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Alcohols are abundant in the universe of chemicals. But their strong C–O bond makes it tough to alter the motif without modifying it first. Seeking a quick method for transforming alcohols into a wide range of other molecules, chemists developed a cross-coupling reaction that removes alcohols from sp3 carbons and replaces them with aromatic substituents. The reaction could be useful to medicinal chemists because it allows them to tweak complex alcohols to make new molecules that could have improved properties.
Cross-coupling reactions with sp3 substituents often use alkyl bromides, explains Princeton University chemistry professor David W. C. MacMillan, who developed the reaction with Zhe Dong, who was a postdoctoral scholar in MacMillan’s lab and is now a professor at Southern University of Science and Technology. “If you think about the diversity of alkyl bromides that are out there, it’s actually really small,” MacMillan says. “If you do the same analysis for alcohols, you realize it’s huge.”
The photoredox reaction uses a commercially available benzoxazolium salt to activate the C–O bond on the alcohol-containing starting compound. A light-activated iridium catalyst then breaks the bond to form a radical on the sp3 carbon atom. At the same time, a nickel catalyst reacts with an aryl halide, which carries the aromatic group that will take the alcohol’s place. This aryl-nickel species traps the carbon radical. Reductive elimination gives the new sp3–sp2 cross-coupled product (Nature 2021, DOI: 10.1038/s41586-021-03920-6).
The reaction works with primary, secondary, and tertiary alcohols. “If I see an alcohol, I can now imagine that could be any heteroaromatic, aromatic, five-membered heteroaromatic that I want it to be,” MacMillan says. He and Dong showed that the reaction works on medicinally important molecules by changing the alcohol on a taxol derivative to a heteroaromatic group (shown).
“The era of photoredox methods for building complex organic molecules has truly arrived,” says Jeremy Green, a veteran medicinal chemist and consultant, in an email. He says the work “opens the floodgates” for coupling sp3 carbons to sp2 carbons because it uses accessible alcohol reagents. Green notes that the cost and availability of the iridium catalyst might be a concern.
MacMillan hopes that chemists will find the reaction easy and useful to use. “It’s one thing when you publish a reaction that gets the concept, but it’s another one to actually make it general so that it works so broadly, that people will adopt it,” he says.
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