DE3928226A1 - Human eye implant lens - has integral fixing loops ensuring min. tension when inserted - Google Patents

Abstract

An intraocular lens, e.g. 7.0 mm in dia. and made of high-polymer polymethylmecacrylate, is affixed in the cavity of a human eye by two flexibly mobile loops (2,3) integral with the lens body (11). The entire length of the loops lies on an equatorial circle in the eye cavity. The loops start tangentially from a common point and extend in opposite peripheral directions. Prior to implantation, the loops engage the lens body in a shape like tulip petals. In the same non-implanted state, the centre points of the arcuate loops form an equilateral triangle with the lens centre point. Loops, which may form two arms of a simple loops, are increasingly spaced from the lens body towards their free ends. ADVANTAGE - Lens is implanted with min. stress, largely reproducing conditions for natural lens.

Description

The invention relates to an intraocular posterior chamber lens for an implantation in the capsular bag of a human Eye according to the preamble of claim 1.

In the known intraocular lenses, in particular rear chamber lenses, with the help of fixation loops The lens fixed in the eye becomes intraocular Implantation of the capsular bag of the eye in the equatorial Badly deformed area. This is because the current known intraocular lenses with regard to their total through the anatomical conditions of the capsule sackes, but those of the sulcus ciliaris (the transition Iris to the ciliary body) are adapted. So it happens strong, oval expansion of the capsular bag, what once there is a risk that the loops of the intraocular lens pierce the capsular bag and get into the ciliary drill body and thus lead to severe irritation on the other hand, the lens can come from the capsular bag be pushed out, resulting in a reduction in optical Lens performance and often an explantation the lens is necessary. You can also open the front Capsule leaves due to the increased pressure or the excessive Pull the intraocular lens tension backwards so that there is no longer any mechanical barrier to proliferation of cells in the equatorial area and thus ver more post-star education is recorded.

The object of the invention is therefore an intraocular Posterior chamber lens for an implantation in a capsular bag  human eye to create the tension-free capsule bag can be implanted and thus the physiological Ratios closest to the natural eye lens.

This object is achieved by the features of Claim 1 solved. Advantageously, the invention create a lens that has a lens body with a large cross-sectional area that is stress-free in the Capsular bag is fixable. Advantageously, the Lens be designed so that on the circular optical Lens body, consisting of one piece with the lens body, two roughly circular arcs, in opposite order fixation loops in one direction joint molding point on the lens body tangentially are shaped, the distance of each fixation loop from The scope of the lens body extends from the molding site to enlarged to the free end of the fixation loop, so that in the two fixation loops when not implanted enclose the lens body approximately tulip-shaped.

In particular, the arc-shaped fixation loops the equator of the capsular bag, in which the lens implan is adjusted. Above all, it is fictional according to the intraocular lens possible, during implantation the External circumference of the fixation loops on the circumference of the opti rule lens body, which is preferably about 7 mm, ver wrestle so that you can with a relatively small dimension Opening that comes for the implantation of the lens at the The front of the capsular bag should be provided. After insertion The fixation loops take the lens into the capsular bag return to their original position and adapt thereby at the equator of the capsular bag. Then you lie over their entire circumferential area at the equator of the capsular bag  stress-free. Bulges in the equatorial area of the capsule sacks are avoided. Because the opening in the front side of the capsular bag can be relatively small, be there is also no risk of the lens falling out of the Capsular bag. One achieves the despite the radial clamping Fixation loops a tension-free implantation of the Lens in the capsular bag because of the outer circumference of the fixations loops adapts to the equator of the capsular bag.

Based on the attached figures, an execution example, the invention explained in more detail. It shows:

Figure 1 is a plan view of a first embodiment of the invention. and

Fig. 2 is a plan view of a second embodiment of the invention.

The exemplary embodiments of intraocular posterior chamber lenses shown in FIGS . 1 and 2 each have a circular lens body 1 as an optical part. In the exemplary embodiments presented, the lens body 1 is biconvex and can have an apex refractive index of up to approximately 25.00 dpt. It is of course also possible to make the lens body 1 thinner for lower peak powers, for example 10.0 dpt. The diameter of the lens body 1 is preferably 7.0 mm. However, in particular in the embodiment shown in FIG. 1 it can be up to approximately 8 mm.

Any eye-compatible material is suitable as lens body material Material. High-polymer polymethyl methacrylate is preferred for use. The lens body material can e.g. B. by a polymerize with a UV absorber.  

In a lying on the circumference of the lens body joint formation 4 tangentially two circular arc-shaped fixation loops 2 and 3 are integrally formed on the lens body 1 . The fixation loops 2 , 3 extend around the circumference of the lens body 1 in opposite directions and surround the lens body 1 tulip-shaped in the unimplanted state. Free ends 6 and 7 of the two fixation loops have a greater distance from the circumference of the lens body 1 than at the molding point 4th In the implanted state, the fixation loops 2 and 3 assume dash-dotted positions shown in FIGS . 1 and 2. They then form a closed circle on their outer circumference, which corresponds to the equator of the capsular bag. In the non-implanted state, the outer circumferences of the two fixation loops 2 and 3 run on a circular arc, the center points m 1 and m 2 of which form an isosceles triangle with the center M of the circumference of the lens body 1 . In the implanted state (dash-dotted line), the center points m 1 and m 2 coincide with the center point M of the lens body 1 , ie the fixation loops lie on a circle concentric with the circumference of the lens body 1 .

