RU2252694C1 - Method for evaluating psychophysiological state of human body - Google Patents

Abstract

FIELD: medicine, reflexodiagnostics.

SUBSTANCE: one should measure the index of bioelectromagnetic reactivity (BEMR) in controlled points on patient's body surface. As controlled points one should apply areas of points Xe-ГУ and paired points of symmetry in carotid sinus area. BEMR index should be measured both before and after test impact upon patient's in controlled points. One should fix the results of measuring and calculate the modulus of difference in measured BEMR values for every pair of symmetrical points. Moreover, one should calculate coefficients of asymmetry Q, W, M in controlled points of carotid sinus area by formulas. As a test one should stimulate receptors of mouth cavity or those of olfactory department. According to the data obtained one should conclude upon patient's psychophysiological state.

EFFECT: higher accuracy of evaluation.

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Description

The invention relates to medicine, namely to diagnosis, and can be used to assess the psychophysiological state of the human body.

There is a method of psychophysiological research of a person and a device for its implementation, according to which the force caused by the manifestations of the vital activity of the human body is recorded, signals corresponding to a cardiac impulse, respiratory excursions of the chest and motor activity are isolated, background characteristics are compared with those measured after a constant time interval and diagnosed stress response with deviations: 60> heart rate> 80; 14> BH> 20; 0.5> Tpok> 0.73, where heart rate is the heart rate, BH is the respiration rate, Tpok time interval. A device for the psychophysical study of a person is a platform made in the form of two parallel platforms, interconnected by three supports, which are piezoelectric type force sensors. The device provides a measurement of the dynamic component of the force applied to the platform (RF Patent No. 2125649, February 27, 1999, A 51 V 5/16).

The main disadvantage of this method is the narrow diagnostic capabilities, since the method allows you to record only a stressful situation. In the known method, all the controlled signals are received not directly by taking information from the human body, but indirectly: they are isolated from the general signal — the oscillatory signal from the piezoelectric sensors, which reduces the reliability of the information.

In addition, the signal from the sensors is formed under the influence of the weight of a person who sits on a chair mounted on the platform, and his physical effort as a result of emphasis on the platform. The latter cannot be fulfilled in the optimal variant, since the physical effort of a person applied to the platform, its magnitude, depend to a large extent on the optimum location on the chair and the position of the subject's body. Since the optimality of the options is evaluated by the operator and the subject himself, a subjective factor is introduced into the research results, which reduces the reliability of the research results. In addition, the method is difficult to implement, since it requires a sufficiently complex device for its implementation.

Thus, the known method for assessing the state of psychophysical human health in the implementation does not ensure the achievement of a technical result, which consists in expanding the diagnostic capabilities of the method, in increasing the reliability and simplification.

Closest to the proposed is a method for assessing the psychophysiological state of the human body, including exposure to the human body by physical activity and assessment of the functional state of the body after exposure. To assess the functional state of the body, the index of bioelectromagnetic reactivity is measured at controlled points on the surface of the patient’s body, while the CE-GU points on the left and right hands and paired symmetry points in the synocarotid zone projected onto the carotid glomerulus and carotid sinus are used as controlled points accordingly, why the synocarotid zone is divided visually by a vertical line into two symmetric parts, then the bioelectromagnetic reactivity index (BEMR) is measured at controlled points kah of the synocarotid zone before and after exposure to the body by physical activity, and at the points of CE-GU after exposure. For each pair of symmetric points in the region of the synocarotid zone, the difference of the measured BEMR indices measured in them before and after exposure to a physical factor is calculated, and then the asymmetry coefficients Q and W are calculated using the formula for the studied points of the synocarotid zone with a projection onto the carotid glomerulus and the carotid sinus, respectively. Then, the coefficient of emotional stability R is determined in the same way by the formula and the index of the psychophysiological state of the human body is calculated J. For values of J more (-20), but less (+30), the psychophysiological state of the human body is determined as compensated, for values J less (-20) or more (+30) the psychophysiological state of the human body is defined as subcompensated (RF Patent No. 2209035, receipt date 04/29/2002, A 61 B 5/04).

