A remote controller updating system for an implantable blood pump including an implantable blood pump, an implantable controller coupled to the implantable blood pump, and a pump driveline including a data network connection in communication with the implantable controller. The system may also include a pump connector coupled to the pump driveline, a remote controller couplable to the implantable blood pump, and a system update assembly including a system update connector couplable to the pump connector and a power source coupled to the system update connector.

Systems and methods for connections in a medical device system are provided. A connector system includes a connector receptacle including first electrical contacts, a connector insert including second electrical contacts and at least one pin, and a locking member rotatably coupled to the connector receptacle, the locking member including a housing and a guide member, the guide member including an annular body that defines at least one groove including a first locking detent and a second locking detent, the at least one pin operable to traverse the at least one groove, engage the first locking detent in a first locked configuration, and engage the second locking detent in a second locked configuration when the connector insert is inserted into the connector receptacle.

Systems and related methods for supplying power to an implantable blood pump are provided. A system includes a base module and a plurality of energy storage devices. A first energy storage device is operatively coupled to the base module. A second energy storage device is operatively coupled to the first modular energy storage device. The energy storage devices are mechanically coupled in series, electrically coupled in parallel, and configured to provide redundant sources of power to drive an implantable blood pump.

An implantable blood pump system is disclosed herein. The implantable blood pump system includes an implantable blood pump and a controller coupled to the blood pump. The controller includes a partially sealed housing defining an internal volume. The controller includes an energy storage component contained within the internal volume and a processor. The processor can generate one or several signals affecting operation of the implantable blood pump. The controller includes a connector receptacle including a plurality of contacts selectively coupled via a circuitry to the energy storage component. The circuitry can electrically couple the plurality of contacts to the energy storage component when a connector insert is received within the connector receptacle and deactivate the plurality of contacts from the energy storage component when the connector insert is not within the connector receptacle.

A catheter pump is disclosed herein. The catheter pump can include a catheter assembly that comprises a drive shaft and an impeller coupled to a distal end of the drive shaft. A driven assembly can be coupled to a proximal end of the drive shaft within a driven assembly housing. The catheter pump can also include a drive system that comprises a motor and a drive magnet coupled to an output shaft of the motor. The drive system can include a drive assembly housing having at least one magnet therein. Further, a securement device can be configured to prevent disengagement of the driven assembly housing from the drive assembly housing during operation of the pump.

The invention generally relates to heart pump systems. In some embodiments, a pressure sensor is provided with a heart pump, either at the inflow or the outflow of the blood pump. The heart pump may further include a flow estimator based on a rotor drive current signal delivered to the rotor. Based on the rotor drive current signal, a differential pressure across the pump may be calculated. The differential pressure in combination with the pressure measurements from the pressure sensor may be used to calculate pressure on the opposite side of the pump from the pressure sensor. In some embodiments, the pressure sensor is located at the outflow of the pump and the pump is coupled with the left ventricle. The differential pressure and pressure measurement may be used to calculate a left ventricular pressure waveform of the patient. With such a measurement, other physiological parameters may be derived.

The invention generally relates to heart pump systems. In some embodiments, a pressure sensor is provided with a heart pump, either at the inflow or the outflow of the blood pump. The heart pump may further include a flow estimator based on a rotor drive current signal delivered to the rotor. Based on the rotor drive current signal, a differential pressure across the pump may be calculated. The differential pressure in combination with the pressure measurements from the pressure sensor may be used to calculate pressure on the opposite side of the pump from the pressure sensor. In some embodiments, the pressure sensor is located at the outflow of the pump and the pump is coupled with the left ventricle. The differential pressure and pressure measurement may be used to calculate a left ventricular pressure waveform of the patient. With such a measurement, other physiological parameters may be derived.

A connector unit for a control unit is configured to control an implantable blood pump. The connector unit includes a supply interface designed for connecting the connector unit to a power supply, a data interface designed for connecting the connector unit to a data processing unit, and a control interface designed for connecting the connector unit to an integrated interface of the control unit. A supply connection of the control unit to the power supply and a data connection of the control unit to the data processing unit can be established at the same time by means of the connector unit. The application furthermore relates to a control unit for controlling an implantable blood pump and to a control system for an implantable blood pump.

A control system for a cardiac assist device includes a sensor implantable in the body at the heart or at an implanted pump of the cardiac assist device, the sensor being for detecting motion of the pump within the body and hence being for monitoring movement of the pump, where the control system is arranged to, in use: receive signals from the sensor, the signals providing information on the movement of the pump; and to process the signals to monitor the pump speed and/or to identify pump malfunction and/or cardiac assist treatment complications.

A control system for a cardiac assist device includes a sensor implantable in the body at the heart or at an implanted pump of the cardiac assist device, the sensor being for detecting motion of the pump within the body and hence being for monitoring movement of the pump, where the control system is arranged to, in use: receive signals from the sensor, the signals providing information on the movement of the pump; and to process the signals to monitor the pump speed and/or to identify pump malfunction and/or cardiac assist treatment complications.