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Drug Metabolism Reviews Volume 7, 1978 - Issue 1
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Research Article

Drug Metabolism in Birds: Part 2

Huo Ping Pan Denver Wildlife Research Center U.S. Fish and Wildlife Service Denver, Colorado, 80225
&
James r. Fouts National Institute of Environmental Health Sciences National Institutes of Health Research Triangle Park, North Carolina, 27709
Pages 141-253 | Published online: 22 Sep 2008

References

  • Committee on Problems of Drug Safety of the Drug Research Board, National Academy of Sciences, National Research Council. Application of Metabolic Data in the Investigation of New Drugs. Clin. Pharmacol. Ther. 1969; 10: 607–634
  • Williams R. T. ldquo;The Metabolism of Certain Drugs and Food Chemicals in Man”. Ann. N. Y. Acad. Sci. 1971; 179: 141–154
  • Avian Biology, D. S. Farner, J. R. King, K. C. Parkes. Academic, New York 1971; Vol. 1: xiii
  • Dustman E. H., Stickel L. F. ldquo;The Occurrence and Significance of Pesticide Residues in Wild Animals”. Ann. N. Y. Acad. Sci. 1969; 160: 162–172
  • The Problems of Birds as Pests, R. K. Murton, E. N. Wright. Academic, Londo 1968; 554
  • O'Brien R. D. ldquo;Selective Toxicity of Insecticides”. Adv. Pest Control Res. 1961; 4: 75–113
  • Albert A. Selective Toxicity, 4th ed. Methuen, London 1968; 531
  • Vesell E. S. “Drug Metabolism in Man”. Ann. N. Y. Acad. Sci. 1971; 179: 773
  • Hathway D. E., Brown S. S., Chasseaud L. F., Hutson D. H. Foreign Compound Metabolism in Mammals. Chemical Society, London 1970; Vol. 1
  • Hathway D. E., Brown S. S., Chasseaud L. F., Hutson D. H., Moore D. H., Sword I. P., Welling P. G. Foreign Compound Metabolism in Mammals. Chemical Society, London 1972; Vol. 2
  • Wilkinson C. F., Brattsten L. B. ldquo;Microsomal Drug Metabolizing Enzymes in Insects”. Drug Me tab. Rev. 1972; 1: 153–228
  • Terriere L. C. “Insecticide Cytoplasmic Interactions in Insects and Vertebrates”. Ann. Rev. Entomol. 1968; 13: 75–98
  • Williams R. T. Detoxication Mechanisms, 2nd ed. Wiley, New York 1959
  • Williams R. T. “The Biogenesis of Conjugation and Detoxication Products”, in Biogenesis of Natural Compounds, P. Bern-Feld. Macmillan, New York 1963; 427–474
  • Brodie B. B., Maickel R. P. Comparative Biochemistry of Drug Metabolism. Proceedings of the First International Pharmacological Meetingr Stockholm, B. B. Brodie, E. G. Erdos. Pergamon, New York 1962; Vol. 6: 299–324
  • Brown G. W., Jr. “Nitrogen Metabolism of Birds”. Comparative Biochemistry of Nitrogen Metabolism, J. W. Campbell. Academic. 1970; Vol. 2: 711–793
  • Menzie C. M. Metabolism of Pesticides, Special Scientific. Report-Wildlife No. 96, Fish and Wildlife Service, U.S. Department of the Interior, Washington, DC 1966
  • Menzie C. M. Metabolism of Pesticides, Special Scientific. Report-Wildlife No. 127, Fish and Wildlife Service, U.S. Department of the Interior, Washington, DC 1969
  • Menzie C. M. Metabolism of Pesticides an Update, Special Scientific. Report-Wildlife No. 184, Fish and Wildlife Service, U.S. Department of the Interior, Washington, DC 1974
  • Verbiscar A. J. Metabolism of Foreign Compounds: An Annotated Bibliography. Oak Ridge National Laboratory, Oak Ridge, Tennessee June, September, October, December, March, June, 1972, 6 issues, 1973
  • Wit J. G. Metabolism of Foreign Compounds by Different Classes of Birds. Proceedings of the 15th International Ornithological Congress, The Hague, The Netherlands, K. H. Voous. Brill, Leiden 1972; 466–474
  • Grzimek's Animal Life Encyclopedia, English ed., B. Grzimek. Van Nostrand Reinhold, New York 1973; 523–561, Bird I (Vol. 7), pp. 496–513; Bird II (Vol. 8), pp. 49–511; Bird HI (Vol. 9)
  • Wit J. G., Snel J. “Enzymatic Glutathione Conjugations with 2,3-Epoxyphenylpropylether and Diethylmaleate by Wild Bird Liver Supernatant”. Eur. J. Pharmacol. 1968; 3: 370–373
  • Wit J. G. ldquo;Conjugations with Glutathione. Distribution of Glutathione S-Aryltransferase in Wild Birds”. Eur. J. Pharmacol. 1968; 5: 100–102
  • Baldwin B. C., Robinson D., Williams R. T. “Studies in Detoxication, 82. The Fate of Benzoic Acid in Some Domestic and Other Birds”. Biochem. J. 1960; 76: 595–600
  • Yoshikawa J. ldquo;tiber das Verhalten der Benzoesaure im Organismus des Huhns bei gleichzeitiger Zufuhr des Glykokolls”. Hoppe-Seyler's Z. Physiol. Chem. 1910; 68: 79–82
  • Bartlet A. L., Kirinya L. M. “Activities of Mixed-Function Oxidases, UDP-Glucuronyl Transferase and Sulphate Conjugation Enzymes in Galliformes and Anseriformes”. Q. J. Exp. Physiol. 1976; 61: 105–119
  • Chhabra R. J., Fouts J. R. ldquo;Biochemical Properties of Some Microsomal Xenobiotic-Metabolizing Enzymes in Rabbit Small Intestine”. Drug Metab. Dispos. 1976; 4: 208–214
  • Campbell T. C., Hayes J. R. ldquo;The Role of Aflatoxin Metabolism in Its Toxic Lesion”. Toxicol. Appl. Pharmacol. 1976; 35: 199–222
  • Wong J. J., Hsieh D. P. H. ldquo;Mutagenicity of Aflatoxins Related to Their Metabolism and Carcinogenic Potential”. Proc. Natl. Acad. Sci. U. S. A. 1976; 7: 2241–2244
  • Longcore J. R., Locke L. N., Bagley G. E., Andrews R. “Significance of lead residues in mallard tissues,”. Special Scientific Report-Wildlife No. 182, U. S. Government Printing Office, Washington, D C 1972; 24
  • Rozman R. S., Locke L. N., MeClure S. F.HI. “Enzyme Changes in Mallard Ducks Fed Iron or Lead Shot”. Avian Pis. 1974; 18: 435–445
  • Fowler J. S. L. ldquo;Chlorinated Hydrocarbon Toxicity in the Fowl and Duck”. J. Comp. Pathol. 1970; 80: 465–471
  • Patterson D. S. P., Roberts B. A., Allcroft R. ldquo;Aflatoxin Metabolism”. Food Cosmet. Toxicol. 1969; 7: 277–279
  • Patterson D. S. P., Allcroft R. ldquo;Metabolism of Aflatoxin in Susceptible and Resistant Animal Species”. Food Cosmet. Toxicol. 1970; 8: 43–53
  • Patterson D. S. P., Roberts B. A. “The Composition of Liver Microsomes and Levels of Detoxicating Enzymes in 9 Animal Species,”. Res. Vet. Sci. 1970; 2: 399–401
  • Patterson D. S. P., Roberts B. A. “The Formation of Aflatoxins B2a and G2a and Their Degradation Products during the in vitro Detoxification of Aflatoxin by Livers of Certain Avian and Mammalian Species”. Food Cosmet. Toxicol. 1970; 8: 527–538
  • Patterson D. S. P., Roberts B. A. “The in vitro Reduction of Aflatoxins B, and B2 by Soluble Avian Liver Enzymes”. Food Cosmet. Toxicol. 1971; 9: 829–837
  • Patterson D. S. P., Roberts B. A. “Steroid Sex Hormones as Inhibitors of Aflatoxin Metabolism in Liver Homogenates,”. Experientia 1972; 28: 929–930
  • Patterson D. S. P., Roberts B. A. ldquo;Aflatoxin Metabolism in Duck-Liver Homogenates: The Relative Importance of Reversible Cyclopentenone Reduction and Hemiacetal Formation”. Food Cosmet. Toxicol. 1972; 10: 501–512
  • Fouts J. R. “Liver Smooth Endoplasmic Reticulum ‘Microsomal’ Drug Metabolizing Enzyme System,”. Methods in Pharmacology, A. Schwartz. Meredith, Des Moines, Iowa 1971; Vol. 1: 287–325
  • Patterson D. S. P. “Metabolism as a Factor in Determining the Toxic Action of the Aflatoxins in Different Animal Species”. Food Cosmet. Toxicol. 1973; 11: 287–294
  • Bassir O., Emafo P. O. “Species Differences in the in vitro Metabolism of Aflatoxin B”. FEBS Lett. 1971; 12: 273–275
  • Johnson R. E., Dahm P. A. “Activation and Degradation Efficiencies of Liver Microsomes from Eight Vertebrate Species, Using Organophosphates as Substrates”. J. Econ. Entomol. 1966; 59: 1437–1442
  • Krieger R. I., Wilkinson C. F. “The Metabolism of 6,7-Dihydroisodrin by Microsomes and Southern Armyworm Larvae”. Pest. Biochem. Physiol. 1971; 1: 92–100
