微滴液相微萃取技术用于气相色谱-质谱法测定食品中的酞酸酯

将一种新型、简单、快速、环境友好的萃取方法微滴液相微萃取(SDME)与气相色谱-质谱法结合用于快速分析食品中的几种酞酸酯(PAEs)。考察了萃取溶剂的种类及用量、微液滴在样品溶液中的深度、萃取时间及搅拌子的搅拌速度对微滴液相微萃取的影响。优化的萃取条件为:萃取溶剂为2.0 μL甲苯,微液滴在样品溶液中的深度为0.75 cm,搅拌速度为1000 r/min,萃取时间为20 min。该方法的线性范围为0.1～4000 μg/L,检测限为25 ng/L～0.8 mg/L,加标回收率为87.1%～114.4%,相对标准偏差为4.9%～11.6%。微滴液相微萃取所需的有机溶剂量很小,是一种快速、简单、安全、有效的水溶性样品的前处理方法。     

液相微萃取-气相色谱/质谱测定水中硝基苯类化合物

建立了水中硝基苯类化合物(硝基苯、1-硝基甲苯、2-硝基甲苯、3-硝基甲苯和邻氯硝基苯)的液相微萃取-气相色谱/质谱检测方法。实验结果显示:甲苯为最佳的萃取剂。确定最佳实验条件为:甲苯体积2μL,萃取时间15 min,搅拌速度300 r/min,萃取温度45℃,溶液pH=5。在此条件下,各目标物的萃取富集倍数为30~38,线性范围为2~250μg/L,检出限为1~2μg/L,测定的相对标准偏差为5%~7%。     

圆盘膜萃取-气相色谱-质谱法同时测定水中16种酞酸酯类化合物

提出了气相色谱-质谱法同时测定水中16种酞酸酯类化合物(PAEs)的方法。采用自制圆盘萃取装置、无塑料制品接触试验程序进行水样富集,对圆盘膜片选择、过膜压力、洗脱剂种类与用量等进行考察;对仪器工作条件离子源温度、升温速率、进样口温度和不同时间段监测离子及增益等进行了探讨。16种PAEs的质量浓度分别在一定的范围内与峰面积呈线性关系,检出限(3S/N)在0.17～2.45μg.L-1之间。以空白蒸馏水为基底,在3个浓度水平下做加标回收试验,回收率在79.8%～104%之间,相对标准偏差(n=6)在1.1%～9.4%之间。     

分散液相微萃取气相色谱/气相色谱质谱法测定白洋淀水中多溴联苯醚

建立了分散液相微萃取(DLLME)与气相色谱-微池电子捕获检测器(GC-μECD)、气相色谱-质谱(GC/MS)联用快速测定水样中42种多溴联苯醚(PBDEs)的新方法。以氯苯(25μL)为萃取剂,乙腈(1.0mL)为分散剂,混匀后注入5.00mL水样中,以3000r/min离心15min,取出下层有机相氮气吹干、定容后取1μL进样分析。在最佳条件下,PBDEs能够被充分提取和良好分离,在2.0～250.0μg/L浓度范围内呈现良好的线性关系,线性相关系数为0.9982～0.9999;检出限为0.2～4.9μg/L(S/N=3)。将本方法应用于白洋淀水中PBDEs的分析检测,样品中均有BDE-166和BDE-209的检出,对水样进行两个浓度水平(0.017和0.170μg/L)的加标实验,回收率为71.4%～110.8%,相对标准偏差为0.99%～11.84%(n=3),能够满足环境水样中痕量PBDEs的测定要求。     

中空纤维膜液相微萃取-气相色谱质谱法测定水中的百菌清

研究了用中空纤维膜液相微萃取-气相色谱质谱法测定水中的百菌清。通过实验确定最佳萃取条件为:萃取剂为甲苯,萃取剂用量3μL,水样体积10mL,萃取温度为45℃,萃取时间为15 min,搅拌速率为500 r/min,萃取后取1μL有机溶剂直接进样进行气相色谱质谱分离检测。在此条件下,百菌清的富集倍数为450倍,方法的线性范围为5~600μg/L,检出限为0.5μg/L。测定实际水样的加标回收率在92.3%~96.0%之间。该方法可以用于水中百菌清的快速检测。     

