GC/MS在监测甲胺磷工业废水中的应用

就甲胺磷工业废水监测中甲胺磷及其干扰组分进行了色谱分离及质谱定性分析,并以火焰光度检定量,用甲胺磷工业原油作为标准,圆满完成了甲胺磷工业废水的监测任务。     

乙酰甲胺磷对斜生栅藻的毒性及细菌降解研究

采用血球计数法测定斜生栅藻细胞数目,研究了乙酰甲胺磷对斜生栅藻的毒性作用,并通过藻类培养液中接种经过筛选得到的乙酰甲胺磷高效降解菌测定其对乙酰甲胺磷毒性的去除影响。研究结果表明,乙酰甲胺磷对斜生栅藻的抑制中浓度(EC50)大于159 mg/L,急性毒性为低毒。但进一步研究发现,在7 d后,EC50为174.68 mg/L,明显低于24 h的1 128.57 mg/L,存在亚慢性毒性。通过藻类培养液接种高效降解菌Y-6,乙酰甲胺磷对藻类的生长抑制程度减轻。     

白菜中甲胺磷残留的动态研究

甲胺磷是一种具有内吸、触杀和防治效果良好的杀虫剂。甲胺磷可被植物的叶丛吸收并运转到各个部分,也可由根吸收土壤中的农药后运转到块茎、瓜果或整个植物,其在株内传导作用快,残效期较长。甲胺磷在粮食作     

甲胺磷农药废水絮凝处理的生物可降解性

甲胺磷生产排放废水ＣＯＤ在１～１．５×１０４ｍｇ／Ｌ左右,经用聚合硫酸铁絮凝处理后废水ＣＯＤ下降１２％,经紫外分光扫描,絮凝后废水与原废水相比有机物呈均匀下降趋势。在活性污泥法的生化条件下的对比试验表明,在絮凝后甲胺磷废水ＣＯＤ高达４０００ｍｇ／Ｌ以上,仍可进生化池处理,生化过程甲胺磷降解速度快,生化周期缩短一半。     

11种农药对淡水发光细菌青海弧菌Q67的毒性研究

以淡水发光细菌青海弧菌Q67作为测试菌剂,利用水质毒性分析仪对11种农药进行了毒性研究,获得11种农药与青海弧菌的剂量-效应关系.结果表明,作用时间为15 min时,5种可溶农药对青海弧菌Q67的毒性大小为敌敌畏＞敌百虫＞杀虫单＞乐果＞乙酰甲胺磷,6种难溶于水农药的毒性大小为甲氨基阿维菌素＞甲胺磷＞莎稗磷＞高效氯氰菊酯...     

2株乙酰甲胺磷降解菌的分离鉴定及降解特性研究

利用富集及驯化培养方法,从长期生产农药企业的废水处理系统、厂房周边污染的土壤和池水中,分离筛选出2株能够高效降解乙酰甲胺磷的菌株Y3、Y6。在形态特征和生理生化鉴定的基础上,对其16S rDNA序列进行了分析,并重点研究了它们对乙酰甲胺磷及其他农药的降解特性和抗性。结果表明,Y3、Y6分别为寡养单胞菌(Stenotrophomonas)和假单胞菌(Pseudomonas)。Y3、Y6在乙酰甲胺磷浓度分别为500 mg/L和1 000 mg/L,培养温度30℃,初始pH8,接种量为2.5%条件下,一周内可以将80%左右的乙酰甲胺磷矿化为磷酸根。外加葡萄糖及酵母膏对降解效率的研究表明,当酵母膏含量为1 g/L时,降解效果最理想;而外加葡萄糖的量,能相对抑制其对农药的降解。抗性实验显示,Y3、Y6均可在较高浓度的其他有机磷类及氨基甲酸酯类农药的普通培养基中生长,对其他农药的抗性也比较广泛。植物侵染实验显示,Y3、Y6对实验中的豆科、禾本科、十字花科及葫芦科植物不具备致病性,说明Y3、Y6环境安全性较强。     

蔬菜中甲胺磷残畄量的“小薄层”快速测定

甲胺磷,又名多灭磷、脱麦隆(Tamaron),化学名为 O,S—二甲基硫代磷酰胺,结构式为     

农药厂废气污染综合治理系统设计与应用

结合浙江某农药厂废气污染的监测、调查和防治方面的经验,总结了农药厂废气污染特点,并采用吸附、吸收和焚烧等综合治理技术有效控制了废气污染.以该农药厂乙酰甲胺磷、包装车间和污水站为例,对主要废气预处理进行了分析:乙酰甲胺磷车间乙酰脱溶真空泵和反应釜产生的氯仿废气经二级深冷回收后进入活性炭吸附处理系统进行预处理;乙酰真空泵产生的其他废气经二级深冷回收预处理;反应釜、溶剂储槽混合废气经水洗、氧化二级吸收预处理;包装车间和污水站废气各自经碱洗吸收预处理.预处理后的废气采用氧化、碱液二级吸收工艺进行废气集中处理,再经锅炉焚烧后,各类废气排放浓度或排放速率均远低于相应标准限值,可实现达标排放.     

