流动注射-毛细管电泳联用及应用进展

流动注射是一种高效进样及在线溶液处理手段。毛细管电泳是一种高分离效率、高选择性的分析技术,但传统的毛细管电泳间歇式进样方式效率低且难用于过程分析,将流动注射进样技术与毛细管电泳结合,既弥补了毛细管电泳的进样缺陷,又可兼具两者的优点。有关两种技术的联用一直都在探索之中。文中对近年流动注射一毛细管电泳联用及应用研究进行了综述。     

基于短毛细管的高速毛细管电泳系统的研究进展

概述了基于短毛细管的高速毛细管电泳系统的研究进展。重点介绍了适用于基于短毛细管的高速毛细管电泳系统的各种进样方法及其在生物分离分析领域的应用,包括光门进样、流动门进样、电动进样、自发进样、流体动力进样和扩散进样等方法。     

毛细管电泳序列分析技术用于在线酶分析研究进展

毛细管电泳技术具有操作简单、样品消耗量少、分离效率高和分析速度快等优势,不仅是一种高效的分离分析技术,而且已经发展成为在线酶分析和酶抑制研究的强有力工具。酶反应全程的实时在线监测,可以实现酶反应动力学过程的高时间分辨精确检测,以更准确地获得反应机制和反应速率常数,有助于更好地了解酶反应机制,从而更全面深入地认识酶在生物代谢中的功能。此外,准确、快速的在线酶抑制剂高通量筛选方法的发展,对加快酶抑制类药物的研发以及疾病的临床诊断亦具有重要意义。电泳媒介微分析法（EMMA）和固定化酶微反应器（IMER）是毛细管电泳酶分析技术中常用的在线分析方法。这两种在线酶分析法的进样方式通常为流体动力学进样和电动进样,无法实现酶反应过程中的无干扰序列进样分析。近年来,基于快速序列进样的毛细管电泳序列分析技术已经发展成为在线酶分析的另一种强有力手段,以实现高时间分辨和高通量的酶分析在线检测。该文从快速序列进样的角度,综述了近年来毛细管电泳序列分析技术在线酶分析的研究进展,并着重介绍了各种序列进样方法及其在酶反应和酶抑制反应中的应用,包括光快门进样、流动门进样、毛细管对接的二维扩散进样、流动注射进样、液滴微流控进样等。     

在线富集二维毛细管电泳分析新体系检测尿样中药物及对映体

将在线富集技术同二维(2D)毛细管电泳(CE)分离相结合同时提高复杂样品中痕量组分的分离度和检测灵敏度.毛细管区带电泳(CZE)作为第一维,分析物根据淌度不同进行分离,第一维流出组分进入第二维毛细管,根据分配系数不同进行胶束电动毛细管色谱(MEKC)分离.采用阳离子选择性耗尽进样(CSEI)在柱预富集,延长进样时间,增大进样量;同时在二维毛细管接口处采用动态pH联接/胶束扫集在线富集技术不仅避免第一维分离组分在接口处扩散,还可进一步压缩样品区带.同常规电动进样CE分离相比,该在线富集二维分离技术的分离能力远远高于一维CZE或MEKC分离,富集倍数达到(0.5～1.2)×104.该法成功应用于人体尿样中四种药物及对映体的分析测定,浓度检出限为0.1～0.3μg/L.进一步研究了人体尿样中四种药物24h内的药代动力学规律.     

芯片毛细管电泳-激光诱导荧光-电荷耦合器件检测系统

采用自组建的芯片毛细管电泳－激光诱导荧光－电荷耦合器件（CCD）检测系统在数十秒内满意地分离了曙红和荧光素。设计了一种进样、分 离电路,可以有效地消除进样通道的样品溶液向分离通道的渗漏。解决了由这种渗漏所引起的电泳峰变宽、拖尾等问题。提高了芯片毛细管电泳的分辨率和分离效率。     

毛细管电泳进样技术新进展

评述了毛细管电泳进样技术新成果。对直接在线进样，二维分离体系中毛细管电泳分离的增样，相关毛细管电泳增样，超微量样品及单个分子的进样，近端进样，双向进样和高温下的进样装置的应用状况作了介绍。     