The known method, in comparison with the analogue, has high reliability due to the use of a bioelectromagnetic reactivity index as a controlled parameter, the values of which accurately reflect the functional and morphological state of the tissues at controlled points. However, since the method evaluates the psychophysiological state of the body according to the reaction of the body to physical activity, this introduces an element of subjectivity in the results of the assessment, since it is difficult to control how faithfully the examined person performed physical exercises, which reduces the reliability of the results. The presence of mathematical formulas for calculating research results complicates the method. In addition, the known method allows to characterize the psychophysiological state of the body in general, namely: compensated and subcompensated, which narrows its diagnostic capabilities.

Thus, the known method for assessing the state of the psychophysical state of a person during implementation does not ensure the achievement of a technical result, which consists in expanding the diagnostic capabilities of the method, in increasing the reliability and simplification.

The present invention solves the problem of creating a method for assessing the psychophysiological state of the human body, the implementation of which allows to achieve a technical result, which consists in expanding the diagnostic capabilities of the method, in increasing the reliability and simplification.

The essence of the invention lies in the fact that in a method for assessing the psychophysiological state of a human body, including a test effect on the human body and assessing the functional state of the body after exposure, in order to assess the functional state of the body, the bioelectromagnetic reactivity index (BEMR) is measured at controlled points on the surface of the patient’s body , as controlled points, use the zones of CE-GU points on the left and right hands and paired symmetry points in the synocarotid zone with the projection to the carotid glomerulus and carotid sinus, respectively, for which the synocarotid zone is divided visually by a vertical line into two symmetrical parts, at the controlled points of the synocarotid zone, the BEMP index is measured before and after the test exposure to the body, and in the zones of CE-GU points after exposure, the measurement results are fixed, after which, for each pair of symmetric points in the region of the synocarotid zone, the modulus of the difference in the values of the BEMR indices measured in them is calculated before and after exposure and the asymmetry coefficients are calculated and Q and W at the controlled points of the synocarotid zone projected onto the carotid glomerulus and the carotid sinus, respectively, according to the general formula: Z = (1-Y / Y *) for Y is greater than Y * or Z = (1-Y * / Y) for Y is less than Y *, where Z is the value of the asymmetry coefficient, Y, Y * is, respectively, the modulus of the difference in the values of the BEMP indices for the pair of symmetrical points studied before and after exposure, as an test they have an irritating effect on the receptors of the oral cavity or the olfactory receptors, in addition , in the zones of the CE-GU points, the BEMR index is measured before the test exposure I on the body, calculate the difference between the measured values of the BEMR indices before and after exposure and calculate the asymmetry coefficient M according to the general formula, if the calculated asymmetry coefficients Q and W and the asymmetry coefficient M are in the range from 20 to 30% - they evaluate the psychophysiological state of the body as normal, if the asymmetry coefficients Q and W and the asymmetry coefficient M exceed 30% - state the presence of excitation, if these asymmetry coefficients are lower than 20% - state the presence of fatigue, if the asymmetry coefficients Q and W are lower than 20 %, and the asymmetry coefficient M exceeds 30% —adaptation is observed, if the asymmetry coefficient Q and W is higher than 30%, and the asymmetry coefficient M is lower than 20%, they indicate the presence of inhibition due to intoxication.

The technical result is achieved as follows. It is known that the receptor systems on the surface of organs, skin, and mucous membranes are highly reactive and transform the effects of both positive and negative factors on them into nerve impulses. Nerve impulse reaches the central nervous system and serves as the basis for the formation of the body's response to exposure. Under the influence of a negative factor, the central nervous system (CNS) forms a protective and adaptive reaction by changing the functional state of the body systems and the morphological and functional state of the tissues. It is known that reflexogenic zones of an organism possess the most accurate and quick reaction to the influence of external factors. Such reflexogenic zones include, in particular, the mucous membranes of the digestive tract and upper respiratory tract. As a result, the use of the proposed method as a test of the irritating effect on the receptors of the oral cavity or receptors of the olfactory department of the subject increases the reliability of the test results.

The choice of controlled points, namely: the zone of CE-GU points on both hands of the patient and paired points of symmetry in the synocarotid zone with a projection onto the carotid glomerulus and the carotid sinus, is due to the following. When exposed to a drug substance, food product, physical factor, etc. first of all, integrative blood indices change quite quickly (in particular, oxygen tension, carbon dioxide tension, pH), the tone of the autonomic nervous system changes, and metabolic processes at the periphery can change significantly. As mentioned above, the most accurate and quick reaction to external factors is the reflexogenic zones of the body. Such reflexogenic zones, in addition to the mucous membranes of the digestive tract and upper respiratory tract, include extrareceptive zones of the skin - zones of acupuncture points and the synocarotid zone.

