DE1964588A1 - Hose system for a peritoneal dialysis machine - Google Patents

Description

Stw .: peritoneal dialysis hose system - Hauni file 1086 hose system for a peritoneal dialysis machine The invention relates to a hose system for a for supplying a metered and temperature-controlled amount of dialysis fluid to the Body of a patient and for the subsequent removal of this fluid from the Body of the patient serving peritoneal dialysis machine with a connection to a Stiletto catheter and with a connection to a storage container for dialysis fluid.

Artificial kidneys have the task of endogenous or exogenous poisoning the toxins via natural (peritoneal dialysis) or artificial (hemodialysis) membranes to eliminate from a patient's body. While those with artificial membranes working hemodialysis apparatus is very expensive and its implementation with accordingly complicated apparatus requires special forces, is used in peritoneal dialysis the peritoneum of the patient is used as a membrane. The preheated dialysis fluid, whose temperature and quantity must be strictly adhered to is with the help of a Stiletto catheter is entered into the patient's abdomen and after a certain amount Dwell time (between ten and forty minutes) pumped out again.

The toxins pass into the dialysis fluid and become discharged with this. Peritoneal dialysis is thus medically easy as such and can be carried out without special forces.

In the case of peritoneal dialysis machines of the type mentioned at the outset, how already mentioned - an exact dosage and temperature control of the patient's body supplied dialysis fluid required, which of course are completely sterile got to.

After completing dialysis and before connecting another patient to the peritoneal dialysis machine, the device should be very fast for a dosage and Temperature control of the dialysis Stw .: peritoneal dialysis hose system - Hauni file 1086 to prepare the liquid required for a new dialysis i.e. time-consuming sterilization of the hose system and the dosing device should be avoided.

The hose system according to the invention satisfies the aforementioned requirement in that a dosing bag made of flexible material for receiving in the hose system of dialysis fluid is provided during a dosing process.

A good observation of the dosage is according to a training of the invention possible when the dosing bag is made of transparent film. Of course The other hose lines can also advantageously be made of transparent plastic exists, because then any irregularities such as air bubbles, especially in the case of colored ones Dialysis fluid, can be recognized at an early stage.

According to a further embodiment of the invention, a hose line for supplying dialysis fluid from a storage container to the dosing bag be provided, from which a hose line for conveying away dialysis fluid branches off from the dosing bag and for conveying to the stiletto catheter. A cushioning generated by a delivery pump for the dialysis fluid in the hose system Pressure surges and the addition of medication enable a branching line, in which a throttle is provided. The throttle is useful in this to the hose line for supplying dialysis fluid to the dosing bag subsequent, provided with a bongen-shaped curvature of the branching off Sole power arranged. Another hose line connected to the dosing bag can be used to supply dialysis fluid to the stylet catheter Lead. This line enables the circulation in the hose system Dialysis fluid before it is supplied to the patient. This is special important if the dialysis fluid during or after the Stw .: Peritoneal dialysis tubing system - Hauni file 1086 Dosing in the dosing bag tempered, e.g. 3. has been heated. Through the last-mentioned training of the The dialysis fluid located in the hose system is also the invention heated, so that it is impossible that the patient at the beginning of a dialysis inadequate tempered dialysis fluid is supplied.

For conveying away the dialysis fluid taken from the patient's body is on the tubing for delivering dialysis fluid to the stylet catheter a hose line for conveying away dialysis fluid removed from the patient's body connected. The occurrence of negative pressure when the patient is constipated is according to a further Äusgestaltung the invention avoided in a simple manner, that of the dialysis fluid removed from the patient's body for removal The hose line used is a safety hose line that is directly connected to the atmosphere connected.

Electrical monitoring circuits are used to increase the safety of dialysis advantageous that record certain operating states of the peritoneal dialysis machine, for which the hose system is intended. The acquisition is advantageously carried out in Electrodes that are connected to an electrical measuring or monitoring circuit. Monitor such safety electrodes, e.g. using the resistor accordingly designed circuits, whether there is a leak in the dosing bag or whether there is a hose line Have formed air bubbles. The hose system according to the invention can be very advantageous Further development is provided with connecting pieces for the electrodes mentioned above be. For example, to indicate a leak in the dosing bag, you can add that to the dosing bag leading hose line a connector for a safety electrode is provided be. It can also be used to determine air bubbles in the feed of dialysis fluid to the hose line serving the stylet catheter at least two connecting pieces can be provided for one safety electrode each. Stw .: Peritoneal Dialysis Hose System - Hauni File 1086 A connector can be very simple and inexpensive as a tubular, electrically conductive connector for two Ends of the hose line may be formed with a connection for an electrode is provided.

The hose system according to the invention is advantageous already from Supplied sterile by the manufacturer, so that only a new one is required to prepare for dialysis Tube system needs to be inserted into the peritoneal dialysis machine, which after dialysis can simply be thrown away.

Stw .: peritoneal dialysis hose system. Hauni File 1086 The Invention is explained in more detail using an exemplary embodiment is illustrative drawing. It showed Figure 1 the structure of a peritoneal dialysis machine according to the invention, FIG. 2 shows an electrode for signaling when a certain adjustable value is reached Liquid level, Figure 3 a hose pump, Figure 4 an electromagnetic Valve for shutting off a hose line, FIG. 5 a monitoring device for a hose line, FIG. 6 shows the hose system of the peritoneal dialysis machine according to the invention drawn by itself, Figure 7 shows a central control arrangement for an automatic run of a dialysis cycle consisting of individual dialyses, FIG. 8 shows the peritoneal dialysis machine according to the invention together with its control arrangement as a mobile unit, Figure 9 shows a variant of the measuring arrangement for the body of the Dialysis fluid withdrawn from the patient again, FIG. 10 shows a mixing arrangement for Merging of Eomponenten to form the dialysis fluid during the dosing.

The peritoneal dialysis machine of FIG. 1 consists essentially of a dosing and Tempierkreis 1, which at the same time the conveyor for the dialysis fluid to the patient contains a withdrawal circuit 2 for withdrawing the dialysis fluid from the patient's body and a measuring circuit 3 for the automatic determination of the the amount of dialysis fluid withdrawn from the patient's body.

