Expert Augmented Prediction of Circulatory and Respiratory Instability from High Resolution Vital Signs.

Journal: NPJ digital medicine
Published Date:

Abstract

Timely detection of circulatory and respiratory instability (CRI) is critical in intensive care units (ICUs), yet existing early warning systems often rely on single-parameter indices that underutilize continuous vital-sign data or on delayed, difficult-to-interpret multimodal clinical data. Leveraging routinely collected high-frequency vital-sign monitoring, we developed an interpretable, expert-augmented early warning system based on 1-second-resolution heart rate, blood pressure, respiratory rate, and oxygen saturation data. Machine‑learning models were trained on 627,958 h of continuous vital‑sign data from 1702 ICU patients at the First Affiliated Hospital of Sun Yat‑sen University and externally validated in the MIMIC‑III cohort. Models incorporating trend-based, reference, and statistical features derived from vital-sign trajectories achieved strong predictive performance (AUROC > 0.8) in both internal and external validation, outperforming conventional single-parameter indices and achieving performance comparable to models incorporating laboratory and demographic variables. Increasing temporal resolution improved predictive accuracy, with trend-based features contributing most strongly to model predictions. To improve clinical interpretability, tree-based models were transformed into physiologically meaningful decision rules and refined through expert-augmented learning, resulting in the Expert-Augmented Early Warning System (EAEWS). EAEWS generated accurate, low-frequency alerts with transparent explanations aligned with bedside monitoring, and may provide a scalable framework for real-time CRI detection in ICUs.

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