RU2410025C2 - Method for normalising psychophysiological state - Google Patents

Abstract

FIELD: medicine. ^ SUBSTANCE: duration, amplitude and form of each continuous brain signal wave are matched with parameters of each sensory signal. Recording each continuous brain signal wave, forming a matched sensory signal and exposing a patient to this signal are consistent and immediate. During the procedure, the patient is suggested to pay attention that the sensory signals perceived reflect brain work. ^ EFFECT: method enables more efficient process normalising psychophysiological state following stress load, psychoemotional and mental strain, and while treating functional disorders of central nervous system, psychosomatic diseases and consequences of organic cerebral affections. ^ 4 cl

Description

The invention relates to medicine, namely to non-pharmacological methods of normalizing the patient’s psychophysiological state, and can be used to normalize the psychophysiological state after stressful loads, psychoemotional and intellectual stress, as well as for treating functional disorders of the central nervous system, psychosomatic diseases and the effects of organic brain damage.

It is known that currently there is an increasing interest in non-drug methods of rehabilitation of patients with various types of pathologies. One of the rapidly developing areas of non-pharmacological correction of the psychophysiological state of the body are neurotherapy methods. Neurotherapy methods use various methods of influencing the body with acoustic, visual, tactile, including temperature signals. Under the conditions of neurotherapy methods, the patient is exposed to sensory signals of different types in the modes of both direct stimulation and biological feedback (BOS).

A known method for the treatment of neurosis by the method of electroencephalographic (EEG) biofeedback (Bekshaev S.S., Levina M.Yu., Yakovlev N.M., Vashchilo E.G. "Dynamics of the structure of the electroencephalogram in patients with neurosis in the course of treatment by the method of biological feedback". Biofeedback-3. Novosibirsk, Nauka, 1998, p.202-211). In this method, acoustic feedback is organized according to the EEG alpha rhythm. A well-known melody is used as a feedback feedback signal, which is turned on if the amplitude of the current oscillation of the EEG alpha rhythm exceeds a predetermined threshold, and is turned off if it does not reach it. The patient is placed in a comfortable chair with his eyes closed at rest. The patient is offered to relax and find a state in which the melody sounds continuously. EEG is recorded bipolar in the lead-forehead.

As a result of such treatment procedures, a positive dynamics of the patient's condition is observed.

However, this method has significant drawbacks that significantly weaken the effectiveness of medical procedures. Firstly, this method does not establish the correspondence of the parameters of the EEG oscillations with the parameters of the sensor signal. A melody appears only if the amplitude of the EEG oscillations belonging to the alpha rhythm exceeds a predetermined threshold. Thus, only moments of the appearance of a limited number of EEG oscillations are reflected in the sensor signal. Secondly, in the sensor signal the temporal parameters of the EEG do not accurately reflect, which does not allow us to talk about matching the time of registration of the patient’s EEG fluctuations with the time of the beginning of exposure to it with the corresponding sensor signals. The distortion of the temporal parameters of the EEG is due to the fact that the duration of the melody should exceed 100 ms, since with a shorter playing time the melody will not be perceived by the patient. But if the melody’s playing time exceeds 100 ms (the average duration of the alpha rhythm fluctuation), then the moment of appearance of the next oscillation will not be reflected in the sensor signal. Thus, in this method, the main EEG parameters are practically not reflected in the sensor signal. Thirdly, the requirement for the patient to search and maintain such a functional state, which would correspond to the intensity of EEG fluctuations not lower than a predetermined threshold, limits the scope of application of the known method to the contingent of patients with preserved mnestic and volitional spheres of the psyche.

Also known is a method of neurotherapy of functional disorders using double feedback from the patient’s EEG (Fedotchev A.I., Bondar A.T., Semenov BC “Neurotherapy of functional disorders using double feedback from the EEG of patient’s oscillators.” All-Russian Scientific and Practical Conference “ Quantitative EEG and neurotherapy ", St. Petersburg, 2007, p.148). In this method, the parameters of sound and light signals are consistent with the activity of theta and alpha rhythms of the EEG. At the same time, the dominant narrow-frequency EEG ranges in theta and alpha rhythms are detected in real time, acoustic feedback signals with an intensity corresponding to the suppression of the EEG theta rhythm are supplied, and light rhythmic signals tuned to the frequency of the dominant EEG alpha rhythm are supplied. The patient is required to find a condition in which the intensity of the sound signals would be minimal.

In this method, the correspondence of the EEG amplitude of theta and alpha rhythms with the intensity of sensory signals of acoustic and visual modalities is established. Thus, in comparison with the previous method, the information content of the feedback channel is increased. Most patients after these procedures note a decrease in the level of tension and stress.

The disadvantage of this method is, firstly, a significant limitation on the number of displayed EEG parameters in the sensor signal. The intensity of sensory signals is brought into correspondence only with the amplitude of the EEG of theta and alpha rhythms, while such parameters of EEG vibrations as duration and shape are not taken into account. Secondly, they do not provide a coordination of the time of registration of the patient's EEG fluctuations with the time of the beginning of exposure to it with the corresponding sensory signals. Thus, in this method, the information content of the feedback channel is limited, which affects the decrease in its effectiveness. Thirdly, the patient is given a cognitive task that requires considerable volitional effort from him, which limits the application of this method to the contingent of patients with intact mnestic and volitional spheres of the psyche.

