A network physiology approach to oxygen saturation variability during normobaric hypoxia.
Yuji JiangJoseph T CostelloThomas B WilliamsNawamin PanyapieanAmar S BhogalAlex Sander da Rosa AraujoJo CorbettAlireza ManiPublished in: Experimental physiology (2020)
Peripheral capillary oxygen saturation ( S p O 2 ) exhibits a complex pattern of fluctuations during hypoxia. The physiological interpretation of S p O 2 variability is not well understood. In this study, we tested the hypothesis that S p O 2 fluctuation carries information about integrated cardio-respiratory control in healthy individuals using a network physiology approach. We explored the use of transfer entropy in order to compute the flow of information between cardio-respiratory signals during hypoxia. Twelve healthy males (mean (SD) age 22 (4) years) were exposed to four simulated environments (fraction of inspired oxygen ( F I O 2 ): 0.12, 0.145, 0.17, and 0.2093) for 45 min, in a single blind randomized controlled design. The flow of information between different physiological parameters ( S p O 2 , respiratory frequency, tidal volume, minute ventilation, heart rate, end-tidal pressure of O2 and CO2 ) were analysed using transfer entropy. Normobaric hypoxia was associated with a significant increase in entropy of the S p O 2 time series. The transfer entropy analysis showed that, particularly at F I O 2 0.145 and 0.12, the flow of information between S p O 2 and other physiological variables exhibits a bidirectional relationship. While reciprocal interactions were observed between different cardio-respiratory parameters during hypoxia, S p O 2 remained the main hub of this network. S p O 2 fluctuations during graded hypoxia exposure carry information about cardio-respiratory control. Therefore, S p O 2 entropy analysis has the potential for non-invasive assessment of the functional connectivity of respiratory control system in various healthcare settings.