RU8259U1 - DEVICE FOR ELECTROSUGESTIVE EXPOSURE - Google Patents

Abstract

1. Device for electrosurgical exposure, containing a pulse voltage source with an adjusting unit, the output of which is connected to the input of the pulse voltage source, and electrodes, characterized in that a power and information transmitting unit is inserted in it, the input of which is connected to the output of the pulse voltage source, light a radiator, the input of which is connected to the output of the pulse voltage source, and a receiving unit, the output of which is connected to the electrodes, and the pulse voltage source with the transmitting block ohms are made structurally in the form of a first autonomous unit, and the receiving unit with electrodes is in the form of a second autonomous unit. 2. The device according to claim 1, characterized in that the transmitting unit comprises a low-frequency amplifier, the input of which is the input of the transmitting unit, and a first inductor containing a first open magnetic circuit with a first winding located on it, and the receiving unit is made in the form of a second inductor with a second open magnetic circuit and the second winding located on it. 3. The device according to claims 1 and 2, characterized in that the magnetic cores of the first and second inductors of the transmitting and receiving blocks are made in the form of rods and oriented in the first and second autonomous blocks so that the longitudinal axis of the magnetic cores can be located on one axis, and the light emitter is mounted in first autonomous unit so that its radiation direction is approximately parallel to the axis of the first magnetic circuit. 4. The device according to claims 1 and 2, characterized in that the magnetic cores of the first and second inductors of the transmitting and receiving units are made in the form of rods and

Description

imf A 61 I 1/34.

DEVICE dm ELECTRIC SUGGESTED DISEASES.

The utility model relates to the field of medicine and medical technology and can be used to treat diseases based on the formation of stagnant foci of excitation or inhibition in the cerebral cortex and can be used to treat neuropsychiatric diseases, psychosomatic diseases, and to relieve reactive conditions, as well as in narcology with the aim of treating various kinds of addictions, for example, food, alcohol, drugs, drugs, tobacco and other addictions, except It can be used in psycho-pedagogy, for example, to enhance the memorization of audio information.

A device is known for electrosleep, containing a variable frequency pulse generator, a first attenuator, a second attenuator, one of which is connected to one terminal of the first attenuator, the first current amplifier, one terminal of which is connected to a different terminal of the first attenuator, contains a first key and a first stabilizer connected in series current, the output of which is connected to one output of the first current amplifier, the second step, the input of which is connected to the output of the generator and pulses of variable frequency, connected in series a third switch and a third attenuator, the output of which is connected to one output of the first attenuator, and the output of the second key, the fourth key is connected in series, the input of which is connected to the timer output and the first key input, the second current stabilizer, a constant frequency pulse generator, and the fifth key whose input connected to the output of a constant frequency pulse generator, a second current amplifier, a fourth atenuator, one output of which is connected to the output of a second current stabilizer and the input of a second current amplifier, the fifth attenuator, consequently, the sixth key and the sixth attenuator are connected, the output of which is connected to the fifth key output, the output of the fifth and other outputs of the fourth attenuator, and the high-frequency pulse generator, the output of which is connected to the inputs of the third and sixth keys, with the outputs of the first and second current amplifiers device outputs (ij.

The disadvantages of the known device are the long duration of treatment due to the low therapeutic effect, due to the fact that the applied effect is only one physical factor of primitive informational structure, capable of exerting influence only at the level of primitive reactions such as tonic or sedative, practically without using higher therapeutic connections brain functions, in particular, their properties of controlling the self-healing systems of the body. This also determines the low functionality of the device, since it does not allow expanding the scope of application, for example, due to the inability to effectively use the device for the treatment of psychosomatic diseases and in narcology. The low functionality of the device is also due to the inability to control the depth of immersion in a state of sleep, as well as the inability to work with altered states of consciousness. In addition, the disadvantages of the known device include a relatively long time of immersion in a state of sleep or analgesia, during which it is necessary to constantly transmit an electric current of a sufficiently large force (10 mA or more) through the brain tissue, which can cause unpredictable side effects and various malignancies. In addition, for these reasons, the applicability of the known device is largely thought to limit contraindications due to the patient’s diseases before treatment. Also, due to the use of wire communication with the electrodes, the device has three operational inconveniences, and taking into account the significant scatter of individual values of electric skin resistance in patients, it has low electrical safety.

