RU64068U1 - DEVICE FOR REFLECTOR CORRECTION OF FUNCTIONAL VIOLATIONS OF THE ORGANISM - Google Patents

Abstract

The utility model is aimed at increasing the reliability of determining functional disorders of organs and body systems and reducing the time of their reflex correction to achieve a clinically favorable result. The device for reflex correction contains an element of thermal effect on AT in the form of an IR LED (12) placed in an IR probe (1) and connected to a controlled current generator (2), a multifunction indicator (3) and control buttons (4) connected through the unit input / output (5) with the network bus of the microcontroller (6), including a microprocessor (7) connected to the network bus, a program block (8), a data memory block (9) and a timer / counter (10), while the microcontroller program block is executed with the ability to control operating modes, translation is controllable of the current generator (2) from the measurement mode to the exposure mode, measuring the IF channels, calculating the asymmetry of the channels, identifying the dominant rhythms of the IF channels, predicting them, highlighting the positive half-waves of the rhythm and conducting exposure during the positive half-waves of the rhythm, as well as generating data for display on multifunctional indicator. 3 s.p. f-ly., 6 ill.

Description

The utility model relates to medicine, in particular to reflexology, and can be used to assess the functional state of the human body based on measurement of thresholds of temperature pain sensitivity (AF) of acupuncture points (AT) and reflex correction of revealed functional disorders of organs and systems of the body.

In modern reflexology, the Akabane thermodiagnostic test is widely used to diagnose the state of the body, which is based on the thermal effect on the symmetric terminal ATs of the main channels (meridians), in order to measure their temperature pain sensitivity thresholds and further evaluate the data obtained (Portnov F.G. Electropuncture reflexology. - Riga .: Zinante, 1998. - P.103. Muzhikov VG Theory and practice of thermopunctural channel diagnostics and treatment. - St. Petersburg: Petrovsky Fund LLC, 2000. - P.27-37).

The following symbols are commonly used on the phalanges of the hands and feet of the symmetrical terminal AT of the main channels (see FIG. 1), which are used in this description of the invention: LU11 - lung; LI1 - large intestine; HC9 - pericardium; TH1 - triple heater; Ht9 is the heart; SI1 - small intestine; SP1 - spleen; Liv1 - the liver; St45 - stomach; GB44 - gall bladder; Ki1 - kidney; BI67 - the bladder. The right and left branch (side) of the channel are denoted by the indices d and s, respectively. In the following description, only AT names are used, and point numbers are omitted.

It is traditionally believed that in a healthy person, the sensitivity of the left and right branches of the channel should be the same. In the presence of pathology, the left and right branches of the channels have different IFs, and the degree of asymmetry between them increases in proportion to the severity of the disease. A pronounced functional impairment of a channel is understood to mean its state when there is a significant asymmetry (more than 30-40%) between its

branches, which indicates the presence of functional disorders in the organ or system that are associated with this channel. By changing the IF by thermal action on the AT channel, it is possible to carry out reflex correction of functional disorders of organs and systems of the body.

Known devices for implementing methods of reflex correction of functional disorders of the cardiovascular system, such as arterial dysfunctions or cardiac arrhythmias (RU 2152777 C1, IPC 7 A61H 39/06, A61N5 / 067, A61B 5/04, op. 20.07.2000. RU 2149625 C1, IPC 7 A61H 39/06, A61N 5/067, A61B 5/04, op. 27.05.2000). Using these devices, frequency channels are evaluated by the Akabane test in the dynamics of observations at various values of blood pressure (RU 2152777, op. 20.07.2000) or the number of heart contractions (RU 2149625, op. 27.05.2000). According to the data of the correlation and regression analysis of the IF channels, the channels with the greatest influence on the normalization of the adjustable parameter are determined and then the detected channels are exposed to the modulated infrared radiation on the detected channels to normalize blood pressure (the number of heart contractions) in the mode from 20 to 30 sec - exposure and from 180 up to 300 sec - a break.

