RU2177717C1 - Method and device for measurement of electric parameters of dermatic and mucosal integuments - Google Patents

Abstract

FIELD: medicine and medical equipment, applicable for estimation of the condition of a biological object according to the electrophysical parameters of its integuments. SUBSTANCE: the method consists in installation of electrodes on the object of measurement testing the action on the object of measurement, as well as in measurement and estimation of the nature of variation of voltage across the electrodes during the testing action. The testing action is accomplished by successive transmission of pulses of current stable in amplitude of the negative and positive polarities respectively. The duration of transmission of a current pulse of the positive polarity exceeds the duration of transmission of a current pulse of he negative polarity at least by one and a half times. The valve of amplitude of the current of the negative polarity exceeds the value of amplitude of the current of the positive polarity at least by one and a half times. The device for measurement of electric parameters of dermatic and mucosal integuments has a basic and measuring electrodes, generators for shaping of current pulses of the negative and positive polarities respectively, synchronizer, measuring amplifier, unit for estimation of the parameters of the measurement object, and a unit for gathering and processing of information. EFFECT: reduced exciting action of the testing current on the nervous and muscular tissues of the object of measurement at simultaneous intactness of the functional condition of the object of measurement. 24 cl, 9 dwg

Description

 The invention relates to medicine and medical equipment, and in particular to methods and devices for assessing the state of a biological object by the electrophysical parameters of its integument, and can be used in functional and electropuncture diagnostics for static and dynamic assessment of a person’s condition based on electrophysical parameters of the surface of his skin and mucous membranes integument, as well as for an integrated assessment of the influence of various medical, natural and other factors on the human body.

 A known method for assessing the electrophysical state of acupuncture points and a device for its implementation (see, for example, US patent 3971388, class A 61 5/04, publ. 07.27.76). In a well-known source of information on the parameters of the transition process, the parameters of the equivalent electrical equivalent circuit of the local area of the skin in the area of the acupuncture point are evaluated. The disadvantages of the known method and device with which it is carried out include the impossibility of ensuring the necessary reproducibility and repeatability of the results, which is caused by the increased inertia of the measuring device, as well as the damaging effect on the cells of the measurement object in the near-electrode region. In addition, when implementing the known method and device in practice, impregnation of the metal of the electrodes into the skin under them and the so-called electrochemical breakdown under the measuring electrode are noted, which does not allow to maintain the intactness of the functional state of the object of study.

 The closest in essence and the technical result achieved are a method for measuring electric skin resistance and a device for its implementation (see, for example, RF patent 2116750, class A 61 B 5/05, publ. 10.08.98), which partially eliminates the disadvantages of the above analogue. The known method involves the installation of electrodes on the measurement object, testing the impact on the measurement object by transmitting between the electrodes a pulse of amplitude-stable current of negative polarity, as well as measuring and evaluating the nature of the voltage change between the electrodes during the testing effect. The device with which the known method is implemented includes a base electrode, a measuring electrode, a generator for generating a current pulse of negative polarity and a unit for collecting and processing information. The disadvantages of the known method and device include significant polarization of the measurement object, which occurs, as shown by studies, after the sixth measurement cycle. This drawback leads to a distortion of the diagnostic results and, therefore, adversely affects the accuracy, reproducibility and repeatability of the results of the evaluation of the studied biological object. In addition, the known method of measuring electric skin resistance and a device for its implementation are intended to evaluate only the resistive component of the electric skin resistance of the measurement object, which from a methodological point of view significantly narrows their scope, in particular, during dynamic diagnostics and dynamic assessment of the influence of various factors on the body person.

 The invention is directed to the creation of such a method for measuring the electrical parameters of the skin and mucous membranes and a device for its implementation, which would improve the accuracy and reproducibility of the results obtained with static and dynamic diagnostics. The technical result that can be obtained by implementing the invention is to reduce the exciting effect of the test current on the nervous and muscle tissue of the measurement object while maintaining the intactness of the functional state of the measurement object.

 The problem is solved due to the fact that in the method of measuring the electrical parameters of the skin and mucous membranes, according to which the electrodes are installed on the measurement object, a test effect is applied to the measurement object by transmitting between the electrodes a pulse of a negative amplitude polarity-stable current and measuring and evaluating the nature of the voltage change between the electrodes during the test action, during the test action between the electrodes, an additional pulse of st the amplitude of the current of positive polarity that follows the current pulse of negative polarity, while the duration of the current pulse of positive polarity is not less than one and a half times the duration of the current pulse of negative polarity, and the amplitude of the current of negative polarity is not less than one and a half times the magnitude of the amplitude of the current of positive polarity.