The meridian of the colon begins from the nail bed of the index finger, continues along the radial edge of this finger between the first and second metacarpal spaces and further to the ulnar fold. At the end, the meridian crosses the lower jaw anterior to its corner and ends at the top of the nasolabial fold. The XE-GU point is the fourth point of the meridian and is located on the line of the meridian between the point in the corner between the thumb and forefinger, and the point on the wrist. The acupuncture point CE-GU is located on the meridian of the colon and is one of the main points of the meridian. The XE-GU point is a source point and an accomplice point and serves to maintain the main point of the meridian. It can enhance the action of the two main points of the meridian as a tonic point, and sedative. In addition, the HA-GU point is the point of energy influx. Through it, energy comes from the previous meridian (F.G. Portnov. Electropuncture reflexotherapy. Riga: ZINATNE, 1987, p. 37, 38, 49, 50, p. 64). It is known that the main acupuncture points that have certain symptoms are located on the meridians, in particular, the conditions of the mucous membranes and excretory system are diagnosed by the acupuncture points of the colon meridian. Consequently, changes in the morphological and functional state of tissues in the zone of the CE-GU point adequately reflect changes in the system of secretions and mucous membranes under the influence of a negative or positive factor, in our case, under the influence of a testing effect.

Thus, the CE-GU point is one of the most active points of the colon meridian, which actively responds to changes in the vital processes of the body, which is adequately reflected in changes in the morphological and functional states of the tissue in the area of the acupuncture point. In this case, the CE-GU point is in direct connection with the reflexogenic zones of the mucous membrane of the body and with metabolic processes in the body. As a result, the use of the CE-GU point as the test one allows us to record the state of microcirculation and metabolic processes in the tissues on the periphery before and after the test exposure, which allows us to use it to control the reaction to the test effect of the somatic nervous system of the body.

The sinocarotid zone is anatomically located at the branching point of the common carotid artery into the external and internal and consists of two formations - the carotid sinus and the carotid glomerulus (body). The carotid glomerulus contains chemoreceptors that are sensitive to changes in the gas composition of the blood and determine the complex reaction of the blood to the action of substances entering the human body, the effects of stressful situations, physical factors, etc. Therefore, the value of the controlled parameter in paired points in the region of the synocarotid zone with a projection onto the carotid glomerulus reflects the state of blood and blood supply to the head, which makes it possible to evaluate the effects of the test effect on the body by the reaction of the blood in the complex.

The carotid sinus is the innervated part of the vessels, in the shell of which there are barreceptors that respond to changes in blood pressure and reflect the state of the vessels, due to the tone of the autonomic nervous system. Monitoring points in the area of the sinocarotid zone with a projection onto the carotid sinus allows us to evaluate the response of the autonomic nervous system to the test effect.

Thus, changes in the controlled parameter in the zones of CE-GU points on both hands and paired points of symmetry in the synocarotid zone with a projection onto the carotid glomerulus and the carotid sinus reflect neuro-humoral regulation mechanisms and a functional relationship with the process under study, which makes it possible to control the consequences test effects on the body as a whole and ensures the reliability of the results of assessing the psychophysiological state of a person.

