气提热脱附毛细管气相色谱—质谱法分析水中痕量挥发性有机物

〕气提水中挥发性有机物并在多孔聚合物TenaxGC上吸附浓缩。为此设计了一种简便的全玻璃气提装置,它可在室温或提高温度下进行有效的气提。通过简单的色谱仪汽化室热脱附,把样品从吸附剂转移到气相色谱柱。在内径0.1毫米OV-17高效金属毛细管柱进行分离。为改善分离柱头用浓氮冷冻。用配有计算机的质谱定性。为改善色谱本底采取了几种措施。方法的检测极限对辛烷、癸烷和十二烷分别是5、10、15ppt这一研究已经用于第二松花江水中有机污染物探查。     

气提吸附／热脱附／气相色谱－质谱法分析污水中的痕量有机物

采用气提吸附／热脱附／气相色谱－质谱法对齐鲁公司所处地区工业污水进行分析。方法采用Ｔｅｎａｘ－ＧＣ吸附剂对样品进行气提吸附，脱附时样品直接进入色谱仪汽化室，一次进样即可完成全组分分析，共检测出含四氯丙醚在内的４０种有机组分，测定了各组分的程序升温保留指数。气相色谱－质谱法测定出四氯丙醚三个异构体的结构。     

气提吸附／热脱附／气相色谱－质谱法分析污水中的痕量有机物

 采用气提吸附／热脱附／气相色谱－质谱法对齐鲁公司所处地区工业污水进行分析。方法采用Ｔｅｎａｘ－ＧＣ吸附剂对样品进行气提吸附，脱附时样品直接进入色谱仪汽化室，一次进样即可完成全组分分析，共检测出含四氯丙醚在内的４０种有机组分，测定了各组分的程序升温保留指数。气相色谱－质谱法测定出四氯丙醚三个异构体的结构。     

锥型与圆柱型液相色谱制备柱的比较研究

用可视化柱上图形分析对入口内径大于出口内径的锥型液相色谱制备柱的样品谱带流型进行了研究。在一定的实验条件下，锥型柱与圆柱型柱的流动相流型曲线相反。对与锥型柱有相同长度、相同容积的圆柱型色谱柱的柱效、样品容量及峰高的比较研究表明：锥型柱优于圆柱型柱。锥型柱的样品容量约为圆柱型柱的2倍，柱效比圆柱型的高36％，色谱流出曲线峰值高于圆柱型柱12％。     

气液色谱法测定汽油中C_5—C_7烃的各单体组成

介绍了测定汽油中C_5—C_7馏分的28个单体烃的气液色谱方法.在最佳的操作条件下,用季戊四醇酯的色谱柱得到了23个色谱峯;用氯萘的色谱柱得到了21个色谱峯.综合两色谱柱所得结果,就可以得到28个单体烃的含量.文中列出了各单体烃在两柱上的相对保留时间及保留体积值,保留体积的对数值与碳原子数呈线性关系.用配制的已知组成试样验证本方法的绝对误差在1％左右,对直馏汽油及石油二次加工汽油平行测定差值为1％.文中还讨论了柱温对分离的影响及不同极性固定液的选择性.试验是在自制的气液色谱仪上进行的,采用热敏电阻热导池作鉴定器.本方法分析一个试样约需4小时.     

气提热脱附毛细管气相色谱法分析水中痕量挥发性有机物

气提热脱附毛细管气相色谱法是一种高灵敏度、高分辨水中有机物的分析方法。在我们以前研究的基础上,本研究提出了一种改良的气提装置,实现了气提装置与玻璃毛细管柱的连接,采用PEG-300做标准样(或内标)溶剂,柱后分流用FID、ECD检测。本文报导有关这些方面的技术情况及评价结果。实验装置及方法 1.装置:图1是气提瓶的结构图。气提瓶容积约400ml,内径40mm,筛板为40ml耐酸漏     

超高效液相色谱-三重四极杆质谱法检测血中脱乙基扎来普隆

建立了全血中脱乙基扎来普隆液相色谱-串联质谱检验法。对p H、淋洗液、缓冲液等条件进行优化,实验选用HLB柱,p H 9硼酸盐缓冲溶液,氨水-甲醇水为淋洗液,乙腈为洗脱液,选用ZORBAX Eclipse Plus C18色谱柱,以A相0.1%甲酸和B相乙腈作为流动相,进行梯度洗脱。采用液相色谱-串联质谱仪的电喷雾电离,正离子模式扫描,MRM模式检测脱乙基扎来普隆。在最优条件下,全血中脱乙基扎来普隆质量浓度在0.1~100 ng/m L范围内有良好线性关系,保留时间为1.95 min。回归方程为y=9971.2ρ-1 813.8,检出限0.1 ng/m L。回收率90%以上,日内与日间精密度均小于10%。方法适用于全血中的脱乙基扎来普隆检测。     

