NO138424B - MICRO-CONTACT LENS. - Google Patents

Abstract

Micro contact lens.

Description

The present invention relates to a micro contact lens

with an optically hard lens core.

Such micro contact lenses were previously manufactured from

glass, and more recently they have been made of plastic.

i As it is known, such contact lens sexes constitute -a complete

ket vision aid, not only for the correction of nearsightedness and farsightedness, but are also available for serious eye diseases such as incorrect curvature of the cornea, and can also be used to a certain extent

tes for complete replacement of the eye lens.

The hard lens, which is preferred for optical reasons, gives the patient discomfort because the lens feels like a foreign body in the eye as a result of its relatively large diameter.

However, even in the manufacture of plastic lenses, the edges of the lenses must be specially processed, as pressure points will otherwise occur on the corneas^.

Furthermore, when contact lenses are used for longer periods of time, the normal flow of tear fluid across the eye will be partially or completely stopped. As a consequence of this, the absolutely necessary supply of oxygen to the cornea will be made practically impossible. However, such an exchange of tear fluid must be continuously guaranteed, as the tear fluid takes over the relevant role of the new lens, because between the contact lens and the cornea, a new lens is formed on the eye's surface by the cavity between the cornea and the contact lens being filled with tear fluid as a result of the capillary action.

Numerous constructions have already been tried out, in that the optical part or the non-optical edge part of the lens has been provided with holes [see e.g. German "Offenlegungsschrift" 2,151,028].

However, practice has shown that in no case has it been possible to talk about a satisfactory yield of tear fluid for such a construction, because the holes are resealed for reasons that will not be discussed here, whereby the expected effect is not achieved.

Nor hydrophilic material with or without additional holes

can solve the problem. Instead, there was a further danger of bacterial contamination resulting from irritation of the edges of the eyelids when such hydraulic materials surrounded the hard core. In general, it can be said that any extraction of liquid essentially perpendicular to the micro-contact lens, to the extent that such an extraction is actually possible, on the one hand leads to the risk of bacterial contamination, and on the other hand leads to insufficient extraction of tear fluid.

In addition to this, it is a fact that for a construction with a lens with a hard core and a more or less soft edge part, there will be a lack of compatibility with the eye as a result of the presence of piastizing agents in the plastic. If, on the other hand, the lenses were hydrophilic, there would be a danger that they could absorb bacteria.

A solution to these problems was also not provided by German patent document 701,970, which worked by a self-adjusting, flexible plastic extending over the cornea and sclera, on which a hard lens was pressed into position through a slot. There was no exchange of liquid, as the eyelids could not, as was the case for later constructions, move the hard lens and thus pump tear fluid under the lens.

A new micro contact lens is now specified which does not have

the disadvantages of the above-mentioned constructions, i.e. it is pleasing

wearable, compatible and impervious to bacteria and suitable for exchange of tear fluid.

This is achieved according to the invention for a micro contact lens

with an optical, hard core characterized by the fact that the hard lens core exhibits a flatter inner curvature than the corneal curvature and is surrounded by a flexible ring-shaped edge part of another eye-friendly, impermeable material, that the flexible edge part is produced by a joint coating of liquid components A and B

on the hard lens core, A being an aliphatic isocyanate and B being a polyacrylate, in particular a hydroxyl group-containing polyacrylate with a medium high hydroxyl content.

According to an advantageous embodiment of the invention there is

over the entire inside of the annular edge part arranged annularly towards the hard core continuous waves, and the transition between the optical zone and the edge part is parabolic shaped. The ring-shaped edge part is preferably "jelly shaped" wavy at the outer edge, and the hard lens core at the circumference is designed with a triangular cross-section, the short side of which is directed towards the inside of the lens.

The effect of the plasticizer's incompatibility with the eye

can be avoided by adapting the feature that the peripheral, flexible edge zone consists of a plastic, which is usually obtained from the liquid components A and B, where A comprises the group of aliphatic isocyan-

ater, and B is representative of the group comprising polyacrylates with an average content of hydroxyl groups, preferably polymethylacrylate or a modified polymethylacrylate. The hard core is essentially made of polymethacrylate.

