RU2218192C1 - Multifunctional electrotherapeutic device - Google Patents

Abstract

FIELD: medicine, in particular, physiotherapy. SUBSTANCE: the device has four modes of operation: water preparation, ionator, ionophoresis, galvanopuncture. The device uses a photoelectric battery, power unit and a storage cell as power sources. The device has a set of silver electrodes, set of carbon electrodes, set of copper electrodes, set of electrodes in the form of copper needles with gold-plated end-pieces. The device may have a mating module with a personal computer. EFFECT: enhanced functional potentialities, comfort, medicinal efficiency and safety, recurrence of the seances of electrotherapy. 8 cl, 4 dwg

Description

 The invention relates to medicine, in particular to devices for physiotherapy.

 A device for iontophoresis containing a current source and two electrodes is known. The current source is connected by poles so that when the electrodes are fixed on the patient’s skin, a closed circuit is formed [1].

 The disadvantages of this device are: low functionality; the lack of adjustment and control of the current between the electrodes due to the different, individual, resistance of the patient’s skin, it is difficult to ensure the repeatability of the treatment process and determine the necessary procedure time; the unidirectional current flow between the electrodes causes the patient’s body to get used to constant exposure and leads to the development of a response of the body that reduces the therapeutic effect.

 Known silver ionizer type LK-31, containing a power supply, a resistor, a switch having two groups of contacts, and silver electrodes, the positive output of the power supply connected to the first output of the resistor, the second output of which is connected to the movable output of the resistor and in parallel with the first output of the milliammeter , with the second terminal of the last connected the first stationary contact of the first group of switch contacts and parallel to the second stationary contact of the second group of switch, the negative output of the power supply is connected a second fixed contact of the second group and in parallel with the second fixed contact switch of the first group. Two silver electrodes are connected respectively to the first and second movable contacts of the switch [2].

 The disadvantages of the device: low functionality; there is no control over the maximum permissible concentration (MPC) of silver ions; there is no control over the pH of water; there is no bactericidal effect of silver ions in an acidic environment.

 The closest to the invention in technical essence and the achieved effect is an electrotherapy device (prototype) containing a photovoltaic battery with silver or copper coated electrodes with silver coating connected to it [3].

 The disadvantages of the device are: low functionality; the unidirectional flow of direct current between the electrodes causes the patient’s habituation to the constant effect and leads to the development of a response that reduces the therapeutic effect; lack of adjustment and current control between the electrodes; the output voltage of the photovoltaic battery has a nonlinear dependence on illumination (orientation relative to the light source) and, given the fact that the resistance of the patient’s skin areas has different values, it becomes impossible to ensure repeatability of iontophoresis sessions; an electric shock that occurs at the time of connecting the electrodes in the patient leads to pain and excitation of the optic nerve, as a result of which the latter, along with the procedure, receives uncomfortable sensations from light tingling to flashes of “light” in the eyes, depending on the individual sensitivity of the patient.

 The technical result to which the invention is directed is to increase therapeutic efficacy, safety and ensure the repeatability of the results of electrotherapy sessions, increase functionality, comfort.

