Effects of two glucose ingestion rates on substrate utilization during moderate-intensity shivering

DP Blondin, I Dépault, P Imbeault, F Péronnet… - European journal of …, 2010 - Springer
DP Blondin, I Dépault, P Imbeault, F Péronnet, MA Imbeault, F Haman
European journal of applied physiology, 2010Springer
Although the importance of food consumption to survive in the cold is well established, most
shivering studies have focused on fuel selection in fasting subjects. Therefore, the aim of the
present study was to provide the first estimates of exogenous glucose as well as liver and
muscle glycogen oxidation rates of non-cold acclimatized men (n= 6) ingesting glucose in
trace amounts (Control; C), and at rates of 400 mg min− 1 (Low Glucose; LG), and 800 mg
min− 1 (High Glucose; HG) during moderate-intensity shivering (~ 3 times resting metabolic …
Abstract
Although the importance of food consumption to survive in the cold is well established, most shivering studies have focused on fuel selection in fasting subjects. Therefore, the aim of the present study was to provide the first estimates of exogenous glucose as well as liver and muscle glycogen oxidation rates of non-cold acclimatized men (n = 6) ingesting glucose in trace amounts (Control; C), and at rates of 400 mg min−1 (Low Glucose; LG), and 800 mg min−1 (High Glucose; HG) during moderate-intensity shivering (~3 times resting metabolic rate or ~20% VO2max) using indirect calorimetry and stable isotope methodologies. Exogenous glucose oxidation peaked at ~200 mg min−1 at the lowest glucose ingestion rate (~400 mg min−1). In addition, glucose ingestion increased the contribution of plasma glucose to total heat production by ~50% but did not change the role played by muscle glycogen (~27% of heat production for control condition and ~23–28% for LG and HG). Instead, the contribution of liver-derived glucose to total heat production was reduced by 40–60% in LG and HG, respectively. In conclusion, glucose ingestion even at low rates contributes a significant proportion of total heat production during moderate intensity shivering and reduces the utilization of liver-derived glucose but not muscle glycogen.
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