RU2753234C1 - Method for psychophysiological correction of the psychological state using virtual reality of a personalised geometric shape - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely to neurology, psychiatry, neurophysiology, neuropsychology. An impact is realised using a visualisation tool. Internal images of closed spaces with different ratios of the areas of the internal surfaces thereof to the areas of minimal imaginary spheres inscribed in said spaces are therein displayed in the form of sequentially alternating frames, on the condition that an image of one space has a predetermined ratio, less for a person than the ratio of the area of the free surface of the hemispheres of the large brain, considering the convolutions and sulci, to the area of the minimal imaginary sphere described around the hemispheres. A session therein is conducted in two phases. In the first phase, the dimensions of geometric shapes defining the shapes of the closed space are changed in the direction of increase in the ratio of the areas of the internal surfaces thereof to the areas of minimal imaginary spheres inscribed in said figures. The dimensions are then changed in the opposite direction in the second phase. The time of the second phase of exposure constitutes 18 to 30% of the first phase with a total duration of one session of 5 to 25 minutes.

EFFECT: provides a possibility of increasing the effectiveness of psychophysiological correction of the psychological state of a person.

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Description

Technology area

The present invention relates to medicine and can be used in neurology, psychiatry, neurophysiology, neuropsychology and a number of other modern neurosciences that study the human brain and its behavior, as well as in the field of information and communication technologies when creating artificial intelligence, robotics and architecture.

State of the art

In the last decade, the use of artificial reality technologies has become a fairly dense part of modern clinical practice. Virtual reality (hereinafter VR) is applicable for simulation training in medicine [2, 7], neurorehabilitation and neurosurgery [1, 15], as well as for the therapy of mental pathology [4].

A number of authors note a significant adherence to VR among the younger generation, which clearly opens up a high level of prospects for using it for the treatment of mental pathology, due to the risk of a recurrence of the COVID-19 pandemic and similar conditions, when access to psychotherapeutic and psychiatric care for patients is limited by consideration of epidemiological safety [3, 8].

Virtual reality (hereinafter VR) is an artificially created computer simulation of a three-dimensional environment, with which one can interact in a subjectively felt way using VR glasses, VR lenses, VR helmet and other gadget platforms [12]. Contact with virtual reality is accompanied by the illusion of complete presence in the synthesized space [14].

Virtual reality creates well-controlled sensory stimuli and can be used as a new method of therapy with the selection of a program for a specific mental symptom [11].

The peculiarity of using VR for psychophysiological correctional work is that in a controlled and safe environment, VR experimenters / therapists can manipulate the VR environment as needed to test various hypotheses about human behavior, as well as to select an individual psychotherapeutic scenario for the treatment of clinically significant psychiatric patients. symptoms. Simultaneously, users and patients can repeatedly experience the situation and control the artificially created environment themselves [10].

At the moment, there is a sufficient number of VR-associated computer programs for the treatment of post-traumatic stress disorders, phobias, autism spectrum disorders, even the experience of using VR for the treatment of psychotic symptoms is described [5].

The main disadvantage of these therapy computer programs is that they do not have a personalized approach. For example, in the therapy of aerophobia, the synthesized reality is not personalized. Moreover, it does not in any way correlate with the anatomical and neurophysiological features of the functioning of the brain of a particular patient. This is just a picture of the phobic situation, displayed in the same way for a large pool of patients.

Modern researchers note that for the effectiveness of psychophysiological correction and psychotherapy, it is necessary to personalize virtual reality as much as possible [9, 13].

So far, VR personalization has been used through the following directions:

1.Simple manipulation of the VR content, in which the patient or therapist can subjectively select or adjust the properties of some objects for themselves or the goals of therapy. Changes, for example: color, light, volume, texture, presence or absence of an object, thus only an external formal personalized correspondence of VR to current tasks is achieved.

