RU2278701C2 - Method of putting systolic and diastolic pressure down - Google Patents

Abstract

FIELD: medicine; magnetotherapy.

SUBSTANCE: to control any influence in the cycle, EEG is preliminary registered. Average and maximal possible levels of instant values of EEG-signal are determined and average amplitude value of Θ- rhythm harmonic is calculated. Low intensity electric magnetic field sequence of pulse influence is carried out when amplitude of Θ- rhythm harmonic is frequency spectrum of EEG at frequency being lower than 7 Hz than average amplitude of rhythm harmonics. Any pulse of electric magnetic field is brought into synchronization with preset value of EEG-signal from range between average and maximal possible levels of instant values of EEG-signal. After any influence pulse is applied, digitization of EEG-signal is delayed for 142 ms. Electric magnetic field is correlated with functional condition.

EFFECT: improved efficiency of treatment.

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Description

The invention relates to medicine, namely to magnetotherapy, and can be used as physiotherapy to reduce systolic and diastolic pressure.

A known method of exposure to the vascular system of the brain by two magnetic fluxes. The exposure is carried out by a constant magnetic field from 300 to 500 Oe on the crown of the head and an alternating electromagnetic field from 35 to 45 mT on the left and right temples. The radiation sources are located at a distance of 1 cm from the irradiated surface (RF, application for invention No. 95109527, 05/10/97, A 61 N 2/04).

Closest to the proposed is a method of treating patients with arterial hypertension, according to which the frontal region is affected by a combined variable and constant magnetic field with a total induction of 40 to 45 mT for 8 to 10 minutes daily with a course of 10 to 12 days ( RF patent No. 2197295, 01/27/03, A 61 N 2/00).

A disadvantage of the known methods is the low physiology and effectiveness. This is due to the fact that the essence of the known methods consists in obtaining a response from the central nervous system (CNS) by intensive exposure to the brain with a strong EMF. The boundaries of the ranges and their values are chosen deliberately high, in order to cause a response of the central nervous system. In the known methods there is no individual approach to the selection of exposure parameters. Consequently, a decrease in the intensity and time of exposure will lead to a lack of effectiveness, since exposure to a low-intensity EMF leads to multidirectional changes in the functional state of the central nervous system, which is explained by the fact that the effect is not correlated with bioelectric activity of the brain, which is aperiodic in nature. As a result, since the effect of the field on neurons in a different functional state is different, the final result of the redistribution of neuron activity remains uncertain. All this reduces the effectiveness and physiology of the methods. In addition, the effect formed in the known methods is not only responsive to the required areas of the cerebral cortex, but also those that are not involved in the process of pressure formation in the vessels of the brain. The inability to form a directed exposure, as well as the lack of an individual approach to the selection of exposure parameters, which lengthens the time required to obtain the desired result of exposure and increases the dose of electromagnetic radiation. It also reduces the physiological and effectiveness of the methods.

Thus, the methods of lowering systolic and diastolic pressure revealed by a patent search during implementation do not provide the achievement of a technical result consisting in increasing physiological and efficiency.

The present invention solves the problem of creating a method of lowering systolic and diastolic pressure, the implementation of which allows to achieve a technical result, which consists in increasing physiology and efficiency.

The essence of the invention lies in the fact that in the method of lowering systolic and diastolic pressure by applying an electromagnetic field to the brain, several controlled cycles of exposure by a sequence of pulses of low-intensity EMF are used to obtain the effect, while EEG is pre-recorded to regulate each exposure in the cycle, the average and the maximum possible levels of instantaneous values of the EEG signal, calculate the harmonics of the θ rhythm and the average amplitude value of the harmonics of the θ rhythm and, in this case, in each cycle, the action of a sequence of pulses of low-intensity EMF is turned on when the amplitude of the θ rhythm with a frequency of 7 Hz is lower than the average amplitude of the rhythm harmonics in the EEG frequency spectrum, and during the action, the appearance of each pulse of the EMF is synchronized with the specified value of the EEG- signal from the range between the average and maximum possible levels of instantaneous values of the EEG signal, and after each exposure pulse, the digitization of the EEG signal is delayed by 142 ms.

