RU2282423C2 - Method for treating amblyopia - Google Patents

Abstract

FIELD: medicine, ophthalmology.

SUBSTANCE: one should affect brightness, space-frequency and contrast canals of visual information processing at applying a helmet with stereo-head-phones to create virtual reality. Then one should conduct light stimulation of central fossa of yellow spot to present bright figures at dark background by decreasing their size gradually. In case of functional scotoma or instable coincidence it is necessary to prescribe exercises on presenting bright figures on dark background in the mode of simultaneous or alternating blinking, starting from larger objects. All exercises should be carried out monocularly at occlusion of an eye with better vision, and in case of bilateral amblyopia - without occlusion. The innovation provides efficient removal of disbinocular, refraction and anisometropic amblyopia, reconstruction of correct monocular spatial localization, development of fusion reserves and improved acuity.

EFFECT: higher efficiency of therapy.

2 cl, 1 dwg, 1 ex, 1 tbl

Description

The invention relates to medicine, namely to ophthalmology, and can be used to treat amblyopia in children.

There are many ways to treat amblyopia, which are based on various principles of exposure and activation of the corresponding channels, or the subsystem of the visual analyzer (according to the theory of its multi-channel functioning: Glezer VD Mechanisms for the recognition of visual images. M., L. 1966, 203 p .; Campbell FW Robson J. // J. Physiol. (Lond.) - 1968 - vol 197, No. 3 - P.551-561).

In 1978, a number of authors (Campbell F.W., Hess R.F. // British J. OphthaI. - 1978 - Vol. 62, No. 11 - P. 748-75) proposed stimulation of the amblyopic eye using frequency-contrast objects. It has been proven that a combination of several types of stimulation is more effective. So, the use of red and green filters with local “blinding” irritation of the central fossa of the retina made it possible to obtain an additional therapeutic effect (N. Kovalchuk // Bulletin of Ophthalmology; 1966, No. 3, pp. 44-49, Avetisov A.B. Use of color filters in the treatment of amblyopia (Thesis of Candidate of Medical Sciences - 1992, p. 95).

E.I. Kovalevsky et al. Successfully applied the simultaneous effect on the brightness and contrast-frequency channels in the form of local exposure to foveola with a structured stimulus (Kovalevsky E.I., Novikova L.A., Dubovskaya L.A. et al. Invention and rationalization in medicine. Republican collection of scientific works M., 1988, pp. 73-75).

All of the above methods can be considered as analogues. From the point of view of the theory of multichannel organization of the visual system, their common drawback is the selective effect on only one or two channels.

A known method for the treatment of amblyopia, which includes the correction of impaired color perception as a component of amblyopia, by stimulating the amblyopic eye with a reversing chromatic chess pattern of opposing colors corresponding to the detected violation of color perception (Shamshinova A.M., Ibatulin R.A.).

The collection of scientific works of the Chelyabinsk Medical Institute (dedicated to the 50th anniversary of the Victory over Nazi Germany. Chelyabinsk, 1995, p. 194) is devoted to the improvement of additional methods of treating amblyopia in children.

This method is chosen as our prototype, since it is closest to the one proposed for its intended purpose and technical solution. However, this method purposefully affects only the color subsystem and does not affect the brightness and contrast-frequency channels for processing visual information, which does not allow to achieve the optimal therapeutic result.

The ability of binocular vision of the surrounding space refers to higher visual functions. The space around us has three dimensions, and its image on the retina is flat. Despite this, normal eyes accurately solve the problem of orientation in space.

The main objective prerequisite for the formation of three-dimensional spatial perception is the distance between the centers of the pupils, i.e. binocular basis. The right and left eyes simultaneously examine the object from different points, as a result of which its image on the retina of the right and left eye is different.

When analyzing two such images of a different nature in the visual zones of the cerebral cortex, a three-dimensional image of the observed picture arises.

