JP2021140125A - Lense for smart contact lens - Google Patents

Abstract

To provide a smart contact lens having smart functions that need energy such as electricity, which is capable of keeping the effective eyesight of a user even when the energy suddenly runs out from the battery and the use of the smart functions is finished, the smart contact lens in use may have to be removed, and a hygienic place where the lens is removed is secured.SOLUTION: The smart contact lens has, from the center side, a first area where a plano lens is formed, a second area where a terrace is formed on at least one of the front and back sides of the lens, and a third area as the periphery.SELECTED DRAWING: Figure 2

Description

The present invention relates to a lens for smart contact lenses.

In recent years, research and development of smart contact lenses equipped with electronic control devices, display devices, camera devices, health / medical devices, etc., and having functions other than visual acuity assisting functions such as visual acuity correction function and eye protection have been promoted.

Special Table 2017-525986

An object of the present invention is to reduce problems that may occur when removing smart contact lenses and to use them more conveniently.
Due to problems with smart functions that use signals and energy such as radio waves, electronics, and electricity, suddenly the energy from the battery etc. is exhausted, the use of smart functions is completed, etc., and the smart contact lens in use is removed. It may be necessary. At that time, the purpose is to maintain effective eyesight for the user without sudden loss of eyesight during an emergency until a hygienic place to remove the lens is secured.
In that respect, the present invention plays a role of hitting a PC motherboard or a desktop case rather than a vision correction medical device.
The present invention has the effect that when the curve of the lens is made elliptical as shown in FIG. 5, the area is proportionally increased by the amount of expansion from the circle to the ellipse.
When the curve of the lens is made polygonal, the area of the tear fluid becomes close to the area of the circular curve, and the effect of increasing the area of the tear fluid can be obtained.
When the curve of the lens is octagonal as shown in FIG. 7, the area of the tear fluid is 1.05 times that of the circular shape.
When the curve of the lens is hexagonal, the area of the tear fluid is 1.10 times larger than that of the circular shape.
When the curve of the lens is pentagonal, the area of the tear fluid is 1.16 times larger than that of the circular shape.
When the curve of the lens is made square, the area of the tear fluid is 1.17 times larger than that of the circular shape.
When the curve of the lens is made triangular, the area of the tear fluid is 1.27 times larger than that of the circular shape.
When the curve of the lens is made into a star shape as shown in FIG. 6, the area of the tear fluid is 3.74 times larger than that of the circular shape.
By applying an irregular multi-deformation curve as shown in FIG. 8, it is possible to obtain tear fluid having an irregular area applicable to an irregularly shaped cornea or irregular astigmatism.

The lens for a smart contact lens according to one aspect of the present invention includes a first region formed from a plano lens from the center side and a first region.
A second region where terraces are formed on at least one of the front and back sides of the lens,
It has a third region that serves as a peripheral edge.

According to an embodiment of the present invention, in one aspect, smart contacts capable of responding to users with various visual acuity conditions such as normal vision, general myopia, high myopia, and hyperopia with a single type or a small number of types. We can manufacture and provide lenses for lenses.

It is a figure for demonstrating the structure of the lens for smart contact lens which concerns on this embodiment. It is a figure for demonstrating the structure in which the terrace was formed on the surface side of the lens for smart contact lens which concerns on this embodiment. It is a figure for demonstrating the structure in which the terrace was formed on the back surface side of the lens for smart contact lens which concerns on this embodiment. It is another figure for demonstrating the structure of the lens for smart contact lens which concerns on this embodiment. It is another figure for demonstrating the structure of the lens for smart contact lens which concerns on this embodiment. It is another figure for demonstrating the structure of the lens for smart contact lens which concerns on this embodiment. It is another figure for demonstrating the structure of the lens for smart contact lens which concerns on this embodiment. It is another figure for demonstrating the structure of the lens for smart contact lens which concerns on this embodiment. It is a figure for demonstrating the retention of tear liquid at the time of wearing the lens for smart contact lens which concerns on this embodiment.

Hereinafter, a lens for a smart contact lens according to an embodiment of the present invention will be described with reference to the drawings. In the present specification, the front surface of the lens refers to the surface on the side that does not come into contact with the eye (cornea) when the lens is attached to the eye, and the back surface of the lens refers to the surface when the lens is attached to the eye. , Refers to the surface on the side in contact with the eye (cornea). FIG. 1 shows a diagram for explaining the structure of a lens for a smart contact lens according to the present embodiment.

As shown in FIG. 1, the lens for a smart contact lens according to the present embodiment has a first region formed from a plano lens from the center side and a first region.
A second region where terraces (terraced rice fields) are formed on at least one of the front and back sides of the lens,
The third area, which is the peripheral edge,
Have.

Each region will be described in detail below.

