_fragment_6: $i > $i).
% 29.32/29.14  tff(decl_71591, type, fn_sticky_end_fragment_7: $i > $i).
% 29.32/29.14  tff(decl_71592, type, fn_sticky_end_fragment_8: $i > $i).
% 29.32/29.14  tff(decl_71593, type, fn_sticky_end_fragment_9: $i > $i).
% 29.32/29.14  tff(decl_71594, type, fn_sticky_end_fragment_10: $i > $i).
% 29.32/29.14  tff(decl_71595, type, fn_sticky_end_fragment_11: $i > $i).
% 29.32/29.14  tff(decl_71596, type, fn_sticky_end_fragment_12: $i > $i).
% 29.32/29.14  tff(decl_71597, type, fn_sticky_end_fragment_13: $i > $i).
% 29.32/29.14  tff(decl_71598, type, fn_sticky_end_fragment_16: $i > $i).
% 29.32/29.14  tff(decl_71599, type, fn_sticky_end_fragment_14: $i > $i).
% 29.32/29.14  tff(decl_71600, type, fn_sticky_end_fragment_17: $i > $i).
% 29.32/29.14  tff(decl_71601, type, fn_sticky_end_fragment_15: $i > $i).
% 29.32/29.14  tff(decl_71602, type, stigma_1: $i > $o).
% 29.32/29.14  tff(decl_71603, type, 'Stigma': $i).
% 29.32/29.14  tff(decl_71604, type, 'The receptive tip of a carpel, which traps pollen grains.': $i).
% 29.32/29.14  tff(decl_71605, type, stigma: $i).
% 29.32/29.14  tff(decl_71606, type, 'Stimulus': $i).
% 29.32/29.14  tff(decl_71607, type, 'Entity that serves as a signal that can be perceived by another entity.': $i).
% 29.32/29.14  tff(decl_71608, type, stimuli: $i).
% 29.32/29.14  tff(decl_71609, type, stimulus: $i).
% 29.32/29.14  tff(decl_71610, type, fn_stimulus_1: $i > $i).
% 29.32/29.14  tff(decl_71611, type, 'Stimulus-Generation': $i).
% 29.32/29.14  tff(decl_71612, type, 'The generation or production of an event, molecule or signal that results in a response.': $i).
% 29.32/29.14  tff(decl_71613, type, 'generation of stimulus': $i).
% 29.32/29.14  tff(decl_71614, type, 'stimulus generation': $i).
% 29.32/29.14  tff(decl_71615, type, 'stimulus-generation': $i).
% 29.32/29.14  tff(decl_71616, type, fn_stimulus_generation_1: $i > $i).
% 29.32/29.14  tff(decl_71617, type, stipe_1: $i > $o).
% 29.32/29.14  tff(decl_71618, type, 'Stipe': $i).
% 29.32/29.14  tff(decl_71619, type, 'The stemlike support structure of marine macroalgae.': $i).
% 29.32/29.14  tff(decl_71620, type, stipe: $i).
% 29.32/29.14  tff(decl_71621, type, stock_1: $i > $o).
% 29.32/29.14  tff(decl_71622, type, 'Stock': $i).
% 29.32/29.14  tff(decl_71623, type, 'A plant with a healthy rootstock, onto which a scion can be grafted.': $i).
% 29.32/29.14  tff(decl_71624, type, 'root stock': $i).
% 29.32/29.14  tff(decl_71625, type, 'root-stock': $i).
% 29.32/29.14  tff(decl_71626, type, stock: $i).
% 29.32/29.14  tff(decl_71627, type, stolon_1: $i > $o).
% 29.32/29.14  tff(decl_71628, type, 'Stolon': $i).
% 29.32/29.14  tff(decl_71629, type, 'A horizontal connection between organisms. In plants, a stolon is a horizontal branch arising from the base of a plant and from which new plants can grow. In colonial marine invertebrates, a stolon connects the individual units of the colony.': $i).
% 29.32/29.14  tff(decl_71630, type, 'adventitious root source': $i).
% 29.32/29.14  tff(decl_71631, type, stolon: $i).
% 29.32/29.14  tff(decl_71632, type, 'Stoma': $i).
% 29.32/29.14  tff(decl_71633, type, 'A pore bordered by guard cells in the epidermal tissue of leaves and stems, that allows gases to exchange between the atmosphere and the internal space of a plant.': $i).
% 29.32/29.14  tff(decl_71634, type, stomata: $i).
% 29.32/29.14  tff(decl_71635, type, stoma: $i).
% 29.32/29.14  tff(decl_71636, type, fn_stoma_4: $i > $i).
% 29.32/29.14  tff(decl_71637, type, 'Stomach': $i).
% 29.32/29.14  tff(decl_71638, type, 'The stomach is a muscular, hollow, dilated part of the alimentary canal which functions as the primary organ of the digestive tract.': $i).
% 29.32/29.14  tff(decl_71639, type, stomach: $i).
% 29.32/29.14  tff(decl_71640, type, fn_stomach_1: $i > $i).
% 29.32/29.14  tff(decl_71641, type, fn_stomach_2: $i > $i).
% 29.32/29.14  tff(decl_71642, type, fn_stomach_3: $i > $i).
% 29.32/29.14  tff(decl_71643, type, fn_stomach_4: $i > $i).
% 29.32/29.14  tff(decl_71644, type, fn_stomach_5: $i > $i).
% 29.32/29.14  tff(decl_71645, type, fn_stomach_7: $i > $i).
% 29.32/29.14  tff(decl_71646, type, fn_stomach_9: $i > $i).
% 29.32/29.14  tff(decl_71647, type, fn_stomach_11: $i > $i).
% 29.32/29.14  tff(decl_71648, type, fn_stomach_12: $i > $i).
% 29.32/29.14  tff(decl_71649, type, fn_stomach_13: $i > $i).
% 29.32/29.14  tff(decl_71650, type, fn_stomach_14: $i > $i).
% 29.32/29.14  tff(decl_71651, type, fn_stomach_17: $i > $i).
% 29.32/29.14  tff(decl_71652, type, fn_stomach_18: $i > $i).
% 29.32/29.14  tff(decl_71653, type, fn_stomach_21: $i > $i).
% 29.32/29.14  tff(decl_71654, type, fn_stomach_22: $i > $i).
% 29.32/29.14  tff(decl_71655, type, fn_stomach_23: $i > $i).
% 29.32/29.14  tff(decl_71656, type, fn_stomach_24: $i > $i).
% 29.32/29.14  tff(decl_71657, type, fn_stomach_25: $i > $i).
% 29.32/29.14  tff(decl_71658, type, fn_stomach_26: $i > $i).
% 29.32/29.14  tff(decl_71659, type, fn_stomach_27: $i > $i).
% 29.32/29.14  tff(decl_71660, type, fn_stomach_28: $i > $i).
% 29.32/29.14  tff(decl_71661, type, fn_stomach_29: $i > $i).
% 29.32/29.14  tff(decl_71662, type, fn_stomach_30: $i > $i).
% 29.32/29.14  tff(decl_71663, type, 'Stone': $i).
% 29.32/29.14  tff(decl_71664, type, 'STOP': $i).
% 29.32/29.14  tff(decl_71665, type, 'An action to bring something to halt.': $i).
% 29.32/29.14  tff(decl_71666, type, stop: $i).
% 29.32/29.14  tff(decl_71667, type, terminate_1: $i > $o).
% 29.32/29.14  tff(decl_71668, type, 'Stop-codon': $i).
% 29.32/29.14  tff(decl_71669, type, 'Stop codon is a triplet of nucleotide present on the mRNA which does not code for any amino acid and thus causes termination of translation. UAA, UAG, and UGA are the examples of stop codons': $i).
% 29.32/29.14  tff(decl_71670, type, 'codon of stop': $i).
% 29.32/29.14  tff(decl_71671, type, 'stop codon': $i).
% 29.32/29.14  tff(decl_71672, type, 'stop-codon': $i).
% 29.32/29.14  tff(decl_71673, type, stop_signal_1: $i > $o).
% 29.32/29.14  tff(decl_71674, type, 'Stop-Signal': $i).
% 29.32/29.14  tff(decl_71675, type, 'Message or instructions, carried by a molecule or electrical pulse, which terminates a biological process.': $i).
% 29.32/29.14  tff(decl_71676, type, 'signal of stop': $i).
% 29.32/29.14  tff(decl_71677, type, 'stop signal': $i).
% 29.32/29.14  tff(decl_71678, type, 'stop-signal': $i).
% 29.32/29.14  tff(decl_71679, type, storage_cell_1: $i > $o).
% 29.32/29.14  tff(decl_71680, type, 'Storage-Cell': $i).
% 29.32/29.14  tff(decl_71681, type, 'These are cells specialized to perform particular jobs such as storage.': $i).
% 29.32/29.14  tff(decl_71682, type, 'cell of storage': $i).
% 29.32/29.14  tff(decl_71683, type, 'storage cell': $i).
% 29.32/29.14  tff(decl_71684, type, 'storage-cell': $i).
% 29.32/29.14  tff(decl_71685, type, fn_storage_cell_1: $i > $i).
% 29.32/29.14  tff(decl_71686, type, fn_storage_cell_4: $i > $i).
% 29.32/29.14  tff(decl_71687, type, fn_storage_cell_5: $i > $i).
% 29.32/29.14  tff(decl_71688, type, fn_storage_cell_6: $i > $i).
% 29.32/29.14  tff(decl_71689, type, fn_storage_cell_7: $i > $i).
% 29.32/29.14  tff(decl_71690, type, fn_storage_cell_8: $i > $i).
% 29.32/29.14  tff(decl_71691, type, fn_storage_cell_9: $i > $i).
% 29.32/29.14  tff(decl_71692, type, fn_storage_cell_10: $i > $i).
% 29.32/29.14  tff(decl_71693, type, fn_storage_cell_11: $i > $i).
% 29.32/29.14  tff(decl_71694, type, fn_storage_cell_12: $i > $i).
% 29.32/29.14  tff(decl_71695, type, fn_storage_cell_13: $i > $i).
% 29.32/29.14  tff(decl_71696, type, fn_storage_cell_14: $i > $i).
% 29.32/29.14  tff(decl_71697, type, fn_storage_cell_15: $i > $i).
% 29.32/29.14  tff(decl_71698, type, fn_storage_cell_16: $i > $i).
% 29.32/29.14  tff(decl_71699, type, fn_storage_cell_17: $i > $i).
% 29.32/29.14  tff(decl_71700, type, fn_storage_cell_18: $i > $i).
% 29.32/29.14  tff(decl_71701, type, fn_storage_cell_19: $i > $i).
% 29.32/29.14  tff(decl_71702, type, fn_storage_cell_20: $i > $i).
% 29.32/29.14  tff(decl_71703, type, fn_storage_cell_21: $i > $i).
% 29.32/29.14  tff(decl_71704, type, fn_storage_cell_22: $i > $i).
% 29.32/29.14  tff(decl_71705, type, fn_storage_cell_23: $i > $i).
% 29.32/29.14  tff(decl_71706, type, fn_storage_cell_24: $i > $i).
% 29.32/29.14  tff(decl_71707, type, fn_storage_cell_25: $i > $i).
% 29.32/29.14  tff(decl_71708, type, fn_storage_cell_26: $i > $i).
% 29.32/29.14  tff(decl_71709, type, fn_storage_cell_27: $i > $i).
% 29.32/29.14  tff(decl_71710, type, fn_storage_cell_28: $i > $i).
% 29.32/29.14  tff(decl_71711, type, fn_storage_cell_29: $i > $i).
% 29.32/29.14  tff(decl_71712, type, fn_storage_cell_30: $i > $i).
% 29.32/29.14  tff(decl_71713, type, fn_storage_cell_31: $i > $i).
% 29.32/29.14  tff(decl_71714, type, fn_storage_cell_32: $i > $i).
% 29.32/29.14  tff(decl_71715, type, fn_storage_cell_33: $i > $i).
% 29.32/29.14  tff(decl_71716, type, fn_storage_cell_34: $i > $i).
% 29.32/29.14  tff(decl_71717, type, fn_storage_cell_35: $i > $i).
% 29.32/29.14  tff(decl_71718, type, fn_storage_cell_3: $i > $i).
% 29.32/29.14  tff(decl_71719, type, fn_storage_cell_2: $i > $i).
% 29.32/29.14  tff(decl_71720, type, 'Storage-Polysaccharide': $i).
% 29.32/29.14  tff(decl_71721, type, 'A polysaccharide used primarily for energy storage (e.g., starch).': $i).
% 29.32/29.14  tff(decl_71722, type, 'polysaccharide of storage': $i).
% 29.32/29.14  tff(decl_71723, type, 'storage polysaccharide': $i).
% 29.32/29.14  tff(decl_71724, type, 'storage-polysaccharide': $i).
% 29.32/29.14  tff(decl_71725, type, fn_storage_polysaccharide_3: $i > $i).
% 29.32/29.14  tff(decl_71726, type, fn_storage_polysaccharide_17: $i > $i).
% 29.32/29.14  tff(decl_71727, type, fn_storage_polysaccharide_18: $i > $i).
% 29.32/29.14  tff(decl_71728, type, fn_storage_polysaccharide_21: $i > $i).
% 29.32/29.14  tff(decl_71729, type, fn_storage_polysaccharide_22: $i > $i).
% 29.32/29.14  tff(decl_71730, type, fn_storage_polysaccharide_29: $i > $i).
% 29.32/29.14  tff(decl_71731, type, fn_storage_polysaccharide_47: $i > $i).
% 29.32/29.14  tff(decl_71732, type, fn_storage_polysaccharide_48: $i > $i).
% 29.32/29.14  tff(decl_71733, type, fn_storage_polysaccharide_50: $i > $i).
% 29.32/29.14  tff(decl_71734, type, fn_storage_polysaccharide_61: $i > $i).
% 29.32/29.14  tff(decl_71735, type, fn_storage_polysaccharide_62: $i > $i).
% 29.32/29.14  tff(decl_71736, type, fn_storage_polysaccharide_63: $i > $i).
% 29.32/29.14  tff(decl_71737, type, fn_storage_polysaccharide_65: $i > $i).
% 29.32/29.14  tff(decl_71738, type, fn_storage_polysaccharide_7: $i > $i).
% 29.32/29.14  tff(decl_71739, type, fn_storage_polysaccharide_8: $i > $i).
% 29.32/29.14  tff(decl_71740, type, fn_storage_polysaccharide_10: $i > $i).
% 29.32/29.14  tff(decl_71741, type, fn_storage_polysaccharide_9: $i > $i).
% 29.32/29.14  tff(decl_71742, type, 'Storage-Polysaccharide-Breakdown': $i).
% 29.32/29.14  tff(decl_71743, type, 'The process of breaking down of a storage polysaccharide is called Storage Polysaccharaide Breakdown.': $i).
% 29.32/29.14  tff(decl_71744, type, 'storage polysaccharide breakdown': $i).
% 29.32/29.14  tff(decl_71745, type, 'storage-polysaccharide-breakdown': $i).
% 29.32/29.14  tff(decl_71746, type, fn_storage_polysaccharide_breakdown_1: $i > $i).
% 29.32/29.14  tff(decl_71747, type, storage_protein_1: $i > $o).
% 29.32/29.14  tff(decl_71748, type, 'Storage-Protein': $i).
% 29.32/29.14  tff(decl_71749, type, 'Storage proteins are biological reserves of metal ions and amino acids, used by organisms. They are found in plant seeds, egg whites, and milk.': $i).
% 29.32/29.14  tff(decl_71750, type, 'protein of storage': $i).
% 29.32/29.14  tff(decl_71751, type, 'storage protein': $i).
% 29.32/29.14  tff(decl_71752, type, 'storage-protein': $i).
% 29.32/29.14  tff(decl_71753, type, fn_storage_protein_5: $i > $i).
% 29.32/29.14  tff(decl_71754, type, fn_storage_protein_6: $i > $i).
% 29.32/29.14  tff(decl_71755, type, fn_storage_protein_7: $i > $i).
% 29.32/29.14  tff(decl_71756, type, fn_storage_protein_8: $i > $i).
% 29.32/29.14  tff(decl_71757, type, fn_storage_protein_9: $i > $i).
% 29.32/29.14  tff(decl_71758, type, fn_storage_protein_10: $i > $i).
% 29.32/29.14  tff(decl_71759, type, fn_storage_protein_11: $i > $i).
% 29.32/29.14  tff(decl_71760, type, fn_storage_protein_12: $i > $i).
% 29.32/29.14  tff(decl_71761, type, fn_storage_protein_13: $i > $i).
% 29.32/29.14  tff(decl_71762, type, fn_storage_protein_14: $i > $i).
% 29.32/29.14  tff(decl_71763, type, fn_storage_protein_15: $i > $i).
% 29.32/29.14  tff(decl_71764, type, fn_storage_protein_16: $i > $i).
% 29.32/29.14  tff(decl_71765, type, fn_storage_protein_17: $i > $i).
% 29.32/29.14  tff(decl_71766, type, fn_storage_protein_18: $i > $i).
% 29.32/29.14  tff(decl_71767, type, fn_storage_protein_19: $i > $i).
% 29.32/29.14  tff(decl_71768, type, fn_storage_protein_20: $i > $i).
% 29.32/29.14  tff(decl_71769, type, fn_storage_protein_21: $i > $i).
% 29.32/29.14  tff(decl_71770, type, fn_storage_protein_1: $i > $i).
% 29.32/29.14  tff(decl_71771, type, fn_storage_protein_3: $i > $i).
% 29.32/29.14  tff(decl_71772, type, fn_storage_protein_2: $i > $i).
% 29.32/29.14  tff(decl_71773, type, fn_storage_protein_4: $i > $i).
% 29.32/29.14  tff(decl_71774, type, 'Store': $i).
% 29.32/29.14  tff(decl_71775, type, 'Stramenopile': $i).
% 29.32/29.14  tff(decl_71776, type, 'A protist with two flagella, one of which is smooth while the other is covered with fine hairs.': $i).
% 29.32/29.14  tff(decl_71777, type, stramenopile: $i).
% 29.32/29.14  tff(decl_71778, type, 'Stratified-Squamous-Epithelium': $i).
% 29.32/29.14  tff(decl_71779, type, 'A type of epithelial tissue that regenerates rapidly near the basement membrane. Commonly found in surfaces subject to abrasion (e.g., lining of the esophagus, anus, vagina).': $i).
% 29.32/29.14  tff(decl_71780, type, 'stratified squamous epithelium': $i).
% 29.32/29.14  tff(decl_71781, type, 'stratified-squamous-epithelium': $i).
% 29.32/29.14  tff(decl_71782, type, stratum_1: $i > $o).
% 29.32/29.14  tff(decl_71783, type, 'Stratum': $i).
% 29.32/29.14  tff(decl_71784, type, 'A layer of sedimentary rock.': $i).
% 29.32/29.14  tff(decl_71785, type, stratum: $i).
% 29.32/29.14  tff(decl_71786, type, 'Stream': $i).
% 29.32/29.14  tff(decl_71787, type, 'A body of water that flows within a bed or channel.': $i).
% 29.32/29.14  tff(decl_71788, type, stream: $i).
% 29.32/29.14  tff(decl_71789, type, 'Streptococcus-Pneumoniae': $i).
% 29.32/29.14  tff(decl_71790, type, 'A species of spherical Gram-positive bacteria belonging to the phylum Firmicutes.': $i).
% 29.32/29.14  tff(decl_71791, type, 'streptococcus pneumoniae': $i).
% 29.32/29.14  tff(decl_71792, type, 'streptococcus-pneumoniae': $i).
% 29.32/29.14  tff(decl_71793, type, 'Streptophyta': $i).
% 29.32/29.14  tff(decl_71794, type, 'The name proposed for a new phylum of plants, including the green algae and the land plants.': $i).
% 29.32/29.14  tff(decl_71795, type, streptophyta: $i).
% 29.32/29.14  tff(decl_71796, type, stress_1: $i > $o).
% 29.32/29.14  tff(decl_71797, type, 'Stress': $i).
% 29.32/29.14  tff(decl_71798, type, 'Any factor that causes bodily or mental tension.': $i).
% 29.32/29.14  tff(decl_71799, type, stress: $i).
% 29.32/29.14  tff(decl_71800, type, 'Striated-Muscle': $i).
% 29.32/29.14  tff(decl_71801, type, 'Muscle fibers that have repeating sarcomeres, giving the appearance of light and dark bands.': $i).
% 29.32/29.14  tff(decl_71802, type, 'striated muscle': $i).
% 29.32/29.14  tff(decl_71803, type, 'striated-muscle': $i).
% 29.32/29.14  tff(decl_71804, type, 'String': $i).
% 29.32/29.14  tff(decl_71805, type, 'atomic symbol': $i).
% 29.32/29.14  tff(decl_71806, type, 'atomic-symbol': $i).
% 29.32/29.14  tff(decl_71807, type, strobilus_1: $i > $o).
% 29.32/29.14  tff(decl_71808, type, 'Strobilus': $i).
% 29.32/29.14  tff(decl_71809, type, 'A cluster of sporophylls, common in gymnosperms and in some seedless vascular plants.': $i).
% 29.32/29.14  tff(decl_71810, type, strobilus: $i).
% 29.32/29.14  tff(decl_71811, type, 'Stroke': $i).
% 29.32/29.14  tff(decl_71812, type, 'Damage or death to brain tissue caused when blood flow is interrupted to the brain.': $i).
% 29.32/29.14  tff(decl_71813, type, stroke: $i).
% 29.32/29.14  tff(decl_71814, type, 'Stroma': $i).
% 29.32/29.14  tff(decl_71815, type, 'Stroma is the fluid filled outside a thylakoid. The stroma contains chloroplast DNA and Ribosome besides many enzymes': $i).
% 29.32/29.14  tff(decl_71816, type, stroma: $i).
% 29.32/29.14  tff(decl_71817, type, stromatolite_1: $i > $o).
% 29.32/29.14  tff(decl_71818, type, 'Stromatolite': $i).
% 29.32/29.14  tff(decl_71819, type, 'Layered structures formed by cyanobacterial cells that adhere films of sediment together.': $i).
% 29.32/29.14  tff(decl_71820, type, stromatolite: $i).
% 29.32/29.14  tff(decl_71821, type, 'Strong-Acid': $i).
% 29.32/29.14  tff(decl_71822, type, 'A strong acid is an acid that ionizes completely in an aqueous solution by losing one proton.': $i).
% 29.32/29.14  tff(decl_71823, type, 'strong acid': $i).
% 29.32/29.14  tff(decl_71824, type, 'strong-acid': $i).
% 29.32/29.14  tff(decl_71825, type, fn_strong_acid_2: $i > $i).
% 29.32/29.14  tff(decl_71826, type, weak_acid_0: $i).
% 29.32/29.14  tff(decl_71827, type, strong_acid_dissociation_reaction_1: $i > $o).
% 29.32/29.14  tff(decl_71828, type, 'Strong-Acid-Dissociation-Reaction': $i).
% 29.32/29.14  tff(decl_71829, type, 'A reaction where 100% of the molecules of an acidic substance release H+ ions into solution.': $i).
% 29.32/29.14  tff(decl_71830, type, 'strong acid dissociation reaction': $i).
% 29.32/29.14  tff(decl_71831, type, 'strong-acid-dissociation-reaction': $i).
% 29.32/29.14  tff(decl_71832, type, weak_acid_dissociation_reaction_1: $i > $o).
% 29.32/29.14  tff(decl_71833, type, fn_strong_acid_dissociation_reaction_1: $i > $i).
% 29.32/29.14  tff(decl_71834, type, fn_strong_acid_dissociation_reaction_2: $i > $i).
% 29.32/29.14  tff(decl_71835, type, fn_strong_acid_dissociation_reaction_4: $i > $i).
% 29.32/29.14  tff(decl_71836, type, fn_strong_acid_dissociation_reaction_5: $i > $i).
% 29.32/29.14  tff(decl_71837, type, fn_strong_acid_dissociation_reaction_3: $i > $i).
% 29.32/29.14  tff(decl_71838, type, 'Strong-Base': $i).
% 29.32/29.14  tff(decl_71839, type, 'A base which hydrolyzes completely, raising the pH of the solution toward 14.': $i).
% 29.32/29.14  tff(decl_71840, type, 'strong base': $i).
% 29.32/29.14  tff(decl_71841, type, 'strong-base': $i).
% 29.32/29.14  tff(decl_71842, type, fn_strong_base_3: $i > $i).
% 29.32/29.14  tff(decl_71843, type, fn_strong_base_4: $i > $i).
% 29.32/29.14  tff(decl_71844, type, fn_strong_base_5: $i > $i).
% 29.32/29.14  tff(decl_71845, type, fn_strong_base_11: $i > $i).
% 29.32/29.14  tff(decl_71846, type, fn_strong_base_12: $i > $i).
% 29.32/29.14  tff(decl_71847, type, fn_strong_base_13: $i > $i).
% 29.32/29.14  tff(decl_71848, type, fn_strong_base_14: $i > $i).
% 29.32/29.14  tff(decl_71849, type, fn_strong_base_15: $i > $i).
% 29.32/29.14  tff(decl_71850, type, fn_strong_base_16: $i > $i).
% 29.32/29.14  tff(decl_71851, type, fn_strong_base_17: $i > $i).
% 29.32/29.14  tff(decl_71852, type, fn_strong_base_18: $i > $i).
% 29.32/29.14  tff(decl_71853, type, fn_strong_base_19: $i > $i).
% 29.32/29.14  tff(decl_71854, type, fn_strong_base_20: $i > $i).
% 29.32/29.14  tff(decl_71855, type, fn_strong_base_22: $i > $i).
% 29.32/29.14  tff(decl_71856, type, fn_strong_base_23: $i > $i).
% 29.32/29.14  tff(decl_71857, type, fn_water_20: $i > $i).
% 29.32/29.14  tff(decl_71858, type, fn_water_21: $i > $i).
% 29.32/29.14  tff(decl_71859, type, fn_water_19: $i > $i).
% 29.32/29.14  tff(decl_71860, type, fn_water_24: $i > $i).
% 29.32/29.14  tff(decl_71861, type, fn_water_23: $i > $i).
% 29.32/29.14  tff(decl_71862, type, fn_water_22: $i > $i).
% 29.32/29.14  tff(decl_71863, type, fn_water_25: $i > $i).
% 29.32/29.14  tff(decl_71864, type, weak_base_0: $i).
% 29.32/29.14  tff(decl_71865, type, fn_strong_base_10: $i > $i).
% 29.32/29.14  tff(decl_71866, type, fn_strong_base_9: $i > $i).
% 29.32/29.14  tff(decl_71867, type, fn_strong_base_8: $i > $i).
% 29.32/29.14  tff(decl_71868, type, fn_strong_base_7: $i > $i).
% 29.32/29.14  tff(decl_71869, type, fn_strong_base_21: $i > $i).
% 29.32/29.14  tff(decl_71870, type, strong_base_dissociation_reaction_1: $i > $o).
% 29.32/29.14  tff(decl_71871, type, 'Strong-Base-Dissociation-Reaction': $i).
% 29.32/29.14  tff(decl_71872, type, 'Dissociation reaction with a strong base such that nearly all of the molecules dissociate.  Strong bases include sodium hydroxide (NaOH), which is also a strong electrolyte.': $i).
% 29.32/29.14  tff(decl_71873, type, 'strong base dissociation reaction': $i).
% 29.32/29.14  tff(decl_71874, type, 'strong-base-dissociation-reaction': $i).
% 29.32/29.14  tff(decl_71875, type, fn_strong_base_dissociation_reaction_1: $i > $i).
% 29.32/29.14  tff(decl_71876, type, fn_strong_base_dissociation_reaction_2: $i > $i).
% 29.32/29.14  tff(decl_71877, type, fn_strong_base_dissociation_reaction_3: $i > $i).
% 29.32/29.14  tff(decl_71878, type, fn_strong_base_dissociation_reaction_4: $i > $i).
% 29.32/29.14  tff(decl_71879, type, fn_strong_base_dissociation_reaction_7: $i > $i).
% 29.32/29.14  tff(decl_71880, type, fn_strong_base_dissociation_reaction_10: $i > $i).
% 29.32/29.14  tff(decl_71881, type, fn_strong_base_dissociation_reaction_11: $i > $i).
% 29.32/29.14  tff(decl_71882, type, fn_strong_base_dissociation_reaction_12: $i > $i).
% 29.32/29.14  tff(decl_71883, type, fn_strong_base_dissociation_reaction_13: $i > $i).
% 29.32/29.14  tff(decl_71884, type, fn_strong_base_dissociation_reaction_14: $i > $i).
% 29.32/29.14  tff(decl_71885, type, fn_strong_base_dissociation_reaction_16: $i > $i).
% 29.32/29.14  tff(decl_71886, type, fn_strong_base_dissociation_reaction_17: $i > $i).
% 29.32/29.14  tff(decl_71887, type, fn_strong_base_dissociation_reaction_18: $i > $i).
% 29.32/29.14  tff(decl_71888, type, fn_strong_base_dissociation_reaction_19: $i > $i).
% 29.32/29.14  tff(decl_71889, type, fn_reverse_reaction_3: $i > $i).
% 29.32/29.14  tff(decl_71890, type, fn_reverse_reaction_4: $i > $i).
% 29.32/29.14  tff(decl_71891, type, fn_strong_base_dissociation_reaction_15: $i > $i).
% 29.32/29.14  tff(decl_71892, type, fn_strong_base_dissociation_reaction_8: $i > $i).
% 29.32/29.14  tff(decl_71893, type, fn_strong_base_dissociation_reaction_9: $i > $i).
% 29.32/29.14  tff(decl_71894, type, 'Strong-Electrolyte': $i).
% 29.32/29.14  tff(decl_71895, type, 'A substance that is completely ionized in solution, for example, strong acids, strong bases, and most salts.': $i).
% 29.32/29.14  tff(decl_71896, type, 'strong electrolyte': $i).
% 29.32/29.14  tff(decl_71897, type, 'strong-electrolyte': $i).
% 29.32/29.14  tff(decl_71898, type, weak_electrolyte_1: $i > $o).
% 29.32/29.14  tff(decl_71899, type, fn_strong_electrolyte_3: $i > $i).
% 29.32/29.14  tff(decl_71900, type, fn_strong_electrolyte_4: $i > $i).
% 29.32/29.14  tff(decl_71901, type, strong_electrolyte_entity_1: $i > $o).
% 29.32/29.14  tff(decl_71902, type, 'Strong-Electrolyte-Entity': $i).
% 29.32/29.14  tff(decl_71903, type, 'A strong electrolyte entity is the basic structural unit of a substance that is completely ionized in solution, for example, strong acids, strong bases, and most salts.': $i).
% 29.32/29.14  tff(decl_71904, type, 'strong electrolyte entity': $i).
% 29.32/29.14  tff(decl_71905, type, 'strong-electrolyte-entity': $i).
% 29.32/29.14  tff(decl_71906, type, fn_strong_electrolyte_entity_1: $i > $i).
% 29.32/29.14  tff(decl_71907, type, strontium_1: $i > $o).
% 29.32/29.14  tff(decl_71908, type, 'Strontium': $i).
% 29.32/29.14  tff(decl_71909, type, 'Strontium is a metal atom with atomic number 38. It is represented by the symbol Sr.': $i).
% 29.32/29.14  tff(decl_71910, type, strontium: $i).
% 29.32/29.14  tff(decl_71911, type, 'Sr': $i).
% 29.32/29.14  tff(decl_71912, type, fn_strontium_4: $i > $i).
% 29.32/29.14  tff(decl_71913, type, fn_strontium_5: $i > $i).
% 29.32/29.14  tff(decl_71914, type, fn_strontium_6: $i > $i).
% 29.32/29.14  tff(decl_71915, type, fn_strontium_7: $i > $i).
% 29.32/29.14  tff(decl_71916, type, fn_strontium_11: $i > $i).
% 29.32/29.14  tff(decl_71917, type, fn_strontium_12: $i > $i).
% 29.32/29.14  tff(decl_71918, type, fn_strontium_13: $i > $i).
% 29.32/29.14  tff(decl_71919, type, fn_strontium_14: $i > $i).
% 29.32/29.14  tff(decl_71920, type, "38": $i).
% 29.32/29.14  tff(decl_71921, type, "0.95": $i).
% 29.32/29.14  tff(decl_71922, type, "87.62": $i).
% 29.32/29.14  tff(decl_71923, type, fn_strontium_9: $i > $i).
% 29.32/29.14  tff(decl_71924, type, fn_strontium_10: $i > $i).
% 29.32/29.14  tff(decl_71925, type, fn_strontium_8: $i > $i).
% 29.32/29.14  tff(decl_71926, type, 'Structural-Complexity-Constant': $i).
% 29.32/29.14  tff(decl_71927, type, 'structural complexity constant': $i).
% 29.32/29.14  tff(decl_71928, type, 'structural-complexity-constant': $i).
% 29.32/29.14  tff(decl_71929, type, structural_complexity_scale_1: $i > $o).
% 29.32/29.14  tff(decl_71930, type, 'Structural-Complexity-Scale': $i).
% 29.32/29.14  tff(decl_71931, type, 'structural complexity scale': $i).
% 29.32/29.14  tff(decl_71932, type, 'structural-complexity-scale': $i).
% 29.32/29.14  tff(decl_71933, type, 'Structural-Complexity-Value': $i).
% 29.32/29.14  tff(decl_71934, type, 'structural complexity': $i).
% 29.32/29.14  tff(decl_71935, type, 'structural-complexity': $i).
% 29.32/29.14  tff(decl_71936, type, 'structural complexity value': $i).
% 29.32/29.14  tff(decl_71937, type, 'structural-complexity-value': $i).
% 29.32/29.14  tff(decl_71938, type, structural_formula_1: $i > $o).
% 29.32/29.14  tff(decl_71939, type, 'Structural-Formula': $i).
% 29.32/29.14  tff(decl_71940, type, 'A graphical representation of the molecular structure of a chemical compound.': $i).
% 29.32/29.14  tff(decl_71941, type, 'structural formula': $i).
% 29.32/29.14  tff(decl_71942, type, 'structural-formula': $i).
% 29.32/29.14  tff(decl_71943, type, structural_gene_1: $i > $o).
% 29.32/29.14  tff(decl_71944, type, 'Structural-Gene': $i).
% 29.32/29.14  tff(decl_71945, type, 'A gene that codes for any RNA or protein product other than a regulatory factor.': $i).
% 29.32/29.14  tff(decl_71946, type, 'structural gene': $i).
% 29.32/29.14  tff(decl_71947, type, 'structural-gene': $i).
% 29.32/29.14  tff(decl_71948, type, fn_structural_gene_1: $i > $i).
% 29.32/29.14  tff(decl_71949, type, fn_structural_gene_2: $i > $i).
% 29.32/29.14  tff(decl_71950, type, 'Structural-Polysaccharide': $i).
% 29.32/29.14  tff(decl_71951, type, 'A polysaccharide used primarily for structural support (e.g., cellulose).': $i).
% 29.32/29.14  tff(decl_71952, type, 'structural polysaccharide': $i).
% 29.32/29.14  tff(decl_71953, type, 'structural-polysaccharide': $i).
% 29.32/29.14  tff(decl_71954, type, fn_structural_polysaccharide_2: $i > $i).
% 29.32/29.14  tff(decl_71955, type, fn_structural_polysaccharide_5: $i > $i).
% 29.32/29.14  tff(decl_71956, type, 'Structural-Protein': $i).
% 29.32/29.14  tff(decl_71957, type, 'A protein whose primary function is structural support.': $i).
% 29.32/29.14  tff(decl_71958, type, 'structural protein': $i).
% 29.32/29.14  tff(decl_71959, type, 'structural-protein': $i).
% 29.32/29.14  tff(decl_71960, type, 'Structural-Role': $i).
% 29.32/29.14  tff(decl_71961, type, 'This is the functional role played by organisms due to its structural shape.': $i).
% 29.32/29.14  tff(decl_71962, type, 'structural role': $i).
% 29.32/29.14  tff(decl_71963, type, 'structural-role': $i).
% 29.32/29.14  tff(decl_71964, type, 'Study': $i).
% 29.32/29.14  tff(decl_71965, type, 'An epidemiological study such as an experiment or clinical trial.': $i).
% 29.32/29.14  tff(decl_71966, type, fn_study_of_membrane_by_electron_microscopy_3: $i > $i).
% 29.32/29.14  tff(decl_71967, type, fn_study_of_membrane_by_electron_microscopy_2: $i > $i).
% 29.32/29.14  tff(decl_71968, type, 'Study-Of-Membrane-By-Electron-Microscopy': $i).
% 29.32/29.14  tff(decl_71969, type, 'A method of preparing cells for electron microscopy called freeze-fracture has demonstrated visually that proteins are indeed embedded in the phospholipid bilayer of the membrane.': $i).
% 29.32/29.14  tff(decl_71970, type, 'study of membrane by electron microscopy': $i).
% 29.32/29.14  tff(decl_71971, type, 'study-of-membrane-by-electron-microscopy': $i).
% 29.32/29.14  tff(decl_71972, type, fn_study_of_membrane_by_electron_microscopy_4: $i > $i).
% 29.32/29.14  tff(decl_71973, type, fn_study_of_membrane_by_electron_microscopy_5: $i > $i).
% 29.32/29.14  tff(decl_71974, type, 'Study-On-Drosophila-By-Morgan': $i).
% 29.32/29.14  tff(decl_71975, type, 'First chosen as a model organism by the pioneering geneticist T. H. Morgan and intensively studied by generations of geneticists after him, the fruit fly Drosophila melanogasteris small and easily grown in the laboratory.': $i).
% 29.32/29.14  tff(decl_71976, type, 'study on drosophila by morgan': $i).
% 29.32/29.14  tff(decl_71977, type, 'study-on-drosophila-by-morgan': $i).
% 29.32/29.14  tff(decl_71978, type, fn_study_on_drosophila_by_morgan_1: $i > $i).
% 29.32/29.14  tff(decl_71979, type, fn_study_on_drosophila_by_morgan_2: $i > $i).
% 29.32/29.14  tff(decl_71980, type, fn_study_on_drosophila_by_morgan_3: $i > $i).
% 29.32/29.14  tff(decl_71981, type, fn_study_on_drosophila_by_morgan_4: $i > $i).
% 29.32/29.14  tff(decl_71982, type, fn_study_on_drosophila_by_morgan_5: $i > $i).
% 29.32/29.14  tff(decl_71983, type, fn_study_on_drosophila_by_morgan_6: $i > $i).
% 29.32/29.14  tff(decl_71984, type, fn_study_on_drosophila_by_morgan_7: $i > $i).
% 29.32/29.14  tff(decl_71985, type, 'Sturtevant': $i).
% 29.32/29.14  tff(decl_71986, type, 'Alfred Sturtevant  was an American geneticist. Using genetic material from the organism Drosophila melanogaster, Sturtevant constructed the first genetic map of a chromosome in 1913.': $i).
% 29.32/29.14  tff(decl_71987, type, 'alfred sturtevant': $i).
% 29.32/29.14  tff(decl_71988, type, 'alfred henry sturtevant': $i).
% 29.32/29.14  tff(decl_71989, type, sturtevant: $i).
% 29.32/29.14  tff(decl_71990, type, fn_sturtevant_1: $i > $i).
% 29.32/29.14  tff(decl_71991, type, fn_sturtevant_2: $i > $i).
% 29.32/29.14  tff(decl_71992, type, fn_sturtevant_3: $i > $i).
% 29.32/29.14  tff(decl_71993, type, style_1: $i > $o).
% 29.32/29.14  tff(decl_71994, type, 'Style': $i).
% 29.32/29.14  tff(decl_71995, type, 'In a flower, the stalk of a carpel, through which pollen tubes grow to reach the ovary.': $i).
% 29.32/29.14  tff(decl_71996, type, 'Stylonychia': $i).
% 29.32/29.14  tff(decl_71997, type, 'A genus of ciliates, common in freshwater and soils.': $i).
% 29.32/29.14  tff(decl_71998, type, stylonychia: $i).
% 29.32/29.14  tff(decl_71999, type, 'Subatomic-Particle': $i).
% 29.32/29.14  tff(decl_72000, type, 'A particle that is one of the constituents of an atom.': $i).
% 29.32/29.14  tff(decl_72001, type, 'Parts that make up atoms.': $i).
% 29.32/29.14  tff(decl_72002, type, 'subatomic particle': $i).
% 29.32/29.14  tff(decl_72003, type, 'subatomic-particle': $i).
% 29.32/29.14  tff(decl_72004, type, 'Subcellular-Assembly': $i).
% 29.32/29.14  tff(decl_72005, type, 'A molecular assembly that functions at the subcellular level.': $i).
% 29.32/29.14  tff(decl_72006, type, 'subcellular assembly': $i).
% 29.32/29.14  tff(decl_72007, type, 'subcellular-assembly': $i).
% 29.32/29.14  tff(decl_72008, type, 'Subcellular-Movement': $i).
% 29.32/29.14  tff(decl_72009, type, 'Movement which occurs at the subcellular level.': $i).
% 29.32/29.14  tff(decl_72010, type, 'subcellular movement': $i).
% 29.32/29.14  tff(decl_72011, type, 'subcellular-movement': $i).
% 29.32/29.14  tff(decl_72012, type, subcellular_process_1: $i > $o).
% 29.32/29.14  tff(decl_72013, type, 'Subcellular-Process': $i).
% 29.32/29.14  tff(decl_72014, type, 'Any process occuring at the subcellular level.': $i).
% 29.32/29.14  tff(decl_72015, type, 'subcellular process': $i).
% 29.32/29.14  tff(decl_72016, type, 'subcellular-process': $i).
% 29.32/29.14  tff(decl_72017, type, 'Subcellular-Region': $i).
% 29.32/29.14  tff(decl_72018, type, 'A region of a subcellular entity.': $i).
% 29.32/29.14  tff(decl_72019, type, 'subcellular region': $i).
% 29.32/29.14  tff(decl_72020, type, 'subcellular-region': $i).
% 29.32/29.14  tff(decl_72021, type, 'Suberin': $i).
% 29.32/29.14  tff(decl_72022, type, 'Suberin is a waxy material impervious to water and dissolved minerals.': $i).
% 29.32/29.14  tff(decl_72023, type, suberin: $i).
% 29.32/29.14  tff(decl_72024, type, subglacial_ecosystem_1: $i > $o).
% 29.32/29.14  tff(decl_72025, type, 'Subglacial-Ecosystem': $i).
% 29.32/29.14  tff(decl_72026, type, 'An ecosystem found beneath glaciers.': $i).
% 29.32/29.14  tff(decl_72027, type, 'subglacial ecosystem': $i).
% 29.32/29.14  tff(decl_72028, type, 'subglacial-ecosystem': $i).
% 29.32/29.14  tff(decl_72029, type, fn_subglacial_ecosystem_1: $i > $i).
% 29.32/29.14  tff(decl_72030, type, fn_subglacial_ecosystem_2: $i > $i).
% 29.32/29.14  tff(decl_72031, type, fn_subglacial_ecosystem_3: $i > $i).
% 29.32/29.14  tff(decl_72032, type, fn_subglacial_ecosystem_5: $i > $i).
% 29.32/29.14  tff(decl_72033, type, fn_subglacial_ecosystem_6: $i > $i).
% 29.32/29.14  tff(decl_72034, type, fn_subglacial_ecosystem_7: $i > $i).
% 29.32/29.14  tff(decl_72035, type, fn_subglacial_ecosystem_8: $i > $i).
% 29.32/29.14  tff(decl_72036, type, fn_subglacial_ecosystem_9: $i > $i).
% 29.32/29.14  tff(decl_72037, type, fn_subglacial_ecosystem_10: $i > $i).
% 29.32/29.14  tff(decl_72038, type, fn_subglacial_ecosystem_11: $i > $i).
% 29.32/29.14  tff(decl_72039, type, fn_subglacial_ecosystem_12: $i > $i).
% 29.32/29.14  tff(decl_72040, type, fn_subglacial_ecosystem_13: $i > $i).
% 29.32/29.14  tff(decl_72041, type, fn_subglacial_ecosystem_14: $i > $i).
% 29.32/29.14  tff(decl_72042, type, fn_subglacial_ecosystem_15: $i > $i).
% 29.32/29.14  tff(decl_72043, type, fn_subglacial_ecosystem_16: $i > $i).
% 29.32/29.14  tff(decl_72044, type, fn_subglacial_ecosystem_17: $i > $i).
% 29.32/29.14  tff(decl_72045, type, fn_subglacial_ecosystem_18: $i > $i).
% 29.32/29.14  tff(decl_72046, type, fn_subglacial_ecosystem_19: $i > $i).
% 29.32/29.14  tff(decl_72047, type, fn_subglacial_ecosystem_20: $i > $i).
% 29.32/29.14  tff(decl_72048, type, fn_subglacial_ecosystem_21: $i > $i).
% 29.32/29.14  tff(decl_72049, type, fn_subglacial_ecosystem_22: $i > $i).
% 29.32/29.14  tff(decl_72050, type, fn_subglacial_ecosystem_23: $i > $i).
% 29.32/29.14  tff(decl_72051, type, fn_subglacial_ecosystem_24: $i > $i).
% 29.32/29.14  tff(decl_72052, type, fn_subglacial_ecosystem_25: $i > $i).
% 29.32/29.14  tff(decl_72053, type, fn_subglacial_ecosystem_26: $i > $i).
% 29.32/29.14  tff(decl_72054, type, fn_subglacial_ecosystem_27: $i > $i).
% 29.32/29.14  tff(decl_72055, type, fn_subglacial_ecosystem_28: $i > $i).
% 29.32/29.14  tff(decl_72056, type, fn_subglacial_ecosystem_29: $i > $i).
% 29.32/29.14  tff(decl_72057, type, fn_subglacial_ecosystem_30: $i > $i).
% 29.32/29.14  tff(decl_72058, type, fn_subglacial_ecosystem_31: $i > $i).
% 29.32/29.14  tff(decl_72059, type, fn_subglacial_ecosystem_32: $i > $i).
% 29.32/29.14  tff(decl_72060, type, fn_subglacial_ecosystem_33: $i > $i).
% 29.32/29.14  tff(decl_72061, type, fn_subglacial_ecosystem_4: $i > $i).
% 29.32/29.14  tff(decl_72062, type, 'Submucosa': $i).
% 29.32/29.14  tff(decl_72063, type, 'The connective tissue that supports a mucous membrane.': $i).
% 29.32/29.14  tff(decl_72064, type, submucosa: $i).
% 29.32/29.14  tff(decl_72065, type, 'Suborganismal-Entity': $i).
% 29.32/29.14  tff(decl_72066, type, 'Suborganismal \\living\\ components of organisms,                      including systems, organs, tissues, and cells.': $i).
% 29.32/29.14  tff(decl_72067, type, 'suborganismal entity': $i).
% 29.32/29.14  tff(decl_72068, type, 'suborganismal-entity': $i).
% 29.32/29.14  tff(decl_72069, type, 'Subscript-Value': $i).
% 29.32/29.14  tff(decl_72070, type, 'a number that indicates the mole proportion of the preceeding element': $i).
% 29.32/29.14  tff(decl_72071, type, subscript: $i).
% 29.32/29.14  tff(decl_72072, type, 'value of subscript': $i).
% 29.32/29.14  tff(decl_72073, type, 'subscript value': $i).
% 29.32/29.14  tff(decl_72074, type, 'subscript-value': $i).
% 29.32/29.14  tff(decl_72075, type, 'Substance': $i).
% 29.32/29.14  tff(decl_72076, type, 'Substance may refer to:Chemical substance, a material with a definite chemical composition Matter, the substance of which all physical objects are made Substance theory, theory positing that a substance is distinct from its properties.': $i).
% 29.32/29.14  tff(decl_72077, type, 'has solvent': $i).
% 29.32/29.14  tff(decl_72078, type, 'has-solvent': $i).
% 29.32/29.14  tff(decl_72079, type, 'has solute': $i).
% 29.32/29.14  tff(decl_72080, type, 'has-solute': $i).
% 29.32/29.14  tff(decl_72081, type, matter: $i).
% 29.32/29.14  tff(decl_72082, type, fn_substance_1: $i > $i).
% 29.32/29.14  tff(decl_72083, type, 'Substance-P': $i).
% 29.32/29.14  tff(decl_72084, type, 'A neuropeptide that mediates the perception of pain.': $i).
% 29.32/29.14  tff(decl_72085, type, 'p of substance': $i).
% 29.32/29.14  tff(decl_72086, type, 'substance p': $i).
% 29.32/29.14  tff(decl_72087, type, 'substance-p': $i).
% 29.32/29.14  tff(decl_72088, type, 'Substrate': $i).
% 29.32/29.14  tff(decl_72089, type, 'The reactant on which an enzyme works.': $i).
% 29.32/29.14  tff(decl_72090, type, substrate: $i).
% 29.32/29.14  tff(decl_72091, type, 'Substrate-Feeder': $i).
% 29.32/29.14  tff(decl_72092, type, 'An animal that lives on or in its food source and eats its way through the food, such as an earthworm.': $i).
% 29.32/29.14  tff(decl_72093, type, 'feeder of substrate': $i).
% 29.32/29.14  tff(decl_72094, type, 'substrate feeder': $i).
% 29.32/29.14  tff(decl_72095, type, 'substrate-feeder': $i).
% 29.32/29.14  tff(decl_72096, type, 'Substrate-Feeding': $i).
% 29.32/29.14  tff(decl_72097, type, 'The act of eating through the substrate, which is also the animal\\s food.': $i).
% 29.32/29.14  tff(decl_72098, type, 'feeding of substrate': $i).
% 29.32/29.14  tff(decl_72099, type, 'substrate feeding': $i).
% 29.32/29.14  tff(decl_72100, type, 'substrate-feeding': $i).
% 29.32/29.14  tff(decl_72101, type, 'Substrate-Level-Phosphorylation': $i).
% 29.32/29.14  tff(decl_72102, type, 'Production of ATP by the direct transfer of a phosphate group from an intermediate molecule to ADP.': $i).
% 29.32/29.14  tff(decl_72103, type, 'substrate level phosphorylation': $i).
% 29.32/29.14  tff(decl_72104, type, 'substrate-level-phosphorylation': $i).
% 29.32/29.14  tff(decl_72105, type, subterranean_ecosystem_1: $i > $o).
% 29.32/29.14  tff(decl_72106, type, 'Subterranean-Ecosystem': $i).
% 29.32/29.14  tff(decl_72107, type, 'Ecosystem, such as a cave or cavern, which is found beneath the surface of the earth. Most subterranean ecosystems receive little to no sunlight.': $i).
% 29.32/29.14  tff(decl_72108, type, 'subterranean ecosystem': $i).
% 29.32/29.14  tff(decl_72109, type, 'subterranean-ecosystem': $i).
% 29.32/29.14  tff(decl_72110, type, fn_subterranean_ecosystem_1: $i > $i).
% 29.32/29.14  tff(decl_72111, type, fn_subterranean_ecosystem_2: $i > $i).
% 29.32/29.14  tff(decl_72112, type, fn_subterranean_ecosystem_3: $i > $i).
% 29.32/29.14  tff(decl_72113, type, fn_subterranean_ecosystem_5: $i > $i).
% 29.32/29.14  tff(decl_72114, type, fn_subterranean_ecosystem_6: $i > $i).
% 29.32/29.14  tff(decl_72115, type, fn_subterranean_ecosystem_7: $i > $i).
% 29.32/29.14  tff(decl_72116, type, fn_subterranean_ecosystem_8: $i > $i).
% 29.32/29.14  tff(decl_72117, type, fn_subterranean_ecosystem_9: $i > $i).
% 29.32/29.14  tff(decl_72118, type, fn_subterranean_ecosystem_4: $i > $i).
% 29.32/29.14  tff(decl_72119, type, 'Succinate': $i).
% 29.32/29.14  tff(decl_72120, type, 'Succinate is a salt or ester of succinic acid.': $i).
% 29.32/29.14  tff(decl_72121, type, succinate: $i).
% 29.32/29.14  tff(decl_72122, type, 'Succinyl-CoA': $i).
% 29.32/29.14  tff(decl_72123, type, 'Succinyl-Coenzyme A, abbreviated as Succinyl-CoA or SucCoA, is a combination of succinic acid and coenzyme A.': $i).
% 29.32/29.14  tff(decl_72124, type, 'succinyl coenzyme a': $i).
% 29.32/29.14  tff(decl_72125, type, 'succinyl-coenzyme-a': $i).
% 29.32/29.14  tff(decl_72126, type, 'suc coa': $i).
% 29.32/29.14  tff(decl_72127, type, 'suc-coa': $i).
% 29.32/29.14  tff(decl_72128, type, 'succinyl coa': $i).
% 29.32/29.14  tff(decl_72129, type, 'succinyl-coa': $i).
% 29.32/29.14  tff(decl_72130, type, fn_succinyl_coa_1: $i > $i).
% 29.32/29.14  tff(decl_72131, type, 'Succulent-Plant': $i).
% 29.32/29.14  tff(decl_72132, type, 'Succulent plants, also known as succulents or fat plants, are water-retaining plants adapted to arid climates or soil conditions. Succulent plants store water in their leaves, stems, and also in roots.': $i).
% 29.32/29.14  tff(decl_72133, type, 'water storing plant': $i).
% 29.32/29.14  tff(decl_72134, type, 'plant of succulent': $i).
% 29.32/29.14  tff(decl_72135, type, 'succulent plant': $i).
% 29.32/29.14  tff(decl_72136, type, 'succulent-plant': $i).
% 29.32/29.14  tff(decl_72137, type, fn_succulent_plant_2: $i > $i).
% 29.32/29.14  tff(decl_72138, type, fn_succulent_plant_6: $i > $i).
% 29.32/29.14  tff(decl_72139, type, fn_succulent_plant_7: $i > $i).
% 29.32/29.14  tff(decl_72140, type, fn_succulent_plant_11: $i > $i).
% 29.32/29.14  tff(decl_72141, type, fn_succulent_plant_12: $i > $i).
% 29.32/29.14  tff(decl_72142, type, fn_succulent_plant_13: $i > $i).
% 29.32/29.14  tff(decl_72143, type, fn_succulent_plant_14: $i > $i).
% 29.32/29.14  tff(decl_72144, type, fn_succulent_plant_21: $i > $i).
% 29.32/29.14  tff(decl_72145, type, fn_succulent_plant_22: $i > $i).
% 29.32/29.14  tff(decl_72146, type, fn_succulent_plant_23: $i > $i).
% 29.32/29.14  tff(decl_72147, type, fn_succulent_plant_25: $i > $i).
% 29.32/29.14  tff(decl_72148, type, fn_succulent_plant_26: $i > $i).
% 29.32/29.14  tff(decl_72149, type, fn_succulent_plant_27: $i > $i).
% 29.32/29.14  tff(decl_72150, type, fn_succulent_plant_28: $i > $i).
% 29.32/29.14  tff(decl_72151, type, fn_succulent_plant_29: $i > $i).
% 29.32/29.14  tff(decl_72152, type, fn_succulent_plant_30: $i > $i).
% 29.32/29.14  tff(decl_72153, type, fn_succulent_plant_34: $i > $i).
% 29.32/29.14  tff(decl_72154, type, fn_succulent_plant_35: $i > $i).
% 29.32/29.14  tff(decl_72155, type, fn_succulent_plant_37: $i > $i).
% 29.32/29.14  tff(decl_72156, type, fn_succulent_plant_39: $i > $i).
% 29.32/29.14  tff(decl_72157, type, fn_succulent_plant_40: $i > $i).
% 29.32/29.14  tff(decl_72158, type, fn_succulent_plant_45: $i > $i).
% 29.32/29.14  tff(decl_72159, type, fn_succulent_plant_47: $i > $i).
% 29.32/29.14  tff(decl_72160, type, fn_succulent_plant_48: $i > $i).
% 29.32/29.14  tff(decl_72161, type, fn_succulent_plant_53: $i > $i).
% 29.32/29.14  tff(decl_72162, type, fn_succulent_plant_54: $i > $i).
% 29.32/29.14  tff(decl_72163, type, fn_succulent_plant_55: $i > $i).
% 29.32/29.14  tff(decl_72164, type, fn_succulent_plant_56: $i > $i).
% 29.32/29.14  tff(decl_72165, type, fn_succulent_plant_57: $i > $i).
% 29.32/29.14  tff(decl_72166, type, fn_succulent_plant_65: $i > $i).
% 29.32/29.14  tff(decl_72167, type, fn_succulent_plant_66: $i > $i).
% 29.32/29.14  tff(decl_72168, type, fn_succulent_plant_67: $i > $i).
% 29.32/29.14  tff(decl_72169, type, fn_succulent_plant_68: $i > $i).
% 29.32/29.14  tff(decl_72170, type, fn_succulent_plant_69: $i > $i).
% 29.32/29.14  tff(decl_72171, type, fn_succulent_plant_70: $i > $i).
% 29.32/29.14  tff(decl_72172, type, fn_succulent_plant_72: $i > $i).
% 29.32/29.14  tff(decl_72173, type, fn_succulent_plant_73: $i > $i).
% 29.32/29.14  tff(decl_72174, type, fn_succulent_plant_18: $i > $i).
% 29.32/29.14  tff(decl_72175, type, fn_succulent_plant_17: $i > $i).
% 29.32/29.14  tff(decl_72176, type, fn_succulent_plant_16: $i > $i).
% 29.32/29.14  tff(decl_72177, type, fn_succulent_plant_15: $i > $i).
% 29.32/29.14  tff(decl_72178, type, fn_succulent_plant_19: $i > $i).
% 29.32/29.14  tff(decl_72179, type, fn_succulent_plant_20: $i > $i).
% 29.32/29.14  tff(decl_72180, type, 'Sucking-Louse': $i).
% 29.32/29.14  tff(decl_72181, type, 'A blood-sucking ectoparasite of mammals.': $i).
% 29.32/29.14  tff(decl_72182, type, 'head lice': $i).
% 29.32/29.14  tff(decl_72183, type, 'head-lice': $i).
% 29.32/29.14  tff(decl_72184, type, lice: $i).
% 29.32/29.14  tff(decl_72185, type, 'crab louse': $i).
% 29.32/29.14  tff(decl_72186, type, 'louse of sucking': $i).
% 29.32/29.14  tff(decl_72187, type, 'Sucrase': $i).
% 29.32/29.14  tff(decl_72188, type, 'Class of enzymes which catalyze the hydrolysis of sucrose to fructose and glucose.': $i).
% 29.32/29.14  tff(decl_72189, type, sucrase: $i).
% 29.32/29.14  tff(decl_72190, type, fn_sucrase_1: $i > $i).
% 29.32/29.14  tff(decl_72191, type, fn_sucrase_2: $i > $i).
% 29.32/29.14  tff(decl_72192, type, fn_sucrase_3: $i > $i).
% 29.32/29.14  tff(decl_72193, type, fn_sucrase_4: $i > $i).
% 29.32/29.14  tff(decl_72194, type, fn_sucrase_5: $i > $i).
% 29.32/29.14  tff(decl_72195, type, fn_sucrase_6: $i > $i).
% 29.32/29.14  tff(decl_72196, type, fn_sucrase_7: $i > $i).
% 29.32/29.14  tff(decl_72197, type, fn_sucrase_8: $i > $i).
% 29.32/29.14  tff(decl_72198, type, fn_sucrase_9: $i > $i).
% 29.32/29.14  tff(decl_72199, type, fn_sucrase_10: $i > $i).
% 29.32/29.14  tff(decl_72200, type, fn_sucrase_11: $i > $i).
% 29.32/29.14  tff(decl_72201, type, 'Sucrose': $i).
% 29.32/29.14  tff(decl_72202, type, 'A disaccharide formed by the linking of the monosaccharides glucose and fructose.': $i).
% 29.32/29.14  tff(decl_72203, type, 'table sugar': $i).
% 29.32/29.14  tff(decl_72204, type, 'table-sugar': $i).
% 29.32/29.14  tff(decl_72205, type, c12h22o11: $i).
% 29.32/29.14  tff(decl_72206, type, sucrose: $i).
% 29.32/29.14  tff(decl_72207, type, fn_sucrose_2: $i > $i).
% 29.32/29.14  tff(decl_72208, type, fn_sucrose_5: $i > $i).
% 29.32/29.14  tff(decl_72209, type, fn_sucrose_6: $i > $i).
% 29.32/29.14  tff(decl_72210, type, fn_sucrose_7: $i > $i).
% 29.32/29.14  tff(decl_72211, type, fn_sucrose_8: $i > $i).
% 29.32/29.14  tff(decl_72212, type, fn_sucrose_9: $i > $i).
% 29.32/29.14  tff(decl_72213, type, fn_sucrose_10: $i > $i).
% 29.32/29.14  tff(decl_72214, type, fn_sucrose_11: $i > $i).
% 29.32/29.14  tff(decl_72215, type, fn_sucrose_12: $i > $i).
% 29.32/29.14  tff(decl_72216, type, fn_sucrose_13: $i > $i).
% 29.32/29.14  tff(decl_72217, type, fn_sucrose_14: $i > $i).
% 29.32/29.14  tff(decl_72218, type, fn_sucrose_15: $i > $i).
% 29.32/29.14  tff(decl_72219, type, fn_sucrose_16: $i > $i).
% 29.32/29.14  tff(decl_72220, type, fn_sucrose_17: $i > $i).
% 29.32/29.14  tff(decl_72221, type, fn_sucrose_18: $i > $i).
% 29.32/29.14  tff(decl_72222, type, fn_sucrose_19: $i > $i).
% 29.32/29.14  tff(decl_72223, type, fn_sucrose_20: $i > $i).
% 29.32/29.14  tff(decl_72224, type, fn_sucrose_21: $i > $i).
% 29.32/29.14  tff(decl_72225, type, fn_sucrose_22: $i > $i).
% 29.32/29.14  tff(decl_72226, type, fn_sucrose_23: $i > $i).
% 29.32/29.14  tff(decl_72227, type, fn_sucrose_24: $i > $i).
% 29.32/29.14  tff(decl_72228, type, fn_sucrose_25: $i > $i).
% 29.32/29.14  tff(decl_72229, type, fn_sucrose_26: $i > $i).
% 29.32/29.14  tff(decl_72230, type, fn_sucrose_27: $i > $i).
% 29.32/29.14  tff(decl_72231, type, fn_sucrose_28: $i > $i).
% 29.32/29.14  tff(decl_72232, type, fn_sucrose_32: $i > $i).
% 29.32/29.14  tff(decl_72233, type, fn_sucrose_33: $i > $i).
% 29.32/29.14  tff(decl_72234, type, fn_sucrose_34: $i > $i).
% 29.32/29.14  tff(decl_72235, type, fn_sucrose_35: $i > $i).
% 29.32/29.14  tff(decl_72236, type, fn_sucrose_36: $i > $i).
% 29.32/29.14  tff(decl_72237, type, fn_sucrose_37: $i > $i).
% 29.32/29.14  tff(decl_72238, type, fn_sucrose_38: $i > $i).
% 29.32/29.14  tff(decl_72239, type, fn_sucrose_39: $i > $i).
% 29.32/29.14  tff(decl_72240, type, fn_sucrose_40: $i > $i).
% 29.32/29.14  tff(decl_72241, type, fn_sucrose_41: $i > $i).
% 29.32/29.14  tff(decl_72242, type, fn_sucrose_42: $i > $i).
% 29.32/29.14  tff(decl_72243, type, fn_sucrose_43: $i > $i).
% 29.32/29.14  tff(decl_72244, type, fn_sucrose_44: $i > $i).
% 29.32/29.14  tff(decl_72245, type, fn_sucrose_45: $i > $i).
% 29.32/29.14  tff(decl_72246, type, fn_sucrose_46: $i > $i).
% 29.32/29.14  tff(decl_72247, type, fn_sucrose_47: $i > $i).
% 29.32/29.14  tff(decl_72248, type, fn_sucrose_48: $i > $i).
% 29.32/29.14  tff(decl_72249, type, fn_sucrose_4: $i > $i).
% 29.32/29.14  tff(decl_72250, type, fn_sucrose_52: $i > $i).
% 29.32/29.14  tff(decl_72251, type, fn_sucrose_3: $i > $i).
% 29.32/29.14  tff(decl_72252, type, fn_sucrose_53: $i > $i).
% 29.32/29.14  tff(decl_72253, type, 'Sucrose-Hydrogen-ion-Cotransporter': $i).
% 29.32/29.14  tff(decl_72254, type, 'A transport protein responsible for simultaneous moving across of sucrose and hydrogen ions across a biomembrane.': $i).
% 29.32/29.14  tff(decl_72255, type, 'sucrose hydrogen ion cotransporter': $i).
% 29.32/29.14  tff(decl_72256, type, 'sucrose-hydrogen-ion-cotransporter': $i).
% 29.32/29.14  tff(decl_72257, type, fn_sucrose_hydrogen_ion_cotransporter_5: $i > $i).
% 29.32/29.14  tff(decl_72258, type, fn_sucrose_hydrogen_ion_cotransporter_6: $i > $i).
% 29.32/29.14  tff(decl_72259, type, fn_sucrose_hydrogen_ion_cotransporter_8: $i > $i).
% 29.32/29.14  tff(decl_72260, type, fn_sucrose_hydrogen_ion_cotransporter_9: $i > $i).
% 29.32/29.14  tff(decl_72261, type, fn_sucrose_hydrogen_ion_cotransporter_10: $i > $i).
% 29.32/29.14  tff(decl_72262, type, fn_sucrose_hydrogen_ion_cotransporter_11: $i > $i).
% 29.32/29.14  tff(decl_72263, type, fn_sucrose_hydrogen_ion_cotransporter_12: $i > $i).
% 29.32/29.14  tff(decl_72264, type, fn_sucrose_hydrogen_ion_cotransporter_13: $i > $i).
% 29.32/29.14  tff(decl_72265, type, fn_sucrose_hydrogen_ion_cotransporter_14: $i > $i).
% 29.32/29.14  tff(decl_72266, type, fn_sucrose_hydrogen_ion_cotransporter_15: $i > $i).
% 29.32/29.14  tff(decl_72267, type, fn_sucrose_hydrogen_ion_cotransporter_16: $i > $i).
% 29.32/29.14  tff(decl_72268, type, fn_sucrose_hydrogen_ion_cotransporter_17: $i > $i).
% 29.32/29.14  tff(decl_72269, type, fn_sucrose_hydrogen_ion_cotransporter_18: $i > $i).
% 29.32/29.14  tff(decl_72270, type, fn_sucrose_hydrogen_ion_cotransporter_19: $i > $i).
% 29.32/29.14  tff(decl_72271, type, fn_sucrose_hydrogen_ion_cotransporter_20: $i > $i).
% 29.32/29.14  tff(decl_72272, type, fn_sucrose_hydrogen_ion_cotransporter_21: $i > $i).
% 29.32/29.14  tff(decl_72273, type, fn_sucrose_hydrogen_ion_cotransporter_22: $i > $i).
% 29.32/29.14  tff(decl_72274, type, fn_sucrose_hydrogen_ion_cotransporter_23: $i > $i).
% 29.32/29.14  tff(decl_72275, type, fn_sucrose_hydrogen_ion_cotransporter_24: $i > $i).
% 29.32/29.14  tff(decl_72276, type, fn_sucrose_hydrogen_ion_cotransporter_25: $i > $i).
% 29.32/29.14  tff(decl_72277, type, fn_sucrose_hydrogen_ion_cotransporter_26: $i > $i).
% 29.32/29.14  tff(decl_72278, type, fn_sucrose_hydrogen_ion_cotransporter_27: $i > $i).
% 29.32/29.14  tff(decl_72279, type, fn_sucrose_hydrogen_ion_cotransporter_29: $i > $i).
% 29.32/29.14  tff(decl_72280, type, fn_sucrose_hydrogen_ion_cotransporter_30: $i > $i).
% 29.32/29.14  tff(decl_72281, type, fn_sucrose_hydrogen_ion_cotransporter_31: $i > $i).
% 29.32/29.14  tff(decl_72282, type, fn_sucrose_hydrogen_ion_cotransporter_32: $i > $i).
% 29.32/29.14  tff(decl_72283, type, fn_sucrose_hydrogen_ion_cotransporter_33: $i > $i).
% 29.32/29.14  tff(decl_72284, type, fn_sucrose_hydrogen_ion_cotransporter_35: $i > $i).
% 29.32/29.14  tff(decl_72285, type, fn_sucrose_hydrogen_ion_cotransporter_36: $i > $i).
% 29.32/29.14  tff(decl_72286, type, fn_sucrose_hydrogen_ion_cotransporter_37: $i > $i).
% 29.32/29.14  tff(decl_72287, type, fn_sucrose_hydrogen_ion_cotransporter_4: $i > $i).
% 29.32/29.14  tff(decl_72288, type, fn_sucrose_hydrogen_ion_cotransporter_3: $i > $i).
% 29.32/29.14  tff(decl_72289, type, fn_sucrose_hydrogen_ion_cotransporter_2: $i > $i).
% 29.32/29.14  tff(decl_72290, type, fn_sucrose_hydrogen_ion_cotransporter_1: $i > $i).
% 29.32/29.14  tff(decl_72291, type, sucrose_transport_from_leaf_1: $i > $o).
% 29.32/29.14  tff(decl_72292, type, 'Sucrose-Transport-From-Leaf': $i).
% 29.32/29.14  tff(decl_72293, type, 'In plants, the process in which sucrose made in the leaves is transported to other parts of the plant.': $i).
% 29.32/29.14  tff(decl_72294, type, 'sucrose transport from leaf': $i).
% 29.32/29.14  tff(decl_72295, type, 'sucrose-transport-from-leaf': $i).
% 29.32/29.14  tff(decl_72296, type, fn_sucrose_transport_from_leaf_1: $i > $i).
% 29.32/29.14  tff(decl_72297, type, fn_sucrose_transport_from_leaf_2: $i > $i).
% 29.32/29.14  tff(decl_72298, type, fn_sucrose_transport_from_leaf_3: $i > $i).
% 29.32/29.14  tff(decl_72299, type, 'Suction-Tube': $i).
% 29.32/29.14  tff(decl_72300, type, 'Medical device used in fetal testing.  The suction tube is inserted through the cervix to remove a sample of the chorionic villi of the placenta.': $i).
% 29.32/29.14  tff(decl_72301, type, 'tube of suction': $i).
% 29.32/29.14  tff(decl_72302, type, 'suction tube': $i).
% 29.32/29.14  tff(decl_72303, type, 'suction-tube': $i).
% 29.32/29.14  tff(decl_72304, type, 'Sugar': $i).
% 29.32/29.14  tff(decl_72305, type, 'Any of a class of sweet-tasting, water-soluble, crystalline carbohydrates, such as the monosaccharides and disaccharides.': $i).
% 29.32/29.14  tff(decl_72306, type, sugar: $i).
% 29.32/29.14  tff(decl_72307, type, 'Sugar-Phosphate-Backbone': $i).
% 29.32/29.14  tff(decl_72308, type, 'Sugar phosphate backbone is the major structural component of the  nucleic acids consisting of sugars and phosphate groups joined by ester bonds.': $i).
% 29.32/29.14  tff(decl_72309, type, 'sugar phosphate backbone': $i).
% 29.32/29.14  tff(decl_72310, type, 'sugar-phosphate-backbone': $i).
% 29.32/29.14  tff(decl_72311, type, sugar_sink_1: $i > $o).
% 29.32/29.14  tff(decl_72312, type, 'Sugar-Sink': $i).
% 29.32/29.14  tff(decl_72313, type, 'A plant organ that is a net consumer or storer of sugar. Growing roots, shoot tips, stems, and fruits are sugar sinks supplied by phloem.': $i).
% 29.32/29.14  tff(decl_72314, type, 'sugar sink': $i).
% 29.32/29.14  tff(decl_72315, type, 'sugar-sink': $i).
% 29.32/29.14  tff(decl_72316, type, fn_sugar_sink_1: $i > $i).
% 29.32/29.14  tff(decl_72317, type, fn_sugar_sink_2: $i > $i).
% 29.32/29.14  tff(decl_72318, type, sugar_solute_1: $i > $o).
% 29.32/29.14  tff(decl_72319, type, 'Sugar-solute': $i).
% 29.32/29.14  tff(decl_72320, type, 'In a solution, the solute is the solid substance which dissolves. In this case, the solute is a sugar.': $i).
% 29.32/29.14  tff(decl_72321, type, 'solute of sugar': $i).
% 29.32/29.14  tff(decl_72322, type, 'sugar solute': $i).
% 29.32/29.14  tff(decl_72323, type, 'sugar-solute': $i).
% 29.32/29.14  tff(decl_72324, type, 'Sugar-Solution': $i).
% 29.32/29.14  tff(decl_72325, type, 'A solution where sugar is the solute and water is the solvent.': $i).
% 29.32/29.14  tff(decl_72326, type, 'solution of sugar': $i).
% 29.32/29.14  tff(decl_72327, type, 'sugar solution': $i).
% 29.32/29.14  tff(decl_72328, type, 'sugar-solution': $i).
% 29.32/29.14  tff(decl_72329, type, sugar_source_1: $i > $o).
% 29.32/29.14  tff(decl_72330, type, 'Sugar-Source': $i).
% 29.32/29.14  tff(decl_72331, type, 'A sugar source is a plant organ that is a net producer of sugar, by photosynthesis or by breakdown of starch.': $i).
% 29.32/29.14  tff(decl_72332, type, 'source of sugar': $i).
% 29.32/29.14  tff(decl_72333, type, 'sugar source': $i).
% 29.32/29.14  tff(decl_72334, type, 'sugar-source': $i).
% 29.32/29.14  tff(decl_72335, type, fn_sugar_source_1: $i > $i).
% 29.32/29.14  tff(decl_72336, type, fn_sugar_source_2: $i > $i).
% 29.32/29.14  tff(decl_72337, type, 'Sugar-Substance': $i).
% 29.32/29.14  tff(decl_72338, type, 'Substance composed of sugar molecules.': $i).
% 29.32/29.14  tff(decl_72339, type, 'substance of sugar': $i).
% 29.32/29.14  tff(decl_72340, type, 'sugar substance': $i).
% 29.32/29.14  tff(decl_72341, type, 'sugar-substance': $i).
% 29.32/29.14  tff(decl_72342, type, fn_sugar_substance_2: $i > $i).
% 29.32/29.14  tff(decl_72343, type, fn_sugar_substance_3: $i > $i).
% 29.32/29.14  tff(decl_72344, type, fn_sugar_substance_1: $i > $i).
% 29.32/29.14  tff(decl_72345, type, 'Sugarcane-Plant': $i).
% 29.32/29.14  tff(decl_72346, type, 'sugarcane, perennial grass of the genus Saccharum cultivated for its juice, from which sugar is processed.': $i).
% 29.32/29.14  tff(decl_72347, type, 'plant of sugarcane': $i).
% 29.32/29.14  tff(decl_72348, type, 'sugarcane plant': $i).
% 29.32/29.14  tff(decl_72349, type, 'sugarcane-plant': $i).
% 29.32/29.14  tff(decl_72350, type, fn_sugarcane_plant_1: $i > $i).
% 29.32/29.14  tff(decl_72351, type, fn_sugarcane_plant_2: $i > $i).
% 29.32/29.14  tff(decl_72352, type, 'Suggest': $i).
% 29.32/29.14  tff(decl_72353, type, propose: $i).
% 29.32/29.14  tff(decl_72354, type, suggest: $i).
% 29.32/29.14  tff(decl_72355, type, advise: $i).
% 29.32/29.14  tff(decl_72356, type, fn_suggest_1: $i > $i).
% 29.32/29.14  tff(decl_72357, type, 'Suggestion': $i).
% 29.32/29.14  tff(decl_72358, type, suggestion: $i).
% 29.32/29.14  tff(decl_72359, type, proposition: $i).
% 29.32/29.14  tff(decl_72360, type, proffer: $i).
% 29.32/29.14  tff(decl_72361, type, suicide_protein_1: $i > $o).
% 29.32/29.14  tff(decl_72362, type, 'Suicide-Protein': $i).
% 29.32/29.14  tff(decl_72363, type, 'A protein responsibile for apoptosis.': $i).
% 29.32/29.14  tff(decl_72364, type, 'suicide protein': $i).
% 29.32/29.14  tff(decl_72365, type, 'suicide-protein': $i).
% 29.32/29.14  tff(decl_72366, type, fn_suicide_protein_1: $i > $i).
% 29.32/29.14  tff(decl_72367, type, 'Sulfate': $i).
% 29.32/29.14  tff(decl_72368, type, 'Polyatomic ion of sulfur with a charge of minus 3.': $i).
% 29.32/29.14  tff(decl_72369, type, fn_sulfate_2: $i > $i).
% 29.32/29.14  tff(decl_72370, type, fn_sulfate_1: $i > $i).
% 29.32/29.14  tff(decl_72371, type, sulfate_reducing_bacterium_1: $i > $o).
% 29.32/29.14  tff(decl_72372, type, 'Sulfate-Reducing-Bacterium': $i).
% 29.32/29.14  tff(decl_72373, type, 'Sulfate-reducing bacteria are those bacteria  that can obtain energy by oxidizing organic compounds or molecular hydrogen (H2) while reducing sulfate to hydrogen sulfide (H2S).': $i).
% 29.32/29.14  tff(decl_72374, type, 'sulfate reducing bacterium': $i).
% 29.32/29.14  tff(decl_72375, type, 'sulfate-reducing-bacterium': $i).
% 29.32/29.14  tff(decl_72376, type, fn_sulfate_reducing_bacterium_4: $i > $i).
% 29.32/29.14  tff(decl_72377, type, fn_sulfate_reducing_bacterium_5: $i > $i).
% 29.32/29.14  tff(decl_72378, type, fn_sulfate_reducing_bacterium_6: $i > $i).
% 29.32/29.14  tff(decl_72379, type, fn_sulfate_reducing_bacterium_7: $i > $i).
% 29.32/29.14  tff(decl_72380, type, fn_sulfate_reducing_bacterium_8: $i > $i).
% 29.32/29.14  tff(decl_72381, type, fn_sulfate_reducing_bacterium_9: $i > $i).
% 29.32/29.14  tff(decl_72382, type, fn_sulfate_reducing_bacterium_10: $i > $i).
% 29.32/29.14  tff(decl_72383, type, fn_sulfate_reducing_bacterium_11: $i > $i).
% 29.32/29.14  tff(decl_72384, type, fn_sulfate_reducing_bacterium_12: $i > $i).
% 29.32/29.14  tff(decl_72385, type, fn_sulfate_reducing_bacterium_13: $i > $i).
% 29.32/29.14  tff(decl_72386, type, fn_sulfate_reducing_bacterium_14: $i > $i).
% 29.32/29.14  tff(decl_72387, type, fn_sulfate_reducing_bacterium_16: $i > $i).
% 29.32/29.14  tff(decl_72388, type, fn_sulfate_reducing_bacterium_17: $i > $i).
% 29.32/29.14  tff(decl_72389, type, fn_sulfate_reducing_bacterium_18: $i > $i).
% 29.32/29.14  tff(decl_72390, type, fn_sulfate_reducing_bacterium_19: $i > $i).
% 29.32/29.14  tff(decl_72391, type, fn_sulfate_reducing_bacterium_20: $i > $i).
% 29.32/29.14  tff(decl_72392, type, fn_sulfate_reducing_bacterium_21: $i > $i).
% 29.32/29.14  tff(decl_72393, type, fn_sulfate_reducing_bacterium_22: $i > $i).
% 29.32/29.14  tff(decl_72394, type, fn_sulfate_reducing_bacterium_23: $i > $i).
% 29.32/29.14  tff(decl_72395, type, fn_sulfate_reducing_bacterium_24: $i > $i).
% 29.32/29.14  tff(decl_72396, type, fn_sulfate_reducing_bacterium_25: $i > $i).
% 29.32/29.14  tff(decl_72397, type, fn_sulfate_reducing_bacterium_2: $i > $i).
% 29.32/29.14  tff(decl_72398, type, fn_sulfate_reducing_bacterium_3: $i > $i).
% 29.32/29.14  tff(decl_72399, type, fn_sulfate_reducing_bacterium_1: $i > $i).
% 29.32/29.14  tff(decl_72400, type, fn_sulfate_reducing_bacterium_15: $i > $i).
% 29.32/29.14  tff(decl_72401, type, 'Sulfhydryl-Group': $i).
% 29.32/29.14  tff(decl_72402, type, 'A sulfhydryl group or thiol group is a functional group composed of a sulfur and a hydrogen atom (-SH)': $i).
% 29.32/29.14  tff(decl_72403, type, 'thiol group': $i).
% 29.32/29.14  tff(decl_72404, type, 'sulfhydryl group': $i).
% 29.32/29.14  tff(decl_72405, type, 'sulfhydryl-group': $i).
% 29.32/29.14  tff(decl_72406, type, fn_sulfhydryl_group_1: $i > $i).
% 29.32/29.14  tff(decl_72407, type, fn_sulfhydryl_group_2: $i > $i).
% 29.32/29.14  tff(decl_72408, type, fn_sulfhydryl_group_4: $i > $i).
% 29.32/29.14  tff(decl_72409, type, fn_sulfhydryl_group_5: $i > $i).
% 29.32/29.14  tff(decl_72410, type, fn_sulfhydryl_group_6: $i > $i).
% 29.32/29.14  tff(decl_72411, type, fn_sulfhydryl_group_7: $i > $i).
% 29.32/29.14  tff(decl_72412, type, fn_sulfhydryl_group_8: $i > $i).
% 29.32/29.14  tff(decl_72413, type, fn_sulfhydryl_group_9: $i > $i).
% 29.32/29.14  tff(decl_72414, type, fn_sulfhydryl_group_10: $i > $i).
% 29.32/29.14  tff(decl_72415, type, fn_sulfhydryl_group_11: $i > $i).
% 29.32/29.14  tff(decl_72416, type, 'Sulfide': $i).
% 29.32/29.14  tff(decl_72417, type, 'Anion of the element Sufur with a charge of minus 1': $i).
% 29.32/29.14  tff(decl_72418, type, fn_sulfide_2: $i > $i).
% 29.32/29.14  tff(decl_72419, type, fn_sulfide_1: $i > $i).
% 29.32/29.14  tff(decl_72420, type, sulfolobus_1: $i > $o).
% 29.32/29.14  tff(decl_72421, type, 'Sulfolobus': $i).
% 29.32/29.14  tff(decl_72422, type, 'A genus of chemoautotrophic archaea found largely in volcanic hot springs.': $i).
% 29.32/29.14  tff(decl_72423, type, sulfolobus: $i).
% 29.32/29.14  tff(decl_72424, type, fn_sulfolobus_1: $i > $i).
% 29.32/29.14  tff(decl_72425, type, fn_sulfolobus_2: $i > $i).
% 29.32/29.14  tff(decl_72426, type, fn_sulfolobus_3: $i > $i).
% 29.32/29.14  tff(decl_72427, type, fn_sulfolobus_4: $i > $i).
% 29.32/29.14  tff(decl_72428, type, fn_sulfolobus_5: $i > $i).
% 29.32/29.14  tff(decl_72429, type, fn_sulfolobus_6: $i > $i).
% 29.32/29.14  tff(decl_72430, type, fn_sulfolobus_7: $i > $i).
% 29.32/29.14  tff(decl_72431, type, fn_sulfolobus_8: $i > $i).
% 29.32/29.14  tff(decl_72432, type, fn_sulfolobus_9: $i > $i).
% 29.32/29.14  tff(decl_72433, type, fn_sulfolobus_10: $i > $i).
% 29.32/29.14  tff(decl_72434, type, fn_sulfolobus_11: $i > $i).
% 29.32/29.14  tff(decl_72435, type, fn_sulfolobus_12: $i > $i).
% 29.32/29.14  tff(decl_72436, type, fn_sulfolobus_13: $i > $i).
% 29.32/29.14  tff(decl_72437, type, fn_sulfolobus_14: $i > $i).
% 29.32/29.14  tff(decl_72438, type, fn_sulfolobus_15: $i > $i).
% 29.32/29.14  tff(decl_72439, type, fn_sulfolobus_16: $i > $i).
% 29.32/29.14  tff(decl_72440, type, fn_sulfolobus_17: $i > $i).
% 29.32/29.14  tff(decl_72441, type, fn_sulfolobus_18: $i > $i).
% 29.32/29.14  tff(decl_72442, type, fn_sulfolobus_19: $i > $i).
% 29.32/29.14  tff(decl_72443, type, fn_sulfolobus_23: $i > $i).
% 29.32/29.14  tff(decl_72444, type, fn_sulfolobus_22: $i > $i).
% 29.32/29.14  tff(decl_72445, type, fn_sulfolobus_20: $i > $i).
% 29.32/29.14  tff(decl_72446, type, fn_sulfolobus_21: $i > $i).
% 29.32/29.14  tff(decl_72447, type, 'Sulfur': $i).
% 29.32/29.14  tff(decl_72448, type, 'Sulfur is a non metal atom with atomic number 16. It is represented by the symbol S.': $i).
% 29.32/29.14  tff(decl_72449, type, sulfur: $i).
% 29.32/29.14  tff(decl_72450, type, fn_sulfur_2: $i > $i).
% 29.32/29.14  tff(decl_72451, type, fn_sulfur_3: $i > $i).
% 29.32/29.14  tff(decl_72452, type, fn_sulfur_7: $i > $i).
% 29.32/29.14  tff(decl_72453, type, fn_sulfur_8: $i > $i).
% 29.32/29.14  tff(decl_72454, type, fn_sulfur_9: $i > $i).
% 29.32/29.14  tff(decl_72455, type, fn_sulfur_10: $i > $i).
% 29.32/29.14  tff(decl_72456, type, fn_sulfur_11: $i > $i).
% 29.32/29.14  tff(decl_72457, type, "2.58": $i).
% 29.32/29.14  tff(decl_72458, type, "32.07": $i).
% 29.32/29.14  tff(decl_72459, type, fn_sulfur_5: $i > $i).
% 29.32/29.14  tff(decl_72460, type, fn_sulfur_4: $i > $i).
% 29.32/29.14  tff(decl_72461, type, fn_sulfur_6: $i > $i).
% 29.32/29.14  tff(decl_72462, type, sulfur_32_1: $i > $o).
% 29.32/29.14  tff(decl_72463, type, 'Sulfur-32': $i).
% 29.32/29.14  tff(decl_72464, type, 'Isotope of sulfur with 16 neutrons.': $i).
% 29.32/29.14  tff(decl_72465, type, 'sulfur 32': $i).
% 29.32/29.14  tff(decl_72466, type, 'sulfur-32': $i).
% 29.32/29.14  tff(decl_72467, type, sulfur_isotope_1: $i > $o).
% 29.32/29.14  tff(decl_72468, type, fn_sulfur_32_2: $i > $i).
% 29.32/29.14  tff(decl_72469, type, fn_sulfur_32_4: $i > $i).
% 29.32/29.14  tff(decl_72470, type, fn_sulfur_32_5: $i > $i).
% 29.32/29.14  tff(decl_72471, type, "31.972e0": $i).
% 29.32/29.14  tff(decl_72472, type, fn_sulfur_isotope_2: $i > $i).
% 29.32/29.14  tff(decl_72473, type, fn_sulfur_32_3: $i > $i).
% 29.32/29.14  tff(decl_72474, type, 'Sulfur-35': $i).
% 29.32/29.14  tff(decl_72475, type, 'This is one of the Sulfur isotopes that possess nineteen neutrons.': $i).
% 29.32/29.14  tff(decl_72476, type, 's 35': $i).
% 29.32/29.14  tff(decl_72477, type, 's-35': $i).
% 29.32/29.14  tff(decl_72478, type, 'sulfur 35': $i).
% 29.32/29.14  tff(decl_72479, type, 'sulfur-35': $i).
% 29.32/29.14  tff(decl_72480, type, fn_sulfur_35_2: $i > $i).
% 29.32/29.14  tff(decl_72481, type, fn_sulfur_35_4: $i > $i).
% 29.32/29.14  tff(decl_72482, type, fn_sulfur_35_5: $i > $i).
% 29.32/29.14  tff(decl_72483, type, "35.0e0": $i).
% 29.32/29.14  tff(decl_72484, type, "34.969e0": $i).
% 29.32/29.14  tff(decl_72485, type, fn_sulfur_35_3: $i > $i).
% 29.32/29.14  tff(decl_72486, type, sulfur_bacterium_1: $i > $o).
% 29.32/29.14  tff(decl_72487, type, 'Sulfur-Bacterium': $i).
% 29.32/29.14  tff(decl_72488, type, 'Any of a diverse group of microbes that metabolize sulfur and sulfur compounds.': $i).
% 29.32/29.14  tff(decl_72489, type, 'bacterium of sulfur': $i).
% 29.32/29.14  tff(decl_72490, type, 'sulfur bacterium': $i).
% 29.32/29.14  tff(decl_72491, type, 'sulfur-bacterium': $i).
% 29.32/29.14  tff(decl_72492, type, fn_sulfur_bacterium_1: $i > $i).
% 29.32/29.14  tff(decl_72493, type, fn_sulfur_bacterium_2: $i > $i).
% 29.32/29.14  tff(decl_72494, type, fn_sulfur_bacterium_3: $i > $i).
% 29.32/29.14  tff(decl_72495, type, fn_sulfur_bacterium_4: $i > $i).
% 29.32/29.14  tff(decl_72496, type, fn_sulfur_bacterium_5: $i > $i).
% 29.32/29.14  tff(decl_72497, type, fn_sulfur_bacterium_6: $i > $i).
% 29.32/29.14  tff(decl_72498, type, fn_sulfur_bacterium_7: $i > $i).
% 29.32/29.14  tff(decl_72499, type, fn_sulfur_bacterium_8: $i > $i).
% 29.32/29.14  tff(decl_72500, type, fn_sulfur_bacterium_9: $i > $i).
% 29.32/29.14  tff(decl_72501, type, fn_sulfur_bacterium_10: $i > $i).
% 29.32/29.14  tff(decl_72502, type, fn_sulfur_bacterium_11: $i > $i).
% 29.32/29.14  tff(decl_72503, type, fn_sulfur_bacterium_12: $i > $i).
% 29.32/29.14  tff(decl_72504, type, fn_sulfur_bacterium_13: $i > $i).
% 29.32/29.14  tff(decl_72505, type, fn_sulfur_bacterium_14: $i > $i).
% 29.32/29.14  tff(decl_72506, type, fn_sulfur_bacterium_15: $i > $i).
% 29.32/29.14  tff(decl_72507, type, fn_sulfur_bacterium_16: $i > $i).
% 29.32/29.14  tff(decl_72508, type, fn_sulfur_bacterium_17: $i > $i).
% 29.32/29.14  tff(decl_72509, type, fn_sulfur_bacterium_18: $i > $i).
% 29.32/29.14  tff(decl_72510, type, fn_sulfur_bacterium_19: $i > $i).
% 29.32/29.14  tff(decl_72511, type, fn_sulfur_bacterium_20: $i > $i).
% 29.32/29.14  tff(decl_72512, type, fn_sulfur_bacterium_21: $i > $i).
% 29.32/29.14  tff(decl_72513, type, fn_sulfur_bacterium_23: $i > $i).
% 29.32/29.14  tff(decl_72514, type, fn_sulfur_bacterium_24: $i > $i).
% 29.32/29.14  tff(decl_72515, type, fn_sulfur_bacterium_25: $i > $i).
% 29.32/29.14  tff(decl_72516, type, fn_sulfur_bacterium_26: $i > $i).
% 29.32/29.14  tff(decl_72517, type, fn_sulfur_bacterium_27: $i > $i).
% 29.32/29.14  tff(decl_72518, type, fn_sulfur_bacterium_28: $i > $i).
% 29.32/29.14  tff(decl_72519, type, fn_sulfur_bacterium_29: $i > $i).
% 29.32/29.14  tff(decl_72520, type, fn_sulfur_bacterium_30: $i > $i).
% 29.32/29.14  tff(decl_72521, type, fn_sulfur_bacterium_35: $i > $i).
% 29.32/29.14  tff(decl_72522, type, fn_sulfur_bacterium_36: $i > $i).
% 29.32/29.14  tff(decl_72523, type, fn_sulfur_bacterium_37: $i > $i).
% 29.32/29.14  tff(decl_72524, type, fn_sulfur_bacterium_38: $i > $i).
% 29.32/29.14  tff(decl_72525, type, fn_sulfur_bacterium_39: $i > $i).
% 29.32/29.14  tff(decl_72526, type, fn_sulfur_bacterium_40: $i > $i).
% 29.32/29.14  tff(decl_72527, type, fn_sulfur_bacterium_41: $i > $i).
% 29.32/29.14  tff(decl_72528, type, fn_sulfur_bacterium_42: $i > $i).
% 29.32/29.14  tff(decl_72529, type, fn_sulfur_bacterium_43: $i > $i).
% 29.32/29.14  tff(decl_72530, type, fn_sulfur_bacterium_44: $i > $i).
% 29.32/29.14  tff(decl_72531, type, fn_sulfur_bacterium_45: $i > $i).
% 29.32/29.14  tff(decl_72532, type, fn_sulfur_bacterium_46: $i > $i).
% 29.32/29.14  tff(decl_72533, type, fn_sulfur_bacterium_47: $i > $i).
% 29.32/29.14  tff(decl_72534, type, fn_sulfur_bacterium_48: $i > $i).
% 29.32/29.14  tff(decl_72535, type, fn_sulfur_bacterium_49: $i > $i).
% 29.32/29.14  tff(decl_72536, type, fn_sulfur_bacterium_50: $i > $i).
% 29.32/29.14  tff(decl_72537, type, fn_sulfur_bacterium_51: $i > $i).
% 29.32/29.14  tff(decl_72538, type, fn_sulfur_bacterium_52: $i > $i).
% 29.32/29.14  tff(decl_72539, type, fn_sulfur_bacterium_59: $i > $i).
% 29.32/29.14  tff(decl_72540, type, fn_sulfur_bacterium_60: $i > $i).
% 29.32/29.14  tff(decl_72541, type, fn_sulfur_bacterium_31: $i > $i).
% 29.32/29.14  tff(decl_72542, type, fn_sulfur_bacterium_32: $i > $i).
% 29.32/29.14  tff(decl_72543, type, fn_sulfur_bacterium_22: $i > $i).
% 29.32/29.14  tff(decl_72544, type, fn_sulfur_bacterium_33: $i > $i).
% 29.32/29.14  tff(decl_72545, type, fn_sulfur_bacterium_53: $i > $i).
% 29.32/29.14  tff(decl_72546, type, fn_sulfur_bacterium_54: $i > $i).
% 29.32/29.14  tff(decl_72547, type, fn_sulfur_bacterium_57: $i > $i).
% 29.32/29.14  tff(decl_72548, type, fn_sulfur_bacterium_58: $i > $i).
% 29.32/29.14  tff(decl_72549, type, fn_sulfur_bacterium_56: $i > $i).
% 29.32/29.14  tff(decl_72550, type, fn_sulfur_bacterium_55: $i > $i).
% 29.32/29.14  tff(decl_72551, type, fn_sulfur_bacterium_34: $i > $i).
% 29.32/29.14  tff(decl_72552, type, sulfur_cycle_1: $i > $o).
% 29.32/29.14  tff(decl_72553, type, 'Sulfur-Cycle': $i).
% 29.32/29.14  tff(decl_72554, type, 'The cycling of sulfur through the biotic and abiotic components of ecosystems.': $i).
% 29.32/29.14  tff(decl_72555, type, 'undergo the sulfur cycle': $i).
% 29.32/29.14  tff(decl_72556, type, 'cycle of sulfur': $i).
% 29.32/29.14  tff(decl_72557, type, 'sulfur cycle': $i).
% 29.32/29.14  tff(decl_72558, type, 'sulfur-cycle': $i).
% 29.32/29.14  tff(decl_72559, type, 'Sulfur-Dioxide': $i).
% 29.32/29.14  tff(decl_72560, type, 'A toxic gas formed by burning sulfur in air.': $i).
% 29.32/29.14  tff(decl_72561, type, 'dioxide of sulfur': $i).
% 29.32/29.14  tff(decl_72562, type, 'sulfur dioxide': $i).
% 29.32/29.14  tff(decl_72563, type, 'sulfur-dioxide': $i).
% 29.32/29.14  tff(decl_72564, type, fn_sulfur_dioxide_1: $i > $i).
% 29.32/29.14  tff(decl_72565, type, fn_sulfur_dioxide_2: $i > $i).
% 29.32/29.14  tff(decl_72566, type, 'Sulfur-Isotope': $i).
% 29.32/29.14  tff(decl_72567, type, 'All the sulfur isoptopes have 16 protons and 16 electrons. They differ in their neutron number.': $i).
% 29.32/29.14  tff(decl_72568, type, 'isotope of sulfur': $i).
% 29.32/29.14  tff(decl_72569, type, 'sulfur isotope': $i).
% 29.32/29.14  tff(decl_72570, type, 'sulfur-isotope': $i).
% 29.32/29.14  tff(decl_72571, type, fn_sulfur_isotope_3: $i > $i).
% 29.32/29.14  tff(decl_72572, type, fn_sulfur_isotope_4: $i > $i).
% 29.32/29.14  tff(decl_72573, type, fn_sulfur_isotope_6: $i > $i).
% 29.32/29.14  tff(decl_72574, type, fn_sulfur_isotope_7: $i > $i).
% 29.32/29.14  tff(decl_72575, type, fn_sulfur_isotope_5: $i > $i).
% 29.32/29.14  tff(decl_72576, type, 'Sulfuric-Acid': $i).
% 29.32/29.14  tff(decl_72577, type, 'Strong acid made from the dissociation of sulfur trioxide in water.': $i).
% 29.32/29.14  tff(decl_72578, type, 'sulfuric acid': $i).
% 29.32/29.14  tff(decl_72579, type, 'sulfuric-acid': $i).
% 29.32/29.14  tff(decl_72580, type, 'Sulfuric-Acid-Compound': $i).
% 29.32/29.14  tff(decl_72581, type, 'It is an organic compound with molecular formula H2SO4.': $i).
% 29.32/29.14  tff(decl_72582, type, 'sulfuric acid compound': $i).
% 29.32/29.14  tff(decl_72583, type, 'sulfuric-acid-compound': $i).
% 29.32/29.14  tff(decl_72584, type, fn_sulfuric_acid_compound_1: $i > $i).
% 29.32/29.14  tff(decl_72585, type, fn_sulfuric_acid_compound_2: $i > $i).
% 29.32/29.14  tff(decl_72586, type, fn_sulfuric_acid_compound_3: $i > $i).
% 29.32/29.14  tff(decl_72587, type, sum_1: $i > $o).
% 29.32/29.14  tff(decl_72588, type, 'Sum': $i).
% 29.32/29.14  tff(decl_72589, type, sum: $i).
% 29.32/29.14  tff(decl_72590, type, summation: $i).
% 29.32/29.14  tff(decl_72591, type, 'sum total': $i).
% 29.32/29.14  tff(decl_72592, type, sum_total: $i).
% 29.32/29.14  tff(decl_72593, type, total: $i).
% 29.32/29.14  tff(decl_72594, type, totality: $i).
% 29.32/29.14  tff(decl_72595, type, tot: $i).
% 29.32/29.14  tff(decl_72596, type, 'tot up': $i).
% 29.32/29.14  tff(decl_72597, type, tot_up: $i).
% 29.32/29.14  tff(decl_72598, type, 'sum up': $i).
% 29.32/29.14  tff(decl_72599, type, sum_up: $i).
% 29.32/29.14  tff(decl_72600, type, summate: $i).
% 29.32/29.14  tff(decl_72601, type, 'tote up': $i).
% 29.32/29.14  tff(decl_72602, type, tote_up: $i).
% 29.32/29.14  tff(decl_72603, type, 'add together': $i).
% 29.32/29.14  tff(decl_72604, type, add_together: $i).
% 29.32/29.14  tff(decl_72605, type, tally: $i).
% 29.32/29.14  tff(decl_72606, type, 'add up': $i).
% 29.32/29.14  tff(decl_72607, type, add_up: $i).
% 29.32/29.14  tff(decl_72608, type, sun_1: $i > $o).
% 29.32/29.14  tff(decl_72609, type, 'Sun': $i).
% 29.32/29.14  tff(decl_72610, type, 'The Sun is the star at the center of the Solar System.': $i).
% 29.32/29.14  tff(decl_72611, type, sun: $i).
% 29.32/29.14  tff(decl_72612, type, 'Sunfish': $i).
% 29.32/29.14  tff(decl_72613, type, 'A type of ray-finned freshwater fish whose feeding behavior  provides further support for optimal foraging theory. Examples include bluegill, crappie, and largemouth bass.': $i).
% 29.32/29.14  tff(decl_72614, type, sunfish: $i).
% 29.32/29.14  tff(decl_72615, type, 'Sunlight': $i).
% 29.32/29.14  tff(decl_72616, type, 'Light that emanates from the sun.': $i).
% 29.32/29.14  tff(decl_72617, type, sunlight: $i).
% 29.32/29.14  tff(decl_72618, type, fn_sunlight_2: $i > $i).
% 29.32/29.14  tff(decl_72619, type, fn_sunlight_3: $i > $i).
% 29.32/29.14  tff(decl_72620, type, 'Supernatant': $i).
% 29.32/29.14  tff(decl_72621, type, 'In Biology, a supernatant is the less dense liquid which forms at the top of a test tube after centrifuging the test tube.': $i).
% 29.32/29.14  tff(decl_72622, type, supernatant: $i).
% 29.32/29.14  tff(decl_72623, type, 'Supper': $i).
% 29.32/29.14  tff(decl_72624, type, supper: $i).
% 29.32/29.14  tff(decl_72625, type, 'Supply': $i).
% 29.32/29.14  tff(decl_72626, type, supply: $i).
% 29.32/29.14  tff(decl_72627, type, furnish: $i).
% 29.32/29.14  tff(decl_72628, type, provide: $i).
% 29.32/29.14  tff(decl_72629, type, 'Support': $i).
% 29.32/29.14  tff(decl_72630, type, 'Suprachiasmatic-Nucleus': $i).
% 29.32/29.14  tff(decl_72631, type, 'A small cluster of neurons in the anterior hypothalamus that is responsible for controlling circadian rhythms.': $i).
% 29.32/29.14  tff(decl_72632, type, scn: $i).
% 29.32/29.14  tff(decl_72633, type, 'suprachiasmatic nucleus': $i).
% 29.32/29.14  tff(decl_72634, type, 'suprachiasmatic-nucleus': $i).
% 29.32/29.14  tff(decl_72635, type, 'Surface': $i).
% 29.32/29.14  tff(decl_72636, type, 'The outermost layer or boundary of an object.': $i).
% 29.32/29.14  tff(decl_72637, type, surface: $i).
% 29.32/29.14  tff(decl_72638, type, 'Surface-Area-Categorical-Constant': $i).
% 29.32/29.14  tff(decl_72639, type, 'surface area categorical constant': $i).
% 29.32/29.14  tff(decl_72640, type, 'surface-area-categorical-constant': $i).
% 29.32/29.14  tff(decl_72641, type, 'Surface-Area-Scalar-Constant': $i).
% 29.32/29.14  tff(decl_72642, type, 'surface area scalar constant': $i).
% 29.32/29.14  tff(decl_72643, type, 'surface-area-scalar-constant': $i).
% 29.32/29.14  tff(decl_72644, type, surface_area_scale_1: $i > $o).
% 29.32/29.14  tff(decl_72645, type, 'Surface-Area-Scale': $i).
% 29.32/29.14  tff(decl_72646, type, 'surface area scale': $i).
% 29.32/29.14  tff(decl_72647, type, 'surface-area-scale': $i).
% 29.32/29.14  tff(decl_72648, type, 'Surface-Area-Value': $i).
% 29.32/29.14  tff(decl_72649, type, 'area of surface': $i).
% 29.32/29.14  tff(decl_72650, type, 'surface-area': $i).
% 29.32/29.14  tff(decl_72651, type, 'surface area value': $i).
% 29.32/29.14  tff(decl_72652, type, 'surface-area-value': $i).
% 29.32/29.14  tff(decl_72653, type, 'Surface-Protein': $i).
% 29.32/29.14  tff(decl_72654, type, 'Protein found on the outer surface of a cell, on the plasma membrane.': $i).
% 29.32/29.14  tff(decl_72655, type, 'protein of surface': $i).
% 29.32/29.14  tff(decl_72656, type, 'surface protein': $i).
% 29.32/29.14  tff(decl_72657, type, 'surface-protein': $i).
% 29.32/29.14  tff(decl_72658, type, fn_surface_protein_3: $i > $i).
% 29.32/29.14  tff(decl_72659, type, fn_surface_protein_4: $i > $i).
% 29.32/29.14  tff(decl_72660, type, fn_surface_protein_5: $i > $i).
% 29.32/29.14  tff(decl_72661, type, fn_surface_protein_6: $i > $i).
% 29.32/29.14  tff(decl_72662, type, fn_surface_protein_7: $i > $i).
% 29.32/29.14  tff(decl_72663, type, fn_surface_protein_1: $i > $i).
% 29.32/29.14  tff(decl_72664, type, fn_surface_protein_2: $i > $i).
% 29.32/29.14  tff(decl_72665, type, 'Surface-Tension-Constant': $i).
% 29.32/29.14  tff(decl_72666, type, 'surface tension constant': $i).
% 29.32/29.14  tff(decl_72667, type, 'surface-tension-constant': $i).
% 29.32/29.14  tff(decl_72668, type, surface_tension_scale_1: $i > $o).
% 29.32/29.14  tff(decl_72669, type, 'Surface-Tension-Scale': $i).
% 29.32/29.14  tff(decl_72670, type, 'surface tension scale': $i).
% 29.32/29.14  tff(decl_72671, type, 'surface-tension-scale': $i).
% 29.32/29.14  tff(decl_72672, type, 'Surface-Tension-Value': $i).
% 29.32/29.14  tff(decl_72673, type, 'tension of surface': $i).
% 29.32/29.14  tff(decl_72674, type, 'surface tension': $i).
% 29.32/29.14  tff(decl_72675, type, 'surface-tension': $i).
% 29.32/29.14  tff(decl_72676, type, 'surface tension value': $i).
% 29.32/29.14  tff(decl_72677, type, 'surface-tension-value': $i).
% 29.32/29.14  tff(decl_72678, type, surfactant_1: $i > $o).
% 29.32/29.14  tff(decl_72679, type, 'Surfactant': $i).
% 29.32/29.14  tff(decl_72680, type, 'A phospholipoprotein secreted by the alveoli that reduces surface tension in the fluid coating the alveoli.': $i).
% 29.32/29.14  tff(decl_72681, type, surfactant: $i).
% 29.32/29.14  tff(decl_72682, type, surrogate_mother_1: $i > $o).
% 29.32/29.14  tff(decl_72683, type, 'Surrogate-Mother': $i).
% 29.32/29.14  tff(decl_72684, type, 'A surrogate mother is a woman who carries a fetus for someone else.': $i).
% 29.32/29.14  tff(decl_72685, type, 'mother of surrogate': $i).
% 29.32/29.14  tff(decl_72686, type, 'surrogate mother': $i).
% 29.32/29.14  tff(decl_72687, type, 'surrogate-mother': $i).
% 29.32/29.14  tff(decl_72688, type, 'Survivorship-Curve': $i).
% 29.32/29.14  tff(decl_72689, type, 'A graph that shows the number or proportion of individuals still alive at each age.': $i).
% 29.32/29.14  tff(decl_72690, type, 'survivorship curve': $i).
% 29.32/29.14  tff(decl_72691, type, 'survivorship-curve': $i).
% 29.32/29.14  tff(decl_72692, type, 'Suspension': $i).
% 29.32/29.14  tff(decl_72693, type, 'A mixture in which fine particles are suspended in a fluid where they are supported by buoyancy.': $i).
% 29.32/29.14  tff(decl_72694, type, suspension: $i).
% 29.32/29.14  tff(decl_72695, type, 'Suspension-Feeder': $i).
% 29.32/29.14  tff(decl_72696, type, 'An aquatic animal that feeds on small particles suspended in the water. Examples include clams and baleen whales.': $i).
% 29.32/29.14  tff(decl_72697, type, 'feeder of suspension': $i).
% 29.32/29.14  tff(decl_72698, type, 'suspension feeder': $i).
% 29.32/29.14  tff(decl_72699, type, 'suspension-feeder': $i).
% 29.32/29.14  tff(decl_72700, type, 'Suspension-Feeding': $i).
% 29.32/29.14  tff(decl_72701, type, 'Feeding on small particles suspended in the water.': $i).
% 29.32/29.14  tff(decl_72702, type, 'feeding of suspension': $i).
% 29.32/29.14  tff(decl_72703, type, 'suspension feeding': $i).
% 29.32/29.14  tff(decl_72704, type, 'suspension-feeding': $i).
% 29.32/29.14  tff(decl_72705, type, 'Sustainable-Agriculture': $i).
% 29.32/29.14  tff(decl_72706, type, 'The application of ecological principles to agriculture, so that farming methods are environmentally safe for long periods of time.': $i).
% 29.32/29.14  tff(decl_72707, type, 'sustainable agriculture': $i).
% 29.32/29.14  tff(decl_72708, type, 'sustainable-agriculture': $i).
% 29.32/29.14  tff(decl_72709, type, 'Sustainable-Development': $i).
% 29.32/29.14  tff(decl_72710, type, 'Development in which resource use not only meets current human need but also allows future generations to meet their needs.': $i).
% 29.32/29.14  tff(decl_72711, type, 'sustainable development': $i).
% 29.32/29.14  tff(decl_72712, type, 'sustainable-development': $i).
% 29.32/29.14  tff(decl_72713, type, swallow_1: $i > $o).
% 29.32/29.14  tff(decl_72714, type, 'Swallow': $i).
% 29.32/29.14  tff(decl_72715, type, 'Process in animals which moves food (in the form of a bolus) from the mouth to the pharnyx and then into the esophagus.': $i).
% 29.32/29.14  tff(decl_72716, type, swallow: $i).
% 29.32/29.14  tff(decl_72717, type, 'Swallowing-Reflex': $i).
% 29.32/29.14  tff(decl_72718, type, 'A reflex triggered by a bolus of food reaching the pharynx, allowing the bolus to enter the esophagus and not the treachea.': $i).
% 29.32/29.14  tff(decl_72719, type, 'swallowing reflex': $i).
% 29.32/29.14  tff(decl_72720, type, 'swallowing-reflex': $i).
% 29.32/29.14  tff(decl_72721, type, fn_swallowing_reflex_1: $i > $i).
% 29.32/29.14  tff(decl_72722, type, fn_swallowing_reflex_2: $i > $i).
% 29.32/29.14  tff(decl_72723, type, fn_swallowing_reflex_3: $i > $i).
% 29.32/29.14  tff(decl_72724, type, fn_swallowing_reflex_4: $i > $i).
% 29.32/29.14  tff(decl_72725, type, fn_swallowing_reflex_5: $i > $i).
% 29.32/29.14  tff(decl_72726, type, fn_swallowing_reflex_6: $i > $i).
% 29.32/29.14  tff(decl_72727, type, fn_swallowing_reflex_7: $i > $i).
% 29.32/29.14  tff(decl_72728, type, fn_swallowing_reflex_8: $i > $i).
% 29.32/29.14  tff(decl_72729, type, fn_swallowing_reflex_9: $i > $i).
% 29.32/29.14  tff(decl_72730, type, fn_swallowing_reflex_10: $i > $i).
% 29.32/29.14  tff(decl_72731, type, fn_swallowing_reflex_11: $i > $i).
% 29.32/29.14  tff(decl_72732, type, fn_swallowing_reflex_12: $i > $i).
% 29.32/29.14  tff(decl_72733, type, fn_swallowing_reflex_13: $i > $i).
% 29.32/29.14  tff(decl_72734, type, fn_swallowing_reflex_14: $i > $i).
% 29.32/29.14  tff(decl_72735, type, fn_swallowing_reflex_15: $i > $i).
% 29.32/29.14  tff(decl_72736, type, fn_swallowing_reflex_16: $i > $i).
% 29.32/29.14  tff(decl_72737, type, fn_swallowing_reflex_17: $i > $i).
% 29.32/29.14  tff(decl_72738, type, fn_swallowing_reflex_18: $i > $i).
% 29.32/29.14  tff(decl_72739, type, fn_swallowing_reflex_19: $i > $i).
% 29.32/29.14  tff(decl_72740, type, fn_trachea_3: $i > $i).
% 29.32/29.14  tff(decl_72741, type, fn_trachea_4: $i > $i).
% 29.32/29.14  tff(decl_72742, type, fn_trachea_2: $i > $i).
% 29.32/29.14  tff(decl_72743, type, 'Sweat': $i).
% 29.32/29.14  tff(decl_72744, type, 'Perspiration; water excreted by the skin as a response to increased body temperature.  Sweat will evaporate from the skin\\s surface, and by evaporative cooling, the body\\s temperature will decrease.': $i).
% 29.32/29.14  tff(decl_72745, type, sweat: $i).
% 29.32/29.14  tff(decl_72746, type, fn_sweat_1: $i > $i).
% 29.32/29.14  tff(decl_72747, type, swim_bladder_1: $i > $o).
% 29.32/29.14  tff(decl_72748, type, 'Swim-Bladder': $i).
% 29.32/29.14  tff(decl_72749, type, 'In some fishes, an internal gas-filled structure that allows the animal to control its buoyancy.': $i).
% 29.32/29.14  tff(decl_72750, type, 'bladder of swim': $i).
% 29.32/29.14  tff(decl_72751, type, 'swim bladder': $i).
% 29.32/29.14  tff(decl_72752, type, 'swim-bladder': $i).
% 29.32/29.14  tff(decl_72753, type, symbiont_1: $i > $o).
% 29.32/29.14  tff(decl_72754, type, 'Symbiont': $i).
% 29.32/29.14  tff(decl_72755, type, 'The smaller partner in a symbiotic association. The symbiont lives within or on the host (the larger partner in the relationship).': $i).
% 29.32/29.14  tff(decl_72756, type, symbiont: $i).
% 29.32/29.14  tff(decl_72757, type, 'Symbiosis': $i).
% 29.32/29.14  tff(decl_72758, type, 'An intimate ecological relationship between individuals of two different species. The larger partner in the relationship is called the host, and the smaller partner is called the symbiont.': $i).
% 29.32/29.14  tff(decl_72759, type, symbiosis: $i).
% 29.32/29.14  tff(decl_72760, type, 'Symbiotic-Fungi': $i).
% 29.32/29.14  tff(decl_72761, type, 'Fungi that form a symbiotic relationship with other organisms.': $i).
% 29.32/29.14  tff(decl_72762, type, 'symbiotic fungus': $i).
% 29.32/29.14  tff(decl_72763, type, 'symbiotic-fungi': $i).
% 29.32/29.14  tff(decl_72764, type, 'Symmetrical-Distribution': $i).
% 29.32/29.14  tff(decl_72765, type, 'A distribution in which observations equidistant from the central maximum have the same frequency. Also known as symmetric distribution.': $i).
% 29.32/29.14  tff(decl_72766, type, 'symmetrical distribution': $i).
% 29.32/29.14  tff(decl_72767, type, 'symmetrical-distribution': $i).
% 29.32/29.14  tff(decl_72768, type, 'Sympathetic-Division': $i).
% 29.32/29.14  tff(decl_72769, type, 'One of three major divisions of the autonomic nervous system. It generally acts to maintain homeostasis but also mobilizes the body\\s': $i).
% 29.32/29.14  tff(decl_72770, type, 'sympathetic division': $i).
% 29.32/29.14  tff(decl_72771, type, 'sympathetic-division': $i).
% 29.32/29.14  tff(decl_72772, type, sympatric_speciation_1: $i > $o).
% 29.32/29.14  tff(decl_72773, type, 'Sympatric-Speciation': $i).
% 29.32/29.14  tff(decl_72774, type, 'The process by which new species evolve in populations that live in the same geographic area.': $i).
% 29.32/29.14  tff(decl_72775, type, 'sympatric speciation': $i).
% 29.32/29.14  tff(decl_72776, type, 'sympatric-speciation': $i).
% 29.32/29.14  tff(decl_72777, type, 'Symplast': $i).
% 29.32/29.14  tff(decl_72778, type, 'In plants, the continuous flow of cytoplasm between cells connected by plasmodesmata.': $i).
% 29.32/29.14  tff(decl_72779, type, symplast: $i).
% 29.32/29.14  tff(decl_72780, type, fn_symplast_1: $i > $i).
% 29.32/29.14  tff(decl_72781, type, fn_symplast_2: $i > $i).
% 29.32/29.14  tff(decl_72782, type, fn_symplast_3: $i > $i).
% 29.32/29.14  tff(decl_72783, type, fn_symplast_4: $i > $i).
% 29.32/29.14  tff(decl_72784, type, fn_symplast_5: $i > $i).
% 29.32/29.14  tff(decl_72785, type, fn_symplast_6: $i > $i).
% 29.32/29.14  tff(decl_72786, type, fn_symplast_7: $i > $i).
% 29.32/29.14  tff(decl_72787, type, fn_symplast_8: $i > $i).
% 29.32/29.14  tff(decl_72788, type, 'Symplastic-Transport': $i).
% 29.32/29.14  tff(decl_72789, type, 'Route of transport of water and solutes in vascular plants which follows a path through the cytosol (the symplast).': $i).
% 29.32/29.14  tff(decl_72790, type, 'symplastic transport': $i).
% 29.32/29.14  tff(decl_72791, type, 'symplastic-transport': $i).
% 29.32/29.14  tff(decl_72792, type, fn_symplastic_transport_3: $i > $i).
% 29.32/29.14  tff(decl_72793, type, 'Synapse': $i).
% 29.32/29.14  tff(decl_72794, type, 'The junction between two neurons, where the dendrites of one neuron communicate with the axon of another. There is a narrow gap between the neurons, into which the presynaptic neuron secretes neurotransmitters that diffuse across the space to the membrane of the postsynaptic neuron.': $i).
% 29.32/29.14  tff(decl_72795, type, synapse: $i).
% 29.32/29.14  tff(decl_72796, type, fn_synapse_2: $i > $i).
% 29.32/29.14  tff(decl_72797, type, anatomical_space_0: $i).
% 29.32/29.14  tff(decl_72798, type, 'Synapsid': $i).
% 29.32/29.14  tff(decl_72799, type, 'A member of the clade of amniote animals that is characterized by a single temporal opening on each side of the skull. Mammals, as well as several lineages of extinct reptiles, are synapsids.': $i).
% 29.32/29.14  tff(decl_72800, type, synapsid: $i).
% 29.32/29.14  tff(decl_72801, type, 'Synapsis': $i).
% 29.32/29.14  tff(decl_72802, type, 'The pairing of duplicated homologous chromosomes in early meiosis. During synapsis the homologous chromosomes make physical contact with each other, allowing crossover events to occur. Synapsis occurs during Prophase I of meiosis.': $i).