: Peritoneal dialysis tubing system - Hauni file 1086 The dosing and Tempierkreis 1 has two or more storage containers 6 and 7 to accommodate a supply of dialysis fluid 5 for a dialysis cycle, the line via a hose 8 end connected to a bag 9 made of flexible transparent plastic. In the course of the hose line 8 is a controllable solenoid valve 11 (details in Figure 4) and a feed conveyor for dialysis fluid to the dosing device respectively; to the patient in the form of a hose pump 12 (details in Figure 3) controllable an electric drive motor 13. The solenoid valve 11 and the drive motor 13 receive control voltages via lines 14 and 15 from a central control arrangement 16 for the independent control of the individual dialysis processes of a dialysis cycle. The drive motor 13 is a direct current motor, since its speed and direction of rotation must be controllable. The direction of rotation can be controlled by the polarity that Control of the speed set via the size of the supplied control voltage will. The drive motor 13 can be regarded as a control device for the feed conveyor 12 will.

The bag 9 is located in a partially containing measuring liquid 17 (Water) filled measuring vessel, also made of transparent plastic 18, with a measuring arrangement 19 for a lower stand and an upper stand (Level) of the measuring liquid 17 in the form of electrodes 21 and 22 (details shows Figure 2) is provided, each in front of a scale 23 for setting the to be dosed Individual amount of dialysis fluid 5 can be moved up and down. The ones from the electrodes 21 and 22 on contact with the measuring liquid 17 emitted measurement signals led via lines 24 and 26 to the central control arrangement 16. The bag 9 represents a partition between the dosing liquid 5 in the one enclosed by the bag 9 Space and the measuring liquid 17 in the measuring vessel 18, when the supply of. Dialysis fluid displaced to the bag 9 measuring liquid.

Stw .: Peritoneal dialysis tubing system - Hauni file 1086 All in one Immersion body 27, which is protected against the measuring liquid 17 by an insulating layer 28 is thermally insulated, there is a heating fluid 299 from an electrical Heating resistor 31 can be heated and via hose lines 32 and 33 to form a hose coil 34 is performed, which surrounds the bag 9 and holds it mechanically in its position.

In the measuring vessel 18 there is a temperature sensor 36 such that it detects the temperature of the measuring liquid 17.

This temperature sensor 36, which is an actual value transmitter of a first thermal Control circuit 35 for keeping the temperature of the measuring liquid 17 constant is connected to a comparator 37, which is also an adjustable one electrical resistance formed setpoint generator 38 is connected0 The comparison element 37 is used to generate the control deviation (difference between setpoint and actual value) and controls An actuator of the thermal control circuit 35 in the form of an amplifier 47 an electric motor 39 of a pump 41 in the circuit of the heating fluid 29. The control can be an on-off control. But it can also be a pump with continuously variable Find funding volume use.

A temperature sensor 42 is located in the displacement body 27 in such a way that it detects the temperature of the heating fluid 29. This temperature sensor, its actual value transmitter of a second thermal control circuit 40 to keep it constant represents the temperature of the heating fluid is connected to a comparison element 43, this also has a setpoint generator designed as an adjustable electrical resistor 44 is connected. The comparison element 43 forms the control deviation of the second thermal control circuit and controls an actuator via a switching amplifier 48 46 for controlling the heating current through the heating resistor 31. The actuator 46 can in the simplest case it can be designed as a switch for the heating current0 but it can also continuously controllable actuator, such as an electronic transistor or thyristor Stw. : Peritoneal dialysis hose system - Haun acute 1086 amplifier, for continuous adjustment the heating power in the electrical heating resistor 31, the comparison element 43 connected downstream be. A single thermal control loop is sufficient, e.g. the second thermal one Control circuit 40, solely for at least approximately keeping the temperature constant Measuring liquid 17; when the temperature of the heating liquid 29 is, for example, of the order of magnitude the body temperature is chosen, i.e. it is set to around 38 degrees Celsius, the dialysis fluid also reaches this final temperature after the heating time, so that - after heat losses in the hose lines to the patient - in these the dialysis fluid arrives at body temperature. With higher demands However, there are two reasons for the constant temperature of the dialysis fluid 5 in the bag 9 thermal control circuits, one for the heating fluid 29, the other for the measuring fluid 17, advantageous.

The bag 9 is connected to an inlet hose line via a further hose line 51 52 connected, which is attached to the stylet catheter 49 in the body of the patient 53 is. The part of the hose line 51 between the dosing bag 9 and the branch point 54 is denoted by 51a. In the hose line 51 lies just before the inlet hose line 52 a via line 50 from the central control arrangement 16 with a control voltage actable solenoid valve 55 (details in Fig. 3). From a junction 54 branches off a bend 56, which consists of an elbow 57 and a throttle 58 and opens into the hose line 8 at a branch point 59. In the course of the hose line 51 are two safety electrodes 61 and 60 connected to T-pieces 55 and 60. 62 (details in FIG. 5) for displaying air bubbles harmful to the patient in the dialysis fluid that sends its measurement signals via lines 63 and 64 to the give central control arrangement 16. Also lies in the course of the hose line 51 another safety valve 67 loaded with a spring 66, the dialysis fluid Stw .: Peritoneal dialysis tubing system - Hauni file 1086 only lets through - if a certain pressure has been exceeded. In the course of the hose line 8 is a Safety electrode 71 connected to a T-piece 70 (details in FIG 5), which sends a measurement signal to the central control arrangement 16 via a line 72 releases when, in particular as a result of a leak in the bag 9, measuring liquid Mix 17 and dialysis fluid 5 in the measuring container 18 with one another. One as Alarm device executed, later described signal arrangement in the central control arrangement 16 ensures that the alarm is triggered and that the entire device is switched on in the event of danger. In the removal circuit 2 is a conveyor for dialysis fluid from the body of the patient in the form of a hose pump 73 (details in FIG. 3) with a controllable electric drive motor 74 and a solenoid valve 76 (details in FIG. 4) in the course of a hose line 77 which is located at a branch point 78 connects to the inlet hose line 52. The drive motor 74 and the solenoid valve 76 are supplied with control voltages via lines 79 and 81 from the central control arrangement 16 can be acted upon. The drive motor 74 is designed as a DC motor, its Speed is adjustable by the size of the control voltage. It can be used as a control device for the discharge conveyor 73 are taken. At a junction 82 is on the hose line 77 a safety hose line 83 is connected, behind a throttle 84 and the branch point 82 an electrical vacuum switch 86 and a manometer 87 lie. The upper part 83a of the safety hose line 83, with which the vacuum switch 86 and the pressure gauge 87 are connected, need not be sterile and is over a connection piece 89 with that belonging to the sterile hose system (186 in FIG. 6) Safety hose line 83 connected. Get from the vacuum so-holder 86 Measurement signals via line 88 to the central control arrangement 16. The upper termination the safety hose line 83 with the throttle 84 is for the sake of clarity for placement in the removal circle outlined in strioh-dotted lines 2 Stw .: Peritoneal dialysis tubing system - Hauni file 1086 below bend 57 drawn; in the implemented version, however, this upper termination is above of the bend 57.

