RU2412682C2 - Method of prevention and treatment of obtained short-sightedness - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, namely to methods of prevention and treatment of short-sightedness. A therapeutic training is performed with using an optical training apparatus representing an optical system of spheroprismatic lenses and a frame. The training is divided on two stages. A first one is conventional and involves visual acuity checkup for prescribing a training apparatus, putting-on of the optical training apparatus accompanied with an eye haziness effect which a patient seeks to overcome actively by turning a sight from larger to smaller objects, or from closer to more distant objects. The training apparatus is repeatedly taken away for rest, self-control and autofocus stimulation. A second stage includes the exercises consisting in fixing a training apparatus with a hand by a bearing handle and moving it in a sagittal direction anteriad from an anterior surface of an eyeball in a range 1.0-1.2 cm to 3.0±1.0 cm to diplopia and back in an initial position. The exercise is made for 10-15 seconds and multiply repeatedly.

EFFECT: as a result of taking the training apparatus away from the eyeball, an effective force of spheroprismatic lenses gains, and as consequence functional values of eyes increase, and short-sightedness stabilises.

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Description

The invention relates to medicine, namely to methods for the prevention and treatment of eye diseases. The technical result is to increase the effective action of the simulator by increasing the distance between the front surface of the eyeball and the back surface of the sphere-prismatic lenses used in the simulator.

State of the art

A known method for the prevention and treatment of myopia using the method of divergent disaccomodation for the prevention and treatment of myopia, adopted as an analogue [1]. The method consists in first determining the visual acuity and the degree of myopia by the subjective method, and then in front of each eye (without correction with minus lenses), prisms with a base to the nose with a force of 1-2 diopters are placed in the test frame, as a result of which divergent disaccommodation occurs. After some time (a few seconds - rarely minutes), visual acuity increases, after which the prism strength is increased (usually up to 2-3 diopters, but not more than 4-5 diopters for each eye) until the maximum increase in visual acuity is achieved.

However, the method is not effective enough due to the fact that the treatment is carried out in a polyclinic setting, since in the inter-course period there comes the detraining and spasm of the ciliary muscle, accompanied by the progression of myopia and worsening visual acuity. The low effectiveness of the treatment is also due to the fact that the effect of micro-fogging, which is caused by positive spherical lenses, is not applied. The treatment according to this method requires specially trained medical personnel, equipment, time, facilities for treatment, which is associated with significant material costs that impede mass prophylaxis and treatment of myopia.

A known method for the prevention and treatment of myopia by using an optical simulator, adopted as a prototype [2]. The simulator is a plastic sphere-prismatic lenses placed in a spectacle frame. The total strength of each of the lenses consists of a positive sphere (0.75 ± 0.5) diopters and a prism in (2.5 ± 0.5) diopters located base to each other.

The simulator is designed for home use. Training is carried out 2-3 times a day, as well as additionally after a long visual load.

The training regimen is built taking into account the age and individual characteristics of the patient. At the beginning of the training, checking visual acuity using special tables or “remembering” it on objects that are surrounded by the patient, put on an optical simulator. In this case, the initial “blurring of vision” occurs, which it is necessary to actively overcome, moving the view from larger to smaller ones or from close ones (located at a distance of no closer than 3 meters) to more distant objects.

The simulator is repeatedly removed for short-term rest and self-control of visual acuity, as well as to stimulate autofocus. Treatment with a simulator will continue throughout the entire period of risk of myopia.

However, the method is distinguished by insufficient efficiency, since the optical power of the lenses, and therefore the efficiency of the prismatic and spherical components of the lens, remain unchanged. Therefore, getting used to the constant load quickly enough. The growth of treatment results stops. In order to increase the effectiveness of training, there is a need to increase the effective strength of the lens by increasing the distance between the front surface of the eye (cornea) and the back surface of the lens. For example, the effective action of a spherical lens with a force of 10.0 diopters when removed by 1.0 cm increases by 1.0 diopters [3].

This happens as follows: it is known that the optical power of a lens is determined by the reciprocal of its focal length. The main focus of the spherical positive lens D is located at point F, the main focal length is determined by the segment located between points A and F (Fig. 1). When the lens D is removed at a distance of AA ₁ from the initial position, the position of the main focus changes by the same amount, which shifts to the point F ₁ . The distance between points A and A ₁ is equal to the distance FF ₁ , since a shift of the same lens by a certain distance leads to a shift in the position of the main focus by the same amount (on the other hand, the effect of decreasing the focal length of the lens D by AA ₁ , equal to the segment FF ₁ ). Then the effective power of the lens located at the point A ₁ is determined by the formula:

А вот теорема подобия треугольников позволяет вычислить, что эффективная сила призматических линз при увеличении расстояния между призмой и передней поверхностью глазного яблока на 1,0 см может удвоиться (фиг.2).Example: a spherical positive lens of 1.0 diopters when shifted to the left by a distance of AA ₁ equal to 1.0 cm, will have a shift of the main focus relative to point F, also by 1.0 cm. Thus, its effective action is enhanced to 1, 01 diopters, i.e. by 1%

But the similarity theorem of triangles allows us to calculate that the effective power of prismatic lenses with an increase in the distance between the prism and the front surface of the eyeball by 1.0 cm can double (figure 2).

