Abstract: Systems, devices and methods are provided for supporting cardiac function. One system comprises an implantable intracardiac device comprising a motor and a pump, a transmitting resonator comprising a magnetic coil and configured to transmit a first level of power through an outer skin surface of the patient and a receiving resonator configured for implantation within the patient, comprising a magnetic coil and configured to transmit a second level of power to the motor within the implanted device. A controller is coupled to the transmitting resonator and configured to control the resonators and other parameters in the system such that the second level of power remains at or above a threshold level, thereby ensuring that the pump will continuously pump blood through the heart at a sufficient rate regardless of any changes in the system, such as power loss due to transmission inefficiencies and/or changes in the relative positions between the transmitting and receiving coils.

Abstract: Systems, devices and methods are provided for supporting cardiac function. A device comprises a catheter having a shaft with a distal end portion configured for advancing through an aortic valve to a left ventricle of a patient and an impeller coupled to the distal end portion of the catheter. One or more inlets are positioned distal of the impeller and coupled to an internal lumen within the catheter to draw blood from the left ventricle through the inlets and into the internal lumen. One or more outlets positioned proximal of the impeller and coupled to the internal lumen to pump the blood through the outlets and into the aorta. The device further includes an extracorporeal motor coupled to a proximal end portion of the catheter and a drive member extending through the catheter shaft and coupling the impeller with the motor to rotate the impeller. The motor may comprise a non-contact motor that generates a magnetic field to rotate the drive member.

Abstract: Systems, devices and methods are provided for supporting cardiac function. One system comprises an implantable intracardiac device comprising a motor and a pump, a transmitting resonator comprising a magnetic coil and configured to transmit a first level of power through an outer skin surface of the patient and a receiving resonator configured for implantation within the patient, comprising a magnetic coil and configured to transmit a second level of power to the motor within the implanted device. A controller is coupled to the transmitting resonator and configured to control the resonators and other parameters in the system such that the second level of power remains at or above a threshold level, thereby ensuring that the pump will continuously pump blood through the heart at a sufficient rate regardless of any changes in the system, such as power loss due to transmission inefficiencies and/or changes in the relative positions between the transmitting and receiving coils.

Abstract: Systems, devices and methods are provided for supporting cardiac function. A device comprises an elongate housing configured for implantation into the right atrium and/or the superior vena cava of a human heart. The housing includes a first inlet and an outlet that define a primary blood flow path from the left atrium through at least a portion of the housing within the right atrium, and to the aorta. The housing comprises a motor disposed within the housing and an impeller coupled to the motor for pumping blood from the first inlet to the outlet of the housing through the primary blood flow path. The device bypasses the left ventricle by drawing freshly oxygenated blood from the left atrium and propelling this blood directly into the aorta. Implanting the pump in the right atrium eliminates the risk of bloods clots forming on the pump from passing into the arteries supplying blood to the brain.

Abstract: The present disclosure provides a pump for supporting heart function, that includes a housing with a rotor disposed within the housing and spaced from an internal surface of the housing to define a clearance therebetween. An impeller is coupled to the rotor for propelling blood from a first inlet to an outlet of the housing along a primary blood flow path. The housing includes a second inlet fluidly coupled to the clearance between the rotor and the housing to define a secondary flow path through the clearance. The blood flowing through the secondary flow path continuously flushes the space between the rotor and the housing to minimize the formation and/or growth of blood clots and/or to remove heat generated by the pump.

Abstract: Systems, devices and methods are provided for supporting cardiac function. One system comprises an implantable intracardiac device comprising a motor and a pump, an external energy source and a transmitting resonator comprising a magnetic coil and configured to receive a first level of power from the external energy source and transmit a second level of power through an outer skin surface of the patient. The system further comprises a receiving resonator configured for implantation within the patient, comprising a magnetic coil and configured to transmit a third level of power to the motor within the implanted device. The third level of power is at least 40% of the first level of power, thereby ensuring that the pump will continuously pump blood through the heart at a sufficient rate regardless of any changes in the system, such as power loss due to transmission inefficiencies and/or changes in the relative positions between the transmitting and receiving coils.

Abstract: Systems, devices and methods are provided for supporting cardiac function. One system comprises an implantable intracardiac device comprising a motor and a pump, a transmitting resonator comprising a magnetic coil and configured to transmit a first level of power through an outer skin surface of the patient and a receiving resonator configured for implantation within the patient, comprising a magnetic coil and configured to transmit a second level of power to the motor within the implanted device. A controller is coupled to the transmitting resonator and configured to control the resonators and other parameters in the system such that the second level of power remains at or above a threshold level, thereby ensuring that the pump will continuously pump blood through the heart at a sufficient rate regardless of any changes in the system, such as power loss due to transmission inefficiencies and/or changes in the relative positions between the transmitting and receiving coils.