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Research Article

Drug Metabolism in Birds: Part 2

&
Pages 141-253 | Published online: 22 Sep 2008

References

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  • Thiegs B. J., Smith G. N., Bevirt J. L. “Determination of 3-Amino-5-nitro-o-toluamide (ANOT) in Chicken Tissues”. J. Agric. Food Chem. 1961; 9: 201–240
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  • Moody J. P., Williams R. T. ldquo;The Fate of 4-Nitrophenyl-arsonic Acid in Hens”. Ibid. 1964; 2: 695–706
  • Moody J. P., Williams R. T. ldquo;The Metabolism of 4-Hy-droxy-3-nitrophenylarsonic Acid in Hens”. Ibid. 1964; 2: 707–715
  • Allewijn F. T. N., Demoen P. J. A. “Metabolic Study of 2-(Acetyl-imino)-3[2-hydroxy-2-(2-thienyl)-ethy1]-thiazoline in Chickens,”. J. Pharm. Sci. 1966; 55: 1028–1032
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  • Filer C. W., Hiscock D. R., Parnell E. W. “Decoquinate. I. An Absorption and Elimination Study in Broiler Chickens Using 14C-Labelled Decoquinate,”. J. Sci. FoodAgric. 1969; 20: 65–69
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  • Craine E. M., Kouba R. F., Ray W. H. “The Disposition of Decoquinate-14C Administered Orally to Chickens”. J. Agric. Food Chem. 1971; 19: 1228–1233
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  • Herrett R. J., Williams C. W., Heotis J. P., Buzard J. A. “Metabolism of 5-Nitro-2-furaldehyde Acetylhy-drazone-C14 (Nihydrazone) in the Chick”. J. Agric. Food Chem. 1967; 15: 433–438
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  • Sunahara S., Kawai K., Urano M. “Genetic Aspect of Isoniazid Metabolism, Part II: Mechanism of Species Difference in Acetylation”. Jpn. J. Human Genet. 1965; 10: 95–104
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  • Fellig J., Westheimer J., Walsh M. J., Marusich W. L. ldquo;Tissue Clearance of Rofenaid in Chickens and Turkeys”. Poult. Sci. 1971; 50: 1777–1783
  • Nakamura H., Yonesawa S., Azechi H., Futamiya K. ldquo;[Studies of the Distribution of Antibiotics within the Body. On the Changes in the Distribution of Crystalline Potassium Penicillin G and Dihydrostreptomycin Sulfate in Chickens Following Oral Administration]”. Dobutsu Igakuhia Kensaj 1967; 5: 131–137, in Japanese, NIH translation
  • Maccari M., Gatti M. T. ldquo;[Distribution and Elimination of Oxytetracycline in the Experimental Animal. (II) Tests on the Chicken]”. Boll. Soc. Ital. Biol. Sper. 1968; 44: 1069–1070, in Italian, NIH translation
  • Scott J. L. “The Metabolism of Injected Epinephrine-C14 Acetate by Leghorn Pullets”. Poult. Sci. 1967; 46: 512–517
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  • Rennick B. R., Pryor M. Z. ldquo;Effects of Autonomic Drugs on Renal Tubular Transport of Catecholamines in the Chicken”. J. Pharmacol. Exp. Ther. 1965; 148: 262–269
  • Quebbemann A. J., Rennick B. R. ldquo;Catechol Transport of the Renal Tubule in the Chicken”. Am. J. Physiol. 1968; 214: 1201–1204
  • Baggot J. D., Davis L. E. “The Pharmacokinetics of Amphetamine in Domestic Animals,”. Proceedings of the Conference on Research Animals in Medicine. Department of Health, Education and Welfare, Washington, DC 1972; 691–699
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  • Potter D. K., Fuller H. L. ldquo;Metabolic Fate of Dietary Tannins in Chickens”. J. Nutr. 1968; 96: 187–191
