Effects of Coronary Stenosis on Coronary Vascular Impedance

Abstract

Introduction: The impedance analysis for circulation system is a powerful tool to comprehensively measure the afterload of the entire circulation system. The spectrum of vascular mechanical parameters derived from the impedance analysis can reveal the compliance and resistance changes in proximal and distal vessels, as well as the wave reflections. However, the similar investigation in the opposition of the coronary circulation is limited, and it is unknown how coronary stenosis affects the vascular impedance of the coronary circulation. In this study, we aimed to quantify and compare the changes in the vascular impedance of coronary circulation from the dynamic pressure and flow relations in healthy and patients with stenosis. Method: The pressure and flow rate waveforms from the main coronary artery were obtained from a lumped-parameter computational model that coupled the systemic circulation with the coronary perfusion within a closed system. Both healthy and diseased (coronary stenosis) pressure-flow relations were examined. A Fourier transform was performed to analyze the pressure and flow data, and the resistance (Z0), characteristic impedance (ZC), wave reflections (RW), total arterial compliance (C), and other hemodynamic parameters were derived. Results: Compared to the healthy subject, the diseased subject presented an increased resistance (Z0 was elevated from 0.44 mmHg ▪ min/ml to 0.59 mmHg ▪ min/ml), increased characteristic impedance (ZC was elevated from 0.07 mmHg ▪ min/ml to 0.14 mmHg ▪ min/ml), and reduced wave reflection (RW was decreased from 0.72 to 0.6). These changes indicate elevated distal arteries and arterioles narrowing and proximal artery stiffening in the entire coronary vasculature. Moreover, the coronary flow and the total arterial compliance (stroke volume divided by pulse pressure) were reduced with the disease progression. These data suggest a reduced coronary perfusion and stiffening of the artery in the coronary circulation. Discussion: The impedance analysis has been widely used for systemic and pulmonary circulations previously to quantify the total afterload of the left and right ventricles, respectively. The distribution of the impedance in different frequencies reflects the anatomical and mechanical properties of the vasculature in the circulation system. This study originally found that the coronary artery impedance is altered by coronary stenosis. The key characteristics include the narrowing of distal coronary arteries and stiffening of proximal coronary arteries. However, since both proximal and distal arteries are altered, the wave reflection was reduced, and this may explain a reduced pulse pressure observed in the diseased subject. The reduction in overall coronary perfusion indicates an impaired blood supply to the ventricle and may be responsible for the dysfunction of the heart. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.