RU2080136C1 - Apparatus for magnetoinfrared therapy - Google Patents

Abstract

FIELD: medical engineering, equipment for combined treatment with magnetic fields and optical radiation in infrared spectral region. SUBSTANCE: apparatus comprises cylindrical casing having lid at its axial end, magnets carried by disc mounted on shaft of electric motor housed by casing to generate rotating magnetic field on side of casing axial-end lid and infrared radiation sources connected to excitation system and made in the form of light-emitting diode or diodes adapted to emit coherent light. Novelty is that infrared radiation sources are arranged on partition disposed in casing interior on side of disc opposed to patient. Disc is made in the form of shutter that is profiled in its rotation plane. Disc-shutter comprises projections and recesses for fixing magnets therein, and openings for periodically emitting infrared radiation in direction of casing axial-end lid. The latter is provided with openings coaxial to light-emitting diodes for exposing patient to infrared radiation. Apparatus also comprises at least one additional light-emitting diode, its optical axis lies in shutter plane situated at mid-height of magnet-carrying projections and is oriented in radial direction. Additional light-emitting diode is secured to projection protruding from inner side of axial-end, while said casing has in its side wall opening coaxial to additional light-emitting diode and intended for passage of infrared rays. Apparatus comprises II-shaped shutter adapted to simultaneously cover all of light-emitting diodes, and unit for selecting and varying rotational speed of shutter. Apparatus is very effective since it permits to subject reflexogenic zones and pathologic area of patient's body to combined effect of both magnetic fields and coherent optical radiation within infrared spectral region. EFFECT: higher efficiency of treatment. 4 cl, 3 dwg

Description

 The invention relates to medical equipment, in particular to devices for the combined effect on reflexogenic zones and pathological parts of the body with magnetic fields and optical radiation of the infrared (IR) range, emitted by LEDs and LEDs with coherent radiation (laser diodes).

 Work is known that confirms the fact that the combined action of laser radiation and a magnetic field has higher therapeutic efficacy compared to their separate use, since their combined use leads to a synergistic effect (A.K. Polonsky et al. Experimental and clinical aspects of magnetic laser Therapy. Pathological physiology and experimental therapy M. Medicine, 1984, issue 3, p. 49 52). At the same time, it was possible to reduce the exposure to the pathological focus compared to using only laser radiation (MA Matyashova et al. Laser and magnetic laser therapy. / Ed. By A.K. Polonsky M. VNIIMP, 1985, issue 3) . The method of magnetic laser therapy is used in the treatment of bruised wounds and open fractures of limb bones. The therapeutic effect was obtained during exacerbation of chronic diseases: thrombophlebitis of the lower extremities, bursitis and deforming arthrosis of the joints, spinal osteochondrosis. In neurological practice, the method was used in the treatment of diseases of the peripheral nervous system: neuritis, radiculitis, sciatica, etc. Due to the ease of use and the almost complete absence of harmful side effects on both the patient and the staff, the method is widely used in various fields of practical medicine ( VV Krivenko et al. Non-traditional methods of diagnosis and therapy. Kiev, Naukova Dumka, 1990, p. 313 315).

 It should be noted that the method of magneto-infrared therapy is realized both with the use of LEDs emitting spontaneous IR radiation, and laser LEDs emitting coherent radiation. The rationale for the therapeutic benefits of using LEDs with coherent radiation is quite controversial, since studies have shown that when passing through skin and tissue with a thickness of tenths of a millimeter, the laser beam does not preserve coherence and polarization, i.e., radiation penetrating deep into the body from a laser source acts like an ordinary unpolarized and incoherent light in the corresponding spectral region (V.I. Kozlov, V.A. Builin. Laser therapy. M. Vladivostok, 1992, p. 8, 47). In other works, it is argued that the coherence of radiation plays an important role, since the complex and extremely optical anisotropic structure of biological objects having a quasi-liquid crystal structure makes it possible for radiation to propagate through living tissue in the waveguide mode, to undergo diffraction and self-diffraction on inhomogeneities with the formation of various interference patterns in the thickness of the tissue, which contributes to a significant concentration of radiation and stimulation of photobiochemical reactions (NK Danilov, A. N. Malov. On the role of the coherence of laser radiation in interaction with biological objects. Materials of the seminar "Application of lasers in science and technology. Novosibirsk, Silap LLP, 1992, p. 98 100).

