A device for monitoring and/or modifying a peritoneal dialysis treatment, including a memory which stores at least one treatment protocol; a control circuitry connected to the memory, wherein said control circuitry generates a report and/or modifies the treatment if an outcome of the treatment is not a desired outcome of the treatment protocol.

A fluid handling cassette, such as that useable with an automated peritoneal dialysis (APD) cycler device or other infusion apparatus, may include a generally planar body having at least one pump chamber formed as a depression in a first side of the body and a plurality of flowpaths for a fluid that includes a channel. A patient line port may be arranged for connection to a patient line and be in fluid communication with the at least one pump chamber via at least a first one of said flowpaths, and an optional membrane may be attached to the first side of the body over the at least one pump chamber. In one embodiment, the membrane may have a pump chamber portion with an unstressed shape that generally conforms to the depression of the at least one pump chamber in the body and is arranged to be movable for movement of the fluid in a useable space of the at least one pump chamber. One or more spacers may be provided in the at least one pump chamber to prevent the membrane from contacting an inner wall of the at least one pump chamber. The patient line, a drain line, and/or a heater bag line may be positioned to be separately occludable in relation to one or more solution lines that are connectable to the cassette.

A direct sodium removal (“DSR”) infusate regimen and methods of use are provided for removing sodium and reducing fluid overload in patients with severe renal dysfunction and/or heart failure, in which a patient has at least a first DSR session with a first DSR infusate having no or low sodium that is instilled into a patient's peritoneal cavity for a first dwell period to cause sodium and excess fluid to migrate to the patient's peritoneal cavity, and thereafter, the patient may undergo conventional dialysis to rebalance the patient's fluid and sodium levels.

A fluid delivery system includes a fluid pump; a pressure sensor for sensing pressure of fluid pumped by the fluid pump, wherein an output from the pressure sensor varies depending upon whether medical fluid or air is pumped during a pump stroke of the medical fluid pump; and a control unit configured to use the output from the pressure sensor to determine whether medical fluid or air is present during the pump stroke.

A leak detector is provided that is incorporated into the wheels of a moveable medical device and/or cart or cabinet therefor. By incorporating a leak detector into the wheels themselves of the movable medical device, the leak detector, despite movement of the medical device, is suitably located to locate leaks with respect to the medical device at all times and requires no additional setup. The leak detector can further be tested by and interface with the moveable medical device to ensure the leak detector is in working condition and provide a convenient interface for a user. Additionally, by using this technology on each of the multiple wheels of a moveable medical device, the detectable area may be bigger than a leak detector at only one location.

A peritoneal dialysis system includes a control unit is programmed to cause (i) a pressure sensor to take a first pressure reading of a reference chamber with a pneumatic valve closed, (ii) a pump actuator to pump fresh dialysis fluid through a fresh dialysis fluid pathway into a patient line expandable chamber, expanding the expandable chamber into a dome, (iii) the pneumatic valve to open, allowing the reference chamber to communicate pneumatically with any air in the dome, (iv) the pressure sensor to take a second pressure reading with the pneumatic valve open, (v) the first and second pressure readings to be used with the ideal gas law to determine an amount of air in the dome, and (vi) the amount of air in the dome and a known volume of the dome to be used to determine an amount of fresh dialysis fluid delivered into the expandable chamber.

A system for producing fluid for peritoneal dialysis (PD) is disclosed. The system includes a fluid path including two or more PD concentrate connectors that are each connected to a source of PD concentrate fluid, and an inlet connector connected to a fluid line arranged for transportation of effluent fluid from a patient. The system also includes a forward osmosis (FO)-unit including a draw side and a feed side separated by a FO-membrane. The FO-unit is fluidly connected to the fluid path and receives one or more PD concentrate fluids at the draw side and the effluent at the feed side. Water is transported from the effluent to the one or more PD concentrate fluids through the FO-membrane via an osmotic pressure gradient between the draw side and the feed side, thereby diluting the one or more PD concentrate fluids into a diluted PD concentrate fluid.

A peritoneal dialysis system includes a control unit configured to (i) store a sleep state pattern for the patient, (ii) begin a patient drain followed by a patient fill when at least one sensor indicates that the patient is in a deep sleep state, (iii) extend a dwell period if the sleep state pattern indicates that the patient will enter a subsequent deep sleep state within a first time duration after a programmed dwell period, and (iv) shorten the dwell period if the sleep state pattern indicates that the patient will leave the deep sleep state within a second time duration after an end of the programmed dwell period. The system alternatively or additionally assesses or records a stress level of and/or a fluid/caloric intake by the patient and takes actions accordingly.

A dialysis system includes a dialysis fluid metering pump; at least one volumetric balancing chamber including a first fixed volume chamber and a first diaphragm positioned and arranged to extend back and forth within the first volumetric balancing chamber; a first outlet line extending between the first volumetric balancing chamber and an inlet to the dialysis fluid metering pump; a second outlet line extending between the first volumetric balancing chamber and a drain line; a first inlet line extending between the first volumetric balancing chamber and an outlet from the dialysis fluid metering pump; a second inlet line extending between the first volumetric balancing chamber and a used dialysis fluid line.

The invention relates to a dialysis device that provides recirculating flow dialysis in a wearable and portable format. It uses an exchangeable purification unit holding a volume of dialysate and/or a sorbent system for the in-situ regeneration of dialysate. The invented dialysis device comprises a carrier that is mounted on a replaceable cartridge. The carrier holds the electronics, user-interface, actuators and sensors. It actuates, controls and monitors the dialysis operation. The cartridge is a replaceable part that is connected to the patient via a flexible tubing. It consists of a reusable housing with a memory chip and holds a disposable inlay containing the purification unit with fluid lines, connectors, dialysate and/or sorbents in combination with a nanofilter. The cartridge is intended for use during the day, as a wearable system. The cartridge can be enlarged with an extension set to offer more capacity. The extended cartridge is intended to be used during the night as a bedside device.