RU2587943C2 - Contact lens having peripheral zones with high modulus - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: group of inventions relates to medicine. Ophthalmic lens comprising: an optical zone adapted for vision correction, optical zone formed from a first material having a first modulus of elasticity; peripheral zone surrounding optical zone and forming an upper region, middle region and lower region, wherein peripheral area is formed from a first material; and active area of increased thickness disposed in middle region; and a thin zone located at top and bottom fields, and one or more zones with a high modulus of elasticity, embedded in thin areas in peripheral zone, wherein one or more zones with a high modulus of elasticity are formed from a second material having a second modulus of elasticity, and second modulus of elasticity greater than first elastic modulus.

EFFECT: use of present group of inventions will reduce tendency of contact lens to gather in folds.

5 cl, 4 dwg

Description

BACKGROUND OF THE INVENTION

1. FIELD OF THE INVENTION

The present invention relates to ophthalmic lenses, and in particular, to soft contact lenses containing one or more zones with a high modulus of elasticity in the peripheral region to stiffen the contact lenses to improve their operation and reduce the tendency of the contact lens to fold.

2. DESCRIPTION OF THE RELATED AREA

Myopia, or myopia, is an optical or refractive defect in the eye, in which light rays from the image are focused at a point in front of the retina. As a rule, myopia develops because the eyeball is too elongated or the contour of the cornea is too oblique. A minus spherical lens can be used to correct myopia. Hypermetropia, or farsightedness, is an optical or refractive defect of the eye in which the rays of light from the image are focused at a point behind the retina. As a rule, hyperopia develops because the eyeball is too short or the outline of the cornea is too flat. A positive spherical lens can be used to correct hyperopia. Astigmatism is an optical or refractive defect of the eye, in which the patient’s vision is blurred due to the inability of the eye to focus a point object in a focused image on the retina. Unlike myopia and / or hyperopia, astigmatism is not associated with the size of the eyeball or the degree of convexity of the cornea, but is caused by the axisymmetry of the cornea or by the incorrect or displaced position of the lens. The vast majority of cases of astigmatism are associated with the axisymmetry of the cornea. The correct cornea is axisymmetric, while in most patients with astigmatism, the cornea is non-axisymmetric. In other words, the cornea is more curved or beveled in one direction or another, thereby causing the image to “stretch” and not allow it to focus at one point. To correct astigmatism, you can use not a spherical, but a cylindrical lens or a toric contact lens.

Typically, for the correction of astigmatic vision, mechanical elements are made in the peripheral zone of the contact lens to achieve rotational stability in the eye for the required vision correction. These mechanical elements include various thicknesses around the peripheral zone of the lens, which may cause contact lenses to tend to crease in the package or when using the lenses. In addition to folding, contact lenses may not work as well as contact lenses with uniform thickness.

Soft contact lenses are generally more comfortable to wear than gas permeable hard contact lenses made of solid materials, and this is due to the materials from which the contact lenses are made, namely silicone hydrogels. These materials have a low modulus of elasticity, which makes them less rigid or hard, whereby contact lenses become more difficult to use and tend to fold in the case of contact lenses to correct astigmatism, as described above.

Thus, the configuration of contact lenses made of silicone hydrogels, which may or may not contain an astigmatism correction element having increased rigidity in the peripheral zones to improve operation and reduce the tendency of the contact lens to fold without compromising comfort, will be advantageous.

SUMMARY OF THE INVENTION

A contact lens containing peripheral zones with a high modulus of elasticity, which are the subject of the present invention, overcomes a number of disadvantages associated with soft contact lenses and, in particular, soft contact lenses designed to correct astigmatism, as briefly described above.

In accordance with one aspect, the present invention relates to an ophthalmic lens. An ophthalmic lens comprises an optical zone configured to correct vision, wherein the optical zone is formed of a first material having a first elastic modulus; a peripheral zone surrounding the optical zone, wherein the peripheral zone is formed of a first material; and one or more zones with a high modulus of elasticity embedded in the peripheral zone, wherein one or more zones with a high modulus of elasticity is formed from a second material having a second modulus of elasticity, the second modulus of elasticity being greater than the first elastic modulus.

