DE4129668A1 - Corrective cataract lens for intact natural eye lens - has optical body with adjustment and support elements produced in one piece - Google Patents

Abstract

The corrective lens (1) has an optical body (2) which on the eye lens side has a concave surface (3) with a curvature corresp. to the outer surface of the eye lens (9). It has an adjustment element (5) which surrounds the optical body, and of which the eye lens-side surface has the same curvature as the concave surface of the optical body. It also has a support element which is formed in one peice with the ajdustment element (5). The support element is thinner than that for adjustment, and the distance between diametrically opposed sections of the support element is at least equal to the distance between counterposed sections of the fibrae zonulares emerging from the ciliary body (10). USE - For the treatment of myopia, hypermetropia, astigmatism and other eye affections.

Description

The invention relates to a correction star glass for a intact natural eye lens with an optical body, a concave surface with a curvature on the eye lens side mung has that of the outer surface of the eye lens corresponds, with an adjusting element that the optical Surrounds body and the surface of the lens on the eye lens same curvature as the concave surface of the optical body pers, and with a support element.

Such correction star glasses are successful at Treatment of myopia (myopia), hypermetropia (Farsightedness), astigmatism and other eyes diseases used.

Usually, to correct eyesight, such as of nearsightedness or farsightedness, glasses or Contact lenses used. The correction achieved with this is only temporarily, because glasses or contact lenses in one sports, such as swimming, do not stop or can remain deployed.

With the help of keratomy a permanent correction of the Eyesight achieved, on the one hand by removing a corneal layer or by changing the shape of the cornea  or by a plurality of radial incisions in the horn skin that heals according to the curvature Cuts changes. This correction is irreversible and with regard to a refraction to be predicted effect insufficiently accurate.

The use of star glasses or is also known artificial eye lenses for correcting aphakia (absence the lens) if a cataract has been removed.

US-A-45 85 456 describes a generic correction star glass, which in combination with an intact natural Lichen eye lens is used. The optical body of the Correction glass consists of one with the eye tissue compatible material. The position fixing of the correc tion glass support elements are used with the Setting element connected open wire loops, like them also in connection with the fixation of artificial eyes lenses are used.

When positioning such a known correction Star glasses in a patient's eye become the support elements arranged in a ciliary groove, causing inflammation of the Eye tissue. Furthermore, in this type of Positioning a slight to strong dislocation of the Star glasses possible.

The object underlying the invention now exists in it, with the correction star glass of the generic type to execute the support element so that with extensive Exclusion of postoperative complications from a disloka tion of the correction star lens practically impossible is.  

This task is based on the correction star glass of the generic type solved in that the Stützele ment and the adjusting element formed as one piece are that the support element is thinner than the setting element and that the distance between diametrically opposite lying sections of the support element at least the same the distance between opposite sections of so-called tin ribbons, including those from the ciliary body outgoing fibrae zonulares are to be understood.

In the correction star glass designed according to the invention will interact with sensitive sections of the Excluded eye tissue, increasing the risk of postopera inflammation caused by contact of the support element in the Eye tissue is excluded. The so-called tin tapes have quite a high strength to the support element and thus also the entire correction star glass in the case of to fix the position given in the operation a very precise alignment with respect to the optical axes of the optical body and the natural eye lens is aimed.

That the support element is thinner than the adjusting element is achieved by reducing the strength, namely in that the support element on its outer Corneal surface along concave surface lines rejuvenated.

The support element can be made of an annular, ver recent extension of the setting element or can of four symmetrical and diametrical to each other in pairs opposite local approaches are formed. These Approaches enable the dimensions of the correction To keep star glasses a little lower. The adjustment element  has two parallel sides in this version, which on the Ends connected by curved arches are at their intersections with the parallel sides the lugs forming the support elements are provided that they are over the circular arc sections, but not over the sides stick out.

The surface of the lens on the eye lens expediently has optical body has a radius of curvature of about 9 to 11 mm. The distance between the diametrically opposite Sections of the support element is approximately 11.5 mm to 12 mm.

An embodiment of the Invention explained in more detail. It shows:

Fig. 1 shows a first embodiment of the Corrections-Star glass in section II of Fig. 3,

Fig. 2 shows a second embodiment of the Corrections-Star glass in plan view,

Fig. 3 is a plan view of the first embodiment of the Corrections-Star glass,

Fig. 4 as a detail in section like Fig. 1, the Ausgestal device of the support element and

Fig. 5 shows a section through an eye with an ordered correction star glass therein.

The Corrections-Star glass 1 shown in Fig. 1 has a body 2 having a biconcave optical surface, namely, an ophthalmic lens-side surface 3 and a surface 4 hornhautseiti gen. The surface 3 on which the outer surface of the eye lens 9 ( FIG. 5) comes to rest has a radius of curvature R which corresponds to that of the outer surface of the eye lens 9 . The radius of curvature R of the surface 3 on the eye lens side is approximately 9 mm to approximately 11 mm. The diameter of the optical body 2 is usually about 4 mm to about 6 mm.

The optical body 2 is surrounded on its entire circumference by an adjusting element 5 . The setting element 5 has a concave surface 6 on the eye lens side with a radius of curvature which corresponds to the radius of curvature R of the surface 3 of the optical body 2 on the eye lens side, the surfaces 3 and 6 merging into one another. With this configuration, the optical body 2 can be precisely aligned on the outer surface of the intact natural eye lens 9 with respect to its optical axis. The diameter D _{2 of} the setting element 5 is approximately 10.0 mm to approximately 10.5 mm.

