Abstract
The human physiological system is stressed to its limits during endurance sports competition events.We describe a whole body computational model for energy conversion during bicycle racing. About 23 per cent of the metabolic energy is used for muscle work, the rest is converted to heat. We calculated heat transfer by conduction and blood flow inside the body, and heat transfer from the skin by radiation, convection and sweat evaporation, resulting in temperature changes in 25 body compartments. We simulated a mountain time trial to Alpe d'Huez during the Tour de France. To approach the time realized by Lance Armstrong in 2004, very high oxygen uptake must be sustained by the simulated cyclist. Temperature was predicted to reach 39°C in the brain, and 39.7°C in leg muscle. In addition to the macroscopic simulation, we analysed the buffering of bursts of high adenosine triphosphate hydrolysis by creatine kinase during cyclical muscle activity at the biochemical pathway level. To investigate the low oxygen to carbohydrate ratio for the brain, which takes up lactate during exercise, we calculated the flux distribution in cerebral energy metabolism. Computational modelling of the human body, describing heat exchange and energy metabolism, makes simulation of endurance sports events feasible. This journal is
| Original language | English |
|---|---|
| Pages (from-to) | 4295-4315 |
| Number of pages | 21 |
| Journal | Philosophical Transactions of the Royal Society of London A. Mathematical, Physical and Engineering Sciences |
| Volume | 369 |
| Issue number | 1954 |
| Early online date | 13 Nov 2011 |
| DOIs | |
| Publication status | Published - Nov 2011 |
| Externally published | Yes |
Keywords
- Heat transport
- Mathematical model
- Metabolic pathways
- Muscle power
- Skeletal muscle metabolism
- Whole body modelling
- n/a OA procedure