RU59388U1 - EYE REFRACTION DEVICE - Google Patents

Abstract

The proposed utility model relates to the field of medicine, namely to devices for the study of refraction and accommodation and can be used in ophthalmology for the study of friendly accommodation. The proposed device provides the ability to obtain new data on the state of the human visual system, namely, on friendly accommodation of the eye, which until recently has been little studied. New data will improve the accuracy of evaluating a healthy and amblyopic eye with dysbinocular amblyopia, choose the right treatment tactics, and evaluate its effectiveness. A device for examining refraction of the eye, consisting of an autorefractometer, including an optical and ophthalmic system, placed in a housing consisting of a base, a panel with an eyepiece for the patient, two side walls and the upper part. The authors see the novelty of the device in that the device additionally contains a stand, on which the side wall of the body rests so that the eye not examined remains unshielded, the stand is made in the form of three brackets interconnected by means of articulated joints, while two brackets are made with the ability to rotate around its axis by 360 °, the third bracket serves as a carrier, in which the handle of the autorefractometer is fixed.

Description

The proposed utility model relates to the field of medicine, namely to devices for the study of refraction and accommodation and can be used in ophthalmology for the study of friendly accommodation.

Amblyopia - a functional defect in the visual system is the second most frequent cause of decreased visual acuity in children. Earlier, its main manifestation was considered a decrease in visual acuity, however, as a result of studying pathogenesis and the clinic, a number of other disorders were revealed. Not the last place in this row is a violation of the accommodation of the amblyopic eye.

Accommodation is the ability of the eye to change its optical setup, that is, the initial refraction, within the space limited by the further and the nearest points of clear vision. Its disorder is manifested by a number of painful conditions, such as accommodation spasm, accommodation paresis, accommodation weakness with amblyopia, myopia, presbyopia. Identification of accommodation disorders allows you to correctly assess the condition of the visual analyzer and carry out the necessary treatment. The development of equipment to conduct such research is relevant.

The simplest device for studying accommodation of the eye is a subjective optometer (see Big Medical Encyclopedia, Editor-in-Chief B.V. Petrovsky, vol. 1, edition 3, Sovetskaya Encyclopedia publishing house., M., 1974, p. 163 )

A subjective optometer consists of an optical system projecting an image of a test object onto the retina of the eye under examination. The position of the test object, corresponding to a clear vision by the patient, characterizes the accommodation of the eye. The known device is used mainly to determine the nearest and further points of clear vision with further calculation of the volume of absolute accommodation according to the Donders formula. However, this device does not allow to determine the reserve (RA) and the amount of relative accommodation (OOA), which also characterize the function of accommodation.

Known devices that allow an objective study of accommodation of the eye. These include refractometers in combination with a device for presenting to the eye a fixation object that stimulates accommodation.

Any refractometer consists of two optical systems: optometric, creating a special brand image in space and projecting it onto the retina of the eye, and ophthalmic, allowing the doctor to conduct studies under the control of either vision or using a photoelectric detector (automatic refractometer). The principle of operation of all refractometers is to find a plane corresponding to the optical installation of the eye, which is achieved by moving the brand image to align with this plane. A prerequisite is the location of the refractometer coaxially with the studied eye and at a certain distance from it.

There are two types of refractometers. Refractometers of the first type are based on obtaining a sharp image of a luminous mark at the bottom of the examined eye. Refractometers of the Rodenshtok, Opton (Germany) and Topkon (Japan) firms are built on this principle.

Refractometers of the second type are based on the Scheiner phenomenon - bifurcation of the image projected onto the retina through different parts of the pupil. The measurement of refraction is achieved by combining the two images also by smoothly changing the convergence of the rays. The most common in this group of refractometers is the Hartinger refractometer.

Ophthalmologists got new opportunities in research and diagnostics with the advent of automatic refractometers.

For the prototype of the proposed utility model, a well-known device for researching eye refraction, consisting of an autorefractometer, including an optical and ophthalmic system, located in a case consisting of a base, a panel with an eyepiece for the patient, two side walls and the upper part (see Yu.Z. Rozenblum, was chosen) "Optometry" St. Petersburg, 1996. - P.82-84.)

