RU2738659C1 - Method for reducing risk of myocardial infarction and device for implementation thereof - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: group of inventions relates to medical equipment. Device is made in the form of a multilayer blanket containing an electrically insulating external layer and an internal layer facing the patient. Layers are made of electrically insulating material, between which current-conducting layer is placed, contacting from opposite sides with current-conducting switching elements, and edges are equipped with fastener-zipper providing detachable connection. Current-conducting screening layer is made from non-ferrous metal, for example, in the form of a Mylar synthetic film, on which a layer of aluminium is applied by sputtering, having a smooth surface with a high reflection coefficient of electromagnetic waves of extremely high frequency (EHF) and infrared (IR) spectrum. Switching elements have galvanic contact with current-conducting screening layer. Method for reducing a risk of myocardial infarction involves exposing the patient to endogenous electromagnetic radiation and screening external electromagnetic fields.

EFFECT: technical result is restoration of normal level of regulatory systems for reducing stress level and reducing risk of developing myocardial infarction.

9 cl, 5 dwg

Description

The invention relates to medicine and can be used for the prevention of dysregulation and restoration of the disturbed normal level of functioning of regulatory systems (UVRS) of the human body, and, in particular, to optimize the functioning of the cardiovascular system in order to reduce the risk of developing myocardial infarction (MI).

Changes in heart rate from cycle to cycle (variability) are the result of its multi-circuit multilevel hierarchical nonlinear control of regulatory systems (Anokhin P.K. Essays on functional systems. - M .: Nauka, 1972.), including in the broad sense of the nervous (central and vegetative ) and humoral regulation Thus, the modus of the cardiointervalogram reflects the level of functioning of the body's regulatory systems, the quality of the body's relationship with the environment, the degree of its response to mental, physical and other types of stress (health, tension of regulatory systems, pre-illness, illness) (Baevsky R.M. ., Berseneva A.P. Introduction to prenosological diagnostics. - M .: Firma "Slovo", 2008 .; Yabluchansky N.N., Martynenko A.V. Heart rate variability. To help the practitioner. Kharkov, 2010.).

Myocardial infarction is a form of coronary artery disease (CHD) in which muscle necrosis develops acutely. Ischemic heart disease is a myocardial damage caused by a disorder of the coronary circulation, in which the myocardium requires more oxygen than it is supplied with the blood and can be acute in the form of myocardial infarction.

In recent years, there has been an increase in the number of deaths from MI. The main reasons for the increased risk of MI are: chronic stress, obesity, high blood pressure, diabetes mellitus, low physical activity.

The degree of risk of developing myocardial infarction can be assessed by indicators of heart rate variability (HRV), such as the stress level SI, from the ratio of LF / HF powers between the low and high frequency components of the heart rate spectrum in the frequency range from 0.0033 ÷ 0.4 Hz, in which the total power of the TP regulation spectrum is calculated ms ² . In the technology for assessing HRV, they operate both with the absolute values of the spectrum parameters and expressed in percentage ratios based on the formula that for 5-minute registration of the rhythm TR = VLF + LF + HF = 100% (Baevsky R.M., Berseneva A.P. . Introduction to prenosological diagnostics. - M .: Firma "Slovo", 2008.).

