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Journal of Crop Health

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01-12-2013 | Review Article

RETRACTED ARTICLE: Botanical Pesticides and Their Mode of Action

Author: Dr. Nabil E. El-Wakeil

Published in: Journal of Crop Health | Issue 4/2013

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Abstract

Pest management is facing economic and ecological challenge worldwide due to human and environmental hazards caused by majority of the synthetic pesticide chemicals. Identification of novel effective insecticidal compounds is essential to combat increasing resistance rates. Botanical pesticides have long been touted as attractive alternatives to synthetic chemical pesticides for pest management because botanicals reputedly pose little threat to the environment or to human health. The body of scientific literature documenting bioactivity of plant derivatives to arthropod pests continues to expand, yet only a handful of botanicals are currently used in agriculture in the industrialized world, and there are few prospects for commercial development of new botanical products. Pyrethrum and neem are well established commercially, pesticides based on plant essential oils have entered the marketplace, and the use of rotenone appears to be waning. A number of plant substances have been considered for use as pest antifeedants, repellents and toxicants, but apart from some natural mosquito repellents, a little commercial success has ensued for plant substances that modify arthropod behavior. Several factors appear to limit the success of botanicals, most notably regulatory barriers and the availability of competing products (newer synthetics and fermentation products) that are cost-effective and relatively safe compared with their predecessors. In the context of agricultural pest management, botanical pesticides are best suited for use in organic food production in industrialized countries but can play a much greater role in the production and postharvest protection of food in developing countries.

Botanicals have been in use for a long time for pest control. The compounds offer many environmental advantages. However, their uses during the 20th century have been rather marginal compared with other bio-control methods of pests and pathogens. Improvement in the understanding of plant allelochemical mechanisms of activity offer new prospects for using these substances in crop protection. I’m trying in this article to present different kinds of botanical pesticides came from different recourses and their mode of actions as well as I will try to examine the reasons behind their limited use (disadvantages) and the actual crop protection developments involving biopesticides of plant origin for organic or traditional agricultures to keep our environment clean and safer for humankind and animals.

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Abd El-Aziz SE, El-Hawary FMA (1997) Inhibitory effects of some essential oils on the development of the cotton leafworm, Spodoptera littoralis (Boisd.). J Egypt German Soc Zool 22:117–130

Abd El-Aziz SE, Sharaby AM (1997) Some biological effects of white mustard oil, Brassica alba against the cotton leafworm, Spodoptera littoralis (Boisd.). A Schädlingskunde, Pflanzenschutz, Umweltschutz 70:62–64

Abdallah SA, Barakat AA, Badawy HMA, Soliman MMM (2004) Insecticidal activity of different wild plant extracts against Aphis craccivora Koch. Egypt J Biol Pest Control 14:165–173

Abdelgaleil SAM (2010) Molluscicidal and insecticidal potential of monoterpenes on the white gardensnail, Theba pisana (Muller) and the cotton leafworm, Spodoptera littoralis (Boisd.). Appl Entomol Zool 45:425–433CrossRef

Abdelgaleil SAM, El-Aswad AF (2005) Antifeedant and growth inhibitory effects of Tetranortriterpenoids isolated from three Meliaceous species on the cotton leafworm, Spodoptera littoralis (Boisd.). J Appl Sci Res 1:234–241

Abdelgaleil SA, Abbassy MA, Belal AS, Abdel Rasoul MA (2008) Bioactivity of two major constituents isolated from the essential oil of Artemisia judaica L. Bioresource Technol 99:5947–5950CrossRef

Abdel-Khalek AA, Amer SA, Momen FM (2010) Repellency and toxicity of extract from Francoeria crispa (Forssk) to Eutetranychus orientalis (Klein) (Acari: Tetranychidae). Archiv Phytopathol & Plant Prot 44:441–445CrossRef

Adel MM, El-Hawary FM, Abdel-Aziz NF, Sammour EA (2010) Some physiological, biochemical and histopathological effects of Artemisia monosperma against the cotton leafworm, Spodoptera littoralis. Arch Phytopathol & Plant Prot 43:1098–1110.CrossRef

Akhtar Y, Rankin CH, Isman MB (2003) Decreased response to feeding deterrents following prolonged exposure in the larvae of a generalist herbivore, Trichoplusia ni (Lepidoptera: Noctuidae). J Insect Behav 16:811–831CrossRef

Alburo R, Olofson H (1987) Agricultural history and the use of botanical insecticides in Argao, Cebu. Philipp Quar Cul & Soc 15:151–172

Allan EJ, Eeswara JP, Jarvis AP, Mordue Luntz AJ, Morgan ED, Stuchbury T (2002) Induction of hairy root cultures of Azadirachta indica A. Juss. and their production of azadirachtin and other important insect bioactive metabolites. Plant Cell Rep 21:374–379CrossRef

Amer SA, Momen FM (2002) Effect of some essential oil on predacious mite Amblyseius swirskii (Phytoseiidae). Acta Phyto Entomol Hung 37:281–286CrossRef

