RU2572749C2 - Device for studying, establishing, recovery, development of functions of binocular vision and increase of vision acuity - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to the field of experimental physiology, psychophysiology and ophthalmology. A set for studying binocular vision mechanisms contains a chin rest with its height-changing mechanism; a removable headrest; provided with a height-changing construction guide with a scale, on which three detachable carriages, made with a possibility of autonomous travel, are installed, with the first carriage being provided with a mechanism for changing and measuring the distance between the centres of elements of test-images, connected with a mechanism of their vertical displacement; a set of detachable pairs of plates from a transparent material with the test-images, which are made with a possibility of installation in pairs on the mechanism for changing and measuring the distance between the centres of the said test-images, containing the following pairs of plates: with identical paired elements of the test-images, the non-paired elements of the test-images, elements of stereopairs, with one identical hole, on the outer edge of which fixed are identical rings with an internal diameter equal to the hole diameter, with control marks for the right and left eye respectively being fastened on the outer edge of the rings, and the rings and the control marks are made of a semi-transparent coloured material, as well as the pairs of plates with one hole, in which the paired elements are installed for changing the rotation angle, fastened from the frontal side of the paired test-images, with the back side of the paired elements being provided with scratches of the scale of the test-image rotation angle mark; a set of detachable objects of bifixation, made in the form of hollow flat geometrical figures of a different size; a set of detachable vertical flat rods of a different width; with the vertical flat rods being made with a possibility of installation on the first, second and third carriages, the objects of bifixation - with a possibility of installation on the second and third carriages.

EFFECT: application of the claimed invention will make it possible to increase the quality of studying, establishing, recovery, development of functions of binocular vision and increase of vision acuity.

26 dwg, 8 ex

Description

The invention relates to the field of experimental physiology, psychophysiology, ophthalmology and can be used to study the physiological mechanism of normal binocular vision, to diagnose binocular functions - a qualitative and quantitative assessment of the state of normal or impaired binocular vision, to establish, restore and develop binocular vision functions, to eliminate various forms of convergent, divergent and vertical strabismus, functional cyclophoria and cyclotropy, as well as to increase visual acuity in cases of accommodation spasm, myopia, hyperopia and various forms of amblyopia.

The closest analogue of the claimed device is a binarimeter (Binarimeter: Aut. St. USSR No. 596220 // Discoveries, inventions, industrial, samples and trademarks, 1978, No. 9. - P. 14), containing a test object, chin, diaphragm, guiding with a scale and two carriages with the possibility of autonomous movement, on one of which is a test object, on the other - a screen with a large-scale grid.

The disadvantage of the analogue is the low accuracy of measuring the distance of a virtual (imaginary) binocular visual image, the lack of the possibility of accurate physiological studies of the mechanisms of binocular vision and advanced diagnostics of the state of binocular vision functions and its disorders, the establishment, restoration of binocular vision and the elimination of various forms of strabismus in various combinations of convergent, divergent and vertical, cyclotropy diagnostics, diagnostics and elimination of functional cyclophoria, about lack of ability to increase visual acuity in cases of amblyopia, hyperopia, with spasm of accommodation and myopia.

Known invention, which is close in technical essence (Russian Patent No. 1792319, October 1, 1992), a device for research and restoration of binocular vision, containing a chin, a forehead, a guide with a scale, three removable carriages mounted on it with the ability to move them , two transparent plates for arranging test image elements on them, a mechanism for changing and measuring the distance between the centers of test image elements and a mechanism for their vertical displacement, and a mechanism for changing and measuring the distance between the centers of the elements of the test images and the mechanism of their vertical displacement are interconnected and mounted on one carriage, a bifix object made in the form of a hollow geometric figure, mounted on another - the second carriage, and a vertical rod mounted on an additional third carriage.

The disadvantages of the prototype are the lack of special designs of test images for accurate physiological studies of the mechanisms of binocular vision, for an extended diagnosis of the functional state of binocular vision and its disorders, the absence of a set of test images for the technical feasibility of establishing binocular vision and the development of stereo vision, eliminating complex forms of converging, diverging , vertical strabismus (in various combinations), cyclotropy diagnostics, diagnostics and elimination of functional cyclophoria, as well as elimination of functional strabismus in various combinations of forms with functional scotoma, decreased visual acuity and amblyopia, lack of test images to increase visual acuity in cases of various forms of amblyopia, hypmetropia, myopia and accommodation spasm, lack of a set of bifixation objects and a set of rods that are necessary to control the establishment, recovery and development of binocular vision, for the diagnosis of binocular functions - qualitative and quantitative Second assessment of the state of the normal or impaired binocular vision, advanced control of the process of correction measures, the lack of height adjustment device designs Chin and the height of the guide to the scale, which are designed for a different age and height subjects and patients.

