RU2190994C2 - Method and device for measuring biological tissue parameters - Google Patents

Abstract

FIELD: medicine; medical engineering. SUBSTANCE: method involves periodically acting upon the object under measurement with electric power and measuring in pauses between actions of electric power of short-circuited electrodes set on skin. The acting electric power magnitude is increased to a value at which the electric current in pauses reaches a predefined value and electric power values that, when acting, supports given value of electric current passing through the biological tissue during pauses and transient process parameters of its formation are used as information parameters describing biological tissue properties. The device has active and indifferent electrodes, electric current-voltage converter, one input of which is connected to the indifferent electrode via electronic switch unit which control output is connected to impulse shaper, electric voltage source, register, the first and the second electronic switch units which control inputs are connected to impulse shaper, amplifier, low frequency filter. The electric voltage source is controllable and its control inputs are connected to low frequency filter outputs and electric current-voltage converter output is alternatively connected to multiplier or comparator unit via the first switch. Voltage by means of which electric current through biological tissue is set in pauses between actions with electric power is supplied to the second input of the comparator unit. The amplifier and low frequency filter connected in series are connected to the output of the comparator unit. The second input of the multiplier unit is connected to the active electrode, its output being connected to the recorder. Switch control is carried out in a way that the signals coming from the active electrode and electric current-voltage converter are delivered to the multiplier unit at the same time. EFFECT: improved reproducibility of measurement results; reduced dependency on psychic factors, environment temperature and humidity. 2 cl, 1 dwg

Description

 The invention relates to the field of health and can be used in medicine and veterinary medicine.

 Known methods for assessing the state of biological organisms, which are that an indifferent electrode having a large surface area in contact with the skin and an active electrode with a small surface area are placed on the skin. The state of the body is judged either by the potential difference between the electrodes, measured using a millivoltmeter, or by the electrical resistance available between the electrodes. In the latter case, an electric energy source is connected to the electrodes and the electric current created by it (with a small internal resistance of the electric energy source) is measured, or the voltage drop in the area between the electrodes (with a large internal resistance of the electric energy source) [1, 2, 3, 4 ].

 Their disadvantages are low information content, which is due to the large variability and poor reproducibility of the measurement results.

 There is also a method for assessing the electrical parameters of local areas of the skin, which consists in the fact that a constant current source is periodically connected to the electrodes installed on the skin, and in the interval between its connections, the electrodes are short-circuited and the electric current flowing through them is measured. The value of this current gives an opinion on the state of this local area of the skin and related systems or organs [5]. This method is closest to the proposed and can be considered as a prototype of the proposed method.

 A device for measuring the electrical parameters of biological tissue zones [6]. It consists of an active and indifferent electrodes, a current-voltage converter, an electronic switch, a source of pulses controlling the switching, a pulse polarity selector, a direct current source, a millivoltmeter. One of the inputs of the current-voltage converter is connected to the indifferent electrode through an electric switch, the control input of which is connected to the source of control pulses, and the second input is connected to the active electrode. The output of the current-voltage converter through a pulse polarity selector is connected to a registrar made in the form of a millivoltmeter. A DC voltage source is connected between the second contact of the electronic switch, in which the first input of the current-voltage converter is closed to this source or to an indifferent electrode with an earth bus connected to it.

 This is the closest device in terms of technical nature and the achieved result. Its disadvantage is that when it is used, it is not possible to obtain good reproducibility of the results obtained, they significantly depend on the ambient temperature, and a correction of the voltage value given by the constant voltage source is required, depending on the individual characteristics of the body, as well as on humidity and ambient temperature Wednesday.

 For all known analogues used to solve this problem, a common drawback is that when conducting measurement operations, the state of biological tissue at a given time is evaluated.

 Biological tissue at different times of the day and depending on external and internal psychophysiological factors can be in different conditions, namely: to be inhibited; to be active; be excited with varying degrees of excitement. The measurement results will reflect this condition, and not characterize the physiological capabilities of organs and systems associated with the area of the skin, the parameters of which are measured.

 The objective of the invention is to increase metrological reliability by improving the reproducibility of the measurement results, reducing their dependence on mental factors, temperature and humidity.

 This problem is achieved due to the fact that in the known method, when the biological tissue is periodically exposed to a source of external electric energy and in the pauses between exposures, the electric current supplied by the biological tissue to the circuit of short-circuited electrodes is measured, the value of electric power is increased to a value at which the electric current in pauses will take a value proportional to the predetermined voltage value in advance, and its instantaneous value is measured at the end of the transient process voltage and evaluate the parameters of the transient process of changing instantaneous power.

