RU2107487C1 - Method and device for performing electroacupuncture diagnosis procedure taking into account mechanical and electric properties of acupuncture points - Google Patents

Abstract

FIELD: medicine; medical engineering. SUBSTANCE: method involves gradually increasing pressure applied to measuring electrode 2 concurrently measuring one of electric parameters of an object like, for instance, current intensity passing through electrode and magnitude of pressure applied to the electrode. Then pressure growth is stopped and change in the value of the measured electric parameter is determined on a predefined time interval under constant pressure applied to the measuring electrode. In taking measurements, the value of the first derivative of the electric parameter to be measured depending on pressure value is determined. Electric parameter increments under constant pressure applied to the electrode are measured at pressure value corresponding to zero or minimum positive value of the mentioned first derivative. The known device for measuring physical parameters has electrode 2 and pressure pickup 4 enclosed in probe each of which is electrically connected to the corresponding measurement channel 9, 11. Unit 19 is introduced into device design for determining the first derivative of the electric parameter to be measured like current intensity depending on pressure applied to electrode 2 and indication unit 20 for showing the received first derivative value. Each input of mentioned unit 19 is connected to output of one of measuring channels 9, 11, the output being connected to input of indication unit 20. EFFECT: enhanced accuracy of diagnosis; enabled polyfunctional measurements. 6 cl, 5 dwg

Description

 The invention relates to the field of electro-acupuncture diagnostics, in particular to a method for electro-acupuncture diagnostics, taking into account the mechanoelectric properties of acupuncture points according to the method of Dr. R. Voll.

 The invention can be used to conduct research on the state of the human body at biologically active points, diagnose with nosodes and test drugs.

 The device, when measuring physical parameters, can also be used for multifunctional measurements and establishing the relationships between electrical parameters and pressure on the measuring electrode in studies of biological and plant tissues.

 Closest to the invention is a modification of the R. Voll method, namely, the method of electroacupuncture diagnostics, taking into account the mechanoelectric properties of acupuncture points, based on the fact that the pressure on the measuring electrode is gradually increased first while measuring the current through the electrode and the magnitude of the pressure applied to it, and when the pressure reaches a predetermined value in the range of 400 - 900 Pa, at which, as it is assumed, the growth of the current value stops, the increase is stopped pressure and measure the magnitude of the change in current for a given period of time at a specified constant pressure on the measuring electrode (see "Topographishe Lage der Messpunkte der Elektroakupunktur von Dr. med. Reinhold voll", Uelzen, 1976, Textband I, s.24 - 25 as well as Bildband II, an advertisement for Voll diagnostic equipment at the end of this volume).

 In the prototype method, the necessary time to stop the growth of pressure on the electrode is set in advance by indicating a certain value of the pressure value, while maintaining which the change in the current through the electrode will be measured. In this case, it is theoretically possible, taking into account the experience of the operator, to set a pressure value that takes into account differences in skin elasticity and thickness in different parts of the body and in different people, leading to a difference in pressure values at which the measured current stops growing as the pressure on the electrode increases. But in practice, the relationships between this pressure value and skin characteristics are quite complex and have not been studied with a sufficient degree of accuracy.

 In addition, in practice, there are cases when the increase in current strength with increasing pressure on the electrode does not stop completely, but only slows down to a certain minimum, after which a further increase in current strength begins. This moment is not predictable, it is difficult to catch by the operator, which increases the error. Repeated measurements to more accurately determine the minimum deceleration of current growth increases the examination time.

 This reduces the quality of diagnostics, the need for repeated measurements increases the time spent on examination, and the need to use qualified specialists who intuitively determine the required pressure value reduces the possibility of using the method, in particular, not allowing it to be used in mass examinations.

 The closest in technical essence is a device containing an electrode for measuring biopotentials and an inductive pressure sensor located in the probe, each of which is electrically connected to a corresponding measuring device that acts as measuring channels of one or another value (A.S. USSR 1173981, A 61 B 5 / 04, 1985). In the specified device using a measuring device, you can measure the current through this electrode. Those. the above device can be used for electroacupuncture diagnostics, taking into account the mechanoelectric properties of acupuncture points.

 The prototype device allows you to implement the known method of electroacupuncture diagnostics, taking into account the mechanoelectric properties of acupuncture points and has its inherent disadvantages: reduced quality of diagnostics, increased time spent on examination, narrowing the scope of the use of the method and device, in particular the impossibility of using them during mass examinations.

 The proposed method and device for its implementation are aimed at improving the quality of diagnostics and expanding the use of the method and device.

 In FIG. 1 shows the probe device for measuring physical parameters; in FIG. 2 is a block diagram of a device; in FIG. 3 is a block diagram of an audible alarm unit when the first derivative reaches zero or a minimum positive value with registration, and the pressure on the measuring electrode is reached; in FIG. 4, 5 - the algorithm of the computer when implementing the proposed method.

