A Bühlmann scite author profile

The functional characteristics of six world-class high-altitude mountaineers were assessed 2-12 mo after the last high-altitude climb. Each climber on one or several occasions had reached altitudes of 8,500 m or above without supplementary O2. Static and dynamic lung volumes and right and left echocardiographic measurements were found to be within normal limits of sedentary controls (SC). Muscle fiber distribution was 70% type I, 22% type IIa, and 7% type IIb. Mean muscle fiber cross-sectional area was significantly smaller than that of SC (-15%) and of long-distance runners (LDR, -51%). The number of capillaries per unit cross-sectional area was significantly greater than that of SC (+ 40%). Total mitochondrial volume was not significantly different from that of SC, but its subsarcolemmal component was equal to that of LDR. Average maximal O2 consumption was 60 +/- 6 ml X kg-1 X min-1, which is between the values of SC and LDR. Average maximal anaerobic power was 28 +/- 2.5 W X kg-1, which is equal to that of SC and 40% lower that that of competitive high jumpers. All subjects were characterized by resting hyperventilation both in normoxia and in moderate (inspired O2 partial pressure = 77 Torr) hypoxia resulting in higher oxyhemoglobin saturation levels in hypoxia. The ventilatory response to four tidal volumes of pure O2 was similar to that of SC. It is concluded that elite high-altitude climbers do not have physiological adaptations to high altitude that justify their unique performance.

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Decompression Sickness

Bühlmann¹

1984

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The Respiratory Dead Space

Rossier¹,

Bühlmann²

1955

Physiological Reviews

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Physiologie und Pathophysiologie der Atmung

Rossier¹,

Bühlmann²,

Wiesinger³

1958

179

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Tauchmedizin

Bühlmann¹

1995

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Deep diving and short decompression by breathing mixed gases

Keller

Bühlmann

1965

Journal of Applied Physiology

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A series of test dives carried out by 14 subjects in depths between 130 and 1,000 ft. for periods varying between 5 min and 2 hr revealed that changes of the inert gas in the breathing mixture permit a considerable shortening of the decompression time. The physical and physiological basis of the method is discussed. physiological properties of He, N2, and Ar related to molecular weight and solubility; differences in diffusion rate and saturation speed of He, N2, and Ar Submitted on January 18, 1965

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Pathophysiologie der Atmung

Rossier

Bühlmann

Wiesinger³

1958

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Post-Decompression Shock Due to Extravasation of Plasma

Brunner

Bühlmann

1964

The Lancet

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A Bühlmann

Physiological profile of world-class high-altitude climbers

Decompression Sickness

The Respiratory Dead Space

Physiologie und Pathophysiologie der Atmung

Tauchmedizin

Deep diving and short decompression by breathing mixed gases

Pathophysiologie der Atmung

Post-Decompression Shock Due to Extravasation of Plasma

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