A device for electrotransaction of Micro-LENAR is known, comprising a rhythmic impact unit, a combinator and amplifier connected in series, an amplitude controller, a protection unit, a current meter and one electrode connected in series, another electrode and a power supply, one output of which is connected by ONE input to the rhythmic effect, the amplifier and the unit are inactive, an amplifier-limiter, the input of which is connected to the output of the amplifier, and the output with the input of the amplitude regulator, pre-connected in series an amplifier and a power amplifier, the output of which is connected to another electrode, a key and a resistor connected in series, and a timer, the input of which is connected to the first output of the rhythm unit, and the output is connected to the input of the sew unit, the inputs of the switch are connected to the second and third outputs of the rhythm unit effects, the regulator’s output is connected to the input of the pre-amplifier, the key input is connected to the output of the current meter, one output of the power supply is connected to one input of the inputs of the timer, amplifier - a limiter, pre-accelerator, power amplifier and current meter, its other output is connected to a resistor and other power inputs of the rhythmic impact unit, amplifier, amplitude regulator, protection unit and timer, and the outputs of the protection unit are connected to other power inputs of the preliminary amplifier and power amplifier 2.

A disadvantage of the well-known usability is the low functionality that does not allow them to be used with sufficient effectiveness in narcology and for the treatment of psychosoptic diseases, as well as the low effectiveness of the effect, manifested in the instability and superficiality of the tranquilizer effect. This is because the effect is carried out only by a physical factor of a weak degree of organization, having a primitive informational structure, which is a sequence of rectangular pulse waves of an electric current of a given frequency, duty cycle and amplitude, which allows you to affect only the functional functions of the brain neurons that correspond to the effect on the information content, and in a juvenile manner, provide only background effects such as tonic or sedative. All this leads to long periods of treatment, the possibility of frequent relapses and side effects as a result of prolonged transmission of electric current through the brain. In addition, the known devices have low operational capabilities due to the low degree of distance due to the wire connection between the electrodes and the generator units, which also results in low electrical safety of the known device.

The closest technical solution to the proposed is a device for electroanalgesia containing a source of pulse voltage and electrodes. In addition, the pulse voltage source contains a power source, first and second generators connected in series, an output unit, the input of which is connected to the output of the second generator, and a matching transformer, the primary winding of which is connected to the output of the output unit, and the electrodes are staggered active and indifferent electrodes are inside the ring, while the latter are connected to the ring and the first output of the matching transformer, and the active electrodes are connected to its second output. In addition, the generator contains two series-connected inverters, a capacitor and a chain of parallel-connected first resistors and series-connected second resistors and diodes, with one end of the circuit connected to the output of the second inverter and a capacitor, the second terminal of which is connected to the output of the first inverter, the output of which connected to the other end of the chain h.

The disadvantages of the known device are low functionality due to the fact that the practically unlimited possibilities of suggestive influences are not used, which can be enhanced by the action of a physiological factor such as the passage of electric current through the brain, and the device’s design does not provide any means that allow and reinforce

parallel suggestive impact at both the conscious and subconscious levels and is limited by the physical factor. In addition, prolonged transmission of electric currents through the brain (30-40 minutes or more) can cause significant unwanted side effects, not only instantaneous, but also remote in time. In connection with the direct connection of the electrodes to the supply network, the known device has a low degree of electrical safety and low operational characteristics. In addition, the device is characterized by a low degree of controllability of the patient’s state directly during the procedure, in particular, it practically does not allow adjusting the levels of analgesia, which also reduces the functionality of the known device.

