Ketogenic Diet but Not Free-sugar Restriction Alters Glucose Tolerance, Lipid Metabolism, Peripheral Tissue Phenotype, and Gut Microbiome: RCT

Overview

Journal Cell Rep Med

Publisher Cell Press

Specialties Biology
General Medicine

Date 2024 Aug 6

PMID 39106867

Authors

Aaron Hengist

Russell G Davies

Jean-Philippe Walhin

Jariya Buniam

Lucy H Merrell

Lucy Rogers

Louise Bradshaw

Alfonso Moreno-Cabanas

Peter J Rogers

Jeff M Brunstrom

Leanne Hodson

Luc J C van Loon

Wiley Barton

Ciara ODonovan

Fiona Crispie

Orla OSullivan

Paul D Cotter

Kathryn Proctor

James A Betts

Francoise Koumanov

Dylan Thompson

Javier T Gonzalez

Affiliations

Soon will be listed here.

Abstract

Restricted sugar and ketogenic diets can alter energy balance/metabolism, but decreased energy intake may be compensated by reduced expenditure. In healthy adults, randomization to restricting free sugars or overall carbohydrates (ketogenic diet) for 12 weeks reduces fat mass without changing energy expenditure versus control. Free-sugar restriction minimally affects metabolism or gut microbiome but decreases low-density lipoprotein cholesterol (LDL-C). In contrast, a ketogenic diet decreases glucose tolerance, increases skeletal muscle PDK4, and reduces AMPK and GLUT4 levels. By week 4, the ketogenic diet reduces fasting glucose and increases apolipoprotein B, C-reactive protein, and postprandial glycerol concentrations. However, despite sustained ketosis, these effects are no longer apparent by week 12, when gut microbial beta diversity is altered, possibly reflective of longer-term adjustments to the ketogenic diet and/or energy balance. These data demonstrate that restricting free sugars or overall carbohydrates reduces energy intake without altering physical activity, but with divergent effects on glucose tolerance, lipoprotein profiles, and gut microbiome.

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