Patent Description:
Multifocal lenses typically have two or more areas, or zones, with different optical powers, such as a far-power optic zone for distance vision, and a near-power optic zone for near or close up vision. In multifocal lenses, the zones may be further subdivided into additional power zones.

Effective use of a bifocal contact lens requires translation of an ocular system between vision surfaces when an eye changes from gazing at an object at a distance to gazing at a nearby object. Alternatively, there may be a desire to have a translating multifocal contact lens that may have one or more intermediate-power zones in addition to far and near-power optic zones. Such a translating contact lens may have to have an ability to control and optimize the amount of movement of a lens when the pupil translates from distance vision, to intermediate vision, to near vision, or any combination thereof.

While there are many designs for soft translating contact lenses, soft contact lenses typically have difficulty translating across the surface of the eye when the focus changes from a straight-ahead gaze, to a downward gaze. Some soft bifocal contact lens designs provide an integrally formed bevel to aid translation. While other lens designs may allow the lens to translate across the surface of an eye when the focus changes from a straight-ahead gaze to a downward gaze, they are less efficient at allowing to control lens movement of a lens during an eye's translation to a different visual direction. Another prior art example, describes a soft multifocal contact lens that has an integrally formed ramped ridge zone adjoining an outwardly extending latitudinal ridge that sits on an eyelid to aid in translation of a lens. The latitudinal ridge portion has a bump at each end, thereby increasing elevation height of the ends of the ridge compared to the elevation height in the middle. However, a disadvantage of these and other known designs is discomfort to the wearer.

International Patent Application Publication No. <CIT> discloses variable focus contact lens, has a body with a first half and an opposite second half. The body also has a first peripheral surface, an opposite second peripheral surface and an associated focal length. The lens includes a first material having a resilience so that as compressive force is applied to the first surface and the second surface, the focal length of the lens changes in proportion to the compressive force. A force-distributing structure is disposed within the lens for distributing force within the lens so as to inhibit astigmatism in the lens as compressive force is applied to the first surface and the second surface.

International Patent Application Publication No. <CIT> discloses dynamic contact lenses fabricated with a dynamic portion that extends outward from the peripheral portion. When worn on an eye the dynamic portion forms a tear lens for correcting vision. The dynamic portion can also be configured to provide a dynamic tear lens that changes optical power with forces applied by eyelids. The dynamic portion can be configured to assume a conforming configuration and at least one non-conforming configuration, or can be configured to assume at least two non-conforming configurations. The dynamic contact lenses can be used for correcting vision such as correcting presbyopia.

The following embodiments and aspects thereof are described and illustrated in conjunction with systems, tools and methods which are meant to be exemplary and illustrative, not limiting in scope.

In some embodiments, the lateral expansion of at least one of the upper and lower peripheral zones causes an at least <NUM>% increase in a circumference of the dome-shaped flexible sheet of material at a <NUM>° arc that is centered at the upper or lower peripheral zone, respectively; and the lateral contraction of at least one of the upper and lower peripheral zones causes an at least <NUM>% decrease in a circumference of the dome-shaped flexible sheet of material at a <NUM>° arc that is centered at the upper or lower peripheral zone, respectively.

In some embodiments, the soft contact lens further comprises at least two slits, wherein: each slit is an elongated portion cut out of the lens; each slit maintains a gap extending from the periphery of the contact lens until the base of the slit towards an inner region of the contact lens when the slit is in a normally neutral state; and each slit is configured to open and close, thereby allowing the flexibility of the lens periphery in order to modify the curvature of the disk-shaped contact lens.

In some embodiments, the gap of any one of the at least two slits is uniform along the length of the slit when the slit is in the normally neutral state.

In some embodiments, the gap of any of the at least two slits is non-uniform along the length of the slit when the slit is in the normally neutral state.

In some embodiments, any of the at least two slits has an elongated "U" shape when the slit is in the normally neutral state.

In some embodiments, any of the at least two slits has a "V" shape when the slit is in the normally neutral state.

In some embodiments, any of the at least two slits has a rectangular shape when the slit is in the normally neutral state.

In some embodiments, any of the at least two slits has a pointed picket shape when the slit is in the normally neutral state.

