RU2757080C2 - Device for influencing patient's circulatory system with electromagnetic field and corresponding method - Google Patents

Abstract

FIELD: medical equipment.

SUBSTANCE: group of inventions relates to medical equipment, a device for influencing the patient’s circulatory system with an electromagnetic field and a corresponding method. The device for influencing the patient’s circulatory system with an alternating electromagnetic field contains means of influencing the patient's circulatory system with the alternating electromagnetic field, a control unit made with the possibility to control the operation of the specified device, wherein the control unit contains software tools that provide the possibility to supply control commands to create the alternating electromagnetic field on a predetermined part of a patient’s body using means of influencing with the alternating electromagnetic field, as well as provide the possibility of processing the results of such an influence. The device also contains a measuring unit capable of measuring physiological parameters of the patient’s cardiovascular system, a displaying unit made with the possibility of displaying measured and calculated physiological parameters of the patient’s cardiovascular system. The alternating electromagnetic field, which influences the patient’s circulatory system, is characterized by an amplitude of magnetic induction, which ranges from 0.04 MT to 0.06 MT, and a frequency that ranges from 700 Hz to 900 Hz.

EFFECT: specified device provides an increase in endothelial function under the influence of the alternating electromagnetic field.

21 cl, 15 dwg

Description

FIELD OF TECHNOLOGY

The present invention relates to a device for physiotherapeutic exposure to an ultra-low intensity alternating electromagnetic field on endothelial function as an element of the human cardiovascular system (CVS), and to assess the effect of such exposure in the treatment of cardiovascular diseases and vascular complications. More specifically, the present invention relates to a device for applying an electromagnetic field to a circulatory system of a patient and a corresponding method.

LEVEL OF TECHNOLOGY

Cardiovascular diseases (CVD) and type 2 diabetes mellitus are widespread in the world and in Russia. So, according to the federal service of state "statistics of the Ministry of Health of the Russian Federation for September 24, 2018 [1], about 2.5 million patients with socially significant diseases were registered (type 2 diabetes mellitus, hypotension, hypertension, etc.). About 55% of them have diseases "characterized by high blood pressure", and about 14% - diabetes mellitus.The progression of CVD is directly related to the state of the endothelium - a monolayer of cells lining the inner surface of blood and lymphatic vessels, as well as heart cavities. important functions of endothelial cells is the release of nitric oxide, which is extremely important for the functioning of the body, the so-called intercellular “messenger.” Nitric oxide (NO) affects the relaxation of vascular smooth muscles, in other words, regulates vascular tone, and, consequently, blood pressure. Ferchgott, L. Ignarro and F. Muradu in 1998 Nobel Prize in Physiology or Medicine for the discovery of With the understanding of the role of nitric oxide as a signaling molecule in the cardiovascular system [2], it became clear that one of the causes of arterial hypertension and other cardiovascular diseases is endothelial dysfunction. In addition, the endothelium regulates programmed cell death and proliferation, plays an important role in the secretory and reproductive system, as well as in the processes of vasoconstriction and vasodilation, regulation of components (thrombin, fibrin) of blood coagulation, angiogenesis, the process of formation of new blood vessels, which ensures tissue growth. and speeds up the healing process.

From the point of view of human physiology, the indicators characterizing the functioning of the CVS are: the speed of propagation of the pulse wave (PWV), blood pressure (BP), heart rate (HR), endothelial function (EF).

The pulse wave is a compression-extension wave propagating through the arteries, caused by the ejection of blood from the left ventricle of the heart during systole, i.e. the state of the heart muscle during the period of contraction, when the left and right ventricles of the heart contract [3]. Thus, PWV in the physical sense is the speed of propagation of a longitudinal wave propagating through the arteries after a cardiac contraction. The value of PWV is a reliable indicator of vascular stiffness [4]. Evaluation of vascular stiffness by determining SRVP allows diagnosing arterial lesions at the preclinical stage, identifying groups of people with high cardiovascular risk [4].

Blood pressure in the physical sense is the difference between the pressure of the blood in the circulatory system and the pressure of the atmosphere. BP is an important physiological parameter of the human body. For example, persistent low (90 mm Hg and 60 mm Hg), as well as high (140 mm Hg and 90 mm Hg) blood pressure may be a symptom of any CVD (for example, arterial hypotension / hypertension) [5].

The resting heart rate in a healthy adult is 60-80 beats per minute. An overly frequent contraction of the heart, as well as a slow one, can be a symptom of various diseases. Thus, heart rate is the most important physiological sign of human health.

In the present invention, the ability of endothelial cells to release nitric oxide is called endothelial function.

