杯芳烃在液相色谱、毛细管电泳和电色谱中的应用进展

利用杯芳烃的分子识别作用提高色谱分离选择性是超分子化学在分离科学中的成功应用.本文从杯芳烃分离材料的制备、分离机理和应用等,综述了近年来杯芳烃在液相色谱、毛细管电泳和电色谱中的研究进展.     

对羟基苯甲酸分子印迹毛细管电色谱整体柱的制备与评价

<正>分子印迹(MIP)是合成预定选择性固定相的新兴技术[1-3],毛细管电色谱(CEC)是一种新型高效微分离技术[4-5],CEC和MIP相结合是当前的前沿课题之一。以对羟基苯甲酸为模板分子,采用在线热聚合制备毛细管电色谱整体柱的研究取得了满意的效果[6-7];以布洛芬为模板分子,以2-乙烯基吡啶为功能单体制备分子印迹毛细管电色谱整体柱,成功用于分离布洛芬同分异构体[8],以(S)-腺苷蛋氨酸为模板分子,采用热引发一步法制备分子印迹毛细     

杯芳烃在液相色谱固定相领域的应用及进展

杯芳烃是一类由苯酚单元通过亚甲基桥连的超分子化合物,具有独特的主客体识别性能,是继冠醚和环糊精之后第三代超分子化合物的主要代表。其被广泛应用于离子通道、有机催化反应、跨膜转运、纯化、色谱分离等方面。基于杯芳烃易于修饰的特点,选取不同性质的化合物进行衍生化,可以制备出具有不同识别能力和高选择性的杯芳烃衍生物,进而应用于不同色谱分离模式,可实现复杂样品的分离分析。该文从杯芳烃、杯芳烃衍生物和杯杂芳烃3个方面综述了近年来杯芳烃在液相色谱固定相方面的研究应用及进展,并对杯芳烃在色谱分离领域的发展提出了展望。     

痕量脑啡肽的毛细管电色谱分析技术研究

加压毛细管电色谱为近年来发展起来的一种高效、快速的新型微柱分离方法.亲水毛细管电色谱相较于反相色谱(RPC)和正相色谱(NPLC),在分离极性化合物时,有其独特优势~([1,2]).最近,基于极性固定相的亲水作用毛细管电色谱(HICEC)备受关注,是当前色谱微分离技术的研究热点.     

共价有机框架材料在毛细管电色谱中的应用进展

毛细管电色谱(CEC)因兼具高效液相色谱(HPLC)的高选择性和毛细管电泳(CE)的高分离效率而受到越来越多研究者的关注。在毛细管电色谱中,选择合适的固定相材料对获得优异的分离效果起着十分重要的作用。近年来,多种新型材料如氧化石墨烯、蛋白质、金属有机框架(MOFs)及共价有机框架(COFs)等被作为固定相应用于毛细管电色谱领域以期获得更好的分离性能,同时拓展毛细管电色谱的应用范围。其中,COFs因具有孔隙率高、比表面积大、高稳定性、孔径可调和可设计性强等独特性质,在毛细管电色谱领域显示出了巨大的应用前景。鉴于此,本文对2016-2023年间COFs在毛细管电色谱领域的研究进展进行了综述,包括COFs毛细管电色谱柱的分类和制备方法,以及基于COFs固定相的毛细管电色谱技术在环境内分泌干扰物、农药、芳香族化合物、氨基酸及药物分离领域中的应用及分离机理等内容。最后对发展基于COFs固定相的毛细管电色谱应努力解决的问题和该技术未来的发展方向进行了分析和展望。     

聚丙烯酸酯类毛细管整体柱的制备及其在加压毛细管电色谱中的应用

毛细管电色谱(CEC)是毛细管电泳(CE)和微径液相色谱(micro—HPLC)技术的结合,是集CE的电子迁移机制和micro-HPLC的分配分离机理发展起来的一种高效微分离技术．CEC以塞子流型的电渗流代替抛物线流型的压力流,具有CE的高效性,能够分离电中性化合物而具有HPLC的高选择性．     

毛细管电色谱柱及其固定相制备技术的进展

毛细管电色谱结合了毛细管电泳的高分离效率和高效液相色谱的高选择性,因而在这几年受到了越来越多的关注。本文介绍了近期毛细管电色谱柱及其固定相制备方法和应用的进展。     

分子印迹聚合物颗粒在毛细管电色谱中的应用

依据分子印迹技术(MIT)制备的分子印迹聚合物(MIP)颗粒对模板分子及其结构类似物具有特异性识别和选择性吸附作用,同时具有较大的比表面积和快速的传质动力学特性,因而被广泛用作液相色谱固定相和固相萃取材料。将MIP颗粒作为固定相应用于毛细管电色谱(CEC),结合了CEC的快速、高效和MIP的高亲和性、高选择性的特点,成为分析科学领域最具有发展前景的分离技术之一。MIP颗粒在CEC领域有几种不同的应用形式: 作为填充材料填充到毛细管柱中;作为嵌入材料嵌入到毛细管柱内部不同基质的骨架中;作为准固定相添加到CEC运行缓冲溶液中。本文综述了近几年MIP颗粒在CEC领域应用的发展,对该领域今后的发展前景进行了展望。     