Amer SA, Momen FM (2005) Effect of French lavender essential oil on some predacious mites of the family Phytoseiidae. Acta Phyto Entomol Hung 40:409–415CrossRef

Antonious GF (2004) Residues and halflives of pyrethrins on field-grown pepper and tomato. J Environ Sci Health B39:491–503CrossRef

Arcury TA, Quandt SA, Bart DB, Hoppin JA, McCauley L, Grzywacs JG, Robson MG (2006) Farmworker exposure to pesticides: methodology issues for the collection of comparable data. Environ Health Persp 11:923–928CrossRef

Ascher KRS, Schmutterer H, Mazor M, Zebitz CPW, Naqvi SNH (2002) The Persian lilac or chinaberry tree: Melia azedarach L. Neem Found, Mumbai, pp 770–820

Atkinson BL, Blackman AJ, Faber H (2004) The degradation of the natural pyrethrins in crop storage. J Agric Food Chem 52:280–287PubMedCrossRef

Auger J, Thibout E (2002) Substances soufrées des Allium et des Crucifères et leurs potentialités phytosanitaires. In: Regnault-Roger C, Philogène BJR, Vincent C (eds) Biopesticides d’Origine Végétale. Lavoisier Tech & Doc, Paris, pp 77–95

Bakkali F, Averbeck S, Averbeck D, Idaomar M (2008) Biological effects of essential oils. Food Chem Toxicol 46:446–475PubMedCrossRef

Belmain S, Stevenson P (2001) Ethnobotanicals in Ghana: reviving and modernizing age-old farmer practice. Pestic Outlook 12:233–338CrossRef

Belmain SR, Neal GE, Ray DE, Golob P (2001) Insecticidal and vertebrate toxicity associated with ethnobotanicals used as post-harvest protectants in Ghana. Food Chem Toxicol 39:287–291PubMedCrossRef

Bernays EA (1990) Plant secondary compounds deterrent but not toxic to the grass specialist acridid Locusta migratoria: implications for the evolution of graminivory. Entomol Exp Appl 54:53–56CrossRef

Bernays EA (1991) Relationship between deterrence and toxicity of plant secondary compounds for the grasshopper Schistocerca americana. J Chem Ecol 17:2519–2526PubMedCrossRef

Betarbet R, Sherer TB, MacKenzie G, Garcia-Osuna M, Panov AV, Greenamyre JT (2000) Chronic systematic pesticide exposure reproduces features of Parkinson’s disease. Nature Neurosci 3:1301–1306PubMedCrossRef

Bloomquist JR (1996) Ion channels as targets for insecticides. Ann Rev Entomol 41:163–190CrossRef

Bloomquist JR (2003) Chloride channels as tools for developing selective insecticides. Arch Insect Biochem & Physiol 54:145–156CrossRef

Bloomquist JR, Boina DR, Chow E, Carlier PR, Reina M, Gonzalez-Coloma A (2008) Mode of action of the plant-derived silphinenes on insect and mammalian GABAA receptor/chloride channel complex. Pestici Biochem & Physiol 91:17–23CrossRef

Boeke SJ, Baumgart IR, van Loon JJA, van Huis A, Dicke M, Kossou DK (2004a) Toxicity and repellence of African plants traditionally used for the protection of stored cowpea against Callosobruchus maculatus. J Stored Prod Res 40:423–438

Boeke SJ, Kossou DK, van Huis A, van Loon JJA, Dicke M (2004b) Field trials with plant products to protect stored cowpea against insect damage. Int J Pest Manag 50:1–9

Bomford MK, Isman MB (1996) Desensitization of fifth instar Spodoptera litura (Lepidoptera: Noctuidae) to azadirachtin and neem. Entomol Exp Appl 81:307–313CrossRef

Bradbury SP, Coats JR (1989) Comparative toxicology of the pyrethroid insecticides. Rev Environ Contam Toxicol 108:134–177

Brown AE (2005) Mode of action of insecticides and related pest control chemicals for production agriculture, ornamentals and turf. Pesticide Info Leaflet Nr 43:1–13. http://pesticide.umd.edu

Buckle J (2003) Clinical aromatherapy: essential oils in practice. Churchill Livingstone, Edinburgh, p 416

Bussaman P, Namsena P, Rattanasena P, Chandrapatya A (2012a) Effect of crude leaf extracts on Colletotrichum gloeosporioides (Penz.) Sacc. Psyche, Article ID 309046, pp 1–6. doi:10.1155/2012/309046

Bussaman P, Sa-uth C, Rattanasena P, Chandrapatya A (2012b) Effect of crude plant extracts on Mushroom Mite, Luciaphorus sp. (Acari: Pygmephoridae). Psyche, Article ID 150958, pp 1–5. doi:10.1155/2012/150958

Buta JG, Lusby WR, Neal JW Jr, Waters RM, Piuarelli GW (1993) Sucrose esters from Nicotiana gossei active against the greenhouse whitefly, Ttialeurodes vaporatiorwll. Phytochemistry 22:859–864CrossRef