The dialysis fluid taken from the patient's body 53 Hose line 77 leading to measuring circuit 3 ends in a collecting vessel 91 which with one in front of a scale 92 for setting the desired liquid level (Level) in the collecting vessel up and down movable electrode 94 (details in Fig. 2) is provided, of which the reaching of the set liquid level indicating measurement signals can be supplied to the central control arrangement 16 via line 96 are. From this collecting vessel, a hose 97 leads, in the train of which a a line 98 can be acted upon with control voltage from the central control arrangement 16 Solenoid valve 99 (details in FIG. 4) is located to a measuring container 101 with two along a scale 102 for setting an upper and a lower liquid level (Level) up and down movable electrodes (details in Fig. 2) 102 and 104, for the delivery of measurement signals when the set liquid levels are reached are connected to the central control arrangement 16 via lines 106 and 107. From the measuring container 101 leads a hose line 108, in the train a via a Line 109 from the central control arrangement 16 can be acted upon with control voltages Solenoid valve 111 and an electric drive motor 112 of a feed pump 113 (cB. A gear pump) to a drain 114.

The central control arrangement 16 each has an adjusting knob 171 and 172 for the speeds of the drive motors 13 and 74 of the hose pumps 12 and 73 on With the adjustment knobs 171 and 172, for example, not shown electrical potentiometers in the excitation circuits of the DC motors Drive motors to change the Stw .: peritoneal dialysis hose system - Hauni file 1086 excitations and thus the speeds can be adjusted. The lines to the excitation windings are also not shown, as this control principle is notoriously known for DC motors. The central control arrangement has also a timer 173 with an adjustable switch contact 173a for the dwell time a single amount of dialysis fluid in the patient's body and a timer 174 with adjustable switching contact 174a for the time the doctor expects to reach the enema a single amount of dialysis fluid in the patient's body.

The buttons 176 and 177 are used to switch the mains voltage on and off for the peritoneal dialysis machine and for the energy supply of the heating (heating resistor 31) provided, the button 178 for the start of a dialysis cycle (at the beginning of the program), that with the dosage and temperature control of the first individual amount of dialysis fluid begins. The button 179 is once used by the operator to initiate the stomach enema to press during the first dialysis. The central control arrangement 16 has also a presettable counter 181 for counting the individual dialysis, a warning lamp 182 and counters 183 and 184 for counting the stomach enema and those in measuring containers 101 recorded quantities.

The functions of the central control arrangement 16, the setting buttons 171 and 172, the timers 173 and 174, the buttons 176 to 179, the counter 181, 183, 184 and the warning lamp 182 are explained in detail with reference to FIG.

The electrode arrangement of FIG. 2 for the highly precise measurement of liquid levels has a tube 122 provided with a slot 121, the inside with a layer 123 is lined with insulating plastic and that in terms of their Levels of the liquid to be monitored.

The tube 122 is on a partially broken-open housing 124, which is electrically separated from it by an insulating layer 125 attached.

Stw .: Peritoneal dialysis hose system - Hauni file 1086 A flexible one electrically conductive metal strip 127 is attached to the pin 126 to the it is laid around in loose turns. On the metal strip 127 there is one in the Tube 122 fixed up and down movable measuring tip 128 made of electrically conductive material, which is kept away from the pipe walls by a plastic sleeve 129. To the drive the metal strip 127 is provided with a roller 131 provided with a friction lining, which are connected with an invisible rotary knob on the outer wall of the housing is. Another roller 132 serves as a counter bearing for the metal strip 127.

The tube 122 is connected to one pole of a voltage source, the housing 124 and with it the metal strip 127 with the other pole in connection. The immersion or the immersion of the measuring liquid from liquid standing in the tube 122 is -depending on the circuit - evaluated as a measuring signal, since here a current flow between the poles is established or interrupted. The housing 124 is together with fittings 133 and 134 in an insulating plate 136, e.g. by means of screw connections (not shown), attachable9 so that it is easy - e.g.

for cleaning - detached from the insulating plate 136 and on this again can be attached. Through the slot 121 it is achieved that the current paths at Immersion of the measuring tip 128 in the liquid to be monitored standing in the tube 122 are small even with a raised probe tip. It is also guaranteed that the The level of the liquid in the tube is the same as the level of the liquid in the one containing the liquid Since the vessel is only low, it practically does not correspond to the liquid level in the pipe falsifying adhesion phenomena can occur. The electrode arrangement is also advantageous because of its very space-saving design when it comes out of the housing 124 no parts protrude even when the probe tip is raised.

According to the electrode arrangement shown in Figure 2 can the electrodes 21, 22, 94 and 103 and 104 in FIG. 1 may be formed.

The hose pump of Figure 3 consists of two rollers 141 and Stw .: Peritoneal Dialysis Tubing System - Hauni File 1086 142, one of which always has a role with a hose line 1439 in which the liquid is to be conveyed, in engagement by pressing on the hose line and its cross-section is practical reduced to zero. The cells 141 and 142 are rotatably seated on levers 144 and 146, respectively. which are rotatably mounted about axes 148 and 149 which are fixedly arranged on a disk 147 and are connected to one another by means of a tension spring 150. The shaft 151 of the disc 147 can be driven by a non-visible electric drive motor, which is advantageous is designed as a DC motor, especially when reversing the direction of rotation and adjustable speed are required. The driven rollers 141 and 142- push upon rotation of the disk 147 against a hose line 143, the cross-section of which changes the point of contact is reduced in size, so that liquid in the hose line is promoted. The tension spring 150 has the purpose that the rollers 141 and 142 of the Lift off hose line 143 when a certain delivery pressure is in the hose line 143 is exceeded, so that the hose pump is damaging to the patient Overpressure is secured. Corresponding to the hose pump shown in FIG the hose pumps 12 and 73 of FIG. 1 can be designed.

