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D:\Final ATSDR\CORRECTIONS CHLORFENVINPHOS 165 8. REFERENCES *Agnihotri NP, Pandey SY, Jain HK, et al. 1981. Persistence, leaching, and movement of chlorfenvinphos, chlorpyrifos, disulfoton, fensulfothion, monocroiophos and tetrachlorvinphos in soil. Ind J Agric Chem 14(1-2):27-31. *Aguera A, Contreras M, Fernandez-Alba AR. 1993. Gas chromatographic analysis of organophosphorus pesticides of horticultural concern. J Chromatogr A 655(2):293-300. *Akintonwa DA. 1984. Theoretical aspects of enzyme induction and inhibition leading to the reversal of resistance to biocides. J Theor Biol 106(1):79-87. *Akintonwa DA. 1985. The correlation between theoretical and experimental biotransformation of 2-chloro-1-(2',4' dichlorophenyl) vinyl diethylphosphate (chlorfenvinphos) in the dog and rat. J Theor Biol 114(1):103-108. *Akintonwa DA, Itam IH. 1988. The development of an assay for determination of monooxygenase of human foetal livers based on rate of decrease in substrate concentration. Drug Des Deliv 3(1):77-83. *Ambrose AM, Larson PS, Borzelleca JF, et al. 1970. Toxicologic studies on Diethyl-1-(2,4-Dichlorophenyl)-2-Chlorovinyl phosphate. Toxicol Appl Pharmacol 17:323-336. *Amer SM, Aly FAE. 1992. Cytogenetic effects of pesticides. IV. Cytogenetic effects of the insecticides Gardona and Dursban. Mutat Res 279(3):169-170. *Ames RG, Brown SK, Rosenberg J, et al. 1989. Health symptoms and occupational exposure to flea control products among California pet handlers. Am Ind Hyg Assoc J 50(9):466-472. *Andersen ME, Clewell HJ, III, Gargas ML, et al. 1987. Physiologically based pharmacokinetics and the risk assessment process for methylene chloride. Toxicol Appl Pharmacol 87:185-205. *Andersen ME, Krishnan K. 1994. Relating in vitro to in vivo exposures with physiologically-based tissue dosimetry and tissue response models. Current concepts and approaches on animal test alternatives. H. Salem, ed. U.S. Army Chemical Research Development and Engineering Center, Aberdeen Proving Ground, Maryland. *Atkinson R. 1988. Estimation of gas-phase hydroxyl radical rate constants for organic chemicals. Environ Toxicol Chem 7:435-442. *Atkinson R, Carter WPL. 1984. Kinetics and mechanisms of the gas-phase reactions of ozone with organic compounds under atmospheric conditions. Chem Rev 84:437-470. *ATSDR. 1989. Decision guide for identifying substance-specific data needs related to toxicologicol profiles. Agency for Toxic Substances and Disease Registry, Division of Toxicology, Atlanta, GA. *Cited in text CHLORFENVINPHOS 166 8. REFERENCES *ATSDR/CDC. 1990. Subcommittee report on biological indicators of organ damage. Agency for Toxic Substances and Disease Registry, Centers for Disease Control and Prevention, Atlanta, GA. *Bagon DA, Warwick CJ. 1982. The determination of atmospheric concentrations of the active ingredient of pesticide formulations by high-performance liquid chromatography. Chromatographia 16:290-293. *Barba A, Navarro M, Navarro-Garcia S. 1993. Adsorption of chlorfenvinphos and methidathion on saturated clays by different cations. J Environ Sci Health, Part B: Pestic Food Contam Agric Wastes 26(5-6):547-556. *Barba A, Navarro M, Navarro Garcia S, et al. 1991. Adsorption of chlorfenvinphos and methidathion from saturating dissolutions of different cations. J Environ Sci Health B26(5-6):547-556. [French] *Barna J, Simon G. 1973. Effect of small oral doses of Birlane (chlorfenvinphos) on intestinal resorption. Kiserl Orvostud 26(6):605-609. *Barnes DG, Dourson M. 1988. Reference dose (RfD): Description and use in health risk assessments. U.S. Environmental Protection Agency. Regul Toxicol Pharmacol 8:471-486. *Barrio CS, Asenio JS, Bernal JG. 1994. GC-NPD investigation of the recovery of organonitrogen and organophosphorus pesticides from apple samples: The effect of the extraction solvent. Chromatogr 30:320-324. *Bauer H, Schonherr J. 1992. Determination of mobilities of organic compounds in plant cuticles and correlation with molar volumes. Pestic Sci 35(1):1-11. Berstein ME. 1984. Agents affecting the male reproductive system: Effects of structure on activity. Drug Metab Rev 15:941-999. *Beroza m, Bowman MC. 1966. Gas Chromatographic Determination of Compound 4072 and Shell SD-8447 by Electron-Capture and Flame-Photometric Detection. J Agr Food Chem 14(6):625-627. *Beynon KI, Davies L, Elgar K. 1966. Analysis of crops and soils for residues of diethyl 1-(2,4,-Dichlorophenyl)-2-Chlorovinyl Phosphate. I. Development of Method. J Sci Food Agric 17:162-167. *Beynon KI, Edwards MJ, Elgar K, et al. 1968. Analysis of crops and soils for residues of chlorfenvinphos insecticide and its breakdown products. J Sci Fd Agric 19:302-307. *Beynon KI, Edwards MJ, Thompson AR, et al. 1971. Persistence of chlorfenvinphos in natural waters. Pestic Sci 