KR102251842B1 - Support Structure for Artificial Eyes Lens - Google Patents

Abstract

The present invention relates to a support structure that replaces the lens and supports the intraocular lens implanted into the eyeball, and extends in an arc concentric with the lens of the artificial lens to form an inward opening and is adjacent to the rim of the lens of the artificial lens. Or a frame disposed to support an edge of one surface of the lens; A plurality of support portions that support the intraocular lens so that the intraocular lens does not deviate from the support structure and are spaced apart from each other in the circumferential direction of the frame; And a plurality of fixing portions extending outward from the frame in the radial direction of the frame and being inserted and fixed in a tunnel having a tip end formed in the sclera of the eye.

Description

Support Structure for Artificial Eyes Lens

The present invention relates to a support structure for an artificial lens, and more particularly, to a support structure for supporting the artificial lens in the eyeball without inserting and seating the artificial lens in the capsular bag.

As a treatment method for ophthalmic diseases that have abnormalities in the lens, such as cataracts, the contents of the lens inside the capsular sac are removed, and an artificial eye lens or intraocular lens manufactured artificially is placed in the space. Insertion surgery is mainly performed.

As an artificial lens, a lens that replaces the human lens and a haptic lens that supports the lens in the capsular bag is mainly used. One of the types primarily used for such an intraocular lens is shown in FIG. 1.

Haptic 120 is configured to support the lens by extending long and thin from the edge of the lens 110 in contact with the inner edge of the lens bag at the tip side, and two or four formed in opposite directions are mainly used. have. In Fig. 1, it is shown that two haptics are formed in a line symmetry.

When performing surgery to insert an artificial lens, a part of the front part of the capsular bag is cut in a circular shape, the capsular bag and the contents of the lens are separated, and the contents of the lens are cut and removed by aspiration, and then the artificial lens is inserted. In this process, the capsular bag is removed. It is often the case that the capsular bag becomes unsupported by receiving the artificial lens due to injury, congenital factors, or other disease.

In this case, a method of fixing the artificial lens to the eye by connecting a thread to the lens rim or haptic of the artificial lens, pulling the thread out of the sclera and fixing it to the sclera is used.

According to this surgical method, since the intraocular lens is supported in the eyeball by the thread, the intraocular lens is not placed in position or is distorted and disposed, so that the intraocular lens does not function properly and sufficient vision is not secured.

In particular, a thread that fixes the artificial lens may be sutured and fixed to the sclera, and bacteria may penetrate into the eyeball from the outside through the thread, causing a disease.

As a solution to this problem, Korean Patent Publication No. 10-1555298 (Document 1) proposes an invention entitled'artificial capsular bag'.

The invention of Document 1 proposes a structure in which a circular thin film is formed as a replacement for the capsular bag, and the thin film is knotted and fixed to the ciliary body in the eye with a fixation chamber.

However, in such a structure, it is very difficult and time consuming to place the artificial lens in the thin film, and in the end, since the thin film is fixed to the eyeball by a thread, the thin film cannot be disposed at the position of the lens in the eye, and it is twisted or deviated from the position. The problem arises as it is, and in particular, knotting and fixing the thread to the ciliary body is a very difficult task and takes a considerable amount of time.

Korean Patent Publication No. 10-1555298 (Document 1)

The present invention is to solve the problems of the prior art described above, and is to provide a support structure that supports the artificial lens in the eye.

Specifically, the present invention is to provide a support structure that fixes the eyeball by inserting and supporting the artificial lens into the capsular bag, so that the artificial lens does not distort or the lens of the artificial lens deviates from its position. It is intended to provide a support structure that supports the eyeball.

In particular, the present invention is to provide a support structure that enables the surgery to be easily performed in fixing the intraocular lens to the eyeball and to facilitate the implantation of the intraocular lens without fear of infection after the operation.

The above-described problem of the present invention is achieved by the support structure according to the present invention, which replaces the lens and supports the artificial lens implanted into the eyeball.

The supporting structure of this invention,

A frame that extends in an arc shape concentric with the lens of the artificial lens to form an opening inward, and is disposed to be adjacent to the rim of the lens of the artificial lens or to support the rim of one surface of the lens;

A plurality of support portions that support the intraocular lens so that the intraocular lens does not deviate from the support structure and are spaced apart from each other in the circumferential direction of the frame; And

A plurality of fixing parts extending from the frame to the outer side in the radial direction of the frame and inserted and fixed at the tip of the tunnel formed in the sclera of the eyeball

Including,
The intraocular lens includes a lens and a plurality of haptics extending radially outward of the lens from the lens to contact the capsular bag, and the intraocular lens is disposed on a frame such that each haptic protrudes between the supports.

