The invention relates generally to wearable accessory carriers for mechanical circulatory support systems, and more specifically relates to belts for carrying peripheral components of a VAD. Such wearable accessory carriers may be suitable for carrying and retaining peripheral components of the VAD in a safe, comfortable, and convenient manner. In certain aspects, the invention provides a wearable accessory carrier configured as an elastic belt with several pockets for holding peripheral components. In other aspects, a wearable accessory carrier may be configured as a belt with a magnetic strip configured to carry one or more modular compartments or pockets for holding peripheral components via magnetic attachment. The wearable accessory carriers disclosed herein may be sized to fit around or configured to be worn on a patient's waist, lower or upper torso, thigh, calf, arm, or other limb.

Provided is a blood pump controller capable of preventing an operation error in performing a battery exchange with a small-sized and light-weighted configuration and exhibiting high waterproof property. A blood pump controller includes: a controller body for driving a blood pump; a battery pack having a first surface on which an electricity-supply-side battery connection connector is disposed and supplying stored electricity to the controller body; and a battery housing body having a slot which has a second surface on which an electricity-receiving-side battery connection connector is disposed and in which the battery pack is housed and held. When the battery pack is housed in the slot, an electrical connection is made between a pair of the battery connection connectors, the first surface and the second surface opposedly face each other, and a first sealing member provides sealing such that the first sealing member surrounds the pair of battery connection connectors.

Provided is a blood pump controller capable of preventing an operation error in performing a battery exchange with a small-sized and light-weighted configuration and exhibiting high waterproof property. A blood pump controller includes: a controller body for driving a blood pump; a battery pack having a first surface on which an electricity-supply-side battery connection connector is disposed and supplying stored electricity to the controller body; and a battery housing body having a slot which has a second surface on which an electricity-receiving-side battery connection connector is disposed and in which the battery pack is housed and held. When the battery pack is housed in the slot, an electrical connection is made between a pair of the battery connection connectors, the first surface and the second surface opposedly face each other, and a first sealing member provides sealing such that the first sealing member surrounds the pair of battery connection connectors.

A medical device for anchoring a cardiac pump in an opening of a ventricular wall of a heart, including a connector to be fitted to the ventricular wall. The connector includes a connection flange and a support skirt. The skirt is to be placed outside the heart when the flange is joined to the ventricular wall. The connector defines a first opening for a part of the body of an insert to pass through. The insert is rigid and defines a second opening for the body of the pump to pass through. The insert includes a distal end that is to be placed inside the heart and a proximal end that is to be placed outside the heart when the insert is joined to the connector. At least one element locks/unlocks the insert in position with respect to the connector when the insert has been introduced into the connector.

A medical device for anchoring a cardiac pump in an opening of a ventricular wall of a heart, including a connector to be fitted to the ventricular wall. The connector includes a connection flange and a support skirt. The skirt is to be placed outside the heart when the flange is joined to the ventricular wall. The connector defines a first opening for a part of the body of an insert to pass through. The insert is rigid and defines a second opening for the body of the pump to pass through. The insert includes a distal end that is to be placed inside the heart and a proximal end that is to be placed outside the heart when the insert is joined to the connector. At least one element locks/unlocks the insert in position with respect to the connector when the insert has been introduced into the connector.

An intravascular heart pump assembly can include a rotor with at least one impeller blade, and a cannula. The present application describes various cannulas that can be manufactured from multiple layers of material to improve flexibility, manufacturability, and durability without increasing an outer diameter of the cannula. In one embodiment, the cannula includes an inflow section having a sheet formed of a shape memory material embedded within a polymer and having at least one lateral hole or aperture in the inflow section. The at least one lateral hole is defined by a first hole in the sheet and a second hole in the outer polymer layer of the cannula. The first hole and the second hole overlap so that blood can enter the cannula through the holes.

An intravascular heart pump assembly can include a rotor with at least one impeller blade, and a cannula. The present application describes various cannulas that can be manufactured from multiple layers of material to improve flexibility, manufacturability, and durability without increasing an outer diameter of the cannula. In one embodiment, the cannula includes an inflow section having a sheet formed of a shape memory material embedded within a polymer and having at least one lateral hole or aperture in the inflow section. The at least one lateral hole is defined by a first hole in the sheet and a second hole in the outer polymer layer of the cannula. The first hole and the second hole overlap so that blood can enter the cannula through the holes.

A blood pump system includes a catheter, a pump housing disposed distal of a distal end of the catheter, a rotor positioned at least partially in the pump housing, a controller, and an electrode coupled a distal region of the blood pump. The electrode can be used to sense electrocardiogram (EKG) signals and transmit the signals to a controller of the blood pump. The operation of the blood pump can be adjusted based on the EKG signal and on cardiac parameters derived from the EKG signal. Further, the controller can determine a need for defibrillation or pacing of the patient's heart based on the signal and can administer treatment with electrical shocks to the heart via the electrode coupled to the blood pump. The use of an electrode with a blood pump already in place in the heart allows for more efficient and safer treatment of serious cardiac conditions.

A blood pump system includes a catheter, a pump housing disposed distal of a distal end of the catheter, a rotor positioned at least partially in the pump housing, a controller, and an electrode coupled a distal region of the blood pump. The electrode can be used to sense electrocardiogram (EKG) signals and transmit the signals to a controller of the blood pump. The operation of the blood pump can be adjusted based on the EKG signal and on cardiac parameters derived from the EKG signal. Further, the controller can determine a need for defibrillation or pacing of the patient's heart based on the signal and can administer treatment with electrical shocks to the heart via the electrode coupled to the blood pump. The use of an electrode with a blood pump already in place in the heart allows for more efficient and safer treatment of serious cardiac conditions.

A heart support system is provided includes a control unit and sound-generating devices, said control unit configured to detect and process alarm events and to carry out control tasks in the heart support system. The heart support system further includes a storage device configured to store one or more defined alarm signal time curves and one or more alarm priorities. Each alarm signal time curve and each alarm priority is assigned to an alarm event. A sound-generation controller is configured such that when an alarm event is detected, the controller overlays a volume time curve onto the alarm signal time curve assigned to the alarm event in the storage device, said volume time curve based on the alarm priority assigned to the respective alarm event in the storage device and the length of time since the detection of the alarm event.