DE102013015386B4 - intraocular lens - Google Patents

Abstract

Intraocular lens with a filter device consisting of blue and / or violet light absorbing chromatophores, wherein the filter device with a double gradient with
the strongest filtering effect directly in the area of the optical axis (OA),
the weakest filter effect in an area directly spaced from the optical axis (OA), but within the field of a normal sized pupil and
- A rising to the edge of the intraocular lens filter effect, comprising, characterized in that the filter device is formed continuously.

Description

The present invention relates to an intraocular lens.

It is well known to replace a natural lens of a human eye with an intraocular lens. This is done to correct lens opacity of the endogenous lens and / or to correct a high refractive vision defect. Furthermore, phakic intraocular lenses are known, which correct for ametropia in addition to the body's own lenses.

A variety of scientific studies has shown that the natural lens of humans turns yellowish with age and thus has an additional filtering effect in the range of short-wave light. This is of importance insofar as it is known that, in particular, short-wave light in the blue and / or violet spectrum is adequately filtered off neither by the cornea nor the aqueous humor or the vitreous body, and thus can reach the retina unhindered without this yellow coloration of the lens. In addition, it could be demonstrated that an increased exposure, especially to short-wave blue light, can damage the sensory receptors, the retinal pigment epithelium and other structures of the retina.

In order to take account of this problem of the harmful components in the blue and / or violet spectrum of light, even with intraocular lenses, UV light and blue light have been absorbing for quite some time, ie. H. yellow tinted intraocular lenses on the market. However, as has been shown in a number of scientific publications, these have the disadvantage that their continuous uniform yellowing, under certain lighting conditions (eg at dusk and poor lighting) to a disturbance of color vision, a reduction of contrast vision and a reduced scotopic sensitivity. In addition, there is evidence that the use of these ultraviolet light and blue light absorbing intraocular lenses can cause impairment of vigilance and mood, as well as affect sleep and circadian rhythm, to the point of depression. For this reason, the use of an intraocular lens makes sense, which under certain lighting conditions (eg very bright daylight) has a corresponding, protective filter effect in the blue light area, but still, especially in poor lighting, more light, even in the short-wave blue light area into the eye, as a completely yellow colored, ultraviolet light and blue light absorbing intraocular lens of conventional design and thus eliminates the aforementioned side effects of these conventional yellow intraocular lenses.

From the US 2005/0143812 A1 For example, an intraocular lens is known which has a circular portion near the lens axis which absorbs light having a wavelength in the range of 400 nm to 550 nm. This intraocular lens has the disadvantage that chromatic aberrations can occur at the boundary of this section. Further, there is a problem of precisely producing such an intraocular lens, since the centering of the circular yellow filter section is not satisfactorily carried out with conventional production means. In a polymerization process it comes to undesirable optical properties that are intolerable.

Next is from the US 2008/0269884 A1 an intraocular lens with a filter device is known which has a first filter gradient arranged in the region of the optical axis and a second filter gradient arranged separately from the latter, in the peripheral region of the intraocular lens.

The invention has for its object to provide an intraocular lens that eliminates the disadvantages mentioned and is particularly suitable for light-sensitive people.

This object is achieved by the intraocular lens having the features of claim 1.

• 1A eine Vorderansicht einer Intraokularlinse,
• 1B eine Seitenansicht der Intraokularlinse von 1A,
• 2 eine Vorderansicht einer phaken Intraokularlinse,
• 3 eine Seitenansicht einer optischen Einrichtung,
• 4 eine Seitenansicht einer optischen Einrichtung gemäß der Erfindung,
• 5 eine schematische Ansicht einer Beschichtungsvorrichtung,
• 6 eine schematische Ansicht einer weiteren Beschichtungsvorrichtung,
• 7 eine Schnittansicht einer optischen Einrichtung,
• 8 eine schematische Ansicht einer weiteren Beschichtungsvorrichtung,
• 9 eine schematische Darstellung eines generativen Fertigungsverfahrens zur Herstellung eines optischen Teils einer Intraokularlinse oder intraokularen Kontaktlinse, und
• 10 eine schematische Darstellung eines Tauchbadverfahrens zur Herstellung eines optischen Teils einer Intraokularlinse oder phaken Intraokularlinse.

In the accompanying drawings show:

• 1A a front view of an intraocular lens,
• 1B a side view of the intraocular lens of 1A .
• 2 a front view of a phakic intraocular lens,
• 3 a side view of an optical device,
• 4 a side view of an optical device according to the invention,
• 5 a schematic view of a coating apparatus,
• 6 a schematic view of another coating device,
• 7 a sectional view of an optical device,
• 8th a schematic view of another coating device,
• 9 a schematic representation of a generative manufacturing process for the production an optical part of an intraocular lens or intraocular contact lens, and
• 10 a schematic representation of a dip process for producing an optical part of an intraocular lens or phakic intraocular lens.