The sum of the amplitudes of the spectrum in the frequency range from 0.4 ÷ 0.15 Hz characterizes the activity of the parasympathetic division of the nervous system (ANS) HF, the sum of the amplitudes of the spectrum in the frequency range 0.15 ÷ 0.04 Hz characterizes the state of the vascular tone regulation system LF, the sum of the amplitudes spectrum in the frequency range 0.04 ÷ 0.0033 Hz characterizes the activity of the sympathetic division of the ANS VLF. There are empirical normative values of HRV indicators when calculating the indicator of activity of regulatory systems (PARS), for example, for LF = 20 ÷ 39% the norm, for HF = 20 ÷ 29% the norm, values that differ from the norm indicate an increase in the risks of developing fatal conditions (Baevsky R. M. Ivanov G. G. et al. Analysis of heart rate variability using electrocardiographic systems / Bulletin of arrhythmology, 2002, 24. - pp. 65-85). Risk assessment by the LF / HF ratio, assessment of the stress level (Yabluchansky N.N., Martynenko A.V. Heart rate variability. To help a practitioner. - Kharkov, 2010; Baevsky R.M., Berseneva A.P. Introduction to prenosological diagnostics. - M .: Firm "Slovo", 2008; Baevsky R.M., Kirillov OI, Kletskin S.Z. Mathematical analysis of changes in heart rate under stress. - M .: Nauka, 1984) described by the following dependencies. Assessment of the risk of developing myocardial infarction is carried out on the following scale: LF / HF = 1 ÷ 2 - There is no risk of developing myocardial infarction; LF / HF = 2 ÷ 4- The tendency to increase the risk of developing myocardial infarction; LF / HF = 4 ÷ 10 - High risk of myocardial infarction; LF / HF => 10 - The condition is close to myocardial infarction. Assessment of the level of stress is carried out on the following scale: SI = 50 ° ÷ 150- The level of stress is normal; SI = 151 ° ÷ 300 - Increased level; SI => 300 - High level.

The level of functioning (quality of functioning) of regulatory systems is determined by the formula: UV = (10-PARS) / 2 + 1 ≤ 5, according to which, on a 5-point scale, the score "5" corresponds to a normal level of functioning, and "1" corresponds to a fatal violation of regulation.

There are methods and complex preventive methods adopted in medical practice to reduce the risk of MI development: diet, weight loss, exercise, drugs, and rejection of bad habits.

For prevention purposes, physical methods of treatment, as well as devices for their implementation, are also used to reduce risk factors for the development and progression of coronary artery disease.

In particular, there is a known method of prevention and treatment with oxygen (oxygen therapy), by inhaling air with a constant oxygen concentration, it is prescribed for patients with heart failure. However, this method has the disadvantage that when it is used, oxygen intoxication may develop and additional humidification of the air stream is required. In addition, this method is used only under the supervision of a doctor in the conditions of treatment-and-prophylactic or sanatorium-resort institutions and are stationary (Ponomarenko G.N., Vorobiev M.G. Physiotherapy manual. - St. Petersburg: IIC "Baltika", 2005).

Also known is the method of rehabilitation medicine - heat therapy - the use of external thermal agents, such as peloids (therapeutic mud) or peloid-like substances (paraffin, ozokerite) to normalize blood circulation, metabolism and immunity, including with an adaptogenic purpose. However, there are medical restrictions on the use of this method, for example, exacerbation of chronic diseases, ischemic heart disease, angina pectoris higher than FC II, cirrhosis of the liver, thyrotoxicosis, etc. In addition, the known method is used only in treatment-and-prophylactic or sanatorium-resort institutions ("Physical and Rehabilitation Medicine: National Guidelines / Ed. By G.N. Ponomarenko. - M .: GEOTAR-Media, 2016.).

For the implementation of non-drug treatment and prevention of various diseases known device according to patent RU 2429030, which can be made, including in the form of a blanket. The combined metallized film includes a metal film, for example, aluminum, laminated on one side with a polymer film with a high degradation temperature, for example, polyethylene terephthalate, and on the other hand, with a polymer film with a lower melting point, for example, polyethylene.

Known device for therapeutic effects according to patent RU 2185207, which can be made, including in the form of a blanket, including two layers of woven material between which is located at least one with a high reflection coefficient of natural electromagnetic waves of the EHF and IR range, made from a synthetic film with a metallization layer on top of which a layer of polymer material is applied.

The closest in technical essence, chosen by the applicant as a prototype, is a method of therapeutic action and a device for its implementation according to patent RU 2053804, in which the patient is wrapped in a multilayer blanket and the patient is exposed to his own electromagnetic radiation in two frequency ranges: extremely high frequency (EHF ) and infrared spectrum (IR), reflected from the conductive shielding layer in the multilayer blanket.

To implement the above-described method, a device is known that is a blanket of polyfactorial therapeutic effects according to patent RU 2053804, containing alternating passive means of affecting the body in the form of stripes. The blanket contains at least three layers, at least two of which form an electrical insulating material, between which a conductive shielding layer of flexible non-ferrous metal strips or metallized synthetic films is located. The screen on the patient's side is made with a smooth surface with a high reflection coefficient of electromagnetic waves of extremely high frequency (EHF) and infrared spectrum (IR). In this case, the strips of the shielding layer are overlapped.

