Formaldehyde-mediated Hydride Liberation of Alkylamines for Intermolecular Reactions in HFIP

03 October 2023, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

The ability of alkylamines to spontaneously liberate hydride ions is typically restrained, except under specific intramolecular reaction settings. Herein, we demonstrate that this reactivity can be unlocked through the simple treatment with formaldehyde in hexafluoroisopropanol (HFIP) solvent, thereby enabling various intermolecular hydride transfer reactions of alkylamines under mild conditions. Besides transformations of small molecules, these reactions enable unique late-stage modification of complex peptides. Mechanistic investigations uncover that the key to these intermolecular hydride transfer processes lies in the accommodating conformation of solvent-mediated macrocyclic transition states, where the aggregates of HFIP molecules act as dexterous proton shuttles. Importantly, negative hyperconjugation between the lone electron pair of nitrogen and the anti-bonding orbital of amine’s C-H bond plays a critical role in the C-H activation, promoting its hydride-liberation.

Keywords

C-H activation
peptide modification
alkylamine dehydrogenation
N-methylation

Supplementary materials

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Supporting Information
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Detailed synthetic procedures, additional control experiments, compound characterization, LC-MS trace, NMR spectra, and computational experiments.
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