Introduction <p>The head-up tilt table test (HUTT) is a lengthy and uncomfortable procedure for patients which often induces fainting. Post-transient loss of consciousness, nausea, vomiting, and pallor may occur. This study aims to develop and evaluate the efficacy of anomaly detection methods based on autoencoding for early prediction of syncope onset, enabling preemptive HUTT termination and thereby avoiding unnecessary discomfort.</p> Methods <p>The four input signals: heart rate (HR), systolic blood pressure (SBP), diastolic blood pressure (DBP), and high frequency normalized RRI (Hfnu_RRI) were processed into feature images for explicit correlation encoding. The feature images served as input for the syncope detector, which consisted of an autoencoder (AE) coupled with an external algorithm that computed the severity of the cardiac anomaly. The choice of AE to model test-negative patients was evaluated across six unique candidate architectures. The best architecture was fine-tuned with the Keras Bayesian tuner. Lastly, the overall syncope detector was validated with 100 iterations.</p> Results <p>The developed temporal convolutional autoencoder anomaly detector (TCAAD) attained an accuracy of 0.9424, a recall of 0.9838, a precision of 0.9141, a specificity of 0.9009, an F1 score of 0.9461, and an early prediction time of 523.69&#xa0;s.</p> Conclusions <p>The model’s performance was comparable to other real-time prediction methods evaluated in this study, and demonstrated one of the longest early prediction times. This highlights the effectiveness of anomaly detection methods combined with signal correlation monitoring.</p>

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Deep Learning-Based Early Prediction of Syncope Onset During Tilt Table Testing via Temporal Convolutional Autoencoder Anomaly Detector

  • Alex Wee Wong,
  • Wee Jian Chin,
  • Maw Pin Tan,
  • Siew-Ying Mok,
  • Choon-Hian Goh

摘要

Introduction

The head-up tilt table test (HUTT) is a lengthy and uncomfortable procedure for patients which often induces fainting. Post-transient loss of consciousness, nausea, vomiting, and pallor may occur. This study aims to develop and evaluate the efficacy of anomaly detection methods based on autoencoding for early prediction of syncope onset, enabling preemptive HUTT termination and thereby avoiding unnecessary discomfort.

Methods

The four input signals: heart rate (HR), systolic blood pressure (SBP), diastolic blood pressure (DBP), and high frequency normalized RRI (Hfnu_RRI) were processed into feature images for explicit correlation encoding. The feature images served as input for the syncope detector, which consisted of an autoencoder (AE) coupled with an external algorithm that computed the severity of the cardiac anomaly. The choice of AE to model test-negative patients was evaluated across six unique candidate architectures. The best architecture was fine-tuned with the Keras Bayesian tuner. Lastly, the overall syncope detector was validated with 100 iterations.

Results

The developed temporal convolutional autoencoder anomaly detector (TCAAD) attained an accuracy of 0.9424, a recall of 0.9838, a precision of 0.9141, a specificity of 0.9009, an F1 score of 0.9461, and an early prediction time of 523.69 s.

Conclusions

The model’s performance was comparable to other real-time prediction methods evaluated in this study, and demonstrated one of the longest early prediction times. This highlights the effectiveness of anomaly detection methods combined with signal correlation monitoring.