脱氧鬼臼毒素对斑马鱼（Danio rerio）代谢酶和抗氧化酶活性的影响（Effects of Deoxypodophyllotoxin on Activities of Metabolic Enzymes and Antioxidant Enzymes of Danio rerio）

为初步探讨脱氧鬼臼毒素(Deoxypodophyllotoxin,DOP)对鱼类的毒性效应,采用静态鱼类急性毒性试验法测定了DOP对斑马鱼(Daniorerio)代谢酶和抗氧化酶活性的影响;参照DOP的96hLC50值,设定4个浓度(0.5、1.0、2.0、4.0mg·L-1)处理斑马鱼,48h后测定斑马鱼肌肉组织腺苷三磷酸酶(ATPase)、过氧化氢酶(CAT)和超氧化物歧化酶(SOD)活性.结果表明,DOP对斑马鱼96hLC50值为3.49mg·L-1,安全浓度为0.36mg·L-1.DOP在0.5~4.0mg·L-1对斑马鱼肌肉总ATPase、Na+-K+-ATPase和Ca2+-ATPase的作用趋势均表现为:1.0和2.0mg·L-1显著激活(p<0.05,p<0.01);4.0mg·L-1显著抑制(p<0.05),抑制率分别为24.4%、12.3%和33.8%.DOP在0.5~4.0mg·L-1对斑马鱼肌肉抗氧化酶的作用趋势与对ATPase的作用趋势一致,表现为:1.0、2.0mg·L-1DOP对SOD和CAT均表现为显著激活(p<0.05,p<0.01);4.0mg·L-1DOP对SOD和CAT均表现为显著抑制(p<0.05),抑制率分别为34.1%和31.9%.以上结果表明,DOP对斑马鱼为中等毒性;斑马鱼肌肉组织ATPase、CAT和SOD可能是脱氧鬼臼毒素的作用标靶之一.     

毒死蜱对我国南方稻区水域中12种淡水鱼的毒性

毒死蜱作为稻田常用农药,普遍存在于稻区沟渠、池塘和河流中,从而对生活在其中的鱼类具有潜在风险。通过短期暴露试验,比较了毒死蜱在纯水、水-沉积物体系中对淡水鱼的毒性效应,进一步研究了毒死蜱在不同鱼体内的生物富集作用,以及对鱼脑Ach E活性的影响。试验结果表明:毒死蜱对12种淡水鱼均表现为高毒或剧毒,最敏感的是太阳鱼,但体系中沉积物的存在会通过吸附作用降低农药对鱼类的毒性;毒死蜱在鱼体内表现为中等或高富集性,其中斑马鱼的富集系数最大;毒死蜱对鱼脑Ach E酶活性有明显抑制作用,其中以虹鳟最敏感。研究结果为稻田常用农药对水生态环境中鱼类安全的风险性评价提供了科学依据。     

评估斑马鱼胚胎毒性试验在农药危害筛选中的应用

考虑到人类社会中大量使用化学物质，想要准确有效地评估这些化学物质对人类和生态受体的潜在风险，研发有效的手段和方法是至关重要的。鱼胚胎急性毒性试验是其中一种工具，已表现出与幼鱼急性毒性标准试验的预测结果高度吻合，而幼鱼试验对资源消耗更多。然而，也有证据表明，对于某些类型的化学物质，包括神经毒素，鱼类胚胎的敏感性低于幼鱼。本文利用已发表的斑马鱼胚胎毒性数据，与3种常用检测用鱼幼鱼(虹鳟鱼、蓝鳃太阳鱼、羊鲷)的半致死浓度50%(LC₅₀)数据进行比较，研究了鱼类胚胎对农药危害评估的效用。在将农药视为单因素的情况下，斑马鱼胚胎和幼鱼毒性数据相关性较差，差异显著(r²=0.28；p2=0.64；p 精选自Glaberman, S., Padilla, S. and Barron, M. G. (2017), Evaluating the zebrafish embryo toxicity test for pesticide hazard screening. Environmental Toxicology and Chemistry, 36: 1221–1226. doi: 10.1002/etc.3641
详情请见http://onlinelibrary.wiley.com/doi/10.1002/etc.3641/full
     