 The specified technical result is achieved by the fact that the electrotherapy device containing a photovoltaic battery with a connector and a set of electrodes, which consists of two silver electrodes (Ag) with a mating connector for connecting to the device, additionally includes: a power supply, a power controller-switch, a battery , a stabilizer and a microcontroller connected to a current generator, which includes a digital-to-analog converter, amplifier, resistor and capacitor, a keyboard, an indication module, dates current, moreover, the positive terminal of the photovoltaic battery is connected to the first input of the power supply controller-switch, the second input of the latter is connected to the positive output of the power supply unit, the third input of the power supply controller-switch is connected to the positive battery terminal, the fourth input of the power supply controller-switch is connected to the first output of the microcontroller , the first output of the power controller-switch is connected to the input of the stabilizer, the negative terminals of the photoelectric battery, power supply and battery are connected to a common with a gadget, the second output of the power supply controller-switch is connected to the first input of the microcontroller, the terminals of the keyboard matrix are connected by a cable to the polling terminals of its status in the microcontroller, the second input of the microcontroller is connected to the first output of the current sensor and in parallel with the fourth pin of the connector, the second output of the current sensor is connected to wire, the second output of the microcontroller is connected to the input of the digital-to-analog converter of the current generator, the output of the digital-to-analog converter is connected to the input of the amplifier, the output of which connected to the first terminal of the connector and in parallel with the first output of the resistor, the second terminal of the resistor is connected to the second and third contacts of the connector, the first terminal of the capacitor and the third input of the microcontroller, the second terminal of the capacitor is connected to the common wire, the third output of the microcontroller is connected to the input of the display module , the first silver electrode is connected to the second contact of the mate of the connector, the second silver electrode is connected to the fourth contact of the mate of the connector, the outputs are stabilized The ora are connected to the corresponding power inputs of the microcontroller and the amplifier of the current generator, the GND output of the stabilizer is connected to a common wire.

 Additionally, the electrotherapy multifunction device may contain a second set of electrodes, which consists of two silver electrodes with a second counterpart of the connector and a second current sensor, the silver electrodes being rigidly fastened together, the first silver electrode connected to the third contact of the second counterpart of the connector, and the second silver electrode connected to the fifth pin of the second mating connector, the fourth input of the microcontroller is connected to the fifth pin of the connector and in parallel with the first the output of the second current sensor, the second output of which is connected to a common wire.

 Also, the electrotherapy multifunctional device may further comprise a pH sensor, a primary transducer, a third current sensor and a third set of electrodes, which consists of two carbon electrodes (C) with a third mating connector, the output of the pH sensor being connected to the input of the primary converter, the output of which is connected to the fifth input of the microcontroller, the first output of the third current sensor is connected to the fourth input of the microcontroller and the sixth pin of the connector connected in parallel, the first carbon ektrod connected to the first terminal of the third mating connector, the second carbon electrode is connected with the sixth terminal of the third mating connector.

 In addition, the electrotherapy multifunction device may contain a real-time clock, a second connector and a removable patient data memory module, the output of the real-time clock being connected to the sixth input of the microcontroller, the fourth output of which is connected through the first contact of the second connector to the input of the patient data memory module, the output of the last connected through the second contact of the second connector to the seventh input of the microcontroller.

 Also, the electrotherapy multifunctional device may further comprise a module for interfacing with a personal computer.

 Additionally, the electrotherapy multifunction device may contain a fourth set of electrophoresis electrodes, which consists of two electrodes made of copper (Cu), the first electrode being connected to the first contact of the first mating connector and the second electrode connected to the sixth contact of the first mating connector.

 Also, the electrotherapy multifunction device may additionally contain a fifth set of electrodes, consisting of two electrodes made in the form of copper needles with gold-plated tips, with the first mating connector, the first electrode connected to the second contact of the first mating connector, and the second electrode connected to the fourth contact of the first mating connector.

 This embodiment of the electrotherapeutic multifunctional device allows us to solve the problem of creating an electrotherapeutic multifunctional device with increased functionality; comfort; therapeutic efficacy and safety, allowing to obtain repeatability and taking into account the results of physiotherapy sessions that preserve the individual characteristics of the client - individual resistance of body parts, current regimes optimal for the patient, as well as time parameters of electrotherapy sessions in an electronic computer database.

 The functional diagram of the electrotherapy multifunction device is presented in figure 1.

 The electrotherapy device is multifunctional, the device further comprises a photovoltaic battery 1, a power supply 2, a power switch controller 3, a battery 4, a stabilizer 5 and a microcontroller 6 connected to a current generator 9, which includes a digital-to-analog converter 11, an amplifier 10, a resistor R and a capacitor C, a keyboard 7, an indicating module 8, a current sensor R1, a connector X1.1, and a set of electrodes for iontophoresis 12, consisting of two silver electrodes (Ag) with a mating connector X1.2 for connecting to the device.

