PCBs和PBDEs的生物效应及人体健康影响的研究现状

环境中的多氯联苯(PCBs)和多溴联苯醚(PBDEs)通过食物链,可以在水生生物实现生物积累。而人类食用这些含有污染的食品,可以造成对人体的健康危害的摄食暴露,导致癌症、内分泌失调等疾病,并影响生育能力和儿童智力发育。但由于生物体内在因素的复杂性,PCBs和PBDEs在生物体内的代谢、放大等机制仍不明确,有待进一步的研究。     

渤海湾脉红螺中多氯联苯和多溴联苯醚的测定分析

应用GC/HRMS对渤海湾脉红螺中的PCBs(多氯联苯)和PBDEs(多溴联苯醚)2类持久性有机污染物进行了测定分析.结果表明:雄性脉红螺中PCB(3～10氯代)的质量分数(10.1 ng/g,以干质量计)和PBDEs(BDE28、BDE47、BDE99、BDE100、BDE153、BDE154、BDE209)的质量分数(1.74 ng//g)均高于雌性脉红螺(分别为8.09和1.38 ng/g);雄性脉红螺中PCBs的WHO-TEQ(毒性当量,8.41 pg/g,以脂肪质量计)高于雌性脉红螺(4.34 pg/g),其中PCB118和PCB126的贡献率分别为13%和77%.脉红螺的不同组织中,性腺和消化腺中w(PCBs)和w(PBDEs)最高,肌肉组织中最低;主要同类物为PCB118、PCB101、PCB28、PCB138、PCB180、PCB52、PCB153和5-PCB以及BDE209.渤海湾脉红螺的消化腺可以作为PCBs和PBDEs的生物指示物.     

加速溶剂萃取-气相色谱质谱法测定海洋沉积物中多氯联苯残留

样品采用加速溶剂萃取,萃取液依次经复合硅胶和石墨化炭黑柱净化后,采用GC-MS法测定样品中的多氯联苯残留。结果表明,方法检出限为(0.005～0.038)×10-9(湿重),样品加标回收率为68.5%～108.4%,RSD为2.1%～11.8%。本方法具有提取效率高,净化效果好,回收率高,准确灵敏等优点,可应用于海洋沉积物中多氯联苯等持久性有机污染物残留的监测。     

电子废物拆解区农业土壤中多氯联苯的污染特征

用GC-μECD分析法测定了路桥表层土壤中144种多氯联苯同类物的含量.目的是了解该地区表层土壤中PCBs的污染水平、空间分布特征和来源.结果表明,样品中ΣPCBs为0.779～937 ng.g-1,均值为75.7 ng.g-1,研究区域中南部污染水平较高.同族体组成特征表明,38个样品组成以penta-CBs、hexa-CBs和tetra-CBs为主,含量范围分别为13.0%～61.1%、4.59%～48.8%和10.1%～31.5%;另外3个样品组成以di-CBs为主,范围为47.1%～75.2%.聚类分析表明,大多数样品主要受到Ar1254工业品的污染,少数样品的污染与Ar1221工业品有关.ΣPCBs与TOC显著相关,表明土壤中TOC的含量是影响PCBs在土壤中蓄积的重要因素之一;各PCBs同族体(除di-CBs与nona-CBs之间外)显著相关,表明各PCBs同族体有相似的输入途径.与国内外其它研究相比,研究区域表层土壤PCBs污染处于中高水平.     

7种指示性多氯联苯混合标准样品量值不确定度研究

分析并评估了异辛烷中7种指示性多氯联苯(PCBs)混合标准样品的量值不确定度。通过分析PCBs纯品中结构相似物、水分、无机物等杂质的含量,采用质量平衡法对PCBs纯品的纯度进行了定值。结果显示,7种指示性PCBs纯品的纯度为98.24%~99.92%,纯度不确定度为0.08%~1.28%。采用称量-容量法制备了各组分浓度均为50.0 μg/mL的异辛烷中7种指示性PCBs混合标准样品,全面分析了各组分的量值不确定度来源,主要包括样品配制、均匀性和长期稳定性等引入的不确定度。结果表明,该标准样品中,7种指示性PCBs组分的合成扩展不确定度为0.7~1.7 μg/mL。该标准样品量值准确且具有计量溯源性,可为我国PCBs相关国际履约监测和新污染物监测提供有效支撑。     

Why biota still accumulate high levels of PCB after removal of PCB contaminated sediments in a Norwegian fjord