The known device operates as follows.

During the examination, the patient’s head is fixed in the facial installation, which prevents the patient’s eye from moving relative to the autorefractometer lens and looks through the eyepiece at the mark. The second eye is obscured by an autorefractometer. The operator, using a special sighting device, points the device at the center of the pupil of the eye being examined and presses the start button. Test mark in infrared

projected onto the bottom of the examined eye. Its image gets to the photosensor through a narrow slit, oriented at any given moment in one of the meridians of the eye being examined, and a special movable optical system. The analyzer is configured to search for the position of the highest image contrast. This search is carried out by moving the lens of a mobile optical system. The position of the lens, in which the contrast is greatest, indicates the refraction of the eye in this meridian. The study is fully automatic. The device is equipped with a computer and a special program. During the measurement, the gap, rotating, passes through all the meridians of the eye under study, and refraction is recorded in three fixed meridians. Measurement is performed twice. If the results coincide, the computer calculates the refraction and astigmatism of the eye according to these data. Having finished the measurement in one eye, the operator points the device to the second eye and presses the start button again. The results are displayed on a digital display, or on a printer. From the subject it is only required to maintain the immobility of the position of the head and look at a special mark. For maximum relaxation of accommodation during the study, the fixation mark is presented as if at an infinitely large distance.

The known device allows you to explore the clinical refraction of the eye in adults and children.

However, the known device does not allow to study friendly accommodation, that is, the passive response of accommodation of the paired eye, which would improve the assessment of the state of the visual system with dysbinocular and refractive amblyopia in children and carry out its necessary correction.

The objective of the proposed utility model is to enable research into friendly accommodation.

The problem is solved in that in the known device for studying refraction of the eye, consisting of an autorefractometer, including an optical and ophthalmic system, placed in a housing consisting of a base, a panel with an eyepiece for the patient, two side walls and the upper part, the device further comprises a stand, on which the side wall of the body rests so that the eye not studied remains unshielded, the stand is made in the form of three brackets interconnected by a hinge connections, while two brackets are made with the possibility of rotation around its axis by 360 °, the third bracket acts as a carrier, in which the handle of the autorefractometer is fixed.

The proposed utility model meets the criterion of "novelty", as the patent information research conducted did not reveal the sources of patent and scientific and technical information that would discredit the novelty of the proposed utility model and contained essential features of the proposed device.

Figure 1 shows a device for measuring accommodation of the eye.

A device for studying refraction of the eye (Fig. 1) consists of an autorefractometer containing an optical and ophthalmic system (not shown in Fig. 1). The housing 1 of the autorefractometer consists of a base 2, a panel with an eyepiece for the patient 3, two side walls 4, 5 and the upper part 6. The housing 1 is mounted on a stand with its side wall 4. The stand is made in the form of three brackets 7, 8, 9 connected between by means of articulated joints rigidly fixed on a metal base 10. Two brackets 7, 8 are made with the possibility of rotation around their axes by 360 °, that is, they are fully rotated. The third bracket 9 serves as a carrier. The bearing bracket 9 is equipped with a socket 11, in which the handle 12 of the autorefractometer is fixed.

Preparing the device for operation.

To the ophthalmological table, with the help of a fixing screw, fix the front installation. The metal base 10 is rigidly fixed with the same screw, on which the brackets 7, 8, 9 are rigidly fixed. The side wall 4 of the autorefractometer is fixed by means of an adjusting sleeve 13 on a full-rotated bracket 7 at eye level of the patient. The handle 12 of the autorefractometer is fixed in the socket 11 of the bearing bracket 9. The system of movable hinges of the bracket allows you to freely move the autorefractometer in the front-rear and side directions.

The device operates as follows.

The patient is seated on a chair in front of the ophthalmic table on which the proposed device is installed. The height of the stool or ophthalmic table is adjusted so that the patient’s head is at the level of an autorefractometer mounted on this table. The patient puts his head on the chin of the facial installation. By adjusting the vertical position of the head using the chin and the horizontal position of the device using the bracket, they achieve the alignment of the visual axis of the eye and the optical axis of the device. The second eye remains open, not obscured by the body of the device. This allows you to present stress tests to the open eye and simultaneously remove the refraction of the other eye.

