Organophosphate

General chemical structure of the organophosphate functional group

Organophosphates (also known as phosphate esters, or OPEs) are a class of organophosphorus compounds with the general structure O=P(OR)3, a central phosphate molecule with alkyl or aromatic substituents.[1] They can be considered as esters of phosphoric acid. Like most functional groups organophosphates occur in a diverse range of forms, with important examples including key biomolecules such as DNA, RNA and ATP, as well as many insecticides, herbicides, nerve agents and flame retardants. OPEs have been widely used in various products as flame retardants, plasticizers, and performance additives to engine oil. The popularity of OPEs as flame retardants came as a substitution for the highly regulated brominated flame retardants.[2] The low cost of production and compatibility to different polymers made OPEs to be widely used in different industries including textile, furniture, electronics as plasticizers and flame retardants. These compounds are added to the final product physically rather than by chemical bond.[3] Due to this, OPEs leak into the environment more readily through volatilization, leaching, and abrasion.[4] OPEs have been detected in different environmental compartments such as air, dust, water, sediment, soil and biota samples at higher frequency and concentration.[1][4]

Chemistry

Synthesis

Various routes exist for the synthesis of organophosphates

Esterification of phosphoric acid
OP(OH)3 + ROH → OP(OH)2(OR) + H2O
OP(OH)2(OR) + R'OH → OP(OH)(OR)(OR') + H2O
OP(OH)(OR)(OR') + R"OH → OP(OR)(OR')(OR") + H2O

Alcohols can be detached from phosphate esters by hydrolysis, which is the reverse of the above reactions. For this reason, phosphate esters are common carriers of organic groups in biosynthesis.

Oxidation of phosphite esters

Organophosphites can be readily oxidised to give organophosphates

P(OR)3 + [O] → OP(OR)3
Alcoholysis of POCl3

Phosphorus oxychloride reacts readily with alcohols to give organophosphates

O=PCl3 + 3 ROH → O=P(OR)3 + 3 HCl

Properties

The phosphate esters bearing OH groups are acidic and partially deprotonated in aqueous solution. For example, DNA and RNA are polymers of the type [PO2(OR)(OR')]n. Polyphosphates also form esters; an important example of an ester of a polyphosphate is ATP, which is the monoester of triphosphoric acid (H5P3O10).

OPEs have a central phosphate molecular group. In the case of organophosphate (OP) triesters, these are three ester bonds with alkyl or aromatic substituents. However, OP diesters are different from the triesters as one of the alkyl ester groups is replaced by a hydroxyl group, making OP diesters phosphoric acids.[2][5] The wide variety of substitutes used in organophosphate esters results in great variations in physicochemical properties, varying from highly polar to very hydrolysis resistant characteristics.[6] OPEs exhibit a wide range of octanol water partitioning coefficient where log Kow values range from -0.98 up to 10.6.[2] The predominant OPEs used as flame retardants and plasticizers have a positive log Kow values ranging between 1.44 and 9.49 signifying hydrophobicity.[2][4][5] Thus, owing to this hydrophobicity OPEs are presumptively bioaccumulated and biomagnified in aquatic ecosystems.[3] Laboratory experiments had shown that the non-halogenated OPEs are prone to photolysis, while the chlorinated OPEs such as TCEP and TCPP, however, seemed to be resistant to degradation by sunlight.[2]

In nature

Guanitoxin

Guanitoxin is a naturally occurring organophosphate produced by cyanobacteria.

The detection of OPEs in the air as far away as Antarctica at concentrations around 1 ng/m3 suggests their persistence in air, and their potential for long-range transport.[5] OPEs were measured in high frequency in air and water and widely distributed in northern hemisphere.[7][8] The chlorinated OPEs (TCEP, TCIPP, TDCIPP) in urban sampling sites and non-halogenated like TBOEP in rural areas respectively were frequently measured in the environment across multiple sites. In the Laurentian Great Lakes total OPEs concentrations were found to be 2–3 orders of magnitude higher than concentrations of brominated flame retardants measured in similar air.[8] Waters from rivers in Germany, Austria, and Spain have been consistently recorded for TBOEP and TCIPP at highest concentrations.[5] From these studies, it is clear that OPE concentrations in both air and water samples are often orders of magnitude higher than other flame retardants, and that concentrations are largely dependent on sampling location, with higher concentrations in more urban, polluted locations.