% 29.32/29.14  tff(decl_72803, type, synapsis: $i).
% 29.32/29.14  tff(decl_72804, type, fn_synapsis_1: $i > $i).
% 29.32/29.14  tff(decl_72805, type, fn_synapsis_2: $i > $i).
% 29.32/29.14  tff(decl_72806, type, fn_synapsis_3: $i > $i).
% 29.32/29.14  tff(decl_72807, type, fn_synapsis_4: $i > $i).
% 29.32/29.14  tff(decl_72808, type, fn_synapsis_5: $i > $i).
% 29.32/29.14  tff(decl_72809, type, fn_synapsis_6: $i > $i).
% 29.32/29.14  tff(decl_72810, type, fn_synapsis_7: $i > $i).
% 29.32/29.14  tff(decl_72811, type, fn_synapsis_8: $i > $i).
% 29.32/29.14  tff(decl_72812, type, fn_synapsis_9: $i > $i).
% 29.32/29.14  tff(decl_72813, type, fn_synapsis_10: $i > $i).
% 29.32/29.14  tff(decl_72814, type, fn_synapsis_11: $i > $i).
% 29.32/29.14  tff(decl_72815, type, fn_synapsis_12: $i > $i).
% 29.32/29.14  tff(decl_72816, type, fn_synapsis_13: $i > $i).
% 29.32/29.14  tff(decl_72817, type, fn_synapsis_14: $i > $i).
% 29.32/29.14  tff(decl_72818, type, fn_synapsis_15: $i > $i).
% 29.32/29.14  tff(decl_72819, type, homologous_chromosomes_0: $i).
% 29.32/29.14  tff(decl_72820, type, 'Synaptic-Cleft': $i).
% 29.32/29.14  tff(decl_72821, type, 'The narrow gap between a presynaptic neuron and a postsynaptic neuron or effector cell.': $i).
% 29.32/29.14  tff(decl_72822, type, cleft: $i).
% 29.32/29.14  tff(decl_72823, type, 'synaptic gap': $i).
% 29.32/29.14  tff(decl_72824, type, 'synaptic cleft': $i).
% 29.32/29.14  tff(decl_72825, type, 'synaptic-cleft': $i).
% 29.32/29.14  tff(decl_72826, type, 'Synaptic-Terminal': $i).
% 29.32/29.14  tff(decl_72827, type, 'An area in the axon of a presynaptic neuron that contains neurotransmitters stored in vesicles.': $i).
% 29.32/29.14  tff(decl_72828, type, 'synaptic terminal': $i).
% 29.32/29.14  tff(decl_72829, type, 'synaptic-terminal': $i).
% 29.32/29.14  tff(decl_72830, type, 'Synaptic-Vesicle': $i).
% 29.32/29.14  tff(decl_72831, type, 'A membrane-bound sac containing neurotransmitter molecules, located at the tip of an axon.': $i).
% 29.32/29.14  tff(decl_72832, type, 'synaptic vesicle': $i).
% 29.32/29.14  tff(decl_72833, type, 'synaptic-vesicle': $i).
% 29.32/29.14  tff(decl_72834, type, fn_synaptic_vesicle_1: $i > $i).
% 29.32/29.14  tff(decl_72835, type, fn_synaptic_vesicle_2: $i > $i).
% 29.32/29.14  tff(decl_72836, type, fn_synaptic_vesicle_3: $i > $i).
% 29.32/29.14  tff(decl_72837, type, fn_synaptic_vesicle_4: $i > $i).
% 29.32/29.14  tff(decl_72838, type, fn_synaptic_vesicle_5: $i > $i).
% 29.32/29.14  tff(decl_72839, type, fn_synaptic_vesicle_6: $i > $i).
% 29.32/29.14  tff(decl_72840, type, fn_synaptic_vesicle_7: $i > $i).
% 29.32/29.14  tff(decl_72841, type, fn_synaptic_vesicle_8: $i > $i).
% 29.32/29.14  tff(decl_72842, type, 'Synaptonemal-Complex': $i).
% 29.32/29.14  tff(decl_72843, type, 'A group of proteins that function as a zipper to hold homologous chromosomes tightly together.': $i).
% 29.32/29.14  tff(decl_72844, type, 'synaptonemal complex': $i).
% 29.32/29.14  tff(decl_72845, type, 'synaptonemal-complex': $i).
% 29.32/29.14  tff(decl_72846, type, fn_synaptonemal_complex_1: $i > $i).
% 29.32/29.14  tff(decl_72847, type, fn_synthesis_of_amino_acid_2: $i > $i).
% 29.32/29.14  tff(decl_72848, type, 'Synthesis-Of-Amino-Acid': $i).
% 29.32/29.14  tff(decl_72849, type, 'The process of synthesizing amino acids is called synthesis of amino acid.': $i).
% 29.32/29.14  tff(decl_72850, type, 'synthesis of amino acid': $i).
% 29.32/29.14  tff(decl_72851, type, 'synthesis-of-amino-acid': $i).
% 29.32/29.14  tff(decl_72852, type, synthesis_of_trna_1: $i > $o).
% 29.32/29.14  tff(decl_72853, type, synthesis_of_aminoacyl_trna_1: $i > $o).
% 29.32/29.14  tff(decl_72854, type, fn_synthesis_of_aminoacyl_trna_3: $i > $i).
% 29.32/29.14  tff(decl_72855, type, 'Synthesis-Of-Aminoacyl-tRNA': $i).
% 29.32/29.14  tff(decl_72856, type, 'This process involves attachment of a specific amino acid to its corresponding tRNA molecule by the enzyme \\Aminoacyl-tRNA synthetase.': $i).
% 29.32/29.14  tff(decl_72857, type, 'synthesis of aminoacyl trna': $i).
% 29.32/29.14  tff(decl_72858, type, 'synthesis-of-aminoacyl-trna': $i).
% 29.32/29.14  tff(decl_72859, type, fn_synthesis_of_aminoacyl_trna_1: $i > $i).
% 29.32/29.14  tff(decl_72860, type, fn_synthesis_of_aminoacyl_trna_4: $i > $i).
% 29.32/29.14  tff(decl_72861, type, fn_synthesis_of_aminoacyl_trna_5: $i > $i).
% 29.32/29.14  tff(decl_72862, type, fn_synthesis_of_aminoacyl_trna_6: $i > $i).
% 29.32/29.14  tff(decl_72863, type, fn_synthesis_of_aminoacyl_trna_7: $i > $i).
% 29.32/29.14  tff(decl_72864, type, fn_synthesis_of_aminoacyl_trna_8: $i > $i).
% 29.32/29.14  tff(decl_72865, type, fn_synthesis_of_trna_2: $i > $i).
% 29.32/29.14  tff(decl_72866, type, fn_synthesis_of_artificial_eukaryotic_genes_without_introns_4: $i > $i).
% 29.32/29.14  tff(decl_72867, type, fn_synthesis_of_artificial_eukaryotic_genes_without_introns_6: $i > $i).
% 29.32/29.14  tff(decl_72868, type, fn_synthesis_of_artificial_eukaryotic_genes_without_introns_5: $i > $i).
% 29.32/29.14  tff(decl_72869, type, 'Synthesis-Of-Artificial-Eukaryotic-Genes-Without-Introns': $i).
% 29.32/29.14  tff(decl_72870, type, 'Genetic engineering in which mRNA is removed from a eukaryotic cell, then reverse transcribed to produce cDNA.': $i).
% 29.32/29.14  tff(decl_72871, type, 'making artificial eukaryotic genes lacking introns': $i).
% 29.32/29.14  tff(decl_72872, type, 'synthesis of artificial eukaryotic genes without intron': $i).
% 29.32/29.14  tff(decl_72873, type, 'synthesis-of-artificial-eukaryotic-genes-without-intron': $i).
% 29.32/29.14  tff(decl_72874, type, fn_synthesis_of_artificial_eukaryotic_genes_without_introns_1: $i > $i).
% 29.32/29.14  tff(decl_72875, type, fn_synthesis_of_artificial_eukaryotic_genes_without_introns_3: $i > $i).
% 29.32/29.14  tff(decl_72876, type, 'Synthesis-of-ATP': $i).
% 29.32/29.14  tff(decl_72877, type, 'It is the process of production of ATP.': $i).
% 29.32/29.14  tff(decl_72878, type, 'atp synthesis': $i).
% 29.32/29.14  tff(decl_72879, type, 'atp-synthesis': $i).
% 29.32/29.14  tff(decl_72880, type, 'synthesis of atp': $i).
% 29.32/29.14  tff(decl_72881, type, 'synthesis-of-atp': $i).
% 29.32/29.14  tff(decl_72882, type, fn_synthesis_of_atp_1: $i > $i).
% 29.32/29.14  tff(decl_72883, type, fn_synthesis_of_atp_2: $i > $i).
% 29.32/29.14  tff(decl_72884, type, fn_synthesis_of_atp_3: $i > $i).
% 29.32/29.14  tff(decl_72885, type, fn_synthesis_of_atp_4: $i > $i).
% 29.32/29.14  tff(decl_72886, type, fn_synthesis_of_atp_5: $i > $i).
% 29.32/29.14  tff(decl_72887, type, synthesis_of_blood_cell_1: $i > $o).
% 29.32/29.14  tff(decl_72888, type, 'Synthesis-Of-Blood-Cell': $i).
% 29.32/29.14  tff(decl_72889, type, 'The process of production of red and white blood cells.': $i).
% 29.32/29.14  tff(decl_72890, type, 'synthesis of blood cell': $i).
% 29.32/29.14  tff(decl_72891, type, 'synthesis-of-blood-cell': $i).
% 29.32/29.14  tff(decl_72892, type, fn_synthesis_of_blood_cell_1: $i > $i).
% 29.32/29.14  tff(decl_72893, type, fn_synthesis_of_blood_cell_2: $i > $i).
% 29.32/29.14  tff(decl_72894, type, fn_synthesis_of_blood_cell_3: $i > $i).
% 29.32/29.14  tff(decl_72895, type, fn_synthesis_of_blood_cell_4: $i > $i).
% 29.32/29.14  tff(decl_72896, type, 'Synthesis-Of-cAMP': $i).
% 29.32/29.14  tff(decl_72897, type, 'The production of cAMP.': $i).
% 29.32/29.14  tff(decl_72898, type, 'camp synthesis': $i).
% 29.32/29.14  tff(decl_72899, type, 'camp-synthesis': $i).
% 29.32/29.14  tff(decl_72900, type, 'synthesis of camp': $i).
% 29.32/29.14  tff(decl_72901, type, 'synthesis-of-camp': $i).
% 29.32/29.14  tff(decl_72902, type, fn_synthesis_of_camp_1: $i > $i).
% 29.32/29.14  tff(decl_72903, type, fn_synthesis_of_camp_2: $i > $i).
% 29.32/29.14  tff(decl_72904, type, fn_synthesis_of_camp_4: $i > $i).
% 29.32/29.14  tff(decl_72905, type, fn_synthesis_of_camp_5: $i > $i).
% 29.32/29.14  tff(decl_72906, type, fn_synthesis_of_camp_6: $i > $i).
% 29.32/29.14  tff(decl_72907, type, fn_synthesis_of_camp_8: $i > $i).
% 29.32/29.14  tff(decl_72908, type, fn_synthesis_of_camp_9: $i > $i).
% 29.32/29.14  tff(decl_72909, type, fn_synthesis_of_camp_10: $i > $i).
% 29.32/29.14  tff(decl_72910, type, fn_synthesis_of_camp_12: $i > $i).
% 29.32/29.14  tff(decl_72911, type, 'Synthesis-Of-Carbohydrate': $i).
% 29.32/29.14  tff(decl_72912, type, 'The production of carbohydrate from raw materials.': $i).
% 29.32/29.14  tff(decl_72913, type, 'carbohydrate synthesis': $i).
% 29.32/29.14  tff(decl_72914, type, 'carbohydrate-synthesis': $i).
% 29.32/29.14  tff(decl_72915, type, 'synthesis of carbohydrate': $i).
% 29.32/29.14  tff(decl_72916, type, 'synthesis-of-carbohydrate': $i).
% 29.32/29.14  tff(decl_72917, type, synthesis_of_coenzyme_1: $i > $o).
% 29.32/29.14  tff(decl_72918, type, synthesis_of_fatty_acid_1: $i > $o).
% 29.32/29.14  tff(decl_72919, type, synthesis_of_inosine_1: $i > $o).
% 29.32/29.14  tff(decl_72920, type, synthesis_of_cell_wall_by_plant_cell_1: $i > $o).
% 29.32/29.14  tff(decl_72921, type, fn_synthesis_of_cell_wall_by_plant_cell_3: $i > $i).
% 29.32/29.14  tff(decl_72922, type, fn_synthesis_of_cell_wall_by_plant_cell_4: $i > $i).
% 29.32/29.14  tff(decl_72923, type, 'Synthesis-Of-Cell-Wall-By-Plant-Cell': $i).
% 29.32/29.14  tff(decl_72924, type, 'The process by which plant cells produce cell walls, during which vesicles of carbohydrates produced by the Golgi apparatus are delivered to the outside of the cell.': $i).
% 29.32/29.14  tff(decl_72925, type, 'synthesis of cell wall by plant cell': $i).
% 29.32/29.14  tff(decl_72926, type, 'synthesis-of-cell-wall-by-plant-cell': $i).
% 29.32/29.14  tff(decl_72927, type, fn_synthesis_of_cell_wall_by_plant_cell_2: $i > $i).
% 29.32/29.14  tff(decl_72928, type, 'Synthesis-of-Cellulose': $i).
% 29.32/29.14  tff(decl_72929, type, 'Cellulose is made by enzymes located within the plasma membrane, which directly deposit this polysaccharide on the outside surface.': $i).
% 29.32/29.14  tff(decl_72930, type, 'cellulose synthesis': $i).
% 29.32/29.14  tff(decl_72931, type, 'cellulose-synthesis': $i).
% 29.32/29.14  tff(decl_72932, type, 'synthesis of cellulose': $i).
% 29.32/29.14  tff(decl_72933, type, 'synthesis-of-cellulose': $i).
% 29.32/29.14  tff(decl_72934, type, fn_synthesis_of_cellulose_1: $i > $i).
% 29.32/29.14  tff(decl_72935, type, fn_synthesis_of_cellulose_4: $i > $i).
% 29.32/29.14  tff(decl_72936, type, fn_synthesis_of_cellulose_5: $i > $i).
% 29.32/29.14  tff(decl_72937, type, fn_synthesis_of_cellulose_6: $i > $i).
% 29.32/29.14  tff(decl_72938, type, fn_synthesis_of_cellulose_7: $i > $i).
% 29.32/29.14  tff(decl_72939, type, fn_synthesis_of_cellulose_8: $i > $i).
% 29.32/29.14  tff(decl_72940, type, fn_synthesis_of_cellulose_9: $i > $i).
% 29.32/29.14  tff(decl_72941, type, fn_synthesis_of_cellulose_10: $i > $i).
% 29.32/29.14  tff(decl_72942, type, fn_synthesis_of_cellulose_11: $i > $i).
% 29.32/29.14  tff(decl_72943, type, fn_synthesis_of_cellulose_12: $i > $i).
% 29.32/29.14  tff(decl_72944, type, fn_synthesis_of_cellulose_13: $i > $i).
% 29.32/29.14  tff(decl_72945, type, fn_synthesis_of_cellulose_14: $i > $i).
% 29.32/29.14  tff(decl_72946, type, fn_synthesis_of_cellulose_15: $i > $i).
% 29.32/29.14  tff(decl_72947, type, fn_synthesis_of_cellulose_16: $i > $i).
% 29.32/29.14  tff(decl_72948, type, fn_synthesis_of_cellulose_17: $i > $i).
% 29.32/29.14  tff(decl_72949, type, fn_synthesis_of_cellulose_18: $i > $i).
% 29.32/29.14  tff(decl_72950, type, fn_synthesis_of_cellulose_2: $i > $i).
% 29.32/29.14  tff(decl_72951, type, fn_synthesis_of_cellulose_3: $i > $i).
% 29.32/29.14  tff(decl_72952, type, synthesis_of_central_vacuole_1: $i > $o).
% 29.32/29.14  tff(decl_72953, type, 'Synthesis-Of-Central-Vacuole': $i).
% 29.32/29.14  tff(decl_72954, type, 'Many plant cells have a large central vacuole that develops by the coalescence of smaller vacuoles. The smaller vacuoles are derived from the endoplasmic reticulum and Golgi apparatus.': $i).
% 29.32/29.14  tff(decl_72955, type, 'synthesis of central vacuole': $i).
% 29.32/29.14  tff(decl_72956, type, 'synthesis-of-central-vacuole': $i).
% 29.32/29.14  tff(decl_72957, type, synthesis_of_vacuole_1: $i > $o).
% 29.32/29.14  tff(decl_72958, type, fn_synthesis_of_central_vacuole_1: $i > $i).
% 29.32/29.14  tff(decl_72959, type, fn_synthesis_of_central_vacuole_2: $i > $i).
% 29.32/29.14  tff(decl_72960, type, fn_synthesis_of_central_vacuole_3: $i > $i).
% 29.32/29.14  tff(decl_72961, type, fn_synthesis_of_central_vacuole_4: $i > $i).
% 29.32/29.14  tff(decl_72962, type, fn_synthesis_of_vacuole_8: $i > $i).
% 29.32/29.14  tff(decl_72963, type, fn_synthesis_of_vacuole_5: $i > $i).
% 29.32/29.14  tff(decl_72964, type, 'Synthesis-Of-Coenzyme': $i).
% 29.32/29.14  tff(decl_72965, type, 'Most vitamins are coenzymes or raw materials from which coenzymes are made.': $i).
% 29.32/29.14  tff(decl_72966, type, 'coenzyme synthesis': $i).
% 29.32/29.14  tff(decl_72967, type, 'coenzyme-synthesis': $i).
% 29.32/29.14  tff(decl_72968, type, 'synthesis of coenzyme': $i).
% 29.32/29.14  tff(decl_72969, type, 'synthesis-of-coenzyme': $i).
% 29.32/29.14  tff(decl_72970, type, fn_synthesis_of_coenzyme_1: $i > $i).
% 29.32/29.14  tff(decl_72971, type, synthesis_of_coenzyme_a_1: $i > $o).
% 29.32/29.14  tff(decl_72972, type, 'Synthesis-Of-Coenzyme-A': $i).
% 29.32/29.14  tff(decl_72973, type, 'The production of Coenzyme A from pantothenate (Vitamin B5) and cysteine.': $i).
% 29.32/29.14  tff(decl_72974, type, 'synthesis of coenzyme a': $i).
% 29.32/29.14  tff(decl_72975, type, 'synthesis-of-coenzyme-a': $i).
% 29.32/29.14  tff(decl_72976, type, fn_synthesis_of_coenzyme_a_1: $i > $i).
% 29.32/29.14  tff(decl_72977, type, fn_synthesis_of_coenzyme_a_2: $i > $i).
% 29.32/29.14  tff(decl_72978, type, synthesis_of_cyclin_1: $i > $o).
% 29.32/29.14  tff(decl_72979, type, 'Synthesis-Of-Cyclin': $i).
% 29.32/29.14  tff(decl_72980, type, 'The process of production of cyclin, an important regulator molecule of the cell cycle.': $i).
% 29.32/29.14  tff(decl_72981, type, 'cyclin synthesis': $i).
% 29.32/29.14  tff(decl_72982, type, 'cyclin-synthesis': $i).
% 29.32/29.14  tff(decl_72983, type, 'synthesis of cyclin': $i).
% 29.32/29.14  tff(decl_72984, type, 'synthesis-of-cyclin': $i).
% 29.32/29.14  tff(decl_72985, type, fn_synthesis_of_cyclin_1: $i > $i).
% 29.32/29.14  tff(decl_72986, type, 'Synthesis-Of-DNA-Strand': $i).
% 29.32/29.14  tff(decl_72987, type, 'The process of synthesis of DNA strand.': $i).
% 29.32/29.14  tff(decl_72988, type, 'synthesis of dna strand': $i).
% 29.32/29.14  tff(decl_72989, type, 'synthesis-of-dna-strand': $i).
% 29.32/29.14  tff(decl_72990, type, fn_synthesis_of_dna_strand_3: $i > $i).
% 29.32/29.14  tff(decl_72991, type, fn_synthesis_of_dna_strand_4: $i > $i).
% 29.32/29.14  tff(decl_72992, type, fn_synthesis_of_dna_strand_5: $i > $i).
% 29.32/29.14  tff(decl_72993, type, fn_synthesis_of_dna_strand_6: $i > $i).
% 29.32/29.14  tff(decl_72994, type, fn_synthesis_of_dna_strand_18: $i > $i).
% 29.32/29.14  tff(decl_72995, type, fn_synthesis_of_dna_strand_19: $i > $i).
% 29.32/29.14  tff(decl_72996, type, fn_synthesis_of_dna_strand_22: $i > $i).
% 29.32/29.14  tff(decl_72997, type, 'Synthesis-Of-Endomembranous-System-Membrane': $i).
% 29.32/29.14  tff(decl_72998, type, 'It is the process of synthesis of membrane for different organelles of cell and plasma membrane.': $i).
% 29.32/29.14  tff(decl_72999, type, 'synthesis of cellular membrane': $i).
% 29.32/29.14  tff(decl_73000, type, 'synthesis-of-cellular-membrane': $i).
% 29.32/29.14  tff(decl_73001, type, 'synthesis of endomembranous system membrane': $i).
% 29.32/29.14  tff(decl_73002, type, 'synthesis-of-endomembranous-system-membrane': $i).
% 29.32/29.14  tff(decl_73003, type, fn_synthesis_of_endomembranous_system_membrane_3: $i > $i).
% 29.32/29.14  tff(decl_73004, type, fn_synthesis_of_endomembranous_system_membrane_4: $i > $i).
% 29.32/29.14  tff(decl_73005, type, fn_synthesis_of_endomembranous_system_membrane_5: $i > $i).
% 29.32/29.14  tff(decl_73006, type, fn_synthesis_of_endomembranous_system_membrane_6: $i > $i).
% 29.32/29.14  tff(decl_73007, type, fn_synthesis_of_endomembranous_system_membrane_8: $i > $i).
% 29.32/29.14  tff(decl_73008, type, fn_synthesis_of_endomembranous_system_membrane_9: $i > $i).
% 29.32/29.14  tff(decl_73009, type, fn_synthesis_of_endomembranous_system_membrane_10: $i > $i).
% 29.32/29.14  tff(decl_73010, type, fn_synthesis_of_endomembranous_system_membrane_11: $i > $i).
% 29.32/29.14  tff(decl_73011, type, fn_synthesis_of_endomembranous_system_membrane_12: $i > $i).
% 29.32/29.14  tff(decl_73012, type, fn_synthesis_of_endomembranous_system_membrane_13: $i > $i).
% 29.32/29.14  tff(decl_73013, type, fn_synthesis_of_endomembranous_system_membrane_14: $i > $i).
% 29.32/29.14  tff(decl_73014, type, fn_synthesis_of_endomembranous_system_membrane_15: $i > $i).
% 29.32/29.14  tff(decl_73015, type, fn_synthesis_of_endomembranous_system_membrane_16: $i > $i).
% 29.32/29.14  tff(decl_73016, type, fn_synthesis_of_endomembranous_system_membrane_17: $i > $i).
% 29.32/29.14  tff(decl_73017, type, fn_synthesis_of_endomembranous_system_membrane_29: $i > $i).
% 29.32/29.14  tff(decl_73018, type, fn_synthesis_of_endomembranous_system_membrane_30: $i > $i).
% 29.32/29.14  tff(decl_73019, type, fn_synthesis_of_endomembranous_system_membrane_31: $i > $i).
% 29.32/29.14  tff(decl_73020, type, fn_synthesis_of_endomembranous_system_membrane_32: $i > $i).
% 29.32/29.14  tff(decl_73021, type, fn_synthesis_of_endomembranous_system_membrane_33: $i > $i).
% 29.32/29.14  tff(decl_73022, type, fn_synthesis_of_endomembranous_system_membrane_34: $i > $i).
% 29.32/29.14  tff(decl_73023, type, fn_synthesis_of_endomembranous_system_membrane_35: $i > $i).
% 29.32/29.14  tff(decl_73024, type, fn_synthesis_of_endomembranous_system_membrane_36: $i > $i).
% 29.32/29.14  tff(decl_73025, type, fn_synthesis_of_endomembranous_system_membrane_37: $i > $i).
% 29.32/29.14  tff(decl_73026, type, fn_synthesis_of_endomembranous_system_membrane_38: $i > $i).
% 29.32/29.14  tff(decl_73027, type, fn_synthesis_of_endomembranous_system_membrane_39: $i > $i).
% 29.32/29.14  tff(decl_73028, type, fn_synthesis_of_endomembranous_system_membrane_40: $i > $i).
% 29.32/29.14  tff(decl_73029, type, fn_synthesis_of_endomembranous_system_membrane_41: $i > $i).
% 29.32/29.14  tff(decl_73030, type, fn_synthesis_of_endomembranous_system_membrane_42: $i > $i).
% 29.32/29.14  tff(decl_73031, type, fn_synthesis_of_endomembranous_system_membrane_43: $i > $i).
% 29.32/29.14  tff(decl_73032, type, fn_synthesis_of_endomembranous_system_membrane_44: $i > $i).
% 29.32/29.14  tff(decl_73033, type, fn_synthesis_of_endomembranous_system_membrane_45: $i > $i).
% 29.32/29.14  tff(decl_73034, type, fn_synthesis_of_endomembranous_system_membrane_46: $i > $i).
% 29.32/29.14  tff(decl_73035, type, fn_synthesis_of_endomembranous_system_membrane_47: $i > $i).
% 29.32/29.14  tff(decl_73036, type, fn_synthesis_of_endomembranous_system_membrane_48: $i > $i).
% 29.32/29.14  tff(decl_73037, type, fn_synthesis_of_endomembranous_system_membrane_49: $i > $i).
% 29.32/29.14  tff(decl_73038, type, fn_synthesis_of_endomembranous_system_membrane_57: $i > $i).
% 29.32/29.14  tff(decl_73039, type, fn_synthesis_of_endomembranous_system_membrane_58: $i > $i).
% 29.32/29.14  tff(decl_73040, type, fn_synthesis_of_endomembranous_system_membrane_61: $i > $i).
% 29.32/29.14  tff(decl_73041, type, fn_synthesis_of_endomembranous_system_membrane_68: $i > $i).
% 29.32/29.14  tff(decl_73042, type, fn_synthesis_of_endomembranous_system_membrane_71: $i > $i).
% 29.32/29.14  tff(decl_73043, type, fn_synthesis_of_endomembranous_system_membrane_73: $i > $i).
% 29.32/29.14  tff(decl_73044, type, fn_synthesis_of_endomembranous_system_membrane_74: $i > $i).
% 29.32/29.14  tff(decl_73045, type, fn_synthesis_of_endomembranous_system_membrane_75: $i > $i).
% 29.32/29.14  tff(decl_73046, type, fn_synthesis_of_endomembranous_system_membrane_76: $i > $i).
% 29.32/29.14  tff(decl_73047, type, fn_synthesis_of_endomembranous_system_membrane_77: $i > $i).
% 29.32/29.14  tff(decl_73048, type, fn_synthesis_of_endomembranous_system_membrane_78: $i > $i).
% 29.32/29.14  tff(decl_73049, type, fn_synthesis_of_endomembranous_system_membrane_79: $i > $i).
% 29.32/29.14  tff(decl_73050, type, fn_synthesis_of_endomembranous_system_membrane_80: $i > $i).
% 29.32/29.14  tff(decl_73051, type, fn_synthesis_of_endomembranous_system_membrane_81: $i > $i).
% 29.32/29.14  tff(decl_73052, type, fn_synthesis_of_endomembranous_system_membrane_82: $i > $i).
% 29.32/29.14  tff(decl_73053, type, fn_synthesis_of_endomembranous_system_membrane_86: $i > $i).
% 29.32/29.14  tff(decl_73054, type, fn_synthesis_of_endomembranous_system_membrane_87: $i > $i).
% 29.32/29.14  tff(decl_73055, type, fn_synthesis_of_endomembranous_system_membrane_88: $i > $i).
% 29.32/29.14  tff(decl_73056, type, fn_synthesis_of_endomembranous_system_membrane_89: $i > $i).
% 29.32/29.14  tff(decl_73057, type, fn_synthesis_of_endomembranous_system_membrane_90: $i > $i).
% 29.32/29.14  tff(decl_73058, type, fn_synthesis_of_endomembranous_system_membrane_91: $i > $i).
% 29.32/29.14  tff(decl_73059, type, fn_synthesis_of_endomembranous_system_membrane_92: $i > $i).
% 29.32/29.14  tff(decl_73060, type, fn_synthesis_of_endomembranous_system_membrane_93: $i > $i).
% 29.32/29.14  tff(decl_73061, type, fn_synthesis_of_endomembranous_system_membrane_94: $i > $i).
% 29.32/29.14  tff(decl_73062, type, fn_synthesis_of_endomembranous_system_membrane_95: $i > $i).
% 29.32/29.14  tff(decl_73063, type, fn_synthesis_of_endomembranous_system_membrane_96: $i > $i).
% 29.32/29.14  tff(decl_73064, type, fn_synthesis_of_endomembranous_system_membrane_97: $i > $i).
% 29.32/29.14  tff(decl_73065, type, fn_synthesis_of_endomembranous_system_membrane_98: $i > $i).
% 29.32/29.14  tff(decl_73066, type, fn_synthesis_of_endomembranous_system_membrane_100: $i > $i).
% 29.32/29.14  tff(decl_73067, type, fn_synthesis_of_endomembranous_system_membrane_101: $i > $i).
% 29.32/29.14  tff(decl_73068, type, fn_synthesis_of_endomembranous_system_membrane_102: $i > $i).
% 29.32/29.14  tff(decl_73069, type, fn_synthesis_of_glycoprotein_23: $i > $i).
% 29.32/29.14  tff(decl_73070, type, fn_synthesis_of_glycoprotein_54: $i > $i).
% 29.32/29.14  tff(decl_73071, type, fn_synthesis_of_glycoprotein_53: $i > $i).
% 29.32/29.14  tff(decl_73072, type, fn_synthesis_of_glycoprotein_49: $i > $i).
% 29.32/29.14  tff(decl_73073, type, fn_synthesis_of_glycoprotein_48: $i > $i).
% 29.32/29.14  tff(decl_73074, type, fn_synthesis_of_glycoprotein_33: $i > $i).
% 29.32/29.14  tff(decl_73075, type, fn_synthesis_of_glycoprotein_32: $i > $i).
% 29.32/29.14  tff(decl_73076, type, fn_synthesis_of_endomembranous_system_membrane_26: $i > $i).
% 29.32/29.14  tff(decl_73077, type, fn_synthesis_of_endomembranous_system_membrane_27: $i > $i).
% 29.32/29.14  tff(decl_73078, type, fn_synthesis_of_endomembranous_system_membrane_25: $i > $i).
% 29.32/29.14  tff(decl_73079, type, fn_synthesis_of_endomembranous_system_membrane_24: $i > $i).
% 29.32/29.14  tff(decl_73080, type, fn_synthesis_of_endomembranous_system_membrane_23: $i > $i).
% 29.32/29.14  tff(decl_73081, type, fn_synthesis_of_endomembranous_system_membrane_21: $i > $i).
% 29.32/29.14  tff(decl_73082, type, fn_synthesis_of_endomembranous_system_membrane_22: $i > $i).
% 29.32/29.14  tff(decl_73083, type, synthesis_of_fad_1: $i > $o).
% 29.32/29.14  tff(decl_73084, type, 'Synthesis-Of-FAD': $i).
% 29.32/29.14  tff(decl_73085, type, 'The biochemical production of FAD by bonding riboflavin to the phosphate group of an ADP molecule.': $i).
% 29.32/29.14  tff(decl_73086, type, 'fad synthesis': $i).
% 29.32/29.14  tff(decl_73087, type, 'fad-synthesis': $i).
% 29.32/29.14  tff(decl_73088, type, 'synthesis of fad': $i).
% 29.32/29.14  tff(decl_73089, type, 'synthesis-of-fad': $i).
% 29.32/29.14  tff(decl_73090, type, fn_synthesis_of_fad_1: $i > $i).
% 29.32/29.14  tff(decl_73091, type, vitamin_b2_1: $i > $o).
% 29.32/29.14  tff(decl_73092, type, fn_synthesis_of_fad_2: $i > $i).
% 29.32/29.14  tff(decl_73093, type, fn_synthesis_of_fat_7: $i > $i).
% 29.32/29.14  tff(decl_73094, type, 'Synthesis-Of-Fat': $i).
% 29.32/29.14  tff(decl_73095, type, 'The production of fat.': $i).
% 29.32/29.14  tff(decl_73096, type, 'fat synthesis': $i).
% 29.32/29.14  tff(decl_73097, type, 'fat-synthesis': $i).
% 29.32/29.14  tff(decl_73098, type, 'synthesis of fat': $i).
% 29.32/29.14  tff(decl_73099, type, 'synthesis-of-fat': $i).
% 29.32/29.14  tff(decl_73100, type, fn_synthesis_of_fat_1: $i > $i).
% 29.32/29.14  tff(decl_73101, type, fn_synthesis_of_fat_3: $i > $i).
% 29.32/29.14  tff(decl_73102, type, fn_synthesis_of_fat_4: $i > $i).
% 29.32/29.14  tff(decl_73103, type, fn_synthesis_of_fat_5: $i > $i).
% 29.32/29.14  tff(decl_73104, type, fn_synthesis_of_fat_6: $i > $i).
% 29.32/29.14  tff(decl_73105, type, fn_synthesis_of_fat_8: $i > $i).
% 29.32/29.14  tff(decl_73106, type, fn_synthesis_of_fat_9: $i > $i).
% 29.32/29.14  tff(decl_73107, type, dehydration_reaction_0: $i).
% 29.32/29.14  tff(decl_73108, type, fn_synthesis_of_fatty_acid_2: $i > $i).
% 29.32/29.14  tff(decl_73109, type, 'Synthesis-Of-Fatty-Acid': $i).
% 29.32/29.14  tff(decl_73110, type, 'The process of synthesizing fatty acids is called synthesis of fatty acid.': $i).
% 29.32/29.14  tff(decl_73111, type, 'synthesis of fatty acid': $i).
% 29.32/29.14  tff(decl_73112, type, 'synthesis-of-fatty-acid': $i).
% 29.32/29.14  tff(decl_73113, type, synthesis_of_fatty_acid_from_acetyl_coa_1: $i > $o).
% 29.32/29.14  tff(decl_73114, type, 'Synthesis-Of-Fatty-Acid-From-Acetyl-CoA': $i).
% 29.32/29.14  tff(decl_73115, type, 'The creation of fatty acids from acetyl-CoA and malonyl-CoA precursors catalyzed by fatty acid synthases.': $i).
% 29.32/29.14  tff(decl_73116, type, 'synthesis of fatty acid from acetyl coa': $i).
% 29.32/29.14  tff(decl_73117, type, 'synthesis-of-fatty-acid-from-acetyl-coa': $i).
% 29.32/29.14  tff(decl_73118, type, fn_synthesis_of_fatty_acid_from_acetyl_coa_1: $i > $i).
% 29.32/29.14  tff(decl_73119, type, fn_synthesis_of_fatty_acid_from_acetyl_coa_2: $i > $i).
% 29.32/29.14  tff(decl_73120, type, fn_synthesis_of_gamete_4: $i > $i).
% 29.32/29.14  tff(decl_73121, type, 'Synthesis-Of-Gamete': $i).
% 29.32/29.14  tff(decl_73122, type, 'This is the generation of gamete by meiosis.': $i).
% 29.32/29.14  tff(decl_73123, type, 'gamete synthesis': $i).
% 29.32/29.14  tff(decl_73124, type, 'gamete-synthesis': $i).
% 29.32/29.14  tff(decl_73125, type, 'synthesis of gamete': $i).
% 29.32/29.14  tff(decl_73126, type, 'synthesis-of-gamete': $i).
% 29.32/29.14  tff(decl_73127, type, fn_synthesis_of_gamete_1: $i > $i).
% 29.32/29.14  tff(decl_73128, type, fn_synthesis_of_gamete_2: $i > $i).
% 29.32/29.14  tff(decl_73129, type, synthesis_of_glucose_6_phosphate_from_glycogen_1: $i > $o).
% 29.32/29.14  tff(decl_73130, type, 'Synthesis-Of-Glucose-6-Phosphate-From-Glycogen': $i).
% 29.32/29.14  tff(decl_73131, type, 'Enzymatic catalysis of the breakdown of glycogen to produce glucose-6 phosphate.': $i).
% 29.32/29.14  tff(decl_73132, type, 'synthesis of glucose 6 phosphate from glycogen': $i).
% 29.32/29.14  tff(decl_73133, type, 'synthesis-of-glucose-6-phosphate-from-glycogen': $i).
% 29.32/29.14  tff(decl_73134, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_7: $i > $i).
% 29.32/29.14  tff(decl_73135, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_8: $i > $i).
% 29.32/29.14  tff(decl_73136, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_9: $i > $i).
% 29.32/29.14  tff(decl_73137, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_10: $i > $i).
% 29.32/29.14  tff(decl_73138, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_11: $i > $i).
% 29.32/29.14  tff(decl_73139, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_12: $i > $i).
% 29.32/29.14  tff(decl_73140, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_13: $i > $i).
% 29.32/29.14  tff(decl_73141, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_14: $i > $i).
% 29.32/29.14  tff(decl_73142, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_15: $i > $i).
% 29.32/29.14  tff(decl_73143, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_16: $i > $i).
% 29.32/29.14  tff(decl_73144, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_17: $i > $i).
% 29.32/29.14  tff(decl_73145, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_18: $i > $i).
% 29.32/29.14  tff(decl_73146, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_19: $i > $i).
% 29.32/29.14  tff(decl_73147, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_20: $i > $i).
% 29.32/29.14  tff(decl_73148, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_21: $i > $i).
% 29.32/29.14  tff(decl_73149, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_22: $i > $i).
% 29.32/29.14  tff(decl_73150, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_23: $i > $i).
% 29.32/29.14  tff(decl_73151, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_24: $i > $i).
% 29.32/29.14  tff(decl_73152, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_25: $i > $i).
% 29.32/29.14  tff(decl_73153, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_26: $i > $i).
% 29.32/29.14  tff(decl_73154, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_27: $i > $i).
% 29.32/29.14  tff(decl_73155, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_28: $i > $i).
% 29.32/29.14  tff(decl_73156, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_29: $i > $i).
% 29.32/29.14  tff(decl_73157, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_30: $i > $i).
% 29.32/29.14  tff(decl_73158, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_31: $i > $i).
% 29.32/29.14  tff(decl_73159, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_4: $i > $i).
% 29.32/29.14  tff(decl_73160, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_3: $i > $i).
% 29.32/29.14  tff(decl_73161, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_6: $i > $i).
% 29.32/29.14  tff(decl_73162, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_5: $i > $i).
% 29.32/29.14  tff(decl_73163, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_2: $i > $i).
% 29.32/29.14  tff(decl_73164, type, fn_synthesis_of_glucose_6_phosphate_from_glycogen_1: $i > $i).
% 29.32/29.14  tff(decl_73165, type, synthesis_of_glucose_from_g3p_1: $i > $o).
% 29.32/29.14  tff(decl_73166, type, 'Synthesis-Of-Glucose-From-G3P': $i).
% 29.32/29.14  tff(decl_73167, type, 'G3P is a 3-carbon sugar that is produced during the Calvin Cycle of photosynthesis.  From this molecule glucose is formed in other metabolic pathways.': $i).
% 29.32/29.14  tff(decl_73168, type, 'synthesis of glucose from g3p': $i).
% 29.32/29.14  tff(decl_73169, type, 'synthesis-of-glucose-from-g3p': $i).
% 29.32/29.14  tff(decl_73170, type, fn_synthesis_of_glucose_from_g3p_1: $i > $i).
% 29.32/29.14  tff(decl_73171, type, fn_synthesis_of_glucose_from_g3p_2: $i > $i).
% 29.32/29.14  tff(decl_73172, type, fn_synthesis_of_glucose_from_g3p_3: $i > $i).
% 29.32/29.14  tff(decl_73173, type, fn_synthesis_of_glucose_from_g3p_4: $i > $i).
% 29.32/29.14  tff(decl_73174, type, synthesis_of_glucose_from_pyruvate_1: $i > $o).
% 29.32/29.14  tff(decl_73175, type, 'Synthesis-Of-Glucose-From-Pyruvate': $i).
% 29.32/29.14  tff(decl_73176, type, 'This is a process of synthesis of glucose from pyruvate.': $i).
% 29.32/29.14  tff(decl_73177, type, 'synthesis of glucose from pyruvate': $i).
% 29.32/29.14  tff(decl_73178, type, 'synthesis-of-glucose-from-pyruvate': $i).
% 29.32/29.14  tff(decl_73179, type, fn_synthesis_of_glucose_from_pyruvate_1: $i > $i).
% 29.32/29.14  tff(decl_73180, type, fn_synthesis_of_glucose_from_pyruvate_2: $i > $i).
% 29.32/29.14  tff(decl_73181, type, synthesis_of_glutamine_with_atp_1: $i > $o).
% 29.32/29.14  tff(decl_73182, type, 'Synthesis-Of-Glutamine-with-ATP': $i).
% 29.32/29.14  tff(decl_73183, type, 'It is the process of formation of glutamine with use of ATP.': $i).
% 29.32/29.14  tff(decl_73184, type, 'synthesis of glutamine with atp': $i).
% 29.32/29.14  tff(decl_73185, type, 'synthesis-of-glutamine-with-atp': $i).
% 29.32/29.14  tff(decl_73186, type, synthesis_of_glutamine_without_atp_1: $i > $o).
% 29.32/29.14  tff(decl_73187, type, fn_synthesis_of_glutamine_with_atp_1: $i > $i).
% 29.32/29.14  tff(decl_73188, type, fn_synthesis_of_glutamine_with_atp_2: $i > $i).
% 29.32/29.14  tff(decl_73189, type, fn_synthesis_of_glutamine_with_atp_3: $i > $i).
% 29.32/29.14  tff(decl_73190, type, fn_synthesis_of_glutamine_with_atp_5: $i > $i).
% 29.32/29.14  tff(decl_73191, type, fn_synthesis_of_glutamine_with_atp_6: $i > $i).
% 29.32/29.14  tff(decl_73192, type, fn_synthesis_of_glutamine_with_atp_11: $i > $i).
% 29.32/29.14  tff(decl_73193, type, fn_synthesis_of_glutamine_with_atp_12: $i > $i).
% 29.32/29.14  tff(decl_73194, type, fn_synthesis_of_glutamine_with_atp_13: $i > $i).
% 29.32/29.14  tff(decl_73195, type, fn_synthesis_of_glutamine_with_atp_14: $i > $i).
% 29.32/29.14  tff(decl_73196, type, fn_synthesis_of_glutamine_with_atp_15: $i > $i).
% 29.32/29.14  tff(decl_73197, type, fn_synthesis_of_glutamine_with_atp_16: $i > $i).
% 29.32/29.14  tff(decl_73198, type, fn_synthesis_of_glutamine_with_atp_17: $i > $i).
% 29.32/29.14  tff(decl_73199, type, fn_synthesis_of_glutamine_with_atp_18: $i > $i).
% 29.32/29.14  tff(decl_73200, type, fn_synthesis_of_glutamine_with_atp_19: $i > $i).
% 29.32/29.14  tff(decl_73201, type, fn_synthesis_of_glutamine_with_atp_20: $i > $i).
% 29.32/29.14  tff(decl_73202, type, fn_synthesis_of_glutamine_with_atp_21: $i > $i).
% 29.32/29.14  tff(decl_73203, type, fn_synthesis_of_glutamine_with_atp_22: $i > $i).
% 29.32/29.14  tff(decl_73204, type, fn_synthesis_of_glutamine_with_atp_23: $i > $i).
% 29.32/29.14  tff(decl_73205, type, fn_synthesis_of_glutamine_with_atp_24: $i > $i).
% 29.32/29.14  tff(decl_73206, type, fn_synthesis_of_glutamine_with_atp_25: $i > $i).
% 29.32/29.14  tff(decl_73207, type, fn_synthesis_of_glutamine_with_atp_26: $i > $i).
% 29.32/29.14  tff(decl_73208, type, fn_synthesis_of_glutamine_with_atp_33: $i > $i).
% 29.32/29.14  tff(decl_73209, type, fn_synthesis_of_glutamine_with_atp_34: $i > $i).
% 29.32/29.14  tff(decl_73210, type, fn_synthesis_of_glutamine_with_atp_35: $i > $i).
% 29.32/29.14  tff(decl_73211, type, fn_synthesis_of_glutamine_with_atp_36: $i > $i).
% 29.32/29.14  tff(decl_73212, type, fn_synthesis_of_glutamine_with_atp_37: $i > $i).
% 29.32/29.14  tff(decl_73213, type, fn_synthesis_of_glutamine_with_atp_38: $i > $i).
% 29.32/29.14  tff(decl_73214, type, fn_synthesis_of_glutamine_with_atp_39: $i > $i).
% 29.32/29.14  tff(decl_73215, type, fn_synthesis_of_glutamine_with_atp_40: $i > $i).
% 29.32/29.14  tff(decl_73216, type, fn_synthesis_of_glutamine_with_atp_41: $i > $i).
% 29.32/29.14  tff(decl_73217, type, fn_synthesis_of_glutamine_with_atp_42: $i > $i).
% 29.32/29.14  tff(decl_73218, type, fn_synthesis_of_glutamine_with_atp_43: $i > $i).
% 29.32/29.14  tff(decl_73219, type, fn_synthesis_of_glutamine_with_atp_44: $i > $i).
% 29.32/29.14  tff(decl_73220, type, fn_synthesis_of_glutamine_with_atp_45: $i > $i).
% 29.32/29.14  tff(decl_73221, type, fn_synthesis_of_glutamine_with_atp_46: $i > $i).
% 29.32/29.14  tff(decl_73222, type, fn_synthesis_of_glutamine_with_atp_47: $i > $i).
% 29.32/29.14  tff(decl_73223, type, fn_synthesis_of_glutamine_with_atp_48: $i > $i).
% 29.32/29.14  tff(decl_73224, type, fn_synthesis_of_glutamine_with_atp_49: $i > $i).
% 29.32/29.14  tff(decl_73225, type, fn_synthesis_of_glutamine_with_atp_50: $i > $i).
% 29.32/29.14  tff(decl_73226, type, fn_synthesis_of_glutamine_with_atp_51: $i > $i).
% 29.32/29.14  tff(decl_73227, type, fn_synthesis_of_glutamine_with_atp_52: $i > $i).
% 29.32/29.14  tff(decl_73228, type, fn_synthesis_of_glutamine_with_atp_53: $i > $i).
% 29.32/29.14  tff(decl_73229, type, fn_synthesis_of_glutamine_with_atp_54: $i > $i).
% 29.32/29.14  tff(decl_73230, type, fn_synthesis_of_glutamine_with_atp_55: $i > $i).
% 29.32/29.14  tff(decl_73231, type, fn_synthesis_of_glutamine_with_atp_56: $i > $i).
% 29.32/29.14  tff(decl_73232, type, fn_synthesis_of_glutamine_with_atp_57: $i > $i).
% 29.32/29.14  tff(decl_73233, type, chemical_reaction_0: $i).
% 29.32/29.14  tff(decl_73234, type, fn_synthesis_of_glutamine_with_atp_30: $i > $i).
% 29.32/29.14  tff(decl_73235, type, fn_synthesis_of_glutamine_with_atp_29: $i > $i).
% 29.32/29.14  tff(decl_73236, type, fn_synthesis_of_glutamine_with_atp_28: $i > $i).
% 29.32/29.14  tff(decl_73237, type, fn_synthesis_of_glutamine_with_atp_27: $i > $i).
% 29.32/29.14  tff(decl_73238, type, fn_synthesis_of_glutamine_with_atp_58: $i > $i).
% 29.32/29.14  tff(decl_73239, type, fn_synthesis_of_glutamine_with_atp_32: $i > $i).
% 29.32/29.14  tff(decl_73240, type, fn_synthesis_of_glutamine_with_atp_31: $i > $i).
% 29.32/29.14  tff(decl_73241, type, fn_synthesis_of_glutamine_with_atp_8: $i > $i).
% 29.32/29.14  tff(decl_73242, type, fn_synthesis_of_glutamine_with_atp_7: $i > $i).
% 29.32/29.14  tff(decl_73243, type, fn_synthesis_of_glutamine_with_atp_4: $i > $i).
% 29.32/29.14  tff(decl_73244, type, fn_synthesis_of_glutamine_with_atp_10: $i > $i).
% 29.32/29.14  tff(decl_73245, type, fn_synthesis_of_glutamine_with_atp_9: $i > $i).
% 29.32/29.14  tff(decl_73246, type, fn_synthesis_of_glutamine_without_atp_3: $i > $i).
% 29.32/29.14  tff(decl_73247, type, 'Synthesis-Of-Glutamine-without-ATP': $i).
% 29.32/29.14  tff(decl_73248, type, 'It is the process of formation of glutamine without use of ATP.': $i).
% 29.32/29.14  tff(decl_73249, type, 'synthesis of glutamine without atp': $i).
% 29.32/29.14  tff(decl_73250, type, 'synthesis-of-glutamine-without-atp': $i).
% 29.32/29.14  tff(decl_73251, type, fn_synthesis_of_glutamine_without_atp_1: $i > $i).
% 29.32/29.14  tff(decl_73252, type, fn_synthesis_of_glutamine_without_atp_4: $i > $i).
% 29.32/29.14  tff(decl_73253, type, fn_synthesis_of_glutamine_without_atp_5: $i > $i).
% 29.32/29.14  tff(decl_73254, type, fn_synthesis_of_glutamine_without_atp_6: $i > $i).
% 29.32/29.14  tff(decl_73255, type, 'Synthesis-Of-Glycoprotein': $i).
% 29.32/29.14  tff(decl_73256, type, 'The formation of a protein with a carbohydrate component.  The addition of the small carbohydrate molecules to proteins occurs in the rough ER during protein synthesis.': $i).
% 29.32/29.14  tff(decl_73257, type, 'glycoprotein synthesis': $i).
% 29.32/29.14  tff(decl_73258, type, 'glycoprotein-synthesis': $i).
% 29.32/29.14  tff(decl_73259, type, 'synthesis of glycoprotein': $i).
% 29.32/29.14  tff(decl_73260, type, 'synthesis-of-glycoprotein': $i).
% 29.32/29.14  tff(decl_73261, type, fn_synthesis_of_glycoprotein_1: $i > $i).
% 29.32/29.14  tff(decl_73262, type, fn_synthesis_of_glycoprotein_4: $i > $i).
% 29.32/29.14  tff(decl_73263, type, fn_synthesis_of_glycoprotein_7: $i > $i).
% 29.32/29.14  tff(decl_73264, type, fn_synthesis_of_glycoprotein_8: $i > $i).
% 29.32/29.14  tff(decl_73265, type, fn_synthesis_of_glycoprotein_9: $i > $i).
% 29.32/29.14  tff(decl_73266, type, fn_synthesis_of_glycoprotein_10: $i > $i).
% 29.32/29.14  tff(decl_73267, type, fn_synthesis_of_glycoprotein_11: $i > $i).
% 29.32/29.14  tff(decl_73268, type, fn_synthesis_of_glycoprotein_12: $i > $i).
% 29.32/29.14  tff(decl_73269, type, fn_synthesis_of_glycoprotein_14: $i > $i).
% 29.32/29.14  tff(decl_73270, type, fn_synthesis_of_glycoprotein_15: $i > $i).
% 29.32/29.14  tff(decl_73271, type, fn_synthesis_of_glycoprotein_16: $i > $i).
% 29.32/29.14  tff(decl_73272, type, fn_synthesis_of_glycoprotein_17: $i > $i).
% 29.32/29.14  tff(decl_73273, type, fn_synthesis_of_glycoprotein_19: $i > $i).
% 29.32/29.14  tff(decl_73274, type, fn_synthesis_of_glycoprotein_20: $i > $i).
% 29.32/29.14  tff(decl_73275, type, fn_synthesis_of_glycoprotein_21: $i > $i).
% 29.32/29.14  tff(decl_73276, type, fn_synthesis_of_glycoprotein_34: $i > $i).
% 29.32/29.14  tff(decl_73277, type, fn_synthesis_of_glycoprotein_35: $i > $i).
% 29.32/29.14  tff(decl_73278, type, fn_synthesis_of_glycoprotein_36: $i > $i).
% 29.32/29.14  tff(decl_73279, type, fn_synthesis_of_glycoprotein_37: $i > $i).
% 29.32/29.14  tff(decl_73280, type, fn_synthesis_of_glycoprotein_38: $i > $i).
% 29.32/29.14  tff(decl_73281, type, fn_synthesis_of_glycoprotein_39: $i > $i).
% 29.32/29.14  tff(decl_73282, type, fn_synthesis_of_glycoprotein_40: $i > $i).
% 29.32/29.14  tff(decl_73283, type, fn_synthesis_of_glycoprotein_41: $i > $i).
% 29.32/29.14  tff(decl_73284, type, fn_synthesis_of_glycoprotein_44: $i > $i).
% 29.32/29.14  tff(decl_73285, type, fn_synthesis_of_glycoprotein_45: $i > $i).
% 29.32/29.14  tff(decl_73286, type, fn_synthesis_of_glycoprotein_47: $i > $i).
% 29.32/29.14  tff(decl_73287, type, fn_synthesis_of_glycoprotein_50: $i > $i).
% 29.32/29.14  tff(decl_73288, type, fn_synthesis_of_glycoprotein_51: $i > $i).
% 29.32/29.14  tff(decl_73289, type, fn_synthesis_of_glycoprotein_68: $i > $i).
% 29.32/29.14  tff(decl_73290, type, fn_synthesis_of_glycoprotein_69: $i > $i).
% 29.32/29.14  tff(decl_73291, type, fn_synthesis_of_glycoprotein_71: $i > $i).
% 29.32/29.14  tff(decl_73292, type, fn_synthesis_of_glycoprotein_72: $i > $i).
% 29.32/29.14  tff(decl_73293, type, fn_synthesis_of_glycoprotein_73: $i > $i).
% 29.32/29.14  tff(decl_73294, type, fn_synthesis_of_glycoprotein_74: $i > $i).
% 29.32/29.14  tff(decl_73295, type, fn_synthesis_of_glycoprotein_75: $i > $i).
% 29.32/29.14  tff(decl_73296, type, fn_synthesis_of_glycoprotein_78: $i > $i).
% 29.32/29.14  tff(decl_73297, type, fn_synthesis_of_glycoprotein_79: $i > $i).
% 29.32/29.14  tff(decl_73298, type, fn_synthesis_of_glycoprotein_80: $i > $i).
% 29.32/29.14  tff(decl_73299, type, fn_synthesis_of_glycoprotein_81: $i > $i).
% 29.32/29.14  tff(decl_73300, type, fn_synthesis_of_glycoprotein_82: $i > $i).
% 29.32/29.14  tff(decl_73301, type, fn_synthesis_of_glycoprotein_86: $i > $i).
% 29.32/29.14  tff(decl_73302, type, fn_synthesis_of_glycoprotein_87: $i > $i).
% 29.32/29.14  tff(decl_73303, type, fn_synthesis_of_glycoprotein_89: $i > $i).
% 29.32/29.14  tff(decl_73304, type, fn_synthesis_of_glycoprotein_90: $i > $i).
% 29.32/29.14  tff(decl_73305, type, fn_synthesis_of_glycoprotein_91: $i > $i).
% 29.32/29.14  tff(decl_73306, type, fn_synthesis_of_glycoprotein_92: $i > $i).
% 29.32/29.14  tff(decl_73307, type, fn_synthesis_of_glycoprotein_94: $i > $i).
% 29.32/29.14  tff(decl_73308, type, fn_synthesis_of_glycoprotein_96: $i > $i).
% 29.32/29.14  tff(decl_73309, type, fn_synthesis_of_glycoprotein_97: $i > $i).
% 29.32/29.14  tff(decl_73310, type, fn_synthesis_of_protein_31: $i > $i).
% 29.32/29.14  tff(decl_73311, type, fn_synthesis_of_protein_30: $i > $i).
% 29.32/29.14  tff(decl_73312, type, fn_synthesis_of_protein_36: $i > $i).
% 29.32/29.14  tff(decl_73313, type, fn_synthesis_of_protein_2: $i > $i).
% 29.32/29.14  tff(decl_73314, type, fn_synthesis_of_protein_29: $i > $i).
% 29.32/29.14  tff(decl_73315, type, fn_synthesis_of_protein_27: $i > $i).
% 29.32/29.14  tff(decl_73316, type, fn_synthesis_of_protein_22: $i > $i).
% 29.32/29.14  tff(decl_73317, type, fn_synthesis_of_protein_42: $i > $i).
% 29.32/29.14  tff(decl_73318, type, fn_synthesis_of_protein_4: $i > $i).
% 29.32/29.14  tff(decl_73319, type, fn_synthesis_of_protein_6: $i > $i).
% 29.32/29.14  tff(decl_73320, type, fn_synthesis_of_protein_28: $i > $i).
% 29.32/29.14  tff(decl_73321, type, fn_synthesis_of_protein_5: $i > $i).
% 29.32/29.14  tff(decl_73322, type, fn_synthesis_of_protein_45: $i > $i).
% 29.32/29.14  tff(decl_73323, type, fn_synthesis_of_protein_15: $i > $i).
% 29.32/29.14  tff(decl_73324, type, fn_synthesis_of_protein_14: $i > $i).
% 29.32/29.14  tff(decl_73325, type, fn_synthesis_of_protein_43: $i > $i).
% 29.32/29.14  tff(decl_73326, type, fn_synthesis_of_protein_44: $i > $i).
% 29.32/29.14  tff(decl_73327, type, fn_synthesis_of_protein_34: $i > $i).
% 29.32/29.14  tff(decl_73328, type, fn_synthesis_of_glycoprotein_22: $i > $i).
% 29.32/29.14  tff(decl_73329, type, fn_synthesis_of_protein_21: $i > $i).
% 29.32/29.14  tff(decl_73330, type, fn_synthesis_of_protein_20: $i > $i).
% 29.32/29.14  tff(decl_73331, type, fn_synthesis_of_protein_37: $i > $i).
% 29.32/29.14  tff(decl_73332, type, fn_synthesis_of_protein_41: $i > $i).
% 29.32/29.14  tff(decl_73333, type, fn_synthesis_of_protein_19: $i > $i).
% 29.32/29.14  tff(decl_73334, type, fn_synthesis_of_protein_17: $i > $i).
% 29.32/29.14  tff(decl_73335, type, fn_synthesis_of_glycoprotein_27: $i > $i).
% 29.32/29.14  tff(decl_73336, type, fn_synthesis_of_glycoprotein_26: $i > $i).
% 29.32/29.14  tff(decl_73337, type, fn_synthesis_of_glycoprotein_85: $i > $i).
% 29.32/29.14  tff(decl_73338, type, fn_synthesis_of_glycoprotein_84: $i > $i).
% 29.32/29.14  tff(decl_73339, type, 'Synthesis-Of-GTP': $i).
% 29.32/29.14  tff(decl_73340, type, 'The GTP is synthesized by the addition of phosphate ion to GDP.': $i).
% 29.32/29.14  tff(decl_73341, type, 'gtp synthesis': $i).
% 29.32/29.14  tff(decl_73342, type, 'gtp-synthesis': $i).
% 29.32/29.14  tff(decl_73343, type, 'synthesis of gtp': $i).
% 29.32/29.14  tff(decl_73344, type, 'synthesis-of-gtp': $i).
% 29.32/29.14  tff(decl_73345, type, fn_synthesis_of_gtp_2: $i > $i).
% 29.32/29.14  tff(decl_73346, type, fn_synthesis_of_gtp_4: $i > $i).
% 29.32/29.14  tff(decl_73347, type, fn_synthesis_of_gtp_5: $i > $i).
% 29.32/29.14  tff(decl_73348, type, fn_synthesis_of_gtp_6: $i > $i).
% 29.32/29.14  tff(decl_73349, type, fn_synthesis_of_gtp_7: $i > $i).
% 29.32/29.14  tff(decl_73350, type, fn_synthesis_of_gtp_8: $i > $i).
% 29.32/29.14  tff(decl_73351, type, fn_synthesis_of_gtp_10: $i > $i).
% 29.32/29.14  tff(decl_73352, type, fn_synthesis_of_gtp_11: $i > $i).
% 29.32/29.14  tff(decl_73353, type, fn_synthesis_of_gtp_12: $i > $i).
% 29.32/29.14  tff(decl_73354, type, synthesis_of_hormone_1: $i > $o).
% 29.32/29.14  tff(decl_73355, type, fn_synthesis_of_hormone_2: $i > $i).
% 29.32/29.14  tff(decl_73356, type, 'Synthesis-Of-Hormone': $i).
% 29.32/29.14  tff(decl_73357, type, 'The production of hormone.': $i).
% 29.32/29.14  tff(decl_73358, type, 'hormone synthesis': $i).
% 29.32/29.14  tff(decl_73359, type, 'hormone-synthesis': $i).
% 29.32/29.14  tff(decl_73360, type, 'synthesis of hormone': $i).
% 29.32/29.14  tff(decl_73361, type, 'synthesis-of-hormone': $i).
% 29.32/29.14  tff(decl_73362, type, fn_synthesis_of_human_protein_in_bacteria_2: $i > $i).
% 29.32/29.14  tff(decl_73363, type, fn_synthesis_of_human_protein_in_bacteria_7: $i > $i).
% 29.32/29.14  tff(decl_73364, type, 'Synthesis-of-Human-Protein-in-Bacteria': $i).
% 29.32/29.14  tff(decl_73365, type, 'Following transformation of bacteria with the addition of a gene which encodes human protein, the process of prokaryotic transcription and translation produce the human protein. Human insulin for medical treatment is made in this way.': $i).
% 29.32/29.14  tff(decl_73366, type, 'synthesis of human protein in bacterium': $i).
% 29.32/29.14  tff(decl_73367, type, 'synthesis-of-human-protein-in-bacteria': $i).
% 29.32/29.14  tff(decl_73368, type, fn_synthesis_of_human_protein_in_bacteria_1: $i > $i).
% 29.32/29.14  tff(decl_73369, type, fn_synthesis_of_human_protein_in_bacteria_4: $i > $i).
% 29.32/29.14  tff(decl_73370, type, fn_synthesis_of_human_protein_in_bacteria_5: $i > $i).
% 29.32/29.14  tff(decl_73371, type, fn_synthesis_of_human_protein_in_bacteria_6: $i > $i).
% 29.32/29.14  tff(decl_73372, type, fn_synthesis_of_human_protein_in_bacteria_8: $i > $i).
% 29.32/29.14  tff(decl_73373, type, fn_synthesis_of_human_protein_in_bacteria_9: $i > $i).
% 29.32/29.14  tff(decl_73374, type, fn_synthesis_of_human_protein_in_bacteria_10: $i > $i).
% 29.32/29.14  tff(decl_73375, type, fn_synthesis_of_inosine_7: $i > $i).
% 29.32/29.14  tff(decl_73376, type, 'Synthesis-of-Inosine': $i).
% 29.32/29.14  tff(decl_73377, type, 'Inosine is formed by enzymatic alteration of adenine after tRNA is synthesized.': $i).
% 29.32/29.14  tff(decl_73378, type, 'inosine synthesis': $i).
% 29.32/29.14  tff(decl_73379, type, 'inosine-synthesis': $i).
% 29.32/29.14  tff(decl_73380, type, 'synthesis of inosine': $i).
% 29.32/29.14  tff(decl_73381, type, 'synthesis-of-inosine': $i).
% 29.32/29.14  tff(decl_73382, type, fn_synthesis_of_inosine_1: $i > $i).
% 29.32/29.14  tff(decl_73383, type, fn_synthesis_of_inosine_3: $i > $i).
% 29.32/29.14  tff(decl_73384, type, fn_synthesis_of_inosine_4: $i > $i).
% 29.32/29.14  tff(decl_73385, type, fn_synthesis_of_inosine_5: $i > $i).
% 29.32/29.14  tff(decl_73386, type, fn_synthesis_of_inosine_6: $i > $i).
% 29.32/29.14  tff(decl_73387, type, 'Synthesis-Of-Insulin': $i).
% 29.32/29.14  tff(decl_73388, type, 'The protein insulin is synthesized as a single polypeptide chain but becomes active only after an enzyme cuts out a central part of the chain, leaving a protein made up of two polypeptide chains connected by disulfide bridges.': $i).
% 29.32/29.14  tff(decl_73389, type, 'insulin synthesis': $i).
% 29.32/29.14  tff(decl_73390, type, 'insulin-synthesis': $i).
% 29.32/29.14  tff(decl_73391, type, 'synthesis of insulin': $i).
% 29.32/29.14  tff(decl_73392, type, 'synthesis-of-insulin': $i).
% 29.32/29.14  tff(decl_73393, type, fn_synthesis_of_insulin_1: $i > $i).
% 29.32/29.14  tff(decl_73394, type, fn_synthesis_of_insulin_3: $i > $i).
% 29.32/29.14  tff(decl_73395, type, fn_synthesis_of_insulin_4: $i > $i).
% 29.32/29.14  tff(decl_73396, type, fn_synthesis_of_insulin_5: $i > $i).
% 29.32/29.14  tff(decl_73397, type, fn_synthesis_of_insulin_6: $i > $i).
% 29.32/29.14  tff(decl_73398, type, fn_synthesis_of_insulin_7: $i > $i).
% 29.32/29.14  tff(decl_73399, type, fn_synthesis_of_insulin_8: $i > $i).
% 29.32/29.14  tff(decl_73400, type, fn_synthesis_of_insulin_9: $i > $i).
% 29.32/29.14  tff(decl_73401, type, fn_synthesis_of_insulin_10: $i > $i).
% 29.32/29.14  tff(decl_73402, type, fn_synthesis_of_insulin_11: $i > $i).
% 29.32/29.14  tff(decl_73403, type, fn_synthesis_of_insulin_12: $i > $i).
% 29.32/29.14  tff(decl_73404, type, fn_synthesis_of_insulin_13: $i > $i).
% 29.32/29.14  tff(decl_73405, type, fn_synthesis_of_insulin_14: $i > $i).
% 29.32/29.14  tff(decl_73406, type, fn_synthesis_of_insulin_15: $i > $i).
% 29.32/29.14  tff(decl_73407, type, fn_synthesis_of_insulin_16: $i > $i).
% 29.32/29.14  tff(decl_73408, type, fn_synthesis_of_insulin_2: $i > $i).
% 29.32/29.14  tff(decl_73409, type, synthesis_of_insulin_by_animal_1: $i > $o).
% 29.32/29.14  tff(decl_73410, type, 'Synthesis-Of-Insulin-By-Animal': $i).
% 29.32/29.14  tff(decl_73411, type, 'Insulin is produced in the pancreas and released when any of the several stimuli are detected. The stimuli include ingested protein and glucose in the blood produced from digested food.': $i).
% 29.32/29.14  tff(decl_73412, type, 'synthesis of insulin by animal': $i).
% 29.32/29.14  tff(decl_73413, type, 'synthesis-of-insulin-by-animal': $i).
% 29.32/29.14  tff(decl_73414, type, fn_synthesis_of_insulin_by_animal_1: $i > $i).
% 29.32/29.14  tff(decl_73415, type, fn_synthesis_of_insulin_by_animal_2: $i > $i).
% 29.32/29.14  tff(decl_73416, type, fn_synthesis_of_insulin_by_animal_3: $i > $i).
% 29.32/29.14  tff(decl_73417, type, fn_synthesis_of_insulin_by_animal_4: $i > $i).
% 29.32/29.14  tff(decl_73418, type, fn_synthesis_of_insulin_by_animal_5: $i > $i).
% 29.32/29.14  tff(decl_73419, type, fn_synthesis_of_insulin_by_animal_6: $i > $i).
% 29.32/29.14  tff(decl_73420, type, fn_synthesis_of_insulin_by_animal_7: $i > $i).
% 29.32/29.14  tff(decl_73421, type, fn_synthesis_of_insulin_by_animal_8: $i > $i).
% 29.32/29.14  tff(decl_73422, type, fn_synthesis_of_insulin_by_animal_9: $i > $i).
% 29.32/29.14  tff(decl_73423, type, fn_synthesis_of_insulin_by_animal_10: $i > $i).
% 29.32/29.14  tff(decl_73424, type, fn_synthesis_of_insulin_by_animal_11: $i > $i).
% 29.32/29.14  tff(decl_73425, type, fn_synthesis_of_insulin_by_animal_12: $i > $i).
% 29.32/29.14  tff(decl_73426, type, fn_synthesis_of_insulin_by_animal_13: $i > $i).
% 29.32/29.14  tff(decl_73427, type, fn_synthesis_of_insulin_by_animal_14: $i > $i).
% 29.32/29.14  tff(decl_73428, type, fn_synthesis_of_insulin_by_animal_15: $i > $i).
% 29.32/29.14  tff(decl_73429, type, fn_synthesis_of_insulin_by_animal_16: $i > $i).
% 29.32/29.14  tff(decl_73430, type, fn_synthesis_of_insulin_by_animal_17: $i > $i).
% 29.32/29.14  tff(decl_73431, type, fn_synthesis_of_insulin_by_animal_18: $i > $i).
% 29.32/29.14  tff(decl_73432, type, fn_synthesis_of_insulin_by_animal_19: $i > $i).
% 29.32/29.14  tff(decl_73433, type, fn_synthesis_of_insulin_by_animal_20: $i > $i).
% 29.32/29.14  tff(decl_73434, type, fn_synthesis_of_insulin_by_animal_21: $i > $i).
% 29.32/29.14  tff(decl_73435, type, fn_synthesis_of_insulin_by_animal_22: $i > $i).
% 29.32/29.14  tff(decl_73436, type, fn_synthesis_of_insulin_by_animal_23: $i > $i).
% 29.32/29.14  tff(decl_73437, type, fn_synthesis_of_insulin_by_animal_24: $i > $i).
% 29.32/29.14  tff(decl_73438, type, fn_synthesis_of_insulin_by_animal_25: $i > $i).
% 29.32/29.14  tff(decl_73439, type, fn_synthesis_of_insulin_by_animal_26: $i > $i).
% 29.32/29.14  tff(decl_73440, type, fn_synthesis_of_insulin_by_animal_27: $i > $i).
% 29.32/29.14  tff(decl_73441, type, fn_synthesis_of_insulin_by_animal_28: $i > $i).
% 29.32/29.14  tff(decl_73442, type, fn_synthesis_of_insulin_by_animal_29: $i > $i).
% 29.32/29.14  tff(decl_73443, type, fn_synthesis_of_insulin_by_animal_30: $i > $i).
% 29.32/29.14  tff(decl_73444, type, fn_synthesis_of_insulin_by_animal_31: $i > $i).
% 29.32/29.14  tff(decl_73445, type, fn_synthesis_of_insulin_by_animal_32: $i > $i).
% 29.32/29.14  tff(decl_73446, type, fn_synthesis_of_insulin_by_animal_33: $i > $i).
% 29.32/29.14  tff(decl_73447, type, fn_synthesis_of_insulin_by_animal_34: $i > $i).
% 29.32/29.14  tff(decl_73448, type, fn_synthesis_of_insulin_by_animal_35: $i > $i).
% 29.32/29.14  tff(decl_73449, type, fn_synthesis_of_insulin_by_animal_36: $i > $i).
% 29.32/29.14  tff(decl_73450, type, fn_synthesis_of_insulin_by_animal_37: $i > $i).
% 29.32/29.14  tff(decl_73451, type, fn_synthesis_of_insulin_by_animal_38: $i > $i).
% 29.32/29.14  tff(decl_73452, type, fn_synthesis_of_insulin_by_animal_42: $i > $i).
% 29.32/29.14  tff(decl_73453, type, fn_synthesis_of_insulin_by_animal_43: $i > $i).
% 29.32/29.14  tff(decl_73454, type, fn_synthesis_of_insulin_by_animal_44: $i > $i).
% 29.32/29.14  tff(decl_73455, type, fn_synthesis_of_insulin_by_animal_45: $i > $i).
% 29.32/29.14  tff(decl_73456, type, fn_synthesis_of_insulin_by_animal_46: $i > $i).
% 29.32/29.14  tff(decl_73457, type, fn_synthesis_of_insulin_by_animal_47: $i > $i).
% 29.32/29.14  tff(decl_73458, type, fn_synthesis_of_insulin_by_animal_48: $i > $i).
% 29.32/29.14  tff(decl_73459, type, fn_synthesis_of_insulin_by_animal_49: $i > $i).
% 29.32/29.14  tff(decl_73460, type, fn_synthesis_of_insulin_by_animal_39: $i > $i).
% 29.32/29.14  tff(decl_73461, type, fn_synthesis_of_insulin_by_animal_40: $i > $i).
% 29.32/29.14  tff(decl_73462, type, fn_synthesis_of_insulin_by_animal_50: $i > $i).
% 29.32/29.14  tff(decl_73463, type, fn_synthesis_of_protein_46: $i > $i).
% 29.32/29.14  tff(decl_73464, type, fn_synthesis_of_protein_40: $i > $i).
% 29.32/29.14  tff(decl_73465, type, fn_synthesis_of_protein_38: $i > $i).
% 29.32/29.14  tff(decl_73466, type, fn_synthesis_of_protein_39: $i > $i).
% 29.32/29.14  tff(decl_73467, type, fn_synthesis_of_insulin_by_animal_41: $i > $i).
% 29.32/29.14  tff(decl_73468, type, 'Synthesis-Of-Lagging-Strand': $i).
% 29.32/29.14  tff(decl_73469, type, 'The elongation of a discontinuously synthesized DNA strand that elongates by means of Okazaki fragments, each synthesized in a 5\\ - 3\\ direction away from the replication fork.': $i).
% 29.32/29.14  tff(decl_73470, type, 'synthesis of lagging strand': $i).
% 29.32/29.14  tff(decl_73471, type, 'synthesis-of-lagging-strand': $i).
% 29.32/29.14  tff(decl_73472, type, fn_synthesis_of_lagging_strand_1: $i > $i).
% 29.32/29.14  tff(decl_73473, type, fn_synthesis_of_lagging_strand_2: $i > $i).
% 29.32/29.14  tff(decl_73474, type, fn_synthesis_of_lagging_strand_3: $i > $i).
% 29.32/29.14  tff(decl_73475, type, fn_synthesis_of_lagging_strand_4: $i > $i).
% 29.32/29.14  tff(decl_73476, type, fn_synthesis_of_lagging_strand_5: $i > $i).
% 29.32/29.14  tff(decl_73477, type, fn_synthesis_of_lagging_strand_6: $i > $i).
% 29.32/29.14  tff(decl_73478, type, fn_synthesis_of_lagging_strand_10: $i > $i).
% 29.32/29.14  tff(decl_73479, type, fn_synthesis_of_lagging_strand_11: $i > $i).
% 29.32/29.14  tff(decl_73480, type, fn_synthesis_of_lagging_strand_12: $i > $i).
% 29.32/29.14  tff(decl_73481, type, fn_synthesis_of_lagging_strand_13: $i > $i).
% 29.32/29.14  tff(decl_73482, type, fn_synthesis_of_lagging_strand_14: $i > $i).
% 29.32/29.14  tff(decl_73483, type, fn_synthesis_of_lagging_strand_15: $i > $i).
% 29.32/29.14  tff(decl_73484, type, fn_synthesis_of_lagging_strand_16: $i > $i).
% 29.32/29.14  tff(decl_73485, type, fn_synthesis_of_lagging_strand_17: $i > $i).
% 29.32/29.14  tff(decl_73486, type, fn_synthesis_of_lagging_strand_18: $i > $i).
% 29.32/29.14  tff(decl_73487, type, fn_synthesis_of_lagging_strand_19: $i > $i).
% 29.32/29.14  tff(decl_73488, type, fn_synthesis_of_lagging_strand_20: $i > $i).
% 29.32/29.14  tff(decl_73489, type, fn_synthesis_of_lagging_strand_21: $i > $i).
% 29.32/29.14  tff(decl_73490, type, fn_synthesis_of_lagging_strand_22: $i > $i).
% 29.32/29.14  tff(decl_73491, type, fn_synthesis_of_lagging_strand_23: $i > $i).
% 29.32/29.14  tff(decl_73492, type, fn_synthesis_of_lagging_strand_24: $i > $i).
% 29.32/29.14  tff(decl_73493, type, fn_synthesis_of_lagging_strand_25: $i > $i).
% 29.32/29.14  tff(decl_73494, type, fn_synthesis_of_lagging_strand_26: $i > $i).
% 29.32/29.14  tff(decl_73495, type, fn_synthesis_of_lagging_strand_27: $i > $i).
% 29.32/29.14  tff(decl_73496, type, fn_synthesis_of_lagging_strand_28: $i > $i).
% 29.32/29.14  tff(decl_73497, type, fn_synthesis_of_lagging_strand_29: $i > $i).
% 29.32/29.14  tff(decl_73498, type, fn_synthesis_of_lagging_strand_30: $i > $i).
% 29.32/29.14  tff(decl_73499, type, fn_synthesis_of_lagging_strand_31: $i > $i).
% 29.32/29.14  tff(decl_73500, type, fn_synthesis_of_lagging_strand_32: $i > $i).
% 29.32/29.14  tff(decl_73501, type, fn_synthesis_of_lagging_strand_33: $i > $i).
% 29.32/29.14  tff(decl_73502, type, fn_synthesis_of_lagging_strand_34: $i > $i).
% 29.32/29.14  tff(decl_73503, type, fn_synthesis_of_lagging_strand_35: $i > $i).
% 29.32/29.14  tff(decl_73504, type, fn_synthesis_of_lagging_strand_36: $i > $i).
% 29.32/29.14  tff(decl_73505, type, fn_synthesis_of_lagging_strand_38: $i > $i).
% 29.32/29.14  tff(decl_73506, type, fn_synthesis_of_lagging_strand_39: $i > $i).
% 29.32/29.14  tff(decl_73507, type, fn_synthesis_of_lagging_strand_40: $i > $i).
% 29.32/29.14  tff(decl_73508, type, deoxyribonucleotide_0: $i).
% 29.32/29.14  tff(decl_73509, type, synthesis_0: $i).
% 29.32/29.14  tff(decl_73510, type, 'Synthesis-Of-Leading-Strand': $i).
% 29.32/29.14  tff(decl_73511, type, 'The elongation of the new complementary DNA strand synthesized continually along the template strand toward the replication fork in the mandatory 5\\ - 3\\ direction.': $i).
% 29.32/29.14  tff(decl_73512, type, 'synthesis of leading strand': $i).
% 29.32/29.14  tff(decl_73513, type, 'synthesis-of-leading-strand': $i).
% 29.32/29.14  tff(decl_73514, type, fn_synthesis_of_leading_strand_1: $i > $i).
% 29.32/29.14  tff(decl_73515, type, fn_synthesis_of_leading_strand_11: $i > $i).
% 29.32/29.14  tff(decl_73516, type, fn_synthesis_of_leading_strand_12: $i > $i).
% 29.32/29.14  tff(decl_73517, type, fn_synthesis_of_leading_strand_13: $i > $i).
% 29.32/29.14  tff(decl_73518, type, fn_synthesis_of_leading_strand_14: $i > $i).
% 29.32/29.14  tff(decl_73519, type, fn_synthesis_of_leading_strand_15: $i > $i).
% 29.32/29.14  tff(decl_73520, type, fn_synthesis_of_leading_strand_19: $i > $i).
% 29.32/29.14  tff(decl_73521, type, fn_synthesis_of_leading_strand_20: $i > $i).
% 29.32/29.14  tff(decl_73522, type, fn_synthesis_of_leading_strand_21: $i > $i).
% 29.32/29.14  tff(decl_73523, type, fn_synthesis_of_leading_strand_22: $i > $i).
% 29.32/29.14  tff(decl_73524, type, fn_synthesis_of_leading_strand_23: $i > $i).
% 29.32/29.14  tff(decl_73525, type, fn_synthesis_of_leading_strand_24: $i > $i).
% 29.32/29.14  tff(decl_73526, type, fn_synthesis_of_leading_strand_27: $i > $i).
% 29.32/29.14  tff(decl_73527, type, fn_synthesis_of_leading_strand_29: $i > $i).
% 29.32/29.14  tff(decl_73528, type, fn_synthesis_of_leading_strand_30: $i > $i).
% 29.32/29.14  tff(decl_73529, type, fn_synthesis_of_leading_strand_31: $i > $i).
% 29.32/29.14  tff(decl_73530, type, fn_synthesis_of_leading_strand_32: $i > $i).
% 29.32/29.14  tff(decl_73531, type, fn_synthesis_of_leading_strand_33: $i > $i).
% 29.32/29.14  tff(decl_73532, type, fn_synthesis_of_leading_strand_34: $i > $i).
% 29.32/29.14  tff(decl_73533, type, fn_synthesis_of_leading_strand_35: $i > $i).
% 29.32/29.14  tff(decl_73534, type, fn_synthesis_of_leading_strand_36: $i > $i).
% 29.32/29.14  tff(decl_73535, type, fn_synthesis_of_leading_strand_37: $i > $i).
% 29.32/29.14  tff(decl_73536, type, fn_synthesis_of_leading_strand_38: $i > $i).
% 29.32/29.14  tff(decl_73537, type, fn_synthesis_of_leading_strand_39: $i > $i).
% 29.32/29.14  tff(decl_73538, type, fn_synthesis_of_leading_strand_40: $i > $i).
% 29.32/29.14  tff(decl_73539, type, fn_synthesis_of_leading_strand_41: $i > $i).
% 29.32/29.14  tff(decl_73540, type, fn_synthesis_of_leading_strand_42: $i > $i).
% 29.32/29.14  tff(decl_73541, type, fn_synthesis_of_leading_strand_43: $i > $i).
% 29.32/29.14  tff(decl_73542, type, fn_synthesis_of_leading_strand_44: $i > $i).
% 29.32/29.14  tff(decl_73543, type, fn_synthesis_of_leading_strand_45: $i > $i).
% 29.32/29.14  tff(decl_73544, type, fn_synthesis_of_leading_strand_46: $i > $i).
% 29.32/29.14  tff(decl_73545, type, fn_synthesis_of_leading_strand_47: $i > $i).
% 29.32/29.14  tff(decl_73546, type, fn_synthesis_of_leading_strand_48: $i > $i).
% 29.32/29.14  tff(decl_73547, type, fn_synthesis_of_leading_strand_49: $i > $i).
% 29.32/29.14  tff(decl_73548, type, fn_synthesis_of_leading_strand_50: $i > $i).
% 29.32/29.14  tff(decl_73549, type, fn_synthesis_of_leading_strand_51: $i > $i).
% 29.32/29.14  tff(decl_73550, type, fn_synthesis_of_leading_strand_52: $i > $i).
% 29.32/29.14  tff(decl_73551, type, fn_synthesis_of_leading_strand_53: $i > $i).
% 29.32/29.14  tff(decl_73552, type, fn_synthesis_of_leading_strand_54: $i > $i).
% 29.32/29.14  tff(decl_73553, type, fn_synthesis_of_leading_strand_55: $i > $i).
% 29.32/29.14  tff(decl_73554, type, fn_synthesis_of_leading_strand_56: $i > $i).
% 29.32/29.14  tff(decl_73555, type, fn_synthesis_of_leading_strand_57: $i > $i).
% 29.32/29.14  tff(decl_73556, type, fn_synthesis_of_leading_strand_58: $i > $i).
% 29.32/29.14  tff(decl_73557, type, fn_synthesis_of_leading_strand_59: $i > $i).
% 29.32/29.14  tff(decl_73558, type, fn_synthesis_of_leading_strand_60: $i > $i).
% 29.32/29.14  tff(decl_73559, type, fn_synthesis_of_leading_strand_61: $i > $i).
% 29.32/29.14  tff(decl_73560, type, fn_synthesis_of_leading_strand_62: $i > $i).
% 29.32/29.15  tff(decl_73561, type, fn_synthesis_of_leading_strand_64: $i > $i).
% 29.32/29.15  tff(decl_73562, type, fn_synthesis_of_leading_strand_65: $i > $i).
% 29.32/29.15  tff(decl_73563, type, fn_synthesis_of_leading_strand_66: $i > $i).
% 29.32/29.15  tff(decl_73564, type, fn_synthesis_of_leading_strand_67: $i > $i).
% 29.32/29.15  tff(decl_73565, type, fn_synthesis_of_leading_strand_69: $i > $i).
% 29.32/29.15  tff(decl_73566, type, fn_synthesis_of_leading_strand_70: $i > $i).
% 29.32/29.15  tff(decl_73567, type, fn_synthesis_of_leading_strand_71: $i > $i).
% 29.32/29.15  tff(decl_73568, type, fn_synthesis_of_leading_strand_72: $i > $i).
% 29.32/29.15  tff(decl_73569, type, fn_synthesis_of_leading_strand_73: $i > $i).
% 29.32/29.15  tff(decl_73570, type, fn_synthesis_of_leading_strand_74: $i > $i).
% 29.32/29.15  tff(decl_73571, type, fn_synthesis_of_leading_strand_18: $i > $i).
% 29.32/29.15  tff(decl_73572, type, fn_synthesis_of_leading_strand_17: $i > $i).
% 29.32/29.15  tff(decl_73573, type, fn_synthesis_of_leading_strand_26: $i > $i).
% 29.32/29.15  tff(decl_73574, type, fn_synthesis_of_leading_strand_25: $i > $i).
% 29.32/29.15  tff(decl_73575, type, fn_synthesis_of_leading_strand_16: $i > $i).
% 29.32/29.15  tff(decl_73576, type, fn_synthesis_of_leading_strand_28: $i > $i).
% 29.32/29.15  tff(decl_73577, type, 'Synthesis-Of-Lipid': $i).
% 29.32/29.15  tff(decl_73578, type, 'The production of lipid.': $i).
% 29.32/29.15  tff(decl_73579, type, 'lipid synthesis': $i).
% 29.32/29.15  tff(decl_73580, type, 'lipid-synthesis': $i).
% 29.32/29.15  tff(decl_73581, type, 'synthesis of lipid': $i).
% 29.32/29.15  tff(decl_73582, type, 'synthesis-of-lipid': $i).
% 29.32/29.15  tff(decl_73583, type, synthesis_of_lipid_in_animal_cell_1: $i > $o).
% 29.32/29.15  tff(decl_73584, type, fn_synthesis_of_lipid_in_animal_cell_2: $i > $i).
% 29.32/29.15  tff(decl_73585, type, 'Synthesis-of-Lipid-in-Animal-Cell': $i).
% 29.32/29.15  tff(decl_73586, type, 'The production of lipid molecules occurs in the smooth endoplasmic reticulum.': $i).
% 29.32/29.15  tff(decl_73587, type, 'synthesis of lipid in animal cell': $i).
% 29.32/29.15  tff(decl_73588, type, 'synthesis-of-lipid-in-animal-cell': $i).
% 29.32/29.15  tff(decl_73589, type, fn_synthesis_of_lipid_in_animal_cell_3: $i > $i).
% 29.32/29.15  tff(decl_73590, type, 'Synthesis-Of-Lysosome': $i).
% 29.32/29.15  tff(decl_73591, type, 'A process by which the vesicles detach from the trans face of the golgi apparatus to form lysosomes.': $i).
% 29.32/29.15  tff(decl_73592, type, 'lysosome synthesis': $i).
% 29.32/29.15  tff(decl_73593, type, 'lysosome-synthesis': $i).
% 29.32/29.15  tff(decl_73594, type, 'synthesis of lysosome': $i).
% 29.32/29.15  tff(decl_73595, type, 'synthesis-of-lysosome': $i).
% 29.32/29.15  tff(decl_73596, type, fn_synthesis_of_lysosome_2: $i > $i).
% 29.32/29.15  tff(decl_73597, type, fn_synthesis_of_lysosome_3: $i > $i).
% 29.32/29.15  tff(decl_73598, type, fn_synthesis_of_lysosome_4: $i > $i).
% 29.32/29.15  tff(decl_73599, type, fn_synthesis_of_lysosome_5: $i > $i).
% 29.32/29.15  tff(decl_73600, type, fn_synthesis_of_lysosome_6: $i > $i).
% 29.32/29.15  tff(decl_73601, type, fn_synthesis_of_lysosome_7: $i > $i).
% 29.32/29.15  tff(decl_73602, type, fn_synthesis_of_lysosome_8: $i > $i).
% 29.32/29.15  tff(decl_73603, type, fn_synthesis_of_lysosome_9: $i > $i).
% 29.32/29.15  tff(decl_73604, type, fn_synthesis_of_lysosome_10: $i > $i).
% 29.32/29.15  tff(decl_73605, type, fn_synthesis_of_lysosome_11: $i > $i).
% 29.32/29.15  tff(decl_73606, type, fn_synthesis_of_lysosome_12: $i > $i).
% 29.32/29.15  tff(decl_73607, type, fn_synthesis_of_lysosome_14: $i > $i).
% 29.32/29.15  tff(decl_73608, type, fn_synthesis_of_lysosome_15: $i > $i).
% 29.32/29.15  tff(decl_73609, type, fn_synthesis_of_lysosome_16: $i > $i).
% 29.32/29.15  tff(decl_73610, type, fn_synthesis_of_lysosome_17: $i > $i).
% 29.32/29.15  tff(decl_73611, type, fn_synthesis_of_lysosome_18: $i > $i).
% 29.32/29.15  tff(decl_73612, type, fn_synthesis_of_lysosome_19: $i > $i).
% 29.32/29.15  tff(decl_73613, type, fn_synthesis_of_lysosome_20: $i > $i).
% 29.32/29.15  tff(decl_73614, type, fn_synthesis_of_lysosome_21: $i > $i).
% 29.32/29.15  tff(decl_73615, type, fn_synthesis_of_lysosome_22: $i > $i).
% 29.32/29.15  tff(decl_73616, type, fn_synthesis_of_lysosome_23: $i > $i).
% 29.32/29.15  tff(decl_73617, type, fn_synthesis_of_lysosome_24: $i > $i).
% 29.32/29.15  tff(decl_73618, type, fn_synthesis_of_lysosome_25: $i > $i).
% 29.32/29.15  tff(decl_73619, type, fn_synthesis_of_lysosome_26: $i > $i).
% 29.32/29.15  tff(decl_73620, type, fn_synthesis_of_lysosome_27: $i > $i).
% 29.32/29.15  tff(decl_73621, type, fn_synthesis_of_lysosome_28: $i > $i).
% 29.32/29.15  tff(decl_73622, type, fn_synthesis_of_lysosome_29: $i > $i).
% 29.32/29.15  tff(decl_73623, type, fn_synthesis_of_lysosome_30: $i > $i).
% 29.32/29.15  tff(decl_73624, type, fn_synthesis_of_lysosome_31: $i > $i).
% 29.32/29.15  tff(decl_73625, type, fn_synthesis_of_lysosome_32: $i > $i).
% 29.32/29.15  tff(decl_73626, type, fn_synthesis_of_lysosome_33: $i > $i).
% 29.32/29.15  tff(decl_73627, type, fn_synthesis_of_lysosome_34: $i > $i).
% 29.32/29.15  tff(decl_73628, type, fn_synthesis_of_lysosome_35: $i > $i).
% 29.32/29.15  tff(decl_73629, type, fn_synthesis_of_lysosome_36: $i > $i).
% 29.32/29.15  tff(decl_73630, type, fn_synthesis_of_lysosome_37: $i > $i).
% 29.32/29.15  tff(decl_73631, type, fn_synthesis_of_lysosome_38: $i > $i).
% 29.32/29.15  tff(decl_73632, type, fn_synthesis_of_lysosome_39: $i > $i).
% 29.32/29.15  tff(decl_73633, type, fn_synthesis_of_lysosome_40: $i > $i).
% 29.32/29.15  tff(decl_73634, type, fn_synthesis_of_lysosome_41: $i > $i).
% 29.32/29.15  tff(decl_73635, type, fn_synthesis_of_lysosome_42: $i > $i).
% 29.32/29.15  tff(decl_73636, type, fn_synthesis_of_lysosome_43: $i > $i).
% 29.32/29.15  tff(decl_73637, type, fn_synthesis_of_lysosome_44: $i > $i).
% 29.32/29.15  tff(decl_73638, type, fn_synthesis_of_lysosome_45: $i > $i).
% 29.32/29.15  tff(decl_73639, type, fn_synthesis_of_lysosome_46: $i > $i).
% 29.32/29.15  tff(decl_73640, type, fn_synthesis_of_lysosome_47: $i > $i).
% 29.32/29.15  tff(decl_73641, type, fn_synthesis_of_lysosome_48: $i > $i).
% 29.32/29.15  tff(decl_73642, type, fn_synthesis_of_lysosome_49: $i > $i).
% 29.32/29.15  tff(decl_73643, type, fn_synthesis_of_lysosome_50: $i > $i).
% 29.32/29.15  tff(decl_73644, type, fn_synthesis_of_lysosome_51: $i > $i).
% 29.32/29.15  tff(decl_73645, type, fn_synthesis_of_lysosome_52: $i > $i).
% 29.32/29.15  tff(decl_73646, type, fn_synthesis_of_protein_35: $i > $i).
% 29.32/29.15  tff(decl_73647, type, fn_synthesis_of_lysosome_53: $i > $i).
% 29.32/29.15  tff(decl_73648, type, fn_synthesis_of_lysosome_54: $i > $i).
% 29.32/29.15  tff(decl_73649, type, fn_synthesis_of_lysosome_13: $i > $i).
% 29.32/29.15  tff(decl_73650, type, fn_synthesis_of_lysosome_1: $i > $i).
% 29.32/29.15  tff(decl_73651, type, 'Synthesis-Of-Membrane-Protein': $i).
% 29.32/29.15  tff(decl_73652, type, 'The production of membrane protein.': $i).
% 29.32/29.15  tff(decl_73653, type, 'synthesis of membrane protein': $i).
% 29.32/29.15  tff(decl_73654, type, 'synthesis-of-membrane-protein': $i).
% 29.32/29.15  tff(decl_73655, type, fn_synthesis_of_membrane_protein_1: $i > $i).
% 29.32/29.15  tff(decl_73656, type, fn_synthesis_of_membrane_protein_2: $i > $i).
% 29.32/29.15  tff(decl_73657, type, fn_synthesis_of_membrane_protein_3: $i > $i).
% 29.32/29.15  tff(decl_73658, type, fn_synthesis_of_membrane_protein_4: $i > $i).
% 29.32/29.15  tff(decl_73659, type, fn_synthesis_of_membrane_protein_7: $i > $i).
% 29.32/29.15  tff(decl_73660, type, fn_synthesis_of_membrane_protein_8: $i > $i).
% 29.32/29.15  tff(decl_73661, type, fn_synthesis_of_membrane_protein_9: $i > $i).
% 29.32/29.15  tff(decl_73662, type, fn_synthesis_of_membrane_protein_10: $i > $i).
% 29.32/29.15  tff(decl_73663, type, fn_synthesis_of_membrane_protein_11: $i > $i).
% 29.32/29.15  tff(decl_73664, type, fn_synthesis_of_membrane_protein_12: $i > $i).
% 29.32/29.15  tff(decl_73665, type, fn_synthesis_of_membrane_protein_13: $i > $i).
% 29.32/29.15  tff(decl_73666, type, fn_synthesis_of_membrane_protein_14: $i > $i).
% 29.32/29.15  tff(decl_73667, type, fn_synthesis_of_membrane_protein_15: $i > $i).
% 29.32/29.15  tff(decl_73668, type, fn_synthesis_of_membrane_protein_18: $i > $i).
% 29.32/29.15  tff(decl_73669, type, fn_synthesis_of_membrane_protein_21: $i > $i).
% 29.32/29.15  tff(decl_73670, type, fn_synthesis_of_membrane_protein_22: $i > $i).
% 29.32/29.15  tff(decl_73671, type, fn_synthesis_of_membrane_protein_24: $i > $i).
% 29.32/29.15  tff(decl_73672, type, fn_synthesis_of_membrane_protein_26: $i > $i).
% 29.32/29.15  tff(decl_73673, type, fn_synthesis_of_membrane_protein_27: $i > $i).
% 29.32/29.15  tff(decl_73674, type, fn_synthesis_of_membrane_protein_28: $i > $i).
% 29.32/29.15  tff(decl_73675, type, fn_synthesis_of_membrane_protein_29: $i > $i).
% 29.32/29.15  tff(decl_73676, type, fn_synthesis_of_membrane_protein_30: $i > $i).
% 29.32/29.15  tff(decl_73677, type, fn_synthesis_of_membrane_protein_31: $i > $i).
% 29.32/29.15  tff(decl_73678, type, fn_synthesis_of_membrane_protein_32: $i > $i).
% 29.32/29.15  tff(decl_73679, type, fn_synthesis_of_membrane_protein_33: $i > $i).
% 29.32/29.15  tff(decl_73680, type, fn_synthesis_of_membrane_protein_34: $i > $i).
% 29.32/29.15  tff(decl_73681, type, fn_synthesis_of_membrane_protein_35: $i > $i).
% 29.32/29.15  tff(decl_73682, type, fn_synthesis_of_membrane_protein_6: $i > $i).
% 29.32/29.15  tff(decl_73683, type, 'Synthesis-Of-mRNA': $i).
% 29.32/29.15  tff(decl_73684, type, 'The process of synthesis of mRNA (Messenger-RNA) using a gene on a template DNA strand as the base.': $i).
% 29.32/29.15  tff(decl_73685, type, 'synthesis of messenger rna': $i).
% 29.32/29.15  tff(decl_73686, type, 'synthesis-of-messenger-rna': $i).
% 29.32/29.15  tff(decl_73687, type, 'mrna synthesis': $i).
% 29.32/29.15  tff(decl_73688, type, 'mrna-synthesis': $i).
% 29.32/29.15  tff(decl_73689, type, 'synthesis of mrna': $i).
% 29.32/29.15  tff(decl_73690, type, 'synthesis-of-mrna': $i).
% 29.32/29.15  tff(decl_73691, type, synthesis_of_mrna_in_eukaryote_1: $i > $o).
% 29.32/29.15  tff(decl_73692, type, 'Synthesis-Of-mRNA-In-Eukaryote': $i).
% 29.32/29.15  tff(decl_73693, type, 'The synthesis of mRNA in eukaryote follows the eukaryotic transcription process followed by the RNA processing. The mRNA finally synthesized moves out from the nucleus to the cytoplasm.': $i).
% 29.32/29.15  tff(decl_73694, type, 'synthesis of mrna in eukaryote': $i).
% 29.32/29.15  tff(decl_73695, type, 'synthesis-of-mrna-in-eukaryote': $i).
% 29.32/29.15  tff(decl_73696, type, synthesis_of_rna_in_eukaryote_1: $i > $o).
% 29.32/29.15  tff(decl_73697, type, fn_synthesis_of_mrna_in_eukaryote_1: $i > $i).
% 29.32/29.15  tff(decl_73698, type, fn_synthesis_of_mrna_in_eukaryote_2: $i > $i).
% 29.32/29.15  tff(decl_73699, type, fn_synthesis_of_mrna_in_eukaryote_4: $i > $i).
% 29.32/29.15  tff(decl_73700, type, fn_synthesis_of_mrna_in_eukaryote_6: $i > $i).
% 29.32/29.15  tff(decl_73701, type, fn_synthesis_of_mrna_in_eukaryote_7: $i > $i).
% 29.32/29.15  tff(decl_73702, type, fn_synthesis_of_mrna_in_eukaryote_8: $i > $i).
% 29.32/29.15  tff(decl_73703, type, fn_synthesis_of_mrna_in_eukaryote_9: $i > $i).
% 29.32/29.15  tff(decl_73704, type, fn_synthesis_of_mrna_in_eukaryote_10: $i > $i).
% 29.32/29.15  tff(decl_73705, type, fn_synthesis_of_mrna_in_eukaryote_11: $i > $i).
% 29.32/29.15  tff(decl_73706, type, fn_synthesis_of_mrna_in_eukaryote_12: $i > $i).
% 29.32/29.15  tff(decl_73707, type, fn_synthesis_of_mrna_in_eukaryote_13: $i > $i).
% 29.32/29.15  tff(decl_73708, type, fn_synthesis_of_mrna_in_eukaryote_14: $i > $i).
% 29.32/29.15  tff(decl_73709, type, fn_synthesis_of_mrna_in_eukaryote_15: $i > $i).
% 29.32/29.15  tff(decl_73710, type, fn_synthesis_of_mrna_in_eukaryote_16: $i > $i).
% 29.32/29.15  tff(decl_73711, type, fn_synthesis_of_mrna_in_eukaryote_17: $i > $i).
% 29.32/29.15  tff(decl_73712, type, fn_synthesis_of_mrna_in_eukaryote_18: $i > $i).
% 29.32/29.15  tff(decl_73713, type, fn_synthesis_of_mrna_in_eukaryote_19: $i > $i).
% 29.32/29.15  tff(decl_73714, type, fn_synthesis_of_mrna_in_eukaryote_20: $i > $i).
% 29.32/29.15  tff(decl_73715, type, fn_synthesis_of_mrna_in_eukaryote_21: $i > $i).
% 29.32/29.15  tff(decl_73716, type, fn_synthesis_of_mrna_in_eukaryote_22: $i > $i).
% 29.32/29.15  tff(decl_73717, type, fn_synthesis_of_mrna_in_eukaryote_23: $i > $i).
% 29.32/29.15  tff(decl_73718, type, fn_synthesis_of_mrna_in_eukaryote_24: $i > $i).
% 29.32/29.15  tff(decl_73719, type, fn_synthesis_of_mrna_in_eukaryote_25: $i > $i).
% 29.32/29.15  tff(decl_73720, type, fn_synthesis_of_mrna_in_eukaryote_26: $i > $i).
% 29.32/29.15  tff(decl_73721, type, fn_synthesis_of_mrna_in_eukaryote_27: $i > $i).
% 29.32/29.15  tff(decl_73722, type, fn_synthesis_of_mrna_in_eukaryote_28: $i > $i).
% 29.32/29.15  tff(decl_73723, type, fn_synthesis_of_mrna_in_eukaryote_29: $i > $i).
% 29.32/29.15  tff(decl_73724, type, fn_synthesis_of_mrna_in_eukaryote_30: $i > $i).
% 29.32/29.15  tff(decl_73725, type, fn_synthesis_of_mrna_in_eukaryote_31: $i > $i).
% 29.32/29.15  tff(decl_73726, type, fn_synthesis_of_mrna_in_eukaryote_32: $i > $i).
% 29.32/29.15  tff(decl_73727, type, fn_synthesis_of_mrna_in_eukaryote_33: $i > $i).
% 29.32/29.15  tff(decl_73728, type, fn_synthesis_of_mrna_in_eukaryote_34: $i > $i).
% 29.32/29.15  tff(decl_73729, type, fn_synthesis_of_mrna_in_eukaryote_35: $i > $i).
% 29.32/29.15  tff(decl_73730, type, fn_synthesis_of_mrna_in_eukaryote_36: $i > $i).
% 29.32/29.15  tff(decl_73731, type, fn_synthesis_of_mrna_in_eukaryote_37: $i > $i).
% 29.32/29.15  tff(decl_73732, type, fn_water_molecule_70: $i > $i).
% 29.32/29.15  tff(decl_73733, type, fn_synthesis_of_rna_in_eukaryote_7: $i > $i).
% 29.32/29.15  tff(decl_73734, type, fn_synthesis_of_mrna_in_eukaryote_38: $i > $i).
% 29.32/29.15  tff(decl_73735, type, fn_synthesis_of_rna_in_eukaryote_15: $i > $i).
% 29.32/29.15  tff(decl_73736, type, fn_synthesis_of_rna_in_eukaryote_4: $i > $i).
% 29.32/29.15  tff(decl_73737, type, fn_synthesis_of_rna_in_eukaryote_6: $i > $i).
% 29.32/29.15  tff(decl_73738, type, fn_synthesis_of_rna_in_eukaryote_5: $i > $i).
% 29.32/29.15  tff(decl_73739, type, fn_synthesis_of_rna_in_eukaryote_8: $i > $i).
% 29.32/29.15  tff(decl_73740, type, fn_synthesis_of_rna_in_eukaryote_3: $i > $i).
% 29.32/29.15  tff(decl_73741, type, fn_synthesis_of_rna_in_eukaryote_11: $i > $i).
% 29.32/29.15  tff(decl_73742, type, fn_synthesis_of_rna_in_eukaryote_12: $i > $i).
% 29.32/29.15  tff(decl_73743, type, fn_synthesis_of_rna_in_eukaryote_13: $i > $i).
% 29.32/29.15  tff(decl_73744, type, fn_synthesis_of_rna_in_eukaryote_14: $i > $i).
% 29.32/29.15  tff(decl_73745, type, fn_synthesis_of_mrna_in_prokaryote_3: $i > $i).
% 29.32/29.15  tff(decl_73746, type, 'Synthesis-Of-mRNA-In-Prokaryote': $i).
% 29.32/29.15  tff(decl_73747, type, 'Transcription in a prokaryotic cell where an mRNA molecule that is complementary to the DNA template is synthesized and used directly in translation omitting post-transcriptional modification as in eukaryotic cells.': $i).
% 29.32/29.15  tff(decl_73748, type, 'transcription in prokaryote': $i).
% 29.32/29.15  tff(decl_73749, type, 'transcription-in-prokaryote': $i).
% 29.32/29.15  tff(decl_73750, type, 'synthesis of mrna in prokaryote': $i).
% 29.32/29.15  tff(decl_73751, type, 'synthesis-of-mrna-in-prokaryote': $i).
% 29.32/29.15  tff(decl_73752, type, synthesis_of_nad_plus_1: $i > $o).
% 29.32/29.15  tff(decl_73753, type, 'Synthesis-Of-NAD-Plus': $i).
% 29.32/29.15  tff(decl_73754, type, 'The biological synthesis of NAD+ either de novo from amino acids or from recycled components such as nicotinamide.': $i).
% 29.32/29.15  tff(decl_73755, type, 'synthesis of nad plus': $i).
% 29.32/29.15  tff(decl_73756, type, 'synthesis-of-nad-plus': $i).
% 29.32/29.15  tff(decl_73757, type, fn_synthesis_of_nad_plus_1: $i > $i).
% 29.32/29.15  tff(decl_73758, type, fn_synthesis_of_nad_plus_2: $i > $i).
% 29.32/29.15  tff(decl_73759, type, fn_synthesis_of_nad_plus_3: $i > $i).
% 29.32/29.15  tff(decl_73760, type, synthesis_of_nadh_1: $i > $o).
% 29.32/29.15  tff(decl_73761, type, 'Synthesis-Of-NADH': $i).
% 29.32/29.15  tff(decl_73762, type, 'The formation of NADH by the reduction of NAD+.': $i).
% 29.32/29.15  tff(decl_73763, type, 'nadh synthesis': $i).
% 29.32/29.15  tff(decl_73764, type, 'nadh-synthesis': $i).
% 29.32/29.15  tff(decl_73765, type, 'synthesis of nadh': $i).
% 29.32/29.15  tff(decl_73766, type, 'synthesis-of-nadh': $i).
% 29.32/29.15  tff(decl_73767, type, fn_synthesis_of_nadh_1: $i > $i).
% 29.32/29.15  tff(decl_73768, type, fn_synthesis_of_nadh_2: $i > $i).
% 29.32/29.15  tff(decl_73769, type, fn_synthesis_of_nadh_3: $i > $i).
% 29.32/29.15  tff(decl_73770, type, 'Synthesis-Of-Nucleic-Acid': $i).
% 29.32/29.15  tff(decl_73771, type, 'The production of nucleic acid.': $i).
% 29.32/29.15  tff(decl_73772, type, 'synthesis of polynucleotide': $i).
% 29.32/29.15  tff(decl_73773, type, 'polynucleotide synthesis': $i).
% 29.32/29.15  tff(decl_73774, type, 'polynucleotide-synthesis': $i).
% 29.32/29.15  tff(decl_73775, type, 'synthesis-of-polynucleotide': $i).
% 29.32/29.15  tff(decl_73776, type, 'synthesis of nucleic acid': $i).
% 29.32/29.15  tff(decl_73777, type, 'synthesis-of-nucleic-acid': $i).
% 29.32/29.15  tff(decl_73778, type, fn_synthesis_of_nucleic_acid_3: $i > $i).
% 29.32/29.15  tff(decl_73779, type, fn_synthesis_of_nucleic_acid_4: $i > $i).
% 29.32/29.15  tff(decl_73780, type, fn_synthesis_of_nucleic_acid_5: $i > $i).
% 29.32/29.15  tff(decl_73781, type, 'Synthesis-Of-Organelle': $i).
% 29.32/29.15  tff(decl_73782, type, 'The creation of organelles and cellular parts within cells.': $i).
% 29.32/29.15  tff(decl_73783, type, 'organelle synthesis': $i).
% 29.32/29.15  tff(decl_73784, type, 'organelle-synthesis': $i).
% 29.32/29.15  tff(decl_73785, type, 'synthesis of organelle': $i).
% 29.32/29.15  tff(decl_73786, type, 'synthesis-of-organelle': $i).
% 29.32/29.15  tff(decl_73787, type, fn_synthesis_of_organelle_2: $i > $i).
% 29.32/29.15  tff(decl_73788, type, 'Synthesis-Of-Organic-Molecule': $i).
% 29.32/29.15  tff(decl_73789, type, 'The production of a carbon-containing molecule.': $i).
% 29.32/29.15  tff(decl_73790, type, 'synthesis of organic molecule': $i).
% 29.32/29.15  tff(decl_73791, type, 'synthesis-of-organic-molecule': $i).
% 29.32/29.15  tff(decl_73792, type, synthesis_of_platelet_derived_growth_factor_1: $i > $o).
% 29.32/29.15  tff(decl_73793, type, 'Synthesis-Of-Platelet-Derived-Growth-Factor': $i).
% 29.32/29.15  tff(decl_73794, type, 'The process of production of platelet derived growth factor, an important signaling molecule in wound healing.': $i).
% 29.32/29.15  tff(decl_73795, type, 'synthesis of platelet derived growth factor': $i).
% 29.32/29.15  tff(decl_73796, type, 'synthesis-of-platelet-derived-growth-factor': $i).
% 29.32/29.15  tff(decl_73797, type, fn_synthesis_of_platelet_derived_growth_factor_1: $i > $i).
% 29.32/29.15  tff(decl_73798, type, fn_synthesis_of_platelet_derived_growth_factor_2: $i > $i).
% 29.32/29.15  tff(decl_73799, type, 'Synthesis-Of-Protein': $i).
% 29.32/29.15  tff(decl_73800, type, 'The process by which a protein molecule is synthesized from amino acids at a ribosome.': $i).
% 29.32/29.15  tff(decl_73801, type, 'protein synthesis': $i).
% 29.32/29.15  tff(decl_73802, type, 'protein-synthesis': $i).
% 29.32/29.15  tff(decl_73803, type, 'synthesis of protein': $i).
% 29.32/29.15  tff(decl_73804, type, 'synthesis-of-protein': $i).
% 29.32/29.15  tff(decl_73805, type, fn_synthesis_of_protein_18: $i > $i).
% 29.32/29.15  tff(decl_73806, type, fn_synthesis_of_protein_23: $i > $i).
% 29.32/29.15  tff(decl_73807, type, fn_synthesis_of_protein_24: $i > $i).
% 29.32/29.15  tff(decl_73808, type, fn_synthesis_of_protein_25: $i > $i).
% 29.32/29.15  tff(decl_73809, type, fn_synthesis_of_protein_26: $i > $i).
% 29.32/29.15  tff(decl_73810, type, fn_synthesis_of_protein_32: $i > $i).
% 29.32/29.15  tff(decl_73811, type, fn_synthesis_of_protein_33: $i > $i).
% 29.32/29.15  tff(decl_73812, type, synthesis_of_protein_in_eukaryotes_1: $i > $o).
% 29.32/29.15  tff(decl_73813, type, 'Synthesis-Of-Protein-in-Eukaryotes': $i).
% 29.32/29.15  tff(decl_73814, type, 'The production of functional proteins from polypeptides in eukayotes.': $i).
% 29.32/29.15  tff(decl_73815, type, 'eukaryotic protein synthesis': $i).
% 29.32/29.15  tff(decl_73816, type, 'eukaryotic-protein-synthesis': $i).
% 29.32/29.15  tff(decl_73817, type, 'synthesis of protein in eukaryote': $i).
% 29.32/29.15  tff(decl_73818, type, 'synthesis-of-protein-in-eukaryote': $i).
% 29.32/29.15  tff(decl_73819, type, fn_synthesis_of_protein_in_eukaryotes_1: $i > $i).
% 29.32/29.15  tff(decl_73820, type, fn_synthesis_of_protein_in_eukaryotes_2: $i > $i).
% 29.32/29.15  tff(decl_73821, type, fn_synthesis_of_protein_in_eukaryotes_3: $i > $i).
% 29.32/29.15  tff(decl_73822, type, fn_synthesis_of_protein_in_eukaryotes_4: $i > $i).
% 29.32/29.15  tff(decl_73823, type, fn_synthesis_of_protein_in_eukaryotes_5: $i > $i).
% 29.32/29.15  tff(decl_73824, type, 'Synthesis-Of-Ribosomal-Subunit': $i).
% 29.32/29.15  tff(decl_73825, type, 'The formation of a ribosomal subunit that is composed of proteins and one or more rRNAs.': $i).
% 29.32/29.15  tff(decl_73826, type, 'synthesis of ribosomal subunit': $i).
% 29.32/29.15  tff(decl_73827, type, 'synthesis-of-ribosomal-subunit': $i).
% 29.32/29.15  tff(decl_73828, type, fn_synthesis_of_ribosomal_subunit_1: $i > $i).
% 29.32/29.15  tff(decl_73829, type, fn_synthesis_of_ribosomal_subunit_3: $i > $i).
% 29.32/29.15  tff(decl_73830, type, fn_synthesis_of_ribosomal_subunit_4: $i > $i).
% 29.32/29.15  tff(decl_73831, type, fn_synthesis_of_ribosomal_subunit_5: $i > $i).
% 29.32/29.15  tff(decl_73832, type, fn_synthesis_of_ribosomal_subunit_6: $i > $i).
% 29.32/29.15  tff(decl_73833, type, fn_synthesis_of_ribosomal_subunit_7: $i > $i).
% 29.32/29.15  tff(decl_73834, type, synthesis_of_ribosome_1: $i > $o).
% 29.32/29.15  tff(decl_73835, type, 'Synthesis-Of-Ribosome': $i).
% 29.32/29.15  tff(decl_73836, type, 'A ribosome is an organelle found in the cytoplasm. The ribosomal subunits pass through the nuclear pores to the cytoplasm, where they can combine to form ribosomes.': $i).
% 29.32/29.15  tff(decl_73837, type, 'ribosome synthesis': $i).
% 29.32/29.15  tff(decl_73838, type, 'ribosome-synthesis': $i).
% 29.32/29.15  tff(decl_73839, type, 'synthesis of ribosome': $i).
% 29.32/29.15  tff(decl_73840, type, 'synthesis-of-ribosome': $i).
% 29.32/29.15  tff(decl_73841, type, fn_synthesis_of_ribosome_1: $i > $i).
% 29.32/29.15  tff(decl_73842, type, fn_synthesis_of_ribosome_2: $i > $i).
% 29.32/29.15  tff(decl_73843, type, fn_synthesis_of_ribosome_3: $i > $i).
% 29.32/29.15  tff(decl_73844, type, fn_synthesis_of_ribosome_4: $i > $i).
% 29.32/29.15  tff(decl_73845, type, fn_synthesis_of_ribosome_5: $i > $i).
% 29.32/29.15  tff(decl_73846, type, fn_synthesis_of_ribosome_6: $i > $i).
% 29.32/29.15  tff(decl_73847, type, synthesis_of_ribosome_in_eukaryotes_1: $i > $o).
% 29.32/29.15  tff(decl_73848, type, 'Synthesis-Of-Ribosome-In-Eukaryotes': $i).
% 29.32/29.15  tff(decl_73849, type, 'The formation of a complete ribosome composed of a large and small subunit that join to form a functional ribosome when they attach to an mRNA molecule.': $i).
% 29.32/29.15  tff(decl_73850, type, 'synthesis of ribosome in eukaryote': $i).
% 29.32/29.15  tff(decl_73851, type, 'synthesis-of-ribosome-in-eukaryote': $i).
% 29.32/29.15  tff(decl_73852, type, fn_synthesis_of_ribosome_in_eukaryotes_1: $i > $i).
% 29.32/29.15  tff(decl_73853, type, fn_synthesis_of_ribosome_in_eukaryotes_2: $i > $i).
% 29.32/29.15  tff(decl_73854, type, fn_synthesis_of_ribosome_in_eukaryotes_3: $i > $i).
% 29.32/29.15  tff(decl_73855, type, fn_synthesis_of_ribosome_in_eukaryotes_4: $i > $i).
% 29.32/29.15  tff(decl_73856, type, fn_synthesis_of_ribosome_in_eukaryotes_5: $i > $i).
% 29.32/29.15  tff(decl_73857, type, fn_synthesis_of_ribosome_in_eukaryotes_6: $i > $i).
% 29.32/29.15  tff(decl_73858, type, fn_synthesis_of_ribosome_in_eukaryotes_7: $i > $i).
% 29.32/29.15  tff(decl_73859, type, fn_synthesis_of_ribosome_in_eukaryotes_8: $i > $i).
% 29.32/29.15  tff(decl_73860, type, fn_synthesis_of_ribosome_in_eukaryotes_9: $i > $i).
% 29.32/29.15  tff(decl_73861, type, fn_synthesis_of_ribosome_in_eukaryotes_10: $i > $i).
% 29.32/29.15  tff(decl_73862, type, fn_synthesis_of_ribosome_in_eukaryotes_11: $i > $i).
% 29.32/29.15  tff(decl_73863, type, fn_synthesis_of_ribosome_in_eukaryotes_12: $i > $i).
% 29.32/29.15  tff(decl_73864, type, fn_synthesis_of_ribosome_in_eukaryotes_13: $i > $i).
% 29.32/29.15  tff(decl_73865, type, fn_synthesis_of_ribosome_in_eukaryotes_14: $i > $i).
% 29.32/29.15  tff(decl_73866, type, fn_synthesis_of_ribosome_in_eukaryotes_15: $i > $i).
% 29.32/29.15  tff(decl_73867, type, fn_synthesis_of_ribosome_in_eukaryotes_16: $i > $i).
% 29.32/29.15  tff(decl_73868, type, fn_synthesis_of_ribosome_in_eukaryotes_17: $i > $i).
% 29.32/29.15  tff(decl_73869, type, fn_synthesis_of_ribosome_in_eukaryotes_18: $i > $i).
