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DOI: 10.1055/a-2680-2368
Unexpected Regiochemical Control in the Nugent–RajanBabu Reductive Epoxide Cyclization
Authors
We thank the NIH for support of this work through grant R35-GM145252. N.S. was supported by a fellowship from the Royal Thai Government.
Abstract
The Nugent–RajanBabu reductive epoxide cyclization has become a mainstay of alternative methods to accomplish classical, biomimetic, cationic polyene cyclizations. In most cases, the regiochemical control for the formation of decalins and perhydrophenanthrenes is exquisite, mirroring that obtained in cationic reactions, to the point where the 6-endo reactivity is anticipated even in the face of potential 5-exo processes. In our studies toward complex, polyoxygenated terpenoid natural products, we had cause to evaluate the reactions of α-alkoxy epoxides in these types of reactions, and we were surprised to uncover a means to control 6-endo vs. 5-exo reactions based on the size of the protecting group on the α-oxygen. This knowledge opens up the possibility of rapid syntheses of highly oxygenated cyclopentane systems, in addition to the expected decalin scaffolds.
Publication History
Received: 19 June 2025
Accepted after revision: 08 August 2025
Accepted Manuscript online:
08 August 2025
Article published online:
22 October 2025
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Gold-catalyzed polyene cyclizations were advanced by Gagné and coworkers:
For recent examples of related π-acid-induced polycyclizations in natural product synthesis, see:
Carreira’s enantioselective, Ir-catalyzed polyene cyclization is an important advance:
For a selected example in total synthesis, see:
Although there are several methods for initiating radical polycyclizations, by far the most used for natural product synthesis involve either reductive radical formation from epoxides or oxidative radical formation from β-ketoesters. For reviews of each, see:
For some key examples, see:
In a related study, our lab used the Co-catalyzed, MHAT-induced radical bicyclization method to make a complex brasilicardin A analogue:
For representative examples, see:
Two total syntheses of brasilicardin A have been reported:
For a review that remains highly relevant, see:
In spite of precedent showing similar substrates undergoing highly enantioselective CBS-catalyzed Diels–Alder cycloaddition, in our hands this procedure resulted in cycloadducts of only 59% see: