Effects of 8-weeks of daily time restricted feeding and aerobic exercise on fat oxidation – A randomized controlled trial

  • Florian Hofstaetter University of Innsbruck, Department of sport science, Austria
  • Linda Rausch University of Innsbruck, Department of sport science, Austria
  • Martin Niedermeier University of Innsbruck, Department of sport science, Austria
  • Martin Kopp University of Innsbruck, Department of sport science, Austria
  • Justin Lawley University of Innsbruck, Department of sport science, Austria
Keywords: fat oxidation, fatmax training, time restricted feeding, intermittent fasting

Abstract

Introduction & Purpose

Substrate metabolism, especially lipid metabolism and thus fat oxidation, is of special interest to reduce the risk of metabolic diseases (diabetes, high cholesterol or triglycerides, etc), and improve athletic performance (Aird et al., 2018). Thus, patients and athletes are recommended to engage in exercise training at a mild to moderate intensity where fat oxidation is high.

Fasting is known to increase lipolysis (i.e., fat oxidation) and therefore may represent a simple intervention to increase training induced adaptions in fat oxidation (Venables & Jeukendrup, 2008). However, breaking the fast with a carbohydrate meal prior to aerobic training may limit these benefits because carbohydrate consumption is known to prioritize carbohydrate oxidation during exercise (Achten & Jeukendrup, 2003).

Therefore, we tested the hypothesis that 8 weeks of aerobic exercise training at a workload that maximizes fat oxidation would improve the maximal rate of fat oxidation during exercise. Moreover, engaging in a fasting regime would augment the improvements in fat oxidation, but breaking the fast prior to training with a carbohydrate rich snack would attenuate the improvements in fat oxidation.

Methods

Thirty-six participants (28 females, 8 males) were randomized into three groups. 1) One group fasted for at least 14 hours prior to training, 2) One group fasted, but consumed a carbohydrate rich snack 30 minutes prior to training, 3) One exercise only control group where participants could eat ad libitum. Pre-tests included anthropometric measurements, a bio-impedance-analyses, and cycle ergometry combined with indirect calorimetry to identify maximum rates of fat oxidation (fatmax). All participants exercised on a stationary bike 3x/week for 60 min at a heart rate that corresponded to 90-100% of their individualized fatmax values. Pre-test measurements were repeated after the intervention. Rates of fat and carbohydrate oxidation, energy expenditure and heart rate were analysed as workload matched and absolute data using a series of 3 x 2 mixed ANOVAs.

Results

3 x 2 mixed ANOVA showed no group-by-time interactions for any workload-matched data (fatmax: p = .371, η²p = .058; CHO: p = .540, η²p = .037; EE: p = .470, η²p = .045; HR: p = .570, η²p = .033). No significant group-by-time interactions at the absolute maximal fat oxidation rate were observed (fatmax: p = .262, η²p = .078; CHO: p = .966, η²p = .002; EE: p = .111, η²p = .125; HR: p = .618, η²p = .029).

Discussion and conclusion

In the current study, the addition of a 16-hour fasting window did not provide any additional improvements in fat oxidation rates beyond an ad libitum control group. This is surprising as both low-intensity training (Achten & Jeukendrup, 2004) and TRF (Jong-Yeon et al., 2002) have independently been shown to improve fat oxidation.

We conclude that fatmax training is an effective lifestyle intervention to improve fat oxidation in young healthy individuals. Collectively, these data suggest fatmax training independent of the fed state might be a useful lifestyle intervention in healthy individuals looking to maintain or improve their metabolic health and avoid future metabolic disease.

References

Achten, J., & Jeukendrup, A. E. (2003). The effect of pre-exercise carbohydrate feedings on the intensity that elicits maximal fat oxidation. Journal of Sports Sciences, 21(12), 1017–1025. https://doi.org/10.1080/02640410310001641403

Achten, J., & Jeukendrup, A. E. (2004). Optimizing fat oxidation through exercise and diet. Nutrition, 20(7-8), 716–727. https://doi.org/10.1016/j.nut.2004.04.005

Aird, T. P., Davies, R. W., & Carson, B. P. (2018). Effects of fasted vs fed-state exercise on performance and post-exercise metabolism: A systematic review and meta-analysis. Scandinavian Journal of Medicine and Science in Sports, 28(5), 1476–1493. https://doi.org/10.1111/sms.13054

Jong-Yeon, K., Hickner, R. C., Dohm, G. L., & Houmard, J. A. (2002). Long- and medium-chain fatty acid oxidation is increased in exercise-trained human skeletal muscle. Metabolism, 51(4), 460–464. https://doi.org/10.1053/meta.2002.31326

Venables, M. C., & Jeukendrup, A. E. (2008). Endurance training and obesity: Effect on substrate metabolism and insulin sensitivity. Medicine & Science in Sports & Exercise, 40(3), 495–502. https://doi.org/10.1249/MSS.0b013e31815f256f

Published
23.09.2024
How to Cite
Hofstaetter, F., Rausch, L., Niedermeier, M., Kopp, M., & Lawley, J. (2024). Effects of 8-weeks of daily time restricted feeding and aerobic exercise on fat oxidation – A randomized controlled trial. Current Issues in Sport Science (CISS), 9(4), 005. https://doi.org/10.36950/2024.4ciss005