Laurent и соавт. (2001) [14] выявили прямую зависимость между уровнем плотности артерий и смертностью от сердечно-сосудистой патологии. При ишемической болезни сердца (ИБС) и АГ происходит увеличение жесткости стенок артерий [15]. Ряд исследователей рассматривает увеличение СРПВ как признак субклинического коронарного атеросклероза и считает обоснованным использовать этот признак как независимый фактор риска ИБС, обнаружение которого особенно важно для пациентов, у которых заболевание протекает бессимптомно [3, 16-19].As indicated above, endothelial dysfunction is characterized by impaired NO synthesis or an increase in its destruction. Possible negative consequences of this process are vasoconstriction, platelet aggregation, leukocyte adhesion and smooth muscle cell proliferation [5-7]. As a result, the blood supply of both individual organs and the whole organism decreases, as a result, there are lesions of target organs [2, 8, 9]. A number of authors [10-13] point to EF as an early indicator of both vascular and renal pathology. Studying a large cohort of outpatients with arterial hypertension (AH), which was followed up for 16 years,

Laurent et al. (2001) [14] found a direct relationship between the level of arterial density and mortality from cardiovascular pathology. In ischemic heart disease (IHD) and hypertension, the stiffness of the arterial walls increases [15]. A number of researchers consider an increase in PWV as a sign of subclinical coronary atherosclerosis and consider it reasonable to use this sign as an independent risk factor for coronary artery disease, the detection of which is especially important for patients in whom the disease is asymptomatic [3, 16-19].

In our country, serious research in the field of magnetic field application in medicine was organized at the Perm Institute in the 30s and 40s. To date, sufficiently convincing factual material has been accumulated, indicating that constant, variable, pulsating, rotating and running magnetic fields have an anti-inflammatory antispasmodic, analgesic, hypotensive, hypocoagulating anti-edema effect, actively affect the metabolism and regeneration processes of injured tissues.

RU 160335 U1 discloses a method of exposure to low-intensity electromagnetic radiation of extremely high frequency, as well as an assessment of the functional activity of the microvascular endothelium. The known method of exposure to low-intensity millimeter radiation helps to increase the parameters of the functional activity of the endothelium.

US 7,089,060 B1 discloses a method for activating a vascular endothelial growth factor (VEGF) receptor in one or more cells, comprising positioning a pulsed electromagnetic field generator near the VEGF receptor so that the electromagnetic field generated by the electromagnetic field generator will pass through the VEGF receptor to activate it. In this case, the generated electromagnetic field has a fluctuation rate that activates the VEGF receptor. The known method reverses the process of osteoporosis and stimulates the healing of fractures caused by osteoporosis, and also increases the rate of healing of other bone fractures and for the fusion of the vertebrae.

US 2009018613 A1 discloses methods and devices for regulating the expression of the vascular endothelial growth factor (VEGF) protein gene in endothelial cells of various target tissues through capacitive coupling or inductive coupling, carried out, for example, using coils generating an electric and / or electromagnetic field, located relative to target cells, specific and selective signals with the cells of these tissues in such a way that the generated field affects diseased or damaged tissues. Known methods and devices provide an increase in the expression of vascular endothelial growth factor in endothelial cells, which contributes to the targeted treatment of peripheral vascular diseases, cardiovascular diseases, wound healing, healing of tendons and ligaments, preventing the growth or spread of tumors and other conditions in which the protein may be involved VEGF.

RU 179371 U1 discloses a vest for diagnostics and complex treatment by exposing a patient to low-intensity electromagnetic radiation in cardiovascular diseases. The vest contains a signal measuring unit and electrodes. The corset part of the vest in the first layer can additionally have openings for wireless sensors, such as photoplesmitograms, temperature sensors, etc. If necessary, an electromagnetic inductor can be attached to the electrode. The vest provides the possibility of a reverse effect on the patient with low-intensity electromagnetic radiation through the electrodes identified during the diagnostic study. The disadvantage of the known useful model is the limited therapeutic effect, the possibility of application on a specific part of the body.

RU 157740 U1 discloses a device for diagnosing and evaluating the treatment of cardiovascular diseases and, if necessary, correcting it, while simultaneously examining photoplethysmography and electrocardiography. In parallel with the treatment carried out with low-intensity electromagnetic fields with an individual algorithm, it is possible to assess the state of endothelial function. The complex of treatment programs includes frequency spectra from 1 to 100 Hz.

RU 2656560 discloses a method for assessing the risk of cardiovascular complications in a patient with combined pathology, according to which the current parameters of the disease being evaluated in the patient and similar previously obtained parameters in healthy volunteers are recorded. For the diagnosed type of disease, the weighting coefficients for each parameter are preliminarily determined using the known average values of the parameters in patients with this disease and the average values of the same parameters of healthy volunteers. RU 2508904 discloses a method for assessing the risk of cardiovascular complications, in which the size of the perivascular zone, the diameters of the venous and arterial parts of the capillaries, the speed of propagation of the pulse wave and the value of endothelial function on the upper limb are determined synchronously with the R peak of the electrocardiogram using the method of optical capillaroscopy of the eponychium of the hand, blood pressure is measured and the K index of the risk of cardiovascular complications is calculated using a mathematical formula.

