RU2824432C2 - Method of designing frameless photochromic soft contact lenses - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: description relates to a new soft contact lens with frameless photochromic material, in which the geometry of the optical and peripheral regions of the lens is optimized to provide the best cosmetic effect for the eye. Disclosed photochromic ophthalmic soft contact lens comprises: a main portion comprising an optical zone and a peripheral zone adjacent to the optical zone, wherein the optical zone comprises a refractive structure, and one or more of the optical zone and the peripheral zone comprises a photochromic dye; and a diffraction structure located within or adjacent to the optical zone. Ophthalmic lens has a thickness profile which is based on a cosmetic profile associated with a target transmission level (%T). Vision profile associated with the ophthalmic lens is determined based on at least a diffraction structure, and the ophthalmic lens has a ratio of thickness values, defined as the ratio of the thickness of the central portion of the optical zone to the maximum thickness of the peripheral zone, wherein for lenses with positive optical power, the ratio of thickness values is determined based on the thickness of the edge of the optical zone and the maximum thickness of the peripheral zone. Said ratio of thickness values is more than 0.65.

EFFECT: providing the best cosmetic effect by optimizing the thickness profile by limiting the change in the degree of darkness during activation of the photochromic dye.

40 cl, 10 dwg, 1 tbl

Description

PREREQUISITES FOR THE CREATION OF THE INVENTION

1. Field of technology

The present disclosure relates to ophthalmic structures such as wearable lenses, including contact lenses, implantable lenses, including inlays and onlays, and any other types of device with optical components, and in particular to ophthalmic devices and methods for constructing frameless photochromic ophthalmic devices.

2. Description of the prior art

Soft contact lenses are primarily designed to correct vision problems, but other aspects of the lens are also considered during the design process, such as handling (for insertion and removal of the lens), comfort, fit, or any other aspect that needs to be considered during the design process. Standard cosmetic lenses, such as colored lenses, provide cosmetic enhancement to the cornea. Typically, the printed pattern and/or colored area does not extend to the edge of the lens, thus not having a visual impact on the scleral area of the eye.

In the present description, a soft contact lens may comprise a monomer mixture comprising a photochromic dye material or may be formed from it. In one aspect, since the photochromic dye is completely mixed with the monomer of the lens material, the photochromic region may cover the entire surface of the lens, covering not only the cornea of the eye, but also the sclera. Once the lens is placed on the eye and the dye is activated, the outer region of the lens may darken (e.g., reduce T% light transmission and appear darker to the viewer). If the thickness of the peripheral part of the lens and the amount of photochromic dye are not properly selected, the transition from the edge of the lens to the sclera will not look cosmetically attractive to the user due to at least a sharp change in darkness in this area. In addition, the vision correction provided by contact lenses is typically achieved by adjusting the refractive power in the optical region. In the case of lenses with strong correction, the thickness in this optical region changes significantly. Lenses with high positive powers (e.g. above +6.00 D) will have a thick central optical zone, while lenses with high negative powers (e.g. -6.00 D) will have a thick peripheral optical zone. As an example, lenses with high positive powers will have a thick central optical zone that tapers toward the edge of the zone, while lenses with high negative powers will thicken toward the edge of the zone. The minimum thickness at either the center or the edge of the optical zone is primarily determined by the elastic modulus of the material. The variation in thickness within the optical zone is also determined by the choice of optical zone diameter. These significant thickness variations within the optical zone will also impact the cosmetic properties of the lens.

Improvements are needed.

SUMMARY OF THE INVENTION

The present invention relates to ophthalmic lenses and methods in which the lens thickness profile is designed to optimize the change in color and aspect of the lens on the eye upon activation of a photochromic dye. The present invention relates to a soft contact lens with a frameless photochromic material in which the optical region and the peripheral region of the lens are designed to provide a target cosmetic effect for the eye.

The photochromic effect within the pupil area must remain constant throughout its aperture. The so-called photochromic effect is the amount of light passing into the eye, which is defined as %T, which is the percentage of light passing through the eye when the dye is activated. This can be obtained by shifting the curvature of the anterior surface from the posterior surface by a certain amount so that the radial thickness along the area remains constant or essentially constant. The radial thickness is the thickness of the lens calculated in the direction perpendicular to the posterior surface of the lens. This setup provides the same %T regardless of the area of the lens used. This approach does not allow vision correction to be achieved by refractive power, since, based on the rules of refraction (Snell's law of refraction), the anterior and posterior surfaces of the lens must have different curvatures to provide a specific refractive power.

