Arterial Blood Gases During Diving in Elite Apnea Divers

 

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Abstract

Elite apnea divers have considerably extended the limits of dive depth and duration but the mechanisms allowing humans to tolerate the compression- and decompression-induced changes in alveolar gas partial pressures are still not fully understood. Therefore we measured arterial blood gas tensions and acid-base-status in two elite apnea divers during simulated wet dives lasting 3 : 55 and 5 : 05 minutes, respectively. Arterial pO₂ followed the compression- (from 13.8/16.9 kPa before the dive to 30 kPa at the start of the bottom time) and decompression-induced (from 13.7/21.0 kPa to 3.3/4.9 kPa immediately after surfacing) variations of ambient pressure, while the arterial pCO₂ remained within the physiologic range (3.0/3.9 kPa before diving vs. 5.7/5.9 kPa at the end of the bottom time), probably due to the CO₂ storage capacity of the blood. These findings may help to explain why humans can sustain deep and long apnea dives without major increases in respiratory drive.

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CM Muth, MD

Division of Pathophysiology and Process Development in Anaesthesia · Department of Anaesthesiology · University Medical School · Ulm · Germany

Parkstr. 11 · 89073 Ulm · Germany

Phone: +49-731-50025140

Fax: 49-731-50025143

Email: claus-martin.muth@medizin.uni-ulm.de