Lung membrane conductance and capillary volume derived from the NO and CO transfer in high-altitude newcomers

Jean-Benoît Martinot, Massimiliano Mulè, Claire de Bisschop, Maria J. Overbeek, Nhat-Nam Le-Dong, Robert Naeije, Hervé Guénard
2013 Journal of applied physiology  
Martinot JB, Mulè M, de Bisschop C, Overbeek MJ, Le-Dong N, Naeije R, Guénard H. Lung membrane conductance and capillary volume derived from the NO and CO transfer in high-altitude newcomers. Acute exposure to high altitude may induce changes in carbon monoxide (CO) membrane conductance (DmCO) and capillary lung volume (Vc). Measurements were performed in 25 lowlanders at Brussels (D0), at 4,300 m after a 2-or 3-day exposure (D2,3) without preceding climbing, and 5 days later (D7,8), before and
more » ... after an exercise test, under a trial with two arterial pulmonary vasodilators or a placebo. The nitric oxide (NO)/CO transfer method was used, assuming both infinite and finite values to the NO blood conductance (NO). Doppler echocardiography provided hemodynamic data. Compared with sea level, lung diffusing capacity for CO increased by 24% at D2,3 and is returned to control at D7,8. The acute increase in lung diffusing capacity for CO resulted from increases in DmCO and Vc with finite and infinite NO assumptions. The alveolar volume increased by 16% at D2,3 and normalized at D7,8. The mean increase in systolic arterial pulmonary pressure at rest at D 2,3 was minimal. In conclusion, the acute increase in Vc may be related to the increase in alveolar volume and to the increase in capillary pressure. Compared with the infinite NO value, the use of a finite NO value led to about a twofold increase in DmCO value and to a persistent increase in DmCO at D7,8 compared with D0. After exercise, Dm CO decreased slightly less in subjects treated by the vasodilators, suggesting a beneficial effect on interstitial edema. altitude; hypoxia; lung diffusion; capillary volume; membrane conductance; pulmonary capillary pressure; pulmonary hypertension 1 This article is the topic of an Invited Editorial by John M. B. Hughes (26a).
doi:10.1152/japplphysiol.01455.2012 pmid:23599397 fatcat:thhslerjrba35neabvhpalqzyy