CS245361B1 - Intercameral lens and method of its production - Google Patents

Abstract

The subject of the invention is intracameral a lens that is made of synthetic a sparingly hydrophilic gel, which in equilibrium with saline a refractive index ranging from 1.38 to 1.45. Her the front wall has the shape of a flat ellipsoid with a radius of curvature of 5 5 to 15 mm, the back wall is spherical or has a rotating surface second order of the radius of curvature 5 to 7 mm and the edge surface is shaped a general anhloid, with a central thickness lens is. 2 to 5 mm. It is produced by mixing a mixture of monomers, solvents and pouring the polymerization catalyst into an open concave mold of material which makes the wetting angle larger with the mixture than zero in which it has a concave rotation symmetrical spherical or rotational surface second-order area and this area is terminated horizontal circular sharp edge wherein the volume of the monomer mixture to be metered is 10 to 80% larger than the void volume form, then the mold is brought up temperature or irradiation in an inert atmosphere into the polymerization conditions of the monomer mixture, the polymerized casting is washed with water or alcohol and finally equilibrate with saline.

Description

The present invention relates to an intracameral lens and to a process for the manufacture thereof.

So far, intracameral lenses, i.e., prosthetic replacements for the missing ophthalmic lens, have been prepared predominantly from polymethyl methacrylate or from glassy masses similar to the refractive index substantially higher than the refractive index of the 1,396 natural lens crystallina of the human eye.

For example, the most commonly used methyl methacrylate has a refractive index of 1.53. In order to achieve the same refraction in the immersion environment of the anterior or posterior chamber as if the natural lens were missing, the artificial material of this kind needs to be shaped quite differently, ie with substantially less curvature of both optical surfaces than we find with a natural lens. so that the artificial lens of this material is in the same location as defined in the eye for the natural lens. Another difference between conventional materials and the natural lens is its substantially higher specific gravity, which is about 1.25 compared to the specific gravity of the natural lens, which is about 1.1. Since the gravitational effect on lenses immersed in an intraocular fluid of 1.04 specific gravity is proportional to the difference between the specific weights of the material and the immersion environment, the lens of conventional material in the eye appears several times heavier than a natural lens. The current practice seeks to mitigate this disadvantage by constructing artificial intracameral lenses as thin as possible, which in turn increases the shape difference from a natural lens further. In order to keep the miniature but relatively heavy lens in a central position, many modifications have been proposed and applied, which consist in attaching to the rim of the lens in the form of differently shaped fibers or foils the projections which support the lens either o angulus iridis in the anterior chamber or which are anchored directly in the iris.

The subject of the invention is an intracameral lens which is made of a synthetic thin-screened hydrophilic gel which, in equilibrium with saline, has a refractive index in the range of 1.38 to 1.45. Its front wall is in the form of a flat ellipsoid with a central radius of curvature of 7 to 15 mm, the rear wall is spherical or has a second-order rotating surface with a central radius of curvature of 5 to 7 mm and the peripheral surface has a general torus shape. mm.

As a synthetic thin-cross-linked hydrophilic gel, copolymers of 2-hydroxyethyl methacrylate with acrylic or methacrylic acid or diglycol methacrylate with up to 1% by weight may advantageously be used. vlcefunctional crosslinker. By using this material it is possible to achieve the desired optical correction in the lens construction corresponding very closely to the refractive index, specific mass, volume and shape of the natural lens, i.e. with a thickness several times greater than that of the intracameral lenses used hitherto.

If the described lens itself could not be kept exactly in the central position in the eye, its correct position can be fixed by means of stitches. Since the stitches could easily be cut through the thin gel, the lens can be treated such that at its peripheral portion not extending into the optical zone, i.e. beyond about 6 mm in diameter, the polymerized textile structure is preferably of a corrugated shape. A lens of this kind is readily manufactured by disintegrating, for example, a corrugated thin knit of polyester yarn, embedding it with a monomer mixture to form the upper convex meniscus, and processing as described above.

