RU79787U1 - PHYSIOTHERAPEUTIC DEVICE FOR LIGHT AND COLOR THERAPY - Google Patents

Abstract

The utility model relates to medicine, namely to the class of medical devices using the interaction of electromagnetic radiation (in particular, the optical wavelength range) with the human and / or animal body in physiotherapy.

The physiotherapeutic apparatus for light and color therapy is intended for the treatment of various skin diseases, diseases of the musculoskeletal system and diseases of internal organs by affecting pathological zones and lesions, as well as biologically active zones and points by optical radiation of LEDs at one of the selected wavelengths or all at once.

The radiating matrix of the apparatus is formed by LEDs of at least five different colors from a row characterizing the color of the human energy centers (chakras), moreover, diodes of the same color are spatially combined into groups located in the field of the radiating matrix, and connected in groups in parallel or parallel-serial a circuit connected to a power source through a radiation parameter control unit. The LEDs in the groups are connected in parallel, if their number does not exceed three and parallel-sequentially for four or more LEDs in the group. The control unit contains a device that ensures the luminescence of each individual group of emitting diodes or the simultaneous illumination of all diode groups with a constant illumination of a group of infrared LEDs. At the same time, the depth of optical exposure in all colors is equal to the depth of penetration of infrared radiation - 3-2 cm. To provide a larger area of overlapping of the spots of illumination by infrared and one of the visible

infrared LEDs are selected with a radiation pattern angle of at least 60-80 °.

The design of the apparatus and the electrical circuit of the control unit allow for sequential sequential or simultaneous illumination of all LED groups, as well as work in various combinations of color groups. This makes it possible to use monochromatic light fluxes for the treatment of pathologies of various organs, the color of which best matches the color of the human energy centers (chakras) closest to the diseased organs.

Description

The utility model relates to medicine, more precisely, to the class of medical devices using the interaction of electromagnetic radiation (in particular, the optical wavelength range) with the human and / or animal organism in physiotherapy.

The physiotherapeutic apparatus for light and color therapy is intended for the treatment of various skin diseases, diseases of the musculoskeletal system and diseases of internal organs by treating pathological zones and lesions, as well as biologically active zones and points by optical radiation of LEDs at one of the selected wavelengths or on several, including all, at the same time.

Known physiotherapeutic apparatuses for light and color therapy, which use optical radiation of laser diodes and LEDs of the near infrared red and other ranges or radiation of a white light source that has passed through a filter system and to influence pathological zones and lesions, as well as biologically active zones and points, polarizers. [1-3]. Some devices use modulation of optical radiation at one or several biologically active frequencies to increase the effectiveness of treatment [2].

The main disadvantage of the existing existing devices for light therapy is the relatively small depth of penetration of the optical radiation of the short-wave section

spectrum (green, blue, blue, violet colors), which significantly narrows the therapeutic possibilities of devices in terms of the depth of tissue development, covered by the pathological, for example, inflammatory, process, and, consequently, the effectiveness of treatment.

It is known that when a color is exposed to a pathological focus simultaneously with near infrared radiation (with a wavelength of 0.8-1 μm), the depth of exposure to light approaches the penetration depth of the infrared stream, which is substantially greater than the penetration depth of light of the visible part of the spectrum. When irradiating, for example, inflamed tissues with both blue and infrared radiation, the inflammation is removed from the entire mass of tissues into which infrared radiation penetrates. In the absence of blue light, the removal of inflammation in the volume does not occur [4].

The closest analogue of the apparatus proposed in this utility model is the Geska-polycvet apparatus [2], which is commercially available in Russia, in which the irradiation of pathological zones, lesions, biologically active zones and points is performed using LEDs of the near infrared range, as well as red, yellow , orange, green and blue colors, grouped by color spatially and electrically. These LEDs form a radiating matrix, which is connected to the corresponding direct current source through the radiation parameter control unit. The patient can be affected by a group of LEDs of the same color, or by all groups of LEDs at the same time.

The purpose of the utility model is to expand the therapeutic capabilities of the apparatus and increase the efficiency of its use

by increasing the depth of study of pathological foci with light of various colors.

This goal is achieved in that at the same time as any one color, the effect is also carried out by near infrared radiation, for which purpose a device is added to the control unit that ensures the luminescence of each separate group of emitting diodes or the simultaneous luminescence of all diode groups with a constant illumination of the group of infrared LEDs. Moreover, if the number of LEDs in the group does not exceed three, they are connected in parallel, while with four or more LEDs in the group, to increase the reliability of the device, they are connected in parallel-series.

Since the LEDs of the same color are spatially grouped and located at a certain distance from the group of infrared LEDs, infrared LEDs are selected with an angle of radiation pattern of at least 60 ° to simultaneously illuminate the tissues with any of the available colors and infrared radiation.

This makes it possible to use various monochromatic light fluxes for the treatment of pathologies of various organs, including those located at a considerable depth in the body, the color of which best matches the color of the human energy centers (chakras) closest to the pathology, and the depth of study of the mass of tissues is determined by the penetration possibilities infrared radiation.

The figures below show one of the many possible versions of the apparatus.

Figure 1 shows the location of the LED groups in the emitting matrix.

