RU2059420C1 - Medical-diagnostic magnetotherapeutic device - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: device has head with optical irradiators and reflector, plug, magnet which is mounted at the output, aid for indicating work of the irradiators, removable washers-diaphragms. Relation of H distance from the top point of the reflector to working surface to diameter D of this surface is equal to 0.3-0.8. The head may be provided with a cylindrical insertion (or with a set of insertions) with reflectors. The head is mounted for movement. Photodiode is mounted onto the surface of the reflector. Magnet is mounted for removal in form of several sections, as well as in form of a film with coating. Functional detectors (temperature detectors) are disposed at the working end of the head. The detectors are used for reading biological parameters. Device may be also provided with washers-diaphragms provided with irradiators, mounted inside the case. The irradiators are made in form of cones and have optical focussing system. Walls of the plug are perforated. Device may be provided additionally with sound-perceiving detector placed onto the surface of the reflector at the edge surface of the head, inside coupling. EFFECT: improved reliability of diagnosis; improved efficiency. 16 cl, 11 dwg

Description

 The invention relates to diagnostic and therapeutic systems, mainly to devices for laser (light) therapy and auscultatory determination of the localization of the inflammatory focus of internal organs, and can be used in clinical and outpatient practice.

 It has been established that low-intensity laser radiation is an effective factor in the treatment of long-term non-healing wounds, ulcers, in dentistry, traumatology, urology, proctology, in the treatment of patients with pulmonary, cardiovascular pathology, in postoperative therapy.

 A device for laser light therapy "Pattern" (ALT), including the head (blocks) of optical radiation, a power supply and control system, as well as nozzles, magnet holder, sleeve and tip. The disadvantage of this device is the large weight and dimensions, inconvenience in operation, the presence of removable bulky nozzles, a decrease in the accuracy of radiation falling on the lesion, and insufficient efficiency of the device.

 Closest to the claimed device is a device (apparatus) for magneto-laser therapy of the Isel type, comprising a head with a reflector and optical emitters with a plug and a ring magnet mounted at the end (output) of the reflector, a power system, a control unit, mainly, the operation of optical emitters, indicator of laser and light infrared radiation and a set of interchangeable diaphragms. The disadvantages of this device is the lack of the ability to quickly change the physical factors and their parameters, radiation loss, lack of effectiveness on the body, because, adapting to the conditions of exposure to magneto-laser therapy, the body’s immune system is not active enough. In addition, the device does not provide feedback with the body, that is, it does not provide for monitoring the body's response to radiation. In addition, upon contact with the patient, fogging of the working surface of the emitting head is possible, which results in a decrease in its reflectivity and laser radiation power. The device also does not allow to observe the picture of the distribution of radiation in the working surface of the reflector, the work of the emitters.

 The technical effect of the claimed device lies in the increased efficiency of exposure to the body by optimizing the size of the reflector (i.e., the radiating and acoustic surfaces of the zones), in the ability to control the reaction of the body, increasing the radiation power, expanding the functionality.

 The specified technical effect is provided in the claimed device, including the head of an optical emitter with a reflector and a magnet installed at the output, a plug, a power system, a control unit and an indication of optical radiation (IR, UV). The ratio of the distance H from the top of the reflector to the working surface in which the emitter is located, to the diameter of its working surface D is 0.3-0.8. The head is equipped with a cylindrical insert located along the central axis, the end surface of which is made with a reflector along one generatrix (flush) and installed with the possibility of movement, and emitters are fixedly located in the end surface, a reflective and / or protective coating is applied to the external surface of the insert, and the inner surface is provided with a soundproof coating.

 In addition, the device can be equipped with a set of cylindrical inserts, each of which contains emitters generating radiation of certain wavelengths.

 Emitters (in an amount of at least one) are located on the concave surface of the reflector parallel to the central axis or at an angle to it, in concentric rows uniformly along the generatrix, in a checkerboard pattern or in another order. As emitters, the device can contain lasers, LEDs, or a combination of both with the same parameters, and of different power and operating modes in the wavelength range from UV to IR spectrum.

 In addition, a photodiode is predominantly flush mounted on the surface of the reflector.

 The permanent magnet can be made sectional, as well as in the form of a film with a sputtering, with constant intensity or with sections of different magnetic field strengths, and the magnet can also be quick-detachable.