The electromagnetic valve of FIG. 4 consists of a cutting edge 152 on one side of a hose line 15D, which is on the other side against the Effect of a compression spring 154 displaceable by an electromagnet 156, as a pressure plate trained anchor 157 faces. In the illustrated solenoid valve if the stroke of the armature is smaller than the diameter of the hose line, it is reduced by twice the wall thickness. The effective cross-section when the valve is open is practically not reduced in the arrangement shown, but the anchor travel smaller. Small anchor distances are, however, in terms of response times and security advantageous. When the electromagnet is energized, the armature 157 moves into the position shown Position in which the hose line 153 Stw .: peritoneal dialysis hose system - Hauni file 1086 is open. When the excitement disappears, e.g. by switching off the excitation voltage, the compression spring 154 pushes the armature 157 back out of the drawing Position against the cutting edge 152, so that the hose line 153 is compressed and the valve closes. The compression spring 154 then also ensures a closing of the valve if the voltage, e.g. in the event of a power failure, to excite the electromagnet 156 fails. According to the solenoid valve shown in Figure 4 can the solenoid valves 11, 55, 76, 99 and 111 in FIG.

The safety electrode of Figure 5 has one in a hose line 163 made of electrically insulating material, e.g. made of transparent plastic T-piece 162 made of electrically conductive material, which with its ends 164 and 165 is connected to the hose line 163 and its center piece 166 has a bore 167 for receiving an electrode 168 designed as a banana plug. The electrode 168 can be fastened to an insulating plate 169, e.g. screwed on.

The safety electrodes correspond to the safety electrode of FIG 61 and 62 formed in Figure 1, which are connected in series and electrically across the dialysis fluid of the hose line 51 are in communication with one another. If there is one between the safety electrodes that is dangerous for the patient Air bubble, so the current flow through the dialysis fluid in the tubing interrupted, which is rated in the central control arrangement 16 as a "fault" and interrupts the dialysis. According to the safety electrode 5, the safety electrode 71 is also formed in FIG a leak in the bag 9 a circuit via the dialysis fluid in the tubing line 8, the measuring liquid 17 in the measuring vessel 18 and via the electrode 21 in the central Control arrangement 16 closes.

Stw .: Peritoneal dialysis tubing system - Hauni file 1086 The one in figure 6, the sterile hose system 186, once again particularly emphasized, is included of the bag 9, the elbow piece 57, the throttle 58, which as T-pieces 55, 60 and 70 for connecting the safety electrodes 61, 62 and 71 designed connection pieces and the piercing cannulas 187, 188, 189, 191, 192 and 193 (for piercing dialysis fluid containing storage containers 6, 7) supplied sterile by the manufacturer.

It can be exchanged particularly easily for each dialysis cycle. The connection of a new hose system 186 to the peritoneal dialysis machine according to FIG the invention requires fol lowing handles: inserting the bag 9 between the Hose coil 34 in the measuring vessel 18, introduction of the safety electrodes 619 62 and 71 in the T-pieces 55 or 60 or 70, insert the hose line 8 into the hose pumps 12 and 73, inserting the hose line 8 between the cutting edge and armature of the solenoid valve 11, inserting the hose line 51 between the cutting edge and armature of the solenoid valve 55, inserting the hose line 72 between the cutting edge and armature of the solenoid valve 76, inserting the hose line 51a into the safety valve 67, inserting the Hose line 77 into the collecting vessel 91, connect the safety hose line 83 with the hose line 83a by means of the connecting piece 88, piercing a or several of the injection cannulas 187 to 193 into the associated dialysis fluid 5 containing storage containers 6 and 7 or further storage containers, subsequent ones Inlet hose line 52 to the stiletto catheter 49, which is in the body of the patient 53 is introduced as soon as dialysis fluid at the end of the inlet tubing line appears In the arch piece 57 an additional substance, e.g. a drug solution, by means of an injection needle 194 some are brought in with the dialysis fluid is also supplied to the patient's body.

Stw .: peritoneal dialysis tubing system - Hauni file 1086 in figure 7 are further details of the central control arrangement framed by dash-dotted lines 16 for the practically automatic program sequence of a dialysis cycle shown Sun. far the figure has elements that are written in previous figures be wear these have the same reference numerals. The electrodes 21, 22, 94, 103 and 104 are in the central control arrangement 16 again symbolized as contacts, whose drawn switching states the drawn liquid levels in the assigned Vessels correspond. Dipping or immersing the electrodes in liquid causes the switching states of the contacts to change.

In reality the electrodes are of course the individual vessels 18, 91 and 101 spatially assigned. The central control arrangement 16 has the following Groups of switching elements on: AND gates 207, 224, 226, 231 and 243 each with two inputs a and b, which only emit a signal at their outputs e9 if a signal is applied to both inputs a and b at the same time.

OR gates 208 and 236 with inputs a and b or a ...

each of which emit a signal at their outputs c, if mio least a signal is applied to an input, negation elements 216, 223, 233, 242 and 244, which invert a signal present at their input a, i.e. at their Output the inverse signal from output c, bistable memories 202, 209, 217, 218, 232, 234 and 237 each with a memory input a and a delete input b. The loading a memory input a is called "set" in effect, since then on A signal appears at the output o of the memory, which remains stored until the L hi input b receives a signal, i.e. the memory is deleted again, whereupon the Signal at output c disappears 9 Amplifier 2039 206, 211, 2149 219, 222, 227, 228, 238 and 239 for signal amplification, motor contactors 204, 212, 221 and 229, the when excited about Stw .: peritoneal dialysis hose system - Hauni files 1086 their contacts a and b supply associated drive motors with control voltage, a timer 213 consisting of an RC element, an emergency switch 241, a cancel button 246 and a main line 247 for the DC voltage supply of the central control arrangement 16.

Mode of operation of the peritoneal dialysis machine according to the figures 1 to 7: First, as described in FIG. 6, - a fresh, sterile hose system inserted into the peritoneal dialysis machine, the inlet hose line 52 already is connected to the stiletto catheter 49, but not yet in the body of the patient 53 is inserted. The attending physician then places the electrodes 21 and 22 in front of the scale 23, the individual amounts of dialysis fluid for the dialyses a.

