SU404466A1 - ELECTRORETINOGRAPH -; - PTG "", s, f ^ H? ^ U ';; t?;', Ii> & L Phi ^ Sh y> &1Us;. ^ ^^ - Google Patents

Description

This invention relates to a medical technique designed to study the retina of humans or animals for the purpose of diagnosing various eye diseases.

Electroretinographers are known, which include an electromagnetic-powered skimming mirror, a radiation source, a cathode ray tube, and a deflection generator.

However, such electroretinographs allow registration of only a single local electrotretinogram when illuminating a single region of the retina, for example, a yellow spot. Meanwhile, full information about the general | functional topography of the retina, the distribution of sensitivity in its individual zones, or the identification of areas of MECHANICAL DAMAGE can be obtained only when included in the study - simultaneously or sequentially - a large number of areas of the retina.

The aim of the invention is to obtain complete information about the general topography of the retina.

To do this (the proposed electroretinograph is equipped with a mirror with a hole, a spherical mirror and a color switch.

The drawing shows a schematic diagram of the proposed electroretinograph.

Electroretinograph contains scanning

2

mirror / with electromagnetic drive 2, radiation source 3, color switch 4, electron beam tube 5, deflection generator 6.

5 Iribor also contains a mirror 7 with a hole and a spherical diffusing screen 8.

The electroretinograph works as follows.

Before the examination, the patient's head is strictly fixed and, in addition, the line of sight is forcibly fixed (for example, by some mark placed in the visual field). This is necessary in order to prevent an arbitrary movement of the retina relative to the surface of the screen 8. The scanning light spot 5 cannot be moved across this screen with the help of an oscillating mirror /, to which the light flux from the radiation source 3 is directed. Mirror / may be provided in

0 is driven by an electromagnetic actuator 2, while the mirror / (flat or spherical) is placed at the end of the rod, which performs a zeroing motion under the action of electromagnetic forces.

5 To eliminate parallax, the light flux is directed onto a spherical screen 8 coaxially with the direction of glance. This is done with the help of a mirror 7 with a hole in the center, through which an 8-eye echo is observed. The same mirror can serve as a protection against disturbing highlights. The flow of Light from mirror 1 to mirror 7 can be both CONGRESS and divergent. In the latter case, the mirror 7 should be concave to focus the light on the screen 5.

The entire optical system is calculated in such a way that, at all its positions, a beam of light would block the hole in the mirror 7.

Thus, a spot of light 9 moving along the screen 8 successively excites the elements of the retina of the eye. The signal from the elements of the retina, taken by the contact lens, after amplification, goes to the brightness modulator of the electron-beam tube 5 used to display the image of the retina of the eye. In this case, the deviation of the electron beam in the tube is synchronized with the deviation of the light beam. For this, the deflection systems of the drive 2 mirrors 1 and the tubes 5 are energized from the common generator 6.

The light is drawn across the screen. It can move along different paths. One of the most convenient paths is spiral, which is easily accomplished using the above scheme.

By installing a spectral or color switch 4 (for example, a disk with openings closed by different light filters) in front of the radiators, forming a scanning spot, you can change the spectral composition of the radiation at each point of the scanned raster, and this can be done in different ways, for example, sequentially giving rasters of different spectral composition, forming regions of different spectral composition on one raster, forming at each point of the raster: Sequence: Vital light flashes

5 of different spectral composition, etc.

An electroretinograph containing a scanner1, its mirror with an electromagnetic drive, a radiation source, an electron-beam tube, a generator of deviation signals, characterized in that, in order to obtain complete information about the overall retinal imaging, it is equipped with a mirror with a hole, a spherical mirror and a color switch .