RU2501538C2 - Method for prevention and treatment of refraction visual impairments and device for implementation thereof - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: group of inventions refers to ophthalmology and may be applicable for prevention and/or treatment of refraction visual impairments. The method for prevention and/or treatment of refraction visual impairments involves creating an optical focus through optical elements on a retinal fovea. The optical focus is created on the periphery on an eye ground in front of the retina in one meridian and behind the retina in the other meridian perpendicular to the first one. A device for prevention and treatment of the refraction visual impairments comprises optical elements with a front surface and an optical centre; the optical elements are presented by lenses with asymmetrical vertical refraction distribution through a geometrical centre of the lens oriented in the device so that the refraction moving from the geometrical centre asymmetrically increases monotonically from both sides of the vertical line passing through the geometrical centre of the lens; the refraction either remains unchanged, or decreases monotonically as compared to the refraction in the geometrical centre in relation to a horizontal line perpendicular to the vertical line through the geometrical centre.

EFFECT: developing the method for prevention and/or treatment of the refraction visual impairments.

6 cl

Description

The inventions, united by the unity of the inventive concept, relate to medicine, more specifically to ophthalmology, and relate to methods and devices for the prevention and treatment of refractive disorders.

There is a method of primary prevention of accommodation spasm and the disorders caused by it: myopia, asthenopia and other visual disorders. The preventive result, according to the author, is achieved by creating comfortable conditions for the eyes to work using sphere-prismatic glasses. The method is as follows. Healthy children and adults in moments of intense work at close range (reading, writing, working at a computer, etc.) use preventive glasses that combine two effects: to create comfort in the ciliary muscle, plus lenses are used, selected according to the principle of comfort (search it is conducted in the zone by 1.5-2-2.5 (maximum up to 3.0) units in the plus side of the eye refraction value determined in the usual way, and prism creation tools are used to maintain the comfortable work of the internal rectus muscles of the eye diverging effect (up to a maximum of 6.25 prdptr.) In this case, in order to maintain the fitness of the muscles involved in the accommodation and convergence processes, it is recommended to use glasses with optical characteristics that provide only half the diopters compared to those used for treatment and secondary prevention. eyes from the work of accommodation and convergence, which are achieved using glasses with diopters + (2.25-3) diopters and a prismatic effect of up to 6-7 prdpts (maximum or submaximal unloading, relaxing effect), in prophylactic glasses a moderate relaxing effect is achieved through the use of average optical characteristics, namely + (1.0 +/- 0.5) diopters. in combination with 2.0 +/- 0.5 ave. diopters, in which the relaxing effect will be preserved and, at the same time, the risk of muscle deterioration is practically absent (see RF Patent No. 2177282, patentee: Ermoshin Andrey Fedorovich, priority of 11/17/2000)

The disadvantages of this method are: a contraindication to the use of streets with heterophory exophore type, the method requires the consistent use of several devices, the method provides prevention only when working close, the method affects only the state of the external rectus muscles and ciliary muscle.

A known method for the prevention and treatment of myopia by the method of divergent disaccommodation according to A.I. Dashevsky (Vatchenko A.A. Spasm of accommodation and myopia. Kiev, Zdorovya, 1977.). The method of divergent disaccommodation is as follows. After determining the visual acuity and the degree of myopia, prisms with a strength of 1-2 ave diopters are placed in front of each eye, facing the nose with the base, which causes divergent disaccommodation. After a fraction of a minute (rarely in a few minutes), visual acuity increases, and the strength of the prisms can be increased (usually up to 2-3 prdptr, but not more than 4 prdptr for each eye) until the maximum increase in visual acuity is achieved. This procedure is repeated daily, which leads to the gradual removal of pseudomyopia and an increase in visual acuity, often to 1.0.

The disadvantages of this method are: the necessity of carrying out the method in a medical office, with the participation of medical personnel, the method only affects the accommodation-convergence relationship.

A known method for the prevention and treatment of myopia (Lyalin AN “Method for the prevention and treatment of myopia.” Patent for the invention No. 2332968, publication date September 10, 2008), which is carried out through training in 4 stages. At the first stage, spherical lenses with optical power from +0.625 to +1.25 diopters are used; cylindrical +1.0 diopters., the axes of which are located in the vertical and horizontal meridians, as well as prismatic lenses 1.5 diopters, located base to each other. At the second stage of training, prismatic lenses with an optical power of 2.0 to 3.0 diopters are used, the base of which is located in the inner quadrants. At the third stage, sphere-prismatic lenses with an optical power of from 0.5 to 2.5 diopters of spherical and from 2.0 to 4.0 diopters of prismatic components with the lenses placed on top of each other are used, and the lens power is increased in increments of 0.5 diopters. At the fourth stage, cylindrical lenses with an optical power of +1.25 diopters, the axes of which are located in the vertical and horizontal meridians, and prismatic lenses with an optical power of 2.0 diopters are used. The “peak-base" lines of the prisms are located in the horizontal and oblique meridians, the base of which are in the inner quadrants. The disadvantage of this method is: the use of several devices for its implementation, the need for the presence and participation of medical personnel, the use of many stages for carrying out the method.