 One of the variants of the preferred embodiment of the method is implemented provided that at least one additional testing effect is performed on the measurement object with a time delay, which allows to expand the scope of the method due to the possibility of dynamic diagnostics.

 When conducting dynamic diagnostics of the measurement object according to one of the options, it is preferable that the duration of the delay in the time of submission of an additional test effect would be at least 1.68 of the total duration of one test effect. This technique allows to increase the accuracy of measurements and reduce the effect of residual polarization on the measurement results.

 According to the second embodiment of the measurement method for conducting dynamic diagnostics, it is preferable that the delay time for the additional test action is at least 1300 ms, which will also improve the accuracy of the additional measurements and reduce the effect of residual polarization on the measurement results.

 When implementing any of the above variants of the method, it is advisable to supply a current pulse of positive polarity with a time delay. The use of this technique allows to increase the accuracy of measurement of such diagnostic parameters as the repolarization capacity of the measurement object and the dispersion index of the repolarization process.

 In another embodiment of the method, it is preferable that the duration of the supply of a current pulse of negative polarity to the electrodes be at least 120 ms and no more than 380 ms, which increases the accuracy of the measurements when passing a current pulse of negative polarity.

 In another embodiment of the method, it is preferable that the duration of the supply of a current pulse of positive polarity to the electrodes be at least 180 ms and not more than 1140 ms, which will improve the accuracy of the measurements when passing a current pulse of positive polarity.

 The technical result obtained by implementing the method is improved provided that the power of the current pulse of negative or positive polarity supplied to the measurement object is at least 0.08 mW and not more than 0.13 mW. This embodiment of the method allows you to save the biological intactness of the functional state of the measurement object.

 One of the variants of the preferred embodiment of the method is realized when the amount of electricity supplied through the electrodes to the measurement object during the period of the positive current pulse is equal to the amount of electricity supplied through the electrodes to the measurement object during the period of the negative current pulse, which reduces polarization object of measurement and, therefore, provides repeatability of the results of the evaluation of a biological object.

In one embodiment of the method, it is preferable that during the test exposure the current density would be at least 2.5 μA / cm ² and not more than 36.6 μA / cm ² . With the above optimal parameters, the likelihood of adverse current effects on the measurement object is reduced.

In another embodiment of the method, it is preferable that the rate of change of the front and the rate of change of the decay of the current pulse density of negative and / or positive polarity be at least 0.3 μA / cm ms and not more than 0.8 μA / cm ² ms in absolute value, in this case, the nature of the change in the front and decrease in the current pulse density is set using the same mathematical dependencies, which allows us to maintain the intactness of the functional state of the measurement object.

 In another embodiment of the method, it is preferable that the voltage measurement during the passage of the current pulse of negative polarity be carried out not less than 100 ms and not more than 250 ms after the start of the current pulse. With this embodiment of the method, the measurement accuracy increases due to an increase in the noise immunity of the obtained estimates.

 One of the variants of the preferred embodiment of the method is implemented in the case when the voltage measurement during the passage of the current pulse of positive polarity is carried out not less than 200 ms and not more than 400 ms after the start of the current pulse. This embodiment of the method allows to increase the measurement accuracy by increasing the noise immunity of the obtained estimates.

 When implementing the last two variants of the method, it is most preferable that the duration of voltage measurements during the passage of a current pulse of positive and / or negative polarity be at least 20 ms. With this embodiment of the method, the measurement accuracy increases due to an increase in the noise immunity of the obtained estimates.

 The technical result obtained is improved in the case of the preferred implementation of the method, when when changing the polarity of the current pulses carry out an additional voltage measurement and assess the nature of the voltage change between the electrodes. The use of this technique allows you to expand the scope of the method due to the possibility of obtaining additional data for evaluating the reactive properties of the measurement site (capacitive parameters or parameters of the endogenous electromotive force), which, in particular, can analyze the stationarity of the repolarization process.

 When implementing the above advantageous variant of the method, it is most preferable to start additional voltage measurement and evaluate the nature of the voltage change from the beginning of the decay of the current pulse of negative polarity and continue until the voltage stabilizes, which will improve the accuracy of the results while maintaining the biological intactness of the measurement object.

 One of the preferable is such an embodiment of the method, in which, after the end of the testing action, the duration and nature of the transition process of restoration of the electrical properties of the measurement object are recorded. The implementation of this technique allows you to expand the scope of the method due to the fact that it becomes possible to obtain additional information about the reactive components of the equivalent circuit of the measurement site, which helps to identify abnormal trends in the response of a biological object to a test pulse.

