Sea Mammal Research Unit, Scottish Oceans Institute, University of St. Andrews, St. Andrews, Scotland, United Kingdom.
Laboratory of Environmental and Respiratory Physiology, Department of Biomedical Sciences, University of Padova, Padova, Italy.
Am J Physiol Regul Integr Comp Physiol. 2024 Dec 1;327(6):R553-R567. doi: 10.1152/ajpregu.00085.2024. Epub 2024 Sep 6.
Although existing literature covers significant detail on the physiology of human freediving, the lack of standardized protocols has hindered comparisons due to confounding variables such as exercise and depth. By accounting for these variables, direct depth-dependent impacts on cardiovascular and blood oxygen regulation can be investigated. In this study, depth-dependent effects on ) cerebral hemodynamic and oxygenation changes, ) arterial oxygen saturation ([Formula: see text]), and ) heart rate during breath-hold diving without confounding effects of exercise were investigated. Six freedivers (51.0 ± 12.6 yr; means ± SD), instrumented with continuous-wave near-infrared spectroscopy for monitoring cerebral hemodynamic and oxygenation measurements, heart rate, and [Formula: see text], performed sled-assisted breath-hold dives to 15 m and 42 m. Arterial blood gas tensions were validated through cross-sectional periodic blood sampling. Cerebral hemodynamic changes were characteristic of breath-hold diving, with changes during ascent from both depths likely driven by decreasing [Formula: see text] due to lung expansion. Although [Formula: see text] was significantly lower following 42-m dives [(5) = -4.183, < 0.05], mean cerebral arterial-venous blood oxygen saturation remained at 74% following dives to both depths. Cerebral oxygenation during ascent from 42 m may have been maintained through increased arterial delivery. Heart rate was variable with no significant difference in minimum heart rate between both depths [(5) = -1.017, > 0.05]. This study presents a standardized methodology, which could provide a basis for future research on human freediving physiology and uncover ways in which freedivers can reduce potential risks of the sport. We present a standardized methodology in which trained breath-hold divers instrumented with wearable near-infrared spectroscopy (NIRS) technology and a cannula for arterial blood sampling completed sled-assisted dives to two different dive depths to account for the confounding factors of exercise and depth during breath-hold diving. In our investigation, we highlight the utility of wearable NIRS systems for continuous hemodynamic and oxygenation monitoring to investigate the impacts of hydrostatic pressure on cardiovascular and blood oxygen regulation.
尽管现有文献涵盖了人类自由潜水生理学的大量细节,但由于运动和深度等混杂变量的存在,缺乏标准化的方案妨碍了比较。通过考虑这些变量,可以研究直接依赖于深度的对心血管和血氧调节的影响。在这项研究中,我们研究了深度依赖性对 ) 脑血流动力学和氧合变化、 ) 动脉血氧饱和度 ([Formula: see text]) 和 ) 屏气潜水期间的心率的影响,而没有运动的混杂影响。六名自由潜水员(51.0 ± 12.6 岁;平均值 ± 标准差),配备连续波近红外光谱仪以监测脑血流动力学和氧合测量、心率和 [Formula: see text] ,进行雪橇辅助的 15 米和 42 米屏气潜水。通过横截面定期血液采样验证动脉血气张力。脑血流动力学变化是屏气潜水的特征,从这两个深度上升时的变化可能是由于肺扩张导致 [Formula: see text] 下降引起的。尽管 42 米潜水后 [Formula: see text] 显著降低 [(5) = -4.183, < 0.05],但在两个深度潜水后,平均脑动静脉血氧饱和度仍保持在 74%。从 42 米上升时的脑氧合可能通过增加动脉输送来维持。心率变化不定,两个深度之间的最低心率没有显著差异 [(5) = -1.017, > 0.05]。本研究提出了一种标准化的方法,可为人类自由潜水生理学的未来研究提供基础,并揭示自由潜水员可以降低该运动潜在风险的方法。我们提出了一种标准化的方法,其中受过训练的屏气潜水员配备可穿戴近红外光谱 (NIRS) 技术和用于动脉采血的套管,完成到两个不同潜水深度的雪橇辅助潜水,以考虑到屏气潜水期间运动和深度的混杂因素。在我们的研究中,我们强调了可穿戴 NIRS 系统用于连续血流动力学和氧合监测的实用性,以研究静水压力对心血管和血氧调节的影响。
