用于电渗控制的新型毛细管电泳装置

提出了一种可利用径向电场控制电渗的新型毛细管电泳装置，着重讨论了其工作原理，电渗控制方法及相关结果。该装置不仅能方便地实现电渗的电场控制，而且通过略加改进，还能与商品仪器兼容。     

径向电场调制毛细管电泳法用于蛋白质分离

利用自制的双向电场控制毛细管电泳新系统,考察了蛋白质的分离情况.结果发现,在低pH值下,通过施加径向电场,不仅可改变电渗流的大小和方向,而且能抑制蛋白质的吸附,进而实现对蛋白质分离效率和分离速度的调控.研究结果表明,可通过物理化学方法实现毛细管电泳的动态或随机调控,这对许多生物样品分离有实际意义.     

毛细管等电聚焦方法及其应用

讨论了毛细管等电聚焦中所涉及的问题,如分离机理、电渗、迁移方法、检测器及其应用。由于毛细管等电聚焦操作方式的多样性,使其可适用于不同的仪器条件。非交联丙烯酰胺涂层能很好地消除电渗和蛋白吸附;而采用未处理的毛细管时,动态涂敷纤维素类亲水聚合物对碱性和中性蛋白亦能取得较好的分离效果。电荷耦合器件成像检测器尚待进一步发展才能成为常用的检测工具。对于复杂样品来说,仍需解决的问题是保证在较宽的ｐＨ范围内ｐＩ的线性。     

毛细管电泳分离I^—和IO3^—中的电渗流的控制与调节

毛细管电泳分离是基于带电粒子在电场下的电动现象，当电场加到带电粒子所处的介质上时，存在电泳和电渗两种电动现象，其中电泳与带电粒子的大小、电荷和形状有关，而电渗与毛细管的表面及电泳介质的组成有关．由于电渗流能显著地影响分析时间和分离效率，因此，控制电渗流在毛细管电泳分离中是一个重要的环节［‘·‘j．此外，调节PH值、离子强度和缓冲液的粘度也是常用的控制电渗流的方法［’j．Ewing［‘与1入一个附加电场来控制电渗流．在缓冲液中加入足够浓度的阳离子表面活性剂将改变电渗流的方向．与通常的电渗流相比，人们对反向…     

杯芳烃涂层毛细管分离单胺类神经递质

本文设计制作了一种对烯丙基杯 [4 ]芳烃涂层毛细管。用于毛细管电泳分离的结果表明 ,此管能分离 5 羟色胺 ( 5 HT)、多巴胺 (DA)、去甲肾上腺素 (NE)、肾上腺素 (E)等结构相近的单胺类神经递质 ,而无涂层管则不能。本涂层管在pH4～ 9范围内的电渗较无涂层管下降约 75% ,且当pH <8时 ,电渗随pH的变化接近于线性关系 ,有利于高重现分离。杯芳烃涂层毛细管不降低紫外检测灵敏度。其主要问题是酚羟基对胺类仍有吸附 (或静电 )作用     

电解质溶液组成对低分子量阴离子毛细管电泳分离的影响

研究了毛细管电泳间接紫外检测法测定低分子量阴离子时电解质溶液中背景电解质、电渗流改性剂、ｐＨ值、有机溶剂等对分离的影响；比较了铬酸根、邻苯二甲酸根、苯甲酸根３种背景离子对不同迁移率阴离子分离的影响，并对间接紫外检测的定量基础及灵敏度进行了讨论；考察了３种不同长链烷基三甲基季铵盐电渗流改性剂浓度对阴离子迁移时间和电渗迁移率的影响，结果表明电渗流的改性效果与烷基链的长度有关；ｐＨ影响阴离子的有效迁移率     

新型毛细管等电聚焦驱动方法的建立及其应用

毛细管等电聚焦(CIEF)在生物分离分析领域中的发展迅速．CIEF可分为两步法聚焦和一步法聚焦．电渗流(EOF)可作为一种新的驱动力．Rassi等根据串连体系中电渗流速率将被平均化的原理,将未涂层毛细管与聚乙二醇涂层的毛细管通过聚四氟乙烯管耦合起来,成功地利用毛细管区带电泳快速分离蛋白．此外,利用电渗流输液原理设计的电渗泵还可用作流动注射和微柱液相色谱的驱动系统。     

