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环糊精聚合物键合手性固定相的合成及手性拆分应用 被引量:2

Synthesis of Cyclodextrin Polymer Bonded Chiral Stationary Phase and Its Application in High Performanc Liquid Chromatography for Enantioseparation
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摘要 用简单缩聚法合成β-环糊精聚合物(β-CDP),并将其键合到自制二氧化硅微球上,合成新型的环糊精聚合物键合型手性固定相(CSP)。合成过程中考察了反应时间、原料比例对所制CSP的影响。用扫描电镜法检验了β-CDP键合硅胶圆整度,以四氮唑蓝法检测环糊精的含量为42.4μmol/g,其环糊精键合量明显高于β-CD单体键合硅胶。最后,将最优条件下得到的手性填料用高压匀浆法装柱,并进行液相色谱法拆分手性药物。将二者与ODS在相同的色谱条件下进行对比,结果表明,环糊精聚合物键合硅胶手性固定相对手性药物拆分能力更强。 β-Cyclodextrin polymer( β-CDP) was synthesized through simple condensation,and then bonded onto homemade silica microspheres to develop a novel chiral stationary phase. The reaction time and material ratio were investigated in the process of the synthesis. Scanning electron microscopy( SEM) was utilized to characterize its ball roundness. Blue tetrazolium method was applied to detect the content of cyclodextrin on β-CDP bonded silica gel,the result was 42. 4 μmol / g,which is markedly higher than that on CD bonded silica gel. Finally,the product was packed with high pressure slurry method,and the chiral column was tested by liquid chromatography to separate chiral drugs.Meanwhile,the above β-CD and β-CDP were compared with ODS to resolve chiral drugs under the same chromatographic conditions. The results demonstrate that the best separation was obtained with β-CDP bonded silica gel.
作者 王雨潇 包建民 李优鑫
机构地区 天津市现代药物传递及功能高效化重点实验室 天津化学化工协同创新中心 天津大学药物科学与技术学院
出处 《精细化工》 EI CAS CSCD 北大核心 2015年第9期968-974,共7页 Fine Chemicals
基金 国家自然科学基金面上项目(21375093) 高等学校博士学科点专项科研基金资助项目(20130032120081) 天津大学自主创新基金资助项目(1102213)~~
关键词 液相色谱法 环糊精聚合物 手性固定相 手性拆分 功能材料 liquid chromatography cyclodextrin polymer chiral stationary phase chiral separation functional materials
分类号 O655.4 [理学—分析化学] O636.1 [理学—高分子化学]
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精细化工
2015年 第9期

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