RU2061512C1 - Device for magnetic laser therapy - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: device refers to therapeutic systems and can be used in clinics, outpatients's clinics and at home. Drawings 1 and 2 demonstrate variants of device with radiator in the form of laser and light-emitting diodes arranged around it and with light-emitting diodes only. New positioning of light-emitting diodes and laser makes it possible to enhance efficiency of operation of device several times which leads to reduced periods of recovery of patients. This is achieved by positioning light-emitting diodes and laser in one plane and by their contacting membrane. In this case maxima of radiation indicatrices of laser and light-emitting diodes are directed perpendicular to plane of membrane and accordingly to cavity subjected to therapy. Outer surface of case is manufactured in the form of heat-sink and nonworking butt of laser is fitted with row of plates to remove heat which provides stable operation of laser. Proposed design of device increases uniformity of irradiation of center of affection, enhances penetrating capability of laser radiation thanks to enlarged area of magnet and improves sanitary and hygienic properties. Combination of permanent magnetic field with low-intensity light-emitting diode and laser radiation of nearest IR region plus thermal radiation generated by contact of device with cavity subjected to therapy provide: for high efficiency in prophylaxis and treatment of acute and chronical diseases; for wide spectrum of usage; for sufficient reduction or complete absence of treatment with drugs. Proposed magnetooptical laser device for therapeutic treatment utilizes physical factors of natural environment such as magnetic field of 40 mT, IR radiation λ= 0.96 mm - a portion of solar spectrum to which our organisms are adapted. That is why such device may be called magnetooptical biostimulator. EFFECT: simplified design and easy handling for treatment and prophylaxis of various disease and due to this it can be recommended for self-treatment of patients. 2 dwg

Description

 The invention relates to medical systems for magnetic laser therapy and can be used in clinical and outpatient practice, as well as in home treatment.

 Known devices for laser and magnetic laser biostimulating therapy in the treatment of purulent wounds. (1).

The use of a magnetic laser therapeutic unit on an outpatient basis showed:
pulsed laser radiation of the near infrared region of the spectrum in combination with a constant radial magnetic field has a high analgesic effect, relieves inflammation and significantly reduces hyperemia,
high penetrating power (up to 40 mm) of laser radiation and a bioeffective pulse repetition rate make it possible to carry out cavity therapy of damaged biological tissues directly through the skin, which significantly expands the functionality of the method and allows the method to be used for various deep damage to biological tissues.

 The disadvantages of such devices are the bulkiness and inconvenience of operation.

 Known devices for magneto-laser therapy, representing a phonendoscope combined with an optical radiation source and a permanent magnet covering the optical stream.

 The emitter is installed outside the subnet of the funnel of the light phonendoscope along its axis so that the maximum of the radiation indicatrix is directed perpendicular to the contact plane of the funnel, and the LEDs are installed in a circle around the axis of symmetry so that the maximum of the indicatrix of the total radiation coincides with the axis of symmetry. (2).

The main disadvantages of this class of devices are:
insufficient efficiency of the device due to the location of the emitter and LEDs in different planes;
insufficient efficiency of the device due to the location of the emitter at a distance of the depth of the phonendoscope funnel from the cavity of the therapy being subjected, which leads to significant losses in radiation power, and the greater the depth of the phonendoscope funnel, the greater the power loss;
reduced functionality of the method due to the location of the emitter at a distance of the depth of the funnel. Since the penetrating ability of laser radiation is up to 40 mm, the location of the emitter at a distance of the depth of the funnel of the phonendoscope dramatically reduces the penetrating ability of laser radiation and thereby reduces the ability to use the method in the treatment of various deep damage to biological tissues;
the lack of cooling of the laser located in the thermal cushion, created on the one hand by the cavity being treated and heated by LEDs located in the immediate vicinity of the laser, and on the other hand with the hand holding the head of the device, all this violates the normal mode of operation of the laser;
low sanitary and hygienic properties of the device due to the inability to completely disinfect the contact plane of the phonendoscope funnel.

 The aim of the invention is to increase the efficiency of the device and therapeutic effects by minimizing radiation losses.

