分子印迹固-液微萃取联用技术检测复杂样品痕量三嗪类除草剂

本文结合分子印迹固相微萃取与中空纤维液相微萃取技术的优点,发展了分子印迹固-液微萃取(MIP-SLME)样品前处理联用技术.设计联用萃取技术装置,以自制的特丁津MIP-SPME涂层研究MIP-SLME技术的萃取条件和萃取性能,建立特丁津MIP-SLME/HPLC联用分析方法,实现复杂生物、环境样品中痕量三嗪类除草剂多残留同时分析.     

微波辅助萃取/样品前处理联用技术的研究进展

微波辅助萃取是近年来新发展的一种样品前处理技术,随着微波辅助萃取的发展和成熟,它与其它样品前处理技术的联用得到了迅速发展。与传统前处理方法相比,这些联用方法具有快速、高效、操作简便、节省溶剂、选择性好、应用范围广的特点。该文综述了微波辅助萃取及其与其它样品前处理技术联用的特点及适用性,并对近年来微波辅助萃取与其它前处理方法联用的发展概况及在分析领域中的应用情况进行了详细总结。     

化学衍生与萃取联用技术在生物样品预处理中的应用

近年来各种萃取技术与化学衍生联用的模式作为一种新型样品处理技术广泛应用于生物样品预处理.这种联用技术不仅能有效去除样品基质,还能有效改善极性大、挥发性强、热稳定性差的目标分析物的回收率,提高方法的选择性和灵敏度.研究者根据待分析物及衍生试剂性质选取不同的联用模式.本文评述了萃取技术与化学衍生联用模式以及其在生物样品预处理中的应用.     

萃取-表面增强拉曼光谱联用技术及其在有害物质检测领域的应用

表面增强拉曼光谱(SERS)技术以其高灵敏度和分子特征指纹光谱在众多领域获得广泛应用,然而对于实际复杂样品中的目标分析物,样品基质会极大地干扰目标分析物SERS信号的准确获取,从而限制SERS在实际样品分析中的应用.萃取-表面增强拉曼光谱(Ex-SERS)联用技术为解决这一现实难题提供了可能性,国内外课题组结合萃取和SERS的各自优势,构建了基于固相萃取、固相微萃取、磁分散固相微萃取、薄层微萃取、液液分散微萃取、擦拭萃取等多种Ex-SERS联用技术,并以此发展了面向多种有害物质的Ex-SERS联用方法,可实现复杂基质中目标分析物的快速原位分离和SERS检测,进一步拓展SERS在实际样品分析中的应用.     

样品前处理-色谱分析在线联用技术的研究进展

样品前处理是色谱分析中耗时最多、最容易引起误差的关键环节,因此有关样品前处理技术与色谱分析的在线联用的研究已成为分析化学的前沿课题。本文综述了近年来各种样品前处理技术与色谱分析在线联用的研究进展,包括固相萃取、固相微萃取与液相微萃取、膜辅助萃取、场作用辅助萃取、气相萃取、热解吸以及微芯片分离技术。     

微波辅助萃取及其联用技术在有机污染物分析中的应用

微波萃取已经发展成为一种常用的快速、高效、污染小的样品的前处理技术。结合有机污染物的气相色谱测定方法,对近年微波萃取技术的研究进展进行了总结,并指出微波与固相微萃取、微固相萃取、顶空萃取、膜分离方法、蒸汽蒸馏萃取、微波催化和消解等方法的联用技术将是微波萃取的重要发展方向。     

基于色谱-质谱联用的脂质分析样品前处理技术研究进展

脂质作为细胞膜和亚细胞膜的主要结构成分,在能量来源、细胞信号传导等多种生物学过程中发挥着重要作用。近年来,脂质分析受到越来越多的关注,其中色谱-质谱联用技术在脂质分析中占据主导地位。由于样品基质复杂,样品前处理有富集痕量物质和减少基质干扰的作用,成为脂质分析中的一个关键步骤。该文综述了近年来基于色谱-质谱联用技术的脂质分析中样品前处理技术的研究进展和应用,对各种样品前处理技术进行了阐述和总结。基于液相的萃取方法有液-液萃取和单一有机溶剂萃取。基于固相的萃取方法包括固相萃取和固相微萃取。场辅助萃取方法包括超临界流体萃取、加压流体萃取、微波辅助萃取和超声辅助萃取。此外,还介绍了在线联用样品前处理方法和用于活体分析的样品前处理方法。最后,对基于色谱-质谱联用的脂质分析样品前处理技术存在的问题及发展趋势进行了探讨。样品前处理技术的发展将提高脂质分析的灵敏度、选择性和分析速度。     