 On the working end of the head or on its lateral surface there are functional sensors mainly of the ECG type, temperature sensors, for removing biological indicators associated with the control system.

 In addition, the claimed device can be equipped with a nozzle-diaphragm with emitters installed in its body, arranged concentrically rows evenly on the surface, in a checkerboard pattern or another order, and as emitters, the nozzle contains lasers, LEDs, or a combination thereof, both with the same and with different wavelengths, the same or different power, with different modes of operation (pulsed, continuous). The device can be equipped with a nozzle-diaphragm made conical (or a set thereof) with a through hole at the apex and a hollow inside (and / or containing a light guide), the inner surface of which is made of reflective material or with a reflective or protective coating. The coatings used in the device can be made of aluminum, silver, gold, copper, magnesium, titanium and other materials, and polishing of materials can also be used. In order that the reflective coating does not warp, does not oxidize, especially under the influence of disinfecting solutions, it is coated with protective coatings, varnishes, and oxide films.

 The inner surface of the head (reflector) and nozzles are made of material with reflective properties or have a reflective coating in the wavelength range generated by the emitters.

 Also, the device can be equipped with a nozzle-diaphragm equipped with an optical (focusing) system. All nozzles are attached to the head (put on it).

 The reflecting surfaces of the reflector, inserts, nozzles, diaphragms, plugs, are equipped with a water-repellent or non-wettable coating. The walls of the plugs, primarily protruding above the surface of the head, are perforated.

 The device is equipped with various sizes and configurations with nozzles-diaphragms, which can be transparent, to visualize the UV and IR range, with a phosphor applied to the surface. In addition, the device can be equipped with a sound pickup sensor (microphone) located flush on the surface of the reflector, on the end surface of the head or in the fitting.

 The claimed combination of distinctive features, leading to a technical effect, which consists in increasing the therapeutic effectiveness of exposure to the body, the ability to control the state of the body and its response to therapeutic effects, in increasing the radiation power, expanding functionality.

 In FIG. 1 shows a General view of the device; in FIG. Option 2 with a removable magnet; in FIG. 3 and 4 options with a cylindrical insert; in FIG. 5 embodiment of the location of the emitters; in FIG. 6 placement of a permanent magnet; in FIG. 7 supplying the device with a functional sensor; in FIG. 8 embodiment of the nozzle-diaphragm with emitters; in FIG. 9 option with a nozzle-diaphragm made conical; in FIG. 10 implementation of the nozzle-diaphragm with an optical focusing system; in FIG. 11 the implementation of perforated plugs; in FIG. 12 location of the control photodiode.

 A device for magneto-light-laser therapy contains a radiating head 1, optical emitters 2 mounted in the body of the head 6 or insert 9 and located in the surface of the reflector 3.

 As emitters, lasers, LEDs, or combinations thereof are used. Moreover, the characteristics of the emitters: wavelength, power, energy, continuous or pulsed operation, etc. can be the same and different. The optimal range of wavelengths of radiation used emitters is 0.4-1.2 microns, but can be used 0.1-1.4 microns. For joint exposure of the patient to optical radiation and a magnetic field, the device is equipped with a permanent magnet 4, which can be not only annular, but also sectional, and also made in the form of a film deposited on the working surface with a rare-earth metal sputtering, for example, samarium-cobalt.

 The magnet can be made both stationary and quick-detachable due to the technical features of its attachment to the head. Moreover, the indicator of magnetic tension can be both constant and different in sections. Replaceable diaphragms 5 are attached to the housing 6 of the replaceable head at its working end, and if they are made of metal or with a metal strip, then they are easily magnetized to the magnet. The device is equipped with a power source with a control and indication unit 7. A magnet can also be placed in the holder 8, if it is quick-detachable.

 The head may be provided with a cylindrical insert 9 or a set of cylindrical inserts 12 in which the emitters 2 are located. A soundproof coating 25 is applied to the inner surface of the insert or it can be made of sound-absorbing material. Since the end surface of the insert and the surface of the reflector have one generatrix, the surface of the hemisphere is not violated at the initial position of the insert.

 The cylindrical insert can be equipped with a drive, which, as one of the options, provides multiple threads on the body of the cylindrical insert 9, a nut 10 with multiple threads and a spring ring 11 mounted in the groove on the nut 10 and the housing 6. Moving is possible, in particular, along and around the axis, taking into account the degrees of freedom.

