RU121438U1 - ARTIFICIAL EYE CRYSTAL - Google Patents

Abstract

1. Artificial lens of the eye (IHG), made of an elastic material as a monolith with the ability to bend and containing an optical part and two diametrically located support elements made flat with variable thickness, decreasing to the periphery, and bent to the front surface of the optical part at an angle of 25 ° to its main plane, the width of the support elements is equal to the diameter of the optical part, their ends are made convex, while the diameter of the optical part is 6 mm, characterized in that in each support element on its longitudinal axis, at the same distance from the center of the IHG, a through hole is made round shapes with a diameter of 0.1 to 0.5 mm, while the ratio of the distance between the points at the most distant from each other, lying on the opposite tops of the ends, to the diameter of the optical part is equal to 1.5-2; and the rear surface of the optical part is provided with a protrusion with a height of 0.001 to 0.3 mm in the form of a cylinder, the diameter of which is equal to the diameter of the optical part, and the base of the protrusion repeats the shape of the rear surface of the optical part. ! 2. The artificial lens of the eye according to claim 1, characterized in that the front surface of the optical part is concave, and the back surface is convex. ! 3. The artificial lens of the eye according to claim 1, characterized in that the optical part is made in the form of a biconvex lens. ! 4. The artificial lens of the eye according to claim 1, characterized in that the front and / or rear surfaces of the optical part are made in the form of an aspherical surface. ! 5. Artificial lens of the eye according to claim 1, characterized in that the rear surface of the optical part is made with a constant radius of curvature of 6 mm. ! 6. Arts

Description

The utility model relates to ophthalmology and can be used in the surgical treatment of high myopia, both for refractive purposes when removing a clear crystalline lens and for a cataract lens.

Closest to the technical solution of the problem is an artificial lens of the eye (IHG) made of an elastic material as a monolith with the possibility of bending and containing the optical part and two diametrically located supporting elements made flat with a variable thickness, decreasing to the periphery and bent to the front surface of the optical parts at an angle of 25 ° to its main plane, the width of the support elements is equal to the diameter of the optical part, their ends are convex, while the diameter of the optical part is 6 mm (RF patent for utility model No. 81067).

The disadvantages of this IHG is that it does not have through holes in the support elements, which makes it difficult to implant in the capsule bag, does not have a protrusion that runs along the entire back surface of the optical part, which worsens its contact with the posterior lens capsule.

Lack of contact with the posterior lens capsule may lead to the development of secondary cataract

The objective of the utility model is the creation of IHG for the surgical treatment of high myopia.

The technical result of the utility model is to reduce the morbidity of the operation and the risk of postoperative complications, such as secondary cataract.

The technical result, according to the utility model, is achieved by the fact that in an artificial lens of the eye made of an elastic material as a monolith with the possibility of bending and containing an optical part and two diametrically located supporting elements made flat with a variable thickness, decreasing to the periphery and bent to the front surface the optical part at an angle of 25 ° to its main plane, the width of the support elements is equal to the diameter of the optical part, their ends are convex, while the diameter of the optical hour and equal to 6 mm, according to the utility model, in each supporting element on its longitudinal axis, at the same distance from the center of the IHG, a through hole of a round shape with a diameter of 0.1 to 0.5 mm is made, with the ratio of the distance between the most distant from each other with points lying on opposite ends of the ends, to the diameter of the optical part is equal to 1.5-2; and the rear surface of the optical part is provided with a protrusion with a height of 0.001 to 0.3 mm in the form of a cylinder whose diameter is equal to the diameter of the optical part, while the base of the protrusion follows the shape of the rear surface of the optical part.

The front surface of the optical part can be concave, and the rear is convex.

The optical part can be made in the form of a biconvex lens.

The front and / or rear surface of the optical part can be made in the form of an aspherical surface.

The rear surface of the optical part can be made with a constant radius of curvature of 6 mm

The front or rear optical surfaces may have a variable radius of curvature to correct corneal astigmatism.

On the supporting elements, labels can be applied to center the IHG according to the strong corneal meridian.

The implementation of IHG in the form of a monolith from an elastic material with the possibility of bending and compatible with the tissues of the eye allows it to be implanted through an ultra-small incision, which minimizes the likelihood of postoperative astigmatism and less damages the hemothophthalmic barrier, which reduces the time for rehabilitation of patients.

The implementation of flat support elements, bent towards the front surface of the optical part and at an angle of 25 degrees to its main plane, allows you to ensure the most stable position of the lens in the capsular bag, to achieve the maximum possible visual functions with high myopia, while removing the transparent and cataract lens.

A protrusion along the entire posterior surface of the optical part excludes the formation of secondary cataract in the distant postoperative period in the treatment of myopia. The height of the protrusion from 0.001 to 0.3 mm is due to the individual features of the structures of the anterior segment of the eye, namely, the thickness of the natural lens of the eye. The through holes located on the longitudinal axis of each haptic element can significantly simplify and reduce the invasiveness of the implantation procedure. The diameter of the holes from 0.1 to 0.5 mm is due to the size of the surgical instruments used in implantation. An angle of 25 degrees, at which the supporting elements are bent from the main plane of the optical part to the front surface, provides prevention of retinal detachment.

