RU2387414C1 - Method of quantitative evaluation of colour sensitivity of photoreceptors of eye retina - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: value of colour sensitivity of each of photoreceptor types is determined separately by means of charts of colour optotypes of blue, green and red colour. Each chart represents matrix, in which geometric parametres of optotypes, located in vertical columns decrease from top to bottom in accordance with international standards. Optotypes with equal dimensions are placed in chart in horizontal lines. Tone of colouring of optotypes in each line decreases from left to right. As optotypes, Landolt rings are used. Colour sensitivity of each type of photoreceptors for each eye is evaluated separately by chart of corresponding colour. First, by chart of one of the colours, it is determined if patient perceives colour of demonstrated optotypes correctly and, if patient makes a mistake, conclusion about loss of colour sensitivity of corresponding type of photoreceptors is made. In case of correct determination of colour of demonstrated optotypes by left column of chart, value of visual acuity is determined for said colour of optotypes, after that by horizontal line, corresponding to obtained visual acuity, by movement of eye from left to right, determined is value of colour sensitivity of said type of photoreceptors by optotypes in that column further which patient cannot correctly recognise demonstrated optotypes.

EFFECT: method allows to evaluate quantitatively colour sensitivity of separately taken each type of photoreceptors of eye retina, spending less time for the procedure.

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Description

The invention relates to medicine and is intended for use in ophthalmology.

Back in the XIX century. English physician and physiologist Thomas Jung found that there are three types of photoreceptors in the retina, each of which is responsible for one of the three primary colors of visible light: blue, green and red. All other colors are obtained by combining these three colors. This property of the human eye is called trichromatic color vision [1, p. 47].

However, some people suffer from insufficient color sensation, in which it is difficult to distinguish between certain colors or their combinations. These include about 7% of men and only 0.5% of women. Most often, the eye with such a disease uses all three primary colors, but in the wrong proportions. Another case of color perception disorder is the response to only two primary colors: usually red and green, less often blue [1, p. 49].

Various pseudoisochromatic tables, first proposed by Stilling in 1876, which show numbers or figures in circles of one color against the background of circles of a different color, are currently used to detect color perception disorders [2, p. 117]. In the CIS, color tables are most often used. Rabkin.

The use of these tables for diagnostics reveals only complete color blind people, but these tables do not make it possible to detect people with partial impairment of the functions of one of the types of retinal photoreceptors. Moreover, there can be no talk of any quantitative assessment of the color sensitivity of various types of photoreceptors.

Due to the fact that when examining patients it is important for an ophthalmologist to know what his color sensations are and how correctly the patient perceives different colors, this problem can be solved only by quantitatively assessing the color sensitivity of each type of retinal photoreceptor. Moreover, in order that the inventive method could be used in a clinic where the optometrist is limited in time, the method for determining color sensitivity should be extremely simple and not take much time.

Color Tables Rabkin are the closest analogue for the intended purpose, but, as was said, they can only give a summary qualitative assessment of the functioning of all types of photoreceptors of the retina at the same time.

The emergence in medical practice of a method for determining the contrast sensitivity of the eye using tables of contrast optotypes [3] allowed us to apply approximately the same approach to the quantitative assessment of the color sensitivity of photoreceptors of the retina, of course, after the development of special tables that provide differentiated quantitative assessment of each type of photoreceptor separately . For this reason, as a prototype of the claimed invention, it is advisable to adopt the method for determining the contrast sensitivity of the eye, described in [3], in which, according to the black optotypes shown in Fig. 1, first the visual acuity of the eye is determined by the left column, and then by the horizontal line corresponding to obtained visual acuity, determine the total contrast sensitivity of the eye as a result of the functioning of all types of photoreceptors of the retina at the same time.

The task of the invention is to develop a method for quantifying the color sensitivity of each type of retinal photoreceptor separately, spending as little time as possible on this procedure.