The disadvantage of all the described devices and methods is that their use allows the treatment of CVD only after their diagnosis, as well as the lack of methods of exposure that provide a significant increase in endothelial function.

In addition, none of the above prior art sources discloses a device for conducting electromagnetic effects on the human circulatory system, which also includes a device for monitoring the results of such exposure, which provides a significant increase in endothelial function to improve the overall therapeutic state.

Thus, there is a need to provide new devices for the therapeutic effect on human CVS. In particular, it is preferable to create devices for carrying out electromagnetic action on the human circulatory system, also including a device for monitoring the results of such action, providing a significant increase in endothelial function, with its rapid and efficient calculation.

DISCLOSURE OF THE INVENTION

The present invention proposes a device for influencing an alternating electromagnetic field on a patient's circulatory system, comprising means of influencing an alternating electromagnetic field on the patient's circulatory system, a control unit configured to control the operation of said device for effecting an electromagnetic field, the control unit comprising software means, providing the ability to send control commands to create an alternating electromagnetic field on a predetermined part of the patient's body by means of exposure to an alternating electromagnetic field, as well as providing the ability to process the results of such exposure; a power supply unit made with the possibility of providing autonomous operation of the specified device or with the possibility of ensuring its operation from the AC mains; a measuring unit configured to measure physiological parameters of the patient's cardiovascular system, such as pulse wave amplitude, pulse wave propagation time, heart rate, blood pressure; a computing unit configured to calculate the speed of propagation of the pulse wave, endothelial function; a display unit configured to display measured and calculated physiological parameters of the patient's cardiovascular system; characterized in that the alternating electromagnetic field, which affects the patient's circulatory system, is characterized by an amplitude of magnetic induction, which ranges from 0.04 mT to 0.06 mT, and a frequency that ranges from 700 Hz to 900 Hz, and the specified device provides an increase endothelial function under the influence of an alternating electromagnetic field.

In one preferred embodiment, the device further comprises an input unit adapted to input data about the patient, in particular the height, weight and age of the patient.

In one preferred embodiment, the means for creating an alternating electromagnetic field are configured to be positioned around the patient's body at a certain distance.

In one preferred embodiment, the means for generating an alternating electromagnetic field are configured to be located in close proximity to the patient's body.

In one preferred embodiment, the device further comprises a memory in which a database is stored for storing measured and calculated physiological parameters of the patient's cardiovascular system.

In one preferred embodiment, the means for acting on the patient's circulatory system with an alternating electromagnetic field comprises a solenoid configured to generate an alternating electromagnetic field upon receipt of a command from a control unit. The amplitude of the magnetic induction is measured at the geometric center of the solenoid.

In another preferred embodiment, the measuring unit of the device contains a plurality of sensors configured to be placed on a predetermined part of the patient's body and in communication with the measuring unit to measure the physiological parameters of the patient's cardiovascular system based on vibrations of the artery walls caused by the passage of the pulse wave.

In yet another preferred embodiment, the measuring unit is also configured to measure physiological parameters of the patient's cardiovascular system in the absence of an electromagnetic field.

In yet another preferred embodiment, the device further comprises a communication interface capable of wired or wireless communication with the computing device for transmitting the calculated parameters to the computing device for subsequent processing.

In yet another preferred embodiment, the device further comprises a compressor to provide a pressure to compress the patient's blood vessels and exceed the patient's systolic pressure by 30-40 mm Hg. Art.

In yet another preferred embodiment, the computing unit calculates endothelial function as the ratio of the pulse wave amplitudes after and before clamping.

In yet another preferred embodiment, the preferred exposure time to the alternating electromagnetic field is 60 minutes.

In another preferred embodiment, the computing unit of the device further comprises a plurality of built-in programs for therapeutic exposure to an electromagnetic field, the control unit being configured to adjust the duration and frequency of exposure in accordance with the selected program.

In addition, the present invention provides a method of influencing an alternating electromagnetic field on the circulatory system of a patient, according to which an alternating electromagnetic field is generated by means of creating an alternating electromagnetic field; measuring the physiological parameters of the patient's cardiovascular system, such as the amplitude of the pulse wave, the propagation time of the pulse wave, heart rate, blood pressure; calculate the speed of propagation of the pulse wave and endothelial function; display the results of calculations using a display unit, and the alternating electromagnetic field, which acts on the patient's circulatory system, is characterized by the amplitude of the magnetic induction, which is from 0.04 mT to 0.06 mT, and the frequency, which is from 700 Hz to 900 Hz.

In one preferred embodiment, the measurement of the physiological parameters of the patient's cardiovascular system is also performed prior to generating an alternating electromagnetic field.

