Keto-adaptation enhances exercise performance and body composition responses to training in endurance athletes

Fionn T McSwiney; Bruce Wardrop; Parker N Hyde; Richard A Lafountain; Jeff S Volek; Lorna Doyle

doi:10.1016/j.metabol.2017.10.010

Keto-adaptation enhances exercise performance and body composition responses to training in endurance athletes

Metabolism. 2018 Apr:81:25-34. doi: 10.1016/j.metabol.2017.10.010. Epub 2017 Nov 3.

Authors

Fionn T McSwiney¹, Bruce Wardrop¹, Parker N Hyde², Richard A Lafountain², Jeff S Volek², Lorna Doyle³

Affiliations

¹ Department of Sport, and Exercise Science, Waterford Institute of Technology, Waterford, Ireland.
² Kinesiology Program, Department of Human Sciences, The Ohio State University, Columbus, OH, USA.
³ Department of Sport, and Exercise Science, Waterford Institute of Technology, Waterford, Ireland. Electronic address: lmdoyle@wit.ie.

PMID: 29108901
DOI: 10.1016/j.metabol.2017.10.010

Abstract

Background: Low-carbohydrate diets have recently grown in popularity among endurance athletes, yet little is known about the long-term (>4wk) performance implications of consuming a low-carbohydrate high fat ketogenic diet (LCKD) in well-trained athletes.

Methods: Twenty male endurance-trained athletes (age 33±11y, body mass 80±11kg; BMI 24.7±3.1kg/m²) who habitually consumed a carbohydrate-based diet, self-selected into a high-carbohydrate (HC) group (n=11, %carbohydrate:protein:fat=65:14:20), or a LCKD group (n=9, 6:17:77). Both groups performed the same training intervention (endurance, strength and high intensity interval training (HIIT)). Prior to and following successful completion of 12-weeks of diet and training, participants had their body composition assessed, and completed a 100km time trial (TT), six second (SS) sprint, and a critical power test (CPT). During post-intervention testing the HC group consumed 30-60g/h carbohydrate, whereas the LCKD group consumed water, and electrolytes.

Results: The LCKD group experienced a significantly greater decrease in body mass (HC -0.8kg, LCKD -5.9kg; P=0.006, effect size (ES): 0.338) and percentage body fat percentage (HC -0.7%, LCKD -5.2%; P=0.008, ES: 0.346). Fasting serum beta-hydroxybutyrate (βHB) significantly increased from 0.1 at baseline to 0.5mmol/L in the LCKD group (P=0.011, ES: 0.403) in week 12. There was no significant change in performance of the 100km TT between groups (HC -1.13min·s, LCKD -4.07min·s, P=0.057, ES: 0.196). SS sprint peak power increased by 0.8 watts per kilogram bodyweight (w/kg) in the LCKD group, versus a -0.1w/kg reduction in the HC group (P=0.025, ES: 0.263). CPT peak power decreased by -0.7w/kg in the HC group, and increased by 1.4w/kg in the LCKD group (P=0.047, ES: 0.212). Fat oxidation in the LCKD group was significantly greater throughout the 100km TT.

Conclusions: Compared to a HC comparison group, a 12-week period of keto-adaptation and exercise training, enhanced body composition, fat oxidation during exercise, and specific measures of performance relevant to competitive endurance athletes.

Keywords: Body composition; Endurance; High-carbohydrate; Ketogenic; Performance.

MeSH terms

Adaptation, Physiological*
Adult
Athletes*
Body Composition*
Diet, Ketogenic*
Dietary Carbohydrates / administration & dosage
Exercise*
Humans
Male
Physical Endurance*

Substances

Dietary Carbohydrates