The proposed device when using it allows you to get the following positive effect.

Using the proposed device, 29 healthy patients (58 eyes) and 116 patients with dysbinocular amblyopia were examined. The studies showed that the proposed device provides the opportunity to obtain new data on the state of the human visual system, namely, friendly accommodation of the eye, which until recently has been little studied. New data will improve the accuracy of evaluating a healthy and amblyopic eye with dysbinocular amblyopia, choose the right treatment tactics, and evaluate its effectiveness.

Examples of specific performance.

Patient T-va M., 7 years old. Diagnosis: first degree hyperopia of the right eye. Hypermetropia of the II degree, dysbinocular anisometropic amblyopia of the II degree of the left eye. Before the study - the right eye: refraction - hyperopia 0.5 D; visual acuity without correction is equal to 1.0; the environment of the eye is transparent, the fundus is unchanged, the visual fixation is central. Left eye: refraction - hyperopia 4.0 D, visual acuity without correction 0.2 with correction sph +3.0 D = 0.4; the environment of the eye is transparent, the fundus is unchanged, the visual fixation is central.

To measure the accommodation of the eye, the patient was seated on a chair in front of the ophthalmic table on which the proposed device was mounted. The patient put her head on the chin of the facial setup. Using the adjusting screw of the facial device and movable brackets, the visual axis of the studied left eye was combined with the optical axis of the device. At the beginning, a load of accommodation of a healthy eye was performed, and the response of accommodation of an amblyopic left eye was recorded. A trial eyeglass frame was put on the girl’s face. In a spectacle frame in front of the best right eye, a prism of 10 ave. base to the temple to reduce the effect of accommodative convergence on the position of the studied eye. From a table with Landolt's rings from a distance of 5 meters, the girl clearly saw 10 lines. At this point, using a manual autorefractometer, the refraction of the amblyopic left eye was determined. Then, an sph - 1.0 D lens from a set of trial spectacle glasses was placed in the spectacle frame. After 1-2 seconds, the girl clearly saw the tighter line of the table. At this time, the refraction of the amblyopic left eye was determined. Then replaced the glass sph - 1,0 D glass sph - 2,0 D and again measured the refraction of the amblyopic eye. Glass change with refraction measurement was carried out up to sph - 5.0 D, each time focusing on a clear image

Landolt rings. Then accommodation was studied by the distant method. For this, a test was read to a healthy right eye for reading from a distance of 1 m, and the refraction of the amblyopic left eye was measured. Then the test was presented from a distance of 33 cm, and its refraction was measured similarly.

After researching the friendly accommodation of the amblyopic eye, we began to study the friendly accommodation of a healthy right eye. For this, a sph +3.0 D glass was placed in front of the amblyopic right eye, which gave a maximum visual acuity of 0.4. In addition, a prism of 10 pr. Diopters was placed in the frame, with a base to the temple to reduce the effect of accommodative convergence on the position of the eye being examined. At rest, at the time of examination, 4 lines measured the refraction of a healthy right eye. Then the correction was reduced by one diopter, placing sph +2.0 D glass in the frame, thereby forcing the amblyopic eye to accommodate with a force of 1.0 D. At this moment, with a stable perception of the fourth row of the table, the refraction of the healthy right eye was measured. Glass changes in front of the amblyopic eye were performed sequentially from sph +3.0 D to sph -2.0 D, with simultaneous measurement of refraction of a healthy eye. After that, they presented a text for reading from 1 m and 33 cm with simultaneous measurement of refraction. The reading test corresponded to the visual acuity of an amblyopic eye.

Claims (1)

A device for examining refraction of the eye, consisting of an autorefractometer, including an optical and ophthalmological system, housed in a housing consisting of a base, a panel with an eyepiece for the patient, two side walls and an upper part, characterized in that the device further comprises a stand, which rests the side wall of the case so that the unexplored eye remains unshielded, the stand is made in the form of three brackets interconnected by means of articulated joints, while two the brackets are rotatable around its axis by 360 °, the third bracket serves as a carrier, in which the handle of the autorefractometer is fixed.