A percutaneous circulatory support device includes a housing, an impeller disposed within the housing and being rotatable relative to the housing, a cannula coupled to the housing, the cannula extending between a proximal portion and a distal portion of the cannula positioned opposite the proximal end, an expandable element arranged near the distal portion of the cannula, the expandable element capable of inflation and deflation, and wherein the expandable element is configured for providing an atraumatic portion at the distal portion of the cannula.

Some embodiments of the disclosure are directed to a novel system for pumping liquid such as blood without damaging cells. In some embodiments, the system includes one or more inflatable elements such as balloons which force liquid from an implanted pump. In some embodiments, one or more elements are configured to directionally inflate. In some embodiments, the directional inflation enables pumping in a bidirectional manner. In some embodiments, the system includes a plurality of elements that inflate sequentially to pump liquid in one direction or another. In some embodiments, the one or more elements are coupled to a tube or stent.

A device to assist the performance of a heart with at least one pump that is formed as a rotary pump and driven via a magneto coupling.

A device to assist the performance of a heart with at least one pump that is formed as a rotary pump and driven via a magneto coupling.

The present invention provides a system for augmenting the contraction of a contractile organ in a subject. The system comprises at least one implantable organ contraction device comprising an electronic linear actuation device (1) for producing a contraction force; an anchoring assembly (13,14) for operably coupling the electronic linear actuation device to at least one wall of the contractile organ; and a controller (65) configured to modify the output parameters of the electronic linear actuation device so as to activate the electronic linear actuation device in a pattern synergistic to the natural contraction cycle of the contractile organ.

Apparatus and methods are described, including a blood pump that includes a catheter, a proximal impeller disposed on the catheter inside a proximal impeller housing, and which is configured to pump blood by rotating inside the proximal impeller housing. A distal impeller is disposed on the catheter inside a distal impeller housing, distally to the proximal impeller, and the distal impeller is configured to pump blood by rotating inside the distal impeller housing. A tubular element is disposed between the proximal impeller housing and the distal impeller housing, the tubular element being configured to have a tubular configuration during rotation of the proximal and distal impellers. Other applications are also described.

The disclosure in particular relates to a ventricular assist device for implantation into a lumen of a blood vessel, comprising an impeller fixed to a rotor shaft, wherein the impeller is configured to rotate around a longitudinal axis of the rotor shaft; a drive unit comprising a magnetic motor configured to cause rotation of the impeller around to the longitudinal axis; a first active magnetic bearing configured to bear a first end section of the rotor shaft relative to the drive unit; a second active magnetic bearing configured to bear a second end section of the rotor shaft relative to the drive unit; and a control unit configured to control the magnetic motor, the first active magnetic bearing and the second active magnetic bearing.

An access device for a heart chamber, a removable hemostatic valve unit, and a system including a cardiac assist unit are disclosed. In examples, the access device) includes an apical base plate and a sealing unit configured to provide a separation of a wet zone from a heart chamber and a dry zone with a gaseous environment outside of said heart chamber inside a patient body at the same time.

Methods and devices that prevent stasis in the LAA by either increasing the flow through the LAA or by closing off or sealing the LAA. Increasing the flow is accomplished through shunts, flow diverters, agitators, or by increasing the size of the ostium. Closing off the LAA is accomplished using seals or by cinching the LAA.

Methods and devices that prevent stasis in the LAA by either increasing the flow through the LAA or by closing off or sealing the LAA. Increasing the flow is accomplished through shunts, flow diverters, agitators, or by increasing the size of the ostium. Closing off the LAA is accomplished using seals or by cinching the LAA.