Pesticide use
History
Dermaton was the first registered product containing chlorfenvinphos. It was introduced in the United States in 1963 and was used as an insecticide and acaricide for controllingRegulation and advisories
No international regulations exist for the use of chlorfenvinphos, although standards and guidelines have been set to protect people from the possible harmful effects of the toxin. No regulation exists for inhalation exposure, but multiple minimal risk levels (MRL) have been estimated for oral exposure. These data have been developed from lowest observed adverse effect levels (LOAEL) in test rats, based on adverse neurological effects. The acute oral MRL has been established at 0.002 mg/kg/day, while the chronic MRL has been established somewhat lower, at 0.0007 mg/kg/day. Furthermore, chlorfenvinphos is one of the chemicals regulated under “The Emergency Planning and Community Right-to-Know act of 1986”. This means that owners and operators of certain facilities that manufacture, import, process or otherwise use the chemical, are obligated to report their annual release of the chemical to any environmental media. However, the use of chlorfenvinphos has now been banned in the European Union and in the United States. In Europe it is banned as a plant protection product. An exception is Switzerland, where chlorfenvinphos is still allowed for use in crops and certain vegetables under the brand name Birlane. In Australia, chlorfenvinphos is partially banned. Thus, it was withdrawn in alfalfa, potatoes and mushrooms, while it is still used in veterinary medicine for combating ectoparasites until 2013.[Szatkowska B, et al., ed. 2011. Impact of Chlorfenvinphos, an organophosphate insecticide on human blood mononuclear cells (in vitro). Pesticide Biochemistry and Physiology, Volume 102, Issue 2, February 2012, Pages 175-181.]Production
Chlorfenvinphos was first introduced in the United States in 1963, by the Royal Dutch Shell, Shell International Chemical Company Ltd., Ciba AG (now Ciba-Geigy AG) and by Allied Chemical Corporation. Its main use was as an insecticide and acaricide used to control insect pests on livestock and household pests such as flies, fleas, and mites.[Farm Chemicals Handbook. 1993. Chlorfenvinphos. Farm Chemicals Handbook, Pesticide Dictionary, 1993. Willoughby, OH: Meister Publishing Co., C75-C76.] Since its first application, many manufacturers included chlorfenvinphos in their products. Some common trade names are Birlane, Dermaton, Sapercon, Steladone, and Supona. Since 1991, however, information on current production of chlorfenvinphos has been conflicting. One source lists base producers of the compound as the American Cyanamid Company. However, no producers of chlorfenvinphos were identified in a 1993 Directory of Chemical Producers for the United States of America.[SRI. 1993. 1993 Directory of Chemical Producers, United States of America. Menlo Park, CA: Stanford Research Institute, International, 520, 808.] Moreover, there have been no registered uses for this compound as a pesticide in the United States since 1995. Chlorfenvinphos is produced by reaction of triethylphosphite (P(OEt)3) with 2,2,2'',4''-tetrachloro acetophenone (C8H4Cl4O). In the production process, both the Z and E isomers are formed in a ratio (Z:E) of 8.5:1. The technical grade material therefore contains over 92% chlorfenvinphos.[Worthing CR, ed. 1983. Chlorfenvinphos. In: The Pesticide Manual, A World Compendium, Seventh edition. The British Crop Protection Council.] Unfortunately, no data is available in the Toxics Release Inventory (TRI) database on total environment releases of this compound from facilities. This is mainly because chlorfenvinphos was not considered a dangerous toxin until the early 1990s. Therefore, chlorfenvinphos is not one of the compounds about which facilities were required to report to the Toxic Release Inventory.Toxicokinetics
Chlorfenvinphos is most commonly absorbed into the body through either ingestion of food products that have been treated with the pesticide, or through dermal absorption, though the latter is much less efficient. Once absorbed, chlorfenvinphos is widely distributed throughout the body, and has been detected in a variety of bodily fluids.[Wagner U, Schlebusch H, van der Ven K, et al. 1990. Detection of phosphate ester pesticides and the triazine herbicide atrazine in human milk, cervical mucus, (and) follicular and sperm fluid. Fresenius' J Anal Chem 337:77-78.] However, as an organophosphorus compound, it does not accumulate well in tissues. The first and most important step of metabolism of chlorfenvinphos in humans is accomplished by the enzyme cytochrome P450 in liver microsomes. This enzyme facilitates oxidative dealkylation of the compound to acetaldehyde and 2-chloro-1-(2,4-dichlorophenyl) vinylethylhydrogen phosphate, the latter of which quickly breaks down toMechanism of toxicity
The toxicity of chlorfenvinphos is primarily caused by its inhibition of cholinesterase activity. Chlorfenvinphos reacts with the acetylcholine binding sites of enzymes that hydrolyze acetylcholine, thereby preventing their catalysis of this reaction. The reaction itself is a phosphorylation, which is reversible. The phosphorylated enzymes can undergo conformational changes and additional reactions however, which prevent the dephosphorylation. This “aging” results in irreversible inhibition of the cholinesterase. Acetylcholine is a neurotransmitter in the nervous system, it targets muscarinic and nicotinic receptors and receptors in the central nervous system. These receptors are used to pass on an action potential across the synaptic cleft between neurons. Inhibition of acetylcholinesterase enzymes results in the accumulation of acetylcholine at its receptors. This leads to continuous or excessive stimulation of neurons that respond to acetylcholine. Cholinergic poisoning leads to different symptoms, depending on the part of the nervous system that is affected. The most likely cause of death in chlorfenvinphos is respiratory failure due to paralysis and bronchoconstriction.Toxicity
