The present invention relates to a peritoneal dialysis machine having at least one machine housing and having at least one drain pan for receiving one or more solution bags for storing consumed dialyzate, wherein the drain pan is connected to at least one weighing cell such that the weight of the drain pan can be detected by means of the weighing cell, wherein at least one damping system is provided to prevent the occurrence of undue force introduction into the weighing cell, wherein the damping system has at least one damper to which the drain pan is directly or indirectly fastened, wherein the damper is connected to the weighing cell such that the weight of the drain pan acting thereon is transmitted to the weighing cell.

Extracorporeal blood treatment apparatus with reservoir status lights and methods of monitoring reservoir status using the same are described. The extracorporeal blood treatment apparatus include a plurality of reservoir scales (30), each of which is configured to weigh a reservoir (32) used in connection with the extracorporeal blood treatment apparatus. A plurality of reservoir status lights (40) are provided, with one or more of the reservoir status lights (40) associated with one of the reservoir scales (30). The one or more reservoir status lights (40) associated with one of the reservoir scales (30) emit light from a location that is closer to their associated reservoir scale than to any other reservoir scale of the extracorporeal blood treatment apparatus.

Blood treatment apparatus and methods of using the same are described herein that include two or more intermediate containers located between a treatment solution source and a port through which the treatment solution is to be delivered with the blood treatment apparatus. The weight of the intermediate containers is measured and used to control the refilling and emptying of treatment solution in the intermediate containers.

A method of displaying a predicted state of a medical apparatus, and a medical apparatus employing the method are disclosed. The method comprises receiving a sensor signal from a sensor of the medical apparatus, filtering the sensor signal by an adaptive filter such that a predicted signal is achieved, determining a state from the predicted signal, and displaying an indication through a user interface of the medical apparatus based on the determined state.

A renal therapy apparatus including at least two feedback controls is disclosed. Each control includes an estimated volume calculator to calculate an estimated volume based on a set flow, a comparator to compare the estimated volume with a measured volume, a volume deviation determining means to determine a volume deviation based on the comparison, a correction calculator to calculate a correction based on the volume deviation, a flow control generator to generate a flow control signal based on the calculated correction amount and the set flow, and a feedback control output to output the controlled flow control signal to a pump associated with each feedback control. A flow correction distributor includes an input to receive correction signals from the correction calculator, a limited correction signal calculator to calculate a limited correction signal for the input correction required signals, and an output to output each calculated limited correction signal to the feedback control from which its underlying correction required signal has been received.

Blood treatment apparatus and methods of using the same are described herein that include two or more intermediate containers located between a treatment solution source and a port through which the treatment solution is to be delivered with the blood treatment apparatus. The weight of the intermediate containers is measured and used to control the refilling and emptying of treatment solution in the intermediate containers.

Provided is a dialysate supply device and a blood dialyzing apparatus including the same. The dialysate supply device includes a flow controller controlling a dialysate flow, a supply pump supplying dialysate to a hemodialyzer, a recovery pump discharging dialysate from the hemodialyzer, a volume chamber storing dialysate, and a pressure-relief bypass maintaining dialysate pressure within a permissible range. The blood dialyzing apparatus includes the dialysate supply device, a blood tube, and a one-way valve disposed on the blood tube. The blood dialyzing apparatus can quickly change dialysate pressure in the hemodialyzer using the dialysate supply device having the flow controller, cylinder and piston, and increase mass transfer and hemodialysis efficiency. Also, the blood dialyzing apparatus may be miniaturized and lightened to provide a portable blood dialyzing apparatus because blood is transferred without using a blood pump.

The present invention provides an extracorporeal dialysis apparatus which allows the automation of some operations in order to make possible a safe home treatment or to facilitate the treatment process for example the priming and/or the blood return process. Thus, the object is to automatically perform a series of processes from hemodialysis preparation to treatment completion safely, reliably and speedily, and to significantly reduce the labor and supply costs.

Ultrafiltration (UF) is monitored in a weight-based system for extracorporeal blood treatment. The system comprises a container holding a fluid that is pumped to or from a dialyzer by a pump. The container is intermittently refilled or drained by an adjustment arrangement during a level adjustment period (LAP). A scale measures the weight of the container. A monitoring device is operated to determine, before and after the LAP while the adjustment arrangement is deactivated and the pump is operated at a known setting, first and second values of a parameter of the pump based on a weight signal from the scale. The parameter may be flow rate or stroke volume. The monitoring device estimates a time profile for the parameter during the LAP based on the first and second values and determines the UF parameter based on the time profile.

A peritoneal dialysis system includes: a drain container; a drain line placed in fluid communication with the drain container and configured to be placed in fluid communication with a patient's peritoneal cavity; a vacuum source configured to apply a pneumatic force to cause used dialysis fluid to flow through the drain line from the patient's peritoneal cavity to the drain container; a weight sensor configured to output a weight of used dialysis fluid delivered to the drain container from the patient's peritoneal cavity; and a controller configured to: (i) determine an actual flow rate of used dialysis fluid removed from the patient's peritoneal cavity based on the output from the weight sensor; (ii) compare the actual flow rate to a desired flow rate; and (iii) adjust the pneumatic force applied by the vacuum source to attempt to match the actual flow rate to the optimal flow rate.