  • Wit J. G. ldquo;Drug Enzymes in Kestrel Liver”. Comp. Biochem. Physiol. 1969; 30: 185–186
  • Walker C. H., El-Zorgani G. A., Kenny J. “Radiotracer-Aided Studies on the Comparative Metabolism of Dieldrin Analogues by Vertebrates,”. Isotope Tracer Studies of Chemical Residues in Food and the Agricultural Environment, Proc. Report Res. Coord. Meet. Ispra, Italy 1972; 65–66
  • Ivie G. W., Dorough H. W., Bryant H. E. ldquo;Fate of Mi-rex- C in Japanese Quail”. Bull. Environ. Contam. Toxicol. 1974; 11: 129–135
  • White I. N. H., Mattocks A. R., Butler W. H. ldquo;The Conversion of the Pyrrolizidine Alkaloid Retrorsine to Pyr-rolic Derivatives in vivo and in vitro and Its Acute Toxicity to Various Animal Species”. Chem.-Biol. Interact. 1973; 6: 207–218
  • Leeuwangh P. “Limitations in the Use of Enzyme Induction as a Parameter for the Assessment of Environmental Effects of Pesticides,”. Side-Effects of Persistent Pesticides and other Chemicals on Birds and Mammals in the Netherlands, J. J. Kolman. TNO-Nieus. 1972; 27: 611–615
  • Bäckström J. ldquo;Distribution Studies of Mercuric Pesticides in Quail and Some Fresh Water Fishes”. Acta Pharmacol. Toxicol. 1969; 27: 1–102
  • Nishimura M., Urakawa N., Ikeda M. “An Autoradiographic Study on the Distribution of Mercury and Its Transfer to the Egg in the Laying Quail”. Jpn. J. Pharmacol. 1971; 21(1)651–659
  • Bagley G. E., Cromartie E. ldquo;Elimination Pattern of Aroclor 1254 Components in the Bobwhite”. J. Chromatogr. 1973; 75: 219–226
  • Law G. L., Mansfield G. P., Muggleton D. F., Parnell E. W. “Dimetridazole: Absorption, Excretion and Metabolism in Turkeys”. Natur. 1963; 197: 1024–1025
  • Rosenblum C., Trenner N. R., Buhs R. P., Hiremath C. B., Koniuszy F. R., Wolf D. E. ldquo;Metabolism of Ronidazole (1-Methyl-5-nitroimidazol-2-ylmethyl Carbamate)”. J. Agric. Food Chem. 1972; 20: 360–371
  • Wiese I. H., Basson N. C. J., Van der Vyver J. H., Van der Merwe J. H. “Toxicology and Dynamics of Dieldrin in the Crowned Guinea Fowl Numida meleagris (L). Phyto-phylactic. 1969; 1: 161–176
  • Meissner G. ldquo;Beiträge zur Kenntniss des Stoffwechsels in thierischen Organismus. IV. Ueber das Verhalten der Benzoesäure in Organismus der Hühner (nach Untersuchungen von C. U. Shepard aus New-Haven)”. Henle-Pfeuffer's Zeit. rat. Med., 3rd Serie. 1868; 31: 216–223
  • Jaffe M. ldquo;Ueber das Verhalten der Benzosäure im Organismus der Vögel”. Ber. Dtsch. Chem. Ges. 1887; 10: 1925–1930
  • Nesheim M. C., Garlich J. D. ldquo;Studies on Ornithine Synthesis in Relation to Benzoic Acid Excretion in the Domestic Fowl”. J. Nutr. 1963; 79: 311–317
  • Bridges J. W., French M. R., Smith R. L., Williams R. T. ldquo;The Fate of Benzoic Acid in Various Species”. Biochem. J. 1970; 118: 47–51
  • Takahashi M. ldquo;Über den Entgiftungsvorgang in Fötalorganismus. II. Synthese der Ornithursäure im bebrüteten Hühnerei bei der Einspritzung von Benzoesäure”. Hoppe-Seyler's Z. Physiol. Chem. 1928; 178: 294–297
  • Takahashi M. ldquo;Über den Entgiftungsvorgang im Fötalorganismus”. Hoppe-Seyler's Z. Physiol. Chem. 1928; 178: 291–293
  • McGilvery R. W., Cohen P. P. “Enzymatic Synthesis of Ornithuric Acids”. J. Biol. Chem. 1950; 183: 179–189
  • Ye F. Yefimochkina. “[Biological Synthesis of 4,4′-Di-aminoornithuric Acid and 4,4′-Diaminolysuric Acids]”. Dokl. Acad. Nauk SSS. 1951; 80: 793–796, in Russian, NIH translation
  • Wolfe H. J., Huang K. C. “The conjugation of the Aminobenzoic Acid Isomers in the Adult and Embryonic Gallus Domesticus”. J. Cell. Comp. Physiol. 1959; 54: 243–249
  • Abou-El-Makaren M. M., Millburn P., Smith R. L., Williams R. T. ldquo;Biliary Excretion of Foreign Compounds”. Biochem. J. 1967; 105: 1289–1293
  • Sperber I. “The Mechanism of Renal Excretion of Some ‘Detoxication Products’ in the Chicken”. Commun. 17th Int. Physiol. Congr. 1947, Abstr.
  • Sperber I. ldquo;Some Experiments on the Formation of Glucuronic Acid Derivatives in the Chicken”. Ann. R. Agric. Coll. Swede. 1947; 15: 108–112
  • Sperber I. ldquo;The Excretion of Some Glucuronic Acid Derivatives and Phenol Sulphuric Esters in the Chicken”. Ann. R. Agric. Coll. Swede. 1948; 15: 317–349
  • Sperber I. “The Excretion of Piperidine, Guanidine, Methyl-guanidine and N-Methylnicotinamide in the Chicken”. Ann. R. Agric. Coll. Swede. 1948; 16: 49–64
  • Sperber I. “The Formation of Sulphuric Esters of Phenols in the Chicken”. Ann. R. Agric. Coll. Swede. 1949; 16: 446–456
  • Baldwin B. C., Robinson D., Williams R. T. “Glucuronide Formation in Hens”. Biochem. J. 1958; 68: 22P–23P
  • Capel I. D., French M. R., Millburn P., Smith R. L., Williams R. T. “The Fate of [14C]Phenol in Various Species”. Xenobiotica 1972; 2: 25–34
  • Capel J. D., Millburn P., Williams R. T. ldquo;Route of Administration and the Conjugation of Phenol in Hens”. Biochem. Soc. Trans. 1974; 2: 875–877
  • Baldwin B. C., Robinson R., Williams R. T. “Studies in Detoxication, 78. Glucuronide and Ethereal Sulphate Formation in Hens”. Biochem. J. 1959; 71: 638–642
  • Quebbemann A. J., Anders M. W. ldquo;Renal Tubular Conjugation and Excretion of Phenol and p-Nitrophenol in the Chicken: Differing Mechanisms of Renal Transfer”. J. Pharmacol. Exp. Ther. 1973; 184: 695–708
  • Litchfield L. T., Jr. “The Effects of Sulfanilamide on the Lower Vertebrates”. J. Pharmacol. Exp. Ther. 1939; 67: 213–223
  • Shaffer J. M., Bieter R. N. ldquo;Conversion of Acetylsul-fonamides to the Unconjugated Form by the Chicken Kidney”. J. Pharmacol. Exp. Ther. 1950; 100: 192–200
  • Adamson R. H., Bridges J. W., Kibby M. R., Walker S. R., Williams R. T. ldquo;The Fate of Sulfadimethoxine in Primates Compared with Other Species”. Biochem. J. 1970; 118: 41–45
  • Simunek J., Hegerová E. ldquo;[Sulfonamide Blood Levels in Chickens of Different Ages after Different Modes of Administration of Na-Sulfadimidine]”. Cesk, Fysiol. 1971; 20: 175–176, in Czechoslovak, NIH translation
  • Blom L. ldquo;Plasma Half-Lives and the Excretion into Egg-White and -Yolk of Three Sulphonamides and Pyrimethamine after Medication of Laying Hens”. Acta Pharmacol. Toxicol. 1975; 37: 79–93
  • Hopwood M. L., Karg H., Gassner F. X. “Conjugation of C14 -Diethylstilbestrol by Chicken Liver in vitro”. Proc. Soc. Exp. Biol. Med. 1963; 113: 233–238
  • Smith G. N., Thiegs B. J., Ludwig P. D. “The Metabolism o. 3, 5-Dinitro-o-toluamide- 14C (Zoalene) in Chickens”. J. Agric. Food Chem. 1963; 11: 247–251
  • Smith G. N., Thiegs B. J., Ludwig P. D. “The Isolation and Identification of the Amino-nitro-o-toluamide Formed by the Biological Reduction o. 3, 5-Dinitro-o-toluamide”. J. Agric. Food Chem. 1963; 11: 257–260
  • 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
  • Smith G. N. The Metabolism o. 3, 5-Dinitro-o-toluamide”. in Proceedings of the 18th International Congress on Pure and Applied Chemistry. 1961; 251–252, Abstracts
  • Smith G. N. “Pathways for the Metabolism o. 3, 5-Dinitro-o-toluamide (Zoalene) in Chickens”. Anal. Biochem. 1964; 7: 461–471
  • Overby J. R., Fredericken R. L. ldquo;Metabolism of Arsanilic Acid”. Toxicol. Appl. Pharmacol. 1965; 7: 855–867
  • Moody J. P., Williams R. T. ldquo;The Fate of Arsanilic Acid and Acetylarsanilic Acid in Hens”. Food Cosmet. Toxicol. 1964; 2: 687–693
  • 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
  • Buttram J. R. “Metabolism of Carbamate and Organophos-phate Insecticides by Cattle and Poultry and Associated Residues in Livestock Products”. Ph. D. Dissertation, University Microfilm, Ann Arbor, Michigan 1964; 26: 4319, Auburn University; Diss. Abstr.
