Cardiovascular disease/stroke risk stratification in deep learning framework: a review

Mrinalini Bhagawati; Sudip Paul; Sushant Agarwal; Athanasios Protogeron; Petros P Sfikakis; George D Kitas; Narendra N Khanna; Zoltan Ruzsa; Aditya M Sharma; Omerzu Tomazu; Monika Turk; Gavino Faa; George Tsoulfas; John R Laird; Vijay Rathore; Amer M Johri; Klaudija Viskovic; Manudeep Kalra; Antonella Balestrieri; Andrew Nicolaides; Inder M Singh; Seemant Chaturvedi; Kosmas I Paraskevas; Mostafa M Fouda; Luca Saba; Jasjit S Suri

doi:10.21037/cdt-22-438

Cardiovascular disease/stroke risk stratification in deep learning framework: a review

Cardiovasc Diagn Ther. 2023 Jun 30;13(3):557-598. doi: 10.21037/cdt-22-438. Epub 2023 Jun 5.

Authors

Mrinalini Bhagawati¹, Sudip Paul¹, Sushant Agarwal^{2

3}, Athanasios Protogeron⁴, Petros P Sfikakis⁵, George D Kitas⁶, Narendra N Khanna⁷, Zoltan Ruzsa⁸, Aditya M Sharma⁹, Omerzu Tomazu¹⁰, Monika Turk¹¹, Gavino Faa¹², George Tsoulfas¹³, John R Laird¹⁴, Vijay Rathore¹⁵, Amer M Johri¹⁶, Klaudija Viskovic¹⁷, Manudeep Kalra¹⁸, Antonella Balestrieri¹⁹, Andrew Nicolaides²⁰, Inder M Singh²¹, Seemant Chaturvedi²², Kosmas I Paraskevas²³, Mostafa M Fouda²⁴, Luca Saba¹⁹, Jasjit S Suri²¹

Affiliations

¹ Department of Biomedical Engineering, North-Eastern Hill University, Shillong, India.
² Advanced Knowledge Engineering Centre, GBTI, Roseville, CA, USA.
³ Department of Computer Science Engineering, PSIT, Kanpur, India.
⁴ Department of Cardiovascular Prevention & Research Unit Clinic & Laboratory of Pathophysiology, National and Kapodistrian University of Athens, Athens, Greece.
⁵ Rheumatology Unit, National Kapodistrian University of Athens, Athens, Greece.
⁶ Arthritis Research UK Centre for Epidemiology, Manchester University, Manchester, UK.
⁷ Department of Cardiology, Indraprastha APOLLO Hospitals, New Delhi, India.
⁸ Semmelweis University, Budapest, Hungary.
⁹ Division of Cardiovascular Medicine, University of Virginia, Charlottesville, VA, USA.
¹⁰ Department of Neurology, University Medical Centre Maribor, Maribor, Slovenia.
¹¹ The Hanse-Wissenschaftskolleg Institute for Advanced Study, Delmenhorst, Germany.
¹² Department of Pathology, A.O.U., di Cagliari -Polo di Monserrato s.s, Cagliari, Italy.
¹³ Aristoteleion University of Thessaloniki, Thessaloniki, Greece.
¹⁴ Cardiology Department, St. Helena Hospital, St. Helena, CA, USA.
¹⁵ Nephrology Department, Kaiser Permanente, Sacramento, CA, USA.
¹⁶ Department of Medicine, Division of Cardiology, Queen's University, Kingston, Canada.
¹⁷ University Hospital for Infectious Diseases, Zagreb, Croatia.
¹⁸ Department of Radiology, Massachusetts General Hospital, Boston, MA, USA.
¹⁹ Department of Radiology, Azienda Ospedaliero Universitaria (A.O.U.), Cagliari, Italy.
²⁰ Vascular Screening and Diagnostic Centre, University of Nicosia Medical School, Nicosia, Cyprus.
²¹ Stroke Diagnostic and Monitoring Division, AtheroPoint™, Roseville, CA, USA.
²² Department of Neurology & Stroke Program, University of Maryland School of Medicine, Baltimore, MD, USA.
²³ Department of Vascular Surgery, Central Clinic of Athens, N. Iraklio, Athens, Greece.
²⁴ Department of ECE, Idaho State University, Pocatello, ID, USA.

Abstract

The global mortality rate is known to be the highest due to cardiovascular disease (CVD). Thus, preventive, and early CVD risk identification in a non-invasive manner is vital as healthcare cost is increasing day by day. Conventional methods for risk prediction of CVD lack robustness due to the non-linear relationship between risk factors and cardiovascular events in multi-ethnic cohorts. Few recently proposed machine learning-based risk stratification reviews without deep learning (DL) integration. The proposed study focuses on CVD risk stratification by the use of techniques mainly solo deep learning (SDL) and hybrid deep learning (HDL). Using a PRISMA model, 286 DL-based CVD studies were selected and analyzed. The databases included were Science Direct, IEEE Xplore, PubMed, and Google Scholar. This review is focused on different SDL and HDL architectures, their characteristics, applications, scientific and clinical validation, along with plaque tissue characterization for CVD/stroke risk stratification. Since signal processing methods are also crucial, the study further briefly presented Electrocardiogram (ECG)-based solutions. Finally, the study presented the risk due to bias in AI systems. The risk of bias tools used were (I) ranking method (RBS), (II) region-based map (RBM), (III) radial bias area (RBA), (IV) prediction model risk of bias assessment tool (PROBAST), and (V) risk of bias in non-randomized studies-of interventions (ROBINS-I). The surrogate carotid ultrasound image was mostly used in the UNet-based DL framework for arterial wall segmentation. Ground truth (GT) selection is vital for reducing the risk of bias (RoB) for CVD risk stratification. It was observed that the convolutional neural network (CNN) algorithms were widely used since the feature extraction process was automated. The ensemble-based DL techniques for risk stratification in CVD are likely to supersede the SDL and HDL paradigms. Due to the reliability, high accuracy, and faster execution on dedicated hardware, these DL methods for CVD risk assessment are powerful and promising. The risk of bias in DL methods can be best reduced by considering multicentre data collection and clinical evaluation.

Keywords: Cardiovascular disease; bias; deep learning; risk stratification.

Publication types

Review