同位素稀释气相色谱-三重四极杆质谱法测定环境空气中的多氯萘北大核心CSCD

环境空气中的多氯萘(PCNs)一般为痕量水平(pg/m^(3)),要实现其准确定量必然对分析方法的提取、净化和仪器分析提出较高要求。研究通过考察提取溶剂种类、净化流程和色谱-质谱参数,建立了加速溶剂萃取(ASE)-多层硅胶复合中性氧化铝柱的净化方法,并利用同位素稀释气相色谱-三重四极杆质谱(GC-MS/MS)对环境空气中的多氯萘进行测定。同时,通过在采样、提取和进样分析前分别添加同位素内标,开展质量控制和保证。结果表明,在2~100 ng/mL范围内3~8氯萘的平均相对响应因子(RRF)的相对标准偏差(RSD)均小于16%。PCNs同类物的方法检出限为1~3 pg/m^(3)(以样品体积为288 m^(3)计算)。采用基质加标法评价了方法对环境空气样品中PCNs测定的精密度和准确度,低、中、高加标水平下3~8氯萘的平均加标回收率分别为89.0%~119.4%、98.6%~122.5%和93.7%~124.5%,测定结果的平均相对标准偏差分别为1.9%~7.0%、1.6%~6.6%和1.0%~4.8%。整个分析过程中,采样内标和提取内标的平均回收率分别为136.2%~146.0%和42.4%~78.1%,RSD分别为5.6%~7.5%和2.7%~17.5%,满足痕量分析的要求且平行性较好。方法的灵敏度和准确度高,精密度良好,适用于环境空气中3~8氯萘的准确定量测定,可在一定程度上缓解多氯萘监测对高分辨气相色谱-高分辨质谱的依赖,为实现多氯萘的国际履约提供方法支持。     

加速溶剂萃取-硅胶柱净化-碱性氧化铝柱分离-气相色谱三重四极杆质谱法测定土壤中的二噁英类化合物

建立了加速溶剂萃取(ASE),酸性硅胶柱、复合硅胶柱及碱性氧化铝柱纯化分离,气相色谱-三重四极杆质谱测定土壤中二噁英/呋喃(PCDD/Fs)、多氯联苯(PCBs)、多氯萘(PCNs)的分析方法.选用正己烷-二氯甲烷(50∶50, V/V)作为ASE的提取溶剂,设定提取温度为120℃,加标回收实验表明本方法可行.用100 mL正己烷-二氯甲烷(95∶5, V/V)及50 mL正己烷-二氯甲烷(50∶50, V/V)依次淋洗碱性氧化铝柱,得到组分A(PCBs及PCNs)与组分B(PCDD/Fs),实现了PCDD/Fs与另外两种化合物的分离,排除了同系物间及其它杂质的干扰.使用同位素稀释-气相色谱三重四极杆质谱法(GC-MS/MS), 在选择反应监测(Selected reaction monitoring, SRM)模式下测定PCDD/Fs、PCBs和PCNs,3种化合物的仪器检出限(LOD)范围分别为0.04~0.25 μg/L, 0.10~0.20 μg/L和0.01~0.05 μg/L,目标物平均相对响应因子(RRF)的相对标准偏差(RSD)均小于13%.基质土加标实验中,3种化合物13C标记的同位素内标回收率的范围分别为50%~95%,51%~103%, 49%~74%.实际样品的分析结果表明,PCDD/Fs、PCBs及PCNs在土壤样品中的总含量范围分别为16.1~1148 pg/g、6.6~152.6 pg/g及10.9~99.5 pg/g,且样品测定结果与高分辨质谱测定结果相吻合.     

