Abstract
Lung and muscle oxygen diffusion capacities (DLO(2) and DMO(2), respectively) are difficult to measure at maximal-intensity exercise and at altitude and they are scarcely reported in the literature, yet they are key components of the O(2) transport cascade. The goal of the present study was to compute DLO(2) and DMO(2) at simulated increasing altitudes between sea-level and Mount Everest. Literature data were compiled to compute DLO(2) and DMO(2) at maximal exercise using a forward iterative algorithm. These computations were repeated every 250 m of increasing altitude between seal level and the altitude of Mount Everest. Computed DLO(2) increased from sea-level to 5500 m and then decreased to the altitude of Mount Everest; yet remaining higher than sea-level values. DMO(2) increased from sea-level to 3500 m and then progressively decreased to values lower than sea-level. The computed variations in DLO(2) and DMO(2) fit with the ability of the lung and muscle to increase their diffusion capacity at altitude, which seemingly indicates an existing diffusion capacity reserve. The muscle reserve seems depleted at a lower altitude than the lung reserve. The clinical relevance of the proposed model requires further investigation.