RU2461396C2 - Method for psychoemotional state correction in individual - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine and may be used for reducing an anxiety level in an individual, particularly in rehabilitation of the patients with a psychosomatic pathology accompanied by emotional disorders. The patient is brought in a positive psychoemotional state. The individual values of the respiratory cycle parameters related to this state to be used thereafter as the control parameters in respiratory training on the basis of biological feedback. The control parameters of the respiratory cycle are presented by respiration rate (RR), the end-expiratory CO₂ concentration (FetCO₂), the relative duration of an expiratory phase and a pause to total duration of the respiratory cycle (Rco₂).

EFFECT: method provides higher effectiveness of anxiety correction.

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Description

The invention relates to medicine and can be used to reduce human anxiety, in particular in the rehabilitation of patients with psychosomatic pathology, accompanied by emotional disorders.

Anxiety is a widespread condition, which is a manifestation of borderline mental disorders, psychosomatic diseases, and stress. Currently, an increased level of anxiety is often found in mentally healthy people as a reaction to social and psychological stress. The problem of correction of anxiety takes on special significance during periods of economic crisis, after a psychological trauma, during the period of rehabilitation for all psychosomatic diseases.

Known methods for the correction of anxiety based on the use of pharmacological preparations. However, they have undesirable side effects on the human body. So, drugs from the group of anxiolytics cause sleep disturbance, irritability, loss of appetite, constipation. Drugs from the group of antidepressants increase blood pressure, disrupt the function of the visual and auditory analyzers, the digestive tract. In addition, most of these drugs are addictive and "withdrawal syndrome" (1).

Known methods of non-pharmacological correction of anxiety, based on psychological effects and / or psychological training, aromatherapy, physiotherapy, music therapy, etc. These include, for example, a method for correcting a person’s psycho-emotional state, including a combination of music therapy with aromatherapy. To reduce anxiety, the following works are used: K. Sen-Sans “The Swan”, and / or “Romance” from the music of G. Sviridov to the story of A. Pushkin “The Blizzard”, and / or “Moonlight” of L. Beethoven’s sonata in combination with aromas of neroli and / or roses and / or sandalwood and / or lavender (2). The insufficient effect of the method is due to the passive participation of the patient in the implementation of the method and the inability to form skills that subsequently allow for self-regulation of the psycho-emotional state. Another drawback is that the listed musical works in some cases can be associated with unpleasant experiences and psychological traumas in connection with personal experience and psychological characteristics. In addition, aromatherapy is contraindicated in allergic disorders, which significantly limits the possibility of using the method.

There is also known a method of correction of the psycho-emotional state of a person, including establishing emotional contact with the patient, conducting massage in the bath, then in the massage room; Massage simultaneously two or more masseuses conduct alternating massage techniques that enhance and level the emotional state. The method allows to reduce situational anxiety (3). The known method has the same disadvantages (passive participation of the patient, the inability to form self-regulation skills).

It was found that the main emotions of a person differ in the characteristics of the respiratory cycle. There are known attempts to simulate basic human emotions (anger, fear, anxiety, sadness, joy) based on respiratory training in frequency, depth, method of breathing (through the nose or mouth), type of breathing (chest, diaphragmatic) (4). However, the well-known qualitative description of the characteristics of the respiratory cycle for positive emotions (joy, etc.) is insufficient for their reproduction. In addition, the subjects observed a coincidence of types of breathing, determined by the indicated signs, corresponding to negative (sadness) and positive (joy) emotional states.

A known method of regulating human breathing, designed, in particular, to reduce anxiety. The method includes inducing the patient to breathe by exposure to a tactile stimulus that sets the respiratory rate. The known method is difficult to reproduce, because it does not contain quantitative parameters of standard respiration, but only an indication of the need to reduce the respiratory rate to correct anxiety. In addition, the patient does not receive a visual picture of his breathing and does not see the results of his efforts to normalize it on the monitor, which makes it difficult to achieve the stated result and prevents the patient from fixing breathing self-regulation skills and, accordingly, the psychoemotional state (5).