 One of the options for the predominant implementation of the method is implemented in the case when one of the electrodes is made active, which will ensure the reproducibility of the measurement results during static diagnostics.

In the above advantageous embodiment of the method, the most optimal method is when the specific pressure on the object of measurement of the active electrode is not less than 400 g / cm ² and not more than 1600 g / cm ² , which improves the stability of the process and the measurement results.

 The problem is also solved due to the fact that the device for measuring the electrical parameters of the skin and mucous membranes, which contains a base electrode, a measuring electrode, a generator for generating a current pulse of negative polarity and a unit for collecting and processing information, is equipped with a generator for generating a current pulse of positive polarity , a synchronization unit, a measuring amplifier and a unit for evaluating the parameters of the measurement object, while the base electrode is connected to the first input of the measuring amplifier, and the measuring electrode is connected in parallel with the corresponding outputs of the generators for generating current pulses of negative and positive polarity and with the second input of the measuring amplifier, the synchronization unit being parallel connected with the corresponding inputs of generators for generating current pulses of negative and positive polarity and with the second and third inputs a block for evaluating the parameters of the measurement object, and a block for evaluating the parameters of the measurement object with its first input connected to a measuring amplifier and its outputs - with a unit for collecting and processing information.

 One of the preferred embodiments of the device is realized when the contact area of the base electrode is not less than 75 times the contact area of the measuring electrode, which allows to increase the accuracy and reliability of measurements by eliminating electromagnetic interference to the measurement object.

 Another advantageous embodiment of the device provides for connecting a unit for collecting and processing information with a synchronization unit, which allows to accelerate the process of assessing the nature of voltage changes during static diagnostics.

 According to one of the variants of the preferred embodiment of the device, the measuring electrode can be made active. This embodiment of the design of the device will ensure reproducibility of the measurement results during static diagnostics.

 When implementing the aforementioned preferred embodiment of the device, it is most expedient that the measuring electrode is connected to the input of the synchronization unit, which ensures reproducibility of the measurement results during static diagnostics.

 Preferred is the embodiment of the device in which it is made with a switch and at least one additional measuring electrode, while the main and additional measuring electrodes are connected to the corresponding outputs of the generators for generating current pulses of negative and positive polarity through the switch, and the unit for the collection and processing of information is connected to the switch, which will expand the scope of the device by providing the opportunity held Measuring at several points during dynamic diagnostics.

 One of the preferred options for constructive implementation of the device provides for its implementation with a resonator of a homeopathic preparation for transferring to the measurement object through the measuring and / or base electrode the frequency properties of the test drug or its electronic copy, which also allows you to expand the scope of the device due to the possibility of determining the reaction of the measurement object to the studied drug or its electronic copy.

 The invention is illustrated by drawings, where in FIG. 1 shows the nature of the change in the current pulse of negative and positive polarity when testing the effect on the measurement object; in FIG. 2 - the same, for two testing impacts; in FIG. 3 - the nature of the voltage change between the electrodes in one measurement cycle; in FIG. 4 is a functional diagram of a device for measuring electrical parameters of the skin and mucous membranes; in FIG. 5 - the same when using an active measuring electrode; in FIG. 6 - the same, when using an additional measuring electrode; in FIG. 7 is a schematic diagram of a synchronization unit; in FIG. 8 is a schematic diagram of a generator for generating a current pulse; and FIG. 9 is a schematic diagram of a unit for evaluating the parameters of the measurement object.

In accordance with the method of measuring the electrical parameters of the skin and mucous membranes, the base electrode 1 and the measuring electrode 2 are installed on the surface of the measurement object 3 (bioobject) and fixed at the measurement sites, for example, using adhesive tape. It should be noted that in order to ensure the equivalence of all subsequent measurements, the base electrode 1 must be at least 10 cm from any measurement point, that is, from the measuring electrode 2. Then, a test action is taken on the measurement object 3 by passing between the electrodes 1 and 2 pulses of amplitude-stable current of negative polarity and a pulse of amplitude-stable current of positive polarity. In this case, a current pulse of positive polarity is passed between the electrodes 1 and 2 after passing between the last current pulse of negative polarity. The duration (T ₂ ) of supplying a current pulse of positive polarity is not less than one and a half times the duration (T ₁ ) of supplying a current pulse of negative polarity, that is, the following condition is met: T ₂ ≥1.5 T ₁ (Fig. 1). At the same time, the magnitude (I ₁ ) of the amplitude of the current of negative polarity is not less than one and a half times the value (I ₂ ) of the amplitude of the current of positive polarity, that is, the condition must be met: I ₁ ≥1.5I ₂ . The indicated relations between pulse durations and current values when passing current pulses of negative and positive polarity are interconnected to obtain the indicated technical result and are obtained empirically. During the testing effect on the measurement object 3, the measurement and evaluation of the nature of the voltage change between the electrodes 1 and 2 are carried out. Based on the data obtained during the measurement, the diagnostic parameters of the biological object are determined, for example, the values of active resistance, respectively, during the passage of negative and positive current pulses during testing effect.