径向电场调制毛细管电泳法用于神经递质分离

利用双向电场控制毛细管电泳系统，考察了神经递质的分离。在pH2.5的0.01mol/L磷酸盐缓冲体系中，通过加入20％（V／V）正丙醇，改善了多巴胺和5－羟色胺的分离效果，但仍不太理想。通过施加径向电场，可进一步提高分离度。本研究不仅拓宽了径向电场调控的样品分离范围，而且为生物活性物质的痕量分析提供了参考依据。     

新型共聚物涂层毛细管电泳柱及其分离蛋白质的研究

研究新型共聚物——ＺＢ系列表面键合剂在毛细管电泳中的应用。采用物理吸附的方法制备了ＺＢ－００４,ＺＢ－０１４,ＺＢ－０１６等３种涂层毛细管柱,在ｐＨ３～５范围内,３种涂层均能有效地降低管壁对蛋白质的吸附作用和电渗流,其中亲水性较弱的ＺＢ－００４涂层的分离性能最好。在ｐＨ＜５时,涂层具有较高的稳定性和良好的分析重复性,但在更高的ｐＨ值条件下,仍然存在着峰形畸变和电渗流迅速增加的现象。     

新型共聚物涂层毛细管电泳柱及其分离蛋白质的研究

 研究新型共聚物——ＺＢ系列表面键合剂在毛细管电泳中的应用。采用物理吸附的方法制备了ＺＢ－００４,ＺＢ－０１４,ＺＢ－０１６等３种涂层毛细管柱,在ｐＨ３～５范围内,３种涂层均能有效地降低管壁对蛋白质的吸附作用和电渗流,其中亲水性较弱的ＺＢ－００４涂层的分离性能最好。在ｐＨ＜５时,涂层具有较高的稳定性和良好的分析重复性,但在更高的ｐＨ值条件下,仍然存在着峰形畸变和电渗流迅速增加的现象。     

A fully automated linear polyacrylamide coating and regeneration method for capillary electrophoresis of proteins

Surface modification of the inner capillary wall in CE of proteins is frequently required to alter EOF and to prevent protein adsorption. Manual protocols for such coating techniques are cumbersome. In this paper, an automated covalent linear polyacrylamide coating and regeneration process is described to support long‐term stability of fused‐silica capillaries for protein analysis. The stability of the resulting capillary coatings was evaluated by a large number of separations using a three‐protein test mixture in pH 6 and 3 buffer systems. The results were compared to that obtained with the use of bare fused‐silica capillaries. If necessary, the fully automated capillary coating process was easily applied to regenerate the capillary to extend its useful life‐time.     

Utilizing the pH hysteresis effect for versatile and simple electrophoretic analysis of proteins in bare fused-silica capillaries

The analysis of peptides and proteins by CE is often desirable due to low sample consumption and possibilities for nondenaturing yet highly effective separations. However, adsorption to the inner surfaces of fused-silica capillaries often is detrimental to such analyses. This phenomenon is especially pronounced in the analysis of basic proteins and proteins containing exposed positively charged patches. To avoid wall interactions numerous buffer additives and static and dynamic wall coating principles have been devised. We previously showed (J. Chromatogr. A 2004, 1059, 215-222) that CE of the basic protein beta2-glycoprotein was rendered possible by an acidic pretreatment step, and we attributed this observation to the so-called pH hysteresis effect that influences the time for pH equilibration of the capillary wall and thus the effective wall charge and the electroosmotic mobility. We here investigate the effects of different pretreatment techniques on EOF values and on the rate of the deprotonation of silanol groups when performing the electrophoresis at neutral pH. We show the utility of this simple approach for the CE analysis of a number of basic proteins in plain silica capillaries at physiological pH.     

Open tubular capillary electrochromatography in etched, chemically modified 20 microns I.D. capillaries.

Fused silica capillaries with an I.D. of 20 microns are etched and then chemically modified by the silanization/hydrosilation method to attach an octadecyl moiety for use in electrokinetic chromatography. The etched capillaries after chemical modification are shown to have an anodic electroosmotic flow below pH 4.5. In comparison to bare 20 microns capillaries and unetched but chemically modified 20 microns capillaries, the etched C18 fused silica tubes show better separation of mixtures of lysozymes and cytochrome c's under identical conditions of buffer, pH and applied voltage. It was also demonstrated that this open tubular approach to capillary electrochromatography was amenable to a number of different types of basic compounds ranging in size from typical small amines to biomolecules. As expected, pH is an important variable that must be controlled in order to obtain an optimized separation. Reproducibility studies verify the stability of the silicon-carbon linkage produced in this modification method so that column lifetimes of at least 300 injections can be expected.     

