新型大孔硅质酰胺型聚合物键合相的制备及其对蛋白质的分离

大孔硅胶与乙烯基硅烷反应后,再与甲基丙烯酰胺和二乙烯基苯共聚成一种新型分离蛋白质的色谱柱填料。考察了这种色谱填料对蛋白质的分离能力,认为其具有柱效高、惰性好和分离效率高的优点,聚合物键合相的制备重复性好。并探讨了流动相中离子强度和ｐＨ值对蛋白质分离的影响。     

硅胶涂敷正相色谱填料的制备及应用

在大孔硅胶表面键合乙烯基硅烷化试剂,然后与甲基丙烯酸环氧丙酯、甲基丙烯酸乙二醇双酯共聚,制得聚合物涂敷硅胶,其表面经一步水解即可得到正相高效液相色谱填料,考察了该填料对苯的衍生物及吡啶等有机化合物的分离情况.实验结果表明,硅胶涂敷正相色谱柱对中性、酸性和碱性化合物均具有良好的色谱分离性能.     

单分散高纯硅胶色谱柱填料的制备

在氨水和氨气催化下使单晶硅粉水解, 合成了单分散、高纯的纳米二氧化硅水溶胶; 再利用聚合诱导胶体凝聚法(PICA)制备单分散脲醛二氧化硅复合微球, 经过高温煅烧后得到球形硅胶色谱柱填料. 通过电感耦合等离子-质谱(ICP-MS)、电子显微镜和BET比表面积测试等手段对球形硅胶的纯度、粒径分布及比表面积进行了表征, 并通过色谱分离对硅胶填料的性能进行了评价. 实验结果表明, 该方法合成的色谱柱填料具有纯度高、粒径分布均匀、机械强度高及分离能力强等优点.     

附聚型锆胶基质阴离子交换微球的制备

离子色谱作为离子性物质(特别是无机阴离子)的最佳分离分析方法,一直受到分析工作者的关注[1].在离子色谱中,固定相是关键之一[2].当前广泛使用的离子色谱固定相主要有两类:一类是聚合物基质,如Dionex公司推广的薄壳型阴离子树脂填料,动力学性能十分出色].这类填料不仅用于无机正负离子,而且由于其对生物活性分子的相容性,也用于蛋白质等生物样品,它们的pH值适用范围宽,但不耐有机溶剂,刚性较差,高压下会变形,影响溶质传递速率.第二类是聚合物-载体复合基质,最常见的是在硅胶微粒表面键合上各种离子交换基团,如聚苯乙烯涂敷硅胶离子交换剂用于蛋白质、核苷酸的分离[4],国内杨瑞琴也报道了用聚马来酸包覆硅胶分离一价阳离子[5].     

亚油酸甲酯硅胶聚合物键合相的制备及对蛋白质的分离

1　引　　言从现代分离科学理论计算得出 ,色谱和电泳是目前所知道最好的两种分离方法 ,但是 ,因受各种因素的限制 ,电泳目前尚不能用于生产规模的生物大分子的分离和纯化。这就是把分离和纯化生物大分子 (包括蛋白质、酶、核酸、多糖等 )的研究重点放在色谱上的原因。在生物技术制取蛋白质的多级纯化过程中 ,液相色谱是一个必需步骤。为了获得生物大分子的快速分离就得从基质到键合基团不断改进色谱柱填料。在本文中介绍的柱填料是键合在大孔硅胶上的乙烯基与亚油酸甲酯和二乙烯基苯共聚形成的。从蛋白质混合样品洗脱曲线看出这一填料具有…     

新型壳聚糖液相色谱填料及其在生物分子分离中的应用

研制了壳聚糖键合硅胶和壳聚糖涂层交联硅胶填料。考察了这两种液相色谱填料对几种小肽、蛋白质和单糖的色谱保留行为。发现它们对小肽有一定的分离能力,在蛋白质的分离中有一定特色,但对单糖的保留不大。     

乙烯基功能化聚甲基倍半硅氧烷色谱填料的制备与评价

以乙烯基三甲氧基硅烷(VTMS)和甲基三甲氧基硅烷(MTMS)为前体,通过酸碱催化水解共缩聚的方法制备得到单分散多孔乙烯基功能化聚甲基倍半硅氧烷(V-PMSQ)微球。当前体混合物中VTMS的摩尔分数从0增加到100%时,微球的比表面,孔容和孔径均单调减小,孔隙率从65%降低至12%。微球的碳含量在16.6%~25.7%的范围内,与十八烷基键合硅胶填料相当。在进行色谱评价时,碱性药物阿米替林表现出对称的峰型,表明微球的硅羟基活性较低。在高p H流动相的条件下,30%和50%VTMS含量的填料可以实现4种碱性药物的基线分离。具有较大p H使用范围的乙烯基功能化聚甲基倍半硅氧烷色谱填料在分离碱性化合物方面具有较大的优势。     