 The positive terminal of the photovoltaic battery 1 is connected to the first input of the power supply controller-switch 3, the second input of the latter is connected to the positive output of the power supply unit 2, the third input of the power supply controller-switch 3 is connected to the positive output of the battery, the fourth input of the power supply controller-switch 3 is connected to the first output microcontroller 6. The first output of the controller-power switch 3 is connected to the input of the stabilizer 5. The minus terminals of the photovoltaic battery 1 and battery 4, as well as the negative output of the power supply us to ground. The second output of the controller-power switch 3 is connected to the first input of the microcontroller 6.

 The terminals of the keyboard matrix 7 are connected by a cable to the polling terminals of its status in the microcontroller 6, the keyboard 7 is implemented as a matrix of 3x4 keys, of which three outputs and four inputs. The keyboard 7 is connected to the corresponding terminals for interrogating the state of the microcontroller 6 with a cable consisting of seven conductors. The second input of the microcontroller 6 is connected to the first output of the current sensor R1 and in parallel with the fourth pin of the connector, the second output of the current sensor R1 is connected to a common wire. The second output of the microcontroller 6 is connected to the input of the digital-to-analog converter 11 of the current generator 9, the output of the digital-to-analog converter 11 is connected to the input of the amplifier 10, the output of which is connected to the first terminal of connector X1.1 and in parallel with the first terminal of resistor R. The second terminal of resistor R is connected to parallel the second and third contacts of the connector X1.1, the first output of the capacitor C and the third input of the microcontroller 6, the second output of the capacitor is connected to a common wire. The third output of the microcontroller 6 is connected to the input of the indicating module 8. The first silver electrode is connected to the second contact of the counterpart of connector X1.2, the second silver electrode is connected to the fourth contact of the counterpart of connector X1.2. The outputs of the stabilizer 5 are connected to the corresponding power inputs of the microcontroller 6 and the amplifier 10 of the current generator 9, the output GND of the stabilizer 5 is connected to a common wire.

 Additionally, the electrotherapy multifunctional device contains a second set of silver electrodes 13, consisting of two silver electrodes with a second counterpart of connector X1.3 and a second current sensor R2. Silver electrodes are rigidly bonded to each other. The first silver electrode is connected to the third pin of the second counterpart of connector X1.3, and the second silver electrode is connected to the fifth pin of the second counterpart of connector X1.3, the fourth input of the microcontroller 6 is connected to the fifth pin of connector X1.1 and in parallel with the first output of the second sensor current R2, the second terminal of which is connected to a common wire.

 Also, the electrotherapy multifunctional device further comprises a pH sensor 15, a primary transducer 16, a third current sensor R3 and a third set of electrodes 14, consisting of two carbon electrodes (C) with a third counterpart of connector X1.4. The output of the pH sensor 15 is connected to the input of the primary Converter 16, the output of which is connected to the fifth input of the microcontroller 6. The first output of the third current sensor R3 is connected to the fourth input of the microcontroller 6 and the sixth pin of connector X1.1. The first carbon electrode is connected to the first contact of the third counterpart of connector X1.4, and the second carbon electrode is connected to the sixth contact of the third counterpart of connector X1.4.

 In addition, the electrotherapy multifunction device contains a real-time clock 17, a second connector X2 and a removable patient data memory module (electronic card) 18. The output of the real-time clock 17 is connected to the sixth input of the microcontroller 6, the fourth output of which is connected through the first contact of the second connector X2 to the input of the patient data memory module 18, the output of the latter is connected through the second contact of the second connector X2 to the seventh input of the microcontroller 6.

 Also, the electrotherapy multifunction device may further comprise a module for interfacing with a personal computer for reading data from a removable patient data memory module (electronic card).

 Additionally, the electrotherapy multifunction device contains a fourth set of electrodes 19, consisting of two electrodes made of copper (Cu), with a first mating connector. The first electrode is connected to the first contact of the first counterpart of connector X1.2, and the second electrode is connected to the sixth contact of the first counterpart of connector X1.2.

