RU2335308C1 - Method of physical therapy - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention is referred to medicine, physiotherapy. The method includes selection of biologically active zones (BAZ) important for treatment. For this purpose perform measurements of electromagnetic radiation of millimeter wavelength (EMR MM) over an integument in projection of eight zones. Then perform processing of each measured signal by its transformation to the digital form, spectral characteristics calculations. Build two graphic dependences: dependence of intensity of the measured signal in time and distribution of a spectrum of the measured signal. Analyze the received diagrams. If slow or fast oscillatory process of changes of signal strength in time is present on the first diagram and-or exponential dependence of distribution of frequencies is absent on the second diagram, choose BAZ for medical influence. The course of treatment includes not less than 14 sessions of an irradiation of area of an integument projection of the chosen BAZ with low intensity impulsive noise electromagnetic radiation in a frequency range of 0.03-500 GHz within 1.5-3 minutes. After the end of the course perform control measurement EMR MM over an integument in BAZ projection. Similarly perform processing of the measured signal and the analysis of its results. Taking into account the obtained results whether prescribe an additional course of procedures, or cancel treatment. The method increases efficiency of treatment due to selection of biologically active zones and a mode of exposure, necessary for treatment.

EFFECT: increase of physiotherapeutic treatment efficiency.

2 cl, 3 ex, 48 dwg

Description

The invention relates to medicine and can be used for physiotherapy procedures used in the treatment of various diseases.

In various branches of medicine, methods of influencing biological objects based on the use of electromagnetic fields are widely used. Currently, it is theoretically grounded and experimentally proved that the vital activity of any biological system, including humans, is accompanied by ultra-weak electromagnetic waves in a wide range of wavelengths - from super-long to very short. The great influence that electromagnetic radiation of the millimeter wavelength range of low intensity has on the state of biological processes of living organisms is also known (Golant MB, Resonant effect of coherent electromagnetic radiation of the millimeter wave range on living organisms, Biophysics, 1989, vol. .6, p. 1004-1014).

Further development of biomedical research has shown the effectiveness of the therapeutic effect when using pulsed noise electromagnetic radiation of the millimeter range, since such radiation includes a large number of therapeutic frequencies having a fairly high uniformity in the distribution of noise power in frequency and noise power above the threshold. In addition, it was found that the use of pulsed noise electromagnetic radiation of the millimeter range with low intensity can dramatically reduce the likelihood of side effects.

A known method of physiotherapeutic exposure, which consists in exposing the biologically active zones to noise electromagnetic radiation of an extremely high frequency range of low intensity (SU 1611345 A1, Temporary Scientific Team “RESPONSE”, 12/07/1997). The disadvantage of this method is the lack of individual choice significant for the impact of biologically active zones of a particular patient. It is known that through biologically active zones (BAS), communication with internal organs is carried out (G. Luvsan. Essays on the methods of oriental reflexology, M .: Nauka, 1980, p. 33). At present, there is enough theoretical, experimental, and clinical material that allows us to state that the leading role in increasing the effectiveness of the therapeutic effect of electromagnetic radiation belongs to the choice of the exposure zone, since the final nonspecific effect of the effect is realized with the participation of various regulatory systems of the macroorganism. The areas of the skin of the BAZ are highly sensitive to electromagnetic radiation. In this regard, the individual selection of exposure zones significantly increases the effectiveness of the therapeutic effect.

The closest analogue is the method of physiotherapeutic effect, which consists in the fact that the patient is first individually selected for the treatment of biologically active zones that are most important for the therapeutic effect by measuring radio signals from biologically active zones with a radiometer, followed by their processing and analysis, while processing the spectrum of the measured signals, in the analysis, the spectra of the altered signals are compared with the spectra of healthy organs, and if they are different, choose these biologically active zones for exposure, exposure is carried out by low-intensity electromagnetic waves in the millimeter, infrared and part of the visible range, modulated by signals corresponding to the signals of healthy organs (RU 2141785 C1, 11.27.1999).

