有机聚合物整体柱及其在生物大分子色谱分离中的应用

整体柱是近年发展起来的一种新型的色谱分离分析技术，与传统的色谱柱相比，具有制作简单、背压低、分辨率高、柱容量大等优点。本文介绍了有机聚合物整体柱及其在生物大分子色谱分离领域的应用，分析了其存在的问题，并展望了其应用前景。     

色谱最新研究亮点——新型功能化色谱分离介质的研究进展

整体柱由于具有制备方法简单、通透性好、柱容量大、易实现快速分离的优点,近年来在生物大分子的高效、快速、高通量分离分析方面得到了较快的发展。但是由于有机聚合物整体柱的表面积小（只有几十平米/g）,内部结构不均一,因此还存在分离小分子物质柱效低的缺点。最近,人们在努力寻求一种较为完美的低压高效的功能化色谱分离介质的制备方法,以期能够在大分子和小分子等多种物质的分离分析中得到普遍应用。     

新型功能化色谱分离介质的研究进展

整体柱由于具有制备方法简单、通透性好、柱容量大、易实现快速分离的优点,近年来在生物大分子的高效、快速、高通量分离分析方面得到了较快的发展。但是由于有机聚合物整体柱的比表面积小(每克只有几十平方米)、内部结构不均一,因此还存在分离小分子物质时柱效低的缺     

高效液相色谱整体柱在药物分离分析中的应用进展

本文对高效液相整体柱在药物分离分析方面的应用进行了综述.主要介绍了以烷氧基硅烷为主要原料,采用溶胶-凝胶法制备的硅胶整体柱,由于其具有微米级通孔结构和大的比表面积,他们在高效、快速分离小分子物质方面得到广泛地应用.对于聚合物整体柱,主要介绍了包括分子印迹聚合物在内的有机聚合物整体柱在药物分离、生物样品的处理等方面的应用.     

有机聚合物整体柱及其在生物样品分离分析前处理中的应用

整体柱由于具有制备简单、内部结构均匀、重现性好、柱效较高和可进行快速分离等优点,在分离、催化等众多领域具有良好的应用前景。 本文综述了近年来有机聚合物整体柱在生物样品分离分析中的应用,并对其存在的问题和发展趋势进行了讨论。     

二乙烯苯-苯乙烯交联聚合物包覆毛细管硅胶整体柱的制备与评价

在优化条件下制备了一类新型的无机-有机复合型毛细管整体柱.即通过在硅胶毛细管整体柱柱床上包覆纳米级聚合物薄膜得到了二乙烯基苯-苯乙烯交联聚合包覆的硅胶整体柱,突破了有机聚合物和无机硅胶整体柱的界限,使之兼具无机、有机两种基质的优点,从而拓展了硅胶整体柱的应用范围.考察了这种交联聚合物包覆的硅胶毛细管整体柱的结构特征和μ-HPLC性能,并成功分离了稠环芳烃类系列小分子化合物,其对于萘的柱效可达28 000 N/m.     

有机-硅胶杂化整体柱的制备及应用研究进展

有机-硅胶杂化整体柱结合了有机聚合物整体柱和硅胶整体柱的优势, 具有制备简单、机械强度高和通透性好等优点, 近年来备受关注. 有机-硅胶杂化整体柱的制备方法主要有常规溶胶-凝胶法、“一锅法”和其它聚合方法. 目前, 杂化整体柱已被广泛应用于微纳尺度分离分析、样品预处理和固定化酶反应器基质中. 本文综述了有机-硅胶杂化整体柱的制备方法及应用研究进展, 并展望了其今后的发展前景.     

