An insecticide is a substance used to kill insects.^[1] They include ovicides and larvicides used against insect eggs and larvae, respectively. Insecticides are used in agriculture, medicine, industry and by consumers. Insecticides are claimed to be a major factor behind the increase in agricultural 20th century's productivity.^[2] Nearly all insecticides have the potential to significantly alter ecosystems; many are toxic to humans; some concentrate along the food chain.

Insecticides can be classified in two major groups as systemic insecticide which have residual or long term activity and contact insecticides, which have no residual activity.

Furthermore, one can distinguish natural insecticides, such as nicotine, pyrethrum and neem extracts, made by plants as defenses against insects, inorganic insecticides, which are metals, versus organic insecticides, which are organic chemical compounds mostly working by contact.

The mode of action describes how the pesticide kills or inactivates a pest. It provides another way of classifying insecticides. Mode of action is important in understanding whether an insecticide will be toxic to unrelated species, such as fish, birds and mammals.

For products that repel rather than kill insects see insect repellents.

Type of activity

Systemic insecticides become incorporated and distributed systemically throughout the whole plant. When insects feed on the plant, they ingest the insecticide. Systemic insecticides produced by transgenic plants are called plant-incorporated protectants (PIPs). For instance, a gene that codes for a specific Bacillus thuringiensis biocidal protein was introduced into corn and other species. The plant manufactures the protein, which kills the insect when consumed.^[3] Systemic insecticides have activity pertaining to their residue which is called "residual activity" or long-term activity.

Contact insecticides are toxic to insects upon direct contact. These can be inorganic insecticides, which are metals and include arsenates, copper and fluorine compounds, which are less commonly used, and the commonly used sulfur. Contact insecticides can be organic insecticides, i.e. organic chemical compounds, synthetically produced, and comprising the largest numbers of pesticides used today. Or they can be natural compounds like pyrethrum, neem oil etc. Contact insecticides usually have no residual activity.

Efficacy can be related to the quality of pesticide application, with small droplets, such as aerosols often improving performance.^{[4][better source needed]}

Major classes

Organochlorides

The best known organochloride, DDT, was created by Swiss scientist Paul Müller. For this discovery, he was awarded the 1948 Nobel Prize for Physiology or Medicine.^[5] DDT was introduced in 1944. It functions by opening sodium channels in the insect's nerve cells.^[6] The contemporaneous rise of the chemical industry facilitated large-scale production of DDT and related chlorinated hydrocarbons.

Organophosphates and carbamates

Organophosphates are another large class of contact insecticides. These also target the insect's nervous system. Organophosphates interfere with the enzymes acetylcholinesterase and other cholinesterases, disrupting nerve impulses and killing or disabling the insect. Organophosphate insecticides and chemical warfare nerve agents (such as sarin, tabun, soman, and VX) work in the same way. Organophosphates have a cumulative toxic effect to wildlife, so multiple exposures to the chemicals amplifies the toxicity.^[7] In the US, organophosphate use declined with the rise of substitutes.^[8]

Carbamate insecticides have similar mechanisms to organophosphates, but have a much shorter duration of action and are somewhat less toxic.^{[citation needed]}

Pyrethroids

Pyrethroid pesticides mimic the insecticidal activity of the natural compound pyrethrum, which is found in pyrethrins. These compounds are nonpersistent sodium channel modulators and are less toxic than organophosphates and carbamates. Compounds in this group are often applied against household pests.^[9]

Neonicotinoids

Neonicotinoids are synthetic analogues of the natural insecticide nicotine (with much lower acute mammalian toxicity and greater field persistence). These chemicals are acetylcholine receptor agonists. They are broad-spectrum systemic insecticides, with rapid action (minutes-hours). They are applied as sprays, drenches, seed and soil treatments. Treated insects exhibit leg tremors, rapid wing motion, stylet withdrawal (aphids), disoriented movement, paralysis and death.^[10] Imidacloprid may be the most common. It has recently come under scrutiny for allegedly pernicious effects on honeybees^[11] and its potential to increase the susceptibility of rice to planthopper attacks.^[12]

Ryanoids

Ryanoids are synthetic analogues with the same mode of action as ryanodine, a naturally occurring insecticide extracted from Ryania speciosa (Flacourtiaceae). They bind to calcium channels in cardiac and skeletal muscle, blocking nerve transmission. Only one such insecticide is currently registered, Rynaxypyr, generic name chlorantraniliprole.^[13]

