Various aspects of the present disclosure are directed toward implantable medical devices, systems, and methods for cardiac assistance.

A system includes a dialyzer having a blood side and a dialysate side, a first extracorporeal circuit including one or more first fluid connectors for connecting the blood side of the dialyzer to the vascular system of a kidney patient, a second extracorporeal circuit including one or more second fluid connectors for connecting the dialysate side of the dialyzer to the vascular system of a healthy animal, a first pump in fluid communication with at least one of the first and second extracorporeal circuits, and a driver mechanically coupled to the first pump, where the driver is configured to drive the first pump using energy from an energy source.

Catheter blood pumps that include an expandable pump portion. The pump portions include a collapsible blood conduit that defines a blood lumen. The collapsible blood conduits include a collapsible scaffold adapted to provide radial support to the blood conduit. The pump portion also includes one or more impellers. The collapsible scaffold may include portions of differing radial stiffness based on location of the one or more impellers therein.

Catheter blood pumps that include an expandable pump portion. The pump portions include a collapsible blood conduit that defines a blood lumen. The collapsible blood conduits include a collapsible scaffold adapted to provide radial support to the blood conduit. The pump portion also includes one or more impellers. The collapsible scaffold may include portions of differing radial stiffness based on location of the one or more impellers therein.

A system includes a dialyzer having a blood side and a dialysate side, a first extracorporeal circuit including one or more first fluid connectors for connecting the blood side of the dialyzer to the vascular system of a kidney patient, a second extracorporeal circuit including one or more second fluid connectors for connecting the dialysate side of the dialyzer to the vascular system of a healthy animal, a first pump in fluid communication with at least one of the first and second extracorporeal circuits, and a driver mechanically coupled to the first pump, where the driver is configured to drive the first pump using energy from an energy source.

A blood flow assist system can include a blood pump and an elongate power lead having a distal end portion connected to the blood pump and a proximal end portion opposite the distal end portion. The power lead can include a lumen extending distally from the proximal end portion of the power lead along a longitudinal axis of the blood flow assist system and one or more electrical contacts disposed on an outer surface of the lead at the proximal end portion of the elongate power lead. The power lead can include a recess extending into the proximal portion of the power lead in a direction transverse to the longitudinal axis, the recess configured to receive a locking pin to releasable connect the power lead to an external device.

A blood flow assist system can include a blood pump and an elongate power lead having a distal end portion connected to the blood pump and a proximal end portion opposite the distal end portion. The power lead can include a lumen extending distally from the proximal end portion of the power lead along a longitudinal axis of the blood flow assist system and one or more electrical contacts disposed on an outer surface of the lead at the proximal end portion of the elongate power lead. The power lead can include a recess extending into the proximal portion of the power lead in a direction transverse to the longitudinal axis, the recess configured to receive a locking pin to releasable connect the power lead to an external device.

The approach presented here concerns a pump for delivering a fluid. The pump comprises an impeller, a drive device with a shaft, a shaft housing and a sealing device. The impeller is shaped to deliver the fluid. The drive device with the shaft is designed to drive the impeller. The shaft housing is shaped to receive the shaft and/or the drive device. The sealing device comprises at least one casing sealing element and/or an impeller sealing element which is received between the drive device and the impeller and which is designed to prevent fluid from entering the drive device and/or the shaft casing during operation of the pump.

The approach presented here concerns a pump for delivering a fluid. The pump comprises an impeller, a drive device with a shaft, a shaft housing and a sealing device. The impeller is shaped to deliver the fluid. The drive device with the shaft is designed to drive the impeller. The shaft housing is shaped to receive the shaft and/or the drive device. The sealing device comprises at least one casing sealing element and/or an impeller sealing element which is received between the drive device and the impeller and which is designed to prevent fluid from entering the drive device and/or the shaft casing during operation of the pump.

The present disclosure discloses an impeller of a cardiac assist device, and the cardiac assist device. The impeller of the cardiac assist device includes an impeller shaft and a plurality of blades; a shape of the plurality of blades is set such that: blade cascades of the plurality of blades are of arc lines that recess towards a same side, and the blade cascade is a planar unfolding shape of an intersection line where a cylindrical surface intersects with the blade. In the present disclosure, a traditional wing-shaped blade cascade is changed, the blade cascades are of arc lines that recess towards the same side, this design enables blood to pass through the impeller at a smaller inflow angle and a greater outflow angle, the smaller inflow angle may generate a greater lift, so that the impeller obtains a greater output power, and meanwhile, a rotational flow can be prevented from being generated at an inflow port, such that the blood stably flows into the impeller. The greater outflow angle can convert the rotation energy of the blood at an outflow port into an axial kinetic energy, thereby obtaining a greater axial speed, and improving the efficiency of the impeller.