In the physiology of vision, there is an opinion that visual information is transmitted phase, it is possible that it is alternately in the right and in the left visual channels (Korpman I.L. 1966, Hamburger F.A. 1949, Verhoeff F.H. 1935). The frequency of these impulses is such that the variability of their transmission is not felt by a person. Therefore, we can assume that the phase-temporal presentation of test objects is one of the physiological methods of binocular presentation of visual information.

The principle of phase separation was used by Aulhovn (1973) in a phase separating haploscope, where the phase change is carried out by rotating sector obturators.

The aim of the proposed method is to increase the effectiveness of the treatment of amblyopia due to the complex effect on the visual analyzer and hanging the visual functions of the macular region of the fundus.

In recent years, there has been significant progress in the use of computer technology in medicine.

Particularly attractive and promising areas of these developments for medical practice is the creation of training programs based on virtual reality.

Virtual reality (from Lat. Virtus - imaginary, imaginary), created by computer means, a three-dimensional model of reality creates the effect of the presence of a person in it, allows you to interact with the objects represented in it, including new methods: changing the shape of the object, free movement between micro and macro levels of space moving the space itself.

Getting acquainted with the literature, we tried to find information regarding the use of this technology (for educational or therapeutic purposes) in ophthalmology. However, we did not find such data in the accessible information space. In this regard, in our opinion, it seems very promising to use the virtual reality effect created by special helmets for ophthalmic practice, namely for the treatment of children with amblyopia.

Considering all of the above, we propose using a virtual reality helmet for therapeutic purposes to increase visual acuity (see drawing).

The essence of our work is as follows.

The standard helmet of virtual reality has special screens (visors) on which an image is projected from the video source, separately for the right and left eye.

The video helmet has two color displays on liquid crystals, each of which creates a contrast image of 789 × 230 elements. Both eyes see different images, at the same time they perceive depth together and a stereo effect is created. The result is a truly stereoscopic image, putting you in the reality of events.

The helmet design includes high-quality stereo headphones. The virtual orientation system responds to every movement of the user's head. The digital signal processing controller provides input accuracy and feedback.

Games are launched in our special processing, and a child (5-12 years old) in a virtual helmet enters the world of virtual reality and enjoys the game.

The helmet, in our opinion, should stimulate the amblyopic eye, making it work.

During medical procedures, tasks can be complicated by adding red-blue filters to existing ones, as well as, if necessary, optical correction of ametropia (spherical and cylindrical glasses).

For the treatment of amblyopia, exercises are used that are performed in a playful manner, which are carried out monocularly, with occlusion better than the seeing eye, and with bilateral amblyopia, occlusion is not performed. Amblyopia treatment is based on light stimulation of the central fossa of the macula and development of the localization abilities of the amblyopic eye. General irritation with retinal light due to a special flash has a disinhibition effect on the function of the amblyopic eye and increases the excitability of the cortical part of the corresponding half of the visual analyzer. With a gradual decrease in the size of bright figures on a dark background, receptors of the central zone of the retina are activated, which contributes to the development of proper fixation. These exercises increase visual acuity, restore correct monocular spatial localization and allow you to train the oculomotor nerves.

In these exercises, additional features are provided: alternating or simultaneous flashing, changing the brightness of red and blue. Selection and sequential change of binocular exercises should be carried out in accordance with the functionality of the patient. If there is a functional scotoma or an unstable combination, it is advisable to prescribe exercises in the blinking mode (simultaneous or alternating), starting with larger objects, the blinking parameters (color, frequency) are selected individually (for example, = 4 Hz or 9 Hz for 1-2 minutes, then decrease the frequency).

As the scotoma is eliminated or its absence, the same exercises are prescribed for the development of fusional reserves. First, select larger objects, then move on to smaller ones.

The results of the exercises are stored in the computer. They allow the doctor to judge the dynamics of treatment and periodically add or change certain exercises. When selecting specific exercises, it is recommended to take into account the age and level of intellectual development of the child. In the first sessions, you should choose exercises with simple and large objects, then move on to more complex and small ones.