液相色谱交联聚苯乙烯固定相的填充

装柱技术是影响液相色谱柱效能的重要因素之一,对硅胶基填料的填充已有深入研究,并有规范操作方法,而对于聚合物微球填料的填充则报道很少。聚合物微球中交联聚苯乙烯不仅具有较好的化学稳定性,而且根据其孔的大小既适于小分子的反     

硅胶聚合物键合相键合基团及流动相盐浓度和pH值对蛋白质分离的影响

介绍了３种同孔径不同键合基团的大孔径硅胶聚合物键上的合成，３种填料是在１００ｎｍ孔径硅胶上键合乙烯基后，分别与甲基丙烯酸羟乙基酯，二乙烯基苯共聚形成ＨＤＳＩ填料；与甲基丙烯酰胺共聚形成ＰＡＭＳＩ填料；与顺丁烯二酸共聚再与乙二胺反应形成ＰＦＭＳＩ填料。比较了它们对蛋白质分离的特性。     

硅胶基质高效液相色谱填料研究进展

高效液相色谱(HPLC)不仅是一种有效的分析分离手段,也是一种重要的高效制备分离技术。色谱柱是HPLC系统的核心,不同性能的填料是HPLC广泛应用的基础。硅胶是开发最早、研究最为深入、应用最为广泛的HPLC固定相基质,其制备方法主要有喷雾干燥法、溶胶-凝胶法、聚合诱导胶体凝聚法及模板法等。近年来,亚2μm小粒径硅胶、核-壳型硅胶、双孔径硅胶、介孔性硅胶、有机杂化硅胶等新型硅胶应用于HPLC并取得了色谱分离技术的飞速发展,例如基于亚2μm填料的超高压液相色谱技术、基于核-壳型填料的快速分离技术、基于杂化硅胶填料的高温液相色谱技术等。硅胶经表面化学键合、聚合物包覆等有机改性可制得先进的大分子限进填料、温敏性填料、手性填料等,大大扩展了HPLC的应用范围。本文对液相色谱用硅胶的制备方法、改性与修饰方法以及硅胶基质固定相的评价方法加以系统综述,概述了新型硅胶在HPLC中的应用进展,并对硅胶基质填料的发展方向与应用前景进行了展望。     

Study on the morphological regulation mechanism of hollow silica microsphere prepared via emulsion droplet template

The morphology regulation of hollow silica microspheres is significant for their properties and applications. In this paper, hollow silica microspheres were formed through the hydrolysis and condensation reaction of tetraethyl orthosilicate (TEOS) at the interface of the emulsion droplet templates composed of liquid paraffin and TEOS, followed by dissolving paraffin with ethanol. The effects of various factors including the emulsifier structure and content, TEOS content, catalyst type, and the ethanol content in the continuous water phase on the particle size, shell thickness and morphology of the prepared hollow silica microspheres were studied in detail. The results show that the diffusion and contact of TEOS and water molecules as well as the hydrolysis condensation reaction of TEOS at the oil-water interface are two critical processes for the synthesis and morphological regulation of hollow silica microspheres. Cationic emulsifier with a hydrophobic chain of appropriate length is the prerequisite for the successful synthesis of hollow silica microspheres. The ethanol content in water phase is the dominant factor to determine the average diameter of hollow microspheres, which can vary from 96 nm to 660 nm with the increase of the volume ratio of alcohol-water from 0 to 0.7. The silica wall thickness varies with the content and the hydrophobic chain length of the emulsifier, TEOS content, and the activity of the catalyst. The component of the soft template will affect the morphology of the silica wall. When the liquid paraffin is replaced by cyclohexane, hollow microspheres with fibrous mesoporous silica wall are fabricated. This work not only enriches the basic theory of interfacial polymerization in the emulsion system, but also provides ideas and methods for expanding the morphology and application of hollow silica microspheres.     

聚合物模板微球表面电性对中空二氧化硅微球形貌的影响

分别以过硫酸钾和偶氮二异丁基脒盐酸盐为引发剂,以聚乙烯吡咯烷酮(PVP)为分散剂,在水中引发苯乙烯聚合制备了2种表面分别带负电性和正电性基团的聚苯乙烯(PS)模板微球.在氨水催化下,利用正硅酸乙酯的水解缩合,形成PS/SiO_2复合微球,去除模板后得到中空SiO_2微球,并对其进行FTIR、电子显微镜、TGA以及氮气吸附等分析表征.结果表明,PS模板微球表面的电性决定了OH-的分布,从而导致PS模板微球表面SiO_2壳层不同的形成机制.当以表面带负电的PS微球为模板时,可得到树莓状的中空SiO_2微球;而以表面带正电的PS微球为模板时,得到是表面光滑的,具有介孔结构的中空SiO_2微球.     