光聚合整体式咖啡因印迹毛细管柱的制备及分离性能

分子印迹技术作为一种制备对目标分子具有专一识别能力的功能高分子的方法 ,近年来在化学化工、生物化学与生物技术的许多领域中得到广泛应用 [1～ 4 ] .分子印迹技术与微分离方法 (包括微柱液相色谱、毛细管电泳、毛细管电色谱和芯片分离等 )结合已引起人们极大的兴趣和关注[5,6] .毛细管柱是毛细管电色谱和微柱液相色谱的关键部件 ,目前普遍使用的是烷基键合硅胶微粒的填充柱 ,存在制备时须烧塞和填充两大困难 ,以及使用时易产生气泡和易折断等缺点 .将含被识别分子 (印迹分子 )、交联剂、溶剂、功能单体和引发剂的混合液注入毛细管 ,经光…     

毛细管电色谱研究进展

毛细管电色谱技术(CEC)是一种集微柱液相色谱的高选择性、多样性及高效毛细管电泳(HPCE)的高效性、高分辩率为一体的新的电泳分离技术。本文介绍了毛细管电色谱的历史、发展及研究现状;并对电色谱的基本理论与技术作了阐述。     

Sol-gel stationary phases for capillary electrochromatography

A review is presented on the current state of the art and future trends in the development of sol-gel stationary phases for capillary electrochromatography (CEC). The design and synthesis of stationary phases with prescribed chromatographic and surface charge properties represent challenging tasks in contemporary CEC research. Further developments in CEC as a high-efficiency liquid-phase separation technique will greatly depend on new breakthroughs in the area of stationary phase development. The requirements imposed on CEC stationary phase performance are significantly more demanding compared with those for HPLC. The design of CEC stationary phase must take into consideration the structural characteristics that will provide not only the selective solute/stationary phase interactions leading to chromatographic separations but also the surface charge properties that determine the magnitude and direction of the electroosmotic flow responsible for the mobile phase movement through the CEC column. Therefore, the stationary phase technology in CEC presents a more complex problem than in conventional chromatographic techniques. Different approaches to stationary phase development have been reported in contemporary CEC literature. The sol-gel approach represents a promising direction in this important research. It is applicable to the preparation of CEC stationary phases in different formats: surface coatings, micro/submicro particles, and monolithic beds. Besides, in the sol-gel approach, appropriate sol-gel precursors and other building blocks can be selected to create a stationary phase with desired structural and surface properties. One remarkable advantage of the sol-gel approach is the mild thermal conditions under which the stationary phase synthesis can be carried out (typically at room temperature). It also provides an effective pathway to integrating the advantageous properties of organic and inorganic material systems, and thereby enhancing and fine-tuning chromatographic selectivity of the created hybrid organic-inorganic stationary phases. This review focuses on recent developments in the design, synthesis, characterization, properties, and applications of sol-gel stationary phases in CEC.     

Molecular imprinting technology in capillary electrochromatography

Molecularly imprinted polymers (MIPs) are tailor-made synthetic polymers with a predetermined selectivity for a given analyte, or group of structurally related compounds, that make them ideal materials for use as stationary phases in affinity chromatography. However, extensive peak broadening and tailing, especially of the more retained compound (normally the template) are often observed. Thus, huge efforts have been made during recent years to use MIPs in capillary electrochromatography, which is inherently a more efficient chromatographic technique than conventional HPLC. Accordingly, this paper gives an overview of the attempts carried out in the recent past to improve the chromatographic performance of MIPs in capillary electrochromatography as well as more recent applications. It is concluded that MIPs are very promising materials for use as selective stationary phases in CEC.     

Monolithic stationary phases for fast ion chromatography and capillary electrochromatography of inorganic ions

The focus of this review is on current developments in monolithic stationary phases for the fast analysis of inorganic ions and other small molecules in ion chromatography (IC) and capillary electrochromatography (CEC), concentrating in particular on the properties of organic (polymer) monolithic materials in comparison to inorganic (silica-based) monoliths. The applicability of these materials for fast IC is discussed in the context of recent publications, including the range of synthesis and modification procedures described. While commercial monolithic silica columns already show promising results on current IC instrumentation, polymer-based monolithic stationary phases are currently predominantly used in the capillary format on modified micro-IC systems. However, they are beginning to find application in IC particularly under high pH conditions, with the potential to replace their particle-packed counterparts.     