The purpose of the utility model is to reduce the duration of transmission of the aelectrocurrent through the patient’s brain and to reduce the undesirable side effects associated with it, as well as to increase the effectiveness of the treatment and to shorten the treatment time due to the use of the effect of the mutual amplification of the physical C electric current) and suggestive factors, in addition, the goal is to improve operational characteristics due to the elimination of wired communication with the electrodes and zagvaleniya, thus, the degree of distance exposure ia, and increasing the electrical safety of the device due to the implementation of full electrical isolation with the electrodes.

To achieve this goal, in a known device for electroanalgesia, containing a pulse voltage source with a control unit, the output of which is connected to the input of the pulse voltage source and electrodes.

additionally, it is supplied with transmitting energy and an information block, the input of which is connected to the output of the pulse signal, the light emitter, the input of which is connected to the output of the pulse voltage source, and the receiving block, the output of which is connected to the electrodes, and the source of pulse voltage with the transmitting unit made structurally in the form of a first autonomous unit, and the receiving unit with electrodes in the form of a second autonomous unit. In addition, the transmitting unit contains a low-frequency power amplifier, the input of which is the input of the transmitting unit, and the first inductor containing the first open magnetic circuit with the first winding located on it, and the receiving unit is made in the form of a second inductor with the second open magnetic circuit and located on it second winding. In addition, the magnetic conductors of the first and second inductors of the transmitting and receiving units are made in the form of rods and oriented in the first and second autonomous units so that the longitudinal axes of the magnetic circuits can be located on one axis, and the light emitter is mounted in the first autonomous unit so that its radiation direction was approximately parallel to the axis of the first magnetic pipe. In addition, the magnetic cores of the first and second inductors of the transmitting and receiving blocks are made in the form of rods and oriented in the first and second autonomous blocks so that the longitudinal axes of the magnetic cores can be located on the same axis, and the light emitter is fixed in the first autonomous block with the possibility of rotation and fixing relative to the longitudinal axis of the first magnetic circuit. In addition, the first stand-alone unit is made in the form of a cylindrical rod.

the first inductor is mounted at its end so that the end of its magnetic circuit is the end of the main rod, and the second autonomous unit is made in the form of a spectacle frame; the electrodes are located above the upper part of the frame at the level of the eyebrow, and the second inluctor is located on the frame in the nose region so that the core of its magnetic circuit is perpendicular to the plane of the frame. In addition, the electrodes are installed at the ends of the flat springs, the other ends of which are connected to the frame and are current leads for the electrodes. In addition, a second light emitter is introduced into it, the input of which is connected to the output of the pulse voltage source, and the second emitter is installed in the first autonomous unit on the other side of the inductor, symmetrically to the first emitter relative to the inductor. In addition, a pulse converter is introduced into it, which is included in the communication gap between the output of the 1-pulse voltage source and the light emitting input so that the converter input is connected to the source output, and the converter output is connected to the emitter input.

Figure 1 depicts a unique national diagram of device g for electrosurgical exposure.

In Fig. 2,3, functional diagrams of implementing the transmitting and receiving units are shown, respectively.

Figure 4 shows a diagram of a structural embodiment of the device.

In Fig.5 depicts kyong receiving unit in the form of a frame in working condition.

In FIG. Figure 8 depicts a functional diagram of the device with an additional pulse converter and a separate second adjustment block gave a light emitter.

The device for electrosurgical impact (figure 1) contains a second autonomous unit I, comprising a receiving unit 2 and electrodes 3 connected to the output of the receiving unit 2, a first autonomous unit 4, containing a pulse voltage source 5, a first adjustment unit 6, the output of which is connected to the input of source 5, the indicator light 7, the input of which is connected to the output of source 5, the transmitting unit 8, whose input is also connected to the output of source 5.

The transmitting unit 8 (FIG. 2) contains a first inductor 9 with ferromagnetic cores II, the input of which is connected to the output of the low-power power amplifier 18, the input of which is the input of the transmitting unit 8.

The receiving unit 2: (Fig.Z) is made in the form of a second inductor II with a core 12.

The light emitter 7 (Fig. 4) is located directly under the transmitting inductor 9 in the block 4. The emitter is attached to the block 4, made in the form of a cylindrical rod 15, with the help of a screw 13 and an arm 19.