(First area)
The first region is the region on the most central side of the lens and corresponds to the optical field of view of the user.

The plano lens in the first region is also called an afocal lens, and refers to a lens having a normal spherical curve and a power of plus or minus 0.00D (Diopter). That is, it should be noted that the lens for smart contact lenses according to the present embodiment does not need to have any function of assisting the eyesight of the user in the lens itself. However, even those who have normal visual acuity may have some refractive error, so for example, a lens of plus or minus 0.00D to plus or minus 2.00D may be used.

(First area)
The first region is usually provided within a diameter of 2 mm to 6 mm, preferably within a diameter of 4 mm from the center of the lens.

When the lens for smart contact lenses according to the present embodiment is applied to smart contacts, the smart function is not normally provided in the first region in order to reduce the influence on the visual acuity of the naked eye, but the first region is not provided. May be given a smart function. When the smart function is applied to the first region, it is preferable to manufacture the first region with a material that transmits light in order to secure a field of view through the lens according to the present embodiment even when the smart function is not used.

(Second area)
The second region is a region provided on the outer peripheral side of the first region, and terraces (also referred to as terraced rice fields or terrace curves) are formed on at least one of the front side and the back side of the lens.

FIG. 2 shows a diagram for explaining a structure in which a terrace is formed on the surface side of the lens for smart contact lenses according to the present embodiment. Further, FIG. 3 shows a diagram for explaining a structure in which a terrace is formed on the back surface side of the lens for smart contact lenses according to the present embodiment.

In the example shown in FIG. 2, the lens for smart contact lenses according to the present embodiment shows an example in which a terrace is formed on the surface side thereof. In the example shown in FIG. 2, an example in which a three-tiered terrace is formed is shown, whereby four tear retention portions are formed. However, the present invention is not limited in this respect, and the lens for smart contact lenses according to the present embodiment can form one or two or more terraces.

Further, in the example shown in FIG. 3, the lens for smart contact lenses according to the present embodiment shows an example in which a terrace is formed on the back surface side thereof. The example shown in FIG. 3 shows an example in which a three-tiered terrace is formed, whereby four tear retention portions are formed. However, the present invention is not limited in this respect, and the lens for smart contact lenses according to the present embodiment can form one or two or more terraces.

Further, regardless of the embodiment described above, the lens for smart contact lenses according to the present embodiment may have a configuration in which terraces are formed on both the front surface and the back surface. That is, as an example, one terrace may be provided on the front surface side of the lens for smart contact lenses, or one terrace may be provided on both the front surface side and the back surface side. Two terraces may be provided on the front surface side, two terraces may be provided on the front surface side, and one terrace may be provided on the back surface side, or both the front surface side and the back surface side may be provided. It may be configured to have two terraces.

The outer peripheral shape of the first region and the second region and the outer peripheral shape of the terrace are not particularly limited. 4 to 8 show another diagram for explaining the structure of the lens for smart contact lenses according to the present embodiment. As shown in FIGS. 4 to 8, the outer peripheral shape of the first region and the second region and the outer peripheral shape of the terrace are, for example, a polygonal shape (see FIG. 4), an ellipse shape (see FIG. 5), and a star shape. It may have any shape such as a polygon (see FIG. 6), an octagon (see FIG. 7), and multiple deformations (see FIG. 8).

The lens for a smart contact lens according to the present embodiment has a second region in which a terrace (terraced rice field) is formed on at least one of the front side and the back side of the lens, so that the user can use the teardrop retention portion during use of the lens. Tears stay. In other words, tear fluid stays between the lens according to the present embodiment and the cornea of the user. The lens for smart contact lenses according to the present embodiment provides appropriate visual acuity due to the retained tear fluid, regardless of whether the user has normal visual acuity or abnormal visual acuity such as general myopia, high myopia, and hyperopia. Will be done. The principle of providing proper visual acuity to the user by tears can be explained, for example, in an aquarium. The glass in the aquarium's aquarium is not given optical power, but the fish and objects in the aquarium can be seen clearly even by those with abnormal eyesight. This is because the refractive index of light in water is different from that in air, so even a person with abnormal eyesight can clearly see things in water. By applying this principle, the lens for smart contact lenses according to the present embodiment has abnormal visual acuity such as general myopia, high myopia, and hyperopia due to the stagnant tear fluid, even if the user has normal visual acuity. However, it is possible to see things clearly as if you were always looking at things in the water.

