基于中空纤维液相微萃取的麻黄碱和伪麻黄碱优势构象的确定及含量测定

利用中空纤维液相微萃取方法(HF-LPME)分析麻黄碱和伪麻黄碱在不同基质中的优势构象,阐明了麻黄碱和伪麻黄碱的萃取机理;结合高效液相色谱(HPLC)建立了微量麻黄碱和伪麻黄碱的分离测定方法。以聚偏氟乙烯中空纤维为有机溶剂载体,正己醇为萃取溶剂,麻黄碱和伪麻黄碱的NaOH(5 mol/L)溶液为样品相,0.01 mol/L H2SO4溶液为接收相,在1200 r/min转速下萃取35 min,收集萃取液直接进行HPLC分析。麻黄碱和伪麻黄碱在水溶液中的线性范围为5～100 μg/L,检出限分别为1.9 μg/L和1.2 μg/L,富集倍数分别为38和61倍,平均回收率分别为100.6%±1.2%和103.2%±3.5%;在鼠尿液中的线性范围为100～5×104 μg/L,检出限分别为30 μg/L和42 μg/L,富集倍数分别为20和17倍,平均回收率分别为108.4%±4.4%和106.1%±5.4%。研究表明该方法操作简单,选择性高,适用于微量麻黄碱的含量测定和分析。     

液-液-液微萃取-高效液相色谱法测定人血浆中的局部麻醉剂

建立了液-液-液微萃取与高效液相色谱联用技术同时测定人血浆中3种局部麻醉剂利多卡因、布比卡因和丁卡因的方法。考察了萃取时间、料液pH值和搅拌速度的影响,取佳萃取条件为萃取溶剂为200μL苯,接受相为1.0μL 0.2 mol/L HC l,搅拌速度为250 r/m in,萃取时间为45 m in。在该条件下,获得了高的富集因子(大于305倍)。方法的线性范围为:利多卡因和布比卡因0.025~5 mg/L,丁卡因0.05~5 mg/L,相关系数大于0.996;检出限依次为0.005、0.015和0.025 mg/L;相对标准偏差小于5%。该方法能有效地去除血浆中复杂基体的干扰,萃取效率高,有机溶剂消耗少,是一种有效、灵敏的同时测定血浆中利多卡因、布比卡因和丁卡因的方法。     

人尿液中麻黄碱和可待因的液-液-液微萃取/高效液相色谱法测定

建立了液-液-液微萃取与高效液相色谱联用技术快速分析尿样中麻黄碱和可待因的方法.优化得到的最佳萃取条件:萃取溶剂为80μL苯,接受相为1.0μL 0.2 mol·L-1的HCI,搅拌速率为80 r·min-1,萃取时间为40 min.在该条件下.获得了高的富集因子(大于117倍).方法的线性范围为麻黄碱0.05-10mg·L-1,可待因0.10-10 mg·L-1,相关系数(r)大于0.997,检出限分别为0.025 mg·L-1和0.05 mg·L-1,相对标准偏差小于9%.该方法能有效地去除尿样中的干扰物质,有机溶剂消耗少,萃取效率高,可同时测定尿样中麻黄碱和可待因.     

液-液-液三相液相微萃取-高效液相色谱法检测尿样中的安非他明和氯胺酮

建立了液-液-液三相液相微萃取与高效液相色谱联用技术测定尿样中的安非他明和氯胺酮的方法。考察了萃取溶剂、料液相pH值、搅拌速度、萃取时间和接受相HCl浓度等因素对富集因子的影响,得到了萃取溶剂为300 μL甲苯,料液相pH值为11,接受相为1.0 μL 0.1 mol/L HCl,搅拌速度为600 r/min,萃取时间为50 min的最佳实验条件。在该条件下,获得了较高的富集因子;方法的线性范围为安非他明0.01～10 μg/mL,氯胺酮0.01～5 μg/mL,相对标准偏差均小于2%,检测限均为5 ng/mL (S/N=3)。建立的三相液相微萃取方法能有效地去除复杂基体的干扰,有机溶剂消耗少,萃取效率高,是一种有效、灵敏的样品前处理方法,适合于尿样中安非他明和氯胺酮的测定。     

