29480-10-2Relevant articles and documents
TFA-Catalyzed [3+2] Spiroannulation of Cyclobutanols: A Route to Spiro[cyclobuta[a]indene-7,1′-cyclobutane] Skeletons
An, Zhenyu,Liu, Yafeng,Sun, Yanwei,Yan, Rulong
, p. 3812 - 3815 (2020)
A straightforward method for the synthesis of spiro[cyclobuta[a]indene-7,1′-cyclobutane] derivatives from cyclobutanols has been developed via one-pot [3+2] spiroannulation. A series of new spiro[cyclobuta[a]indene-7,1′-cyclobutane] derivatives are facile
Nickel-Catalyzed Arylation/Alkenylation of tert-Cyclobutanols with Aryl/Alkenyl Triflates via a C - C Bond Cleavage
Wang, Zhen,Hu, Yuanyuan,Jin, Hongwei,Liu, Yunkui,Zhou, Bingwei
, p. 466 - 474 (2020/12/22)
Herein, we first present a nickel-catalyzed arylation and alkenylation of tert-cyclobutanols with aryl/alkenyl triflates via a C-C bond cleavage. An array of γ-substituted ketones was obtained in moderate-to-good yields, thus featuring earth-abundant nick
Regio- and Stereoselective Rhodium(II)-Catalyzed C–H Functionalization of Cyclobutanes
Garlets, Zachary J.,Wertz, Benjamin D.,Liu, Wenbin,Voight, Eric A.,Davies, Huw M.L.
supporting information, p. 304 - 313 (2020/01/08)
Recent developments in controlled C–H functionalization transformations continue to inspire new retrosynthetic disconnections. One tactic in C–H functionalization is the intermolecular C–H insertion reaction of rhodium-bound carbenes. These intermediates can undergo highly selective transformations through the modulation of the ligand framework of the rhodium catalyst. This work describes our continued efforts toward differentiating C–H bonds in the same molecule by judicious catalyst choice. Substituted cyclobutanes that exist as a mixture of interconverting conformers and possess neighboring C–H bonds within a highly strained framework are the targets herein for challenging the current suite of catalysts. Although most C–H functionalization tactics focus on generating 1,2-disubstituted cyclobutanes via substrate-controlled directing-group methods, the regiodivergent methods discussed in this paper provide access to chiral 1,1-disubstituted and cis-1,3-disubstituted cyclobutanes simply by changing the catalyst identity, thus permitting entry to novel chemical space. This study shows how to control site selectivity in C–H functionalization by simply using the correct catalyst. Cyclobutanes were used as the scaffold to illustrate the impact of catalyst control because the core unit is incorporated into various structures of biomedical interest. The catalysts control whether the chemistry occurs at C1 or C3 of the cyclobutane. Traditional synthetic strategies have viewed most C–H bonds as chemically inert and utilize functional groups for transformations. C–H functionalization is an attractive alternative strategy for the synthesis of complex organic molecules because it leads to the possibility of rapidly accessing novel chemical space. To fully develop this alternative approach, it is necessary to identify ways for reacting at specific C–H bonds even when a number of similar C–H bonds may exist in a substrate molecule. It would be particularly beneficial if a collection of catalysts were available, each with a preference for reaction at a specific C–H bond. Over the past few years, we have developed such a collection of catalysts for C–H functionalization chemistry of rhodium-bound carbenes. In this paper, we illustrate how these catalysts can be applied to the selective functionalization of cyclobutanes, leading to the formation of pharmaceutically relevant chiral building blocks.