The technical result is achieved as follows. As shown above, the bioelectric activity of the brain is aperiodic. Therefore, the effect of EMF uncorrelated with the biological activity of the brain leads to multidirectional and unpredictable changes in the functional state of the central nervous system. It is known that the functional state of the central nervous system is characterized by both the prevailing frequency spectrum and a certain amplitude range of the EEG signal (Kratin Yu.G., Guselnikov V.I. “Technique and technique of electroencelography, L .: Nauka, 1971, p.15, 157) . In the proposed method, preliminary registration of the electroencephalogram (EEG) allows you to record the functional state of the central nervous system before exposure. To do this, determine the average and maximum possible levels of instantaneous values of the EEG signal, calculate the harmonics of the θ rhythm and the average amplitude of the harmonics of the θ rhythm.

The binding of the temporal characteristics of the action to the characteristics of the frequency spectrum of the θ rhythm is explained as follows. The θ rhythm is the second, after the alpha rhythm, rhythm playing the role of the “functional core”. The θ rhythm plays an essential role in the mechanisms of intracenter regulation and, presumably, its functional significance is enhanced in cases of pathological disorders when the regulatory role of the alpha rhythm for some reason is unsound. For subcortical structures, which are more inert, the θ rhythm apparently plays the same role as the alpha rhythm for the cortex, i.e. It is a regulator that provides alternate opening and closing of nerve cells for information flows. There is evidence of the synchronizing role of the θ rhythm, contributing to the establishment of communication between individual brain structures. The θ rhythm is closely connected with the mechanisms of regulation of subcortical structures (primarily, structures of the limbic system and hypothalamus), which ensure the regulation of emotional reactions, the tone of the autonomic nervous system, and the central mechanisms of regulation of the activity of the cardiovascular system. There is evidence that the individual frequency components of the EEG are those rhythmic regulators that provide coordination of intracenter relationships. This also applies to individual frequency leaving θ rhythms. The presence on the EEG of a hypersynchronized rhythm with a frequency of 7 Hz in the projection zone of non-specific thalamic systems (in the central frontal areas) is prognostically favorable for the subsequent formation of an alpha rhythm in patients in a coma after neurosurgical operations, and the occurrence of low-frequency θ activity (5 Hz ), which extends to all parts of the cortex, is, on the contrary, a prognostically unfavorable sign, indicating that phylogenetically older brain systems involve tm, electrical activity of the whole brain (“Mechanisms of the activity of the human brain”, part 1, Neurophysiology of man. L .: Nauka, 1988, pp. 474-484; ibid., Chapter 3; “Biopotentials of the human brain” under the editorship of academician Rusinova BC, Moscow: Medicine, 1987, p. 169-191).

It follows from the foregoing that the use of controlled action by EMF pulses, the temporal parameters of which are tied to the θ rhythm, provide integrative systemic changes in the functioning of subcortical structures, which are also responsible for the tone of the neurons of the vasomotor center. This increases the physiological and efficiency of the method.

The choice of the moment of switching on for the impact of the low-intensity EMF characteristics of the frequency range of the θ rhythm spectrum forms a directional effect on the central nervous system, namely: they allow one to obtain adaptive changes in the total bioelectric activity (EEG) associated with a change in the functional activity of subcortical structures. This leads, in particular, to the normalization of mean arterial pressure (lowering of systolic and diastolic pressure). In other words, the central nervous system forms the body’s adaptive response to the effect, but, unlike the prototype, in the proposed method, the body’s adaptation to the effect is used for directed adaptive biocontrol of the body, which eliminates the negative impact of the body’s adaptation on the treatment process. As a result, both the physiological nature of the method and the efficiency are increased. In addition, since the proposed method each time uses an individual EEG, this eliminates the formation of the central nervous system of the adaptive reaction of the body to the average exposure conditions and conditions, in contrast to the prototype, which also increases the physiology and effectiveness of the claimed method.

The impact of low-intensity EMF does not, in contrast to the prototype, impact on the central nervous system, and acts gently, which makes the adaptive reaction of the body to the exposure more physiological and increases the efficiency of the method. The use of low-intensity EMF for exposure to pulses allows one to minimize the duration of the interaction of the body with the electromagnetic field, which increases the physiology and effectiveness of the claimed method.

At the moments of the action of the EMF pulse, a tip occurs. Therefore, after the action of the pulse, the EEG signal is recorded after a time sufficient to level the arising pickups, which increases the efficiency of the method. In the claimed method, the duration of the delay time of the registration of the EEG signal after exposure is 142 ms. In addition, the recording delay time of 142 ms is the period of the θ-rhythm harmonic with a frequency of 7 Hz.

