RU2150966C1 - Psychocoding device - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: device that may be found useful in psychiatry and narcology including treatment of alcoholism, narcomania, food, nicotinic, toxic, and other dependences, as well as treatment of psychosomatic diseases by attacking conscious and unconscious spheres of human psychics has therapeutic- effect and biological feedback simulation unit 1 that can be implemented as microcomputer with relevant software and functions to generate control signals arriving at inputs of stimulator unit 2 whose function is to supply stimulating signals to light-emitting members 8, sound- emitting members 9, and tactile-effect members 10 mounted in helmet- simulator 7 of sensors put on patientТs head. Stimulating signals picked off second outputs of stimulator unit 2 are passed, respectively, to 13, 14, 15 of light-, sound-, and tactile-effect members of unit 12 that simulates effect of mentioned members on patientТs brain. Time separation of signals, dynamics of their variation, change-over from manual to automatic control of device are controlled by control unit 16 incorporated in therapeutic- effect simulation and biological feedback unit 1 and by remote-control console 19 that may be connected to unit 1 through cable 24 or wireless channel. EFFECT: enlarged functional capabilities. 13 cl, 5 dwg

Description

 The invention relates to medicine and medical equipment and can be used in psychiatry and narcology, in particular for the treatment of alcohol, drugs, food, nicotine, toxic and other addictions, as well as for the treatment of psychosomatic diseases by methods of influencing the conscious and unconscious sphere of the human psyche.

 A known apparatus for inducing artificial sleep, comprising a motor, axle, pulleys, transmissions and elements for influencing the patient’s visual receptors in the form of light sources and rotating strips, moreover, the elements for influencing the patient’s visual analyzer are made in the form of a green panel on which are mounted on a common the axis are two movable strips with silver and red discs at the ends and four green sources [1].

 In the known device, the principle of programming the psychological state is used, consisting in associating the desired result of the suggestion formula pronounced by the therapist during the operation of the device, an arbitrary change in the state of the device recorded by the patient, in particular, the disc disks coincide when they rotate in opposite directions or the intersection of one of the mark marks on the screen . However, such a change in the state of the device is primitive and does not indicate any connection with the current state of the patient and his feelings, for which reason the device provides only a small depth of penetration of the suggestion formula into the patient’s consciousness and subconscious mind, and therefore the known device has low efficiency and long terms of treatment, calculated in multiple procedures. In addition, the device does not allow you to activate the hidden reserves and capabilities of the body, since they allow the psychotherapist to work with him only by straightforward directive methods, in connection with which the known device has limited functionality to use it with sufficient effect only for the simplest effects, for example, for pain relief and does not allow use it to treat various kinds of addictions and psychosomatic diseases.

 A light-sound device for psychophysiological relaxation is known, comprising a control unit consisting of a time relay and a rhythm stimulation sensor, a light pulse generating unit, a screen, a photo transducer, a controlled sound generator, an electro-acoustic transducer, the control unit being connected to a light pulse generating unit optically coupled to the screen and photoconverter, the output of which is connected to the input of a controlled sound generator connected to the electro-acoustic transducer spruce; the light pulse forming unit is made with an optical shutter of variable transparency, and the rhythm stimulation sensor is made in the form of a functional converter mechanically connected to a time relay and a light pulse shaper [2].

 The known device allows for the implementation of light-sound rhythmic effects on the visual and auditory analyzers of the patient, physiologically consistent with the actual desired respiratory rate of the patient. However, the disadvantages of the device are low functionality and long treatment periods due to low efficiency due to the fact that regulation is carried out according to one parameter (respiratory rate) directly without the use of metaphors. For this reason, the scope of the device is limited only to use for relaxation, for psychophysiological unloading and treatment of a limited number of neuroses associated with the direct effect of stress loads. Even with these applications, the known device has a long treatment time, because to achieve a noticeable result requires a large number of repetitive procedures.