The lens for smart contact lenses according to the present embodiment is a tear that stays depending on the number and type of terraces in the second region (whether it is applied to the front surface or the back surface), the inclination width of the terrace, the outer peripheral shape of the terrace, and the like. Since the thickness (amount) of the liquid can be changed, it is possible to provide a lens applicable to various types of users such as those for normal vision, general myopia, high myopia, and hyperopia. In addition, at this time, regardless of the user's strict visual acuity, by preparing a small number of types of lenses for normal vision, general myopia, high myopia, hyperopia, etc., it can be applied to all users. Product development is possible. Furthermore, the lens for smart contact lenses according to the present embodiment can be used by a single lens even for users with any visual acuity condition such as normal vision, general myopia, high myopia, and hyperopia. It seems that it is possible to develop various products. Therefore, in the future, it is expected that a product development strategy such as purchasing a lens for smart contact according to the present embodiment will be possible as if the user selects sunglasses at a general mass retailer.

Further, as described above, the lens for smart contact lenses according to the present embodiment provides the user with appropriate visual acuity depending on the thickness of the tear fluid that stays, so that the lens itself corrects the shape of the cornea. It is not necessary to have a specific function, and it has a feature that a plano lens can be used.

Further, the lens for smart contact lenses according to the present embodiment can provide the user's appropriate visual acuity by the tear fluid of the user. Therefore, when applied to a smart contact lens, the user can maintain his / her eyesight even when the smart function is stopped or the energy supply to the smart function is stopped. Furthermore, even if the eyes are exhausted by using smart contact lenses, the smart contact lenses can be recovered by simply turning off the smart function, so that it is not necessary to remove the smart contact lenses.

(Third area)
The third region is an outer edge region of the lens for smart contact lenses provided on the outer peripheral side of the second region, and is a region provided with a curve that allows tears to flow in and out between the eye and the lens.

(Other areas)
The lens for smart contact lenses according to the present embodiment may have other regions (sometimes referred to as a fourth region) other than the first to third regions described above.

As another region, for example, a fourth region provided between the second region and the third region and having a fitting curve that assists the fitting between the user's eye and the lens for smart contact lenses. And so on.

The outer peripheral diameter of the entire lens of the lens for smart contact lenses according to the present embodiment is preferably 10 mm or more so that the terrace in the second region does not affect the shape of the cornea of the user. It is more preferably 16 mm or more.

Further, the thickness of the lens for smart contact lenses according to the present embodiment is preferably 0.03 mm or less so as not to affect the cornea of the user.

Since the lens for smart contact lenses according to the present embodiment can be applied to all users regardless of the visual acuity state of the user, when the smart function is given, a plurality of smart functions are distributed to one eye or both eyes. Can be granted.

An example in which it is confirmed that the tear fluid stays in the tear fluid retention portion in the second region by using the lens for a smart contact lens according to the present embodiment will be described below.

A blue pigment is added to the tears of a wearer wearing a lens for smart contact lenses in which the outer peripheral shape of the first region and the second region and the outer peripheral shape of the terrace shown in FIG. 4 are square, and a slit lamp is used. The amount of tear fluid was confirmed with a microscope.

FIG. 9 shows a diagram for explaining the retention of tear fluid when the lens for smart contact lens according to the present embodiment is attached. In this embodiment, when the tear fluid stays at the tear fluid retention portion, it can be confirmed as a ring of rings in a slit lamp microscope.

More specifically, when the tear thickness is 0.02 mm or less, a relatively dark and dark ring can be confirmed, and when the tear thickness exceeds 0.02 mm, it is relatively bright. You can see the brightly colored ring. Then, the data of the thickness and shape of the tear fluid in the created lens for smart contact lenses and the type of the user's appropriate visual condition (for example, normal myopia, general myopia, high myopia or hyperopia) corresponding to them are obtained. By creating in advance, it is possible to provide a lens that can be applied to various types of users such as those for normal vision, general myopia, high myopia, and hyperopia. At this time, regardless of the user's strict visual acuity, a small number of types of lenses for normal vision, general myopia, high myopia, hyperopia, etc. should be a single type lens that can be adapted to the total visual acuity state. With preparation, it is possible to develop products that are applicable to all users with a variety of different types of vision.

Claims (6)

Lenses that can be used with a single lens, a ready-made lens, or a small number of lenses, regardless of whether the user has normal vision, general myopia, high myopia, or hyperopia. A contact lens for smart contact lenses, the first region in which the center side is formed from a plano lens, and
A second region where terraces are formed on at least one of the front and back sides of the lens,
The third area, which is the peripheral edge,
Contact lenses for smart contact lenses. In the second region, the terrace is formed on the front side of the lens.
The contact lens for a smart contact lens according to claim 1. In the second region, the terrace is formed on the back side of the lens.
The contact lens for a smart contact lens according to claim 1. The outer peripheral shape of the second region has a shape selected from the group of square circle, ellipse, star, polygon and multi-deformation.
The contact lens for a smart contact lens according to any one of claims 1 to 3. Between the second region and the third region, there is a fourth region that assists in fitting between the smart contact lens and the user's eye.
The contact lens according to any one of claims 1 to 4.

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