% 29.32/29.15  tff(decl_73870, type, 'Synthesis-Of-RNA': $i).
% 29.32/29.15  tff(decl_73871, type, 'The formation of RNA molecules from genes that are transcribed from the organisms chromosomes.': $i).
% 29.32/29.15  tff(decl_73872, type, 'rna synthesis': $i).
% 29.32/29.15  tff(decl_73873, type, 'rna-synthesis': $i).
% 29.32/29.15  tff(decl_73874, type, 'synthesis of rna': $i).
% 29.32/29.15  tff(decl_73875, type, 'synthesis-of-rna': $i).
% 29.32/29.15  tff(decl_73876, type, fn_synthesis_of_rna_1: $i > $i).
% 29.32/29.15  tff(decl_73877, type, fn_synthesis_of_rna_5: $i > $i).
% 29.32/29.15  tff(decl_73878, type, fn_synthesis_of_rna_6: $i > $i).
% 29.32/29.15  tff(decl_73879, type, fn_synthesis_of_rna_7: $i > $i).
% 29.32/29.15  tff(decl_73880, type, 'Synthesis-Of-RNA-In-Eukaryote': $i).
% 29.32/29.15  tff(decl_73881, type, 'The formation of rRNA molecules by the transcription of rRNA genes.': $i).
% 29.32/29.15  tff(decl_73882, type, 'synthesis of rna in eukaryote': $i).
% 29.32/29.15  tff(decl_73883, type, 'synthesis-of-rna-in-eukaryote': $i).
% 29.32/29.15  tff(decl_73884, type, fn_synthesis_of_rna_in_eukaryote_1: $i > $i).
% 29.32/29.15  tff(decl_73885, type, fn_synthesis_of_rna_in_eukaryote_2: $i > $i).
% 29.32/29.15  tff(decl_73886, type, fn_synthesis_of_rna_in_eukaryote_9: $i > $i).
% 29.32/29.15  tff(decl_73887, type, fn_synthesis_of_rna_in_eukaryote_10: $i > $i).
% 29.32/29.15  tff(decl_73888, type, 'Synthesis-Of-rRNA': $i).
% 29.32/29.15  tff(decl_73889, type, 'The process of synthesis of rRNA (Ribosomal-RNA) using a gene on a template DNA strand as the base.': $i).
% 29.32/29.15  tff(decl_73890, type, 'synthesis of ribosomal rna': $i).
% 29.32/29.15  tff(decl_73891, type, 'synthesis-of-ribosomal-rna': $i).
% 29.32/29.15  tff(decl_73892, type, 'rrna synthesis': $i).
% 29.32/29.15  tff(decl_73893, type, 'rrna-synthesis': $i).
% 29.32/29.15  tff(decl_73894, type, 'synthesis of rrna': $i).
% 29.32/29.15  tff(decl_73895, type, 'synthesis-of-rrna': $i).
% 29.32/29.15  tff(decl_73896, type, fn_synthesis_of_rrna_2: $i > $i).
% 29.32/29.15  tff(decl_73897, type, fn_synthesis_of_rrna_3: $i > $i).
% 29.32/29.15  tff(decl_73898, type, synthesis_of_rrna_in_eukaryote_1: $i > $o).
% 29.32/29.15  tff(decl_73899, type, 'Synthesis-of-rRNA-In-Eukaryote': $i).
% 29.32/29.15  tff(decl_73900, type, 'In eukaryotic cells of plants and animals the 18S and 28S rRNA molecules also transcribed by rDNA of nucleolar organizer (No) region of chromo some and nucleolus acts as a site of synthesis and maturation of these rRNA molecules.  5S rRNA is transcribed by rDNA occur outside the nucleolar organizer region.': $i).
% 29.32/29.15  tff(decl_73901, type, 'synthesis of rrna in eukaryote': $i).
% 29.32/29.15  tff(decl_73902, type, 'synthesis-of-rrna-in-eukaryote': $i).
% 29.32/29.15  tff(decl_73903, type, fn_synthesis_of_rrna_in_eukaryote_2: $i > $i).
% 29.32/29.15  tff(decl_73904, type, fn_synthesis_of_rrna_in_eukaryote_3: $i > $i).
% 29.32/29.15  tff(decl_73905, type, fn_synthesis_of_rrna_in_eukaryote_4: $i > $i).
% 29.32/29.15  tff(decl_73906, type, fn_synthesis_of_rrna_in_eukaryote_5: $i > $i).
% 29.32/29.15  tff(decl_73907, type, fn_synthesis_of_rrna_in_eukaryote_6: $i > $i).
% 29.32/29.15  tff(decl_73908, type, fn_synthesis_of_rrna_in_eukaryote_7: $i > $i).
% 29.32/29.15  tff(decl_73909, type, fn_synthesis_of_rrna_in_eukaryote_8: $i > $i).
% 29.32/29.15  tff(decl_73910, type, fn_synthesis_of_rrna_in_eukaryote_9: $i > $i).
% 29.32/29.15  tff(decl_73911, type, fn_synthesis_of_rrna_in_eukaryote_10: $i > $i).
% 29.32/29.15  tff(decl_73912, type, fn_synthesis_of_rrna_in_eukaryote_11: $i > $i).
% 29.32/29.15  tff(decl_73913, type, fn_synthesis_of_rrna_in_eukaryote_12: $i > $i).
% 29.32/29.15  tff(decl_73914, type, fn_synthesis_of_rrna_in_eukaryote_13: $i > $i).
% 29.32/29.15  tff(decl_73915, type, fn_synthesis_of_rrna_in_eukaryote_14: $i > $i).
% 29.32/29.15  tff(decl_73916, type, fn_synthesis_of_rrna_in_eukaryote_15: $i > $i).
% 29.32/29.15  tff(decl_73917, type, fn_synthesis_of_rrna_in_eukaryote_16: $i > $i).
% 29.32/29.15  tff(decl_73918, type, fn_synthesis_of_rrna_in_eukaryote_17: $i > $i).
% 29.32/29.15  tff(decl_73919, type, fn_synthesis_of_rrna_in_eukaryote_18: $i > $i).
% 29.32/29.15  tff(decl_73920, type, fn_synthesis_of_rrna_in_eukaryote_19: $i > $i).
% 29.32/29.15  tff(decl_73921, type, fn_synthesis_of_rrna_in_eukaryote_20: $i > $i).
% 29.32/29.15  tff(decl_73922, type, fn_synthesis_of_rrna_in_eukaryote_21: $i > $i).
% 29.32/29.15  tff(decl_73923, type, fn_synthesis_of_rrna_in_eukaryote_22: $i > $i).
% 29.32/29.15  tff(decl_73924, type, fn_synthesis_of_rrna_in_eukaryote_23: $i > $i).
% 29.32/29.15  tff(decl_73925, type, fn_synthesis_of_rrna_in_eukaryote_24: $i > $i).
% 29.32/29.15  tff(decl_73926, type, fn_synthesis_of_rrna_in_eukaryote_25: $i > $i).
% 29.32/29.15  tff(decl_73927, type, fn_synthesis_of_rrna_in_eukaryote_26: $i > $i).
% 29.32/29.15  tff(decl_73928, type, fn_synthesis_of_rrna_in_eukaryote_27: $i > $i).
% 29.32/29.15  tff(decl_73929, type, fn_synthesis_of_rrna_in_eukaryote_28: $i > $i).
% 29.32/29.15  tff(decl_73930, type, fn_synthesis_of_rrna_in_eukaryote_29: $i > $i).
% 29.32/29.15  tff(decl_73931, type, synthesis_of_sex_hormone_1: $i > $o).
% 29.32/29.15  tff(decl_73932, type, fn_synthesis_of_sex_hormone_5: $i > $i).
% 29.32/29.15  tff(decl_73933, type, 'Synthesis-of-Sex-Hormone': $i).
% 29.32/29.15  tff(decl_73934, type, 'The process of synthesis of sex-hormone is called synthesis of sex hormone.': $i).
% 29.32/29.15  tff(decl_73935, type, 'synthesis of sex hormone': $i).
% 29.32/29.15  tff(decl_73936, type, 'synthesis-of-sex-hormone': $i).
% 29.32/29.15  tff(decl_73937, type, fn_synthesis_of_sex_hormone_2: $i > $i).
% 29.32/29.15  tff(decl_73938, type, fn_synthesis_of_sex_hormone_4: $i > $i).
% 29.32/29.15  tff(decl_73939, type, fn_synthesis_of_sex_hormone_6: $i > $i).
% 29.32/29.15  tff(decl_73940, type, fn_synthesis_of_sex_hormone_7: $i > $i).
% 29.32/29.15  tff(decl_73941, type, synthesis_of_starch_1: $i > $o).
% 29.32/29.15  tff(decl_73942, type, 'Synthesis-Of-Starch': $i).
% 29.32/29.15  tff(decl_73943, type, 'The enzymatic process of making starch, a polysaccharide, from monosaccharide monomers of glucose.': $i).
% 29.32/29.15  tff(decl_73944, type, 'starch synthesis': $i).
% 29.32/29.15  tff(decl_73945, type, 'starch-synthesis': $i).
% 29.32/29.15  tff(decl_73946, type, 'synthesis of starch': $i).
% 29.32/29.15  tff(decl_73947, type, 'synthesis-of-starch': $i).
% 29.32/29.15  tff(decl_73948, type, fn_synthesis_of_starch_1: $i > $i).
% 29.32/29.15  tff(decl_73949, type, fn_synthesis_of_starch_2: $i > $i).
% 29.32/29.15  tff(decl_73950, type, fn_synthesis_of_starch_3: $i > $i).
% 29.32/29.15  tff(decl_73951, type, fn_synthesis_of_starch_4: $i > $i).
% 29.32/29.15  tff(decl_73952, type, fn_synthesis_of_starch_5: $i > $i).
% 29.32/29.15  tff(decl_73953, type, fn_synthesis_of_starch_6: $i > $i).
% 29.32/29.15  tff(decl_73954, type, fn_synthesis_of_starch_7: $i > $i).
% 29.32/29.15  tff(decl_73955, type, fn_synthesis_of_starch_8: $i > $i).
% 29.32/29.15  tff(decl_73956, type, synthesis_of_steroid_1: $i > $o).
% 29.32/29.15  tff(decl_73957, type, fn_synthesis_of_steroid_2: $i > $i).
% 29.32/29.15  tff(decl_73958, type, 'Synthesis-of-Steroid': $i).
% 29.32/29.15  tff(decl_73959, type, 'The process of producing the specialized lipids called steroids.': $i).
% 29.32/29.15  tff(decl_73960, type, 'steroid synthesis': $i).
% 29.32/29.15  tff(decl_73961, type, 'steroid-synthesis': $i).
% 29.32/29.15  tff(decl_73962, type, 'synthesis of steroid': $i).
% 29.32/29.15  tff(decl_73963, type, 'synthesis-of-steroid': $i).
% 29.32/29.15  tff(decl_73964, type, fn_synthesis_of_steroid_3: $i > $i).
% 29.32/29.15  tff(decl_73965, type, 'Synthesis-Of-tRNA': $i).
% 29.32/29.15  tff(decl_73966, type, 'The process of synthesis of tRNA (Transfer-RNA) using a gene on a template DNA strand as the base.': $i).
% 29.32/29.15  tff(decl_73967, type, 'synthesis of transfer rna': $i).
% 29.32/29.15  tff(decl_73968, type, 'synthesis-of-transfer-rna': $i).
% 29.32/29.15  tff(decl_73969, type, 'trna synthesis': $i).
% 29.32/29.15  tff(decl_73970, type, 'trna-synthesis': $i).
% 29.32/29.15  tff(decl_73971, type, 'synthesis of trna': $i).
% 29.32/29.15  tff(decl_73972, type, 'synthesis-of-trna': $i).
% 29.32/29.15  tff(decl_73973, type, synthesis_of_trna_in_eukaryote_1: $i > $o).
% 29.32/29.15  tff(decl_73974, type, 'Synthesis-of-tRNA-In-Eukaryote': $i).
% 29.32/29.15  tff(decl_73975, type, 'The synthesis of tRNA in eukaryote follows the eukaryotic transcription process followed by the RNA processing. The tRNA finally synthesized moves out from the nucleus to the cytoplasm.': $i).
% 29.32/29.15  tff(decl_73976, type, 'synthesis of trna in eukaryote': $i).
% 29.32/29.15  tff(decl_73977, type, 'synthesis-of-trna-in-eukaryote': $i).
% 29.32/29.15  tff(decl_73978, type, fn_synthesis_of_trna_in_eukaryote_2: $i > $i).
% 29.32/29.15  tff(decl_73979, type, fn_synthesis_of_trna_in_eukaryote_3: $i > $i).
% 29.32/29.15  tff(decl_73980, type, fn_synthesis_of_trna_in_eukaryote_5: $i > $i).
% 29.32/29.15  tff(decl_73981, type, fn_synthesis_of_trna_in_eukaryote_6: $i > $i).
% 29.32/29.15  tff(decl_73982, type, fn_synthesis_of_trna_in_eukaryote_7: $i > $i).
% 29.32/29.15  tff(decl_73983, type, fn_synthesis_of_trna_in_eukaryote_8: $i > $i).
% 29.32/29.15  tff(decl_73984, type, fn_synthesis_of_trna_in_eukaryote_9: $i > $i).
% 29.32/29.15  tff(decl_73985, type, fn_synthesis_of_trna_in_eukaryote_10: $i > $i).
% 29.32/29.15  tff(decl_73986, type, fn_synthesis_of_trna_in_eukaryote_11: $i > $i).
% 29.32/29.15  tff(decl_73987, type, fn_synthesis_of_trna_in_eukaryote_12: $i > $i).
% 29.32/29.15  tff(decl_73988, type, fn_synthesis_of_trna_in_eukaryote_13: $i > $i).
% 29.32/29.15  tff(decl_73989, type, fn_synthesis_of_trna_in_eukaryote_14: $i > $i).
% 29.32/29.15  tff(decl_73990, type, fn_synthesis_of_trna_in_eukaryote_15: $i > $i).
% 29.32/29.15  tff(decl_73991, type, fn_synthesis_of_trna_in_eukaryote_16: $i > $i).
% 29.32/29.15  tff(decl_73992, type, fn_synthesis_of_trna_in_eukaryote_17: $i > $i).
% 29.32/29.15  tff(decl_73993, type, fn_synthesis_of_trna_in_eukaryote_18: $i > $i).
% 29.32/29.15  tff(decl_73994, type, fn_synthesis_of_trna_in_eukaryote_19: $i > $i).
% 29.32/29.15  tff(decl_73995, type, fn_synthesis_of_trna_in_eukaryote_20: $i > $i).
% 29.32/29.15  tff(decl_73996, type, fn_synthesis_of_trna_in_eukaryote_21: $i > $i).
% 29.32/29.15  tff(decl_73997, type, fn_synthesis_of_trna_in_eukaryote_4: $i > $i).
% 29.32/29.15  tff(decl_73998, type, 'Synthesis-Of-Vacuole': $i).
% 29.32/29.15  tff(decl_73999, type, 'A vacuole is formed by pinching off the surface of an endoplasmic reticulum and golgi-apparatus.': $i).
% 29.32/29.15  tff(decl_74000, type, 'vacuole synthesis': $i).
% 29.32/29.15  tff(decl_74001, type, 'vacuole-synthesis': $i).
% 29.32/29.15  tff(decl_74002, type, 'synthesis of vacuole': $i).
% 29.32/29.15  tff(decl_74003, type, 'synthesis-of-vacuole': $i).
% 29.32/29.15  tff(decl_74004, type, fn_synthesis_of_vacuole_1: $i > $i).
% 29.32/29.15  tff(decl_74005, type, fn_synthesis_of_vacuole_2: $i > $i).
% 29.32/29.15  tff(decl_74006, type, fn_synthesis_of_vacuole_3: $i > $i).
% 29.32/29.15  tff(decl_74007, type, fn_synthesis_of_vacuole_4: $i > $i).
% 29.32/29.15  tff(decl_74008, type, fn_synthesis_of_vacuole_6: $i > $i).
% 29.32/29.15  tff(decl_74009, type, fn_synthesis_of_vacuole_7: $i > $i).
% 29.32/29.15  tff(decl_74010, type, fn_synthesis_of_vacuole_9: $i > $i).
% 29.32/29.15  tff(decl_74011, type, 'Synthesis-Reaction': $i).
% 29.32/29.15  tff(decl_74012, type, 'Synthesis reactions are reactions that produce new molecules from two or more reactants.': $i).
% 29.32/29.15  tff(decl_74013, type, 'reaction of synthesis': $i).
% 29.32/29.15  tff(decl_74014, type, 'synthesis reaction': $i).
% 29.32/29.15  tff(decl_74015, type, 'synthesis-reaction': $i).
% 29.32/29.15  tff(decl_74016, type, synthetic_endorphins_1: $i > $o).
% 29.32/29.15  tff(decl_74017, type, 'Synthetic-Endorphins': $i).
% 29.32/29.15  tff(decl_74018, type, 'Certain opiates  which attach to and mimic the effects of naturally occuring endorphins.': $i).
% 29.32/29.15  tff(decl_74019, type, 'synthetic endorphins': $i).
% 29.32/29.15  tff(decl_74020, type, 'synthetic endorphin': $i).
% 29.32/29.15  tff(decl_74021, type, 'synthetic-endorphin': $i).
% 29.32/29.15  tff(decl_74022, type, 'Syringe': $i).
% 29.32/29.15  tff(decl_74023, type, 'A device used for injecting or drawing fluids through a membrane.': $i).
% 29.32/29.15  tff(decl_74024, type, syringe: $i).
% 29.32/29.15  tff(decl_74025, type, 'System': $i).
% 29.32/29.15  tff(decl_74026, type, system: $i).
% 29.32/29.15  tff(decl_74027, type, 'Systematics': $i).
% 29.32/29.15  tff(decl_74028, type, 'The scientific study of the classification of organisms and determination of the evolutionary relationships among organisms.': $i).
% 29.32/29.15  tff(decl_74029, type, systematics: $i).
% 29.32/29.15  tff(decl_74030, type, systemic_acquired_resistance_1: $i > $o).
% 29.32/29.15  tff(decl_74031, type, 'Systemic-Acquired-Resistance': $i).
% 29.32/29.15  tff(decl_74032, type, 'Response in plants which have been infected by a pathogen that prevents further infection by that pathogen.': $i).
% 29.32/29.15  tff(decl_74033, type, 'systemic acquired resistance': $i).
% 29.32/29.15  tff(decl_74034, type, 'systemic-acquired-resistance': $i).
% 29.32/29.15  tff(decl_74035, type, systemic_circuit_1: $i > $o).
% 29.32/29.15  tff(decl_74036, type, 'Systemic-Circuit': $i).
% 29.32/29.15  tff(decl_74037, type, 'The branch of the circulatory system that pumps oxygenated blood to all organs and tissues of the body.': $i).
% 29.32/29.15  tff(decl_74038, type, 'systemic circuit': $i).
% 29.32/29.15  tff(decl_74039, type, 'systemic-circuit': $i).
% 29.32/29.15  tff(decl_74040, type, systems_biology_1: $i > $o).
% 29.32/29.15  tff(decl_74041, type, 'Systems-Biology': $i).
% 29.32/29.15  tff(decl_74042, type, 'An approach to the study of biology whose goal is to understand entire biological systems, rather than focusing only on parts of systems.': $i).
% 29.32/29.15  tff(decl_74043, type, 'systems biology': $i).
% 29.32/29.15  tff(decl_74044, type, 'systems-biology': $i).
% 29.32/29.15  tff(decl_74045, type, systole_1: $i > $o).
% 29.32/29.15  tff(decl_74046, type, 'Systole': $i).
% 29.32/29.15  tff(decl_74047, type, 'The part of the cardiac cycle when the left ventricle contracts and pumps blood through the aorta. More generally, systole can refer to the contraction of any of the heart chambers.': $i).
% 29.32/29.15  tff(decl_74048, type, systole: $i).
% 29.32/29.15  tff(decl_74049, type, t_cell_receptor_1: $i > $o).
% 29.32/29.15  tff(decl_74050, type, 'T-Cell-Receptor': $i).
% 29.32/29.15  tff(decl_74051, type, 'A molecule on the surface of a T cell that recognizes antigens presented by major histocompatibility complex (MHC) molecules.': $i).
% 29.32/29.15  tff(decl_74052, type, 't cell receptor': $i).
% 29.32/29.15  tff(decl_74053, type, 't-cell receptor': $i).
% 29.32/29.15  tff(decl_74054, type, 't-cell-receptor': $i).
% 29.32/29.15  tff(decl_74055, type, fn_t_cell_receptor_1: $i > $i).
% 29.32/29.15  tff(decl_74056, type, 'T-Cells': $i).
% 29.32/29.15  tff(decl_74057, type, 'Lymphocytes that mature in the thymus gland, distinguished from other lymphocytes by the presence of T-cell receptors on the surface. T cells function in cell-mediated immunity; some are helper cells in adaptive immunity.': $i).
% 29.32/29.15  tff(decl_74058, type, 't cells': $i).
% 29.32/29.15  tff(decl_74059, type, 't-cells': $i).
% 29.32/29.15  tff(decl_74060, type, 't cell': $i).
% 29.32/29.15  tff(decl_74061, type, 't-cell': $i).
% 29.32/29.15  tff(decl_74062, type, 'T2-Phage': $i).
% 29.32/29.15  tff(decl_74063, type, 'The virus used in the Hershey-Chase experiment to determine whether protein or DNA was the source of genetic information.': $i).
% 29.32/29.15  tff(decl_74064, type, 't2 phage': $i).
% 29.32/29.15  tff(decl_74065, type, 't2-phage': $i).
% 29.32/29.15  tff(decl_74066, type, 'T3': $i).
% 29.32/29.15  tff(decl_74067, type, 'Triiodothyronine, one of the hormones secreted by the thyroid gland in vertebrates. It regulates metabolism, development, and maturation.': $i).
% 29.32/29.15  tff(decl_74068, type, triiodothyronine: $i).
% 29.32/29.15  tff(decl_74069, type, t3: $i).
% 29.32/29.15  tff(decl_74070, type, fn_t3_1: $i > $i).
% 29.32/29.15  tff(decl_74071, type, iodine_0: $i).
% 29.32/29.15  tff(decl_74072, type, fn_thyroid_hormone_11: $i > $i).
% 29.32/29.15  tff(decl_74073, type, 'T4': $i).
% 29.32/29.15  tff(decl_74074, type, 'Thyroxine, one of the hormones secreted by the thyroid gland in vertebrates. Thyroxine is the form that circulates in the blood, but is converted to T3 (triiodothyronine) by the target cells.': $i).
% 29.32/29.15  tff(decl_74075, type, thyroxine: $i).
% 29.32/29.15  tff(decl_74076, type, t4: $i).
% 29.32/29.15  tff(decl_74077, type, fn_t4_1: $i > $i).
% 29.32/29.15  tff(decl_74078, type, t4_phage_1: $i > $o).
% 29.32/29.15  tff(decl_74079, type, 'T4-Phage': $i).
% 29.32/29.15  tff(decl_74080, type, 'Among the largest of the  bacteriophages. It has a tail sheath and infects E. Coli bacteria.': $i).
% 29.32/29.15  tff(decl_74081, type, 't4 bacteriophage': $i).
% 29.32/29.15  tff(decl_74082, type, 'phage t4': $i).
% 29.32/29.15  tff(decl_74083, type, 'phage of t4': $i).
% 29.32/29.15  tff(decl_74084, type, 't4 phage': $i).
% 29.32/29.15  tff(decl_74085, type, 't4-phage': $i).
% 29.32/29.15  tff(decl_74086, type, virulent_phage_1: $i > $o).
% 29.32/29.15  tff(decl_74087, type, 'Tadpole': $i).
% 29.32/29.15  tff(decl_74088, type, 'A larval frog or toad is called the tadpole.': $i).
% 29.32/29.15  tff(decl_74089, type, polywog: $i).
% 29.32/29.15  tff(decl_74090, type, tadpole: $i).
% 29.32/29.15  tff(decl_74091, type, fn_tadpole_1: $i > $i).
% 29.32/29.15  tff(decl_74092, type, 'Tail': $i).
% 29.32/29.15  tff(decl_74093, type, 'The tail is the section at the rear end of an animal\\s body; in general, the term refers to a distinct, flexible appendage to the torso.': $i).
% 29.32/29.15  tff(decl_74094, type, tail: $i).
% 29.32/29.15  tff(decl_74095, type, 'Tail-Region': $i).
% 29.32/29.15  tff(decl_74096, type, 'The end or most posterior region.': $i).
% 29.32/29.15  tff(decl_74097, type, 'region of tail': $i).
% 29.32/29.15  tff(decl_74098, type, 'tail region': $i).
% 29.32/29.15  tff(decl_74099, type, 'tail-region': $i).
% 29.32/29.15  tff(decl_74100, type, 'Take': $i).
% 29.32/29.15  tff(decl_74101, type, 'Take-Apart': $i).
% 29.32/29.15  tff(decl_74102, type, 'take apart': $i).
% 29.32/29.15  tff(decl_74103, type, take_apart: $i).
% 29.32/29.15  tff(decl_74104, type, break_apart: $i).
% 29.32/29.15  tff(decl_74105, type, disassemble: $i).
% 29.32/29.15  tff(decl_74106, type, dismantle: $i).
% 29.32/29.15  tff(decl_74107, type, 'take-apart': $i).
% 29.32/29.15  tff(decl_74108, type, 'Take-Control': $i).
% 29.32/29.15  tff(decl_74109, type, control: $i).
% 29.32/29.15  tff(decl_74110, type, 'take control': $i).
% 29.32/29.15  tff(decl_74111, type, take_control: $i).
% 29.32/29.15  tff(decl_74112, type, 'take charge': $i).
% 29.32/29.15  tff(decl_74113, type, take_charge: $i).
% 29.32/29.15  tff(decl_74114, type, 'take control of': $i).
% 29.32/29.15  tff(decl_74115, type, 'control of take': $i).
% 29.32/29.15  tff(decl_74116, type, 'take-control': $i).
% 29.32/29.15  tff(decl_74117, type, fn_take_control_1: $i > $i).
% 29.32/29.15  tff(decl_74118, type, fn_take_control_2: $i > $i).
% 29.32/29.15  tff(decl_74119, type, 'Take-In': $i).
% 29.32/29.15  tff(decl_74120, type, sorb: $i).
% 29.32/29.15  tff(decl_74121, type, 'take up': $i).
% 29.32/29.15  tff(decl_74122, type, take_up: $i).
% 29.32/29.15  tff(decl_74123, type, 'take in': $i).
% 29.32/29.15  tff(decl_74124, type, 'take-in': $i).
% 29.32/29.15  tff(decl_74125, type, tamoxifen_1: $i > $o).
% 29.32/29.15  tff(decl_74126, type, 'Tamoxifen': $i).
% 29.32/29.15  tff(decl_74127, type, 'Drug used in the treatment of some forms of breast cancer.': $i).
% 29.32/29.15  tff(decl_74128, type, tamoxifen: $i).
% 29.32/29.15  tff(decl_74129, type, fn_tamoxifen_1: $i > $i).
% 29.32/29.15  tff(decl_74130, type, fn_tamoxifen_2: $i > $i).
% 29.32/29.15  tff(decl_74131, type, 'Tandemly-Repeated-DNA': $i).
% 29.32/29.15  tff(decl_74132, type, 'Repeated short sequences of DNA.': $i).
% 29.32/29.15  tff(decl_74133, type, 'tandemly repeated dna': $i).
% 29.32/29.15  tff(decl_74134, type, 'tandemly-repeated-dna': $i).
% 29.32/29.15  tff(decl_74135, type, fn_tandemly_repeated_dna_3: $i > $i).
% 29.32/29.15  tff(decl_74136, type, 'Tangible-Entity': $i).
% 29.32/29.15  tff(decl_74137, type, 'material of raw': $i).
% 29.32/29.15  tff(decl_74138, type, 'raw material': $i).
% 29.32/29.15  tff(decl_74139, type, 'raw-material': $i).
% 29.32/29.15  tff(decl_74140, type, material: $i).
% 29.32/29.15  tff(decl_74141, type, portion: $i).
% 29.32/29.15  tff(decl_74142, type, component: $i).
% 29.32/29.15  tff(decl_74143, type, 'has part': $i).
% 29.32/29.15  tff(decl_74144, type, 'has-part': $i).
% 29.32/29.15  tff(decl_74145, type, thing: $i).
% 29.32/29.15  tff(decl_74146, type, 'tangible entity': $i).
% 29.32/29.15  tff(decl_74147, type, 'tangible-entity': $i).
% 29.32/29.15  tff(decl_74148, type, tantalum_1: $i > $o).
% 29.32/29.15  tff(decl_74149, type, 'Tantalum': $i).
% 29.32/29.15  tff(decl_74150, type, 'Tantalum is a metal atom with atomic number 73. It is represented by the symbol Ta.': $i).
% 29.32/29.15  tff(decl_74151, type, tantalum: $i).
% 29.32/29.15  tff(decl_74152, type, 'Ta': $i).
% 29.32/29.15  tff(decl_74153, type, fn_tantalum_3: $i > $i).
% 29.32/29.15  tff(decl_74154, type, fn_tantalum_4: $i > $i).
% 29.32/29.15  tff(decl_74155, type, fn_tantalum_5: $i > $i).
% 29.32/29.15  tff(decl_74156, type, fn_tantalum_9: $i > $i).
% 29.32/29.15  tff(decl_74157, type, fn_tantalum_10: $i > $i).
% 29.32/29.15  tff(decl_74158, type, fn_tantalum_11: $i > $i).
% 29.32/29.15  tff(decl_74159, type, fn_tantalum_12: $i > $i).
% 29.32/29.15  tff(decl_74160, type, "181": $i).
% 29.32/29.15  tff(decl_74161, type, "180.9": $i).
% 29.32/29.15  tff(decl_74162, type, fn_tantalum_7: $i > $i).
% 29.32/29.15  tff(decl_74163, type, fn_tantalum_8: $i > $i).
% 29.32/29.15  tff(decl_74164, type, fn_tantalum_6: $i > $i).
% 29.32/29.15  tff(decl_74165, type, 'Tapeworm': $i).
% 29.32/29.15  tff(decl_74166, type, 'A member of a class of parasitic flatworms, inhabiting the intestines of vertebrate hosts.': $i).
% 29.32/29.15  tff(decl_74167, type, tapeworm: $i).
% 29.32/29.15  tff(decl_74168, type, 'Taproot': $i).
% 29.32/29.15  tff(decl_74169, type, 'A large, downward growing vertical root from which lateral roots arise.': $i).
% 29.32/29.15  tff(decl_74170, type, taproot: $i).
% 29.32/29.15  tff(decl_74171, type, 'Taq-Polymerase': $i).
% 29.32/29.15  tff(decl_74172, type, 'Taq polymerase is a thermostable DNA polymerase frequently used in polymerase chain reaction (PCR), methods for greatly amplifying short segments of DNA.': $i).
% 29.32/29.15  tff(decl_74173, type, 'taq polymerase': $i).
% 29.32/29.15  tff(decl_74174, type, 'taq-polymerase': $i).
% 29.32/29.15  tff(decl_74175, type, fn_taq_polymerase_1: $i > $i).
% 29.32/29.15  tff(decl_74176, type, fn_taq_polymerase_6: $i > $i).
% 29.32/29.15  tff(decl_74177, type, fn_taq_polymerase_7: $i > $i).
% 29.32/29.15  tff(decl_74178, type, fn_taq_polymerase_8: $i > $i).
% 29.32/29.15  tff(decl_74179, type, fn_taq_polymerase_9: $i > $i).
% 29.32/29.15  tff(decl_74180, type, fn_taq_polymerase_10: $i > $i).
% 29.32/29.15  tff(decl_74181, type, fn_taq_polymerase_11: $i > $i).
% 29.32/29.15  tff(decl_74182, type, fn_taq_polymerase_12: $i > $i).
% 29.32/29.15  tff(decl_74183, type, fn_taq_polymerase_13: $i > $i).
% 29.32/29.15  tff(decl_74184, type, fn_taq_polymerase_14: $i > $i).
% 29.32/29.15  tff(decl_74185, type, fn_taq_polymerase_15: $i > $i).
% 29.32/29.15  tff(decl_74186, type, fn_taq_polymerase_16: $i > $i).
% 29.32/29.15  tff(decl_74187, type, fn_taq_polymerase_17: $i > $i).
% 29.32/29.15  tff(decl_74188, type, fn_taq_polymerase_18: $i > $i).
% 29.32/29.15  tff(decl_74189, type, fn_taq_polymerase_19: $i > $i).
% 29.32/29.15  tff(decl_74190, type, fn_taq_polymerase_20: $i > $i).
% 29.32/29.15  tff(decl_74191, type, fn_taq_polymerase_21: $i > $i).
% 29.32/29.15  tff(decl_74192, type, fn_taq_polymerase_22: $i > $i).
% 29.32/29.15  tff(decl_74193, type, fn_taq_polymerase_23: $i > $i).
% 29.32/29.15  tff(decl_74194, type, fn_taq_polymerase_24: $i > $i).
% 29.32/29.15  tff(decl_74195, type, fn_taq_polymerase_25: $i > $i).
% 29.32/29.15  tff(decl_74196, type, thermocycler_1: $i > $o).
% 29.32/29.15  tff(decl_74197, type, fn_taq_polymerase_26: $i > $i).
% 29.32/29.15  tff(decl_74198, type, fn_taq_polymerase_27: $i > $i).
% 29.32/29.15  tff(decl_74199, type, fn_taq_polymerase_28: $i > $i).
% 29.32/29.15  tff(decl_74200, type, fn_taq_polymerase_29: $i > $i).
% 29.32/29.15  tff(decl_74201, type, fn_thermocycler_1: $i > $i).
% 29.32/29.15  tff(decl_74202, type, fn_taq_polymerase_5: $i > $i).
% 29.32/29.15  tff(decl_74203, type, fn_taq_polymerase_4: $i > $i).
% 29.32/29.15  tff(decl_74204, type, fn_taq_polymerase_3: $i > $i).
% 29.32/29.15  tff(decl_74205, type, fn_taq_polymerase_2: $i > $i).
% 29.32/29.15  tff(decl_74206, type, tardigrade_1: $i > $o).
% 29.32/29.15  tff(decl_74207, type, 'Tardigrade': $i).
% 29.32/29.15  tff(decl_74208, type, 'A member of the phylum Tardigrada, part of the superphylum Ecdysozoa. They are microscopic, water-dwelling, segmented animals with four pairs of stubb legs. Tardigrades are known for their ability to dehydrate into a dormant resting stage called a tun, which can withstand extreme high and low temperatures, high levels of radiation, and anoxic conditions.': $i).
% 29.32/29.15  tff(decl_74209, type, tardigrade: $i).
% 29.32/29.15  tff(decl_74210, type, 'Target': $i).
% 29.32/29.15  tff(decl_74211, type, target: $i).
% 29.32/29.15  tff(decl_74212, type, 'Target-Cell': $i).
% 29.32/29.15  tff(decl_74213, type, 'A cell that has receptors for a particular signaling molecule such as a hormone.': $i).
% 29.32/29.15  tff(decl_74214, type, 'cell of target': $i).
% 29.32/29.15  tff(decl_74215, type, 'target cell': $i).
% 29.32/29.15  tff(decl_74216, type, 'target-cell': $i).
% 29.32/29.15  tff(decl_74217, type, fn_target_cell_2: $i > $i).
% 29.32/29.15  tff(decl_74218, type, fn_target_destination_5: $i > $i).
% 29.32/29.15  tff(decl_74219, type, 'Target-Destination': $i).
% 29.32/29.15  tff(decl_74220, type, 'A cell site where substances, such as proteins, must be transported in order to become functional.': $i).
% 29.32/29.15  tff(decl_74221, type, 'destination of target': $i).
% 29.32/29.15  tff(decl_74222, type, 'target destination': $i).
% 29.32/29.15  tff(decl_74223, type, 'target-destination': $i).
% 29.32/29.15  tff(decl_74224, type, fn_target_destination_2: $i > $i).
% 29.32/29.15  tff(decl_74225, type, fn_target_destination_3: $i > $i).
% 29.32/29.15  tff(decl_74226, type, fn_target_destination_4: $i > $i).
% 29.32/29.15  tff(decl_74227, type, tastant_1: $i > $o).
% 29.32/29.15  tff(decl_74228, type, 'Tastant': $i).
% 29.32/29.15  tff(decl_74229, type, 'Any chemical that initiates the sense of taste by stimulating the receptors in a taste bud.': $i).
% 29.32/29.15  tff(decl_74230, type, taste_bud_1: $i > $o).
% 29.32/29.15  tff(decl_74231, type, 'Taste-Bud': $i).
% 29.32/29.15  tff(decl_74232, type, 'One of many small papillae on the tongue that contain the receptors for taste.': $i).
% 29.32/29.15  tff(decl_74233, type, 'bud of taste': $i).
% 29.32/29.15  tff(decl_74234, type, 'taste bud': $i).
% 29.32/29.15  tff(decl_74235, type, 'taste-bud': $i).
% 29.32/29.15  tff(decl_74236, type, 'Taste-Constant': $i).
% 29.32/29.15  tff(decl_74237, type, 'constant of taste': $i).
% 29.32/29.15  tff(decl_74238, type, 'taste constant': $i).
% 29.32/29.15  tff(decl_74239, type, 'taste-constant': $i).
% 29.32/29.15  tff(decl_74240, type, 'Taste-Value': $i).
% 29.32/29.15  tff(decl_74241, type, 'the sensation that results when taste buds in the tongue and throat convey information about the chemical composition of a soluble stimulus': $i).
% 29.32/29.15  tff(decl_74242, type, 'taste sensation': $i).
% 29.32/29.15  tff(decl_74243, type, 'gustatory sensation': $i).
% 29.32/29.15  tff(decl_74244, type, 'taste perception': $i).
% 29.32/29.15  tff(decl_74245, type, 'gustatory perception': $i).
% 29.32/29.15  tff(decl_74246, type, 'value of taste': $i).
% 29.32/29.15  tff(decl_74247, type, 'taste value': $i).
% 29.32/29.15  tff(decl_74248, type, 'taste-value': $i).
% 29.32/29.15  tff(decl_74249, type, fn_tata_box_7: $i > $i).
% 29.32/29.15  tff(decl_74250, type, fn_tata_box_6: $i > $i).
% 29.32/29.15  tff(decl_74251, type, fn_tata_box_4: $i > $i).
% 29.32/29.15  tff(decl_74252, type, 'TATA-Box': $i).
% 29.32/29.15  tff(decl_74253, type, 'A DNA sequence found in the promoter region of genes. It is involved in initiating transcription.': $i).
% 29.32/29.15  tff(decl_74254, type, 'goldberg hogness box': $i).
% 29.32/29.15  tff(decl_74255, type, 'goldberg-hogness-box': $i).
% 29.32/29.15  tff(decl_74256, type, 'tata box': $i).
% 29.32/29.15  tff(decl_74257, type, 'tata-box': $i).
% 29.32/29.15  tff(decl_74258, type, fn_tata_box_3: $i > $i).
% 29.32/29.15  tff(decl_74259, type, taxis_1: $i > $o).
% 29.32/29.15  tff(decl_74260, type, 'Taxis': $i).
% 29.32/29.15  tff(decl_74261, type, 'A behavioral response involving movement toward or away from a stimulus.': $i).
% 29.32/29.15  tff(decl_74262, type, taxi: $i).
% 29.32/29.15  tff(decl_74263, type, taxol_1: $i > $o).
% 29.32/29.15  tff(decl_74264, type, 'Taxol': $i).
% 29.32/29.15  tff(decl_74265, type, 'Drug used in the treatment of certain cancers, derived from the yew tree.': $i).
% 29.32/29.15  tff(decl_74266, type, taxol: $i).
% 29.32/29.15  tff(decl_74267, type, 'Taxon': $i).
% 29.32/29.15  tff(decl_74268, type, 'A named group of one or more populations, judged by a taxonomist to be a unit.': $i).
% 29.32/29.15  tff(decl_74269, type, taxon: $i).
% 29.32/29.15  tff(decl_74270, type, 'Taxonomy': $i).
% 29.32/29.15  tff(decl_74271, type, 'The scientific discipline of identifying and naming groups of organisms.': $i).
% 29.32/29.15  tff(decl_74272, type, taxonomy: $i).
% 29.32/29.15  tff(decl_74273, type, 'Tay-Sachs-disease': $i).
% 29.32/29.15  tff(decl_74274, type, 'Tay-Sachs disease is an autosomal recessive genetic disorder in the family of lysosomal storage diseases caused by a deficiency in the lipid digesting enzyme. The lysosomes become engorged with indigestible substrates, that interfere in cellular activities': $i).
% 29.32/29.15  tff(decl_74275, type, tsd: $i).
% 29.32/29.15  tff(decl_74276, type, 'gm2 gangliosidosis': $i).
% 29.32/29.15  tff(decl_74277, type, 'hexosaminidase a deficiency': $i).
% 29.32/29.15  tff(decl_74278, type, 'tay sachs': $i).
% 29.32/29.15  tff(decl_74279, type, 'tay-sachs': $i).
% 29.32/29.15  tff(decl_74280, type, 'tay sachs disease': $i).
% 29.32/29.15  tff(decl_74281, type, 'tay-sachs-disease': $i).
% 29.32/29.15  tff(decl_74282, type, fn_tay_sachs_disease_1: $i > $i).
% 29.32/29.15  tff(decl_74283, type, fn_tay_sachs_disease_2: $i > $i).
% 29.32/29.15  tff(decl_74284, type, 'Teach': $i).
% 29.32/29.15  tff(decl_74285, type, teach: $i).
% 29.32/29.15  tff(decl_74286, type, instruct: $i).
% 29.32/29.15  tff(decl_74287, type, fn_teach_1: $i > $i).
% 29.32/29.15  tff(decl_74288, type, fn_teach_2: $i > $i).
% 29.32/29.15  tff(decl_74289, type, fn_teach_3: $i > $i).
% 29.32/29.15  tff(decl_74290, type, teacher_1: $i > $o).
% 29.32/29.15  tff(decl_74291, type, fn_teach_4: $i > $i).
% 29.32/29.15  tff(decl_74292, type, fn_teacher_1: $i > $i).
% 29.32/29.15  tff(decl_74293, type, 'Teacher': $i).
% 29.32/29.15  tff(decl_74294, type, teacher: $i).
% 29.32/29.15  tff(decl_74295, type, instructor: $i).
% 29.32/29.15  tff(decl_74296, type, team_1: $i > $o).
% 29.32/29.15  tff(decl_74297, type, 'Team': $i).
% 29.32/29.15  tff(decl_74298, type, 'a relatively small organization of Roles with a goal': $i).
% 29.32/29.15  tff(decl_74299, type, team: $i).
% 29.32/29.15  tff(decl_74300, type, squad: $i).
% 29.32/29.15  tff(decl_74301, type, 'Tear': $i).
% 29.32/29.15  tff(decl_74302, type, 'Bodily fluid secreted by the lacrimal glands of eye.': $i).
% 29.32/29.15  tff(decl_74303, type, tear: $i).
% 29.32/29.15  tff(decl_74304, type, fn_tear_1: $i > $i).
% 29.32/29.15  tff(decl_74305, type, technetium_1: $i > $o).
% 29.32/29.15  tff(decl_74306, type, 'Technetium': $i).
% 29.32/29.15  tff(decl_74307, type, 'Technetium is a metal atom with atomic number 43. It is represented by the symbol Tc.': $i).
% 29.32/29.15  tff(decl_74308, type, technetium: $i).
% 29.32/29.15  tff(decl_74309, type, 'Tc': $i).
% 29.32/29.15  tff(decl_74310, type, fn_technetium_4: $i > $i).
% 29.32/29.15  tff(decl_74311, type, fn_technetium_5: $i > $i).
% 29.32/29.15  tff(decl_74312, type, fn_technetium_6: $i > $i).
% 29.32/29.15  tff(decl_74313, type, fn_technetium_7: $i > $i).
% 29.32/29.15  tff(decl_74314, type, fn_technetium_11: $i > $i).
% 29.32/29.15  tff(decl_74315, type, fn_technetium_12: $i > $i).
% 29.32/29.15  tff(decl_74316, type, fn_technetium_13: $i > $i).
% 29.32/29.15  tff(decl_74317, type, fn_technetium_14: $i > $i).
% 29.32/29.15  tff(decl_74318, type, "43": $i).
% 29.32/29.15  tff(decl_74319, type, fn_technetium_9: $i > $i).
% 29.32/29.15  tff(decl_74320, type, fn_technetium_10: $i > $i).
% 29.32/29.15  tff(decl_74321, type, fn_technetium_8: $i > $i).
% 29.32/29.15  tff(decl_74322, type, 'Technique': $i).
% 29.32/29.15  tff(decl_74323, type, 'The procedure used to perform a particular task.': $i).
% 29.32/29.15  tff(decl_74324, type, technique: $i).
% 29.32/29.15  tff(decl_74325, type, tellurium_1: $i > $o).
% 29.32/29.15  tff(decl_74326, type, 'Tellurium': $i).
% 29.32/29.15  tff(decl_74327, type, 'Tellurium is a metalloid atom with atomic number 52. It is represented by the symbol Te.': $i).
% 29.32/29.15  tff(decl_74328, type, tellurium: $i).
% 29.32/29.15  tff(decl_74329, type, 'Te': $i).
% 29.32/29.15  tff(decl_74330, type, fn_tellurium_3: $i > $i).
% 29.32/29.15  tff(decl_74331, type, fn_tellurium_4: $i > $i).
% 29.32/29.15  tff(decl_74332, type, fn_tellurium_5: $i > $i).
% 29.32/29.15  tff(decl_74333, type, fn_tellurium_9: $i > $i).
% 29.32/29.15  tff(decl_74334, type, fn_tellurium_10: $i > $i).
% 29.32/29.15  tff(decl_74335, type, fn_tellurium_11: $i > $i).
% 29.32/29.15  tff(decl_74336, type, fn_tellurium_12: $i > $i).
% 29.32/29.15  tff(decl_74337, type, "128": $i).
% 29.32/29.15  tff(decl_74338, type, "127.6": $i).
% 29.32/29.15  tff(decl_74339, type, fn_tellurium_7: $i > $i).
% 29.32/29.15  tff(decl_74340, type, fn_tellurium_8: $i > $i).
% 29.32/29.15  tff(decl_74341, type, fn_tellurium_6: $i > $i).
% 29.32/29.15  tff(decl_74342, type, 'Telomerase': $i).
% 29.32/29.15  tff(decl_74343, type, 'Telomerase is an enzyme which adds noncoding DNA to telomeres in a eukaryotic organism in oder to replace DNA lost during cell division.': $i).
% 29.32/29.15  tff(decl_74344, type, telomerase: $i).
% 29.32/29.15  tff(decl_74345, type, fn_telomerase_1: $i > $i).
% 29.32/29.15  tff(decl_74346, type, fn_telomerase_2: $i > $i).
% 29.32/29.15  tff(decl_74347, type, fn_telomerase_5: $i > $i).
% 29.32/29.15  tff(decl_74348, type, fn_telomerase_6: $i > $i).
% 29.32/29.15  tff(decl_74349, type, fn_telomerase_7: $i > $i).
% 29.32/29.15  tff(decl_74350, type, fn_telomerase_8: $i > $i).
% 29.32/29.15  tff(decl_74351, type, fn_telomerase_12: $i > $i).
% 29.32/29.15  tff(decl_74352, type, fn_telomerase_13: $i > $i).
% 29.32/29.15  tff(decl_74353, type, fn_telomerase_14: $i > $i).
% 29.32/29.15  tff(decl_74354, type, fn_telomerase_15: $i > $i).
% 29.32/29.15  tff(decl_74355, type, fn_telomerase_16: $i > $i).
% 29.32/29.15  tff(decl_74356, type, fn_telomerase_17: $i > $i).
% 29.32/29.15  tff(decl_74357, type, fn_telomerase_18: $i > $i).
% 29.32/29.15  tff(decl_74358, type, fn_telomerase_19: $i > $i).
% 29.32/29.15  tff(decl_74359, type, fn_telomerase_20: $i > $i).
% 29.32/29.15  tff(decl_74360, type, fn_telomerase_21: $i > $i).
% 29.32/29.15  tff(decl_74361, type, fn_telomerase_22: $i > $i).
% 29.32/29.15  tff(decl_74362, type, fn_telomerase_23: $i > $i).
% 29.32/29.15  tff(decl_74363, type, fn_telomerase_24: $i > $i).
% 29.32/29.15  tff(decl_74364, type, fn_telomerase_25: $i > $i).
% 29.32/29.15  tff(decl_74365, type, fn_telomerase_26: $i > $i).
% 29.32/29.15  tff(decl_74366, type, fn_telomerase_27: $i > $i).
% 29.32/29.15  tff(decl_74367, type, fn_telomerase_28: $i > $i).
% 29.32/29.15  tff(decl_74368, type, fn_telomerase_29: $i > $i).
% 29.32/29.15  tff(decl_74369, type, fn_telomerase_30: $i > $i).
% 29.32/29.15  tff(decl_74370, type, fn_telomerase_31: $i > $i).
% 29.32/29.15  tff(decl_74371, type, fn_telomerase_32: $i > $i).
% 29.32/29.15  tff(decl_74372, type, fn_telomerase_33: $i > $i).
% 29.32/29.15  tff(decl_74373, type, fn_telomerase_34: $i > $i).
% 29.32/29.15  tff(decl_74374, type, 'Telomere': $i).
% 29.32/29.15  tff(decl_74375, type, 'A region of repetitive DNA at the tips of a chromatid. It protects the tip of the chromosome from degradation, safeguards the integrity of genes at the end of the chromosome, and prevents fusion with another chromosome.': $i).
% 29.32/29.15  tff(decl_74376, type, 'cellular clock': $i).
% 29.32/29.15  tff(decl_74377, type, 'cellular-clock': $i).
% 29.32/29.15  tff(decl_74378, type, telomere: $i).
% 29.32/29.15  tff(decl_74379, type, fn_telomere_2: $i > $i).
% 29.32/29.15  tff(decl_74380, type, fn_telomere_6: $i > $i).
% 29.32/29.15  tff(decl_74381, type, fn_telomere_7: $i > $i).
% 29.32/29.15  tff(decl_74382, type, fn_telomere_9: $i > $i).
% 29.32/29.15  tff(decl_74383, type, fn_telomere_4: $i > $i).
% 29.32/29.15  tff(decl_74384, type, 'Telomere-With-3-Prime-Overhang': $i).
% 29.32/29.15  tff(decl_74385, type, 'This is telomere region of the replicated DNA strand present at terminal ends with an RNA stretch added to it by telomerase. It is formed during DNA replication termination in eukaryotes': $i).
% 29.32/29.15  tff(decl_74386, type, 'telomere with 3 prime overhang': $i).
% 29.32/29.15  tff(decl_74387, type, 'telomere-with-3-prime-overhang': $i).
% 29.32/29.15  tff(decl_74388, type, 'Telophase': $i).
% 29.32/29.15  tff(decl_74389, type, 'Telophase is the final stage of mitosis during which diagnostic processes occur including cytokinesis, unravelling of condense chromosomes, and formation of daughter nuclei.': $i).
% 29.32/29.15  tff(decl_74390, type, 'undergo telophase': $i).
% 29.32/29.15  tff(decl_74391, type, telophase: $i).
% 29.32/29.15  tff(decl_74392, type, fn_telophase_1: $i > $i).
% 29.32/29.15  tff(decl_74393, type, fn_telophase_2: $i > $i).
% 29.32/29.15  tff(decl_74394, type, fn_telophase_3: $i > $i).
% 29.32/29.15  tff(decl_74395, type, fn_telophase_4: $i > $i).
% 29.32/29.15  tff(decl_74396, type, fn_telophase_5: $i > $i).
% 29.32/29.15  tff(decl_74397, type, fn_telophase_6: $i > $i).
% 29.32/29.15  tff(decl_74398, type, fn_telophase_7: $i > $i).
% 29.32/29.15  tff(decl_74399, type, fn_telophase_8: $i > $i).
% 29.32/29.15  tff(decl_74400, type, fn_telophase_9: $i > $i).
% 29.32/29.15  tff(decl_74401, type, fn_telophase_11: $i > $i).
% 29.32/29.15  tff(decl_74402, type, fn_telophase_12: $i > $i).
% 29.32/29.15  tff(decl_74403, type, fn_telophase_13: $i > $i).
% 29.32/29.15  tff(decl_74404, type, fn_telophase_14: $i > $i).
% 29.32/29.15  tff(decl_74405, type, fn_telophase_16: $i > $i).
% 29.32/29.15  tff(decl_74406, type, fn_telophase_17: $i > $i).
% 29.32/29.15  tff(decl_74407, type, fn_telophase_19: $i > $i).
% 29.32/29.15  tff(decl_74408, type, fn_telophase_20: $i > $i).
% 29.32/29.15  tff(decl_74409, type, fn_telophase_21: $i > $i).
% 29.32/29.15  tff(decl_74410, type, fn_telophase_22: $i > $i).
% 29.32/29.15  tff(decl_74411, type, fn_telophase_23: $i > $i).
% 29.32/29.15  tff(decl_74412, type, fn_telophase_24: $i > $i).
% 29.32/29.15  tff(decl_74413, type, fn_telophase_25: $i > $i).
% 29.32/29.15  tff(decl_74414, type, fn_telophase_26: $i > $i).
% 29.32/29.15  tff(decl_74415, type, fn_telophase_27: $i > $i).
% 29.32/29.15  tff(decl_74416, type, fn_telophase_28: $i > $i).
% 29.32/29.15  tff(decl_74417, type, telophase_i_1: $i > $o).
% 29.32/29.15  tff(decl_74418, type, 'Telophase-I': $i).
% 29.32/29.15  tff(decl_74419, type, 'The homologous chromosomes continue to move-apart until they reach the poles of the cell. Each pole, has a haploid chromosome set.': $i).
% 29.32/29.15  tff(decl_74420, type, 'undergo telophase i': $i).
% 29.32/29.15  tff(decl_74421, type, 'undergo telophase-i': $i).
% 29.32/29.15  tff(decl_74422, type, 'telophase i': $i).
% 29.32/29.15  tff(decl_74423, type, 'telophase-i': $i).
% 29.32/29.15  tff(decl_74424, type, fn_telophase_i_1: $i > $i).
% 29.32/29.15  tff(decl_74425, type, fn_telophase_i_2: $i > $i).
% 29.32/29.15  tff(decl_74426, type, fn_telophase_i_3: $i > $i).
% 29.32/29.15  tff(decl_74427, type, fn_telophase_i_4: $i > $i).
% 29.32/29.15  tff(decl_74428, type, fn_telophase_i_5: $i > $i).
% 29.32/29.15  tff(decl_74429, type, fn_telophase_i_6: $i > $i).
% 29.32/29.15  tff(decl_74430, type, fn_telophase_i_7: $i > $i).
% 29.32/29.15  tff(decl_74431, type, fn_telophase_i_8: $i > $i).
% 29.32/29.15  tff(decl_74432, type, fn_telophase_i_9: $i > $i).
% 29.32/29.15  tff(decl_74433, type, fn_telophase_i_10: $i > $i).
% 29.32/29.15  tff(decl_74434, type, 'Telophase-II': $i).
% 29.32/29.15  tff(decl_74435, type, 'Nuclei form at the opposite poles of the cell.': $i).
% 29.32/29.15  tff(decl_74436, type, 'undergo telophase ii': $i).
% 29.32/29.15  tff(decl_74437, type, 'undergo telophase-ii': $i).
% 29.32/29.15  tff(decl_74438, type, 'telophase ii': $i).
% 29.32/29.15  tff(decl_74439, type, 'telophase-ii': $i).
% 29.32/29.15  tff(decl_74440, type, fn_telophase_ii_1: $i > $i).
% 29.32/29.15  tff(decl_74441, type, fn_telophase_ii_2: $i > $i).
% 29.32/29.15  tff(decl_74442, type, fn_telophase_ii_3: $i > $i).
% 29.32/29.15  tff(decl_74443, type, fn_telophase_ii_4: $i > $i).
% 29.32/29.15  tff(decl_74444, type, fn_telophase_ii_5: $i > $i).
% 29.32/29.15  tff(decl_74445, type, 'Temperate-Broadleaf-Forest': $i).
% 29.32/29.15  tff(decl_74446, type, 'A temperate biome of midlatitude regions, characterized by distinct warm and cool seasons and enough rainfall to support large, broadleaf deciduous trees such as oaks, beeches, and maples.': $i).
% 29.32/29.15  tff(decl_74447, type, 'temperate broadleaf forest': $i).
% 29.32/29.15  tff(decl_74448, type, 'temperate-broadleaf-forest': $i).
% 29.32/29.15  tff(decl_74449, type, 'Temperate-Grassland': $i).
% 29.32/29.15  tff(decl_74450, type, 'A biome in which grasses and forbs are the dominant vegetation.': $i).
% 29.32/29.15  tff(decl_74451, type, 'temperate grassland': $i).
% 29.32/29.15  tff(decl_74452, type, 'temperate-grassland': $i).
% 29.32/29.15  tff(decl_74453, type, 'Temperate-Phage': $i).
% 29.32/29.15  tff(decl_74454, type, 'A phage that is capable of reproducing by either a lytic or lysogenic cycle.': $i).
% 29.32/29.15  tff(decl_74455, type, 'temperate virus': $i).
% 29.32/29.15  tff(decl_74456, type, 'lysogenic virus': $i).
% 29.32/29.15  tff(decl_74457, type, 'temperate phage': $i).
% 29.32/29.15  tff(decl_74458, type, 'temperate-phage': $i).
% 29.32/29.15  tff(decl_74459, type, fn_temperate_phage_1: $i > $i).
% 29.32/29.15  tff(decl_74460, type, fn_temperate_phage_2: $i > $i).
% 29.32/29.15  tff(decl_74461, type, fn_temperate_phage_3: $i > $i).
% 29.32/29.15  tff(decl_74462, type, 'Temperature-Categorical-Constant': $i).
% 29.32/29.15  tff(decl_74463, type, 'temperature categorical constant': $i).
% 29.32/29.15  tff(decl_74464, type, 'temperature-categorical-constant': $i).
% 29.32/29.15  tff(decl_74465, type, 'Temperature-Constant': $i).
% 29.32/29.15  tff(decl_74466, type, 'constant of temperature': $i).
% 29.32/29.15  tff(decl_74467, type, 'temperature constant': $i).
% 29.32/29.15  tff(decl_74468, type, 'temperature-constant': $i).
% 29.32/29.15  tff(decl_74469, type, 'Temperature-Fluctuation': $i).
% 29.32/29.15  tff(decl_74470, type, 'A change in temperature.': $i).
% 29.32/29.15  tff(decl_74471, type, 'fluctuation of temperature': $i).
% 29.32/29.15  tff(decl_74472, type, 'temperature fluctuation': $i).
% 29.32/29.15  tff(decl_74473, type, 'temperature-fluctuation': $i).
% 29.32/29.15  tff(decl_74474, type, fn_temperature_fluctuation_2: $i > $i).
% 29.32/29.15  tff(decl_74475, type, fn_temperature_fluctuation_4: $i > $i).
% 29.32/29.15  tff(decl_74476, type, fn_temperature_fluctuation_5: $i > $i).
% 29.32/29.15  tff(decl_74477, type, temperature_scale_1: $i > $o).
% 29.32/29.15  tff(decl_74478, type, 'Temperature-Scale': $i).
% 29.32/29.15  tff(decl_74479, type, 'scale of temperature': $i).
% 29.32/29.15  tff(decl_74480, type, 'temperature scale': $i).
% 29.32/29.15  tff(decl_74481, type, 'temperature-scale': $i).
% 29.32/29.15  tff(decl_74482, type, 'Temperature-Value': $i).
% 29.32/29.15  tff(decl_74483, type, 'the degree of hotness or coldness of a body or environment': $i).
% 29.32/29.15  tff(decl_74484, type, temperature: $i).
% 29.32/29.15  tff(decl_74485, type, 'value of temperature': $i).
% 29.32/29.15  tff(decl_74486, type, 'temperature value': $i).
% 29.32/29.15  tff(decl_74487, type, 'temperature-value': $i).
% 29.32/29.15  tff(decl_74488, type, 'Template': $i).
% 29.32/29.15  tff(decl_74489, type, 'A role played by an object in a copy event, serving as the thing from which a copy is made.': $i).
% 29.32/29.15  tff(decl_74490, type, template: $i).
% 29.32/29.15  tff(decl_74491, type, 'Temporal-Entity': $i).
% 29.32/29.15  tff(decl_74492, type, 'time before': $i).
% 29.32/29.15  tff(decl_74493, type, 'time-before': $i).
% 29.32/29.15  tff(decl_74494, type, 'entity of temporal': $i).
% 29.32/29.15  tff(decl_74495, type, 'temporal entity': $i).
% 29.32/29.15  tff(decl_74496, type, 'temporal-entity': $i).
% 29.32/29.15  tff(decl_74497, type, 'Temporal-Isolation': $i).
% 29.32/29.15  tff(decl_74498, type, 'A type of reporductive isolation in which two species breed during different times of the day, different seasons, or different years, and thus cannot interbreed.': $i).
% 29.32/29.15  tff(decl_74499, type, 'isolation of temporal': $i).
% 29.32/29.15  tff(decl_74500, type, 'temporal isolation': $i).
% 29.32/29.15  tff(decl_74501, type, 'temporal-isolation': $i).
% 29.32/29.15  tff(decl_74502, type, temporal_lobe_1: $i > $o).
% 29.32/29.15  tff(decl_74503, type, 'Temporal-Lobe': $i).
% 29.32/29.15  tff(decl_74504, type, 'Lateral region of the cerebral cortex responsible for hearing and language comprehension.': $i).
% 29.32/29.15  tff(decl_74505, type, 'lobe of temporal': $i).
% 29.32/29.15  tff(decl_74506, type, 'temporal lobe': $i).
% 29.32/29.15  tff(decl_74507, type, 'temporal-lobe': $i).
% 29.32/29.15  tff(decl_74508, type, temporal_relation_1: $i > $o).
% 29.32/29.15  tff(decl_74509, type, 'Temporal-Relation': $i).
% 29.32/29.15  tff(decl_74510, type, 'A temporal relation is a relation between an entity or event, and a temporal entity. In such relations, the entity or event is placed in absolute or relative position to the time denoted by the temporal entity. If a relation is a temporal relation, then its inverse is also a temporal relation.': $i).
% 29.32/29.15  tff(decl_74511, type, 'relation of temporal': $i).
% 29.32/29.15  tff(decl_74512, type, 'temporal relation': $i).
% 29.32/29.15  tff(decl_74513, type, 'temporal-relation': $i).
% 29.32/29.15  tff(decl_74514, type, temporal_summation_1: $i > $o).
% 29.32/29.15  tff(decl_74515, type, 'Temporal-Summation': $i).
% 29.32/29.15  tff(decl_74516, type, 'A result of neural integration in which a rapid succession of multiple EPSPs and IPSPs determine the membrane potential of a postsynaptic cell.': $i).
% 29.32/29.15  tff(decl_74517, type, 'summation of temporal': $i).
% 29.32/29.15  tff(decl_74518, type, 'temporal summation': $i).
% 29.32/29.15  tff(decl_74519, type, 'temporal-summation': $i).
% 29.32/29.15  tff(decl_74520, type, 'Tendon': $i).
% 29.32/29.15  tff(decl_74521, type, 'A tough band of fibrous connective tissue that attaches muscle to bone.': $i).
% 29.32/29.15  tff(decl_74522, type, tendon: $i).
% 29.32/29.15  tff(decl_74523, type, fn_tendon_1: $i > $i).
% 29.32/29.15  tff(decl_74524, type, fn_tendon_2: $i > $i).
% 29.32/29.15  tff(decl_74525, type, 'Tentacle': $i).
% 29.32/29.15  tff(decl_74526, type, 'Flexible, elongated appendage in animals specialzed for locomotion or capturing prey.': $i).
% 29.32/29.15  tff(decl_74527, type, tentacle: $i).
% 29.32/29.15  tff(decl_74528, type, teratogen_1: $i > $o).
% 29.32/29.15  tff(decl_74529, type, 'Teratogen': $i).
% 29.32/29.15  tff(decl_74530, type, 'A chemical or physical agent that interferes with development; a chemical that causes birth defects.': $i).
% 29.32/29.15  tff(decl_74531, type, teratogen: $i).
% 29.32/29.15  tff(decl_74532, type, terbium_1: $i > $o).
% 29.32/29.15  tff(decl_74533, type, 'Terbium': $i).
% 29.32/29.15  tff(decl_74534, type, 'Terbium is a metal atom with atomic number 65. It is represented by the symbol Tb.': $i).
% 29.32/29.15  tff(decl_74535, type, terbium: $i).
% 29.32/29.15  tff(decl_74536, type, tb: $i).
% 29.32/29.15  tff(decl_74537, type, fn_terbium_3: $i > $i).
% 29.32/29.15  tff(decl_74538, type, fn_terbium_4: $i > $i).
% 29.32/29.15  tff(decl_74539, type, fn_terbium_5: $i > $i).
% 29.32/29.15  tff(decl_74540, type, fn_terbium_9: $i > $i).
% 29.32/29.15  tff(decl_74541, type, fn_terbium_10: $i > $i).
% 29.32/29.15  tff(decl_74542, type, fn_terbium_11: $i > $i).
% 29.32/29.15  tff(decl_74543, type, fn_terbium_12: $i > $i).
% 29.32/29.15  tff(decl_74544, type, "65": $i).
% 29.32/29.15  tff(decl_74545, type, "158.9": $i).
% 29.32/29.15  tff(decl_74546, type, fn_terbium_7: $i > $i).
% 29.32/29.15  tff(decl_74547, type, fn_terbium_8: $i > $i).
% 29.32/29.15  tff(decl_74548, type, fn_terbium_6: $i > $i).
% 29.32/29.15  tff(decl_74549, type, 'Terminate': $i).
% 29.32/29.15  tff(decl_74550, type, 'To bring to an end.': $i).
% 29.32/29.15  tff(decl_74551, type, terminate: $i).
% 29.32/29.15  tff(decl_74552, type, termination_1: $i > $o).
% 29.32/29.15  tff(decl_74553, type, 'Termination': $i).
% 29.32/29.15  tff(decl_74554, type, 'The ending phase of a cellular process.': $i).
% 29.32/29.15  tff(decl_74555, type, termination: $i).
% 29.32/29.15  tff(decl_74556, type, 'Terminator-Sequence': $i).
% 29.32/29.15  tff(decl_74557, type, 'A sequence of nucleotides that indicates the end of a gene. This sequence causes the RNA polymerase to detach from the DNA transcript and thus ends transcription.': $i).
% 29.32/29.15  tff(decl_74558, type, terminator: $i).
% 29.32/29.15  tff(decl_74559, type, 'transcriptional terminator sequence': $i).
% 29.32/29.15  tff(decl_74560, type, 'transcriptional-terminator-sequence': $i).
% 29.32/29.15  tff(decl_74561, type, 'sequence of terminator': $i).
% 29.32/29.15  tff(decl_74562, type, 'terminator sequence': $i).
% 29.32/29.15  tff(decl_74563, type, 'terminator-sequence': $i).
% 29.32/29.15  tff(decl_74564, type, termite_1: $i > $o).
% 29.32/29.15  tff(decl_74565, type, 'Termite': $i).
% 29.32/29.15  tff(decl_74566, type, 'Termites are pale-colored, usually soft-bodied social insects of the order Isoptera that live mostly in warm regions': $i).
% 29.32/29.15  tff(decl_74567, type, termite: $i).
% 29.32/29.15  tff(decl_74568, type, fn_termite_1: $i > $i).
% 29.32/29.15  tff(decl_74569, type, fn_termite_2: $i > $i).
% 29.32/29.15  tff(decl_74570, type, fn_termite_3: $i > $i).
% 29.32/29.15  tff(decl_74571, type, fn_termite_4: $i > $i).
% 29.32/29.15  tff(decl_74572, type, fn_termite_5: $i > $i).
% 29.32/29.15  tff(decl_74573, type, fn_termite_6: $i > $i).
% 29.32/29.15  tff(decl_74574, type, fn_termite_7: $i > $i).
% 29.32/29.15  tff(decl_74575, type, fn_termite_8: $i > $i).
% 29.32/29.15  tff(decl_74576, type, fn_termite_9: $i > $i).
% 29.32/29.15  tff(decl_74577, type, fn_termite_10: $i > $i).
% 29.32/29.15  tff(decl_74578, type, fn_termite_13: $i > $i).
% 29.32/29.15  tff(decl_74579, type, fn_termite_14: $i > $i).
% 29.32/29.15  tff(decl_74580, type, fn_termite_15: $i > $i).
% 29.32/29.15  tff(decl_74581, type, fn_termite_16: $i > $i).
% 29.32/29.15  tff(decl_74582, type, fn_termite_17: $i > $i).
% 29.32/29.15  tff(decl_74583, type, fn_termite_18: $i > $i).
% 29.32/29.15  tff(decl_74584, type, fn_termite_19: $i > $i).
% 29.32/29.15  tff(decl_74585, type, fn_termite_20: $i > $i).
% 29.32/29.15  tff(decl_74586, type, fn_termite_21: $i > $i).
% 29.32/29.15  tff(decl_74587, type, fn_termite_22: $i > $i).
% 29.32/29.15  tff(decl_74588, type, fn_termite_23: $i > $i).
% 29.32/29.15  tff(decl_74589, type, fn_termite_24: $i > $i).
% 29.32/29.15  tff(decl_74590, type, fn_termite_25: $i > $i).
% 29.32/29.15  tff(decl_74591, type, fn_termite_26: $i > $i).
% 29.32/29.15  tff(decl_74592, type, fn_termite_27: $i > $i).
% 29.32/29.15  tff(decl_74593, type, fn_termite_28: $i > $i).
% 29.32/29.15  tff(decl_74594, type, fn_termite_29: $i > $i).
% 29.32/29.15  tff(decl_74595, type, fn_termite_30: $i > $i).
% 29.32/29.15  tff(decl_74596, type, fn_termite_31: $i > $i).
% 29.32/29.15  tff(decl_74597, type, fn_termite_32: $i > $i).
% 29.32/29.15  tff(decl_74598, type, fn_termite_33: $i > $i).
% 29.32/29.15  tff(decl_74599, type, fn_termite_34: $i > $i).
% 29.32/29.15  tff(decl_74600, type, fn_termite_35: $i > $i).
% 29.32/29.15  tff(decl_74601, type, fn_termite_36: $i > $i).
% 29.32/29.15  tff(decl_74602, type, fn_termite_37: $i > $i).
% 29.32/29.15  tff(decl_74603, type, fn_termite_38: $i > $i).
% 29.32/29.15  tff(decl_74604, type, fn_termite_39: $i > $i).
% 29.32/29.15  tff(decl_74605, type, fn_termite_40: $i > $i).
% 29.32/29.15  tff(decl_74606, type, fn_termite_41: $i > $i).
% 29.32/29.15  tff(decl_74607, type, fn_termite_42: $i > $i).
% 29.32/29.15  tff(decl_74608, type, fn_termite_43: $i > $i).
% 29.32/29.15  tff(decl_74609, type, fn_termite_44: $i > $i).
% 29.32/29.15  tff(decl_74610, type, fn_termite_45: $i > $i).
% 29.32/29.15  tff(decl_74611, type, fn_termite_46: $i > $i).
% 29.32/29.15  tff(decl_74612, type, fn_termite_47: $i > $i).
% 29.32/29.15  tff(decl_74613, type, fn_termite_48: $i > $i).
% 29.32/29.15  tff(decl_74614, type, fn_termite_49: $i > $i).
% 29.32/29.15  tff(decl_74615, type, fn_termite_50: $i > $i).
% 29.32/29.15  tff(decl_74616, type, fn_termite_51: $i > $i).
% 29.32/29.15  tff(decl_74617, type, fn_termite_52: $i > $i).
% 29.32/29.15  tff(decl_74618, type, fn_termite_53: $i > $i).
% 29.32/29.15  tff(decl_74619, type, fn_termite_54: $i > $i).
% 29.32/29.15  tff(decl_74620, type, fn_termite_55: $i > $i).
% 29.32/29.15  tff(decl_74621, type, fn_termite_56: $i > $i).
% 29.32/29.15  tff(decl_74622, type, fn_termite_57: $i > $i).
% 29.32/29.15  tff(decl_74623, type, fn_termite_58: $i > $i).
% 29.32/29.15  tff(decl_74624, type, fn_termite_59: $i > $i).
% 29.32/29.15  tff(decl_74625, type, fn_termite_60: $i > $i).
% 29.32/29.15  tff(decl_74626, type, fn_termite_61: $i > $i).
% 29.32/29.15  tff(decl_74627, type, fn_termite_62: $i > $i).
% 29.32/29.15  tff(decl_74628, type, fn_termite_63: $i > $i).
% 29.32/29.15  tff(decl_74629, type, fn_termite_64: $i > $i).
% 29.32/29.15  tff(decl_74630, type, fn_termite_65: $i > $i).
% 29.32/29.15  tff(decl_74631, type, fn_termite_66: $i > $i).
% 29.32/29.15  tff(decl_74632, type, fn_termite_67: $i > $i).
% 29.32/29.15  tff(decl_74633, type, fn_termite_68: $i > $i).
% 29.32/29.15  tff(decl_74634, type, fn_termite_69: $i > $i).
% 29.32/29.15  tff(decl_74635, type, fn_termite_70: $i > $i).
% 29.32/29.15  tff(decl_74636, type, fn_termite_71: $i > $i).
% 29.32/29.15  tff(decl_74637, type, fn_termite_72: $i > $i).
% 29.32/29.15  tff(decl_74638, type, fn_termite_73: $i > $i).
% 29.32/29.15  tff(decl_74639, type, fn_termite_74: $i > $i).
% 29.32/29.15  tff(decl_74640, type, fn_termite_75: $i > $i).
% 29.32/29.15  tff(decl_74641, type, fn_termite_76: $i > $i).
% 29.32/29.15  tff(decl_74642, type, fn_termite_77: $i > $i).
% 29.32/29.15  tff(decl_74643, type, fn_termite_78: $i > $i).
% 29.32/29.15  tff(decl_74644, type, fn_termite_79: $i > $i).
% 29.32/29.15  tff(decl_74645, type, fn_termite_80: $i > $i).
% 29.32/29.15  tff(decl_74646, type, fn_termite_83: $i > $i).
% 29.32/29.15  tff(decl_74647, type, fn_termite_84: $i > $i).
% 29.32/29.15  tff(decl_74648, type, fn_termite_85: $i > $i).
% 29.32/29.15  tff(decl_74649, type, fn_termite_86: $i > $i).
% 29.32/29.15  tff(decl_74650, type, fn_termite_87: $i > $i).
% 29.32/29.15  tff(decl_74651, type, fn_termite_88: $i > $i).
% 29.32/29.15  tff(decl_74652, type, fn_termite_89: $i > $i).
% 29.32/29.15  tff(decl_74653, type, fn_termite_90: $i > $i).
% 29.32/29.15  tff(decl_74654, type, fn_termite_91: $i > $i).
% 29.32/29.15  tff(decl_74655, type, fn_termite_92: $i > $i).
% 29.32/29.15  tff(decl_74656, type, fn_termite_95: $i > $i).
% 29.32/29.15  tff(decl_74657, type, fn_herbivore_11: $i > $i).
% 29.32/29.15  tff(decl_74658, type, fn_herbivore_1: $i > $i).
% 29.32/29.15  tff(decl_74659, type, fn_cellulose_digestion_2: $i > $i).
% 29.32/29.15  tff(decl_74660, type, fn_termite_81: $i > $i).
% 29.32/29.15  tff(decl_74661, type, fn_termite_82: $i > $i).
% 29.32/29.15  tff(decl_74662, type, fn_termite_93: $i > $i).
% 29.32/29.15  tff(decl_74663, type, fn_termite_94: $i > $i).
% 29.32/29.15  tff(decl_74664, type, 'Terrestrial-Biome': $i).
% 29.32/29.15  tff(decl_74665, type, 'A biome on land.': $i).
% 29.32/29.15  tff(decl_74666, type, 'terrestrial biome': $i).
% 29.32/29.15  tff(decl_74667, type, 'terrestrial-biome': $i).
% 29.32/29.15  tff(decl_74668, type, 'Terrestrial-Ecosystem': $i).
% 29.32/29.15  tff(decl_74669, type, 'An ecosystem located primarily on land.': $i).
% 29.32/29.15  tff(decl_74670, type, 'terrestrial ecosystem': $i).
% 29.32/29.15  tff(decl_74671, type, 'terrestrial-ecosystem': $i).
% 29.32/29.15  tff(decl_74672, type, 'Terrestrial-Nitrogen-Cycle': $i).
% 29.32/29.15  tff(decl_74673, type, 'The portion of the nitrogen cycle that occurs on land.': $i).
% 29.32/29.15  tff(decl_74674, type, 'undergo the terrestrial nitrogen cycle': $i).
% 29.32/29.15  tff(decl_74675, type, 'terrestrial nitrogen cycle': $i).
% 29.32/29.15  tff(decl_74676, type, 'terrestrial-nitrogen-cycle': $i).
% 29.32/29.15  tff(decl_74677, type, fn_terrestrial_nitrogen_cycle_1: $i > $i).
% 29.32/29.15  tff(decl_74678, type, fn_terrestrial_nitrogen_cycle_5: $i > $i).
% 29.32/29.15  tff(decl_74679, type, fn_terrestrial_nitrogen_cycle_6: $i > $i).
% 29.32/29.15  tff(decl_74680, type, fn_terrestrial_nitrogen_cycle_7: $i > $i).
% 29.32/29.15  tff(decl_74681, type, fn_terrestrial_nitrogen_cycle_9: $i > $i).
% 29.32/29.15  tff(decl_74682, type, fn_terrestrial_nitrogen_cycle_10: $i > $i).
% 29.32/29.15  tff(decl_74683, type, fn_terrestrial_nitrogen_cycle_11: $i > $i).
% 29.32/29.15  tff(decl_74684, type, fn_terrestrial_nitrogen_cycle_12: $i > $i).
% 29.32/29.15  tff(decl_74685, type, fn_terrestrial_nitrogen_cycle_13: $i > $i).
% 29.32/29.15  tff(decl_74686, type, fn_terrestrial_nitrogen_cycle_14: $i > $i).
% 29.32/29.15  tff(decl_74687, type, fn_terrestrial_nitrogen_cycle_15: $i > $i).
% 29.32/29.15  tff(decl_74688, type, fn_terrestrial_nitrogen_cycle_17: $i > $i).
% 29.32/29.15  tff(decl_74689, type, fn_terrestrial_nitrogen_cycle_18: $i > $i).
% 29.32/29.15  tff(decl_74690, type, fn_terrestrial_nitrogen_cycle_19: $i > $i).
% 29.32/29.15  tff(decl_74691, type, fn_terrestrial_nitrogen_cycle_21: $i > $i).
% 29.32/29.15  tff(decl_74692, type, fn_terrestrial_nitrogen_cycle_22: $i > $i).
% 29.32/29.15  tff(decl_74693, type, fn_terrestrial_nitrogen_cycle_25: $i > $i).
% 29.32/29.15  tff(decl_74694, type, fn_terrestrial_nitrogen_cycle_26: $i > $i).
% 29.32/29.15  tff(decl_74695, type, fn_terrestrial_nitrogen_cycle_27: $i > $i).
% 29.32/29.15  tff(decl_74696, type, fn_terrestrial_nitrogen_cycle_29: $i > $i).
% 29.32/29.15  tff(decl_74697, type, fn_terrestrial_nitrogen_cycle_30: $i > $i).
% 29.32/29.15  tff(decl_74698, type, fn_terrestrial_nitrogen_cycle_31: $i > $i).
% 29.32/29.15  tff(decl_74699, type, fn_terrestrial_nitrogen_cycle_32: $i > $i).
% 29.32/29.15  tff(decl_74700, type, fn_terrestrial_nitrogen_cycle_33: $i > $i).
% 29.32/29.15  tff(decl_74701, type, fn_terrestrial_nitrogen_cycle_35: $i > $i).
% 29.32/29.15  tff(decl_74702, type, fn_terrestrial_nitrogen_cycle_38: $i > $i).
% 29.32/29.15  tff(decl_74703, type, fn_terrestrial_nitrogen_cycle_39: $i > $i).
% 29.32/29.15  tff(decl_74704, type, fn_terrestrial_nitrogen_cycle_40: $i > $i).
% 29.32/29.15  tff(decl_74705, type, fn_terrestrial_nitrogen_cycle_41: $i > $i).
% 29.32/29.15  tff(decl_74706, type, fn_terrestrial_nitrogen_cycle_44: $i > $i).
% 29.32/29.15  tff(decl_74707, type, fn_terrestrial_nitrogen_cycle_45: $i > $i).
% 29.32/29.15  tff(decl_74708, type, fn_terrestrial_nitrogen_cycle_46: $i > $i).
% 29.32/29.15  tff(decl_74709, type, fn_terrestrial_nitrogen_cycle_47: $i > $i).
% 29.32/29.15  tff(decl_74710, type, fn_terrestrial_nitrogen_cycle_49: $i > $i).
% 29.32/29.15  tff(decl_74711, type, fn_terrestrial_nitrogen_cycle_50: $i > $i).
% 29.32/29.15  tff(decl_74712, type, fn_terrestrial_nitrogen_cycle_51: $i > $i).
% 29.32/29.15  tff(decl_74713, type, fn_terrestrial_nitrogen_cycle_52: $i > $i).
% 29.32/29.15  tff(decl_74714, type, fn_terrestrial_nitrogen_cycle_54: $i > $i).
% 29.32/29.15  tff(decl_74715, type, fn_terrestrial_nitrogen_cycle_55: $i > $i).
% 29.32/29.15  tff(decl_74716, type, fn_terrestrial_nitrogen_cycle_56: $i > $i).
% 29.32/29.15  tff(decl_74717, type, fn_terrestrial_nitrogen_cycle_57: $i > $i).
% 29.32/29.15  tff(decl_74718, type, fn_terrestrial_nitrogen_cycle_58: $i > $i).
% 29.32/29.15  tff(decl_74719, type, fn_terrestrial_nitrogen_cycle_59: $i > $i).
% 29.32/29.15  tff(decl_74720, type, fn_terrestrial_nitrogen_cycle_60: $i > $i).
% 29.32/29.15  tff(decl_74721, type, fn_terrestrial_nitrogen_cycle_61: $i > $i).
% 29.32/29.15  tff(decl_74722, type, fn_terrestrial_nitrogen_cycle_62: $i > $i).
% 29.32/29.15  tff(decl_74723, type, fn_terrestrial_nitrogen_cycle_63: $i > $i).
% 29.32/29.15  tff(decl_74724, type, fn_terrestrial_nitrogen_cycle_64: $i > $i).
% 29.32/29.15  tff(decl_74725, type, fn_terrestrial_nitrogen_cycle_65: $i > $i).
% 29.32/29.15  tff(decl_74726, type, fn_terrestrial_nitrogen_cycle_66: $i > $i).
% 29.32/29.15  tff(decl_74727, type, fn_terrestrial_nitrogen_cycle_67: $i > $i).
% 29.32/29.15  tff(decl_74728, type, fn_terrestrial_nitrogen_cycle_68: $i > $i).
% 29.32/29.15  tff(decl_74729, type, fn_terrestrial_nitrogen_cycle_69: $i > $i).
% 29.32/29.15  tff(decl_74730, type, fn_terrestrial_nitrogen_cycle_70: $i > $i).
% 29.32/29.15  tff(decl_74731, type, fn_terrestrial_nitrogen_cycle_71: $i > $i).
% 29.32/29.15  tff(decl_74732, type, fn_terrestrial_nitrogen_cycle_72: $i > $i).
% 29.32/29.15  tff(decl_74733, type, fn_terrestrial_nitrogen_cycle_73: $i > $i).
% 29.32/29.15  tff(decl_74734, type, fn_terrestrial_nitrogen_cycle_75: $i > $i).
% 29.32/29.15  tff(decl_74735, type, fn_terrestrial_nitrogen_cycle_74: $i > $i).
% 29.32/29.15  tff(decl_74736, type, 'Terrestrial-Organism': $i).
% 29.32/29.15  tff(decl_74737, type, 'A living thing adapted to live on land.': $i).
% 29.32/29.15  tff(decl_74738, type, 'land dwelling organism': $i).
% 29.32/29.15  tff(decl_74739, type, 'terrestrial organism': $i).
% 29.32/29.15  tff(decl_74740, type, 'terrestrial-organism': $i).
% 29.32/29.15  tff(decl_74741, type, 'Terrestrial-Plant': $i).
% 29.32/29.15  tff(decl_74742, type, 'A plant adapted to live on land.': $i).
% 29.32/29.15  tff(decl_74743, type, embryophyte: $i).
% 29.32/29.15  tff(decl_74744, type, 'terrestrial plant': $i).
% 29.32/29.15  tff(decl_74745, type, 'terrestrial-plant': $i).
% 29.32/29.15  tff(decl_74746, type, territoriality_1: $i > $o).
% 29.32/29.15  tff(decl_74747, type, 'Territoriality': $i).
% 29.32/29.15  tff(decl_74748, type, 'A competitive behavior in which an animal excludes other individuals from a physical space that it claims as its territory.': $i).
% 29.32/29.15  tff(decl_74749, type, territoriality: $i).
% 29.32/29.15  tff(decl_74750, type, 'Territory': $i).
% 29.32/29.15  tff(decl_74751, type, 'a relatively large Region delineated on some dimension (administrative, strategic, commercial, private, geographical, ...)': $i).
% 29.32/29.15  tff(decl_74752, type, territory: $i).
% 29.32/29.15  tff(decl_74753, type, district: $i).
% 29.32/29.15  tff(decl_74754, type, 'territorial dominion': $i).
% 29.32/29.15  tff(decl_74755, type, territorial_dominion: $i).
% 29.32/29.15  tff(decl_74756, type, dominion: $i).
% 29.32/29.15  tff(decl_74757, type, 'Tertiary-Consumer': $i).
% 29.32/29.15  tff(decl_74758, type, 'A member of a trophic chain that is above secondary consumers; an animal that feeds on other carnivores.': $i).
% 29.32/29.15  tff(decl_74759, type, 'consumer of tertiary': $i).
% 29.32/29.15  tff(decl_74760, type, 'tertiary consumer': $i).
% 29.32/29.15  tff(decl_74761, type, 'tertiary-consumer': $i).
% 29.32/29.15  tff(decl_74762, type, fn_tertiary_consumer_1: $i > $i).
% 29.32/29.15  tff(decl_74763, type, fn_tertiary_consumer_2: $i > $i).
% 29.32/29.15  tff(decl_74764, type, fn_tertiary_consumer_3: $i > $i).
% 29.32/29.15  tff(decl_74765, type, fn_tertiary_consumer_4: $i > $i).
% 29.32/29.15  tff(decl_74766, type, fn_tertiary_consumer_5: $i > $i).
% 29.32/29.15  tff(decl_74767, type, fn_tertiary_consumer_6: $i > $i).
% 29.32/29.15  tff(decl_74768, type, fn_tertiary_consumer_7: $i > $i).
% 29.32/29.15  tff(decl_74769, type, fn_tertiary_consumer_8: $i > $i).
% 29.32/29.15  tff(decl_74770, type, tertiary_consumers_1: $i > $o).
% 29.32/29.15  tff(decl_74771, type, 'Tertiary-Consumers': $i).
% 29.32/29.15  tff(decl_74772, type, 'Group of organisms in an ecosystem which feeds directly on secondary consumers.': $i).
% 29.32/29.15  tff(decl_74773, type, 'Tertiary-Protein-Structure': $i).
% 29.32/29.15  tff(decl_74774, type, 'The overall shape of a protein molecule due to interactions of amino acid side chains, including hydrophobic interactions, ionic bonds, hydrogen bonds, and disulfide bridges.': $i).
% 29.32/29.15  tff(decl_74775, type, 'third stage of protein folding': $i).
% 29.32/29.15  tff(decl_74776, type, 'tertiary structure': $i).
% 29.32/29.15  tff(decl_74777, type, 'tertiary protein structure': $i).
% 29.32/29.15  tff(decl_74778, type, 'tertiary-protein-structure': $i).
% 29.32/29.15  tff(decl_74779, type, fn_tertiary_protein_structure_1: $i > $i).
% 29.32/29.15  tff(decl_74780, type, fn_tertiary_protein_structure_2: $i > $i).
% 29.32/29.15  tff(decl_74781, type, fn_tertiary_protein_structure_3: $i > $i).
% 29.32/29.15  tff(decl_74782, type, fn_tertiary_protein_structure_6: $i > $i).
% 29.32/29.15  tff(decl_74783, type, fn_tertiary_protein_structure_7: $i > $i).
% 29.32/29.15  tff(decl_74784, type, fn_tertiary_protein_structure_8: $i > $i).
% 29.32/29.15  tff(decl_74785, type, fn_tertiary_protein_structure_9: $i > $i).
% 29.32/29.15  tff(decl_74786, type, fn_tertiary_protein_structure_10: $i > $i).
% 29.32/29.15  tff(decl_74787, type, fn_tertiary_protein_structure_11: $i > $i).
% 29.32/29.15  tff(decl_74788, type, fn_tertiary_protein_structure_12: $i > $i).
% 29.32/29.15  tff(decl_74789, type, fn_tertiary_protein_structure_13: $i > $i).
% 29.32/29.15  tff(decl_74790, type, fn_tertiary_protein_structure_14: $i > $i).
% 29.32/29.15  tff(decl_74791, type, fn_tertiary_protein_structure_15: $i > $i).
% 29.32/29.15  tff(decl_74792, type, fn_tertiary_protein_structure_16: $i > $i).
% 29.32/29.15  tff(decl_74793, type, fn_tertiary_protein_structure_17: $i > $i).
% 29.32/29.15  tff(decl_74794, type, fn_tertiary_protein_structure_18: $i > $i).
% 29.32/29.15  tff(decl_74795, type, fn_tertiary_protein_structure_19: $i > $i).
% 29.32/29.15  tff(decl_74796, type, fn_tertiary_protein_structure_20: $i > $i).
% 29.32/29.15  tff(decl_74797, type, fn_tertiary_protein_structure_21: $i > $i).
% 29.32/29.15  tff(decl_74798, type, fn_tertiary_protein_structure_22: $i > $i).
% 29.32/29.15  tff(decl_74799, type, fn_tertiary_protein_structure_23: $i > $i).
% 29.32/29.15  tff(decl_74800, type, fn_tertiary_protein_structure_24: $i > $i).
% 29.32/29.15  tff(decl_74801, type, fn_tertiary_protein_structure_25: $i > $i).
% 29.32/29.15  tff(decl_74802, type, fn_tertiary_protein_structure_26: $i > $i).
% 29.32/29.15  tff(decl_74803, type, fn_tertiary_protein_structure_27: $i > $i).
% 29.32/29.15  tff(decl_74804, type, fn_tertiary_protein_structure_28: $i > $i).
% 29.32/29.15  tff(decl_74805, type, fn_tertiary_protein_structure_29: $i > $i).
% 29.32/29.15  tff(decl_74806, type, fn_tertiary_protein_structure_30: $i > $i).
% 29.32/29.15  tff(decl_74807, type, fn_tertiary_protein_structure_31: $i > $i).
% 29.32/29.15  tff(decl_74808, type, fn_tertiary_protein_structure_32: $i > $i).
% 29.32/29.15  tff(decl_74809, type, fn_tertiary_protein_structure_33: $i > $i).
% 29.32/29.15  tff(decl_74810, type, fn_tertiary_protein_structure_34: $i > $i).
% 29.32/29.15  tff(decl_74811, type, fn_tertiary_protein_structure_35: $i > $i).
% 29.32/29.15  tff(decl_74812, type, fn_tertiary_protein_structure_36: $i > $i).
% 29.32/29.15  tff(decl_74813, type, fn_tertiary_protein_structure_37: $i > $i).
% 29.32/29.15  tff(decl_74814, type, fn_tertiary_protein_structure_38: $i > $i).
% 29.32/29.15  tff(decl_74815, type, fn_tertiary_protein_structure_39: $i > $i).
% 29.32/29.15  tff(decl_74816, type, fn_tertiary_protein_structure_40: $i > $i).
% 29.32/29.15  tff(decl_74817, type, fn_tertiary_protein_structure_41: $i > $i).
% 29.32/29.15  tff(decl_74818, type, fn_tertiary_protein_structure_42: $i > $i).
% 29.32/29.15  tff(decl_74819, type, fn_tertiary_protein_structure_43: $i > $i).
% 29.32/29.15  tff(decl_74820, type, fn_tertiary_protein_structure_44: $i > $i).
% 29.32/29.15  tff(decl_74821, type, fn_tertiary_protein_structure_45: $i > $i).
% 29.32/29.15  tff(decl_74822, type, fn_tertiary_protein_structure_46: $i > $i).
% 29.32/29.15  tff(decl_74823, type, fn_tertiary_protein_structure_47: $i > $i).
% 29.32/29.15  tff(decl_74824, type, fn_tertiary_protein_structure_48: $i > $i).
% 29.32/29.15  tff(decl_74825, type, fn_tertiary_protein_structure_49: $i > $i).
% 29.32/29.15  tff(decl_74826, type, fn_tertiary_protein_structure_50: $i > $i).
% 29.32/29.15  tff(decl_74827, type, fn_tertiary_protein_structure_51: $i > $i).
% 29.32/29.15  tff(decl_74828, type, fn_tertiary_protein_structure_52: $i > $i).
% 29.32/29.15  tff(decl_74829, type, fn_tertiary_protein_structure_53: $i > $i).
% 29.32/29.15  tff(decl_74830, type, fn_tertiary_protein_structure_54: $i > $i).
% 29.32/29.15  tff(decl_74831, type, fn_tertiary_protein_structure_55: $i > $i).
% 29.32/29.15  tff(decl_74832, type, fn_tertiary_protein_structure_56: $i > $i).
% 29.32/29.15  tff(decl_74833, type, fn_tertiary_protein_structure_57: $i > $i).
% 29.32/29.15  tff(decl_74834, type, fn_tertiary_protein_structure_58: $i > $i).
% 29.32/29.15  tff(decl_74835, type, fn_tertiary_protein_structure_59: $i > $i).
% 29.32/29.15  tff(decl_74836, type, fn_tertiary_protein_structure_60: $i > $i).
% 29.32/29.15  tff(decl_74837, type, fn_tertiary_protein_structure_61: $i > $i).
% 29.32/29.15  tff(decl_74838, type, fn_tertiary_protein_structure_62: $i > $i).
% 29.32/29.15  tff(decl_74839, type, fn_tertiary_protein_structure_63: $i > $i).
% 29.32/29.15  tff(decl_74840, type, fn_tertiary_protein_structure_64: $i > $i).
% 29.32/29.15  tff(decl_74841, type, fn_tertiary_protein_structure_66: $i > $i).
% 29.32/29.15  tff(decl_74842, type, fn_tertiary_protein_structure_67: $i > $i).
% 29.32/29.15  tff(decl_74843, type, fn_tertiary_protein_structure_68: $i > $i).
% 29.32/29.15  tff(decl_74844, type, fn_tertiary_protein_structure_69: $i > $i).
% 29.32/29.15  tff(decl_74845, type, fn_tertiary_protein_structure_70: $i > $i).
% 29.32/29.15  tff(decl_74846, type, fn_tertiary_protein_structure_71: $i > $i).
% 29.32/29.15  tff(decl_74847, type, fn_tertiary_protein_structure_72: $i > $i).
% 29.32/29.15  tff(decl_74848, type, fn_tertiary_protein_structure_73: $i > $i).
% 29.32/29.15  tff(decl_74849, type, fn_tertiary_protein_structure_74: $i > $i).
% 29.32/29.15  tff(decl_74850, type, fn_tertiary_protein_structure_75: $i > $i).
% 29.32/29.15  tff(decl_74851, type, fn_tertiary_protein_structure_76: $i > $i).
% 29.32/29.15  tff(decl_74852, type, fn_tertiary_protein_structure_77: $i > $i).
% 29.32/29.15  tff(decl_74853, type, fn_tertiary_protein_structure_78: $i > $i).
% 29.32/29.15  tff(decl_74854, type, fn_tertiary_protein_structure_79: $i > $i).
% 29.32/29.15  tff(decl_74855, type, fn_tertiary_protein_structure_80: $i > $i).
% 29.32/29.15  tff(decl_74856, type, fn_tertiary_protein_structure_81: $i > $i).
% 29.32/29.15  tff(decl_74857, type, fn_tertiary_protein_structure_82: $i > $i).
% 29.32/29.15  tff(decl_74858, type, fn_tertiary_protein_structure_83: $i > $i).
% 29.32/29.15  tff(decl_74859, type, fn_tertiary_protein_structure_84: $i > $i).
% 29.32/29.15  tff(decl_74860, type, fn_tertiary_protein_structure_85: $i > $i).
% 29.32/29.15  tff(decl_74861, type, fn_tertiary_protein_structure_86: $i > $i).
% 29.32/29.15  tff(decl_74862, type, fn_tertiary_protein_structure_87: $i > $i).
% 29.32/29.15  tff(decl_74863, type, fn_tertiary_protein_structure_88: $i > $i).
% 29.32/29.15  tff(decl_74864, type, fn_tertiary_protein_structure_89: $i > $i).
% 29.32/29.15  tff(decl_74865, type, fn_tertiary_protein_structure_90: $i > $i).
% 29.32/29.15  tff(decl_74866, type, fn_tertiary_protein_structure_91: $i > $i).
% 29.32/29.15  tff(decl_74867, type, fn_tertiary_protein_structure_92: $i > $i).
% 29.32/29.15  tff(decl_74868, type, fn_tertiary_protein_structure_93: $i > $i).
% 29.32/29.15  tff(decl_74869, type, fn_tertiary_protein_structure_94: $i > $i).
% 29.32/29.15  tff(decl_74870, type, fn_tertiary_protein_structure_95: $i > $i).
% 29.32/29.15  tff(decl_74871, type, fn_tertiary_protein_structure_96: $i > $i).
% 29.32/29.15  tff(decl_74872, type, fn_tertiary_protein_structure_97: $i > $i).
% 29.32/29.15  tff(decl_74873, type, fn_tertiary_protein_structure_98: $i > $i).
% 29.32/29.15  tff(decl_74874, type, fn_tertiary_protein_structure_99: $i > $i).
% 29.32/29.15  tff(decl_74875, type, fn_tertiary_protein_structure_100: $i > $i).
% 29.32/29.15  tff(decl_74876, type, fn_tertiary_protein_structure_101: $i > $i).
% 29.32/29.15  tff(decl_74877, type, fn_tertiary_protein_structure_102: $i > $i).
% 29.32/29.15  tff(decl_74878, type, fn_tertiary_protein_structure_103: $i > $i).
% 29.32/29.15  tff(decl_74879, type, fn_tertiary_protein_structure_104: $i > $i).
% 29.32/29.15  tff(decl_74880, type, fn_tertiary_protein_structure_105: $i > $i).
% 29.32/29.15  tff(decl_74881, type, fn_tertiary_protein_structure_106: $i > $i).
% 29.32/29.15  tff(decl_74882, type, fn_tertiary_protein_structure_107: $i > $i).
% 29.32/29.15  tff(decl_74883, type, fn_tertiary_protein_structure_108: $i > $i).
% 29.32/29.15  tff(decl_74884, type, fn_tertiary_protein_structure_109: $i > $i).
% 29.32/29.15  tff(decl_74885, type, fn_tertiary_protein_structure_110: $i > $i).
% 29.32/29.15  tff(decl_74886, type, fn_tertiary_protein_structure_111: $i > $i).
% 29.32/29.15  tff(decl_74887, type, fn_tertiary_protein_structure_112: $i > $i).
% 29.32/29.15  tff(decl_74888, type, fn_tertiary_protein_structure_113: $i > $i).
% 29.32/29.15  tff(decl_74889, type, fn_tertiary_protein_structure_114: $i > $i).
% 29.32/29.15  tff(decl_74890, type, fn_tertiary_protein_structure_115: $i > $i).
% 29.32/29.15  tff(decl_74891, type, fn_tertiary_protein_structure_116: $i > $i).
% 29.32/29.15  tff(decl_74892, type, fn_tertiary_protein_structure_117: $i > $i).
% 29.32/29.15  tff(decl_74893, type, fn_hydrogen_bond_1: $i > $i).
% 29.32/29.15  tff(decl_74894, type, fn_tertiary_protein_structure_118: $i > $i).
% 29.32/29.15  tff(decl_74895, type, fn_tertiary_protein_structure_4: $i > $i).
% 29.32/29.15  tff(decl_74896, type, fn_tertiary_protein_structure_5: $i > $i).
% 29.32/29.15  tff(decl_74897, type, 'Test-Tube': $i).
% 29.32/29.15  tff(decl_74898, type, 'Test tube is a cylindrical container used to carry a material on which a study is done.': $i).
% 29.32/29.15  tff(decl_74899, type, 'tube of test': $i).
% 29.32/29.15  tff(decl_74900, type, 'test tube': $i).
% 29.32/29.15  tff(decl_74901, type, 'test-tube': $i).
% 29.32/29.15  tff(decl_74902, type, 'Test-Tube-Cloning': $i).
% 29.32/29.15  tff(decl_74903, type, 'The in vitro method of cloning an organism using tissue from the original organism and an artificial medium containing nutrients.': $i).
% 29.32/29.15  tff(decl_74904, type, 'test tube cloning': $i).
% 29.32/29.15  tff(decl_74905, type, 'test-tube-cloning': $i).
% 29.32/29.15  tff(decl_74906, type, 'Testcross': $i).
% 29.32/29.15  tff(decl_74907, type, 'Breeding an organism of unknown genotype with a homozygous recessive individual to determine the unknown genotype. The ratio of phenotypes in the offspring reveals the unknown genotype.': $i).
% 29.32/29.15  tff(decl_74908, type, 'test cross': $i).
% 29.32/29.15  tff(decl_74909, type, testcross: $i).
% 29.32/29.15  tff(decl_74910, type, fn_testcross_1: $i > $i).
% 29.32/29.15  tff(decl_74911, type, fn_testcross_2: $i > $i).
% 29.32/29.15  tff(decl_74912, type, fn_testcross_3: $i > $i).
% 29.32/29.15  tff(decl_74913, type, 'Testes': $i).
% 29.32/29.15  tff(decl_74914, type, 'Male gonads, where reproductive hormones and sperm are produced.': $i).
% 29.32/29.15  tff(decl_74915, type, testis: $i).
% 29.32/29.15  tff(decl_74916, type, fn_testes_1: $i > $i).
% 29.32/29.15  tff(decl_74917, type, fn_testes_2: $i > $i).
% 29.32/29.15  tff(decl_74918, type, fn_testes_3: $i > $i).
% 29.32/29.15  tff(decl_74919, type, fn_testes_4: $i > $i).
% 29.32/29.15  tff(decl_74920, type, 'Testosterone': $i).
% 29.32/29.15  tff(decl_74921, type, 'Testosterone is a steroid hormone from the androgen group and is found in mammals, reptiles, birds,and other vertebrates.': $i).
% 29.32/29.15  tff(decl_74922, type, 'male sex hormone': $i).
% 29.32/29.15  tff(decl_74923, type, 'male-sex-hormone': $i).
% 29.32/29.15  tff(decl_74924, type, testosterone: $i).
% 29.32/29.15  tff(decl_74925, type, fn_testosterone_3: $i > $i).
% 29.32/29.15  tff(decl_74926, type, fn_testosterone_4: $i > $i).
% 29.32/29.15  tff(decl_74927, type, fn_testosterone_5: $i > $i).
% 29.32/29.15  tff(decl_74928, type, fn_testosterone_6: $i > $i).
% 29.32/29.15  tff(decl_74929, type, fn_testosterone_7: $i > $i).
% 29.32/29.15  tff(decl_74930, type, fn_testosterone_8: $i > $i).
% 29.32/29.15  tff(decl_74931, type, fn_testosterone_10: $i > $i).
% 29.32/29.15  tff(decl_74932, type, fn_testosterone_11: $i > $i).
% 29.32/29.15  tff(decl_74933, type, fn_testosterone_13: $i > $i).
% 29.32/29.15  tff(decl_74934, type, fn_testosterone_2: $i > $i).
% 29.32/29.15  tff(decl_74935, type, fn_testosterone_1: $i > $i).
% 29.32/29.15  tff(decl_74936, type, 'Testosterone-Receptor': $i).
% 29.32/29.15  tff(decl_74937, type, 'Receptor that testosterone binds to to initiate a cell signal transduction event.': $i).
% 29.32/29.15  tff(decl_74938, type, 'receptor of testosterone': $i).
% 29.32/29.15  tff(decl_74939, type, 'testosterone receptor': $i).
% 29.32/29.15  tff(decl_74940, type, 'testosterone-receptor': $i).
% 29.32/29.15  tff(decl_74941, type, testosterone_secretion_in_males_1: $i > $o).
% 29.32/29.15  tff(decl_74942, type, 'Testosterone-Secretion-In-Males': $i).
% 29.32/29.15  tff(decl_74943, type, 'The process of producing and releasing testosterone from the testis.': $i).
% 29.32/29.15  tff(decl_74944, type, 'testosterone secretion in male': $i).
% 29.32/29.15  tff(decl_74945, type, 'testosterone-secretion-in-male': $i).
% 29.32/29.15  tff(decl_74946, type, fn_testosterone_secretion_in_males_1: $i > $i).
% 29.32/29.15  tff(decl_74947, type, fn_testosterone_secretion_in_males_2: $i > $i).
% 29.32/29.15  tff(decl_74948, type, fn_testosterone_secretion_in_males_3: $i > $i).
% 29.32/29.15  tff(decl_74949, type, fn_testosterone_secretion_in_males_4: $i > $i).
% 29.32/29.15  tff(decl_74950, type, fn_testosterone_secretion_in_males_5: $i > $i).
% 29.32/29.15  tff(decl_74951, type, 'Tetanus': $i).
% 29.32/29.15  tff(decl_74952, type, 'The prolonged maximal contraction of a skeletal muscle, usually caused by toxins produced by the bacterium Clostridium tetani.': $i).
% 29.32/29.15  tff(decl_74953, type, lockjaw: $i).
% 29.32/29.15  tff(decl_74954, type, tetanus: $i).
% 29.32/29.15  tff(decl_74955, type, 'Tetracycline': $i).
% 29.32/29.15  tff(decl_74956, type, 'A broad spectrum antibiotic used to treat bacterial infections, including pneumonia and other respiratory tract infections; acne; infections of skin, genital and urinary systems; and the infection that causes stomach ulcers.': $i).
% 29.32/29.15  tff(decl_74957, type, tetracycline: $i).
% 29.32/29.15  tff(decl_74958, type, 'Tetrad': $i).
% 29.32/29.15  tff(decl_74959, type, 'Complex of homologous chromosomes formed during synapsis, totalling 4 chromatids.': $i).
% 29.32/29.15  tff(decl_74960, type, 'pair of homologous chromosome': $i).
% 29.32/29.15  tff(decl_74961, type, 'pair-of-homologous-chromosome': $i).
% 29.32/29.15  tff(decl_74962, type, 'homologous chromosome pair': $i).
% 29.32/29.15  tff(decl_74963, type, 'homologous-chromosome-pair': $i).
% 29.32/29.15  tff(decl_74964, type, tetrad: $i).
% 29.32/29.15  tff(decl_74965, type, 'Tetrapod': $i).
% 29.32/29.15  tff(decl_74966, type, 'A vertebrate with two pairs of limbs; includes reptiles, birds, amphibians, and mammals.': $i).
% 29.32/29.15  tff(decl_74967, type, tetrapod: $i).
% 29.32/29.15  tff(decl_74968, type, 'Tetrapod-Fish': $i).
% 29.32/29.15  tff(decl_74969, type, 'Member of an extinct tetrapod, Acanthostega, which was one of the first vertebrates to have recognizable limbs.': $i).
% 29.32/29.15  tff(decl_74970, type, acanthostega: $i).
% 29.32/29.15  tff(decl_74971, type, lobster: $i).
% 29.32/29.15  tff(decl_74972, type, 'fish of tetrapod': $i).
% 29.32/29.15  tff(decl_74973, type, 'tetrapod fish': $i).
% 29.32/29.15  tff(decl_74974, type, 'tetrapod-fish': $i).
% 29.32/29.15  tff(decl_74975, type, 'Text-Field': $i).
% 29.32/29.15  tff(decl_74976, type, 'a message field whose content is a text constant': $i).
% 29.32/29.15  tff(decl_74977, type, 'field of text': $i).
% 29.32/29.15  tff(decl_74978, type, 'text field': $i).
% 29.32/29.15  tff(decl_74979, type, 'text-field': $i).
% 29.32/29.15  tff(decl_74980, type, 'Texture-Constant': $i).
% 29.32/29.15  tff(decl_74981, type, 'constant of texture': $i).
% 29.32/29.15  tff(decl_74982, type, 'texture constant': $i).
% 29.32/29.15  tff(decl_74983, type, 'texture-constant': $i).
% 29.32/29.15  tff(decl_74984, type, 'Texture-Value': $i).
% 29.32/29.15  tff(decl_74985, type, 'the feel of a surface or a fabric': $i).
% 29.32/29.15  tff(decl_74986, type, texture: $i).
% 29.32/29.15  tff(decl_74987, type, 'value of texture': $i).
% 29.32/29.15  tff(decl_74988, type, 'texture value': $i).
% 29.32/29.15  tff(decl_74989, type, 'texture-value': $i).
% 29.32/29.15  tff(decl_74990, type, 'Thalamus': $i).
% 29.32/29.15  tff(decl_74991, type, 'A structure in the vertebrate brain, located between the cerebral cortex and the midbrain. It functions as a relay station, directing sensory and motor signals to the cerebral cortex and regulating consciousness, sleep, and alertness.': $i).
% 29.32/29.15  tff(decl_74992, type, thalamus: $i).
% 29.32/29.15  tff(decl_74993, type, thalidomide_1: $i > $o).
% 29.32/29.15  tff(decl_74994, type, 'Thalidomide': $i).
% 29.32/29.15  tff(decl_74995, type, 'A drug prescribed to pregnant women in the 1950s and 1960s, to prevent or reduce morning sickness. It was later found to be a teratogen that caused severe birth defects.': $i).
% 29.32/29.15  tff(decl_74996, type, thalidomide: $i).
% 29.32/29.15  tff(decl_74997, type, thallium_1: $i > $o).
% 29.32/29.15  tff(decl_74998, type, 'Thallium': $i).
% 29.32/29.15  tff(decl_74999, type, 'Thallium is a metal atom with atomic number 81. It is represented by the symbol Tl.': $i).
% 29.32/29.15  tff(decl_75000, type, thallium: $i).
% 29.32/29.15  tff(decl_75001, type, 'Tl': $i).
% 29.32/29.15  tff(decl_75002, type, fn_thallium_3: $i > $i).
% 29.32/29.15  tff(decl_75003, type, fn_thallium_4: $i > $i).
% 29.32/29.15  tff(decl_75004, type, fn_thallium_5: $i > $i).
% 29.32/29.15  tff(decl_75005, type, fn_thallium_9: $i > $i).
% 29.32/29.15  tff(decl_75006, type, fn_thallium_10: $i > $i).
% 29.32/29.15  tff(decl_75007, type, fn_thallium_11: $i > $i).
% 29.32/29.15  tff(decl_75008, type, fn_thallium_12: $i > $i).
% 29.32/29.15  tff(decl_75009, type, "123": $i).
% 29.32/29.15  tff(decl_75010, type, "204": $i).
% 29.32/29.15  tff(decl_75011, type, "204.4": $i).
% 29.32/29.15  tff(decl_75012, type, fn_thallium_7: $i > $i).
% 29.32/29.15  tff(decl_75013, type, fn_thallium_8: $i > $i).
% 29.32/29.15  tff(decl_75014, type, fn_thallium_6: $i > $i).
% 29.32/29.15  tff(decl_75015, type, thallus_1: $i > $o).
% 29.32/29.15  tff(decl_75016, type, 'Thallus': $i).
% 29.32/29.15  tff(decl_75017, type, 'The body of a seaweed, consisting of a holdfast, stipe, and blades. Lacks plant structures such as roots, leaves, and stems.': $i).
% 29.32/29.15  tff(decl_75018, type, thallus: $i).
% 29.32/29.15  tff(decl_75019, type, 'Theory': $i).
% 29.32/29.15  tff(decl_75020, type, 'In science, an explanation of a natural phenomenon that is broad in scope, supported by much evidence, and from which new hypotheses are generated.': $i).
% 29.32/29.15  tff(decl_75021, type, theory: $i).
% 29.32/29.15  tff(decl_75022, type, therapeutic_cloning_1: $i > $o).
% 29.32/29.15  tff(decl_75023, type, 'Therapeutic-Cloning': $i).
% 29.32/29.15  tff(decl_75024, type, 'A technique to create a cloned ovum that has a donor nucleus.': $i).
% 29.32/29.15  tff(decl_75025, type, 'somatic cell nuclear transfer': $i).
% 29.32/29.15  tff(decl_75026, type, 'therapeutic cloning': $i).
% 29.32/29.15  tff(decl_75027, type, 'therapeutic-cloning': $i).
% 29.32/29.15  tff(decl_75028, type, fn_therapeutic_cloning_1: $i > $i).
% 29.32/29.15  tff(decl_75029, type, fn_therapeutic_cloning_2: $i > $i).
% 29.32/29.15  tff(decl_75030, type, fn_therapeutic_cloning_3: $i > $i).
% 29.32/29.15  tff(decl_75031, type, fn_therapeutic_cloning_4: $i > $i).
% 29.32/29.15  tff(decl_75032, type, fn_therapeutic_cloning_5: $i > $i).
% 29.32/29.15  tff(decl_75033, type, fn_therapeutic_cloning_6: $i > $i).
% 29.32/29.15  tff(decl_75034, type, fn_therapeutic_cloning_7: $i > $i).
% 29.32/29.15  tff(decl_75035, type, fn_therapeutic_cloning_8: $i > $i).
% 29.32/29.15  tff(decl_75036, type, 'Thermal-Energy': $i).
% 29.32/29.15  tff(decl_75037, type, 'Energy that produces heat is thermal energy.': $i).
% 29.32/29.15  tff(decl_75038, type, 'heat energy': $i).
% 29.32/29.15  tff(decl_75039, type, 'heat-energy': $i).
% 29.32/29.15  tff(decl_75040, type, 'energy of thermal': $i).
% 29.32/29.15  tff(decl_75041, type, 'thermal energy': $i).
% 29.32/29.15  tff(decl_75042, type, 'thermal-energy': $i).
% 29.32/29.15  tff(decl_75043, type, thermal_energy_increase_in_organism_1: $i > $o).
% 29.32/29.15  tff(decl_75044, type, 'Thermal-Energy-Increase-In-Organism': $i).
% 29.32/29.15  tff(decl_75045, type, 'An increase in thermal energy increases the temperature of an organism.': $i).
% 29.32/29.15  tff(decl_75046, type, 'thermal energy increase in organism': $i).
% 29.32/29.15  tff(decl_75047, type, 'thermal-energy-increase-in-organism': $i).
% 29.32/29.15  tff(decl_75048, type, fn_thermal_energy_increase_in_organism_1: $i > $i).
% 29.32/29.15  tff(decl_75049, type, fn_thermal_energy_increase_in_organism_2: $i > $i).
% 29.32/29.15  tff(decl_75050, type, fn_thermal_energy_increase_in_organism_3: $i > $i).
% 29.32/29.15  tff(decl_75051, type, fn_thermal_energy_increase_in_organism_6: $i > $i).
% 29.32/29.15  tff(decl_75052, type, fn_thermal_energy_increase_in_organism_7: $i > $i).
% 29.32/29.15  tff(decl_75053, type, fn_thermal_energy_increase_in_organism_5: $i > $i).
% 29.32/29.15  tff(decl_75054, type, fn_thermal_energy_increase_in_organism_4: $i > $i).
% 29.32/29.15  tff(decl_75055, type, 'Thermal-Motion': $i).
% 29.32/29.15  tff(decl_75056, type, 'The constant, random movement of molecules.': $i).
% 29.32/29.15  tff(decl_75057, type, 'motion of thermal': $i).
% 29.32/29.15  tff(decl_75058, type, 'thermal motion': $i).
% 29.32/29.15  tff(decl_75059, type, 'thermal-motion': $i).
% 29.32/29.15  tff(decl_75060, type, fn_thermal_motion_1: $i > $i).
% 29.32/29.15  tff(decl_75061, type, fn_thermal_motion_2: $i > $i).
% 29.32/29.15  tff(decl_75062, type, thermocline_1: $i > $o).
% 29.32/29.15  tff(decl_75063, type, 'Thermocline': $i).
% 29.32/29.15  tff(decl_75064, type, 'A thin layer in a large body of water or air in which the temperature changes more rapidly with depth than in the layers above and below.': $i).
% 29.32/29.15  tff(decl_75065, type, thermocline: $i).
% 29.32/29.15  tff(decl_75066, type, 'Thermocycler': $i).
% 29.32/29.15  tff(decl_75067, type, 'The thermocycler is a laboratory apparatus used to amplify segments of DNA via the polymerase chain reaction (PCR) process.': $i).
% 29.32/29.15  tff(decl_75068, type, 'pcr machine': $i).
% 29.32/29.15  tff(decl_75069, type, thermalcycler: $i).
% 29.32/29.15  tff(decl_75070, type, 'thermal cycler': $i).
% 29.32/29.15  tff(decl_75071, type, 'thermal-cycler': $i).
% 29.32/29.15  tff(decl_75072, type, thermocycler: $i).
% 29.32/29.15  tff(decl_75073, type, fn_thermocycler_2: $i > $i).
% 29.32/29.15  tff(decl_75074, type, fn_thermocycler_3: $i > $i).
% 29.32/29.15  tff(decl_75075, type, fn_thermocycler_4: $i > $i).
% 29.32/29.15  tff(decl_75076, type, "75.0e0": $i).
% 29.32/29.15  tff(decl_75077, type, fn_thermocycler_5: $i > $i).
% 29.32/29.15  tff(decl_75078, type, 'Thermodynamic-System': $i).
% 29.32/29.15  tff(decl_75079, type, 'A thermodynamic system is a precisely defined macroscopic region of the universe, often called a physical system, that is studied using the principles of thermodynamics.': $i).
% 29.32/29.15  tff(decl_75080, type, 'thermodynamic system': $i).
% 29.32/29.15  tff(decl_75081, type, 'thermodynamic-system': $i).
% 29.32/29.15  tff(decl_75082, type, 'Thermodynamics': $i).