In some embodiments, the upper peripheral zone comprises at least one upper slit comprising at least one of the at least two elongated slits, wherein the at least one upper slit is configured to open and close, thereby dynamically adapting the curvature of the upper peripheral zone, and wherein the lower peripheral zone comprises at least one lower slit comprising at least another one of the at least two elongated slits, wherein the at least one lower slit is configured to open and close, thereby dynamically adapting the curvature of the lower peripheral zone.

In some embodiments, the at least one upper slit comprises at least two upper slits, and wherein the at least one lower slit comprises at least two lower slits.

In some embodiments, the optic zone comprises at least two optic zones having different dioptric powers.

In some embodiments, the optic zone comprises a distance vision zone, and a near vision zone, wherein the distance vision zone has a different dioptric power than the near vision zone.

In some embodiments, the optic zone has an aspheric configuration.

In some embodiments, the optic zone has a translating configuration.

In some embodiments, the optic zone has a concentric configuration, wherein the distance vision zone is located at the center of the optic zone, and wherein the near vision zone is ring-shaped and is located at the periphery of the optic zone.

In some embodiments, the optic zone further comprises a ring-shaped intermediate optic zone located between the distance vision zone and the near vision zone.

In some embodiments, the upper peripheral zone is configured to expand and the lower peripheral zone is configured to contract when the visual axis of the eye is aligned with the lower periphery of the optic zone, and wherein the upper peripheral zone and the lower peripheral zone are configured to be at a normally neutral state when the visual axis of the eye is aligned with the center of the optic zone.

In some embodiments, the soft contact lens further comprises a stabilizing middle zone positioned between the upper and lower peripheral zones, wherein the thickness of the stabilizing middle zone is greater than the thickness of the upper and lower peripheral zones.

In some embodiments, the soft contact lens has the following measurements: a length of each of the slits: <NUM>-<NUM> millimeters (mm), or <NUM>-<NUM>; and a gap provided by each of the slits: <NUM>-<NUM>.

A soft translating multifocal contact lens is disclosed herein, having a dynamically adaptable periphery that expands and contracts, allowing the lens to modify its curvature to accommodate the changing shape of the wearer's eye as the lens moves vertically over the eye's surface. Optionally, the lens is a multifocal lens. As the wearer shifts his focus between the different vision zones of the lens, the lens moves vertically over the surface of the eyeball, accordingly. The ability of the lens to accommodate its curvature to the varying curvature of the eye's surface may provide an easier and more comfortable experience for the wearer when shifting his focus to different regions of the lens.

The lens's periphery may be disposed with one or more slits that open and close, thereby dynamically changing the curvature of the periphery and enabling the lens to move vertically over the surface of the eye as the wearer switches his focus between the various multifocal optical zones of the lens.

Reference is now made to <FIG>, <FIG>, <FIG>, which show a soft contact lens <NUM> having an adaptable curvature, in accordance with an embodiment. Each pair of these figures, namely 1A-B, 2A-B, and 3A-B, shows lens <NUM> in a frontal view and a cross-sectional view, respectively.

Lens <NUM> may be a dome-shaped flexible sheet of material (a suitable soft contact lens material), such as but not limited to silicon elastomers, silicone-containing macromers such as may include hydrogels, silicone-containing hydrogels, and the like. The surface of lens <NUM> may be a siloxane, or may include a substance having a siloxane functionality, such as polydimethyl siloxane macromers, methacryloxypropyl polydimethyl siloxane macromers, methacryloxypropyl polyalkyl siloxanes, and combinations thereof, and/or dilocone hydrogel or other hydrogel, such as etafilcon A. For a further discussion of soft contact lenses and their tensile properties, as well as suitable materials for soft contact lenses, see <NPL>.

The center region of lens <NUM> may be an optic zone <NUM> that aligns with the wearer's visual axis and provides one or more sub-regions for corrective vision, details of which are provided below. The peripheral region of lens <NUM> bordering optic zone <NUM> may be a non-optic zone, that covers a portion of the cornea and sclera of the eye. The non-optic zone may include three general sections: an upper peripheral zone 104a and lower peripheral zone 104b above and beneath the optic zone <NUM> at the upper and lower peripheries of lens <NUM>, as well as a stabilizing middle zone 104c positioned between zones 104a and 104b, surrounding zone <NUM> from either side.

For the description that follows, it may be understood that the terms 'upper' and 'lower', and 'upwards' and 'downwards', are used for the purposes of clarity only, to accord the description with the drawings, and are not meant to be taken in an absolute sense. The lenses described herein below may have a symmetry about the horizontal axis, and thus the upper and lower features may be identical and interchangeable.

