RU147848U1 - MULTIFUNCTIONAL NEURO-OPHTHALMIC SIMULATOR - Google Patents

Abstract

1. A multifunctional neuroophthalmology simulator, which is a device for vision correction, containing two diaphragms inserted into the housing and one pair of movable lenses pivotally connected to the housing, characterized in that the housing comprises a vibration-insulating gasket from the inside of the housing periphery, lenses and diaphragms connected to case by means of round threaded plastic pads with the possibility of their replacement. 2. A device for correcting vision according to claim 1, characterized in that the movable lenses close and open with the possibility of fixation in the upper position. A device for correcting vision according to paragraphs. 1 and 2, characterized in that the distance between the movable lenses and the diaphragms of the housing is about 10 mm. 4. A device for correcting vision according to claim 3, characterized in that the movable lenses are made in the form of round plastic disks with a thickness of 3 mm and a diameter of 50 mm. A vision correction device according to claim 4, characterized in that the movable lenses are made of color translucent plastic, which is a filter of red, green, blue and yellow. A vision correction device according to claim 4, characterized in that the movable lenses are made of white translucent matte plastic. A vision correction device according to claim 4, characterized in that the movable lenses are made of transparent translucent plastic. A vision correction device according to claim 4, characterized in that various patterns can be applied to the movable lenses. A device for correcting vision according to paragraphs. 4-8, characterized in that the apertures are apertures made of opaque black plastic

Description

The utility model relates to the field of medicine, more specifically to ophthalmic devices for correcting vision by combining diaphragms and lenses of glasses.

Known glasses containing a frame and strip lenses or diaphragms with various slit and hole holes for diffraction of light rays (PM RU 10890, PM RU 106968, Patent RU 2226083, RF Patent 2176809, RF Patent, 2102045, RF Patent 2257182, Patent CN 101559014, U.S. Patent 4,249,803, CN Patent 2106378, etc.). When using these glasses, visual acuity increases in those cases when refractive errors are accompanied by transparency violations in the optical media of the eye, the depth of focus increases, and the sensitivity of vision to defocus the image decreases, thereby creating conditions for eye relaxation after work associated with overloading visual function.

Also known are glasses containing a frame or a casing and lenses, which are spectral filters (Patent RU 2466697, PM RF No. 112037, PM RF 88542, WO 2009053502). It is possible to use spectral filters in the form of “nozzles” on corrective glasses (PM RF 35068, PM RF 17852, Patent CN201293882) or use a set of light filters (Rosenblum Yu.Z., Zak P.P., Ostrovsky M.A., Aliev A. -G.D., Smolyaninova I.L., Bora E.V., Ivanidze V.N., Proskurina N.G., Mikhailova L.N. Spectral filters as a type of medical vision correction. Information reference booklet "Ophthalmic network Of Russia ", issue 1. - M., 1995, p. 42-50). Red-green glasses (stereoscopic, anaglyphic) are known, in which a red filter is placed in front of one eye and green or blue in front of the other [Avetisov S.E., Kashchenko TP, Shamshinova A.M. Visual functions and their correction in children // Guide for doctors - M .: OJSC “Publishing house“ Medicine ”, 2005. - 872 p.]. These glasses are used mainly for the diagnostic purpose - to study binocular vision in patients with refractive pathology. As a separator of visual fields, red-green glasses are used in the treatment of binocular disorders such as amblyopia and strabismus by computer methods (the EYE and Contour programs). In particular, in the EYE program, exercises for combining and shifting images are carried out, and fusion reserves are trained. However, as an independent means of prevention and treatment of myopia, red-green (blue) glasses are still not used. This is probably due to their lack of effectiveness relative to other known drugs used in the treatment of myopia.

The use of light filters in optical simulators and glasses can increase visual acuity, contrast sensitivity of the eyes, as well as visual comfort in various types of lighting. Spectral filters protect the retina from photo damage.