% 29.32/29.15  tff(decl_75083, type, 'The branch of science that studies the energy transformations that occur in physical systems.': $i).
% 29.32/29.15  tff(decl_75084, type, thermodynamics: $i).
% 29.32/29.15  tff(decl_75085, type, fn_thermodynamics_1: $i > $i).
% 29.32/29.15  tff(decl_75086, type, fn_thermodynamics_2: $i > $i).
% 29.32/29.15  tff(decl_75087, type, fn_thermodynamics_3: $i > $i).
% 29.32/29.15  tff(decl_75088, type, fn_thermodynamics_4: $i > $i).
% 29.32/29.15  tff(decl_75089, type, 'Thermoreceptor': $i).
% 29.32/29.15  tff(decl_75090, type, 'A sensory receptor that is stimulated by either heat or cold.': $i).
% 29.32/29.15  tff(decl_75091, type, thermoreceptor: $i).
% 29.32/29.15  tff(decl_75092, type, 'Thermoregulation': $i).
% 29.32/29.15  tff(decl_75093, type, 'The ability to maintain the internal body temperature within a range in which physiological processes can occur normally.': $i).
% 29.32/29.15  tff(decl_75094, type, thermoregulation: $i).
% 29.32/29.15  tff(decl_75095, type, theropod_1: $i > $o).
% 29.32/29.15  tff(decl_75096, type, 'Theropod': $i).
% 29.32/29.15  tff(decl_75097, type, 'Member of a clade that includes saurischian dinosaurs (bipedal carnivores such as T. rex) and birds.': $i).
% 29.32/29.15  tff(decl_75098, type, theropod: $i).
% 29.32/29.15  tff(decl_75099, type, 'Thick-Filament': $i).
% 29.32/29.15  tff(decl_75100, type, 'In muscle fibers, a filament made of arrangements of myosin molecules.': $i).
% 29.32/29.15  tff(decl_75101, type, 'thick fiber': $i).
% 29.32/29.15  tff(decl_75102, type, 'thick-fiber': $i).
% 29.32/29.15  tff(decl_75103, type, 'filament of thick': $i).
% 29.32/29.15  tff(decl_75104, type, 'thick filament': $i).
% 29.32/29.15  tff(decl_75105, type, 'thick-filament': $i).
% 29.32/29.15  tff(decl_75106, type, 'Thickness-Constant': $i).
% 29.32/29.15  tff(decl_75107, type, 'constant of thickness': $i).
% 29.32/29.15  tff(decl_75108, type, 'thickness constant': $i).
% 29.32/29.15  tff(decl_75109, type, 'thickness-constant': $i).
% 29.32/29.15  tff(decl_75110, type, thickness_scale_1: $i > $o).
% 29.32/29.15  tff(decl_75111, type, 'Thickness-Scale': $i).
% 29.32/29.15  tff(decl_75112, type, 'scale of thickness': $i).
% 29.32/29.15  tff(decl_75113, type, 'thickness scale': $i).
% 29.32/29.15  tff(decl_75114, type, 'thickness-scale': $i).
% 29.32/29.15  tff(decl_75115, type, 'Thigmomorphogenesis': $i).
% 29.32/29.15  tff(decl_75116, type, 'In plants, an altered growth pattern in response to a mechanical stimulus, such as consistent strong winds.': $i).
% 29.32/29.15  tff(decl_75117, type, thigmomorphogenesis: $i).
% 29.32/29.15  tff(decl_75118, type, 'Thigmotropism': $i).
% 29.32/29.15  tff(decl_75119, type, 'In plants, directional movement or growth in response to a mechanical stimulus.': $i).
% 29.32/29.15  tff(decl_75120, type, thigmotropism: $i).
% 29.32/29.15  tff(decl_75121, type, 'Thin-Filament': $i).
% 29.32/29.15  tff(decl_75122, type, 'In muscle fibers, a filament made of paired strands of actin and protein coiled together.': $i).
% 29.32/29.15  tff(decl_75123, type, 'thin fiber': $i).
% 29.32/29.15  tff(decl_75124, type, 'thin-fiber': $i).
% 29.32/29.15  tff(decl_75125, type, 'thin filament': $i).
% 29.32/29.15  tff(decl_75126, type, 'thin-filament': $i).
% 29.32/29.15  tff(decl_75127, type, thiol_1: $i > $o).
% 29.32/29.15  tff(decl_75128, type, 'Thiol': $i).
% 29.32/29.15  tff(decl_75129, type, 'A thiol is an organosulfur compound that contains a sulfur-hydrogen bond (S-H).': $i).
% 29.32/29.15  tff(decl_75130, type, thiol: $i).
% 29.32/29.15  tff(decl_75131, type, fn_thiol_3: $i > $i).
% 29.32/29.15  tff(decl_75132, type, fn_thiol_4: $i > $i).
% 29.32/29.15  tff(decl_75133, type, fn_thiol_5: $i > $i).
% 29.32/29.15  tff(decl_75134, type, fn_thiol_6: $i > $i).
% 29.32/29.15  tff(decl_75135, type, fn_thiol_7: $i > $i).
% 29.32/29.15  tff(decl_75136, type, fn_thiol_8: $i > $i).
% 29.32/29.15  tff(decl_75137, type, fn_thiol_9: $i > $i).
% 29.32/29.15  tff(decl_75138, type, fn_thiol_10: $i > $i).
% 29.32/29.15  tff(decl_75139, type, fn_thiol_11: $i > $i).
% 29.32/29.15  tff(decl_75140, type, fn_thiol_12: $i > $i).
% 29.32/29.15  tff(decl_75141, type, fn_thiol_1: $i > $i).
% 29.32/29.15  tff(decl_75142, type, fn_thiol_2: $i > $i).
% 29.32/29.15  tff(decl_75143, type, 'Third-Electron-Shell': $i).
% 29.32/29.15  tff(decl_75144, type, 'The third energy shell of an atom, containing the valence electrons involved in the chemical reactions of that atom.': $i).
% 29.32/29.15  tff(decl_75145, type, 'third electron shell': $i).
% 29.32/29.15  tff(decl_75146, type, 'third electron-shell': $i).
% 29.32/29.15  tff(decl_75147, type, 'third-electron-shell': $i).
% 29.32/29.15  tff(decl_75148, type, fn_third_electron_shell_1: $i > $i).
% 29.32/29.15  tff(decl_75149, type, fn_third_electron_shell_2: $i > $i).
% 29.32/29.15  tff(decl_75150, type, fn_third_electron_shell_3: $i > $i).
% 29.32/29.15  tff(decl_75151, type, fn_third_electron_shell_4: $i > $i).
% 29.32/29.15  tff(decl_75152, type, 'Thorax': $i).
% 29.32/29.15  tff(decl_75153, type, 'The thorax is a division of an animal\\s body that lies between the head and the abdomen.': $i).
% 29.32/29.15  tff(decl_75154, type, thorax: $i).
% 29.32/29.15  tff(decl_75155, type, thorium_1: $i > $o).
% 29.32/29.15  tff(decl_75156, type, 'Thorium': $i).
% 29.32/29.15  tff(decl_75157, type, 'Thorium is a metal atom with atomic number 90. It is represented by the symbol Th.': $i).
% 29.32/29.15  tff(decl_75158, type, thorium: $i).
% 29.32/29.15  tff(decl_75159, type, th: $i).
% 29.32/29.15  tff(decl_75160, type, fn_thorium_4: $i > $i).
% 29.32/29.15  tff(decl_75161, type, fn_thorium_5: $i > $i).
% 29.32/29.15  tff(decl_75162, type, fn_thorium_6: $i > $i).
% 29.32/29.15  tff(decl_75163, type, fn_thorium_7: $i > $i).
% 29.32/29.15  tff(decl_75164, type, fn_thorium_11: $i > $i).
% 29.32/29.15  tff(decl_75165, type, fn_thorium_12: $i > $i).
% 29.32/29.15  tff(decl_75166, type, fn_thorium_13: $i > $i).
% 29.32/29.15  tff(decl_75167, type, fn_thorium_14: $i > $i).
% 29.32/29.15  tff(decl_75168, type, "142": $i).
% 29.32/29.15  tff(decl_75169, type, "232": $i).
% 29.32/29.15  tff(decl_75170, type, fn_thorium_9: $i > $i).
% 29.32/29.15  tff(decl_75171, type, fn_thorium_10: $i > $i).
% 29.32/29.15  tff(decl_75172, type, fn_thorium_8: $i > $i).
% 29.32/29.15  tff(decl_75173, type, 'Threatened-Species': $i).
% 29.32/29.15  tff(decl_75174, type, 'Any species that may become endangered in the near future.': $i).
% 29.32/29.15  tff(decl_75175, type, 'threatened species': $i).
% 29.32/29.15  tff(decl_75176, type, 'threatened-specy': $i).
% 29.32/29.15  tff(decl_75177, type, 'Three-Phosphoglycerate': $i).
% 29.32/29.15  tff(decl_75178, type, 'Phosphorylated intermediate molecule produced through carbon-fixation in the first phase of photosynthesis.': $i).
% 29.32/29.15  tff(decl_75179, type, '3 phosphoglycerate': $i).
% 29.32/29.15  tff(decl_75180, type, '3-phosphoglycerate': $i).
% 29.32/29.15  tff(decl_75181, type, '3 phosphoglyceric acid': $i).
% 29.32/29.15  tff(decl_75182, type, '3-phosphoglyceric-acid': $i).
% 29.32/29.15  tff(decl_75183, type, '3pg': $i).
% 29.32/29.15  tff(decl_75184, type, 'glycerate 3 phosphate': $i).
% 29.32/29.15  tff(decl_75185, type, 'glycerate-3-phosphate': $i).
% 29.32/29.15  tff(decl_75186, type, gp: $i).
% 29.32/29.15  tff(decl_75187, type, 'three phosphoglycerate': $i).
% 29.32/29.15  tff(decl_75188, type, 'three-phosphoglycerate': $i).
% 29.32/29.15  tff(decl_75189, type, 'Three-Prime-End-of-mRNA': $i).
% 29.32/29.15  tff(decl_75190, type, 'The end of the mRNA molecule to which nucleotides are added as it is synthesized during transcription.': $i).
% 29.32/29.15  tff(decl_75191, type, 'three prime end of mrna': $i).
% 29.32/29.15  tff(decl_75192, type, 'three-prime-end-of-mrna': $i).
% 29.32/29.15  tff(decl_75193, type, three_prime_nucleotide_1: $i > $o).
% 29.32/29.15  tff(decl_75194, type, 'Three-Prime-Nucleotide': $i).
% 29.32/29.15  tff(decl_75195, type, 'Nucleotide at the 3\\ end of a sequence.': $i).
% 29.32/29.15  tff(decl_75196, type, '3\\ nucleotide': $i).
% 29.32/29.15  tff(decl_75197, type, 'three prime base': $i).
% 29.32/29.15  tff(decl_75198, type, '3\\ base': $i).
% 29.32/29.15  tff(decl_75199, type, '3 prime nucleotide': $i).
% 29.32/29.15  tff(decl_75200, type, '3-prime-nucleotide': $i).
% 29.32/29.15  tff(decl_75201, type, 'three prime nucleotide': $i).
% 29.32/29.15  tff(decl_75202, type, 'three-prime-nucleotide': $i).
% 29.32/29.15  tff(decl_75203, type, fn_three_prime_nucleotide_1: $i > $i).
% 29.32/29.15  tff(decl_75204, type, 'Threonine': $i).
% 29.32/29.15  tff(decl_75205, type, thr: $i).
% 29.32/29.15  tff(decl_75206, type, t: $i).
% 29.32/29.15  tff(decl_75207, type, threonine: $i).
% 29.32/29.15  tff(decl_75208, type, 'Threshold-Potential': $i).
% 29.32/29.15  tff(decl_75209, type, 'In excitable cells such as neurons and muscle cells, the membrane potential that must be reached before an action potential is generated.': $i).
% 29.32/29.15  tff(decl_75210, type, 'potential of threshold': $i).
% 29.32/29.15  tff(decl_75211, type, 'threshold potential': $i).
% 29.32/29.15  tff(decl_75212, type, 'threshold-potential': $i).
% 29.32/29.15  tff(decl_75213, type, 'Thrombus': $i).
% 29.32/29.15  tff(decl_75214, type, 'A solid mass of platelets and fibrin that blocks the flow of blood through a blood vessel.': $i).
% 29.32/29.15  tff(decl_75215, type, 'blood clot': $i).
% 29.32/29.15  tff(decl_75216, type, 'blood-clot': $i).
% 29.32/29.15  tff(decl_75217, type, thrombus: $i).
% 29.32/29.15  tff(decl_75218, type, throw_1: $i > $o).
% 29.32/29.15  tff(decl_75219, type, 'Throw': $i).
% 29.32/29.15  tff(decl_75220, type, thulium_1: $i > $o).
% 29.32/29.15  tff(decl_75221, type, 'Thulium': $i).
% 29.32/29.15  tff(decl_75222, type, 'Thulium is a metal atom with atomic number 69. It is represented by the symbol Tm.': $i).
% 29.32/29.15  tff(decl_75223, type, thulium: $i).
% 29.32/29.15  tff(decl_75224, type, tm: $i).
% 29.32/29.15  tff(decl_75225, type, fn_thulium_3: $i > $i).
% 29.32/29.15  tff(decl_75226, type, fn_thulium_4: $i > $i).
% 29.32/29.15  tff(decl_75227, type, fn_thulium_5: $i > $i).
% 29.32/29.15  tff(decl_75228, type, fn_thulium_9: $i > $i).
% 29.32/29.15  tff(decl_75229, type, fn_thulium_10: $i > $i).
% 29.32/29.15  tff(decl_75230, type, fn_thulium_11: $i > $i).
% 29.32/29.15  tff(decl_75231, type, fn_thulium_12: $i > $i).
% 29.32/29.15  tff(decl_75232, type, "69": $i).
% 29.32/29.15  tff(decl_75233, type, "1.25": $i).
% 29.32/29.15  tff(decl_75234, type, "169": $i).
% 29.32/29.15  tff(decl_75235, type, "168.9": $i).
% 29.32/29.15  tff(decl_75236, type, fn_thulium_7: $i > $i).
% 29.32/29.15  tff(decl_75237, type, fn_thulium_8: $i > $i).
% 29.32/29.15  tff(decl_75238, type, fn_thulium_6: $i > $i).
% 29.32/29.15  tff(decl_75239, type, 'Thylakoid': $i).
% 29.32/29.15  tff(decl_75240, type, 'Thylakoid is a membrane-bound compartment inside chloroplast. It is the site of light dependent reaction of photosynthesis': $i).
% 29.32/29.15  tff(decl_75241, type, thylakoid: $i).
% 29.32/29.15  tff(decl_75242, type, thylakoids: $i).
% 29.32/29.15  tff(decl_75243, type, 'thylakoid sac': $i).
% 29.32/29.15  tff(decl_75244, type, fn_thylakoid_6: $i > $i).
% 29.32/29.15  tff(decl_75245, type, 'Thylakoid-Electron-Transport-Chain': $i).
% 29.32/29.15  tff(decl_75246, type, 'A series of membrane proteins found in the thylakoid membrane that couples electron transfer from a donor molecule to a acceptor molecule  with the transfer of protons across a membrane.': $i).
% 29.32/29.15  tff(decl_75247, type, 'electron transport chain in chloroplast': $i).
% 29.32/29.15  tff(decl_75248, type, 'thylakoid electron transport chain': $i).
% 29.32/29.15  tff(decl_75249, type, 'thylakoid-electron-transport-chain': $i).
% 29.32/29.15  tff(decl_75250, type, fn_thylakoid_electron_transport_chain_24: $i > $i).
% 29.32/29.15  tff(decl_75251, type, 'Thylakoid-Membrane': $i).
% 29.32/29.15  tff(decl_75252, type, 'Thylakoid membrane contains photosystem and electron transport chain, which perform light reaction.': $i).
% 29.32/29.15  tff(decl_75253, type, 'membrane of thylakoid': $i).
% 29.32/29.15  tff(decl_75254, type, 'thylakoid membrane': $i).
% 29.32/29.15  tff(decl_75255, type, 'thylakoid-membrane': $i).
% 29.32/29.15  tff(decl_75256, type, fn_thylakoid_membrane_5: $i > $i).
% 29.32/29.15  tff(decl_75257, type, fn_thylakoid_membrane_17: $i > $i).
% 29.32/29.15  tff(decl_75258, type, fn_thylakoid_membrane_18: $i > $i).
% 29.32/29.15  tff(decl_75259, type, atp_synthase_0: $i).
% 29.32/29.15  tff(decl_75260, type, 'Thylakoid-Space': $i).
% 29.32/29.15  tff(decl_75261, type, 'The lumen or space inside a thylakoid.': $i).
% 29.32/29.15  tff(decl_75262, type, 'thylakoid lumen': $i).
% 29.32/29.15  tff(decl_75263, type, 'space of thylakoid': $i).
% 29.32/29.15  tff(decl_75264, type, 'thylakoid space': $i).
% 29.32/29.15  tff(decl_75265, type, 'thylakoid-space': $i).
% 29.32/29.15  tff(decl_75266, type, fn_thylakoid_space_1: $i > $i).
% 29.32/29.15  tff(decl_75267, type, 'Thymine': $i).
% 29.32/29.15  tff(decl_75268, type, 'One of the five most common nitrogenous bases which make up nucleotide monomers of nucleic acids. Thymine is present only in DNA.': $i).
% 29.32/29.15  tff(decl_75269, type, thymine: $i).
% 29.32/29.15  tff(decl_75270, type, 'Thymine-At-DNA-Strand-Opposite-To-DNA-Strand': $i).
% 29.32/29.15  tff(decl_75271, type, 'This is a situation in which the thymine at DNA stand is opposite to DNA Strand having  Adenine.': $i).
% 29.32/29.15  tff(decl_75272, type, 'thymine at dna strand opposite to dna strand': $i).
% 29.32/29.15  tff(decl_75273, type, 'thymine-at-dna-strand-opposite-to-dna-strand': $i).
% 29.32/29.15  tff(decl_75274, type, fn_thymine_at_dna_strand_opposite_to_dna_strand_1: $i > $i).
% 29.32/29.15  tff(decl_75275, type, 'Thymine-At-DNA-Strand-Opposite-To-RNA-Strand': $i).
% 29.32/29.15  tff(decl_75276, type, 'This is a situation in which the thymine at DNA stand is opposite to RNA Strand': $i).
% 29.32/29.15  tff(decl_75277, type, 'thymine at dna strand opposite to rna strand': $i).
% 29.32/29.15  tff(decl_75278, type, 'thymine-at-dna-strand-opposite-to-rna-strand': $i).
% 29.32/29.15  tff(decl_75279, type, thymine_dimer_1: $i > $o).
% 29.32/29.15  tff(decl_75280, type, 'Thymine-Dimer': $i).
% 29.32/29.15  tff(decl_75281, type, 'Thymine dimer is a deformity in DNA resulted from joining of two thymine nucleotides present consecutively on the DNA. It is formed by the reaction of high energy radiations or highly reactive chemical molecules with DNA': $i).
% 29.32/29.15  tff(decl_75282, type, 'dimer of thymine': $i).
% 29.32/29.15  tff(decl_75283, type, 'thymine dimer': $i).
% 29.32/29.15  tff(decl_75284, type, 'thymine-dimer': $i).
% 29.32/29.15  tff(decl_75285, type, fn_thymine_dimer_1: $i > $i).
% 29.32/29.15  tff(decl_75286, type, fn_thymine_dimer_2: $i > $i).
% 29.32/29.15  tff(decl_75287, type, fn_thymine_dimer_3: $i > $i).
% 29.32/29.15  tff(decl_75288, type, fn_thymine_dimer_4: $i > $i).
% 29.32/29.15  tff(decl_75289, type, fn_thymine_dimer_5: $i > $i).
% 29.32/29.15  tff(decl_75290, type, fn_thymine_dimer_6: $i > $i).
% 29.32/29.15  tff(decl_75291, type, fn_thymine_dimer_7: $i > $i).
% 29.32/29.15  tff(decl_75292, type, fn_thymine_dimer_8: $i > $i).
% 29.32/29.15  tff(decl_75293, type, fn_thymine_dimer_9: $i > $i).
% 29.32/29.15  tff(decl_75294, type, fn_thymine_dimer_10: $i > $i).
% 29.32/29.15  tff(decl_75295, type, fn_thymine_dimer_11: $i > $i).
% 29.32/29.15  tff(decl_75296, type, fn_thymine_dimer_12: $i > $i).
% 29.32/29.15  tff(decl_75297, type, fn_thymine_dimer_13: $i > $i).
% 29.32/29.15  tff(decl_75298, type, fn_thymine_dimer_14: $i > $i).
% 29.32/29.15  tff(decl_75299, type, fn_thymine_dimer_15: $i > $i).
% 29.32/29.15  tff(decl_75300, type, fn_thymine_dimer_16: $i > $i).
% 29.32/29.15  tff(decl_75301, type, fn_thymine_dimer_17: $i > $i).
% 29.32/29.15  tff(decl_75302, type, fn_thymine_dimer_18: $i > $i).
% 29.32/29.15  tff(decl_75303, type, fn_thymine_dimer_19: $i > $i).
% 29.32/29.15  tff(decl_75304, type, fn_thymine_dimer_20: $i > $i).
% 29.32/29.15  tff(decl_75305, type, fn_thymine_dimer_21: $i > $i).
% 29.32/29.15  tff(decl_75306, type, fn_thymine_dimer_23: $i > $i).
% 29.32/29.15  tff(decl_75307, type, thymine_0: $i).
% 29.32/29.15  tff(decl_75308, type, fn_thymine_dimer_22: $i > $i).
% 29.32/29.15  tff(decl_75309, type, thymus_1: $i > $o).
% 29.32/29.15  tff(decl_75310, type, 'Thymus': $i).
% 29.32/29.15  tff(decl_75311, type, 'In vertebrates, an organ in the thoracic cavity that is the site of T cell maturation.': $i).
% 29.32/29.15  tff(decl_75312, type, thymus: $i).
% 29.32/29.15  tff(decl_75313, type, 'Thyroid-Gland': $i).
% 29.32/29.15  tff(decl_75314, type, 'An endocrine gland located in the neck, below the thyroid cartilage.  It secretes the hormones triidiothyronine (T3) and thyroxine (T2), which regulate the metabolic rate. It also secretes the hormone calcitonin, which is involved in the regulation of calcium in the body.': $i).
% 29.32/29.15  tff(decl_75315, type, 'gland of thyroid': $i).
% 29.32/29.15  tff(decl_75316, type, 'thyroid gland': $i).
% 29.32/29.15  tff(decl_75317, type, 'thyroid-gland': $i).
% 29.32/29.15  tff(decl_75318, type, fn_thyroid_gland_1: $i > $i).
% 29.32/29.15  tff(decl_75319, type, fn_thyroid_gland_2: $i > $i).
% 29.32/29.15  tff(decl_75320, type, fn_thyroid_gland_3: $i > $i).
% 29.32/29.15  tff(decl_75321, type, fn_thyroid_gland_4: $i > $i).
% 29.32/29.15  tff(decl_75322, type, fn_thyroid_gland_5: $i > $i).
% 29.32/29.15  tff(decl_75323, type, fn_thyroid_hormone_14: $i > $i).
% 29.32/29.15  tff(decl_75324, type, fn_thyroid_hormone_13: $i > $i).
% 29.32/29.15  tff(decl_75325, type, fn_thyroid_hormone_12: $i > $i).
% 29.32/29.15  tff(decl_75326, type, 'Thyroid-Hormone': $i).
% 29.32/29.15  tff(decl_75327, type, 'A hormone produced by the thyroid gland. The thyroid hormones are thyroxine  (T4) and triiodothyronine (T3).': $i).
% 29.32/29.15  tff(decl_75328, type, 'hormone of thyroid': $i).
% 29.32/29.15  tff(decl_75329, type, 'thyroid hormone': $i).
% 29.32/29.15  tff(decl_75330, type, 'thyroid-hormone': $i).
% 29.32/29.15  tff(decl_75331, type, fn_thyroid_hormone_1: $i > $i).
% 29.32/29.15  tff(decl_75332, type, fn_thyroid_hormone_2: $i > $i).
% 29.32/29.15  tff(decl_75333, type, fn_thyroid_hormone_3: $i > $i).
% 29.32/29.15  tff(decl_75334, type, fn_thyroid_hormone_4: $i > $i).
% 29.32/29.15  tff(decl_75335, type, fn_thyroid_hormone_5: $i > $i).
% 29.32/29.15  tff(decl_75336, type, fn_thyroid_hormone_6: $i > $i).
% 29.32/29.15  tff(decl_75337, type, fn_thyroid_hormone_7: $i > $i).
% 29.32/29.15  tff(decl_75338, type, fn_thyroid_hormone_8: $i > $i).
% 29.32/29.15  tff(decl_75339, type, fn_thyroid_hormone_9: $i > $i).
% 29.32/29.15  tff(decl_75340, type, fn_thyroid_hormone_10: $i > $i).
% 29.32/29.15  tff(decl_75341, type, fn_thyroid_hormone_16: $i > $i).
% 29.32/29.15  tff(decl_75342, type, fn_thyroid_hormone_15: $i > $i).
% 29.32/29.15  tff(decl_75343, type, 'Thyroid-Hormone-Receptor': $i).
% 29.32/29.15  tff(decl_75344, type, 'A receptor protein on the surface of a cell or in its interior that binds to thyroid hormone.': $i).
% 29.32/29.15  tff(decl_75345, type, 'thyroid hormone receptor': $i).
% 29.32/29.15  tff(decl_75346, type, 'thyroid-hormone-receptor': $i).
% 29.32/29.15  tff(decl_75347, type, 'Thyroid-Peptide-Hormone': $i).
% 29.32/29.15  tff(decl_75348, type, 'thyroid peptide hormone': $i).
% 29.32/29.15  tff(decl_75349, type, 'thyroid-peptide-hormone': $i).
% 29.32/29.15  tff(decl_75350, type, 'Ti-Plasmid': $i).
% 29.32/29.15  tff(decl_75351, type, 'A circular plasmid found in the genome of Agrobacterium, a bacterium that causes tumors in the plants it infects. Because the plasmid is readily passed from the bacterial genome to the host genome, it is commonly used as a genetic vector in genetic engineering.': $i).
% 29.32/29.15  tff(decl_75352, type, 'plasmid of ti': $i).
% 29.32/29.15  tff(decl_75353, type, 'ti plasmid': $i).
% 29.32/29.15  tff(decl_75354, type, 'ti-plasmid': $i).
% 29.32/29.15  tff(decl_75355, type, 'Tick': $i).
% 29.32/29.15  tff(decl_75356, type, 'A small arachnid in the order Ixodida. They are external parasites and feed on the blood of mammals, birds, and reptiles.': $i).
% 29.32/29.15  tff(decl_75357, type, tick: $i).
% 29.32/29.15  tff(decl_75358, type, 'Tight-Junction': $i).
% 29.32/29.15  tff(decl_75359, type, 'A type of intercellular junction in animal cells where adjacent cells are tightly bound together and material cannot pass through the extracellular matrix between them.': $i).
% 29.32/29.15  tff(decl_75360, type, 'tight junction': $i).
% 29.32/29.15  tff(decl_75361, type, 'tight-junction': $i).
% 29.32/29.15  tff(decl_75362, type, fn_tight_junction_1: $i > $i).
% 29.32/29.15  tff(decl_75363, type, fn_tight_junction_2: $i > $i).
% 29.32/29.15  tff(decl_75364, type, fn_tight_junction_3: $i > $i).
% 29.32/29.15  tff(decl_75365, type, fn_tight_junction_4: $i > $i).
% 29.32/29.15  tff(decl_75366, type, fn_tight_junction_5: $i > $i).
% 29.32/29.15  tff(decl_75367, type, fn_tight_junction_6: $i > $i).
% 29.32/29.15  tff(decl_75368, type, fn_tight_junction_7: $i > $i).
% 29.32/29.15  tff(decl_75369, type, fn_tight_junction_8: $i > $i).
% 29.32/29.15  tff(decl_75370, type, fn_tight_junction_9: $i > $i).
% 29.32/29.15  tff(decl_75371, type, fn_tight_junction_10: $i > $i).
% 29.32/29.15  tff(decl_75372, type, fn_tight_junction_11: $i > $i).
% 29.32/29.15  tff(decl_75373, type, fn_tight_junction_12: $i > $i).
% 29.32/29.15  tff(decl_75374, type, fn_tight_junction_13: $i > $i).
% 29.32/29.15  tff(decl_75375, type, fn_tight_junction_14: $i > $i).
% 29.32/29.15  tff(decl_75376, type, fn_tight_junction_15: $i > $i).
% 29.32/29.15  tff(decl_75377, type, fn_tight_junction_16: $i > $i).
% 29.32/29.15  tff(decl_75378, type, fn_tight_junction_20: $i > $i).
% 29.32/29.15  tff(decl_75379, type, fn_tight_junction_21: $i > $i).
% 29.32/29.15  tff(decl_75380, type, fn_tight_junction_22: $i > $i).
% 29.32/29.15  tff(decl_75381, type, fn_tight_junction_24: $i > $i).
% 29.32/29.15  tff(decl_75382, type, fn_tight_junction_25: $i > $i).
% 29.32/29.15  tff(decl_75383, type, fn_tight_junction_26: $i > $i).
% 29.32/29.15  tff(decl_75384, type, fn_tight_junction_27: $i > $i).
% 29.32/29.15  tff(decl_75385, type, fn_tight_junction_28: $i > $i).
% 29.32/29.15  tff(decl_75386, type, fn_tight_junction_29: $i > $i).
% 29.32/29.15  tff(decl_75387, type, fn_tight_junction_30: $i > $i).
% 29.32/29.15  tff(decl_75388, type, fn_tight_junction_31: $i > $i).
% 29.32/29.15  tff(decl_75389, type, fn_tight_junction_32: $i > $i).
% 29.32/29.15  tff(decl_75390, type, fn_tight_junction_33: $i > $i).
% 29.32/29.15  tff(decl_75391, type, fn_tight_junction_34: $i > $i).
% 29.32/29.15  tff(decl_75392, type, fn_tight_junction_35: $i > $i).
% 29.32/29.15  tff(decl_75393, type, fn_tight_junction_36: $i > $i).
% 29.32/29.15  tff(decl_75394, type, fn_tight_junction_37: $i > $i).
% 29.32/29.15  tff(decl_75395, type, fn_tight_junction_38: $i > $i).
% 29.32/29.15  tff(decl_75396, type, fn_tight_junction_39: $i > $i).
% 29.32/29.15  tff(decl_75397, type, fn_tight_junction_40: $i > $i).
% 29.32/29.15  tff(decl_75398, type, fn_tight_junction_41: $i > $i).
% 29.32/29.15  tff(decl_75399, type, fn_tight_junction_42: $i > $i).
% 29.32/29.15  tff(decl_75400, type, fn_tight_junction_43: $i > $i).
% 29.32/29.15  tff(decl_75401, type, fn_tight_junction_44: $i > $i).
% 29.32/29.15  tff(decl_75402, type, fn_tight_junction_45: $i > $i).
% 29.32/29.15  tff(decl_75403, type, fn_tight_junction_46: $i > $i).
% 29.32/29.15  tff(decl_75404, type, fn_tight_junction_47: $i > $i).
% 29.32/29.15  tff(decl_75405, type, fn_tight_junction_48: $i > $i).
% 29.32/29.15  tff(decl_75406, type, fn_tight_junction_49: $i > $i).
% 29.32/29.15  tff(decl_75407, type, fn_tight_junction_50: $i > $i).
% 29.32/29.15  tff(decl_75408, type, fn_tight_junction_51: $i > $i).
% 29.32/29.15  tff(decl_75409, type, fn_tight_junction_52: $i > $i).
% 29.32/29.15  tff(decl_75410, type, fn_tight_junction_53: $i > $i).
% 29.32/29.15  tff(decl_75411, type, fn_tight_junction_54: $i > $i).
% 29.32/29.15  tff(decl_75412, type, fn_tight_junction_55: $i > $i).
% 29.32/29.15  tff(decl_75413, type, fn_tight_junction_56: $i > $i).
% 29.32/29.15  tff(decl_75414, type, fn_tight_junction_57: $i > $i).
% 29.32/29.15  tff(decl_75415, type, fn_tight_junction_58: $i > $i).
% 29.32/29.15  tff(decl_75416, type, fn_tight_junction_59: $i > $i).
% 29.32/29.15  tff(decl_75417, type, fn_tight_junction_60: $i > $i).
% 29.32/29.15  tff(decl_75418, type, fn_tight_junction_62: $i > $i).
% 29.32/29.15  tff(decl_75419, type, fn_tight_junction_63: $i > $i).
% 29.32/29.15  tff(decl_75420, type, fn_tight_junction_67: $i > $i).
% 29.32/29.15  tff(decl_75421, type, fn_tight_junction_66: $i > $i).
% 29.32/29.15  tff(decl_75422, type, fn_tight_junction_65: $i > $i).
% 29.32/29.15  tff(decl_75423, type, 'Time-Instant': $i).
% 29.32/29.15  tff(decl_75424, type, 'inside of time': $i).
% 29.32/29.15  tff(decl_75425, type, 'time inside': $i).
% 29.32/29.15  tff(decl_75426, type, 'time-inside': $i).
% 29.32/29.15  tff(decl_75427, type, 'time end': $i).
% 29.32/29.15  tff(decl_75428, type, 'time-end': $i).
% 29.32/29.15  tff(decl_75429, type, 'time between': $i).
% 29.32/29.15  tff(decl_75430, type, 'time-between': $i).
% 29.32/29.15  tff(decl_75431, type, 'time begins or in': $i).
% 29.32/29.15  tff(decl_75432, type, 'time-begins-or-in': $i).
% 29.32/29.15  tff(decl_75433, type, 'time begin': $i).
% 29.32/29.15  tff(decl_75434, type, 'time-begin': $i).
% 29.32/29.15  tff(decl_75435, type, 'at of time': $i).
% 29.32/29.15  tff(decl_75436, type, 'time at': $i).
% 29.32/29.15  tff(decl_75437, type, 'time-at': $i).
% 29.32/29.15  tff(decl_75438, type, 'point in time': $i).
% 29.32/29.15  tff(decl_75439, type, point_in_time: $i).
% 29.32/29.15  tff(decl_75440, type, 'instant of time': $i).
% 29.32/29.15  tff(decl_75441, type, 'time instant': $i).
% 29.32/29.15  tff(decl_75442, type, 'time-instant': $i).
% 29.32/29.15  tff(decl_75443, type, 'Time-Interval': $i).
% 29.32/29.15  tff(decl_75444, type, 'existence time': $i).
% 29.32/29.15  tff(decl_75445, type, 'existence-time': $i).
% 29.32/29.15  tff(decl_75446, type, 'time of existence': $i).
% 29.32/29.15  tff(decl_75447, type, 'time-of-existence': $i).
% 29.32/29.15  tff(decl_75448, type, 'time int start': $i).
% 29.32/29.15  tff(decl_75449, type, 'time-int-start': $i).
% 29.32/29.15  tff(decl_75450, type, 'time int overlap': $i).
% 29.32/29.15  tff(decl_75451, type, 'time-int-overlap': $i).
% 29.32/29.15  tff(decl_75452, type, 'time int meet': $i).
% 29.32/29.15  tff(decl_75453, type, 'time-int-meet': $i).
% 29.32/29.15  tff(decl_75454, type, 'time int finish': $i).
% 29.32/29.15  tff(decl_75455, type, 'time-int-finishe': $i).
% 29.32/29.15  tff(decl_75456, type, 'time int equal': $i).
% 29.32/29.15  tff(decl_75457, type, 'time-int-equal': $i).
% 29.32/29.15  tff(decl_75458, type, 'time int during': $i).
% 29.32/29.15  tff(decl_75459, type, 'time-int-during': $i).
% 29.32/29.15  tff(decl_75460, type, 'time int before': $i).
% 29.32/29.15  tff(decl_75461, type, 'time-int-before': $i).
% 29.32/29.15  tff(decl_75462, type, 'during of time': $i).
% 29.32/29.15  tff(decl_75463, type, 'time during': $i).
% 29.32/29.15  tff(decl_75464, type, 'time-during': $i).
% 29.32/29.15  tff(decl_75465, type, 'time interval': $i).
% 29.32/29.15  tff(decl_75466, type, time_interval: $i).
% 29.32/29.15  tff(decl_75467, type, interval: $i).
% 29.32/29.15  tff(decl_75468, type, 'interval of time': $i).
% 29.32/29.15  tff(decl_75469, type, 'time-interval': $i).
% 29.32/29.15  tff(decl_75470, type, 'Time-Span': $i).
% 29.32/29.15  tff(decl_75471, type, 'Division of time.': $i).
% 29.32/29.15  tff(decl_75472, type, 'span of time': $i).
% 29.32/29.15  tff(decl_75473, type, 'time span': $i).
% 29.32/29.15  tff(decl_75474, type, 'time-span': $i).
% 29.32/29.15  tff(decl_75475, type, 'Time-Zone-Constant': $i).
% 29.32/29.15  tff(decl_75476, type, 'time zone constant': $i).
% 29.32/29.15  tff(decl_75477, type, 'time-zone-constant': $i).
% 29.32/29.15  tff(decl_75478, type, 'Tin': $i).
% 29.32/29.15  tff(decl_75479, type, 'Tin is a metal atom with atomic number 50. It is represented by the symbol Sn.': $i).
% 29.32/29.15  tff(decl_75480, type, tin: $i).
% 29.32/29.15  tff(decl_75481, type, 'Sn': $i).
% 29.32/29.15  tff(decl_75482, type, fn_tin_3: $i > $i).
% 29.32/29.15  tff(decl_75483, type, fn_tin_4: $i > $i).
% 29.32/29.15  tff(decl_75484, type, fn_tin_5: $i > $i).
% 29.32/29.15  tff(decl_75485, type, fn_tin_9: $i > $i).
% 29.32/29.15  tff(decl_75486, type, fn_tin_10: $i > $i).
% 29.32/29.15  tff(decl_75487, type, fn_tin_11: $i > $i).
% 29.32/29.15  tff(decl_75488, type, fn_tin_12: $i > $i).
% 29.32/29.15  tff(decl_75489, type, "1.96": $i).
% 29.32/29.15  tff(decl_75490, type, "119": $i).
% 29.32/29.15  tff(decl_75491, type, "118.7": $i).
% 29.32/29.15  tff(decl_75492, type, fn_tin_7: $i > $i).
% 29.32/29.15  tff(decl_75493, type, fn_tin_8: $i > $i).
% 29.32/29.15  tff(decl_75494, type, fn_tin_6: $i > $i).
% 29.32/29.15  tff(decl_75495, type, 'Tip': $i).
% 29.32/29.15  tff(decl_75496, type, 'The top or extremepoint of something is called as tip.': $i).
% 29.32/29.15  tff(decl_75497, type, tip: $i).
% 29.32/29.15  tff(decl_75498, type, 'Tissue': $i).
% 29.32/29.15  tff(decl_75499, type, 'A tissue is a group of cells derived from a common developmental origon which conduct a similar physiological role in an organism .': $i).
% 29.32/29.15  tff(decl_75500, type, tissue: $i).
% 29.32/29.15  tff(decl_75501, type, fn_tissue_movement_2: $i > $i).
% 29.32/29.15  tff(decl_75502, type, 'Tissue-Movement': $i).
% 29.32/29.15  tff(decl_75503, type, 'Movements of tissues in the course of development is called as tissue movement.': $i).
% 29.32/29.15  tff(decl_75504, type, 'movement of tissue': $i).
% 29.32/29.15  tff(decl_75505, type, 'tissue movement': $i).
% 29.32/29.15  tff(decl_75506, type, 'tissue-movement': $i).
% 29.32/29.15  tff(decl_75507, type, tissue_repair_1: $i > $o).
% 29.32/29.15  tff(decl_75508, type, 'Tissue-Repair': $i).
% 29.32/29.15  tff(decl_75509, type, 'The process in which cell signaling and cell division result in healing and repair of damaged tissue.': $i).
% 29.32/29.15  tff(decl_75510, type, 'repair of tissue': $i).
% 29.32/29.15  tff(decl_75511, type, 'tissue repair': $i).
% 29.32/29.15  tff(decl_75512, type, 'tissue-repair': $i).
% 29.32/29.15  tff(decl_75513, type, fn_tissue_repair_1: $i > $i).
% 29.32/29.15  tff(decl_75514, type, fn_tissue_repair_2: $i > $i).
% 29.32/29.15  tff(decl_75515, type, fn_tissue_repair_3: $i > $i).
% 29.32/29.15  tff(decl_75516, type, fn_tissue_repair_4: $i > $i).
% 29.32/29.15  tff(decl_75517, type, fn_tissue_repair_5: $i > $i).
% 29.32/29.15  tff(decl_75518, type, fn_tissue_repair_6: $i > $i).
% 29.32/29.15  tff(decl_75519, type, fn_tissue_repair_7: $i > $i).
% 29.32/29.15  tff(decl_75520, type, fn_tissue_repair_8: $i > $i).
% 29.32/29.15  tff(decl_75521, type, fn_tissue_repair_9: $i > $i).
% 29.32/29.15  tff(decl_75522, type, fn_tissue_repair_10: $i > $i).
% 29.32/29.15  tff(decl_75523, type, fn_tissue_specific_protein_4: $i > $i).
% 29.32/29.15  tff(decl_75524, type, fn_tissue_specific_protein_3: $i > $i).
% 29.32/29.15  tff(decl_75525, type, fn_tissue_specific_protein_2: $i > $i).
% 29.32/29.15  tff(decl_75526, type, 'Tissue-Specific-Protein': $i).
% 29.32/29.15  tff(decl_75527, type, 'A protein specific to the definite kind of tissue.': $i).
% 29.32/29.15  tff(decl_75528, type, 'tissue specific protein': $i).
% 29.32/29.15  tff(decl_75529, type, 'tissue-specific-protein': $i).
% 29.32/29.15  tff(decl_75530, type, 'Tissue-System': $i).
% 29.32/29.15  tff(decl_75531, type, 'A collection of tissues that form a functional unit connecting a subset of the organs in a plant.': $i).
% 29.32/29.15  tff(decl_75532, type, 'system of tissue': $i).
% 29.32/29.15  tff(decl_75533, type, 'tissue system': $i).
% 29.32/29.15  tff(decl_75534, type, 'tissue-system': $i).
% 29.32/29.15  tff(decl_75535, type, titanium_1: $i > $o).
% 29.32/29.15  tff(decl_75536, type, 'Titanium': $i).
% 29.32/29.15  tff(decl_75537, type, 'Titanium is a metal atom with atomic number 22. It is represented by the symbol Ti.': $i).
% 29.32/29.15  tff(decl_75538, type, titanium: $i).
% 29.32/29.15  tff(decl_75539, type, 'Ti': $i).
% 29.32/29.15  tff(decl_75540, type, fn_titanium_3: $i > $i).
% 29.32/29.15  tff(decl_75541, type, fn_titanium_4: $i > $i).
% 29.32/29.15  tff(decl_75542, type, fn_titanium_5: $i > $i).
% 29.32/29.15  tff(decl_75543, type, fn_titanium_9: $i > $i).
% 29.32/29.15  tff(decl_75544, type, fn_titanium_10: $i > $i).
% 29.32/29.15  tff(decl_75545, type, fn_titanium_11: $i > $i).
% 29.32/29.15  tff(decl_75546, type, fn_titanium_12: $i > $i).
% 29.32/29.15  tff(decl_75547, type, "1.54": $i).
% 29.32/29.15  tff(decl_75548, type, "47.87": $i).
% 29.32/29.15  tff(decl_75549, type, fn_titanium_7: $i > $i).
% 29.32/29.15  tff(decl_75550, type, fn_titanium_8: $i > $i).
% 29.32/29.15  tff(decl_75551, type, fn_titanium_6: $i > $i).
% 29.32/29.15  tff(decl_75552, type, tlr_1: $i > $o).
% 29.32/29.15  tff(decl_75553, type, 'TLR': $i).
% 29.32/29.15  tff(decl_75554, type, 'Toll-like receptor; one of a class of transmembrane proteins found on phagocytic cells such as macrophages. TLRs recognize molecules derived from pathogenic microbes.': $i).
% 29.32/29.15  tff(decl_75555, type, 'toll like receptor': $i).
% 29.32/29.15  tff(decl_75556, type, 'toll-like-receptor': $i).
% 29.32/29.15  tff(decl_75557, type, tlr: $i).
% 29.32/29.15  tff(decl_75558, type, fn_tlr_1: $i > $i).
% 29.32/29.15  tff(decl_75559, type, fn_tlr_2: $i > $i).
% 29.32/29.15  tff(decl_75560, type, fn_tlr_3: $i > $i).
% 29.32/29.15  tff(decl_75561, type, fn_tlr_4: $i > $i).
% 29.32/29.15  tff(decl_75562, type, fn_tlr_5: $i > $i).
% 29.32/29.15  tff(decl_75563, type, fn_tlr_6: $i > $i).
% 29.32/29.15  tff(decl_75564, type, fn_tlr_7: $i > $i).
% 29.32/29.15  tff(decl_75565, type, fn_tlr_8: $i > $i).
% 29.32/29.15  tff(decl_75566, type, fn_tlr_9: $i > $i).
% 29.32/29.15  tff(decl_75567, type, fn_tlr_10: $i > $i).
% 29.32/29.15  tff(decl_75568, type, fn_tlr_11: $i > $i).
% 29.32/29.15  tff(decl_75569, type, fn_tlr_12: $i > $i).
% 29.32/29.15  tff(decl_75570, type, fn_tlr_13: $i > $i).
% 29.32/29.15  tff(decl_75571, type, fn_tlr_14: $i > $i).
% 29.32/29.15  tff(decl_75572, type, fn_tlr_15: $i > $i).
% 29.32/29.15  tff(decl_75573, type, fn_tlr_16: $i > $i).
% 29.32/29.15  tff(decl_75574, type, fn_tlr_17: $i > $i).
% 29.32/29.15  tff(decl_75575, type, 'Tobacco-Mosaic-Disease': $i).
% 29.32/29.15  tff(decl_75576, type, 'An RNA virus that infects plants in the family Solanaceae, including tobacco. It causes distinctive patterns of mottling and discoloration of the leaves.': $i).
% 29.32/29.15  tff(decl_75577, type, tmd: $i).
% 29.32/29.15  tff(decl_75578, type, 'tobacco mosaic disease': $i).
% 29.32/29.15  tff(decl_75579, type, 'tobacco-mosaic-disease': $i).
% 29.32/29.15  tff(decl_75580, type, tobacco_plant_1: $i > $o).
% 29.32/29.15  tff(decl_75581, type, 'Tobacco-Plant': $i).
% 29.32/29.15  tff(decl_75582, type, 'It is a herbaceous plant which belong to family Solanaceae.': $i).
% 29.32/29.15  tff(decl_75583, type, 'plant of tobacco': $i).
% 29.32/29.15  tff(decl_75584, type, 'tobacco plant': $i).
% 29.32/29.15  tff(decl_75585, type, 'tobacco-plant': $i).
% 29.32/29.15  tff(decl_75586, type, fn_tobacco_plant_1: $i > $i).
% 29.32/29.15  tff(decl_75587, type, fn_tobacco_plant_2: $i > $i).
% 29.32/29.15  tff(decl_75588, type, fn_tobacco_plant_5: $i > $i).
% 29.32/29.15  tff(decl_75589, type, fn_tobacco_plant_6: $i > $i).
% 29.32/29.15  tff(decl_75590, type, fn_tobacco_plant_7: $i > $i).
% 29.32/29.15  tff(decl_75591, type, fn_tobacco_plant_8: $i > $i).
% 29.32/29.15  tff(decl_75592, type, fn_tobacco_plant_15: $i > $i).
% 29.32/29.15  tff(decl_75593, type, fn_tobacco_plant_16: $i > $i).
% 29.32/29.15  tff(decl_75594, type, fn_tobacco_plant_17: $i > $i).
% 29.32/29.15  tff(decl_75595, type, fn_tobacco_plant_18: $i > $i).
% 29.32/29.15  tff(decl_75596, type, fn_tobacco_plant_19: $i > $i).
% 29.32/29.15  tff(decl_75597, type, fn_tobacco_plant_20: $i > $i).
% 29.32/29.15  tff(decl_75598, type, fn_tobacco_plant_21: $i > $i).
% 29.32/29.15  tff(decl_75599, type, fn_tobacco_plant_22: $i > $i).
% 29.32/29.15  tff(decl_75600, type, fn_tobacco_plant_23: $i > $i).
% 29.32/29.15  tff(decl_75601, type, fn_tobacco_plant_24: $i > $i).
% 29.32/29.15  tff(decl_75602, type, fn_tobacco_plant_25: $i > $i).
% 29.32/29.15  tff(decl_75603, type, fn_tobacco_plant_26: $i > $i).
% 29.32/29.15  tff(decl_75604, type, fn_tobacco_plant_27: $i > $i).
% 29.32/29.15  tff(decl_75605, type, fn_tobacco_plant_28: $i > $i).
% 29.32/29.15  tff(decl_75606, type, fn_tobacco_plant_29: $i > $i).
% 29.32/29.15  tff(decl_75607, type, fn_tobacco_plant_30: $i > $i).
% 29.32/29.15  tff(decl_75608, type, fn_tobacco_plant_31: $i > $i).
% 29.32/29.15  tff(decl_75609, type, fn_tobacco_plant_32: $i > $i).
% 29.32/29.15  tff(decl_75610, type, fn_tobacco_plant_33: $i > $i).
% 29.32/29.15  tff(decl_75611, type, fn_tobacco_plant_34: $i > $i).
% 29.32/29.15  tff(decl_75612, type, fn_tobacco_plant_35: $i > $i).
% 29.32/29.15  tff(decl_75613, type, fn_tobacco_plant_36: $i > $i).
% 29.32/29.15  tff(decl_75614, type, fn_tobacco_plant_37: $i > $i).
% 29.32/29.15  tff(decl_75615, type, fn_tobacco_plant_38: $i > $i).
% 29.32/29.15  tff(decl_75616, type, fn_tobacco_plant_39: $i > $i).
% 29.32/29.15  tff(decl_75617, type, fn_tobacco_plant_40: $i > $i).
% 29.32/29.15  tff(decl_75618, type, fn_tobacco_plant_41: $i > $i).
% 29.32/29.15  tff(decl_75619, type, fn_tobacco_plant_42: $i > $i).
% 29.32/29.15  tff(decl_75620, type, fn_tobacco_plant_43: $i > $i).
% 29.32/29.15  tff(decl_75621, type, fn_tobacco_plant_44: $i > $i).
% 29.32/29.15  tff(decl_75622, type, fn_tobacco_plant_45: $i > $i).
% 29.32/29.15  tff(decl_75623, type, fn_tobacco_plant_48: $i > $i).
% 29.32/29.15  tff(decl_75624, type, fn_tobacco_plant_49: $i > $i).
% 29.32/29.15  tff(decl_75625, type, fn_tobacco_plant_50: $i > $i).
% 29.32/29.15  tff(decl_75626, type, fn_tobacco_plant_51: $i > $i).
% 29.32/29.15  tff(decl_75627, type, fn_tobacco_plant_52: $i > $i).
% 29.32/29.15  tff(decl_75628, type, fn_tobacco_plant_53: $i > $i).
% 29.32/29.15  tff(decl_75629, type, fn_tobacco_plant_54: $i > $i).
% 29.32/29.15  tff(decl_75630, type, fn_tobacco_plant_55: $i > $i).
% 29.32/29.15  tff(decl_75631, type, fn_tobacco_plant_56: $i > $i).
% 29.32/29.15  tff(decl_75632, type, fn_tobacco_plant_57: $i > $i).
% 29.32/29.15  tff(decl_75633, type, fn_tobacco_plant_58: $i > $i).
% 29.32/29.15  tff(decl_75634, type, fn_tobacco_plant_59: $i > $i).
% 29.32/29.15  tff(decl_75635, type, fn_tobacco_plant_60: $i > $i).
% 29.32/29.15  tff(decl_75636, type, fn_tobacco_plant_61: $i > $i).
% 29.32/29.15  tff(decl_75637, type, fn_tobacco_plant_62: $i > $i).
% 29.32/29.15  tff(decl_75638, type, fn_tobacco_plant_63: $i > $i).
% 29.32/29.15  tff(decl_75639, type, fn_tobacco_plant_64: $i > $i).
% 29.32/29.15  tff(decl_75640, type, fn_tobacco_plant_65: $i > $i).
% 29.32/29.15  tff(decl_75641, type, fn_tobacco_plant_66: $i > $i).
% 29.32/29.15  tff(decl_75642, type, fn_tobacco_plant_67: $i > $i).
% 29.32/29.15  tff(decl_75643, type, fn_tobacco_plant_68: $i > $i).
% 29.32/29.15  tff(decl_75644, type, fn_tobacco_plant_69: $i > $i).
% 29.32/29.15  tff(decl_75645, type, fn_tobacco_plant_70: $i > $i).
% 29.32/29.15  tff(decl_75646, type, fn_tobacco_plant_71: $i > $i).
% 29.32/29.15  tff(decl_75647, type, fn_tobacco_plant_72: $i > $i).
% 29.32/29.15  tff(decl_75648, type, fn_tobacco_plant_73: $i > $i).
% 29.32/29.15  tff(decl_75649, type, fn_tobacco_plant_74: $i > $i).
% 29.32/29.15  tff(decl_75650, type, fn_tobacco_plant_75: $i > $i).
% 29.32/29.15  tff(decl_75651, type, fn_tobacco_plant_76: $i > $i).
% 29.32/29.15  tff(decl_75652, type, fn_tobacco_plant_77: $i > $i).
% 29.32/29.15  tff(decl_75653, type, fn_tobacco_plant_4: $i > $i).
% 29.32/29.15  tff(decl_75654, type, fn_tobacco_plant_3: $i > $i).
% 29.32/29.15  tff(decl_75655, type, fn_tobacco_plant_46: $i > $i).
% 29.32/29.15  tff(decl_75656, type, fn_tobacco_plant_47: $i > $i).
% 29.32/29.15  tff(decl_75657, type, fn_tobacco_plant_13: $i > $i).
% 29.32/29.15  tff(decl_75658, type, fn_tobacco_plant_10: $i > $i).
% 29.32/29.15  tff(decl_75659, type, fn_tobacco_plant_9: $i > $i).
% 29.32/29.15  tff(decl_75660, type, fn_tobacco_plant_11: $i > $i).
% 29.32/29.15  tff(decl_75661, type, fn_tobacco_plant_12: $i > $i).
% 29.32/29.15  tff(decl_75662, type, fn_tobacco_plant_14: $i > $i).
% 29.32/29.15  tff(decl_75663, type, 'Toe': $i).
% 29.32/29.15  tff(decl_75664, type, 'Any of the digits at the end of a human foot.': $i).
% 29.32/29.15  tff(decl_75665, type, toe: $i).
% 29.32/29.15  tff(decl_75666, type, tomato_chimera_1: $i > $o).
% 29.32/29.15  tff(decl_75667, type, 'Tomato-Chimera': $i).
% 29.32/29.15  tff(decl_75668, type, 'A tomato plant with a mix of genetially different cells from different origins.': $i).
% 29.32/29.15  tff(decl_75669, type, 'chimera of tomato': $i).
% 29.32/29.15  tff(decl_75670, type, 'tomato chimera': $i).
% 29.32/29.15  tff(decl_75671, type, 'tomato-chimera': $i).
% 29.32/29.15  tff(decl_75672, type, tomato_plant_1: $i > $o).
% 29.32/29.15  tff(decl_75673, type, 'Tomato-Chimera-Experiment': $i).
% 29.32/29.15  tff(decl_75674, type, 'Experiment in which the process of flower development was studied by combining genetically different tomato plants to create a tomato chimera.': $i).
% 29.32/29.15  tff(decl_75675, type, 'tomato chimera experiment': $i).
% 29.32/29.15  tff(decl_75676, type, 'tomato-chimera-experiment': $i).
% 29.32/29.15  tff(decl_75677, type, fn_tomato_chimera_experiment_1: $i > $i).
% 29.32/29.15  tff(decl_75678, type, fn_tomato_chimera_experiment_2: $i > $i).
% 29.32/29.15  tff(decl_75679, type, fn_tomato_chimera_experiment_3: $i > $i).
% 29.32/29.15  tff(decl_75680, type, fn_tomato_chimera_experiment_4: $i > $i).
% 29.32/29.15  tff(decl_75681, type, fn_tomato_chimera_experiment_5: $i > $i).
% 29.32/29.15  tff(decl_75682, type, tomato_fasciated_gene_1: $i > $o).
% 29.32/29.15  tff(decl_75683, type, 'Tomato-Fasciated-Gene': $i).
% 29.32/29.15  tff(decl_75684, type, 'The gene that is most often used to confer size to tomatoes is the Fasciated gene.': $i).
% 29.32/29.15  tff(decl_75685, type, 'tomato fasciated gene': $i).
% 29.32/29.15  tff(decl_75686, type, 'tomato-fasciated-gene': $i).
% 29.32/29.15  tff(decl_75687, type, fn_tomato_fasciated_gene_1: $i > $i).
% 29.32/29.15  tff(decl_75688, type, fn_tomato_fasciated_gene_2: $i > $i).
% 29.32/29.15  tff(decl_75689, type, 'Tomato-Plant': $i).
% 29.32/29.15  tff(decl_75690, type, 'The tomato plant belongs to the nightshade family. It is a perennial in its native habitat and provides edible fruits.': $i).
% 29.32/29.15  tff(decl_75691, type, 'plant of tomato': $i).
% 29.32/29.15  tff(decl_75692, type, 'tomato plant': $i).
% 29.32/29.15  tff(decl_75693, type, 'tomato-plant': $i).
% 29.32/29.15  tff(decl_75694, type, fn_tomato_plant_1: $i > $i).
% 29.32/29.15  tff(decl_75695, type, fn_tomato_plant_2: $i > $i).
% 29.32/29.15  tff(decl_75696, type, fn_tomato_plant_3: $i > $i).
% 29.32/29.15  tff(decl_75697, type, fn_tomato_plant_4: $i > $i).
% 29.32/29.15  tff(decl_75698, type, fn_tomato_plant_5: $i > $i).
% 29.32/29.15  tff(decl_75699, type, fn_tomato_plant_6: $i > $i).
% 29.32/29.15  tff(decl_75700, type, fn_tomato_plant_7: $i > $i).
% 29.32/29.15  tff(decl_75701, type, fn_tomato_plant_8: $i > $i).
% 29.32/29.15  tff(decl_75702, type, fn_tomato_plant_9: $i > $i).
% 29.32/29.15  tff(decl_75703, type, fn_tomato_plant_10: $i > $i).
% 29.32/29.15  tff(decl_75704, type, fn_tomato_plant_11: $i > $i).
% 29.32/29.15  tff(decl_75705, type, fn_tomato_plant_12: $i > $i).
% 29.32/29.15  tff(decl_75706, type, fn_tomato_plant_13: $i > $i).
% 29.32/29.15  tff(decl_75707, type, fn_tomato_plant_14: $i > $i).
% 29.32/29.15  tff(decl_75708, type, fn_tomato_plant_15: $i > $i).
% 29.32/29.15  tff(decl_75709, type, fn_tomato_plant_16: $i > $i).
% 29.32/29.15  tff(decl_75710, type, fn_tomato_plant_17: $i > $i).
% 29.32/29.15  tff(decl_75711, type, fn_tomato_plant_20: $i > $i).
% 29.32/29.15  tff(decl_75712, type, fn_tomato_plant_21: $i > $i).
% 29.32/29.15  tff(decl_75713, type, fn_tomato_plant_22: $i > $i).
% 29.32/29.15  tff(decl_75714, type, fn_tomato_plant_23: $i > $i).
% 29.32/29.15  tff(decl_75715, type, fn_tomato_plant_24: $i > $i).
% 29.32/29.15  tff(decl_75716, type, fn_tomato_plant_25: $i > $i).
% 29.32/29.15  tff(decl_75717, type, fn_tomato_plant_26: $i > $i).
% 29.32/29.15  tff(decl_75718, type, fn_tomato_plant_18: $i > $i).
% 29.32/29.15  tff(decl_75719, type, fn_tomato_plant_19: $i > $i).
% 29.32/29.15  tff(decl_75720, type, 'Tongue': $i).
% 29.32/29.15  tff(decl_75721, type, 'Muscular organ in the mouth of vertebrates which functions in the sensation of taste and in digestion. In some animals, it also functions in communication.': $i).
% 29.32/29.15  tff(decl_75722, type, 'Tonicity': $i).
% 29.32/29.15  tff(decl_75723, type, 'A measure of the osmotic pressure gradient between two liquids separated by a semi-permeable membrane.': $i).
% 29.32/29.15  tff(decl_75724, type, tonicity: $i).
% 29.32/29.15  tff(decl_75725, type, 'Tonoplast': $i).
% 29.32/29.15  tff(decl_75726, type, 'The tonoplast is the cytoplasmic membrane surrounding a vacuole, separating the vacuolar contents from the cell\\s cytoplasm. It helps in selective transfer of solutes.': $i).
% 29.32/29.15  tff(decl_75727, type, 'vacuolar membrane': $i).
% 29.32/29.15  tff(decl_75728, type, tonoplast: $i).
% 29.32/29.15  tff(decl_75729, type, fn_tonoplast_1: $i > $i).
% 29.32/29.15  tff(decl_75730, type, 'Tooth': $i).
% 29.32/29.15  tff(decl_75731, type, 'A small, calcified structure in the jaws of many vertebrate animals, used to rip, shred, bite, or chew food.': $i).
% 29.32/29.15  tff(decl_75732, type, tooth: $i).
% 29.32/29.15  tff(decl_75733, type, tooth_brushing_1: $i > $o).
% 29.32/29.15  tff(decl_75734, type, 'Tooth-Brushing': $i).
% 29.32/29.15  tff(decl_75735, type, 'Cleaning of the teeth with a brush.': $i).
% 29.32/29.15  tff(decl_75736, type, 'brushing of tooth': $i).
% 29.32/29.15  tff(decl_75737, type, 'tooth brushing': $i).
% 29.32/29.15  tff(decl_75738, type, 'tooth-brushing': $i).
% 29.32/29.15  tff(decl_75739, type, fn_tooth_brushing_1: $i > $i).
% 29.32/29.15  tff(decl_75740, type, fn_tooth_brushing_2: $i > $i).
% 29.32/29.15  tff(decl_75741, type, tooth_flossing_1: $i > $o).
% 29.32/29.15  tff(decl_75742, type, 'Tooth-Flossing': $i).
% 29.32/29.15  tff(decl_75743, type, 'Cleaning of the teeth and between the teeth with a length of floss.': $i).
% 29.32/29.15  tff(decl_75744, type, 'tooth flossing': $i).
% 29.32/29.15  tff(decl_75745, type, 'tooth-flossing': $i).
% 29.32/29.15  tff(decl_75746, type, fn_tooth_flossing_1: $i > $i).
% 29.32/29.15  tff(decl_75747, type, fn_tooth_flossing_2: $i > $i).
% 29.32/29.15  tff(decl_75748, type, topoisomerase_1: $i > $o).
% 29.32/29.15  tff(decl_75749, type, 'Topoisomerase': $i).
% 29.32/29.15  tff(decl_75750, type, 'An enzyme that oversees the unwinding of DNA strands during DNA replication.': $i).
% 29.32/29.15  tff(decl_75751, type, topoisomerase: $i).
% 29.32/29.15  tff(decl_75752, type, fn_topoisomerase_1: $i > $i).
% 29.32/29.15  tff(decl_75753, type, fn_topoisomerase_2: $i > $i).
% 29.32/29.15  tff(decl_75754, type, fn_topoisomerase_3: $i > $i).
% 29.32/29.15  tff(decl_75755, type, fn_topoisomerase_4: $i > $i).
% 29.32/29.15  tff(decl_75756, type, fn_topoisomerase_5: $i > $i).
% 29.32/29.15  tff(decl_75757, type, fn_topoisomerase_6: $i > $i).
% 29.32/29.15  tff(decl_75758, type, fn_topoisomerase_7: $i > $i).
% 29.32/29.15  tff(decl_75759, type, fn_topoisomerase_8: $i > $i).
% 29.32/29.15  tff(decl_75760, type, fn_topoisomerase_9: $i > $i).
% 29.32/29.15  tff(decl_75761, type, fn_topoisomerase_10: $i > $i).
% 29.32/29.15  tff(decl_75762, type, fn_topoisomerase_11: $i > $i).
% 29.32/29.15  tff(decl_75763, type, fn_topoisomerase_12: $i > $i).
% 29.32/29.15  tff(decl_75764, type, fn_topoisomerase_13: $i > $i).
% 29.32/29.15  tff(decl_75765, type, fn_topoisomerase_14: $i > $i).
% 29.32/29.15  tff(decl_75766, type, fn_topoisomerase_15: $i > $i).
% 29.32/29.15  tff(decl_75767, type, fn_topoisomerase_16: $i > $i).
% 29.32/29.15  tff(decl_75768, type, fn_topoisomerase_17: $i > $i).
% 29.32/29.15  tff(decl_75769, type, fn_topoisomerase_18: $i > $i).
% 29.32/29.15  tff(decl_75770, type, fn_topoisomerase_19: $i > $i).
% 29.32/29.15  tff(decl_75771, type, fn_topoisomerase_20: $i > $i).
% 29.32/29.15  tff(decl_75772, type, 'Topsoil': $i).
% 29.32/29.15  tff(decl_75773, type, 'The uppermost layer of soil, containing the highest concentration of organic matter and microbes. Topsoil is the most biologically active of Earth\\s soils.': $i).
% 29.32/29.15  tff(decl_75774, type, topsoil: $i).
% 29.32/29.15  tff(decl_75775, type, 'Torpor': $i).
% 29.32/29.15  tff(decl_75776, type, 'In animals, a state of decreased physiological activity and metabolism.': $i).
% 29.32/29.15  tff(decl_75777, type, torpor: $i).
% 29.32/29.15  tff(decl_75778, type, 'Torsion': $i).
% 29.32/29.15  tff(decl_75779, type, 'In the larval development of gastropod molluscs, a 180-degree rotation of the visceral mass and associated organs, resulting in the positioning of the mantle cavity and anus over the animal\\s head.': $i).
% 29.32/29.15  tff(decl_75780, type, torsion: $i).
% 29.32/29.15  tff(decl_75781, type, totipotent_1: $i > $o).
% 29.32/29.15  tff(decl_75782, type, 'Totipotent': $i).
% 29.32/29.15  tff(decl_75783, type, 'Term used to describe a cell that can give rise to all the differentiated cells in an organism, including the extraembryonic membranes in species that have them.': $i).
% 29.32/29.15  tff(decl_75784, type, totipotent: $i).
% 29.32/29.15  tff(decl_75785, type, totipotent_cell_1: $i > $o).
% 29.32/29.15  tff(decl_75786, type, 'Totipotent-Cell': $i).
% 29.32/29.15  tff(decl_75787, type, 'The cell that is capable of developing into any cell type is called totipotent cell.': $i).
% 29.32/29.15  tff(decl_75788, type, 'totipotent stem cell': $i).
% 29.32/29.15  tff(decl_75789, type, 'cell of totipotent': $i).
% 29.32/29.15  tff(decl_75790, type, 'totipotent cell': $i).
% 29.32/29.15  tff(decl_75791, type, 'totipotent-cell': $i).
% 29.32/29.15  tff(decl_75792, type, fn_totipotent_cell_1: $i > $i).
% 29.32/29.15  tff(decl_75793, type, fn_totipotent_cell_2: $i > $i).
% 29.32/29.15  tff(decl_75794, type, fn_totipotent_cell_3: $i > $i).
% 29.32/29.15  tff(decl_75795, type, fn_totipotent_cell_4: $i > $i).
% 29.32/29.15  tff(decl_75796, type, fn_totipotent_cell_5: $i > $i).
% 29.32/29.15  tff(decl_75797, type, fn_totipotent_cell_6: $i > $i).
% 29.32/29.15  tff(decl_75798, type, fn_totipotent_cell_7: $i > $i).
% 29.32/29.15  tff(decl_75799, type, fn_totipotent_cell_8: $i > $i).
% 29.32/29.15  tff(decl_75800, type, fn_totipotent_cell_9: $i > $i).
% 29.32/29.15  tff(decl_75801, type, fn_totipotent_cell_10: $i > $i).
% 29.32/29.15  tff(decl_75802, type, fn_totipotent_cell_11: $i > $i).
% 29.32/29.15  tff(decl_75803, type, 'Touch': $i).
% 29.32/29.15  tff(decl_75804, type, 'The process of interpreting information from the effects of receptors in the skin and other mucous membranes being activated - primarily by contact.': $i).
% 29.32/29.15  tff(decl_75805, type, 'Toxin': $i).
% 29.32/29.15  tff(decl_75806, type, 'A substance produced by a living organism that induces injury or illness if ingested or otherwise introduced into the body of another organism.': $i).
% 29.32/29.15  tff(decl_75807, type, poison: $i).
% 29.32/29.15  tff(decl_75808, type, toxin: $i).
% 29.32/29.15  tff(decl_75809, type, trace_chemical_entity_1: $i > $o).
% 29.32/29.15  tff(decl_75810, type, 'Trace-Chemical-Entity': $i).
% 29.32/29.15  tff(decl_75811, type, 'An element required for life, but in very small amounts.': $i).
% 29.32/29.15  tff(decl_75812, type, 'trace chemical entity': $i).
% 29.32/29.15  tff(decl_75813, type, 'trace-chemical-entity': $i).
% 29.32/29.15  tff(decl_75814, type, fn_trace_chemical_entity_1: $i > $i).
% 29.32/29.15  tff(decl_75815, type, trace_element_1: $i > $o).
% 29.32/29.15  tff(decl_75816, type, 'Trace-Element': $i).
% 29.32/29.15  tff(decl_75817, type, 'A trace element is an element in a sample that has an average concentration of less than 100 parts per million measured in atomic count, or less than 100 micrograms per gram.': $i).
% 29.32/29.15  tff(decl_75818, type, 'element of trace': $i).
% 29.32/29.15  tff(decl_75819, type, 'trace element': $i).
% 29.32/29.15  tff(decl_75820, type, 'trace-element': $i).
% 29.32/29.15  tff(decl_75821, type, fn_trace_element_2: $i > $i).
% 29.32/29.15  tff(decl_75822, type, fn_trace_element_3: $i > $i).
% 29.32/29.15  tff(decl_75823, type, 'Trachea': $i).
% 29.32/29.15  tff(decl_75824, type, 'The largest tube of the vertebrate respiratory system; it conducts air between the mouth and nasal cavities and the bronchi.': $i).
% 29.32/29.15  tff(decl_75825, type, windpipe: $i).
% 29.32/29.15  tff(decl_75826, type, trachea: $i).
% 29.32/29.15  tff(decl_75827, type, fn_trachea_5: $i > $i).
% 29.32/29.15  tff(decl_75828, type, fn_trachea_6: $i > $i).
% 29.32/29.15  tff(decl_75829, type, fn_trachea_7: $i > $i).
% 29.32/29.15  tff(decl_75830, type, fn_trachea_8: $i > $i).
% 29.32/29.15  tff(decl_75831, type, fn_trachea_9: $i > $i).
% 29.32/29.15  tff(decl_75832, type, fn_trachea_10: $i > $i).
% 29.32/29.15  tff(decl_75833, type, tracheal_system_1: $i > $o).
% 29.32/29.15  tff(decl_75834, type, 'Tracheal-System': $i).
% 29.32/29.15  tff(decl_75835, type, 'In terrestrial arthropods such as insects and spiders, a system of highly branched tubules that open to the outside and deliver oxygen to individual cells.': $i).
% 29.32/29.15  tff(decl_75836, type, 'tracheal system': $i).
% 29.32/29.15  tff(decl_75837, type, 'tracheal-system': $i).
% 29.32/29.15  tff(decl_75838, type, 'Tracheid': $i).
% 29.32/29.15  tff(decl_75839, type, 'A long cell found in the xylem of vascular plants. Tracheids function in the transport of water and dissolved minerals through the plant and are dead in their functional state.': $i).
% 29.32/29.15  tff(decl_75840, type, tracheid: $i).
% 29.32/29.15  tff(decl_75841, type, water_conducting_cell_1: $i > $o).
% 29.32/29.15  tff(decl_75842, type, fn_tracheid_1: $i > $i).
% 29.32/29.15  tff(decl_75843, type, fn_tracheid_2: $i > $i).
% 29.32/29.15  tff(decl_75844, type, fn_tracheid_3: $i > $i).
% 29.32/29.15  tff(decl_75845, type, fn_tracheid_4: $i > $i).
% 29.32/29.15  tff(decl_75846, type, fn_tracheid_5: $i > $i).
% 29.32/29.15  tff(decl_75847, type, fn_tracheid_6: $i > $i).
% 29.32/29.15  tff(decl_75848, type, fn_tracheid_7: $i > $i).
% 29.32/29.15  tff(decl_75849, type, fn_tracheid_8: $i > $i).
% 29.32/29.15  tff(decl_75850, type, fn_tracheid_9: $i > $i).
% 29.32/29.15  tff(decl_75851, type, fn_tracheid_10: $i > $i).
% 29.32/29.15  tff(decl_75852, type, fn_tracheid_11: $i > $i).
% 29.32/29.15  tff(decl_75853, type, fn_tracheid_12: $i > $i).
% 29.32/29.15  tff(decl_75854, type, fn_tracheid_18: $i > $i).
% 29.32/29.15  tff(decl_75855, type, fn_tracheid_22: $i > $i).
% 29.32/29.15  tff(decl_75856, type, fn_tracheid_23: $i > $i).
% 29.32/29.15  tff(decl_75857, type, fn_tracheid_24: $i > $i).
% 29.32/29.15  tff(decl_75858, type, fn_tracheid_25: $i > $i).
% 29.32/29.15  tff(decl_75859, type, fn_tracheid_26: $i > $i).
% 29.32/29.15  tff(decl_75860, type, fn_tracheid_27: $i > $i).
% 29.32/29.15  tff(decl_75861, type, fn_tracheid_28: $i > $i).
% 29.32/29.15  tff(decl_75862, type, fn_tracheid_29: $i > $i).
% 29.32/29.15  tff(decl_75863, type, fn_tracheid_30: $i > $i).
% 29.32/29.15  tff(decl_75864, type, fn_tracheid_31: $i > $i).
% 29.32/29.15  tff(decl_75865, type, fn_tracheid_32: $i > $i).
% 29.32/29.15  tff(decl_75866, type, fn_tracheid_33: $i > $i).
% 29.32/29.15  tff(decl_75867, type, fn_tracheid_34: $i > $i).
% 29.32/29.15  tff(decl_75868, type, fn_tracheid_35: $i > $i).
% 29.32/29.15  tff(decl_75869, type, fn_tracheid_36: $i > $i).
% 29.32/29.15  tff(decl_75870, type, fn_tracheid_37: $i > $i).
% 29.32/29.15  tff(decl_75871, type, fn_tracheid_38: $i > $i).
% 29.32/29.15  tff(decl_75872, type, fn_tracheid_39: $i > $i).
% 29.32/29.15  tff(decl_75873, type, fn_tracheid_40: $i > $i).
% 29.32/29.15  tff(decl_75874, type, fn_tracheid_41: $i > $i).
% 29.32/29.15  tff(decl_75875, type, fn_tracheid_42: $i > $i).
% 29.32/29.15  tff(decl_75876, type, fn_tracheid_43: $i > $i).
% 29.32/29.15  tff(decl_75877, type, fn_tracheid_44: $i > $i).
% 29.32/29.15  tff(decl_75878, type, fn_tracheid_45: $i > $i).
% 29.32/29.15  tff(decl_75879, type, fn_tracheid_47: $i > $i).
% 29.32/29.15  tff(decl_75880, type, fn_tracheid_48: $i > $i).
% 29.32/29.15  tff(decl_75881, type, fn_tracheid_49: $i > $i).
% 29.32/29.15  tff(decl_75882, type, fn_tracheid_50: $i > $i).
% 29.32/29.15  tff(decl_75883, type, fn_tracheid_51: $i > $i).
% 29.32/29.15  tff(decl_75884, type, fn_tracheid_52: $i > $i).
% 29.32/29.15  tff(decl_75885, type, fn_tracheid_53: $i > $i).
% 29.32/29.15  tff(decl_75886, type, fn_tracheid_54: $i > $i).
% 29.32/29.15  tff(decl_75887, type, fn_tracheid_55: $i > $i).
% 29.32/29.15  tff(decl_75888, type, fn_tracheid_56: $i > $i).
% 29.32/29.15  tff(decl_75889, type, fn_tracheid_57: $i > $i).
% 29.32/29.15  tff(decl_75890, type, fn_tracheid_58: $i > $i).
% 29.32/29.15  tff(decl_75891, type, fn_tracheid_59: $i > $i).
% 29.32/29.15  tff(decl_75892, type, fn_tracheid_60: $i > $i).
% 29.32/29.15  tff(decl_75893, type, fn_tracheid_61: $i > $i).
% 29.32/29.15  tff(decl_75894, type, fn_tracheid_62: $i > $i).
% 29.32/29.15  tff(decl_75895, type, fn_tracheid_63: $i > $i).
% 29.32/29.15  tff(decl_75896, type, fn_tracheid_64: $i > $i).
% 29.32/29.15  tff(decl_75897, type, fn_tracheid_65: $i > $i).
% 29.32/29.15  tff(decl_75898, type, fn_tracheid_66: $i > $i).
% 29.32/29.15  tff(decl_75899, type, fn_tracheid_67: $i > $i).
% 29.32/29.15  tff(decl_75900, type, fn_tracheid_70: $i > $i).
% 29.32/29.15  tff(decl_75901, type, fn_tracheid_71: $i > $i).
% 29.32/29.15  tff(decl_75902, type, fn_tracheid_72: $i > $i).
% 29.32/29.15  tff(decl_75903, type, fn_tracheid_74: $i > $i).
% 29.32/29.15  tff(decl_75904, type, fn_tracheid_75: $i > $i).
% 29.32/29.15  tff(decl_75905, type, fn_tracheid_76: $i > $i).
% 29.32/29.15  tff(decl_75906, type, fn_tracheid_77: $i > $i).
% 29.32/29.15  tff(decl_75907, type, fn_tracheid_78: $i > $i).
% 29.32/29.15  tff(decl_75908, type, fn_tracheid_79: $i > $i).
% 29.32/29.15  tff(decl_75909, type, cavity_0: $i).
% 29.32/29.15  tff(decl_75910, type, fn_tracheid_46: $i > $i).
% 29.32/29.15  tff(decl_75911, type, fn_tracheid_68: $i > $i).
% 29.32/29.15  tff(decl_75912, type, fn_tracheid_69: $i > $i).
% 29.32/29.15  tff(decl_75913, type, fn_tracheid_21: $i > $i).
% 29.32/29.15  tff(decl_75914, type, fn_tracheid_73: $i > $i).
% 29.32/29.15  tff(decl_75915, type, fn_tracheid_20: $i > $i).
% 29.32/29.15  tff(decl_75916, type, trade_1: $i > $o).
% 29.32/29.15  tff(decl_75917, type, 'Trade': $i).
% 29.32/29.15  tff(decl_75918, type, 'Trade is the transfer of ownership of goods and services from one person to another.': $i).
% 29.32/29.15  tff(decl_75919, type, trade: $i).
% 29.32/29.15  tff(decl_75920, type, 'Trailer-segment': $i).
% 29.32/29.15  tff(decl_75921, type, 'Trailer segment is a sequence at mRNA which contains the \\stop codon\\ serving as termination signal for protein/polypeptide synthesis': $i).
% 29.32/29.15  tff(decl_75922, type, 'segment of trailer': $i).
% 29.32/29.15  tff(decl_75923, type, 'trailer segment': $i).
% 29.32/29.15  tff(decl_75924, type, 'trailer-segment': $i).
% 29.32/29.15  tff(decl_75925, type, training_1: $i > $o).
% 29.32/29.15  tff(decl_75926, type, 'Training': $i).
% 29.32/29.15  tff(decl_75927, type, training: $i).
% 29.32/29.15  tff(decl_75928, type, grooming: $i).
% 29.32/29.15  tff(decl_75929, type, train: $i).
% 29.32/29.15  tff(decl_75930, type, 'Trait': $i).
% 29.32/29.15  tff(decl_75931, type, 'A physical or physiological variant of a character.': $i).
% 29.32/29.15  tff(decl_75932, type, attribute: $i).
% 29.32/29.15  tff(decl_75933, type, feature: $i).
% 29.32/29.15  tff(decl_75934, type, 'discrete trait': $i).
% 29.32/29.15  tff(decl_75935, type, 'physical feature': $i).
% 29.32/29.15  tff(decl_75936, type, variant: $i).
% 29.32/29.15  tff(decl_75937, type, 'evolutionary adaptation': $i).
% 29.32/29.15  tff(decl_75938, type, 'Trait-Constant': $i).
% 29.32/29.15  tff(decl_75939, type, 'constant of trait': $i).
% 29.32/29.15  tff(decl_75940, type, 'trait constant': $i).
% 29.32/29.15  tff(decl_75941, type, 'trait-constant': $i).
% 29.32/29.15  tff(decl_75942, type, 'Trait-On-A-Range': $i).
% 29.32/29.15  tff(decl_75943, type, 'It refers to ranging of a phenotypic trait.': $i).
% 29.32/29.15  tff(decl_75944, type, 'trait on a range': $i).
% 29.32/29.15  tff(decl_75945, type, 'trait-on-a-range': $i).
% 29.32/29.15  tff(decl_75946, type, 'Trait-On-A-Scale': $i).
% 29.32/29.15  tff(decl_75947, type, 'Scoring of a trait on certain scale.': $i).
% 29.32/29.15  tff(decl_75948, type, 'trait on a scale': $i).
% 29.32/29.15  tff(decl_75949, type, 'trait-on-a-scale': $i).
% 29.32/29.15  tff(decl_75950, type, 'Trait-On-One-End-Of-A-Range': $i).
% 29.32/29.15  tff(decl_75951, type, 'It refers to phenotypic trait at an end of a defined range.': $i).
% 29.32/29.15  tff(decl_75952, type, 'trait on one end of a range': $i).
% 29.32/29.15  tff(decl_75953, type, 'trait-on-one-end-of-a-range': $i).
% 29.32/29.15  tff(decl_75954, type, trait_on_the_middle_of_the_range_1: $i > $o).
% 29.32/29.15  tff(decl_75955, type, 'Trait-On-The-Middle-Of-The-Range': $i).
% 29.32/29.15  tff(decl_75956, type, 'It refers to phenotypic trait at the middle of defined range.': $i).
% 29.32/29.15  tff(decl_75957, type, 'trait on the middle of the range': $i).
% 29.32/29.15  tff(decl_75958, type, 'trait-on-the-middle-of-the-range': $i).
% 29.32/29.15  tff(decl_75959, type, 'Trait-Value': $i).
% 29.32/29.15  tff(decl_75960, type, 'a distinguishing feature of personal nature': $i).
% 29.32/29.15  tff(decl_75961, type, 'value of trait': $i).
% 29.32/29.15  tff(decl_75962, type, 'trait value': $i).
% 29.32/29.15  tff(decl_75963, type, 'trait-value': $i).
% 29.32/29.15  tff(decl_75964, type, trancription_in_mitochondria_1: $i > $o).
% 29.32/29.15  tff(decl_75965, type, fn_trancription_in_mitochondria_1: $i > $i).
% 29.32/29.15  tff(decl_75966, type, 'Trancription-In-Mitochondria': $i).
% 29.32/29.15  tff(decl_75967, type, 'The synthesis of RNA using mitochondrial DNA as a template.': $i).
% 29.32/29.15  tff(decl_75968, type, 'trancription in mitochondrion': $i).
% 29.32/29.15  tff(decl_75969, type, 'trancription-in-mitochondria': $i).
% 29.32/29.15  tff(decl_75970, type, 'Trans-face': $i).
% 29.32/29.15  tff(decl_75971, type, 'Trans face is one of the faces of the organelles.': $i).
% 29.32/29.15  tff(decl_75972, type, 'trans face': $i).
% 29.32/29.15  tff(decl_75973, type, 'trans-face': $i).
% 29.32/29.15  tff(decl_75974, type, fn_trans_face_1: $i > $i).
% 29.32/29.15  tff(decl_75975, type, fn_trans_face_2: $i > $i).
% 29.32/29.15  tff(decl_75976, type, fn_trans_face_3: $i > $i).
% 29.32/29.15  tff(decl_75977, type, 'Trans-Fat': $i).
% 29.32/29.15  tff(decl_75978, type, 'An unsaturated fat containing one or more trans double bonds.': $i).
% 29.32/29.15  tff(decl_75979, type, 'trans fat': $i).
% 29.32/29.15  tff(decl_75980, type, 'trans-fat': $i).
% 29.32/29.15  tff(decl_75981, type, 'Transcribed-Terminator': $i).
% 29.32/29.15  tff(decl_75982, type, 'A sequence of nucleotides in DNA that marks the end of a gene and signals RNA polymerase to release the newly made RNA molecule and detach from the DNA.': $i).
% 29.32/29.15  tff(decl_75983, type, 'transcribed terminator': $i).
% 29.32/29.15  tff(decl_75984, type, 'transcribed-terminator': $i).
% 29.32/29.15  tff(decl_75985, type, fn_transcribed_terminator_1: $i > $i).
% 29.32/29.15  tff(decl_75986, type, fn_transcribed_terminator_2: $i > $i).
% 29.32/29.15  tff(decl_75987, type, fn_transcribed_terminator_3: $i > $i).
% 29.32/29.15  tff(decl_75988, type, fn_transcribed_terminator_4: $i > $i).
% 29.32/29.15  tff(decl_75989, type, fn_transcribed_terminator_5: $i > $i).
% 29.32/29.15  tff(decl_75990, type, fn_transcribed_terminator_6: $i > $i).
% 29.32/29.15  tff(decl_75991, type, fn_transcribed_terminator_7: $i > $i).
% 29.32/29.15  tff(decl_75992, type, fn_transcribed_terminator_8: $i > $i).
% 29.32/29.15  tff(decl_75993, type, fn_transcribed_terminator_9: $i > $i).
% 29.32/29.15  tff(decl_75994, type, fn_transcribed_terminator_10: $i > $i).
% 29.32/29.15  tff(decl_75995, type, fn_transcribed_terminator_11: $i > $i).
% 29.32/29.15  tff(decl_75996, type, fn_transcribed_terminator_12: $i > $i).
% 29.32/29.15  tff(decl_75997, type, fn_transcribed_terminator_13: $i > $i).
% 29.32/29.15  tff(decl_75998, type, 'Transcription': $i).
% 29.32/29.15  tff(decl_75999, type, 'The production of an mRNA transcript from a DNA strand that is used as a template.': $i).
% 29.32/29.15  tff(decl_76000, type, 'pre mrna synthesis': $i).
% 29.32/29.15  tff(decl_76001, type, 'pre-mrna-synthesis': $i).
% 29.32/29.15  tff(decl_76002, type, 'synthesis of rna from dna template': $i).
% 29.32/29.15  tff(decl_76003, type, 'synthesis of rna from a dna template': $i).
% 29.32/29.15  tff(decl_76004, type, fn_transcription_3: $i > $i).
% 29.32/29.15  tff(decl_76005, type, fn_transcription_4: $i > $i).
% 29.32/29.15  tff(decl_76006, type, fn_transcription_5: $i > $i).
% 29.32/29.15  tff(decl_76007, type, fn_transcription_7: $i > $i).
% 29.32/29.15  tff(decl_76008, type, fn_transcription_10: $i > $i).
% 29.32/29.15  tff(decl_76009, type, fn_transcription_11: $i > $i).
% 29.32/29.15  tff(decl_76010, type, fn_transcription_12: $i > $i).
% 29.32/29.15  tff(decl_76011, type, fn_transcription_14: $i > $i).
% 29.32/29.15  tff(decl_76012, type, fn_transcription_15: $i > $i).
% 29.32/29.15  tff(decl_76013, type, fn_transcription_16: $i > $i).
% 29.32/29.15  tff(decl_76014, type, fn_transcription_17: $i > $i).
% 29.32/29.15  tff(decl_76015, type, fn_transcription_18: $i > $i).
% 29.32/29.15  tff(decl_76016, type, transcription_termination_1: $i > $o).
% 29.32/29.15  tff(decl_76017, type, fn_transcription_unit_1: $i > $i).
% 29.32/29.15  tff(decl_76018, type, fn_transcription_elongation_6: $i > $i).
% 29.32/29.15  tff(decl_76019, type, fn_transcription_elongation_7: $i > $i).
% 29.32/29.15  tff(decl_76020, type, fn_transcription_termination_1: $i > $i).
% 29.32/29.15  tff(decl_76021, type, fn_transcription_termination_2: $i > $i).
% 29.32/29.15  tff(decl_76022, type, fn_transcription_termination_3: $i > $i).
% 29.32/29.15  tff(decl_76023, type, fn_transcription_elongation_4: $i > $i).
% 29.32/29.15  tff(decl_76024, type, fn_transcription_8: $i > $i).
% 29.32/29.15  tff(decl_76025, type, fn_transcription_9: $i > $i).
% 29.32/29.15  tff(decl_76026, type, 'Transcription-Elongation': $i).
% 29.32/29.15  tff(decl_76027, type, 'The continuous addition of RNA nucleotides to the 3\\ end of the mRNA transcript that is being formed.': $i).
% 29.32/29.15  tff(decl_76028, type, 'rna synthesis elongation': $i).
% 29.32/29.15  tff(decl_76029, type, 'elongation of transcription': $i).
% 29.32/29.15  tff(decl_76030, type, 'transcription elongation': $i).
% 29.32/29.15  tff(decl_76031, type, 'transcription-elongation': $i).
% 29.32/29.15  tff(decl_76032, type, transcription_phase_1: $i > $o).
% 29.32/29.15  tff(decl_76033, type, fn_transcription_elongation_1: $i > $i).
% 29.32/29.15  tff(decl_76034, type, fn_transcription_elongation_2: $i > $i).
% 29.32/29.15  tff(decl_76035, type, fn_transcription_elongation_3: $i > $i).
% 29.32/29.15  tff(decl_76036, type, fn_transcription_elongation_5: $i > $i).
% 29.32/29.15  tff(decl_76037, type, fn_transcription_elongation_8: $i > $i).
% 29.32/29.15  tff(decl_76038, type, fn_transcription_elongation_9: $i > $i).
% 29.32/29.15  tff(decl_76039, type, 'Transcription-Factor': $i).
% 29.32/29.15  tff(decl_76040, type, 'A protein that binds to a specific DNA sequence and thus affects the transcription of that particular gene.': $i).
% 29.32/29.15  tff(decl_76041, type, 'sequence specific dna binding factor': $i).
% 29.32/29.15  tff(decl_76042, type, 'sequence-specific dna binding factor': $i).
% 29.32/29.15  tff(decl_76043, type, 'general transcription factor': $i).
% 29.32/29.15  tff(decl_76044, type, 'factor of transcription': $i).
% 29.32/29.15  tff(decl_76045, type, 'transcription factor': $i).
% 29.32/29.15  tff(decl_76046, type, 'transcription-factor': $i).
% 29.32/29.15  tff(decl_76047, type, fn_transcription_factor_2: $i > $i).
% 29.32/29.15  tff(decl_76048, type, fn_transcription_factor_3: $i > $i).
% 29.32/29.15  tff(decl_76049, type, fn_transcription_factor_4: $i > $i).
% 29.32/29.15  tff(decl_76050, type, fn_transcription_factor_5: $i > $i).
% 29.32/29.15  tff(decl_76051, type, fn_transcription_factor_6: $i > $i).
% 29.32/29.15  tff(decl_76052, type, fn_transcription_factor_7: $i > $i).
% 29.32/29.15  tff(decl_76053, type, fn_transcription_factor_9: $i > $i).
% 29.32/29.15  tff(decl_76054, type, 'Transcription-Factor-Gene': $i).
% 29.32/29.15  tff(decl_76055, type, 'A gene that codes for Transcription factor.': $i).
% 29.32/29.15  tff(decl_76056, type, 'transcription factor gene': $i).
% 29.32/29.15  tff(decl_76057, type, 'transcription-factor-gene': $i).
% 29.32/29.15  tff(decl_76058, type, fn_transcription_factor_gene_1: $i > $i).
% 29.32/29.15  tff(decl_76059, type, fn_transcription_factor_gene_2: $i > $i).
% 29.32/29.15  tff(decl_76060, type, transcription_in_chloroplast_1: $i > $o).
% 29.32/29.15  tff(decl_76061, type, fn_transcription_in_chloroplast_1: $i > $i).
% 29.32/29.15  tff(decl_76062, type, 'Transcription-In-Chloroplast': $i).
% 29.32/29.15  tff(decl_76063, type, 'Transcription, the first step of protein synthesis, uses DNA as the template to form mRNA. Because chloroplasts have their own DNA, some proteins are synthesized in the chloroplast.': $i).
% 29.32/29.15  tff(decl_76064, type, 'transcription in chloroplast': $i).
% 29.32/29.15  tff(decl_76065, type, 'transcription-in-chloroplast': $i).
% 29.32/29.15  tff(decl_76066, type, 'Transcription-Initiation': $i).
% 29.32/29.15  tff(decl_76067, type, 'The commencement of transcription which begins when transcription factors bind to the promoter on the DNA, which mediates the binding of RNA polymerase to the DNA, forming a transcription initiation complex.': $i).
% 29.32/29.15  tff(decl_76068, type, 'rna synthesis initiation': $i).
% 29.32/29.15  tff(decl_76069, type, 'rna synthesis-initiation': $i).
% 29.32/29.15  tff(decl_76070, type, 'initiation of transcription': $i).
% 29.32/29.15  tff(decl_76071, type, 'transcription initiation': $i).
% 29.32/29.15  tff(decl_76072, type, 'transcription-initiation': $i).
% 29.32/29.15  tff(decl_76073, type, fn_transcription_initiation_1: $i > $i).
% 29.32/29.15  tff(decl_76074, type, fn_transcription_initiation_2: $i > $i).
% 29.32/29.15  tff(decl_76075, type, fn_transcription_initiation_3: $i > $i).
% 29.32/29.15  tff(decl_76076, type, fn_transcription_initiation_4: $i > $i).
% 29.32/29.15  tff(decl_76077, type, fn_transcription_initiation_6: $i > $i).
% 29.32/29.15  tff(decl_76078, type, fn_transcription_initiation_8: $i > $i).
% 29.32/29.15  tff(decl_76079, type, fn_transcription_initiation_9: $i > $i).
% 29.32/29.15  tff(decl_76080, type, fn_transcription_initiation_10: $i > $i).
% 29.32/29.15  tff(decl_76081, type, fn_transcription_initiation_11: $i > $i).
% 29.32/29.15  tff(decl_76082, type, fn_transcription_initiation_12: $i > $i).
% 29.32/29.15  tff(decl_76083, type, fn_transcription_initiation_13: $i > $i).
% 29.32/29.15  tff(decl_76084, type, fn_transcription_initiation_14: $i > $i).
% 29.32/29.15  tff(decl_76085, type, transcription_initiation_complex_1: $i > $o).
% 29.32/29.15  tff(decl_76086, type, fn_transcription_initiation_15: $i > $i).
% 29.32/29.15  tff(decl_76087, type, fn_transcription_initiation_16: $i > $i).
% 29.32/29.15  tff(decl_76088, type, fn_transcription_initiation_17: $i > $i).
% 29.32/29.15  tff(decl_76089, type, fn_transcription_initiation_18: $i > $i).
% 29.32/29.15  tff(decl_76090, type, fn_transcription_initiation_complex_1: $i > $i).
% 29.32/29.15  tff(decl_76091, type, fn_transcription_initiation_complex_3: $i > $i).
% 29.32/29.15  tff(decl_76092, type, fn_transcription_initiation_complex_2: $i > $i).
% 29.32/29.15  tff(decl_76093, type, transcription_factor_0: $i).
% 29.32/29.15  tff(decl_76094, type, 'Transcription-Initiation-complex': $i).
% 29.32/29.15  tff(decl_76095, type, 'It is a complex formed by joining of transcription factor and RNA polymerase on promoter': $i).
% 29.32/29.15  tff(decl_76096, type, 'transcription initiation complex': $i).
% 29.32/29.15  tff(decl_76097, type, 'transcription-initiation-complex': $i).
% 29.32/29.15  tff(decl_76098, type, 'Transcription-Of-Bicoid-Gene': $i).
% 29.32/29.15  tff(decl_76099, type, 'Transcription of the bicoid gene, or Bicoid RNA synthesis, is the process of creating an equivalent Bicoid RNA copy of a sequence of DNA.': $i).
% 29.32/29.15  tff(decl_76100, type, 'transcription of bicoid gene': $i).
% 29.32/29.15  tff(decl_76101, type, 'transcription-of-bicoid-gene': $i).
% 29.32/29.15  tff(decl_76102, type, fn_transcription_of_bicoid_gene_1: $i > $i).
% 29.32/29.15  tff(decl_76103, type, fn_transcription_of_bicoid_gene_2: $i > $i).
% 29.32/29.15  tff(decl_76104, type, fn_transcription_of_bicoid_gene_3: $i > $i).
% 29.32/29.15  tff(decl_76105, type, 'Transcription-Phase': $i).
% 29.32/29.15  tff(decl_76106, type, 'Phase of Transcription': $i).
% 29.32/29.15  tff(decl_76107, type, 'undergo the transcription phase': $i).
% 29.32/29.15  tff(decl_76108, type, 'phase of transcription': $i).
% 29.32/29.15  tff(decl_76109, type, 'transcription phase': $i).
% 29.32/29.15  tff(decl_76110, type, 'transcription-phase': $i).
% 29.32/29.15  tff(decl_76111, type, 'Transcription-Termination': $i).
% 29.32/29.15  tff(decl_76112, type, 'The process of terminating the transcription of DNA, signaled when the RNA polymerase transcribes a terminator sequence in the DNA.': $i).
% 29.32/29.15  tff(decl_76113, type, 'rna synthesis termination': $i).
% 29.32/29.15  tff(decl_76114, type, 'termination of transcription': $i).
% 29.32/29.15  tff(decl_76115, type, 'transcription termination': $i).
% 29.32/29.15  tff(decl_76116, type, 'transcription-termination': $i).
% 29.32/29.15  tff(decl_76117, type, fn_transcription_termination_4: $i > $i).
% 29.32/29.15  tff(decl_76118, type, fn_transcription_termination_5: $i > $i).
% 29.32/29.15  tff(decl_76119, type, fn_transcription_termination_in_eukaryotes_1: $i > $i).
% 29.32/29.15  tff(decl_76120, type, 'Transcription-Termination-in-Eukaryotes': $i).
% 29.32/29.15  tff(decl_76121, type, 'The completion of transcription in nucleated cells.  The release of the DNA from the RNA transcript occurs after RNA polymerase reaches the termination sequence and adds 10-35 ribonucleotides to the mRNA following the termination sequence.': $i).
% 29.32/29.15  tff(decl_76122, type, 'transcription termination in eukaryote': $i).
% 29.32/29.15  tff(decl_76123, type, 'transcription-termination-in-eukaryote': $i).
% 29.32/29.15  tff(decl_76124, type, fn_transcription_termination_in_prokaryotes_1: $i > $i).
% 29.32/29.15  tff(decl_76125, type, 'Transcription-Termination-in-Prokaryotes': $i).
% 29.32/29.15  tff(decl_76126, type, 'The completion of transcription in prokaryotes occurring when the RNA polymerase reaches the termination signal releasing the DNA and RNA.': $i).
% 29.32/29.15  tff(decl_76127, type, 'transcription termination in prokaryote': $i).
% 29.32/29.15  tff(decl_76128, type, 'transcription-termination-in-prokaryote': $i).
% 29.32/29.15  tff(decl_76129, type, 'Transcription-Unit': $i).
% 29.32/29.15  tff(decl_76130, type, 'A region of DNA that is transcribed into mRNA.': $i).
% 29.32/29.15  tff(decl_76131, type, 'unit of transcription': $i).
% 29.32/29.15  tff(decl_76132, type, 'transcription unit': $i).
% 29.32/29.15  tff(decl_76133, type, 'transcription-unit': $i).
% 29.32/29.15  tff(decl_76134, type, fn_transcription_unit_2: $i > $i).
% 29.32/29.15  tff(decl_76135, type, fn_transcription_unit_3: $i > $i).
% 29.32/29.15  tff(decl_76136, type, fn_transcription_unit_4: $i > $i).
% 29.32/29.15  tff(decl_76137, type, fn_transcription_unit_5: $i > $i).
% 29.32/29.15  tff(decl_76138, type, fn_transcription_unit_6: $i > $i).
% 29.32/29.15  tff(decl_76139, type, fn_transcription_unit_7: $i > $i).
% 29.32/29.15  tff(decl_76140, type, fn_transcription_unit_8: $i > $i).
% 29.32/29.15  tff(decl_76141, type, fn_transcription_unit_9: $i > $i).
% 29.32/29.15  tff(decl_76142, type, fn_transcription_unit_10: $i > $i).
% 29.32/29.15  tff(decl_76143, type, fn_transcription_unit_11: $i > $i).
% 29.32/29.15  tff(decl_76144, type, fn_transcription_unit_12: $i > $i).
% 29.32/29.15  tff(decl_76145, type, fn_transcription_unit_13: $i > $i).
% 29.32/29.15  tff(decl_76146, type, fn_transcription_unit_14: $i > $i).
% 29.32/29.15  tff(decl_76147, type, fn_transcription_unit_15: $i > $i).
% 29.32/29.15  tff(decl_76148, type, fn_transcription_unit_16: $i > $i).
% 29.32/29.15  tff(decl_76149, type, fn_transcription_unit_17: $i > $i).
% 29.32/29.15  tff(decl_76150, type, fn_transcription_unit_18: $i > $i).
% 29.32/29.15  tff(decl_76151, type, intron_0: $i).
% 29.32/29.15  tff(decl_76152, type, transcriptional_activation_1: $i > $o).
% 29.32/29.15  tff(decl_76153, type, 'Transcriptional-Activation': $i).
% 29.32/29.15  tff(decl_76154, type, 'Transcriptional Activation is a method of inducible expression where transcription is reversibly turned on or off.': $i).
% 29.32/29.15  tff(decl_76155, type, 'transcriptional activation': $i).
% 29.32/29.15  tff(decl_76156, type, 'transcriptional-activation': $i).
% 29.32/29.15  tff(decl_76157, type, transcriptional_inhibition_1: $i > $o).
% 29.32/29.15  tff(decl_76158, type, fn_transcriptional_activation_1: $i > $i).
% 29.32/29.15  tff(decl_76159, type, fn_transcriptional_activation_2: $i > $i).
% 29.32/29.15  tff(decl_76160, type, 'Transcriptional-Inhibition': $i).
% 29.32/29.15  tff(decl_76161, type, 'The inhibition of transcription, the first spet in protein synthesis.': $i).
% 29.32/29.15  tff(decl_76162, type, 'transcriptional inhibition': $i).
% 29.32/29.15  tff(decl_76163, type, 'transcriptional-inhibition': $i).
% 29.32/29.15  tff(decl_76164, type, fn_transcriptional_inhibition_1: $i > $i).
% 29.32/29.15  tff(decl_76165, type, fn_transcriptional_inhibition_2: $i > $i).
% 29.32/29.15  tff(decl_76166, type, 'Transcriptional-Regulation': $i).
% 29.32/29.15  tff(decl_76167, type, 'Transcriptional regulation is the change in gene expression levels by altering transcription rates.': $i).
% 29.32/29.15  tff(decl_76168, type, 'transcriptional regulation': $i).
% 29.32/29.15  tff(decl_76169, type, 'transcriptional-regulation': $i).
% 29.32/29.15  tff(decl_76170, type, fn_transcriptional_regulation_1: $i > $i).
% 29.32/29.15  tff(decl_76171, type, transducin_1: $i > $o).
% 29.32/29.15  tff(decl_76172, type, 'Transducin': $i).
% 29.32/29.15  tff(decl_76173, type, 'A G-Protein that activates an enzyme that chemically alters the second messenger in the rod cell.': $i).
% 29.32/29.15  tff(decl_76174, type, transducin: $i).
% 29.32/29.15  tff(decl_76175, type, 'Transduction': $i).
% 29.32/29.15  tff(decl_76176, type, 'The use of a bacteriophage vector to transfer viral, bacterial, or both bacterial and viral DNA from one cell to another.': $i).
% 29.32/29.15  tff(decl_76177, type, transduce: $i).
% 29.32/29.15  tff(decl_76178, type, 'Transduction-Gene-Transfer': $i).
% 29.32/29.15  tff(decl_76179, type, 'A type of horizontal gene transfer in which phages (viruses) carry bacterial DNA from one host cell to another.': $i).
% 29.32/29.15  tff(decl_76180, type, 'transduction gene transfer': $i).
% 29.32/29.15  tff(decl_76181, type, 'transduction-gene-transfer': $i).
% 29.32/29.15  tff(decl_76182, type, fn_transduction_gene_transfer_2: $i > $i).
% 29.32/29.15  tff(decl_76183, type, fn_transduction_gene_transfer_6: $i > $i).
% 29.32/29.15  tff(decl_76184, type, 'Transfer': $i).
% 29.32/29.15  tff(decl_76185, type, transfer_cell_1: $i > $o).
% 29.32/29.15  tff(decl_76186, type, 'Transfer-Cell': $i).
% 29.32/29.15  tff(decl_76187, type, 'In a plant, a companion cell with numerous ingrowths of its wall, which increase the cell\\s surface area and the transfer of solutes between apoplast and symplast.': $i).
% 29.32/29.15  tff(decl_76188, type, 'cell of transfer': $i).
% 29.32/29.15  tff(decl_76189, type, 'transfer cell': $i).
% 29.32/29.15  tff(decl_76190, type, 'transfer-cell': $i).
% 29.32/29.15  tff(decl_76191, type, 'Transfer-Of-Malate-To-Bundle-Sheath-Cell': $i).
% 29.32/29.15  tff(decl_76192, type, 'The transfer of malate synthesized in mesophyll cells to bundle sheath cells through plasmodesmata.': $i).
% 29.32/29.15  tff(decl_76193, type, 'transfer of malate to bundle sheath cell': $i).
% 29.32/29.15  tff(decl_76194, type, 'transfer-of-malate-to-bundle-sheath-cell': $i).
% 29.32/29.15  tff(decl_76195, type, fn_transfer_of_malate_to_bundle_sheath_cell_3: $i > $i).
% 29.32/29.15  tff(decl_76196, type, 'Transferase': $i).
% 29.32/29.15  tff(decl_76197, type, 'Enzymes which catalyze the transfer a functional group (e.g. a methyl or phosphate group).': $i).
% 29.32/29.15  tff(decl_76198, type, transferase: $i).
% 29.32/29.15  tff(decl_76199, type, 'Transformation': $i).
% 29.32/29.15  tff(decl_76200, type, '(1) The conversion of a normal animal cell to a cancerous cell.  (2) A change in genotype and phenotype due to the assimilation of external DNA by a cell.  When the external DNA is from a member of a different species, transformation results in horizontal gene transfer.': $i).
% 29.32/29.15  tff(decl_76201, type, 'Transformation-In-Bacterial-Genetics': $i).
% 29.32/29.15  tff(decl_76202, type, 'A change in genotype and phenotype due to the assimilation of external DNA by a cell.': $i).
% 29.32/29.15  tff(decl_76203, type, 'transformation in bacterial genetics': $i).
% 29.32/29.15  tff(decl_76204, type, 'transformation-in-bacterial-genetic': $i).
% 29.32/29.15  tff(decl_76205, type, fn_transformation_in_bacterial_genetics_1: $i > $i).
% 29.32/29.15  tff(decl_76206, type, fn_transformation_in_bacterial_genetics_2: $i > $i).
% 29.32/29.15  tff(decl_76207, type, fn_transformation_in_bacterial_genetics_3: $i > $i).
% 29.32/29.15  tff(decl_76208, type, fn_transformation_in_bacterial_genetics_4: $i > $i).
% 29.32/29.15  tff(decl_76209, type, fn_transformation_in_bacterial_genetics_5: $i > $i).
% 29.32/29.15  tff(decl_76210, type, fn_transformation_in_bacterial_genetics_6: $i > $i).
% 29.32/29.15  tff(decl_76211, type, fn_transformation_in_bacterial_genetics_7: $i > $i).
% 29.32/29.15  tff(decl_76212, type, fn_transformation_in_bacterial_genetics_8: $i > $i).
% 29.32/29.15  tff(decl_76213, type, fn_transformation_in_bacterial_genetics_9: $i > $i).
% 29.32/29.15  tff(decl_76214, type, fn_transformation_in_bacterial_genetics_10: $i > $i).
% 29.32/29.15  tff(decl_76215, type, fn_transformation_in_bacterial_genetics_11: $i > $i).
% 29.32/29.15  tff(decl_76216, type, fn_transformation_in_bacterial_genetics_12: $i > $i).
% 29.32/29.15  tff(decl_76217, type, fn_transformation_in_bacterial_genetics_13: $i > $i).
% 29.32/29.15  tff(decl_76218, type, fn_transformation_in_bacterial_genetics_14: $i > $i).
% 29.32/29.15  tff(decl_76219, type, fn_transformation_in_bacterial_genetics_15: $i > $i).
% 29.32/29.15  tff(decl_76220, type, fn_transformation_in_bacterial_genetics_16: $i > $i).
% 29.32/29.15  tff(decl_76221, type, transformation_lab_technique_1: $i > $o).
% 29.32/29.15  tff(decl_76222, type, 'Transformation-Lab-Technique': $i).
% 29.32/29.15  tff(decl_76223, type, 'A laboratory procedure used to introduce a foreign plasmid into a bacteria and to use that bacteria to amplify the plasmid in order to make large quantities of it.': $i).
% 29.32/29.15  tff(decl_76224, type, 'transformation lab technique': $i).
% 29.32/29.15  tff(decl_76225, type, 'transformation-lab-technique': $i).
% 29.32/29.15  tff(decl_76226, type, fn_transformation_lab_technique_1: $i > $i).
% 29.32/29.15  tff(decl_76227, type, fn_transformation_lab_technique_2: $i > $i).
% 29.32/29.15  tff(decl_76228, type, fn_transformation_lab_technique_3: $i > $i).
% 29.32/29.15  tff(decl_76229, type, fn_transformed_bacterial_cell_16: $i > $i).
% 29.32/29.15  tff(decl_76230, type, 'Transformation-Of-Cell-To-Cancerous-Cell': $i).
% 29.32/29.15  tff(decl_76231, type, 'The conversion of a normal animal cell to a cancerous cell.': $i).
% 29.32/29.15  tff(decl_76232, type, 'transformation of cell to cancerous cell': $i).
% 29.32/29.15  tff(decl_76233, type, 'transformation-of-cell-to-cancerous-cell': $i).
% 29.32/29.15  tff(decl_76234, type, fn_transformation_of_cell_to_cancerous_cell_1: $i > $i).
% 29.32/29.15  tff(decl_76235, type, fn_transformation_of_cell_to_cancerous_cell_2: $i > $i).
% 29.32/29.15  tff(decl_76236, type, fn_transformation_of_cell_to_cancerous_cell_3: $i > $i).
% 29.32/29.15  tff(decl_76237, type, fn_transformation_of_cell_to_cancerous_cell_4: $i > $i).
% 29.32/29.15  tff(decl_76238, type, fn_transformation_of_cell_to_cancerous_cell_5: $i > $i).
% 29.32/29.15  tff(decl_76239, type, fn_transformation_of_cell_to_cancerous_cell_6: $i > $i).
% 29.32/29.15  tff(decl_76240, type, fn_transformation_of_cell_to_cancerous_cell_7: $i > $i).
% 29.32/29.15  tff(decl_76241, type, fn_transformation_of_cell_to_cancerous_cell_8: $i > $i).
% 29.32/29.15  tff(decl_76242, type, fn_transformation_of_cell_to_cancerous_cell_9: $i > $i).
% 29.32/29.15  tff(decl_76243, type, fn_transformation_of_cell_to_cancerous_cell_10: $i > $i).
% 29.32/29.15  tff(decl_76244, type, fn_transformation_of_cell_to_cancerous_cell_11: $i > $i).
% 29.32/29.15  tff(decl_76245, type, fn_transformation_of_cell_to_cancerous_cell_12: $i > $i).
% 29.32/29.15  tff(decl_76246, type, fn_transformation_of_cell_to_cancerous_cell_13: $i > $i).
% 29.32/29.15  tff(decl_76247, type, fn_transformation_of_cell_to_cancerous_cell_14: $i > $i).
% 29.32/29.15  tff(decl_76248, type, 'Transformed-Bacterial-Cell': $i).
% 29.32/29.15  tff(decl_76249, type, 'Recombinant bacterial cell that is the result of the Transformation lab technique.  This cell has a recombinant plasmid.': $i).
% 29.32/29.15  tff(decl_76250, type, 'transformed cell': $i).
% 29.32/29.15  tff(decl_76251, type, 'recombinant bacteria': $i).
% 29.32/29.15  tff(decl_76252, type, 'transformed bacterial cell': $i).
% 29.32/29.15  tff(decl_76253, type, 'transformed-bacterial-cell': $i).
% 29.32/29.15  tff(decl_76254, type, fn_transformed_bacterial_cell_1: $i > $i).
% 29.32/29.15  tff(decl_76255, type, fn_transformed_bacterial_cell_2: $i > $i).
% 29.32/29.15  tff(decl_76256, type, fn_transformed_bacterial_cell_3: $i > $i).
% 29.32/29.15  tff(decl_76257, type, fn_transformed_bacterial_cell_4: $i > $i).
% 29.32/29.15  tff(decl_76258, type, fn_transformed_bacterial_cell_5: $i > $i).
% 29.32/29.15  tff(decl_76259, type, fn_transformed_bacterial_cell_6: $i > $i).
% 29.32/29.15  tff(decl_76260, type, fn_transformed_bacterial_cell_7: $i > $i).
% 29.32/29.15  tff(decl_76261, type, fn_transformed_bacterial_cell_10: $i > $i).
% 29.32/29.15  tff(decl_76262, type, fn_transformed_bacterial_cell_11: $i > $i).
% 29.32/29.15  tff(decl_76263, type, fn_transformed_bacterial_cell_12: $i > $i).
% 29.32/29.15  tff(decl_76264, type, fn_transformed_bacterial_cell_13: $i > $i).
% 29.32/29.15  tff(decl_76265, type, fn_transformed_bacterial_cell_14: $i > $i).
% 29.32/29.15  tff(decl_76266, type, fn_transformed_bacterial_cell_15: $i > $i).
% 29.32/29.15  tff(decl_76267, type, fn_transformed_bacterial_cell_17: $i > $i).
% 29.32/29.15  tff(decl_76268, type, fn_transformed_bacterial_cell_18: $i > $i).
% 29.32/29.15  tff(decl_76269, type, fn_transformed_bacterial_cell_19: $i > $i).
% 29.32/29.15  tff(decl_76270, type, fn_transformed_bacterial_cell_20: $i > $i).
% 29.32/29.15  tff(decl_76271, type, fn_transformed_bacterial_cell_21: $i > $i).
% 29.32/29.15  tff(decl_76272, type, fn_transformed_bacterial_cell_22: $i > $i).
% 29.32/29.15  tff(decl_76273, type, fn_transformed_bacterial_cell_23: $i > $i).
% 29.32/29.15  tff(decl_76274, type, fn_transformed_bacterial_cell_26: $i > $i).
% 29.32/29.15  tff(decl_76275, type, fn_transformed_bacterial_cell_27: $i > $i).
% 29.32/29.15  tff(decl_76276, type, fn_transformed_bacterial_cell_24: $i > $i).
% 29.32/29.15  tff(decl_76277, type, fn_transformed_bacterial_cell_25: $i > $i).
% 29.32/29.15  tff(decl_76278, type, 'Transgenic-Organism': $i).
% 29.32/29.15  tff(decl_76279, type, 'A biotechnology method using a transgenic mammalian organism for the production of blood clotting factors.': $i).
% 29.32/29.15  tff(decl_76280, type, 'transgenic organism': $i).
% 29.32/29.15  tff(decl_76281, type, 'transgenic-organism': $i).
% 29.32/29.15  tff(decl_76282, type, transgenic_organism_for_clotting_factor_manufacture_1: $i > $o).
% 29.32/29.15  tff(decl_76283, type, fn_transgenic_organism_for_clotting_factor_manufacture_2: $i > $i).
% 29.32/29.15  tff(decl_76284, type, 'Transgenic-Organism-For-Clotting-Factor-Manufacture': $i).
% 29.32/29.15  tff(decl_76285, type, 'transgenic organism for clotting factor manufacture': $i).
% 29.32/29.15  tff(decl_76286, type, 'transgenic-organism-for-clotting-factor-manufacture': $i).
% 29.32/29.15  tff(decl_76287, type, transgenic_organism_for_drug_manufacture_1: $i > $o).
% 29.32/29.15  tff(decl_76288, type, transgenic_organism_for_hormone_manufacture_1: $i > $o).
% 29.32/29.15  tff(decl_76289, type, fn_transgenic_organism_for_clotting_factor_manufacture_3: $i > $i).
% 29.32/29.15  tff(decl_76290, type, 'Transgenic-Organism-For-Drug-Manufacture': $i).
% 29.32/29.15  tff(decl_76291, type, 'A biotechnology method using a transgenic  organism for the production of pharmaceutical products.': $i).
% 29.32/29.15  tff(decl_76292, type, 'transgenic organism for drug manufacture': $i).
% 29.32/29.15  tff(decl_76293, type, 'transgenic-organism-for-drug-manufacture': $i).
% 29.32/29.15  tff(decl_76294, type, 'Transgenic-Organism-For-Hormone-Manufacture': $i).
% 29.32/29.15  tff(decl_76295, type, 'A biotechnology method using a transgenic organism for the production of hormonel products.': $i).
% 29.32/29.15  tff(decl_76296, type, 'transgenic organism for hormone manufacture': $i).
% 29.32/29.15  tff(decl_76297, type, 'transgenic-organism-for-hormone-manufacture': $i).
% 29.32/29.15  tff(decl_76298, type, 'Transitional-Endoplasmic-Reticulum': $i).
% 29.32/29.15  tff(decl_76299, type, 'It is a specialized region of Endoplasmic Reticulum from where vesicles bud off.': $i).
% 29.32/29.15  tff(decl_76300, type, 'transitional endoplasmic reticulum': $i).
% 29.32/29.15  tff(decl_76301, type, 'transitional-endoplasmic-reticulum': $i).