Accumulation of polychlorinated biphenyls (PCBs) in blue mussels (Mytilus edulis) and semipermeable membrane devices (SPMDs) was still high after the removal of PCB contaminated sediments from a Norwegian fjord by dredging. The accumulation of low chlorinated PCB congeners with a low octanol water-partitioning coefficient (K_ow) in blue mussels and SPMDs was higher than for the highly chlorinated congeners with a high K_ow. The accumulation of low chlorinated congeners was also higher in a lightly contaminated area compared to a highly contaminated area. That dredging the contaminated sediments was unsuccessful in lowering PCB levels in the biota may be for the following reasons: (1) Due to the low solubility of PCBs in the water it is possible that a decrease in the sediment concentration of PCB would leave the water concentrations of PCB unchanged. (2) Removal of the fine organic sediments may also play an important role, since a seabed with coarse inorganic material has a lesser ability to bind PCB. (3) The dredging may whirl up fine contaminated particles that eventually settles on the seabed producing a thin contaminated sediment layer that determine the water concentration. (4) Bioaccumulation in blue mussels and in the SPMDs occurs mostly from PCB dissolved in the water column. Since the water concentration of PCB is unchanged by the dredging, the accumulation in SPMDs and mussels is the same as before dredging. Further monitoring need to be carried out to report the long-term effect of the dredging.     

高脂肪样品中PCBs和OCPs分离方法研究

研究开发了用于分离高脂肪样品中21种多氯联苯（PCBs）和22种有机氯农药（OCPs）的分离柱填料,以及利用该填料分离含脂肪的动物组织样品中PCBs或OCPs的方法。该填料按质量百分比由硅胶-弗罗里硅土混合物30%-35%、酸性改性硅胶50%-60%和无水硫酸钠10%-15%组成,并使用自主研发的四通道色谱分离仪对样品进行分离和净化。利用本方法的填料分离PCBs或OCPs,分离方法高效、快速、工艺简单,可在成本较低的条件下达到显著的分离效果。PCBs化合物柱回收率可达96.4%-119%,对鱼脂肪组织加标回收率可达74.4%-100%;OCPs化合物柱回收率可达78.4%-103%,对鱼脂肪组织加标回收率可达78.3%-102%。结果表明该填料可用于分离PCBs或OCPs,色谱分离效果良好,可以满足高脂肪样品中OCPs和PCBs的监测分离需要。     

Medium ‐ pressure ‐ liquid ‐ extraction (MPLE) of selected polychlorinated biphenyls from soil (MPLE II) 1

The extraction of PCBs from spiked soils using the Medium‐Pressure Liquid‐Extraction method showed good recovery rates. Comparison of MPLE and Soxhlet extraction of naturally contaminated soil showed similar results. However, too large quantities of solvents have to be used in MPLE procedure and the elution profile makes it unlikely, that the aspired separation from PAHs would be sufficient.     

城市不同功能区径流中PCBs的污染特征及毒性评价

选取温州不同城市功能区小区路面、停车场、汇流口、小区屋面以及交通干道作为研究对象,采集径流样品测定了14种多氯联苯(PCBs)的浓度,并对其进行多元统计分析,探讨了其可能的污染来源.结果表明,不同城市功能区径流中PCBs含量和检出率有所差别但变化不大,其中小区屋面要高于交通干道、汇流口、停车场和小区路面(均值分别为337.9, 306.3, 240.1, 193.2, 172.7ng/L);径流中以五氯代PCBs为主,占到总量31.4%~56.2%;径流中PCBs跟SS浓度相关性较差;由多元统计分析结果可以看出,高低氯代PCBs污染来源不同;TEQs在汇流口、小区路面、停车场径流中浓度相对较大,分别达到4.4, 4.1, 4.0ng/L,这跟其径流中CB126含量较高有关.     

Dechlorination of 2,2＇,4,4＇,5,5＇-hexachlorobiphenyl by thermal reaction with activated carbon-supported copper or zinc

Activated carbon （AC）-supported copper or zinc made from ion exchange resin （IRCu-C and IRZn-C） have an increased metal load of 557.3 mg·g^-1 and 502.8 mg·g^-1 compared to those prepared by the traditional method involving impregnation with AC and copper （II） citrate or zinc citrate solution （LaCu-C and LaZn-C） of 12.9 mg·g^-1 and 46.0 mg·g^-1 respectively. When applied to decompose 2,2＇,4,4＇,5,5＇-hexachlorobiphenyl at 250 ℃, IRCu-C achieved higher activity of 99.0% decomposition efficiency than LaCu-C of 84.7%, IRZn-C of 90.5% and LaZn-C of 62.7%. When the reaction temperature rose to 350 ℃, all the four kinds of reactants can decompose PCB- 153 with efficiency above 90%. Further, X-ray photoelec- tron spectroscopy characterization of IRCu-C before and after the reaction indicated transformation of 19.1% of Cu atoms into Cu^2＋, illustrating that Cu is the active ingredient or electron donor promoting the decomposition of PCB- 153. The mechanism underlying this process differs from a traditional H donor. However, there is no significant change on the surface of IRZn-C before and after the reaction, suggesting that Zn acts as catalyst during the process of PCB-153 decomposition.