Preparation of hollow silica microspheres with controlled shell thickness in supercritical fluids

This article presents a novel route to prepare hollow silica microspheres with well-defined wall thickness by using cross-linked polystyrene (PS) microspheres as templates with the assistance of supercritical carbon dioxide (SC-CO₂). In this approach, the cross-linked PS templates can be firstly prepared via emulsifier-free polymerization method by using ethylene glycol dimethacrylate or divinylbenzene as cross-linkers. Then, the silica shell from the sol–gel process of tetraethyl orthosilicate (TEOS) which was penetrated into the PS template with the assistance of SC-CO₂ was obtained. Finally, the hollow silica spheres were generated after calcinations at 600 °C for 4 h. The shell thickness of the hollow silica spheres could be finely tuned not only by adjusting the TEOS/PS ratio, which is the most frequently used method, but also by changing the pressure and aging time of the SC-CO₂ treatment. Fourier transform infrared spectroscopy, transmission electron microscopy, and scanning electron microscope were used to characterize these hollow silica spheres.     

Preparation of silica microspheres with a broad pore size distribution and their use as the support for a coated cellulose derivative chiral stationary phase

A templating strategy using crosslinked and functionalized polymeric beads to synthesize silica microspheres with a broad pore size distribution has been developed. The polymer/silica hybrid microspheres were prepared by utilizing the combination of a templating weak cation exchange resin, a structure‐directing agent N‐trimethoxysilylpropyl‐N,N,N‐trimethylammonium chloride, and a silica precursor tetraethyl orthosilicate. The silica microspheres were then obtained after calcinating the hybrid microspheres. The as‐prepared materials were characterized by scanning electron microscopy, mercury intrusion porosimeter, and thermal gravimetric analysis. The results showed that the starting templating beads were about 5 μm in diameter and the formed silica microspheres were less than 3 μm with a pore size range of 10–150 nm, some pores were even extended to beyond 250 nm. It was demonstrated that cellulose tris(3,5‐dimethylphenylcarbamate) was readily coated onto the surface of the as‐synthesized silica microspheres without any additional surface pretreatment. The coated silica microspheres were uniformly dispersed even with high loading of the chiral stationary phase, which exhibited high resolution chiral separations in high‐performance liquid chromatography.     

Preparation of Porous Hollow SiO2 Spheres by a Modified St?ber Process Using MF Microspheres as Templates

Using the surface charged and acid dissolvable melamine formaldehyde (MF) microspheres as sacrificial hard templates, silica coated MF core?Cshell composite microspheres, denoted as MF@SiO₂, were synthesized via a surfactant-assisted sol?Cgel process by using tetraethyl orthosilicate (TEOS) as silica source. Hollow SiO₂ spheres with mesoporous shells were then obtained after selective removal of the MF cores and the pore directing surfactant by hydrochloric acid etching or calcinations in air. Interesting shrinkage phenomena were observed in both the hollow products derived from hydrochloric acid etching and calcinations. The influence of the ratio of MF sphere to TEOS and the removal method of the MF core on the size of the hollow spheres, the shell thickness and the shell surface roughness have been studied. The composition, the thermal stability, the morphology, the surface area and pore size distribution, the wall thickness and adsorption properties of the hollow spheres derived from hydrochloric acid etching and calcinations were also investigated and compared based on the FTIR, SEM, TEM, TGA, Nitrogen adsorption?Cdesorption and spectrophotometer techniques or measurements.     

Preparation and characterization of polymer/silica nanocomposites via double in situ miniemulsion polymerization

Polymer/SiO₂ nanocomposite microspheres were prepared by double in situ miniemulsion polymerization in the presence of methyl methacrylate, butyl acrylate, γ‐methacryloxy(propyl) trimethoxysilane, and tetraethoxysilane (TEOS). By taking full advantage of phase separation between the growing polymer particles and TEOS, inorganic/polymer microspheres were fabricated successfully in a one‐step process with the formation of SiO₂ particles and the polymerization of organic monomers taking place simultaneously. The morphology of nanocomposite microspheres and the microstructure, mechanical properties, thermal properties, and optical properties of the nanocomposite films were characterized and discussed. The results showed that hybrid microspheres had a raspberry‐like structure with silica nanoparticles on the shells of polymer. The silica particles of about 20 nm were highly dispersed within the nanocomposite films without aggregations. The transmittance of nanocomposite film was comparable to that of the copolymer film at around 70–80% from 400 to 800 nm. The mechanical properties and the fire‐retardant behavior of the polymer matrix were improved by the incorporation of silica nanoparticles. © 2010 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 48: 3128–3134, 2010     

