DE3428895A1 - Intraocular lens - Google Patents

Abstract

The invention relates to an intraocular lens (1) for implantation in an ocular chamber (3, 9) of an eye (2), having a lens part (21, 22) and a haptik (4). In order to achieve a high imaging quality for the intraocular lens, it is proposed in accordance with the invention to construct the lens part of the intraocular lens (1) as an integrated double lens consisting of an inner core lens (21) made from high-index material and an outer lens (22) which surrounds the latter on all sides and is made from low-index material. It is possible in this case to colour the core lens or to coat it with anti-reflection coatings (23) for the absorption of UV radiation, without needing to fear that these additional materials will be washed out by the aqueous humour. <IMAGE>

Description

The invention relates to an intraocular lens

according to the preamble of claim 1.

Such intraocular lenses, which have a lens part and a haptic have, are implanted in the eye chamber of a patient when the natural lens can no longer perform its function, z. B. because they are through Star is tarnished. It is known to implant silicone intraocular lenses, because these elastic intraocular lenses pass through a very small opening in the cornea of the eye brought into the eye chamber and implanted there, from which previously the crushed cloudy natural lens has been removed. A disadvantage of such elastic intraocular lenses made of silicone is the relatively low refractive index this material, so that relatively thick lenses for the required diopter range are necessary.

Glass lenses have the advantage of a higher refractive index, however the specific weight of glass is significantly higher than that of water, so that the lens made of glass has a relatively heavy weight in the ocular ventricular fluid Has. In addition, it is more difficult with glass lenses than with silicone lenses, the haptics to connect with the lens part.

Furthermore, materials for intraocular lenses are acrylic glasses, e.g. B * the frequently used methyl methacrylate resins, whose specific gravity can be very high close to that of the aqueous humor, so that the intraocular lens has only a relatively low weight in the chamber liquid. Even if this Material in the eye is inert, it has been found that partially the back of the cornea sensitive to contact with acrylic glass, so at least the implantation such intraocular lenses in the anterior chamber can be problematic.

Regardless of what material the intraocular lenses are made of it is necessary for the required diopter range with a #alvalue graduation make available a variety of expensive shapes in which to use the intraocular lens be shaped.

For the state of the art, see DE-OS 32 28 352, for example, see DE-AS 28 13 496, DE-PS 26 33 095 and US-PS 4,080,709.

The thicker such intraocular lenses, the higher the chromatic aberration, so that attentive patients sometimes cross color boundaries complain. This is particularly true of silicone lenses. The same is true for thicker ones Lenses also have larger spherical aberrations, so that the imaging accuracy suffers.

It would also be beneficial to be able to color intraocular lenses. In particular elderly people complain of removing and replacing the clouded natural lens through an artificial intraocular lens via so-called blue vision. This could go through a coloring of the intraocular lens according to the age distribution of the # natural Eye lens can be prevented.

It would also be beneficial if the intraocular lens as well as the natural one The lens of the eye would be almost impermeable to ultraviolet light, so that the retina Protected is silicone in particular, but leaves ultraviolet light almost undamped by.

In order to realize the last two proposals, the Lens material additives are added, or on the lens material or layers of paint or UV-impermeable layers are applied. Should be here however, ensure that this is either added or applied material not from the chamber water can be washed out or washed off. While there are materials under investigation, these materials are for the practice either not yet appropriate or not yet approved by state authorities authorized.

The invention is based on the object of providing an intraocular lens Specify the type in question, which is easy to manufacture and at the same time a has good image quality; in addition, colorings or coatings of the Lens part be possible.

This object is according to the invention by the claims 1 specified characteristic features solved.

Accordingly, the lens part of the intraocular lens is made up of a core lens and an outer lens that completely encases them. The core lens is made of high refractive index material, a. B. polyimide with a refractive index between 1.5 and 1.8, while the outer lens is made of low refractive index material, preferably made from the tried and tested silicone, which is inert to aqueous humor, with a refractive index of about 1.4.

Such a design of the intraocular lens has several advantages with himself.

So z. B. only a single one for the encapsulating outer lens Shape or at least only a few shapes be provided that ß the focal length of the intraocular lens can essentially be determined by the shape of the inner core lens.

Since the core lens is completely encased by the outer lens, can the core lens colored or coated, e.g. B. be mirrored without It must be feared that these additives will be washed out.

Otherwise occurring LinXsen errors especially chromatic and spherical aberration can be almost eliminated by treating the core lens so that a high image quality is also achieved.

An intraocular lens according to the invention has the same refractive power also lighter than a silicone lens, so that its weight in the aqueous humor is less.

In addition, the specific gravity of an intraocular lens can according to the invention can be artificially reduced by e.g. B. the core lens from two meniscus lenses or is composed of two plano-convex lenses, between which an air space remains. The volume of the air space is determined to accommodate the weight of the intraocular lens becomes zero in the aqueous humor.