In accordance with another aspect, the present invention relates to a method for manufacturing an ophthalmic lens. The method comprises dispensing a first material onto a front curved surface of a lens casting mold to create a portion with a first elastic modulus with a predetermined pattern, adding a second material with a second elastic modulus onto the front curved surface of the lens molding and on top of the first material, the second elastic modulus being less than the first modulus of elasticity, and pairing the rear curved surface of the mold for casting a lens with the front curved surface of the mold for casting a lens to form an ophthalmolo of a lens.

The present invention relates to a contact lens, which includes one or more zones with a high modulus of elasticity in the peripheral portion or zone of the contact lens to give the contact lens selective rigidity in these zones. By stiffening certain areas of the contact lens, contact lenses are obtained with improved operating characteristics and a decrease in the tendency of the lens to fold without compromising comfort, which is possible due to the low elastic modulus of the silicone hydrogel forming the lens. One or more zones with a high modulus of elasticity can be embedded in any type of soft contact lens for spherical, astigmatic and / or both spherical and astigmatic correction, as well as in variable and / or multifocal lenses for the treatment of presbyopia. One or more zones with a high modulus of elasticity can be formed in any suitable shape, with any suitable size, and can be formed from any suitable material. One or more zones with a high modulus of elasticity can be formed from a monomer having a higher modulus of elasticity than the monomer that forms the bulk of the contact lens, or simply by attaching an impurity to the lens monomer in a specific area.

The contact lens constituting the subject of the present invention can be manufactured using any suitable method without significantly increasing costs or complexity. This configuration can be applied to any number or type of soft contact lenses. In one embodiment, the manufacturing method simply involves adding material to the casting mold that has a higher elastic modulus than the rest of the contact lens material that does not mix or mix poorly with the rest of the contact lens material in this way that he remains on the site. In another embodiment, zones of increased stiffness can be made by varying the intensity of the curing light along the contact lens and pre-stretching the contact lens to create resistance to deformation.

In the technical description, the term "rigidity" should be understood as a function of the modulus of elasticity of the material, the thickness of the material, the shape of the material, and any stress or tension provided in this material. Thus, for a given shape and a given thickness, a material with a higher elastic modulus will be more rigid than a material with a lower elastic modulus.

BRIEF DESCRIPTION OF THE FIGURES

The foregoing and other characteristics and advantages of the present invention will become apparent after the following more detailed description of the preferred embodiments of the present invention, illustrated by the accompanying figures.

Figure 1 presents a schematic illustration of a first example of a contact lens containing a zone with a high modulus of elasticity embedded in the peripheral zone of the lens in accordance with the present invention.

Figure 2 presents a schematic illustration of a second example of a contact lens containing zones with two high elastic moduli embedded in the peripheral zone of the lens in accordance with the present invention.

Figure 3 presents a schematic illustration of a third example of a contact lens containing zones with two high elastic moduli embedded in the peripheral zone of the lens in accordance with the present invention.

Figure 4 presents a schematic illustration of an example of a method of manufacturing contact lenses containing one or more zones with a high modulus of elasticity in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Contact lenses are called lenses that are worn directly on the eye. Contact lenses are medical devices and can be used to correct vision and / or for cosmetic or other therapeutic reasons. Contact lenses have been used on an industrial scale to improve vision since the 1950s. The first contact lenses were made from hard materials, they were relatively expensive and fragile. In addition, these first contact lenses were made from materials that did not provide sufficient oxygen diffusion through the contact lens into the conjunctiva and cornea, which could potentially lead to a number of adverse clinical events. Although these contact lenses are still in use today, they are not suitable for all patients due to the low level of primary comfort. Further developments in this area led to the creation of soft contact lenses based on hydrogels, which are currently extremely popular and widely used. In particular, the silicone-hydrogel contact lenses currently available combine the benefits of silicone with extremely high oxygen permeability, with recognized wearing comfort and clinical performance of hydrogels. Essentially, these silicone-hydrogel contact lenses have higher oxygen permeability and are substantially more comfortable to wear than contact lenses made from solid materials used in the past. However, these new contact lenses are not without limitations.