中空纤维碳纳米管/正辛醇固-液协同微萃取机理及其应用

讨论了以中空纤维为载体的碳纳米管/正辛醇固-液协同微萃取机理,建立了中空纤维碳纳米管/正辛醇固-液协同微萃取-高效液相色谱法同时测定复杂样品中微量咖啡酸、阿魏酸和肉桂酸含量的方法.以2.5 cm长的聚偏氟乙烯中空纤维为碳纳米管正辛醇分散液载体,供相为分析物的HCl(pH 2.1)溶液,接受相为pH 12.7的NaOH溶液,在35℃下,搅拌萃取60 min,萃取液进行高效液相色谱紫外检测.在优化的实验条件下,分析物的线性范围均在0.05～50 μg/L,r＞0.9990 (n=5);检出限均为0.015μg/L;日内与日间精密度均小于9.8％(n=9),平均回收率为93.8％～115.2％;富集倍数分别为514,942和1084倍.在以中空纤维为支持体的碳纳米管/正辛醇微萃取中,碳纳米管/正辛醇分散液嵌入中空纤维管壁上的微孔中形成了碳纳米管/正辛醇固-液微萃取单元束,对苯丙烯酸类化合物起到协同萃取作用.     

分散液液微萃取-反萃取-接受相固化-高效液相色谱法测定减肥茶中的西布曲明

建立了分散液液微萃取-反萃取-接受相固化与高效液相色谱联用测定减肥茶中西布曲明的方法。优化的条件为:400"L石油醚为萃取剂、120"L甲醇为分散剂、14"L 0.2 mol/L HCl溶液和1"L甲醇的混合溶液为接受相,萃取2 min。在优化条件下西布曲明的富集因子可达130倍。方法的线性范围为0.6～200"g/L,检测出限为0.2"g/L,定量限为0.6"g/L。样品加标回收率介于91.9%～108.4%,日间相对标准偏差小于14%。     

液-液-液微萃取/高效液相色谱法测定人血浆中的西地那非和伐地那非

建立了液-液-液微萃取与高效液相色谱联用同时测定血浆中西地那非和伐地那非的方法。考察了萃取溶剂、溶剂体积、接受相液滴大小、搅拌速度和萃取时间等因素对富集因子的影响,得到了萃取溶剂为300 μL 甲苯、接受相为2 μL 0.2 mol/L HCl、搅拌速度为600 r/min和萃取时间为40 min的最佳实验条件。在该条件下,获得了较高的富集因子。两种组分的线性范围均为5 μg/L~1.0 mg/L,加标回收率高于87%,其相对标准偏差小于5%。以信噪比为3计,西地那非的检测限为1 μg/L,伐地那非为0.5 μg/L。该方法能有效地去除复杂基体的干扰,有机溶剂消耗少,萃取效率高,是一种有效的、灵敏的样品前处理方法,适用于血浆中微量西地那非和伐地那非的测定。     

液相微萃取-离子色谱法测定污水中痕量芳香胺

基于中空纤维液相微萃取技术,建立了河流污水中两种芳香胺类物质（邻甲苯胺和对氯苯胺）的离子色谱分析方法。采用中空纤维液相微萃取和离子色谱联用技术,对中空纤维萃取条件进行优化。优化的萃取条件：萃取溶剂为正辛醇,供体相中NaOH的浓度为0.01mol/L, NaCl的浓度为500g/L,接受相中HCl的浓度为0.1 mol/L,搅拌速度为430r/min,萃取时间为30min,在优化条件下,邻甲苯胺的富集倍数为88倍,对氯苯胺的富集倍数为124倍。供体相中邻甲苯胺和对氯苯胺的浓度在0.005–0.1mg/L范围内成良好线性,相关系数为0.9998-0.9999 ,检出限为0.2-0.5μg /L,相对标准偏差为0.85-3.38 %。结论：这种方法操作简单,环境友好,提高了离子色谱检测芳香胺类物质的灵敏度。     

