RU85334U1 - DEVICE FOR RESTORING VISUAL FUNCTIONS - Google Patents

Abstract

1. A device for restoring visual functions, comprising a housing in which a pulse generator is located, the outputs of which are connected to two light stimulators fixed in a light-protective spectacle frame, in which LEDs are fixed, which have three primary colors: red, green and blue, control buttons for switching color LEDs and the inclusion of a timer, pulse generator and power supply, characterized in that the controlled pulse generator with its output is connected to the input of the standard pulse generator, the output to it is connected to the input of the mixing and color saturation unit, it has controls for controlling: multi-color LEDs that are connected to light stimulators and are mounted in a light-protective spectacle frame, a timer that has several steps for adjusting the stimulation time and control buttons for choosing color, its saturation, brightness and pulse generation frequency and power on the device. ! 2. The device according to claim 1, characterized in that all the blocks in the device can be implemented on a microcontroller. ! 3. The device according to claim 1, characterized in that all of the listed elements can be in a light-protective spectacle frame.

Description

The utility model relates to medical equipment, and more specifically to ophthalmology, is intended to relieve visual fatigue and can be used to treat: dystrophic diseases of the retina; optic nerve; amblyopia; myopia; to reduce intraocular pressure.

Currently, photostimulation is widely used in the clinic to restore visual functions. It was found that green light has a positive effect on high eye pressure, an elastotonometric curve, ease of outflow of intraocular fluid [EV Garshina, et al. Chromatic stimulation of visual functions in patients with glaucoma. Actual issues of ophthalmology. 1996].

It was noted that under the influence of green light there is a narrowing of the blind spot by the angioscot, an increase in the electric sensitivity and lability of the eye, and an increase in the critical frequency of flicker fusion. The positive effect of green light on visual acuity, peripheral visual field and the dynamics of eye pressure in patients with primary open-angle glaucoma - POAG was shown. It was noted that stimulation with a red flickering light activates the metabolism in the retina and blood flow in its central macular region, and the constant illumination of the retina with light of any color slows down the metabolism [see eg:

Sickel W. Retinal metabolism in dark and light // Physiology of photoreceptor organs. Berlin, Heidelberg. N. Y. S ringer - Verlag. 1972. Vol. 2. - P. 667-727].

In his book “The Eye and His Work” (Moscow, 1950), S. Kravkov noted the significant role of flickering light: “It is absolutely indisputable that visual stimuli also have a general effect on the state of the organism as a whole. This influence “from the eye” is carried out through the anatomical connections between the retina, on the one hand, and the centers of the autonomic nervous system and the pituitary gland, on the other hand, the centers of the autonomic nervous system are located in this area, affecting the most important reactions of our body (blood pressure, respiration, metabolic processes). The pituitary gland is a very important gland of internal secretion, secreting a number of hormones. "

However, it was also noted that in the treatment of macular degeneration, with a flickering red light, in patients prone to hypertension, blood pressure rises by an average of 5-8 mm Hg, which in turn increases intraocular pressure - IOP, [see for example: Shigina N.A., Kuman I.G. and others. Features of pulsed chromatic color in the diagnosis and treatment of ADS. // Clinical Ophthalmology. 2002. V.3. No. 1. p. 37-40]. Such patients were treated only with green light, however, green light reduces the effectiveness of treatment for macular degeneration. In [see V.D. Il'ichev, O.D. Silaev. rehabilitative sound environments. Jour. RAS, Science in Russia No. 12, 2004], it was shown that stimulation with green light for 10 sessions normalizes blood pressure during hypertension.

Research at GU MNTK "Eye Microsurgery" them. ac. S.N. Fedorova, in which 38 children aged 6 to 15 years with partial atrophy of the optic nerve and post-traumatic etiology participated, showed that after stimulation with green light with a frequency of 36-38 Hz, the critical frequency of flicker fusion - CSFM, increased the area of relative and absolute cattle decreased by an average of 35.6%. Visual acuity reached an average of 0.63 from 0.08 to 0.4 and averaged 0.25. The course of treatment was 3 minutes for 10 days [see T.E. Marchinkova, E. M. Mironova and others. Dynamic studies of CSFM in children with optic nerve pathology. Sat report. Conf. Honey. Smolensk Institute, 2004].