A known method of correcting the psycho-emotional state of a person, including determining the parameters of the respiratory cycle and the cycle of respiratory sinus arrhythmia of the patient; determination of the optimal respiratory rate, ensuring the achievement of resonant characteristics of the respiratory rate and heart rate in the range from 0.0315 Hz to 0.234 Hz; conducting respiratory training, in which the subject is offered, on the basis of biological feedback, to bring the respiratory rate closer to the optimal one, notifying him of the beginning of each breath with a sound, video, or tactile signal (6). The effectiveness of the known method is based on the theoretical assumption that the synchronization of the parameters of the respiratory and cardiac cycles with the positive psycho-emotional state of a person, however, this connection does not have a specific expression in the known method, and the description of the method does not contain information about the subject achieving a comfortable emotional state. Another disadvantage is that according to the known method, respiratory training is carried out only at the beginning of inspiration. The subject is unable to control other respiration parameters, which can lead, for example, to an uncontrolled increase in tidal volume even against the background of a decrease in respiratory rate and, accordingly, to an increase in alveolar ventilation of the lungs and a decrease in CO ₂ content in arterial blood, i.e., hypocapnia, which is one of the main symptoms of hyperventilation in anxiety conditions.

The problem to which the invention is directed, is to increase the effectiveness of the correction of anxiety. The solution to this problem is achieved by the fact that the patient is preliminarily brought into a positive psychoemotional state, individual values of the parameters of the respiratory cycle corresponding to this state are determined by capnography, which are subsequently used as control parameters during respiratory training; as the parameters of the respiratory cycle, use the respiratory rate (BH), the concentration of CO ₂ at the end of expiration (FetCO ₂ ), the relative duration of the expiratory phase and the subsequent pause to the total duration of the respiratory cycle (Rco ₂ ).

Description of the invention

The way to correct a person’s psychoemotional state includes, at the first stage, achieving a patient’s positive psychoemotional state with the help of a psychotherapist or psychologist, for example, by updating emotionally significant memories or experiences (7). Based on the capnogram, the parameters of the respiratory cycle are determined that correspond to the positive psycho-emotional state of the patient, the onset of which he reports with a signal (for example, by pressing the corresponding computer key), after which the capnogram is recorded. As such parameters, for example, the respiratory rate (BH), the concentration of CO ₂ at the end of expiration (FetCO ₂ ), the relative duration of the expiratory phase and the subsequent pause to the total duration of the respiratory cycle (Reo ₂ ) can be used. Rco ₂ = (duration of the expiratory phase + duration of the subsequent pause) / (total duration of the respiratory cycle). In the future, a respiratory training course is conducted based on biological feedback, where individual parameters of the patient’s respiratory cycle obtained in the first stage are used as control parameters. At the same time, the patient is presented in real mode with his capnogram and control parameters of the respiratory cycle corresponding to the positive psychoemotional state of the patient, which he is invited to achieve (Fig. 1). The success of respiratory training is controlled directly by capnogram indicators (for example, BH, FetCO ₂ , Rco ₂ ) and / or during a computer game (Fig. 2), the plot of which is controlled depending on the degree of deviation of the patient’s respiratory cycle parameters from the control parameters. The duration of the training session is from 10 to 30 minutes. Classes are held daily for 6-12 days. If necessary, conduct repeated courses - after 2-3 months.

It is enough to enter the patient once into a positive psycho-emotional state to determine the corresponding individual values of the control parameters of the respiratory cycle, so that later they can be used during sessions and repeated courses of respiratory training.

To implement the claimed method, a hardware-software complex “BOS-capnography” can be used (8). The complex allows for respiratory training based on biological feedback in a capnogram and / or in a game form according to the following respiration parameters: BH, FetCO ₂ , Rco ₂ under the guidance of a specialist (instructor). During respiratory training by capnogram, the values of the patient's respiratory cycle parameters are displayed on the monitor screen. When conducting respiratory training in a game form, the BOS-capnography complex allows simultaneous control of three parameters of the patient’s respiratory cycle. To assess the parameters of the respiratory cycle during the implementation of the claimed method, for example, the Mikon domestic medical capnograph (ZAO Laspek) can be used, designed to monitor (monitor) in real time the function of external respiration according to the parameters of the respiratory cycle, including BH, FetCO ₂ , Rco ₂ (8). As can be seen in Fig. 1, the capnogram can be presented on the monitor screen with a different time scan, for example, 1 (30 s) or 2 (3 min). The patient is also shown on the monitor screen in real time the numerical values of the parameters of his respiratory cycle, which he needs to bring in accordance with the specified values of the control parameters. During respiratory training involving the computer game “Flight of Breathing” (9), the value of the FetCO ₂ respiratory cycle parameter corresponds to the height of the eagle’s flight above the water towards the island, the BH parameter - to the frequency of wing flapping. The smoothness of the movement of the wings depends on the value of the parameter “Rco ₂ ”. During respiratory training, a specialist (doctor or psychologist) gives instructions to the patient and helps to control breathing. As can be seen from Fig. 2, the eagle is shown to the patient on the monitor screen as a control object 3, leading 4, flight altitude indicator 5, session progress 6, the final goal of the flight is paradise island 7. Numerical values of the respiratory control parameters are also displayed on the monitor screen cycle - FetCO ₂ and BH. In order to avoid patient information overload, the numerical value “Rco ₂ ” may not be displayed on the monitor screen, but its achievement is under the supervision of a specialist. The patient is informed on the screen about the elapsed time and the moment of reaching the values of the controlling parameters of the respiratory cycle, the latter coincides with the "landing" of the eagle on the island.