 Closest to the proposed is a device for electrotherapy, containing a block of action on the visual analyzer, light-emitting elements connected to the output of the block of action on the visual analyzer, a block on the auditory analyzer with sound-emitting elements connected to its output. In addition, the device contains an electrical stimulator, a clock generator, an oscilloscope, an ozonizer, an electric sleep unit, a diode, a transistor, an LED, an electronic stopwatch and a heart rate sensor connected by inputs to the output of an oscilloscope connected via a key to a clock generator, the first and second outputs of which are connected respectively, with the first and second inputs of the coincidence circuit, the output of which is connected to the input of the stimulation unit, combining the electrical stimulator and the stimulus circuit to the visual analyzer, the input of the ozonizer and the first input of the block of influence on the auditory analyzer, the second input of which is connected to the output of the pulse sensor, while the first output of the clock pulse generator is connected through the resistor to the base of the transistor, the collector of which is connected through the diode to the electric sleep unit and directly to the LED [3].

 The known device can significantly reduce the treatment time for alcohol dependence to one procedure, however, it does not make it possible to obtain a stable treatment effect for a sufficiently long period of time, due to the low efficiency of the device. The known device does not allow the creation of closed self-reinforcing foci of excitation in the patient’s brain, aimed at blocking addictions and curing psychosomatic diseases due to the use of the simplest stimulating effects at the sensory level and unloading of the conscious sphere because of this. The device does not allow modeling the positive result of the treatment as a physiotherapeutic procedure and presenting it to the patient. All this leads to low efficiency of the known device and short remission periods, and also because of this low functionality, which practically does not allow the device to be successfully used to treat strong addictions, such as drugs and food, for the treatment of psychosomatic diseases. In addition, the device has a rather high stress factor of influence, which, in combination with the electric sleep generator used in it, can give significant negative side effects, and the use of electric sleep greatly reduces the electrical safety of the device due to the large uncontrolled spread of the individual value of electric skin resistance in various patients.

 The aim of the invention is to expand the functionality, increase the effectiveness of the impact, reduce the treatment time and increase the duration of remissions due to the inclusion of the hidden device of the patient with the proposed device and direct them to healing and release from addiction, by significantly increasing the depth of penetration of the formulas of suggestion into consciousness and the patient’s subconscious and their fixation, as well as the inclusion of self-reinforcing mechanisms of learned formulas over time, which is achieved I am by imitating the therapeutic effect as a physiotherapeutic procedure with a change in the morphological structures and functional state of the patient’s brain, as well as by presenting the imitation of the objective desired results of the treatment as achieved.

