RU2169551C1 - Device for electropuncture - Google Patents

Abstract

FIELD: medical equipment, applicable for estimation of electrophysiological state of the points of acupuncture in reflexodiagnosis and reflexotherapy. SUBSTANCE: the device has interconnected thirty measuring and four positive electrodes, switches of inputs, calibration, measuring currents, filter, amplifier, measuring resistor, measuring voltage forming unit, controller unit, personal computer. Each of the four sources of measuring voltages in the measuring voltage forming unit is connected to a common wire via a 10-Mom resistor, and a feedback filter is connected between each of the four sources of measuring voltages and each input of the switch of the measuring voltage sources, the feedback filter passes a signal within a frequency range of 10 to 20 Hz, it is made for smooth variation of the time of signal passage through the filter within this range. EFFECT: enhanced physiologity, sensitivity, provision of separate monitoring of organs in the meridian of three planes. 3 dwg

Description

 The invention relates to medical equipment and can be used to assess the electrophysiological state of acupuncture points (TA) in reflexology and reflexology, as well as to search for points.

 When creating modern devices for electropuncture, there always arises the need for a compromise solution to the problems of metrological support and the tasks of preserving the biological safety of the object of examination - the human body. While maintaining the absolute biological safety of the facility, it is not possible to achieve high indicators of accuracy and information content of measurements.

 The fact that the biomedical and technical features of electropuncture devices are interconnected became known in 1979, when reliable information about the negative consequences of acupuncture procedures began to appear in the literature (see Zagryadsky V.A., Zlokazov V.P. Metrology and electrical safety at puncture electrodiagnostics / Bulletin of the Taganrog Radio Engineering University - Taganrog: Publishing House of TRTU, 1998, p. 68-71). Multidisciplinary biomedical research for medical support of the Buran space program (see ibid., P. 68, 71) showed that the test signal during electropuncture influences adversely affects TA, their corresponding tissues, internal organs, and also the whole organism . The greatest destructive reactions are observed in the internal organs associated with the test TA. Significant morphological consequences manifest themselves from mechanical damage in TA, lasting up to 1.5 months. The cumulative effect of mast cells on electro-puncture effects was found. These cells belong to the elements of the diffuse endocrine system, which has both local and general effects on the body. They perceive information about the state of the environment in which they are localized, and carry out a response by releasing substances deposited in them. Many neurons secrete the same biologically active substances as mast cells. Granules with these substances can be found in the blood, intercellular substance, on the surface of connective tissue, in the membranes of nerves and receptor formations. Serial exposure to mast cells, which are always abundant in TA, by electrical energy during electropuncture causes an increased accumulation of biologically active substances in them and contributes at some point to an avalanche-like release of them into the blood and intercellular fluid, which often leads to serious and sad consequences.

 Thus, it is obvious that the biomedical and technical characteristics of the device for electropuncture are interconnected. However, in most known devices and methods, the harmful effects of electropuncture on the body are not taken into account, since it would have to go to the deterioration of the accuracy and information content of the measurements. On the other hand, the energy effect on TA during electropuncture introduces an error in the measurements, since the measurement object is an active nonlinear living environment that responds to the effect in the form of biologically significant damage.

 A device for electropuncture is known, including a probe electrode and a reference electrode, the conductive surface of which is 25 times the area of the end of the probe electrode. A generator is connected to the latter, generating electrical signals with a high content of harmonic components. A transducer of impedance, measured at the end of the electrode, into frequency is connected to both electrodes. A computer is connected to it, on the screen of which the resistance values are reproduced. The computer is provided with a program for data analysis (see U.S. Pat. No. 5,339,827, A 61 H 39/02, 1994).

 The disadvantages of the known device are the lack of protective elements of the body from the negative effects of electric current on TA, as well as the low reliability of the measurement results. The reliability of the data reduces the unstable position of the electrodes on the human skin, which increases the amount of interference and introduces significant subjective errors in the measurement.

