RU2725754C1 - Method for transcranial electrical stimulation of endorphin cerebral mechanisms for normalizing the tone of the vegetative nervous system and a device for its implementation - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: group of inventions refers to medical equipment, namely to a method for transcranial electrical stimulation of endorphine cerebral mechanisms for normalizing the tone of the vegetative nervous system (VNS) and a device for its implementation. Method involves contact exposure of the forehead region and behind the ears with current pulses. At that, bipolar or unipolar current pulses of duration 3.75±0.4 ms and period of follow-up 12.9±0.6 ms are applied. Before the beginning of the procedure, the patient's VNS tone is assessed by calculating the vegetative balance index (VBI) by formula VBI=Amo/VR, where Amo is mode amplitude in relative units, VR is variation range of R-R intervals in seconds. If the VBI values are less than 1 Hz – vagotonia, unipolar current pulses are applied. If values VBI from 1 to 2.5 Hz are normotonia, bipolar current pulses are used to achieve sedation, and to achieve activation, unipolar current pulses are applied. If values above 2.5 Hz are sympathicotonia, bipolar current pulses are applied. Device includes a generator, a timer, a voltage-to-current converter (WCC), frontal and behind the ears electrodes, an R-R interval sensor, a vegetative balance index unit (VBI), activation-sedation button, mode switch, polarity button and switch. Tome electrodes are connected in parallel.EFFECT: individual transcranial electrical stimulation of the endorphine mechanisms of the brain is provided for normalizing the VNS tonus taking into account both the initial tone of the VNS of the patient and the current state of his innervation and blood supply systems of the head.3 cl, 1 dwg

Description

The invention relates to medicine, namely to physiotherapy.

A known method of stimulation of the antinociceptive system (SU, copyright certificate N15222500 A 61 N 1/32, 1985). The method consists in the fact that the effect is carried out on the forehead and mastoid processes, on which current-conducting electrodes with cloth moistened pads are placed. For a therapeutic effect, first a direct current is supplied, and then rectangular pulses of the same polarity are added to it with a frequency of 70-80 Hz with a pulse duration of 3-4 ms and a ratio of constant and pulse currents of an average value of 2-5: 1. In this case, the total current strength is changed from 5 to 25 mA with a duration of exposure of 25 - 35 minutes. The method allows to stimulate the production of endorphins, which leads, in particular, to the normalization of the tone of the autonomic nervous system (ANS).

The disadvantages of this method are the following:

1. The lack of effectiveness of stimulation of the antinociceptive system, and hence the low degree of impact on the tone of the ANS of the patient, since the method does not take into account individual differences both in the initial state of the ANS of the patients and in the state of the innervation and blood supply systems of the head.

A known method of transcranial electrical stimulation (TES) of the endorphin mechanisms of the brain and a device for its implementation (RU 2159639 A61N 1/36 (2000.01) A61N 1/34 (2000.01)), the closest in technical essence and the achieved result.

The method consists in contacting the region of the forehead and mastoid processes of the patient with an electric current of 0.2-5 mA in the form of a sequence of monopolar rectangular pulses with a front and slice duration of not more than 20 μs, followed by a period of 12.9 + 0.4 ms with a duty cycle of 3.2-3.7 for 15-40 minutes, while in the process of electrical stimulation, a positive instrumental musical and speech effect is additionally carried out.

The disadvantages of the method are the following:

1. This method does not allow to take into account the initial tone of the autonomic nervous system (ANS) of the patient, in particular, the presence of sympathicotonia (ST), normotonia (NT) or vagotonia (VT), which significantly affects both the process of selecting exposure parameters and the effectiveness procedures.

2. The method does not take into account individual differences in the current state of the innervation and blood supply systems of the head, which reduces the effectiveness of the impact, because does not provide for a corresponding change in the direction of current flow.

The device in accordance with this invention contains a pulse signal source, which is used as a generator, a filtering unit, an adder amplifier, a voltage-current converter, a current meter, and stimulation electrodes. In addition, the device additionally includes a control unit, a keyboard unit, a musical speech unit, a non-volatile memory unit, an indicator unit, a test signal unit, biological feedback sensors and an amplifier converter.

