Effect of dissolved organic matter on the toxicity of chlorotoluron to Triticum aestivum

Response of two wheat cultivars （Triticum aestivum cv. YM 158 and NM 9） to the herbicide chlorotoluron and the effect of two forms of dissolved organic matter on the chlorotoluron toxicity to the plants were characterized. Treatment with chlorotoluron at 10-50 μg/ml inhibited the seed germination and a dose-response was observed. The inhibition of seed germination was correlated to the depression of a-amylase activities. To identify whether chlorotoluron induced oxidative damage to wheat plants, the malondlaldehyde （MDA） content and electrolyte leakage were measured. Results showed that both MDA content and electrolyte leakage in the chlorotoluron-treated roots significantly increased. Activities of several key enzymes were measured that operate in citric acid cycle and carbohydrate metabolic pathway. Inhibited activities of citrate synthase and NADP-isocitrate dehydrogenase were observed in the chlorotoluron-treated roots as compared to control plants. We also examined malate dehydrogenase and phosphoenolpyruvate carboxylase in wheat roots exposed to 30 μg/ml chlorotoluron, liowever, none of the enzymes showed significant changes in activities. Application of 160 μg/ml dissolved organic matter （DOM） extracted from non-treated sludge（NTS） and heat-expanded sludge （lIES） in the medium with 30 μg/ml chlorotoluron induced an additive inhibition of seed germination and plant growth. The inhibition of growth due to the DOM treatment was associated with the depression of activities of a-amylase, citrate synthase and NADP-isocitrate dehydrogenase, as well as the increase in malondlaldehyde content and electrolyte leakage. These results suggested that the presence of DOM might enhance the uptake and accumulation of chlorotoluron, and thus resulted in greater toxicity in wheat plants. The two forms of DOM exhibited differences in regulation of chlorotoluron toxicity to the wheat plants. Treatments with DOM-NTS induced greater toxicity to plants as compared to those with DOM-HES. In addition to DOM affecting chlorotoluron-induced toxicity to wheat plants, the cultivars could have also contributed to differences. Generally, NM-9 showed a higher sensitivity to chlorotoluron than YM 158 either in the absence or in the presence of DOM.

Effect of Dissolved Organic Matter on Chlorotoluron Sorption and Desorption in Soils

A batch equilibrium techniques was used to examine the effect of dissolved organic matter （DOM） extracted from both non-treated sludge （NTS） and heat-expanded sludge （HES） on the sorption and desorption of chlorotoluron （3-（3-chloro-p-tolyl）-1,1-dimethylurea） in two types of soils, a yellow fluvo-aquic and a red soil from China. Without DOM,sorption of chlorotoluron was significantly greater （P 〈 0.05） in the red soil than in the yellow fluvo-aquic soil. However,with DOM the effect was dependent on the soil type and nature of DOM. Chlorotoluron sorption was lower in the yellow fluvo-aquic soil than in the red soil, suggesting that with the same DOM levels the yellow fluvo-aquic soil had a lower sorption capacity for this herbicide. Application of DOM from both NTS and HES led to a general decrease in sorption to the soils and an increase in desorption from the soils. Desorption of chlorotoluron also significantly increased （P 〈 0.05） with an increase in the DOM concentration. Additionally, for sorption and desorption, at each DOM treatment level the NTS treatments were significantly lower （P 〈 0.05） than the HES treatments. This implied that non-treated sludge had a greater effect on the sorption and desorption of chlorotoluron than heat-expanded sludge.

Impact of atrazine and nitrogen fertilizers on the sorption of chlorotoluron in soil and model sorbents

Sorption of chlorotoluron in ammonium sulfate, urea and atrazine multi-solutes system was investigated by batch experiments. The results showed application of nitrogen fertilizers to the soil could affect the behavior of chlorotoluron. At the same concentration of N, sorption of chlorotoluron decreased as the concentration of atrazine increased on the day 0 and 6 in soil, respectively. The sorption of chlorotoluron increased from 0 to 6 d when soils were preincubated with deionized water, ammonium sulfate and urea solution for 6 d. That indicated incubation time was one of the most important factors for the sorption of chlorotoluron in nitrogen fertilizers treatments. The individual sorption isotherms of chlorotoluron in rubbery polymer and silica were strictly linear in single solute system, but there were competition sorption between pesticides or between pesticides and nitrogen fertilizers. That indicated the sorption taken place by concurrent solid-phase dissolution mechanism and sorption on the interface of water-organic matter or water-mineral matter.