It may be desirable that the photochromic effect in the peripheral region does not differ greatly from the photochromic effect in the inner region. If the peripheral region is significantly thicker than the optic region, the peripheral zone will appear much darker and will not be cosmetically attractive to the wearer. Such conditions arise when using lenses with large negative optical powers, as shown in Fig. 1, where the thickness of the central part is minimal and the thickness of the peripheral part is maximal, which provides the greatest difference in thickness. Similarly, for lenses with large positive optical powers, as shown in Fig. 2, a large difference in thickness will arise between the edge of the optic zone and the peripheral region.

A person skilled in soft contact lens design can easily design a contact lens with a constant thickness from its geometric center to its edge (Fig. 3). Such a lens will provide all the cosmetic benefits, but strictly speaking, will not be able to provide adequate vision correction.

In the present description, the vision correction (e.g., according to the target vision profile) can be obtained using the approach based on diffractive optics, in which the vision correction is designed for a given thickness profile in the optical zone. The thickness profile can be optimized not in terms of the optical properties of the lens, but in terms of its mechanical properties and geometric properties to provide cosmetic properties, comfort, ease of processing and fitting. More specifically, the cosmetic aspect or cosmetic profile of the lens can include the target thickness of the lens or the percentage of photochromic dye resulting in a specific level of %T and darkness upon activation, or both. Other characteristics or performance indicators can be included in the cosmetic profile.

According to the present description, the comfort, processing and fitting aspects of the lens, determined by the properties of the lens material in combination with the mechanical and geometric properties of the lens, can be optimized or adapted independently of the vision correction. The mechanical properties of the lens material can depend on the amount of photochromic material added to the main monomer forming the lens material. Since the vision correction can be separated (e.g., completely separated, independent) from the mechanical aspect of the lens, the geometry can be optimized from a cosmetic point of view to obtain the best visual effect on the eye, especially for the peripheral region of the lens covering a portion of the sclera, where the photochromic dye can be more visually noticeable to the user when activated.

BRIEF DESCRIPTION OF GRAPHIC MATERIALS

The above and other features and advantages of the description will become apparent from consideration of the following more detailed description of preferred embodiments of the description shown in the accompanying drawings.

Fig. 1 shows a cross-section of a lens with a high negative optical power, in which the thickest region in the central optical zone is located at its center.

Fig. 2 shows a cross-section of a lens with a large positive optical power, in which the thickest region in the central optical zone is located at its edge.

Fig. 3 shows a cross-section of a lens in which the radial thickness remains constant from the center to the edge.

Figs. 4A-4B show examples of peripheral radial thickness for monofocal type contact lenses for a variety of SKUs ranging from -12.0 D to +8.00 D.

Fig. 5A and 5B show two views of an exemplary diffraction surface.

Fig. 6A and 6B illustrate an example of a soft contact lens comprising 1% photochromic dye that has been activated and 4% photochromic dye that has been activated.

Fig. 7 shows an example of a soft contact lens containing 4% photochromic dye that has been activated.

Fig. 8 shows an example of a soft contact lens containing 1% photochromic dye that has been activated.

Fig. 9 shows an example of a soft contact lens containing 1% photochromic dye that has been activated.

Fig. 10 shows a cross-section of a lens in which the thickness profile in the central optical zone and the peripheral region is designed to optimize the cosmetic aspect of the lens on the eye upon activation of the photochromic dye.

DETAILED DESCRIPTION

In the present description, the contact lens may comprise a front surface or surface optical power, a back surface or base curve, and an edge. The front and back surfaces of the lens are defined by at least three regions: an inner region that provides vision correction, an outer peripheral zone of the lens that provides mechanical stability of the lens on the eye, and an intermediate region located between the inner region and the outer region and used to merge the two above-mentioned regions so as to avoid inhomogeneities.

The term "optical zone" refers to the essentially central portion of the lens that provides the corrective power for a lens wearer who is ametropic or presbyopic. The term "ametropia" refers to the optical power required to provide good visual acuity essentially at a distance. This is known to include myopia or hyperopia. Presbyopia is corrected by adding an algebraically positive optical power to the portion of the optical zone to correct the wearer's near visual acuity requirements. It should be recognized that these optical powers may be provided by either refractive means or diffractive means or both.

