北京工业废水和城市污水中有机氯农药残留分析

建立了基于HLB固相萃取柱和气相色谱-电子捕获(GC-ECD)测定水体中有机氯农药的方法,并对方法的回收率、灵敏度进行了评价,同时分析了北京市七类典型污染点源50个采样点位有机氯农药的浓度,检测到的有机氯农药包括γ-六六六、β-六六六、4,4’-滴滴涕、α-六六六、δ-六六六、硫丹Ⅰ、4,4’-滴滴伊、艾氏剂和异狄氏剂,它们的检出率分别为90%、60%、50%、46%、26%、8%、6%、2%和2%。主要有机氯农药污染残留为γ-六六六、β-六六六和4,4’-滴滴涕。检出有机氯农药浓度范围是0.20~76.40ng/L。方法对有机氯农药的回收率达到60.93%~141.50%,方法检测限为0.27~2.90ng/L。     

中空纤维膜萃取-气相色谱法测定水中有机氯农药

提出了中空纤维膜萃取-气相色谱法测定水中有机氯农药的方法。首先研究了8种有机氯农药的线性范围,然后测定了中空纤维膜萃取对水中有机氯农药的回收率,最后用中空纤维膜萃取-气相色谱法对实际水样进行检测。结果表明,8种有机氯农药在0.5~10μg/L范围内具有良好的线性关系,中空纤维膜萃取法对水中8种有机氯农药的富集倍数为389~464,回收率为77%~92%,可以满足分析要求。     

乌鲁木齐地表水饮用水源地水体有机氯农药健康风险评价

为了解乌鲁木齐市地表饮用水源地水体中有机氯农药(OCPs)对人体产生的潜在健康危害风险,从一号冰川、英雄桥、乌拉泊水库的9个采样点采集水样,采用液液萃取-气相色谱/质谱法对其中的有机氯农药残留状况进行了测定,水样中9种有机氯化合物的总质量浓度为15.1 ng/L～41.2 ng/L。应用美国国家环保局(US EPA)推荐的健康风险评价方法,对乌鲁木齐市地表饮用水源地水体中有机氯农药通过食用途径进入人体的危害进行了风险计算和初步评价。结果表明,各监测断面的致癌风险和非致癌风险低于ICRP和USEPA推荐的最大可接受风险水平,初步认为目前乌鲁木齐市地表饮用水源地水体中有机氯农药不会对人体产生明显的健康危害。     

超声波萃取-气相色谱/质谱法测定土壤中15种Pops类有机氯农药

用探头式超声波萃取仪、己烷/丙酮混合溶剂提取土壤中的15种Pops类有机氯农药(包括六氯苯、七氯、六六六、氯丹、艾氏剂、狄氏剂、异狄氏剂、灭蚁灵、滴滴涕),萃取溶液经氟罗里硅土柱净化、氮吹浓缩,用气相色谱/质谱仪(GC-MS)进行测定。方法检出限0.4～1.4μg/kg,空白样品有机氯农药加标回收率为52.8%～118%、有机氯标记替代物回收率为71.0%～122%,RSD为6.8%～16.5%。     

官厅水库沉积物表层中的有机氯农药分布特征及风险评价

采用气相色谱法对北京市官厅水库沉积物表层中持久性有机氯农药(OCPs)的残留状况进行了调查,并对有机氯农药污染水平和生态风险作出评价。结果表明:沉积物中有机氯农药总含量为8.48 ng/g～24.40 ng/g,其中HCHs和DDTs的含量较高,分别为1.11 ng/g～7.73 ng/g和2.97 ng/g～10.52 ng/g,其组分特征为来自环境的残留。与沉积物风险评估低值(ERL)和风险评估中值(ERM)对比评价沉积物中有机污染物的风险程度,官厅水库沉积物表层中的有机氯农药存在一定的生态风险。     

南四湖表层沉积物中有机氯农药的含量及分布特征

利用气相色谱-电子俘获检测(GC-ECD)方法对南四湖表层沉积物中13种有机氯农药进行了分析测定。每个采样点均检出了有机氯农药,与世界其它类似水体比较,南四湖表层沉积物中的有机氯农药处于低水平含量,属于低生态风险水平。多数点位有机氯农药均是由于历史上使用造成的,但不排除个别点位存在新的污染源。     

乌江流域中上游水体中有机氯农药残留现状调查

采集了乌江流域中上游30个采样点的60个水样品,用液-液萃取对样品进行前处理,然后用GC-ECD测定有机氯农药含量,分析有机氯农药残留现状。结果表明,有机氯农药在样品中都有不同程度的检出,其中六六六、滴滴涕类物质的检出率分别为90.7%、46.9%,质量浓度为4.03~42.89 ng/L,同我国其它区域相比,乌江流域中上游水体中的有机氯含量处于中等水平,低于相应的标准限值。故就有机氯农药这类污染物在水中的含量来说,乌江流域中上游的水体是相对安全的。但由于这类污染物是持久性的,因此它们在水环境中的存在和影响也是不容忽视的。     