A diagnostic sign when choosing a BAS for subsequent exposure in the known method is the spectral characteristic of the radiation of healthy organs. As you know, the concept of “healthy organ” refers to the macro level of the organization of a living system, and between changes in the micro level, for example, cells and the macro level, there is an individual time interval with a very unsteady and difficult to grasp border. In this connection, the diagnostic feature of the known method “spectral characteristic of radiation of healthy organs” does not sufficiently reliably reflect the condition of a particular patient.

In addition, the known method has corresponding limitations. It is difficult to imagine how the therapeutic effect is carried out in case of a disease, for example, hematopoietic and lymphoid tissue (lymphoblastoma and lymphonulomatosis), of the sympathetic nervous system (sympatoblastoma), since in this case it is not possible to determine the spectrum of a “healthy organ”.

The problem solved by the invention is to create a method of physiotherapeutic exposure, allowing at an early stage of the development of pathology to determine systemic disorders of the patient’s body condition and to purposefully carry out exposure to low-intensity pulsed electromagnetic radiation in the region of extremely high-frequency, infrared and visible wave ranges, aimed at restoring the biological state through normalization of the complex chain of reactions of the body.

The technical result consists in expanding the functional capabilities of the method of therapeutic effects and increasing the effectiveness of physiotherapeutic effects by increasing the number of diagnostic signs in determining biologically active zones with systemic disorders and targeted effects to restore the identified violations.

This is achieved by the fact that in the method of physiotherapeutic influence, first, the biologically active zones (BAS) that are significant for the treatment are selected by measuring the electromagnetic radiation of the millimeter wavelength range (EMR MM) over the skin in the projection of eight BASs, such as Uz1, the projection of which is located on the cranial the lid in front of the crown of the Uz2, the projection of which is located on the skull cover directly above the external occipital protrusion of Uz3, the projection of which is located on the front surface of the jugular notch of the handle the sternum Uz4, the projection of which is located on the front surface of the body above the grudino-sternal synchondrosis Uz5, the projection of which is located on the front surface of the body above the apex of the lower sternal triangle Bz1, the projection of which is located on the front surface of the body directly under the cartilage of the IX and X ribs on the right Bz2, the projection of which located on the front surface of the body directly under the cartilage of the IX and X ribs on the left Bz3, the projection of which is located on the front surface of the body of the pubic bone, with after By processing each measured signal by digitizing it, calculating the spectral characteristic and plotting two graphical dependences: the dependence of the intensity of the measured signal over time and the distribution of the spectrum of the measured signal, the obtained curves are analyzed, and if there is a slow or fast oscillatory process of changes in the signal intensity over time in the first graph and / or in the absence of an exponential dependence of the frequency distribution in the second graph, select the investigated base for therapeutic treatment, which consists in conducting at least 14 sessions, each of which includes sequential irradiation of the projection area of the skin of the selected BAS with pulsed noise electromagnetic radiation of low intensity in the frequency range 0.03-500 GHz for 1.5-3 minutes, after at the end of the course, they carry out a control measurement of EMR MM over the skin of the patient in the projection of the BAS, similarly process the measured signal and analyze its results, taking into account which an additional course is prescribed The procedure for either discontinue treatment.

A control measurement of the electromagnetic study over the skin in the BAS projection is carried out after each additional course of procedures, the number of additional courses is determined by the analysis of the results of processing each control measurement.

It is known that the human body has its own sources and repeaters of millimeter-wave electromagnetic waves that support the body in a state of homeostasis due to the synchronization of electromechanical vibrations of cellular substructures, which affects the regulatory systems of the body (see Devyatkov N.D. and others. The role of synchronization under the influence of weak signals of the millimeter wave range on living organisms, Prince Non-thermal effects of millimeter radiation, under the editorship of ND Devyatkov, M., IRE Academy of Sciences of the USSR, 198 1, pp. 1-17).

In case of pathological disorders of various etiologies, the body cells generate electromagnetic signals at resonant frequencies, which are absorbed in places of structural disorders that have their own “abnormal” frequencies. In cases where the power of internal sources of electromagnetic radiation is sufficient, and the disturbances are insignificant, molecular structures are normalized under the influence of forced resonant vibrations. If internal sources are weakened due to age-related changes or past illnesses, as well as any external factors, for example, technogenic or natural factors, molecular structure disturbances are significant, and communication communications are broken due to their exit from resonance, then a coherent resonant electromagnetic effect capable of restore damaged structures and functions of affected tissues, organs or systems of the body and then normalize their functioning (see ibid.).