% 29.32/29.15  tff(decl_76302, type, fn_transitional_endoplasmic_reticulum_1: $i > $i).
% 29.32/29.15  tff(decl_76303, type, fn_transitional_endoplasmic_reticulum_3: $i > $i).
% 29.32/29.15  tff(decl_76304, type, 'Translation': $i).
% 29.32/29.15  tff(decl_76305, type, 'The construction of a polypeptide chain, adding amino acids in the order prescribed by the information in an mRNA transcript. During the process of translation, the language of nucleotides is': $i).
% 29.32/29.15  tff(decl_76306, type, 'synthesis of polypeptide': $i).
% 29.32/29.15  tff(decl_76307, type, translation: $i).
% 29.32/29.15  tff(decl_76308, type, translate: $i).
% 29.32/29.15  tff(decl_76309, type, fn_translation_2: $i > $i).
% 29.32/29.15  tff(decl_76310, type, fn_translation_3: $i > $i).
% 29.32/29.15  tff(decl_76311, type, fn_translation_4: $i > $i).
% 29.32/29.15  tff(decl_76312, type, fn_translation_5: $i > $i).
% 29.32/29.15  tff(decl_76313, type, fn_translation_6: $i > $i).
% 29.32/29.15  tff(decl_76314, type, fn_translation_9: $i > $i).
% 29.32/29.15  tff(decl_76315, type, fn_translation_22: $i > $i).
% 29.32/29.15  tff(decl_76316, type, fn_translation_24: $i > $i).
% 29.32/29.15  tff(decl_76317, type, fn_translation_25: $i > $i).
% 29.32/29.15  tff(decl_76318, type, fn_translation_30: $i > $i).
% 29.32/29.15  tff(decl_76319, type, fn_translation_31: $i > $i).
% 29.32/29.15  tff(decl_76320, type, fn_translation_32: $i > $i).
% 29.32/29.15  tff(decl_76321, type, fn_translation_33: $i > $i).
% 29.32/29.15  tff(decl_76322, type, fn_translation_34: $i > $i).
% 29.32/29.15  tff(decl_76323, type, fn_translation_35: $i > $i).
% 29.32/29.15  tff(decl_76324, type, fn_translation_termination_37: $i > $i).
% 29.32/29.15  tff(decl_76325, type, fn_water_molecule_69: $i > $i).
% 29.32/29.15  tff(decl_76326, type, fn_water_molecule_68: $i > $i).
% 29.32/29.15  tff(decl_76327, type, fn_water_molecule_52: $i > $i).
% 29.32/29.15  tff(decl_76328, type, 'Translation-Elongation': $i).
% 29.32/29.15  tff(decl_76329, type, 'Translation-Elongation is the phase of actual synthesis of polypeptide. It is preceded by the Translation-Initiation phase and is followed by the Translation-Termination': $i).
% 29.32/29.15  tff(decl_76330, type, 'translation elongation': $i).
% 29.32/29.15  tff(decl_76331, type, 'translation-elongation': $i).
% 29.32/29.15  tff(decl_76332, type, 'elongation of translation': $i).
% 29.32/29.15  tff(decl_76333, type, translation_phase_1: $i > $o).
% 29.32/29.15  tff(decl_76334, type, fn_translation_elongation_3: $i > $i).
% 29.32/29.15  tff(decl_76335, type, fn_translation_elongation_4: $i > $i).
% 29.32/29.15  tff(decl_76336, type, fn_translation_elongation_5: $i > $i).
% 29.32/29.15  tff(decl_76337, type, fn_translation_elongation_6: $i > $i).
% 29.32/29.15  tff(decl_76338, type, fn_translation_elongation_7: $i > $i).
% 29.32/29.15  tff(decl_76339, type, fn_translation_elongation_8: $i > $i).
% 29.32/29.15  tff(decl_76340, type, fn_translation_elongation_12: $i > $i).
% 29.32/29.15  tff(decl_76341, type, fn_translation_elongation_13: $i > $i).
% 29.32/29.15  tff(decl_76342, type, fn_translation_elongation_14: $i > $i).
% 29.32/29.15  tff(decl_76343, type, fn_translation_elongation_16: $i > $i).
% 29.32/29.15  tff(decl_76344, type, fn_translation_elongation_17: $i > $i).
% 29.32/29.15  tff(decl_76345, type, fn_translation_elongation_18: $i > $i).
% 29.32/29.15  tff(decl_76346, type, fn_translation_elongation_19: $i > $i).
% 29.32/29.15  tff(decl_76347, type, fn_translation_elongation_20: $i > $i).
% 29.32/29.15  tff(decl_76348, type, fn_translation_elongation_22: $i > $i).
% 29.32/29.15  tff(decl_76349, type, fn_translation_elongation_23: $i > $i).
% 29.32/29.15  tff(decl_76350, type, fn_translation_elongation_24: $i > $i).
% 29.32/29.15  tff(decl_76351, type, fn_translation_initiation_12: $i > $i).
% 29.32/29.15  tff(decl_76352, type, fn_translation_initiation_15: $i > $i).
% 29.32/29.15  tff(decl_76353, type, peptide_bond_formation_0: $i).
% 29.32/29.15  tff(decl_76354, type, translation_in_chloroplast_1: $i > $o).
% 29.32/29.15  tff(decl_76355, type, fn_translation_in_chloroplast_1: $i > $i).
% 29.32/29.15  tff(decl_76356, type, 'Translation-In-Chloroplast': $i).
% 29.32/29.15  tff(decl_76357, type, 'Translation, the second step of protein synthesis, uses mRNA as the template to form polypeptides. Because chloroplasts have their own DNA, some proteins are synthesized in the chloroplast.': $i).
% 29.32/29.15  tff(decl_76358, type, 'translation in chloroplast': $i).
% 29.32/29.15  tff(decl_76359, type, 'translation-in-chloroplast': $i).
% 29.32/29.15  tff(decl_76360, type, translation_in_mitochondria_1: $i > $o).
% 29.32/29.15  tff(decl_76361, type, translation_in_prokaryotes_1: $i > $o).
% 29.32/29.15  tff(decl_76362, type, translation_of_bicoid_mrna_1: $i > $o).
% 29.32/29.15  tff(decl_76363, type, fn_translation_in_mitochondria_2: $i > $i).
% 29.32/29.15  tff(decl_76364, type, 'Translation-In-Mitochondria': $i).
% 29.32/29.15  tff(decl_76365, type, 'The second step of protein synthesis where mRNA transcribed from mitochondrial DNA is used as the template to form polypeptides in the mitochondria.': $i).
% 29.32/29.15  tff(decl_76366, type, 'translation in mitochondrion': $i).
% 29.32/29.15  tff(decl_76367, type, 'translation-in-mitochondria': $i).
% 29.32/29.15  tff(decl_76368, type, 'Translation-In-Prokaryotes': $i).
% 29.32/29.15  tff(decl_76369, type, 'Prokaryotic translation is the process by which messenger RNA is translated into proteins in prokaryotes.': $i).
% 29.32/29.15  tff(decl_76370, type, 'protein synthesis in prokaryotes': $i).
% 29.32/29.15  tff(decl_76371, type, 'translation in prokaryote': $i).
% 29.32/29.15  tff(decl_76372, type, 'translation-in-prokaryote': $i).
% 29.32/29.15  tff(decl_76373, type, fn_translation_in_prokaryotes_1: $i > $i).
% 29.32/29.15  tff(decl_76374, type, fn_translation_in_prokaryotes_2: $i > $i).
% 29.32/29.15  tff(decl_76375, type, fn_translation_in_prokaryotes_3: $i > $i).
% 29.32/29.15  tff(decl_76376, type, fn_translation_in_prokaryotes_4: $i > $i).
% 29.32/29.15  tff(decl_76377, type, fn_translation_in_prokaryotes_7: $i > $i).
% 29.32/29.15  tff(decl_76378, type, fn_translation_in_prokaryotes_8: $i > $i).
% 29.32/29.15  tff(decl_76379, type, fn_translation_in_prokaryotes_9: $i > $i).
% 29.32/29.15  tff(decl_76380, type, fn_translation_in_prokaryotes_10: $i > $i).
% 29.32/29.15  tff(decl_76381, type, fn_translation_in_prokaryotes_11: $i > $i).
% 29.32/29.15  tff(decl_76382, type, fn_translation_in_prokaryotes_12: $i > $i).
% 29.32/29.15  tff(decl_76383, type, fn_translation_in_prokaryotes_13: $i > $i).
% 29.32/29.15  tff(decl_76384, type, fn_translation_in_prokaryotes_14: $i > $i).
% 29.32/29.15  tff(decl_76385, type, fn_translation_in_prokaryotes_15: $i > $i).
% 29.32/29.15  tff(decl_76386, type, fn_translation_in_prokaryotes_16: $i > $i).
% 29.32/29.15  tff(decl_76387, type, fn_translation_in_prokaryotes_17: $i > $i).
% 29.32/29.15  tff(decl_76388, type, fn_translation_in_prokaryotes_18: $i > $i).
% 29.32/29.15  tff(decl_76389, type, fn_translation_in_prokaryotes_19: $i > $i).
% 29.32/29.15  tff(decl_76390, type, fn_translation_in_prokaryotes_20: $i > $i).
% 29.32/29.15  tff(decl_76391, type, fn_translation_in_prokaryotes_21: $i > $i).
% 29.32/29.15  tff(decl_76392, type, fn_translation_in_prokaryotes_22: $i > $i).
% 29.32/29.15  tff(decl_76393, type, fn_translation_in_prokaryotes_23: $i > $i).
% 29.32/29.15  tff(decl_76394, type, fn_translation_in_prokaryotes_24: $i > $i).
% 29.32/29.15  tff(decl_76395, type, fn_translation_in_prokaryotes_25: $i > $i).
% 29.32/29.15  tff(decl_76396, type, fn_translation_in_prokaryotes_26: $i > $i).
% 29.32/29.15  tff(decl_76397, type, fn_translation_in_prokaryotes_27: $i > $i).
% 29.32/29.15  tff(decl_76398, type, fn_translation_in_prokaryotes_28: $i > $i).
% 29.32/29.15  tff(decl_76399, type, fn_translation_in_prokaryotes_29: $i > $i).
% 29.32/29.15  tff(decl_76400, type, fn_translation_in_prokaryotes_30: $i > $i).
% 29.32/29.15  tff(decl_76401, type, fn_translation_in_prokaryotes_31: $i > $i).
% 29.32/29.15  tff(decl_76402, type, fn_translation_in_prokaryotes_32: $i > $i).
% 29.32/29.15  tff(decl_76403, type, fn_translation_in_prokaryotes_33: $i > $i).
% 29.32/29.15  tff(decl_76404, type, fn_translation_in_prokaryotes_34: $i > $i).
% 29.32/29.15  tff(decl_76405, type, fn_translation_in_prokaryotes_5: $i > $i).
% 29.32/29.15  tff(decl_76406, type, fn_translation_in_prokaryotes_6: $i > $i).
% 29.32/29.15  tff(decl_76407, type, 'Translation-Initiation': $i).
% 29.32/29.15  tff(decl_76408, type, 'Translation-initiation is the phase of start of protein synthesis i.e. Translation. Here the ribosome machinery is build up on the template mRNA to start the translation process': $i).
% 29.32/29.15  tff(decl_76409, type, 'translation initiation': $i).
% 29.32/29.15  tff(decl_76410, type, 'translation-initiation': $i).
% 29.32/29.15  tff(decl_76411, type, 'initiate translation': $i).
% 29.32/29.15  tff(decl_76412, type, 'initiation of translation': $i).
% 29.32/29.15  tff(decl_76413, type, fn_translation_initiation_1: $i > $i).
% 29.32/29.15  tff(decl_76414, type, fn_translation_initiation_2: $i > $i).
% 29.32/29.15  tff(decl_76415, type, fn_translation_initiation_3: $i > $i).
% 29.32/29.15  tff(decl_76416, type, fn_translation_initiation_5: $i > $i).
% 29.32/29.15  tff(decl_76417, type, fn_translation_initiation_6: $i > $i).
% 29.32/29.15  tff(decl_76418, type, fn_translation_initiation_7: $i > $i).
% 29.32/29.15  tff(decl_76419, type, fn_translation_initiation_9: $i > $i).
% 29.32/29.15  tff(decl_76420, type, fn_translation_initiation_14: $i > $i).
% 29.32/29.15  tff(decl_76421, type, fn_translation_initiation_16: $i > $i).
% 29.32/29.16  tff(decl_76422, type, fn_translation_initiation_17: $i > $i).
% 29.32/29.16  tff(decl_76423, type, fn_translation_initiation_18: $i > $i).
% 29.32/29.16  tff(decl_76424, type, fn_translation_initiation_19: $i > $i).
% 29.32/29.16  tff(decl_76425, type, fn_translation_initiation_20: $i > $i).
% 29.32/29.16  tff(decl_76426, type, fn_translation_initiation_21: $i > $i).
% 29.32/29.16  tff(decl_76427, type, fn_translation_initiation_complex_2: $i > $i).
% 29.32/29.16  tff(decl_76428, type, fn_translation_phase_2: $i > $i).
% 29.32/29.16  tff(decl_76429, type, 'Translation-Initiation-Complex': $i).
% 29.32/29.16  tff(decl_76430, type, 'A translation initiation complex is an assembly of mRMA, initiator tRNA, a small ribosomal subunit and a large ribosomal subunit.': $i).
% 29.32/29.16  tff(decl_76431, type, 'translation assembly': $i).
% 29.32/29.16  tff(decl_76432, type, 'translation initiation complex': $i).
% 29.32/29.16  tff(decl_76433, type, 'translation-initiation-complex': $i).
% 29.32/29.16  tff(decl_76434, type, fn_translation_initiation_complex_1: $i > $i).
% 29.32/29.16  tff(decl_76435, type, fn_translation_initiation_complex_3: $i > $i).
% 29.32/29.16  tff(decl_76436, type, fn_translation_initiation_complex_4: $i > $i).
% 29.32/29.16  tff(decl_76437, type, 'Translation-Of-Bicoid-mRNA': $i).
% 29.32/29.16  tff(decl_76438, type, 'Translation of bicoid mRNA uses bicoid mRNA as the template which direct the bicoid protein synthesis.': $i).
% 29.32/29.16  tff(decl_76439, type, 'translation of bicoid mrna': $i).
% 29.32/29.16  tff(decl_76440, type, 'translation-of-bicoid-mrna': $i).
% 29.32/29.16  tff(decl_76441, type, fn_translation_of_bicoid_mrna_1: $i > $i).
% 29.32/29.16  tff(decl_76442, type, fn_translation_of_bicoid_mrna_2: $i > $i).
% 29.32/29.16  tff(decl_76443, type, fn_translation_of_bicoid_mrna_3: $i > $i).
% 29.32/29.16  tff(decl_76444, type, fn_translation_of_bicoid_mrna_4: $i > $i).
% 29.32/29.16  tff(decl_76445, type, fn_translation_of_bicoid_mrna_5: $i > $i).
% 29.32/29.16  tff(decl_76446, type, fn_translation_of_bicoid_mrna_6: $i > $i).
% 29.32/29.16  tff(decl_76447, type, fn_translation_of_bicoid_mrna_7: $i > $i).
% 29.32/29.16  tff(decl_76448, type, fn_translation_of_bicoid_mrna_8: $i > $i).
% 29.32/29.16  tff(decl_76449, type, fn_translation_of_bicoid_mrna_9: $i > $i).
% 29.32/29.16  tff(decl_76450, type, fn_translation_of_bicoid_mrna_10: $i > $i).
% 29.32/29.16  tff(decl_76451, type, fn_translation_of_bicoid_mrna_11: $i > $i).
% 29.32/29.16  tff(decl_76452, type, fn_translation_of_bicoid_mrna_12: $i > $i).
% 29.32/29.16  tff(decl_76453, type, fn_translation_of_bicoid_mrna_13: $i > $i).
% 29.32/29.16  tff(decl_76454, type, fn_translation_of_bicoid_mrna_14: $i > $i).
% 29.32/29.16  tff(decl_76455, type, fn_translation_of_bicoid_mrna_15: $i > $i).
% 29.32/29.16  tff(decl_76456, type, fn_translation_of_bicoid_mrna_16: $i > $i).
% 29.32/29.16  tff(decl_76457, type, fn_translation_of_bicoid_mrna_17: $i > $i).
% 29.32/29.16  tff(decl_76458, type, fn_translation_of_bicoid_mrna_18: $i > $i).
% 29.32/29.16  tff(decl_76459, type, fn_translation_of_bicoid_mrna_19: $i > $i).
% 29.32/29.16  tff(decl_76460, type, fn_translation_of_bicoid_mrna_20: $i > $i).
% 29.32/29.16  tff(decl_76461, type, fn_translation_of_bicoid_mrna_21: $i > $i).
% 29.32/29.16  tff(decl_76462, type, fn_translation_of_bicoid_mrna_22: $i > $i).
% 29.32/29.16  tff(decl_76463, type, fn_translation_of_bicoid_mrna_23: $i > $i).
% 29.32/29.16  tff(decl_76464, type, fn_translation_of_bicoid_mrna_24: $i > $i).
% 29.32/29.16  tff(decl_76465, type, fn_translation_of_bicoid_mrna_25: $i > $i).
% 29.32/29.16  tff(decl_76466, type, fn_translation_of_bicoid_mrna_26: $i > $i).
% 29.32/29.16  tff(decl_76467, type, fn_translation_of_bicoid_mrna_27: $i > $i).
% 29.32/29.16  tff(decl_76468, type, fn_translation_of_bicoid_mrna_28: $i > $i).
% 29.32/29.16  tff(decl_76469, type, fn_translation_of_bicoid_mrna_32: $i > $i).
% 29.32/29.16  tff(decl_76470, type, fn_translation_of_bicoid_mrna_29: $i > $i).
% 29.32/29.16  tff(decl_76471, type, fn_translation_of_bicoid_mrna_33: $i > $i).
% 29.32/29.16  tff(decl_76472, type, fn_translation_of_bicoid_mrna_30: $i > $i).
% 29.32/29.16  tff(decl_76473, type, fn_translation_of_bicoid_mrna_31: $i > $i).
% 29.32/29.16  tff(decl_76474, type, 'Translation-Phase': $i).
% 29.32/29.16  tff(decl_76475, type, 'Steps in the process of translation RNA to polypeptide.': $i).
% 29.32/29.16  tff(decl_76476, type, 'undergo the translation phase': $i).
% 29.32/29.16  tff(decl_76477, type, 'phase of translation': $i).
% 29.32/29.16  tff(decl_76478, type, 'translation phase': $i).
% 29.32/29.16  tff(decl_76479, type, 'translation-phase': $i).
% 29.32/29.16  tff(decl_76480, type, fn_translation_phase_1: $i > $i).
% 29.32/29.16  tff(decl_76481, type, 'Translation-Termination': $i).
% 29.32/29.16  tff(decl_76482, type, 'Translation-Termination is the terminal phase of the Translation. It brings about the termination of synthesis of polypeptide. This phase is preceded by the Translation-elongation': $i).
% 29.32/29.16  tff(decl_76483, type, 'translation termination': $i).
% 29.32/29.16  tff(decl_76484, type, 'translation-termination': $i).
% 29.32/29.16  tff(decl_76485, type, 'end of translation': $i).
% 29.32/29.16  tff(decl_76486, type, 'termination of translation': $i).
% 29.32/29.16  tff(decl_76487, type, fn_translation_termination_1: $i > $i).
% 29.32/29.16  tff(decl_76488, type, fn_translation_termination_3: $i > $i).
% 29.32/29.16  tff(decl_76489, type, fn_translation_termination_4: $i > $i).
% 29.32/29.16  tff(decl_76490, type, fn_translation_termination_5: $i > $i).
% 29.32/29.16  tff(decl_76491, type, fn_translation_termination_7: $i > $i).
% 29.32/29.16  tff(decl_76492, type, fn_translation_termination_8: $i > $i).
% 29.32/29.16  tff(decl_76493, type, fn_translation_termination_9: $i > $i).
% 29.32/29.16  tff(decl_76494, type, fn_translation_termination_10: $i > $i).
% 29.32/29.16  tff(decl_76495, type, fn_translation_termination_11: $i > $i).
% 29.32/29.16  tff(decl_76496, type, fn_translation_termination_12: $i > $i).
% 29.32/29.16  tff(decl_76497, type, fn_translation_termination_13: $i > $i).
% 29.32/29.16  tff(decl_76498, type, fn_translation_termination_14: $i > $i).
% 29.32/29.16  tff(decl_76499, type, fn_translation_termination_15: $i > $i).
% 29.32/29.16  tff(decl_76500, type, fn_translation_termination_16: $i > $i).
% 29.32/29.16  tff(decl_76501, type, fn_translation_termination_17: $i > $i).
% 29.32/29.16  tff(decl_76502, type, fn_translation_termination_18: $i > $i).
% 29.32/29.16  tff(decl_76503, type, fn_translation_termination_19: $i > $i).
% 29.32/29.16  tff(decl_76504, type, fn_translation_termination_20: $i > $i).
% 29.32/29.16  tff(decl_76505, type, fn_translation_termination_21: $i > $i).
% 29.32/29.16  tff(decl_76506, type, fn_translation_termination_22: $i > $i).
% 29.32/29.16  tff(decl_76507, type, fn_translation_termination_23: $i > $i).
% 29.32/29.16  tff(decl_76508, type, fn_translation_termination_24: $i > $i).
% 29.32/29.16  tff(decl_76509, type, fn_translation_termination_25: $i > $i).
% 29.32/29.16  tff(decl_76510, type, fn_translation_termination_26: $i > $i).
% 29.32/29.16  tff(decl_76511, type, fn_translation_termination_27: $i > $i).
% 29.32/29.16  tff(decl_76512, type, fn_translation_termination_28: $i > $i).
% 29.32/29.16  tff(decl_76513, type, fn_translation_termination_29: $i > $i).
% 29.32/29.16  tff(decl_76514, type, fn_translation_termination_30: $i > $i).
% 29.32/29.16  tff(decl_76515, type, fn_translation_termination_31: $i > $i).
% 29.32/29.16  tff(decl_76516, type, fn_translation_termination_32: $i > $i).
% 29.32/29.16  tff(decl_76517, type, fn_translation_termination_33: $i > $i).
% 29.32/29.16  tff(decl_76518, type, fn_translation_termination_34: $i > $i).
% 29.32/29.16  tff(decl_76519, type, fn_translation_termination_35: $i > $i).
% 29.32/29.16  tff(decl_76520, type, water_0: $i).
% 29.32/29.16  tff(decl_76521, type, 'Translocation': $i).
% 29.32/29.16  tff(decl_76522, type, '(1) A rearrangement of parts between nonhomologous chromosomes. (2) In protein synthesis, the third stage in the construction of a growing polypeptide chain, when the RNA carrying the polypeptide chain moves from the A spot to the P spot on the ribosome. (3) The movement of organic materials in the phloem of vascular plants.': $i).
% 29.32/29.16  tff(decl_76523, type, 'Translocation-During-Translation': $i).
% 29.32/29.16  tff(decl_76524, type, 'During protein synthesis, the third stage in the elongation cycle, when the RNA carrying the growing polypeptide moves from the A site to the P site on the ribosome.': $i).
% 29.32/29.16  tff(decl_76525, type, 'translocation during translation': $i).
% 29.32/29.16  tff(decl_76526, type, 'translocation-during-translation': $i).
% 29.32/29.16  tff(decl_76527, type, fn_translocation_during_translation_1: $i > $i).
% 29.32/29.16  tff(decl_76528, type, fn_translocation_during_translation_2: $i > $i).
% 29.32/29.16  tff(decl_76529, type, fn_translocation_during_translation_3: $i > $i).
% 29.32/29.16  tff(decl_76530, type, fn_translocation_during_translation_4: $i > $i).
% 29.32/29.16  tff(decl_76531, type, fn_translocation_during_translation_5: $i > $i).
% 29.32/29.16  tff(decl_76532, type, fn_translocation_during_translation_6: $i > $i).
% 29.32/29.16  tff(decl_76533, type, fn_translocation_during_translation_7: $i > $i).
% 29.32/29.16  tff(decl_76534, type, fn_translocation_during_translation_8: $i > $i).
% 29.32/29.16  tff(decl_76535, type, fn_translocation_during_translation_9: $i > $i).
% 29.32/29.16  tff(decl_76536, type, fn_translocation_during_translation_10: $i > $i).
% 29.32/29.16  tff(decl_76537, type, fn_translocation_during_translation_11: $i > $i).
% 29.32/29.16  tff(decl_76538, type, fn_translocation_during_translation_12: $i > $i).
% 29.32/29.16  tff(decl_76539, type, fn_translocation_during_translation_13: $i > $i).
% 29.32/29.16  tff(decl_76540, type, fn_translocation_during_translation_14: $i > $i).
% 29.32/29.16  tff(decl_76541, type, fn_translocation_during_translation_15: $i > $i).
% 29.32/29.16  tff(decl_76542, type, fn_translocation_during_translation_16: $i > $i).
% 29.32/29.16  tff(decl_76543, type, fn_translocation_during_translation_17: $i > $i).
% 29.32/29.16  tff(decl_76544, type, fn_translocation_during_translation_18: $i > $i).
% 29.32/29.16  tff(decl_76545, type, fn_translocation_during_translation_19: $i > $i).
% 29.32/29.16  tff(decl_76546, type, fn_translocation_during_translation_20: $i > $i).
% 29.32/29.16  tff(decl_76547, type, fn_translocation_during_translation_21: $i > $i).
% 29.32/29.16  tff(decl_76548, type, fn_trna_4: $i > $i).
% 29.32/29.16  tff(decl_76549, type, 'Translocation-Of-Phloem-Sap': $i).
% 29.32/29.16  tff(decl_76550, type, 'The transport of organic nutrients in the phloem of vascular plants.': $i).
% 29.32/29.16  tff(decl_76551, type, 'translocation of phloem sap': $i).
% 29.32/29.16  tff(decl_76552, type, 'translocation-of-phloem-sap': $i).
% 29.32/29.16  tff(decl_76553, type, fn_translocation_of_phloem_sap_3: $i > $i).
% 29.32/29.16  tff(decl_76554, type, fn_translocation_of_phloem_sap_4: $i > $i).
% 29.32/29.16  tff(decl_76555, type, fn_translocation_of_phloem_sap_5: $i > $i).
% 29.32/29.16  tff(decl_76556, type, fn_translocation_of_phloem_sap_6: $i > $i).
% 29.32/29.16  tff(decl_76557, type, fn_translocation_of_phloem_sap_7: $i > $i).
% 29.32/29.16  tff(decl_76558, type, fn_translocation_of_phloem_sap_8: $i > $i).
% 29.32/29.16  tff(decl_76559, type, fn_translocation_of_phloem_sap_13: $i > $i).
% 29.32/29.16  tff(decl_76560, type, fn_translocation_of_phloem_sap_14: $i > $i).
% 29.32/29.16  tff(decl_76561, type, fn_translocation_of_phloem_sap_15: $i > $i).
% 29.32/29.16  tff(decl_76562, type, fn_translocation_of_phloem_sap_17: $i > $i).
% 29.32/29.16  tff(decl_76563, type, fn_translocation_of_phloem_sap_18: $i > $i).
% 29.32/29.16  tff(decl_76564, type, fn_translocation_of_phloem_sap_19: $i > $i).
% 29.32/29.16  tff(decl_76565, type, fn_translocation_of_phloem_sap_20: $i > $i).
% 29.32/29.16  tff(decl_76566, type, fn_translocation_of_phloem_sap_22: $i > $i).
% 29.32/29.16  tff(decl_76567, type, fn_translocation_of_phloem_sap_25: $i > $i).
% 29.32/29.16  tff(decl_76568, type, fn_translocation_of_phloem_sap_26: $i > $i).
% 29.32/29.16  tff(decl_76569, type, fn_translocation_of_phloem_sap_27: $i > $i).
% 29.32/29.16  tff(decl_76570, type, fn_translocation_of_phloem_sap_28: $i > $i).
% 29.32/29.16  tff(decl_76571, type, fn_translocation_of_phloem_sap_29: $i > $i).
% 29.32/29.16  tff(decl_76572, type, fn_translocation_of_phloem_sap_30: $i > $i).
% 29.32/29.16  tff(decl_76573, type, fn_translocation_of_phloem_sap_31: $i > $i).
% 29.32/29.16  tff(decl_76574, type, fn_translocation_of_phloem_sap_32: $i > $i).
% 29.32/29.16  tff(decl_76575, type, fn_translocation_of_phloem_sap_33: $i > $i).
% 29.32/29.16  tff(decl_76576, type, fn_translocation_of_phloem_sap_34: $i > $i).
% 29.32/29.16  tff(decl_76577, type, fn_translocation_of_phloem_sap_35: $i > $i).
% 29.32/29.16  tff(decl_76578, type, fn_translocation_of_phloem_sap_36: $i > $i).
% 29.32/29.16  tff(decl_76579, type, fn_translocation_of_phloem_sap_37: $i > $i).
% 29.32/29.16  tff(decl_76580, type, fn_translocation_of_phloem_sap_38: $i > $i).
% 29.32/29.16  tff(decl_76581, type, fn_translocation_of_phloem_sap_39: $i > $i).
% 29.32/29.16  tff(decl_76582, type, fn_translocation_of_phloem_sap_40: $i > $i).
% 29.32/29.16  tff(decl_76583, type, unloading_of_sugar_at_sugar_sink_1: $i > $o).
% 29.32/29.16  tff(decl_76584, type, fn_translocation_of_phloem_sap_41: $i > $i).
% 29.32/29.16  tff(decl_76585, type, fn_translocation_of_phloem_sap_42: $i > $i).
% 29.32/29.16  tff(decl_76586, type, fn_translocation_of_phloem_sap_43: $i > $i).
% 29.32/29.16  tff(decl_76587, type, fn_translocation_of_phloem_sap_44: $i > $i).
% 29.32/29.16  tff(decl_76588, type, fn_translocation_of_phloem_sap_45: $i > $i).
% 29.32/29.16  tff(decl_76589, type, fn_translocation_of_phloem_sap_46: $i > $i).
% 29.32/29.16  tff(decl_76590, type, fn_translocation_of_phloem_sap_47: $i > $i).
% 29.32/29.16  tff(decl_76591, type, fn_translocation_of_phloem_sap_48: $i > $i).
% 29.32/29.16  tff(decl_76592, type, fn_translocation_of_phloem_sap_49: $i > $i).
% 29.32/29.16  tff(decl_76593, type, fn_translocation_of_phloem_sap_50: $i > $i).
% 29.32/29.16  tff(decl_76594, type, fn_translocation_of_phloem_sap_52: $i > $i).
% 29.32/29.16  tff(decl_76595, type, fn_unloading_of_sugar_at_sugar_sink_1: $i > $i).
% 29.32/29.16  tff(decl_76596, type, translocation_of_phloem_sap_0: $i).
% 29.32/29.16  tff(decl_76597, type, diffusion_0: $i).
% 29.32/29.16  tff(decl_76598, type, fn_translocation_of_phloem_sap_51: $i > $i).
% 29.32/29.16  tff(decl_76599, type, fn_translocation_of_phloem_sap_23: $i > $i).
% 29.32/29.16  tff(decl_76600, type, fn_translocation_of_phloem_sap_24: $i > $i).
% 29.32/29.16  tff(decl_76601, type, 'Transmembrane-Protein': $i).
% 29.32/29.16  tff(decl_76602, type, 'A protein that goes from one side of a membrane through to the other side of the membrane.': $i).
% 29.32/29.16  tff(decl_76603, type, tp: $i).
% 29.32/29.16  tff(decl_76604, type, 'transmembrane protein': $i).
% 29.32/29.16  tff(decl_76605, type, 'transmembrane-protein': $i).
% 29.32/29.16  tff(decl_76606, type, 'Transmembrane-Transport': $i).
% 29.32/29.16  tff(decl_76607, type, 'Route of transport of water and solutes from one cell to another in vascular plants which follows a path requiring repeated crossings of plasma membranes.': $i).
% 29.32/29.16  tff(decl_76608, type, 'transmembrane transport': $i).
% 29.32/29.16  tff(decl_76609, type, 'transmembrane-transport': $i).
% 29.32/29.16  tff(decl_76610, type, fn_transmembrane_transport_1: $i > $i).
% 29.32/29.16  tff(decl_76611, type, fn_transmembrane_transport_4: $i > $i).
% 29.32/29.16  tff(decl_76612, type, 'Transmission-Electron-Microscope': $i).
% 29.32/29.16  tff(decl_76613, type, 'An microscope used in transmission electron microscopy, a technique whereby a beam of electrons is transmitted through an ultra thin specimen, interacting with the specimen as it passes through. An image is formed from the interaction of the electrons transmitted through the specimen; the image is magnified and focused onto an imaging device, such as a fluorescent screen, on a layer of photographic film, or to be detected by a sensor such as a CCD camera.': $i).
% 29.32/29.16  tff(decl_76614, type, 'transmission electron microscope': $i).
% 29.32/29.16  tff(decl_76615, type, 'transmission-electron-microscope': $i).
% 29.32/29.16  tff(decl_76616, type, 'Transmission-Electron-Microscopy': $i).
% 29.32/29.16  tff(decl_76617, type, 'Transmission electron microscopy (TEM) is a microscopy technique whereby a beam of electrons is transmitted through an ultra thin specimen, interacting with the specimen as it passes through. An image is formed from the interaction of the electrons transmitted through the specimen; the image is magnified and focused onto an imaging device, such as a fluorescent screen, on a layer of photographic film, or to be detected by a sensor such as a CCD camera.': $i).
% 29.32/29.16  tff(decl_76618, type, 'transmission electron microscopy': $i).
% 29.32/29.16  tff(decl_76619, type, 'transmission-electron-microscopy': $i).
% 29.32/29.16  tff(decl_76620, type, fn_transmission_electron_microscopy_1: $i > $i).
% 29.32/29.16  tff(decl_76621, type, fn_transmission_electron_microscopy_2: $i > $i).
% 29.32/29.16  tff(decl_76622, type, 'Transmission-Of-Information': $i).
% 29.32/29.16  tff(decl_76623, type, 'The process of moving information from one location to another or one person to another.': $i).
% 29.32/29.16  tff(decl_76624, type, 'information transmission': $i).
% 29.32/29.16  tff(decl_76625, type, 'information-transmission': $i).
% 29.32/29.16  tff(decl_76626, type, 'transmission of information': $i).
% 29.32/29.16  tff(decl_76627, type, 'transmission-of-information': $i).
% 29.32/29.16  tff(decl_76628, type, fn_transmission_of_information_1: $i > $i).
% 29.32/29.16  tff(decl_76629, type, 'Transmit': $i).
% 29.32/29.16  tff(decl_76630, type, transmission: $i).
% 29.32/29.16  tff(decl_76631, type, channel: $i).
% 29.32/29.16  tff(decl_76632, type, channelize: $i).
% 29.32/29.16  tff(decl_76633, type, transmit_as_cellular_process_1: $i > $o).
% 29.32/29.16  tff(decl_76634, type, 'Transmit-As-Cellular-Process': $i).
% 29.32/29.16  tff(decl_76635, type, 'The passage of a nerve impulse along the axon of a neuron.': $i).
% 29.32/29.16  tff(decl_76636, type, 'transmit as cellular process': $i).
% 29.32/29.16  tff(decl_76637, type, 'transmit-as-cellular-process': $i).
% 29.32/29.16  tff(decl_76638, type, 'Transmittance-Scalar-Constant': $i).
% 29.32/29.16  tff(decl_76639, type, 'transmittance scalar constant': $i).
% 29.32/29.16  tff(decl_76640, type, 'transmittance-scalar-constant': $i).
% 29.32/29.16  tff(decl_76641, type, transmittance_scale_1: $i > $o).
% 29.32/29.16  tff(decl_76642, type, 'Transmittance-Scale': $i).
% 29.32/29.16  tff(decl_76643, type, 'scale of transmittance': $i).
% 29.32/29.16  tff(decl_76644, type, 'transmittance scale': $i).
% 29.32/29.16  tff(decl_76645, type, 'transmittance-scale': $i).
% 29.32/29.16  tff(decl_76646, type, 'Transmittance-Value': $i).
% 29.32/29.16  tff(decl_76647, type, contagion: $i).
% 29.32/29.16  tff(decl_76648, type, 'value of transmittance': $i).
% 29.32/29.16  tff(decl_76649, type, 'transmittance value': $i).
% 29.32/29.16  tff(decl_76650, type, 'transmittance-value': $i).
% 29.32/29.16  tff(decl_76651, type, 'Transmitting-Cell': $i).
% 29.32/29.16  tff(decl_76652, type, 'The cell that is secreting the chemical signal to be received by a target cell.': $i).
% 29.32/29.16  tff(decl_76653, type, 'cell of transmitting': $i).
% 29.32/29.16  tff(decl_76654, type, 'transmitting cell': $i).
% 29.32/29.16  tff(decl_76655, type, 'transmitting-cell': $i).
% 29.32/29.16  tff(decl_76656, type, fn_transmitting_cell_1: $i > $i).
% 29.32/29.16  tff(decl_76657, type, fn_transmitting_cell_3: $i > $i).
% 29.32/29.16  tff(decl_76658, type, 'Transpiration': $i).
% 29.32/29.16  tff(decl_76659, type, 'Part of the water cycle that involves the loss of water from plants due to evaporation.': $i).
% 29.32/29.16  tff(decl_76660, type, transpire: $i).
% 29.32/29.16  tff(decl_76661, type, transpiration: $i).
% 29.32/29.16  tff(decl_76662, type, fn_transpiration_2: $i > $i).
% 29.32/29.16  tff(decl_76663, type, fn_transpiration_3: $i > $i).
% 29.32/29.16  tff(decl_76664, type, fn_transpiration_4: $i > $i).
% 29.32/29.16  tff(decl_76665, type, fn_transpiration_5: $i > $i).
% 29.32/29.16  tff(decl_76666, type, fn_transpiration_6: $i > $i).
% 29.32/29.16  tff(decl_76667, type, fn_transpiration_7: $i > $i).
% 29.32/29.16  tff(decl_76668, type, fn_transpiration_8: $i > $i).
% 29.32/29.16  tff(decl_76669, type, fn_transpiration_9: $i > $i).
% 29.32/29.16  tff(decl_76670, type, fn_transpiration_10: $i > $i).
% 29.32/29.16  tff(decl_76671, type, fn_transpiration_11: $i > $i).
% 29.32/29.16  tff(decl_76672, type, fn_transpiration_12: $i > $i).
% 29.32/29.16  tff(decl_76673, type, fn_transpiration_14: $i > $i).
% 29.32/29.16  tff(decl_76674, type, fn_transpiration_15: $i > $i).
% 29.32/29.16  tff(decl_76675, type, fn_transpiration_16: $i > $i).
% 29.32/29.16  tff(decl_76676, type, fn_transpiration_17: $i > $i).
% 29.32/29.16  tff(decl_76677, type, fn_transpiration_18: $i > $i).
% 29.32/29.16  tff(decl_76678, type, fn_transpiration_19: $i > $i).
% 29.32/29.16  tff(decl_76679, type, fn_transpiration_20: $i > $i).
% 29.32/29.16  tff(decl_76680, type, fn_transpiration_22: $i > $i).
% 29.32/29.16  tff(decl_76681, type, fn_transpiration_23: $i > $i).
% 29.32/29.16  tff(decl_76682, type, fn_transpiration_24: $i > $i).
% 29.32/29.16  tff(decl_76683, type, fn_water_evaporation_15: $i > $i).
% 29.32/29.16  tff(decl_76684, type, fn_water_evaporation_14: $i > $i).
% 29.32/29.16  tff(decl_76685, type, fn_water_evaporation_13: $i > $i).
% 29.32/29.16  tff(decl_76686, type, 'Transpirational-Pull': $i).
% 29.32/29.16  tff(decl_76687, type, 'Transpirational pull is the pull exerted on xylem sap due to transpiration. This pull is responsible for the upward movement of xylem sap from root towards leaves.': $i).
% 29.32/29.16  tff(decl_76688, type, 'transpirational pull': $i).
% 29.32/29.16  tff(decl_76689, type, 'transpirational-pull': $i).
% 29.32/29.16  tff(decl_76690, type, fn_transpirational_pull_1: $i > $i).
% 29.32/29.16  tff(decl_76691, type, fn_transpirational_pull_2: $i > $i).
% 29.32/29.16  tff(decl_76692, type, fn_transpirational_pull_3: $i > $i).
% 29.32/29.16  tff(decl_76693, type, fn_transpirational_pull_4: $i > $i).
% 29.32/29.16  tff(decl_76694, type, fn_transpirational_pull_5: $i > $i).
% 29.32/29.16  tff(decl_76695, type, fn_transpirational_pull_6: $i > $i).
% 29.32/29.16  tff(decl_76696, type, fn_transpirational_pull_7: $i > $i).
% 29.32/29.16  tff(decl_76697, type, fn_transpirational_pull_10: $i > $i).
% 29.32/29.16  tff(decl_76698, type, fn_transpirational_pull_11: $i > $i).
% 29.32/29.16  tff(decl_76699, type, fn_transpirational_pull_12: $i > $i).
% 29.32/29.16  tff(decl_76700, type, fn_transpirational_pull_13: $i > $i).
% 29.32/29.16  tff(decl_76701, type, fn_transpirational_pull_14: $i > $i).
% 29.32/29.16  tff(decl_76702, type, fn_transpirational_pull_15: $i > $i).
% 29.32/29.16  tff(decl_76703, type, fn_transpirational_pull_16: $i > $i).
% 29.32/29.16  tff(decl_76704, type, fn_transpirational_pull_17: $i > $i).
% 29.32/29.16  tff(decl_76705, type, fn_transpirational_pull_18: $i > $i).
% 29.32/29.16  tff(decl_76706, type, fn_transpirational_pull_19: $i > $i).
% 29.32/29.16  tff(decl_76707, type, fn_transpirational_pull_20: $i > $i).
% 29.32/29.16  tff(decl_76708, type, fn_transpirational_pull_21: $i > $i).
% 29.32/29.16  tff(decl_76709, type, fn_transpirational_pull_22: $i > $i).
% 29.32/29.16  tff(decl_76710, type, fn_transpirational_pull_23: $i > $i).
% 29.32/29.16  tff(decl_76711, type, fn_transpirational_pull_24: $i > $i).
% 29.32/29.16  tff(decl_76712, type, fn_transpirational_pull_25: $i > $i).
% 29.32/29.16  tff(decl_76713, type, fn_transpirational_pull_26: $i > $i).
% 29.32/29.16  tff(decl_76714, type, fn_transpirational_pull_27: $i > $i).
% 29.32/29.16  tff(decl_76715, type, fn_transpirational_pull_28: $i > $i).
% 29.32/29.16  tff(decl_76716, type, fn_transpirational_pull_29: $i > $i).
% 29.32/29.16  tff(decl_76717, type, fn_transpirational_pull_30: $i > $i).
% 29.32/29.16  tff(decl_76718, type, fn_transpirational_pull_31: $i > $i).
% 29.32/29.16  tff(decl_76719, type, fn_transpirational_pull_32: $i > $i).
% 29.32/29.16  tff(decl_76720, type, fn_transpirational_pull_33: $i > $i).
% 29.32/29.16  tff(decl_76721, type, fn_transpirational_pull_34: $i > $i).
% 29.32/29.16  tff(decl_76722, type, fn_transpirational_pull_35: $i > $i).
% 29.32/29.16  tff(decl_76723, type, fn_transpirational_pull_36: $i > $i).
% 29.32/29.16  tff(decl_76724, type, fn_transpirational_pull_37: $i > $i).
% 29.32/29.16  tff(decl_76725, type, fn_transpirational_pull_38: $i > $i).
% 29.32/29.16  tff(decl_76726, type, fn_transpirational_pull_39: $i > $i).
% 29.32/29.16  tff(decl_76727, type, fn_transpirational_pull_40: $i > $i).
% 29.32/29.16  tff(decl_76728, type, fn_transpirational_pull_41: $i > $i).
% 29.32/29.16  tff(decl_76729, type, fn_transpirational_pull_42: $i > $i).
% 29.32/29.16  tff(decl_76730, type, fn_transpirational_pull_43: $i > $i).
% 29.32/29.16  tff(decl_76731, type, fn_transpirational_pull_44: $i > $i).
% 29.32/29.16  tff(decl_76732, type, fn_transpirational_pull_45: $i > $i).
% 29.32/29.16  tff(decl_76733, type, fn_transpirational_pull_46: $i > $i).
% 29.32/29.16  tff(decl_76734, type, fn_transpirational_pull_47: $i > $i).
% 29.32/29.16  tff(decl_76735, type, fn_transpirational_pull_48: $i > $i).
% 29.32/29.16  tff(decl_76736, type, fn_transpirational_pull_49: $i > $i).
% 29.32/29.16  tff(decl_76737, type, fn_transpirational_pull_50: $i > $i).
% 29.32/29.16  tff(decl_76738, type, fn_transpirational_pull_51: $i > $i).
% 29.32/29.16  tff(decl_76739, type, transplant_rejection_1: $i > $o).
% 29.32/29.16  tff(decl_76740, type, fn_transplant_rejection_3: $i > $i).
% 29.32/29.16  tff(decl_76741, type, fn_transplant_rejection_5: $i > $i).
% 29.32/29.16  tff(decl_76742, type, fn_transplant_rejection_2: $i > $i).
% 29.32/29.16  tff(decl_76743, type, fn_transplant_rejection_4: $i > $i).
% 29.32/29.16  tff(decl_76744, type, fn_transplant_rejection_6: $i > $i).
% 29.32/29.16  tff(decl_76745, type, 'Transplant-Rejection': $i).
% 29.32/29.16  tff(decl_76746, type, 'Transplant rejection occurs when a transplanted organ or tissue is not accepted by the body of the transplant recipient. This is explained by the concept that the immune system of the recipient attacks the transplanted organ or tissue.': $i).
% 29.32/29.16  tff(decl_76747, type, 'rejection of transplant': $i).
% 29.32/29.16  tff(decl_76748, type, 'transplant rejection': $i).
% 29.32/29.16  tff(decl_76749, type, 'transplant-rejection': $i).
% 29.32/29.16  tff(decl_76750, type, transplanted_species_1: $i > $o).
% 29.32/29.16  tff(decl_76751, type, 'Transplanted-Species': $i).
% 29.32/29.16  tff(decl_76752, type, 'A species that has been moved into a new environment': $i).
% 29.32/29.16  tff(decl_76753, type, 'transplanted species': $i).
% 29.32/29.16  tff(decl_76754, type, 'transplanted-specy': $i).
% 29.32/29.16  tff(decl_76755, type, 'Transport-Epithelium': $i).
% 29.32/29.16  tff(decl_76756, type, 'Layers of epithelial cells specialized to regulate the movement of solutes.': $i).
% 29.32/29.16  tff(decl_76757, type, 'epithelium of transport': $i).
% 29.32/29.16  tff(decl_76758, type, 'transport epithelium': $i).
% 29.32/29.16  tff(decl_76759, type, 'transport-epithelium': $i).
% 29.32/29.16  tff(decl_76760, type, transport_of_cholesterol_in_blood_1: $i > $o).
% 29.32/29.16  tff(decl_76761, type, fn_transport_of_cholesterol_in_blood_1: $i > $i).
% 29.32/29.16  tff(decl_76762, type, 'Transport-Of-Cholesterol-In-Blood': $i).
% 29.32/29.16  tff(decl_76763, type, 'Cholesterol travels in the blood in particles called low-density lipoproteins (LDLs), complexes of lipids and proteins.': $i).
% 29.32/29.16  tff(decl_76764, type, 'transport of cholesterol in blood': $i).
% 29.32/29.16  tff(decl_76765, type, 'transport-of-cholesterol-in-blood': $i).
% 29.32/29.16  tff(decl_76766, type, fn_transport_of_cholesterol_in_blood_3: $i > $i).
% 29.32/29.16  tff(decl_76767, type, fn_transport_of_cholesterol_in_blood_4: $i > $i).
% 29.32/29.16  tff(decl_76768, type, transport_of_pyruvate_from_cytosol_to_mitochondrion_1: $i > $o).
% 29.32/29.16  tff(decl_76769, type, 'Transport-Of-Pyruvate-From-Cytosol-To-Mitochondrion': $i).
% 29.32/29.16  tff(decl_76770, type, 'In eukaryotic cells the Swanson conversion occurs inside the mitochondria, after transport of the substrate, pyruvate, from the cytosol. The transport of pyruvate into the mitochondria is via a transport protein and is active, consuming energy.': $i).
% 29.32/29.16  tff(decl_76771, type, 'transport of pyruvate from cytosol to mitochondrion': $i).
% 29.32/29.16  tff(decl_76772, type, 'transport-of-pyruvate-from-cytosol-to-mitochondrion': $i).
% 29.32/29.16  tff(decl_76773, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_1: $i > $i).
% 29.32/29.16  tff(decl_76774, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_2: $i > $i).
% 29.32/29.16  tff(decl_76775, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_3: $i > $i).
% 29.32/29.16  tff(decl_76776, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_4: $i > $i).
% 29.32/29.16  tff(decl_76777, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_7: $i > $i).
% 29.32/29.16  tff(decl_76778, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_8: $i > $i).
% 29.32/29.16  tff(decl_76779, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_9: $i > $i).
% 29.32/29.16  tff(decl_76780, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_12: $i > $i).
% 29.32/29.16  tff(decl_76781, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_13: $i > $i).
% 29.32/29.16  tff(decl_76782, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_14: $i > $i).
% 29.32/29.16  tff(decl_76783, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_15: $i > $i).
% 29.32/29.16  tff(decl_76784, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_16: $i > $i).
% 29.32/29.16  tff(decl_76785, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_17: $i > $i).
% 29.32/29.16  tff(decl_76786, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_18: $i > $i).
% 29.32/29.16  tff(decl_76787, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_19: $i > $i).
% 29.32/29.16  tff(decl_76788, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_20: $i > $i).
% 29.32/29.16  tff(decl_76789, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_21: $i > $i).
% 29.32/29.16  tff(decl_76790, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_22: $i > $i).
% 29.32/29.16  tff(decl_76791, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_23: $i > $i).
% 29.32/29.16  tff(decl_76792, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_24: $i > $i).
% 29.32/29.16  tff(decl_76793, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_25: $i > $i).
% 29.32/29.16  tff(decl_76794, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_26: $i > $i).
% 29.32/29.16  tff(decl_76795, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_27: $i > $i).
% 29.32/29.16  tff(decl_76796, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_29: $i > $i).
% 29.32/29.16  tff(decl_76797, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_30: $i > $i).
% 29.32/29.16  tff(decl_76798, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_31: $i > $i).
% 29.32/29.16  tff(decl_76799, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_32: $i > $i).
% 29.32/29.16  tff(decl_76800, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_33: $i > $i).
% 29.32/29.16  tff(decl_76801, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_34: $i > $i).
% 29.32/29.16  tff(decl_76802, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_35: $i > $i).
% 29.32/29.16  tff(decl_76803, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_36: $i > $i).
% 29.32/29.16  tff(decl_76804, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_28: $i > $i).
% 29.32/29.16  tff(decl_76805, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_5: $i > $i).
% 29.32/29.16  tff(decl_76806, type, fn_active_transport_15: $i > $i).
% 29.32/29.16  tff(decl_76807, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_6: $i > $i).
% 29.32/29.16  tff(decl_76808, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_10: $i > $i).
% 29.32/29.16  tff(decl_76809, type, fn_transport_of_pyruvate_from_cytosol_to_mitochondrion_11: $i > $i).
% 29.32/29.16  tff(decl_76810, type, 'Transport-Protein': $i).
% 29.32/29.16  tff(decl_76811, type, 'A transmembrane protein that helps a certain type of molecule to cross a biomembrane.': $i).
% 29.32/29.16  tff(decl_76812, type, 'protein of transport': $i).
% 29.32/29.16  tff(decl_76813, type, 'transport protein': $i).
% 29.32/29.16  tff(decl_76814, type, 'transport-protein': $i).
% 29.32/29.16  tff(decl_76815, type, fn_transport_protein_1: $i > $i).
% 29.32/29.16  tff(decl_76816, type, fn_transport_protein_2: $i > $i).
% 29.32/29.16  tff(decl_76817, type, fn_transport_protein_3: $i > $i).
% 29.32/29.16  tff(decl_76818, type, 'Transport-Vesicle': $i).
% 29.32/29.16  tff(decl_76819, type, 'Transport vesicle is a vesicle which transits from one part of the cell to another': $i).
% 29.32/29.16  tff(decl_76820, type, 'vesicle of transport': $i).
% 29.32/29.16  tff(decl_76821, type, 'transport vesicle': $i).
% 29.32/29.16  tff(decl_76822, type, 'transport-vesicle': $i).
% 29.32/29.16  tff(decl_76823, type, fn_transport_vesicle_2: $i > $i).
% 29.32/29.16  tff(decl_76824, type, fn_transport_vesicle_3: $i > $i).
% 29.32/29.16  tff(decl_76825, type, 'Transport-Work': $i).
% 29.32/29.16  tff(decl_76826, type, 'In cells and organisms, transport  work is the process of using energy to move or transport molecules or objects into, out of, or around in the cell.': $i).
% 29.32/29.16  tff(decl_76827, type, 'work of transport': $i).
% 29.32/29.16  tff(decl_76828, type, 'transport work': $i).
% 29.32/29.16  tff(decl_76829, type, 'transport-work': $i).
% 29.32/29.16  tff(decl_76830, type, 'Transposase': $i).
% 29.32/29.16  tff(decl_76831, type, 'An enzyme that acts on transposable elements in DNA mutagenesis.': $i).
% 29.32/29.16  tff(decl_76832, type, transposase: $i).
% 29.32/29.16  tff(decl_76833, type, fn_transposase_1: $i > $i).
% 29.32/29.16  tff(decl_76834, type, fn_transposase_2: $i > $i).
% 29.32/29.16  tff(decl_76835, type, fn_transposase_3: $i > $i).
% 29.32/29.16  tff(decl_76836, type, fn_transposase_4: $i > $i).
% 29.32/29.16  tff(decl_76837, type, fn_transposase_5: $i > $i).
% 29.32/29.16  tff(decl_76838, type, fn_transposase_6: $i > $i).
% 29.32/29.16  tff(decl_76839, type, 'Transposon': $i).
% 29.32/29.16  tff(decl_76840, type, 'A transposable element that moves within a genome by means of a DNA intermediate.': $i).
% 29.32/29.16  tff(decl_76841, type, 'jumping gene': $i).
% 29.32/29.16  tff(decl_76842, type, 'jumping-gene': $i).
% 29.32/29.16  tff(decl_76843, type, 'transposable genetic element': $i).
% 29.32/29.16  tff(decl_76844, type, 'transposable-genetic-element': $i).
% 29.32/29.16  tff(decl_76845, type, 'mobile genetic element': $i).
% 29.32/29.16  tff(decl_76846, type, 'mobile-genetic-element': $i).
% 29.32/29.16  tff(decl_76847, type, 'transposable element transposon': $i).
% 29.32/29.16  tff(decl_76848, type, 'transposable-element-transposon': $i).
% 29.32/29.16  tff(decl_76849, type, 'mobile segment': $i).
% 29.32/29.16  tff(decl_76850, type, 'mobile-segment': $i).
% 29.32/29.16  tff(decl_76851, type, 'mobile segment of dna': $i).
% 29.32/29.16  tff(decl_76852, type, 'mobile-segment-of-dna': $i).
% 29.32/29.16  tff(decl_76853, type, transposon: $i).
% 29.32/29.16  tff(decl_76854, type, fn_transposon_4: $i > $i).
% 29.32/29.16  tff(decl_76855, type, fn_transposon_5: $i > $i).
% 29.32/29.16  tff(decl_76856, type, fn_transposon_6: $i > $i).
% 29.32/29.16  tff(decl_76857, type, fn_transposon_7: $i > $i).
% 29.32/29.16  tff(decl_76858, type, fn_transposon_12: $i > $i).
% 29.32/29.16  tff(decl_76859, type, fn_transposon_16: $i > $i).
% 29.32/29.16  tff(decl_76860, type, fn_transposon_19: $i > $i).
% 29.32/29.16  tff(decl_76861, type, fn_transposon_20: $i > $i).
% 29.32/29.16  tff(decl_76862, type, fn_transposon_21: $i > $i).
% 29.32/29.16  tff(decl_76863, type, fn_transposon_23: $i > $i).
% 29.32/29.16  tff(decl_76864, type, fn_transposon_30: $i > $i).
% 29.32/29.16  tff(decl_76865, type, transverse_1: $i > $o).
% 29.32/29.16  tff(decl_76866, type, 'Transverse': $i).
% 29.32/29.16  tff(decl_76867, type, 'Region spanning the width of an organism or entity, as from dorsal to ventral.': $i).
% 29.32/29.16  tff(decl_76868, type, transverse: $i).
% 29.32/29.16  tff(decl_76869, type, 'Transverse-Tubule': $i).
% 29.32/29.16  tff(decl_76870, type, 'A deep invagination in the plasma membrane of a muscle fiber cell; it allows the membrane depolarization to penetrate quickly into the interior of the cell.': $i).
% 29.32/29.16  tff(decl_76871, type, 't tubule': $i).
% 29.32/29.16  tff(decl_76872, type, 't-tubule': $i).
% 29.32/29.16  tff(decl_76873, type, 'tubule of transverse': $i).
% 29.32/29.16  tff(decl_76874, type, 'transverse tubule': $i).
% 29.32/29.16  tff(decl_76875, type, 'transverse-tubule': $i).
% 29.32/29.16  tff(decl_76876, type, tree_1: $i > $o).
% 29.32/29.16  tff(decl_76877, type, 'Tree': $i).
% 29.32/29.16  tff(decl_76878, type, 'A perennial woody plant with an elongated trunk that supports branches and leaves.': $i).
% 29.32/29.16  tff(decl_76879, type, tree: $i).
% 29.32/29.16  tff(decl_76880, type, tree_branch_1: $i > $o).
% 29.32/29.16  tff(decl_76881, type, 'Tree-Branch': $i).
% 29.32/29.16  tff(decl_76882, type, 'A limb of a tree arising from the trunk.': $i).
% 29.32/29.16  tff(decl_76883, type, branch: $i).
% 29.32/29.16  tff(decl_76884, type, 'branch of tree': $i).
% 29.32/29.16  tff(decl_76885, type, 'tree branch': $i).
% 29.32/29.16  tff(decl_76886, type, 'tree-branch': $i).
% 29.32/29.16  tff(decl_76887, type, 'Tree-Of-Life': $i).
% 29.32/29.16  tff(decl_76888, type, 'A branching diagram that represents the evolutionary history of all life forms.': $i).
% 29.32/29.16  tff(decl_76889, type, 'life tree': $i).
% 29.32/29.16  tff(decl_76890, type, 'life-tree': $i).
% 29.32/29.16  tff(decl_76891, type, 'tree of life': $i).
% 29.32/29.16  tff(decl_76892, type, 'tree-of-life': $i).
% 29.32/29.16  tff(decl_76893, type, tree_trunk_1: $i > $o).
% 29.32/29.16  tff(decl_76894, type, 'Tree-Trunk': $i).
% 29.32/29.16  tff(decl_76895, type, 'The bark covered stem of a tree.': $i).
% 29.32/29.16  tff(decl_76896, type, trunk: $i).
% 29.32/29.16  tff(decl_76897, type, 'trunk of tree': $i).
% 29.32/29.16  tff(decl_76898, type, 'tree trunk': $i).
% 29.32/29.16  tff(decl_76899, type, 'tree-trunk': $i).
% 29.32/29.16  tff(decl_76900, type, 'Trematode': $i).
% 29.32/29.16  tff(decl_76901, type, 'A parasitic flatworm in the class Trematoda, commonly referred to as flukes. In humans, different species of flukes can parasite the liver, intestines, blood, and lungs.': $i).
% 29.32/29.16  tff(decl_76902, type, fluke: $i).
% 29.32/29.16  tff(decl_76903, type, trematode: $i).
% 29.32/29.16  tff(decl_76904, type, 'Trespass': $i).
% 29.32/29.16  tff(decl_76905, type, trespass: $i).
% 29.32/29.16  tff(decl_76906, type, intrude: $i).
% 29.32/29.16  tff(decl_76907, type, transgress: $i).
% 29.32/29.16  tff(decl_76908, type, overstep: $i).
% 29.32/29.16  tff(decl_76909, type, unauthorized_1: $i > $o).
% 29.32/29.16  tff(decl_76910, type, trichome_1: $i > $o).
% 29.32/29.16  tff(decl_76911, type, 'Trichome': $i).
% 29.32/29.16  tff(decl_76912, type, 'Trichomes are hairlike outgrowths in plants.': $i).
% 29.32/29.16  tff(decl_76913, type, trichome: $i).
% 29.32/29.16  tff(decl_76914, type, trichomonad_1: $i > $o).
% 29.32/29.16  tff(decl_76915, type, 'Trichomonad': $i).
% 29.32/29.16  tff(decl_76916, type, 'An order of anaerobic protists, most of which are parasites or other endosymbionts of animals.': $i).
% 29.32/29.16  tff(decl_76917, type, trichomonad: $i).
% 29.32/29.16  tff(decl_76918, type, 'Trichoptera': $i).
% 29.32/29.16  tff(decl_76919, type, 'Order of the class Insecta having two pairs of hairy wings, chewing mouthparts, and aquatic larvae.': $i).
% 29.32/29.16  tff(decl_76920, type, caddisflies: $i).
% 29.32/29.16  tff(decl_76921, type, trichoptera: $i).
% 29.32/29.16  tff(decl_76922, type, trigger_node_1: $i > $o).
% 29.32/29.16  tff(decl_76923, type, 'Trigger-Node': $i).
% 29.32/29.16  tff(decl_76924, type, 'node of trigger': $i).
% 29.32/29.16  tff(decl_76925, type, 'trigger node': $i).
% 29.32/29.16  tff(decl_76926, type, 'trigger-node': $i).
% 29.32/29.16  tff(decl_76927, type, 'Trilobite': $i).
% 29.32/29.16  tff(decl_76928, type, 'A well-studied group (subphylum or class) of extinct marine arthropods.': $i).
% 29.32/29.16  tff(decl_76929, type, trilobite: $i).
% 29.32/29.16  tff(decl_76930, type, 'Trimer': $i).
% 29.32/29.16  tff(decl_76931, type, 'A molecule made up of three smaller, identical molecules.': $i).
% 29.32/29.16  tff(decl_76932, type, trimer: $i).
% 29.32/29.16  tff(decl_76933, type, fn_trimer_1: $i > $i).
% 29.32/29.16  tff(decl_76934, type, 'Triose': $i).
% 29.32/29.16  tff(decl_76935, type, 'A triose is a monosaccharide containing three carbon atoms. There are only two trioses, an aldotriose (glyceraldehyde) and a ketotriose (dihydroxyacetone).': $i).
% 29.32/29.16  tff(decl_76936, type, 'three carbon sugar': $i).
% 29.32/29.16  tff(decl_76937, type, 'three-carbon-sugar': $i).
% 29.32/29.16  tff(decl_76938, type, triose: $i).
% 29.32/29.16  tff(decl_76939, type, fn_triose_1: $i > $i).
% 29.32/29.16  tff(decl_76940, type, fn_triose_2: $i > $i).
% 29.32/29.16  tff(decl_76941, type, 'Triose-Phosphate-Dehydrogenase': $i).
% 29.32/29.16  tff(decl_76942, type, 'The enzyme that catalyzes the sixth step of glycolysis where, first, a hydrogen from glyceraldehyde-3-phosphate is transferred to NAD+ to form NADH, and second, it adds a phosphate from the cytosol to the oxidized glyceraldehyde-3-phosphate to form 1,3-bisphosphoglycerate.': $i).
% 29.32/29.16  tff(decl_76943, type, 'triose phosphate dehydrogenase': $i).
% 29.32/29.16  tff(decl_76944, type, 'triose-phosphate-dehydrogenase': $i).
% 29.32/29.16  tff(decl_76945, type, fn_triose_phosphate_dehydrogenase_8: $i > $i).
% 29.32/29.16  tff(decl_76946, type, fn_triose_phosphate_dehydrogenase_11: $i > $i).
% 29.32/29.16  tff(decl_76947, type, fn_triose_phosphate_dehydrogenase_12: $i > $i).
% 29.32/29.16  tff(decl_76948, type, fn_triose_phosphate_dehydrogenase_14: $i > $i).
% 29.32/29.16  tff(decl_76949, type, fn_triose_phosphate_dehydrogenase_15: $i > $i).
% 29.32/29.16  tff(decl_76950, type, fn_triose_phosphate_dehydrogenase_16: $i > $i).
% 29.32/29.16  tff(decl_76951, type, fn_triose_phosphate_dehydrogenase_17: $i > $i).
% 29.32/29.16  tff(decl_76952, type, fn_triose_phosphate_dehydrogenase_18: $i > $i).
% 29.32/29.16  tff(decl_76953, type, fn_triose_phosphate_dehydrogenase_19: $i > $i).
% 29.32/29.16  tff(decl_76954, type, fn_triose_phosphate_dehydrogenase_20: $i > $i).
% 29.32/29.16  tff(decl_76955, type, fn_triose_phosphate_dehydrogenase_21: $i > $i).
% 29.32/29.16  tff(decl_76956, type, fn_triose_phosphate_dehydrogenase_22: $i > $i).
% 29.32/29.16  tff(decl_76957, type, fn_triose_phosphate_dehydrogenase_23: $i > $i).
% 29.32/29.16  tff(decl_76958, type, fn_triose_phosphate_dehydrogenase_24: $i > $i).
% 29.32/29.16  tff(decl_76959, type, fn_triose_phosphate_dehydrogenase_25: $i > $i).
% 29.32/29.16  tff(decl_76960, type, fn_triose_phosphate_dehydrogenase_26: $i > $i).
% 29.32/29.16  tff(decl_76961, type, fn_triose_phosphate_dehydrogenase_27: $i > $i).
% 29.32/29.16  tff(decl_76962, type, fn_triose_phosphate_dehydrogenase_28: $i > $i).
% 29.32/29.16  tff(decl_76963, type, fn_triose_phosphate_dehydrogenase_29: $i > $i).
% 29.32/29.16  tff(decl_76964, type, fn_triose_phosphate_dehydrogenase_30: $i > $i).
% 29.32/29.16  tff(decl_76965, type, fn_triose_phosphate_dehydrogenase_31: $i > $i).
% 29.32/29.16  tff(decl_76966, type, fn_dehydrogenase_2: $i > $i).
% 29.32/29.16  tff(decl_76967, type, fn_triose_phosphate_dehydrogenase_32: $i > $i).
% 29.32/29.16  tff(decl_76968, type, fn_dehydrogenase_1: $i > $i).
% 29.32/29.16  tff(decl_76969, type, 'Triple-Response': $i).
% 29.32/29.16  tff(decl_76970, type, 'A plant seedling growth response to a mechanical stress such as a solid object above. The triple response involves a decrease of stem elongation, a strengthening of the stem by growing thicker, and horizontal growth until the shoot has grown beyond the obstruction and resumes growing upright.': $i).
% 29.32/29.16  tff(decl_76971, type, 'response of triple': $i).
% 29.32/29.16  tff(decl_76972, type, 'triple response': $i).
% 29.32/29.16  tff(decl_76973, type, 'triple-response': $i).
% 29.32/29.16  tff(decl_76974, type, 'Triple-X': $i).
% 29.32/29.16  tff(decl_76975, type, 'In humans, a female born with three X chromosomes.': $i).
% 29.32/29.16  tff(decl_76976, type, 'triple x': $i).
% 29.32/29.16  tff(decl_76977, type, 'triple-x': $i).
% 29.32/29.16  tff(decl_76978, type, 'xxx female': $i).
% 29.32/29.16  tff(decl_76979, type, 'xxx-female': $i).
% 29.32/29.16  tff(decl_76980, type, xxx: $i).
% 29.32/29.16  tff(decl_76981, type, 'x of triple': $i).
% 29.32/29.16  tff(decl_76982, type, triplet_code_1: $i > $o).
% 29.32/29.16  tff(decl_76983, type, 'Triplet-Code': $i).
% 29.32/29.16  tff(decl_76984, type, 'The genetic code, in which a grouping of three nucleotides specifies an amino acid to be incorporated into a polypeptide chain.': $i).
% 29.32/29.16  tff(decl_76985, type, 'code of triplet': $i).
% 29.32/29.16  tff(decl_76986, type, 'triplet code': $i).
% 29.32/29.16  tff(decl_76987, type, 'triplet-code': $i).
% 29.32/29.16  tff(decl_76988, type, 'Triploblastic': $i).
% 29.32/29.16  tff(decl_76989, type, 'Having tissues derived from three embryonic germ layers: endoderm, mesoderm, and ectoderm. Most animals are triploblastic.': $i).
% 29.32/29.16  tff(decl_76990, type, triploblastic: $i).
% 29.32/29.16  tff(decl_76991, type, trisomic_1: $i > $o).
% 29.32/29.16  tff(decl_76992, type, 'Trisomic': $i).
% 29.32/29.16  tff(decl_76993, type, 'Having three copies of a chromosome instead of the normal two copies found in a diploid cell.': $i).
% 29.32/29.16  tff(decl_76994, type, trisomic: $i).
% 29.32/29.16  tff(decl_76995, type, trisomy_1: $i > $o).
% 29.32/29.16  tff(decl_76996, type, 'Trisomy': $i).
% 29.32/29.16  tff(decl_76997, type, 'The possession of three copies of a chromosome, instead of the usual diploid number of two.': $i).
% 29.32/29.16  tff(decl_76998, type, trisomy: $i).
% 29.32/29.16  tff(decl_76999, type, 'TRNA': $i).
% 29.32/29.16  tff(decl_77000, type, 'tRNA is a type of RNA which functions as the bearer of the amino acid moeities to the polypeptide synthesis site on ribosome during translation process': $i).
% 29.32/29.16  tff(decl_77001, type, 'transfer ribo nucleic acid': $i).
% 29.32/29.16  tff(decl_77002, type, 'transfer ribo-nucleic acid': $i).
% 29.32/29.16  tff(decl_77003, type, 'transfer ribonucleic acid': $i).
% 29.32/29.16  tff(decl_77004, type, trna: $i).
% 29.32/29.16  tff(decl_77005, type, 'transfer rna': $i).
% 29.32/29.16  tff(decl_77006, type, 'transfer-rna': $i).
% 29.32/29.16  tff(decl_77007, type, fn_trna_3: $i > $i).
% 29.32/29.16  tff(decl_77008, type, fn_trna_5: $i > $i).
% 29.32/29.16  tff(decl_77009, type, fn_trna_6: $i > $i).
% 29.32/29.16  tff(decl_77010, type, fn_trna_7: $i > $i).
% 29.32/29.16  tff(decl_77011, type, fn_trna_8: $i > $i).
% 29.32/29.16  tff(decl_77012, type, fn_trna_9: $i > $i).
% 29.32/29.16  tff(decl_77013, type, fn_trna_10: $i > $i).
% 29.32/29.16  tff(decl_77014, type, fn_trna_11: $i > $i).
% 29.32/29.16  tff(decl_77015, type, fn_trna_12: $i > $i).
% 29.32/29.16  tff(decl_77016, type, fn_trna_13: $i > $i).
% 29.32/29.16  tff(decl_77017, type, fn_trna_14: $i > $i).
% 29.32/29.16  tff(decl_77018, type, fn_trna_15: $i > $i).
% 29.32/29.16  tff(decl_77019, type, fn_trna_16: $i > $i).
% 29.32/29.16  tff(decl_77020, type, fn_trna_17: $i > $i).
% 29.32/29.16  tff(decl_77021, type, fn_trna_18: $i > $i).
% 29.32/29.16  tff(decl_77022, type, fn_trna_22: $i > $i).
% 29.32/29.16  tff(decl_77023, type, fn_trna_21: $i > $i).
% 29.32/29.16  tff(decl_77024, type, fn_trna_19: $i > $i).
% 29.32/29.16  tff(decl_77025, type, fn_trna_20: $i > $i).
% 29.32/29.16  tff(decl_77026, type, trochophore_larva_1: $i > $o).
% 29.32/29.16  tff(decl_77027, type, 'Trochophore-Larva': $i).
% 29.32/29.16  tff(decl_77028, type, 'Larval form of annelids and molluscs, characterized by a ciliated band called a prototroch. The trochophore is one of the traits used to group animals into the clade Lophotrochozoa.': $i).
% 29.32/29.16  tff(decl_77029, type, 'trochophore larva': $i).
% 29.32/29.16  tff(decl_77030, type, 'trochophore-larva': $i).
% 29.32/29.16  tff(decl_77031, type, fn_trochophore_larva_1: $i > $i).
% 29.32/29.16  tff(decl_77032, type, 'Trophic-Cascade-Model': $i).
% 29.32/29.16  tff(decl_77033, type, 'A top-down model that states that predation is the primary factor of community structure because predators control the populations of herbivores, which control the population of plants, which in turn control nutrient levels in the community.': $i).
% 29.32/29.16  tff(decl_77034, type, 'trophic cascade model': $i).
% 29.32/29.16  tff(decl_77035, type, 'trophic-cascade-model': $i).
% 29.32/29.16  tff(decl_77036, type, 'Trophic-Level': $i).
% 29.32/29.16  tff(decl_77037, type, 'Ecological grouping of organisms which is based upon the source of the organism\\s energy.': $i).
% 29.32/29.16  tff(decl_77038, type, 'trophic level': $i).
% 29.32/29.16  tff(decl_77039, type, 'trophic-level': $i).
% 29.32/29.16  tff(decl_77040, type, 'Trophic-Structure': $i).
% 29.32/29.16  tff(decl_77041, type, 'The feeding relationships among organisms in an ecosystem. These relationships determine the pattern of energy flow and chemical cycling through the ecosystem.': $i).
% 29.32/29.16  tff(decl_77042, type, 'trophic structure': $i).
% 29.32/29.16  tff(decl_77043, type, 'trophic-structure': $i).
% 29.32/29.16  tff(decl_77044, type, 'Trophoblast': $i).
% 29.32/29.16  tff(decl_77045, type, 'A cell forming the outer layer of a mammalian blastocyst. It will develop into the fetal part of the placenta but is not part of the embryo itself.': $i).
% 29.32/29.16  tff(decl_77046, type, trophoblast: $i).
% 29.32/29.16  tff(decl_77047, type, 'Tropic-Hormone': $i).
% 29.32/29.16  tff(decl_77048, type, 'A hormone whose target is another endocrine gland.': $i).
% 29.32/29.16  tff(decl_77049, type, 'hormone of tropic': $i).
% 29.32/29.16  tff(decl_77050, type, 'tropic hormone': $i).
% 29.32/29.16  tff(decl_77051, type, 'tropic-hormone': $i).
% 29.32/29.16  tff(decl_77052, type, tropical_air_1: $i > $o).
% 29.32/29.16  tff(decl_77053, type, 'Tropical-Air': $i).
% 29.32/29.16  tff(decl_77054, type, 'Warm and humid air from tropical and subtropical regions.': $i).
% 29.32/29.16  tff(decl_77055, type, 'tropical air': $i).
% 29.32/29.16  tff(decl_77056, type, 'tropical-air': $i).
% 29.32/29.16  tff(decl_77057, type, fn_tropical_air_1: $i > $i).
% 29.32/29.16  tff(decl_77058, type, fn_tropical_air_2: $i > $i).
% 29.32/29.16  tff(decl_77059, type, fn_tropical_air_3: $i > $i).
% 29.32/29.16  tff(decl_77060, type, fn_tropical_air_4: $i > $i).
% 29.32/29.16  tff(decl_77061, type, fn_tropical_air_5: $i > $i).
% 29.32/29.16  tff(decl_77062, type, fn_tropical_air_6: $i > $i).
% 29.32/29.16  tff(decl_77063, type, fn_tropical_air_7: $i > $i).
% 29.32/29.16  tff(decl_77064, type, fn_tropical_air_8: $i > $i).
% 29.32/29.16  tff(decl_77065, type, fn_tropical_air_9: $i > $i).
% 29.32/29.16  tff(decl_77066, type, fn_tropical_air_10: $i > $i).
% 29.32/29.16  tff(decl_77067, type, fn_tropical_region_1: $i > $i).
% 29.32/29.16  tff(decl_77068, type, fn_tropical_air_11: $i > $i).
% 29.32/29.16  tff(decl_77069, type, 'Tropical-Rain-Forest': $i).
% 29.32/29.16  tff(decl_77070, type, 'A terrestrial biome occurring the Tropic of Cancer and the Tropic of Capricorn, characterized by high average temperatures and high levels of rain.': $i).
% 29.32/29.16  tff(decl_77071, type, 'tropical rain forest': $i).
% 29.32/29.16  tff(decl_77072, type, 'tropical-rain-forest': $i).
% 29.32/29.16  tff(decl_77073, type, fn_tropical_rain_forest_1: $i > $i).
% 29.32/29.16  tff(decl_77074, type, fn_tropical_rain_forest_2: $i > $i).
% 29.32/29.16  tff(decl_77075, type, fn_tropical_rain_forest_3: $i > $i).
% 29.32/29.16  tff(decl_77076, type, fn_tropical_rain_forest_4: $i > $i).
% 29.32/29.16  tff(decl_77077, type, fn_tropical_rain_forest_5: $i > $i).
% 29.32/29.16  tff(decl_77078, type, 'Tropical-Region': $i).
% 29.32/29.16  tff(decl_77079, type, 'The part of the earth that is between the Tropic of Cancer and the Tropic of Capricorn.': $i).
% 29.32/29.16  tff(decl_77080, type, 'tropical region': $i).
% 29.32/29.16  tff(decl_77081, type, 'tropical-region': $i).
% 29.32/29.16  tff(decl_77082, type, 'Tropical-Sea': $i).
% 29.32/29.16  tff(decl_77083, type, 'A sea found in the tropic region, surrounding the equator.': $i).
% 29.32/29.16  tff(decl_77084, type, 'tropical sea': $i).
% 29.32/29.16  tff(decl_77085, type, 'tropical-sea': $i).
% 29.32/29.16  tff(decl_77086, type, 'Tropics': $i).
% 29.32/29.16  tff(decl_77087, type, 'The latitudes between the Tropic of Cancer (23.5 degrees north) and the Tropic of Capricorn (23.4 degrees south).': $i).
% 29.32/29.16  tff(decl_77088, type, tropics: $i).
% 29.32/29.16  tff(decl_77089, type, tropic: $i).
% 29.32/29.16  tff(decl_77090, type, 'Tropism': $i).
% 29.32/29.16  tff(decl_77091, type, 'Tropism describes plant growth toward or away from various types of stimuli.': $i).
% 29.32/29.16  tff(decl_77092, type, tropism: $i).
% 29.32/29.16  tff(decl_77093, type, 'Tropomyosin': $i).
% 29.32/29.16  tff(decl_77094, type, 'A protein found in muscle tissue that inhibits muscle contraction by preventing myosin from binding to actin.': $i).
% 29.32/29.16  tff(decl_77095, type, tropomyosin: $i).
% 29.32/29.16  tff(decl_77096, type, 'Troponin-Complex': $i).
% 29.32/29.16  tff(decl_77097, type, 'A group of proteins that regulate where tropomyosin attaches on a thin filament in muscle fibers.': $i).
% 29.32/29.16  tff(decl_77098, type, 'troponin complex': $i).
% 29.32/29.16  tff(decl_77099, type, 'troponin-complex': $i).
% 29.32/29.16  tff(decl_77100, type, trp_operon_1: $i > $o).
% 29.32/29.16  tff(decl_77101, type, 'Trp-Operon': $i).
% 29.32/29.16  tff(decl_77102, type, 'A group of genes that regulates the synthesis of the amino acid - tryptophan in prokaryotes.': $i).
% 29.32/29.16  tff(decl_77103, type, 'trp operon': $i).
% 29.32/29.16  tff(decl_77104, type, 'trp-operon': $i).
% 29.32/29.16  tff(decl_77105, type, fn_trp_operon_1: $i > $i).
% 29.32/29.16  tff(decl_77106, type, fn_trp_operon_2: $i > $i).
% 29.32/29.16  tff(decl_77107, type, fn_trp_operon_3: $i > $i).
% 29.32/29.16  tff(decl_77108, type, fn_trp_operon_4: $i > $i).
% 29.32/29.16  tff(decl_77109, type, fn_trp_operon_5: $i > $i).
% 29.32/29.16  tff(decl_77110, type, fn_trp_operon_6: $i > $i).
% 29.32/29.16  tff(decl_77111, type, fn_trp_operon_7: $i > $i).
% 29.32/29.16  tff(decl_77112, type, fn_trp_operon_regulation_2: $i > $i).
% 29.32/29.16  tff(decl_77113, type, 'Trp-Operon-Regulation': $i).
% 29.32/29.16  tff(decl_77114, type, 'Regulation of the trp operon mediated by the TrpR gene.': $i).
% 29.32/29.16  tff(decl_77115, type, 'regulation of the trp operon': $i).
% 29.32/29.16  tff(decl_77116, type, 'trp operon regulation': $i).
% 29.32/29.16  tff(decl_77117, type, 'trp-operon-regulation': $i).
% 29.32/29.16  tff(decl_77118, type, 'TrpR': $i).
% 29.32/29.16  tff(decl_77119, type, 'DNA-binding transcriptional repressor, tryptophan-binding': $i).
% 29.32/29.16  tff(decl_77120, type, 'regulatory gene for trp operon': $i).
% 29.32/29.16  tff(decl_77121, type, 'trp regulatory gene': $i).
% 29.32/29.16  tff(decl_77122, type, 'trpr regulatory gene': $i).
% 29.32/29.16  tff(decl_77123, type, trpr: $i).
% 29.32/29.16  tff(decl_77124, type, fn_trpr_3: $i > $i).
% 29.32/29.16  tff(decl_77125, type, fn_trpr_4: $i > $i).
% 29.32/29.16  tff(decl_77126, type, fn_trpr_5: $i > $i).
% 29.32/29.16  tff(decl_77127, type, fn_trpr_8: $i > $i).
% 29.32/29.16  tff(decl_77128, type, fn_trpr_9: $i > $i).
% 29.32/29.16  tff(decl_77129, type, fn_trpr_10: $i > $i).
% 29.32/29.16  tff(decl_77130, type, fn_trpr_11: $i > $i).
% 29.32/29.16  tff(decl_77131, type, fn_trpr_12: $i > $i).
% 29.32/29.16  tff(decl_77132, type, fn_trpr_13: $i > $i).
% 29.32/29.16  tff(decl_77133, type, fn_trpr_14: $i > $i).
% 29.32/29.16  tff(decl_77134, type, fn_trpr_15: $i > $i).
% 29.32/29.16  tff(decl_77135, type, fn_trpr_16: $i > $i).
% 29.32/29.16  tff(decl_77136, type, fn_trpr_17: $i > $i).
% 29.32/29.16  tff(decl_77137, type, fn_trpr_18: $i > $i).
% 29.32/29.16  tff(decl_77138, type, fn_trpr_19: $i > $i).
% 29.32/29.16  tff(decl_77139, type, fn_trpr_20: $i > $i).
% 29.32/29.16  tff(decl_77140, type, fn_trpr_21: $i > $i).
% 29.32/29.16  tff(decl_77141, type, fn_trpr_7: $i > $i).
% 29.32/29.16  tff(decl_77142, type, fn_trpr_6: $i > $i).
% 29.32/29.16  tff(decl_77143, type, 'True-breeding': $i).
% 29.32/29.16  tff(decl_77144, type, 'Plants that produce offspring of the same variety when they self-pollinate.': $i).
% 29.32/29.16  tff(decl_77145, type, 'breeding of true': $i).
% 29.32/29.16  tff(decl_77146, type, 'true breeding': $i).
% 29.32/29.16  tff(decl_77147, type, 'true-breeding': $i).
% 29.32/29.16  tff(decl_77148, type, fn_true_breeding_1: $i > $i).
% 29.32/29.16  tff(decl_77149, type, fn_true_breeding_2: $i > $i).
% 29.32/29.16  tff(decl_77150, type, fn_true_breeding_3: $i > $i).
% 29.32/29.16  tff(decl_77151, type, fn_true_breeding_4: $i > $i).
% 29.32/29.16  tff(decl_77152, type, fn_true_breeding_7: $i > $i).
% 29.32/29.16  tff(decl_77153, type, fn_true_breeding_8: $i > $i).
% 29.32/29.16  tff(decl_77154, type, fn_true_breeding_9: $i > $i).
% 29.32/29.16  tff(decl_77155, type, fn_true_breeding_10: $i > $i).
% 29.32/29.16  tff(decl_77156, type, fn_true_breeding_17: $i > $i).
% 29.32/29.16  tff(decl_77157, type, fn_true_breeding_18: $i > $i).
% 29.32/29.16  tff(decl_77158, type, fn_true_breeding_19: $i > $i).
% 29.32/29.16  tff(decl_77159, type, fn_true_breeding_20: $i > $i).
% 29.32/29.16  tff(decl_77160, type, fn_true_breeding_21: $i > $i).
% 29.32/29.16  tff(decl_77161, type, fn_true_breeding_22: $i > $i).
% 29.32/29.16  tff(decl_77162, type, fn_true_breeding_23: $i > $i).
% 29.32/29.16  tff(decl_77163, type, fn_true_breeding_24: $i > $i).
% 29.32/29.16  tff(decl_77164, type, fn_true_breeding_25: $i > $i).
% 29.32/29.16  tff(decl_77165, type, fn_true_breeding_26: $i > $i).
% 29.32/29.16  tff(decl_77166, type, fn_true_breeding_27: $i > $i).
% 29.32/29.16  tff(decl_77167, type, fn_true_breeding_28: $i > $i).
% 29.32/29.16  tff(decl_77168, type, fn_true_breeding_29: $i > $i).
% 29.32/29.16  tff(decl_77169, type, fn_true_breeding_30: $i > $i).
% 29.32/29.16  tff(decl_77170, type, fn_true_breeding_31: $i > $i).
% 29.32/29.16  tff(decl_77171, type, fn_true_breeding_32: $i > $i).
% 29.32/29.16  tff(decl_77172, type, fn_true_breeding_33: $i > $i).
% 29.32/29.16  tff(decl_77173, type, fn_true_breeding_34: $i > $i).
% 29.32/29.16  tff(decl_77174, type, fn_true_breeding_35: $i > $i).
% 29.32/29.16  tff(decl_77175, type, fn_true_breeding_36: $i > $i).
% 29.32/29.16  tff(decl_77176, type, fn_true_breeding_37: $i > $i).
% 29.32/29.16  tff(decl_77177, type, fn_true_breeding_38: $i > $i).
% 29.32/29.16  tff(decl_77178, type, fn_true_breeding_39: $i > $i).
% 29.32/29.16  tff(decl_77179, type, fn_true_breeding_40: $i > $i).
% 29.32/29.16  tff(decl_77180, type, fn_true_breeding_41: $i > $i).
% 29.32/29.16  tff(decl_77181, type, fn_true_breeding_42: $i > $i).
% 29.32/29.16  tff(decl_77182, type, fn_true_breeding_43: $i > $i).
% 29.32/29.16  tff(decl_77183, type, fn_true_breeding_44: $i > $i).
% 29.32/29.16  tff(decl_77184, type, fn_true_breeding_45: $i > $i).
% 29.32/29.16  tff(decl_77185, type, fn_true_breeding_46: $i > $i).
% 29.32/29.16  tff(decl_77186, type, fn_true_breeding_47: $i > $i).
% 29.32/29.16  tff(decl_77187, type, fn_true_breeding_48: $i > $i).
% 29.32/29.16  tff(decl_77188, type, fn_true_breeding_49: $i > $i).
% 29.32/29.16  tff(decl_77189, type, fn_true_breeding_50: $i > $i).
% 29.32/29.16  tff(decl_77190, type, fn_true_breeding_51: $i > $i).
% 29.32/29.16  tff(decl_77191, type, fn_true_breeding_52: $i > $i).
% 29.32/29.16  tff(decl_77192, type, fn_true_breeding_53: $i > $i).
% 29.32/29.16  tff(decl_77193, type, fn_true_breeding_54: $i > $i).
% 29.32/29.16  tff(decl_77194, type, fn_true_breeding_55: $i > $i).
% 29.32/29.16  tff(decl_77195, type, fn_true_breeding_56: $i > $i).
% 29.32/29.16  tff(decl_77196, type, fn_true_breeding_57: $i > $i).
% 29.32/29.16  tff(decl_77197, type, fn_true_breeding_58: $i > $i).
% 29.32/29.16  tff(decl_77198, type, fn_true_breeding_59: $i > $i).
% 29.32/29.16  tff(decl_77199, type, fn_true_breeding_60: $i > $i).
% 29.32/29.16  tff(decl_77200, type, fn_true_breeding_61: $i > $i).
% 29.32/29.16  tff(decl_77201, type, fn_true_breeding_62: $i > $i).
% 29.32/29.16  tff(decl_77202, type, fn_true_breeding_63: $i > $i).
% 29.32/29.16  tff(decl_77203, type, fn_true_breeding_64: $i > $i).
% 29.32/29.16  tff(decl_77204, type, fn_true_breeding_65: $i > $i).
% 29.32/29.16  tff(decl_77205, type, fn_true_breeding_68: $i > $i).
% 29.32/29.16  tff(decl_77206, type, fn_true_breeding_69: $i > $i).
% 29.32/29.16  tff(decl_77207, type, fn_true_breeding_6: $i > $i).
% 29.32/29.16  tff(decl_77208, type, fn_true_breeding_5: $i > $i).
% 29.32/29.16  tff(decl_77209, type, fn_true_breeding_13: $i > $i).
% 29.32/29.16  tff(decl_77210, type, fn_true_breeding_14: $i > $i).
% 29.32/29.16  tff(decl_77211, type, fn_true_breeding_12: $i > $i).
% 29.32/29.16  tff(decl_77212, type, fn_true_breeding_11: $i > $i).
% 29.32/29.16  tff(decl_77213, type, fn_true_breeding_16: $i > $i).
% 29.32/29.16  tff(decl_77214, type, fn_true_breeding_15: $i > $i).
% 29.32/29.16  tff(decl_77215, type, fn_true_breeding_67: $i > $i).
% 29.32/29.16  tff(decl_77216, type, fn_true_breeding_66: $i > $i).
% 29.32/29.16  tff(decl_77217, type, 'Truffle': $i).
% 29.32/29.16  tff(decl_77218, type, 'The fruiting body of certain types of underground fungi. Fungal spores are dispersed when an animal digs up and eats the truffle.': $i).
% 29.32/29.16  tff(decl_77219, type, truffle: $i).
% 29.32/29.16  tff(decl_77220, type, 'Truth-Constant': $i).
% 29.32/29.16  tff(decl_77221, type, 'constant of truth': $i).
% 29.32/29.16  tff(decl_77222, type, 'truth constant': $i).
% 29.32/29.16  tff(decl_77223, type, 'truth-constant': $i).
% 29.32/29.16  tff(decl_77224, type, 'Truth-Value': $i).
% 29.32/29.16  tff(decl_77225, type, 'the truth value of an information': $i).
% 29.32/29.16  tff(decl_77226, type, 'the true': $i).
% 29.32/29.16  tff(decl_77227, type, verity: $i).
% 29.32/29.16  tff(decl_77228, type, accuracy: $i).
% 29.32/29.16  tff(decl_77229, type, truth: $i).
% 29.32/29.16  tff(decl_77230, type, 'value of truth': $i).
% 29.32/29.16  tff(decl_77231, type, 'truth value': $i).
% 29.32/29.16  tff(decl_77232, type, 'truth-value': $i).
% 29.32/29.16  tff(decl_77233, type, 'Trypanosome': $i).
% 29.32/29.16  tff(decl_77234, type, 'A parasitic protozoan of the class Kinetoplastida. In humans, trypanosomes causes sleeping sickness and Chagas disease.': $i).
% 29.32/29.16  tff(decl_77235, type, trypanosome: $i).
% 29.32/29.16  tff(decl_77236, type, 'Trypsin': $i).
% 29.32/29.16  tff(decl_77237, type, 'Trypsin is a digestive enzyme that hydrolyzes proteins. The enzyme is produced in the pancreas from the inactive proenzyme trypsinogen.': $i).
% 29.32/29.16  tff(decl_77238, type, trypsin: $i).
% 29.32/29.16  tff(decl_77239, type, fn_trypsin_1: $i > $i).
% 29.32/29.16  tff(decl_77240, type, fn_trypsin_2: $i > $i).
% 29.32/29.16  tff(decl_77241, type, fn_trypsin_3: $i > $i).
% 29.32/29.16  tff(decl_77242, type, fn_trypsin_4: $i > $i).
% 29.32/29.16  tff(decl_77243, type, fn_trypsin_5: $i > $i).
% 29.32/29.16  tff(decl_77244, type, fn_trypsin_6: $i > $i).
% 29.32/29.16  tff(decl_77245, type, fn_trypsin_7: $i > $i).
% 29.32/29.16  tff(decl_77246, type, fn_trypsin_8: $i > $i).
% 29.32/29.16  tff(decl_77247, type, fn_trypsin_9: $i > $i).
% 29.32/29.16  tff(decl_77248, type, fn_trypsin_10: $i > $i).
% 29.32/29.16  tff(decl_77249, type, fn_trypsin_11: $i > $i).
% 29.32/29.16  tff(decl_77250, type, fn_trypsin_12: $i > $i).
% 29.32/29.16  tff(decl_77251, type, fn_trypsin_13: $i > $i).
% 29.32/29.16  tff(decl_77252, type, fn_trypsin_14: $i > $i).
% 29.32/29.16  tff(decl_77253, type, 'Tryptophan': $i).
% 29.32/29.16  tff(decl_77254, type, trp: $i).
% 29.32/29.16  tff(decl_77255, type, 'W': $i).
% 29.32/29.16  tff(decl_77256, type, tryptophan: $i).
% 29.32/29.16  tff(decl_77257, type, 'TTAGGG': $i).
% 29.32/29.16  tff(decl_77258, type, 'The short DNA sequence that is repeated and added to the end of the chromosome molecule to prevent the eroding of the chromosomes after successive rounds of DNA replication.': $i).
% 29.32/29.16  tff(decl_77259, type, ttaggg: $i).
% 29.32/29.16  tff(decl_77260, type, fn_ttaggg_1: $i > $i).
% 29.32/29.16  tff(decl_77261, type, 'Tuatara': $i).
% 29.32/29.16  tff(decl_77262, type, 'A reptile that is found only in New Zealand and is the last living representative of its order.': $i).
% 29.32/29.16  tff(decl_77263, type, tuatara: $i).
% 29.32/29.16  tff(decl_77264, type, 'Tubal-Ligation': $i).
% 29.32/29.16  tff(decl_77265, type, 'A permanent means of birth control in which a woman\\s fallopian tubes are either clamped and blocked or severed and sealed, preventing an egg from passing through the tubes.': $i).
% 29.32/29.16  tff(decl_77266, type, tubectomy: $i).
% 29.32/29.16  tff(decl_77267, type, 'getting tubes tied': $i).
% 29.32/29.16  tff(decl_77268, type, 'getting-tubes-tied': $i).
% 29.32/29.16  tff(decl_77269, type, 'tubal ligation': $i).
% 29.32/29.16  tff(decl_77270, type, 'tubal-ligation': $i).
% 29.32/29.16  tff(decl_77271, type, tube_foot_1: $i > $o).
% 29.32/29.16  tff(decl_77272, type, 'Tube-Foot': $i).
% 29.32/29.16  tff(decl_77273, type, 'One of many external extensions of the water vascular system in echinoderms. Echinoderms use their tube feet for locomotion, feeding, or both. Tube feet also function as gas exchange surfaces.': $i).
% 29.32/29.16  tff(decl_77274, type, 'foot of tube': $i).
% 29.32/29.16  tff(decl_77275, type, 'tube foot': $i).
% 29.32/29.16  tff(decl_77276, type, 'tube-foot': $i).
% 29.32/29.16  tff(decl_77277, type, 'Tuber': $i).
% 29.32/29.16  tff(decl_77278, type, 'A fleshy underground stem or root serving for reproductive and food storage': $i).
% 29.32/29.16  tff(decl_77279, type, tuber: $i).
% 29.32/29.16  tff(decl_77280, type, fn_tuber_1: $i > $i).
% 29.32/29.16  tff(decl_77281, type, fn_tuber_2: $i > $i).
% 29.32/29.16  tff(decl_77282, type, fn_tuber_3: $i > $i).
% 29.32/29.16  tff(decl_77283, type, 'Tuberculosis': $i).
% 29.32/29.16  tff(decl_77284, type, 'An infectious and highly contagious disease caused by the bacterium Mycobacterium tuberculosis. The disease usually attacks the lungs and is spread when an infected person sneezes or coughs. Drug-resistant tuberculosis is becoming a problem throughout the world.': $i).
% 29.32/29.16  tff(decl_77285, type, mtb: $i).
% 29.32/29.16  tff(decl_77286, type, consumption: $i).
% 29.32/29.16  tff(decl_77287, type, tuberculosis: $i).
% 29.32/29.16  tff(decl_77288, type, 'Tubule': $i).
% 29.32/29.16  tff(decl_77289, type, 'A small anatomical tube that is lined with glandular epithelium.': $i).
% 29.32/29.16  tff(decl_77290, type, tubule: $i).
% 29.32/29.16  tff(decl_77291, type, 'Tubulin': $i).
% 29.32/29.16  tff(decl_77292, type, 'Tubulin is a protein which serves as a building block of Microtubule': $i).
% 29.32/29.16  tff(decl_77293, type, 'tubulin dimer': $i).
% 29.32/29.16  tff(decl_77294, type, 'tubulin-dimer': $i).
% 29.32/29.16  tff(decl_77295, type, tubulin: $i).
% 29.32/29.16  tff(decl_77296, type, fn_tubulin_5: $i > $i).
% 29.32/29.16  tff(decl_77297, type, fn_tubulin_6: $i > $i).
% 29.32/29.16  tff(decl_77298, type, fn_tubulin_7: $i > $i).
% 29.32/29.16  tff(decl_77299, type, fn_tubulin_8: $i > $i).
% 29.32/29.16  tff(decl_77300, type, fn_tubulin_9: $i > $i).
% 29.32/29.16  tff(decl_77301, type, fn_tubulin_10: $i > $i).
% 29.32/29.16  tff(decl_77302, type, fn_tubulin_11: $i > $i).
% 29.32/29.16  tff(decl_77303, type, fn_tubulin_12: $i > $i).
% 29.32/29.16  tff(decl_77304, type, fn_tubulin_13: $i > $i).
% 29.32/29.16  tff(decl_77305, type, fn_tubulin_14: $i > $i).
% 29.32/29.16  tff(decl_77306, type, fn_tubulin_15: $i > $i).
% 29.32/29.16  tff(decl_77307, type, fn_tubulin_16: $i > $i).
% 29.32/29.16  tff(decl_77308, type, fn_tubulin_17: $i > $i).
% 29.32/29.16  tff(decl_77309, type, fn_tubulin_18: $i > $i).
% 29.32/29.16  tff(decl_77310, type, fn_tubulin_20: $i > $i).
% 29.32/29.16  tff(decl_77311, type, fn_tubulin_1: $i > $i).
% 29.32/29.16  tff(decl_77312, type, fn_tubulin_4: $i > $i).
% 29.32/29.16  tff(decl_77313, type, fn_tubulin_3: $i > $i).
% 29.32/29.16  tff(decl_77314, type, fn_tubulin_2: $i > $i).
% 29.32/29.16  tff(decl_77315, type, 'Tumor': $i).
% 29.32/29.16  tff(decl_77316, type, 'An abnormal mass of tissue as a result of neoplasia, the abnormal proliferation of cells.': $i).
% 29.32/29.16  tff(decl_77317, type, neoplasm: $i).
% 29.32/29.16  tff(decl_77318, type, tumor: $i).
% 29.32/29.16  tff(decl_77319, type, tumor_characterization_1: $i > $o).
% 29.32/29.16  tff(decl_77320, type, 'Tumor-Characterization': $i).
% 29.32/29.16  tff(decl_77321, type, 'Technique of clinical medicine which identifies tumor type and characteristics for more effective treatment.': $i).
% 29.32/29.16  tff(decl_77322, type, 'characterization of tumor': $i).
% 29.32/29.16  tff(decl_77323, type, 'tumor characterization': $i).
% 29.32/29.16  tff(decl_77324, type, 'tumor-characterization': $i).
% 29.32/29.16  tff(decl_77325, type, fn_tumor_characterization_1: $i > $i).
% 29.32/29.16  tff(decl_77326, type, fn_tumor_characterization_2: $i > $i).
% 29.32/29.16  tff(decl_77327, type, fn_tumor_characterization_3: $i > $i).
% 29.32/29.16  tff(decl_77328, type, fn_tumor_characterization_4: $i > $i).
% 29.32/29.16  tff(decl_77329, type, fn_tumor_characterization_5: $i > $i).
% 29.32/29.16  tff(decl_77330, type, fn_tumor_characterization_6: $i > $i).
% 29.32/29.16  tff(decl_77331, type, fn_tumor_characterization_7: $i > $i).
% 29.32/29.16  tff(decl_77332, type, fn_tumor_characterization_8: $i > $i).
% 29.32/29.16  tff(decl_77333, type, 'Tumor-Growth': $i).
% 29.32/29.16  tff(decl_77334, type, 'Uncontrolled cell division of cancerous cells, resulting in the growth of a tumor. Tumor growth often also includes growth of supporting tissues, such as blood vessels.': $i).
% 29.32/29.16  tff(decl_77335, type, 'growth of tumor': $i).
% 29.32/29.16  tff(decl_77336, type, 'tumor growth': $i).
% 29.32/29.16  tff(decl_77337, type, 'tumor-growth': $i).
% 29.32/29.16  tff(decl_77338, type, fn_tumor_growth_4: $i > $i).
% 29.32/29.16  tff(decl_77339, type, fn_tumor_growth_9: $i > $i).
% 29.32/29.16  tff(decl_77340, type, 'Tumor-Suppression': $i).
% 29.32/29.16  tff(decl_77341, type, 'Inhibition of uncontrolled cell growth that contributes to cancer by inhibiting cell division.': $i).
% 29.32/29.16  tff(decl_77342, type, 'suppression of tumor': $i).
% 29.32/29.16  tff(decl_77343, type, 'tumor suppression': $i).
% 29.32/29.16  tff(decl_77344, type, 'tumor-suppression': $i).
% 29.32/29.16  tff(decl_77345, type, 'Tumor-Suppressor-Gene': $i).
% 29.32/29.16  tff(decl_77346, type, 'Genes whose normal products inhibit cell division.': $i).
% 29.32/29.16  tff(decl_77347, type, 'tumor suppressor gene': $i).
% 29.32/29.16  tff(decl_77348, type, 'tumor-suppressor gene': $i).
% 29.32/29.16  tff(decl_77349, type, 'tumor-suppressor-gene': $i).
% 29.32/29.16  tff(decl_77350, type, fn_tumor_suppressor_gene_1: $i > $i).
% 29.32/29.16  tff(decl_77351, type, fn_tumor_suppressor_gene_2: $i > $i).
% 29.32/29.16  tff(decl_77352, type, fn_tumor_suppressor_gene_3: $i > $i).
% 29.32/29.16  tff(decl_77353, type, fn_tumor_suppressor_gene_4: $i > $i).
% 29.32/29.16  tff(decl_77354, type, fn_tumor_suppressor_gene_5: $i > $i).
% 29.32/29.16  tff(decl_77355, type, fn_tumor_suppressor_gene_6: $i > $i).
% 29.32/29.16  tff(decl_77356, type, fn_tumor_suppressor_gene_7: $i > $i).
% 29.32/29.16  tff(decl_77357, type, fn_tumor_suppressor_gene_8: $i > $i).
% 29.32/29.16  tff(decl_77358, type, fn_tumor_suppressor_gene_9: $i > $i).
% 29.32/29.16  tff(decl_77359, type, fn_tumor_suppressor_gene_10: $i > $i).
% 29.32/29.16  tff(decl_77360, type, fn_tumor_suppressor_gene_25: $i > $i).
% 29.32/29.16  tff(decl_77361, type, fn_tumor_suppressor_gene_26: $i > $i).
% 29.32/29.16  tff(decl_77362, type, fn_tumor_suppressor_gene_30: $i > $i).
% 29.32/29.16  tff(decl_77363, type, fn_tumor_suppressor_gene_31: $i > $i).
% 29.32/29.16  tff(decl_77364, type, 'Tumor-Virus': $i).
% 29.32/29.16  tff(decl_77365, type, 'Viruses that can cause tumors in animals.': $i).
% 29.32/29.16  tff(decl_77366, type, 'cancer virus': $i).
% 29.32/29.16  tff(decl_77367, type, 'virus associated with cancer': $i).
% 29.32/29.16  tff(decl_77368, type, 'virus of tumor': $i).
% 29.32/29.16  tff(decl_77369, type, 'tumor virus': $i).
% 29.32/29.16  tff(decl_77370, type, 'tumor-virus': $i).
% 29.32/29.16  tff(decl_77371, type, fn_tumor_virus_1: $i > $i).
% 29.32/29.16  tff(decl_77372, type, fn_tumor_virus_2: $i > $i).
% 29.32/29.16  tff(decl_77373, type, fn_tumor_virus_3: $i > $i).
% 29.32/29.16  tff(decl_77374, type, fn_tumor_virus_4: $i > $i).
% 29.32/29.16  tff(decl_77375, type, fn_tumor_virus_5: $i > $i).
% 29.32/29.16  tff(decl_77376, type, fn_tumor_virus_6: $i > $i).
% 29.32/29.16  tff(decl_77377, type, fn_tumor_virus_7: $i > $i).
% 29.32/29.16  tff(decl_77378, type, fn_tumor_virus_8: $i > $i).
% 29.32/29.16  tff(decl_77379, type, 'Tundra': $i).
% 29.32/29.16  tff(decl_77380, type, 'A biome where plant growth is limited because of low temperature and a short growing season. Arctic tundra occurs at extreme northern latitudes, and alpine tundra occurs at high altitudes.': $i).
% 29.32/29.16  tff(decl_77381, type, tundra: $i).
% 29.32/29.16  tff(decl_77382, type, fn_tundra_1: $i > $i).
% 29.32/29.16  tff(decl_77383, type, fn_tundra_2: $i > $i).
% 29.32/29.16  tff(decl_77384, type, fn_tundra_3: $i > $i).
% 29.32/29.16  tff(decl_77385, type, fn_tundra_4: $i > $i).
% 29.32/29.16  tff(decl_77386, type, fn_tundra_5: $i > $i).
% 29.32/29.16  tff(decl_77387, type, tungsten_1: $i > $o).
% 29.32/29.16  tff(decl_77388, type, 'Tungsten': $i).
% 29.32/29.16  tff(decl_77389, type, 'Tungsten is a metal atom with atomic number 74. It is represented by the symbol W.': $i).
% 29.32/29.16  tff(decl_77390, type, tungsten: $i).
% 29.32/29.16  tff(decl_77391, type, fn_tungsten_3: $i > $i).
% 29.32/29.16  tff(decl_77392, type, fn_tungsten_4: $i > $i).
% 29.32/29.16  tff(decl_77393, type, fn_tungsten_5: $i > $i).
% 29.32/29.16  tff(decl_77394, type, fn_tungsten_9: $i > $i).
% 29.32/29.16  tff(decl_77395, type, fn_tungsten_10: $i > $i).
% 29.32/29.16  tff(decl_77396, type, fn_tungsten_11: $i > $i).
% 29.32/29.16  tff(decl_77397, type, fn_tungsten_12: $i > $i).
% 29.32/29.16  tff(decl_77398, type, "2.36": $i).
% 29.32/29.16  tff(decl_77399, type, "184": $i).
% 29.32/29.16  tff(decl_77400, type, "183.8": $i).
% 29.32/29.16  tff(decl_77401, type, fn_tungsten_7: $i > $i).
% 29.32/29.16  tff(decl_77402, type, fn_tungsten_8: $i > $i).
% 29.32/29.16  tff(decl_77403, type, fn_tungsten_6: $i > $i).
% 29.32/29.16  tff(decl_77404, type, 'Tunicate': $i).
% 29.32/29.16  tff(decl_77405, type, 'A benthic member of the subphylum Urochordata, commonly called a sea squirt. Tunicates are sessile marine organisms whose bodies are covered in a saclike tunic.': $i).
% 29.32/29.16  tff(decl_77406, type, tunicate: $i).
% 29.32/29.16  tff(decl_77407, type, 'Turbellarian': $i).
% 29.32/29.16  tff(decl_77408, type, 'A member of the platyhelminth class Turbellaria, consisting of free-living marine and freshwater flatworms.': $i).
% 29.32/29.16  tff(decl_77409, type, turbellarian: $i).
% 29.32/29.16  tff(decl_77410, type, turgid_1: $i > $o).
% 29.32/29.16  tff(decl_77411, type, 'Turgid': $i).
% 29.32/29.16  tff(decl_77412, type, 'Swollen, or filled with fluid. A plant cell is said to be turgid if osmotic conditions cause water to enter the cell and cause it to swell.': $i).
% 29.32/29.16  tff(decl_77413, type, turgid: $i).
% 29.32/29.16  tff(decl_77414, type, 'Turgid-Cell': $i).
% 29.32/29.16  tff(decl_77415, type, 'A turgid cell is a walled cell which has high turgor pressure due to osmosis and is rigid and firm. This is the healthy state for most walled cells.': $i).
% 29.32/29.16  tff(decl_77416, type, 'swollen cell': $i).
% 29.32/29.16  tff(decl_77417, type, 'swollen-cell': $i).
% 29.32/29.16  tff(decl_77418, type, 'turgid cell': $i).
% 29.32/29.16  tff(decl_77419, type, 'turgid-cell': $i).
% 29.32/29.16  tff(decl_77420, type, fn_turgid_cell_5: $i > $i).
% 29.32/29.16  tff(decl_77421, type, fn_turgid_cell_7: $i > $i).
% 29.32/29.16  tff(decl_77422, type, fn_turgid_cell_8: $i > $i).
% 29.32/29.16  tff(decl_77423, type, fn_turgid_cell_9: $i > $i).
% 29.32/29.16  tff(decl_77424, type, fn_turgid_cell_14: $i > $i).
% 29.32/29.16  tff(decl_77425, type, fn_turgid_cell_15: $i > $i).
% 29.32/29.16  tff(decl_77426, type, fn_turgid_cell_16: $i > $i).
% 29.32/29.16  tff(decl_77427, type, fn_turgid_cell_17: $i > $i).
% 29.32/29.16  tff(decl_77428, type, fn_turgid_cell_18: $i > $i).
% 29.32/29.16  tff(decl_77429, type, fn_turgid_cell_19: $i > $i).
% 29.32/29.16  tff(decl_77430, type, fn_turgid_cell_20: $i > $i).
% 29.32/29.16  tff(decl_77431, type, fn_turgid_cell_21: $i > $i).
% 29.32/29.16  tff(decl_77432, type, fn_turgid_cell_22: $i > $i).
% 29.32/29.16  tff(decl_77433, type, fn_turgid_cell_24: $i > $i).
% 29.32/29.16  tff(decl_77434, type, fn_turgid_cell_25: $i > $i).
% 29.32/29.16  tff(decl_77435, type, fn_turgid_cell_26: $i > $i).
% 29.32/29.16  tff(decl_77436, type, fn_turgid_cell_27: $i > $i).
% 29.32/29.16  tff(decl_77437, type, fn_turgid_cell_31: $i > $i).
% 29.32/29.16  tff(decl_77438, type, fn_turgid_cell_32: $i > $i).
% 29.32/29.16  tff(decl_77439, type, fn_turgid_cell_33: $i > $i).
% 29.32/29.16  tff(decl_77440, type, fn_turgid_cell_34: $i > $i).
% 29.32/29.16  tff(decl_77441, type, fn_turgid_cell_35: $i > $i).
% 29.32/29.16  tff(decl_77442, type, fn_turgid_cell_36: $i > $i).
% 29.32/29.16  tff(decl_77443, type, fn_turgid_cell_37: $i > $i).
% 29.32/29.16  tff(decl_77444, type, fn_turgid_cell_38: $i > $i).
% 29.32/29.16  tff(decl_77445, type, fn_turgid_cell_39: $i > $i).
% 29.32/29.16  tff(decl_77446, type, fn_turgid_cell_40: $i > $i).
% 29.32/29.16  tff(decl_77447, type, fn_turgid_cell_41: $i > $i).
% 29.32/29.16  tff(decl_77448, type, fn_turgid_cell_47: $i > $i).
% 29.32/29.16  tff(decl_77449, type, fn_turgid_cell_48: $i > $i).
% 29.32/29.16  tff(decl_77450, type, fn_turgid_cell_49: $i > $i).
% 29.32/29.16  tff(decl_77451, type, fn_turgid_cell_50: $i > $i).
% 29.32/29.16  tff(decl_77452, type, fn_turgid_cell_51: $i > $i).
% 29.32/29.16  tff(decl_77453, type, fn_turgid_cell_52: $i > $i).
% 29.32/29.16  tff(decl_77454, type, fn_turgid_cell_53: $i > $i).
% 29.32/29.16  tff(decl_77455, type, fn_turgid_cell_54: $i > $i).
% 29.32/29.16  tff(decl_77456, type, fn_turgid_cell_55: $i > $i).
% 29.32/29.16  tff(decl_77457, type, fn_turgid_cell_56: $i > $i).
% 29.32/29.16  tff(decl_77458, type, fn_turgid_cell_57: $i > $i).
% 29.32/29.16  tff(decl_77459, type, fn_turgid_cell_58: $i > $i).
% 29.32/29.16  tff(decl_77460, type, fn_turgid_cell_59: $i > $i).
% 29.32/29.16  tff(decl_77461, type, fn_turgid_cell_60: $i > $i).
% 29.32/29.16  tff(decl_77462, type, fn_turgid_cell_61: $i > $i).
% 29.32/29.16  tff(decl_77463, type, fn_turgid_cell_62: $i > $i).
% 29.32/29.16  tff(decl_77464, type, fn_turgid_cell_63: $i > $i).
% 29.32/29.16  tff(decl_77465, type, fn_turgid_cell_64: $i > $i).
% 29.32/29.16  tff(decl_77466, type, fn_turgid_cell_65: $i > $i).
% 29.32/29.16  tff(decl_77467, type, fn_turgid_cell_66: $i > $i).
% 29.32/29.16  tff(decl_77468, type, fn_turgid_cell_68: $i > $i).
% 29.32/29.16  tff(decl_77469, type, fn_turgid_cell_69: $i > $i).
% 29.32/29.16  tff(decl_77470, type, fn_turgid_cell_70: $i > $i).
% 29.32/29.16  tff(decl_77471, type, fn_turgid_cell_71: $i > $i).
% 29.32/29.16  tff(decl_77472, type, fn_turgid_cell_72: $i > $i).
% 29.32/29.16  tff(decl_77473, type, fn_turgid_cell_76: $i > $i).
% 29.32/29.16  tff(decl_77474, type, fn_turgid_cell_78: $i > $i).
% 29.32/29.16  tff(decl_77475, type, fn_turgid_cell_80: $i > $i).
% 29.32/29.16  tff(decl_77476, type, fn_turgid_cell_81: $i > $i).
% 29.32/29.16  tff(decl_77477, type, fn_turgid_cell_82: $i > $i).
% 29.32/29.16  tff(decl_77478, type, fn_turgid_cell_83: $i > $i).
% 29.32/29.16  tff(decl_77479, type, fn_turgid_cell_84: $i > $i).
% 29.32/29.16  tff(decl_77480, type, fn_turgid_cell_85: $i > $i).
% 29.32/29.16  tff(decl_77481, type, fn_turgid_cell_86: $i > $i).
% 29.32/29.16  tff(decl_77482, type, fn_turgid_cell_87: $i > $i).
% 29.32/29.16  tff(decl_77483, type, fn_turgid_cell_88: $i > $i).
% 29.32/29.16  tff(decl_77484, type, fn_turgid_cell_89: $i > $i).
% 29.32/29.16  tff(decl_77485, type, fn_turgid_cell_90: $i > $i).
% 29.32/29.16  tff(decl_77486, type, fn_turgid_cell_91: $i > $i).
% 29.32/29.16  tff(decl_77487, type, fn_turgid_cell_92: $i > $i).
% 29.32/29.16  tff(decl_77488, type, fn_turgid_cell_93: $i > $i).
% 29.32/29.16  tff(decl_77489, type, fn_turgid_cell_94: $i > $i).
% 29.32/29.16  tff(decl_77490, type, fn_turgid_cell_95: $i > $i).
% 29.32/29.16  tff(decl_77491, type, fn_turgid_cell_96: $i > $i).
% 29.32/29.16  tff(decl_77492, type, fn_turgid_cell_97: $i > $i).
% 29.32/29.16  tff(decl_77493, type, fn_turgid_cell_98: $i > $i).
% 29.32/29.16  tff(decl_77494, type, fn_turgid_cell_99: $i > $i).
% 29.32/29.16  tff(decl_77495, type, fn_turgid_cell_100: $i > $i).
% 29.32/29.16  tff(decl_77496, type, fn_turgid_cell_101: $i > $i).
% 29.32/29.16  tff(decl_77497, type, fn_turgid_cell_102: $i > $i).
% 29.32/29.16  tff(decl_77498, type, fn_turgid_cell_103: $i > $i).
% 29.32/29.16  tff(decl_77499, type, fn_turgid_cell_104: $i > $i).
% 29.32/29.16  tff(decl_77500, type, fn_concentration_gradient_2: $i > $i).
% 29.32/29.16  tff(decl_77501, type, fn_turgid_cell_73: $i > $i).
% 29.32/29.16  tff(decl_77502, type, fn_turgid_cell_46: $i > $i).
% 29.32/29.16  tff(decl_77503, type, fn_turgid_cell_105: $i > $i).
% 29.32/29.16  tff(decl_77504, type, fn_turgid_cell_106: $i > $i).
% 29.32/29.16  tff(decl_77505, type, fn_turgid_cell_44: $i > $i).
% 29.32/29.16  tff(decl_77506, type, fn_turgid_cell_45: $i > $i).
% 29.32/29.16  tff(decl_77507, type, fn_turgid_cell_43: $i > $i).
% 29.32/29.16  tff(decl_77508, type, fn_turgid_cell_79: $i > $i).
% 29.32/29.16  tff(decl_77509, type, fn_turgid_cell_42: $i > $i).
% 29.32/29.16  tff(decl_77510, type, fn_turgid_cell_77: $i > $i).
% 29.32/29.16  tff(decl_77511, type, fn_turgid_cell_29: $i > $i).
% 29.32/29.16  tff(decl_77512, type, fn_turgid_cell_30: $i > $i).
% 29.32/29.16  tff(decl_77513, type, 'Turgor-Pressure': $i).
