Organotitanium Click Chemistry

Fine Chemical Engineering Pub Date : 2023-05-24 DOI:10.37256/fce.4220232854

Gregory G. Arzoumanidis

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Abstract

The click chemistry of titanium exemplified by the “green” [3 + 2] cycloaddition of the [Ti-N3] moiety with nitriles RCN to form a tetrazole ligand, is currently limited in scope, but the future of this open and wide field is bright, full of promising new synthetic approaches discussed herein, for pharmacological and bio orthogonal applications. This prediction is based on emerging click reaction possibilities from newly prepared titanium azides (complex 6), to existing titanium azides, including the commercially available Ti(N3)4, Cp2Ti(N3)2, (iPrO)2Ti(N3)2, and their multiple derivatives, participating in cycloaddition, exchange and other reaction types with alkynes, alkenes, nitriles, and related click synthons. Most of the organotitanium click reactions show nearly quantitative yields, as in the reaction of Ti(OiPr)4 with (CH3)2SiN3. Structural, mechanistic, stereo control and other effects on reactivity are briefly discussed. The main emphasis in this review article is on recently discovered organotitanium complexes like 2-phenylindole titanium dichloride, easily modified by insertion reactions of small molecules like CO2, SO2 or even RN3, serving as springboards of a new era in organotitanium click chemistry, by the original syntheses of non-toxic, potentially bioactive complexes.

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有机钛点击化学

钛的点击化学以[Ti-N3]部分与腈RCN的“绿色”[3 + 2]环加成形成四唑配体为例，目前范围有限，但这一开放和广阔的领域的未来是光明的，充满了有前途的新合成方法，在药理学和生物正交应用中。这一预测是基于从新制备的叠氮钛化合物(配合物6)到现有的叠氮钛化合物(包括市购的Ti(N3)4、Cp2Ti(N3)2、(iPrO)2Ti(N3)2及其多种衍生物，与炔烃、烯烃、腈和相关的键合子进行环加成、交换等反应的可能性。大多数有机钛的键合反应，如Ti(OiPr)4与(CH3)2SiN3的反应，都显示出接近定量的产率。简要讨论了结构、机械、立体控制和其他对反应性的影响。这篇综述文章的重点是最近发现的有机钛配合物，如2-苯基吲哚二氯化钛，很容易被CO2, SO2甚至RN3等小分子的插入反应修饰，通过原始合成无毒，具有潜在生物活性的配合物，作为有机钛化学新时代的跳板。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Fine Chemical Engineering

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