Systems and methods for cleaning and disinfecting a medical therapy device that delivers any one of hemodialysis, hemodiafiltration and hemofiltration. The system has a base module that has at least one segment of a controlled compliant flow path and at least one pair of jumpered ports configured on the base module. One or more components have connections connectable to the jumpered ports of the base module to provide for fluid communication between the segment of the controlled compliant flow path in the base module and a flow path defined by the one or more components. The base module is connected to the one or more components that define a flow path configurable for carrying out in part at least one function performed during any one of hemodialysis, hemodiafiltration or hemofiltration.

A photopheresis system (200) is disclosed, and that may be configured to execute one or more protocols. These protocols include: 1) protocols (400; 430; 460) for purging air out of a centrifuge bowl (210) used by the photopheresis system (200); 2) protocols (500; 510 550) for assessing the installation/operation of one or more pressure domes (330) used by the photopheresis system (200); and 3) protocols (580; 600; 660; 700; 740) for collecting buffy coat from blood processed by the photopheresis system (200).

A nested syringe comprising: a first chamber comprising: an inner tube extending from a base of the first chamber and defining a base opening in the base; an adapter tube in fluid communication with the inner tube via the base opening; at least one base port in the base for providing fluid communication between the adaptor tube and a first inner volume of the first chamber; a second chamber, adapted for insertion into the first chamber wherein the second chamber comprises a third port adapted to provide fluid communication between the inner tube and a second inner volume of the second chamber and adapted for preventing fluid communication between the first inner volume and the second inner volume when the second chamber is inserted into the first chamber and the inner tube penetrates the third port; and a plunger, wherein the plunger is adapted for insertion into the second chamber.

A hemodialysis system is disclosed. The hemodialysis system includes a disposable set including a blood pumping tube, a fresh dialysate pumping tube, and a spent dialysate pumping tube. The hemodialysis system also includes a dialysis instrument including a blood pump head, a fresh dialysate pump head, a spent dialysate pump head, a first motor positioned and arranged to operate the blood pump head, a second motor positioned and arranged to operate the fresh dialysate pump head, and a third motor positioned and arranged to operate the spent dialysate pump head. When the disposable set is loaded into the dialysis instrument, the blood pumping tube comes into registry with the blood pump head, the fresh dialysate pumping tube comes into registry with the fresh dialysate pump head, and spent dialysate pumping tube comes into registry with the spent dialysate pump head.

The present invention relates to a method of removing blood from an extracorporeal blood circuit following termination of a blood treatment session, wherein blood is concurrently removed both from an arterial conduit portion and from a venous conduit portion of the extracorporeal blood circuit. It further relates to a method for recognizing and/or eliminating air inclusions in or from an extracorporeal blood circuit and a treatment apparatus as well as a tube system.

A photopheresis system (200) is disclosed, and that may be configured to execute one or more protocols. These protocols include: 1) protocols (400; 430; 460) for purging air out of a centrifuge bowl (210) used by the photopheresis system (200); 2) protocols (500; 510 550) for assessing the installation/operation of one or more pressure domes (330) used by the photopheresis system (200); and 3) protocols (580; 600; 660; 700; 740) for collecting buffy coat from blood processed by the photopheresis system (200).

A priming sensor for a medical fluid delivery device is disclosed. In an example, the priming sensor includes light emitters and a detector. The detector is configured to detect light emitted by the emitters that interacts with a patient tube connected to the priming sensor. A processor of a medical fluid delivery device causes the emitters to operate in a sweep pattern during a sweep period. The processor receives output data from the detector that is indicative of light detected during the sweep period. The processor creates an output waveform corresponding to the sweep period based on the output data and compares the output waveform to at least one reference waveform to determine one of (a) a no-tube state, (b) a dry tube state, or (c) a wet tube state. The processor provides an output indicative of the comparison for operation of the medical fluid delivery device.

A dialysis system may include a dialysis machine (e.g., a peritoneal dialysis machine or a hemodialysis machine) for transferring a liquid to a patient via tubing. The dialysis system may include an air management device for filtering out air content from the liquid prior to transferring to the patient. The air management device may be a connector cap for use in a peritoneal dialysis system during a priming process. Alternatively, the air management device may be a drip chamber for use in a hemodialysis system. The air management device may include a vent. In addition, the air management device may include a movable element for sealing the vent. In addition, and/or alternatively, the air management device may include a reservoir for receiving an overflow of liquid.

A method for venting a dialyzer which has a dialyzate chamber, a blood chamber and a semi-permeable dialyzer membrane separating these two chambers. An overpressure is generated in the dialyzate chamber with respect to the blood chamber for removing air inclusions lying at the surface of the membrane at the dialyzate chamber side after a filling of the dialyzate chamber and before a filling of the blood chamber.

A system for assisting a patient's heart has a pump, an oxygenator, a holder having a pump receiving portion for removably receiving the pump and an oxygenator receiving portion for removably receiving the oxygenator, and a harness configured to surround at least a portion of a patient's torso. The holder is connected to the harness. The system further has a brace connected to at least a portion of the harness. The brace is configured to extend behind a back portion of a user's head and to support tubing connected to at least one of the pump and the oxygenator. A priming tray and wet-to-wet connector connecting the cardiac assist system to the cannula so are also disclosed.