The adjusting element 5 also has a support element 7 ( Fig. 1, Fig. 2) or 7 '' a and 7 '' b ( Fig. 3), which is formed with it in one piece or monolithically and various can be designed what will be explained later.

The correction star glass, consisting of the optical body 2 , the adjusting element 5 and the support element 7 or 7 '' a, 7 '' b can be produced by casting a material into a mold, for example a material such as polymethyl methacrylate, silicone rubber, Polyhydroethyl methacrylate, silicone-methyl metacrylate copolymer, polyvinylpyrrolidone and the like, that is to say from materials which are compatible with the tissue and the liquid medium of the eye and are preferably hydrophilic and / or oxygen-permeable.

In the embodiment shown in FIG. 2, the support element 7 is designed in a ring shape, that is to say it surrounds the adjustment element 5, which is circular in plan view, on its entire outer peripheral surface.

In the embodiment of FIG. 3, the setting element 5 has two opposite parallel straight sides, each of which is connected by two opposite circular arc sections. The support element is formed by two pairs of diametrically opposed approaches 7 '' a and 7 '' b, which are provided at the intersections of the parallel sides and the circular arc sections of the adjusting element 5 , the approaches 7 '' a and 7 '' b superior portions of the setting element 5 is limited by the parallel sides of the adjustment member. 5

In each of these configurations, the thickness h of the support element 7 is reduced compared to the thickness H of the adjusting element 5 . For example, if the thickness H of the adjusting element 5 is 0.1 mm, the thickness h of the support element 7 on the outer circumferential surface is 0.01 to 0.05 mm. In order to avoid injury to the eye tissue, the support element 7 must not have any sharp edges, therefore the thickness reduction runs along a curvilinear or concave surface line on the cornea-side surface of the support element 7 . The eye lens side surface of the Stützel element 7 has the same radius of curvature R as the eye lens side surface 3 of the optical body 2 , which also applies to the design with the approaches 7 '' a and 7 '' b. The distance D ₃ between the diametrically opposite ends of the support element 7 or the lugs 7 '' a and 7 '' b must not be less than the diametrical distance between the fibrous zonulares emanating from the ciliary body, which as the tin strips 10 ( Fig. 5), this distance being between approximately 11.5 and approximately 12.0 mm.

For insertion of the correction star glass 1 , the cornea or the circular corneal edge is cut, whereby a slot leading into the anterior chamber 8 of FIG. 5 is formed. The correction star glass 1 is inserted with tweezers over the area of a previously dilated pupil first in the position "6 o'clock" and then "12 o'clock" in the rear eye chamber. Then the correction star lens 1 is positioned by moving the eye lens side surface 6 of the adjusting element 5 over the outer surface of the intact eye lens 9 until the position is reached in which the optical axes of the optical body and the eye lens 9 match, whereby the optical body 2 bears on the outer surface of the eye lens 9 and the support element 7 and the approaches 7 '' a and 7 '' b in the network of the fibular zonular or the tin strips 10 are held. Then the cuts are sewn.

Depending on the optical requirements, a concave-convex or toroidal configuration can be used instead of the biconcave configuration of the optical body 2 .

Claims (7)

1. correction star glass ( 1 ) for an intact natural eye lens ( 9 )

• - With an optical body ( 2 ) having a concave surface ( 3 ) with a curvature (R) on the eye lens side, which speaks ent of the outer surface of the eye lens ( 9 ),
• - With an adjusting element ( 5 ) which surrounds the optical body ( 2 ) and whose eye lens side surface ( 6 ) has the same curvature (R) as the concave surface ( 3 ) of the optical body ( 2 ) and
• - With a support element ( 7 ; 7 '' a, 7 '' b),

characterized,

• - That the support element ( 7 , 7 '' a, 7 '' b) and the adjusting element ( 5 ) are formed as one piece,
• - That the support element ( 7 , 7 '' a, 7 '' b) is thinner than the adjusting element ( 5 ) and
• - That the distance between diametrically opposite sections of the support element ( 7 , 7 '' a, 7 '' b) is at least the same as the distance between opposite sections of the fibrous outgoing from the ciliary body zonulares (tin strips 10 ).

2. correction star glass according to claim 1, characterized in that the eye lens side surface ( 3 ) of the optical body ( 2 ) has a radius of curvature (R) of about 9 to about 11 mm. 3. correction star glass according to claim 1 or 2, characterized in that the distance between the diametrically opposite sections of the support zelements ( 7 , 7 '' a, 7 '' b) is about 11.5 to about 12 mm. 4. correction star glass according to any one of the preceding claims, characterized in that the support element ( 7 ) is annular. 5. correction star glass according to one of claims 1 to 3, characterized in that the supporting element of at least four approaches ( 7 '' a, 7 '' b) is formed, which are arranged in pairs opposite to each other. 6. correction star lens according to claim 5, characterized in that the adjusting element ( 5 ) has two opposite parallel sides and two opposing outwardly curved circular arc sections as a border, the reduced in thickness, the supporting element forming approaches ( 7 ''A, 7 ''b) at the intersection of the parallel sides with the circular arc sections beyond this, but not beyond the sides.