聚合物包覆二氧化锆液相色谱固定相的制备与评价

在溶液体系中通过自由基引发长链碳烯-1、二乙烯苯和乙烯基二氧化锆交联聚合反应得到聚长链碳烯-苯乙烯包覆二氧化锆固定相.考察了这种交联聚合物包覆柱填料的色谱性能和化学稳定性,并用这种填料分离了稠环芳烃和碱性化合物.     

活性自由基聚合(Iniferter)法制备聚合物包覆硅胶固定相及其色谱性能评价

应用活性自由基聚合法, 在接枝iniferter的硅球表面键合甲基丙烯酸异辛酯-co-乙二醇二甲基丙烯酸酯聚合层, 制备了聚合物包覆硅胶色谱固定相, 并研究了合成条件对于聚合层及分离效果的影响. 在一定聚合时间中, 接枝聚合物质量与反应时间呈线性关系, 并可以在得到聚合物包覆硅胶的基础上, 利用包覆硅胶中的iniferter再次引发接枝聚合, 体现了活性自由基聚合的特点. 聚合物包覆硅胶对于烷基苯同系物、碱性化合物及羟基苯甲酸酯具有很好的色谱分离能力及柱效, 同时, 由于聚合层能够有效地覆盖硅球表面的硅羟基, 减小了碱性化合物的拖尾. 研究工作提供了新的聚合物包覆硅胶固定相的合成方法.     

肝素温度敏感色谱填料的制备与性能研究

利用自由基聚合法制备了含有聚(N-异丙基丙烯酰胺/N-丙烯酰氧琥珀酰亚胺)和肝素共聚物的温度敏感的亲和色谱填料; 通过热失重分析得到该填料表面聚合物的接枝率为9.45%; Elison-Morgan 法测定该填料表面的肝素含量为3.6mg/g. 将其用作HPLC 固定相, 分离苯和氢化可的松, 表明该色谱固定相具有温度敏感特性; 该色谱柱对凝血酶具有较强的亲和作用, 通过控制温度缩短了凝血酶的释放时间, 回收率为81.4%, 这为蛋白质的分离提供了一个快速有效的方法.     

八碳烯和十八碳烯与二乙烯基苯交联聚合包覆二氧化钛固定相的合成及反相色谱性能的评价

分别合成了八碳烯-1以及十八碳烯-1与二乙烯基苯交联聚合包覆二氧化钛固定相,对它们进行了元素分析和漫反射红外光潜的表征,并用这两种填料分离了稠环芳烃、烷基苯、苯胺类碱性化合物、卤代苯.实验证明这种交联聚合包覆崮定相对有机流动相和碱具有高稳定性.最后将两种固定相用于合成药中辛伐他汀和洛伐他汀的分离检测.     

二氧化锆微球表面键合磺化交联聚苯乙烯固相萃取填料的制备及应用

以聚合诱导胶体凝聚法(PICA)制备二氧化锆微球,用钛酸酯偶联剂对其进行表面改性,使其接枝上碳碳双键基团。在溶液体系中,该双键与单体苯乙烯和二乙烯苯在自由基引发下交联聚合,形成的聚合物包覆在二氧化锆微球表面。再通过磺化方法将磺酸基离子连接到苯环上,得到阳离子交换固相萃取填料。通过红外光谱、扫描电镜/X射线能谱等手段对其进行了表征。将装填得到的固相萃取柱与高效液相色谱联用,测定了水中的甲基磺草酮、阿特拉津和乙草胺。3种化合物的色谱峰面积与质量浓度呈良好的线性关系,相关系数(r²)均大于0.99;甲基磺草酮、阿特拉津和乙草胺的检出限分别为5.41、6.72和13.4 μg/L。结果表明,制得的聚合物包覆二氧化锆微球的粒径为6~8 μm,用该填料制成的固相萃取小柱对3种目标物的吸附率高。     

包覆聚丁二烯型HPLC柱填料的制备与评价

王俊德等［１］预言,未来的ＨＰＬＣ分离介质很可能是在无机填料表面包敷一层有机聚合物的复合体．因为此类填料既弥补了键合硅胶固定相ｐＨ应用范围窄及残余硅羟基易引起不可逆吸附使峰形拖尾等不足,又克服了聚合物填料的刚性差及难以进行梯度淋洗等缺陷．近年来,关于...     