Practical developments are known in which both IR LEDs and laser diodes are used. In particular, the industry produces devices for magneto-laser therapy: "AMLT-01", designed and manufactured at VNIIMP, Moscow (B. A. Razygrin and others. Magneto-laser therapy and its technical support. Electron-optical and physico-optical equipment. Development and application.Scientific works of VNIIMP, M. 1985, p. 35 37). Erga, Magnetron Research and Production Complex, Kaluga, and Mlada Research and Production Enterprise Lazma, Moscow (work by V.I. Kozlov and V.A. Builin), Uzor-2K Medical and Laser Center, Kaluga (OK K. Skobelkin and others. The use of magnetic laser therapy apparatus on gallium arsenide "Pattern-2K" in medicine. Methodical recommendations. M. 1991, p.76). A known apparatus for magneto-infrared irradiation "MIO-1", in which the light sources are LEDs (G. R. Soloviev. Magnetotherapeutic equipment. M. Medicine, 1991, S. 142 143). Also known are inventions in which various designs of devices for magnetic laser therapy are proposed [1, 2]
The main disadvantage of the aforementioned known apparatuses and devices is the insufficiently high efficiency of exposure to a magnetic field, which is due to the use of permanent ring magnets that are fixed on the body. In this case, such important biotropic parameters as the frequency and type of the law of variation of the magnetic field are not involved. At the same time, it is known that a pulsed magnetic field is characterized by greater biological activity compared to sinusoidal and pulsating fields, and the constant magnetic field has the least effect (work by G.R.Solovieva, p.20). This fact corresponds to the general position that an increase in the number of parameters and their intensity increases the efficiency of exposure to a magnetic field. The rotating magnetic field, whose biotropic parameter is the direction and speed of rotation of the magnetic induction vector, has a great effect on biological objects.

 At the same time, it is known that the maximum effectiveness of treatment is achieved with biosynchronized exposure in accordance with the rhythms of muscle tone, pulse and respiration of the patient, taking into account the speed of blood flow. The most “effective” in this sense are low frequencies of exposure (work by V. I. Kozlov and V. A. Builin, p. 67). For example, the frequency of 1, 2 Hz is the "fundamental frequency", the basis of so many rhythmic processes in the body that are multiples of this frequency. Indeed, 1.2 Hz is 72 beats per minute, the rhythm of cardiac activity.

 “Exciting” frequencies from 1 to 6 Hz, “inhibiting” from 6 to 10 Hz. 1 Hz laser modulation is used to treat foci of infection; 2 2.5 Hz for the treatment of burns (effect on the points of "consent"); 5 Hz in rheumatology (effect on sedative points); 10 Hz in traumatology (impact on tonic points); 20 Hz is used to act on herald points; 40 Hz to the point of origin of the meridians with muscle atrophy; 80 Hz for exposure to infectious foci (wounds, ulcers) and to the end points of meridians. The known apparatus does not allow the simultaneous exposure to a magnetic field and infrared radiation at low modulation frequencies and the preservation of the same intensity of infrared radiation in the entire range of the above frequencies of optimal biosynchronization.

 The objective of the invention is to create a device for magneto-infrared therapy that meets the requirements for mass (mainly home) devices with regard to simplicity of design, minimizing dimensions and cost, ease of management and selection of exposure modes in accordance with previously developed methodological recommendations. At the same time, the apparatus should have expanded functionality with respect to the set of biotropic parameters used, provide a reduction in the duration of the procedure (with an established diagnosis of the disease) without losing the therapeutic effectiveness of the combined effect of heterogeneous physical factors.

 The technical result of the invention is expressed in the creation of a structurally simple, small-sized and technologically advanced apparatus for mass application that provides high efficiency magneto-infrared exposure at modulation frequencies that meet the principles of biosynchronized resonant effects on reflexogenic zones and pathological tissues, organs and systems of the human body. At the same time, the device has the ability to select therapeutic treatment modes by combining IR radiation with either rotating or pulsating magnetic fields. The range of modulation frequencies used includes the most bioresonant frequencies in the range from units to several tens of hertz. Such capabilities are not provided by any of the known devices for magneto-infrared therapy.