It is a further object of the present invention to provide a method for producing an intracameral lens comprising pouring a mixture of monomers, solvent and polymerization catalyst into an open concave mold of a material which forms a contact angle greater than zero with the mixture in which the concave rotationally symmetrical surface is spherical or second-order rotary surfaces and this surface is terminated by a horizontal circular sharp edge. The monomer mixture is metered into the mold cavity in a quantity greater than the volume of the cavity below the mold edge. If the mold material is not completely wettable or even completely non-wettable, for example teflon, the monomer mixture does not flow over the edge, but forms a convex surface of the type of flat rotating ellipsoid, i.e. the one required for the lens described above. .

Depending on the amount of overdose above the volume of the mold cavity, any central radius can be adjusted on this protruding drop without the slightest difficulties in the field of central curvature that may be considered. The most suitable shape of the protruding meniscus of the liquid is obtained if the dispensed volume of the liquid is 10 to 80% greater than the volume of the cavity of the mold below its horizontal edge. After the metering has been carried out, the monomer mixture is brought to polymerization conditions, i.e., in an inert atmosphere, to the polymerization temperature or to photochemically effective light using photoinitiators. After the polymerization is finished, the casting can be removed from the mold, or even with the mold, immersed in water, where it will fall out of the mold spontaneously.

The lens no longer requires any additional mechanical adjustments as its surfaces are perfectly optically accurate and completely smooth. It is sufficient to wash it perfectly into extractable low-molecular impurities with water or aqueous alcohol and finally to equilibrate with saline, where it can be stored indefinitely after sterilization.

The lens according to the invention can also be produced by treating the highly hydrophilic material to the anhydrous or near-anhydrous state of the so-called xerogel and bringing it to the desired shape by turning, grinding and polishing, for example, but to a reduced scale. swell with water to the desired size. Although this method is technically feasible, it is very expensive, especially for the inevitably large proportion of human labor.

The production of the described lens by monomer casting in two-piece casting molds has not been successful because it is a relatively massive casting, which during polymerization undergoes considerable shrinkage, which either leads to the formation of bubbles or to destruction of the casting.

An advantage of the described lens is that it can be applied during cataract surgery to the void that remains after removal of the cloudy lens. If the operation was conducted so that the posterior capsula lensis was retained after lens elimination, the space for the shape and size of a similar artificial lens is precisely delimited by this thin natural film, which is generally perfectly transparent. Depending on the shape and volume or weight of the removed lens, the closest matching lens to be placed in place of the removed lens can be found from a larger pool of these readily available intracameral lenses. The softness of the strongly hydrophilic gel which can be introduced into the posterior chamber of the eye by the thin-walled tube through the pupillary opening smaller than the diameter of the artificial lens in its fully relaxed state is advantageously used. In principle, there is also the possibility of introducing a partially or completely dried lens whose dimensions are greatly reduced by the pupillary opening. By swelling in equilibrium with the surrounding vitreous humor or aqueous humor, the treated lens acquires its definite size after a short time of several hours.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is illustrated in greater detail in the accompanying drawing, in which: FIG. 1 is an axial sectional view of the intracameral lens of the present invention; and FIG. 2 is an axial sectional view of the casting mold;

1 shows the individual surfaces of the lens according to the invention in the form of their meridian curves: the upper surface 1 in the form of a flat ellipsoid, the lower surface 2 in the form of a spherical shape and the peripheral surface 2 in the form of a general torus.

A casting mold with varying amounts of the dosed mixture is shown in Fig. 2. The mold cavity 2, terminated by a sharp edge 5, defines a space for a monomer mixture whose excess volume is enclosed by a surface tension in the portion 6 which projects above the edge.

The curves a, b, c, d indicate the cross-section of the surface of the convex meniscus, which is produced by a gradually increasing amount of the dosed mixture. í &

Example

A mixture of 10 ml of 2-hydroxyethyl methacrylate, 0.03 ml of ethylenedimethacrylate and 0.16 g of sodium methacrylate is diluted with 10 ml of glycerin. After all components are completely dissolved, 0.015 g of ammonium persulfate as a 25% aqueous solution is added to the mixture as polymerization catalyst. The homogenized clear liquid is filled into the polypropylene molds shown in Figure 2, the cavity of which is formed by a central spherical cap and ball radius of 6 mm and a width of 9 mm, followed by a torus surface created by rotation of a 1 mm diameter meridian circle. from 3.7 mm axis. The torus surface ends with a sharp circular edge of 9.4 mm diameter that defines a sagittal mold depth of 2.9 mm. The cavity volume of this mold is 134 microliters. The volume of the dosing mixture was measured to obtain four kinds of lenses according to different doses: 181, 214, 247 and 278 microliters.