Non-optic zone <NUM> may include an upper peripheral zone 104a located at the upper periphery of lens <NUM>, and a lower peripheral zone 104b located at the lower periphery of lens <NUM>. The curvature of each of upper peripheral zone 104a and lower peripheral zone 104b may be dynamically adaptable, to allow modifying the overall curvature of lens <NUM> dynamically, and accommodate a vertical movement of lens <NUM> over the surface of the eye. This change of curvature may be expressed by a change in the circumference of lens <NUM> at one or two arcs extend over a certain angle at upper peripheral zone 104a and lower peripheral zone 104b. The arcs are illustrated in <FIG> - they are the circumference of lens <NUM> (disregarding the circumference of the slits) delimited between the dashed lines forming angles α and β. The arcs may be, for example, of <NUM>°. Namely, over upper and lower arcs of <NUM>° each, the circumference may change between minus and plus <NUM>% as lens <NUM> dynamically changes its curvature. These arcs are illustrated for the purpose of more clearly showing that the change of curvature of lens <NUM> is majorly expressed at these arcs, and less so (or not at all) beyond these arcs.

The at least <NUM>% may be, in some embodiments, between <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, <NUM>-<NUM>%, or more than <NUM>%. Each possibility represents a separate embodiment of the invention.

To achieve the curvature modification, one or more slits <NUM> may be provided with each of upper peripheral zone 104a and lower peripheral zone 104b, such as slits 106a, 106b, 106c, and 106d. Slits <NUM> may open at the periphery of lens <NUM> and close as necessary to dynamically adapt the curvature of lens <NUM>, such as at peripheral zones 104a and 104b, accordingly. Optionally, lens <NUM> has two upper slits 106a, 106b, and two lower slits 106c, 106d, however it may be understood that this is but one implementation, and more or fewer slits may be used. For example, an alternative lens (not shown) may have three, or four, or five, or more upper slits, and three, or four, or five, or more, lower slits. Optionally, the number upper slits is different than the number of lower slits. For example, there may be more upper slits than lower slits, alternatively, there may be fewer upper slits than lower slits.

Slits <NUM> may be elongated and thin portions cut out of lens <NUM> that, in their normally neutral state (when the lens is in its rested state, namely when the wearer's gaze is straight ahead), maintain a gap extending from the periphery of lens <NUM> until the base of slits <NUM>, towards an inner region of lens <NUM>. When in the normally neutral state, slits <NUM> may have any suitable shape, such as but not limited to an elongated U-shape, V-shape, rectangular shape, a pointed picket-shape having a "V" shaped base pointing towards the center of lens <NUM> and elongated vertical walls extending to the periphery of lens <NUM>. In the normally neutral state, the gap maintained along the length any of slits <NUM> may be substantially uniform. Alternatively, in the normally neutral state, the gap along any of slits <NUM> may be non-uniform, for example the gap may be larger at the periphery of lens <NUM> and may taper towards the base of slits <NUM>. It may be appreciated that although slits <NUM> are shown having a uniform shape and size, this is not meant to be limiting, and different slits <NUM> on the same lens <NUM> may have a different shape and/or size. When opened, slits <NUM> increase the gap at the periphery of lens <NUM>, when closed, slits <NUM> may decrease the gap at the periphery of lens <NUM>. Slits <NUM> may fully close, closing the gap at the periphery of lens <NUM>. Slits <NUM> may partially open and/or partially close, increasing and/or decreasing the circumference of lens <NUM> as necessary.

Opening slits <NUM> opens a wider gap at the periphery of lens <NUM>, lengthening the circumference of lens <NUM>. Referring to <FIG>, upper slits 106a and 106b are open, lengthening the circumference of lens <NUM> at its upper periphery. When fully open, the gap caused by slits <NUM> at the periphery of lens <NUM> may range from <NUM> millimeter (mm) to <NUM>. When closed, the peripheral ends of slits <NUM> may touch (or be very close to one another, for example between <NUM> to <NUM> from each other), forming a teardrop shape, such as lower slits 106c and 106d of <FIG>, maintaining the uniform gap at the inner end of slits <NUM> and closing the gap at the periphery of lens <NUM>, shortening the circumference of lens <NUM> at its lower periphery. The opening of slits <NUM> at any of upper and lower peripheral zones 104a and 104b causes their curvature to decrease and thus flatten, accordingly. Conversely, closing any of slits <NUM> at any of upper and lower peripheral zones 104a and 104b causes their curvature to increase and become more convex, accordingly. <FIG> show the opposite of <FIG>, namely - upper slits 106a and 106b are closed, and lower slits 106c and 106d are open.

