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使用非共价点击化学的分子共轭

Molecular conjugation using non-covalent click chemistry.

作者信息

Schreiber Cynthia L, Smith Bradley D

机构信息

Department of Chemistry and Biochemistry, University of Notre Dame, Notre Dame, IN, USA.

出版信息

Nat Rev Chem. 2019 Jun;3(6):393-400. doi: 10.1038/s41570-019-0095-1. Epub 2019 Apr 24.

DOI:10.1038/s41570-019-0095-1
PMID:33834115
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8025804/
Abstract

Molecular conjugation refers to methods used in biomedicine, advanced materials and nanotechnology to link two partners - from small molecules to large and sometimes functionally complex biopolymers. The methods ideally have a broad structural scope, proceed under very mild conditions (including in HO), occur at a rapid rate and in quantitative yield with no by-products, enable bioorthogonal reactivity and have zero toxicity. Over the past two decades, the field of click chemistry has emerged to afford us new and efficient methods of molecular conjugation. These methods are based on chemical reactions that produce permanently linked conjugates, and we refer to this field here as covalent click chemistry. Alternatively, if molecular conjugation is undertaken using a pair of complementary molecular recognition partners that associate strongly and selectively to form a thermodynamically stable non-covalent complex, then we refer to this strategy as non-covalent click chemistry. This Perspective is concerned with this latter approach and highlights two distinct applications of non-covalent click chemistry in molecular conjugation: the pre-assembly of molecular conjugates or surface-coated nanoparticles and the in situ capture of tagged biomolecular targets for imaging or analysis.

摘要

分子共轭是指生物医学、先进材料和纳米技术中用于连接两个分子的方法,这两个分子可以从小分子到大型的、有时功能复杂的生物聚合物。理想情况下,这些方法具有广泛的结构范围,能在非常温和的条件下进行(包括在水中),反应速度快,产率高且无副产物,具有生物正交反应性且毒性为零。在过去的二十年里,点击化学领域应运而生,为我们提供了新的、高效的分子共轭方法。这些方法基于化学反应生成永久连接的共轭物,我们在此将这个领域称为共价点击化学。另外,如果分子共轭是利用一对互补的分子识别伴侣进行的,它们能强烈且选择性地结合形成热力学稳定的非共价复合物,那么我们将这种策略称为非共价点击化学。本综述关注的是后一种方法,并强调了非共价点击化学在分子共轭中的两个不同应用:分子共轭物或表面包覆纳米颗粒的预组装,以及用于成像或分析的标记生物分子靶标的原位捕获。

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