KR102222674B1 - Apparatus for fixing intraocular lens including supporting part deformed to T-shape - Google Patents

Abstract

The present invention, in a device for fixing an intraocular lens (IOL) including an optic through which light passes and a haptic extending from the optic to the sclera, provides an IOL fixation device equipped with a T-shaped deformable support part, comprising a support part selectively rotating toward the optic side. According to the IOL fixation device equipped with the T-shaped deformable support part, the IOL can be seated inside the eye without using a separate suture by installing the support part on the haptic of the IOL, withdrawing the support part out of the eye using the withdrawing part, and fixing the same to the sclera. Further, according to the present invention, by providing the support part with a first magnet and the withdrawing part with a second magnet, the support part can be more easily drawn out of the eyeball by using magnetic force. In addition, according to the present invention, the length of the haptic can be adjusted according to the situation by inserting the haptic slidably into the support part, and the support part can be rotatably installed with respect to the haptic, so that the haptic can be more effectively fixed to the sclera.

Description

TECHNICAL FIELD {Apparatus for fixing intraocular lens including supporting part deformed to T-shape}

The present invention relates to an artificial intraocular lens fixing device having a support that is transformed into a T-shape, and more particularly, after inserting the artificial intraocular lens into the eyeball, the haptic of the intraocular lens is fixed to the sclera. It relates to a device to let.

When the lens present in the human eye is denatured by aging, metabolic disease or trauma, the transparency of the lens is lost, which is called a cataract. When a cataract comes, the lens is removed, and then the insertion of an appropriate intraocular lens to correct the refractive state of the eye in place of the removed lens is essential. However, due to the fact that it is a patient with damage to the lens capsule and ciliary platoon that must support the lens or the intraocular lens after surgery in the existing human tissue, the ophthalmologist said that it is not a general surgical method of inserting an artificial lens into the lens capsule, but rather more complicated. Perform the considered scleral fixation.
In general, in intraocular lens scleral fixation, a very thin thread called 10-0 prolene is tied at both ends of the haptic lens of the intraocular lens via the sclera, and the intraocular lens is inserted into the eyeball, and the outer part of the eyeball. This is a method of fixing by suturing the thread of the sclera. This type of surgery increases the likelihood of complications such as loss of the vitreous body in the eye or infection in the eyeball due to a thread breakage during the operation, the thread is wound around an artificial lens, or the like, or due to a complex surgical method. In addition, the suture and the knot protruding out of the eyeball are buried under a thin tissue called the conjunctiva, but it is not uncommon to penetrate the conjunctiva after surgery and expose it to the outside of the conjunctiva. In the long term after surgery, you may experience a feeling of foreign body or discomfort, or suture-related infection.
Therefore, there is a need to develop a new medical aid that can stably place the intraocular lens inside the eyeball without complications while making the operation easier.

The present invention has been developed in response to the above needs, and an object of the present invention is to provide an artificial lens fixing device having a support that is transformed into a T shape capable of seating the intraocular lens inside the eyeball without the use of sutures.

The present invention is a device for fixing an intraocular lens (IOL) including an optic through which light passes and a haptic extending from the optic to a sclera, sliding to the haptic It is possible to provide an artificial lens fixing device having a support portion that is installed to be capable of being transformed into a T shape including a support portion that selectively rotates toward the optical side.
The support unit includes a support body into which the haptic is slidably inserted into the support body, and a fixing member installed on the support body and selectively fixing the haptic inserted into the support body to the support body.
The haptic, extending radially outward from an outer peripheral surface of the optic, is formed to bend toward the optic, and the support body includes a first support member disposed on the opposite side of the optic based on the haptic, and the And a second support member that is disposed on the side of the optic based on the haptic, is disposed to surround the haptic together with the first support member, and has a length shorter than that of the first support body.
The second support member has one end disposed on the same plane as one end of the first support member, and the fixing member is installed at the other end of the second support member, and the support body includes the fixing member as a center. To the optical side.
In the artificial lens fixing device having a support that is transformed into a T shape according to the present invention, after the artificial lens is inserted into the eyeball, it is coupled to the support to draw the support to the outside of the eyeball, and the support is sclera. It further includes a lead-out portion to be fixed to.
The support portion includes a support body into which the haptic is inserted, and a first magnet installed in the support body, and the withdrawal portion is installed in the withdrawal body and the withdrawal body, and pulls the first magnet. It includes a second magnet.
The second magnet is disposed inside an end of the withdrawal body on the side of the support, and the withdrawal portion protrudes from the end of the withdrawal body toward the support, and is arranged to be spaced apart from each other by a width of the first magnet. And, it further includes a pair of protruding members for selectively receiving the first magnet in the space between the spaced apart.
The first magnet is separated from the support body by the withdrawal portion after the support body is pulled out of the eyeball.
The support body is pulled out of the eyeball and then moves along the length of the haptic, and after a portion of the haptic protruding outward from the support body is cut, the end of the withdrawal portion faces the optic side. It is rotated and fixed to the sclera.