Cabizza M, Angioni A, Melis M, Cabras M, Tuberoso CV, Cabras P (2004) Rotenone and rotenoids in cubé resins, formulations, and residues on olives. J Agric Food Chem 52:288–293PubMedCrossRef

Caboni P, Cabras M, Angioni A, Russo M, Cabras P (2002) Persistence of azadirachtin residues on olives after field treatment. J Agric Food Chem 50:3491–3494PubMedCrossRef

Cabras P, Caboni P, Cabras M, Angioni A, Russo M (2002) Rotenone residues on olives and in olive oil. J Agric Food Chem 50:2576–2580PubMedCrossRef

Cagen SZ, Malley LA, Parker CM, Cardiner TH, van Gelder GA, Jud VA (1984) Pyrethroid-mediated skin sensory stimulation characterized by a new behavioral paradigm. Toxicol Appl Pharmacol 76:270–279PubMedCrossRef

Carpinella MC, Defago MT, Valladares G, Palacios SM (2003) Antifeedant and insecticide properties of a limonoid from Melia azedarach (Meliaceae) with potential use for pest management. J Agric Food Chem 51:369–374PubMedCrossRef

Casanova H, Ortiz C, Pel’aez C, Vallejo A, Moreno ME, Acevedo M (2002) Insecticide formulations based on nicotine oleate stabilized by sodium caseinate. J Agric Food Chem 50:6389–6394PubMedCrossRef

Casida JE (1973) Pyrethrum the natural insecticide. Academic Press, New York, p 329

Casida JE, Quistad GB (1995) Pyrethrum flowers: production, chemistry, toxicology and uses. Oxford Univ Press, Oxford, p 356

CDPR (California Department of Pesticide Regulation) (2005) Summary of pesticide use report data 2003, indexed by chemical. http://www.cdpr.ca.gov/ (Accessed: 25 March 2013)

Céspedes CL, Calderón JS, Lina L, Aranda E (2000) Growth inhibitory effects on fall armyworm Spodoptera frugiperda of some limonoids isolated from Cedrela spp (Meliaceae). J Agric Food Chem 48:1903–1908PubMedCrossRef

Céspedes CL, Avila JG, Marin JC, Domínguez ML, Torres P, Aranda E (2006) Natural compounds as antioxidant and molting inhibitors can play a role as a model for search of new botanical pesticides, Rai and Carpinella (eds) Naturally Occurring Bioactive Compounds, ISBN-13:978–0-444-52241-2, Chapter 1:1–27

Charleston DS (2004) Integrating biological control and botanical pesticides for management of Plutella xylostella. PhD Thesis Wageningen Univ, p 176

Chen W, Isman MB, Chiu SF (1995) Antifeedant and growth inhibitory effects of the limonoid toosendanin and Melia toosendan extracts on the variegated cutworm, Peridroma saucia (Lep., Noctuidae). J Appl Entomol 119:367–370CrossRef

Childs FJ, Chamberlain JR, Antwi EA et al (2001) Improvement of neem and its potential benefits to poor farmers. Dept of Internat Develop, UK, p 32

Chiu SF (1988) Recent advances in research on botanical insecticides in China. In: Arnason AT, Philogène BJR, Morand P (eds) Insecticides of plant origin. American Chemical Society, Washington, DC. pp 69–77

Coats JR (1990) Mechanisms of toxic action and structure-activity relationships for organochlorine and synthetic pyrethroid insecticides. Environ Health Perspect 87:255–262PubMedPubMedCentralCrossRef

Coats JR (1994) Risks from natural versus synthetic insecticides. Annu Rev Entomol 39:489–515PubMedCrossRef

Coats JR, Symonik DM, Bradbury SP, Dyer SD, Timson LK, Atchison GJ (1989) Toxicology of synthetic pyrethroids in aquatic organisms: an overview. Environ Toxicol Chem 8:671–679CrossRef

Coats JR, Karr LL, Drewes CD (1991) Toxicity and neurotoxic e!ects of monoterpenoids in insects and earthworms. Am Chem Soc Symp Ser 449:306–316

Coppen JJW (1995) Flavours and fragrances of plant origin. Food and Agriculture Organization, Rome, p 101

Copping LG (2001) The biopesticide manual, 2nd edn. British Crop Protection Council, Farnham, p 528

Copping LG, Menn JJ (2000) Biopesticides: a review of their action, applications and efficacy. Pest Manag Sci 56:651–676CrossRef

Davies IH (1985) The pyrethroids: an historical introduction. In: Leahey JP (ed) The pyrethroid insecticides. Taylor and Francis, Philadelphia, p 440

Delaplane KS (1992) Controlling tracheal mites (Acari: Tarsonemidae) in colonies of honey bees (Apidae) with vegetable oil and menthol. J Econ Entomol 85:2118–2124CrossRef