The disadvantages of the device are as follows:

1. This device does not contain means for determining the initial tone of the autonomic nervous system (ANS) of a person, in particular, the presence of sympathicotonia (ST), normotonia (NT) or vagotonia (VT), which significantly affects both the process of selecting exposure parameters and prognosis of the effectiveness of the procedure.

2. This device does not contain means for changing the direction of flow of the acting current, which is necessary to increase efficiency by taking into account individual differences in the state of the innervation and blood supply systems of the head.

The technical problem is the development of a method and device for providing individually effective transcranial electrical stimulation of the endorphin brain mechanisms to normalize the tone of the ANS, taking into account both the initial tone of the ANS of patients and the state of the innervation and blood supply systems of the head.

The technical result is to provide individually effective transcranial electrical stimulation of the endorphin mechanisms of the brain to normalize the tone of the ANS, taking into account both the initial tone of the ANS of the patient and the current state of his innervation and blood supply systems of the head.

The technical problem is solved and the technical result is achieved by the development of a method for transcranial electrical stimulation of the endorphin mechanisms of the brain to normalize the tone of the ANS and a device for implementing the method.

A method of transcranial electrical stimulation of brain endorphin mechanisms to normalize the ANS tone, including contacting current impulses on the forehead and behind the ears, consists in acting with bipolar or monopolar current impulses with a duration of 3.75 ± 0.4 ms and a repetition period of 12.9 ± 0.6 ms, in addition, before the start of the procedure, the tone of the ANS of the patient is evaluated, in particular, by calculating the index of vegetative equilibrium of the IVR according to the formula:

IVR = Amo / BP, Where

Amo - the amplitude of the mode in relative units,

BP - variational range of R-R intervals in seconds,

for IVR values less than 1 Hz - vagotonia, conduct monopolar current pulses, for IVR values from 1 to 2.5 Hz - normotonies, to achieve sedation, conduct bipolar current pulses, and to achieve activation, carry out monopolar current pulses, for IVR values above 2.5 Hz - sympathicotonia, conduct exposure to bipolar current pulses.

The method is additionally characterized in that 1-3 minutes after the start of the procedure, the patient senses localization, if there are sensations of vibration or burning only under the frontal electrode or simultaneously under all electrodes, they stimulate with the direct current direction, and if there are sensations only behind the ears carry out stimulation with an inverse direction of the current, while the direct direction of the current is considered to be the presence of an anode behind the ears at the time of the pulse, and the cathode on the forehead, and the opposite direction of the current is considered.

The TPP device of the endorphin mechanisms of the brain for normalizing the ANS tone is characterized by the presence of a generator, timer, PNT voltage-current converter, frontal and behind-the-ear electrodes, the device also includes an RR-interval sensor, an autonomic equilibrium index block, an activation-sedation button, a mode switch, a button polarity and a switch, while the timer is connected to the input of the generator, the first and second outputs of which are connected, respectively, to the first and second inputs of the mode switch, the third and fourth inputs of which are connected, respectively, to the first and second outputs of the IVR unit, the RR-interval sensor connected to the first input of the IVR block, to the second input of which an activation-sedation button is connected, the output of the mode switch is connected to the PNT input, the first and second outputs of which are connected, respectively, to the first and second inputs of the switch, the polarity button is connected to the third input, the first switch output connected to frontal electrode, and the second output to the behind-the-ear electrodes connected in parallel.

Before the start of the procedure, the patient's ANS tone is assessed, which can be done, in particular, using the index of vegetative equilibrium of the IVR, for which an array of 110 values is formed using the RR interval sensor, then a histogram of RR intervals is constructed with a step of 50 ms, the 5 smallest and the largest values, for the remaining 100 intervals, the vegetative equilibrium index is calculated by the formula: IVR = Amo / BP, where Amo is the amplitude of the mode in relative units, and BP is the variational range of R-R intervals in seconds. Exposure begins in the forward direction. For values of an IVR of less than 1 Hz (vagotonia), monopolar current pulses are applied, for a value of 1 to 2.5 Hz (normotonium), they are subjected to bipolar current pulses to achieve sedation, and monopolar current pulses are applied to achieve activation, for values above 2.5 Hz (sympathicotonia) are exposed to bipolar current pulses. When the values of the IVR less than 0.1 Hz and more than 10 Hz, the effect is not carried out.