While the fixation loops 2 and 3 are formed by two simple fixation threads in the embodiment shown in FIG. 1, the haptic in the embodiment shown in FIG. 2 is a self-contained double loop 5 to which the fixation loops 2 and 3 are connected. Here, too, the double loop encompasses the entire circumference of the lens body 1 , the distance between the free ends 6 and 7 from the circumference of the lens body 1 being greater in the non-implanted state than at the shaping point 4 . In the implanted state (dash-dotted line), the double loops of the fixation loops 2 and 3 lie on circles 1 concentric with the center M of the lens body. In the non-implanted state, the fixation loops lie in a tulip shape on circles, the center points m 1 and m 2 of which form an isosceles triangle with the center point M of the lens body 1 . In the implanted state, the double loops of the haptic (dash-dotted position) also lie on circles around the center M of the lens body 1 . Here too, the fixation loops 2 and 3 lie on a circle which is adapted to the equator of the capsular bag.

The two fixation loops 2 and 3 lie in the implanted state on a circle around the lens body axis or the center point M lying thereon. This circle has a diameter of approximately 9.5 mm to 11.5 mm. This water diameter is preferably dimensioned at 10.0 mm. The thread thickness be about 1.5 mm in the embodiment.

The distance between the respective fixation loops 2 and 3 in the area of the shaping point 4 compared to the peripheral part of the lens body 1 present there is shorter than the distance between the free ends 6 and 7 of the fixation loops 2 and 3 compared to the one there Have peripheral area of the lens body 1 . The distance between the respective fixation loops in the area of the shaping point 4 or 5 in the exemplary embodiment is approximately 0.5 mm to 0.6 mm and the distance in the area of the free ends 6 and 7 is in the exemplary embodiment in the unimplanted state was more than double to three times the distance in the area of the molding point. In this way, the tulip-like shape of the haptic is achieved in the non-implanted state, the two free ends 6 and 7 being directed towards one another.

In the exemplary embodiments shown in the figures, the fixation loops are elastically deformable, so that the overall diameter of the lens can be reduced to that of the lens body 1 . During the radial clamping of the fixation loops, they attach to the equator of the capsular bag without tension, since, as explained above, the fixation loops are molded onto the lens body 1 in such a way that their outer circumference corresponds to the equator of the capsular bag. In this way, a perfect fixation without bulges and pressure points is achieved.

Claims (9)

1. Intraocular posterior chamber lens for an implantation in the human eye with an optical lens body and a haptic provided in the form of two elastically deformable fixation loops on this lens body for fixing the lens in the eye, the fixation loops consisting of one piece with the lens body being flexible on the latter are movably formed and, in the implanted state, essentially the entire outer circumference of each fixation loop, beginning at a respective shaping point until the end of the fixation loop lies on a circle corresponding to the equator of the eye capsule bag according to P 39 27 360.1, characterized in that the two fixation loops ( 2 , 3 ) are integrally formed tangentially on the lens body ( 1 ) in a common shaping point ( 4 ) and extend in opposite circumferential directions and surround the lens body ( 1 ) in a tulip-shaped manner in the non-implanted state. 2. Intraocular posterior chamber lens according to claim 1, characterized in that the distance of each fixation loop ( 2 , 3 ) from the circumference of the lens body ( 1 ) from its formation point ( 4 ) to the free end ( 6 , 7 ) increases ver. 3. intraocular posterior chamber lens according to claim 1 or 2, characterized in that the fixation loops ( 2 , 3 ) have the shape of arcs, the centers (m 1 and m 2 ) with the center (M) of the lens body ( 1 ) in the non-implanted state Form corners of an isosceles triangle. 4. intraocular posterior chamber lens according to one of claims 1 to 3, characterized in that the two fixation loops ( 2 , 3 ) are formed by a self-contained double loop ( 5 ). 5. Intraocular posterior chamber lens according to one of claims 1 to 4, characterized in that the diameter of the lens body ( 1 ) is approximately 7.0 mm. 6. Intraocular posterior chamber lens according to one of the claims 1 to 5, characterized in that the lens body material is high polymer polymethyl methacrylate. 7. Intraocular posterior chamber lens according to one of the claims 1 to 6, characterized in that the lens material has a UV absorber. 8. Intraocular posterior chamber lens according to one of claims 1 to 7, characterized in that the lens body ( 1 ) is biconvex. 9. Intraocular posterior chamber lens according to one of claims 1 to 8, characterized in that the fixation loops ( 2 , 3 ) are deformable in such a way that their entire circumference lies on a circle with a diameter of about 10 mm.