 On the object 3 of the measurement can be carried out one test action, which allows for its static diagnosis. At least one additional testing effect can be performed on the measurement object 3 with a time delay (Fig. 2). Moreover, all parameters of the additional testing effect must comply with the above conditions for the main (first) testing effect.

It has been established that the empirically preferred duration (T ₄ ) of the delay in the time of the additional testing effect on the measurement object is at least 1.68 of the duration (T ₃ ) of the main testing effect, that is, the conditions must be met: T ₄ ≥1.68 T ₃ . The specified ratio is optimal in the case when the durations of the main (T ₃ ) and additional (T ₄ ) effects on the measurement object are equal.

In the case when the duration (T ₃ ) of the main test effect does not coincide with the duration (T ₄ ) of the additional test effect, the preferred duration (T ₄ ) of the delay in the time of the additional test effect on the measurement object 3 should be at least 1300 ms. The indicated value was obtained experimentally.

In the general case, during each testing action on the measurement object, a current pulse of positive polarity can be supplied immediately after the transition process consisting in repolarization of the measurement object 3 after a current pulse of negative polarity is applied (Fig. 2). However, it is preferable that the current pulse of positive polarity is delayed (T ₉ ) in time (Fig. 1).

The duration (T ₁ ) of supplying a current pulse of negative polarity can be at least 120 ms and not more than 380 ms, that is, the condition is met: 120 ms ≤ T ₁ ≤ 380 ms.

It is empirically established that the optimal duration (T ₂ ) of supplying a current pulse of positive polarity should be at least 180 ms and not more than 1140 ms, that is, it is preferable to perform the following, in which: 120 ms ≤ T ₁ ≤ 380 ms.

Some optimal parameters of the testing effect on the measurement object 3 were experimentally established. So, during the test exposure, the current pulse power of negative or positive polarity supplied through the electrodes 1 and 2 to the measurement object 3, the value of which is not less than 0.08 mW and not more than 0.13 mW, is most preferable. The amount of electricity supplied to the measurement object 3 during the period of the current pulse of positive polarity should preferably be equal to the amount of electricity supplied to the measurement object 3 during the period of the current pulse of negative polarity. During the test action through the electrodes 1 and 2 on the measurement object 3, the current density value is preferably not less than 2.5 μA / cm ² and not more than 36.6 μA / cm. The lower limit of this range is due to the fact that with a decrease in current density, the measurement error sharply increases due to the growth of dispersion. When you go beyond the upper boundary of the specified range, the intactness of the measurement object 3 is violated. The rate of change of the front and the rate of change of the decay of the current pulse density of negative and / or positive polarity is preferably not less than 0.3 μA / cm ² ms and not more than 0.8 μA / cm ² ms in absolute value. In this case, the nature of the change in the front and decrease in the current pulse density is set using the same mathematical dependencies. For example, if the nature of the change in the front of the current pulse density of a negative polarity (from the moment the current pulse is fed a negative polarity to the moment of stabilization of its amplitude) is set, for example, by the exponent, then the nature of the change in the front of the current pulse of positive polarity (in the period from the moment of the positive polarity until stabilization of its amplitude) must also be specified by the exponent. Similar conditions should be observed for the nature of the change in the decline in current density, respectively, of negative and positive polarity (Fig. 1).

The voltage measurement during the passage of the current pulse of negative polarity is preferably carried out after a period of time (T ₅ ), the value of which is not less than 100 ms and not more than 250 ms, taking as the reference point the start of the current pulse of negative polarity (Fig. 3), i.e. the condition must be met: 100 ms ≤ T ₅ ≤ 250 ms. Similarly, the voltage measurement during the passage of a current pulse of positive polarity is preferably carried out after a period of time (T ₇ ), the value of which is at least 200 ms and not more than 400 ms, taking as the reference point the start of the current pulse supply of positive polarity, that is, the condition must be met: 200 ms ≤ T ₇ ≤ 400 ms. In addition, the optimal duration (T _ISM ) of voltage measurements is at least 20 ms. The above optimal ranges of the above parameters are determined empirically.