The supporting structure of this configuration cuts the cornea and is inserted into the eyeball through the incision site of the cornea. Upon insertion, the frame of the supporting structure can be folded and inserted. In the inserted support structure, the frame is arranged concentrically with the pupil at the back of the iris.

The tip of the fixing part of the supporting structure is inserted into the sclera to form a fixed tunnel, and the tip of each fixing part is inserted into the tunnel of the sclera through the sclera and sealed. Thereby, the supporting structure of this invention is fixed in the eyeball.

The artificial lens is inserted through the incision site of the cornea, and the lens of the artificial lens is supported on the support and fixed to the support structure. In the case of an artificial lens with a haptic, the haptic is disposed protruding between the supports. In this way, the artificial lens is supported by the support structure of this invention and implanted into the eye.

According to the configuration of the supporting structure of this invention, the artificial lens is implanted and fixed to the eyeball without being supported by the capsular bag.

In addition, since the supporting structure of this invention is fixed to the eyeball without a separate means for fixing it to the eyeball, in particular, since the fixing part of the supporting structure is inserted and fixed in the tunnel formed in the sclera, the suture thread is passed through the sclera in transplantation surgery. Since there is no need to fix the supporting structure, the operation is simple and there is little risk of infection after the operation.

In addition, even if the capsular bag is damaged during an operation to insert the artificial lens into the capsular bag, the support structure of the present invention can be inserted into the eyeball to support the already inserted artificial lens in the eyeball.

The supporting structure of this invention can have four embodiments.

As a first embodiment, the supporting structure of this invention,

Each support portion extends from the frame and extends from the first portion of the lens of the intraocular lens in contact with the one surface opposite to the one surface of the frame, and the second portion extending from the tip of the first portion and in contact with the opposite surface of the one surface of the lens. The artificial lens may be supported by contacting the edges of both surfaces of the lens of the artificial lens with the first part and the second part of the support part.

As a second embodiment, the supporting structure of this invention,

Each of the supporting portions is composed of a first portion extending from the frame and in contact with the one surface opposite to one surface of the frame in the lens of the intraocular lens, and a second portion extending from the frame and in contact with the opposite surface of the one surface of the lens. The artificial lens may be supported by contacting the edges of both surfaces of the lens of the artificial lens with the first part and the second part of the artificial lens.

As a third embodiment, the supporting structure of the present invention,

The circumference of the one side surface of the artificial lens is in contact with one side of the frame, and each of the support portions extends from the frame and is configured to come into contact with a surface opposite to the side surface of the artificial lens, so that the edges of both surfaces of the lens are in contact with one side of the frame. The artificial lens can be supported by contacting the support.

According to the embodiments of the support structure of the present invention, the lens of the artificial lens is supported by a frame and a support part or only by a support part in the support structure of the present invention, and the support part has a structure separate from the frame. The frame and the support portion can be integrally formed by simple injection molding because the frame and the support portion can be formed as an integral part that extends by protruding from the frame.

In addition, the process of supporting and fixing the artificial lens to the support structure is performed within the eyeball.In the above-described embodiments of the present invention, the support portions are spaced apart from each other in the circumferential direction and protrude from the frame, so the edge of the lens of the artificial lens The intraocular lens can be supported by the support structure through a simple operation of allowing the lens to be inserted between the frame and the support or the support.

Fixation of the artificial lens that has been performed from the prior art to the present, that is, a surgery in which an artificial lens with a haptic attached thereto is inserted into the capsular bag so that the haptic is unfolded and supported by the capsular bag, or a thin film replacing the capsular bag is applied to the eyeball with a thread. It is very difficult and time consuming to fix the lens on and insert the artificial lens into the thin film.

However, according to the configuration of the support structure of the present invention, the support structure is fixed to the eyeball by simply inserting the support structure into the eyeball and then inserting the fixing part into the tunnel formed in the sclera. It is a simple operation of inserting the lens rim of the intraocular lens into the support and the intraocular lens is supported and fixed to the support structure.