Facile synthesis of amino-functionalized hollow silica microspheres and their potential application for ultrasound imaging

By using the positive charged polystyrene (PS) microsphere as template, mono-disperse amino-(-NH(2)) functionalized hollow silica microspheres (HSMS-NH(2)) with ~1310 nm in diameter and uniform shells were successfully prepared with a modified sol-gel process. The amino functionalized silica were coated on the PS microspheres via ammonia catalysis, co-hydrolysis and condensation of TEOS and APTES, and then the PS templates were selectively dissolved in THF solution to form the functional hollow microspheres. The controllable thickness (35-85 nm) and amino density (2.46×10(-5)-6.18×10(-5) mol/g) of the shells could be facilely tuned by changing the amount of TEOS and APTES. In vitro ultrasound images of as-prepared HSMS-NH(2) with different concentrations in the physiological saline solution were further investigated. The obvious signal enhancement indicates that as-prepared HSMS-NH(2) has a great potential application for ultrasound imaging.     

Effects of pH on mechanical and morphological studies of silica filled polyvinyl chloride-50% epoxidized natural rubber (PVC-ENR50) nanocomposite

Effects of pH on mechanical properties as well as morphological studies of sol–gel derived in situ silica in polyvinyl chloride-50% epoxidized natural rubber (PVC-ENR50) nanocomposites are reported. In particular, a range of acid concentrations was investigated. These nanocomposites were prepared by solution casting technique and tetraethoxysilane (TEOS) was used as the silica precursor. The prepared nanocomposites were characterized using tensile test, scanning electron microscopy (SEM) and transmission electron microscopy (TEM). The tensile test indicated that the highest mechanical strength was at 30% TEOS added for the nanocomposite prepared at pH 2.0. At pH 1.0 and 1.5 the maximum tensile strength reading was at 20% TEOS added with value of 24.3 and 24.5 MPa, respectively. SEM and TEM revealed the dispersion of silica particles in the polymer matrix. For nanocomposites prepared at pH 1.0 and 1.5, the silica particles were finely dispersed with the average size of 60 nm until 20% TEOS added. Meanwhile for nanocomposite prepared at pH 2.0, silica particles were homogenously distributed in the polymer matrix with average diameter of 30 nm until 30% TEOS and agglomerated after 30% TEOS loading.     

Preparation of Hollow Silica Microspheres via Poly(N-isopropylacrylamide)

Core-shell structured SiO₂/poly(N-isopropylacrylamide) (SiO₂/PNIPAM) microspheres were successfully fabricated through hydrolysis and condensation reaction of tertraethyl or-thosilicate (TEOS) on the surface of PNIPAM template at 50 oC. The PNIPAM template can be easily removed by water at room temperature so that SiO₂ hollow microspheres were finally obtained. The transmission electron microscope and scanning electron microscope observations indicated that SiO₂ hollow microspheres with an average diameter of 150 nm can be formed only if there are enough concentration of PNIPAM and TEOS, and the hy-drolysis time of TEOS. FTIR analysis showed that part of PNIPAM remained on the wall of SiO₂ because of the strong interaction between PNIPAM and silica. This work provides a clean and efficient way to prepare hollow microspheres.     

Acrylic polymer/silica hybrids prepared by emulsifier‐free emulsion polymerization and the sol–gel process

Acrylic polymer/silica hybrids were prepared by emulsifier‐free emulsion polymerization and the sol–gel process. Acrylic polymer emulsions containing triethoxysilyl groups were synthesized by emulsifier‐free batch emulsion polymerization. The acrylic polymer/silica hybrid films prepared from the acrylic polymer emulsions and tetraethoxysilane (TEOS) were transparent and solvent‐resistant. Atomic force microscopy studies of the hybrid film surface suggested that the hybrid films did not contain large (e.g., micrometer‐size) silica particles, which could be formed because of the organic–inorganic phase separation. The Si? O? Si bond formed by the cocondensation of TEOS and the triethoxysilyl groups on the acrylic polymer increased the miscibility between the acrylic polymer component and the silica component in the hybrid films, in which the nanometer‐size silica domains (particles) were dispersed homogeneously in the acrylic polymer component. © 2005 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 44: 273–280, 2006