The IF of the channel changes rhythmically under the influence of physiological rhythms, which are understood as the operating cycles of the functioning of cells, organs and body systems with periods from milliseconds to minutes. At maximum values of the IF channel, it and the organ (physiological system), the function of which it reflects, are in a state of functional insufficiency (hypofunction of the channel). If the IF of the channel is low, this indicates the presence of functional redundancy (hyperfunction of the channel and its associated organ).

A disadvantage of the known devices is the lack of synchronization of exposure with a rhythmic change in the IF channels under the influence of physiological rhythms, as a result of which the exposure time is increased to achieve a clinically favorable result. An increase in the exposure time arises due to its conduct while the canal branch is in the state of least susceptibility, which levels the result of the action compared to if it went into the phases of the rhythm wave with the highest susceptibility.

The device for reflexology, selected as a prototype of the claimed device, contains a physiological parameter sensor, a control unit, a switching unit, a pulse generator and an element of influence on AT in the form of an IR emitter (RU 2152777, op. 20.07.2000). The device provides an assessment of the condition of the channels by the Akabane test based on the threshold of temperature pain sensitivity (IF) AT, the determination of channels with the greatest influence on the normalization of blood pressure and subsequent exposure of the detected channels to AT.

The disadvantage of the device adopted for the prototype is the lack of synchronization of exposure with a rhythmic change in the IF channels under the influence of physiological rhythms, resulting in increased exposure time to achieve a clinically favorable result.

The task this utility model is aimed at is to normalize functional disorders of organs and systems of the body based on the detection of rhythmic changes in the IF channels and reflex action at the moments of the predicted finding of the channel in hypofunction.

The technical result achieved by using this utility model is to increase the reliability of determining functional disorders of organs and systems of the body and reduce the time of their reflex correction to achieve a clinically favorable result.

The task with the achievement of the above technical result is achieved by the fact that a multifunctional indicator and control buttons connected through the input unit are introduced into the device for the reflex correction of functional disorders of the body, containing the thermal element for AT at the form of a PC LED connected to a controlled current generator I / O with the network bus of the microcontroller, including a microprocessor connected to the network bus, a program block, a data memory block and a timer / counter, with IR light The diode is located in an IR probe containing a start / stop switch, the anode of the LED is connected to the positive bus of the controlled current generator, the negative bus of which, the LED cathode and the first contact of the start / stop switch are connected to the common ground bus, the second contact of the start / stop switch stop and input of the controlled current generator are connected

through the input / output block with the microcontroller network bus, and the microcontroller program block is configured to control the operating modes, transfer the controlled current generator from the measurement mode to the exposure mode, measure the IF channels, calculate the asymmetry of the channels, identify the dominant rhythms of the IF channels, predict them, select positive half-waves of the rhythm and conducting exposure during the positive half-waves of the rhythm, as well as generating data for display on the multifunctional indicator.

The technical result is also achieved by the fact that:

the start / stop switch is made in the form of a push-button switch with self-resetting, the IR probe is made in the form of a handle of insulating material, on the outer surface of which there is a start / stop switch button, and an IR LED is placed at the end of the handle;

the microcontroller program block contains, connected by a two-way communication with the program block bus, which is its input / output, an operating mode control unit, a current generator control signal generation unit, an IF channel measurement unit, a channel asymmetry calculation unit, a dominant frequency channel rhythm extraction unit, a prediction unit IF channel rhythms, a positive half-wave extraction block and a data generation block for display;

a controlled current generator provides the ability to emit an IR LED: in measurement mode - pulsed infrared radiation with a wavelength in the range from 780 to 1600 nm, a repetition period of 1 second, a pulse duration in the range of 0.7 to 0.9 seconds and a power density in a pulse 200 mW / cm ² , and in the exposure mode - pulsed infrared radiation with a wavelength in the range from 780 to 1600 nm, with a varying repetition rate within 28 ± 4 Hz, a pulse duration equal to 0.5 of the repetition period, and power density in impulse varying during the exposure linearly in the range from 200 mW / cm ² to 300 mW / cm ² .