 Also, the electrotherapy multifunctional device further comprises a fifth set of electrodes 20, consisting of two electrodes made in the form of needles made of copper (Cu) with gold-plated tips (Au), with the first counterpart of the connector, the first electrode being connected to the second contact of the first counterpart of the connector X1 .2, and the second electrode is connected to the fourth pin of the first mating connector X1.2.

 The first, second, third, fourth and fifth inputs of the microcontroller 6 are the analog inputs of the built-in analog-to-digital Converter.

 Microcontroller 6, which is the basis of the electrotherapy multifunction device, is based on the AT90LS2333 AVR RISC microcontroller from Atmel Inc with a built-in analog-to-digital converter, photovoltaic battery 1 - MSM-5-70 manufactured by Ryazan Metal Ceramic Instruments Plant, power supply controller-switch 3 is made on microcircuits DS 1611 - a controller of four power supplies and DS 1336 - a switch for main and battery (battery) power circuits of Dallas Inc, a replaceable patient data memory module 18 n based on the AT25C160 chip from Atmel Inc, the real-time clock 17 is made on a DS 1307 chip from Dallas Inc, the amplifier 10 is on a K1460UD2P chip manufactured by the STC of the CIS in Bryansk. Silver electrodes can be made of silver or silver-plated copper; a combination of one copper and one silver electrode is possible. The electrodes can be made in the form of rods, plates, needles and their combination or in the form of group probes. Instead of current sensors R1, R2, and R3, one common current sensor R1 can be used.

A feature of the electrotherapy multifunctional device is: the use of a combined power system, which allows it to be used both in stationary and in field conditions; increased functionality - four operating modes:
1) iontophoresis mode, silver ones are used - of the first set and / or copper electrodes - of the fourth set, graphs of the output voltage are shown in figure 2;
2) the mode of the ionizer, silver electrodes of the second set are used, the graphs of the output voltage are shown in figure 3;
3) the water treatment mode with pH control, carbon electrodes of the third set are used, the graph of the output voltage is shown in figure 4;
4) the mode of electro-puncture and electro-acupuncture, silver electrodes of the first set and gold-plated electrodes of the fifth set are used, the graphs of the output voltage are similar to the first mode, shown in figure 2. The shape of the output voltage and current can additionally be changed by entering from the keyboard of the device using mathematical functions.

 The use of iontophoresis according to the method of treatment by the method of local electrophoresis of patients with diabetes mellitus of the initial stage, proposed by B.I. Bleskin [3], will reduce the dose of drugs, and in some cases completely replace drug electrotherapy with iontophoresis.

 The electrotherapeutic multifunction device operates as follows.

 When the device is turned on, the microcontroller 6 diagnoses the device, from the first output of the microcontroller 6, a signal is received with the code of the source 3 connected to the second output of the controller-switch 3 — a photovoltaic battery 1, a power supply 2, or a battery 4. The microcontroller 6 measures the voltage at its first input. The priority of use is power supply 2, photovoltaic battery 1 and battery 4. When operating from power supply 2 or photovoltaic battery 1, battery 4 is simultaneously charged. Battery 4 is used in the field in the dark or in poor lighting of photovoltaic battery 1.

 Before starting work, prepare an aqueous solution containing an ionic silver agent - silver water. The bactericidal effect of Ag + silver is higher at alkaline pH. At pH values of 8 and 9, the death of bacteria is accelerated by 1.8 times compared with a neutral medium, and in an acidic environment, the bactericidal effect of silver ions is practically absent. Therefore, before preparing the silver solution, water is treated using the third set - carbon electrodes. Using the counterpart of connector X1.4, carbon electrodes are connected to the device. A vessel is taken, the required amount of water is poured, a tarpaulin glass and carbon electrodes are lowered into the vessel, so that the positive carbon electrode is in the tarpaulin glass and the negative is outside. Lower the pH 15 sensor into the beaker. Turn on the device. On the keyboard 7 dial the code of the water treatment mode and the required pH of the solution. The microcontroller 6 sets the maximum possible code at the second output, which is fed to the input of the digital-to-analog converter 11 of the current generator 9, from the output of which, through the amplifier 10 and the first contact of the connector X1.10, the current is supplied to the third set of carbon electrodes 14.