 This goal is achieved by the fact that in the known device for electrotherapy, containing a block of influence on the visual analyzer, light-emitting elements connected to the output of the block of influence on the visual analyzer, a block of influence on the auditory analyzer with sound-emitting elements connected to its output, an additional EEG sensor simulator is introduced made in the form of a helmet connected to the outputs of the blocks of influence on the visual and auditory analyzers, and light and sound-emitting elements are located in the helmet; one control input to the blocks of influence on the visual and auditory analyzers; a unit for simulating therapeutic effects and biological feedback, the first and second outputs of which are connected to the control inputs of the blocks of action on the visual and auditory analyzers. In addition, an additional block of influence on a tactile analyzer with a control input and a block of organs of tactile influence, an input of which is connected to the output of a block of influence on a tactile analyzer, a control input of which is connected to the third output of a block of simulation of therapeutic effect and biological feedback, are introduced into it, and the block Tactile organs placed in the helmet. In addition, the second outputs to the blocks of influence on the visual, auditory and tactile analyzers and the block simulating the impact on the brain are introduced into it, the first input of which is connected to the second output of the block of influence on the visual analyzer, the second input is connected to the second output of the block of influence on the auditory analyzer , and the third input is connected to the second output of the impact unit on the tactile analyzer. In addition, the block simulating the effects on the brain contains light-emitting elements, the inputs of which are the first input of the block simulating the effects on the brain, the sound source, the input of which is the second input of the block simulating the effects on the brain, and the source of thermal radiation, the input of which is the third input of the block simulating the impact to the brain. In addition, the block simulating the effects on the brain contains a pulse shock mechanism with a switch. In addition, the block simulating the effects on the brain is made in the form of a pistol. In addition, an external remote control is additionally introduced into it, the output of which is connected to the input of the unit for simulating therapeutic effects and biological feedback. In addition, the connection of the remote control to the unit simulating the therapeutic effect and biological feedback is made wired. In addition, the connection of the remote control to the unit simulating therapeutic effects and biological feedback is made wireless. In addition, the unit for simulating therapeutic effects and biological feedback contains a control unit, the first three outputs of which are outputs of the unit for simulating therapeutic effects and biological feedback; a timer whose input is connected to the fourth output of the control unit; an indication unit, the first input of which is connected to the output of the timer, and the second input is connected to the fifth output of the control unit; an EEG signal simulation unit, the input of which is connected to the sixth output of the control unit, and the output is connected to the third input of the display unit; a unit for imitating a tomogram of the brain, the input of which is connected to the seventh output of the control unit, and the output is connected to the fourth input of the display unit; the input of the control unit is the input of the block simulating therapeutic effects and biological feedback. In addition, a microcomputer containing connected microcomputers, a display, and a keyboard was used as a block for simulating the therapeutic effect and biological feedback. In addition, the remote control is structurally combined with a block simulating effects on the brain. In addition, the tactile elements are made in the form of vibrational electromagnets with rod cores installed in the helmet, the tactile elements are placed on the helmet in the area of the superciliary arches, in the parietal region and in the parotid regions.

 In FIG. 1 shows a functional diagram of a device for psychocoding.

 Figure 2 shows the connection diagram of the blocks of the device for psychocoding.

 In FIG. 3-5 illustrate examples of screen forms for a block simulating therapeutic effects and biological feedback made using a microcomputer.

 A device for psychocoding (Fig. 1, 2) contains a block 1 simulating therapeutic effects and biological feedback, block 2 stimulants, three inputs of which are connected to three outputs of block 1, block 2 stimulants containing blocks of visual 3, auditory 4 and tactile 5 analyzers, each of which contains two outputs, and the inputs form the inputs of block 2 stimulants; the first outputs of blocks 3-5 of which are connected by a first cable 6 to a block 7 - a sensor simulator, for example EEG, made in the form of a helmet and containing light-emitting 8, sound-emitting 9 elements and tactile elements 10, designed to act on the corresponding patient analyzers; the second outputs of blocks 3-5 of block 2 are connected by a second cable 11 to the inputs of the block 12 simulating the impact on the brain, which contains light-emitting 13, sound-emitting 14 elements and elements 15 of tactile action, the inputs of which are the inputs of the block 12 simulating the effect on the brain, which is made in the form a gun; block 1 simulating therapeutic effects and biological feedback contains a control block 16, the input of which is the input of block 1, and the first three outputs are outputs of block 1; block 17 forming a simulation of the tomogram of the brain, the input of which is connected to the seventh output of the control unit 16; an indication unit 18, the second input of which is connected to the fifth output of the control unit 16, and the fourth input is connected to the output of the brain tomogram simulation imaging unit 17; block 20 simulating EEG signals, the input of which is connected to the sixth output of the control unit 16, and the output of block 20 is connected to the third input of the display unit 18; a timer 23, the input of which is connected to the fourth output of the control unit 16, and the output is connected to the first input of the display unit 18; the device also includes a remote control 19, connected by a third cable 24 to the input of block 1 simulating therapeutic effects and biological feedback; unit 12 simulating the effect on the brain also contains a switch 21 and a pulsed percussion mechanism 22. The remote control 19 can be wirelessly connected to the unit 1 simulating therapeutic effects and biological feedback using, for example, infrared or radio channel, or can be structurally combined with the unit 12 simulations of effects on the brain.