It can also be connected to the central control arrangement 16 by means of the Adjustment knobs 171 and 172 the speed of the dosage and the belly enema or the belly outlet. He also uses the timer 173 to set the Dwell time during which a single amount of dialysis fluid is in the body of the patient is located, and by means of the timer 174 the expected maximum Duration of the construction run-in. Corresponding to the amount of for the entire dialysis cycle The dialysis fluid provided is also the counter 181 for specifying the number of the individual dialyses. Finally, the setpoint generator 38 (potentiometer) also the temperature of the liquid to be measured and, via setpoint generator 44, the temperature the heating fluid can be preselected. For example in the collecting vessel 91 and measuring container 101 any remaining liquid from the previous dialysis cycle is drained. The button 176, which connects the main line 247 to the network PO, is then pressed. The main line 247, which is connected to voltage, supplies the voltage for the control and Control signals of the central control arrangement 16 and the current for Stw .: Peritoneal Dialysis Hose System - Hauni File 1086 Heating Resistance 31.

After these preparatory acts, pushes to start a dialysis cycle an operator presses button 178 to initiate the first dialysis. It runs Now start the first dialysis in the following way. The button 178 enters the memory 202 setting signal at its input a, so that the memory 202 at its output c the motor contactor 204 energized via amplifier 203. This closes its contacts a and b, so that the drive motor 13 of the hose pump 12 via double line 15 Receives control voltage and can start up in the direction of rotation of the metering (arrow 251). Simultaneously excites the signal coming from output c of memory 202 via amplifier 206 and line 14 the solenoid valve 11, which opens. The peristaltic pump can now Dialysis fluid 5 from the containers 6 and 7 via hose line 8 to the bag 9 pumps. As the contents of the bag increase, measuring liquid 17 is displaced so that its level in the measuring vessel 18 rises. During this dosing process, the Dialysis fluid already warmed, because the pump 41 heating fluid through the Heating coil 34 promotes and thus increases the temperature of the measuring liquid 17.

When the set temperature value of the measuring liquid is reached, detected by the temperature sensor 36 of the first thermal control circuit 35 is, the control deviation at comparator 47 disappears and the pump 41 stops quiet. The temperature of the heating fluid 29 is controlled by the second thermal control circuit 40 held constant. Is the desired amount of dialysis fluid in bag 9, then the level of the measuring liquid 17 reaches the upper electrode 22 (in FIG 7 this means closing the correspondingly labeled contact). The measurement signal the electrode 22 passed via line 26 to the central control arrangement 16, in which it applied to the erase input b of the memory 202, so that the memory is deleted and the signal at its output c and thus the control voltages disappear on lines 14 and 15. This has the consequence that the drive motor 13th Stw .: Peritoneal Dialysis Hose System - Hauni file 1086 is resting and that the solenoid valve 11 closes, i.e. that the metering 9 thus the feeding of dialysis fluid to the bag 9 has ended. Arrived from the electrode 22 a signal also to input a of the AND gate 207. Its input b only receives a Signal when the operator presses the button 179 to fully automatic in the following Has pressed the end of the dialysis cycle. This button is only pressed when the dialysis fluid in the bag 9 safely reaches its prescribed temperature has what by a not shown, on the warming time and / or temperature the dialysing fluid responsive display device can be reported 0 The actuation of the pushbutton 179 by the doctor is necessary, since the Insertion of the stiletto catheter 49 into the body of the patient 53 follows. That at its input a applied with a signal OR gate 208 is at his Output c a signal to input b of AND gate 207 from Das on both inputs AND gate 207 to which signals are applied to a and b is now at its output c from a signal which arrives at the input a of the memory 209 and sets it. The signal output from its output c excites the motor contactor via amplifier 211 212, which closes its contacts a and b and thus line 15 with a control voltage reversed polarity applied so that the drive motor 15, the hose pump 12 drives in the opposite direction of rotation according to arrow 252. Solenoid valve 11 remains closed. The peristaltic pump 12 circulates the dialysis fluid through hose line 8, elbow 57 and hose line 51a.

around. During this agitation, the doctor can use one at the bottom of the curved piece 57 inserted injection needle 194 medication of the dialysis fluid admit. During the circulation, the one in the hose lines is also outside The dialysis fluid located in the bag 9 is heated from output c of the memory 209 emitted signal also reaches the timer 113, which after a certain Delay time via amplifier 214 a control voltage on line Stw .: Peritoneal dialysis tubing system - Hauni file 1086 50 provides the control voltage is supplied to the solenoid valve 55, which opens. Now the peristaltic pump can 12 Dosing liquid from bag 9 via hose line 8, elbow 57 and hose line 51 convey to the inlet hose line 52. Dialysis fluid comes at the end the inlet hose line 52 and to the one connected to this hose line Stiletto catheter 49 on, the doctor guides the stiletto catheter 49 into the abdomen of the patient 53 and the delivery of metered and temperature-controlled dialysis fluid to the patient, hereinafter referred to as "abdominal enema", begins. In the bow piece 57 a pressurized gas bubble 9 arises because of the throttle 58 the eventual Cushions pressure surges in the dialysis fluid. The given by the timer 213 The signal is also fed to the counter 183, the count of which is one unit is increased. The counter 183 is used to measure and display the number of abdominal enemas. It can also determine the number of individual doses and thus the amount of the patient 53 total amount of dialysis fluid supplied can be preset so that the counter, e.g. via OR gate 236, ends the dialysis cycle as soon as the intended Amount of dialysis fluid has been supplied. This ensures that that the dialysis fluid present in the storage containers 6 and 7 is not completely is spent and air gets into the lines to the patient. Is the whole dosed and tempered individual amount of dialysis fluid conveyed from the bag 9, then the level of the measuring liquid 17 has reached the lower electrode 21 (in Figure 7 means opening the correspondingly labeled contact).

That fed to the input a of the negation element 216 via line 24 The measuring signal of the electrode 21 disappears when the electrode is no longer in the measuring liquid immersed, so that the negation element 216 emits a signal at its output c The signal is applied to the erasure input b of the memory 209 and erases it; so that first, the motor contactor 212 : Peritoneal dialysis tubing system Hauni file 1086 is de-energized and thus the control voltage to the drive motor 13 on line 15 disappears, which thus stands still, secondly the control voltage Line 50 disappears so that the solenoid valve 55 closes. The ones in the body the patient's dialysis fluid must now linger there, with them Absorbs toxins.

