DE3116270A1 - EYE IMPLANT - Google Patents

Description

description

The invention relates to an eye implant according to the preamble of the main claim.

Patients undergoing eye surgery due to cataracts have to undergo, are often fitted with lens implants. Such lenses as well as theirs Insertion techniques are described in a 1976 article by the inventor of this application entitled "A Lens For All Seasons ". Further developments of such lenses come from Dr. Peter Choyce, from the inventor as well as from other researchers. These implants have made a major breakthrough, so they are already many hundreds of lens implants are inserted. In the known techniques, the lens is in the introduced anterior chamber. The attachment is made, for example, by four point-shaped contacts, formed by feet protruding from the lens.

However, it has occasionally been found to be useful to insert an implant into the posterior chamber of the eye if an extra capsular operation is to be removed

the lens of the eye was made, the posterior cap-

however remained intact.

It is an object of the invention to provide one for insertion into the posterior chamber of the eye to create a suitable lens that exerts minimal tissue pressure and is both light can be centered and precisely determined. In addition, the lens to be created should go through without difficulty the pupil can be used.

An eye implant according to the characteristics of the main claim is used to solve this problem. The implant or the lens has a lens body which is sized to fit through the pupil. It extends one leg extends radially outward from the edge of the lens and ends in a curved edge portion that is relative of the leg end is attached in the middle. The curved edge section lies in one that runs behind the lens Level. On the side of the lens opposite the leg is a thin, flexible web in the form of a attached open hook on the edge of the lens, which has a curved portion at its free end and which lies in the same plane as the edge portion. In this way, the edge portion and the Hook portion can be accommodated in opposite parts of the ciliary sulcus to relate the lens body

aligned with the pupil.

The invention is explained in more detail below with reference to figures; show it:
5

Figure 1 is a front view of an embodiment

for a posterior chamber of the eye;
FIG. 2 an inserted into the posterior chamber of the eye

Lens according to Figure 1;
"Ό Figure 3 is a front view of a development of the

Lens according to Figure 1;
Figure 4 is a front view of a further embodiment

the lens according to FIG. 1.

"15 Figure 1 shows a lens 10 to be inserted into an eye, The lens 10 has a plano-convex lens body 12 which, in its 6-Uhi position, is essentially has molded rigid leg 14. The leg 14 extends from an edge of the lens body 12 in the direction

* 0 of the diameter. At the end of the leg 14, opposite the lens body 12, a curved edge section 16 is formed centrally. The edge portion 16 is about 6 to 8 mm long and has essentially the same thickness and width as the leg 14,. Namely about 1.2 mm. The edge portion 16 lies in a plane that is perpendicular to

an axis 10a running through the lens 10 and the leg 14 and has a curved outer surface 16a, which is rounded and smoothed at the corners in order over its entire length in the sulcus ciliaris of the with of the lens 10 to be fitted posterior chamber to rest.

A flexible one is attached to the lens body 12 of the lens 10 Support web 18 formed on or attached to it. The bridge -ΙΟ 18 is formed according to US Pat. No. 4,159,546, for example. The support web 18 is arranged such that it touches the ciliary sulcus in the 12 o'clock position, wherein its attachment to the lens body 12 approximately in the 3 o'clock position is provided.

In an expedient embodiment, the lens body 12 has a diameter of approximately 4 to 6 mm. The length of the tendon the edge portion 16 is about 6 to 8 mm; the same measure also applies to the diameter of the Bay end of the support web 18. The radius of the outer surface 16a of the edge portion 16 is measured from Center of the lens body 12 on the order of about 6 to 7 mm, the same dimension for the The distance between the web 18 and the center point of the lens body 12, measured along the axis 10a, is as follows

that the distance from the web 18 to the outer surface 16a of the Edge 16 corresponds approximately to the diameter of the posterior chamber of an eye.

