细菌群体感应信号分子的光电检测技术

群体感应（quorum sensing，QS）是一种依赖菌群密度的细菌交流系统。在探究细菌群体感应系统的调控机制中，对QS信号分子的鉴别和检测是不可或缺的环节，其对生命科学、药学等领域涉及细菌等微生物的相互作用、高效检测和作用机制解析等具有重要的参考意义。本文在总结不同类型细菌QS信号分子来源和结构的基础上，对QS信号分子的光电检测方法和技术进行了综述，重点对光电传感检测的敏感介质、传感界面、传感机制及测试效果进行探讨，同时关注了将微流控芯片分析技术应用于细菌QS信号分子原位监测的相关研究进展。     

核壳型离子印迹聚合物的制备与应用

离子印迹聚合物(IIPs)是利用分子印迹技术对目标离子进行印迹、聚合进而得到对模板离子有选择性吸附的聚合物。核壳型离子印迹聚合物作为一种新型吸附材料被应用于样品的处理和实际检测中。本文对核壳型离子印迹聚合物的核壳类型、印迹聚合物的制备方法及实际检测应用等最新研究进展进行综述,为核壳型离子印迹聚合物的研究与应用提供参考。     

生物印迹:一个直接的酶修饰技术

生物印迹技术是一个简单、直接的酶修饰技术,已应用到有机合成、生物传感器制备和生物分离等领域,在推动化学品绿色合成方面具有潜在的应用价值。本文在生物印迹概念的提出与发展、分类、应用以及印迹技术策略的发展等方面综述近期研究成果,针对生物印迹研究过程的现实问题,展望其未来的发展趋势,为生物印迹相关研究提供有益的借鉴。     

分子印迹技术及其在生物领域内的应用

分子印迹技术是近十年来发展起来的模拟抗体-抗原相互作用原理的新技术。在存在印迹分子的条件下,通过模板聚合可以构造出具有选择性识别位点的印迹聚合物。该聚合物可作为用于生物物质的监测、分析、分离与纯化等的基质。本文就分子印迹技术的产生、发展及其在生物领域中的应用做了较为详细的阐述,并对该技术的发展前景进行了预测 。     

分子印迹技术及其在生物领域内的应用

分子印迹技术是近十年来发展起来的模拟抗体－抗原相互作用原理的新技术。在存在印迹分子的条件下,通过模板聚合可以构造出具有选择性识别位点的印迹聚合物,该聚合物可作为用于生物物质的监测、分析、分离与纯化等的基质,本文就分子印迹技术的产生、发展及其在生物领域中的应用做了较为详细的阐述,并对该技术的发展前景进行了预测。     

分子印迹技术研究新进展

分子印迹技术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。现已应用于色谱分离、抗体和受体模拟物、固相萃取、生物传感器等领域。     

分子印迹技术用于生物大分子的识别

分子印迹技术是一种人工合成具有分子识别功能的介质的一种新技术,近年来在许多领域都得到很大的发展。本文介绍了分子印迹技术的发展现状,尤其对生物大分子的分子印迹技术进行了详细论述,对生物大分子印迹采用的功能单体,印迹分子的种类,印迹的方法,印迹的机理,存在的问题和应用的前景等分别进行了讨论。     

CRISPR传感检测技术的研究进展

CRISPR传感检测技术具有便宜、简单、便携、高灵敏和高特异等优点,被称为“下一代分子诊断技术”。由于CRISPR-Cas系统具有特异的识别、顺式切割和非特异性的反式切割能力,已经实现了对DNA和RNA等核酸靶标以及蛋白质、外泌体、细胞和小分子等非核酸靶标的检测。为了解不同CRISPR传感检测技术的优势和发展历程,促进该技术的发展和应用,本文根据不同Cas蛋白的活性特征,对目前的CRISPR传感检测技术进行了分类总结,并在此基础上根据检测的靶标类型,依次总结了各种CRISPR传感检测技术的应用情况,以期为开发新型CRISPR传感检测技术提供参考。     