  • Buns R. P., Polin D., Beattie J. O., Beck J. L., Smith J. L., Speth O. C., Trenner N. R. ldquo;The Metabolism of Ethopabate in Chickens”. J. Pharmacol. Exp. Ther. 1966; 154: 357–363
  • Cox P. O., Hollifield R. D., Heotis J. P. ldquo;The Spec-trophotofluorometric Determination of Buquinolate in Poultry Tissue and Eggs”. Poult. Sci. 1967; 46: 680–686
  • Herrett R. J., Williams C. W., Klein G. M., Heotis J. P. “The Distribution of C14 in the Chick Following the Administration of Buquinolate-3-C14”. Poult. Sci. 1967; 3: 755–761
  • Polin D., Herrett R. J., Williams C. W., Cox P. L., Heotis J. P. “Buquinolate Excretion in Growing Chickens Fed Buquinolate-3-14C”. Poult. Sci. 1969; 48: 1859
  • 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
  • Button R. G., Muggleton D. F., Parnell E. W. ldquo;Decoquinate. II. Absorption and Residue Studies in Chickens”. J. Sci. FoodAgric. 1969; 20: 70–73
  • 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
  • Kouba R. F., Craine E. M., Ray W. H. ldquo;Presence of Residues in Eggs Laid by Chickens Receiving Decoquinate”. J. Agric. Food Chem. 1972; 20: 589–592
  • Komai T., Nambu K., Shindo H. “Metabolic Fate and Mechanism of Action of Chloroethylthiamine, IV. Urinary Metabolite of 35S-Chloroethylthiamine”. J. Vitaminol. 1972; 18: 102–111
  • Rogers E. F. “Modified Thiamines,”. The Vitamins, Chemistry, Physiology, Pathology, Methods, 2nd ed. Academic, New York 1972; Vol. 5: 133
  • Thomas J. M., Nakaue H. S., Reid B. L. ldquo;Effect of Acetylsalicylic Acid and Some Chemical Analogs on Chick Growth and Selected Biochemical Parameters”. Poult. Sci. 1967; 46: 1216–1219
  • 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
  • Davison C., Williams R. T. “The Metabolism o. 5, 5′-Methylene-disalicylic Acid in Various Species”. J. Pharm. Pharmacol. 1968; 20: 12–18
  • Smith G. N. “The Metabolism of 36Cl-clopicol (3, 5-Di-chloro-2, 6-dimethyl-4-pyridinol) in Chickens”. Poult. Sci. 1969; 48: 420–436
  • Tominaga F., Tsubota Y., Iida T. ldquo;The Metabolism of Dimethialium in Chickens and Rats”. J. Takeda Res. Lab. 1970; 29: 470–477
  • Fischer V. W., Fitch C. D. ldquo;Affinity of Chloroquine for Bone”. J. Pharm. Pharmacol. 1975; 27: 527–529
  • Rash J. J., Lynch M. J. “Metabolism of 2-[3-Chloro-4-(4-chloro-benzoyl)pheny1]-as-triazine-3, 5-(2H,4H)-dione by the Chicken”. Drug Metab. Dispos. 1976; 4: 59–64
  • 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
  • Dabija G., Anghel V., Feteanu A., Nemteanu S. “Absorption, diffusion, persistence et elimination de la Sulfadiazine marquee au 35S chez le lapin et la poulet,”. Arch. Vet. 1967; 3: 193–202
  • 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
  • Rennick B., Yoss N. “Renal Tubular Excretion of Dl-Epinephrine-2-C14 in the Chicken”. J. Pharmacol. Exp. Ther. 1962; 138: 347–350
  • 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
  • Baggot J. D., Davis L. E. ldquo;A Comparative Study of the Pharmacokinetics of Amphetamine”. Res. Vet. Sci. 1973; 14: 207–215
  • 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
  • Koeman J. H., Oudejans R. H. M., Huisman E. A. ldquo;Danger of Chlorinated Hydrocarbon Insecticides in Birds' Eggs”. Natur. 1967; 215: 1094–1096
  • Cummings J. G., Zee K. T., Turner V., Quinn F., Cook R. E. ldquo;Residues in Eggs from Low Level Feeding of Five Chlorinated Hydrocarbon Insecticides to Hens”. J. Assoc. Off. Anal. Chem. 1966; 49: 354–364
  • Getzendaner M. E. ldquo;Study of Residues of Dalapon in Chicken Tissues and Eggs Following Repeated Feeding”. J. Agric. Food Chem. 1968; 16: 856–862
  • McCully K. A., McKinley W. P., Phillips W. E. J. “The Effect of the Route of Administration of Single Doses of p, p'-DDT on Residues in Adipose and Liver Tissues”. J. Assoc. Off. Anal. Chem. 1968; 51: 1050–1057
  • Abou-Donia M. B., Menzel D. B. “The Metabolism in vivo of 1,1, l-Trichloro-2,2-bis(p-chlorophenyl)ethane (DDT., 1, 1-Dichloro-2-2-bis(p-chlorophenyl)ethane (DDD), and 1,1-Dichloro-2, 2-bis(p-chlorophenyl)ethylene (DDE) in the Chick by Embryonic Injection and Dietary Ingestion”. Biochem. Pharmacol. 1968; 17: 2143–2161
  • Abou-Donia M. B. “DDT and Related Chlorinated Hydrocarbons: Their Metabolism in the Chick and Their Induction of Microsomal Enzymes”. Ph.D. Dissertation, University of California, Berkeley 1967
  • Bitman J., Cecil H. C., Fries G. F. “Nonconversion of o,p′-DDT to p,p′-DDT in Rats, Sheep, Chickens, and Quail”. Scienc. 1971; 174: 64–66
  • Ecobichon D. J., Saschenbrecker P. W. ldquo;Pharmacodynamic Study of DDT in Cockerels”. Can. J. Physiol. Pharmacol. 1968; 46: 785–794
  • Feil V. J., Lamoureux C. H., Zaylskie R. G. “Metabolism of o, p'-DDT in Chickens”. J. Agric. Food Chem. 1975; 23: 382–388
  • Wright F. C., Riner J. C., Younger R. L. ldquo;Residues in Chickens Given DDT”. J. Agric. Food Chem. 1972; 20: 17–19
  • Rao S. L. N., McKinley W. P. ldquo;Metabolism of Organophosphorous Insecticides by Liver Homogenates from Different Species”. Can J. Biochem. 1969; 47: 1155–1159
  • Paulson G. D., Feil V. J. ldquo;The Fate of a Single Oral Dose of Carbaryl (1-Naphthyl N-methylcarbamate) in the Chicken”. Poult. Sci. 1969; 48: 1593–1597
  • Paulson G. D., Feil V. J., Zaylskie R. G., Portnoy C. E., Zehr M. V. “Isolation and Identification of Metabolites of Carbaryl (1-Naphthyl N-Methylcarbamate) in Chicken Urine,”. 158th Am. Chem. Soc. Meet., Div. Pest. Chem. 1969, Abstr. #34
  • Paulson G. D., Zaylskie R. G., Zehr M. V., Portnoy C. E., Feil V. J. “Metabolies of Carbaryl (1-Naphthyl Methyl-carbamate) in Chicken Urine,”. J. Agric. Food Chem. 1970; 18: 110–115
  • Andrawes N. R., Chancey E. L., Crabtree R. J., Herrett R. A., Weiden M. H. J. “Fate of Naphthyl-1-14C Carbaryl in Laying Chickens,”. J. Agric. Food Chem. 1972; 20: 608–617
  • Casida J. E., Augustinsson B. K.-. ldquo;Reaction of Plasma Albumin with 1-Naphthyl-N-methylcarbamabe and Certain Other Esters”. Biochim. Biophys. Act. 1959; 36: 411–426
  • Hicks B. W., Dorough H. W., Davis R. B. ldquo;Fate of Carbofuran in Laying Hens”. J. Econ. Entomol. 1970; 63: 1108–1111
  • Paulson G. D., Zehr M. V., Dockter M. M. “Metabolism of Propham (Isopropyl N-Phenylcarbamate) in the Chicken,”. N. Dak. Acad. Sci. Pro. 1971; 25: 22
  • Paulson G. D., Dockter M. M., Jacobsen A. M., Zaylskie R. G. ldquo;Isopropyl Carbanilate (Propham) Metabolism in the Chicken: Balance Studies and Isolation and Identification of Excreted Metabolites”. J. Agric. Food Chem. 1972; 20: 867–876
  • Paulson G. D., Zehr M. V. ldquo;Metabolism of p-Chloro-phenyl N-Methylcarbamate in the Chicken”. J. Agric. Food Chem. 1971; 19: 471–474
  • Hicks B. W., Dorough H. W., Mehendale H. M. ldquo;Metabolism of Aldicarb Pesticide in Laying Hens”. J. Agric. Food Chem. 1972; 20: 151–156
  • Guthrie F. E., Donaldson W. E. ldquo;Distribution of DDT and Dieldrin in the Avian Embryo”. Toxicol. Appl. Pharmacol. 1970; 16: 475–481
  • Davison K. L. “Dieldrin-14C Balance in Rats, Sheep and Chickens”. Bull. Environ. Contain. Toxicol. 1973; 10: 16–23
