A peritoneal dialysis system includes a control unit configured to cause (i) a fluid inlet valve and a fluid outlet valve to occlude a fluid inlet line and a fluid outlet line, respectively, while a linear actuator moves a piston to create a positive pressure within a pump housing, the positive pressure measured by a pressure sensor, and (ii) the fluid inlet valve to occlude the fluid inlet line and the fluid outlet valve to open the fluid outlet line, while the linear actuator moves the piston so as to maintain the positive pressure within the pump housing while fluid is pumped out of the fluid pump chamber via the opened fluid outlet line.

A hemodialysis machine comprising a dialysate flow path for delivering a flow of dialysate solution through a dialyser, the flow path including a flow balancer for achieving a balance in the dialysate solution flow volume observed between an inlet and an outlet of the dialyser over the course of a treatment, the flow balancer comprising a first flow balance pump having an inlet valve and an outlet valve and a second flow balance pump having an inlet valve and an outlet valve, wherein the flow path further includes a flow restrictor means downstream of the flow balance pumps to reduce the pressure difference across the valves in the dialysate flow path.

A peritoneal dialysis system includes a chamber; a hydraulic pump; an inflatable bladder located within the chamber and in hydraulic fluid communication with the hydraulic pump; and a control unit configured to cause known amounts of hydraulic fluid to be metered to and from the inflatable bladder and to determine (i) a first amount of air before a discharge stroke via a first ideal gas law calculation, (ii) a second amount of air after the discharge stroke via a second ideal gas law calculation, and (iii) a discharge volume of fresh or used dialysis fluid for the discharge stroke by subtracting a difference between the first and second amounts of air from a known amount of hydraulic fluid metered to the inflatable bladder for the discharge stroke.

In a blood purification device containing a blood purifier, a blood circuit, a blood pump, and a dialysate line having a fresh dialysate supply line and a used dialysate discharge line, a pair of plunger pumps are disposed in the dialysate line. The pair of plunger pumps are synchronized so that delivery of a fresh dialysate from one plunger pump and suction of a used dialysate into the other plunger pump simultaneously occur and the stroke of at least one of the pair of plunger pumps is made variable.

In medical apparatus, for example a dialysis machine, a pump in conjunction with a multichambered reservoir is provided. The volume pumped is determined by counting the number of fills of the reservoir made during a pumping phase. A less expensive pump may be used whilst maintaining an accurate determination of the volume pumped.

The present invention relates to a dialysis machine having a dialyzer and having a first balancing chamber and having a second balancing chamber, wherein the first inflows of the first balancing chamber halves are in fluid communication with a source of fresh dialyzate and the first outflows of the first balancing chamber halves are in fluid communication with a dialyzer inflow, and wherein the second inflows of the second balancing chamber halves are in fluid communication with a dialyzer outflow and the second outflows of the second balancing chamber halves are in fluid communication with a drain, wherein a third balancing chamber is provided that has two balancing chamber halves that are separated from one another by a movable wall, wherein each of the balancing chamber halves has a respective inflow and a respective outflow that are each provided with valves that are configured to close or open the respective inflow or outflow, wherein the two inflows are in fluid communication with a source of fresh dialyzate, and wherein the two outflows are in fluid communication with the dialyzer inflow.

An oxygenator includes: a housing; a bubble-removing hollow fiber membrane layer removing a bubble; a gas-exchanging hollow fiber membrane layer exchanging a gas with blood; and a discharge port to discharge the bubble removed by the bubble-removing hollow fiber membrane layer to the outside of the housing. The oxygenator further includes a gas permeable portion that is arranged between the discharge port and an end portion of the bubble-removing hollow fiber membrane layer, is formed by a member having gas permeability, and allows passage of the bubble removed by the bubble-removing hollow fiber membrane layer without allowing passage of plasma leaking through the bubble-removing hollow fiber membrane layer. A plasma capture chamber that captures the plasma leaking through the bubble-removing hollow fiber membrane layer is formed between the end portion of the bubble-removing hollow fiber membrane layer and the gas permeable portion.

A dialysis machine which monitors the pressure of blood entering and leaving a patient's body using several sensors (37, 39) and adapts the pressure of a dialysate solution feed to compensate for compliances in the dialysate fluid flow path. As a consequence, better flow balance is maintained throughout dialysis treatment leading to a more uniform removal of waste materials from the blood.

A device for extracorporeal blood treatment, in particular a dialysis machine, including an internal fluidic system to which a blood treatment unit, in particular a dialyzer, can be connected, the internal fluidic system comprising at least one balancing chamber on the fresh flow side for balancing fresh treatment fluid flowing to the blood treatment unit and at least one balancing chamber on the used flow side for balancing used treatment fluid flowing off the blood treatment unit, wherein the device has a measuring device for gravimetric detection of treatment fluid in the balancing chamber on the fresh flow side and/or a measuring device for gravimetric detection of treatment fluid in the balancing chamber on the used flow side. A method of balancing treatment fluid in such a device.

Provided is a blood purifying apparatus having a fluid pumping device, which further includes first to sixth chambers each having an internal space, a chamber pressurizing member compressing or expanding the internal spaces of the fluid chambers, a chamber pressurizing member driver driving the chamber pressurizing member, and a flow controller. The chambers are each connected with a first flow tube through which a fluid is provided to the chamber and a second flow tube through which a fluid of the chamber is discharged therefrom. The flow controller controls a flow passage through the flow tubes connected to the first to fourth chambers.