A container system configured to transfer heat to a fluid contained within the container system, such as dialysate. The container system may be configured to fluidly couple to a medical machine. The container system includes a flexible material comprising a wall of the container system. In examples, the flexible material defines a container volume configured to contain the fluid. The flexible material mechanically supports a circuit configured to generate and transfer heat to the fluid. The circuit is configured to flex and/or bend when the flexible material flexes and/or bends. In examples, the container system includes control circuitry configured to cause the circuit to generate heat based on a temperature of the fluid.

A system for preparing a medicament for use by a medicament user includes a proportioning machine with a controller and pumping and clamping actuators to engage a fluid circuit having pumping and clamping portions that engage with respective actuators of the proportioning machine. The fluid circuit includes a mixing container that is prefilled with concentrated medicament. The proportioning machine is configured to receive purified water and to mix it with the concentrated medicament to produce a medicament and to output the medicament to a medicament consumer in such a way that to the medicament consumer the medicament appears to be provided from a bag of medicament.

A blood circuit assembly for a dialysis unit may include an organizing tray, a pair of pneumatic pumps mounted to the organizing tray for circulating blood received from a patient through a circuit including a dialyzer unit and returned to the patient, an air trap mounted to the organizing tray arranged to remove air from blood circulating in the circuit, a pair of dialyzer connections arranged to connect to the inlet and outlet of a dialyzer unit, and a pair of blood line connectors, one inlet blood line connector for receiving blood from the patient and providing blood to the pneumatic pumps and the other outlet blood line connector for returning blood to the patient.

This dialysis device is configured so that residual liquid in a powder container 42 and a bypass path 51 can be drained. Accordingly, the dialysis device is provided with: a first liquid draining path 71 connecting a clean water supply path 31 to a stock solution supply path 44 on the upstream side of a liquid feed pump 33; a second liquid draining path 72 connecting the clean water supply path to a dialysate discharge path 32 on the downstream side of the liquid feed pump; and an opening path 77 allowing a branch path 43 to communicate with the outer space by opening an on-off valve 78. By opening the on-off valve of the opening path and actuating the liquid feed pump, a liquid in the powder container 42 and a liquid in the bypass path 51 can be discharged through the first liquid draining path and the second liquid draining path.

A dialysis machine (e.g., a peritoneal dialysis (PD) machine) can include a safety feature that enables the dialysis machine to automatically identify the connections made by a user in preparation for treatment. A smart connector is disclosed that uses a split RFID device that is operational when a first portion of the connector is mated to a second portion of the connector, and is not operational when the first portion is disconnected from the second portion. In an embodiment, the split RFID device incorporates an RFID chip in the first portion of the connector and an antenna in the second portion of the connector. In an embodiment, the RFID chip can store a tag that encodes information that indicates a formulation or a volume of a dialysis bag connected to the ports of a disposable cassette such that the dialysis machine can automatically discover the configuration of the dialysis setup.

Various sorbent cartridges for use in sorbent dialysis are constructed to allow even dialysate stream flow through the sorbent cartridges, at relatively high flow rates, with sufficient engagement with sorbent media within the sorbent cartridges and without creating drill-through problems. The sorbent cartridges may have various columns and/or compartments for housing the sorbent media. The sorbent cartridges may have various horizontally oriented restrictors, with particularly sized holes, and with various vertically oriented side walls, that both form the various columns and/or compartments and that direct and control the dialysate stream through the sorbent cartridges in an even manner.

The present invention relates to an apparatus for preparing a dialysis solution, wherein the apparatus has a dialyzate line for conducting a dialysis solution and has means that are configured to discontinuously convey a dialysis solution in the dialyzate line, wherein the apparatus has a conductivity sensor that is arranged to measure the conductivity of the dialysis solution, and wherein the apparatus has a concentrate line opening into the dialyzate line upstream of the conductivity sensor at an addition point and having a concentrate pump and has a concentrate container from which the concentrate pump conveys concentrate into the concentrate line and from this into the dialyzate line, characterized in that the apparatus has a controller that is connected to the conductivity sensor and to the concentrate pump and that is configured to control the concentrate pump such that the conductivity fluctuations over time in the dialysis solution downstream of the addition point are reduced with respect to a continuous concentrate conveying.

Fluid channel sealing devices, frangible seals, fluid circuits, associated controllers and methods of using the same are provided for controlling fluid distribution using a reconfigurable blocking element having first and second portions to establish a first configuration free of any open channels such that fluid is prevented from flowing through the channel and a second configuration where the first and second portions are separated to establish an open channel and allow fluid to pass.

Dialysis systems for operating dialysis machines (e.g., peritoneal dialysis machines) for conducting dialysis treatments are disclosed. The dialysis system may include a spent dialysate container for receiving spent dialysate from a patient. In use, the spent dialysate containers are arranged and configured to provide one or more mechanical advantages to ease disposal of the spent dialysate. For example, the spent dialysate container may receive the spent dialysate from the patient and enable the patient or caregiver to dispose of the spent dialysate without requiring the patient or caregiver to lift bags of spent dialysate or incorporate lengthy drain lines. The spent dialysate container may include a reservoir to receive the spent dialysate, wheels to enable the patient or caregiver to transport the reservoir, mechanisms to facilitate disposal of the spent dialysate from the reservoir, a nozzle to dispose of the spent dialysate, and/or a disinfectant to disinfect the drain.

A medical fluid generation system is disclosed. In an example, a peritoneal dialysis fluid generation system includes water purification equipment configured to provide purified water; a presterilized tubing set including a container for storing peritoneal dialysis fluid; at least one glucose or buffer concentrate; and a hemodialysis machine in fluid communication with the water purification equipment. The hemodialysis machine includes at least one mixing pump for mixing the at least one glucose or buffer concentrate with the purified water to form peritoneal dialysis fluid, a dialysis fluid pump for delivering the peritoneal dialysis fluid to the container, and a control unit configured to control the at least one mixing pump to form the peritoneal dialysis fluid and the dialysis fluid pump to deliver the peritoneal dialysis fluid to the container.