Application of Machine Learning Methods for Evaluating Systemic Vascular Resistance Based on Non-Invasive Hemodynamic Parameters
Keywords:
systemic vascular resistance, hemodynamics, non-invasive parameters, machine learning, classificationAbstract
The article presents the results of a study aimed at applying machine learning methods for the non-invasive assessment of systemic vascular resistance (SVR), which is an important integral indicator of peripheral circulation and is widely used in clinical practice for the diagnosis of cardiovascular pathologies. Hemodynamic signals, in particular the pulse wave and related physiological parameters, are characterized by a combination of pronounced rhythmicity and stochastic variations caused by regulatory mechanisms of the cardiovascular system and the influence of external factors. The relevance of this study is due to the fact that traditional methods for determining SVR, such as linear deterministic models, systems of differential equations, spectral and wavelet analysis, are based on invasive procedures related to cardiac output and mean arterial pressure. These methods require specialized equipment, highly qualified personnel, and are associated with risks for patients, which limits their application in routine clinical practice and screening studies and increases the need for safe, accessible, and automated assessment methods.
In this work, a mathematical formalization of hemodynamic signals based on cyclic random processes is proposed, which serves as a theoretical basis for the application of machine learning methods and allows simultaneous description of periodic components of the cardiac cycle and random signal fluctuations. This approach is based on the use of non-invasive hemodynamic parameters, including heart rate, arterial blood pressure, morphological characteristics of the pulse wave, and heart rate variability indices. To improve model quality, data preprocessing was performed using normalization, multicollinearity analysis (VIF), dimensionality reduction by principal component analysis (PCA), and heteroscedasticity testing. Modern machine learning algorithms were applied to build the models, including logistic regression, the k-nearest neighbors method, support vector machines, and random forest. It is shown that the use of cyclic random processes provides a basis for the formation of more informative and physiologically meaningful features suitable for classification and predictive modeling.
A generalized block diagram of hemodynamic signal modeling was developed, covering the stages of preprocessing, mathematical modeling, informative feature extraction, and classification or prediction of hemodynamic states. The obtained results confirm the feasibility of using cyclic random processes as a fundamental tool for constructing hybrid analysis systems that combine mathematical modeling and artificial intelligence methods and can be applied in modern biomedical diagnostic and clinical decision support systems.
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