Enhancing cardiovascular risk prediction: the role of wall viscoelasticity in machine learning models.

Abstract

This study aims to evaluate the significance of wall viscoelasticity in enhancing cardiovascular disease (CVD) risk prediction. We collected data on ten patient features, categorized into demographics (age, gender, blood pressure, smoking history), blood lab data (HDL, LDL, blood glucose levels), and wall mechanics (Peterson's modulus, stiffness parameter, energy dissipation ratio). Outcome variables were classified as low or high CVD risk based on total plaque area computed from carotid ultrasound images. We employed eight machine learning classifiers and conducted a comparative analysis of feature importance. Incorporating mechanical attributes significantly improved predictive accuracies for most machine learning models. The Random Forest Bagging Method (RFBM) showed the best performance, achieving an accuracy of 93.0% and an AUC of 0.98 with all 10 features. Including either elastic or viscous features alongside the conventional features enhanced prediction for most models. For the tree-based bagging models (DTBM and RFBM), including the viscous feature (energy dissipation ratio) alongside conventional features resulted in greater accuracy improvements compared to the elastic features. This study underscores the significant impact of integrating wall viscosity on CVD prediction and highlights the potential for combining both elastic and viscous wall characteristics to achieve more accurate risk assessment.