Unlocking carbene reactivity by metallaphotoredox α-elimination

Article

Boyle, Benjamin T.; Dow, Nathan W.; Kelly, Christopher B.; Bryan, Marian C.; MacMillan, David W. C.

Princeton University; Johnson & Johnson; Janssen Pharmaceuticals; Johnson & Johnson; Janssen Pharmaceuticals

Nature

0028-6273

10.1038/s41586-024-07628-1

2024-07-25

The ability to tame high-energy intermediates is important for synthetic chemistry, enabling the construction of complex molecules and propelling advances in the field of synthesis. Along these lines, carbenes and carbenoid intermediates are particularly attractive, but often unknown, high-energy intermediates1,2. Classical methods to access metal carbene intermediates exploit two-electron chemistry to form the carbon-metal bond. However, these methods are usually prohibitive because of reagent safety concerns, limiting their broad implementation in synthesis3-6. Mechanistically, an alternative approach to carbene intermediates that could circumvent these pitfalls would involve two single-electron steps: radical addition to metal to forge the initial carbon-metal bond followed by redox-promoted alpha-elimination to yield the desired metal carbene intermediate. Here we realize this strategy through a metallaphotoredox platform that exploits iron carbene reactivity using readily available chemical feedstocks as radical sources and alpha-elimination from six classes of previously underexploited leaving groups. These discoveries permit cyclopropanation and sigma-bond insertion into N-H, S-H and P-H bonds from abundant and bench-stable carboxylic acids, amino acids and alcohols, thereby providing a general solution to the challenge of carbene-mediated chemical diversification. Metal carbenes are accessed using a metallaphotoredox platform that exploits iron carbene reactivity using readily available chemical feedstocks and alpha-elimination.