RU2093134C1 - Method designed to determine kinetic parameters of electric potentials of acupuncture points, when performing the diagnostics of organism, and device intended for its realization - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: determination of kinetic parameters of electric potentials of acupuncture points in measuring the electric potentials of biologically active points when the latter are exposed to effect of stabilized current in definite modes of operation. Device intended for realization of the given method has computer bus conjugation unit, control register, status register, timer, two units of optoelectronic decoupling, comparator, generator of triangular-shaped signal, amplifier, eight switches, five switching elements, active and passive electrodes, two stabilized current sources, two stabilized voltage sources, and four resistors. EFFECT: more extended field of application. 2 cl, 2 dwg

Description

 The invention relates to medicine and medical equipment and can be used in electropunctural diagnostics of the state of the human body and higher animals.

The closest to the method for determining the kinetic parameters of the electric potentials of acupuncture points in the diagnosis of the body in essence to the proposed method is based on measuring the electrical parameters of the skin at acupuncture points when the object is stabilized by direct current of negative polarity with a force of 8 + 10% μA and recording time intervals from the moment of the onset of exposure, during which a transition process of establishing skin-polarization potentials develops, p Thus, with the size of the interval until the end of the sharp potential change within 7-30 s and with a change in the sign of the potential at the beginning of the interval, pregnancy is diagnosed, with an interval of 40-75 s, a benign neoplasm with a slow growth is diagnosed, with an interval of 75-95 s a benign neoplasm with rapid growth, with an interval of more than 100-105 s, a malignant neoplasm is diagnosed, and with an interval of 30-40 s or with an extremum in the value of the potential, it is diagnosed in inflammatory process [1]
The disadvantage of this method is the relatively narrow scope, limited by the determination of characteristic parameters only for the diagnosis of pregnancy and diseases of the female genital area, as well as the relatively low efficiency, due to the need to form not only the first derivative function that characterizes the change in potential, but also the second and third derivatives.

 The required result is to expand the scope based on the implementation of the possibility of using defined parameters for the diagnosis of human and higher animals, and increasing the efficiency of diagnosis.

 The required technical result regarding the method for determining the kinetic parameters of the electric potentials of acupuncture points in the diagnosis of the organism is achieved by the fact that in the method consisting in measuring the electric potentials of biologically active points when exposed to a stabilized current, the effect is carried out for 20-120 with positive pulses and negative polarity, which determine the anodic and cathodic modes, respectively, at a pulse repetition rate of 0.33 Hz with a duration of 2.7 s, at this, the measured functions use the time functions of the total, active and resistive potentials in both modes, which determine the kinetic parameters, which are the time interval until the maximum on the right reaches the first derivative of the active potential in the cathode mode, the magnitude of the first derivative of the resistive potential in the anode mode , asymptotic values of the active, full and resistive potentials in the anode mode, the maximum value of the resistive potential in the ano SG mode, the time to reach the maximum value in the anode potential of the resistive mode and the asymptotic values of the total and active cathode potentials mode.

 An analysis of the scientific and technical literature showed that prior to the filing date of the application, there were no methods for determining electrical potentials in diagnosing the state of an organism with the indicated set of features. Therefore, the proposal for a method meets the requirement of novelty.

 In addition, the required technical result is achieved by the entire newly introduced set of features, which are not found in the scientific, technical and medical literature. Therefore, the proposal meets the requirement of inventive step.

 At the same time, the description provides detailed recommendations on the implementation of the operations of the method, and also presents the device with which it is implemented in clinical practice. Consequently, the proposal meets the requirement of industrial applicability.

 Closest to the device for implementing the method for determining the kinetic parameters of electric potentials of acupuncture points in the diagnosis of the organism to the proposed device is a device containing a voltage source, a search and pre-excitation circuit, an amplitude indicator, active and passive electrodes, series-connected polarity switching unit connected to a voltage source , a constant stabilized current source and a switching unit connected to an amplitude indicator s, with passive and active electrodes, a time indicator and a pre-excitation switching unit, while the pre-excitation switching unit is connected to the active and passive electrodes, an amplitude indicator, a polarity switching unit and an excitation circuit, and the time indicator is connected to a voltage source (ed. certificate N 1158197, class A 61 H 39/00, 1981).