When changing the polarity of the current pulses, it is advisable to carry out an additional voltage measurement and assess the nature of the voltage between the electrodes 1 and 2. Additional measurements are carried out during the period of time (T ₆ ) of the transient repolarization process, that is, they start from the beginning of the decline of the current pulse of negative polarity and continue until the voltage stabilizes. During additional measurements, diagnostic parameters are determined, for example, the capacitive component of the electrophysical properties of the biological object (repolarization capacity) and repolarization time, as well as additional characteristics, for example, the stationarity of repolarization.

After the end of the testing effect on the measurement object, it is advisable to record the duration and nature of the transition process of restoring the electrical properties of the measurement object 3. According to the data obtained during the time period (T ₈ ) of the transition process of restoration of the electrical properties of the measurement object 3, additional diagnostic parameters are determined, for example, the capacitive component of the electrophysical properties of the biological object (discharge capacity), as well as additional characteristics, for example, the discharge stationarity index.

One of the electrodes, preferably the measuring electrode 2, can be made active, that is, such an electrode is made with a device that provides, with a certain force by pressing the electrode on the measurement object 3, a trigger pulse. The trigger pulse provides a test effect on the measurement object 3. The value of the optimal specific pressure on the object 3 of the measurement of the active electrode is not less than 400 g / cm ² and not more than 1600 g / cm ² .

 In more detail, an example of a specific implementation of the method for measuring the electrical parameters of the skin and mucous membranes will be given below when describing the operation of the device.

 A device for measuring the electrical parameters of the skin and mucous membranes includes a base electrode 1 and a measuring electrode 2, which are installed at the measurement sites on the measurement object 3, for example, on the skin site of the biological object. The device comprises a generator 4 for generating a current pulse of negative polarity and a generator 5 for generating a current pulse of positive polarity, each of which can be made, for example, in the form of a voltage reference source 6, an electronic switch 7 and a current source 8 (Fig. 8), which are standard nodes. The device also includes a synchronization unit 9, which is designed to synchronize the measurement process of the properties of the measurement object 3 and can be performed, for example, in the form of two pulse formers 10 and a delay unit 11 (Fig. 7), which are also standard nodes, which are electrically connected to each other. The device includes a measuring amplifier 12, which is designed to amplify and scale electrical signals and convert them to a voltage proportional to the change in the electrical properties of the system "measurement object 3 - base electrode 1 - measuring electrode 2". As the measuring amplifier 12, for example, a standard operational amplifier can be used. Block 13 for evaluating the parameters of the measurement object 3, which is part of the device, is intended for analog-to-digital conversion of a voltage signal, storing fragments of this signal and calculating the necessary information parameters. The unit 13 for evaluating the parameters of the measurement object 3 is a specific computing device that implements the algorithm for assessing the electrophysical parameters of the measurement object 3, and can be performed, for example, in the form of electrically interconnected read-only memory 14, analog-to-digital converter 15, memory 16 , the input control register 17, the processor 18 and four registers 19, 20, 21 and 22 for the corresponding electrophysical parameters of the measurement object 3 (Fig. 9). Block 23 for collecting and processing information is also part of the device and is intended to control the measurement process, data storage, visualization and diagnostic interpretation of the information received and is implemented using standard computing tools. The base electrode 1 is connected to the first input of the measuring amplifier 12 (Fig. 4). The measuring electrode 2 is connected in parallel with the corresponding outputs of the generators 4 and 5 for generating current pulses of negative and positive polarity and with the second input of the measuring amplifier 12. The synchronization unit 9 is connected in parallel with the corresponding outputs of the generators 4 and 5 for generating current pulses of negative and positive polarity and, respectively with the second and third inputs of block 13 for evaluating the parameters of the measurement object 3. Block 13 for evaluating the parameters of the measurement object with its first input is connected to the measuring amplifier 12 and its outputs - with block 23 for collecting and processing information.

 According to one embodiment of the device, the contact area of the base electrode 1 is no less than 75 times the contact area of the measuring electrode 2. By the contact area is meant the surface area of the corresponding electrode 1 or 2, which directly interacts with the measurement object 3 during a test action on the latter , that is, for example, with the surface of the skin of a biological object. The indicated ratio between the contact areas of the electrodes 1 and 2 was obtained empirically.

 In the embodiment of the structural embodiment of the device for measuring the electrical parameters of the skin and mucous membranes, the block 23 for collecting and processing information can be connected to the synchronization block 9 (Fig. 4).

 The measuring electrode 2 can be made active. As the active electrode, any known electrode design can be used (see, for example, RF patent 2033749), which ensures, at a certain pressure on the measurement object 3, the formation of a trigger pulse (signal).

 In the case when an active electrode is used as the measuring electrode 2, the embodiment of the device in which the measuring electrode 2 should be connected to the input of the synchronization unit 9 is most preferable (Fig. 5).