The known method, including gymnastics for the eyes "Vigilance" proposed Utekhin Yu.A. (V.Artamonov "Think about your eyes" (Conversation with Yu.A. Utekhin) M .: Vneshsigma LLP, 1992, pp. 27-28.). The basic principle of gymnastics: to read and write at the maximum distance, and not with both eyes, but alternately, then one, then the other.

1) It is recommended to move the objects under consideration to the maximum distance at which a clear vision is maintained.

2) Perform all the small work alternately, then with one or the other eye for 15-30 minutes each. To do this, it is recommended to cover one eye with a “curtain” of paper or fabric.

3) Twice a month, measure the maximum distance from which the text is clearly understood and record the result in a diary. For the results to be comparable, you need to use the same text and similar lighting conditions when measuring. Working in this way are the principles of 1) the distance of the considered objects in order to reduce the work of accommodation; 2) alternate use of the right and left eye in order to exclude the work of convergence.

The disadvantage of this method is that it requires a person who is engaged in a significant concentration of attention for the duration of the training, to create special conditions for carrying out the method, devices or devices for blocking the eyes are necessary, and the method is limited to affecting accommodation and convergence only.

A known method of spectral optical reflex therapy to improve vision, which is based on a cyclical change in the degree of tension of accommodation of the eye. The method is carried out by changing the spectral composition of the intense luminous flux, where one luminous flux forms visual stimuli on the retina and the other flux forms the color backgrounds of visual stimuli. The spectral composition is changed with a cyclic increase and decrease in the wavelength of the position of the center of the spectral distribution of intensities of the more intense of the mentioned light fluxes. The spectral compositions of the light fluxes are formed with different values of the wavelengths of the positions of the centers of the spectral distributions of the intensities of the light fluxes (see Application No. 2001100289/14 of 05/01/2001, Applicant A. Eremeev, published on 10/10/2001).

The disadvantage of this method is directed light differently stimulating the retina, which can disrupt biochemical processes in it in some cases, the effect of improving vision is achieved only by changing the accommodation voltage, a complex, cost-effective device is used to implement the method, the method is not safe for degenerative changes in the retina and optical structures of the eye.

A known method for the prevention and treatment of acquired myopia using an optical simulator containing an optical system of sphere-prismatic lenses and a rim by increasing the distance between the front surface of the eye and the optical system of the simulator, characterized in that the distance is produced by fixing the simulator for the supporting arch and moving it to sagittal direction anterior to the anterior surface of the eye until diplopia appears and back to its original position. 2. The method according to claim 1, characterized in that the increase in the distance between the front surface of the eye and the optical system of the simulator is in the range from 1.0-1.2 to 3.0 ± 1.0 cm. 3. The method according to claim 1 , characterized in that the increase in the distance between the front surface of the eye and the optical system of the simulator is carried out within 10-15 C. 4. The method according to claim 1, characterized in that the increase in the distance between the front surface of the eye and the optical system of the simulator is carried out repeatedly. 5. The method according to claim 1, characterized in that the increase in the distance between the front surface of the eye and the optical system of the simulator is carried out automatically (see RF Patent No. 2007147269, IPC: A61N. Published June 27, 2009, author: Korepanov Alexander Valentinovich ( RU), Kuznetsova Galina Evgenievna (RU), Starikova Dina Ilsurovna (RU)).

The disadvantages of this method are: it is desirable to carry out the method in a medical office, the presence and participation in the method of medical personnel or consumer training in controlling the simulator is necessary, requires the use of a special expensive device.

Closest to the proposed method is a known method of restraining myopia in a nearsighted person, which involves wearing glasses with optical elements that provide optical correction of myopia, both in the central area of the retina, and the correction of myopia or hyperopia at the periphery in diameter of at least 270 degrees (see US Patent 2010/0157240 A1, IPC G02C 7/04, G02C 7/06, A61B 3/00 GregorF.Schmid, application No. 12/639,101 dated 12/16/2009, published 06/24/10).

The disadvantage of this method is the lack of indications for prophylactic use in refractive disorders, it does not provide selective correction on the periphery of only one of the meridians, does not provide for the simultaneous hypercorrection of myopia or hyperopia on the periphery of the water meridian and hypocorrection of myopia or hyperopia on the periphery in a mutually perpendicular meridian.

The objective of the invention is to provide a method for the prevention and treatment of refractive disorders of vision, in particular, which allows, along with restraining the development of myopia in a shortsighted person, to prevent the occurrence of shortsightedness in a person at risk of myopia.

The problem is solved by achieving a technical result, which consists in regulating the ratio of the values of axial refraction with refraction at the periphery from the nasal and temporal sides of one of the meridians, as well as in regulating the ratio of the values of the refractive power of mutually perpendicular meridians.

The technical result is achieved in a method for the prevention and treatment of refractive disorders by focusing visual images, when viewed through optical elements, on the foveal region of the retina and focusing visual images on the periphery of the fundus in front of the retina in one meridian and behind the retina in another meridian, perpendicular to the first, in particular in front of the retina in the horizontal plane and behind the retina in the vertical plane on the periphery of the fundus, and on the retina in the center, which provides enhanced ref ktsii eyes in the horizontal plane at 30 degrees to the periphery of the fovea with the nasal and temporal sides with no change or attenuation of refraction in the vertical plane of 30 degrees from the top and bottom of the fovea, which leads to a weakening of refraction of the visual axis.