 A device for measuring physical parameters includes (Fig. 1) a probe consisting of a hollow body 1 with a spring-loaded electrode 2. The rear end of the electrode 2 is passed through a dielectric tab 3 fixed in the housing 1 and an inductor 4, which is a pressure sensor on the electrode 2. B as a pressure sensor can also be used, for example, a piezoelectric element (not shown in the drawing).

 The terminal 5 of the electrode 2 is connected (Fig. 2) to the input 8 of the channel 9 for measuring an electrical parameter, in particular, the current through the electrode 2. Another input 10 of the channel 9 is connected to the reference electrode 11. The terminals 6, 7 of the pressure sensor (inductor 4) are connected with inputs 12, 13 of the channel 14 pressure measurement. The output of each of the channels 9 and 14 for measuring electrical parameters and pressure is connected to the corresponding indicator 15 or 16 of the indicated values, as well as to the corresponding input 17 or 18 of the block 19 for determining the first derivative of the dependence of the electric parameter (in particular, the current through the electrode) on the pressure electrode. The output of the side 19 is connected to the input of the indicator 20 of the magnitude of the first derivative. Each of the channels 9, 14 for measuring parameters can include or consist of an amplifier, arrow or digital priors can be used as indicators 15, 16, 20, and the first derivative determination unit 19 is, for example, a differentiating circuit, but can be made and in the form of a processor, in particular, type KM 1850BE35 (not shown in the drawing). Structurally, the scales or scoreboards of indicators 15, 16, 20 are placed side by side or can be combined to improve the convenience of monitoring all of the indicated values (not shown in the drawing).

 In addition, in an embodiment of the device (dashed line in Fig. 2), the outputs of the pressure measuring channel 14 and the first derivative determination unit 19 are connected, respectively, to the inputs 21 and 22 of the sound signaling unit 23 when the first derivative reaches zero or minimum positive value with the achieved while the pressure on the measuring electrode.

 Block 23 is made, for example, as follows (figure 3).

 The inputs 21, 22 of block 23 are, respectively, the inputs of analog-to-digital converters (ADCs) 24 and 25. The output of the ADC 25 is connected to the input of the microprocessor 26, the output 27 of which is connected through the amplifier 28 of the audio frequencies to the speaker 29. The output 30 of the microprocessor 26 is connected to the control input of the key 31, through the normally open contacts of which the output of the ADC 24 is connected to the input of a digital indicator 32, for example, type KIPC O2A-5 / 8K. As an ADC 24, 25, microcircuits of the 1113PV1 type can be used, microprocessor 26 - a single-chip computer KM 1850BE35, amplifier 28 - a 555PA8 chip.

 If it is necessary to use a light signaling that the first derivative has reached zero or a minimum positive value, a light diode with a power source is inserted into block 23, the circuit of which is closed by a signal from the output 30 of processor 26 (not shown in the drawing).

 The device operates as follows.

 When the reference electrode 11 is applied to the test object (patient) and the contact with the corresponding acupuncture point is connected, the ends of the measuring electrode 2 are measured by the indicator 15, in particular, the current through the electrode, and the pressure applied by the operator to the electrode 2 is shown by indicator 16. As the operator presses the electrode 2 further, indicators 15 and 16 show corresponding changes in current and pressure. In accordance with the electrical signals arriving at the inputs 17, 18 of the block 19 with the block 9 and 14 in the side 19, the value of the first derivative of the dependence of current strength on pressure is determined, the value of which is displayed on indicator 20.

 In the presence of block 23, a signal corresponding to the pressure value on electrode 2 is fed through ADC 24 to a normally closed contact of key 32. A signal reflecting the value of the first derivative of the dependence of current strength on pressure is output from block 19 through ADC 25 to the input of processor 26 analyzing the value of the first derivative reaches zero or a minimum positive value. Upon reaching the first derivative of one of these values, output 17 of the processor 26 delivers a sound frequency signal generated by the processor and, amplified, is reproduced by the speaker 29, signaling the operator. Simultaneously with the output 30 of the processor 26, a short-term pulse signal is supplied to the control input of the key 31, which closes its contacts for a short time. The current pressure value at the electrode 2 through the contacts of the key is supplied to the digital display 32 and is fixed on it.

 The method of electroacupuncture diagnostics taking into account the mechanoelectric properties of acupuncture points is carried out using the device shown in figure 2 as follows.

 Having applied the reference electrode 11 and the measuring electrode 2 to the corresponding points of the patient, they begin to increase the pressure on the measuring electrode, observing the magnitude of the first derivative on the indicator 20. With increasing pressure on the electrode 2, at first, there is a significant increase in the current through the electrode, so that the magnitude of the first the derivative has a non-zero value, and with a slowdown in the growth of current, its value decreases. When the first derivative reaches zero, the operator stops the further increase in pressure on the electrode 2 and, while maintaining the pressure not reached the level, begins to monitor the magnitude of the current strength on the indicator 15, measuring its decrease over a given period of time (on average from 4 to 15 s). The time for increasing the pressure on the electrode 2 is usually not more than 3 s.