分子印迹技术用于生物大分子的识别

分子印迹技术是一种人工合成具有分子识别功能的介质的一种新技术,近年来在许多领域都得到很大的发展。本文介绍了分子印迹技术的发展现状,尤其对生物大分子的分子印迹技术进行了详细论述,对生物大分子印迹采用的功能单体、印迹分子的种类、印迹的方法、印迹的机理、存在的问题和应用的前景等分别进行了讨论。     

基于新型发光材料的荧光免疫吸附检测技术研究进展

摘要：荧光免疫吸附检测技术利用荧光物质标记识别分子,基于待测物与识别分子的特异性结合对待测物进行定性定量分析,具有操作简单、耗时少、成本低、稳定性好等优点。随着纳米材料的飞速发展及其在荧光免疫吸附检测技术中的广泛应用,该技术在生物检测的领域具有更加广阔的应用前景。本文介绍了量子点、碳点、稀土上转换纳米粒子、聚集诱导发光材料等新型发光材料的光学性能特点以及将其构建新型荧光免疫吸附检测平台,综述了近年来基于这些新型发光材料构建荧光免疫吸附检测平台对蛋白、核酸、病毒、细菌和小分子霉菌毒素等物质检测的研究进展,并讨论了该技术在未来的发展过程中需要解决的问题,包括进一步提高自动化水平争取实现实时检测,以及加快检测技术在诊断领域的临床转化等,希望本文的系统介绍可以助力高性能荧光免疫吸附检测技术的发展。     

Molecular imprinting in sol-gel matrix

Molecular imprinting is a newly developed methodology which provides molecular assemblies of desired structures and properties and is being increasingly used for several applications such as in separation processes, microreactors, immunoassays and antibody mimics, catalysis, artificial enzymes, biosensor recognition elements and bio- and chemo-sensors. The ambient processing conditions and versatility of the sol-gel process makes sol-gel glassy matrix suitable for molecular imprinting. The progress of sol-gel based molecular imprinted polymers (MIPs) for various applications can be seen from the growing number of publications. The main focus of the review is molecular imprinting in sol-gel matrix and applications of molecular imprinted sol-gel derived materials for the development of sensors. Combining sol-gel process with molecular imprinting enables to procure the sensors with greater sensitivity and selectivity necessary for sensing applications. The merits, problems, challenges and factors affecting molecular imprinting in sol-gel matrix have been discussed. Considerable attention has been drawn on recent developments like use of organically modified silane precursors (ORMOSILS) for the synthesis of hybrid molecular imprinted polymers (HMIPs) and applying surface sol-gel process for molecular imprinting. The development of molecular imprinted sol-gel nanotubes for biochemical separation and bio-imprinting is a new advancement and is under progress. Templated xerogels and molecularly imprinted sol-gel films provide a good platform for various sensor applications.     

Molecularly imprinted polymeric membranes

Molecularly imprinted polymeric membranes have been emerged since 1990. Among various kinds of molecular imprinting studies, the application of molecular imprinting to membrane separation is still a novel investigation. In the present review paper, molecularly imprinted polymeric membranes are summarized and examined. The application of molecular imprinting to membrane separation shortly leads to high performance separation membranes.     

Selective solid-phase extraction of bio- and environmental samples using molecularly imprinted polymers

Of the many applications of molecular imprinting in analytical separation science, the one with highest potential of soon being used in routine analysis is that of solid-phase extraction. Already several examples of selective pre-concentration of biological and environmental samples have been reported. The interest in imprinted extraction sorbents originates from the high selectivities and affinities obtainable, properties which can be qualitatively and quantitatively pre-determined for a particular analyte and separation by the imprinting process. This review summarises work published on molecular imprinted solid-phase extraction and discusses some imprinted-sorbent specific method development issues.     

Some new developments and challenges in non-covalent molecular imprinting technology

The technique of molecular imprinting allows the formation of specific recognition and catalytic sites in macromolecules via the use of templates. Molecularly imprinted polymers have been applied in an increasing number of applications where molecular binding events are of interest. These include the use of molecularly imprinted polymers as tailor-made separation materials, antibody and receptor binding site mimics in recognition and assay systems, enzyme mimics for catalytic applications and as recognition elements in biosensors. The stability and low cost of molecularly imprinted polymers make them advantageous for use in analysis as well as in industrial-scale production and application.     