The technical result can also be achieved in a method for the prevention and treatment of refractive disorders of focused visual images, when viewed through optical elements, on the foveal region of the retina and by focusing visual images on the periphery of the fundus in front of the retina in one meridian and on the retina in another meridian, perpendicular to the first one also provides regulation of the ratio of axial refraction to refraction at the periphery.

A device for the prevention and treatment of refractive disorders, in particular myopia, presented in the form of special glasses with a prismatic effect; these are bifocal sphere-prismatic glasses (BSPO) proposed by E.V. and Yu.A. Utekhiny for unloading accommodation and convergence when working at close range; the lenses in these glasses have the main part for distances from 0 to -11 diopters and the near element glued in the lower part, containing a sphere + 2.25 diopters and a prism of 6.75 prpts with the base to the nose; such glasses provide an optical installation of the eye to a distance of 45 cm without tension accommodation and convergence. (see Yu.Z. Rosenblum, Optometry, St. Petersburg Hippocrates Publishing House, 1996. p. 55). The disadvantages of this device are: a priority effect on accommodation and convergence when working near, the presence of a jump in the image occurring at the boundary of the lens and the prismatic element, the device is limited in use for heterophory by the type of esophory, and also BSO glasses are not aesthetic.

Since 1784, bifocal optical lenses inserted into the frame have been known, they form a device in the form of glasses that help to see distant objects as clearly as close ones. The bifocal lens has two optical zones with different refractions, usually for distance and near. (see Mo Dzhali, “Spectacle lenses and their selection”, St. Petersburg, VEKO publishing house, 2006. pp. 123-124). Bifocal lenses are made either from one glass, on the surface of which (usually the back), by grinding and polishing they form a zone with a different refractive power, or from two glasses with different refractive indices, sintered between each other. In such bifocal lenses, the dividing line is almost invisible. In a single bifocal lens, the optical centers of areas intended for distance and near are located on one vertical line. In sintered bifocal lenses, the geometric centers of the lower part of the lenses for the right and left glass are displaced inward from the vertical meridian of the lens by 2.5 mm. In such glasses, visual lines pass through the centers of the lenses when viewing both distant and close objects. (see Yu.Z. Rosenblum, Optometry, St. Petersburg Hippocrates Publishing House, 1996. pp. 52-53).

The disadvantages of this device are: the presence of a jump in the image at the point of transition of one refraction to another, the preventive effect of the glasses is ensured only by unloading accommodation when working close, low efficiency when applied, they do not provide a multidirectional change in focus on the retina in mutually perpendicular meridians.

A device equipped with progressive lenses is known (Olga Scherbakova “Progressive Lenses”, prepared according to the materials of CarlZeiss, Veko # 8 (63), published on December 24, 2002 in the Medical Library on the server Medlinks.ru), in which a smooth increase in refraction is achieved by a surface design in which the radius of curvature gradually decreases, both in the vertical and horizontal directions, the lenses have two stable zones of vision correction: the upper for the distance and the lower for the near, the area between the zones for near and far, in which going on t increase (progression) of refraction, is called a “corridor” or progression zone and, thanks to a smooth increase in refraction, the glasses wearer, lowering his eyes down for reading, uses a zone with higher refraction values, which is necessary for vision correction in this range, in peripheral zones located Outside the “corridor” of progression, a gradual increase in distortion occurs.

The disadvantages of this device are: the indications do not use refractive disorders for the prevention and treatment, do not create a selective multidirectional focus change on the retina in mutually perpendicular meridians, there are significant “conjugation” areas on the periphery of the progressive lenses that distort the image when viewed through them, require a period of getting used to.

Closest to the proposed is a device that includes an optical element for correcting myopia in the eye of the owner, an optical element having a front surface, an optical axis, and an optical center, the optical element includes: (a) a central zone providing a first optical correction for a significant correction of myopia associated with the foveal region of the wearer's eye, the central zone includes an area in order to maintain central vision over the angular range of the ocular about rotation of the optical axis; and (b) a peripheral zone surrounding the central zone, a peripheral zone providing a second optical correction to substantially correct the myopia or hyperopia associated with the peripheral region of the retina of the wearer's eye; where the average surface force of the peripheral zone within a radius of 20 mm from the optical center, measured along the front surface is not less than + 0.50 D relative to the surface force in the optical center, the azimuthal value of which is not less than 270 degrees. (see Patent US 2010/0157240 A1, IPC G02C 7/04, G02C 7/06, A61B 3/00 GregorF. Schmid, application No. 12/639,101 dated December 16, 2009, published June 24, 10).

The disadvantage of this device is the peripheral correction of refraction in a radius of at least 270 degrees, because of this, the prototype does not provide an increase in the collecting refractive power along one meridian and an increase in the scattering power of refraction along the mutually perpendicular meridian relative to the optical (geometric) center of the optical element, which prevents the effective regulation of the ratio of values axial refraction to peripheral refraction. The method does not provide for the possibility of exposure to other types of refraction, except myopia. Features of the formation of refraction in this lens suggests the presence of multiple aberrations of the peripheral zone, causing significant discomfort when using this device.