 The current between the electrodes is controlled by the microcontroller 6, measures the voltage drop at the third current sensor R3, which is fed to the fifth input of the microcontroller 6, then, according to Ohm's law, it calculates the real value of the flowing current. Information on the current pH value is received from the pH sensor 15 through the primary converter 16 to the fifth input of the microcontroller 6. When the pH value entered from the keyboard 7 of the device reaches the microcontroller 6, the current between the electrodes is turned off, for which it sends a zero code to the input of the digital-analog converter 11 of the current generator 9 its second exit.

 The operation mode is indicated by a two-color LED, which is part of the display module 8. The current flow between the electrodes is indicated by a red LED, and the end of the mode is indicated by a green LED. When the required pH is reached, an end-mode sound signal is generated using the piezo emitter of display module 8. The process time T0 depends on the salt composition of water, time T2 is the area of regulation of a given pH. In a tarpaulin glass, water with an acidic medium, the so-called "dead" water, is obtained, and in the rest, water with a given pH value, the so-called "live" water. Carefully remove the tarpaulin glass from the vessel and pour the acidic water into the previously prepared container. Acid and alkaline water can be used independently for medical purposes for external and internal use.

Ion mode. Preparation of "silver" water (water containing an ionic silver agent). For the solution, either pre-purified water or alkaline "living" water with the required pH value is taken. To prepare small amounts of the solution, electrodes for iontophoresis 12 can be used, and large electrodes of the ionizer 13. Connect with the help of the counterpart of connector X1.2 or X1.3, the corresponding set of electrodes is the first or second, turn on the device and enter the mode code from the keyboard 7 ionizer (unipolar or bipolar), enter data on the volume of the prepared solution and the required concentration of silver ions in the solution. The dosage of the amount of silver transferred to the solution is calculated according to the Faraday law by the microcontroller 6. The amount of silver m in milligrams (mg) dissolved in water as a result of electrolysis is determined by the formula
m = KIT0 n / 100,
where: K is the electrochemical equivalent of silver, equal to 1.118 mg / As; I is the strength of the current passing through water A (I = Ux / Re, where Ux is the voltage at the electrodes, Re is the distributed resistance between the electrodes); T0 is the electrolysis time, s; n is the silver current output, depending on the salt composition of water, equal to 80-90%, is determined by a pH sensor 15. The electrolysis time calculates, sets and monitors the microcontroller 6 using a real-time clock 17.

 The use of a bipolar mode allows to reduce the wear of silver electrodes, and unipolar - to apply a set of one (positive) silver electrode and one copper electrode, which reduces the cost of a set of electrodes. The operating mode is indicated by a two-color LED, which is part of the display module 8. The current flow between the electrodes is indicated by red light, and the end of the mode is green. The concentration of silver in the solution is calculated by the microcontroller 3 and displays the indicating module 8 on the digital display with a step of one second. When the required concentration of silver ions is reached, an end signal is issued using the piezo emitter of the indicating module 8. The silver water solution is ready for iontophoresis, disinfection or aerosol inhalation.

 Iontophoresis mode.

