RU113655U1 - DEVICE FOR TRAINING BINOCULAR VISION - Google Patents

Abstract

A device for training binocular vision by the method of negative sequential visual images, including two independent light sources with opaque racket-shaped marks glued to them, the "handles" of which are turned in opposite directions, characterized in that it is additionally equipped with a screen, a screen illuminator, and source controls light and a screen illuminator in the form of push-button switches located on the base of the device, while the light sources and the screen illuminator are made on flat LED matrices covered with a matte diffusing mask and are placed in separate rectangular cases fixed in a vertical plane perpendicular to the base and parallel to the screen, with the possibility of angular movement of each of them around the longitudinal axis.

Description

The utility model relates to medical equipment, in particular to devices for ophthalmology, and can be used as a training binocular vision.

A fusion diploscope is known, including a support column and a drive, and equipped with a beam with guides and measuring bars pivotally mounted on a support column, and three light sources with a rheostat, one of which is mounted on an arm in the center of the beam, and the other two are mounted on movable carriages in guide beams. In this case, the drive is located in the central part of the beam, and the rheostat is in the support column, on the external part of which the light source switches and the rheostat regulator are installed. Moreover, an arm for attaching red filters is installed at one end of the beam (patent for utility model of the Russian Federation No. 23760, class A61F 9/00. Publish. July 20, 2002).

A disadvantage of the known device is that it is designed to determine the area of the working volume of binocular vision for near and far, and does not allow the training procedure.

Also known is a fusion simulator, including a pair of stand-alone photo probes and a stand-alone power supply charger. At the same time, each of the photo probes is made in the form of a support stand with a handle-holder at the base, at the top of the support stand there is an aiming device made in the form of a sighting device and a diopter, and a set of point polychromatic photo targets placed in line with the sighting device . Moreover, a battery is installed inside the handle-holder, equipped with a switch and a contact assembly for a power supply charger (patent for utility model of the Russian Federation No. 65757, class A61F 9/00. Published on 08.27.2007).

The disadvantage of this device is the need for the patient to choose an object as a distant target, the orientation of the two photo targets relative to each other. A complex algorithm of sequential actions and aiming at a distant photo target does not allow training in children of preschool and primary school age.

Closest to what is proposed in its technical essence is a device for training binocular vision using the method of negative sequential visual images, including two independent light sources in the form of incandescent lamps with glued light-tight brands in the form of rackets, the “pens” of which are turned in opposite directions (Zhokhov V .P., Kormakova I.A., Plaksina L.I. “Rehabilitation of children suffering from friendly strabismus and amblyopia.” - M.: All-Russian Society of the Blind, 1989, p.25).

The disadvantage of this device is the uneven illumination around lightproof brands, which does not allow to obtain a stable consistent image and prevents the formation of binocular vision. In addition, the device does not have a screen and the ability to highlight it, which leads to the inconvenience of using this device. In addition, the device is bulky, does not take into account the angle of view and causes the risk of burns due to the use of incandescent lamps.

The task to which the claimed utility model is aimed is to improve the quality and comfort of binocular vision training.

The technical result consists in ensuring the formation of a clear sequential image, increasing the usability of the device, developing and consolidating binocular vision.

The problem is solved in that the device for training binocular vision using the method of negative sequential visual images, including two independent light sources glued onto them with opaque marks in the form of rackets, the “pens” of which are turned in opposite directions, is additionally equipped with a screen, a screen illuminator and controls light sources and a screen illuminator in the form of pushbuttons located on the base of the device, while the light sources and the screen illuminator are They are mounted on flat LED matrices covered with a matte scattering mask and placed in separate rectangular cases fixed in a vertical plane perpendicular to the base and parallel to the screen, with the possibility of angular movement of each of them around the longitudinal axis.

The additional inclusion of the screen and its illuminator in the design of the device allows you to minimize and localize the training area, improves the usability of the device and the quality of treatment.