The 1A and 1B show an intraocular lens 100 that is made of an optical part 10 and a haptic part 12 consists. The intraocular lens 100 may be both a rigid and a foldable intraocular lens.

2 shows a front view of a phakic intraocular lens 200 also made of an optical part 10 and a haptic part 12 consists.

Hereinafter, the invention will be for simplicity only on the optical part 10 explained. As materials for the intraocular lens 100 or the phakic intraocular lens 200 Methacrylates, acrylates, stiffer hydrogels, silicone polymers, as well as derivatives and combinations of these can be used.

The optical part 10 is designed so that a filtering effect strongest in the optical axis OA in the field of the pupil under strong light.

This will, as in 3 is shown, an optical device e through one on the lens part 10 applied coating 14 formed, whose filtering effect in the region of the optical axis OA is the largest and extends to the edge of the optical part 10 decreased. This can be achieved, for example, by the fact that the filtering effect or the ink layer thickness D in the area of the optical axis OA is greatest within the contour of the intraocular lens or phakic intraocular lens. Preferably, an extremely thin layer is used in which the chromophore portion of the optical axis OA to the edge of the optical part 10 is gradually reduced.

The coating 14 In one embodiment, it is a film of an immunologically compatible material. The coating 14 in another embodiment, consists of blue light and / or violet-filtering acrylate, methacrylate, hydrogel, silicone polymer, and derivatives of these and combinations of these or other immunologically compatible, inert material and material adapted to the intraocular milieu of the eye.

In the application example according to the invention, as in 4 is shown, an optical device E1 formed, whose applied layer for filtering effect or density of chromatophores in the region of the pupil opening in the state under normal light conditions directly adjacent to the optical axis OA is smallest and extending both to the edge of the optical part 10 towards and in the direction of the optical axis OA increased. Such an optical device E1 is particularly advantageous for photosensitive humans, for example albinism or patients with missing iris. In this application, a double gradient of the continuous filter device is necessary with the strongest filter effect directly in the area of the optical axis OA , the weakest filter effect in an area directly spaced from the optical axis OA but within the field of the normal sized pupil and again steplessly increasing gradient of the filter effect towards the edge of the optical device E1 out.

The production of an intraocular lens 100 or a phakic intraocular lens 200 will be on hand by 5 described. First, the intraocular lens 100 or the phakic intraocular lens 200 on a recording 40 , z. B. a rotatably mounted rotation device positioned and held.

Thereafter, a blue light or violet light filtering medium containing the corresponding chromophores M (hereinafter for the sake of simplicity only as a medium M referred to), the above-described requirements for the formation of the coating 14 corresponds to the intraocular lens 100 or the phakic intraocular lens 200 by means of a nozzle 52 having nozzle device 50 applied. After application of the medium M This is done by moving the recording 40 Centrifugal forces urged outward in rotation. Depending on the speed and the elapsed time, a different filtering gradient of the coating 14 generated.

Alternatively, the medium becomes M applied during the turning process.

Furthermore, alternatively, the medium M by means of a nozzle unit 54 applied. The nozzles 54a have different diameters d, extending from the optical axis OA towards the periphery of the optical part 10 to rejuvenate, as in 6 is shown.

The arrangement of the nozzles 54a in the nozzle unit 54 is provided in the example shown in the form of a series. In another example, not shown, the nozzle unit 54 cylindrically shaped, and the nozzles 54a are arranged concentrically in the form of circles.

According to an alternative example, the nozzles have 54a the same diameter d, but with the concentration of the coloring, ie the concentration of chromophores that through the different nozzles 54a guided media M different from each other.

Although in the example shown only an intraocular lens 100 or phakic intraocular lens 200 is coated, according to a modified embodiment, the receptacle and the nozzle device 50 designed so that at the same time a variety of intraocular lenses 100 or phakic intraocular lenses 200 be coated.

In a further, not shown embodiment, the coating 14 with uniform thickness D applied. In a subsequent process step, the coating 14 mechanically or chemically removed such that the thickness D in the region of the optical axis OA is the largest and extends to the edge of the optical part 10 decreased. Mechanical or chemical ablation follows the contour of the intraocular lens or the phakic intraocular lens to avoid prism formation.

In the embodiment of 6 either the recording turns 40 or the nozzle unit 54 , In a modified embodiment, both the recording rotate 40 and the nozzle unit 54 but at different speeds and / or in opposite directions of rotation. Also, a change in the rotational speed of the recording 40 and / or the nozzle unit 54 during the coating process possible.