 For the treatment process by iontophoresis, the positive (anode) and negative (cathode) electrodes of the first set of 12 silver electrodes are wrapped with cotton wool, moistened with prepared silver water and tightly fixed to the patient's body. Using the mating connector X1.2, connect the electrodes to the device’s connector X1.1. Next, an individual data memory module 18 of the patient is connected using connector X2. Turn on the device. From the keyboard 7 enter: iontophoresis mode code (diagnostic, determining the optimal current for the patient or procedural: unipolar positive; unipolar negative and bipolar modes); patient registration code. Then, if necessary, an initial measurement procedure is carried out. The microcontroller 6 sets using a current generator 9 mode of linearly changing (increasing) current in the range from 0 to 10 mA. At the time of the patient’s sensation of slight tingling, the current change at the device output from the keyboard 7 is stopped and the received current value reduced by 5% is recorded in the patient data memory module 18, for which the microcontroller 6 measures the voltage at its third input and calculates the resistance value of the body section the patient, which is then fixed in the patient data memory module 18.

 The doctor gradually creates a patient databank on the resistance of characteristic sections of the patient’s body with the assignment of the code of the body section in accordance with the anatomical atlas. When carrying out the repeated procedure, the previously recorded value is used. After the session, the doctor rewrites the new data through the interface module with the personal computer into a common computer database. To conduct the treatment process by the method of endonasal (e.g. intranasal) iontophoresis, a silver electrode bisected into two probes is used, wrapped with cotton wool, moistened with silver water and inserted into the patient's nostrils. The second electrode is wrapped with cotton, moistened with water and tightly fixed on the cervical region of the patient. Next, carry out the procedure for measuring the resistance of a portion of the patient’s body with recording the result in the patient data memory module 18. The difference is in changing the range of allowed currents between the electrodes. When determining the individual sensitivity of the patient, the current between the electrodes varies from 0 to 1 mA. The range of variation of the output current can be quickly changed by entering a new range of values from the keyboard 6 of the device.

 When conducting therapeutic iontophoresis, the doctor selects the exposure parameters: t1, T0, t2, T1, where t1 is the rise time of the current (voltage) to the operating value; T0 is the pulse time of electrotherapeutic iontophoresis, t2 is the current (voltage) decay time; T1 is the time interval between exposures; Ux is the voltage at the electrodes, is formed by the microcontroller 6 based on the individual patient data, and determines the current between the electrodes.

 Electropuncture and electroacupuncture mode.

 The therapeutic effect can be carried out in two ways: by the method of electro-puncture - electrodes are used for external electrical exposure to the active points of the patient; by the method of electroacupuncture - electrical exposure is carried out on the subcutaneous tissue at the acupuncture points using the first set of 12 silver or the fifth set of 20 gold-plated copper electrodes. The electrodes are connected to the device using the mating connector X1.2. Work is carried out on the atlas of active points. Each point on the atlas is assigned a different code from the point codes for iontophoresis.

 At the beginning of work with the patient, initial testing is performed. Enter the measurement mode from the keyboard 6 of the device. The negative electrode is wrapped with cotton dipped in water and left clamped in the patient's hand. The second electrode is found at the minimum resistance, which is indicated on the display module 8, the active point and register the point code and the obtained value in the patient data memory module 18. Next, search for other active points necessary during the treatment, using the comparison method with the previously recorded measurement result and mark them on the patient’s body. During the treatment session, the doctor selects the exposure parameters: t1, T0, t2, T1, where t1 is the current (voltage) rise time to the operating value; T0 is the pulse time of the electrotherapeutic effect, t2 is the current (voltage) decay time; T1 is the time interval between exposures; Ux is the voltage at the electrodes, is formed by the microcontroller 6 based on the individual patient data. Further, the procedure for conducting a treatment session is similar to the iontophoresis regimen.

Sources of information
1. Description of the invention to the copyright certificate SU 1152595 A, cl. A 61 N 1/18, 1982

 2. Kulsky L.A. In the book: "Silver Water", Kiev, 1977.

 3. Description of the invention to patent RU 2000125 C, cl. A 61 N 1/20, 1/30, 1991

Claims (8)

