A circulatory support device includes a flexible cannula having a fluid outlet at a proximal end; and a pump assembly disposed at a distal end of the flexible cannula. The pump assembly includes a pump housing having a fluid inlet defined therein; a motor disposed within a distal end of the housing; and an impeller, driven to rotate by the motor, and configured to push blood toward the fluid outlet.

The present disclosure relates to a motor for an extracorporeal blood pump, an extracorporeal blood pump, and an extracorporeal blood pump system. The motor for an extracorporeal blood pump comprises: a housing; an actuator located in the housing and used for driving an impeller in a pump head of the extracorporeal blood pump; at least one sensor located in the housing; and a motor driving-control assembly located in the housing and used to control operation of the motor. Integrating the motor driving-control assembly into the housing of the motor can significantly reduce the dependence of the motor on the control host of the extracorporeal blood pump, the risk of communication failure between the motor and the control host, and the risk of malfunction of the motor driving-control assembly, thereby greatly improving the safety and reliability of the extracorporeal blood pump.

The present disclosure relates to a motor for an extracorporeal blood pump, an extracorporeal blood pump, and an extracorporeal blood pump system. The motor for an extracorporeal blood pump comprises: a housing; an actuator located in the housing and used for driving an impeller in a pump head of the extracorporeal blood pump; at least one sensor located in the housing; and a motor driving-control assembly located in the housing and used to control operation of the motor. Integrating the motor driving-control assembly into the housing of the motor can significantly reduce the dependence of the motor on the control host of the extracorporeal blood pump, the risk of communication failure between the motor and the control host, and the risk of malfunction of the motor driving-control assembly, thereby greatly improving the safety and reliability of the extracorporeal blood pump.

A blood pump-oxygenator system comprises at least one blood pump, an oxygenator, inflow and outflow cannulas, connected to form a closed series circuit operable as a cardiopulmonary bypass system for extracorporeal processing of the patient's blood. The blood pump conveys blood through the circuit from the patient into the inflow cannula, through the oxygenator and out of the outflow cannula back into the patient. A manifold is connected between the inflow and outflow cannulas so blood passes through the manifold, wherein the manifold accommodates the blood pump and the oxygenator to form a recirculation loop configured to recirculate at least part of the blood in the circuit so the blood passes over the oxygenator multiple times. An extra blood pump is positioned at the outflow cannula to deliver a set volume to the patient, controllable independently from the blood pump that circulates the blood in the manifold including the oxygenator.

A vascular access system comprising a sheath, a slitted sleeve, and a sealing portion of the slitted sleeve. The slitted sleeve comprises a tubular sleeve body having a longitudinal slit along its length, wherein the slitted sleeve is adapted to receive a first portion of a medical device therein. The longitudinal slit closes, but does not seal, after the first portion of the medical device is inserted therein. The sealing portion of the slitted sleeve is configured to fill a gap and form a seal between an inner surface of the sheath and a portion of the first portion of the medical device disposed in the sheath when the sheath is inserted in the blood vessel and the slitted sleeve is inserted into the sheath lumen. A vascular access device accessory and a method for inserting it into a sheath are also provided.

A percutaneous circulatory support device includes a housing and an impeller disposed within the housing. The impeller is rotatable relative to the housing to cause blood to flow through the housing. A cannula is coupled to the housing, and a distal tip portion is coupled to the cannula opposite the housing. The distal tip portion includes an inner shaping core configured to maintain a predetermined shape of the distal tip portion and an outer layer disposed outwardly from the inner shaping core or the distal tip portion includes an atraumatic, sphere-shaped distal end.

A percutaneous circulatory support device includes a housing and an impeller disposed within the housing. The impeller is rotatable relative to the housing to cause blood to flow through the housing. A cannula is coupled to the housing, and a distal tip portion is coupled to the cannula opposite the housing. The distal tip portion includes an inner shaping core configured to maintain a predetermined shape of the distal tip portion and an outer layer disposed outwardly from the inner shaping core or the distal tip portion includes an atraumatic, sphere-shaped distal end.

A blood pump including a housing having an inflow tube defining a major axis spanning through the inflow tube and a flow path spanning along the major axis, a rotor disposed within the inflow tube, the rotor and the inflow tube defining a gap therebetween, a stator surrounding the inflow tube and the rotor, and the housing defining an access conduit spanning through the inflow tube and the stator transverse to the major axis, the access conduit being in communication with the gap.

A blood pump including a housing having an inflow tube defining a major axis spanning through the inflow tube and a flow path spanning along the major axis, a rotor disposed within the inflow tube, the rotor and the inflow tube defining a gap therebetween, a stator surrounding the inflow tube and the rotor, and the housing defining an access conduit spanning through the inflow tube and the stator transverse to the major axis, the access conduit being in communication with the gap.

A connector for a medical device. The connector including an elongate body having a proximal end and a distal end. The connector further including a strut, a plurality of conductors, and a plurality of electrical contacts. The strut being disposed within the elongate body and defining a plurality of channels. Each of the plurality of channels having a proximal end and a distal end opposite the proximal end. The plurality of conductors being disposed within the elongate body and are sized and configured to be received within the plurality of channels and extend between the proximal end and the distal end. The plurality of electrical contacts being coupled to an outer surface of the elongate body and in communication with the plurality of conductors.