Environmental Fate and Toxicology of Dimethoate

Scoy, April Van; Pennell, Ashley; Zhang, Xuyang

doi:10.1007/978-3-319-23573-8_3

Cited by 37 publications

(32 citation statements)

References 53 publications

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“…The half-life of dimethoate in clay loam soil was determined to be 10 and 5 days at 10°C and 20°C, respectively. This confirmed a faster decrease in the pesticide due to the increased temperature [9]. HPLC analysis was carried out to check degradation.…”

Section: Discussionmentioning

confidence: 72%

“…Organism SS3 c showed the best degradation potential and HPLC (High Performance Liquid Chromatography) analysis was carried out for the sample degraded by the organism. Dimethoate adsorption was measured on eight soil types (pH from 8.0-8.45; OM from 0.73-2.95%; clay content from 5.9-14.9%) in which resulting isotherms followed an L-shape [9]. Some pesticides hydrolyze very rapidly.…”

Section: Discussionmentioning

confidence: 99%

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Isolation and Characterization of Microorganisms that Degrade Dimethoate

Singh¹,

Iyer²

2017

J Bioremediat Biodegrad

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Microorganisms have the ability to degrade a large number of pollutants found in the environment. Microorganisms such as bacteria can degrade toxic compounds and chemicals in an environment friendly way. Dimethoate is an organophosphate pesticide. It is a broad-spectrum insecticide. In the present study, dimethoate degrading microorganisms have been isolated from various soil samples. The different isolates that were obtained were characterized by various biochemical tests. Standardization of degradation was performed. Leuco crystal violet reagent was used as an indicator and colorimetric analysis was done at 595 nm. In total, 8 isolates were got. 3 belonged to Bacillus sp. and 3 were identified as Staphylococcus aureus. 2 isolates were identified as Aspergillus sp. HPLC analysis was carried out for the organism that showed the best degradation results.

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Section: Discussionmentioning

confidence: 72%

Section: Discussionmentioning

confidence: 99%

Isolation and Characterization of Microorganisms that Degrade Dimethoate

Singh¹,

Iyer²

2017

J Bioremediat Biodegrad

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“…The 96‐h EC50s of dimethoate that indicate higher toxicity at test series PEST + nTiO 2 than at test series PEST despite more efficient degradation (Table 4) could, in addition, be induced by the formation of metabolites that are more toxic than the parent substance (Evgenidou et al 2006; Farner Budarz et al 2017). It was shown that during photocatalytic degradation with nTiO 2 , dimethoate is degraded into 9 by‐products (Evgenidou et al 2006), whereas the major by‐product, omethoate (Van Scoy et al 2016), is 90‐fold more toxic than the mother compound (Pesticide Properties Database; Lewis et al 2016). Likewise, the photocatalysis (UV = 5.8 W/m 2 ; TiO 2 = 120 mg/L) of malathion sharply increases its toxicity toward Vibrio fischeri , whereas no increase in toxicity was observed when treating malathion with UV alone (Li et al 2019).…”

Section: Discussionmentioning

confidence: 99%

Reduction of Pesticide Toxicity Under Field‐Relevant Conditions? The Interaction of Titanium Dioxide Nanoparticles, Ultraviolet, and Natural Organic Matter

Lüderwald

Meyer

Gerstle

et al. 2020

Enviro Toxic and Chemistry

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In surface waters, the illumination of photoactive engineered nanomaterials (ENMs) with ultraviolet (UV) light triggers the formation of reactive intermediates, consequently altering the ecotoxicological potential of co-occurring organic micropollutants including pesticides due to catalytic degradation. Simultaneously, omnipresent natural organic matter (NOM) adsorbs onto ENM surfaces, altering the ENM surface properties. Also, NOM absorbs light, reducing the photo(cata) lytic transformation of pesticides. Interactions between these environmental factors impact 1) directly the ecotoxicity of photoactive ENMs, and 2) indirectly the degradation of pesticides. We assessed the impact of field-relevant UV radiation (up to 2.6 W UVA/m²), NOM (4 mg TOC/L), and photoactive ENM (nTiO 2 , 50 µg/L) on the acute toxicity of 6 pesticides in Daphnia magna. We selected azoxystrobin, dimethoate, malathion, parathion, permethrin, and pirimicarb because of their varying photo-and hydrolytic stabilities. Increasing UVA alone partially reduced pesticide toxicity, seemingly due to enhanced degradation. Even at 50 µg/L, nano-sized titanium dioxide (nTiO 2) reduced but also increased pesticide toxicity (depending on the applied pesticide), which is attributable to 1) more efficient degradation and potentially 2) photocatalytically induced formation of toxic by-products. Natural organic matter 1) partially reduced pesticide toxicity, not evidently accompanied by enhanced pesticide degradation, but also 2) inhibited pesticide degradation, effectively increasing the pesticide toxicity. Predicting the ecotoxicological potential of pesticides based on their interaction with UV light or interaction with NOM was hardly possible, which was even more difficult in the presence of nTiO 2 .

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Section: Figurementioning

confidence: 99%

“…Due to dimethoate's high water solubility and low soil persistence, its potential to runoff into surface waters and leaching into groundwater is high [15]. The most important degradation pathways of dimethoate in the environment are hydrolysis, photolysis and microbiological degradation [15]. The photocatalytic oxidation and microbial metabolism of dimethoate often have omethoate as the final product, which is not desirable due to its extreme toxicity.…”

Section: Figurementioning

confidence: 99%

Decomposition of Dimethoate and Omethoate in Aqueous Solutions – Half-Life, Neurotoxicity and Mechanism of Hydrolysis

Anićijević¹,

Petković²,

Pašti³

et al. 2021

Preprint

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Organophosphate pesticides are used in large quantities. However, they exhibit toxic effects on non-target organisms. Dimethoate and its oxo-analog omethoate inhibit acetylcholinesterase and are toxic for mammals. Moreover, they show extreme toxicity for bees. Once in the environment, they undergo chemical transformations and decomposition. We show that dime-thoate and omethoate decompose rapidly in alkaline aqueous solutions (half-lives 5.7 and 0.89 days) but are highly stable in acidic solutions (half-lives 124 and 104 days). These differences are explained using quantum chemical calculations, indicating that a weaker P–S bond in omethoate is more susceptible to hydrolysis, particularly at a high pH. The toxicity of these pesticides solutions decreases over time, indicating that no or very little highly toxic omethoate is formed during hydrolysis. Presented data can be used to predict dimethoate and omethoate concentrations in contaminated water depending on pH. Presented results suggest that alkaline hydrolysis of organophosphates has an advantage over other techniques for their removal since there is no risk of omethoate accumulation and increased toxicity of contaminated water.

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Environmental Fate and Toxicology of Dimethoate

Cited by 37 publications

References 53 publications

Isolation and Characterization of Microorganisms that Degrade Dimethoate

Isolation and Characterization of Microorganisms that Degrade Dimethoate

Reduction of Pesticide Toxicity Under Field‐Relevant Conditions? The Interaction of Titanium Dioxide Nanoparticles, Ultraviolet, and Natural Organic Matter

Decomposition of Dimethoate and Omethoate in Aqueous Solutions – Half-Life, Neurotoxicity and Mechanism of Hydrolysis

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