FR2622984A1 - Contact lens forming a solar filter - Google Patents

Abstract

The contact lens 10 of the invention is placed over the eye 1, matching the shape of the cornea 2, and ensuring its position centred on the axis X-X of the pupil 3 by its bevelled edge 12 bearing on the choroid. The lens 10 is provided, on the pupillary axis X-X, with a substantially circular tinted zone 13 which forms a solar filter and the diameter of which is approximately 2 mm. Under high illuminations, the pupil 3 contracts to a diameter less than that of the tinted zone and the incident flux passes, for the most part, through the tinted zone 13. Under lower illumination, the pupil dilates beyond the diameter of the tinted zone 13, the filter role of which is attenuated. The physiological effect is equivalent to that of sunglasses with absorption which can vary as a function of the illumination, but the protection is invisible.

Description

"Contact lens forming solar filter"
The invention relates to a contact lens, in particular a soft lens1 for protecting the eye against excessive light radiation.

 To protect the eyes from excessive light radiation, such as full sun, sunglasses are used which have tinted lenses to partially absorb the light radiation; the glasses can be neutral gray to also absorb the radiation over the extent of the solar spectrum, or have preferential absorption regions in the spectrum, in particular at the limits of the visible.

 Sunglasses have two kinds of drawbacks; they mask part of the screwing and they must be handled frequently to respond to variations in lighting.

 The disadvantages of the first kind have psychological foundations: the wearing of glasses passes for unsightly, even if, in particular in the field of sunglasses, the manufacturers of glasses seek presentations which confer on the face an esthetic contribution, and takes away the physiognomy part of its expressiveness: moreover, the shadow cast by the glasses induces uneven tones visible when the glasses are removed.

 The disadvantages of the second kind can be summarized as follows: either the wearer, in response to variations in lighting such as those experienced when entering a room from outside, or leaving this room to the outside, take off or put on his glasses again, at the risk of damaging or losing them; or else the wearer keeps his glasses on when entering a dark zone, where he is partially blind, or does not put them back on when returning to an area with strong light, and is partially blinded by dazzling.

 This kind of drawback becomes particularly annoying, for example, for a car driver who takes a road tunnel, whereas the consequences of a temporary vision obliteration can be serious, while the handling of glasses is often inappropriate.

 These disadvantages of the second kind can be overcome in the case of sunglasses, by the use of photosensitive lenses with variations in absorption. Note, however, that the lens accommodation time constant remains relatively large. Temporary vision loss occurs when the lighting variations are abrupt.

 It is understood that contact lenses forming sun filters suppress. radically the disadvantages of the first kind.

 But it is excluded to remove and put back contact lenses as one can do it with glasses. In addition, it would be practically impossible to keep the lenses securely other than in place over the eyes.

 The object of the invention is to produce contact lenses for sun protection, which do not appreciably modify the natural accommodation of the eye to variations in light level, and which can benefit from all the improvements in physiological tolerance. that we bring to contact lenses.

 For this purpose, the invention provides a contact lens, in particular a flexible lens, intended to protect the eye against excessive light radiation, characterized in that it includes a tinted area capable of partially absorbing the incident radiation, this tinted area coming to be placed in the axis of the pupil of the eye.

 As the tinted zone is in contact with the eye in the axis of the pupil, this one, with the strong illuminations, is contracted so that the light which penetrates in the eye crossed, at least in major part, the tinted area. The lens then behaves like a sunglass lens.

 If 1. ' illumination decreases, the pupil dilates; the light that enters the eye then passes partly through the tinted area, and for the rest around this area. Attenuation is reduced on average.

 If the overall lighting is poor, most of the light will enter the eye, passing around the tinted area.

 It will be noted that the lighting transitions will receive the pupil's response with physiological time constants, and that the variations in light flux received by the eye will be less significant than the lighting variations, since the transmission of light at high illuminations is attenuated.

 In other words, the response speed is higher than that of the naked eye.

 Preferably, the tinted area is circular, to correspond to the shape of the pupil. The diameter of this zone will preferably also be between the extreme pupil diameters resulting from the accommodation to light, so that the variable mean transmission effect is obtained.

 A diameter of the order of 2 mm may well be suitable.

 Of course, the tinted area may be neutral gray or have selective absorption ranges, in particular towards the limits of the visible spectrum.

 In another aspect, the invention provides a method of manufacturing a sun protection contact lens, where the lens is placed on a support in a form suitable for imparting a determined position relative to a pupillary axis, a tube is approached injector along this axis until contact with the lens, the inside diameter of the tube corresponding to the chosen diameter of the area to be tinted, a solution dye is injected through this tube capable of diffusing into the lens material, the dye on contact for a sufficient time to obtain a desired coloring density, the injector tube is removed and the lens is washed to remove excess dye.