化学工业出版社化学专业图书推荐

正《液相色谱分离材料——制备与应用》欧俊杰、邹汉法等编著本书以固定相分类,系统介绍了各种液相色谱分离材料和整体柱的制备及应用技术,内容包括:球形硅胶微球固定相、有机聚合物     

《色谱》第25卷总目次

色谱固定相专栏121引言张玉奎,邹汉法122整体材料研究进展及其在微柱分析领域中的应用朱贵杰,张丽华,梁振,张维冰,张玉奎129分子印迹整体柱在高效液相色谱和电色谱手性分离中的应用欧俊杰,董靖,吴明火,孔亮,邹汉法135亲和色谱中配基的筛选与应用赵睿,刘国诠142有机聚合物整体柱     

手性有机聚合物毛细管电色谱整体柱研究进展

毛细管电色谱具有高分离效率、多种保留机制和高选择性的优点。近年来,利用毛细管电色谱进行对映异构体的手性拆分受到了广泛关注。相对于传统的填充柱和开管柱,整体柱在手性拆分方面具有显著优势。与手性硅基整体柱相似,手性有机聚合物整体柱由于具有大孔,可产生较高的流速而压降较小。该文综述了近十年手性有机聚合物整体柱制备方法的研究进展,将手性有机聚合物整体柱的制备方法分为"原位聚合法"和"手性修饰法"两种,虽然前者制备简单并广泛应用于早期研究,但聚合混合液成分的微小改变即可引起最终聚合物的形态变化,并且大部分带丙烯基的手性选择剂较难从市场购买。因此,手性修饰法因作为手性选择剂基质的整体柱制备且优化只需进行一次的优势而受到普遍关注。亲核取代、杂环开环和点击化学是常用的修饰手段。该文总结了这两种制备方法的应用,同时对未来的研究方向提出参考性意见。     

Monolithic bed structure for capillary liquid chromatography

Monolithic stationary phases show promise for LC as a result of their good permeability, ease of preparation and broad selectivity. Inorganic silica monoliths have been extensively studied and applied for separation of small molecules. The presence of a large number of through pores and small skeletal structure allows the chromatographic efficiencies of silica monoliths to be comparable to columns packed with 5 μm silica particles, at much lower back pressure. In comparison, organic polymeric monoliths have been mostly used for separation of bio-molecules; however, recently, applications are expanding to small molecules as well. Organic monoliths with high surface areas and fused morphology rather than conventional globular morphology have shown good performance for small molecule separations. Factors such as domain size, through-pore size and mesopore size of the monolithic structures have been found to govern the efficiency of monolithic columns. The structure and performance of monolithic columns are reviewed in comparison to particle packed columns. Studying and characterizing the bed structures of organic monolithic columns can provide great insights into their performance, and aid in structure-directed synthesis of new and improved monoliths.     

纳米材料掺杂聚合物整体柱的构筑及在前处理领域的应用

聚合物整体柱是由单体、交联剂、引发剂和致孔剂在模具中通过原位聚合而成的棒状整体.与传统的填充式固相萃取柱相比,聚合物整体柱吸附剂凭借制备简单、柱压低、传质快及pH使用范围宽泛等优点已广泛应用于食品分析、生物医药和环境卫生等领域的前处理中.然而,通常由于聚合方式难以控制,聚合物整体柱在制备过程中容易产生颗粒堆积、孔道不均...     

Open-celled polymeric foam monoliths for heavy metal separations study

Open-celled polymeric foam monoliths prepared by high internal phase emulsion polymerization (HIPE) are being investigated as improved materials for separation of heavy metals. In column flow studies, the foam monoliths have high flow rates and are durable up to at least 40 psi. A 4-vinylpyridine functionality has been incorporated into vinylbenzylchloride/styrene copolymer foams by graft-polymerization of vinylpyridine. The open structure of the foam and the flexible graft-polymerized ion-exchange chains result in improved kinetics in metal uptake. Iron uptake kinetics were greatly increased in the grafted foams over resin beads of similar structure. Plutonium uptake kinetics were moderately increased in the foams.     

