College of Chemistry and Pharmaceutical Sciences, Qingdao Agricultural University, Qingdao, 266109, China.
Top Curr Chem (Cham). 2016 Apr;374(2):17. doi: 10.1007/s41061-016-0018-2. Epub 2016 Mar 22.
The cascade [1,n]-hydrogen transfer/cyclization, recognized as the tert-amino effect one century ago, has received considerable interest in recent decades, and great achievements have been made. With the aid of this strategy, the inert C(sp(3))-H bonds can be directly functionalized into C-C, C-N, C-O bonds under catalysis of Lewis acids, Brønsted acids, as well as organocatalysts, and even merely under thermal conditions. Hydrogen can be transferred intramolecularly from hydrogen donor to acceptor in the form of hydride, or proton, followed by cyclization to furnish the cyclic products in processes featuring high atom economy. Methylene/methine adjacent to heteroatoms, e.g., nitrogen, oxygen, sulfur, can be exploited as hydride donor as well as methylene/methine without heteroatom assistance. Miscellaneous electrophilic subunits or intermediates, e.g., alkylidene malonate, carbophilic metal activated alkyne or allene, α,β-unsaturated aldehydes/ketone, saturated aldehydes/iminium, ketenimine/carbodiimide, metal carbenoid, electron-withdrawing groups activated allene/alkyne, in situ generated carbocation, can serve as hydride acceptors. This methodology has shown preeminent power to construct 5-, 6-, or 7-membered heterocyclic as well as carbon rings. In this chapter, various hydrogen donors and acceptors are adequately discussed.
级联[1,n]-氢转移/环化反应,早在一个世纪前就被认为是叔氨基效应,近几十年来受到了相当多的关注,并取得了巨大的成就。借助这一策略,在路易斯酸、布朗斯台德酸以及有机催化剂的催化作用下,惰性的 C(sp(3))-H 键可以直接官能化为 C-C、C-N 和 C-O 键,甚至仅仅在热条件下也可以。氢可以以氢化物或质子的形式从供氢体向受体进行分子内转移,然后通过环化反应以高原子经济性生成环状产物。杂原子(如氮、氧、硫)相邻的亚甲基/次甲基可以作为供氢体以及没有杂原子辅助的亚甲基/次甲基。各种亲电亚基或中间体,如亚烷基丙二酸酯、碳亲核金属活化炔或丙二烯、α,β-不饱和醛/酮、饱和醛/亚胺、烯酮亚胺/碳二亚胺、金属卡宾、吸电子基团活化的炔或丙二烯、原位生成的碳正离子,可以作为氢受体。该方法在构建 5、6 或 7 元杂环以及碳环方面表现出卓越的能力。在本章中,充分讨论了各种氢供体和受体。