Separation and screening of compounds of biological origin using molecularly imprinted polymers

Molecularly imprinted polymers (MIPs) represent a new class of materials possessing high selectivity and affinity for the target molecule. Since their discovery in 1972, molecularly imprinted polymers have attracted considerable interest from bio- and chemical laboratories to pharmaceutical institutes. They have been utilized as sensors, catalysts, sorbents for solid-phase extraction, stationary phase for liquid chromatography, mimics of enzymes, receptors and antibodies. Among which, the application of molecularly imprinted polymers for molecular recognition-based separation and screening of compounds has undergone rapid extension and received much attention in recent years. This article mainly focuses on the separation and screening of certain pharmacophoric compounds of interests from biological origin using molecular imprinting technology. Examples of extraction and recognition of active components as anti-tumors or anti-Hepatitis C virus inhibitors from Chinese traditional herbs using molecularly imprinting technology are particularized in this article. Comparison between the screening effect based on MIPs and that based on antibodies is also represented. Consequently the merits and demerits of these two technologies are highlighted.     

Membrane separations using molecularly imprinted polymers

This review presents an overview on the promising field of molecularly imprinted membranes (MIM). The focus is onto the separation of molecules in liquid mixtures via membrane transport selectivity. First, the status of synthetic membranes and membrane separation technology is briefly summarized, emphasizing the need for novel membranes with higher selectivities. Innovative principles for the preparation of membranes with improved or novel functionality include self-assembly or supramolecular aggregation as well as the use of templates. Based on a detailed analysis of the literature, the main established preparation methods for MIM are outlined: simultaneous membrane formation and imprinting, or preparation of imprinted composite membranes. Then, the separation capability of MIM is discussed for two different types, as a function of their barrier structure. Microporous MIM can continuously separate mixtures based on facilitated diffusion of the template, or they can change their permeability in the presence of the template ("gate effect"). Macroporous MIM can be developed towards molecule-specific membrane adsorbers. Emerging further combinations of molecularly imprinted polymers (MIPs), especially MIP nanoparticles or microgels, with membranes and membrane processes are briefly outlined as well. Finally, the application potential for advanced MIM separation technologies is summarized.     

Separation and sensing based on molecular recognition using molecularly imprinted polymers

Molecular recognition-based separation and sensing systems have received much attention in various fields because of their high selectivity for target molecules. Molecular imprinting has been recognized as a promising technique for the development of such systems, where the molecule to be recognized is added to a reaction mixture of a cross-linker(s), a solvent(s), and a functional monomer(s) that possesses a functional groups(s) capable of interacting with the target molecule. Binding sites in the resultant polymers involve functional groups originating from the added functional monomer(s), which can be constructed according to the shape and chemical properties of the target molecules. After removal of the target molecules, these molecularly imprinted complementary binding sites exhibit high selectivity and affinity for the template molecule. In this article, recent developments in molecularly imprinted polymers are described with their applications as separation media in liquid chromatography, capillary electrophoresis, solid-phase extraction, and membranes. Examples of binding assays and sensing systems using molecularly imprinted polymers are also presented.     

元基因组文库分析技术研究进展

随着新的分析技术的不断出现和成熟,促进了微生物分子生态学及相关学科的诞生和迅速发展。其中,元基因组文库分析技术即是近年来微生物分子生态学研究领域兴起的一种新的分析技术。就元基因组分析技术诞生的背景及该技术的原理进行了讨论,着重阐述了元基因组文库分析技术在寻找新基因、开发新的生物活性物质、研究群落中微生物多样性、人类元基因组测序等方面的应用。另外,归纳总结了目前国际上常用的诸如PCR为基础的筛选、荧光原位杂交（fluorescent in situ hybridization,FISH）、底物诱导的基因表达筛选（substrate induced gene expression screening,SIGEX）、基因芯片等元基因组文库筛选方法,并就不同方法的优缺点进行了分析和讨论,指出了目前元基因组文库分析技术存在的主要问题并对今后该技术的发展进行了展望。