RU2236164C1 - Method and device for studying state and correcting human organism functioning systems - Google Patents

Abstract

FIELD: medical engineering; medicine.

SUBSTANCE: method involves analyzing macroscopic image of frontal eye part. Dynamic changes of color tints saturation and symmetry in their distribution on visible frontal eye parts are studied. The frontal eye parts are illuminated with luminous flux with illumination intensity equal to 10-300 lx, temperature equal to 3200-3800° K. The image is taken from the illuminated zone and displayed on screen. Color tints and distribution structure symmetry are recorded on visible frontal eye parts in time period required for obtaining total difference in color background structure symmetry on each discrete binocular eye movement displayed on the screen. When correcting human organism functioning systems, irritating agents are used and the organism functioning systems are made return to normal state with biofeedback being used by observing changes in color tints and image structure symmetry when acting with irritating agents. The device has head support member, chamber for recording color tints and image structure symmetry within anterior chamber area, its objective is directed to patient under study, screen connected to image transfer camera channel and light source for illuminating human body zone under study. The screen is positioned on direct visibility line of sight of patient under study whose head is fixed on support member. The light source produces luminous flux with illumination intensity equal to 10-300 lx, temperature equal to 3200-3800° K. The device also has flexible optical fiber light guide for transferring the luminous flux from the luminous source to zone to be illuminated.

EFFECT: enhanced effectiveness in identifying and adjusting human organism functioning systems states.

3 cl, 1 dwg

Description

The invention relates to the field of diagnostics and early warning of occupational risks by monitoring and correcting the working ability of workers, as well as to the field of healthcare, in particular, to determining deviations of the psychophysiological functions of the human body from the norm, due to the state of the information environment of his body, and to returning the functions of the body and of his information environment to their optimal norm through exposure to the sensory systems of the human body, to the area is insured I, in particular, to determine the probability of an insured event the insured.

A known method of research and correction of the functioning systems of the human body, which consists in the fact that the examined person is illuminated with the iris, which is used for diagnostics, an image is taken from the illuminated area, a captured image is displayed on the screen, an assessment of the state of functioning systems of the organism of the examined person and the degree of deviation functions of his body from the norm are carried out according to color tones and symmetry of the image structure and, acting on the sensory systems of the body, achieve return reduction of the functioning systems of the body that have deviations from the norm to their optimal state (E.S. Velhover. Clinical Iridology. M.: Orbit, 1992, pp. 9, 113, 114).

A device is known for implementing a method for determining and correcting the functioning systems of a human body, containing a support for the head, a camera, the lens of which is aimed at the person being examined, a screen connected to the camera’s image transmission channel, and a light source for illuminating the area being examined (E.S. Velhover. Clinical Iridology, Moscow: Orbit, 1992, p. 113, 114).

The known method, implemented using the known device, allows you to display a flat image of the examined area, which determines the deviation of the functioning systems of the human body from the norm, and to assess the degree of possibility of each system of functioning of the human body returning to normal when exposed to it with appropriate drugs, physiotherapeutic and other means. However, the effectiveness of the impact of the known method on the human body is insufficient, since the person exposed to the known method has a passive role. In addition, the greatest efficiency of the method and device is implemented in a narrow range of lighting temperatures, providing a more realistic image of the illuminated portion of the face of the person under study due to the greatest saturation of the "blue" part of the spectrum, and illumination, providing the optimal signal-to-noise ratio in the camera.

The task to which this method and device for its implementation is directed is to determine with greater certainty the state of the functioning systems of the human body and their correction, as well as to determine the presence and possibility of developing individual abilities of the person being examined.

The technical result obtained from the use of the invention consists in the possibility of reliable determination of the state of the functioning systems of the human body from the displayed hologram of the examined illuminated anatomical zone of the human body, as well as the correction of the functioning of the body by stimulating self-regulation of body functions through biological feedback established by observation of the subject changes in color and symmetry of the image structure on the screen during Via stimuli.