三相中空纤维液相微萃取/超高效液相色谱-串联质谱法检测饮品中的苯甲酸与山梨酸

将三相中空纤维液相微萃取(HF-LPME)和超高效液相色谱与串联质谱技术(UPLC-MS/MS)相结合检测饮品中的苯甲酸和山梨酸。通过优化选定三相中空纤维液相微萃取的最佳萃取条件:正辛醇为萃取剂,给出相的pH值为2.7,接收相的pH值为13.6,转速1 000 r/min,萃取时间30 min,以一步完成萃取、净化、富集过程,并用Waters ACQUITYTMUPLC BEH C18(50 mm×2.1 mm,1.7μm)色谱柱进行分离,流速0.25 mL/min,流动相为甲醇和10 mmol/L乙酸铵溶液,梯度洗脱,电喷雾负模式(ESI-)电离和多反应监测(MRM)模式检测,外标法定量。该方法在0.05～5.0 mg/L范围内具有良好的线性关系,r均大于0.997,苯甲酸和山梨酸的检出限(S/N=3)分别为0.005、0.01 mg/L,定量下限(S/N=10)分别为0.01、0.02 mg/L,在0.1、1.0、4.0 mg/L加标水平下的回收率为91%～103%,相对标准偏差小于6.0%。将该方法运用于实际样品的检测,方法准确、快速、灵敏、绿色环保,适于复杂基质饮品中苯甲酸和山梨酸的检测。     

水中酚类化合物的液-液-液微萃取/ 高效液相色谱联用分析研究

建立了液-液-液微萃取/高效液相色谱联用(LLLME/HPLC)测定环境水中痕量酚类化合物2-甲基苯酚、2-硝基苯酚、2,4-二氯苯酚的分析方法,研究了有机相溶剂种类及其体积、料液相pH值与离子强度、接受相的体积、组成及浓度和搅拌速率、萃取时间等因素对分析物萃取效率的影响。实验结果表明,该方法对酚类化合物的富集倍数可达到404~747倍,方法的线性范围为0.2~300μg/L,RSD(n=6)为6.8%~11.4%。测定加标自来水、江水以及生活污水样品的回收率为83%~110%。     

Comparison of conventional hollow fiber based liquid phase microextraction and electromembrane extraction efficiencies for the extraction of ephedrine from biological fluids

In the present study, hollow fiber liquid phase microextraction (HF-LPME) based on pH gradient and electromembrane extraction (EME) coupled with high-performance liquid chromatography (HPLC) was compared for the extraction of ephedrine from biological samples. The influences of fundamental parameters affecting the extraction efficiency of ephedrine were studied and optimized for both methods. Under the optimized conditions, preconcentration factors of 120 and 35 for urine and 51 and 8 for human plasma were obtained using EME and HF-LPME, respectively. The calibration curves showed good linearity for urine and plasma samples by both methods with the coefficient of estimations higher than 0.98. The limits of detection were obtained 5 and 10 ng mL(-1) using EME and 60 and 200 ng mL(-1) by HF-LPME for urine and plasma samples respectively. The relative standard deviations of the analysis were found in the range of 5.2-8.6% (n=3). The results showed that in comparison with HF-LPME based on pH gradient, EME is a much more effective transport process, providing high extraction efficiencies in very short time.     

Automated polyvinylidene difluoride hollow fiber liquid-phase microextraction of flunitrazepam in plasma and urine samples for gas chromatography/tandem mass spectrometry

A new polyvinylidene difluoride (PVDF) hollow fiber (200 μm wall thickness, 1.2 mm internal diameter, 0.2 μm pore size) was compared with two other polypropylene (PP) hollow fibers (200, 300 μm wall thickness, 1.2 mm internal diameter, 0.2 μm pore size) in the automated hollow fiber liquid-phase microextraction (HF-LPME) of flunitrazepam (FLNZ) in biological samples. With higher porosity and better solvent compatibility, the PVDF hollow fiber showed advantages with faster extraction efficiency and operational accuracy. Parameters of the CTC autosampler program for HF-LPME in plasma and urine samples were carefully investigated to ensure accuracy and reproducibility. Several parameters influencing the efficiency of HF-LPME of FLNZ in plasma and urine samples were optimized, including type of porous hollow fiber, organic solvent, agitation rate, extraction time, salt concentration, organic modifier, and pH. Under optimal conditions, extraction recoveries of FLNZ in plasma and urine samples were 6.5% and 83.5%, respectively, corresponding to the enrichment factor of 13 in plasma matrix and 167 in urine matrix. Excellent sample clean-up was observed and good linearities (r² = 0.9979 for plasma sample and 0.9995 for urine sample) were obtained in the range of 0.1–1000 ng/mL (plasma sample) and 0.01–1000 ng/mL (urine sample). The limits of detection (S/N = 3) were 0.025 ng/mL in plasma matrix and 0.001 ng/mL in urine matrix by gas chromatography/mass spectrometry/mass spectrometry.     

