Simple determination of dimethylsulfide (DMS) and dimethylsulfoniopropionate (DMSP) using solid-phase microextraction and gas chromatography-mass spectrometry

Solid-phase microextraction (SPME) is a simple, sensitive and less destructive method for the determination of dimethylsulfide (DMS) in seawater. Combined with detection by gas chromatography-mass spectrometry (GC-MS), the method had sufficient sensitivity (minimum detectable concentration of DMS was 0.05 nM), and practical levels of reproducibility (relative standard deviation ≤7%) and linearity (r ² > 0.995) over a wide concentration range (0.5 to 910 nM). The protocol developed was applied to a Sagami Bay water sample to determine concentrations of DMS and DMSP, and in situ DMSP-lyase activity.     

分散液液微萃取-气相色谱法测定环境水样中间甲苯酚

针对环境中痕量的间甲苯酚用一般仪器很难直接分析测定的问题,提出将分散液液微萃取技术与气相色谱联用测定环境水样中间甲苯酚的新方法.实验考察了影响分散液液微萃取效率的因素,包括萃取剂种类和用量、分散剂种类和用量、萃取时间、离心时间和盐度等,确定了最佳萃取条件为:200μL氯苯(萃取剂)和2.5mL丙酮(分散剂)混匀后,快速注入水样,室温静置8min,以3000r/min离心8rain,吸取1μL沉积相进行气相色谱分析.实验结果为:在最佳的萃取条件下,间甲苯酚的富集倍数为98.7倍,方法的线性范围为0.05～50mg/L,检出限为4.2μg/L(S/N=3),相对标准偏差为5.64％.将方法用于实际水样的测定,水样的加标回收率在86％～～122％,相对标准偏差(RSD)为3.3％～7.3％(n=3),实验表明该方法操作简便快速、成本低、环境友好,可用于实际水样的测定.     

Application of the Response Surface Method for Optimization of Headspace Liquid Phase Microextraction of Trihalomethanes in Drinking Water

An optimized analysis method based on headspace liquid phase microextraction (HS‐LPME) and gas chromatography coupled with mass spectrometry was proposed for the determination of trihalomethanes (THMs) in drinking water. The response surface method (RSM) was used to optimize the extraction of THMs for analysis by HS‐LPME. The temperature, extraction time and NaCl concentration were found to be important extraction parameters. The coefficient of determination (R²) for the model was 94.97%. A high probability value (P < 0.0001) for the regression indicated that the model had a high level of significance. The optimum conditions were seen to be: temperature 42.0°C, NaCl concentration 0.30 g/mL, and extraction time 28 min. The response variable was the summation of the THMs chromatography peak areas and the reproducibility of this was investigated in five replicate experiments under the optimized conditions. The relative standard deviations (RSD%) of the THMs ranged from 8.0–11.6%. The limits of detection (LODs), based on a signal‐to‐noise ratio (S/N) of three ranged from 0.42–0.78 μg/L, and were lower than the maximum limits for THMs in drinking water established by the WHO.     

Surfactant Enhance DLLME/FO‐LADS: Assay of Malachite Green Level in Aquatic Environment of Trout Fish

Malachite green (MG), a traditional agent used in aquaculture although is not approved; its low cost and high efficacy make illicit use likely. We developed a small‐scale, simple, and sensitive dispersive liquid–liquid microextraction procedure for the assay of trace amounts of MG in aquatic environment of Trout fish. Fiber optic‐linear array detection spectrophotometry with charge‐coupled device detector benefiting from a microcell was used for this purpose. The method is based on enhancement effect of an anionic surfactant on the extraction of MG in to very fine multidroplets of microextraction solvent which made assisted by disperser solvent. Under the optimum conditions, the enrichment factor 77.5 was obtained from a 5‐mL water sample. The calibration graph was linear up to 5 × 10^?7 mol L^?1 with detection limit of 1 × 10^?8 mol L^?1. The relative standard deviation for seven replicate measurements of 4 × 10^?7 and 5 × 10^?8 mol L^?1 of MG were 3.3 and 4.5%, respectively.     

顶空进样-固相微萃取测定饮用水源水中吡啶

用75μm CarboxenTM-Polydimethylsiloxane(CAR-PDMS)固相微萃取头顶空萃取15 mL水样中的吡啶,萃取物用气相色谱-质谱法进行分离和检测,采用内标法和质谱的选择离子监测模式进行定量分析。优化了顶空进样-固相微萃取条件,获得较佳的萃取温度(58.0℃)和萃取时间(40 min)。在优化的条件下,方法检出限为1.5μg/L,标准曲线的线性相关系数为0.9994,线性范围为2.5～50.0μg/L;饮用水源水和纯水加标平均回收率为75.6%～81.3%,相对标准偏差(RSD,n=6)为9.60%～12.21%。使用顶空萃取方式可避免样品基体的复杂性,有利于保护萃取头涂层,同时无需使用有机萃取溶剂;使用质谱检测器可减小假阳性带来的影响。顶空进样-固相微萃取操作简单、环保、灵敏度高,适合用于饮用水源水中吡啶的监测分析。     