The essence of the claimed invention is as follows. For a differentiated quantitative assessment of the color sensitivity of each of the types of photoreceptors of the retina, specially designed tables of color optotypes are proposed, the colors of which correspond to those colors that only one of the types of photoreceptors can respond to, i.e. the optotypes of each table are either blue, green, or red. In total, three types of tables shown in the figures should be used: FIGS. 2, 4. In each of the tables it is enough to place four columns of optotypes, the geometric parameters of which in each column are reduced from top to bottom in accordance with international standards used in the tables used to determine the severity view, for example in the Golovin-Sivtsev table.

At the same time, it is advisable to use modified Landolt rings as optotypes. The essence of the modification is the introduction of two additional rings with a double vertical or double horizontal section, which reduces the probability of correctly guessing the test object from 0.25 to 0.17. The geometrical parameters of the Landolt rings on the tables under development correspond to the geometrical parameters of the rings on the Golovin-Sivtsev table for the rows: 0,1; 0.2; 0.3; 0.4; 0.5; 0.6; 0.7; 0.8; 0.9; 1.0; 1,5.

The color sensitivity value of the examined type of photoreceptor is a value inversely proportional to the minimum (threshold) value of the contrast of the optotype that the patient is able to recognize. It is determined by the formula

where S is the value of color sensitivity of the examined type of photoreceptors;

To _p - threshold contrast value of the optotypes of the weakest color tone, correctly identified during the examination.

The coloration tones of the optotypes in each table are reduced in horizontal rows from left to right so as to cover the range of color sensitivity of each type of photoreceptor from the minimum value corresponding to the diseased eye with the minimum sensitivity to the maximum corresponding to the sensitivity of the healthy eye.

As you know, the contrast of an object relative to the background is determined by the formula

where E _f - the magnitude of the light flux reflected from the background on which the object is observed;

E _about - the magnitude of the light flux reflected from the observed object.

The tests showed that the maximum contrast of optotypes of different colors relative to the same white background, calculated by the formula (2), is different and is:

- for optotypes of blue color - 0.8 (3);

- for green optotypes - 0.6 (6);

- for optotypes of red color - 0.77.

Accordingly, the minimum color sensitivity of the eye will be 1.2; 1.5; 1.3.

The average statistical value of the maximum color sensitivity of a healthy eye, determined by formula (1), as shown by tests, was approximately 5 for all colors of optotypes, which corresponds to a contrast of test objects with respect to background of 0.2.

For the convenience of the ophthalmologist and the evaluation of the results of the examination, it is advisable to express the following color sensitivity values in all color tables with integers within the working range of the tables: 2; 3. For this purpose, in all the tables, the colors of the optotypes were selected, the contrast of which was: 0.5; 0.33.

Thus, the range of values of the determined color sensitivity of the photoreceptors of the retina on the tables is as follows:

- for blue - 1.2; 2; 3; 5;

- for green - 1.5; 2; 3; 5;

- for red - 1.3; 2; 3; 5.

These numbers are shown under the respective optotype columns in each color table.

The procedure for quantifying the color sensitivity of each type of photoreceptor should be as follows. First, the patient is presented with one of the color tables, for example blue, and find out in what color he sees this table. If the color of the optotypes is incorrectly named, then a conclusion is drawn about the absence of color sensations of the blue photoreceptors. If the color is named correctly, then the visual acuity of the eye for a given color of optotypes is determined from the left column of optotypes in the table. This is done by identifying optotypes with the smallest geometric parameters, which will correspond to visual acuity. It must be borne in mind that the visual acuity of the eye by color optotypes can differ significantly from the visual acuity of the same eye by black optotypes. In addition, the visual acuity of the eyes for tables of different colors may be different.

Then, by the line corresponding to the obtained visual acuity, the color sensitivity of this type of photoreceptor (in our case blue) is determined. To do this, the patient’s gaze is moved along the line to the column beyond which the patient cannot correctly identify the optotypes. Below, under the optotypes of this column, the value of the color sensitivity of the examined photoreceptors is indicated.

After that, the color sensitivity value for photoreceptors responding to green and red is determined sequentially by a similar technique.