The molds, which are still held in a horizontal position, are then carefully inserted into a tunnel heated to 75 ° C in which an inert atmosphere is maintained by a gentle stream of nitrogen.

After thirty minutes, the polymerization is already brought to virtually full conversion. The gel casting molds are allowed to stand for 24 hours at distilled water in distilled water, after which time the lenses are released from the molds. For perfect washing, they are heated for several days at 80 ° C in 50% aqueous isopropyl alcohol, which is replaced every day. The next few days are similarly washed with distilled water and the washed lenses are finally stored in an aqueous solution of 0.6% sodium chloride (NaCl) and 0.43% sodium bicarbonate (NaHCO3), in which they remain ready for surgical application. According to the four different doses of the monomer mixture, the lenses have the following parameters: 4.1; 4.9; 5.6 and 6.3 mm, central curvature of the front face 15, 10, 8 and 7 mm, brittleness in the immersion of saline 13; 15; 16.5 and 18 dioptres. The refractive index of all these lenses is 1.41 and all have the same diameter of 9.4 mm.

Fig. 2 shows an axial section thereof, with their front surface corresponding to curves b, 4 *

If the monomer mixture is prepared by diluting the amount of monomers with a different volume of glycerin than 20 ml, a lens of the same shape but of a different size is obtained after all the final operations. If added in ml of glycerin, the size is changed from the original by -1/3 by the factor f = (0.4 + 0.04 V). For example, if the monomer mixture is only diluted with 7 ml of glycerin, all length measures such as diameter, thickness and radius of curvature will be increased by a factor of 1.14, if diluted with 20 ml of glycerin, the lenses will be reduced by a factor of 0.94. Since the dilution of the monomer mixture has no significant effect on the resulting refractive index of the gel, the refraction is changed so that the above-mentioned values have to be divided by the relevant factor f.

Similarly to the gel type, other sparsely crosslinked hydrophilic polymers having a refractive index in the range of 1.38 to 1.44 in equilibrium with the physiological environment, for example, copolymers of hydroxyethyl methacrylate with diglycol monomethacrylate crosslinked with a small amount of triglycol dimethacrylate or terpolymers of hydroxyethyl methacrylate . Possible monomer components are salts of itaconic acid, vinylpyrrolidone, methacrylic acid amides, methacrylonitrile and other hydrophilic monomers.

Claims (6)

An intracameral lens, characterized in that it is made of a synthetic sparse hydrophilic gel which, in equilibrium with saline, has a refractive index in the range of 1.38 to 1.45. 2. An intracameral lens according to claim 1, wherein the front wall has a flat ellipsoid shape having a center radius of curvature of 7.5 to 15 mm, the rear wall is spherical or has a second order rotational surface with a center radius of curvature of 5 to 7 mm and an edge. the surface has the shape of a general torus, the central thickness of the lens being 2 to 5 mm. 3. The lens of claim 1, wherein the hydrophilic gel is a copolymer of 2-hydroxyethyl methacrylate with acrylic or methacrylic acid or with diglycol methacrylate with up to 1% by weight. multifunctional crosslinker. 4. An intracameral lens according to claim 1 or 2, characterized in that a textile structure, for example of a corrugated shape, is polymerized in its peripheral portion with a diameter of 6 mm. 5. An intracameral lens according to claim 1 or 2, characterized in that it is housed in a thin-walled container with, for example, a hydrophilic inner surface that tapers to one open end to a diameter smaller than the diameter of the intracameral lens. 6. The method of claim 1, wherein the mixture of monomers, solvent, and polymerization catalyst is poured into an open concave mold of a material that forms a contact angle greater than zero with the mixture in which the concave rotational symmetrical surface is spherical. or a second-order rotational surface and this surface is terminated by a horizontal circular sharp edge, wherein the volume of the monomer mixture being dosed is 10 to 80% greater than the mold cavity volume, then brought to the polymerization conditions of the monomer mixture by increasing temperature or irradiation under inert atmosphere; the polymerized cast is washed with water or alcohol and finally equilibrated with saline.