1. A multifunction electrotherapy device containing a photoelectric battery, a connector and a set of electrodes, consisting of two silver electrodes with a mating connector for connecting to the device, a power supply unit, a power controller-switch, a battery, a stabilizer, and a microcontroller connected to a current generator, which includes a digital-to-analog converter, amplifier, resistor and capacitor, a keyboard, an indication module, a current sensor, and the positive output of the photoelectric battery is connected with the first input of the power supply controller-switch, the second input of the last one is connected to the positive output of the power supply unit, the third input of the power supply controller-switch is connected to the battery positive output, the fourth input of the power supply controller-switch is connected to the first output of the microcontroller, the first output of the power supply controller-switch is connected to the input of the stabilizer, the negative terminals of the photovoltaic battery, power supply and battery are connected to a common wire, the second output of the controller-power switch is connected to the first during the microcontroller, the terminals of the keyboard matrix are connected by a cable to the polling terminals of its state in the microcontroller, the second input of the microcontroller is connected to the first output of the current sensor and, in parallel, to the fourth pin of the connector, the second output of the current sensor is connected to a common wire, the second output of the microcontroller is connected to the digital input -analog converter of the current generator, the output of the digital-to-analog converter is connected to the input of the amplifier, the output of which is connected to the first contact of the connector and, in parallel, to the first output resistor, the second terminal of the resistor is connected to the second and third pins of the connector connected in parallel, the first terminal of the capacitor and the third input of the microcontroller, the second terminal of the capacitor is connected to a common wire, the third output of the microcontroller is connected to the input of the display module, the first silver electrode is connected to the second contact of the mating connector , the second silver electrode is connected to the fourth contact of the mating connector, the stabilizer outputs are connected to the corresponding power inputs of the microcontroller and amplifier of the current generator, the output of the GND stabilizer is connected to a common wire. 2. The electrotherapeutic multifunctional device according to claim 1, characterized in that an additional second set of electrodes is introduced, consisting of two silver electrodes with a second counterpart of the connector and a second current sensor, the silver electrodes being rigidly bonded to each other, the first silver electrode is connected to the third contact the second mate of the connector, the second silver electrode is connected to the fifth pin of the second mate of the connector, the fourth input of the microcontroller is connected to the fifth pin of the connector and, in parallel specifically, with the first terminal of the second current sensor, the second terminal of which is connected to a common wire. 3. The electrotherapy device is multifunctional according to claims 1 and 2, characterized in that an additional pH sensor, a primary converter, a third current sensor and a third set of electrodes are introduced, consisting of two carbon electrodes with a third mating connector, the output of the pH sensor being connected to the input a primary converter, the output of which is connected to the fifth input of the microcontroller, the first output of the third current sensor is connected to the fifth input of the microcontroller and the sixth pin of the connector, connected in parallel, the first ny electrode connected to the first terminal of the third mating connector, the second carbon electrode is connected with the sixth terminal of the third mating connector. 4. The electrotherapy multifunction device according to claims 1 to 3, characterized in that an additional real-time clock, a second connector and a removable patient data memory module are introduced, the output of the real-time clock being connected to the sixth input of the microcontroller, the fourth output of which is connected through the first contact of the second connector with the input of the patient data memory module, the output of the latter is connected through the second contact of the second connector to the seventh input of the microcontroller. 5. The electrotherapy multifunctional device according to claim 4, characterized in that a module for interfacing with a personal computer is introduced. 6. The electrotherapy device is multifunctional according to claims 1-5, characterized in that it further comprises a fourth set of electrodes, consisting of two electrodes made of copper, with a first counterpart of the connector, the first electrode being connected to the second contact of the first counterpart of the connector, and the second electrode is connected to the fourth contact of the first mating connector. 7. The electrotherapy device is multifunctional according to claims 1 to 6, characterized in that it further comprises a fifth set of electrodes, consisting of two electrodes made in the form of copper needles with gold-plated tips, with a first mating connector, the first electrode being connected to the second contact the first mate of the connector, and the second electrode is connected to the fourth contact of the first mate of the connector. 8. The electrotherapy device is multifunctional according to claims 1 and 2, characterized in that in the set of silver electrodes one of them is made of silver, and the other is made of copper with a silver coating.

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