Before treatment, during the sessions and after treatment, it is necessary to conduct control studies using traditional methods: measuring visual acuity, strabismus angle, assessing the nature of vision in the color test and fusional ability in synoptophore.

Our therapeutic method differs from traditional methods: it is carried out in the form of a game with active participation and greater patient interest, objective control at any stage of treatment. It also differs from all therapeutic methods for this pathology in that during the session the patient is isolated from everything around him (vision and hearing), since he sees and listens only to the therapeutic game. Exercises are carried out daily, 2 times a day for 10-15 minutes, for one course of treatment 15 sessions.

The proposed method has been tested in the treatment of 36 children suffering from amblyopia (table 1).

In the first group (20 people), the method was used in combination with the traditional treatment of amblyopia. The control was 20 children with the same ophthalmological status, treated only with traditional methods.

In the second group (16 people), the treatment by the proposed method was carried out after the traditional treatment of amblyopia, which did not produce an effect. Improving visual function was observed in 7 patients.

Example. Patient K., 6 years old, 8 months old, was admitted to a specialized kindergarten for the treatment of strabismus and amblyopia in October 2000 with a diagnosis of friendly non-accommodating convergent strabismus, dysbinocular amblyopia of a high degree of the right eye, mild hypermetropia of the right eye and the middle degree of the left eye. Strabismus was detected at the age of 1.5 years.

On admission: visual acuity of the right eye = 0.2 n / a, left eye = 0.6 is not corrected, strabismus angle according to Hirschberg = 12 °, there is central visual fixation. As a result of pleoptic treatment, which included penalization for the near ones, local glare of the central fossa of the retina of the right eye, exercises on the corrector-localizer, other pleoptic exercises, after 3 months the visual acuity of the right eye reached 0.3 with a corresponding correction. Over the next 3 months, no improvement was noted with continued treatment. In June 2001, treatment was started with our proposed method. After 15 sessions (1 month), visual acuity reached 0.6 and the strabismus angle decreased to 3 ° according to Hirschberg.

Thus, the proposed method of treatment increases the effectiveness of eliminating dysbinocular, refractive and anisometropic amblyopia, and can also be used as an independent method for persistent, poorly treatable amblyopia with traditional methods.

Table number 1
Dynamics of visual acuity in the main and control groups of patients. Severity of Amblyopia Criteria for evaluation Main group Control group The difference in the increase in visual acuity in the main and control groups Weak
(4 people) * Average
increase
visual acuity
* Average
gradient
increase
0.3

σ = 0.0816
mx = 0,0408
1.65
0.23

σ = 0,0503
mx = 0.252
1.43



0,07 Average
(11 people) * Average
increase
visual acuity
*Average

gradient

increase
0.35
σ = 0.1255

mx = 0,0378

2.83
0.24
σ = 0.1087

mx = 0,0327

2.07


0.11 High
(3 people) * Average
increase
visual acuity
* Average
gradient
increase
0.3
σ = 0.1732

mx = 0.1000
4.3

0.18
σ = 0.373

mx = 0.0215
2.5

0.12 Highly
high
(2 people) * Average
increase
visual acuity
* Average
gradient
increase
0.06
σ = 0,071

mx = 0.0050
3.0
0.05
σ = 0.0141

mx = 0,0100
2.75
0.01

Claims (3)

1. A method of treating amblyopia, including visual stimulation upon presentation of a test object in terms of color separation of visual fields by affecting the brightness, spatial frequency and contrast channels of processing visual information, characterized in that they use a helmet to create virtual reality with stereo headphones, while carry out light stimulation of the central fossa of the macula and present bright figures against a dark background, gradually reducing their size, in the presence of a functional scotoma or For active combination, exercises are required to present bright figures on a dark background in the mode of simultaneous or alternating blinking, starting with larger objects, all exercises are carried out monocularly with occlusion of the better seeing eye, and with bilateral amblyopia without occlusion. 2. The method according to claim 1, characterized in that the exercises provide for the addition of red-blue filters to existing ones. 3. The method according to claim 1, characterized in that the exercises provide for changing the brightness of red and blue.