Deng AL, Ogendo JO, Owuor G, Bett PK, Omolo EO, Mugisha-Kamatenesi M, Mihale JM (2009) Factors determining the use of botanical insect pest control methods by small-holder farmers in the Lake Victoria basin, Kenya. African J Environ Sci & Technol 3:108–115

Dev S, Koul O (1997) Insecticides of natural origin. Harwood Acad, Amsterdam, p 365

Dimetry NZ (2012) Prospects of botanical pesticides for the future in integrated pest management programme (IPM) with special reference to neem uses in Egypt. Arch Phytopathol & Plant Prot 45:1138–1161CrossRef

Dimetry NZ, El-Hawary FMA (1997) Synergistic effect of some additives on the biological activity and toxicity of Neem-based formulations against the cowpea aphid, Aphis craccivora Koch. Internat J Tropical Insect Sci 17:395–399CrossRef

Dimetry NZ, Amer SAA, Reda AS (1993) Biological activity of 2 Neem seed kernel extracts against the 2-spotted spider mite Tetranychus urticae. J Appl Entomol 116: 308–312CrossRef

Dimetry NZ, Abd El-Salam AME, El-Hawary FMA (2010) Importance of plant extract formulations in managing different pests attacking beans in new reclaimed area and under storage conditions. Arch Phytopathol & Plant Prot 43:700–711CrossRef

Dosemeci M, Alavanja MC, Rowland AS, Mage D, Zahm SH, Rothman N, Lubin JH, Hoppin JA, Sandler DP, Blair A (2002) A quantitative approach for estimating exposure to pesticides in the agricultural health study. Ann Occup Hyp 46:245–260

El-Sayed EI (1982–1983a) Evaluation of the insecticidal properties of the common Indian neem (Azadirachta Indica A Juss) seeds against the Egyptian cotton leaf worm (Spodoptera litoralis) (Boisd.). Bull Entomol Soc Egypt, Econ Ser 13:39–47

El-Sayed EI (1982–1983b) Neem (Azadirachta indica A. Juss) seeds as antifeedant and ovipositional repellent for the Egyptian cotton leafworm Spodoptera littoralis (Boisd.). Bull Entomol Soc Egypt, Econ Ser 13:49–58

El-Hawary FMA, Sammour EA (2006) The bioactivity and mechanism of action of some wild plant extracts on Aphis craccivora. Bull NRC, Egypt 31:545–556

El-Hosary RA (2011) Evaluation of some essential oils against Sesamia cretica Led. under field conditions. J Am Sci 7:563–568

El-Sebai TN, El-Wakeil NE, Abdallah SA (2005) Efficacy of certain mineral, natural oils and insecticides against the Whitefly, Bemisia tabaci on cucumber plants and their side effects on the associated predators. Bull Entomol Soc Egypt, Econ Ser 31:229–241

El-Shazly AM, Dora G, Wink M (2005) Alkaloids of Haloxylon salicornicum (Moq.) Bunge ex Boiss. (Chenopodiaceae). Pharmazie 60:949–952PubMed

El-Wakeil NE, Gaafar N, Vidal S (2006) Side effect of some neem products on natural enemies of Helicoverpa, Trichogramma spp. And Chrysoperla carnea. Archiv Phytopathol & Plant Prot 39:445–455CrossRef

El-Wakeil N, Gaafar N, Sallam A, Volkmar C (2013) Side effects of insecticide applications on natural enemies and possibility of integration in plant protection strategies. Published in book “Insecticides: development of safer and more effective technologies” (ISBN 978-953-51-0958-7) Intech Open Access Publisher, pp 3–56

Enan E (2001) Insecticidal activity of essential oils: octopaminergic sites of action. Comp Biochem Physiol 130C:325–337

Enan EE (2005a) Molecular and pharmacological analysis of an octopamine receptor from American cockroach and fruit fly in response to plant essential oils. Arch Insect Biochem & Physiol 59:161–171

Enan EE (2005b) Molecular response of Drosophila melanogaster tyramine receptor cascade to plant essential oils. Insect Biochem & Molec Biol 35:309–321

Fang N, Casida J (1998) Anticancer action of cubè insecticide: correlation for rotenoid constituents between inhibition of NADH-ubiquinone oxidoreductase and induced ornithine decarboxylase activities. Proc. Natl Acad Sci USA 95:3380–3384CrossRef

Farone WA, Palmer T, Puterka J (2002) Polyol ester insecticides and method of synthesis. U.S. Patent 6,419,941

Feng R, Chen W, Isman MB (1995) Synergism of malathion and inhibition of midgut esterase activities by an extract from Melia Toosendan (Meliaceae). Pestic Biochem Physiol 53:34–41CrossRef

Fields PG, Xie YS, Hou X (2001) Repellent effect of pea (Pisum sativum) fractions against stored-product pests. J Stored Prod Res 37:359–370PubMedCrossRef

Floris I, Satta A, Cabras P, Garau VL, Angioni A (2004) Comparison between two thymol formulations in the control of Varroa destructor: effectiveness, persistence and residues. J Econ Entomol 97:187–191PubMedCrossRef

