A pressure measuring device 30 installs on a tube 11 for transferring a medium BL so as to measure a pressure of the medium BL inside the tube 11. The pressure measuring device 30 includes a main body portion 31 mountable to the tube 11, polarizing means 34 disposed in the main body portion 31 so that light oscillating in a specific direction is transmitted therethrough, an image acquisition unit 32 disposed in the main body portion 31 so that image information on a pressure receiver that is deformed in response to the received pressure is acquired through the polarizing means 34, and a control unit 100 that converts the image information acquired by the image acquisition unit 32 into pressure information about the pressure.

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.

The present disclosure relates to various aspects of a procedure for reducing the carbon dioxide content in blood during the treatment of patients. A first aspect of the present disclosure relates to a buffer solution for use in reducing the carbon dioxide content in the blood when treating a patient suffering from pulmonary insufficiency or the complete failure of lung function, wherein the fluid is in gas exchange with a portion of the patient's blood conducted through an extracorporeal circuit. The first aspect of the present disclosure further relates to an apparatus for the extracorporeal reduction of the carbon dioxide content in the blood using said buffer solution. A second aspect of the present disclosure relates to a system for extracorporeal blood treatment, likewise using said buffer solution and the apparatus, and furthermore to a treatment apparatus for extracorporeal blood treatment comprising the aforementioned system. A third aspect of the present disclosure relates to a functional unit for performing extracorporeal blood treatment, a blood-guiding apparatus for interacting with the functional unit for performing an extracorporeal blood treatment using the aforementioned buffer solution, which comprises a blood treatment element, wherein the blood treatment element is the aforementioned apparatus for the extracorporeal reduction of the carbon dioxide content in the blood. In a fourth aspect, the present disclosure relates to a treatment system comprising the aforementioned apparatus for the extracorporeal reduction of the carbon dioxide content in blood as well as a balancing device. In a fifth aspect, the present disclosure relates to a treatment system comprising the aforementioned apparatus for the extracorporeal reduction of the carbon dioxide content in blood as well as a means for reducing the pressure of the aforementioned buffer solution used in said treatment system.

An oxygen supply unit for use with a blood oxygenator comprises an oxygen concentrator and a carbon dioxide scrubber. In an on-line operational mode, oxygen-rich gas from the oxygen concentrator is predominantly supplied to the blood oxygenator with a reduced flow of recycled gas from the concentrator. In an off-line operational mode where the oxygen supply unit is being powered by battery only, a larger flow of recycled gas from the blood oxygenator is passed through the carbon dioxide scrubber and combined with a lesser amount of oxygen-rich gas from the oxygen concentrator. The oxygen supply unit may be used in combination with a blood pump and oxygenator to provide ambulatory blood oxygenation to patients with compromised lung function.

A device for extracorporeal blood circulation includes a potted body having an oxygenator module including at least two of a plurality of circular hollow fiber mat layers, a heat exchanger module including at least two of the plurality of circular hollow fiber mat layers, a blood inlet port adjacent a first end of the potted body and a blood outlet port adjacent a second end of the potted body. The device includes a gas inlet and outlet port and a fluid inlet and outlet port. A first of the plurality of hollow fiber mats includes a plurality of hollow fibers aligned in a direction that is angled relative to a direction of alignment of the plurality of hollow fibers of a second of the plurality of hollow fiber mats and, the plurality of hollow fiber mats are aligned to have the same orientation as one another.

Extracorporeal life support (ECLS) systems, devices and methods wherein a portable ECLS device is used to deliver cardiovascular support to a humans or animal patient (or harvested organ(s)) during pre-hospital or inter-hospital transport.

An integrated on-line monitoring and thermostatic heating apparatus for a bioartificial liver device, the apparatus including a blood inlet, a blood pump, an arterial drip chamber, a bioreactor module, a venous drip chamber, and a blood reinfusion port which are connected in sequence. The bioreactor module includes a thermostatic water tank and a bioreactor disposed in the thermostatic water tank. The bioreactor includes a container, and a first partition and a second partition which are disposed in the container. The first partition and the second partition separate the container into three independent parts, that is, a plasma separator, an oxygenator, and a reactor. The plasma separator and the oxygenator are connected through an external connection pipe. The external connection pipe is equipped with a separation pump. The second partition includes a communication hole, and the reactor and the oxygenator are connected through the communication hole.

A blood pump is disclosed. The blood pump apparatus is arranged to provide pulsatile flow, and comprises a flexible inner cylindrical duct providing a blood flow region, and an outer cylindrical duct arranged to surround the inner cylindrical duct and arranged to accommodate a pumping fluid. In the pump the inner cylindrical duct is described as comprising a blood inlet for receiving blood into the region, a blood outlet for passing blood out from the blood flow region and a passageway therebetween. There is also described the feature of the inner duct comprising a non return valve at the blood inlet and a non return valve at the blood outlet, the outer cylindrical duct having a fluid port for a pumping fluid, and a pump device arranged to cyclically deliver and withdraw pumping fluid to the fluid port thereby cyclically compressing and expanding the flexible inner cylindrical duct urging blood through the blood flow region and delivering a pulsating blood flow through the blood outlet.

A bioartificial liver device including a bioreaction chamber having a plurality of semi-permeable membranes and a plurality of filter spaces each confined by two adjacent semi-permeable membranes; a plurality of liver cell perfusion ports each communicating with one of the filter spaces for introducing the liver cells into the filter spaces, and a positive peristaltic pump. In the device, the semi-permeable membranes are disposed substantially horizontal with respect to the ground, and the positive peristaltic pump is adapted to drive the plasma flow from the bottom wall of the device to the top wall. The device of the invention improves the cell loading and the area for substance exchange between the blood and the liver cells.

A catheter system with two lumens (e.g., a major lumen and a minor lumen) that can be inserted peripherally into the left heart. The major lumen is used for venting, or blood volume removal, and the minor lumen is used to deliver a treatment substance directly to the left heart. In particular, the minor lumen can be used to deliver an anticoagulation medication directly to the left ventricle. The major lumen can be incorporated into an ECMO system.