 A device for removing bioelectric signals, including a stable current generator and a voltage amplifier, an information processing unit, two electrodes - a base and a measuring one. The measuring electrode is connected to the amplifier, has a housing with a sleeve and a washer and a spring-loaded metal probe rigidly mounted in the sleeve, which moves along the housing. The contact surface of the probe and the end surface of the sleeve are located in the same plane, and the ratio of their diameters is set from 0.8 to 0.5 (see US Pat. RF, N 2033749, A 61 B 5/05, 1995, Bull. N 12).

 The known device allows for more accurate removal of bioelectric signals due to the fixed position of the measuring electrode while reducing damaging effects on the body due to the use of a test signal of electric current stabilized in amplitude at the same level.

 The disadvantages of the known device are low information content and conditional cross-correlation of data obtained as a result of simultaneous measurements of resistances in different TAs, due to its equipping with only one pair of electrodes, as well as insufficient safety of measurements due to the need for their repeated repetition in the same TA .

 These disadvantages are partially eliminated in another known device for electropuncture - a multichannel device of the brand "BITA-12-MG" (see VG Makats. Fundamentals of acupuncture bioenergy diagnostics. - Vinnitsa, 1991.- S. 73 -78). The known device is intended for continuous comparative study of the bioelectric activity of individual circuits of a bioobject (or exposure) with data output to a computer, analysis and display of material on a display. The known device comprises one positive and twenty-four measuring electrodes connected in series, an input switch, a filter, an amplifier, an analog-to-digital converter (ADC), and a personal computer. It is intended for a comparative study of the bioelectric activity of twenty-four studied acupuncture zones along the twelve classic meridians on the right and left relative to the umbilical region. In the known device, an external current source is not used, but the current generated by the biological object is measured, which minimizes the damaging effect on the latter.

 A disadvantage of the known device is the low reliability of the measurement results when monitoring the status of TA during the diagnosis, search or stimulation of points, which reduces the accuracy of diagnosis and the effectiveness of therapy using the known device for electropuncture. The causes of the disadvantages are the weakness of the recorded bioelectric signal in the absence of an external voltage supply to the SLT, as well as the presence of interference in the measurements.

 The closest technical solution to the present invention is the electropuncture device selected as a prototype, including twenty-five measuring electrodes connected in series, one of which is freely movable, switches for calibrating inputs, measuring currents, a filter, an amplifier, a controller unit, a personal computer. The calibration switch is connected at its input to the first measuring electrode. A measuring resistor is connected between the common wire and the connection point of the measuring current switch with the filter. The measuring voltage generator unit is connected to the common wire by one of its outputs, and four positive electrodes are connected to four others. In addition, the mode control bus connects the switches of the inputs, measuring currents, amplifier, controller blocks, and the measuring voltage generator. The controller unit is also connected by a bus to a personal computer and contains a central processing unit (CPU) connected to each other by an address / data bus with an ADC, operational and read-only memory devices, a light indication buffer and an optocoupler isolation device, connected, in addition, to a common bus with CPU The measuring voltage generator block contains four independent measuring voltage sources, switches of measuring voltage sources and groups, the measuring voltage sources being connected to a common wire, and the switches to a mode control bus. All electrodes, except the search one, are rigidly fixed to the patient’s body. The measuring resistor eliminates noise fluctuations, increasing the reliability of the obtained data, and determines the short circuit current, increasing the safety of the procedure for the patient (see US Pat. RF N 2123318, A 61 H 39/00, 1998, Bull. N 35).

 Despite the reliability of the obtained measurement results and the presence of some electrical safety elements of patients, the known device for electropuncture does not provide, during its operation, a combination of reliable body protection from the damaging effects of the electrical signal supplied to the TA, with high sensitivity to changes in the measured signal and full information about the state of all organs and systems.

 The disadvantages of the known device are the impossibility of ensuring during its operation the physiological nature of the test signal and monitoring the adequacy of the measurements in one SLT, diagnosing the meridian of the three body cavities, as well as automatically changing the measurement modes for current and voltage and sensitive reaction to these changes.