流动注射-毛细管电泳分流式电动进样歧视效应特征的研究

以碱性药物盐酸伪麻黄碱和酸性药物布洛芬为对象研究了分流式电动进样(一种用于流动注射-毛细管电泳(FI-CE)联用系统的新进样方法)歧视效应的特性。结果发现:在样品介质与运行缓冲液一致的条件下,FI-CE分流式电动进样产生的歧视效应与电动进样相似,但获得的校正曲线的线性明显优于电动进样,而与没有歧视效应的压力进样所获得的线性相似。利用这些特征提高了同时测定复方布洛芬片中少量组分盐酸伪麻黄碱和主要组分布洛芬的分析性能。在24次/h的采样频率下,盐酸伪麻黄碱的检测限为0.7 mg/L,比采用压力进样的毛细管电泳法所得的检测限低30%。连续进样11次分析含有13.1 mg/L盐酸伪麻黄碱和81.4 mg/L布洛芬的试样溶液,峰面积的相对标准偏差分别为2.8%(盐酸伪麻黄碱)和1.2%(布洛芬),明显优于采用压力进样的毛细管电泳法。用该法测定了两批复方布洛芬片中两种组分的含量,所得结果与高效液相色谱法的测定结果一致。     

芯片电泳推拉式压力进样方法

芯片电泳作为微流控分析系统的典型代表,广泛涉及材料、微加工方法、微液流控制、分离模式和检测方法等诸多方面.与传统分析系统一样,样品制备和引入也是微全分析系统实现样品到结果首先面临的问题.电进样一直是芯片电泳系统的主流进样方法.而传统毛细管电泳系统中与电进样同样经常使用的压力进样方法则很少用于芯片电泳系统.     

毛细管区带电泳的离子交换在柱预富集技术研究

提出了离子交换固相萃取的毛细管区带电泳在柱预富集技术。预富集毛细管和分离毛细管的端面靠紧,二者通过一段带侧孔的聚四氟乙烯（PTFE）套管固定。预富集毛细管内壁键合羧基阳离子交换基团,进样时分析离子被保留在预富集管的固定相上,用2mol／L的氯化铵溶液洗脱,再进行毛细管区带电泳分离。方法成功富集和分离了两种低浓度的药物阳离子,普萘洛尔和美托洛尔的灵敏度比常规电动进样分别提高4200和3400倍,其浓度检出限分别为0．02μg/L和0．14μg/L。     

高效毛细管电泳-紫外检测法测定饮料等包装材料中的双酚A

建立了饮料等包装材料中双酚A的高效毛细管电泳-紫外检测法.以无水乙醇为提取溶剂,采用硼砂-十二烷基硫酸钠-乙腈溶液为运行缓冲液(pH 9.5);分离毛细管为50cm×50μm,有效长度41cm的熔融石英毛细管;电泳温度为20℃;检测波长为195n m;重力进样,进样时间为15s.以相对迁移时间定性,标准曲线法定量.方法...     

pH-mediated acid stacking with reverse pressure for the analysis of cationic pharmaceuticals in capillary electrophoresis

When using capillary electrophoresis (CE) for the analysis of biological samples, it is often necessary to employ techniques to overcome peak-broadening that results from having a high-conductivity sample matrix. To improve the concentration detection limits and separation efficiency of cationic pharmaceuticals in CE, pH-mediated acid stacking was performed to electrofocus the sample, improving separation sensitivity for the analyzed cations by 60-fold. However, this method introduces a large titrated acid plug into the capillary. To overcome the limitations this low-conductivity plug poses to stacking, the plug was removed prior to the separation step by applying reverse pressure to force it out of the anode of the capillary. Employing this technique allows for roughly twice the volume of sample to be injected. A maximum sample injection time of 240 s was attainable with baseline peak resolution compared to a maximum sample injection time of 120 s without reverse pressure, leading to a twofold decrease in the limits of detection of the analytes used. Separation efficiency overall is also improved when utilizing the reverse pressure step. For example, a 60 s sample injection time results in 94,000 theoretical plates as compared to 60,500 theoretical plates without reverse pressure. This reverse-pressure method was used for detection and quantitation of several cationic pharmaceuticals that were prepared in Ringer's solution to simulate microdialysis sampling conditions.     

Rapid electrophoretic separations in short capillaries using contactless conductivity detection and a sequential injection analysis manifold for hydrodynamic sample loading

A sequential injection-capillary electrophoresis (SI-CE) system for the fast and automated quantitative analysis of anions and cations is described. Because of the low sample load in capillary electrophoresis a split injection approach had to be used to achieve reliable hydrodynamic injection. The use of a capillary of 8 cm effective length allowed for the separation of five inorganic cations within 11 s. One common electrolyte solution containing 12 mM l-histidine and 2 mM 18-crown-6 whose pH value was adjusted to 4.0 with 10% v/v acetic acid was used for anions and cations, thus the analysis of both groups of analytes could be carried out in rapid sequence simply by switching the polarity of the high voltage supply. The system also allows automated flushing of the capillary. Detection limits between about 2 and 5 micromol l(-1) could be achieved with the contactless conductivity detector employed.     