Pesticides

Today, organophosphates make up about 50% of the killing agents in chemical pesticides.[9]

Organophosphate pesticides (OPPs), like some nerve agents, inhibit acetylcholinesterase (IRAC mode of action 1b),[10] which is broadly essential for normal function in insects, but also in humans and many other animals.[11] OPPs affect this enzyme in varied ways, a principal one being through irreversible covalent inhibition,[12] and so create potentials for poisoning that vary in degree. The brain sends out neurotransmitters to the nerve endings in the body; organophosphates disrupt this process from occurring. This chemical, organophosphate works by disrupting the enzyme acetylcholinesterase. Acetylcholinesterase break down the acetylcholine neurotransmitter, which sends out signals to other nerve endings in the body.[9]

For instance, parathion, one of the first OPPs commercialized, is many times more potent than malathion, an insecticide used in combating the Mediterranean fruit fly (Med-fly) and West Nile virus-transmitting mosquitoes.[13] Human and animal exposure to them can be through ingestion of foods containing them, or via absorption through the skin or lungs.[11]

The human and animal toxicity of OPPs make them a societal health and environmental concern;[11] the EPA banned most residential uses of organophosphates in 2001, but their agricultural use, as pesticides on fruits and vegetables, is still permitted, as is their use in mosquito abatement in public spaces such as parks.[11] For instance, the most commonly used OPP in the U.S., malathion,[14] sees wide application in agriculture, residential landscaping, and pest control programs (including mosquito control in public recreation areas).[15] As of 2010, forty such OPPs were registered for use in the U.S.,[16] with at least 73 million pounds used in one time period in agricultural and residential settings.[16] Commonly used organophosphates have included:

Studies have shown that prolonged exposure to OPPs—e.g., in the case of farm workers—can lead to health problems, including increased risks for cardiovascular and respiratory disease, and cancer. In the case of pregnant women, exposure can result in premature births.[18] In addition, permanent damage to the brain's chemical make-up, and changes in human behavior and emotion can occur to the fetus in pregnant women.[19]

Organophosphate pesticides degrade rapidly by hydrolysis on exposure to sunlight, air, and soil, although small amounts can be detected in food and drinking water. Organophosphates contaminate drinking water by moving through the soil to the ground water.[20] When the pesticide degrades, it is broken down into several chemicals.[20] Organophosphates degrade faster than the organochlorides. The greater acute toxicity of OPPs results in the elevated risk associated with this class of compounds (see the Toxicity section below).

Nerve agents

History

Early pioneers in the field include Jean Louis Lassaigne (early 19th century) and Philippe de Clermont (1854). In 1932, German chemist Willy Lange and his graduate student, Gerde von Krueger, first described the cholinergic nervous system effects of organophosphates, noting a choking sensation and a dimming of vision after exposure on themselves, which they attributed to the esters themselves.[21] This discovery later inspired German chemist Gerhard Schrader at company IG Farben in the 1930s to experiment with these compounds as insecticides. Their potential use as chemical warfare agents soon became apparent, and the Nazi government put Schrader in charge of developing organophosphate (in the broader sense of the word) nerve gases. Schrader's laboratory discovered the G series of weapons, which included Sarin, Tabun, and Soman. The Nazis produced large quantities of these compounds, though did not use them during World War II. British scientists experimented with a cholinergic organophosphate of their own, called diisopropylfluorophosphate, during the war. The British later produced VX nerve agent, which was many times more potent than the G series, in the early 1950s, almost 20 years after the Germans had discovered the G series.

After World War II, American companies gained access to some information from Schrader's laboratory, and began synthesizing organophosphate pesticides in large quantities. Parathion was among the first marketed, followed by malathion and azinphosmethyl. The popularity of these insecticides increased after many of the organochlorine insecticides such as DDT, dieldrin, and heptachlor were banned in the 1970s.

Structural features

Effective organophosphates have the following structural features:

  • A terminal oxygen connected to phosphorus by a double bond, i.e. a phosphoryl group
  • Two lipophilic groups bonded to the phosphorus
  • A leaving group bonded to the phosphorus, often a halide

Fine tuning

Within these requirements, a large number of different lipophilic and leaving groups have been used. The variation of these groups is one means of fine tuning the toxicity of the compound. A good example of this chemistry are the P-thiocyanate compounds which use an aryl (or alkyl) group and an alkylamino group as the lipophilic groups. The thiocyanate is the leaving group.