The aim of the invention is to expand the technical and functional capabilities of the device. As a result of technical solutions, the claimed device allows you to expand and improve the quality of physiological studies and psychophysiological experiments, expand the diagnosis of the functional state of binocular vision, improve the quality of use of the device to establish, restore and develop binocular vision, develop high-quality stereo vision and eliminate simple and complex forms of convergent and divergent strabismus , combined with vertical strabismus, combined with functional scotoma and amblyopia of varying degrees, determine the angle with cyclotropia and cyclophoria, eliminate cyclophoria and some forms of functional cyclotropy, and also increase visual acuity with a spasm of accommodation, myopia, hyperopia and in various cases of amblyopia.

This goal is achieved due to the fact that the prototype device containing a guide with a scale, three removable carriages mounted on it with the possibility of their independent movement, two transparent plates on which test image elements are fixed, a mechanism for changing and measuring the distance between the centers of the test elements -images and the mechanism of their vertical displacement, the mechanism for changing and measuring the distance between the centers of the test elements and the vertical displacement mechanism of the elements of test images inens between themselves and are mounted on one carriage, a bifixation object made in the form of a hollow geometric figure mounted on another second carriage, and a vertical rod mounted on the third carriage, a chin and a forehead, is equipped with a guide structure with a scale connected to the structure for changing its height that keeps the rail in horizontal position when its height changes, and also the chin is connected to the rail with a mechanism for changing its height and a removable forehead, three removable carriages, data on it with the possibility of their autonomous movement and made with the possibility of reinstalling them in any combination, the device is equipped with a set of removable pairs of plates made of transparent material, for placing on them only identical pairs of test image elements, identical and unpaired test image elements, and elements stereopairs, as well as in the kit, there are pairs of plates having, respectively, one identical hole, on the outer edge of which identical rings with an inner diameter equal to about a verst, control marks for the right eye are attached to the outer edge of the rings for the right eye, control marks for the left eye are attached to the outer edge of the rings for the left eye, pairs of rings and control marks are made of translucent colored material, other pairs of plates are included respectively, along one hole and contain paired structures of solid material, on the front side of which paired images are strengthened, and on the other side of the reverse side of the structure, there are risks of marking the angle n the gate of the test image, each design of the test object with the image is installed in the hole with the possibility of dosed rotation of the images in the frontal plane relative to the plane of the plate, on each plate on the front side there is a scale for marking the angle of rotation of the image so that the numbers are visible from the back of the plate in angular degrees and the risk of marking the angle of rotation of the images located on the back of the structure, and to pairs of plates there is a replaceable set of paired structures with different test images, in addition, the device is equipped with a set of removable bifix objects made in the form of hollow flat geometric shapes of different sizes, a set of removable vertical flat rods of different widths, bifix objects in the form of hollow flat geometric shapes and vertical flat rods can be installed simultaneously in any combinations on the second and third carriages, and you can install one of the vertical rods on the first carriage with a mechanism for changing and measuring the distance between the centers lementov test images and a mechanism for dispensing their vertical displacement.

The proposed device is illustrated by drawings:

In FIG. 1 (side view), FIG. 2 (top view), FIG. 3 (frontal view) schematically shows a device for researching, diagnosing, establishing, restoring and developing binocular vision functions and increasing visual acuity. The device comprises: a guide with a scale (1), a structure (2) for changing the height of this guide, a carriage (3) with a mechanism (4) for changing and measuring the distance between the centers of the test image elements connected to the test dosed vertical displacement mechanism (5) -images, pairs of plates (6) made of a transparent material with elements of test images (7), a second carriage (8), and a third carriage (9), on which a vertical rod (10) and a bifixation object (11), a chin with design changes in height (12), removable forehead (13). In FIG. 4, FIG. 6, FIG. 8 illustrates examples of a set of pairs of plates (6) (see FIG. 3) made of a transparent material with test images (7) (see FIG. 3) containing only identical pairs of test image elements; FIG. 5, FIG. 7, FIG. Fig. 9 shows examples of a set of pairs of plates (6) (see Fig. 3) made of a transparent material with test images (7) (see Fig. 3), with identical and unpaired elements of test images, in Fig. 10, Fig. 11, FIG. 12, FIG. 13 shows examples of a set of pairs of plates (6) (see FIG. 3) made of a transparent material with test images (7) (see FIG. 3), with stereo pair elements, in FIG. 14, FIG. Figure 15 shows examples of a set of pairs of plates (6) (see Fig. 3) made of a transparent material with test images (7) (see Fig. 3), with stereo pair elements and with unpaired image elements.