 A device for psychocoding (Fig. 1,2) works as follows.

 Preliminarily, a group lesson is conducted with patients according to a special technique, using the method of rational psychotherapy in a wakeful state. At the same time, a collective installation is being formed to increase the significance of the procedure, as well as an explanation of the "mechanisms" of the forthcoming "physiotherapeutic" procedure of the direct impact on the structure of the patient's brain. In the process of explanation, the preconceived sensations are associated, which are then artificially induced in the patient using the device with the steps of exposure and the desired results.

 Then, with each patient, an individual procedure is carried out using the proposed device.

 The device is connected to the network and, before working with the patients, the programming unit 1 for simulating the therapeutic effect and biological feedback is programmed due to the fact that a control program for the stimulant block 2 with the visual stimulus 3, auditory 4 and tactile 5 analyzers, which determines three channels the type, shape, frequency, duration of the stimulating signals and the dynamics of their parameters in time, generated by blocks 3, 4, 5 and transmitted via cable 6 to the block simulator 7 of EEG sensors, made in the form of a helmet, the inputs of the corresponding light-emitting 8 and sound-emitting 9 elements and tactile elements 10 installed in the helmet simulator 7. The program may also include automatic or manual switching of stimulating signals from the first outputs of blocks 3, 4, 5 to their second outputs , i.e. the termination of the supply of stimulating signals to the simulator 7 and the supply of the necessary stimulating signals through the second cable 11 to the inputs of the block 12 simulating the impact on the brain, made, for example, in the form of a gun, the inputs of which are the inputs of light-emitting 13, sound-emitting 14 elements and elements 15 of the tactile effect of block 12 , or provides for the parallel operation of blocks 7 and 12 with the appropriate separation of time. The program also provides for the required redistribution of the functions of automatic and manual control of blocks 3-5 of the block of stimulants and impact elements 8-10, 13-15. The program is introduced into the control unit 16 of the control unit 1 of the simulation of therapeutic effects and biological feedback. If the latter is made in the form of a microcomputer with a display and a keyboard, the control unit 16 is implemented in software and hardware form, including a control program, a communication interface between the microcomputer and the exposure units 3, 4, 5, and interface software. In this case, the program is entered from the keyboard of the microcomputer. The program can be introduced once before working with many patients and can remain unchanged in the future, or adjusted as necessary and the therapist’s desire. The use of microcomputers can significantly simplify the adjustment of the impact program or its complete change.

 After the device is prepared for operation (programming of the control unit 16 is completed), an individual procedure is carried out with it with each patient. To do this, the patient is seated in a comfortable chair in a small office with good sound insulation in twilight lighting and comfortable conditions (pressure, humidity, temperature). A helmet-simulator 7 is put on the patient’s head and a control program is launched in block 16 (from the microcomputer keyboard with microprocessor implementation of block 1). In this case, the control signal from the output of the (sixth) control unit 16 is input to the brain tomogram simulation unit 17, which generates a tomogram image signal supplied to the third input of the display unit 18. The screen of block 18 displays one or more slices of a typical tomogram of the brain of a healthy person (Fig.3-5) and is located in the field of view of the patient. After that, the patient’s gaze is fixed on the screen of the display unit 18 with the necessary explanations, identifying the real structure of the patient’s brain with the images on the screen of the block 18 and showing the “pathological” foci of stagnant excitation that “cause” the addiction and psychosomatic diseases. Further, the tomogram image signal from the block 17 to the display unit 18 is stopped, and the control unit 16 generates control signals for the first three outputs, which are supplied to the control inputs of the exposure units 3-5, which generate stimulating signals with parameters determined by the program of the control unit 16. Stimulating signals are transmitted through cable 6 to the inputs of the helmet-simulator 7, the inputs of which are the inputs of light-emitting 8, sound-emitting 9 elements and tactile elements 10 located in the helmet 7, which carry out the corresponding effects on the visual, auditory and tactile analyzers of the patient. The tactile elements 10 can be vibrational electromagnets with rod cores mounted in the helmet 7 so that when the helmet 7 is put on the patient’s head, the rod cores come into contact with human skin on the head, for example, in the parietal region, in the parotid regions, superciliary arches, etc. When stimulating signals are received on them, the core cores vibrate and irritate the skin integuments (mechanoreceptors) of the head at appropriate points, which can be modeled in astnosti sensations when the current at electrosleep or "electrotherapy" effect, which is supported by the respective formulas verbal suggestions. The program can specify, for example, first sequential, and then the summarized effect of blocks 3-5 and elements 8-10 of the impact on the patient, or immediately summarized the simultaneous action of all blocks 3-5, 8-10. The time intervals of exposure through these three channels and the dynamics of changes in the parameters of stimulating signals can be set automatically by the program of block 16, or manually by a general practitioner from the remote control 19 or from the keyboard of the microcomputer along the course of exposure.