Accordingly, in the present invention, the operation of inserting the support structure and fixing it to the eyeball and the operation of supporting the artificial lens on the fixed support structure can be performed in a very simple and quick time. In addition, in the present invention, almost all types of artificial lenses can be supported, so that the support structure of the present invention can be implanted into the eyeball without removing the previously inserted and dislocated artificial lens, so that the inserted artificial lens can be supported.

As a further embodiment of this invention,

The artificial lens includes a lens and a plurality of haptics extending radially outward of the lens from the lens and configured to contact the capsular bag,

Each support is formed in a ring shape fixed to the frame,

The haptics of the intraocular lens may be inserted into each ring to support the intraocular lens.

In this case, since the haptic constituting the artificial lens is inserted into and fixed to the ring of the support structure, the support of the artificial lens can be made more firmly and separation is reliably prevented.

On the other hand, the support structure of the present invention may be formed by injecting synthetic resin as a whole, but it is preferable that the fixing part is formed to have lower rigidity than the frame.

If the frame is formed to have lower rigidity than the fixed part, the frame can be folded and inserted in the operation of incising the cornea and inserting the supporting structure of this invention through the incision site of the cornea, so the insertion operation is made easy, but the fixed part is Compared to this, since it has high rigidity, the stability of the state in which the frame and the support part are supported by the sclera increases.

As an additional feature of this invention, in the support structure of this invention,

The front end side of the fixing part has the same curvature as the sclera and may be formed in a curve concentric with the frame.

According to this configuration, since the tip of the fixing part inserted into the tunnel formed in the sclera matches the shape of the sclera, it is easy to insert into the tunnel of the sclera and can be well seated after insertion.

However, in the support structure of the present invention, since the fixing portion is formed of a material having elasticity, it can be inserted and seated in the tunnel of the sclera even if it is formed in a different curvature or straight line from the sclera, or is not concentric with the frame.

As a further feature of the present invention, in the supporting structure of the present invention, a thread and a needle are sequentially coupled to the tip of the fixing part.

In surgery for implanting the supporting structure according to the present invention into the eye, the tip must be inserted into a tunnel formed outside the sclera by passing the sclera through a hole formed in the sclera.

According to a further feature of the present invention, a thread and a needle are coupled to the tip of the fixing part, so when inserting the supporting structure of the present invention into the eye, first insert the thread and needle connected to the tip of the fixing part into the eyeball, and then into the sclera. The needle is protruded to the outer surface of the sclera through the formed hole, and then the remaining elements of the supporting structure are inserted into the eyeball, and the needle protruding from the outer surface of the sclera is pulled. The tip of the fixing part protrudes to the outer surface of the sclera through the hole. A needle can be used when inserting the tip of the fixing part protruding in this way into the tunnel formed in the sclera.

After using the thread and needle, remove it from the tip of the fixing part.

As such, according to a further feature of the present invention, the operation of fixing the supporting structure according to the present invention to the sclera can be performed very easily.

1 is a diagram showing a commonly used artificial lens.
2 is a plan view showing a state in which an artificial lens is supported on a support structure according to a first embodiment of the present invention.
3 is a longitudinal sectional view taken along line AA of FIG. 2.
4 is a cross-sectional view of the eyeball showing a state in which the supporting structure of the intraocular lens according to the first embodiment of the present invention is inserted and fixed to the eyeball.
5 is a longitudinal cross-sectional view taken along line AA in FIG. 2, a view of a first modification of the support structure according to the first embodiment of the present invention.
6 is a longitudinal cross-sectional view taken along line AA in FIG. 2, a view of a second modification of the supporting structure according to the first embodiment of the present invention.
7 is a plan view showing a state in which the artificial lens is supported by the support structure of the artificial lens according to the second embodiment of the present invention.
8 is a longitudinal sectional view taken along line BB of FIG. 6.
9 is a view of the support structure as viewed from arrow C of FIG. 6.

Hereinafter, as detailed information for carrying out the present invention, the configuration and operation of the supporting structure according to embodiments of the present invention will be described in detail with reference to the drawings.

First, the configuration of the support structure 1 of the first embodiment will be described with reference to FIGS. 2 and 3.