In FIG. 16, FIG. 17, FIG. 18 schematically shows examples of a set of pairs of plates (6) (see Fig. 3) made of a transparent material with test images that are used to establish binocular vision and control its development. The arrangement of pairs of plates of transparent material shown in FIG. 16, FIG. 17 and FIG. 18 contain holes (13) in transparent plates, rings of a translucent color film (14), labels of a translucent color film (15) for the right and left eye. In some cases of monitoring the correction of binocular vision functions, it is possible to replace a translucent film with an opaque film.

In FIG. 19 (test object profile), FIG. 20 (a pair of plates of the test object frontally from the back) schematically shows transparent plates with the design of test objects used to diagnose cyclotropia and cyclophoria, correct cyclophoria and some forms of cyclotropy, as well as for training, development and advanced control of stereo vision. The device of plates of transparent material (16) contains holes in the plates (17), paired structures made of solid material (18) for changing the angle of rotation of test objects, to which paired images are attached (19), and on the other side, the risks are attached to the back of the structure (20) (see Fig. 19 and Fig. 21) - to mark the angle of rotation of the test image, each design with the test image is installed in the hole (17) with a handle (21) for dosed rotation in the frontal plane relative to the plane of the plate, on each plate from the front sides a scale (22) is attached (see Fig. 19, Fig. 20), which is graded in angular degrees, so that figures in angular degrees and risks (20) (Fig. 21) of the angle of rotation of the test are visible on the back of the plate -images located on the front side of the structures, and to the plates there is a removable set of pairs of structures with various test images (examples: Fig. 22, Fig. 23, Fig. 24, Fig. 25) for diagnosis and control, as well as to eliminate various forms of strabismus with cyclophoria and cyclotropy, the test images in FIG. 23 and FIG. 25 are additionally used for teaching and developing stereo vision and advanced stereo vision control.

In FIG. 26 shows a diagram of the principle of operation of the inventive device - a scheme for merging pairs of images in cross diplopia: (C) - corresponding receptive fields OD - the right eye and OS - the left eye. (Letter designations were introduced by L.N. Mogilev (1982). As a result of the merging of pairs of images A and B, a virtual visual image appears. This visual image consists of three images: in the center, ab is a virtual binocular image, a is a virtual monocular image of the right eye ( OD), b - virtual monocular image of the left eye (OS). Moreover, the binocular image - ab is perceived far from the subject at a distance L behind the plane of the real double image. This is a depth effect. All elements of the virtual visual image in this case tea is perceived as enlarged. If you change the distance P - between the centers of images of test A and B or change the distance N - from the eyes to the elements of double images, then the distance - L changes to the virtual binocular image ab. With increasing distances P the distance - L increases, this effect changes in depth, in addition, the size of the entire virtual visual image increases, this is the effect of changing the value.With increasing distance N, the distance - L increases, and the size of the elements of the virtual visual image decreases It is because the value of the real projection on the receptive fields of the retina decreases.

The inventive device operates as follows.

For physiological studies, the subject fixes the position of the head using the chin (12) and forehead (13) of FIG. 1. To measure the distance in the space of the virtual binocular visual image, a carriage (3) with two plates (6) and a pair of identical test image elements (7) in the form of two circles with a diameter of 6 or 10 mm is installed at a predetermined distance along the guide (1) and the carriage (9) with the bifixation object (11). When looking into the distance through transparent plates with test image elements, physiological doubling and the merging of adjacent bifurcated elements occur (see the merging scheme of double images in Fig. 26), as a result, the subject sees a virtual image consisting of three images (L.N. Mogilev, 1982). In this case, the middle one is a virtual binocular visual image that is perceived to be remote in space at a certain distance, and monocular visual images located to the right and left of it do not have a certain distance in space. However, the perceived size of all three virtual images is equally increased if the visual acuity and optical properties of the right and left eyes are equal or differ slightly.

The subject is given the task by changing the distance between the plates of the test images, using the mechanism (4) to combine the virtual binocular visual image with the plane of the bifixation object in the form of a hollow geometric figure. On the scale of the mechanism (4), readings are taken about the distance between the test elements corresponding to a certain distance in the space of the virtual binocular visual image. The accuracy of the readings during repeated measurements indicate the normal functional state of binocular vision. With normal binocular vision, the accuracy of combining the virtual binocular visual image with the object of bifixation should not exceed 0.3-0.4 mm.

For psychophysiological experiments and scientific research, in addition to the claimed device, a measuring frame device mounted on a second carriage 8 (Fig. 1) from the Binarimer invention (USSR Author's Certificate No. 1630786. Bull. No. 8, 1991) is used.