The objective of the invention is to provide a device for the prevention of refractive disorders of the eye, the most common of which are myopia.

A prerequisite for the development of the proposed method and device for its implementation were the results of studies of peripheral refraction at 30 degrees from the visual axis of the eye from the nasal and temporal sides. Studies conducted on the clinical base of the ArtOptika Vision Center in 196 patients aged 5 to 36 years with various types of refraction showed regular changes in the state of peripheral refraction, 30 degrees from the visual axis of the eye from the nasal and temporal sides, in relation to the value central refraction measured along the visual axis. The studies revealed that in nearsighted patients, peripheral refraction is relatively far-sighted compared to central, in far-sighted patients, peripheral refraction is relatively short-sighted compared to central refraction, and in emmetropic patients, peripheral refraction is 30 degrees from the visual axis of the eye from the nasal and temporal sides slightly different from the central one. The results obtained are consistent with the data of other authors, so when studying peripheral refraction in a large group of children with long-term observation, it was noted that 2 years before the appearance of central myopic refraction and clinical manifestations of myopia, pronounced relative peripheral hyperopia (Peripheral Refraction and Ocular Shape in Children, D. Mutti et al., Investigative Ophthalmology & Visual Science / April 2000, vol. 41, no. 5, 1022-1030). Based on the results of his own research and the results obtained by other authors, and in recent decades, in model animal experiments, Josh Wallman formulated a hypothesis about homeostatic mechanisms for controlling eye growth, where the state of peripheral refraction of the eye plays the main role. The author testifies that the creation of myopic or hyperopic year focus on the periphery of the retina causes a versatile cascade of biochemical transformations in the retina, vascular eye and sclera, which creates the prerequisites for the formation of various types of refraction. (Homeostasis of Eye Growth and Question of Myopia, Josh Wallman and Jonathan Winawer, Neuron, Volume 43, Issue 4, 447-468, August 19, 2004).

The problem is solved by achieving a technical result, which consists in regulating the ratio of the values of axial refraction with refraction at the periphery from the nasal and temporal sides in one of the meridians, as well as in regulating the ratio of the values of the refractive forces of mutually perpendicular meridians.

The claimed technical result is achieved in a device for the prevention and treatment of refractive errors of vision, including optical elements, in the form of lenses with a front surface and an optical center, with an asymmetric distribution of refraction relative to one of the meridians passing through the geometric center of the lens, on one and the other side of the meridian at an asymmetric distance from the geometric center, the refraction is monotonically enhanced, and with respect to the mutually perpendicular meridian passing through the geometry esky center refraktsiyane menyaetsyalibo monotonically diminishes with respect to refraction in the geometric center.

For subjects with hyperopia along the visual axis, a device should be used for the prevention and treatment of refractive disorders of vision, including optical elements, in the form of lenses with a front surface and an optical center with an asymmetric distribution of refraction relative to one of the meridians passing through the geometric center of the lens, one at a time the other side of the meridian at an asymmetric distance from the geometric center, the refraction monotonically weakens, and relatively mutually perpendicular meridian on passing through the geometric center, the refraction does not change or monotonously amplifies with respect to refraction in the geometric center.

Also, in individual cases, the technical result will be achieved in a device for the prevention and treatment of refractive errors of vision, including optical elements, in the form of lenses with a front surface and an optical center with an asymmetric distribution of refraction relative to one of the meridians passing through the geometric center of the lens, on one side of the meridian at an asymmetric distance from the geometric center, refraction is monotonically enhanced, on the other side, refraction is monotonously weakened, and relatively of a mutually perpendicular meridian passing through the geometric center, the refraction does not change, monotonously weakens, or monotonically amplifies with respect to refraction in the geometrical center.

In particular, the claimed technical result is achieved in a device for the prevention and treatment of refractive errors, including optical elements in the form of lenses with a front surface and an optical center, with an asymmetric distribution of refraction relative to the vertical passing through the geometric center of the lens, oriented in such a way that on one and the other side relative to the vertical passing through the geometric center of the lens, with an asymmetric distance from the geometric center of the refractor I monotonically increases, and relative to the horizontal, perpendicular to the vertical passing through the geometric center, refraction does not change monotonically or weakening in relation to the refractive index in the geometric center.

In another embodiment of the device, in particular, the claimed technical result is achieved in a device for the prevention and treatment of refractive errors of vision, including optical elements in the form of lenses with a front surface and an optical center, with an asymmetric distribution of refraction relative to the vertical passing through the geometric center of the lens, oriented the device in such a way that on one and on the other side relative to the vertical passing through the geometric center of the lens, at an asymmetric distance from the geometric center, the refraction is monotonously weakening, and relative to the horizontal, perpendicular to the vertical through the geometric center, the refraction does not change or monotonically increases with respect to the refraction in the geometric center.

The device is illustrated in graphic material, where Figs. 1-25 show embodiments of the proposed device for the prevention and treatment of refractive visual impairment.