According to the artificial intraocular lens fixing device having a support part transforming into a T shape according to the present invention, the support part is installed on the haptic of the artificial lens, and the support part is drawn out of the eyeball using the withdrawal part, and then applied to the sclera. By fixing, the intraocular lens can be placed inside the eyeball without using a separate suture. Further, according to the present invention, by providing the first magnet in the support portion and the second magnet in the lead portion, it is possible to more easily take out the support portion out of the eyeball using magnetic force. In addition, according to the present invention, the haptic can be slidably inserted into the support unit, so that the length of the haptic can be adjusted according to the situation, and the support unit is rotatably installed with respect to the haptic, so that the haptic can be more effectively fixed to the sclera.

1 is a diagram showing the structure of an eyeball.
2 is a view showing a state in which the artificial lens fixing device having a support part transforming into a T shape according to the present invention is installed on the artificial lens.
3 is a view showing a state in which the withdrawal portion is coupled to the support.
4 is a view showing a state in which a lead-out part separates a first magnet part of a support part from a support body.
5 is a view showing a state in which the support body moves along the length of the haptic of the artificial lens.
6 is a view showing a state in which the support body rotates toward the optic of the artificial lens after the end of the haptic is cut.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.
1 to 6, an intraocular lens 10 is a place where a lens was previously located, and after being inserted through a surgical operation, it is fixed to the sclera and is then fixed to the eyeball. ) As to be seated inside, it includes an optical (11) and a haptic (12). The optic 11 is to be refracted by passing light, and serves as a conventional lens. The haptic 12 is fixed to the sclera to seat the optic 11 on the eyeball, and extends radially outward from the outer circumferential surface of the optic 11, and is formed in a shape that is curved toward the optic 11 .
The intraocular lens fixing device (hereinafter, referred to as'fixing device') 1000 having a support part transforming into a T-shape according to the present invention is for seating the intraocular lens 10 in the eyeball, and the support part 100 ) And a lead-out unit 1200.
The support part 1100 is installed on the haptic 12 and includes a support body 1110, a first magnet 1120, and a fixing member 1130. The support body 1110 is installed so that the haptic 12 is inserted therein. In this case, the support body 1110 includes a first support member 1111 and a second support member 1112. The first support member 1111 is disposed on the opposite side of the optic 11 based on the haptic 12. The second support member 1112 is disposed on the side of the optic 11 based on the haptic 12 and is disposed to surround the haptic 12 together with the first support member 1111.
The second support member 1112 is formed to be shorter than the first support member 1111 when the end of the support body 1110 is taken as a reference surface. More specifically, one end of the first support member 1111 and the second support member 1112 is disposed on the same plane with one end at the side of the lead portion 1200. In addition, the second support member 1112 has a length from one end to the other end shorter than that of the first support member 1111. The first magnet 1120 is disposed at one end of the first support member 1111 and the second support member 1112. In addition, the first magnet 1120 receives a force drawn to the second magnet 1220 by a magnetic force generated between the second magnet 1220 of the withdrawal portion 1200 to be described later.
The haptic 12 is slidably inserted into the support body 1110. In addition, the fixing member 1130 is installed on the support body 1110 and selectively fixes the haptic 12 inserted into the support body 1110 to the support body 1110. More specifically, the fixing member 1130 is installed on the opposite side of the first magnet 1120 based on the second support member 1112. That is, the fixing member 1130 is installed at the other end of the second support member 1112. In addition, the fixing member 1130 supports the haptic 12 so that the haptic 12 can slide inside the support body 1110, but when the haptic 12 is fixed to the sclera The haptic 12 is fixed to the support body 1110 so that the haptic 12 can no longer slide inside the support body 1110.
After the artificial lens 10 is inserted into the eyeball, the withdrawal part 1200 is coupled to the supporter 1100 to draw the supporter 100 to the outside of the eyeball. In addition, the withdrawal part 1200 fixes the support part 1100 to the sclera to completely seat the intraocular lens 10 inside the eyeball. To this end, the lead portion 1200 includes a lead body 1210, a second magnet 1220, and a pair of protruding members 1230.
The lead body 1210 has a larger width than the support body 1110. The second magnet 1220 is disposed inside an end portion of the withdrawal body 1210 on the side of the support part 1100, and pulls the first magnet 1120. Therefore, even if the second magnet 1220 does not have a separate member for fastening the withdrawal part 1200 to the support part 1100, the support part 1100 can be more easily withdrawn to the outside of the eyeball. . The pair of protruding members 1230 protrude toward the support 1100 from the end of the withdrawal main body 1210 and are disposed to be spaced apart from each other by the width of the first magnet 1120. The first magnet 1120 is pulled toward the lead portion 1200 by the second magnet 1220, and the first magnet 1120 is spaced apart between the pair of protruding members 1230. The first magnet 1120 is selectively accommodated in the space of. Accordingly, the support part 1100 is combined with the withdrawal part 1200 and is withdrawn to the outside of the eyeball by the withdrawal part 1200.
Hereinafter, a process of fixing the intraocular lens 10 to the eye by the fixing device 1000 according to the present invention will be described with reference to FIGS. 2 to 6.
Although not shown in the drawing, the intraocular lens 10 is inserted into the eyeball by using a separate tool, and more particularly, into the ciliary body shown in FIG. 1. At this time, the artificial intraocular lens 10 is inserted into the ciliary body while the support part 1100 is installed on the haptic 12.
2 and 3, after the intraocular lens 10 is inserted into the eyeball, the withdrawal part 1200 is inserted into the eyeball and is coupled to the support part 1100. In this case, the support part 1100 and the lead part 1200 are coupled to each other by an attractive force between the first magnet 1120 and the second magnet 1220. After being combined with the support part 1100, the withdrawal part 1200 draws the haptic 12 to which the support part 1100 and the support part 1100 are combined to the outside of the eyeball.
Referring to FIG. 4, after placing the support part 1100 and the haptic 12 on the sclera, the lead part 1200 separates the first magnet 1120 from the support body 1110. Next, referring to FIG. 5, the support body 1110 moves along the length of the haptic 12. In FIG. 5, the support body 1110 is shown to have moved to a portion where the haptic 12 and the optic 11 are connected, but the support body 1110 also moves toward the end of the haptic 12. I can.
Finally, referring to FIG. 6, a portion of the haptic 12 that protrudes outward from the end of the support body 1110 at the side of the lead portion 1200 is cut. In addition, the support body 1110 rotates around the fixing member 1130 so that an end thereof faces the optic 11 side. Since the length based on the end of the support body 1110 is shorter than the length of the first support member 1112, the support body 1110 is fixed It is possible to rotate around the member 1130. In this case, the support body 1110 is disposed at a right angle to the end of the haptic 12, that is, in a T-shape. Thereafter, the support body 1110 is fixed to the sclera, thereby fixing the haptic 12 to the sclera. Meanwhile, since the support body 1110 is fixed to the sclera and semi-permanently installed inside a human body, the support body 1110 may be formed of a material such as medical silicone.
According to the fixing device 1000 according to the present invention, the support part 1100 is installed on the haptic 12 of the artificial lens 10, and the support part 100 is attached to the eyeball using the withdrawal part 1200. By pulling out and fixing it to the sclera, the artificial lens 10 can be completely seated inside the eyeball without using a separate suture as in the prior art.
In addition, according to the present invention, by providing the first magnet 1120 to the support part 1100 and the second magnet 1220 to the lead-out part 1200, the support part 1100 is moved to the outside of the eyeball using magnetic force. It can be withdrawn more easily. In addition, according to the present invention, the haptic 12 is slidably inserted into the support part 1100 to adjust the length of the haptic 12 according to the situation, and the support part 1100 rotates with respect to the haptic 12 By being installed as possible, the haptic 12 can be more effectively fixed to the sclera.

