顶空固相微萃取-气相色谱-质谱法快速测定酱油中的挥发性风味成分

建立了一种快速简便地测定酱油中挥发性风味成分的顶空固相微萃取（HS-SPME）-气相色谱-质谱法(GC-MS)。以2-辛醇为内标,考察了萃取头、萃取时间、离子强度、萃取温度对酱油样品中挥发性风味物质萃取的影响。该方法对酱油中常见挥发性风味成分的测定有良好的重复性和回收率,对常见挥发性物质的定量比较准确。优化的HS-SPME条件为：涂层厚度为85 μm聚丙烯酸酯(PA)萃取纤维头,于45 ℃、NaCl质量浓度为250 g/L下对酱油样品顶空吸附40 min,于250 ℃下解吸2 min后进行GC-MS分离鉴定。酱油样品的分析结果表明,其挥发性风味物质中含量较高的是醇、酸、酯和酚类,此外还有一些羰基化合物和杂环化合物。     

顶空固相微萃取-气相色谱-质谱法用于白术中挥发性成分的分析

采用顶空固相微萃取-气相色谱-质谱法(HS-SPME-GC-MS)分离鉴定了白术中的挥发性成分,并与采用传统的水蒸气蒸馏法(SD)提取的挥发性成分进行了比较。实验中筛选了固相微萃取纤维头,优化了SPME的操作条件。样品在70 ℃下平衡30 min后,用65 μm聚二甲基硅氧烷-二乙烯基苯(PDMS-DVB)纤维头对白术样品顶空吸附30 min,于250 ℃下解吸4 min, 然后采用GC-MS对解吸物进行分离鉴定;采用HS-SPME-GC-MS鉴定出41种组分,占总峰面积的90.81%;采用SD-GC-MS鉴定出31个组分,占总峰面积的88.19%,且采用SD所提取的组分基本上都被固相微萃取所提取。结果表明, HS-SPME可取代耗时的SD用于白术中挥发性物质的提取。     

顶空固相微萃取-气相色谱-质谱联用快速分析八角茴香中风味物质

采用顶空固相微萃取与气相色谱-质谱联用技术，对八角茴香中风味物质进行了分析。选用自制聚丙烯酸树脂涂层，对样品量、萃取时间、萃取温度、解吸时间等参数进行了优化，结果表明0．10g样品在60℃水浴中顶空萃取40min，250℃下解吸2min达到最佳条件。比较了顶空固相微萃取与传统水蒸气蒸馏两种前处理方法，分析结果非常相似。该方法可用于快速分析八角茴香中的风味物质。     

顶空固相微萃取-气相色谱-质谱法对柑橘蜜中挥发性组分的定性和半定量分析

采用顶空固相微萃取与气相色谱-质谱法结合进行柑橘蜜中挥发性组分的定性和半定量分析。取柑橘蜜4.00g与水1.00g置于顶空瓶中,用DVB/CAR/PDMS纤维头作萃取头,将顶空瓶密封,在50℃水浴中搅拌10min,萃取50min。取出萃取头,插入气相色谱仪中于255℃解吸3.5min,经TG-5MS毛细管柱分离,质谱测定采用电子轰击离子化方式。用此方法分析了4种柑橘蜜样品,鉴定了72种挥发性组分,主要有醇、烃、酮、醛及酯类化合物,并确定柠檬烯、反式和顺式氧化芳樟醇、β-芳樟醇以及柠檬醛为其特征性成分。按方法对8种样品进行分析,测得各特征性成分的绝对峰面积的相对标准偏差(n=5)在2.9%~20%之间。     

固相微萃取/气相色谱-质谱联用技术测定燕窝中挥发性成分

该文以印尼产的燕窝为材料,使用固相微萃取(SPME)技术萃取燕窝中挥发性成分并以气相色谱-质谱(GC-MS)联用仪进行测定。考察了萃取头类型、萃取温度、萃取时间和解吸时间对固相微萃取(SPME)在燕窝挥发性成分测定中的影响。结果表明:以65μm聚二甲基硅氧烷/二乙烯基苯(PDMS/DVB)萃取头、在60℃下萃取60 min,解吸2 min的条件下,SPME/GC-MS技术可检出燕窝中挥发性成分醇、烃、醛、酯、醚类等化合物共82种。该方法具有操作简便、快速、重复性好和灵敏度高的特点,适用于燕窝中挥发性成分的测定。     

