顶空固相微萃取-气相色谱质谱联用技术分析甜樱桃芳香成分

采用固相微萃取技术(SPME)提取‘红灯’甜樱桃果实芳香成分,运用气相色谱-质谱-计算机联用技术进行芳香成分分析,共检测出41种芳香成分,占总峰面积的98.81%,质量分数较高的芳香成分依次为反-1,4-己二烯、己醛、2-己烯醛、(E)-2-乙烯-1-醇、1-己醇、乙醇(、E,E)-2,4-己二烯醛、己酸乙酯、苯甲醛等。     

固相微萃取-气相色谱-质谱分析牡丹花的挥发性成分

用固相微萃取装置（SPME）顶空提取牡丹花的挥发性成分,采用气相色谱-质谱（GC-MS）联用技术定性分析不同品种牡丹花的挥发性成分,归一法计算其相对百分含量,同时对SPME与水气蒸馏提取效果进行了比较。10个品种牡丹花共检出34种成分,其中多数是烷烃。不同品种牡丹花的成分与相对百分含量不同,少量的醇、酯、烯等成为其特有成分。     

花生微波烘烤香气成分分析方法的建立与应用

建立了烤制花生香气成分分析的顶空固相微萃取/气相色谱-质谱(HS SPME/GC-MS)分析方法。优化的实验条件:HP-5色谱柱,萃取平衡温度80℃,萃取时间40 min,解析时间5 min。采用该方法对四粒红、大白沙、鲁花3种花生进行微波炉焙烤后产生的挥发性香气成分进行分析,共鉴定出29种成分,其中主要包括杂环类化合物9种,醛类化合物7种,醇类化合物3种,烯类化合物3种,酚类化合物2种,酯类化合物3种,其他化合物2种。根据上述风味物质对花生香味的贡献大小,选择7种主要特征香气成分2,5-二甲基吡嗪、2-乙基-3,5(6)-二甲基吡嗪、2-乙基-6-甲基吡嗪、2-戊基呋喃、2,3-二氢苯并呋喃、苯甲醛和苯乙醛进行定量分析,其标准曲线相关系数均超过0.997,标准物质的加标回收率为85%~101%,RSD不大于6.9%,检出限为0.63~13.4μg/L。比较了不同花生品种的香气差异,并通过分析不良风味成分苯乙醛的含量,发现以大白沙花生的特征香气浓度最高,苯乙醛含量最低,更适宜利用微波烘焙技术生产咸干花生食品。     

超声雾化顶空单滴微萃取-气相色谱-质谱法测定果汁中的芳香成分

本文建立了超声雾化顶空单滴微萃取-气相色谱-质谱(GC-MS)联用测定果汁中的β-月桂烯、D-柠檬烯和异戊酸叶醇酯含量的方法。考察了萃取溶剂、萃取时间、富集时间等影响芳香成分萃取效率的因素。在最优的实验条件下,对三种果汁中的芳香成分进行了分析,测得三种果汁中β-月桂烯、D-柠檬烯和异戊酸叶醇酯的含量分别为12.0~488.6μg·mL~(-1)、542.8~1.237×10~4μg·mL~(-1)和0.0470~498.5μg·mL~(-1)。方法的回收率范围为78.5%~110.4%,相对标准偏差为1.3%~4.4%。     

葫芦脲用作固相微萃取涂层新材料

本文对葫芦脲(CB)作为一种新型固相微萃取(SPME)涂层材料进行了研究并用于中药白豆蔻的气相色谱分析测定.本文采用的CB SPME涂层制备方法简便、快速,并具有良好的热稳定性和重复性.CB[6]SPME萃取得到的主要成分与水蒸气蒸馏（SD）法基本一致,并且CB[6]SPME对色谱后流出的目标成分的相对峰面积比明显高于SD法和商品SPME萃取材料PDMS/CAR和PDMS/DVB,这可能是由于葫芦脲的特殊分子结构及其与组分分子间选择性作用所致.葫芦脲作为一种新型SPME涂层材料具有很大的研究潜力和应用前景.     

顶空固相微萃取-气质联用技术分析5种荷花的挥发性成分

采用顶空固相微萃取-气相色谱质谱联用(HS-SPME-GC-MS)技术分析测定了5个品种荷花中的挥发性成分.考察了不同萃取头和萃取温度对荷花挥发性成分萃取的影响,选用65μm PDMS/DVB SPME萃取头和25℃室温萃取荷花中的挥发性成分得到较好的萃取效果.应用峰面积归一化法测定各挥发性成分的相对含量,5个品种共鉴...     