10: artificial lens 11: optic
12: haptic 1000: artificial lens fixing device having a support that is transformed into a T-shape
1100: support part 1200: lead-out part

Claims (9)

In the device for fixing an intraocular lens (IOL) including an optic through which light passes and a haptic extending from the optic to a sclera,
It is installed to be slidably on the haptic, and includes a support portion selectively rotating toward the optic,
The support part,
A support body into which the haptic is slidably inserted therein,
It is installed on the support body, and includes a fixing member for selectively fixing the haptic inserted into the support body to the support body,
The haptic is extended radially outward from an outer peripheral surface of the optic, and is formed to be bent toward the optic,
The support body,
A first support member disposed on the opposite side of the optic based on the haptic,
An artificial intraocular lens fixing device comprising a second support member that is disposed on the side of the optic based on the haptic to surround the haptic together with the first support member, and has a length shorter than that of the first support member. delete delete The method according to claim 1,
The second support member, one end is disposed on the same plane as the one end of the first support member,
The fixing member is installed at the other end of the second support member,
The support body is an artificial intraocular lens fixing device that rotates toward the optic with the fixing member as a center. delete In the device for fixing an intraocular lens (IOL) including an optic through which light passes and a haptic extending from the optic to a sclera,
It is installed to be slidably on the haptic, and includes a support portion selectively rotating toward the optic,
After the intraocular lens is inserted into the eyeball, it is coupled to the support to draw out the support to the outside of the eyeball, and further comprises a drawer for fixing the support to the sclera,
The support part,
A support body into which the haptic is inserted,
It includes a first magnet installed on the support body,
The withdrawal part,
Withdrawal body,
An artificial intraocular lens fixing device installed on the withdrawal body and including a second magnet pulling the first magnet. The method of claim 6,
The second magnet is disposed inside an end of the withdrawal body on the side of the support,
The withdrawal part,
A pair of protruding members protruding from the end of the withdrawal body toward the support part, disposed to be spaced apart from each other by a width of the first magnet, and selectively receiving the first magnet into a space between the first magnets are further provided. IOL fixture comprising. The method of claim 6,
The first magnet is, after the support body is withdrawn to the outside of the eyeball, the artificial lens fixing device separated from the support body by the withdrawal portion. The method of claim 6,
The support body is pulled out of the eyeball and then moves along the length of the haptic, and after a portion of the haptic protruding outward from the support body is cut, the end of the withdrawal portion faces the optic side. An artificial intraocular lens fixing device that is rotated and fixed to the sclera.

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