A Multiscale Model of the Cardiovascular System That Regulates Arterial Pressure Via closed Loop baroreflex Control of Chronotropism, Cell-level Contractility, and Vascular Tone

Overview

Journal Biomech Model Mechanobiol

Publisher Springer

Date 2022 Sep 15

PMID 36107358

Authors

Hossein Sharifi

Charles K Mann

Jonathan F Wenk

Kenneth S Campbell

Affiliations

Soon will be listed here.

Abstract

Multiscale models of the cardiovascular system can provide new insights into physiological and pathological processes. PyMyoVent is a computer model that bridges from molecular- to organ-level function and which simulates a left ventricle pumping blood through the systemic circulation. Initial work with PyMyoVent focused on the end-systolic pressure volume relationship and ranked potential therapeutic strategies by their impact on contractility. This manuscript extends the PyMyoVent framework by adding closed-loop feedback control of arterial pressure. The control algorithm mimics important features of the physiological baroreflex and was developed as part of a long-term program that focuses on growth and biological remodeling. Inspired by the underlying biology, the reflex algorithm uses an afferent signal derived from arterial pressure to drive a kinetic model that mimics the net result of neural processing in the medulla and cell-level responses to autonomic drive. The kinetic model outputs control signals that are constrained between limits that represent maximum parasympathetic and maximum sympathetic drive and which modulate heart rate, intracellular Ca dynamics, the molecular-level function of both the thick and the thin myofilaments, and vascular tone. Simulations show that the algorithm can regulate mean arterial pressure at user-defined setpoints as well as maintaining arterial pressure when challenged by changes in blood volume and/or valve resistance. The reflex also regulates arterial pressure when cell-level contractility is modulated to mimic the idealized impact of myotropes. These capabilities will be important for future work that uses computer modeling to investigate clinical conditions and treatments.

Citing Articles

Multiscale Finite Element Modeling of Left Ventricular Growth in Simulations of Valve Disease.

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Advancing clinical translation of cardiac biomechanics models: a comprehensive review, applications and future pathways.

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