The second self-contained unit 1 is made 11 in the rear of the spectacle frame 14, on the transfer of which a receiving inductor II with a core 12 is mounted so that its longitudinal axis is perpendicular to the plane of the ice holders of the frame 14, above which electrodes 3 are connected in their plane, connected to the frame 14 by spring-loaded current leads 21, simultaneously the function of pressing the electrodes 3 to the plot of the eyebrows on

.

In an embodiment of the device with two light emitting emitters 7, the inputs of which are connected to the output of the pulse source 5 (Fig. 6), while the light emitters 7 are parallel to the inductor II of the first autonomous unit 4 on both sides of it so that they all lie in the same the plane, and the emitters 7 are fixed (BOBMOJKHO, stationary) at the end of the rod 15 using the brackets 19 (Fig.7),

A variant of the device (Fig. 8) may comprise a pulse converter 16 in the first autoshop block, the input of which is connected to the output of the source 5, and the output is connected to the input of one or both light emitters 7, the second adjustment block 17, the output of which is connected to the upstream input of the converter 16 pulse train, which can be used as a frequency divider with an adjustable division ratio, which is set from the second block of adjustments 17, which can also introduce an adjustable time delay (phase shift) between the electrically and light and tshulsami.

A device for electrosurgical exposure (figL) works as follows.

The patient is seated in a comfortable chair under comfortable external conditions in a darkened room with soundproofing and placed on it is the second car-washing unit I so that the receiving unit 2 is fixed on the patient in an accessible place, and the electrodes 3 are placed on the corresponding parts of the head, usually used for electrosleep or electroanalgesia , for example, on the superciliary areas. After that, the first autonomous unit 4 is turned on, having previously diverted it from the casing to a distance exceeding the radius of action of the device’s receiving and transmitting path. As a result, the source of impulse voltage 5 of the first autonomous unit 4 decides to generate a pulse sequence, the parameters of which, namely, the frequency, duty cycle and shape of the pulses (for example, the steepness of the fronts of rectangular pulses) can be adjusted by the therapist using the adjustment block 6. Pulses from the output of the source 5 steps ie the input light emitter 7, on vnrabatyvaschego Kaédi incoming pulse flash light. Mastota following pulp pulses is set in the adjusting unit 6 so that it does not exceed the flicker fusion frequency (no more than 16 Hz) and the most pleasant milking cottage according to its individual sensations. At the same time, the eyes of Pascha must be fixed on the first autonomous block 4 and flashes of light 7 so that a stable connection is formed in the brain between the image of block 4 and the flashes of indicator 7. After this, the patient is asked to close his eyes and slowly begin to bring block 4 to the second autonomous block I so that the transmitting block 8 of block 4 moves towards the top of the block 2. In this case, block 4 is oriented by the inductor 9 of the transmitting block 8 towards the inductor 10 of the adjacent block I, namely, so that during movements of the unit 4, the longitudinal axes passing through the cores II and 12 of the inductors 9 and 10, respectively, are approximately aligned. The indicator light 7 of the first autonomous unit 4 is oriented with the help of the rotary unit 13 so that the light beam emitted by it during the flash gets into the eyes the patient. As block 4 approaches block I, the inductive coupling between the transmitting 9 and receiving 10 inductors increases, and the amplitude of the 10 tsulls of the Nalshunya induced in the second 1hd13 block increases. Simultaneously with etigl, paschat through closed eyelids sees an increase in the brightness of flashes of light from light 1, indicating that the first block 4 is approaching it. The operator then broadcasts to the patient suggestive information describing the upcoming result of the therapeutic effect, accompanying it with a description of the actual patient and condition when triggered devices. The suggestive briefing that is transmitted to the patient may contain verbal formulas for entering the patient into a state of sleep, trance or analgesia with practically any degree of depth with a setting for turning on the forge, (1 step into effect, starting from the moment the device is triggered. Depending on the specific purpose, the suggestive information may contain imperative or rational formulas aimed at overcoming addictions (drugs, alcohol, etc.) and also for healing from various diseases (mainly, sychosomatic) and the inclusion of the body’s general defenses aimed at self-healing, for example, law, in the form of placing blocks in the brain or triggering of the central brain mechanisms. This way, a therapeutic effect is made on the unconscious sphere through conscious consciousness. the patient’s burial level in an altered state of consciousness due to the high flexibility of the suggestive effect is even more increased due to the proposed combination with the action of electric current. Starting from a certain distance, depending on the magnitude of the amplitude generated by the source of 5 Ш1 pulses and the parameters of the inductors 9 and 10 (number of turns, sizes, shape and magnetic permeability of the cores II and 12), the voltage pulse voltage, inducing it in the adjacent inductor 12 and coming to the electrodes 3 exceeds the individual value of the patient sensitivity threshold. As a result of this, they appear in the field of vision with closed eyes, which is regarded by im as a response of the device. This leads to instant activation of the suggestive information communicated to the patient and the inclusion of super-memory by him. relation to this information. After that, the device is dislodged, and the frame 14 is removed. Thus, the passage of current through the brain tissue, exceeding the threshold of sensitivity, lasts no more than a few seconds, which completely eliminates any side effects. In addition, due to the fact that the first autonomous unit 4 of the device is made in the form of a rod 15 of an elongated cylindrical shape (see Fig. 4), and also due to the fact that the appearance of phosphenes in the patient is directly associated with the approach of the unit 4 to the head, due to the continuous operation of the light emitter 7 and due to the wireless communication of blocks I and 4, the patient’s subconscious mind implicitly perceives the action of the device as the effect of a kind of magic wand. Since every person’s subconscious has traces of memory of the immanent omnipotence of magic since childhood, the most powerful setting is activated to remove any restrictions in achieving the result of the procedure. Thus, a therapeutic effect on the unconscious sphere through the subconscious subculture is carried out.

