RU191844U1 - FUSION SIMULATOR - Google Patents

Abstract

The utility model relates to ophthalmology and can be used to form a binocular fusion fusion reflex. The fusion simulator is made in the form of a photoprobe. The photo probe contains an aiming device in the form of a sight 1 and a diopter 2, LED photo targets 3 and 4 and a power source located in the end handle-holder 5 located at the end of the rack 6. LED photo targets 3 and 4 and the sight 1 are installed along the longitudinal axis of the rack 6 pa the end opposite the handle 5 and made for observation through the diopter with the right eye and for observation through the diopter with the left eye. The photo targets 3 for observation through the diopter with the right eye are located between the end face of the rack 6 and the sight 1. The photo targets 4 for observation through the diopter with the left eye are located between the sight 1 and the handle 5. The handle holder 5 is made with the window 7 of the selector switch for photographic target 3 photodiodes for observation through diopter 2 with the right eye and photodiodes 4 of the target for observation through diopter 2 with the left eye. Window 7 is equipped with photo target indicators and a frequency response scale from 10 to 60 Hz.

Description

The utility model relates to ophthalmology and can be used to form a binocular fusion fusion reflex.

Known fusion simulator containing an autonomous power source and two autonomous photo probes, each of which is connected to a power source and includes an aiming device in the form of a sight and a diopter, a stand with a pen holder, LED photo targets placed on one photo probe for observation with the left eye and on the other photo probe for observation with the right eye (RU 2331402 C1, 08.28.2008).

The well-known simulator allows the possibility of the formation of a fusion reflex and the strengthening of binocular visual acuity, however, two autonomous photo probes connected to an autonomous power source complicate its operation and make it difficult to conduct treatment in the presence of astigmatism.

The analogue (prototype) closest to the proposed utility model is a fusion simulator made in the form of autonomous photo probes, each of which contains a sighting device in the form of a sight and a diopter, a stand with a pen holder, LED photo targets and a power source (RU 65757 U1, 27.08. 2007).

Compared to the analogue, the prototype is more convenient in operation, but the location of the LED targets on autonomous photo probes also complicates the treatment.

The problem the real utility model is aimed at is the development of a fusion simulator that does not have the disadvantages of known designs.

Achievable when using the proposed utility model, the technical result is an increase in visual acuity by providing the possibility of the formation of a natural fusion reflex to affect a specific type of refraction.

The essence of the utility model is expressed in the aggregate of essential features, in which the fusion trainer in the form of a photo probe with an aiming device in the form of a sight and a diopter, with LED photo targets and with a power source located in the end handle-holder located at the end of the rack differs from the closest analogue in that that the LED photo targets and the sight are mounted along the longitudinal axis of the rack at the end opposite the handle and are made for observation through the diopter with the right eye and for observation through the diopter with the left g the basics, and photo targets for observation through the diopter with the right eye are located between the end face of the rack and the sight, and photo targets for observation through the diopter with the left eye are located between the sight and the handle made with the window for regulating the selective inclusion of photo target photodiodes for observation through the diopter with the right eye and photo target photodiodes for observation through the diopter with the left eye, while the window is equipped with photo target pointers and a frequency response scale from 10 to 60 Hz.

The proposed simulator due to the presence of a selective inclusion regulator allows you to alternately turn on the white, red and green LEDs, which allows you to increase the effectiveness of the treatment.

The choice of frequency response from 10 Hz to 60 Hz is due to the possibility of perception of the eye.

The mirror arrangement of LED targets with respect to the sights (sight and diopter) makes it possible to synchronize them in the upper and lower segment, which is located along the line of greater ametropia for various types of astigmatism on the TABO scale. The resulting mirror line clearly occupies a position along this axis and has a specific effect on the patient’s visual impairment associated with astigmatism.

The placement of the power source in the handle-holder simplifies the design and provides ease of use.

The presence on the controller of inclusion of the indicators of photo target for observation through the diopter by the right eye (R) and photo target for observation through the diopter of the right eye (L) is due to the possible difference in the frequency-contrast characteristics of the right and left eye. This difference requires a different value of the frequency-contrast characteristic for each eye, since this value is individual.

The device is illustrated in the drawing, which schematically shows a General view of the fusional simulator.

The fusion simulator is made in the form of a photoprobe. The photo probe will restrain the sighting device in the form of a sight 1 and a diopter 2, LED photo targets 3 and 4 and a power source located in the end handle-holder 5 located at the end of the rack 6. LED photo targets 3 and 4 and the sight 1 are mounted along the longitudinal axis of the rack 6 on the end opposite the handle 5 and made for observation through the diopter with the right eye and for observation through the diopter with the left eye. The photo targets 3 for observation through the diopter with the right eye are located between the end face of the rack 6 and the sight 1. The photo targets 4 for observation through the diopter with the left eye are located between the sight 1 and the handle 5. The handle holder 5 is made with the window 7 of the selector switch for photographic target 3 photodiodes for observation through diopter 2 with the right eye and photodiodes 4 of the target for observation through diopter 2 with the left eye. Window 7 is equipped with photo target indicators and a frequency response scale from 10 to 60 Hz.

The power source is installed in the handle-holder 5 through slot 8.