It is well known that vagotonia (VT) is a complex state of the ANS, provoked by the excessive tonus of the vagus nerve, which regulates the activity of internal organs, endocrine glands, and vessels. BT has several tens of symptoms, which makes it difficult to diagnose, but established vagotonia is an occasion for appropriate treatment. BT is extremely common among children and adolescents. According to statistics, more than half of children with non-infectious diseases come to the pediatrician precisely with this problem. Adults are also increasingly faced with vagotonia. The reason for this is a decreasing physical activity of the population, an unhealthy lifestyle, a high level of stress, excessive physical and emotional stress at work and at home.

The most common signs of vagotonia are weakness, hypotension, bradycardia, shortness of breath, non-localized pains in the abdomen and chest, dizziness and decreased resistance to any kind of stress, fatigue. Vagotonia is accompanied by sleep disturbance - patients find it difficult to fall asleep, sleep restlessly or suffer from insomnia, but are sleepy during the day. In addition to the above, patients with BT experience other symptoms - poor tolerance of heat and cold, chilliness, excessive sweating, fluctuations in body temperature towards its decrease, itching of the skin and tendency to allergies, runny nose without a clear infectious cause, excess body weight with reduced appetite, meteorological dependence and deterioration in well-being during sudden changes in weather conditions.

Vagotonia is not a disease, but may be a harbinger of the disease. Sometimes, to stop the symptoms of vagotonia, it is enough to normalize the mode of work, sleep and rest, establish proper nutrition, and practice regular exercises in sports. If the correct regimen, nutrition and sport do not bring the desired result, drug therapy is prescribed. However, in most cases, BT is poorly stopped by drug methods.

Given that vagotonia is a pronounced endorphin-deficient state, it is preferable to use methods of activation of the endorphin system taking into account individual characteristics. We found that in order to normalize the tone of the ANS of patients with vagotonia, it is necessary to carry out transcranial electrical stimulation (TES) of the endorphin system with monopolar current pulses of 3.75 ± 0.4 ms duration and a follow-up period of 12.9 ± 0.6 ms applied to the surface of the scalp in the forehead and behind the ears. TPP in this mode has an activity-enhancing effect, increases immunity, anesthetizes, etc.

Unlike vagotonia, sympathicotonia (CT) is manifested by an increase in the tone of the sympathetic part of the autonomic nervous system with the appearance of characteristic symptoms - hypertension, tachycardia, fever, hunger, etc. It can be one of the manifestations of a mixed variant of autonomic dysfunction or an independent form of pathology, and often requires medical and even surgical treatment. Sympathicotonia, as well as vagotonia, is not considered a disease, it is a complex symptom complex that occurs due to functional disorders of autonomic regulation, which can occur against a background of another pathology or even for no apparent reason. However, this disorder cannot be ignored, because its complications can pose a threat to the patient’s life, provoke neurosis and significantly reduce the quality of life. According to some reports, up to 80% of the population suffers from this disorder, and at least a third of them need the help of specialists. Among patients, several times more women, the symptoms are more pronounced in children, adolescents, during menopause and pregnancy.

Signs of CT are: tendency to increase blood pressure; a slight increase in body temperature to 37-37.5 degrees; feeling of heat; increased heart rate and respiration; paresthesia, constipation; decreased sweating and dry skin; eye gloss, dilated pupils, increased appetite along with weight loss, migraine, dizziness, bouts of loss of consciousness; pronounced weather sensitivity.

Sympathicotonics are characterized by emotional lability - short temper, irritability, tendency to neurosis and neurasthenia, distraction, difficulty concentrating and learning.

Treatment of CT should be comprehensive, lengthy and individually selected depending on the prevailing symptoms. Of primary importance are non-drug methods of correcting the tone of autonomic innervation. Sympathicotonia is also an endorphin-deficient state and, therefore, the use of TES is indicated in this case. To normalize the tone of the ANS of patients according to the sympathicotonic type, it is necessary to conduct transcranial electrical stimulation of the endorphin system, applied to the surface of the scalp in the forehead and behind the ears. TPP in this mode has an activity-lowering effect, normalizes blood pressure, anesthetizes, etc.