2. The use of neurophysiological monitoring and biofeedback with VR content represents the most complex and modern stage of personalization. It allows you to dynamically monitor the neurophysiological, cardiological and other state of the patient, it is carried out using artificial intelligence systems.

The disadvantage of this method is that it is difficult to predict the consequences of such an impact, and therapeutic sessions are lengthened and complicated due to complex multicomponent monitoring [6].

Known methods (RF patents No. 2668697, 2686170, 2691301, 2692949, allowing, on the basis of a single system-forming factor, which is a minimum energy consumption in interaction with the environment, both inside the central nervous system and the human environment, in principle, to assess the morpho-functional features of the head the brain during its functioning and interaction with the surrounding space.

In this case, the brain and the human environment are presented in the form of simply connected regions, homeomorphic to the sphere, which is the structural attractor of the system under consideration.

At the same time, a connection was established between the parameters of closed spaces (for example, a sphere, a cube, a parallelepiped, a cylinder, a pyramid) and the morpho-functional characteristics of the cerebral hemispheres.

Here, the objectively existing morphophysiological features of the patient's cerebral hemispheres are taken into account, which determine the spatial perception of the surrounding space by a person and have a significant impact on his psychophysiological state, as well as the features of the surrounding spaces. In addition, these methods make it possible to plan and create architectural objects, taking into account the individual needs of the human brain, ensuring maximum adaptation and optimal functioning.

Therefore, these methods can be used to create a personalized VR, which is based on the principle of a single structural attractor for the human brain and the geometric shape of the enclosed space surrounding it.

The present invention is aimed at increasing the efficiency of psychophysiological correction of the human body by creating and using virtual reality of a personalized geometric shape.

The invention can be used:

- with personalized psychophysiological correction, for therapy and prevention of mental disorders;

- in order to study the structure and functioning of the cerebral hemispheres during their accommodation in a closed (including virtual) space;

- in the creation and research of artificial intelligence and personalized robotics;

- when creating closed spaces with a personalized geometric shape, in architecture.

The technical result is to increase the effectiveness of psychophysiological correction due to the combined individual psychological and neurophysiological effects of virtual reality of a personalized geometric shape on the central nervous system of a person.

The essence of the invention

The specified technical result is achieved through a set of features given in the corresponding claims.

A method of psychophysiological correction of a psychological state using virtual reality of a personalized geometric shape includes exposure using a visualization tool.

At the same time, at least internal images of closed spaces are shown in the form of sequentially alternating frames, having different ratios of the areas of their internal surfaces to the areas of minimal imaginary spheres inscribed in these spaces.

These actions are carried out under the condition that at least the image of one space has the specified ratio less for a person than the ratio of the free surface area of the cerebral hemispheres, taking into account the convolutions and grooves, to the area of the minimum imaginary sphere described around them.

Moreover, the session is carried out in two phases, while in the first phase the dimensions of the geometric figures that determine the forms of the closed space are changed in the direction of increasing the ratio of the areas of their internal surfaces to the areas of the minimal imaginary spheres inscribed in these figures, and then in the second phase they change the dimensions in the opposite direction , while the time of the second phase of exposure is 18 ... 30% t of the first phase with the total duration of one session 5 ... .25 min.

In accordance with another preferred embodiment of the method, at least one of the studies mentioned below is additionally carried out: questioning the psychological state of a person before and after the session, measuring the pulse, blood pressure, functional near-infrared spectroscopy, electroencephalography, and studying the level of oxygen saturation in the blood.

In accordance with another preferred embodiment of the method, in addition, before the session, macroencephalometry of the cerebral hemispheres is performed to determine the ratio of the free surface area of the hemispheres, taking into account the convolutions and grooves, to the area of the minimum imaginary sphere described around them.

In accordance with another preferred embodiment of the method, an internal image of the space of at least one of the following volumetric images is additionally shown: a sphere, a cube, a parallelepiped, a cylinder, a cone or a pyramid.

In accordance with another preferred embodiment of the method, VR glasses are used as rendering means.

