RU2253414C1 - Method for producing uniformly scattered radiation for and optical stimulating visual function-stimulating means - Google Patents

Abstract

FIELD: medicine; medical engineering.

SUBSTANCE: method involves first scattering laser radiation and then selecting the scattered radiation by means of diffuse reflection. The method is put in practice by applying special purpose device for stimulating visual function. Laser radiation of visible and/or infrared spectrum light is applied. Scattering and following radiation selection is carried out in isogonal direction with respect to radiation propagation direction. Patient vision field is restricted preventing it against action of external illumination and non-scattered rays from optic axes of the radiators.

EFFECT: improved quality of uniformly scattered optical radiation.

6 cl, 1 dwg

Description

The invention relates to methods and devices for treating eyes and can be used to prevent visual impairment, relieve visual fatigue, etc.

For many applications in medicine, in particular for the treatment and prevention of visual function disorders, the task of forming a uniformly scattered radiation field of the visible and infrared ranges of the spectrum is especially urgent (The use of low-energy laser radiation for the treatment of patients with progressive myopia. A manual for doctors. Moscow Research Institute of Ophthalmic Helmholtz diseases).

A known method of improving visual functions (patent RU 2071301 C1, 1997.01.10), which consists in the fact that the eyes of the patient are exposed to light radiation with a wavelength lying in the visible region of the spectrum, while the first eye is exposed to the blinking light, and the first and second eyes are exposed to light radiation with illumination of 5-100 Lx and the same wavelength of 400 to 700 nm, while the blinking frequency of the light radiation that affects the first eye is 0.06-1.0 Hz. In addition, the second eye is exposed to constant light radiation. Also, the effect on both eyes is carried out alternately by the same light radiation.

The known method does not take into account the individual characteristics of the color perception of different eyes of the same patient, as well as the possibility of using radiation not only visible, but infrared and mixed spectral ranges. In addition, it does not use a higher frequency range of flashes, for example, 1.0-30.0 Hz, which is considered promising for relaxation sessions (Association of Applied Psychophysiology. USA, Dallas. 1991).

These disadvantages limit the scope of the known method.

The closest in purpose and the achieved result to the claimed method is a method implemented in an ophthalmic laser speckle stimulator (patent RU 2207607 C2, 2003.06.27), which is adopted as a prototype.

The prototype method consists in the fact that the laser radiation is diffusely scattered first, then channelized by reflection from a diffuse surface, covering the radiation along its propagation, while the scattered radiation in the sewer is additionally passed through a scattering refractive element. Before diffuse radiation scattering, the indicatrix of the laser radiation is converted into a shape with a cross section of a higher order of symmetry, for example, square. Radiated in this direction, the radiation is additionally subjected to one or more successive diffuse scattering by passing it through a diffuser (diffusers).

However, in the prototype method, it is necessary to greatly attenuate the radiation propagating along the optical axis of the laser, since observation is carried out along this axis towards the laser radiation, which leads to large losses of light energy, and due to the insufficient application of the proposed sewer system for this purpose, it is necessary to introduce radiation additional scattering refractive elements, which makes the prototype method is not efficient enough and economical.

Laser vision stimulants, known as speckle stimulants, are produced by the industry and are widely used in therapeutic practice.

Known devices that incorporate a helium-neon laser, the radiation of which is transmitted through a fiber optic cable to a special nozzle, on which the patient's gaze is fixed (Quarterly information and reference review "OFTALMINFO". Issue 2, 3 quarter 1998. Research and Production Company “ TYPES ”).

In another known device (copyright certificate SU 1639625 A1, 04/07/1991) the radiation of a helium-neon laser is introduced through an opening into a hollow ball with a diffuse-reflecting surface, and is output through an opening in the plane of the laser optical axis, but offset from it outside the radiation pattern laser, so that direct radiation cannot get into the patient’s eyes.

However, these known devices have poor technical, economic and weight characteristics.

The best technical and economic indicators have devices that use semiconductor lasers (previously mentioned patent RU 2207607 C2).

More effective is an ophthalmic laser speckle stimulator according to RU 2207607 C2, selected as a prototype device.

The prototype device comprises a semiconductor laser transmitting a diffuse diffuser of the light flux, a reflector, the inner surface of which is made in the form of a body of revolution (truncated cone), expanding in cross section, and a frosted transmitting screen, while the diffuser of the light flux is installed in the small base of the reflector, transmitting the screen - in its large base, and the inner surface of the reflector is made diffusely reflective.

