1. Asymmetric Synthesis of Cα‐Substituted Prolines through Curtin–Hammett‐Controlled Diastereoselective N‐Alkylation.
- Author
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Cho, Hyunkyung, Jeon, Hongjun, Shin, Jae Eui, Lee, Seokwoo, Park, Soojun, and Kim, Sanghee
- Subjects
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PROLINE , *NANOPARTICLES , *ENANTIOSELECTIVE catalysis , *ALKYLATION , *RING formation (Chemistry) - Abstract
Asymmetric synthesis of α‐substituted proline derivatives has been accomplished by an efficient chirality‐transfer method. High diastereoselectivity of the N‐alkylation of the proline ester (C→N chirality transfer) was achieved when a 2,3‐disubstituted benzyl group was used as the N‐substituent. DFT calculations provided a mechanistic rationale for the high degree of stereoselectivity. The generated N‐chirality of the quaternary ammonium salt was transferred back to the α‐carbon through a stereoselective [2,3]‐Stevens rearrangement (N→C chirality transfer) to give α‐substituted proline ester. C→N→C chirality transfer: An efficient chirality‐transfer process was established for the asymmetric synthesis of α‐substituted proline derivatives. Using a 2,3‐disubstituted benzyl group as the N‐substituent, a high level of C→N chirality transfer was achieved, which enabled the enantioselective synthesis of the α‐substituted prolines through [2,3]‐Stevens rearrangement (N→C chirality transfer). DFT calculations suggested that this selective N‐alkylation follows Curtin–Hammett kinetics. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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