 The disadvantage of this technical solution is the relatively low accuracy of the determination of parameters caused by the relatively low accuracy of control, relatively narrow functionality and lack of universalization.

 The required technical result is to increase control accuracy by eliminating mechanical switches, expand functionality by using a universal interface, increase the accuracy of parameter determination due to changes in pulse-width conversion and universalization of the device, allowing it to be used as a standard computer unit.

 The required technical result regarding the device for implementing the method for determining the kinetic parameters of the electric potentials of acupuncture points in the diagnosis of the body is achieved by the fact that the device containing passive and active electrodes, the input terminals of which are designed to connect with the patient, the first source of stabilized current, the first and second keys, and a power supply, a control unit, an amplifier, an interface unit, a pulse-width modulator, made in the form of a comparator, the first unit optoelectronic isolation, a deciding unit made in the form of a computer, the data input-output of which is connected to the data input-output of the interface unit, a rectangular pulse generator, the output of which is connected to the first input of the control unit, the second input of which is connected to the output of the first optoelectronic isolation unit, register control, the first output of which is connected to the control input of the power supply, and the second output is connected to the input of the first block of optoelectronic isolation, sequentially connected to the second block of optoelectronic isolation language, the input of which is connected to the output of the comparator, and a timer, a status register, the first input of which is connected to the output of the second optoelectronic isolation unit, the second, third, fourth, fifth and sixth inputs are connected to the zero bus of the device via the same switching elements, and the output is combined with timer input / output and inputs of the control register and the interface unit, the address, read and write inputs of which are connected to the computer output, a triangular waveform generator, the output of which is connected to the first input of the comparator, the second input which is connected to the output of the amplifier, the first and second stabilized voltage sources and a second stabilized current source, the first terminals of which are connected to the first terminal of the first stabilized current source and to the device zero bus, the second terminal of the first stabilized current source is connected to the first terminal of the second switch, the third and the fourth key, the first terminals of which are connected to the second terminals of the first and second sources of stabilized voltage, respectively, the fifth key, the first terminal to which is connected to the output terminal of the active electrode, and the second terminal is connected to the subtracting input of the amplifier, the sixth key, the first terminal of which is connected to the output terminal of the passive electrode, and the second terminal is connected to the summing input of the amplifier, the seventh key, the first terminal of which is connected to the second terminals of the first , the second, third and fourth keys, the eighth key, the first terminal of which is connected to the first terminal of the sixth key, the first resistor, the first terminal of which is connected to the zero bus of the device, and the second to the lemma is connected to the summing input of the amplifier, a second resistor, the first terminal of which is connected to the zero bus of the device, a third resistor, the first terminal of which is connected to the second terminal of the seventh key, and a fourth resistor, the first terminal of which is connected to the second terminals of the second resistor and the eighth key, and the second terminal is connected to the second terminal of the third resistor and the output of the amplifier, while the outputs of the power supply are connected to the corresponding power inputs of the interface unit, status register, timer and register control, and the inputs are the power inputs of the device, and the outputs from the first to the eighth control unit are connected to the control inputs of their corresponding keys from the first to the eighth.

 Analysis of the scientific and technical literature showed that prior to the filing date of the application, there were no devices with the indicated set of features. Consequently, the proposal meets the requirement of novelty.

 In addition, the required technical result is achieved by the newly introduced set of essential features, which are not found in the known literature. Therefore, the proposal meets the requirement of inventive step.

 At the same time, the device includes known elements and gives examples of the constructive implementation of newly introduced elements and all the necessary information for their implementation. Consequently, the proposal meets the requirements of industrial applicability.

 In FIG. 1 shows an electrical block diagram of a device for implementing a method for determining the kinetic parameters of electric potentials of acupuncture points in the diagnosis of an organism; FIG. 2 example of its constructive implementation.