气相色谱-质谱法测定地下水中多氯萘

建立了地下水中1-氯萘、2-氯萘、1,4-二氯萘、1,2,3,4-四氯萘、1,3,5,7-四氯萘、1,2,3,5,7-五氯萘、1,2,3,5,6,7-六氯萘、1,2,3,4,5,6,7-七氯萘和八氯萘9种多氯萘(PCNs)的气相色谱-质谱(GC-MS)分析方法。对比研究了液液萃取(LLE)和固相萃取(SPE)萃取地下水中PCNs的提取效率,优选二氯甲烷-液液萃取为PCNs检测的前处理方法。在优化条件下,9种PCNs的线性范围为5~100μg/L,各组分的相关系数(r)大于0.995,方法检出限(S/N=3)为4.21~7.41 ng/L,地下水的平均加标回收率为70.7%~112%,相对标准偏差(RSD,n=5)均小于9.9%。该方法已用于地下水样中多氯萘的检测。     

加速溶剂-固相萃取-高效液相色谱法测定土壤及蚯蚓样品中多环芳烃

研究了加速溶剂萃取( ASE)、固相萃取柱净化( SPE)、高效液相色谱( HPLC)联合( ASE-SPE-HPLC)测定土壤及蚯蚓样品中7种多环芳烃(PAHs)的分析方法,确定了以正己烷-丙酮(4∶1, V/V)作为萃取剂,用ASE对土壤及蚯蚓进行萃取,提取液经SPE柱净化(土壤样品用硅胶柱净化,蚯蚓样品用 Al2 O3-硅胶柱净化),正己烷-二氯甲烷(9∶1, V/V)进行洗脱,洗脱体积为10 mL,旋转浓缩蒸干后,乙腈定容,过0.22μm有机滤膜,最后用HPLC对提取液中7种PAHs进行定量的分析方法。土壤样品方法回收率在83.5%~110.2%之间,相对标准偏差为1.0%~4.6%;蚯蚓样品回收率在81.2%~97.1%之间,相对标准偏差为1.6%~4.2%。方法检出限为0.15~0.85μg/kg,且重现性好。可满足样品分析的质量控制要求,表明本分析方法具有良好的准确性与可靠性。     

加速溶剂萃取-多层硅胶柱净化-气相色谱串联三重四级杆质谱法测定土壤和沉积物中的多氯萘

通过制作多氯萘(PCNs)在商品多层硅胶柱上的流出曲线、优化气相色谱质谱参数和利用三重四级杆质谱的多重反应监测模式,应用氘代一氯萘#2作为一氯和二氯代萘的定量内标,建立了基于DB-5MS和Rt-βDEXcst两根色谱柱的同位素稀释测定土壤和沉积物中多氯萘的分析方法,实现了两种高毒性六氯代萘#66和#67的基线分离。18种多氯萘同类物校正曲线在1.0~240μg/L浓度范围的相对响应因子为0.70~5.45,相对标准偏差小于18.5%。方法检出限在0.014~0.858μg/L之间,定量限在0.048~2.862μg/L之间。30 m的Rt-βDEXcst色谱柱方法效果优于60 m的DB-5MS色谱柱,但前者耗时较长。实际样品分析表明,7种PCNs回收率标记物,除一氯代萘约为6%外,其余均大于28%。测试土壤和沉积物样品中以低氯代萘为主。     

微波萃取/GC-MS法对电子电气产品中多氯萘的测定

建立了微波萃取/GC-MS法检测电子电气产品中多氯萘的方法。将破碎后的样品以甲苯为溶剂进行微波萃取,萃取液经硅胶小柱净化、平行蒸发定量浓缩后采用气相色谱-质谱法测定多氯萘的含量,外标法定量。优化了样品前处理条件,包括前处理方式、微波萃取溶剂、萃取时间,以及净化小柱的选择。对于8种含不同氯原子数的多氯萘,在1~50 mg/L范围内,线性关系良好,相关系数均大于0.995;方法定量下限为0.2~1.0 mg/kg,相对标准偏差为2.7%~7.2%,回收率为77%~112%。该法操作简便、分析迅速、结果准确,可以满足对电子电气产品中多氯萘的定性确证和定量分析。     

