RU2019163C1 - Ophthalmologic device for laser therapy - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: ophthalmologic device has helium-neon laser provided with control unit and optic system having modulator, power attenuator and diffusion scatterer located at outlet of optic system. New is, diffusion scatter is carried out in the form of inside surface of photometric sphere with two openings, one opening - inlet one is located coaxially with optic system for input of radiation and the second one - outlet is located so that inlet opening and crossing point of inlet laser ray with sphere surface are out of field of view of patient. Positive short-focus lens is disposed axially movably along optic system in front of diffusion scatterer. EFFECT: improved efficiency of treatment owing to security of distribution uniformity of power density of radiation beam on tissue of eyeball including peripheral part of retina. 1 dwg

Description

 The invention relates to medicine, and more particularly to an ophthalmic technique in which low-intensity laser emitters are used to stimulate the activity of eye tissues.

 The closest technical solution is an ophthalmic installation containing a helium-neon laser with a wavelength of 632.8 nm and an optical system having a diffuse diffuser in the form of a plate at the output, made, for example, from milk or frosted glass. The unit is designed to stimulate the activity of the cornea and retina.

 The disadvantage of the installation is that it does not provide a uniform distribution of the power density of the radiation flux on the cornea and retina due to the fact that frosted glass, for example, is used as a diffuse diffuser, and it has an uneven scattering indicatrix. As a result, the central zones of the cornea and retina are irradiated with greater power, therefore, the stimulation of the activity of the tissues of these zones will be more effective, and the further the zone is removed from the center, the weaker the stimulating effect of laser radiation. The disadvantage is that it is not possible to irradiate the peripheral areas of the fundus, due to the insufficient angular size of the diffuse diffuser used.

 The objective of the invention is to provide a device that ensures uniform distribution of the power density of the radiation flux on the tissues of the eyeball, including the peripheral parts of the retina.

 The technical result consists in increasing the efficiency of laser stimulation of the eye tissue, in particular the cornea and retina, resulting in an improvement in visual functions.

 The specified technical result can be obtained if, in an ophthalmic laser therapy device containing a helium-neon laser with a control unit and an optical system including a modulator, a power attenuator and a diffuse diffuser, the diffuse diffuser is made in the form of the inner surface of the photometric sphere, the inlet of which is located coaxial with the optical system, and the outlet is located so that the inlet and the point of intersection of the incoming laser beam with the surface of the photometer cal spheres placed out of sight of the patient, wherein between the diffuse scatterer and introduced attenuator positive short-focus lens mounted movably along the axis of the optical system.

 The drawing shows a diagram of the device.

 An ophthalmic device for laser therapy contains a radiation source - a helium-neon laser 1 with a wavelength of 632.8 nm with a power supply, a control unit 2 with an electronic time switch, a modulator 3, a polarizing power attenuator 4, a positive short-focus lens 5, installed with the possibility displacement along the axis of the optical system, diffuse diffuser 6, made in the form of the inner surface of the photometric sphere, with two holes: input 7, located coaxially with the optical radiation input system and a weekend 8.

 The device operates as follows. The light from the radiation source 1, passing through the modulator 3, the power attenuator 4, which allows you to smoothly adjust the flux power density at the output of the optical system, enters the photometric sphere 6 through the inlet 7, previously scattered by the positive short-focus lens 5. In the photometric sphere, the beam is repeatedly reflected through the outlet 8 diffuse-diffused flow enters the tissue 9 of the eyeball of the patient.

 PRI me R. Before starting the procedure, the doctor determines the necessary parameters of laser radiation specifically for each patient: the power density of the stream at the output of the optical system, the duration of the session, the number of procedures. Using the time relay, which is part of the control unit, and a power attenuator, the device is tuned to the specified parameters. The patient’s head is fixed in a special device, while the condition is met that the front pole of the cornea of the eye coincides with the center of the outlet of the sphere and is 7-10 mm from it. Having placed the irradiation object in accordance with the requirement, include the installation. The effect of laser flow on the eyeball tissue begins, causing stimulation of metabolic processes. After the set time has elapsed, the installation automatically shuts down.

 An ophthalmic device for laser therapy has allowed to act on the tissues of the eyeball with a stream with a uniform power density, which provided stimulation of the activity of the tissues of the eye with the same strength at any point. So for the first time it became possible to irradiate peripheral parts of the retina with the same power density as the central zones. For the patient, the procedure is simple, since the effect of the laser stream coming from the sphere does not tire the eye, there is no need for a rigid fixation of the gaze since the illumination of the photometric sphere at any point is the same.

Claims (1)

 OPHTHALMIC DEVICE FOR LASER THERAPY, containing a helium-neon laser with a control unit and an optical system including a modulator, a power attenuator and a diffuse diffuser, characterized in that the diffuse diffuser is the inner surface of the photometric sphere, the inlet of which is aligned with the optical system, and the output is located so that the inlet and the intersection point of the incoming laser beam with the surface of the photometric sphere are placed outside the field of view of the patient ententa, while between the diffuse diffuser and the attenuator a positive short-focus lens is inserted, mounted with the possibility of movement along the axis of the optical system.

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