The study is carried out as follows: the subject fixes the position of the head with the help of the chin (12) and the forehead (13) of FIG. 1. To measure the distance in the space of the virtual binocular visual image, a carriage (3) with two plates (6) and a pair of stereo images in the form of two ellipses with a diameter of 10 and a height of 20 mm are installed at a predetermined distance along the guide (1) angle (one ellipse is 3 angular degrees, and the second ellipse is 357 angular degrees from the vertical, set the measuring frame (author certificate No. N1630786) on the carriage (9). When looking into the distance through physiological plates with test image elements, physiological doubling and fusion of neighboring bisected elements (see the scheme of merging double images in Fig. 26), as a result, the subject sees a virtual (imaginary) image (LN Mogilev, 1982) .In this case, the average one is a virtual binocular visual image that is perceived to be distant in space at a certain distance with a certain angle of inclination of the ellipse in space, and monocular visual images located to the right and left of it do not have a certain distance in space. Depending on the distance between the centers of the pairs of test images, which determines the angle of convergence or divergence, the virtual binocular image has a different angle of inclination in space. For each given characteristic of the distances from the observer’s eyes to the pairs of test images and the distance between their centers, the experimenter establishes and combines the measuring frame with the plane oriented in the space of the perceived virtual binocular image (stereo image), and measures its distance, angle tilt and its dimensions. (Methodologically, this is a close task performed by stereophotogrammetrists on a stereo comparator when compiling topographic maps from stereo photographs of the area). It is proved that the angle of inclination, the size of the ellipse and its remoteness in space will significantly change with convergence or divergence.

Depending on the use of pairs of stereo images of such measurements and studies, many can be done, and not all psychophysiological phenomena have been studied. Experiments with virtual images can be demonstration material at a workshop in studying the physiology of the visual system.

To diagnose binocular visual impairment, the subject fixes the position of the head with the chin (12), the forehead (13) is removed, put (Fig. 2) on the guide (1) carriage (8) with a vertical shaft (10) and find the distance from the eyes to the shaft at which his doubling occurs. Then, at the same distance, instead of a carriage (8) with a vertical rod, a carriage (3) is installed with a distance changing mechanism (4) and a vertical displacement mechanism (5) and a plate (6) with test images (7) in the form of two circles with a diameter of 16 or 24 mm or with a different diameter (the choice of the diameter of the circles depends on the diagnosis and the task of the examination). By changing the distance between the plates using the moving mechanism of the test images, find the distance between the centers of the pairs of test images at which there is a virtual binocular visual image (Fig. 26). For in-depth diagnostics, a vertical rod (10) is mounted on the first carriage. In this case, a feeling of a three-element virtual image should arise, where between the first and second, second and third images the visual images of the double rod are symmetrically felt. If the visual images are displaced vertically, then use the mechanism (5) of the vertical displacement of the test elements, controlling it until the fusion appears. Then the elements of the test are displaced until the correct perception of the virtual visual image appears. The angle of vertical displacement reflects the degree of vertical deviation. And the values of the distance between the centers of the test elements and the distance from the eyes to the test image characterize the fusion ability and the possibility of changing the amplitude of the fusion.

If there is no double feeling (for example: with divergent strabismus or with a functional scotoma), then a pair of plates with a test object (Fig. 16, or Fig. 17, or Fig. 1) are mounted on the mechanism for changing and measuring distance 4 (see Fig. 1). .18) with rings and marks for the right and left eyes. In this case, with the correct position of the eyes, the subject feels one whole ring with two marks (for the right and left eyes) or with four marks (for the right and left eyes). The choice of test object depends on the diagnosis and the task of the examination. If the subject does not see the virtual image with monocular marks, it is necessary to feel the whole ring with two marks due to changes in the distances between the centers of the pairs of test objects using the mechanism of moving pairs of test images and moving the carriage on which they are located and due to additional optical lenses identified during the fusion search. When the fusion is reached, the corresponding distance readings are taken from the device’s scales.

To diagnose cyclotropy and cyclophoria, plates with a test object (Fig. 19, Fig. 20) are mounted on the mechanism (4) (see Fig. 1) for changing and measuring the distance. For example, test images of the grid of FIG. 22 or the lines of FIG. 23. During cyclodeviation, there is cyclic diplopia, by rotating the test images (19) with the handle (21), the image presented in front of the eye with a cyclic angle is displaced, and the cyclo-angle of each test image at which fusion occurs is determined and determined the risk marker (20) shows on a scale (22) the angle of cyclic deviation, that is, cyclic strabismus (cyclophoria - if the angle is not constant, or cyclotropy - a constant angle of cyclodeviation).