顶空-固相微萃取-气相色谱-质谱法测定烟气中挥发性和半挥发性成分

提出了顶空-固相微萃取-气相色谱-质谱法测定烟气中挥发性和半挥发性成分。结合信息量最大的原则,确定了固相微萃取时萃取纤维头为碳分子筛/聚二甲基硅烷萃取纤维头,萃取温度为70℃,萃取时间为60min。在气相色谱分离中用Agilent DB-1色谱柱为固定相,在质谱分析中采用全扫描模式。结果表明:共鉴定出107种成分,含量最大的成分是烟碱(18.07%),其次是新植二烯(11.46%),主要的3类挥发性和半挥发性成分依次为苯系物、酮类以及杂环类。     

固相微萃取/气相色谱-质谱法对乌梅浸膏挥发性成分的分析研究

对乌梅浸膏挥发性物质的固相微萃取条件进行了研究。运用正交实验设计,比较了不同萃取头、平衡温度及采样时间对分析结果的影响,通过气相色谱-质谱(GC-MS)的分析监控,结合信息量最大原则,确定了固相微萃取的最佳条件:萃取纤维头为聚二甲基硅氧烷,平衡温度为70℃,采样时间45 min。通过GC-MS进行定性定量分析,共鉴定出38种成分,主要挥发性成分依次为糠醛(24.88%)、2-甲基-3-羟基苯甲醛(13.57%)和5-甲基糠醛(10.16%)。     

气相色谱-质谱法检测人造板中挥发性有机物

取过0.18 mm筛的人造板粉末0.300 0 g,在60℃水浴中进行顶空固相微萃取(SPME)30 min;用75μm CAR/PDMS纤维头富集样品释放出的挥发性有机物。使用自制简易冷阱聚焦装置,将纤维头插入气相色谱(GC)进样口解吸3 min,所得溶液采用气相色谱-质谱法检测其中的挥发性有机物。结果表明:在刨花板、中密度纤维板及胶合板中,共检出95种物质,其中苯系物27种,醛/酮类11种,烷烃类8种,醇/酯类11种,萜类物质38种。     

顶空固相微萃取-气相色谱-质谱联用分析干柴胡药材中有机挥发物

采用顶空固相微萃取与气相色谱-质谱联用技术检测分析干柴胡药材中挥发性成分,选用聚丙烯酸酯涂层,就萃取时间、温度、体积、样品量、预热时间及脱附时间等条件进行了优化,结果表明,30mL萃取瓶里0．5g样品90℃温度下预热40min后,以85μmPA涂层顶空萃取50min,于250℃脱附5min,测得88个峰,鉴定26种化合物成分。方法所得结果与传统提取方法(蒸馏提取法)比较,相对含量较高的成分一致,方法重现性理想,可应用于柴胡药材挥发性物质的快速分析。     

萝卜炖牛腩挥发性风味成分的分离与鉴定

采用固相微萃取(solid-phase micro extraction,SPME)法和溶剂辅助蒸发(solvent-assisted flavor evaporation,SAFE)法提取萝卜炖牛腩中的挥发性风味成分,利用气相色谱-质谱联用(gas chromatography-mass spectrometry,GC-MS)技术对其挥发性风味成分进行分析。对影响固相微萃取的操作条件萃取头纤维种类、样品量、吸附温度以及萃取时间进行了优化,结果表明当选择65μm PDMS/DVB(粉色)萃取头、样品量为8 g、吸附温度为60℃、萃取时间为40 min时,萃取效果最佳。两种方法共鉴定出98种挥发性成分,包括烃类11种、醛类13种、酮类11种、酸类7种、醇类22种、酯类12种、醚类4种、酚类6种、含硫含氮及其他杂环化合物12种。其中,醛类、醚类和含硫含氮及其他杂环化合物可能对萝卜炖牛腩特征风味的形成有着重要的影响。     