中空纤维液相微萃取-高效液相色谱法测定纺织品中10种含氯苯酚类化合物

建立了中空纤维液相微萃取-高效液相色谱法测定纺织品中10种含氯苯酚类化合物的方法。系统地优化了影响萃取效率的因素,得到的最佳萃取条件为：萃取溶剂为正己烷,接受相NaOH溶液的浓度为0.10 mol/L,萃取时间为60 min,搅拌速度为600 r/min。在最佳萃取条件下,10种含氯苯酚在0.01～1.00 mg/L范围内线性关系良好（r>0.999）,10种含氯苯酚的检出限（信噪比为3）为0.01 mg/kg,富集倍数为95～101。在空白样品中添加0.01、0.05和0.1 mg/kg 3个不同水平的10种含氯苯酚类化合物,其平均回收率为78.8%～105.1%,相对标准偏差为0.3%～7.3%。研究结果表明该方法灵敏度高、简便、准确,可用于纺织品中含氯苯酚类化合物的测定。     

Analysis of PBDEs in soil,dust, spiked lake water,and human serum samples by hollow fiber-liquid phase microextraction combined with GC-ICP-MS

A novel method for the analysis of four polybrominated diphenyl ethers (PBDEs) in environmental and human serum samples based on hollow fiber-liquid phase microextraction (HF-LPME) followed by gas chromatography-inductively coupled plasma mass spectrometric (GC-ICP-MS) detection has been developed. The organic solvent in the porous hollow fiber was first dipped into the sample for extraction at a given time, and the retracted organic phase was introduced into the GC-ICP-MS for analysis. The addition of methanol has a strong effect on the HF-LPME extraction efficiency. Other significant parameters affecting the extraction efficiency of HF-LPME were also studied. HF-LPME was effective to isolate the analytes from the complex matrix. Under the optimized conditions, the detection limits of the proposed method varied from 15.2 to 40.5 ng/L. In general, the relative standard deviations (RSDs) were less than 10%. Good linearity was obtained with the correlation coefficients all better than 0.999. The proposed method is simple, quick, few microliters of organic solvent required, and is especially suitable for the analysis of the real sample with small amount available. The overall process of HF-LPME with GC-ICP-MS was applied successfully for the determination of polybrominated diphenyl ethers (PBDEs) in environmental and spiked human serum samples, and the results were satisfactory.     

水和生物体液中曲马多镇痛药的中空纤维膜液相微萃取

使用中空纤维膜液相微萃取技术(LPME-HFM)建立了从水和生物样品(尿和血浆)中提取曲马多的方法。在室温(20 ℃)下用聚偏氟乙烯中空纤维膜过滤提取样品。萃取过程中用4 μL甲苯作为萃取溶剂。用度冷丁作为内标,气相色谱法-氢火焰离子化检测器分析测定,最低检测限达0.01 mg/L(自来水、尿)或0.05 mg/L(血浆)。和传统的液液萃取方法相比,该方法集萃取和浓缩一步完成,更简便、快速、绿色环保。     

Electrospray ionization-ion mobility spectrometry as a detection system for three-phase hollow fiber microextraction technique and simultaneous determination of trimipramine and desipramine in urine and plasma samples