To establish, restore the fusion and develop the fusion amplitude, install (see Fig. 1) a vertical rod on the carriage (3) with a vertical displacement mechanism (5) and a mechanism (4) for changing and measuring the distance between the centers of the pairs and install a pair of plates (test object - two circles with a diameter of 16 or 24 mm). For example: the carriage (3) is set at a distance of 10 cm from the eyes, while the distance between the plates is set so that pairs of double projection of the test object merge. Then, rotating the flywheel of the mechanism for changing the distance between pairs of circles smoothly, gradually increase the distance between pairs of circles, developing the amplitude of the fusion. Step by step, bringing this distance to the interpupillary distance and 1.0 mm more than the interpupillary distance, which corresponds to the direction of the visual axes when looking at a distance to the object over 100 meters. If the patient does not have doubling, then the ring test with marks (Fig. 16 or Fig. 17) is installed as a test, and the position of the rings is found when the image of the whole ring with colored marks appears. In this case, the fusion is developed from the fusion position found at an angle of symmetrical exodivergence to a minimum of 20 mm between the centers of the test elements, and to a maximum of the interpupillary distance and 1.0 mm more than the distance between the centers of the pupils, which corresponds to the normal perception of objects at distances over 100 m.

To go from haploscopic vision to visual bifixation in vivo, a carriage (3) is installed (see Fig. 1) with a mechanism (4) for changing and measuring the distance between the centers of the test elements, plates (6) with a test image (7) - a pair of identical circles. Then, at a predetermined distance, a carriage (8) is installed with the bifixation object (11) in the form of a hollow flat geometric figure. For example: the carriage (2) is installed at a distance of 25 cm from the eyes, and the carriage (8) with the bifix object (11) is at a distance of 40 cm. The distance between the plates is set so that the bifix object does not double. Observation of the virtual visual image and the real image of the bifixation object allows you to begin the transition from haploscopic vision to natural bifixation by moving the carriage (8) along the guide in the range of 5 cm or by moving the test moving mechanism in the range of 2-3 mm, in the patient during tracking and switching attention from the virtual binocular visual image to the object of bifixation, they begin to develop a sense of localization of the virtual binocular visual image in the “depth effect” space. Then, the “depth effect” is developed from minimum to maximum distances into the distance (more than 100 meters) according to normal binocular vision.

To develop the accuracy of sensing the relative remoteness of objects in space (see Fig. 1), a carriage (3) with a mechanism (4 and 5) is installed, plates (6) with a test image (7) - a pair of identical circles, then a carriage (8 ) with the bifix object (11) and the carriage (9), set the second bifix object (11). For example: the carriage (3) is installed at a distance of 30 cm, the carriage (8) with the first object of bifixation at a distance of 50 cm and the carriage (9) with the second object of bifixation at a distance of 55 cm.The task of the subject is to find two distances (between the centers of the test objects ), in which the virtual binocular visual image will be combined first with the first object of bifixation, and then with the second object of bifixation. Performing this task allows you to fix the established or restored binocular vision and develop a feeling of relative remoteness, which is necessary for the development of stereo vision. The accuracy of multiple spatial alignment of the binocular visual image with the first object of bifixation, then with the second indicates the normal development of the binocular system.

Depending on the task of establishing, restoring, developing binocular vision or stereo vision, one, two or all three carriages can be used.

For the development of stereo vision, a carriage (3) is installed with a mechanism (4 and 5), plates of test images with a stereo pair are installed on the mechanism (4) for changing and measuring the distance (Fig. 10, or Fig. 11, or Fig. 12, or Fig. 13), or a pair of plates with a structure (Fig. 19, Fig. 20) with a test object (Fig. 23 or Fig. 25) with a stereo image on which the rotation angle is set so that the horizontal parallax does not exceed 0.2 angles. hail. If doubling of the image elements occurs, then the images are set so that the horizontal parallax is less than 0.1 angles. hail. The subject, switching attention from one part of the image to another having the specified horizontal parallax, gradually develops stereo vision during such a training. Then the horizontal parallax is gradually increased due to the rotation of the pairs of images (Fig. 25, design of Fig. 19) and in subsequent training is adjusted to 1.5 degrees. Thus, a range of stereo vision is developed. Then increase the severity of stereo vision due to the complexity of the structure of stereo images and changes in stereoscopic parallax.

To increase visual acuity with amblyopia, hyperopia and myopia (see Fig. 1), plates with test images (paired text, or stereo text, or paired with stereo elements and with not identically arranged circles) are installed on the mechanism for changing and measuring distance (4) , drawing or text of Fig. 14, Fig. 15, Fig 12, Fig. 13). For each case of visual acuity disorders, test images and test image shifts are individual; the technique for increasing visual acuity contains Know-How.

