RU2407423C1 - Device for diagnosing visual system pathology in children by critical frequency of flickers fusion - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: device contains case, in which placed is pulse-generating device, whose outlets are electrically connected with two light stimulators, made in form of light diodes fixed in headlights of toy car, with one headlight producing constant light, display and power supply unit, which is electrically connected with pulse-generating device. Pulse-generating device contains two pulse generators, made in form of microcontroller, by means of which generation of pulse within the range from 15 to 60 Hz is performed. Microcontroller has two outlets for connection of light stimulators, one outlet for one headlight, the other outlet for the other headlight with regulated difference of generation of pulses between headlights from 2 to 6 Hz. Device also contains buttons for control of pulse generation frequency, light pulse colour, switching-over of headlights and power supply init. Display is made with possibility to show indices of critical frequency of flickers fusion for left and right eye.

EFFECT: application of claimed device allows to reduce time for testing, reduce adaptation effect and increase test accuracy.

2 cl, 1 dwg

Description

The invention relates to ophthalmology, and more specifically to devices for diagnosing pathologies of children's vision by studying the critical frequency of flicker fusion.

The invention can be used for differential diagnosis of the functional state of the retina and optic nerve in children from 4 years of age.

It is known that in pediatric ophthalmology very often the early diagnosis of pathology of the retina and optic nerve causes difficulties in connection with the microsymptomatic picture of clinical signs in the fundus, which leads to diagnostic errors. In order to clarify the diagnosis, it is necessary to conduct long-term psychophysiological and not always desirable "contact" electrophysiological studies, which are often difficult to conduct for children especially at the age of 4-7 years.

Visual perception is a complex multi-level and multi-channel process, starting with the projection of the image on the retina and ending in the higher parts of the visual cortex.

The onset of the photochemical reaction of the pigment under the influence of absorbed light triggers a chain of rapid bioelectric reactions throughout the visual analyzer. Violation in one link of this complex chain of the visual system leads to visual impairment.

Light perception and color perception is that basic on which other functions of vision are built. For its implementation, it is not the absolute sensitivity of the eye to light and color that is important, but the sensitivity to their changes in space and time, the so-called contrast sensitivity, expressed by the psychophysical laws of vision.

There are two types of contrast sensitivity - spatial and temporal.

Temporary contrast sensitivity is the maximum frequency of flickering of light stimuli per unit time, at which the phenomenon of fusion of individual visual sensations occurs. This phenomenon is the critical flicker fusion frequency (CFSM). In healthy children, CFSM does not depend on visual acuity, on refraction and on the size of the pupil and slightly varies under the influence of side stimuli: sound, olfactory, taste and tactile.

Significantly, the values of CFSM are significantly changed in a number of pathological processes in the organ of vision in children, for example, with partial atrophy of the optic nerve, congenital cone-shaped dysfunction, glaucoma, maculudystrophy, and some other diseases. Of particular importance is the study of CSFM in children with X - chromosomal retinoschisis, where the indicators reflect the pathogenesis of the disease, starting with damage to the third neuron of the visual analyzer, with damage to the layer of nerve fibers of the inner layer of the retina and the progression of the pathology to its outer layers.

Normally, in healthy children, CESF on average is: 43.2 ± 0.5 Hz per red stimulus; 43.6 ± 0.7 Hz per green stimulus and 40.3 ± 0.6 Hz per blue stimulus (E.V. Rogatina, K.V. Golubtsov et al. Critical frequency of flicker fusion in the differential diagnosis of diseases of the retina and optic nerve in children. Actual issues of ophthalmology, materials of the Anniversary All-Russian Conference. Moscow - 2000. Publishing House of Helmholtz Scientific Research Institute of GB, Part 2, pp. 88-91).

With various pathologies of vision, such as, for example, with partial atrophy of the optic nerve (CASN), CPSM indicators decrease and average 37 ± 2 Hz, with retinal pathology, especially in its macular zone, indicators can decrease to 26 Hz or less. The decrease in CSFM in ChASN depends on the degree of damage to the fibers of the optic nerve, which was confirmed by electrophysiological studies. Studies have shown that in children at the stage of an active inflammatory process, the values of CFSM can decrease to 14-18 Hz for red and green stimuli, and during the period of restoration of visual functions, CFSM increases to 28-38 Hz, but still do not reach normal values.

