RU2108122C1 - Method and device for physiotherapeutic irradiation with light - Google Patents

Abstract

FIELD: medicine, human organ and tissue irradiation in gastroenterology, stomatology, dermatology, urology, prolonged incorporal irradiation of blood, wounds and biotissues. SUBSTANCE: method is fulfilled by conducting irradiation of bioobject with electromagnetic waves within optic range regulated according to frequency-energetic parameters by emitter. The latter is put into autonomous capsule and placed in front of necessary object under impact. Beam pattern of emitter is chosen within a range of 0.2-4π steradian. Autonomous waterproof capsule has a power source connected with a light source through a control unit. Capsule's body has elements made of optically transparent material. EFFECT: higher efficiency of impact due to autonomy and encapsulation. 2 cl, 22 cl, 10 dwg

Description

 The invention relates to medicine, in particular to physiotherapy, and relates to methods and apparatus for physiotherapeutic irradiation with light of human organs and tissues.

 A known method of light therapy, which consists in irradiating reflex zones or a pathological area using a device including a radiation unit, a power supply unit and a means of delivering light radiation from the radiation unit to a biological object [1].

 The disadvantages of this method are the relatively high cost of equipment, the complexity of the delivery of radiation to some hollow organs, such as the small intestine.

 The closest in technical and medical essence to the invention is a method consisting in irradiating a biological object using a device including a power supply, a control unit, a radiator, the radiator being at a relatively short distance from the biological object or in direct contact with it [2].

 The disadvantages of the prototype method are the large size and weight of the device used for irradiation, the need for the constant presence of a highly qualified specialist during the entire session to monitor and control the exposure process, the need for a special outpatient room where the equipment is located.

 The purpose of the invention is to increase the effectiveness of light therapy.

 The method for physiotherapeutic light irradiation by irradiating a biological object with electromagnetic waves in the optical range by means of an emitter that is adjustable in frequency and energy parameters is supplemented by irradiating the biological object by placing the emitter in an autonomous capsule installed directly in front of the object with a radiation pattern in the range from 0, 2 to 4 π steradian.

 The capsule is placed on the outer surface of the bioobject with the possibility of fixing on it. It is possible to place the capsule in a tubular organ of a biological object with the possibility of its longitudinal and rotational movements. In a predetermined position, the capsule is installed in the tubular organs by means of a permanent magnet located on the surface of the biological object, or an elastic element. The capsule emitter irradiates in a programmable mode from continuous to pulsed with variable power and wavelength. A variant of the autonomous inclusion of the capsule through external exposure. The capsule is equipped with elements that record the parameters of the external environment, which are used to control the radiation parameters.

 The method can be implemented using a device for physiotherapy with light irradiation, including a power source electrically connected through a control element to a light source optically connected to a forming optical emitting system, the device being autonomous and provided with a housing in the form of a waterproof streamlined capsule, the housing also has elements of optically transparent material, opposite which a forming optical emitting system is installed in nm.

 The capsule may additionally be equipped with a fixation device on a biological object. The fixation device on the biological object is made in the form of an elastic element. The fixing device can also be made in the form of a magnet. The capsule body is made of a material resistant to aggressive biological environment. The capsule additionally contains environmental sensors. The capsule may additionally be equipped with a device for evacuating it from the surface of the biological object or from the organ of the biological object, for example, in the form of a thread.

 The power source of the capsule can be placed outside of it. In addition, the power source can be combined with a light source and is based on a chemical or biochemical reaction. The control contains a programmable timer. The optical forming system is a collecting lens and optical fiber sequentially mounted in a waterproof case. The environmental sensor is equipped with a photometer, the optical axis of which coincides with the optical axis of the light source included in the electric circuit in series and / or parallel to the emitter. The environmental sensor can also be made in the form of a photometer and a mirror, arranged to hit part of the radiation reflected from the biological object on the mirror and reflect it on the photometer, which is connected to the electric circuit in series and / or parallel to the emitter. The capsule body can be equipped with additional terminals connected to the terminals of the power source, for recharging.