The peripheral zone may provide stabilization of the lens on the eye, including centration and position. This region of the lens also provides mechanical properties, such as processing related to ease of insertion and ease of removal, comfort, and fit. The tightness of the lens on the eye provides either a loose fit, which may result in excessive movement, or a tight fit, which may result in insufficient movement. Positional stability may be desirable when the optic zone contains elements that are non-rotationally symmetrical, such as elements for the correction of astigmatism and/or other higher-order aberrations. The intermediate zone may provide fusion of the optic zone and peripheral zone along tangent curves. It should be noted that both the optic zone and peripheral zone may be designed independently of each other, although their configurations may sometimes be closely related if specific requirements exist. For example, a toric lens configuration with an astigmatic optical zone may require a peripheral zone to hold the lens in a predetermined position on the eye.

The photochromic effect can be achieved for cosmetic purposes with a constant thickness across the inner and outer areas of the lens. This cannot be achieved in the inner area of the lens because vision correction is usually achieved through refractive power, which requires a change in thickness either at the center of the lens or at the edge of the optical zone to account for the change in curvature of the front surface of the lens.

Figs. 4A-4B show examples of radial lens thickness for SKUs ranging from -12.0 D to 8.00 D for monofocal soft contact lenses. The central thickness (CT) can vary from 0.70 mm to 0.270 mm across the SKU range, with the minimum thickness and maximum thickness values being determined by the refractive index of the lens material, the choice of optical zone diameter, and the mechanical properties of the lens material. The maximum peripheral thickness (PT) can vary based on the same lens material selection and lens design options as for CT.

The mechanical component of the lens can be designed to provide the best cosmetic effect. The target photochromic effect (e.g., based on the cosmetic profile) can be obtained for cosmetic purposes with a constant thickness over the inner and outer regions of the lens. For example, the thickness of the central portion can be adjusted based on the desired darkness determined by the amount of photochromic dye present in the monomer mixture. At a low concentration (e.g., a concentration below 1.00%) of the photochromic dye, a greater thickness of the central portion may be required to achieve the same degree of darkness obtained with a higher concentration of the photochromic dye. The thickness of the central portion can also be adjusted based on the desired %T value, which can also provide different levels of darkness.

It is known to those skilled in the art of soft contact lens design that a peripheral zone with a greater thickness provides better processing characteristics. The thickness of the peripheral zone may depend on the rigidity of the material. A rigid lens material requires a thinner peripheral zone thickness to provide the same processing characteristics as a softer material. The difference in thickness between the edge of the optical zone and the inner region of the peripheral zone is dealt with by means of an intermediate zone, the purpose of which is to smoothly merge the two regions. A photochromic lens may require a combination of peripheral thickness, so that the peripheral region of the lens is thicker than the inner region of the lens to maintain ease of processing and provide a better cosmetic effect than a conventional lens.

Other criteria such as lens wrap, lens inversion, lens wrap, typically evaluated using finite element analysis (FEA) modeling, may also be considered in the lens design process. Such criteria related to the mechanical characteristics of the lens may also be included in the process of optimizing the cosmetic effect and adjusting according to the desired lens characteristics.

The vision correction component (e.g. based on the vision profile) can be designed based on the selected thickness profile of the inner region of the lens. It will be obvious to a person skilled in the art of designing soft contact lenses that the inner region can be optimized for a variety of thickness levels. It should be noted that this second stage of description can be performed in parallel with the first stage of description.

The use of the diffractive approach has the advantage that the diffractive optical zone can produce an optical power on the lens surface that is independent of the shape of the surface. Moreover, the optical power of the lens can be a combination of the refractive power and the diffractive power, which can together provide the total desired power. The diffractive surface of the lens has the general properties depicted in the planar profile and cross-sectional profile of the surface shown in Figs. 5A and 5B. It consists of a plurality of small zones separated by steps. In the figure, the steps are exaggerated, typically their height is only a few μm. This structure is added to the underlying base curvature. Each zone, corresponding to a ring, has approximately the same surface area and width, which is smaller, the further the ring is located from the geometric center. The general simplified equation, which gives the radial distance r _i of the boundary of the i-th zone from the center, is as follows:

(1)

where P is the diffraction power in diopters at the calculated wavelength ω. To obtain the radius in mm, it is convenient to measure the wavelength in µm (e.g. 0.543) and the power in diopters.