In yet another preferred embodiment, the preferred exposure time to the alternating electromagnetic field is 60 minutes.

In another preferred embodiment, the patient's blood vessels are clamped at a pressure 30-40 mm Hg higher than the patient's systolic pressure.

In yet another preferred embodiment, endothelial function is calculated as the ratio of the pulse wave amplitudes after and before clamping.

In yet another preferred embodiment, the method further comprises, concurrently with calculating endothelial function, determining a change in pulse wave velocity before and after clamping.

In yet another preferred embodiment, the method further comprises adjusting the duration and frequency of exposure in accordance with the selected program of therapeutic exposure to the electromagnetic field.

In yet another preferred embodiment, the method further comprises entering data about the patient, in particular the height, weight and age of the patient,

The proposed device and method are safe for medical use, since they do not affect such important characteristics of the cardiovascular system as pulse rate, systolic and diastolic pressure. Thus, the present invention provides a positive effect of the action of an alternating electromagnetic field on EF, which is useful in the provision of medical care to people with diseases characterized by endothelial dysfunction, typical for ischemic heart disease, type 2 diabetes mellitus, postinfarction cardiosclerosis and other cardiovascular diseases.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram of a device for applying an electromagnetic field to a circulatory system of a patient in accordance with one embodiment of the present invention.

FIG. 2 shows a sequence diagram of a study with five identical sequential measurement sessions.

FIG. 3 shows a graph of the dependence of the magnetic induction (mT) in the geometric center of the solenoid on the frequency (Hz) at a fixed voltage (V).

FIG. 4 shows a graph of changes in endothelial function (EF) on the shoulder, finger, wrist, depending on the amplitude of the magnetic field induction B (mT).

FIG. 5 shows a graph of changes in endothelial function (EF) on the shoulder, finger, wrist, depending on the frequency N (Hz) of the electromagnetic field.

FIG. 6 is a graph showing heart rate versus time.

FIG. 7 and 8 show diagrams of normalized systolic and diastolic pressure versus time.

FIG. 9 is a graph showing normalized endothelial function versus time for shoulder measurement.

FIG. 10 is a graph showing normalized endothelial function versus time for measurement at the wrist.

FIG. 11 is a graph showing normalized endothelial function versus time for finger measurements.

FIG. 12 shows a screenshot of the results of calculating the p-parameter by the Wilcoxon test.

FIG. 13 is a graph showing normalized pulse wave velocity versus time for shoulder measurements.

FIG. 14 is a graph showing normalized pulse wave velocity versus time for a wrist measurement.

FIG. 15 is a graph showing normalized pulse wave velocity versus time for finger measurements.

CARRYING OUT THE INVENTION

FIG. 1 schematically shows a device 100 for applying an electromagnetic field to a patient's circulatory system. The device 100 generally comprises a patient input unit 110, a control unit 120, a power supply unit 130, a measurement unit 140, a computing unit 150 displaying unit 160, and a database 170. The device may also include a communication interface 180 configured to implement a wired or wireless communication with a computing device for transmitting the calculated parameters to the computing device for their subsequent processing. The device 100 also contains means for influencing an alternating electromagnetic field on the patient's circulatory system (not shown in Fig. 1), which, for example, contain at least one solenoid and cuffs, and can be located around the patient's body at some distance or in close proximity to the patient's body.

Other modifications and additions that may be made to the present device will be apparent to those skilled in the art. For example, in the present invention, without limitation, changes and modifications can be made by including in the device such additional elements as a digital signal converter, a switch, a program selector, memory devices, and the like, which are also included in the protection scope of the present invention.

The device 100 operates as follows. In the data entry unit 110, information about the patient, such as height, weight, and the like, is inputted as necessary. The computing unit 150 calculates the distance (L) between the sensor cuffs for placement on a given part of the patient's body. Further, on a given part of the patient's body, cuffs with sensors are placed at a predetermined distance (L) and a solenoid so as not to create discomfort. The sensor cuffs are configured to be coupled to the device 100 by any means known in the art. The sensors pick up the vibrations of the artery walls, and using the measuring unit 140 measure the amplitude of the pulse wave (PW) on a given part of the patient's body, as well as the time of the PW propagation. Measurement of blood pressure is carried out simultaneously using the oscillometric method and the Korotkov method. Next, the computing unit 150 calculates the PWR based on the obtained data on the time of the PT propagation and the distance between the cuffs located on a given part of the body, as the ratio L / Δt. The software of the device 100 allows to automatically calculate the SRVP, at least 2 consecutive measurements are carried out with automatic calculation of the average value.

