DE19501444A1 - Intra ocular two lens system - Google Patents

Abstract

The intra ocular lens (15) is made such that only in its central area (15') does it act as a convex lens. Although it is a very powerful lens (e.g. +60 dioptre), due to the central section being on the optical axis (13) of the eye it can be kept small (e.g. 5.5mm) and this is held at a distance from the iris which reduces irritation. Around the central area is a disc shaped outer area (15'') with the edge facing the retina being rounded. Diametrically opposing each other on the outer area are two extension pieces (18) which join two spring arms (19) for locating the lens. A hole (20) is used for an insertion instrument.

Description

The invention relates to an intraocular posterior chamber lens of a two-lens system or a two-lens System with such a back chamber lens.

Intraocular lenses are used worldwide in the cataract surgery, d. H. with cataracts, on by default puts. Here the patient's clouded lens leaving the natural lens Casing bag (lens capsule) removed and through a artificial intraocular lens, which replaced today increasingly within the posterior chamber of the eye, i.e. H. behind the iris, in the capsular bag. For Bracket of the intraocular lens are used on this arranged haptic elements that are in the sulcus ciliaris, d. H. between iris and capsular bag, or in the capsular bag, support the actually "physiological place".  

It is known from EP 00 92 552 B1 for degeneration the macula, d. H. the central area of the retina (Retina) with the usually highest density of optic cells, to use a two-lens system, the natural one Lens by a trained as a diverging lens intraocular posterior chamber lens with very large negative Refractive power replaced and combined with glasses, whose lens as a positive lens with positive refractive power is trained. The intraocular posterior chamber lens forms together with the spectacle lens and the cornea (Cornea) of the eye a telescope system, so that on the Retina of the eye compared to the conditions in the natural eye creates an enlarged image of the environment will, d. H. the image created on the retina is larger than the macular degenerate in this patient, so that despite the damage to the retina, eyesight can be significantly improved overall.

The publication by G. Gerten and H.-H. Cook, "Cataracts in Retinitis Pigmentosa", 1990, published from the German Retinitis Pigmentosa Association e.V. in Quickborn, deals with patient information, who suffer from retinitis pigmentosa, among others that degenerates the areas of the retina surrounding the macula are degenerate or increasingly degenerate. Such patients typically suffer from a so-called tube look, d. H. only in a narrow central field of vision is one more or less sharp vision possible, provided that there is no cataract. In section 4.1 "Forecast of Intervention "on page 29 of the last specified pressure writing is in connection with the retinitis pigmentosa stated that in the event of a simultaneous cataract  the natural lens of the eye through an artificial one intraocular lens can be replaced, the "Of course not improving the visual impression in an expansion of the field of vision ".

The object of the invention is now to patients with retinitis Pigmentosa has a much improved visual space enable orientation.

This object is achieved with a two-lens System of the type specified solved in that the intraocular posterior chamber lens as a collecting lens very large positive refractive index and with one located near the cornea of the eye divergent lens with a larger negative refractive index is combined.

The invention is based on the one hand on the general Thoughts through the cornea of the eye as well as that artificial two-lens system of the invention optical system compared to an optical system normal natural eye with a more or less to train strong wide-angle characteristics, and on the other hand on the surprising realization that that generated on the retina and compared to the ratio nits inevitably with a normal-sighted eye reduced image of the environment still very clearly recognized can be. In this way the retinitis Patients suffering from pigmentosa for the first time Extension of the field of vision with good visibility of the objects appearing in the field of view.  

The rear chamber lens preferably has a haptic for fixation in the capsular bag, this haptic in particular is preferably designed so that it on the one hand the capsular bag in a circular manner and on the other hand the intraocular lens pronounced backwards, towards the retina, pushes against the back of the capsular bag.