As an evaluation criterion in the proposed method using the index of bioelectromagnetic reactivity (BEMR). The measurement of the BEMR index is based on the property of living tissue to transform electromagnetic waves induced by external electromagnetic fields in the form of a response signal, namely, geo- and heliomagnetic fields, which are low-frequency pulsed complex-modulated fields that are most appropriate for a living organism. As a result of the bioelectric activity of living tissues, when a living organism (organ) is exposed to external electromagnetic fields, a low-frequency pulsed complex-modulated EMF is induced in living tissues in the form of electromagnetic oscillatory processes, but its spectral composition differs from the spectral composition of the acting EMF (V.I. Bankov and etc. Low-frequency pulsed complex-modulated electromagnetic fields in medicine and biology. Ekaterinburg: Publishing House of Ural State University, 1992, p. 33 ... 43). All layers of tissue are involved in the formation of parameters of electromagnetic oscillations, since intrinsic oscillatory processes in living tissue (organ) are caused by metabolic processes and microcirculation, which is based on certain parameters of homeostasis. Therefore, the parameters of electromagnetic vibrational processes in living tissue correspond to a very specific functional and morphological state of living tissue (Sent-Dieri A. “Bioenergy” Theory of energy transfer. M: Publishing house FIZMAT, 1960, p.3 ... 14). All this made it possible to control the functional and morphological state of the tissue by analyzing the appearance or disappearance of one or another harmonic interacting with the tissue. This is called the “determination of the bioelectromagnetic reactivity index of living tissues” - the BEMP index (V.I. Bankov et al. Low-frequency pulsed complex-modulated electromagnetic fields in medicine and biology. Ekaterinburg: Publishing House of Ural State University, 1992, p. 38; Using the properties of a pulsed complex-modulated field for physiological studies of the central nervous system. Abstract for the degree of Doctor of Biological Sciences. M: USSR Academy of Sciences, Institute of Higher Nervous Activity and Neurophysiology, 1988, p. 12 ... 1 4).

Thus, in the proposed method, the measured values of the BEMR indices at controlled points on the skin surface in the synocarotid zone and in the zones of CE-GU points on the skin surface of both hands correspond to the functional and morphological state of the tissues in the area of these points, which ensures the reliability of the control results and allows you to evaluate the effect of the test on the body as a whole.

The proposed method is based on the fundamental property of the human body - bilateral symmetry, which is determined by the duplication of the anatomical structures of the body and increases the reliability of its functioning in extreme environmental conditions (skin extra-receptors / some issues of local diagnosis and therapy / E.S. Velhover, G.V. .Kushnir. Chisinau: STIINCA, 1984, p. 28 ... 40). Bilateral symmetry is closely related to functional (physiological) asymmetry, due to the predominance of the regulatory functions of the cerebral hemispheres and parts of the autonomic system (parasympathetic or sympathetic). Ideally, the functional asymmetry should be close to zero. However, due to the different neuro-trophic (regulatory) functions of the central nervous system, living tissues of symmetrical organs (or symmetrical parts of the organ) have a different level of metabolic processes, microcirculation (blood supply) (Ognev B.V. Asymmetry of the human vascular and nervous system, their theoretical and practical value.Vestnik of the Academy of Medical Sciences: USSR, 1948, No. 4, p.264 Skobsky IL Humoral asymmetry in the organism of the development of diseases.M .: 1969, p.35 ... 60; Piransky BC Symmetry and asymmetry of the anatomical structure. works of Saratovs Medical Institute, 1968, v. 56, issue 73, p. 125; E.S. Velhover, U. V. Kushnir. Skin extra-receptors / some issues of local diagnosis and therapy /, Chisinau: STIINCA, 1984, p. 28 ... 40). For the surface of the skin of healthy symmetrical organs or their symmetrical parts, the functional (physiological) norm is a shift of symmetry from 20 to 30%. Using the properties of the human body - the presence of bilateral symmetry allows us to evaluate the results of the testing effect on the human body by the level of mismatch of the controlled parameter at the pair of symmetry points of the organ under study - the synocarotid zone, for which the synocarotid zone is divided visually by a vertical line into two symmetric parts, and at the points XE-GU on the hands of the left and right hands. Using the natural property of the human body — the presence of bilateral symmetry to evaluate the results of the testing effect, ensures the reliability of the evaluation results.

The result of calculating for each pair of symmetric points under study the values of the differences of the BEMR indices measured in them before and after the test exposure characterizes the functional asymmetry at these points, respectively, before and after the exposure.

The result of calculating the quotient of the division Y / Y * or Y * / Y, where Y, Y * is the difference in the values of the BEMR indices for the pair of symmetric points studied before and after exposure, allows you to quantify how many times the asymmetry has changed after exposure.

The calculation of the asymmetry coefficients Q, W, and M at the studied points of the synocarotid zone and at the CE-GU points, respectively, according to the general formula: Z = (1-Y / Y *) for Y is greater than Y * or Z = (1-Y * / Y) for Y less than Y * allows us to estimate how much the asymmetry value at the studied points differs from unity, i.e. from the ideal value.