One approach to thinking about diffractive lenses is the fact that light waves are periodic, and that they repeat after each wavelength. The zone boundaries are typically positioned so that the optical paths to the desired image point are increased by the wavelength. This can be thought of as observing the propagation of light across a surface to identify individual waves. In the case of a standard monofocal diffractive lens, at the location of the step, the physical height of the step is set to delay the light by 1 wavelength. The area between the steps is a parabolic surface, which essentially also focuses the light on the desired image location. In principle, at the intended wavelength, all the light is focused correctly, and the ray tracing concept of all light rays being directed to the focus is consistent with the wavefront-based concept of light.

The diffractive structure can be implemented as a physical microrelief on one of the surfaces of the lens, and it will presumably be in contact with the tear film, which has a refractive index of about 1.336. An alternative would be to create a physical profile at the intersection of two surfaces of different materials within the lens itself. The height of each step is determined by the expression:

(2)

where n ₂ and n ₁ are the refractive index values of the two materials. Using index values of, say, 1.42 and 1.336, the physical step height for a wavelength of 0.543 would be about 6.5 µm.

The number of zones for a given diffractive lens diameter is given by equation 1, which can be transformed as follows:

(3)

For a diffractive lens with a diameter of 8.5 mm and a power of 4.0 D, 66 zones will be created, each with a step of 6.5 µm at the boundary.

The width of the outer zone is also given below in Table 1. This indicates how accurately the step must be manufactured so that it does not obscure a significant portion of the zone. For 4.0 D at 8.5 mm diameter, the outer zone width of 32 µm is about 1/5 of the step height.

Table 1

Diffraction optical power (diopters) N zones Minimum zone width (mm) (last zone) 1 17 0.128 2 33 0.065 3 50 0.043 4 67 0.032

For the soft contact lens designer, there are other critical aspects of diffractive surface design that determine optical performance that have not been described in detail. These may include longitudinal chromatic aberration, diffraction efficiency, and step scatter.

The diffractive surface can be placed on the front surface of the lens or on the back surface of the lens. The diffractive surface should always be covered by the tear film, and the tear film should be continuous without any pattern from the diffractive structure. The diffractive surface can be preferably placed on the back surface of the lens. The diffractive power can also be divided between both surfaces to minimize the zone height in the case of high-power lenses. Another solution would be to embed the diffractive surface inside the lens.

For soft contact lenses based on refractive power, the optic zone diameter varies across the SKU range due to thickness limitations. Lenses with high negative powers (e.g., below -6.00 D), which require a flat front curvature, have a smaller optic zone diameter than lenses with low powers due to the large thickness at the edge of the optic zone. To control the thickness at this location, the optic zone diameter is reduced so that the thickness is approximately the same as the maximum thickness of the peripheral portion (Fig. 4A and B). Lenses with high positive powers, which require a more stepped front curvature, also have a smaller optic zone diameter than lenses with low powers due to the large thickness at the center of the optic zone. To control the thickness at this location, the optic zone diameter is reduced so that the thickness of the central portion is approximately the same as the maximum thickness of the peripheral portion.

Due to the design of the optics based on the diffraction principle and its independence from the base surface/bearing surface, there are no more thickness limitations, so that the SKU has the same optical zone (OZ) diameter across the entire SKU range. Depending on these thickness limitations, the OZ diameter is typically in the range of 7.00 mm to 9.50 mm. In diffraction type configurations, the optical zone diameter is not limited to small diameters for SKUs with high optical power. The OZ diameter is preferably set to at least 8.50 mm and preferably 9.00 mm. The only limitation that can lead to smaller OZ diameter values will be the size of the diffraction zones. The width of the outer zones of the diffraction surface must be large enough to still be manufacturable.

Examples

The thickness ratio can be defined as the ratio of the central thickness to the maximum peripheral thickness. The thickness ratio is presented in the examples section in the second paragraph. The smaller the ratio, the greater the difference in thickness between the central thickness and the maximum peripheral thickness. A ratio of one would correspond to a lens of constant thickness.

