DE3600227A1 - Ultrafiltration control device - Google Patents

Abstract

In the ultrafiltration control device according to the invention, it is proposed that the liquid flow rate entering into the dialyser (60) can be measured by a flow meter (50) and can be controlled to be constant via a pump (30) arranged upstream of the dialyser (60), and that the liquid flow rate leaving the dialyser (60) can be measured via a second flow meter (53) and can be controlled via a second pump (31) arranged downstream of the dialyser (60) in such a way that the difference between the liquid flow rates corresponds to the desired ultrafiltration volume diffusing across the semipermeable membrane. <IMAGE>

Description

The invention relates to a device for measuring and controlling the ultrafiltration rate in dialyzers or filters for treatment of blood used in an extracorporeal circulation will.

When treating the blood in the extracorporeal circuit plays balancing the mass exchange on the filters used or dialyzers play a crucial role for the Condition of the patient.

From DE-AS 22 59 787 is an artificial kidney with more precise Adjustment of the ultrafiltrate throughput known, from which closed volume withdrawn a certain amount of liquid becomes. This amount is over dialyzer membrane with ultrafiltrate replaced. With this device, the liquid of the closed Volume in certain time periods through fresh dialysis fluid to be replaced to reflect the concentration gradient to maintain the membrane at a certain level the Clearence.

From EP-A-01 04 460 A2 a device is described, which also ultrafiltration by withdrawing liquid from a solid Volume controls. However, there are two chambers to which the dialyzer is connected alternately. Not with the chamber which is in engagement with the dialyzer is also connected  fresh dialysis fluid filled. This facility is needed however, a considerable technical effort to make the constant To enable switching of the dialyzer to one chamber at a time.

From DE-PS 25 48 759 a device is known in which the ultrafiltration rate is discontinuous due to direct flow measurement is determined by exposing the dialyzer to the "TMP" becomes. The "TMP" can be changed based on the measurement result to obtain the desired ultrafiltration flow. These Device has the disadvantage that during the measurement Dialysis must be interrupted. Ultrafiltration can also be used influence only via the "TMP".

From DE-PS 33 13 421 a device is described in the ultrafiltration rate using flow meters in the extracorporeal Blood circulation is determined. In this respect, this possibility appears difficult than absolutely sterile sensors in the blood have to be used, which in practice is only possible under great circumstances Realize effort.

The invention has for its object, while avoiding the disadvantages described to create an ultrafiltration control, which enables the desired ultrafiltration during treatment precisely regulated and with a technically justifiable effort on measuring and control devices in compliance with the Demand for optimal effectiveness and a wide range of treatments.

The problem is solved in a first embodiment by that the amount of liquid entering the dialyzer over a  Flow meter measurable and over a arranged in front of the dialyzer Pump is constantly adjustable, and that from the dialyzer escaping amount of liquid via a second flow meter measurable and via a pump arranged behind the dialyzer is so controllable that the difference in the amounts of liquid the desired diffusing over the semipermeable membrane Corresponds to the ultrafiltration volume.

In a second embodiment, a flow meter is used that with the appropriate frequency alternating in front of and behind the Dialyzer is switched to the prevailing rivers to record and thus regulate the set values.

By inserting flow meters into the dialysis fluid circuit the simple structure of a "single pass device" remains received with minimal technical effort. In addition a variety of treatment options can be derived from the measured values obtained derive, for the so far specifically for that constructed devices had to be used.

The invention is described below using exemplary embodiments explained with reference to the drawings.

Fig. 1 shows a first embodiment of a Aufbereitunsteils with ultrafiltration measurement and control device. Completely prepared dialysis fluid is made available in a reservoir 10 . A first pump 30 delivers the liquid via the connecting lines 20, 21, check valve 40 and connecting line 22 to the first flow meter 50 . The flow meter 50 is equipped with a measured value converter 51 for detecting the suspended height and with a temperature sensor 52 for detecting the medium temperature.

The measured values are fed to the evaluation device 88 via the connections 81 and 82 . The evaluation device is operatively connected to the pump 30 via the line 80 . This makes it possible to regulate the actual value of the flow to a defined target value, preferably 500 ml / min.