Due to the fact that the test method of the proposed method uses an irritating effect directly on the receptors of the oral cavity or receptors of the olfactory department, which convert them into nerve impulses, it is possible to directly transmit the test effect to the central nervous system, which increases the reliability of the assessment of the psychophysiological state of the subject. Moreover, thanks to the choice of control points, the values of the BEMR indices measured at the control points reflect the state of the autonomic and somatic nervous systems. As a result, in the proposed method, the reaction to the effect generated directly by the nervous system of the body is controlled, which also increases the reliability of the method. The ability to control the reaction to the effect formed directly by the nervous system of the body, allowed us to use the proposed method for assessing the psychophysiological state of a person to identify the presence of a mismatch in the joint work of the autonomic and somatic nervous systems. The presence of a quantitative characteristic of the mismatch made it possible to specify the psychophysiological state of a person, which expanded the diagnostic capabilities of the method.

As was shown above, control of points in the region of the synocarotid zone with a projection onto the carotid sinus allows us to evaluate the reaction of the autonomic nervous system to a test effect on the body. The autonomic nervous system, innervating the smooth muscles of all organs, the heart and glands, is responsible for the nervous regulation of the internal environment. The functions of the autonomic nervous system are to maintain the constancy of the internal environment (homeostasis) or to adapt it to changing environmental conditions (for example, mechanical work, food intake, lack of water, heat and cold, etc.). Therefore, the state of blood and blood supply to the head, controlled at points in the region of the synocarotid zone with a projection onto the carotid glomerulus, is a factor reflecting the activity of the autonomic nervous system. As a result, the values of the asymmetry coefficients Q, W characterize the combined reaction of the autonomic nervous system to the test effect.

The influence of the autonomic nervous system is usually not directly controlled by the consciousness, while the somatic nervous system is responsible for the afferent and efferent connections of the body with the environment and in most cases is controlled by consciousness. In the body, the autonomic and somatic nervous systems act synergistically. Their nerve centers, at the level of the trunk and hemispheres of the brain, cannot be separated morphologically. In the proposed method, the response to the testing effect of the somatic nervous system of the body reflects the value of the symmetry coefficient M. In a healthy body, the action of both nervous systems is consistent, therefore, in this case, the asymmetry coefficients Q, W and M correspond to the norm: from 20 to 30%. Therefore, if the calculated asymmetry coefficients Q and W and the asymmetry coefficient M are within normal limits, i.e. from 20 to 30% - evaluate the psychophysiological state of the body as normal.

If the asymmetry coefficients Q and W or the asymmetry coefficient M take values different from the norm, this indicates the presence of a mismatch in the action of the autonomic and somatic nervous systems. It was experimentally obtained: if the asymmetry coefficients Q and W and the asymmetry coefficient M exceed 30%, they indicate the presence of excitation, if these asymmetry coefficients are lower than 20%, they indicate the presence of fatigue, if the asymmetry coefficients Q and W are lower than 20%, and the asymmetry coefficient M exceeds 30% % - detect maladaptation, if the asymmetry coefficient Q and W is higher than 30%, and the asymmetry coefficient M is lower than 20% - they indicate the presence of inhibition due to intoxication.

The lack of complex mathematical formulas for the quantitative assessment of the psychophysiological state of the body simplifies the proposed method, compared with the prototype.

Thus, from the foregoing, it follows that the proposed method for assessing the psychophysiological state of the human body during the implementation ensures the achievement of a technical result, which consists in expanding the diagnostic capabilities of the method, in increasing the reliability and simplification.

