EA000494B1 - Device for local magnetotherapy - Google Patents

Abstract

1. A method for magnetotherapy consisting of positioning an inductor close to the organ subjected to therapeutic treatment, exposing said organ during the certain time period to pulse magnetic field at the impulse frequency of magnetic field being harmonized with the organ biological cycle, measuring at least one characteristic of the tissue in the area of said organ during the magnetotherapy session, characterized in that for a biological cycle determining pulse rate of magnetic field, is registered a characteristic frequency response of the measured parameter, the time for administering the session of treatment is determined upon obtaining a change of the measured parameter. 2. The method according to Claim 1, characterized in that for a measured parameter is determined impedance and/or an magnetic permeability and/or a temperature and/or an acoustic parameter of tissues of the organ subjected to treatment. 3. The method according to Claims 1 and 2, characterized in that a therapeutic session is administered at least in two steps while the first, preparatory step is conducted till the first change of the measured parameter is obtained, and the session is discontinued at the next change of the measured parameter. 4. The method according to Claim 3, characterized in that at least two parameters are measured and the first preparatory step is conducted till the change of the first measured parameter is obtained, and the therapeutic session is discontinued at the next change of the other measured parameter. 5. The method according to Claims 3, 4, characterized in that the field amplitude is gradually reduced in the course of the second step. 6. The method according to Claims 1 to 5, characterized in that the frequency of pulse rate is selected on the basis of analysis of quasi-periodical signals. 7. The method according to Claims 1 to 6, characterized in that the frequency of pulse repetition is selected on the basis of analysis of quasi-periodical signals.

Description

The present invention relates to medicine, in particular to magnetotherapy of various diseases and abnormal phenomena in humans and other living organisms. The invention can be used in the treatment and prevention of various diseases and abnormalities.

Known methods for local therapeutic effects on the human body of a magnetic field of high-frequency electromagnetic waves that cause a thermal effect [1]. Such methods are widely used in practice in physiotherapy rooms, however, they mainly use the heating function and, in some cases, may be contraindicated.

Known methods of magnetotherapy, consisting in the effect of a pulsed or alternating magnetic field of low frequency on various organs that determine the type of magnet used in the form of a probe, solenoid, etc. [2]. Such methods allow local effects on the selected organ, but do not determine the parameters of this effect.

A known method of magnetotherapy [3] for the treatment of gynecological diseases by irradiating a biological object with a moving in time and space pulsed magnetic field of low frequency (like a traveling wave), which coincides with a contraction of the heart muscle.

A device for implementing the above method generates packets of pulsed magnetic fields of direct current with a heart rate and synchronized with the latter, and the magnitude of the magnetic induction at each processed point of the biological object varies from 0 to maximum 40-60 mTs and again smoothly to 0, which is one from important healing factors.

In this method, the packet of pulsed magnetic fields is displaced discretely, by a distance corresponding to the distance between the axes of the fields in the packet.

There is also a method similar to the above [4] for treating patients with chronic coronary heart disease, which consists in synchronizing the traveling magnetic field with the cardiac cycle.

Typically, in such methods, the therapy is carried out in sessions for certain periods of time, the duration of which is determined by the doctor. Moreover, in the process of exposure, individual characteristics of the organ and the organism as a whole during the procedure are not taken into account, which reduces the objectivity of assessing the duration, number and frequency of procedures to obtain the maximum positive therapeutic effect. Moreover, with a significant overdose, the therapeutic effect may be negative.

Known methods for measuring the parameters of biological organs, such as measuring the resistance between two or more zones of the human body [5].

There are also known methods of measuring the impedance of biological tissues when exposed to magnetic fields, for example, a method for determining human resistance [6]. This method allows the examination of persons exposed to magnetic fields by determining the quasistationary potentials between the forehead and hand and calculating the gradient of resistance, but does not allow an assessment of the state of individual organs.

In the course of research, the authors found that when exposed to a magnetic field, biological tissues, when a certain dose is set, change their characteristics, in particular, impedance (resistance). As it turned out, this indicates the adequacy of the effects and changes in the organ tissue carried out by a magnetic field. From this we can conclude that further exposure does not lead to further changes and can even be harmful, leading to tissue inhibition and a decrease in the therapeutic effect.

According to the invention, an inductor of one form or another, determined by the maximum degree of proximity of the inductor to the selected organ, is placed near this organ, exposed to this organ by a pulsed magnetic field with a magnetic pulse frequency, consistent with the biological rhythm of the organ, for a certain period of time and measured at least one parameter of tissue in the region of said organ during magnetotherapy. The method is characterized in that as the biological rhythm that determines the frequency of the magnetic field pulses, choose the characteristic frequency of the response of the measured parameter to the influence of the magnetic pulse, and the time of treatment is determined by the change in the measured parameter.

As a measured parameter, measurements of temperature, electrical impedance, tissue magnetic permeability, acoustic location, or measurement of the acoustic response to magnetic effects in the area of the organ being treated can be performed.