 The basis of the invention is the task: in the device for electropuncture by incorporating new structural elements into it in the form of an additional delay line and regulating the signal and means for studying the additional meridian on the human body, creating new connections between them to increase physiology, sensitivity, and provide the possibility of separate control of organs along the meridian of three cavities during its operation, which provides a combination of reliable protection of the body from the damaging effects of electric signal supplied to the SLT high performance - measurement accuracy and informative data on the state of all organs and systems.

 The problem is solved in that in the known device for electropuncture, which includes serially connected twenty-four measuring electrodes, input switches, calibrations, measuring currents, filter, amplifier, controller unit, personal computer, and the calibration switch is connected with its input to the first measuring electrode, and the output - with the input of the input switch, and between the common wire and the connection point of the measuring currents switch with the filter, a measuring resistor is connected, with a common the measuring voltage former is connected to one of its outputs, and four positive electrodes are connected to four other outputs; in addition, the mode and control current switches, an amplifier, the measuring voltage former, and the controller block are also connected to the mode control bus a personal computer with a bus and contains a central processing unit connected to each other by an address / data bus with an analog-to-digital converter, operational and constant This includes memory devices, a light indication buffer and an optocoupler isolation device, also connected by a common bus to the central processing unit, in addition, the measuring voltage generator unit contains four independent measuring voltage sources, commutators of measuring voltage sources and electrode groups, and the measuring voltage sources are connected to a common a wire, and the switches with a mode control bus, in addition between the output of each of the four sources of measuring voltage In the unit of the measuring voltage generator between the output of each of the four sources of measuring voltage and each of the four inputs of the switch of the sources of measuring voltage, a signal delay line is turned on, consisting of a series-connected resistor with a resistance of 10 MΩ and a feedback filter that transmits a signal in the frequency range from 10 up to 20 Hz, made with the possibility of smoothly changing the time the signal travels through the filter within this range, in addition, the device will complement It is fully equipped with six measuring electrodes for studying the meridian of three body cavities, which are connected to the input switch input.

 Between the totality of the above features of the invention and the achieved technical result, there is a causal relationship.

 It should be noted that during the operation of the known device, due to the lack of regulation (stabilization) of the measurement current, noise arises in the measuring voltage source in the measuring circuit, which, acting on the TA, adversely affects the state of the corresponding tissues and organs. To eliminate this drawback, four resistors are additionally introduced into the claimed device, each of which has a resistance of 10 MΩ and is connected by its input to the output of one of the sources of the measuring voltages. At the same time, the sensitivity of the device increased: a resistor with high resistance sensitively reacts to the slightest changes in the measuring signal in amplitude and shape: the amplitude of the signal decreases, and its shape changes from a rectangular to a wavy one. To make the signal more physiological, it is necessary to ensure its smooth increase with a given time interval. In the inventive device, this effect is achieved by sequentially connecting, through a resistor with a resistance of 10 MOhm, to a circuit a measuring voltage source-switch of voltage sources of a filter with feedback passing a signal in the frequency range from 10 to 20 Hz, made with the possibility of smoothly changing the time the signal travels through the filter to within this range (four filters in total by the number of measuring voltage sources). The value of the electrical characteristic of the resistor of 10 MΩ is optimal and selected experimentally: when the resistance of the resistor is less than 10 MΩ, the problem of the invention is not solved due to the insufficient sensitivity of the device; when the resistance of the resistor is greater than 10 megohms, the sensitivity of the device increases so much that noise characteristics are superimposed on the measured values and due to this the accuracy of the claimed device decreases. The value of the signal front from 50 to 100 ms for each of the four feedback filters is also experimentally selected as the most physiological. When the signal exposure time is less than 50 ms, transients still occur in the tissues caused by this effect, which means that the measured characteristics will not correspond to reality, starting from 50 to 100 ms, the processes in the tissues are stabilized and measurements in this time range most accurately reflect physiological state of tissues. If the exposure time of the electric signal is more than 100 ms, the biological cell is damaged due to prolonged exposure and the measurements will be unphysiological and their results inaccurate.