The use in the proposed method of several adjustable cycles of exposure by a pulse sequence of low-intensity EMF increases the efficiency of the method. Due to the fact that in the proposed method for regulating each effect in the cycle, the EEG is pre-recorded, the average and maximum possible levels of instantaneous values of the EEG signal are determined, the harmonics of the θ rhythm and the average amplitude of the harmonics of the θ rhythm are calculated, an individual approach to each patient is provided, which reduces the likelihood of an adaptive reaction of the body to exposure, increases the physiological nature of the method, and therefore increases the efficiency. Due to the fact that, in each cycle, the exposure is switched on by a sequence of pulses of low-intensity EMF, when the harmonic amplitude of the θ rhythm with a frequency of 7 Hz is lower than the average amplitude of the rhythm harmonics in the EEG frequency spectrum, and during the action, the appearance of each exposure pulse is synchronized with the specified value of the EEG signal from the range between the average and maximum possible levels of instantaneous values of the EEG signal, the formation of a directed effect on the central nervous system is provided, which leads to the formation of edney compensatory changes that lead to a decrease in systolic and diastolic blood pressure. At the same time, the choice in the cycle of the moment of switching on the action by a sequence of pulses of low-intensity EMF and the time of appearance of each pulse of the effect takes into account the nature of the patient's electroencephalogram, takes into account the functional state of the central nervous system, which allows you to use the property of adapting the body to external influences for directed adaptive biocontrol of the functional state of the body, increases the physiology and effectiveness of the claimed method.

Thus, the claimed method of lowering systolic and diastolic pressure during the implementation ensures the achievement of a technical result, which consists in increasing the physiological and efficiency.

A method of lowering systolic and diastolic pressure is as follows. The brain is affected by an electromagnetic field. To obtain the effect, several controlled cycles of exposure by a sequence of pulses of low-intensity EMF are used. To control each effect, the EEG, the average and maximum possible levels of the instantaneous values of the EEG signal are pre-recorded in the cycle, the harmonics of the θ rhythm and the average amplitude value of the harmonics of the θ rhythm are calculated. Moreover, in each cycle, the action of a sequence of pulses of low-intensity EMF is turned on when the amplitude of the θ rhythm with a frequency of 7 Hz is lower than the average amplitude of the rhythm harmonics in the EEG frequency spectrum, and during the action, the appearance of each exposure pulse is synchronized with the specified value of the EEG signal from the range between the average and maximum possible levels of instantaneous values of the EEG signal. In this case, after each exposure pulse, the digitization of the EEG signal is delayed by 142 ms.

The method can be implemented, for example, using the device described in patent No. 2089240, A 61 N 2/04, 01/28/91. "A method for regulating the functional state of the central nervous system in the sleep-wake cycle and a device for its implementation." The device contains electrodes for biopotential removal connected in series, a biopotential amplifier (UB), an analog-to-digital converter (ADC), a comparator, a pulse generator control unit (BU), a pulse generator (GI), an electromagnetic field inductor (IMP). In addition, the device contains a personal computer (PC) connected to the controlled input of the comparator and the output of the ADC.

The device allows you to determine the functional state of the central nervous system by conducting a PC spectral and amplitude analysis of the digitized section of the EEG and then automatically decide to turn on - not turn on the exposure. When deciding to “turn on” the PC sets the comparator operation mode for controlling the exposure: sets the comparator response threshold (the set value of the EEG signal from the range between the average and maximum possible levels of the instantaneous values of the EEG signal), after each exposure pulse, it delays the digitization of the EEG signal by 142 ms

The signal delay, on the one hand, levels the pickup arising from the EMF pulse, and, on the other hand, sets the minimum possible period between two EMF pulses during exposure. The number of pulses during each exposure in the cycle depends on the above conditions, current bioelectric activity during exposure, exposure duration. The duration of each exposure from the sequence of EMF pulses in the presented examples corresponded to the unsteadiness of the EEG signal and amounted to 10 s. This time is sufficient to change the nature of the total bioelectric activity (EEG).

In this case, the EMF intensity was 170 A / m, and the pulse duration was 1 ms. A pulse duration of 1 ms was optimal at a given EMF intensity based on minimizing the time of interaction with the EMF of the irradiated brain.