The main disadvantage of these known solutions is the insufficiently high functionality of the devices, which is associated with the impossibility of changing the shape and location of the holes in the diaphragms, and also because it is not possible to combine colored eyeglass lenses with diaphragms having different holes, which significantly increase the efficiency of vision correction with various eye diseases.

As the closest analogue (prototype) to the claimed technical solution, a vision correction device was selected that contains two diaphragms with through holes inserted in a spectacle frame and additionally having at least one pair of movable diaphragms articulated (RF Patent No. 2163876).

The disadvantage of the prototype is the inability to combine different apertures and lenses, achieving fusion not only due to color filters, but also due to various visual forms made by holes in the diaphragms, thereby limiting the functionality of the device. This device does not allow to extinguish the spectacle frame vibro-acoustic wave coming from the periphery.

The objective of the utility model is to create a multifunctional neuro-ophthalmological simulator that can improve the efficiency and accuracy of the degree of vision correction for various eye diseases due to the individual selection of a combination of diaphragms and lenses, as well as expanding the functionality of the device due to the possibility of using the device for both correction and for rehabilitation training of vision in the treatment of its disorders, in the rehabilitation period, as well as to relieve fatigue and times loads of vision after or in the course of production activities associated with long visual work.

This problem is solved by the fact that the claimed device contains two diaphragms inserted into the housing and one pair of movable lenses pivotally connected to the housing, while the housing contains a vibro-noise insulation gasket from the inside along the periphery, and the lenses and diaphragms are connected to the housing via round plastic threaded pads with the possibility of replacement.

The movable lenses close and open with the possibility of fixation in the upper position. The distance between the movable lenses and the diaphragms of the housing is about 10 mm. The lenses are made in the form of round plastic disks with a thickness of 3 mm and a diameter of 50 mm from colored light-transmitting plastic, they are light filters of red, green, blue and yellow, or they can be made of white matte or transparent transparent plastic.

Various patterns can be applied to lenses by stamping, engraving, or other methods. For example, the application of cross-shaped lines, as in an optical sight, sets the central fixation and helps the eye to focus on the perception of an object in the same way as in other optical devices, for example, binoculars. This application helps the eye to fix and center visual attention, which automatically sets the visual training mode.

The apertures of the device are apertures made of lightproof black plastic with a thickness of 3 mm and a diameter of 50 mm and have a spherical hole with a diameter of 7 mm or 2 mm located in the center of the diaphragm, a spherical hole with a diameter of 2 mm located at a distance of 0.5 cm from the central axis of the diaphragm and a spherical hole 2 mm in diameter located at a distance of 1 cm from the central axis of the diaphragm, or are diaphragms without holes, or diaphragms are diaphragms with a hole made in the form of an oblong slot 2.5 cm long, located on the central horizontal axis in the plane of the lens, or the diaphragms are diaphragms with spherical holes with a diameter of 1.5 mm around the entire perimeter of the diaphragm.

The body is made of opaque plastic, which partially dampens the vibro-acoustic wave coming from the periphery and has ventilation holes to provide oxygen to the eyes. A vibro-noise insulation pad of soft, porous material with good ventilation is attached to the inside of the case, which allows you to completely extinguish glare that can penetrate the case through the ventilation holes.

The lenses conduct a vibro-acoustic wave, i.e. visual and noise flows have a single focus on the membrane of the eye, which creates training synchronization, focusing visual attention and combining it with vibro-acoustic.

The choice of lens color is determined by color vision and a specific human ophthalmic disease. The lenses are presented in red, green, blue and yellow and provide the elimination of the irritating effect of the spectrum bands associated with a particular visual defect in humans. In addition, such light therapy through the eyes can affect the main control centers of the brain, which regulate all the functions of the human body, since the functioning of the eyes directly depends on the nervous system and is controlled by it, thereby bringing into correspondence both the physical and emotional states of the person, which allows at the same time improve visual acuity and contrast, as well as reduce emotional stress in a person and affect his psychosomatic state.