顶空固相微萃取-气相色谱-质谱法测定小米黄酒风味成分

为全面了解小米黄酒风味成分的构成和气味特征,优化了85μm聚丙烯酸酯(PA)、100μm聚二甲基硅氧烷(PDMS)、75μm碳分子筛(CAR)/PDMS、50/30μm二乙烯基苯(DVB)/CAR/PDMS萃取头提取小米黄酒风味成分的条件,采用顶空固相微萃取(headspace solid phase microextraction,HS-SPME)-气相色谱-质谱法(GC-MS)对风味成分进行定性、定量分析,并计算气味活性值(odor active value,OAV),同时利用OAV分析风味成分的气味特征和气味强度。结果显示:不同萃取头的最优萃取条件为样品量8 mL、萃取时间40 min、萃取温度60℃、NaCl添加量1.5 g。小米黄酒风味成分由醇、酯、含苯化合物、烃、酸、醛、酮、烯、酚和杂环类化合物构成,醇为主要风味成分。通过OAV确定了苯乙醇、苯乙烯、2-甲基萘、1-甲基萘、苯甲醛、苯乙醛、2-甲氧基-苯酚为小米黄酒气味特征成分,苯基乙醇、苯乙醛对气味贡献最大。PA和PDMS萃取头分别对极性和非极性化合物具有较好的吸附效果,CAR/PDMS和DVB/CAR/PDMS萃取头对中等极性化合物具有较好的吸附效果。该研究全面了解了小米黄酒风味成分的构成,为其产品开发及品质控制提供理论了依据。     

Evaluation of solid-phase micro-extraction coupled to gas chromatography-mass spectrometry for the headspace analysis of volatile compounds in cocoa products

The aroma profile of cocoa products was investigated by headspace solid-phase micro-extraction (HS-SPME) combined with gas chromatography–mass spectrometry (GC–MS). SPME fibers coated with 100 μm polydimethylsiloxane coating (PDMS), 65 μm polydimethylsiloxane/divinylbenzene coating (PDMS-DVB), 75 μm carboxen/polydimethylsiloxane coating (CAR-PDMS) and 50/30 μm divinylbenzene/carboxen on polydimethylsiloxane on a StableFlex fiber (DVB/CAR-PDMS) were evaluated. Several extraction times and temperature conditions were also tested to achieve optimum recovery. Suspensions of the samples in distilled water or in brine (25% NaCl in distilled water) were investigated to examine their effect on the composition of the headspace. The SPME fiber coated with 50/30 μm DVB/CAR-PDMS afforded the highest extraction efficiency, particularly when the samples were extracted at 60 °C for 15 min under dry conditions with toluene as an internal standard. Forty-five compounds were extracted and tentatively identified, most of which have previously been reported as odor-active compounds. The method developed allows sensitive and representative analysis of cocoa products with high reproducibility. Further research is ongoing to study chocolate making processes using this method for the quantitative analysis of volatile compounds contributing to the flavor/odor profile.     

Comparative study of extraction techniques for determination of garlic flavor components by gas chromatography–mass spectrometry

Several sampling techniques based on steam distillation (SD), simultaneous distillation and solvent extraction (SDE), solid-phase trapping solvent extraction (SPTE), and headspace solid-phase microextraction (HS-SPME) have been compared for the determination of Korean garlic flavor components by gas chromatography–mass spectrometry (GC–MS). Diallyl disulfide (57.88%), allyl sulfide (23.59%), and diallyl trisulfide (11.40%) were found to be the predominant flavor components of garlic samples extracted by SDE whereas these components were at levels of 89.77%, 2.43%, and 3.89% when the same sample was extracted by SD, 97.77%, 0.17%, and 0.10% by SPTE, and 97.85%, 0.01%, and 0.01% by HS-SPME using the 50/30-m divinyl benzene/carboxen/polydimethylsiloxane (DVB/CAR/PDMS) fiber. Thermal degradation of components such as allyl methyl sulfide, dimethyl disulfide, and thiirane were observed for SDE and SD but not for SPTE or HS-SPME. HS-SPME had several advantages compared with SD, SDE, and SPTE—rapid solvent-free extraction, no apparent thermal degradation, less laborious manipulation, and less sample requirement. Five different fiber coatings were evaluated to select a suitable fiber for HS-SPME of garlic flavor components. DVB/CAR/PDMS was most efficient among the five types of fiber investigated.     

