HU191765B - Device for automatic controlling of permanent bladder irrigation - Google Patents

Abstract

Field of the Invention The present invention relates to an apparatus for automatically regulating sustained urinary bladder rinsing. The device according to the invention has a rinse aid (10) for flushing fluid (10) through the catheter (4) into the bladder (5) and a conduit (11) for the outflow tube connected to the urine collection vessel (7). The rinse pipe (10) is equipped with a variable speed pump (2) and a pressure relief unit (3), and a blood detector (6) for the outlet pipe (11). The pump (2), the pressure sensor unit (3) and the signal input (21) of the signal detector (9) of the blood detector (6) are connected to a central control unit (8) and are preferably secured to the pipeline by a clamp. The blood detector (6) is preferably a light detector that provides a bleeding-related signal. (Figure I) -1-

Description

BACKGROUND OF THE INVENTION The present invention relates to an apparatus for automatically controlling sustained bladder flushing, which can vary the amount of costly flushing fluid depending upon postoperative bleeding, save significant amounts, relieve the need for constant patient care, and increase the safety of intensive care. prevents or signals the formation of excessive blood clots in the bladder.

It is known that bladder flushing is used to prevent blood clots after bladder and prostate surgery. This involves gravitational delivery of a specially formulated flushing fluid from a reservoir via a catheter into the bladder, from where it passes along with blood and urine to a urine collection vessel. Strict sterility and a closed flushing system should be provided throughout the entire rinse to eliminate the risk of infection.

In practice, the rate at which the flushing fluid flows has been manually adjusted by the nursing staff depending on the current rate of bleeding.

This practice has two major drawbacks.

One of the disadvantages is that in the case of suddenly increasing bleeding, if it is not detected by the nursing staff within a short time, a blood clot forms in the bladder. This can lead to serious complications, ascending infection, sepsis.

The same consequences can result in over-saturation of the urine collection vessel and failure to empty the vessel.

Another major disadvantage is that a very large amount of expensive flushing fluid is consumed unnecessarily and wasted if the flow rate of the flushing fluid is carefully set too fast. The amount of flushing liquid thus wasted can reach up to ten liters per day. Of course, this waste significantly increases the cost of care.

The object of the present invention is to overcome the shortcomings of the known solution for preventing coagulation, i.e. to prevent the use of excess amount of rinsing fluid, and to prevent the risk of infection due to insufficient quantity of rinsing fluid due to blood clotting.

The present invention is based on the discovery that the amount of rinsing fluid can be optimized without the constant presence of nursing staff by automatically adjusting the flow rate as a function of bleeding intensity.

Based on the above recognition, automatic control of sustained bladder flushing is accomplished with an apparatus having a flush conduit for flushing fluid through the catheter and a drainage outlet connected to a vessel. The flushing line has a variable speed pump and pressure sensing unit, and the outlet line has a blood detector. It is connected to a central control unit connected to the signal input of the pump, the pressure sensor unit and the blood detector indicator unit.

It is advisable to make the flushing pipe and the drain pipe out of a transparent plastic and use an electroplating on one side of the drain pipe as a blood detector and a photodiode on the opposite side of the pipe and then change the pump speed through the photodiode signal amplifier in the event of a reduction in light to the photodiode, the pump will deliver more rinsing fluid to the bladder.

The voltage regulator for varying the pump speed may advantageously consist of a power transistor having a voltage drop potentiometer connected to its emitter and collector. This potentiometer is used to set the minimum amount of rinse liquid. The emitter is connected to the body and the collector is connected to the positive voltage via the pump motor, whereby the emergency detector signal is applied to the base.

Advantageously, a change in pressure of the flushing fluid, when the pla container is emptied or the fluid passage is blocked, can be generated by a central control unit having a three-way OR gate. The first and second inputs of the OR gate are connected to the blood detector via an inverter or integrator, and the third input is connected to the pressure sensor unit, and the OR gate output is connected to the signal input of the signaling unit. The inverter receives a logical "1" to the first input of the OR gate even when, for whatever reason, no blood or flushing fluid enters the outlet duct and this malfunction is signaled by the signaling unit. The integrator on the second input prevents darkening for a short period of time of one to two seconds - eg. in the event of a small blood clot - trigger an unnecessary signal on the circuit.

The signaling unit may be located in the central room of the nursing staff and / or in the patient room and preferably consists of an acoustic signal and / or a light signal connected in series with a power transistor.

In the event of any automation malfunction or power failure, the entire system can be reset to its normal operating mode by attaching the pump, pressure sensor unit, and blood detector to each of the two pipelines. After removing them, gravity moves under the influence of gravity.

The sealing and sterility of the entire system is preferably achieved by using a plastic bag known per se as a urine collection vessel. The drawings, in which like reference numerals denote like details, are a possible exemplary embodiment of the apparatus of the invention.

In the drawing it is

Figure 1 is a block diagram of the

Figure 2 is a block diagram of a component, a

Figure 3 is a wiring diagram for a component.