Example 1. Patient A.D. (age 7 years). Diagnosis: Converging strabismus, operated on. The strabismus angle after surgery is 15 °, the nature of vision is monocular, the refraction of the right eye is +1.5 D, the left eye is +1.5 D, the visual acuity of the right eye is 0.7, and the left eye is 0.9.

The establishment of binocular vision by the claimed device. The patient fixed the position of the head using the chin (12), (Fig. 1). On the mechanism (4), (Fig. 1), changes and measurements of the distance between the centers of the pairs of test images installed a pair of plates with a test image - circles with a diameter of 16 mm and set the rod 4 mm wide in order to control the correct perception of the virtual image. For 8 sessions, the patient was trained to see the virtual image correctly, while achieving the ability to fusion with a symmetrical position of the eyes. Then, during 14 sessions, the fusion amplitude was developed in full, manipulating the test moving mechanism and moving its carriage along the entire length of the carriage guides, as well as developing the fusion when turning the head to the right, left, up, down, holding a virtual visual image at different distances from eye to test images. Then, for 5 sessions, using the object of bifixation - a hollow ring, deep vision was developed. And the next 4 sessions using two bifixation objects (hollow rings of different diameters) developed the ability to perceive the relative distance of objects. Then during 71 sessions, stereo vision, visual acuity and binocular visual acuity were developed. The exercises were carried out with a phased complication of stereo pictures, from simple test objects with two parts with a gradual change in disparity from 25 angles. min to 1.5 degrees, and then with a phased complication of stereo pictures and with a change in disparity from 25 angles. min to 0.75 ang. min

As a result of treatment: the nature of vision is binocular, without spectacle correction, visual acuity of the right eye is 1.0, the left eye is 1.0, and binocularly 1.0. Lang stereotests - all answers are positive. Strabismus angle 0. Binocular vision, stereo vision and deep vision are established.

Example 2. Patient R.E. (age 19 years). Diagnosis: Divergent strabismus post-traumatic. Diverting strabismus occurred after a traumatic brain injury. Disrupted convergence, constant diplopia, decreased visual acuity of the left eye. Visual acuity of the right eye of 1.0, the left eye of 0.7. Strabismus angle 15 degrees. The nature of vision is simultaneous.

The restoration of binocular vision is performed by the claimed device. The patient fixed the position of the head using the chin (12), (Fig. 1). On the mechanism (4) (Fig. 1), changes and measurements of the distance between the centers of the pairs of test images installed test image - rings with labels (Fig. 4). The position of the test image was found at which the correct sensation of the virtual image arose. Then they began to perform exercises to restore the amplitude of fusion and convergence. Over 7 sessions, convergence was restored, constant diplopia stopped, deep vision was restored without special exercises, visual acuity of the left eye was restored to 1.0, however, stereo vision has not yet recovered and the direct position of the eyes is unstable. With the help of a set of stereo tests with phased complication, the restoration of stereo vision began. In 10 training sessions, stereo vision was fully restored. As a result: the nature of vision is binocular, strabismus is completely eliminated, stereo vision and visual acuity are restored.

Example 3. Patient A.I. (age 17 years). Diagnosis: Friendly divergent strabismus, which occurred 5 years after the operation of convergent strabismus. Refraction of the right eye - myopia - 2.5 D, and left eye emetropia. Visual acuity of the right eye of 0.1, the left eye of 0.9. The angle of squint 15-20 degrees. The nature of vision is monocular.

The establishment of binocular vision by the claimed device. The patient fixed the position of the head using the chin (12), (Fig. 1). On the mechanism (4), (Fig. 1), changes and measurements of the distance between the centers of the pairs of test images installed a test image - a ring with two labels (Fig. 4). During 4 sessions, they trained to correctly see the virtual visual image. The fusion reflex is normal. Then, during 14 sessions, the fusion amplitude was developed in full, manipulating the test moving mechanism and moving its special carriage along the entire length of the carriage guides, as well as developing head turns to the right, left, up, down, holding a virtual image at different distances from the eyes to test images. A sense of depth and a feeling of relative remoteness developed in 1 session. Then they began to develop stereo vision and visual acuity of binocular vision, and for 37 sessions they got the result. With correction of the right eye - 2.5, visual acuity of 0.7, the left eye without correction of 0.9. The nature of vision is binocular, the squint angle is 0 degrees.

Example 4. Patient K.I. (age 12 years). Diagnosis: Convergent strabismus with a vertical component, operated on. The strabismus angle after surgery is 10 °, the vertical deviation of the left eye is 5-10 °, the nature of vision is simultaneous, the visual acuity of the right eye is 0.7, and the left eye is 0.4. In glasses, the right eye is +1.25 D, the visual acuity of the right eye is 1.0, the left eye is +1.75 D, the visual acuity of the left eye is 0.8.