The support structure 1 of the first embodiment is extended in an arc shape concentric with the lens 110 of the artificial intraocular lens 100 to form an opening 11 having a diameter larger than the maximum diameter of the pupil inward. Frame 10 disposed to face one surface, four support parts 20 disposed to be spaced apart from each other in the circumferential direction of the frame 10 to support the intraocular lens so that the intraocular lens does not deviate from the support structure 1, frame A plurality of fixing parts 30 that extend radially outward of the frame 10 from (10) and are inserted into and fixed to the tunnel formed in the sclera of the eyeball, and one end is fixed to the tip of the fixing part 30 It consists of a thread 40 extending from the tip of the top 30 and a needle 50 coupled to the tip of the thread 40.

In the first embodiment, the frame 10, the support part 20, and the fixing part 30 are integrally injection-molded, and the materials are PMMA (polymethyl methacrylate), polypropylene, polyimide, and silicone. (Silicone), acrylic resin (Acrylic), etc. may be used.

The frame 10, the support part 20, and the fixing part 30 may be made of resin of the same material, but in the support structure 1 of the first embodiment, the frame 10 and the support part 20 are fixed part 30 It may be made of a different material that is softer than the material forming the frame 10, only the frame 10 may be made of a different material that is softer than the support or fixing portion 30.

In this case, it may be integrally injection-molded using different types of materials, or may be bonded to each other after injection-molding the fixing part 30 separately from the frame 10 and the support part 20.

In this way, the frame 10 has lower rigidity compared to other parts, and when the support structure of the first embodiment is inserted into the eye, the frame 10 is folded or bent to facilitate insertion.

In addition, by increasing the thickness or width of the fixing part 30 compared to the frame 10 and the support part 20 to increase the overall cross-sectional area, the rigidity of the frame and the support part may be lower than that of the fixing part 30.

The frame 10 has a thin and flat cross-section as a whole and has a shape extending in a circular shape on a plane. The inside of the frame 10 has a circular opening 11, and the lens 110 of the artificial lens 100 is disposed in the opening 11.

Two fixing portions 30 extend from the frame 10.

Each of the fixing parts 30 is placed on the same plane as the frame 10, but extends in a straight line in the tangential direction from the frame 10 and is then formed in a curved shape in the same direction as the frame 10. .

The first portion 31 in contact with the frame 10 in the fixing portion 30 extends in a straight line, and forms a portion that extends toward the sclera in the eyeball when inserted into the eyeball.

The second part 32 spaced apart from the frame 10 in the fixing part 30 and extending in a curved shape is generally formed in an arc shape concentric with the frame 10, and its radius of curvature is formed equal to the radius of curvature of the sclera. When the supporting structure is implanted into the eye, the tip side of the second part 32 is inserted into the sclera.

On the other hand, in the support structures of the first and second embodiments to be described later, the second portions of the fixing portions are all formed with the same curvature as the radius of curvature of the sclera to facilitate insertion into the tunnel formed in the sclera. By forming the radius of curvature of 32 smaller than the radius of curvature of the sclera, the second portion 32 may be brought into close contact with the restoring force from the tunnel of the sclera to the inside of the sclera.

The two fixing parts 30 are arranged at 180 degrees apart from each other with respect to the frame 10 and are arranged in a line symmetry with respect to the center point of the frame 10.

Four support portions 20 are formed, and are disposed on the frame 10 at an equal interval of 90 degrees from each other.

Referring to the cross-sectional view of FIG. 3, each of the support portions 20 is from the first portion 21 and the first portion 21 extending inclined to the outside of the frame 10 from the plane formed by the frame 10. It consists of a second portion 22 that extends inclined to the inside of the frame.

According to the structure of this support, the rim of the one side surface 111 of the lens 110 of the artificial lens 110 is supported by the first part 21 of the support, and the rim of the opposite surface 112 is the second part 22 of the support part. Supported by

In this way, since each support part 20 restrains and supports both surfaces of the lens 110 of the artificial lens in a total of four places, the artificial lens 100 is coupled to the frame 10 by the support parts 20. Will be maintained.

In the support structure 1 of the first embodiment, a total of four support portions are installed, but only three support portions may be installed, or if the width is formed wide, the two support portions may be disposed symmetrically to each other.

A hole 34 is formed at the tip of the second part 32 of the fixing part 30, and one end of the thread 40 is coupled to the hole 34, and a needle ( 50) is combined. The thread 40 and the needle 50 guide the second part 32 of the fixing part 30 to be inserted into the sclera.