液晶用作气液色谱固定液的研究(Ⅰ)——硅藻土薄层玻璃毛细管柱色谱分离甲基苯甲酸异构体

本文以甲基苯甲酸(甲酯)异构体为例,用五种芳羧酸双酯液晶作气液色谱固定液在填充柱上进行了分离,讨论了液晶分子结构对分离效能的影响;并考核了在液晶毛细管色谱柱上的分离效能和柱温,载气流速的影响等。     

三聚氰胺在双色谱柱串联模式下的色谱保留研究

研究了亲水相互作用色谱柱串联C_(18)柱上三聚氰胺的色谱保留,并应用牛奶基质中三聚氰胺的高效分离。将HILIC柱与C_(18)柱串联,研究不同色谱柱串联顺序及色谱分离条件下三聚氰胺的保留情况,结果表明:当流动相为乙腈-乙酸铵(10mmol/L)=85∶15(v/v)、柱温30℃、流速0.75mL/min、检测波长220nm、HILIC柱在前C_(18)柱在后串联时,三聚氰胺分离效果最佳。在最佳的色谱条件下,对市售牛奶进行测定,未检测出三聚氰胺,加标回收率在81.1%～119%,三聚氰胺在双柱模式下分析效果良好。     

顶空气相色谱法测定茶多酚工业废水中的三氯甲烷

改用氢火焰离子化检测器和毛细管色谱柱,以医用100 mL输液瓶为气液平衡瓶,采用带锁定气密性注射器,利用顶空气相色谱法对茶多酚工业废水中三氯甲烷含量进行了测定,通过实验得到最佳顶空色谱条件。结果表明,以SPETM-1毛细管色谱柱,FID检测器进行顶空气相色谱测定,标准曲线相关系数为0.9997,RSD为2.73%～5.16%之间,回收率在99.28%～99.98%之间,方法精密度好,准确度高,能满足工业分析要求。     

Fast Temperature Programming in Gas Chromatography using Resistive Heating

The features of a resistive-heated capillary column for fast temperature-programmed gas chromatography (GC) have been evaluated. Experiments were carried out using a commercial available EZ Flash GC, an assembly which can be used to upgrade existing gas chromatographs. The capillary column is placed inside a metal tube which can be heated, and cooled, much more rapidly than any conventional GC oven. The EZ Flash assembly can generate temperature ramps up to 1200°/min and can be cooled down from 300 to 50°C in 30 s. Samples were injected via a conventional split/splitless injector and transferred to the GC column. The combination of a short column (5 m×0.25 mm i. d.), a high gas flow rate (up to 10 mL/min), and fast temperature programmes typically decreased analysis times from 30 min to about 2.5 min. Both the split and splitless injection mode could be used. With n-alkanes as test analytes, the standard deviations of the retention times with respect to the peak width were less than 15% (n = 7). First results on RSDs of peak areas of less than 3% for all but one n-alkane indicate that the technique can also be used for quantification. The combined use of a short GC column and fast temperature gradients does cause some loss of separation efficiency, but the approach is ideally suited for fast screening as illustrated for polycyclic aromatic hydrocarbons, organophosphorus pesticides, and triazine herbicides as test compounds. Total analysis times – which included injection, separation, and equilibration to initial conditions – were typically less than 3 min.     

Effects of pressure drop on absolute retention matching in comprehensive two-dimensional gas chromatography

Comprehensive two-dimensional gas chromatography (GC x GC) analysis has the capability to resolve many more components of complex mixtures than traditional single column GC analysis. There is an increasing need to provide reliable identification of these separated components; time-of-flight mass spectrometry (TOFMS) is the most appropriate technology to achieve this task. Rather than require MS for all GC x GC separations, it is desirable to assign peak identities to specific peak positions in the GC x GC separation space, and this necessitates matching peak retentions in the two experiments - GC x GC-FID and GC x GC-TOFMS. The atmospheric vs. vacuum outlet conditions confound this task. It is shown here that by employing a supplementary gas supply, provided to a T-union between the column outlet and the MS interface, it is possible to generate 2D chromatograms for GC x GC-FID and GC x GC-TOFMS that are essentially exactly matched. There is no degradation in separation performance or efficiency in the second column in the system interfaced to the T-union. Since the GC x GC-FID experiment uses hydrogen for maximum efficiency, and GC x GC-TOFMS uses helium carrier, translation of (conditions/retentions) must account for the different viscosities of the carrier gases. Translation of conditions is based on well-known principles established in single column analysis. Tabulated data illustrate that retention reproducibility was of the order of better than 4 s for the average first dimension retention difference, and about 40 ms for the average second dimension retention difference when comparing GC x GC-FID and GC x GC-TOFMS results. This should provide considerable support for identification in routine GC x GC-FID analysis of specific sample types, once the peaks in 2D separation space have been assigned identities through GC x GC-TOFMS analysis.     