 A nozzle 20 is included in the kit for the apparatus, comprising a housing 21 with optical emitters 2 located therein, located on a reflective surface, including one having a shape close to reflector 3. The nozzle can even be installed on a standard stethoscope housing. In its center there is a hole (Fig. 8), transmitting radiation from the radiating head. Thus, an increase in the radiation power is achieved, it remains possible to use different wavelengths, for example, the red range on the nozzle and the IR spectrum on the head. The execution of the nozzle of metal allows you to use the magnetic field of the head. You can use an additional quick-detachable magnet. A recording element, functional sensors, phosphor indication can be attached to the nozzle. The nozzle expands the therapeutic capabilities of the device.

 For acupuncture, minor surgery, a nozzle 15 with an optical focusing system is used, which contains a mirror lens 16 and a tube 17 located on the outside of the nozzle, the working end of which is located in the focal plane of the lens, which allows you to combine the focus of the lens with the irradiated point and at the same time protect the organ of vision Patient and staff from scattered laser radiation. The focusing system can also be attached to both the head and the cylindrical insert. In both versions, the radiation can be output through the light guide.

 To expand the functionality, remove the biopotential in order to monitor the patient’s condition and create conditions for feedback, and the possibility of correcting radiation exposure parameters, a functional sensor 18 is installed on the working surface of the head or on the surface of magnet 4, which is connected to the control unit 7.

 To control the operability of the device, including during a therapeutic session, a photodiode 26 is located on the surface of the reflector, which can be placed in the body of the laser emitter. To indicate the presence of IR and UV radiation, the head can be equipped with a nozzle transparent to these wavelength ranges with a phosphor deposited on its surface. It turns out an indicator-visualizer, which is attached to the radiating head. It allows the doctor to observe, for example, infrared radiation in the green region of the spectrum, including its distribution along the diameter of the working surface of the head, which subsequently adheres to the body. From here it is possible, by moving the cylindrical insert and rotating it, to achieve the required power and configuration of the radiation field.

 For the duration of certain types of laser therapy, to protect the patient and staff from reflected laser radiation, the fitting 22 is provided with a plug with a reflective coating inside 23, in the body of which perforations 24 are made.

 Additionally, the device is equipped with a conical nozzle-diaphragm 19, which allows for localized irradiation of sites such as the auditory meatus, auricle, while protecting adjacent tissue areas that do not need radiation from radiation. To prevent condensate from falling out (influence), all reflective surfaces (reflector, diaphragms, etc.) can be equipped with a water-repellent, non-wettable coating and / or made of a material with such properties.

 The sound pickup sensor (with microphone) can be mounted on the head, in particular in the acoustic plane, in the auditory opening, on the end surface of the magnet. The boundary values of the ratio of the distance H from the top of the reflector in which the emitter is located to the working surface to the diameter of this surface D are selected based on the optimal combination of the acoustic properties of the device and the useful power (energy), optical radiation.

 A ratio of these parameters of less than 0.3 leads to a decrease in the acoustic properties of the device, which significantly worsens its diagnostic qualities, an increase in the ratio of these parameters of more than 0.8 leads to a decrease in the power of the optical radiation flux and again violates the acoustics, which significantly worsens the therapeutic and diagnostic effects .

 The inventive device operates as follows. A radiating head 1 and / or a nozzle 20 are connected to the power sources, which are fixed on the patient's body. Using appropriate controls on the power source 7 include optical emitters 2.

 Simultaneously with the effect of radiation on the patient, the magnetic field of the permanent magnet 4, executed in accordance with the requirements of the law of distribution of the characteristics of the magnetic field, acts. It is important that the presence of a dressing, drugs on the wound does not distort the topology of the magnetic field. If necessary, the magnet can be easily removed from the radiating head. To provide possibilities for varying the power flux (radiation energy), a cylindrical insert 9 is moved with optical emitters 2 mounted therein, approximating or removing it relative to the irradiated surface of the body. Changes in the parameters of the acting radiation (wavelength, power flux, pulse frequency, etc.) are made by changing the cylindrical insert with the corresponding emitters 3 mounted in it.

 Depending on the requirements of the law of distribution of radiation intensity, a certain arrangement of emitters is used (both location along the surface and relative to the optical axis), a certain combination of optical emitters 2 and their parameters.

