A gas delivery system is provided. The gas delivery system includes a pump operable to receive blood from a patient. A gas transfer unit is in fluid communication with the pump and operable to receive the blood from the pump and deliver a therapeutic amount of xenon gas to the blood. A patient connector withdraws and/or infuses the blood into the patient.

A gas delivery system is provided. The gas delivery system includes a pump operable to receive blood from a patient. A gas transfer unit is in fluid communication with the pump and operable to receive the blood from the pump and deliver a therapeutic amount of xenon gas to the blood. A patient connector withdraws and/or infuses the blood into the patient.

A dual lumen drainage cannula configured for use in a veno-arterial extracorporeal membrane oxygenation (VA ECMO) system includes a first drainage tube having a proximal end, a distal end, and at least one aperture defined in the distal end. The dual lumen drainage cannula further includes a second drainage tube having a proximal end, a distal end, and at least one aperture defined in the distal end. The dual lumen drainage cannula further includes an outlet fitting in fluid communication with the first drainage tube and the second drainage tube. The distal end of the second drainage tube is joined to a portion of the first drainage tube between the proximal and distal ends of the first drainage tube.

A dual lumen drainage cannula configured for use in a veno-arterial extracorporeal membrane oxygenation (VA ECMO) system includes a first drainage tube having a proximal end, a distal end, and at least one aperture defined in the distal end. The dual lumen drainage cannula further includes a second drainage tube having a proximal end, a distal end, and at least one aperture defined in the distal end. The dual lumen drainage cannula further includes an outlet fitting in fluid communication with the first drainage tube and the second drainage tube. The distal end of the second drainage tube is joined to a portion of the first drainage tube between the proximal and distal ends of the first drainage tube.

An arterial cannula connects to a heart-lung machine for supplying a patient with oxygen-rich blood and includes a tubular body having a front end region for positioning at the aortic arch, a main region, and a rear end region for connection to the supply side. The length of the tubular body is dimensioned so that the cannula can be placed at the femoral artery and extends to the aortic arch. The tubular body is flexible and includes a lumen, and perforations in the front end region. The front end region is pre-curved, following the shape of the aortic arch. An insertion aid is located inside the tubular body for placing the cannula and is slidable into or withdrawable from the tubular body after the cannula has been placed. The curvature of the front end region adjusts automatically after the cannula is placed and the insertion aid withdrawn.

An exchanger for medical use comprises: a box-like body having a base, an upper end, a peripheral wall that delimits a heat exchange chamber; the body having: a first aperture from which a fluid to be thermo-regulated enters and a first exit of the thermo-regulated fluid; a second delivery aperture of a thermo-regulator fluid and a second exit of the thermo-regulated fluid; a heat exchange element that exchanges heat by lapping, housed in the exchange chamber and held between two holding elements, dividing the exchange chamber into a zone where the thermo-regulator fluid flows and a zone where the fluid to be thermo-regulated flows, which are fluid-dynamically separated from each other; a collection compartment to collect the air separated from the fluid to be thermo-regulated, obtained in the opposite end, connected to the thermo-regulation chamber and equipped with an aperture toward the outside; the box-like body has a second housing chamber for a pumping group, connected with the heat exchange chamber.

An exchanger for medical use comprises: a box-like body having a base, an upper end, a peripheral wall that delimits a heat exchange chamber; the body having: a first aperture from which a fluid to be thermo-regulated enters and a first exit of the thermo-regulated fluid; a second delivery aperture of a thermo-regulator fluid and a second exit of the thermo-regulated fluid; a heat exchange element that exchanges heat by lapping, housed in the exchange chamber and held between two holding elements, dividing the exchange chamber into a zone where the thermo-regulator fluid flows and a zone where the fluid to be thermo-regulated flows, which are fluid-dynamically separated from each other; a collection compartment to collect the air separated from the fluid to be thermo-regulated, obtained in the opposite end, connected to the thermo-regulation chamber and equipped with an aperture toward the outside; the box-like body has a second housing chamber for a pumping group, connected with the heat exchange chamber.

This document describes stepper motor drive systems. The stepper motor drive systems can be used in many different applications including, for example, to drive a stepper motor of an occluder device in association with a heart-lung machine.

An assembly with a blood pump and a control unit to control the flow rate at the blood pump includes a device that is designed to deliver a parameter of the breathing cycle or a parameter associated with the breathing cycle. In this way, it is also made possible for a parameter that correlates to the breathing cycle to be used to control the blood pump, in order to proactively prevent problems associated with the drainage.

The present disclosure provides systems and methods for controlling gas-enrichment, e.g., oxygen-enrichment, therapy. One or more sensors and/or one or more imaging systems may be used to measure or determine one or more physiological parameters of the patient. Feedback regarding one or more physiological parameters or microvascular resistance may be provided for titrating or controlling the gas-enrichment therapy.