In this way, on the one hand, a particularly secure position Fixation of the posterior chamber lens is achieved because of the lens through the haptics practically on the entire equator of the capsule sacks and therefore on the entire ciliary muscles and via the back of the lens at the central area of the capsule sack, which is stretched out, is supported. It can thus be guaranteed that the intra cular posterior chamber lens no postoperative tilting movement able to carry out the functions for the optical properties of a multi-lens system are particularly harmful are. On the other hand, in this embodiment allows the one located in the beam path at the back Posterior chamber lens is particularly close to the retina, so that on the one hand irritation of the iris, e.g. B. irido capsular Synechia that can be safely avoided and others on the other hand the refractive interface of the retina whole of cornea and the artificial two-lens System formed optical system closer to the Retina can lie, as it is with regard to a ver larger field of view is desirable.

The diverging lens of the two-lens system can be used as intraocular anterior chamber lens or - especially in younger patients - as a contact shell, preferably as so-called permanent contact shell, the long time on the Eye may be trained.

Otherwise, the preferred features of the Invention on the claims and the following Description of preferred embodiments, which are explained using the drawing.

It shows

Fig. 1 is a schematic sectional view of a normal eye into account,

Fig. 2 is a sectional view of the eye with the fiction, modern two-lens system,

Fig. 3 is a front view of the intraocular posterior chamber lens and

Fig. 4 is a side view of the posterior chamber lens accordingly the arrow IV in Fig. 3.

Referring to FIG. 1, the light passes through the cornea 1 (cornea) in the eye 2, passes through the cornea lying between 1 and 3 iris anterior chamber 4 and passes through the area enclosed by the iris 3 pupil. 5 The light then passes through the rear chamber 7 of the eye 2 formed between the iris 3 and the lens 6 and subsequently the lens 6 and the vitreous body 8 , which fills the space between the lens 6 and the retina 9 . On the retina 9 , the light is captured by optic cells (rods and cones) and converted into nerve impulses, which are fed to the visual center of the brain via the optic nerve 10 .

The cornea 1 and the chambers 4 and 7 and the lens 6 essentially form the optical system, ie the natural lens system, of the eye 2 , which is an object 11 in the field of vision of the eye, shown schematically as an arrow in FIG. 1, in a basically known manner Mapped as a reduced image 12 on the retina 9 . Here, the part 11 'of the object 11 , which is close to or on the optical axis 13 of the eye 2 , appears as an image part 12 ' on the macula 9 ', ie the central region of the retina 9 adjacent to the optical axis 13 , which is particularly high Has optic cell density and accordingly enables a particularly high resolution, ie details and contours of the image part 12 'are particularly well recognizable. With increasing distance from the macula 9 ', the visual cell density of the retina 9 and thus the image resolution capacity are lower. This is practically not noticed by people with normal functioning eyes because the eyes constantly involuntarily make small swiveling movements, so that "interesting" or fast-moving objects, initially only on areas of the retina 9 at a greater distance from the macula 9 'as an image appear to be "scanned" as quickly as possible by the eye. This results in a consistently sharp visual impression within a very wide field of view.

In patients with retinitis pigmentosa, the retina 9 outside a narrow area near the optical axis 13 of the eye 2 , in particular outside the macula 9 ', is severely degenerate and inoperable. In the example of FIG. 1, at most part 11 'of the object or the associated image 12 ' can then be recognized. Objects or object areas which are further away from the optical axis 13 are not perceived at all. This leads to the patient suffering from a pronounced "tube gaze" and in particular the orienting vision is very considerably restricted. In the absence of a perceptible visual impression in the case of objects or parts of objects, the images of which appear on areas of the retina 9 which are inoperable, the eye 2 also does not automatically pivot in the direction of such objects. As a result, the patient can practically no longer perceive the surroundings reasonably.

Here can be a very essential by the invention Improvement can be achieved.

The natural lens 6 , which is often clouded due to a cataract and therefore unusable in patients with retinitis pigmentosa, is removed while leaving the capsular bag 14 enveloping the lens 6 and opened on the front side and replaced by an intraocular posterior chamber lens 15 , which according to the invention has a very high refractive power , which is of the order of magnitude about three times the refractive power of a healthy natural lens 6 and is approximately +60 diopters. As will be shown further below, this lens is arranged as far back as possible in the eye 2 , ie at the greatest possible distance from the cornea 1 , and is preferably fixed in the capsular bag 14 in the manner shown below.