Diagnostics and the establishment of binocular vision by the claimed device. The patient fixed the position of the head using the chin (12) (Fig. 1). On the mechanism (4) (Fig. 1), changes and measurements of the distance between the centers of the pairs of test images connected to the mechanism (5) of their vertical displacement, set a pair of plates with the test image - circles with a diameter of 16 mm. Using the inventive device, at a distance from the eyes to the test of 10 cm, between the centers of the pairs of circles 3.0 cm and with a vertical offset of 5 degrees, the position of the test images was found at which the correct perception of the virtual visual image arose. Then, exercises were carried out to develop the amplitude of the fusion and eliminate the vertical component of the squint. For 3 sessions, the result of the development of fusion was achieved and the vertical angle was eliminated with a straight look. But when looking up, the vertical angle was still manifest. However, they decided to develop deep vision. For 1 session, the result was achieved. Then they began to carry out exercises to develop stereo vision and eliminate the vertical component of strabismus when looking up. Gradually complicating stereo images and performing head movements up and down, left and right, while maintaining a sense of stereo perception, the vertical component was completely eliminated and stereo vision was developed to a normal state. The result was achieved in 42 sessions. The nature of vision is binocular, the angle of squint is 0, the control of stereo vision according to the Lang test 1 and 2 is the norm, without glasses the visual acuity of the right eye is 1.0, the left eye is 1.0. However, it is recommended to use +1.0 D glasses for both eyes for reading. Control during the year showed persistence of the achieved result.

Example 5. Patient R.M. (age 9 years). Diagnosis: convergent strabismus with a vertical component, constant cyclo-vertical-horizontal diplopia, hyperopia +4.5 in both eyes.

A pair of plates with a rotation mechanism of the test object (Fig. 19) was installed on the mechanism (4) (Fig. 1) for changing and measuring the distance between the centers of the pairs of the test image (Fig. 19); a grid image was used as a test image for measuring the deviation angle (Fig. 1). 22). Diagnostics of the inventive device were carried out, and it was found that the patient has 8 angles of cyclotropy. hail. First, they achieved the development of a fusional reflex at an angle of cyclodeviation and began to eliminate cyclotropy. The patient fixed the position of the head using the chin (12) (Fig. 1). To eliminate cyclotropy at the first stage, we used a test image (an ellipsoid image with a thickness of 6 mm in the center). By angular displacement of the test image in front of the right eye, we found the angle of rotation of the image at which the two images merged. These actions are carried out thanks to the fusion reflex at an angle of cyclodeviation. This is an indicator that with a gradual smooth angular mixing of the image of the eye should also unfold. Over 27 treatment sessions, gradually and smoothly reducing the image rotation angle, the deviation angle was reduced to 2 angles. hail. Then, using test images with a given lattice spread from 2 to 0 angles. hail, reached a normal merger. Then they started to eliminate the converging and vertical deviation angles by developing the fusion amplitude. And then they completed a series of exercises to develop stereo and deep vision. For 58 sessions, the result was achieved to eliminate all forms of strabismus and cyclo-vertical-horizontal diplopia, normal binocular, deep and stereo vision was developed, visual acuity in glasses was reached 1.0 in both eyes. Control over 4 years showed the sustainability of the result.

Example 6. Patient C.S. (age 12 years). Diagnosis: Mild myopia. Refraction of the right and left eye - 1.5 D. Visual acuity of the right eye of 0.4, the left eye of 0.45, two eyes of 0.6.

A functional correction of visual acuity by the claimed device. The patient fixed the position of the head with the chin (12) of FIG. one.

On the mechanism (4) (Fig. 1), changes and measurements of the distance between the centers of the pairs of test images installed a pair of plates with stereo text. Set the distance at which when merging double images, three virtual images are clearly visible. Then conducted sessions to increase visual acuity. The essence of the training is to gradually increase the distance from the eyes to the test image and adjust the clear perception of the virtual image using the test movement mechanism, which was controlled by the accommodation mechanism through interaction with the vergence mechanism. As a result of these actions, the work of the ciliary muscles was trained, which led to an increase in visual acuity. Sessions were carried out twice a week, the total number - 10 sessions. After the exercises, the visual acuity of the right eye is 0.7, the left eye is 0.8, and two eyes are 0.9.

Example 7. Patient R.L. (age 16 years). Diagnosis: Hypermetropia of the right eye of a high degree, left eye of an average degree, amblyopia of the right eye of an average degree. Refraction of the right eye - +7.0 D, left eye + 4.0 D. Visual acuity of the right eye 0.2, left eye 1.0. In glasses, the right eye is + 6.0 D, the visual acuity of the right eye is 0.4, the left eye is + 4.0 D, the visual acuity of the left eye is 1.5.

