Division of Chemistry & Mathematical Science, School of Physical & Mathematical Sciences, Nanyang Technological University, Singapore, 637371, Singapore.
Guizhou University of Traditional Chinese Medicine, Guiyang, 550025, China.
Angew Chem Int Ed Engl. 2021 Jan 4;60(1):159-165. doi: 10.1002/anie.202008369. Epub 2020 Nov 3.
The dominated approaches for asymmetric aldol reactions have primarily focused on the aldol carbon-carbon bond-forming events. Here we postulate and develop a new catalytic strategy that seeks to modulate the reaction thermodynamics and control the product enantioselectivities via post-aldol processes. Specifically, an NHC catalyst is used to activate a masked enolate substrate (vinyl carbonate) to promote the aldol reaction in a non-enantioselective manner. This reversible aldol event is subsequently followed by an enantioselective acylative kinetic resolution that is mediated by the same (chiral) NHC catalyst without introducing any additional substance. This post-aldol process takes care of the enantioselectivity issues and drives the otherwise reversible aldol reaction toward a complete conversion. The acylated aldol products bearing quaternary/tetrasubstituted carbon stereogenic centers are formed in good yields and high optical purities.
对于不对称醛醇反应,占主导地位的方法主要集中在醛醇碳-碳键形成事件上。在这里,我们假设并开发了一种新的催化策略,试图通过后醛醇过程调节反应热力学并控制产物对映选择性。具体来说,使用 NHC 催化剂激活掩蔽烯醇化物底物(碳酸乙烯酯)以非对映选择性的方式促进醛醇反应。随后,通过相同的(手性)NHC 催化剂介导的对映选择性酰基化动力学拆分来进行后续反应,而无需引入任何其他物质。这个后醛醇过程解决了对映选择性问题,并使原本可逆的醛醇反应朝着完全转化的方向进行。带有季碳/四取代碳手性中心的酰化醛醇产物以良好的收率和高光学纯度形成。