To compensate for the excessive positive refractive power of the posterior chamber lens 15 , a scattering lens is arranged on the cornea 1 in the form of an anterior chamber lens 16 shown only in dotted lines or in the form of a contact shell 17 to be worn on the outside of the cornea 1 . The negative refractive power of this lens 16 or contact shell 17 is of the order of magnitude of -30 diopters.

Basically, it is also possible to use glasses instead of the front chamber lenses 16 or the contact shells 17 . Due to the greater distance of the spectacle lenses from the eye, a negative refractive power in the order of magnitude of -20 diopters is sufficient for the spectacle lenses.

The two-lens system 15/16 or 15/17 acts similar to an "inverted telescope", ie the object 11 is compared to a normal-sighted eye 2 as a much smaller image 12 "on the still functional part even with retinitis pigmentosa the retina 9 , in particular the macula 9 ', which is synonymous with the fact that the field of view of the eye 2 shown in FIG. 2 widens significantly despite large, practically inoperative areas of the retina 9 .

Surprisingly, it has been found that the advantages of expanding the field of view far outweigh the effect of reducing the images on the retina 9 . This can certainly not only be explained by the fact that the visual cell density is also comparatively high in patients with retinitis pigmentosa in the area of the macula 9 or areas of the retina 9 adjacent thereto. Rather, the "image evaluation" of the brain also plays a role here, which "knows" or "learns" in a short time, the size of the objects associated with the respective images on the retina 9 , so that the patient can "correct" these objects Perceives.

Referring to FIGS. 3 and 4, the posterior chamber lens 15 is preferably formed only in a central region 15 'as a converging lens. This ensures that the maximum thickness of the rear chamber lens 15 remains small in the direction of the optical axis 13 despite the high refractive power. This offers the advantage that a large distance is guaranteed between the iris 3 and the posterior chamber lens 15 and, accordingly, any irritation of the iris 3 can be avoided. The diameter of the area 15 ', which is 5.5 mm in example, is slightly larger than the normal diameter of the pupil 5 , so that practically all of the pupil 5 penetrating light can pass through the converging lens area 15 '.

To the radially outside adjoins the converging lens area 15 ', an annular disk-shaped area 15 '', the outer edge of which is well rounded, in particular on the side facing the retina 9 . The outer edge typically has an approximately semicircular profile.

On two diametrically opposite circumference pieces of the annular disc-shaped area 15 'two plate-shaped extensions 18 are formed, which are inclined relative to the plane of the annular disk-shaped area 15 ' by about 15 ° in the direction of the front of the lens 15 . The extensions 18 go without sharp edges, preferably with curves, in the annular disc-shaped area 15 ''.

The extensions 18 can be connected with a certain resilience to the annular disk-shaped region 15 '', in such a way that the lens 15 increases its distance somewhat from a plane containing the outer edges of the extensions 18 when forces perpendicular to the outer edges of both extensions 18 to the optical axis 13 act in the radial inward direction.

The outer edges of the extensions 18 are rounded like the outer edge of the annular disc-shaped area 15 '' and be, for example, in turn sit a semicircular edge profile.

The peripheral edge of the extensions 18 each merges into an open, arcuate loop 19 , which extends from one extension 18 to the vicinity of the other extension and forms a resilient strap, which in the relaxed state in the axial view of the lens 15 is a slightly spiral Has a shape such that the free end of each loop 19 is at a slightly greater distance from the lens center than the connection areas of the loops 19 on the extensions 18 .

As can be seen in particular from FIG. 4, each sling 19 has a certain helical pitch in the relaxed state, so that the lens 15 can be "screwed" into the opened capsular bag 14 during the operative implantation. In order to facilitate the insertion of the lens 15 into the capsular bag 14 , an opening 20 for inserting an operating set can be provided in at least one of the extensions 18 .