 In FIG. 1 shows the proposed device, a General view; figure 2 is a view along arrow A in figure 1, (1 - housing, 2 - battery, 3 - control element, 4 - light source, 5 - optically transparent housing element, 6 - optical forming system, 7 - device fixation, 8 - evacuation device, 9 - limiter); figure 3 - device when irradiating a tubular organ when moving in it, General view (1 - permanent magnet, 2 - bioobject, 3 - device for physiotherapy with light, 4 - object of exposure); figure 4 is a device that irradiates a tubular organ stationary, general view (1 - device, 2 - tubular organ, 3 - elastic element); figure 5 - device with contactless power from an external source, general view (1 - device, 2 - AC source, 3 - emitter-antenna, 4 - object of influence, 5 - switch); figure 6 - device mounted on the outer surface of the biological object, general view (1 - power source, 2 - control element, 3 - emitter, 4 - body, 5 - optically transparent body element, 6 - pathology area, 7 - adhesive tape or fixation element); in FIG. 7 - a device with feedback on the power of the reflected stream; general view: (a) with a front-mounted environmental sensor (1 - housing, 2 - photodetector, 3 - battery, 4 - light source, 5 - optically transparent housing element); (b) with the opposite location of the environmental sensor (1 - housing, 2 - optically transparent housing element, 3 - battery, 4 - control element, 5 - emitter, 6 - mirror, 7 - photodetector); Fig. 8 is a circuit diagram of a device using an external power source, general view (1 - housing (dielectric), 2 - optically transparent housing element, 3 - receiving antenna of electromagnetic waves, 4 - detector, 5 - capacitor, 6 - emitter ); figure 9 is an optical diagram of a device having a radiation pattern close to a spherical one, general view (1 - optically transparent case, 2 - battery, 3 - control element, 4 - radiators); figure 10 is an optical diagram and a General view of a device with a flexible optical fiber (1 - housing, 2 - power supply, 3 - control element, 4 - emitter, 5 - optical forming system, 6 - optical fiber, 7 - protective cover).

 The body of an autonomous capsule is a surface of revolution: an ellipsoid, sphere, cylinder or cylinder, conjugated with a sphere or cone filled with gas. The body material is plastic, for example protacryl, glass, transparent transparent natural and artificial minerals, metal, for example stainless steel. In the first case, the housing, as a rule, is one-piece, in the second - detachable. The light emitter, consisting of a light source and a forming optical system, is located in the capsule so that the optical axis of the radiation coincides with the axis of symmetry of the housing ellipsoid. Part of the case necessarily has elements of a material transparent to radiation, for example, organic glass. The light source is a semiconductor LED, such as AL 336, a semiconductor laser, such as ILPN-101. The source is supplied from small-sized batteries, for example, N 379A, voltage of 1.5 V. The overall dimensions of the capsule depend on the used radiation power and the area of the irradiated area.

 The specified method is as follows.

An autonomous capsule (FIGS. 1 and 2), containing a power source 1, a control element 2, a light source 3, a lens 5 in a single housing 4, is turned on before the start of the session by acting on the control element 2. Then the capsule is placed in close proximity to the object impact 6 (6) (reflexogenic zone or area of pathology) and can also be fixed in this position using, for example, a bandage or adhesive plaster. Further light exposure to the study capsule is offline,
Such a small capsule can irradiate a pathology region with a size of 1x1 cm for a long time with a power of 0.1 - 100 mW in the wavelength range of 0.2 - 2.0 microns. With such light sources, the radiation pattern has the form of a cone with a solid angle of at least 0.2 π steradian. Also, a known chemical compound having a fluorescence effect, for example, a tetracycline compound, can be used as a light source. In this case, the radiation pattern made with an optically transparent spherical body becomes spherical (4π steradian). A capsule has a similar diagram in which electrically parallel connected radiation sources are used located on the surface of a sphere inside a transparent capsule, also having a spherical shape (Fig. 10). In order for the radiation to be more evenly distributed over the surface of the bioobject, the outer and inner surfaces of the transparent capsule body can be made not smooth, with increased roughness, to create diffuse reflection and scattering of light.

 To treat a number of diseases that occur in the hollow tubular organs of the body, in particular in the small intestine, the capsule is placed in the gastrointestinal tract (swallowed by the patient), then it naturally passes through the gastrointestinal tract and is excreted. Due to the small size of the capsule (25 mm), a high ability to pass the gastrointestinal tract without damage is achieved. Passing through the tubular organs, the capsule emits light of a given power and wavelength, affecting the area of pathology. In the treatment of areas accessible for endoscopic examination, a capsule equipped with an evacuation device should be used in the form of a flexible conductor thread, with which the capsule can be removed from the organ in reverse.

 To increase the duration of irradiation, the capsule with the irradiator turned on 3 can be held near the pathology area 4, in particular in the gastrointestinal tract) using a permanent magnet 1, which is superimposed on the projection area of the irradiated zone 2 on the body surface (Fig. 3). Moreover, an additional therapeutic effect is achieved due to the combined effect of the light flux and constant magnetic field. The capsule material in this case is ferromagnetic, for example nickel.

 Another fixation option is when the capsule 1 is stationary in the cavity of the organ 2, for example, in the auditory canal or in the rectum. In this case, the capsule is fixed in the tubular organ inside using the elastic element 3 (figure 4) due to the action of elastic forces on the inner surface of the organ.