LEDs of seven different colors infrared 1, red 2, orange 3, yellow 4, green 5, blue 6, blue 7 are located in groups of three diodes in each. A group of four infrared diodes 1 is located in the center. This arrangement of LEDs allows you to easily and efficiently process a given area of the patient’s body, implementing the developed methods for treating various diseases. When all groups of diodes are turned on, a fairly uniformly lit surface of a sufficiently large area is simultaneously created.

Figure 2 presents a block diagram of the apparatus.

The groups of LEDs 1-7 through the radiation parameter control unit 8 are connected to a power source 9.

The control unit of the radiation parameters 8 provides the following basic functions:

using a special switch 10, sequential, alternate or simultaneous connection of one or more groups of diodes 2-7 to the power source 8, so that at any given time one of the six groups of diodes can shine, or all at the same time;

- constant glow of infrared LEDs 1;

- using a special generator-frequency synthesizer 11, the modulation of optical radiation at one or more biologically active frequencies.

As a power source 9, you can use either a battery pack or accumulators (3-6 batteries with a voltage of 1.5 V), and a network voltage converter with 220 V AC to 5-9 V DC (network adapter with an output voltage of 6-9 V )

Figure 3 presents an example of a connection diagram of LEDs in groups.

In order to increase the reliability of the device, the LEDs in the groups are connected in parallel or series-parallel circuits, which are connected to the power source 9 through the radiation parameter control unit 8. The LEDs of two groups (for example, red 2 and orange 3) - three in a group - are connected in parallel, and infrared group 1, in which four LEDs - in series and parallel. With this scheme of connecting LEDs, failure of one or even several LEDs of different colors does not lead to failure of the device, while maintaining its operability and the possibility of treating diseases.

Figure 4 shows the course of light rays from LEDs of various colors and infrared LEDs and the position of the light spots from them on the glass of the output window 12 of the apparatus 13.

For definiteness, the location of the LEDs is taken at the cross section of figure 1 along the vertical axis. In the center of the upper figure of FIG. 4, infrared diodes 1 are located on the printed circuit board 14, green LEDs 5 are on the left, red 2 are on the right. The lines 15 located between the LEDs 1, 2, 5 and the glass of the output window 12 of the apparatus 13 show the boundaries of the diagram radiation of LEDs. In this example, we used radiation patterns, which are often found in the reference materials of companies manufacturing LEDs [5]: for infrared LEDs, the angle of the radiation pattern is taken to be 100 °, for red and green - 60 °. The lower figure of figure 4 shows the spots of illumination of the glass of the output window 12 of the apparatus; shown for clarity, two spots for each color. Circles 16 belong to

infrared LEDs, 17 - to red 2 and 18 - to green LEDs 5. Due to the wider radiation pattern of infrared LEDs, the circles are overlapped and, as a result, the patient’s body area is simultaneously illuminated with any of six colors and infrared light when the glass is located the output window 12 of the device on the patient’s body. Removing the apparatus from the surface of the body leads to even greater overlap of the rays.

Physiotherapeutic apparatus for light and color therapy works as follows. When you turn on the device in the network in the output window 12 of the device 13 appears optical radiation at one of the wavelengths and at the same time infrared radiation (in one of the possible modes of operation of the device may include combinations of groups or all diodes at the same time). Using switch 10, it is necessary to select the operating mode of the device recommended by special medical guidelines (the color of the radiation, the necessary combination of groups of LEDs or the simultaneous inclusion of all colors), position the emitter of the device near the area to be processed according to medical guidelines, and carry out the planned procedure in the time specified in the recommendations.

The compliance of the physiotherapeutic apparatus for light and color therapy with the requirements of medical practice in terms of functional and methodological capabilities is confirmed by the test reports of the apparatuses, conducted on the recommendation of the Ministry of Health of the Russian Federation and the Russian Health Inspection.

Information sources:

1. Illarionov V.E. "Technique and methods of laser therapy procedures. (Reference)", M, 1994.

2. Zverev V.A. et al. “Physiotherapeutic apparatus for light and color therapy”, RF patent for utility model No. 33016 with priority dated December 6, 2002.

3. Instructions for use of the Zepter Bioptron apparatus.

4. Nalivaiko B.A. and others. "Apparatus for light therapy", patent of the Russian Federation for utility model No. 37636, priority dated January 16, 2004.

5. Kingbright Optoelectronic Component Catalog 2005-2006, pp. 83-99.

Claims (3)

1. Physiotherapeutic apparatus for light and color therapy, containing a power source, a radiation parameter control unit, emitting diodes with different spectra from the light and infrared radiation ranges, spatially and electrically combined into groups and forming an emitting matrix connected to the power source through the control unit, characterized in that said control unit comprises a device providing a luminescence for each separate group of emitting diodes or a simultaneous luminescence of all diode g SCP group under constant glow of infrared LEDs. 2. The apparatus according to claim 1, characterized in that the LEDs in the groups are connected in parallel, if their number does not exceed three and in parallel-series for four or more LEDs in the group. 3. The apparatus according to claim 1, characterized in that the infrared LEDs are selected with a radiation pattern angle of at least 60-80 °.