RU2385692C1 - Intraocular lens - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: intraocular lens (IOL) comprises optical and reference elements. A back surface of the optical element represents a segment of a concave spherical surface, and a front surface of the optical element is curvilinear surfaces bent towards the back surface of the optical element with the continuous curvature having one central optical axis. A central surface of the front surface is a segment of a concave hyperbolic surface, and the relation of its diametre to the diametre of the optical element is within 0.2 to 0.3. The second piece of the front surface is a segment of a concave parabolic surface, and the relation of its diametre to the diametre of the optical element is in the range 0.3 to 0.5. The peripheral piece of the front surface of the optical element represents a segment of a third-order concave surface formed by rotation about the central optical axis of the curve matched with Chebyshev polynomial, and the relation of the diametre of this surface to the diametre of the optical element is in the range 0.3 to 0.4.

EFFECT: application of said IOL enables to improve acuity of daylight and night vision to an intact-eye level.

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Description

The invention relates to the field of ophthalmic surgery.

One of the problems of ophthalmic surgery is to ensure the correct (natural) correlation between the acuity of central vision and the magnitude of the central scotoma after ophthalmic surgery.

The relationship between the acuity of central vision and the magnitude of the central scotoma is shown in figure 1 (W. Happe. Ophthalmology. M .: Medicine, 2004, p. 49). The indicated dependences characterize the optical apparatus and the visual analyzer of the normal eye.

Known artificial lens of the eye (IHG) according to the patent of Russian Federation No. 2061432, consisting of an optical lens, support elements, pivotally mounted and located along the perimeter of the optical lens and oriented with free ends from the edge to its center, while at the ends of the support elements adjacent to the Central part optical lens, holes are made for fixing to the iris along the edge of the pupil, and recesses are made in the optical lens at the locations of the supporting elements.

However, this IHG has a significant drawback: it does not provide the correct ratio between the acuity of central vision and the magnitude of the central scotoma after ophthalmic surgery.

The technical result of the invention is to increase the severity of photopic and scotopic vision to the level of an intact eye.

The technical result is achieved by the fact that in the artificial lens of the eye containing the optical and supporting elements, the rear surface of the optical element is made in the form of a segment of a concave spherical surface, and the front surface of the optical element is made in the form of curved surfaces with continuous curvature concave towards the rear surface of the optical element, having one central optical axis, the central surface of the front surface is made in the form of a segment of concave hyperbolic rotation hi, the ratio of its diameter to the diameter of the optical element lies in the range from 0.2 to 0.3, the second part of the front surface is made in the form of a segment of a concave parabolic surface, and the ratio of its diameter to the diameter of the optical element lies in the range from 0.3 to 0.5, the peripheral part of the front surface of the optical element is made in the form of a segment of a concave surface of the third order formed by rotation around the central optical axis of the curve corresponding to the Chebyshev polynomial, and the ratio of the diameter of this the surface to the diameter of the optical element lies in the range from 0.3 to 0.4.

By a curve corresponding to a third-order Chebyshev polynomial is meant a third-order polynomial from the Chebyshev polynomial system (Mathematical Encyclopedia. M., 1990, v. 2, p. 869).

The system of essential distinguishing features proposed by the authors is necessary and sufficient for an unambiguous positive solution of the stated technical problem - increasing the acuity of photopic and scotopic vision to an intact level.

The claimed IHG is illustrated by drawings: figure 1-2.

Figure 1 - curves of the relationship between the acuity of central vision and the magnitude of the central scotoma in the human eye.

Figure 2 - frontal section of the IHG.

In figure 1 is indicated: 1 - axis of visual acuity, in angular minutes; 2 - angular values measured from the Central fossa 3; 4 - nasal region; temporal region 5; 6 - photopic vision curve; 7 - scotopic vision curve; 8 - maximum curve 6.

The indicated dependences characterize the optical apparatus and the visual analyzer of the normal eye, which was taken as a criterion for the design of the IHG: the proposed design of the IHG in combination with other elements of the optical system of the eye gives similar characteristics of optical visual acuity as in strong light (curve 6) and a narrow pupil, and in low light (curve 7) and a wide pupil.

Figure 2 indicates: 9 - the rear surface of the optical element, 10 - the Central surface of the front surface of the IHG, 11 - the second part of the front surface of the IHG, 12 - the peripheral part of the front surface of the IHG, 13 - the supporting element.

The artificial lens of the eye contains optical and reference elements. The rear surface of the optical element is made in the form of a segment of a concave spherical surface. The front surface of the optical element is made in the form of curved surfaces with a continuous curvature, concave toward the rear surface of the optical element, having one central optical axis. The central surface 10 of the front surface is made in the form of a segment of a concave hyperbolic surface, and the ratio of its diameter to the diameter of the optical element lies in the range from 0.2 to 0.3. The second part 11 of the front surface is made in the form of a segment of a concave parabolic surface, and the ratio of its diameter to the diameter of the optical element lies in the range from 0.3 to 0.5. The peripheral part 12 of the front surface of the optical element is made in the form of a segment of a concave surface of the third order formed by rotation around the central optical axis of the curve corresponding to the Chebyshev polynomial, and the ratio of the diameter of this surface to the diameter of the optical element lies in the range from 0.3 to 0.4.

Optical visual acuity with the proposed design of the IHG corresponds to the complex curves of figure 1 due to the coordination of the parameters of the three surfaces 10, 11, 12 from the center to the periphery of the optical element of the IHG (figure 2). Ensures both the correspondence of curve 6 of figure 1 with high illumination and a narrow pupil, and curve 7 of figure 1 with low illumination and a wide pupil.

The proposed IHG allows for a natural relationship between the acuity of central vision and the magnitude of the central scotoma.

IHG is implanted under local anesthesia. Capsulorexis is performed, phacoemulsification of the lens is performed, and lens masses are removed. IHG is introduced into the capsule bag.

Using IHG allows you to achieve the claimed technical result - to increase the severity of photopic and scotopic vision to the level of an intact eye.

Claims (1)

An artificial lens of the eye containing optical and supporting elements, characterized in that the rear surface of the optical element is made in the form of a segment of a concave spherical surface, and the front surface of the optical element is made in the form of concave curved surfaces with continuous curvature towards the rear surface of the optical element, having one the Central optical axis, the Central surface of the front surface is made in the form of a segment of a concave hyperbolic surface, and the ratio its diameter to the diameter of the optical element lies in the range from 0.2 to 0.3, the second part of the front surface is made in the form of a segment of a concave parabolic surface, and the ratio of its diameter to the diameter of the optical element lies in the range from 0.3 to 0.5, the peripheral part of the front surface of the optical element is made in the form of a segment of a concave surface of the third order formed by rotation around the central optical axis of the curve corresponding to the Chebyshev polynomial, and the ratio of the diameter of this surface to the diameter of the optical element ranges from 0.3 to 0.4.

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