2(1):5-7. *Beynon KI, Hutson DH, Wright AN. 1973. The metabolism and degradation of vinyl phosphate insecticides. Residue Rev 47:55-142. *Beynon KI, Wright AN. 1968. Breakdown of C-Chlorfenvinphos insectide on crops. J Sci Food Agric 19:146-153. *Binstein S, Devillers J. 1994. QSAR for organic chemical sorption in soils and sediments. Chemosphere 28(6):1171-1188. CHLORFENVINPHOS 167 8. REFERENCES *Bowman BT, Sans WW. 1983. Determination of octanol-water partitioning coefficients (Kow) of 61 organophosphorus and carbamate insecticides and their relationship to respective water solubility (S) values. J Environ Sci Health B18(6):667-683. *Boyd EM, Carsky E. 1969. Kwashiorkorigenic diet and diazinon toxicity. Acta Pharmacol Toxicol 27(4):284-294. *Bradway DE, Moseman R, May R. 1981. Analysis of Alkyl Phosphates by Extractive Alkylation. Bull Environ Contam Toxicol 26:520-523. *Braun HE, Frank R. 1980. Organochlorine and organophosphorus insecticides: Their use in eleven agricultural watersheds and their loss to stream waters in southern Ontario, Canada, 1975-1977. Sci Tot Environ 15:169-192. *Brzezinski J. 1978. Effects of chlorfenvinfos on the disulfiram induced decrease of endogenous noradrenaline in the rat brain. Pol J Pharmacol Pharm 30(1):69-71. *Bysshe SE. 1990. Bioconcentration factors in aquatic organisms. In: WJ Lyman, WF Reehl, DH Rosenblatt, eds. Handbook of chemical properties estimation methods. Environmental behavior of organic compounds. Washington, DC: American Chemical Society, 5-1 - 5-30. *Camara MA, Navarro M, Navarro-Garcia S, et al. 1992. Catalytic degradation of chlorfenvinphos and methidathion deposited on kaolinite and bentonite saturated by different cations. J Environ Sci Health, Part B: Pestic Food Contam Agric Wastes 27(3):293-306. *Chambers JE, Levi EL. 1992. Organophosphates: Chemistry, Fate, and Effect. San Diego, CA: Academy Press. *Clewell HJ III, Andersen ME. 1985. Risk assessment extrapolations using physiologically-based pharmacokinetic modeling. Toxicol Ind Health 1:111-131. *Corneliussen PE. 1970. Pesticide residues in total diet samples. Pestic Monit J 4(3):89-105. *Coye MJ, Barnett PG, Midtling JE, et al. 1987. Clinical confirmation of organophosphate poisoning by serial cholinesterase analyses. Arch Intern Med 147:438-442. *Cupp CM, Kleiber G, Reigart R, et al. 1975. Hypothermia in organophosphate poisoning and response to PAM. J South Carolina Med Assoc 71(5):166-168. *Davies DB, Holub BJ. 1980. Comparative subacute toxicity of dietary diazinon in the male and female rat. Toxicology and Applied Pharmacology 54:359-367. *Dean BJ. 1972. The mutagenic effects of organophosphorus pesticides on microorganisms. Arch Toxicol 30:67-74. *Dolara P, Vezzani A, Caderni G, et al. 1993. Genetic toxicity of a mixture of fifteen pesticides commonly found in the Italian diet. Cell Biol Toxicol 9(4):333-343. *Domine D, Devillers J, Chastrette M, et al. 1992. Multivariant structure-property relationships (MSPR) of pesticides. Pestic Sci 35:73-82. *Donninger C. 1971. Species specificity of phosphate triester anticholinesterases. Bull World Health Org 44(1-3):265-268. CHLORFENVINPHOS 168 8. REFERENCES *Dudka J, Szczepaniak S. 1993. [Investigation of chlorfenvinphos influence on levels of free tryptophan in blood plasma of the rat]. Rocz Panstw Zakl Hig 44(2-3):199-203. [Polish] *Duggan RE, Corneliussen PE. 1972. Dietary intake of pesticide chemicals in the United States (III): June 1968-April 1970. Pestic Monit J 5:331-341. *Duggan RE, Corneliussen PE, Duggan MB, et al. 1983. Pesticide residue levels in foods in the United States from June 1, 1969 to June 30, 1976. Washington, DC: Food and Drug Administration, Division of Chemical Technology, 15, 22, 27, 30, 32, 33. *Edson EF, Noakes DN. 1960. The comparative toxicity of six organophosphorous insecticides in the rat. Toxicol Appl Pharmacol 2:523-539. *Edwards CA, Thompson AR, Benyon KI, et al. 1968. Some effects of chlorfenvinphos, an organophosphorus insecticide, on populations of soil animals. Rev Ecol Biol Sol 5:199-224. *Edwards MJ, Beynon KI, Edwards CA, et al. 1971. Movement of chlorfenvinphos in soil. Pestic Sci 2(1):1-4. *Eisenreich SJ, Looney BB, Thornton JD. 1981. Airborne organic contaminants in the Great Lakes ecosystem. Environ Sci Technol 15:30-38. **Ellenhorn MJ, Barceloux DG. 1988. Medical Toxicology: Diagnosis and treatment of human poisoning. Elsevier. New York. *Endo G, Horiguchi S, Kiyota I, et al. 1988. Serum cholinesterase and erythrocyte acetylcholinesterase activities in workers occupationally exposed to organophosphates. Proc. ICMR Semin. 8 Pr 561-564. *EPA. 1976. U.S. Environmental Protection Agency. Code of Federal Regulations. 40 CFR 180.3. *EPA. 1978a. Memorandum Toxicology Branch Data review for chlorfenvienphos. Requested by Burroughs
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