3种有机磷农药对水生生物的乙酰胆碱酯酶抑制效应的物种敏感度分析初探

通过筛选敌敌畏、马拉硫磷和对硫磷3种有机磷农药对水生生物的急性毒性数据和乙酰胆碱酯酶抑制效应数据,构建物种敏感度分布曲线进行了比较分析。结果表明,敌敌畏对水生生物的急性毒性和乙酰胆碱酯酶抑制效应的大小顺序为:酶体内抑制效应酶体外抑制效应急性毒性;马拉硫磷和对硫磷的乙酰胆碱酯酶抑制效应数据不足但趋势相似,顺序为:酶体内抑制效应急性毒性酶体外抑制效应。敌敌畏的急性毒性和酶体外抑制效应的5%危害浓度(HC5)分别为2.07μg·L~(-1)和1.53μg·L~(-1),两者相差1.4倍。在水质基准推导中,乙酰胆碱酯酶抑制效应数据对有机磷农药的水生生物基准具有重要的参考价值。     

几种典型有害化学品对水生生物的急性毒性

采用水体中3个营养级别的水生生物（绿藻、水Sou和鱼）测试卤代酚类、硝基苯类、烷基苯类典型有毒有害化学品对水生生物的急性毒性，同时对上述物质对水生生物的安全性进行初步评估，并预测了上述物质对水生生物的环境安全浓度，研究结果表明，在3类12种有机污染物中，卤代酚类物质对水生生物的毒性最强，其中五氯苯酚对水生生物具有极高毒性。在3个营养级别的受试生物中，剑尾鱼对上述毒物具有较好的敏感性，结果稳定，重现性好，说明剑尾鱼是一种优良的水生毒性试验材料，图1表3参11。     

Impact of malathion on the biochemical parameters of gobiid fish, Glossogobius giuris (Ham)

There is a dearth of information regarding the changes in heart muscle metabolites induced by pesticides. In the present study, the gobiid fish, Glossogobius giuris, was exposed to sub lethal concentrations of (0.05, 0.25 and 0.5 ppm) organophosphorus pesticide, malathion for short duration (24 to 96 hr). The cardiac muscles showed maximum depletion of glycogen and cholesterol content during 72 and 96 hr after treatment with 0.5 ppm malathion. Whereas a slight fluctuation of protein and glycogen content was observed in low concentration (0.05 ppm) of malathion. The levels of protein showed a significant decrease at high concentration (0.5 ppm) when treated for longer duration (96 hr). The present study reports metabolic dysfunction in response to malathion toxicity in the fish.     

毒死蜱、马拉硫磷和氰戊菊酯对赤子爱胜蚓（Eisenia foetida）的急性毒性

采用滤纸接触法和土壤培养法研究了毒死蜱(Chlorpyrifos)、马拉硫磷(Malathion)和氰戊菊酯(Fenvalerate)对赤子爱胜蚓(Eisenia foetida)的急性毒性效应.滤纸接触法试验浓度分别设置为,毒死蜱:3.14、6.28、9.42、12.56、15.70、18.84μg·cm-2;马拉硫磷:3.10、6.20、12.40、18.60、24.80、31.40μg·cm-2;氰戊菊酯:0.31、0.62、1.24、1.86、2.48、3.14μg·cm-2.土壤培养法试验浓度分别设置为,毒死蜱:100、125、150、175、200、225、250mg·kg-1;马拉硫磷:350、400、450、500、550、600mg·kg-1;氰戊菊酯:20、30、40、50、60、70、80mg·kg-1.结果表明:采用滤纸接触法测得的各农药对蚯蚓48h的半数致死浓度(LC50)分别为毒死蜱12.26μg·cm-2、马拉硫磷19.61μg·cm-2、氰戊菊酯1.03μg·cm-2;采用土壤培养法测得的各农药对蚯蚓7d的LC50分别为毒死蜱427.67mg·kg-1、马拉硫磷742.53mg·kg-1、氰戊菊酯81.81mg·kg-1,14d的LC50分别为毒死蜱182.21mg·kg-1、马拉硫磷497.29mg·kg-1、氰戊菊酯37.46mg·kg-1.根据《化学农药环境安全评价试验准则》,这3种农药对蚯蚓的毒性均为低毒级.     