The use of TES therapy for normotonia (NT) is indicated for practically healthy people who nevertheless need some correction associated with fatigue, mild stress, insufficient recovery, or, conversely, excitement after exercise (both physical and emotional, and intellectual) or after too short sleep. In these situations, TES is prescribed with the pulse parameters indicated below, and when it is necessary to use the sedative function, TES are carried out by bipolar current pulses with a duration of 3.75 ± 0.4 ms and a repetition period of 12.9 ± 0.6 ms, and when an activating function is required TPPs conduct monopolar current pulses of a similar duration and period.

One of the important conditions for the effective use of TES-therapy is to take into account the individual characteristics and the state of the innervating and blood supply systems of the patient’s head and brain.

As you know, the innervation of all the organs of the head and brain structures is provided by the cranial nerves in the amount of 12 pairs that originate from the brain nerve tissue. One part of them performs sensitive functions, the other - motor, the third combines both. They have afferent and efferent fibers (or only one of these species), responsible for receiving or transmitting information, respectively.

The blood supply to the brain is carried out by two internal carotid arteries and two vertebral arteries. The outflow of blood occurs through two jugular veins. Near the base of the skull, the main arteries form the Willis circle, from which the arteries depart, which supply blood to the brain tissue and other areas of the head (skin, muscles, sensory organs, etc.).

Sensations under the electrodes during TES-therapy indirectly indicate the state of both of these systems and allow us to predict the effectiveness of the procedures. If there are sensations of tingling, tingling, light pressure only under the frontal electrodes or simultaneously under all the electrodes, the probability of effective procedures is higher, and the effect itself occurs faster. In the presence of these sensations, only under the behind-the-ear electrodes, the prognosis is less favorable. In this case, as a rule, it is necessary to carry out more procedures before the onset of the effect, more often various side effects occur. Therefore, in order to increase the efficiency, it is necessary to change the polarity of the signal supplied to the electrodes, achieving the sensation of the procedure only under the frontal electrodes or simultaneously under all the electrodes.

In figure 1. a block diagram of the device is presented, where: 1 is a timer, 2 is a generator, 3 is a mode switch, 4 is a PNT voltage-current converter, 5 is a switch, 6 is a sensor of RR intervals, 7 is an IVR block, 8 is a polarity button with switch, 9 - frontal electrode, 10 - behind-the-ear electrodes, 11 - activation-sedation button.

The device operates as follows. Timer 1 forms the duration of the procedure, the signal from its output controls the operation of generator 2. Generator 2 gives a signal at the first (monopolar pulses) and second (bipolar pulses) outputs connected, respectively, to the first and second input of mode switch 3. To the third and fourth the inputs of the mode 3 switch are connected, respectively, the first and second outputs of the IVR block 7, the first input of which receives a signal from the RR sensor of intervals 6, and the second input receives a signal from the activation-sedation button 11. At the first output of the IVR block 7, logical 1 if the value of the IVR is less than 1 Hz and the logical 0 if the value of the IVR is greater than or equal to 1 Hz, logical 1 is formed at the second output of the block of the IVR 7 when the value of the IIR is more than 2.5 Hz and a low level when the value of the IIR is less than or equal to 2.5 Hz. The output of the mode switch 3 receives a signal from either the first or second outputs of the generator 2, depending on the combination of signals at its third and fourth inputs: if there is a logical 1 at the third input, the signal from the first input (monopolar pulses) is transmitted to the output, there is a logical 1 on the fourth input, the signal from the second input (bipolar pulses) is transmitted to the output. With the values of the IVR within 1 ... 2.5 Hz, the state of the first and second outputs of the IVR block 7 depends on the signal of the activation-sedation button 11: when it receives a logical 1 - logical 1 appears on the first output of the IVR block 7 (unipolar pulses turn on), and with a logical 0, at the second output of the IVR 7 block (bipolar pulses will turn on). The position of the activation-sedation button 11 is set manually depending on the task of the procedure - activation or sedation. The signal in the form of voltage pulses from the output of the mode switch 3 is fed to the input of the voltage-current converter (PNT) 4, the first and second outputs of which form a current output and are connected, respectively, to the first and second inputs of switch 4, the third input of which is connected to the button polarity 8. The first and second outputs of the mode switch 5 are connected, respectively, to the frontal electrode 9 and the behind-the-ear electrodes 10 connected in parallel. The direction of current flow in the load is provided either in the forward direction - from the behind-the-ear electrodes 10 (since in this situation they perform the function of the anode) to the frontal electrode 9 (performs the function of the cathode), or in the inverse direction from the frontal electrode 9 (anode) to behind the ear electrodes 10 (cathode), and depends on the signal of the polarity button 8, which is set manually depending on the location of the patient’s sensations - it is necessary to set the polarity so that the patient experiences sensations either only in the area of the frontal electrode 9 or simultaneously on all electrodes.