 The capsule can be equipped with sensors that record the state of the environment, which are used to control the radiation parameters. So, to increase the therapeutic effect, biosynchronization of light exposure with dynamic measured physiological parameters of a person, for example, with a pulse wave, is possible. To do this, use known pulse wave recorders. The capsule is turned on by external action at the time of the maximum pulse wave recorded by known devices, and turned off after the passage of the pulse wave. Continuous modulation of the radiation power by dynamic physiological parameters can also be carried out.

To reduce the influence of the optical properties of a biological object on the process of radiation exposure on pathology, it is possible to automatically adjust the radiation output power according to the reflected light flux power. For this (Fig.6), the capsule 1 is additionally equipped with a photometer 2 included in the electric circuit in series with the power element 3 and the semiconductor emitter 4. In this case, the radiation power at the output is determined by the formula
P = β • W + P _o , (1),
Where
β is the calibration coefficient;
W is the power of the reflected light flux;
P ₀ - radiation power in a non-reflective body (constant).

 Exposure to radiation can occur in a programmable mode, the parameters of which are set by the doctor or pre-programmed. The simplest mode is constant power and wavelength. Pulse modes are also available with virtually no limit on pulse duty cycle. This is achieved by including a single or multivibrator in the electric circuit, for example, the K1006VI1 timer, and supplying the emitter from the pulses of this generator, and the radiation mode (changing the duration and duty cycle of the pulses) is programmed by changing the values of the resistors and capacitor connected to the terminals of the timer chip. The range of variation of the pulse repetition rate, possible when using this timer chip, is from 0.001 to 100000 Hz. The use of the pulse mode makes it possible to synchronize treatment with the individual biological rhythms of the patient, which increases the effectiveness of treatment. When using LED light sources, the radiation wavelength can periodically change, for example, from red to green, which expands the spectrum of effects on the biological object. Also, to expand the spectrum of exposure, several LEDs can be used with series or parallel switching with different wavelengths - from ultraviolet to infrared ranges.

 The inclusion of the emitter in the capsule can be made either by direct contact or by external exposure. Upon direct contact, the capsule is equipped with a known device that closes the contacts of the emitter. When turned on by external influence, the capsule 1 (Fig. 5) is made of a non-conductive material, equipped with a known electromagnetic chopper 2 and placed in the external electromagnetic field of the electromagnet 3. When the external electromagnet 3 is turned on, the contacts of the electromagnetic chopper 2 in the capsule are closed and the radiation source 4 is turned on. The emitter can be powered by non-contact excitation of electromagnetic waves by waves, such as microwave waves). The electrical circuit necessary for converting electromagnetic waves into a constant voltage supply to the emitter is shown in Fig. 5 and includes a receiving antenna of electromagnetic waves connected to a detector, which, in turn, is connected to the emitter.

 To improve the supply of light radiation to the pathological region, a capsule may be used, including a sealed optical fiber optically connected to the optical system and emitters (Fig. 10). Such a device can improve the supply of radiation, in particular, to the eardrum due to the significant curvature of the ear canal.

 Sterilization of the capsule can be carried out, for example, with 96% alcohol or in another way. The total battery life when using standard components is up to 24 hours (at least 3 hours). The dosage of light therapy can be carried out using a timer, for example, made in the form of a chip K1006VI1.

 The specific implementation of the device.

 The autonomous capsule for the treatment of middle ear inflammation is a protacryl case, which has the shape of an ellipsoid with axial dimensions of 15 mm and 5 mm. Two N 379A batteries with a voltage of 1.5 V each are integrated into the capsule, connected in series with each other and a AL336 semiconductor LED emitting 5 mW in the infrared region of the spectrum, wavelength range 0.89-0.91 μm.

 Example 1. Patient S., 19 years old, paresis of the foot in the foot, suppuration of the wound. Antibiotic therapy in combination with light therapy. The self-contained capsule is fixed with a bandage over the wound. The total duration of the session 4 hours; in the irradiation mode 15 minutes, then a pause of 45 minutes. The wavelength of 0.67 microns, the radiation power of 3 mW. Result: normal wound healing.

 Example 2. Patient B., 37 years old, inflammation in the gum after removal of the premolar of the lower dentition. Light therapy with an autonomous capsule, which the patient holds in the mouth under the tongue for 3 hours. Therapy mode: radiation with a power of 1 mW, pulse duration 10 minutes, a break of 30 minutes. The wavelength is 0.67 microns. Result: The symptoms of inflammation have disappeared.

