离子液体在毛细管电泳中的应用

离子液体是在室温下或接近于室温下呈液态的物质.基于离子液体独特的物理化学性质,在毛细管电泳中应用最多.综述了近年来离子液体在毛细管电泳中应用的研究进展(引用文献43篇).     

离子液体单滴微萃取-高效液相色谱法测定水体中磺胺类药物

应用离子液体单滴微萃取(SDME)技术,建立了水体中7种磺胺类药物的高效液相色谱(HPLC)分析方法.考察了萃取剂种类与体积、萃取时间、搅拌速度、溶液pH值、盐浓度及萃取温度对萃取效率的影响.确定了最佳萃取条件为:利用9 μL-丁基-3-甲基咪唑六氟磷酸盐([C<,4MIM][PF<,6])离子液体作为萃取液滴,在搅拌...     

元胡中延胡索乙素的离子液体-毛细管电泳法测定

建立了以离子液体为电解质,测定元胡药材中延胡索乙素含量的毛细管电泳新方法.探讨了离子液体浓度、pH值、分离电压对分离效果的影响以及分离的机理.在以石英毛细管为分离柱,50 mmol/L 1-丁基-3-甲基咪唑四氟硼酸盐(pH 7.1)为电泳介质,分离电压20 kV的条件下,延胡索乙素可与其它组分在5 min内完全分离.延胡索乙素的线性范围为31.25 ～500 mg/L,检出限为4.86 mg/L,回收率为95% ～102%.     

毛细管电泳法表征离子液体与蛋白质的相互作用

基于毛细管区带电泳考察了不同离子液体的阳离子母核、烷基侧链碳原子数目和阴离子组成对牛血清白蛋白的影响,以及离子液体[C4mim]BF4与肌红蛋白、牛血清白蛋白、血红蛋白、牛凝血酶和转铁蛋白之间的相互作用。利用亲和毛细管电泳法比较了[C4mim]BF4与上述蛋白之间的相互作用,并计算得到结合常数Kb分别为1.24×107 L/mol,1.23×106 L/mol,5.75×104 L/mol和5.60×104 L/mol。结果表明,转铁蛋白、血红蛋白、肌红蛋白、牛血清白蛋白与离子液体的相互作用依次减弱,存在1～2个数量级的差异。结合毛细管区带电泳和亲和毛细管电泳模式可实现离子液体与多种蛋白质相互作用的定性与定量表征。     

双浊点萃取-毛细管电泳法测定天然水中酚类化合物的研究

建立了双浊点萃取(dCPE)-毛细管电泳(CE)法测定天然水中酚类化合物的新方法。以Triton X-114为萃取剂,NaOH为反萃取剂,对苯酚、2,4,6-三氯苯酚和邻硝基苯酚进行双浊点萃取。考察了pH值、萃取剂浓度、平衡温度及时间和离子强度等因素对萃取率的影响。dCPE方法的优化条件为:pH=2.0、Triton X-114的浓度为0.14%(m/V)、平衡温度为40℃、平衡时间为10min、NaCl浓度为4.0%(m/V);电泳条件为:10mmol/L硼砂-磷酸钠缓冲溶液(pH=9.8)、电压18kV、检测波长210nm。在最优的条件下,苯酚、2,4,6-三氯苯酚、邻硝基苯酚的检出限(S/N=3)分别为0.10、0.15和0.18μg/mL;富集因子分别为24.0、19.3和20.1;相对标准偏差(RSD)分别为3.9%、2.6%和3.3%(c=2.0μg/mL,n=3)。     

手性离子液体在毛细管电泳手性分离中的应用

简要介绍了手性离子液体用于毛细管电泳手性分离的一般原理,系统地介绍了基于手性离子液体的毛细管电泳对映体拆分的一元手性选择体系和二元手性选择体系,并在国内外研究现状的基础上展望了手性离子液体在毛细管电泳手性分离中的应用前景。     

基于非手性离子液体的毛细管电泳法拆分3种手性药物

建立了以非手性离子液体1-正丁基-3-甲基咪唑氯(［BMIM］Cl)为手性分离的添加剂、β-环糊精作为手性选择剂的毛细管区带电泳(CZE)分离扑尔敏、氯霉素前体和氧氟沙星3种对映体的方法,并与未添加［BMIM］Cl的CZE分离情况进行了对比研究。发现［BMIM］Cl对手性药物的拆分有协同作用,不仅能够增加对映体的分离度,还能有效地抑制毛细管内壁对样品分子的吸附作用,改善峰形。采用离子液体辅助手性选择剂(尤其是环糊精)的CZE改进方法,为其他毛细管电泳难以分离的手性药物的分离分析提供了新的方法。     