Biocompatible polymeric monoliths for protein and peptide separations

The concept of biocompatibility with reference to chromatographic stationary phases for separation of biomolecules (including proteins and peptides) is introduced. Biocompatible is a characteristic that indicates resistance to nonspecific adsorption of biomolecules and preservation of their structures and biochemical functions. Two types of biocompatible polymeric monoliths [i. e., polyacrylamide‐ and poly(meth)acrylate‐based monoliths] used for protein and peptide separations are reviewed in detail, with emphasis on size exclusion, ion exchange, and hydrophobic interaction chromatographic modes. Biocompatible monoliths for enzyme reactors are also included. The two main synthetic approaches to produce biocompatible monoliths are summarized, i. e., surface modification of a monolith that is not inherently biocompatible and direct copolymerization of hydrophilic monomers to form a biocompatible monolith directly. Integration of polyethylene glycol into the poly(meth)acrylate monolith network is becoming popular for reduction of non‐specific protein interactions.     

Recent advances in polymer monoliths for ion-exchange chromatography

The use of polymeric materials in ion-exchange chromatography applications is advantageous because of their typically high mechanical stability and tolerance of a wide range of pH conditions. The possibility of using polymeric monoliths in ion-exchange chromatography is therefore obvious and many of the same strategies developed for polymeric particles have been adapted for use with polymeric monoliths. In this review different strategies for the synthesis of polymeric monoliths with ion-exchange functionality are discussed. The incorporation of ion-exchange functionality by co-polymerization is included, as also are different post-polymerization alterations to the monolith surface such as grafting. The formulations and strategies presented include materials intended for use in analytical separations in ion-exchange chromatography, sample pre-treatment or enrichment applications, and materials for capillary electrochromatography. Finally, examples of the use of polymeric monoliths in ion-exchange chromatography applications are included with examples published in the years 2003 to 2008.

Recent strategies to enhance the performance of polymer monoliths for analytical separations

This review summarizes recent developments made in the incorporation of functional materials into organic polymer monoliths, together with new monolithic forms and formats, which enhance their application as supports and stationary phase materials for sample preparation and chromatographic separations. While polymer monoliths are well‐known supports for the separation of large molecules, recent developments have been made to improve their features for the separation of small molecules. The selectivity and performance of organic polymer monoliths has been improved by the incorporation of different materials, such as metal‐organic frameworks, covalent organic frameworks, or other types of nanostructured materials (carbon nanohorns, nanodiamonds, polyoxometalates, layered double hydroxides, or attapulgite). The surface area of polymer monoliths has been significantly increased by polymer hypercrosslinking, resulting in increased efficiency when applied to the separation of small molecules. In addition, recent exploration of less conventional supports for casting polymer monoliths, including photonic fibres and 3D printed materials, has opened new avenues for the applications of polymer monoliths in the field of separation science. Recent developments made in these topics are covered, focusing on the strategies followed by the authors to prepare the polymer monoliths and the effect of these modifications on the developed analytical applications.     

Porous polymer monoliths for small molecule separations: advancements and limitations

Porous polymer monoliths are considered to be one of the major breakthroughs in separation science. These materials are well known to be best suited for the separation of large molecules, specifically proteins, an observation most often explained by convective mass transfer and the absence of small pores in the polymer scaffold. However, this conception is not sufficient to explain the performance of small molecules. This review focuses in particular on the preparation of (macro)porous polymer monoliths by simple free-radical processes and the key events in their formation. There is special focus on the fluid transport properties in the heterogeneous macropore space (flow dispersion) and on the transport of small molecules in the swollen, and sometimes permanently porous, globule-scale polymer matrix. For small molecule applications in liquid chromatography, it is consistently found in the literature that the major limit for the application of macroporous polymer monoliths lies not in the optimization of surface area and/or modification of the material and microscopic morphological properties only, but in the improvement of mass transfer properties. In this review we discuss the effect of resistance to mass transfer arising from the nanoscale gel porosity. Gel porosity induces stagnant mass transfer zones in chromatographic processes, which hamper mass transfer efficiency and have a detrimental effect on macroscopic chromatographic dispersion under equilibrium (isocratic) elution conditions. The inherent inhomogeneity of polymer networks derived from free-radical cross-linking polymerization, and hence the absence of a rigid (meso)porous pore space, represents a major challenge for the preparation of efficient polymeric materials for the separation of small molecules.     