Currently available contact lenses remain an effective means for correcting vision from an economic point of view. Thin plastic lenses are located above the cornea to correct visual defects, including myopia, or myopia, hyperopia, or hyperopia, astigmatism, i.e. asphericity of the cornea, as well as presbyopia, i.e. loss of ability of the lens to accommodate. Various forms of contact lenses are available, which can be made from a variety of materials to provide different functionality. Soft contact lenses for everyday wear, as a rule, are made of soft polymer plastic materials that are combined with water for oxygen permeability. Soft contact lenses for everyday wear can be disposable lenses for everyday wear or disposable lenses for long-term wear. Disposable daily wear lenses are usually worn for one day and then discarded, while long-term disposable lenses are usually worn for up to thirty days. To provide different functionality of colored soft contact lenses, different materials are used. For example, tinted contact lenses use a lighter tint to facilitate the user's search for a dropped contact lens, intensifying tinted contact lenses have a translucent shade that can enhance the user's natural eye color, colored tinted contact lenses have a dark, opaque shade that can change color the user's eye, and tinted contact lenses can enhance certain colors while dimming others. Rigid gas-permeable contact lenses made of solid materials are made of silicone polymers, but they are harder than soft contact lenses and do not contain water, which makes them better in shape and more durable, although they are essentially less comfortable to wear. Bifocal contact lenses are specifically designed for patients with presbyopia and are available in both soft and hard contact lenses. Toric contact lenses are specially designed for patients with astigmatism, and are also available in both soft and hard contact lenses. Combination lenses are also available that combine different aspects of the lenses described above, such as hybrid contact lenses.

Soft contact lenses are generally more comfortable to wear than hard, gas permeable contact lenses made of hard materials. Currently available contact lenses are made from silicone hydrogels, including ethafilcon, halifilcon, Senofilcon and narafilcon. Other silicone hydrogels include lotrafilcon, balafilcon, vifilcon and omafilcon. Typically, these materials have a low modulus of elasticity, for example, for etafilcon A, Young's modulus is approximately 0.3 × 10 ⁶ Pa, for Halifilcon A, Young's modulus is approximately 0.43 × 10 ⁶ Pa, for Senofilcon A, Young's modulus is approximately 0, 72 × 10 ⁶ Pa, for balafilcon A, Young's modulus is approximately 1.1 × 10 ⁶ Pa, and for Lotrafilcon A, Young's modulus is approximately 1.4 × 10 ⁶ Pa. Since the elastic modulus of these materials is so low, the operation of contact lenses becomes more complex. For example, with astigmatic vision correction, mechanical elements are specially made in the peripheral zone of the contact lens to achieve rotational stability in the eye for the required vision correction. These mechanical elements typically include various thicknesses in the circumference of the peripheral zone of the lens, which can lead to the tendency of the lens to fold in packaging or during operation of the lens. In particular, when trying to remove the lens from the package and / or trying to place the lens on the eye, the presence of wrinkles on the lens can make these tasks difficult. In addition to wrinkling, contact lenses may not perform as well as contact lenses with uniform thickness.

The present invention includes one or more zones with a high modulus of elasticity in the peripheral portion of the contact lens, which increases the rigidity of the contact lens in these areas to improve operation and reduce the tendency of the contact lens to fold without compromising comfort. One or more zones with a high modulus of elasticity can be embedded in any type of soft contact lens for spherical, astigmatic and / or both spherical and astigmatic correction, as well as in variable and / or multifocal lenses for the treatment of presbyopia. One or more zones with a high modulus of elasticity may contain any suitable configuration and size. For example, in one embodiment, one or more high elastic modulus zones may comprise one continuous ring around the peripheral zone of the lens. Orientation and orientation can also be adapted to the required stiffness response (i.e., the surrounding area with a high modulus can lead to a different response compared to axial spar with similar dimensions and modulus). Ring sizes can be resized to fit restrictions or specific configuration requirements. In another embodiment, one or more zones with a high modulus of elasticity may comprise one or more separate regions located on contact lenses to enhance these regions. One or more zones with a high modulus of elasticity can be formed using any number of methods using any number of materials. In one embodiment, one or more zones with a high modulus of elasticity can be formed from a specific material having a higher modulus of elasticity than the material that forms the bulk of the contact lens. In an alternative embodiment, one or more zones with a high modulus of elasticity can be formed by adding material that changes the modulus of elasticity of the main part of the material in the required areas.