Although the examples shown are based on the application of the coating 14 on the directed to the interior of the eye optical part 10 the intraocular lens 100 or phakic intraocular lens 200 In another embodiment, the application of the coating can 14 on the outward optical part 10 the intraocular lens 100 or the phakic intraocular lens 200 done in the same way.

According to another embodiment, a plurality of intraocular lenses 100 or phakic intraocular lenses 200 positioned in a receptacle and subjected to a dip. After taking the picture with the intraocular lenses 100 or phakic intraocular lenses 200 is waited for a predetermined period of time until the filter effect of the coating in the region of the optical axis OA larger than in the peripheral area. Thereafter, the fixation of this state, z. B. by a drying process, a glaze or an additional other protective layer of the materials mentioned below.

In this procedure, the surface of the intraocular lens 100 or the phakic intraocular lens 200 be provided with a wetting agent to facilitate the coating. If a vapor deposition process is used, or by another method, the dye should be harmonized after incorporation into the intraocular lens material or intraocular contact lens material in the interior of the eye (both to protect the intraocular environment from the dye and to protect the dye the effects of the intraocular milieu, eg metallic components in the dye and their possibility of corrosion) is the application of a protective sheath of acrylate, methacrylate, hydrogel, silicone polymer and derivatives and combinations thereof or of another immunologically compatible, inert material and the intraocular milieu of the Auges adapted material makes sense.

In this procedure, the surface of the intraocular lens 100 or the phakic intraocular lens 200 be provided with a wetting agent to facilitate the coating. In the embodiments which describe infiltration of the dye into the intraocular lens or phakic intraocular lens, a solvent which facilitates dye penetration can be used.

The medium M can be either liquid, viscous or powdery. Also, nanoparticles are for the medium M used.

In a further embodiment, the medium M into the interior of the optical part 10 the intraocular lens 100 or phakic intraocular lens 200 brought in.

As in 7 is shown in the interior of the optical part 10 an inner part 20 for forming an optical device E2 cast. The inner part 20 has the appropriate chromophores to filter the blue and / or violet lights.

The inner part 20 In this example, it is made of the same material as the optical part 10 the intraocular lens 100 or the phakic intraocular lens 200 , Preferably, the chromophore portion of the inner part is 20 in the area of the optical axis OA and decreases gradually to the edge of the optical part 10 out, with the inner part 20 has a smaller dimension than the optical part, so that a portion spaced from the edge of the optical part 10 is equipped without chromophore portion and thus in the seam / end edge area / transition area between inner and outer part both media of different or the same base materials are optically clear.

In 7 is the inner part 20 shown as a separate part. In this embodiment, in which the inner part 20 and the optical part 10 the intraocular lens 100 or the phakic intraocular lens 200 Made of the same material, the contours blur, leaving a one-piece optical part 10 is formed. As a manufacturing method, multicomponent casting with running components could be selected. In order to facilitate the blurring of the chromatophore dye from the center of the intraocular lens or phakic intraocular lens in its peripheries, the concentration of the solvent in the mixture can be varied.

By the shape of the inner part 20 can the desired chromophore distribution in the optical part 10 be prepared so that a filter effect analogous to the optical device e from 3 or the optical device E1 from 4 is achieved.

8th shows another manufacturing process that is similar to 5 works. The optical part 10 the intraocular lens 100 or phakic intraocular lens 200 is only as a part 10A present, so the medium M by means of the nozzle device 50 is applied to an inner region of the optical part.

After application of the medium M, the missing area of the optical part becomes 10 , z. B. by casting.

In another example, for the in 8th The production method shown, the nozzle unit 54 from 6 used analogously.

Another manufacturing method of at least the optical part 10 the intraocular lens 100 or the phakic intraocular lens 200 is determined by 9 explained. The optical part 10 the intraocular lens 100 or the phakic intraocular lens 200 is by a generative manufacturing process such. B. produced selective laser melting.

These are a laser beam source 300 and a mirror 302 provided by the laser beam source 300 emitted laser beam LS to a holding plate 304 leads. The mirror 302 is by means of an actuator 306 so adjustable that all areas of the retaining plate 304 with the laser beam LS are reachable.

By means of a variety of chambers K1 to K6 having container 308 is the precisely metered amount of powder or granules on the holding plate 304 applied. This is the container 308 by means of an actuator 310 adjustable in x-direction, y-direction and z-direction.

In addition, not shown actuators are provided, which open and close the respective chambers K1 to K6 make.