In this regard, the electromagnetic radiation of the millimeter wavelength range in the projection of the BAS of the patient is the most informative for determining possible violations of the molecular structures of the body systems for which these biologically active zones are responsible. Violations of molecular structures make it possible to capture the earliest stages of pathological processes when it undergoes the earlier, not yet externally (symptomatologically) manifesting phases of their development.

Thus, measuring the electromagnetic radiation of the millimeter wavelength range above the skin in the projection of the BAS allows us to determine the systemic disorders of the body at an early stage of the pathological process, and therefore, to identify the BAS is most significant for physiotherapeutic effects aimed at restoring the biological state of the patient.

The impact on the BAS with detected violations of pulsed noise electromagnetic radiation in a wide frequency range of 0.03-500 GHz low intensity allows you to compensate for changes in electromagnetic radiation at the micro level and, thereby, normalize the functioning of the affected tissues, organs and systems.

For a systematic approach when choosing biologically active zones that are significant for the therapeutic effect, it is essential to measure electromagnetic radiation in the projection of at least eight BASs of the patient responsible for important organs and systems.

Using a highly sensitive receiver that provides registration of the measured signal at least 0.2 · 10 ¹⁴ discrete values per second, can significantly increase the information content of the measurements.

In addition, as a result of experimental studies, it was found that the measurement time of 1.5-4 minutes of BAZ electromagnetic radiation is the most optimal time interval for obtaining reliable data characterizing the state of the BAZ.

When processing the measured signal, two graphical dependencies are built: the dependence of the intensity of electromagnetic radiation at each moment of time and the spectral characteristic of electromagnetic radiation, i.e. quantitative and qualitative characteristics of the measured signal. This allows us to introduce additional diagnostic features when analyzing the state of the BAS.

The following graphic signs are the diagnostic signs in determining the state of a BAS: the presence of a slow or fast oscillatory process of changes in signal intensity over time in the first graph and the absence of an exponential dependence of the spectral characteristics of the measured signal. They were determined as a result of experimental studies when measuring the electromagnetic radiation of the millimeter wavelength range above the skin in the projection of BAZ in more than 1000 areas of seriously ill patients with an established diagnosis obtained by examination using traditional methods.

These signs are nonspecific and characterize deviations from the norm of managers and, in some cases, executive systems of the body.

The use in the present invention of signs characterizing pronounced deviations from the norm allows one to more accurately determine the state of control and executive systems, since the time gap between the action of the damaging factor and the change in organs and systems, including the irreversible nature, is known, and therefore, increase efficiency therapeutic effect.

The physiotherapeutic effect is as follows.

The patient is placed in a position convenient for him and successively measure the electromagnetic radiation of the MM-range of wavelengths above the skin in the projection of at least eight biologically active zones, universal and basic. The following zones are used as universal zones:

Uz1, the projection of which is located on the skull cover (calvaria cranii) immediately in front of the crown of the head (vertex);

Uz2, the projection of which is located on the skull cover directly above the external occipital protrusion (protuberantia occipitalis externa);

Uz3, the projection of which is located on the front surface with a jugular notch of the sternum handle (incisura jugularis manubrium sfeni);

Uz4, the projection of which is located on the front surface of the body over the grip-sternal synchondrosis (sternum angle - angulus sterni);

Uz5, the projection of which is located on the front surface of the body above the apex of the lower sternum triangle (angulus infra sternalis).

As the base zones use biologically active zones:

Bz1, the projection of which is located on the front surface of the body directly under the cartilage of the IX and X ribs on the right;

Bz2, the projection of which is located on the front surface of the body directly under the cartilage of the IX and X ribs on the left;

Bz3, the projection of which is located on the front surface of the pubic bone body (osis pubis body).

When measuring the electromagnetic field in the projection of each of the BASs, the receiving antenna of the highly sensitive receiver of electromagnetic radiation (high-sensitivity radiometer) is brought to the patient’s body surface at a distance of 5-10 mm above the projection area of the measured biologically active zone using a special tripod, placing the longitudinal axis of the antenna perpendicular to the body surface.