Brief Description of Drawings

For a better understanding, but only by way of example, the present invention will be described with reference to the attached drawing, figure 1 of which shows a graph of a session of demonstration of internal images of closed spaces in the form of simple personalized geometric figures.

A detailed description of the implementation of the method and its use.

The use of the present method is based on the neurophysiological, biochemical, biomechanical and electrical processes objectively occurring in the human brain.

A method of psychophysiological correction of a psychological state using virtual reality of a personalized geometric shape includes the stages of its impact with a visualization tool on the organs of vision and the human brain.

As visualization means, for example, VR glasses or VR lenses, or VR helmet or 3D display can be used. It should be understood that when demonstrating virtual reality to a person, for example, in the form of a room in the form of a closed space, he sees at least part of this space at a time and can virtually move inside it, approaching or moving away from one or another part of it.

At the same time, an idea of the space in which he is placed is formed in the human brain, accompanied by the excitation of certain areas of the cortex of the hemispheres of his brain and the appearance of a stress-strain state in him.

Since the displayed spaces have different geometric shapes of internal volumes, they will have different effects on individual areas of the patient's cerebral hemispheres, in which certain zones of excitation were formed at the time of the session. This effect will have a dominant effect on the normal state of consciousness, determined by the activity of both cerebral hemispheres, which normally have functional asymmetry.

The stress-strain state of the cerebral hemispheres, both as a whole and its individual parts, on the one hand, depends on the biochemical, electrical, biomechanical processes occurring in the brain, and on the other hand itself influences the course of these processes, blocking them or activating individual functional zones, and thus has a coordinating effect on the course of neurophysiological processes in the brain. This, in turn, affects the psychophysiological state of a person.

At the same time, the above processes, accompanied by a stress-strain state of the cerebral hemispheres, both as a whole and its parts, largely depend on their shape, size, tissue density gradient, topographic location of functional and excitation zones.

However, an integral indicator characterizing the structural attractor of the hemispheres, which predetermines their stress-strain state, is the hemisphere shape coefficient, defined as the ratio of the free surface area of the cerebral hemispheres, taking into account the convolutions and grooves, to the area of the minimal imaginary sphere described around them.

For an average individual, the coefficient of the hemispheres shape, expressed in dimensionless quantities of the same name with the space surrounding a person, is 2.3. In this case, the specified coefficient is individual and can vary at least in the range of 1.8-3.1.

At the same time, volumetric geometric figures, when viewed in the form of simply connected spaces, homeomorphic to a sphere, also have certain coefficients of their shape, which determine their structural attractor, which also predetermines the nature of their effect on neurophysiological processes in the brain when information about these spaces is introduced through the organs of vision into brain.

For example, for the simplest volumetric geometric shapes, such as a sphere and a cube, it is constant and, respectively, equal to 1 and 1.9, and for a parallelepiped, cone and pyramid it depends on the ratio of their sizes and can reach values significantly exceeding, for example, the average coefficient of the hemispheres, equal to 2.3.

Moreover, according to the proposed invention, in order to increase the effectiveness of psychophysiological correction of a person, he is shown in the form of sequentially alternating frames, at least internal images of closed spaces having different ratios of the areas of their internal surfaces to the areas of minimal imaginary spheres inscribed in these spaces.

It should be understood that, for example, a room can be used as a volumetric space, which is predominantly in the form of a parallelepiped, a sphere or a cylinder, which are its frame-forming elements, objects can be located in the room and a VR psychotherapeutic story can be demonstrated.

For example, the use of closed spaces, which are based on the simplest geometric shapes, for which their shape factor is known, makes it possible to control the process of influencing the human brain and thereby achieve a predictable effect on its psychophysiological state.

However, in this case, in order to achieve a significant result, it is necessary to observe the condition that at least the image of at least one demonstrated volumetric closed space must have the ratio of the area of its internal surfaces to the area of the minimum imaginary sphere inscribed in it, less than for a person, the ratio of the area the free surface of the cerebral hemispheres, taking into account the convolutions and grooves to the area of the minimum imaginary sphere described around them.

