A compact highly efficient and low hemolytic centrifugal blood pump with a magnetically levitated impeller.

A magnetically levitated (maglev) centrifugal blood pump (CBP), intended for use as a ventricular assist device, needs to be highly durable and reliable for long-term use without any mechanical failure. Furthermore, maglev CBPs should be small enough to be implanted into patients of various size and weight. We have developed a compact maglev CBP employing a two-degree-of-freedom controlled magnetic bearing, with a magnetically suspended impeller directly driven by an internal brushless direct current (DC) motor. The magnetic bearing actively controls the radial motion of the impeller and passively supports axial and angular motions using a permanent magnet embedded in the impeller. The overall dimensions of the maglev CBP are 65 mm in diameter and 40 mm in height. The total power consumption and pump efficiency for pumping 6 L/min against a head pressure of 105 mm Hg were 6.5 W and 21%, respectively. To evaluate the characteristics of the maglev CBP when subjected to a disturbance, excitation of the base, simulating the movement of the patient in various directions, and the sudden interception of the outlet tube connected with the pump in a mock circulatory loop, simulating an unexpected kink and emergent clamp during a heart surgery, were tested by monitoring the five-degree-of-freedom motion of the impeller. Furthermore, the hemolytic characteristics of the maglev CBP were compared with those of the Medtronic Biomedicus BPX-80, which demonstrated the superiority of the maglev CBP.

[1]  Setsuo Takatani,et al.  Quantification of the secondary flow in a radial coupled centrifugal blood pump based on particle tracking velocimetry. , 2004, Artificial organs.

[2]  S Westaby,et al.  Reliable long-term non-pulsatile circulatory support without anticoagulation. , 2001, European journal of cardio-thoracic surgery : official journal of the European Association for Cardio-thoracic Surgery.

[3]  Natale Barletta,et al.  Principle and Application of a Bearingless Slice Motor , 1997 .

[4]  K. Halbach Design of permanent multipole magnets with oriented rare earth cobalt material , 1980 .

[5]  T. Masuzawa,et al.  Magnetically suspended rotary blood pump with radial type combined motor-bearing. , 2000, Artificial organs.

[6]  Toru Masuzawa,et al.  Magnetically suspended centrifugal blood pump with a self bearing motor. , 2001 .

[7]  Tadahiko Shinshi,et al.  Magnetically Suspended Centrifugal Blood Pump With a Radial Magnetic Driver , 2005, ASAIO journal.

[8]  Yuji Ishino,et al.  Development of a three-axis active vibration isolation system using zero-power magnetic suspension , 2003, 42nd IEEE International Conference on Decision and Control (IEEE Cat. No.03CH37475).

[9]  Nong Zhang,et al.  Experimental determination of dynamic characteristics of the VentrAssist implantable rotary blood pump. , 2004, Artificial organs.

[10]  S. Takatani,et al.  A New Design for a Compact Centrifugal Blood Pump with a Magnetically Levitated Rotor , 2004, ASAIO journal.

[11]  K. Litwak,et al.  HeartMate III: Pump Design for a Centrifugal LVAD with a Magnetically Levitated Rotor , 2001, ASAIO journal.

[12]  Y Nosé,et al.  The need for standardizing the index of hemolysis. , 1994, Artificial organs.

[13]  G Bearnson,et al.  Performance of a continuous flow ventricular assist device: magnetic bearing design, construction, and testing. , 1998, Artificial organs.

[14]  S Takatani,et al.  Development of a compact, sealless, tripod supported, magnetically driven centrifugal blood pump. , 2000, Artificial organs.

[15]  Y Nosé,et al.  Hydraulic assessment of the floating impeller phenomena in a centrifugal pump. , 1997, Artificial organs.