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基于碘化银固定相的薄层色谱-红外光谱联用研究 被引量:2

The Analysis for Silver Iodide Fine Particles of TLC/FTIR Matrix
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摘要 在分析复杂混合物方面原位薄层色谱-红外光谱联用有巨大潜力,二者联用能够相互取长补短,极大地提高对复杂混合物的解析能力。但因固定相自身的红外吸收能够对样品的检测造成干扰,使该方法进展缓慢。实验应用对中红外光透明的碘化银纳米微粒作为固定相制备薄层层析板,并对碘化银薄层板的层析效果及原位红外光谱检测的可行性进行了初步的研究。通过正交设计实验法优化反应条件,制备出粒径为100nm左右的碘化银颗粒;应用沉降-挥发法制备薄层层析板,实验表明该薄层板具备分离混合物的能力,且原位红外光谱检测结果表明碘化银作为固定相不干扰样品检测。 In situ TLC/FTIR technique has tremendous potential in the analysis of complex mixtures. However, the progress in this technique was quite slow. The reason is that conventional stationary phase has strong absorption in FTIR spectrum and thus brings about severe interference in the detection of samples. To solve the problem, the authors propose to use AgI fine particles as stationary phase of TLC plate. The reasons are as follows: Silver iodide fine particles have no absorbance in an IR region be- tween 4 000 and 800 cm-1 , therefore, the interference caused by IR absorption of stationary phase can be removed. Moreover, silver iodide is stable and insolvable in water and organic solvents and thus it will not be destroyed by mobile phase or react with samples during the TLC separation. To improve TLC separation efficiency and quality of FTIR spectra during the TLC/FTIR a- nalysis, the size of AgI particles should be below 500 nm. We used orthogonal design approach to optimize the experimental con- dition to AgI particles so that the average size of AgI particles is around 100 nm. No absorption of impurity or adsorbed water were observed in FTIR spectrum of the AgI particles the authors used "settlement volatilization method" to prepare TLC plate without using polymeric adhesive that may bring about significant interference in FTIR analysis. Preliminary TLC experiments proved that the TLC plate using AgI fine particles as stationary phase can separate mixtures of rhodamine B and bromophenol blue successfully. Applications of silver iodide fine particles as stationary phase have bright perspective in the development of insitu TLC/FTHR analysis techniques.
作者 祝青 苏晓 吴海军 翟延君 夏锦明 布和巴特 徐怡庄 吴瑾光
机构地区 辽宁中医药大学药学院 北京大学化学与分子工程学院 山东省临沂市产品质量监督检验所 内蒙古民族大学蒙医药学院 沈阳度太生物制药研究中心
出处 《光谱学与光谱分析》 SCIE EI CAS CSCD 北大核心 2012年第7期1790-1794,共5页 Spectroscopy and Spectral Analysis
基金 国家自然科学基金项目(50973003) 国家(863计划)重大项目(2010AA03A406) 科技部平台项目(2005DKA32800) 北京市专利基金项目 北京大学先进技术研究院培育项目资助
关键词 薄层色谱 红外光谱 纳米 TLC FTIR Nano
分类号 O657.3 [理学—分析化学]
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参考文献7

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同被引文献16

  • 1Shenna J. , Anal. Chem. , 2010, 82, 4895--4910.
  • 2Chen G. M. , Yuan C. P. , Yang J. P. , Zhang J. P. , Zhang J. H. , Chem. Res. Chinese Universities, 2012, 28(1), 153-155.
  • 3Zhang Y. , Xie Y. F. , Zhao B. , Chem. Res. Chinese Universities, 2011, 27 (6) , 924-928.
  • 4McCoy N. R. , Fiebig C. E. , Anal. Chem. , 1%5, 37(4) , 593-595.
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  • 9郭勍,徐桂云,常理文.大豆磷脂组成的薄层色谱分析[J].分析化学,1998,26(1):81-84. 被引量:42
  • 10刘元瑞,葛海生,赵康虎,孙素琴,周群.制备薄层色谱联合FTIR检测中药制剂中添加化学药品方法的研究[J].中国药学杂志,2009,44(24):1924-1927. 被引量:7

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光谱学与光谱分析
2012年 第7期

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