A Telesurveillance System with Automatic Electrocardiogram Interpretation Based on Support Vector Machine and Rule-based Processing

Overview

Journal JMIR Med Inform

Publisher JMIR Publications

Specialty Medical Informatics

Date 2015 May 9

PMID 25953306

Citations 6

Authors

Te-Wei Ho

Chen-Wei Huang

Ching-Miao Lin

Feipei Lai

Jian-Jiun Ding

Yi-Lwun Ho

Chi-Sheng Hung

Affiliations

Soon will be listed here.

Abstract

Background: Telehealth care is a global trend affecting clinical practice around the world. To mitigate the workload of health professionals and provide ubiquitous health care, a comprehensive surveillance system with value-added services based on information technologies must be established.

Objective: We conducted this study to describe our proposed telesurveillance system designed for monitoring and classifying electrocardiogram (ECG) signals and to evaluate the performance of ECG classification.

Methods: We established a telesurveillance system with an automatic ECG interpretation mechanism. The system included: (1) automatic ECG signal transmission via telecommunication, (2) ECG signal processing, including noise elimination, peak estimation, and feature extraction, (3) automatic ECG interpretation based on the support vector machine (SVM) classifier and rule-based processing, and (4) display of ECG signals and their analyzed results. We analyzed 213,420 ECG signals that were diagnosed by cardiologists as the gold standard to verify the classification performance.

Results: In the clinical ECG database from the Telehealth Center of the National Taiwan University Hospital (NTUH), the experimental results showed that the ECG classifier yielded a specificity value of 96.66% for normal rhythm detection, a sensitivity value of 98.50% for disease recognition, and an accuracy value of 81.17% for noise detection. For the detection performance of specific diseases, the recognition model mainly generated sensitivity values of 92.70% for atrial fibrillation, 89.10% for pacemaker rhythm, 88.60% for atrial premature contraction, 72.98% for T-wave inversion, 62.21% for atrial flutter, and 62.57% for first-degree atrioventricular block.

Conclusions: Through connected telehealth care devices, the telesurveillance system, and the automatic ECG interpretation system, this mechanism was intentionally designed for continuous decision-making support and is reliable enough to reduce the need for face-to-face diagnosis. With this value-added service, the system could widely assist physicians and other health professionals with decision making in clinical practice. The system will be very helpful for the patient who suffers from cardiac disease, but for whom it is inconvenient to go to the hospital very often.

Citing Articles

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Yang L, Lee J, Tsai C, Chen Y, Huang C, Wu H J Med Internet Res. 2023; 25:e47947.

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The Impact of Synchronous Telehealth Services With a Digital Platform on Day-by-Day Home Blood Pressure Variability in Patients with Cardiovascular Diseases: Retrospective Cohort Study.

Chen Y, Hung C, Huang C, Lee J, Yu J, Ho Y J Med Internet Res. 2022; 24(1):e22957.

PMID: 35006089 PMC: 8787660. DOI: 10.2196/22957.

A Lightweight Deep Learning Model for Fast Electrocardiographic Beats Classification With a Wearable Cardiac Monitor: Development and Validation Study.

Jeon E, Oh K, Kwon S, Son H, Yun Y, Jung E JMIR Med Inform. 2020; 8(3):e17037.

PMID: 32163037 PMC: 7099397. DOI: 10.2196/17037.

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