A novel method based on three-phase hollow fiber microextraction technique (HF-LPME) coupled with electrospray ionization-ion mobility spectrometry (ESI-IMS) was developed for the simultaneous determination of two antidepressant drugs (trimipramine and desipramine) in urine and plasma samples. The effects of various parameters such as type of organic solvent, composition of donor and acceptor phase, stirring rate, salt addition, extraction time, and temperature were investigated. Under the optimized conditions, the relative standard deviation was in the range of 5–6%, and the method quantitation limit (MQL) of utilizing HF-LPME/ESI-IMS was 5 μg/L for both drugs. The relative recoveries obtained by the proposed method from urine and plasma samples were in the range 94% to 97% for trimipramine and 92% to 96% for desipramine. Finally, the feasibility of the proposed method was successfully confirmed by extraction and determination of trace amounts of trimipramine and desipramine in biological samples without any significant matrix effect.     

中空纤维三相液相微萃取-薄层色谱分离同步荧光法测定酱油中的色胺含量

以三相中空纤维液相微萃取(HF-LPME)作为样品前处理方法,结合薄层色谱分离,同步荧光光谱法测定酱油中色胺的含量。通过单因素实验确立的萃取最优条件为:样品溶液p H值为12.0,正辛醇为萃取溶剂,0.1 mol/L的HCl为接受相,搅拌速度为590 r/min,萃取时间为60 min;取20μL接受相进行TLC分析,样品点用异丙醇溶解后离心分离;采用同步荧光在λem=350.4 nm处进行定量分析。在最佳萃取条件下,方法的线性范围为0.32~50 mg/L(r0.978 0),检出限(S/N=3)为0.32 mg/L。酱油样品的加标回收率为87.5%~107.7%,相对标准偏差(RSD)不大于6.6%。该方法操作简单、绿色高效、灵敏度高,可用于酱油中色胺的快速准确测定。     

On‐line extraction and determination of two herbicides: Comparison between two modes of three‐phase hollow fiber microextraction

Two different modes of three‐phase hollow fiber liquid‐phase microextraction were studied for the extraction of two herbicides, bensulfuron‐methyl and linuron. In these two modes, the acceptor phases in the lumen of the hollow fiber were aqueous and organic solvents. The extraction and determination were performed using an automated hollow fiber microextraction instrument followed by high‐performance liquid chromatography. For both three‐phase hollow fiber liquid‐phase microextraction modes, the effect of the main parameters on the extraction efficiency were investigated and optimized by central composite design. Under optimal conditions, both modes showed good linearity and repeatability, but the three‐phase hollow fiber liquid‐phase microextraction based on two immiscible organic solvents has a better extraction efficiency and figures of merit. The calibration curves for three‐phase hollow fiber liquid‐phase microextraction with an organic acceptor phase were linear in the range of 0.3–200 and 0.1–150 μg/L and the limits of detection were 0.1 and 0.06 μg/L for bensulfuron‐methyl and linuron, respectively. For the conventional three‐phase hollow fiber liquid‐phase microextraction, the calibration curves were linear in the range of 3.0–250 and 15–400 μg/L and LODs were 1.0 and 5.0 μg/L for bensulfuron‐methyl and linuron, respectively. The real sample analysis was carried out by three‐phase hollow fiber liquid phase microextraction based on two immiscible organic solvents because of its more favorable characteristics.     

Monolithic molecular imprinted polymer fiber for recognition and solid phase microextraction of ephedrine and pseudoephedrine in biological samples prior to capillary electrophoresis analysis

A novel capillary electrophoresis (CE) method coupled with monolithic molecular imprinted polymer (MIP) fiber based solid phase microextraction (SPME) was developed for selective and sensitive determination of ephedrine (E) and pseudoephedrine (PE). With in situ polymerization in a silica capillary mold and E as template, the MIP fibers could be produced in batch reproducibly and each fiber was available for 50 extraction cycles without significant decrease in extraction ability. Using the MIP fiber under optimized extraction conditions, CE detection limits of E and PE were greatly lowered from 0.20 to 0.00096 μg/mL and 0.12 to 0.0011 μg/mL, respectively. Analysis of urine and serum samples by the MIP-SPME-CE method was also performed, with results indicating that E and PE could be selectively extracted. The recoveries and relative standard deviations (RSDs) for sample analysis were found in the range of 91–104% and 3.8–9.1%, respectively.