  • Westberg G. L. “Comparative Studies of the Metabolism of 3-Chloro-p-toluidine and 2-Chloro-4-acetotoluidine in Rats and Chickens and Methodology for the Determination of 3-Chloro-p-toluidine and Metabolites in Animal Tissues,”. University of California, Davis 1974; 59, M.S. Dissertation
  • 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
  • Jaffé M., Cohn R. ldquo;Ueber das Verhalten des Furfurols im Stoffwechsel der Huhner”. Ber. Dtsch. Chem. Ges. 1888; 21: 3461–3465
  • Dannand W. J., Huff J. W. ldquo;Dinicotinylornithine: A Metabolite of Nicotinamide in the Chicken”. J. Biol. Chem. 1947; 168: 121–127
  • Chang M. L. W., Johnson B. C. “Nicotinic Acid Metabolism. III. C14-Carboxyl-Labeled Nicotinamide and Nicotinic Acid in the Chick”. J. Biol. Chem. 1957; 226: 799–804
  • Cayen M. N., Carter A. L., Common R. H. ldquo;The Conversion of Genistein to Equol in the Fowl”. Biochim. Biophys. Act. 1964; 86: 56–64
  • Tang G., Common R. H. ldquo;Urinary Conversion Products of Certain Orally Administered Isoflavones in the Fowl”. Biochim. Biophys. Act. 1968; 158: 402–413
  • Chang H. H., Robinson A. R., Common R. H. ldquo;Excretion of Radioactive Daidzein and Equol as Monosulfates and Disulfates in the Urine of the Laying Hen”. Can. J. Biochem. 1975; 53: 223–230
  • Lyman C. M., Cronin J. T., Trant M. M., Odell G. V. “Metabolism of Gossypol in the Chick,”. J. Am. Oil Chem. Soc. 1969; 46: 100–104
  • Abou-Donia M. B., Lyman C. M. “Metabolic Fate of Gossypol: The Metabolism of Gossypol-14C in Laying Hens”. Toxicol. Appl. Pharmacol. 1970; 17: 160–173
  • Mabee M. S., Chipley J. R. “Tissue Distribution and Metabolism of Aflatoxin B1,-14c in Layer Chickens”. J. Food Sci. 1973; 38: 566–570
  • Van Zytveld W. A., Kelley D. C., Dennis S. M. ldquo;Afla-toxicosis: The Presence of Aflatoxins or Their Metabolites in Livers and Skeletal Muscles of Chicks”. Poult. Sci. 1970; 49: 1350–1356
  • Mabee M. S., Chipley J. R. “Tissue Distribution and Metabolism of Aflatoxin B,-14C in Broiler Chickens”. Appl. Microbiol. 1973; 25: 763–769
  • Chipley J. R., Mabee M. S., Applegate K. L., Dreyfus M. S. “Further Characterization of Tissue Distribution and Metabolism of [14C]Aflatoxin B, in Chickens”. Appl. Microbiol. 1974; 28: 1027–1029
  • Masri M. S., Booth A. N., Hsieh D. P. H. “Comparative Metabolic Conversion of Aflatoxin B, to M, and Q”. Life Sci. 1974; 15: 203–212
  • Harland E. C., Cardeilhac P. T. “Excretion of Carbon- 14-Labeled Aflatoxin B, via Bile, Urine, and Intestinal Contents of the Chicken”. Am. J. Vet. Res. 1975; 36: 909–912
  • Sawhney D. S., Vadehra D. V., Baker R. C. “The Metabolism of 14C Aflatoxins in Laying Hens”. Poult. Sci. 1973; 52: 1302–1304
  • Mathur R. S., Common R. H., Collins D. C., Layne D. S. ldquo;Steroid Estrogen Conjugates of Hen's Urine: Formation in vivo of Steroid Estrogen Monosulphates and Disulphates from Injected Estradiol-170”. Bioehim. Biophys. Act. 1969; 176: 394–402
  • Quamme G. A., Layne D. S., Williamson D. G. “Species Differences in the Formation in vitro of Estrogen Conjugates,”. Comp. Biochem. Physiol. 1971; 39B: 25–30
  • Hopwood M. L., Karg H., Gassner F. X. “Conjugation of C14-Diethylstilbestrol by Chicken Liver in vitro”. Proc. Soc. Exp. Biol. Med. 1963; 113: 233–238
  • Robinson A. R., Henneberry G. O., Common R. H. “Steroid Estrogen Conjugates of Hens' Urine: Identification of Radioactive Estron-β-glucuronide, Estradiol-17β-3-β-glu-curonide, Estradiol-17α-3-β-glucuronide, Estrone Sulphate, Estradiol-17β-3-sulphate and Estradiol-17α-3-sulphate, as Metabolites of Injected [14C]Estrone”. Bioehim. Biophys. Act. 1973; 326: 93–102
  • Hoshiai Z.-N. “Uber das Verhalten des Pyridins im Or-ganismus des Huhns”. Hoppe-Seyler's Z. Physiol. Chem. 1909; 62: 118–119
  • Totani G. “Uber das Verhalten der Phenylessigsaure im Or-ganismus des Huhns”. Hoppe-Seyler's Z. Physiol. Chem. 1910; 68: 75–78
  • James M. O., Smith R. L., Williams R. T., Reiden-Berg M. “The Conjugation of Phenylacetic Acid in Man, Sub-Hu-man Primates and Some Non-Primate Species,”. Proc. R. Soc. London 1972; B182: 25–35
  • Barbeau A., Inoue N., Tsukada Y., Butterworth R. F. ldquo;The Neuropharmacology of Taurine”. Life Sci. 1975; 17: 669–678, Minireview
  • Sherwin C. P., Helfand M. ldquo;Comparative Metabolism of Certain Aromatic Acids”. J. Biol. Chem. 1919; 40: 17–27
  • Sherwin C. P., Crowdle J. H. ldquo;Detoxication in the Organism of the Fowl”. Proc. Soc. Exp. Biol. Med. 1922; 19: 318–320
  • Crowdle J. H., Sherwin C. P. ldquo;The Chemical Defence Mechanism of the Fowl”. J. Biol. Chem. 1923; 55: 15–31
  • Sendju Y. ldquo;Über das Verhalten des α-Picolins und der α-Picolinsäure im Organismus verschiedener Tiere”. J. Biochem. (Tokyo. 1927; 7: 273–281
  • Fouts J. R., Kamm J. J., Brodie B. B. “Enzymatic Reduction of Prontosil and Other Azo Dyes”. J. Pharmacol. Exp. Ther. 1957; 120: 291–300
  • Mitoma C., Posner H. S., Leonard F. ldquo;Aromatization of Hexahydrobenzoic Acid by Mammalian Liver Mitochondria”. Biochim. Biophys. Act. 1958; 27: 156–160
  • Baldwin B. C., Robinson D., Williams R. T. ldquo;Studies in Detoxication. 83. The Aromatization of Cyclohexanecar-boxylic Acid in Hens”. Biochem. J. 1960; 76: 600–602
  • Parke D. V. “Studies in Detoxication. 84. The Metabolism of [14C]-Aniline in the Rabbit and Other Animals”. Biochem. J. 1960; 77: 493–502
  • Brauer R. W., Julian L. M., Krebs J. S. “Maturation of Liver Function in the Chick Embryo as Explored with S3S-Sulfobromophthalein-Vascular Factors, Bilary Secretion, and Conjugation,”. Ann. N. Y. Acad. Sci. 1963; 111: 135–156
  • Debackere M., Uehleke H. “C- and N-Hydroxylation of Aromatic Amines by Isolated Liver Microsomes of Different Species,”. in Proceedings of the European Society for the Study of Drug Toxicity, Amsterdam. Excerpta Medica, 1964; Vol. 4: 40–45
  • Creaven P. J., Parke D. V., Williams R. T. ldquo;A Fluori-metric Study of the Hydroxylation of Biphenyl in vitro by Liver Preparations of Various Species”. Biochem. J. 1965; 96: 879–885
  • Kealy R. D. “Studies on the Absorption, Metabolism, and Excretion of the Carbon-14 Labeled Tetrasodium Salt of Ethylenediaminetetraacetic Acid in Chicks,”. Ph. D. Dissertation, University of Arkansas. 1967
  • Machinist J. M., Dehner E. W., Ziegler D. M. ldquo;Microsomal Oxidases. HI. Comparison of Species and Organ Distribution of Dialkylarylamine-N-oxide Dealkylase and Di-alkylarylamine-N-oxidase”. Arch. Biochem. Biophys. 1968; 125: 858–864
  • Abou-Donia M. B., Menzel D. B. “Chick Microsomal Oxidases. Isolation, Properties, and Stimulation by Embryonic Exposure to 1,1, 1-Trichloro-2, 2-bis(p-chlorophenyl) ethane”. Biochemistr 1968; 7: 3788–3794
  • Rowels S. G., Born G. S., Christian J. E., Kessler W. V. “Metabolic Fate of 2,4, 5-Triiodobenzoic Acid in Laying Hens”. J. Pharm. Sci. 1970; 59: 257–259
  • Eto M., Abe M. ldquo;Metabolic Activation of Alkylphenyl Phosphates”. Biochem. Pharmacol. 1971; 20: 967–969
  • Eto M., Abe M., Takahara H. ldquo;Metabolism of Tri-p-ethylphenyl Phosphate and Neurotoxicity of the Metabolites”. Agric. Biol. Chem. Toky. 1971; 35: 929–940