Since the sclera of the eye is slightly less convex than the cornea (or, in different terms, the radius of the sclera is larger than the radius of the cornea), dynamically modifying the curvature of the peripheral regions of lens <NUM> by opening and/or closing any of slits <NUM> may allow fitting its curvature to different vertical positions on the eye's surface, in which different areas of the lens are positioned over different areas of the sclera and the cornea. Without the dynamic modification of the curvature of lens <NUM>, a lens is at risk of remaining stationary on the eyeball when the wearer moves the eyeball around. Namely, a lens without dynamic curvature modification will likely move with the eyeball movement - up, down, right, and left. In contrast, the dynamic modification of present embodiments aids in ensuring that lens <NUM> can slide over the eyeball - but only up and down (vertically) and not laterally (horizontally) - when the wearer's gaze changes.

Optic zone <NUM> may include multiple sub-zones, each having a different dioptric power and correcting for a different type of refractive condition, such as a distance vision zone 102a for correcting for myopia, a near vision zone 102b for correcting for hyperopia, and 102c for correcting for intermediate vision. Alternatively, these optic sub-zones or other optic sub-zones which are not shown, may have a different purpose. Although the configuration illustrated in the figures for the different corrective sub-zones of optic zone <NUM> is concentric, this is but one implementation and is not meant to be limiting. Other suitable configurations such as aspheric or translating configurations may be used, accordingly.

In general, with respect to any configuration for optic zone <NUM>, the upper peripheral zone 104a is configured to expand and the lower peripheral zone 104b is configured to contract when the visual axis of the eye is aligned with the lower periphery of the optic zone, allowing lens <NUM> to move vertically upwards with respect to the eyeball. Similarly, upper peripheral zone and the lower peripheral zone 104a and 104b are configured to be at their normally neutral state when the visual axis of the eye is aligned with the center of the optic zone.

Distance vision zone 102a, may be substantially round-shaped and located at the center of the optic zone <NUM>, comprising the center of lens <NUM>, allowing the wearer to focus for distance by looking straight ahead when lens <NUM> is positioned centrally over the cornea. As shown in <FIG>, the wearer's pupil <NUM> is positioned in the middle of distance vision zone 102a aligning his visual axis through the center of lens <NUM>, to correct his distance vision.

Near vision zone 102b may be substantially ring-shaped and may be located at the periphery of the optic zone <NUM>, allowing the wearer to focus for near vision by looking down, such as when reading. As shown in <FIG>, the near vision zone 102b comprising the bottom periphery of the optic zone <NUM> is positioned substantially over the wearer's pupil <NUM>, aligning his visual axis through the bottom of optic zone <NUM>, to correct his near vision. The difference between <FIG> and <FIG> may be appreciated as the position of lens <NUM>, centered over the cornea for distance vision in <FIG>, has shifted upwards relative to the pupil <NUM> in <FIG> when the wearer aligns his visual axis (pupil <NUM>) with the lower near vision zone 102b for near vision. Such vertical shifting of lens <NUM> over the wearer's eyeball may be facilitated by modifying the curvature of the upper and lower peripheral zones 104a and 104b via slits 106a, 106b, 106c, and 106d to accommodate the changing curvature of the eyeball. Conversely, when the wearer aligns his visual axis (pupil <NUM>) with the upper near vision zone 102b for near vision, as shown in <FIG>, the position of lens <NUM> shifts downwards relative to pupil <NUM>.

Optionally, lens <NUM> may include a ring-shaped intermediate optic zone 102c located between the distance vision zone 102a and the near vision zone 102b to correct for an intermediate focal distances ranging between far and near ranges. Shifting the visual axis to align with intermediate optic zone 102a corrects the wearer's intermediate vision accordingly.

Optionally, lens <NUM> may include a zone for correcting astigmatism, and which may overlap or be separate from the corrective zones described above.