基于色谱-质谱联用的脂质分析样品前处理技术研究进展（英文）

脂质作为细胞膜和亚细胞膜的主要结构成分,在能量来源、细胞信号传导等多种生物学过程中发挥着重要作用。近年来,脂质分析受到越来越多的关注,其中色谱-质谱联用技术在脂质分析中占据主导地位。由于样品基质复杂,样品前处理有富集痕量物质和减少基质干扰的作用,成为脂质分析中的一个关键步骤。该文综述了近年来基于色谱-质谱联用技术的脂质分析中样品前处理技术的研究进展和应用,对各种样品前处理技术进行了阐述和总结。基于液相的萃取方法有液-液萃取和单一有机溶剂萃取。基于固相的萃取方法包括固相萃取和固相微萃取。场辅助萃取方法包括超临界流体萃取、加压流体萃取、微波辅助萃取和超声辅助萃取。此外,还介绍了在线联用样品前处理方法和用于活体分析的样品前处理方法。最后,对基于色谱-质谱联用的脂质分析样品前处理技术存在的问题及发展趋势进行了探讨。样品前处理技术的发展将提高脂质分析的灵敏度、选择性和分析速度。     

浊点萃取技术及其在有机化合物分离分析中的应用

浊点萃取是基于表面活性剂水溶液中相分离现象的萃取浓缩技术，已成功实现了与HPLC、CE和FI等分析仪器的联用，用于各种金属离子、生物分子和不同极性有机化合物浓缩分离处理，是一种替代有机溶剂萃取的良好形式。本文简要介绍了浊点萃取技术的原理和流程，详细总结了在有机化合物分离分析中的应用以及与不同分析仪器联用时遇到的问题和处理方法。     

液相微萃取研究与应用

液相微萃取是近年来新兴的一种微型化样品前处理技术。该技术集萃取、净化、浓缩于一体,具有溶剂耗量少、成本低廉、操作便捷、精确和灵敏度高的特点。本文全面深入地综述了液相微萃取的各种工作模式及其原理和特点,阐述了相关的联用分析技术和方法的适用性,归纳和分析了影响萃取的主要影响因素及优化的方法,突出了上述几方面中具有发展潜力的新进展,包括各种动态萃取模式与装置、 与其它技术联用的新策略、离子液体作为萃取溶剂等,详细总结了近年来液相微萃取技术在环境、药物和食品等分析领域中的应用情况。     

固相微萃取-液相色谱联用技术研究进展*

本文较系统地介绍了固相微萃取-液相色谱联用技术的原理、特点、发展现状及其发展趋势,并对该技术在样品前处理尤其是环境样品前处理中的应用作了较详细的综述     

Monolithic silica column for in-tube solid-phase microextraction coupled to high-performance liquid chromatography

In-tube solid-phase microextraction (SPME) has successfully been coupled to capillary LC, and further an automated in-tube SPME system has been developed using a commercially available HPLC auto-sampler. However, an open tubular capillary column with a thick film of polymer (stationary phase) is unfavorable because the ratio of the surface area of coating layer contacted with sample solution to the volume of the capillary column is insufficient for mass transfer. A highly efficient SPME column is. therefore, required. We introduced a C18-bonded monolithic capillary column that was used for in-tube SPME. The column consisted of continuous porous silica having a double-pore structure. Both the through-pore and the meso-pore were optimized for in-tube SPME, and the optimized capillary column was connected to an HPLC injection valve for characterization. The results demonstrated that the pre-concentration efficiency is excellent compared with the conventional in-tube SPME. The novel method for both introduction and concentration of the samples was effective. satisfactory and suitable for use in the SPME medium.     

