TY - JOUR
T1 - Exogenous glucose oxidation during exercise is positively related to body size
T2 - Body size and carbohydrate metabolism
AU - Ijaz, Abdullah
AU - Collins, Adam
AU - Moreno-Cabañas, Alfonso
AU - Bradshaw, Louise
AU - Hutchins, Katie
AU - Podlogar, Tim
AU - Wallis, Gareth A
AU - Gonzalez, Javier
PY - 2024/8/6
Y1 - 2024/8/6
N2 - There is little evidence that body size alters exogenous glucose oxidation rates during exercise. This study assessed whether larger people oxidize more exogenous glucose during exercise than smaller people. Fifteen cyclists were allocated into two groups based on body mass (SMALL, <70 kg body mass, n=9, 2 female) or (LARGE, >70 kg body mass, n=6) matched for lactate threshold (SMALL: 2.3±0.4 Wkg-1, LARGE: 2.3±0.3 Wkg-1). SMALL completed 120 min of cycling at 95% of lactate threshold1. LARGE completed two trials in a random order, one at 95% of lactate threshold1 [thereby exercising at the same relative intensity (RELATIVE)], and one at an absolute intensity matched to SMALL (ABSOLUTE). In all trials, cyclists ingested 90 gh-1 of 13C-enriched glucose. Total exogenous glucose oxidation was (mean±SD) 33±8 gh-1 in SMALL versus 45±13 gh-1 in LARGE-RELATIVE (mean difference: 13 gh-1, 95%CI 2 to 24 gh-1, p=0.03]. Large positive correlations were observed for measures of exogenous carbohydrate oxidation versus body size (body mass, height and body surface area; e.g., body surface area versus peak exogenous glucose oxidation, r=0.85,95%CI: 0.51 to 0.95, p<0.01). When larger athletes reduced the intensity from RELATIVE to ABSOLUTE, total exogenous glucose oxidation was 39±7 gh-1 (p=0.43 versus LARGE-RELATIVE). In conclusion, the capacity for exogenous glucose oxidation is, on average, higher in larger athletes than smaller athletes during exercise. The extent to which this is due to higher absolute exercise intensity requires further research, but body size may be a consideration in tailoring sports nutrition guidelines for carbohydrate intake during exercise.
AB - There is little evidence that body size alters exogenous glucose oxidation rates during exercise. This study assessed whether larger people oxidize more exogenous glucose during exercise than smaller people. Fifteen cyclists were allocated into two groups based on body mass (SMALL, <70 kg body mass, n=9, 2 female) or (LARGE, >70 kg body mass, n=6) matched for lactate threshold (SMALL: 2.3±0.4 Wkg-1, LARGE: 2.3±0.3 Wkg-1). SMALL completed 120 min of cycling at 95% of lactate threshold1. LARGE completed two trials in a random order, one at 95% of lactate threshold1 [thereby exercising at the same relative intensity (RELATIVE)], and one at an absolute intensity matched to SMALL (ABSOLUTE). In all trials, cyclists ingested 90 gh-1 of 13C-enriched glucose. Total exogenous glucose oxidation was (mean±SD) 33±8 gh-1 in SMALL versus 45±13 gh-1 in LARGE-RELATIVE (mean difference: 13 gh-1, 95%CI 2 to 24 gh-1, p=0.03]. Large positive correlations were observed for measures of exogenous carbohydrate oxidation versus body size (body mass, height and body surface area; e.g., body surface area versus peak exogenous glucose oxidation, r=0.85,95%CI: 0.51 to 0.95, p<0.01). When larger athletes reduced the intensity from RELATIVE to ABSOLUTE, total exogenous glucose oxidation was 39±7 gh-1 (p=0.43 versus LARGE-RELATIVE). In conclusion, the capacity for exogenous glucose oxidation is, on average, higher in larger athletes than smaller athletes during exercise. The extent to which this is due to higher absolute exercise intensity requires further research, but body size may be a consideration in tailoring sports nutrition guidelines for carbohydrate intake during exercise.
KW - carbohydrate
KW - cycling
KW - metabolism
KW - sports nutrition
M3 - Article
SN - 1526-484X
JO - International Journal of Sport Nutrition and Exercise Metabolism
JF - International Journal of Sport Nutrition and Exercise Metabolism
ER -