Characterization of Ayran Aroma Active Compounds by Solvent-Assisted Flavor Evaporation (SAFE) with Gas Chromatography–Mass Spectrometry–Olfactometry (GC–MS–O) and Aroma Extract Dilution Analysis (AEDA)

The aroma compounds of ayran were isolated using solvent-assisted flavor evaporation (SAFE) resulting in a more representative extract of ayran odor compared to liquid–liquid extraction (LLE), solid-phase extraction (SPE), and simultaneous distillation–extraction (SDE). The aromatic extract was subjected to sensory analysis and identified and quantified by gas chromatography–mass spectrometry (GC–MS). A total of 19 volatile compounds were detected that included alcohols, aldehyde, acids, esters, ketones, and terpenes. However, the compounds present at the highest concentrations were ethyl lactate, ethanol, 2,3-butanediol, acetoin, and acetic acid. The key odorants for the ayran drinks were detected using aroma extract dilution analysis (AEDA) and GC–MS–olfactometry (GC–MS–O). A total of 14 aroma-active compounds were determined for the first time. The flavor dilution (FD) factors ranged between 4 and 512 while their odor activity values (OAVs) were from 1.35 to 1126.99. Ethyl lactate (FD of 512 whey/creamy), 2-methylbutanal (FD of 512, fruity), acetoin (FD of 256, buttery creamy), and butanoic acid (FD of 256, cheesy-sweet) were the strongest aroma-active components of the Ayran drink.     

Analysis of flavor and perfume using an internally cooled coated fiber device

A miniaturized internally cooled coated fiber device was applied for the analysis of flavors and fragrances from various matrices. Its integration with a CTC CombiPAL autosampler enabled high throughput for the analysis of analytes in complex matrices that required simultaneous heating of the matrices and cooling of the fiber coating to achieve high extraction efficiency. It was found that up to ten times increase of extraction efficiencies was observed when the device was used to extract flavor compounds in water, even when limited sample temperatures were used to preserve the integrity of target compounds. The extraction of the flavor compounds in water with the device was reproducible, with RSD not larger than 15%. The lower limits of the linear ranges were in the low ppb range, which was about one order of magnitude smaller than those obtained with the commercialized 100 microm PDMS fibers. Exhaustive extraction of some perfume ingredients from a complex matrix (shampoo) was realized. All achieved recoveries were not less than 80%. The repeatability of the extraction of the perfume compounds from shampoo was better than 10%. The linear ranges were about 1-3000 microg/g, and the LOD was about 0.2-1 microg/g. The automated internally cooled coated fiber device was demonstrated to be a powerful sample preparation tool in flavor and fragrance analysis.     

Optimization of HS-SPME for GC-MS Analysis and Its Application in Characterization of Volatile Compounds in Sweet Potato

Volatile compounds are the main chemical species determining the characteristic aroma of food. A procedure based on headspace solid-phase microextraction (HP-SPME) coupled to gas chromatography-mass spectrometry (GC-MS) was developed to investigate the volatile compounds of sweet potato. The experimental conditions (fiber coating, incubation temperature and time, extraction time) were optimized for the extraction of volatile compounds from sweet potato. The samples incubated at 80 °C for 30 min and extracted at 80 °C by the fiber with a divinylbenzene/carboxen/polydimethylsiloxane (DVB/CAR/PDMS) coating for 30 min gave the most effective extraction of the analytes. The optimized method was applied to study the volatile profile of four sweet potato cultivars (Anna, Jieshu95-16, Ayamursaki, and Shuangzai) with different aroma. In total, 68 compounds were identified and the dominants were aldehydes, followed by alcohols, ketones, and terpenes. Significant differences were observed among the volatile profile of four cultivars. Furthermore, each cultivar was characterized by different compounds with typical flavor. The results substantiated that the optimized HS-SPME GC-MS method could provide an efficient and convenient approach to study the flavor characteristics of sweet potato. This is the basis for studying the key aroma-active compounds and selecting odor-rich accessions, which will help in the targeted improvement of sweet potato flavor in breeding.     