原子转移自由基聚合制备PDMAEMA亲水作用色谱固定相及其性能评价

以甲基丙烯酸二甲氨乙酯为单体,2-溴异丁酰溴为引发剂,CuBr/五甲基二乙烯基三胺(PMDETA)为催化剂,通过原子转移自由基聚合(ATRP)反应,将甲基丙烯酸二甲氨乙酯(DMAEMA)接枝到5μm大孔硅胶表面上,得到了接枝聚合物(PDMAEMA)亲水作用色谱固定相.通过改变反应体系中单体的量,制备了三种不同接枝量的亲水作用色谱固定相,利用元素分析对所制备的固定相进行了表征.详细考察了该固定相的分离性能以及流动相中盐浓度、水含量对溶质保留行为的影响,并将该固定相用于宁心宝胶囊中核苷类化合物的分离和测定.在亲水模式下,该固定相可以基线分离7种核苷类化合物,保留时间随着接枝量的增加而增大,与氨基亲水作用色谱柱相比,该合成柱的分离效率高,溶质在该填料上的保留符合分配作用保留机理.实验结果表明,该填料具有良好的分离性能.     

弱酸型阳离子色谱填料的研制及性能评价

合成制备了一种新型弱阳离子色谱柱填料,以6 μm的单分散聚苯乙烯二乙烯基苯(St-DVB)微球为基球,对其进行化学改性得到阳离子色谱固定相.分别用碱金属及碱土金属离子对用该填料制成的色谱柱的色谱性能进行了测试,结果表明该柱填料对常见阳离子具有很好的分离效果、良好的重复性和低的检出限.     

用线性溶剂化能相关(LSERs)方法评价聚合物包覆钛胶固定相并与相关固定相比较

利用线性溶剂化能相关(LSERs)方法对聚(乙基苯乙烯-二乙烯基苯)包覆钛胶固定相(ES-DVB-TiO₂)的保留行为进行评价,并与聚丁二烯涂覆钛胶固定相(PBD-TiO₂),键合硅胶固定相(ODS)和树脂固定相(PR-1)作了比较,计算出各变最对logk'的百分方差数,发现V₂、Σα₂^H,和Σβ₂^H对logk'有较大的贡献,与聚合物固定相PRP-1近似,因此它们有相似的保留机理,即吸附机理大于分配机理.     

交联聚苯乙烯包覆二氧化锆柱填料的制备与评价

交联聚苯乙烯包覆二氧化锆固定相是在溶液体系中通过自由基引发乙基苯乙烯、二乙烯基苯和乙烯基二氧化锆共聚反应获得。IR和SEM表征这种填料的表面特征，考察了这种交联聚合物包覆柱填料的色谱性能和化学稳定性，并用这种填料分离了苯甲酸酯类和碱性化合物。     

十二烷基键合氧化锆填充电色谱柱的研究

以十二烷基键合氧化锆(C12-ZrO2)作为固定相,制备了填充毛细管电色谱(CEC)柱,较为系统地研究了流动相条件对电渗流的影响、填充CEC柱的稳定性、碱性与中性化合物的保留与流动相pH值和有机溶剂含量的关系。C12-ZrO2固定相填充CEC柱在pH3～11．7范围内具有极好的稳定性;利用磷酸盐与氧化锆表面之间较强的相互作用,能够有效解决传统硅胶键合烷基固定相在有机溶剂含量低的流动相条件下不稳定的问题;同时吸附磷酸盐的固定相表面使得在更宽的流动相pH值范围内CEC柱有足够的电渗流,进一步拓宽CEC的应用领域。     

Recent trends in open-tubular capillary electrochromatography

Capillary electrochromatography (CEC), which combines the advantages of the high efficiency of capillary electrophoresis (CE) and the high selectivity of liquid chromatography (LC), has recently received considerable attention. Most CEC experiments have been performed with capillary columns packed with small LC packing materials (1.5–5 μm particle diameter). However, problems such as difficulties in packing the small LC packing materials and fabricating the frits still exist in preparing the CEC column. The use of open-tubular columns in CEC is therefore an alternative approach that can eliminate the problems encountered in packed-column CEC. So far, several types of open-tubular columns have been proposed for CEC separations and in this article recent progress in this area is reviewed.     