微滴液相微萃取技术用于气相色谱-质谱法分析药品中的酞酸酯和对羟基苯甲酸酯

用微滴液相微萃取(SDME)与气相色谱-离子阱质谱联用测定药品中的酞酸酯和对羟基苯甲酸酯。考察了萃取溶剂的种类及用量、微液滴在样品溶液中的深度、萃取时间及搅拌子的搅拌速度对微滴液相微萃取效果的影响。优化的萃取条件:萃取溶剂为1.5 μL甲苯,微液滴在样品溶液中的深度为0.8 cm,搅拌子的搅拌速度为1000 r/min,萃取时间为20 min。该方法的线性范围为0.032~80 mg/L,检出限为0.6 μg/L~1.28 mg/L,加标回收率为95.85%~148.85%,相对标准偏差为3.9%~14.9%。     

分散液相微萃取-气相色谱/质谱快速分析水中的硝基苯类化合物

建立了分散液相微萃取.气相色谱,质谱快速分析水中硝基苯、对硝基苯、1,3一二硝基苯和2,4-二硝基氯苯的新方法.将含有18μL氯苯(萃取荆)的0.25 mL丙酮(分散剂)作为萃取体系,快速注入到5.0 mL水溶液中.在4000r/min下离心2.0 min后,得到(10.0±0.5)μL沉积相(氯苯),取底部沉积相1.0μL进行气相色谱,质谱分析.方法线性范围0.5～50μg/L(r2=0.9986～0.9994),检出限0.2～0.5μg/L,相对标准偏差4.2%～7.3%(n=5).将该方法用于环境水样的测定,加标回收率72.9%～89.6%.     

中空纤维液相微萃取-气相色谱/质谱联用检测水中的氯化苄

建立了一种以中空纤维液相微萃取(HF-LPME)前处理样品,利用气相色谱/质谱(GC/MS)对水中痕量氯化苄进行检测的方法。优化的实验条件为:3.0μL甲苯为萃取溶剂,在中等搅拌速率下室温萃取15 min。方法的线性范围为1~100μg/L,线性相关系数r=0.9995;检出限为0.5μg/L(S/N=3);相对标准偏差为5.37%(n=5)。用于水库水和被污染河水的测定,加标回收率分别为95.7%和93.6%,结果满意。     

固相膜萃取-超声解吸-气相色谱-质谱法分析水中酞酸酯类化合物

酞酸酯(PAEs)是一种常用的增塑剂,由于其广泛应用已经对环境造成了污染.本研究建立了固相膜萃取-超声解吸-气相色谱-质谱分析水中酞酸酯类化合物的方法.对萃取条件、解吸条件进行了优化,确定了最佳的实验条件.在水浴温度40℃,超声功率50%的条件下超声7 min,测定水中PAEs的检出限(S/N>3)在0.05 ~0.26 μg/L之间;对不同基质空白样品进行加标回收实验,回收率在76.2%~112.3%之间,相对标准偏差小于10%.     

固相微萃取气相色谱法(SPME-GC)测定水体中邻苯二甲酸酯

选用85μm PA纤维,考证了萃取温度、萃取时间、搅拌、离子强度及解析时间等影响因素,最后确立了65℃萃取温度、60min萃取时间、稳定的磁力搅拌、5min解析时间、用带电子捕获检测器的毛细管气相色谱（CGC—ECD）分离测定、外标标准曲线法定量分析水体中邻苯二甲酸酯（PAEs）的方法。该方法具有较好的精密度（RSD≤16％）和较低的检出限（DLDBP=0．003μg/L,DLDEDEHP=0．05μg/L）,水样加标回收率在70％～130％之间。用该法测定了长江水样、太湖水样、自来水及蒸馏水的PAEs含量,DBP在0．1～0．4μg/L,DEHP在0．2～1．2μg/L,DMP、DEP、DOP均未检测到。     

Determination of substituted benzenes in water samples by fiber-in-tube liquid phase microextraction coupled with gas chromatography