Flame retardants

Flame retardants (FRs) are chemicals that have been used on different consumer materials to prevent combustion and to delay the spread of fire after ignition.[22] The increased demand to satisfy fire safety standards for flammability of plastic materials used in devices and appliances along with the strict regulation of brominated flame retardants has driven the high volume of production and consumption of OPEs.[2][5] Most flame retardants used are halogenated OPEs, and the effectiveness of the flame retardant increases with the increased number of halogenated substituents.[2][5]

OPEs are utilized as additive flame retardants which means the concentration of these flame retardants decreases with time as they readily leak into the environment.[5] There are several mechanisms flame retardants use to prevent fire, however the most effective ones are the gas phase and the solid phase reactions.[2] In the solid phase, halogenated flame retardants produce a char layer on burning materials suffocating the combustion, as well as in the gas phase they remove H+ and OH radicals from the flammable gasses, by reaction with the Br and Cl atoms to further slow down the burning process.[5] Non-halogenated OPEs are effective mainly in the solid phase of burning materials. Upon exposure to heat the phosphorus compounds react to form a polymeric form of phosphorous acid. The acid causes a char layer that covers the burning material, blocking it from contact with oxygen, which in turn slows down the combustion reaction.[2]

Health effects

Poisoning

Many "organophosphates" are potent nerve agents, functioning by inhibiting the action of acetylcholinesterase (AChE) in nerve cells. They are one of the most common causes of poisoning worldwide, and are frequently intentionally used in suicides in agricultural areas. Organophosphosphate pesticides can be absorbed by all routes, including inhalation, ingestion, and dermal absorption. Their inhibitory effects on the acetylcholinesterase enzyme lead to a pathological excess of acetylcholine in the body. Their toxicity is not limited to the acute phase, however, and chronic effects have long been noted. Neurotransmitters such as acetylcholine (which is affected by organophosphate pesticides) are profoundly important in the brain's development, and many organophosphates have neurotoxic effects on developing organisms, even from low levels of exposure. Other organophosphates are not toxic, yet their main metabolites, such as their oxons, are. Treatment includes both a pralidoxime binder and an anticholinergic such as atropine.

Chronic toxicity

Repeated or prolonged exposure to organophosphates may result in the same effects as acute exposure including the delayed symptoms. Other effects reported in workers repeatedly exposed include impaired memory and concentration, disorientation, severe depression, irritability, confusion, headache, speech difficulties, delayed reaction times, nightmares, sleepwalking, drowsiness, or insomnia. An influenza-like condition with headache, nausea, weakness, loss of appetite, and malaise has also been reported.[23]

A recent study done by Madurai Kamaraj University in India have shown a direct correlation between usage of organophosphates and diabetes among the Indian agricultural population.[24]

The physiological difference of OPEs in size and polarity greatly influences the physical and biochemical toxicity of the compound group.[1] The chemical structures of OP triesters used as flame retardants and plasticizers are essentially similar to those of OP insecticides that target the nervous system of insects.[5] Multiple toxicological studies have shown that OPEs such as TBOEP, TCIPP, TDCIPP, triethyl phosphate (TEP), and tris(methylphenyl)phosphate (TMPP) elicit effects on embryonic development, mRNA expression, thyroid hormones, circulating bile acid concentrations, and the neurological system in fish, birds, rodents, and/or humans.[25]

Low-level exposure

Even at relatively low levels, organophosphates may be hazardous to human health. These pesticides act on acetylcholinesterase,[26] an enzyme found in the brain. Thus, fetuses and young children, whose brain development depends on a strict sequence of biological events, may be most at risk.[27] They can be absorbed through the lungs or skin or by eating them on food. According to a 2008 report from the U.S. Department of Agriculture, ″detectable″ traces of organophosphate were found in a representative sample of produce tested by the agency, 28% of frozen blueberries, 20% of celery, 27% of green beans, 17% of peaches, 8% of broccoli, and 25% of strawberries.[28]

Cancer

The United States Environmental Protection Agency lists parathion as a possible human carcinogen.[29] The International Agency for Research on Cancer (IARC), found that some organophosphates may increase cancer risk.[30] Tetrachlorvinphos and parathion were classified as "possibly carcinogenic", whereas malathion and diazinon were classified as probably carcinogenic to humans.[31]

Health effects on children

A 2013 review of 27 studies on prenatal and early childhood exposures to organophosphate pesticides found all but one showed negative neurodevelopmental outcomes. In the ten studies that assessed prenatal exposure, "cognitive deficits (related to working memory) were found in children at age 7 years, behavioral deficits (related to attention) seen mainly in toddlers, and motor deficits (abnormal reflexes), seen mainly in neonates."[32]

