Department of Chemistry, The Pennsylvania State University, University Park, Pennsylvania 16802, United States.
Acc Chem Res. 2021 Sep 7;54(17):3415-3437. doi: 10.1021/acs.accounts.1c00329. Epub 2021 Aug 12.
Recently, alkene dicarbofunctionalization, i.e., the powerful organic synthesis method of alkene difunctionalization with two carbon sources, emerged as a formidable reaction with immense promise to synthesize complex molecules expeditiously from simple chemicals. This reaction is generally achieved with transition metals (TMs) through interception by carbon sources of an alkylmetal [β-H-C(sp)-[M]] species, a key intermediate prone to undergo rapid β-H elimination. Related prior reports, since Paolo Chiusoli and Catellani's work in 1982 [ 1982, 23, 4517], have used bicyclic and disubstituted terminal alkenes, wherein β-H elimination is avoided by geometric restriction or complete lack of β-H's. With reasoning that β-H-C(sp)-[M] intermediates could be rendered amenable to interception with the use of first row late TMs and formation of coordination-assisted transient metallacycles, these two strategies were implemented to address the β-H elimination problem in alkene dicarbofunctionalization reactions.Because first row late TMs catalyze C(sp)-C(sp) coupling, Cu and Ni were anticipated to impart sufficient stability to β-H-C(sp)-[M] intermediates, generated catalytically upon alkene carbometalation, for their subsequent interception by carbon electrophiles/nucleophiles in three-component reactions. Additionally, such an innate property could enable alkene difunctionalization with carbon coupling partners through entropically driven cyclization/coupling reactions. The cyclometalation concept to stabilize intractable β-H-C(sp)-[M] intermediates was hypothesized when three-component reactions were performed. The idea of cyclometalation to curtail β-H elimination is founded upon Whitesides's [ 1976, 98, 6521] observation that metallacycles undergo β-H elimination much slower than acyclic alkylmetals.In this Account, examples of alkene dicarbofunctionalization reactions demonstrate that Cu and Ni catalysts could enable cyclization/coupling of alkenylzinc reagents, alkyl halides, and aryl halides to afford complex carbo- and heterocycles. In addition, forming coordination-assisted transient nickellacycles enabled regioselective performance of three-component dicarbofunctionalization of various alkenyl compounds. In situ reaction of [M]-H with alkenes generated after β-H elimination induced an unprecedented metallacycle contraction process, in which six-membered metal-containing rings shrank to five-membered cycles, allowing creation of new carbon-carbon bonds at allylic (1,3) positions. Applications of these regioselective alkene dicarbofunctionalization reactions are discussed.
最近,烯键双官能化反应,即通过两个碳源对烯烃进行双官能化的强大有机合成方法,作为一种迅速合成复杂分子的反应而出现,具有巨大的应用潜力,可以从简单的化学物质中快速合成。这种反应通常是通过过渡金属 (TMs) 与烷基金属 [β-H-C(sp)-[M]] 物种的碳源拦截来实现的,这是一种容易发生快速 β-H 消除的关键中间体。自 Paolo Chiusoli 和 Catellani 于 1982 年的工作以来 [1982, 23, 4517],相关的早期报道一直使用双环和取代的末端烯烃,其中通过几何限制或完全缺乏β-H 来避免β-H 消除。基于β-H-C(sp)-[M]中间体可以通过使用第一行晚期 TMs 形成配位辅助瞬态金属环来进行拦截的推理,这两种策略都被用于解决烯键双官能化反应中的β-H 消除问题。由于第一行晚期 TMs 催化 C(sp)-C(sp)偶联,预计 Cu 和 Ni 能够赋予β-H-C(sp)-[M]中间体足够的稳定性,这些中间体在烯烃碳金属化后催化生成,以便随后通过三组分反应被碳亲电体/亲核试剂拦截。此外,这种内在性质可以通过熵驱动的环化/偶联反应使烯烃与碳偶联伙伴进行双官能化。当进行三组分反应时,假设了环金属化概念来稳定难以处理的β-H-C(sp)-[M]中间体。通过 Whitesides [1976, 98, 6521] 的观察,即金属环化物比无环烷基金属更容易发生β-H 消除,来建立环金属化以减少β-H 消除的想法。在本说明中,烯键双官能化反应的例子表明,Cu 和 Ni 催化剂可以使烯基锌试剂、烷基卤化物和芳基卤化物的环化/偶联,从而得到复杂的碳环和杂环。此外,形成配位辅助的瞬态镍环使得各种烯基化合物的三组分双官能化具有区域选择性。β-H 消除后生成的 [M]-H 与烯烃的原位反应引发了前所未有的金属环收缩过程,其中六元金属环收缩为五元环,允许在烯丙基 (1,3) 位置形成新的碳-碳键。讨论了这些区域选择性烯键双官能化反应的应用。