RU664U1 - Amblyopia treatment device - Google Patents

Abstract

A device for treating amblyopia, comprising a laser, a lens and a screen arranged in series, characterized in that a beam of optical fibers is placed between the lens and the screen, and the lens is mounted to move along the laser beam.

Description

DEVICE FOR TREATING AMBJOPIA

A useful model about the need for medical equipment, in particular, for the equipment used for the treatment, prevention and diagnosis of amblyopia.

It is known that urethra is a vomiting for the treatment of amblyopia, which forms a counter-lattice growing in a growing random-pro-tetranet venous lattice containing a drive onto which a disc with applied

on it stripes converging to the center (a, No. 1660697,

A 61 P 9 / 00.1989), A disadvantage of the known device is that -EiTO it has limited functionality and is ineffective for the treatment of certain varieties of amblyopia.

The closest in its technical essence and therapeutic effect is the known device for the treatment and prevention of amblyopia, containing a laser, lens and means for forming interference speckles, made in the form of a screen with a rough surface, which, um, can be set in motion (S.L. Shapovalov et al. Laser speckles in diagnostics and professional rehabilitation in civil aviation, Methodical manual M, Air transport, 1989, е.4-5).

When laser radiation is reflected from a rough surface, interference п hell is formed - a set of darkened and illuminated areas @ high contrast (spatial lattice) When the screen is moved, a change in the conditions of interference occurs due to chaotic movement of illuminated and з1 Darkened areas - a dynamic speckle is formed,%

A disadvantage of the known ue-device is the comparative DIFFICULTY and cumbersome co-construction, manifested in the need

compliance with special conditions for illuminating the screen with laser radiation and observing the electric structure on the screen, the presence of a mechanical screen moving unit, which is of considerable size, and the corresponding drive, which reduces the usability of the device, affects its dimensions and mobility

In addition, the known device does not allow you to change and adjust the size and contrast of the structural elements presented to the patient speckle,

The inventive utility model is aimed at simplifying the design and expanding functionality,

The specified result is achieved by the fact that the device for the treatment of gallipopia contains a laser, a lens mounted with the ability to move along the laser beam, czvchok evtvodov and screen.

Distinctive features of the claimed device are: installation of the lens e the ability to move; placement between the lens and the screen of the beam of optical fibers

Placing a fiber bundle with a lens and a screen allows you to create speckle on the screen regardless of the quality of the surface of the screen, which reduces the requirements for it, and therefore, any surface can serve as a screen,

In addition, since the divergence of the laser beam passing through the beam of the optical fibers is much larger than its divergence before entering the beam, the ecl-structure of a sufficiently large size can

observe at small distances from the output end - of the optical fibers

Since the optical fiber bundle is flexible, this allows directing the radiation in any direction, which can be done by the patient using the device, or a laboratory assistant. Moreover, the properties of the optical fiber bundle are such that light involuntary movements of the patient’s hand

. t

bridges can be equipped with a mechanical drive

screen, which simplifies the instrument’s contour, reduces its dimensions

instrumentation, "because in fact an active laser and a fiber bundle, and the role

screen can carry and poured baking paper) and simplifies its operation

The physical nature of the phenomenon of spots moving inside the speckle lies in the fact that detached fibers of the fiber inside the fiber bundle undergo relative deformations and displacements, which leads to a change in the output ends of the fiber bundle relative phase differences of the light waves, 11 |) passing through different fibers , and, consequently, to a change in the interference conditions of these light waves on the screen and to a change in the position of individual spots inside the speckle.

In addition, it was experimentally established that if the lens is moved along the beam to a small extent relative to the end of the optical fiber bundle, then the size and contrast of the structural elements inside the speckle observed on the screen change. And such a change in the structural elements of speckle is necessary in the treatment of certain types of amblyopia. If we carry out lenses in the absence of a fiber bundle, then such a change in the speckle elements (at small displacements) is not observed.

Thus, due to the totality of the distinguishing features, it is possible to expand the functionality of the device and at the same time simplify its contouring

The essence of the utility model is explained by drawings. On Fig, 1 presents a block diagram of elite for the treatment of amblyopia. On Fig, 2 presents a block diagram of a typical case of the implementation of the device.

The device comprises a laser 1, in which, for example, the hen-baked helium-neon laser LGN-207, and a lens 2, © MT, unique with a means of moving it 3, can be used as a means of moving 3, any known, for example, electromagnetic a relay whose core is connected to the lens, or a pneumatic or hydraulic cylinder whose stem v is connected to the lens, the Lie® lens can be mounted on a table moved by means of a helical gear, etc.

Between the lens and the screen there is a @ @ beam of 4 optical fibers, which is composed of fibers with a diameter of about 20 microns. The number of fibers in the beam reaches 80-110 pieces, the diameter of the entrance pupil is about 2 mm. The beam is placed so that the laser radiation hits its end. At some distance from the beam of optical fibers, a screen 5 is placed, which can be any surface , nelrimer, white wall, sheet of paper, etc.

The device operates as follows: 80m, Laser I and its beam are turned on, passing through the lens 2 and the optical fiber beam 4 directed towards the screen 5; they form an interference pattern of laser speckle presented to the patient on it. If necessary, if it is provided for by the treatment procedure, the moving means 3 of the lens 2, and the livza moves along the beam. In this case, a change in the size and contrast of the structural elements of the observed speckle occurs. The nature of the change in the structural elements of the speckle will depend on the nature of the movement lenses, This can be a discrete movement, smooth, variable in harmonic law, etc. The magnitude of the necessary movement of the lens along the beam and its

.

The arrangement with respect to the short waveguides is selected experimentally, depending on the optical characteristics of the lens and the parameters of the radiation incident on it (Radius® wavefront curvature.

4 distance to the waist of the laser beam),

As a rule, the distance between the lens and the end of the fiber bundle should be close to the focal length of the lens, and the amount of lens movement along the beam varies within a few millimeters

The device can be implemented in a more compact version, presented in FIG. 2. In this case, the device contains a laser I, a lens 2 connected to its moving means 3, a fiber bundle 4, a screen 5, which is made in the form of frosted glass placed in a hollow body 6 is preferably cylindrical in shape, rigidly connected to the end of the beam of optical fibers 4, In the housing 6 between the beam of optical fibers 4 and the glass 5 is a scattering lens 7, which, expanding the laser beam, allows to reduce the longitudinal dimensions of the housing 6 and forms an image of stem glass 5.

The device works the same way as described above, except that speckles are observed on a matte glass 5, which acts as a screen. To observe the e-waves, the patient picks up the case 6 and selects a convenient position for observation.

: f ecfiM 4 Formula

Claims (1)

A device for treating amblyopia, comprising a laser, a lens and a screen arranged in series, characterized in that a beam of optical fibers is placed between the lens and the screen, and the lens is mounted to move along the laser beam.