Capillary electrophoretic determination of S-carboxymethyl-L-cysteine and its major metabolites in human urine: feasibility investigation using on-column detection of non-derivatized solutes in capillaries with minimal electroosmosis

The capillary electrophoretic analysis of S-carboxymethyl-L-cysteine and some of its metabolites in human urine is reported using (i) on-column detection of underivatized solutes, (ii) minimal sample pretreatment and (iii) capillary columns with minimized electroosmosis. Experimental results obtained with two apparatus, the HPE-100 (Bio-Rad), featuring coated fused silica capillaries of 25 microns i.d., and with the Tachophor 2127 (LKB), having Teflon capillaries of 500 microns i.d. are discussed. Drug concentrations down to 0.2 mg/mL on capillary isotachophoresis and 0.03 mg/mL on capillary zone electrophoresis can be monitored with these instruments.     

Co‐electroosmotic capillary electrophoresis of basic proteins with 1‐alkyl‐3‐methylimidazolium tetrafluoroborate ionic liquids as non‐covalent coating agents of the fused‐silica capillary and additives of the electrolyte solution

The paper reports the results of a study carried out to evaluate the use of three 1‐alkyl‐3‐methylimidazolium‐based ionic liquids as non‐covalent coating agents for bare fused‐silica capillaries and additives of the electrolyte solutions (BGE) for CE of basic proteins in the co‐EOF separation mode. The three ionic liquids are differentiated from each other by the length of the alkyl group on the imidazolium cation, consisting of either an ethyl, butyl or octyl substituent, whereas tetrafluoroborate is the common anionic component of the ionic liquids. Coating the capillary with the ionic liquid resulted in improved peak shape and protein separation, while the EOF was maintained cathodic. This indicates that each ionic liquid is effective at masking the protein interaction sites on the inner surface of the capillary, also when its adsorption onto the capillary wall has not completely neutralized all the negative charges arising from the ionization of the silanol groups and the ionic liquid is not incorporated into the BGE employed for separation. Using the coated capillaries with BGE containing the ionic liquid employed for the coating, at concentration low enough to maintaining the EOF cathodic, both peak shape and protein separation varied to different extents, based on the particular ionic liquid used and its concentration. Fast and efficient separation of the model basic protein mixture in co‐electroosmotic CE is obtained with the 1‐butyl‐3‐methylimidazolium tetrafluoroborate coated capillary and 100 mM acetate buffer (pH 4.0) containing 4.4 mM 1‐butyl‐3‐methylimidazolium tetrafluoroborate as the BGE.     

Poly(tetrafluoroethylene) separation capillaries for capillary electrophoresis. Properties and applications

Poly(tetrafluoroethylene) (PTFE) is a material widely known for its inertness and excellent electrical properties. It is also transparent in the UV region and has a reasonable thermal conductivity. These properties make PTFE a suitable material for the separation capillary in capillary electrophoresis. Differences in the chemistry of the capillary wall compared to fused silica (FS) can make PTFE an interesting alternative to FS for some special applications. In this work, properties of a commercial PTFE capillary of approx. 100 microm i.d. were investigated, including the dependence of electroosmotic flow (EOF) on pH for unmodified and dynamically modified PTFE, optical properties, and practical aspects of use. The main problems encountered for the particular PTFE capillary used in this study were that it was mechanically too soft for routine usage and the crystallinity of the PTFE caused light scattering, leading to high background absorbance values in the low UV region. The profile of the EOF versus pH for bare PTFE surprisingly showed significantly negative EOF values at pH < 4.2, with an EOF of -30 x 10(-9) m2 V(-1) s(-1) being observed at pH 2.5. This is likely to be caused by either impurities or additives of basic character in the PTFE, so that after their protonation at acidic pH they establish a positive charge on the capillary wall and create a negative EOF. A stable cationic semi-permanent coating of poly(diallyldimethylammonium chloride) (PDDAC) could be established on the PTFE capillary and led to very similar magnitudes of EOF to those observed with FS. A hexadecanesulfonate coating produced a cathodic EOF of extremely high magnitude ranging between +90 and +110 x 10(-9) m2 s(-1) V(-1), which are values high enough to allow counter-EOF separation of high mobility inorganic anions. In addition, pH-independent micellar electrokinetic capillary chromatography (MEKC) separations could be easily realised due to hydrophobic adsorption of sodium dodecylsulfate (used to form the micelles) on the wall of the PTFE capillary. The use of polymers that would be mechanically more robust and optically transparent in the low-UV region should make such CE capillaries an interesting alternative to fused silica.     