 According to one embodiment of the design of the device for measuring the electrical parameters of the skin and mucous membranes, it can be performed with a switch 24 and at least one additional measuring electrode 25, while the main 2 and additional 25 measuring electrodes are connected to the output of the generator 4 and 5 respectively, for generating current pulses of negative and positive polarity through the switch 24, and the block 23 for collecting and processing information is connected to the switch 24 (Fig. 6).

 The device can be performed with a resonator 26 of a homeopathic preparation for transferring to the measurement object through a measuring 2 and / or base 1 electrode the frequency properties of the test drug or its electronic copy (Fig. 4). The resonator 26 of the homeopathic preparation is, for example, a wave emitter that acts on the radiation object with electromagnetic waves with certain predetermined characteristics and can be used as a known design of any corresponding resonator.

 A device for measuring the electrical parameters of the skin and mucous membranes works as follows.

The base electrode 1 and the measuring electrode 2 are installed on the measurement object 3 (biological object), in the particular case on the patient’s body, in those places, information on the electrophysical properties of which is important from a diagnostic point of view. The base electrode 1 and the measuring electrode 2 are fixed on the object 3. Then, the device is activated by applying a trigger pulse to the input of the synchronization unit 9. In the case when a passive electrode is used as the measuring electrode 2 (Fig. 4), a trigger pulse is initiated from block 23 for collecting and processing information. In the case when selective diagnostics of the measurement object 3 is carried out, that is, when an active electrode is used as the measuring electrode 2 (Fig. 5), the trigger pulse is generated using the appropriate device (not shown) of the measuring electrode 2 when a specific the pressure of the latter on the object 3 measurements. At the moment the trigger pulse arrives at the input of the synchronization unit 9, a positive voltage level appears at its first output, which is transmitted simultaneously to the trigger input of the generator 4 to form a current pulse of negative polarity and the second input of block 13 for evaluating the parameters of the measurement object 3. When a voltage of a predetermined level appears at the starting input of a generator 4 to form a current pulse of negative polarity using a reference voltage source 6, an electronic switch 7 and a current source 8 (Fig. 8), a pulse of a negative amplitude stable current amplitude with corresponding parameters is generated, the numerical values of the part which are described in more detail in the description of the method. Simultaneously with the beginning of the testing effect on the measurement object with a negative current pulse, a voltage signal is generated at the output of the measuring amplifier 12, which is proportional to the voltage drop between the base electrode 1 and the measuring electrode 2. The voltage signal is applied to the first input of block 13 to evaluate the parameters of the measurement object 3, in which it using the analog-to-digital Converter 15 (Fig. 9) is converted into a binary code value. The voltage signal converted to binary code values is processed by processor 18. After the time (T ₅ ) of the transient process (Fig. 3), measurements begin. During the measurement period (T _measurement ), the data of each voltage signal converted into binary code values are supplied to the storage device 16 of the block 13 for evaluating the parameters of the measurement object 3, where an array of instantly measured voltage values converted to digital form is accumulated. Next, using block 13 to evaluate the parameters of the measurement object 3, diagnostic parameters are evaluated, for example, the active resistance during the passage of a current pulse of negative polarity and the reliability criterion for the obtained estimate, the active resistance during the passage of a current pulse of negative polarity.

 After processing the information, the obtained diagnostic parameters are recorded in the register 19 of block 13 for evaluating the parameters of the measurement object 3. The duration of the supply of a current pulse of negative polarity to the base 1 and measuring 2 electrodes is determined by the presence at the first output of the synchronization unit 9 of a predetermined voltage level and after its disappearance, the generator 4 is turned off to generate a current pulse of negative polarity. Simultaneously with this process, using unit 13 to evaluate the parameters of object 3, measurements begin to carry out additional measurements and assess the nature of the voltage change between the base electrode 1 and the measuring 2 electrode when the polarity of the current pulses changes (transient repolarization). Additional measurements are carried out in the period from the moment of supplying a current pulse of negative polarity to the end of the transient repolarization process.

 By the method described above, the data of each voltage signal converted into binary code values during the transient process is transferred to the memory module of unit 13 for evaluating the parameters of the measurement object 3, where an array of instantly measured voltage values converted to digital form is accumulated. Using block 13 to evaluate the parameters of the measurement object 3, the repolarization time is determined. Next, using block 13 to evaluate the parameters of the measurement object 3, the following diagnostic parameters are evaluated, for example, the repolarization capacity of the measurement object 3 and the dispersion index of the repolarization process relative to the moving average.

