A polysulfone-urethane copolymer is disclosed, which can be used as a membrane polymer, e.g., a matrix polymer, a pore forming agent, or both, while enhancing a membrane's blood compatibility. Methods are disclosed for forming the copolymer and incorporating the copolymer in membranes (e.g., spun hollow fibers, flat membranes) and other products.

A system and method for reducing gas bubbles, including gaseous microemboli (GME) during cardiopulmonary bypass (CPB) by the use of an oxygenator with venous blood bypass and a filter in the venous blood bypass is provided.

A method controls a device for extracorporeal blood gas exchange. The device has a membrane as a gas-liquid barrier between a bloodstream and a gas stream. The membrane further makes possible a passing over of the carbon dioxide content from the bloodstream into the gas stream. The device has at least one actuator. A change in a value of an operating parameter of the actuator brings about a change in a value of the carbon dioxide content that passes over from the bloodstream into the gas stream. The method further includes providing breathing gas information that indicates a carbon dioxide concentration in breathing gas and providing a control signal, which indicates a request for setting a value of the operating parameter and changing of the value of the operating parameter as a function of the carbon dioxide concentration in the breathing gas.

A gas delivery device includes a nitric oxide generating system. The system has a medium including a source of nitrite ions. A working electrode is in contact with the medium. A Cu(II)-ligand complex is in contact with the working electrode. A reference/counter electrode is, or a reference electrode and a counter electrode are in contact with the medium and separated from the working electrode. An inlet conduit is to deliver nitrogen gas to the medium, and an outlet conduit is to transport a stream of nitrogen gas and nitric oxide from the medium. An inspiratory gas conduit is operatively connected to the outlet conduit to introduce an oxygen-containing gas and form an output gas stream of the gas delivery device.

The present invention is directed to a dual lumen cannula configured to be inserted into a patient's body as simple as a single lumen cannula. The dual lumen cannula includes at least one inner lumen configured to be inserted into an outer lumen and connected via an inner lumen connection unit and an outer unit connection unit. Embodiments of the presenting invention further allow for the connection of at least one flow router to the other end of the inner lumen connection unit. When installed, the outer lumen is first inserted into the patient's body, followed by the insertion of the inner lumen into the outer lumen of the already cannulated patient until the inner lumen connector unit is in coupling contact with the outer lumen connector unit. The invention is also directed to a transformable dual lumen cannula into a single lumen cannula and vice versa that allow patients that are first being treated by low flow approach to be treated by high flow approach.

A winding system for winding up concatenated hollow fibers onto a winding core includes a winding core of a device for the mass transfer and/or heat exchange between two media and which winding core is to be inserted together with the hollow fibers wound thereon, into the housing of the device and to remain therein, and at least one coupling element, preferably two coupling elements, wherein the at least one coupling element has two axially opposing connecting regions and is temporarily connectable, by means of the first connecting region, to the winding core for conjoint rotation therewith, and is temporarily connectable, by means of the second connecting region, with a drive for conjoint rotation therewith, the drive being provided for the rotation of the winding core about a winding axis.

An extracorporeal blood treatment module includes a plurality of gas transfer units, having a first polymer layer with a plurality of gas channels, a second polymer layer with a plurality of blood channels, and a gas permeable membrane disposed between the plurality of gas channels and the plurality of blood channels, a fluid transfer unit integrated with the plurality of gas transfer units, and including a third polymer layer having a plurality of fluid collection channels, a fourth polymer layer having a plurality of blood channels, and a fluid permeable membrane disposed between the plurality of fluid collection channels and the plurality of blood channels, and a housing containing the plurality of gas transfer units and fluid transfer unit.

A device for the rapid attachment of biomedical devices, comprising: at least one base element associable with a supporting plane and defining a guiding seat extending along a sliding direction, the guiding seat being intended to receive by shifting an anchoring element associable with one or more biomedical devices; removable attachment device/component (or the like) of the base element to the supporting plane; removable locking device/component (or the like) of the anchoring element associated with the base element, the locking device/component locking the anchoring element with respect to the base element along the sliding direction upon reaching a predefined anchoring position.

Provided are methods and arrangements wherein gases are removed via semipermeable membranes from aqueous, optionally complex biological substance mixtures, by dialysis in an aqueous medium. Special carrier molecules for gases are included in the dialysate that are regenerated in the dialysate circuit so that they can be used for further gas exchange cycles on the membrane.

A system including tubing and a filter configured to be fluidly coupled to a vacuum source and to a heater/cooler unit by the tubing. The filter includes a filter container having negative air pressure in the filter container provided by the vacuum source to pull aerosol from the heater/cooler unit into the filter container and eliminate and/or reduce the aerosol emitted from the heater/cooler unit.