The method also differs in that the treatment session is carried out in at least two stages, the first stage, preparatory, leading to the first change in the measured parameter, and the session is terminated with a subsequent change in the measured parameter. Thus, when measuring only one parameter, changes occurring in the organ tissues during the preparatory stage of therapy or tissue heating are detected, and then subsequent changes that occur directly during therapy. At the same time, at the first stage, due to the action of closed currents of the magnetic field, an increase in blood flow, activation of cell activity, metabolic processes in cells and membranes can occur. At the second stage, the direct function of the organ should be stimulated, which should also be observed in a subsequent change in the measured parameter.

When measuring at least two parameters, the first is the preparatory stage, they lead to a change in the first measured parameter, and the session is terminated with a subsequent change in another measured parameter.

According to one example of the method, the amplitude of the field is gradually reduced during the second stage so as not to cause the inhibitory effect of an overdose of the magnetic field.

The pulse repetition rate is selected based on the analysis of quasiperiodic signals. The analysis can be carried out according to the technique given in [7].

Based on the same analysis, the pulse repetition rate is also determined.

In FIG. 1 and 2 are illustrations of an example application of the method. In FIG. 1 is a diagram of therapy and measurements in the treatment of prostate diseases.

In FIG. 2 is a graph of a sensor signal in the indicated example. Possible embodiments of the method. The impact on the organ undergoing therapy is carried out by packs of pulses of a magnetic field, the repetition rate of the packs is consistent with one of the biological rhythms (heart rate, alpha rhythm, etc.), usually in the range from 1 to 10 Hz. The pulse repetition rate in the packet is selected based on the response of the measured parameter of the organ being treated (usually about 100 Hz or more). The measured signal is analyzed, the amplitude of the magnetic field is set at the level of the absence of sensations of influence (reflex nature), although during therapy the sensations of an integral nature can further arise, and during the treatment of the genital organs even an orgasm can occur. Usually fields with induction of 1-50 mT are used. In the proposed method, it is preferable to use fields with an induction of 1 -1 0 mT, as they do not cause a physiological or reflex action, but have only a stimulating effect.

According to the application, at least one of the parameters is measured in the course of therapy, which can determine the changes that occur in the tissues of the organ. For these purposes, the resistance or impedance of the tissues of an organ or tissues in the immediate vicinity may be measured. In general, it can even be the temperature of the organ, although this parameter is one of the most inertial. One of the most acceptable parameters is the measurement of tissue magnetic permeability. Any of these measurements can be carried out either by a special sensor, or by a sensor combined with an inductor. Studies have shown that when conducting magnetic field therapy, biological processes in tissue cells are stimulated and this is reflected in a change in the electromagnetic and other parameters of the tissues of the organ exposed. In the process of therapy, this parameter changes and, accordingly, the duration and intensity of the session can be determined from this change.

In the process of research, it was also found that changes in biological activity and, accordingly, the measured parameter occurs in two stages. At the first stage, the cells are prepared, i.e., their preliminary heating. At the same time, a change in the measured parameter occurs - the first change. Then, in the continuation of the process, a magnetic field is applied, which directly stimulates and normalizes the functions of the selected organ. During the second stage - the stage of direct therapy - the value of the measured parameter can remain unchanged or smoothly change, and then experience a change when saturation is achieved.

It is advisable to carry out these two stages in different modes, because at the first stage it is necessary to overcome the inertia of the state or pathology of the organ, and the process of stimulation or normalization should be carried out in the soft mode. For this, the amplitude of the magnetic field directly during therapy can be reduced. Moreover, the subthreshold effect during stimulation has a more effective effect and does not cause side effects.

During therapy, it is preferable to measure simultaneously two independent or related parameters, for example, impedance and magnetic permeability. The use of this method increases the reliability of information about the course of the therapy process. At the same time, the state of organs, their readiness for stimulation, saturation, or adequacy of the dosage of the magnetic field can be evaluated using various parameters.

The measured parameters can be estimated by analyzing quasiperiodic signals using a computer or a dedicated processor. Based on this analysis, exposure parameters can be selected, such as the pulse packet repetition rate and the pulse repetition rate in the packet, the amplitude and duration of the session at each stage.

Thus, in each case and for each patient, therapy is carried out until a positive effect is achieved and, depending on the individual patient and his condition. Moreover, choosing the frequency and amplitude of the magnetic field pulses individually, based on the analysis of signals using a computer or a special analyzer, they achieve the optimal mode. For this, the repetition rate of the magnetic field pulses is chosen comparable with the characteristic frequency of the organ being treated (usually of the order of 100 Hz), and the repetition rate of bursts of pulses (of the order of 1-10 Hz). The amplitude of the magnetic field pulses is chosen below the threshold of reflex sensitivity, i.e. exposure to a magnetic field becomes more effective and the likelihood of side effects is significantly reduced.