The technical result from the use of the invention is achieved by the fact that in the method of studying the state of the functioning systems of the human body, a macroscopic image of the front of the eye is analyzed by dynamic changes in the saturation of color tones and the symmetry of the structure of their distribution on the visible front parts of the eye, while the front parts of the eyes are illuminated with a light flux with illumination equal to 10 to 300 lux, temperature from 3200 to 3800 Kelvin, they take an image from the illuminated zone, display the image On the screen, color tones and the symmetry of the structure of their distribution on the visible front parts of the eyes are recorded over a period of time necessary to obtain a summing difference in the color tone and symmetry of the structure with each discrete binocular micromotion of the eyes presented on the screen.

The result of the correction of the functioning systems of the human body from the use of the invention is achieved by the fact that in the method of correcting the functioning systems of the human body, the study of the functioning systems of the human body is carried out by analyzing the macroscopic image of the front of the eye by dynamic changes in the saturation of color tones and the symmetry of the structure of their distribution on the visible front parts of the eye while the front parts of the eyes are illuminated with a luminous flux with illumination from 10 to 300 lux, from 3200 to 3800 according to Kelvin, the image is taken from the illuminated area, the image is displayed on the screen, registration of color tones and symmetry of the structure of their distribution on the visible front parts of the eyes is carried out for the period of time necessary to obtain a summing difference in color tone and symmetry of the structure for each discrete binocular micromotion of the eyes presented on the screen, and acting on stimuli, they achieve the return of the functioning systems of the body to a normal state when used and biofeedback by observing the changes of color tones and the symmetry structure of the image during exposure to irritants.

In addition, in the device for studying the functional systems of the human body, containing a support for the head, a camera, the lens of which is aimed at the person being examined, a screen connected to the image transfer channel of the camera, and a light source to illuminate the area of the person being examined, the screen is placed on the line of sight the gaze of the examined person, whose head is placed on the support, and the light source is configured to create a luminous flux with illumination H from 10 to 300 lux and a color temperature T _c from 3200 to 3800 K, in A flexible fiber optic fiber has been introduced for transmitting the light flux from the light source to the illuminated area, while the camera is configured to register color tones and symmetry of the structure in the volume of the anterior chamber of the eye.

Information processes ensure the coordinated interaction of many functional systems in the human body to meet his needs from metabolic to mental and social levels. Most of these functional systems are converted to brain structures; as a result, the acceptors of the results of the action of individual functional systems are integrated into the brain into a single common information holographic screen of the brain.

By analogy with a physical hologram, the signaling about the needs of the body acts in the form of a reference wave, and the signaling about satisfying the needs of the body - the subject wave. The interaction of the reference and subject waves is carried out on the interference basis of the interaction of wave and discrete processes on special topographic information screens. The most perfect level of the holographic information screen of the body is the structure of the brain. An element of the holographic screen of the brain is a visual analyzer formed in ontogenesis "by the part of the brain extended to the periphery." Moreover, in his work (function), not only an analogy of the physical holographic process is observed, but also in his connective tissue media a physical optical hologram is formed - a volumetric color body.

Rhythmically organized unconscious binocular micro-movements of a person’s eyes when fixing spatial elements of the external environment are carried out according to a certain advanced program, which begins to take place in time even before the line of sight is directed at the object, and have certain amplitude-frequency characteristics. The paths of eye micromotion relative to the fixation object, combined on the plane of two-dimensional coordinates in the form of the positions of the total vector, form a crosshair on the coordinate plane - the “phenomenon of the cross”. The visual axis of the eyes most often intersect not on the "wings" of the cross, but in its center. Therefore, the accelerations arising from their "cam" movement are not the same; as a result of centrifugal movement of the chamber aqueous humor of the eye, sections of addition and subtraction of the "crests" of light waves appear, which create an interference pattern.

In accordance with the laws of coherent optics of micromotion, human eyes restore the reflected front of diffracted waves with respect to the characteristics of their frequency-spatial interaction with the observed object. Thus, micromotion of the eyes ensures the formation of a hologram as a result of interference in the tissue media of the eye of a light - object - wave and a reference wave created by binocular micromotion of the eye.