A description will be given of an action in which the artificial lens 100 is supported by the support structure 1 of the first embodiment.

The artificial lens 100 is the same as that shown in FIG. 1 and has a lens 110 and two haptics 120 extending from the edge of the lens.

The lens 110 is placed concentrically on the frame 10 and is fixed to the support structure 1 by the frame 10 and four support portions 20.

The edges of both surfaces 111 and 112 of the lens come into contact with the first portion 21 and the second portion 22 of the support portion 20. Since the support part 20 restrains the lens 110 at four positions, the lens 110 does not deviate from the support structure 1 in any direction.

Meanwhile, the haptic 120 of the intraocular lens protrudes between the support parts 20 and is placed in a protruding state out of the frame 10.

Since the haptic 120 of the artificial lens 100 is provided to be supported by the capsular bag of the human eye, when the artificial lens 100 is supported by the support structure 1 of the first embodiment, the haptic ( The haptic 120 of the artificial lens does not interfere with the use of the support structure 1 of the first embodiment, although the haptic 120 of this artificial lens does not perform any function.

4 shows a state in which the intraocular lens 100 is implanted in the eyeball and supported by the support structure 1 of Example 1. FIG.

Referring to FIG. 4, a state in which the artificial lens is supported by the support structure 1 of the first embodiment and implanted in the eye, and a surgical method for forming such a state will be described.

In order to implant the artificial lens 100 into the eye, first, the cornea 201 is cut and an instrument is inserted into the incision site to remove the damaged lens and capsular bag by aspiration.

Subsequently, the support structure 1 according to the first embodiment of the present invention is inserted through the incision in the cornea 201.

When the support structure 1 is inserted through the incision of the cornea 201, the frame 10 is folded or bent to insert it, and after being placed at the rear of the iris 202, the frame 10 is unfolded so that the frame 10 is concentric with the pupil 204. Arrange it so that it is.

The support structure of the first embodiment is made of a material having high elasticity, and in particular, the frame 10 has a softer or lower rigidity compared to the fixing part 30, so it is easy to be folded and inserted into the incision of the cornea 201, and the fixing part ( Since 30) is relatively hard or has high rigidity, it is advantageous for supporting the support structure 1 to the eyeball.

In the sclera 203, two holes (not shown) through which the second portion 32 of the fixing part 30 can pass through and come out to the outside are formed. Through these holes, the needle 50 is pulled out.

In the support structure 1, the frame 10 and the support part 20 are arranged to the rear of the iris 202, and when the needle 50 exposed to the outside of the sclera 203 is pulled, the thread 40 coupled to the needle is As it is pulled, the tip of the second part 32 of the fixing part is exposed to the outside of the sclera.

A tunnel (not shown) into which the tip of the second part 32 of the fixing part is inserted is formed in the sclera 203, and the tip of the fixing part 30 is inserted into the tunnel.

If necessary, the outer surface of the sclera between the tunnel and the hole of the sclera 203 passing through the fixing part is cut to form a groove in which the second part 32 of the fixing part is placed, and the tip 32 of the fixing part is formed. The groove can be closed after insertion into the tunnel.

After the tip of the fixing part 30 is exposed to the outside of the sclera 203, the thread 40 and the needle 50 are removed from the fixing part 30.

According to this configuration and action, in the surgery of inserting the support structure 1 and the artificial lens of the first embodiment into the eye, a very thin and elastic fixing part 30 is disposed through the sclera 203 and is disposed at the tip. Can be easily inserted into the tunnel.

After inserting the artificial lens 100 through the incision of the cornea 201, the rim of the lens 110 is fitted to the support part 20, so that the artificial lens 100 is attached to the support structure 1 of the first embodiment. It is fixed.

In this way, as shown in FIG. 4, the frame 10 and the support part 20 of the support structure 1 are disposed at the rear of the iris 102, and the fixing part 30 extends from the frame 10. The second part 32 penetrates the sclera 203 and the tip is inserted and fixed in the tunnel, and the lens 110 of the artificial lens is supported by the support structure 1 concentrically with the frame 10 of the support structure. It is implanted in the eye.

Meanwhile, in the above description, it has been described that the support structure 1 is fixed to the eye, and then the artificial lens 100 is inserted to be supported by the support structure 1, but in actual surgery, a different situation may occur.