高分辨气相色谱-质谱法同时测定食用油中二噁英和呋喃的多氯(溴)代二苯并衍生物的含量

提出了用高分辨气相色谱-质谱法同时测定食用油中17种多氯取代以及8种多溴取代的苯并二噁英和苯并呋喃含量的方法。食用油样品依次经过酸性硅胶床、多段硅胶柱及Florisil柱净化。净化中分别用正己烷、正己烷-二氯甲烷(97+3)混合液、正己烷-二氯甲烷(40+60)和单一的二氯甲烷作为淋洗剂,洗脱上述化合物,GC-MS测定。各化合物的检出限(3S/N)在0.022 3~1.67μg·L-1之间。用标准加入法测得多氯代化合物的回收率在97.8%~118%之间,多溴代化合物的回收率在96.5%~113%之间,测定值的相对标准偏差(n=5)分别为4.9%~6.7%和6.6%~17%之间。     

土壤中10种多溴联苯醚的加速溶剂-固相萃取净化方法优化研究

建立了土壤中10种多溴联苯醚(PBDEs)的加速溶剂萃取-固相萃取净化-气相色谱分析测定方法.采用加速溶剂萃取(ASE)技术对土壤中10种PBDEs进行提取,并对4种萃取体系(正己烷、正己烷-丙酮(4∶1,V/V)、正己烷-丙酮(1∶1,V/V)、正己烷-二氯甲烷(1∶1,V/V))进行优化;采用固相萃取(SPE)技术对样品进行净化,制备了10种不同填料的SPE柱,通过洗脱实验和加标回收率实验对各SPE柱的净化性能进行对比筛选.最终优化条件为正己烷-丙酮(4∶1,V/V)体系提取,酸性硅胶柱净化.在优化条件下,10种PBDEs的回收率为74.4％ ～ 125.2％,相对标准偏差为4.4％ ～ 14.4％,方法检出限为0.04～0.22 ng/mL.本方法简单、快速、净化效果较好、重现性和回收率良好,可用于土壤样品中PBDEs的分析.     

硅胶固相萃取净化/高效液相色谱-串联质谱法测定海洋生物体中六溴环十二烷

建立了海洋生物体中六溴环十二烷(HBCDs)的硅胶固相萃取净化/液相色谱-串联质谱法。样品采用正己烷提取,经硅胶固相萃取柱净化,液相色谱-串联质谱分析。根据硅胶固相萃取柱的使用特性,对洗脱条件进行优化。在ACQUITY UPLC BEH C18色谱柱上进行分离,流动相为水和甲醇乙腈(V甲醇∶V乙腈=4∶6)混合溶液,梯度洗脱。质谱采用电喷雾负离子电离,多反应监测模式,内标法定量。六溴环十二烷在0.50~100.0μg/L范围内线性关系良好,相关系数(r2)大于0.995,定量下限为0.20μg/kg,回收率为85.6%~97.3%,相对标准偏差为3.9%~8.8%。该方法基质干扰小、重复性好,适用于海洋生物中六溴环十二烷的测定。     

固相萃取-气相色谱法定量分析橄榄油中饱和烃矿物油和芳香烃矿物油

建立了固相萃取(SPE)净化、程序升温进样结合气相色谱-氢火焰离子化检测器(PTV-GC-FID)定量分析橄榄油中饱和烃矿物油(MOSH)和芳香烃矿物油(MOAH)污染残留的方法。样品经正己烷溶解后,利用环氧化反应结合自制的分子筛SPE柱和0.3%AgNO_3硅胶SPE柱交替净化方式,消除了样品中脂质、蜡酯、烯烃、天然烷烃等干扰,并实现MOSH和MOAH的有效分离,氮吹浓缩后,经程序升温进样口大体积进样注入GC-FID分析,外标法定量。优化了环氧化试剂用量、环氧化反应时间、固相萃取洗脱体积等实验参数。结果表明,矿物油标准参考物Gravex 913润滑油在2.0~500.0 mg/L范围内呈良好线性关系,MOSH和MOAH的检出限分别为1.0和0.3 mg/kg,定量限分别为3.0和1.0 mg/kg,加标回收率分别为93.2%~103.7%和78.5%~81.3%,相对标准偏差分别为2.7%~5.0%和2.9%~4.0%。本方法净化效果好、试剂用量少、操作简单、检出限低,能有效分离植物油中MOSH和MOAH,适用于橄榄油中矿物油的定量检测。     