Figure 1 presents a front view of the proposed device, made in the form of glasses, which are a frame 1 with optical elements installed in it (right - 2p and left 2l) with geometric centers of the lenses 3p and 3l with a horizontal axis 4.

Figure 2 shows a front view of the device using a spectacle frame 5 with holders 6p and 6l of optical elements 3p and 3l, nose stop 7, while the holders 6p and 6l are made with the possibility of movement in the horizontal plane (shown by arrows), nose stop 7 is made with the possibility of vertical movement (shown by arrows).

Figure 3 shows the same as in figure 2, but a top view showing the clips 8p and 8l, the scales 9p and 9l, placed on the upper end 10 of the frame 5, designed to measure the distance of the holders 6p and 6l from the center of the nose stop 7 (mm.), While the latches 8p and 8l are made with the possibility of movement in the radial direction (shown by arrows).

Figure 4 shows the right optical element 2p for creating an optical focus in front of the retina in the 11p plane and behind the retina in the 12p plane on the periphery of the fundus, and the focus on the retina in its central part, containing optical centers located in one plane 11p, thus that the refraction is distributed asymmetrically with respect to the plane 12p passing through the geometric center 3p, and at different distances from the geometric center 3p monotonously weakens, while the refraction within the plane 12p passing through the geometric the center of 3p is unchanged or monotonically amplifies with respect to refraction in the geometric center of 3p, with the plane 11p lying horizontally and the plane 12p vertically.

Figure 5 shows the left optical element 2L for creating optical focus in front of the retina in the 11l plane and behind the retina in the 12l plane on the periphery of the fundus, and the focus on the retina in its central part, containing optical centers located in the same 11l plane, thus that the refraction is distributed asymmetrically with respect to the 12l plane passing through the geometric center of 3l, and at different distances from the geometric center 3l monotonously weakens, while the refraction within the 12l plane passing through the geometric the center center of 3L is unchanged or monotonously increases with respect to refraction in the geometric center of 3L, while the 11l plane is horizontal and the 12l plane is vertical.

Figure 6 shows the same as in figure 4, but the plane 11p is located vertically, and 12p is horizontal.

Figure 7 shows the same as in figure 5, but the plane 11p is located vertically, and 12p is horizontal.

On Fig shows the same as in figure 4, but the plane 11p is located at an angle of 45 degrees relative to the vertical, and 12p is mutually perpendicular to the plane 11p.

Figure 9 shows the same as in figure 5, but the plane 11p is located at an angle of 45 degrees relative to the vertical, and 12p is mutually perpendicular to the plane 11p.

Figure 10, 14, 18, 22 shows the change in refraction with distance from the geometric center 3p within the plane 11p, while the vertical axis shows refraction in diopters, and the horizontal axis shows the distance from the geometric center 3p.

11, 15, 19, 23 show the change in refraction with distance from the geometric center 3p within the plane 12p, while the vertical axis shows the refraction in diopters, and the horizontal axis shows the distance from the geometric center 3p.

On Fig, 16, 20, 24 shows the change in refraction with distance from the geometric center of 3L within the 11l plane, while the vertical axis shows the refraction in diopters, and the horizontal - the distance from the geometric center of 3L.

13, 17, 21, 25 show the change in refraction with distance from the geometric center of 3 l within the plane of 12 l, while the vertical axis shows refraction in diopters, and the horizontal axis shows the distance from the geometric center of 3 l.

The device shown in figure 2, 3, is universal and can be used with various anthropometric data of patients.

In approbation of the inventive method with a device for its implementation involved 86 people aged 7 to 36 years, with various refractive disorders of vision.

Patients used the proposed device to implement the method for the prevention and treatment of refractive disorders for several days to several months for 1-6 hours under natural or artificial lighting without restricting gaze fixation.

Example 1. Patient S., 36 years old, diagnosis: mild myopia, accompanied by complaints of visual impairment in the distance after prolonged use of a computer monitor. Ophthalmic status before applying the method.

Axial refraction: OD sph -1.00dptr., Sul -0.50dptr., Ah 98 g., OS sph -1.25dptr., Sul -0.50 dptr., Ah 75 gr.

Visual acuity without correction: OD 0.2 sph -0.75 dptr., Sul -0.50 dptr., Ah 95 gr. = 1.0, OS 0.2 with sph - 1.25dptr., Sul -0.50dptr., Ah 75 gr. = 1.0.

Peripheral refraction 30 degrees from fovea:

OD horizontally from the bow sph + 1.25 diopters., Cal +1.00 diopters, ax 64 g., From the temporal side sph + 0.50 diopters, sul -1.50 diopters, ax 130 gr.

OD vertically on top sph + 0.50 dptr., Sul -1.00 dptr., Ah 48 g., Bottom sph - 0.12 dptr., Sul - 1.75 dptr., Ah 179 gr.,

OS horizontally from the nose side sph +1.12 diopters., Sul + 0.75 diopters., Ah 36 gr., From the temporal side sph +0.25 diopters., Sul -2.25 diopters., Ah 110g ..

