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钯和铜介导的 N-芳基键形成反应在生物活性化合物的合成中的应用。

Palladium- and copper-mediated N-aryl bond formation reactions for the synthesis of biological active compounds.

机构信息

Institute of Organic Chemistry, University of Regensburg, Universitätsstr. 31, D-93053 Regensburg, Germany.

出版信息

Beilstein J Org Chem. 2011 Jan 14;7:59-74. doi: 10.3762/bjoc.7.10.

DOI:10.3762/bjoc.7.10
PMID:21286396
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3029007/
Abstract

N-Arylated aliphatic and aromatic amines are important substituents in many biologically active compounds. In the last few years, transition-metal-mediated N-aryl bond formation has become a standard procedure for the introduction of amines into aromatic systems. While N-arylation of simple aromatic halides by simple amines works with many of the described methods in high yield, the reactions may require detailed optimization if applied to the synthesis of complex molecules with additional functional groups, such as natural products or drugs. We discuss and compare in this review the three main N-arylation methods in their application to the synthesis of biologically active compounds: Palladium-catalysed Buchwald-Hartwig-type reactions, copper-mediated Ullmann-type and Chan-Lam-type N-arylation reactions. The discussed examples show that palladium-catalysed reactions are favoured for large-scale applications and tolerate sterically demanding substituents on the coupling partners better than Chan-Lam reactions. Chan-Lam N-arylations are particularly mild and do not require additional ligands, which facilitates the work-up. However, reaction times can be very long. Ullmann- and Buchwald-Hartwig-type methods have been used in intramolecular reactions, giving access to complex ring structures. All three N-arylation methods have specific advantages and disadvantages that should be considered when selecting the reaction conditions for a desired C-N bond formation in the course of a total synthesis or drug synthesis.

摘要

N-芳基脂肪族和芳香族胺是许多生物活性化合物中的重要取代基。在过去的几年中,过渡金属介导的 N-芳基键形成已成为将胺引入芳基体系的标准程序。虽然简单的芳基卤化物与简单的胺的 N-芳基化反应在许多描述的方法中都能高产率进行,但如果应用于具有附加官能团的复杂分子(如天然产物或药物)的合成,则反应可能需要详细优化。我们在本文中讨论并比较了三种主要的 N-芳基化方法在合成生物活性化合物中的应用:钯催化的 Buchwald-Hartwig 型反应、铜介导的 Ullmann 型和 Chan-Lam 型 N-芳基化反应。所讨论的实例表明,钯催化反应更适合大规模应用,并且对偶联伙伴上的空间位阻取代基的容忍度优于 Chan-Lam 反应。Chan-Lam N-芳基化反应特别温和,不需要额外的配体,这便于后处理。然而,反应时间可能非常长。Ullmann 和 Buchwald-Hartwig 型方法已用于分子内反应,可获得复杂的环结构。在全合成或药物合成过程中选择所需 C-N 键形成的反应条件时,所有三种 N-芳基化方法都有其特定的优缺点,应予以考虑。

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