20.27:

α-Hydroxy Ketones via Reductive Coupling of Esters: Acyloin Condensation Overview

JoVE Core
Organic Chemistry
A subscription to JoVE is required to view this content.  Sign in or start your free trial.
JoVE Core Organic Chemistry
α-Hydroxy Ketones via Reductive Coupling of Esters: Acyloin Condensation Overview

2,750 Views

00:00 min

April 30, 2023

The pinacol and McMurry reactions involve the reductive coupling of ketones or aldehydes. Similarly, the bimolecular reductive coupling of two ester molecules in the presence of sodium metal in an aprotic solvent yields an α-hydroxy ketone product. The α-hydroxy ketone is also called acyloin, so the reaction is referred to as ‘acyloin condensation.’

Figure1

In the acyloin condensation reaction, esters are converted to ketyls, which undergo radical dimerization to form an unstable tetrahedral intermediate. Further, this intermediate collapses to give a 1,2-diketone intermediate. The 1,2-diketones are comparatively more reactive than ketones towards electrophiles and reducing agents because of lower π* energy. Consequently, two electrons sequentially transfer to the 1,2-diketone to form an enediolate. Lastly, the enediolate intermediate is quenched with acid to yield an α-hydroxy ketone with a good yield.

Often some by-products are obtained alongside the major product because of the reactivity of nucleophilic enediolate. To overcome the side reactions and improve the yield of an acyloin, trimethylsilyl chloride is used to silylate the enediolate. This results in a bis-silyl ether, further hydrolyzed with aqueous acid to give α-hydroxy ketones.