Apparatus and methods are described including a blood pump that includes an impeller that has proximal and distal bushings, and is configured to pump blood through a subject's body. A frame, which includes proximal and distal bearings, is disposed around the impeller. An axial shaft passes through the proximal and distal bearings of the frame and the proximal and distal bushings of the impeller. The axial shaft is coupled to at least one of the proximal and distal bushings of the impeller, such that the at least one bushing is held in an axially-fixed position with respect to the axial shaft, and is not held in an axially-fixed position with respect to the proximal and distal bearings. Other applications are also described.

Apparatus and methods are described including a blood pump that includes an impeller that has proximal and distal bushings, and is configured to pump blood through a subject's body. A frame, which includes proximal and distal bearings, is disposed around the impeller. An axial shaft passes through the proximal and distal bearings of the frame and the proximal and distal bushings of the impeller. The axial shaft is coupled to at least one of the proximal and distal bushings of the impeller, such that the at least one bushing is held in an axially-fixed position with respect to the axial shaft, and is not held in an axially-fixed position with respect to the proximal and distal bearings. Other applications are also described.

A blood pumping device having at least a first pump and a second pump, and a first and second pump actuating means for inducing a blood flow in a body's circulatory system is disclosed. Each pump comprises one upper chamber having an inlet channel and one lower chamber having an outlet channel. The upper and lower chambers are separated by a movable valve plane provided with a valve. The pump actuating means are configured to apply a movement to said valve plane in an upward and downward direction between said upper and lower chambers in response to control signals from a control unit, such that when said valve plane moves in an upward direction the valve provided in the valve plane is in an open position allowing a flow of blood from the upper chamber to the lower chamber, and when the valve plane moves in a downward direction the valve is in the closed position and blood is ejected from the lower chamber through the outlet channel. The bottom part of the bag portion has a shape that makes a turn of between 110° to 150° to cause blood entering the lower chamber to hit the stopping surface and come to a sudden stop, wherein the turn causes the flow of blood along the inner surface of the bag portion to abruptly change; and directs blood at the stopping surface to continue flowing along the outlet channel.

The catheter device comprises a motor at the proximal end of the catheter device and a drive shaft, extending from the proximal end section to the distal end section of the catheter device, for driving a rotating element located at the distal end of the catheter device. The catheter device also comprises a hose-like catheter body which encompasses the drive shaft and extends from the proximal end section to the distal end section. At the proximal end of the catheter device, the drive shaft is connected to a motor by a clutch. The clutch is a magnetic clutch with a proximal and a distal magnet unit. The proximal magnet unit is connected to the motor and the distal magnet unit to the drive shaft. The distal magnet unit is mounted fluid-tight in a clutch housing. The proximal end of the catheter body makes a fluid-tight connection with the clutch housing.

An implant system for restoring and improving physiological intracardiac flow in a human heart is provided including a force transducting, structurally stabilizing, and functionally assisting ventricular inflatable cardiac implant within a human heart for restoring and improving physiologic intracardiac flow, restoring the ventricular vortex, preventing atrioventricular pressure gradient loss, mitigating valvular regurgitation, and utilizing native energy and force, via force transduction, to restore geometric elliptical proportion and function to the atria, the ventricles and ventricular walls, and the valvular apparatus itself.

An implant system for restoring and improving physiological intracardiac flow in a human heart is provided including a force transducting, structurally stabilizing, and functionally assisting ventricular inflatable cardiac implant within a human heart for restoring and improving physiologic intracardiac flow, restoring the ventricular vortex, preventing atrioventricular pressure gradient loss, mitigating valvular regurgitation, and utilizing native energy and force, via force transduction, to restore geometric elliptical proportion and function to the atria, the ventricles and ventricular walls, and the valvular apparatus itself.

Disclosed is an assembly for fitting/removing a heart pump in a sleeve secured in an opening in a ventricular wall, the assembly including a guide element with a distal end, a proximal end, and a lumen extending between, and opening at, the distal and proximal ends, the heart pump having a pump body. With this pump body including an assembly element, the assembly includes a gripping unit which can slide in the lumen, the gripping unit having at its free end an assembly part which is complementary with the assembly element, which part is configured to cooperate with the assembly element, and to join this free end to the pump body, in order to permit the gripping and displacement of the heart pump.

Disclosed is an assembly for fitting/removing a heart pump in a sleeve secured in an opening in a ventricular wall, the assembly including a guide element with a distal end, a proximal end, and a lumen extending between, and opening at, the distal and proximal ends, the heart pump having a pump body. With this pump body including an assembly element, the assembly includes a gripping unit which can slide in the lumen, the gripping unit having at its free end an assembly part which is complementary with the assembly element, which part is configured to cooperate with the assembly element, and to join this free end to the pump body, in order to permit the gripping and displacement of the heart pump.

Mechanical circulatory supports configured to operate in series with the native heart are disclosed. In an embodiment, a centrifugal pump is used. In an embodiment, inlet and outlet ports are connected into the aorta and blood flow is diverted through a lumen and a centrifugal pump between the inlet and outlet ports. The supports may create a pressure rise between about 40-80 mmHg, and maintain a flow rate of about 5 L/min. The support may be configured to be inserted in a collinear manner with the descending aorta. The support may be optimized to replicate naturally occurring vortex formation within the aorta. Diffusers of different dimensions and configurations, such as helical configuration, and/or the orientation of installation may be used to optimize vortex formation. The support may use an impeller which is electromagnetically suspended, stabilized, and rotated to pump blood.

Apparatus and methods are described including a blood pump that includes an impeller, and a motor configured to drive the impeller to pump blood by rotating the impeller. The impeller is configured to undergo axial motion, in response to changes in a pressure against which the impeller is pumping. A sensor detects the axial motion of the impeller, and generates a sensor signal in response thereto. A computer processor receives the sensor signal and generates an output in response thereto. Other applications are also described.