Table 3. ML classifiers used to evaluate risk assessment and make predictions.
| Authors | ML algorithms | Aim | Performance |
| Przewlocka-Kosmala, et al.[33] | Cluster analysis | To identify prognostic phenotypes among patients with heart failure and preserved ejection fraction | Lower left ventricle systolic reserve may have a prognostic role in heart failure and preserved ejection fraction |
| Kwon, et al.[34] | Deep neural network | To detect in-hospital cardiac arrest and death without attempted resuscitation | AUC: 0.85 |
| AUPRC: 0.044 | |||
| Daghistani, et al.[35] | Random forest | To predict in-hospital length of stay among cardiac patients | Random forest outperformed among the other models with |
| Artificial neural network | Sensitivity: 80% | ||
| Support vector machine | Accuracy: 80% | ||
| Bayesian network | AUC: 0.94 | ||
| Mortazavi, et al.[36] | Logistic regression | To predict 30-day all-cause of hospitalreadmission of patients with heart failure | Random forest outperformedclassical statistical methods |
| Poisson regression | |||
| Random forest | |||
| Boosting | |||
| Bhattacharya, et al.[37] | Logistic regression | To assess the risk of ventricular arrhythmia in hypertrophic cardiomyopathy | Sensitivity: 0.73 |
| Naıve bayes | Specificity: 0.76 | ||
| Decision tree | AUC: 0.83 | ||
| Random forest | |||
| Alaa, et al.[38] | Supprto vector machines | To evaluate cardiovascular risk in asymptomatic people | AUC: 0.724 |
| Random forest | |||
| Neural network | |||
| AdaBoost | |||
| Gradient boosting |
AUC: area under the curve; AUPRC: area under the precision recall curve; ML: machine learning.