Please use this identifier to cite or link to this item: http://hdl.handle.net/10553/50916
Title: Integrative conductance of oxygen during exercise at altitude
Authors: Calbet, Jose A. L. 
Lundby, Carsten
Boushel, Robert
UNESCO Clasification: 241106 Fisiología del ejercicio
Keywords: VO2max
Oxygen transport
Fatigue
Lung
Diffusing capacity
Issue Date: 2016
Publisher: 0065-2598
Journal: Advances in Experimental Medicine and Biology 
Abstract: In the oxygen (O2) cascade downstream steps can never achieve higher flows of O2 than the preceding ones. At the lung the transfer of O2 is determined by the O2 gradient between the alveolar space and the lung capillaries and the O2 diffusing capacity (DLO2). While DLO2 may be increased several times during exercise by recruiting more lung capillaries and by increasing the oxygen carrying capacity of blood due to higher peripheral extraction of O2, the capacity to enhance the alveolocapillary PO2 gradient is more limited. The transfer of oxygen from the alveolar space to the hemoglobin (Hb) must overcome first the resistance offered by the alveolocapillary membrane (1/DM) and the capillary blood (1/θVc). The fractional contribution of each of these two components to DLO2 remains unknown. During exercise these resistances are reduced by the recruitment of lung capillaries. The factors that reduce the slope of the oxygen dissociation curve of the Hb (ODC) (i.e., lactic acidosis and hyperthermia) increase 1/θVc contributing to limit DLO2. These effects are accentuated in hypoxia. Reducing the size of the active muscle mass improves pulmonary gas exchange during exercise and reduces the rightward shift of the ODC. The flow of oxygen from the muscle capillaries to the mitochondria is pressumably limited by muscle O2 conductance (DmcO2) (an estimation of muscle oxygen diffusing capacity). However, during maximal whole body exercise in normoxia, a higher flow of O2 is achieved at the same pressure gradients after increasing blood [Hb], implying that in healthy humans exercising in normoxia there is a functional reserve in DmcO2. This conclusion is supported by the fact that during small muscle exercise in chronic hypoxia, peak exercise DmcO2 is similar to that observed during exercise in normoxia despite a markedly lower O2 pressure gradient driving diffusion.
URI: http://hdl.handle.net/10553/50916
ISBN: 978-1-4899-7676-5
ISSN: 0065-2598
DOI: 10.1007/978-1-4899-7678-9_26
Source: Hypoxia: Translation In Progress[ISSN 0065-2598],v. 903, p. 395-408
Appears in Collections:Capítulo de libro
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