固相微萃取-气相色谱-质谱法分析火龙果果肉中挥发性成分

火龙果不仅具有保健功能,还具有降血压、降血脂、润肺、解毒、养颜等药用功效,被称为21世纪保健食品和果品珍品。目前关于火龙果的研究主要集中在茎、花、种籽、果实色素等方面[1-6],而对其果肉中挥发性成分的研究未见报道,但果肉中挥发性成分对于水果的保鲜具有重要的作用[7]。近年来,固相微萃取(SPME)技术在水果挥发性成分分析方面已得到了一定的应用[8-9],SPME具     

水果风味物质的SPME-SPE-GC-MS 分析体系研究

水果果汁中的芳香性风味物质尽管含量很低,却是区别各种果汁最重要的1个特征参数,是判断果汁饮料的指纹性指标.近年来随着质谱技术的发展,因其快速准确的结构鉴定等优点而逐渐发展成为水果等天然产物风味物质结构鉴定的重要技术手段之一.水果中的风味物质主要为游离态挥发性香气成分、半挥发性有机物、以及以键合态存在的有机物[1,2],系统的检测体系研究报道不多,本文以芒果为例,结合SPME、固相萃取(SPE)以及酶解技术开发系统分析风味物质的前处理体系,优化GC-MS条件,快速、全面的分析风味物质,为我国西部地区丰富天然水果资源的进一步开发利用起探索性指导作用.     

固相微萃取技术的进展及其在食品分析中应用的现状

固相微萃取(SPME)是当今色谱分析中使用极为广泛的样品前处理方法,这一技术将萃取、浓缩、解吸、进样等功能集于一体,灵敏度高且操作简便。该文简要介绍了近年来SPME涂层、装置及相应技术的演变,综述了SPME在国内外食品分析中的应用现状,并讨论了国内部分研究者在采用这一技术进行定量分析时存在的一些共性问题。     

SPME/GC-MS鉴别沉香真伪方法研究

采用固相微萃取/气相色谱-质谱联用(SPME/GC-MS)对沉香的成分进行研究,建立以特征成分鉴别沉香真伪的方法。通过SPME富集沉香的气味成分,GC-MS测定其化学组成,确定天然沉香的6种特征成分,并通过面积归一化确定特征成分在气味成分中的相对含量;通过沉香样品中气味成分的种类及其相对含量与天然沉香特征成分对比,判断沉香的真伪。SPME/GC-MS法具有样品用量小、操作简便快速、检测灵敏度高、特征性强、结果准确可靠的特点,适用于沉香气味成分的分析及真伪鉴别,且不破坏沉香收藏品的整体结构,已成功用于沉香药材及其工艺品等的真伪鉴别。     

Hydroxyundecanethiol-Modified Steel Fibers for the Selective Solid-Phase Microextraction of Polycyclic Aromatic Hydrocarbons from River and Wastewater

A novel organic–inorganic composite-coated fiber was developed for selective solid-phase microextraction (SPME) by direct electrodeposition of zinc oxide microparticles on a pretreated stainless steel wire followed by self-assembly of hydroxyundecanethiol with zinc–sulfur bonds. The performance of the hydroxyundecyl-modified zinc oxide-coated steel fiber was then assessed for SPME of polar aromatic compounds coupled to high-performance liquid chromatography with ultraviolet detection. Excellent extraction and selectivity were obtained for polycyclic aromatic hydrocarbons. The extraction and desorption times, temperature, stirring rate, and ionic strength were optimized. The limits of detection were from 0.034 to 0.132?µg?L^?1. The relative standard deviations were from 3.4 to 4.9% for a single fiber and from 5.1 to 6.4% for multiple fibers. The recovery of polycyclic aromatic hydrocarbons in environmental water fortified at 5.0 and 50?µg?L^?1 was from 83.1 to 103% with relative standard deviations below 8.4%. This fiber was shown to withstand at least 200 extraction and desorption cycles. The method was used for the preconcentration and determination of polycyclic aromatic hydrocarbons in environmental water.     

胺桥杯［4］芳烃固相微萃取探头的特性及其应用

采用溶胶-凝胶方法制备了25,27-二羟基-26,28-(1′,10′-二氧代-4′,7′-二氮杂-3′,8′-二氧代亚辛基)-对-特丁基-杯［4］芳烃/羟基硅油(胺桥杯［4］/OH-TSO)固相微萃取(SPME)探头,通过对脂肪胺和芳胺的分析研究了它的特性。该探头具有耐高温、抗溶剂冲洗、使用寿命长、重现性好等特点。杯环上极性胺桥的引入增强了涂层的极性,因而在不需衍生的情况下对脂肪胺和芳胺都具有很好的萃取能力,表现出对胺类化合物的特殊选择性。脂肪胺的检出限为0.19～39.51 μg/L,线性范围达3个数     

Solid-phase microextraction of monocyclic aromatic amines using novel fibers coated with crown ether.