The anterior part of the eye, which includes the corneal layer irrigated by the lacrimal masses, and the anterior chamber of the eye, filled with a liquid crystal colloid, as well as the connective tissue of the iris containing fibroblasts, macrophages and pigment cells - melanocytes, as well as collagen tissue, plays the role of an analogue of layered photographic plate and forms a volumetric optical body of a hologram, which is reproduced on the screen by the camera.

As a result of the optical interference interaction of two information media of the body - external and internal - in the tissue media of the anterior part of the eye along its optical axis, a three-dimensional “optical color body” of the hologram (torus) appears, closed between two other “optical bodies” - “completely white body” "- sclera, and" absolutely black body "- the pupil.

The dynamics of changes in the saturation of various color tones of the “optical body” of the hologram, as well as the symmetry of their distribution — these colorioptical and geometric indicators — can reflect the state of adaptive results regulated by various functional systems.

The level of saturation of color tones of the visible part of the spectrum of the hologram of the anterior portion of the eye reflects the dynamics of the deviation of various physiological indicators from the individual norm, as well as their return to the optimal stable state.

The use of the holographic phenomenon of the anterior part of the eye was informative for identifying the typological features of self-regulation during psychoemotional stress and their relationship with higher mental functions and the social status of a person.

The state of the information environment (the psychophysiological state of the person being studied) is carried out by a specialist using visual analysis of a macroscopic image of the front of the eye according to dynamic changes in the saturation of color tones and the symmetry of the structure of their distribution on the visible front of the eyes. Can be used for analysis and auxiliary computer software that allows you to quantitatively register in the dynamics from visit to visit, as well as directly during the feedback session, changes in the saturation of color tones and the symmetry of their distribution in the polar coordinate system.

The monitor screen should always face the subject so that he can see the resulting image of his own eye and be able to observe the dynamics of color tones when exposed to stimuli on the projection zones of the body, which provides an inverse visual biological connection. In this case, the specialist, showing a pointer to the received image on the screen, informs the examined person about the peculiarities of the psychophysiological processes in his body.

The invention is illustrated by the drawing, which shows a schematic illustration of a device for implementing the method for determining and correcting the functioning systems of the human body. To implement the proposed method, the person being examined is seated in front of the tool table 1 on an adjustable seat (not shown in the drawing), ensuring its comfortable fit. The human head is fixed on the support 2 for the head mounted on the tool table 1 and having the ability to change in height. A movable manipulator device is attached to the head support 2, which makes it possible to bring a light guide 9 to the face and fix it, directing light to the examined area. Behind the instrument table 1, a screen 4 (monitor) is located on line 3 of the visual axis of the human eye. The lens 5 of camera 6 is directed to the examined area of the person, which can be used as a camera that allows you to receive an image at low illumination of an object, for example 0.5 lux, and have a lens with a variable focal length for the possibility of forming an image with a different zoom scale, made with the ability to register color tones and symmetry of the zone structure for a certain period of time to obtain a summing difference in color tone and symmetry of the structure for each discrete micromotion of the illuminated zone, presented in the form of a hologram depicted on the screen. The camera 6 is mounted on an adjustable tripod 7 in front of the person being examined at a distance of at least 10 cm and at an angle relative to the optical axis of the camera 6, which makes it possible for the person being examined to see on the screen 4 an image of the illuminated area of his own eye in the form of a hologram, offset relative to line 3 of the visual axis of the eyes a person directed to the screen 4. The light from the source 8 is directed to the examined area, in this case, the eyes. In order to exclude the annoying noise and thermal effects of the light source 8 a human subject, the structural performance of the light source 8 provides the use of a low voltage (12-24 volts) incandescent lamps with halogen cycle up to 50 watts of power and convection cooling. The body of the light source isolates the lamp from the penetration of its light into the environment and is equipped with a fiberglass fiber 9 with a cross section of 6 to 15 mm, consisting of light-conducting fibers and allowing illuminating the studied area at a distance. The luminous flux emanating from the optical fiber 9 has an illumination E equal to 10 to 300 lux and a temperature T _c from 3200 to 3800 K. Lighting parameters play a key role in obtaining the necessary diagnostic signs and are physiologically harmless to the vision apparatus, since they are close to natural natural sunlight (E = 300 Lux, T _c = 3200 K). The angle of incidence of the light flux on the eye should be arbitrarily changed by a specialist during the examination to identify diagnostic signs. The power to the lamp is supplied through a step-down transformer (not shown in the drawing) from an AC network with a standard voltage and frequency. A light filter (IR filter) can be installed in the housing between the optical fiber 9 and the lamp, which cuts off infrared radiation in the range of 900-1200 nM to exclude its effect on the person under study and obtain the necessary diagnostic signs. To obtain a monochromatic flow between the end of the optical fiber 9 and an IR filter (not shown in the drawing), a device for attaching and changing color filters is placed.

