Jack Reeves and his science.

John T. (Jack) Reeves' science is reviewed across the 37 years of his research career at the University of Colorado Health Sciences Center, a period which occupied approximately half his remarkable life. His contributions centered on understanding the inter-relatedness as well as the underlying mechanisms controlling the various components of the O(2) transport system.

Insights by Peruvian scientists into the pathogenesis of human chronic hypoxic pulmonary hypertension.

Pulmonary hypertension had long been suspected in high-altitude natives of the Andes. However, it remained for a team of Peruvian scientists led by Dante Penaloza to provide not only the first clear evidence that humans living at high altitude did indeed have chronic, and occasionally severe, pulmonary hypertension, but more importantly, that this was a consequence of structural changes in the pulmonary vascular bed. Novel histological findings by one of the team, Javier Arias-Stella, indicated that hypoxia-induced thickening of the pulmonary arteriolar walls was the primary cause of the elevated pressure.

Exercise-dependent ventilatory sensitivity to hypoxia in Andean natives.

In Andean natives (NAT), the ventilatory response to hypoxia is blunted at rest but potential interaction with exercise has been little studied. Therefore, during three levels of submaximal exercise, 13 NAT were compared with 6 sojourners (SOJ) acclimatized at 4,360 m for an average of 7 months. Exercise ventilation was measured first breathing oxygen (PI(O(2)) 410 Torr) and then ambient air (PI(O(2)) 86 Torr).

Circulatory responses to high altitude in the cat and rabbit.

Cats were taken from Denver (5,200 ft.) to Mt. Evans (14,150 ft.

Pulmonary vasoconstriction in steers at high altitude.

Each of ten steers taken for 9 weeks to 12,700 ft. (Mt. Evans, Colorado) showed a marked increase in pulmonary artery (PA) pressure.

Pulmonary circulation and oxygen transport in lambs at high altitude.

The oxygen transport and pulmonary hemodynamics of lambs native to low altitude were evaluated in Denver and on Mount Evans (12,700 ft.). Because the Hb-O2 dissociation curve is placed well to the right of most other mammals, markedly depressed arterial O2 saturations (59%) occurred at high altitude.