 Upon reaching the maximum increase in emotional reactions to impacts and the patient entering a state of superficial trance, the visual stimulation is switched off manually from the remote control 19 or automatically according to the program from the control unit 16. After that, the therapist takes in the hand-block 12 simulating the effect on the brain, made in the form of a pistol, directs it to the region of the patient’s nose and turns on the second outputs of the blocks 3-5 exposure, stimulating signals from which begin to flow through the second cable 11 to the light emitting 13, sound-emitting 14 elements and tactile elements 15, the latter can be made in the form of a source of directional thermal or infrared radiation.

 At the same time, the control signal from the seventh output of the control unit 16 is fed to the input of the EEG signal simulator 20, which generates image signals of the multi-channel EEG derivation that are sent to the display unit 18 and displayed on its screen. Then the therapist fixes the patient’s gaze on the screen of block 18 and begins to slowly approach block 12 to the patient’s nose. At the moment of maximum voltage of the patient, on command from the remote control 19 through the control unit 16, the action blocks 3-5 are switched to a sharp change in the nature of the generated stimulating signals. At the same time, the latter cause a flash of light in the light-emitting elements 13 of the block 12, generating a sharp loud sound, for example, a click in the sound-emitting elements 9 of the helmet 7 and the elements 14 of the block 12 and a jump in heat increase in the tactile elements 15 of the block 12. A switch 21 can also be turned on simultaneously. pulse impact mechanism 22 (figure 2), inflicting a light blow on the nose of the patient with a close presentation to him block 12.

 At the same time, on command from the remote control 19, a signal is supplied through the control unit 16 to the input of the EEG signal simulating unit 20, which causes a sharp abrupt change in the nature of all the waves on the screen of unit 18 simulating the patient's EEG, which is also recorded by the patient and is accompanied by the corresponding verbal formulas of suggestion in which the therapist convinces the patient of the therapeutic changes made in the brain. In conclusion, they demonstrate on the screen of block 18 the image of the new “changed” brain tomogram generated by block 17 and inform the patient about the changes made and their connection with the release from addictions and psychosomatic diseases.

 In addition, during the entire individual therapeutic procedure, control signals from the fourth output of block 16 are sent to a timer 23, the time signals from which with the corresponding necessary marks, for example, when switching operating modes, are sent to the first input of the display unit 18 and displayed on its screen in conjunction with other images. The second input of block 18 can receive signals directly from the fifth output of the control block 16, due to which commands for switching the device modes can be displayed as service information for the therapist, displayed simultaneously with the working images, which also, when observed by the patient, increases the significance of the procedure, and therefore, the effect exposure. The control signals from the output of the remote control 19 of the remote control can be supplied to the control unit 16 via the third cable 24 or via a wireless communication line (for example, infrared).

