Sudden cardiac death multiparametric classification system for Chagas heart disease's patients based on clinical data and 24-hours ECG monitoring

Carlos H. L. Cavalcante; Pedro E. O. Primo; Carlos A. F. Sales; Weslley L. Caldas; João H. M. Silva; Amauri H. Souza; Emmanuel S. Marinho; Roberto C. Pedrosa; João A. L. Marques; Hélcio S. Santos; João P. V. Madeiro; Carlos H. L. Cavalcante; Pedro E. O. Primo; Carlos A. F. Sales; Weslley L. Caldas; João H. M. Silva; Amauri H. Souza; Emmanuel S. Marinho; Roberto C. Pedrosa; João A. L. Marques; Hélcio S. Santos; João P. V. Madeiro

doi:10.3934/mbe.2023402

Mathematical Biosciences and Engineering

2023, Volume 20, Issue 5: 9159-9178. doi: 10.3934/mbe.2023402

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Sudden cardiac death multiparametric classification system for Chagas heart disease's patients based on clinical data and 24-hours ECG monitoring

1.
Federal Institute of Education and Technology of Ceara, Maracanau, Ceara, Brazil
2.
State University of Ceara - Center for Science and Technology, Fortaleza, Ceara, Brazil
3.
Computer Science Department – Federal University of Ceara, Fortaleza, Ceara, Brazil
4.
Oswaldo Cruz Foundation (Fiocruz), Eusebio, Ceara, Brazil
5.
Edson Saad Heart Institute – Federal University of Rio de Janeiro, Rio de Janeiro, Brazil
6.
Laboratory of Applied Neurosciences -University of Saint Joseph, Macau SAR, China

Academic Editor: Simon James Fong

Received: 30 September 2022 Revised: 01 February 2023 Accepted: 20 February 2023 Published: 14 March 2023

About 6.5 million people are infected with Chagas disease (CD) globally, and WHO estimates that $ > million people worldwide suffer from ChHD. Sudden cardiac death (SCD) represents one of the leading causes of death worldwide and affects approximately 65% of ChHD patients at a rate of 24 per 1000 patient-years, much greater than the SCD rate in the general population. Its occurrence in the specific context of ChHD needs to be better exploited. This paper provides the first evidence supporting the use of machine learning (ML) methods within non-invasive tests: patients' clinical data and cardiac restitution metrics (CRM) features extracted from ECG-Holter recordings as an adjunct in the SCD risk assessment in ChHD. The feature selection (FS) flows evaluated 5 different groups of attributes formed from patients' clinical and physiological data to identify relevant attributes among 57 features reported by 315 patients at HUCFF-UFRJ. The FS flow with FS techniques (variance, ANOVA, and recursive feature elimination) and Naive Bayes (NB) model achieved the best classification performance with 90.63% recall (sensitivity) and 80.55% AUC. The initial feature set is reduced to a subset of 13 features (4 Classification; 1 Treatment; 1 CRM; and 7 Heart Tests). The proposed method represents an intelligent diagnostic support system that predicts the high risk of SCD in ChHD patients and highlights the clinical and CRM data that most strongly impact the final outcome.
- sudden cardiac death,
- Chagas heart disease,
- machine learning,
- ECG
Citation: Carlos H. L. Cavalcante, Pedro E. O. Primo, Carlos A. F. Sales, Weslley L. Caldas, João H. M. Silva, Amauri H. Souza, Emmanuel S. Marinho, Roberto C. Pedrosa, João A. L. Marques, Hélcio S. Santos, João P. V. Madeiro. Sudden cardiac death multiparametric classification system for Chagas heart disease's patients based on clinical data and 24-hours ECG monitoring[J]. Mathematical Biosciences and Engineering, 2023, 20(5): 9159-9178. doi: 10.3934/mbe.2023402

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Abstract

About 6.5 million people are infected with Chagas disease (CD) globally, and WHO estimates that $ > million people worldwide suffer from ChHD. Sudden cardiac death (SCD) represents one of the leading causes of death worldwide and affects approximately 65% of ChHD patients at a rate of 24 per 1000 patient-years, much greater than the SCD rate in the general population. Its occurrence in the specific context of ChHD needs to be better exploited. This paper provides the first evidence supporting the use of machine learning (ML) methods within non-invasive tests: patients' clinical data and cardiac restitution metrics (CRM) features extracted from ECG-Holter recordings as an adjunct in the SCD risk assessment in ChHD. The feature selection (FS) flows evaluated 5 different groups of attributes formed from patients' clinical and physiological data to identify relevant attributes among 57 features reported by 315 patients at HUCFF-UFRJ. The FS flow with FS techniques (variance, ANOVA, and recursive feature elimination) and Naive Bayes (NB) model achieved the best classification performance with 90.63% recall (sensitivity) and 80.55% AUC. The initial feature set is reduced to a subset of 13 features (4 Classification; 1 Treatment; 1 CRM; and 7 Heart Tests). The proposed method represents an intelligent diagnostic support system that predicts the high risk of SCD in ChHD patients and highlights the clinical and CRM data that most strongly impact the final outcome.

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