Metabolic considerations in pyrethroid design

References

• Abernathy C.O., Ueda K., Engel J.L., Gaughan L.C., Casida J.E. Substrate-specificity and toxicological significance of pyrethroid-hydrolyzing esterases of mouse liver microsomes. Pesticide Biochemistry and Physiology 1973; 3: 300–311
   Web of Science ®Google Scholar
• Elliott M. The pyrethroids: early discovery, recent advances and the future. Pesticide Science 1989; 27: 337–351
   Google Scholar
• Elliott M., Farnham A.W., Janes N.F., Needham P.H., Pearson B.C. 5-Benzyl-3-furylmethyl chrysanthemate: a new potent insecticide. Nature 1967; 213: 493–494
   Web of Science ®Google Scholar
• Elloitt M., Farnham A.W., Janes N.F., Needham P.H., Pulman D.A. Insecticidally active conformations of pyrethroids. Mechanisms of Pesticide Action, G.K. Kohn. American Chemical Society, Washington 1974a; 80–91
   Google Scholar
• Elliott M., Farnham A.W., Janes N.F., Needham P.H., Pulman D.A. Synthetic insecticide with a new order of activity. Nature 1974b; 248: 710–711
   PubMed Web of Science ®Google Scholar
• Elliott M., Farnham A.W., Janes N.F., Needham P.H., Pullman D.A., Stevenson J.H. A photostable pyrethroid. Nature 1973; 246: 169–170
   PubMed Web of Science ®Google Scholar
• Elliott M., Janes N.F. Chemistry of the natural pyrethrins. Pyrethrum: The Natural Insecticide, J.E. Casida. Academic Press, New York 1973; 55–100
   Google Scholar
• Elliott M., Janes N.F., Kimmel E.C., Casida J.E. Metabolic fate of pyrethrin I, pyrethrin II, and allethrin administered orally to rats. Journal of Agricultural and Food Chemistry 1972; 20: 300–313
   PubMedGoogle Scholar
• Engel J.F., Plummer E.L., Stewart R.R., VanSaun W.A., Montgomery R.E., Cruickshank P.A., Harnish W.N., Nethery A.A., Crosby G.A. Synthesis and biological activity of a new group of broad-spectrum pyrethroid insecticides. Pesticide Chemistry: Human Welfare and the Environment, J. Miyamoto, P.C. Kearney. Pergamon, Oxford 1982; 101–106
   Google Scholar
• Gaughan L.C., Unai T., Casida J.E. Permethrin metabolism in rats. Journal of Agricultural and Food Chemistry 1977; 25: 9–17
   Web of Science ®Google Scholar
• Gray A.J., Soderlund D.M. Mammalian toxicology of pyrethroids. Insecticides, D.H. Huston, T.R. Roberts. Wiley, Chichester 1985; 193–248, Progress in Pesticide Biochemistry and Toxicology, Volume 5
   Google Scholar
• Jutsum A.R., Gordon R. F. S., Ruscoe C. N. E. Tefluthrin—a novel soil insecticide. Proceedings of the 1986 British Crop Protection Conference—Pests and Diseases. 1986. BCPC Publications, Thornton Heath, UK, 97–106
   Google Scholar
• Lawrence L.J., Casida J.E. Pyrethroid toxicology: mouse intracerebral structure-toxicity relationships. Pesticide Biochemistry and Physiology 1982; 18: 9–14
   Web of Science ®Google Scholar
• McLaughlin G.A. History of pyrethrum. Pyrethrum: The Natural Insecticide, J.E. Casida. Academic Press, New York 1973; 3–15
   Google Scholar
• Miyamoto J., Nishida T., Ueda K. Metabolic fate of resmethrin, 5-benzyl-3-furylmethyl dl-trans-chrysanthemate in the rat. Pesticide Biochemistry and Physiology 1971; 1: 293–306
   Google Scholar
• Ohno N., Fujimoto K., Okuno Y., Mizutani T., Hirano M., Itaya N., Honda T., Yoshioka H. A new class of pyrethroidal insecticides; α-substituted phenylacetic acid esters. Agricultural and Biological Chemistry 1974; 38: 881–883
   Web of Science ®Google Scholar
• Ruzo L.O., Unai Y., Casida J.E. Decamethrin metabolism in rats. Journal of Agricultural and Food Chemistry 1978; 26: 918–925
   PubMed Web of Science ®Google Scholar
• Sawicki R.M. Insecticidal activity of pyrethrum extract and its four constituents against house flies. III. Knock-down and recovery of flies treated with pyrethrum extract with and without piperonyl butoxide. Journal of the Science of Food and Agriculture 1962; 13: 283–292
   Google Scholar
• Scott J.G., Georghiou G.P. Mechanisms responsible for high levels of permethrin resistance in the house fly. Pesticide Science 1986; 17: 195–206
   Google Scholar
• Soderlund D.M., Abdel-Aal Y. A. I., Helmuth D.W. Selective inhibition of separate esterases in rat and mouse liver microsomes hydrolyzing malathion, trans-permethrin, and cis-permethrin. Pesticide Biochemistry and Physiology 1982; 17: 162–169
   Web of Science ®Google Scholar
• Soderlund D.M., Casida J.E. Effects of pyrethroid structure on rates of hydrolysis and oxidation by mouse liver microsomal enzymes. Pesticide Biochemistry and Physiology 1977a; 7: 391–401
   Web of Science ®Google Scholar
• Soderlund D.M., Casida J.E. Substrate specificity of mouse-liver microsomal enzymes in pyrethroid metabolism. Synthetic Pyrethroids, M. Elliott. American Chemical Society, Washington 1977b; 162–172
   Google Scholar
• Soderlund D.M., Sanborn J.R., Lee P.W. Metabolism of pyrethrins and pyrethroids in insects. Progress in Pesticide Biechemistry and Toxicology, D.H. Hutson, T.R. Roberts. Wiley, Chichester 1983; Volume 3: 401–135
   Google Scholar
• Udagawa T., Numata S., Oda K., Shiraishi S., Kodaka K., Nakatani K. A new type of synthetic pyrethroid insecticide. Recent Advances in the Chemistry of Insect Control, N.F. Janes. Royal Society of Chemistry, London 1985; 192–204
   Google Scholar
• Ueda K., Gaughan L.C., Casida J.E. Photodecomposition of resmethrin and related pyrethroids. Journal of Agricultural and Food Chemistry 1974; 22: 212–220
   PubMedGoogle Scholar
• Ueda K., Gaughan L.C., Casida J.E. Metabolism of (+)-trans- and (+)-cis-resmethrin in rats. Journal of Agricultural and Food Chemistry 1975; 23: 106–115
   PubMed Web of Science ®Google Scholar
• Yamamoto I., Casida J.E. O-demethyl pyrethrin II analogs from oxidation of pyrethrin I, allethrin, dimethrin, and phthalthrin by a house fly enzyme system. Journal of Economic Entomology 1966; 59: 1542–1543
   Web of Science ®Google Scholar