 A device for implementing the method for determining the kinetic parameters of the electric potentials of acupuncture points during body diagnostics (Fig. 1) comprises a computer bus interface unit 1, control register 2, state register 3, timer 4, the input-output of which is combined with the inputs of register 2 and block 1 and with the output of register 3, the first optoelectronic isolation unit 5, the input of which is connected to the output of register 2, and the control unit 6, the square-wave generator, the output of which is connected to the second input of the unit 6, are connected in series to A second optoelectronic isolation unit 8, the output of which is connected to the first inputs of timer 4 and register 3, the input of which is connected to the output of unit 1, a comparator 9, the output of which is connected to the input of the second unit 8, and a triangular-shaped signal generator 10 whose output is connected to the first input a comparator 9, an amplifier 11, the output of which is connected to the second input of the comparator 9, the keys from the first 12-1 to the eighth 12-8, the first resistor 13 connected between the zero bus of the device and the summing input of the amplifier 11, the second resistor 14, the first terminal of which is connected on with the zero bus of the device, the fourth resistor 15 connected between the output of the amplifier and the second terminal of the second resistor 14, combined with the first terminal of the eighth key 12-8, the third resistor 16 connected between the output of the amplifier 11 and the first terminal of the seventh key 12-7, the second the terminal of which is connected to the first terminals of the keys from the first 12-1 to the fourth 12-4, the second terminals of the first 12-1 and second 12-2 keys through their corresponding first 17-1 and second 17-2 stabilized current sources are connected to the zero bus of the device and the second terminals of the third 1 2-3 and the fourth 12-4 keys through the corresponding first 17-3 and second 17-4 stabilized voltage sources are connected to the zero bus of the device, the power supply unit 18, the first input of which is connected to the second output of the register 3, the second and third inputs of which are device power inputs, and the outputs are connected to the corresponding power inputs of unit 1, registers 2, 3, and timer 4, while the second terminals of the sixth 12-6 and eighth 12-8 keys are connected to the output terminal of the passive electrode 20-1, the first terminal the fifth key is connected to the subtracting the amplifier 11, and the second terminal is connected to the output terminal of the active electrode 20-2, the outputs from the first 19-1 to the eighth 19-8 of block 6 are connected to the control inputs of their respective keys from the first 12-1 to the eighth 12-8, and switching elements from the first 21-1 to the fifth 21-5, through which the zero bus of the device is connected to the corresponding inputs of the state register 3.

 The computer bus interface unit 1 can be made as standard and consist of an address decoder, a control signal buffer, a data bus buffer, and a ready signal shaper.

 The control register 2 can be implemented on the KR1533IR35 chip, the status register 3 on the KR1533AP5 chip, and the timer on the KR1810VI54 chip.

 The first 5 and second 8 optoelectronic isolation blocks can be performed on AOT128A optotransistors, a control unit 6 on a K561LN2 chip, a square-wave generator 7 on a standard comparator with an operational amplifier in the feedback circuit, a triangular signal generator 10 on an integrator (KR544UD2 chip) and a comparator (chip KR544UD2), comparator 9 on the chip KR544UD2, amplifier 11 - on the chip KR140UD20.

 The power supply unit 18 can be made in a standard version and consist of a voltage converter, a control pulse generator, a switching element on two transistors, two output voltage stabilizers and power filters.

 Structurally, the device is made in the form of a printed circuit board of the RS XT / AT standard and is installed in the connector of the motherboard (Fig. 2).

 A device is operating to implement a method for determining the kinetic parameters of electric potentials of acupuncture points in the diagnosis of the body as follows.

 The device is designed to analyze the body's response to weak electrical effects at biologically active points based on the determination of the kinetic parameters of the electric potentials of these points and is used in stationary conditions together with a personal computer.

 The device periodically with a frequency of 0.33 Hz generates electric current pulses with a duration of 2.7 s, in the pauses between which the parameters of the change in the potentials of biologically active points are determined, which characterize the body's response to this effect and allow diagnosing various diseases at stages that cannot be recognized by ordinary methods, or in significantly less time.