As shown in FIG. 1, the flushing fluid reservoir 1 is connected via a flushing tube to a pump 2 and then to a pressure sensing unit 3, from where it is introduced into a bladder 5 via a vessel of a known three-way catheter 4. From the bladder 5 through the outlet conduit to the second vessel of the catheter 4 through the blood detector 6, a mixture of irrigation fluid, urine and blood flows into a urine collecting vessel 7. The pump 2 is connected to a voltage regulator output 18 of a voltage regulator 12, which is connected via an inverter 15 to the first input of the OR gate 14 and via an integrator 13 to the second input of the OR gate 14. The pressure sensing unit 3 is a pressure indicator on the central control unit 8

Through its 191,765 turns, it is connected to the third input of the OR gate 14 and the blood detector 6 is also connected to the light change detection input 20 of the central control unit 8. The light change input 20 is the same as the input of the voltage control unit 12. The output of the OR gate 14 is connected to the signal input 21 of the signaling unit 9, which actuates an acoustic signal 17a and a light signal 17b connected to a collector of a power transistor 16.

The blood detector 6 shown in Figure 2 consists of a light source 22 disposed on one side of the discharge conduit 11 and a photodiode 23 disposed on the opposite side of the discharge conduit 11 and an amplifier 24 having a photodiode 23 in its amplifier 24 and an output 20 in the central control unit. connected.

The voltage control unit 12 shown in Fig. 3 consists of a power transistor 25 and a voltage drop potentiometer 26 connected to its emitter and collector. The collector of the power transistor 25 is metallically connected to the voltage regulator output 18 of the central control unit 8 and its base to the luminance signal input 20.

The device of the present invention can be used to control sustained bladder flushing as follows:

The voltage drop potentiometer 26 of the voltage regulating unit 12 adjusts the resting speed of the peristaltic pump 2 to deliver a predetermined minimum amount of flushing fluid to the bladder 5. The rinsing fluid, which has become dark after bladder or prostate surgery, passes between the light source 22 and the photodiode 23, thereby reducing the illumination of the photodiode 23, thereby increasing the resistance of the photodiode 23, and in proportion to the increased power output. It opens. As a result, the voltage on the motor of the pump 2 increases, which increases the speed of the pump 2 and thus the amount of flushing fluid. The increased amount of flushing fluid will result in a more transparent mixture flowing through the all-out duct, and a negative feedback control will occur,

If there is a persistent dark mixture in the outflow line 11 due to heavy bleeding, the integrator 13 will logically enter 1 at the second input of the OR gate 14, whereupon the signal transducer 17a and the light detector 17b will be actuated simultaneously.

However, if there is no flushing fluid due to any malfunction, plugging or possible emptying of the flushing fluid reservoir 1, the light change signal input 20 will be at logic level "o", this level will take logic "j" through inverter 15. actuates the first input of the OR gate 14 and the signaling unit 9 as described above.

The pressure sensing unit 3, which is preferably a plastic plastic container with electrical contacts or possibly a strain gauge, also actuates the indicating unit 9 by a logic level J signal to the third input of the OR gate 14. This occurs when the flow of flushing fluid for any reason, e.g. greater blood clot formation or cessation of saturation of the 7 urine collection vessels.

The blood detector 6 can also be calibrated by not only actuating the indicator unit 9, e.g. the outflow line 11 has slipped out of the catheter 4, but also automatically stops the pump 2 in case of a malfunction.

The unit can be operated from a battery during shorter power outages of one to two hours, and can be configured to provide a warning when the power is disconnected.

As can be seen from the exemplary embodiment, the device of the present invention, while fully delivering the intended benefits, prevents blood clotting and dangerous complications, optimizes the amount of rinsing fluid used, provides significant nursing cost savings, enhances the safety of intensive care, otherwise, overloaded nursing staff.

Claims (7)

Apparatus for automatically controlling sustained bladder flushing, with a flushing tube delivering flushing fluid through a catheter to a bladder and a drain line connected to a urine collection vessel (7), characterized in that the flushing tube (10) and a blood detector (6) is connected to the outlet duct (11), whereby it is connected to a central control unit (8) connected to the pump (2), the pressure sensor unit (3) and the signal input (21) of the blood detector (6). Apparatus according to claim 1, characterized in that the flushing duct (10) and the outlet duct (11) are made of transparent plastic and the blood detector (6) is provided by an electric light source (22) on one side of the outlet duct (11). ), a photodiode (23) disposed on the opposite side of the pipeline (11) and an amplifier (24) providing a signal proportional to the light emitted to the photodiode (23). Apparatus according to claim 1 or 2, characterized in that the voltage control unit (12) consists of a power transistor (25) controlled by the signal of the blood detector (6) and a voltage drop potentiometer (26) connected to its emitter and collector. 4. Apparatus according to any one of claims 1 to 3, characterized in that the central control unit (8) has a three-input OR gate (14) having first and second inputs via an inverter (15) or integrator (13) to the blood detector (6). connected to a pressure sensor unit (3), wherein the output of the OR gate (14) is connected to the signal input (21) of the signaling unit (9). 5. Apparatus according to any one of claims 1 to 3, characterized in that the signaling unit (9) consists of a power transistor (16) and a sound signal (17a) and / or a light signal (17b) connected in series with it. 6. Apparatus according to any one of claims 1 to 4, characterized in that the pump (2), the pressure measuring unit (3) and the blood detector (6) are provided with one fixing clip. 7. Device according to any one of claims 1 to 3, characterized in that the pump (2) is a voltage controlled peristaltic pump.