A method for determination of toluene, ethylbenzene, p-xylene, o-xylene, 1,3,5-trimethylbenzene and 1,2,4-trimethylbenzene in water samples was developed by a fiber-in-tube liquid phase microextraction technique (fiber-in-tube LPME) coupled with GC-flame ionization detector (FID). The method used a tube packed with polytetrafluoroethylene (PTFE) fibers as an extraction medium, improving the stableness of the solvent and the performance of extraction. Certain amounts of curled PTFE fibers were packed into a section of PTFE tube. Because the fibers were curled, they formed network structure in the tube. The fiber packed tube was firstly immersed into organic solvent to be filled with organic solvent and then was exposing to an aqueous solution to extract the target compounds. The extract was then retracted by a conventional GC microsyringe and analyzed by GC-FID. Extraction of the analytes in 8 ml aqueous solution for 15 min yielded enrichment factors of 224-361. The precision (R.S.D., n = 5) was 3.6-8.1% for peak area. The limit of detection (LOD, S/N = 3) for the six substituted benzenes were in the range of 0.3-5.0 μg l⁻¹.     

SPME-GC联用测定环境水样中的酚类化合物

建立了固相微萃取与气相色谱联用技术测定环境水样中酚类化合物的方法. 探讨了pH、离子强度、萃取头类型、萃取时间以及解析时间等条件对酚类化合物萃取量的影响, 优化了GC仪器条件. 在优化的条件下, 酚类化合物的响应值与浓度有良好的线性关系, 线性范围为0.20～200 μg/L, 检出限在0.019～0.10 μg/L之间, 相对标准偏差(RSD, n=5)为4.4%～11%, 水样平均加标回收率为92.2%～101.9%, 所建立的方法可测定环境水样中的酚类化合物.     

Determination of diphenylether herbicides in water samples by solid-phase microextraction coupled to liquid chromatography

Solid-phase microextraction (SPME) coupled to LC for the analysis of five diphenylether herbicides (aclonifen, bifenox, fluoroglycofen-ethyl, oxyfluorfen, and lactofen) is described. Various parameters of extraction of analytes onto the fiber (such as type of fiber, extraction time and temperature, pH, impact of salt and organic solute) and desorption from the fiber in the desorption chamber prior to separation (such as type and composition of desorption solvent, desorption mode, soaking time, and flush-out time) were studied and optimized. Four commercially available SPME fibers were studied. PDMS/divinylbenzene (PDMS/DVB, 60 microm) and carbowax/ templated resin (CW/TPR, 50 microm) fibers were selected due to better extraction efficiencies. Repeatability (RSD, < 7%), correlation coefficient (> 0.994), and detection limit (0.33-1.74 and 0.22-1.94 ng/mL, respectively, for PDMS/DVB and CW/TPR) were investigated. Relative recovery (81-104% for PDMS/DVB and 83-100% for CW/TPR fiber) values have also been calculated. The developed method was successfully applied to the analysis of river water and water collected from a vegetable garden.     

管内固相微萃取-气相色谱法联用在线测定水中有机物

将管内固相微萃取与气相色谱法结合，建立了水中痕量有机物的在线分析装置。采用毛细管气相色谱柱作为萃取柱，水样中的分析物在萃取柱中被萃取浓缩，溶剂解吸后的样品通过阀切换和柱内进样技术直接由载气携带进入气相色谱柱。采用OV-1萃取柱，对水样中的5种芳烃的富集倍数为34～85。     

Determination of aliphatic amines in water by gas chromatography using headspace solvent microextraction

The possibility of applying headspace microextraction into a single drop for the determination of amines in aqueous solutions is demonstrated. A 1 μl drop of benzyl alcohol containing 2-butanone as an internal standard was suspended from the tip of a micro syringe needle over the headspace of stirred sample solutions for extraction. The drop was then injected directly into a GC. The total chromatographic determination was less than 10 min. Optimization of experimental conditions (sampling time, sampling temperature, stirring rate, ionic strength of the solution, concentration of reagents, time of extraction and organic drop volume) with respect to the extraction efficiency were investigated and the linear range and the precision were also examined. Calibration curves yielded good linearity and concentrations down to 2.5 ng ml⁻¹ were detectable with R.S.D. values ranging from 6.0 to 12.0%. Finally, the method was successfully applied to the extraction and determination of amines in tap and river water samples. This system represents an inexpensive, fast, simple and precise sample cleanup and preconcentration method for the determination of volatile organic compounds at trace levels.     