Plant-incorporated protectants

Transgenic crops that act as insecticides began in 1996 with a genetically modified potato that produced the Cry protein, derived from the bacterium Bacillus thuringiensis, which is toxic to beetle larvae such as the Colorado potato beetle. The technique has been expanded to include the use of RNA interference RNAi that fatally silences crucial insect genes. RNAi likely evolved as a defense against viruses. Midgut cells in many larvae take up the molecules and help spread the signal. The technology can target only insects that have the silenced sequence, as was demonstrated when a particular RNAi affected only one of four fruit fly species. The technique is expected to replace many other insecticides, which are losing effectiveness due to the spread of pesticide resistance.^[14]

Biological

Many plants exude substances to repel insects. Premier examples are substances activated by the enzyme myrosinase. This enzyme converts glucosinolates to various compounds that are toxic to herbivorous insects. One product of this enzyme is allyl isothiocyanate, the pungent ingredient in horseradish sauces.

The myrosinase is released only upon crushing the flesh of horseradish. Since allyl isothiocyanate is harmful to the plant as well as the insect, it is stored in the harmless form of the glucosinolate, separate from the myrosinase enzyme.^[15]

In general, tree rosin is considered a natural insecticide. To be specific, the production of oleoresin by conifer species is a component of the defense response against insect attack and fungal pathogen infection.^[16]

Bacterial

Bacillus thuringiensis is a bacterial disease that affects Lepidopterans and some other insects. Toxins produced by strains of this bacterium are used as a larvicide against caterpillars, beetles, and mosquitoes. Toxins from Saccharopolyspora spinosa are isolated from fermentations and sold as Spinosad. Because these toxins have little effect on other organisms, they are considered more environmentally friendly than synthetic pesticides. The toxin from B. thuringiensis (Bt toxin) has been incorporated directly into plants through the use of genetic engineering. Other biological insecticides include products based on entomopathogenic fungi (e.g., Beauveria bassiana, Metarhizium anisopliae), nematodes (e.g., Steinernema feltiae) and viruses (e.g., Cydia pomonella granulovirus).^{[citation needed]}

Insect growth regulators

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Insect growth regulator (IGR) is a term coined to include insect hormone mimics and an earlier class of chemicals, the benzoylphenyl ureas, which inhibit chitin(exoskeleton) biosynthesis in insects. Diflubenzuron is a member of the latter class, used primarily to control caterpillars that are pests. The most successful insecticides in this class are the juvenoids (juvenile hormone analogues). Of these, methoprene is most widely used. It has no observable acute toxicity in rats and is approved by World Health Organization (WHO) for use in drinking water cisterns to combat malaria. Most of its uses are to combat insects where the adult is the pest, including mosquitoes, several fly species, and fleas. Two very similar products, hydroprene and kinoprene, are used for controlling species such as cockroaches and white flies. Methoprene was registered with the EPA in 1975. Virtually no reports of resistance have been filed. A more recent type of IGR is the ecdysone agonist tebufenozide (MIMIC), which is used in forestry and other applications for control of caterpillars, which are far more sensitive to its hormonal effects than other insect orders.

Environmental effects

Effects on nontarget species

Some insecticides kill or harm other creatures in addition to those they are intended to kill. For example, birds may be poisoned when they eat food that was recently sprayed with insecticides or when they mistake an insecticide granule on the ground for food and eat it.^[7]

Sprayed insecticide may drift from the area to which it is applied and into wildlife areas, especially when it is sprayed aerially.^[7]

DDT

The development of DDT was motivated by desire to replace more dangerous or less effective alternatives. DDT was introduced to replace lead and arsenic-based compounds, which were in widespread use in the early 1940s.^[17]