  • Sharma R. P., Watanabe P. G. “Metabolism and Elimination of Tri-o-tolyl Phosphate (TOTP), a Neurotoxic Organo-phosphate in Chickens”. Toxicol. Appl. Pharmacol. 1973; 25: 483
  • Awensson R., Ulfvarson U. ldquo;Distribution and Excretion of Various Mercury Compounds after Single Injections in Poultry”. Acta Pharmacol. Toxicol. 1968; 26: 259–272
  • Kiwimaë A., Awensson R., Ulfvarson U., Westöö G. “Methylmercury Compounds in Eggs from Hens after Oral Administration of Mercury Compounds,”. J. Agric. Food Chem. 1969; 17: 1014–1016
  • Miller V. L., Larkin D. V., Bearse G. E., Hamilton C. M. “The Effects of Dosage and Adminiseration of Two Mercurials on Mercury Retention in Two Strains of Chickens”. Poult. Sci. 1967; 46: 142–146
  • Miller V. L., Bearse G. E., Russell T. S., Csonka E. ldquo;The Effect of Several Hormones and Sodium Thiomalate on Retention of Mercury by Two Strains of Chicks”. Poult. Sci. 1969; 48: 613–620
  • Vostal J., Heller J. “Renal Excretory Mechanisms of Heavy Metals, I. Transtubular Transport of Heavy Metal Ions in the Avian Kidney”. Environ. Res. 1968; 2: 1–10
  • Nimmo-Smith R. H. ldquo;Aromatic N-Deacylation by Chicken-Kidney Mitochondria”. Biochem. J. 1960; 75: 284–293
  • Brodie B. B., Axelrod J. ldquo;The Fate of Acetanilide in Man”. J.' Pharmacol. Exp. Ther. 1948; 94: 29–38
  • Dutton G. J. “Aspects of the Formation of ' Foreign1 Glu-curonides in Developing Tissues”. Biochem. J. 1961; 80: 2P
  • Dutton G. J., Ko V. “The Synthesis of o-Aminophenyl Glucuronide in Several Tissues of the Domestic Fowl, Gallus gallus, during Development”. Biochem. J. 1966; 99: 550–556
  • Dutton G. J. ldquo;Comparison of Glucuronide Synthesis in Developing Mammalian and Avian Liver”. Ann. N. Y. Acad. Sci. 1963; 111: 259–273
  • Ko V., Dutton G. J., Nemeth A. M. “Development of Uridine Diphosphate Glucuronyltransferase Activity in Cultures of Chick-Embryo Liver,”. Biochem. J. 1967; 104: 991–998
  • Skeaand B. R., Nemeth A. M. ldquo;Factors Influencing Premature Induction of UDP-Glucuronyltransferase Activity in Cultured Chick Embryo Liver Cells”. Proc. Natl. Acad. Sci. U. S. A. 1969; 64: 795–802
  • Dutton G. J. ldquo;Developmental Studies on Some Enzymes Associated with'Detoxication'”. Enzym. 1975; 15: 304–317
  • Dutton G. J. ldquo;Control of UDP-Glucuronyltransferase Activity”. Biochem Pharmacol 1975; 24: 1835–1841
  • Strittmatter C. F., Umberger F. T. ldquo;Oxidative Enzyme Components of Avian Liver Microsomes. Changes during Embryonic Development and the Effects of Phenobarbital Administration”. Biochim. Biophys. Act. 1969; 180: 18–27
  • Strittmatter C. F. ldquo;Differentiation of Electron Transport Systems in Mitochondria and Microsomes during Embryonic Development”. Arch. Biochem. Biophys. 1963; 102: 293–305
  • Roerig S., Fujimoto J. M., Wang R. I. H., Pollock S. H., Lange D. ldquo;Preliminary Characterization of Enzymes for Redution of Naloxone and Naltrexone in Rabbit and Chicken Liver”. Drug Metab. Dispos. 1976; 4: 53–58
  • Sperber I. “A New Method for the Study of Renal Tubular Excretion in Birds”. Natur. 1946; 158: 130
  • Mc J., Laughlin J., Marliac P., Verrett M. J., Mutchler K. M., Fitzhugh O. G. ldquo;The Injection of Chemicals into the Yolk Sac of Fertile Eggs Prior to Incubation as a Toxicity Test”. Toxicol. Appl. Pharmacol. 1963; 5: 760–771
  • Paulson G. D. “An Improved Method for Separate Collection of Urine, Feces, and Expiratory Gases from Mature Chicken,”. Poult. Sci. 1969; 48: 1331–1336
  • Sanderson D. M., Edson E. F. ldquo;Toxicological Properties of the Organophosphorus Insecticide Dimethoate”. Br. J. Ind. Med. 1964; 21: 52–64
  • Lamb D. W., Greichus Y. A., Linder R. L. “Distribution of Dieldrin- 14C in Pheasant Tissues after a Single Administration”. J. Agric. Food Chem. 1970; 18: 168–171
  • Fink C. P.-, Kerékjartó B. “Zur enzymatischen Hy-droxylierung von Cumarin, II. Die Mikrosomalen Reak-tionsprodukte bei verschiedenen Tierarten”. Hoppe-Seyler's Z. Physiol. Chem. 1966; 345: 272–279
  • Johnson W. J. ldquo;Biological Acetylation of Isoniazid”. Natur. 1954; 174: 744–745
  • Lipmann F. “Acetylation of Sulfanilamide by Liver Homogen-ates and Extracts”. J. Biol. Chem. 1945; 160: 173–179
  • Leibman K. C., Anaclerio A. M. “Comparative Studies on Sulfanilamide Acetylation: An Inhibitor in Dog Liver”. in Proceedings of the 1st International Pharmacological Meeting, B. Uvnäs. Macmillan, New York 1962; Vol. 6: 91–96
  • Benöhr H. C., Franz W., Krisch K. “Carboxylesterasen der Mikrosomenfraktion: Hydrolyse von Tributyrin, Procain und Phenacetin durch einige Organe und Lebermikrosomen verschiedener Tierarten”. Naunyn-Schmiedebergs Arch. Pharmakol. exp. Pathol. 1966; 255: 163–177
  • Goedde H. W., Schloot W., Valesky A. ldquo;Individual Different Response to Drugs: Characterization of an INH-Acetylating System in Rhesus Monkeys”. Biochem. Pharmacol. 1967; 16: 1793–1799
  • Ziemianski S. [Acetylation of Sulfonamides by Pigeon Liver Preparations].”. Acta Pol. Pharm. 1967; 24: 445–450, in Polish, NIH translation
  • Eyring E. J., Ford P. C. ldquo;Comparison of Acetylsalicylic Acid (Aspirin) Hydrolase Activities in Various Tissues of Several Species”. Comp. Biochem. Physiol. 1972; 43: 333–337
  • Robinson J., Richardson A., Brown V. K. H. ldquo;Biology: Pharmacodynamics of Dieldrin in Pigeons”. Natur. 1967; 213: 734–736
  • Hassal K. A. “Reductive Dechlorination of DDT: The Effect of Some Physical and Chemical Agents on DDD Production by Pigeon Liver Preparations”. Pest. Biochem. Physiol. 1971; 1: 259–266
  • Walker C. H., El Zorgani G. A. ldquo;Metabolism of a Dieldrin Analogue–Secondary Oxidation by Liver Microsomes”. Life Sci. 1973; 13: 585–593
  • Runnels J. M., Khan M. A. Q. ldquo;Hepatic Mixed-Function Oxidase Activity Towards Cyclodiene Insecticides in the Domestic Pigeon”. Am. Zool. 1973; 13: 1308–1309
  • Runnels J. M., Khan M. A. Q. “Characteristics of the Hepatic Mixed-Function Oxidase of the Pigeon, Columba livia”. Gen. Pharmacol. 1975; 6: 97–103
  • Pohl R. J., Bend J. R., Guarino A. M., Fouts J. R. “Hepatic Microsomal Mixed-Function Oxidase Activity of Several Marine Species from Coastal Maine”. Drug Metab. Dispos. 1974; 2: 545–555
  • Hassal K. A., Manning D. ldquo;Anaerobic Metabolism of DDT Analogs by Pigeon Liver Preparations”. Pest. Biochem. Physiol. 1972; 2: 331–336
  • Walker C. H. ldquo;Reductive Dechlorination of p.p'-DDT by Pigeon Liver Microsomes”. Life Sci. 1969; 8: 1111–1115
  • DeFreitas A. S., Norstrom R. J. ldquo;Turnover and Metabolism of Polychlorinated Biphenyls in Relation to Their Chemical Structure and the Movement of Lipids in the Pigeon”. Can. J. Physiol. Pharmacol. 1974; 52: 1080–1094
  • Bailey S., Bunyan P. J. ldquo;Interpretation of Persistence and Effects of Polychlorinated Biphenyls in Birds”. Natur. 1972; 236: 34–36
  • Hutzinger O., Nash D. M., Safe S., DeFreitas A. S. W., Norstrom R. J., Wildish D. J., Zitko V. “Polychlorinated Biphenyls: Metabolic Behavior of Pure Isomers in Pigeons, Rats, and Brook Trout”. Scienc. 1972; 178: 312–314