全氟/多氟化合物分析方法的研究进展

随着全氟和多氟化合物（perfluoroalkyl and polyfluoroalkyl substances,PFASs）被列入《斯德哥尔摩公约》的持久性有机污染物名录,各国对于该类物质的关注逐步升高。该类物质在环境中的广泛检出,使得其环境行为研究不断扩展和加深。目前,针对不同类型PFASs的样品前处理方式与检测方法也在不断发展中,而从中选择最合适的前处理和分析方法是开展PFASs环境科学、管理和污染控制研究的前提。该文针对传统PFASs及其异构体、PFASs前体物和新型PFASs等的样品前处理方法、色谱-质谱分析方法进行归纳总结,认识其现状和问题,并在此基础上对其发展进行了展望。     

固相萃取-气相色谱-串联质谱法同时测定武汉市普通人群血清中35种有机氯农药与多氯联苯

有机氯农药(OCPs)和多氯联苯(PCBs)是两类重要的持久性有机污染物,可在环境介质中长期存在,并通过多种途径进入人体,导致人体的高暴露风险。OCPs和PCBs对人体存在诸多健康危害,精准定量人体内OCPs和PCBs的暴露水平是健康效应评价的关键。该研究基于固相萃取-气相色谱-串联质谱联用技术(SPE-GC-MS/MS)建立了同时检测100 μL血清中35种OCPs和PCBs的分析方法。血清样品经尿素沉淀蛋白后,采用Oasis^® HLB小柱净化,正己烷-二氯甲烷混合溶液(1∶1, v/v)洗脱,氮吹近干,正己烷定容,多反应监测(MRM)模式检测,内标法定量分析。结果表明,OCPs和PCBs在0.05~50.0 ng/mL范围内线性关系良好,检出限在1.2~71.4 ng/L之间。35种目标分析物的加标回收率在72.6%~142%之间,相对标准偏差小于25%。利用所建立的方法检测了武汉市普通人群血清样本中OCPs和PCBs的浓度水平,结果表明武汉市普通人群广泛暴露于OCPs和PCBs,且以OCPs为主。有8种OCPs和7种PCBs检出率高于50%,其中p,p'-滴滴伊、p,p'-滴滴滴和甲氧滴滴涕检出率达100%,非类二噁英PCBs是PCBs的主要成分。血清中OCPs浓度随年龄增长呈升高趋势,在60岁以上存在性别差异;不同性别、年龄人群血清中PCBs浓度无统计学差异。该方法样本用量少,操作简便,具有较高的准确度和精密度,适用于环境健康研究中大量人群血清样本中痕量OCPs和PCBs的生物监测。     

Analysis of emerging and related pollutants in aquatic biota

Water bodies cover approximately 70 % of the earth´s surface, making them ecosystems with a high environmental value and the habitat for numerous species of flora and fauna. Emerging pollutants (EPs) are ubiquitous anthropogenic compounds of environmental concern that can be found at different concentration levels in matrices such as sediment, water and aquatic biota. In addition, EPs can be bioaccumulated and biomagnified, inducing adverse effects on biota, and posing a risk to humans when contaminated biota is consumed. Unlike abiotic matrices, the occurrence of EPs in aquatic biota has not been widely studied. This is probably because their complexity, due to the presence of lipids, proteins and other organic compounds, makes the extraction and analysis of EPs difficult. This review gathers the most relevant analytical methods published between 2014 and 2019, comparing them and evaluating their strengths and weaknesses. It is intended to provide a better understanding of the development of new and improved methods, and to be a reference for researchers who are looking for the best methodology for their studies.     

Advances in the environmental analysis of polychlorinated naphthalenes and toxaphene

Recent advances in the analysis of the chlorinated environmental pollutants polychlorinated naphthalenes (PCNs) and toxaphene are highlighted in this review. Method improvements have been realized for PCNs over the past decade in isomer-specific quantification, peak resolution, and the availability of mass-labeled standards. Toxaphene method advancements include the application of new capillary gas chromatographic (GC) stationary phases, mass spectrometry (MS), especially ion trap MS, and the availability of Standard Reference Materials that are value-assigned for total toxaphene and selected congener concentrations. An area of promise for the separation of complex mixtures such as PCNs and toxaphene is the development of multidimensional GC techniques. The need for continued advancements and efficiencies in the analysis of contaminants such as PCNs and toxaphene remains as monitoring requirements for these compound classes are established under international agreements.     

