A treatise on Organophosphate pesticide pollution: Current strategies and advancements in their environmental degradation and elimination

Pesticides have been used in the field of agriculture ever since their role in protection of crops from pests which include four different categories namely insects, mites, rodents and animals has been identified. Organophosphate pesticides are one of the most extensively applied insecticides in the...

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Vydáno v:	Ecotoxicology and environmental safety Ročník 207; s. 111483
Hlavní autoři:	Kaushal, Jyoti, Khatri, Madhu, Arya, Shailendra Kumar
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	Netherlands Elsevier Inc 01.01.2021 Elsevier
Témata:	Abiotic degradation Acetylcholinesterase Agriculture Animals Biotic degradation Crops, Agricultural - metabolism Environmental Exposure - analysis Environmental Pollutants - metabolism Environmental Pollution Insecta - metabolism Insecticides - toxicity Nervous System Diseases Organophosphate pesticide Organophosphates Organophosphorus Compounds - toxicity Pesticides - toxicity Toxicology Toxicology Abiotic degradation Biotic degradation Acetylcholinesterase Organophosphate pesticide
ISSN:	0147-6513, 1090-2414, 1090-2414
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Abstract	Pesticides have been used in the field of agriculture ever since their role in protection of crops from pests which include four different categories namely insects, mites, rodents and animals has been identified. Organophosphate pesticides are one of the most extensively applied insecticides in the field of agriculture such that around 40% of all the pesticides that are produced and used commercially belong to this category. The main toxicological effect of these pesticides when exposed to a living being encompasses the irremediable inhibition of the acetylcholinesterase (AChE) enzyme which is involved in the neurotransmission of signals and hence its inhibition causes impairment of the respiratory tract and neuromuscular transmission. Apart from being used as a pesticide, organophosphates have also been applied as herbicides to some extent. The residues of these highly toxic chemicals have found route into the underground water system by seeping into the ground, in rivers where the agricultural run off water is disposed, and in the air when sprayed on the crops hence posing a threat to all the living strata exposed to these chemicals in various ways which are discussed further. Many significant studies have been carried out in order to evaluate the health risks associated with these pesticides which commonly include acute neurological disorders. This review emphasizes on the toxicological effects of organophosphate pesticides and the recent methods of detection that are used to identify trace amounts of organophosphate pesticides along with strategies which are used for their degradation. •Organophosphate pesticides have been identified as inhibitory substances for enzyme Acetylcholinesterase.•The blockage of the enzyme’s active site by organophosphate phosphorylation reaction occurs at serine residue.•The detection strategies for organophosphate pesticides are described which include many biological, chemical and physical parameters.•Degradation strategies, both biotic and abiotic for organophosphate pesticide degradation are discussed.
AbstractList	Pesticides have been used in the field of agriculture ever since their role in protection of crops from pests which include four different categories namely insects, mites, rodents and animals has been identified. Organophosphate pesticides are one of the most extensively applied insecticides in the field of agriculture such that around 40% of all the pesticides that are produced and used commercially belong to this category. The main toxicological effect of these pesticides when exposed to a living being encompasses the irremediable inhibition of the acetylcholinesterase (AChE) enzyme which is involved in the neurotransmission of signals and hence its inhibition causes impairment of the respiratory tract and neuromuscular transmission. Apart from being used as a pesticide, organophosphates have also been applied as herbicides to some extent. The residues of these highly toxic chemicals have found route into the underground water system by seeping into the ground, in rivers where the agricultural run off water is disposed, and in the air when sprayed on the crops hence posing a threat to all the living strata exposed to these chemicals in various ways which are discussed further. Many significant studies have been carried out in order to evaluate the health risks associated with these pesticides which commonly include acute neurological disorders. This review emphasizes on the toxicological effects of organophosphate pesticides and the recent methods of detection that are used to identify trace amounts of organophosphate pesticides along with strategies which are used for their degradation. Pesticides have been used in the field of agriculture ever since their role in protection of crops from pests which include four different categories namely insects, mites, rodents and animals has been identified. Organophosphate pesticides are one of the most extensively applied insecticides in the field of agriculture such that around 40% of all the pesticides that are produced and used commercially belong to this category. The main toxicological effect of these pesticides when exposed to a living being encompasses the irremediable inhibition of the acetylcholinesterase (AChE) enzyme which is involved in the neurotransmission of signals and hence its inhibition causes impairment of the respiratory tract and neuromuscular transmission. Apart from being used as a pesticide, organophosphates have also been applied as herbicides to some extent. The residues of these highly toxic chemicals have found route into the underground water system by seeping into the ground, in rivers