A systematic review of neurodevelopmental effects of prenatal and postnatal organophosphate pesticide exposure was done in 2014. The review found that "Most of the studies evaluating prenatal exposure observed a negative effect on mental development and an increase in attention problems in preschool and school children."[33]

In the US the organophosphate phosmet was banned for use on household fruit trees, ornamentals, and domestic pets in 2001 as other pesticides became available for these uses. Many other uses of phosmet were still allowed, especially commercial ones.[34]

Affected populations

According to the EPA, organophosphate use in 2004 accounts for 40% of all insecticide products used in the United States.[35] Out of concerns for potential hazards of organophosphate exposure to child development, the EPA began phasing out forms of organophosphates used indoors in 2001.[35] While it is used in forestry, urban, and public health spraying (mosquito abatement programs, etc.) as well, the general population has been observed to have low exposure.[36] Thus, the primary affected population that faces exposure to organophosphates are farmworkers, especially those in countries that have fewer restrictions on its usage, such as in India.[37]

Farmworkers in the United States

In the United States, migrant and seasonal farmworkers are the most susceptible to organophosphate exposure. Of the U.S. farmworker population, there are about 4.2 million seasonal or migrant men, women, and even children, 70% of which are born in Mexico and an overwhelming 90% majority of these are Latino.[38] This almost homogenous racial aspect of employment in farm work in the United States highly suggests social, economic, and political factors undercurrents that would explain their vulnerability.[39] Half of the farmworker population in the United States do not have legal documentation and two thirds live in poverty, making it difficult to fully understand and document the characteristics of this population with relative certainty.[40] Furthermore, the group faces linguistic barriers, with about 70% of the migrant seasonal farmworker population reporting that they cannot speak English well.[41] 

In the United States, poverty and lack of documentation status puts migrant farmworkers in housing situations that make them far more likely to contract infectious or parasitic diseases and to suffer from chemical related ailments than the general U.S. population.[42] Field workers who are exposed to pesticides continue to further expose their families in their residences, especially through contaminated clothing in which the residue settles as house dust.[42] Increased rates of a full range of adverse birth outcomes result from high exposure to pesticides in a study of 500,000 births among farm workers in California's San Joaquin Valley.[43]

Economic, social, racial, and political barriers make passing policy and creating protective measures less likely to occur; in the context of their jobs, migrant seasonal farm workers are structurally vulnerable to exploitation and working conditions that are Occupational Factors not up to health standards if they are unable to find the necessary physical and social resources to protect themselves.[44]    

The nature of their job may require constant exposure to toxins and pesticides and subjects them to increasingly extreme weather as climate change progresses. Thus, migrant farm work has been ranked conservatively as possibly the second most dangerous job in the country.[45]

Regulatory efforts

Organophosphates (OPs) were among the most widely used insecticides until the 21st century.[46] And until the mid 1990s, general pesticide regulation was dependent on the Federal Food, Drug and Cosmetic Act (FFDCA) and the Federal Insecticide, Fungicide, and Rodenticide Act (FIFRA) passed in 1938 and 1947, respectively.[47] In 1993, the Environmental Protection Agency (EPA) was bound by a pledge made to Congress to significantly reduce the amount of pesticides used in the United States, and the U.S. Department of Agriculture, along with the Food and Drug Administration, joined the EPA in this commitment.[48] Then, in 1996, The Food Quality Protection Act (FQPA) was signed into law to strengthen the regulation of pesticide in food and make regulation practices more consistent.[47] One way that this strengthening was accomplished was through mandating aggregate and cumulative exposure risk assessments in derivative food tolerance levels.[47] The EPA selected OPs as the first class of pesticides for assessing food tolerances because of their specific toxicity behavior as acetylcholinesterase inhibitors.[47]

Between 1996 and 1999, the use of OPs actually increased (despite the passing of the FQPA) from 75 million to 91 million pounds per year.[47] However, this is mainly due to the cotton boll weevil eradication program through the U.S Department of Agriculture and the use of OPs eventually decreased to 46 million pounds per year by 2004.[47] The residential use of OP pesticides may have declined more quickly, when compared to commercial use, largely due to the voluntary cancellation of chlorpyrifos and diazinon as approved pesticides for home use.[47] The phaseout of both chlorpyrifos and diazinon for most residential uses was complete in 2005.[47]