The device operates as follows. In the identification mode of the functional state of the PC, the comparator turns off or sets a threshold on it that exceeds the specified one. This leads to disabling exposure to EMF pulses. In this mode, the signal from the electrodes for removing the biopotential is supplied to the UB and then to the ADC. The digitized signal from the ADC is fed to a PC, which performs spectral and amplitude analysis, determines the functional state of the central nervous system and decides whether or not to enable exposure to EMF pulses. When deciding to turn on the impact of a personal computer, it sets the operation mode of the device: the threshold of the comparator is equal to the specified threshold (from the range between the average and maximum possible levels of instantaneous values of the EEG signal); the delay time of the comparator after operation (after each exposure pulse, the digitization of the EEG signal is delayed by 142 ms); in each cycle - the moment of exposure to a sequence of pulses of low-intensity EMF (when the amplitude of the θ rhythm with a frequency of 7 Hz is lower than the average amplitude of the harmonics of the rhythm in the EEG frequency spectrum); exposure time in a cycle of 10 s.

After that, the device goes into controlled exposure mode. PC conducts amplitude and spectral analysis of the EEG. It determines the moment the action is turned on (when the harmonic amplitude of the θ rhythm with a frequency of 7 Hz is lower than the average amplitude of the harmonic of the rhythm in the EEG frequency spectrum) and when the threshold of the comparator reaches a predetermined level (it is in the range between the average and maximum possible levels of instantaneous values of the EEG signal), forms a signal at its control input. As a result, in each cycle during exposure, the appearance of each exposure pulse is synchronized with a given value of the EEG signal from the range between the average and maximum possible levels of instantaneous values of the EEG signal. The comparator is triggered and sends a signal to the control unit, which supplies a control signal to the GI. The latter delivers a current pulse to the IMF, which leads to the appearance of an EMF pulse in space with a biological object. After the comparator is triggered, the PC disables it for the delay time. At the end of the delay time, the PC again sets the set threshold on the comparator to determine the moment of synchronization with the EEG of the next EMF pulse, etc. After the exposure time, the PC disables the comparator, again analyzes the digitized signal to determine the functional state of the central nervous system and forms the next cycle of exposure by a pulse train of low-intensity EMF.

The patient was seated on a chair. A radiation source was installed over the patient’s crown at a distance that ensured an EMF intensity of 170 A / m. To register the EEG used the left central lead. The reference electrode was placed on the mastoid (bone behind the ear).

The method was used to normalize pressure in 12 patients. The research results are summarized in table.

Table 1 No. Before exposure After exposure SD / DD mmHg Average pressure DD + 0.42 (SD-DD) SD / DD mmHg Medium pressure one 119/80 96.4 110/75 84.7 2 160/110 131 148/110 126 3 100/80 88.4 90/70 78,4 four 140/100 116.8 130/95 109.7 5 130/70 95.2 110/65 83.9 6 125/80 98.9 115/75 91.8 7 145/105 121.8 135/95 111.8 8 105/70 84.7 95/60 74.7 9 150/100 121 145/100 118.9 10 150/100 121 140/95 113.9 eleven 145/100 119 135/98 113.5 12 160/105 128 145/95 116

Thus, a reliable decrease follows from the table: systolic - P <0.01 (12 out of 12), diastolic - P <0.05 (10 out of 12) and average - P <0.01 (12 out of 12) blood pressure.

In the control: 17 experiments were conducted with a mismatch either in the time of switching on the effect or the time of delay. In 9 cases there is no change in pressure, in 5 cases - a slight increase and only in 3 cases - a slight decrease in pressure.

Claims (1)

A method of lowering systolic and diastolic pressure by exposure to the brain by an electromagnetic field, characterized in that the EEG is pre-recorded in the cycle to regulate each exposure, the average and maximum possible levels of instantaneous values of the EEG signal are determined, and the average amplitude value of the harmonics of the θ rhythm is calculated, of this action by a sequence of pulses of low-intensity EMF is carried out when the harmonic amplitude of the θ rhythm with a frequency of 7 Hz is lower than the average a in the EEG frequency spectrum plitudy rhythm harmonics; in this case, each EMF pulse is synchronized with a predetermined value of the EEG signal from the range between the average and maximum possible levels of instantaneous values of the EEG signal, and after each exposure pulse, the digitization of the EEG signal is delayed by 142 ms.