Comparison of simultaneous distillation extraction and solid-phase microextraction for the determination of volatile flavor components

Traditional simultaneous distillation extraction (SDE) and solid-phase microextraction (SPME) techniques were compared for their effectiveness in the extraction of volatile flavor compounds from various mustard paste samples. Each method was used to evaluate the responses of some analytes from real samples and calibration standards in order to provide sensitivity comparisons between the two techniques. Experimental results showed traditional SDE lacked the sensitivity needed to evaluate certain flavor volatiles, such as 1,2-propanediol. Dramatic improvements in the extraction ability of the SPME fibers over the traditional SDE method were noted. Different SPME fibers were investigated to determine the selectivity of the various fibers to the different flavor compounds present in the mustard paste samples. Parameters that might affect the SPME, such as the duration of absorption and desorption, temperature of extraction, and the polarity and structure of the fiber were investigated. Of the various fibers investigated, the PDMS–DVB fiber proved to be the most desirable for these analytes.     

Characterization of Kimchi Flavor with Preconcentration by Head Space Solid-Phase Microextraction and Stir Bar Sorptive Extraction and Analysis by Gas Chromatography-Mass Spectrometry

Kimchi is a traditional fermented vegetable, known for its complex flavor. Herein, we compared compounds related to the kimchi flavor, identified by gas chromatography-mass spectrometry (GC-MS) with the developed solid phase microextraction (SPME) and stir bar sorptive extraction (SBSE) techniques. Although headspace-solid phase microextraction (HS-SPME) detected more volatile compounds than nondestructive-headspace-solid-phase microextraction (ND-HS-SPME), those identified by ND-HS-SPME were considered closely related to the flavor of the intact kimchi. Furthermore, direct immersion-stir bar sorptive extraction (DI-SBSE) detected more volatile and nonvolatile compounds than headspace-stir bar sorptive extraction (HS-SBSE), while more sulfur compounds were identified by HS-SBSE. Therefore, we recommend the use of the HS-SPME method using a divinylbenzene/carboxen/polydimethylsiloxane fiber for identifying compounds related to the kimchi flavor. In addition, principal component analysis showed ND-HS-SPME and HS-SBSE to be closely clustered. Overall, we estimated that the samples obtained via the nondestructive sample preparation emits fewer polar volatile flavor compounds than those obtained using the destructive sample preparation. Considering the findings presented herein, we believe that this study contributes to optimizing the flavor analysis of kimchi and other fermented vegetables.     

顶空吸附萃取-气相色谱法分析小麦中部分风味物质

采用顶空吸附萃取法(headspace sorptive extraction, HSSE)建立了小麦中部分风味物质的分析方法。以硅橡胶为原料,采用溶胶-热空气硫化法,在模具中定型制得硅橡胶萃取棒。萃取棒的硅橡胶层体积约为87 μL,热稳定性好,耐热温度达到390 ℃。萃取棒吸附的风味物质经自制热解吸装置热脱附,被吹扫进入气相色谱仪进行分析。考察了萃取温度及时间、相比、热解吸条件对该方法萃取效率的影响。在优化条件下分析小麦粉标准样品,结果表明:方法的线性关系良好(r>0.9979),检出限为0.09～1.00 μg/kg,标准物质的平均添加回收率为95%～121%,相对标准偏差在2.2%～7.8%之间。对小麦粉实际样品进行分析,采用外标法得到了7种风味物质的绝对含量。该方法简便快捷,检出限低,适用于小麦中风味物质的快速定量分析。