 Due to a change in the algorithm for supplying the acting voltage, its damaging effect on the body is reduced to a minimum. In addition, an unexpected additional effect appeared: the possibility of realizing feedback with the body. Due to the exclusion of the influence of transients in the measurement zone (point), it became possible to determine the number of necessary measurements. By transient processes we mean functional changes in biological tissue under the action of an electric signal supplied to it, which are manifested in a change in its own electrical characteristics. Since the change of characteristics continues until their relative stabilization, it is possible to program the accounting of the stabilization period. Thus, exactly as many measurements are performed as the body signals, after which its reaction to the changes made begins. However, its implementation would not be possible without increasing the sensitivity of the device, that is, without the function of a resistor that compensates for the magnitude of the supplied signal.

 Another significant feature of the invention is the introduction of an additional six measuring electrodes, with which it became possible to conduct a detailed examination (impact) of the meridian of three cavities: chest, abdominal and pelvic. Using the prototype device, separate monitoring of the state of the organs of the chest, abdominal cavity, and pelvis is not provided. Diagnosis and treatment in this case are carried out very approximately, namely: they determine whether there are (are not) any disorders in the internal organs; have an effect on general TA. The use of an additional six electrodes to act on the paired meridian of the three cavities became possible only in the inventive device by minimizing the damaging effects of the electrical signal on the body. The impact on such vital organs (heart, lungs, liver, pancreas, kidneys, internal genital organs) located in three cavities using known devices would be too dangerous.

 As you can see, the inventive device for electropuncture during its operation provides a combination of reliable protection of the body from the damaging effects of the electrical signal supplied to the TA, with high technical characteristics - measurement accuracy and full information about the state of all organs and systems. In addition, when operating the inventive device, it becomes possible to objectively evaluate the effect of electromagnetic fields on the patient, and the process of controlling the device itself is simplified by automating the procedures for determining a sufficient number of measurements at a point and selecting the current strength acting on the SLT.

 The invention is illustrated by the drawings in FIG. 1 - FIG. 3. In FIG. 1 presents a General functional block diagram of the inventive device for acupuncture. In FIG. 2 shows a functional block diagram of a block of a shaper of measuring voltages. In FIG. 3 shows the functional block diagram of the controller unit.

 The device for electropuncture (Fig. 1) contains thirty measuring electrodes 1, which are connected to the input switch 2. Between the first measuring electrode 1 and the input switch 2, a calibration switch 3 is connected. To the output of the input switch 2 is connected the input of the switch of measuring currents 4. To the output of the last the input of the filter 5 is connected, and the input of the amplifier 6 is connected to the output of the filter 5. A measuring resistor 7 is connected between the connection point of the filter 5 and the switch of the measuring currents 4 and the common wire. The output of the amplifier 6 is connected to the input controller unit 8. In addition, these two nodes are interconnected by the mode control bus 9.

 The unit for generating measuring voltages 10 (Fig. 2) is connected with four positive electrodes 11 and with a common wire. In addition, the common control bus mode 9 are also connected between the switches of the inputs 2 and the measuring currents 4 and the block of the shaper of the measuring voltage 10. The controller unit 8 is connected to a personal computer 12 via bus 13.

 The block of the shaper of the measuring voltages 10 (Fig. 2) contains four sources of measuring voltages 14 connected to a common wire and with four inputs of the switch of voltage sources 15, the output of which is connected to the input of the switch of groups 16, which has four outputs for connecting four positive electrodes 11. Between the output of each of the four sources of measuring voltages 14 and one of the four inputs of the switch voltage sources 15 included a delay line signal, consisting of series-connected res ora 17 (one of four) and the feedback filter 18 (one of four). The switches of voltage sources 15 and groups 16 are also connected to the control bus mode 9.