The prototype device uses the entire laser beam, and not just its axial region. However, observation is carried out in the direction of the axis of the beam toward the laser radiation, which requires a strong attenuation of direct radiation. The use of the well-known canalization system for this purpose is not enough, and additional scattering refractive elements have to be introduced, which makes the prototype device inefficient and economical.

The task of the claimed group of inventions is to create a more efficient, economical and easy to use method and device for forming a field of uniformly scattered optical radiation, including laser, to stimulate vision.

Accordingly, its technical result is a technical effect, objectively manifested when using the device and method and consisting in solving this problem.

The technical result is achieved by the fact that the method of forming a field of uniformly scattered optical radiation to stimulate vision is that the laser radiation is first scattered, and then the scattered radiation is selected by diffuse reflection, while, unlike the closest analogue, it is carried out by specially created for him, a vision stimulator, using laser radiation of the visible and / or infrared ranges of the spectrum, scattering and subsequent selection of radiation is carried out isogonally the direction of radiation propagation, and the patient’s field of vision is limited, preventing both external illumination and non-scattered rays from the optical axis of the emitters getting into it.

The vision stimulator comprises a first laser source and a laser transducer with a diffuse reflector. In contrast to the closest analogue, a second laser radiation source is introduced into it, while the first and second laser radiation sources can be switched on simultaneously or separately, the radiation from the sources has a visible and / or infrared range, the radiation converter is made in the form of a flat fiber to the opposite ends of which laser sources are connected, filling with their radiation the entire aperture of the optical fiber, a surface is deposited on the lateral surface of the optical fiber in the patient’s field of vision the output structure that uniformly scatters the radiation in the directions isogonal to its side surface, and the diffuse reflector is located behind the radiation transducer and diffuses the scattered radiation through the transducer to the patient; a light field limiter is placed in front of the radiation transducer to prevent non-scattered rays from entering the patient’s field of vision optical transducer and diffuse reflector, radiation sources, laser transducer, diffuse reflection Tel limiter light field placed in a special anatomical frame, limiting the field of view of the patient from the ambient light.

The listed set of essential features of the stimulator of vision is sufficient to achieve a technical result in all cases to which the requested amount of legal protection applies.

In special cases of its implementation or use, the stimulator may have a surface output structure made in the form of a diffraction grating or a sprayed diffuse layer having characteristic parameters linearly increasing along these structures from a zero value at the radiation input with a proportionality factor equal to 10 ^-3 .

The stimulator may also contain a limiter of the light field, made in the form of a frame; continuous sources of laser radiation or modulated sources of laser radiation with a main modulation frequency of 0.1-30.0 Hz, or multiple modulation frequencies or a set of frequencies that vary according to special algorithms.

Laser sources, such as diodes, can be electrically connected to a power source through circuit boards to ensure the functioning of laser sources.

The device may contain a special anatomical frame in the form of a closed mask having a nasal support and temples.

Due to the proposed combination of features, laser radiation with a sharply non-uniform intensity distribution in the beam cross section is converted to uniformly scattered radiation, with an isogonal propagation direction with respect to the initial one. The linear size of the scattering field is determined by the dimensions of the surface of the output structure. At the same time, there is a speckle field in the observer's field of view, the angular resolution of which increases with distance from the surface output structure.

In the case of a laser beam, the field of uniformly scattered radiation directed by the output surface structure will consist of speckles resulting from the interference of coherent waves scattered by microroughnesses in the structure, the angular resolution of which depends on the distance of the patient’s eyes to the structure, i.e. from in which zone (near or far) field the visual organ is located.

Unlike the prototype method, in the claimed invention, the observation of uniformly scattered radiation is carried out not along the optical axis of the source, but isogonally, which completely eliminates the need to attenuate the axial radiation and change its indicatrix using additional scattering refractive elements and allows to translate a significant part of the light energy of the source into uniformly scattered radiation.

The essence of the group of inventions is illustrated in the drawing, which shows a diagram of a stimulator of vision.

In a preferred embodiment, the laser vision stimulator comprises: an anatomical mask 10, which shunts the external illumination and is simultaneously a supporting construct for the other functional elements of the device, two laser diodes of the red or infrared range of spectrum 1, two radiator of laser diodes 3, designed to cool the laser diodes, two control boards 2 providing the operation of laser diodes, a control unit and power supply of laser diodes 12, connected by an electric cable 11, with the boards 2, two attachment points 4, which provide the connection of laser diodes to the radiation converter, which, in turn, consists of a flat optical fiber 5, which transmits the laser diodes in the patient's field of view and the output surface structure 6, uniformly scattering the radiation of the laser diodes isogonal to the propagation direction radiation inside the light guide, a diffuse reflector 7, reflecting the scattered radiation in the direction of the observer, the limiter of the light field 8, which prevents getting into the field of view the patient of any rays that have not passed scattering through the surface output structure 6, two flexible behind-the-ear supports 9, which, in combination with the nose support of the anatomical mask 10, securely fix the device to the patient’s head.