In Figs. 6A and 6B, photochromic lenses were produced using a standard soft contact lens geometry, such as the Acuvue2 lens. The prescription for this lens is -1.00 D. The amount of dye between the first example (A) and the second example (B) varies from 1.0% to 4.0%. Both images show a lens with activated dye. In each case, the difference between the optic zone and the peripheral zone of the lens is evident due to the difference in darkness. In this example, the central thickness of the lens is about 0.124 mm, and the maximum thickness of the peripheral portion is about 0.240 mm. The ratio of the central thickness to the peripheral thickness (CT/PT) is about 0.51.

In the second example (Fig. 7), a photochromic lens with an optical power of -1.00 D was obtained using 1% photochromic dye added to the monomer mixture. The thickness of the central part of the lens is about 0.080 mm, and the maximum thickness of the peripheral part is about 0.203 mm. The ratio of the CT/PT thickness values is about 0.39. Similar to the previous example, the optical zone has less darkness than the peripheral region of the lens. Both regions are very different from each other when the photochromic dye is activated.

In Fig. 8, a photochromic lens with an optical power of -1.00 D was obtained using 1% of a photochromic dye added to the monomer mixture. The thickness of the central portion of the lens is about 0.158 mm, and the maximum thickness of the peripheral portion is about 0.187 mm. The ratio of the CT/PT thickness values is about 0.85. In another example shown in Fig. 9, a photochromic lens with an optical power of -1.00 D was also obtained using 1% of a photochromic dye added to the monomer mixture. The thickness of the central portion of the lens is about 0.117 mm, and the maximum thickness of the peripheral portion is about 0.182 mm. The ratio of the CT/PT thickness values is about 0.64. Thus, by thickening the optical region while thinning the peripheral region, it is possible to achieve a darkness balance throughout the lens while reducing the amount of transmitted light (%T). In a preferred embodiment, to obtain a cosmetically acceptable lens, the CT/PT thickness ratio should be at least greater than 0.65, but preferably greater than 0.85. Fig. 10 shows the radial peripheral thickness of a soft contact lens with a thickness ratio of 0.85. The greater the thickness of the central portion, the greater the thickness of the peripheral portion will be for the same thickness ratio, which will improve the processing characteristics of the lens.

In the examples given, the ratio is determined for CT and the maximum peripheral thickness when the refractive power of the lens was -1.00 D. For lenses with a positive optical power, the ratio of thickness values should be determined based on the edge thickness of the optical zone and the maximum peripheral thickness. Preferably, the ratio of thickness values should be determined based on the minimum thickness of the optical zone and the maximum thickness of the peripheral part.

A lower thickness ratio can be achieved by gradually applying the photochromic dye to the peripheral area of the lens, thereby providing a greater peripheral thickness for further processing enhancement if required.

It should be obvious to those skilled in the art of soft contact lens design that adding a diffractive component to a lens with a thickness profile corresponding to the thickness in one of the latter examples will not change the cosmetic performance of that lens when the photochromic dye is activated.

Methods of construction

The present description relates to methods for constructing a soft contact lens with a photochromic material, in which the optical region and the peripheral region of the lens are designed to provide the best cosmetic effect for the eye. The contact lens comprises a rigid surrogate coated with a shell of a material commonly used for soft contact lenses. The reactive photochromic dye may be part of a monomer forming the outer layer of the lens (mixed with the main monomer that makes up the material of the soft contact lens), or a rigid material forming the surrogate, or both, so that the photochromic region of the lens is formed either in the geometric center of the lens or near its edge, in the case where the photochromic region is embedded inside the outer layer or formed from a combination of the outer layer and the surrogate.

One of the purposes of the surrogate is to provide the necessary vision correction by using diffractive optics as a means of providing the required vision correction. The methods described in the present description can be used in the correction of vision of any type, including, without limitation, lower-order aberrations such as defocus caused by myopia or hyperopia, astigmatism, presbyopia, etc.; higher-order aberrations caused, for example, by keratoconus, etc.; or in any other vision correction options using information about the state of vision of a particular patient. One of the advantages of using diffractive optics is that the mechanical geometry of the surrogate used in it does not need to differ significantly in order to provide a wide variety of vision correction options.