The lens 10 shown in Figure 1 can be fastened in such a way that no rotation of the lens body 12 in the Eye of a patient is done. Already known lens implants for the posterior chamber, for example the lens according to US Pat. No. 4,159,546, or lenses according to Pearce, Harris or Simcoe have the disadvantage that a Decentration is possible because the flexible, lower bay of these lenses decentration of the lens body down or up. In these known lenses, the lack of a horizontal one

'* Support also allows for horizontal decentering. In the lens 10 according to the invention, which has a leg 14 of invariable length, the vertical centering of the lens body 12 is determined by the leg 14. The curved edge portion 16 prevents one

^ horizontal displacement and also carries the weight of the lens 10 on a large support surface. Of the flexible support bar 18 allows the insertion of the lens 10 through the pupil and holds the desired position in the Eye upright until a fiber fixation in the posterior chamber is done. The leg 14 prevents

Also prevents the lens 10 from being twisted and held in place of the lens body 12 through the pupil.

Since the leg 14 and the support web 18 are inclined forward and there also the edge portion 16 and the Support web 18 have an extension in the circumferential direction, the lens body is at a distance from the iris so that there is no rubbing of the iris tissue. In another Execution of the support web 18, the leg 14 and the edge portion 16 are in the same plane as the Lens body 12.

In the 12 o'clock position, in the 3 o'clock position and in 3 o'clock position and in the 9 o'clock position of the lens body 12 and in the edge section 16 (on the axis 10a) openings 19 are provided. The openings 19 are used for inserting a surgical instrument to accommodate and center lens 10 in the eye.

The lens body 12 shown in Figure 1 is either plano-convex or biconvex, the plane surface of the lens body 12 is preferably facing the iris 24, since this is the greatest distance between the iris 24 and Front surface of the lens body 12 results. This prevents irritation of the iris margins in the postoperative

Period.

Figure 2 shows a section through the eye socket, wherein the lens 10 is inserted into an eyeball 20. The eyeball 20 has the cornea 22 and the iris 24, in which the eye hole or the pupil 26 is arranged centrally is. The iris 24 divides the eyeball 20 into an anterior eye chamber 28 and a posterior eye chamber 30. The lens 10 is arranged in the rear eye chamber 30 of the eyeball 20 such that the edge portion 16 rests against the ciliary sulcus 32 in order to be fixed like fibers. Figure 2 also shows the remainder of the anterior capsule 34 of the rear chamber 30 and the rear capsule 36.

The weight vectors of the lens 10 acting in the 6 o'clock direction bring about a permanent centering of the lens body 12 in the eye chamber 30. The curved surface 16a of the edge portion 16 of the lens 10 leaves handle yourself so that it slides easily into the ciliary sulcus 32 without closing the posterior capsule 36 penetrate. In this way, the lens 10 is fixed and centered without any additional fixing is required.

It is clear that before inserting the lens 10 through

an opening must be made in the anterior capsule 34 for the pupil 26 to break down the natural lens and remove.

The lens body 12, the leg 14, the edge portion 16 and the support web 18 are all made of one material made suitable for implantation in the eye. Polymethyl methacrylate is an example of this (PMMA) suitable. As already proposed in US application 28 609, are also here in one embodiment Lens body 12 and the edge portion 16 made of rigid material, such as polymethyl methacrylate (PMMA), while the leg 14 is made of a softer material, for example a hydrogel (PHEMA) consists; in another embodiment, the leg 14 is made of PMMA. The support web 16 consists of a Made of extruded PMMA, polypropylene or a similar material.

^ ⁰ A preferred embodiment of the invention thus relates to an implantable into an eye lens 10 having a lens body 12 having a support web 18 in the 12 o'clock position and a narrow leg 14 in the 6 o'clock position, the leg 14 a supporting Edge portion 16 has. The curved edge portion 16 has its

Center of curvature at the center of the lens body 12 and has a distance from this which is approximately the corresponds to half the diameter of the posterior chamber 30 into which the lens 10 is to be inserted. the The total length of the lens 10 corresponds approximately to the diameter of the rear eye chamber 30.