固相萃取-气相色谱法测定水中多种农药类内分泌干扰物

建立了水样中用固相萃取小柱提取和净化、GC-ECD检测、GC-MSD定性证实的农药类内分泌干扰物检测方法,该方法样品提取、浓缩、净化步骤简便,能实现31种目标物同时检测。方法检测限0.05~0.50μg/L。添加回收率69%~101%,相对标准偏差低于10%。选择农药包括有机氯类(如滴滴涕、六六六、三氯杀螨醇、艾氏剂、异狄氏剂、狄氏剂、七氯、硫丹、氯丹等),氨基甲酸酯类(如甲草胺、乙草胺等),除虫菊酯类(如氯氰菊酯、速灭菊酯等)及其它农药(如氟乐灵、除草醚、毒死蜱)。该方法应用到测定某水库的水样,水库中31种农药类内分泌干扰物总浓度为48.8~890 ng/L,平均浓度295 ng/L。     

气相色谱法测定赤水河中段水体中14种有机氯农药的残留

建立了用正己烷萃取,气相色谱—电子捕获（GC—ECD）测定水体中有机氯农药痕量残留的方法。结果表明：六氯苯、α-HCH、β-HCH、γ-HCH、δ-HCH、p,p′-DDD、p,p′-DDE、p,p′-DDT、艾氏剂、狄氏剂、异狄氏剂、七氯、环氧七氯、o,p′-DDT 14种农药在14 min内有较好的分离;2个不同浓...     

固相萃取- GC/MS法测定水中有机氯农药

建立了固相萃取-气相色谱／质谱联用测定水中痕量六六六、滴滴涕和环氧七氯的方法。采用C18固相萃取柱富集水样,二氯甲烷／丙酮混合溶剂洗脱,加入菲-d10作为内标,利用气相色谱／质谱联用仪选择离子监测模式检测,内标法定量,定性、定量准确,线性响应良好,干扰小,按采样1 L计算,方法检出限为4．26ng／L～19、2ng／L,RSD在0、4％-6、3％之间,平均加标回收率在77．7％～118％之间,实际样品测定结果表明方法能满足环境水体中痕量有机氯农药的监测要求。     

Analysis of pesticide residues in Peninsular Malaysian waterways

The use of organochlorine pesticides has caused concern due to their effects on human health and the Malaysian aquatic ecosystem, particularly so in view of their persistent and bioaccumulative properties. Since the extent of organochlorine pesticide pollution in Malaysian waterways is unknown except for isolated instances, a systematic survey has now been carried out. Water samples from various rivers were extracted, cleaned up with Florisil and analysed for the individual organochlorine pesticides by gas chromatography (GC) with an electron capture detector (ECD). DDE, DDT and heptachlor were present in all the river water samples of the west coast of Peninsular Malaysia. Other organochlorine pesticides were also identified from the water samples. However, the levels of all these are still below criteria values for Malaysian aquatic life, indicating that organochlorine pesticide pollution is less of a problem than other organic or inorganic pollutants.     

Organochlorine Pesticide Residues in Wheat and Drinking Water Samples from Jaipur, Rajasthan, India

The organochlorine pesticide contamination in dietary sources has caused serious threat to the human progeny. The present study was therefore conducted to evaluate the pesticide contamination in wheat flour and drinking water from Jaipur City, Rajasthan, India using Gas Chromatograph. All the wheat and water samples were found to be contaminated with various organochlorine pesticide residues of DDT and its metabolites, HCH and its isomers, heptachlor and its expoxide and aldrin. The amount of pesticide detected in wheat flour was higher than the permissible limits prescribed by WHO/FAO. In drinking water only a few pesticides exceeded the permissible limits. Seasonal variations of pesticides residues were also observed during the study period.     

Pesticide residue level in tea ecosystems of Hill and Dooars regions of West Bengal, India

In the present study we quantified the residues of organophosphorus (e.g. ethion and chlorpyrifos), organochlorine (e.g. heptachlor, dicofol, alpha-endosulfan, beta-endosulfan, endosulfan sulfate) and synthetic pyrethroid (e.g. cypermethrin and deltamethrin) pesticides in made tea, fresh tea leaves, soils and water bodies from selected tea gardens in the Dooars and Hill regions of West Bengal, India during April and November, 2006. The organophosphorus (OP) pesticide residues were detected in 100% substrate samples of made tea, fresh tea leaves and soil in the Dooars region. In the Hill region, 20% to 40% of the substrate samples contained residues of organophosphorus (OP) pesticides. The organochlorine (OC) pesticide residues were detected in 33% to 100% of the substrate samples, excluding the water bodies in the Dooars region and 0% to 40% in the Hill region. The estimated mean totals of studied pesticides were higher in fresh tea leaves than in made tea and soils. The synthetic pyrethroid (SP) pesticide residues could not be detected in the soils of both the regions and in the water bodies of the Dooars. Sixteen percent and 20% of the made tea samples exceeded the MRL level of chlorpyrifos in Dooars and Hill regions respectively. The residues of heptachlor exceeded the MRL in 33% (April) and 100% (November) in the Dooars and 40% (April) and 20% (November) in the Hill region. Based on the study it was revealed that the residues of banned items like heptachlor and chlorpyrifos in made tea may pose health hazards to the consumers.     