The efficiency of respiratory training based on biological feedback simultaneously on two or more parameters of the respiratory cycle using computer games was shown earlier (9, 10).

Respiratory training according to the claimed method makes it easier for the patient to acquire the skill of self-regulation of breathing in accordance with the controlling parameters of the respiratory cycle, because they are as close as possible to his characteristic way of manifesting positive emotions through breathing. Successful achievement by a patient of predetermined control parameters of the respiratory cycle according to the law of feedback forms a positive emotional mood in the patient. Moreover, in accordance with the competing properties of emotions (7), the patient displaces negative emotions. In the process of respiratory training on control parameters based on biological feedback, the patient develops the skill of self-adjustment of breathing, which allows him to subsequently randomly potentiate his positive emotions when signs of anxiety appear.

The list of figures, drawings and other materials.

Table. The parameters of the respiratory cycle in the control group and in the observation group (according to the claimed method) before and at the end of a 10-minute session of respiratory training (M ± SD).

Fig. 1. “Capnography” mode screen for establishing control parameters of the respiratory cycle and conducting respiratory training based on biological feedback.

Fig. 2. Screen in the "Flight of breathing" mode for conducting a game session of respiratory training based on biological feedback on individual parameters of the respiratory cycle.

Fig. 3. The level of situational anxiety in the examined patients of the control group and the observation group (according to the claimed method) before and after a 10-minute session of respiratory training based on biological feedback.

Case Studies

1. Group examples.

13 patients with anxiety disorders aged 25 to 65 years were randomly divided into 2 groups: observation group and control group. In both groups, the level of situational anxiety was determined according to Spielberger (11) before and after respiratory training based on biological feedback. The initial value of the level of anxiety in the groups (in the control - 42.6 ± 8.7, observations - 38.7 ± 10.5 points) corresponded to the average level (12). The difference was not significant (p> 0.1). Thus, the groups were comparable for comparing changes in anxiety.

In each group, a 10-minute session of respiratory training based on biological feedback was conducted, which consisted of 5 minutes of respiratory training in a capnogram and 5 minutes using a game session of respiratory training in the “Flight of breathing” scenario. As control parameters for respiratory training in the control group, the well-known normative parameters of the respiratory cycle of a healthy person at rest were used, and in the observation group, the control parameters of the respiratory cycle according to the claimed invention (see step 1 of the description of the invention).

In the control group (6 people) in the 10-minute training, the control parameters of the respiratory cycle corresponded to the average values for healthy people at rest: respiratory rate of 12 per minute, FetCO ₂ = 5.0%, Rco ₂ = 0.60 (table). The purpose of the respiratory training was to reproduce the breath corresponding to the above capnography parameters. In the control group, prior to the session, the values of the respiratory cycle parameters significantly differed from the control parameters. At the end of the session, they approached the control parameters: FetCO ₂ increased, BH decreased, Rco ₂ decreased. However, the level of situational anxiety in the subjects after the training did not decrease and even tended to increase: 42.6 ± 8.7 before and 45.0 ± 12.5 points after the training (Fig. 3).

In the observation group (7 people) to implement the claimed method at the 1st stage in comfortable conditions, under the guidance of a psychologist, patients were helped to model a positive emotional state by updating actual emotionally significant memories (7). For each patient, using capnography, individual control parameters of the respiratory cycle were established corresponding to the positive psycho-emotional state of the patient: respiration rate, FetCO ₂ and Rco ₂ . Moreover, the average values of the respiratory rate, FetCO ₂ and Rco ₂ in the initial state and at the end of the respiratory training session did not have significant differences (p> 0.1) from the average values of the control parameters. At the same time, in each case (see Section 2 “Individual Examples”), the initial individual parameters of the patient’s respiratory cycle could significantly differ from the values of the individual control parameters in a positive psychoemotional state. As a result of a single 10-minute session, the level of situational anxiety in the group on average decreased from 38.7 ± 10.5 to 32.6 ± 3.8 points (p <0.05) and was significantly lower (p <0.05 ) than in the control group (Fig. 3). Moreover, all participants in the studies noted a subjective improvement in the psycho-emotional state.