Parathion (Ethyl) use is banned or restricted in 23 countries and its import is illegal in a total of 50 countries.[49] Its use was banned in the U.S. in 2000 and it has not been used since 2003.[49]

In 2001, the EPA placed new restrictions on the use of the organophosphates phosmet and azinphos-methyl to increase protection of agricultural workers. The crop uses reported at that time as being phased out in four years included those for almonds, tart cherries, cotton, cranberries, peaches, pistachios, and walnuts. The crops with time-limited registration included apples/crab apples, blueberries, sweet cherries, pears, pine seed orchards, brussels sprouts, cane berries, and the use of azinphos-methyl by nurseries for quarantine requirements.[50] The labeled uses of phosmet include alfalfa, orchard crops (e.g. almonds, walnuts, apples, cherries), blueberries, citrus, grapes, ornamental trees (not for use in residential, park, or recreational areas) and nonbearing fruit trees, Christmas trees and conifers (tree farms), potatoes, and peas.[51] Azinphos-methyl has been banned in Europe since 2006.[52]

In May 2006, the Environmental Protection Agency (EPA) reviewed the use of dichlorvos and proposed its continued sale, despite concerns over its safety and considerable evidence suggesting it is carcinogenic and harmful to the brain and nervous system, especially in children. Environmentalists charge that the latest decision was the product of backroom deals with industry and political interference.[53]

As of 2013, thirty-six types of organophosphates were registered for use in the United States.[46] Organophosphates are currently used in a variety of environments (e.g. agriculture, gardens and veterinary practices), however, several notable OPs have been discontinued for use.[46] This includes parathion, which is no longer registered for any use, and chlorpyrifos (as mentioned previously), which is no longer registered for home use.[46] And again, other than for agricultural use, the OP diazinon has been banned in the U.S.