In the chambers K1 to K6 of the container 306 There are powders or granules with different chromophore content. Layer by layer, the powder or granules are applied to the holding plate 304 and then melting by means of the laser beam LS ,

The laser beam source 300 , the actuator 306 for the mirror 302 , the actuator 310 for the container 308 and the actuators for opening and closing the chambers K1 to K6 are controllable by means of a computer.

The illustrated generative manufacturing method is only illustrative and not to be construed as limiting. Thus, other generative manufacturing methods can be used.

Also, the application of the medium M can be carried out by means of a printing process. The printed medium M has a high adhesion to the optical part 10 ,

The gradient of the chromophore effect can also be adjusted by means of a radiation-induced, polarimetric or magnetic method.

10 shows a schematic representation of a dip process for producing an optical part of an intraocular lens 100 or phakic intraocular lens 200 , The intraocular lens 100 or the phakic intraocular lens 200 is in a recording 40 clamped. The recording 40 with clamped intraocular lens 100 or phakic intraocular lens 200 gets into the medium M lying in a trough-shaped container 60 is recorded, dipped and then removed again from the medium M. The medium M forms the optical device e analogous to the embodiment according to 3 ,

The curing process is time-controlled as a function of the viscosity of the medium M and the desired filter effect free of prismatic drop formation. This is z. B. achieved with a suspension device, not shown, the dripped or raised from the dip intraocular lens in the manner of a spit 100 or phakic intraocular lens 200 such that the potentially possible drop formation, caused by the gravitation, is counteracted. This can be exemplified by mechanical means, e.g. B. by air or liquid jets, or carried out in a chemical manner.

Although in 10 for example, a single intraocular lens 100 shown is the recording 40 also be designed to be a phakic intraocular lens 200 absorbs or a variety of intraocular lenses 100 and / or phakic intraocular lenses 200 at the same time.

In a further, not shown embodiment is on the optical part 10 the intraocular lens 100 or the phakic intraocular lens 200 in the material of the optical part 10 diffusible medium M used in a targeted amount on the optical part 10 is applied and in the material of the optical part 10 diffused.

There are z. As used colors that have solvents that have a solubility of the material of the optical part 10 make, such. As benzene, toluene, esters, ketones and chlorinated hydrocarbons. The diffusibility can also be influenced by influencing the temperature of the colors or the material of the optical part 10 to be controlled.

Also, hybrids between the described embodiments are expressly possible. So z. B. an optical part 10 that is both an interior part 20 as well as a coating 14 has, be formed.

The present invention relates to an intraocular lens or phakic intraocular lens which has an optical part with an optical device which influences the beam path of blue and / or violet light components. The optical device is designed such that it influences the beam path of the blue and / or violet light components in such a way that these light components are filtered.

The optical device changes the optical path so that in a region adjacent to the optical axis of the optical device in a continuous manner less light components emerge than in a region remote from the optical axis. As a result, the blue light components are effectively attenuated, with a gradual transition, as in the explained prior art, effectively prevented. This is realized in a preferred manner in that the optical device is formed by a coating applied to the optical part of the intraocular lens or phakic intraocular lens coating, whose filtering effect is greatest in the region of the optical axis and decreases toward the edge of the optical part or its portion of chromatophores is greatest in the region of the optical axis and decreases towards the edge of the optical part. The dosimetric function of the natural mydriasis and miosis to protect the macula from the blue light wave spectrum under extreme light exposures is thus naturally achieved by the optical unit protected in this patent.

According to the invention, the optical device changes the beam path so that in a region adjacent to the optical axis of the optical device in a stepless manner more blue and / or violet light components emerge from it than in a region remote from the optical axis. This embodiment relates to photosensitivity, e.g. B. persons suffering from aniridia or albinism. This is realized in a preferred manner in that the optical device is formed by a coating applied to the optical part of the intraocular lens or phakic intraocular lens coating whose filter effect is smallest in the area directly next to the optical axis and increases towards the edge of the optical part or their proportion of chromatophores in the region directly next to the optical axis is smallest and increases towards the edge of the optical part. This serves to functionally replace the missing dosimetric function of the natural mydriasis and miosis and to protect the macular protection against the blue light wave spectrum under extreme light exposures. This embodiment of the invention has two stepless blue / violet light filter gradients. Lowest filter effect in the area adjacent to the optical axis OA still open in the field under normal lighting conditions pupil towards the optical axis OA and the second filtering action increasing towards the periphery.

The optical device is formed in particular by an inner part introduced into the interior of the optical part or is produced by a generative manufacturing method. As a result, contact of the blue light and / or violet-filtering medium with areas of the eye is avoided, so that allergic reactions are excluded.