两种除草剂复合污染对蚯蚓的毒性效应

以赤子爱胜蚓为研究对象,采用滤纸急性毒性实验,研究了农药绿麦隆与阿特拉津对蚯蚓的单一和复合毒性效应,2种农药对蚯蚓体内超氧化物歧化酶(SOD酶)活力的影响以及通过苏木素-伊红(HE)染色病理染色切片观察了染毒蚯蚓的细胞形态。单一毒性实验表明,阿特拉津对蚯蚓的毒性大于绿麦隆,绿麦隆和阿特拉津48 h的半致死浓度分别为189.64和43.33 mg.L-1。复合毒性实验表明,绿麦隆分别与30和40 mg.L-1阿特拉津复合,其48 h的半致死量分别为116.03和48.14 mg.L-1。绿麦隆和阿特拉津的复合污染对蚯蚓的毒性具有明显的协同作用,而这种协同作用与污染物的浓度有关。通过观察单一和复合体系中毒蚯蚓SOD酶活力可以看出,无论是单一还是复合体系,随着2种农药浓度的增加,蚯蚓体内SOD酶活性增强。病理HE切片表明,随着绿麦隆浓度的增加,蚯蚓表皮和肠道受损越来越严重,而阿特拉津单体系和绿麦隆与阿特拉津复合体系中毒蚯蚓的消化道破损比较严重,说明绿麦隆和阿特拉津进入蚯蚓体内后作用的部位不同。

阿特拉津和绿麦隆对赤子爱胜蚓组织抗氧化酶活性的影响

通过模拟污染实验,分析了阿特拉津和绿麦隆在单一和混合污染胁迫下对蚯蚓鲜重和抗氧化酶(超氧化物歧化酶(SOD)和过氧化氢酶(CAT))活性的影响.结果表明,蚯蚓鲜重随着处理时间的延长而降低,与处理浓度有一定的相关性.两种除草剂在蚯蚓体内的代谢表现为低浓度时诱导了SOD和CAT活性的增加,而高浓度时则抑制其活性;阿特拉津对蚯蚓SOD和CAT的诱导效应和抑制效应大于绿麦隆.

粮食中绿麦隆残留量的气相色谱分析

本文用六氟丁酸酐直接衍生化气相色谱法测定粮食中绿麦隆农药残留量.粮食样品用甲醇-水提取.滤液用二氯甲烷或三氯甲烷-石油醚混合溶剂萃取,经硅镁吸附剂净化.以丙酮-石油醚为洗脱剂,洗脱液浓缩后用七氟丁酸酐直接衍生化,采用气相色谱法,电子捕获检测器测定.方法的线性范围为0—2.5μg·ml^(-1).对5g粮食样品,方法检出限为0.01mg·kg^(-1).对于小麦、玉米和大豆样品,加标回收率为82.4—91.2%,相对标准偏差为4.1—10.3%.对实际样品的测定和有关单位验证的结果表明,本方法适合于粮食中绿麦隆残留量的测定.

四种除草剂对土壤脲酶活性的影响研究

为研究4种除草剂对土壤脲酶活性的影响及其程度,在实验室模拟条件下,乙草胺、莠去津、绿麦隆、丁草胺4种除草剂单一处理人工土壤时,研究了土壤脲酶活性的变化。结果表明,在供试浓度范围内,4种除草剂对土壤脲酶均有不同程度的激活作用,其中乙草胺、莠去津、绿麦隆、丁草胺对土壤脲酶活性的最大激活率分别为53.6%、17.4%、31.9%和25.5%,最大抑制率分别为34.8%、27.0%、18.7%和55.8%,且4种除草剂处理剂量与土壤脲酶活性之间的二元一次方程拟合效果较好,达到了显著或极显著相关水平,总体上表现为先增加后降低、低浓度诱导高浓度抑制的规律性变化。从4种除草剂处理浓度对土壤脲酶的增幅和方程系数来看,对土壤脲酶活性的影响为:丁草胺>乙草胺>绿麦隆>莠去津。

小麦品种对绿麦隆反应敏感性的遗传研究

本研究以对绿麦隆反应敏感的苏麦3号、望水白及宁7840和不敏感的宁麦6号及扬麦5号五个小麦品种为亲本,在冷温室内、在有效用药量为0.15克/米~2的条件下,观察了绿麦隆对亲本、F_1及部分 F_2和回交后代苗期表现的影响。结果表明,对绿麦隆反应的敏感性的差异受一对基因控制,敏感为隐性,不敏感为显性。建议把苏麦3号和望水白中的同质敏感基因符号暂定名为 cht。并指出通过常规育种手段选育耐绿麦隆的小麦新品种并不十分困难。