For 1.5-4 minutes, the receiver antenna receives electromagnetic radiation in the MM wavelength range. At the output, the receiver detects the measured signal. The signal from the output of the receiver is fed to the input of an analog-to-digital converter that converts the analog waveform to digital form for subsequent signal processing in a computer.

The doctor starts the monitoring program, which performs the following sequence of actions:

- storing each next value from the output of the analog-to-digital converter at a given time (more than 0.2 · 10 ¹⁴ discrete values per second);

- smoothing a number of obtained values of the measured signal;

- construction of a graphical dependence of the radiation intensity of the altered signal at each moment in time;

- calculation of the spectral characteristics of the low-frequency component of the measured signal, for example, by Fourier transform;

- presentation of the received graphic dependencies on a computer monitor with their subsequent listing.

The obtained curves are analyzed by a doctor. In the presence of a slow or fast oscillatory process of changes in signal intensity over time in the first graph and / or the absence of an exponential dependence of the frequency distribution in the second graph, the BAS is chosen for therapeutic effect.

The doctor prescribes a course of physiotherapeutic procedures for at least 14 sessions.

During the session, sequentially, the skin integument in the projection of individually selected BASs is exposed to pulsed noise electromagnetic radiation in the frequency range (0.03-500) GHz of low intensity for 1.5-3 minutes.

Used in the proposed method, electromagnetic radiation includes extremely high frequency, infrared and visible frequency ranges that contain a sufficient number of therapeutic frequencies. Exposure to the BAS with signs characterizing the impairment restores homeostasis in the patient’s body and further harmonizes control and executive systems.

After a course of exposure, a control measurement of the electromagnetic radiation of the MM-range of wavelengths above the skin in the BAS projection is carried out, a similar processing and analysis of the measurement results is carried out, and if there are any violations, an additional course of therapeutic effects is prescribed.

The control measurement is carried out after each additional course of exposure. This allows you to track the dynamics of the treatment process.

In order to increase the effectiveness of the therapeutic effect, in some cases, electromagnetic radiation of local zones is measured. These include the following BAZ:

Lz1, the projection area of which is located on the front surface of the body above the right mammary gland;

Lz2, the projection area of which is located on the front surface of the body above the left mammary gland;

Lz3, the projection area of which is located on the front surface of the body immediately in front of the pubic mound on the right (tuberculum pubicum);

Lz4, the projection area of which is located on the front surface of the body immediately in front of the pubic mound on the left.

The proposed method does not limit the number of used BAS. For a specialist, it is obvious that the larger the number of measurements, the more information about violations in the body can be obtained, and therefore, with greater efficiency to carry out a therapeutic effect aimed at restoring the body.

In addition, to clarify the status of BAS, it is possible to monitor BAS. Why additionally sequentially in time they measure the same BAZ at least 4 times. According to the results of processing and subsequent analysis of the obtained curves, the state of the BAZ is specified.

The number of additional courses is determined by the results of the analysis, in the absence of violations of the impact is stopped.

The method is confirmed by specific examples. Examples are illustrated by drawings (see Figs. 1-48), each of which presents the results of measurements of the investigated BAS in the form of two graphs, the first graph characterizes the dependence of the intensity of the measured signal over time, the second - the distribution of the spectrum of the measured signal.

Example 1. Patient A., 57 years old, established diagnosis: chronic gastritis, chronic cholecystitis.

The treatment was carried out in accordance with the proposed method.

In the initial measurement of the electromagnetic radiation of basic and universal BASs, the following was established: when analyzing the spectral characteristics, it was established - in BAZ Uz1, Uz2, Uz3, Uz4, Uz5, Bz1, Bz2, Bz3 - the absence of exponential dependence, the presence of high-amplitude components of the spectrum of the measured signal (see Fig. .1, 3, 5, 7, 9, 11, 13, 15). The study of the graph of the intensity of electromagnetic radiation at each moment of time showed that the state is close to normal in all BAZ, with the exception of BAZ Uz3, in which the oscillatory process is clearly expressed (see also). However, taking into account all the diagnostic signs for exposure, it is recommended to use all BAS.