 An additional objective of the invention is also the expansion of the functionality of the device by increasing the area of the ring magnet without changing the dimensions of the housing, as well as creating conditions for the normal operation of the laser.

 An additional objective of the invention is the use of thermal radiation arising from the operation of the LEDs in contact with the cavity of the therapy to increase the effectiveness of the therapeutic effect of the device.

 An additional objective of the invention is to improve the sanitary-hygienic properties of the device.

 This goal is achieved by the fact that in the known device for magneto-laser therapy, including a housing, an optical emitter consisting of a laser and a number of LEDs, a ring magnet and a power supply system, the LEDs are located in the same plane with the laser so that the maximum indicatrix of the laser radiation and LEDs were directed perpendicular to the cavity of the therapy being treated.

 In the case of the emitter with one LEDs, all the LEDs are located in the same plane and the maximum indicatrix of the radiation of each LED is directed perpendicular to the cavity of the therapy.

 In addition, the goal is achieved by the fact that the plane of the emitters through the optically transparent hygienic film (membrane) is in full contact with the cavity of the therapy.

 In addition, the goal is achieved in that with an increase in the area of the ring magnet, a constant radial magnetic field increases. In combination with laser radiation, a high analgesic effect is achieved, the inflammatory phenomena of the cavity of the therapy being treated are removed, and the penetrating power of laser and LED radiation is increased.

 In addition, the goal is achieved in that the thermal radiation generated by the operation of the LEDs in contact with the cavity of the therapy being subjected, in combination with the action of a magnetic field and laser radiation, increases the efficiency of the therapeutic effect of the device.

 In addition, the goal is achieved by the fact that the emitter body is made in the form of a radiator, and the non-working end of the laser is equipped with a number of plates, which creates the possibility of natural air cooling of the laser and ensures its normal operation according to the technical specifications.

 In addition, the goal is achieved in that the contact surface of the device and the patient’s cavity are separated by a hygienic film (membrane) both for single use and with the use of disinfectants.

 A comparative analysis of the claimed device for magneto-laser therapy with a prototype (Izel apparatus. Methodological recommendations. 1991) shows that the proposed device differs in the location of the emitter: the laser and LEDs are located in the same plane so that the maximum indicatrix of the laser radiation and each the LED is directed perpendicular to the cavity of the therapy undergoing, this arrangement allows to increase the uniformity of exposure and reduce radiation loss over a distance.

 In addition, the proposed device is characterized in that the plane of the emitter through an optically transparent hygienic film (membrane) is brought into full contact with the cavity, which significantly reduces radiation loss in comparison with the prototype (Apparatus "Izel", guidelines. 1991), where the laser and LEDs are located outside the cavity of the phonendoscope funnel and a significant part is lost when radiation passes from the bottom of the funnel to the plane of the funnel end face, which sharply reduces the laser radiation penetration, thereby lowering tsya functionality of the method in the treatment of deep tissues damaged.

 In addition, the proposed device is characterized in that the area of the ring magnet is increased, which significantly improves the functionality of the device.

 In addition, the proposed device is characterized in that the emitter body is made in the form of a radiator, and the non-working end of the laser is equipped with a number of plates, natural air cooling of the laser is created, which ensures the normal operation of the laser according to the technical specifications, in the prototype (Izel apparatus. Methodological recommendations, 1991 d) there is no cooling of the laser, which during prolonged operation of the emitter leads to disruption of the normal operation of the laser, because with increasing temperature, the laser changes its power. Therefore, the use of the emitter body as a radiator is necessary to ensure the normal operation of the laser and increase the efficiency of the device.

 In addition, the proposed device is characterized in that between the plane of the device and the contact cavity of the patient introduced hygienic disposable film. In the prototype (Izel apparatus. Methodological recommendations. 1991) a one-time hygienic cover protecting the contact surface of the device is not provided, and the disinfection of the contact surface is difficult due to the presence of the joints of the magnet and the housing in the contact plane of the phonendoscope funnel with the formation of cracks around the perimeter.

 Thus, the claimed design of the device magneto-laser therapy meets the criterion of "novelty."