铁丝原位自转化-固相微萃取新涂层应用于萃取环境水样中多环芳烃的性能研究

多环芳烃(PAHs)是一类具有致癌作用且难以降解的持久性有机污染物,广泛存在于环境中。环境中痕量PAHs的直接分析往往因检测手段的检出限达不到要求而存在困难,需要结合分离富集手段。常规的样品前处理技术如索氏提取、液液萃取等存在耗时长、使用大量有机溶剂等问题。因此为了提高效率、避免对自然环境的二次污染,有必要开发一种简便、环境友好的新型样品前处理技术。固相微萃取(SPME)是一种集采样、富集、进样于一体的无溶剂前处理技术,与气相色谱-质谱(GC-MS)等技术联用可实现复杂基质中痕量有机物的快速富集和检测。目前SPME技术的研究热点主要集中在改善涂层的萃取性能以及提高其机械强度方面。本文采用铁丝(IW)作为载体,同时又提供了铁离子来源,以原位自转化的方式在具有良好机械稳定性的铁丝上生长出一层多孔结构的金属有机骨架化合物多孔膜[MIL-53(Fe)];将其作为固相微萃取涂层[IW@MIL-53(Fe)],以7种难挥发的稠环PAHs作为目标分析物,以浸入式模式进行萃取,并结合GC-MS作为检测手段验证其萃取性能。结果表明:新涂层的萃取性能是商用100μm PDMS涂层的1～2倍,且涂层可稳定使用120次以上。该方法的检出限为0.03～2.25ng/L,线性范围为250～10000ng/L,相关系数为0.9903～0.9991。将建立的方法应用于自然水体中PAHs的检测,加标回收率为80.1%～108.5%。本研究不仅为高性能SPME涂层简单、快速制备提供了新思路,而且所建立的方法有望应用于水体中痕量有机污染物的准确和高灵敏检测。     

海产腹足类有机锡化合物的检测方法

三丁基锡(TBT)等有机锡化合物因其毒性及结构上的特点被广泛应用于船舶、网箱渔排等的防污涂料中.它的主要作用是在水体中持久地释放出可以有效杀死海洋污损生物的毒性物质,从而达到防护船舶、渔排等体表的目的[1],然而进入海洋环境的有机锡化合物在防污的同时也会影响到许多非靶生物,并对海洋生态系统的结构与功能产生严重的危害,被认为是迄今为止人为引入海洋环境毒性最大的物质之一[2～4].因此,检测海洋生物体内的有机锡含量成为对有机锡污染生态效应调查与研究不可缺少的手段[5～7].     

我国东南沿海3港口有机锡污染的调查

利用顶空固相微萃取与气相色谱表面发射火焰光度检测法于2001年11月至2002年8月对我国东南沿海厦门、汕头和惠阳3个大型港口21个站位的水样、底泥和生物样的有机锡污染现状进行调查.结果表明,绝大多数样品的一丁基锡(MBT)含量最高,三丁基锡(TBT)次之,二丁基锡(DBT)大多低于检测限.水样的TBT含量实测值从低于检测限至9.8ng/dm3,泥样的为0.3~174.7ng/g(干重),生物样的为2.1~23.0ng/g(湿重).水样TBT含量均值以惠阳港的为最高,泥样和生物样的均以厦门港的最高.影响有机锡含量及其空间分布的主要因素有港口船舶吞吐量、水文状况、季节和与大型码头的距离.关联的海产腹足类性畸变调查结果发现,我国沿海有机锡污染比较普遍和严重,已对生态系统产生实质性的负面生态效应.     

新型有机-无机杂化涂层-气相色谱/质谱联用测定正构烷烃性能研究

水体中正构烷烃的含量反映了研究区域有机物污染水平.痕量正构烷烃的测定常常需要结合分离富集方法才能保证灵敏度和选择性,液液萃取等常规分离富集方法存在耗时长、有机溶剂使用量大等缺点,而新型固相微萃取(SPME)分离富集技术相比而言具有高效简便、富集效率高的特点.本文采用溶胶-凝胶法自制稳定性和耐基质性能更优的有机-无机杂化SPME涂层,结合气相色谱-质谱(GC - MS)检测技术,对水样中26种正构烷烃进行同时测定.在优化的SPME - GC/MS条件下,采用浸入式萃取方式,萃取温度为25℃,萃取时间为30 min,26种正构烷烃的分析信号与浓度之间有良好的线性关系(线性相关系数为0.9935 ～0.9999),方法检出限为0.011 ～0.085μg/L(k=3),相对标准偏差(RSD,n=5)为3.9％ ～10.0％.新型有机-无机杂化涂层与传统的分离富集技术相比,减少了有机溶剂的使用,提高了工作效率;与商用PDMS涂层相比,增加了正构烷烃同时检测的种类,提高了灵敏度,检出限低2～10倍.自制的有机-无机杂化SPME涂层体现出优异的分析性能和应用潜力.     

Application of Dispersive Liquid–Liquid Microextraction Based on Solidification of Floating Organic Droplet Multi‐residue Method for the Simultaneous Determination of Polychlorinated Biphenyls,Organochlorine, and Pyrethroid Pesticides in Aqueous Sample

Dispersive liquid–liquid microextraction based on solidification of floating organic droplet (DLLME‐SFO) technique was successfully applied for simultaneous assay of eight polychlorinated biphenyls, two organochlorine, and four pyrethroid pesticides multi‐residue in aqueous samples by using GC‐electron capture detection. The effects of various parameters such as kind of extractant and dispersant and volume of them, extraction time, effect of salt addition, and pH were optimized. As a result, 5.0 µL 1‐dodecanol was chosen as extraction solvent, 600 µL methanol were used as dispersive solvent without salt addition, pH was adjusted to 7. Under the optimized conditions, the limits of detection (LOD) were ranged from 1.4 to 8.3 ng L^?1. Satisfactory linear range was observed from 5.0 to 2000 ng L^?1 with correlation coefficient better than 0.9909. Good precisions were also acquired with RSD better than 13.6% for all target analytes. The enrichment factors of the method were ranged from 786 to 1427. The method can be successfully applied to simultaneous separation and determination of three class residues in real water samples and good recoveries were obtained ranging from 76 to 130, 73 to 129, and 78 to 130% for tap water, lake water, and industrial waste water, respectively.