The method of assessing the psychophysiological state of the human body is implemented as follows. In accordance with the method, a test effect on the human body and an assessment of the functional state of the body after exposure are performed. As a test, they irritate the receptors of the oral cavity or receptors of the olfactory department. Before and after exposure, BEMR indices are measured at controlled points on the patient’s body surface: zones of CE-GU points on the left and right hands and paired symmetry points in the synocarotid zone with a projection onto the carotid glomerulus and the carotid sinus. Then, for each pair of symmetric points, the difference between the measured BEMR indices measured before and after the exposure is calculated, and the asymmetry coefficients Q, W, M are calculated at the controlled points of the synocarotid zone projected onto the carotid glomerulus and carotid sinus, respectively, according to the general formula: Z = ( 1-Y / Y *) for Y is greater than Y * or Z = (1-Y * / Y) for Y is less than Y *, where Z is the value of the asymmetry coefficient, Y, Y * is the modulus of the difference in the values of the BEMR indices for the pair of studied symmetrical points before and after exposure. Assess the functional state of the body after exposure: if the calculated asymmetry coefficients Q and W and the asymmetry coefficient M are in the range from 20 to 30% - assess the psychophysiological state of the body as normal, if the asymmetry coefficients Q and W and the asymmetry coefficient M exceed 30% - note the presence excitations, if these asymmetry coefficients are lower than 20% - note the presence of fatigue, if the asymmetry coefficients Q and W are lower than 20%, and the asymmetry coefficient M exceeds 30% - they detect maladaptation, if the coefficient the asymmetry coefficient Q and W is higher than 30%, and the asymmetry coefficient M is lower than 20% - they indicate the presence of inhibition due to intoxication.

The method can be implemented by means of a device for determining the bioelectromagnetic reactivity of living organ tissues, a block diagram of which is described in the literature: V.I. Bankov et al. Low-frequency pulsed complex-modulated fields in medicine and biology, Ekaterinburg: Ural University Press, 1992, p. 39, Fig. 8.

The device contains a sensor that is applied to the surface of the tissue under study, a balanced demodulator, a pulsed complex modulated electromagnetic field generator (ISM EMF), a corrector, a detector, an amplifier, an analog-to-digital converter, and an indicating device. As a sensor, the device uses a miniature loop antenna, which is part of the measuring open oscillatory circuit, tuned to a pulsed complex-modulated mode of operation. In addition to the sensor, the measuring oscillatory circuit includes an ISM EMF generator, a balanced demodulator, a detector, and a corrector. The vibrational circuit is excited at the moment the sensor touches the surface of living tissue.

Currently, the device is implemented in the expert-diagnostic device “Lira-100”, developed and manufactured in the department of medical cybernetics of the Central Scientific Research Laboratory of the Ural State Academy. The device was demonstrated in 1997 at the All-Russian Exhibition of Manufacturers of Medical Equipment and Medical Devices and was awarded the I Degree Diploma by the Ministry of Health. The device is protected by patents of the Russian Federation: No. 2107964 with priority 04/28/95, No. 2080820 with priority from 08/01/94, No. 2095758 with priority 04/28/95, No. 96121429/07 with priority from 04/28/95. The device contains a sensor, converter, amplifier - filter, microprocessor, analog-to-digital converter and recorder - indicator. The sensor is made in the form of a miniature loop antenna and provides registration of the IMS EMF of living tissues in the form of values of the BEMR indices that are displayed on the indicator screen. The sensor is mounted on the surface of the body without strong pressure so as not to spontaneously increase local microcirculation.

In all examples of the method, the college students at the Mining Academy of Yekaterinburg acted as the subjects. The age of the subjects 18, 19 years.

Secondary measurements of the BEMR index at control points were performed 2 ... 3 minutes after the test exposure. This time is enough for the formation of the adaptive reaction to the impact by the nervous system of the body.

As a test that has an irritating effect on the receptors of the oral cavity, any strong taste irritant was used, for example, carbonated mineral or any carbonated water (0.5 cups), chewing gum with a strong taste stimulus (chewing time 1 minute); ammonia, toilet, perfume, etc. were used to affect the olfactory receptors. The impact on the receptors of the olfactory department was carried out from two to three seconds.

All test results are confirmed by clinical studies.

Example 1. Surveyed K., age 19 years old, assessed the psychophysiological state of the body in accordance with the claimed method.

The test effect was carried out on the receptors of the oral cavity. As a test exposure, the subject was asked to drink half a glass of mineral water.

At controlled points on the surface of the patient’s body: paired symmetry points in the synocarotid zone projected onto the carotid glomerulus (T1, T2) and the carotid sinus (T3, T4), respectively, and the CE-GU points on the left and right hands (T5, T6 ), - BEMR indices were measured before and after exposure.

Before exposure: T1 = 4.494; T2 = 4.282; T3 = 4.024; T4 = 4.212; T5 = 4.659; T6 = 4.047.

After exposure: T1 = 3.529; T2 = 3.341; T3 = 3.394; T4 = 3.506; T5 = 3.482; T6 = 3.388.

Then, for each pair of symmetric points, the difference between the measured BEMR indices measured before and after the exposure was calculated.

