Palladium (II)-catalyzed cascade reactions initiated with directed activation of unactivated sp3 C–H bonds

Tetrahedron chem Pub Date : 2023-08-01 DOI:10.1016/j.tchem.2023.100046

Robbie Ge , Faith Herington , Alana Mangawang , Debabrata Maiti , Haibo Ge

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Abstract

Cascade reactions—chemical processes consisting of two or more reactions in one pot—offer considerable advantages in terms of time, cost, atom efficiency, and reduced waste generation, and have thus unsurprisingly attracted considerable attention amongst the chemical community in recent decades. On the other hand, transition metal-catalyzed site-selective carbon-hydrogen (C–H) bond functionalization represents one of the most significant and efficient synthetic approaches in organic chemistry, enabling the conversion of common petroleum chemicals into highly valuable products in a single step. Utilization of this approach in cascades dramatically improves its applicability by allowing for the efficient construction of complex molecules from simple starting materials in a single pot. This perspective summarizes the developments in palladium (II)-catalyzed cascade reactions initiated with directed activation of unactivated aliphatic C–H bonds and our recent efforts in synthesizing bicyclic lactones, followed by current challenges and future opportunities.

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钯(II)催化的级联反应由未激活的sp3 C-H键的定向激活引发

级联反应——在一个罐中由两个或多个反应组成的化学过程——在时间、成本、原子效率和减少废物产生方面具有相当大的优势，因此在近几十年来受到了化学界的广泛关注。另一方面，过渡金属催化的位点选择性碳氢键功能化是有机化学中最重要和最有效的合成方法之一，它可以在一步内将普通石油化学品转化为高价值产品。这种方法在级联中的应用极大地提高了其适用性，因为它允许在单个锅中从简单的起始材料高效地构建复杂分子。本观点总结了钯(II)催化的级联反应的进展，这些反应是由未激活的脂肪族C-H键的定向激活引发的，以及我们最近在合成双环内酯方面的努力，以及当前的挑战和未来的机遇。

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