To determine endothelial function using the computing unit 150, a clamp test is used in one of the cuffs. In one of the cuffs, imposed on a given part of the patient's body, after recording the amplitudes of the pulse waves for 27-40 seconds before clamping, a pressure is created and held for 3 minutes, exceeding the systolic pressure of the subject by 30-40 mm Hg. At the end of hyperemia, repeated measurements of the amplitudes of the pulse waves on the arteries of the clamped part of the body are carried out using sensors and the measuring unit 140. Then the computing unit 150 calculates the endothelial function as the ratio of the values of the amplitudes of the pulse waves after and before clamping:

EF = (A / A0-1) * 100%,

where A0 is the PV amplitude before clamping, A is the PV amplitude after clamping. Simultaneously with the determination of the EF, the change in the speed of propagation of pulse waves at the locations of the cuffs before and after three-minute clamping is determined: ASRPV = (V / V0-1) * 100%, where V0 is the speed of the pulse wave before clamping, V is the PT velocity after clamping.

To level the consequences of compression of the cuffs, pause for 3 minutes.

Three minutes after the determination of the EF, a double measurement of the systolic and diastolic blood pressure is performed using the oscillometric method and the Korotkov method. At the same time, the heart rate is measured.

All measurements and calculations are carried out automatically using the measuring unit 140 and the computing unit 150 and are stored in the database 170 in the memory of the device 100.

Further, upon a command from the control unit 120, an alternating electromagnetic field is generated using a solenoid. Within 1 hour, the solenoid creates an electromagnetic field with an amplitude of B ₀ = 0.01-0.15 mT and a frequency of 400-1600 Hz.

The next three sessions of measurements are made after the start of the exposure to the electromagnetic field, the total duration of which is 60 minutes. During this time, with an interval of 20 minutes, 3 measurements of the same type of the above parameters of the CVS are carried out using the device in accordance with the present invention.

Each session of measurements using the device in accordance with the present invention includes the same type of sequential operations performed in automatic mode:

1) Double measurement of the pulse wave velocity (PWV).

2) Measurement of endothelial function (EF).

3) Double measurement of blood pressure (BP)

FIG. 2 shows the sequence of measurement steps, where T1 is the period of adaptation of the patient to the room temperature regime, T2 is the first exposure period, T3 is the second exposure period, T4 is the third exposure period, T5 is the pause before the last measurement, the field exposure is disabled.

After completing the study of PWV and EF for each measurement session, the device 100, using the display unit 160, shows the values of PWV, EF, ARPV, calculated using the computing unit 150, as well as the measured heart rate (HR) and blood pressure.

The device 100 in accordance with the present invention provides fast and convenient reading of the results of measurements and calculations by the attending physician, low labor intensity during the therapeutic effect, and a significant increase in EF. In addition, the device in accordance with the present invention allows treatment and therapeutic effects without removing clothing, ointments, plaster and other dressings, wet or dry, since the electromagnetic field freely penetrates through them. In addition, exposure to an alternating electromagnetic field with an amplitude of 0.04 mT to 0.06 mT and a frequency of 700 Hz to 900 Hz slightly differs from the natural level of the Earth's magnetic field, which means it is familiar to humans and is well tolerated.

Experiments carried out by the inventors of the present invention are described below.

EXPERIMENTS

To assess the effect on endothelial function under the influence of an ultra-low intensity electromagnetic field, a number of experiments were carried out in which 30 volunteer volunteers took part, among them 6 women, aged 20 to 25 years and 24 men, aged 18 to 77 years. conditionally healthy, without chronic diseases, including cardiovascular pathologies. The average age of the subjects was 30 years.

On the eve of the study, subjects were asked to refrain from smoking and drinking caffeinated beverages. Before starting the study, participants in the experiment rested in a sitting position for 15-20 minutes in a room at room temperature (22-24 ° C).

Before the study, the participants were informed about the purpose, content, benefits and safety of the experiment, after which the subject signed an informed consent to participate in the experiment. Each subject signed an informed consent; he also had the opportunity to terminate his participation in the experiment at any time. Persons with signs of cardiovascular diseases, disturbances in the functioning of internal organs, the central nervous system, and infectious diseases were not allowed to the experiment.

Research methods

All methods are non-invasive, do not create pain, temperature or mechanical effects.

The safety of exposure to medical personnel and the subject does not exceed sanitary standards and is confirmed on the basis of the following:

1) In accordance with the document regulating the rules for working with a magnetic field, developed at Cornell University, USA (Ithaca, NY): “Magnetic field safety guide. Environmental health and Safety ”([8], Appendix 1), at a magnetic field frequency from 300 Hz to 30 kHz, the maximum allowable field amplitude for general and local exposure is 0.2 mT. According to the present invention, the maximum amplitude of the electromagnetic field generated by the solenoid is limited to 0.15 mT. More specifically, the generated electromagnetic field applied to the patient has an amplitude of 0.04 mT to 0.06 mT and a frequency of 700 Hz to 900 Hz.

2) The ratio of the frequency and amplitude of the electromagnetic field used in the experiment satisfies the Brezovich criterion, defined as the product of the amplitude of the magnetic induction by the frequency of the magnetic field, which completely excludes heating of biological tissues, which means it is safe.