When performing the first autonomous unit 4 with one light emitter 7 (Fig. 4), the movement of the transmitting inductance ".

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pa 9 of block 4 to the receiving inductor 10 of the second autonomous block I is carried out so that the emitter 7 is located at the bottom of the index 9 and the bay is oriented approximately to the nose bridge region. In this case, the inductor 9 itself is oriented to the area between the eyebrows, i.e. where the second inductor 10 of the receiving unit 2 is located on a frame 14, similar to a spectacle frame. When performing a device with two emitters 7 operating synchronously (Figs. 5-7), when approaching the patient’s head, they are oriented with the inductor in the same horizontal plane as so that the flashes from each emitter 7 fall into the corresponding eye of the patient. This increases the reliability of perception of the approximation of block 4 with closed eyelids of the patient. When performing the first stand-alone unit 4 with an additional transducer 16 of the emitter 7 strokes and the second adjustment unit 17 (Fig. 8), the frequency of the acting electric pulses is regulated regardless of the fusion flicker frequency. As a result of this, the frequency of electrical pulses, set in the first block 6 of adjustments, can exceed the fusion flicker frequency and is set from the condition of optimal energy transfer to receiving block 2 and the best physiological effect (50 or 100 Hz, as in electrosleep). In this case, the converter 16 lowers the pulse frequency from the source output to a value not exceeding the flicker fusion frequency (16 Hz), and its division coefficient, as well as the time delay value, is independently adjusted using the second adjustment unit 17. Thus, the transmitting unit 8 simultaneously transmits to the top unit 2 both the energy for supplying the electrodes and the information in the form of frequency, duty cycle and forcing of the generated pulses, as well as their amplitude and the nature of its change when block 4 approaches block I. Thus , the physical influence factor in itself is complicated by the introduction of an information load into the law of change in the amplitude of pulses arriving at the electrodes of the Z. and when the threshold of reality is exceeded. In addition, a suggestive factor of influence is added, which, together with the physical factor, is a complexly organized information system that allows involving higher brain functions in the process of exposure.

