Science

Divergent and consecutive skeletal editing of saturated primary amines

2026. 4. 29. Source: Science

Summary

Given the prevalence of nitrogen heterocycles in pharmaceuticals, divergent skeletal editing techniques that enable rapid access to a diverse library of azacycles from a single substrate are highly desirable. Herein, we report a skeletal editing approach that converts abundant saturated primary amines into N-heterocycles, with exceptional functional-group compatibility, broad skeletal diversity, superior regioselectivity, and diastereospecificity (both >20:1). By harnessing the reactivity

Content

# Divergent and consecutive skeletal editing of saturated primary amines *Published: 2026 Apr 30* Given the prevalence of nitrogen heterocycles in pharmaceuticals, divergent skeletal editing techniques that enable rapid access to a diverse library of azacycles from a single substrate are highly desirable. Herein, we report a skeletal editing approach that converts abundant saturated primary amines into N-heterocycles, with exceptional functional-group compatibility, broad skeletal diversity, superior regioselectivity, and diastereospecificity (both >20:1). By harnessing the reactivity of hypervalent iodines, an imino ether intermediate is generated through mild iodane-mediated oxidation, facile N-internalization, and methoxy anion addition. This pivotal intermediate serves as a versatile platform capable of interception by a wide spectrum of nucleophiles, thereby enabling the generation of structurally diverse nitrogen heterocycles (>15 classes). Furthermore, this strategy enables challenging site-controlled carbon-to-nitrogen transmutation and ring contraction of natural products through a one-pot, consecutive skeletal editing sequence. DOI: 10.1126/science.aee5416