The present disclosure discloses an integrated membrane oxygenator including an oxygenator and a filter attached to the oxygenator. The oxygenator may include an upper cover, a lower cover, a shell, and an oxygenation structure. Two ends of the filter may be respectively connected with the upper cover and the lower cover. The oxygenation structure may include a mandrel, an oxygen pressure membrane, and a temperature-changing membrane arranged inside the shell. The filter may include a filter shell, a diversion structure, and a filter screen arranged inside the filter shell. An inlet of the filter shell may be connected with a blood outlet on the lower cover of the oxygenator, and blood oxygenated by the oxygenator may directly enter the filter for filtration.

The embodiments of the present disclosure may provide a membrane oxygenator with a built-in filter, including an upper cover, a lower cover, a shell and an oxygenation structure, wherein two ends of the shell may be respectively connected to the upper cover and the lower cover, and the oxygenation structure may be disposed in the shell, including a mandrel, a filter screen, an oxygen pressure membrane, and a temperature-changing membrane in turn from a center to an outside. The blood may flow in from an upper blood inlet of the membrane oxygenator, traverse the temperature-changing membrane, oxygen pressure membrane and filter screen in turn, and then flow out from a blood outlet under the mandrel. During a process of traversing, a flow rate of the blood may gradually slow down, and the blood may fully contact the oxygen pressure membrane and the filter screen.

A perfusion apparatus includes a reservoir and a perfusion-liquid feeding path that feeds a perfusion liquid from the reservoir to an organ. The perfusion-liquid feeding path includes a feeding pipe and a deaeration unit that is interposed in the feeding pipe and includes an air chamber and a deaeration pump. The deaeration pump is a roller tube pump in which a plurality of rollers squeeze a flexible gas pipe while rotating, to cause a flow of gas in the gas pipe, and discharges gas from a gas layer in an upper portion of the air chamber to outside. This makes it possible to discharge gas in the air chamber while keeping the perfusion-liquid feeding path hermetic. Therefore, it is possible to remove bubbles in the perfusion liquid fed to the organ without limiting the height of the organ and without stopping feeding the perfusion liquid to the organ.

A blood processing apparatus includes an optional heat exchanger and a gas exchanger disposed within a housing. In some instances, the gas exchanger can include a screen filter spirally wound into the gas exchanger such that blood passing through the gas exchanger passes through the screen filter and is filtered by the spirally wound screen filter a plurality of times.

This disclosure relates to dialysis systems and methods. In some implementations, a dialysis system includes a dialysis machine with a fluid line and a drain line, a blood line set configured to be connected to the dialysis machine, and a drain apparatus coupled to the dialysis machine. The drain apparatus includes a chamber configured to receive an end of a patient line of the blood line set, an inlet line, an outlet line, and a valve. The inlet line has a first end configured to be coupled to the chamber and a second end configured to be coupled to the fluid line of the dialysis machine. The outlet line has a first end configured to be coupled to the chamber and a second end configured to be coupled to the drain line of the dialysis machine. The valve is configured to control flow of fluid through the outlet line.

A dialysis fluid system includes a dialysis fluid inlet; a dialysis fluid outlet; a pump positioned and arranged to pump dialysis fluid through the dialysis fluid inlet and the dialysis fluid outlet; and an inductive heater located between the dialysis fluid inlet and the dialysis fluid outlet, the inductive heater including a fluid flowpath positioned and arranged to receive non-heated dialysis fluid from the dialysis fluid inlet and to output heated dialysis fluid to the a dialysis fluid outlet, a conductive heater element located within the fluid flowpath so as to be or act as a secondary coil of a transformer, and a primary coil of the transformer located outside of the fluid flowpath and positioned so as to magnetically induce a current into the conductive heater element, causing the conductive heater element and surrounding fluid to heat.

A hemodiafiltration system with a disposable pumping unit is disclosed. An example system includes a medical fluid pump actuator, a medical fluid heater, a blood filter and a disposable unit. The example disposable unit includes a medical fluid cassette portion including a medical fluid cassette housing configured to be operatively connected to the medical fluid pump actuator to pump medical fluid through the medical fluid cassette portion when the medical fluid cassette portion is in fluid communication with a medical fluid source. The example medical fluid cassette portion is also configured to be placed in fluid communication with the blood filter and with an extracorporeal circuit communicating with the blood filter, the fluid communication enabling hemodiafiltration to be performed. The example disposable unit also includes a heater bag configured to be placed in operable communication with the medical fluid heater and in fluid communication with the medical fluid cassette portion.

An extracorporeal blood treatment apparatus comprises: a blood treatment device; an extracorporeal blood circuit comprising a blood withdrawal line and a blood return line coupled to the extracorporeal blood treatment device, wherein the blood return line presents a heating zone coupled or configured to be coupled to a blood warmer; a blood pump configured to be coupled to a pump section of the blood withdrawal line; at least a post-infusion line connected to the blood return line upstream of the heating zone; an air trapping device placed on the blood return line upstream of the heating zone.

An extracorporeal circulation apparatus has a blood reservoir temporarily storing blood and a presence information acquisition unit to detect presence or absence of blood at respective wall locations in a two-dimensional array. A control unit determines the position of a blood surface on the basis of consecutive elements in the array having detected blood along at least one of a first direction parallel to the blood surface and a second direction perpendicular to the blood surface.

Devices and methods for enhancing the operations of fluid systems are provided. For example, this document provides variable-elevation drop tubes that are well suited for use with medical fluid reservoirs. While the variable-elevation drop tubes provided herein are described in the context of a medical fluid system, such as an extracorporeal blood flow circuit, it should be understood that the devices and methods provided herein are not limited to such contexts.