 The controller unit 8 (Fig. 3) contains a CPU 19, which includes an ADC 20, connected, in addition, with an amplifier 6 via bus 9. The controller unit 8 also includes operational 21 and permanent 22 memory devices and a light indication buffer 23 which are connected to each other and to the CPU 19 using the address / data bus 24. The CPU 19 is connected by a common bus 25 to the optocoupler isolation device 26, which through the bus 13 has access to a personal computer 12.

 The inventive device for electropuncture operates in accordance with the program embedded in the permanent storage device 22 in the controller unit 8, under the control of commands received from the personal computer 12. Upon power-up, the device for electropuncture is calibrated (without connecting a patient) by measuring the ADC zero bias voltage 20 in the short-circuit mode of the first measuring electrode 1 with the first positive electrode 11 using the calibration switch 3 and voltage noise trips in idle mode when opening the circuit of the first measuring electrode and the input switch 2 using the calibration switch 3.

 The calibration result is processed in the controller 8, reported to the personal computer 12 and taken into account when processing the measurement results in the operating mode. Upon receipt of the software initialization command from the personal computer 12, the controller 8 tests the communication line with the computer 12 and indicates the readiness of the device for electro-puncture to the operating mode. Then twenty-four measuring electrodes 1 are fixed on the patient’s body to control the twelve main meridians on the left and right, and six additional ones for the meridian of three cavities: chest, abdominal and pelvic and four positive electrodes 11 on the four limbs of the patient. In operating mode, on command from a computer 12, the inventive device connects one of thirty measuring electrodes 1 through an input switch 2 and one of four positive electrodes 11 using a group switch 16. The principle of operation of the inventive device for electrical function in terms of electrical measurements at points does not change depending from the choice of point search modes, diagnostics or treatment. Only the choice of the program for setting the mode and data processing changes. To the selected and connected positive electrode 11, one of the four sources of measuring voltages 14 from the block of the shaper of measuring voltages 10 is automatically selected and connected. The ratings of the sources of measuring voltages 14 are set in advance. The unit of the shaper of the measuring voltages 10 provides an individual approach to the patient, taking into account the physiological characteristics of each, sets four gradations of the magnitude of the voltage (from 1.0 to 10.0 V) that affects the patient and is selected using a personal computer program 12. The signal from one of four sources of measuring voltages 14 enters the signal delay line, consisting of a series-connected resistor 17 (one of four) and a feedback filter 18 (one of four). The delay line of the measuring signal provides a physiologically adequate character of the growth of its front, which brings into correspondence the severity of transients in the measurement zone and the compensatory abilities of tissue cells in this zone. Monitoring the sufficiency of measurements in one SLT is ensured by including feedback in the filter 18 and creating the possibility of a smooth change in the signal flow in it, which makes it possible to control the SL response to the test signal by double differentiation of the resulting difference in the signal-response pair. Automatic change of measurement modes for current and voltage and sensitive response to these changes is achieved by comparing the potential difference on the measuring resistor 7 and the resistor 17.

 Thus, the command from the personal computer 12 determines the magnitude of the voltage applied to the external circuit - the patient, as well as the configuration of the circuit: which pair of electrodes must be connected at a given time. In addition, the same command determines the resistance value of the measuring resistor 7, connected to the measuring circuit through the switch of the measuring currents 4. From the output of the switch inputs 2, the measuring current taken by one of the thirty electrodes is supplied to the switch of the measuring currents 4, from the output of the switch 4 to the measuring resistor 7, from which the voltage is removed by the filter 5, is filtered out from interference and interference in the measuring circuit. The measuring resistor 7, connected in series with the patient, is a divider - a constant additional resistance in the circuit, the value of which is selected depending on the patient’s bioelectric resistance, bringing the claimed device closer to the function performed in relation to the person, to the current source or to the voltage source . Thus, the measuring resistor 7 allows you to keep displayed on the display the electrical characteristics of any patient within the dynamic range, allows you to make the peaks on the graph changes indicators sharper, i.e. more different, leveling noise fluctuations, increasing the reliability of the data. In addition, the measuring resistor 7 determines the short circuit current, ensuring the safety of the procedure for the patient.