 The first 5 and second 6 blocks are designed to prevent electric shock to the patient and divide the device into parts (see the dotted line in Fig. 1), which allows you to untie the computer bus and the patient.

 The device is controlled by a computer through a pairing unit 1.

 The control register 2 is used to generate and store three signals that control the operation mode of the amplifier 11. By this, the signals pass through the first block 5 and enter the control unit 6, the other input of which receives signals from the output of the rectangular pulse generator 7. The output signals of block 6 control the keys from the first 12-1 to the eighth 12-8 and determine the current mode of operation of the amplifier 11: "search", "work", "check". Each of these modes, in turn, is divided into time intervals: “exposure interval” and “analysis interval”, the durations of which are determined, respectively, by the duration of the pulse and pause of the generator 7.

 The signal from the output of the amplifier 11 is fed to the input of the comparator 9 and compared in it with the signal fed to the other input of the comparator 9 from the generator 10 of the signals of a triangular shape. When the signal level of amplifier 11 exceeds the signal level of generator 10, rectangular pulses are formed at the output of comparator 9, which are transmitted through the second block 9 to the count control input of timer 4. Pulses with a frequency ten times lower than the frequency of system pulses entering block 1 are fed to its counting input from the computer.

 There are three measurement modes.

 The first mode is test. In this mode, zero voltage is applied to the input of amplifier 11, and the amplifier 11 itself is put into non-inverting mode with a unity gain. Active 20-1 and passive 20-2 electrodes are disconnected from the body. The timer 4 serves pulses with a duty cycle of 2.

 Second search mode. The active electrode 20-1 receives a voltage of +10 V (or -10 V depending on the polarity), and the passive electrode 20-2 is connected to the non-inverting input of the amplifier 11. In the non-inverting mode, the amplifier 11 is used in the unit gain mode. In this mode, pulses are sent to the timer, the duration of which is proportional to the current between the electrodes. In this case, the minimum pulse duration will be at the maximum positive current, and the maximum at the maximum negative input current. Therefore, the values read from the timer are proportional to the current value, but have a constant bias equal to the value obtained at the current equal to zero, which corresponds to the value received from the timer in test mode.

 The third mode is work. The active electrode 20-1 is connected to the inverting input of the amplifier 11, and the passive electrode 20-2 to the output of the amplifier 11. The active electrode 20-1 receives a current from the current source of +8 μA (or -8 kmA, depending on the selected polarity), and in the analysis interval, the current source is turned off. The amplifier 11 is turned on in inverting mode with a gain determined by the resistance of the patient’s body area between the electrodes. The voltage at the output of the operational amplifier in the exposure interval is directly proportional to the resistance included between the electrodes and, in addition, depends on the voltage between the points of their application. In this mode, pulses are sent to timer 4, the duration of which is proportional to the resistance between the electrodes. In this case, the minimum pulse duration will be at maximum resistance at a negative input current, and minimum at maximum resistance at a positive input current. Therefore, the values read from timer 4 are proportional to the resistance value, but have a constant bias. This offset can also be considered as corresponding to the value received from timer 4 in test mode. It is necessary to pay attention to the fact that the deviations of the values read from the timer 4 from the value at zero have a different sign compared to the search mode with the same polarity of the source of action.

 The pulse arriving at timer 4 is simultaneously reflected in the state of the corresponding bit in the state register 3 in order to determine the moment of reading the correct reading from timer 4.

 All voltages necessary for the part of the device galvanically isolated from the computer bus are generated by the power supply unit 18. Register 2 controls allows you to turn on the power of the device.

 As a result of the operation of the device described above, a computer measures the time functions of the full, active and resistive potentials in the anode and cathode modes, which control the kinetic parameters necessary for diagnosing the state of the body. The kinetic parameters are the time intervals until the first derivative of the resistive potential in the cathode mode reaches a maximum on the right, the values of the first derivative of the resistive potential in the anode mode, the asymptotic values of the active, total, and resistive potentials in the anode mode, the time to reach the maximum value of the resistive potential in the anode mode and the asymptotic value of the total and active potentials in the cathode mode.

