Ensemble learning of myocardial displacements for myocardial infarction detection in echocardiography

Tuan Nguyen; Phi Nguyen; Dai Tran; Hung Pham; Quang Nguyen; Thanh Le; Hanh Van; Bach Do; Phuong Tran; Vinh Le; Thuy Nguyen; Long Tran; Hieu Pham

doi:10.3389/fcvm.2023.1185172

Ensemble learning of myocardial displacements for myocardial infarction detection in echocardiography

Front Cardiovasc Med. 2023 Oct 13:10:1185172. doi: 10.3389/fcvm.2023.1185172. eCollection 2023.

Authors

Tuan Nguyen^#^{1

2}, Phi Nguyen^#³, Dai Tran⁴, Hung Pham⁵, Quang Nguyen⁵, Thanh Le⁵, Hanh Van⁵, Bach Do⁵, Phuong Tran⁵, Vinh Le⁶, Thuy Nguyen⁶, Long Tran³, Hieu Pham^{1

2}

Affiliations

¹ VinUni-Illinois Smart Health Center, VinUniversity, Hanoi, Vietnam.
² College of Engineering and Computer Science, VinUniversity, Hanoi, Vietnam.
³ Institute for Artificial Intelligence, VNU University of Engineering and Technology, Hanoi, Vietnam.
⁴ Cardiovascular Center, E Hospital, Hanoi, Vietnam.
⁵ Vietnam National Heart Institute, Bach Mai Hospital, Hanoi, Vietnam.
⁶ Faculty of Information Technology, VNU University of Engineering and Technology, Hanoi, Vietnam.

^# Contributed equally.

Abstract

Background: Early detection and localization of myocardial infarction (MI) can reduce the severity of cardiac damage through timely treatment interventions. In recent years, deep learning techniques have shown promise for detecting MI in echocardiographic images. Existing attempts typically formulate this task as classification and rely on a single segmentation model to estimate myocardial segment displacements. However, there has been no examination of how segmentation accuracy affects MI classification performance or the potential benefits of using ensemble learning approaches. Our study investigates this relationship and introduces a robust method that combines features from multiple segmentation models to improve MI classification performance by leveraging ensemble learning.

Materials and methods: Our method combines myocardial segment displacement features from multiple segmentation models, which are then input into a typical classifier to estimate the risk of MI. We validated the proposed approach on two datasets: the public HMC-QU dataset (109 echocardiograms) for training and validation, and an E-Hospital dataset (60 echocardiograms) from a local clinical site in Vietnam for independent testing. Model performance was evaluated based on accuracy, sensitivity, and specificity.

Results: The proposed approach demonstrated excellent performance in detecting MI. It achieved an F1 score of 0.942, corresponding to an accuracy of 91.4%, a sensitivity of 94.1%, and a specificity of 88.3%. The results showed that the proposed approach outperformed the state-of-the-art feature-based method, which had a precision of 85.2%, a specificity of 70.1%, a sensitivity of 85.9%, an accuracy of 85.5%, and an accuracy of 80.2% on the HMC-QU dataset. On the external validation set, the proposed model still performed well, with an F1 score of 0.8, an accuracy of 76.7%, a sensitivity of 77.8%, and a specificity of 75.0%.

Conclusions: Our study demonstrated the ability to accurately predict MI in echocardiograms by combining information from several segmentation models. Further research is necessary to determine its potential use in clinical settings as a tool to assist cardiologists and technicians with objective assessments and reduce dependence on operator subjectivity. Our research codes are available on GitHub at https://github.com/vinuni-vishc/mi-detection-echo.

Keywords: deep learning; diagnostic ability; echocardiography; image segmentation; machine learning; motion estimation; myocardial infarction; regional wall motion abnormality.

Grants and funding

The research is supported by the Vingroup Innovation Foundation (VINIF) under project code VINIF.2019.DA02, and it is also supported by the VinUni-Illinois Smart Health Center at VinUniversity.