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Insecticides. Stephen J. Toth, Jr. Wayne G. Buhler Department of Entomology Department of Horticultural Science North Carolina State University North Carolina State University. Photograph by Scott Bauer. Insects and Mites. 99% of species are of minor importance
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Insecticides Stephen J. Toth, Jr. Wayne G. Buhler Department of Entomology Department of Horticultural Science North Carolina State University North Carolina State University Photograph by Scott Bauer
Insects and Mites • 99% of species are of minor importance • Beneficial insects and mites are small group which include honey bees, lady beetles, parasitic wasps, and predaceous mites • Destructive insects and mites represent the smallest but most notable group Photographs by Steve Bambara and Jack Bacheler.
History of Insecticide Use • Greek philosopher Homer reported the use of sulfur for fumigation and other pest control uses (1000 B.C.) • Pliny the Elder reported pest control practices from Greek literature (70 A.D.); included use of pepper and tobacco extracts, soapy water, vinegar, turpentine, fish oil, brine, lye, etc.
History of Insecticide Use • As recently as the 1940s, insecticides limited to the arsenicals, petroleum oils, nicotine, pyrethrum, rotenone, sulfur, hydrogen cyanide gas and cryolite • Synthetic organic insecticides introduced after World War II National Agriculture Library
The Criteria for JudgingInsecticide Effectiveness • Controls insects • Cost effective • Environmentally safe • Can be used safely Tim McCabe
Mode of Action of Insecticides • Nerve poisons (axonic and synaptic) • Metabolic inhibitors • Muscle poisons • Alkylating agents • Physical toxicants • Cytolytic (cellular) toxins USDA/ARS
Mode of Action of InsecticidesNerve Poisons • Axonic poisons: effect electronic transmission of nerve impulses along nerve axon; cause repetitive discharges of nerves that eventually results in paralysis; examples include DDT, pyrethrum and synthetic pyrethroids • Synaptic poisons: effect electronic transmission (chemical) of nerve impulse across junction between nerve cells (synapses); cause repetitive discharges of nerves that results in paralysis; examples include organochlorines, organphosphates, carbamates and nicotine
Mode of Action of Insecticides • Metabolic inhibitors: effect electron transport chain; examples are rotenone (slows heartbeat, depresses respiration and oxygen consumption, and causes paralysis and death) and arsenicals (inhibit respiratory enzymes) • Muscle poisons: have a direct action on muscle tissue; examples are ryania and sabadilla which increases oxygen consumption, followed by paralysis and death • Alkylating agents: react directly with chromosomes and enzymes in cells; examples are fumigants such as methyl bromide and ethylene dibromide
Mode of Action of Insecticides • Physical toxicants: mechanically blocks a physiological process; examples are oil (blocks respiratory openings in insects) and boric acid and silica gel (effects insect cuticle causing dehydration and death) • Cytolytic (cellular) toxins: cause cells to rupture and disintegrate; example is Bacillus thuringiensis which is ingested by insects and disrupts cells in the gut (causing paralysis of gut and cessation of feeding)
Routes of Exposure to Insecticides • Stomach poisons: insecticide must be ingested by the insect for toxic effect • Contact poisons: the insect must come into contact with insecticide for toxic effect Scott Bauer
Classes of Insecticides: Inorganics • Inorganic insecticides do not contain carbon • Usually white and crystalline, resembling salts • Stable chemicals (persistent), do not evaporate and are frequently soluble in water • Sulfur: stomach poison; oldest known insecticide; controls mites, thrips, scale insects and caterpillars • Arsenicals: stomach poisons; very useful to agriculture from 1930 to 1956; include Paris green, lead arsenate and calcium arsenate • Others: cryolite (fluorine), boric acid and silica gels