Before exposure: Y1 = 0.212 Y2 = 0.188 Y3 = 0.612 After exposure: Y1 '= 0.188 Y2 '= 0.212 Y3 '= 0.098

Then, the asymmetry coefficients Q, W, and M were calculated at controlled points using the general formula: Z = (1-Y / Y *) for Y greater than Y * or Z = (1-Y * / Y) for Y less than Y *, where Z - the value of the asymmetry coefficient, Y, Y * - respectively, the difference in the values of the BEMR indices for the pair of symmetrical points studied before and after exposure.

Q = (1-0.188 / 0.212) = 0.113 Q = 11.3% W = (1-0.188 / 0.212) = 0.113 W = 11.3% M = (1-0.098 / 0.612) = 0.84 M = 84%

Thus, the asymmetry coefficients Q and W are lower than 20%, and the asymmetry coefficient M exceeds 30%. The psychophysiological state of the body of the subject is assessed as maladaptation.

Example 2. Surveyed P., age 19 years, assessed the psychophysiological state of the body in accordance with the claimed method.

The test effect was carried out on the receptors of the oral cavity. Chewing gum with menthol was proposed as a test exposure.

At controlled points on the surface of the patient’s body: paired points of symmetry in the synocarotid zone projected onto the carotid glomerulus (T1, T2) and the carotid sinus (TK, T4), respectively, and the CE-GU points on the left and right hands (T5, T6 ), BEMR indices were measured before and after exposure.

Before exposure: T1 = 3.889; T2 = 3.369; T3 = 3.976; T4 = 3.388; T5 = 3.835; T6 = 4.118.

After exposure: T1 = 5.035; T2 = 4.494; T3 = 4,800; T4 = 3.882; T5 = 4.518; T6 = 4.635

Then, for each pair of symmetric points, the difference between the measured BEMR indices measured before and after the exposure was calculated.

Before exposure: Y1 = 0.165 Y2 = 0.588 Y3 = 0.283 After exposure: Y1 '= 0.541; Y2 '= 0.918 Y3 '= 0.17

Then, the asymmetry coefficients Q, W, and M were calculated at controlled points using the general formula: Z = (1-Y / Y *) for Y greater than Y * or Z = (1-Y * / Y) for Y less than Y *, where Z - the value of the asymmetry coefficient, Y, Y * - respectively, the difference in the values of the BEMR indices for the pair of symmetrical points studied before and after exposure.

Q = (1-0.165 / 0.541) = 0.695 Q = 69.5% W = (1-0.588 / 0.918) = 0.359 W = 35.9% M = (1-0.17 / 0.283) = 0.587 M = 58.7%

Thus, all the asymmetry coefficients Q, W, and M are above 30%, which indicates the presence of excitation.

Example 3. Surveyed N., aged 18 years, assessed the psychophysiological state of the body in accordance with the claimed method.

The test effect was carried out on the olfactory receptors. As a test exposure, the subject was asked to smell ammonia.

At controlled points on the surface of the patient’s body: paired points of symmetry in the synocarotid zone projected onto the carotid glomerulus (T1, T2) and the carotid sinus (TK, T4), respectively, and the CE-GU points on the left and right hands (T5, T6 ), BEMR indices were measured before and after exposure.

Before exposure: T1 = 4.941; T2 = 5.271; T3 = 4.659; T4 = 4.706; T5 = 3.741; T6 = 3,459

After exposure: T1 = 4.705; T2 = 4.918; T3 = 4,000; T4 = 4.282; T5 = 3.388; T6 = 3.082

Then, for each pair of symmetric points, the difference between the values of the BEMR indices measured in them before and after exposure was calculated.

Before exposure: Y1 = 0.33 Y2 = 0.047 Y3 = 0.282 After exposure: Y1 '= 0.212 Y2 '= 0.282 Y3 '= 0.306

Then, the asymmetry coefficients Q, W, and M were calculated at controlled points using the general formula: Z = (1-Y / Y *) for Y greater than Y * or Z = (1-Y * / Y) for Y less than Y *, where Z - the value of the asymmetry coefficient, Y, Y * - respectively, the difference in the values of the BEMR indices for the pair of symmetrical points studied before and after exposure.