Three solid-phase microextraction (SPME) fibers prepared by the sol-gel method, containing hydroxydibenzo-14-crown-4 (OH-DB14C4), dihydroxy-substituted saturated urushiol crown ether (DHSU14C4) and 3,5-dibutyl-unsymmetry-dibenzo-14-crown-4-dihydroxy crown ether (DBUD14C4), respectively, were evaluated for the determination of aromatic amine (aniline, m-toluidine, N,N-diethylaniline, N-ethyl-m-toluidine, 3,4-dimethylaniline). The sol-gel-derived hydroxy-dibenzo14-crown-4-coated fiber has the best affinity for several aniline derivatives. Optimization was carried out for the determination of aromatic amines with SPME fibers. The linearity was from 0.11 to 29 microg/ml and detection limits varied from 0.17 to 0.98 ng/ml. Relative standard deviation (n=5) was found to be 3.23-6.20%. The coating proved to be very stable at high temperature (to 340 degrees C) and in different solvents (organic and inorganic). The method was applied to the determination of aromatic amines in wastewater samples from a pharmaceutical factory.     

Air sampling of aromatic hydrocarbons in the presence of ozone by solid-phase microextraction

Effects of ozone on air sampling of standard gas mixtures of aromatic hydrocarbons were tested using solid-phase microextraction (SPME). Standard concentrations of ozone ranging from 10 ppb (v/v) to 6400 ppm (v/v) were generated using an in-house built ozone generator based on corona discharge. Effects of temperature, discharge voltage, and oxygen flow on the ozone generation were tested. The working dc voltage had the greatest effect on generated ozone concentration and was proportional to the ozone concentration. Generation temperature and oxygen flow rate were inversely proportional to ozone concentrations. Produced ozone was mixed with standard benzene, toluene, ethylbenzene, and xylenes (BTEX) gas at less than 100 ppb (v/v). Air samples were collected with poly(dimethylsiloxane) (PDMS) 100 microm SPME fibers and analyzed by gas chromatography (GC)-flame ionization detection (FID) and GC-MS. Significant reductions of BTEX concentrations were observed. In addition, some products of BTEX-ozone-oxygen reactions were identified. SPME worked well as a rapid sampler for BTEX and BTEX-ozone-oxygen reaction products. No significant deterioration of the PDMS coating and no significant reduction of absorption capacity were observed after repeated exposure to ozone.     

Separation and identification of aromatic acids in soil and the Everglades sediment samples using solid-phase microextraction followed by capillary zone electrophoresis

The separation and identification of aromatic acids in soil and the Everglades sediment samples was carried out using solid-phase microextraction (SPME) followed by capillary zone electrophoresis (CZE). The soil and sediment samples were subject to a series of sample treatments including oxidative hydrolysis with molecular oxygen in a sodium hydroxide solution, acidification and filtration. The aromatic acids in the sample filtrate were extracted using SPME with a polyacrylate-coated fiber. The acids adsorbed on the fiber were subsequently desorbed in methanol. The desorbed acids were then separated by CZE. Several aromatic acids (e.g.. salicylic acid, p-coumaric acid, ferulic acid and vanillic acid) in both soil and sediment samples were separated, identified and quantified. The results of this study show that the combination of SPME with CZE is promising for environmental analysis.     

Evaluation of solid-phase microextraction methods for determination of trace concentration aldehydes in aqueous solution

A method for trace analysis of a wide range of aldehydes (saturated/unsaturated aliphatic, aromatic aldehydes, including hydroxylated species, and dialdehydes) in an aqueous solution was optimized. An evaluation of three solid-phase microextraction (SPME) techniques (headspace, liquid-phase, and on-fiber derivatization) with o-(2,3,4,5,6-pentafluorobenzyl)hydroxylamine hydrochloride (PFBHA) aldehyde derivatization was performed focusing on the optimization of the main extraction parameters (temperature and time). The optimized method employed the liquid-phase SPME (D-L-SPME) of derivatized aldehydes at 80 degrees C for 30 min. Limits of detection (LODs) using this optimal method were in the range of 0.1-4.4 microg/L for the majority of aliphatic (saturated, unsaturated), aromatic aldehydes and dialdehydes. Formaldehyde LODs and those of some hydroxylated aromatic aldehydes were between 32 and 55 microg/L. Headspace SPME using an on-fiber derivatization generally showed a lower sensitivity and several compounds were not detected. Another technique, the optimized headspace SPME of aldehydes derivatized in aqueous solution, was not as sensitive as D-L-SPME for hydroxylated aromatic aldehydes. The developed method was used to analyze aqueous particulate matter extracts; this method achieved higher sensitivities than those obtained with US Environmental Protection Agency (EPA) Method 556.     