Soft contact lenses are primarily designed to correct vision problems, but other aspects of the lens are also considered during the design process, such as handling (for insertion and removal of the lens), comfort, fit, or any other aspect that needs to be considered during the design process. Standard cosmetic lenses, such as colored lenses, provide cosmetic enhancement in the corneal area. Typically, the printed pattern and/or colored area does not extend to the edge of the lens, and therefore does not have a visual impact on the scleral area of the eye.

In the present description, the photochromic area may cover the entire surface of the lens, encompassing not only the cornea of the eye, but also the sclera. After the lens is placed on the eye and the photochromic dye is activated, the outer area of the lens may also darken. If the thickness of the peripheral part of the lens and the amount of photochromic dye are incorrectly selected, the transition from the edge of the lens to the sclera will not look cosmetically attractive to the user due to the abrupt change in darkness in this area. The proposed configuration provides a solution to the problem of this visual effect, according to which the thickness of the peripheral part is designed to optimize the change in color and aspect of the lens on the eye when the photochromic dye is activated.

Since the vision correction aspect of the lens is provided by the surrogate and the other aspects of the lens such as processing, comfort, fit or any other aspect that needs to be considered during the design process are dependent on the outer layer, the mechanical and optical characteristics are controlled independently of each other, providing many advantages to the contact lens. The unique soft skirt can be tailored to specific needs such as processing, fit, comfort or can be designed uniformly across the entire SKU range so that it provides:

- similar or essentially similar quality of processing for the entire range of SKUs;

- similar or substantially similar fit for the entire range of SKUs;

- similar or substantially similar comfort characteristics across the entire SKU range.

Diffractive optics can be used on either the front or back surface of the surrogate or a combination of both.

Below are examples of combining both components to achieve different photochromic effects:

- a special case when the surrogate provides only a photochromic region formed only in the central region of the lens;

- another special case, when the outer layer provides only the photochromic area formed between the edges of the lens;

- a third special case, where the surrogate and the outer layer provide a photochromic region formed between the edges of the lens. In this special case, the effect of the photochromic dye (the level of darkness) in both regions may be the same or different.

Although the present invention has been shown and described in the form of embodiments believed to be the most practical and preferred, it should be understood that those skilled in the art may suggest deviations from the specific configurations and methods described and shown, which may be used without departing from the spirit and scope of the invention. The present invention is not limited to the specific structures described and illustrated, but should be considered consistent with all modifications within the scope defined by the appended claims.

Claims (52)