Characteristics and advantages of the invention will emerge from the description which follows by way of example, with reference to the appended drawings in which
FIG. 1 represents an eye provided with a lens according to the invention, seen in section
Figure 2 is an enlarged front view of a lens according to the invention
Figure 3 is a section along the plane III-III of Figure 2
Figure 4 is a schematic representation of the manufacturing process of a lens according to the invention.

 As can be seen in FIG. 1, the eyeball 1 has a slightly protruding cornea 2, due to a radius of curvature slightly less than that of the globe 1 proper. The cornea 2 is transparent and lets appear the tinted iris, with in its center a pupil 3 which appears in black. As is known, the iris is capable of dilating or contracting the pupil 3 to regulate the light flux which enters the eye 1, as a reflex of the recording of this light flux by the optic nerve.

According to the invention, the eye 1 is provided with a lens
contact contact 10, here of the so-called flexible type made of hydrophilic polymer material. This contact lens 10 follows the curvature of the cornea 2, and carries by its edge 12 on the choroid, of greater radius of curvature than the cornea 2, so that its axis of symmetry XX coincides with the main optical axis of the eye and goes in particular through the center of pupil 3.

 In the center of the contact lens 10 is a zone 13, which is substantially circular, tinted so as to constitute a sun filter similar to a sunglass lens.

 The color of the central zone can be a neutral gray, with substantially the same absorption rate over the extent of the visible spectrum, so as not to substantially alter the perception of colors. It is generally preferable to use for this area a dye (generally a mixture of co-dyes) which will have a uniform absorption over most of the visible spectrum, the absorption increasing frankly in violet to effectively filter the ultraviolet, and possibly having a growing in deep red.

 As best seen in Figures 2 and 3, the lens 10 thins bevel 12 on its edge, to allow the flutter of the eyelids and the renewal of the tear fluid in contact with the lens. In its present representation, the thickness of the lens is uniform inside the bevel 1, since it is not asked for a correction of ametropia, no more than with a normal glass of sunglasses. We have exaggerated the thickness of this lens to make this point more visible. But it goes without saying that the present invention can also be applied to contact lenses shaped for a correction of myopia or hyperopia.

 The tinted central zone 13 has an intermediate diameter (see FIG. 2) between the maximum diameter 3a that the pupil can take in low light, and the minimum diameter 3b that the pupil takes in intense light. For the reasons that will be developed below, the diameter of the preferable central zone would be that of the pupil for the illumination from which the wearing of sunglasses (in the current state of the art) is appropriate.

 Of course, this lighting threshold varies with individuals, as does the diameter of the corresponding pupil. We will therefore choose an average value, which we currently accept close to 2 mm.

 At intense illuminations, the pupillary diameter becomes smaller than the diameter of the tinted area 13. As the lens 10 is in contact with the cornea 2, a major part of the incoming light flux passes through the tinted area 13 which attenuates this flow. The protection and attenuation provided are then comparable to that of conventional sunglasses.

 As the illumination decreases, the pupillary diameter will increase until it reaches and then exceeds the diameter of the tinted area 13. The luminous flux entering the eye will then pass, for its central part, through the tinted area 13, and for a peripheral part, through the non-tinted area of the lens 10. Thus the cooperation of the tinted area 13 and the clear lens crown between the tinted area and the periphery with pupil diameter makes the lens 10 play the role a variable density filter, adjusted by the pupillary accommodation reflex.

 Furthermore, the pupillary opening varies as the square of the diameter. For a pupillary diameter twice that of the tinted area 13, three quarters of the incident light flux enters the eye without absorption, while the fourth quarter is attenuated by the tinted area.

 Also, for reduced lighting levels, the attenuation provided by the tinted area 13 becomes negligible; it is unnecessary to remove the contact lenses of the invention in dimly lit places.

 In addition, at light transitions, pupillary accommodation will be performed on weighted light values.

 It will be noted that, although the lens 10, located in contact with the cornea, is a short distance from the pupil, it is located in front of the main optical plane of the lens. As a result, an image of the very blurred tinted area is formed on the retina, with maximum attenuation of the light flux on the axis, and a monotonous attenuation decrease by deviating from this axis. In the field of vision, a darkened central area appears, surrounded by a lighter ring, with a gradient transition. Also, the central area of the retina, or macula, which is more sensitive to light, is better protected than the less sensitive peripheral areas.

