Speed Modulation of the Continuous-Flow Total Artificial Heart to Simulate a Physiologic Arterial Pressure Waveform

This study demonstrated the concept of using speed modulation in a continuous-flow total artificial heart (CFTAH) to shape arterial pressure waveforms and to adjust pressure pulsatility. A programmable function generator was used to determine the optimum pulsatile speed profile. Three speed profiles [sinusoidal, rectangular, and optimized (a profile optimized for generation of a physiologic arterial pressure waveform)] were evaluated using the CFTAH mock circulatory loop. Hemodynamic parameters were recorded at average pump speeds of 2,700 rpm and a modulation cycle of 60 beats per minute. The effects of varying physiologically relevant vascular resistance and lumped compliance on the hemodynamics were assessed. The feasibility of using speed modulation to manipulate systemic arterial pressure waveforms, including a physiologic pressure waveform, was demonstrated in vitro. The additional pump power consumption needed to generate a physiologic pulsatile pressure was 16.2% of the power consumption in nonpulsatile continuous-flow mode. The induced pressure waveforms and pulse pressure were shown to be very responsive to changes in both systemic vascular resistance and arterial compliance. This system also allowed pulsatile pulmonary arterial waveform. Speed modulation in the CFTAH could enable physicians to obtain desired pressure waveforms by simple manual adjustment of speed control input waveforms.

[1]  Ernst Wolner,et al.  Renal function after implantation of continuous versus pulsatile flow left ventricular assist devices. , 2008, The Journal of heart and lung transplantation : the official publication of the International Society for Heart Transplantation.

[2]  Kiyotaka Fukamachi,et al.  In vivo acute performance of the Cleveland Clinic self-regulating, continuous-flow total artificial heart. , 2010, The Journal of heart and lung transplantation : the official publication of the International Society for Heart Transplantation.

[3]  H. Harasaki,et al.  Chronic nonpulsatile blood flow. I. Cerebral autoregulation in chronic nonpulsatile biventricular bypass: carotid blood flow response to hypercapnia. , 1994, The Journal of thoracic and cardiovascular surgery.

[4]  Jg Copeland,et al.  CardioWest Total Artificial Heart Investigators. Cardiac replacement with a total artificial heart as a bridge to transplantation , 2004 .

[5]  O H Frazier,et al.  Surgery for Acquired Cardiovascular Disease Initial experience with the AbioCor Implantable Replacement Heart System , 2004 .

[6]  Kiyotaka Fukamachi,et al.  An innovative, sensorless, pulsatile, continuous-flow total artificial heart: device design and initial in vitro study. , 2010, The Journal of heart and lung transplantation : the official publication of the International Society for Heart Transplantation.

[7]  A. Undar,et al.  Comparison of two types of neonatal extracorporeal life support systems with pulsatile and nonpulsatile flow. , 2009, Artificial organs.

[8]  Marvin J Slepian,et al.  Cardiac replacement with a total artificial heart as a bridge to transplantation. , 2004, The New England journal of medicine.

[9]  S. Schenk,et al.  Preclinical readiness testing of the Arrow International CorAide left ventricular assist system. , 2004, The Annals of thoracic surgery.

[10]  William A. Smith,et al.  Reduced pulsatility induces periarteritis in kidney: role of the local renin-angiotensin system. , 2008, The Journal of thoracic and cardiovascular surgery.

[11]  A. Undar,et al.  Comparison of pumps and oxygenators with pulsatile and nonpulsatile modes in an infant cardiopulmonary bypass model. , 2009, Artificial organs.