Flow characteristics and required control algorithm of an implantable centrifugal left ventricular assist device

SummaryAs the clinical application of LVADs has increased, attempts have been made to develop smaller, less expensive, more durable and efficient implantable devices using rotary blood pumps. Since chronic circulatory support with implantable continuous-flow LVADs will be established in the near future, we need to determine the flow characteristics through an implantable continuous-flow LVAD. This study describes the flow characteristics through an implantable centrifugal blood pump as a left ventricular assist device (LVAD) to obtain a simple non-invasive algorithm to control its assist flow rate adequately. A prototype of the completely seal-less and pivot bearing-supported centrifugal blood pump was implanted into two calves, bypassing from the left ventricle to the descending aorta. Device motor speed, voltage, current, flow rate, and aortic blood pressure were monitored continuously. The flow patterns revealed forward flow in ventricular systole and backward flow in diastole. As the pump speed increased, an end-diastolic notch became evident in the flow profile. Although the flow rate (Q [1/min]) and rotational speed (R [rpm]) had a linear correlation (Q=0.0042R−5.159;r=0.96), this linearity was altered after the end-diastolic notch was evident. The end-diastolic notch is considered to be a sign of the sucking phenomenon of the centrifugal pump. Also, although the consumed current (I [A]) and flow rate had a linear correlation (I=0.212Q+0.29;r=0.97), this linearity also changed after the end-diastolic notch was evident. Based upon the above findings, we propose a simple algorithm to maintain submaximal flow without inducing sucking. To maintain the submaximal flow rate without measuring flow rate, the sucking point is determined by monitoring consumed current according to gradual increases in voltage.

[1]  G Damm,et al.  Baylor Gyro Pump: a completely seal-less centrifugal pump aiming for long-term circulatory support. , 2008, Artificial organs.

[2]  T. Akamatsu,et al.  Development of a Magnetically Suspended Centrifugal Pump as a Cardiac Assist Device for Long-Term Application , 1996, ASAIO journal.

[3]  G. Noon,et al.  Ex vivo evaluation of the NASA/DeBakey axial flow ventricular assist device. Results of a 2 week screening test. , 1996, ASAIO journal.

[4]  George Damm,et al.  Development of a Pivot Bearing Supported Sealless Centrifugal Pump for Ventricular Assist. , 1996, Artificial organs.

[5]  J R Boston,et al.  Controller for an Axial Flow Blood Pump. , 1996, Artificial organs.

[6]  William A Smith,et al.  The Cleveland Clinic Rotodynamic Pump Program. , 1996, Artificial organs.

[7]  U Losert,et al.  An implantable seal-less centrifugal pump with integrated double-disk motor. , 1995, Artificial organs.

[8]  Y. Nosé FDA approval of clinical studies on left ventricular assist system for its therapeutic application. , 1996, Artificial organs.

[9]  O. Frazier,et al.  Improved left ventricular function after chronic left ventricular unloading. , 1996, The Annals of thoracic surgery.

[10]  G Rosenberg,et al.  Noninvasive control of cardiac output for alternately ejecting dual-pusherplate pumps. , 2008, Artificial organs.

[11]  P. Allaire,et al.  Development of a Prototype Magnetically Suspended Rotor Ventricular Assist Device , 1996, ASAIO journal.

[12]  U Losert,et al.  Noninvasive monitoring of rotary blood pumps: necessity, possibilities, and limitations. , 2008, Artificial organs.

[13]  J. Antaki,et al.  Long-term animal survival with an implantable axial flow pump as a left ventricular assist device. , 2008, Artificial organs.

[14]  T Nakatani,et al.  Long-term circulatory support to promote recovery from profound heart failure. , 1995, ASAIO journal.

[15]  Hisateru Takano,et al.  Development of a Centrifugal Pump with Improved Antithrombogenicity and Hemolytic Property for Chronic Circulatory Support. , 1996, Artificial organs.

[16]  M. Oz,et al.  Miniature axial flow pump for ventricular assistance in children and small adults. , 1996, The Journal of thoracic and cardiovascular surgery.

[17]  Y Nosé,et al.  Development and evaluation of antithrombogenic centrifugal pump: the Baylor C-Gyro Pump Eccentric Inlet Port Model. , 1994, Artificial organs.

[18]  G Damm,et al.  An ultimate, compact, seal-less centrifugal ventricular assist device: Baylor C-Gyro pump. , 1994, Artificial organs.

[19]  B. Griffith,et al.  Transplant candidate's clinical status rather than right ventricular function defines need for univentricular versus biventricular support. , 1996, The Journal of thoracic and cardiovascular surgery.

[20]  P. McCarthy,et al.  HeartMate implantable left ventricular assist device: bridge to transplantation and future applications. , 1995, The Annals of thoracic surgery.