Exercise performed immediately after fructose ingestion enhances fructose oxidation and suppresses fructose storage

Exercise prevents the adverse effects of a high-fructose diet through mechanisms that remain unknown. We assessed the hypothesis that exercise prevents fructose-induced increases in very-low-density lipoprotein (VLDL) triglycerides by decreasing the fructose conversion into glucose and VLDL-triglyce...

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Bibliographic Details
Published in:The American journal of clinical nutrition 2016-02, Vol.103 (2), p.348-355
Main Authors: Egli, Léonie, Lecoultre, Virgile, Cros, Jérémy, Rosset, Robin, Marques, Anne-Sophie, Schneiter, Philippe, Hodson, Leanne, Gabert, Laure, Laville, Martine, Tappy, Luc
Format: Article
Language:English
Subjects:
Adult
Bicycling
Biomarkers - analysis
Biomarkers - blood
Blood Glucose - analysis
Blood Glucose - metabolism
Breath Tests
Carbohydrate Metabolism
Carbon Dioxide - analysis
Carbon Dioxide - metabolism
Carbon Isotopes
Cross-Over Studies
Dietary Carbohydrates - administration & dosage
Dietary Carbohydrates - adverse effects
Dietary Carbohydrates - metabolism
Exercise
Fructose - administration & dosage
Fructose - adverse effects
Fructose - metabolism
Glucose
Humans
Lactic Acid - blood
Lactic Acid - metabolism
Life Sciences
Lipids
Lipoproteins, VLDL - blood
Lipoproteins, VLDL - chemistry
Lipoproteins, VLDL - metabolism
Low density lipoprotein
Male
Motor Activity
Oxidation
Oxidation-Reduction
Palmitic Acid - blood
Palmitic Acid - metabolism
Postprandial Period
Sedentary Behavior
Young Adult
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Summary:Exercise prevents the adverse effects of a high-fructose diet through mechanisms that remain unknown. We assessed the hypothesis that exercise prevents fructose-induced increases in very-low-density lipoprotein (VLDL) triglycerides by decreasing the fructose conversion into glucose and VLDL-triglyceride and fructose carbon storage into hepatic glycogen and lipids. Eight healthy men were studied on 3 occasions after 4 d consuming a weight-maintenance, high-fructose diet. On the fifth day, the men ingested an oral (13)C-labeled fructose load (0.75 g/kg), and their total fructose oxidation ((13)CO2 production), fructose storage (fructose ingestion minus (13)C-fructose oxidation), fructose conversion into blood (13)C glucose (gluconeogenesis from fructose), blood VLDL-(13)C palmitate (a marker of hepatic de novo lipogenesis), and lactate concentrations were monitored over 7 postprandial h. On one occasion, participants remained lying down throughout the experiment [fructose treatment alone with no exercise condition (NoEx)], and on the other 2 occasions, they performed a 60-min exercise either 75 min before fructose ingestion [exercise, then fructose condition (ExFru)] or 90 min after fructose ingestion [fructose, then exercise condition (FruEx)]. Fructose oxidation was significantly (P < 0.001) higher in the FruEx (80% ± 3% of ingested fructose) than in the ExFru (46% ± 1%) and NoEx (49% ± 1%). Consequently, fructose storage was lower in the FruEx than in the other 2 conditions (P < 0.001). Fructose conversion into blood (13)C glucose, VLDL-(13)C palmitate, and postprandial plasma lactate concentrations was not significantly different between conditions. Compared with sedentary conditions, exercise performed immediately after fructose ingestion increases fructose oxidation and decreases fructose storage. In contrast, exercise performed before fructose ingestion does not significantly alter fructose oxidation and storage. In both conditions, exercise did not abolish fructose conversion into glucose or its incorporation into VLDL triglycerides. This trial was registered at clinicaltrials.gov as NCT01866215.
ISSN:0002-9165
1938-3207
DOI:10.3945/ajcn.115.116988