The invention relates to an oxygenator with a housing wall, defining a housing chamber with a blood inlet and a blood outlet, a gas inlet and a gas outlet, and also with a heating element which is arranged in the oxygenator between the blood inlet and blood outlet in order to control the temperature of the blood flowing through the housing chamber. The oxygenator also comprises an electric connection and the heating element has an electric resistor which is designed as a wire. The invention also relates to a method for controlling the heat emission at the heating element of an oxygenator by measuring the flow of blood through the oxygenator and the power of a pump influencing the flow, with the heating power being adjusted in accordance therewith.

A dual lumen drainage cannula configured for use in a VA ECMO system includes a first drainage tube having a proximal end, a distal end, and at least one aperture in at least one wall of the first drainage tube proximate to the distal end of the first drainage tube, and a second drainage tube having a proximal end, a distal end, and at least one aperture in at least one wall of the second drainage tube proximate to the distal end of the second drainage tube. The first drainage tube passes through the second drainage tube. The dual lumen drainage cannula also includes a sleeve positioned adjacent to an interior wall of the second drainage tube. The sleeve is formed of a flexible material so as to be expandable and collapsible within the second drainage tube.

The device of the present invention includes a dual chamber gas exchanger that is configured for increased flexibility and scalability for many clinical applications. The dual chamber oxygenator can be configured and used in various applications, such as in a heart-lung machine for cardiopulmonary support during cardiothoracic surgery, in an extracorporeal membrane oxygenation (ECMO) circuitry, as a respiratory assist device for patients with lung failure, and the like. The dual chamber gas exchanger features two sweep gas flow paths and two gas exchange membrane bundles enclosed in a housing structure with various blood flow distribution and gas distribution mechanisms. The gas exchanger includes an outer housing, an intermediate housing, two gas exchange fiber bundles, a blood inlet, a blood outlet, two gas inlets, two gas outlets, two gas distribution chambers and an optional heat exchanger.

The present disclosure relates to a diffusion device, such as a blood oxygenator or gas exchanger, having improved flow characteristics.

A blood treatment method is described that is adapted to at least partially eliminate the carbon dioxide content of the type comprising a step of drawing a blood flow. Advantageously according to the invention, the method further comprises the steps of: acidifying the blood flow with transformation of the related blood bicarbonate content into gaseous carbon dioxide; and eliminating the gaseous carbon dioxide content by means of a pressure gradient.

The invention relates to a container in the form of a bag having a flexible bag wall at least in a region, in which a first and a second hollow channel section, pass through the bag wall in a fluid-tight manner, wherein the hollow channel sections respectively have an open channel end that is located within the container for connecting the open channel ends to one another in a separable and fluid-tight manner.

The present disclosure provides a system for oxygenating blood. The system may include an implantable blood pump that may draw a supply of blood from the circulatory system of a mammalian subject, such as a human being. The blood pump may provide the supply of blood to an adaptor, where the supply of blood may be supplied to either or both of a first branch or second branch. The first branch may lead to an external blood oxygenator. The oxygenator may oxygenate the blood, and the blood may be returned to the circulatory system of the mammalian subject. The second branch may bypass the oxygenator and may connect to the circulatory system of the mammalian subject. In this regard, while the blood is supplied to the second branch, the oxygenator may be disconnected and blood may be prevented from entering the first branch.

Distributed liquid-flow systems—in which flow spreads out from a system inlet and traverses the system through multiple discrete, smaller flow channels—are constructed to minimize variations in flow-resistance-induced pressure drop from the system inlet to entrances to the flow channels. Because flow-driving pressure will be more uniform at the entrances to the flow channels, flow along the channels will be more uniform. Disclosed embodiments may be particularly suitable or advantageous for use in gas-exchange/artificial lung devices.

An arrangement and a method for cardiopulmonary bypass is provided. The arrangement includes a reservoir configured to receive blood from the cardiotomy of a patient. An oxygenator receives the blood from the reservoir. An arterial connection is connected to the patient for supplying the blood from the oxygenator. A pump is provided for pumping the blood through the oxygenator to the arterial connection and the patient. The arrangement includes a supply device including a supply conduit attached to the reservoir. The supply device supplies a displacing gas to the reservoir via the supply conduit.

An extracorporeal blood circulation management device having an oxygenator accurately determines oxygen consumption by the target person and oxygen delivery by the oxygenator. Oxygenation-related parameter values in the blood are determined at regular intervals. An in-body passing time (a cycle time for a particular volume of blood to pass from input sensors to output sensors) is determined. Parameter values separated by the in-body passing time are selected as comparison targets to evaluate oxygenation consumption of the target person. An oxygenator unit passing time is determined. Parameter values separated by the oxygenator unit passing time are selected as comparison targets to evaluate oxygenation delivery of the oxygenation unit.