 The device in which the proposed method is implemented is shown in the drawing. The numbers denote: 1, 3, 4 - respectively, the first, second, third electronic switches; 2 - current-voltage converter; 5 - multiplier; 6 - a comparison device; 7 - amplifier; 8 - low pass filter; 9 - registrar; 10 - pulse generator; 11 - controlled source of electrical voltage; 12 - key enable measurement mode.

 The device has an active and indifferent electrode placed on the surface of the skin. The active electrode is connected to the input of the current-voltage converter (PNT) 2. An indifferent electrode is connected to a common bus. The second input of PNT 2 through switch 1 is periodically connected to a common bus and to a controlled voltage source 11. PNT2 has a small input resistance. PNT2 output through the third switch 4, which works synchronously with switches 1 and 3, is periodically connected either with a comparator 6 or with one of the inputs of the multiplier 5. Voltage from the active electrode is applied to the second input of the multiplier 5, to which it is periodically connected via switch 3 The signal from the output of the multiplier 5 is fed to the registrar 9, the role of which, for example, can be performed by a millivoltmeter. On the comparator 6 through the switch on the measurement mode 12 is supplied voltage Uset. Using it, the value of the current given to the PNT 2 circuit by the biological tissue is set when the electrodes are short-circuited through the low input resistance of the PNT. The output of the comparator is connected to the input of the amplifier 7, the output of which is connected to the input of the low-pass filter (low-pass filter) 8. The output of the low-pass filter is connected to the voltage control input of the controlled voltage source 11. The voltage that controls the switches 1, 3, 4 is supplied from the output of the electric generator pulses 10.

 The operation of the device in which the proposed method is implemented is as follows. After the active and indifferent electrodes are installed on the biological tissue, the measurement mode switch 12 is turned on. A voltage U.sup. Is applied to the comparator 6. When the switches 1, 3, 4 are in position a, the biological tissue is exposed to electric energy, the power of which is measured using a multiplier 5 and recorder 9. When the switches 1, 3, 4 are in position b, the electrodes are short-circuited through the input resistance PNT 2. The electric current generated by the biological tissue is converted into voltage and supplied to the comparator 6. If this voltage is not equal to the specified U back, then an electric device appears at the output of the comparator nonstoichiometric signal. It is amplified by amplifier 7. The constant component of the amplified signal is extracted using the low-pass filter 8. The signal from the low-pass filter is fed to the control input of the controlled voltage source 11. Under its influence, the output voltage of the latter changes to a level at which the electric current of the electrodes in position b of switches 1, 3 , 4 takes a value proportional to Uset. The value of this power is measured by the recorder 9 in the position a of the switches 1, 3, 4.

 Simplified diagram of the operation of the device since the closure of the key switch mode measurement 12 can be described as follows. At the first time, the voltage at the output of the low-pass filter 8 will have a small value despite the fact that the constant component of the output voltage of the comparative device 6 will have the largest value. This is due to the fact that when a step-by-step voltage Ureach is applied and a step change in the output voltage of the amplifier 7 occurs, the voltage at the output of the low-pass filter 8 increases slowly. Its speed depends on the value of the upper frequency bandwidth of the low-pass filter 8. Therefore, the voltage at the output of a controlled source of electrical voltage 11 will be small. The pulse generator 10 generates relatively high-frequency pulses, the frequency of which is many times (tens or more) higher than the upper passband of the low-pass filter 8. Therefore, during the rise in voltage at the output of the low-pass filter 8, switches 1, 3, 4 repeatedly appear in position a and b. With each new cycle, the voltage at the output of a controlled source of electrical voltage increases in magnitude. Therefore, in position a of the switch 1 on the biological tissue is an increasing energy impact. This leads to an increase in the electric current flowing through the input of the PNT 2 at position b of the switch 1. Accordingly, the output voltage of the PNT 2 increases, which in the comparator 6 is subtracted from the voltage U back. This process continues until the output voltage of the comparator device becomes small, depending on the statism of the system, which is characterized by a loop gain. The latter depends on the amplification factors of amplifier 7 and the low-pass filter 8 and the PNT 2 conversion coefficients and the controlled source of electrical voltage 11. In the ideal case, with loop amplification tending to infinity, the electric current supplied by biological tissue is highly accurate proportional to the voltage U back. At the end of the transition process of establishing a voltage that provides a specified value of the electric current given by the biological tissue in the pauses between exposure to electric energy, the exposure power is found by multiplying the instantaneous values of current and voltage. To do this, an instantaneous voltage value is supplied to the multiplier 5 through the switch 3, which is in position b, from the active electrode, and through the switch 4, the voltage is proportional to the electric current flowing through the biological tissue during energy exposure. In multiplier 5, they are multiplied by each other. Therefore, the output signal of the multiplier is proportional to the instantaneous electric power. It is measured using a recorder 9, for which, for example, a millivoltmeter can be used.

