Wearable Tracking of Eye and Body Movements During Breaching Training: Towards Real-Time Blast Injury Monitoring

TL;DR

This paper presents a wearable system that monitors physiological responses during blast exposure, using machine learning to assess injury risk in real-time, which could improve blast injury detection in occupational settings.

Contribution

The study introduces a novel wearable device that combines multiple physiological signals with machine learning to predict blast injury risk in real-time.

Findings

Blast events as low as 0.25 psi relate to physiological changes.

Fused physiological measures improve injury risk prediction.

Identified individuals with rapid physiological deterioration after low-level blasts.

Abstract

Repeated exposure to blast overpressure in occupational settings has been associated with changes in cognitive and psychological health, as well as deficits in neurosensory subsystems. In this work, we describe a wearable system to simultaneously monitor physiology and blast exposure levels and demonstrate how this system can identify individualized exposure levels corresponding to acute physiological response to blast exposure. Machine learning was used to develop a dose-response model that fused multiple physiological measures (electrooculuography, gait, and balance) into a single risk score by predicting the level of blast exposure on held-out subjects (Fused model, R = 0.60). We found that blast events with peak pressure levels as low as 0.25 psi could be related to physiological changes and hence may contribute to blast injury. We also identified an individual subject with deteriorating reaction time scores that consistently showed a rapid and anomalous change in physiology-based risk scores after exposure to low-level blast events. Our results suggest that the wearable approach to blast monitoring is viable in weapons training environments as a complement to more direct but sparsely administered brain health assessments, potentially viable in austere environments, and that fusing multiple physiological signals can improve sensitivity.