RU138750U1 - SIMULATOR FOR CORRECTION OF PRESBIOPIA - Google Patents

Abstract

The simulator for presbyopia correction contains a hollow tube with a diameter of 15 mm and a length of 240 mm with a longitudinal slot along its entire length of 8 mm, while the hollow tube is equipped with plastic plugs on both sides and a ball with a diameter of 12 mm is placed in it with the possibility of its free movement in the cavity tube and observing it through a longitudinal slot.

Description

The utility model relates to medicine, in particular, physiology of vision and ophthalmology and can be used as a simulator for the correction of presbyopia.

It is known that with age after 40 years, the vast majority of people develop farsightedness - the so-called "age presbyopia" - when near-distance vision ceases to be sharp, and glasses with plus diopters are needed for reading. This is due to a decrease in the strength of the ciliary (ciliary) muscle, which controls the degree of curvature of the lens, and a decrease in the elasticity of the lens itself.

The methods of prevention and correction of presbyopia described in the literature are palming, eye movement to the left - to the right, etc. - they do not allow directly training the ciliary muscle and therefore are ineffective (O. Pankov. The most common eye diseases. Moscow, Astrel, 2011, 222 s).

A known method of treatment and prevention of presbyopia using the selection of a lens or lens system (patent No. 2471212 "Method for the treatment of presbyopia", 2013). The method is quite complex, it consists in a thorough sequential selection of contact lenses of various optical powers for the correction of near and far vision. However, the selection of lenses is carried out by the doctor, the patient cannot do this on his own. The method does not directly affect the ciliary muscle.

Known eye trainer in the form of perforated glasses, which the authors propose for the treatment and prevention of various eye diseases, including for training at hyperopia (patent No. 2271794 "Eye trainer"). However, this simulator actually eliminates spherical aberration of the eye, as a result of which the image becomes sharper, and this allows you to see sharply, not including the ciliary muscle. Therefore, this simulator does not train her.

However, the ciliary muscle is well trained in tracking an object moving in space towards the observer and in the opposite direction. Indeed, from the physiology of binocular vision it is known that:

The ciliary muscle is innervated by the oculomotor nerve, which innervates the other (external) muscles of the eye, turning the eye in different directions.

As it turned out, in the process of convergence and divergence — the convergence and divergence of the axes of the eyes during the bifixation of an approaching or receding object — the ciliary muscle is always included in the work (SV Kravkov, Glaz and his work. Medghiz, Moscow, 1945, 355 pp.)

Therefore, for the prevention of presbyopia, such sports games as badminton, tennis and table tennis are useful, when playing in which tracking of an approaching and moving away object (shuttlecock, ball or ball) is necessary.

No prototype found.

The proposed utility model is a device that simulates the movement of the ball in table tennis, as it provides for the observation of a constantly moving object in the direction perpendicular to the eyes, while the observer is in a stationary position, which is extremely important for vision correction in presbyopia for severe, including neurological patients and elderly patients.

The technical result consists in restoring the tone of the ciliary muscles during presbyopia, due to the direct effect on the ciliary muscles as a result of periodic convergence and divergence of the axes of the eyes when the object is approaching and moving away when using the simulator to continuously monitor an object moving in the forward and backward direction perpendicular to eyes for a short period of time.

The technical result is achieved by the fact that the simulator for presbyopia correction contains a hollow tube with a diameter of 15 mm and a length of 240 mm with a longitudinal slot 8 mm wide over its entire length, while the tube is equipped with plastic plugs on both sides and a ball with a diameter of 12 mm is placed in it, s the possibility of its free movement in the cavity of the tube and observation of it through a longitudinal slot.

The proposed device is illustrated in figures 1 and 2 (A, B). In fig. 1 shows the appearance of the device, and in fig. 2 (A and B) - type of use of the device in direct and lateral projections.

The simulator for presbyopia correction contains a hollow tube (1) with a diameter of 15 mm and a length of 240 mm. On both sides the tube is closed with plastic plugs (2), inside of which there is a ball (3) with a diameter of 12 mm, which allows it to move freely in the cavity of the tube. The tube has a longitudinal slot (4) with a width of 8 mm (Fig. 1). Moreover, the specified slot width allows you to observe the ball moving in the forward and reverse directions perpendicular to the eyes.

The proposed simulator for the correction of presbyopia works as follows. The patient takes the tube in his hands and places it perpendicularly at a distance of 15-30 cm from the eyes, so that the ball is visible in the slot of the tube. By swaying the tube along the longitudinal axis, the patient sets the ball in motion. The ball moves in the direction from the patient’s eyes and back, at a speed that the patient adjusts so as to ensure the convergence of the axes of the eyes and the bifix of the ball as it approaches without unpleasant sensations. The closer the distance and the slower the speed of movement of the ball, the more effective the effect on the ciliary muscles.

With continuous tracking of the ball, moving in the forward and reverse direction perpendicular to the eyes for a short period of time and with daily and repeated use of it, a direct effect is exerted on the ciliary muscles, with the restoration of their tone and the implementation of vision correction during presbyopia.

Modern working methods for 90% involve the use of computers. Long-term use of a computer puts a person in specific conditions when he watches the monitor screen for many hours at a fixed distance from his eyes. This leads to a kind of "contracture" of the ciliary muscle of the eyes, as a result of which there may be a "spasm of accommodation" - when objects at a close distance from a person are sharply visible, and distant objects are seen blurry. The proposed simulator is compact and can be easily carried with you and, if necessary, periodically use. Using it for several minutes at an o'clock at work, it is possible to eliminate manifestations of such "spasm". Another area of application of the simulator is the prevention and correction of presbyopia. Weakening of the ciliary muscle of the eye and a decrease in the elasticity of the lens with age lead to difficulty seeing at close range, including the inability to read without glasses. The proposed simulator allows anyone, without leaving home, to give a load on the ciliary muscle and thereby train it, providing prevention and correction of hyperopia.

Thus, the simulator we offer provides a direct effect on the ciliary muscles due to the periodic convergence and divergence of the axes of the eyes during bifixation of an approaching and receding object (a ball freely moving in the cavity of the tube). In addition, when using the simulator for continuous tracking of an object moving in the forward and reverse direction perpendicular to the eyes for a short period of time, the restoration of the ciliary muscle tone during presbyopia is ensured.

Claims (1)

The simulator for presbyopia correction contains a hollow tube with a diameter of 15 mm and a length of 240 mm with a longitudinal slot along its entire length of 8 mm, while the hollow tube is equipped with plastic plugs on both sides and a ball with a diameter of 12 mm is placed in it with the possibility of its free movement in the cavity tube and observing it through a longitudinal slot.

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