Reference is now made to <FIG>, which, for the purposes of clarity, shows lens <NUM> of <FIG> with additional annotations, useful for conveying various measurements of the lens. The length of each of slits <NUM> may range from <NUM> to <NUM>, or more specifically from <NUM> to <NUM>, for example approximately <NUM>. Slits <NUM> may extend inwards, from the outer edge of lens <NUM>. Optionally, slits <NUM> may extend from the edge of lens <NUM> until the outer edge of optic zone <NUM>. Slits <NUM> may have a neutral 'straight' position that maintains a uniform gap along the length of slit ranging from <NUM> to <NUM> (<FIG>), for example approximately <NUM>. The distance 'sg' between slits may range from <NUM> to <NUM>, for example approximately <NUM>.

Optionally, one or more portions of middle zone 104c of lens <NUM>, positioned between the upper and lower peripheral zones 104a and 104b, may be thicker than upper and lower peripheral zones 104a and 104b, serving to stabilize lens <NUM> horizontally over the eye. The total diameter of near vision zone 102b may range between <NUM> and <NUM> and may be approximately <NUM>. The total diameter of distance vision zone 102a may range between <NUM> and <NUM>, for example approximately <NUM>. The thickness of intermediate zone 104c may range from <NUM> and <NUM> and may be approximately <NUM>. The diameter D1 of lens <NUM> may range from <NUM> and <NUM>, and may be approximately <NUM>. The thickness of lens <NUM> at middle zone 104c, in <FIG>, may range from <NUM> and <NUM>, and may be approximately <NUM>. The thickness of lens <NUM> at points at the thin areas, indicated in grey, may range from <NUM> and <NUM>, and may be approximately <NUM>.

Some optical defects, such as astigmatism, are caused by a deformation of the cornea or inner source due to the inner shape of the eye's lens. Referring to <FIG>, the curvature of the anterior face of the central optic zone 102a may accommodate such deformations by having a different radius at the horizontal and vertical meridian.

The central optic zone 102a portion of lens <NUM>, which is configured to rest over a human cornea, may be somewhat flatter (i.e., having a larger radius) than a typical cornea. The sagittal depth, S2, of the posterior face of the central optic zone 102a, may be smaller than the sagittal depth S1 of the cornea, resulting in a gap of S1 minus S2 between lens <NUM> and the eye's surface at the cornea. This gap may reduce surface tension between lens <NUM> and the surface of the eye, allowing the lens <NUM> to move over the surface of the eye more freely.

Optionally, the gap may range from <NUM> to <NUM>. This gap, caused by the relative flatness of lens <NUM>, together with slits <NUM> allow lens <NUM> to move over the eye's surface in response to the user's change of focus.

The vertical motion of lens <NUM> over the eye is now described:
Referring to <FIG>, slits <NUM> are at a normally neutral state when the pupil <NUM> is positioned over the center of lens <NUM>, aligning the visual axis of the eye (pupil <NUM>) with the distance vision zone 102a at the center of lens <NUM>.

Referring to <FIG>, as the wearer turns his gaze downwards, such as to read, the eyeball rotates downwards, shifting the visual axis of his eye down to the lower near vision zone 102b. As the wearer blinks, his lower and upper eyelids may push lens <NUM> upwards. Upper slits 106a and 106b open, expanding upper peripheral zone 104a slightly, and flattening the curvature of lens <NUM> at upper peripheral zone 104a to accommodate the slightly less convex sclera above the cornea. At the same time, lower slits 106c and 106d close, contracting lower peripheral zone 104b slightly, and increasing the curvature of lens <NUM> at lower peripheral zone 104b to accommodate the slightly more convex cornea, now aligned with near vision zone 102b at the lower portion of optic zone <NUM>, adjacent to the upper portion of lower peripheral zone 104b. Modifying the curvature of lens <NUM> thus, and reducing its surface tension with the surface of the eyeball may facilitate this upwards motion over the surface of the eyeball.

When the wearer shifts his gaze back for distance vision, slits <NUM> revert to their normally neutral state as shown in <FIG>, and lens <NUM> returns to be centrally aligned over the cornea, with the pupil <NUM> positioned centered in distance vision zone 102a.