The signal output by negation element 216 is the input of the Memory 217 supplied and sets this. The memory 217 is at its output c from a signal that the drive of the preset timer 173 to set the Dwell time can start. The signal output by negator 216 is also fed to the set input a of the memory 202, which is thereby set and at its Output G emits a signal that via amplifier 203 and motor contactor 204 a control voltage triggers a control voltage on line 14 on line 15 and via amplifier 206, so that the drive motor 13 runs in the direction of rotation of the metering according to arrow 251 and the solenoid valve 11 opens. This allows in the dwell time of the first Dialysis process in which the dosed individual amount remains in the patient's body, already the individual amount of dialysis fluid for the following dialysis process prepared, i.e. dosed and tempered.

The hose pump 12 thus delivers again in the manner described above Dialysis fluid from the storage containers 6 and 7 into the bag 9, with already a heating occurs until the electrode 22 increases the dosage to that already described Way ended by sending a measurement signal to clear input b of memory 202. The drive motor 13 stands still again, the solenoid valve 11 closes. While the remainder of the dwell time can contain the dosed dialysis fluid in the bag 9 heat safely to the desired temperature to the end.

After the dwell time has elapsed, the preset switching contact is activated 173a of the timer 173 sends a signal to the clear input b of the memory 217 and to the Set input a of memory 218. Stw .: peritoneal dialysis hose system - Hauni file 1086 The pointer of the timer 173 goes down because of the disappearing signal at the output c of the memory 217 and on the drive of the timer again in its drawn Starting position back. The memory 218 transmits a signal at its output c Amplifier 219 to -the motor contactor 221, which closes its contacts a and b, whereby a control voltage is given on line 79, which drives the drive motor 74 dr peristaltic pump 73 starts up. The signal at output c of memory 218 is also after amplification fed in the amplifier 222 via line 81 to the solenoid valve 76, which opens. The peristaltic pump 73 now delivers through the inlet hose line 52 and the hose line 77 dialysis fluid from the patient's body, which is there with toxins has loaded, to the collecting vessel 91, which is referred to as "belly outlet". That The signal emitted by output c of the memory 218 is inverted by the negation element 223. The AND gates 224 and 226 therefore receive no signals at their inputs a, see above that through amplifier 227 (line 98) the solenoid valve 99 and amplifier 228 and motor contactor 229 (double line 109) the solenoid valve 111 and the Drive motor 112 no control voltages can be supplied.

As soon as the liquid level in the collecting vessel 91 reaches the electrode 94, this triggers a measurement signal via line 96 (in FIG. 7 this means closing of the correspondingly designated contact); if now the Unterdruckachalter 86 responds and via line 89 a measurement signal to the central control arrangement 16, the is to be rated as the end of the abdominal outlet, then the AND gate receives 231 on both Inputs a and b signals, so that there is a signal at its output c on the clear input b of the memory 218 outputs, the signal at the output c disappears. It go away hence the control voltages on lines 79 and 81, so that the drive motor 74 stops and the solenoid valve 76 closes.

The abdominal discharge of the first individual dialysis is thus ended. Stw .: Peritoneal dialysis tube system -Hauni file 1086 The one at output c of the AND element 231 output signal is also applied to the input b of the OR gate 208, des sen output c a signal to the second input b of the AND gate 207th gives its Input a already from electrode 22 when dosing the second individual amount for the second dialysis session had received a signal. That at the output c of the AND element 207 output signal is applied to the input a of the memory 209 and sets this, so that via motor contactor 212 line 15 is supplied with a control voltage of such a polarity receives that the drive motor 13 of the hose pump 12 in the direction of rotation accordingly Arrow 252 to initiate the second dialysis (abdominal enema) starts and the into the Tubing circulates dialysis fluid.

The timer 174 is drawn from the measurement signal of the electrode 21 in its The initial position is reset if its pointer has not yet reached the switch contact 174a the actual abdominal break-in time was shorter than the preset maximum Time was After the time determined by the timer 213 after which the dialysis fluid is heated in the hose system, valve 55 receives control voltage via line 50, so that it opens to initiate the abdominal enema.

The deletion of the memory 218 by the output c of the AND gate 231 coming signal causes a signal at output c of negation element 223, which acts on the inputs a of the AND gates 224 and 226. Since at the entrance b of the AND gate 224 a signal from the memory 232 is already pending, which is not via the electrode 104 immersed in liquid (in Pig. 7 this means that the corresponding Contact is hit) and via the negation member 233 on its input a had received a setting signal, alao emits a signal at its output c, triggers the signal emitted from output c of AND element 224 via amplifier 227 a control voltage on line 98 to solenoid valve 99, which opens. Stw .: Peritoneal dialysis tubing system - Hauni file 1086 It can now flow out of the Collecting container 91 flow through hose 97 into measuring container 101 until it is reached For a certain set amount of the liquid level, the electrode 103 achieved. This sends a measurement signal via line 106 to the central control arrangement 16 (in Fig. 7 this means closing the corresponding contact), which is the set input a of the memory 234 is applied, the output c of which then emits a signal that firstly the erasure input b of the memory 232 is applied, so that the signal on the output c of which disappears and, secondly, the input of the AND element 226 is applied. While the input b of the AND gate 224 because of the deletion of the memory 232 none Input signal receives more, so that its Dignal disappears at output c appears because of the application of both inputs a and b of the AND gate 226 at its output c a signal. As a result, firstly, the control voltage on line 98 disappears, solenoid valve 99 closes, and secondly the double line 189 a control voltage from the motor contactor 629 selects that from the signal Fom Output of the AND gate 226 via amplifier 228 was to be excited. The control voltage on line 109 causes the solenoid valve 111 to open and the drive motor 112 to start up, so that the pump 113 transfers the measured liquid via hose line 108 to drain 114 promotes.