 From the filter 5, the signal is amplified by the amplifier 6 to the value of the range of the operating voltage of the ADC 20. From the output of the amplifier 6, the signal is fed to the input of the ADC 20, which is an integral part of the CPU 19 in the controller unit 8. The controller unit 8 synchronizes the connection and disconnection times of the measuring and positive electrodes with accuracy in time, and also buffers the measurement results and exchanges information with a personal computer in synchronous mode, which, in turn, allows the program to be highly efficient in a personal computer make efficient use of computer resources and process results in parallel with measurements. Here, digitizing the voltage of the incoming signal, additional digital filtering of interference and interference from an alternating voltage of 220/380 V network. The algorithm of the controller unit 8 allows you to control the operation of the device, process the measurement results, transfer the measured signal values to a computer 12 or accumulate the results in a random access memory 21. The signal is transmitted to a personal computer 12 through an optocoupler isolation device 26, which performs galvanic isolation with a personal computer 12, as well as the conversion of signal levels between the computer 12 and the controller unit 8. The operation mode of the device is displayed by indicators b Scope of light indication 23.

 The connections between the nodes of the claimed device, including those carried out using buses 9, 13, 24, 25, are constructed in such a way as to ensure the function of the measuring circuit with respect to the patient at a particular time or close to the current source or close to the voltage source.

 In terms of protection against electric shock of a person, the claimed device for electrical puncture is made according to electrical safety class II type H according to GOST 12.2.025-75.

 The device uses an IBM-type personal computer 12 connected via the RS-232 interface and an optocoupler isolation device 26 based on a type 6 N 136 opt 20 microcircuit.

CPU 19 is based on a single-crystal microcomputer JNTEL 80 with 196 sq-20;
light indication buffer 23 - type 82 microcircuit with 55 A;
read only memory 22 - 27F256;
random access memory 21-61C256;
measuring resistor 7-C2-36;
resistor 17 with a resistance of 10 MOhm - C2-36;
filter 5 and amplifier 6 - based on operational amplifiers of type K 544 UD 2A and K 157 UD 2A;
a filter 18 with feedback and a variable time dump - based on an operational amplifier of type K 544 UD 2A;
measuring voltage sources 14 - KR142EN12A.

 The elemental base of all the switches (2, 3, 4, 15, 16) of the claimed device is made on the basis of microcircuits of the type K590KN6 and K561KTZ.

As measuring electrodes 1 we used EPKK-2 electrodes manufactured by NPP REMA (Lviv) according to TU 64-1-3175-76;
as positive electrodes 11, electrodes of the electrocardiographic type mE. 443.101.1

Claims (1)

 A device for electropuncture, including twenty-four measuring electrodes connected in series, input switches, calibrations, measuring currents, a filter, an amplifier, a controller unit, a personal computer, the calibration switch being connected by its input to the first measuring electrode and the output to the input of the input switch, and a measuring resistor is connected between the common wire and the connection point of the measuring currents switch with the filter, the measuring voltage generator unit is connected to the common wire one of its outputs, and four positive electrodes are connected to four other outputs, the mode and control current switches, the amplifier, the measuring voltage driver, the controller unit, which is also connected to the personal computer by a bus and contains interconnected data address bus central processing unit with an analog-to-digital converter, operational and read-only memory devices, light indication buffer and device in the optocoupler isolation, also connected by a bus to the central processing unit, the measuring voltage generator unit contains four independent measuring voltage sources, switches of measuring voltage sources and groups of electrodes, the measuring voltage sources being connected to a common wire, and the switches to a mode control bus, characterized in that in the block of the shaper of the measuring voltage between the output of each of the four sources of measuring voltage and each of the four inputs s of the switch of the sources of measuring voltages, a signal delay line is included, consisting of a series-connected resistor with a resistance of 10 MΩ and a feedback filter passing a signal in the frequency range of 10 - 20 Hz, made with the possibility of smoothly changing the signal propagation time through the filter within this range, the device is additionally equipped with six measuring electrodes for examining the meridian of the three body cavities that are connected to the input switch input.

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