A medical apparatus is provided that includes an implantable element, in particular a heart pump, and a control unit for the implantable element, which control unit is connected to the implantable element by means of a first connection. The problem of arranging an antenna of a radio module on the control unit expediently and favourably is solved in that the control unit is configured for arrangement outside the patient's body and has a predetermined orientation relative to the patient's body and has a radio module, wherein an antenna of the radio module is arranged in such a way that the region in which the patient's body is intended to be positioned, as considered from the control unit, is shielded from the antenna at least in part by electromagnetically shielding, in particular electrically conductive parts of the control unit or housing thereof.

Present embodiments are directed to measuring and calculating parameters to control and monitor a power transfer in an implanted medical device. The medical device may be implanted in a subject and typically includes an artificial heart or ventricle assist device. The system measures parameters and uses the parameters to calculate a coupling coefficient for coils that transfer power between an external primary and an implanted secondary. The system uses the calculated coupling coefficient to estimate heat flux being generated in the system. Based on the level heat flux detected, the system may issue alerts to warn the subject or control actions to mitigate the effects of the heat flux.

A driveline for an implantable blood pump including a percutaneous outer tube configured to connect with the blood pump when the blood pump is implanted within a body of a patient and an external controller outside of the body of the patient and at least one ultra-violet light emitter coupled to the outer tube.

A driveline for an implantable blood pump including a percutaneous connector including an outer tube, the outer tube defining an exterior surface and having a proximal portion and a distal portion opposite the proximal portion, the proximal portion being couplable to the implantable blood pump disposed within a body of a patient and the distal portion being couplable to a controller outside of the body of the patient and at least one electronic instrument coupled to the outer tube and fluidically sealed from the exterior surface.

Methods and apparatus for wireless power transfer and communications are provided. In one embodiment, a wireless power transfer system comprises an external transmit resonator configured to transmit wireless power, an implantable receive resonator configured to receive the transmitted wireless power from the transmit resonator, and a user interface device comprising a resonant coil circuit, the resonant coil circuit being configured to receive magnetic communication signals from the transmit resonator or the receive resonator and to display information relating to the magnetic communication signals to a user of the user interface device.

This document discusses, among other things, systems and methods to reduce ischemic or metabolic injury to a patient's heart. A system to reduce ischemic or metabolic injury to a patient's heart may include a pulse generator for generating electrical pulses or shock, a pacing lead with at least one pacing electrode configured to deliver electrical pulses received from the pulse generator to the patient's heart, a controller configured to control timing of electrical pulses to reduce wall stress of the heart, and a reservoir, fluidically coupled to a lumen and a pump, wherein the pump is configured, under control of the controller, to move contents from the reservoir through the lumen to an area of the heart with the reduced wall stress, wherein the contents include autologous respiration-competent mitochondria or other respiratory-promoting agents.

Methods and apparatus for wireless power transfer and communications are provided. In one embodiment, a wireless power transfer system comprises an external transmit resonator configured to transmit wireless power, an implantable receive resonator configured to receive the transmitted wireless power from the transmit resonator, and a user interface device comprising a resonant coil circuit, the resonant coil circuit being configured to receive magnetic communication signals from the transmit resonator or the receive resonator and to display information relating to the magnetic communication signals to a user of the user interface device.

Devices, systems and methods for establishing a blood flow conduit between a chamber in a heart of a patient and a remote location. A blood inflow cannula having an outer surface and proximal and distal end portions. The distal end portion is configured for insertion into the chamber of the heart. First and second anchor elements have respective maximum width dimensions extending outwardly from the outer surface of the cannula. The first anchor element is positioned more distally than the second anchor element defining a tissue receiving space therebetween. The maximum width dimension of the first anchor element may be larger than the maximum width dimension of the second anchor element in use. The first anchor element is configured to be positioned inside the heart chamber and the second anchor element is configured to be positioned outside the heart chamber with heart tissue held in the tissue receiving space therebetween.

Systems for tuning a wireless power transfer system are provided, which may include any number of features. In one embodiment, a wireless power transfer system can include a transmit controller connected to the transmitter resonator and configured to measure an impedance on the transmitter resonator. The transmit controller can be configured to determine a load resistance of the receiver resonator and a coupling coefficient between the transmitter and receiver resonators based on the measured impedance on the transmitter resonator. The transmit controller can be further configured to adjust a power transmission parameter of the transmitter resonator based on the determined load resistance and the coupling coefficient to achieve a controlled voltage at a load of the receiver. Methods of use are also provided.

A cannula system for conveying a liquid, in particular blood, is provided comprising: a cannula with a tube element having a front end region and a rear end region, wherein a channel extends through the tube element from the front end region of the tube element to the rear end region of the tube element; a hollow body, wherein the hollow body has a front end region that can be inserted into the channel of the tube element through a front inlet opening of the channel; and a connector which is designed to receive the front end region of the tube element and the front end region of the hollow body in an internal region of the connector when the cannula system is in a connection state, in which the front end region of the tube element is inserted into the channel of the tube element of the cannula.