A Novel Hepatocyte Ketone Production Assay to Help the Selection of Nutrients for the Ketogenic Diet Treatment of Epilepsy

Overview

Journal Sci Rep

Specialty Science

Date 2024 May 24

PMID 38789658

Authors

Hester Meeusen

Alessia Romagnolo

Sophie A C Holsink

Thijs J M van den Broek

Ardy van Helvoort

Jan A Gorter

Erwin A van Vliet

J Martin Verkuyl

Jose P Silva

Eleonora Aronica

Affiliations

Soon will be listed here.

Abstract

The classic ketogenic diet is an effective treatment option for drug-resistant epilepsy, but its high fat content challenges patient compliance. Optimizing liver ketone production guided by a method comparing substrates for their ketogenic potential may help to reduce the fat content of the diet without loss in ketosis induction. Here, we present a liver cell assay measuring the β-hydroxybutyrate (βHB) yield from fatty acid substrates. Even chain albumin-conjugated fatty acids comprising between 4 and 18 carbon atoms showed a sigmoidal concentration-βHB response curve (CRC) whereas acetate and omega-3 PUFAs produced no CRC. While CRCs were not distinguished by their half-maximal effective concentration (EC50), they differed by maximum response, which related inversely to the carbon chain length and was highest for butyrate. The assay also suitably assessed the βHB yield from fatty acid blends detecting shifts in maximum response from exchanging medium chain fatty acids for long chain fatty acids. The assay further detected a dual role for butyrate and hexanoic acid as ketogenic substrate at high concentration and ketogenic enhancer at low concentration, augmenting the βHB yield from oleic acid and a fatty acid blend. The assay also found propionate to inhibit ketogenesis from oleic acid and a fatty acid blend at low physiological concentration. Although the in vitro assay shows promise as a tool to optimize the ketogenic yield of a fat blend, its predictive value requires human validation.

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