 An increase in metrological reliability, which is characterized by better reproducibility of readings, a decrease in their dependence on the state of biological tissue (its inhibition or activity), temperature and humidity of the environment, and an increase in the volume of measurement information are achieved due to the fact that by external electrical exposure the biological tissue is brought to a certain reproduced in any conditions, a state in which, in the pauses between the effects of it, a certain value of e is given to the load electric current and, ultimately, electric power. Therefore, the state of biological tissue at the time of the start of the measurement operation does not significantly affect the measurement results. The reproducibility of the readings is much better than with other known analogues.

 At the same time, the regime of “excitation” of biological tissue (from the point of view of “transferring” electric energy to the load during pauses) will not depend on the parameters of the environment (its temperature and humidity), which is also very important for increasing metrological reliability.

The duration of the process of establishing a static regime will characterize the state (degree of inhibition or arousal) of biological tissue at the time the measurements begin. Estimating the parameters of the transient process of changing the instantaneous power recorded by the registrar, you can get additional information about the properties of biological tissue. Its reliability increases with changes in the voltage setting the electric current Uad. So, if the voltage Uset _{1 is} abruptly reduced to a lower value of Uset ₂ , then the transition to a "lower energy level" will characterize the dynamic characteristics of biological tissue. Thus, when using the proposed method and device, the volume of measuring information on the properties of biological tissue obtained during measurements significantly increases.

Sources of information
1. Gusev V.G. Instrument reflexology and conceptual issues of creating technical means for its implementation. In the journal "Acupuncture and traditional methods of treatment", 1, 1992, p.5-18.

 2. Markov Yu.V. Reflexotherapy in modern medicine. St. Petersburg, Nauka, 1992, 182 p.

 3. Portnov F.G. Electropuncture reflexology. Zinatne, 1988, 352 p.

 4. Copyright certificate of the USSR 940773, IPC A 61 H 39/02 of 07/07/82. Device for detecting acupuncture points / V.G. Gusev and others.

5. Copyright certificate of the USSR 1806724, IPC ⁵ A 61 H 39/00, A 61 B 5/00 of 04/07/93. A method for assessing the electrophysical state of acupuncture points. / V.A. Zagryadsky et al.

6. RF patent 2057519, IPC ⁶ A 61 H 39/02 of 04/10/96. A device for measuring the electrical parameters of biological tissue zones. / Gusev V.G.

Claims (2)

 1. The method of measuring the parameters of biological tissue, which consists in installing conductive electrodes on the skin, to which the electric energy source is periodically connected, and in the pauses between its connections, the electrodes are short-circuited and the electric current flowing through them is measured, characterized in that the acting electric power increase to a value at which the electric current in pauses takes a value proportional to the predetermined voltage value in advance, measure its instantaneous value at the end of the transition process and the establishment of the voltage to estimate the parameters of the transition process instantaneous power changes.  2. A device for measuring the parameters of biological tissue, containing an active and indifferent electrode, a current-voltage converter, one of the inputs of which is connected to the indifferent electrode through a first electronic switch, the control input of which is connected to a pulse generator, an electric voltage source and a recorder, characterized in that the second and third electronic switches are additionally introduced into it, the control inputs of which are connected to the pulse generator, a multiplier comparing a device, an amplifier, a low-pass filter, a measurement mode enable switch, and the voltage source is made controllable, and the current-voltage converter output is connected to the multiplier or to the comparison device through the third switch, and the second output of the comparison device is connected to the voltage source via the switch measurement mode, an amplifier and a low-pass filter connected in series to the output of the comparison device, the output of the low-pass filter is connected to the control the inputs of a controlled source of electrical voltage, and the second input of the multiplier through the second switch is connected to the active electrode, its output is connected to the recorder.