OS vertically on top sph +1.00 diopters., Sul +1.25 diopters., Ah 128 g., Bottom sph - 0.12 diopters., Sul - 1.75 diopters., Ah 12 gr.,

The patient applied the claimed method, when the patient for 6 hours used the device in the form of glasses, presented in figure 1, figure 4, figure 5, figure 22, figure 23, figure 24, figure 25, and when viewed objects through optical elements in the form of aspherical lenses, the optical centers of which are in the same horizontal plane and have a geometric center with zero refraction, oriented in the device in such a way that on one or the other side, at different distances from the geometric center, it monotonically amplifies to +2 , 0 diopters, and in vertical p oskosti refraction has not changed.

Thus, the device provided a decrease in the relative hyperopic defocus at the periphery of the retina horizontally, thereby contributing to an increase in the clarity of the projected image, creating a condition for changing the refraction of the eye. The course of treatment was 7 days.

Ophthalmic status after application of the method.

Axial refraction: OD sph -0.75 dptr., Sul -0.25 dptr., Ah 100g., OS sph -1.00 dptr., Sul -0.50dptr., Ah 75 gr.

Visual acuity without correction: OD 0.3 with sph -0.75 dptr., Sul -0.25 dptr., Ah 100 gr. = 1.0, OS 0.3 with sph -1.00 diop., Sul -0.50 diop., Ah 75 gr. = 1.0.

Peripheral refraction 30 degrees from Fovea horizontally and vertically:

OD horizontally from the bow sph +0.75 diopters., Sul + 1.00 diopters., Ax 64 g., From the temporal side sph +0.00 diopters., Sul -1.50 diopters., Ah 130 gr.

OD vertically on top sph + 0.50 dptr., Sul -1.00 dptr., Ah 52 g., Bottom sph -0.25 dptr., Sul -1.75 dptr., Ah 4 gr.,

OS horizontally from the nose side sph +1.00 diopters., Sul +0.50 diopters., Ah 45 gr., From the temporal side sph - 0.25 diopters., Sul -2.25 diopters., Ah 108 gr.

OS vertically on top sph +0.50 diopters., Sul +1.00 diopters., Ah 136 g., Bottom sph -0.12 diopters., Sul -1.75 dptr., Ah 8 gr.,

Thus, as a result of treatment with the proposed method, an increase in visual acuity without correction was noted, myopia indices decreased according to refractometry and subjective correction. Peripheral refraction 30 degrees from the fovea horizontally from the temporal and nasal sides intensified, and vertically, above and below, weakened or remained unchanged.

Example 2. Patient A., 10 years old, diagnosis: progressive weak myopia of both eyes, accompanied by complaints of visual impairment in the distance over the past year. Ophthalmic status before applying the method.

Axial refraction: OD sph -1.50 diopters., Sul -0.75 diopters., Ah 8 g., OS sph -1.50 diopters., Sul -0.25 diopters., Ah 165 gr.

Visual acuity without correction: OD 0.1 sph -2.00 diopters, sul -0.75 diopters, ah 10 gr. = 1.0, OS 0.1 sph -1.75 dptr., Sul -0.25 dptr. ah 165 gr. = 1.0.

Peripheral refraction 30 degrees from Fovea horizontally and vertically:

OD horizontally from the bow sph + 2.00 diopters, sul -0.75 diopters, ax 87 gr., From the temporal side sph +1.75 diopters, sul -1.00 diopters, ax 112 g. , OD vertically on top sph +1.25 dptr., Sul +0.75 dptr., Ah 130 g., Bottom sph -0.50 dptr., Sul -1.00 dptr., Ah 164 gr.,

OS horizontally from the nose side sph +1.50 diopters., Sul-0.50 diopters., Ah 44 gr., From the temporal side sph +1.25 diopters., Sul -1.00 diopters., Ah 110 gr.

OS vertical top sph +0.75 dptr., Sul +1.50 dptr., Ah 122 gr., Bottom sph -0.75 dptr., Sul -0.75 dptr., Ah 8 gr.

The patient applied the claimed method, when the patient for 6 hours used the device in the form of glasses, presented in figure 1, figure 4, figure 5, figure 10, figure 11, figure 12, figure 13, and when viewed objects through optical elements in the form of aspherical lenses, the optical centers of which are in the same horizontal plane and have a geometric center with zero refraction, oriented in the device so that on one and the other side, at different distances from the geometric center, the refraction is monotonically enhanced up to +1.75 diopters., and in tikalnoy on one plane and on the other side of the geometric center of refraction monotonically weakened to -0.25 diopters. The device provided a decrease in the relative hyperopia at the periphery of the retina horizontally and created an increase in the relative hyperopia at the periphery of the retina, increasing the clarity of the projected image on the periphery in the horizontal plane, and slightly reducing the clarity of the image on the periphery, contributing to a change in the ratio of refractive indices on the periphery in mutually perpendicular meridians with respect to axial refraction of the eye. The course of treatment was 14 days.

Ophthalmic status after treatment.

Axial refraction: OD sph - 1.00 dptr., Sul-0.50 dptr., Ah 12 gr., OS sph -1.25 dptr., Sul - 0.25 dptr., Ah 170 gr.