From this it follows that in order to guarantee the relaxation of stable excitation zones in the cerebral cortex, it is necessary to enter into it information about the space, which has a shape coefficient smaller than the cerebral hemispheres.

This will allow to achieve relaxation of the zones of excessive excitement or, at least, to reduce tension in them, which is essential for further controlled effective impact on the psychophysiological state of the patient.

Such a shape is guaranteed, for example, a sphere, which has a shape factor equal to one, and which is always less than the shape factor of the cerebral hemispheres of a person, equal, for example, for an average individual to 2.3. It should be noted that other simple geometric volumetric shapes, for example, a cube and a cylinder, can have a shape factor that is less than that of the hemispheres.

Since the specified coefficient is individual and can vary at least in the range of 1.8-3.1, according to one of the preferred embodiments of the method, it is selected from the specified limits. The limits are determined by the possible morphological characteristics of the human cerebral hemispheres.

To increase the efficiency of the present method in accordance with its other preferred embodiment, in addition to the session, macroencephalometry of the cerebral hemispheres of the patient is carried out to determine the ratio of the free surface area of the hemispheres, taking into account the convolutions and grooves, to the area of the minimum imaginary sphere described around them. This will further detail the program for demonstrating volumetric spaces, based on the individual characteristics of the patient's cerebral hemispheres, and thereby increase the technical result.

When a personalized geometric shape is shown in a chain of sequential VR frames, which have coefficients of the latter, greater than those of the cerebral hemispheres, neurons are activated in other functional areas of the brain and, thereby, its efficiency increases, due to the individual characteristics of the human brain, which are up to this is largely unused.

Thus, when implementing the present method, the set task of normalizing neurophysiological processes in the brain is solved due to sequential controlled relaxation and tension in its individual functional zones, taking into account their topography.

To obtain a higher technical result, the method provides for its most preferred executions.

So, in accordance with one of the preferred embodiments, at least one of the studies mentioned below is additionally carried out: questioning the psychological state of a person before and after the session, measuring the pulse, blood pressure, functional near-infrared spectroscopy, electroencephalography, studying the level of oxygen saturation in the blood ...

Additional questioning of the psychological state is carried out in accordance with one of the known methods used. The purpose of this survey is to find out the actual psychological and mental state of the patient. This allows you to use an individual approach to form a personalized program of targeted impact on his brain.

Additional measurement of pulse, blood pressure, functional near-infrared spectroscopy, electroencephalography, study of the level of oxygen saturation in the blood, measurement of pulse and oxygen saturation in the blood, after the session allows you to assess the patient's condition and most accurately plan the next session, which will shorten the rehabilitation time and will increase the efficiency of the method.

In accordance with another preferred embodiment of the method, the internal volumetric images of the space of at least one of the following volumetric images are shown: a sphere, a cube, a parallelepiped, a cylinder, a cone or a pyramid.

It is known that three-dimensional images of these figures have significantly different coefficients of their shape, therefore each image will have a correspondingly relaxing or activating effect on the hemispheres of the human brain.

In this case, the formation of the sequence and duration of the demonstration of these internal volumetric images depends on the primary state of the patient and the goal of psychophysiological correction.

In the process of displaying images, the change in the geometric shape of the virtual space can be carried out abruptly or smoothly, fixing the boundaries of the transition between spaces. With a smooth change in the shape of the displayed spaces, a more gentle effect on the brain of the individual is provided.

In this case, according to the invention, the session is carried out in two phases, where in the first phase the dimensions of the geometric figures that determine the forms of the closed space are changed in the direction of increasing the ratio of the areas of their internal surfaces to the areas of the minimal imaginary spheres inscribed in these figures, and then in the second phase these dimensions are changed in the opposite direction, while the time of the second phase of exposure is 18 ... 30% of the duration of the first phase with a total session duration of 5-25 minutes.