Based on long-term clinical studies conducted in children of different ages by testing the critical frequency of flicker fusion to color stimuli, recommendations are given on the use of this method in pediatric ophthalmology (see, for example, E.V. Rogatina, A.A. Yakovlev, A. V. Khvatova, KV Golubtsov et al. Critical frequency of flicker fusion to color stimuli in the diagnosis of diseases of the retina and optic nerve in children. A manual for doctors. Publishing House of Helmholtz Moscow Scientific Research Institute of GB. Moscow - 2001, p. 18 and T .S. Egorova, K.V. Golubtsov. CFCM in the definition visual efficiency of visually impaired students. Information Processes, 2002, Vol.2, №1, s.106-110). The above works reveal the features of functional visual disturbances in children, including poorly seeing schoolchildren.

Studies of CFSM in children can be carried out from 4 years of age. Such studies are most informative in pediatric ophthalmic pediatrics, especially in the early stages of the pathological process.

Currently, ophthalmic pediatrics gives preference to time-frequency techniques, i.e. including the study of the critical frequency of flicker fusion (E.N.Iomdina, T.S. Egorova and others. The relationship of the accommodation state with the temporary contrast sensitivity of the eye. Biomechanics of the eye. 2005. Proceedings of the conference. Moscow - 2005, p. 48-51 )

The instruments used for these studies are compact, easy to use and are adapted for examining children's eyesight.

The diagnostic process on the developed devices (see, for example, certificate for utility model No. 6989, K.V. Golubtsov, G.V. Kazarin, E.V. Rogatin) was as follows.

First, the CFSM is tested. The child is presented with a luminous color test from a distance of 25-30 cm installed in the headlight of a toy car with a constantly increasing flicker frequency, which the tester smoothly adjusts until the flicker disappears. The study begins with red, then show green and the last - blue. At the moment when the child ceases to distinguish between flickering, he should immediately give a signal to the researcher, for example, say “Stop!”. The tester at this moment stops adjusting the frequency of the CSCM, and the measurement result is displayed on the digital indicator of the device. The result of the first step is designated as (P1).

Then they begin testing with a maximum flicker frequency, for example with a frequency of 55 Hz, and gradually reduce it until the child perceives a flicker, to which he also gives a “Stop!” Signal. This is the second result of the study (P2).

The final result of the CFSM study is determined by calculating the arithmetic mean value of these two quantities:

CFCF = (P1 + P2) / 2,

where P1 is the result of the merger of flickers,

P2 is the result of flickering.

The P1 index is normally always higher than the P2 indicator as a result of the existing visual inertia in the form of a sequential image.

It should be noted that in such devices one headlight of a toy car is constantly on, which the child is guided by, and the other headlight flickers, with the help of which the performance of the CSFM is tested.

However, the drawback of this technique is that to clarify the accuracy of the CFSM indicators, testing should be repeated two times, in some cases three times for each color, which leads to significant fatigue and a decrease in the child’s attention, therefore, reduces the true indicators of CFSM.

A known method for diagnosing the degree of human fatigue (see, for example, patent SU No. 1445694, A61B 5/16), which consists in the fact that before the eyes of the patient they place a light-protective spectacle frame with LEDs integrated in the front panel connected to a means for generating pulses and for the formation of light pulses of different wavelengths of green, red and blue, and diagnose the functional state of the visual system.

Light pulses are simultaneously presented to both eyes paracentrically and the degree of interhemispheric functional asymmetry of the brain is determined by the difference in the critical frequency of flicker fusion, which is used to judge the degree of fatigue of the examined patient. This method is difficult to use to diagnose the pathology of the visual system in a child, since the child is often afraid to put on a light-protective frame with built-in LEDs. In addition, the child cannot give an exact answer to the doctor’s questions during the study.

A device is known for diagnosing the pathology of the visual system in children at the critical fusion flicker frequency (see patent RU No. 2196497 C2, A61B 3/00). This device contains a housing that contains means for generating pulses, the outputs of which are electrically connected with two light stimulators made in the form of LEDs mounted in the headlights of a toy car, and a power supply unit that is electrically connected with means for generating pulses. The means for generating pulses is made on the basis of a microprocessor, by means of which a controlled frequency pulse is generated in the range from 1 to 60 Hz. In addition, the device contains a digital indicator for indicating the fusion flicker frequency. The device’s panel also contains control buttons for displaying and switching color stimuli.

The disadvantages of this device are the significant cost of the device and the duration of the study, which leads to fatigue of the child and a decrease in the accuracy of the CFCM indicators.