The coating or the inner part consist in particular of yellow-colored acrylate, methacrylate, hydrogel, silicone polymer and derivatives and combinations of these or of another immunologically compatible, inert material and the intraocular milieu of the eye adapted material. Since known materials are used, inexpensive production of the intraocular lens or phakic intraocular lens is possible.

In one embodiment, the optical device is formed by prism ring-type phakic intraocular lenses placed in the front and back of an intraocular lens or in front of and behind an intraocular lens, which initially spread the entire light spectrum chromatically within the path of the optical part and then partially recombine it. This achieves the inherent Newtonian chromatic aberration in the natural eye lens.

A method for producing an intraocular lens or a phakic intraocular lens comprises the following method steps: positioning the intraocular lens or the phakic intraocular lens on a recording, applying or introducing a blue light and / or violet-filtering medium onto a central region of the optical part of the intraocular lens or the phakic intraocular lens, and putting the recording in rotation. In a further embodiment, the method for producing an intraocular lens or a phakic intraocular lens comprises the following method steps: positioning the intraocular lens or the phakic intraocular lens on a recording, setting the recording in rotation, and applying a blue light and / or violet light filtering medium to a central region of a optical region of the intraocular lens or the phakic intraocular lens. With these methods, a simple production of an intraocular lens or phakic intraocular lens with the blue light components and / or violet light components filtering properties is possible.

When using a multi-component casting process and the use of generative manufacturing processes, a particularly precise distribution of the chromatophores can be made possible.

A further method for producing a stepless blue light filter of an intraocular lens or a phakic intraocular lens comprises the following method steps: positioning the intraocular lens or the phakic intraocular lens and applying or introducing a blue light and / or violet light filtering medium, which is absorbed / absorbed by the intraocular lens material respectively phakic intraocular lens material a change or damage of the material properties, and in particular free from a change in the refractive properties of the intraocular lens or intraocular contact lens by means of a precisely centered injection or drip device, the cohesion and adhesion forces, including the natural gravity of gravity, in a central region of a optical part of the intraocular lens or the phakic intraocular lens to achieve a continuously decreasing gradient of yellow tint, the v. From the center in the periphery v on the intraocular lenses to be sounded or phakic intraocular lenses decreases.

Another method for producing an intraocular lens or phakic intraocular lens having an optical part with an optical device which influences the beam path of blue and / or violet light components includes the use of a vertical submersible method by means of exactly the front or rear hemisphere the intraocular lens or the phakic intraocular lens completely or only in the optical range of the slightly beyond the size of the pupil in the narrow state out in strong light acting section with the convex surface immersed immersed slowly from the immersion medium with Chromatophorenhaltigen as possible without metallic content existing dye to raise and according to the acting time the longest held at the apex of the intraocular lens or the apex of the phakic intraocular lens in the dip tank there to achieve the highest dye concentration in contrast to the eq peripheral peripheral region of the intraocular lens to be stained or phakic intraocular lens. The timely continuous elevation from the dip ensures the stepless and thus no aberration phenomenon leading decreasing Chromatophoren tint from the pole point of the intraocular lens or phakic intraocular lens in their peripheries. The double-gradient staining for z. For example, patients such as albinos and absent iris patients may be prepared by time variations of immersion and elevation from the immersion bath, differential spray diameters in the dripping process, and different immersion diameters in the processes described above.

In the described method can also influence the temperature of the medium M be made to the desired filtering effect of the optical part 10 to achieve. In particular, in the polymerization of colored and non-colored medium using the centrifugal force method, a seamless gradient can be fixed by the action of temperature differences. By using various concentrations of solvents according to the in the 5 . 6 . 8th and 10 shown methods of both different concentrations of the medium M according to the in 9 shown method, a desired degree of the filtering effect of the optical part 10 be achieved. In the case of metallic components in the color medium (prevention of corrosion) or other unfinished intraocular lens or intraocular contact lens harmonization in the intraocular milieu, application of a glaze or protective sheath of acrylate, methacrylate, hydrogel, silicone polymer and derivatives and combinations from this or another immunologically compatible, inert material and material adapted to the intraocular milieu of the eye, the harmonization of that optical unit in the eye is achieved.

Claims (1)

Intraocular lens having a filter device formed by chromatophores absorbing blue and / or violet light components, wherein the filter device has a double gradient with - the strongest filter effect directly in the region of the optical axis (OA), - the weakest filter effect in an area directly spaced from the optical axis (OA), but within the field of a normal-sized pupil and - a rising to the edge of the intraocular lens filtering action, characterized in that the filter means is formed continuously.

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