RU2242196C2 - Method and device for treating the cases of false myopia - Google Patents

Abstract

FIELD: medicine; medical engineering.

SUBSTANCE: method involves applying helium-neon laser radiation treatment to ciliary body. Diascleral irradiation is spread over a circle perimeter using variable-speed fine-point scanning radiation. Laser device has helium-neon laser, power supply source, unit for controlling power, deflector, control unit, rectangular pulse oscillator, electronic key, movable head having prism and facial setter. The rectangular pulse oscillator output is connected to controlling input of the electronic key, power supply source output is connected to controlled input of the electronic key, electronic key output is connected to helium-neon laser input which output is optically connected to deflector input which output is optically connected to movable prism.

EFFECT: enhanced effectiveness of treatment.

2 cl, 1 dwg

Description

The invention relates to medicine, in particular ophthalmology, and can be used to treat false myopia. A disease is widespread in children, which, as a result of progression, leads to the development of high myopia with thinning of the membranes of the eye and low vision with a number of complications in the fundus, which cannot be corrected with glasses and contact lenses. Deep organic changes in the membranes of the eye, in the retina and choroid are accompanied by low vision or blindness and make up a high percentage of disability (over 20). Therefore, one of the main tasks is the prevention and treatment of false myopia (accommodation spasm), which contributes to the progression of true myopia. Unfortunately, the low effectiveness of the known methods of treatment, caused by the insufficiently studied etiology and pathogenesis of this disease, require their repeated use in ophthalmic practice, which often do not satisfy either the doctor or the patient.

Currently, ophthalmic practice is widely used to treat false myopia by irradiating a ciliary body with helium-neon laser radiation in a power mode from 5 to 20 μW for 3 to 5 minutes with a number of seanoses from 5 to 10 (A.A.Semenov, F. A. Romashenkov and others in the materials of the All-Union Conference on Pediatric Ophthalmology, Riga, 1991, p. 34-35). However, the effectiveness of the treatment was stable only in 40-50 percent of cases. Moreover, as a rule, positive results in almost half of the cases were unstable. Therefore, it was necessary to resort to repeated courses of treatment, which is a significant drawback of the method and indicates a low treatment efficiency.

At present, it is well known that irradiation of a helium-neon laser in a continuous mode has a disinfecting property and enhances hemodynamic processes in the irradiation zone.

However, it is also known that due to adaptation processes a significant part of the impact efficiency is due to a change in the exposure factor (in this case, radiation from a helium-neon laser).

The objective of the invention in terms of the method is to develop an effective method for the treatment of false myopia by improving the hemodynamic parameters of the ciliary body when exposed to irradiation of a helium-neon laser in order to obtain stable visual functions.

The technical result, according to the invention, is achieved by the fact that in the method of treating false myopia, including the exposure to helium-neon laser radiation on the ciliary body with a total irradiation time of 3-5 minutes per session and with the number of sessions 6-8 per treatment course, irradiation is carried out diasklerally around a circumference 2 mm larger than the diameter of the cornea, using different-speed small-dot scanning radiation with a frequency of 7.5 r / s and pulse-amplitude modulation with a frequency of 60-70 Hz and a power of 100-140 μW.

The objective of the invention in terms of the device is to create a laser device for the treatment of false myopia, in order to obtain stable visual functions.

The technical result is achieved by the fact that the laser device for the treatment of false myopia contains a helium-neon laser, a power supply, a power control unit, a deflector, a control unit, a rectangular pulse generator, an electronic key, a movable head with a prism and a facial unit, while the output a rectangular pulse generator is connected to the control input of the electronic key, the output of the power supply is connected to the controlled input of the electronic key, the output of the electronic key is connected to the input of a helium-neon laser, stroke which is optically coupled to the input of the power control unit, whose output is connected optically to the input of the deflector, the output of which is optically coupled to the movable prism.

The invention is illustrated in the drawing.

The drawing shows a block diagram of a device for treating false myopia, containing a power supply 1, a helium-neon laser 2, a power control unit 3, a deflector 4, a control unit 5, a movable head with a prism 6, a face unit 7, a square-wave pulse generator 8 and an electronic key 9, while the output of the rectangular pulse generator 8 is connected to the control input of the electronic key 9, the output of the power supply 1 is connected to the controlled input of the electronic key 9, and the controlled output of the electronic key 9 is connected to the helium-neon input laser 2, the output of a helium-neon laser 2, connected optically to the input of the power control unit 3, which output is optically connected to the input of the deflector 4, and an output control unit 5 is connected to defelektorom 4, the output of which is optically coupled to the movable prism 6.