A common disadvantage of the known devices in the form of blankets with a conductive shielding layer is the lack of means for preserving and evenly distributing heat around the patient, which reduces the effectiveness of the effect due to possible heat leaks in the IR range, which, in turn, can lead to an increase in the duration of each wrapping session. In addition, a common disadvantage of the known devices in the form of blankets with a conductive shielding layer is the absence of switching elements for galvanic connection of the edges of the conductive layer when wrapping a patient in order to improve the shielding properties of the conductive layer in the form of an extension of the frequency range. The known devices cannot provide effective reflection of electromagnetic waves in the frequency range 0.0033 ÷ 0.4 Hz by the presence of an overlap formed when the patient is wrapped with a blanket, i.e. in the range of spectral assessment of the heart rate, in which the regulation of the cardiovascular system (CVS) of the body works. Therefore, the known blankets do not provide effective normalization of the level of functioning in the regulation of the cardiovascular system (CVS) to reduce the risk of MI.

The objective of the invention is to increase the efficiency of restoring the level of functioning of regulatory systems to reduce the level of stress and reduce the risk of developing myocardial infarction.

EFFECT: restoration of the normal level of functioning of regulatory systems to reduce the level of stress and reduce the risk of developing myocardial infarction by expanding the frequency range of waves reflected from the current-conducting shielding layer to the frequency range of the functioning of the cardiovascular system 0.0033 ÷ 0.4 Hz.

To solve this problem, a method is proposed to reduce the risk of developing myocardial infarction by exposing the patient to endogenous electromagnetic radiation and shielding external electromagnetic fields, for which the patient is wrapped in a multilayer blanket containing a conductive shielding layer, characterized in that the patient is preliminarily wrapped with a cloth made of natural cotton, and the subsequent wrapping is carried out with a multilayer blanket, which is made with the possibility of detachable conductive connection of its free edges, while the opposite edges of the conductive shielding layer are galvanically connected by connecting conductive switching elements with the formation of an electric circuit closed around the patient to expand the frequency ranges from EHF and infrared radiation of the electromagnetic field from vortex currents up to the frequency range 0.0033 ÷ 0.4 Hz.

A device for reducing the risk of developing myocardial infarction, which is a multilayer blanket, in which at least two layers are formed by an electrically insulating material, between which there is a conductive shielding layer of non-ferrous metal, which is a conductive shielding layer on the patient's side made with a smooth surface with a high reflection coefficient of electromagnetic waves extremely high frequency (EHF) and infrared (IR) spectrum, characterized in that the blanket is made with the possibility of detachable connection of its edges with the help of conductive switching elements galvanically connected to the opposite edges of the shielding layer, which, when connected, form an electric circuit closed around the patient.

The device additionally contains a "zipper-fastener".

Preferably, aluminum is used as the non-ferrous metal for the conductive shielding layer. Materials for creating a conductive layer can also be applied by spraying, galvanic deposition, including materials with a relative magnetic permeability significantly exceeding unity. Aluminum foil can be used as a conductive shielding layer.

The conductive switching elements located on opposite sides of the conductive layer are preferably made in the form of metal buttons that act as contact pads.

The conductive shielding layer on the patient's side has a smooth surface with a high reflection coefficient of electromagnetic waves of extremely high frequency (EHF) and infrared spectrum.

Any textile material suitable for this purpose can be used as the electrical insulating material.

Exposure to the patient with its own electromagnetic field is carried out within a time interval not exceeding 20 minutes.

The claimed method and device are interconnected by a single inventive concept.

In the claimed device, the conductive shielding layer returns to a person his electromagnetic oscillations in a phase opposite to the primary radiation. Thus, the claimed device implements negative feedback (OF). OOS, as you know, from different fields of science and technology, is a way to stabilize the output parameters, allowing them to keep them in the corridor of standard values.

During the wrapping session, the parameters of the human regulatory systems first decrease because humoral mechanisms of self-regulation are triggered, requiring energy expenditures, and then, at the end of the session, the process of normalization of the values of such parameters as LF, HF and their ratio occurs, the stress level SI, the level of the total spectrum power TR increases if it was less than normal values and falls if it significantly exceeded the norm.

