A catheter includes a catheter body, a pump assembly and a cannula. The pump assembly can be disposed at a distal end of the catheter body and has a distal portion. The cannula can be coupled to the distal end portion of the pump assembly and can include a proximal cannula portion and a distal cannula portion. The distal cannula portion has an approximately helical shape which can allow the cannula to be inserted into a patient's right heart and pump blood therethrough. In certain implementations, the distal tip of the helical shape has a slight bias relative to the main helix to further facilitate delivery of the device. In certain applications this bias is toward the central axis of the helix.

An impeller for a pump is disclosed herein. The impeller can include a hub having a fixed end and a free end. The impeller can also have a plurality of blades supported by the hub. Each blade can have a fixed end coupled to the hub and a free end. The impeller can have a stored configuration and a deployed configuration, the blades in the deployed configuration extending away from the hub, and the blades in the stored configuration being compressed against the hub.

Intravascular blood pump systems that include a catheter assembly and an external console assembly. The catheter assembly may be in one or more of fluidic or electrical communication. The catheter assembly may include a controller with an executable method stored therein, wherein the executable method may be configured to receive sensed information that is indicative of a sensed characteristic of fluid in a fluid pathway, at least a portion of the fluid pathway disposed within the catheter assembly, and cause an alert if any of the sensed information is indicative that the external console assembly is not functioning properly.

Intravascular blood pump systems that include a catheter assembly and an external console assembly. The catheter assembly may be in one or more of fluidic or electrical communication. The catheter assembly may include a controller with an executable method stored therein, wherein the executable method may be configured to receive sensed information that is indicative of a sensed characteristic of fluid in a fluid pathway, at least a portion of the fluid pathway disposed within the catheter assembly, and cause an alert if any of the sensed information is indicative that the external console assembly is not functioning properly.

A device for controlling the functioning of a cardiac prosthesis, the device for controlling includes a control path, the control path having a control system designed and arranged to monitor and regulate the electrical supply of a cardiac prosthesis; a first insulating system designed and arranged to electrically insulate the cardiac prosthesis from the electrical supply; and a controller designed and arranged to monitor and regulate the electrical supply.

A system for cleaning an implanted blood pump, comprising: an inflow catheter having an expandable inflow member positioned about the periphery thereof; an inflow tube coupled with the inflow catheter; a valve assembly coupled to the inflow tube; an outflow tube coupled to the valve assembly; and an outflow catheter having an expandable outflow member positioned about the periphery thereof, the outflow catheter being coupled to the outflow tube. In use, the inflow tube and outflow tube extend through the skin of a human body, the inflow catheter and outflow catheter are positioned within the human body, and the valve assembly is positioned outside the human body.

The present disclosure provides for a method, control device, and implantable system, for acquiring a plurality of flow rate data points over time, each data point indicative of a flow rate of blood through the pump, calculating, based on the plurality of acquired flow rate data points, a value characterizing one or more features of a waveform formed from the plurality of flow rate data points; and determining, based on the value, the presence or absence of a suction condition in the pump.

Techniques and systems for using spectroscopy- and/or image-based sensing with an intravascular blood pump may be provided. The techniques generally include capturing a spectral response to light of a measured tissue and/or blood. Based on the specific needs, the method may include, e.g., determining a type of the measured tissue based on the spectral response, determining if the type of the measured tissue matches a target tissue type, determining a health of the measured tissue based on the spectral response, determining a treatment plan based on the health of the measured tissue, determining a type and/or quantity of components and/or characteristics in the blood, and/or determining a degree of heart recovery based on the type and/or quantity of the components and/or characteristics in the blood.

Techniques and systems for using spectroscopy- and/or image-based sensing with an intravascular blood pump may be provided. The techniques generally include capturing a spectral response to light of a measured tissue and/or blood. Based on the specific needs, the method may include, e.g., determining a type of the measured tissue based on the spectral response, determining if the type of the measured tissue matches a target tissue type, determining a health of the measured tissue based on the spectral response, determining a treatment plan based on the health of the measured tissue, determining a type and/or quantity of components and/or characteristics in the blood, and/or determining a degree of heart recovery based on the type and/or quantity of the components and/or characteristics in the blood.

A method is provided of controlling a pump including a electrical motor coupled to a rotor which carries first and second impellers at opposite ends thereof. The method includes: (a) driving the rotor using the motor, so as to circulate fluid from the first impeller through a first fluid circuit, the second impeller, a second fluid circuit, and back to the first impeller; (b) determining a resistance of the first fluid circuit, based on a first motor parameter which is a function of electrical power delivered to the motor; (c) determining a flow rate through the first fluid circuit based on a second motor parameter which is a function of electrical power delivered to the motor; and (d) varying at least one operational parameter of the pump so as to maintain a predetermined relationship between the flow rate and the resistance of the first fluid circuit.