For example, the capsular bag is damaged during surgery to remove the lens by aspiration from the eyeball and insert the artificial lens into the capsular bag so that the haptics of the artificial lens are supported by the capsular bag. Situations can arise that cannot be done. In addition, there is a case where the artificial lens implanted in the eyeball is not held in place due to trauma or disease, etc. and is dislodged into the vitreous cavity (106 in FIG. 4).

In such a case, the support structure 1 of the first embodiment is inserted through the incision of the cornea 201 and the process as described above is performed.

Meanwhile, the support part 20 of the support structure 1 may be disposed to face the rear side, that is, the opposite side of the cornea 201. That is, in the state shown in FIG. 3, the support part 20 is disposed forward, that is, toward the cornea 201 side, and the frame 10 is disposed at the rear side, but on the contrary, the frame 10 is disposed forward and the support part ( 20) is placed toward the rear retina 205.

By doing this, it is possible to easily fit the artificial intraocular lens 100 separated by the vitreous cavity 206 into the support part 20 of the support structure 1 disposed behind the iris 203.

However, even if the support structure 1 of the first embodiment is arranged in the state shown in FIG. 3, the artificial lens 100 that is separated from the vitreous cavity 206 through the opening 11 of the frame 10 is a support structure. It is possible to fix by moving toward the support part 20 of the.

Modification examples of the first embodiment will be described with reference to FIGS. 5 and 6.

5 and 6, except for the structures of the support portions 20-1 and 20-2, the other configurations are the same as those of the first embodiment.

In the support structure of the first modification shown in FIG. 5, the support part 20-1 extends vertically from the surface of the frame 10 and extends from the first part 23 to the inside of the frame 10. It consists of a second part (24).

With this structure, the rim of one surface 111 of the lens 110 of the artificial lens 110 is supported on the surface of the frame 10, and the rim of the other surface 112 is on the second part 24 of the support part 20'. Supported by

In the support structure of the first modified example shown in FIG. 6, the support part 20-2 has the first part 25 and the second part 26 from the end of the frame 10 on the side of the opening 11, that is, the inner circumference. They extend inclined to opposite sides.

Both surfaces of the rim of the lens 110 of the artificial lens are in contact with the first part 25 and the second part 26, so that the lens 110 is restrained and supported by the support part 20-2.

In the configuration of this modified example, as in the first embodiment shown in FIGS. 2 to 3, the lens 110 of the artificial lens is constrained to the support structure by the support portions 20-1 and 20-2 and the frame 10. It is supported, and the arrangement and number of the support portions 20-1 and 20-2 may also be configured in the same manner as in the first embodiment.

Next, the support structure 2 of the second embodiment will be described with reference to FIGS. 7 to 9.

The support structure 2 of the second embodiment is also the same as the first embodiment in that it is composed of a frame 10, a support part 20-3, and a fixing part 30, and only at the tip of the fixing part 30 It differs from the first embodiment in that the thread and the needle are not coupled and in the configuration of the support part 20-3.

However, in the support structure of the second embodiment, a thread and a needle may be combined for convenience of surgery.

The configuration of the support part 20-3 in the support structure 2 of the second embodiment will be described.

The support structure 2 of the second embodiment is provided with two support portions 20-3.

9 is a view as viewed from arrow C of FIG. 7, omitting the artificial lens 100 and showing only the support structure. Referring to FIG. 9, the support portion 20-3 is parallel to the surface of the frame 10 between the two second portions 28 and 28 extending obliquely from the surface of the frame 10. It consists of a first portion 27 that is spaced apart and extended by a predetermined distance.

Accordingly, the first and second portions 28 and 29 of the support 20-3 form a ring 29 together with the surface of the frame 10, so that the haptics 120 of the artificial lens 100 are respectively It is inserted into the ring 25 of and protrudes to the outside of the support structure (2).

In the artificial lens 100, one surface of the lens 110 is placed on the surface of the frame 10, and two haptics 120 are formed by a support part 20-3 and a ring 29 formed by the surface of the frame 10 It passes through and protrudes from the frame 10 of the support structure 2.

Accordingly, the artificial lens 100 is restrained and supported by the support structure 2.

The process of implanting the support structure 2 of the second embodiment into the eyeball and allowing the artificial lens 100 to be supported by the support structure is substantially the same as that of the first embodiment.