The claimed invention differs from the prototype invention. In particular, in the blanket according to the prototype, when the patient is wrapped with an overlap, a galvanically closed circuit is not formed for effective shielding, because the connection between the edges of the conductive shielding layer between the edges of the blanket occurs only capacitively through the formed electric capacitor Co (Fig. 1), which creates a frequency-dependent resistance in the circuit of the conducting layer to the alternating (eddy) current I induced from the patient's endogenous radiation.

It is known that the capacitive resistance X _{with the} electric current flowing through it increases with a decrease in its frequency f (Kotelnikov V.A., Nikolaev A.M. Fundamentals of radio engineering. Part I. - M .: State publication of literature on communications and radio, 1950 .) and is expressed by the formula:

X _c = 1 / 2π _* f _* C

where C is the value of the capacitance of the electric capacitor.

With a blanket size of 2x2 meters, the overlap area can be on the order of one square meter. Thus, the area of the plates of the resulting capacitor is S≈1 m ² , the distance between the plates d = 0.01m, the value of the capacitance Cо will be according to the well-known formula with an air dielectric:

Co≈ε _о * S / d = 177 nF, where ε _о = 8.85 * 10 ^-12 F / m - absolute dielectric constant (Encyclopedic Dictionary of a School Student. Natural Sciences. Volume I. - Moscow: Russian Encyclopedic Association, 2003 .).

In this case, the value of the capacitive resistance Xc1 at a frequency of f = 0.0033 Hz will be:

Xs1 = 1 / (2π * f * Co) ≈280 MOhm,

Taking into account that the ohmic resistance of the conductive shielding material is units of Ohm, then the current resistance of 280 MΩ is equivalent to complete isolation of the patient from the effect of the field reflected from the conductive shielding layer in the range of functioning of the CVS.

In addition, the known method uses an extremely high frequency operating range, which corresponds to values of 50-300 GHz. (Ponomarenko G.N., Vorobiev M.G. Physiotherapy manual. - SPb .: IITs "Baltika", 2005.). For the lowest frequency equal to 50 GHz in the EHF range, the capacitive resistance will be Xc2 = 0.0017 Ohm. The difference between Xc2 is more than 10 orders of magnitude. From a comparison of the capacitive resistance values, it can be concluded that the prototype device cannot provide a low-resistance resistance in the current-conducting shielding layer circuit in the frequency range 0.0033 ÷ 0.4 Hz for the induced eddy current to flow.

In the claimed invention, the opposite ends of the blanket are closed by an electric conductor using the EC switching elements (Fig. 2), while C ₀ becomes equal to zero and the frequency dependence disappears for both the induced eddy current in the conductive shielding layer from the patient and from external sources of electromagnetic radiation ...

The claimed invention provides a new technical result, eliminating the disadvantages inherent in the prototype. The galvanic connection in the claimed invention eliminates the frequency dependence of the resistance for the flow of low-frequency eddy currents and therefore the restoration of the disturbed normal level of functioning of the regulatory systems (UVRS) of the human body occurs in the frequency range of regulation of the cardiovascular system (CVS) of the body. Eddy current is alternating and is formed in the conductive shielding layer under the action of an endogenous electromagnetic field. In this case, charges are formed at the edges of the conductive layer with polarity determined by the current direction of the eddy current.

In the claimed invention, the restoration of UVR occurs also by providing effective shielding of the patient from external electromagnetic radiation of various nature.

The elimination of the frequency dependence of the resistance is achieved in the inventive device by galvanic connection using the switching elements of the opposite edges of the conductive shielding layer.