甲胺磷在水稻茎叶、谷壳和糙米中残留测定

本文描述了用气相色谱法测定水稻茎叶、糙米和谷壳中甲胺磷的残留分析方法.茎叶、糙米和谷壳中甲胺磷的最小检出浓度分别为0.005ppm、0.01ppm、0.01ppm.在0.1ppm和0.05ppm添加浓度下,糙米回收率分别为83.6±3.98%、80.0±3.1%.在0.1ppm、0.05ppm添加浓度下,谷壳中回收率分别为82.4±3.3%、76.1±1.61%.在0.5ppm、5ppm、15ppm添加浓度下,茎叶回收率分别为86.2±2.72%、78.4±2.92%和82.6±2.89%.     

高效微生物在农药废水治理中的应用

阐明了高效微生物在废水治理中的重要作用,概述了高效微生物的主要选育途径,国内外高效微生物研究及应用的进展,介绍了高效微生物在农药废水治理中的研究与应用情况,并就甲胺磷农药废水高效降解菌的选育及处理应用,存在问题及研究趋势作了初步探讨。     

Hydrolytic and metabolic products of acephate in water and mouse liver

Acephate was incubated in distilled water of three different pH's at 37 degrees C for 7 days. Three hydrolytic products were formed: methamidophos, O,S-dimethyl phosphorothiolate (DMPT), and O-methylacetyl phosphoramidothiolate (OMPT). A single dose of acephate was also fed to mice, and their livers were excised and analyzed for metabolic products up to 30 hours. Three products were detected: methamidophos, DMPT, and S-methylacetyl phosphoramidothiolate (SMPT). The anticholinesterase properties of acephate, methamidophos, DMPT, SMPT, and OMPT were determined. Only acephate and methamidophos had measurable inhibitory effects on the mouse erythrocyte enzyme, methamidophos being about ten times more effective than acephate. The amount of methamidophos formed in the water and mouse liver was too low to have any direct effect on the toxicity of acephate. Acephate toxicity to aquatic insects would depend on its persistence in water, its uptake by the insects, its conversion to methamidophos, and the combined inhibitory effect of acephate and methamidophos on the cholinesterase enzyme. The toxicity of acephate to mammals would depend on the direct anticholinesterase effect of the chemical and to a small extent on methamidophos.     

Adsorption,desorption, and mobility of two insecticides in Malaysian agricultural soil

Laboratory studies utilizing radioisotopic techniques were conducted to determine the adsorption, desorption, and mobility of endosulfan (6,7,8,9,10,10-hexachloro-1,5,5a,6,9,9a-hexahydro-6,9-methano-2,4,3-benzodioxanthiepin3-oxide) and methamidophos (O,S-dimethyl phosphorothioate) in sandy loam and clay soils of the Cameron Highlands and the Muda rice-growing area, respectively. High Freundlich adsorption distribution coefficients [Kads(f)] for endosulfan (6.74 and 18.75) and low values for methamidophos (0.40 and 0.98) were obtained in the sandy loam and clay soils, respectively. The observed Koc values for endosulfan were 350.85 (sandy loam) and 1143.19 (clay) while Koc values of 20.92 (sandy loam) and 59.63 (clay) were obtained for methamidophos. Log Kow of 0.40 and 1.25 were calculated for endosulfan as well as -1.96 and -1.21 for methamidophos in the sandy loam and clay soils, respectively. Desorption was common to both pesticides but the desorption capacity of methamidophos from each soil type far exceeded that of endosulfan. Soil thin layer chromatography (TLC) and column studies showed that while methamidophos was very mobile in both soils, endosulfan displayed zero mobility in clay soil.     

Some toxicological aspects of methamidophos exposure in mice

Cholinesterase activity in the brain, RBC and plasma of Swiss mice was determined following different routes of administration of methamidophos. Continuous feeding with the insecticide caused a progressive inhibition of both plasma- and erythrocyte enzymes. The effect of methamidophos was more pronounced when applied in diet than when administered dermally or intraperitoneally. Following a single injection (i.p.) of methamidophos, the brain enzyme showed maximum inhibition 24 hr following treatment. At the appearance of tremors, the plasma and RBC-enzymes showed considerable inhibition, the former being more inhibited. The plasma enzyme appears to be the most sensitive enzyme and may be taken as a suitable index for exposure to methamidophos.     