where the agricultural run off water is disposed, and in the air when sprayed on the crops hence posing a threat to all the living strata exposed to these chemicals in various ways which are discussed further. Many significant studies have been carried out in order to evaluate the health risks associated with these pesticides which commonly include acute neurological disorders. This review emphasizes on the toxicological effects of organophosphate pesticides and the recent methods of detection that are used to identify trace amounts of organophosphate pesticides along with strategies which are used for their degradation.Pesticides have been used in the field of agriculture ever since their role in protection of crops from pests which include four different categories namely insects, mites, rodents and animals has been identified. Organophosphate pesticides are one of the most extensively applied insecticides in the field of agriculture such that around 40% of all the pesticides that are produced and used commercially belong to this category. The main toxicological effect of these pesticides when exposed to a living being encompasses the irremediable inhibition of the acetylcholinesterase (AChE) enzyme which is involved in the neurotransmission of signals and hence its inhibition causes impairment of the respiratory tract and neuromuscular transmission. Apart from being used as a pesticide, organophosphates have also been applied as herbicides to some extent. The residues of these highly toxic chemicals have found route into the underground water system by seeping into the ground, in rivers where the agricultural run off water is disposed, and in the air when sprayed on the crops hence posing a threat to all the living strata exposed to these chemicals in various ways which are discussed further. Many significant studies have been carried out in order to evaluate the health risks associated with these pesticides which commonly include acute neurological disorders. This review emphasizes on the toxicological effects of organophosphate pesticides and the recent methods of detection that are used to identify trace amounts of organophosphate pesticides along with strategies which are used for their degradation. Pesticides have been used in the field of agriculture ever since their role in protection of crops from pests which include four different categories namely insects, mites, rodents and animals has been identified. Organophosphate pesticides are one of the most extensively applied insecticides in the field of agriculture such that around 40% of all the pesticides that are produced and used commercially belong to this category. The main toxicological effect of these pesticides when exposed to a living being encompasses the irremediable inhibition of the acetylcholinesterase (AChE) enzyme which is involved in the neurotransmission of signals and hence its inhibition causes impairment of the respiratory tract and neuromuscular transmission. Apart from being used as a pesticide, organophosphates have also been applied as herbicides to some extent. The residues of these highly toxic chemicals have found route into the underground water system by seeping into the ground, in rivers where the agricultural run off water is disposed, and in the air when sprayed on the crops hence posing a threat to all the living strata exposed to these chemicals in various ways which are discussed further. Many significant studies have been carried out in order to evaluate the health risks associated with these pesticides which commonly include acute neurological disorders. This review emphasizes on the toxicological effects of organophosphate pesticides and the recent methods of detection that are used to identify trace amounts of organophosphate pesticides along with strategies which are used for their degradation. •Organophosphate pesticides have been identified as inhibitory substances for enzyme Acetylcholinesterase.•The blockage of the enzyme’s active site by organophosphate phosphorylation reaction occurs at serine residue.•The detection strategies for organophosphate pesticides are described which include many biological, chemical and physical parameters.•Degradation strategies, both biotic and abiotic for organophosphate pesticide degradation are discussed.
ArticleNumber	111483
Author	Arya, Shailendra Kumar Kaushal, Jyoti Khatri, Madhu
Author_xml	– sequence: 1 givenname: Jyoti surname: Kaushal fullname: Kaushal, Jyoti – sequence: 2 givenname: Madhu surname: Khatri fullname: Khatri, Madhu – sequence: 3 givenname: Shailendra Kumar surname: Arya fullname: Arya, Shailendra Kumar email: skarya@pu.ac.in
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/33120277$$D View this record in MEDLINE/PubMed
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Keywords	Toxicology Abiotic degradation Biotic degradation Acetylcholinesterase Organophosphate pesticide
Language	English
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PublicationTitle	Ecotoxicology and environmental safety
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Eng. J. doi: 10.1016/j.cej.2019.02.040
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Snippet	Pesticides have been used in the field of agriculture ever since their role in protection of crops from pests which include four different categories namely...
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SubjectTerms	Abiotic degradation Acetylcholinesterase Agriculture Animals Biotic degradation Crops, Agricultural - metabolism Environmental Exposure - analysis Environmental Pollutants - metabolism Environmental Pollution Insecta - metabolism Insecticides - toxicity Nervous System Diseases Organophosphate pesticide Organophosphates Organophosphorus Compounds - toxicity Pesticides - toxicity Toxicology
Title	A treatise on Organophosphate pesticide pollution: Current strategies and advancements in their environmental degradation and elimination
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