 The signal from the photodiode located on the reflector surface enters the control unit having the appropriate indication means (for example, an LED), by which it is possible to judge the operability of optical emitters. It is also important for cases when the emitters operate in the invisible range (UV or IR).

 If it is necessary to remove any functional parameters using the functional sensors 18, it is possible to pair the apparatus for magneto-laser and (light) therapy through the control unit with the corresponding external equipment. To localize the irradiated surface, interchangeable diaphragms 5 are used, having openings, grooves of various shapes and sizes.

 Diaphragms have the ability to quickly install on the radiating head. In particular, for the implementation of acupuncture, a diaphragm with a pupil of 1-3 mm is used. For the same purpose, a nozzle with an optical focusing system can be used. In the case of using the latter, the maximum concentration of radiation energy at the irradiated point is achieved.

 The proposed device for light (laser) magnetotherapy retains all the advantages of known devices of this type with regard to ease of use and shortening the treatment time, in addition, it increases the efficiency of exposure to the body of physical factors, increases the positive effects on the cardiovascular and respiratory system, central nervous system and on the immune system. In addition, the device has the ability to control the reaction of the body and adjust the therapeutic process taking into account the reaction of the body by varying the parameters of optical radiation and magnetic exposure over a wide range.

Claims (16)

 1. TREATMENT AND DIAGNOSTIC DEVICE FOR MAGNETIC LIGHTING THERAPY, containing a head with optical emitters, a reflector and a plug mounted at the output of a ring magnet, a power source with a control unit and indication of the operation of optical emitters, including a photodiode, interchangeable nozzles, diaphragm, the ratio of which is different, the ratio of which H from the top of the reflector to the working surface to the diameter D of its working surface is 0.3 0.8.  2. The device according to claim 1, characterized in that the head is provided with a cylindrical insert located along its central axis, the end surface of which is made with a reflector along one generatrix, and installed with the possibility of movement, while the emitters are fixed in the end surface on the outer surface the inserts are coated with reflective and / or protective coatings, and the inner surface is provided with a soundproof coating.  3. The device according to paragraphs. 1 and 2, characterized in that it is equipped with a set of cylindrical inserts, each of which contains emitters generating radiation of certain wavelengths.  4. The device according to p. 1, characterized in that the emitters are located on the concave surface of the reflector parallel to the main axis or at an angle to it in concentric rows uniformly along the generatrix, in a checkerboard pattern or otherwise.  5. The device according to claim 1, characterized in that the photodiode is mounted on the surface of the reflector, mainly flush.  6. The device according to claim 1, characterized in that the magnet is removable.  7. The device according to p. 1, characterized in that the permanent magnet is made sectional and / or in the form of a film with a sputtering, with constant intensity or with sections of different magnetic field strengths.  8. The device according to p. 1, characterized in that on the working end of the head or on its side surface there are functional sensors mainly of the ECG type, temperature sensors, for removing biological indicators associated with the control system.  9. The device according to claim 1, characterized in that the nozzle-diaphragm is equipped with emitters installed in its casing, arranged on the surface in concentric rows evenly, in a checkerboard pattern or another order, the nozzle contains lasers as emitters, lasers, or a combination of both, and different wavelengths, of the same or different power, with different modes of operation.  10. The device according to p. 1, characterized in that the nozzle-diaphragm is made conical, and the inner surface is made with a reflective and / or protective coating.  11. The device according to paragraphs. 1, 9 and 10, characterized in that the inner surface of the nozzles, diaphragms and caps have a reflective and / or protective coating in the wavelength range of the emitters.  12. The device according to paragraphs. 1 and 10, characterized in that the nozzle-diaphragm is equipped with an optical focusing system.  13. The device according to paragraphs. 1, 2, 9 11, characterized in that the reflective surfaces of the reflector, insert, nozzle-diaphragm are equipped with a water-repellent or non-wettable coating.  14. The device according to claim 1, characterized in that the walls of the plug are perforated.  15. The device according to p. 1, characterized in that it is equipped with a transparent nozzle with a phosphor deposited on its surface.  16. The device according to paragraphs. 1 3, 7 9, characterized in that it is additionally equipped with a sound pick-up microphone, located on the surface of the reflector, and / or on the end surface of the head, or in the fitting.

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