Packing columns for capillary electrochromatography

Considering the current interest in capillary electrochromatography (CEC), performed in packed columns, we present the different methods used to pack capillary columns for use in CEC. General considerations on column packing are given and the column fabrication process is discussed in sufficient detail to allow instruction to those who are not experienced in the field. Five different packing methods are discussed to deliver packing material into the capillary column from a practical view point: slurry pressure packing, packing with supercritical CO2, electrokinetic packing, using centripetal forces, and packing by gravity. Entrapment of particulate material by sintering and sol-gel technology is also mentioned. Although slurry pressure packing procedures are most common, higher separation efficiencies are obtained using other packing approaches. Electrokinetic packing seems to be the simplest technique to deliver the packing material into the capillary columns. Nevertheless, as with the other packing techniques, skill and experience are required to complete all the steps involved in the fabrication of packed columns for CEC.     

Packing capilllary electrochromatography columns using vacuum--a preliminary study

This paper introducesa novel method for packing Capillary Electrochromatography Columns (CEC). Using vacuum packing methodology, silica particles as small as 1 microm were successfully packed into the capillary columns with 75 microm inner diameter. The columns are verystable and show no noticeable loss in efficiency after 200 sample injections. The performance of these vacuum packed capillary columns was evaluated with a mixture of aromatic and non-aromatic compounds. A 24 cm long capillary column can produce peak efficiencies of around 45,000 plates for benzene.     

Aspects of column fabrication for packed capillary electrochromatography

Various parameters have been evaluated to develop a process for optimization of column manufacture for packed capillary electrochromatography (CEC). Spherisorb ODS-1 was packed into 75 microm I.D. capillaries to establish a standard set of packing conditions to afford high-performance columns free of voids. Numerous silica-based packing materials including porous and non-porous reversed-phase and ion-exchange phases were employed to evaluate the applicability of the standard conditions. Success of column manufacture and performance demonstrate a relationship to the colligative properties of the packing materials under the applied conditions. Frequently encountered difficulties arising from inadequate column conditioning and void formation in the packed bed are identified and discussed.     

Enantiomer separations by capillary electrochromatography using chiral stationary phases

The applicability of capillary electrochromatography (CEC) using packed capillary column to enantiomer separations was investigated. As chiral stationary phases, OD type packing materials of 5 and 3 microm particle diameters, originally designed for conventional high-performance liquid chromatography (HPLC) were employed. The chiral packing materials were packed by a pressurized method into a 100 microm I.D. fused-silica capillary. Several racemic enantiomers, such as acidic, neutral and basic drug components, were successfully resolved, typically by using acidic or basic solutions containing acetonitrile as mobile phases. The separation efficiencies for some enantiomers in the chiral CEC system using the 5 microm OD type packing were superior to those obtained in HPLC using chiral packings. The plate heights obtained for several enantiomers were 8-13 microm or the reduced plate height of 1.6-2.6, which indicates the high efficiency of this chiral CEC system.     

Capillary columns with in situ formed porous monolithic packing for micro high-performance liquid chromatography and capillary electrochromatography.