The claimed method and device for its implementation relate to the process of self-regulation, which has the nature of negative feedback and consists in stabilizing the parameter TP in the normal range. At increased power, the TP decreases, and vice versa, at a lower power, its growth is observed. Thus, the direction of the regulation change always occurs with the opposite sign. The indicated effect is confirmed by clinical observations of the direction of the process of changing the indicator of the total power of the TR regulation spectrum. There are approximate standard values TP = 1000 ÷ 2000 ms ² . A decrease in the regulation power of less than 500 ms ² is considered to be low resources, insufficient to ensure a normal UVR, more than 3500 ms ² means a high supply of resources, but this can be the reason for the very rapid development of dangerous situations - an increase in heart rate, an increase in blood pressure, manifestations of arrhythmias. A value of less than 200 ms ² means that the body's reserves are depleted and the risk of developing heart catastrophes is high. During the wrapping session with a single procedure, a slight decrease in TP values is observed, and after the session, an increase in the TP value is observed if it was less than 1000 ms ² and a decrease in TP if there was an excess of more than 3500 ms ² .

The use of the proposed device, which implements the galvanic connection of opposite sides of the conductive layer, allowed:

- to reduce the risk of developing myocardial infarction by reducing the ratio of LF / HF indicators on average from 6 to 2.8, which indicates a 2.14-fold decrease in the risk of developing myocardial infarction,

- to reduce the level of stress SI by 2 ÷ 4 times;

- adjust the level of the total power of the TP spectrum to the normal level by optimizing the self-regulation process in the frequency range of the functioning of the cardiovascular system.

In addition, in comparison with the prototype, it allowed to reduce the exposure session time from 20 ÷ 40 minutes to 10 ÷ 20 minutes.

The inventive device contains a detachable connection in the form of a "zipper", providing a butt joint of the edges, which provides a hermetic wrap in order to maintain and uniform distribution of endogenous heat of the patient. The use of a zipper in the claimed device provides protection against endogenous heat leaks in the form of infrared radiation.

The use of wrapping the patient with cotton products improves the psycho-emotional state and improves the heat exchange process, increasing the comfort of the procedure.

All of the above allows us to conclude that the claimed group of inventions provides a new technical result and allows us to conclude that the claimed group of inventions meets the criterion of "inventive step".

Comparison of the proposed method and device for its implementation with the prototype allows us to conclude that the claimed method and device meet the criterion of novelty.

The inventive method and device are implemented as follows.

The galvanic connection of opposite sides of the conductive layer is illustrated in Fig. 1, which shows a schematic diagram of the formation of a flat capacitor from a conductive layer with an air gap when the patient is wrapped with an overlap. A galvanic connection using switching elements (designated in Fig. 1 by letters - FE) provides a frequency independent connection of the sides of the conductive layer, the direction of the current is shown by the symbol I.

Fig. 2. general view of the device is shown,

Fig. 3. and Fig. 4. shows the section of the device.

The device is made in the form of a multilayer blanket containing an electrically insulating outer layer 1 and an inner layer 2 facing the patient, layers 1 and 2 are made of an electrically insulating material, between which a conductive layer 6 is placed, contacting from opposite sides with conductive switching elements 3 and 4, edges equipped with a zipper 5 providing a detachable connection. Switching elements 3 are metal snap fasteners. Electrical insulating layers are made of cotton fabric 4 ... 6 mm. The conductive shielding layer 6 is a synthetic Mylar film on which a layer of aluminum is sprayed. The switching elements 3 and 4 are in galvanic contact with the conductive shielding layer 6.

The claimed method is illustrated by the following examples of specific implementation.

Example 1.

Patient I., woman, 43 years old, Heart rate variability parameters:

- before the course therapy TP = 773 ms ² , LF / HF = 4.2, stress level SI = 380, HR = 77 beats / min. PARS = 4.9, UVRS = 3.

- after 14 days of course therapy for 20 minutes a day, the parameters were TP = 1620ms ² , LF / HF = 1.9, stress level SI = 160, HR = 75 beats / min. PARS = 3.

From the given example it follows:

1. The total power of the TP growth spectrum is 2.1 times.

2. The SI stress level decreased 2.3 times.

3. PARS decreased 1.6 times.

4. UVRS = 4.5

5. The risk of developing myocardial infarction LF / HF decreased 2.2 times.

The obtained index values indicate a positive result of exposure according to the claimed method and the device as a whole. There is an improvement in FRS from 3 to 4.5 on a 5-point scale and a decrease in the risk of developing MI by 2.2 times.

Before the course exposure, the risk of developing myocardial infarction was characterized as "High level of risk of myocardial infarction", and after the course exposure, the risk of developing myocardial infarction was characterized as "There is no risk of developing myocardial infarction."