 The essence of the invention lies in the fact that in the device for magneto-infrared therapy, which includes a cylindrical body with an end cap, magnets mounted on a disk mounted on a shaft of an electric motor located in the body, and generating a rotating magnetic field from the end cap of the case, as well as connected to excitation system sources of infrared radiation in the form of LEDs or LEDs with coherent radiation, infrared radiation sources are placed on a partition located in the cavity case on the side of the disk opposite to the patient, the disk is made in the form of a shutter shaped in the plane of rotation, containing protrusions with recesses for attaching magnets to them and holes for periodically transmitting infrared radiation in the direction of the end cover of the case, and the cover has holes for removing infrared radiation to the patient, coaxial with the LEDs. The device contains at least one additional LED, the optical axis of which lies in the plane of the shutter, located at half the height of the protrusions with magnets, and is oriented in the radial direction, while the LED is mounted on the protrusion located on the inner side of the end cap, and the housing has a side side hole for removing infrared radiation, coaxial with an additional LED. The obturator has a U-shape in the plane of the cross section, the vertical parts of which are formed by protrusions with magnets, which serve to interrupt the infrared radiation flux emitted in the axial or perpendicular directions by the main and additional LEDs. The device is equipped with a unit for changing and selecting fixed values of the shutter speed and connected to the LED power supply.

 In FIG. 1 shows a cross section of a device in a longitudinal plane; in FIG. 2 section in the plane AA at the position of the obturator, providing overlapping of radiant fluxes from the main and additional LEDs; in FIG. 3 cross-section along AA at the position of the obturator, which ensures the transmission of radiant fluxes from the LEDs in the directions of the longitudinal and transverse planes (the obturator is shown in a design having a U-shape and corresponding to paragraph 3 of the formula).

 The device comprises a cylindrical housing 1 with an end cap 2, pressed against the housing 1 by an annular retainer 3 of a threaded or bayonet type. At least two permanent magnets 4 and 5, made on the basis of rare-earth materials, are mounted on a disk 6 mounted on a shaft 7 of an electric motor 8 located in the housing 1. The magnets 4 and 5 are turned towards the cover 2 by the opposite poles "N" and "S " The device has at least two LEDs 9 and 10, mounted on a partition 11 located in the cavity of the housing 1 from the side of the disk 6, opposite to the patient. The LEDs 9 and 10 are connected to an excitation system consisting of a power supply 12, which converts an alternating voltage of 220 V of an industrial network into a constant low-voltage voltage. A power unit 12 is also connected to a unit 13 having a vernier (not shown) brought to the surface of the housing 1. With it, you can change and select the fixed values of the rotational speed of the electric motor 8 and, therefore, the disk 6. The disk 6 is made in the form of a shutter, profiled in the plane of its rotation. It contains protrusions 14 and 15 with recesses in which magnets 4 and 5 are fixed. The obturator 6 also has openings 16 and 17 (Fig. 2) for periodically transmitting IR radiation in the direction of the end cap 2 having openings 18 and 19 (Fig. 1 ) to remove the IR radiation to the patient, coaxial with the LEDs 9 and 10. When performing the obturator 6 in the embodiment shown in FIG. 3 and having a U-shaped cross-section, the disk 6 with the holes 16 and 17 are absent, and the obturator has a strip 20 connecting the protrusions 14 and 15 and mounted in the middle on the shaft 7. The device also has at least one additional LED 21 connected to the power supply 12. The LED 21 is mounted on the protrusion 22 located on the inner side of the end cover 2, and its optical axis lies in the plane of the obturator located at half the height of the protrusions 14 and 15 with magnets 4 and 5. The optical axis of the LED 21 oriented to radio direction so that the infrared radiation flux generated by it passes through an opening 23 in the side wall of the housing 1, coaxial with the LED 21. In block 12 there is a switch (not shown) that supplies power to the LEDs 9 and 10 in the case of magneto-infrared therapy with rotating magnetic field or LED 21 in the case of magneto-infrared therapy with a pulsating magnetic field. When the power is turned off from all the LEDs, a therapy mode is provided with rotating or pulsating magnetic fields, depending on which part the device is brought to the pathological focus: end cap 2 or side surface of housing 1 in the area of the hole 23.