<FIG> show the opposite of <FIG>. Namely, in <FIG>, the wearer turns his gaze upwards, the eyeball rotates upwards, shifting the visual axis of his eye up to the upper near vision zone 102b. Lower slits 106c and 106d open, expanding lower peripheral zone 104b slightly, and flattening the curvature of lens <NUM> at lower peripheral zone 104b to accommodate the slightly less convex sclera below the cornea. At the same time, upper slits 106a and 106b close, contracting upper peripheral zone 104a slightly, and increasing the curvature of lens <NUM> at upper peripheral zone 104b to accommodate the slightly more convex cornea, now aligned with near vision zone 102b at the lower portion of optic zone <NUM>, adjacent to the lower portion of upper peripheral zone 104b.

The optical properties described above may be implemented on both sides of lens <NUM>, allowing the wearer to place either face of the lens on the surface of the eye, to correct the vision accordingly. For example, correction for astigmatism, myopia and hyperopia may be implemented on any side of lens <NUM>. Lens <NUM> may be a Toric lens and may be produced using any suitable technology, such as by standard lath cut, molded, oscillation system, or diffractive technology.

It may be appreciated that the lens described above allows the lens to move over the eyeball while avoiding some of the drawbacks of the ballasted lens designs. Ballasted lenses are typically thicker at their lower half to provide stability. However, this thickness at the lower half may cut off the supply of oxygen to the cornea and regions of the sclera, interfering with the proper metabolism of these tissues and leading to discomfort by the wearer.

Lens <NUM> may be manufactured using any suitable method, such as but not limited to spin-cast techniques, injection moulding, cast moulding, etc. For example, a suitable cast moulding technique is described <CIT>.

Reference is now made to <FIG>, which shows a soft contact lens <NUM> having an adaptable curvature, in accordance with an embodiment. Lens <NUM> is similar to lens <NUM> of the former figures, with the notable difference that lens <NUM> is truncated <NUM> at its lower area, and is devoid of a lower peripheral zone. Reference numerals in <FIG> are larger by <NUM> than their corresponding elements in the previous figures, to simplify the discussion. All these elements may be identical across <FIG> and the other figures.

This truncated structure of lens <NUM> avoids the need for lower peripheral slits, because there is now nothing in the lower area of the lens which prevents it from freely sliding over the varying curvature of the cornea and/or sclera.

The truncation line may be straight, as shown in <FIG>, or may be arcuate or have any other shape (not shown). The truncation line may be perpendicular to a longitudinal dimension of slits 206a-b, or be disposed at an angle of, for example, <NUM> to <NUM> degrees relative to that longitudinal dimension (not shown).

The truncation line may border with optic zone <NUM>, or be slightly distant from it, such as at a distance of <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, or more than <NUM> from the optic zone. Each possibility represents a separate embodiment of the invention.

Those of skill in the art will also readily recognize an opposite embodiment (not shown), in which the truncation line is at the top of the lens and the one or more slits are at its bottom.

In the figures, elements are not always provided with reference numbers; a certain element, for example, may be provided with a reference number in one of more figures, and be shown without that reference number in other one or more figures - merely for reasons of brevity. Since all figures in this application show the same device, it is intended that an element having the same shape and appearing in different figures, sometimes with a reference number and sometimes not - be interpreted as the same element.

Claim 1:
A soft translating contact lens (<NUM>), comprising:
a dome-shaped flexible sheet of material, comprising:
(a) a non-optic zone (<NUM>) comprising the periphery of the dome-shaped flexible sheet of material, wherein the non-optic zone is configured to cover a portion of the cornea and portion of the sclera of an eye, wherein the non-optic zone comprises:
an upper peripheral zone (104a) comprising an upper part of the periphery of the dome-shaped flexible sheet of material,
a lower peripheral zone (104b) comprising a lower part of the periphery of the dome-shaped flexible sheet of material, and
at least one slit (<NUM>), each slit is an elongated portion cut out of the lens;
each slit maintains a gap extending from the periphery of the contact lens until the base of the slit towards an inner region of the contact lens when the slit is in a normally neutral state; and
each slit is configured to open and close, thereby allowing the flexibility of the lens periphery in order to modify the curvature of the disk-shaped contact lens, ,and wherein the curvature of the dome-shaped flexible sheet of material is dynamically adaptable, by virtue of at least one of the upper and lower peripheral zones being structured to laterally expand and contract; and
(b) an optic zone (<NUM>) disposed in an area of the dome-shaped flexible sheet of material that lies between the upper and lower peripheral zones, wherein the optic zone is configured to align with a visual axis of the eye.