The attachment of the haptic to the lens part is unproblematic, as proven techniques can be used here that are used in conjunction with Silicone lenses are used.

In the case of an intraocular lens according to the invention, it is also possible one extreme in the middle of the core lens, which is preferably composed of two lenses to arrange a thin aperture with a small aperture. This increases the imaging accuracy higher, and this aperture can also be seen as a substitute for accanodation. At a optical bench in the water has been shown to be extremely thin Aperture with an aperture of about 2 mm a patient from infinitely to 45 cm Could see distance sharply. However, such a solid artificial diaphragm is in the center of the core lens for a careful inspection of the inner eye, in particular-the Retina, disadvantageous.

Further refinements of the invention emerge from the subclaims emerged. The invention is shown in more detail in three exemplary embodiments with reference to the drawing explained. In the Drawing represent; Figure 1 is a schematic Cross-section through a human eye with one inserted into the posterior chamber Intraocular lens according to the invention; FIG. 2a shows a cross section through an intraocular lens according to the invention, which consists of a core lens and an outer lens encasing it is composed; FIG. 2b shows a plan view of the core lens in FIG. 2a; figure 3 shows a cross section through a further exemplary embodiment of a core lens with an indicated Outer lens; and FIG. 4 shows a cross section through a modified core lens of a Intraocular lens according to the invention; In Figure 1 is the arrangement of an intraocular Lens 1 shown in an eye 2. The intraocular lens is in the rear Eye chamber 3 held with the aid of a haptic 4. The back of the intraocular The lens faces the glass body 5 on which the emergency skin is attached. 6 connects. the posterior chamber 3 is forward through the iris 7 with a pupil opening 8 limited with respect to an anterior chamber 9 of the eye. The anterior chamber of the eye is from the cornea 10 covered.

Instead of implanting the intraocular lens in the posterior chamber 3, there is also the option of placing the intraocular lens in the anterior chamber 9 to be arranged, with the haptic 4 in # the corner area 11 between the iris 7 and cornea 10 intervenes. The haptics must then of course be adapted to this type of implantation be.

The implantation of the intraolular lens according to FIG. 1 becomes reliable avoided that this lens touches the back of the cornea 10 with the haptics.

In Figure 2a, the intraocular lens 1 is shown on an enlarged scale. This intraocular lens 1 is made up of a core lens 21 and one of these completely encasing outer lens 22 composed. The optical axis is denoted by A. The haptic 4 is connected to the outer lens 22, but can also, as in FIG 2a denoted by 4-1 and shown in dashed lines, connected to the core lens 21 The outer lens 22 has a radius Rl on the front and a radius Rl on the rear a radius R2, while the core line 21 has a front radius R3 and a has rear radius R4.

The core lens 21 is made of a high refractive index material, e.g. B. a Polymer, such as polyimide or the like, and has one between 1.5 and 1.8 lying index of refraction. The outer lens 22 is made of silicone, which has a refractive index of about 1.4 has silicone is inert to aqueous humor.

The image quality can be reduced by the formation of the individual radii R1 to R4 of the lens in terms of both chromatic aberration and spherical aberration be made very high.

The core lens 21 is provided with an anti-reflective coating 23 at least on the Coated front side, which further increases the image quality can.

Either the material of the core lens 21 or the anti-reflective coating chosen so that the intraocular lens 1 does not have UV radiation or only to a greatly reduced extent Lets through dimensions.

It is also possible to color the material of the core lens 21 in order to adapt the permeability of the intraocular lens 1 to that of the natural lens of the eye.

It is advantageous to use the radii R1 and R2 of the outer lens 22 for all required diopter ranges or at least for a wide diopter range to keep the same and the required number of diopters in each case adjust the formation of the core lens 21. The finished core lens is then in a divisible shape, not shown here, and for producing the outer lens 22 coated with silicone.

The formation of the intraocular lens from a high refractive core lens 21 and a relatively low refractive outer lens 22 also has the advantage that the course of the refractive index over the depth of the intraocular lens the course within is at least approximated to a natural lens of the eye at the boundaries between outer lens 22 and core lens 21 can by corresponding Adaptation of the anti-reflective coating 23 can be kept small. The anti-reflective coating has z. B. a refractive index around 1.5.

In Figure 3 is an exploded view of a modified core lens 21-1 shown, which is encased by the indicated outer lens 22-1. The core lens 21-1 consists of two plano-convex partial lenses 24-1 and 24-2, which are like a Condenser are composed. The conical surfaces of the partial lenses can of course have different radii. Between the partial lenses 24-1 and 24-2 is one very thin aperture 25-1 with a small aperture 26-1 provided, which in the assembled State of the core lens 21-1 rests against the flat surface of the front partial lens 24-1. The two partial lenses 24-1 and 24-2 are separated from one another by a spacer ring 27 held at a distance so that between the two facing flat surfaces a cavity 28-1 is formed of the partial lenses. This cavity is filled with air, possibly slightly evacuated. The volume of this cavity 28-1 is chosen so that the complete intraocular lens from core lens 21-1 and outer lens 22-1 im Aqueous humor has no weight.