The output surface structures have characteristic parameters that linearly increase along the structures from a zero value at the radiation input with a small proportionality coefficient (equal to about 10 ^-3 ). Such characteristic parameters are: the stroke depth for embossed or a change in the refractive index for modulation diffraction gratings; density of the sprayed diffuse layer for chaotic structures.

The specified special case of the implementation of the stimulator of vision works as follows.

The patient puts the device on his head, adjusting with the help of the earhooks 9 and the nose support of the anatomical mask 10, selects a comfortable position (sitting or lying), the operating mode (continuous or pulsed) and turns on the power source 12. The rays of two laser diodes 1 pass into the planar fiber 5, exciting a light field in it, which is directed towards the patient’s eyes with the help of output surface structures 6 and a diffuse reflector 7, the radiation from the areas of the optical axes being shielded by the light field limiter 8, in p As a result, only scattered radiation enters the patient's field of vision. The biostimulating effect acting upon observation of superficial excretory structures 6 improves blood supply to the organ of vision, increases the light sensitivity of healthy eyes, and relaxes the patient’s psycho-emotional sphere, which leads to the removal or reduction of visual fatigue.

The inventive device is made in the form of models in which semiconductor lasers are used in the red range of the powerful radiation spectrum of 3-5 mW.

The planar fiber is made of optically transparent polystyrene, the diffuse reflector is made of diffusely reflecting plastic, and the field limiter is made of opaque polyvinyl chloride. The output surface structure was formed by creating a regular relief by thermal pressing with a stroke depth linearly increasing along the structure with a proportionality coefficient equal to about 10 ^-3 from the zero value at the input. The output surface structure has an area of about 40 cm ² . Additional scattering refractive optical elements were not used.

The light load on the organs of vision with a divergence of radiation of approximately 1.0 rad is much less than the remote control value of the chronic exposure to laser radiation in the red spectrum.

To achieve a positive effect, reduce visual fatigue, 10-12 procedures are carried out lasting 3-5 minutes.

Claims (6)

1. The method of forming a field of uniformly scattered optical radiation to stimulate vision, which consists in the fact that the laser radiation is first scattered, and then the scattered radiation is selected by diffuse reflection, characterized in that it is carried out by the vision stimulator according to claim 2, using a laser radiation of the visible and / or infrared spectral ranges, scattering and subsequent selection of radiation is carried out isogonal to the direction of radiation propagation, and the patient’s field of view is limited, preventing it from getting both external illumination and unscattered rays from the region of the optical axes of the emitters. 2. The vision stimulator comprises a first laser radiation source and a laser radiation transducer with a diffuse reflector, characterized in that a second laser radiation source is introduced into it, while the first and second laser radiation sources have the possibility of synchronous or separate switching on, the radiation of the sources is visible and / or the infrared range of the spectrum, the radiation converter is made in the form of a flat fiber, to the opposite ends of which are connected laser sources that fill their radiation the entire aperture of the fiber, on the side surface of the fiber in the patient’s field of view, a surface output structure is applied that uniformly scatters the radiation in the directions isogonal to its side surface, and the diffuse reflector is placed behind the radiation transducer and diffuses the scattered radiation through the transducer to the patient, a light field limiter is placed in front of the radiation transducer to prevent rays not optically scattered from entering the patient’s field of vision m transducer and diffuse reflector, radiation sources, laser radiation transducer, diffuse reflector, light field limiter are placed in an anatomical frame that limits the patient's field of vision from external exposure. 3. The stimulator according to claim 2, characterized in that the surface output structure is made in the form of a diffraction grating or a sprayed diffuse layer having characteristic parameters that linearly increase along the structures. 4. The stimulator according to claim 2, characterized in that the limiter of the light field is made in the form of a frame. 5. The stimulator according to claim 2, characterized in that it contains continuous or modulated sources of laser radiation with a main modulation frequency of 0.1-30.0 Hz, or a multiple of the modulation frequencies, or a set of variable. 6. The stimulator according to claim 2, characterized in that the laser radiation sources, for example diodes, are electrically connected to the power source through the boards for ensuring the functioning of the laser radiation sources.