共查询到19条相似文献,搜索用时 65 毫秒
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分子印迹聚合物研究:从小分子到生物大分子 总被引:4,自引:0,他引:4
分子印迹技术是一项制备功能聚合物材料的方法,其对印迹分子的专一性选择识别能力引起了人们的广泛关注。随着方法的基本确立和技术的逐渐成熟,其应用领域和范围不断扩大。本文在总结以往研究结果的基础上,对迄今为止进展相对缓慢的生物大分子印迹研究予以了特别关注,对相关的水环境下的分子识别问题进行了仔细的讨论,认真的分析了生物大分子印迹研究工作的难点和不利因素,对分子印迹技术的未来发展和应用前景进行了展望。 相似文献
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分子印迹聚合物微球的制备及应用研究进展 总被引:6,自引:1,他引:6
球形分子印迹聚合物具有制备简单、使用方便;分子识别效率高且便于功能设计等优点,近年来成为分子印迹技术领域研究的热点之一。对球形分子印迹聚合物微球的制备及其应用研究进展作了较为详细的介绍。 相似文献
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分子印迹聚合物(molecular imprinting polymers,MIPs)是利用分子印迹技术合成的一种交联高聚物.分子印迹技术(molecular imprinting technique,MIT)是在近十几年来才发展起来的一门边缘科学技术.它结合了高分子化学、生物化学等学科,是模拟抗体-抗原相互作用的一种新技术,具有选择性识别位点的性质,作为传感器的理想敏感材料的制备方法日益受到研究者们的重视.本文综述了分子印迹技术的原理和分子印迹聚合物的制备方法,及其应用于传感器敏感材料的研究现状,并展望了其发展前景. 相似文献
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Molecular recognition plays an important role in biological and chemical processes. Since molecular imprinting techniques can afford complementary binding sites for a target molecule, the molecularly imprinted polymer (MIP) for the target molecule has been used for its specific recognition as chromatographic media, solid-phase ex- 相似文献
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分子印迹聚合物是具有与模板分子形状、大小及官能团完全匹配的特异识别位点的高分子聚合物,能选择性识别、有效富集目标分析物(模板分子)并去除干扰物,已广泛应用于样品前处理、化学/生物传感、药物输送等领域.然而,在合成过程中,仍存在模板分子洗脱困难、有效识别位点少、结合容量低、传质速率慢等问题.核-壳型分子印迹聚合物即在核层颗粒表面进行分子印迹,即表面印迹,印迹位点仅存在于壳层结构中,利于模板分子洗脱及扩散,能够增加有效识别位点并提高印迹容量.依据核层材料的不同,本文详细介绍了以磁性材料及非磁性材料为核的核-壳型分子印迹聚合物的合成与应用,探讨了中空核-壳分子印迹聚合物的制备与发展,并对核-壳印迹聚合物的发展前景进行了展望. 相似文献
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分子印迹聚合物是一种含特异性识别位点的高分子材料,具有高稳定性、低成本、制备简单和可重复利用等特点,常被作为仿生抗体应用于免疫分析。本文综述了分子印迹免疫吸附分析(molecularly imprinted sorbent immunoassays, MIAs)的研究进展,介绍了以不同标记物为探针的仿生免疫分析方法的发展,着重介绍了均相免疫分析系统与分子印迹聚合物的新型合成方法在MIAs中的应用。最后,本文指出分子印迹聚合物的一些缺点并没有阻碍其在免疫吸附分析中的应用,并对MIAs仍然存在的问题和发展前景进行了分析。 相似文献
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Yi Ge Benjamin Butler Farhan Mirza Sabeeh Habib‐Ullah Dan Fei 《Macromolecular rapid communications》2013,34(11):903-915
The use of the molecular imprinting technique to produce polymers with high specificity for a given “molecular template” has undergone a rapid and expansive evolution since the inception of the idea over half a century ago. It was only a matter of time before the seemingly inevitable “marriage” of this concept with another modern research obsession, the generation of “smart” polymers, capable of reacting quickly, accurately and reproducibly to changes in their environment. Many advances have since been made, concerning the quality and diversity of these systems and polymers responsive to temperature, pH and a host of other environmental cues now exist. This article provides a succinct overview of the process and outcomes of “smart” molecular imprinting, followed by a detailed assessment of recent developments and applications in such field.
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《Analytical letters》2012,45(13):1940-1957
Abstract The preparation of a methacrylate polymer molecularly imprinted (MIP) with paracetamol (APAP) was performed. After extraction of the APAP template molecule, the MIPs were incorporated into a graphite–polyurethane (GPU) matrix, and the resulting composites were used to prepare modified electrodes intended to be used in APAP determination. The best results were found using a 2.5% MIP in the GPU electrode and a 500-µm MIP particle size. This electrode was used in the determination of APAP in pharmaceutical formulations, reaching a 6.7 × 10?8 mol L?1 limit of detection. The 2.5% MIP-GPU-modified electrode showed better sensitivity than the nonimprinted methacrylate GPU-modified electrodes. Interference of phenacetin in the APAP response decreased remarkably when the proposed electrode was used. 相似文献
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Yuanyuan Ma Tianxiang Chen Muhammad Zubair Iqbal Fang Yang Norbert Hampp Aiguo Wu Liqiang Luo 《Electrophoresis》2019,40(16-17):2011-2028
As a result of their advantages for superparamagnetic properties, good biocompatibility, and high binding capacity, functionalized magnetic materials became widely popular over the past couple of decades, being applied on large scale in various processes of sample preparation for biomedicine. In this work, we perform an in‐depth review on the current progress in the field of magnetic bead separation, discussing in detail the physical basis of this process, various synthesis methods and surface modification strategies. We place special focus of attention as well on the latest applications of magnetic polymer microspheres in cell separation, protein purification, immobilized enzyme, nucleic acid separation, and extraction of bioactive compounds with low molecular weight. Existing problems are highlighted and possible trends of magnetic separation techniques for biomedicine in the future are proposed. 相似文献
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