Improving the reliability of determining functional disorders of the patient’s organs and systems is ensured by their assessment of the asymmetry of the IF of the right and left branches of the channel, which, when expressed functional

violations have significant asymmetries in excess of the proportion of the "golden section" (1.64).

The decrease in the time of reflex correction to achieve a clinically favorable result is due to the fact that the channel with the greatest asymmetry is selected for reflex correction, the dominant IF rhythms of its symmetric branches are isolated, and the channel branch with a large average IF value is affected into positive half-waves of the predicted IF rhythm, that is, then when the branch of the channel is in a state of hypofunction, which ensures rapid alignment of the asymmetry of the channel. Alignment of the asymmetry of the channel, and as a result, the approximation of the rhythm parameters of its symmetrical branches, the channel indicates the normalization of the functional state of the organs and systems of the body associated with it.

The utility model is illustrated by drawings, which depict:

figure 1 - the location of the symmetrical end AT of the main channels;

figure 2 is a structural electrical diagram of the device;

figure 3 is a structural electrical diagram of a block of programs;

figure 4 - algorithm of the device;

figure 5 is a periodogram of the IF symmetric branches of the channel BI, selected for reflex correction: a) the right branch; b) the left branch;

figure 6 is a graphical representation of the predicted rhythms of the IF channel BI: a) the right branch; b) the left branch.

Device for reflex correction contains (see figure 2) IR probe 1, the housing of which is made in the form of a handle made of insulating material and contains an IR LED 12 located at the end of the handle, and a start / stop switch 13. The switch 13 is made in the form of a push-button switch with self-reset, the button of which is located on the outer surface of the handle.

The anode of the LED 12 is connected to the positive bus of the controlled current generator 2, the negative bus of which, the cathode of the LED 12 and the first contact of the switch 13 are connected to a common ground bus. The connection of the IR probe 1 with the controlled generator 2 and the input / output unit 5 can be detachable.

The controlled current generator 2, the second contact of the switch 13, the multi-function indicator 3 and the control buttons 4 are connected via an input / output unit 5 to the network bus 11 of the microcontroller 6, which includes a microprocessor 7, a program block 8, a data memory unit 9 and a timer / counter 10 connected to the network bus 11.

Block 5 provides the pairing of units 1 ... 4 of the device with the microcontroller 6 through its input / output interfaces by the number of mating units.

Block 8 of the programs of the microcontroller 6 is made with the ability to control operating modes, transfer the controlled current generator from the measurement mode to the exposure mode, measure the IF channel, calculate the asymmetry of the channels, identify the dominant rhythms of the IF channels, predict them, highlight positive half-waves of the rhythm and conduct exposure for positive half-waves of rhythm, as well as the formation of data for display on a multifunctional indicator.

Block 8 programs (see figure 3) contains a block 8-1 control modes, block 8-2 generating control signals of the current generator, block 8-3 measuring IF channels, block 8-4 calculating the asymmetry of the channels, block 8-5 selection dominant rhythms of IF channels, block 8-6 for predicting the rhythms of IF channels, block 8-7 for selecting positive half-waves of a rhythm, and block 8-8 for generating data for display. Blocks 8-1 ... 8-8 are connected to a common bus 8-9, which is the input / output bus of program block 8.

IR LED 12 connected to the output of a controlled current generator 2 emits:

in measurement mode — pulsed infrared radiation with a wavelength in the range from 780 to 1600 nm, a repetition period of 1 second, a pulse duration in the range of 0.7 to 0.9 seconds and a power density in the pulse of 200 mW / cm ² ;

in the exposure mode — pulsed infrared radiation with a wavelength in the range from 780 to 1600 nm, with a variable repetition rate within 28 ± 4 Hz, a pulse duration equal to 0.5 of the repetition period, and a power density in the pulse that varies during the exposure linearly ranging from 200 mW / cm ² to 300 mW / cm ² .