在线多通道拉曼光谱检测系统的建立及毛细管电泳的联用

利用氩离子激光器和ICCD自组装了毛细管电泳－激光拉曼光谱联用分析系统,用已知拉曼谱图的苯和甲苯对系统进行调试,详细讨论了光路系统对灵敏度的影响,用甲基橙和甲基红混合体系进行拉曼－毛细管电泳联用的实验研究,得到了较好的甲基橙和甲基红的在线电泳－时间分辨激光拉曼谱图。     

液相微萃取-毛细管电泳联用对汗液基质中4种芳香胺的同时测定

采用纤维膜三相液相微萃取(HF-LLLME)技术,对汗液基质中的苯胺、邻甲苯胺、对氯苯胺、对硝基苯胺进行了分离富集。以正辛醇为有机相,在供体相pH为9.0,NaCl质量浓度为200g/L,接收相pH为1.0,萃取时间为60min的条件下,4种芳香胺的富集倍数为410～1250倍。将接收相直接进行毛细管电泳(CE)测定,样品相中4种芳香胺的质量浓度在10～100μg/L范围内与电泳峰面积呈良好线性,相关系数均大于0.992,4种芳香胺的检出限为1～10μg/L。运用该法对偶氮染料汗液环境下光致降解过程中产生的苯胺进行测定,回收率为91%～93%,结果满意。     

集成化液膜萃取-反萃取-毛细管电泳联用芯片

我们设计并制作了集成有支持液膜萃取-反萃取试样预处理的毛细管电泳(SLMEBE-CCE)微流控芯片. 分别以荧光素钠和丁基罗丹明B作为模型待测物和共存物, 在该芯片上进行了在线试样预处理与毛细管电泳联用的初步实验.     

On-line coupling of ionic liquid-based single-drop microextraction with capillary electrophoresis for sensitive detection of phenols

An ionic liquid-based single-drop microextraction (IL-SDME) procedure using IL as an extractant on-line coupled to capillary electrophoresis (CE) is proposed. The method is capable of quantifying trace amounts of phenols in environmental water samples. For the SDME of three phenols, a 2.40 nL IL microdrop was exposed for 10 min to the aqueous sample and then was directly injected into the capillary column for analysis. Extraction parameters such as the extraction time, the IL single-drop volume, pH of the sample solution, ionic strength, volume of the sample solution and the extraction temperature were systematically investigated. Detection limits to three phenols were less than 0.05 μg mL⁻¹, and their calibration curves were all linear (R² ≥ 0.9994) in the range from 0.05 to 50 μg mL⁻¹. And enrichment factors for three phenols were 156, 107 and 257 without agitation, respectively. This method was then utilized to analyze two real environmental samples from Yellow River and tap water, obtaining satisfactory results. Compared with the usual SDME for CE, IL-SDME–CE is a simple, low-cost, fast and environmentally friendly preconcentration technique.     

Novel approach to improve the detection of colchicine via online coupling of ionic liquid-based single-drop microextraction with capillary electrophoresis

A novel approach based on ionic liquid‐single‐drop microextraction (IL‐SDME) online coupling with capillary electrophoresis (CE) was used to determine a toxic alkaloid – colchicine. The IL‐SDME procedure was optimized by extraction solvent, drop volume controlling, sample volume and pH, extraction time, and ionic strength. Under optimum conditions, enrichment factor was as much as 41‐fold with a relative standard deviation of 2.8% (n=3). Linear range of response was observed from 1 to 100 μg/mL, with detection limit of 0.25 μg/mL and correlation coefficient (R²) of 0.9994. The extraction of colchicine from spiked Lanzhou lily sample was performed and obtaining good result with an average recovery rate of 102.4 and 98.8% at 5 and 50 μg/mL, respectively. Comparing with the previous methods, IL‐SDME‐CE is really a convenient, economical, and environmentally benign way for determining colchicine.     