A common drawback of these methods is, firstly, the lack of reflection in the parameters of sensory signals of the whole complex of EEG parameters. In the best case, the correspondence of sensor signals is established with the amplitude indicators of the selected EEG frequency ranges, while the duration and shape of the EEG oscillations are not taken into account in the parameters of sensor signals. Secondly, in the proposed methods there is no coordination of the time of registration of the EEG fluctuations of the patient with the time of the beginning of exposure to him with the corresponding sensor signals. Therefore, the above methods either ignore or significantly distort the temporal parameters of the brain, focusing only on the amplitude-frequency indicators. However, it is known that time is one of the main coordinates of the brain’s work, which is reflected in the time-specific distribution of events of the central nervous system specific for each psychophysiological state (MN Livanov, “Spatio-temporal organization of potentials and systemic brain activity.” M. , Science, 1989). Thirdly, the drawback of the above methods is the limitation of the treatment process to the limits of voluntary self-regulation, which in practice requires significant volitional efforts from patients to search for such psychophysiological conditions, the electroencephalographic expression of which would correspond to the preset by the operator-operator: the melody should last longer, the sound should be louder etc. At the same time, it is known that the control of EEG parameters is the easier, the closer to normal the bioelectrical activity of the brain (Soroko S.I., Suvorov NB, Kutuev VB, Bekshaev SS “Individual features of arbitrary regulation of the bioelectric activity of the brain. ”Human Physiology, 1975, No. 5, pp. 746-751). Therefore, methods of neurotherapy based on voluntary self-regulation are not effective in the treatment of patients with impaired bioelectric activity of the brain. In addition, the condition of voluntary self-regulation does not allow reflecting the whole complex of EEG parameters in the sensor signal, since multi-purpose and multi-parameter feedback requires such efforts from the patient to concentrate that they cannot be realized in conditions of an upset psychophysiological state. Thus, neurotherapy methods that use the principle of cognitive and voluntary control of EEG parameters are forced to limit the number of displayed indicators of brain bioelectric activity, thereby weakening the information capacity of the feedback channel, and hence the effectiveness of the method.

These disadvantages reduce the effectiveness of known methods of neurotherapy.

The closest to the invention according to the technical nature and the achieved result is a method of bioacoustic correction of the psychophysiological state of the body (Konstantinov KV, Miroshnikov DB, Sizov VV Patent for invention No. 2192777 “Method of bioacoustic correction of the psychophysiological state of the body”), including registration of EEG from two or more points of removal of the EEG, the establishment of an unambiguous correspondence between the spatial location of the points of registration of the EEG and sound sources, transposition to zhdogo EEG oscillations separately and sequentially into the audio frequency range, simultaneous effect obtained sound signals to the patient.

This method, chosen as the prototype of the present invention, allows, in comparison with other known methods, to increase the accuracy of transmitting information about the current state of the central nervous system in the feedback loop by transposing the sequence of the initial EEG vibrations into the region of audible frequencies and reflecting the spatial parameters of the EEG in the sound image. In this method, no threshold values are set for the EEG parameters and the emphasis is not on the search and retention of a condition by the patient, which allows the principle of involuntary self-regulation to be implemented, which allows expanding the circle of patients with various disorders of the central nervous system.

The disadvantage of the prototype is, firstly, that there is no coordination of the time of registration of the EEG fluctuations of the patient with the time of the beginning of exposure to it with the corresponding sensory signals. Secondly, the fact that transposing an EEG signal into an audible range of sound frequencies is not an optimal way of matching the EEG parameters and the sensor signal. When the EEG signal is transposed into the region of audible frequencies, the harmonics of the original signal are moved on the frequency scale only with the initial ratios of the amplitudes, frequencies and phases of the EEG signal in the acoustic sensor signal. This, undoubtedly, is an important condition for the organization of biofeedback, since it allows you to transfer the initial information in the feedback channel with acceptable distortions as a first approximation. However, the no less important condition for transmitting information in the biofeedback channel is the patient’s perception of sensory signals. In this regard, the linear reflection of the relations of amplitudes, frequencies and phases of the original signal, which is used when transposing the signals, does not provide high efficiency of this method. Thirdly, the fact that this method creates sensory signals only of acoustic modality, which limits the scope of the method to the contingent of patients with intact hearing. Fourth, the fact that the method of transposing frequencies is unacceptable when creating sensory signals of visual and tactile modalities. Fifth, the fact that this method does not offer the patient to pay attention to the fact that the sensory signals perceived by him reflect the work of his brain, which negatively affects the efficiency of the process of normalizing the patient's psychophysiological state.

These disadvantages of the selected prototype method limit its effectiveness.

