RU2363423C1 - Accommodating intraocular lens - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: intraocular lens includes optical and support elements. The support elements are composite. The first support element is made in form of a closed ellipsoidal elastic transparent polymer jacket, congruent to the inner surface of the capsular sack and filled with transparent liquid. The first support element can change its geometrical shape and provides for reciprocal motion along the transverse axis of symmetry, which coincides with the central optical axis of the optical element. The surface of the first support element has, on its side facing the capsulorhexis zone, not less than three rectangular stop lugs, located at equal angular distance from each other and each made in form of a rectangular plate, bent at a right angle. The second support element is made in form of an elliptical segment, arched congruently to the outer surface of the first support element and is provided with not less than three lugs, situated at equal angular distance from each other. The second support element can interact with the stop lugs of the first support element and is joined to an elastic optical element, which can execute reciprocal motion along the transverse axis of symmetry together with the second support element.

EFFECT: improvement of accommodating properties, reduction of local deformations of tissue of the capsular sack.

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Description

The invention relates to medicine, and more particularly to ophthalmic surgery.

Known artificial lens of the eye (IHG), consisting of many optical layers with different refractive indices, US patent No. 4731078, 1988. The change in the optical power of the IHG is achieved either by changing the refractive index of one of the liquid layers, or by changing the curvature of the surface of the layer adjacent to the liquid Wednesday.

The change in the refractive index of one of the liquid layers of the lens can be controlled by the strength of the electromagnetic field. Changing the optical power of the IHG can provide vision in the distance and near, in addition, a gradual increase in the strength of the IOL for clear vision along the entire length from far to near objects is possible.

The change in the strength of the ICH can be carried out due to the energy of the piezoelectric material. The latter can be mounted in the optical elements of the IHG.

However, this IHG has significant drawbacks: it has insufficient accommodation, and, in addition, it does not allow a metered change in optical power.

Known IHG US patent No. 4790847, 1988

IHG contains an optical part and two diametrically located supporting elements.

The optical part is made in the form of a flat-convex optical part, touching from the inside the inner part of the front surface of the capsule bag.

The supporting elements are made in the form of curved "V" -shaped arcs, and the inflection point of these arcs interacts with the inner surface of the capsular bag, with one end of this arc fixed to the center of the rear surface of the optical part, and the other freely located in the space of the capsular bag. Supporting elements interact with the area of attachment of the zinc cords and allow the optical part to move forward while contracting the ciliary muscle to focus objects near the eye, and back when the muscle relaxes to focus distant objects.

However, this IHG has significant drawbacks; it has rather high local deformations of the capsule bag tissues due to the interaction with the inflection point “V” of the shaped curved arc of each of the supporting elements and does not allow a change in the optical power in a dosed manner.

The technical result of the invention: improving accommodating properties, reducing local deformation of the tissues of the capsular bag, dosed change in the optical power of the ICH.

The technical result is achieved in that in the accommodating artificial lens of the eye containing the optical and supporting elements, according to the invention, the supporting elements are made integral, the first supporting element is made in the form of a closed ellipsoidal elastic light-transmitting polymer shell, a congruent inner surface of the capsular bag and filled with light-transmitting liquid, while the first supporting element is configured to change the geometric shape and provide reciprocating about the movement along the transverse axis of symmetry, coinciding with the Central optical axis of the optical element; the surface of the first support element contains on the side facing the capsulorexis zone at least three rectangular support protrusions, each made in the form of a rectangular plate bent at right angles, the side of the support protrusion attached to the surface of the first support element is perpendicular to the longitudinal axis of symmetry of the first support element , the other side of the protrusion is facing inward and toward the central optical axis, while the supporting protrusions are equally located on the surface of the first supporting element m angular distance from each other; the second support element is made in the form of a curved congruent outer surface of the first support element of the elliptical segment and is equipped with at least three protrusions located at the same angular distance from each other, while the second support element is configured to interact with the support protrusions of the first support element and is connected to an elastic optical element configured to reciprocate along the transverse axis of symmetry together with the second supporting element.

IHG is illustrated by drawings.

Figure 1 - frontal section of the first supporting element.

Figure 2 is a view along arrow A.

Figure 3 is a side view of the second support element.

Figure 4 - frontal section of the IHG.

IHG is as follows.

The accommodating artificial eye lens contains optical and reference elements.