1. A photochromic ophthalmic soft contact lens comprising: a main portion comprising an optical zone and a peripheral zone located adjacent to the optical zone, wherein the optical zone comprises a refractive structure and one or more of the optical zone and the peripheral zone comprises a photochromic dye; and a diffractive structure located within or adjacent to the optical zone, wherein the ophthalmic lens has a thickness profile that is designed based on a cosmetic profile associated with a target transmittance level (%T), wherein the vision profile associated with the ophthalmic lens is determined based on at least the diffractive structure, and the ophthalmic lens has a thickness ratio defined as the ratio of the thickness of the central portion of the optical zone to the maximum thickness of the peripheral zone, wherein for lenses with positive optical power, the thickness ratio is determined based on the thickness of the edge of the optical zone and the maximum thickness of the peripheral zone, and wherein the specified ratio of thickness values is more than 0.65. 2. A photochromic ophthalmic lens according to claim 1, wherein the thickness profile is optimized based on the cosmetic profile according to the vision profile. 3. The photochromic ophthalmic lens of claim 1, wherein the cosmetic profile provides a targeted amount of photochromic dye in one or more of the optical zone and the peripheral zone. 4. A photochromic ophthalmic lens according to claim 1, wherein the vision profile comprises an optical power profile. 5. A photochromic ophthalmic lens according to claim 1, wherein the vision profile is determined based on at least a refractive structure and a diffractive structure. 6. The photochromic ophthalmic lens of claim 1, wherein the vision profile is related to a target optical power. 7. The photochromic ophthalmic lens of claim 6, wherein the target optical power is in the range of -20 D to +20 D. 8. The photochromic ophthalmic lens of claim 6, wherein the target optical power is in the range of -12 D to +8 D. 9. A photochromic ophthalmic lens according to claim 1, wherein the diffractive structure is located on the rear optical surface of the photochromic ophthalmic lens. 10. A photochromic ophthalmic lens according to claim 1, wherein the diffractive structure is located on the front optical surface of the photochromic ophthalmic lens. 11. The photochromic ophthalmic lens of claim 1, wherein the diffractive structure is located on one or more of the anterior optical surface or the posterior optical surface of the photochromic ophthalmic lens. 12. The photochromic ophthalmic lens of claim 1, wherein the diffractive structure is embedded in the photochromic ophthalmic lens. 13. A photochromic ophthalmic lens according to claim 1, wherein the ratio of thickness values is greater than 0.75. 14. A photochromic ophthalmic lens according to claim 1, wherein the ratio of thickness values is greater than 0.85. 15. A photochromic ophthalmic lens according to claim 1, wherein the diffractive structure is located adjacent to the periphery of the optical zone. 16. A photochromic ophthalmic lens according to claim 1, wherein the diffractive structure is located adjacent to the peripheral zone. 17. A photochromic ophthalmic lens according to claim 1, wherein the diffractive structure is located around the circumference of the optical zone. 18. A photochromic ophthalmic lens according to claim 1, wherein the diffractive structure is located around the circumference of at least a portion of the optical zone. 19. A photochromic ophthalmic lens according to claim 1, wherein the diffractive structure is located around the circumference of the optical zone with a predetermined radius from the center of the optical zone. 20. An ophthalmic lens according to claim 1, wherein the diffractive structure comprises mechanical elements designed to provide optical diffraction of incident light. 21. A method for producing a photochromic ophthalmic soft contact lens, comprising: definition of vision profile; determination of the cosmetic profile associated with the target transmittance level (%T); forming a main portion comprising an optical zone and a peripheral zone located adjacent to the optical zone, wherein the optical zone comprises a refractive structure, and one or more of the optical zone and the peripheral zone comprises a photochromic dye, wherein one or more of the optical zone and the peripheral zone has a thickness profile formed based on a cosmetic profile; and formation of a diffraction structure based on the vision profile, located within the optical zone or adjacent to it, such that the ophthalmic lens has a thickness ratio defined as the ratio of the thickness of the central optical zone to the maximum thickness of the peripheral zone, wherein for lenses with positive optical power the thickness ratio is determined based on the thickness of the edge of the optical zone and the maximum thickness of the peripheral zone, and wherein the specified ratio of thickness values is more than 0.65. 22. The method of claim 21, wherein the thickness profile is optimized based on the cosmetic profile over the vision profile. 23. The method of claim 21, wherein the cosmetic profile provides a target amount of photochromic dye in one or more of the optical zone and the peripheral zone. 24. The method of claim 21, wherein the vision profile comprises a power profile. 25. The method of claim 21, wherein the vision profile is determined based on at least a refractive structure and a diffractive structure. 26. The method of claim 21, wherein the vision profile is related to a target optical power. 27. The method of claim 26, wherein the target optical power is in the range of -20 D to +20 D. 28. The method of claim 26, wherein the target optical power is in the range of -12 D to +8 D. 29. The method according to claim 21, wherein the diffractive structure is located on the rear optical surface of the photochromic ophthalmic lens. 30. The method according to claim 21, wherein the diffractive structure is located on the front optical surface of the photochromic ophthalmic lens. 31. The method of claim 21, wherein the diffractive structure is located on one or more of the anterior optical surface or the posterior optical surface of the photochromic ophthalmic lens. 32. The method of claim 21, wherein the diffractive structure is embedded in a photochromic ophthalmic lens. 33. The method according to claim 21, wherein the ratio of thickness values is greater than 0.75. 34. The method according to claim 21, wherein the ratio of thickness values is greater than 0.85. 35. The method according to claim 21, wherein the diffractive structure is located adjacent to the periphery of the optical zone. 36. The method according to claim 21, wherein the diffractive structure is located adjacent to the peripheral zone. 37. The method according to claim 21, wherein the diffractive structure is located around the circumference of the optical zone. 38. The method according to claim 21, wherein the diffractive structure is located around the circumference of at least part of the optical zone. 39. The method according to claim 21, wherein the diffractive structure is located along the circumference of the optical zone with a predetermined radius from the center of the optical zone. 40. The method according to claim 21, wherein the diffractive structure comprises mechanical elements designed to provide optical diffraction of incident light.

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