Auct with this msdifiiziexten IntraQkul # rl.i # se it is possible to have a or to coat both core lenses with anti-reflective coatings 23-1 or the like and to color the partial lenses 24-1 and 24-2.

In Figure 4 is another embodiment of a composite Core lens 21-2 shown. This core lens 21-2 consists of two meniscus lenses 29-1 and 29-2, between which a cavity 28-2 remains. The volume of this cavity is chosen as above. This core lens 21-2 is also provided with anti-reflective coatings 23-2 or the like provided.

There is also a diaphragm 25-2 with a small diaphragm opening 26-2 provided, with this diaphragm directly on the back of the anterior meniscus lens 29-1 applied, e.g. B.

is vaporized.

The core lenses 21 for an intraocular lens 1 can be cast and be polished or sanded. the coating with silicone is in a form unproblematic.

The finished intraocular lens and its individual parts can, such as known from silicone lenses, are sterilized at high temperature.

On the core lenses 21, 21-1 and 21-2 of the intraocular lenses described above a small optical marking 30 can preferably also be applied, e.g. in the form of a crosshair or a small star, with this marker on the front convex part of the core lens is located in the optical axis A. These optical marking does not interfere with seeing, but enables it in a simple way Check that the intraocular lens is correctly positioned. Such an optical mark in the form of a crosshair is for the core lens according to FIG. 2a in FIG. 2b shown. It goes without saying that this is also the case with the other exemplary embodiments possible.

The intraocular lenses shown in the drawing are not true to size. The diameter of the outer lens is normally around 6 mm, the thickness of the intraocular lens along the optical axis about 0.7 mm. The core lens has a diameter of approx. 5 mm and a thickness in the direction of the optical axis between 0.3 and 0.5 mm. Of the The cavity between the partial lenses of the core lens has an axial extension of approximately 0.15 mm.

Claims (14)

Intraocular lens claims 1. Intraocular lens for implantation into an eye chamber with a lens part and. a haptic, characterized in that that the lens part as an integrated double lens from an inner core lens (21) made of highly refractive material and an outer lens (22) encasing it on all sides is made of lower refractive index material. 2. Intraocular lens according to claim 1, characterized in that the Core lens (21) made from a polymer, preferably polyimide, with a refractive index is between 1.5 and 1.8, and that the outer lens (22) made of silicone with a. Refraction as is x of about 1.4. 3. Intraocular lens according to claim 1 or 2, characterized in that that at the transitions between the two lens materials at least partially Anti-reflective coverings (23) are provided. 4. Intraocular lens according to one of the preceding claims characterized in that the core lens (21) is colored. 5. Intraocular lens according to one of the preceding claims, characterized characterized in that the material of the core lens (21) is essentially for UV light is impermeable. 6. Intraocular lens according to one of the preceding claims, characterized marked that. on the core lens (21) at least partially absorbing UV light Coatings (23) are provided. 7. Intraocular lens according to one of the preceding claims, characterized characterized in that the core lens (21) is composed of several partial lenses (24, 29) is. 8. Intraocular lens according to claim 7, characterized in that between the partial lenses (24-1, 24-2; 29-1, 29-2) have a cavity (28-1, 28-2), the volume of which is chosen so that the weight of the implanted intraocular lens (1) in the eye chamber (3, 9) is zero. 9. Intraocular lens according to claim 7 or 8, characterized in that that the partial lenses are two plano-convex lenses (24-1, 24-2) which are planar with theirs Sides are facing each other, and that the partial lenses (24-1, 24-2) by a Spacer ring (20) are kept at a distance from each other. 10. Intraocular lens according to one of claims 7 to 9, characterized in that that the partial lenses (2) are separated from one another by a cavity (28-2) meniscus lenses (29-1, 29-2) are. 11. Intraocular lens according to one of the preceding claims, characterized characterized in that in the area of the Sernlinie (21) a thin screen (25) with a small aperture (26) is provided 12. Intraocular lens according to claim 11, characterized in that in the formation of the intraocular lens (1) made of several reren partial lenses (24, 29) arranged the diaphragm (25) between the partial lenses is. 13. Intraocular lens according to claim 11 or 12, characterized in that that the diaphragm (25-2) is a coating. 14. Intraocular lens according to one of the preceding claims, characterized characterized in that on the core lens (21) in the optical axis of the intraocular lens (1) an optical marking (30) is applied.