共查询到19条相似文献,搜索用时 450 毫秒
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化学库及分子差异性设计研究进展 总被引:2,自引:0,他引:2
组合化学是近年来发展起来的一种快速合成和平行筛选群体化合物的新方法。它可以用来设计先导化合物,也可以对药物分子进行结构改造。本文主要综述了化学库的合成以及计算机辅助组合化学的研究进展。 相似文献
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动态组合化学是组合化学的一个新兴分支,在药物先导化合物的发现中有广阔的应用前景。在动态组合化学库中,利用靶标分子的诱导结合作用,通过可逆共价反应,能够选择性的筛选到与靶标分子存在强相互作用的优势化合物。本文按照动态组合化学方法简介、动态组合化学中的可逆共价化学、动态组合化学库的分类、动态组合化学库筛选方法的研究进展及动态组合化学在药物先导化合物发现过程中的应用等5个方面对动态组合化学进行了概述。 相似文献
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小分子化合物可以调节生物学过程,是研究活性生物大分子特别是蛋白质以及药物的重要工具,而高通量筛选是发现活性分子的重要方法.分子阵列是近年来新出现的一种高通量筛选技术,上面含有成千上万种组合合成的化合物以及天然产物,可以用于发现新的先导化合物,以及筛选已有的先导化合物.现在分子阵列已经成功应用于蛋白分析和先导化合物的发现等许多领域.本文综述了近年来分子阵列的构建过程、原位合成和非原位合成等各种固定化策略以及荧光免疫检测、表面等离子体共振成像技术等检测手段,并介绍了化学分子印刷阵列方法,最后总结了分子阵列的应用,并对分子阵列在我国中药发展等方面将起到的潜在作用作了展望. 相似文献
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小分子化合物可以调节生物学过程,是研究活性生物大分子(特别是蛋白质)以及药物的重要工具,而高通量筛选是发现活性分子的重要方法。分子阵列是近年来新出现的一种高通量筛选技术,上面含有成千上万种组合合成的化合物以及天然产物,可以用于发现新的先导化合物,以及筛选已有的先导化合物。现在分子阵列已经成功应用于蛋白分析、先导化合物的发现等许多领域。本文综述了近年来分子阵列的构建过程,原位合成、非原位合成等各种固定化策略以及荧光免疫检测,表面等离子体共振成像技术等检测手段,并介绍了化学分子印刷阵列方法,最后总结了分子阵列的应用,并对分子阵列在我国中药发展等有方面将起到的潜在作用作了展望。 相似文献
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新药物分子设计的某些理论方法 总被引:2,自引:0,他引:2
新药物的先导物设计和新药物的优选设计是两个不同的概念和范畴,本文介绍了发现先导药物的组合化学、群集筛选和计算机筛选方法等最新进展。同时介绍了构效关系研究中的某些基本理论方法。讨论了新药物分子设计的某些问题及其弥补措施。 相似文献
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组合化学是一种将计算机辅助设计、有机化学合成以及高通量筛选一体化的技术. 它以高效、微量、高度自动化的特点而受到世人瞩目, 对药物研发中加速寻找先导化合物起到了极大的推进作用. 近年来随着纳米技术的迅速发展, 组合化学策略和高通量技术也在此领域中得到应用. 为在今后的研究中能够更好地将组合化学技术应用于纳米材料和纳米技术研究领域, 本文综述了组合化学在开发新型纳米材料以及通过对纳米材料进行表面化学修饰来提高其在生物医学领域的应用研究进展, 并对目前应用于纳米技术研究的高通量筛选技术, 如磁共振成像、自动化基因芯片系统和荧光激活细胞分类术以及对纳米组合化学目前遇到的一些挑战进行了简单概括, 并对其未来的发展趋势提出了展望. 相似文献
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Ivar Ugi Matthias Goebel Bernhard Gruber Martin Heilingbrunner Carola Heiß Werner Hörl Oliver Kern Manfred Starnecker Alexander Dömling 《Research on Chemical Intermediates》1996,22(7):625-644
Standard chemistry prescribes the conversion of one or two compounds into their products. In contrast, Eintopf (one-pot) multicomponent reactions (MCRs) involve at least three different compounds. One-pot MCRs are a useful tool in combinatorial chemistry: From a mixture of educts a large number of products can be simultaneously formed in liquid phase, called a soluble molecular library. The member compounds of such libraries are investigated simultaneously for desired properties, e.g. antibiotic activity. The main constraint is, that the underlying chemistry must not produce unknown side reactions and must lead to a broad spectrum of stable products with high yields. Isocyanide multicomponent chemistry allows the generation of soluble libraries of very different sizes, which are easy to screen for biological or pharmaceutical efficacy using the algorithms presented. Products can easily be enumerated and the kinetics of the isocyanide chemistry is simple to investigate. Combinatorial chemistry is capable of generating and optimizing leads faster and with fewer resources than by conventional means. Combinatorial chemistry based on isocyanide chemistry is by far the most important and most impressive technique in use today to reducing time and costs associated with lead generation and optimization during the drug discovery process. The simplicity of the reaction conditions involved means that the generation and screening of libraries can be automated. 相似文献
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Wilhelm F. Maier 《Angewandte Chemie (International ed. in English)》1999,38(9):1216-1218
One should not underestimate the capability of the combinatorial method in solid-state chemistry; this is the opinion of the author. Combinatorial chemistry can provide a large number of new compounds, but once the components that are interesting for a certain application have been successfully selected, the techniques of conventional catalysis and materials research are required. The strengths of conventional chemistry lie in the optimization, systematic modification, and improvement of new lead structures. In contrast, discovery is the potential strength of combinatorial chemistry. Careful design is most important for the synthesis of useful libraries, since the diversity of the periodic table is much too large to be accessed comprehensively or systematically by such large libraries. 相似文献
