Starling-like flow control of a left ventricular assist device: in vitro validation.

The application of rotary left ventricular (LV) assist devices (LVADs) is expanding from bridge to transplant, to destination and bridge to recovery therapy. Conventional constant speed LVAD controllers do not regulate flow according to preload, and can cause over/underpumping, leading to harmful ventricular suction or pulmonary edema, respectively. We implemented a novel adaptive controller which maintains a linear relationship between mean flow and flow pulsatility to imitate native Starling-like flow regulation which requires only the measurement of VAD flow. In vitro controller evaluation was conducted and the flow sensitivity was compared during simulations of postural change, pulmonary hypertension, and the transition from sleep to wake. The Starling-like controller's flow sensitivity to preload was measured as 0.39 L/min/mm Hg, 10 times greater than constant speed control (0.04 L/min/mm Hg). Constant speed control induced LV suction after sudden simulated pulmonary hypertension, whereas Starling-like control reduced mean flow from 4.14 to 3.58 L/min, maintaining safe support. From simulated sleep to wake, Starling-like control increased flow 2.93 to 4.11 L/min as a response to the increased residual LV pulsatility. The proposed controller has the potential to better match device outflow to patient demand in comparison with conventional constant speed control.

[1]  M. Loebe,et al.  Current status of the MicroMed DeBakey Noon Ventricular Assist Device. , 2010, Texas Heart Institute journal.

[2]  Nicholas Richard Gaddum,et al.  A passively controlled biventricular support device. , 2010, Artificial organs.

[3]  A. Guyton,et al.  Textbook of Medical Physiology , 1961 .

[4]  H. Zimmer Who discovered the Frank-Starling mechanism? , 2002, News in physiological sciences : an international journal of physiology produced jointly by the International Union of Physiological Sciences and the American Physiological Society.

[5]  BRYAN FRITZ,et al.  Development of an Inlet Pressure Sensor for Control in a Left Ventricular Assist Device , 2010, ASAIO journal.

[6]  R. Hetzer,et al.  Alternative technique for implantation of biventricular support with HeartWare implantable continuous flow pump. , 2011, ASAIO journal.

[7]  Nigel H. Lovell,et al.  Automated Non-invasive Detection of Pumping States in an Implantable Rotary Blood Pump , 2006, 2006 International Conference of the IEEE Engineering in Medicine and Biology Society.

[8]  Einly Lim,et al.  Theoretical foundations of a Starling-like controller for rotary blood pumps. , 2012, Artificial organs.

[9]  H. N. Michael Centrifugal and axial flow pumps: by A. J. Stepanoff. 428 pages, illustrations, diagrams, 15 × 24 cm. New York, John Wiley & Sons, Inc., 1948. Price, $7.50 , 1948 .

[10]  E. Birks Left ventricular assist devices , 2009, Heart.

[11]  F. Colacino,et al.  Left ventricle afterload impedance control by an axial flow ventricular assist device: a potential tool for ventricular recovery. , 2010, Artificial organs.

[12]  P. Ayre,et al.  Paradoxical effects of viscosity on the VentrAssist rotary blood pump. , 2000, Artificial organs.

[13]  D. Mason,et al.  Response of rotary blood pumps to changes in preload and afterload at a fixed speed setting are unphysiological when compared with the natural heart. , 2011, Artificial organs.

[14]  Ulrich Steinseifer,et al.  A compact mock circulation loop for the in vitro testing of cardiovascular devices. , 2010, Artificial organs.

[15]  N H Lovell,et al.  Non-invasive flow estimation in an implantable rotary blood pump: a study considering non-pulsatile and pulsatile flows. , 2003, Physiological measurement.

[16]  Gang Tao,et al.  A bridge from short-term to long-term left ventricular assist device--experimental verification of a physiological controller. , 2004, Artificial organs.

[17]  Magdi H. Yacoub,et al.  Reversal of Severe Heart Failure With a Continuous-Flow Left Ventricular Assist Device and Pharmacological Therapy: A Prospective Study , 2011, Circulation.

[18]  Nicholas Richard Gaddum,et al.  Optimizing the response from a passively controlled biventricular assist device. , 2010, Artificial organs.

[19]  M B Visscher,et al.  The regulation of the energy output of the heart , 1927, The Journal of physiology.

[20]  John F Fraser,et al.  Comparison of preload-sensitive pressure and flow controller strategies for a dual device biventricular support system. , 2012, Artificial organs.

[21]  Daniel Timms,et al.  Passive control of a biventricular assist device with compliant inflow cannulae. , 2012, Artificial organs.

[22]  J. Fleg,et al.  Exercise cardiac output is maintained with advancing age in healthy human subjects: cardiac dilatation and increased stroke volume compensate for a diminished heart rate. , 1984, Circulation.

[23]  M A Griffin,et al.  Left ventricular assist devices. , 1998, RN.

[24]  A.J.Stepanoff Centrifugal and Axial Flow Pumps: Design and Application , 1957 .

[25]  Andrew P. Bradley,et al.  Evaluation of a morphological filter in mean cardiac output determination: application to left ventricular assist devices , 2013, Medical & Biological Engineering & Computing.

[26]  N H Lovell,et al.  Non-invasive estimation of pulsatile flow and differential pressure in an implantable rotary blood pump for heart failure patients , 2009, Physiological measurement.

[27]  John F. Fraser,et al.  Increasing the transmitted flow pulse in a rotary left ventricular assist device. , 2012, Artificial organs.

[28]  Mikhail Skliar,et al.  Physiological control of blood pumps using intrinsic pump parameters: a computer simulation study. , 2006, Artificial organs.

[29]  Jong-Chul Park,et al.  Enhanced chondrogenic responses of human articular chondrocytes onto silk fibroin/wool keratose scaffolds treated with microwave-induced argon plasma. , 2010, Artificial organs.