the electrode 103 simultaneously gives a signal to the preset Counter 181, the counter reading of which is decreased by one unit. Electrode 103 The counter 184 also gives a signal, the status of which is a measure for the patient is the amount of liquid withdrawn. From the difference between the counter readings from the counter 184 and 183 can be used to determine the amount of liquid that the petient discharged @@@@ With the dimension @@@@ ter 101 le @@ so electrode 104 loosens over Lei - @@@@@@ @@@@@@ @@ el in the central @@@@@@ arrangement Stw .: peritoneal dialysis hose system Hauni file 1086 contact, which is inverted by the negation element 233 and since t as Set signal applied to the set input a of the memory 232, so that it is set will. The signal appearing at the output c of the memory 232 acts on the input b los AND gate 224, at whose output c a signal appears, which again A control voltage on line 98 to the solenoid valve via amplifier 227 99 triggers so that this opens. The one appearing at output c of memory 232 However, the signal also acts on the clear input of the memory 234, its signal at the output c disappears, so that the signal at the input b of the AND gate 226 also disappears. This has the consequence that the control voltage on line 109 disappears, so that the solenoid valve 111 closes and the drive motor 112 stops. Liquid can now again be drawn from the collecting vessel 91 silver hose line 97 flow to the measuring container 101 until the electrode 103 is immersed in the liquid emits a measuring signal that - as described - the closing of the solenoid valve 99 and the supply of control voltage to the drive motor 11. and the solenoid valve 111 triggers. At the same time, the count of the counter 181 increases again by one unit humiliated.

The entire contents of the collecting vessel are in the described manner 91 of a single dialysis. The remainder in the measuring container 101 is through The liquid of the following dialysis process is replenished up to the level of the electrode 103.

One dialysis procedure after the other is carried out in the manner described fully automatically controlled and the fluid withdrawn from the patient's body measured until the counter 181 has reset the preset number to zero. In this case it gives a signal at input c of the OR gate 236, at its output c a signal appears which is fed to the set input a of the memory 237. Whose Output signal at output c actuated after amplification via amplifier 238 Stw .: Peritoneal dialysis tubing system - Hauni files amine warning lamp 182 and post-energized Amplification via amplifier 239 the emergency switch 241, which luit the entire system Except the heating switches off. An operator called by the warning lamp 182 now completes the last dialysis process, i.e. it ends the abdominal discharge, whereupon the entire dialysis cycle is ended.

In a procedure like peritoneal dialysis, there can be several Faults occur that have to be recognized and also with an automatic process must not cause any dangerous conditions for the patient. The following is describes the mode of action of several safety circuits with which hazards arise can be encountered.

An important requirement in peritoneal dialysis is avoidance any penetration of germs into the sterile dialysis fluid.

Such an intrusion is, for example, practically undetectable if the bag 9 has a leak and unsterile measuring liquid penetrates into the bag 9. The safety electrode 71 is used to monitor such a hazard, via line 72 a measurement signal to a signal arrangement in the central control arrangement 16 gives (in Figure 7 this means closing the corresponding contact). This Signal applied to the input d of the OR gate 236, so that its output c a signal via amplifier 238 to warning lamp 182 and via amplifier 239 Provides excitation signal to the emergency switch 241 to turn off the entire device. The OR gate 236 forms together with the warning lamp 182 and the emergency switch 241 an alarm device that uses the warning lamp to indicate a malfunction or an error displays and calls the staff and the system automatically via the emergency switch turns off.

Another possible hazard is the formation of air bubbles in the tubing system containing the dialysis fluid that is not in the body of the patient Stw .: peritoneal dialysis hose system - Hauni file 1086. The safety electrodes are used to indicate this dangerous condition 61 and 62, between which a current flow is interrupted when the air baler is applied. In this case, corresponding measurement signals le are sent to the via lines 63 and 64 central control arrangement 16 given (in Fig. 7 this indicates opening of a corresponding Contact). The negation element 242 ensures that this signal is inverted a signal is present at the input e of the OR gate 236. At the output c of the OR gate a signal which actuates the warning lamp 82 and the emergency switch 241 then appears.

in a more dangerous case it is that the patient is "constipated", i.e. that the dialysis fluid no longer flows properly into his body or expires. D The 174 watch is used to determine whether there is a blockage in the case of an abdominal enema. Is not before reaching the preset Schaltkon contact 174a belly inlet ended, i.e. the electrode 21 has not emitted its measurement signal by then, then an o al arrives at input a of the OR gate 236, at rn output c then arrives again the warning lamp 182 and emergency switch 241 activating signal is present.

The determination of a blockage in the case of abdominal discharge is carried out by a vacuum switch 86 taken over. Its measurement signal succeeded in addition to the input a of the AND element 243, whose input b via the negation element 244 from the measurement signal of the electrode 94 is applied. When the electrode 94 responds when the vacuum switch 86 has not yet spoken to, it means that the expected amount of dialysis is not being received liquid has been pumped out of the body of the patient 53, the negative pressure so not due to the end of the ba spout, but due to a blockage is The Sig output from the output c of the AND element 243 applies to the input b of the OR element 236, at the output @@@@@@ the warning lamp 182 and the emergency alarm 146 @@@@@@@@@@@@@ @@ ne @ @@@@@ hen @@@@ Stw .: peritoneal dialysis hose system - Hauni-Jilde 1086 The memory 237 can be used by the operator after remedying a fault can be deleted again by the delete button 276.

Except for the safety circuits in the central control arrangement The peritoneal dialysis machine has 16, in which logical connections have to be made according to the invention, built-in fuses that work purely mechanically.

At the increase in pressure associated with constipation at the abdominal enema is, some of the dialysis fluid is returned via the safety valve 67 to the bag 9. In addition, the pressure in the hose line 8 presses The rolls of the peristaltic pump 12 from the hose line 8 against the liquid Action of the spring 180 back. It immediately becomes the damaging purely mechanically Effect of constipation (increase in pressure in the patient) avoided before the safety circuit the central control arrangement 16 has responded and the operating personnel alarmed. With the negative pressure associated with an obstruction in the case of abdominal discharge is, air is sucked in through the safety hose line 83, causing an impermissible A build-up of negative pressure in the patient is avoided before the negative pressure switch 86 switches off the entire device.

FIG. 8 shows the spatial configuration of the peritoneal dialysis machine according to the invention shown as a unit 262 movable on rollers 261. The one in earlier Elements of the device already described in the figures have the same reference symbols provided and no longer specifically explained. Located on the control panel 263 All buttons, counters, setting buttons and lamps are clearly arranged. In addition to the operating elements already explained, there is also a button 260 to switch to manual control and a button 266 to switch to automatic Program control provided. There is also a button 267 for manual control of the Belly- Stw .: peritoneal dialysis tubing system - Hauni file 1086 inlet and a button 268 for manual control of the ventral outlet provided, the only take effect after pressing button 264. Hand control details are not shown because they are trivial in terms of circuitry. 269 is an indicator lamp, which lights up as long as there is dialysis fluid in the tube system is circulated after dosing.