In FIG. 1 shows an embodiment of a device with a laser emitter and LEDs mounted around it; figure 2 presents a variant of the device with the emitter on the LEDs
A device for cavity magneto-laser therapy is a radiator body carrying a source of optical stimulated radiation with a permanent magnet covering the optical stream. Semiconductor lasers (ILPN, LDN, etc.) with a wavelength of 0.8 are used as emitters. 1.3 microns and LEDs with a wavelength of 0.5. 0.7 μm and 0.8.1.3 μm.

 Permanent magnet 1 and a set of rings 2 allow you to provide the necessary magnetic induction from 40 to 60 MT.

 For hygienic purposes, the emitter plane is tightened with an optically transparent film (membrane), which can be subjected to cold sterilization (wiping) after each patient or can be used once for infectious diseases. For a quick change of the hygienic film, a ring 5 is provided.

 The case-radiator 7 has such a shape of the ribs that allows you to combine ease of use: the ability to conveniently and reliably hold the device and perform its main function of natural air cooling of the laser.

 For air exchange, through holes are made in the housing. The laser 3 and a series of LEDs 4 are placed in the same plane. The non-working end of the laser is mounted through the plates 8, which are tightly adjacent to the housing 7 and thereby create heat dissipation along the radiator housing.

 The emitter plane protrudes 1 mm beyond the device body, this is necessary to bring the emitter plane into full contact with the plane of the therapy being subjected and for convenient sterilization.

 Boards 9 and 10, indication 11, microswitches 12, and cover 13 are also located in the housing 7. The spacer sleeve 14 holds the board 3, forming a laser air cooling cavity between the plates 8 and the board 3 through the holes in the housing 7, and the sleeve 15 is located between the boards 3 and 10, holds through the rubber sleeve 15 current-carrying wires 17 that connect the radiating head to the power supply 18.

 The operation of the device for cavity magnetic laser therapy is as follows.

 Having determined the localization of the lesion, for example, in the lungs, the emitter plane is brought into contact with the cavity and, with the help of microswitches 12, includes laser and LED radiation.

 Thus produce irradiation of the lesion. For irradiation of small surfaces, it is possible to use diaphragms with holes of different profiles and different diameters.

 The proposed device for cavity magnetic laser therapy surpasses all the advantages of the prototype in terms of ease of use, increasing the penetrating power of laser radiation, reducing the recovery time of patients, as well as improving sanitary and hygienic qualities.

 A prototype of the apparatus of therapeutic magneto-optical low-intensity radiation designed for the treatment of lung diseases in the treatment of pneumonia, pleurisy, bronchitis, etc., has been developed. as well as helping relieve pain in coronary heart disease.

 The device can be used in the treatment of small wounds, burns, injuries, reduce itching.

 The therapeutic effects of the device can be combined with medication and other therapeutic agents.

 The use of the device is effective for the treatment of adults and children, especially in case of allergic reactions to drugs and drug intolerance.

 Technical characteristics of the prototype.

Radiation wavelength, microns:
laser 0.8.1.3
LED 0.65.1.3
Radiation power, mW
laser 3.40
LED 60.120
Magnetic induction at the exit, MT 40
The number of radiation sources, pcs. 7.12
Nutrition:
voltage, V 220- + 22
frequency, Hz 50 1
Power consumption, VA (no more) 6
Weight of a radiator, kg (no more) 0,1
Overall dimensions of the electronic unit, mm 60x100x80
Overall dimensions of the radiating head, mm f 50, height 43.

 The proposed device for cavity magnetic laser therapy, in addition to the above advantages over the known ones, is harmless to the personnel working with it and, due to its compactness, is convenient when visiting a patient at home.

 In addition, the simplicity and accessibility of the development of techniques for working with the device allows you to use it for self-treatment.

Claims (2)

 1. Device for magnetic laser cavity therapy, comprising a housing with a membrane, an optical emitter containing a laser and a number of LEDs, a ring magnet and a power system, characterized in that the LEDs and the laser are located in the same plane and are installed with the possibility of contact with the membrane, the maximum of indicatrixes of laser radiation and LEDs are directed perpendicular to the plane of the membrane.  2. The device according to p. 1, characterized in that the outer surface of the housing is made in the form of a radiator, and the non-working end of the laser is equipped with a number of plates to remove heat.

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