Insect Control: Biological and Synthetic Agents - Index of
Insect Control: Biological and Synthetic Agents - Index of
Insect Control: Biological and Synthetic Agents - Index of
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106 3: Neonicotinoid <strong>Insect</strong>icides<br />
Elbert, A., Erdelen, C., Kühnhold, J., Nauen, R., Schmidt,<br />
H.W., et al., 2000. Thiacloprid, a novel neonicotinoid<br />
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Protection Conference: Pests <strong>and</strong> Diseases 1, 21–26.<br />
Elbert, A., Nauen, R., 1996. Bioassays for imidacloprid<br />
for a resistance monitoring against the whitefly Bemisia<br />
tabaci. Proc. Brighton Crop Protection Conference:<br />
Pests <strong>and</strong> Diseases 2, 731–738.<br />
Elbert, A., Nauen, R., 2004. New applications for neonicotinoid<br />
insecticides using imidacloprid as an example.<br />
In: Horowitz, A.R., Ishaaya, I. (Eds.), Novel<br />
Approaches to <strong>Insect</strong> Pest Management in Field <strong>and</strong><br />
Protected Crops. Springer, New York, pp. 29–44.<br />
Elbert, A., Nauen, R., Cahill, M., Devonshire, A.L., Scarr,<br />
A.W., et al., 1996. Resistance management with chloronicotinyl<br />
insecticides using imidacloprid as an example.<br />
Pflanzenschutz-Nachrichten Bayer 49, 5–53.<br />
Elbert, A., Nauen, R., Leicht, W., 1998. Imidacloprid, a<br />
novel chloronicotinyl insecticide, biological activity <strong>and</strong><br />
agricultural importance. In: Ishaaya, I., Degheele, D.<br />
(Eds.), <strong>Insect</strong>icides with Novel Modes <strong>of</strong> Action,<br />
Mechanism, <strong>and</strong> Application. Springer, New York, pp.<br />
50–73.<br />
Elbert, A., Overbeck, H., Iwaya, K., Tsuboi, S., 1990.<br />
Imidacloprid, a novel systemic nitromethylene analog<br />
insecticide for crop protection. Proc. Brighton Crop<br />
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Epe, C., Coati, N., Stanneck, D., 2003. Efficacy <strong>of</strong><br />
the compound preparation imidacloprid 10% (w/v)/<br />
permethrin 50% (w/v) spot-on against ticks (I. ricinus,<br />
R. sanguineus) <strong>and</strong> fleas (C. felis) on dogs. Parasitol.<br />
Res. 90, 122–124.<br />
Everett, R., Cunningham, J., Arther, R., Bledsoe, D.L.,<br />
Mencke, N., 2000. Comparative evaluation <strong>of</strong> the<br />
speed <strong>of</strong> flea kill <strong>of</strong> imidacloprid <strong>and</strong> selamectin in<br />
dogs. Vet. Therap. 1, 229–234.<br />
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Feyereisen, R., 1995. Molecular biology <strong>of</strong> insecticide<br />
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Chalmers, A.E., 1993. A point mutation in Drosophila<br />
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Field, L.M., Blackmann, R.L., Devonshire, A.L., 2001.<br />
Evolution <strong>of</strong> amplified esterase genes as a mode <strong>of</strong><br />
insecticide resistance in aphids. In: Ishaaya, I. (Ed.),<br />
Biochemical Sites Important in <strong>Insect</strong>icide Action <strong>and</strong><br />
Resistance. Springer, Berlin, pp. 209–219.<br />
Field, L.M., Devonshire, A.L., Forde, B.G., 1988. Molecular<br />
evidence that insecticide resistance in peach potato<br />
aphids, Myzus persicae (Sulz), results from amplification<br />
<strong>of</strong> an esterase gene. Biochem. J. 251, 309–315.<br />
Foster, S.P., Denholm, I., Devonshire, A.L., 2000. The ups<br />
<strong>and</strong> downs <strong>of</strong> insecticide resistance in peach potato<br />
aphids (Myzus persicae) in the UK. Crop Protect. 19,<br />
873–879.<br />
Foster, S.P., Denholm, I., Harling, Z.K., Moores, G.D.,<br />
Devonshire, A.L., 1998. Intensification <strong>of</strong> resistance in<br />
UK field populations <strong>of</strong> the peach potato aphid, Myzus<br />
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Entomol. Res. 88, 127–130.<br />
Foster, S.P., Denholm, I., Thompson, R., 2003. Variation<br />
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Mgt Sci. 59, 166–173.<br />
Foster, S.P., Devonshire, A.L., 1999. Field-simulator study<br />
<strong>of</strong> insecticide resistance conferred by esterase-, MACE-,<br />
<strong>and</strong> kdr-based mechanisms in the peach potato aphid,<br />
Myzus persicae (Sulzer). Pestic. Sci. 55, 810–814.<br />
Fourie, L.J., Du R<strong>and</strong>, C., Heine, J., 2003. Evaluation <strong>of</strong><br />
the efficacy <strong>of</strong> an imidacloprid 10%/moxidectin 2.5%<br />
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Parasitol. Res. 90, 135–136.<br />
Genchi, C., Traldi, G., Bianciardi, P., 2000. Efficacy <strong>of</strong><br />
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Vet. Therap. 2, 71–80.<br />
Georghiou, G.P., 1983. Management <strong>of</strong> resistance in<br />
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Resistance to Pesticides. Plenum, New York, pp.<br />
769–792.<br />
Göbel, T., Gsell, L., Huter, O.F., Maienfisch, P., Naef, R.,<br />
et al., 1999. <strong>Synthetic</strong> approaches towards CGA<br />
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in <strong>Insect</strong>s. Elsevier, Amsterdam, pp. 195–307.<br />
Graton, J., Berthelot, M., Gal, J.-F., Laurence, C.,<br />
Lebreton, J., et al., 2003. The nicotinic pharmacophore:<br />
thermodynamics <strong>of</strong> the hydrogen-bonding complexation<br />
<strong>of</strong> nicotin, nornicotine, <strong>and</strong> models. J. Organ.<br />
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Green, M.B., LeBaron, H.M., Moberg, W.K., 1990. Managing<br />
Resistance to Agrochemicals: From Fundamental<br />
to Practical Strategies. American Chemical Society,<br />
Washington, DC.<br />
Greenwood, R., Ford, M.G., Scarr, A., 2002. Neonicotinoid<br />
pharmacokinetics. Proc. Brighton Crop Protection<br />
Conference: Pest <strong>and</strong> Diseases 1, 153–160.<br />
Griffin, L., Krieger, K., Liege, P., 1997. Imidacloprid: a<br />
new compound for control <strong>of</strong> fleas initiated dermatitis.<br />
Suppl. Comp. Cont. Educ. Prac. Vet. 19, 17–20.<br />
Guirao, P., Beitia, F., Cenis, J.L., 1997. Biotype determination<br />
<strong>of</strong> Spanish populations <strong>of</strong> Bemisia tabaci (Hemiptera:<br />
Aleyrodidae). Bull. Entomol. Res. 87, 587–593.<br />
Gundelfinger, E.D., 1992. How complex is the nicotinic<br />
receptor system <strong>of</strong> insects? Trends Neurosci. 15,<br />
206–211.<br />
Gunning, R.V., Moores, G.D., 2001. Insensitive acetylcholinesterase<br />
as sites for resistance to organophosphates<br />
<strong>and</strong> carbamates in insects: insensitive<br />
acetylcholinesterase confers resistance in Lepidoptera.