Automated sampling system for the analysis of amino acids using microfluidic capillary electrophoresis

An improved automated continuous sample introduction system for microfluidic capillary electrophoresis (CE) is described. A sample plate was designed into gear-shaped and was fixed onto the shaft of a step motor. Twenty slotted reservoirs for containing samples and working electrolytes were fabricated on the “gear tooth” of the plate. A single 7.5-cm long Teflon AF-coated silica capillary serves as separation channel, sampling probe, as well as liquid-core waveguide (LCW) for light transmission. Platinum layer deposited on the capillary tip serves as the electrode. Automated continuous sample introduction was achieved by scanning the capillary tip through the slots of reservoirs. The sample was introduced into capillary and separated immediately in the capillary with only about 2-nL gross sample consumption. The laser-induced fluorescence (LIF) method with LCW technique was used for detecting fluorescein isothiocyanate (FITC)-labeled amino acids. With electric-field strength of 320 V/cm for injection and separation, and 1.0-s sample injection time, a mixture of FITC-labeled arginine and leucine was separated with a throughput of 60/h and a carryover of 2.7%.     

利用瞬间等速电泳的毛细管区带电泳大体积电动进样的研究

采用添加乙腈引发的场放大进样与瞬间等速电泳结合的预富集方法,实现了在毛细管内大体积高盐样品中阳离子的有效富集与分离。详细讨论了影响富集的缓冲体系、尾随离子种类、毛细管有效长度、进样时间和等速电泳时间等重要因素。选择在400 mmol/L LiAc-HAc缓冲液(pH 4.5)和400 mmol/L　β-丙氨酸-HAc尾随液(pH 4.5)及10 kV下样品和尾随溶液电动注入时间分别为270和90 s的条件下对高盐溶液中两种结构相近的药物普萘洛尔和美托洛尔进行了富集和分离。该方法富集倍数约为常规电动进样的280倍,普萘洛尔和美托洛尔的检出限分别为2×10-3和8×10-3 mg/L。     

Multisyringe flow injection analysis coupled to capillary electrophoresis (MSFIA-CE) as a novel analytical tool applied to the pre-concentration, separation and determination of nitrophenols

For the first time, a multisyringe flow injection analysis capillary electrophoresis system is described. The potential of the hyphenation for sample treatment including analyte pre-concentration is demonstrated by its successful application to the determination of mono-nitrophenols (NPs) in different water samples. The analytical system was used to automate in-line sample acidification, analyte pre-concentration, elution, hydrodynamic injection, electrophoretic separation, and detection as well as the maintenance and re-conditioning of the solid-phase extraction (SPE) column and the separation capillary. A pre-concentration factor of better than 115 and detection down to 0.11 micromol L(-1) were achieved. Detection was carried out at visible wavelength using a blue LED as a low baseline-noise light source. High repeatability was obtained each for migration times and for peak heights with relative standard deviations typically below 2.5 and 6% including the pre-concentration procedure, respectively. Three injections per hour were achieved by running in parallel the pre-concentrating and the electrophoretic separation procedures. Instrumental control and data registration and evaluation were carried out with the software package AutoAnalysis, allowing autonomous operation of the analytical system.     

Simultaneous separation of inorganic anions and cations using capillary electrophoresis with a movable contactless conductivity detector

A number of small inorganic anions and cations were separated after injection of the sample into both ends of a separation capillary. The ions were detected using a capacitively coupled contactless conductivity detector (CCCCD) which could be placed at various positions along the capillary length. Counter-directional migration of anions and cations occurs towards the detector, which is placed at an appropriate position along the capillary so that the migration order is determined by the respective effective separation capillary lengths for both anions and cations. As the CCCCD detector can be easily moved to any position along the capillary, virtually any effective separation length can be attained. Depending on the number of analytes in the sample, one can choose to obtain either electropherograms with inter-migrating zones of cations and anions or separations with distinct regions of anion and cation zones, respectively. A new term 'apparent separation selectivity' is introduced to describe the manner in which the position of the detector can be varied in order to determine the final separation.     