The multifunctional indicator 3 is intended to display the operating modes of the device, the measurement data of the IF channels, the selected and predicted dominant rhythms of the IF channels, the commands for beginning and ending measurements and reflex correction of channels and other overhead information. The operation of the device and the information displayed on the indicator 3 is carried out using the control buttons 4 directly or in the "General menu" mode, and the radiation of the infrared probe 1 is controlled by the switch button 13.

The device is implemented on a microprocessor type ATmega 128 and serial elements of computer technology.

The operation of the device will be described taking into account the data from the given clinical example.

Figure 4 shows the algorithm of the device, implemented under the control of the microprocessor 7 according to the program recorded in block 8 programs.

The device starts by measuring the IF channels. The measurement is carried out by the patient alone or with the help of medical personnel. Place the IR probe 1 on the terminal AT of the right branch of the LUd channel located on the phalanx of the thumb of the patient’s right hand (see FIG. 1), with the LED 12 in direct contact with the skin surface. Press the switch button 13 start / stop. When the switch 13 is triggered, a start strobe / pulse is generated, which turns on the controlled current generator 2 in the measurement mode and activates the timer / counter 10. In the measurement mode from the controlled current generator 2, a LED sequence 12 is supplied with a pulse repetition period of 1 second, the pulse duration within from 0.7 to 0.9 seconds and a current value providing IR radiation of the LED 12 with a power density in the pulse of 200 mW / cm ² . The heat source is an IR LED 12, the lens of which is a hemisphere with a radius of the order of 1.5 mm, which makes it possible to measure IF AT from the skin surface, corresponding in area to the morphological substrate AT. The emitted wavelength can lie in the range from 780 to 1600 nm, that is, in the “water transfer window” and the optimal permeability of the skin and tissues (see, for example, patent RU N2122208, IPC 6 G01N 33/49, АВВ 5/00, Op. 20.11.1998). It is preferable to use as an LED 12 an IR LED of type 3AL107B with a wavelength of 920 nm, which showed

reliable results. The power density is selected from the condition of providing a dynamic range of variation of the IF channels in a different state, ranging from 2 to 100 seconds, with an average threshold value of 5 to 10 seconds. This condition is satisfied by the power density of infrared radiation in a pulse of 200 mW / cm ² . Impact in a pulsed mode with a repetition period of 1 second and pulse durations ranging from 0.7 to 0.9 seconds was chosen empirically based on a variety of observations and provides a more clear threshold for the perception of pain.

When the patient experiences the first pain, the switch button 13 is pressed a second time. The arising stop strobe / pulse turns off the controlled current generator 2 and stops the timer / counter 10. The time interval from the beginning of the irradiation AT to the appearance of the first pain, counted down timer / counter 10, at a constant radiated power density is proportional to the energy emitted by the LED 12, and corresponds to the physiological threshold of temperature pain sensitivity (IF), in this case the right branch of the lung channel (LUd).

Then, to assess the degree of asymmetry of this channel, an IR probe 1 is placed on the terminal AT of the left lung of the canal of the lung (LUs) located on the phalanx of the thumb of the patient’s left hand, and the IF LUs are measured. In such a sequence, the IF data of all twelve main channels located on the phalanges of the hands and feet are measured and entered into the memory unit 9.

Based on the measured values of the inverters d and ins of the same channels in block 8-4, the asymmetry of each channel is calculated by the formula

K = (IFd / IFs) ^a ,

where a = 1 if IF d> IF s and a = -1 otherwise.

For channels with asymmetry K> L, the channel with the greatest asymmetry is selected for reflex correction. The value of L is chosen equal to 1.64, which corresponds to the ratio of HCH and PS in the proportion of the "golden section", which is a universal criterion for detecting functional disorders in the body (see, for example, patent RU N2198600, op. 20.02.2003).

Exceeding the asymmetry coefficient K by more than 1.64 times indicates pronounced functional disorders of the organs and systems of the body.

Table 1 shows the practical results of pairwise measurements of the dc and ins of the main channels and the values of their asymmetry coefficients K.

According to the test results, the most pronounced asymmetry was noted on the BI channel of the bladder and is K (BI) = 4.54, which indicates the presence of functional disorders of this channel (K> 1.64).