See also

References

  1. 1 2 3 Greaves, Alana K.; Letcher, Robert J.; Chen, Da; McGoldrick, Daryl J.; Gauthier, Lewis T.; Backus, Sean M. (2016-10-01). "Retrospective analysis of organophosphate flame retardants in herring gull eggs and relation to the aquatic food web in the Laurentian Great Lakes of North America". Environmental Research. 150: 255–263. Bibcode:2016ER....150..255G. doi:10.1016/j.envres.2016.06.006. ISSN 0013-9351. PMID 27322497.
  2. 1 2 3 4 5 6 7 8 9 Veen, Ike van der; Boer, Jacob de (2012). "Phosphorus flame retardants: Properties, production, environmental occurrence, toxicity and analysis". Chemosphere. 88 (10): 1119–1153. Bibcode:2012Chmsp..88.1119V. doi:10.1016/j.chemosphere.2012.03.067. PMID 22537891.
  3. 1 2 Wang, Xiaolei; Zhong, Wenjue; Xiao, Bowen; Liu, Qing; Yang, Liping; Covaci, Adrian; Zhu, Lingyan (2019-04-01). "Bioavailability and biomagnification of organophosphate esters in the food web of Taihu Lake, China: Impacts of chemical properties and metabolism". Environment International. 125: 25–32. doi:10.1016/j.envint.2019.01.018. ISSN 0160-4120. PMID 30690428.
  4. 1 2 3 Wei, Gao-Ling; Li, Ding-Qiang; Zhuo, Mu-Ning; Liao, Yi-Shan; Xie, Zhen-Yue; Guo, Tai-Long; Li, Jun-Jie; Zhang, Si-Yi; Liang, Zhi-Quan (January 2015). "Organophosphorus flame retardants and plasticizers: Sources, occurrence, toxicity and human exposure". Environmental Pollution. 196: 29–46. doi:10.1016/j.envpol.2014.09.012. PMID 25290907.
  5. 1 2 3 4 5 6 7 8 9 Greaves, Alana K.; Letcher, Robert J. (January 2017). "A Review of Organophosphate Esters in the Environment from Biological Effects to Distribution and Fate". Bulletin of Environmental Contamination and Toxicology. 98 (1): 2–7. doi:10.1007/s00128-016-1898-0. ISSN 0007-4861. PMID 27510993. S2CID 19824807.
  6. McDonough, Carrie A.; De Silva, Amila O.; Sun, Caoxin; Cabrerizo, Ana; Adelman, David; Soltwedel, Thomas; Bauerfeind, Eduard; Muir, Derek C. G.; Lohmann, Rainer (2018-06-05). "Dissolved Organophosphate Esters and Polybrominated Diphenyl Ethers in Remote Marine Environments: Arctic Surface Water Distributions and Net Transport through Fram Strait". Environmental Science & Technology. 52 (11): 6208–6216. Bibcode:2018EnST...52.6208M. doi:10.1021/acs.est.8b01127. ISSN 0013-936X. PMID 29787253.
  7. Salamova, Amina; Ma, Yuning; Venier, Marta; Hites, Ronald A. (2014-01-14). "High Levels of Organophosphate Flame Retardants in the Great Lakes Atmosphere". Environmental Science & Technology Letters. 1 (1): 8–14. doi:10.1021/ez400034n.
  8. 1 2 Venier, Marta; Dove, Alice; Romanak, Kevin; Backus, Sean; Hites, Ronald (2014-08-19). "Flame Retardants and Legacy Chemicals in Great Lakes' Water". Environmental Science & Technology. 48 (16): 9563–9572. Bibcode:2014EnST...48.9563V. doi:10.1021/es501509r. ISSN 0013-936X. PMID 25045802.
  9. 1 2 "Organophosphates: Background, Pathophysiology, Epidemiology". 2016-11-29. Archived from the original on 2017-04-24. {{cite journal}}: Cite journal requires |journal= (help)
  10. "IRAC Mode of Action Classification Scheme Version 9.4". IRAC (Insecticide Resistance Action Committee) (pdf). March 2020.
  11. 1 2 3 4 Goodman, Brenda (21 Apr 2011). "Pesticide Exposure in Womb Linked to Lower IQ". Health & Pregnancy. WebMD. Archived from the original on 2011-04-24.
  12. Peter, J. V.; Sudarsan, T. I.; Moran, J. L. (2014). "Clinical features of organophosphate poisoning: A review of different classification systems and approaches". Indian Journal of Critical Care Medicine. 18 (11): 735–745. doi:10.4103/0972-5229.144017. PMC 4238091. PMID 25425841.
  13. "Malathion". Environmental Protection Agency. Archived from the original on 2017-05-04.
  14. 1 2 Bonner MR, Coble J, Blair A, et al. (2007). "Malathion Exposure and the Incidence of Cancer in the Agricultural Health Study". American Journal of Epidemiology. 166 (9): 1023–34. doi:10.1093/aje/kwm182. PMID 17720683.
  15. 1 2 "Malathion for Mosquito Control - Pesticides - US EPA". 7 March 2011. Archived from the original on 7 March 2011. Retrieved 29 April 2018.{{cite web}}: CS1 maint: bot: original URL status unknown (link)
  16. 1 2 Maugh II, Thomas H. (16 May 2010). "Study links pesticide to ADHD in children". Los Angeles Times. Archived from the original on 23 April 2011.