Transport of the insecticides chlorpyrifos,chlorfenvinphos, carbofuran,carbosulfan, and furathiocarb from soil into the foliage of cauliflower and Brussels sprouts plants grown in the field

In several field assays made in different locations in 1988 and 1989, cauliflower and Brussels sprouts plants were treated some days after plantation by pouring onto soil around the stem of the plant one of the insecticides chlorpyrifos, chlorfenvinphos, carbofuran, carbosulfan, or furathiocarb, for protection against the root fly. During plant growth, each of the insecticides (and their soil metabolites) was transported from soil into the plant foliage, where it could give—during a certain period of time—a secondary plant protection against the foliage insects. The foliage concentrations of the non systemic chlorpyrifos and chlorfenvinphos were equal or greater than 1 mg/kg fresh weight during a period of about 44 days after soil treatment in Brussels sprouts crops, and 35 days in cauliflower crops. Comparison of 1988 and 1989 however showed that these periods of time changed according to the weather conditions, especially rainfall. These periods of time were greater when the insecticide soil concentrations were greater—and thus when the rates of insecticide soil metabolism were smaller— and when the rainfall were greater—water transporting the insecticides from soil to the foliage. Similar relationships were observed with the systemic insecticides carbofuran, carbosulfan and furathiocarb; the weights per plant of insecticide compounds transported from soil into the foliage however were greater with these systemic insecticides than they were with the non systemic chlorpyrifos and chlorfenvinphos. The extreme values observed for the periods of time of insecticide foliage concentrations equal or greater than 1 mg/kg fresh weight thus were: 1. in cauliflower crops: 21 to 36 days for chlorpyrifos, and 23 to 39 days for chlorpyrifos + oxon; 24 to 37 days for chlorfenvinphos; 20 to 48 days for carbofuran; 2. in Brussels sprouts crops: 43 to 49 days for chlorpyrifos; 47 to 53 days for chlorpyrifos + oxon; 41 to 45 days for chlorfenvinphos; between 2 to 3 months for carbofuran, carbofuran + carbosulfan, and carbofuran + furathiocarb in the fields treated respectively with either carbofuran, carbosulfan, or furathiocarb. Moreover, in the spring and summer cauliflower crops made on fields onto which continuous cauliflower crops—with their soil insecticide treatments—had been made since a greater number of years (greater soil “history”), the insecticide compounds soil and foliage concentrations generally were lower.     

杀虫剂对土壤温室气体排放的影响

在室内培养条件下,研究了在施用尿素的土壤（有效氮质量分数为200 mg·kg^-1）中分别添加不同剂量（在5、10和50 mg·kg^-1）的吡虫啉和毒死蜱2种杀虫剂时,杀虫剂对土壤温室气体CO2、N2O和CH4排放过程的影响。结果表明：和空白相比,施用尿素明显地增加了土壤中温室气体N2O和CO2的排放量,但对CH4的排放无明显影响。当施用5 mg·kg^-1吡虫啉时,土壤中N2O和CO2排放总量和尿素处理相比无明显差异,但吡虫啉用量上升至10和50 mg·kg^-1时则显著降低了温室气体N2O和CO2的排放量（P〈0.05）,N2O排放量分别降低了26.89%和53.10%,CO2排放量分别降低15.14%和13.79%。毒死蜱在5、10和50 mg·kg^-1三种用量时土壤的N2O排放量与尿素处理相比均无明显差异。毒死蜱在5和10 mg·kg^-1用量时则明显抑制了土壤CO2的排放（p〈0.05）,分别比尿素处理降低了19.88%和19.02%;用量上升到50 mg·kg^-1用量时,土壤的CO2排放量与尿素处理相比无差异。吡虫啉和毒死蜱对CH4排放量均没有明显影响。可见,杀虫剂施用明显影响到土壤温室气体的排放,但不同杀虫剂品种及其用量的效应也存在明显差异。     

