Pusher-plate type TAH system operated in the left and right free-running variable rate mode.

A TAH system utilizing two pusher-plate type pumps was developed and tested in two calves for 45 and 108 days with excellent results. A Hall effect sensor was utilized to operate each pump with a full stroke at variable rates (VR); each pump was then allowed to run independently at different rates depending on its own preload and afterload. With this system, the animals' atrial pressures were kept to near-normal levels (less than 10 mmHg). However, significant differences in the left and right pump flows were observed (left higher than right) and they ranged from 5 to 30% of the left flow with a mean of 15%. These flow differences may be due to the bronchial circulation and related shunts. Right pump flows averaged 70 to 95 ml/min-kg and circulating blood volume ranged from 67 to 95 ml/kg. When various control modes including fixed rate and master-slave type simultaneously or alternatively ejecting VR modes were applied in the same animals and both pump flows were forced to be equal, unphysiological atrial pressures resulted. This result indicates that perhaps left and right flow differences are necessary physiological conditions to regulate the atrial pressures within normal ranges. Metabolic data also indicated that under simultaneously and alternately ejecting modes, A-V O2 content differences were increased due to decreased right pump flow as compared with those of the free-running VR mode. The left and right free-running VR mode of operation imposed minimal constraints on the animals' cardiovascular system and therefore yielded excellent hemodynamic and metabolic results.

[1]  H Harasaki,et al.  The dura mater valve: in vitro characteristics and pathological changes after implantation in calves. , 2008, Artificial organs.

[2]  I. Koshino,et al.  Survival for 145 days with a total artificial heart. , 1977, Journal of Thoracic and Cardiovascular Surgery.

[3]  R Kiraly,et al.  Totally implantable left ventricular assist device for human application. , 1980, Transactions - American Society for Artificial Internal Organs.

[4]  H Harasaki,et al.  Chronic nonpulsatile blood flow in an alive, awake animal 34-day survival. , 1980, Transactions - American Society for Artificial Internal Organs.

[5]  R Kiraly,et al.  Comparative evaluation of nonpulsatile and pulsatile cardiac prostheses. , 1980, Transactions - American Society for Artificial Internal Organs.

[6]  T. Akutsu,et al.  A microcomputer based control system for the artificial heart. , 1979, Transactions - American Society for Artificial Internal Organs.

[7]  H. Harasaki,et al.  Transient and permanent problems associated with the total artificial heart implantation. , 1979, Transactions - American Society for Artificial Internal Organs.

[8]  F. Iwaya,et al.  Comparison of pneumatic and electrically powered total artificial hearts in vivo. , 1978, Transactions - American Society for Artificial Internal Organs.

[9]  E S Bücherl,et al.  The relationship of cardiac output and venous pressure in long surviving calves with total artificial heart. , 1978, Transactions - American Society for Artificial Internal Organs.

[10]  W S Pierce,et al.  Automatic control of the artificial heart. , 1976, Transactions - American Society for Artificial Internal Organs.

[11]  M. Klain,et al.  Can we achieve over 100 hours' survival with a total mechanical heart? , 1971, Transactions - American Society for Artificial Internal Organs.

[12]  T. Akutsu,et al.  Total artificial hearts with built-in valves. , 1970, Transactions - American Society for Artificial Internal Organs.

[13]  W J Kolff,et al.  Total replacement artificial heart and driving system with inherent regulation of cardiac output. , 1969, Transactions - American Society for Artificial Internal Organs.

[14]  W J Kolff,et al.  Control systems for artificial hearts. , 1968, Transactions - American Society for Artificial Internal Organs.