  17. "Fenitrothion". Pesticide Information Profiles. Extension Toxicology Network. Sep 1995. Archived from the original on 2004-08-21.
  18. Morello-Frosch, Rachel; Zuk, Miriam; Jerrett, Michael; Shamasunder, Bhavna; Kyle, Amy D. (May 2011). "Understanding the Cumulative Impacts of Inequalities in Environmental Health: Implications for Policy" (PDF). Health Affairs. 30 (5): 879–87. doi:10.1377/hlthaff.2011.0153. PMID 21555471.
  19. "Organophosphates". tools.niehs.nih.gov. Archived from the original on 2017-04-24. Retrieved 2017-04-24.
  20. 1 2 "Fallon Nevada: FAQs: Organophosphates". Centers for Disease Control and Prevention,Department of Health and Human Services. Archived from the original on 2018-03-12. Retrieved 2018-03-11.
  21. Petroianu, G.A. 2010. Toxicity of phosphor esters: Willy Lange (1900–1976) and Gerda von Krueger (1907–after 1970). College of Medicine, Florida International University, Miami, USA. Retrieved from: "Archived copy". Archived from the original on 2018-03-13. Retrieved 2018-03-12.{{cite web}}: CS1 maint: archived copy as title (link) .
  22. Kemmlein, S (September 2003). "BFR—governmental testing programme". Environment International. 29 (6): 781–792. doi:10.1016/s0160-4120(03)00112-0. ISSN 0160-4120. PMID 12850096.
  23. "PARATHION". Pesticide Information Profiles. Extension Toxicology Network. Sep 1993. Archived from the original on 2007-07-22.
  24. Velmurugan, Ganesan; Ramprasath, Tharmarajan; Swaminathan, Krishnan; Mithieux, Gilles; Rajendhran, Jeyaprakash; Dhivakar, Mani; Parthasarathy, Ayothi; Babu, D.D. Venkatesh; Thumburaj, Leishman John; Freddy, Allen J.; Dinakaran, Vasudevan; Puhari, Shanavas Syed Mohamed; Rekha, Balakrishnan; Christy, Yacob Jenifer; Anusha, Sivakumar; Divya, Ganesan; Suganya, Kannan; Meganathan, Boominathan; Kalyanaraman, Narayanan; Vasudevan, Varadaraj; Kamaraj, Raju; Karthik, Maruthan; Jeyakumar, Balakrishnan; Abhishek, Albert; Paul, Eldho; Pushpanathan, Muthuirulan; Rajmohan, Rajamani Koushick; Velayutham, Kumaravel; Lyon, Alexander R.; Ramasamy, Subbiah (2017). "Gut microbial degradation of organophosphate insecticides-induces glucose intolerance via gluconeogenesis". Genome Biology. 18 (1): 8. doi:10.1186/s13059-016-1134-6. PMC 5260025. PMID 28115022.
  25. Greaves, Alana K.; Letcher, Robert J. (2014-07-15). "Comparative Body Compartment Composition and In Ovo Transfer of Organophosphate Flame Retardants in North American Great Lakes Herring Gulls". Environmental Science & Technology. 48 (14): 7942–7950. Bibcode:2014EnST...48.7942G. doi:10.1021/es501334w. ISSN 0013-936X. PMID 24905208.
  26. "Organophosphates FAQs". Centers for Disease Control and Prevention. DHHS Department of Health and Human Services. Archived from the original on 20 January 2016. Retrieved 6 February 2016.
  27. Jurewicz, Joanna; Hanke, Wojciech (9 Jul 2008). "Prenatal and Childhood Exposure to Pesticides and Neurobehavioral Development: Review of Epidemiological Studies". International Journal of Occupational Medicine and Environmental Health. Versita, Warsaw. 21 (2): 121–132. doi:10.2478/v10001-008-0014-z. ISSN 1896-494X. PMID 18614459. Archived from the original on 17 July 2012.
  28. "Study: ADHD linked to pesticide exposure". CNN. 17 May 2010. Archived from the original on 18 May 2010.
  29. "Parathion (CASRN 56-38-2)". IRIS Summaries. U.S. EPA. 9 Aug 2012. Archived from the original on 2006-10-10.
  30. "IARC Monographs Volume 112: evaluation of five organophosphate insecticides and herbicides" (PDF). World Health Organization. Archived (PDF) from the original on 2017-04-17.
  31. "Archived copy" (PDF). Archived (PDF) from the original on 2017-04-17. Retrieved 2016-05-20.{{cite web}}: CS1 maint: archived copy as title (link)
  32. Muñoz-Quezada, M. T.; Lucero, B. A.; Barr, D. B.; Steenland, K.; Levy, K.; Ryan, P. B.; Iglesias, V.; Alvarado, S.; Concha, C.; Rojas, E.; Vega, C. (2013). "Neurodevelopmental effects in children associated with exposure to organophosphate pesticides: a systematic review". Neurotoxicology. 39: 158–68. doi:10.1016/j.neuro.2013.09.003. PMC 3899350. PMID 24121005.
  33. González-Alzaga, B.; Lacasaña, M.; Aguilar-Garduño, C.; Rodríguez-Barranco, M.; Ballester, F.; Rebagliato, M.; Hernández, A. F. (2014). "A systematic review of neurodevelopmental effects of prenatal and postnatal organophosphate pesticide exposure". Toxicology Letters. 230 (2): 104–21. doi:10.1016/j.toxlet.2013.11.019. PMID 24291036.