Calculation example:

It is given that a ray of light from a point source B falls on a straight line FF ₁ at an angle of 90 ° to point B ₁ . Further, at a distance AB ₁ from the straight line FF _1, there is a prism with an optical power X, which deflects light by an angle ω. The refracted ray falls to the point D, so the deviation is equal to the segment B ₁ D. By connecting the points A, B ₁ , D, we get a right triangle AB ₁ D with an angle at the vertex equal to the angle ω. When the prism is removed at a distance B ₁ A _{1, the} beam deflected by the prism at an angle ω ₁ equal to the angle ω (since the optical power of the lens remains the same) falls on the straight line FF ₁ to point C, forming a right triangle A ₁ B ₁ C. Formed triangles AB ₁ D and A ₁ B ₁ C are similar, because in the triangle similarity theorem the first sign of the similarity of triangles says that if the two angles of the triangles are equal, then the triangles are similar. In our case, the angle ω is equal to the angle ω ₁ , the angle e is 90 ° and is common to both triangles.

A consequence of the similarity theorem for triangles allows us to conclude that if the triangles are similar, then the ratio of the perimeters of similar triangles, the ratio of heights, medians, and bisectors are equal to the similarity coefficient - K. Since the increase in the effective force is directly proportional to the increase in the deviation distance, which in turn depends on the distance lenses and is determined by the similarity coefficient, then the effective force will be calculated by the formula xxx.

The aim of the invention is to increase the effectiveness of the method of prevention and treatment of myopia using a new sequence of actions for the use of a sphere-prismatic simulator. This goal is achieved by increasing the effective strength of the lens by changing the distance between the front surface of the eye and the optical system of the simulator in the range from 1.0-1.2 cm to 3.0 ± 1.0 cm, which is done by removing the simulator (frame frames) from the front surface of the eye in the sagittal direction for 10-15 seconds and return to the starting position, and the movement is carried out repeatedly. In addition, the distance can be changed using an automatic device.

In the claimed method, we use in the simulator a sphere-prismatic lens having a spherical component (+) 1.0 diopters. Since the increase in effective action is 1% at a distance of 1.0 cm from the original and 2% at a distance of 2.0 cm from the original position, the use of spherical lenses of small strength is still of clinical importance.

As you know, in the inventive method, we use sphero-prismatic lenses in the simulators having a prismatic component equal to 2.0 pr. Diopters. With an increase in the distance from 1.0 cm to 2.0 cm from the front surface of the eye, we have a similarity coefficient equal to 2. Therefore, the deviation of the light beam also increases by 2 times, thus, the effective prism power in 2 diopters increases to 4.0 diopters . With an increase in the distance between the lens and the eye to 3.0 cm, the effective strength of the prism is 6.0 pr. Diopters.

The result is a smooth increase in the effective power of the lenses at a constant optical power. An individual criterion for assessing the optimal distance for removing the frame of the frame with lenses is the appearance of double vision (diplopia) of the signs of the table or observed objects. Persistent diplopia indicates the onset of binocular fixation disorders, therefore, a subsequent increase in distance is impractical due to the termination of the divergent disaccommodation reflex. On the other hand, the appearance of double vision indicates the achievement of the maximum muscle load tolerated by this patient, which allows individualization of the training process. Thus, by removing the lenses from the front surface of the eyeball, an increase is achieved, with a smooth, effective force of the spherical and especially pronounced prismatic components of the lens, which significantly increases the effectiveness of each workout, in particular, and the final result as a whole.

Before starting treatment, an ophthalmic examination is performed. Visometry is performed, the determination of the relative accommodation reserves (ROA), biomicroscopy, ophthalmoscopy, microscopy using mydriatic, autorefractometric and echobiometric studies.

Treatment with the above method is prescribed to patients with established spasm of accommodation and acquired myopia. Training is carried out 2-3 times a day, as well as after a long visual load.

The training regimen is built taking into account the age and individual characteristics of the patient. Training time is divided into 2 stages. At the beginning of the training, checking visual acuity using special tables or “remembering” it on objects that are surrounded by the patient, put on an optical simulator. In this case, the initial “blurring of vision” takes place, which must be actively sought to overcome, moving the view from larger to smaller ones or from close ones (located at a distance of no closer than 3 meters) to more distant objects. The simulator is repeatedly removed (after 20-30 seconds) for rest, self-control and stimulation of autofocus.