辣椒油化学成分的气相色谱-质谱分析

采用溶液进样和顶空固相微萃取进样，GC－MS分离鉴定，总离子流色谱的峰面积归一化法定量分析了辣椒油的化学成分；在溶液进样方法中，鉴定的主要成分相对含量依次为辣椒碱（37.0％）、亚麻酸乙酯（26.3%)、棕榈酸（10.9%)、二氢辣椒碱（10.1%)、邻苯二甲酸二乙基己基酯（1.2%)和硬脂酸（1.1%)等；在顶空固相微萃取方法中，鉴定的成分主要为易挥发的头香成分，依次为顺－2，4α,5,6,9,9α-六氢-3,5,5，9－四甲基－1H－苯并环庚烯（22.9%)、2，4α，5，6，7，8，9，9α－八氢－3，5，5－三乙基－1H苯并环庚烯（9.2%)、正十五烷（6.7%)、艾蒿脑（5.9%)、正戊酸己酯（5.2%)、正十六烷（3.3%)、麝香内酯（3.3%)、正十七烷（2.4%)及5，6，7，7α－四氢－4，4，7α－三甲基－2（4H)-苯并呋喃酮（2.2%)等。     

Determination of microcystins in water using integrated solid-phase microextraction with microbore high-performance liquid chromatography-electrospray quadruple time-of-flight mass spectrometry

The development of a technique combining solid-phase microextraction (SPME) with microbore high-performance liquid chromatography (micro-HPLC)-tandem quadrupole time-of-flight (QTOF) mass spectrometry (MS) for determination of dissolved microcystins in water is reported. Several important parameters affecting the efficiency of SPME extraction of microcystins are investigated. A microbore C18 column HPLC coupled with tandem QTOF-MS with information-dependent acquisition (IDA) is developed to effectively analyze microcystins in microliter volumes of SPME extracts. The micro-HPLC-QTOF-MS with IDA technique provides comprehensive information, including a survey chromatogram (total ion chromatogram), full scan mass spectrum, and product ion scan mass spectra at different collision energies for individual analytes, which allows for both identification and quantitation in the same run. Linear calibration curves of microcystin standard [microcystin (MC)-arginine (R)R] 1-100 microg/L and of microcystin standard [MC-leucine (L)R] 1-250 microg/L are obtained with a correlation coefficient of 0.996. The combination of SPME with HPLC-QTOF-MS and IDA offers limits of detection of 0.6 pg for MC-RR and 1.6 pg for MC-LR. Analysis of spiked lake-water samples shows a recovery of > 86% for MC-RR and > 70% for MC-LR. This technique requires small sample volumes, minimizes the use of organic solvents, and provides sensitive and information-rich analysis of unknown samples.     

新型的样品前处理技术-固相微萃取

文中对固相微萃取，作为一种试样预处理的新技术，在1990-2004年的进展作了评述，介绍了固相微萃取技术的装置、试验方法、原理、涂层、影响因素、应用及发展趋势，引用文献39篇。     

Coupling solid-phase microextraction to liquid chromatography. A review

Solid-phase microextraction (SPME) is a technique for extraction of organic compounds from gaseous, aqueous, and solid matrices. SPME is rapid and simple, ideal for automation and for in situ measurements, and no harmful solvents are needed. The principle of SPME involves equilibration of the analytes between the sample matrix and an organic polymeric phase coated on a fused-silica fiber. SPME is traditionally combined with analysis by gas chromatography (GC) and this combination has proved sensitive, accurate, and precise for quantitative analysis of different classes of volatile compound. More recently SPME has been coupled with liquid chromatography to widen its range of application to non-volatile and thermally unstable compounds also. This article reviews the status of SPME coupled with liquid chromatography. It focuses on different applications of the technique, e.g. environmental samples, biological fluids, and food samples, to show that SPME-HPLC has great potential in the analysis of a wide range of compounds in different matrices.     