  • Bailey S., Bunyan P. J., Rennison B. D., Taylor A. “The Metabolism o. 1, 1-Di(p-chlorophenyl)-., 2, 2-tri-chloroethane an. 1,1-Di(p-chlorophenyl)-2, 2-dichloroethane in the Pigeon”. Toxicol. Appl. Pharmacol. 1969; 14: 13–22
  • Bailey S., Bunyan P. J., Rennison B. D., Taylor A. “The Metabolism o. 1, 1-Di(p-chlorophenyl)-2, 2-dichloro-ethylene an. 1, 1-Di(p-chlorophenyl)-2-chloroethylene in the Pigeon”. Toxicol. Appl. Pharmacol. 1969; 14: 23–32
  • French M. C., Jefferies D. J. “Degradation and Disappearance of ortho, para Isomer of Technical DDT in Living and Dead Avian Tissues”. Scienc. 1969; 165: 914–916
  • Creaven P. J., Parke D. V., Williams R. T. ldquo;A Spec-trofluorimetric Study of the 7-Hydroxylation of Coumarin by Liver Microsomes”. Biochem. J. 1966; 96: 390–398
  • Adamson R. H., Bridges J. W., Evans M. E., Williams R. T. ldquo;Species Differences in the Aromatization of Quinic Acid in vivo and the Role of Gut Bacteria”. Biochem. J. 1970; 116: 437–443
  • Williams R. T. ldquo;Toxicologic Implications of Biotransformation by Intestinal Microflora”. Toxicol. Appl. Pharmacol. 1972; 23: 769–781
  • McMillan D. E., Dewey W. L., Turk R. F., Harris L. S., McNeil J. H., Jr. “Blood Levels of 3H-A9-Tetrahydrocannabinol and Its Metabolites in Tolerant and Nontolerant Pigeons”. Biochem. Pharmacol. 1973; 22: 383–397
  • Adamson R. H., Dixon R. L., Francis F. L., Rail D. P. ldquo;Comparative Biochemistry of Drug Metabolism by Azo and Nitro Reductase”. Proc. Natl. Acad. Sci. U. S. A. 1965; 54: 1386–1391
  • Wit J. G., Leeuwangh P. “Mercapturic Acid Formation and Enzyme-Catalyzed Conjugations with Glutathione in Pigeons”. Biochim. Biophys. Act. 1969; 177: 329–335
  • Neuberg C., Reinfurth E. “Phytochemische Reduktionen XVII. Mitteilung. Partielle Reduktion von Dinitrokorpern”. Biochem. Z. 1923; 139: 561–568
  • Ichihara K., Kusunose E., Kusunose M. ldquo;Some Properties and Distribution of the ω-Hydroxylation System of Medium-Chain Fatty Acids”. Biochim. Biophys. Act. 1969; 176: 704–712
  • Hamberg M., Samuelsson B., Bjorkhem I. “Oxygenases in Fatty Acid and Steroid Metabolism”. Molecular Mechanisms of Oxygen Activation, O. Hayaishi. Academic, New York 1974; 29–85
  • James S. P., Needham D. ldquo;Some Metabolites of S-Pentyl-L-cysteine in the Rabbit and Other Species”. Xenobiotic. 1973; 3: 207–218
  • Bridges J. W., Evans M. E., Idle J. R., Millburn P., Osiyemi F. O., Smith R. L., Williams R. T. “The Conjugation of Indolylacetic Acid in Man, Monkeys and Other Species”. Xenobiotic 1974; 4: 645–652
  • Hulcher F. H., Oleson W. H., Lofland H. B. ldquo;Choles-terol-7α-hydroxylase of Pigeon Liver Microsomes”. Arch. Biochem. Biophys. 1974; 165: 313–322
  • Hayano M. “Oxygenases in Lipid and Sterol Metabolism”. Oxygenases, O. Hayishi. Academic, New York 1962; 182–240
  • Lincer J. L., Peakall D. B. ldquo;PCB Pharmacodynamics in the Ring Dove and Early Gas Chromatographic Peak Diminution”. Environ. Pollut. 1973; 4: 59–68
  • Pan H. P., Hook G. E. R. “Hepatic Mixed-Function Oxidases of Red-Winged Blackbird and Rat: A Comparative Study”. Pharmacologist 1974; 16(2)195
  • Pan H. P., Hook G. E. R., Fouts J. R. ldquo;The Liver Parenchyma and Foreign Compound Metabolism in Red-Winged Blackbird Compared with Rat”. Xenobiotic 1975; 5: 17–24
  • Fouts J. R. “Physiological Impairment of Drug Metabolism”. in Proceedings of the 1st International Pharmacological Meeting, B. Uvnas. Macmillan, New York 1962; Vol. 6: 257–275
  • Pan H. P., Fouts J. R., Devereux T. R. “Hepatic Microsomal N-Oxydation and N-Demethylation of N, N-Dimethylaniline in Red-Winged Blackbird Compared with Rat and Other Birds”. Life Sci. 1975; 17: 819–826
  • Stickeland L. F., Stickel W. H. “Distribution of DDT Residues in Tissues of Birds in Relation to Mortality, Body Condition, and Time”. in Pesticides Symposia, W. B. Deichmann. Helios, Miami 1970; 57–65
  • Stickel L. F. “Pesticide Residues in Birds and Mammals”. Environmental Pollution by Pesticides, C. A. Edwards. Plenum, London 1973; 254–312
  • Murphy S. D. “Liver Metabolism and Toxicity of Thiophos-phate Insecticides in Mammalian, Avian and Piscine Species”. Proc. Soc. Exp. Biol. Med. 1966; 123: 392–398
  • Hitchcock M., Murphy S. D. “Enzymatic Reduction of O, O -(4-Nitrophenyl) Phosphorothioate, O.O-Diethyl O -(4-Nitrophenyl) Phosphate, and O-Ethyl O -(4-Nitrophenyl) Benzene Thiophosphonate by Tissues from Mammals, Birds, and Fishes”. Biochem. Pharmacol. 1967; 16: 1801–1811
  • Murphy S. D. ldquo;Mechanisms of Pesticide Interactions in Vertebrates”. Residue Rev. 1969; 25: 201–221
  • Murphy S. D. “The Toxicity of Pesticides and Their Metabolites”. Degradation of Synthetic Organic Molecules in the Biosphere. National Academy of Science, Washington, DC 1972; 313–335
  • Peoples S. A. “Studies on the Use of DRC-1339 in Starling Control”, R. G. Schwab. University of California, Davis 1965; 12–19, in Progress Report on Starling Control
  • Peoples S. A. “A Colorimetric Method for DRC-1339 and Its Metabolites in Bird Feces and Mammalian Urine”, R. G. Schwab. University of California. 1967; 10–11, in Progress Report on Starling Control
  • Peoples S. A., Apostolou A. “A Comparison between the Metabolism of DRC-1339 in Rabbits and in Starlings”, R. G. Schwab. University of California, Davis 1967; 8–9, in Progress Report in Starling Control
  • Apostolou A. “Comparative Toxicology of the Avicides 3-Chloro-p-toluidine and 2-Chloro-4-acetotoluidide in Birds and Mammals”. Ph.D. Dissertation, University of California, Davis 1969; 147
  • Mull R. L., Giri S. N. ldquo;The Role of Renal Aromatic N-De-acetylase in Selective Toxicity of Avicide 3-Chloro-p-toluidine in Birds”. Biochim. Biophys. Act. 1972; 273: 222–228
  • Mull R. L. “Comparative Studies of Acute and Sub-Acute Toxicity of 3-Chloro-p-toluidine, Studies of the Effects of an Acutely Toxic Dose in Chickens on Certain Clinical Biochemical Parameters, and Comparative Studies of a Renal Aromatic N-Deacetylase”. Ph. D. Dissertation, University of California, Davis 1971; 105
  • Schafer E. W. “The Acute Oral Toxicity of 369 Pesticidal, Pharmaceutical and Other Chemicals to Wild Birds”. Toxicol. Appl. Pharmacol. 1972; 21: 315–330
  • DeCino T. J., Cunningham D. J., Schafer E. W. “Toxicity of DRC-1339 to Starlings”. J. Wildl. Manage. 1966; 30: 249–253
  • Apostolou A., Peoples S. A. ldquo;Toxicity of the Avicide 2-Chloro-4-acetotoluidide in Rats: A Comparison with Its Nonacetylated Form 3-Chloro-p-toluidine”. Toxicol. Appl. Pharmacol. 1971; 18: 517–521
  • Mull R. L., Giri S. N., Peoples S. A. ldquo;Effects of an Acutely Toxic Dose of the Avicide 3-Chloro-p-toluidine in Chickens”. Toxicol. Appl. Pharmacol. 1972; 22: 458–464
  • Felsenstein W. C., Smith R. P., Gosselin R. E. ldquo;Toxicologic Studies on the Avicide 3-Chloro-p-toluidine”. Toxicol. Appl. Pharmacol. 1974; 28: 110–125
  • Borison H. L., Snow S. R., Longnecker D. S., Smith R. P. “3-Chloro-p-toluidine: Effects of Lethal Doses in Rats and Cats”. Toxicol. Appl. Pharmacol. 1974; 31: 403–412
  • National Library of Medicine. Drug Interactions. National Library of Medicine, Bethesda, Maryland 1972; Vol. 1