FIG. 3 shows a further development of a lens 40 which can be implanted in an eye a lens body 12, a leg 14 and a rim portion 16 as previously described. the Lens 40 is also provided with a support web 18 and a second support web 18a, the latter being approximately in the 9 o'clock position is connected to the lens body 12. The support webs 18 and 18a have an identical shape and are arranged with respect to the axis 10a of the lens 40 and with respect to the leg 14 in the same way. In that the flexible support webs 18 and 18a are oppositely curved and symmetrical with respect to the axis 10a Are mounted, forces are balanced that would cause a rotation of the lens 40, so that the implantable Lens 40 is even more stable.

In Figure 4, the same parts are again provided with the same reference numerals, the previously described

implantable lens 10 is developed and provided with the reference numeral 50. The lens 50 has a lens body 12 and a support web 18 as in the embodiment according to FIG. Instead of the leg 14 and the edge section 16, which are molded onto the lens body 12 of the lens 10 in the embodiment according to FIG according to the figure 1 have. The loop 52 is in one embodiment made of extruded PMMA, polypropylene or a similar material and is roughly in the 6 o'clock position on the lens body anchored ^L _{12th

15th

20th

25th

Claims (13)

- one formed on the lens body (12) and extending from a first edge section of the lens body (12) radially outwardly extending leg (14); - A curved edge section (16) arranged centrally at the free end of the leg (14), the circular curvature diameter corresponds to the diameter of the circularly delimited eye chamber; and - A flexible plug anchored on the edge of the lens body (12) approximately opposite the leg (14)! (18), the free end of which is curved in an arc and is arranged centrally with respect to an axis (10a) extending through the leg (14). 2. Eye implant according to claim 1, characterized in that the contact plane of the arcuate edge portion (16) and the curved end of the flexible web (18) for a posterior chamber (30) to be inserted lens (10) is in front of the lens body (12). 3. Eye implant according to claim 1, characterized in that the lens body (12) consists of the same Fabric such as the leg (14), the arcuate edge portion (16) and the flexible web (18). 4. Eye implant according to claim 1, characterized in that the lens body (12), the leg (14) and the arcuate edge portion (16) consist of a rigid material such as polymethyl methacrylate (PMMA) and that the flexible web is made of a softer material, for example a material such as polypropylene is made. 5. Eye implant according to claim 1, characterized in that the leg (14) in the 6 o'clock position on Edge of the lens body (12) is arranged. 6. Eye implant according to claim 1, characterized in that the leg (14), the arcuate edge portion (16) and the flexible web (18) lie in the same plane as the lens body (12). 7. Eye implant according to one of claims 1 to 6, characterized characterized in that the lens body (12) is plano-convex, the planar surface of the before Lens body (12) lying, through the curved end of the web (18) and the curved edge portion (16) facing the running contact plane. 8. Eye implant according to claim 7, characterized in that the flexible web (18) on the edge of the lens body (12) anchored approximately at the 3 o'clock position is. 9. Eye implant according to one of claims 1 to 8, characterized in that on the circumference of the lens (10, 40, 50) openings (19) are provided to facilitate insertion and centering. 10. Eye implant according to one of claims 1 to 8, characterized in that the flexible web (18) Curved in an inverted U-shape and symmetrical with respect to the axis (10a) running through the leg (14) is attached to the lens body (12). 11. Eye implant according to claim 10, characterized in that the ends of the webs (18,18a) in the 3 o'clock and 9 o'clock on the lens body (12) are anchored. 12. Eye implant according to one of claims 1 to 12, characterized in that the leg (52) is in the form a closed loop extending radially outward from the lens body (12) and at its end into an arc-shaped edge section arranged symmetrically with respect to the leg transforms. 13. Eye implant according to claim 12, characterized in that the lens body (12) consists of a rigid Material like polymethyl methacrylate (PMMA) is made up while the loop (52) and the flexible The web (18) is made of a softer material such as polypropylene.