Forget G, Goodman T, de Villiers A (eds) (1993) Impact of pesticide use on health in developing countries. Int Dev Res Centre, Ottawa p 335

Fradin MS, Day JF (2002) Comparative efficacy of insect repellents against mosquito bites. N Engl J Med 347:13–18PubMedCrossRef

Gilkeson LA, Adams RW (2000) Integrated pest management manual for landscape pests in British Columbia. Province of British Columbia Press, p 130

Glynne-Jones A (2001) Pyrethrum. Pestic Outlook 12:195–198CrossRef

Gonzalez-Coloma A, Valencia F, Martin N, Hoffmann JJ, Hutter L et al (2002) Silphinene sesquiterpenes as model insect antifeedants. J Chem Ecol 28:117–129PubMedCrossRef

Grundy DL, Still CC (1985) Inhibition of acetylcholinesterases by pulegone1, 2- epoxide. Pestici Biochem & Physiol 23:383–388CrossRef

Guerrero A, Rosell G (2004) Enzyme inhibitors in biorational approaches for pest control. Mini-Rev Med Chem 4:757–767PubMed

Guerrero A, Rosell G (2005) Biorational approaches for insect control by enzymatic inhibition. Curr Med Chem 12:461–469PubMedCrossRef

Hayes WJ Jr (1982) Pesticides studied in man. Williams & Wilkins, Baltimore, p 672

Haynes KF (1988) Sublethal effects of neurotoxic insecticides on insect behaviour. Ann Rev Entomol 33:149–168CrossRef

Hedin PA, Hollingworth RM, Masler EP, Miyamoto J, Thompson DG (eds) (1997) Phytochemicals for pest control. American Chemical Society, Washington, DC, p 372CrossRef

Henk PM, Vijverberg JM, Van Der Zalm, Van Den Bercken J (1982) Similar mode of action of pyrethroids and DDT on sodium channel gating in myelinated nerves. Nature 295:601–603. doi:10.1038/295601a0CrossRef

Henn T, Weinzierl R, Gray M, Steffey K (1991) Alternatives in insect management: field and forage crops. Cooperative extension service, University of Illinois at Urbana-Champaign, Circ. 1307

Hollingworth R, Ahmmadsahib K, Gedelhak G, McLaughlin J (1994) Newinhibitors of complex I of the mitochondrial electron transport chain with activity as pesticides. Biochem Soc Trans 22:230–233PubMedCrossRef

Hussein HI (2005) Composition of essential oils isolated from three plant species and their molluscicidal activity against Theba pisana snails. J Pest Cont Environ Sci 13:15–24

Immaraju JA (1998) The commercial use of azadirachtin and its integration into viable pest control programmes. Pestic Sci 54:285–289CrossRef

Ismail AI, Abd El-Salam AME, Soliman MMM (2004) Field evaluation of plant derivative and chemical compounds and their mixtures against Ceroplastes floridensis Com. on orange trees. Egypt J Biol Pest Control 14:175–179

Isman MB (1993) Growth inhibitory and antifeedant effects of azadirachtin on six noctuids of regional economic importance. Pestic Sci 38:57–63CrossRef

Isman MB (1997) Neem and other botanical insecticides: barriers to commercialization. Phytoparasitica 25:339–344CrossRef

Isman MB (1999) Pesticides based on plant essential oils. Pestic Outlook 10:68–72

Isman MB (2000) Plant essential oils for pest and disease management. Crop Prot 19:603–608CrossRef

Isman MB (2002) Insect antifeedants. Pestic Outlook 13:152–157CrossRef

Isman MB (2004) Factors limiting commercial success of neem insecticides in North America and Western Europe. In: Koul O, Wahab S (eds) Neem: today and in the new millennium. Kluwer Acad, Dordrecht, p 33–41CrossRef

Isman MB (2005) Problems and opportunities for the commercialization of botanical insecticides. In Regnault-Roger C, Philogène BJR, Vincent C (eds) Biopesticides of plant origin. Lavoisier, Paris, pp 283–291

Isman MB (2006) Botanical insecticides, deterrents, and repellents in modern agriculture and an increasingly regulated world. Annu Rev Entomol 51:45–66PubMedCrossRef

Isman MB (2008) Botanical insecticides: for richer, for poorer. Pest Manag Sci 64:8–11PubMedCrossRef

Isman MB, Matsuura H, MacKinnon S, Durst T, Towers GHN, Arnason JT (1996) Phytochemistry of the Meliaceae. So many terpenoids, so few insecticides. In: Romeo JT, Saunders JA, Barbosa P (eds) Phytochemical diversity and redundancy. Plenum, New York, pp 155–178CrossRef

Jacobson M (ed) (1989) Focus on phytochemical pesticides, vol 1: the neem tree. CRC Press, Boca Raton, p 178