Visual acuity without correction: OD 0.2 with sph -1.50 diopters, sul -0.50 diopters, ax10 gr. = 1.0, OS 0.3 with sph - 1.5 diopters, sul -0.25 diopters, ax 170 g. = 1.0.

Peripheral refraction 30 degrees from Fovea horizontally and vertically:

OD horizontally from the bow sph +1.25 diopters., Sul-0.50 diopters., Ah 76 gr., From the temporal side sph +1.00 diopters, sul -0.75 diopters, ah 96 g.

OD vertically on top sph +1.50 diopters., Sul +1.00 diopters, ax 135 gr., Bottom sph - 0.50 diopters., Sul -0.75 diopters., Ah 168 g., OS no horizontal with nasal side sph +1.25 diopters., sul -0.50 diopters., ah 46, from the temporal side sph +1.00 diopters., sul -1.25 diopters., ah 118.

OS vertical top sph +1.50 diopters., Sul +1.50 diopters., Ah 117 gr., Bottom sph -0.50 diopters., Sul -0.75 diopters., Ah 10 gr.,

As a result of the treatment by the proposed method and device, an increase in visual acuity without correction was noted, myopia indices decreased according to axial refractometry and subjective correction. Peripheral refraction, measured at 30 degrees horizontally from the nasal and temporal sides of the fovea, intensified, and, in turn, a weakening of peripheral refraction from above and below 30 degrees vertically.

Example 3. Patient A., 7 years old, diagnosis: mixed direct astigmatism of both eyes. The child did not make a complaint, but the parents noted that the child does not see the remote objects. Ophthalmic status before treatment.

Axial refraction: OD sph +0.12 diopters, sul -0.75 diopters, ax 166, OS sph +0.25 diopters, sul -1.00 diopters, ax 160.

Visual acuity without correction: OD 0.6 sul -0.75 diopters, ax 165 = 1.0, OS 0.7 diopters, sul -1.00 ax 160 = 1.0.

Peripheral refraction 30 degrees from fovea:

OD horizontally from the bow sph +1.25 diopters, sul +0.75 diopters, ax 22, from the temporal side sph +1.00 diopters, sul +0.50 diopters, ax 18,

OD vertically on top sph +2.25 diopters., Sul +0.50 diopters., Ax 92 g., From below sph +0.75 diopters., Sul - 1.00 diopters., Ah 77 g.,

OS horizontally from the bow sph + 0.75 dptr., Sul +0.75 dptr., Ah 52, from the temporal side sph +1.50 dptr., Sul + 1.12 dptr., Ah 38.

OS vertically on top sph +1.00 diopters, sul +1.00 diopters, ax 87 gr., Bottom sph +0.25 diopters, sul -0.50 diopters, ax 156 gr.,

The treatment was carried out in which the patient for 6 hours used the device in the form of glasses, presented in figure 1, figure 4, figure 5, figure 14, figure 15, figure 16, figure 17, and when viewing objects through optical elements in the form of aspherical lenses, the optical centers of which are in the same horizontal plane and have a geometric center with zero refraction, oriented in the device in such a way that on one and on the other side, at different distances from the geometric, it monotonically increases to +2, 50 diopters, and in the vertical plane one at a time and on the other side of the geometric center, the refraction monotonously decreased by 0.25 diopters. The device provided a change in hyperopic defocus to myopic on the horizontal periphery of the retina, creating a condition for changing eye refraction. The course of treatment was 5 days.

Ophthalmic status after treatment.

Refraction: OD sph + 0.50 diopters., Sul +0.25 diopters., Ah 80, OS sph +0.75 diopters., Sul + 0.50 diop., Ah 76. Visual acuity without correction: OD 1, 0; OS 1.0 ,.

Peripheral refraction 30 degrees from fovea:

OD horizontally from the bow sph + 0.75 dptr., Sul + 0.50 diop., Ah 26, from the temporal side sph + 0.75 dptr., Sul + 0.50 diop., Ah 16,

OD vertically on top sph +2.25 diopters., Sul + 0.70 diopters., Ah 90, from below sph +1.25 diopters., Sul -1.00 diopters., Ah 80,

OS horizontally from the nose side sph +0.50 diopters., Sul +0.75 diopters., Ah 56, from the temporal side sph +0.75 diopters., Sul + 1.00 diopters., Ah 34.

OS vertical top sph +1.00 diopters., Sul +1.25 diopters., Ah 84, bottom sph +0.50 diopters., Sul -0.50 diopters., Ah 149,

As a result of treatment with the proposed method, a restoration of visual acuity was noted, mixed astigmatism passed into emmetropic refraction with a physiological hyperopic astigmatic component. A marked increase in peripheral refraction measured at 30 degrees from the nasal and temporal sides of the fovea and vertical attenuation from above and below.

Example 4. Patient A., 14 years old, diagnosis: moderate hyperopia of both eyes. The child did not complain, he constantly used glasses with eyeglass lenses of 1.50 diopters in front of each eye.

Ophthalmic status before the application of the treatment method.