Recent applications in capillary electrochromatography

The most recent and important applications in capillary electrochromatography (CEC) are summarized, covering literature published since May 2001. A selection of new developments in stationary phases for CEC is highlighted, and enantiomeric separations and chiral stationary phases are discussed. Also, CEC applications of biological molecules, pharmaceuticals, and applications in the field of industrial and environmental analysis are summarized. For this review three modes of CEC were taken into account, i.e., packed-column CEC, CEC using monolith technology, and open-tubular CEC.     

Monolithic enantiomer-selective stationary phases for capillary electrochromatography

Monolithic materials have become a well-established format for stationary phases in the field of capillary electrochromatography. Four types of monoliths, namely particle-fixed, silica-based, polymer-based, and molecularly imprinted monoliths, have been utilized as enantiomer-selective stationary phases in CEC. This review summarizes recent developments in the area of monolithic enantiomer-selective stationary phases for CEC. The preparative procedure and the characterization of these columns are highlighted. In addition, the disadvantages and limitations of different monolithic enantiomer-selective stationary phases in CEC are briefly discussed.     

Capillary electrochromatography with physically and dynamically absorbed stationary phases

Adsorption is always considered a troublesome effect in capillary electrophoresis (CE) and capillary electrochromatography (CEC). However, the adsorption effect can also be exploited to prepare or optimize the stationary phase in CEC. Compared with the chemical synthesis of new stationary phase materials for CEC, this method is simpler and more convenient. This review is focused on CEC with physically and dynamically adsorbed stationary phases. Separation of some acidic, basic and neutral solutes as well as enantiomers in CEC with dynamically adsorbed stationary phases are presented. The theory for the migration of charged solutes and the stationary phases currently used in CEC are also briefly reviewed.     

Recent progress in adsorbed stationary phases for capillary electrochromatography

This review surveys the recent progress in the adsorbed stationary phases for capillary electrochromatography (CEC). Adsorption-based methods for preparation of stationary phase are novel approaches in CEC, which allow rapid and facile preparing stationary phases with desirable selectivity onto an open-tubular fused-silica capillary, a bare-silica or ion-exchange packed column or a monolithic silica or polymer column. A variety of adsorbing agents have been developed as adsorbed stationary phases, including ionic long-chain surfactant, protein, peptide, amino acid, charged cyclodextrin (CD), basic compound, aliphatic ionene, and ion-exchange latex particle. The adsorbed stationary phases have been applied to separation of neutral, basic and acidic organic compounds, inorganic anions and enantiomers. They have also been applied to on-line sample concentration, fast separation and study of the competitive binding of enantiomers with protein.     

Chiral silica-based monoliths in chromatography and capillary electrochromatography

Chiral-modified silica-based monoliths have become well-established stationary phases for both high performance liquid chromatography (HPLC) and capillary electrochromatography (CEC). The silica-based monoliths were fabricated either in situ in the capillaries for nano-HPLC and CEC or in a mould for “conventional” HPLC. The present review summarizes the chiral modification of silica monoliths and the recent development in the field of enantioselective separations by nano-HPLC and CEC.     

毛细管电色谱和加压毛细管电色谱的进展与应用

毛细管电色谱(CEC)以内含色谱固定相的毛细管为分离柱,以电渗流为驱动力,既可以分离带电物质也可以分离中性物质。它结合了毛细管电泳和高效液相色谱两者的优点,兼具高柱效、高分辨率、高选择性和高峰容量的特点,同时具有色谱和电泳的双重分离机理。然而,“纯粹”的电色谱在实际应用中有着天然的弱点,即: 在电流通过毛细管柱中的流动相时容易产生气泡(焦耳热作用),从而使电流中断和电渗流停止,毛细管柱必须被重新用流动相润湿后方能再次使用。加压毛细管电色谱(pCEC)将液相色谱中的压力流引入CEC系统中,不仅解决了气泡、干柱等问题,而且实现了定量阀进样和二元梯度洗脱。CEC和pCEC作为微分离领域的两种前沿技术,满足了当前复杂样品分析和分析仪器微型化的需求,近年来获得了广泛的关注。本文综述了这两种技术近来的发展,包括仪器、色谱固定相的发展,总结了其在生命科学、药物分析、食品安全以及环保样品分析等方面的应用进展,评述了各方法的特点,并展望了CEC和pCEC今后的发展和应用前景。