The described invention is a hyperthermia and hyperoxygenation medical apparatus for treating diseases of the blood and purification of stored blood supplies. The invention comprises a hollow chamber through which blood is made to flow. Within the hollow chamber are a heating element and a gas diffuser. As blood flows through the chamber, blood is heated to a preset limit while ozone or other beneficial gas is diffused into the blood by a diffuser with pores to a preset concentration. After heating and gasification, blood exits the hollow chamber and is either returned to the patient or returned to storage. The hollow chamber, heating element and gas diffuser are designed to maintain efficient, linear blood flow through the invention, in part by taking advantage of die radial symmetry of the hollow chamber and diffuser designs. Linear flow ensures uniform and controlled heating and gasification of the blood with negligible undesirable turbulence to the blood components.

The present disclosure relates to a hemodialysis catheter that can monitor intravascular pressure using a MEMS sensor. The hemodialysis catheter comprises a venous lumen, an atrial lumen, and at least one MEMS system sensor. The hemodialysis catheter also comprises a data acquisition and processing system. The hemodialysis catheter can communicate with a monitor system to display pressure data.

A bi-directional perfusion cannula is provided that includes an elongate tube for insertion into an artery. The elongate tube has a first aperture at a distal end of the tube which is forward during insertion and configured so that blood can flow into the artery in the direction of insertion, an elbow formed in the elongate tube, and a second aperture formed in or slightly rearward of the elbow and configured for supplying blood into the artery in a second direction which is generally opposite to the insertion direction.

A method for collecting plasma includes determining the weight and hematocrit of a donor, and inserting a venous-access device into the donor. The method then withdraws blood from the donor through a draw line connected to a blood component separation device, and introduces anticoagulant into the withdrawn blood. The blood component separation device separates the blood into a plasma component and a second blood component, and the plasma component is collected from the blood component separation device and into a plasma collection container. The method may then calculate (1) a percentage of anticoagulant in the collected plasma component, and (2) a volume of pure plasma collected within the plasma collection container. The volume of pure plasma may be based, at least in part, on the calculated percentage of anticoagulant. The method may continue until a target volume of pure plasma is collected within the plasma collection container.

A flow path cassette includes superimposed first and second flexible sheets, where a plurality of flow paths are disposed therebetween and detection channel portions are disposed at one or more points along one or more of the plurality the flow paths. Each of the detection channel portions includes a first bulging portion and an opposing second bulging portion. A plate member is aligned with the second bulging portion, and a deformation preventative member is aligned with the first bulging portion. The plate member may move with the second bulging portion, while the deformation preventative member prevents deformation of the first bulging portion.

A fluid diverting device for an apparatus for extracorporeal treatment of blood is configured to be placed in-line between a main portion (22) of the apparatus (1) and a vascular access of a patient (P) and comprises: a substantially H-shaped conduits assembly comprising a withdrawal conduit (23), a return conduit (24) and at least one bridging conduit (25, 125) connecting the withdrawal conduit (23) to the return conduit (24). The withdrawal conduit (23) is connectable upstream and downstream to a withdrawal line (6) of the apparatus (1), the return conduit (24) is connectable upstream and downstream to a return line (7) of the apparatus (1). A plurality of valves (26, 27, 28, 29, 30, 32) or distributors (201, 202) operate on the withdrawal conduit (23), on the return conduit (24) and on the at least one bridging conduit (25) and are configured to divert a flow of liquid and/or blood without disconnecting the patient (P).

A system for regulating blood flow in extracorporeal circulation, and including a blood reservoir to receive blood from a patient, an oxygenator to condition the blood, a centrifugal pump to pump the blood from the blood reservoir to the oxygenator and back to the patient, an electronic remote clamp to regulate flow of the blood, and a controller to operate in a flow control mode and a speed control mode. The controller includes an operational element to set a blood flow value in the flow control mode and to set a speed of the centrifugal pump in the speed control mode. The controller to automatically switch between the flow control mode and the speed control mode in response to one or more trigger conditions and to automatically switch between the speed control mode and the flow control mode in response to opening the electronic remote clamp.

A blood treatment device for extracorporeal blood treatment and a method for monitoring the fill level of blood with the blood treatment device. The device includes at least one blood conducting system and at least one chamber container for separating bubbles from the blood to be treated. The device further includes a blood pumping device designed to pump the blood and generate pressure pulses with a predefined frequency in the blood conducting system. The blood treatment device additionally has at least one pressure detection sensor for capturing the pressure pulse introduced by the blood pumping device and a data processing unit designed to derive a fill level parameter from the pressure pulse captured and to modify the state of an information signal as a function of the fill level parameter. At least one alarm device is activated as a function of the state of the information signal.

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 proximate its distal end and in fluid communication with the lumen of the first drainage tube, and a second drainage tube having a proximal end, a distal end, and at least one aperture defined proximate its distal end and in fluid communication with the lumen of the second drainage tube. The dual lumen drainage cannula further includes a flow restrictor disposed within the lumen of at least one of the first and second drainage tubes, configured to adjust the flow distribution of blood flow through the lumens of the first and second drainage tubes.

A medical wetness sensing device includes a base adapted to be disposed on a wearer of the medical wetness sensing device. The base includes a first electrical conductor and a second electrical conductor electrically insulated from the first electrical conductor. The first electrical conductor includes a hinge portion enabling a first portion of the first electrical conductor to deflect, at the hinge portion, relative to a second portion of the first electrical conductor. The medical wetness sensing device includes a controller electrically connected to the first electrical conductor and the second electrical conductor. The controller is configured to detect a presence or an absence of a medical fluid electrically connecting the first and second electrical conductors.