# Recent advances in the cleavage of non-activated amides

**Authors:** Eun-Sol Choi, Hyo-Jun Lee

PMC · DOI: 10.3762/bjoc.22.23 · Beilstein Journal of Organic Chemistry · 2026-02-19

## TL;DR

This review discusses recent methods to break non-activated amide bonds, which are typically hard to modify, enabling new ways to synthesize important chemical compounds.

## Contribution

The paper highlights novel strategies for chemoselective cleavage of non-activated amide bonds using catalytic and activating methods.

## Key findings

- Transition-metal catalysis enables selective cleavage of non-activated amide bonds.
- Electrophilic activation and strong base-counter-cation systems improve amide bond reactivity.
- N-based activating groups offer new pathways for amide functionalization.

## Abstract

The amide bond is one of the most fundamental and widely utilized functional groups in organic chemistry, central to the structures of pharmaceuticals, bioactive molecules, and advanced materials. However, its exceptional resonance stabilization renders the C–N bond highly inert, posing a persistent synthetic challenge for its transformation. While twisted amides with distorted C–N bonds have offered useful reactivity enhancements, the selective activation of conventional, non-activated amides remains far more difficult. This review summarizes recent advances over the past decade in the activation and cleavage of non-activated amide C–N bonds for their conversion into diverse carboxylic acid derivatives. Key strategies covered include transition-metal catalysis, electrophilic activation, strong base-counter-cation systems, and N-based activating groups that enable chemoselective bond cleavage. Together, these developments provide powerful tools for amide functionalization and offer new opportunities for efficient, practical, and selective syntheses.

## Full-text entities

- **Chemicals:** menthone (MESH:C019466), CO2 (MESH:D002245), dimethyl sulfate (MESH:C007482), benzoxazole (MESH:D001583), Q (MESH:D005973), N,N-diethylbenzamide (MESH:C016089), thiophene (MESH:D013876), CuBr2 (MESH:C408079), Nb2O5 (MESH:C073337), OH- (MESH:C031356), methyl benzoate (MESH:C044605), Tungsten (MESH:D014414), N-fluorobenzenesulfonimide (MESH:C523711), Benzylamine (MESH:C030796), anilide (MESH:D000813), U (MESH:D014501), KI (MESH:C066186), alkali (MESH:D000468), alcohol (MESH:D000438), butanol (MESH:D000440), H (MESH:D006859), 1-adamantanol (MESH:C434445), fenofibric acid (MESH:C006012), imidate (MESH:D007096), trifluoroacetic anhydride (MESH:C017958), Z. (MESH:C000597310), Y (MESH:D015019), formamides (MESH:D005559), Manganese (MESH:D008345), indole (MESH:C030374), benzamide (MESH:C037689), S (MESH:D013455), pyrrolidine (MESH:C032519), graphite (MESH:D006108), DPT-BM (-), Anilines (MESH:D000814), N-benzyl-N-methylamine (MESH:C029991), potassium tert-butoxide (MESH:C077664), n-butanol (MESH:D020001), alkali metal (MESH:D008672), potassium (MESH:D011188), AA (MESH:D000596), amine (MESH:D000588), ethyl ester (MESH:C465446), CeO2 (MESH:C030583), octanol (MESH:D000442), F (MESH:D005461), E (MESH:D004540), 2-aminophenol (MESH:C027667), L (MESH:D007930), amide (MESH:D000577), water (MESH:D014867), TCCA (MESH:C557580), Palladium (MESH:D010165), diamide (MESH:D003958), phenol (MESH:D019800), Lewis acid (MESH:D058116), N,N-dimethylbenzamide (MESH:C038529), peptide (MESH:D010455), butylamine (MESH:D002082)
- **Mutations:** glycine residue in 94

## Full text

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## Figures

24 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12927485/full.md

## References

77 references — full list in the complete paper: https://tomesphere.com/paper/PMC12927485/full.md

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Source: https://tomesphere.com/paper/PMC12927485