The dialysis fluid requires the flow meter 50 to provide an arrangement of solenoid valves 41, 42, 43 which allow the dialyzer 60 to be operated in three different operating states:

Valve 42 opened, 41 and 42 closed. Here, the liquid is directed past the dialyzer. This condition is called "bypass". The dialyzer is separated from the dialyzing fluid in the bypass, and the same flow flows through both flow meters. This makes it possible to identify deviations in the measurement values of the flow meters and to evaluate them for the measurement accuracy.

Valve 42 closed, 41 and 43 open. The dialysis fluid is passed through the dialyzer. This condition is called "dialysis". The liquid is fed through the membrane of the dialyzer 60 ultrafiltrate. In the second flow meter, this results in a changed flow compared to the first flow meter.

Valve 41 closed, 42 and 43 open. Here, the dialysis fluid is directed past the dialyzer, but the dialyzer is operatively connected to the dialysis fluid via valve 43 . This condition is called "filtration". Liquid, which is transported via the membrane of the dialyzer, reaches the dialyzing liquid via the open valve 43 and can also be detected by the second flow meter 53 .

The second flow meter 53 works on the same principle as the first flow meter 50 . It is equipped with the sensor for detecting the floating height 54 and with the temperature sensor 55 for temperature compensation of the flow. The measured values are fed to the evaluation device 88 via the connections 84 and 85 . The evaluation device determines the actual value of the ultrafiltration rate from the measured values available at connections 81, 82, 84 and 85 . The evaluation device 88 determines the target value of the ultrafiltration rate from the values available at the input 87 . The output 31 of the pump 31 is controlled via the active connection 86 so that the target and actual values of the ultrafiltration rates match.

All information such as weight, time and ultrafiltration can be read off the measured value display 89 .

The evaluation device 88 engages with the metering pump 32 via the operative connection 90 . The pump 32 conveys substitution solution 11 via the line 29 into the extracorporeal blood circuit and replaces a certain part of the volume withdrawn from the patient 64 .

The extracorporeal blood circuit is formed from the arterial connection 63 , the blood pump 62 , the blood part of the dialyzer 60 and the venous lines 66, 65 and the bladder trap 71 with return pressure detection.

The evaluation device 74 forms the highest transmembrane pressure present on the membrane from the measured values for the venous return pressure 73 and the pressure at the dialysis fluid inlet of the dialyzer. This value is monitored on the monitor 75 in order to 1. prevent reinfusion of non-sterile dialysis fluid on the dialyzer membrane and 2. in order to create a redundant monitoring system for ultrafiltration control via the transmembrane pressure.

In FIG. 2, a second embodiment is shown of a processing part. The dialysis fluid is supplied from the reservoir 110 by means of the pump 130 , via the lines 120 and 122 to the valve arrangement 191 to 196 . The following switching states can be selected with this valve arrangement: Bypass: Valves 191 and 194 are switched to passage, valves 192, 193, 195 and 196 are blocked. The liquid flows through the flow meter 150 to the outlet 128 , the dialyzer is separated from the dialyzing liquid.

Dialysis phase I: The valves 191, 193 and 196 are switched to pass. The liquid flows through the flow meter 150 and the dialyzer 160 to the outlet 128 . The flow meter detects the amount of liquid flowing into the dialyzer.

Dialysis phase II: Valves 195, 192 and 194 are switched on. The liquid flows through the dialyzer and is increased by the filtration volume and then reaches the outlet 128 via the flow meter 150 . By constantly switching between phases I and II, the actual value of the ultrafiltration rate can be determined by integrating the flow measurement values.

Filtration phase I: valves 191, 194 and 196 are switched to flow. The dialysis fluid is passed through the flow meter 150 and past the dialyzer 160 . However, the dialyzer is operatively connected to the liquid via valve 196 .

Filtration phase II: The valves 191, 192 and 194 are switched to flow. The dialysis liquid is enriched with filtrate via the valve 192 and thus passes through the flow meter 150 and the valve 194 to the outlet 128 . The flow meter measures the sum of the dialysis fluid flow and the filtrate flow. By constantly switching between phases I and II, evaluation device 188 can determine the actual value of the amount of filtrate. Since the same flow meter is used to record the flows in front of and behind the dialyzer, it is not necessary to generate a correction value.

The function of the evaluation device with control of a metering pump 132 for the substitution solution balancing takes place in the same way as already described under FIG. 1.