DDT was brought to public attention by Rachel Carson's book Silent Spring. One side-effect of DDT is to reduce the thickness of shells on the eggs of predatory birds. The shells sometimes become too thin to be viable, reducing bird populations. This occurs with DDT and related compounds due to the process of bioaccumulation, wherein the chemical, due to its stability and fat solubility, accumulates in organisms' fatty tissues. Also, DDT may biomagnify, which causes progressively higher concentrations in the body fat of animals farther up the food chain. The near-worldwide ban on agricultural use of DDT and related chemicals has allowed some of these birds, such as the peregrine falcon, to recover in recent years. A number of organochlorine pesticides have been banned from most uses worldwide. Globally they are controlled via the Stockholm Convention on persistent organic pollutants. These include: aldrin, chlordane, DDT, dieldrin, endrin, heptachlor, mirex and toxaphene.^{[citation needed]}

Pollinator decline

Insecticides can kill bees and may be a cause of pollinator decline, the loss of bees that pollinate plants, and colony collapse disorder (CCD),^[18] in which worker bees from a beehive or Western honey bee colony abruptly disappear. Loss of pollinators means a reduction in crop yields.^[18] Sublethal doses of insecticides (i.e. imidacloprid and other neonicotinoids) affect bee foraging behavior.^[19] However, research into the causes of CCD was inconclusive as of June 2007.^[20]

Individual insecticides

See also

• Integrated pest management
• Fogger
• Index of pesticide articles
• Endangered arthropod
• Pesticide application

References

This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed. (December 2010)

Further reading

• McWilliams, James E., "‘The Horizon Opened Up Very Greatly’: Leland O. Howard and the Transition to Chemical Insecticides in the United States, 1894–1927," Agricultural History, 82 (Fall 2008), 468–95.

External links

Look up insecticide in Wiktionary, the free dictionary.

Wikisource has the text of the 1920 Encyclopedia Americana article Insecticide.

• InsectBuzz.com - Daily updated news on insects and their relatives, including information on insecticides and their alternatives
• International Pesticide Application Research Centre (IPARC)
• Pestworld.org – Official site of the National Pest Management Association
• Classification of insecticides
• Streaming online video about efforts to reduce insecticide use in rice in Bangladesh. on Windows Media Player, on RealPlayer
• How Insecticides Work – Has a thorough explanation on how insecticides work.
• University of California Integrated pest management program
• Using Insecticides, Michigan State University Extension
• Example of Insecticide application in the Tsubo-en Zen garden (Japanese dry rock garden) in Lelystad, The Netherlands.

v t e Pest control: insecticides Carbamates Aldicarb Bendiocarb Carbaryl Carbofuran Ethienocarb Fenobucarb Oxamyl Methomyl Propoxur Inorganic compounds Aluminium phosphide Boric acid Chromated copper arsenate Copper(II) arsenate Copper(I) cyanide Diatomaceous earth Lead hydrogen arsenate Paris Green Scheele's Green Insect growth regulators Benzoylureas Flufenoxuron Lufenuron Diflubenzuron Methoprene Hydroprene Pyriproxyfen Neonicotinoids Acetamiprid Clothianidin Dinotefuran Imidacloprid Nitenpyram Nithiazine Thiacloprid Thiamethoxam Organochlorides Aldrin Beta-HCH Carbon tetrachloride Chlordane Cyclodiene 1,2-DCB 1,4-DCB 1,1-DCE 1,2-DCE DDD DDE DDT Dicofol Dieldrin Endosulfan Endrin Heptachlor Kepone Lindane Methoxychlor Mirex Tetradifon Toxaphene Organophosphorus Acephate Azamethiphos Azinphos-methyl Bensulide Chlorethoxyfos Chlorfenvinphos Chlorpyrifos Chlorpyrifos-methyl Coumaphos Demeton-S-methyl Diazinon Dicrotophos Diisopropyl fluorophosphate Dimethoate Dioxathion Disulfoton Ethion Ethoprop Fenamiphos Fenitrothion Fenthion Fosthiazate Isoxathion Malathion Methamidophos Methidathion Mevinphos Monocrotophos Naled Omethoate Oxydemeton-methyl Parathion Parathion-methyl Phenthoate Phorate Phosalone Phosmet Phoxim Pirimiphos-methyl Quinalphos Temefos Tebupirimfos Terbufos Tetrachlorvinphos Tribufos Trichlorfon Pyrethroids Acrinathrin Allethrins Bifenthrin Bioallethrin Cyfluthrin Cyhalothrin Cypermethrin Cyphenothrin Deltamethrin Empenthrin Esfenvalerate Etofenprox Fenvalerate Flumethrin Imiprothrin Metofluthrin Permethrin Phenothrin Prallethrin Pyrethrin (I, II; chrysanthemic acid) Pyrethrum Resmethrin Silafluofen Tefluthrin Tetramethrin Tralomethrin Transfluthrin Ryanoids Chlorantraniliprole Cyantraniliprole Flubendiamide Ryanodine Ryanodol Other chemicals Amitraz Azadirachtin Chlordimeform Chlorfenapyr Cyromazine Fenazaquin Fenoxycarb Fipronil Hydramethylnon Indoxacarb Limonene Pyridaben Pyriprole Ryanodine Sesamex Spinosad Sulfluramid Tebufenozide Tebufenpyrad Veracevine Xanthone Metabolites Oxon Malaoxon Paraoxon TCPy Biopesticides Bacillus thuringiensis Baculovirus Beauveria bassiana Beauveria brongniartii Metarhizium acridum Metarhizium anisopliae Nomuraea rileyi Lecanicillium lecanii Paecilomyces fumosoroseus Paenibacillus popilliae Purpureocillium lilacinum