Applications of a sulfonated-polymer wall-modified open-tubular fused-silica capillary in capillary zone electrophoretic separations

A fused-silica capillary that is wall-modified via chemically bonding a sulfonated polymer to the capillary wall has a uniform negative charge density on its surface and produces an electroosmotic flow (EOF) greater than 4 x 10(-4) cm2 V(-1) s(-1) The EOF is nearly independent of buffer pH over the pH range of 2 to 10 and is lower than the EOF obtained for the bare fused-silica capillary at the more basic pH but is higher at the more acidic buffer pH. Optimization of buffer pH can be based on analyte pKa values to improve the overall quality of the capillary zone electrophoresis (CZE) separation of complex mixtures of weak acid and base analytes. Because of the high EOF in an acidic buffer, the capillary is useful for the separation of weak organic bases which are in their cation forms in the acidic buffer. EOF for the sulfonic acid bonded phase capillary can be adjusted via buffer additives such as organic solvent, tetraalkylammonium salts, multivalent cations and alkylsulfonic acids. The advantages of utilizing buffer pH and the EOF buffer modifiers to enhance migration time, selectivity, and resolution in CZE separations with this capillary are illustrated using a series of test analyte mixtures of inorganic anions, carboxylic acids, alkylsulfonic acids, benzenesulfonic acids, sulfas, pyridines, anilines or small-chain peptides.     

Validation of CE modeling with a contactless conductivity array detector

Dynamic computer simulation data are compared for the first time with CE data obtained with a laboratory made system comprising an array of 8 contactless conductivity detectors (C⁴Ds). The experimental setup featured a 50 μm id linear polyacrylamide (LPA) coated fused‐silica capillary of 70 cm length and a purpose built sequential injection analysis manifold for fluid handling of continuous or discontinuous buffer configurations and sample injection. The LPA coated capillary exhibits a low EOF and the manifold allows the placement of the first detector at about 2.7 cm from the sample inlet. Agreement of simulated electropherograms with experimental data was obtained for the migration and separation of cationic and anionic analyte and system zones in CZE configurations in which EOF and other column properties are constant. For configurations with discontinuous buffer systems, including ITP, experimental data obtained with the array detector revealed that the EOF is not constant. Comparison of simulation and experimental data of ITP systems provided the insight that the EOF can be estimated with an ionic strength dependent model similar to that previously used to describe EOF in fused‐silica capillaries dynamically double coated with Polybrene and poly(vinylsulfonate). For the LPA coated capillaries, the electroosmotic mobility was determined to be 17‐fold smaller compared to the case with the charged double coating. Simulation and array detection provide means for quickly investigating electrophoretic transport and separation properties. Without realistic input parameters, modeling alone is not providing data that match CE results.     

Mobility-based selective on-line preconcentration of proteins in capillary electrophoresis by controlling electroosmotic flow

A simple method to perform selective on-line preconcentration of protein samples in capillary electrophoresis (CE) is described. The selectivity, based on protein electrophoretic mobility, was achieved by controlling electroosmotic flow (EOF). A short section of dialysis hollow fiber, serving as a porous joint, was connected between two lengths of fused silica capillary. High voltage was applied separately to each capillary, and the EOF in the system was controlled independently of the local electric field intensity by controlling the total voltage drop. An equation relating the EOF with the total voltage drop was derived and evaluated experimentally. On-line preconcentration of both positively charged and negatively charged model proteins was demonstrated without using discontinuous background electrolytes, and protein analytes were concentrated by approximately 60-200-fold under various conditions. For positively charged proteins, positive voltages of the same magnitude were applied at the free ends of the connected capillaries while the porous joint was grounded. This provided a zero EOF in the system and a non-zero local electric field in each capillary to drive the positively charged analytes to the porous joint. CE separation was then initiated by switching the polarity of the high voltage over the second capillary. For negatively charged proteins, the procedure was the same except negative voltages were applied at the free ends of the capillaries. Mobility-based selective on-line preconcentration was also demonstrated with two negatively charged proteins, i.e. beta-lactoglobulin B and myoglobin. In this case, negative voltages of different values were applied at the free ends of the capillaries with different values, which provided a non-zero EOF in the system. The direction of EOF was the same as that of the electrophoretic migration velocities of the protein analytes in the first capillary and opposite in the second capillary. By controlling the EOF, beta-lactoglobulin B, which has a higher mobility, could be concentrated over 150-fold with a 15 min injection while myoglobin, which has a lower mobility, was eliminated from the system.