手性有机小分子催化烯胺不对称还原

手性胺是合成天然产物和手性药物的重要中间体，亚胺和烯胺的不对称催化还原是制备手性胺最直接有效的方式之一。手性有机小分子催化的亚胺不对称还原已取得了可喜的进展，但到目前为止，有机小分子催化的烯胺不对称还原，尤其是环状烯胺的不对称还原还少有报道。 本研究从手性叔丁基亚磺酰胺出发，设计并合成了一系列含有叔丁基亚磺酰基的新型脲类及硫脲类催化剂，并将其用于催化三氯硅烷对烯胺的不对称还原，尤其是1, 4-二氢吡啶酯类环状烯胺的不对称还原。通过对催化反应条件的优化，发现当添加1eq H2O时，反应收率和对映选择性明显提高，获得高达99% 的收率和88% ee，同时也取得了很好的非对映选择性（dr = 8:92）。首次实现了三氯硅烷对1, 4-二氢吡啶酯类环状烯胺的高立体选择性还原。 通过机理方面的研究，我们推测反应过程中可能是：首先，底物1, 4-二氢吡啶酯与催化剂形成氢键而被活化，当加入添加剂后，添加剂与三氯硅烷反应释放出一个质子，然后受活化的1, 4-二氢吡啶酯捕获该质子转变成更活泼的亚胺正离子的中间体。随后，在催化剂上的手性硫氧的活化下，三氯硅烷的负氢加成到受活化的亚胺正离子的中间体上，最后生成比较有利的反式产物1, 4, 5, 6-四氢吡啶乙酯。 Calalytic enantioselective reduction of imines and enamines represents one of the most straightforward and efficient methods for the preparation of chiral amines, which is an important class of intermediates for the synthesis of natural products and chiral drugs. Significant progresses have been made in organocatalytic enantioselective reduction of imines. However, asymmetric reduction of enamines, especially of cyclic enamines catalyzed by small organocatalysts has scarcely been reported. In this study, starting from chiral tert-butanesulfinamide, a series of structurally simple tert-butanesulfinyl urea and thiourea organocatalysts were developed and employed in asymmetric reduction of enamines by triclorosilane, particularly in the reduction of cyclic enamines such as Hantzsch 1, 4-dihydropyridines. During the optimization of reaction condictions, we found that the addition of one equivalent of H2O could significantly improve the yields and enatioselectivities. Under optimal condictions, 99% yield, up to 88% ee, and 8:92 diastereomeric ratio were obtained. Thus, we have for the first time realized the highly stereoselective reduction of Hantzsch 1, 4-dihydropyridines catalyzed by triclorosilane. As for the mechanism, we speculate that the Hantzsch 1, 4-dihydropyridine was firstly engaged with the catalyst through hydrogen bond. The proton released from the reaction of the additive and triclorosilane next added to one of the C=C bond to make an active iminium intermediate, which was then attacked by the nucleophlic hydrogen of HSiCl3 activated by the Lewis basic sulfinyl function of the catalyst to provide superior trans-1, 4, 5, 6-tetrahydropyridine products.

路易斯碱催化的烯胺不对称还原研究

手性胺不仅是许多天然产物和手性药物的重要结构单元，而且也是非常有用的拆分试剂、手性配体和手性催化剂。亚胺和烯胺的不对称催化还原是制备手性胺的最直接有效的方式之一，手性有机小分子催化的亚胺不对称还原已取得了很大的进展，但到目前为止，有机小分子催化的烯胺不对称还原极少见文献报道。 本研究以廉价的三氯氢硅为氢源、DMF 等路易斯碱为催化剂实现了烯胺的高效还原。通过反应条件的优化，各种烯胺底物在0.1 eq. DMF 催化下、12 个小时内可以获得非常高的收率（>93%）。 在本课题组前期研究的基础上，我们筛选并设计了一系列以手性哌啶酸和叔丁基亚磺酰胺为母体的有机小分子路易斯碱催化剂，它们能催化三氯氢硅对(Z)-N-苄氧羰基-1-苯基丙烯胺的不对称还原，获得很高的收率和中等的对映选择性，并且具有很好的底物普适性。另外，通过机理方面的研究，我们推测在反应过程中一分子烯胺先捕获一个质子而转变为亚胺正离子，然后受到路易斯碱活化的三氯氢硅中的富电氢原子进攻该亚胺正离子得到还原产物。 另外，本文列出了在此课题进展中所发现的一些新反应，并且试图去阐释这些反应的作用机理。 Catalytic enantioselective reduction of imines and enamines represents one of the most straightforward and efficient methods for the preparation of chiral amines, which are not only important building blocks of many natrural products and chiral drugs, but also can serve as useful resolution reagents, chiral ligands and chiral catalysts. By now, asymmetric reduction of enamines catalyzed by organocatalysts has scarcely been reported, although organocatalyzed enantioselective reduction of imines has already gained great progress. In this study, we report the DMF-catalyzed reduction of enamines with high yields using HSiCl3 as the reducing agent. Under the optimized reaction conditions, various enamines can be reduced in the presence of 0.1 eq. DMF with high yields (>93%) in 12 hours. We screened a set of Lewis base organocatalysts derived from chiral pipecolinic acid and tert-butanesulfinamide for the reduction of (Z)-N-Cbz-1- phenylpropenamine, including newly designed ones and some of those previously developed in our lab. However, only moderate stereoselectivities, albeit high yields were obtained. As for the mechanism, we speculate that the enamine firstly engages a proton to form an iminium species, which is then attacked by the nucleophlic hydrogen of HSiCl3 activated by Leiws base. During the above studies, we have also discovered some new reactions, for which feasible mechanisms were proposed.