The device for blood oxygenation includes a gas exchange chamber with passage openings. One side the chamber is connected in a gas-tight manner with the expansion tank feeding the gas mixture containing oxygen to the chamber, having the inlet opening of gas mixture from the feeding installation. The other side of the chamber is connected in a gas-tight manner with the gas mixture discharging tank, having the outlet opening of gas mixture. The inner part of the chamber has a membrane as a capillary bundle permeable to gas mixture particles and non-permeable to blood particles, ends of which are anchored in the passage openings. The capillary bundle is tensed with a tension force and is parallel to the longitudinal axis of the chamber and to each other, or are arranged spirally. The side wall of the chamber has at least one inlet/outlet opening.

The invention relates to a blood treatment device for carrying out an extracorporeal blood treatment in which blood is guided in a blood guidance device having a main blood line and at least one secondary line, the latter being fluidically connected to the main blood line and the main blood line having a dialyzer and, downstream from the dialyzer, a blood treatment element, wherein the blood treatment device has a control device; and a pump configuration, which is equipped for generating blood flows in the main blood line and also in the at least one secondary line, wherein the control device is designed to operate the pump configuration in such a way that a first blood flow rate in the dialyzer is decoupled from a second blood flow rate in the blood treatment element. Furthermore, the invention relates to a blood guidance device for cooperation with the blood treatment device as well as for a blood treatment system.

The present invention relates to a system (100) for extracorporeal blood treatment comprising a first inlet (1) for introducing a bloodstream to be treated into the system (100), three blood treatment apparatus (A, D, G), as well as an outlet (2) for discharging a treated bloodstream from the system (100), wherein the system comprises an adsorber apparatus (A) and/or a plasma separator apparatus, a dialysis apparatus (D) and a gas exchange apparatus (G), and wherein the three blood treatment apparatus (A, D, G) are sequentially connected in series in a functional state of system (100) application between the inlet (1) and the outlet (2) of the system relative to a direction of blood flow of a bloodstream to be treated and can be consecutively perfused extracorporeally by a bloodstream to be treated. The present invention further relates to a treatment apparatus comprising such a system, a kit comprising the components of such a system, a method for operating such a system (100) as well as a method for extracorporeal blood treatment with such a system (100).

Adaptors, cannulas, caps, tube couplers, and systems thereof provide endovascular access through an established ECLS system. Adaptors having curved or angled shafts navigate right angle side ports of standard bypass cannulas and permit hemostatic introduction and direction of an intervention device to the axial flow path of the cannula lumen and bypass system. A modified cannula having an angled side port is also provided for use as an arterial cannula. A cap having an occluding surface may be inserted into the angled side port to prevent blood from stagnating in the angled side port. A tube coupler is also provided having an access port, such as an angled access port, and may be spliced into an established bypass system for vascular access point. Multiple couplers can be used to provide multiple access points. The adaptors and occlusive cap are interchangeable with each other and with secondary circuits.

Disclosed herein are rolled-membrane microfluidic diffusion devices and corresponding methods of manufacture. Also disclosed herein are three-dimensionally printed microfluidic devices and corresponding methods of manufacture. Optionally, the disclosed microfluidic devices can function as artificial lung devices.

A portable medical apparatus for cardiopulmonary aid to patients includes a transportable machine body that integrates an heater/cooler unit and an extracorporeal circuit for circulating the blood of a patient. The extracorporeal circuit includes a line for drawing venous blood from the patient, a line for returning arterial blood to the patient, a pumping unit for pumping blood along the extracorporeal circuit, a heat exchanger for thermoregulating blood in the extracorporeal circuit, and an oxygenator unit for blood oxygenation.

The present disclosure relates to extracorporeal blood circuits used for gas exchange in blood, in particular circuits for cardiopulmonary bypass.

A cannula for the circulation of a fluid in an artery, includes a main lumen conveying a volume of fluid towards a first distal end; an accessory lumen including at least one inner portion arranged inside the main lumen, including: a proximal end situated downstream from the proximal end of the main lumen so as to capture a fraction of the flow of fluid entering the main lumen; a bent portion modifying the direction of flow of the fluid flow captured by the accessory lumen with respect to the direction of flow of the fluid emerging from the first end; a second distal end situated upstream from the first distal end of the main lumen, emerging on a side opening of the cannula so as to direct the captured fraction of liquid in the modified direction of flow.

Excess water can be removed from blood by passing the blood through channels that are surrounded by nanotubes with spaces therebetween. Each channel is wide enough for blood to flow through, and the nanotubes are spaced close enough to each other to retain the blood within the channels. Gas passing through the spaces between the nanotubes outside the channels comes into contact with the blood at the outer boundaries of the channels, and the excess water in the blood evaporates into the gas. In other embodiments, an undesirable molecule (e.g., ammonia) can be removed from blood by passing the blood through channels that are surrounded by nanotubes with spaces therebetween. Gas passing through the spaces between the nanotubes outside the channels comes into contact with the blood at the outer boundaries of the channels, and the undesirable molecule in the blood diffuses into the gas.

A molecule can be removed from blood by passing the blood through channels that are surrounded by nanotubes with spaces therebetween. Each channel is wide enough for blood to flow through, and the nanotubes are spaced close enough to each other to retain the blood within the channels. Gas passing through the spaces between the nanotubes outside the channels comes into contact with the blood at the outer boundaries of the channels, and the molecule in the blood diffuses into the gas. In other embodiments, a molecule can be introduced into blood by passing the blood through channels that are surrounded by nanotubes with spaces therebetween. Gas that includes the molecule passes through the spaces between the nanotubes outside the channels. The gas comes into contact with the blood at the outer boundaries of the channels, and the molecule in the gas diffuses into the blood.