 The device operates as follows. When you turn it on to an AC voltage of 220 V, block 12 generates a low-voltage DC voltage, which is supplied to block 13. Using block 13, the voltage is adjusted in a range that allows you to select the speed of rotation of the shaft 7 of the electric motor 8 in the range from several tens to 9000 rpm (for example, for the engine ДПМ-20-Н1 / Н2-16) and, therefore, the choice of modulation frequencies of magnetic fields and radiant fluxes using a shutter 6. In particular, when there are two magnets placed on a shutter ore as shown in FIG. 1, the frequency of rotation of the magnetic induction vector from the end cap 2 can be selected in the range from tenths of a hertz to 150 Hz, which allows you to cover the range of the main frequencies used in biosynchronized therapy. On the side surface of the housing 1 there are pulsations of a magnetic field with a frequency of up to 300 Hz, with half of the alternating pulsations having one direction of the magnetic induction vector, and half the opposite. The choice of magnetotherapy modes with rotating or pulsating fields, as well as rotation frequencies and pulsations, is made in accordance with the specific methodological recommendations developed for this pathology. When applying a low-voltage voltage from block 12 to the LEDs 9 and 10, the latter begin to emit infrared radiation in a continuous mode. This radiation is blocked by a shutter 6 rotating with a given frequency and comes out in the form of pulses only at times when the protrusions 14 and 15 are in a horizontal (perpendicular to the plane of the drawing) plane. At such moments, IR radiation passes through the holes 16 and 17 (Fig. 2) in the disk 6 (which may not only have a circular shape) or past the strap 20 (Fig. 3). Next, the radiation through the holes 18 and 19 in the end cap 2 fall on the patient's body. The moments of the appearance of IR radiation pulses are in strict phase dependence with respect to the angular position of the magnetic induction vector, and the amplitude of the pulses does not depend on the modulation frequency chosen. The uniformity of exposure to the diseased area is achieved by moving the device relative to the surface of the body.

When connecting to the block 12 of the LED 21, mounted on the protrusion 22 of the cover 2 so that its optical axis lies in the plane of rotation of the obturator 6, the protrusions 14 and 15 periodically block the emitted IR radiation output to the diseased part of the body through the hole 23 in the side wall of the housing 1 As a result, each pulsation of the magnetic field with the direction of the magnetic induction vector changing by 180 ^{o is} accompanied by a synchronized pulse of infrared radiation independent of the amplitude of the modulation frequency, which predetermines their combined effect yours to a pathological site.

 It is easy to see that the design of the proposed device for magneto-infrared therapy meets the requirements for physiotherapeutic mass applications with regard to simplicity, small size, manufacturability. It uses accessible elemental base and structural materials that are widely used in modern instrumentation. At the same time, the device has significant advantages in terms of functionality with respect to the choice of magneto-infrared exposure modes and the frequency range of modulation frequencies compared to the prototype.

 Currently, in the joint-stock company "NPAP Altaymedpribor" work is underway to organize a wide release of the proposed device, primarily for home use.

Claims (4)

 1. A device for magneto-infrared therapy, comprising a cylindrical body with an end cap, magnets mounted on a disk mounted on a shaft of an electric motor located in the body, and generating a rotating magnetic field from the end cap of the housing, as well as infrared radiation sources connected to the excitation system in in the form of light guides or LEDs with coherent radiation, characterized in that the sources of infrared radiation are placed on a partition located in the cavity of the housing from the side of the dis the opposite to the patient, the disk is made in the form of a sealed obturator in the plane of rotation, containing protrusions with recesses for attaching magnets to them and holes for periodically transmitting infrared radiation in the direction of the end cover of the case, the cover having holes for removing infrared radiation to the patient, coaxial with LEDs.  2. The device according to claim 1, characterized in that it contains at least one additional LED, the optical axis of which lies in the plane of the obturator, located at half the height of the protrusions with magnets, and is oriented in the radial direction, while the LED is mounted on the protrusion, located on the inner side of the end cap, and the housing has a hole on the side for removing infrared radiation, coaxial with the additional LED.  3. The device according to paragraphs. 1 and 2, characterized in that the obturator has a U-shaped in the plane of the cross-sectional shape, the vertical parts of which are formed by protrusions with magnets, serve to interrupt the fluxes of infrared radiation emitted in the axial or perpendicular directions of the main and additional LEDs.  4. The device according to paragraphs. 1 and 2, characterized in that it is equipped with a unit for changing and selecting fixed values of the shutter speed and connected to the LED power supply.

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