悬浮固化分散液液微萃取-毛细管电泳法测定水中磺酰脲类除草剂

建立了悬浮固化分散液液微萃取-毛细管电泳法同时测定水中磺酰脲类除草剂残留的方法。以十二醇为萃取剂、甲醇为分散剂,采用悬浮固化分散液液微萃取技术对水样进行分离提取,并结合毛细管电泳法进行测定。该方法可以有效提取、分离、检测水中残留的微量苯磺隆、吡嘧磺隆、苄嘧磺隆等9种磺酰脲类除草剂,各待测物在10.0~1000 μg/L范围内线性关系良好,相关系数r≥0.992,方法检出限为2.40~7.50 μg/L,方法精密度为6.55%~13.9%。将该方法用于实际水样的测定,取得了较满意的结果,加标回收率为82.0%~104%。该方法简便快速,适合水中磺酰脲类除草剂的同时测定。     

Comparison of efficiencies between single-drop microextraction and continuous-flow microextraction for the determination of methomyl in natural waters

Two liquid-phase microextraction (LPME) approaches, static direct-immersed single-drop microextraction (DI-SDME) and continuous-flow microextraction (CFME), were used to extract methomyl in water samples and their respective extraction efficiencies were compared. Several important parameters affecting extraction efficiency such as the type of extraction solvent, solvent drop volume, stirring speed or flow rate, extraction time and salt concentration were optimised. The optimised conditions were as follows: 3.0-µL tetrachloroethane (C₂H₂Cl₄) as the extraction solvent, 15% NaCl (w/v), 15 min extraction time and stirring speed at 600 rpm for DI-SDME; 3.5-µL C₂H₂Cl₄ as the extraction solvent, 15% NaCl (w/v), 21 min extraction time and flowing rate at 0.8 mL min^?1 for CFME. Under the previous optimal conditions, the linear range, detection limit (S/N = 3) and precision (RSD, n = 6) were 5.0-5000 ng mL^?1, 1.5 ng mL^?1, 6.9% for DI-SDME, and 4.0–10000 ng mL^?1, 2.5 ng mL^?1, 4.6% for CFME, respectively. Lake and river water samples were successfully analysed by DI-SDME and CFME. The result demonstrated that both SDME and CFME techniques are simple, low cost and amity to environment. As a result, the two approaches have tremendous potential in trace analysis of methomyl in natural waters.     

An ionic liquid as a solvent for headspace single drop microextraction of chlorobenzenes from water samples

A headspace single-drop microextraction (HS-SDME) procedure using room temperature ionic liquid and coupled to high-performance liquid chromatography capable of quantifying trace amounts of chlorobenzenes in environmental water samples is proposed. A Plackett-Burman design for screening was carried out in order to determine the significant experimental conditions affecting the HS-SDME process (namely drop volume, aqueous sample volume, stirring speed, ionic strength, extraction time and temperature), and then a central composite design was used to optimize the significant conditions. The optimum experimental conditions found from this statistical evaluation were: a 5 μL microdrop of 1-butyl-3-methylimidazolium hexafluorophosphate, exposed for 37 min to the headspace of a 10 mL aqueous sample placed in a 15 mL vial, stirred at 1580 rpm at room temperature and containing 30% (w/v) NaCl. The calculated calibration curves gave a high level of linearity for all target analytes with correlation coefficients ranging between 0.9981 and 0.9997. The repeatability of the proposed method, expressed as relative standard deviation, varied between 1.6 and 5.1% (n = 5). The limits of detection ranged between 0.102 and 0.203 μg L⁻¹. Matrix effects upon extraction were evaluated by analysing spiked tap and river water as well as effluent water samples originating from a municipal wastewater treatment plant.     

Dispersive liquid‐liquid microextraction coupled with pressure‐assisted electrokinetic injection for simultaneous enrichment of seven phenolic compounds in water samples followed by determination using capillary electrophoresis

Offline dispersive liquid‐liquid microextraction combined with online pressure‐assisted electrokinetic injection was developed to simultaneously enrich seven phenolic compounds in water samples, followed by determination using capillary electrophoresis, namely phenol, 4‐chlorophenol, pentachlorophenol, 2,4,6‐trichlorophenol, 2,4‐dichlorophenol, 2‐chlorophenol, and 2,6‐dichlorophenol. Several parameters affecting separation performance of capillary electrophoresis and the enrichment efficiency of pressure‐assisted electrokinetic injection and dispersive liquid‐liquid microextraction were systematically investigated. Under the optimal conditions, seven phenolic compounds were completely separated within 14 min and good enrichment factors were obtained of 61, 236, 3705, 3288, 920, 86, and 1807 for phenol, 4‐chlorophenol, pentachlorophenol, 2,4,6‐trichlorophenol, 2,4‐dichlorophenol, 2‐chlorophenol, and 2,6‐dichlorophenol, respectively. Good linearity was attained in the range of 0.1–200 μg/L for 2,4‐dichlorophenol, 0.5–200 μg/L for 4‐chlorophenol, pentachlorophenol, 2,4,6‐trichlorophenol, 2‐chlorophenol, and 2,6‐dichlorophenol, as well as 1–200 μg/L for phenol, with correlation coefficients (r) over 0.9905. The limits of detection and quantification ranging from 0.03–0.28 and 0.07–0.94 μg/L were attained. This two step enrichment method was potentially applicable for the rapid and simultaneous determination of phenolic compounds in water samples.     