The location of the holes of various types in the diaphragms is selected experimentally and provides an optimal effect on the eyes. The holes allow the light flux to pass to the eye and enter the retina in the form of narrow coherent beams corresponding to their number and shape, providing enhanced image clarity and refractive ability of the eye without accommodation due to self-focusing of the eye.

In FIG. 1 shows a diagram of a multifunctional neuro-ophthalmological simulator. The device comprises a housing (1) with ventilation holes (2) inside of which a vibro-noise insulation gasket (3) is installed on the periphery with diaphragms (5) inserted through round plastic plates with thread (4), as well as hinges attached to the housing (1) ( 6) additional round plastic threaded pads with thread (7) with lenses (8) and an elastic wide tape - holder (9), ears (10) attached to the body (1) to hold the elastic tape (9).

In FIG. 2 is a variant of the diaphragm (5), a front view in which the hole is made in the form of a spherical hole with a diameter of 7 mm or 2 mm and is located in the center of the diaphragm.

In FIG. 3 is a variant of the diaphragm (5), a front view in which a spherical hole with a diameter of 2 mm is located at a distance of 0.5 cm from the central axis of the diaphragm.

Figure 4 is a variant of the diaphragm (5), a front view in which a spherical hole with a diameter of 2 mm is located at a distance of 1 cm from the Central axis of the diaphragm.

Figure 5 is a variant of the diaphragm (5), a front view in which the spherical holes have a diameter of 1.5 mm and are located around the perimeter of the diaphragm.

In FIG. 6 is an embodiment of the diaphragm (5), a front view in which the hole is made in the form of an elongated slot 2.5 cm long, located on the central horizontal or vertical axis in the plane of the lens.

In FIG. 7 is an embodiment of a lens (8), a front view on which cruciform lines are applied, as in an optical sight.

The device works as follows: The device is mounted on the head due to an elastic wide tape (9), easily adjustable and providing a comfortable fit.

The light beam coming to the colored movable lenses (8) pivotally connected to the housing (1) through round plastic threaded plates (7) and passing through the holes of the diaphragms (5) inserted into the breathable housing (1) by means of round plastic threaded plates (4) comes to the eyes. As a result of exposure to the retina of the eye with a highly directional, high-energy color light beam, physicochemical processes occur that can significantly improve vision and treat specific eye diseases.

Using the proposed optical device allows you to correct optical aberrations, improve color perception, enhances motor activity of the muscles surrounding the eye, relieves eye fatigue, treats myopia, farsightedness, astigmatism, strabismus and other diseases through a combination of lenses and diaphragms of the device, which can be changed thanks to round plastic overlays with thread (4, 7).

Examples of specific applications of the device:

At the heart of one of the training regimes on this device is gymnastics "Vigilance" for the eyes of Academician Utekhin Yuri Alexandrovich. The meaning of this gymnastics is as follows: one eye or the other is closed with a dark blindfold, which trains and improves the focusing of the eye, which is not under the blindfold, while giving the opportunity to rest and relax the eye, which is under the dark blindfold. The addiction of each eye to such a regimen increases visual acuity, relieves additional stress from the eyes. The proposed device provides an opportunity for a better similar training. For example, the eye, which should be closed with a dark bandage in the simulator, is closed with white light-penetrating glass, which loads only the retina cones, and the eye, which is open under the pirate blindfold, is stopped in the simulator with black opaque glass with a 7 mm round opening opposite the pupil, which directs the light-information visual flow to the center of the congestion of cones, the maximum focus point of the eye. This creates a more effective training situation than the use of a pirate bandage on 1 eye in Utekhin gymnastics, since tasks that are used more effectively and purposefully are used for which a pirate bandage is used. And since the simulator lenses are interchangeable, that is, there is the opportunity for alternate eye training. Also, training modes can be enhanced by changing white translucent glass to black, opaque, as well as improving the light perception of the eyes by wearing colored transparent glass, red, blue or green on the external level of the simulator in front of a glass with a 7 mm round hole. Thus, the stream of light entering the center of the retina of the eye will be of a specific spectrum, exciting and amplifying only the group of cones that respond to it. Fundamentally, in the retina there are 3 types of color-responsive cones, red, blue and green. Accordingly, the red light filter will create more activity for some and reduced activity for other sensitive cells, which can achieve different training tasks.