Example. Figure 1 shows a diagram of therapy and measurements in the treatment of diseases of the prostate gland.

In particular, in the treatment of prostate diseases, a sensor for measuring the parameter of tissue conductivity characteristics near the body being treated can be made in the form of a catheter at which an even number of electrically conductive rings are located at a certain distance from each other, which are electrically connected to a commuting, recording and analyzing devices.

The sensor 1 is inserted through the urethra and placed directly in contact with the prostate gland 2. The therapeutic magnetic inductor 3 (administered rectally) is placed in the rectum so that the therapeutic magnetic field is directed to the prostate gland. Sensor 1 detects a change in the conductivity of the prostate gland at times between individual pulses of a therapeutic magnetic field. Since in the process of magnetotherapy there is a change in the active and reactive components of the conductivity of the organ, therefore, the magnitude of the signal coming from the sensor 1 to the signal analyzer or computer changes.

The signal change of such a sensor is shown in FIG. 2. Clinical trials have shown that, depending on the individual characteristics and the specific condition of the patient, the absolute value of the conductivity signals lies in a wide dynamic range. In the process of magnetotherapy, the signal value can smoothly change, both in the direction of increasing the absolute value, and in the direction of its decrease. However, in the vast majority of patients (at least 80%), at some point in time, a sharp change in the signal level occurs (region A), which is about 30% of the signal amplitude and is easily recorded by the signal analyzer. This provides an individual dosage in the process of magnetotherapy. Upon subsequent exposure to a magnetic field, the signal magnitude stabilizes, but at a certain point in time, a second change in the signal occurs, which is also recorded by the analyzer. This second change can be identified with the beginning of the normal functioning of the body.

With too long exposure, a weakening of the stimulating effect can occur, the intensity of biochemical processes can change, and with further exposure to the magnetic field, even oppression can occur. Therefore, it is advisable to stop the therapeutic effect of the magnetic field upon the normal functioning of the organ, or after a short period of time after the start of functioning, which is monitored by the second change in the measured parameter.

When two parameters are measured simultaneously, the first stage can be determined by one of the parameters, and the end of the second stage by the second measured parameter.

An external manifestation of the functioning of an organ can also serve as a criterion that determines the duration of the second period. So, for example, in the above example, the appearance of an erection can serve as a criterion. In the treatment of female organs, the onset of orgasm is also possible.

The magnetic field parameters are selected on the basis of a computer analysis of quasiperiodic signals described, for example, in [7].

Clinical trials have shown high efficiency of the applied method and had no complications.

Information sources

1. Handbook of physiotherapy (edited by VG Yasnogorodsky). M., Medicine, 1992, p. thirteen.

2. Methodical recommendations. Differentiated use of magnetic fields for neurological manifestations of lumbar osteochondrosis. NININF Ministry of Health of the BSSR, Mn. 1990, p. 14.

3. The method of pulsed magnetic therapy of biological objects and a device for its implementation. Application RU No. 94009616, A 61N 2/00.

4. A method for the treatment of patients with chronic coronary heart disease. Auth. St. SU No. 1537276, A 61N 2/00.

5. A method for determining the resistance of a person to the influence of a magnetic field. Auth. St. SU No. 1648344, A 61B 5/00.

6. A method for determining the active component of the impedance of biological tissue and a device for its implementation. Auth. St. SU No. 1547808, A 61B 5/00, 5/02.

7. The method of analysis of quasiperiodic physiological signals. Auth. St. SU No.

Claims (7)

1. The method of local magnetotherapy, which consists in placing the inductor near the organ being treated, exposing the organ to a pulsed magnetic field with a magnetic field pulse frequency consistent with the biological rhythm for a certain period of time, measuring at least one tissue parameter in areas of the specified organ in the process of magnetotherapy, characterized in that as a biological rhythm that determines the frequency of the magnetic field pulses, determine the characteristic response frequency is measured the first parameter, wherein the time of the therapy session is determined by obtaining the measured parameter changes. 2. The method according to claim 1, characterized in that the impedance and / or magnetic permeability and / or temperature and / or acoustic parameter of the tissues of the organ to be treated are determined as the measured parameter. 3. The method according to claims 1, 2, characterized in that the therapy session is carried out in at least two stages, the first stage, preparatory, leading to the first change in the measured parameter, and the session is terminated with a subsequent change in the measured parameter. 4. The method according to claim 3, characterized in that at least two parameters are measured, the first stage being preparatory, leading to a change in the first measured parameter, and stopping the session upon subsequent change of another measured parameter. 5. The method according to PP.3, 4 characterized in that the field amplitude is gradually reduced during the second stage. 6. The method according to claims 1-5, characterized in that the pulse repetition rate is selected based on the analysis of quasiperiodic signals. 7. The method according to claims 1 to 6, characterized in that the pulse repetition rate is selected based on the analysis of quasiperiodic signals.