 It will be noted on this subject that, in binocular vision, if the areas tinted. contact lenses are not placed in the same way with respect to the pupillary axes, it will appear in the field of vision two offset peripheral rings (analogous to the field of vision of binoculars incorrectly adjusted to the pupillary distance). If only one peripheral ring appears in the binocular field of vision, this will be a sign of correct centering of the contact lenses.

 In addition, the image perceived by a subject results from an interpretation in the cerebral cortex of retinal images, which favors the details of the image to which the subject pays attention over the details disdained.

As soon as the subject focuses his attention on the center of the retinal image, he "forgets" the presence of the peripheral ring.

 To proceed with the coloring of the tinted area 13, it is possible to operate as shown diagrammatically in FIG. 4.

 Take a lens 10, flexible1 either neutral for protection against excessive light radiation, or convergent or divergent shape if you also want to correct farsightedness or myopia, respectively, and dilate it in physiological saline.

 The lens 10 is placed, by its concave face, on a convex support 20a of appropriate radius, machined-in a flat frame 20 to which it is connected by a groove 21 such that the bevelled edge 12 of the lens 10 is housed in this groove 21 practically without play. Thus the center of the lens 10 is located on the axis of the convex support 20a.

 One descends along the central axis of the support 20a, perpendicular to the frame plane 20, a tube 22 whose internal diameter corresponds to the diameter of the area to be tinted 13, until it comes into contact with the convex face of the lens 10. The tube 22 extends an ampoule 24 containing a dye 23 in solution, the dye being chosen for its absorption spectrum and its ability to be fixed on the lens material, and the solvent for its compatibility with the dye and its ability to diffuse. in the lens material. During the descent, the dye solution 23 is slightly depressed in the bulb 24, so as to form, at the end of the tube 22, a concave meniscus.

 The bulb 24 is put under slight overpressure so as to bring the dye 23 into contact with the lens 10, and the dye solution 23 is allowed to diffuse in the lens 10 for a time determined experimentally; the overpressure is removed and the tube 22 is raised.

 The lens is immersed in a fixing bath, for example of the tanning type.

 The lens is rinsed thoroughly, then soaped.

 The lens is sterilized in a 9 gil sodium chloride solution.

 Checks are carried out before packaging the lens in the usual way for sale.

 It will be appreciated that the lenses of the invention allow the protection of the eyes against excessive light radiation, without the means of this protection being visible to third parties. In particular, in places where the lighting is moderate, the tinted area is smaller in diameter than that of the pupil and does not stand out against the black background.

 But in addition, the lenses of the invention could be invaluable for the filming of cinema or television scenes where the actors, working in an atmosphere with high illumination, may be forced to do without protective glasses because of requirements. of their roles.

 The advantages of the lenses of the invention have already been mentioned above for vehicle drivers, when they undergo marked transitions in illumination.

 Finally, it goes without saying that the invention, in combination with contact lenses for ametropia correction, allows wearers of combined lenses to take full advantage of all the advantages provided by corrective lenses, even at lighting levels. very high.

Claims (7)

 1. Contact lens (10), in particular flexible lens, intended to protect the eye (1) against excessive light radiation, characterized in that it comprises a tinted zone (13) capable of partially absorbing the incident radiation, this tinted area (13) coming to be placed in the axis (XX) of pupil (3) of the eye.  2. Lens according to claim 1, characterized in that the tinted area (13) is substantially circular.  3. Lens according to claim 2, characterized in that the tinted area (13) has a diameter between the extreme diameters (3a, 3b) of accommodation of the pupil.  4. Lens according to claim 2 or claim 3, characterized in that the tinted area (13) has a diameter of about 2 mm.  5. Lens according to any one of claims 1 to 4, characterized in that the tinted area (13) has a substantially equal absorption for the visible spectrum.  6. Lens according to any one of claims 1 to 5, characterized in that the tinted zone (13) has an enhanced absorption at the limits of the visible, at least on the violet side.  7. Method for manufacturing a contact lens (10), in particular a flexible lens, intended to protect the eye (1) against excessive light radiation, this lens (10) comprising for this purpose a circular tinted area (13) of chosen diameter, able to partially absorb incident radiation, which is placed in the axis (XX) of pupil (3) of the eye (1), characterized in that the lens (10) is placed on a support of a specific shape to give the lens a determined position relative to a pupillary axis (XX), an injector tube (22) is approached along this pupillary axis (XX) until contact with the lens (10), injects through this tube (22) a dye in solution (23) capable of diffusing into the lens (10), the dye (23) is kept in contact for a predetermined time, the injector tube (22) is removed, and fixed the dye and the lens is washed.