Abstract: A dialysis machine assembly having an internal flushing and filling facility for a blood flow circuit of the assembly is disclosed. The dialysis machine assembly includes dialyzer having a membrane and an inlet and an outlet for blood side with corresponding blood tubes and an inlet and an outlet for dialysate side with a valve located downstream of the outlet for dialysate side. A dialysis liquid supply is connected to the inlet for the dialysate side and the valve is partially closed to force dialysis liquid to flow through the membrane from the dialysate side to the blood side through the blood tubes to flush and fill a blood flow circuit prior to performing a dialysis treatment with the dialysis machine.
Abstract: The checking apparatus for injection- or infusion-type pumps comprises a glass piston syringe, a linear potentiometer whose spindle is rigidly connected to the piston of the glass piston syringe, a pressure transducer in communication with the syringe inlet, and an electronic computing and evaluating means connected through a water-filled tube to the glass piston syringe and presses water into the glass piston syringe at a predetermined delivery rate. The apparatus displays on three display panels. These important parameters can be measured quickly and precisely with the aid of said apparatus.
Abstract: A method to determine the delivery rate and delivery volume per unit of time of a liquid involves connecting one end of a sealed tube to the outlet of the pump, with the other end being provided with a pressure sensor. The pump is activated to pump liquid in to the tube, and air pressure readings are obtained at time intervals. The measured pressures may be used to determine the delivery rate of the pump. The delivery volume (V) is determined by the formula V=VO.times.A/(A+PO), wherein VO is the total tube volume, A is the measured air pressure, and PO is the absolute air pressure at the test beginning. Volumes not delivered by the pump due to back pressure may be determined by filling the tube with liquid and measuring the increase in liquid pressure per unit of time against the known delivery rate of the pump.
Abstract: In the on-line method of the invention, dialysis liquid which has been produced or prepared by a dialysis machine is taken from the dialyzer at the blood side and pumped, either by means of a blood pump of the machine or by the pump of the dialysis liquid circuit, through the blood tubes, optionally using the filling program specific to the machine. As a result, the extracorporeal blood circulation system need no longer be flushed and filled with a salt solution, which has so far entailed considerable costs.
Abstract: Not only the dialysis machine, but also its outer supply conduits and connection tubes together with the associated water distribution system can be flushed and disinfected in the present disinfection method by including these members in the cleaning circuit. Energy is saved and the amount of disinfectants is reduced during hot cleaning and chemical disinfection in a recirculatory process, and the duration of the disinfecting operations can moreover be decreased. Furthermore, a five-valve assembly is provided in or on the dialysis apparatus, in an additional apparatus with respect to the dialysis apparatus or in a water supply system integrated into the wall of a dialysis station for the dialysis apparatus so as to carry out the disinfection method, and a supply means is provided for introducing the disinfectant into the recirculatory circuit.