Determination of phthalic acid esters in Chinese white spirit using dispersive liquid–liquid microextraction coupled with sweeping β‐cyclodextrin‐modified micellar electrokinetic chromatography

A simple method that consumes low organic solvent is proposed for the analysis of phthalic acid esters in Chinese white spirit using dispersive liquid–liquid microextraction coupled with sweeping‐micellar electrokinetic chromatography. Tetrachloromethane and white‐spirit‐containing ethanol were used as the extraction and dispersing solvents, respectively. The electrophoresis separation buffer was composed of 5 mM β‐cyclodextrin, 50 mM sodium dodecyl sulfate and 25 mM borate buffer (pH 9.2) with 9% acetonitrile, enabling the baseline resolution of the analytes within 13 min. Under the optimum conditions, satisfactory linearities (5–1000 ng/mL, r ≥ 0.9909), good reproducibility (RSD ≤ 6.7% for peak area, and RSD ≤ 2.8% for migration time), low detection limits (0.4–0.8 ng/mL) and acceptable recovery rates (89.6–105.7%) were obtained. The proposed method was successfully applied to 22 Chinese white spirits, and the content of dibutyl phthalate in 55% of the samples exceeded the Specific Migration Limit of 0.3 mg/kg established by the domestic and international regulations.     

Identification of 19 phthalic acid esters in dairy products by gas chromatography with mass spectrometry

A detection method for 19 kinds of phthalic acid ester compounds analyzed by n‐hexane/ether/acetonitrile 1:7:8 v/v/v mixed solvent extraction, quick, easy, cheap, effective, rugged, and safe purification and internal standard method of quantitative gas chromatography with mass spectrometry was established. This method can effectively remove interfering materials, such as lipids, fatty acids, and pigments, from dairy products. The 19 kinds of phthalic acid ester compounds were within a 0.025–0.2 mg/kg range, the recovery rate was 65.2–125.7%, relative standard deviation was 7.9–15.4% (n = 6), and the limit of detection was 0.005–0.02 mg/kg. Concentrations of the 19 kinds of phthalic acid ester compounds ranged between 0.01 and 0.12 mg/kg in ten dairy materials and 20 dairy products. The established method is simple, rapid, accurate, and highly sensitive.     

Rapid analysis of phthalic acid esters in environmental water using fast elution gas chromatography with mass spectrometry and adaptive library spectra

A method for the fast determination of the components in a complex sample by using gas chromatography with mass spectrometry was developed and used for the quantitative analysis of phthalic acid esters in environmental water. In the method, the adaptively corrected mass spectra were used to compensate for the differences between the library spectra and the measured ones in the experiment. The correction was obtained by the iterative transformation of the library spectra using iterative target transformation factor analysis, and the resolution was performed by non‐negative immune algorithm using the corrected spectra. Rapid analysis of 16 phthalic acid esters in water samples was achieved using fast elution gas chromatography with mass spectrometry measurements. The results show that the mass spectra and chromatographic profiles of the phthalic acid esters can be obtained from the overlapping signal of 13 min elution, and accurate quantitative analysis can be obtained. The recoveries of the phthalic acid esters obtained by standard addition are between 90.3 and 107.4%, and the relative standard deviations obtained in repeated measurements are less than 9%.     

固相微萃取-气相色谱法测定白洋淀水样中的邻苯二甲酸酯类化合物

建立了固相微萃取(SPME)-气相色谱法(GC)分析环境水样中痕量邻苯二甲酸酯类化合物(PAEs)的方法。选用100 μm聚二甲基硅烷(PDMS)萃取纤维,在磁力搅拌条件下,对水样中的PAEs萃取富集60 min,然后直接注入GC进样口,在250 ℃温度下解吸4 min后进行分析测定,13种PAEs能得到充分提取和分离。方法的重现性(以相对标准偏差(RSD)计为0.2%～9.7%,检出限为0.02～0.83 μg/L。将本方法应用于白洋淀水样中PAEs的分析检测发现,样品中邻苯二甲酸二异丁酯(DIBP)、邻苯二甲酸二丁酯(DBP)、邻苯二甲酸二(2-乙基己基)酯(DEHP)检出率相对较高。对水样进行两个浓度水平(2.5 μg/L和5.0 μg/L)的加标试验,加标回收率为75.3%～111.0%,RSD为2.1%～8.0%(n=3),能够满足环境水样中痕量PAEs的测定要求。