 In this case, the anodic and cathodic modes correspond to the effects of pulses of positive and negative polarity, the full potential corresponds to the average signal level, and the potential value at a current equal to zero corresponds to the active potential. The resistive potential corresponds to the absolute value of the difference between the total and active potentials.

Claims (2)

 1. The method of determining the kinetic parameters of the electric potentials of acupuncture points in the diagnosis of the body, which consists in measuring the electric potentials of biologically active points when exposed to a stabilized current, characterized in that the effect is carried out for 20 120 with pulses of positive and negative polarity, which determine anodic and cathodic modes, respectively, at a pulse repetition rate of 0.33 Hz with a duration of 2.7 s, using the measured electric potentials t are the time functions of the full, active and resistive potentials in both modes, according to which the kinetic parameters are determined, which are the time interval until the maximum of the first derivative of the active potential in the cathode mode reaches the right, the values of the first derivative of the resistive potential in the anode mode, the asymptotic values of the active, full and resistive potentials in the anode mode, the value of the maximum value of the resistive potential in the anode mode, the time to reach the maximum value the resistive potential in the anode mode and the asymptotic values of the total and active potentials in the cathode mode.  2. A device for determining the kinetic parameters of the electric potentials of acupuncture points in the diagnosis of the body, containing passive and active electrodes, the input terminals of which are designed to connect with the patient, the first stabilized current source, the first and second keys and a power supply, characterized in that the control unit is introduced , amplifier, interface unit, pulse-width modulator, made in the form of a comparator, the first block of optoelectronic isolation, the decisive unit, made in the form of a computer, input-output is given of which is connected to the input / output of the data of the interface unit, a rectangular pulse generator, the output of which is connected to the first input of the control unit, the second input of which is connected to the output of the first block of optoelectronic isolation, the control register, the first output of which is connected to the control input of the power supply, and the second the output is connected to the input of the first optoelectronic isolation unit, the second optoelectronic isolation unit is connected in series, the input of which is connected to the output of the comparator, and the timer, status register, ne the output of which is connected to the output of the second optoelectronic isolation unit, the second, third, fourth, fifth and sixth inputs are connected to the device’s zero bus through the corresponding switching elements, and the output is combined with the timer I / O and the inputs of the control register and the interface unit, address inputs, read and write which is connected to the output of the computer, a triangular signal generator, the output of which is connected to the first input of the comparator, the second input of which is connected to the output of the amplifier, the first and second stabilized voltage sources and a second stabilized current source, the first terminals of which are connected to the first terminal of the first stabilized current source and to the device zero bus, the second terminal of the first stabilized current source is connected to the first terminal of the second switch, the third and fourth switches, the first terminals of which are connected to the second terminals respectively, of the first and second sources of stabilized voltage, the fifth key, the first terminal of which is connected to the output terminals of the active electrode, and the second terminal is is dined with the subtracting input of the amplifier, the sixth key, the first terminal of which is connected to the output terminal of the passive electrode, and the second terminal is connected to the summing input of the amplifier, the seventh key, the first terminal of which is connected to the second terminals of the first, second, third and fourth keys, the eighth key, the first terminal of which is connected to the first terminal of the sixth key, the first resistor, the first terminal of which is connected to the zero bus of the device, and the second terminal is connected to the summing input of the amplifier, the second resistor, the first terminal which is connected to the zero bus of the device, a third resistor, the first terminal of which is connected to the second terminal of the seventh key, and a fourth resistor, the first terminal of which is connected to the second terminals of the second resistor and the eighth key, and the second terminal is connected to the second terminal of the third resistor and the output of the amplifier while the outputs of the power supply are connected to the corresponding inputs of the power supply of the interface unit, status register, timer and control register, and the inputs are the power inputs of the device, the outputs from the first to my control unit connected to the control inputs of the corresponding keys of the first to the eighth.

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