An Explainable Machine-Learning Model for Compensatory Reserve Measurement: Methods for Feature Selection and the Effects of Subject Variability

• Published in: Bioengineering (Basel) Vol. 10; no. 5; p. 612
• Main Authors: Bedolla, Carlos N., Gonzalez, Jose M., Vega, Saul J., Convertino, Víctor A., Snider, Eric J.
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 19.05.2023; MDPI
• Subjects: 60 APPLIED LIFE SCIENCES; Algorithms; Artificial intelligence; Artificial neural networks; Bioengineering; Biotechnology & Applied Microbiology; Blood pressure; Caregivers; Compensators; compensatory mechanisms; Computer simulation; Decision trees; Deep learning; Emergency medical care; Emergency medical services; Engineering; feature extraction; Hemodynamics; Hemorrhage; Hypovolemia; Learning algorithms; Lower body negative pressure; Machine learning; Medical personnel; Medical research; Neural networks; personalized medicine; Physiology; R&D; Research & development; Sensors; Signal processing; Variability; Vital signs; Waveforms; United States; United States > US; compensatory mechanisms; lower body negative pressure; machine learning; feature extraction; signal processing; personalized medicine
• ISSN: 2306-5354; 2306-5354
• DOI: 10.3390/bioengineering10050612

Tracking vital signs accurately is critical for triaging a patient and ensuring timely therapeutic intervention. The patient’s status is often clouded by compensatory mechanisms that can mask injury severity. The compensatory reserve measurement (CRM) is a triaging tool derived from an arterial waveform that has been shown to allow for earlier detection of hemorrhagic shock. However, the deep-learning artificial neural networks developed for its estimation do not explain how specific arterial waveform elements lead to predicting CRM due to the large number of parameters needed to tune these models. Alternatively, we investigate how classical machine-learning models driven by specific features extracted from the arterial waveform can be used to estimate CRM. More than 50 features were extracted from human arterial blood pressure data sets collected during simulated hypovolemic shock resulting from exposure to progressive levels of lower body negative pressure. A bagged decision tree design using the ten most significant features was selected as optimal for CRM estimation. This resulted in an average root mean squared error in all test data of 0.171, similar to the error for a deep-learning CRM algorithm at 0.159. By separating the dataset into sub-groups based on the severity of simulated hypovolemic shock withstood, large subject variability was observed, and the key features identified for these sub-groups differed. This methodology could allow for the identification of unique features and machine-learning models to differentiate individuals with good compensatory mechanisms against hypovolemia from those that might be poor compensators, leading to improved triage of trauma patients and ultimately enhancing military and emergency medicine.