Various embodiments of a fluid handling system are disclosed herein. For example, the fluid handling system can include a catheter assembly and a console configured to control the operation of the catheter assembly. A removable interface member can be configured to provide fluid and electrical communication between the catheter assembly and the console.

A mechanical circulatory support system includes an implantable blood pump, an implantable prosthetic rib assembly, and an implantable drive cable. The prosthetic rib assembly includes a prosthetic rib segment and a percutaneous electrical connector mounted to the prosthetic rib segment. The prosthetic rib segment is configured to be mounted to a patient's rib in place of a resected segment of the patient's rib. The electrical connector includes a skin interface portion configured to interface with an edge of a skin aperture through the patient's skin. The electrical connector is configured to expose a connection port of the electrical connector via the skin aperture. The implantable power cable is connected with or configured to be connected with each of the blood pump and the percutaneous electrical connector for transferring electric power received by the percutaneous electrical connector to the blood pump.

A percutaneous lead assembly for an active implantable device, the lead assembly comprising a sheath with a plurality of wires extending from a proximal end to a distal end. The wires being adapted to power the active implantable device; the distal end having at least one electrode fixed thereon. The electrodes being in communication with sensor electronics and wherein at least one electrode is on the outer layer of the lead assembly in which the electrode is used to detect at least one of acceleration and electrical signals of an organ.

A system, such as a blood pump system, is provided for securing a releasable connection between two elements, in particular between two cables or between two hollow bodies, said system comprising: a first connector and a second connector that is releasably connectable to the first connector, a securing sleeve which, when the first connector is connected to the second connector, is movable, by displacement of the securing sleeve relative to the first connector and relative to the second connector into a securing position in which the securing sleeve completely or at least partially receives the first connector and the second connector, and a latching device with at least one latching element, wherein the latching device is configured to produce a latching connection between the securing sleeve in the securing position and the first connector and/or the second connector connected to the first connector.

The application relates to a heart pump device and an operating method for a heart pump device. The proposed heart pump device comprises an implantable heart pump and a controller for controlling the heart pump. The controller and the heart pump are connected to one another by way of a line with wires. Moreover, the controller is configured to supply the heart pump with electrical power by way of a first of the wires. Furthermore, the controller and the heart pump each comprise a coupling interface. Here, electrical signals for transferring data between the controller and the heart pump are able to be coupled into the first wire or able to be coupled out of the first wire by way of these coupling interfaces.

The present disclosure provides intravascular ventricular assist devices for insertion into the vasculature of an individual to improve the overall blood flow of the individual. In many embodiments, the intravascular ventricular assist devices described herein provide an individual with an intravascular ventricular assist device that is sized and configured for insertion into an aortic root or pulmonary root such that its reduced size and placement provide the individual with an improved quality of life.

A fluid handling system includes a console configured to connect with a first electrical interface that is configured to connect to a plurality of components of the fluid handling system, the console including a second electrical interface configured to connect with the first electrical interface, a display, and one or more hardware processors. A control system includes the one or more hardware processors and a non-transitory memory storing instructions that, when executed, cause the control system to: detect an electrical signal from a first component of the plurality of components of the fluid handling system responsive to a caretaker performing a first instruction; determine a system state of the fluid handling system based at least in part on the electrical signal from the first component; compare the system state with a predetermined state condition corresponding to said first instruction; and output an indication on the display of the system state.

A fluid handling system includes a console configured to connect with a first electrical interface that is configured to connect to a plurality of components of the fluid handling system, the console including a second electrical interface configured to connect with the first electrical interface, a display, and one or more hardware processors. A control system includes the one or more hardware processors and a non-transitory memory storing instructions that, when executed, cause the control system to: detect an electrical signal from a first component of the plurality of components of the fluid handling system responsive to a caretaker performing a first instruction; determine a system state of the fluid handling system based at least in part on the electrical signal from the first component; compare the system state with a predetermined state condition corresponding to said first instruction; and output an indication on the display of the system state.

An external controller assembly for a medical device implanted in a patient includes an external controller and an external driveline assembly. The external controller includes an external controller display viewable by the patient. The external driveline assembly includes an external driveline cable and an external driveline distal connector. The external driveline cable is connected to the external driveline distal connector and the external controller. The external driveline cable accommodates positioning of the external driveline distal connector, by the patient, for simultaneous viewing of the external driveline distal connector and the external controller display by the patient. The external driveline distal connector is adapted to be connected to the distal driveline proximal connector by the patient. The external driveline distal connector is adapted to be disconnected from the distal driveline proximal connector by the patient.

An external controller assembly for a medical device implanted in a patient includes an external controller and an external driveline assembly. The external controller includes an external controller display viewable by the patient. The external driveline assembly includes an external driveline cable and an external driveline distal connector. The external driveline cable is connected to the external driveline distal connector and the external controller. The external driveline cable accommodates positioning of the external driveline distal connector, by the patient, for simultaneous viewing of the external driveline distal connector and the external controller display by the patient. The external driveline distal connector is adapted to be connected to the distal driveline proximal connector by the patient. The external driveline distal connector is adapted to be disconnected from the distal driveline proximal connector by the patient.