The effect of power-based control on the haemodynamics and valve function of the biventricular assist circulation system.

Abstract

Biventricular assist devices (BiVAD) are capable of providing mechanical support to the left and right ventricles to improve blood supply in heart failure, thereby maintaining patients' lives and improving their quality of life. But there is evidence that the incidence of aortic valve incompetence and other valvular pathologies is related to BiVAD support. Such as constant speed (CS) control may cause the valve to close completely and lose its normal valve function. The valve function is related to the percentage of valve opening which is approximately 30% of the cardiac cycle. This study developed a power-based control model for BiVAD that could regulate motors' speed by altering the power to satisfy objectives of keeping valve function and restoring physiologic perfusion. The effects of the power-based controller on the hemodynamics and valve function were investigated by simulating BiVAD under constant power and variable power controls. Different heart failure and activity levels were also mimicked under variable power control to obtain the BiVAD's critical parameters and the assist ratios. The results show that the power-based control can help the BiVAD to assist a patient with heart failure, and the power settings should comprehensively consider objectives of valve function and physiologic perfusion.