The proposed simulator, made in the form of a photoprobe, operates as follows: the patient selects an object directly in front of him as an aiming target and puts a photoprobe in front of his eyes. The photo probe is installed close to the eye and the patient fixes the distant object through the sight 1 and diopter 2. In window 7, the value "0" is set. Then the patient switches the value “0” to “1” and so on until he stops seeing the blinking. This is done with both the right and left eye. After a series of workouts, a blinking may appear on either one or both eyes. Then the simulator switch to the following values. Work with one and three LEDs is the same.

Photo targets 3 and 4 are included. The device is ready to go.

First step. The left eye is closed.

The right eye through the sight 1 and the diopter 2 conduct aiming on the distant target of the photodiodes photographic 3 to observe through the diopter 2 with the right eye. They open the left eye, they see two targets of the photo probe - one true, combined with the right photo targets with a distant photo target, and another phantom, located from the left eye out of the true target.

Second step. The right eye is closed. The left eye through the sight 1 and the diopter 2 of the left carry out aiming at the distant target of the photodiodes of the photographic targets 4.

At the same time, a set of photo targets 3 are linearly aligned with a distant aiming target, open the right eye, see two targets of the photoprobe - one true one, combined with the left photoprobe with a distant aiming target and the other phantom one, which is a set of photo targets of the left photo probe and located outside the left eye from the true target , i.e. to the left of the true set of photo targets of the left probe.

Third step. At the same time, the right and left eye through the sights of the right and left photo probes aim at the distant aiming target. With proper aiming, the true image of the target targets is combined with each other in the form of one merged bright target, while phantom target targets are located on the sides of the combined image; the photo target for the right eye is visible to the left of the true merged photo target.

Thus, a “trident” figure arises in the field of view, characterizing the effect of fusion (fusion) of the fields of vision of both eyes in natural conditions

The indicated actions are repeated several times during the time set for each patient during the period of one training session.

In the presence of astigmatism, the target line is located according to the obtained degrees of astigmatism on the TABO scale - this provides the treatment effect - the effect on large amitropia in a particular astigmatism.

The proposed device provides the ability to form a natural fusion reflex for long and short distances.

Training with the “trident” figure allows you to strengthen and develop binocular vision in most cases, its violation.

Thus, the proposed device allows you to provide the possibility of forming a natural fusion reflex for long and short distances, training the fusion reflex and strengthening binocular visual acuity.

The proposed utility model is illustrated by examples.

Example 1

Pilot V. born in 1989. Diagnosis: complex myopic astigmatism in both eyes.

Visual acuity of the right eye = 0.7, left eye = 0.5 with correction = 1.0

Refractometry data in the meridian of the greatest ametropia of the right eye -1.75 D ax 75 ° of the smallest ametropia -0.75 D. The left eye in the meridian of the largest ametropia 2.0 D ax 110 ° of the smallest ametropia 1.0 D.

The probe in front of the right eye is positioned at an angle of 70 ° to 80 ° on the TABO scale. Then, in front of the left eye, the same probe is placed at an angle from 100 ° to 115 ° on the TABO scale. Then move the probe from the right eye forward until the appearance of the figure of the "trident", then from the left eye forward to the appearance of the figure of the "trident".

Working in antiphase on the right and left eye, we achieve the preservation of the trident shape.

Refraction data does not change. Visual acuity increases: the right eye to 0.9 and the left to 0.8. Binocular vision is 1.0

Example 2

Onboard guide N. 1998. Diagnosis: Mixed astigmatism.

Visual acuity of the right eye = 0.4, left eye = 0.3 with correction = 1.0

Refractometry data in the meridian of greatest ametropia 2.25 D ax 90 ° least +0.75 D of the right eye. The left eye in the meridian of the largest ametropia is 2.5 D x 95 °, the smallest +1.0 D.

The probe is placed in front of the right eye vertically - at an angle of 90 ° on the TABO scale. Then the same probe is installed in front of the left eye at an angle from 90 ° to 100 ° on the TABO scale. The probe is moved from one eye to the other until a trident appears. Then they work in antiphase with an exposure of 1.5 minutes, ensuring the preservation of the trident shape.

Refractometry data does not change, and the visual acuity of both eyes increased to 0.6, and binocular vision to 0.7.

Example 3

Pilot born in 1964. Diagnosis: complex hyperopic astigmatism in both eyes.

Acuity of both eyes = 0.6 with correction = 1.0

Refractometry data in the meridian of greatest ametropia +2.0 D ax OD 110 ° ax OS 80 ° in the meridian of least ametropia + 1.0D.

The probe in front of the right eye is placed at an angle of 105 ° -115 ° on the TABO scale, then in front of the left eye the same probe is placed at an angle of 75 ° -85 ° on the TABO scale. The probe is moved from one eye to the other until a trident appears. Then they work in antiphase with an exposure of 1.5 minutes and also achieve the preservation of the trident shape.

At the same time, visual acuity increased to 0.8, and binocularly to 0.9, respectively.

Claims (1)

A fusion simulator in the form of a photo probe with an aiming device in the form of a sight and a diopter, with LED photo targets and with a power source located in the end grip-holder located at the end of the rack, characterized in that the LED photo targets and the sight are mounted along the longitudinal axis of the rack on the opposite of the end handles are made for observation through the diopter with the right eye and for observation through the diopter with the left eye, and photo targets for observation through the diopter with the right eye are located between the end of the rack and the sight ohm, and the photo targets for observation through the diopter with the left eye are located between the sighting device and the handle made with the window of the selector switch for the photodiodes for observation through the diopter with the right eye and the photo target photodiodes for observation through the diopter with the left eye, while the window is equipped with photo indicators and a scale of frequency characteristics .

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