On the selected BI channel with maximum asymmetry, a series of N continuously repeating pairwise measurements of the inverters dd and inverters s is performed.

According to the obtained N measurements, in block 8-5, dominant rhythms of the right and left channel branches are distinguished. The dominant rhythm is the rhythm with the most reliable estimates, which is isolated using one of the standard mathematical methods for determining hidden rhythms, for example, cosinor analysis (see, for example, Cugini P., Di Palma L. Cosinor analysis: a procedure for estimating biological rhythms as integral function by measuring the area under their best-fitting waveform profile. Biol. Rhithm Res. 25: 94: 15-36).

To highlight the dominant IF rhythm, it is preferable to use the standard Time Series Analysis (TSA) software packages of Seriel Cosinor V5.2 or TSA Seriel Cosinor 6.3 (see, for example, http // www.euroestech.net / downloaduk.php), which have the most developed service support system and give the most accurate results.

The TSA program provides, according to the measurements taken for dc and ins, the allocation of periods of dominant rhythms and their graphical construction (forecast) in time with the imposition of measurement results to assess the reliability of the results. To ensure the accuracy of rhythm separation using cosinor analysis, the number of N measurements in a series should be at least six. The larger the number of measurements, the more accurate the final result. Measurements can be equally spaced or unequally spaced. The measurement time should not exceed 5-10 minutes.

Table 2 shows the results of pairwise IF measurements of the symmetric branches of the BI channel for N = 7.

Figure 5 shows the obtained from the measurement periodogram of the IF rhythm of the symmetric branches of the BI channel: right (Fig. 5a) and left (Fig. 6b).

The dominant rhythm of the dph of the right branch of the channel with a confidence of 70% is the rhythm with a period of 121.6 seconds and an average value of the dph of 29.8 seconds. For the left side channel IFs, the dominant rhythm with a confidence of 63% is the rhythm with a period of 182.4 seconds and an average value of IFs equal to 10.2 seconds.

A graphic image of the IF rhythms predicted in block 8-6 of the left and right branches of the BI channel with superimposed measurement results (dashed lines) are shown in Fig.6a and Fig.6b, respectively. The prediction of dominant IF rhythms is carried out for the duration of a reflex correction session.

In block 8-7, a channel branch with a large average IF value is selected, in this example, the right branch (Fig. 6a), and the start and end times of the positive half-waves of the predicted IF frequency rhythm following the time of the last IF frequency measurement are determined. On figa shaded the first two positive half-waves of the predicted rhythm IF d of the right branch of the channel selected for exposure.

When the current time coincides with the beginning of the first positive half-wave of the rhythm of the frequency converter, reflex correction of the right branch of the BI channel is performed.

To do this, by command from block 8-1, the controlled current generator 2 is transferred to the exposure mode. In this mode, under the control of the signal supplied to the control input of the current generator 2, it generates a sequence of pulses with a variable repetition rate within 28 ± 4 Hz, a pulse duration equal to 0.5 of the repetition period, and a current value that emits IR LED 12 infrared radiation with a wavelength in the range of 780-1400 nm and a power density that varies linearly during exposure from 200 mW / cm ² to 300 mW / cm ² .

The pulse repetition rate of 28 Hz corresponds to the average frequency β ₂ of the brain rhythm, and the frequency deviation of ± 4 Hz is selected from the condition of overlapping a possible range of individual changes in the frequency of β ₂ brain rhythm in patients, which has shown high efficiency in practice.

A linear increase in power density during exposure ensures the activity of the IF branch of the channel, regardless of its initial physiological state.

The pulse duration in the exposure mode is selected from the condition of the best physiological perception of IF by the patient in this mode, the pulse duration of 0.5 from the repetition period is selected experimentally.