Thus, the device allows you to:
- enter the patient into a state of increased suggestibility (light trance) with a decrease in the criticality of perception with the help of organized light-emitting and tactile influences in a certain way;
- imitate in this state of the patient the apparatus "physiotherapeutic" effect on the patient's brain "producing" its morphofunctional changes;
- imitate biological feedback by presenting to a patient who is in a state of increased suggestibility, to imitate changes in non-abstract, namely, “his” physiological parameters of the brain, such as EEG and tomograms, directly into the process of simulating therapeutic effects.

The device was used in the treatment of a group of 323 patients with alcoholism, smoking and overweight, of which:
with 1 stage of alcoholism - 51 patients;
with 2 stages of alcoholism - 98 patients;
with 3 stages of alcoholism - 24 patients;
with smoking problems - 63 patients;
overweight - 87 patients.

 Using the proposed device for 1 year it was blocked: with the first stage of alcoholism - 28 patients, remission was 94%; with the second stage - 43, remission was 91%; with the third stage - 14 patients, remission - 86%.

 For 2 years it was blocked: with the first stage of alcoholism - 17 patients, remission -92%; with the second stage - 39 patients, remission 89%; with the third stage - 6 people, remission 86%.

 For three years were treated: with the first stage of alcoholism - 6 patients, remission -89%; with the second stage - 16 people, remission -89%; with the third stage - 4 patients, remission - 82%.

 Persons with a dependence on smoking were blocked for one term for 6 months, regardless of the length of smoking, remission was 96%.

 In the overweight treatment group, blocking was performed at the veca for three months. The choice of weight loss was determined by the patients themselves. The weight within the range of the choice of 2–5 kG under-selection was 76%, more than the selection was 21%. With weight loss, blood pressure in patients of degrees 1 and 2 stabilized and decreased in 85% of cases, during the year there were no attacks of bronchial asthma in 79%, renal sand and stones with renal pathology in 73% of cases disappeared, and gastric ulcer exacerbations were not observed. intestinal tract in 69% of patients.

 In all the above examples, a single individual exposure procedure was applied using the proposed device.

The proposed device of the day of psychocoding in comparison with known analogues, including the prototype, has the following advantages:
- significantly wider functionality due to the introduction of additional elements connected in the proposed manner, allowing to increase the duration of remissions; and a significant reduction in the number of relapses, which allows you to use the device not only for the treatment of alcoholism, but also for any kind of addiction, such as narcotic, toxic, food, nicotine, etc., as well as diseases of a large psychiatry and psychosomatic diseases;
- increased impact efficiency and high persistence of the therapeutic effect, since the additionally introduced elements in their interaction with the elements of the prototype allow you to activate the latent reserve capabilities of the patient by significantly increasing the depth of penetration of the suggestion formulas using the device into the patient’s consciousness and subconscious mind due to the use of therapeutic imitation in the proposed device physiotherapeutic effects and high patient confidence in th positive effect of treatment by the use of a simulation device biofeedback;
- long periods of remission at short periods of treatment (a single procedure) due to the device turning on self-reinforcing mechanisms of the learned suggestion formulas over time, because by performing the device completely as a simulator of instrumental effects directly on the patient’s brain structures and masking using additionally introduced elements of the therapeutic therapeutic nature procedures, the most powerful developed conscious sphere is used as one of the impact factors ia on the subconscious, which is not allowed to achieve any of the known devices;
- drug-free nature of the impact of the device and its high infectious protection;
- simplicity of design, the absence of expensive blocks and elements, low cost (several orders of magnitude lower than real physiotherapeutic and diagnostic equipment), as well as ease of operation and maintenance;
- high electrical safety, as the device does not use electric sleep or any other electrodes of influence, and also does not use diagnostic electrodes connected to electrical equipment.

