Medical fluid management assembly includes: a pneumatic manifold including multiple plates forming pneumatic passageways, a pneumatic valve chamber and a pneumatic pump chamber, the valve chamber in pneumatic communication with at least one passageway, the pump chamber in pneumatic communication with at least one passageway; and a fluid manifold including multiple fluid pathways, a fluid valve chamber in selective fluid communication with a fluid pump chamber and at least one fluid pathway, wherein (a) the pneumatic valve chamber and the fluid valve chamber are mated together to compress a membrane and (b) the pneumatic pump chamber and the fluid pump chamber are mated together to compress a membrane, wherein at least one of the pneumatic valve chamber or the pneumatic pump chamber extends from the at least one plate, or the fluid valve chamber or the fluid pump chamber extends from the fluid manifold to aid in compressing the membranes.

A method and device for linearizing an optical sensor in a dialysis apparatus. The method includes introducing a sensor to the dialysate-side drain line, determining the linear range of the optical sensor, backwards extrapolating the data from the linear range and correcting the data from the non-linear range.

A device is disclosed for determining an access flow rate of a patient when connected to a blood treatment machine. The device performs a measurement phase in which the blood treatment machine is caused to operate in first and second operating states, where the second operating state at least differs from the first operating state by a change of flow direction of blood or treatment fluid through a dialyzer of the blood treatment machine. Based on sensor values representing a fluid property of the treatment fluid in the first and second operating states, the device computes a measurement value of comparison parameter (e.g. a ratio or a difference) that compares treatment efficiency in the first operating state to treatment efficiency in the second operating state, and determines, based on the measurement value, an estimated value of the access flow rate.

A method and device for linearizing an optical sensor in a dialysis apparatus. The method includes introducing a sensor to the dialysate-side drain line, determining the linear range of the optical sensor, backwards extrapolating the data from the linear range and correcting the data from the non-linear range.

Embodiments of the disclosure include a method and system for estimating flow rates of a fluid or medium though a dialyzer during a dialysis treatment (e.g., a hemodialysis treatment). Pressure sensors are incorporated in dialyzers used for hemodialysis to achieve continuous monitoring of fluid balance of the body. During dialysis, obtaining fluid input and output pressures experienced at various inlets and outlets of dialyzers is easier than obtaining flow rates at these inlets and outlets, but using flow rates is better in determining the effectiveness of a dialyzer during hemodialysis. Embodiments of the disclosure thus use pressure measurements at inlets and outlets of a dialyzer along with a dialyzer model to determine fluid flow rates through the dialyzer. The fluid flow rates are used to determine whether there are leakages or occlusions in tubing during the dialysis treatment.

The present invention relates to a method of identifying a filter, wherein the filter has at least one retentate side and at least one permeate side which are separated from one another by at least one filter medium, wherein the method comprises generating a pressure in a fluid, in particular in a liquid, on the retentate side or on the permeate side by means of a pressure source, in particular by means of a pump; switching off the pressure source; and the measurement of the pressure development in the fluid over time subsequent to the switching off of the pressure source.

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.

A method of detecting an indication of a potential intradialytic morbid event (IME) by monitoring a patient's condition during excess fluid removal by ultrafiltration during a hemodialysis treatment includes determining the patient's relative blood volume (RBV), and removing a portion of the volume of excess fluid from blood of the patient at an initial ultrafiltration rate while periodically monitoring a second derivative over time of the relative blood volume (SDRBV). The method then includes continuing to remove excess fluid from blood of the patient at the same ultrafilration rate, or, optionally, incrementally increasing the ultrafiltration rate. The method further includes triggering an alarm for an IME for the patient if the SDRBV is in a range of between a low SDRBV alarm level and a high SDRBV alarm level, and, alternatively or additionally monitoring the patient's normalized blood pressure ratio, and taking a remedial action if the alarm is triggered.

A control unit (30) is arranged to control a dialysis fluid distribution system (12) comprising first and second volumetric pumps (PI, P2) arranged upstream and downstream of a dialyzer (13). The control unit (30) is operable in a calibration mode, to establish a bypass flow path that bypasses the dialyzer (13) and extends from the first pump (P1) to the second pump (P2) in fluid communication with a calibration chamber (26) and to operate the pumps (P1, P2) at different combinations of speeds that cause first and second changes in fluid level in the chamber (26). The first and second changes correspond to first and second known volumes in the chamber (26). The control unit (30) measures, by a level detector (28) in the chamber (26), first and second time periods for the first and second changes, and computes the stroke volumes of the pumps (P1, P2) as a function of the speeds of the pumps (PI, P2), the first and second time periods, and the first and second known volumes. By computing the stroke volumes, the control unit (30) is operable to achieve an accurate ultrafiltration (UF) rate in the dialyzer (13) by controlling the relative speeds of the pumps (P1, P2).