An indicator lamp 271 is used to display the dwell time and its duration is controlled by the timer 173. The dwell time can be set by means of a button 270 but also quit early. 272 is the mains connection, 273 is a row of contacts for a remote display of the most important measured values. The one from FIG. 8 is particularly good Space-saving and compact design of the peritoneal dialysis machine according to the invention can be seen in which all control elements and storage containers are housed are.

In Figure 9, a measuring circuit 303 is shown in which during the measurement a certain amount of liquid in a measuring container from another beforehand filled measuring container liquid is conveyed into the drain. To this end are the collecting vessel 391 with an electrode 394 via hose lines 397a and 397b, in each of which there is a solenoid valve 39a or 399b, two in parallel connected measuring containers 401a and 401b with electrodes 405a and 403b, respectively.

A hose line 408a or 408a leads from each measuring container.

408b, in the course of which one solenoid valve 411a or 411b to drain 414. Electrodes 394, 403a and 403b and the solenoid valves 399a, 399b, 408a, 408b are the same with the central control arrangement (not shown) connected that the valves 399, 411 have the same switching state, the inverse is the switching state of the solenoid valves 399, 411.

If, for example, measuring container 401a is filled, what is the purpose of the solenoid valve 399a is open and the solenoid valve 411a is closed, then the measuring container 401b emptied, where-ZU the solenoid valve 399b is closed and the electric Stw .: Peritoneal Dialysis Circuit - Hauni File 1086 solenoid valve 411b is open. If the liquid level has reached the electrode 403a, its measuring signal triggers Switching the valves off in such a way that measuring container 401b is filled and measuring container 401a is emptied.

The advantage of this measuring arrangement is the greater measuring speed, since liquid can flow off practically continuously from the collecting container 391.

Figure 10 shows a storage container arrangement in which a large Reservoir 506 with distilled water and several smaller reservoirs 507, 508 and 509 are provided for receiving concentrate. By mixing the distilled water from reservoir 506 with concentrate from one or more the container 507, 508 and 509 during the dosing becomes the dialysis fluid educated. The hose pump 512 can be driven by a drive motor 513. before the hose pump 512 is an electromagnetic valve 511. The hose pump 512 is used again for dosing and performing the abdominal enema. De peristaltic pumps 601, 602 and 603 can be driven by drive motors 604 or 606 or 607, and those by resistance regulators 608 or 609 or 611 are adjustable with respect to their speeds. The peristaltic pumps 601 to 603 convey parallel to the peristaltic pump 512. By setting the conveying speed of the peristaltic pumps 601 to 603, the mixing ratio of water to concentrate, i.e. the concentration of the dialysis fluid can be adjusted.

The smaller storage containers are located by means of the solenoid valves 612 to 614 507 to 509 lockable.

The advantage of the sole hose system according to the invention is that that no more cleaning work is carried out after the end of dialysis need what is particularly important in view of the shortage of staff in the nursing professions and is beneficial. To prepare for a new dialysis, simply start a new one Hose system inserted into the peritoneal dialysis machine, on the one hand to the storage container for dialysis Stw .: peritoneal dialysis hose system - Hauni files 1086 fluid and on the other hand connected to the stiletto catheter. A cleaning the dosing and temperature control device for the dialysis fluid is not required. Connection pieces for the safety electrodes are already included in the cable and designed so that the connection with the actual safety electrodes - e.g. by drilling a hole - is very easy and not an important one Causes costs. These connectors can after dialysis together with the The rest of the hose system can also be simply thrown away.

- patent claims -

Claims (11)

Stw .: Peritoneal dialysis sole system - Hauni file 1086 Patentan Proverbs hose system for a for feeding in a metered and tempered amount Dialysis fluid to the body of a patient and for subsequent removal Serving peritoneal dialysis machine with a connection to a stiletto catheter and a connection to a storage container for dialysis fluid, characterized in that that in the tube system (186) a metering bag (9) made of flexible material for Admission of dialysis fluid (5) is provided during a lbsiervorgangs. 2. Hose system according to claim 1, characterized in that the Dosing bag (9) consists of transparent film. 3. Hose system according to claim 1 and / or 2, characterized in that that a hose line (8) for supplying dialysis fluid (5) from a Storage container (6, 7) is provided for the dosing bag (9), from which a hose line (57, 51, 52) for conveying dialysis fluid from the dosing bag and to the Feed branches off to the stiletto catheter (49). 4. Hose system according to claim 3, characterized in that in a part (57) of the branching line is provided with a throttle (58). 5. Hose system according to claim 4, characterized in that the Throttle (67) in which is attached to the hose line (8) for supplying dialysis fluid to the dosing bag (9) adjoining, provided with an arcuate curvature Part (57) of the branching hose line is provided. Stw .: Peritoneal Dialysis Circuit - Hauni File 1086 6. Hose system according to claim 3 to 5, characterized in that a further hose line is attached to the dosing bag (9) (51a) is connected to the for supplying dialysis fluid to the Stylet catheter (49) serving line (51) leads. 7. Hose system according to one or more of the preceding claims, characterized in that on the hose line (51) for supplying dialysis fluid to the stylet catheter (49) a hose line (77) for conveying away from the body dialysis fluid withdrawn from the patient is connected. 8. Hose system according to claim 7, characterized in that on the hose line (77) removed from the patient's body for removal Dialysis fluid a safety hose line that is directly connected to the atmosphere (83) is connected. 9. Hose system according to one or more of the preceding claims, characterized in that in the hose line leading to the dosing bag (9) (8) a connector (70) for a safety electrode (71) is provided. 10. sole hose system according to one or more of the preceding claims, characterized in that in the for supplying dialysis fluid to the Stylet catheter (49) serving hose line (51) at least two connecting pieces (55, 60) are provided for one safety electrode (61, 62) each. 11. Hose system according to claim 9 or 10, characterized in that that a connection piece as a tubular, electrically conductive connection piece is designed for two ends of the hose line with a connection for one Electrode is provided. L e r s e i t e