The distance between the points most distant from each other, lying on opposite ends of the ends, to the diameter of the optical part is equal to 1.5-2, due to the anatomical features of the capsule bag.

The utility model is illustrated by a drawing, in which Fig. 1 shows a side view of the IHG and in Fig. 2 is a top view. IHG, according to the utility model, contains an optical part 1 and flat support elements 2, while the width of the support elements 2 is equal to the diameter of the optical part 1, and the ends 3 are made convex.

In each supporting element 2 on its longitudinal axis, at the same distance from the center of the IHG, a through hole 4 of a round shape with a diameter of 0.1 to 0.5 mm is made.

The rear surface of the optical part 1 is provided with a protrusion 5 of a cylindrical shape, a height of from 0.001 to 0.3 mm, the diameter of which is equal to the diameter of the optical part 1.

IHG, according to the utility model, contains two flat supporting elements 2, bent towards the front surface of the optical part 1 and at an angle of 25 ° to its main plane, the ends of the ends 3 are convex, and the rear surface of the optical part 1 can be made with a radius of curvature 6 mm or with a variable radius of curvature. Flat support elements 2 are made with a variable thickness, gradually decrease to their periphery, and the ratio of the distance between the points most distant from each other, lying on opposite vertices of the ends 3 of the support elements 2, to the diameter of the optical part 1 is 1.5-2. IHG, according to a utility model, after local anesthesia, a corneal or mixed corneoscleral tunnel incision, standard phacoemulsification and filling of the capsule bag with viscoelastic are bent and implanted into the capsule bag. IHG can be performed, for example, from a collagen copolymer. IHG, according to a utility model, was implanted in patients with high myopia in two eyes with a clear crystalline lens and in four eyes with a cataractically changed crystalline lens. Example 1. A patient, 38 years old, complained of decreased vision of OU. On examination, the cornea is transparent, the anterior chamber is deep, the pupil is actively reacting to light, the lenses are transparent. Fundus - pronounced myopic changes. Objectively - visual acuity in both eyes - 0.01 sph - 25 = 0.2, IOP - 14 mmHg. Was diagnosed with OU:

high myopia.

Based on the fact that the patient does not tolerate contact and spectacle correction, it was decided to perform the extraction of a transparent lens with implantation of the proposed IHG,

After the standard phacoemulsification procedure, the patient was implanted on the right eye with an IHG performed according to a utility model, in which the front surface of the optical part is concave and the rear surface is convex, while the rear surface of the optical part is made with a constant radius of curvature of 6 mm.

The postoperative period was uneventful. Visual acuity at discharge from the hospital was 0.5 with a slight spherical cylindrical correction.

Example 2 A 57-year-old patient complained of decreased OU vision, more to the right. On examination, the cornea is transparent, the anterior chamber is deep, the pupil is actively reacting to light, the lenses are transparent.

Fundus - pronounced myopic changes. Objectively - visual acuity OD - 0.01 sph - 25 = 0.02, OS - 0.05 sph - 27 = 0.06. IOP at OU - 18 mmHg

Was diagnosed with OU Complicated cataract. Myopia of a high degree.

Based on the fact that the patient on the right eye has more pronounced opacities in the cortical layers of the lens, it was decided to perform cataract phacoemulsification with implantation of ICH.

After the standard phacoemulsification procedure, IHG was implanted in the patient’s right eye, the optical part of which was made in the form of a biconvex lens.

The postoperative period was uneventful. Visual acuity at discharge from the hospital was OD 0.4 with a slight spherocylindrical correction.

Claims (7)

1. The artificial lens of the eye (IHG), made of an elastic material as a monolith with the possibility of bending and containing the optical part and two diametrically located supporting elements made flat with a variable thickness, decreasing to the periphery, and bent to the front surface of the optical part at an angle of 25 ° to its main plane, the width of the support elements is equal to the diameter of the optical part, their ends are convex, while the diameter of the optical part is 6 mm, characterized in that in each support element the birth axis, at the same distance from the center of the ICH, a through hole of a circular shape with a diameter of 0.1 to 0.5 mm is made, the ratio of the distance between the points most distant from each other lying on opposite ends of the ends to the diameter of the optical part is 1, 5-2; and the rear surface of the optical part is provided with a protrusion with a height of 0.001 to 0.3 mm in the form of a cylinder whose diameter is equal to the diameter of the optical part, while the base of the protrusion follows the shape of the rear surface of the optical part. 2. The artificial lens of the eye according to claim 1, characterized in that the front surface of the optical part is concave, and the rear is convex. 3. The artificial lens of the eye according to claim 1, characterized in that the optical part is made in the form of a biconvex lens. 4. The artificial lens of the eye according to claim 1, characterized in that the front and / or rear surfaces of the optical part are made in the form of an aspherical surface. 5. The artificial lens of the eye according to claim 1, characterized in that the rear surface of the optical part is made with a constant radius of curvature of 6 mm 6. The artificial lens of the eye according to claim 1, characterized in that the front or rear surface of the optical part has a variable radius of curvature to correct corneal astigmatism. 7. The artificial lens of the eye according to claims 1-6, characterized in that the supporting elements are labeled for centering the IHG according to the strong corneal meridian.