Johnson HA, Oberlies NH, Alali FQ, McLaughlin JE (2000) Thwarting resistance: annonaceous acetogenins as new pesticidal and antitumor agents. In Cutler SJ, Cutler JG (eds) Biological active natural products: pharmaceuticals. Boca Raton, CRC Press, pp 173–83

Jayasekara TK, Stevenson PC, Hall DR, Belmain SR (2005) Effect of volatile constituents from Securidaca longepedunculata on insect pests of stored grain. J Chem Ecol 31:303–313PubMedCrossRef

Katz J, Prescott K, Woolf AD (1996) Strychnine poisoning from a Cambodian traditional remedy. Am J Emerg Med 14:475–477PubMedCrossRef

Keane S, Ryan MF (1999) Purification, characterisation and inhibition of monoterpenes of acetylcholonesterase from the waxmoth, Galleria melonella. Insect Biochem & Molec Biol 29:1097–1104CrossRef

Khambay BP, Batty D, Jewess PJ, Bateman GL, Hollomon DW (2003) Mode of action and pesticidal activity of the natural product dunnione and of some analogues. Pest Manag Sci 59:174–182PubMedCrossRef

Khater HF (2012) Ecosmart biorational insecticides: alternative insect control strategies, insecticides- advances in integrated pest management, ed F Perveen, ISBN: 978-953-307-780-2, InTech publisher, pp 17–60

Klein Gebbinck EA, Jansen BJM, de Groot A (2002) Insect antifeedant activity of clerodane dieterpenes and related model compounds. Phytochemistry 61:737–770PubMedCrossRef

Kostyukovsky M, Rafaeli A, Gileadi C, Demchenko N, Shaaya E (2002) Activation of octopaminergic receptors by essential oil constituents isolated from aromatic plants: possible mode of action against insect pests. Pest Manag Sci 58:1101–1106PubMedCrossRef

Koul O, Dhaliwal GS (2001) Phytochemical biopesticides. Harwood Acad, Amster, p 223

Kraus W (2002) Azadirachtin and other triterpenoids. Neem Found, Mumbai, pp 39–111

Kubo I (2000) Tyrosinase inhibitors from plants. Rev Latinoamer Quim 28:7–20

Kukel CF, Jennings KR (1994) Delphinium alkaloids as inhibitors of alpha-bungarotoxin binding to rat and insect neural membranes. Can J Physiol & Pharmacol 72:104–107CrossRef

Kurita N, Miyaji M, Kurane R, Takahara Y (1981) Antifungal activity of components of essential oils. Agric Biol Chem 45:945–952

Leatemia JA, Isman MB (2004a) Efficacy of crude seed extracts of Annona squamosa against Plutella xylostella L. in the greenhouse. Int J Pest Manag 50:129–133

Leatemia JA, Isman MB (2004b) Insecticidal activity of crude seed extracts of Annona spp., Lansium domesticum and Sandoricum koetjape against lepidopteran larvae. Phytoparasitica 32:30–37

Lewis MA, Arnason JT, Philogene, BJR, Rupprecht JK, Mclaughlin JL (1993) Inhibition of respiration at site I by Asimicin, an insecticidal Acetogenin of the Pawpaw, Asimina triloba (Annonaceae). Pestic Biochem & Physiol 45:15–23CrossRef

Londershausen M, Leight W, Lieb F, Moeschler H (1991) Molecular mode of action of annonins. Pestic Sci 33:427–438CrossRef

Lowery DT, Isman MB (1995) Toxicity of neem to natural enemies of aphids. Phytoparasitica 23:297–306CrossRef

Maistrello L, Henderson G, Laine RA (2004) Efficacy of vetiver oil and nootkatone as soil barriers against Formosan subterranean termite. J Econ Entomol 94:1532–1537CrossRef

Marco GJ, Hollingworth RM, Durham W (eds) (1987) Silent Spring Revisited. American Chemical Society, Washington, DC, p 214

Matsuzaki T, Shinozaki Y, Suhara S, Tobita T, Shigematsu H, Koiwai A (1991) Leaf surface glycolipids from Nicotiana acuminate & Nicotiana pauciflora. Agric Biol Chem 55:1417–1419

McLaughlin GA (1973) History of pyrethrum. Academic, New York, pp 3–15

McLaughlin JL, Zeng L, Oberlies NJ, Alfonso D, Johnson JA, Cummings BA (1997) Annonaceous acetogenins as new natural pesticides: recent progress. Washington, DC Am Chem Soc, pp 117–133

Mikolajczak KL, McLaughlin JL, Rupprecht JK (1988) Control of Pests with Annonaceous Acetogenins. (divisional patent on asimicin) U.S. Patent No. 4,855,319

Miyazawa M, Watanabe H, Kameoka H (1997) Inhibition of acetylcholinesterase activity by monoterpenoids with a pmenthane skeleton. J Agric & Food Chem 45:677–679CrossRef

Moeschler HF, Pfuger W, Wendlisch D (1987) Pure annonin and a process for the preparation thereof. U.S. Patent No. 4,689,323