Use of Solid Phase Microextraction (SPME) with Ion Mobility Spectrometry∗

Abstract

We report the use of solid phase microextraction (SPME) combined with ion mobility spectrometry (IMS) for sampling, screening and identification of organic compounds that are readily detected by IMS. This is a new SPME application. SPME has emerged recently as an excellent sample preparation technique for gas chromatography (GC) and high performance liquid chromatography (HPLC). We have found that SPME can be used very conveniently with IMS. An example of SPME-IMS is described using SPME headspace sampling at room temperature with 0.1 mL vials containing 1.0 microgram or less of either cocaine freebase or cocaine hydrochloride. This is followed by analysis using IMS. A hole, drilled in the IMS sample ticket holder, serves as the SPME-IMS interface.

     

Determination of polycyclic aromatic hydrocarbons in water by solid-phase microextraction and liquid chromatography.

This study describes the determination of polycyclic aromatic hydrocarbons (PAHs) in water using high-performance liquid chromatography (HPLC) coupled with fluorescence detection (FLD). Because individual PAHs are generally present in water only at trace levels, a sensitive and accurate determination technique is essential. The separation and detection of five PAHs were run completely within 25 min by the HPLC/FLD system with an analytical C18 column, a fluorescence detection, and acetonitrile-water gradient elution. Calibration graphs were linear with very good correlation coefficients (r > 0.9998), and the detection limits were in the range of 2-6 ng/l for five PAHs. Solid phase microextraction (SPME) was performed for sample pretreatment prior to HPLC-FLD determination, and the governing parameters were investigated. Compared to conventional methods, SPME has high recovery, saves considerable time, and reduces solvents waste. The extraction efficiencies of five PAHs were above 88% and the extraction times were 35 min in one pretreatment procedure. One particular discovery is that 1.5 M sodium monochloroactate (ClCH2COONa) can improve the extraction yield of PAH compounds more than other inorganic salts. The SPME-HPLC-FLD technique provides a relatively simple, convenient, practical procedure, which was here successfully applied to determine five PAHs in water from authentic water samples.     

Applications of solid-phase microextraction in food analysis

Food analysis is important for the evaluation of the nutritional value and quality of fresh and processed products, and for monitoring food additives and other toxic contaminants. Sample preparation, such as extraction, concentration and isolation of analytes, greatly influences the reliable and accurate analysis of food. Solid-phase microextraction (SPME) is a new sample preparation technique using a fused-silica fiber that is coated on the outside with an appropriate stationary phase. Analyte in the sample is directly extracted to the fiber coating. The SPME technique can be used routinely in combination with gas chromatography (GC), GC–mass spectrometry (GC–MS), high-performance liquid chromatography (HPLC) or LC–MS. Furthermore, another SPME technique known as in-tube SPME has also been developed for combination with LC or LC–MS using an open tubular fused-silica capillary column as an SPME device instead of SPME fiber. These methods using SPME techniques save preparation time, solvent purchase and disposal costs, and can improve the detection limits. This review summarizes the SPME techniques for coupling with various analytical instruments and the applications of these techniques to food analysis.     

Selective capillary coating materials for in-tube solid-phase microextraction coupled to liquid chromatography to determine drugs and biomarkers in biological samples: A review

In-tube solid-phase microextraction (in-tube SPME) coupled with high performance liquid chromatography (HPLC) or liquid chromatography coupled to mass spectrometry (LC-MS) successfully determines drugs or biomarkers in biological samples by direct sample injection or by simple sample treatment. This technique uses a capillary column as extraction device. Several capillaries (wall-coated open tubular, sorbent-packed, porous monolithic rods, or fiber-packed) with unique phases have been developed and evaluated, aiming to improve the efficiency and selectivity of the in-tube SPME-LC technique. This review describes new developments and applications occurred in recent years, and discusses future trends with emphasis on new extraction devices and current technology used for the synthesis of selective sorbents for bioanalysis, such as (i) polypyrrole, (ii) restricted-access materials, (iii) immunosorbents, (iv) molecular imprinting polymers, (v) monolithic polymers, and (vi) bi-functional materials.