A known method of treating cataracts in the initial stage and a device for its implementation [see for example: patent RU No. 2030908, A51F 9/00]. In the specified method, the therapeutic effect is carried out by pulsed light radiation with a frequency of 0.05-1 Hz of a long wavelength of 360-450 nm for a duration of 15-20 minutes. The method involves the treatment of cataracts at an early stage of development. The disadvantage of this method is the range of light radiation and the limited frequency range of stimulation. At the same time, it is known that the use of rays with a wavelength of 320-400 nm increases the incidence of cataracts [see e.g. Zak P.P. Theoretical foundations of spectral vision correction. In the book // Spectral vision correction. Ed. Scientific World. Moscow. 2005. P.190, Ostrovsky MA, Zak PP, et al. Protection of eye structures from light damage and optimization of visual functions. // Bulletin of the ANSSSR. 1988. No. 2. S.63-73. and studies by other authors: Eder, Hiler, Taylor, 19 84].

A known method for the prevention and treatment of eye diseases [see for example, patent RU No. 2117466, Zverev V.A. et al.], in which pulsed light exposure occurs with a frequency of 0.08-1 Hz in the wavelength range from 300 to 760 nm with simultaneous exposure to a constant magnetic field of 30-40 mTs (millitesla). The choice of the spectrum of color stimulation is based on the nosology of the disease, for example, with cataract 300-390 nm, with glaucoma 510-550 nm, for the treatment of myopia or hyperopia 620-760 nm. The duration of exposure is 2-7 minutes, 1-3 times a day, the course of treatment is 20-24 sessions. In addition, this method provides for a psychotherapeutic effect before each session in the form of color music for 15-20 minutes. In this method, the low-frequency range of stimulating pulses in the range of 0.08-1 Hz, practically provides a constant light retina. Another disadvantage is, as in the previous method, the range of light radiation. In addition, it is known that rays with a wavelength of 740 nm to 1-2 nm (IR radiation) can cause damage to structures: the mucous membrane of the eye, lens and retina.

A device for the diagnosis and restoration of visual functions [see for example: RU patent No. 2071301 C1, cl. A61F 9/00], comprising a housing in which a pulse generator is located, the outputs of which are connected to two light stimulators fixed in a light shield, and a power supply unit that is electrically connected to the pulse generator. Using this device, both eyes of the patient are exposed to light from a long wavelength lying in the visible region of the spectrum 400-700 nm, with a flash frequency of 0.06-1 Hz. The specified device contains glasses with light-insulating eyepieces, each of which has a light-diffusing reflector, inside of which a light source is fixed and a replaceable light filter installed opposite it.

The device also contains a regulator of the blinking frequency of light radiation, a switch providing a predetermined light exposure to each eye, a regulator providing a predetermined light exposure to each eye, and a power supply. In this device, all the blocks for influencing the patient’s visual system are placed on a special table in the doctor’s office. The disadvantage of this device is the duration of the procedure, in addition, the frequency and spectrum of radiation has the same characteristics as in the devices described above.

A known method for the treatment of macular degeneration [see for example: USSR author's certificate No. 839529, Soldatova et al., A61F 9/00 or patent SU 1650129], in which, against the background of antioxidase therapy, photostimulation of the central zone of the retina with monochromatic light with a wavelength of 530-590 nm in a pulsed mode with a stimulation frequency of 25 -40 Hz depending on the critical flicker fusion frequency (CFSM). The disadvantage of this method of treatment is that conditions are created under which the effect is not so much on the central as on the peripheral zone of the retina. Photostimulation occurs in mesopic lighting conditions of 30-40 lux, while the pupil expands, sensitivity increases, and therefore the level of perception of the rod system, i.e. its peripheral area. In addition, the entire retina is exposed to light, since the rays of light entering the eyes are significantly scattered from a large light source and located at a distance of 0.5 m from the eyes, the flash energy is 0.3-0.5 J. In the method, it is recommended to use only yellow-green part of the spectrum. However, this mainly activates the cones, which are located in the paracentral region of the retina. From the above it follows that the proposed radiation spectrum mainly stimulates the paracentral region of the retina, which reduces the effectiveness of the treatment of macular degeneration.