 Example 3. Patient K., 52 years old, hemorrhoidal bleeding. The treatment was carried out with a light therapy autonomous capsule installed in the rectum at a distance of 3 cm from the exit. Fastening on an elastic element, evacuation of the capsule with a thread, the end of which is outside. Treatment regimen: exposure to light with a wavelength of 0.63 microns with a power of 5 mW for 20 minutes, then the patient removes capsule 1 on his own, 30 minutes break. Patient installing capsule 2 independently and irradiating with light 0.89 microns with a power of 3 mW, 10 min Removal by the patient of capsule 2 on his own, a break of 3 hours, then a repeat of the entire procedure. Result: cessation of bleeding.

 The proposed method and device can be used in gastroenterology, otolaryngology (irradiation of the nasal cavity, as well as the auditory canal, throat with stationary capsules), in dentistry (irradiation of the oral cavity with stationary capsules or a capsule that the patient holds in the mouth), in dermatology (radiation stationary capsules placed on the skin), for long-term incorporation of blood with stationary capsules sewn in subcutaneously, in urology (irradiation with stationary ones installed in the area of m of the bladder and ureter with capsules), in gynecology (fixed in the uterus and in the tubes with capsules), in traumatology (irradiation of wounds and burns, as well as areas of regeneration, transplantation of biological tissues). It is also possible to use an autonomous capsule for preventive purposes, primarily to reduce microbial contamination of the surrounding air environment, as well as liquids through the use of ultraviolet radiation.

 Sources of information.

 1. Illarionov V.E. basics of laser therapy. M .: Respect, 1992, p.26.

 2. Ibid., P. 45.

Claims (23)

 1. A method for physiotherapeutic light irradiation by irradiating a biological object with electromagnetic waves in the optical range by means of an emitter that is adjustable in frequency and energy parameters, characterized in that the irradiation of the biological object is carried out by an emitter in an autonomous capsule installed directly in front of the object of influence, and the radiation pattern of the emitter is selected in the range from 0.2 to 4 π steradian.  2. The method according to p. 1, characterized in that the capsule is placed on the outer surface of the biological object with the possibility of fixing on it.  3. The method according to p. 1, characterized in that the capsule is placed in a tubular organ of a biological object with the possibility of its longitudinal and rotational movements.  4. The method according to claim 3, characterized in that the capsule is installed in a predetermined position in the tubular organs by means of a magnet placed on the surface.  5. The method according to claim 3, characterized in that the capsule is installed in a predetermined position in the tubular organs by means of an elastic element.  6. The method according to claim 1, characterized in that the capsule emitter irradiates in a programmed mode from continuous to pulsed with a variable power and wavelength.  7. The method according to claim 1, characterized in that the capsule include external exposure.  8. The method according to p. 1, characterized in that the capsule is equipped with elements that record the parameters of the external environment.  9. A device for physiotherapeutic light irradiation, comprising a power source electrically connected through a control element to a light source optically coupled to a forming optical emitting system, characterized in that the device is autonomous and provided with a housing in the form of a waterproof streamlined capsule, while the housing has elements from an optically transparent material, opposite which a forming optical emitting system is installed in it.  10. The device according to claim 9, characterized in that the capsule is additionally equipped with a fixation device on a biological object.  11. The device according to claim 10, characterized in that the fixing device is made in the form of an elastic element.  12. The device according to claim 10, characterized in that the fixing device is made in the form of a magnet.  13. The device according to claim 9, characterized in that the capsule body is made of a material resistant to aggressive biological environment.  14. The device according to claim 9, characterized in that the environmental sensors are additionally placed in the capsule.  15. The device according to claim 9, characterized in that the capsule is additionally equipped with a device for evacuating it from the surface of the biological object or from the organ of the biological object.  16. The device according to p. 15, characterized in that the capsule evacuation device is made in the form of a thread.  17. The device according to claim 9, characterized in that the power source is placed outside the capsule.  18. The device according to claim 9, characterized in that the power source is combined with a light source and is based on a chemical or biochemical reaction.  19. The device according to claim 9, characterized in that the control element contains a programmable timer.  20. The device according to p. 9, characterized in that the forming optical emitting system is made in the form of a collecting lens and optical fiber installed in series in a waterproof case.  21. The device according to 14, characterized in that the environmental sensor contains a photometer, the optical axis of which coincides with the optical axis of the light source, connected in series and / or parallel to the light source.  22. The device according to 14, characterized in that the environmental sensor is equipped with a photometer and a mirror with the possibility of falling on the mirror part of the radiation reflected from the biological object and reflecting it on the photometer, and the photometer is connected to the electric circuit in series and / or parallel to the emitter.  23. The device according to claim 9, characterized in that the capsule body is additionally equipped with terminals connected to the terminals of the power source, for recharging.

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