3) In the Russian Federation, the level of electromagnetic training safe for humans is regulated by sanitary and epidemiological rules and regulations, namely, "SanPiN 2.2.4.3359-16 Sanitary and epidemiological requirements for physical factors at workplaces" (section 7: electric, magnetic, electromagnetic fields on workplaces), approved by the decree of the chief state sanitary doctor of the Russian Federation dated June 21, 2016. In accordance with these rules, the established norm for the magnitude of the induction of an alternating magnetic field of an industrial frequency of 50 Hz (the frequency closest to the proposed for use frequency range, regulated in "SanPiN 2.2.4.3359-16") when exposed to less than 1 hour per day is for total exposure 2 mT, for local - 8 mT. The planned impact is limited by the maximum amplitude levels of the electromagnetic field of 0.15 mT, which is significantly less than the sanitary standards, namely, by more than an order of magnitude for the general impact, and more than 50 times for the local one.

The amplitude of the pulse wave (PW) on the shoulder, wrist, and thumb was measured in dynamics, as well as the time of PW propagation. Further, according to the measurements obtained, 3 physiological parameters were determined: the speed of propagation of the pulse wave (PWV), endothelial function (EF), blood pressure (BP) and heart rate (HR).

Blood pressure was measured simultaneously using the oscillometric method and the Korotkov method. During the experiment, an electrocardiogram was also recorded. For this, the sensor electrodes were attached to the outer side of the palm of the right hand, the outer and inner sides of the palm of the left hand.

Cuffs were placed on the subject's arm. Two cuffs were attached to the shoulder and wrist over the projection of the brachial and wrist arteries, the third around the thumb. During the experiment, the subject's hand was located at the level of the heart in a natural position.

The experiment began with a conversation with a doctor and simultaneously with the adaptation of the subject to the temperature regime of the room (22-23 degrees C) for about 15-20 minutes.

The cyclogram of the study included 5 identical consecutive measurement sessions (the average duration of each is ~ 10 min). The measurements were carried out on the subject's right hand.

The first dimension is the original. The purpose of this measurement is to assess the initial parameters of the human CVS. The doctor evaluates the nature and heart rate, the presence of cardiac arrhythmias and conduction disorders, blood pressure, indicators of arm arterial stiffness and endothelial function. At this stage, the subject can be removed from participation in the experiment if, during the measurement, any pathological signs are revealed.

To select stable frequency and voltage ranges suitable for effecting the electromagnetic field in accordance with the present invention, frequency and magnetic induction measurements were carried out at a fixed voltage from 1 to 15 Volts in 1 V steps. The frequency was varied from 1 to 8000 Hz in variable steps. (from 1 to 1000 Hz). The induction of the electromagnetic field was measured at the geometric center of the solenoid. The measurement results are shown in FIG. 3.

Further, the experiment was continued to reveal the influence of the variable MF on the EF, as a result of which the graphs of the EF dependences on the frequency and amplitude of the MF were obtained, shown in Fig. 4 and 5.

The measurement results were averaged over the number of subjects in the experiment, and then normalized relative to the EF values before exposure to the electromagnetic field. This value on the graphs was taken as a unit. Thus, all points lying below unity along the ordinate correspond to a decrease in the EF after exposure to MF, and all points lying above one correspond to an increase in EF after exposure to MF.

As a result of this series of experiments, it was found that MF of various frequencies and amplitudes can lead to both an increase and a decrease in the magnitude of the EF. As shown in FIG. 4, in particular, that the strongest increase in EF causes MF with inductions of 0.05 mT and 0.23 mT. The amplitudes of the MF were also established, causing a decrease in EF - 0.02 mT and 0.29 mT. However, the detected decrease in EF is noticeably less than the increase: the maximum decrease was 10-15%, the maximum increase was 30-35%.

The study of the effect of frequency on EF showed the effect of MF (up to 20-25% increase in EF on the shoulder and wrist and up to 45-65% on the finger). To select a constant frequency and amplitude for further experiment, the authors of the invention were guided by the data obtained on the shoulder and wrist, since measurements on the finger strongly depend on the micro movements of the finger and the individual characteristics of the capillary system of the subject. The frequency dependence of the EF value (Figure 14) made it possible to highlight the points - 150 Hz, 833 Hz, as corresponding to the frequencies at which the greatest increase in endothelial function was observed (for the shoulder and wrist).

Using the data described above, the authors selected the frequency and amplitude of the MF for further assessing the effect of the variable MF on the EF, as well as on such CVS parameters as the pulse wave velocity, pulse, blood pressure (systolic blood pressure, diastolic blood pressure).