The fiber 9 can be mounted on the support 2 for the head when illuminating the area at a fixed angle or move manually to vary the angle and distance of illumination when highlighting the structure of the illuminated area and other diagnostic signs.

The image obtained by the camera 6 is transmitted to the monitor screen 4 directly or via a computer (not shown in the drawing). An important condition for the implementation of the method is the absence of discomfort for the person under study and the absence of the effect of additional “irritants” on the person under study, for example, a conventional cooling system eliminates the noise coming from the fan during the forced cooling system of the light source. After fixing the head of the person under study in the support 2, the examined area is illuminated, for example, one eye, with a light source 8 having a luminous flux with an illuminance E of 10 to 300 lux and a temperature T _c from 3200 to 3800 K. Camera 6 allows you to images on the screen of color tones and the symmetry of the eye structure for a certain period of time to obtain a summing difference in the color tone and symmetry of the structure with each discrete micromotion of the eye, presented in the form of a hologram on the screen. The temperature interval T _c equal to 3200-3800 K is based on the fact that the higher T _c , the more uniform the spectrum of the light beam and the more necessary the “blue” part of the spectrum is more saturated to obtain a more realistic image of the hologram. The range of illumination E, equal to 10 to 300 lux, also corresponds to the temperature of optimal lighting for studio equipment, and when this range is observed, the optimal signal-to-noise ratio is established.

The color tone and the symmetry of the image structure on screen 4 determine the degree of deviation of the studied systems of functioning of the human body from the norm. Then they act on the sensory systems of the body and achieve the return of the functioning systems of the body having deviations from the norm to their optimal state. At the same time, the correction of the functioning systems of the body is carried out with stimuli that stimulate self-regulation of functions through biological feedback established by a person observing changes in the color tone and symmetry of the image structure of the illuminated zone, in particular his own eye, during the action of stimuli.

A change in the symmetry of the distribution of color tones relative to the optical axis of the eye, namely, an increase in the asymmetry of the optical (holographic) color body relative to the center of the pupil (optical axis) of the eye, can serve as indicators of a persistent violation of one or another function, which also determines the formation of a stable metabolic process.

The increase in radial and axial asymmetries relative to the center, as well as the radial “axes” of the coordinate pattern of the topical projections of the functional informational connections of the human body in the front sections of the right and left eyes, can serve as an indicator of the specific changes in physiological functions, including clinical forms of disorders (Information biomedical information Technologies, M .: GEOTAR - MED, 2002, p. 212-240).

The method of studying the functional states of the human body using the topographic phenomenon of the anterior parts of the eyes is able to record the initial stages of the violation of the multiparameter informational interaction of the functional systems of the human body and, therefore, significantly outstrip the data of clinical examinations.

The method allows you to register informational dysfunctions in the human body in the absence of any pronounced clinical symptoms of diseases and disability.