Moreover, the loops 19 have a circular or oval cross section and spherically rounded free ends.

After inserting the lens 15 into the capsular bag 14 , the loops 19 form a practically closed ring and the extensions 18 form two stable, elastic spokes carrying this ring, both the loops 19 and the extensions 18 forming the spokes forming the equator of the capsular bag 14 and accordingly try to relax the ciliary muscles 21 holding the capsule sack on the outside of the equator in a ring. The annular support at the equator of the capsular bag 14 bridges any fissures in the ciliary muscles 21 , so that even in the event of contractions of the ciliary muscles 21 , which serve to deform the healthy eye and the accompanying accommodation of the lens 6 (see FIG. 1), none at all Tilting of the lens 15 can occur.

In addition, the position of the lens 15 in the capsular bag 14 is also secured in that the lens 15 tries to relax the capsular bag 14 due to the angled extensions 18 backwards towards the retina 9 , the capsular bag 14 both on the outer edge of the ring-shaped area 15 '' as well as at the rear center of the area 15 'under certain tension.

Insofar as the ciliary muscles 21 cause a change in the kink angle between the extensions 18 and the annular disk-shaped region 15 '' of the lens 15 during contractions, a slight displacement of the lens 15 occurs in the direction of the optical axis 13 of the eye 2 , as a result of which the axial Distance between the rear chamber lens 15 and the front chamber lens 16 or the contact shell 17 changed somewhat, with the result that the ciliary muscles 21 can cause a limited akko modification of the eye 2 .

The relatively small maximum thickness of the lens 15 in the direction of the optical axis 13 ensures that the average distance between the front and rear sides of the lens 15 from the anterior chamber lens 16 or the contact shell 17 is comparatively large, this distance due to the backward tense arrangement of the lens 15 in the capsular bag 14 is still enlarged. This allows a more pronounced wide-angle effect of the two-lens system 15/16 and 15/17 according to the invention to be achieved with respect to a lens 15, which is conceivable in principle, both with regard to the diameter and also with respect to the thickness of the converging lens region 15 '.

The anterior chamber lens 16 and the contact shell 17 , both of which are designed as strong diverging lenses, are each known per se - as a one-lens system - for correcting extreme myopia (nearsightedness), so that structural details need not be explained.

Claims (7)

1. Two-lens system with intraocular posterior chamber lens, characterized in that the intraocular posterior chamber lens ( 15 ) is designed as a converging lens with a very large positive refractive power and combined with a close-up or portable diverging lens ( 16 , 17 ) with a large negative refractive power . 2. Two-lens system according to claim 1, characterized in that the refractive power of the posterior chamber lens ( 15 ) is approximately three times as large as the refractive power of a natural eye lens ( 6 ) and is approximately +60 diopters in the aqueous humor. 3. Two-lens system according to claim 1 or 2, characterized in that the diverging lens ( 16 , 17 ) has a negative refractive power, the amount of which has an order of magnitude of approximately -30 diopters in the aqueous humor. 4. Two-lens system according to one of claims 1 to 3, characterized in that the rear chamber lens ( 15 ) is designed for fixation in the capsular bag ( 14 ). 5. two-lens system of any one of claims 1 to 4, characterized in that the posterior chamber lens (15) having a haptic (18, 19) through which the lens (15) in the eye (2) rearward to the retina ( 9 ) towards the capsular bag ( 14 ). 6. Two-lens system according to one of claims 1 to 5, characterized in that the diverging lens is designed as a long-term on the eye ( 2 ) wearable permanent contact lens or shell (17). 7. rear chamber lens, in particular for a two-lens system, according to one of claims 1 to 6, characterized in that an annular disk-shaped area ( 15 '') adjoins a central converging lens area ( 15 ) radially outward, which with on its outer edge Haptic elements ( 18 , 19 ) is provided, which are pronounced - for example by about 15 ° - angled toward the front of the lens.