The point of 0.05 mT was chosen as the MF amplitude, since at this magnitude of the MF induction, the maximum effect on EF was observed, however, a beneficial effect on EF is also observed in the entire range from 0.04 mT to 0.06 mT. The value of 800 Hz was chosen as the MF frequency, since at this frequency the greatest effect of an increase in the EF was observed, however, the beneficial effect of an increase in EF is also observed in the entire range from 700 Hz to 900 Hz.

Further, the effect of an alternating electromagnetic field with an induction of 0.05 mT and a frequency of 800 Hz on such CVS parameters as pulse (HR), blood pressure (systolic and diastolic), pulse wave propagation velocity, endothelial function was studied. The last 2 parameters were measured for three areas of the subject's body - shoulder, wrist and index finger. All measurements were taken on the right hand.

The measured values of heart rate, blood pressure, PWV, depending on time, were averaged over 30 subjects, and also normalized according to the law:

F _i (t) = (f (t _i ) / f (t ₀ ) -1) * 100%, where F _i is the time-dependent function of heart rate, blood pressure, PWV, t is time, i = 1, 2, 3 , 4, 5 is the measurement number.

The measurement results are shown in FIG. 6-11. Thus, all the graphs show an increase or decrease in the considered function relative to its initial values (before the electromagnetic field was turned on) at a time equal to 0. As shown in Fig. 6, the subjects' pulse did not change significantly during the experiment. The maximum deviation from the initial state was about 4%, which fits into the rate of variation of the pulse of a person at rest, determined by doctors [20]. Changes in diastolic pressure did not exceed 4 percent (Fig. 7), systolic pressure during the experiment did not change by more than 0.5% (Fig. 8), relative to the initial SBP and DBP, respectively.

Based on the results obtained, the authors found that the effect of an electromagnetic field with a frequency of 800 Hz and an amplitude of 0.05 mT does not significantly affect blood pressure and heart rate (pulse).

In addition, it was found that, in general, exposure to an electromagnetic field with an amplitude of 0.04 mT to 0.06 mT and a frequency of 700 Hz to 900 Hz does not significantly affect blood pressure and heart rate (pulse).

In particular, the proposed device for exposure to an alternating electromagnetic field on the patient's circulatory system and the corresponding method when exposed to an electromagnetic field for 1 hour with a frequency of f = 800 Hz and an amplitude of magnetic induction B ₀ = 0.05 mT provide a significant increase in endothelial function, which can be useful in the treatment of cardiovascular pathologies.

The initial EF data for 30 subjects were averaged and then normalized relative to the point corresponding to the time reference point (t = 0 min.). This point corresponds to the initial EF level in the subjects before exposure to the electromagnetic field. The normalization was carried out in accordance with the law: F _i (t) = (f (t _i ) / f (t ₁ ), where f _i is the endothelial function of the i-th dimension, i is the number of the measurement, t ₀ = 0 min. of the applied normalization, all values that are above 1 on the ordinate axis correspond to an increase in the EF, all values that are below - to a decrease in EF.

The results shown in FIG. 9-11 show that the method chosen by the authors after 1.5 hours of study gives an approximately 20 percent increase in endothelial function on the shoulder (Fig. 9), an approximately 30 percent increase in endothelial function on the wrist (Fig. 10), approximately 40 percent increase in endothelial function on the finger (Fig. 11).

The reliability of the data obtained is confirmed by the level of statistical significance (Fig. 12), calculated by the nonparametric method for calculating the p - parameter - the Wilcoxon test, also known as the T - Wilcoxon test or the Mann-Whitney test for independent samples [21]. The p-parameter calculated according to the Wilcoxon criterion makes it possible to assess the significance of the results obtained. At P <0.05, the result is considered statistically significant.

Thus, the increase in EF, recorded in the 4th and 5th dimensions, is statistically significant on the shoulder, wrist and finger. The increase in EF, recorded in the 2nd dimension, is significant only in the finger, and the increase in EF, recorded in the 3rd dimension, is significant on the finger and on the wrist (Fig. 12).

Thus, it was found that exposure to an electromagnetic field for 1 hour with a frequency of f = 800 Hz and an amplitude of magnetic induction B ₀ = 0.05 mT leads to a statistically significant increase in EF on the shoulder, wrist, and finger. In particular, a significant increase in endothelial function in the shoulder, wrist and finger was found by about 20%, 30%, 40%, respectively. The discovered effect can be useful in the treatment of cardiovascular pathologies.

It was also found that this effect does not have a statistically significant effect on the speed of propagation of the pulse wave; it can lead to both its increase (wrist and finger) and its decrease (shoulder).

Thus, the discovered positive effect of the effect of an alternating magnetic field on EF can be useful in providing medical care to people with diseases characterized by endothelial dysfunction, typical of ischemic heart disease, type 2 diabetes mellitus, postinfarction cardiosclerosis and other cardiovascular diseases.