 It should be noted that the parameter indicator of the dispersion of the repolarization process is important both for assessing the quality of the parameter of the repolarization capacitance of the measurement object 3 and has its own diagnostic value. After processing the information received, these diagnostic parameters are fixed in the corresponding register 20 of block 13 to evaluate the parameters of the measurement object 3. Immediately after completing the above measurements and evaluating the corresponding diagnostic parameters or with a time delay, a positive voltage level is formed at the second output of the synchronization unit 9, which is transmitted simultaneously to the starting input of the generator 5 to form a current pulse of positive polarity and the second input of the unit 13 for evaluating the parameters object of 3 dimensions. When a voltage of a predetermined level appears at the starting input of a generator 5 to form a current pulse of positive polarity using a reference voltage source 6, an electronic switch 7 and a current source 8 (Fig. 8), a pulse of a positive amplitude stable current amplitude with corresponding parameters is generated, numerical values of the part which are defined in more detail in the description of the method. When measuring and evaluating the nature of the voltage change between the base electrode 1 and the measuring electrode 2 during the period of supplying a current pulse of positive polarity, the device operates in the same way, that is, as it works during the passage of a current pulse of negative polarity through the electrodes. At the same time, using unit 13 to evaluate the parameters of the measurement object 3, diagnostic parameters are evaluated, for example, the resistance during the passage of a current pulse of positive polarity and the reliability criterion for the resulting estimate.

 After processing the information, the obtained diagnostic parameters are fixed in the corresponding register 21 of block 13 for evaluating the parameters of the measurement object 3. The duration of the supply of a current pulse of positive polarity to the base 1 and measuring 2 electrodes is determined by the presence at the first output of the synchronization unit 9 of a predetermined voltage level and after its disappearance, the generator 5 is turned off to generate a current pulse of a positive polarity. Simultaneously with this process, using the unit 13 for evaluating the parameters of the measurement object 3, they begin to carry out additional measurements and assess the nature of the voltage change between the base electrode 1 and the measuring electrode 2 during the discharge of the measurement object 3 (transient discharge process). Additional measurements are carried out in the period from the moment of the end of the current pulse of positive polarity to the end of the transient discharge process of the measurement object 3. Using block 13 to evaluate the parameters of the object 3 measurements determine the discharge time. Next, using block 13 to evaluate the parameters of the measurement object 3, diagnostic parameters are evaluated, for example, the discharge capacity of the measurement object 3 and the dispersion index of the discharge process relative to the moving average. It should be noted that the parameter indicator of the dispersion of the discharge process of the measurement object 3 is important both for assessing the quality of the parameter of the discharge capacity of the measurement object 3 and has its own diagnostic value. After processing the information received, these diagnostic parameters are recorded in the register 22 of block 13 for evaluating the parameters of the measurement object 3.

 After completion of the testing effect on the measurement object 3, the data is exchanged between block 13 for evaluating the parameters of the measurement object and block 23 for collecting and processing information in which the obtained measured values are accumulated and then subjected to a diagnostic interpretation in accordance with a given diagnostic algorithm.

 The operation of the device when using in its circuit at least one additional measuring electrode 25 is carried out similarly as described above. The difference lies in the fact that with the help of the switch 24, a sequential interrogation of the main measuring electrode 2 and the additional measuring electrode 25 is carried out during a test action on the measurement object 3.

 When a homeopathic preparation is included in the structure of the resonator device 26, it works as described above. In this case, the resonator 26 of the homeopathic preparation generates electromagnetic waves, the characteristics of which determine the properties of the studied drug or its electronic copy. Electromagnetic waves act on the object of measurement 3 and under their action the properties of the latter change. Changes in the properties of the measurement object 3 are measured and evaluated as described above. Based on a comparison of the properties of the measurement object 3 before and after exposure to the homeopathic preparation through the resonator 26, a corresponding conclusion is drawn about the expected nature of the effect of the test drug or its electronic copy on the measurement object 3.

Claims (26)