The recommended number of sessions can be up to 10 or more, depending on the patient's condition and obtaining a stable result. This method can be applied situationally, for example, to normalize a psychological state or prophylactically.

The minimum period of time for the session under consideration is due to the need to create a stable effect, taking into account the neurophysiological processes occurring in the human brain.

The maximum limit of the time interval for a session is due, on the one hand, to the sufficiency of its effect on the human brain to create a stable effect, and on the other hand, by a decrease in this effect with an increase in the duration of the session due to overexcitation of individual sections of the cerebral cortex.

In this case, the demonstration of virtual spaces is carried out against the background of sound and / or color accompaniment. This allows for deeper relaxation and focusing effects.

You can also demonstrate internal volumetric images in the form of closed spaces with stationary or moving objects placed in them, as well as certain subjects that help eliminate phobias.

Examples of implementation of the method

As an example, let us consider one preferred embodiment of the method in the form of demonstrating a series of internal spaces of volumetric images of the simplest geometric shapes. This example of the implementation of the method will be simple and straightforward. Moreover, it will testify to the possibility of creating virtual spaces of personalized geometric shapes, in this case having a general harmonizing effect on the psychophysiological state of the patient.

However, it should be understood that when implementing the present method, it is possible to use internal volumetric images of closed spaces of various shapes, including complex shapes.

Before the start of the session of demonstration of the above-mentioned internal volumetric images, the psychological state of the patient is questioned, for example, according to any known technique that meets the clinical problem to be solved. Next, the patient's pulse, blood pressure and oxygen saturation in the blood are measured.

Further, in accordance with the diagram shown in Fig. 1, using VR glasses, for example, mod. Samsung HMD Odyssey - Windows Mixed Reality Headset shows the patient a series of internal volumetric images of the following spaces in the form of a sphere, cube, pyramid and cylinder.

An entire session can contain one or more series. The series can be of the same type or differ from one another in the number of displayed virtual spaces, their form, sequence and duration of demonstration. The choice of the session program depends on the patient's condition and the tasks to be solved, for example, on his rehabilitation.

At the same time, the values of the shape coefficients of the displayed volumetric images and the patient's cerebral hemispheres are indicated on the vertical axis of the diagram. The duration of the demonstration of each volumetric image in the series, the entire series and the entire session is indicated on the horizontal axis of the diagram. Curve I represents the abrupt change in the shape coefficients of the displayed spaces. Line III corresponds to the value of the coefficient of the shape of the cerebral hemispheres for the average patient. This coefficient is constant and in this case it is equal to 2.3.

To understand an example of the implementation of the method, consider one series of demonstrations of the above volumetric images. First, the inner space of the sphere is shown for 2.0 min. In this case, the dimensions of the sphere can be variable. Since the coefficient of the shape of the sphere is much less than the coefficient of the shape of the hemispheres (it remains unchanged when the size of the sphere changes), this contributes to the relaxation of both individual functional zones of the cortex of the hemispheres and the hemispheres as a whole, accompanied by a decrease in the magnitude of mechanical stresses in them, and primarily tangential ( tangent) form-changing mechanical stresses.

This has a significant effect on the biochemical, electrical, biomechanical processes occurring both in individual functional zones and in the cerebral hemispheres as a whole. At the same time, the spatial multi-connectivity of the hemispheres changes in the direction of their simple connectivity.

Further, in this example, the displayed space is abruptly changed and within 2 minutes they demonstrate the inner space of the cube, which also has a shape factor, as a rule, is less than the coefficient of the hemispheres and in which this factor does not depend on the size of the cube.In the course of the session, the dimensions of the cube as well as the sphere can be changed. Although the cube has a shape factor, as a rule, it is less than the shape factor of the normal hemispheres, nevertheless, it approaches this factor, which contributes to the onset of the formation of mechanical stresses, both in individual functional zones of the hemispheres, and in them as a whole.