The developed method and device have been successfully applied in practice.

Example 1. Patient K., 43 years old, complained of weakness, shortness of breath, chest pain, periodic dizziness, and rapid fatigue. An examination of significant pathologies did not reveal.

Using the device according to this invention, the vegetative equilibrium index IVR = 0.5 Hz was evaluated, which corresponds to the vagotonic type of ANS imbalance (vagotonia). A course of TES therapy was prescribed: 7 procedures lasting 20 minutes, which was determined by the timer settings, the stimulation mode was monopolar current pulses with a duration of 3.75 ± 0.4 ms and a repetition period of 12.9 ± 0.6 ms. At the beginning of the course, the effect was carried out in the forward direction: through the frontal (cathode) and behind the ear electrodes (anode).

After 2 sessions, the patient's condition changed slightly, IVR = 0.65 Hz. The patient clarified the localization of sensations during stimulation, she tested them exclusively on the behind-the-ear electrodes. Using the polarity button, the polarity of the electrodes connection was reversed (the anode was supplied through the frontal electrode and the cathode through the ear electrodes), after which 5 more procedures were performed. At the end of the course, the patient felt well, a significant increase in strength was noted, chest pain and dizziness were completely gone, sleep was normal. Measured IVR = 1.6 Hz, which corresponds to the norm.

Example 2. Patient N., 51 years old, complained of frequent high blood pressure, tachycardia, periodically noticed an increase in body temperature to 37-37.3 degrees without signs of infection, as well as meteosensitivity. The patient is characterized by short temper, irritability. On examination, dry skin, unnatural gloss of the eyes, dilated pupils were noted. Blood and urine tests did not reveal obvious abnormalities.

Using the device according to this invention, the vegetative equilibrium index IVR = 6.5 Hz was evaluated, which corresponds to a significant unbalance of the ANS according to the type of sympathicotonia. A course of TES-therapy was prescribed for 12 procedures of 30 minutes each with bipolar current pulses lasting 3.75 ± 0.4 ms and a repetition period of 12.9 ± 0.6 ms. The impact was carried out in the forward direction, the duration was determined by the timer, while the patient during the session felt a slight vibration only under the frontal electrode. A total of 12 sessions were conducted in two courses of 6 procedures with a break of 1 week. At the end of treatment, the patient felt good, stopped complaining of high blood pressure, became much more calm, practically stopped responding to the weather, normalized sleep, and dry skin disappeared. Measured IVR = 2.4 Hz, which corresponds to the upper limit of the norm.

Example 3. Patient D., 27 years old, an athlete, asked to help improve athletic performance, as well as increase motivation, because began to experience more fatigue after training, recover more slowly, more frequent cases of minor injuries, as well as portability of flights to competitions, which is associated with a change in time zones. According to the results of the examination, he is practically healthy, has developed musculature, pulse rate is below normal (50 beats per minute), which is not uncommon for athletes.