Although the present invention may be particularly advantageous with soft contact lenses for correcting astigmatism, it should be noted that zones with a high modulus of elasticity can be used to improve the performance of any soft contact lens.

1 shows a first embodiment of a contact lens 100 comprising an optical zone 102, a peripheral zone 104, and a high elastic modulus zone 106. The optical zone 102 is a part of the contact lens 100 by which vision correction is achieved. In other words, the optical zone 102 provides vision correction and is tailored to a specific need, such as monofocal myopia or hyperopia correction, astigmatic vision correction, bifocal vision correction, multifocal vision correction, individual correction, or in the form of any other configuration that can provide vision correction. A peripheral zone 104 surrounds the optical zone 102 and provides mechanical stability to the contact lens 100 on the eye. In other words, the peripheral zone 104 provides mechanical characteristics that affect the location and stabilization of the contact lens 100 on the eye, including centering and orientation. Orientation stabilization is fundamental when the optical region 102 includes non-axisymmetric elements, such as elements for correcting astigmatism and / or correcting higher order aberration. In some contact lens configurations, an additional intermediate zone can be used between the optical zone 102 and the peripheral zone 104. The additional intermediate zone allows a smooth transition from the optical zone 102 to the peripheral zone 104. It should be noted that both the optical zone 102 and the peripheral zone 104 can be performed separately, although sometimes their configurations are closely related to each other in the presence of specific requirements. For example, the configuration of a toric contact lens with an astigmatic optical zone may require a specific peripheral zone to hold the contact lens in a given orientation on the eye. Toric contact lenses differ in configuration from spherical contact lenses. Part of the optical zone of toric contact lenses has two optical powers, spherical and cylindrical, which are created by curved surfaces that are essentially perpendicular to each other. To provide the necessary correction of astigmatic vision, the profiles of the optical forces must maintain a position at a specific angle to the cylindrical axis on the eye. The mechanical or external peripheral zone of toric contact lenses typically comprises stabilization means for proper rotation and orientation of the cylindrical or astigmatic axis with the installation in the required position when wearing the lens on the eye. Rotating the contact lens to the proper position when moving the contact lens or installing it on the eye is of great importance in the manufacture of a toric contact lens. It should also be noted that although in this embodiment, the elements or zones are circular or circular, it is also possible to use non-circular zones and / or non-ring configurations.

In this embodiment, one high elastic modulus zone 106 comprises an annular ring located in the peripheral zone 104, in close proximity to the outer circumference of the optical zone 102. As indicated above, the high elastic modulus zone 106 can be formed from any number of materials using any the number of methods, and in any number of configurations, depending on the necessary operating parameters of the contact lens 100. A material with a higher elastic modulus is stiffer than a material with a lower elastic modulus. The stiffness of the component, element and / or part determines how much it will deflect or deform under the influence of a given load. In the aspect of materials, it should be noted that the stiffer the material, the greater the load required for its elastic deformation; however, it should be noted that the total stiffness is not the same as the elastic modulus; the latter is an integral property of the material, while stiffness is a function of the modulus of elasticity, as well as thickness, cross-sectional area and / or element contour. Thus, for a given contour in the section and thickness, the higher the modulus of elasticity of the material, the greater the stiffness of the material in this section; on the other hand, it is possible to produce materials with identical elastic moduli to obtain different stiffnesses depending on geometric properties (for example, an element with a rectangular cross section has greater resistance to bending when the bending moment is aligned with the long side of the rectangle, compared with the short side). The increased rigidity in one zone 106 with a high modulus of elasticity will provide contact lenses 100 with the ability to fold less frequently and ease of operation.

In an alternative embodiment, zones with a high modulus of elasticity can be located at separate locations within the peripheral zone of the contact lens. Each of the Acuvue® Oasys® for Astigmatism and Acuvue® Advance® for Astigmatism lenses includes an accelerated stabilization configuration element. In this configuration, the contact lens contains four active zones of increased thickness located in the middle peripheral zone of the contact lens, and a double thin zone in the upper and lower parts of the peripheral zone. Thus, in this type of configuration, zones with a high modulus of elasticity can preferably be located in thin zones symmetrical with respect to the vertical meridian of the contact lens.