The results obtained indicate that each person has positive and negative emotions expressed in their own way, which is reflected in the individual characteristic of the respiratory cycle corresponding to them (emotions).

2. Individual examples

Example 1. Victor N., 47 years old. Diagnosis: hypertension stage 2-A. The level of situational anxiety according to Spielberg is 47. The initial indicators of the respiratory cycle:

FetCO ₂ = 4.4%; BH = 13.1 per minute; Rco ₂ = 0.60.

At the first stage, under the guidance of a psychologist, the patient was helped to model a positive psychoemotional state by updating emotionally significant memories (7). The following individual values of the control parameters for respiratory training were established, corresponding to the positive psycho-emotional state of the patient: FetCO ₂ = 4.4%; BH = 9.0 per minute; Rco ₂ = 0.60.

A second study was conducted after 10 days to exclude the effect of psychotherapeutic effects on the patient in the first stage. The initial level of situational anxiety on this day was 46 points, and blood pressure - 150/92. Then a 10-minute capnogram respiratory training session was conducted on the basis of biological feedback on the given individual values of the control parameters, which led to a decrease in the level of situational anxiety to 38 points. In this case, blood pressure decreased to 140/85, and the heart rate did not actually change: initially 70, at the end of the session - 69 beats per minute.

Example 2. Sergey G., 35 years old. Diagnosis: somatomorphic autonomic dysfunction. The initial level of situational anxiety is 46 points.

Initial indicators of the patient's respiratory cycle: FetCO ₂ = 5.0%; BH = 16.7 per minute; Rco ₂ = 0.64.

At the 1st stage according to the claimed invention (see example 1), the following values of the individual control parameters for respiratory training were established: FetCO ₂ = 5.6%; BH = 14.0 per minute; Rco ₂ = 0.67.

After 8 days, the initial level of situational anxiety remained at 47 points. A 10-minute respiratory training session was conducted on the basis of a computer game according to the “Flight of breathing” scenario according to the given individual control parameters, which led to a decrease in situational anxiety to 35 points. At the same time, the heart rate decreased from 73 to 67 beats per minute.

Example 3. Serova G., 19 years old. Diagnosis: Anxiety Disorders. The initial level of situational anxiety is 48 points. Baseline respiration: FetCO ₂ = 4.6%; BH = 23.4 per minute; Rco ₂ = 0.67.

At the 1st stage according to the claimed invention (see example 1), the following individual control parameters for respiratory training were established:

FetCO ₂ = 4.6%; BH = 19 per minute; Rco ₂ = 0.61.

After 7 days, a 10-minute session of respiratory training was carried out according to the capnogram and based on a computer game according to the “Flight of breathing” scenario according to the given individual control parameters of the respiratory cycle, which led to a decrease in situational anxiety from 49 to 36 points before and after the session, respectively. At the same time, the heart rate decreased from 103 to 96 beats per minute.

In the presented individual examples, attention is drawn, firstly, to the significant variability of the individual parameters of the respiratory cycle in patients with high anxiety (above 44 Spielberger points), and secondly, their significant difference from the generally accepted average values of control parameters for a healthy person, which were used in the control group. The reduction of anxiety in the above examples to an average level (35-44 points (12)) according to the claimed method confirms the effectiveness of using individual control parameters during respiratory training of the patient, characterizing the features of his breathing in a positive psycho-emotional state.

List of sources used

1. Reference Vidal 2009. Medicines in Russia. Publishing house AstraFarmServis. 2009.S. B-505, B-1489.

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3. RF patent for the invention No. 2182020. A method of correction of the psychoemotional state of a person. 2002. IPC A61M 21/00, A61H 7/00.

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Claims (2)

1. A method for correcting a person’s psychoemotional state, including determining the control parameters of the patient’s respiratory cycle, performing respiratory training on the basis of biological feedback with the presentation of the specified parameters, characterized in that the patient is preliminarily brought into a positive psychoemotional state, individual parameter values corresponding to this state are determined respiratory cycle, which are subsequently used as control parameters for rovedenii respiratory training. 2. The method according to claim 1, characterized in that the respiratory rate (RR), the concentration of CO ₂ at the end of expiration (FetCO ₂ ), the relative duration of the expiratory phase and the subsequent pause to the total duration of the respiratory cycle are used as control parameters of the respiratory cycle (RCO ₂ ).

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