Then, for 2 minutes, the inner space of the pyramid is shown having a shape factor of 3.4, which is greater than the shape factor of the hemispheres, which causes an additional increase in the above mechanical stresses.

The specified set of displayed volumetric images forms the bottom part of the first series of the diagram. In this case, the coefficient of the shape of the pyramid, which characterizes its structural attractor, is significantly greater than the structural attractor of the cerebral hemispheres. This causes additional stress in the functional areas of the cerebral cortex.

Thus, during the session there is a controlled, which is very important, transition from relaxation of mechanical stresses in the cerebral hemispheres and their functional zones to an increase in these stresses.

Then, for 1 min, a volumetric image of the inner space of the cylinder is shown, the height of which is equal to its diameter and in which the aspect ratio is 1.5. The interior of the sphere is then demonstrated again for 2 minutes.

The transition from the demonstration of the inner space of the pyramid to the demonstration of the inner space of the cylinder and from the cylinder to the sphere is a descending branch of the curve of the first series of the session. Moreover, its duration is significantly less than the duration of the ascending branch of the diagram and is about 30% of it.

Thus, the demonstrated series of internal spaces tends to the shape of the incident wave. This allows you to achieve the greatest relaxation effect following an increase in mechanical stress in the cerebral hemispheres, and as a result, allows you to remove mechanical stress in individual functional areas of the hemispheres and prepare them for the perception of the next series of spaces.

Further, depending on the patient's condition, the series can be repeated in an unchanged form, or can be individually changed.

In accordance with the present method, the demonstration of internal volumetric images of closed spaces can be carried out with a continuous change in the dimensions of the displayed volumes, for example, a pyramid and a cylinder (curve II). This will allow you to more smoothly affect the functional areas of the cerebral hemispheres.

Further, after the session, in accordance with one of the preferred embodiments of the method, the psychological state of the patient is questioned. They measure his pulse, blood pressure and oxygen saturation in the blood and make a conclusion about the effectiveness of the first session and then plan a program for the further recovery of the patient.

Although the present invention has been described with a certain degree of detail, various changes and modifications may be made without departing from the spirit and scope of the invention set forth in the following claims.

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Claims (5)

1. A method of psychophysiological correction of a psychological state using virtual reality of a personalized geometric shape, including exposure using a visualization tool, while demonstrating in the form of successively alternating frames, at least internal images of closed spaces having different ratios of the areas of their internal surfaces to the areas of minimum imaginary spheres inscribed in these spaces, provided that at least the image of one space has the specified ratio less for a person than the ratio of the free surface area of the cerebral hemispheres, taking into account the convolutions and grooves, to the area of the minimum imaginary sphere described around them, moreover, the session is carried out in two phases, while in the first phase the dimensions of the geometric figures that determine the forms of the closed space are changed in the direction of increasing the ratio of the areas of their internal surfaces to the areas of the minimum imaginary spheres inscribed in these figures, and then, in the second phase, the dimensions are changed in the opposite direction, while the time of the second phase of exposure is 18-30% of the first phase with a total duration of one session of 5-25 minutes. 2. The method according to claim 1, characterized in that at least one of the studies mentioned below is additionally carried out: questioning the psychological state of a person before and after the session, measuring the pulse, blood pressure, functional near-infrared spectroscopy, electroencephalography, level study oxygen saturation in the blood. 3. The method according to claim 1, characterized in that, additionally, before the session, macroencephalometry of the cerebral hemispheres is carried out to determine the ratio of the free surface area of the hemispheres, taking into account the convolutions and grooves, to the area of the minimum imaginary sphere described around them. 4. The method according to claim 1, characterized in that it additionally shows the internal images of the space of at least one of the following volumetric images: a sphere, a cube, a parallelepiped, a cylinder, a cone or a pyramid. 5. The method according to claim 1, characterized in that VR glasses are used as the visualization means.

Images