Application of a thermal desorption cold trap injector to multidimensional GC and GC-MS

The Thermal desorption Cold Trap injector (TCT) was used as a part of modified multidimensional GC (MDGC) or MDGC mass spectroscopy (MS) systems. These systems were based on a preparative GC (GC1), an analytical GC (GC2), or GC-MS and the TCT. The TCT was mounted on the GC2 or GC-MS. Analysis was carried out as follows: first, the volatile compounds heart-cut after separation on the GC1 column were adsorbed onto the Porapak Q column out of the GC1 oven. This Porapak Q column was then coupled to the TCT, and the volatile compounds adsorbed on the Porapak Q were thermally desorbed, cold trapped, and injected onto an analytical column in the GC2 or GC-MS. Repeatability of the retention time (RT) and area % of model samples consisting of citronellol, decanol, and geranyl acetate was examined. Also, the volatile compounds present at very low concentrations in ethanol solution were concentrated on the Porapak Q column. These were injected onto the analytical column by the same method as described above, and the repeatability of the RT and area % on the chromatogram was examined. In the two experiments, the standard deviation of the RT and area % for each compound was about 0.02 and less than 2.85, respectively. A commercial geranium oil was successfully analyzed by this technique. The results indicate that this modified MDGC and MDGC-MS system are very useful for detection and determination of compounds in complex mixtures.     

Novel oxidation reaction of prochlorperazine with bromate in the presence of synergistic activators and its application to trace determination by flow injection/spectrophotometric method

Valve-based comprehensive two-dimensional gas chromatography (GC × GC) is one of the most compact, robust, and inexpensive GC × GC instrument designs. The major drawback of a valve-based modulation configuration lies in diminished detection sensitivity. This loss in sensitivity is because under typical operating conditions the fraction of the first column (i.e., column 1) effluent transferred to the second column (i.e., column 2) is likely to be ∼5-10%. To address this loss in sensitivity, we report the development of a unique total-transfer (i.e., 100%) valve-based GC × GC, without adding complexity to the instrumentation. The new instrument design relies upon simply blocking one of the appropriate ports of the high-speed six-port diaphragm valve that is used as the modulator between columns 1 and 2. The modulation period and difference in head pressure between columns 1 and 2 are found to be the two primary variables that are controlled to provide good detection sensitivity and 100% mass transfer from column 1 to column 2. The detection sensitivity is better with a longer the modulation period. A limit of detection of 0.03 ng/μl was obtained for octane. This sensitive GC × GC configuration is also shown to provide acceptable separation peak capacity, with good separations achieved for real complex samples: gasoline and Eucalyptus oil, where compounds were spread out over much of the two-dimensional separation space. In principle, this total-transfer, valve-based GC × GC is more portable and less expensive than currently available GC × GC instrumentation.     

Comprehensive two-dimensional gas chromatography using a high-temperature phosphonium ionic liquid column

A high-temperature ionic liquid, trihexyl(tetradecyl)phosphonium bis(trifluoromethane)sulfonamide, was used as the primary column stationary phase for comprehensive two-dimensional gas chromatography (GC × GC). The ionic liquid (IL) column was coupled to a 5% diphenyl/95% dimethyl polysiloxane (HP-5) secondary column. The retention characteristics of the IL column were compared to polyethylene glycol (DB-Wax) and 50% phenyl/50% methyl polysiloxane (HP-50+). A series of homologous compounds that included hydrocarbons, oxygenated organics, and halogenated alkanes were analyzed with each column combination. This comparison showed that the ionic liquid is less polar than DB-Wax but more polar than HP-50+. The most unique feature of the IL × HP-5 column combination is that alkanes, cyclic alkanes, and alkenes eluted in a narrow band in the GC × GC chromatogram; whereas, these compounds occupied a much larger portion of the DB-Wax × HP-5 and the HP-50+ × HP-5 chromatograms. Each column combination was used to analyze diesel fuel. The IL × HP-5 chromatogram displayed narrow bands for three major compound classes in diesel fuel: saturates, monoaromatics, and diaromatics. The IL column was used at temperatures as high as 290 °C for several months without any noticeable changes in column performance.     

