Role of the Air-Blood Barrier Phenotype in Lung Oxygen Uptake and Control of Extravascular Water.

The air blood barrier phenotype can be reasonably described by the ratio of lung capillary blood volume to the diffusion capacity of the alveolar membrane (), which can be determined at rest in normoxia. The distribution of the ratio in the population is normal; shifts from ∼1, reflecting a higher number of alveoli of smaller radius, providing a high alveolar surface and a limited extension of the capillary network, to just opposite features on increasing up to ∼6. We studied the kinetics of alveolar-capillary equilibration on exposure to edemagenic conditions (work at ∼60% maximum aerobic power) in hypoxia (HA) (PO 90 mmHg), based on an estimate of time constant of equilibration (τ) and blood capillary transit time (). A shunt-like effect was described for subjects having a high ratio, reflecting a longer τ (>0.5 s) and a shorter (<0.8 s) due to pulmonary vasoconstriction and a larger increase in cardiac output (>3-fold). The tendency to develop lung edema in edemagenic conditions (work in HA) was found to be directly proportional to the value of as suggested by an estimate of the mechanical properties of the respiratory system with the forced frequency oscillation technique.