 If the value of the first derivative decreases with an increase in pressure on the electrode 2 and then begins to increase without reaching a zero value, the operator remembers the minimum achieved value of the first derivative and, reducing the pressure on the electrode 2, ensures that the first derivative returns to the specified minimum value . After that, he stops reducing the pressure and, maintaining it at the achieved level, measures the drop in current for a given period of time.

 When using a device with an audible alarm unit 23 to achieve the first derivative of zero or minimum value and register the pressure value obtained on the electrode 2, the operator stops the pressure increase by the sound signal of the speaker 29 of the indicated unit and further maintains the pressure value at the level shown by indicator 32, producing measurement of current drop for the required period of time.

 The measured values of the current drop over a given period of time at the acupuncture points examined are used to diagnose the condition of the patient.

 Presented in FIG. 1 and 2, a device for measuring physical parameters can be performed using a personal computer such as IBM PC. The outputs of the channels 9 and 14 of the parameter measurement via the appropriate interface are connected to the PC processor (not shown in the drawings).

 The values of the measured parameters are displayed on the display screen, sound signals are supplied by a PC speaker operating under the control of a program, the algorithm of which is presented in FIGS. 4, 5.

 The method of electroacupuncture diagnostics, taking into account the mechanoelectric properties of acupuncture points, is carried out using a PC as follows.

 After starting the program, electrode 2 is applied to the acupuncture point, the coordinates of which are displayed on the display screen. If the pressure P applied to the electrode exceeds a certain minimum Po value, an audible signal starts to measure, the counter of the measurement time displayed on the display screen is turned on. When the operator increases the pressure on the electrode 2, a graph of the dependence of the measured current through the electrode on the pressure on it is displayed on the display screen. Upon reaching the indicated first derivative of zero or minimum value, a corresponding sound signal is supplied and the value of the pressure reached at that is displayed. At the same time, the on-screen countdown of the exposure time by the operator of constant pressure begins. The operator maintains a predetermined pressure to measure the magnitude of the current drop over a given period of time. A graph of current strength versus measurement time is displayed on the display screen. At the end of the set measurement time, an audible signal is signaled about this, the received value of the current drop is displayed on the screen. The operator stops the pressure on the electrode 2, removes it from the investigated point. The obtained measurement data points are recorded in the computer memory. If necessary, the screen displays the coordinates of the next acupuncture point and all of the above is repeated during its study. At the end of the measurements, for all given acupuncture points, a measurement protocol is printed for this patient.

 In the study of biological and plant tissues, the supporting 11 and measuring 2 electrodes are placed at appropriate points in the tissue and the dependences of the required electrical parameters, for example, biopotentials, on the pressure on the measuring electrode are taken.

Claims (6)

 1. The method of electroacupuncture diagnostics, taking into account the mechanoelectric properties of acupuncture points, based on the fact that the pressure on the measuring electrode is gradually increased at the same time using the electrode of one of the electrical parameters of the object, for example, the current through the electrode, and the pressure applied to the electrode, and then stop the increase in pressure and measure the magnitude of the change in the electrical parameter for a given period of time with constant pressure on the measuring electron od, characterized in that during the measurement process, the value of the first derivative of the dependence of the measured electric parameter on the pressure value is determined, and the change in the electric parameter at constant pressure on the electrode is measured at a pressure value corresponding to the zero or minimum positive value of the first derivative.  2. The method according to claim 1, characterized in that the pressure increase on the measuring electrode is stopped when the first derivative reaches zero, further supporting the pressure at the achieved level.  3. The method according to claim 1, characterized in that after reaching the first derivative of the minimum positive value and the subsequent increase in the value of the derivative, the pressure on the measuring electrode is reduced to a value corresponding to the minimum value of the first derivative, further maintaining the pressure at a specified level.  4. The method according to claims 1 to 3, characterized in that the moment the first derivative reaches zero or a minimum positive value is noted with an audio or light signal and the pressure value reached at that moment is recorded on the measuring electrode.  5. A device for measuring physical parameters, comprising a measuring electrode and a pressure sensor located in the probe, each of which is electrically connected to a corresponding measurement channel, characterized in that a unit for determining the first derivative of the dependence of the measured electric parameter, for example, amperage, on pressure is inserted and an indicator of the obtained value of the first derivative, each of the two inputs of the indicated block is connected to the output of one of the measurement channels, and the output to the indicator input.  6. The device according to claim 5, characterized in that an acoustic or light alarm unit is inserted into it about the moment the first derivative reaches zero or minimum positive value with registration of the pressure reached at that moment on the measuring electrode, and the outputs of the channel for measuring pressure on the electrode and block the definitions of the first derivative are connected to the corresponding inputs of the indicated sound or light signaling unit.

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