An extracorporeal blood filtering machine can include a blood circuit, an effluent circuit, and a source fluid circuit and can be controlled by a controller. The extracorporeal blood filtering machine can also include access ports for connecting the source fluid circuit to the blood circuit, as well as blood sensors to detect possible issues with the extracorporeal blood filtering machine. The extracorporeal blood filtering machine can include density sensors and flow sensors that enable it to be more accurate and to operate while being transported. The extracorporeal blood filtering machine can further include a user interface and can display fluid inflow/outflow information. A medical fluid container can automatically empty after being filled. An apparatus for supporting a medical fluid container can include a hanger and an attachment member with the apparatus able to adjust to ensure the medical fluid container remains properly oriented directly under a medical fluid container scale.

A combined bio-artificial liver support system, includes branch tubes that are connected in sequence: a blood input branch tube, an upstream tail end of which is set as a blood input end, a first plasma separation branch tube comprising at least a first plasma separator, a non-biological purification branch tube comprising at least a plasma perfusion device and a bilirubin adsorber, a biological purification branch tube comprising at least a hepatocyte culture cartridge assembly, and a plasma return branch tube, a downstream tail end of which is set as a blood output end.

A system and method for removing gas bubbles from fluid. An active filter apparatus forces the bubbles to the center of the filter, while a pump supplies fluid to the filter.

A system for detecting bubbles within a liquid flowing in an interior of a pipe. The system includes a transmitter emitting directed light through the liquid flowing through the pipe and a receiver for receiving the emitted directed light from the transmitter. The transmitter and receiver are affixed on opposite sides of the pipe. The system also includes a microcontroller having a modulator. The microcontroller communicates with the transmitter and receiver. The microcontroller sends a modulation protocol for emitting the directed light with a specified modulation protocol to the transmitter and receiver. The transmitter emits the directed light as modulated light based upon the modulation protocol and the receiver filters out all unmodulated light, correlates information on modulated light received from the transmitter and sends correlated light information to the microcontroller. The microcontroller determines a presence of bubbles in the liquid based on the light information received from the receiver.

In a system for extracorporeal membrane oxygenation including a blood pump and an oxygenator, the oxygenator includes fibrous mats stacked in a housing and arranged parallel to one another, and the blood pump includes a control unit that provides for a continuous variation of the volume of flow over time.

A blood purification apparatus that is capable of, with no preparatory operations, performing substitution by supplying dialysate in a dialysate introduction line to a blood circuit during ultrafiltration treatment, or performing blood return by immediately supplying the dialysate in the dialysate introduction line to the blood circuit after the ultrafiltration treatment. A blood purification apparatus includes a dialyzer, a dialysate introduction line, a dialysate drain line L2 through which drain liquid from the dialyzer is drained, and an ultrafiltration pump capable of removing water from the blood in the blood circuit. The blood purification apparatus is capable of performing substitution or blood return by supplying the dialysate in the dialysate introduction line L1 to the blood circuit. In an ultrafiltration treatment in which the ultrafiltration pump is activated while the introduction of the dialysate into the dialyzer is stopped, dialysate delivery is performed while the introduction of the dialysate into the dialyzer is prevented.

A multi-lumen sensing system (10) includes medical tubing (20) having a plurality of lumens (22A, 22B) and at least one secondary passageway (24) extending in an axial direction of the medical tubing, wherein the secondary passageway is between the plurality of lumens. The multi-lumen sensing system may include a sensing receptacle (30) defining a channel (32) in which a lengthwise portion of the medical tubing is received. A plurality of ultrasonic transmitting elements (40T, 42T) may be arranged within the secondary passageway of the medical tubing or as part of the sensing receptacle for transmitting respective ultrasonic signals across the lumens to a corresponding plurality of ultrasonic receiving elements (40R, 42R) of the sensing receptacle. Alternatively, the sensing receptacle may include a plurality of ultrasonic transmitting and receiving elements (40, 42, 44) transmitting respective signals across the lumens for return reflection at an interface of the secondary passageway.

A user interface for a machine for extracorporeal blood treatment comprises a touch screen and a controller programmed to display on a screen (16) a display in which two distinct areas are arranged, one of which (161) exhibits a series of touch keys (17). Activation of any one touch key (17) causes visualization of an image in a second area (162) of the screen. The images are displayed alternatively and are at least partly different one from another. Each touch key (17) is associated to an instruction, or to a group of instructions, all concerned with readying the machine for use. Each image is a pictograph of a configuration of the machine, correlated with an instruction associated to the touch key (17) selected. The operator is aided in making the machine ready for treatment.

A hemodialysis system configured to purge air from a blood circuit comprising: a dialyzer; a dialysis fluid circuit operable with the dialyzer via dialysis fluid inlet and outlet lines; the blood circuit operable with the dialyzer and including an arterial line, a venous line, a blood pump operable with the arterial line upstream of the dialyzer, and a physiologically acceptable fluid source in fluid communication with the arterial line upstream of the blood pump; and an air purging scheme wherein, with the dialysis fluid inlet and outlet lines connected to the dialyzer, air is purged using dialysis fluid or other physiologically acceptable fluid pumped by at least one of the fresh or used dialysis fluid pumps from the dialysis fluid circuit, through the dialyzer, into the blood circuit, in combination with dialysis fluid or other physiologically acceptable fluid from the source introduced directly into the blood circuit.

The present invention relates to an apparatus (1) for holding a disposable medical item, in particular a dialyzer (2), plasma filter or adsorbent, for treating blood, a system (10) comprising such an apparatus, and a method for operating a disposable medical item for treating blood. A bearing device (4) is thereby configured to rotatably support the disposable item, and a drive device (5) is thereby configured to rotate the rotatably mounted disposable item around a longitudinal axis (L) extending substantially in a direction in which the blood flows through the disposable item when the disposable item is in operation. Alternatively or additionally, a sensor device (6) is configured to detect a rotation of the rotatably mounted disposable item around at least one rotational axis (L, Q), in particular around the longitudinal axis (L) and/or around a transverse axis (Q) running perpendicular to the longitudinal axis (L) and output corresponding sensor data. A control device (5) is further configured to control the drive device (5) and/or process the sensor data output by the sensor device (6).