Some toxicological aspects op methamidophos exposure in mice 1

Abstract

Cholinesterase activity in the brain, RBC and plasma of Swiss mice was determined following different routes of administration of methamidophos. Continuous feeding with the insecticide caused a progressive inhibition of both plasma‐ and erythrocyte enzymes. The effect of methamidophos was more pronounced when applied in diet than when administered dermally or intraperitoneally. Following a single injection (i.p.) of methamidophos, the brain enzyme showed maximum inhibition 24 hr following treatment. At the appearance of tremors, the plasma and RBC‐enzymes showed considerable inhibition, the former being more inhibited. The plasma enzyme appears to be the most sensitive enzyme and may be taken as a suitable index for exposure to methamidophos.     

Toxicity and metabolism of acephate in adult and larval insects

Abstract

Adult and larval insects from the terrestrial and aquatic environments were exposed to acephate. The chemical was more toxic to adult insects than to larvae, and was a poor insect cholinesterase inhibitor in vitro compared to methamidophos which was a much stronger inhibitor. Both acephate and methamidophos inhibited the adult cholinesterase in vitro much more strongly than they did the larval enzymes. Acephate was metabolized by the insects to methamidophos which did not appear to be the only metabolite, although no other metabolites were looked for. The cholinesterase of insects exposed to sublethal levels of acephate was inhibited, but this inhibition appeared to be due to the combined effect of acephate and methamidophos and not to any hypothetical substance with greater anticholinesterase activity. This was bourne out when acephate was incubated with mixed function oxidases (MFO). No activated product with potent anticholinesterase activity was identified. Methamidophos was not produced by the MFO system but by some other unidentified mechanism.     

Studies on the toxicity, metabolism, and anticholinesterase properties of acephate and methamidophos

The toxicity of acephate to four species of aquatic insects, as well as the metabolism and cholinesterase-inhibiting properties of the chemical in the rat were studied. The results indicated that mayfly larvae were very sensitive to the toxic effects of acephate, whereas larvae of the stonefly, damselfly and mosquito were much less sensitive. In the rat, orally-administered acephate was rapidly absorbed from the intestines and severely inhibited the cholinesterases in the blood and brain. The enzymes began to recover after 24 hours, while the chemical was completely eliminated within three days. The amount of methamidophos observed in the liver was extremely low. The cholinesterase-inhibiting properties of acephate and methamidophos were compared in vitro to that of paraoxon, a known strong anticholinesterase. Enzymes from four vertebrates were used. In all cases, except one, acephate was found to be six orders of magnitude weaker than paraoxon, whereas methamidophos was three orders weaker. Trout brain cholinesterase was the exception; it was as sensitive to paraoxon as it was to methamidophos. Finally, four cholinesterases were inhibited with methamidophos, and their ability to reactivate spontaneously or to recover by induction with pyridine aldoxime methiodide (PAM) in vitro were determined. The results suggested that methamidophos-inhibited cholinesterases did not reactivate spontaneously; instead the enzymes remained inhibited either in a phosphorylated or an aged state. The significance of these results are discussed in relation to the use of acephate for forest insect pests.     

Effects of methamidophos on the community structure,antagonism towards Rhizoctonia solani,and phlD diversity of soil Pseudomonas

A microcosm incubation study using an aquic brown soil from northeast China (a Cambisol in the UN Food and Agriculture Organization FAO Soil Taxonomy) was conducted to examine the effects of different concentrations (0, 50, 150, and 250 mg kg^?1) of methamidophos (O,S-dimethyl phosphoramidothioato) on Pseudomonas, one of the most important gram-negative bacteria in soil. Amplified ribosomal DNA restriction analysis (ARDRA) was performed to study the Pseudomonas community structure, an in vitro assay was made to test the antagonistic activity of isolated Pseudomonas strains against soil-borne Rhizoctonia solani, a major member of the pathogens highly related to soil-borne plant diseases, and special primer amplification and sequencing were performed to investigate the diversity of phlD, an essential gene in the biosynthesis of 2, 4-diacetylphloroglucinol (2, 4-DAPG), which has biocontrol activity in phlD ⁺isolates. With exposure to increasing methamidophos concentrations, the total number of soil Pseudomonas ARDRA patterns decreased significantly, but with less change in the same treatments over 1, 3, and 5 weeks of incubation. The number of isolated Pseudomonas strains with antagonistic activity against R. solani as well as the diversity and appearance frequency of the strains' phlD gene also decreased with increasing concentrations of methamidophos, especially at high methamidophos concentrations. Applying methamidophos could increase the risk of soil-borne plant diseases by decreasing the diversity of the soil Pseudomonas community and the amount of R. solani antagonists, particularly those with the phlD gene.     