Classes of Insecticides: Botanicals • Botanical insecticides are toxicants derived from plants • Flowers, leaves and roots are finely ground and used, or toxic ingredients of plants are extracted and used alone or in mixture; expensive; low toxicity to mammals • Used for centuries; maximum use in U. S. in the 1960s • Nicotine: tobacco extracts, nicotine sulfate; nicotine is a nerve poison (mimics acetylcholine at nerve synapse) Ken Hammond
Classes of Insecticides: Botanicals • Rotenone: roots of Derris or cube plants; rotenone is both contact and stomach poison; used for control of many insects and fish • Pyrethrum: extracted from flower of chrysanthemum; nerve poison that paralyzes insects quickly (“knock down” effect); used in household sprays and aerosols, and on many vegetables, fruits and ornamental plants • Others: Ryania (roots of shrub), Limonene (citrus peels), Sabadilla (seeds of lily) and Neem (oil extracts of neem tree seeds)
Classes of Insecticides: Organochlorines • Insecticides that contain carbon (organo-),chlorine and hydrogen; also known as chlorinated hydrocarbons • Highly persistent and bioaccumulate in environment • DDT: nerve poison (effects axon); more than 4 billion pounds used in agriculture and for public health; very inexpensive to produce (22 cents per pound); DDT’s persistence in the environment resulted in ban of its use in U. S. in 1973
Classes of Insecticides: Organochlorines • Lindane: gamma isomer of benzenehexachloride; nerve poison that resembles DDT; limited uses remain • Cyclodienes: includes chlordane, aldrin, dieldrin and heptachlor; extremely persistent insecticides and stable in the soil; used in soil to control termites and soil insect pests of agriculture; uses cancelled (1975-1988) • Toxaphene: a polychloroterpene; once used on cotton
Classes of Insecticides: Organophosphates • Insecticides that contain phosphorus • Distinctive features are their acute toxicity to vertebrate animals and chemical instability (less persistent in the environment than organochlorines); related to nerve gases • Nerve poisons that inhibit acetylcholinesterase at nerve synapses; cause rapid twitching of muscles and paralysis • Examples include malathion, chlorpyrifos (Dursban), diazinon and methyl parathion
Classes of Insecticides: Carbamates • Insecticides that are derivatives of carbamic acid • Distinctive features are their low toxicity to mammals (exception is aldicarb) and broad spectrum of insect control (used widely for lawn and garden insects) • Nerve poisons that inhibit acetylcholinesterase at nerve synapses; cause rapid twitching of muscles and paralysis • Examples are carbaryl (Sevin) and aldicarb (Temik)
Classes of Insecticides: Pyrethroids • Synthetic insecticides related to pyrethrum (botanical) • Pyrethroids are much more stable in sunlight (persistent) than pyrethrum and effective against insects at very low application rates (0.1 pound per acre) • Nerve poisons that effect nerve axon; cause repetitive discharges of nerves which results in eventual paralysis • Examples are allethrin and permethrin
Classes of Insecticides: Biorationals • Natural or synthetic substances specific for target pest(s), but have no adverse effect on humans or environment • Insect pheromones: sex pheromones used for male trapping, monitoring, detection and mating disruption; example is gossyplure (pink bollworm) Jack Bacheler
Classes of Insecticides: Biorationals • Insect growth regulators: disrupt the growth and development of immature insects into adults; insect mortality is typically slow; examples are methoprene and fenoxycarb (Logic) • Microbials: bacteria (Bacillus thuringiensis), viruses, fungi, protozoa and nematodes that are isolated, cultured and mass-produced for use as insecticides Scott Bauer
Classes of Insecticides: New Chemicals • Nicotinoids: action similar to nicotine; example is imidacloprid (Gaucho) • Spinosyns: fermentation product of soil-inhabiting microorganisms; example is spinosid (Tracer) • Pyrrole: chlorfenapyr (Pirate) • Phenylpyrazole: fipronil (Frontline)
References • Ware, G. W. An Introduction to Insecticides. 3rd edition. Radcliffe’s IPM World Textbook. (http://ipmworld.umn.edu/chapters/ware.htm) • Ware, G. W. 1994. The Pesticide Book. 4th edition. Thomson Publications, Fresno, California. pp. 41-74.