固相微萃取新型涂层的制备和特性(英文)

 以聚甲基苯基乙烯基硅氧烷为主要成分 ,采用溶胶 凝胶技术和自由基引发交联反应的方法首次制备了一种固相微萃取新涂层 ,并与气相联用 ,分析了芳香族化合物 ,考察了它的萃取性能。结果表明 :该涂层提供了大的比表面积 ,可获得高的萃取效率。与相应的商用固相微萃取涂层相比 ,该涂层具有更好的灵敏度和选择性 ,且热稳定性好 ,使用寿命长。     

Determination of petroleum hydrocarbons in contaminated soils using solid-phase microextraction with gas chromatography-mass spectrometry.

Manual solid-phase microextraction (SPME) coupled with gas chromatography-mass spectrometry is investigated as a possible alternative for the determination of petroleum hydrocarbons in soils. Spiked onto an agricultural soil is a commercial diesel fuel (DF) with the following composition by weight: 12% linear alkanes, 52% saturated hydrocarbons (branched and cyclic), 21% alkylated aromatic hydrocarbons, 6% polycyclic aromatic hydrocarbons, and 9% unidentified compounds. The spiked soil samples are aged three days at room temperature before analysis. The optimal conditions for the SPME of DF from soils are examined and maximum sensitivity is obtained using a 100-microm polydimethylsiloxane fiber at a sampling temperature of 47 degrees C by sonication both in the headspace and directly through a water medium. The reproducibility of the whole technique showed a relative standard deviation of 10%. The parameters that can influence the recovery of DF (such as the time of SPME extraction, the presence of organic solvent and water, and the matrix) are investigated. The linearity is verified in the range of 40 to 1200 mg/L for the direct injection of DF, 0.1 to 1 mg/L for the SPME of DF from water, and 1 to 50 mg/Kg of dry soil for the SPME of DF from soils. The detection limits are respectively 0.5 mg/L, 0.02 mg/L, and 0.1 mg/Kg of dry soil. The method is corroborated by comparing the results with those obtained by the traditional way.     

Standard-free kinetic calibration for rapid on-site analysis by solid-phase microextraction

In this study, a new calibration method, standard-free kinetic calibration, is proposed for rapid on-site analysis by solid-phase microextraction (SPME), based on the diffusion-controlled mass transfer model and equilibrium extraction. With this calibration method, all analytes can be directly calibrated with only two samplings. The feasibility of this calibration method was validated in a standard aqueous solution flow-through system and a standard gas flow-through system. The distribution coefficients of five polycyclic aromatic hydrocarbons (PAHs), including naphthalene, acenaphthene, fluorene, anthracene, and pyrene, between water and the PDMS fiber coating were determined and the concentrations of the PAHs in the flow-through system were successfully calibrated with the proposed standard-free calibration method. The extracted amounts of BTEX (benzene, toluene, ethylbezene, o-xylene) at equilibrium were also successfully calibrated with this method with two rapid sampling periods at 5 and 10 s. Compared with the previous calibration methods for rapid on-site analysis by SPME, this method does not require a standard to calibrate the extraction, nor does it require additional equipment to control or measure the flow velocity of the sample matrix. In addition, all of the extracted analytes can be quantified without considering whether the system reached equilibrium. The newly proposed standard-free kinetic calibration approach enriched the calibration methods available for on-site analysis by SPME.     

A highly thermal-resistant electrospun-based polyetherimide nanofibers coating for solid-phase microextraction

A high-temperature-resistant solid-phase microextraction (SPME) fiber was prepared based on polyetherimide (PEI) by the electrospinning method. The PEI polymeric solution was converted to nanofibers using high voltages and directly coated on a stainless steel SPME needle. The scanning electron microscopy images of PEI coating showed fibers with diameter range of 500–650 nm with a homogeneous and smooth surface morphology. The SPME nanofibers coating was optimized for PEI percentage, electrospinning voltage, and time. The extraction efficiency of the coating was investigated for headspace SPME of some environmentally important polycyclic aromatic hydrocarbons from aqueous samples followed by gas chromatography–mass spectrometry measurement. In addition, the important extraction parameters including extraction temperature, extraction time, ionic strength, as well as desorption temperature and time were investigated and optimized. The detection limits of the method under optimized conditions ranged from 1 to 5 ng L^?1 using time-scheduled selected ion monitoring mode. The relative standard deviations of the method were between 1.1 and 7.1 %, at a concentration level of 500 ng L^?1. The calibration curves of polycyclic aromatic hydrocarbons showed linearity in the range of 5–1000 ng L^?1. The developed method was successfully applied to real water samples and the relative recovery percentages obtained from the spiked water samples were from 84 to 98 % for all the selected analytes except for acenaphthene which was from 75 to 106 %.