The control measurement after the course is presented in FIGS. 2, 4, 6, 8, 10, 12, 14, 16. The analysis of the curves characterizing the electromagnetic radiation in the BAZ obtained during the control measurement shows the positive dynamics of treatment in Uz3, Uz5, Bz1 ( see Fig.6, 10, 12). The patient notes an improvement in general condition, namely, normal sleep, decreased irritability, improved performance, ceased to disturb pain in the epigastric region, burps disappeared.

A repeated course of physiotherapy is recommended.

Example 2. Patient K., 45 years old, the diagnosis is lymphogranulomatosis. After a course of radiation therapy, he sought treatment.

The treatment was carried out in accordance with the proposed method. According to the results of the primary measurement, it was established that all systems are included in the disease. The process is extremely difficult (see Fig.17-32). The impact was carried out on all studied BAS.

After the therapeutic effect, the control measurements showed the dynamics of the process for the better. However, pathological signs persist in the zone Uz4 and Uz5, Bz1, and improvement has occurred in the zone Uz3 and Bz3. The therapeutic effect is present, additional courses of treatment are recommended.

Example 3. Patient F., 73 g., Complaints - discomfort in the epigastric region, heartburn, long stool delays (3-4 days), resentment. The treatment was carried out in accordance with the proposed method. In the initial measurement of the BAZ electromagnetic radiation, the obtained curves show that almost all zones are included in the pathological process (see Figs. 33-48). Moreover, the low-frequency modulating component has an oscillatory process at Uz1, Uz3, Bz3. The presence of high amplitudes is in Uz2, Uz5, Bz1 and Bz2. There is no exponential dependence in all zones, especially Uz3.

A comparative analysis of the obtained curves in the primary and control measurements showed a positive dynamics in the dependence of the radiation intensity over time in the BAZ Uz5, Bz2, Uz1, according to the spectral characteristics - in the BAZ Uz2, Uz3, Uz5, Bz2. Subjectively, pain, heartburn disappeared, sleep returned to normal, stool returned to normal. Subsequent treatment courses are recommended.

Claims (2)

1. The method of physiotherapeutic effect, including the selection of biologically active zones (BAS) that are significant for the treatment by measuring the electromagnetic radiation of the millimeter wavelength range (EMR MM) over the skin in a projection of eight zones, such as Uz1, the projection of which is located on the skull cover just before the crown of the head; Uz2, the projection of which is located on the skull cover directly above the external occipital protrusion; Uz3, the projection of which is located on the front surface of the jugular notch of the sternum handle; Uz4, the projection of which is located on the front surface of the body over the grip-sternal synchondrosis; Uz5, the projection of which is located on the front surface of the body above the apex of the lower sternum triangle; Bz1, the projection of which is located on the front surface of the body directly under the cartilage of the IX and X ribs on the right; Bz2, the projection of which is located on the front surface of the body directly under the cartilage of the IX and X ribs on the left; Bz3, the projection of which is located on the front surface of the pubic bone body, with subsequent processing of each measured signal by digitizing it, calculating the spectral characteristics and plotting two graphical dependences: the dependences of the measured signal intensity over time and the distribution of the spectrum of the measured signal, the obtained curves are analyzed, and in the presence of a slow or fast oscillatory process of changes in signal intensity over time in the first graph and / or the absence of of the potential dependence of the frequency distribution in the second graph, the studied BAS is selected for the therapeutic effect, which consists in conducting at least 14 sessions, each of which includes sequential irradiation of the projection area of the skin of the selected BAS with low-intensity pulsed electromagnetic radiation in the frequency range 0.03-500 GHz in 1.5-3 minutes, after the end of the course, a control measurement of EMR MM is performed over the skin in the projection of the BAS, processing of the measured s Nala and analysis of its results, taking into account that either appoint an additional course of treatments, or abandon treatment. 2. The method according to claim 1, characterized in that the control measurement of EMR MM over the skin in the projection of the BAS is carried out after each additional course of procedures, the number of additional courses is determined by the analysis of the results of processing each control measurement.

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