Morse S, Ward A, McNamara N, Denholm I (2002) Exploring the factors that influence the uptake of botanical insecticides by farmers: a case study of tobacco-based products in Nigeria. Exp Agric 38:469–479CrossRef

Narahashi T (1976) Effects of insecticides on nervous conduction and synaptic transmission Editor(s): Wilkinson, Christopher Foster. Insectic Biochem Physiol pp 327–352 nPublisher: Plenum, New York, NY CODEN: 34LXAP; English

Nathanson JA, Hunnicutt EJ, Kantham L, Scavon C (1993) Cocaine as a naturally occurring insecticide. Proc National Acad Sci USA 90:9645–9648CrossRef

National Research Council (1992) Neem. A tree for solving global problems. National Academy Press, Washington, DC, p 141

National Research Council (2000) The future role of pesticides in US Agriculture. National Academy Press, Washington, DC, p 301

Naumann K, Isman MB (1996) Toxicity of neem (Azadirachta indica A. uss) seed extracts to larval honeybees and estimation of dangers from field applications. Am Bee J 136:518–520

Ngoh SP, Hoo L, Pang FY, Huang Y, Kini MR, Ho SH (1998) Insecticidal and repellent properties of nine volatile constituents of essential oils against the American cockroach. Periplaneta Americana (L.). Pestic Sci 54:261–268CrossRef

Okuna Y, Sen T, Ito S, Kaneko H, Watanabe T et al (1986) Differential metabolism of fenvalerate and granuloma fonnation. II. Toxicological significance of a lipophilic conjugate from fenvalerate. Toxicol Appl Pharmacol 83:157–169CrossRef

Pavela R, Vrchotová N, Šerá B (2008) Growth inhibitory effect of extracts from Reynoutria sp. plants against Spodoptera littoralis larvae. Agrociencia 42:573–584

Perry AS, Yamamoto I, Ishaaya I, Perry RY (1998) Insecticides in Agriculture and Environment: Retrospects and Prospects. Springer-Verlag, Berlin, p 261CrossRef

Pesticide Action Network (2004) Pesticide registration by country. http://www. pesticideinfo.org/SearchCountries.jsp (Accessed: 15 April 2013)

Peterson C, Coats J (2001) Insect repellents past, present and future. Pestic Outlook 12:154–158CrossRef

Philogène BJR, Arnason JT, Towers GHN, Abramowski Z, Campos F, Champagne D, McLachlan D (1984) Berberine: a naturally occurring phototoxic alkaloid. J Chem Ecol 10:115–123PubMedCrossRef

Philogène BJR, Regnault-Roger C, Vincent C (2005) Botanicals: yesteday’s and today’s promises. In: Regnault-Roger C, Philogène BJR, Vincent C (eds) Biopesticides of plant origin. Lavoisier and Andover, UK, pp 1–15

Pittarelli GW, Buta JG, Neal JW Jr, Lusby WR, Waters RM (1993) Biological pesticide derived from Nicotiana Plants. U.S. Patent No. 5,260,281

Prakash A, Rao J (1997) Botanical pesticides in agriculture. CRC Press, Boca Raton, p 461

Priestley CM, Williamson EM, Wafford KA, Sattelle DB (2003) Thymol, a constituent of thyme essential oil, is a positive allosteric modulator of human GABAA receptors and a homo-oligomeric GABA receptor from Drosophila melanogaster. Br J Pharmacol 140:1363–1372PubMedPubMedCentralCrossRef

Quarles W (1996) EPA exempts least-toxic pesticides. IPM Pract 18:16–17

Ratra GS, Casida JE (2001) GABA receptor subunit composition relative to insecticide potency and selectivity. Toxicol Letters 122:215–222CrossRef

Rattan RS (2010) Mechanism of action of insecticidal secondary metabolites of plant origin. Crop Prot 29:913–920CrossRef

Regnault-Roger C, Philogène BJR (2008) Past and current prospects for the use of botanicals and plant allelochemicals in integrated pest management. Pharmac Biol 46:41–52CrossRef

Regnault-Roger C, Hamraoui A, Holeman M, Théron E, Pinel R (1993) Insecticidal effect of essential oils from mediterranean plants upon A. obtectus Say (Coleoptera, Bruchidae), a pest of kidney bean (Phaseolus vulgaris L.). J Chem Ecol 19:1231–1242CrossRef

Regnault-Roger C, Philogène BJR, Vincent C (eds) (2005) Biopesticides of plant origin. Lavoisier, Paris, p 313

Rembold H, Mwangi R (2002) Melia volkensii Gürke. Neem Found, Mumbai, pp 827–32

Rice PJ, Coats JR (1994) Insecticidal properties of monoterpenoid derivatives to the house fly (Muscidae) and red flour beetle (Tenebrionidae). Pestic Sci 41:195–202CrossRef

Richards AG, Cutkomp LA (1945) Cholinesterase of insect nerves. J Cell Comp Physiol 26:57–61CrossRef

Ryan MF, Byrne O (1988) Plant-insect coevolution and inhibition of acetylcholineesterase. J Chem Ecol 14:1965–1975PubMedCrossRef

