A rotor for a pump has a housing and a rotor, and has at least one blade. The rotor is able to be actuated to rotate about an axis of rotation in order to convey a fluid in the axial or radial direction, and the rotor is able to be deformed in the radial direction between a first, radially compressed state and a second, radially expanded state. At a maximum speed of rotation of the rotor at which the power of the pump is at a maximum, the blade is essentially radially oriented, and/or the rotor has its maximum diameter.

A rotor for a pump has a housing and a rotor, and has at least one blade. The rotor is able to be actuated to rotate about an axis of rotation in order to convey a fluid in the axial or radial direction, and the rotor is able to be deformed in the radial direction between a first, radially compressed state and a second, radially expanded state. At a maximum speed of rotation of the rotor at which the power of the pump is at a maximum, the blade is essentially radially oriented, and/or the rotor has its maximum diameter.

The application pertains to a blood pump system, in particular a ventricular assist device, VAD, the system including a blood pump, which comprises: a housing, including an inlet and an outlet, preferably an axial influx and a tangential outflow; a motor actuator, wherein the motor includes a plurality of motor coils (for driving an impeller); an impeller, wherein the impeller is located in the housing and includes a plurality of rotor magnets.

The system further comprises a drive line; and a control unit for controlling operation of the pump, the control unit configured to: operate the motor, such that the impeller rotates around an axis; and measure the rotor position in a direction along the axis using at least one of the plurality of the motor coils.

The application pertains to a blood pump system, in particular a ventricular assist device, VAD, the system including a blood pump, which comprises: a housing, including an inlet and an outlet, preferably an axial influx and a tangential outflow; a motor actuator, wherein the motor includes a plurality of motor coils (for driving an impeller); an impeller, wherein the impeller is located in the housing and includes a plurality of rotor magnets.

The system further comprises a drive line; and a control unit for controlling operation of the pump, the control unit configured to: operate the motor, such that the impeller rotates around an axis; and measure the rotor position in a direction along the axis using at least one of the plurality of the motor coils.

An integrated flow source is a limiting factor in numerous microfluidic applications. In addition to precise gradients and controlling molecular transports, a built-in source of stable and accurate flow can enable novel shear stress modulations for long-term cell culturing studies. The Tesla turbine, when used as a pump on the microfluidic regime, produces stable and accurate fluid gradients by utilizing laminar flow between its rotating discs Utilizing a stereolithography based 3D printer, a tesla pump (Ø10 cm) and associated housing capable of driving a microfluidic gradient is provided having a printed rotor surface topology of the pump in order to enhance pumping of biological fluids like blood at elevated viscosities. The surface topology is tuned via 3D pixilation, and this modulation completely recovered the pressure loss between pumping water at 1 cP versus glycerol solution at 3 cP. As a result, increased fluid viscosities, and even Non-Newtonian viscosities, can be used.

Disclosed herein is an outflow graft assembly for an implantable blood pump. The outflow graft assembly includes a graft, a locking nut including a plurality of planar edges and a plurality of corners, and a U-shaped fixation clip. The U-shaped fixation clip includes a first flat segment including a first flexure including a first locking feature, a second flat segment including a second flexure including a second locking feature, an arcuate segment extending between the first flat segment and the second flat segment, and a lip including a first flat and a second flat. The U-shaped fixation clip is configured to engage the locking nut such that the first and second locking features contact associated corners of the plurality of corners and the first and second flats contact associated planar edges of the plurality of planar edges, thereby preventing rotation of the locking nut relative to the fixation clip.

An improved system for supporting (e.g., localization and/or positioning of) intravascular devices discussed herein provides for example a multi-element arrangement. A set of struts optionally projects from the intravascular device and contacts the vessel walls. The localization and positioning of the pump may be provided by the struts and/or by use of a tether opposing a propulsive force to ensure localization.

A percutaneous circulatory support device includes an impeller housing and a primary impeller disposed within the impeller housing. The primary impeller is rotatable relative to the impeller housing to cause blood to flow through the percutaneous circulatory support device. The device further includes a counter impeller disposed within the impeller housing.

A percutaneous circulatory support device includes an impeller housing and a primary impeller disposed within the impeller housing. The primary impeller is rotatable relative to the impeller housing to cause blood to flow through the percutaneous circulatory support device. The device further includes a counter impeller disposed within the impeller housing.

A magnetically levitated motor includes a stator, a rotor configured to rotate relative to the stator, and a passive radial magnetic bearing configured to support the rotor relative to the stator in a radial direction. An active longitudinal magnetic bearing is configured to selectively position the rotor relative to the stator in an axial direction.