  • May D. G., Fujimoto J. M., Inturrisi C. E. “The Tubular Transport and Metabolism of Morphine-N-methyl-C14 by the Chicken Kidney”. J. Pharmacol. Exp. Ther. 1967; 157: 626–635
  • May D. G., Fujimoto J. M. “Mechanisms in the Renal Tubular Transport of Morphine and a Metabolite”. Proc. Int. Union Physiol. Sci. 1968; 7: 285
  • Fujimoto J. M., Haarstad V. B. ldquo;The Isolation of Morphine Ethereal Sulfate from Urine of the Chicken and Cat”. J. Pharmacol. Exp. Ther. 1969; 165: 45–51
  • Watrous W. M., May D. G., Fujimoto J. M. ldquo;Mechanisms of the Renal Tubular Transport of Morphine and Morphine Ethereal Sulfate in the Chicken”. J. Pharmacol. Exp. Ther. 1970; 172: 224–229
  • Watrous W. M., Fujimoto J. M. ldquo;Inhibition of Morphine Metabolism by Catechol in the Chicken Kidney”. Biochem. Pharmacol. 1971; 20: 1479–1491
  • Erne K., Sperber I. ldquo;Renal Tubular Transfer of Phenoxy-acetic Acids in the Chicken”. Acta Pharmacol. Toxicol. 1974; 35: 233–241
  • Fujimoto J. M. “Isolation of Two Different Glucuronide Metabolites of Naloxone from the Urine of Rabbit and Chicken”. J. Pharmacol. Exp. Ther. 1969; 168: 180–186
  • Chatterjie N., Inturrisi C. E., Fujimoto J. M., Roerig S. “Species Variation in the Stereochemistry of a Metabolite of Naltrexone,”. Pharmacologist 1974; 16(2)226
  • Chatterjie N., Fujimoto M. J., Inturrisi C. E., Roerig S., Wang R. I. H., Bowen D. V., Field F. H., Clarke D. D. ldquo;Isolation and Stereochemical Identification of a Metabolite of Naltrexone from Human Urine”. Drug Metab. Dispos. 1974; 2: 401–405
  • Lu T. C., Gosling J. A., Taylor D. G. ldquo;In vivo Studies on the Uptake of Tritium Labeled Decamethonium in the Chicken CNS”. Eur. J. Pharmacol. 1968; 3: 364–365
  • Dialameh G. H., Taggart W. V., Matschiner J. T., Olson R. E. ldquo;Isolation and Characterization of Menaquinone-4 as a Product of Menadione Metabolism in Chicks and Rats”. Int. J. Vit. Nutr. 1971; 41: 391–400
  • Nachtomi E., Alumot E. ldquo;Comparison of Ethylene Dibromide and Carbon Tetrachloride Toxicity in Rats and Chicks; Blood and Liver Levels; Lipid Peroxidation”. Exp. Mol. Pathol. 1972; 16: 71–78
  • Nachtomi E. ldquo;Effect of Ethylene Dibromide and Carbon Tetrachloride on Lipid Peroxidation in Rat and Chick Liver”. Exp. Mol. Pathol. 1972; 17: 171–175
  • Narashimhan T. R., Nair S. G. “Comparative Activity of Some Liver Enzymes of Ducks and Chicken, and the Effects of Hepatotoxicity Induced by CCl4 on the Levels of a Few of Them”. Indian J. Anim. Sci. 1974; 44: 53–59
  • Olney C. E., Donaldson W. E., Kerr T. W. ldquo;Methoxy-chlor in Eggs and Chicken Tissues”. J. Econ. Entomol. 1962; 55: 477–479
  • Thompson E. M., Mountney G. J., Ware G. W. ldquo;Meth-oxychlor Residues in Chicken Eggs”. J. Econ. Entomol. 1967; 60: 235–237
  • Erne K. ldquo;Distribution and Elimination of Chlorinated Phenoxy-acetic Acids in Animals”. Acta Vet. Scand. 1966; 7: 1–17
  • Whitacre D. M., Ware G. W. ldquo;Retention of Vaporized Lindane by Plants and Animals”. J. Agric., Food Chem. 1967; 15: 492–496
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  • Peoples S. A., Westberg G. L. “The Selective Nephrotoxicity of 3-Chloro-p-toluidine (CPT) and 2-Chloro-4-Acetotoluidine (CAT) is due to a Difference in the Metabolic Handling of Both Compounds by the Two Species”. Fed. Pro. 1975; 34: 227
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