 1. A method of measuring the electrical parameters of the skin and mucous membranes, including the installation of electrodes on the measurement object, the implementation of the test effect on the measurement object by transmitting between the electrodes a pulse of stable amplitude negative negative polarity, as well as measuring and evaluating the nature of the voltage change between the electrodes during the testing effect, characterized in that during the test action between the electrodes, an additional pulse of a stable amplitude current is passed polarity, which is supplied behind the current pulse of negative polarity, while the duration of the current pulse of positive polarity is not less than one and a half times the duration of the current pulse of negative polarity, and the amplitude of the current of negative polarity is not less than one and a half times the amplitude of the positive current polarity.  2. The method according to p. 1, characterized in that at least one additional testing effect is performed on the measurement object with a time delay.  3. The method according to p. 2, characterized in that the delay time of the filing of the additional test effect is not less than 1.68 of the duration of the test effect.  4. The method according to p. 2, characterized in that the delay time of the filing of the additional test effect is at least 1300 ms.  5. The method according to one of paragraphs. 1-4, characterized in that the supply of a current pulse of positive polarity is carried out with a time delay.  6. The method according to one of paragraphs. 1-5, characterized in that the duration of the current pulse of negative polarity is at least 120 ms and not more than 380 ms.  7. The method according to one of paragraphs. 1-5, characterized in that the duration of the current pulse of positive polarity is not less than 180 ms and not more than 1140 ms.  8. The method according to one of paragraphs. 1-7, characterized in that the power of the current pulse of negative or positive polarity supplied to the measurement object is at least 0.08 mW and not more than 0.13 mW.  9. The method according to one of paragraphs. 1-8, characterized in that the amount of electricity supplied to the measurement object during the period of the current pulse of positive polarity is equal to the amount of electricity supplied to the measurement object during the period of the current pulse of negative polarity. 10. The method according to one of paragraphs. 1-9, characterized in that during the test exposure, the current density is not less than 2.5 μA / cm ² and not more than 36.6 μA / cm ² . 11. The method according to one of paragraphs. 1-10, characterized in that the rate of change of the front and the rate of change of the decay of the current pulse density of negative and / or positive polarity is not less than 0.3 μA / cm ² ms and not more than 0.8 μA / cm ² ms in absolute value, in this case, the nature of the change in the front and decrease in the current pulse density is set using the same mathematical dependencies.  12. The method according to one of paragraphs. 1-11, characterized in that the voltage measurement during the passage of the current pulse of negative polarity is carried out not less than 100 ms and not more than 250 ms after the start of the current pulse.  13. The method according to one of paragraphs. 1-12, characterized in that the voltage measurement during the passage of the current pulse of positive polarity is carried out not less than 200 ms and not more than 400 ms after the start of the current pulse.  14. The method according to one of p. 12 or 13, characterized in that the duration of the voltage measurement is at least 20 ms.  15. The method according to one of paragraphs. 1-14, characterized in that when changing the polarity of the current pulses carry out an additional voltage measurement and assess the nature of the voltage change between the electrodes.  16. The method according to p. 15, characterized in that the additional voltage measurement and assessment of the nature of the voltage change starts from the beginning of the recession of the current pulse of negative polarity and continues until the voltage stabilizes.  17. The method according to one of paragraphs. 1-16, characterized in that after the end of the testing action, the duration and nature of the transition process of restoring the electrical properties of the measurement object is recorded.  18. The method according to one of paragraphs. 1-17, characterized in that one of the electrodes is made active. 19. The method according to p. 18, characterized in that the specific pressure on the object of measurement of the active electrode is at least 400 g / cm ² and not more than 1600 g / cm ² .  20. A device for measuring electrical parameters of the skin and mucous membranes, including a base electrode, a measuring electrode, a generator for generating a current pulse of negative polarity and a unit for collecting and processing information, characterized in that it is equipped with a generator for generating a current pulse of positive polarity, a synchronization unit , a measuring amplifier and a unit for evaluating the parameters of the measurement object, while the base electrode is connected to the first input of the measuring amplifier, the second input of which ohm is connected to the measuring electrode, and the measuring electrode is connected in parallel with the respective outputs of the generators for generating current pulses of negative and positive polarity, and the synchronization unit is connected in parallel with the corresponding inputs of the generators for generating current pulses of negative and positive polarity and, respectively, with the second and third inputs of the block for evaluation of the parameters of the measurement object, and the unit for evaluating the parameters of the measurement object with its first input is connected to itelnym amplifier and its output to the unit for the collection and processing of information.  21. The device according to p. 20, characterized in that the contact area of the base electrode is not less than 75 times the contact area of the measuring electrode.  22. The device according to one of p. 20 or 21, characterized in that the unit for collecting and processing information is connected to the synchronization unit.  23. The device according to one of p. 20 or 21, characterized in that the measuring electrode is made active.  24. The device according to p. 23, characterized in that the measuring electrode is connected to the input of the synchronization unit.  25. The device according to p. 20, characterized in that it is made with a switch and at least one additional measuring electrode, while the main and additional measuring electrodes are connected to the respective outputs of the generators for generating current pulses of negative and positive polarity through the switch, and the unit for collecting and processing information is connected to the switch.  26. The device according to p. 20, characterized in that it is made with a resonator of a homeopathic preparation for transmission to the measurement object through the measuring and / or base electrode the frequency properties of the test drug or its electronic copy.

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