Example 2.

Patient M., male, 63 years old, parameters of heart rate variability:

- before the course therapy TP = 320 ms ² , LF / HF = 7.1, stress level SI = 420, HR = 84 beats / min., PARS = 7.3, UVR = 2.3.

- after 14 days of course therapy for 20 minutes a day, the following parameters were recorded: TP = 660 ms ² , LF / HF = 2.2, stress level SI = 260, HR = 76 beats / min. PARS = 4.2, UVRS = 3.9.

From the given example it follows:

1. The total power of the TP growth spectrum is 2 times.

2. The SI stress level decreased 1.6 times.

3. PARS decreased by 1.73 times.

4. UFRS increased by 1.69 times.

5. The risk of developing myocardial infarction LF / HF decreased by 1.72 times.

The obtained index values indicate a positive result of exposure according to the claimed method and device as a whole, the FRS increased from 1.69 to 3.9 and the risk of MI developing by 1.72 times.

Before the course exposure, the risk of developing myocardial infarction was characterized as "Very high risk of developing myocardial infarction", and after the course exposure, the risk of developing myocardial infarction was characterized as "The tendency to develop the risk of myocardial infarction is low."

According to the prototype, the risk of developing myocardial infarction over a time interval of 20 minutes decreased by an average of 1.1 times.

The course of treatment by the claimed method consists of 10-20 sessions.

The absence of negative results and the ease of use of the claimed invention, which does not involve the use of power supplies, allow us to conclude that it is safe. The claimed invention can be widely used for the treatment and prevention of dysfunctions of regulatory systems in order to reduce the risk of MI in medical and medical institutions, as well as in the field and at home.

The inventive method and device for its implementation make it possible to ensure their increased functionality, including by ensuring effective shielding of the patient from external electromagnetic radiation of various nature, using the patient's own endogenous reflected radiation, which coincides with the frequency range of the CVS, which leads to the restoration of the normal level of functioning regulatory systems and reduces the risk of myocardial infarction, while reducing the duration of procedures.

Claims (9)

1. A method of reducing the risk of developing myocardial infarction by exposing a patient to endogenous electromagnetic radiation while simultaneously shielding the patient from external electromagnetic fields by wrapping the patient with a multilayer blanket containing a conductive shielding layer configured to reflect electromagnetic radiation towards the patient, characterized in that the patient is preliminarily wrapped with cotton cloth, and the subsequent wrapping is carried out with a multilayer blanket, which is made with the possibility of detachable conductive connection of its free edges, while the opposite edges of the conductive shielding layer are galvanically connected by connecting conductive switching elements to form an electric circuit closed around the patient to emit an electromagnetic field from vortex currents of the conductive shielding layer in the frequency ranges 0.0033 ÷ 0.4 Hz, extremely high frequency and infrared frequencies spectrum. 2. The method according to claim 1, characterized in that the detachable conductive connection of the free edges of the blanket is carried out by means of contact pads made in the form of metal buttons. 3. A method according to claim. 1, characterized in that the edges of the multilayer blanket are connected by means of a zipper. 4. A method according to claim 1, characterized in that one wrapping session is carried out for preferably 20 minutes. 5. The method according to claim 1, characterized in that the conductive shielding layer capable of reflecting electromagnetic radiation towards the patient is an aluminum foil. 6. A device for reducing the risk of developing myocardial infarction, which is a multilayer blanket, in which at least two layers are formed by an electrically insulating material, between which there is a conductive shielding layer made of non-ferrous metal, the conductive shielding layer on the patient's side is made with a smooth surface to reflect electromagnetic waves of extremely high frequency and infrared spectrum in the direction of the patient, characterized in that the multilayer blanket is made with the possibility of detachable connection of its edges using conductive switching elements galvanically connected to the opposite edges of the conductive shielding layer, which, when connected, form an electric circuit closed around the patient. 7. The device according to claim 6, characterized in that the conductive switching elements are represented by metal buttons. 8. A device according to claim 6, characterized in that the edges of the multilayer blanket are provided with a zipper. 9. The device according to claim 6, characterized in that the conductive shielding layer is made of metal foil.

Images