% 29.32/29.16  tff(decl_77514, type, 'Turgor Pressure is the pressure of the cell contents against the cell wall in plant cells.': $i).
% 29.32/29.16  tff(decl_77515, type, turgidity: $i).
% 29.32/29.16  tff(decl_77516, type, 'pressure of turgor': $i).
% 29.32/29.16  tff(decl_77517, type, 'turgor pressure': $i).
% 29.32/29.16  tff(decl_77518, type, 'turgor-pressure': $i).
% 29.32/29.16  tff(decl_77519, type, 'Turner-Syndrome': $i).
% 29.32/29.16  tff(decl_77520, type, 'a chromosomal abnormality in which all or part of one of the sex chromosomes is absent.  Also refered to as Monosomy X.': $i).
% 29.32/29.16  tff(decl_77521, type, xo: $i).
% 29.32/29.16  tff(decl_77522, type, 'syndrome of turner': $i).
% 29.32/29.16  tff(decl_77523, type, 'turner syndrome': $i).
% 29.32/29.16  tff(decl_77524, type, 'turner-syndrome': $i).
% 29.32/29.16  tff(decl_77525, type, fn_turner_syndrome_2: $i > $i).
% 29.32/29.16  tff(decl_77526, type, fn_turner_syndrome_3: $i > $i).
% 29.32/29.16  tff(decl_77527, type, fn_turner_syndrome_5: $i > $i).
% 29.32/29.16  tff(decl_77528, type, fn_turner_syndrome_6: $i > $i).
% 29.32/29.16  tff(decl_77529, type, fn_turner_syndrome_7: $i > $i).
% 29.32/29.16  tff(decl_77530, type, fn_turner_syndrome_8: $i > $i).
% 29.32/29.16  tff(decl_77531, type, turnover_1: $i > $o).
% 29.32/29.16  tff(decl_77532, type, 'Turnover': $i).
% 29.32/29.16  tff(decl_77533, type, 'Vertical mixing of water in a lake, which occurs when surface water cools, becomes dense, and sinks.': $i).
% 29.32/29.16  tff(decl_77534, type, 'turn over': $i).
% 29.32/29.16  tff(decl_77535, type, turnover: $i).
% 29.32/29.16  tff(decl_77536, type, twenty_letter_amino_acid_code_1: $i > $o).
% 29.32/29.16  tff(decl_77537, type, 'Twenty-Letter-Amino-Acid-Code': $i).
% 29.32/29.16  tff(decl_77538, type, 'The code used to refer to amino acids which provides short names (one to three letters) for each amino acid.': $i).
% 29.32/29.16  tff(decl_77539, type, 'twenty letter amino acid code': $i).
% 29.32/29.16  tff(decl_77540, type, 'twenty-letter-amino-acid-code': $i).
% 29.32/29.16  tff(decl_77541, type, twin_study_1: $i > $o).
% 29.32/29.16  tff(decl_77542, type, 'Twin-Study': $i).
% 29.32/29.16  tff(decl_77543, type, 'A study that compares identical twins reared apart, to investigate the effects of genetics and environment on behavior and other traits.': $i).
% 29.32/29.16  tff(decl_77544, type, 'study of twin': $i).
% 29.32/29.16  tff(decl_77545, type, 'twin study': $i).
% 29.32/29.16  tff(decl_77546, type, 'twin-study': $i).
% 29.32/29.16  tff(decl_77547, type, 'Twist': $i).
% 29.32/29.16  tff(decl_77548, type, 'The act of object being exerted pressure to modify itself or distort its shape.': $i).
% 29.32/29.16  tff(decl_77549, type, twist: $i).
% 29.32/29.16  tff(decl_77550, type, fn_twist_1: $i > $i).
% 29.32/29.16  tff(decl_77551, type, 'Two-Cell-Embryo': $i).
% 29.32/29.16  tff(decl_77552, type, 'An embryo that has divided into two cells is called a two cell embryo.': $i).
% 29.32/29.16  tff(decl_77553, type, 'two cell embryo': $i).
% 29.32/29.16  tff(decl_77554, type, 'two-cell-embryo': $i).
% 29.32/29.16  tff(decl_77555, type, fn_two_cell_embryo_1: $i > $i).
% 29.32/29.16  tff(decl_77556, type, 'Two-Cell-Stage': $i).
% 29.32/29.16  tff(decl_77557, type, 'The developmental stage of an organism where the embryo has divided into two cells is called a two cell stage.': $i).
% 29.32/29.16  tff(decl_77558, type, 'undergo the two cell stage': $i).
% 29.32/29.16  tff(decl_77559, type, 'two cell stage': $i).
% 29.32/29.16  tff(decl_77560, type, 'two-cell-stage': $i).
% 29.32/29.16  tff(decl_77561, type, fn_two_cell_stage_2: $i > $i).
% 29.32/29.16  tff(decl_77562, type, 'Two-Phosphoglycerate': $i).
% 29.32/29.16  tff(decl_77563, type, 'In glycolysis, during energy payoff phase 2-phosphoglycerate is formed from 3-phosphoglycerate.': $i).
% 29.32/29.16  tff(decl_77564, type, '2 phosphoglycerate': $i).
% 29.32/29.16  tff(decl_77565, type, '2-phosphoglycerate': $i).
% 29.32/29.16  tff(decl_77566, type, '2 phosphoglyceric acid': $i).
% 29.32/29.16  tff(decl_77567, type, '2-phosphoglyceric-acid': $i).
% 29.32/29.16  tff(decl_77568, type, '2pg': $i).
% 29.32/29.16  tff(decl_77569, type, 'glyceral 2 phosphate': $i).
% 29.32/29.16  tff(decl_77570, type, 'glyceral-2-phosphate': $i).
% 29.32/29.16  tff(decl_77571, type, 'two phosphoglycerate': $i).
% 29.32/29.16  tff(decl_77572, type, 'two-phosphoglycerate': $i).
% 29.32/29.16  tff(decl_77573, type, tympanic_membrane_1: $i > $o).
% 29.32/29.16  tff(decl_77574, type, 'Tympanic-Membrane': $i).
% 29.32/29.16  tff(decl_77575, type, 'The eardrum; a membrane that separates the outer and middle portions of the ear.': $i).
% 29.32/29.16  tff(decl_77576, type, 'ear drum': $i).
% 29.32/29.16  tff(decl_77577, type, 'ear-drum': $i).
% 29.32/29.16  tff(decl_77578, type, 'tympanic membrane': $i).
% 29.32/29.16  tff(decl_77579, type, 'tympanic-membrane': $i).
% 29.32/29.16  tff(decl_77580, type, 'Type-1-Diabetes-Mellitus': $i).
% 29.32/29.16  tff(decl_77581, type, 'A form of diabetes that is caused by an autoimmune attack on the insulin-secreting cells of the pancreas.': $i).
% 29.32/29.16  tff(decl_77582, type, 'type 1 diabetes mellitus': $i).
% 29.32/29.16  tff(decl_77583, type, 'type-1-diabetes-mellitus': $i).
% 29.32/29.16  tff(decl_77584, type, type_2_diabetes_mellitus_1: $i > $o).
% 29.32/29.16  tff(decl_77585, type, type_3_diabetes_mellitus_1: $i > $o).
% 29.32/29.16  tff(decl_77586, type, 'Type-2-Diabetes-Mellitus': $i).
% 29.32/29.16  tff(decl_77587, type, 'A form of diabetes that is caused by lifestyle factors such as obesity and diet.': $i).
% 29.32/29.16  tff(decl_77588, type, 'type 2 diabetes mellitus': $i).
% 29.32/29.16  tff(decl_77589, type, 'type-2-diabetes-mellitus': $i).
% 29.32/29.16  tff(decl_77590, type, 'Type-3-Diabetes-Mellitus': $i).
% 29.32/29.16  tff(decl_77591, type, 'A form of diabetes that occurs in pregnancy, also known as gestational diabetes.': $i).
% 29.32/29.16  tff(decl_77592, type, 'type 3 diabetes mellitus': $i).
% 29.32/29.16  tff(decl_77593, type, 'type-3-diabetes-mellitus': $i).
% 29.32/29.16  tff(decl_77594, type, 'Tyrosine': $i).
% 29.32/29.16  tff(decl_77595, type, tyr: $i).
% 29.32/29.16  tff(decl_77596, type, tyrosine: $i).
% 29.32/29.16  tff(decl_77597, type, fn_tyrosine_3: $i > $i).
% 29.32/29.16  tff(decl_77598, type, fn_tyrosine_4: $i > $i).
% 29.32/29.16  tff(decl_77599, type, fn_tyrosine_5: $i > $i).
% 29.32/29.16  tff(decl_77600, type, fn_tyrosine_6: $i > $i).
% 29.32/29.16  tff(decl_77601, type, fn_tyrosine_7: $i > $i).
% 29.32/29.16  tff(decl_77602, type, fn_tyrosine_8: $i > $i).
% 29.32/29.16  tff(decl_77603, type, fn_tyrosine_9: $i > $i).
% 29.32/29.16  tff(decl_77604, type, fn_tyrosine_10: $i > $i).
% 29.32/29.16  tff(decl_77605, type, fn_tyrosine_11: $i > $i).
% 29.32/29.16  tff(decl_77606, type, fn_tyrosine_12: $i > $i).
% 29.32/29.16  tff(decl_77607, type, fn_tyrosine_13: $i > $i).
% 29.32/29.16  tff(decl_77608, type, fn_tyrosine_14: $i > $i).
% 29.32/29.16  tff(decl_77609, type, fn_tyrosine_15: $i > $i).
% 29.32/29.16  tff(decl_77610, type, fn_tyrosine_16: $i > $i).
% 29.32/29.16  tff(decl_77611, type, fn_tyrosine_17: $i > $i).
% 29.32/29.16  tff(decl_77612, type, fn_tyrosine_18: $i > $i).
% 29.32/29.16  tff(decl_77613, type, fn_tyrosine_19: $i > $i).
% 29.32/29.16  tff(decl_77614, type, fn_tyrosine_20: $i > $i).
% 29.32/29.16  tff(decl_77615, type, fn_tyrosine_21: $i > $i).
% 29.32/29.16  tff(decl_77616, type, fn_tyrosine_22: $i > $i).
% 29.32/29.16  tff(decl_77617, type, fn_tyrosine_23: $i > $i).
% 29.32/29.16  tff(decl_77618, type, fn_tyrosine_24: $i > $i).
% 29.32/29.16  tff(decl_77619, type, fn_tyrosine_25: $i > $i).
% 29.32/29.16  tff(decl_77620, type, fn_tyrosine_26: $i > $i).
% 29.32/29.16  tff(decl_77621, type, fn_tyrosine_27: $i > $i).
% 29.32/29.16  tff(decl_77622, type, fn_tyrosine_28: $i > $i).
% 29.32/29.16  tff(decl_77623, type, fn_tyrosine_29: $i > $i).
% 29.32/29.16  tff(decl_77624, type, fn_tyrosine_30: $i > $i).
% 29.32/29.16  tff(decl_77625, type, fn_tyrosine_31: $i > $i).
% 29.32/29.16  tff(decl_77626, type, fn_tyrosine_32: $i > $i).
% 29.32/29.16  tff(decl_77627, type, fn_tyrosine_33: $i > $i).
% 29.32/29.16  tff(decl_77628, type, fn_tyrosine_34: $i > $i).
% 29.32/29.16  tff(decl_77629, type, fn_tyrosine_35: $i > $i).
% 29.32/29.16  tff(decl_77630, type, fn_tyrosine_36: $i > $i).
% 29.32/29.16  tff(decl_77631, type, fn_tyrosine_37: $i > $i).
% 29.32/29.16  tff(decl_77632, type, fn_tyrosine_38: $i > $i).
% 29.32/29.16  tff(decl_77633, type, fn_tyrosine_39: $i > $i).
% 29.32/29.16  tff(decl_77634, type, fn_tyrosine_40: $i > $i).
% 29.32/29.16  tff(decl_77635, type, fn_tyrosine_41: $i > $i).
% 29.32/29.16  tff(decl_77636, type, fn_tyrosine_42: $i > $i).
% 29.32/29.16  tff(decl_77637, type, fn_tyrosine_43: $i > $i).
% 29.32/29.16  tff(decl_77638, type, fn_tyrosine_44: $i > $i).
% 29.32/29.16  tff(decl_77639, type, fn_tyrosine_45: $i > $i).
% 29.32/29.16  tff(decl_77640, type, fn_tyrosine_46: $i > $i).
% 29.32/29.16  tff(decl_77641, type, fn_tyrosine_47: $i > $i).
% 29.32/29.16  tff(decl_77642, type, fn_tyrosine_48: $i > $i).
% 29.32/29.16  tff(decl_77643, type, fn_tyrosine_49: $i > $i).
% 29.32/29.16  tff(decl_77644, type, fn_tyrosine_50: $i > $i).
% 29.32/29.16  tff(decl_77645, type, fn_tyrosine_52: $i > $i).
% 29.32/29.16  tff(decl_77646, type, fn_tyrosine_53: $i > $i).
% 29.32/29.16  tff(decl_77647, type, fn_tyrosine_54: $i > $i).
% 29.32/29.16  tff(decl_77648, type, fn_tyrosine_55: $i > $i).
% 29.32/29.16  tff(decl_77649, type, fn_tyrosine_56: $i > $i).
% 29.32/29.16  tff(decl_77650, type, fn_tyrosine_57: $i > $i).
% 29.32/29.16  tff(decl_77651, type, fn_tyrosine_58: $i > $i).
% 29.32/29.16  tff(decl_77652, type, fn_tyrosine_59: $i > $i).
% 29.32/29.16  tff(decl_77653, type, fn_tyrosine_51: $i > $i).
% 29.32/29.16  tff(decl_77654, type, fn_tyrosine_61: $i > $i).
% 29.32/29.16  tff(decl_77655, type, fn_tyrosine_60: $i > $i).
% 29.32/29.16  tff(decl_77656, type, 'Tyrosine-Kinase': $i).
% 29.32/29.16  tff(decl_77657, type, 'Enzyme which transfers a phosphate group from ATP to a protein.': $i).
% 29.32/29.16  tff(decl_77658, type, 'kinase of tyrosine': $i).
% 29.32/29.16  tff(decl_77659, type, 'tyrosine kinase': $i).
% 29.32/29.16  tff(decl_77660, type, 'tyrosine-kinase': $i).
% 29.32/29.16  tff(decl_77661, type, fn_tyrosine_kinase_1: $i > $i).
% 29.32/29.16  tff(decl_77662, type, fn_tyrosine_kinase_2: $i > $i).
% 29.32/29.16  tff(decl_77663, type, fn_tyrosine_kinase_3: $i > $i).
% 29.32/29.16  tff(decl_77664, type, fn_tyrosine_kinase_4: $i > $i).
% 29.32/29.16  tff(decl_77665, type, fn_tyrosine_kinase_5: $i > $i).
% 29.32/29.16  tff(decl_77666, type, fn_tyrosine_kinase_6: $i > $i).
% 29.32/29.16  tff(decl_77667, type, fn_tyrosine_kinase_7: $i > $i).
% 29.32/29.16  tff(decl_77668, type, fn_tyrosine_kinase_8: $i > $i).
% 29.32/29.16  tff(decl_77669, type, uaa_1: $i > $o).
% 29.32/29.16  tff(decl_77670, type, 'UAA': $i).
% 29.32/29.16  tff(decl_77671, type, 'A stop codon.': $i).
% 29.32/29.16  tff(decl_77672, type, uaa: $i).
% 29.32/29.16  tff(decl_77673, type, uag_1: $i > $o).
% 29.32/29.16  tff(decl_77674, type, 'UAG': $i).
% 29.32/29.16  tff(decl_77675, type, uag: $i).
% 29.32/29.16  tff(decl_77676, type, 'Ubiquinone': $i).
% 29.32/29.16  tff(decl_77677, type, 'A quinone compound that serves as an electron carrier between flavoproteins and in cellular respiration.': $i).
% 29.32/29.16  tff(decl_77678, type, coq: $i).
% 29.32/29.16  tff(decl_77679, type, 'coenzyme q': $i).
% 29.32/29.16  tff(decl_77680, type, ubiquinone: $i).
% 29.32/29.16  tff(decl_77681, type, fn_ubiquinone_1: $i > $i).
% 29.32/29.16  tff(decl_77682, type, fn_ubiquinone_2: $i > $i).
% 29.32/29.16  tff(decl_77683, type, 'Ubiquitin': $i).
% 29.32/29.16  tff(decl_77684, type, 'Ubiquitin is a small regulatory protein that has been found in almost all tissues of eukaryotic organisms.': $i).
% 29.32/29.16  tff(decl_77685, type, ubiquitin: $i).
% 29.32/29.16  tff(decl_77686, type, fn_ubiquitin_8: $i > $i).
% 29.32/29.16  tff(decl_77687, type, fn_ubiquitin_9: $i > $i).
% 29.32/29.16  tff(decl_77688, type, fn_ubiquitin_10: $i > $i).
% 29.32/29.16  tff(decl_77689, type, fn_ubiquitin_11: $i > $i).
% 29.32/29.16  tff(decl_77690, type, fn_ubiquitin_12: $i > $i).
% 29.32/29.16  tff(decl_77691, type, fn_ubiquitin_13: $i > $i).
% 29.32/29.16  tff(decl_77692, type, fn_ubiquitin_14: $i > $i).
% 29.32/29.16  tff(decl_77693, type, fn_ubiquitin_15: $i > $i).
% 29.32/29.16  tff(decl_77694, type, fn_ubiquitin_16: $i > $i).
% 29.32/29.16  tff(decl_77695, type, fn_ubiquitin_17: $i > $i).
% 29.32/29.16  tff(decl_77696, type, fn_ubiquitin_18: $i > $i).
% 29.32/29.16  tff(decl_77697, type, fn_ubiquitin_19: $i > $i).
% 29.32/29.16  tff(decl_77698, type, fn_ubiquitin_20: $i > $i).
% 29.32/29.16  tff(decl_77699, type, fn_ubiquitin_21: $i > $i).
% 29.32/29.16  tff(decl_77700, type, fn_ubiquitin_22: $i > $i).
% 29.32/29.16  tff(decl_77701, type, fn_ubiquitin_26: $i > $i).
% 29.32/29.16  tff(decl_77702, type, fn_ubiquitin_24: $i > $i).
% 29.32/29.16  tff(decl_77703, type, fn_ubiquitin_25: $i > $i).
% 29.32/29.16  tff(decl_77704, type, fn_ubiquitin_23: $i > $i).
% 29.32/29.16  tff(decl_77705, type, ubiquitin_conjugating_enzyme_1: $i > $o).
% 29.32/29.16  tff(decl_77706, type, 'Ubiquitin-Conjugating-Enzyme': $i).
% 29.32/29.16  tff(decl_77707, type, 'An enzyme that attaches molecules of a small protein called ubiquitin to proteins to mark them for degradation.': $i).
% 29.32/29.16  tff(decl_77708, type, 'e2 enzymes': $i).
% 29.32/29.16  tff(decl_77709, type, 'e2-enzymes': $i).
% 29.32/29.16  tff(decl_77710, type, 'ubiquitin carrier enzymes': $i).
% 29.32/29.16  tff(decl_77711, type, 'ubiquitin-carrier-enzymes': $i).
% 29.32/29.16  tff(decl_77712, type, 'ubiquitin conjugating enzyme': $i).
% 29.32/29.16  tff(decl_77713, type, 'ubiquitin-conjugating-enzyme': $i).
% 29.32/29.16  tff(decl_77714, type, fn_ubiquitin_conjugating_enzyme_1: $i > $i).
% 29.32/29.16  tff(decl_77715, type, fn_ubiquitin_conjugating_enzyme_2: $i > $i).
% 29.32/29.16  tff(decl_77716, type, fn_ubiquitin_conjugating_enzyme_3: $i > $i).
% 29.32/29.16  tff(decl_77717, type, fn_ubiquitin_conjugating_enzyme_4: $i > $i).
% 29.32/29.16  tff(decl_77718, type, fn_ubiquitin_conjugating_enzyme_5: $i > $i).
% 29.32/29.16  tff(decl_77719, type, fn_ubiquitin_conjugating_enzyme_6: $i > $i).
% 29.32/29.16  tff(decl_77720, type, fn_ubiquitin_conjugating_enzyme_7: $i > $i).
% 29.32/29.16  tff(decl_77721, type, fn_ubiquitin_conjugating_enzyme_8: $i > $i).
% 29.32/29.16  tff(decl_77722, type, fn_ubiquitin_conjugating_enzyme_9: $i > $i).
% 29.32/29.16  tff(decl_77723, type, fn_ubiquitin_conjugating_enzyme_10: $i > $i).
% 29.32/29.16  tff(decl_77724, type, fn_ubiquitin_conjugating_enzyme_11: $i > $i).
% 29.32/29.16  tff(decl_77725, type, fn_ubiquitin_conjugating_enzyme_12: $i > $i).
% 29.32/29.16  tff(decl_77726, type, fn_ubiquitin_conjugating_enzyme_13: $i > $i).
% 29.32/29.16  tff(decl_77727, type, fn_ubiquitin_conjugating_enzyme_14: $i > $i).
% 29.32/29.16  tff(decl_77728, type, fn_ubiquitin_conjugating_enzyme_15: $i > $i).
% 29.32/29.16  tff(decl_77729, type, fn_ubiquitin_conjugating_enzyme_16: $i > $i).
% 29.32/29.16  tff(decl_77730, type, fn_ubiquitin_conjugating_enzyme_17: $i > $i).
% 29.32/29.16  tff(decl_77731, type, fn_ubiquitin_conjugating_enzyme_18: $i > $i).
% 29.32/29.16  tff(decl_77732, type, fn_ubiquitin_conjugating_enzyme_19: $i > $i).
% 29.32/29.16  tff(decl_77733, type, fn_ubiquitin_conjugating_enzyme_20: $i > $i).
% 29.32/29.16  tff(decl_77734, type, fn_ubiquitin_conjugating_enzyme_21: $i > $i).
% 29.32/29.16  tff(decl_77735, type, fn_ubiquitin_conjugating_enzyme_22: $i > $i).
% 29.32/29.16  tff(decl_77736, type, fn_ubiquitin_conjugating_enzyme_23: $i > $i).
% 29.32/29.16  tff(decl_77737, type, 'Udder': $i).
% 29.32/29.16  tff(decl_77738, type, 'An udder is an organ formed of the mammary glands of female quadruped mammals, especially ruminants such as cattle, goats, sheep and deer.': $i).
% 29.32/29.16  tff(decl_77739, type, udder: $i).
% 29.32/29.16  tff(decl_77740, type, 'UGA': $i).
% 29.32/29.16  tff(decl_77741, type, uga: $i).
% 29.32/29.16  tff(decl_77742, type, 'Ultrametric-Tree': $i).
% 29.32/29.16  tff(decl_77743, type, 'A tree with equal root-to-tip path lengths for all lineages, for example one built with the assumption of a molecular clock.': $i).
% 29.32/29.16  tff(decl_77744, type, 'ultrametric tree': $i).
% 29.32/29.16  tff(decl_77745, type, 'ultrametric-tree': $i).
% 29.32/29.16  tff(decl_77746, type, 'Ultrasound-Imaging': $i).
% 29.32/29.16  tff(decl_77747, type, 'The use of high-frequency sound waves to visualize soft tissues such as muscles and internal organs.': $i).
% 29.32/29.16  tff(decl_77748, type, 'imaging of ultrasound': $i).
% 29.32/29.16  tff(decl_77749, type, 'ultrasound imaging': $i).
% 29.32/29.16  tff(decl_77750, type, 'ultrasound-imaging': $i).
% 29.32/29.16  tff(decl_77751, type, 'Ultraviolet-Rays': $i).
% 29.32/29.16  tff(decl_77752, type, 'Electromagnetic radiation with a wavelength shorter than that of visible light, but longer than x-rays.': $i).
% 29.32/29.16  tff(decl_77753, type, 'ultraviolet ray': $i).
% 29.32/29.16  tff(decl_77754, type, 'ultraviolet-ray': $i).
% 29.32/29.16  tff(decl_77755, type, fn_ultraviolet_rays_3: $i > $i).
% 29.32/29.16  tff(decl_77756, type, fn_ultraviolet_rays_4: $i > $i).
% 29.32/29.16  tff(decl_77757, type, fn_ultraviolet_rays_7: $i > $i).
% 29.32/29.16  tff(decl_77758, type, "380.0e0": $i).
% 29.32/29.16  tff(decl_77759, type, fn_ultraviolet_rays_6: $i > $i).
% 29.32/29.16  tff(decl_77760, type, 'Unauthorized': $i).
% 29.32/29.16  tff(decl_77761, type, unauthorized: $i).
% 29.32/29.16  tff(decl_77762, type, unauthorised: $i).
% 29.32/29.16  tff(decl_77763, type, wildcat: $i).
% 29.32/29.16  tff(decl_77764, type, 'Unblock': $i).
% 29.32/29.16  tff(decl_77765, type, unblock: $i).
% 29.32/29.16  tff(decl_77766, type, 'Uncoupling-Protein': $i).
% 29.32/29.16  tff(decl_77767, type, 'Protein present in mitochndrial membranes of some organisms which stops oxidative phosphorylation by eliminating the proton gradient.': $i).
% 29.32/29.16  tff(decl_77768, type, 'uncoupling protein': $i).
% 29.32/29.16  tff(decl_77769, type, 'uncoupling-protein': $i).
% 29.32/29.16  tff(decl_77770, type, 'Undernourishment': $i).
% 29.32/29.16  tff(decl_77771, type, 'A chronic lack of sufficient calories in the diet.': $i).
% 29.32/29.16  tff(decl_77772, type, undernourishment: $i).
% 29.32/29.16  tff(decl_77773, type, 'Undifferentiated-Cell': $i).
% 29.32/29.16  tff(decl_77774, type, 'A cell that has not yet expressed signs of its future specific type is called as an undifferentiated cell.': $i).
% 29.32/29.16  tff(decl_77775, type, 'undifferentiated cell': $i).
% 29.32/29.16  tff(decl_77776, type, 'undifferentiated-cell': $i).
% 29.32/29.16  tff(decl_77777, type, undifferentiated_cell_nuclear_transplantation_1: $i > $o).
% 29.32/29.16  tff(decl_77778, type, 'Undifferentiated-Cell-Nuclear-Transplantation': $i).
% 29.32/29.16  tff(decl_77779, type, 'The technique of placing a nucleus from undifferentiated cell into an enucleated cell.': $i).
% 29.32/29.16  tff(decl_77780, type, 'undifferentiated cell nuclear transplantation': $i).
% 29.32/29.16  tff(decl_77781, type, 'undifferentiated-cell-nuclear-transplantation': $i).
% 29.32/29.16  tff(decl_77782, type, fn_undifferentiated_cell_nuclear_transplantation_1: $i > $i).
% 29.32/29.16  tff(decl_77783, type, 'Undifferentiated-Cell-Nucleus-Transplantation-To-Frog-Egg': $i).
% 29.32/29.16  tff(decl_77784, type, 'Animal researchers have approached the genomic equivalence question by replacing the nucleus of an unfertilized egg cell or zygote with the nucleus of a differentiated cell.': $i).
% 29.32/29.16  tff(decl_77785, type, 'undifferentiated cell nucleus transplantation to frog egg': $i).
% 29.32/29.16  tff(decl_77786, type, 'undifferentiated-cell-nucleus-transplantation-to-frog-egg': $i).
% 29.32/29.16  tff(decl_77787, type, fn_undifferentiated_cell_nucleus_transplantation_to_frog_egg_1: $i > $i).
% 29.32/29.16  tff(decl_77788, type, fn_undifferentiated_cell_nucleus_transplantation_to_frog_egg_2: $i > $i).
% 29.32/29.16  tff(decl_77789, type, fn_undifferentiated_cell_nucleus_transplantation_to_frog_egg_3: $i > $i).
% 29.32/29.16  tff(decl_77790, type, fn_undifferentiated_cell_nucleus_transplantation_to_frog_egg_4: $i > $i).
% 29.32/29.16  tff(decl_77791, type, fn_undifferentiated_cell_nucleus_transplantation_to_frog_egg_5: $i > $i).
% 29.32/29.16  tff(decl_77792, type, 'Undifferentiated-Embryonic-Cell': $i).
% 29.32/29.16  tff(decl_77793, type, 'An undifferentiated cell of the embryo.': $i).
% 29.32/29.16  tff(decl_77794, type, 'undifferentiated embryonic cell': $i).
% 29.32/29.16  tff(decl_77795, type, 'undifferentiated-embryonic-cell': $i).
% 29.32/29.16  tff(decl_77796, type, 'Unequal-Sharing': $i).
% 29.32/29.16  tff(decl_77797, type, 'This is the unequal distribution of resources among the entities.': $i).
% 29.32/29.16  tff(decl_77798, type, 'unequal sharing': $i).
% 29.32/29.16  tff(decl_77799, type, 'unequal-sharing': $i).
% 29.32/29.16  tff(decl_77800, type, 'Unequal-Sharing-of-Electrons': $i).
% 29.32/29.16  tff(decl_77801, type, 'An unequal sharing of electrons between two atoms in a molecule results in a polar covalent bond.': $i).
% 29.32/29.16  tff(decl_77802, type, 'unequal sharing of electron': $i).
% 29.32/29.16  tff(decl_77803, type, 'unequal-sharing-of-electron': $i).
% 29.32/29.16  tff(decl_77804, type, 'Unfertilized-Egg': $i).
% 29.32/29.16  tff(decl_77805, type, 'An egg which has not been fertilized by a male gamete.': $i).
% 29.32/29.16  tff(decl_77806, type, 'unfertilized-egg': $i).
% 29.32/29.16  tff(decl_77807, type, 'Unfolded-Protein': $i).
% 29.32/29.16  tff(decl_77808, type, 'A protein that is not folded.': $i).
% 29.32/29.16  tff(decl_77809, type, 'unfolded protein': $i).
% 29.32/29.16  tff(decl_77810, type, 'unfolded-protein': $i).
% 29.32/29.16  tff(decl_77811, type, 'Ungulate': $i).
% 29.32/29.16  tff(decl_77812, type, 'Superorder of mammals which contains animals which walk on their toes. Most ungulates are hoofed animals.': $i).
% 29.32/29.16  tff(decl_77813, type, ungulate: $i).
% 29.32/29.16  tff(decl_77814, type, 'Unicellular-Organism': $i).
% 29.32/29.16  tff(decl_77815, type, 'An organism consisting of a single cell.': $i).
% 29.32/29.16  tff(decl_77816, type, 'A unicelluar organism is an organism that is composed of only one cell.': $i).
% 29.32/29.16  tff(decl_77817, type, microbe: $i).
% 29.32/29.16  tff(decl_77818, type, 'unicellular organism': $i).
% 29.32/29.16  tff(decl_77819, type, 'unicellular-organism': $i).
% 29.32/29.16  tff(decl_77820, type, uniform_pattern_of_dispersion_1: $i > $o).
% 29.32/29.16  tff(decl_77821, type, 'Uniform-Pattern-Of-Dispersion': $i).
% 29.32/29.16  tff(decl_77822, type, 'A pattern in which indivduals are evenly distributed in a population.': $i).
% 29.32/29.16  tff(decl_77823, type, 'uniform pattern of dispersion': $i).
% 29.32/29.16  tff(decl_77824, type, 'uniform-pattern-of-dispersion': $i).
% 29.32/29.16  tff(decl_77825, type, 'Uniformitarianism': $i).
% 29.32/29.16  tff(decl_77826, type, 'The assumption that the natural laws now operating in the universe are constant over time.': $i).
% 29.32/29.16  tff(decl_77827, type, uniformitarianism: $i).
% 29.32/29.16  tff(decl_77828, type, 'Unikonta': $i).
% 29.32/29.16  tff(decl_77829, type, 'A proposed taxonomic grouping that includes amoebas and opisthokonts.': $i).
% 29.32/29.16  tff(decl_77830, type, unikonta: $i).
% 29.32/29.16  tff(decl_77831, type, unit_conversion_1: $i > $o).
% 29.32/29.16  tff(decl_77832, type, 'Unit-Conversion': $i).
% 29.32/29.16  tff(decl_77833, type, 'converts one property value directed by a given unit of measurement': $i).
% 29.32/29.16  tff(decl_77834, type, 'conversion of unit': $i).
% 29.32/29.16  tff(decl_77835, type, 'unit conversion': $i).
% 29.32/29.16  tff(decl_77836, type, 'unit-conversion': $i).
% 29.32/29.16  tff(decl_77837, type, 'Unit-of-Measurement': $i).
% 29.32/29.16  tff(decl_77838, type, 'Unitless-Value': $i).
% 29.32/29.16  tff(decl_77839, type, slope: $i).
% 29.32/29.16  tff(decl_77840, type, precedence: $i).
% 29.32/29.16  tff(decl_77841, type, precedency: $i).
% 29.32/29.16  tff(decl_77842, type, priority: $i).
% 29.32/29.16  tff(decl_77843, type, magnification: $i).
% 29.32/29.16  tff(decl_77844, type, importance: $i).
% 29.32/29.16  tff(decl_77845, type, 'unitless value': $i).
% 29.32/29.16  tff(decl_77846, type, 'unitless-value': $i).
% 29.32/29.16  tff(decl_77847, type, university_1: $i > $o).
% 29.32/29.16  tff(decl_77848, type, 'University': $i).
% 29.32/29.16  tff(decl_77849, type, 'a higher-institution of teaching, studying, research, etc.': $i).
% 29.32/29.16  tff(decl_77850, type, university: $i).
% 29.32/29.16  tff(decl_77851, type, unlinked_gene_1: $i > $o).
% 29.32/29.16  tff(decl_77852, type, 'Unlinked-Gene': $i).
% 29.32/29.16  tff(decl_77853, type, 'Genes that are located on two different chromosomes.': $i).
% 29.32/29.16  tff(decl_77854, type, 'unlinked gene': $i).
% 29.32/29.16  tff(decl_77855, type, 'unlinked-gene': $i).
% 29.32/29.16  tff(decl_77856, type, fn_unlinked_gene_1: $i > $i).
% 29.32/29.16  tff(decl_77857, type, fn_unlinked_gene_2: $i > $i).
% 29.32/29.16  tff(decl_77858, type, fn_unlinked_gene_3: $i > $i).
% 29.32/29.16  tff(decl_77859, type, fn_unlinked_gene_4: $i > $i).
% 29.32/29.16  tff(decl_77860, type, 'Unloading-Of-Sugar-At-Sugar-Sink': $i).
% 29.32/29.16  tff(decl_77861, type, 'It involves the unloading of sugar into sugar sink during the process of  Translocation of phloem sap.': $i).
% 29.32/29.16  tff(decl_77862, type, unload: $i).
% 29.32/29.16  tff(decl_77863, type, 'unloading of sugar at sugar sink': $i).
% 29.32/29.16  tff(decl_77864, type, 'unloading-of-sugar-at-sugar-sink': $i).
% 29.32/29.16  tff(decl_77865, type, fn_unloading_of_sugar_at_sugar_sink_2: $i > $i).
% 29.32/29.16  tff(decl_77866, type, fn_unloading_of_sugar_at_sugar_sink_3: $i > $i).
% 29.32/29.16  tff(decl_77867, type, fn_unloading_of_sugar_at_sugar_sink_4: $i > $i).
% 29.32/29.16  tff(decl_77868, type, fn_unloading_of_sugar_at_sugar_sink_5: $i > $i).
% 29.32/29.16  tff(decl_77869, type, fn_unloading_of_sugar_at_sugar_sink_6: $i > $i).
% 29.32/29.16  tff(decl_77870, type, 'Unobstruct': $i).
% 29.32/29.16  tff(decl_77871, type, disengage: $i).
% 29.32/29.16  tff(decl_77872, type, unobstruct: $i).
% 29.32/29.16  tff(decl_77873, type, 'Unpaired-Electron': $i).
% 29.32/29.16  tff(decl_77874, type, 'An electron that occupies an orbital singly, rather than as part of an electron pair.': $i).
% 29.32/29.16  tff(decl_77875, type, 'unpaired electron': $i).
% 29.32/29.16  tff(decl_77876, type, 'unpaired-electron': $i).
% 29.32/29.16  tff(decl_77877, type, unrestrain_1: $i > $o).
% 29.32/29.16  tff(decl_77878, type, 'Unrestrain': $i).
% 29.32/29.16  tff(decl_77879, type, 'let loose': $i).
% 29.32/29.16  tff(decl_77880, type, let_loose: $i).
% 29.32/29.16  tff(decl_77881, type, loose: $i).
% 29.32/29.16  tff(decl_77882, type, unleash: $i).
% 29.32/29.16  tff(decl_77883, type, unrestrain: $i).
% 29.32/29.16  tff(decl_77884, type, fn_unrestrain_1: $i > $i).
% 29.32/29.16  tff(decl_77885, type, unripened_fruit_1: $i > $o).
% 29.32/29.16  tff(decl_77886, type, 'Unripened-Fruit': $i).
% 29.32/29.16  tff(decl_77887, type, 'The fruits that are not ripe or have not matured are unripened fruits.': $i).
% 29.32/29.16  tff(decl_77888, type, 'unripened fruit': $i).
% 29.32/29.16  tff(decl_77889, type, 'unripened-fruit': $i).
% 29.32/29.16  tff(decl_77890, type, 'Unsaturated-Fat': $i).
% 29.32/29.16  tff(decl_77891, type, 'An unsaturated fat is a fat or fatty acid in which there is at least one double bond within the fatty acid chain.': $i).
% 29.32/29.16  tff(decl_77892, type, 'unsaturated fat': $i).
% 29.32/29.16  tff(decl_77893, type, 'unsaturated-fat': $i).
% 29.32/29.16  tff(decl_77894, type, fn_unsaturated_fat_1: $i > $i).
% 29.32/29.16  tff(decl_77895, type, fn_unsaturated_fat_2: $i > $i).
% 29.32/29.16  tff(decl_77896, type, fn_unsaturated_fat_3: $i > $i).
% 29.32/29.16  tff(decl_77897, type, fn_unsaturated_fat_4: $i > $i).
% 29.32/29.16  tff(decl_77898, type, 'Unsaturated-Fatty-Acid': $i).
% 29.32/29.16  tff(decl_77899, type, 'Unsaturated fatty acids are fatty acids,with one or more double-bonds.': $i).
% 29.32/29.16  tff(decl_77900, type, 'unsaturated fatty acid tail': $i).
% 29.32/29.16  tff(decl_77901, type, 'unsaturated-fatty-acid-tail': $i).
% 29.32/29.16  tff(decl_77902, type, 'unsaturated hydrocarbon tail': $i).
% 29.32/29.16  tff(decl_77903, type, 'unsaturated phospholipid': $i).
% 29.32/29.16  tff(decl_77904, type, 'unsaturated hydrocarbon': $i).
% 29.32/29.16  tff(decl_77905, type, 'unsaturated fatty acid': $i).
% 29.32/29.16  tff(decl_77906, type, 'unsaturated-fatty-acid': $i).
% 29.32/29.16  tff(decl_77907, type, fn_unsaturated_fatty_acid_2: $i > $i).
% 29.32/29.16  tff(decl_77908, type, fn_unsaturated_fatty_acid_3: $i > $i).
% 29.32/29.16  tff(decl_77909, type, fn_unsaturated_fatty_acid_17: $i > $i).
% 29.32/29.16  tff(decl_77910, type, fn_unsaturated_fatty_acid_24: $i > $i).
% 29.32/29.16  tff(decl_77911, type, fn_unsaturated_fatty_acid_42: $i > $i).
% 29.32/29.16  tff(decl_77912, type, fn_unsaturated_fatty_acid_54: $i > $i).
% 29.32/29.16  tff(decl_77913, type, fn_unsaturated_fatty_acid_62: $i > $i).
% 29.32/29.16  tff(decl_77914, type, fn_unsaturated_fatty_acid_65: $i > $i).
% 29.32/29.16  tff(decl_77915, type, fn_unsaturated_fatty_acid_67: $i > $i).
% 29.32/29.16  tff(decl_77916, type, fn_unsaturated_fatty_acid_78: $i > $i).
% 29.32/29.16  tff(decl_77917, type, fn_unsaturated_fatty_acid_79: $i > $i).
% 29.32/29.16  tff(decl_77918, type, fn_unsaturated_fatty_acid_80: $i > $i).
% 29.32/29.16  tff(decl_77919, type, fn_unsaturated_fatty_acid_81: $i > $i).
% 29.32/29.16  tff(decl_77920, type, fn_unsaturated_fatty_acid_82: $i > $i).
% 29.32/29.16  tff(decl_77921, type, fn_unsaturated_fatty_acid_83: $i > $i).
% 29.32/29.16  tff(decl_77922, type, fn_unsaturated_fatty_acid_84: $i > $i).
% 29.32/29.16  tff(decl_77923, type, 'Unstable-System': $i).
% 29.32/29.16  tff(decl_77924, type, 'The system which is not stable is unstable system. The instability is due to randomness in free energy.': $i).
% 29.32/29.16  tff(decl_77925, type, 'unstable system': $i).
% 29.32/29.16  tff(decl_77926, type, 'unstable-system': $i).
% 29.32/29.16  tff(decl_77927, type, 'Untransformed-Bacterial-Cell': $i).
% 29.32/29.16  tff(decl_77928, type, 'A cultured bacterial cell that has not incorporated a foreign plasmid\\s genome during a transformation proceudre.  The resultant untransformed bacterial cell will be genetically identical to the parent bacterial cell.': $i).
% 29.32/29.16  tff(decl_77929, type, 'untransformed cell': $i).
% 29.32/29.16  tff(decl_77930, type, 'untransformed bacterial cell': $i).
% 29.32/29.16  tff(decl_77931, type, 'untransformed-bacterial-cell': $i).
% 29.32/29.16  tff(decl_77932, type, fn_untransformed_bacterial_cell_1: $i > $i).
% 29.32/29.16  tff(decl_77933, type, fn_untransformed_bacterial_cell_2: $i > $i).
% 29.32/29.16  tff(decl_77934, type, fn_untransformed_bacterial_cell_3: $i > $i).
% 29.32/29.16  tff(decl_77935, type, fn_untransformed_bacterial_cell_4: $i > $i).
% 29.32/29.16  tff(decl_77936, type, fn_untransformed_bacterial_cell_9: $i > $i).
% 29.32/29.16  tff(decl_77937, type, fn_untransformed_bacterial_cell_10: $i > $i).
% 29.32/29.16  tff(decl_77938, type, fn_untransformed_bacterial_cell_11: $i > $i).
% 29.32/29.16  tff(decl_77939, type, fn_untransformed_bacterial_cell_12: $i > $i).
% 29.32/29.16  tff(decl_77940, type, fn_untransformed_bacterial_cell_13: $i > $i).
% 29.32/29.16  tff(decl_77941, type, fn_untransformed_bacterial_cell_14: $i > $i).
% 29.32/29.16  tff(decl_77942, type, fn_untransformed_bacterial_cell_15: $i > $i).
% 29.32/29.16  tff(decl_77943, type, fn_untransformed_bacterial_cell_16: $i > $i).
% 29.32/29.16  tff(decl_77944, type, fn_untransformed_bacterial_cell_17: $i > $i).
% 29.32/29.16  tff(decl_77945, type, fn_untransformed_bacterial_cell_18: $i > $i).
% 29.32/29.16  tff(decl_77946, type, fn_untransformed_bacterial_cell_19: $i > $i).
% 29.32/29.16  tff(decl_77947, type, fn_untransformed_bacterial_cell_20: $i > $i).
% 29.32/29.16  tff(decl_77948, type, fn_untransformed_bacterial_cell_21: $i > $i).
% 29.32/29.16  tff(decl_77949, type, fn_untransformed_bacterial_cell_22: $i > $i).
% 29.32/29.16  tff(decl_77950, type, fn_untransformed_bacterial_cell_23: $i > $i).
% 29.32/29.16  tff(decl_77951, type, fn_untransformed_bacterial_cell_24: $i > $i).
% 29.32/29.16  tff(decl_77952, type, fn_untransformed_bacterial_cell_25: $i > $i).
% 29.32/29.16  tff(decl_77953, type, fn_untransformed_bacterial_cell_26: $i > $i).
% 29.32/29.16  tff(decl_77954, type, fn_untransformed_bacterial_cell_27: $i > $i).
% 29.32/29.16  tff(decl_77955, type, fn_untransformed_bacterial_cell_28: $i > $i).
% 29.32/29.16  tff(decl_77956, type, fn_untransformed_bacterial_cell_29: $i > $i).
% 29.32/29.16  tff(decl_77957, type, fn_untransformed_bacterial_cell_30: $i > $i).
% 29.32/29.16  tff(decl_77958, type, fn_untransformed_bacterial_cell_31: $i > $i).
% 29.32/29.16  tff(decl_77959, type, fn_untransformed_bacterial_cell_32: $i > $i).
% 29.32/29.16  tff(decl_77960, type, fn_untransformed_bacterial_cell_33: $i > $i).
% 29.32/29.16  tff(decl_77961, type, fn_untransformed_bacterial_cell_34: $i > $i).
% 29.32/29.16  tff(decl_77962, type, fn_untransformed_bacterial_cell_35: $i > $i).
% 29.32/29.16  tff(decl_77963, type, fn_untransformed_bacterial_cell_36: $i > $i).
% 29.32/29.16  tff(decl_77964, type, fn_untransformed_bacterial_cell_8: $i > $i).
% 29.32/29.16  tff(decl_77965, type, fn_untransformed_bacterial_cell_7: $i > $i).
% 29.32/29.16  tff(decl_77966, type, fn_untransformed_bacterial_cell_6: $i > $i).
% 29.32/29.16  tff(decl_77967, type, fn_untransformed_bacterial_cell_5: $i > $i).
% 29.32/29.16  tff(decl_77968, type, 'UoM-Acceleration-Magnitude': $i).
% 29.32/29.16  tff(decl_77969, type, 'uom acceleration magnitude': $i).
% 29.32/29.16  tff(decl_77970, type, 'uom-acceleration-magnitude': $i).
% 29.32/29.16  tff(decl_77971, type, 'UoM-Angle': $i).
% 29.32/29.16  tff(decl_77972, type, 'uom angle': $i).
% 29.32/29.16  tff(decl_77973, type, 'uom-angle': $i).
% 29.32/29.16  tff(decl_77974, type, 'UoM-Area': $i).
% 29.32/29.16  tff(decl_77975, type, 'uom area': $i).
% 29.32/29.16  tff(decl_77976, type, 'uom-area': $i).
% 29.32/29.16  tff(decl_77977, type, 'UoM-Brightness': $i).
% 29.32/29.16  tff(decl_77978, type, 'uom brightness': $i).
% 29.32/29.16  tff(decl_77979, type, 'uom-brightness': $i).
% 29.32/29.16  tff(decl_77980, type, 'UoM-Concentration': $i).
% 29.32/29.16  tff(decl_77981, type, 'uom concentration': $i).
% 29.32/29.16  tff(decl_77982, type, 'uom-concentration': $i).
% 29.32/29.16  tff(decl_77983, type, 'UoM-Conductivity': $i).
% 29.32/29.16  tff(decl_77984, type, 'uom conductivity': $i).
% 29.32/29.16  tff(decl_77985, type, 'uom-conductivity': $i).
% 29.32/29.16  tff(decl_77986, type, 'UoM-Coordinate': $i).
% 29.32/29.16  tff(decl_77987, type, degree: $i).
% 29.32/29.16  tff(decl_77988, type, arcminute: $i).
% 29.32/29.16  tff(decl_77989, type, arcsecond: $i).
% 29.32/29.16  tff(decl_77990, type, degrees: $i).
% 29.32/29.16  tff(decl_77991, type, arcminutes: $i).
% 29.32/29.16  tff(decl_77992, type, arcseconds: $i).
% 29.32/29.16  tff(decl_77993, type, 'uom coordinate': $i).
% 29.32/29.16  tff(decl_77994, type, 'uom-coordinate': $i).
% 29.32/29.16  tff(decl_77995, type, 'UoM-Density': $i).
% 29.32/29.16  tff(decl_77996, type, 'uom density': $i).
% 29.32/29.16  tff(decl_77997, type, 'uom-density': $i).
% 29.32/29.16  tff(decl_77998, type, 'UoM-Duration': $i).
% 29.32/29.16  tff(decl_77999, type, 'uom duration': $i).
% 29.32/29.16  tff(decl_78000, type, 'uom-duration': $i).
% 29.32/29.16  tff(decl_78001, type, 'UoM-Energy': $i).
% 29.32/29.16  tff(decl_78002, type, 'uom energy': $i).
% 29.32/29.16  tff(decl_78003, type, 'uom-energy': $i).
% 29.32/29.16  tff(decl_78004, type, 'UoM-Frequency': $i).
% 29.32/29.16  tff(decl_78005, type, 'uom frequency': $i).
% 29.32/29.16  tff(decl_78006, type, 'uom-frequency': $i).
% 29.32/29.16  tff(decl_78007, type, 'UoM-Heat-of-Vaporization': $i).
% 29.32/29.16  tff(decl_78008, type, 'uom heat of vaporization': $i).
% 29.32/29.16  tff(decl_78009, type, 'uom-heat-of-vaporization': $i).
% 29.32/29.16  tff(decl_78010, type, uom_intensity_1: $i > $o).
% 29.32/29.16  tff(decl_78011, type, 'UoM-Intensity': $i).
% 29.32/29.16  tff(decl_78012, type, 'uom intensity': $i).
% 29.32/29.16  tff(decl_78013, type, 'uom-intensity': $i).
% 29.32/29.16  tff(decl_78014, type, 'UoM-Length': $i).
% 29.32/29.16  tff(decl_78015, type, 'uom length': $i).
% 29.32/29.16  tff(decl_78016, type, 'uom-length': $i).
% 29.32/29.16  tff(decl_78017, type, 'UoM-Luminance': $i).
% 29.32/29.16  tff(decl_78018, type, 'uom luminance': $i).
% 29.32/29.16  tff(decl_78019, type, 'uom-luminance': $i).
% 29.32/29.16  tff(decl_78020, type, 'UoM-Luminous-Flux': $i).
% 29.32/29.16  tff(decl_78021, type, 'uom luminous flux': $i).
% 29.32/29.16  tff(decl_78022, type, 'uom-luminous-flux': $i).
% 29.32/29.16  tff(decl_78023, type, 'UoM-Luminous-Intensity': $i).
% 29.32/29.16  tff(decl_78024, type, 'uom luminous intensity': $i).
% 29.32/29.16  tff(decl_78025, type, 'uom-luminous-intensity': $i).
% 29.32/29.16  tff(decl_78026, type, 'UoM-Mass': $i).
% 29.32/29.16  tff(decl_78027, type, 'uom mass': $i).
% 29.32/29.16  tff(decl_78028, type, 'uom-mass': $i).
% 29.32/29.16  tff(decl_78029, type, 'UoM-Moment-of-Inertia': $i).
% 29.32/29.16  tff(decl_78030, type, 'uom moment of inertia': $i).
% 29.32/29.16  tff(decl_78031, type, 'uom-moment-of-inertia': $i).
% 29.32/29.16  tff(decl_78032, type, 'UoM-Momentum': $i).
% 29.32/29.16  tff(decl_78033, type, 'uom momentum': $i).
% 29.32/29.16  tff(decl_78034, type, 'uom-momentum': $i).
% 29.32/29.16  tff(decl_78035, type, 'UoM-Potential-Quantity': $i).
% 29.32/29.16  tff(decl_78036, type, 'uom potential quantity': $i).
% 29.32/29.16  tff(decl_78037, type, 'uom-potential-quantity': $i).
% 29.32/29.16  tff(decl_78038, type, 'UoM-Power': $i).
% 29.32/29.16  tff(decl_78039, type, 'uom power': $i).
% 29.32/29.16  tff(decl_78040, type, 'uom-power': $i).
% 29.32/29.16  tff(decl_78041, type, 'UoM-Pressure': $i).
% 29.32/29.16  tff(decl_78042, type, 'uom pressure': $i).
% 29.32/29.16  tff(decl_78043, type, 'uom-pressure': $i).
% 29.32/29.16  tff(decl_78044, type, 'UoM-Quantity': $i).
% 29.32/29.16  tff(decl_78045, type, 'uom quantity': $i).
% 29.32/29.16  tff(decl_78046, type, 'uom-quantity': $i).
% 29.32/29.16  tff(decl_78047, type, 'UoM-Rate': $i).
% 29.32/29.16  tff(decl_78048, type, 'uom rate': $i).
% 29.32/29.16  tff(decl_78049, type, 'uom-rate': $i).
% 29.32/29.16  tff(decl_78050, type, 'UoM-Rotational-Rate': $i).
% 29.32/29.16  tff(decl_78051, type, 'uom rotational rate': $i).
% 29.32/29.16  tff(decl_78052, type, 'uom-rotational-rate': $i).
% 29.32/29.16  tff(decl_78053, type, 'UoM-Specific-Heat': $i).
% 29.32/29.16  tff(decl_78054, type, 'uom specific heat': $i).
% 29.32/29.16  tff(decl_78055, type, 'uom-specific-heat': $i).
% 29.32/29.16  tff(decl_78056, type, 'UoM-Specific-Surface-Area': $i).
% 29.32/29.16  tff(decl_78057, type, 'uom specific surface area': $i).
% 29.32/29.16  tff(decl_78058, type, 'uom-specific-surface-area': $i).
% 29.32/29.16  tff(decl_78059, type, 'UoM-Speed': $i).
% 29.32/29.16  tff(decl_78060, type, 'uom speed': $i).
% 29.32/29.16  tff(decl_78061, type, 'uom-speed': $i).
% 29.32/29.16  tff(decl_78062, type, 'UoM-Surface-Area': $i).
% 29.32/29.16  tff(decl_78063, type, 'uom surface area': $i).
% 29.32/29.16  tff(decl_78064, type, 'uom-surface-area': $i).
% 29.32/29.16  tff(decl_78065, type, 'UoM-Temperature': $i).
% 29.32/29.16  tff(decl_78066, type, 'uom temperature': $i).
% 29.32/29.16  tff(decl_78067, type, 'uom-temperature': $i).
% 29.32/29.16  tff(decl_78068, type, 'UoM-Time': $i).
% 29.32/29.16  tff(decl_78069, type, 'uom time': $i).
% 29.32/29.16  tff(decl_78070, type, 'uom-time': $i).
% 29.32/29.16  tff(decl_78071, type, 'UoM-Unitless': $i).
% 29.32/29.16  tff(decl_78072, type, 'uom unitless': $i).
% 29.32/29.16  tff(decl_78073, type, 'uom-unitless': $i).
% 29.32/29.16  tff(decl_78074, type, 'UoM-Voltage': $i).
% 29.32/29.16  tff(decl_78075, type, 'uom voltage': $i).
% 29.32/29.16  tff(decl_78076, type, 'uom-voltage': $i).
% 29.32/29.16  tff(decl_78077, type, 'UoM-Volume': $i).
% 29.32/29.16  tff(decl_78078, type, 'uom volume': $i).
% 29.32/29.16  tff(decl_78079, type, 'uom-volume': $i).
% 29.32/29.16  tff(decl_78080, type, 'UoM-Worth': $i).
% 29.32/29.16  tff(decl_78081, type, 'uom worth': $i).
% 29.32/29.16  tff(decl_78082, type, 'uom-worth': $i).
% 29.32/29.16  tff(decl_78083, type, uptake_of_calcium_ion_by_chloroplast_1: $i > $o).
% 29.32/29.16  tff(decl_78084, type, 'Uptake-Of-Calcium-Ion-By-Chloroplast': $i).
% 29.32/29.16  tff(decl_78085, type, 'The active transport of Ca2+ ions from cytosol into the chloropast.': $i).
% 29.32/29.16  tff(decl_78086, type, 'uptake of calcium ion by chloroplast': $i).
% 29.32/29.16  tff(decl_78087, type, 'uptake-of-calcium-ion-by-chloroplast': $i).
% 29.32/29.16  tff(decl_78088, type, uptake_of_calcium_ion_by_mitochondria_1: $i > $o).
% 29.32/29.16  tff(decl_78089, type, fn_uptake_of_calcium_ion_by_chloroplast_1: $i > $i).
% 29.32/29.16  tff(decl_78090, type, fn_uptake_of_calcium_ion_by_chloroplast_2: $i > $i).
% 29.32/29.16  tff(decl_78091, type, fn_uptake_of_calcium_ion_by_chloroplast_3: $i > $i).
% 29.32/29.16  tff(decl_78092, type, fn_uptake_of_calcium_ion_by_chloroplast_4: $i > $i).
% 29.32/29.16  tff(decl_78093, type, fn_uptake_of_calcium_ion_by_chloroplast_5: $i > $i).
% 29.32/29.16  tff(decl_78094, type, fn_uptake_of_calcium_ion_by_chloroplast_6: $i > $i).
% 29.32/29.16  tff(decl_78095, type, fn_uptake_of_calcium_ion_by_chloroplast_8: $i > $i).
% 29.32/29.16  tff(decl_78096, type, fn_uptake_of_calcium_ion_by_chloroplast_14: $i > $i).
% 29.32/29.16  tff(decl_78097, type, fn_uptake_of_calcium_ion_by_chloroplast_15: $i > $i).
% 29.32/29.16  tff(decl_78098, type, fn_uptake_of_calcium_ion_by_chloroplast_16: $i > $i).
% 29.32/29.16  tff(decl_78099, type, fn_uptake_of_calcium_ion_by_chloroplast_17: $i > $i).
% 29.32/29.16  tff(decl_78100, type, fn_uptake_of_calcium_ion_by_chloroplast_18: $i > $i).
% 29.32/29.16  tff(decl_78101, type, fn_uptake_of_calcium_ion_by_chloroplast_19: $i > $i).
% 29.32/29.16  tff(decl_78102, type, fn_uptake_of_calcium_ion_by_chloroplast_20: $i > $i).
% 29.32/29.16  tff(decl_78103, type, fn_uptake_of_calcium_ion_by_chloroplast_21: $i > $i).
% 29.32/29.16  tff(decl_78104, type, fn_uptake_of_calcium_ion_by_chloroplast_22: $i > $i).
% 29.32/29.16  tff(decl_78105, type, fn_uptake_of_calcium_ion_by_chloroplast_23: $i > $i).
% 29.32/29.16  tff(decl_78106, type, fn_uptake_of_calcium_ion_by_chloroplast_24: $i > $i).
% 29.32/29.16  tff(decl_78107, type, fn_uptake_of_calcium_ion_by_chloroplast_25: $i > $i).
% 29.32/29.16  tff(decl_78108, type, fn_uptake_of_calcium_ion_by_chloroplast_26: $i > $i).
% 29.32/29.16  tff(decl_78109, type, fn_uptake_of_calcium_ion_by_chloroplast_27: $i > $i).
% 29.32/29.16  tff(decl_78110, type, fn_uptake_of_calcium_ion_by_chloroplast_28: $i > $i).
% 29.32/29.16  tff(decl_78111, type, fn_uptake_of_calcium_ion_by_chloroplast_29: $i > $i).
% 29.32/29.16  tff(decl_78112, type, fn_uptake_of_calcium_ion_by_chloroplast_30: $i > $i).
% 29.32/29.16  tff(decl_78113, type, fn_uptake_of_calcium_ion_by_chloroplast_31: $i > $i).
% 29.32/29.16  tff(decl_78114, type, fn_uptake_of_calcium_ion_by_chloroplast_32: $i > $i).
% 29.32/29.16  tff(decl_78115, type, fn_uptake_of_calcium_ion_by_chloroplast_33: $i > $i).
% 29.32/29.16  tff(decl_78116, type, fn_uptake_of_calcium_ion_by_chloroplast_34: $i > $i).
% 29.32/29.16  tff(decl_78117, type, fn_uptake_of_calcium_ion_by_chloroplast_35: $i > $i).
% 29.32/29.16  tff(decl_78118, type, fn_uptake_of_calcium_ion_by_chloroplast_36: $i > $i).
% 29.32/29.16  tff(decl_78119, type, fn_uptake_of_calcium_ion_by_chloroplast_37: $i > $i).
% 29.32/29.16  tff(decl_78120, type, fn_uptake_of_calcium_ion_by_chloroplast_38: $i > $i).
% 29.32/29.16  tff(decl_78121, type, fn_uptake_of_calcium_ion_by_chloroplast_39: $i > $i).
% 29.32/29.16  tff(decl_78122, type, fn_uptake_of_calcium_ion_by_chloroplast_40: $i > $i).
% 29.32/29.16  tff(decl_78123, type, fn_uptake_of_calcium_ion_by_chloroplast_41: $i > $i).
% 29.32/29.16  tff(decl_78124, type, fn_uptake_of_calcium_ion_by_chloroplast_42: $i > $i).
% 29.32/29.16  tff(decl_78125, type, fn_uptake_of_calcium_ion_by_chloroplast_43: $i > $i).
% 29.32/29.16  tff(decl_78126, type, fn_uptake_of_calcium_ion_by_chloroplast_44: $i > $i).
% 29.32/29.16  tff(decl_78127, type, fn_uptake_of_calcium_ion_by_chloroplast_45: $i > $i).
% 29.32/29.16  tff(decl_78128, type, fn_uptake_of_calcium_ion_by_chloroplast_46: $i > $i).
% 29.32/29.16  tff(decl_78129, type, fn_uptake_of_calcium_ion_by_chloroplast_47: $i > $i).
% 29.32/29.16  tff(decl_78130, type, fn_uptake_of_calcium_ion_by_chloroplast_48: $i > $i).
% 29.32/29.16  tff(decl_78131, type, fn_uptake_of_calcium_ion_by_chloroplast_49: $i > $i).
% 29.32/29.16  tff(decl_78132, type, fn_uptake_of_calcium_ion_by_chloroplast_50: $i > $i).
% 29.32/29.16  tff(decl_78133, type, fn_uptake_of_calcium_ion_by_chloroplast_51: $i > $i).
% 29.32/29.16  tff(decl_78134, type, fn_uptake_of_calcium_ion_by_chloroplast_52: $i > $i).
% 29.32/29.16  tff(decl_78135, type, fn_uptake_of_calcium_ion_by_chloroplast_53: $i > $i).
% 29.32/29.16  tff(decl_78136, type, fn_uptake_of_calcium_ion_by_chloroplast_54: $i > $i).
% 29.32/29.16  tff(decl_78137, type, fn_uptake_of_calcium_ion_by_chloroplast_55: $i > $i).
% 29.32/29.16  tff(decl_78138, type, fn_uptake_of_calcium_ion_by_chloroplast_56: $i > $i).
% 29.32/29.16  tff(decl_78139, type, fn_uptake_of_calcium_ion_by_chloroplast_57: $i > $i).
% 29.32/29.16  tff(decl_78140, type, fn_uptake_of_calcium_ion_by_chloroplast_58: $i > $i).
% 29.32/29.16  tff(decl_78141, type, fn_uptake_of_calcium_ion_by_chloroplast_59: $i > $i).
% 29.32/29.16  tff(decl_78142, type, fn_uptake_of_calcium_ion_by_chloroplast_60: $i > $i).
% 29.32/29.16  tff(decl_78143, type, fn_uptake_of_calcium_ion_by_chloroplast_61: $i > $i).
% 29.32/29.16  tff(decl_78144, type, fn_uptake_of_calcium_ion_by_chloroplast_62: $i > $i).
% 29.32/29.16  tff(decl_78145, type, fn_uptake_of_calcium_ion_by_chloroplast_63: $i > $i).
% 29.32/29.16  tff(decl_78146, type, fn_uptake_of_calcium_ion_by_chloroplast_64: $i > $i).
% 29.32/29.16  tff(decl_78147, type, fn_uptake_of_calcium_ion_by_chloroplast_65: $i > $i).
% 29.32/29.16  tff(decl_78148, type, fn_uptake_of_calcium_ion_by_chloroplast_66: $i > $i).
% 29.32/29.16  tff(decl_78149, type, fn_uptake_of_calcium_ion_by_chloroplast_67: $i > $i).
% 29.32/29.16  tff(decl_78150, type, fn_uptake_of_calcium_ion_by_chloroplast_68: $i > $i).
% 29.32/29.16  tff(decl_78151, type, fn_uptake_of_calcium_ion_by_chloroplast_69: $i > $i).
% 29.32/29.16  tff(decl_78152, type, fn_uptake_of_calcium_ion_by_chloroplast_70: $i > $i).
% 29.32/29.16  tff(decl_78153, type, fn_uptake_of_calcium_ion_by_chloroplast_71: $i > $i).
% 29.32/29.16  tff(decl_78154, type, fn_uptake_of_calcium_ion_by_chloroplast_72: $i > $i).
% 29.32/29.16  tff(decl_78155, type, fn_uptake_of_calcium_ion_by_chloroplast_73: $i > $i).
% 29.32/29.16  tff(decl_78156, type, fn_uptake_of_calcium_ion_by_chloroplast_74: $i > $i).
% 29.32/29.16  tff(decl_78157, type, fn_uptake_of_calcium_ion_by_chloroplast_75: $i > $i).
% 29.32/29.16  tff(decl_78158, type, fn_uptake_of_calcium_ion_by_chloroplast_76: $i > $i).
% 29.32/29.16  tff(decl_78159, type, fn_uptake_of_calcium_ion_by_chloroplast_77: $i > $i).
% 29.32/29.16  tff(decl_78160, type, fn_uptake_of_calcium_ion_by_chloroplast_78: $i > $i).
% 29.32/29.16  tff(decl_78161, type, fn_uptake_of_calcium_ion_by_chloroplast_79: $i > $i).
% 29.32/29.16  tff(decl_78162, type, fn_uptake_of_calcium_ion_by_chloroplast_80: $i > $i).
% 29.32/29.16  tff(decl_78163, type, fn_uptake_of_calcium_ion_by_chloroplast_81: $i > $i).
% 29.32/29.16  tff(decl_78164, type, fn_uptake_of_calcium_ion_by_chloroplast_82: $i > $i).
% 29.32/29.16  tff(decl_78165, type, fn_uptake_of_calcium_ion_by_chloroplast_83: $i > $i).
% 29.32/29.16  tff(decl_78166, type, fn_uptake_of_calcium_ion_by_chloroplast_84: $i > $i).
% 29.32/29.16  tff(decl_78167, type, fn_uptake_of_calcium_ion_by_chloroplast_85: $i > $i).
% 29.32/29.16  tff(decl_78168, type, fn_uptake_of_calcium_ion_by_chloroplast_86: $i > $i).
% 29.32/29.16  tff(decl_78169, type, fn_uptake_of_calcium_ion_by_chloroplast_87: $i > $i).
% 29.32/29.16  tff(decl_78170, type, fn_uptake_of_calcium_ion_by_chloroplast_88: $i > $i).
% 29.32/29.16  tff(decl_78171, type, fn_uptake_of_calcium_ion_by_chloroplast_89: $i > $i).
% 29.32/29.16  tff(decl_78172, type, fn_uptake_of_calcium_ion_by_chloroplast_90: $i > $i).
% 29.32/29.16  tff(decl_78173, type, fn_uptake_of_calcium_ion_by_chloroplast_91: $i > $i).
% 29.32/29.16  tff(decl_78174, type, fn_uptake_of_calcium_ion_by_chloroplast_92: $i > $i).
% 29.32/29.16  tff(decl_78175, type, fn_uptake_of_calcium_ion_by_chloroplast_93: $i > $i).
% 29.32/29.16  tff(decl_78176, type, fn_uptake_of_calcium_ion_by_chloroplast_94: $i > $i).
% 29.32/29.16  tff(decl_78177, type, fn_uptake_of_calcium_ion_by_chloroplast_95: $i > $i).
% 29.32/29.16  tff(decl_78178, type, fn_uptake_of_calcium_ion_by_chloroplast_96: $i > $i).
% 29.32/29.16  tff(decl_78179, type, fn_uptake_of_calcium_ion_by_chloroplast_97: $i > $i).
% 29.32/29.16  tff(decl_78180, type, fn_uptake_of_calcium_ion_by_chloroplast_98: $i > $i).
% 29.32/29.16  tff(decl_78181, type, fn_uptake_of_calcium_ion_by_chloroplast_99: $i > $i).
% 29.32/29.16  tff(decl_78182, type, fn_uptake_of_calcium_ion_by_chloroplast_105: $i > $i).
% 29.32/29.16  tff(decl_78183, type, fn_uptake_of_calcium_ion_by_chloroplast_106: $i > $i).
% 29.32/29.16  tff(decl_78184, type, fn_uptake_of_calcium_ion_by_chloroplast_107: $i > $i).
% 29.32/29.16  tff(decl_78185, type, fn_uptake_of_calcium_ion_by_chloroplast_108: $i > $i).
% 29.32/29.16  tff(decl_78186, type, fn_uptake_of_calcium_ion_by_chloroplast_109: $i > $i).
% 29.32/29.16  tff(decl_78187, type, fn_uptake_of_calcium_ion_by_chloroplast_110: $i > $i).
% 29.32/29.16  tff(decl_78188, type, fn_uptake_of_calcium_ion_by_chloroplast_111: $i > $i).
% 29.32/29.16  tff(decl_78189, type, fn_uptake_of_calcium_ion_by_chloroplast_112: $i > $i).
% 29.32/29.16  tff(decl_78190, type, fn_uptake_of_calcium_ion_by_chloroplast_113: $i > $i).
% 29.32/29.16  tff(decl_78191, type, fn_uptake_of_calcium_ion_by_chloroplast_100: $i > $i).
% 29.32/29.16  tff(decl_78192, type, fn_uptake_of_calcium_ion_by_chloroplast_101: $i > $i).
% 29.32/29.16  tff(decl_78193, type, fn_uptake_of_calcium_ion_by_chloroplast_102: $i > $i).
% 29.32/29.16  tff(decl_78194, type, fn_uptake_of_calcium_ion_by_chloroplast_104: $i > $i).
% 29.32/29.16  tff(decl_78195, type, fn_uptake_of_calcium_ion_by_chloroplast_103: $i > $i).
% 29.32/29.16  tff(decl_78196, type, fn_uptake_of_calcium_ion_by_chloroplast_13: $i > $i).
% 29.32/29.16  tff(decl_78197, type, fn_uptake_of_calcium_ion_by_chloroplast_12: $i > $i).
% 29.32/29.16  tff(decl_78198, type, fn_uptake_of_calcium_ion_by_chloroplast_11: $i > $i).
% 29.32/29.16  tff(decl_78199, type, fn_uptake_of_calcium_ion_by_chloroplast_10: $i > $i).
% 29.32/29.16  tff(decl_78200, type, 'Uptake-Of-Calcium-Ion-By-Endoplasmic-Reticulum': $i).
% 29.32/29.16  tff(decl_78201, type, 'The active transport of Ca2+ ions from cytosol into the endoplasmic reticulum.': $i).
% 29.32/29.16  tff(decl_78202, type, 'uptake of calcium ion by endoplasmic reticulum': $i).
% 29.32/29.16  tff(decl_78203, type, 'uptake-of-calcium-ion-by-endoplasmic-reticulum': $i).
% 29.32/29.16  tff(decl_78204, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_1: $i > $i).
% 29.32/29.16  tff(decl_78205, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_2: $i > $i).
% 29.32/29.16  tff(decl_78206, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_3: $i > $i).
% 29.32/29.16  tff(decl_78207, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_5: $i > $i).
% 29.32/29.16  tff(decl_78208, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_6: $i > $i).
% 29.32/29.16  tff(decl_78209, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_13: $i > $i).
% 29.32/29.16  tff(decl_78210, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_14: $i > $i).
% 29.32/29.16  tff(decl_78211, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_15: $i > $i).
% 29.32/29.16  tff(decl_78212, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_16: $i > $i).
% 29.32/29.16  tff(decl_78213, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_17: $i > $i).
% 29.32/29.16  tff(decl_78214, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_18: $i > $i).
% 29.32/29.16  tff(decl_78215, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_19: $i > $i).
% 29.32/29.16  tff(decl_78216, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_20: $i > $i).
% 29.32/29.16  tff(decl_78217, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_21: $i > $i).
% 29.32/29.16  tff(decl_78218, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_22: $i > $i).
% 29.32/29.16  tff(decl_78219, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_23: $i > $i).
% 29.32/29.16  tff(decl_78220, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_24: $i > $i).
% 29.32/29.16  tff(decl_78221, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_25: $i > $i).
% 29.32/29.16  tff(decl_78222, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_26: $i > $i).
% 29.32/29.16  tff(decl_78223, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_28: $i > $i).
% 29.32/29.16  tff(decl_78224, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_29: $i > $i).
% 29.32/29.16  tff(decl_78225, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_30: $i > $i).
% 29.32/29.16  tff(decl_78226, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_31: $i > $i).
% 29.32/29.16  tff(decl_78227, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_32: $i > $i).
% 29.32/29.16  tff(decl_78228, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_35: $i > $i).
% 29.32/29.16  tff(decl_78229, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_36: $i > $i).
% 29.32/29.16  tff(decl_78230, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_37: $i > $i).
% 29.32/29.16  tff(decl_78231, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_38: $i > $i).
% 29.32/29.16  tff(decl_78232, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_39: $i > $i).
% 29.32/29.16  tff(decl_78233, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_40: $i > $i).
% 29.32/29.16  tff(decl_78234, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_41: $i > $i).
% 29.32/29.16  tff(decl_78235, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_42: $i > $i).
% 29.32/29.16  tff(decl_78236, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_43: $i > $i).
% 29.32/29.16  tff(decl_78237, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_44: $i > $i).
% 29.32/29.16  tff(decl_78238, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_45: $i > $i).
% 29.32/29.16  tff(decl_78239, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_46: $i > $i).
% 29.32/29.16  tff(decl_78240, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_47: $i > $i).
% 29.32/29.16  tff(decl_78241, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_48: $i > $i).
% 29.32/29.16  tff(decl_78242, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_49: $i > $i).
% 29.32/29.16  tff(decl_78243, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_50: $i > $i).
% 29.32/29.16  tff(decl_78244, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_51: $i > $i).
% 29.32/29.16  tff(decl_78245, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_52: $i > $i).
% 29.32/29.16  tff(decl_78246, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_53: $i > $i).
% 29.32/29.16  tff(decl_78247, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_54: $i > $i).
% 29.32/29.16  tff(decl_78248, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_58: $i > $i).
% 29.32/29.16  tff(decl_78249, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_62: $i > $i).
% 29.32/29.16  tff(decl_78250, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_63: $i > $i).
% 29.32/29.16  tff(decl_78251, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_64: $i > $i).
% 29.32/29.16  tff(decl_78252, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_65: $i > $i).
% 29.32/29.16  tff(decl_78253, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_66: $i > $i).
% 29.32/29.16  tff(decl_78254, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_68: $i > $i).
% 29.32/29.16  tff(decl_78255, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_69: $i > $i).
% 29.32/29.16  tff(decl_78256, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_70: $i > $i).
% 29.32/29.16  tff(decl_78257, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_71: $i > $i).
% 29.32/29.16  tff(decl_78258, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_72: $i > $i).
% 29.32/29.16  tff(decl_78259, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_73: $i > $i).
% 29.32/29.16  tff(decl_78260, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_74: $i > $i).
% 29.32/29.16  tff(decl_78261, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_75: $i > $i).
% 29.32/29.16  tff(decl_78262, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_76: $i > $i).
% 29.32/29.16  tff(decl_78263, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_77: $i > $i).
% 29.32/29.16  tff(decl_78264, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_78: $i > $i).
% 29.32/29.16  tff(decl_78265, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_79: $i > $i).
% 29.32/29.16  tff(decl_78266, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_80: $i > $i).
% 29.32/29.16  tff(decl_78267, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_81: $i > $i).
% 29.32/29.16  tff(decl_78268, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_82: $i > $i).
% 29.32/29.16  tff(decl_78269, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_83: $i > $i).
% 29.32/29.16  tff(decl_78270, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_84: $i > $i).
% 29.32/29.16  tff(decl_78271, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_85: $i > $i).
% 29.32/29.16  tff(decl_78272, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_86: $i > $i).
% 29.32/29.16  tff(decl_78273, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_87: $i > $i).
% 29.32/29.16  tff(decl_78274, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_88: $i > $i).
% 29.32/29.16  tff(decl_78275, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_89: $i > $i).
% 29.32/29.16  tff(decl_78276, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_90: $i > $i).
% 29.32/29.16  tff(decl_78277, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_91: $i > $i).
% 29.32/29.16  tff(decl_78278, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_92: $i > $i).
% 29.32/29.16  tff(decl_78279, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_93: $i > $i).
% 29.32/29.16  tff(decl_78280, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_94: $i > $i).
% 29.32/29.16  tff(decl_78281, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_95: $i > $i).
% 29.32/29.16  tff(decl_78282, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_96: $i > $i).
% 29.32/29.16  tff(decl_78283, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_97: $i > $i).
% 29.32/29.16  tff(decl_78284, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_98: $i > $i).
% 29.32/29.16  tff(decl_78285, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_99: $i > $i).
% 29.32/29.16  tff(decl_78286, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_100: $i > $i).
% 29.32/29.16  tff(decl_78287, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_101: $i > $i).
% 29.32/29.16  tff(decl_78288, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_104: $i > $i).
% 29.32/29.16  tff(decl_78289, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_102: $i > $i).
% 29.32/29.16  tff(decl_78290, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_103: $i > $i).
% 29.32/29.16  tff(decl_78291, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_59: $i > $i).
% 29.32/29.16  tff(decl_78292, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_7: $i > $i).
% 29.32/29.16  tff(decl_78293, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_8: $i > $i).
% 29.32/29.16  tff(decl_78294, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_9: $i > $i).
% 29.32/29.16  tff(decl_78295, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_61: $i > $i).
% 29.32/29.16  tff(decl_78296, type, fn_uptake_of_calcium_ion_by_endoplasmic_reticulum_60: $i > $i).
% 29.32/29.16  tff(decl_78297, type, 'Uptake-Of-Calcium-Ion-By-Mitochondria': $i).
% 29.32/29.16  tff(decl_78298, type, 'The active transport of Ca2+ ions from cytosol into the mitochondria.': $i).
% 29.32/29.16  tff(decl_78299, type, 'uptake of calcium ion by mitochondrion': $i).
% 29.32/29.16  tff(decl_78300, type, 'uptake-of-calcium-ion-by-mitochondria': $i).
% 29.32/29.16  tff(decl_78301, type, fn_uptake_of_calcium_ion_by_mitochondria_1: $i > $i).
% 29.32/29.16  tff(decl_78302, type, fn_uptake_of_calcium_ion_by_mitochondria_3: $i > $i).
% 29.32/29.16  tff(decl_78303, type, fn_uptake_of_calcium_ion_by_mitochondria_4: $i > $i).
% 29.32/29.16  tff(decl_78304, type, fn_uptake_of_calcium_ion_by_mitochondria_5: $i > $i).
% 29.32/29.16  tff(decl_78305, type, fn_uptake_of_calcium_ion_by_mitochondria_6: $i > $i).
% 29.32/29.16  tff(decl_78306, type, fn_uptake_of_calcium_ion_by_mitochondria_7: $i > $i).
% 29.32/29.16  tff(decl_78307, type, fn_uptake_of_calcium_ion_by_mitochondria_12: $i > $i).
% 29.32/29.16  tff(decl_78308, type, fn_uptake_of_calcium_ion_by_mitochondria_13: $i > $i).
% 29.32/29.16  tff(decl_78309, type, fn_uptake_of_calcium_ion_by_mitochondria_14: $i > $i).
% 29.32/29.16  tff(decl_78310, type, fn_uptake_of_calcium_ion_by_mitochondria_15: $i > $i).
% 29.32/29.16  tff(decl_78311, type, fn_uptake_of_calcium_ion_by_mitochondria_16: $i > $i).
% 29.32/29.16  tff(decl_78312, type, fn_uptake_of_calcium_ion_by_mitochondria_17: $i > $i).
% 29.32/29.16  tff(decl_78313, type, fn_uptake_of_calcium_ion_by_mitochondria_18: $i > $i).
% 29.32/29.16  tff(decl_78314, type, fn_uptake_of_calcium_ion_by_mitochondria_19: $i > $i).
% 29.32/29.16  tff(decl_78315, type, fn_uptake_of_calcium_ion_by_mitochondria_20: $i > $i).
% 29.32/29.16  tff(decl_78316, type, fn_uptake_of_calcium_ion_by_mitochondria_21: $i > $i).
% 29.32/29.16  tff(decl_78317, type, fn_uptake_of_calcium_ion_by_mitochondria_22: $i > $i).
% 29.32/29.16  tff(decl_78318, type, fn_uptake_of_calcium_ion_by_mitochondria_23: $i > $i).
% 29.32/29.16  tff(decl_78319, type, fn_uptake_of_calcium_ion_by_mitochondria_24: $i > $i).
% 29.32/29.16  tff(decl_78320, type, fn_uptake_of_calcium_ion_by_mitochondria_25: $i > $i).
% 29.32/29.16  tff(decl_78321, type, fn_uptake_of_calcium_ion_by_mitochondria_26: $i > $i).
% 29.32/29.16  tff(decl_78322, type, fn_uptake_of_calcium_ion_by_mitochondria_27: $i > $i).
% 29.32/29.16  tff(decl_78323, type, fn_uptake_of_calcium_ion_by_mitochondria_28: $i > $i).
% 29.32/29.16  tff(decl_78324, type, fn_uptake_of_calcium_ion_by_mitochondria_29: $i > $i).
% 29.32/29.16  tff(decl_78325, type, fn_uptake_of_calcium_ion_by_mitochondria_30: $i > $i).
% 29.32/29.16  tff(decl_78326, type, fn_uptake_of_calcium_ion_by_mitochondria_31: $i > $i).
% 29.32/29.16  tff(decl_78327, type, fn_uptake_of_calcium_ion_by_mitochondria_32: $i > $i).
% 29.32/29.16  tff(decl_78328, type, fn_uptake_of_calcium_ion_by_mitochondria_33: $i > $i).
% 29.32/29.16  tff(decl_78329, type, fn_uptake_of_calcium_ion_by_mitochondria_34: $i > $i).
% 29.32/29.16  tff(decl_78330, type, fn_uptake_of_calcium_ion_by_mitochondria_35: $i > $i).
% 29.32/29.16  tff(decl_78331, type, fn_uptake_of_calcium_ion_by_mitochondria_36: $i > $i).
% 29.32/29.16  tff(decl_78332, type, fn_uptake_of_calcium_ion_by_mitochondria_37: $i > $i).
% 29.32/29.16  tff(decl_78333, type, fn_uptake_of_calcium_ion_by_mitochondria_38: $i > $i).
% 29.32/29.16  tff(decl_78334, type, fn_uptake_of_calcium_ion_by_mitochondria_39: $i > $i).
% 29.32/29.16  tff(decl_78335, type, fn_uptake_of_calcium_ion_by_mitochondria_40: $i > $i).
% 29.32/29.16  tff(decl_78336, type, fn_uptake_of_calcium_ion_by_mitochondria_41: $i > $i).
% 29.32/29.16  tff(decl_78337, type, fn_uptake_of_calcium_ion_by_mitochondria_42: $i > $i).
% 29.32/29.16  tff(decl_78338, type, fn_uptake_of_calcium_ion_by_mitochondria_43: $i > $i).
% 29.32/29.16  tff(decl_78339, type, fn_uptake_of_calcium_ion_by_mitochondria_44: $i > $i).
% 29.32/29.16  tff(decl_78340, type, fn_uptake_of_calcium_ion_by_mitochondria_45: $i > $i).
% 29.32/29.16  tff(decl_78341, type, fn_uptake_of_calcium_ion_by_mitochondria_46: $i > $i).
% 29.32/29.16  tff(decl_78342, type, fn_uptake_of_calcium_ion_by_mitochondria_47: $i > $i).
% 29.32/29.16  tff(decl_78343, type, fn_uptake_of_calcium_ion_by_mitochondria_48: $i > $i).
% 29.32/29.16  tff(decl_78344, type, fn_uptake_of_calcium_ion_by_mitochondria_49: $i > $i).
% 29.32/29.16  tff(decl_78345, type, fn_uptake_of_calcium_ion_by_mitochondria_50: $i > $i).
% 29.32/29.16  tff(decl_78346, type, fn_uptake_of_calcium_ion_by_mitochondria_51: $i > $i).
% 29.32/29.16  tff(decl_78347, type, fn_uptake_of_calcium_ion_by_mitochondria_52: $i > $i).
% 29.32/29.16  tff(decl_78348, type, fn_uptake_of_calcium_ion_by_mitochondria_53: $i > $i).
% 29.32/29.16  tff(decl_78349, type, fn_uptake_of_calcium_ion_by_mitochondria_54: $i > $i).
% 29.32/29.16  tff(decl_78350, type, fn_uptake_of_calcium_ion_by_mitochondria_55: $i > $i).
% 29.32/29.16  tff(decl_78351, type, fn_uptake_of_calcium_ion_by_mitochondria_56: $i > $i).
% 29.32/29.16  tff(decl_78352, type, fn_uptake_of_calcium_ion_by_mitochondria_57: $i > $i).
% 29.32/29.16  tff(decl_78353, type, fn_uptake_of_calcium_ion_by_mitochondria_58: $i > $i).
% 29.32/29.16  tff(decl_78354, type, fn_uptake_of_calcium_ion_by_mitochondria_59: $i > $i).
% 29.32/29.16  tff(decl_78355, type, fn_uptake_of_calcium_ion_by_mitochondria_60: $i > $i).
% 29.32/29.16  tff(decl_78356, type, fn_uptake_of_calcium_ion_by_mitochondria_61: $i > $i).
% 29.32/29.16  tff(decl_78357, type, fn_uptake_of_calcium_ion_by_mitochondria_62: $i > $i).
% 29.32/29.16  tff(decl_78358, type, fn_uptake_of_calcium_ion_by_mitochondria_63: $i > $i).
% 29.32/29.16  tff(decl_78359, type, fn_uptake_of_calcium_ion_by_mitochondria_64: $i > $i).
% 29.32/29.16  tff(decl_78360, type, fn_uptake_of_calcium_ion_by_mitochondria_65: $i > $i).
% 29.32/29.16  tff(decl_78361, type, fn_uptake_of_calcium_ion_by_mitochondria_66: $i > $i).
% 29.32/29.16  tff(decl_78362, type, fn_uptake_of_calcium_ion_by_mitochondria_67: $i > $i).
% 29.32/29.16  tff(decl_78363, type, fn_uptake_of_calcium_ion_by_mitochondria_68: $i > $i).
% 29.32/29.16  tff(decl_78364, type, fn_uptake_of_calcium_ion_by_mitochondria_69: $i > $i).
% 29.32/29.16  tff(decl_78365, type, fn_uptake_of_calcium_ion_by_mitochondria_70: $i > $i).
% 29.32/29.16  tff(decl_78366, type, fn_uptake_of_calcium_ion_by_mitochondria_71: $i > $i).
% 29.32/29.16  tff(decl_78367, type, fn_uptake_of_calcium_ion_by_mitochondria_74: $i > $i).
% 29.32/29.16  tff(decl_78368, type, fn_uptake_of_calcium_ion_by_mitochondria_75: $i > $i).
% 29.32/29.16  tff(decl_78369, type, fn_uptake_of_calcium_ion_by_mitochondria_76: $i > $i).
% 29.32/29.16  tff(decl_78370, type, fn_uptake_of_calcium_ion_by_mitochondria_77: $i > $i).
% 29.32/29.16  tff(decl_78371, type, fn_uptake_of_calcium_ion_by_mitochondria_11: $i > $i).
% 29.32/29.16  tff(decl_78372, type, fn_uptake_of_calcium_ion_by_mitochondria_72: $i > $i).
% 29.32/29.16  tff(decl_78373, type, fn_uptake_of_calcium_ion_by_mitochondria_10: $i > $i).
% 29.32/29.16  tff(decl_78374, type, fn_uptake_of_calcium_ion_by_mitochondria_73: $i > $i).
% 29.32/29.16  tff(decl_78375, type, fn_uptake_of_calcium_ion_by_mitochondria_9: $i > $i).
% 29.32/29.16  tff(decl_78376, type, uptake_of_cholesterol_by_human_cell_1: $i > $o).
% 29.32/29.16  tff(decl_78377, type, 'Uptake-Of-Cholesterol-By-Human-Cell': $i).
% 29.32/29.16  tff(decl_78378, type, 'Human cells use the process to take in cholesterol for use in the synthesis of membranes and as a precursor for the synthesis of other steroids.': $i).
% 29.32/29.16  tff(decl_78379, type, 'cholesterol uptake': $i).
% 29.32/29.16  tff(decl_78380, type, 'uptake of cholesterol by human cell': $i).
% 29.32/29.16  tff(decl_78381, type, 'uptake-of-cholesterol-by-human-cell': $i).
% 29.32/29.16  tff(decl_78382, type, fn_uptake_of_cholesterol_by_human_cell_1: $i > $i).
% 29.32/29.16  tff(decl_78383, type, fn_uptake_of_cholesterol_by_human_cell_2: $i > $i).
% 29.32/29.16  tff(decl_78384, type, uptake_of_hydrogen_ion_by_base_1: $i > $o).
% 29.32/29.16  tff(decl_78385, type, 'Uptake-Of-Hydrogen-Ion-By-Base': $i).
% 29.32/29.16  tff(decl_78386, type, 'The process by which a base, with its OH- functional group, takes up a hydrogen ion (H+) to form water and a salt.': $i).
% 29.32/29.16  tff(decl_78387, type, 'neutralization of base': $i).
% 29.32/29.16  tff(decl_78388, type, 'neutralization-of-base': $i).
% 29.32/29.16  tff(decl_78389, type, 'uptake of hydrogen ion by base': $i).
% 29.32/29.16  tff(decl_78390, type, 'uptake-of-hydrogen-ion-by-base': $i).
% 29.32/29.16  tff(decl_78391, type, fn_uptake_of_hydrogen_ion_by_base_1: $i > $i).
% 29.32/29.16  tff(decl_78392, type, fn_uptake_of_hydrogen_ion_by_base_2: $i > $i).
% 29.32/29.16  tff(decl_78393, type, fn_uptake_of_hydrogen_ion_by_base_4: $i > $i).
% 29.32/29.16  tff(decl_78394, type, fn_uptake_of_hydrogen_ion_by_base_5: $i > $i).
% 29.32/29.16  tff(decl_78395, type, fn_uptake_of_hydrogen_ion_by_base_8: $i > $i).
% 29.32/29.16  tff(decl_78396, type, fn_uptake_of_hydrogen_ion_by_base_9: $i > $i).
% 29.32/29.16  tff(decl_78397, type, fn_uptake_of_hydrogen_ion_by_base_10: $i > $i).
% 29.32/29.16  tff(decl_78398, type, fn_uptake_of_hydrogen_ion_by_base_11: $i > $i).
% 29.32/29.16  tff(decl_78399, type, fn_uptake_of_hydrogen_ion_by_base_12: $i > $i).
% 29.32/29.16  tff(decl_78400, type, fn_uptake_of_hydrogen_ion_by_base_13: $i > $i).
% 29.32/29.16  tff(decl_78401, type, fn_uptake_of_hydrogen_ion_by_base_14: $i > $i).
% 29.32/29.16  tff(decl_78402, type, fn_uptake_of_hydrogen_ion_by_base_7: $i > $i).
% 29.32/29.16  tff(decl_78403, type, fn_uptake_of_hydrogen_ion_by_base_3: $i > $i).
% 29.32/29.16  tff(decl_78404, type, fn_uptake_of_hydrogen_ion_by_base_6: $i > $i).
% 29.32/29.16  tff(decl_78405, type, uptake_of_nutrient_by_cell_using_proton_pump_1: $i > $o).
% 29.32/29.16  tff(decl_78406, type, 'Uptake-Of-Nutrient-By-Cell-Using-Proton-Pump': $i).
% 29.32/29.16  tff(decl_78407, type, 'The voltage and H+ gradient represents a dual energy source that can drive other processes, such as the uptake of nutrients.': $i).
% 29.32/29.16  tff(decl_78408, type, 'uptake of nutrient by cell using proton pump': $i).
% 29.32/29.16  tff(decl_78409, type, 'uptake-of-nutrient-by-cell-using-proton-pump': $i).
% 29.32/29.16  tff(decl_78410, type, fn_uptake_of_nutrient_by_cell_using_proton_pump_2: $i > $i).
% 29.32/29.16  tff(decl_78411, type, 'Uptake-Of-Nutrient-By-Plant-Cell-Using-Proton-Pump': $i).
% 29.32/29.16  tff(decl_78412, type, 'uptake of nutrient by plant cell using proton pump': $i).
% 29.32/29.16  tff(decl_78413, type, 'uptake-of-nutrient-by-plant-cell-using-proton-pump': $i).
% 29.32/29.16  tff(decl_78414, type, fn_uptake_of_nutrient_by_plant_cell_using_proton_pump_3: $i > $i).
% 29.32/29.16  tff(decl_78415, type, uptake_of_nutrient_by_prokaryote_using_proton_motive_force_1: $i > $o).
% 29.32/29.16  tff(decl_78416, type, 'Uptake-Of-Nutrient-By-Prokaryote-Using-Proton-Motive-Force': $i).
% 29.32/29.16  tff(decl_78417, type, 'This is the uptake of nutrient by prokaryote using proton motive force.': $i).
% 29.32/29.16  tff(decl_78418, type, 'uptake a nutrient': $i).
% 29.32/29.16  tff(decl_78419, type, 'uptake of nutrient by prokaryote using proton motive force': $i).
% 29.32/29.16  tff(decl_78420, type, 'uptake-of-nutrient-by-prokaryote-using-proton-motive-force': $i).
% 29.32/29.16  tff(decl_78421, type, fn_uptake_of_nutrient_by_prokaryote_using_proton_motive_force_1: $i > $i).
% 29.32/29.16  tff(decl_78422, type, 'Uracil': $i).
% 29.32/29.16  tff(decl_78423, type, 'One of the five most common nitrogenous bases which make up nucleotide monomers of nucleic acids. Uracil is present only in RNA.': $i).
% 29.32/29.16  tff(decl_78424, type, uracil: $i).
% 29.32/29.16  tff(decl_78425, type, fn_uracil_at_rna_strand_opposite_to_dna_strand_4: $i > $i).
% 29.32/29.16  tff(decl_78426, type, fn_uracil_at_rna_strand_opposite_to_dna_strand_3: $i > $i).
% 29.32/29.16  tff(decl_78427, type, 'Uracil-At-RNA-Strand-Opposite-To-DNA-Strand': $i).
% 29.32/29.16  tff(decl_78428, type, 'This is a situation in which uracil at RNA strand is opposite to DNA strand having Adenine.': $i).
% 29.32/29.16  tff(decl_78429, type, 'uracil at rna strand opposite to dna strand': $i).
% 29.32/29.16  tff(decl_78430, type, 'uracil-at-rna-strand-opposite-to-dna-strand': $i).
% 29.32/29.16  tff(decl_78431, type, fn_uracil_at_rna_strand_opposite_to_dna_strand_2: $i > $i).
% 29.32/29.16  tff(decl_78432, type, fn_uracil_at_rna_strand_opposite_to_rna_strand_3: $i > $i).
% 29.32/29.16  tff(decl_78433, type, fn_uracil_at_rna_strand_opposite_to_rna_strand_2: $i > $i).
% 29.32/29.16  tff(decl_78434, type, 'Uracil-At-RNA-Strand-Opposite-To-RNA-Strand': $i).
% 29.32/29.16  tff(decl_78435, type, 'This is a situation in which Uracil at RNA strand is located opposite to RNA Strand having Adenine.': $i).
% 29.32/29.16  tff(decl_78436, type, 'uracil at rna strand opposite to rna strand': $i).
% 29.32/29.16  tff(decl_78437, type, 'uracil-at-rna-strand-opposite-to-rna-strand': $i).
% 29.32/29.16  tff(decl_78438, type, fn_uracil_at_rna_strand_opposite_to_rna_strand_4: $i > $i).
% 29.32/29.16  tff(decl_78439, type, 'Uranium': $i).
% 29.32/29.16  tff(decl_78440, type, 'Uranium is a naturally-ocurring radioactive element with different isotopes including Uranium 238 which has a half-life of 4.5 billion years': $i).
% 29.32/29.16  tff(decl_78441, type, u: $i).
% 29.32/29.16  tff(decl_78442, type, uranium: $i).
% 29.32/29.16  tff(decl_78443, type, fn_uranium_1: $i > $i).
% 29.32/29.16  tff(decl_78444, type, fn_uranium_3: $i > $i).
% 29.32/29.16  tff(decl_78445, type, fn_uranium_4: $i > $i).
% 29.32/29.16  tff(decl_78446, type, fn_uranium_6: $i > $i).
% 29.32/29.16  tff(decl_78447, type, fn_uranium_7: $i > $i).
% 29.32/29.16  tff(decl_78448, type, fn_uranium_8: $i > $i).
% 29.32/29.16  tff(decl_78449, type, fn_uranium_9: $i > $i).
% 29.32/29.16  tff(decl_78450, type, fn_uranium_10: $i > $i).
% 29.32/29.16  tff(decl_78451, type, "238.0e0": $i).
% 29.32/29.16  tff(decl_78452, type, "92": $i).
% 29.32/29.16  tff(decl_78453, type, "143": $i).
% 29.32/29.16  tff(decl_78454, type, "146": $i).
% 29.32/29.16  tff(decl_78455, type, "1.38": $i).
% 29.32/29.16  tff(decl_78456, type, "238": $i).
% 29.32/29.16  tff(decl_78457, type, fn_uranium_12: $i > $i).
% 29.32/29.16  tff(decl_78458, type, fn_uranium_11: $i > $i).
% 29.32/29.16  tff(decl_78459, type, fn_uranium_13: $i > $i).
% 29.32/29.16  tff(decl_78460, type, uranium_235_1: $i > $o).
% 29.32/29.16  tff(decl_78461, type, 'Uranium-235': $i).
% 29.32/29.16  tff(decl_78462, type, 'This is one of the Phosphorous isotopes that possess one hundred forty three neutrons.': $i).
% 29.32/29.16  tff(decl_78463, type, 'uranium 235': $i).
% 29.32/29.16  tff(decl_78464, type, 'uranium-235': $i).
% 29.32/29.16  tff(decl_78465, type, uranium_isotope_1: $i > $o).
% 29.32/29.16  tff(decl_78466, type, fn_uranium_235_2: $i > $i).
% 29.32/29.16  tff(decl_78467, type, fn_uranium_235_3: $i > $i).
% 29.32/29.16  tff(decl_78468, type, "235.044e0": $i).
% 29.32/29.16  tff(decl_78469, type, fn_uranium_isotope_3: $i > $i).
% 29.32/29.16  tff(decl_78470, type, fn_uranium_235_1: $i > $i).
% 29.32/29.16  tff(decl_78471, type, uranium_238_1: $i > $o).
% 29.32/29.16  tff(decl_78472, type, 'Uranium-238': $i).
% 29.32/29.16  tff(decl_78473, type, 'This is one of the Phosphorous isotopes that possess one hundred forty six neutrons.': $i).
% 29.32/29.16  tff(decl_78474, type, 'uranium 238': $i).
% 29.32/29.16  tff(decl_78475, type, 'uranium-238': $i).
% 29.32/29.16  tff(decl_78476, type, fn_uranium_238_2: $i > $i).
% 29.32/29.16  tff(decl_78477, type, fn_uranium_238_3: $i > $i).
% 29.32/29.16  tff(decl_78478, type, "237.049e0": $i).
% 29.32/29.16  tff(decl_78479, type, fn_uranium_238_1: $i > $i).
% 29.32/29.16  tff(decl_78480, type, 'Uranium-Isotope': $i).
% 29.32/29.16  tff(decl_78481, type, 'All the uranium isoptopes have 92 protons and 92 electrons. They differ in their neutron number.': $i).
% 29.32/29.16  tff(decl_78482, type, 'isotope of uranium': $i).
% 29.32/29.16  tff(decl_78483, type, 'uranium isotope': $i).
% 29.32/29.16  tff(decl_78484, type, 'uranium-isotope': $i).
% 29.32/29.16  tff(decl_78485, type, fn_uranium_isotope_1: $i > $i).
% 29.32/29.16  tff(decl_78486, type, fn_uranium_isotope_2: $i > $i).
% 29.32/29.16  tff(decl_78487, type, fn_uranium_isotope_6: $i > $i).
% 29.32/29.16  tff(decl_78488, type, "1.38e0": $i).
% 29.32/29.16  tff(decl_78489, type, "92.0e0": $i).
% 29.32/29.16  tff(decl_78490, type, fn_uranium_isotope_5: $i > $i).
% 29.32/29.16  tff(decl_78491, type, 'Urea': $i).
% 29.32/29.16  tff(decl_78492, type, 'A soluble nitrogenous waste molecule from the catabolism of protein and nucleic acids produced in the liverand excreted by the kidneys of some types of vertebrates.': $i).
% 29.32/29.16  tff(decl_78493, type, 'urea nitrogen': $i).
% 29.32/29.16  tff(decl_78494, type, 'urea-nitrogen': $i).
% 29.32/29.16  tff(decl_78495, type, 'co(nh2)2': $i).
% 29.32/29.16  tff(decl_78496, type, urea: $i).
% 29.32/29.16  tff(decl_78497, type, fn_urea_1: $i > $i).
% 29.32/29.16  tff(decl_78498, type, fn_urea_2: $i > $i).
% 29.32/29.16  tff(decl_78499, type, urea_substance_1: $i > $o).
% 29.32/29.16  tff(decl_78500, type, 'Urea-Substance': $i).
% 29.32/29.16  tff(decl_78501, type, 'Substance consisting of urea molecules.': $i).
% 29.32/29.16  tff(decl_78502, type, 'substance of urea': $i).
% 29.32/29.16  tff(decl_78503, type, 'urea substance': $i).
% 29.32/29.16  tff(decl_78504, type, 'urea-substance': $i).
% 29.32/29.16  tff(decl_78505, type, fn_urea_substance_1: $i > $i).
% 29.32/29.16  tff(decl_78506, type, fn_urea_substance_3: $i > $i).
% 29.32/29.16  tff(decl_78507, type, fn_urea_substance_2: $i > $i).
% 29.32/29.16  tff(decl_78508, type, ureter_1: $i > $o).
% 29.32/29.16  tff(decl_78509, type, 'Ureter': $i).
% 29.32/29.16  tff(decl_78510, type, 'A tube that carries filtrate from the kidney to the urinary bladder.': $i).
% 29.32/29.16  tff(decl_78511, type, ureter: $i).
% 29.32/29.16  tff(decl_78512, type, urethra_1: $i > $o).
% 29.32/29.16  tff(decl_78513, type, 'Urethra': $i).
% 29.32/29.16  tff(decl_78514, type, 'A tube that drains the urinary bladder. In male mammals the urethra is also the tube from which semen is ejaculated.': $i).
% 29.32/29.16  tff(decl_78515, type, urethra: $i).
% 29.32/29.16  tff(decl_78516, type, 'Uric-Acid': $i).
% 29.32/29.16  tff(decl_78517, type, 'A waste product from the digestion of proteins and nucleic acids in reptiles (including birds) and terrestrial invertebrates. Compared to other forms of nitrogenous waste, uric acid is the most water-conserving and the least toxic.': $i).
% 29.32/29.16  tff(decl_78518, type, 'uric acid': $i).
% 29.32/29.16  tff(decl_78519, type, 'uric-acid': $i).
% 29.32/29.16  tff(decl_78520, type, urinary_bladder_1: $i > $o).
% 29.32/29.16  tff(decl_78521, type, 'Urinary-Bladder': $i).
% 29.32/29.16  tff(decl_78522, type, 'The organ that collects urine from the kidneys and stores it prior to urination.': $i).
% 29.32/29.16  tff(decl_78523, type, bladder: $i).
% 29.32/29.16  tff(decl_78524, type, 'urinary bladder': $i).
% 29.32/29.16  tff(decl_78525, type, 'urinary-bladder': $i).
% 29.32/29.16  tff(decl_78526, type, 'Urine': $i).
% 29.32/29.16  tff(decl_78527, type, 'A liquid form of exrement containing water, salts, and urea. Urine is produced by the kidneys and is stored in the bladder before being eliminated by urination.': $i).
% 29.32/29.16  tff(decl_78528, type, urine: $i).
% 29.32/29.16  tff(decl_78529, type, fn_urine_1: $i > $i).
% 29.32/29.16  tff(decl_78530, type, 'Useful-Product': $i).
% 29.32/29.16  tff(decl_78531, type, 'A product with practical value and that is beneficial.': $i).
% 29.32/29.16  tff(decl_78532, type, 'useful product': $i).
% 29.32/29.16  tff(decl_78533, type, 'useful-product': $i).
% 29.32/29.16  tff(decl_78534, type, 'Uterus': $i).
% 29.32/29.16  tff(decl_78535, type, 'An organ in female animals in which eggs are fertilized and/or offspring develop.': $i).
% 29.32/29.16  tff(decl_78536, type, uterus: $i).
% 29.32/29.16  tff(decl_78537, type, 'Utricle': $i).
% 29.32/29.16  tff(decl_78538, type, 'In the vertebrate ear, one of two chambers containing sensory cells that translate movements of the head to neural impulses. The utricle is part of the vestibular system, which is important in maintaining the sense of balance, or equilibrium.': $i).
% 29.32/29.16  tff(decl_78539, type, utricle: $i).
% 29.32/29.16  tff(decl_78540, type, va_element_1: $i > $o).
% 29.32/29.16  tff(decl_78541, type, 'VA-Element': $i).
% 29.32/29.16  tff(decl_78542, type, 'Elements in group 5A of the periodic table are N, P, As, Sb and Bi.': $i).
% 29.32/29.16  tff(decl_78543, type, va: $i).
% 29.32/29.16  tff(decl_78544, type, 'group va elements': $i).
% 29.32/29.16  tff(decl_78545, type, 'group-va-elements': $i).
% 29.32/29.16  tff(decl_78546, type, 'group 15 elements': $i).
% 29.32/29.16  tff(decl_78547, type, 'group-15-elements': $i).
% 29.32/29.16  tff(decl_78548, type, 'element of va': $i).
% 29.32/29.16  tff(decl_78549, type, 'va element': $i).
% 29.32/29.16  tff(decl_78550, type, 'va-element': $i).
% 29.32/29.16  tff(decl_78551, type, vaccine_1: $i > $o).
% 29.32/29.16  tff(decl_78552, type, 'Vaccine': $i).
% 29.32/29.16  tff(decl_78553, type, 'A harmless variant or derivative of a pathogen that stimulates a host\\s immune system to mount defenses against the pathogen.': $i).
% 29.32/29.16  tff(decl_78554, type, 'medical weapon used to fight virus': $i).
% 29.32/29.16  tff(decl_78555, type, 'medical weapon used to fight viral infections': $i).
% 29.32/29.16  tff(decl_78556, type, innoculation: $i).
% 29.32/29.16  tff(decl_78557, type, vaccine: $i).
% 29.32/29.16  tff(decl_78558, type, fn_vaccine_1: $i > $i).
% 29.32/29.16  tff(decl_78559, type, fn_vaccine_2: $i > $i).
% 29.32/29.16  tff(decl_78560, type, fn_vaccine_3: $i > $i).
% 29.32/29.16  tff(decl_78561, type, fn_vaccine_4: $i > $i).
% 29.32/29.16  tff(decl_78562, type, fn_vaccine_5: $i > $i).
% 29.32/29.16  tff(decl_78563, type, fn_vaccine_6: $i > $i).
% 29.32/29.16  tff(decl_78564, type, 'Vacuole': $i).
% 29.32/29.16  tff(decl_78565, type, 'A membrane-bound sac whose specialized function varies in different kinds of cells. Vacuoles are larger than vesicles, which are structurally similar.': $i).
% 29.32/29.16  tff(decl_78566, type, vacuole: $i).
% 29.32/29.16  tff(decl_78567, type, fn_vacuole_1: $i > $i).
% 29.32/29.16  tff(decl_78568, type, fn_vesicle_4: $i > $i).
% 29.32/29.16  tff(decl_78569, type, fn_vesicle_3: $i > $i).
% 29.32/29.16  tff(decl_78570, type, fn_vesicle_13: $i > $i).
% 29.32/29.16  tff(decl_78571, type, vacuole_content_1: $i > $o).
% 29.32/29.16  tff(decl_78572, type, 'Vacuole-content': $i).
% 29.32/29.16  tff(decl_78573, type, 'The contents inside the vacuole': $i).
% 29.32/29.16  tff(decl_78574, type, 'content of vacuole': $i).
% 29.32/29.16  tff(decl_78575, type, 'vacuole content': $i).
% 29.32/29.16  tff(decl_78576, type, 'vacuole-content': $i).
% 29.32/29.16  tff(decl_78577, type, vagina_1: $i > $o).
% 29.32/29.16  tff(decl_78578, type, 'Vagina': $i).
% 29.32/29.16  tff(decl_78579, type, 'A muscular tract between the uterus and the outside of the body; in mammals, young are born through the vagina.': $i).
% 29.32/29.16  tff(decl_78580, type, vagina: $i).
% 29.32/29.16  tff(decl_78581, type, fn_valence_electron_2: $i > $i).
% 29.32/29.16  tff(decl_78582, type, 'Valence-Electron': $i).
% 29.32/29.16  tff(decl_78583, type, 'An electron in the outermost electron shell of an atom.  Valence electrons can participate in bonds with other atoms.': $i).
% 29.32/29.16  tff(decl_78584, type, 'outer electron': $i).
% 29.32/29.16  tff(decl_78585, type, 'electron of valence': $i).
% 29.32/29.16  tff(decl_78586, type, 'valence electron': $i).
% 29.32/29.16  tff(decl_78587, type, 'valence-electron': $i).
% 29.32/29.16  tff(decl_78588, type, fn_valence_shell_4: $i > $i).
% 29.32/29.16  tff(decl_78589, type, fn_valence_shell_5: $i > $i).
% 29.32/29.16  tff(decl_78590, type, 'Valence-Shell': $i).
% 29.32/29.16  tff(decl_78591, type, 'The outermost shell of an atom. It contains the valence electrons that determine the chemical reactivity of the atom.': $i).
% 29.32/29.16  tff(decl_78592, type, 'outermost shell': $i).
% 29.32/29.16  tff(decl_78593, type, 'outermost energy shell': $i).
% 29.32/29.16  tff(decl_78594, type, 'valence energy level': $i).
% 29.32/29.16  tff(decl_78595, type, 'valence energy shell': $i).
% 29.32/29.16  tff(decl_78596, type, 'shell of valence': $i).
% 29.32/29.16  tff(decl_78597, type, 'valence shell': $i).
% 29.32/29.16  tff(decl_78598, type, 'valence-shell': $i).
% 29.32/29.16  tff(decl_78599, type, fn_valence_shell_2: $i > $i).
% 29.32/29.16  tff(decl_78600, type, fn_valence_shell_3: $i > $i).
% 29.32/29.16  tff(decl_78601, type, 'Valence-Value': $i).
% 29.32/29.16  tff(decl_78602, type, valency: $i).
% 29.32/29.16  tff(decl_78603, type, 'bonding capacity': $i).
% 29.32/29.16  tff(decl_78604, type, valence: $i).
% 29.32/29.16  tff(decl_78605, type, 'value of valence': $i).
% 29.32/29.16  tff(decl_78606, type, 'valence value': $i).
% 29.32/29.16  tff(decl_78607, type, 'valence-value': $i).
% 29.32/29.16  tff(decl_78608, type, 'Valine': $i).
% 29.32/29.16  tff(decl_78609, type, valine: $i).
% 29.32/29.16  tff(decl_78610, type, 'Valve': $i).
% 29.32/29.16  tff(decl_78611, type, 'A device that regulates, directs or controls the flow of a fluid by opening, closing, or partially obstructing various passageways.': $i).
% 29.32/29.16  tff(decl_78612, type, valve: $i).
% 29.32/29.16  tff(decl_78613, type, 'Van-Der-Waal-Interaction': $i).
% 29.32/29.16  tff(decl_78614, type, 'Weak attractions between molecules or parts of molecules that result from the transient local partial charges.': $i).
% 29.32/29.16  tff(decl_78615, type, 'van der waal\\s force': $i).
% 29.32/29.16  tff(decl_78616, type, 'van der waal force': $i).
% 29.32/29.16  tff(decl_78617, type, 'van der waals force': $i).
% 29.32/29.16  tff(decl_78618, type, 'van der waals interaction': $i).
% 29.32/29.16  tff(decl_78619, type, 'van der waal interaction': $i).
% 29.32/29.16  tff(decl_78620, type, 'van-der-waal-interaction': $i).
% 29.32/29.16  tff(decl_78621, type, fn_van_der_waal_interaction_3: $i > $i).
% 29.32/29.16  tff(decl_78622, type, fn_van_der_waal_interaction_4: $i > $i).
% 29.32/29.16  tff(decl_78623, type, 'Vanadium': $i).
% 29.32/29.16  tff(decl_78624, type, 'Vanadium is a metal atom with atomic number 23. It is represented by the symbol V.': $i).
% 29.32/29.16  tff(decl_78625, type, vanadium: $i).
% 29.32/29.16  tff(decl_78626, type, 'V': $i).
% 29.32/29.16  tff(decl_78627, type, fn_vanadium_3: $i > $i).
% 29.32/29.16  tff(decl_78628, type, fn_vanadium_4: $i > $i).
% 29.32/29.16  tff(decl_78629, type, fn_vanadium_5: $i > $i).
% 29.32/29.16  tff(decl_78630, type, fn_vanadium_9: $i > $i).
% 29.32/29.16  tff(decl_78631, type, fn_vanadium_10: $i > $i).
% 29.32/29.16  tff(decl_78632, type, fn_vanadium_11: $i > $i).
% 29.32/29.16  tff(decl_78633, type, fn_vanadium_12: $i > $i).
% 29.32/29.16  tff(decl_78634, type, "1.63": $i).
% 29.32/29.16  tff(decl_78635, type, "50.94": $i).
% 29.32/29.16  tff(decl_78636, type, fn_vanadium_7: $i > $i).
% 29.32/29.16  tff(decl_78637, type, fn_vanadium_8: $i > $i).
% 29.32/29.16  tff(decl_78638, type, fn_vanadium_6: $i > $i).
% 29.32/29.16  tff(decl_78639, type, 'Vancomycin': $i).
% 29.32/29.16  tff(decl_78640, type, 'An antibiotic used in the treatment of bacterial infections.': $i).
% 29.32/29.16  tff(decl_78641, type, vancomycin: $i).
% 29.32/29.16  tff(decl_78642, type, 'Vapor': $i).
% 29.32/29.16  tff(decl_78643, type, 'A substance that is usually a solid or liquid suspended in air.': $i).
% 29.32/29.16  tff(decl_78644, type, vapour: $i).
% 29.32/29.16  tff(decl_78645, type, vapor: $i).
% 29.32/29.16  tff(decl_78646, type, 'Variable-Domain': $i).
% 29.32/29.16  tff(decl_78647, type, 'A type of protein domain present in a homeodomain protein': $i).
% 29.32/29.16  tff(decl_78648, type, 'domain of variable': $i).
% 29.32/29.16  tff(decl_78649, type, 'variable domain': $i).
% 29.32/29.16  tff(decl_78650, type, 'variable-domain': $i).
% 29.32/29.16  tff(decl_78651, type, fn_variable_domain_3: $i > $i).
% 29.32/29.16  tff(decl_78652, type, fn_variable_domain_4: $i > $i).
% 29.32/29.16  tff(decl_78653, type, fn_variable_domain_5: $i > $i).
% 29.32/29.16  tff(decl_78654, type, fn_variable_domain_6: $i > $i).
% 29.32/29.16  tff(decl_78655, type, fn_variable_domain_7: $i > $i).
% 29.32/29.16  tff(decl_78656, type, fn_variable_domain_8: $i > $i).
% 29.32/29.16  tff(decl_78657, type, fn_variable_domain_9: $i > $i).
% 29.32/29.16  tff(decl_78658, type, fn_variable_domain_10: $i > $i).
% 29.32/29.16  tff(decl_78659, type, fn_variable_domain_11: $i > $i).
% 29.32/29.16  tff(decl_78660, type, variable_region_1: $i > $o).
% 29.32/29.16  tff(decl_78661, type, 'Variable-Region': $i).
% 29.32/29.16  tff(decl_78662, type, 'A region on an immunoglobulin polypeptide chain which gives a particular antibody its unique function.': $i).
% 29.32/29.16  tff(decl_78663, type, 'v region': $i).
% 29.32/29.16  tff(decl_78664, type, 'region of variable': $i).
% 29.32/29.16  tff(decl_78665, type, 'variable region': $i).
% 29.32/29.16  tff(decl_78666, type, 'variable-region': $i).
% 29.32/29.16  tff(decl_78667, type, fn_variable_region_1: $i > $i).
% 29.32/29.16  tff(decl_78668, type, fn_variable_region_2: $i > $i).
% 29.32/29.16  tff(decl_78669, type, fn_variable_region_3: $i > $i).
% 29.32/29.16  tff(decl_78670, type, fn_variable_region_4: $i > $i).
% 29.32/29.16  tff(decl_78671, type, fn_variable_region_5: $i > $i).
% 29.32/29.16  tff(decl_78672, type, fn_variable_region_6: $i > $i).
% 29.32/29.16  tff(decl_78673, type, fn_variable_region_7: $i > $i).
% 29.32/29.16  tff(decl_78674, type, fn_variable_region_8: $i > $i).
% 29.32/29.16  tff(decl_78675, type, fn_variable_region_9: $i > $i).
% 29.32/29.16  tff(decl_78676, type, 'Variable-Region-DNA-Sequence': $i).
% 29.32/29.16  tff(decl_78677, type, 'A sequence of DNA providing the code for the variable region on an immunoglobulin polypeptide chain.': $i).
% 29.32/29.16  tff(decl_78678, type, 'variable region dna sequence': $i).
% 29.32/29.16  tff(decl_78679, type, 'variable-region-dna-sequence': $i).
% 29.32/29.16  tff(decl_78680, type, fn_variable_region_dna_sequence_1: $i > $i).
% 29.32/29.16  tff(decl_78681, type, fn_variable_region_dna_sequence_2: $i > $i).
% 29.32/29.16  tff(decl_78682, type, fn_variable_region_dna_sequence_3: $i > $i).
% 29.32/29.16  tff(decl_78683, type, fn_variable_region_dna_sequence_4: $i > $i).
% 29.32/29.16  tff(decl_78684, type, fn_variable_region_dna_sequence_5: $i > $i).
% 29.32/29.16  tff(decl_78685, type, variable_region_0: $i).
% 29.32/29.16  tff(decl_78686, type, variable_region_dna_sequence_0: $i).
% 29.32/29.16  tff(decl_78687, type, vas_deferens_1: $i > $o).