Use of disposable open tubular ion exchange pre-columns for in-line clean-up of serum and plasma samples prior to capillary electrophoretic analysis of inorganic cations

A simple analytical system using disposable, open-tubular ion exchange clean-up precolumns coupled in-line to capillary electrophoresis for direct injection of biological samples is presented. The clean-up precolumns were prepared from fused silica capillaries by thermally initiated layer-by-layer polymerization of poly(butadiene-maleic acid) (PBMA) directly on the capillary wall. Typically, 6 cm long precolumns with 4-layers of PBMA were used for sample pretreatment. A robust and reproducible coupling between the precolumn (75 μm ID) and the analytical capillary (50 μm ID) was achieved using an inexpensive, commercially available low dead volume union. No extra dispersion of the analyte zones was observed. Proteins and other high molecular weight compounds from biological sample matrices were retained on the cation-exchanger sites of the precolumn, which eliminated their adsorption on analytical capillary walls and ensured stable electroosmotic flow and migration times of target analytes. Unretained small inorganic cations migrated freely into the analytical capillary for separation and detection. Applicability of the sample clean-up procedure was proved by determination of major inorganic cations in blood serum and plasma samples using capillary electrophoresis with contactless conductivity detection. Separations were performed in background electrolyte solution consisting of 15 mM L-arginine, 12.5 mM maleic acid, 3 mM 18-crown-6 at pH 5.5 and repeatabilities of migration times and peak areas were below 1.5% and 7.3%, respectively. Less than 1 μL of biological sample was required for injection.     

Novel variable volume injector for performing sample introduction in a miniaturised isotachophoresis device

A microdevice design furnished with a novel sample injector, capable of delivering variable volume samples, for miniaturised isotachophoretic separations is presented. Micromachining by direct milling was used to realise two flow channel network designs on poly(methyl methacrylate) chips. Both designs comprised a wide bore sample channel interfaced, via a short connection channel, to a narrow bore separation channel. Superior injection performance was observed with a connection channel angled at 45 degrees to the separation channel compared to a device using a channel angled at 90 degrees. Automated delivery of electrolytes to the microdevice was demonstrated with both hydrostatic pumping and syringe pumps; both gave reproducible sample injection. A range of different sampling strategies were investigated. Isotachophoretic separations of model analytes (metal ions and an anionic dye) demonstrated the potential of the device. Separations of ten metal cations were achieved in under 475 s.     

Eluent-Induced Separation of Inorganic Cations in Capillary Liquid Chromatography with Contactless Conductivity Detector

A non-suppressed contactless conductivity detector has been used as a capillary detector in a capillary ion chromatograph, combining a reversed-phase C30 column permanently modified with ionic surfactant. The C30 column (100 × 0.32 mm. id) was modified with sodium dodecyl sulfate (SDS) for the separation of inorganic cations. Monovalent cations could be separated by the proposed system, in which methanesulfonic acid (MSA) and SDS were employed as the mobile phase component, but divalent cations could not be eluted under this condition. As for the case of SDS used as the eluent, an H⁺-cation-exchange column was placed before the sample injector to convert the Na⁺ from the eluent into H⁺, and when the mixture of MSA and dodecyl sulfuric acid was used as the eluent, the retention of cations was improved and baseline separation of the cations was achieved within 23 min. The effect of the eluent composition on the retention behavior of inorganic cations was investigated. The repeatability of retention time and peak height varied from 0.39 to 0.58 and 2.21 to 3.25 % as relative standard deviation, respectively.

     

Eluent-Induced Separation of Inorganic Cations in Capillary Liquid Chromatography with Contactless Conductivity Detector

A non-suppressed contactless conductivity detector has been used as a capillary detector in a capillary ion chromatograph, combining a reversed-phase C30 column permanently modified with ionic surfactant. The C30 column (100 × 0.32 mm. id) was modified with sodium dodecyl sulfate (SDS) for the separation of inorganic cations. Monovalent cations could be separated by the proposed system, in which methanesulfonic acid (MSA) and SDS were employed as the mobile phase component, but divalent cations could not be eluted under this condition. As for the case of SDS used as the eluent, an H⁺-cation-exchange column was placed before the sample injector to convert the Na⁺ from the eluent into H⁺, and when the mixture of MSA and dodecyl sulfuric acid was used as the eluent, the retention of cations was improved and baseline separation of the cations was achieved within 23 min. The effect of the eluent composition on the retention behavior of inorganic cations was investigated. The repeatability of retention time and peak height varied from 0.39 to 0.58 and 2.21 to 3.25 % as relative standard deviation, respectively.