Figure 2 presents an example implementation of a contact lens 200 containing an optical zone 202, a peripheral zone 204 and two separate zones with a high modulus of elasticity 206 and 208. For the purposes of the present description, it is assumed that the contact lens 200 is made in accordance with the configuration of accelerated stabilization described above. In this exemplary embodiment, zones with a high modulus of elasticity 206 and 208 are annular structures located in regions of thinner contact lens material as described above. As in the embodiment described above, zones with a high modulus of elasticity 206 and 208 may vary in thickness, width, contour, orientation, and may contain any suitable material having an elastic modulus higher than that of the base material of contact lenses. Figure 3 presents an example implementation of a contact lens 300 with the same type of thin zones as in Figure 2 (accelerated stabilization configuration), but in which the contour of the zones with a high modulus of elasticity 306 and 308 is essentially oval in contact with the optical zone 302 and occupies a substantial part of the peripheral zone 304.

It should be noted that any suitable biocompatible materials can be used to create zones with a high modulus of elasticity in the contact lens. These materials are preferably transparent, compatible with the monomer containing the bulk of the contact lens, and have the same refractive index. Existing methods for forming contact lenses can be easily modified to make contact lenses in accordance with the present invention. Differences in monomer viscosity can be used to maintain separation during lens manufacturing. To form a lens of acceptable quality, the shrinkage and expansion coefficients of both materials must be considered.

Figure 4 presents a simple example of a method of creating zones with a high modulus of elasticity in a contact lens. In a first step, the front curved surface 400 of the mold for casting a contact lens is arranged for further processing. In the second stage, the monomer with a higher modulus of elasticity 402 is dosed according to the necessary scheme onto the plastic of the front curved surface 400 of the casting mold. As described above, any number of suitable materials may be used in this step. In a third step, the primary monomer of the lens 404 is metered on top of the monomer with a higher modulus of elasticity 402 and the front curved surface 400 of the mold. In a fourth step, the rear curved surface 406 of the injection mold is positioned or mated with the front curved surface 402 of the injection mold to form the lens and then cured using known means to create a contact lens with one or more zones with a high modulus of elasticity.

According to another embodiment, more rigid zones can be obtained by a controlled curing process with changing conditions. For example, by varying the intensity of the curing light along the profile of the contact lens, it is possible to achieve different stiffnesses obtained in different areas.

In a preferred embodiment, the core material for forming the contact lens includes narafilcon A, and zones with a higher modulus of elasticity comprise a modified version of narafilcon A with a higher modulus of elasticity. A modified version of narafilcon A is created by increasing the amount of crosslinking agent.

Although the shown and described embodiments are considered to be the most practical and preferred, it is obvious that those skilled in the art will be able to depart from the specific described and shown configurations and methods and can be used without departing from the spirit and scope of the present invention. The present invention is not limited to the individual constructs described and shown in this document, but all its constructions must be consistent with all modifications that may be included in the scope of the attached claims.

Claims (5)

1. Ophthalmic lens containing:
an optical zone configured to correct vision, wherein the optical zone is formed of a first material having a first elastic modulus;
a peripheral zone surrounding the optical zone and forming the upper region, the middle region and the lower region, and the peripheral zone is formed of the first material, and
active zones of increased thickness located in the specified middle region, and
thin zones located in the upper and lower regions, and
one or more zones with a high modulus of elasticity embedded in said thin zones in the peripheral zone, wherein one or more zones with a high modulus of elasticity are formed of a second material having a second modulus of elasticity, the second modulus of elasticity being greater than the first elastic modulus. 2. The ophthalmic lens according to claim 1, wherein the ophthalmic lens is a contact lens. 3. The ophthalmic lens according to claim 2, wherein the contact lens is a soft contact lens. 4. The ophthalmic lens according to claim 3, wherein the soft contact lens contains silicone hydrogel. 5. A method of manufacturing an ophthalmic lens according to claim 1, containing stages in which:
metering the second material onto the front curved surface of the lens casting mold to create a portion with a second elastic modulus with a predetermined pattern;
add the first material with the first modulus of elasticity on the front curved surface of the mold for casting the lens and on top of the second material, the second modulus of elasticity greater than the first modulus of elasticity; and
match the rear curved surface of the mold for casting lenses with the front curved surface of the mold for casting lenses to form an ophthalmic lens.

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