Removal of organophosphorus pesticides from water by electrogenerated Fenton's reagent

Aqueous solutions of organophosphorus pesticides were completely mineralized via in-situ generated hydroxyl radicals (HO^·) by the Electro-Fenton process. Formation of Fenton's reagent (H₂O₂, Fe²⁺) was carried out by simultaneous reduction of O₂ and Fe³⁺ on carbon cathode in acidic medium. The electrochemistry combined with Fenton's reagent provides an excellent way to continuously produce the hydroxyl radical, a powerful oxidant. We demonstrate the efficiency of the Electro-Fenton process to degrade three organophosphorus insecticides: malathion, parathion ethyl and tetra-ethyl-pyrophosphate (TEPP). Degradation kinetics and removals of chemical oxygen demand (COD) have been investigated. Here we show that the mineralization efficiency was over 80% for three organophosphorus pesticides.     

9种杀虫剂对中华大刀螂幼虫的毒性

螳螂是田间控制害虫种群增加的重要捕食性天敌之一。以中华大刀螂3龄幼虫(Paratenodera sinensis Saussure)为受试生物,利用9种常用杀虫剂配制成不同浓度梯度的药剂,通过喷雾法直接暴露,分别测定了LC50和死亡率来评价不同杀虫剂对中华大刀螂毒性和危害程度的影响。结果显示,9种杀虫剂对中华大刀螂幼虫的毒性(LC50值)差异很大,用药后24h的LC50在0.7182～347.7962mg·L-1之间,LC95在8.8057～1734.5650mg·L-1之间;用药后48h的LC50在0.3564～193.6887mg·L-1之间,LC95在3.8958～1548.3258mg·L-1之间;用药后72h的LC50在0.2232～115.3391mg·L-1之间,LC95在1.7730～530.6462mg·L-1之间。不同杀虫剂对中华大刀螂幼虫的毒性差异最高达到543.46倍。毒性大小依次为,高效氯氟氰菊酯﹥啶虫脒﹥联苯菊酯﹥毒死蜱﹥噻虫嗪﹥茚虫威﹥吡虫啉﹥阿维菌素﹥苏云金杆菌原粉(Bt)。根据田间推荐浓度处理的死亡率判断,毒死蜱、联苯菊酯、啶虫脒、高效氯氟氰菊酯为有害水平,Bt为中度有害水平,吡虫啉、茚虫威、噻虫嗪为微害水平,阿维菌素接近无害水平。根据LC50与田间推荐浓度的比值判断,阿维菌素、吡虫啉对螳螂种群数量不会产生太大影响;Bt、茚虫威和噻虫嗪对螳螂种群数量会产生一定危害;而毒死蜱、啶虫脒、联苯菊酯和高效氯氟氰菊酯将严重影响螳螂种群数量的稳定性。在24～72h范围内,不同杀虫剂LC50和LC95随施药时间的延长而降低,说明暴露时间越长毒性越大,危害程度也越大。建议在中华大刀螂生活范围内减少高效氯氟氰菊酯、联苯菊酯、啶虫脒和毒死蜱的施用,推荐杀虫剂田间使用量时,除考虑对防治对象的防效,还应考虑对天敌种群的危害,提高药剂使用安全性,保护天敌种群的稳定性。     

Influence of selected insecticides on phosphatase activity in groundnut (Arachis hypogeae L.) soils

Selected insecticides, Chloropyrifos, Dichlorovos, Methyl parathion, Phorate and Methomyl, at concentrations ranging from 0 to 10 kg ha(-1) were tested for their non-target effects towards activity of phosphatases in two soils. In soil samples receiving 2.5 kg ha(-1) of the insecticides Dichlorovos, Phorate and Methomyl and also in soil samples receiving 5.0 kg ha(-1) of the insecticides, Chloropyrifos and Methyl parathion, the activity of phosphatase was significantly more at 20 days period of incubation and decreased progressively with increasing period of incubation.