The location of the controls in the form of push-button switches on the base of the device increases the convenience of its use and does not distract the patient when he controls himself.

The use of flat LED matrices as a backlight for brands that form a negative stimulus, when covered with a matte diffusing mask, increases the clarity and stability of the formation of a consistent image observed by the patient on the screen, which improves the quality of treatment.

Placing the light sources and the screen illuminator in separate rectangular cases with the possibility of angular movement of each of them around the longitudinal axis allows you to adjust the light sources to the patient’s viewing angle, and illuminate the screen as evenly as possible, which also improves the quality of treatment.

Figure 1 shows a diagram of a device for training binocular vision.

The device contains two light sources with light-tight grades 1 glued on them in the form of rackets with “handles” on a backlit background 2 placed in the housing 3. The diameter of the round part of each light source 1 is 8-12 mm, and the diameter of the backlight 2 is 30- 40 mm. Below housing 3 is housing 4 with a matrix for backlighting 5 of screen 6. The screen size is 50 × 50 cm. Housings 3 and 4 are moved around the longitudinal axis 7. Below housing 4 is the base of the device 8 with controls 9 in the form of push-button switches.

The device operates as follows.

Cover the patient’s left eye with an opaque occluder or hand and turn on the right light source using one of the buttons of control 9. The patient looks with his right eye at light source 2 with mark 1 for about 20 seconds. Then they cover the patient’s right eye and turn on the base of the device 8 the left light source using one of the buttons 9. Also for 20 seconds. the patient looks with his left eye on the light source 2 with the mark 1. Then the patient looks at the screen 6 and observes successive images with both eyes repeating the appearance of brands 1. The patient's task is to “merge” two consecutive images into two with two eyes open. To stimulate 6 consecutive images observed on the screen in approximately 1-1.5 minutes. the backlight 5 should be turned on for 1-2 seconds, after which the patient can again see a sequential image on screen 6. The on / off cycle of the backlight 5 is repeated 2-3 times.

The device was tested in the Eye Clinic of the Saratov State Medical University and the Municipal Preschool Educational Institution “Compensating Kindergarten No. 3” in Saratov in the treatment of binocular vision disorders in children.

Children (102 children) aged 4-12 were divided into four groups: with binocular vision impairment with strabismus without amblyopia (group 1, n = 32) and binocular vision impairment with strabismus with amblyopia (group 2, n = 30) . Children of both groups were treated using the proposed device. Each of the above two groups of patients had a corresponding comparison group (n = 20 people), which were treated using the prototype device. During the treatment session, 2-3 exercises were carried out to observe successive images. The course of treatment is 15-20 days. Before and after the course of treatment, the state of binocular vision was evaluated by the four-point test method.

In addition to clinical trials, before and after the course of treatment, the functions of the outer layers of the retina were evaluated using electroretinograms.

The results of the studies showed that when using the claimed device after three courses of treatment in the first group of patients, binocular vision recovery was observed in 71.8%, in the second group - in 50%, which is 1.5-2.0 times higher than in the comparison groups. The increase in visual acuity in the second group was 65%, and in the comparison group - 34%, there was an increase in the amplitude of waves a and b of the electroretinogram in the main groups by 8-10%, in the comparison groups - by 4-6%, which indicates the effectiveness of the claimed device .

The use of the claimed device improves the effectiveness of treatment, comfort and convenience in use.

Claims (1)

A device for training binocular vision using the method of negative sequential visual images, including two independent light sources glued onto them with opaque brands in the form of rackets, the “pens” of which are turned in opposite directions, characterized in that it is additionally equipped with a screen, a screen illuminator, and source controls light and a screen illuminator in the form of push-button switches located on the base of the device, while the light sources and the screen illuminator are made on a flat FIR LED matrices closed matt scattering mask, and placed in individual rectangular housings fixed in a vertical plane perpendicular to the base and parallel to the screen, with the possibility of angular movement of each of them around the longitudinal axis.