Sources of information
1. USSR author's certificate N 330871, IPC ⁶ A 61 M 21/00, 1972

2. USSR author's certificate N 1463309, IPC ⁶ A 61 M 21/00, 1989

3. RF patent N 2005500, IPC ⁶ A 61 M 21/00, 1994

Claims (13)

 1. A device for psychocoding containing a block of influence on the visual analyzer, light-emitting elements connected to the output of the block on the visual analyzer, block on the auditory analyzer with sound-emitting elements connected to its output, characterized in that a simulator of EEG sensors is inserted into it, made in the form of a helmet connected to the outputs of the blocks of influence on the visual and auditory analyzers, and light and sound-emitting elements are located in the helmet; one control input to the blocks of influence on the visual and auditory analyzers; a unit for simulating therapeutic effects and biological feedback, the first and second outputs of which are connected to the control inputs of the blocks of action on the visual and auditory analyzers.  2. The device for psychocoding according to claim 1, characterized in that it additionally introduces a block of influence on a tactile analyzer with a control input and a block of organs of tactile influence, the input of which is connected to the output of the block of influence on a tactile analyzer, the control input of which is connected to the third output block imitation of therapeutic effects and biological feedback, and a block of organs of tactile influence is placed in the helmet.  3. The psychocoding device according to claim 1, characterized in that the second outputs are additionally introduced into the blocks of influence on the visual, auditory and tactile analyzers and the block simulating the effect on the brain, the first input of which is connected to the second output of the block of influence on the visual analyzer, the second input connected to the second output of the impact unit on the auditory analyzer, and the third input is connected to the second output of the impact unit on the tactile analyzer.  4. The device for psychocoding according to claims 1 to 3, characterized in that the block simulating the effect on the brain contains light-emitting elements, the inputs of which are the first input of the block simulating the effect on the brain, the sound source, the input of which is the second input of the block simulating the effect on the brain, and a source of thermal radiation, the input of which is the third input of the block simulating effects on the brain.  5. The device for psychocoding according to claim 1 - 4, characterized in that the block simulating the effects on the brain contains a pulse shock mechanism with a switch.  6. A device for psychocoding according to claims 1 to 5, characterized in that the block simulating the effect on the brain is made in the form of a gun.  7. A device for psychocoding according to claims 1 to 6, characterized in that an external remote control is additionally introduced into it, the output of which is connected to the input of the treatment simulation and biological feedback simulation unit.  8. The device for psychocoding according to claims 1 to 7, characterized in that the connection of the remote control to the unit for simulating therapeutic effects and biological feedback is made wired.  9. The device for psychocoding according to claims 1 to 7, characterized in that the connection of the remote control to the unit simulating the therapeutic effect and biological feedback is made wireless.  10. The device for psychocoding according to claims 1 to 6, characterized in that the unit for simulating therapeutic effects and biological feedback contains a control unit, the first three outputs of which are outputs of the unit for simulating therapeutic effects and biological feedback; a timer whose input is connected to the fourth output of the control unit; an indication unit, the first input of which is connected to the output of the timer, and the second input is connected to the fifth output of the control unit; an EEG signal simulation unit, the input of which is connected to the sixth output of the control unit, and the output is connected to the third input of the display unit; a unit for imitating a tomogram of the brain, the input of which is connected to the seventh output of the control unit, and the output is connected to the fourth input of the display unit; the input of the control unit is the input of the block simulating therapeutic effects and biological feedback.  11. A device for psychocoding according to claims 1 to 6, characterized in that a microcomputer containing connected microcomputers, a display and a keyboard is used as a block for simulating the therapeutic effect and biological feedback.  12. A device for psychocoding according to claims 1 to 6, characterized in that the remote control is structurally combined with a block simulating the effects on the brain.  13. A device for psychocoding according to claims 1 to 12, characterized in that the tactile elements are made in the form of vibration electromagnets with rod cores installed in the helmet, the tactile elements are placed on the helmet, in the area of the superciliary arches, in the parietal region and in parotid areas.

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