v t e Pesticides Pesticide types Acaricide Bactericide Biocide Bioherbicide Biopesticide Fungicide Herbicide Insecticide Molluscicide Nematicide Piscicide Rodenticide Related topics Health effects Environmental effects Fumigation Agricultural spray adjuvant Biological pest control Gene silencing Green pest management Integrated pest management Maximum residue limit Non-pesticide management Persistent organic pollutant Pest control Application Drift Formulation Degradation Misuse Paradox of the pesticides Poisoning Research Residue Resistance Bee toxicity Restricted use Pesticide Action Network Silent Spring The Pesticide Question Toxicity Class By country Canada European Union New Zealand United States Integrated Pest Management Index of pesticide articles Pesticide categories

v t e Insecta orders Kingdom: Animalia Phylum: Arthropoda (unranked): Pancrustacea Subphylum: Hexapoda   Extant Monocondylia Archaeognatha (jumping bristletails) D i c o n d y l i a Apterygota * Thysanura (Zygentoma) (silverfish, firebrats) P t e r y g o t a Palaeoptera Ephemeropteroidea Ephemeroptera (mayflies) Odonatoptera Odonata (dragonflies, damselflies) N e o p t e r a Polyneoptera Plecoptera (stoneflies) Dermaptera (earwigs) Embioptera (webspinners) Phasmatodea (stick and leaf insects) Notoptera (ice-crawlers, gladiators) Orthoptera (crickets, wetas, grasshoppers, locusts) Zoraptera (angel insects) Dictyoptera Blattodea (cockroaches, termites) Mantodea (mantises) E u m e t a b o l a Paraneoptera * Psocodea (barklice, lice) Thysanoptera (thrips) Hemiptera (cicadas, aphids, true bugs) E n d o p t e r y g o t a basal Hymenoptera (sawflies, wasps, ants, bees) Neuropteroidea Coleopterida Strepsiptera (twisted-winged parasites) Coleoptera (beetles) Neuropterida Raphidioptera (snakeflies) Megaloptera (alderflies, dobsonflies, fishflies) Neuroptera (net-winged insects: lacewings, mantidflies, antlions) Panorpida (Mecopterida) Antliophora Mecoptera (scorpionflies) + Siphonaptera (fleas) Diptera (gnats, mosquitoes, flies) Amphiesmenoptera Trichoptera (caddisflies) Lepidoptera (moths, butterflies) Four most speciose orders are marked in bold Italic are paraphyletic groups Based on Sasaki et al. (2013)   Extinct Archodonata Blattoptera Caloneurodea Campylopteridae Carbotriplurida Coxoplectoptera Diaphanopterodea Eoblattodea Eocoronidae Eudiaphanoptera Erasipteridae Gerarus Geroptera Glosselytrodea Heraridea Hypoperlida Lapeyriidae Meganisoptera (griffinflies or "giant dragonflies") Megasecoptera Mendozachorista Miomoptera Monura Palaeodictyoptera Paoliida Permoplecoptera Protanisoptera Protelytroptera Protephemerida Protodiptera Protorthoptera Protozygoptera Pseudopulex Rhyniognatha Syntonoptera Titanoptera Triadophlebioptera Extinct incertae sedis families and genera are marked in italic Wikispecies

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