The closest analogue, taken as a prototype, is a device [see RU patent No. 218968]. The specified device contains a housing in which a pulse generator is located, the outputs of which are connected to two light stimulators made in the form of LEDs fixed in a light-protective spectacle frame. The device comprises a power supply unit, which is electrically connected to the pulse generator, and a timer connected between the power supply unit and the pulse generator. The device also contains a control button for switching the color of the LEDs. The disadvantage of this device is the inability to stimulate a mixture of colors to change the spectral composition of the stimuli. It is known, for example: that a mixture of red with green, with a certain ratio of the brightness of each color, makes it possible to obtain a neutral yellow color.

It is known that the color distinction in the yellow-red range has individual specifics. Presumably, this is due to the existence in humans of two spectral genetic populations of red cones [see e.g. Zak P.P. and others. Spectral vision correction. Moscow, ed. The Scientific World, p. 190, 2005]. It was also shown that flickering light with a frequency close to critical (36-39 Hz) affects both the centers responsible for eye movement and the paths connecting these centers with the eye muscles and improves the ciliary muscle of the eye and circulation in the blood vessels of the eye . As experiments on 200 test students of universities conducted to relieve visual fatigue after classes on computers showed that stimulation with a mixture of green and red light, with a stimulation frequency of 36-40 Hz, relieves visual fatigue in most subjects and increases visual acuity. The frequency and color selected individually for each patient increase visual acuity, reduce high eye pressure, normalize blood pressure, increase accommodation, improve the functioning of the ciliary muscle of the eye, and, accordingly, increase the field of view.

In the proposed utility model, the device comprises a housing - 1, in which are located: a power supply unit - 2 connected to a controlled timer - 3, which is connected to a controlled pulse generator - 4, electrically connected to a standard pulse generator - 5, color mixing unit - 6, electrically connected to multi-color LEDs - 7, a light-protective spectacle frame - 8, and controllers for controlling multi-color LEDs (see figure 1).

The implementation of the color mixing function is carried out due to the ratio of the brightness of one color in relation. The brightness of a different color. In physical terms, color saturation is determined by the nature of the distribution in the spectrum of visible color. So, for example, with the same brightness of green and red, a person with normal vision defines this color as yellow. With a greater brightness of red in relation to green - the color is perceived as orange.

A distinctive feature of the proposed device is that the controlled pulse generator, with its output connected to the input of the standard pulse generator, the output of which is connected to the input of the mixing and color saturation unit, has regulators for controlling: multi-color LEDs that are connected to the light stimulators and are mounted in a light-protective eyeglass a frame, a timer that has several steps for adjusting the stimulation time and control buttons for choosing a color, its saturation, brightness and frequency pulses and power on the device.

The frequency of pulse generation, in contrast to the above devices, ranges from 35 to 45 Hz, and is individually selected by the patient.

This device allows the patient to regulate such characteristics as: stimulation time; choice of color and its saturation; frequency and brightness of pulses.

All units in the device can be implemented on the microcontroller. For the convenience of the patient, all of the listed device elements may be in a light-protective spectacle frame.

Claims (3)

1. A device for restoring visual functions, comprising a housing in which a pulse generator is located, the outputs of which are connected to two light stimulators fixed in a light-protective spectacle frame, in which LEDs are fixed, which have three primary colors: red, green and blue, control buttons for switching color LEDs and the inclusion of a timer, pulse generator and power supply, characterized in that the controlled pulse generator with its output is connected to the input of the standard pulse generator, the output to it is connected to the input of the mixing and color saturation unit, it has controls for controlling: multi-color LEDs that are connected to light stimulators and are mounted in a light-protective spectacle frame, a timer that has several steps for adjusting the stimulation time and control buttons for choosing color, its saturation, brightness and pulse generation frequency and power on the device. 2. The device according to claim 1, characterized in that all the blocks in the device can be implemented on a microcontroller. 3. The device according to claim 1, characterized in that all of the listed elements can be in a light-protective spectacle frame.