RU2363424C1 - Accommodating intraocular lens - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to ophthalmosurgery. The accommodating intraocular lens has optical and support elements. The optical element is made in form of a first closed ellipsoidal elastic transparent polymer jacket, filled with transparent liquid. The jacket is symmetrical about the optical axis and can change is geometrical shape and can provide for reciprocating motion of the front surface of the optical element along the optical axis of the accommodating intraocular lens, as well as change of curvature of the peripheral area of the jacket in the space in front of the capsular sack. The support element is made in form of a second closed ellipsoidal elastic transparent polymer jacket, filled with transparent liquid. The jacket is symmetrical about the longitudinal axis of the support element, can change its shape inside the capsular sack and provides for reciprocal motion along the optical axis of the accommodating intraocular lens. The support and optical elements are joined together by an elastic channel and are made such that, the transparent liquid can flow from one jacket to the other.

EFFECT: improvement of accommodating properties, spatial distribution of local deformations of tissue of the capsular sack, reduction of the size of these deformations and reduction of permanent injury 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. Changing 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 medium .

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 distance and near vision, in addition, a gradual increase in the strength of the IHG 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 haptic elements of the IHG.

However, this IHG has significant drawbacks: it has insufficient accommodation, and in addition, it does not prevent the occurrence of local deformations in the ocular tissues.

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, with the inflection point of these arcs interacting 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: lack of accommodating properties, uneven pressure of the supporting elements on the tissue of the capsular bag, which causes their local deformations, and, therefore, significant irreversible deformation of the tissue of the capsular bag.

EFFECT: improved accommodation properties, improved spatial distribution of local deformations of capsular bag tissues, a decrease in the magnitude of these deformations, decreased irreversible trauma to capsular bag tissues, while expanding the potential of artificial eye lenses.

The technical result is achieved by the fact that in an accommodating artificial lens of the eye (AIHG) containing optical and supporting elements, the optical element is made in the form of a first closed ellipsoidal elastic light-transmitting polymer shell filled with light-transmitting liquid, while the shell is symmetrical about the optical axis and made with the possibility of changing its geometric shape and providing reciprocating motion of the front surface of the optical element along the optical axis A HCG, and changes the curvature of its peripheral areas in the space in front of the capsular bag; the supporting element is made in the form of a second closed ellipsoidal elastic light-transmitting polymer shell filled with light-transmitting fluid, the shell being symmetrical about the longitudinal axis of the supporting element and configured to change its shape in the space of the capsular bag and provide reciprocating motion along the optical axis of the AHI, and the supporting and the optical elements are interconnected by means of an elastic channel and configured to flow light transmitting Liquids from one shell to another.

The proposed set of distinctive features is necessary and sufficient for a clear positive achievement of the claimed technical result.

The proposed AIHG is characterized by a drawing.

The drawing shows a frontal section of the proposed AIHG.

The accommodating artificial eye lens contains an optical 1 and a support element 2. The optical element 1 is made in the form of a first closed ellipsoidal elastic light-transmitting polymer shell 3 filled with light-transmitting liquid 4.

The shell 3 of the optical element 1 is symmetric with respect to the optical axis 5 and is configured to change its geometric shape and provide reciprocating motion of the front surface 6 of the optical element 1 along the optical axis 5 of the AHI. There is a change in the curvature of the peripheral regions 7 of the shell 3 in the space in front of the capsular bag 8.

The curvature of the peripheral regions 7 increases, and the central part 9 of the optical element 1 becomes flatter, which also affects accommodation.

The supporting element 2 is made in the form of a second closed ellipsoidal elastic light-transmitting polymer shell 10.

The back of the shell 10 is congruent with the back surface 11 of the capsule bag 8 to provide a more complete interaction between them.

The shell 10 is filled with a light transmitting liquid 4.

The optical axis 5 coincides with the longitudinal axis of the support element.

The shell 10 is made with the possibility of changing its shape inside the space of the capsule bag 8 and providing reciprocating motion along the optical axis 5 of the AIHG. The shell 3 of the support element and the shell 10 of the optical element 2 are interconnected using an elastic channel and are configured to flow light-transmitting fluid from one shell to another.

The implementation of the support element in the form of a second closed ellipsoidal elastic light-transmitting polymer shell 10 filled with light-transmitting fluid 4 allows to improve the uniformity of the distribution of local deformations of the shell 10 on the inner surface of the tissue of the capsular bag 8, to reduce the magnitude of these deformations, to reduce irreversible injuries of the tissue of the capsular bag.

The implementation of the optical element 1 in the form of a first closed ellipsoidal elastic light-transmitting polymer shell 3 when it interacts with the outer tissue sections of the capsule bag 8 allows you to achieve the same claimed technical result.

In addition, a smooth change in the volume of the shell 3 by means of an elastic channel makes it possible to increase the smoothness of the regulation of the accommodating properties of AHIG in addition to the smooth provision of the reciprocating movement of the front surface 6 of the optical element 1.

IHG works as follows.

The support element 2 interacts with the area of attachment of the zinc ligaments.

When the ciliary muscle contracts to focus on objects located close by, the elastic shell 10 of the support element 2 is compressed, through the elastic channel, the light-transmitting fluid 4 flows into the elastic shell 3.

The front surface of the optical element 1 moves forward.

When the ciliary muscle is relaxed to focus distant objects, the light-transmitting liquid 4 flows through the elastic channel from the elastic membrane 3 into the elastic membrane 10.

Thus, the proposed AIHG invention allows to improve the accommodating properties of AIHG, to reduce trauma to the capsule bag tissue, to reduce the magnitude of these deformations, to reduce the irreversibility of trauma to the tissue of the capsular bag while expanding the potential of artificial eye lenses.

Claims (1)

An accommodating artificial lens of the eye (AIHG) containing optical and support elements, characterized in that the optical element is made in the form of a first closed ellipsoidal elastic light-transmitting polymer shell filled with light-transmitting liquid, while the shell is symmetrical about the optical axis and is configured to change its geometric shape and providing reciprocating motion of the front surface of the optical element along the optical axis of AHIG, as well as changes in curvature in the peripheral regions of the shell space in front of the capsular bag; the support element is made in the form of a second closed ellipsoidal elastic light-transmitting polymer shell filled with light-transmitting fluid, the shell being symmetrical about the longitudinal axis of the support element, configured to change its shape in the space of the capsular bag, and provide reciprocating motion along the optical axis of the AHI, supporting and optical elements are interconnected by means of an elastic channel and are made with the possibility of flowing light transmitting fluids from one shell to another.

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