Abstract
Recent observations suggest that development of venous gas emboli (VGE) during high-altitude flying whilst breathing hyperoxic gas will be reduced by intermittent excursions to moderate altitude. The present study aimed to investigate if an early, single excursion from high to moderate altitude can be used as an in-flight means to reduce high-altitude decompression strain. Ten healthy men were investigated whilst breathing oxygen in a hypobaric chamber under two conditions, once during a 90-min continuous exposure to a simulated cabin altitude of 24,000 ft (High; H) and once during 10 min at 24,000 ft, followed by 30 min at 15,000 ft and by 80 min at 24,000 ft (high–low–high; H–L–H). VGE scores were assessed by cardiac ultrasound, using a 6-graded scale. In H, VGE increased throughout the course of the sojourn at 24,000 ft to attain peak value [median (range)] of 3 (2–4) at min 90, just prior to descent. In H–L–H, median VGE scores were 0 throughout the trial, except for at min 10, just prior to the excursion to 15,000 ft, whence the VGE score was 1.5 (0–3). Thus, an early, single excursion from high to moderate cabin altitude holds promise as an in-flight means to reduce the risk of altitude decompression sickness during long-duration high-altitude flying in aircraft with limited cabin pressurization. Presumably, such excursion acts by facilitating the gas exchange in decompression bubbles from a predomination of nitrogen to that of oxygen.
Highlights
Decompression strain remains a cardinal problem in several aerospace settings, for instance, during extra-vehicular space activities (“space walks”), high-altitude high-opening parachuting and, not the least, during high-altitude flying in military aircraft (McLean 2020; Stepanek and Webb 2008)
We have in a series of experiments investigated the decompression strain induced by high-altitude flying (at a cabin pressure corresponding to an altitude of 24,000 ft (7315 m; cabin altitude) interrupted by excursions to cabin altitudes of 15,000–20,000 ft (4572–6096 m), which are realistic for refueling, but not sufficient to completely compress gas bubbles formed in blood and other tissues at high altitude (Ånell et al 2019, 2020)
In the H condition, the presence of venous gas emboli (VGE) increased during the course of the exposure to 24,000 ft (p < 0.001), with the highest values being noted at the end of the exposure, both at rest [at 85 min, median: 1.5 (0–3)] and after knee bends [90 min: 3 (2–4)] (Fig. 1)
Summary
Decompression strain remains a cardinal problem in several aerospace settings, for instance, during extra-vehicular space activities (“space walks”), high-altitude high-opening parachuting and, not the least, during high-altitude flying in military aircraft (McLean 2020; Stepanek and Webb 2008). We have in a series of experiments investigated the decompression strain induced by high-altitude flying (at a cabin pressure corresponding to an altitude of 24,000 ft (7315 m; cabin altitude) interrupted by excursions to cabin altitudes of 15,000–20,000 ft (4572–6096 m), which are realistic for refueling, but not sufficient to completely compress gas bubbles formed in blood and other tissues at high altitude (Ånell et al 2019, 2020). By contrast, i.e. with the pilot breathing
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