Thus, the study of the functional states of the human body using the holographic phenomenon of the anterior parts of the eyes is a reliable and reliable way of information control over the effectiveness and direction of rehabilitation and treatment. The registration of the dynamics of the processes of self-regulation of human physiological functions on the basis of numerical indicators of the saturation of color tones relative to the coordinate pattern of the topical projections of the functional information connections of the human body in the front parts of the eyes and the symmetry of their distribution allows us to identify individual characteristics of the integration of functional systems, and also allows the integral assessment of the state of the information environment person.

The invention can be used:

- in the field of labor protection and social development, in the field of social insurance, for certification of workplaces, for certification of labor protection works, for balancing the personnel of organizations and enterprises, for professional selection, for monitoring professional risks for each employee and the collective as a whole, to identify the subjects of emergency and traumatic situations, to determine the working capacity of workers, to identify a tendency to bad habits, to restore working capacity, professionally rehabilitation, as well as in its periodic medical examinations, in addition, to identify potential and actual leaders in the team and selection of personnel for vacant positions as well as for learning effective and safe techniques and methods of work;

- in medicine and veterinary medicine to identify the relationship of prevailing diseases and the main causes of the formation of diseases, as well as to select and conduct rehabilitation, correctional and therapeutic measures and registration of dynamic changes in the functional states of the human and animal body;

- in pedagogy to diagnose the psychophysiological characteristics of a child during training and education, to study the impact on the body of educational and physical exertion and the possibility of mastering training programs, for early vocational guidance, to select appropriate training for his capabilities, as well as to select sports that correspond to psychophysiological capabilities ;

- in the field of personnel management for personnel certification;

- in the social sphere for professional and social rehabilitation;

- in gerontology for the diagnosis of psychophysiological abilities to adapt and the functional reserves of the body of elderly and elderly people to form the most optimal forms of life support;

- in psychology to record the effects of stress factors;

- in ecology for recording the effects of harmful and dangerous environmental factors;

- in insurance to determine the probability of an insured event;

- in the field of security for the certification of the population.

Claims (3)

1. A method for studying the state of functioning systems of the human body, which consists in the fact that the study of the functioning systems of the human body is carried out by analyzing a macroscopic image of the front of the eye by dynamic changes in the saturation of color tones and the symmetry of the structure of their distribution on the visible front parts of the eye, while the front parts the eye is illuminated with a light flux with illumination equal to from 10 to 300 lux, a temperature of 3200 to 3800 K, an image is taken from the illuminated zone, removed from display on the screen, registration of color tones and symmetry of the structure of their distribution on the visible front parts of the eyes is carried out for the period of time necessary to obtain a summing difference in color tone and symmetry of the structure with each discrete binocular micromotion of the eyes presented on the screen. 2. A method of correcting the functioning systems of the human body, namely, that the study of the functioning systems of the human body is carried out by analyzing a macroscopic image of the front of the eye by dynamic changes in the saturation of color tones and the symmetry of the structure of their distribution on the visible front of the eye, while the front of the eye illuminated with a light flux with illumination equal to from 10 to 300 lux, temperature from 3200 to 3800 K, an image is taken from the illuminated zone, the image is displayed on the tap, registration of color tones and symmetry of the structure of their distribution on the visible front parts of the eyes is carried out for the period of time necessary to obtain a summing difference in color tone and symmetry of the structure with each discrete binocular micromotion of the eyes displayed on the screen, and, acting on stimuli, they achieve the return of the systems the functioning of the body to a normal state when using biological feedback by observing changes in color tones and symmetry of the string Image tours during the action of stimuli. 3. A device for studying the state of the functioning systems of the human body, containing a support for the head, a camera, the lens of which is aimed at the person being examined, a screen connected to the image transfer channel of the camera, and a light source to illuminate the area of the person being examined, characterized in that the screen is placed on a line line of sight of the examined person, whose head is fixed on a support, and the light source is made with the possibility of creating a luminous flux with illumination from 10 to 300 lux and a temperature of 3200 to 380 0 K, a flexible optical fiber light guide was introduced into the device to transmit the light flux from the light source to the illuminated area, while the camera is configured to register color tones and symmetry of the structure in the volume of the front camera of the eye.