Another training mode on this device may be - “Reptile Vision” mode, which allows you to:

1. To remove the acquired stereotypes of visual behavior associated with a deterioration in visual perception.

2. Get rid of night blindness (poor vision in the twilight).

3. Activate the night vision mode, for those who wish to develop such an ability.

In this mode, the simulator is used with 2 black diaphragms with elongated vertical slots and two movable lenses in yellow or orange. You can alternately experiment with yellow and orange colors, focusing on personal feelings. This enhances the effect by giving the brain a different color rendering mode from the right and left eye.

Time to use the simulator: 15-20 minutes for 1 time (no more), 2-3 times during the day, a break between workouts of at least 2 hours.

Methodology: observation of everything that is happening around is desirable in natural conditions in the summer. In winter, use in warm rooms with lots of colorful items.

Usage: in the daytime, preferably in daylight. In the early morning and late evening, this training is not recommended.

The glasses were tested on 10 patients with vision from -5 to +4 D for 1 month according to the described training modes. The whole group noted comfort, improved vision by 1.0-3.0 D, on average, during the first two weeks of using the proposed device.

Thus, through the use of a combined effect on the eye through the use of a combination of translucent lenses, which are light filters and opaque diaphragms, in particular with an elongated hole and spherical holes, in combination with the basic principles of various training modes of application of the device, extremely high results can be achieved in correcting vision defects .

Claims (13)

1. A multifunctional neuroophthalmology simulator, which is a device for vision correction, containing two diaphragms inserted into the housing and one pair of movable lenses pivotally connected to the housing, characterized in that the housing comprises a vibration-insulating gasket from the inside of the housing periphery, lenses and diaphragms connected to case by means of round threaded plastic pads with the possibility of their replacement. 2. A device for correcting vision according to claim 1, characterized in that the movable lenses close and open with the possibility of fixation in the upper position. 3. A device for correcting vision according to paragraphs. 1 and 2, characterized in that the distance between the movable lenses and the diaphragms of the housing is about 10 mm. 4. A device for correcting vision according to claim 3, characterized in that the movable lenses are made in the form of round plastic disks with a thickness of 3 mm and a diameter of 50 mm. 5. A device for correcting vision according to claim 4, characterized in that the movable lenses are made of color translucent plastic, which is a filter of red, green, blue and yellow. 6. A device for correcting vision according to claim 4, characterized in that the movable lenses are made of white translucent opaque plastic. 7. A device for correcting vision according to claim 4, characterized in that the movable lenses are made of transparent translucent plastic. 8. A device for correcting vision according to claim 4, characterized in that various patterns can be applied to the movable lenses. 9. A device for correcting vision according to paragraphs. 4-8, characterized in that the diaphragms are diaphragms of opaque black plastic with a thickness of 3 mm and a diameter of 50 mm. 10. The device for correcting vision according to claim 9, characterized in that the diaphragms have a spherical hole with a diameter of 7 mm or 2 mm located in the center of the diaphragm, a spherical hole with a diameter of 2 mm located at a distance of 0.5 cm from the central axis of the diaphragm, and a spherical hole with a diameter of 2 mm, located at a distance of 1 cm from the central axis of the diaphragm. 11. The device for correcting vision according to claim 9, characterized in that the diaphragms are diaphragms without holes. 12. The device for correcting vision according to claim 9, characterized in that the diaphragms are apertures with an aperture made in the form of an elongated slot 2.5 cm long, located on the central horizontal or vertical axis in the plane of the lens. 13. The device for correcting vision according to claim 9, characterized in that the diaphragms are diaphragms with spherical holes with a diameter of 1.5 mm, around the entire perimeter of the diaphragm.

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