To start the exposure, place the IR probe 1 on the AT of the right branch of the BI channel and press the switch button 13 at a time that corresponds to the beginning of the positive half-wave of the rhythm. Exposure to AT is carried out for one or several consecutive positive half-waves of the HR rhythm until the first pain in the patient appears (until the IF channel is reached) or until the total exposure time equal to TV is reached. The impact is terminated by pressing the button of the switch 13. By this, the effect on the AT is modulated by thermal pulses, ensuring the clinically maximum effect of the reflex correction due to the effect while the channel is in hypofunction. The total exposure time Tv choose no more than three minutes, which in most cases is sufficient for effective exposure. Longer exposure can cause burns to the skin surface.

After a time Tp of relaxation AT, a control measurement of the asymmetry of the channel on which the exposure was performed is carried out. The TP relaxation time AT necessary for stabilizing the AT activity after exposure is taken for at least 20 minutes (see, for example, Muzhikov VG Discrete thermopuncture test. Message 1. Principle, methods for conducting and evaluating results // Reflexotherapy. - 2005 . - No. 1 (12). - S.34-38).

If the asymmetry of the channel K> 1.64 during the control measurement is maintained, then continue the reflex correction in the subsequent after the control measurement positive half-wave rhythm of the specified branch of the channel until the asymmetry of the channel K <1.64. The number of subsequent exposures should not be more than three.

Preservation of the asymmetry of the channel after three exposure during one session indicates the organic nature of the disease, for treatment

which requires more frequent daily exposure for a long time, taking into account the severity of the disease. When revealing several asymmetric channels with K> L, they are reflexively corrected sequentially, starting from the channel with the greatest asymmetry.

In the above example, as a result of reflex correction, the asymmetry coefficient of the BI channel has become equal to K (BI) = 1.2, which indicates a clinically favorable result.

If necessary, control measurements can be continued in the dynamics of observation, which allows us to estimate the rhythm parameters in the symmetrical branches of the channel on the basis of the data obtained after exposure.

Example.

Patient B ..., 43 years old. Complaints of menstrual irregularities, pain in the lumbar spine.

In accordance with the algorithm of the operation of the claimed device using the manufactured prototype of the device, pairwise measurements of the IF of the right and left branches of the main channels were carried out, the results of which and the calculated asymmetry coefficients are presented in table 1.

According to the measurement results, the most pronounced asymmetry K = 4.54 was noted on the BI channel of the bladder, which corresponds to the nature of complaints. To assess the rhythm of the IF of the branches of this channel, 7 pairwise measurements of the IF of its right and left branches were performed (see table 2).

Figure 5 shows the TSA program calculated from these measurements of the IF rhythm periodogram of the symmetrical branches of the BI channel: right (Fig. 5a) and left (Fig. 6b). The dominant rhythm of the dph of the right branch of the channel with a confidence of 70% is the rhythm with a period of 121.6 seconds and an average value of the dph of 29.8 seconds. For the left side channel IFs, the dominant rhythm with a confidence of 63% is the rhythm with a period of 182.4 seconds and an average value of IFs equal to 10.2 seconds.

A graphical representation of the predicted rhythms of the left and right branches of the BI channel with superimposed measurement results (dashed lines) are shown in Fig.6a and Fig.6b, respectively.

The channel branch with a large average IF value is the right branch (Fig. 6a). On figa shaded the first two positive half-waves of the predicted rhythm IF d, following after the time of the last measurement IF d.

If the current time coincided with the beginning of the first positive half-wave of the rhythm of the dcd, the BId point was exposed during two consecutive positive half-waves until the first pain in the patient appeared, which occurred 112 seconds after the start of exposure.

20 minutes after the end of the exposure, a control measurement of the asymmetry coefficient of the BI channel was carried out, which revealed a significant decrease in the level of asymmetry. K (VI) became equal to 1.2 (see table 3), which indicates a clinically favorable result. Table 3 also shows the results of additional IF measurements of the remaining channels after exposure.

10 minutes after the end of the exposure, the patient noted a complete absence of lower back pain.

According to the results of an additional control evaluation of the rhythm parameters in the symmetric branches of this channel, 25 minutes after the termination of reflex correction, the alignment of the amplitude and frequency of the IF rhythms in both branches was noted, which confirms the normalization of the channel state.