The aim of the creation of the invention is to increase the efficiency of the processes of normalizing the patient's psychophysiological state after stressful loads, psychoemotional and intellectual stress, as well as in the treatment of functional disorders of the central nervous system, psychosomatic diseases and the effects of organic brain damage.

This goal is achieved by the fact that in the proposed method of normalizing the psychophysiological state, each oscillation of the patient’s brain signal is separately and sequentially recorded, a corresponding sensor signal is generated in accordance with the duration, amplitude and shape of each oscillation of the brain signal, and the patient is affected by this sensor signal. In this case, the registration of each oscillation of the brain signal, the formation of the corresponding sensor signal and the impact on the patient with this signal is carried out sequentially, without time intervals between these actions. During the procedure, the patient is asked to pay attention to the fact that the sensory signals perceived by him reflect the work of his brain.

Thus, brain signals are represented as a temporary sequence of oscillations. The main vibration parameters (duration, amplitude and shape) are consistent with the parameters of sensory signals, with each unique oscillation of the brain signal corresponding to a unique sensory signal. As a result, in this method, the main parameters of the brain signal oscillations are reflected with high accuracy in the sensor signal. The method allows to increase the efficiency of the processes of normalizing the psychophysiological state after stressful loads, psychoemotional and intellectual stress, as well as in the treatment of functional disorders of the central nervous system, psychosomatic diseases and the effects of organic brain damage.

A comparative analysis of the prototype and the proposed method shows that the differences of the latter lie in the method of obtaining sensory signals and in the method of exposure to sensory signals on the patient, and, therefore, the proposed method meets the criterion of "novelty."

Comparison of the proposed method with other technical solutions known in the art allows us to conclude that it does not follow from them in an obvious way and, therefore, meets the criterion of "inventive step".

The compliance of the proposed method with the criterion of "industrial applicability" is confirmed by the implementation in devices and devices of medical equipment.

The inventive method is implemented using a device that contains a block for recording brain signals (block 1), brain signal sensors, a block for converting brain signals into corresponding sensory signals (block 2), a block for influencing a patient with generated sensory signals (block 3), and also a block monitoring the current parameters of the oscillations of the brain signals (block 4) and the control unit (block 5).

During the treatment procedure, fluctuations in brain signals are recorded in block 1, and in block 4, the current psychophysiological state of the patient is monitored by fluctuations in brain signals. In block 2, the brain signal oscillations recorded by the sensors are converted into sensory signals taking into account the duration, amplitude and shape of each brain signal oscillation and, with the help of block 3, the generated sensor signals act on the patient. In this case, the registration of each brain signal, the formation of the corresponding sensor signal and the impact on the patient with this signal is carried out sequentially, without intervals between these actions. During the procedure, the patient is asked to pay attention to the fact that the sensory signals perceived by him reflect the work of his brain. The duration of the treatment procedure is set in block 5.

At the Institute of Experimental Medicine (St. Petersburg) in the Physiological Department. IP Pavlova obtained the results of studies on the application of the proposed method in the treatment of patients with functional disorders of the central nervous system, psychosomatic diseases and the effects of organic brain lesions of varying severity. During the research, from 5 to 7 procedures were performed with each patient. During the procedures, the patient’s brain signals were recorded and the patient was affected by sensory signals formed in accordance with the duration, amplitude and shape of each oscillation of the brain signal. On average, the duration of each procedure was 15-20 minutes.

During the procedures, normalization of the psychophysiological state of patients was noted, which was expressed in a significant decrease in the level of reactive and personal anxiety by the Spilberger-Khanin test, improvement of well-being, activity and mood by the SAN test (well-being, activity, mood), and a decrease in the level of depression according to the TID test (anxiety and depression), a decrease in the number of errors and a decrease in reaction time in visual and acoustic sensorimotor tests, an increase in the alpha rhythm index, a decrease in the beta rhythm index, and decreased and the level of asymmetry.

Thus, the proposed method in comparison with the prototype allows you to more effectively restore the psychophysiological state by establishing an unambiguous correspondence of the amplitude, duration and shape of each waveform of the brain signals with the corresponding parameters of the sensory signals that affect the patient, as well as by registering each waveform brain signal, the formation of the corresponding sensor signal and the impact on the patient with this signal is carried out sequentially, without intervals between these actions.

The proposed method of normalizing the psychophysiological state can be widely used in rehabilitation and medical institutions.

Claims (4)

1. A method of normalizing the psychophysiological state, including recording the patient’s brain signals, converting the selected parameters of the brain signals to sensory signals and exposing the patient to these sensory signals, characterized in that each sensory signal is formed in accordance with the duration, amplitude and shape of each oscillation of the brain signal, and the registration of each oscillation of the brain signal, the formation of the corresponding sensor signal and the impact on the patient with this signal is carried out by a follower But, without time intervals between these actions. 2. The method according to claim 1, characterized in that the patient is offered to pay attention to the fact that the sensory signals perceived by him reflect the work of his brain. 3. The method according to claim 1 or 2, characterized in that the sensory signals use separately sound, light or tactile effect. 4. The method according to claim 1 or 2, characterized in that as the sensory signals use any complex combination of sound, light and tactile effects.