In order to eliminate measurement errors caused by different conditions of illumination of the tables, when determining the color sensitivity of each type of photoreceptor, it is necessary to apply the optimal illumination of the tables, equal to about 300 lux, which the Rott apparatus can provide. Therefore, when measuring the color sensitivity of photoreceptors, color tables should be placed in the Rott apparatus. The dimensions of the tables are specially designed for their use in this machine.

The list of drawings explaining the essence of the claimed invention:

- figure 1 is a table of contrast optotypes to determine the contrast sensitivity of the eyes;

- figure 2 is a table of optotypes painted in blue tones to determine the color sensitivity of photoreceptors that respond to blue;

- figure 3 is a table of optotypes, painted in green tones, to determine the color sensitivity of photoreceptors that respond to green;

- figure 4 is a table of optotypes painted in red tones to determine the color sensitivity of photoreceptors that respond to red.

The inventive method for quantifying the color sensitivity of various types of photoreceptors relates to the diagnosis of eye diseases. When discussing information confirming the possibility of implementing the method under consideration, it is necessary to refer to the already mentioned factors of loss of color sensitivity of the retinal photoreceptors in [1, p. 49]. Used in the prototype method for determining the contrast sensitivity of the eyes using tables of contrast optotypes, characterizing the total assessment of the functioning of all types of photoreceptors of the retina, it can be concluded that with a sequential differentiated assessment of the color sensitivity of each of the types of photoreceptors by using tables with color optotypes, quantitative values of color sensitivity of each type of photoreceptors separately.

The determination of the color sensitivity of any type of photoreceptor of the retina is carried out in the following sequence. One of the color tables of the optotypes, for example, shown in figure 2, is placed in the Rott apparatus. Covering the left eye, determine the correct color sensation of the right eye. In the case of incorrect color perception, a conclusion is drawn about the loss of color sensitivity of this type of photoreceptor. In the case of correct color sensation, the visual acuity of the right eye is determined from the left optotype column using the smallest Landolt rings that the patient is able to correctly identify. Then the patient shifts his gaze to the right along the line of optotypes that corresponds to the visual acuity of the eye, as determined by the table shown, until he is able to correctly identify these optotypes. The last correctly recognized optotypes will characterize the color sensitivity of this type of photoreceptor, the value of which is indicated in the table below under the column of optotypes on which the recognition operation was stopped. Then, closing the right eye, repeat the same operations and determine the color sensitivity of the left eye for the same type of photoreceptors. By changing successively the remaining color optotype tables in the Rott apparatus, the color sensitivity of two other types of retinal photoreceptors is determined by a similar method.

The production of color optotype tables can be carried out both in a printing way and on high-resolution color printers and high-quality printing after the development of tables by computer graphics.

Used sources

1. Zinn W., Solomon G. Vision, glasses and contact lenses. - St. Petersburg: "Peter", 1996. S. 47; 49.

2. Shamshinova A.N., Volkov V.V. Functional research methods in ophthalmology. - M.: Medicine, 1999. S. 117.

3. Patent RB No. 9853, IPC-A61B 3/02, BI No. 5, 2007.

Claims (1)

A method for quantitatively assessing the color sensitivity of the retina photoreceptors, which consists in using tables constructed in accordance with a matrix of contrast optotype tables to determine the contrast sensitivity of the eye, using Landolt rings as geometries whose geometric parameters decrease from top to bottom in vertical columns, corresponding to visual acuity from 0.1 to 1.5, characterized in that for a differentiated assessment of the color sensitivity of each type of photorecept tori that respond only to blue, green or red, use tables whose optotypes are colored either blue, green, or red, respectively, and the color tones in each table are weakened in horizontal rows from left to right, first determine whether the patient perceives the color of the optotypes of one of the tables and, in case of incorrect color sensation, concludes that the color sensitivity of the corresponding type of photoreceptor is lost, and in the case of correct color sensation, the visual acuity of the eye is determined for demonstrated color of optotypes on the left column of the table, then on optotypes in the horizontal line corresponding to the obtained value of visual acuity, identifying the optotypes fix the optotypes with the least weak color and determine the numerical value of the color sensitivity of this type of photoreceptor as a value inversely proportional to the contrast value of the color tone of the optotype, on which identification ended.

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