Assessment of the state of organs and systems of the patient’s body by the asymmetry coefficient of the IF channels increases the reliability of determining their functional disorders. Carrying out reflex correction on the channel with the greatest asymmetry while the canal branch is in a state of hypofunction, it reduces the time spent on normalizing the functional state of organs and systems of the body.

The proposed device for the implementation of reflex correction makes it possible to obtain reliable and reliable results, convenient in work and can be used in everyday practice of specialists.

Tables

Table 1
- Results of primary IF measurement of the main channels Channel Lu Li NA TN Ht SI SP Liv St GB Ki BI IF d (sec) 7 5 5 5 four 5 9 10 9 10 9 59 IFs (sec) 6 5 5 four 6 5 eleven 5 5 7 8 13 TO 1.17 1,2 one 1.25 1,5 one 1.22 2 1.8 1.43 1.12 4,54 table 2
- Results of pairwise IF measurements of symmetric branches of the BI channel No. p / p (d / s) Measurement time (sec) IF d (sec) IFs (sec) 1d
1s 0
fourteen 37 13 2d
2s 38
52 29th 12 3d
3s 67
80 13 12 4d
4s 161
169 43 6 5d
5s 183
195 10 9 6d
6s 300
309 27 8 7d
7s 341
352 25 9 Table 3
- Results of the control measurement of the IF of the main channels Channel Lu Li NA TN Ht SI SP Liv St GB Ki BI IF d (sec) 6 6 8 5 6 5 7 6 6 9 13 24 IFs (sec) 6 5 6 6 5 6 8 7 5 10 eleven twenty TO one 1,2 1.33 1,2 1,2 1,2 1.14 1.17 1,2 1,1 1.18 1,2

Claims (4)

1. A device for the reflex correction of functional disorders of the body, containing an element of thermal effect on AT in the form of an infrared (PC) LED connected to a controlled current generator, characterized in that a multifunctional indicator and control buttons are connected to it via an input / output unit with the microcontroller’s network bus, including a microprocessor connected to the network bus, a program block, a data memory unit and a timer / counter, while the IR LED is located in the IR probe, which contains a switch start / stop, the anode of the LED is connected to the positive bus of the controlled current generator, the negative bus of which, the cathode of the LED and the first contact of the start / stop switch are connected to the common ground bus, the second contact of the start / stop switch and the input of the controlled current generator are connected through the input unit I / O with a microcontroller network bus, and the microcontroller program block is configured to control operating modes, transfer a controlled current generator from measurement mode to exposure mode, measure IF channels, calculate AC channel metrics, allocation of dominant rhythms of IF channels, their prediction, allocation of positive half-waves of a rhythm and exposure during positive half-waves of a rhythm, as well as generation of data for display on a multifunctional indicator. 2. The device according to claim 1, characterized in that the start / stop switch is made in the form of a push-button switch with self-resetting, the IR probe is made in the form of a handle of insulating material, on the outer surface of which there is a start / stop switch button, and at the end of the handle is located IR LED. 3. The device according to claim 1, characterized in that the microcontroller program block comprises two-way communication with the program block bus, which is its input / output, the operating mode control unit, the current generator control signal generation unit, the IF channel measurement unit, the calculation unit asymmetries of the channels, a block for isolating the dominant rhythms of the IF channel, a block for predicting the rhythms of the IF channel, a block for extracting positive half-waves of the rhythm, and a block for generating data for display. 4. The device according to claim 1, characterized in that the controlled current generator provides the ability to emit an IR LED: in measurement mode, pulsed infrared radiation with a wavelength in the range from 780 to 1600 nm, a repetition period of 1 s, and a pulse duration in the range from 0 , 7 to 0.9 s and a power density per pulse of 200 mW / cm ² , and in the exposure mode - pulsed infrared radiation with a wavelength in the range from 780 to 1600 nm, with a varying repetition rate within 28 ± 4 Hz, pulse duration equal to 0.5 of the repetition period And a power density per pulse which varies linearly over the exposure time in the range from 200 to 300 mW / cm ^2.