毛细管电泳分析中的富集技术及其应用

毛细管电泳（CE）具有分析速度快、分离效率高、样品消耗少、成本低廉等优点,已被应用于无机离子、有机小分子、蛋白质、核酸及细胞等的分析中。CE中最常用的检测方式是紫外检测（UV）,但由于常规进样样品体积小、检测光程短,CE-UV的灵敏度往往不能满足复杂样品中痕量物质直接分析的要求。CE中的在柱富集技术包括堆积、动态pH界面、吹扫和瞬间等速电泳等,可在很大程度上提高CE-UV的检测灵敏度;另外,固相和液相微萃取技术及其与在柱富集技术相结合应用在CE中也能净化样品基质,进一步提高富集倍数,改善分析灵敏度,从而拓宽了CE-UV在复杂样品分析中的应用范围。     

毛细管电泳结合压力辅助电动进样测定水样中4种酚类雌激素

在毛细管电泳的胶束电动色谱（MEKC）模式下,采用压力辅助电动进样（PAEKI）的进样方式在线富集4种酚类雌激素（PEs）。对影响PAEKI的进样电压、进样时间等进行考察,并与传统的压力进样比较。结果表明,在最优的PAEKI条件下（-9 kV,0.3 psi（约2.1 kPa）,0.4 min）,4种PEs在7 min内基线分离,线性关系良好,相关系数（r）大于0.9936,己烷雌酚和双烯雌酚的线性范围为0.05~5 mg/L、双酚A和己烯雌酚的线性范围为0.1~10 mg/L;检出限（S/N=3）为0.0071~0.017 mg/L,富集倍数为11~15。使用该MEKC-PAEKI法对自来水和湖水水样进行测定,得到定量限（S/N=10）分别为0.029~0.064 mg/L和0.033~0.079 mg/L;加标回收率为75.6%~110.1%,相对标准偏差（n=5）为4.6%~11.8%。PAEKI不需要使用其他试剂,只需对电泳仪的参数进行适当调整即可实现对分析物的在线富集,简单、快速、自动化程度高。     

Dispersive liquid–liquid microextraction of five chlorophenols in water samples followed by determination using capillary electrophoresis

Dispersive liquid–liquid microextraction (DLLME) coupled with CE was developed for simultaneous determination of five types of chlorophenols (CPs), namely 2‐chlorophenol (2‐CP), 4‐chlorophenol (4‐CP), 2,4‐dichlorophenol (2,4‐DCP), 2,6‐dichlorophenol (2,6‐DCP), and 2,4,6‐trichlorophenol (2,4,6‐TCP) in water samples. Several parameters affecting DLLME and CE conditions were systematically investigated. Under the optimized DLLME‐CE conditions, the five CPs were separated completely within 7.5 min and good enrichment factors were obtained of 40, 193, 102, 15, and 107 for 4‐CP, 2,4,6‐TCP, 2,4‐DCP, 2‐CP, and 2,6‐DCP, respectively. Good linearity was attained in the range of 1–200 μg/L for 2,4,6‐TCP, 2,4‐DCP, 2−300 μg/L for 4‐CP and 2‐CP, and 1−300 μg/L for 2,6‐DCP, with correlation coefficients (r) over 0.99. The LOD (S/N = 3) and the LOQ (S/N = 10) were 0.31−0.75 μg/L and 1.01−2.43 μg/L, respectively. Recoveries ranging from 60.85 to 112.36% were obtained with tap, lake, and river water spiked at three concentration levels and the RSDs (for n = 3) were 1.31–11.38%. With the characteristics of simplicity, cost‐saving, and environmental friendliness, the developed DLLME‐CE method proved to be potentially applicable for the rapid, sensitive, and simultaneous determination of trace CPs in complicated water samples.