Salama HS, Sharaby AM (1988) Feeding deterrence induced by some plants in Spodoptera littoralis and their potentiating effect on Bacillus thuringiensis Berliner. Internat J Tropical Insect Sci 9: 573–577CrossRef

Salama HS, Wassel G, Saleh R (1970) Resistance of some varieties of Mangifera indica (L.) to scale insects infestation due to flavonoids. Curr Sci 39:497

Sallam AA, Volkmar C, El-Wakeil NE (2009) Effectiveness of different bio–rational insecticides applied on wheat plants to control cereal aphids. J Plant Dis & Prot 116:283–287CrossRef

Sallena RC (1989) Insecticides from neem. In: Amason IT, Phllogene BJR, Morand P (eds) Insecticides of plant origin. American Chemical Society, Washington, DC, p 213

Sammour EA, El-Hawary FM, Abdel-Aziz NF (2011) Comparative study on the efficacy of neemix and basil oil formulations on the cowpea aphid Aphis craccivora Koch. Arch Phytopathol & Plant Prot 44:655–670CrossRef

Schmutterer H (1990) Properties and potential of natural pesticides from the neem tree, Azadirachta indica. Annu Rev Entomol 35:271–297PubMedCrossRef

Schmutterer H (ed) (2002) The neem tree. Neem Found, Mumbai, p 892

Sharaby AM (1988) Anti-insect properties of the essential oil of lemon grass, Cymbopogen citratus against Spodoptera exigua (Hbn). Internat J Trop Insect Sci 9:77–80CrossRef

Shepard H (1951) The chemistry and action of insecticides. McGraw-Hill, New York, p 504

Spollen KM, Isman MB (1996) Acute and sublethal effects of a neem insecticide on the commercial biocontrol agents Phytoseiulus persimilis and Amblyseius cucumeris and Aphidoletes aphidimyza. J Econ Entomol 89:1379–1386CrossRef

Stroh J, Wan MT, Isman MB, Moul DJ (1998) Evaluation of the acute toxicity to juvenile Pacific coho salmon and rainbow trout of some plant essential oils, a formulated product, and the carrier. Bull Environ Contam Toxicol 60:923–930PubMedCrossRef

Tamayo MC, Rufat M, Bravo JM, San Segundo B (2000) Accumulation of a maize proteinase inhibitor in response to wounding and insect feeding and characterization of its activity toward digestive proteinases of Spodoptera littoralis larvae. Planta 211:62–71PubMedCrossRef

Tang JD, Gilboa S, Roush RT, Shelton AM (1997) Inheritance, stability and lack-of-fitness costs of field-selected resistance to Bacillus thuringiensis in diamondback moth (Lepidoptera: Plutellidae) from Florida. J Econ Entomol 90:732–741CrossRef

Thacker JMR (2002) An introduction to arthropod pest control. Cambridge University Press, Cambridge, p 343

Thibout E, Auger J (1997) Composés soufrés des Allium et lutte contre les insectes. Acta Bot Gallica 144:419–426CrossRef

Thibout E, Lecomte C, Auger J (1986) Substances soufrées des Allium et insectes. Acta Bot Gallica 143:137–142CrossRef

Trumble JT (2002) Caveat emptor: safety considerations for natural products used in arthropod control. Am Entomol 48:7–13CrossRef

Wan MT, Watts RG, Isman MB, Strub R (1996) An evaluation of the acute toxicity to juvenile Pacific northwest salmon of azadirachtin, neem extract and neem-based products. Bull Environ Contam Toxicol 56:432–439PubMedCrossRef

Ware GW (1983) Pesticides. Theory and application. Freeman, San Francisco, p 308

Ware GW (1988) The pesticide book. Thomson Publication, USA

Weinzierl RA (2000) Botanical insecticides, soaps, and oils. In: Rechcigl JE, Rechcigl NA (eds) Biological and biotechnological control of insect pests. Lewis Publishers, Boca Raton, pp 101–121

Whittaker RH, Feeny P (1971) Allelochemicals: chemical interactions between species. Science 171:757–770PubMedCrossRef

Yamamoto C, Kurokawa M (1970) Synaptic potentials recorded in brain slices and their modification by changes in the level of tissue ATP. Exp Brain Res 10:159–170PubMedCrossRef

Zhao JZ, Li YX, Collins HL, Gusukuma-Minuto L, Mau RFL et al (2002) Monitoring and characterization of diamondback moth resistance to spinosad. J Econ Ent 95:430–436CrossRef

Title: RETRACTED ARTICLE: Botanical Pesticides and Their Mode of Action
Author: Dr. Nabil E. El-Wakeil
Publication date: 01-12-2013
Publisher: Springer Berlin Heidelberg
Published in: Journal of Crop Health / Issue 4/2013
Print ISSN: 2948-264X
Electronic ISSN: 2948-2658
DOI: https://doi.org/10.1007/s10343-013-0308-3

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