绿麦隆和阿特拉津联合染毒对小鼠睾丸的影响

目的研究绿麦隆和阿特拉津单体系及联合作用对小鼠睾丸形态及结构的影响。方法将昆明种小鼠按灌胃农药和剂量随机分为20组犤1个对照组,4个绿麦隆染毒组(321.5、1250、2500、5000mg/kg),3个阿特拉津染毒组(218.75、875、1750mg/kg),12个联合染毒组犦,每组10只。连续25d经口灌胃,每天1次,每次1ml。并用光学显微镜、电子显微镜对小鼠睾丸病理学变化进行观察。结果农药单体系及联合染毒体系各剂量组对小鼠睾丸均有不同程度的损伤。与对照组比较,光学显微镜观察所见为各剂量组出现不同程度生精上皮细胞排列疏松、紊乱,生精细胞脱落,层次减少,病变严重;电子显微镜观察为各剂量组出现不同程度生精细胞线粒体呈空泡样改变,核膜肿胀、弯曲,支持细胞功能低下随染毒剂量增加,上述病理学变化有加重趋势,联合染毒组病理变化比单体系染毒组更明显。结论绿麦隆和阿特拉津对小鼠睾丸的毒性与染毒剂量相关,联合作用体系加重了对小鼠睾丸的毒性效应。

差示扫描量热法测定除草剂绿麦隆的纯度

研究了用差示扫描量热法（DSC）测定绿麦隆的纯度。该法测定最佳条件为升温速率0．5K·min^-1，样品量2～3mg，保护气流速20mL·min^-1。用本法测得绿麦隆原药的纯度为98．35％，相对标准偏差（RSD）为0．034％，测定结果与已知纯度相符。并将测定结果与高效液相色谱（HPLC）法进行了比较。该法具有操作简便，样品用量少，准确度和精密度均较高等优点。

绿麦隆、阿特拉津单一与复合污染对蚯蚓的毒性效应研究

以赤子爱胜蚓为研究对象,采用滤纸急性毒性实验研究了农药绿麦隆、阿特拉津对蚯蚓的单一和复合毒性效应。单一毒性实验表明,绿麦隆与阿特拉津单独存在时,均对赤子爱胜蚓产生毒性。阿特拉津对蚯蚓的毒性大于绿麦隆,绿麦隆和阿特拉津48h的半致死质量浓度分别为189.64和43.33mg·L-1。复合毒性实验表明,绿麦隆与30mg·L-1和40mg·L-1的阿特拉津复合,其48h的半致死量分别为116.03和48.14mg·L-1。绿麦隆和阿特拉津的复合污染对蚯蚓具有明显的协同作用,而这种协同作用与污染物的质量浓度有关。

绿麦隆与莠去津混用防除玉米田杂草

２５％绿麦隆可湿性粉剂与５０％莠去津可湿性粉剂按１：１混合后，于玉米播后苗前按亩用量１５０～２５０克对水土表喷雾，对一年生各类杂草均有很好防效，并有明显增效作用，且对后茬作物安全。

绿麦隆在水溶液中光降解动力学研究

以低功率紫外灯和荧光灯为光源对水溶液中的绿麦隆进行光降解，探讨了光解的影响因素．研究表明，绿麦隆在紫外光照下较易降解，其光解符合准一级动力学方程，反应速率常数为２３×１０－２ｍｉｎ－１；在水环境中经长期光照会逐渐矿化为Ｃｌ－、ＣＯ２、ＮＯ－３等无机离子；运用ＧＣ／ＭＳ技术鉴定了绿麦隆的几种光解中间产物，异氰酸（３氯—４甲基）—苯酚酯是主要中间体，并推测了绿麦隆的光解反应历程．

绿·乙·莠对玉米的安全性及除草效果

田间测定了氯·乙·莠对玉米的安全性及其除草效果,结果表明,40%氯·乙·莠可湿性粉剂3375～3750g/hm2防除玉米田禾本科杂草稗草、狗尾草、马唐效果较好,株防效为74.4%～99.2%;对阔叶杂草中的反枝苋也有很好的效果,株防效为91.4%～100%。在推荐剂量下,氯·乙·莠防除玉米田杂草对玉米安全,且有显著的增产作用,比空白对照增产9.9%～16.2%。

水溶性有机物对绿麦隆胁迫下小麦幼苗生物利用性和毒性的影响

研究了在2种来源的DOM(水溶性有机物)和绿麦隆作用下,小麦幼苗在不同培养时间(4和10 d)组织累积量和抗氧化系统的响应,探讨了小麦幼苗在DOM作用下对绿麦隆胁迫的毒性响应影响及机制.结果表明:在不同的培养期内,绿麦隆均抑制了小麦幼苗的生长,而2种不同来源的DOM均缓解了绿麦隆对植株的毒性.DOM的施加使绿麦隆胁迫下小麦叶和根中的丙二醛(MDA)含量降低,同时绿麦隆诱导的超氧化物歧化酶(SOD)和过氧化氢酶(CAT)的活力也有所降低,然而过氧化物酶(POD)和谷胱甘肽巯基转移酶(GST)的活性却有一定程度的增高.使用RT-PCR半定量分析方法对SOD和GST的酶活性变化进行了分析,以确证DOM缓解绿麦隆对小麦幼苗的毒性调节机制.