A functional correction of visual acuity by the claimed device. The patient fixed the position of the head using the chin (12) (Fig. 1). On the mechanism (4) (Fig. 1), changes and measurements of the distance between the centers of the pairs of test images, set test objects for training fusion. Within 3 sessions, trained to correctly see the virtual image. Then, stereo tests with identical and non-identical elements of test image pairs were mounted on the mechanism (4) (Fig. 1). We performed exercises to develop visual acuity of the right eye and visual acuity for 48 sessions. As a result of corrective actions, visual acuity (without glasses) of the right eye was 1.0, the left eye was 1.5, and the magnitude of hyperopia was reduced. To work near the points were written: the right eye +2.25 D, the left eye +2.0 D, in order to prevent the development of amblyopia again. As a result of training, the visual acuity of the right eye increased significantly.

Example 8. Patient T.A. (age 11 years). Diagnosis: Hypermetopic astigmatism, amblyopia of the right and left eye. Refraction of the right eye - Em \ + 5.0 D, left eye +2.0 \ + 4.0 D. Visual acuity of the right eye 0.1, left eye 0.3. In glasses, the right eye is Cyl + 3.5 ax 90 °; the left eye is Cyl + 2.5 ax 90 ° - visual acuity of the right eye is 0.4, and the left eye is 0.6.

A functional correction of visual acuity by the claimed device. The patient fixed the position of the head using the chin (12) (Fig. 1). A pair of plates were installed on the mechanism (4) (Fig. 1) for changing and measuring the distance between the centers of the pairs of the test image (Fig. 16). During 8 sessions, they trained to see the virtual image correctly. Then, stereo tests were installed with identical and non-identical elements of the pairs of test images. We performed exercises for the development of stereo vision and visual acuity of each eye for 23 sessions. As a result of the exercises, visual acuity was established (without glasses) of the right eye of 0.7, the left eye of 1.0.

Thus, the proposed device can be used for physiological and psychophysiological studies of the mechanisms and functions of binocular vision, for diagnosis - a qualitative and quantitative assessment of the state of normal or impaired binocular vision, and also allows you to set and restore binocular vision, develop fusion, deep vision and stereo vision, while eliminating the complex and simple forms of convergent and divergent strabismus, combined with a vertical component, combined with fun scotoma and amblyopia, as well as diagnose cyclophoria and cyclotropy, eliminate cyclophoria and some forms of cyclotropy, as well as increase visual acuity with amblyopia, hyperopia and hyperopic astigmatism, spasm of accommodation and myopia. In addition, the device is applicable for a wide range of age groups (children from 5 years old, adolescents and adults).

Bibliography

Mogilev L.N. Binarimeter: Aut. St. USSR N 596220. // Discoveries, inventions, industry. Samples and trademarks, 1978, No. 9. - S. 14. Mogilev L.N. The mechanisms of spatial vision. - L .: Nauka, 1982. - 111 p.

Rabichev I.E. A device for studying binocular vision disorders. RF patent No. 1792319, bull. No. 4, 1993. - P.199.

Rabichev I.E., Salyaeva A.R. Binarimeter Auth. St. USSR No. 1630786. Bull. No. 8, 1991. - S. 167.

Claims (1)

A kit for studying the mechanisms of binocular vision, containing a chin with a mechanism for changing its height; removable forehead; equipped with a structure for changing the height of the guide with a scale on which three removable carriages are mounted, made with the possibility of autonomous movement, while the first carriage is equipped with a mechanism for changing and measuring the distance between the centers of the elements of the test images connected to the mechanism of their vertical displacement; a set of removable pairs of plates of transparent material with test images that are configured to be installed in pairs on the mechanism for changing and measuring the distance between the centers of these test images, containing the following pairs of plates: with identical paired elements of test images, unpaired elements of test images, elements of stereo pairs, with one identical hole, on the outer edge of which identical rings are fixed with an inner diameter equal to the diameter of the hole, while on the outer edge of the rings are attached to ontrol marks for the right and left eyes, respectively, and the rings and control marks are made of translucent colored material, as well as a pair of plates with one hole, in which are paired elements for changing the angle of rotation, mounted on the front side of the paired test images, and from the back sides of paired elements there are risks of a scale mark elevation angle of the test image; a set of removable bifixation objects made in the form of hollow flat geometric shapes of different sizes; a set of removable vertical flat rods of different widths; while the vertical flat rods are made with the possibility of installation on the first, second and third carriages, bifixation objects with the possibility of installation on the second and third carriages.

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