In the second half of the training, an exercise is performed consisting of the gradual distance of the simulator to a distance of 2.0-3.0 cm from the surface of the eyeball in the sagittal direction until the sensation of bifurcation of objects and the same smooth return of the simulator to its original position within 10-15 seconds. The exercise is repeated several times until you feel slightly tired.

Treatment with training glasses should continue throughout the entire period of risk of developing myopia.

As a result of prolonged use in the treatment of an optical system consisting of 2 lenses having spherical (0.75 ± 0.5 diopters) and prismatic (2.5 ± 0.5 pr diopters) components placed in the spectacle frame with the base to each other used both in a static and dynamic position, a consistently high level of relaxation and a degree of muscle training are achieved, accompanied by a steady increase in visual acuity, a decrease in the strength of corrective glasses, and stabilization of the myopic process.

An example of a specific implementation of the method:

Patient Kuznetsova E.M., born in 1997, 10 years old, student of the 3rd grade of the humanitarian lyceum. Over the past six months, he has noted a decrease in visual acuity, the appearance of a feeling of fatigue in the eyes, which he associates with a high intensity of school loads. The patient underwent ophthalmological examinations: visometry, autorefractometry, ophthalmoscopy, echobiometry and determination of the reserves of relative accommodation. Visual acuity in the right eye was 0.3 with a correction of (-) 2.0 diopters = 1.0; on the left eye - 0.2 with correction (-) 2.0 diopters = 1.0. The reserve of relative accommodation was 1.5 diopters. With refractometry, myopia was found to be 0.75 diopters. The length of the anteroposterior axis (PZO) of the right eye was 23.8 mm, of the left -24.0 mm. Diagnosis: Myopia 0.75 diopters, spasm of accommodation, chronic eye fatigue syndrome in both eyes.

Since the patient could not be systematically treated at the clinic due to lack of free time, she was prescribed treatment at home using a simulator with sphere-prismatic lenses made according to the formula: sphere + 1.0 diopters and a prism 2.0 pr diopters located in a frame base to each other. Training was carried out 1-3 times a day for 5-10 minutes each. In the first of two stages of training, the patient put on a simulator, examined the signs of the table through the lenses, periodically removing it. The second stage of the training was carried out as follows: the support arch of the rim was fixed with a hand, which then smoothly moved the frame of the simulator rim with lenses in the sagittal direction from the front surface of the eye until diplopia appeared and back to its original position. The phenomenon of diplopia occurred at a distance of 2.0-3.0 cm anterior to the surface of the cornea. The exercise was performed in 10-15 seconds. The exercises were repeated repeatedly until signs of mild fatigue appeared. As a result of training for a month, visual acuity without correction improved from 0.3 to 0.8 in the right eye and from 0.2 to 0.6. Subjective correction decreased by 1.25 diopters, ROA increased by 1.5 diopters. This indicator (ROA) indicates the normalization of the accommodative ability of the ciliary muscle. Recommended to continue training during a period of intense visual stress.

Compared with the known treatment methodology with similar simulators, the proposed method is distinguished by its effectiveness, since the effective strength of the simulator lenses was enhanced by the spherical component from +1.0 diopters to 1.02 diopters, and most importantly, the prismatic component with 2.0 pr diopters up to 4.0-6.0 ave. Dptr only due to a change in the exercise algorithm. This method does not require any additional costs, affordable and safe to use. These advantages of the method allow the use of known optical simulators with greater efficiency for mass prophylaxis and treatment of acquired myopia.

Treatment results: as a result of the application of the proposed method in a group of 15 people, an increase in visual acuity was noted by 0.1-0.8, an average of 0.36; a decrease in the strength of corrective glasses - by 0.5-1.5 diopters, an average of 0.74 diopters; an increase in the relative accommodation reserves was detected by 1.0–2.5 diopters, an average of 1.84 diopters. Compared with the known methods, the proposed one allows improving functional indicators by 10-30%, preventing the progression of myopia at the observation time of up to 1 year in 94% of patients with acquired myopia.

Treatment by the proposed method does not require additional vision correction. Therefore, the absence of the need to change lenses allows you to conduct training without the help of an ophthalmologist at home and at work.

Thus, this method is a highly effective, affordable, safe method for the prevention and treatment of myopia, allowing training for a long period of time.

Claims (5)

1. A 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 changed by fixing the simulator by the supporting arch and moving it in the 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 carried out 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 for 10-15 seconds. 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 in automatic mode.

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