Claims (17)

1. Ultrafiltration control device, characterized in that the amount of liquid entering the dialyzer ( 60 ) can be measured via a flow meter ( 50 ) and can be constantly controlled by means of a pump ( 30 ) arranged in front of the dialyzer ( 60 ), and that the dialyzer ( 60 ) emerging liquid quantity can be measured via a second flow meter ( 53 ) and can be regulated via a second pump ( 31 ) arranged behind the dialyzer ( 60 ) such that the difference in the liquid quantities corresponds to the desired ultrafiltration volume diffusing through the semipermeable membrane. 2. Control device according to claim 1, characterized in that the flow meters ( 50, 53 ) work on the principle of the variable area flow meter, the floating heights of the variable area with respect to the calibration reference point being continuously detected via transducers ( 51 ) and converted into electrical signals. 3. Control device according to claim 2, characterized in that the detection of the levitation height by the running time of Ultrasound pulses are generated that are generated by a transmitter reflected from the surface of the float and from a receiver can be received, the direction of sound propagation preferably with the direction of movement of the float coincides with changes in flow. 4. Control device according to claim 1 to 3, characterized in that each flow meter ( 50, 53 ) is equipped with a device ( 52 ) for detecting the temperature of the liquid to be measured in order to compensate for the temperature influence of the measuring method used. 5. Control device in particular according to claim 1 to 4, characterized in that a flow meter ( 150 ) is used, which is alternately connected in front of and behind the dialyzer ( 160 ) with a corresponding frequency in order to detect the prevailing flows and thus the set values to regulate. 6. Control device according to claim 1 to 6, characterized in that a program-controlled measuring and control device is provided as an evaluation device ( 88, 188 ) for determining the flow values, filtration amount, time control, weight control and error detection. 7. Control device according to claim 6, characterized in that the evaluation device ( 88, 188 ) determines the actual flows and thus the ultrafiltration rate from the measured floating heights of the floating bodies, taking into account the measured temperatures, with the aid of a calibration table created for the measuring system. 8. Control device according to claim 1 to 7, characterized in that pressure sensors are arranged in the extracorporeal blood circuit and in the dialysis fluid area, with whose signal the prevailing on the membrane of the dialyzer ( 60, 160 ) "transmembrane pressure" can be detected, and that its size in Dependence on the ultrafiltration rate and on the specific values of the dialyzer used is monitored. 9. Control device according to claim 1 to 4, characterized in that the flow meter ( 50, 53 ) at the beginning of the treatment and during dialysis are connected in succession at regular intervals directly in the "bypass" and are thus subjected to the same flow. 10. Control device according to claim 9, characterized in that during the operating state "bypass" the deviation of the flow meters ( 50, 53 ) among each other is detected and stored, and that this value is used as a correction of the ultrafiltration amount for the subsequent measuring cycle. 11. Control device according to claim 1 to 10, characterized in that the evaluation device ( 88, 188 ) for detecting the ultrafiltration rate is equipped with setting devices which, in addition to other parameters, allow input of treatment time and weight loss. 12. Control device according to claim 11, characterized in that the evaluation device ( 88, 188 ) calculates the required ultrafiltration rate from the parameters "remaining treatment time" and "weight still to be removed", so that changes in the ultrafiltration values are possible during a treatment. 13. Control device according to claim 10 to 12, characterized in that that the following parameters are available or permanent displayed: total treatment time, treated time, Remaining treatment time, programmed weight loss, already withdrawn weight, to be withdrawn until the end of treatment Weight, setpoint of the ultrafiltration rate and measured Ultrafiltration rate. 14. Control device according to claim 1 to 13, characterized in that the dialysing liquid is bypassed during the treatment on the dialyzer ( 60, 160 ) and the dialyzer is only in operative connection with its outlet with the dialyzing liquid for carrying out the filtration in the course of a sequential dialysis . 15. Control device according to claim 14, characterized in that that a signal is available on an electrical connector is used to control an infusion pump can be used to regulate the dosing of a substitution solution In the course of hemofiltration. 16. Control device according to claim 1 to 13, characterized in that during a dialysis treatment on the evaluation device ( 88, 188 ) for the ultrafiltration rate, an electrical signal is available with which an infusion pump can be controlled to balance a substitution solution in the course of hemodiafiltration. 17. Control device according to claim 1 to 16, characterized in that ultrafiltration during treatment can be selected according to a specific profile.