Q = (1-0,212 / 0,0,330) = 0,358 Q = 35.8% W = (1-0.047 / 0.282) = 0.833 W = 83.3% M = (1-0.286 / 0.306) = 0.065 M = 6.5%

Thus, all the asymmetry coefficients Q, W are higher than 30%, and M is lower than 20%, which indicates the presence of inhibition due to intoxication.

Example 4. Surveyed L., age 18 years old, assessed the psychophysiological state of the body in accordance with the claimed method.

The test effect was carried out on the olfactory receptors. As a test exposure, the subject was asked to smell cologne.

At controlled points on the surface of the patient’s body: paired symmetry points in the synocarotid zone projected onto the carotid glomerulus (T1, T2) and the carotid sinus (T3, T4), respectively, and the CE-GU points on the left and right hands (T5, T6 ), BEMR indices were measured before and after exposure.

Before exposure: T1 = 3,506; T2 = 4.213; T3 = 3.835; T4 = 3.294; T5 = 3.647; T6 = 4.363.

After exposure: T1 = 3.882; T2 = 1.788; T3 = 4.259; T4 = 2.988; T5 = 3.976; T6 = 4.424

Then, for each pair of symmetric points, the difference between the measured BEMR indices measured before and after the exposure was calculated.

Before exposure: Y1 = 0.1.157 Y2 = 0,0,541 Y3 = 0.716 After exposure: Y1 '= 0.2.094 Y2 '= 1.271 Y3 ' = 0,0,266

Then, the asymmetry coefficients Q, W, and M were calculated at controlled points using the general formula: Z = (1-Y / Y *) for Y greater than Y * or Z = (1-Y * / Y) for Y less than Y *, where Z - the value of the asymmetry coefficient, Y, Y * - respectively, the difference in the values of the BEMR indices for the pair of symmetrical points studied before and after exposure.

Q = (1-1.157 / 2.094) = 0.448 Q = 44.8% W = (1-0.541 / 1.271) = 0.574 W = 57.4% M = (1-0.266 / 0.716) = 0.372 M = 37.2%

Thus, all the asymmetry coefficients Q, W, and M are above 30%, which indicates the presence of excitation.

Claims (1)

A method for assessing the psychophysiological state of the human body, including a test effect on the human body and assessing the functional state of the body after exposure, in order to assess the functional state of the body, the bioelectromagnetic reactivity index (BEMR) is measured at controlled points on the patient’s body surface, point zones are used as controlled points CE-GU on the left and right hands and paired points of symmetry in the synocarotid zone with a projection on the carotid glomerulus and on the carotid insus, respectively, for which the synocarotid zone is divided visually by a vertical line into two symmetric parts, at the controlled points of the synocarotid zone, the BEMR index is measured before and after the test exposure to the body, and in the zones of CE-GU points after exposure, the measurement results are recorded, and then for each pair of symmetrical points in the region of the synocarotid zone, the modulus of the difference of the measured BEMR indices measured in them before and after exposure is calculated, and the asymmetry coefficients Q and W at the controlled points of the synocarotids are calculated zone with a projection onto the carotid glomerulus and the carotid sinus, respectively, according to the general formula Z = (1-Y / Y *) for Y is greater than Y * or Z = (1-Y * / Y) for Y is less than Y *, where Z is the value of the asymmetry coefficient, Y, Y *, respectively, the modulus of the difference in the values of the BEMR indices for the pair of symmetrical points studied before and after exposure, characterized in that they have an irritating effect on the oral or olfactory receptors as a test, in addition, in the areas of the points CE-GU measure the BEMR index before the test effect on the body, calculated the difference between the measured values of the BEMR indices before and after exposure and calculate the asymmetry coefficient M according to the general formula, if the calculated asymmetry coefficients Q and W and the asymmetry coefficient M are in the range from 20 to 30% - assess the psychophysiological state of the body as normal if the asymmetry coefficients Q and W and the asymmetry coefficient M exceed 30% - note the presence of excitation, if these asymmetry coefficients are lower than 20% - state the presence of fatigue, if the asymmetry coefficients Q and W are lower than 20%, and the asymmetry coefficient M etria exceeds 30% - they indicate maladaptation, if the asymmetry coefficient Q and W is higher than 30%, and the asymmetry coefficient M is lower than 20% - they indicate the presence of inhibition due to intoxication.