Characterization and utilization of a novel triflate ionic liquid stationary phase for use in comprehensive two-dimensional gas chromatography

A novel triflate (trifluoromethylsulfonate) ionic liquid (IL) thin film (0.08 microm) stationary phase was implemented for use within the second column of a comprehensive GC x GC configuration. The first column in the configuration had a 5% phenyl/95% dimethyl polysiloxane (DMPS) stationary phase with a 0.4 microm film. The DMPS x IL column configuration was used to separate a mixture of 32 compounds of various chemical functional classes. The GC x GC results for the IL column were compared with a commercially available polar column (with a 0.1 microm PEG stationary phase film) used as the second column instead. Additional studies focused on the rapid and selective separation of four phosphorous-oxygen (P-O) containing compounds from the 32-compound matrix: dimethyl methylphosphonate (DMMP), diethyl methylphosphonate (DEMP), diisopropyl methylphosphonate (DIMP), and triethyl phosphate (TEP). van't Hoff plots (plots of ln k vs. 1/T) demonstrated the difference in retention between the P-O containing compounds (with DMMP reported in detail) and other classes of compounds (i. e., 2-pentanol and n-dodecane as representative) using either the IL column or the commercial PEG column. The selectivity (alpha) of the triflate IL column and the commercially available PEG column were also compared. The IL column provided significantly larger selectivities between DMMP and the other two compounds (2-pentanol and n-dodecane) than the commercial PEG column. The alpha for DMMP relative to n-dodecane was 3.0-fold greater for the triflate IL column, and the alpha for DMMP relative to 2-pentanol was 1.7-fold greater for the triflate IL column than for the PEG column.     

Application of comprehensive two-dimensional gas chromatography to drugs analysis in doping control

Comprehensive two-dimensional gas chromatography (GC×GC) now occupies a niche within the GC technology regime. The technique is undeniably unique in the manner in which the experiment is conducted, the way results are presented and the interpretive opportunities offered. For the 1000th volume of this journal it is appropriate to expand upon these features, and review the progress made in GC×GC to date. Firstly, brief general comment is made on multidimensional procedures, and to review key aspects of GC×GC. The use of the targeted multidimensional GC method allows absolute retentions in the second dimension of a GC×GC experiment to be estimated, and also offers a novel way to obtain enhanced response for resolved solutes. Then, to illustrate the utility of the technique, the application of GC×GC to the screening of drugs and their metabolites in biological fluids is described using prolintane metabolites in canine urine as an example, with samples taken at four time intervals after administration. This example illustrates the first application of GC×GC in the field of forensic toxicology, an area traditionally dominated by GC–MS. Most drug compounds were found to be retained on the 0.8-m second column for a greater time than the modulation period (3 s) used for initial analysis, under the conditions described. Hence a 0.4-m D2 BPX50 (50% phenyl methyl polysilphenylene) column was then used throughout, with most compounds retained less than 4 s. For the standard drug mixture, three overlapping drugs on the first dimension column (BPX5) were subsequently baseline resolved on the BPX50 column. For prolintane administration samples, the parent drug and metabolites could be effectively resolved from background matrix peaks. Likewise a 23-drug spike standard in horse urine blank gave acceptable resolution of the drugs from matrix peaks.     

在线高效液相色谱-毛细管气相色谱联用方法的建立

建立了一种以保留间隙柱技术和阀切换以及定量管样品转移为接口并具有早期溶剂蒸气出口的在线液相色谱与毛细管气相色谱联用方法。考察了主要实验条件,如溶剂蒸发温度、载气压力等对联机系统性能的影响,并用萘和联苯对该系统的线性范围进行了测定。利用联机系统对一种轻柴油样品进行了分析。     

Ultra-fast essential oil characterization by capillary GC on a 50 microm ID column

A 5 m x 50 microm capillary column with 0.05 microm stationary phase film thickness, with a calculated efficiency of almost 20,000 plates per metre (under optimum conditions), was used for very fasthigh resolution GC analysis of lime essential oil. The total analysis time of this volatile essential oil was less than 90 s. Fast GC is shown to be appropriate for essential oil quality assurance analysis, and quantitative results of key components are comparable with those obtained by using conventional GC analysis. The fast GC analysis is approximately 33 times faster than the conventional GC method.     

气相色谱法测定磷酸三甲苯酯异构体含量

建立测定磷酸三甲苯酯临、间、对位异构体含量的气相色谱方法。通过优化色谱分析条件,如降低初始柱箱温度和程序升温速度,可较好分离开TCP的10种同分异构体。选用弱极性的AB–5MS色谱柱,设置柱箱初始温度为120℃,升温速度为3℃/min,终温为300℃。使用相应的纯物质,对其中的临-临-临,间-间-间,对-对-对进行了定量分析。三种异构体在各自的线性范围内均呈良好的线性,线性相关系数大于0.999,检出限为0.162 7~0.168 8 mg/L,测定结果的相对标准偏差小于5%(n=6)。该方法检出限低,重现性好,适合于磷酸三甲苯酯异构体含量的检测。