% 29.32/29.16  tff(decl_78688, type, 'Vas-Deferens': $i).
% 29.32/29.16  tff(decl_78689, type, 'In male manmals, the tube that transports sperm from the epididymis to the urethra.': $i).
% 29.32/29.16  tff(decl_78690, type, 'vas deferens': $i).
% 29.32/29.16  tff(decl_78691, type, 'vas-deferens': $i).
% 29.32/29.16  tff(decl_78692, type, 'vas-deferen': $i).
% 29.32/29.16  tff(decl_78693, type, 'Vasa-Recta': $i).
% 29.32/29.16  tff(decl_78694, type, 'A series of capillaries in the medulla of the kidney that lie parallel to and serve the loop of Henle.': $i).
% 29.32/29.16  tff(decl_78695, type, 'vasa rectum': $i).
% 29.32/29.16  tff(decl_78696, type, 'vasa-recta': $i).
% 29.32/29.16  tff(decl_78697, type, 'Vascular-Cambium': $i).
% 29.32/29.16  tff(decl_78698, type, 'A lateral meristem in woody plants that gives rise to secondary xylem and secondary phloem.': $i).
% 29.32/29.16  tff(decl_78699, type, 'vascular cambium': $i).
% 29.32/29.16  tff(decl_78700, type, 'vascular-cambium': $i).
% 29.32/29.16  tff(decl_78701, type, 'Vascular-Plant': $i).
% 29.32/29.16  tff(decl_78702, type, 'A plant that has vascular tissue. Most living plant species are vascular plants; exceptions include mosses, hornworts, and liverworts.': $i).
% 29.32/29.16  tff(decl_78703, type, 'vascular plant': $i).
% 29.32/29.16  tff(decl_78704, type, 'vascular-plant': $i).
% 29.32/29.16  tff(decl_78705, type, fn_vascular_plant_3: $i > $i).
% 29.32/29.16  tff(decl_78706, type, fn_vascular_plant_4: $i > $i).
% 29.32/29.16  tff(decl_78707, type, fn_vascular_plant_5: $i > $i).
% 29.32/29.16  tff(decl_78708, type, fn_vascular_plant_10: $i > $i).
% 29.32/29.16  tff(decl_78709, type, 'Vascular-Tissue': $i).
% 29.32/29.16  tff(decl_78710, type, 'In plants, tissue that consists of cells joined into tubes for the transport of water and nutrients throughout the plant.': $i).
% 29.32/29.16  tff(decl_78711, type, 'vascular tissue': $i).
% 29.32/29.16  tff(decl_78712, type, 'vascular-tissue': $i).
% 29.32/29.16  tff(decl_78713, type, 'Vascular-Tissue-System': $i).
% 29.32/29.16  tff(decl_78714, type, 'Vascular tissue system connects leaves and roots, allowing sugars to move from leaves to roots in the phloem and allowing water and minerals to move to the leaves in the xylem.': $i).
% 29.32/29.16  tff(decl_78715, type, 'vascular tissue system': $i).
% 29.32/29.16  tff(decl_78716, type, 'vascular-tissue-system': $i).
% 29.32/29.16  tff(decl_78717, type, 'Vasectomy': $i).
% 29.32/29.16  tff(decl_78718, type, 'A form of permanent male sterilization in which each vas deferens is cut and sealed to prevent the passage of sperm to the urethra.': $i).
% 29.32/29.16  tff(decl_78719, type, vasectomize: $i).
% 29.32/29.16  tff(decl_78720, type, vasectomy: $i).
% 29.32/29.16  tff(decl_78721, type, vasocongestion_1: $i > $o).
% 29.32/29.16  tff(decl_78722, type, 'Vasocongestion': $i).
% 29.32/29.16  tff(decl_78723, type, 'A localized swelling of tissues caused by increased blood flow and blood pressure to the area.': $i).
% 29.32/29.16  tff(decl_78724, type, vasocongestion: $i).
% 29.32/29.16  tff(decl_78725, type, vasoconstriction_1: $i > $o).
% 29.32/29.16  tff(decl_78726, type, 'Vasoconstriction': $i).
% 29.32/29.16  tff(decl_78727, type, 'A narrowing of blood vessel diameter caused by muscular contraction of the walls of the vessels.': $i).
% 29.32/29.16  tff(decl_78728, type, 'blood vessel constriction': $i).
% 29.32/29.16  tff(decl_78729, type, vasoconstriction: $i).
% 29.32/29.16  tff(decl_78730, type, vasodilation_1: $i > $o).
% 29.32/29.16  tff(decl_78731, type, 'Vasodilation': $i).
% 29.32/29.16  tff(decl_78732, type, 'A widening of blood vessel diameter caused by relaxation of muscles in the walls of the vessels.': $i).
% 29.32/29.16  tff(decl_78733, type, 'blood vessel dilation': $i).
% 29.32/29.16  tff(decl_78734, type, vasodilation: $i).
% 29.32/29.16  tff(decl_78735, type, vector_1: $i > $o).
% 29.32/29.16  tff(decl_78736, type, 'Vector': $i).
% 29.32/29.16  tff(decl_78737, type, 'An organism that transmits pathogens from a reservoir to a new host.': $i).
% 29.32/29.16  tff(decl_78738, type, vector: $i).
% 29.32/29.16  tff(decl_78739, type, vegetable_1: $i > $o).
% 29.32/29.16  tff(decl_78740, type, 'Vegetable': $i).
% 29.32/29.16  tff(decl_78741, type, 'The part of a plant that is used for food, exclusive of fruit and seeds.': $i).
% 29.32/29.16  tff(decl_78742, type, vegetable: $i).
% 29.32/29.16  tff(decl_78743, type, fn_vegetable_2: $i > $i).
% 29.32/29.16  tff(decl_78744, type, fn_vegetable_3: $i > $i).
% 29.32/29.16  tff(decl_78745, type, fn_vegetable_4: $i > $i).
% 29.32/29.16  tff(decl_78746, type, fn_vegetable_5: $i > $i).
% 29.32/29.16  tff(decl_78747, type, fn_vegetable_6: $i > $i).
% 29.32/29.16  tff(decl_78748, type, 'Vegetable-Oil': $i).
% 29.32/29.16  tff(decl_78749, type, 'It is a form of lipid present generally in seeds.': $i).
% 29.32/29.16  tff(decl_78750, type, 'oil of vegetable': $i).
% 29.32/29.16  tff(decl_78751, type, 'vegetable oil': $i).
% 29.32/29.16  tff(decl_78752, type, 'vegetable-oil': $i).
% 29.32/29.16  tff(decl_78753, type, fn_vegetable_oil_2: $i > $i).
% 29.32/29.16  tff(decl_78754, type, fn_vegetable_oil_3: $i > $i).
% 29.32/29.16  tff(decl_78755, type, fn_vegetable_oil_4: $i > $i).
% 29.32/29.16  tff(decl_78756, type, vegetal_pole_1: $i > $o).
% 29.32/29.16  tff(decl_78757, type, 'Vegetal-Pole': $i).
% 29.32/29.16  tff(decl_78758, type, 'The pole in the hemisphere of an egg that contains the highest concentration of yolk.': $i).
% 29.32/29.16  tff(decl_78759, type, 'vegetal pole': $i).
% 29.32/29.16  tff(decl_78760, type, 'vegetal-pole': $i).
% 29.32/29.16  tff(decl_78761, type, 'Vegetation': $i).
% 29.32/29.16  tff(decl_78762, type, 'All the plant life in a particular geographic region or time period.': $i).
% 29.32/29.16  tff(decl_78763, type, 'plant community': $i).
% 29.32/29.16  tff(decl_78764, type, vegetation: $i).
% 29.32/29.16  tff(decl_78765, type, 'Vegetative-Reproduction': $i).
% 29.32/29.16  tff(decl_78766, type, 'A form of asexual reproduction in plants, in which new individuals are formed without the use of seeds or spores.': $i).
% 29.32/29.16  tff(decl_78767, type, 'vegetative reproduction': $i).
% 29.32/29.16  tff(decl_78768, type, 'vegetative-reproduction': $i).
% 29.32/29.16  tff(decl_78769, type, vehicle_1: $i > $o).
% 29.32/29.16  tff(decl_78770, type, 'Vehicle': $i).
% 29.32/29.16  tff(decl_78771, type, 'The object or medium which transports the object moved during a move event.': $i).
% 29.32/29.16  tff(decl_78772, type, vehicle: $i).
% 29.32/29.16  tff(decl_78773, type, fomite: $i).
% 29.32/29.16  tff(decl_78774, type, fn_vehicle_1: $i > $i).
% 29.32/29.16  tff(decl_78775, type, 'Vein': $i).
% 29.32/29.16  tff(decl_78776, type, '(1) In animals, a blood vessel that transports blood towards the heart; (2) in plants, a vascular bundle in a leaf.': $i).
% 29.32/29.16  tff(decl_78777, type, vein: $i).
% 29.32/29.16  tff(decl_78778, type, 'Velocity-Constant': $i).
% 29.32/29.16  tff(decl_78779, type, 'constant of velocity': $i).
% 29.32/29.16  tff(decl_78780, type, 'velocity constant': $i).
% 29.32/29.16  tff(decl_78781, type, 'velocity-constant': $i).
% 29.32/29.16  tff(decl_78782, type, velocity_scale_1: $i > $o).
% 29.32/29.16  tff(decl_78783, type, 'Velocity-Scale': $i).
% 29.32/29.16  tff(decl_78784, type, 'scale of velocity': $i).
% 29.32/29.16  tff(decl_78785, type, 'velocity scale': $i).
% 29.32/29.16  tff(decl_78786, type, 'velocity-scale': $i).
% 29.32/29.16  tff(decl_78787, type, venomous_organism_1: $i > $o).
% 29.32/29.16  tff(decl_78788, type, 'Venomous-Organism': $i).
% 29.32/29.16  tff(decl_78789, type, 'Organism which actively produces and delivers venom as a defense or predation mechanism.': $i).
% 29.32/29.16  tff(decl_78790, type, 'venomous organism': $i).
% 29.32/29.16  tff(decl_78791, type, 'venomous-organism': $i).
% 29.32/29.16  tff(decl_78792, type, ventilation_1: $i > $o).
% 29.32/29.16  tff(decl_78793, type, 'Ventilation': $i).
% 29.32/29.16  tff(decl_78794, type, 'The active movement of water or air over a gas exchange surface.': $i).
% 29.32/29.16  tff(decl_78795, type, 'flow of air': $i).
% 29.32/29.16  tff(decl_78796, type, ventilate: $i).
% 29.32/29.16  tff(decl_78797, type, ventilation: $i).
% 29.32/29.16  tff(decl_78798, type, ventral_1: $i > $o).
% 29.32/29.16  tff(decl_78799, type, 'Ventral': $i).
% 29.32/29.16  tff(decl_78800, type, 'Region on the belly side of the body.  Opposite of dorsal.': $i).
% 29.32/29.16  tff(decl_78801, type, 'belly side,': $i).
% 29.32/29.16  tff(decl_78802, type, 'front side': $i).
% 29.32/29.16  tff(decl_78803, type, 'belly side': $i).
% 29.32/29.16  tff(decl_78804, type, ventral: $i).
% 29.32/29.16  tff(decl_78805, type, 'Ventral-Surface': $i).
% 29.32/29.16  tff(decl_78806, type, 'The anterior surface or the front side of an animal is called the ventral surface.': $i).
% 29.32/29.16  tff(decl_78807, type, 'surface of ventral': $i).
% 29.32/29.16  tff(decl_78808, type, 'ventral surface': $i).
% 29.32/29.16  tff(decl_78809, type, 'ventral-surface': $i).
% 29.32/29.16  tff(decl_78810, type, 'Ventricle': $i).
% 29.32/29.16  tff(decl_78811, type, '(1) The heart chamber that is contractile and pumps blood; (2) one of a system of structures in the brain that are continuous with the central canal of the spinal cord and filled with cerebrospinal fluid.': $i).
% 29.32/29.16  tff(decl_78812, type, ventricle: $i).
% 29.32/29.16  tff(decl_78813, type, 'Venule': $i).
% 29.32/29.16  tff(decl_78814, type, 'A tiny vessel that carries blood returning from a capillary bed to a vein.': $i).
% 29.32/29.16  tff(decl_78815, type, venule: $i).
% 29.32/29.16  tff(decl_78816, type, 'Vernalization': $i).
% 29.32/29.16  tff(decl_78817, type, 'The requirement of a period of exposure to cold temperatures before some plants will flower.': $i).
% 29.32/29.16  tff(decl_78818, type, 'cold induced flowering': $i).
% 29.32/29.16  tff(decl_78819, type, 'cold-induced flowering': $i).
% 29.32/29.16  tff(decl_78820, type, vernalization: $i).
% 29.32/29.16  tff(decl_78821, type, version_1: $i > $o).
% 29.32/29.16  tff(decl_78822, type, 'Version': $i).
% 29.32/29.16  tff(decl_78823, type, 'Tue Mar 19 14:08:44 PDT 2013': $i).
% 29.32/29.16  tff(decl_78824, type, version: $i).
% 29.32/29.16  tff(decl_78825, type, 'Vertebrate': $i).
% 29.32/29.16  tff(decl_78826, type, 'Animals in the Phylum Chordata which have diagnostic characteristics including a well-developed skull and a backbone composed of vertebrae.': $i).
% 29.32/29.16  tff(decl_78827, type, vertebrate: $i).
% 29.32/29.16  tff(decl_78828, type, fn_vertebrate_9: $i > $i).
% 29.32/29.16  tff(decl_78829, type, fn_vertebrate_10: $i > $i).
% 29.32/29.16  tff(decl_78830, type, fn_vertebrate_11: $i > $i).
% 29.32/29.16  tff(decl_78831, type, fn_vertebrate_12: $i > $i).
% 29.32/29.16  tff(decl_78832, type, fn_vertebrate_14: $i > $i).
% 29.32/29.16  tff(decl_78833, type, fn_vertebrate_21: $i > $i).
% 29.32/29.16  tff(decl_78834, type, fn_vertebrate_22: $i > $i).
% 29.32/29.16  tff(decl_78835, type, fn_vertebrate_28: $i > $i).
% 29.32/29.16  tff(decl_78836, type, fn_vertebrate_29: $i > $i).
% 29.32/29.16  tff(decl_78837, type, fn_vertebrate_30: $i > $i).
% 29.32/29.16  tff(decl_78838, type, fn_vertebrate_31: $i > $i).
% 29.32/29.16  tff(decl_78839, type, fn_vertebrate_32: $i > $i).
% 29.32/29.16  tff(decl_78840, type, fn_vertebrate_36: $i > $i).
% 29.32/29.16  tff(decl_78841, type, fn_vertebrate_37: $i > $i).
% 29.32/29.16  tff(decl_78842, type, fn_vertebrate_38: $i > $i).
% 29.32/29.16  tff(decl_78843, type, fn_vertebrate_39: $i > $i).
% 29.32/29.16  tff(decl_78844, type, fn_vertebrate_52: $i > $i).
% 29.32/29.16  tff(decl_78845, type, lung_0: $i).
% 29.32/29.16  tff(decl_78846, type, 'Vertebrate-Appendage': $i).
% 29.32/29.16  tff(decl_78847, type, 'An external body part, or natural prolongation, that protrudes from a vertebrate\\s body.': $i).
% 29.32/29.16  tff(decl_78848, type, 'appendage of vertebrate': $i).
% 29.32/29.16  tff(decl_78849, type, 'vertebrate appendage': $i).
% 29.32/29.16  tff(decl_78850, type, 'vertebrate-appendage': $i).
% 29.32/29.16  tff(decl_78851, type, 'Vertebrate-Cell': $i).
% 29.32/29.16  tff(decl_78852, type, 'The cell of a vertebrate animal.': $i).
% 29.32/29.16  tff(decl_78853, type, 'cell of a vertebrate': $i).
% 29.32/29.16  tff(decl_78854, type, 'cell-of-a-vertebrate': $i).
% 29.32/29.16  tff(decl_78855, type, 'cell of vertebrate': $i).
% 29.32/29.16  tff(decl_78856, type, 'vertebrate cell': $i).
% 29.32/29.16  tff(decl_78857, type, 'vertebrate-cell': $i).
% 29.32/29.16  tff(decl_78858, type, 'Vertebrate-Homeotic-Gene': $i).
% 29.32/29.16  tff(decl_78859, type, 'Homeotic gene present in vertebrates.': $i).
% 29.32/29.16  tff(decl_78860, type, 'vertebrate homeotic gene': $i).
% 29.32/29.16  tff(decl_78861, type, 'vertebrate-homeotic-gene': $i).
% 29.32/29.16  tff(decl_78862, type, fn_vertebrate_homeotic_gene_1: $i > $i).
% 29.32/29.16  tff(decl_78863, type, fn_vertebrate_homeotic_gene_6: $i > $i).
% 29.32/29.16  tff(decl_78864, type, fn_vertebrate_homeotic_gene_7: $i > $i).
% 29.32/29.16  tff(decl_78865, type, fn_vertebrate_homeotic_gene_8: $i > $i).
% 29.32/29.16  tff(decl_78866, type, fn_vertebrate_homeotic_gene_9: $i > $i).
% 29.32/29.16  tff(decl_78867, type, fn_vertebrate_homeotic_gene_10: $i > $i).
% 29.32/29.16  tff(decl_78868, type, fn_vertebrate_homeotic_gene_11: $i > $i).
% 29.32/29.16  tff(decl_78869, type, fn_vertebrate_homeotic_gene_12: $i > $i).
% 29.32/29.16  tff(decl_78870, type, fn_vertebrate_homeotic_gene_13: $i > $i).
% 29.32/29.16  tff(decl_78871, type, fn_vertebrate_homeotic_gene_14: $i > $i).
% 29.32/29.16  tff(decl_78872, type, fn_vertebrate_homeotic_gene_15: $i > $i).
% 29.32/29.16  tff(decl_78873, type, fn_vertebrate_homeotic_gene_16: $i > $i).
% 29.32/29.16  tff(decl_78874, type, fn_vertebrate_homeotic_gene_17: $i > $i).
% 29.32/29.16  tff(decl_78875, type, fn_vertebrate_homeotic_gene_19: $i > $i).
% 29.32/29.16  tff(decl_78876, type, fn_vertebrate_homeotic_gene_21: $i > $i).
% 29.32/29.16  tff(decl_78877, type, fn_vertebrate_homeotic_gene_22: $i > $i).
% 29.32/29.16  tff(decl_78878, type, fn_vertebrate_homeotic_gene_23: $i > $i).
% 29.32/29.16  tff(decl_78879, type, fn_vertebrate_homeotic_gene_4: $i > $i).
% 29.32/29.16  tff(decl_78880, type, fn_vertebrate_homeotic_gene_5: $i > $i).
% 29.32/29.16  tff(decl_78881, type, fn_vertebrate_homeotic_gene_3: $i > $i).
% 29.32/29.16  tff(decl_78882, type, fn_vertebrate_homeotic_gene_2: $i > $i).
% 29.32/29.16  tff(decl_78883, type, 'Vertical-Transmission': $i).
% 29.32/29.16  tff(decl_78884, type, 'The inheritance or transmission of a viral infection from the parent to the offspring.': $i).
% 29.32/29.16  tff(decl_78885, type, 'vertical gene transfer': $i).
% 29.32/29.16  tff(decl_78886, type, 'transmission of vertical': $i).
% 29.32/29.16  tff(decl_78887, type, 'vertical transmission': $i).
% 29.32/29.16  tff(decl_78888, type, 'vertical-transmission': $i).
% 29.32/29.16  tff(decl_78889, type, fn_vertical_transmission_1: $i > $i).
% 29.32/29.16  tff(decl_78890, type, fn_vertical_transmission_2: $i > $i).
% 29.32/29.16  tff(decl_78891, type, fn_vertical_transmission_3: $i > $i).
% 29.32/29.16  tff(decl_78892, type, fn_vertical_transmission_4: $i > $i).
% 29.32/29.16  tff(decl_78893, type, fn_vertical_transmission_5: $i > $i).
% 29.32/29.16  tff(decl_78894, type, fn_vertical_transmission_6: $i > $i).
% 29.32/29.16  tff(decl_78895, type, fn_vertical_transmission_7: $i > $i).
% 29.32/29.16  tff(decl_78896, type, fn_vertical_transmission_8: $i > $i).
% 29.32/29.16  tff(decl_78897, type, fn_vertical_transmission_9: $i > $i).
% 29.32/29.16  tff(decl_78898, type, fn_vertical_transmission_10: $i > $i).
% 29.32/29.16  tff(decl_78899, type, fn_vertical_transmission_11: $i > $i).
% 29.32/29.16  tff(decl_78900, type, fn_vertical_transmission_12: $i > $i).
% 29.32/29.16  tff(decl_78901, type, fn_vertical_transmission_13: $i > $i).
% 29.32/29.16  tff(decl_78902, type, fn_vertical_transmission_14: $i > $i).
% 29.32/29.16  tff(decl_78903, type, fn_vertical_transmission_15: $i > $i).
% 29.32/29.16  tff(decl_78904, type, fn_vertical_transmission_16: $i > $i).
% 29.32/29.16  tff(decl_78905, type, fn_viral_infection_22: $i > $i).
% 29.32/29.16  tff(decl_78906, type, vervet_1: $i > $o).
% 29.32/29.16  tff(decl_78907, type, 'Vervet': $i).
% 29.32/29.16  tff(decl_78908, type, 'Chlorocebus pygerythrus, an Old World monkey used in studies of learning and social behavior.': $i).
% 29.32/29.16  tff(decl_78909, type, vervet: $i).
% 29.32/29.16  tff(decl_78910, type, 'Vesicle': $i).
% 29.32/29.16  tff(decl_78911, type, 'Vesicle is a small membrane-bound sac. Its main purpose is to store and transport material from one site to another site inside a cell': $i).
% 29.32/29.16  tff(decl_78912, type, vesicle: $i).
% 29.32/29.16  tff(decl_78913, type, fn_vesicle_2: $i > $i).
% 29.32/29.16  tff(decl_78914, type, fn_vesicle_11: $i > $i).
% 29.32/29.16  tff(decl_78915, type, fn_vesicle_12: $i > $i).
% 29.32/29.16  tff(decl_78916, type, vacuole_0: $i).
% 29.32/29.16  tff(decl_78917, type, 'Vessel': $i).
% 29.32/29.16  tff(decl_78918, type, 'A water-transporting tube in vascular plants.': $i).
% 29.32/29.16  tff(decl_78919, type, vessel: $i).
% 29.32/29.16  tff(decl_78920, type, fn_vessel_2: $i > $i).
% 29.32/29.16  tff(decl_78921, type, fn_vessel_4: $i > $i).
% 29.32/29.16  tff(decl_78922, type, fn_vessel_5: $i > $i).
% 29.32/29.16  tff(decl_78923, type, fn_vessel_6: $i > $i).
% 29.32/29.16  tff(decl_78924, type, fn_vessel_10: $i > $i).
% 29.32/29.16  tff(decl_78925, type, fn_vessel_11: $i > $i).
% 29.32/29.16  tff(decl_78926, type, fn_vessel_12: $i > $i).
% 29.32/29.16  tff(decl_78927, type, fn_vessel_13: $i > $i).
% 29.32/29.16  tff(decl_78928, type, fn_vessel_14: $i > $i).
% 29.32/29.16  tff(decl_78929, type, fn_vessel_element_59: $i > $i).
% 29.32/29.16  tff(decl_78930, type, fn_vessel_element_54: $i > $i).
% 29.32/29.16  tff(decl_78931, type, 'Vessel-Element': $i).
% 29.32/29.16  tff(decl_78932, type, 'A water-transporting cell in vascular plants. Vessel elements are dead when functionally mature, and are aligned end-to-end to form the vessels that conduct water through the plant\\s body.': $i).
% 29.32/29.16  tff(decl_78933, type, 'element of vessel': $i).
% 29.32/29.16  tff(decl_78934, type, 'vessel element': $i).
% 29.32/29.16  tff(decl_78935, type, 'vessel-element': $i).
% 29.32/29.16  tff(decl_78936, type, fn_vessel_element_2: $i > $i).
% 29.32/29.16  tff(decl_78937, type, fn_vessel_element_4: $i > $i).
% 29.32/29.16  tff(decl_78938, type, fn_vessel_element_6: $i > $i).
% 29.32/29.16  tff(decl_78939, type, fn_vessel_element_8: $i > $i).
% 29.32/29.16  tff(decl_78940, type, fn_vessel_element_9: $i > $i).
% 29.32/29.16  tff(decl_78941, type, fn_vessel_element_10: $i > $i).
% 29.32/29.16  tff(decl_78942, type, fn_vessel_element_11: $i > $i).
% 29.32/29.16  tff(decl_78943, type, fn_vessel_element_12: $i > $i).
% 29.32/29.16  tff(decl_78944, type, fn_vessel_element_13: $i > $i).
% 29.32/29.16  tff(decl_78945, type, fn_vessel_element_14: $i > $i).
% 29.32/29.16  tff(decl_78946, type, fn_vessel_element_15: $i > $i).
% 29.32/29.16  tff(decl_78947, type, fn_vessel_element_16: $i > $i).
% 29.32/29.16  tff(decl_78948, type, fn_vessel_element_17: $i > $i).
% 29.32/29.16  tff(decl_78949, type, fn_vessel_element_18: $i > $i).
% 29.32/29.16  tff(decl_78950, type, fn_vessel_element_19: $i > $i).
% 29.32/29.16  tff(decl_78951, type, fn_vessel_element_20: $i > $i).
% 29.32/29.16  tff(decl_78952, type, fn_vessel_element_21: $i > $i).
% 29.32/29.16  tff(decl_78953, type, fn_vessel_element_22: $i > $i).
% 29.32/29.16  tff(decl_78954, type, fn_vessel_element_25: $i > $i).
% 29.32/29.16  tff(decl_78955, type, fn_vessel_element_26: $i > $i).
% 29.32/29.16  tff(decl_78956, type, fn_vessel_element_27: $i > $i).
% 29.32/29.16  tff(decl_78957, type, fn_vessel_element_28: $i > $i).
% 29.32/29.16  tff(decl_78958, type, fn_vessel_element_29: $i > $i).
% 29.32/29.16  tff(decl_78959, type, fn_vessel_element_30: $i > $i).
% 29.32/29.16  tff(decl_78960, type, fn_vessel_element_31: $i > $i).
% 29.32/29.16  tff(decl_78961, type, fn_vessel_element_32: $i > $i).
% 29.32/29.16  tff(decl_78962, type, fn_vessel_element_33: $i > $i).
% 29.32/29.16  tff(decl_78963, type, fn_vessel_element_34: $i > $i).
% 29.32/29.16  tff(decl_78964, type, fn_vessel_element_35: $i > $i).
% 29.32/29.16  tff(decl_78965, type, fn_vessel_element_36: $i > $i).
% 29.32/29.16  tff(decl_78966, type, fn_vessel_element_37: $i > $i).
% 29.32/29.16  tff(decl_78967, type, fn_vessel_element_38: $i > $i).
% 29.32/29.16  tff(decl_78968, type, fn_vessel_element_39: $i > $i).
% 29.32/29.16  tff(decl_78969, type, fn_vessel_element_40: $i > $i).
% 29.32/29.16  tff(decl_78970, type, fn_vessel_element_41: $i > $i).
% 29.32/29.16  tff(decl_78971, type, fn_vessel_element_42: $i > $i).
% 29.32/29.16  tff(decl_78972, type, fn_vessel_element_43: $i > $i).
% 29.32/29.16  tff(decl_78973, type, fn_vessel_element_44: $i > $i).
% 29.32/29.16  tff(decl_78974, type, fn_vessel_element_45: $i > $i).
% 29.32/29.16  tff(decl_78975, type, fn_vessel_element_46: $i > $i).
% 29.32/29.16  tff(decl_78976, type, fn_vessel_element_47: $i > $i).
% 29.32/29.16  tff(decl_78977, type, fn_vessel_element_48: $i > $i).
% 29.32/29.16  tff(decl_78978, type, fn_vessel_element_49: $i > $i).
% 29.32/29.16  tff(decl_78979, type, fn_vessel_element_50: $i > $i).
% 29.32/29.16  tff(decl_78980, type, fn_vessel_element_51: $i > $i).
% 29.32/29.16  tff(decl_78981, type, fn_vessel_element_53: $i > $i).
% 29.32/29.16  tff(decl_78982, type, fn_vessel_element_55: $i > $i).
% 29.32/29.16  tff(decl_78983, type, fn_vessel_element_56: $i > $i).
% 29.32/29.16  tff(decl_78984, type, fn_vessel_element_57: $i > $i).
% 29.32/29.16  tff(decl_78985, type, fn_vessel_element_60: $i > $i).
% 29.32/29.16  tff(decl_78986, type, fn_vessel_element_61: $i > $i).
% 29.32/29.16  tff(decl_78987, type, fn_vessel_element_62: $i > $i).
% 29.32/29.16  tff(decl_78988, type, fn_vessel_element_63: $i > $i).
% 29.32/29.16  tff(decl_78989, type, fn_vessel_element_64: $i > $i).
% 29.32/29.16  tff(decl_78990, type, fn_vessel_element_65: $i > $i).
% 29.32/29.16  tff(decl_78991, type, fn_vessel_element_66: $i > $i).
% 29.32/29.16  tff(decl_78992, type, fn_vessel_element_67: $i > $i).
% 29.32/29.16  tff(decl_78993, type, fn_vessel_element_68: $i > $i).
% 29.32/29.16  tff(decl_78994, type, fn_vessel_element_69: $i > $i).
% 29.32/29.16  tff(decl_78995, type, fn_vessel_element_70: $i > $i).
% 29.32/29.16  tff(decl_78996, type, fn_vessel_element_72: $i > $i).
% 29.32/29.16  tff(decl_78997, type, fn_vessel_element_73: $i > $i).
% 29.32/29.16  tff(decl_78998, type, fn_vessel_element_74: $i > $i).
% 29.32/29.16  tff(decl_78999, type, fn_vessel_element_75: $i > $i).
% 29.32/29.16  tff(decl_79000, type, fn_vessel_element_76: $i > $i).
% 29.32/29.16  tff(decl_79001, type, fn_vessel_element_79: $i > $i).
% 29.32/29.16  tff(decl_79002, type, fn_vessel_element_80: $i > $i).
% 29.32/29.16  tff(decl_79003, type, fn_vessel_element_81: $i > $i).
% 29.32/29.16  tff(decl_79004, type, fn_plant_cell_wall_8: $i > $i).
% 29.32/29.16  tff(decl_79005, type, tracheid_0: $i).
% 29.32/29.16  tff(decl_79006, type, cell_wall_0: $i).
% 29.32/29.16  tff(decl_79007, type, fn_vessel_element_52: $i > $i).
% 29.32/29.16  tff(decl_79008, type, fn_vessel_element_58: $i > $i).
% 29.32/29.16  tff(decl_79009, type, fn_vessel_element_71: $i > $i).
% 29.32/29.16  tff(decl_79010, type, fn_vessel_element_24: $i > $i).
% 29.32/29.16  tff(decl_79011, type, fn_vessel_element_77: $i > $i).
% 29.32/29.16  tff(decl_79012, type, fn_vessel_element_78: $i > $i).
% 29.32/29.16  tff(decl_79013, type, fn_vessel_element_23: $i > $i).
% 29.32/29.16  tff(decl_79014, type, 'Vestibule-Of-The-Ear': $i).
% 29.32/29.16  tff(decl_79015, type, 'Region of the inner ear, related to maintaining balance, in which the semi-circular canals converge.': $i).
% 29.32/29.16  tff(decl_79016, type, 'ear vestibule': $i).
% 29.32/29.16  tff(decl_79017, type, vestibule: $i).
% 29.32/29.16  tff(decl_79018, type, 'vestibule of the ear': $i).
% 29.32/29.16  tff(decl_79019, type, 'vestibule-of-the-ear': $i).
% 29.32/29.16  tff(decl_79020, type, via_chalcogen_element_1: $i > $o).
% 29.32/29.16  tff(decl_79021, type, 'VIA-Chalcogen-Element': $i).
% 29.32/29.16  tff(decl_79022, type, 'Elements in group 6A of the periodic table called the chalcogens. They are O, S, Se, Te, Po and the unnamed element 116.': $i).
% 29.32/29.16  tff(decl_79023, type, chalcogen: $i).
% 29.32/29.16  tff(decl_79024, type, via: $i).
% 29.32/29.16  tff(decl_79025, type, 'group via elements': $i).
% 29.32/29.16  tff(decl_79026, type, 'group-via-elements': $i).
% 29.32/29.16  tff(decl_79027, type, 'group 16 elements': $i).
% 29.32/29.16  tff(decl_79028, type, 'group-16-elements': $i).
% 29.32/29.16  tff(decl_79029, type, 'via chalcogen element': $i).
% 29.32/29.16  tff(decl_79030, type, 'via-chalcogen-element': $i).
% 29.32/29.16  tff(decl_79031, type, viagra_1: $i > $o).
% 29.32/29.16  tff(decl_79032, type, 'Viagra': $i).
% 29.32/29.16  tff(decl_79033, type, 'A drug, sildenafil, that allows increased blood flow into the penis; used to treat erectile impotence in men.': $i).
% 29.32/29.16  tff(decl_79034, type, sildenafil: $i).
% 29.32/29.16  tff(decl_79035, type, viagra: $i).
% 29.32/29.16  tff(decl_79036, type, 'Vibrio-Cholerae': $i).
% 29.32/29.16  tff(decl_79037, type, 'A proteobacterium that causes the disease cholera.': $i).
% 29.32/29.16  tff(decl_79038, type, 'cholera causing agent': $i).
% 29.32/29.16  tff(decl_79039, type, 'cholera causing bacteria': $i).
% 29.32/29.16  tff(decl_79040, type, 'cholera bacteria': $i).
% 29.32/29.16  tff(decl_79041, type, 'vibrio cholerae': $i).
% 29.32/29.16  tff(decl_79042, type, 'vibrio-cholerae': $i).
% 29.32/29.16  tff(decl_79043, type, view_1: $i > $o).
% 29.32/29.16  tff(decl_79044, type, 'View': $i).
% 29.32/29.16  tff(decl_79045, type, position: $i).
% 29.32/29.16  tff(decl_79046, type, view: $i).
% 29.32/29.16  tff(decl_79047, type, perspective: $i).
% 29.32/29.16  tff(decl_79048, type, 'Viewpoint': $i).
% 29.32/29.16  tff(decl_79049, type, viewpoint: $i).
% 29.32/29.16  tff(decl_79050, type, viewpoint_query_type_1: $i > $o).
% 29.32/29.16  tff(decl_79051, type, 'Viewpoint-Query-Type': $i).
% 29.32/29.16  tff(decl_79052, type, 'viewpoint query type': $i).
% 29.32/29.16  tff(decl_79053, type, 'viewpoint-query-type': $i).
% 29.32/29.16  tff(decl_79054, type, viia_halogen_element_1: $i > $o).
% 29.32/29.16  tff(decl_79055, type, 'VIIA-Halogen-Element': $i).
% 29.32/29.16  tff(decl_79056, type, 'Elements in group 7A of the periodic table are called the halogens. They are F, Cl, Br, I and At.': $i).
% 29.32/29.16  tff(decl_79057, type, 'viia halogen element': $i).
% 29.32/29.16  tff(decl_79058, type, 'viia-halogen-element': $i).
% 29.32/29.16  tff(decl_79059, type, 'Villus': $i).
% 29.32/29.16  tff(decl_79060, type, 'Small, finger-like projection that increases the surface area of an epithelium such as the lining of the small intestine and the fetal chorion in mammals.': $i).
% 29.32/29.16  tff(decl_79061, type, villi: $i).
% 29.32/29.16  tff(decl_79062, type, villus: $i).
% 29.32/29.16  tff(decl_79063, type, fn_villus_2: $i > $i).
% 29.32/29.16  tff(decl_79064, type, 'Vinegar': $i).
% 29.32/29.16  tff(decl_79065, type, 'Vinegar is an acidic liquid produced from the fermentation of ethanol in a process that yields its key ingredient, acetic acid (ethanoic acid). It also may come in a diluted form.': $i).
% 29.32/29.16  tff(decl_79066, type, vinegar: $i).
% 29.32/29.16  tff(decl_79067, type, fn_vinegar_2: $i > $i).
% 29.32/29.16  tff(decl_79068, type, fn_vinegar_3: $i > $i).
% 29.32/29.16  tff(decl_79069, type, fn_acetic_acid_2: $i > $i).
% 29.32/29.16  tff(decl_79070, type, fn_vinegar_1: $i > $i).
% 29.32/29.16  tff(decl_79071, type, 'Violet-Blue-Light': $i).
% 29.32/29.16  tff(decl_79072, type, 'The portion of the electromagnetic spectrum that can be detected as violet-blue by the human eye, ranging in wavelength from about 410 nm to 450 nm.': $i).
% 29.32/29.16  tff(decl_79073, type, 'violet blue light': $i).
% 29.32/29.16  tff(decl_79074, type, 'violet-blue-light': $i).
% 29.32/29.16  tff(decl_79075, type, fn_violet_blue_light_3: $i > $i).
% 29.32/29.16  tff(decl_79076, type, fn_violet_blue_light_4: $i > $i).
% 29.32/29.16  tff(decl_79077, type, fn_violet_blue_light_5: $i > $i).
% 29.32/29.16  tff(decl_79078, type, "410.0e0": $i).
% 29.32/29.16  tff(decl_79079, type, fn_violet_blue_light_6: $i > $i).
% 29.32/29.16  tff(decl_79080, type, 'Violet-Light': $i).
% 29.32/29.16  tff(decl_79081, type, 'The portion of the electromagnetic spectrum that can be detected as violet, ranging in wavelength from about 380 nm to 450 nm.': $i).
% 29.32/29.16  tff(decl_79082, type, 'light of violet': $i).
% 29.32/29.16  tff(decl_79083, type, 'violet light': $i).
% 29.32/29.16  tff(decl_79084, type, 'violet-light': $i).
% 29.32/29.16  tff(decl_79085, type, fn_violet_light_2: $i > $i).
% 29.32/29.16  tff(decl_79086, type, fn_violet_light_3: $i > $i).
% 29.32/29.16  tff(decl_79087, type, fn_violet_light_7: $i > $i).
% 29.32/29.16  tff(decl_79088, type, fn_violet_light_9: $i > $i).
% 29.32/29.16  tff(decl_79089, type, fn_violet_light_10: $i > $i).
% 29.32/29.16  tff(decl_79090, type, fn_violet_light_6: $i > $i).
% 29.32/29.16  tff(decl_79091, type, 'Viral-Disease': $i).
% 29.32/29.16  tff(decl_79092, type, 'Abnormal condition in an organism, caused by infection with a virus.': $i).
% 29.32/29.16  tff(decl_79093, type, 'viral disease': $i).
% 29.32/29.16  tff(decl_79094, type, 'viral-disease': $i).
% 29.32/29.16  tff(decl_79095, type, 'Viral-Envelope': $i).
% 29.32/29.16  tff(decl_79096, type, 'A membrane that cloaks the capsid that in turn encloses a viral genome.': $i).
% 29.32/29.16  tff(decl_79097, type, 'viral envelope': $i).
% 29.32/29.16  tff(decl_79098, type, 'viral-envelope': $i).
% 29.32/29.16  tff(decl_79099, type, fn_viral_envelope_1: $i > $i).
% 29.32/29.16  tff(decl_79100, type, fn_viral_envelope_2: $i > $i).
% 29.32/29.16  tff(decl_79101, type, fn_viral_envelope_3: $i > $i).
% 29.32/29.16  tff(decl_79102, type, fn_viral_envelope_4: $i > $i).
% 29.32/29.16  tff(decl_79103, type, fn_viral_envelope_5: $i > $i).
% 29.32/29.16  tff(decl_79104, type, fn_viral_envelope_6: $i > $i).
% 29.32/29.16  tff(decl_79105, type, fn_viral_envelope_7: $i > $i).
% 29.32/29.16  tff(decl_79106, type, fn_viral_envelope_8: $i > $i).
% 29.32/29.16  tff(decl_79107, type, fn_viral_envelope_9: $i > $i).
% 29.32/29.16  tff(decl_79108, type, fn_viral_envelope_10: $i > $i).
% 29.32/29.16  tff(decl_79109, type, fn_viral_envelope_12: $i > $i).
% 29.32/29.16  tff(decl_79110, type, fn_viral_envelope_13: $i > $i).
% 29.32/29.16  tff(decl_79111, type, fn_viral_envelope_14: $i > $i).
% 29.32/29.16  tff(decl_79112, type, fn_viral_envelope_15: $i > $i).
% 29.32/29.16  tff(decl_79113, type, fn_viral_envelope_16: $i > $i).
% 29.32/29.16  tff(decl_79114, type, fn_viral_envelope_18: $i > $i).
% 29.32/29.16  tff(decl_79115, type, fn_viral_envelope_19: $i > $i).
% 29.32/29.16  tff(decl_79116, type, 'Viral-Infection': $i).
% 29.32/29.16  tff(decl_79117, type, 'Infection caused by a virus.': $i).
% 29.32/29.16  tff(decl_79118, type, 'viral infection': $i).
% 29.32/29.16  tff(decl_79119, type, 'viral replication': $i).
% 29.32/29.16  tff(decl_79120, type, 'virus spread': $i).
% 29.32/29.16  tff(decl_79121, type, 'virus replication': $i).
% 29.32/29.16  tff(decl_79122, type, 'viral spread': $i).
% 29.32/29.16  tff(decl_79123, type, 'viral reproduction': $i).
% 29.32/29.16  tff(decl_79124, type, 'virus reproduction': $i).
% 29.32/29.16  tff(decl_79125, type, 'viral-infection': $i).
% 29.32/29.16  tff(decl_79126, type, fn_viral_infection_2: $i > $i).
% 29.32/29.16  tff(decl_79127, type, fn_viral_infection_3: $i > $i).
% 29.32/29.16  tff(decl_79128, type, fn_viral_infection_4: $i > $i).
% 29.32/29.16  tff(decl_79129, type, fn_viral_infection_5: $i > $i).
% 29.32/29.16  tff(decl_79130, type, fn_viral_infection_6: $i > $i).
% 29.32/29.16  tff(decl_79131, type, fn_viral_infection_7: $i > $i).
% 29.32/29.16  tff(decl_79132, type, fn_viral_infection_8: $i > $i).
% 29.32/29.16  tff(decl_79133, type, fn_viral_infection_9: $i > $i).
% 29.32/29.16  tff(decl_79134, type, fn_viral_infection_11: $i > $i).
% 29.32/29.16  tff(decl_79135, type, fn_viral_infection_13: $i > $i).
% 29.32/29.16  tff(decl_79136, type, fn_viral_infection_17: $i > $i).
% 29.32/29.16  tff(decl_79137, type, fn_viral_infection_18: $i > $i).
% 29.32/29.16  tff(decl_79138, type, fn_viral_infection_19: $i > $i).
% 29.32/29.16  tff(decl_79139, type, fn_viral_infection_20: $i > $i).
% 29.32/29.16  tff(decl_79140, type, fn_viral_infection_21: $i > $i).
% 29.32/29.16  tff(decl_79141, type, virus_0: $i).
% 29.32/29.16  tff(decl_79142, type, capsid_0: $i).
% 29.32/29.16  tff(decl_79143, type, 'Viroid': $i).
% 29.32/29.16  tff(decl_79144, type, 'A plant pathogen consisting of a molecule of naked, circular RNA a few hundred nucleotides long.': $i).
% 29.32/29.16  tff(decl_79145, type, viroid: $i).
% 29.32/29.16  tff(decl_79146, type, fn_viroid_1: $i > $i).
% 29.32/29.16  tff(decl_79147, type, fn_viroid_2: $i > $i).
% 29.32/29.16  tff(decl_79148, type, fn_viroid_3: $i > $i).
% 29.32/29.16  tff(decl_79149, type, fn_viroid_4: $i > $i).
% 29.32/29.16  tff(decl_79150, type, fn_viroid_5: $i > $i).
% 29.32/29.16  tff(decl_79151, type, fn_viroid_6: $i > $i).
% 29.32/29.16  tff(decl_79152, type, fn_viroid_7: $i > $i).
% 29.32/29.16  tff(decl_79153, type, fn_viroid_8: $i > $i).
% 29.32/29.16  tff(decl_79154, type, fn_viroid_9: $i > $i).
% 29.32/29.16  tff(decl_79155, type, fn_viroid_10: $i > $i).
% 29.32/29.16  tff(decl_79156, type, fn_viroid_11: $i > $i).
% 29.32/29.16  tff(decl_79157, type, fn_viroid_12: $i > $i).
% 29.32/29.16  tff(decl_79158, type, fn_viroid_13: $i > $i).
% 29.32/29.16  tff(decl_79159, type, fn_viroid_14: $i > $i).
% 29.32/29.16  tff(decl_79160, type, fn_viroid_15: $i > $i).
% 29.32/29.16  tff(decl_79161, type, fn_viroid_16: $i > $i).
% 29.32/29.16  tff(decl_79162, type, fn_viroid_17: $i > $i).
% 29.32/29.16  tff(decl_79163, type, fn_viroid_18: $i > $i).
% 29.32/29.16  tff(decl_79164, type, fn_viroid_19: $i > $i).
% 29.32/29.16  tff(decl_79165, type, fn_viroid_20: $i > $i).
% 29.32/29.16  tff(decl_79166, type, fn_viroid_21: $i > $i).
% 29.32/29.16  tff(decl_79167, type, fn_viroid_22: $i > $i).
% 29.32/29.16  tff(decl_79168, type, fn_viroid_23: $i > $i).
% 29.32/29.16  tff(decl_79169, type, fn_viroid_24: $i > $i).
% 29.32/29.16  tff(decl_79170, type, fn_viroid_25: $i > $i).
% 29.32/29.16  tff(decl_79171, type, fn_viroid_26: $i > $i).
% 29.32/29.16  tff(decl_79172, type, fn_viroid_27: $i > $i).
% 29.32/29.16  tff(decl_79173, type, fn_viroid_28: $i > $i).
% 29.32/29.16  tff(decl_79174, type, fn_viroid_29: $i > $i).
% 29.32/29.16  tff(decl_79175, type, fn_viroid_30: $i > $i).
% 29.32/29.16  tff(decl_79176, type, fn_viroid_31: $i > $i).
% 29.32/29.16  tff(decl_79177, type, fn_viroid_32: $i > $i).
% 29.32/29.16  tff(decl_79178, type, fn_viroid_33: $i > $i).
% 29.32/29.16  tff(decl_79179, type, fn_viroid_34: $i > $i).
% 29.32/29.16  tff(decl_79180, type, fn_viroid_35: $i > $i).
% 29.32/29.16  tff(decl_79181, type, fn_viroid_36: $i > $i).
% 29.32/29.16  tff(decl_79182, type, fn_viroid_37: $i > $i).
% 29.32/29.16  tff(decl_79183, type, fn_viroid_38: $i > $i).
% 29.32/29.16  tff(decl_79184, type, fn_viroid_39: $i > $i).
% 29.32/29.16  tff(decl_79185, type, fn_viroid_40: $i > $i).
% 29.32/29.16  tff(decl_79186, type, fn_viroid_46: $i > $i).
% 29.32/29.16  tff(decl_79187, type, fn_viroid_47: $i > $i).
% 29.32/29.16  tff(decl_79188, type, fn_viroid_48: $i > $i).
% 29.32/29.16  tff(decl_79189, type, fn_viroid_49: $i > $i).
% 29.32/29.16  tff(decl_79190, type, fn_viroid_50: $i > $i).
% 29.32/29.16  tff(decl_79191, type, fn_viroid_51: $i > $i).
% 29.32/29.16  tff(decl_79192, type, fn_viroid_52: $i > $i).
% 29.32/29.16  tff(decl_79193, type, fn_viroid_53: $i > $i).
% 29.32/29.16  tff(decl_79194, type, fn_viroid_54: $i > $i).
% 29.32/29.16  tff(decl_79195, type, fn_viroid_55: $i > $i).
% 29.32/29.16  tff(decl_79196, type, fn_viroid_56: $i > $i).
% 29.32/29.16  tff(decl_79197, type, fn_viroid_58: $i > $i).
% 29.32/29.16  tff(decl_79198, type, fn_viroid_59: $i > $i).
% 29.32/29.16  tff(decl_79199, type, fn_viroid_61: $i > $i).
% 29.32/29.16  tff(decl_79200, type, fn_viroid_62: $i > $i).
% 29.32/29.16  tff(decl_79201, type, fn_viroid_63: $i > $i).
% 29.32/29.16  tff(decl_79202, type, fn_viroid_64: $i > $i).
% 29.32/29.16  tff(decl_79203, type, fn_viroid_65: $i > $i).
% 29.32/29.16  tff(decl_79204, type, fn_viroid_66: $i > $i).
% 29.32/29.16  tff(decl_79205, type, fn_viroid_67: $i > $i).
% 29.32/29.16  tff(decl_79206, type, fn_viroid_68: $i > $i).
% 29.32/29.16  tff(decl_79207, type, fn_viroid_69: $i > $i).
% 29.32/29.16  tff(decl_79208, type, fn_viroid_70: $i > $i).
% 29.32/29.16  tff(decl_79209, type, fn_viroid_71: $i > $i).
% 29.32/29.16  tff(decl_79210, type, fn_viroid_72: $i > $i).
% 29.32/29.16  tff(decl_79211, type, fn_viroid_73: $i > $i).
% 29.32/29.16  tff(decl_79212, type, fn_viroid_74: $i > $i).
% 29.32/29.16  tff(decl_79213, type, fn_viroid_75: $i > $i).
% 29.32/29.16  tff(decl_79214, type, fn_viroid_76: $i > $i).
% 29.32/29.16  tff(decl_79215, type, fn_viroid_77: $i > $i).
% 29.32/29.16  tff(decl_79216, type, fn_viroid_78: $i > $i).
% 29.32/29.16  tff(decl_79217, type, fn_viroid_79: $i > $i).
% 29.32/29.16  tff(decl_79218, type, fn_viroid_82: $i > $i).
% 29.32/29.16  tff(decl_79219, type, fn_viroid_83: $i > $i).
% 29.32/29.16  tff(decl_79220, type, fn_viroid_84: $i > $i).
% 29.32/29.16  tff(decl_79221, type, fn_viroid_85: $i > $i).
% 29.32/29.16  tff(decl_79222, type, fn_viroid_86: $i > $i).
% 29.32/29.16  tff(decl_79223, type, fn_viroid_87: $i > $i).
% 29.32/29.16  tff(decl_79224, type, fn_viroid_88: $i > $i).
% 29.32/29.16  tff(decl_79225, type, fn_viroid_80: $i > $i).
% 29.32/29.16  tff(decl_79226, type, fn_viroid_81: $i > $i).
% 29.32/29.16  tff(decl_79227, type, fn_viroid_44: $i > $i).
% 29.32/29.16  tff(decl_79228, type, fn_viroid_43: $i > $i).
% 29.32/29.16  tff(decl_79229, type, fn_viroid_60: $i > $i).
% 29.32/29.16  tff(decl_79230, type, fn_viroid_41: $i > $i).
% 29.32/29.16  tff(decl_79231, type, fn_viroid_42: $i > $i).
% 29.32/29.16  tff(decl_79232, type, fn_viroid_45: $i > $i).
% 29.32/29.16  tff(decl_79233, type, fn_viroid_57: $i > $i).
% 29.32/29.16  tff(decl_79234, type, 'Virulent': $i).
% 29.32/29.16  tff(decl_79235, type, 'Term used to describe a pathogen that is highly infective and extremely harmful in its effects.': $i).
% 29.32/29.16  tff(decl_79236, type, virulent: $i).
% 29.32/29.16  tff(decl_79237, type, 'Virulent-Phage': $i).
% 29.32/29.16  tff(decl_79238, type, 'A phage that reproduces only by a lytic cycle.': $i).
% 29.32/29.16  tff(decl_79239, type, 'virulent virus': $i).
% 29.32/29.16  tff(decl_79240, type, 'lytic virus': $i).
% 29.32/29.16  tff(decl_79241, type, 'phage of virulent': $i).
% 29.32/29.16  tff(decl_79242, type, 'virulent phage': $i).
% 29.32/29.16  tff(decl_79243, type, 'virulent-phage': $i).
% 29.32/29.16  tff(decl_79244, type, fn_virulent_phage_1: $i > $i).
% 29.32/29.16  tff(decl_79245, type, 'Virus': $i).
% 29.32/29.16  tff(decl_79246, type, 'A small infective agent that consists of a bit of nucleic acid wrapped in a protein coat. Viruses can replicate only inside a living cell.': $i).
% 29.32/29.16  tff(decl_79247, type, virus: $i).
% 29.32/29.16  tff(decl_79248, type, fn_virus_4: $i > $i).
% 29.32/29.16  tff(decl_79249, type, fn_virus_5: $i > $i).
% 29.32/29.16  tff(decl_79250, type, fn_virus_6: $i > $i).
% 29.32/29.16  tff(decl_79251, type, fn_virus_7: $i > $i).
% 29.32/29.16  tff(decl_79252, type, fn_virus_8: $i > $i).
% 29.32/29.16  tff(decl_79253, type, fn_virus_9: $i > $i).
% 29.32/29.16  tff(decl_79254, type, fn_virus_13: $i > $i).
% 29.32/29.16  tff(decl_79255, type, fn_virus_14: $i > $i).
% 29.32/29.16  tff(decl_79256, type, fn_virus_15: $i > $i).
% 29.32/29.16  tff(decl_79257, type, fn_virus_16: $i > $i).
% 29.32/29.16  tff(decl_79258, type, fn_virus_17: $i > $i).
% 29.32/29.16  tff(decl_79259, type, fn_virus_18: $i > $i).
% 29.32/29.16  tff(decl_79260, type, fn_virus_19: $i > $i).
% 29.32/29.16  tff(decl_79261, type, fn_virus_20: $i > $i).
% 29.32/29.16  tff(decl_79262, type, fn_virus_24: $i > $i).
% 29.32/29.16  tff(decl_79263, type, fn_virus_25: $i > $i).
% 29.32/29.16  tff(decl_79264, type, fn_virus_26: $i > $i).
% 29.32/29.16  tff(decl_79265, type, visceral_mass_1: $i > $o).
% 29.32/29.16  tff(decl_79266, type, 'Visceral-Mass': $i).
% 29.32/29.16  tff(decl_79267, type, 'One of the main parts of a mollusc\\s body, containing most of the soft viscera.': $i).
% 29.32/29.16  tff(decl_79268, type, 'visceral mass': $i).
% 29.32/29.16  tff(decl_79269, type, 'visceral-mass': $i).
% 29.32/29.16  tff(decl_79270, type, 'Visibility-Constant': $i).
% 29.32/29.16  tff(decl_79271, type, 'constant of visibility': $i).
% 29.32/29.16  tff(decl_79272, type, 'visibility constant': $i).
% 29.32/29.16  tff(decl_79273, type, 'visibility-constant': $i).
% 29.32/29.16  tff(decl_79274, type, 'Visibility-Scalar-Constant': $i).
% 29.32/29.16  tff(decl_79275, type, 'visibility scalar constant': $i).
% 29.32/29.16  tff(decl_79276, type, 'visibility-scalar-constant': $i).
% 29.32/29.16  tff(decl_79277, type, visibility_scale_1: $i > $o).
% 29.32/29.16  tff(decl_79278, type, 'Visibility-Scale': $i).
% 29.32/29.16  tff(decl_79279, type, 'scale of visibility': $i).
% 29.32/29.16  tff(decl_79280, type, 'visibility scale': $i).
% 29.32/29.16  tff(decl_79281, type, 'visibility-scale': $i).
% 29.32/29.16  tff(decl_79282, type, 'Visibility-Value': $i).
% 29.32/29.16  tff(decl_79283, type, visible: $i).
% 29.32/29.16  tff(decl_79284, type, visibility: $i).
% 29.32/29.16  tff(decl_79285, type, 'value of visibility': $i).
% 29.32/29.16  tff(decl_79286, type, 'visibility value': $i).
% 29.32/29.16  tff(decl_79287, type, 'visibility-value': $i).
% 29.32/29.16  tff(decl_79288, type, 'Visible-Light': $i).
% 29.32/29.16  tff(decl_79289, type, 'The wavelengths, from about 380 nm to 750 nm, within the electromagnetic spectrum that are detectable to the human eye as colors.': $i).
% 29.32/29.16  tff(decl_79290, type, 'white light': $i).
% 29.32/29.16  tff(decl_79291, type, 'visible light spectrum': $i).
% 29.32/29.16  tff(decl_79292, type, 'white light spectrum': $i).
% 29.32/29.16  tff(decl_79293, type, 'visible spectrum': $i).
% 29.32/29.16  tff(decl_79294, type, 'white spectrum': $i).
% 29.32/29.16  tff(decl_79295, type, 'visible electromagnetic spectrum': $i).
% 29.32/29.16  tff(decl_79296, type, 'white electromagnetic spectrum': $i).
% 29.32/29.16  tff(decl_79297, type, 'visible light electromagnetic spectrum': $i).
% 29.32/29.16  tff(decl_79298, type, 'white light electromagnetic spectrum': $i).
% 29.32/29.16  tff(decl_79299, type, 'light of visible': $i).
% 29.32/29.16  tff(decl_79300, type, 'visible-light': $i).
% 29.32/29.16  tff(decl_79301, type, fn_visible_light_1: $i > $i).
% 29.32/29.16  tff(decl_79302, type, fn_visible_light_2: $i > $i).
% 29.32/29.16  tff(decl_79303, type, fn_visible_light_3: $i > $i).
% 29.32/29.16  tff(decl_79304, type, fn_visible_light_4: $i > $i).
% 29.32/29.16  tff(decl_79305, type, fn_visible_light_5: $i > $i).
% 29.32/29.16  tff(decl_79306, type, fn_visible_light_6: $i > $i).
% 29.32/29.16  tff(decl_79307, type, fn_visible_light_8: $i > $i).
% 29.32/29.16  tff(decl_79308, type, fn_visible_light_9: $i > $i).
% 29.32/29.16  tff(decl_79309, type, fn_visible_light_12: $i > $i).
% 29.32/29.16  tff(decl_79310, type, fn_visible_light_13: $i > $i).
% 29.32/29.16  tff(decl_79311, type, fn_visible_light_16: $i > $i).
% 29.32/29.16  tff(decl_79312, type, fn_visible_light_18: $i > $i).
% 29.32/29.16  tff(decl_79313, type, 'Visual-Pigment': $i).
% 29.32/29.16  tff(decl_79314, type, 'Pigment which functions in light absoprtion during animal vision.': $i).
% 29.32/29.16  tff(decl_79315, type, 'visual pigment': $i).
% 29.32/29.16  tff(decl_79316, type, 'visual-pigment': $i).
% 29.32/29.16  tff(decl_79317, type, 'Vitamin': $i).
% 29.32/29.16  tff(decl_79318, type, 'An organic compound that an organism requires as a nutrient in limited amounts.': $i).
% 29.32/29.16  tff(decl_79319, type, vitamin: $i).
% 29.32/29.16  tff(decl_79320, type, fn_vitamin_1: $i > $i).
% 29.32/29.16  tff(decl_79321, type, fn_vitamin_2: $i > $i).
% 29.32/29.16  tff(decl_79322, type, 'Vitamin-A': $i).
% 29.32/29.16  tff(decl_79323, type, 'Retinol (Vitamin A)  serves as a component of visual pigments and a coenzyme in the maintenance of epithelial tissues. Major dietary sources include dark green and orange vegetables and fruits and dairy products.': $i).
% 29.32/29.16  tff(decl_79324, type, 'vitamin a': $i).
% 29.32/29.16  tff(decl_79325, type, 'vitamin-a': $i).
% 29.32/29.16  tff(decl_79326, type, 'Vitamin-B': $i).
% 29.32/29.16  tff(decl_79327, type, 'Water soluble vitamins that act as cofactors in metabolic pathways.': $i).
% 29.32/29.16  tff(decl_79328, type, 'b of vitamin': $i).
% 29.32/29.16  tff(decl_79329, type, 'vitamin b': $i).
% 29.32/29.16  tff(decl_79330, type, 'vitamin-b': $i).
% 29.32/29.16  tff(decl_79331, type, water_soluble_vitamin_1: $i > $o).
% 29.32/29.16  tff(decl_79332, type, vitamin_b1_1: $i > $o).
% 29.32/29.16  tff(decl_79333, type, 'Vitamin-B1': $i).
% 29.32/29.16  tff(decl_79334, type, 'Thymine (Vitamin B1)  serves as a coenzyme in the removal of carbon dioxide from organic compounds. Major dietary sources include pork, legumes, peanuts and whole grains.': $i).
% 29.32/29.16  tff(decl_79335, type, 'vitamin b1': $i).
% 29.32/29.16  tff(decl_79336, type, 'vitamin-b1': $i).
% 29.32/29.16  tff(decl_79337, type, fn_vitamin_b1_1: $i > $i).
% 29.32/29.16  tff(decl_79338, type, fn_vitamin_b1_2: $i > $i).
% 29.32/29.16  tff(decl_79339, type, 'Vitamin-B2': $i).
% 29.32/29.16  tff(decl_79340, type, 'A nutrient that is the central component of the coenzymes FAD and FMN. It is also called riboflavin, and is found in meats, dairy products, legumes, and leafy vegetables.': $i).
% 29.32/29.16  tff(decl_79341, type, riboflavin: $i).
% 29.32/29.16  tff(decl_79342, type, 'vitamin b2': $i).
% 29.32/29.16  tff(decl_79343, type, 'vitamin-b2': $i).
% 29.32/29.16  tff(decl_79344, type, fn_vitamin_b2_1: $i > $i).
% 29.32/29.16  tff(decl_79345, type, fn_vitamin_b2_2: $i > $i).
% 29.32/29.16  tff(decl_79346, type, fn_vitamin_b2_3: $i > $i).
% 29.32/29.16  tff(decl_79347, type, 'Vitamin-B3': $i).
% 29.32/29.16  tff(decl_79348, type, 'Niacin is an essential B vitamin and the precursor molecule for the formation of the electron carrier NAD+.': $i).
% 29.32/29.16  tff(decl_79349, type, niacin: $i).
% 29.32/29.16  tff(decl_79350, type, 'vitamin b3': $i).
% 29.32/29.16  tff(decl_79351, type, 'vitamin-b3': $i).
% 29.32/29.16  tff(decl_79352, type, fn_vitamin_b3_1: $i > $i).
% 29.32/29.16  tff(decl_79353, type, fn_vitamin_b3_2: $i > $i).
% 29.32/29.16  tff(decl_79354, type, 'Vitamin-B5': $i).
% 29.32/29.16  tff(decl_79355, type, 'Panthothhenic acid (vitamin B5) serves as a component of coenzyme A. Major dietary sources includemeats, dairy products, whole grains, fruits and vegetables.': $i).
% 29.32/29.16  tff(decl_79356, type, 'vitamin b5': $i).
% 29.32/29.16  tff(decl_79357, type, 'vitamin-b5': $i).
% 29.32/29.16  tff(decl_79358, type, 'Vitamin-B7': $i).
% 29.32/29.16  tff(decl_79359, type, 'Biotin (Vitamin B7)  serves as a coenzyme in the synthesis of fat, glycogen and amino acids. Major dietary sources include legumes, vegetables and meats.': $i).
% 29.32/29.16  tff(decl_79360, type, 'vitamin b7': $i).
% 29.32/29.16  tff(decl_79361, type, 'vitamin-b7': $i).
% 29.32/29.16  tff(decl_79362, type, 'Vitamin-B9': $i).
% 29.32/29.16  tff(decl_79363, type, 'Folic Acid (Vitamin B9)  serves as a coenzyme in nucleic acid and amino acid metabolism.  Major dietary sources include green vegetables, oranges, nuts, legumes and whole grains.': $i).
% 29.32/29.16  tff(decl_79364, type, 'vitamin b9': $i).
% 29.32/29.16  tff(decl_79365, type, 'vitamin-b9': $i).
% 29.32/29.16  tff(decl_79366, type, 'Vitamin-C': $i).
% 29.32/29.16  tff(decl_79367, type, 'Ascorbic acid (Vitamin C)  serves as an antioxidant and a coenzyme in collagen synthesis.  Major dietary sources include citrus fruits, broccoli, and tomatoes.': $i).
% 29.32/29.16  tff(decl_79368, type, 'c of vitamin': $i).
% 29.32/29.16  tff(decl_79369, type, 'vitamin c': $i).
% 29.32/29.16  tff(decl_79370, type, 'vitamin-c': $i).
% 29.32/29.16  tff(decl_79371, type, fn_vitamin_c_1: $i > $i).
% 29.32/29.16  tff(decl_79372, type, 'Vitamin-D': $i).
% 29.32/29.16  tff(decl_79373, type, 'Vitamin D serves as a coenzyme in the absorption and use of calcium and phosphorus. Major dietary sources include dairy products and egg yolks.': $i).
% 29.32/29.16  tff(decl_79374, type, 'd of vitamin': $i).
% 29.32/29.16  tff(decl_79375, type, 'vitamin d': $i).
% 29.32/29.16  tff(decl_79376, type, 'vitamin-d': $i).
% 29.32/29.16  tff(decl_79377, type, vitamin_e_1: $i > $o).
% 29.32/29.16  tff(decl_79378, type, 'Vitamin-E': $i).
% 29.32/29.16  tff(decl_79379, type, 'Tocopherol (Vitamin E)  serves as an antioxidant  which helps prevent damage to cell membranes. Major dietary sources include vegetable oils, nuts and seeds.': $i).
% 29.32/29.16  tff(decl_79380, type, 'e of vitamin': $i).
% 29.32/29.16  tff(decl_79381, type, 'vitamin e': $i).
% 29.32/29.16  tff(decl_79382, type, 'vitamin-e': $i).
% 29.32/29.16  tff(decl_79383, type, fn_vitamin_e_1: $i > $i).
% 29.32/29.16  tff(decl_79384, type, fn_vitamin_e_2: $i > $i).
% 29.32/29.16  tff(decl_79385, type, fn_vitamin_e_3: $i > $i).
% 29.32/29.16  tff(decl_79386, type, fn_vitamin_e_4: $i > $i).
% 29.32/29.16  tff(decl_79387, type, fn_vitamin_e_5: $i > $i).
% 29.32/29.16  tff(decl_79388, type, 'Vitamin-K': $i).
% 29.32/29.16  tff(decl_79389, type, 'Phylloquinone (Vitamin K)  serves as a coenzyme in the process of blood clotting. Major dietary sources include green vegetables and tea; it is also made by symbiotic bacteria in the colon of animals.': $i).
% 29.32/29.16  tff(decl_79390, type, 'k of vitamin': $i).
% 29.32/29.16  tff(decl_79391, type, 'vitamin k': $i).
% 29.32/29.16  tff(decl_79392, type, 'vitamin-k': $i).
% 29.32/29.16  tff(decl_79393, type, 'Vitreous-Humor': $i).
% 29.32/29.16  tff(decl_79394, type, 'The clear gel that fills the space between the lens and the retina in the vertebrate eye.': $i).
% 29.32/29.16  tff(decl_79395, type, 'vitreous humor': $i).
% 29.32/29.16  tff(decl_79396, type, 'vitreous-humor': $i).
% 29.32/29.16  tff(decl_79397, type, 'Viviparous': $i).
% 29.32/29.16  tff(decl_79398, type, 'Giving birth to live young that developed within the mother\\s body and obtained some degree of nourishment from her instead of relying solely on energy and nutrients provided in the egg.': $i).
% 29.32/29.16  tff(decl_79399, type, viviparous: $i).
% 29.32/29.16  tff(decl_79400, type, 'live bearing': $i).
% 29.32/29.16  tff(decl_79401, type, 'live-bearing': $i).
% 29.32/29.16  tff(decl_79402, type, 'Vocal-Cord': $i).
% 29.32/29.16  tff(decl_79403, type, 'One of a pair of bands of mucous membrane in the larynx. During phonation, the vocal cords vibrate as air is pushed over them and generate sound.': $i).
% 29.32/29.16  tff(decl_79404, type, 'vocal folds': $i).
% 29.32/29.16  tff(decl_79405, type, 'vocal-folds': $i).
% 29.32/29.16  tff(decl_79406, type, 'vocal cord': $i).
% 29.32/29.16  tff(decl_79407, type, 'vocal-cord': $i).
% 29.32/29.16  tff(decl_79408, type, 'Voltage': $i).
% 29.32/29.16  tff(decl_79409, type, 'Electrical potential energy and a separation of opposite charges.': $i).
% 29.32/29.16  tff(decl_79410, type, 'electrical potential energy': $i).
% 29.32/29.16  tff(decl_79411, type, 'electrical-potential-energy': $i).
% 29.32/29.16  tff(decl_79412, type, 'electrical potential': $i).
% 29.32/29.16  tff(decl_79413, type, 'electrical-potential': $i).
% 29.32/29.16  tff(decl_79414, type, voltage: $i).
% 29.32/29.16  tff(decl_79415, type, fn_voltage_1: $i > $i).
% 29.32/29.16  tff(decl_79416, type, fn_voltage_2: $i > $i).
% 29.32/29.16  tff(decl_79417, type, fn_voltage_3: $i > $i).
% 29.32/29.16  tff(decl_79418, type, fn_voltage_6: $i > $i).
% 29.32/29.16  tff(decl_79419, type, fn_voltage_7: $i > $i).
% 29.32/29.16  tff(decl_79420, type, voltage_constant_1: $i > $o).
% 29.32/29.16  tff(decl_79421, type, 'Voltage-Constant': $i).
% 29.32/29.16  tff(decl_79422, type, 'constant of voltage': $i).
% 29.32/29.16  tff(decl_79423, type, 'voltage constant': $i).
% 29.32/29.16  tff(decl_79424, type, 'voltage-constant': $i).
% 29.32/29.16  tff(decl_79425, type, 'Voltage-Gated-Ion-Channel': $i).
% 29.32/29.16  tff(decl_79426, type, 'A transport protein with voltage-sensitive gates that is closed in the resting state and opens slowly in response to depolarization.': $i).
% 29.32/29.16  tff(decl_79427, type, 'voltage gated ion channel': $i).
% 29.32/29.16  tff(decl_79428, type, 'voltage-gated ion-channel': $i).
% 29.32/29.16  tff(decl_79429, type, 'voltage-gated-ion-channel': $i).
% 29.32/29.16  tff(decl_79430, type, 'Voltage-Value': $i).
% 29.32/29.16  tff(decl_79431, type, 'the rate at which energy is drawn from a source that produces a flow of electricity in a circuit': $i).
% 29.32/29.16  tff(decl_79432, type, 'electromotive force': $i).
% 29.32/29.16  tff(decl_79433, type, emf: $i).
% 29.32/29.16  tff(decl_79434, type, 'electric potential': $i).
% 29.32/29.16  tff(decl_79435, type, 'potential difference': $i).
% 29.32/29.16  tff(decl_79436, type, 'potential drop': $i).
% 29.32/29.16  tff(decl_79437, type, 'value of voltage': $i).
% 29.32/29.16  tff(decl_79438, type, 'voltage value': $i).
% 29.32/29.16  tff(decl_79439, type, 'voltage-value': $i).
% 29.32/29.16  tff(decl_79440, type, 'Volume-Constant': $i).
% 29.32/29.16  tff(decl_79441, type, 'constant of volume': $i).
% 29.32/29.16  tff(decl_79442, type, 'volume constant': $i).
% 29.32/29.16  tff(decl_79443, type, 'volume-constant': $i).
% 29.32/29.16  tff(decl_79444, type, volume_scale_1: $i > $o).
% 29.32/29.16  tff(decl_79445, type, 'Volume-Scale': $i).
% 29.32/29.16  tff(decl_79446, type, 'scale of volume': $i).
% 29.32/29.16  tff(decl_79447, type, 'volume scale': $i).
% 29.32/29.16  tff(decl_79448, type, 'volume-scale': $i).
% 29.32/29.16  tff(decl_79449, type, 'Volume-Value': $i).
% 29.32/29.16  tff(decl_79450, type, 'volume is a property for describing the amount of space occupied by a three-dimensional object as measured in cubic units': $i).
% 29.32/29.16  tff(decl_79451, type, 'value of volume': $i).
% 29.32/29.16  tff(decl_79452, type, 'volume value': $i).
% 29.32/29.16  tff(decl_79453, type, 'volume-value': $i).
% 29.32/29.16  tff(decl_79454, type, 'Vulva': $i).
% 29.32/29.16  tff(decl_79455, type, 'The external genitals of female mammals.': $i).
% 29.32/29.16  tff(decl_79456, type, vulva: $i).
% 29.32/29.16  tff(decl_79457, type, fn_vulva_1: $i > $i).
% 29.32/29.16  tff(decl_79458, type, fn_vulva_2: $i > $i).
% 29.32/29.16  tff(decl_79459, type, fn_vulva_3: $i > $i).
% 29.32/29.16  tff(decl_79460, type, fn_vulva_4: $i > $i).
% 29.32/29.16  tff(decl_79461, type, fn_vulva_5: $i > $i).
% 29.32/29.16  tff(decl_79462, type, fn_vulva_6: $i > $i).
% 29.32/29.16  tff(decl_79463, type, 'Vulva-Development': $i).
% 29.32/29.16  tff(decl_79464, type, 'The macrophysiological process involved in development of vulva.': $i).
% 29.32/29.16  tff(decl_79465, type, 'vulva formation': $i).
% 29.32/29.16  tff(decl_79466, type, 'development of vulva': $i).
% 29.32/29.16  tff(decl_79467, type, 'vulva development': $i).
% 29.32/29.16  tff(decl_79468, type, 'vulva-development': $i).
% 29.32/29.16  tff(decl_79469, type, fn_vulva_development_2: $i > $i).
% 29.32/29.16  tff(decl_79470, type, 'Vulval-Precursor-Cell': $i).
% 29.32/29.16  tff(decl_79471, type, 'The vulva of an organism develops from vulvalprecursor cells.': $i).
% 29.32/29.16  tff(decl_79472, type, 'vulval precursor cell': $i).
% 29.32/29.16  tff(decl_79473, type, 'vulval-precursor-cell': $i).
% 29.32/29.16  tff(decl_79474, type, fn_vulval_precursor_cell_1: $i > $i).
% 29.32/29.16  tff(decl_79475, type, fn_vulval_precursor_cell_2: $i > $i).
% 29.32/29.16  tff(decl_79476, type, fn_vulval_precursor_cell_3: $i > $i).
% 29.32/29.16  tff(decl_79477, type, fn_vulval_precursor_cell_4: $i > $i).
% 29.32/29.16  tff(decl_79478, type, fn_vulval_precursor_cell_5: $i > $i).
% 29.32/29.16  tff(decl_79479, type, fn_vulval_precursor_cell_6: $i > $i).
% 29.32/29.16  tff(decl_79480, type, fn_vulval_precursor_cell_7: $i > $i).
% 29.32/29.16  tff(decl_79481, type, fn_vulval_precursor_cell_8: $i > $i).
% 29.32/29.16  tff(decl_79482, type, fn_vulval_precursor_cell_9: $i > $i).
% 29.32/29.16  tff(decl_79483, type, fn_vulval_precursor_cell_10: $i > $i).
% 29.32/29.16  tff(decl_79484, type, fn_vulval_precursor_cell_11: $i > $i).
% 29.32/29.16  tff(decl_79485, type, fn_vulval_precursor_cell_12: $i > $i).
% 29.32/29.16  tff(decl_79486, type, fn_vulval_precursor_cell_13: $i > $i).
% 29.32/29.16  tff(decl_79487, type, fn_vulval_precursor_cell_14: $i > $i).
% 29.32/29.16  tff(decl_79488, type, fn_vulval_precursor_cell_15: $i > $i).
% 29.32/29.16  tff(decl_79489, type, fn_vulval_precursor_cell_16: $i > $i).
% 29.32/29.16  tff(decl_79490, type, fn_vulval_precursor_cell_17: $i > $i).
% 29.32/29.16  tff(decl_79491, type, fn_vulval_precursor_cell_18: $i > $i).
% 29.32/29.16  tff(decl_79492, type, fn_vulval_precursor_cell_19: $i > $i).
% 29.32/29.16  tff(decl_79493, type, fn_vulval_precursor_cell_20: $i > $i).
% 29.32/29.16  tff(decl_79494, type, fn_vulval_precursor_cell_21: $i > $i).
% 29.32/29.16  tff(decl_79495, type, fn_vulval_precursor_cell_22: $i > $i).
% 29.32/29.16  tff(decl_79496, type, fn_vulval_precursor_cell_23: $i > $i).
% 29.32/29.16  tff(decl_79497, type, fn_vulval_precursor_cell_24: $i > $i).
% 29.32/29.16  tff(decl_79498, type, fn_vulval_precursor_cell_25: $i > $i).
% 29.32/29.16  tff(decl_79499, type, fn_vulval_precursor_cell_26: $i > $i).
% 29.32/29.16  tff(decl_79500, type, fn_vulval_precursor_cell_27: $i > $i).
% 29.32/29.16  tff(decl_79501, type, fn_vulval_precursor_cell_28: $i > $i).
% 29.32/29.16  tff(decl_79502, type, fn_vulval_precursor_cell_29: $i > $i).
% 29.32/29.16  tff(decl_79503, type, fn_vulval_precursor_cell_30: $i > $i).
% 29.32/29.16  tff(decl_79504, type, fn_vulval_precursor_cell_31: $i > $i).
% 29.32/29.16  tff(decl_79505, type, fn_vulval_precursor_cell_32: $i > $i).
% 29.32/29.16  tff(decl_79506, type, fn_vulval_precursor_cell_33: $i > $i).
% 29.32/29.16  tff(decl_79507, type, fn_vulval_precursor_cell_34: $i > $i).
% 29.32/29.16  tff(decl_79508, type, fn_vulval_precursor_cell_35: $i > $i).
% 29.32/29.16  tff(decl_79509, type, fn_vulval_precursor_cell_36: $i > $i).
% 29.32/29.16  tff(decl_79510, type, fn_vulval_precursor_cell_37: $i > $i).
% 29.32/29.16  tff(decl_79511, type, fn_vulval_precursor_cell_38: $i > $i).
% 29.32/29.16  tff(decl_79512, type, fn_vulval_precursor_cell_39: $i > $i).
% 29.32/29.16  tff(decl_79513, type, fn_vulval_precursor_cell_40: $i > $i).
% 29.32/29.16  tff(decl_79514, type, fn_vulval_precursor_cell_41: $i > $i).
% 29.32/29.16  tff(decl_79515, type, fn_vulval_precursor_cell_42: $i > $i).
% 29.32/29.16  tff(decl_79516, type, fn_vulval_precursor_cell_43: $i > $i).
% 29.32/29.16  tff(decl_79517, type, fn_vulval_precursor_cell_44: $i > $i).
% 29.32/29.16  tff(decl_79518, type, fn_vulval_precursor_cell_47: $i > $i).
% 29.32/29.16  tff(decl_79519, type, fn_vulval_precursor_cell_48: $i > $i).
% 29.32/29.16  tff(decl_79520, type, fn_vulval_precursor_cell_49: $i > $i).
% 29.32/29.16  tff(decl_79521, type, fn_vulval_precursor_cell_50: $i > $i).
% 29.32/29.16  tff(decl_79522, type, fn_vulval_precursor_cell_51: $i > $i).
% 29.32/29.16  tff(decl_79523, type, fn_vulval_precursor_cell_45: $i > $i).
% 29.32/29.16  tff(decl_79524, type, fn_vulval_precursor_cell_46: $i > $i).
% 29.32/29.16  tff(decl_79525, type, 'Walk': $i).
% 29.32/29.16  tff(decl_79526, type, 'Wall': $i).
% 29.32/29.16  tff(decl_79527, type, 'a vertical architectural structure that acts as a barrier': $i).
% 29.32/29.16  tff(decl_79528, type, wall: $i).
% 29.32/29.16  tff(decl_79529, type, fn_wall_1: $i > $i).
% 29.32/29.16  tff(decl_79530, type, fn_wall_3: $i > $i).
% 29.32/29.16  tff(decl_79531, type, 'Walled-Cell': $i).
% 29.32/29.16  tff(decl_79532, type, 'A cell with cell wall is a walled cell.': $i).
% 29.32/29.16  tff(decl_79533, type, 'cell with a cell wall': $i).
% 29.32/29.16  tff(decl_79534, type, 'cell-with-a-cell-wall': $i).
% 29.32/29.16  tff(decl_79535, type, 'walled cell': $i).
% 29.32/29.16  tff(decl_79536, type, 'walled-cell': $i).
% 29.32/29.16  tff(decl_79537, type, 'Walled-Cell-Inside-Hypertonic-Solution': $i).
% 29.32/29.16  tff(decl_79538, type, 'This is the situation when walled cell is placed inside hypertonic solution.': $i).
% 29.32/29.16  tff(decl_79539, type, 'walled cell inside hypertonic solution': $i).
% 29.32/29.16  tff(decl_79540, type, 'walled-cell-inside-hypertonic-solution': $i).
% 29.32/29.16  tff(decl_79541, type, fn_walled_cell_inside_hypertonic_solution_1: $i > $i).
% 29.32/29.16  tff(decl_79542, type, fn_walled_cell_inside_hypertonic_solution_2: $i > $i).
% 29.32/29.16  tff(decl_79543, type, fn_walled_cell_inside_hypertonic_solution_5: $i > $i).
% 29.32/29.16  tff(decl_79544, type, fn_walled_cell_inside_hypertonic_solution_12: $i > $i).
% 29.32/29.16  tff(decl_79545, type, fn_walled_cell_inside_hypertonic_solution_13: $i > $i).
% 29.32/29.16  tff(decl_79546, type, fn_walled_cell_inside_hypertonic_solution_14: $i > $i).
% 29.32/29.16  tff(decl_79547, type, fn_walled_cell_inside_hypertonic_solution_22: $i > $i).
% 29.32/29.16  tff(decl_79548, type, fn_walled_cell_inside_hypertonic_solution_23: $i > $i).
% 29.32/29.16  tff(decl_79549, type, fn_walled_cell_inside_hypertonic_solution_25: $i > $i).
% 29.32/29.16  tff(decl_79550, type, fn_walled_cell_inside_hypertonic_solution_26: $i > $i).
% 29.32/29.16  tff(decl_79551, type, fn_walled_cell_inside_hypertonic_solution_27: $i > $i).
% 29.32/29.16  tff(decl_79552, type, fn_walled_cell_inside_hypertonic_solution_28: $i > $i).
% 29.32/29.16  tff(decl_79553, type, fn_walled_cell_inside_hypertonic_solution_36: $i > $i).
% 29.32/29.16  tff(decl_79554, type, fn_walled_cell_inside_hypertonic_solution_37: $i > $i).
% 29.32/29.16  tff(decl_79555, type, fn_plasmolysis_2: $i > $i).
% 29.32/29.16  tff(decl_79556, type, fn_plasmolysis_1: $i > $i).
% 29.32/29.16  tff(decl_79557, type, 'Walled-Cell-Inside-Hypotonic-Solution': $i).
% 29.32/29.16  tff(decl_79558, type, 'This is the situation in which walled cell is placed inside hypotonic solution.': $i).
% 29.32/29.16  tff(decl_79559, type, 'walled cell inside hypotonic solution': $i).
% 29.32/29.16  tff(decl_79560, type, 'walled-cell-inside-hypotonic-solution': $i).
% 29.32/29.16  tff(decl_79561, type, fn_walled_cell_inside_hypotonic_solution_1: $i > $i).
% 29.32/29.16  tff(decl_79562, type, fn_walled_cell_inside_hypotonic_solution_2: $i > $i).
% 29.32/29.16  tff(decl_79563, type, fn_walled_cell_inside_hypotonic_solution_5: $i > $i).
% 29.32/29.16  tff(decl_79564, type, fn_walled_cell_inside_hypotonic_solution_6: $i > $i).
% 29.32/29.16  tff(decl_79565, type, fn_walled_cell_inside_hypotonic_solution_7: $i > $i).
% 29.32/29.16  tff(decl_79566, type, fn_walled_cell_inside_hypotonic_solution_8: $i > $i).
% 29.32/29.16  tff(decl_79567, type, fn_walled_cell_inside_hypotonic_solution_10: $i > $i).
% 29.32/29.16  tff(decl_79568, type, fn_walled_cell_inside_hypotonic_solution_11: $i > $i).
% 29.32/29.16  tff(decl_79569, type, fn_walled_cell_inside_hypotonic_solution_13: $i > $i).
% 29.32/29.16  tff(decl_79570, type, fn_walled_cell_inside_hypotonic_solution_18: $i > $i).
% 29.32/29.16  tff(decl_79571, type, fn_walled_cell_inside_hypotonic_solution_19: $i > $i).
% 29.32/29.16  tff(decl_79572, type, fn_walled_cell_inside_hypotonic_solution_20: $i > $i).
% 29.32/29.16  tff(decl_79573, type, fn_walled_cell_inside_hypotonic_solution_21: $i > $i).
% 29.32/29.16  tff(decl_79574, type, fn_walled_cell_inside_hypotonic_solution_22: $i > $i).
% 29.32/29.16  tff(decl_79575, type, fn_walled_cell_inside_hypotonic_solution_23: $i > $i).
% 29.32/29.16  tff(decl_79576, type, fn_walled_cell_inside_hypotonic_solution_24: $i > $i).
% 29.32/29.16  tff(decl_79577, type, fn_walled_cell_inside_hypotonic_solution_25: $i > $i).
% 29.32/29.16  tff(decl_79578, type, fn_walled_cell_inside_hypotonic_solution_26: $i > $i).
% 29.32/29.16  tff(decl_79579, type, fn_walled_cell_inside_hypotonic_solution_27: $i > $i).
% 29.32/29.16  tff(decl_79580, type, fn_walled_cell_inside_hypotonic_solution_28: $i > $i).
% 29.32/29.16  tff(decl_79581, type, fn_walled_cell_inside_hypotonic_solution_29: $i > $i).
% 29.32/29.16  tff(decl_79582, type, fn_walled_cell_inside_hypotonic_solution_30: $i > $i).
% 29.32/29.16  tff(decl_79583, type, fn_walled_cell_inside_hypotonic_solution_31: $i > $i).
% 29.32/29.16  tff(decl_79584, type, fn_walled_cell_inside_hypotonic_solution_33: $i > $i).
% 29.32/29.16  tff(decl_79585, type, fn_walled_cell_inside_hypotonic_solution_34: $i > $i).
% 29.32/29.16  tff(decl_79586, type, fn_walled_cell_inside_hypotonic_solution_35: $i > $i).
% 29.32/29.16  tff(decl_79587, type, fn_walled_cell_inside_hypotonic_solution_36: $i > $i).
% 29.32/29.16  tff(decl_79588, type, fn_walled_cell_inside_hypotonic_solution_37: $i > $i).
% 29.32/29.16  tff(decl_79589, type, fn_walled_cell_inside_hypotonic_solution_38: $i > $i).
% 29.32/29.16  tff(decl_79590, type, fn_walled_cell_inside_hypotonic_solution_39: $i > $i).
% 29.32/29.16  tff(decl_79591, type, fn_walled_cell_inside_hypotonic_solution_40: $i > $i).
% 29.32/29.16  tff(decl_79592, type, fn_walled_cell_inside_hypotonic_solution_41: $i > $i).
% 29.32/29.16  tff(decl_79593, type, fn_walled_cell_inside_hypotonic_solution_42: $i > $i).
% 29.32/29.16  tff(decl_79594, type, fn_walled_cell_inside_hypotonic_solution_43: $i > $i).
% 29.32/29.16  tff(decl_79595, type, fn_walled_cell_inside_hypotonic_solution_44: $i > $i).
% 29.32/29.16  tff(decl_79596, type, fn_walled_cell_inside_hypotonic_solution_45: $i > $i).
% 29.32/29.16  tff(decl_79597, type, fn_walled_cell_inside_hypotonic_solution_46: $i > $i).
% 29.32/29.16  tff(decl_79598, type, fn_walled_cell_inside_hypotonic_solution_54: $i > $i).
% 29.32/29.16  tff(decl_79599, type, fn_walled_cell_inside_hypotonic_solution_55: $i > $i).
% 29.32/29.16  tff(decl_79600, type, fn_walled_cell_inside_hypotonic_solution_56: $i > $i).
% 29.32/29.16  tff(decl_79601, type, fn_walled_cell_inside_hypotonic_solution_57: $i > $i).
% 29.32/29.16  tff(decl_79602, type, fn_walled_cell_inside_hypotonic_solution_58: $i > $i).
% 29.32/29.16  tff(decl_79603, type, fn_walled_cell_inside_hypotonic_solution_59: $i > $i).
% 29.32/29.16  tff(decl_79604, type, fn_walled_cell_inside_hypotonic_solution_60: $i > $i).
% 29.32/29.16  tff(decl_79605, type, fn_walled_cell_inside_hypotonic_solution_61: $i > $i).
% 29.32/29.16  tff(decl_79606, type, fn_walled_cell_inside_hypotonic_solution_62: $i > $i).
% 29.32/29.16  tff(decl_79607, type, fn_walled_cell_inside_hypotonic_solution_63: $i > $i).
% 29.32/29.16  tff(decl_79608, type, fn_walled_cell_inside_hypotonic_solution_64: $i > $i).
% 29.32/29.16  tff(decl_79609, type, fn_walled_cell_inside_hypotonic_solution_65: $i > $i).
% 29.32/29.16  tff(decl_79610, type, fn_walled_cell_inside_hypotonic_solution_66: $i > $i).
% 29.32/29.16  tff(decl_79611, type, fn_walled_cell_inside_hypotonic_solution_67: $i > $i).
% 29.32/29.16  tff(decl_79612, type, fn_walled_cell_inside_hypotonic_solution_68: $i > $i).
% 29.32/29.16  tff(decl_79613, type, fn_walled_cell_inside_hypotonic_solution_69: $i > $i).
% 29.32/29.16  tff(decl_79614, type, fn_walled_cell_inside_hypotonic_solution_70: $i > $i).
% 29.32/29.16  tff(decl_79615, type, fn_walled_cell_inside_hypotonic_solution_71: $i > $i).
% 29.32/29.16  tff(decl_79616, type, fn_walled_cell_inside_hypotonic_solution_72: $i > $i).
% 29.32/29.16  tff(decl_79617, type, fn_walled_cell_inside_hypotonic_solution_73: $i > $i).
% 29.32/29.16  tff(decl_79618, type, fn_walled_cell_inside_hypotonic_solution_74: $i > $i).
% 29.32/29.16  tff(decl_79619, type, fn_walled_cell_inside_hypotonic_solution_75: $i > $i).
% 29.32/29.16  tff(decl_79620, type, fn_walled_cell_inside_hypotonic_solution_76: $i > $i).
% 29.32/29.16  tff(decl_79621, type, fn_walled_cell_inside_hypotonic_solution_77: $i > $i).
% 29.32/29.16  tff(decl_79622, type, fn_walled_cell_inside_hypotonic_solution_78: $i > $i).
% 29.32/29.16  tff(decl_79623, type, fn_walled_cell_inside_hypotonic_solution_79: $i > $i).
% 29.32/29.16  tff(decl_79624, type, fn_walled_cell_inside_hypotonic_solution_80: $i > $i).
% 29.32/29.16  tff(decl_79625, type, fn_walled_cell_inside_hypotonic_solution_81: $i > $i).
% 29.32/29.16  tff(decl_79626, type, fn_walled_cell_inside_hypotonic_solution_82: $i > $i).
% 29.32/29.16  tff(decl_79627, type, fn_walled_cell_inside_hypotonic_solution_83: $i > $i).
% 29.32/29.16  tff(decl_79628, type, fn_walled_cell_inside_hypotonic_solution_84: $i > $i).
% 29.32/29.16  tff(decl_79629, type, fn_walled_cell_inside_hypotonic_solution_85: $i > $i).
% 29.32/29.16  tff(decl_79630, type, fn_walled_cell_inside_hypotonic_solution_86: $i > $i).
% 29.32/29.16  tff(decl_79631, type, fn_walled_cell_inside_hypotonic_solution_87: $i > $i).
% 29.32/29.16  tff(decl_79632, type, fn_walled_cell_inside_hypotonic_solution_88: $i > $i).
% 29.32/29.16  tff(decl_79633, type, fn_walled_cell_inside_hypotonic_solution_89: $i > $i).
% 29.32/29.16  tff(decl_79634, type, fn_turgid_cell_13: $i > $i).
% 29.32/29.16  tff(decl_79635, type, fn_turgid_cell_28: $i > $i).
% 29.32/29.16  tff(decl_79636, type, fn_turgid_cell_12: $i > $i).
% 29.32/29.16  tff(decl_79637, type, fn_walled_cell_inside_hypotonic_solution_12: $i > $i).
% 29.32/29.16  tff(decl_79638, type, fn_walled_cell_inside_hypotonic_solution_51: $i > $i).
% 29.32/29.16  tff(decl_79639, type, fn_walled_cell_inside_hypotonic_solution_32: $i > $i).
% 29.32/29.16  tff(decl_79640, type, fn_walled_cell_inside_hypotonic_solution_9: $i > $i).
% 29.32/29.16  tff(decl_79641, type, fn_walled_cell_inside_hypotonic_solution_52: $i > $i).
% 29.32/29.16  tff(decl_79642, type, fn_walled_cell_inside_hypotonic_solution_53: $i > $i).
% 29.32/29.16  tff(decl_79643, type, fn_walled_cell_inside_hypotonic_solution_47: $i > $i).
% 29.32/29.16  tff(decl_79644, type, fn_walled_cell_inside_hypotonic_solution_48: $i > $i).
% 29.32/29.16  tff(decl_79645, type, fn_walled_cell_inside_hypotonic_solution_17: $i > $i).
% 29.32/29.16  tff(decl_79646, type, fn_walled_cell_inside_hypotonic_solution_49: $i > $i).
% 29.32/29.16  tff(decl_79647, type, fn_walled_cell_inside_hypotonic_solution_50: $i > $i).
% 29.32/29.16  tff(decl_79648, type, fn_walled_cell_inside_hypotonic_solution_14: $i > $i).
% 29.32/29.16  tff(decl_79649, type, fn_walled_cell_inside_hypotonic_solution_15: $i > $i).
% 29.32/29.16  tff(decl_79650, type, fn_walled_cell_inside_hypotonic_solution_16: $i > $i).
% 29.32/29.16  tff(decl_79651, type, fn_walled_cell_inside_hypotonic_solution_90: $i > $i).
% 29.32/29.16  tff(decl_79652, type, 'Walled-Cell-Inside-Isotonic-Solution': $i).
% 29.32/29.16  tff(decl_79653, type, 'This is the situation in which walled cell is placed inside isotonic solution.': $i).
% 29.32/29.16  tff(decl_79654, type, 'walled cell inside isotonic solution': $i).
% 29.32/29.16  tff(decl_79655, type, 'walled-cell-inside-isotonic-solution': $i).
% 29.32/29.16  tff(decl_79656, type, fn_walled_cell_inside_isotonic_solution_1: $i > $i).
% 29.32/29.16  tff(decl_79657, type, fn_walled_cell_inside_isotonic_solution_2: $i > $i).
% 29.32/29.16  tff(decl_79658, type, fn_walled_cell_inside_isotonic_solution_5: $i > $i).
% 29.32/29.16  tff(decl_79659, type, fn_walled_cell_inside_isotonic_solution_18: $i > $i).
% 29.32/29.16  tff(decl_79660, type, fn_walled_cell_inside_isotonic_solution_20: $i > $i).
% 29.32/29.16  tff(decl_79661, type, fn_walled_cell_inside_isotonic_solution_19: $i > $i).
% 29.32/29.16  tff(decl_79662, type, walled_protist_cell_1: $i > $o).
% 29.32/29.16  tff(decl_79663, type, fn_walled_protist_cell_2: $i > $i).
% 29.32/29.16  tff(decl_79664, type, 'Walled-Protist-Cell': $i).
% 29.32/29.16  tff(decl_79665, type, 'It is a protist cell that contains a cell-wall.': $i).
% 29.32/29.16  tff(decl_79666, type, 'walled protist cell': $i).
% 29.32/29.16  tff(decl_79667, type, 'walled-protist-cell': $i).
% 29.32/29.16  tff(decl_79668, type, walther_flemming_1: $i > $o).
% 29.32/29.16  tff(decl_79669, type, 'Walther-Flemming': $i).
% 29.32/29.16  tff(decl_79670, type, 'German biologist who studied the cell cycle and is credited with the discovery of chromatin and identifying the steps of mitosis.': $i).
% 29.32/29.16  tff(decl_79671, type, 'walther flemming': $i).
% 29.32/29.16  tff(decl_79672, type, 'walther-flemming': $i).
% 29.32/29.16  tff(decl_79673, type, warm_object_1: $i > $o).
% 29.32/29.16  tff(decl_79674, type, 'Warm-Object': $i).
% 29.32/29.16  tff(decl_79675, type, 'An object whose temperature has increased slightly.': $i).
% 29.32/29.16  tff(decl_79676, type, 'warm object': $i).
% 29.32/29.16  tff(decl_79677, type, 'warm-object': $i).
% 29.32/29.16  tff(decl_79678, type, fn_warm_object_4: $i > $i).
% 29.32/29.16  tff(decl_79679, type, fn_warm_object_6: $i > $i).
% 29.32/29.16  tff(decl_79680, type, fn_warm_object_7: $i > $i).
% 29.32/29.16  tff(decl_79681, type, fn_warm_object_8: $i > $i).
% 29.32/29.16  tff(decl_79682, type, fn_warm_object_10: $i > $i).
% 29.32/29.16  tff(decl_79683, type, fn_warm_object_11: $i > $i).
% 29.32/29.16  tff(decl_79684, type, fn_warm_object_12: $i > $i).
% 29.32/29.16  tff(decl_79685, type, fn_warm_object_13: $i > $i).
% 29.32/29.16  tff(decl_79686, type, fn_warm_object_14: $i > $i).
% 29.32/29.16  tff(decl_79687, type, fn_warm_object_15: $i > $i).
% 29.32/29.16  tff(decl_79688, type, fn_warm_object_17: $i > $i).
% 29.32/29.16  tff(decl_79689, type, fn_warm_object_18: $i > $i).
% 29.32/29.16  tff(decl_79690, type, fn_warm_object_19: $i > $i).
% 29.32/29.16  tff(decl_79691, type, fn_warm_object_20: $i > $i).
% 29.32/29.16  tff(decl_79692, type, fn_warm_object_21: $i > $i).
% 29.32/29.16  tff(decl_79693, type, fn_warm_object_22: $i > $i).
% 29.32/29.16  tff(decl_79694, type, 'FinalTemperature_WarmBody': $i).
% 29.32/29.16  tff(decl_79695, type, 'FinalTemperature_CoolBody': $i).
% 29.32/29.16  tff(decl_79696, type, fn_warm_object_23: $i > $i).
% 29.32/29.16  tff(decl_79697, type, fn_warm_object_16: $i > $i).
% 29.32/29.16  tff(decl_79698, type, fn_warm_object_9: $i > $i).
% 29.32/29.16  tff(decl_79699, type, 'WAS-Protein': $i).
% 29.32/29.16  tff(decl_79700, type, 'Protein, named after WAS or Wiskott-Aldrich syndrome, which plays an important role in the relay of cellular signals in the cellular immune system response by organizing the cytoskeleton for proper signal transduction. Absence of the protein leads to WAS Syndrome.': $i).
% 29.32/29.16  tff(decl_79701, type, 'was protein': $i).
% 29.32/29.16  tff(decl_79702, type, 'was-protein': $i).
% 29.32/29.16  tff(decl_79703, type, fn_was_protein_9: $i > $i).
% 29.32/29.16  tff(decl_79704, type, fn_was_protein_10: $i > $i).
% 29.32/29.16  tff(decl_79705, type, fn_was_protein_11: $i > $i).
% 29.32/29.16  tff(decl_79706, type, fn_was_protein_12: $i > $i).
% 29.32/29.16  tff(decl_79707, type, fn_was_protein_13: $i > $i).
% 29.32/29.16  tff(decl_79708, type, fn_was_protein_14: $i > $i).
% 29.32/29.16  tff(decl_79709, type, fn_was_protein_15: $i > $i).
% 29.32/29.16  tff(decl_79710, type, fn_was_protein_16: $i > $i).
% 29.32/29.16  tff(decl_79711, type, fn_was_protein_17: $i > $i).
% 29.32/29.16  tff(decl_79712, type, fn_was_protein_18: $i > $i).
% 29.32/29.16  tff(decl_79713, type, fn_was_protein_19: $i > $i).
% 29.32/29.16  tff(decl_79714, type, fn_was_protein_20: $i > $i).
% 29.32/29.16  tff(decl_79715, type, fn_was_protein_21: $i > $i).
% 29.32/29.16  tff(decl_79716, type, fn_was_protein_22: $i > $i).
% 29.32/29.16  tff(decl_79717, type, fn_was_protein_23: $i > $i).
% 29.32/29.16  tff(decl_79718, type, fn_was_protein_24: $i > $i).
% 29.32/29.16  tff(decl_79719, type, fn_was_protein_25: $i > $i).
% 29.32/29.16  tff(decl_79720, type, fn_was_protein_26: $i > $i).
% 29.32/29.16  tff(decl_79721, type, fn_was_protein_27: $i > $i).
% 29.32/29.16  tff(decl_79722, type, fn_was_protein_28: $i > $i).
% 29.32/29.16  tff(decl_79723, type, fn_was_protein_29: $i > $i).
% 29.32/29.16  tff(decl_79724, type, fn_was_protein_30: $i > $i).
% 29.32/29.16  tff(decl_79725, type, fn_was_protein_31: $i > $i).
% 29.32/29.16  tff(decl_79726, type, fn_was_protein_32: $i > $i).
% 29.32/29.16  tff(decl_79727, type, fn_was_protein_33: $i > $i).
% 29.32/29.16  tff(decl_79728, type, fn_was_protein_34: $i > $i).
% 29.32/29.16  tff(decl_79729, type, fn_was_protein_35: $i > $i).
% 29.32/29.16  tff(decl_79730, type, fn_was_protein_36: $i > $i).
% 29.32/29.16  tff(decl_79731, type, fn_was_protein_37: $i > $i).
% 29.32/29.16  tff(decl_79732, type, fn_was_protein_38: $i > $i).
% 29.32/29.16  tff(decl_79733, type, fn_was_protein_39: $i > $i).
% 29.32/29.16  tff(decl_79734, type, fn_was_protein_8: $i > $i).
% 29.32/29.16  tff(decl_79735, type, fn_was_protein_4: $i > $i).
% 29.32/29.16  tff(decl_79736, type, fn_was_protein_3: $i > $i).
% 29.32/29.16  tff(decl_79737, type, fn_was_protein_2: $i > $i).
% 29.32/29.16  tff(decl_79738, type, fn_was_protein_5: $i > $i).
% 29.32/29.16  tff(decl_79739, type, fn_was_protein_7: $i > $i).
% 29.32/29.16  tff(decl_79740, type, fn_was_protein_6: $i > $i).
% 29.32/29.16  tff(decl_79741, type, fn_was_protein_1: $i > $i).
% 29.32/29.16  tff(decl_79742, type, 'Waste': $i).
% 29.32/29.16  tff(decl_79743, type, 'A waste product of a Consume action.': $i).
% 29.32/29.16  tff(decl_79744, type, waste: $i).
% 29.32/29.16  tff(decl_79745, type, 'Waste-Product': $i).
% 29.32/29.16  tff(decl_79746, type, 'Waste is also referred to as rubbish, trash, garbage, or junk depending upon the type of material and the regional terminology.': $i).
% 29.32/29.16  tff(decl_79747, type, 'product of waste': $i).
% 29.32/29.16  tff(decl_79748, type, 'waste product': $i).
% 29.32/29.17  tff(decl_79749, type, 'waste-product': $i).
% 29.32/29.17  tff(decl_79750, type, 'Water': $i).
% 29.32/29.17  tff(decl_79751, type, 'A molecular compound composed of hydrogen and oxygen atoms (formula H2O).  It is a clear, odorless, tasteless liquid, with a freezing point at 32F or 0C and boiling point at 212F or 100C, that in a more or less impure state constitutes rain, oceans, lakes, rivers, etc. and exists in all three states, solid, liquid, and gas, in nature.': $i).
% 29.32/29.17  tff(decl_79752, type, 'universal solvent': $i).
% 29.32/29.17  tff(decl_79753, type, water: $i).
% 29.32/29.17  tff(decl_79754, type, fn_water_4: $i > $i).
% 29.32/29.17  tff(decl_79755, type, fn_water_5: $i > $i).
% 29.32/29.17  tff(decl_79756, type, fn_water_6: $i > $i).
% 29.32/29.17  tff(decl_79757, type, fn_water_10: $i > $i).
% 29.32/29.17  tff(decl_79758, type, fn_water_11: $i > $i).
% 29.32/29.17  tff(decl_79759, type, fn_water_12: $i > $i).
% 29.32/29.17  tff(decl_79760, type, fn_water_13: $i > $i).
% 29.32/29.17  tff(decl_79761, type, fn_water_16: $i > $i).
% 29.32/29.17  tff(decl_79762, type, fn_water_28: $i > $i).
% 29.32/29.17  tff(decl_79763, type, fn_water_29: $i > $i).
% 29.32/29.17  tff(decl_79764, type, fn_water_34: $i > $i).
% 29.32/29.17  tff(decl_79765, type, fn_water_36: $i > $i).
% 29.32/29.17  tff(decl_79766, type, fn_water_37: $i > $i).
% 29.32/29.17  tff(decl_79767, type, fn_water_38: $i > $i).
% 29.32/29.17  tff(decl_79768, type, fn_water_55: $i > $i).
% 29.32/29.17  tff(decl_79769, type, fn_water_56: $i > $i).
% 29.32/29.17  tff(decl_79770, type, fn_water_57: $i > $i).
% 29.32/29.17  tff(decl_79771, type, fn_water_58: $i > $i).
% 29.32/29.17  tff(decl_79772, type, fn_water_59: $i > $i).
% 29.32/29.17  tff(decl_79773, type, fn_water_60: $i > $i).
% 29.32/29.17  tff(decl_79774, type, fn_water_61: $i > $i).
% 29.32/29.17  tff(decl_79775, type, fn_water_63: $i > $i).
% 29.32/29.17  tff(decl_79776, type, fn_water_64: $i > $i).
% 29.32/29.17  tff(decl_79777, type, fn_water_65: $i > $i).
% 29.32/29.17  tff(decl_79778, type, fn_water_66: $i > $i).
% 29.32/29.17  tff(decl_79779, type, fn_water_67: $i > $i).
% 29.32/29.17  tff(decl_79780, type, fn_water_68: $i > $i).
% 29.32/29.17  tff(decl_79781, type, fn_water_69: $i > $i).
% 29.32/29.17  tff(decl_79782, type, fn_water_70: $i > $i).
% 29.32/29.17  tff(decl_79783, type, fn_water_71: $i > $i).
% 29.32/29.17  tff(decl_79784, type, fn_water_73: $i > $i).
% 29.32/29.17  tff(decl_79785, type, fn_water_74: $i > $i).
% 29.32/29.17  tff(decl_79786, type, fn_water_77: $i > $i).
% 29.32/29.17  tff(decl_79787, type, fn_water_82: $i > $i).
% 29.32/29.17  tff(decl_79788, type, fn_water_85: $i > $i).
% 29.32/29.17  tff(decl_79789, type, fn_water_90: $i > $i).
% 29.32/29.17  tff(decl_79790, type, fn_water_91: $i > $i).
% 29.32/29.17  tff(decl_79791, type, fn_water_102: $i > $i).
% 29.32/29.17  tff(decl_79792, type, fn_water_103: $i > $i).
% 29.32/29.17  tff(decl_79793, type, fn_water_104: $i > $i).
% 29.32/29.17  tff(decl_79794, type, fn_water_108: $i > $i).
% 29.32/29.17  tff(decl_79795, type, fn_water_111: $i > $i).
% 29.32/29.17  tff(decl_79796, type, fn_water_112: $i > $i).
% 29.32/29.17  tff(decl_79797, type, fn_water_115: $i > $i).
% 29.32/29.17  tff(decl_79798, type, fn_water_molecule_31: $i > $i).
% 29.32/29.17  tff(decl_79799, type, fn_water_molecule_22: $i > $i).
% 29.32/29.17  tff(decl_79800, type, fn_water_molecule_29: $i > $i).
% 29.32/29.17  tff(decl_79801, type, fn_water_molecule_28: $i > $i).
% 29.32/29.17  tff(decl_79802, type, fn_water_molecule_30: $i > $i).
% 29.32/29.17  tff(decl_79803, type, fn_water_molecule_25: $i > $i).
% 29.32/29.17  tff(decl_79804, type, fn_water_molecule_23: $i > $i).
% 29.32/29.17  tff(decl_79805, type, fn_water_molecule_24: $i > $i).
% 29.32/29.17  tff(decl_79806, type, fn_water_molecule_59: $i > $i).
% 29.32/29.17  tff(decl_79807, type, fn_water_molecule_67: $i > $i).
% 29.32/29.17  tff(decl_79808, type, fn_water_molecule_7: $i > $i).
% 29.32/29.17  tff(decl_79809, type, fn_water_molecule_21: $i > $i).
% 29.32/29.17  tff(decl_79810, type, fn_water_molecule_15: $i > $i).
% 29.32/29.17  tff(decl_79811, type, fn_water_molecule_65: $i > $i).
% 29.32/29.17  tff(decl_79812, type, fn_water_molecule_60: $i > $i).
% 29.32/29.17  tff(decl_79813, type, fn_water_molecule_57: $i > $i).
% 29.32/29.17  tff(decl_79814, type, fn_water_molecule_49: $i > $i).
% 29.32/29.17  tff(decl_79815, type, hydrogen_bond_0: $i).
% 29.32/29.17  tff(decl_79816, type, "580.0e0": $i).
% 29.32/29.17  tff(decl_79817, type, fn_water_75: $i > $i).
% 29.32/29.17  tff(decl_79818, type, fn_water_86: $i > $i).
% 29.32/29.17  tff(decl_79819, type, fn_water_116: $i > $i).
% 29.32/29.17  tff(decl_79820, type, fn_water_48: $i > $i).
% 29.32/29.17  tff(decl_79821, type, fn_water_54: $i > $i).
% 29.32/29.17  tff(decl_79822, type, fn_water_53: $i > $i).
% 29.32/29.17  tff(decl_79823, type, fn_water_50: $i > $i).
% 29.32/29.17  tff(decl_79824, type, fn_water_52: $i > $i).
% 29.32/29.17  tff(decl_79825, type, fn_water_51: $i > $i).
% 29.32/29.17  tff(decl_79826, type, fn_water_62: $i > $i).
% 29.32/29.17  tff(decl_79827, type, fn_water_49: $i > $i).
% 29.32/29.17  tff(decl_79828, type, fn_water_46: $i > $i).
% 29.32/29.17  tff(decl_79829, type, fn_water_45: $i > $i).
% 29.32/29.17  tff(decl_79830, type, fn_water_47: $i > $i).
% 29.32/29.17  tff(decl_79831, type, fn_water_72: $i > $i).
% 29.32/29.17  tff(decl_79832, type, water_at_zero_degree_celcius_1: $i > $o).
% 29.32/29.17  tff(decl_79833, type, 'Water-At-Zero-Degree-Celcius': $i).
% 29.32/29.17  tff(decl_79834, type, 'At zero degrees Celcius, water freezes and becomes solid.': $i).
% 29.32/29.17  tff(decl_79835, type, 'water at zero degrees': $i).
% 29.32/29.17  tff(decl_79836, type, 'water at zero degree celcius': $i).
% 29.32/29.17  tff(decl_79837, type, 'water-at-zero-degree-celcius': $i).
% 29.32/29.17  tff(decl_79838, type, fn_water_at_zero_degree_celcius_3: $i > $i).
% 29.32/29.17  tff(decl_79839, type, fn_water_at_zero_degree_celcius_4: $i > $i).
% 29.32/29.17  tff(decl_79840, type, fn_water_at_zero_degree_celcius_7: $i > $i).
% 29.32/29.17  tff(decl_79841, type, fn_water_at_zero_degree_celcius_8: $i > $i).
% 29.32/29.17  tff(decl_79842, type, fn_water_at_zero_degree_celcius_9: $i > $i).
% 29.32/29.17  tff(decl_79843, type, fn_water_at_zero_degree_celcius_10: $i > $i).
% 29.32/29.17  tff(decl_79844, type, fn_water_at_zero_degree_celcius_11: $i > $i).
% 29.32/29.17  tff(decl_79845, type, fn_water_at_zero_degree_celcius_12: $i > $i).
% 29.32/29.17  tff(decl_79846, type, fn_water_at_zero_degree_celcius_13: $i > $i).
% 29.32/29.17  tff(decl_79847, type, fn_water_at_zero_degree_celcius_14: $i > $i).
% 29.32/29.17  tff(decl_79848, type, fn_water_at_zero_degree_celcius_15: $i > $i).
% 29.32/29.17  tff(decl_79849, type, fn_water_at_zero_degree_celcius_16: $i > $i).
% 29.32/29.17  tff(decl_79850, type, fn_water_at_zero_degree_celcius_17: $i > $i).
% 29.32/29.17  tff(decl_79851, type, fn_water_at_zero_degree_celcius_18: $i > $i).
% 29.32/29.17  tff(decl_79852, type, fn_water_at_zero_degree_celcius_19: $i > $i).
% 29.32/29.17  tff(decl_79853, type, fn_water_at_zero_degree_celcius_20: $i > $i).
% 29.32/29.17  tff(decl_79854, type, fn_water_at_zero_degree_celcius_21: $i > $i).
% 29.32/29.17  tff(decl_79855, type, fn_water_at_zero_degree_celcius_22: $i > $i).
% 29.32/29.17  tff(decl_79856, type, fn_water_at_zero_degree_celcius_23: $i > $i).
% 29.32/29.17  tff(decl_79857, type, fn_water_at_zero_degree_celcius_24: $i > $i).
% 29.32/29.17  tff(decl_79858, type, fn_water_at_zero_degree_celcius_26: $i > $i).
% 29.32/29.17  tff(decl_79859, type, fn_water_at_zero_degree_celcius_27: $i > $i).
% 29.32/29.17  tff(decl_79860, type, fn_water_at_zero_degree_celcius_28: $i > $i).
% 29.32/29.17  tff(decl_79861, type, fn_water_at_zero_degree_celcius_29: $i > $i).
% 29.32/29.17  tff(decl_79862, type, fn_water_at_zero_degree_celcius_30: $i > $i).
% 29.32/29.17  tff(decl_79863, type, fn_water_at_zero_degree_celcius_31: $i > $i).
% 29.32/29.17  tff(decl_79864, type, fn_water_at_zero_degree_celcius_32: $i > $i).
% 29.32/29.17  tff(decl_79865, type, fn_water_at_zero_degree_celcius_33: $i > $i).
% 29.32/29.17  tff(decl_79866, type, fn_water_at_zero_degree_celcius_34: $i > $i).
% 29.32/29.17  tff(decl_79867, type, fn_water_at_zero_degree_celcius_35: $i > $i).
% 29.32/29.17  tff(decl_79868, type, fn_water_at_zero_degree_celcius_36: $i > $i).
% 29.32/29.17  tff(decl_79869, type, fn_water_at_zero_degree_celcius_37: $i > $i).
% 29.32/29.17  tff(decl_79870, type, fn_water_at_zero_degree_celcius_38: $i > $i).
% 29.32/29.17  tff(decl_79871, type, fn_water_at_zero_degree_celcius_39: $i > $i).
% 29.32/29.17  tff(decl_79872, type, fn_water_at_zero_degree_celcius_40: $i > $i).
% 29.32/29.17  tff(decl_79873, type, fn_water_at_zero_degree_celcius_41: $i > $i).
% 29.32/29.17  tff(decl_79874, type, fn_water_at_zero_degree_celcius_42: $i > $i).
% 29.32/29.17  tff(decl_79875, type, fn_water_at_zero_degree_celcius_43: $i > $i).
% 29.32/29.17  tff(decl_79876, type, fn_water_at_zero_degree_celcius_44: $i > $i).
% 29.32/29.17  tff(decl_79877, type, fn_water_at_zero_degree_celcius_45: $i > $i).
% 29.32/29.17  tff(decl_79878, type, fn_water_at_zero_degree_celcius_46: $i > $i).
% 29.32/29.17  tff(decl_79879, type, fn_water_at_zero_degree_celcius_47: $i > $i).
% 29.32/29.17  tff(decl_79880, type, fn_water_at_zero_degree_celcius_48: $i > $i).
% 29.32/29.17  tff(decl_79881, type, fn_water_at_zero_degree_celcius_54: $i > $i).
% 29.32/29.17  tff(decl_79882, type, fn_water_at_zero_degree_celcius_55: $i > $i).
% 29.32/29.17  tff(decl_79883, type, fn_water_molecule_56: $i > $i).
% 29.32/29.17  tff(decl_79884, type, fn_water_molecule_37: $i > $i).
% 29.32/29.17  tff(decl_79885, type, fn_water_molecule_55: $i > $i).
% 29.32/29.17  tff(decl_79886, type, fn_water_molecule_41: $i > $i).
% 29.32/29.17  tff(decl_79887, type, fn_water_molecule_71: $i > $i).
% 29.32/29.17  tff(decl_79888, type, fn_water_at_zero_degree_celcius_5: $i > $i).
% 29.32/29.17  tff(decl_79889, type, fn_water_41: $i > $i).
% 29.32/29.17  tff(decl_79890, type, fn_water_at_zero_degree_celcius_25: $i > $i).
% 29.32/29.17  tff(decl_79891, type, fn_water_at_zero_degree_celcius_6: $i > $i).
% 29.32/29.17  tff(decl_79892, type, fn_water_44: $i > $i).
% 29.32/29.17  tff(decl_79893, type, fn_water_at_zero_degree_celcius_52: $i > $i).
% 29.32/29.17  tff(decl_79894, type, fn_water_at_zero_degree_celcius_53: $i > $i).
% 29.32/29.17  tff(decl_79895, type, fn_water_at_zero_degree_celcius_50: $i > $i).
% 29.32/29.17  tff(decl_79896, type, fn_water_at_zero_degree_celcius_51: $i > $i).
% 29.32/29.17  tff(decl_79897, type, fn_water_at_zero_degree_celcius_49: $i > $i).
% 29.32/29.17  tff(decl_79898, type, 'Water-Balance': $i).
% 29.32/29.17  tff(decl_79899, type, 'In hydrology, a water balance equation can be used to describe the flow of water in and out of a system.': $i).
% 29.32/29.17  tff(decl_79900, type, 'balance of water': $i).
% 29.32/29.17  tff(decl_79901, type, 'water balance': $i).
% 29.32/29.17  tff(decl_79902, type, 'water-balance': $i).