Using the device according to this invention, the vegetative equilibrium index IVR = 1.2 Hz was evaluated, which corresponds to the norm, however, closer to the vagotonic type. Since it was required to activate the functional state of the patient, a course of TES-therapy was prescribed for 10 sessions of 15 minutes with monopolar current pulses of 3.75 ± 0.4 ms duration and a follow-up period of 12.9 ± 0.6 ms. The exposure was carried out in the inverse direction, since in the forward direction the patient felt a slight vibration only under the behind-the-ear electrodes, the duration was set by a timer. Conducted 10 sessions in a single course, according to one procedure in 2 days. Upon completion, the patient began to endure higher loads in training, stopped complaining of poor acclimatization, and the number of injuries decreased. It is recommended to periodically repeat the courses in accordance with the training schedule. Athletic performance began to grow, as a result, he won a prize at important competitions for him. Measured IVR = 1.7 Hz, which corresponds to the norm.

Example 4. Patient O., 34 years old, office worker, with signs of excess weight. She complained of a constant feeling of hunger, fatigue, nervousness. Also noted the complaints of the authorities, because there were difficulties with the completion of transactions (as a sales manager), because there was not enough strength and patience to communicate with customers. On the whole, it seemed like a healthy, but tired, person.

Using the device according to this invention, the vegetative equilibrium index IVR = 2.2 Hz was evaluated, which corresponds to the norm, but closer to the sympathicotonic type. Since it was necessary to sedate the patient, a course of TES-therapy with bipolar current pulses of 3.75 ± 0.4 ms duration and a follow-up period of 12.9 ± 0.6 ms was prescribed. The exposure was carried out in the forward direction, the patient experienced sensations about the same under all electrodes. Conducted 5 sessions in a daily mode. As a result, the patient reported an improvement in mood and well-being, a decrease in appetite. In connection with the increase in working capacity, commercial results also increased, which affected its bonus. Measurements of the IVR showed a slight shift of the IVR = 1.9 Hz, which is normal.

Thus, the above examples show that the newly developed method of transcranial electrostimulation of endorphin brain mechanisms to normalize the ANS tone and a device for its implementation can effectively implement the task - normalization of the patient ANS tone by individualizing exposure parameters taking into account the initial state of the ANS and in accordance with the current the state of the innervation and blood supply systems of the head of each patient.

Claims (7)

1. A method of transcranial electrical stimulation of the endorphin brain mechanisms to normalize the tone of the autonomic nervous system (ANS), including contacting the current area with the pulses of the forehead and behind the ears, characterized in that they act with bipolar or monopolar current pulses of 3.75 ± 0.4 ms duration and the follow-up period of 12.9 ± 0.6 ms, in addition, before the start of the procedure, the tone of the ANS of the patient is evaluated, in particular, by calculating the index of autonomic equilibrium (IVR) according to the formula: IVR = Amo / BP, where Amo - the amplitude of the mode in relative units, BP - variational range of R-R intervals in seconds, for IVR values less than 1 Hz - vagotonia, conduct monopolar current pulses, for IVR values of 1 to 2.5 Hz - normotonies, to achieve sedation, conduct bipolar current pulses, and to achieve activation, carry out monopolar current pulses, with values above 2.5 Hz - sympathicotonia, conduct exposure to bipolar current pulses. 2. The method according to claim 1, characterized in that 1-3 minutes after the start of the procedure, if there are sensations of vibration or burning in the patient under the frontal and / or under all electrodes, stimulation is performed with the direct direction of the current, if there are sensations only behind the ears, they are changed the direction of the current is inverse, while the direct direction of the current is considered to be the presence of the anode behind the ears, and the cathode on the forehead, and the inverse direction of the current is considered the opposite. 3. A device for transcranial electrical stimulation of brain endorphin mechanisms to normalize the ANS tone, characterized by the presence of a generator, timer, voltage-current transducer (PNT), frontal and behind-the-ear electrodes, the device also includes an RR interval sensor, an index of autonomic equilibrium index of IVR, an activation-sedation button , a mode switch, a polarity button and a switch, while the timer is connected to the input of the generator, the first and second outputs of which are connected respectively to the first and second inputs of the mode switch, the third and fourth inputs of which are connected respectively to the first and second outputs of the IVR block, RR interval sensor connected to the first input of the IVR unit, to the second input of which an activation-sedation button is connected, the output of the mode switch is connected to the PNT input, the first and second outputs of which are connected respectively to the first and second inputs of the switch, the polarity button is connected to the third input of it, the first output the switch is connected to the frontal electrode, and the second output to the behind-the-ear electrodes connected in parallel.

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