Axial refraction: OD sph +3.75 diopters, sul 0.00, OS sph +3.25 diopters, cyl +0.50 diopters, ax 160. Visual acuity without correction and subjective correction: OD 0.4 with sph + 2.00 diopters = 1.0, OS 0.5 sph +1.75 diopters = 1.0 /. Peripheral refraction 30 degrees from fovea:

OD horizontally from the bow sph + 1.50 dptr., Sul + 1.00 dptr, ax 53, from the temporal side sph + 2.00 dptr., Sul + 0.75 dptr., Ax 68, OD vertically from above sph +1, 75 dptr., Sul +1.25 dptr., Ah 138 gr., Bottom sph +2.75 dptr., Sul +1.25 dptr., Ah 84 gr.,

OS horizontally from the bow sph +1.75 diopters., Sul + 0.50 diopters., Ax 141 gr., From the temporal side sph + 2.25 diopters., Sul +1.00 diopters., Ah 69 gr.

OS vertically on top sph + 2.00 diopters., Sul +0.75 diopters., Ah 66 gr., Bottom sph + 2.75 diopters., Sul +0.75 diopters., Ah 109 gr.

The treatment was carried out in which the patient for 4 weeks at least 6 hours a day used the device in the form of glasses, presented in figure 1, figure 4, figure 5, figure 18, figure 19, figure 20, Fig.21, and when viewing objects through optical elements in the form of aspherical lenses, the optical centers of which are in the same vertical plane and have a geometric center with refraction of 1.50 diopters., oriented in the device in such a way that one and the other side in the horizontal plane, at different distances from the geometric monotonously reduces This is 3.00 diopters, and throughout the entire vertical meridian, the refraction coincided with the refraction in the geometric center. Thus, the device ensured a decrease in the magnitude of the hyperopic defocus on the retina in the fovea and an increase in the magnitude of the hyperopic defocus on the periphery of the retina horizontally without changing the vertical defocus, creating a condition for changing the refraction of the eye. Ophthalmic status after application of the method. Axial refraction: OD sph + 2.75 diopters, sul +0.75 diopters, ax 67 gr., OS sph + 2.50 diopters, cyl +1.00 diopters, ax 165 gr.

Visual acuity without correction and subjective correction: OD 0.6 sph +1.25 diopters. = 1.0, OS 0.8 with sph +1.00 diopters. = 1.0.

Peripheral refraction 30 degrees from fovea:

OD horizontally from the bow sph +1.75 diopters, sul +1.25 diopters, ax 61 gr., From the temporal side sph + 2.50 diopters, sul +1.25 diopters, ax 70 gr. ,

OD vertically on top sph +1.25 diopters., Sul +1.12 diopters., Ah 143 gr., Bottom sph +1.75 diopters., Sul +1.50 diopters., Ah 77 gr.

OS horizontally from the nose side sph + 2.50 diopters., Cal +1.00 diopters, ax 132 gr., From the temporal side sph + 2.50 diopters, cal +1.00 diopters, ax 69 gr.

OS vertical top sph +1.75 diopters, sul +0.50 diopters, ax 64 g., Bottom sph +2.12 diopters, sul + 0.05 diopters, ax 118 g.

Claims (6)

1. A method for the prevention and / or treatment of refractive disorders of vision, including creating an optical focus through optical elements on the foveal region of the retina, characterized in that they create an optical focus on the periphery of the fundus in front of the retina in one meridian and behind the retina in another meridian perpendicular to the first. 2. The method according to claim 1, characterized in that they create an optical focus on the periphery of the fundus in front of the retina in the horizontal plane and behind the retina in the vertical plane. 3. A method for the prevention and / or treatment of refractive disorders of vision, including creating an optical focus through optical elements on the foveal region of the retina, characterized in that they create an optical focus on the periphery of the fundus in front of the retina in the horizontal plane and on the retina in the vertical plane. 4. A device for the prevention and treatment of refractive errors of vision, including optical elements with a front surface and an optical center, characterized in that the optical elements are selected lenses with an asymmetric distribution of refraction relative to the vertical passing through the geometric center of the lens, oriented in such a way, that on one and on the other side relative to the vertical passing through the geometric center of the lens, with asymmetric distance from the geometric center, refraction monotonically amplifies, and relative to the horizontal, passing perpendicularly to the vertical through the geometric center, the refraction does not change or monotonously weakens with respect to refraction in the geometric center. 5. A device for the prevention and treatment of refractive errors of vision, including optical elements with a front surface and an optical center, characterized in that the optical elements are selected lenses with an asymmetric distribution of refraction relative to the vertical passing through the geometric center of the lens, oriented in such a way, that on one and on the other side relative to the vertical passing through the geometric center of the lens, with asymmetric distance from the geometric center, refraction monotonously weakens, and relative to the horizontal, passing perpendicularly to the vertical through the geometric center, the refraction does not change or monotonously increases with respect to refraction in the geometric center. 6. A device for the prevention and treatment of refractive errors of vision, including optical elements with a front surface and an optical center, characterized in that the optical elements are selected lenses with an asymmetric distribution of refraction relative to one of the meridians passing through the geometric center of the lens, one at a time the other side of the meridian at an asymmetric distance from the geometric center, the refraction is monotonically enhanced, and relatively mutually perpendicular to the meridian passing through geometric center, refraction does not change or monotonously weakens with respect to refraction in the geometric center.

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