% 29.32/29.17  tff(decl_79903, type, 'Water-Body': $i).
% 29.32/29.17  tff(decl_79904, type, 'A large area of land which is covered by water, such as an ocean or lake.': $i).
% 29.32/29.17  tff(decl_79905, type, 'deep water body': $i).
% 29.32/29.17  tff(decl_79906, type, 'deep body of water': $i).
% 29.32/29.17  tff(decl_79907, type, 'body of water': $i).
% 29.32/29.17  tff(decl_79908, type, 'water body': $i).
% 29.32/29.17  tff(decl_79909, type, 'water-body': $i).
% 29.32/29.17  tff(decl_79910, type, fn_water_body_1: $i > $i).
% 29.32/29.17  tff(decl_79911, type, fn_water_body_3: $i > $i).
% 29.32/29.17  tff(decl_79912, type, fn_water_body_4: $i > $i).
% 29.32/29.17  tff(decl_79913, type, fn_water_body_7: $i > $i).
% 29.32/29.17  tff(decl_79914, type, fn_water_body_8: $i > $i).
% 29.32/29.17  tff(decl_79915, type, fn_water_body_9: $i > $i).
% 29.32/29.17  tff(decl_79916, type, water_column_1: $i > $o).
% 29.32/29.17  tff(decl_79917, type, 'Water-Column': $i).
% 29.32/29.17  tff(decl_79918, type, 'A vertical cross section of a body of water from the water\\s surface to the bottom sediment.  This is often used to study the stratified layers in a body of water.': $i).
% 29.32/29.17  tff(decl_79919, type, 'column of water': $i).
% 29.32/29.17  tff(decl_79920, type, 'water column': $i).
% 29.32/29.17  tff(decl_79921, type, 'water-column': $i).
% 29.32/29.17  tff(decl_79922, type, fn_water_column_1: $i > $i).
% 29.32/29.17  tff(decl_79923, type, fn_water_column_2: $i > $i).
% 29.32/29.17  tff(decl_79924, type, fn_water_column_3: $i > $i).
% 29.32/29.17  tff(decl_79925, type, fn_water_column_4: $i > $i).
% 29.32/29.17  tff(decl_79926, type, 'Water-Conducting-Cell': $i).
% 29.32/29.17  tff(decl_79927, type, 'Plant cells that are involved in transport': $i).
% 29.32/29.17  tff(decl_79928, type, 'water conducting cell': $i).
% 29.32/29.17  tff(decl_79929, type, 'water-conducting-cell': $i).
% 29.32/29.17  tff(decl_79930, type, 'Water-Cycle': $i).
% 29.32/29.17  tff(decl_79931, type, 'The cycling of water through ecosystems, mainly involving changes between liquid and gaseous states.': $i).
% 29.32/29.17  tff(decl_79932, type, 'hydrological cycle': $i).
% 29.32/29.17  tff(decl_79933, type, 'h2o cycle': $i).
% 29.32/29.17  tff(decl_79934, type, 'undergo the water cycle': $i).
% 29.32/29.17  tff(decl_79935, type, cycle: $i).
% 29.32/29.17  tff(decl_79936, type, 'cycle of water': $i).
% 29.32/29.17  tff(decl_79937, type, 'water cycle': $i).
% 29.32/29.17  tff(decl_79938, type, 'water-cycle': $i).
% 29.32/29.17  tff(decl_79939, type, fn_water_cycle_1: $i > $i).
% 29.32/29.17  tff(decl_79940, type, fn_water_cycle_3: $i > $i).
% 29.32/29.17  tff(decl_79941, type, fn_water_cycle_4: $i > $i).
% 29.32/29.17  tff(decl_79942, type, fn_water_cycle_5: $i > $i).
% 29.32/29.17  tff(decl_79943, type, fn_water_cycle_6: $i > $i).
% 29.32/29.17  tff(decl_79944, type, fn_water_cycle_7: $i > $i).
% 29.32/29.17  tff(decl_79945, type, fn_water_cycle_8: $i > $i).
% 29.32/29.17  tff(decl_79946, type, fn_water_cycle_9: $i > $i).
% 29.32/29.17  tff(decl_79947, type, fn_water_cycle_10: $i > $i).
% 29.32/29.17  tff(decl_79948, type, fn_water_cycle_11: $i > $i).
% 29.32/29.17  tff(decl_79949, type, fn_water_cycle_12: $i > $i).
% 29.32/29.17  tff(decl_79950, type, fn_water_cycle_13: $i > $i).
% 29.32/29.17  tff(decl_79951, type, fn_water_cycle_14: $i > $i).
% 29.32/29.17  tff(decl_79952, type, fn_water_cycle_15: $i > $i).
% 29.32/29.17  tff(decl_79953, type, fn_water_cycle_16: $i > $i).
% 29.32/29.17  tff(decl_79954, type, fn_water_cycle_17: $i > $i).
% 29.32/29.17  tff(decl_79955, type, fn_water_cycle_18: $i > $i).
% 29.32/29.17  tff(decl_79956, type, fn_water_cycle_19: $i > $i).
% 29.32/29.17  tff(decl_79957, type, fn_water_cycle_20: $i > $i).
% 29.32/29.17  tff(decl_79958, type, fn_water_cycle_21: $i > $i).
% 29.32/29.17  tff(decl_79959, type, fn_water_cycle_22: $i > $i).
% 29.32/29.17  tff(decl_79960, type, fn_water_cycle_23: $i > $i).
% 29.32/29.17  tff(decl_79961, type, fn_water_cycle_24: $i > $i).
% 29.32/29.17  tff(decl_79962, type, fn_water_cycle_25: $i > $i).
% 29.32/29.17  tff(decl_79963, type, fn_water_cycle_26: $i > $i).
% 29.32/29.17  tff(decl_79964, type, fn_water_cycle_27: $i > $i).
% 29.32/29.17  tff(decl_79965, type, fn_water_cycle_28: $i > $i).
% 29.32/29.17  tff(decl_79966, type, fn_water_cycle_29: $i > $i).
% 29.32/29.17  tff(decl_79967, type, fn_water_cycle_30: $i > $i).
% 29.32/29.17  tff(decl_79968, type, fn_water_cycle_31: $i > $i).
% 29.32/29.17  tff(decl_79969, type, fn_water_cycle_32: $i > $i).
% 29.32/29.17  tff(decl_79970, type, fn_water_cycle_33: $i > $i).
% 29.32/29.17  tff(decl_79971, type, 'Water-Cycle-Process': $i).
% 29.32/29.17  tff(decl_79972, type, 'A process which forms a part of the water cycles in an ecosystem.': $i).
% 29.32/29.17  tff(decl_79973, type, 'water cycle process': $i).
% 29.32/29.17  tff(decl_79974, type, 'water-cycle-process': $i).
% 29.32/29.17  tff(decl_79975, type, 'Water-Evaporation': $i).
% 29.32/29.17  tff(decl_79976, type, 'When water becomes a vapor.': $i).
% 29.32/29.17  tff(decl_79977, type, 'vaporization of water': $i).
% 29.32/29.17  tff(decl_79978, type, 'evaporation of water': $i).
% 29.32/29.17  tff(decl_79979, type, 'water evaporation': $i).
% 29.32/29.17  tff(decl_79980, type, 'water-evaporation': $i).
% 29.32/29.17  tff(decl_79981, type, fn_water_evaporation_1: $i > $i).
% 29.32/29.17  tff(decl_79982, type, fn_water_evaporation_2: $i > $i).
% 29.32/29.17  tff(decl_79983, type, fn_water_evaporation_3: $i > $i).
% 29.32/29.17  tff(decl_79984, type, fn_water_evaporation_4: $i > $i).
% 29.32/29.17  tff(decl_79985, type, fn_water_evaporation_5: $i > $i).
% 29.32/29.17  tff(decl_79986, type, fn_water_evaporation_6: $i > $i).
% 29.32/29.17  tff(decl_79987, type, fn_water_evaporation_7: $i > $i).
% 29.32/29.17  tff(decl_79988, type, fn_water_evaporation_8: $i > $i).
% 29.32/29.17  tff(decl_79989, type, fn_water_evaporation_10: $i > $i).
% 29.32/29.17  tff(decl_79990, type, fn_water_evaporation_11: $i > $i).
% 29.32/29.17  tff(decl_79991, type, fn_water_evaporation_12: $i > $i).
% 29.32/29.17  tff(decl_79992, type, fn_water_evaporation_17: $i > $i).
% 29.32/29.17  tff(decl_79993, type, fn_water_evaporation_18: $i > $i).
% 29.32/29.17  tff(decl_79994, type, 'Water-Molecule': $i).
% 29.32/29.17  tff(decl_79995, type, 'A V-shaped, polar molecule composed of two hydrogen atoms covalently bonded to an oxygen atom.  The polarity and shape of the molecule is the result of the oxygen atom being more electronegative than the hydrogen atoms, and the polarity of the water molecules give rise to the unique properties of water.': $i).
% 29.32/29.17  tff(decl_79996, type, h2o: $i).
% 29.32/29.17  tff(decl_79997, type, 'molecule of water': $i).
% 29.32/29.17  tff(decl_79998, type, 'water molecule': $i).
% 29.32/29.17  tff(decl_79999, type, 'water-molecule': $i).
% 29.32/29.17  tff(decl_80000, type, fn_water_molecule_5: $i > $i).
% 29.32/29.17  tff(decl_80001, type, fn_water_molecule_14: $i > $i).
% 29.32/29.17  tff(decl_80002, type, fn_water_molecule_19: $i > $i).
% 29.32/29.17  tff(decl_80003, type, fn_water_molecule_20: $i > $i).
% 29.32/29.17  tff(decl_80004, type, fn_water_molecule_53: $i > $i).
% 29.32/29.17  tff(decl_80005, type, fn_water_molecule_58: $i > $i).
% 29.32/29.17  tff(decl_80006, type, fn_water_molecule_9: $i > $i).
% 29.32/29.17  tff(decl_80007, type, fn_water_molecule_8: $i > $i).
% 29.32/29.17  tff(decl_80008, type, fn_water_molecule_32: $i > $i).
% 29.32/29.17  tff(decl_80009, type, fn_water_molecule_11: $i > $i).
% 29.32/29.17  tff(decl_80010, type, fn_water_molecule_10: $i > $i).
% 29.32/29.17  tff(decl_80011, type, fn_water_molecule_12: $i > $i).
% 29.32/29.17  tff(decl_80012, type, fn_water_molecule_17: $i > $i).
% 29.32/29.17  tff(decl_80013, type, 'Water-Potential-Gradient': $i).
% 29.32/29.17  tff(decl_80014, type, 'A region along which the water potential increases or decreases. In other words, it is the difference in water potential between two regions.': $i).
% 29.32/29.17  tff(decl_80015, type, 'water potential gradient': $i).
% 29.32/29.17  tff(decl_80016, type, 'water-potential-gradient': $i).
% 29.32/29.17  tff(decl_80017, type, 'Water-Soluble-Protein': $i).
% 29.32/29.17  tff(decl_80018, type, 'A protein that can dissolve in water due to polar regions or ionic side chains.': $i).
% 29.32/29.17  tff(decl_80019, type, 'water soluble protein': $i).
% 29.32/29.17  tff(decl_80020, type, 'water-soluble-protein': $i).
% 29.32/29.17  tff(decl_80021, type, fn_water_soluble_protein_1: $i > $i).
% 29.32/29.17  tff(decl_80022, type, fn_water_soluble_protein_2: $i > $i).
% 29.32/29.17  tff(decl_80023, type, fn_water_soluble_protein_3: $i > $i).
% 29.32/29.17  tff(decl_80024, type, fn_water_soluble_protein_5: $i > $i).
% 29.32/29.17  tff(decl_80025, type, fn_water_soluble_protein_4: $i > $i).
% 29.32/29.17  tff(decl_80026, type, 'Water-Soluble-Vitamin': $i).
% 29.32/29.17  tff(decl_80027, type, 'A water-soluble organic molecule required in the diet in very small amounts.': $i).
% 29.32/29.17  tff(decl_80028, type, 'water soluble vitamin': $i).
% 29.32/29.17  tff(decl_80029, type, 'water-soluble-vitamin': $i).
% 29.32/29.17  tff(decl_80030, type, fn_water_soluble_vitamin_2: $i > $i).
% 29.32/29.17  tff(decl_80031, type, fn_water_soluble_vitamin_1: $i > $i).
% 29.32/29.17  tff(decl_80032, type, water_strider_1: $i > $o).
% 29.32/29.17  tff(decl_80033, type, 'Water-Strider': $i).
% 29.32/29.17  tff(decl_80034, type, 'Insect species of the order Hemiptera which lives on the surface of ponds of lakes. Hydrophobic molecules in the insect\\s legs and the surface tension of water make it possible for the insect to move on the surface.': $i).
% 29.32/29.17  tff(decl_80035, type, 'strider of water': $i).
% 29.32/29.17  tff(decl_80036, type, 'water strider': $i).
% 29.32/29.17  tff(decl_80037, type, 'water-strider': $i).
% 29.32/29.17  tff(decl_80038, type, fn_water_strider_1: $i > $i).
% 29.32/29.17  tff(decl_80039, type, fn_water_strider_2: $i > $i).
% 29.32/29.17  tff(decl_80040, type, fn_water_strider_3: $i > $i).
% 29.32/29.17  tff(decl_80041, type, fn_water_strider_4: $i > $i).
% 29.32/29.17  tff(decl_80042, type, fn_water_strider_5: $i > $i).
% 29.32/29.17  tff(decl_80043, type, fn_water_strider_6: $i > $i).
% 29.32/29.17  tff(decl_80044, type, fn_water_strider_7: $i > $i).
% 29.32/29.17  tff(decl_80045, type, fn_water_strider_8: $i > $i).
% 29.32/29.17  tff(decl_80046, type, fn_water_strider_9: $i > $i).
% 29.32/29.17  tff(decl_80047, type, fn_water_strider_10: $i > $i).
% 29.32/29.17  tff(decl_80048, type, fn_water_strider_11: $i > $i).
% 29.32/29.17  tff(decl_80049, type, fn_water_strider_12: $i > $i).
% 29.32/29.17  tff(decl_80050, type, fn_water_strider_13: $i > $i).
% 29.32/29.17  tff(decl_80051, type, fn_water_strider_14: $i > $i).
% 29.32/29.17  tff(decl_80052, type, fn_water_strider_15: $i > $i).
% 29.32/29.17  tff(decl_80053, type, fn_water_strider_16: $i > $i).
% 29.32/29.17  tff(decl_80054, type, fn_water_strider_17: $i > $i).
% 29.32/29.17  tff(decl_80055, type, fn_water_strider_18: $i > $i).
% 29.32/29.17  tff(decl_80056, type, fn_water_strider_19: $i > $i).
% 29.32/29.17  tff(decl_80057, type, fn_water_strider_20: $i > $i).
% 29.32/29.17  tff(decl_80058, type, fn_water_strider_21: $i > $i).
% 29.32/29.17  tff(decl_80059, type, fn_water_strider_22: $i > $i).
% 29.32/29.17  tff(decl_80060, type, fn_water_strider_23: $i > $i).
% 29.32/29.17  tff(decl_80061, type, fn_water_strider_24: $i > $i).
% 29.32/29.17  tff(decl_80062, type, fn_water_strider_25: $i > $i).
% 29.32/29.17  tff(decl_80063, type, 'Water-Transport-In-Plant': $i).
% 29.32/29.17  tff(decl_80064, type, 'Water enters the plant at the roots then passes up the xylem structures to the rest of the plant.': $i).
% 29.32/29.17  tff(decl_80065, type, 'water transport in plant': $i).
% 29.32/29.17  tff(decl_80066, type, 'water-transport-in-plant': $i).
% 29.32/29.17  tff(decl_80067, type, fn_water_transport_in_plant_1: $i > $i).
% 29.32/29.17  tff(decl_80068, type, fn_water_transport_in_plant_2: $i > $i).
% 29.32/29.17  tff(decl_80069, type, fn_water_transport_in_plant_4: $i > $i).
% 29.32/29.17  tff(decl_80070, type, 'Water-Vapor': $i).
% 29.32/29.17  tff(decl_80071, type, 'Water molecules suspended in the air.': $i).
% 29.32/29.17  tff(decl_80072, type, 'water vapour': $i).
% 29.32/29.17  tff(decl_80073, type, 'vapor of water': $i).
% 29.32/29.17  tff(decl_80074, type, 'water vapor': $i).
% 29.32/29.17  tff(decl_80075, type, 'water-vapor': $i).
% 29.32/29.17  tff(decl_80076, type, 'Water-Vascular-System': $i).
% 29.32/29.17  tff(decl_80077, type, 'In echinoderms, a system of fluid-filled canals that are visible externally as tube feet. The water vascular system is used for feeding, locomotion, or both. The external tube feet also function as a gas exchange surface.': $i).
% 29.32/29.17  tff(decl_80078, type, 'echinoderm vascular system': $i).
% 29.32/29.17  tff(decl_80079, type, 'echinoderm system': $i).
% 29.32/29.17  tff(decl_80080, type, 'water vascular system': $i).
% 29.32/29.17  tff(decl_80081, type, 'water-vascular-system': $i).
% 29.32/29.17  tff(decl_80082, type, 'Wax': $i).
% 29.32/29.17  tff(decl_80083, type, 'Class of lipids which is semisolid and malleable at room temperature. Waxes have a variety of functions in organisms, including lubrication, waterproofing, and protection.': $i).
% 29.32/29.17  tff(decl_80084, type, wax: $i).
% 29.32/29.17  tff(decl_80085, type, 'Waxy-Cuticle': $i).
% 29.32/29.17  tff(decl_80086, type, 'A covering on the surface of stems and leaves that prevents desiccation in terrestrial plants.': $i).
% 29.32/29.17  tff(decl_80087, type, 'waxy cuticle': $i).
% 29.32/29.17  tff(decl_80088, type, 'waxy-cuticle': $i).
% 29.32/29.17  tff(decl_80089, type, fn_waxy_cuticle_1: $i > $i).
% 29.32/29.17  tff(decl_80090, type, 'Weak-Acid': $i).
% 29.32/29.17  tff(decl_80091, type, 'An acid that does not dissociate completely. It does not release all of its hydrogens in a solution, donating only a partial amount of its protons to the solution.  Examples of weak acids include acetic acid (CH3COOH) and oxalic acid (H2C2O4).': $i).
% 29.32/29.17  tff(decl_80092, type, 'weak acid': $i).
% 29.32/29.17  tff(decl_80093, type, 'weak-acid': $i).
% 29.32/29.17  tff(decl_80094, type, fn_weak_acid_1: $i > $i).
% 29.32/29.17  tff(decl_80095, type, fn_weak_acid_4: $i > $i).
% 29.32/29.17  tff(decl_80096, type, fn_weak_acid_5: $i > $i).
% 29.32/29.17  tff(decl_80097, type, fn_weak_acid_6: $i > $i).
% 29.32/29.17  tff(decl_80098, type, fn_weak_acid_8: $i > $i).
% 29.32/29.17  tff(decl_80099, type, 'Weak-Acid-Dissociation-Reaction': $i).
% 29.32/29.17  tff(decl_80100, type, 'A reaction where only a portion of the molecules of a substance releases H+ ions into solution.': $i).
% 29.32/29.17  tff(decl_80101, type, 'weak acid dissociation reaction': $i).
% 29.32/29.17  tff(decl_80102, type, 'weak-acid-dissociation-reaction': $i).
% 29.32/29.17  tff(decl_80103, type, fn_weak_acid_dissociation_reaction_1: $i > $i).
% 29.32/29.17  tff(decl_80104, type, fn_weak_acid_dissociation_reaction_2: $i > $i).
% 29.32/29.17  tff(decl_80105, type, fn_weak_acid_dissociation_reaction_3: $i > $i).
% 29.32/29.17  tff(decl_80106, type, fn_weak_acid_dissociation_reaction_4: $i > $i).
% 29.32/29.17  tff(decl_80107, type, fn_weak_acid_dissociation_reaction_5: $i > $i).
% 29.32/29.17  tff(decl_80108, type, fn_weak_base_1: $i > $i).
% 29.32/29.17  tff(decl_80109, type, 'Weak-Base': $i).
% 29.32/29.17  tff(decl_80110, type, 'A chemical base that does not ionize fully in an aqueous solution.': $i).
% 29.32/29.17  tff(decl_80111, type, 'weak base': $i).
% 29.32/29.17  tff(decl_80112, type, 'weak-base': $i).
% 29.32/29.17  tff(decl_80113, type, strong_base_0: $i).
% 29.32/29.17  tff(decl_80114, type, 'Weak-Electrolyte': $i).
% 29.32/29.17  tff(decl_80115, type, 'weak electrolyte': $i).
% 29.32/29.17  tff(decl_80116, type, 'weak-electrolyte': $i).
% 29.32/29.17  tff(decl_80117, type, fn_weak_electrolyte_3: $i > $i).
% 29.32/29.17  tff(decl_80118, type, fn_weak_electrolyte_4: $i > $i).
% 29.32/29.17  tff(decl_80119, type, weak_electrolyte_entity_1: $i > $o).
% 29.32/29.17  tff(decl_80120, type, 'Weak-Electrolyte-Entity': $i).
% 29.32/29.17  tff(decl_80121, type, 'A weak electrolyte entity is the basic structural unit of a substance that only partly ionizes in solution.': $i).
% 29.32/29.17  tff(decl_80122, type, 'weak electrolyte entity': $i).
% 29.32/29.17  tff(decl_80123, type, 'weak-electrolyte-entity': $i).
% 29.32/29.17  tff(decl_80124, type, fn_weak_electrolyte_entity_1: $i > $i).
% 29.32/29.17  tff(decl_80125, type, fn_weak_interaction_2: $i > $i).
% 29.32/29.17  tff(decl_80126, type, 'Weak-Interaction': $i).
% 29.32/29.17  tff(decl_80127, type, 'Weak interaction (often called the weak force or sometimes the weak nuclear force) is one of the four fundamental interactions of nature, along with strong interaction, electromagnetic force, and gravitation.': $i).
% 29.32/29.17  tff(decl_80128, type, 'weak force': $i).
% 29.32/29.17  tff(decl_80129, type, 'weak-force': $i).
% 29.32/29.17  tff(decl_80130, type, 'weak nuclear force': $i).
% 29.32/29.17  tff(decl_80131, type, 'weak-nuclear-force': $i).
% 29.32/29.17  tff(decl_80132, type, 'weak chemical bond': $i).
% 29.32/29.17  tff(decl_80133, type, 'weak interaction': $i).
% 29.32/29.17  tff(decl_80134, type, 'weak-interaction': $i).
% 29.32/29.17  tff(decl_80135, type, 'Weathering': $i).
% 29.32/29.17  tff(decl_80136, type, 'The gradual wearing away or eroding of rocks at the earth\\s surface.': $i).
% 29.32/29.17  tff(decl_80137, type, weathering: $i).
% 29.32/29.17  tff(decl_80138, type, webbed_finger_1: $i > $o).
% 29.32/29.17  tff(decl_80139, type, 'Webbed-Finger': $i).
% 29.32/29.17  tff(decl_80140, type, 'A condition where two or more fingers are fused caused by failure of the fingers to separate during development in the womb.': $i).
% 29.32/29.17  tff(decl_80141, type, syndactyly: $i).
% 29.32/29.17  tff(decl_80142, type, 'webbed finger': $i).
% 29.32/29.17  tff(decl_80143, type, 'webbed-finger': $i).
% 29.32/29.17  tff(decl_80144, type, webbed_foot_development_1: $i > $o).
% 29.32/29.17  tff(decl_80145, type, 'Webbed-Foot-Development': $i).
% 29.32/29.17  tff(decl_80146, type, 'Type of limb development in certain animals, such as ducks and frogs, which results in the retention of skin and membranes between the toes, as an adaptation for aquatic movement.': $i).
% 29.32/29.17  tff(decl_80147, type, 'webbed foot development': $i).
% 29.32/29.17  tff(decl_80148, type, 'webbed-foot-development': $i).
% 29.32/29.17  tff(decl_80149, type, fn_webbed_foot_development_1: $i > $i).
% 29.32/29.17  tff(decl_80150, type, fn_webbed_foot_development_2: $i > $i).
% 29.32/29.17  tff(decl_80151, type, fn_webbed_foot_development_3: $i > $i).
% 29.32/29.17  tff(decl_80152, type, fn_webbed_foot_development_4: $i > $i).
% 29.32/29.17  tff(decl_80153, type, fn_webbed_foot_development_8: $i > $i).
% 29.32/29.17  tff(decl_80154, type, fn_webbed_foot_development_9: $i > $i).
% 29.32/29.17  tff(decl_80155, type, fn_webbed_foot_development_10: $i > $i).
% 29.32/29.17  tff(decl_80156, type, fn_webbed_foot_development_11: $i > $i).
% 29.32/29.17  tff(decl_80157, type, fn_webbed_foot_development_12: $i > $i).
% 29.32/29.17  tff(decl_80158, type, fn_webbed_foot_development_13: $i > $i).
% 29.32/29.17  tff(decl_80159, type, fn_webbed_foot_development_14: $i > $i).
% 29.32/29.17  tff(decl_80160, type, fn_webbed_foot_development_15: $i > $i).
% 29.32/29.17  tff(decl_80161, type, fn_webbed_foot_development_16: $i > $i).
% 29.32/29.17  tff(decl_80162, type, fn_webbed_foot_development_17: $i > $i).
% 29.32/29.17  tff(decl_80163, type, fn_webbed_foot_development_18: $i > $i).
% 29.32/29.17  tff(decl_80164, type, fn_webbed_foot_development_19: $i > $i).
% 29.32/29.17  tff(decl_80165, type, fn_webbed_foot_development_20: $i > $i).
% 29.32/29.17  tff(decl_80166, type, fn_webbed_foot_development_21: $i > $i).
% 29.32/29.17  tff(decl_80167, type, fn_webbed_foot_development_22: $i > $i).
% 29.32/29.17  tff(decl_80168, type, fn_webbed_foot_development_23: $i > $i).
% 29.32/29.17  tff(decl_80169, type, fn_webbed_foot_development_24: $i > $i).
% 29.32/29.17  tff(decl_80170, type, fn_webbed_foot_development_25: $i > $i).
% 29.32/29.17  tff(decl_80171, type, fn_webbed_foot_development_26: $i > $i).
% 29.32/29.17  tff(decl_80172, type, fn_webbed_foot_development_27: $i > $i).
% 29.32/29.17  tff(decl_80173, type, fn_webbed_foot_development_28: $i > $i).
% 29.32/29.17  tff(decl_80174, type, fn_webbed_foot_development_7: $i > $i).
% 29.32/29.17  tff(decl_80175, type, fn_webbed_foot_development_6: $i > $i).
% 29.32/29.17  tff(decl_80176, type, fn_webbed_foot_development_5: $i > $i).
% 29.32/29.17  tff(decl_80177, type, 'Webbed-Toe': $i).
% 29.32/29.17  tff(decl_80178, type, 'Webbed toes is the common name for syndactyly affecting the feet. It is characterised by the fusion of two or more digits of the feet.': $i).
% 29.32/29.17  tff(decl_80179, type, 'webbed toe': $i).
% 29.32/29.17  tff(decl_80180, type, 'webbed-toe': $i).
% 29.32/29.17  tff(decl_80181, type, 'Wet': $i).
% 29.32/29.17  tff(decl_80182, type, wet: $i).
% 29.32/29.17  tff(decl_80183, type, wetland_1: $i > $o).
% 29.32/29.17  tff(decl_80184, type, 'Wetland': $i).
% 29.32/29.17  tff(decl_80185, type, bog: $i).
% 29.32/29.17  tff(decl_80186, type, marsh: $i).
% 29.32/29.17  tff(decl_80187, type, wetland: $i).
% 29.32/29.17  tff(decl_80188, type, 'Wetness-Constant': $i).
% 29.32/29.17  tff(decl_80189, type, 'constant of wetness': $i).
% 29.32/29.17  tff(decl_80190, type, 'wetness constant': $i).
% 29.32/29.17  tff(decl_80191, type, 'wetness-constant': $i).
% 29.32/29.17  tff(decl_80192, type, wetness_scale_1: $i > $o).
% 29.32/29.17  tff(decl_80193, type, 'Wetness-Scale': $i).
% 29.32/29.17  tff(decl_80194, type, 'scale of wetness': $i).
% 29.32/29.17  tff(decl_80195, type, 'wetness scale': $i).
% 29.32/29.17  tff(decl_80196, type, 'wetness-scale': $i).
% 29.32/29.17  tff(decl_80197, type, 'Wetness-Value': $i).
% 29.32/29.17  tff(decl_80198, type, 'the condition of containing or being covered by a liquid': $i).
% 29.32/29.17  tff(decl_80199, type, wetness: $i).
% 29.32/29.17  tff(decl_80200, type, 'value of wetness': $i).
% 29.32/29.17  tff(decl_80201, type, 'wetness value': $i).
% 29.32/29.17  tff(decl_80202, type, 'wetness-value': $i).
% 29.32/29.17  tff(decl_80203, type, whale_1: $i > $o).
% 29.32/29.17  tff(decl_80204, type, 'Whale': $i).
% 29.32/29.17  tff(decl_80205, type, 'Common name for members of the order Cetacea . Features of whales include a hairless streamlined body, flippers, and nostrils located on top of the head.': $i).
% 29.32/29.17  tff(decl_80206, type, whale: $i).
% 29.32/29.17  tff(decl_80207, type, 'Wheat-Plant': $i).
% 29.32/29.17  tff(decl_80208, type, 'Wheat is a cereal grass of the genus Triticum (family Poaceae) and its edible grain, one of the oldest and most important of the cereal crops.': $i).
% 29.32/29.17  tff(decl_80209, type, wheat: $i).
% 29.32/29.17  tff(decl_80210, type, 'plant of wheat': $i).
% 29.32/29.17  tff(decl_80211, type, 'wheat plant': $i).
% 29.32/29.17  tff(decl_80212, type, 'wheat-plant': $i).
% 29.32/29.17  tff(decl_80213, type, fn_wheat_plant_1: $i > $i).
% 29.32/29.17  tff(decl_80214, type, fn_wheat_plant_2: $i > $i).
% 29.32/29.17  tff(decl_80215, type, fn_wheat_plant_3: $i > $i).
% 29.32/29.17  tff(decl_80216, type, fn_wheat_plant_4: $i > $i).
% 29.32/29.17  tff(decl_80217, type, fn_wheat_plant_5: $i > $i).
% 29.32/29.17  tff(decl_80218, type, fn_wheat_plant_6: $i > $i).
% 29.32/29.17  tff(decl_80219, type, fn_wheat_plant_7: $i > $i).
% 29.32/29.17  tff(decl_80220, type, fn_wheat_plant_8: $i > $i).
% 29.32/29.17  tff(decl_80221, type, fn_wheat_plant_9: $i > $i).
% 29.32/29.17  tff(decl_80222, type, fn_wheat_plant_10: $i > $i).
% 29.32/29.17  tff(decl_80223, type, fn_wheat_plant_11: $i > $i).
% 29.32/29.17  tff(decl_80224, type, fn_wheat_plant_12: $i > $i).
% 29.32/29.17  tff(decl_80225, type, fn_wheat_plant_13: $i > $i).
% 29.32/29.17  tff(decl_80226, type, fn_wheat_plant_14: $i > $i).
% 29.32/29.17  tff(decl_80227, type, fn_wheat_plant_16: $i > $i).
% 29.32/29.17  tff(decl_80228, type, fn_wheat_plant_17: $i > $i).
% 29.32/29.17  tff(decl_80229, type, fn_wheat_plant_18: $i > $i).
% 29.32/29.17  tff(decl_80230, type, fn_wheat_plant_19: $i > $i).
% 29.32/29.17  tff(decl_80231, type, fn_wheat_plant_20: $i > $i).
% 29.32/29.17  tff(decl_80232, type, fn_wheat_plant_21: $i > $i).
% 29.32/29.17  tff(decl_80233, type, fn_wheat_plant_22: $i > $i).
% 29.32/29.17  tff(decl_80234, type, fn_wheat_plant_23: $i > $i).
% 29.32/29.17  tff(decl_80235, type, fn_wheat_plant_24: $i > $i).
% 29.32/29.17  tff(decl_80236, type, fn_wheat_plant_25: $i > $i).
% 29.32/29.17  tff(decl_80237, type, fn_wheat_plant_26: $i > $i).
% 29.32/29.17  tff(decl_80238, type, fn_wheat_plant_27: $i > $i).
% 29.32/29.17  tff(decl_80239, type, fn_wheat_plant_28: $i > $i).
% 29.32/29.17  tff(decl_80240, type, fn_wheat_plant_29: $i > $i).
% 29.32/29.17  tff(decl_80241, type, fn_wheat_plant_30: $i > $i).
% 29.32/29.17  tff(decl_80242, type, fn_wheat_plant_31: $i > $i).
% 29.32/29.17  tff(decl_80243, type, fn_wheat_plant_32: $i > $i).
% 29.32/29.17  tff(decl_80244, type, fn_wheat_plant_33: $i > $i).
% 29.32/29.17  tff(decl_80245, type, fn_wheat_plant_34: $i > $i).
% 29.32/29.17  tff(decl_80246, type, fn_wheat_plant_35: $i > $i).
% 29.32/29.17  tff(decl_80247, type, fn_wheat_plant_36: $i > $i).
% 29.32/29.17  tff(decl_80248, type, fn_wheat_plant_37: $i > $i).
% 29.32/29.17  tff(decl_80249, type, fn_wheat_plant_38: $i > $i).
% 29.32/29.17  tff(decl_80250, type, fn_wheat_plant_39: $i > $i).
% 29.32/29.17  tff(decl_80251, type, fn_wheat_plant_40: $i > $i).
% 29.32/29.17  tff(decl_80252, type, fn_wheat_plant_41: $i > $i).
% 29.32/29.17  tff(decl_80253, type, fn_wheat_plant_42: $i > $i).
% 29.32/29.17  tff(decl_80254, type, fn_wheat_plant_43: $i > $i).
% 29.32/29.17  tff(decl_80255, type, fn_wheat_plant_44: $i > $i).
% 29.32/29.17  tff(decl_80256, type, fn_wheat_plant_45: $i > $i).
% 29.32/29.17  tff(decl_80257, type, fn_wheat_plant_46: $i > $i).
% 29.32/29.17  tff(decl_80258, type, fn_wheat_plant_47: $i > $i).
% 29.32/29.17  tff(decl_80259, type, fn_wheat_plant_48: $i > $i).
% 29.32/29.17  tff(decl_80260, type, fn_wheat_plant_49: $i > $i).
% 29.32/29.17  tff(decl_80261, type, fn_wheat_plant_50: $i > $i).
% 29.32/29.17  tff(decl_80262, type, fn_wheat_plant_51: $i > $i).
% 29.32/29.17  tff(decl_80263, type, fn_wheat_plant_52: $i > $i).
% 29.32/29.17  tff(decl_80264, type, fn_wheat_plant_53: $i > $i).
% 29.32/29.17  tff(decl_80265, type, fn_wheat_plant_54: $i > $i).
% 29.32/29.17  tff(decl_80266, type, fn_wheat_plant_55: $i > $i).
% 29.32/29.17  tff(decl_80267, type, fn_wheat_plant_56: $i > $i).
% 29.32/29.17  tff(decl_80268, type, fn_wheat_plant_57: $i > $i).
% 29.32/29.17  tff(decl_80269, type, fn_wheat_plant_58: $i > $i).
% 29.32/29.17  tff(decl_80270, type, fn_wheat_plant_59: $i > $i).
% 29.32/29.17  tff(decl_80271, type, fn_wheat_plant_60: $i > $i).
% 29.32/29.17  tff(decl_80272, type, fn_wheat_plant_61: $i > $i).
% 29.32/29.17  tff(decl_80273, type, fn_wheat_plant_62: $i > $i).
% 29.32/29.17  tff(decl_80274, type, fn_wheat_plant_63: $i > $i).
% 29.32/29.17  tff(decl_80275, type, fn_wheat_plant_64: $i > $i).
% 29.32/29.17  tff(decl_80276, type, fn_wheat_plant_65: $i > $i).
% 29.32/29.17  tff(decl_80277, type, fn_wheat_plant_66: $i > $i).
% 29.32/29.17  tff(decl_80278, type, fn_wheat_plant_67: $i > $i).
% 29.32/29.17  tff(decl_80279, type, fn_wheat_plant_68: $i > $i).
% 29.32/29.17  tff(decl_80280, type, fn_wheat_plant_69: $i > $i).
% 29.32/29.17  tff(decl_80281, type, fn_wheat_plant_70: $i > $i).
% 29.32/29.17  tff(decl_80282, type, fn_wheat_plant_71: $i > $i).
% 29.32/29.17  tff(decl_80283, type, fn_wheat_plant_72: $i > $i).
% 29.32/29.17  tff(decl_80284, type, fn_wheat_plant_73: $i > $i).
% 29.32/29.17  tff(decl_80285, type, fn_wheat_plant_74: $i > $i).
% 29.32/29.17  tff(decl_80286, type, fn_wheat_plant_75: $i > $i).
% 29.32/29.17  tff(decl_80287, type, fn_wheat_plant_81: $i > $i).
% 29.32/29.17  tff(decl_80288, type, fn_wheat_plant_78: $i > $i).
% 29.32/29.17  tff(decl_80289, type, fn_wheat_plant_79: $i > $i).
% 29.32/29.17  tff(decl_80290, type, fn_c3_plant_7: $i > $i).
% 29.32/29.17  tff(decl_80291, type, fn_wheat_plant_80: $i > $i).
% 29.32/29.17  tff(decl_80292, type, fn_wheat_plant_76: $i > $i).
% 29.32/29.17  tff(decl_80293, type, fn_c3_plant_6: $i > $i).
% 29.32/29.17  tff(decl_80294, type, fn_wheat_plant_77: $i > $i).
% 29.32/29.17  tff(decl_80295, type, fn_wheat_plant_15: $i > $i).
% 29.32/29.17  tff(decl_80296, type, fn_c3_plant_10: $i > $i).
% 29.32/29.17  tff(decl_80297, type, 'White': $i).
% 29.32/29.17  tff(decl_80298, type, 'The color that reflects all wavelengths of visible light; being without color; the opposite of black.': $i).
% 29.32/29.17  tff(decl_80299, type, white: $i).
% 29.32/29.17  tff(decl_80300, type, 'White-Matter': $i).
% 29.32/29.17  tff(decl_80301, type, 'Central nervous system tissue consisting mostly of glial cells and myelinated axons.': $i).
% 29.32/29.17  tff(decl_80302, type, 'matter of white': $i).
% 29.32/29.17  tff(decl_80303, type, 'white matter': $i).
% 29.32/29.17  tff(decl_80304, type, 'white-matter': $i).
% 29.32/29.17  tff(decl_80305, type, 'Whorl': $i).
% 29.32/29.17  tff(decl_80306, type, 'A whorl is an arrangement of sepals, petals, leaves, or branches in which all the parts are attached at the same point and surround or wrap around the stem.': $i).
% 29.32/29.17  tff(decl_80307, type, whorl: $i).
% 29.32/29.17  tff(decl_80308, type, 'Width-Constant': $i).
% 29.32/29.17  tff(decl_80309, type, 'constant of width': $i).
% 29.32/29.17  tff(decl_80310, type, 'width constant': $i).
% 29.32/29.17  tff(decl_80311, type, 'width-constant': $i).
% 29.32/29.17  tff(decl_80312, type, width_scale_1: $i > $o).
% 29.32/29.17  tff(decl_80313, type, 'Width-Scale': $i).
% 29.32/29.17  tff(decl_80314, type, 'scale of width': $i).
% 29.32/29.17  tff(decl_80315, type, 'width scale': $i).
% 29.32/29.17  tff(decl_80316, type, 'width-scale': $i).
% 29.32/29.17  tff(decl_80317, type, 'Wild-Type': $i).
% 29.32/29.17  tff(decl_80318, type, 'An individual with the normal phenotype.': $i).
% 29.32/29.17  tff(decl_80319, type, 'wild phenotype': $i).
% 29.32/29.17  tff(decl_80320, type, 'normal phenotype': $i).
% 29.32/29.17  tff(decl_80321, type, 'type of wild': $i).
% 29.32/29.17  tff(decl_80322, type, 'wild type': $i).
% 29.32/29.17  tff(decl_80323, type, 'wild-type': $i).
% 29.32/29.17  tff(decl_80324, type, wilting_1: $i > $o).
% 29.32/29.17  tff(decl_80325, type, 'Wilting': $i).
% 29.32/29.17  tff(decl_80326, type, 'Wilting refers to the loss of rigidity of non-woody parts of plants.': $i).
% 29.32/29.17  tff(decl_80327, type, wilt: $i).
% 29.32/29.17  tff(decl_80328, type, wilting: $i).
% 29.32/29.17  tff(decl_80329, type, fn_wilting_1: $i > $i).
% 29.32/29.17  tff(decl_80330, type, fn_wilting_2: $i > $i).
% 29.32/29.17  tff(decl_80331, type, fn_wilting_3: $i > $i).
% 29.32/29.17  tff(decl_80332, type, fn_wilting_4: $i > $i).
% 29.32/29.17  tff(decl_80333, type, fn_wilting_5: $i > $i).
% 29.32/29.17  tff(decl_80334, type, fn_wilting_6: $i > $i).
% 29.32/29.17  tff(decl_80335, type, fn_wilting_7: $i > $i).
% 29.32/29.17  tff(decl_80336, type, fn_wilting_9: $i > $i).
% 29.32/29.17  tff(decl_80337, type, fn_wilting_10: $i > $i).
% 29.32/29.17  tff(decl_80338, type, fn_wilting_11: $i > $i).
% 29.32/29.17  tff(decl_80339, type, fn_wilting_12: $i > $i).
% 29.32/29.17  tff(decl_80340, type, fn_wilting_13: $i > $i).
% 29.32/29.17  tff(decl_80341, type, fn_wilting_14: $i > $i).
% 29.32/29.17  tff(decl_80342, type, fn_wilting_8: $i > $i).
% 29.32/29.17  tff(decl_80343, type, wind_1: $i > $o).
% 29.32/29.17  tff(decl_80344, type, 'Wind': $i).
% 29.32/29.17  tff(decl_80345, type, 'Atmospheric currents.': $i).
% 29.32/29.17  tff(decl_80346, type, breeze: $i).
% 29.32/29.17  tff(decl_80347, type, wine_1: $i > $o).
% 29.32/29.17  tff(decl_80348, type, 'Wine': $i).
% 29.32/29.17  tff(decl_80349, type, 'Wine is an alcoholic beverage, typically made of fermented grape juice.': $i).
% 29.32/29.17  tff(decl_80350, type, wine: $i).
% 29.32/29.17  tff(decl_80351, type, fn_wine_1: $i > $i).
% 29.32/29.17  tff(decl_80352, type, fn_wine_2: $i > $i).
% 29.32/29.17  tff(decl_80353, type, fn_wine_3: $i > $i).
% 29.32/29.17  tff(decl_80354, type, fn_wine_4: $i > $i).
% 29.32/29.17  tff(decl_80355, type, fn_wine_5: $i > $i).
% 29.32/29.17  tff(decl_80356, type, wing_1: $i > $o).
% 29.32/29.17  tff(decl_80357, type, 'Wing': $i).
% 29.32/29.17  tff(decl_80358, type, 'In birds, the forelimb, which is modified for flying. In insects, an outgrowth of the exoskeleton that allows flight.': $i).
% 29.32/29.17  tff(decl_80359, type, wing: $i).
% 29.32/29.17  tff(decl_80360, type, 'Winner': $i).
% 29.32/29.17  tff(decl_80361, type, winner: $i).
% 29.32/29.17  tff(decl_80362, type, victor: $i).
% 29.32/29.17  tff(decl_80363, type, 'Withdraw': $i).
% 29.32/29.17  tff(decl_80364, type, withdraw: $i).
% 29.32/29.17  tff(decl_80365, type, draw: $i).
% 29.32/29.17  tff(decl_80366, type, 'take out': $i).
% 29.32/29.17  tff(decl_80367, type, take_out: $i).
% 29.32/29.17  tff(decl_80368, type, unpack: $i).
% 29.32/29.17  tff(decl_80369, type, wobble_hypothesis_1: $i > $o).
% 29.32/29.17  tff(decl_80370, type, 'Wobble-Hypothesis': $i).
% 29.32/29.17  tff(decl_80371, type, 'Flexibility in the base-pairing rules in which the nucleotide at the 5\\end of a tRNA anticodon can form hydrogen bonds with more than one kind of base in the third position (3\\end) of a codon.': $i).
% 29.32/29.17  tff(decl_80372, type, 'hypothesis of wobble': $i).
% 29.32/29.17  tff(decl_80373, type, 'wobble hypothesis': $i).
% 29.32/29.17  tff(decl_80374, type, 'wobble-hypothesis': $i).
% 29.32/29.17  tff(decl_80375, type, fn_wobble_hypothesis_1: $i > $i).
% 29.32/29.17  tff(decl_80376, type, 'Wood': $i).
% 29.32/29.17  tff(decl_80377, type, wood: $i).
% 29.32/29.17  tff(decl_80378, type, fn_wood_1: $i > $i).
% 29.32/29.17  tff(decl_80379, type, 'Woody-Plant': $i).
% 29.32/29.17  tff(decl_80380, type, 'Vascular plant with growth such that it develops wood, or dead internal tissues.': $i).
% 29.32/29.17  tff(decl_80381, type, 'woody plant': $i).
% 29.32/29.17  tff(decl_80382, type, 'woody-plant': $i).
% 29.32/29.17  tff(decl_80383, type, fn_woody_plant_1: $i > $i).
% 29.32/29.17  tff(decl_80384, type, fn_woody_plant_2: $i > $i).
% 29.32/29.17  tff(decl_80385, type, fn_woody_plant_14: $i > $i).
% 29.32/29.17  tff(decl_80386, type, fn_woody_plant_13: $i > $i).
% 29.32/29.17  tff(decl_80387, type, 'Work': $i).
% 29.32/29.17  tff(decl_80388, type, 'Work is the amount of energy transferred by a force': $i).
% 29.32/29.17  tff(decl_80389, type, 'Workgroup': $i).
% 29.32/29.17  tff(decl_80390, type, workgroup: $i).
% 29.32/29.17  tff(decl_80391, type, 'Worth-Constant': $i).
% 29.32/29.17  tff(decl_80392, type, 'constant of worth': $i).
% 29.32/29.17  tff(decl_80393, type, 'worth constant': $i).
% 29.32/29.17  tff(decl_80394, type, 'worth-constant': $i).
% 29.32/29.17  tff(decl_80395, type, worth_scale_1: $i > $o).
% 29.32/29.17  tff(decl_80396, type, 'Worth-Scale': $i).
% 29.32/29.17  tff(decl_80397, type, 'scale of worth': $i).
% 29.32/29.17  tff(decl_80398, type, 'worth scale': $i).
% 29.32/29.17  tff(decl_80399, type, 'worth-scale': $i).
% 29.32/29.17  tff(decl_80400, type, 'Worth-Value': $i).
% 29.32/29.17  tff(decl_80401, type, 'an indefinite quantity of something having a specified value': $i).
% 29.32/29.17  tff(decl_80402, type, worth: $i).
% 29.32/29.17  tff(decl_80403, type, 'value of worth': $i).
% 29.32/29.17  tff(decl_80404, type, 'worth value': $i).
% 29.32/29.17  tff(decl_80405, type, 'worth-value': $i).
% 29.32/29.17  tff(decl_80406, type, wound_repair_1: $i > $o).
% 29.32/29.17  tff(decl_80407, type, 'Wound-Repair': $i).
% 29.32/29.17  tff(decl_80408, type, 'Process in which tears or abrasions of tissues are sealed and repaired.': $i).
% 29.32/29.17  tff(decl_80409, type, 'repair of wound': $i).
% 29.32/29.17  tff(decl_80410, type, 'wound repair': $i).
% 29.32/29.17  tff(decl_80411, type, 'wound-repair': $i).
% 29.32/29.17  tff(decl_80412, type, fn_wound_repair_1: $i > $i).
% 29.32/29.17  tff(decl_80413, type, fn_wound_repair_2: $i > $i).
% 29.32/29.17  tff(decl_80414, type, fn_wound_repair_3: $i > $i).
% 29.32/29.17  tff(decl_80415, type, fn_wound_repair_4: $i > $i).
% 29.32/29.17  tff(decl_80416, type, fn_wound_repair_5: $i > $i).
% 29.32/29.17  tff(decl_80417, type, fn_wound_repair_6: $i > $i).
% 29.32/29.17  tff(decl_80418, type, fn_wound_repair_7: $i > $i).
% 29.32/29.17  tff(decl_80419, type, fn_wound_repair_8: $i > $i).
% 29.32/29.17  tff(decl_80420, type, wound_repair_in_liver_1: $i > $o).
% 29.32/29.17  tff(decl_80421, type, 'Wound-Repair-In-Liver': $i).
% 29.32/29.17  tff(decl_80422, type, 'Process in which tears or abrasions of liver tissues are sealed and repaired.': $i).
% 29.32/29.17  tff(decl_80423, type, 'wound repair in liver': $i).
% 29.32/29.17  tff(decl_80424, type, 'wound-repair-in-liver': $i).
% 29.32/29.17  tff(decl_80425, type, fn_wound_repair_in_liver_1: $i > $i).
% 29.32/29.17  tff(decl_80426, type, fn_wound_repair_in_liver_2: $i > $i).
% 29.32/29.17  tff(decl_80427, type, fn_wound_repair_in_liver_3: $i > $i).
% 29.32/29.17  tff(decl_80428, type, fn_wound_repair_in_liver_4: $i > $i).
% 29.32/29.17  tff(decl_80429, type, fn_wound_repair_in_liver_5: $i > $i).
% 29.32/29.17  tff(decl_80430, type, fn_wound_repair_in_liver_6: $i > $i).
% 29.32/29.17  tff(decl_80431, type, fn_wound_repair_in_liver_7: $i > $i).
% 29.32/29.17  tff(decl_80432, type, fn_wound_repair_in_liver_8: $i > $i).
% 29.32/29.17  tff(decl_80433, type, fn_wound_repair_in_liver_9: $i > $i).
% 29.32/29.17  tff(decl_80434, type, fn_wound_repair_in_liver_10: $i > $i).
% 29.32/29.17  tff(decl_80435, type, fn_wound_repair_in_liver_11: $i > $i).
% 29.32/29.17  tff(decl_80436, type, fn_wound_repair_in_liver_12: $i > $i).
% 29.32/29.17  tff(decl_80437, type, fn_wound_repair_in_liver_13: $i > $i).
% 29.32/29.17  tff(decl_80438, type, fn_wound_repair_in_liver_14: $i > $i).
% 29.32/29.17  tff(decl_80439, type, fn_wound_repair_in_liver_15: $i > $i).
% 29.32/29.17  tff(decl_80440, type, fn_wound_repair_in_liver_16: $i > $i).
% 29.32/29.17  tff(decl_80441, type, fn_wound_repair_in_liver_17: $i > $i).
% 29.32/29.17  tff(decl_80442, type, liver_cell_0: $i).
% 29.32/29.17  tff(decl_80443, type, 'Write': $i).
% 29.32/29.17  tff(decl_80444, type, compose: $i).
% 29.32/29.17  tff(decl_80445, type, pen: $i).
% 29.32/29.17  tff(decl_80446, type, indite: $i).
% 29.32/29.17  tff(decl_80447, type, fn_write_1: $i > $i).
% 29.32/29.17  tff(decl_80448, type, 'X-Chromosome': $i).
% 29.32/29.17  tff(decl_80449, type, 'The X chromosome is one of the two sex-determining chromosomes in many animal species, including mammals (the other is the Y chromosome). It is a part of the XY sex-determination system and X0 sex-determination system.': $i).
% 29.32/29.17  tff(decl_80450, type, 'x chromosomes': $i).
% 29.32/29.17  tff(decl_80451, type, 'x-chromosomes': $i).
% 29.32/29.17  tff(decl_80452, type, 'chromosome of x': $i).
% 29.32/29.17  tff(decl_80453, type, 'x chromosome': $i).
% 29.32/29.17  tff(decl_80454, type, 'x-chromosome': $i).
% 29.32/29.17  tff(decl_80455, type, 'X-Chromosome-Dominant': $i).
% 29.32/29.17  tff(decl_80456, type, 'An X chromosome that carries a dominant allele for a specified gene.': $i).
% 29.32/29.17  tff(decl_80457, type, 'x chromosome dominant': $i).
% 29.32/29.17  tff(decl_80458, type, 'x-chromosome-dominant': $i).
% 29.32/29.17  tff(decl_80459, type, 'X-Chromosome-Phenotype-Dominant': $i).
% 29.32/29.17  tff(decl_80460, type, 'The phenotype of a female who has one or two dominant alleles for an X chromosome gene or of a male who has the dominant allele for an X chromosome gene.': $i).
% 29.32/29.17  tff(decl_80461, type, 'x chromosome phenotype dominant': $i).
% 29.32/29.17  tff(decl_80462, type, 'x-chromosome-phenotype-dominant': $i).
% 29.32/29.17  tff(decl_80463, type, fn_x_chromosome_phenotype_dominant_1: $i > $i).
% 29.32/29.17  tff(decl_80464, type, fn_x_chromosome_phenotype_dominant_2: $i > $i).
% 29.32/29.17  tff(decl_80465, type, fn_x_chromosome_phenotype_dominant_3: $i > $i).
% 29.32/29.17  tff(decl_80466, type, fn_x_chromosome_phenotype_dominant_4: $i > $i).
% 29.32/29.17  tff(decl_80467, type, 'X-Chromosome-Phenotype-Recessive': $i).
% 29.32/29.17  tff(decl_80468, type, 'The phenotype of a female who has two recessive alleles for an X chromosome gene or of a male who has the recessive allele for an X chromosome gene.': $i).
% 29.32/29.17  tff(decl_80469, type, 'x chromosome phenotype recessive': $i).
% 29.32/29.17  tff(decl_80470, type, 'x-chromosome-phenotype-recessive': $i).
% 29.32/29.17  tff(decl_80471, type, fn_x_chromosome_phenotype_recessive_1: $i > $i).
% 29.32/29.17  tff(decl_80472, type, fn_x_chromosome_phenotype_recessive_2: $i > $i).
% 29.32/29.17  tff(decl_80473, type, fn_x_chromosome_phenotype_recessive_3: $i > $i).
% 29.32/29.17  tff(decl_80474, type, fn_x_chromosome_phenotype_recessive_4: $i > $i).
% 29.32/29.17  tff(decl_80475, type, 'X-Chromosome-Recessive': $i).
% 29.32/29.17  tff(decl_80476, type, 'An X chromosome that carries a recessive allele for a specified gene.': $i).
% 29.32/29.17  tff(decl_80477, type, 'x chromosome recessive': $i).
% 29.32/29.17  tff(decl_80478, type, 'x-chromosome-recessive': $i).
% 29.32/29.17  tff(decl_80479, type, 'X-Dominant-And-Y': $i).
% 29.32/29.17  tff(decl_80480, type, 'The genotype of a male somatic cell containing a dominant allele for a specific gene on the X chromosome.': $i).
% 29.32/29.17  tff(decl_80481, type, 'x dominant and y': $i).
% 29.32/29.17  tff(decl_80482, type, 'x-dominant-and-y': $i).
% 29.32/29.17  tff(decl_80483, type, fn_x_dominant_and_y_1: $i > $i).
% 29.32/29.17  tff(decl_80484, type, 'X-Linked-Inheritance': $i).
% 29.32/29.17  tff(decl_80485, type, 'Inheritance of characteristics that are determined by genes carried on the X chromosome(s).': $i).
% 29.32/29.17  tff(decl_80486, type, 'x linked inheritance': $i).
% 29.32/29.17  tff(decl_80487, type, 'x-linked-inheritance': $i).
% 29.32/29.17  tff(decl_80488, type, fn_x_linked_inheritance_1: $i > $i).
% 29.32/29.17  tff(decl_80489, type, x_linked_inheritance_from_dominant_male_parent_1: $i > $o).
% 29.32/29.17  tff(decl_80490, type, 'X-Linked-Inheritance-From-Dominant-Male-Parent': $i).
% 29.32/29.17  tff(decl_80491, type, 'A form of X chromosome linked inheritance whereby the male parent is dominant for the inherited trait.': $i).
% 29.32/29.17  tff(decl_80492, type, 'x linked inheritance from dominant male parent': $i).
% 29.32/29.17  tff(decl_80493, type, 'x-linked-inheritance-from-dominant-male-parent': $i).
% 29.32/29.17  tff(decl_80494, type, x_linked_inheritance_from_male_parent_1: $i > $o).
% 29.32/29.17  tff(decl_80495, type, x_linked_inheritance_from_recessive_male_parent_1: $i > $o).
% 29.32/29.17  tff(decl_80496, type, fn_x_linked_inheritance_from_dominant_male_parent_1: $i > $i).
% 29.32/29.17  tff(decl_80497, type, x_linked_inheritance_from_heterozygous_female_parent_1: $i > $o).
% 29.32/29.17  tff(decl_80498, type, 'X-Linked-Inheritance-From-Heterozygous-Female-Parent': $i).
% 29.32/29.17  tff(decl_80499, type, 'Inheritance of characteristics that are determined by genes carried on the maternal X chromosomes of a female parent who is heterozygous for the defined characteristic.': $i).
% 29.32/29.17  tff(decl_80500, type, 'x linked inheritance from heterozygous female parent': $i).
% 29.32/29.17  tff(decl_80501, type, 'x-linked-inheritance-from-heterozygous-female-parent': $i).
% 29.32/29.17  tff(decl_80502, type, x_linked_inheritance_from_homozygous_female_parent_1: $i > $o).
% 29.32/29.17  tff(decl_80503, type, fn_x_linked_inheritance_from_heterozygous_female_parent_1: $i > $i).
% 29.32/29.17  tff(decl_80504, type, fn_x_linked_inheritance_from_heterozygous_female_parent_4: $i > $i).
% 29.32/29.17  tff(decl_80505, type, fn_x_linked_inheritance_from_heterozygous_female_parent_5: $i > $i).
% 29.32/29.17  tff(decl_80506, type, fn_x_linked_inheritance_from_heterozygous_female_parent_6: $i > $i).
% 29.32/29.17  tff(decl_80507, type, fn_x_linked_inheritance_from_heterozygous_female_parent_7: $i > $i).
% 29.32/29.17  tff(decl_80508, type, fn_x_linked_inheritance_from_heterozygous_female_parent_8: $i > $i).
% 29.32/29.17  tff(decl_80509, type, fn_x_linked_inheritance_from_heterozygous_female_parent_9: $i > $i).
% 29.32/29.17  tff(decl_80510, type, fn_x_linked_inheritance_from_heterozygous_female_parent_10: $i > $i).
% 29.32/29.17  tff(decl_80511, type, fn_x_linked_inheritance_from_heterozygous_female_parent_11: $i > $i).
% 29.32/29.17  tff(decl_80512, type, fn_x_linked_inheritance_from_heterozygous_female_parent_12: $i > $i).
% 29.32/29.17  tff(decl_80513, type, fn_x_linked_inheritance_from_heterozygous_female_parent_13: $i > $i).
% 29.32/29.17  tff(decl_80514, type, fn_x_linked_inheritance_from_heterozygous_female_parent_14: $i > $i).
% 29.32/29.17  tff(decl_80515, type, fn_x_linked_inheritance_from_heterozygous_female_parent_15: $i > $i).
% 29.32/29.17  tff(decl_80516, type, fn_x_linked_inheritance_from_heterozygous_female_parent_16: $i > $i).
% 29.32/29.17  tff(decl_80517, type, x_linked_inheritance_from_homozygous_dominant_female_parent_1: $i > $o).
% 29.32/29.17  tff(decl_80518, type, 'X-Linked-Inheritance-From-Homozygous-Dominant-Female-Parent': $i).
% 29.32/29.17  tff(decl_80519, type, 'A form of X chromosome linked inheritance whereby the female parent is homozygous dominant for the inherited trait.': $i).
% 29.32/29.17  tff(decl_80520, type, 'x linked inheritance from homozygous dominant female parent': $i).
% 29.32/29.17  tff(decl_80521, type, 'x-linked-inheritance-from-homozygous-dominant-female-parent': $i).
% 29.32/29.17  tff(decl_80522, type, x_linked_inheritance_from_homozygous_recessive_female_parent_1: $i > $o).
% 29.32/29.17  tff(decl_80523, type, fn_x_linked_inheritance_from_homozygous_dominant_female_parent_1: $i > $i).
% 29.32/29.17  tff(decl_80524, type, 'X-Linked-Inheritance-From-Homozygous-Female-Parent': $i).
% 29.32/29.17  tff(decl_80525, type, 'Inheritance of characteristics that are determined by genes carried on the maternal X chromosomes of a female parent who is homozygous for the defined characteristic.': $i).
% 29.32/29.17  tff(decl_80526, type, 'x linked inheritance from homozygous female parent': $i).
% 29.32/29.17  tff(decl_80527, type, 'x-linked-inheritance-from-homozygous-female-parent': $i).
% 29.32/29.17  tff(decl_80528, type, fn_x_linked_inheritance_from_homozygous_female_parent_4: $i > $i).
% 29.32/29.17  tff(decl_80529, type, fn_x_linked_inheritance_from_homozygous_female_parent_5: $i > $i).
% 29.32/29.17  tff(decl_80530, type, fn_x_linked_inheritance_from_homozygous_female_parent_6: $i > $i).
% 29.32/29.17  tff(decl_80531, type, fn_x_linked_inheritance_from_homozygous_female_parent_7: $i > $i).
% 29.32/29.17  tff(decl_80532, type, fn_x_linked_inheritance_from_homozygous_female_parent_8: $i > $i).
% 29.32/29.17  tff(decl_80533, type, fn_x_linked_inheritance_from_homozygous_female_parent_9: $i > $i).
% 29.32/29.17  tff(decl_80534, type, fn_x_linked_inheritance_from_homozygous_female_parent_10: $i > $i).
% 29.32/29.17  tff(decl_80535, type, fn_x_linked_inheritance_from_homozygous_female_parent_11: $i > $i).
% 29.32/29.17  tff(decl_80536, type, fn_x_linked_inheritance_from_homozygous_female_parent_12: $i > $i).
% 29.32/29.17  tff(decl_80537, type, fn_x_linked_inheritance_from_homozygous_female_parent_13: $i > $i).
% 29.32/29.17  tff(decl_80538, type, fn_x_linked_inheritance_from_homozygous_female_parent_14: $i > $i).
% 29.32/29.17  tff(decl_80539, type, fn_x_linked_inheritance_from_homozygous_female_parent_15: $i > $i).
% 29.32/29.17  tff(decl_80540, type, fn_x_linked_inheritance_from_homozygous_female_parent_16: $i > $i).
% 29.32/29.17  tff(decl_80541, type, 'X-Linked-Inheritance-From-Homozygous-Recessive-Female-Parent': $i).
% 29.32/29.17  tff(decl_80542, type, 'A form of X chromosome linked inheritance whereby the female parent is homozygous recessive for the inherited trait.': $i).
% 29.32/29.17  tff(decl_80543, type, 'x linked inheritance from homozygous recessive female parent': $i).
% 29.32/29.17  tff(decl_80544, type, 'x-linked-inheritance-from-homozygous-recessive-female-parent': $i).
% 29.32/29.17  tff(decl_80545, type, fn_x_linked_inheritance_from_homozygous_recessive_female_parent_1: $i > $i).
% 29.32/29.17  tff(decl_80546, type, fn_x_linked_inheritance_from_homozygous_recessive_female_parent_2: $i > $i).
% 29.32/29.17  tff(decl_80547, type, 'X-Linked-Inheritance-From-Male-Parent': $i).
% 29.32/29.17  tff(decl_80548, type, 'Inheritance of a gene on the male parent\\s X chromosome.': $i).
% 29.32/29.17  tff(decl_80549, type, 'x linked inheritance from male parent': $i).
% 29.32/29.17  tff(decl_80550, type, 'x-linked-inheritance-from-male-parent': $i).
% 29.32/29.17  tff(decl_80551, type, fn_x_linked_inheritance_from_male_parent_2: $i > $i).
% 29.32/29.17  tff(decl_80552, type, fn_x_linked_inheritance_from_male_parent_3: $i > $i).
% 29.32/29.17  tff(decl_80553, type, fn_x_linked_inheritance_from_male_parent_4: $i > $i).
% 29.32/29.17  tff(decl_80554, type, 'X-Linked-Inheritance-From-Recessive-Male-Parent': $i).
% 29.32/29.17  tff(decl_80555, type, 'A form of X chromosome linked inheritance whereby the male parent is recessive for the inherited trait.': $i).
% 29.32/29.17  tff(decl_80556, type, 'x linked inheritance from recessive male parent': $i).
% 29.32/29.17  tff(decl_80557, type, 'x-linked-inheritance-from-recessive-male-parent': $i).
% 29.32/29.17  tff(decl_80558, type, fn_x_linked_inheritance_from_recessive_male_parent_1: $i > $i).
% 29.32/29.17  tff(decl_80559, type, 'X-Ray-Crystallography': $i).
% 29.32/29.17  tff(decl_80560, type, 'A technique used to determine the arrangement of atoms within a crystal.': $i).
% 29.32/29.17  tff(decl_80561, type, 'x ray crystallography': $i).
% 29.32/29.17  tff(decl_80562, type, 'x-ray-crystallography': $i).
% 29.32/29.17  tff(decl_80563, type, fn_x_ray_crystallography_1: $i > $i).
% 29.32/29.17  tff(decl_80564, type, x_ray_diffraction_pattern_1: $i > $o).
% 29.32/29.17  tff(decl_80565, type, fn_x_ray_diffraction_pattern_1: $i > $i).
% 29.32/29.17  tff(decl_80566, type, 'X-Ray-Diffraction-Pattern': $i).
% 29.32/29.17  tff(decl_80567, type, 'Pattern of spots produced by the X-Ray Diffraction technique which reveals details about molecular structure.': $i).
% 29.32/29.17  tff(decl_80568, type, 'x ray diffraction pattern': $i).
% 29.32/29.17  tff(decl_80569, type, 'x-ray-diffraction-pattern': $i).
% 29.32/29.17  tff(decl_80570, type, fn_x_ray_diffraction_pattern_2: $i > $i).
% 29.32/29.17  tff(decl_80571, type, 'X-Rays': $i).
% 29.32/29.17  tff(decl_80572, type, 'X-rays are the electromagnetic radiation with wavelenth ranging from 0.001 nm to 1 nm. Their wavelength is shorter than that of ultraviolet-rays, but longer than gamma-rays': $i).
% 29.32/29.17  tff(decl_80573, type, 'x ray': $i).
% 29.32/29.17  tff(decl_80574, type, 'x-ray': $i).
% 29.32/29.17  tff(decl_80575, type, fn_x_rays_2: $i > $i).
% 29.32/29.17  tff(decl_80576, type, fn_x_rays_3: $i > $i).
% 29.32/29.17  tff(decl_80577, type, fn_x_rays_4: $i > $i).
% 29.32/29.17  tff(decl_80578, type, xenon_1: $i > $o).
% 29.32/29.17  tff(decl_80579, type, 'Xenon': $i).
% 29.32/29.17  tff(decl_80580, type, 'Xenon is a non metal atom with atomic number 54. It is represented by the symbol Xe.': $i).
% 29.32/29.17  tff(decl_80581, type, 'Xe': $i).
% 29.32/29.17  tff(decl_80582, type, xenon: $i).
% 29.32/29.17  tff(decl_80583, type, fn_xenon_4: $i > $i).
% 29.32/29.17  tff(decl_80584, type, fn_xenon_5: $i > $i).
% 29.32/29.17  tff(decl_80585, type, fn_xenon_6: $i > $i).
% 29.32/29.17  tff(decl_80586, type, fn_xenon_7: $i > $i).
% 29.32/29.17  tff(decl_80587, type, fn_xenon_11: $i > $i).
% 29.32/29.17  tff(decl_80588, type, fn_xenon_12: $i > $i).
% 29.32/29.17  tff(decl_80589, type, fn_xenon_13: $i > $i).
% 29.32/29.17  tff(decl_80590, type, fn_xenon_14: $i > $i).
% 29.32/29.17  tff(decl_80591, type, "2.6": $i).
% 29.32/29.17  tff(decl_80592, type, "131.3": $i).
% 29.32/29.17  tff(decl_80593, type, fn_xenon_9: $i > $i).
% 29.32/29.17  tff(decl_80594, type, fn_xenon_8: $i > $i).
% 29.32/29.17  tff(decl_80595, type, fn_xenon_10: $i > $i).
% 29.32/29.17  tff(decl_80596, type, 'Xerophyte': $i).
% 29.32/29.17  tff(decl_80597, type, 'A plant adapted to an arid climate.': $i).
% 29.32/29.17  tff(decl_80598, type, xerophyte: $i).
% 29.32/29.17  tff(decl_80599, type, 'XIST-Gene': $i).
% 29.32/29.17  tff(decl_80600, type, 'A gene that codes for Xist RNA.': $i).
% 29.32/29.17  tff(decl_80601, type, 'x inactive specific transcript': $i).
% 29.32/29.17  tff(decl_80602, type, 'x-inactive-specific-transcript': $i).
% 29.32/29.17  tff(decl_80603, type, 'x inactive specific transcript gene': $i).
% 29.32/29.17  tff(decl_80604, type, 'x-inactive-specific-transcript-gene': $i).
% 29.32/29.17  tff(decl_80605, type, 'xist gene': $i).
% 29.32/29.17  tff(decl_80606, type, 'xist-gene': $i).
% 29.32/29.17  tff(decl_80607, type, 'XIST-RNA': $i).
% 29.32/29.17  tff(decl_80608, type, 'An RNA molecule that plays critical roles in the choice of which X chromosome remains active and which will become a Barr body.': $i).
% 29.32/29.17  tff(decl_80609, type, 'x inactive specific transcript rna': $i).
% 29.32/29.17  tff(decl_80610, type, 'x-inactive-specific-transcript-rna': $i).
% 29.32/29.17  tff(decl_80611, type, 'xist rna': $i).
% 29.32/29.17  tff(decl_80612, type, 'xist-rna': $i).
% 29.32/29.17  tff(decl_80613, type, fn_xist_rna_7: $i > $i).
% 29.32/29.17  tff(decl_80614, type, fn_xist_rna_8: $i > $i).
% 29.32/29.17  tff(decl_80615, type, fn_xist_rna_10: $i > $i).
% 29.32/29.17  tff(decl_80616, type, fn_xist_rna_12: $i > $i).
% 29.32/29.17  tff(decl_80617, type, fn_xist_rna_16: $i > $i).
% 29.32/29.17  tff(decl_80618, type, fn_xist_rna_17: $i > $i).
% 29.32/29.17  tff(decl_80619, type, fn_xist_rna_18: $i > $i).
% 29.32/29.17  tff(decl_80620, type, fn_xist_rna_19: $i > $i).
% 29.32/29.17  tff(decl_80621, type, fn_xist_rna_20: $i > $i).
% 29.32/29.17  tff(decl_80622, type, fn_xist_rna_21: $i > $i).
% 29.32/29.17  tff(decl_80623, type, fn_xist_rna_22: $i > $i).
% 29.32/29.17  tff(decl_80624, type, fn_xist_rna_23: $i > $i).
% 29.32/29.17  tff(decl_80625, type, fn_xist_rna_24: $i > $i).
% 29.32/29.17  tff(decl_80626, type, fn_xist_rna_25: $i > $i).
% 29.32/29.17  tff(decl_80627, type, fn_xist_rna_26: $i > $i).
% 29.32/29.17  tff(decl_80628, type, fn_xist_rna_27: $i > $i).
% 29.32/29.17  tff(decl_80629, type, fn_xist_rna_3: $i > $i).
% 29.32/29.17  tff(decl_80630, type, fn_xist_rna_4: $i > $i).
% 29.32/29.17  tff(decl_80631, type, fn_xist_rna_6: $i > $i).
% 29.32/29.17  tff(decl_80632, type, fn_xist_rna_5: $i > $i).
% 29.32/29.17  tff(decl_80633, type, fn_xist_rna_1: $i > $i).
% 29.32/29.17  tff(decl_80634, type, fn_xist_rna_2: $i > $i).
% 29.32/29.17  tff(decl_80635, type, fn_xist_rna_9: $i > $i).
% 29.32/29.17  tff(decl_80636, type, 'Xylem': $i).
% 29.32/29.17  tff(decl_80637, type, 'The water-conducting tissue found in vascular plants. Xylem consists of tracheids and vessel elements forming tubes that draw water and nutrients from the roots up through the plant.': $i).
% 29.32/29.17  tff(decl_80638, type, 'xylem vessel': $i).
% 29.32/29.17  tff(decl_80639, type, xylem: $i).
% 29.32/29.17  tff(decl_80640, type, fn_xylem_1: $i > $i).
% 29.32/29.17  tff(decl_80641, type, fn_xylem_2: $i > $i).
% 29.32/29.17  tff(decl_80642, type, fn_xylem_3: $i > $i).
% 29.32/29.17  tff(decl_80643, type, fn_xylem_5: $i > $i).
% 29.32/29.17  tff(decl_80644, type, fn_xylem_6: $i > $i).
% 29.32/29.17  tff(decl_80645, type, fn_xylem_8: $i > $i).
% 29.32/29.17  tff(decl_80646, type, fn_xylem_9: $i > $i).
% 29.32/29.17  tff(decl_80647, type, fn_xylem_11: $i > $i).
% 29.32/29.17  tff(decl_80648, type, fn_xylem_14: $i > $i).
% 29.32/29.17  tff(decl_80649, type, fn_xylem_17: $i > $i).
% 29.32/29.17  tff(decl_80650, type, fn_xylem_18: $i > $i).
% 29.32/29.17  tff(decl_80651, type, fn_xylem_19: $i > $i).
% 29.32/29.17  tff(decl_80652, type, fn_xylem_20: $i > $i).
% 29.32/29.17  tff(decl_80653, type, fn_xylem_21: $i > $i).
% 29.32/29.17  tff(decl_80654, type, fn_xylem_22: $i > $i).
% 29.32/29.17  tff(decl_80655, type, fn_xylem_23: $i > $i).
% 29.32/29.17  tff(decl_80656, type, fn_xylem_24: $i > $i).
% 29.32/29.17  tff(decl_80657, type, fn_xylem_25: $i > $i).
% 29.32/29.17  tff(decl_80658, type, fn_xylem_26: $i > $i).
% 29.32/29.17  tff(decl_80659, type, fn_xylem_27: $i > $i).
% 29.32/29.17  tff(decl_80660, type, fn_xylem_28: $i > $i).
% 29.32/29.17  tff(decl_80661, type, fn_xylem_29: $i > $i).
% 29.32/29.17  tff(decl_80662, type, fn_xylem_30: $i > $i).
% 29.32/29.17  tff(decl_80663, type, fn_xylem_31: $i > $i).
% 29.32/29.17  tff(decl_80664, type, fn_xylem_33: $i > $i).
% 29.32/29.17  tff(decl_80665, type, 'Xylem-Sap': $i).
% 29.32/29.17  tff(decl_80666, type, 'The dilute solution of water and dissolved minerals carried through vessels and tracheids.': $i).
% 29.32/29.17  tff(decl_80667, type, 'xylem fluid': $i).
% 29.32/29.17  tff(decl_80668, type, 'xylem-fluid': $i).
% 29.32/29.17  tff(decl_80669, type, 'xylem liquid': $i).
% 29.32/29.17  tff(decl_80670, type, 'xylem-liquid': $i).
% 29.32/29.17  tff(decl_80671, type, 'sap of xylem': $i).
% 29.32/29.17  tff(decl_80672, type, 'xylem sap': $i).
% 29.32/29.17  tff(decl_80673, type, 'xylem-sap': $i).
% 29.32/29.17  tff(decl_80674, type, fn_xylem_sap_3: $i > $i).
% 29.32/29.17  tff(decl_80675, type, fn_xylem_sap_4: $i > $i).
% 29.32/29.17  tff(decl_80676, type, fn_xylem_sap_5: $i > $i).
% 29.32/29.17  tff(decl_80677, type, fn_xylem_sap_16: $i > $i).
% 29.32/29.17  tff(decl_80678, type, fn_xylem_sap_20: $i > $i).
% 29.32/29.17  tff(decl_80679, type, fn_xylem_sap_21: $i > $i).
% 29.32/29.17  tff(decl_80680, type, fn_xylem_sap_15: $i > $i).
% 29.32/29.17  tff(decl_80681, type, fn_xylem_sap_17: $i > $i).
% 29.32/29.17  tff(decl_80682, type, fn_xylem_sap_14: $i > $i).
% 29.32/29.17  tff(decl_80683, type, fn_xylem_sap_19: $i > $i).
% 29.32/29.17  tff(decl_80684, type, fn_xylem_sap_13: $i > $i).
% 29.32/29.17  tff(decl_80685, type, fn_xylem_sap_18: $i > $i).
% 29.32/29.17  tff(decl_80686, type, 'Y-Chromosome': $i).
% 29.32/29.17  tff(decl_80687, type, 'The Y chromosome is one of the two sex-determining chromosomes in most mammals, including humans. In mammals, it contains the gene SRY, which triggers testis development if present.': $i).
% 29.32/29.17  tff(decl_80688, type, 'chromosome of y': $i).
% 29.32/29.17  tff(decl_80689, type, 'y chromosome': $i).
% 29.32/29.17  tff(decl_80690, type, 'y-chromosome': $i).
% 29.32/29.17  tff(decl_80691, type, y_linked_inheritance_1: $i > $o).
% 29.32/29.17  tff(decl_80692, type, 'Y-Linked-Inheritance': $i).
% 29.32/29.17  tff(decl_80693, type, 'Inheritance of characteristics that are determined by genes carried on the Y chromosome.': $i).
% 29.32/29.17  tff(decl_80694, type, 'y linked inheritance': $i).
% 29.32/29.17  tff(decl_80695, type, 'y-linked-inheritance': $i).
% 29.32/29.17  tff(decl_80696, type, fn_y_linked_inheritance_1: $i > $i).
% 29.32/29.17  tff(decl_80697, type, fn_y_linked_inheritance_2: $i > $i).
% 29.32/29.17  tff(decl_80698, type, fn_y_linked_inheritance_3: $i > $i).
% 29.32/29.17  tff(decl_80699, type, fn_y_linked_inheritance_6: $i > $i).
% 29.32/29.17  tff(decl_80700, type, fn_y_linked_inheritance_7: $i > $i).
% 29.32/29.17  tff(decl_80701, type, fn_y_linked_inheritance_8: $i > $i).
% 29.32/29.17  tff(decl_80702, type, fn_y_linked_inheritance_9: $i > $i).
% 29.32/29.17  tff(decl_80703, type, fn_y_linked_inheritance_10: $i > $i).
% 29.32/29.17  tff(decl_80704, type, fn_y_linked_inheritance_11: $i > $i).
% 29.32/29.17  tff(decl_80705, type, fn_y_linked_inheritance_12: $i > $i).
% 29.32/29.17  tff(decl_80706, type, fn_y_linked_inheritance_13: $i > $i).
% 29.32/29.17  tff(decl_80707, type, fn_y_linked_inheritance_14: $i > $i).
% 29.32/29.17  tff(decl_80708, type, fn_y_linked_inheritance_15: $i > $i).
% 29.32/29.17  tff(decl_80709, type, fn_y_linked_inheritance_16: $i > $i).
% 29.32/29.17  tff(decl_80710, type, fn_y_linked_inheritance_17: $i > $i).
% 29.32/29.17  tff(decl_80711, type, fn_y_linked_inheritance_18: $i > $i).
% 29.32/29.17  tff(decl_80712, type, fn_y_linked_inheritance_19: $i > $i).
% 29.32/29.17  tff(decl_80713, type, fn_y_linked_inheritance_20: $i > $i).
% 29.32/29.17  tff(decl_80714, type, fn_y_linked_inheritance_21: $i > $i).
% 29.32/29.17  tff(decl_80715, type, 'Yeast': $i).
% 29.32/29.17  tff(decl_80716, type, 'Single-celled fungus that reproduces asexually by binary fission or by the pinching of small buds off a parent cell; some species exhibit cell fusion between different mating types.  Yeast has plasmids and can be cultured easily and quickly.': $i).
% 29.32/29.17  tff(decl_80717, type, 'yeast cell': $i).
% 29.32/29.17  tff(decl_80718, type, 'yeast-cell': $i).
% 29.32/29.17  tff(decl_80719, type, fn_yeast_1: $i > $i).
% 29.32/29.17  tff(decl_80720, type, fn_yeast_5: $i > $i).
% 29.32/29.17  tff(decl_80721, type, fn_yeast_7: $i > $i).
% 29.32/29.17  tff(decl_80722, type, fn_yeast_8: $i > $i).
% 29.32/29.17  tff(decl_80723, type, fn_yeast_9: $i > $i).
% 29.32/29.17  tff(decl_80724, type, fn_yeast_10: $i > $i).
% 29.32/29.17  tff(decl_80725, type, fn_yeast_11: $i > $i).
% 29.32/29.17  tff(decl_80726, type, fn_yeast_12: $i > $i).
% 29.32/29.17  tff(decl_80727, type, fn_yeast_13: $i > $i).
% 29.32/29.17  tff(decl_80728, type, fn_yeast_14: $i > $i).
% 29.32/29.17  tff(decl_80729, type, fn_yeast_15: $i > $i).
% 29.32/29.17  tff(decl_80730, type, fn_yeast_16: $i > $i).
% 29.32/29.17  tff(decl_80731, type, fn_yeast_17: $i > $i).
% 29.32/29.17  tff(decl_80732, type, fn_yeast_20: $i > $i).
% 29.32/29.17  tff(decl_80733, type, fn_yeast_26: $i > $i).
% 29.32/29.17  tff(decl_80734, type, fn_yeast_24: $i > $i).
% 29.32/29.17  tff(decl_80735, type, fn_yeast_25: $i > $i).
% 29.32/29.17  tff(decl_80736, type, fn_yeast_22: $i > $i).
% 29.32/29.17  tff(decl_80737, type, fn_yeast_23: $i > $i).
% 29.32/29.17  tff(decl_80738, type, 'Yeast-Artificial-Chromosome': $i).
% 29.32/29.17  tff(decl_80739, type, 'An artificial version of a yeast chrosome, which can carry inserted fragments of DNA a million base pairs long.': $i).
% 29.32/29.17  tff(decl_80740, type, yac: $i).
% 29.32/29.17  tff(decl_80741, type, 'yeast artificial chromosome': $i).
% 29.32/29.17  tff(decl_80742, type, 'yeast-artificial-chromosome': $i).
% 29.32/29.17  tff(decl_80743, type, 'Yeast-Mating-Factor': $i).
% 29.32/29.17  tff(decl_80744, type, 'A pheromone produced by yeast to signal the presence of a mating cell.  a cells produce a-factor, and alpha cells produce alpha-factor.  Mating only occurs between a and alpha cells and never between two cells of the same type.': $i).
% 29.32/29.17  tff(decl_80745, type, ymf: $i).
% 29.32/29.17  tff(decl_80746, type, 'yeast mating factor': $i).
% 29.32/29.17  tff(decl_80747, type, 'yeast-mating-factor': $i).
% 29.32/29.17  tff(decl_80748, type, 'Yeast-Transcription-Factor-Gene': $i).
% 29.32/29.17  tff(decl_80749, type, 'A gene that codes for yeast transcription factor.': $i).
% 29.32/29.17  tff(decl_80750, type, 'yeast transcription factor gene': $i).
% 29.32/29.17  tff(decl_80751, type, 'yeast-transcription-factor-gene': $i).
% 29.32/29.17  tff(decl_80752, type, yeasted_bread_1: $i > $o).
% 29.32/29.17  tff(decl_80753, type, 'Yeasted-Bread': $i).
% 29.32/29.17  tff(decl_80754, type, 'Food made by combining flour and yeast. Through the process of fermentation, the yeast produce carbon dioxide which causes the bread to rise.': $i).
% 29.32/29.17  tff(decl_80755, type, 'yeasted bread': $i).
% 29.32/29.17  tff(decl_80756, type, 'yeasted-bread': $i).
% 29.32/29.17  tff(decl_80757, type, fn_yeasted_bread_1: $i > $i).
% 29.32/29.17  tff(decl_80758, type, fn_yeasted_bread_2: $i > $i).
% 29.32/29.17  tff(decl_80759, type, fn_yeasted_bread_3: $i > $i).
% 29.32/29.17  tff(decl_80760, type, fn_yeasted_bread_4: $i > $i).
% 29.32/29.17  tff(decl_80761, type, fn_yeasted_bread_5: $i > $i).
% 29.32/29.17  tff(decl_80762, type, fn_yeasted_bread_6: $i > $i).
% 29.32/29.17  tff(decl_80763, type, fn_yeasted_bread_7: $i > $i).
% 29.32/29.17  tff(decl_80764, type, 'Yellow-Light': $i).
% 29.32/29.17  tff(decl_80765, type, 'The portion of the electromagnetic spectrum that can be detected as yellow, ranging in wavelength from about 570 nm to 590 nm.': $i).
% 29.32/29.17  tff(decl_80766, type, 'light of yellow': $i).
% 29.32/29.17  tff(decl_80767, type, 'yellow light': $i).
% 29.32/29.17  tff(decl_80768, type, 'yellow-light': $i).
% 29.32/29.17  tff(decl_80769, type, fn_yellow_light_2: $i > $i).
% 29.32/29.17  tff(decl_80770, type, fn_yellow_light_3: $i > $i).
% 29.32/29.17  tff(decl_80771, type, fn_yellow_light_7: $i > $i).
% 29.32/29.17  tff(decl_80772, type, fn_yellow_light_9: $i > $i).
% 29.32/29.17  tff(decl_80773, type, fn_yellow_light_10: $i > $i).
% 29.32/29.17  tff(decl_80774, type, fn_yellow_light_6: $i > $i).
% 29.32/29.17  tff(decl_80775, type, yes_no_viewpoint_1: $i > $o).
% 29.32/29.17  tff(decl_80776, type, 'Yes-No-Viewpoint': $i).
% 29.32/29.17  tff(decl_80777, type, 'yes no viewpoint': $i).
% 29.32/29.17  tff(decl_80778, type, 'yes-no-viewpoint': $i).
% 29.32/29.17  tff(decl_80779, type, 'Yogurt': $i).
% 29.32/29.17  tff(decl_80780, type, 'Yoghurt or yogurt is a dairy product produced by bacterial fermentation of milk.': $i).
% 29.32/29.17  tff(decl_80781, type, yogurt: $i).
% 29.32/29.17  tff(decl_80782, type, fn_yogurt_1: $i > $i).
% 29.32/29.17  tff(decl_80783, type, fn_yogurt_2: $i > $i).
% 29.32/29.17  tff(decl_80784, type, fn_yogurt_3: $i > $i).
% 29.32/29.17  tff(decl_80785, type, fn_yogurt_4: $i > $i).
% 29.32/29.17  tff(decl_80786, type, fn_yogurt_6: $i > $i).
% 29.32/29.17  tff(decl_80787, type, fn_yogurt_9: $i > $i).
% 29.32/29.17  tff(decl_80788, type, fn_yogurt_10: $i > $i).
% 29.32/29.17  tff(decl_80789, type, 'Yolk': $i).
% 29.32/29.17  tff(decl_80790, type, 'The part of an egg that nourishes the developing embryo.': $i).
% 29.32/29.17  tff(decl_80791, type, yolk: $i).
% 29.32/29.17  tff(decl_80792, type, fn_yolk_1: $i > $i).
% 29.32/29.17  tff(decl_80793, type, fn_yolk_2: $i > $i).
% 29.32/29.17  tff(decl_80794, type, yolk_plug_1: $i > $o).
% 29.32/29.17  tff(decl_80795, type, 'Yolk-Plug': $i).
% 29.32/29.17  tff(decl_80796, type, 'In an amphibian gastrula, a group of large endodermal cells that contain nutrients and will end up on the inside of the embryo, covered by ectoderm.': $i).
% 29.32/29.17  tff(decl_80797, type, 'plug of yolk': $i).
% 29.32/29.17  tff(decl_80798, type, 'yolk plug': $i).
% 29.32/29.17  tff(decl_80799, type, 'yolk-plug': $i).
% 29.32/29.17  tff(decl_80800, type, 'Yolk-Sac': $i).
% 29.32/29.17  tff(decl_80801, type, 'One of four extraembryonic membranes. In humans it provides the first circulatory system of the developing embryo.': $i).
% 29.32/29.17  tff(decl_80802, type, 'sac of yolk': $i).
% 29.32/29.17  tff(decl_80803, type, 'yolk sac': $i).
% 29.32/29.17  tff(decl_80804, type, 'yolk-sac': $i).
% 29.32/29.17  tff(decl_80805, type, ytterbium_1: $i > $o).
% 29.32/29.17  tff(decl_80806, type, 'Ytterbium': $i).
% 29.32/29.17  tff(decl_80807, type, 'Ytterbium is a metal atom with atomic number 70. It is represented by the symbol Yb.': $i).
% 29.32/29.17  tff(decl_80808, type, ytterbium: $i).
% 29.32/29.17  tff(decl_80809, type, yb: $i).
% 29.32/29.17  tff(decl_80810, type, fn_ytterbium_3: $i > $i).
% 29.32/29.17  tff(decl_80811, type, fn_ytterbium_4: $i > $i).
% 29.32/29.17  tff(decl_80812, type, fn_ytterbium_5: $i > $i).
% 29.32/29.17  tff(decl_80813, type, fn_ytterbium_9: $i > $i).
% 29.32/29.17  tff(decl_80814, type, fn_ytterbium_10: $i > $i).
% 29.32/29.17  tff(decl_80815, type, fn_ytterbium_11: $i > $i).
% 29.32/29.17  tff(decl_80816, type, fn_ytterbium_12: $i > $i).
% 29.32/29.17  tff(decl_80817, type, fn_ytterbium_7: $i > $i).
% 29.32/29.17  tff(decl_80818, type, fn_ytterbium_8: $i > $i).
% 29.32/29.17  tff(decl_80819, type, fn_ytterbium_6: $i > $i).
% 29.32/29.17  tff(decl_80820, type, yttrium_1: $i > $o).
% 29.32/29.17  tff(decl_80821, type, 'Yttrium': $i).
% 29.32/29.17  tff(decl_80822, type, 'Yttrium is a metal atom with atomic number 39. It is represented by the symbol Y.': $i).
% 29.32/29.17  tff(decl_80823, type, yttrium: $i).
% 29.32/29.17  tff(decl_80824, type, fn_yttrium_4: $i > $i).
% 29.32/29.17  tff(decl_80825, type, fn_yttrium_5: $i > $i).
% 29.32/29.17  tff(decl_80826, type, fn_yttrium_6: $i > $i).
% 29.32/29.17  tff(decl_80827, type, fn_yttrium_7: $i > $i).
% 29.32/29.17  tff(decl_80828, type, fn_yttrium_11: $i > $i).
% 29.32/29.17  tff(decl_80829, type, fn_yttrium_12: $i > $i).
% 29.32/29.17  tff(decl_80830, type, fn_yttrium_13: $i > $i).
% 29.32/29.17  tff(decl_80831, type, fn_yttrium_14: $i > $i).
% 29.32/29.17  tff(decl_80832, type, "88.91": $i).
% 29.32/29.17  tff(decl_80833, type, fn_yttrium_9: $i > $i).
% 29.32/29.17  tff(decl_80834, type, fn_yttrium_10: $i > $i).
% 29.32/29.17  tff(decl_80835, type, fn_yttrium_8: $i > $i).
% 29.32/29.17  tff(decl_80836, type, 'Z-Line-Filament': $i).
% 29.32/29.17  tff(decl_80837, type, 'The border that separates and connects adjacent sarcomeres in a muscle.': $i).
% 29.32/29.17  tff(decl_80838, type, 'z filament': $i).
% 29.32/29.17  tff(decl_80839, type, 'z-filament': $i).
% 29.32/29.17  tff(decl_80840, type, 'z line filament': $i).
% 29.32/29.17  tff(decl_80841, type, 'z-line-filament': $i).
% 29.32/29.17  tff(decl_80842, type, zebra_1: $i > $o).
% 29.32/29.17  tff(decl_80843, type, 'Zebra': $i).
% 29.32/29.17  tff(decl_80844, type, 'One of several species of African equids that are characterized by distinctive black and white stripes.': $i).
% 29.32/29.17  tff(decl_80845, type, zebra: $i).
% 29.32/29.17  tff(decl_80846, type, zebra_mussel_1: $i > $o).
% 29.32/29.17  tff(decl_80847, type, 'Zebra-Mussel': $i).
% 29.32/29.17  tff(decl_80848, type, 'Dreissena polymorpha, a species of small freshwater mussel originally native to Europe and considered an invasive species in many other areas.': $i).
% 29.32/29.17  tff(decl_80849, type, 'mussel of zebra': $i).
% 29.32/29.17  tff(decl_80850, type, 'zebra mussel': $i).
% 29.32/29.17  tff(decl_80851, type, 'zebra-mussel': $i).
% 29.32/29.17  tff(decl_80852, type, 'Zebrafish': $i).
% 29.32/29.17  tff(decl_80853, type, 'A tropical freshwater minnow, commonly used as a model organism in biological research.': $i).
% 29.32/29.17  tff(decl_80854, type, zebrafish: $i).
% 29.32/29.17  tff(decl_80855, type, fn_zebrafish_1: $i > $i).
% 29.32/29.17  tff(decl_80856, type, fn_zebrafish_developmental_genetics_1: $i > $i).
% 29.32/29.17  tff(decl_80857, type, 'Zebrafish-Developmental-Genetics': $i).
% 29.32/29.17  tff(decl_80858, type, 'Developmental genetics of zebrafish studies the effect that genes have in a phenotype, given normal or abnormal epigenetic parameters.': $i).
% 29.32/29.17  tff(decl_80859, type, 'zebrafish developmental genetics': $i).
% 29.32/29.17  tff(decl_80860, type, 'zebrafish-developmental-genetic': $i).
% 29.32/29.17  tff(decl_80861, type, 'Zero-Population-Growth': $i).
% 29.32/29.17  tff(decl_80862, type, 'A state of stable population size, when the population is neither growing nor shrinking.': $i).
% 29.32/29.17  tff(decl_80863, type, 'zero population growth': $i).
% 29.32/29.17  tff(decl_80864, type, 'zero-population-growth': $i).
% 29.32/29.17  tff(decl_80865, type, 'Zinc': $i).
% 29.32/29.17  tff(decl_80866, type, 'Zinc is a metal atom with atomic number 30. It is represented by the symbol Zn.': $i).
% 29.32/29.17  tff(decl_80867, type, zinc: $i).
% 29.32/29.17  tff(decl_80868, type, 'Zn': $i).
% 29.32/29.17  tff(decl_80869, type, fn_zinc_4: $i > $i).
% 29.32/29.17  tff(decl_80870, type, fn_zinc_5: $i > $i).
% 29.32/29.17  tff(decl_80871, type, fn_zinc_6: $i > $i).
% 29.32/29.17  tff(decl_80872, type, fn_zinc_7: $i > $i).
% 29.32/29.17  tff(decl_80873, type, fn_zinc_11: $i > $i).
% 29.32/29.17  tff(decl_80874, type, fn_zinc_12: $i > $i).
% 29.32/29.17  tff(decl_80875, type, fn_zinc_13: $i > $i).
% 29.32/29.17  tff(decl_80876, type, fn_zinc_14: $i > $i).
% 29.32/29.17  tff(decl_80877, type, "1.65": $i).
% 29.32/29.17  tff(decl_80878, type, "65.41": $i).
% 29.32/29.17  tff(decl_80879, type, fn_zinc_9: $i > $i).
% 29.32/29.17  tff(decl_80880, type, fn_zinc_10: $i > $i).
% 29.32/29.17  tff(decl_80881, type, fn_zinc_8: $i > $i).
% 29.32/29.17  tff(decl_80882, type, zirconium_1: $i > $o).
% 29.32/29.17  tff(decl_80883, type, 'Zirconium': $i).
% 29.32/29.17  tff(decl_80884, type, 'Zirconium is a metal atom with atomic number 40. It is represented by the symbol Zr.': $i).
% 29.32/29.17  tff(decl_80885, type, zirconium: $i).
% 29.32/29.17  tff(decl_80886, type, 'Zr': $i).
% 29.32/29.17  tff(decl_80887, type, fn_zirconium_3: $i > $i).
% 29.32/29.17  tff(decl_80888, type, fn_zirconium_4: $i > $i).
% 29.32/29.17  tff(decl_80889, type, fn_zirconium_5: $i > $i).
% 29.32/29.17  tff(decl_80890, type, fn_zirconium_9: $i > $i).
% 29.32/29.17  tff(decl_80891, type, fn_zirconium_10: $i > $i).
% 29.32/29.17  tff(decl_80892, type, fn_zirconium_11: $i > $i).
% 29.32/29.17  tff(decl_80893, type, fn_zirconium_12: $i > $i).
% 29.32/29.17  tff(decl_80894, type, "1.33": $i).
% 29.32/29.17  tff(decl_80895, type, "91.22": $i).
% 29.32/29.17  tff(decl_80896, type, fn_zirconium_7: $i > $i).
% 29.32/29.17  tff(decl_80897, type, fn_zirconium_8: $i > $i).
% 29.32/29.17  tff(decl_80898, type, fn_zirconium_6: $i > $i).
% 29.32/29.17  tff(decl_80899, type, zn_plus_2_1: $i > $o).
% 29.32/29.17  tff(decl_80900, type, 'Zn-Plus-2': $i).
% 29.32/29.17  tff(decl_80901, type, 'An ion of Zinc with 2 positive charge.': $i).
% 29.32/29.17  tff(decl_80902, type, 'zn plus 2': $i).
% 29.32/29.17  tff(decl_80903, type, 'zn-plus-2': $i).
% 29.32/29.17  tff(decl_80904, type, fn_zn_plus_2_1: $i > $i).
% 29.32/29.17  tff(decl_80905, type, 'Zona-Pellucida': $i).
% 29.32/29.17  tff(decl_80906, type, 'A glycoprotein membrane surrounding the plasma membrane of a mammalian ovum.': $i).
% 29.32/29.17  tff(decl_80907, type, 'zona pellucida': $i).
% 29.32/29.17  tff(decl_80908, type, 'zona-pellucida': $i).
% 29.32/29.17  tff(decl_80909, type, zone_of_polarizing_activity_1: $i > $o).
% 29.32/29.17  tff(decl_80910, type, 'Zone-Of-Polarizing-Activity': $i).
% 29.32/29.17  tff(decl_80911, type, 'A block of mesodermal tissue that signals a developing limb bud to establish the proper anterior/posterior polarity of the limb.': $i).
% 29.32/29.17  tff(decl_80912, type, zpa: $i).
% 29.32/29.17  tff(decl_80913, type, 'zone of polarizing activity': $i).
% 29.32/29.17  tff(decl_80914, type, 'zone-of-polarizing-activity': $i).
% 29.32/29.17  tff(decl_80915, type, 'Zoned-Reserve': $i).
% 29.32/29.17  tff(decl_80916, type, 'A large region that is protected from human activity, surrounded by other areas that have been and continue to be used by humans.': $i).
% 29.32/29.17  tff(decl_80917, type, 'zoned reserve': $i).
% 29.32/29.17  tff(decl_80918, type, 'zoned-reserve': $i).
% 29.32/29.17  tff(decl_80919, type, 'Zoonotic-Pathogen': $i).
% 29.32/29.17  tff(decl_80920, type, 'A disease-causing pathogen that enters the human population from another species of animal. Examples include Yersenia pestis, the bacterium that causes plague, and the rabies virus.': $i).
% 29.32/29.17  tff(decl_80921, type, 'zoonotic pathogen': $i).
% 29.32/29.17  tff(decl_80922, type, 'zoonotic-pathogen': $i).
% 29.32/29.17  tff(decl_80923, type, 'Zoospore': $i).
% 29.32/29.17  tff(decl_80924, type, 'A motile, asexually produced spore produced by some algae, protists, and fungi.': $i).
% 29.32/29.17  tff(decl_80925, type, zoospore: $i).
% 29.32/29.17  tff(decl_80926, type, 'Zygomycete': $i).
% 29.32/29.17  tff(decl_80927, type, 'A fungus of the phylum Zygomycota. The phylum is named for a structure called a zygosporangium, where spores are produced during sexual reproduction.': $i).
% 29.32/29.17  tff(decl_80928, type, zygomycota: $i).
% 29.32/29.17  tff(decl_80929, type, zygomycete: $i).
% 29.32/29.17  tff(decl_80930, type, 'Zygosporangium': $i).
% 29.32/29.17  tff(decl_80931, type, 'The defining structure of the zygomycetes; a thick-walled structure in which spores are produced.': $i).
% 29.32/29.17  tff(decl_80932, type, zygosporangium: $i).
% 29.32/29.17  tff(decl_80933, type, 'Zygote': $i).
% 29.32/29.17  tff(decl_80934, type, 'The diploid result of the fusion of haploid gametes; a fertilized egg.': $i).
% 29.32/29.17  tff(decl_80935, type, 'fertilized egg': $i).
% 29.32/29.17  tff(decl_80936, type, 'fertilized-egg': $i).
% 29.32/29.17  tff(decl_80937, type, zygote: $i).
% 29.32/29.17  tff(decl_80938, type, fn_zygote_1: $i > $i).
% 29.32/29.17  tff(decl_80939, type, fn_zygote_2: $i > $i).
% 29.32/29.17  tff(decl_80940, type, a_cell: $i).
% 29.32/29.17  fof(a528132, axiom, ![X1]:((cell_1(X1)=>(((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((original_name_2(X1,'Cell')&description_2(X1,'The basic unit from which living organisms are made, consisting of an aqueous solution of organic molecules enclosed by a membrane.  All cells arise from existing cells, usually by a process of division into two.  (Alberts:ECB:G-3).'))&user_description_2(X1,'The basic unit from which living organisms are made.'))&concept2words_2(X1,cell))&living_entity_1(X1))&cell_pole_1(fn_cell_1(X1)))&cytoskeleton_1(fn_cell_2(X1)))&surface_1(fn_cell_4(X1)))&shape_value_1(fn_cell_5(X1)))&specific_surface_area_value_1(fn_cell_7(X1)))&motor_protein_1(fn_cell_8(X1)))&protein_enzyme_1(fn_cell_9(X1)))&size_value_1(fn_cell_11(X1)))&structural_complexity_value_1(fn_cell_13(X1)))&ribosome_1(fn_cell_14(X1)))&length_value_1(fn_cell_18(X1)))&length_value_1(fn_cell_19(X1)))&length_value_1(fn_cell_20(X1)))&membrane_potential_1(fn_cell_21(X1)))&volume_value_1(fn_cell_22(X1)))&genome_1(fn_cell_24(X1)))&chromosome_1(fn_cell_25(X1)))&tangible_entity_1(fn_cell_26(X1)))&phospholipid_bilayer_1(fn_cell_26(X1)))&surface_1(fn_cell_27(X1)))&cytoplasmic_side_1(fn_cell_27(X1)))&mixture_1(fn_cell_28(X1)))&cytoplasm_1(fn_cell_28(X1)))&substance_1(fn_cell_29(X1)))&cytosol_1(fn_cell_29(X1)))&plasma_membrane_1(fn_cell_30(X1)))&cell_1(fn_cytoplasm_7(fn_cell_28(X1))))&cytoplasm_1(fn_cytoplasmic_side_1(fn_cell_27(X1))))&substance_1(fn_mixture_1(fn_cell_28(X1))))&cytosol_1(fn_cytoplasm_8(fn_cell_28(X1))))&tangible_entity_1(fn_biomembrane_63(fn_cell_30(X1))))&phospholipid_bilayer_1(fn_biomembrane_63(fn_cell_30(X1))))&tangible_entity_1(fn_plasma_membrane_71(fn_cell_30(X1))))&phospholipid_bilayer_1(fn_plasma_membrane_71(fn_cell_30(X1))))&surface_1(fn_biomembrane_47(fn_cell_30(X1))))&cytoplasmic_side_1(fn_plasma_membrane_66(fn_cell_30(X1))))&is_across_2(fn_cell_21(X1),fn_cell_30(X1)))&shape_2(X1,fn_cell_5(X1)))&specific_surface_area_2(X1,fn_cell_7(X1)))&size_2(X1,fn_cell_11(X1)))&structural_complexity_2(X1,fn_cell_13(X1)))&diameter_2(X1,fn_cell_18(X1)))&volume_2(X1,fn_cell_22(X1)))&exactCardinality(X1,has_region_0,"2",cell_pole_0))&has_region_2(X1,fn_cell_1(X1)))&has_region_2(X1,fn_cell_4(X1)))&minCardinality(X1,has_part_0,"1",chromosome_0))&has_part_2(X1,fn_cell_2(X1)))&has_part_2(X1,fn_cell_25(X1)))&has_part_2(X1,fn_cell_24(X1)))&has_part_2(X1,fn_cell_8(X1)))&has_part_2(X1,fn_cell_14(X1)))&has_part_2(X1,fn_cell_30(X1)))&is_inside_2(fn_cell_28(X1),fn_cell_30(X1)))&has_part_2(fn_cell_28(X1),fn_cell_9(X1)))&the_cardinal_value_2(fn_cell_20(X1),"100.0e0"))&cardinal_unit_class_2(fn_cell_20(X1),micrometer_0))&greater_than_or_equal_to_2(fn_cell_20(X1),fn_cell_18(X1)))&the_cardinal_value_2(fn_cell_19(X1),"0.1e0"))&cardinal_unit_class_2(fn_cell_19(X1),micrometer_0))&greater_than_or_equal_to_2(fn_cell_18(X1),fn_cell_19(X1)))&is_inside_2(fn_cell_14(X1),fn_cell_29(X1)))&the_scalar_value_2(fn_cell_13(X1),simple_0))&scalar_unit_class_2(fn_cell_13(X1),organism_0))&directly_proportional_2(fn_cell_11(X1),fn_cell_22(X1)))&is_oriented_toward_2(fn_cell_27(X1),fn_cell_28(X1)))&is_at_2(fn_cell_26(X1),fn_cell_4(X1)))&has_part_2(X1,fn_cell_28(X1)))&has_part_2(fn_cell_28(X1),fn_cell_29(X1)))&has_region_2(fn_cell_30(X1),fn_cell_27(X1)))&has_part_2(fn_cell_30(X1),fn_cell_26(X1)))&is_facing_2(fn_cell_27(X1),fn_cell_28(X1)))&X1=fn_cytoplasm_7(fn_cell_28(X1)))&fn_cell_29(X1)=fn_mixture_1(fn_cell_28(X1)))&fn_cell_29(X1)=fn_cytoplasm_8(fn_cell_28(X1)))&fn_cell_27(X1)=fn_biomembrane_47(fn_cell_30(X1)))&fn_cell_27(X1)=fn_plasma_membrane_66(fn_cell_30(X1)))&fn_cell_26(X1)=fn_biomembrane_63(fn_cell_30(X1)))&fn_cell_26(X1)=fn_plasma_membrane_71(fn_cell_30(X1)))&fn_cell_28(X1)=fn_cytoplasmic_side_1(fn_cell_27(X1)))&fn_mixture_1(fn_cell_28(X1))=fn_cytoplasm_8(fn_cell_28(X1)))&fn_cytoplasm_8(fn_cell_28(X1))=fn_biomembrane_63(fn_cell_30(X1)))&fn_biomembrane_63(fn_cell_30(X1))=fn_plasma_membrane_71(fn_cell_30(X1)))&fn_plasma_membrane_71(fn_cell_30(X1))=fn_biomembrane_47(fn_cell_30(X1)))&fn_biomembrane_47(fn_cell_30(X1))=fn_plasma_membrane_66(fn_cell_30(X1))))), file('/export/starexec/sandbox2/benchmark/Axioms/BIO001+0.ax', a528132)).
% 29.32/29.17  fof(ask, conjecture, cytoskeleton_1(fn_cell_2(a_cell)), file('/export/starexec/sandbox2/benchmark/theBenchmark.p', ask)).
% 29.32/29.17  fof(a_cell, axiom, cell_1(a_cell), file('/export/starexec/sandbox2/benchmark/theBenchmark.p', a_cell)).
% 29.32/29.17  fof(c_0_3, plain, ![X5195]:(((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((((original_name_2(X5195,'Cell')|~cell_1(X5195))&(description_2(X5195,'The basic unit from which living organisms are made, consisting of an aqueous solution of organic molecules enclosed by a membrane.  All cells arise from existing cells, usually by a process of division into two.  (Alberts:ECB:G-3).')|~cell_1(X5195)))&(user_description_2(X5195,'The basic unit from which living organisms are made.')|~cell_1(X5195)))&(concept2words_2(X5195,cell)|~cell_1(X5195)))&(living_entity_1(X5195)|~cell_1(X5195)))&(cell_pole_1(fn_cell_1(X5195))|~cell_1(X5195)))&(cytoskeleton_1(fn_cell_2(X5195))|~cell_1(X5195)))&(surface_1(fn_cell_4(X5195))|~cell_1(X5195)))&(shape_value_1(fn_cell_5(X5195))|~cell_1(X5195)))&(specific_surface_area_value_1(fn_cell_7(X5195))|~cell_1(X5195)))&(motor_protein_1(fn_cell_8(X5195))|~cell_1(X5195)))&(protein_enzyme_1(fn_cell_9(X5195))|~cell_1(X5195)))&(size_value_1(fn_cell_11(X5195))|~cell_1(X5195)))&(structural_complexity_value_1(fn_cell_13(X5195))|~cell_1(X5195)))&(ribosome_1(fn_cell_14(X5195))|~cell_1(X5195)))&(length_value_1(fn_cell_18(X5195))|~cell_1(X5195)))&(length_value_1(fn_cell_19(X5195))|~cell_1(X5195)))&(length_value_1(fn_cell_20(X5195))|~cell_1(X5195)))&(membrane_potential_1(fn_cell_21(X5195))|~cell_1(X5195)))&(volume_value_1(fn_cell_22(X5195))|~cell_1(X5195)))&(genome_1(fn_cell_24(X5195))|~cell_1(X5195)))&(chromosome_1(fn_cell_25(X5195))|~cell_1(X5195)))&(tangible_entity_1(fn_cell_26(X5195))|~cell_1(X5195)))&(phospholipid_bilayer_1(fn_cell_26(X5195))|~cell_1(X5195)))&(surface_1(fn_cell_27(X5195))|~cell_1(X5195)))&(cytoplasmic_side_1(fn_cell_27(X5195))|~cell_1(X5195)))&(mixture_1(fn_cell_28(X5195))|~cell_1(X5195)))&(cytoplasm_1(fn_cell_28(X5195))|~cell_1(X5195)))&(substance_1(fn_cell_29(X5195))|~cell_1(X5195)))&(cytosol_1(fn_cell_29(X5195))|~cell_1(X5195)))&(plasma_membrane_1(fn_cell_30(X5195))|~cell_1(X5195)))&(cell_1(fn_cytoplasm_7(fn_cell_28(X5195)))|~cell_1(X5195)))&(cytoplasm_1(fn_cytoplasmic_side_1(fn_cell_27(X5195)))|~cell_1(X5195)))&(substance_1(fn_mixture_1(fn_cell_28(X5195)))|~cell_1(X5195)))&(cytosol_1(fn_cytoplasm_8(fn_cell_28(X5195)))|~cell_1(X5195)))&(tangible_entity_1(fn_biomembrane_63(fn_cell_30(X5195)))|~cell_1(X5195)))&(phospholipid_bilayer_1(fn_biomembrane_63(fn_cell_30(X5195)))|~cell_1(X5195)))&(tangible_entity_1(fn_plasma_membrane_71(fn_cell_30(X5195)))|~cell_1(X5195)))&(phospholipid_bilayer_1(fn_plasma_membrane_71(fn_cell_30(X5195)))|~cell_1(X5195)))&(surface_1(fn_biomembrane_47(fn_cell_30(X5195)))|~cell_1(X5195)))&(cytoplasmic_side_1(fn_plasma_membrane_66(fn_cell_30(X5195)))|~cell_1(X5195)))&(is_across_2(fn_cell_21(X5195),fn_cell_30(X5195))|~cell_1(X5195)))&(shape_2(X5195,fn_cell_5(X5195))|~cell_1(X5195)))&(specific_surface_area_2(X5195,fn_cell_7(X5195))|~cell_1(X5195)))&(size_2(X5195,fn_cell_11(X5195))|~cell_1(X5195)))&(structural_complexity_2(X5195,fn_cell_13(X5195))|~cell_1(X5195)))&(diameter_2(X5195,fn_cell_18(X5195))|~cell_1(X5195)))&(volume_2(X5195,fn_cell_22(X5195))|~cell_1(X5195)))&(exactCardinality(X5195,has_region_0,"2",cell_pole_0)|~cell_1(X5195)))&(has_region_2(X5195,fn_cell_1(X5195))|~cell_1(X5195)))&(has_region_2(X5195,fn_cell_4(X5195))|~cell_1(X5195)))&(minCardinality(X5195,has_part_0,"1",chromosome_0)|~cell_1(X5195)))&(has_part_2(X5195,fn_cell_2(X5195))|~cell_1(X5195)))&(has_part_2(X5195,fn_cell_25(X5195))|~cell_1(X5195)))&(has_part_2(X5195,fn_cell_24(X5195))|~cell_1(X5195)))&(has_part_2(X5195,fn_cell_8(X5195))|~cell_1(X5195)))&(has_part_2(X5195,fn_cell_14(X5195))|~cell_1(X5195)))&(has_part_2(X5195,fn_cell_30(X5195))|~cell_1(X5195)))&(is_inside_2(fn_cell_28(X5195),fn_cell_30(X5195))|~cell_1(X5195)))&(has_part_2(fn_cell_28(X5195),fn_cell_9(X5195))|~cell_1(X5195)))&(the_cardinal_value_2(fn_cell_20(X5195),"100.0e0")|~cell_1(X5195)))&(cardinal_unit_class_2(fn_cell_20(X5195),micrometer_0)|~cell_1(X5195)))&(greater_than_or_equal_to_2(fn_cell_20(X5195),fn_cell_18(X5195))|~cell_1(X5195)))&(the_cardinal_value_2(fn_cell_19(X5195),"0.1e0")|~cell_1(X5195)))&(cardinal_unit_class_2(fn_cell_19(X5195),micrometer_0)|~cell_1(X5195)))&(greater_than_or_equal_to_2(fn_cell_18(X5195),fn_cell_19(X5195))|~cell_1(X5195)))&(is_inside_2(fn_cell_14(X5195),fn_cell_29(X5195))|~cell_1(X5195)))&(the_scalar_value_2(fn_cell_13(X5195),simple_0)|~cell_1(X5195)))&(scalar_unit_class_2(fn_cell_13(X5195),organism_0)|~cell_1(X5195)))&(directly_proportional_2(fn_cell_11(X5195),fn_cell_22(X5195))|~cell_1(X5195)))&(is_oriented_toward_2(fn_cell_27(X5195),fn_cell_28(X5195))|~cell_1(X5195)))&(is_at_2(fn_cell_26(X5195),fn_cell_4(X5195))|~cell_1(X5195)))&(has_part_2(X5195,fn_cell_28(X5195))|~cell_1(X5195)))&(has_part_2(fn_cell_28(X5195),fn_cell_29(X5195))|~cell_1(X5195)))&(has_region_2(fn_cell_30(X5195),fn_cell_27(X5195))|~cell_1(X5195)))&(has_part_2(fn_cell_30(X5195),fn_cell_26(X5195))|~cell_1(X5195)))&(is_facing_2(fn_cell_27(X5195),fn_cell_28(X5195))|~cell_1(X5195)))&(X5195=fn_cytoplasm_7(fn_cell_28(X5195))|~cell_1(X5195)))&(fn_cell_29(X5195)=fn_mixture_1(fn_cell_28(X5195))|~cell_1(X5195)))&(fn_cell_29(X5195)=fn_cytoplasm_8(fn_cell_28(X5195))|~cell_1(X5195)))&(fn_cell_27(X5195)=fn_biomembrane_47(fn_cell_30(X5195))|~cell_1(X5195)))&(fn_cell_27(X5195)=fn_plasma_membrane_66(fn_cell_30(X5195))|~cell_1(X5195)))&(fn_cell_26(X5195)=fn_biomembrane_63(fn_cell_30(X5195))|~cell_1(X5195)))&(fn_cell_26(X5195)=fn_plasma_membrane_71(fn_cell_30(X5195))|~cell_1(X5195)))&(fn_cell_28(X5195)=fn_cytoplasmic_side_1(fn_cell_27(X5195))|~cell_1(X5195)))&(fn_mixture_1(fn_cell_28(X5195))=fn_cytoplasm_8(fn_cell_28(X5195))|~cell_1(X5195)))&(fn_cytoplasm_8(fn_cell_28(X5195))=fn_biomembrane_63(fn_cell_30(X5195))|~cell_1(X5195)))&(fn_biomembrane_63(fn_cell_30(X5195))=fn_plasma_membrane_71(fn_cell_30(X5195))|~cell_1(X5195)))&(fn_plasma_membrane_71(fn_cell_30(X5195))=fn_biomembrane_47(fn_cell_30(X5195))|~cell_1(X5195)))&(fn_biomembrane_47(fn_cell_30(X5195))=fn_plasma_membrane_66(fn_cell_30(X5195))|~cell_1(X5195)))), inference(distribute,[status(thm)],[inference(variable_rename,[status(thm)],[inference(fof_nnf,[status(thm)],[a528132])])])).
% 29.32/29.17  fof(c_0_4, negated_conjecture, ~cytoskeleton_1(fn_cell_2(a_cell)), inference(fof_simplification,[status(thm)],[inference(assume_negation,[status(cth)],[ask])])).
% 29.32/29.17  cnf(c_0_5, plain, (cytoskeleton_1(fn_cell_2(X1))|~cell_1(X1)), inference(split_conjunct,[status(thm)],[c_0_3])).
% 29.32/29.17  cnf(c_0_6, negated_conjecture, (~cytoskeleton_1(fn_cell_2(a_cell))), inference(split_conjunct,[status(thm)],[c_0_4])).
% 29.32/29.17  cnf(c_0_7, plain, (cell_1(a_cell)), inference(split_conjunct,[status(thm)],[a_cell])).
% 29.32/29.17  cnf(c_0_8, plain, ($false), inference(cdclpropres,[status(thm)],[c_0_5, c_0_6, c_0_7]), ['proof']).
% 29.32/29.17  % SZS output end Proof
% 29.32/29.17  % Total time : 24.685000 s
% 29.32/29.17  % SZS output end Proof
% 29.32/29.17  % Total time : 28.190000 s
%------------------------------------------------------------------------------