A method for treating false myopia when using a laser device according to the invention is as follows: the patient sits down and fixes with his forehead and chin on the front of the facial unit 7 using the generated scan with a frequency of 7.5 r / s in two mutually perpendicular planes and amplitude-pulse modulation a helium-neon laser beam of an average power of 100-140 μW, in the form of a discontinuous circle with a diameter 2 mm larger than the cornea for irradiating the ciliary body.

The ciliary body is irradiated with diasclerally moving around the circumference of different-speed small-point radiation 3-5 min for one session. The number of sessions ranges from 6 to 8 every other day. Refraction and visual acuity are determined immediately after the course of treatment, after six months and after 1 year. The effectiveness of the proposed method of treatment increases almost 2 times, that is, in 80 percent of cases it is possible to obtain a stable therapeutic effect within 1 year of observation.

A laser device according to the invention operates as follows.

The rectangular pulse generator 8 generates rectangular pulses with a frequency of 60-70 Hz and a duty cycle equal to two, these pulses are fed to the control input of the electronic key 9, the controlled input of which is connected to the output of the power supply 1, and its controlled output is connected to the input of a helium-neon laser 1, Thus, pulse-amplitude modulation of the radiation of a helium-neon laser 1 is carried out. This radiation passes through the power control unit 3, by means of which the required average radiation power p an emergency 100-140 μW and a deflector 4, by means of which the required trajectory of the laser spot is provided on the surface of the patient’s eyeball and through a prism 6 mounted on the movable head, by which the laser radiation is guided to the patient’s eye.

The authors use the well-known deflector 4 (Yu.K. Rebrin "Optical deflector", publ. "Technique" Kiev, 1988, p.129), made in the form of two movable mirrors, the initial position of which is a plane parallel to each other and having an angle of 45 ° relative to the direction of the laser radiation, with the axis of rotation of the mirrors being perpendicular to each other and the direction of the laser radiation, the deflection angles of the deflector mirrors are controlled by a known control unit 5 (B. I. Gorshkov, "Elements of electronic devices", ed. "Radio and communication ", Moscow, 1988, p.100), made in the form of a generator of sinusoidal oscillations with a purity of 75 Hz, and a phase shifter that provides a phase shift of 90 °.

A movable head with prism 6 (Leksto laser, Russia, Eye Microsurgery, 2000) is necessary for applying scanned radiation to the patient’s eye.

Example 1. Patient P. 15 years. He was admitted with a diagnosis of moderate myopia (-4.0 D) with accommodation spasm up to 5.5 D in both eyes. Visual acuity of 0.1 with a correction of 5.5 D = 0.9 in both eyes.

The patient was prescribed treatment - transscleral irradiation of the ciliary body according to the invention, by scanning radiation of a helium-neon laser. A total of 8 sessions were conducted for 5 minutes each session: with a frequency of 7.5 rpm and pulse-amplitude modulation with a frequency of 70 Hz, power 140 μW. After treatment, the spasm of accommodation disappeared. After treatment, the visual acuity of both eyes with a correction of -4.0 D = 1.0. The same indicators of visual acuity remained after six months and after 1 year.

Claims (2)

1. A method of treating false myopia, including the exposure to a helium-neon laser on a ciliary body with a total irradiation time of 3-5 minutes per session and with a number of sessions of 6-8 per treatment course, characterized in that the irradiation is carried out diasklerally around 2 mm larger than the diameter of the cornea, with different-speed small-dot scanning radiation with a frequency of 7.5 r / s and pulse-amplitude modulation with a frequency of 60-70 Hz, power 100-140 μW. 2. A laser device for the treatment of false myopia, characterized in that it contains a helium-neon laser, a power supply unit, a power control unit, a deflector, a control unit, a rectangular pulse generator, an electronic key, a movable head with a prism and a facial unit, with the output a rectangular pulse generator is connected to the control input of the electronic key, the output of the power supply is connected to a controlled input of the electronic key, the output of the electronic key is connected to the input of a helium-neon laser, the output of which is optically connected to the input of the power control unit, the output of which is optically connected to the input of the deflector, the output of which is optically connected to the movable prism.