Characterizing drivers of change in intraoperative cerebral saturation using supervised machine learning.
Journal:
Journal of clinical monitoring and computing
Published Date:
Feb 7, 2025
Abstract
Regional cerebral oxygen saturation (rSO) is used to monitor cerebral perfusion with emerging evidence that optimization of rSO may improve neurological and non-neurological outcomes. To manipulate rSO an understanding of the variables that drive its behavior is necessary, and this can be accomplished using supervised machine learning. This study aimed to establish a hierarchy by which various hemodynamic and ventilatory variables contribute to intraoperative changes in rSO. A post-hoc analysis 146 patients undergoing high risk surgery. rSO was partitioned into segments with a change of at least 3% points over 5 min. Features from hemodynamic and ventilatory variables were used to train a machine learning classification algorithm (XGBoost) for prediction of association with either up or down-sloping rSO. The classifier was optimized and validated using five-fold cross validation. Feature importance was quantified based on information gain and permutation feature importance. The optimized classifier demonstrated a mean accuracy of 77.1% (SD 8.0%) and a mean area-under-ROC-curve of 0.86 (SD 0.06). The most important features based on information gain were the slope of the associated ETCO signal, the slope of the SPO signal, and the mean of the MAP signal. CO is a significant mediator of changes in rSO in an intraoperative setting, through its established effects on cerebral blood flow. This study furthers our overall understanding of the complex physiologic process that governs cerebral oxygenation by quantifying the hierarchy by which rSO is affected. Clinical Trial Number NCT01838733 (ClinicalTrials.gov).
Authors
Keywords
Adult
Aged
Algorithms
Brain
Carbon Dioxide
Cerebrovascular Circulation
Female
Hemodynamics
Humans
Machine Learning
Male
Middle Aged
Monitoring, Intraoperative
Oximetry
Oxygen
Oxygen Saturation
Reproducibility of Results
ROC Curve
Signal Processing, Computer-Assisted
Spectroscopy, Near-Infrared
Supervised Machine Learning