Processes driving the degradation of polybrominated diphenyl ethers in terrestrial environment

Polybrominated diphenyl ethers (PBDEs), a class of brominated flame retardants, have gained the attention of many researchers due to their persistence in various environmental matrices. Their usage in numerous consumer products has lent credence to their ability to retard flammable gas formation and brought attention to their ubiquitous occurrence in the environment. PBDEs have been described as endocrine-disrupting chemicals because of their interference with the endocrine system in aquatic and terrestrial animals. In spite of the progress in research over the decades on PBDEs, a full understanding of the environmental behavior and fate of this contaminant is still elusive. Therefore, terrestrial contamination of PBDEs has been evaluated in conjunction with their levels of toxicity, transformation, and transport in various environmental compartments. This review provides a wider perspective of the behavior of PBDEs in the terrestrial environment. Through examining the numerous studies on the environmental contamination of PBDEs, a number of mounting concerns and data gaps have been identified. Numerous methodologies have been discussed including adsorption, catalytic, photocatalytic, electrocatalytic, photo-electrocatalytic, aerobic, and anaerobic degradation. The comparative PBDE degradation analysis suggests that the oxidative degradation pathway is the most appropriate way of wastewater treatment while the role of other soil ingredients on subsurface treatments is still under investigation.     

Passive sampling as a tool for obtaining reliable analytical information in environmental quality monitoring

Passive sampling technology has been developing very quickly for the past 20 years, and is widely used for monitoring pollutants in different environments, for example air, water, and soil. It has many significant advantages, including simplicity, low cost, no need for expensive and complicated equipment, no power requirements, unattended operation, and the ability to produce accurate results. The present generation of passive samplers enables detection and analysis of bioavailable pollutants at low and very low concentrations and investigation of the environmental concentration of organic and inorganic pollutants not only on the local scale but also on continental and global scales. This review describes the current application of passive sampling techniques in environmental analysis and monitoring, under both equilibrium and non-equilibrium conditions.     

Microanalysis of Volatile Organic Compounds (VOCs) in Water Samples – Methods and Instruments

Volatile organic compounds (VOCs), due to their toxicity and persistence in the environment, are particularly important pollutants. Some of these compounds are mutagens, teratogens or carcinogens, while others are responsible for the degradation of organoleptic parameters such as taste and odour of water. This review focuses on a number of key procedural steps in the analysis of volatile organic compounds (VOCs) in water samples. A wide spectrum of techniques for the isolation and preconcentration of the aforementioned pollutants for trace organic analysis by gas chromatography are presented and discussed. The advantages and disadvantages of these techniques are discussed and novel developments are also taken into consideration.     

Application of Compound-Specific Isotope Analysis in Environmental Forensic and Strategic Management Avenue for Pesticide Residues

Unintended pesticide pollution in soil, crops, and adjacent environments has caused several issues for both pesticide users and consumers. For users, pesticides utilized should provide higher yield and lower persistence while considering both the environment and agricultural products. Most people are concerned that agricultural products expose humans to pesticides accumulating in vegetation. Thus, many countries have guidelines for assessing and managing pesticide pollution, for farming in diverse environments, as all life forms in soil are untargeted to these pesticides. The stable isotope approach has been a useful technique to find the source of organic matter in studies relating to aquatic ecology and environmental sciences since the 1980s. In this study, we discuss commonly used analytical methods using liquid and gas chromatography coupled with isotopic ratio mass spectrometry, as well as the advanced compound-specific isotope analysis (CSIA). CSIA applications are discussed for tracing organic pollutants and understanding chemical reactions (mechanisms) in natural environments. It shows great applicability for the issues on unintended pesticide pollution in several environments with the progress history of isotope application in agricultural and environmental studies. We also suggest future study directions based on the forensic applications of stable isotope analysis to trace pesticides in the environment and crops.