Analysis and fate of acephate and its metabolite,methamidophos, in pepper and cucumber

Abstract

Levels of acephate (Orthene^R) and its principle metabolite, methamidophos, in/on greenhouse‐grown pepper and cucumber fruits and leaves in relation to the applied methamidophos were monitored. Dislodgeable and total residues of acephate and methamidophos were determined by gas‐liquid chromatography equipped with a flame ionization detector (GC‐FID) and were confirmed by nitrogen phosphorus detector (GC‐NPD). The dissipation curves of the residues followed first‐order kinetics (R²> 0.96). Initial residues of acephate on fruits varied between pepper (15.12 ppm) and cucumber (2.16 ppm) . Total residues in fruits and leaves determined at intervals following application revealed the greater persistence of acephate on pepper fruits (half‐life [t_1/2] of 6 d) than on cucumber fruits (t_1/2 was 3.7 d) . T_1/2 values for the applied methamidophos were 4.7 and 5.3 d on pepper and cucumber fruits, respectively. Deacety‐lation of acephate (formation of its metabolite) was detectable 1 d following acephate treatment and reached a maximum of 2.05% of initial acephate residues 3 d after application on pepper fruits. On cucumber fruits, acephate metabolite reached a maximum of 2.12% one wk following application. No acephate residues were detected above the limit of detection of 0.001 ppm in pepper fruits 50 d following acephate application while its metabolite was detectable at that time (detectability limit was 0.0001 ppm).     

Effect of methamidophos and urea application on microbial communities in soils as determined by microbial biomass and community level physiological profiles

In this study, we evaluated the effect of the application by two agrochemicals, methamidophos (O,S-dimethyl phosphoroamidothioate) and urea, on microbial diversity in soil, using the combined approaches of soil microbial biomass analysis and community level physiological profiles (CLPPs). The results showed that both a low and a high level of methamidophos application (CS2 and CS3) and urea application (CS4) significantly decreased microbial biomass C (Cmic) by 41-83% compared with the control (CS1). The soil organic C (Corg) values of CS3 and CS4 were significantly higher and lower by 24% and 14%, respectively, than that of CS1. Similarly to Cmic, the values of Cmic/Corg of the three applied soils which decreased were lower by 31-84% than that of CS1. In contrast, the respiration activity of the three applied soils were significantly higher than the control. Agrochemical application also significantly increased the soil total of N and P (Ntol and Ptol) and decreased the Corg/Ntol and Corg/Ptol values. The CLPPs results showed that the AWCD (average well color development) of the three applied soils were significantly higher than that of CS1 during the incubation period. Substrate richness, Shannon and Simpson indices of microbial communities under chemical stresses, increased significantly. In addition, the CFU (colony-forming unit) numbers of methamidophos metabolized bacteria in CS2 and CS3 also increased significantly by 86.1% and 188.9% compared with that of CS1. The combined results suggest that agrochemicals reduce microbial biomass and enhance functional diversities of soil microbial communities; meanwhile, some species of bacteria may be enriched in soils under methamidophos stress.     

Assessing the toxicity of organophosphorous pesticides to indigenous algae with implication for their ecotoxicological impact to aquatic ecosystems

This study aimed to determine the toxicity of three organophosphorous pesticides, chlorpyrifos, terbufos and methamidophos, to three indigenous algal species isolated from local rivers and algal mixtures. The diatom Nitzschia sp. (0.30–1.68 mg L^?1 of EC₅₀ -the estimated concentration related to a 50% growth reduction) and the cyanobacteria Oscillatoria sp. (EC₅₀ of 0.33–7.99 mg L^?1) were sensitive to single pesticide treatment and the chlorophyta Chlorella sp. was the most tolerant (EC₅₀ of 1.29–41.16 mg L^?1). In treatment with the mixture of three pesticides, Chlorella sp. became the most sensitive alga. The antagonistic joint toxic effects on three indigenous algae and algal mixtures were found for most of the two pesticide mixtures. The results suggested that mixture of pesticides might induce the detoxification mechanisms more easily than the single pesticide. The synergistic interactions between terbufos and methamidophos to algal mixtures and between methamidophos and chlorpyrifos to Nitzschia sp. indicated methamidophos might act as a potential synergist. Differential sensitivity of three families of algae to these pesticides might result in changes in the algal community structures after river water has been contaminated with different pesticides, posing great ecological risk on the structure and functioning of the aquatic ecosystem.