A device is known for recording the critical frequency of flicker fusion in children, taken for protopit (see, for example, certificate for utility model RU No. 11037, bull. No. 9, 1999). This device contains a pulse generator associated with a frequency driver based on a single-chip computer, and light sources (red, green and blue), which are installed in the headlights of the toy car’s body, one of the headlights constantly on and the other flickering.

The disadvantages of this device are the duration of the study and the accuracy of the CFCM indicators.

The basis of the present invention is the task of creating a device for diagnosing pathology of the visual system in children at a critical flicker fusion frequency, where, unlike the above developments, both headlights of a toy car flash. Flashing headlights of a toy car, i.e. the flashing of the light stimulators located in the headlights is carried out with a certain flicker difference between the headlights, with a certain frequency. The flicker difference between the headlights is adjustable and ranges from 2 to 6 Hz.

Such a methodical method significantly reduces the testing time, reduces the adaptation effect and increases the accuracy of the study.

The problem is solved in that in a device for studying the critical frequency of flicker fusion in children, containing a housing in which there is a means for generating pulses, the outputs of which are electrically connected with two light stimulators, made in the form of LEDs, mounted in the welds of a toy car, with one headlight lights up constantly, the display and the power supply, which is electrically connected to the means for generating pulses, includes means for generating pulses containing two pulse generators, which which are made in the form of a microcontroller, through which pulses are generated in the range from 15 to 60 Hz, and the microcontroller has two outputs for connecting light stimulators, one output for one headlight, and a second output for another headlight with an adjustable difference in pulse generation between the headlights from 2 to 6 Hz, the device also contains buttons to control the frequency of the pulse generation, the color of the light pulses, the headlights and the power supply, while the display is configured to reflect the critical part The fusion of flickers for the left and right eye.

This device contains a power source inside the case - a rechargeable battery and an indicator of its charge and discharge.

The device, unlike the prototype, significantly reduces the study time and increases the accuracy of the CFCM indicators. The research technique is as follows. At the beginning of testing, in accordance with the age of the child, he is introduced to the device (toy car) and examination methods. Then they conduct a test examination, when the CSFM is determined with two eyes, and the flicker frequency is set so that the child sees one of the headlights flicker. The child must determine which headlamp of the toy flickers, and which headlamp does not flicker.

Moreover, one of the headlights of a toy car can flash in red, the other headlight can flash in green or blue, or both lights flash in the same color.

Then the flicker frequency is set: one headlight of a toy car, for example, 40 Hz, and the other headlight of a toy car — 36 Hz, and the child is asked to answer which of the headlights flickers. But already monocular, at first it is better with the seeing eye. If the child answers that both headlights flicker, the researcher increases the frequency of light pulses in the headlights until the child detects that the flicker of one of the headlights has stopped. The doctor fixes the result and increases the flicker of another headlight until the flicker disappears. The obtained indicators of the flicker frequency of two headlights will be the result of the study. After this, the research procedure is repeated, but with a worse seeing eye. Testing a child with ametropia can be carried out in optimal spectacle correction. As experiments have shown, such a technique gives more accurate indicators of CSFM and does not lead to fatigue of vision and the process of adaptation to flickering stimuli.

The drawing shows a block diagram of the device, where: 1 - left headlight with a three-color LED, 2 - right headlight with a three-color LED; 3 - microcontroller; 4 - display, 5 - button for controlling the flicker frequency of the left headlight; 6 - control button flickering right headlight; 7 - button for controlling the color of the stimulus of the left headlight; 8 - button for controlling the color of stimuli of the right headlight; 9 - button for controlling the frequency of flickering of two headlights together; 10 - device case, 11 - power supply unit (mains adapter).

Claims (2)

1. A device for studying the critical frequency of flicker fusion in children, comprising a housing in which there is a means for generating pulses, the outputs of which are electrically connected to two light stimulators made in the form of LEDs mounted in the headlights of a toy car, with one headlight constantly on, a display and a power supply unit, which is electrically connected with the means for generating pulses, characterized in that the means for generating pulses contains two pulse generators, which are made in the form of micro an ontroller, through which pulses are generated in the range from 15 to 60 Hz, the microcontroller has two outputs for connecting light stimulators, one output for one headlight, a second output for another headlight with an adjustable pulse generation difference between the headlights from 2 to 6 Hz, the device also contains buttons to control the frequency of the pulse generation, the color of the light pulses, the headlights and the power supply, while the display is configured to reflect indicators of the critical fusion flicker frequency for the left th and right eye. 2. The device according to claim 1, characterized in that the power source is made in the form of a battery, and inside the housing contains an indicator of charge and discharge of the power source.

Images