  • Davison K. L., Sell J. L. “Dieldrin and p, p'-DDT Effects on Some Microsomal Enzymes of Livers of Chickens and Mallard Ducks”. J. Agric. Food Chem. 1972; 20: 1198–1205
  • Sell J. L., Davison K. L. “Changes in the Activities of Hepatic Microsomal', Enzymes Caused by DDT and Dieldrin”. Fed. Pro. 1973; 32: 2003–2009
  • Davison K. L., Sell J. L. ldquo;Dieldrin and DDT Effects on Reproduction and Some Hepatic Mixed-Function Oxidases in the Mallard Duck”. Arch. Environ. Contain. Toxicol. 1974; 2: 302–314
  • Sifri M., Sell J. L., Davison K. L. “Comparative Effect of p, p'-DDT on Hepatic Microsomal Enzymes in Young Quail, Chicks and Ducklings”. Proc. N. Dak. Acad. Sci. 1973; 27: 33
  • Sifri M., Sell J. L., Davison D. L. “Comparative Effects of p, p'-DDT and Pentobarbital on Hepatic Microsomal Enzymes in Young Quail, Chicks and Ducklings”. Comp. Bio-chem. Physiol. 1975; 51B: 213–219
  • Sifri M., Sell J. L., Davison K. L. “Comparative Effects of Dietary Vitamin A and p, p'-DDT on Microsomal Aniline Hydroxylase Activity and Vitamin A in Livers of Young Quail and Ducklings”. Proc. N. Dak. Acad. Sci. 1974; 28: 29
  • Sifri M., Sell J. L., Davison K. L. “Comparative Effect of p, p'-DDT and Vitamin A on Drug Metabolizing Enzymes in Chicks, Ducklings, and Quail”. Pharmacologist 1975; 17(2)249
  • Patterson D. S. P., Roberts B. A. ldquo;Differences in the Effect of Phenobarbital Treatment on the in vitro Metabolism of Aflatoxin and Aniline by Duck and Rat Livers”. Biochem. Pharmacol. 1971; 20: 3377–3383
  • Lincer J. L., Peakall D. B. ldquo;Metabolic Effects of Poly-chlorinated Biphenyls in the American Kestrel”. Natur. 1970; 228: 783–784
  • Gillett J. W., Porter R. D., Wiemeyer S. N., Gram T. H., Schroeder D. H., Gillette J. R. “, Induction of Liver Microsomal Activities in Japanese Quail with Supplemental Information on the Induction of Microsomal Ethylmorphine De-methylase Activity in Sparrow Hawk Livers by Diets Containing DDT and Dieldrin or DDE”. The Biological Impact of Pesticides in the Environment, J. W. Gillett. Oregon State University Press, Corvallis 1970; 59–62
  • Bunyan P. J., Page J. M. J. “Pesticide-Induced Changes in Hepatic Microsomal Enzyme Systems. Some Effects o. 1, 1-Di(p-chlorophenyl)-2, 2-dichloroethylene (DDE) an. 1, 1-Di(p-chlorophenyl)-2-chloroethylene (DDMU) in the Rat and Japanese Quail”. Chem.-Biol. Interact. 1973; 6: 249–257
  • Gillett J. W., Chan T. M., Terriere L. C. “Interactions between DDT Analogs and Microsomal Epoxidase Systems”. J. Agric. Food Chem. 1966; 14: 540–545
  • Bunyan P. J., Davidson J., Shorthill M. J. “Hepatic Glucose-6-phosphate Dehydrogenase and 6-Phosphogluconate Dehydrogenase Levels in Japanese Quail Following the Ingestion of p,p′-DDT and Related Compounds”. Chem.-Biol. Interact. 1970; 2: 175–182
  • Bernstein J. D., Johnson S. L. ldquo;Effects of Diphenyl-hydantoin upon Estrogen Metabolism by Liver Microsomes by DDT-Treated Japanese Quail”. Bull. Environ. Contam. Toxicol. 1973; 10: 309–314
  • Bogoch S., Dreyfus J. The Broad Range of Use of Diphenylhydantoin, Bibliography and Review. Dreyfus Medical Foundation. 1970; Vol. I
  • Bogoch S., Dreyfus J., D P H. A Supplement to the Broad Range of Use of Diphenylhydantoin. Dreyfus Medical Foundation. 1975; Vol. II, 1975
  • Polin D., Ringer R. K. ldquo;Withdrawal Rates of DDT from Chickens Treated with Diphenylhydantoin”. Can. J. Physiol. Pharmacol. 1975; 53: 166–173
  • Villareale M., Gould L. V., Wasserman R. H., Barr A., Chiroff R. T., Bergstrom W. H. ldquo;Diphenylhydantoin: Effects on Calcium Metabolism in the Chick”. Scienc. 1974; 183: 671–673
  • Sell J. L., Davison K. L., Poonacha K. B. “Decreased Aniline Hydroxylase Activity in Japanese Quail Due to Dietary DDT”. J. Agric. FoodChem. 1972; 20: 553–557
  • Gillett J. W., Arscott G. H. ldquo;Microsomal Epoxidation in Japanese Quail: Induction by Dietary Dieldrin”. Comp. Bio-chem. Physiol. 1969; 30: 589–600
  • Gillett J. W. “Induction in Different Species”. in Proceedings of the 2nd International Congress of Pesticide Chemicals, A. Tahori. Gordon and Breach, New York 1972; Vol. 6: 197–235
  • Chhabra R. S., Fouts J. R. “Stimulation of Hepatic Microsomal Drug-Metabolizing Enzymes in Mice by 1,1,1-Tri-chloro-2,2-bis(p-chlorophenyl)ethane (DDT) and 3,4-Benz-pyrene”. Toxicol. Appl. Pharmacol. 1973; 25: 60–70
  • Bunyan P. J., Townsend M. G., Taylor A. “Pesticide-Induced Changes in Hepatic Microsomal Enzyme Systems. Some Effects o. 1, 1-di(p-chlorophenyl)-., 2, 2-trichloro-ethane (DDT) an. 1, 1-Di(p-chlorophenyl)-2, 2-dichloro-ethylene (DDE) in the Rat and Japanese Quail”. Chem.-Biol. Interact. 1972; 5: 13–26
  • Bunyan P. J., Taylor A., Townsend M. G. “The Effects o. 1, 1-Di(p-chlorophenyl)-., 2, 2-trichloroethane (DDT) an. 1, 1-Di(p-chlorophenyl)-2,2-dichloroethylene (DDE) on Hepatic Microsomal Oxidase in the Rat and Japanese Quail”. Biochem. J. 1970; 118: 51–52
  • Goldsmith R. H., Soares J. H., Jr. “Barbiturate Potentiation in Mercury Poisoning”. Bull. Environ. Contam. Toxicol. 1975; 13: 737–740
  • Dieter M. P., Ludke J. L. ldquo;Studies on Combined Effects of Organophosphates and Heavy Metals in Birds. I. Plasma and Brain Cholinesterase in Coturnix Quail Fed Methyl Mercury and Orally Dosed with Parathion”. Bull. Environ. Contam. Toxicol. 1975; 13: 257–262
  • Dieter M. P. “Further Studies on the Use of Enzyme Profiles to Monitor Residue Accumulation in Wildlife: Plasma Enzymes in Starlings Fed Graded Concentrations of Morsodren, DDE, Aroclor 1254, and Malathion”. Arch. Environ. Contam. Toxicol. 1975; 3: 142–150
  • Ludke J. L. “Interaction of Dieldrin and DDE Residues in Japanese Quail, Coturnix coturnix japonica”. Bull. Environ. Contam. Toxicol. 1974; 11: 297–302
  • Cecil H. C., Bitman J., Harris S. J. ldquo;Effects of Different Classes of Pesticides on Pentobarbital Anesthesia and Toxicity in Japanese Quail”. J. Agric. Food Chem. 1973; 21: 114–117
  • Turk D. E. “Dietary Antibiotics and the Absorption of Zinc-65 and 131I-Labeled Oleic Acid”. Poult. Sci. 1968; 47: 1768–1771
  • Matsumoto T., Itoh H., Akiba Y. “Effects of (-)-5-Vinyl-2-oxazolidinethione on the Radioiodine Metabolism in Growing Chicks”. Poult. Sci. 1969; 48: 1061–1069
  • DeSomer P., Vanderhaeghe H., Eyssen H. “Influence of Basic Antibiotics on Serum- and Liver-Cholesterol Concentrations in Chicks”. Natur. 1964; 204: 1306
  • Eyssen H., Evrard E., Vanderhaeghe H. “Cholesterol Lowering Effects on N-Methylated Neomycin and Basic Antibiotics”. J. Lab. Clin. Med. 1966; 68: 753–768
  • Eyssen H., Vanderhaeghe H., DeSomer P. ldquo;Effect of Polybasic Antibiotics and Sulfaguanidine on Absorption and Excretion of Cholesterol and Bile Salts”. Fed. Proc. 1971; 30: 1803–1807
  • Klinger J., Zimmermann B., Oelszner W., Fischer D. H.-, Westermann K. ldquo;Zurn Tremorin-Oxotremorin stoffwechsel bei Kücken”. Acta Biol. Med. Ger. 1971; 26: 1039–1044
  • Gutman Y., Kidron M. ldquo;Liver N-Demethylating Activity-Temperature Effect and Phenobarbital Induction in Different Species”. Biochem. Pharmacol. 1971; 20: 3547–3549