  34. Holloway, Rodney L. (December 2002). "Phosmet (Imidan)" (PDF). Chemogram: 2.
  35. 1 2 "Environmental Health Perspectives – Population-Based Biomonitoring of Exposure to Organophosphate and Pyrethroid Pesticides in New York City". ehp.niehs.nih.gov. Archived from the original on 2017-04-28. Retrieved 2017-04-24.
  36. "IARC Monographs Volume 112: evaluation of five organophosphate insecticides and herbicides" (PDF). iarc.fr. Archived (PDF) from the original on 17 April 2017. Retrieved 29 April 2018.
  37. "Organophosphates: A Common But Deadly Pesticide". 2013-07-18. Archived from the original on 2017-04-09. Retrieved 2017-04-24.
  38. Arcury, T A; Quandt, S A; Dearry, A (2017-04-24). "Farmworker pesticide exposure and community-based participatory research: rationale and practical applications". Environmental Health Perspectives. 109 (Suppl 3): 429–434. doi:10.1289/ehp.01109s3429. ISSN 0091-6765. PMC 1240561. PMID 11427392.
  39. Joan D. Flocks, e Environmental and Social Injustice of Farmworker Pesticide Exposure, 19 Geo. J. on Poverty L. & Pol'y 255 (2012).
  40. Villarejo, Don (2003-11-28). "The Health of U.S. Hired Farm Workers". Annual Review of Public Health. 24: 175–193. doi:10.1146/annurev.publhealth.24.100901.140901. PMID 12359914.
  41. Farmworker Health Factsheet. N.p.: National Center For Farmworker Health, Aug. 2012. PDF. "Archived copy" (PDF). Archived (PDF) from the original on 2015-09-22. Retrieved 2017-04-24.{{cite web}}: CS1 maint: archived copy as title (link) 
  42. 1 2 Hansen, Eric; Donohoe, Martin (2003-05-01). "Health issues of migrant and seasonal farmworkers". Journal of Health Care for the Poor and Underserved. 14 (2): 153–164. doi:10.1353/hpu.2010.0790. ISSN 1049-2089. PMID 12739296. S2CID 37962307.
  43. Larsen, Ashley; Gaines, Steven (2017-08-29). "Agricultural pesticide use and adverse birth outcomes in the San Joaquin Valley of California". Nature Communications. 8 (1): 302. Bibcode:2017NatCo...8..302L. doi:10.1038/s41467-017-00349-2. ISSN 2041-1723. PMC 5575123. PMID 28851866.
  44. Quesada, James; Hart, Laurie K.; Bourgois, Philippe (2017-04-24). "Structural Vulnerability and Health: Latino Migrant Laborers in the United States". Medical Anthropology. 30 (4): 339–362. doi:10.1080/01459740.2011.576725. ISSN 0145-9740. PMC 3146033. PMID 21777121.
  45. "NOW with Bill Moyers. Politics & Economy. On the Border. Migrant Labor in United States | PBS". www.pbs.org. Archived from the original on 2017-05-06. Retrieved 2017-04-24.
  46. 1 2 3 4 Roberts, J.R.; Reigart, J.R. (2013). Recognition and Management of Pesticide Poisonings (PDF) (6th ed.). Environmental Protection Agency. p. 43. Archived (PDF) from the original on 13 May 2017. Retrieved 10 March 2018.
  47. 1 2 3 4 5 6 7 8 Clune, A.L.; Ryan, P.B.; Barr, D.B. (April 2012). "Have Regulatory Efforts to Reduce Organophosphorus Insecticide Exposures Been Effective?". Environmental Health Perspectives. 120 (4): 521–525. doi:10.1289/ehp.1104323. PMC 3339465. PMID 22251442.
  48. Fenske, R. (November 1999). "Organophosphates and the Risk Cup". Agrichemical and Environmental News (163): 6–8. Archived from the original on 11 March 2018. Retrieved 10 March 2018.
  49. 1 2 "Parathion (Ethyl) - Remaining Use Canceled 9/00". Pesticide Active Ingredient Information. Cornell University. 13 Oct 2000. Archived from the original on 2011-09-27.
  50. Hess, Glenn (1 Nov 2011). "US EPA restricts pesticides azinphos-methyl, phosmet". ICIS.com.
  51. Peck, Chuck; Aubee, Catherine (29 Mar 2010). "Risks of Phosmet Use to the Federally Threatened and Endangered California Tiger Salamander (Ambystoma californiense)" (PDF). Pesticide Effects Determinations. Environmental Fate and Effects Division, Office of Pesticide Programs. Archived (PDF) from the original on 2011-02-04.
  52. Scott, Alex (4 Aug 2008). "Europe Rejects Appeal for Use of Azinphos-methyl Pesticide". IHS Chemical Week. Archived from the original on 2011-07-08.
  53. Raeburn, Paul (14 Aug 2006). "Slow-Acting". Scientific American. Archived from the original on 2013-09-21.
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