However, after implanting the support structure 2 of the second embodiment into the eyeball, the two haptics 120 of the artificial lens 100 must be inserted into the ring 25 formed by the support part 20-3 of the support structure. Is different from the first embodiment.

In addition to having two haptics, some artificial lenses have four haptics. In the case of such an intraocular lens, only two mutually haptics are inserted into the ring 25 of the support part 20-3, and the remaining haptics are disposed to protrude outward from the frame 10.

On the other hand, in the second embodiment, the ring 29 through which the haptic 120 of the artificial lens passes and is supported is formed by the frame 10 and the support part 20-3, but the support part is formed in a ring shape and the support part It can also be configured by coupling to a frame. In addition, although the shape of the ring is not limited, it is preferable to provide the haptic over a wide width of the frame 10 so that the haptic can be easily inserted and supported regardless of the arrangement and shape of the haptic 120.

The configuration and operation of the embodiments of the present invention have been described above, and the present invention is not limited to these embodiments, and various modifications are possible and components may be added within the scope described in the claims. The support structure and the support structure to which the components are added are within the scope of this invention.

1. 2: support structure 10: frame
20: support part 30: fixing part
100: artificial lens 110: lens
120: Haptic

Claims (8)

As a support structure that supports the intraocular lens implanted into the eyeball by replacing the capsular bag,
A frame that extends in an arc shape concentric with the lens of the artificial lens to form an opening inward, and is disposed to be adjacent to the rim of the lens of the artificial lens or to support the rim of one surface of the lens;
A plurality of support portions that support the intraocular lens so that the intraocular lens does not deviate from the support structure and are spaced apart from each other in the circumferential direction of the frame; And
A plurality of fixing parts extending from the frame to the outer side in the radial direction of the frame and inserted and fixed at the tip of the tunnel formed in the sclera of the eyeball
Including,
The artificial lens includes a lens and a plurality of haptics extending radially outward of the lens from the lens and configured to contact the capsular bag, and the artificial lens is a support structure disposed on a frame such that each haptic protrudes between the support portions. . The method according to claim 1,
Each support portion extends from the frame and includes a first portion of the lens of the intraocular lens in contact with the one surface opposite to the one surface of the frame, and a second portion extending from the tip of the first portion and in contact with the opposite surface of the one surface of the lens. And the artificial lens is supported by contacting edges of both surfaces of the lens of the artificial lens on the first and second parts of the support. The method according to claim 1,
Each of the supporting portions is composed of a first portion extending from the frame and in contact with the one surface opposite to one surface of the frame in the lens of the intraocular lens, and a second portion extending from the frame and in contact with the surface opposite to the surface of the lens. The support structure of which the artificial lens is supported by contacting the edges of both surfaces of the lens of the artificial lens with the first part and the second part of the artificial lens. The method according to claim 1,
The circumference of the one surface of the artificial lens is in contact with one surface of the frame, and each of the support portions extends from the frame and is configured to come into contact with a surface opposite to the surface of the one surface of the artificial lens. A support structure in which the artificial lens is supported by contacting the support. As a support structure that supports the intraocular lens implanted into the eye by replacing the lens,
A frame that extends in an arc shape concentric with the lens of the artificial lens to form an opening inward, and is disposed to be adjacent to the rim of the lens of the artificial lens or to support the rim of one surface of the lens;
A plurality of support portions that support the intraocular lens so that the intraocular lens does not deviate from the support structure and are spaced apart from each other in the circumferential direction of the frame; And
A plurality of fixing parts extending from the frame to the outer side in the radial direction of the frame and inserted and fixed at the tip of the tunnel formed in the sclera of the eyeball
Including,
The artificial lens includes a lens and a plurality of haptics extending radially outward of the lens from the lens and configured to contact the capsular bag,
Each support is formed in a ring shape fixed to the frame,
The haptics of the intraocular lens is inserted into each ring to support the intraocular lens. The method according to any one of claims 1 to 5,
Doedoe formed by injecting synthetic resin as a whole, the support structure that the fixing portion has a higher rigidity than the frame. The method according to any one of claims 1 to 5,
The supporting structure at the tip side of the fixing part has the same curvature as the sclera and is formed in a curve concentric with the frame. The method according to any one of claims 1 to 5,
A supporting structure in which a thread and a needle are sequentially coupled to the tip of the fixing part.

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