Capillary columns with monolithic stationary phase were prepared from silanized fused-silica capillaries of 75 microns I.D. by in situ copolymerization of divinylbenzene either with styrene or vinylbenzyl chloride in the presence of a suitable porogen. The porous monolithic support in this study was used either directly or upon functionalization of the surface to obtain a stationary phase that was appropriate for the separation of peptides by capillary electrochromatography (CEC). The main advantages of monolithic columns are as follows. They do not need retaining frits, they do not have charged particles that can get dislodged in high electric field, and they have relatively high permeability and stability. Whereas such columns are designed especially for CEC, they find application in micro high-performance liquid chromatography (mu-HPLC) as well. Five different porogens were employed to prepare the monolithic columns that were examined for permeability and porosity. The flexibility of fused-silica capillaries was not adversely affected by the monolithic packing and the longevity of the columns was satisfactory. This may also be due to the polymerization technique, which resulted in a fluid-impervious outer layer of the monolith that precluded contact between the fused-silica surface and the liquid mobile phase. For the most promising columns, the conductivity ratios and the parameters of the simplified van Deemter equation, both in mu-HPLC and CEC, were evaluated. It was found that the efficiency of the monolithic columns in CEC was significantly higher than in mu-HPLC in the same way as observed with capillary columns having conventional particulate packing. This is attributed to the relaxation of band-broadening with electroosmotic flow (EOF) with respect to that with viscous flow. It follows then that the requirement of high packing uniformity to obtain high efficiency may also be relaxed in CEC. Angiotensin-type peptides were separated by CEC with columns packed with a monolithic stationary phase having fixed n-octyl chains and quaternary ammonium groups at the surface. Plate heights of about 8 microns were routinely obtained. The mechanism of the separation is based on the interplay between EOF, chromatographic retention and electrophoretic migration of the positively charged peptides. The results of the complex migration process, with highly nonlinear dependence of the migration times on the organic modifier and the salt concentration, cannot be interpreted within the framework of classical chromatography or electrophoresis.     

A drying step in the protocol to pack capillary columns by centripetal forces for capillary electrochromatography.

Capillary columns have been packed for capillary electrochromatography (CEC) using centripetal forces. The packed columns were maintained under wet conditions or they were dried with nitrogen gas prior to forming the retaining frits. Upon fabrication of the retaining frits, the dried columns were resolvated with the mobile phase. The performance of the columns was evaluated to determine the effect of the drying step during the packing procedure. The columns submitted to the drying step showed improved separation efficiencies and stronger retention characteristics than those kept under wet conditions. The drying step allows the silica-based packing material to be better accommodated inside the capillary column. Upon solvation, the packing material "swells," resulting in a greater packing density, which allows for a stronger retention and improved separation efficiencies. The drying step led to a 13% increase in retention on columns packed with isopropanol. An increase of 15-20% in theoretical plates for the most retained compounds was also observed in such columns.     

磁场辅助毛细管电色谱

磁场辅助毛细管电色谱是液相色谱研究领域中出现的新技术．它利用外加磁场的引力将置于毛细管内的具有磁响应性的硅胶微球或四氧化三铁微球固定在管内任意位置．磁场固定微球聚集体既可用作填充柱,直接用于电色谱分离;也可用作柱筛,用于填装由商品色谱填料组成的色谱柱．这一技术的优势在于制备简便易行,柱管可以再生使用,适合于微流控芯片上柱筛或柱床的制作．本文简要评述磁场辅助毛细管电色谱的进展,包括磁性色谱填料的制备,磁场固定柱床电色谱,磁性柱筛电色谱及毛细管柱内柱结构参数的测定等方面．     

Packing structure and self-heating in capillary electrochromatography

The origin of bubble formation during operation of capillary electrochromatography (CEC) has been an issue of debate. Ohmic heating resulted from current passed through a packed column was proposed as the primary cause. However, this explanation has been questioned on the ground that the current measured in CEC is much lower than that measured with open-tubular separation systems where no bubble formation occurs. To resolve this issue, we carried out a theoretical study correlating self-heating of the electrolyte with packing structure of the column. We used a bundle of capillary tubes, a bundle of two types of capillary tubes and two bundles of capillary tubes connected serially to model, respectively, the flow channels in the column of non-porous particles, in the column of porous particles and in the column of various packing densities. The results from this study indicate that, for columns of homogeneous packing density, the heat output is indeed smaller than that in open-tubular columns of the same dimensions. In this case, the self-heating cannot be a key factor responsible for the bubble formation in CEC. However, for columns of heterogeneous packing density, a large excess of heat release may be produced in column sections of high packing density and, in turn, over-heating in such sections may become the primary cause for the formation of bubbles. It follows from this study that preparation of columns of homogeneous packing structure is essential to obtain reproducible and bubble-free CEC systems.