Claims (35)

1. A device for influencing an alternating electromagnetic field on the patient's circulatory system, containing: means of influencing an alternating electromagnetic field on the patient's circulatory system; a control unit configured to control the operation of said device for effecting an electromagnetic field, the control unit contains software tools that provide control commands for creating an alternating electromagnetic field on a predetermined part of the patient's body by means of exposure to an alternating electromagnetic field, and providing the ability to process the results of such an impact; a power supply unit made with the possibility of providing autonomous operation of the specified device or with the possibility of ensuring its operation from the AC mains; a measuring unit configured to measure physiological parameters of the patient's cardiovascular system, such as pulse wave amplitude, pulse wave propagation time, heart rate, blood pressure; a computing unit configured to calculate the speed of propagation of the pulse wave, endothelial function; a display unit configured to display measured and calculated physiological parameters of the patient's cardiovascular system; characterized in that an alternating electromagnetic field, which affects the patient's circulatory system, is characterized by an amplitude of magnetic induction, which ranges from 0.04 mT to 0.06 mT, and a frequency that ranges from 700 Hz to 900 Hz, moreover, the specified device provides an increase in endothelial function under the influence of an alternating electromagnetic field. 2. The device of claim. 1, further comprising a data input unit configured to input data about the patient, in particular the height, weight and age of the patient. 3. The device according to claim 1 or 2, in which the means for creating an alternating electromagnetic field are configured to be positioned around the patient's body at a certain distance. 4. The device according to claim 1 or 2, in which the means for creating an alternating electromagnetic field are arranged to be located in the immediate vicinity of the patient's body. 5. A device according to any of the preceding claims, further comprising a storage device in which a database is stored for storing measured and calculated physiological parameters of the patient's cardiovascular system. 6. A device according to any of the preceding claims, in which the means for influencing an alternating electromagnetic field on the patient's circulatory system comprise a solenoid configured to create an alternating electromagnetic field upon receipt of a command from the control unit. 7. The device according to any of the preceding claims, in which the measuring unit contains a plurality of sensors configured to be placed on a given part of the patient's body and with the possibility of communication with the measuring unit for measuring the physiological parameters of the patient's cardiovascular system based on vibrations of the artery walls caused by the passage pulse wave. 8. A device according to any of the preceding claims, wherein the measuring unit is also configured to measure physiological parameters of the patient's cardiovascular system in the absence of an electromagnetic field. 9. An apparatus according to any of the preceding claims, further comprising a communication interface configured to perform wired or wireless communication with a computing device for transmitting the calculated parameters to the computing device for subsequent processing. 10. A device according to any one of the preceding claims, further comprising a compressor for providing a pressure that provides compression of the patient's blood vessels and exceeds the patient's systolic pressure by 30-40 mm Hg. Art. 11. The device according to claim 10, wherein the computing unit calculates the endothelial function as the ratio of the pulse wave amplitudes after and before clamping. 12. An apparatus according to any of the preceding claims, wherein the preferred exposure time to the alternating electromagnetic field is 60 minutes. 13. A device according to any of the preceding claims, in which the computing unit further comprises a plurality of built-in programs for therapeutic exposure to an electromagnetic field, and the control unit is configured to regulate the duration and frequency of exposure in accordance with the selected program. 14. A method of influencing an alternating electromagnetic field on a patient's circulatory system using a device for effecting an electromagnetic field on a patient's circulatory system according to claim 1, according to which generate an alternating electromagnetic field using means for creating an alternating electromagnetic field; measuring the physiological parameters of the patient's cardiovascular system, such as the amplitude of the pulse wave, the propagation time of the pulse wave, heart rate, blood pressure; calculate the speed of propagation of the pulse wave and endothelial function; display the results of calculations using a display block, moreover, the alternating electromagnetic field, which acts on the patient's circulatory system, is characterized by the amplitude of magnetic induction, which is from 0.04 mT to 0.06 mT, and the frequency, which is from 700 Hz to 900 Hz. 15. The method according to claim 14, according to which the measurement of the physiological parameters of the patient's cardiovascular system is also carried out before generating an alternating electromagnetic field. 16. The method of claim 14 or 15, wherein the preferred exposure time to the alternating electromagnetic field is 60 minutes. 17. The method according to any one of paragraphs. 14-16, according to which the patient's blood vessels are additionally clamped with a pressure exceeding the patient's systolic pressure by 30-40 mm Hg. Art. 18. The method according to claim 17, according to which endothelial function is calculated as the ratio of the pulse wave amplitudes after and before clamping. 19. The method according to claim 17, further comprising, simultaneously with calculating the endothelial function, determining the change in the propagation velocity of the pulse wave before and after clamping. 20. The method according to any one of claims. 14-19, which additionally includes regulation of the duration and frequency of exposure in accordance with the selected program of therapeutic exposure to the electromagnetic field. 21. The method according to any one of paragraphs. 14-20, further comprising entering data about the patient, in particular the height, weight and age of the patient.

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