The proposed device for electrosurgical impact in comparison with well-known analogues, including the prototype, has eating advantages:

- reducing the time of exposure to electric shock on the brain to several seconds, which completely eliminates any undesirable side effects due to the implementation of the device blocks in the proposed manner and the introduction of additional elements;

- Significantly higher impact efficiency due to the fact that the implementation of the device allows the use of a suggestive impact factor along with the physical one, which in combination creates the affect of mutual reinforcement of both factors, exceeding the simple effects of their application separately; significantly wider functional capabilities due to the expansion of the scope, increasing the versatility of the device, as well as due to the achievement of the possibility of smooth regulation of the level of immersion in a changed consciousness;

devices due to the increase in the effect of exposure, due to the combination and mutual reinforcement of the physical and suggestive factors;

- almost complete electrical safety and improved performance due to the high degree of distance due to the lack of wired communication.

Sources 1

1. The author's certificate of the USSR J I7II9I6, MESH 61 H 1/36, 1992.

2. The author's certificate of the USSR i I7II9I4, IPC A 61 H 1/34, 1992.

3. USSR author's certificate Je 1277968, IvIIK A 61 I 1/34, 1986.

Posted by: s

.A.Shostal I.S. Repkin

Claims (8)

1. Device for electrosurgical exposure, containing a pulse voltage source with an adjusting unit, the output of which is connected to the input of the pulse voltage source, and electrodes, characterized in that a power and information transmitting unit is inserted in it, the input of which is connected to the output of the pulse voltage source, light a radiator, the input of which is connected to the output of the pulse voltage source, and a receiving unit, the output of which is connected to the electrodes, and the pulse voltage source with the transmitting block They are made structurally in the form of a first autonomous unit, and the receiving unit with electrodes is in the form of a second autonomous unit.  2. The device according to p. 1, characterized in that the transmitting unit contains a low-frequency amplifier, the input of which is the input of the transmitting unit, and the first inductor containing the first open magnetic circuit with the first winding located on it, and the receiving unit is made in the form of a second inductor with the second open magnetic circuit and the second winding located on it.  3. The device according to claims 1 and 2, characterized in that the magnetic cores of the first and second inductors of the transmitting and receiving blocks are made in the form of rods and oriented in the first and second autonomous blocks so that the longitudinal axis of the magnetic cores can be located on one axis, and the light emitter mounted in the first autonomous unit so that its radiation direction was approximately parallel to the axis of the first magnetic circuit.  4. The device according to claims 1 and 2, characterized in that the magnetic circuits of the first and second inductors of the transmitting and receiving blocks are made in the form of rods and oriented in the first and second autonomous blocks so that the longitudinal axis of the magnetic circuits can be located on one axis, and the light emitter fixed in the first autonomous unit with the possibility of rotation and fixing relative to the longitudinal axis of the first magnetic circuit.  5. The device according to claims 1 and 2, characterized in that the first autonomous unit is made in the form of a cylindrical rod, while the first inductor is mounted at its end so that the end of its magnetic circuit is the end of the cylindrical rod, and the second autonomous unit is made in the form of a spectacle frames, electrodes are located above the upper part of the frame at the level of the eyebrow, and the second inductor is located on the frame in the nose region so that the core of its magnetic circuit is perpendicular to the plane of the frame.  6. The device according to p. 5, characterized in that the electrodes are mounted on the ends of the flat springs, the other ends of which are connected to the frame and are current conductors for the electrodes.  7. The device according to paragraphs. 1, 2, 5 and 6 and claim 3 or 4, characterized in that a second light emitter is inserted into it, the input of which is connected to the output of the pulse voltage source, and the second emitter is installed in the first autonomous unit on the other side of the inductor symmetrically to the first emitter with respect to inductor. 8. The device according to claims 1, 2, 5 and 6 and claims 3 or 4, or 7, characterized in that a pulse converter is inserted into it, which is included in the communication gap between the output of the pulse voltage source and the input of the light emitter so that the input the converter is connected to the output of the source, and the output of the converter is connected to the input of the emitter.