The supporting elements are made integral. The first supporting element 1 is made in the form (Fig. 1) of a closed ellipsoidal elastic light-transmitting polymer shell congruent to the inner surface of the capsule bag. It is filled with light-transmitting liquid 2. The first support element 1 is configured to change the geometric shape and provide reciprocating motion along the transverse axis of symmetry 3, coinciding with the Central optical axis of the optical element.

The surface of the first support element 1 comprises, on the side facing the capsulorexis zone, at least three rectangular support projections 4, each made in the form of a rectangular plate bent at a right angle. The side of the support protrusion attached to the surface of the first support element 1 is perpendicular to the longitudinal axis of symmetry 5 of the first support element 1, the other side of the protrusion 4 is turned inward towards the transverse axis 3, while the support protrusions 4 are located on the surface of the first support element 1 at the same angular distance apart the second support element 6 is made in the form of a curved congruent outer surface of the first support element 1 of the elliptical segment and is equipped with at least three protrusions located at the same angular distance from each other. The supporting element 6 is made with the possibility of rotation relative to the transverse axis 3 and interact with the supporting protrusions 4 of the first supporting element 1.

The second support element 6 rotates around the axis 3 and extends with its protrusions beyond the support protrusions 4 and is thus fixed on the surface of the support element 1.

The second supporting element 6 is connected with an elastic optical element 7 located on the front surface of the capsule bag 8 and configured to reciprocate along the transverse axis of symmetry 3 together with the second supporting element 6.

To remove the optical element 7, the second support element 6 is rotated relative to the optical axis 3 and disengaged from the support projections 4. The complete assembly is shown in FIG. 4.

IHG works as follows.

Light rays pass through the capsulorexis zone to the optical element 7. Then, through the second support element 6 and the first support element 1, light rays enter the back surface of the capsular bag 8 and then onto the retina.

The action of the ciliary muscles is transmitted to the surface of the capsular bag 8 and through it to the supporting element 1. When the ciliary muscles are compressed (not shown), the surface of the first supporting element 1 is compressed and together with the second supporting element 6 and the optical element 7 moves towards capsulorhexis.

If the ciliary muscles relax, the reverse movement of the optical element occurs. Thus, under the action of the ciliary muscles, the geometric shape of the shell of the supporting element 1 changes, which ensures the reciprocating movement of the shell 1 along the axis 3 and the second supporting element 6 and the optical element 7 connected to it.

This ensures the effect of accommodation IHG. The design of the support element 1 provides for a decrease in pressure on the internal tissues of the capsular bag and, as a consequence, a decrease in deformations.

The removable design of the second support element 6 and the optical element 7 connected to it provides for the possibility of a metered change in the optical power of the IHG by replacing one block (second supporting element 6 with the optical element 7) by another. IHG is implanted as follows.

Through the zone of capsulorexis, the first support element 1 is initially implanted, then the second support element 6 and the associated optical element 7. In this case, the optical element 7 is installed in the area of the front surface of the capsular bag 8.

EFFECT: invention allows improving accommodating properties, reducing local deformations of capsular bag tissues, and achieving a metered change in the optical power of ICH.

Claims (1)

An accommodating artificial eye lens containing optical and supporting elements, characterized in that the supporting elements are made integral, the first supporting element is made in the form of a closed ellipsoidal elastic light-transmitting polymer shell, a congruent inner surface of the capsular bag, and filled with light-transmitting liquid, while the first supporting element is made with the possibility of changing the geometric shape and providing reciprocating motion along the transverse axis of symmetry, with incident with the central optical axis of the optical element, the surface of the first support element contains on the side facing the capsulorexis zone at least three rectangular support protrusions, each made in the form of a rectangular plate bent at right angles, the side of the support protrusion attached to the surface of the first support element is perpendicular to the longitudinal axis of symmetry of the first support element, the other side of the protrusion faces inward and toward the transverse axis of symmetry, while the support protrusions are located married on the surface of the first support element at the same angular distance from each other; the second support element is made in the form of a curved congruent outer surface of the first support element of the elliptical segment and is equipped with at least three protrusions located at the same angular distance from each other, while the second support element is configured to interact with the support protrusions of the first support element and is connected to an elastic optical element configured to reciprocate along the transverse axis of symmetry together with the second supporting element.

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