More particularly, the hard core of a minus lens will be somewhat bent over at its peripheral surface, although it may be constructed in the form of a V-shaped edge groove or may be provided with a tooth profile. The aim according to the present invention therefore leads to complete fulfillment of the above-mentioned conditions, as this is based on the discovery that perforations which were previously considered necessary were excessive or even harmful.

When closing the eye lids, the lens, which rests relatively flat on the eyeball, and which is spherical at least in the cornea-membrane zone, will be moved forwards and backwards, and despite its soft edges, the desired pumping effect will be maintained, whereby a satisfactory exchange of tear fluid, and therefore a sufficient supply of oxygen to the cornea.

The micro contact lens according to the present invention is therefore comfortable, wearable, compatible and impervious to bacteria, and it will also repel bacteria, as there is no place where they can settle.

The hard optical zone, as well as the transition to the flexible, soft edge can have the most different diameters, and can for example be 6, 7, 8, 9 mm etc., and in each case of the order of magnitude of the corneal lens. The connection between the flexible edge and the hard core can be improved by making use of the feature that during polymerization a small part of the plastic will form a plug connection through a hole in the hard core.

The different types of connection between the peripheral edge and a stabilized central optical zone form a sufficiently large transition surface to ensure a smooth and permanent connection.

The flexible edge. can also be produced by polymerisation, by other bonds obtained chemically, by induction welding or any melting or pressing process and in general all possible connections that allow both elements to form a close connection between the edge of the hard lens and the soft lens.

The soft, flexible edge, i.e. the peripheral zone, can be designed in a smooth parabolic shape, or with corrugations which are directed towards the optical centre. This form of corrugation can, however, be specified in the periphery. According to one embodiment, the edge is similar to that of a jellyfish, which promotes the access of tear fluid, and thus exchange.

Despite the soft edge, the pumping effect will, as follows

of eye closure, remain undisturbed, and consequently lacrimal fluid enriched with oxygen can adequately supply the cornea behind the lens.

With regard to another proposal which has become known (Swiss patent no. 473,393, according to which the entire inner surface of the contact lens is covered with a soft, flexible material) there is shown the advantage that the suction effect which can be expected in the last-mentioned case, does not take place in the present case.

A particular advantage can be obtained if the effect leading to a jellyfish-like effect is combined with a parabolic construction starting at the last third of the diameter of the hard lens. The S;now corrugators for the jellyfish construction can also be produced during the polymerization itself.

If the flexible edge part is polymerized from the two liquid components, corrugations or small channels can in this case be directly formed at the same time. The polymerization is preferably carried out on a hard substrate, preferably on a metal-coated spherical part, so that a smooth surface is obtained directly during production. There will be no trace of further processing as a result of the material's flexibility. The stresses that can be expected as a result of joining by welding do not occur in this case.

Examples of embodiments of the present invention will be described in more detail with reference to the attached drawings, where

Fig. 1 shows a first embodiment of the contact lens according to the present invention, Fig. 2 shows a possible embodiment of the transition, Fig. 3 shows a further embodiment of the transition, Figs. 4, 5 and 6 show minus lenses with different types of connection, Fig. 7 shows a further embodiment in a plan and side view.

Fig. 1-3 show positive lenses.

In fig. 1, the contact lens is constructed spherically at the apex at 1 and approx. 3.0 mm from the apex, it transitions into a parabolic shape with a smooth transition 2. The parabola overlaps the flexible edge part 3, which in this case is polymerized.

The edge of the hard lens 4 is carefully machined, and at 5 it is constructed so that it runs obliquely. The result of this is that a large, straight contact surface is formed. The edges follow the general shape of the lens and taper more and more, and end in a rounded, chamfered zone 6. From the inner to the outer direction, the chamfered zone is thus delimited by the parabolic zone and an optical zone. The ring width for the flexible material is e.g. 1 mm and the average thickness of the lens is approx. 4 mm.