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Until recently, repetitive solid-phase synthesis procedures were used predominantly for the preparation of oligomers such as peptides, oligosaccharides, peptoids, oligocarbamates, peptide vinylogues, oligomers of pyrrolin-4-one, peptide phosphates, and peptide nucleic acids. However, the oligomers thus produced have a limited range of possible backbone structures due to the restricted number of building blocks and synthetic techniques available. Biologically active compounds of this type are generally not suitable as therapeutic agents but can serve as lead structures for optimization. “Combinatorial organic synthesis” has been developed with the aim of obtaining low molecular weight compounds by pathways other than those of oligomer synthesis. This concept was first described in 1971 by Ugi.[56f,g,59c] Combinatorial synthesis offers new strategies for preparing diverse molecules, which can then be screened to provide lead structures. Combinatorial chemistry is compatible with both solution-phase and solid-phase synthesis. Moreover, this approach is conducive to automation, as proven by recent successes in the synthesis of peptide libraries. These developments have led to a renaissance in solid-phase organic synthesis (SPOS), which has been in use since the 1970s. Fully automated combinatorial chemistry relies not only on the testing and optimization of known chemical reactions on solid supports, but also on the development of highly efficient techniques for simultaneous multiple syntheses. Almost all of the standard reactions in organic chemistry can be carried out using suitable supports, anchors, and protecting groups with all the advantages of solid-phase synthesis, which until now have been exploited only sporadically by synthetic organic chemists. Among the reported organic reactions developed on solid supports are Diels–Alder reactions, 1,3-dipolar cycloadditions, Wittig and Wittig–Horner reactions, Michael additions, oxidations, reductions, and Pd-catalyzed C? C bond formation. In this article we present a comprehensive review of the previously published solid-phase syntheses of nonpeptidic organic compounds. 相似文献
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Mittoo S 《Combinatorial chemistry & high throughput screening》2006,9(6):421-423
Since oxidative cellular damage contributes to the development of cancers, heart disease and ageing, the synthesis of antioxidative agents which are able to either prevent or mitigate oxidative stress to cells is an important area of investigation. Combinatorial chemistry has had a profound impact on the discovery and optimisation of potential lead compounds, especially in the medicinal field. This review details recent examples of combinatorial chemistry dealing with the synthesis of novel antioxidants with an emphasis on solid phase compound synthesis and parallel library synthesis. 相似文献
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Combinatorial synthesis of anti-HIV agents--a review 总被引:1,自引:0,他引:1
Sriram D Yogeeswari P Nagappa AN 《Combinatorial chemistry & high throughput screening》2005,8(5):377-385
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Mineno T Stanford KM Walker LA Avery MA 《Combinatorial chemistry & high throughput screening》2002,5(6):481-487
Combinatorial chemistry has become a dramatically useful tool for the development of new medicinal agents. In the search to discover a novel and effective lead for the treatment of giardiasis, solution-phase synthesis of a library of isoflavone derivatives has been accomplished. Of the products screened, several compounds such as P(A1,B1) and P(A1,B11) exhibited potent antigiardial activity. The details of synthesis, in vitro antigiardial assay, and preliminary structure-activity relationships of these compounds are described. 相似文献
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XIAO Xiao-Yi 《高等学校化学研究》2001,17(3)
Combinatorial chemistry has produced libraries of millions of compounds in the last decade. Screening of those compounds, unfortunately, has not yet yielded as many new drug candidates as initially expected. Among a number of possible reasons, one is that many libraries combinatorial chemistry produced in the early periods are of the nature of linear, flat, and flexible molecules such as peptides and oligonucleotides, which do not have the desired properties to selectively interact with their targets to yield high quality hits and leads. In order to increase the number of quality hits and leads, rigid, structural featurerich and drug-like compound libraries are highly desirable. Design and development of structural features-rich and natural product-like combinatorial libraries, as well as high speed library production using modern solution and solid phase synthesis techniques such as IRORI's Directed Sorting technology, will be discussed. 相似文献