绿麦隆复合体系对小鼠睾丸组织的影响

目的:研究绿麦隆复合体系对小鼠睾丸组织的影响。方法:雄性昆明小鼠经口染毒绿麦隆25 d,取睾丸组织作为标本观察。结果:绿麦隆单体系及复合体系各剂量组对小鼠睾丸均有不同程度的改变。光镜观察所见:生精上皮细胞排列疏松、紊乱;生精细胞脱落,层次减少。电镜观察所见:生精细胞线粒体呈空泡样改变,核膜肿胀、弯曲,支持细胞数目减少,部分细胞紧密连接破坏。结论:小鼠睾丸呈细胞退行性改变趋势,随剂量增加及复合染毒,病变加重。

反相高效液相色谱法测定绿麦隆

反相高效液相色谱法测定绿麦隆王以燕，孙绮丽，张百臻（农业部农药检定所，国家农药质量监督检测中心北京１０００２６）１前言绿麦隆（ｃｈｌｏｒｏｔｏｌｕｒｏｎ）是一取代脲类麦田除草剂，它具有选择性内吸传导作用，目前是我国广泛使用的除草剂之一。绿麦隆分析方法...

氮肥对绿麦隆在土壤中吸附-解吸作用的影响

通过室内模拟试验,研究了硫铵、尿素对绿麦隆在土壤中吸附、解吸作用的影响。结果表明,当绿麦隆与硫铵或尿素同时施入土壤后,土壤对绿麦隆的吸附作用增加,并随氮肥浓度的增加吸附作用增强;用氮肥培养土壤6d后加入绿麦隆,吸附能力为尿素处理>对照>硫铵处理,与未经培养的处理相比降低了6.18%￣30.99%,这与土壤中DOC的含量和种类有关。解吸试验表明,绿麦隆从未经硫铵或尿素培养土壤上的解吸能力高于对照10.53%￣38.60%,而其从用硫铵和尿素培养6d土壤上的解吸能力与对照无明显差异。另外,其与未经培养的土壤相比,解吸能力增加了大约2倍。这些结果表明,硫铵和尿素影响绿麦隆在土壤中的吸附、解吸作用,从而影响绿麦隆在土体中的迁移。

液相色谱法测定玉米和土壤中绿麦隆的方法

为评价常用除草剂绿麦隆的用药安全性,利用有机溶剂固液萃取的提取技术,通过对振荡时间提取回收率的对比,确定提取时间为2 h,在此基础上,采用C_(18)色谱柱分离,乙腈-水洗脱,在243 nm下测定玉米植株、玉米籽粒和土壤中残留的绿麦隆农药的高效液相色谱分析方法。该方法绿麦隆的最低检出量为1.0×10^(-3)ng,最低检出浓度为0.001 mg/kg。加标回收率90.4%~108.8%。说明该方法易于操作,回收率高,是测定玉米和土壤中绿麦隆的有效定量方法。

阿特拉津对绿麦隆吸附-解吸作用的影响

采用批平衡实验,研究绿麦隆在单一及复合污染体系中的吸附-解吸行为。结果表明,无论是单一体系还是复合体系,吸附等温线均可用Freundlich模型进行良好的拟合。随着阿特拉津浓度的增加,土壤对绿麦隆的吸附作用降低,表明绿麦隆和阿特拉津之间存在竞争吸附,这可能与土壤的有机质类型和绿麦隆、阿特拉津的性质、结构有关。解吸实验表明,随着阿特拉津的浓度增加,绿麦隆的解吸作用增加。吸附过程的拟合指数n值大于解吸过程的对应值,即绿麦隆在不同体系中的解吸作用均存在一定的滞后性。应用Freundlich解吸等温线参数对吸附-解吸等温线的滞后作用进行量化,CT、(CT+0.5AT)、(CT+1AT)和(CT+2AT)处理解吸等温线的滞后系数ω分别为165.200,146.132,94.534和85.945,即随阿特拉津浓度增加,绿麦隆解吸等温线的滞后性降低。