Toxic effects
The toxic effects of accumulation of acetylcholine can be divided into three categories, based upon its actions in different parts of the nervous system. Muscarinic receptors that respond to acetylcholine are found in smooth muscles, the heart and exocrine glands. The muscarinic symptoms of cholinergic poisoning are therefore tightness in the chest, wheezing due to bronchoconstriction, bradycardia, miosis, increased salivation, lacrimation and sweating and increased peristalsis, which leads to nausea, vomiting and diarrhea. Nicotinic receptors responding to acetylcholine can be found in skeletal muscle and the autonomic ganglia. The nicotinic symptoms of cholinergic poisoning are therefore fatigue, involuntary twitching, muscular weakness, hypertension and hyperglycemia. Symptoms of accumulation of acetylcholine in the central nervous system are diverse and include tension, anxiety, ataxia, convulsions, depression of the respiratory and circulatory centers and coma.[Timbrell, J.A. 2009. Principles of Biochemical Toxicology, Fourth Edition. New York. .]Acute toxicity
The acute toxicity of chlorfenvinphos varies widely between species. Oral LD50 values range from 9.6–39 mg/kg in rats to >12,000 mg/kg in dogs.[Gardner, J. (1992) Birlane technical: acute oral and dermal toxicity in rat, skin and eye irritancy in rabbit and skin sensitization potential in guinea pig. Unpublished report from Shell Research Ltd, Sittingbourne Research Centre, Sittingbourne, United Kingdom.] Though no direct data on the acute toxicity in humans is available, an ''in vitro'' study of the detoxification of chlorfenvinphos has shown that human liver enzymes were almost as effective as those of rabbits, who have an oral LD50 of 412-4,700 mg/kg.,Long-term toxicity
Prolonged exposure to chlorfenvinphos has been observed to decrease plasma and erythrocyte cholinesterase activity in humans.[Ottevanger, C.F. (1976) An epidemiological and toxicological study of occupational exposure to an organphosphorus pesticide. University of Amsterdam, MD Thesis. Rotterdam, Phoenix & den Oudsten.] No significant genotoxicity, carcinogenicity or teratogenicity has been reported. On the basis of a NOAEL of 0.05 mg/kg observed in rats, an acceptable daily intake for humans of 0.0005 mg/kg has been established.[National Institute of Public Health and Environmental Protection. (1994). Pesticide residues in food: 1994 evaluations Part II Toxicology. Bilthoven, Netherlands.]Biomarkers
Biomarkers of exposure
Traces of unchanged chlorfenvinphos and its polar metabolites can be detected in animals, which have been exposed to chlorfenvinphos. These small amounts can be used to prove that chlorfenvinphos exposure has occurred and the method of analysis is non-invasive. Another method to assess chlorfenvinphos exposure is to measure the activity of cholinesterases in the blood. Two pools of cholinesterases exist in the blood: acetylcholinesterase in erythrocytes and pseudocholinesterase in plasma. The acetylcholinesterase in erythrocytes is identical to the acetylcholinesterase found in neuromuscular tissue. The function of plasma pseudocholinesterase is unknown, but its activity is considered to be a more sensitive biomarker for organophosphate exposure than erythrocyte cholinesterase activity. The inhibition of the individual cholinesterases or the inhibition of their combined activity can be used as a marker of exposure. However, cholinesterase inhibition is caused by all anticholinesterase compounds and is therefore not a specific biomarker for chlorfenvinphos. In addition, the activity of cholinesterases in the blood varies in populations and there are no studies which have measured a correlation between chlorfenvinphos exposure and cholinesterase inhibition. There have been suggestions that chlorfenvinphos or its metabolites would be a better biomarker of exposure than its cholinesterase activity inhibition.Biomarkers of effect
In combination with analysis of reductions in cholinesterase activity in the blood, symptoms of organophosphate poisoning can be used to identify victims of organophosphate poisoning. These symptoms are not specific for chlorfenvinphos, but for anticholinesterase compounds in general.Treatments of exposure
Ingestion of chlorfenvinphos, either by accident or through suicidal intent, can be treated as with other acute organophosphate poisonings. This includes a combination of three approaches: # Administration of an anticholinergic such as atropine, considered an antidote; # Administration of a cholinesterase reactivator, in the pyridinium oxime family, usually pralidoxime; # Administration of anticonvulsants, e.g. benzodiazepines (of which diazepam is most effective). The efficacy of oxime treatment is controversial. Ingestion of organophosphates as residues on food rarely reaches clinically relevant doses.References
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