Voltage-assisted capillary LC of peptides using monolithic capillary columns prepared by ring-opening metathesis polymerization

We examined the use of monolithic capillary columns prepared via ring-opening metathesis polymerization (ROMP) for peptide separation in voltage-assisted capillary LC (voltage-assisted CLC). In order to demonstrate their potential for peptide separation, ROMP-derived monoliths with RP properties were prepared. The preparation procedure of monoliths was transferred from ROMP monoliths optimized for CLC. ROMP monoliths were synthesized within the confines of 200 microm id fused-silica capillaries with a length of 37 cm. After optimization of the chromatographic conditions, the separation performance was tested using a well-defined set of artificial peptides as well as two peptidic mixtures resulting from a tryptic digest of BSA as well as a collagenase digest of collagen. ROMP monoliths showed comparable performance to other monolithic separation media in voltage-assisted CLC published so far. Therefore, we conclude that by optimizing the composition of the ROMP monoliths as well as by using the controlled manner of their functionalization, ROMP monoliths bear a great potential in CLC and CEC.     

On the separation of small molecules by means of nano-liquid chromatography with methacrylate-based macroporous polymer monoliths

Macroporous monolithic poly(butyl methacrylate-co-ethylene dimethacrylate) stationary phases were synthesized in the confines of 100 μm I.D. fused-silica capillaries via a free radical copolymerization of mono and divinyl monomeric precursors in the presence of porogenic diluents. These columns were used in order to determine their suitability for the reversed-phase separation of small molecules in isocratic nano-LC mode. Carefully designed experiments at varying realized phase ratio by a terminated polymerization reaction, as well as content of organic modifier in the mobile phase, address the most significant parameters affecting the isocratic performance of these monoliths in the separation of small molecules. We show that the performance of methacrylate-based porous polymer monoliths is strongly affected by the retention factor of the analytes separated. A study of the porous and hydrodynamic properties reveals that the actual nature of the partition and adsorption of the small analyte molecules between mobile and stationary (solvated) polymer phases are most crucial for their performance. This is due to a significant gel porosity of the polymeric stationary phase. The gel porosity reflects stagnant mass transfer zones restricting their applicability in the separation of small molecules under conditions of strong retention.     

The effect of the pore structure and zeta potential of porous polymer monoliths on separation performance in ion-exchange mode

Most often, in bioseparations involving charged macromolecules, the chromatographic systems have low Reynolds and high Peclet numbers. For such systems, an expression is developed and presented in this work for evaluating the throughput in polymeric monoliths where ion-exchange adsorption occurs, as a function of (i) the pressure drop along the length of the monolith, (ii) the functional form and width of the throughpore-size distribution of the monolith, and (iii) the magnitude of the zeta potential on the surface of the throughpores of the monolith. Gaussian and log-normal throughpore-size distributions whose mean throughpore-size and standard deviation values are based on experimentally measured throughpore-size distribution data by mercury porosimetry employed on polymeric monoliths are used in this work, and their effect on the throughput relative to that obtained from a polymeric monolith having a uniform throughpore-size distribution is studied for different values of the ratio of the standard deviation to the mean throughpore-size. The results indicate that relatively modest increases in the throughput, when compared with the throughput that could be achieved in a polymeric monolith having a uniform throughpore-size distribution, could be obtained in polymeric monoliths having disperse throughpore-size distributions, and the magnitude of the increase becomes larger when the disperse distribution is skewed to larger throughpore sizes. Furthermore, the results of this work indicate that, under certain conditions, relatively modest increases in the throughput of a charged analyte could also be achieved by altering the value of the zeta potential on the surface of the throughpores of the monolith. Due to the difficulties inherent in controlling the functional form and width of the throughpore-size distribution during the synthesis of polymeric monoliths, it would appear to be more practical to increase the value of the throughput of a charged analyte by altering the value of the zeta potential through prudent selection of the ion-exchange surface functional groups and fine-tuned with the pH of the mobile phase. Thus, for ion-exchange chromatography systems, the zeta potential could be considered an important parameter for column designers and operators to manipulate, since its alteration could increase the through-put of a charged analyte in polymeric monoliths or in columns packed with charged particles.