The positive lens shown in fig. 2 is in cross-section bevelled in a triangular manner, i.e. bevelled from two sides, and the shorter leg extends from the inner curve of the lens. The sloping arrangement of the upper leg is approx. the same as shown in fig. 1. As a result, regardless of the connection in question, the strength of the flexible edge part will be increased significantly, as the mounted lens edge practically serves as a stabilizing core for the flexible edge part. At 7, for example, this lens has a radius for the inner curve of 8.5 mm, and at 8 the average thickness is 0.35 mm.

The optical power is 3.0 diopters. The ring width

at the peripheral edge 9 is 1 mm. In other respects, the construction is similar to that shown in fig. 1. In order to provide a further bend in the strength of the connection between the hard lens core and the peripheral part, the hard lens is provided in certain places with holes 10, through which plug-like connections are formed between the plastic above and below the lens core, which has a triangular cross-section when the plastic mass is polymerized on.

A further positive lens, shown in fig. 3, is drawn and polished in a circular manner in the outer part of the hard core at 11, which also forms a large contact surface and an advantageous transition. The semi-circular construction of the edge in the cross-section can be easily recognized. The negative lens shown in fig. 4 has a blunt edge transition at 12. The edge part is wider here. The ratio of the width of the double ring width to the diameter of the hard lens core is approx. 5.5:10. At 13 the spherical line is again indicated.

For the case of the negative lens according to fig. 5, the hard lens core 14 has at its periphery an incision 15, into which the flexible edge fits with a complementary form 16, which is connected, for example, with an adhesive.

A mechanical, very strong form of the transition can be seen in fig. 6. In this case, the edge of the hard lens 17 is machined

in a crown-like shape, as the flexible edge with two legs 18 pas-

looking over the machined part of the edge of the lens 17.

Fig. 7 shows in the upper part a plan section, and in the lower part

part a side section of an embodiment with a jellyfish-like edge, and the raised and lowered parts of the jellyfish are indicated by 19. As seen above the edge, therefore, a wave-shaped profile is indicated which is advantageous for the supply of tear fluid.

In the case of some of the lenses shown, the flexible edge portion is made by the usual application of the liquid components A and B to the hard core, in which case A is a component from the group of aliphatic xocyanates, and B is representative of - the group of polyacrylates containing central hydroxy groups.

As a substrate for the transition, a spherical part is used which is covered with a coating.

Also in the case of the jellyfish shape, this will not be noticed by the eye lid itself. In the case of polyacrylate, there may be questions about polymethylmethacrylate or a modified polymethylacrylate, which is polymerized using heat at 40 - 80°C. A polycarbonate is also suitable for production.

Alongside normal contact lenses, it is naturally also possible to produce colored lenses, cosmetic lenses, toroidal lenses

ler multifocal lenses with the.soft contact lens advantages.

Claims (6)

1. Micro contact lens with an optical, hard lens core, characterized in that the hard lens core exhibits a flatter internal curvature than the curvature of the cornea and is surrounded by a flexible ring-shaped edge part of another, eye-friendly, impermeable material, that the flexible edge part is produced by a common coating of liquid components A and B on the hard lens core, A being an aliphatic isocyanate and B being a polyacrylate, in particular a hydroxyl group-containing polyacrylate with a medium-high hydroxyl content. 2. Micro contact lens according to claim 1, characterized by. that the polyacrylate is a polymethyl acrylate or a modified polymethyl methacrylate. 3. Micro contact lens according to claim 1 or 2, characterized in that the annular edge part (3) is "seaweed" wavy at the outer edge. 4. Micro contact lens according to claim 3, characterized in that over the entire inside of the annular edge part are arranged annular waves running towards the hard core, 5. Micro contact lens according to claims 1-4, characterized in that the transition between the optical zone and the edge part is parabolic-shaped. 6. Micro contact lens according to claims 1-5, characterized in that the hard lens core at the circumference is designed with a triangular cross-section, the short side of which is directed towards the inside of the lens.