气相色谱法同时测定地表水中的百菌清、环氧七氯和有机氯农药

用正己烷一次同时萃取地表水中的百菌清、环氧七氯和有机氯农药,萃取液脱水后进气相色谱仪进行测定。当取样体积为500ml时,方法检出限为0．01～0．02μg,／L,标准曲线相关系数大于0．999,方法精密度的相对标准偏差为1．5％-4．0％,加标回收率为81．6％～109．6％。该方法用于实际样品测定,结果令人满意。     

Distribution and bioaccumulation of organochlorine pesticides (OCPs) in food web of Nansi Lake,China

The concentration of 12 organochlorine pesticides (OCPs) were measured in water, sediment, aquatic plant, and animal (shrimp and fish) of Nansi Lake by gas chromatography equipped with an electron capture detector. The total OCPs concentrations were 65.31–100.31 ng L^?1 in water, 2.9–6.91 ng g^?1 dry weight (dw) in sediments, 1.29–6.42 ng g^?1 dw in aquatic plants and 7.57–17.22 ng g^?1 dw in animals. The OCPs composition profiles showed that heptachlor compounds was also the predominant OCPs contaminants in addition to hexachlorocyclohexanes (HCHs) and dichlorodiphenyltrichloroethanes (DDTs) in Nansi Lake. According to the source of HCHs and DDTs in sediment samples, there was no new input and the HCHs pollution mainly came from the use of Lindane in Nansi Lake. Bioaccumulation of OCPs in aquatic biota indicated that DDTs and heptachlor compounds had a strong accumulation, followed by HCHs and drins. The accumulation abilities of fish for OCPs were higher than those of plants and shrimps. The OCPs biota-sediment accumulation factor values of Channa argus was the highest in fish samples, followed by Carassius auratus, and Cyprinus caspio. Risk assessment of sediment showed that heptachlor epoxide had a higher occurrence possibility of adverse ecological effects to benthic species. Based on the calculation of acceptable daily intake and hazard ratio, HCHs in fish and shrimps from Nansi Lake had a lifetime cancer risk of greater than one per million. The risk assessment of water, sediment, and fish indicated the water environment of Nansi Lake is at a safe level at present.     

The Status of Pesticide Residues in the Drinking Water Sources in Meiliangwan Bay, Taihu Lake of China

The study was carried out to assess the levels of pesticide residues in the water of Meiliangwan Bay, Taihu Lake of China. The most commonly employed organochlorine pesticides (OCPs), organophosphorus pesticides (OPPs) and herbicide atrazine were analyzed. The water samples were collected seasonally from Meiliangwan Bay within a period of one year. The pesticides were analyzed by gas chromatography (GC) with μECD or NPD after solid-phase extraction (SPE), which was confirmed by GC with an ion trap mass spectrometry (MS). The mean concentrations were 1.98 ng/l for lindane, 0.378 ng/l for heptachlor epoxide, 0.367 ng/l for p,p′-DDE, 0.496 ng/l for p,p′-DDD, 1.06 ng/l for p,p′-DDT and 51.6 ng/l for dichlorvos, 39.0 ng/l for demeton, 346 ng/l for dimethoate, 4.12 ng/l for methyl parathion, 11.6 ng/l for malathion, 2.17 ng/l for parathion and 217 ng/l for atrazine. Generally, low concentrations of OCP were found, whereas the concentrations of the OPPs and atrazine in the water of Taihu Lake were relatively high. Heptachlor epoxide and lindane were the two most commonly encountered OCPs while dichlorvos, demeton and dimethoate were found to have much higher concentrations and occurrences than other OPPs.     

Mercury concentrations in tidal marsh sparrows and their use as bioindicators in Delaware Bay, USA

National parks are used worldwide as a means to protect the ecological integrity of unique ecosystems. Dilek National Park in western Turkey is a protected habitat for several endangered and severely threatened species. Thirty-seven water and 59 sediment samples were collected and analyzed for pesticides at two different sampling depths. The park is contaminated with 16 different organochlorine pesticides, with more pesticides detected in sediments than in water. The most prevalent pesticides in the 30–60-cm depth were DDT (69.5% of the samples), heptachlor (62.3%), a-endosulfan (55% of samples), and endrin (37%). Lindane isomers were present, but at <30% of the sediment samples. These pesticides could be a long-term contamination source that enters the food web used by the very species the park is trying to protect.