This centrifugal blood pump apparatus includes an impeller (10) provided in a blood chamber (7), and a plurality of coils (20) provided in a motor chamber (8) for driving the impeller (10) to rotate with a dividing wall (6) interposed therebetween. A flexible substrate (23) in the shape of a strip is arranged to surround outer circumferences of the plurality of coils (20), and is connected to the plurality of coils (20) and a connector (24). A driving voltage (VU, VV, VW) is externally supplied to the plurality of coils (20) via the connector (24) and the flexible substrate (23). Thus, assembling workability, productivity and reliability are improved.

Integral artificial heart device capable of storing venous blood in dynamic atria, without interrupting the continuous return of the blood. The device comprises a right ventricle (A1) and left ventricle (A2) pulsing simultaneously, and the reactive right atrium (C1) and left atrium (not illustrated) thereof, immersed in a pneumatic spec (D) having a variable vacuum D, which is driven by a solenoid (35), acting sequentially, by repulsion, on the permanent magnet discs (20, 21) included in the elastic ventricular membranes (18, 19), which beat simultaneously in the ventricular spaces (A1) and (A2), and, in the opposite direction, in pneumatic space (D) which houses elastic tubes acting as atria. The device simultaneously ejects systolic volumes, and accepts the proportion of continuously returning venous blood to store in the atria, during the systole, such that said continuous return is not interrupted by sequential systolic closure of the intake ports.

The invention relates to a controller unit (100) and method for controlling a cardiac prosthesis (200). The prosthesis comprising: at least one pump portion (202, 203, 602, 702); an inlet (210, 610, 710) connected to said at least one pump portion; an outlet (213, 613, 713) connected to said at least one pump portion; a pressure sensor (231; 232) configured to measure pressure of a fluid flowing from the inlet to the outlet; a pump actuator (221, 222) configured to induce the flow of the fluid flow. The controller unit further comprises a memory and a processing unit, wherein the controller unit is configured to: obtain a pressure value from the pressure sensor, obtain a desired value for the pressure of the fluid flowing into the pump, calculate an error signal equal to the difference of desired value for the pressure and the measured pressure, and control the output of the pump such that the measured pressure is near or equal to the desired pressure, by controlling a pump stroke rate and/or a pump stroke volume.

A heart pump including a housing defining a cavity including at least one inlet aligned with an axis of the cavity and at least one outlet provided in a circumferential outer wall of the cavity. An impeller is provided within the cavity, the impeller including a rotor and vanes mounted on the rotor for urging fluid from the inlet radially outwardly to the outlet. A drive is provided for rotating the impeller in the cavity, the drive including a plurality of circumferentially spaced permanent drive magnets mounted within and proximate a first face of the rotor, adjacent drive magnets having opposing polarities and a plurality of circumferentially spaced drive coils mounted within the housing proximate a first end of the cavity, each coil being wound on a respective drive stator pole of a drive stator and being substantially radially aligned with the drive magnets, the drive coils being configured to generate a drive magnetic field that cooperates with the drive magnets to thereby rotate the impeller. A magnetic bearing is also provided to thereby at least one of control an axial position of the impeller and at least partially restrain radial movement of the impeller.

A heart pump including a housing defining a cavity including at least one inlet aligned with an axis of the cavity and at least one outlet provided in a circumferential outer wall of the cavity. An impeller is provided within the cavity, the impeller including a rotor and vanes mounted on the rotor for urging fluid from the inlet radially outwardly to the outlet. A drive is provided for rotating the impeller in the cavity, the drive including a plurality of circumferentially spaced permanent drive magnets mounted within and proximate a first face of the rotor, adjacent drive magnets having opposing polarities and a plurality of circumferentially spaced drive coils mounted within the housing proximate a first end of the cavity, each coil being wound on a respective drive stator pole of a drive stator and being substantially radially aligned with the drive magnets, the drive coils being configured to generate a drive magnetic field that cooperates with the drive magnets to thereby rotate the impeller. A magnetic bearing is also provided to thereby at least one of control an axial position of the impeller and at least partially restrain radial movement of the impeller.

A device for controlling the functioning of a cardiac prosthesis, the device for controlling includes a control path, the control path having a control system designed and arranged to monitor and regulate the electrical supply of a cardiac prosthesis; a first insulating system designed and arranged to electrically insulate the cardiac prosthesis from the electrical supply; and a controller designed and arranged to monitor and regulate the electrical supply.

A system for cleaning an implanted blood pump, comprising: an inflow catheter having an expandable inflow member positioned about the periphery thereof; an inflow tube coupled with the inflow catheter; a valve assembly coupled to the inflow tube; an outflow tube coupled to the valve assembly; and an outflow catheter having an expandable outflow member positioned about the periphery thereof, the outflow catheter being coupled to the outflow tube. In use, the inflow tube and outflow tube extend through the skin of a human body, the inflow catheter and outflow catheter are positioned within the human body, and the valve assembly is positioned outside the human body.

A centrifugal pump includes a rotating shaft, a pump substrate, a housing and an impeller. The pump substrate has a driving unit configured to rotate the rotating shaft. The housing has an inlet and an outlet and forms a pump chamber with the pump substrate. A body fluid sucked from the inlet flows through the pump chamber. The impeller is housed in the pump chamber and is configured to use the rotating shaft as an axis. The pump substrate has a magnetism generating source. The rotating shaft protrudes into the pump chamber from the pump substrate, and is pivotally supported on the pump substrate. A magnetic fluid is disposed on at least one of spaces formed among the pump substrate, the rotating shaft, and the impeller.

A method is provided of controlling a pump including a electrical motor coupled to a rotor which carries first and second impellers at opposite ends thereof. The method includes: (a) driving the rotor using the motor, so as to circulate fluid from the first impeller through a first fluid circuit, the second impeller, a second fluid circuit, and back to the first impeller; (b) determining a resistance of the first fluid circuit, based on a first motor parameter which is a function of electrical power delivered to the motor; (c) determining a flow rate through the first fluid circuit based on a second motor parameter which is a function of electrical power delivered to the motor; and (d) varying at least one operational parameter of the pump so as to maintain a predetermined relationship between the flow rate and the resistance of the first fluid circuit.

Disclosed is an electromechanical device generating bilateral pressure impulses, wherein the alternative and specular movement of the homologous cursors (CV, CO), pacing one of the Cartesian axes, exclusively manages mobile cores (NEM) of electromagnets (EM) with planned solicitation, for supplying the necessary mechanical energy for the correct working of operating machines of different kinds, and in particular of a permanent artificial heart.