  • Burchell G., Dutton G. J., Nemeth A. M. ldquo;Development of Phenobarbital-Sensitive Control Mechanisms for Uridine Diphosphate Glucuronyltransferase Activity in Chick Embryo Liver”. J. Cell Biol. 1972; 55: 448–456
  • Wishart G. J., Dutton G. J. ldquo;Effect of Phenobarbital and Other Xenobiotics on the Repression in ovo of Chick Embryo Uridine Disphosphate Glucuronyltransferase Activity”. Biochem. Soc. Trans. 1973; 1: 1214–1215
  • Burchell B., Dutton G. J., Winsnes A. “Comparison of Culture-Inducted, Phenobarbital-Induced and Naturally-Developing UDP-Glucuronyl-Transferase. Enzym. 1974; 17: 146–154
  • Wishart G. J., Dutton G. J. ldquo;Release by Phenobarbital of the Repression of UDP-Glucuronyltransferase Activity in ovo”. Biochem. Pharmacol. 1975; 24: 451–454
  • Mick D. L., Long K. R., Aldinger S. M. ldquo;The Effects of Dietary Dieldrin on Residues in Eggs and Tissues of Laying Hens and the Effects of Phenobarbital and Charcoal on These Residues”. Bull. Environ. Contain. Toxicol. 1973; 9: 197–203
  • Fujimoto J. M., Hakim R. “Inhibition of Renal Tubular Transport and Not Metabolism of Morphine by SKF525A in the Chicken”. Pharmacologist 1970; 12(2)292
  • Poland A., Kappas A. ldquo;The Metabolism of Aminopyrine in Chick Embryo Hepatic Cell Culture: Effects of Competitive Substrates and Carbon Monoxide”. Mol. Pharmacol. 1971; 7: 697–705
  • Sell J. L., Davison K. L., Puyear R. L. “Aniline Hydroxylase, N-Demethylase, and Cytochrome P-450 in Liver Microsomes of Hens Fed DDT and Dieldrin”. J. Agric. Food Chem. 1971; 19: 58–60
  • Cummings J. G., Eidelman M., Turner V., Reed D., Zee K. T., Cook R. E. “Residues in Poultry Tissues from Low Level Feeding of Five Chlorinated Hydrocarbon Insecticides to Hens”. J. Assoc. Off. Anal. Chem. 1967; 50: 418–425
  • Nowicki H. G., Norman A. W. “Enhanced Hepatic Metabolism of Testosterone, 4-Androstene-3,17-dione, and Estradiol-170 in Chickens Pretreated with DDT or PCB”. Steroid. 1972; 19: 85–100
  • Fouts J. R. ldquo;Some Effects of Insecticides on Hepatic Microsomal Enzymes in Various Animal Species”. Rev. Can. Biol. 1970; 29: 377–389
  • Stephen B. J., Garlich J. D., Guthrie F. E. “Effect of DDT on Induction of Microsomal Enzymes and Deposition of Calcium in the Domestic Chicken”. Bull. Environ. Contain. Toxicol. 1971; 5: 569–575
  • Britton W. M. ldquo;Influence of High Levels of DDT in the Diet on Liver Microsomal Estrogen Metabolism in the Laying Hen”. Bull. Environ. Contain. Toxicol. 1975; 13: 698–702
  • Puyear R. L., Paulson G. D. ldquo;Effect of Carbaryl (i-Naphthyl N-Methylcarbamate) on Pentobarbital-Induced Sleeping Time and Some Liver Microsomal Enzymes in White Leghorn Cockerels”. Toxicol. Appl. Pharmacol. 1972; 22: 621–627
  • Jellinck P. H., Smith G. ldquo;Aryl Hydroxylase Induction in the Chick Embryo by Polycyclic Hydrocarbons”. Biochim. Biophys. Act. 1973; 304: 520–525
  • Rogers L. E. ldquo;Specific Activity of Hepatic Formyltetrahy-drofolic Acid Synthetase and Formiminotetrahydrofolic Acid Transferase after Administration of Methotrexate to Chicks”. Biochem. Pharmacol. 1971; 20: 492–494
  • Konyukhov A. F., Poloz D. D., Kokhtyuk F. P. ldquo;[Anthio Metabolism in the Chicken]”. Veterinarii 1974; 5: 108–109, in Russian, NIH translation
  • Bend J. R., Peakall D. B., Miller D. S., Kinter W. B. ldquo;Effects of DDE Administration on Hepatic Microsomal Mixed-Function Oxidase Activities in the Puffin Fratercula arctica and the White Pekin Duck Anas platyrhynchos”. Bull. Mt. Desert Island Biol. Lab. 1974; 14: 4–6
  • Peakall D. B. ldquo;Pesticide-Induced Enzyme Breakdown of Steroids in Birds”. Natur. 1967; 216: 505–506
  • Miller D. S., Kinter W. B., Peakall D. B. ldquo;Enzymatic Basis for DDE-Induced Eggshell Thinning in a Sensitive Bird”. Natur. 1976; 259: 122–124
  • Williams R. T. “Detoxication Mechanisms in vivo”. in Proceedings of the 1st International Pharmacological Meeting, B. Uvnäs. Macmillan, New York 1962; Vol. 6: 1–12
  • Williams R. T. “Drug Metabolism in Man as Compared with Laboratory Animals”. in Proceedings of the European Society for the Study of Drug Toxicity. Excerpta Medica, 1964; Vol. 4: 9–22
  • Williams R. T. “Comparative Patterns of Drug Metabolism”. Fed_Proc. 1967; 26: 1029–1039
  • Williams R. T. “Species Variations in Drug Biotransformations”. Fundamentals of Drug Metabolism and Drug Distribution, B. N. La Du, H. G. Mandel, E. L. Way. Williams and Wilkins, Baltimore 1971; 187–205
  • Stickel L. F., Rhodes L. I. “The Thin Eggshell Problem”. The Biological Impact of Pesticides in the Environment, J. W. Gillett. Oregon State University Press, Corvallis 1970; 31–35
  • Sinclair P. R., Granick S. “Uroporphyrin Formation Induced by Chlorinated Hydrocarbons (Lindane, Polychlorinated Biphenyls, Tetrachlorodibenzo-p-dioxin). Requirements for Endogenous Iron, Protein Synthesis and Drug-Metabolizing Activity”. Biochem. Biophys. Res. Commun. 1974; 61: 124–133
  • Strik J. J. T. W. A. ldquo;Chemical Porphyria in Japanese Quail (Coturnix c. Japonica)”. Enzym. 1973; 16: 211–223
  • Fish M. S., Sweeley C. C., Johnson N. M., Lawrence E. P., Horning E. C. “Chemical and Enzymic Rearrangements of N, N-Dimethyl Amino Acid Oxides”. Biochem. Biophys. Act. 1956; 21: 196–197
  • Das M. L., Ziegler D. M. “Rat Liver Oxidative N-De-alkylase and N-Oxidase Activities as a Function of Animal Age”. Arch. Biochem. Biophys. 1970; 140: 300–306
  • Williams R. T. (1976) “Species Variations in the Pathways of Drug Metabolism”. Presented at the Pinehurst Conference. March, 1976. Pine-hurst, North Carolina, 10–12
  • Nebert D. W., Felton J. S. ldquo;Importance of Genetic Factors Influencing the Metabolism of Foreign Compounds”. Fed. Pro. 1976; 35: 1133–1141
  • Nebert D. W., Kon H. “Genetic Regulation of Aryl Hydrocarbon Hydroxylase Induction. V. Specific Changes in Spin State of Cytochrome P450 from Genetically Responsive Animals”. J. Biol. Chem. 1973; 248: 169–178
  • Nebert D. W., Considine N., Owens I. S. ldquo;Genetic Expression of Aryl Hydrocarbon Hydroxylase Induction. VI. Control of Other Aromatic Hydrocarbon-Inducible Mono-Oxygenase Activities at or near the Same Genetic Locus”. Arch. Biochem. Biophys. 1973; 157: 148–159
  • Nebertand D. W., Robinson J. R. “Further Studies on Genetically Mediated Differences in Monooxygenase Activities and Spin State of Cytochrome P460 Iron from Rabbit, Rat, and Mouse Liver”. J. Biol. Chem. 1973; 248: 7637–7647
  • Wiebel F. J., Leutz J. C., Gelboin H. W. “Aryl Hydrocarbon (Benzo[a]pyrene) Hydroxylase: Inducible in Extrahe-patic Tissues of Mouse Strains Not Inducible in Liver. Arch. Biochem. Biophys. 1973; 154: 292–294
  • Chhabra R. S., Tredger J. M., Philpot R. M., Routs J. R. ldquo;Selection of Inducers: An Important Factor in Characterizing Genetic Differences to Induction of Aryl Hydrocarbon Hydroxylase in Strains of Mice”. Life Sci. 1974; 15: 123–130
  • Fouts J. R. ldquo;Overview of the Field: Environmental Factors Affecting Chemical or Drug Effects in Animals”. Fed. Pro. 1976; 35: 1162–1165

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