Incorporating Autoregulatory Mechanisms of the Cardiovascular System in Three-Dimensional Finite Element Models of Arterial Blood Flow

• Published in: Annals of biomedical engineering Vol. 38; no. 7; pp. 2314 - 2330
• Main Authors: Kim, H. J, Jansen, K. E, Taylor, C. A
• Format: Journal Article
• Language: English
• Published: Boston Boston : Springer US 01.07.2010; Springer US; Springer Nature B.V
• Subjects: aorta; Aorta - physiology; Arteries - physiology; Arteries - physiopathology; autoregulation; Biochemistry; Biological and Medical Physics; Biomedical and Life Sciences; Biomedical Engineering and Bioengineering; Biomedicine; Biophysics; blood flow; Cardiovascular System; Classical Mechanics; Coronary; Coronary Vessels; exercise; Finite elements; Hemodynamics - physiology; Homeostasis - physiology; Humans; Mathematical models; Pulmonary Circulation; Autoregulation; Finite elements; Coronary; Aorta; Exercise; Blood flow
• ISSN: 0090-6964; 1573-9686
• DOI: 10.1007/s10439-010-9992-7

The cardiovascular system is a closed-loop system in which billions of vessels interact with each other, and it enables the control of the systemic arterial pressure and varying organ flow through autoregulatory mechanisms. In this study, we describe the development of mathematical models of autoregulatory mechanisms for systemic arterial pressure and coronary flow and discuss the connection of these models to a hybrid numerical/analytic closed-loop model of the cardiovascular system. The closed-loop model consists of two lumped parameter heart models representing the left and right sides of the heart, a three-dimensional finite element model of the aorta with coronary arteries, three-element Windkessel models and lumped parameter coronary vascular models that represent the systemic circulation, and a three-element Windkessel model to approximate the pulmonary circulation. Using the connection between the systemic arterial pressure and coronary flow regulation systems, and the hybrid closed-loop model, we studied how the heart, coronary vascular beds, and arterial system respond to physiologic changes during light exercise and showed that these models can realistically simulate temporal behaviors of the heart, coronary vascular beds, and arterial system during exercise of healthy subjects. These models can be used to study temporal changes occurring in the heart, coronary vascular beds, and arterial system during cardiovascular intervention or changes in physiological states.